From 88f8e66e56662549b77ba464dde74322f317aa3c Mon Sep 17 00:00:00 2001 From: Reid Townson Date: Wed, 6 Jul 2016 09:47:23 -0400 Subject: [PATCH 01/34] Add radionuclide source and spectrum Add support for radionuclide sources, with spectra contained in ENSDF format. Spectrum data file from LNHB are provided in a subsequent commit. The radionuclide source is in early development at this stage. Radionuclide sources may emit a combination of particle types from beta emission, transition photons, x-rays and Auger electrons. The radionuclide spectrum tracks excited daughter states and emits correlated transition photons. Alpha emissions are modelled, but alpha particles are discarded. Decay structures are created in egs_ensdf as tree hierarchies, based on data from the ENSDF format files. The decay structures are used to sample emissions for the radionuclide spectrum. Multiple radionuclide spectra may be specified for one radionuclide source along with weights to balance relative activities of mixtures. The radionuclide source can access the time of emission and shower number of the most recent source particle using getTime() and getShowerIndex(). These calls allow applications to implement coincidence counting scenarios. The time of each disintegration is uniformly distributed over the total simulation time (determined from ncase and the total mixture activity provided as an input). Transition photons sample their delay from the correlated disintegration based on their half-life for emission. This implementation may need some refinement. In this initial commit, beta emissions are not modelled correctly. Instead of the appropriate energy spectrum, the beta energies are sampled uniformly between 0 and the maximum. This will be improved in a subsequent commit. --- HEN_HOUSE/egs++/Makefile | 6 +- HEN_HOUSE/egs++/egs_base_source.h | 85 ++ HEN_HOUSE/egs++/egs_ensdf.cpp | 1307 +++++++++++++++++ HEN_HOUSE/egs++/egs_ensdf.h | 422 ++++++ HEN_HOUSE/egs++/egs_spectra.cpp | 358 ++++- .../sources/egs_radionuclide_source/Makefile | 44 + .../egs_radionuclide_source.cpp | 298 ++++ .../egs_radionuclide_source.h | 369 +++++ 8 files changed, 2884 insertions(+), 5 deletions(-) create mode 100644 HEN_HOUSE/egs++/egs_ensdf.cpp create mode 100644 HEN_HOUSE/egs++/egs_ensdf.h create mode 100644 HEN_HOUSE/egs++/sources/egs_radionuclide_source/Makefile create mode 100644 HEN_HOUSE/egs++/sources/egs_radionuclide_source/egs_radionuclide_source.cpp create mode 100644 HEN_HOUSE/egs++/sources/egs_radionuclide_source/egs_radionuclide_source.h diff --git a/HEN_HOUSE/egs++/Makefile b/HEN_HOUSE/egs++/Makefile index 54e53c00d..74b395f00 100644 --- a/HEN_HOUSE/egs++/Makefile +++ b/HEN_HOUSE/egs++/Makefile @@ -41,7 +41,8 @@ egspp_files = egs_input egs_base_geometry egs_library egs_transformations \ egs_projectors egs_alias_table egs_object_factory egs_spectra \ egs_base_source egs_functions egs_application egs_run_control \ egs_scoring egs_interpolator egs_atomic_relaxations \ - egs_ausgab_object egs_particle_track egs_fortran_geometry + egs_ausgab_object egs_particle_track egs_fortran_geometry \ + egs_ensdf egspp_objects = $(addprefix $(DSO1), $(addsuffix .$(obje), $(egspp_files))) config1h = $(IEGS1)$(DSEP)egs_config1.h egs_libconfig.h egs_functions.h @@ -54,7 +55,8 @@ geometry_libs = egs_planes egs_cd_geometry egs_gtransformed egs_nd_geometry \ source_libs = egs_collimated_source egs_isotropic_source egs_parallel_beam \ egs_point_source egs_source_collection egs_transformed_source \ - egs_beam_source egs_phsp_source egs_angular_spread iaea_phsp_source + egs_beam_source egs_phsp_source egs_angular_spread \ + iaea_phsp_source egs_radionuclide_source shape_libs = egs_circle egs_ellipse egs_extended_shape egs_gaussian_shape \ egs_line_shape egs_polygon_shape egs_rectangle egs_shape_collection \ diff --git a/HEN_HOUSE/egs++/egs_base_source.h b/HEN_HOUSE/egs++/egs_base_source.h index dad92d7a4..af5006e1d 100644 --- a/HEN_HOUSE/egs++/egs_base_source.h +++ b/HEN_HOUSE/egs++/egs_base_source.h @@ -133,6 +133,13 @@ class EGS_EXPORT EGS_BaseSource : public EGS_Object { EGS_Float &E, EGS_Float &wt, // energy and weight EGS_Vector &x, EGS_Vector &u) = 0; // position and direction +// virtual EGS_I64 getNextParticle(EGS_RandomGenerator *rndm, +// int &q, int &latch, // charge and latch +// EGS_Float &E, EGS_Float &wt, // energy and weight +// EGS_Vector &x, EGS_Vector &u, // position and direction +// EGS_I64 &ishower, EGS_Float &time +// ) {}; + /*! \brief Set the next simulation chunk to start at \a nstart and to consist of \a nrun particles. @@ -168,6 +175,28 @@ class EGS_EXPORT EGS_BaseSource : public EGS_Object { * simulation source). */ virtual EGS_Float getFluence() const = 0; + + /*! \brief Get the time of emission for the most recently sampled particle + * + * This method is only reimplemented by EGS_RadionuclideSource. It + * returns the emission time of the particle that was most recently sampled. + */ + virtual double getTime() const {}; + + /*! \brief Get the shower index for radionuclide emissions + * + * This method is only reimplemented by EGS_RadionuclideSource. It + * gets the index of the most recent shower. + */ + virtual EGS_I64 getShowerIndex() const {}; + + /*! \brief Prints out the sampled emissions for radionuclide spectra + * + * This method is only reimplemented by EGS_RadionuclideSource. It + * prints the actual sampled intensity of each type of emission from + * the radionuclide spectra. + */ + virtual void printSampledEmissions() {}; /*! \brief Store the source state into the stream \a data_out. * @@ -309,6 +338,7 @@ class EGS_EXPORT EGS_BaseSource : public EGS_Object { * \link EGS_DoubleGaussianSpectrum a double-Gaussian spectrum\endlink, * \link EGS_UniformSpectrum a uniform spectrum\endlink and * \link EGS_TabulatedSpectrum a tabulated spectrum\endlink. + * \link EGS_RadionuclideSpectrum a radionuclide spectrum\endlink. * */ class EGS_EXPORT EGS_BaseSpectrum { @@ -349,6 +379,61 @@ class EGS_EXPORT EGS_BaseSpectrum { sum_E2 += e*e; return e; }; + + /*! \brief Get the charge for the most recently sampled particle + * + * This method is only reimplemented by EGS_RadionuclideSpectrum. It + * returns the charge of the particle that was most recently sampled + * using sampleEnergy(). + */ + virtual int getCharge() const {}; + + /*! \brief Get the time of emission for the most recently sampled particle + * + * This method is only reimplemented by EGS_RadionuclideSpectrum. It + * returns the emission time of the particle that was most recently sampled + * using sampleEnergy(). + */ + virtual double getTime() const {}; + + /*! \brief Set the maximum time of emission + * + * This method is only reimplemented by EGS_RadionuclideSpectrum. It + * sets the maximum time, or the length of the experiment for + * simulations using the time variable. + */ + virtual void setMaximumTime(double maxTime) {}; + + /*! \brief Get the shower index for radionuclide emissions + * + * This method is only reimplemented by EGS_RadionuclideSpectrum. It + * gets the index of the most recent shower produced using sampleEnergy(). + */ + virtual EGS_I64 getShowerIndex() const {}; + + /*! \brief Get the spectrum weight for radionuclide spectra + * + * This method is only reimplemented by EGS_RadionuclideSpectrum. It + * gets the weight of the spectrum to balance emissions from multiple + * spectra. + */ + virtual EGS_Float getSpectrumWeight() const {}; + + /*! \brief Set the spectrum weight for radionuclide spectra + * + * This method is only reimplemented by EGS_RadionuclideSpectrum. It + * sets the weight of the spectrum to balance emissions from multiple + * spectra. This allows a source to normalize the spectrum weights. + */ + virtual void setSpectrumWeight(EGS_Float newWeight) {}; + + /*! \brief Prints out the sampled emissions for radionuclide spectra + * + * This method is only reimplemented by EGS_RadionuclideSpectrum. It + * prints the actual sampled intensity of each type of emission from + * the radionuclide spectra. + */ + virtual void printSampledEmissions() {}; /*! \brief Get the maximum energy of this spectrum. * diff --git a/HEN_HOUSE/egs++/egs_ensdf.cpp b/HEN_HOUSE/egs++/egs_ensdf.cpp new file mode 100644 index 000000000..5c384e8f2 --- /dev/null +++ b/HEN_HOUSE/egs++/egs_ensdf.cpp @@ -0,0 +1,1307 @@ +/* +############################################################################### +# +# EGSnrc egs++ ensdf +# Copyright (C) 2015 National Research Council Canada +# +# This file is part of EGSnrc. +# +# EGSnrc is free software: you can redistribute it and/or modify it under +# the terms of the GNU Affero General Public License as published by the +# Free Software Foundation, either version 3 of the License, or (at your +# option) any later version. +# +# EGSnrc is distributed in the hope that it will be useful, but WITHOUT ANY +# WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS +# FOR A PARTICULAR PURPOSE. See the GNU Affero General Public License for +# more details. +# +# You should have received a copy of the GNU Affero General Public License +# along with EGSnrc. If not, see . +# +############################################################################### +# +# Author: Reid Townson, 2016 +# +# Contributors: +# +############################################################################### +*/ + +/*! \file egs_ensdf.cpp + * \brief The ensdf implementation + * \RT + * + */ + +#include "egs_ensdf.h" + +EGS_Ensdf::EGS_Ensdf(const string isotope, const string ensdf_filename) { + + if(ensdf_file.is_open()) { + ensdf_file.close(); + } + + radionuclide = isotope.substr(0, isotope.find_last_of(".")); + + printf("EGS_Ensdf::EGS_Ensdf: Isotope: " + "%s\n",isotope.c_str()); + printf("EGS_Ensdf::EGS_Ensdf: Now loading ensdf file: " + "\"%s\"\n",ensdf_filename.c_str()); + + ensdf_file.open(ensdf_filename.c_str(),ios::in); + if(!ensdf_file.is_open()) { + egsWarning("EGS_Ensdf::EGS_Ensdf: failed to open ensdf file %s" + " for reading\n",ensdf_filename.c_str()); + return; + } + + string line; + vector ensdf; + while(getline(ensdf_file, line)) { + ensdf.push_back(line); + } + + if(ensdf_file.is_open()) { + ensdf_file.close(); + } + + // Get the isotope + if(!createIsotope(ensdf)) { + egsWarning("EGS_Ensdf::EGS_Ensdf: error reading ensdf isotope data\n"); + return; + } + +} + +EGS_Ensdf::~EGS_Ensdf() { + if(ensdf_file.is_open()) { + ensdf_file.close(); + } + + for(vector::iterator it = myParentRecords.begin(); + it!=myParentRecords.end(); it++) { + delete *it; + *it=0; + } + myParentRecords.clear(); + for(vector::iterator it = + myNormalizationRecords.begin(); + it!=myNormalizationRecords.end(); it++) { + delete *it; + *it=0; + } + myNormalizationRecords.clear(); + for(vector::iterator it = + myLevelRecords.begin(); + it!=myLevelRecords.end(); it++) { + delete *it; + *it=0; + } + myLevelRecords.clear(); + for(vector::iterator it = + myBetaMinusRecords.begin(); + it!=myBetaMinusRecords.end(); it++) { + delete *it; + *it=0; + } + myBetaMinusRecords.clear(); + for(vector::iterator it = + myBetaPlusRecords.begin(); + it!=myBetaPlusRecords.end(); it++) { + delete *it; + *it=0; + } + myBetaPlusRecords.clear(); + for(vector::iterator it = + myGammaRecords.begin(); + it!=myGammaRecords.end(); it++) { + delete *it; + *it=0; + } + myGammaRecords.clear(); + for(vector::iterator it = + myAlphaRecords.begin(); + it!=myAlphaRecords.end(); it++) { + delete *it; + *it=0; + } + myAlphaRecords.clear(); +} + +string egsRemoveWhite(string myString) { + string result = ""; + + for(unsigned int i = 0; i ensdf) { + + // The daughter isotope name + string id = ensdf.front().substr(0,5); + string daughter = egsRemoveWhite(id); + + // The parent element + string element = radionuclide.substr(0, radionuclide.find("-")); + + // The atomic weight + A = findAtomicWeight(element); + if(A == 0) { + egsWarning("EGS_Ensdf::createIsotope: element does not exist in our " + "data (%s)\n", element.c_str()); + return false; + } + + // Parse the ensdf data + parseEnsdf(ensdf); + + return true; +} + +map EGS_Ensdf::getElementMap() { + map elementTable; + elementTable["H"] = 1; + elementTable["HE"] = 2; + elementTable["LI"] = 3; + elementTable["BE"] = 4; + elementTable["B"] = 5; + elementTable["C"] = 6; + elementTable["N"] = 7; + elementTable["O"] = 8; + elementTable["F"] = 9; + elementTable["NE"] = 10; + elementTable["NA"] = 11; + elementTable["MG"] = 12; + elementTable["AL"] = 13; + elementTable["SI"] = 14; + elementTable["P"] = 15; + elementTable["S"] = 16; + elementTable["CL"] = 17; + elementTable["AR"] = 18; + elementTable["K"] = 19; + elementTable["CA"] = 20; + elementTable["SC"] = 21; + elementTable["TI"] = 22; + elementTable["V"] = 23; + elementTable["CR"] = 24; + elementTable["MN"] = 25; + elementTable["FE"] = 26; + elementTable["CO"] = 27; + elementTable["NI"] = 28; + elementTable["CU"] = 29; + elementTable["ZN"] = 30; + elementTable["GA"] = 31; + elementTable["GE"] = 32; + elementTable["AS"] = 33; + elementTable["SE"] = 34; + elementTable["BR"] = 35; + elementTable["KR"] = 36; + elementTable["RB"] = 37; + elementTable["SR"] = 38; + elementTable["Y"] = 39; + elementTable["ZR"] = 40; + elementTable["NB"] = 41; + elementTable["MO"] = 42; + elementTable["TC"] = 43; + elementTable["RU"] = 44; + elementTable["RH"] = 45; + elementTable["PD"] = 46; + elementTable["AG"] = 47; + elementTable["CD"] = 48; + elementTable["IN"] = 49; + elementTable["SN"] = 50; + elementTable["SB"] = 51; + elementTable["TE"] = 52; + elementTable["I"] = 53; + elementTable["XE"] = 54; + elementTable["CS"] = 55; + elementTable["BA"] = 56; + elementTable["LA"] = 57; + elementTable["CE"] = 58; + elementTable["PR"] = 59; + elementTable["ND"] = 60; + elementTable["PM"] = 61; + elementTable["SM"] = 62; + elementTable["EU"] = 63; + elementTable["GD"] = 64; + elementTable["TB"] = 65; + elementTable["DY"] = 66; + elementTable["HO"] = 67; + elementTable["ER"] = 68; + elementTable["TM"] = 69; + elementTable["YB"] = 70; + elementTable["LU"] = 71; + elementTable["HF"] = 72; + elementTable["TA"] = 73; + elementTable["W"] = 74; + elementTable["RE"] = 75; + elementTable["OS"] = 76; + elementTable["IR"] = 77; + elementTable["PT"] = 78; + elementTable["AU"] = 79; + elementTable["HG"] = 80; + elementTable["TL"] = 81; + elementTable["PB"] = 82; + elementTable["BI"] = 83; + elementTable["PO"] = 84; + elementTable["AT"] = 85; + elementTable["RN"] = 86; + elementTable["FR"] = 87; + elementTable["RA"] = 88; + elementTable["AC"] = 89; + elementTable["TH"] = 90; + elementTable["PA"] = 91; + elementTable["U"] = 92; + elementTable["NP"] = 93; + elementTable["PU"] = 94; + elementTable["AM"] = 95; + elementTable["CM"] = 96; + elementTable["BK"] = 97; + elementTable["CF"] = 98; + elementTable["ES"] = 99; + elementTable["FM"] = 100; + elementTable["MD"] = 101; + elementTable["NO"] = 102; + elementTable["LR"] = 103; + elementTable["RF"] = 104; + elementTable["DB"] = 105; + elementTable["SG"] = 106; + elementTable["BH"] = 107; + elementTable["HS"] = 108; + elementTable["MT"] = 109; + elementTable["DS"] = 110; + elementTable["RG"] = 111; + elementTable["CN"] = 112; + elementTable["UUT"] = 113; + elementTable["UUQ"] = 114; + elementTable["UUP"] = 115; + elementTable["UUH"] = 116; + elementTable["UUS"] = 117; + elementTable["UUO"] = 118; + + return elementTable; +} + +unsigned short int EGS_Ensdf::findAtomicWeight(string element) { + transform(element.begin(), element.end(), element.begin(), ::toupper); + + map elementMap = getElementMap(); + + if(elementMap.find(element) != elementMap.end()) { + return elementMap[element]; + } else { + return 0; + } +} + +// Parse an ensdf file to create a decay structure +void EGS_Ensdf::parseEnsdf(vector ensdf) { + /* IDs of recordStack + * 0 Identification (not used) + * 1 History (not used) + * 2 Q-value + * 3 Cross-Reference (not used) + * 4 Comment + * 5 Parent + * 6 Normalization + * 7 Level + * 8 Beta- + * 9 EC + Beta+ + * 10 Alpha + * 11 Delayed Particle + * 12 Gamma + * 13 Reference (not used) + * */ + for(int i = 0; i < 14; i++) { + recordStack.push_back(vector()); + } + + // Loop over each line + // When we recognize a line as containing an important record, + // add it to the recordStack + // Any time we get to a new record (line[5]==' '), call buildRecords() + for(vector::iterator it = ensdf.begin(); it!=ensdf.end();it++) { + + string line = *it; + printf("ENSDF::parseEnsdf: %s\n", line.c_str()); + // Identification + if(line[6]==' ' && line[7]==' ' && line[8]==' ') { + + // History + } else if(line[6]==' ' && line[7]=='H' && line[8]==' ') { + + // Q-value + } else if(line[6]== ' ' && line[7]=='Q' && line[8]==' ') { + + // Cross-Reference + } else if(line[6]==' ' && line[7]=='X') { + + // Comment + } else if((line[6]=='C' || line[6]=='D' || line[6]=='T' || + line[6]=='c' || line[6]=='d' || line[6]=='t')) { + if(line[5]==' ') { + buildRecords(); + } + recordStack[4].push_back(line); + + //Parent + } else if(line[6]==' ' && line[7]=='P') { + if(line[5]==' ') { + buildRecords(); + } + recordStack[5].push_back(line); + + // Normalization + } else if(line[6]==' ' && line[7]=='N') { + if(line[5]==' ') { + buildRecords(); + } + recordStack[6].push_back(line); + + // Level + } if(line[6]==' ' && line[7]=='L' && line[8]== ' ') { + if(line[5]==' ') { + buildRecords(); + } + recordStack[7].push_back(line); + + // Beta- + } else if(line[6]==' ' && line[7]=='B' && line[8]==' ') { + if(line[5]==' ') { + buildRecords(); + } + recordStack[8].push_back(line); + + // Beta+ and Electron Capture + } else if(line[6]==' ' && line[7]=='E' && line[8]==' ') { + if(line[5]==' ') { + buildRecords(); + } + recordStack[9].push_back(line); + + // Alpha + } else if(line[6]==' ' && line[7]=='A' && line[8]==' ') { + if(line[5]==' ') { + buildRecords(); + } + recordStack[10].push_back(line); + + // Delayed Particle + } else if(line[6]==' ' && (line[7]=='D' || line[7]==' ') && + (line[8]=='N' || line[8]=='P' || line[8]=='A')) { + if(line[5]==' ') { + buildRecords(); + } + recordStack[11].push_back(line); + + // Gamma + } else if(line[6]==' ' && line[7]=='G' && line[8]==' ') { + if(line[5]==' ') { + buildRecords(); + } + recordStack[12].push_back(line); + } + } + + // Build the records into objects + if(!recordStack.empty()) { + buildRecords(); + } + + // Combine the beta- and beta+ records together + for(vector::iterator it = myBetaMinusRecords.begin(); + it!=myBetaMinusRecords.end(); it++) { + + myBetaRecords.push_back(*it); + } + + for(vector::iterator it = myBetaPlusRecords.begin(); + it!=myBetaPlusRecords.end(); it++) { + + myBetaRecords.push_back(*it); + } + + // Get X-ray and auger emissions from comments + getEmissionsFromComments(); + + for(unsigned int i=0; i < xrayEnergies.size(); ++i) { + printf("EGS_Ensdf::parseEnsdf: XRays (E,I): %f %f\n", + xrayEnergies[i], xrayIntensities[i]); + } + for(unsigned int i=0; i < augerEnergies.size(); ++i) { + printf("EGS_Ensdf::parseEnsdf: Auger (E,I): %f %f\n", + augerEnergies[i], augerIntensities[i]); + } +} + +// Create record objects from the arrays +void EGS_Ensdf::buildRecords() { + ParentRecord *LastParent = 0; + if(!myParentRecords.empty()) { + LastParent = myParentRecords.back(); + } + NormalizationRecord *LastNormalization = 0; + if(!myNormalizationRecords.empty()) { + LastNormalization = myNormalizationRecords.back(); + } + LevelRecord *LastLevel = 0; + if(!myLevelRecords.empty()) { + LastLevel = myLevelRecords.back(); + } + + for(int i = 0; i < recordStack.size(); i++) { +// printf("EGS_Ensdf::buildRecords:test %d\n",i); + if(!recordStack[i].empty()) { + if(i==0) { + + } else if(i==1) { + + } else if(i==2) { + + } else if(i==3) { + + } else if(i==4) { + myCommentRecords.push_back(new CommentRecord(recordStack[i])); + } else if(i==5) { + myParentRecords.push_back(new ParentRecord(recordStack[i])); + } else if(i==6) { + myNormalizationRecords.push_back(new + NormalizationRecord(recordStack[i], LastParent)); + } else if(i==7) { + myLevelRecords.push_back(new LevelRecord(recordStack[i])); + } else if(i==8) { + myBetaMinusRecords.push_back(new + BetaMinusRecord(recordStack[i], LastParent, + LastNormalization, LastLevel)); + } else if(i==9) { + myBetaPlusRecords.push_back(new + BetaPlusRecord(recordStack[i], LastParent, + LastNormalization, LastLevel)); + } else if(i==10) { + myAlphaRecords.push_back(new + AlphaRecord(recordStack[i], LastParent, + LastNormalization, LastLevel)); + } else if(i==11) { + printf("EGS_Ensdf::buildRecords: ERROR: Delayed particle not " + "supported! Further development required.\n"); + } else if(i==12) { + myGammaRecords.push_back(new + GammaRecord(recordStack[i], LastNormalization, LastLevel)); + } + + recordStack[i].clear(); + } + } +} + +// Normalize intensities for alpha, beta, gamma objects +void EGS_Ensdf::normalizeIntensities() { + + // Add up the beta, alpha, xray and auger decay intensities + double totalDecayIntensity = 0; + double lastIntensity = 0; + for(vector::iterator beta = myBetaRecords.begin(); + beta != myBetaRecords.end(); beta++) { + + printf("EGS_Ensdf::normalizeIntensities: Beta (E,I): %f %f\n", + (*beta)->getFinalEnergy(), (*beta)->getBetaIntensity()); + + totalDecayIntensity += (*beta)->getBetaIntensity(); + } + for(vector::iterator alpha = myAlphaRecords.begin(); + alpha != myAlphaRecords.end(); alpha++) { + + printf("EGS_Ensdf::normalizeIntensities: Alpha (E,I): %f %f\n", + (*alpha)->getFinalEnergy(), (*alpha)->getAlphaIntensity()); + + totalDecayIntensity += (*alpha)->getAlphaIntensity(); + } + for(unsigned int i=0; i < xrayIntensities.size(); ++i) { + printf("EGS_Ensdf::normalizeIntensities: XRay (E,I): %f %f\n", + xrayEnergies[i], xrayIntensities[i]); + + totalDecayIntensity += xrayIntensities[i]; + } + for(unsigned int i=0; i < augerIntensities.size(); ++i) { + printf("EGS_Ensdf::normalizeIntensities: Auger (E,I): %f %f\n", + augerEnergies[i], augerIntensities[i]); + + totalDecayIntensity += augerIntensities[i]; + } + + printf("EGS_Ensdf::normalizeIntensities: totalDecayIntensity: " + "%f\n",totalDecayIntensity); + + // Normalize beta emission intensities + for(vector::iterator beta = myBetaRecords.begin(); + beta != myBetaRecords.end(); beta++) { + + (*beta)->setBetaIntensity( + (*beta)->getBetaIntensity() / totalDecayIntensity); + + if((beta - myBetaRecords.begin()) > 0) { + (*beta)->setBetaIntensity( + (*beta)->getBetaIntensity() + (*(beta-1))->getBetaIntensity()); + } + lastIntensity = (*beta)->getBetaIntensity(); + + printf("EGS_Ensdf::normalizeIntensities: Beta (E,I): %f %f\n", + (*beta)->getFinalEnergy(), (*beta)->getBetaIntensity()); + } + + // Normalize alpha emission intensities + for(vector::iterator alpha = myAlphaRecords.begin(); + alpha != myAlphaRecords.end(); alpha++) { + + (*alpha)->setAlphaIntensity( + (*alpha)->getAlphaIntensity() / totalDecayIntensity); + + if((alpha - myAlphaRecords.begin()) == 0 && lastIntensity > 0) { + (*alpha)->setAlphaIntensity( + (*alpha)->getAlphaIntensity() + lastIntensity); + } else if((alpha - myAlphaRecords.begin()) > 0) { + (*alpha)->setAlphaIntensity( + (*alpha)->getAlphaIntensity() + + (*(alpha-1))->getAlphaIntensity()); + } + lastIntensity = (*alpha)->getAlphaIntensity(); + } + + // Normalize XRay emission intensities + for(unsigned int i=0; i < xrayIntensities.size(); ++i) { + xrayIntensities[i] /= totalDecayIntensity; + + if(i==0 && lastIntensity > 0) { + xrayIntensities[i] += lastIntensity; + } else if(i > 0) { + xrayIntensities[i] += xrayIntensities[i-1]; + } + lastIntensity = xrayIntensities[i]; + } + + // Normalize auger emission intensities + for(unsigned int i=0; i < augerIntensities.size(); ++i) { + augerIntensities[i] /= totalDecayIntensity; + + if(i==0 && lastIntensity > 0) { + augerIntensities[i] += lastIntensity; + } else if(i > 0) { + augerIntensities[i] += augerIntensities[i-1]; + } + lastIntensity = augerIntensities[i]; + } + + // Get the gamma transition intensities + // and the total intensity for each level + unsigned int j = 0; + vector totalLevelIntensity; + totalLevelIntensity.resize(myLevelRecords.size()); + for(vector::iterator it = myLevelRecords.begin(); + it!=myLevelRecords.end(); it++) { + + totalLevelIntensity[j] = 0; + for(vector::iterator gamma = myGammaRecords.begin(); + gamma != myGammaRecords.end(); gamma++) { + + if((*gamma)->getLevelRecord() == (*it)) { + totalLevelIntensity[j] += (*gamma)->getTransitionIntensity(); + printf("EGS_Ensdf::normalizeIntensities: %d %f %f\n", j, + (*gamma)->getTransitionIntensity(), + totalLevelIntensity[j]); + } + } + ++j; + } + + // Normalize transition intensities over each level + j = 0; + for(vector::iterator it = myLevelRecords.begin(); + it!=myLevelRecords.end(); it++) { + + unsigned int i = 0; + for(vector::iterator gamma = myGammaRecords.begin(); + gamma != myGammaRecords.end(); gamma++) { + + if((*gamma)->getLevelRecord() == (*it)) { + + (*gamma)->setTransitionIntensity( + (*gamma)->getTransitionIntensity() / + totalLevelIntensity[j]); + + if(i > 0) { + (*gamma)->setTransitionIntensity( + (*gamma)->getTransitionIntensity() + + (*(gamma-1))->getTransitionIntensity()); + } + ++i; + + printf("EGS_Ensdf::normalizeIntensities: Gamma intensities: " + "%f\n",(*gamma)->getTransitionIntensity()); + } + } + ++j; + } + + // Determine the final level that the gammas decay towards + // We have to use the gamma decay energy to guess at the resulting + // energy state of the radionuclide + for(vector::iterator gamma = myGammaRecords.begin(); + gamma != myGammaRecords.end(); gamma++) { + + double energy = (*gamma)->getDecayEnergy(); + double guessedLevelEnergy = + ((*gamma)->getLevelRecord()->getEnergy() - energy); + + printf("EGS_Ensdf::normalizeIntensities: Gamma (LE,E,GE): " + "%f %f %f\n",(*gamma)->getLevelRecord()->getEnergy(), + energy, guessedLevelEnergy); + + double bestMatch = 1E10; + LevelRecord *level; + for(vector::iterator it = myLevelRecords.begin(); + it!=myLevelRecords.end(); it++) { + + double testMatch = fabs((*it)->getEnergy()-guessedLevelEnergy); + + if(testMatch < bestMatch && + (testMatch < guessedLevelEnergy*0.3 || testMatch < 20 )) { + + bestMatch = testMatch; + level = (*it); + } + } + if(bestMatch == 1E10) { + printf("EGS_Ensdf::normalizeIntensities: Warning: Could not find a " + "level with energy matching decay of gamma with energy E=%f, " + "assuming ground state\n",energy); + (*gamma)->setFinalLevel(myLevelRecords.front()); + } else { + (*gamma)->setFinalLevel(level); + } + + printf("EGS_Ensdf::normalizeIntensities: Gamma (final level E): " + "%f\n",level->getEnergy()); + } +} + +void EGS_Ensdf::getEmissionsFromComments() { + bool xrayContinues = false; + bool augerContinues = false; + bool gotTotal = false; + vector multilineEnergies, + multilineIntensities; + + for(vector::iterator comment = myCommentRecords.begin(); + comment != myCommentRecords.end(); comment++) { + + string line = (*comment)->getComment(); + + // Check for the end of multi-line records + // and average them together + if(line.length() < 48 || + ((xrayContinues || augerContinues) && line.at(30) != '|')) { + + if(gotTotal) { + gotTotal = false; + } + + if((xrayContinues || augerContinues) + && multilineEnergies.size() > 0) { + + double energySum = 0; + double intensitySum = 0; + unsigned int numNonzeroE = 0; + unsigned int numNonzeroI = 0; + for(unsigned int i=0; i < multilineEnergies.size(); ++i) { + if(multilineEnergies[i] > 0) { + energySum += multilineEnergies[i]; + numNonzeroE++; + } + } + for(unsigned int i=0; i < multilineIntensities.size(); ++i) { + if(multilineIntensities[i] > 0) { + intensitySum += multilineIntensities[i]; + numNonzeroI++; + } + } + double energy; + if(numNonzeroE > 0) { + energy = energySum / numNonzeroE; + } + double intensity; + if(numNonzeroI > 0) { + intensity = intensitySum / numNonzeroI; + } + + if(numNonzeroE > 0 && numNonzeroI > 0) { + if(xrayContinues) { + xrayEnergies.push_back(energy); + xrayIntensities.push_back(intensity); + } else { + augerEnergies.push_back(energy); + augerIntensities.push_back(intensity); + } + } + + multilineEnergies.clear(); + multilineIntensities.clear(); + } + + xrayContinues = false; + augerContinues = false; + } + + // Check for records containing XRays or Auger electrons + if(line.length() > 48) { + + // Skip this line if we already recorded the total + // emission for the line + if(gotTotal) { + continue; + } + + string emissionLine = egsTrimString(line.substr(47)); + + // See if the line is an XRay or Auger + if(emissionLine.at(0) != 'X' && + emissionLine.find("AUGER") == std::string::npos) { + continue; + } + +// printf("EGS_Ensdf::getEmissionsFromComments: %s\n", +// emissionLine.c_str()); + + string eStr = egsTrimString(line.substr(13, 15)); + + // If we have a range in energy (e.g. 0.1-0.3) + // Find the average + size_t eDash = eStr.find('-'); + double energy; + if(eDash!=std::string::npos) { + if(eStr.length() > eDash+1) { + double e1 = atof(eStr.substr(0, eDash).c_str()); + double e2 = atof(eStr.substr(eDash+1).c_str()); + energy = (e1 + e2) / 2; + } else { + energy = atof(eStr.substr(0, eDash).c_str()); + } + } else { + energy = atof(eStr.c_str()); + } + + // Convert the energy from keV to MeV + energy /= 100; + + // Get the intensity + string iStr = egsTrimString(line.substr(32, 9)); + double intensity = atof(iStr.c_str()); + + // If this line is the total of the next lines, we will + // skip the next lines and just use this one + if(emissionLine.find("(total)") != std::string::npos) { + gotTotal = true; + } + + // Multi-line records have a bar '|' at 30 + // We will store the data and average them later + if(line.at(30) == '|') { + if(emissionLine.at(0) == 'X') { + xrayContinues = true; + } else if(emissionLine.find("AUGER") != std::string::npos) { + augerContinues = true; + } + + multilineEnergies.push_back(energy); + multilineIntensities.push_back(intensity); + + } else { + if(emissionLine.at(0) == 'X') { + if(energy > 0 && intensity > 0) { + xrayEnergies.push_back(energy); + xrayIntensities.push_back(intensity); + } + } else if(emissionLine.find("AUGER") != std::string::npos) { + augerEnergies.push_back(energy); + augerIntensities.push_back(intensity); + } + } + +// printf("EGS_Ensdf::getEmissionsFromComments: (E,I) %f %f\n", +// energy, intensity); + } + } +} + +vector EGS_Ensdf::getXRayIntensities() const { + return xrayIntensities; +} + +vector EGS_Ensdf::getXRayEnergies() const { + return xrayEnergies; +} + +vector EGS_Ensdf::getAugerIntensities() const { + return augerIntensities; +} + +vector EGS_Ensdf::getAugerEnergies() const { + return augerEnergies; +} + +vector EGS_Ensdf::getParentRecords() const { + return myParentRecords; +} + +vector EGS_Ensdf::getLevelRecords() const { + return myLevelRecords; +} + +vector EGS_Ensdf::getBetaRecords() const { + return myBetaRecords; +} + +vector EGS_Ensdf::getGammaRecords() const { + return myGammaRecords; +} + +vector EGS_Ensdf::getAlphaRecords() const { + return myAlphaRecords; +} + +Record::Record(vector ensdf) { + if(!ensdf.empty()) { + lines = ensdf; + } +} + +Record::~Record() { + +} + +vector Record::getRecords() const { + return lines; +} + +double Record::recordToDouble(int startPos, int endPos) { + if(!lines.empty()) { + string record = lines.front().substr(startPos-1, + endPos-startPos+1); + return atof(record.c_str()); + } else { + printf("Record::recordToDouble: Error: Record is empty\n"); + return -1; + } +} + +double Record::parseHalfLife(int startPos, int endPos) { + if(lines.empty()) { + printf("Record::parseHalfLife: Error: Record is empty\n"); + return -5; + } + + string halfLifeStr = egsTrimString(lines.front().substr(startPos-1, + endPos-startPos+1)); + printf("Record::parseHalfLife: %s\n", halfLifeStr.c_str()); + + // Return -1 for stable + if(halfLifeStr.substr(0,5).compare("STABLE") == 0) { + return -1; + } + + // Store the length of the numeric part of the string in i + unsigned int numLength; + for(numLength = 0; numLength < halfLifeStr.length(); numLength++) { + if(!isdigit(halfLifeStr[numLength]) + && halfLifeStr.at(numLength) != '.') { + + break; + } + } + + // If there was no numeric component return -2 + if(halfLifeStr.size() < numLength+2) { + return -2; + } + + // Get the numeric part + double hl = atof(halfLifeStr.substr(0, numLength).c_str()); + + // Convert to units of seconds + if(halfLifeStr.size()>numLength+2) { + string units = halfLifeStr.substr(numLength+1, 2); + if(units.compare("Y ") == 0) + hl *= 31556925.26; + else if(units.compare("D ") == 0) + hl *= 86400; + else if(units.compare("H ") == 0) + hl *= 3600; + else if(units.compare("M ") == 0) + hl *= 60; + else if(units.compare("S ") == 0) + hl *= 1; + else if(units.compare("MS") == 0) + hl *= 1E-3; + else if(units.compare("US") == 0) + hl *= 1E-6; + else if(units.compare("NS") == 0) + hl *= 1E-9; + else if(units.compare("PS") == 0) + hl *= 1E-12; + else if(units.compare("FS") == 0) + hl *= 1E-15; + else if(units.compare("AS") == 0) + hl *= 1E-18; + else + return -3; + } else if(halfLifeStr.size()>numLength+1) { + string units = halfLifeStr.substr(numLength+1, 1); + if(units.compare("Y") == 0) + hl *= 31556925.26; + else if(units.compare("D") == 0) + hl *= 86400; + else if(units.compare("H") == 0) + hl *= 3600; + else if(units.compare("M") == 0) + hl *= 60; + else if(units.compare("S") == 0) + hl *= 1; + else { + return -3; + } + } else { + hl = -4; + } + + return hl; +} + +// Comment Record +CommentRecord::CommentRecord(vector ensdf):Record(ensdf) { + processEnsdf(); +} + +void CommentRecord::processEnsdf() { + if(!lines.empty()) { + + comment = lines.front(); + } +} + +string CommentRecord::getComment() { + return comment; +} + +// Parent Record +ParentRecord::ParentRecord(vector ensdf):Record(ensdf) { + processEnsdf(); +} + +void ParentRecord::processEnsdf() { + halfLife = parseHalfLife(40, 49); + printf("ParentRecord::processEnsdf: %f\n", halfLife); +} + +double ParentRecord::getHalfLife() const { + return halfLife; +} + +const ParentRecord * ParentRecordLeaf::getParentRecord() const { + return getBranch(); +} + +ParentRecordLeaf::ParentRecordLeaf(ParentRecord + *myRecord):Leaf(myRecord) { + +} + +// Normalization Record +NormalizationRecord::NormalizationRecord(vector ensdf, + ParentRecord *myParent):Record(ensdf), ParentRecordLeaf(myParent) { + processEnsdf(); +} + +void NormalizationRecord::processEnsdf() { + normalizeRelative = recordToDouble(10, 19); + normalizeTransition = recordToDouble(22, 29); + normalizeBranch = recordToDouble(32, 39); + normalizeBeta = recordToDouble(42, 49); + printf("NormalizationRecord::processEnsdf: %f %f %f %f\n", + normalizeRelative, normalizeTransition, normalizeBranch, normalizeBeta); +} + +// Multiplier for converting relative photon intensity to photons per 100 +// decays in the parent through the decay branch or to photons per 100 neutron +// captures in an (n,gamma) reaction. Required if the absolute photon intensity +// can be calculated +double NormalizationRecord::getRelativeMultiplier() const { + return normalizeRelative; +} + +// Multiplier for convert relative transition intensity (including conversion +// electrons) to transitions per 100 decays of the parent through this decay +// branch or per 100 neutron captures in an (n,gamma) reaction +double NormalizationRecord::getTransitionMultiplier() const { + return normalizeTransition; +} + +// Branching ratio multiplier for converting intensity per 100 decays +// through this decay branch to intensity per 100 decays of the parent nuclide +double NormalizationRecord::getBranchMultiplier() const { + return normalizeBranch; +} + +// Multiplier for converting relative beta- and electron capture intensities to +// intensities per 100 decays through this decay branch. Required if known +double NormalizationRecord::getBetaMultiplier() const { + return normalizeBeta; +} + +const NormalizationRecord * NormalizationRecordLeaf::getNormalizationRecord() + const { + return getBranch(); +} + +NormalizationRecordLeaf::NormalizationRecordLeaf(NormalizationRecord + *myRecord):Leaf(myRecord) { + +} + +// Level Record +LevelRecord::LevelRecord(vector ensdf):Record(ensdf) { + processEnsdf(); +} + +void LevelRecord::processEnsdf() { + energy = recordToDouble(10, 19) / 1000; // Convert keV to MeV + halfLife = recordToDouble(40, 49); + printf("LevelRecord::processEnsdf: %f %f\n", energy, halfLife); +} + +double LevelRecord::getEnergy() const { + return energy; +} + +double LevelRecord::getHalfLife() const { + return halfLife; +} + +const LevelRecord * LevelRecordLeaf::getLevelRecord() const { + return getBranch(); +} + +LevelRecordLeaf::LevelRecordLeaf(LevelRecord + *myRecord):Leaf(myRecord) { + +} + +// Beta Record +BetaRecordLeaf::BetaRecordLeaf(vector ensdf, + ParentRecord *myParent, NormalizationRecord *myNormalization, + LevelRecord *myLevel): + ParentRecordLeaf(myParent), + NormalizationRecordLeaf(myNormalization), + LevelRecordLeaf(myLevel), + Record(ensdf) { + numSampled = 0; +} +int BetaRecordLeaf::getCharge() const { + return q; +} + +void BetaRecordLeaf::incrNumSampled() { + numSampled++; +} + +EGS_I64 BetaRecordLeaf::getNumSampled() const { + return numSampled; +} + +// Beta- Record +BetaMinusRecord::BetaMinusRecord(vector ensdf, + ParentRecord *myParent, NormalizationRecord *myNormalization, + LevelRecord *myLevel):BetaRecordLeaf(ensdf, myParent, + myNormalization, myLevel) { + processEnsdf(); + q = -1; +} + +void BetaMinusRecord::processEnsdf() { + finalEnergy = recordToDouble(10, 19) / 1000; // Convert keV to MeV + betaIntensity = recordToDouble(22, 29); + if(getNormalizationRecord()) { + betaIntensity *= getNormalizationRecord()->getBetaMultiplier() * + getNormalizationRecord()->getBranchMultiplier(); + } + printf("BetaMinusRecord::processEnsdf: %f %f\n", finalEnergy, + betaIntensity); +} + +double BetaMinusRecord::getFinalEnergy() const { + return finalEnergy; +} + +double BetaMinusRecord::getBetaIntensity() const { + return betaIntensity; +} + +void BetaMinusRecord::setBetaIntensity(double newIntensity) { + betaIntensity = newIntensity; +} + +// Beta+ Record (and Electron Capture) +BetaPlusRecord::BetaPlusRecord(vector ensdf, + ParentRecord *myParent, NormalizationRecord *myNormalization, + LevelRecord *myLevel):BetaRecordLeaf(ensdf, myParent, + myNormalization, myLevel) { + processEnsdf(); + q = 1; +} + +void BetaPlusRecord::processEnsdf() { + finalEnergy = recordToDouble(10, 19) / 1000; // Convert keV to MeV + betaIntensity = recordToDouble(22, 29); + ecIntensity = recordToDouble(32, 39); + if(getNormalizationRecord()) { + betaIntensity *= getNormalizationRecord()->getBetaMultiplier() * + getNormalizationRecord()->getBranchMultiplier(); + } + printf("BetaPlusRecord::processEnsdf: %f %f %f\n", finalEnergy, + betaIntensity, ecIntensity); +} + +double BetaPlusRecord::getFinalEnergy() const { + return finalEnergy; +} + +double BetaPlusRecord::getBetaIntensity() const { + return betaIntensity; +} + +double BetaPlusRecord::getECIntensity() const { + return ecIntensity; +} + +void BetaPlusRecord::setBetaIntensity(double newIntensity) { + betaIntensity = newIntensity; +} + +void BetaPlusRecord::setECIntensity(double newIntensity) { + ecIntensity = newIntensity; +} + +// Gamma Record +GammaRecord::GammaRecord(vector ensdf, NormalizationRecord + *myNormalization, LevelRecord *myLevel):Record(ensdf), + NormalizationRecordLeaf(myNormalization), LevelRecordLeaf(myLevel) { + processEnsdf(); + q = 0; + numSampled = 0; +} + +void GammaRecord::processEnsdf() { + decayEnergy = recordToDouble(10, 19) / 1000; // Convert keV to MeV + transitionIntensity = recordToDouble(22, 29); + halfLife = parseHalfLife(40, 49); + + if(getNormalizationRecord()) { + transitionIntensity *= + getNormalizationRecord()->getRelativeMultiplier() * + getNormalizationRecord()->getBranchMultiplier(); + } + + printf("GammaRecord::processEnsdf: %f %f %f\n", decayEnergy, + transitionIntensity, halfLife); +} + +double GammaRecord::getDecayEnergy() const { + return decayEnergy; +} + +double GammaRecord::getTransitionIntensity() const { + return transitionIntensity; +} + +void GammaRecord::setTransitionIntensity(double newIntensity) { + transitionIntensity = newIntensity; +} + +int GammaRecord::getCharge() const { + return q; +} + +void GammaRecord::incrNumSampled() { + numSampled++; +} + +EGS_I64 GammaRecord::getNumSampled() const { + return numSampled; +} + +LevelRecord * GammaRecord::getFinalLevel() const { + return finalLevel; +} + +void GammaRecord::setFinalLevel(LevelRecord *newLevel) { + finalLevel = newLevel; +} + +double GammaRecord::getHalfLife() const { + return halfLife; +} + +// Alpha Record +AlphaRecord::AlphaRecord(vector ensdf, + ParentRecord *myParent, NormalizationRecord *myNormalization, + LevelRecord *myLevel):Record(ensdf), + ParentRecordLeaf(myParent), NormalizationRecordLeaf(myNormalization), + LevelRecordLeaf(myLevel) { + processEnsdf(); + q = 2; + numSampled = 0; +} + +void AlphaRecord::processEnsdf() { + finalEnergy = recordToDouble(10, 19) / 1000; // Convert keV to MeV + alphaIntensity = recordToDouble(22, 29); + printf("AlphaRecord::processEnsdf: %f %f\n", finalEnergy, + alphaIntensity); +} + +double AlphaRecord::getFinalEnergy() const { + return finalEnergy; +} + +double AlphaRecord::getAlphaIntensity() const { + return alphaIntensity; +} + +void AlphaRecord::setAlphaIntensity(double newIntensity) { + alphaIntensity = newIntensity; +} + +int AlphaRecord::getCharge() const { + return q; +} + +void AlphaRecord::incrNumSampled() { + numSampled++; +} + +EGS_I64 AlphaRecord::getNumSampled() const { + return numSampled; +} + diff --git a/HEN_HOUSE/egs++/egs_ensdf.h b/HEN_HOUSE/egs++/egs_ensdf.h new file mode 100644 index 000000000..d6b0c98e4 --- /dev/null +++ b/HEN_HOUSE/egs++/egs_ensdf.h @@ -0,0 +1,422 @@ +/* +############################################################################### +# +# EGSnrc egs++ ensdf headers +# Copyright (C) 2015 National Research Council Canada +# +# This file is part of EGSnrc. +# +# EGSnrc is free software: you can redistribute it and/or modify it under +# the terms of the GNU Affero General Public License as published by the +# Free Software Foundation, either version 3 of the License, or (at your +# option) any later version. +# +# EGSnrc is distributed in the hope that it will be useful, but WITHOUT ANY +# WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS +# FOR A PARTICULAR PURPOSE. See the GNU Affero General Public License for +# more details. +# +# You should have received a copy of the GNU Affero General Public License +# along with EGSnrc. If not, see . +# +############################################################################### +# +# Author: Reid Townson, 2016 +# +# Contributors: +# +############################################################################### +*/ + + +/*! \file egs_ensdf.h + * \brief The ensdf library header file + * \RT + * + */ + +#ifndef EGS_ENSDF_ +#define EGS_ENSDF_ + +#include "egs_libconfig.h" +#include "egs_functions.h" +#include "egs_math.h" + +#include +#include +#include +#include +#include + +using namespace std; + +template class Branch { +public: + + Branch() {} + + ~Branch() { + for(typename vector::iterator it = branchLeaves.begin(); + it!=branchLeaves.end(); it++) { + (*it)->removeBranch(); + } + branchLeaves.clear(); + } + + void addLeaf(T * leaf) { + branchLeaves.push_back(leaf); + } + + void removeLeaf(T * leaf) { + branchLeaves.erase(std::remove(branchLeaves.begin(), + branchLeaves.end(), + leaf), branchLeaves.end()); + } + + vector getLeaves() const { + return branchLeaves; + } + + // A new == operator for this class + bool operator==(const Branch & rhs) const { + for(typename vector::const_iterator it = branchLeaves.begin(); + it!=branchLeaves.end(); it++) { + + bool foundLeaf = false; + for(typename vector::const_iterator irhs = + rhs.branchLeaves.begin(); + irhs!=rhs.branchLeaves.end(); irhs++) { + + if(*irhs != 0 && *it != 0) { + if(*irhs == *it) { + foundLeaf = true; + } + } + } + + if(!foundLeaf) { + return false; + } + } + return true; + } + +protected: + vector branchLeaves; +}; + +template class Leaf { +public: + + Leaf(T * existingTree) { + tree = existingTree; + if(tree) { + tree->addLeaf(this); + } + } + + ~Leaf() { + if(tree) { + tree->removeLeaf(this); + } + tree = 0; + } + + virtual T * getBranch() const + { + return tree; + } + + void removeBranch() { + tree = 0; + } + + // A new == operator for this class + bool operator== (const T& rhs) const + { + if(tree==0 && rhs.tree==0) { + return true; + } else if((tree==0) && rhs.tree!=0) { + return false; + } else if((tree!=0) && rhs.tree==0) { + return false; + } else if(tree!=0 && rhs.tree!=0) { + return *tree == *(rhs.tree); + } + } + +private: + T * tree; +}; + +// The Record class +class Record { +public: + Record(vector ensdf); + virtual ~Record(); + vector getRecords() const; + +protected: + double recordToDouble(int startPos, int endPos); + double parseHalfLife(int startPos, int endPos); + + // All the lines corresponding to this record type + vector lines; +}; + +// Comment Record +class CommentRecord : public Record { +public: + CommentRecord(vector ensdf); + string getComment(); + +private: + string comment; + void processEnsdf(); +}; + +// Parent Record +class ParentRecord : public Record, public Branch > { +public: + ParentRecord(vector ensdf); + double getHalfLife() const; + +protected: + double halfLife; + +private: + void processEnsdf(); +}; + +class ParentRecordLeaf : public Leaf { +public: + ParentRecordLeaf(ParentRecord * myRecord); + virtual const ParentRecord * getParentRecord() const; +}; + +// Normalization Record +class NormalizationRecord : public Record, public + Branch >, public ParentRecordLeaf { +public: + NormalizationRecord(vector ensdf, ParentRecord *parent); + double getRelativeMultiplier() const; + double getTransitionMultiplier() const; + double getBranchMultiplier() const; + double getBetaMultiplier() const; + +protected: + double normalizeRelative; + double normalizeTransition; + double normalizeBeta; + double normalizeBranch; + +private: + void processEnsdf(); +}; + +class NormalizationRecordLeaf : public Leaf { +public: + NormalizationRecordLeaf(NormalizationRecord * myRecord); + virtual const NormalizationRecord * getNormalizationRecord() const; +}; + +// Level Record +class LevelRecord : public Record, public Branch > { +public: + LevelRecord(vector ensdf); + double getEnergy() const; + double getHalfLife() const; + +protected: + double energy; + double halfLife; + +private: + void processEnsdf(); +}; + +class LevelRecordLeaf : public Leaf { +public: + LevelRecordLeaf(LevelRecord * myRecord); + virtual const LevelRecord * getLevelRecord() const; +}; + +// Generic beta record +class BetaRecordLeaf : public Record, public ParentRecordLeaf, public + NormalizationRecordLeaf, public LevelRecordLeaf { +public: + BetaRecordLeaf(vector ensdf, ParentRecord *myParent, + NormalizationRecord *myNormalization, LevelRecord *myLevel); + + virtual double getFinalEnergy() const = 0; + virtual double getBetaIntensity() const = 0; + virtual void setBetaIntensity(double newIntensity) = 0; + int getCharge() const; + void incrNumSampled(); + EGS_I64 getNumSampled() const; + +protected: + EGS_I64 numSampled; + double finalEnergy; + double betaIntensity; + int q; +}; + +// Beta- record +class BetaMinusRecord : public BetaRecordLeaf { +public: + BetaMinusRecord(vector ensdf, ParentRecord *myParent, + NormalizationRecord *myNormalization, LevelRecord *myLevel); + + double getFinalEnergy() const; + double getBetaIntensity() const; + void setBetaIntensity(double newIntensity); + +private: + void processEnsdf(); +}; + +// Beta+ Record (and Electron Capture) +class BetaPlusRecord : public BetaRecordLeaf { +public: + BetaPlusRecord(vector ensdf, ParentRecord *myParent, + NormalizationRecord *myNormalization, LevelRecord *myLevel); + + double getFinalEnergy() const; + double getBetaIntensity() const; + double getECIntensity() const; + void setBetaIntensity(double newIntensity); + void setECIntensity(double newIntensity); + +protected: + double ecIntensity; + +private: + void processEnsdf(); +}; + +// Gamma record +class GammaRecord : public Record, public NormalizationRecordLeaf, public + LevelRecordLeaf { +public: + GammaRecord(vector ensdf, NormalizationRecord *myNormalization, + LevelRecord *myLevel); + + double getDecayEnergy() const; + double getTransitionIntensity() const; + void setTransitionIntensity(double newIntensity); + int getCharge() const; + LevelRecord * getFinalLevel() const; + void setFinalLevel(LevelRecord *newLevel); + double getHalfLife() const; + void incrNumSampled(); + EGS_I64 getNumSampled() const; + +protected: + EGS_I64 numSampled; + double decayEnergy; + double transitionIntensity; + double halfLife; + int q; + LevelRecord *finalLevel; + +private: + void processEnsdf(); +}; + +// Alpha record +class AlphaRecord : public Record, public ParentRecordLeaf, public + NormalizationRecordLeaf, public LevelRecordLeaf { +public: + AlphaRecord(vector ensdf, ParentRecord *myParent, + NormalizationRecord *myNormalization, LevelRecord *myLevel); + + double getFinalEnergy() const; + double getAlphaIntensity() const; + int getCharge() const; + void setAlphaIntensity(double newIntensity); + void incrNumSampled(); + EGS_I64 getNumSampled() const; + +protected: + EGS_I64 numSampled; + double finalEnergy; + double alphaIntensity; + int q; + +private: + void processEnsdf(); +}; + + +/*! \brief The ensdf class + + \ingroup egspp_main + + ... add description here + +*/ +class EGS_EXPORT EGS_Ensdf { + +public: + + /*! \brief Construct an ensdf object + * + */ + EGS_Ensdf(const string isotope, const string ensdf_filename=""); + + /*! \brief Destructor. Deallocates all allocated memory */ + ~EGS_Ensdf(); + + vector getRecords() const; + vector getBetaRecords() const; + vector getParentRecords() const; + vector getLevelRecords() const; + vector getAlphaRecords() const; + vector getGammaRecords() const; + vector getXRayIntensities() const; + vector getXRayEnergies() const; + vector getAugerIntensities() const; + vector getAugerEnergies() const; + string radionuclide; + + void normalizeIntensities(); + +protected: + + bool createIsotope(vector ensdf); + map getElementMap(); + unsigned short int findAtomicWeight(string element); + void parseEnsdf(vector ensdf); + void buildRecords(); + + void getEmissionsFromComments(); + + ifstream ensdf_file; + unsigned short int A; + + vector myRecords; + vector myCommentRecords; + vector myParentRecords; + vector myNormalizationRecords; + vector myLevelRecords; + vector myBetaRecords; + vector myBetaMinusRecords; + vector myBetaPlusRecords; + vector myAlphaRecords; + vector myGammaRecords; + +private: + + vector > recordStack; + vector commentLines; + vector xrayEnergies, + xrayIntensities, + augerEnergies, + augerIntensities; +}; + + + + +#endif diff --git a/HEN_HOUSE/egs++/egs_spectra.cpp b/HEN_HOUSE/egs++/egs_spectra.cpp index f2de2c7c6..c7968aa4e 100644 --- a/HEN_HOUSE/egs++/egs_spectra.cpp +++ b/HEN_HOUSE/egs++/egs_spectra.cpp @@ -39,6 +39,8 @@ #include "egs_alias_table.h" #include "egs_input.h" #include "egs_math.h" +#include "egs_ensdf.h" +#include "egs_application.h" #include #include "egs_math.h" @@ -51,6 +53,8 @@ #define S_STREAM std::istrstream #endif + + using namespace std; void EGS_BaseSpectrum::reportAverageEnergy() const { @@ -434,7 +438,313 @@ class EGS_EXPORT EGS_TabulatedSpectrum : public EGS_BaseSpectrum { }; -static char spec_msg1[] = "EGS_BaseSpectrum::createSpectrum:"; +/*! \brief A radionuclide spectrum. + * + * \ingroup egspp_main + * + + + + */ +class EGS_EXPORT EGS_RadionuclideSpectrum : public EGS_BaseSpectrum { + +public: + + /*! \brief Construct a radionuclide spectrum. + */ + EGS_RadionuclideSpectrum(const string isotope, const string ensdf_file, +const EGS_Float weight) : + EGS_BaseSpectrum() { + + // Read in the data file for the isotope + // and build the decay structure + decays = new EGS_Ensdf(isotope, ensdf_file); + + // Normalize the emission and transition intensities + decays->normalizeIntensities(); + + // Get the particle records from the decay scheme + myBetas = decays->getBetaRecords(); + myAlphas = decays->getAlphaRecords(); + myGammas = decays->getGammaRecords(); + myLevels = decays->getLevelRecords(); + xrayIntensities = decays->getXRayIntensities(); + xrayEnergies = decays->getXRayEnergies(); + augerIntensities = decays->getAugerIntensities(); + augerEnergies = decays->getAugerEnergies(); + + // Initialization + currentLevel = 0; + Emax = 0; + currentTime = 0; + ishower = -1; // Start with ishower -1 so first shower has index 0 + + // Get the maximum energy for emissions + for(vector::iterator beta = myBetas.begin(); + beta != myBetas.end(); beta++) { + + double energy = (*beta)->getFinalEnergy(); + if(Emax < energy) { + Emax = energy; + } + } + for(vector::iterator alpha = myAlphas.begin(); + alpha != myAlphas.end(); alpha++) { + + double energy = (*alpha)->getFinalEnergy(); + if(Emax < energy) { + Emax = energy; + } + } + for(vector::iterator gamma = myGammas.begin(); + gamma != myGammas.end(); gamma++) { + + double energy = (*gamma)->getDecayEnergy(); + if(Emax < energy) { + Emax = energy; + } + } + for(unsigned int i=0; i < xrayEnergies.size(); ++i) { + numSampledXRay.push_back(0); + if(Emax < xrayEnergies[i]) { + Emax = xrayEnergies[i]; + } + } + for(unsigned int i=0; i < augerEnergies.size(); ++i) { + numSampledAuger.push_back(0); + if(Emax < augerEnergies[i]) { + Emax = augerEnergies[i]; + } + } + + // Set the weight of the spectrum + spectrumWeight = weight; + + printf("EGS_RadionuclideSpectrum: Emax: %f\n",Emax); + printf("EGS_RadionuclideSpectrum: Weight: %f\n",weight); + }; + + ~EGS_RadionuclideSpectrum() { + delete decays; + }; + + int getCharge() const { + return currentQ; + } + + double getTime() const { + return currentTime; + } + + void setMaximumTime(double maxTime) { + Tmax = maxTime; + } + + EGS_I64 getShowerIndex() const { + return ishower; + } + + EGS_Float getSpectrumWeight() const { + return spectrumWeight; + } + + void setSpectrumWeight(EGS_Float newWeight) { + spectrumWeight = newWeight; + } + + void printSampledEmissions() { + printf("\nSampled %s emissions:\n", decays->radionuclide.c_str()); + printf("========================\n"); + printf("Energy | Intensity per 100 emissions\n"); + if(myBetas.size() > 0) { + printf("Beta records:\n"); + } + for(vector::iterator beta = myBetas.begin(); + beta != myBetas.end(); beta++) { + + printf("%f %f\n", (*beta)->getFinalEnergy(), + ((EGS_Float)(*beta)->getNumSampled()/ishower)*100); + } + if(myAlphas.size() > 0) { + printf("Alpha records:\n"); + } + for(vector::iterator alpha = myAlphas.begin(); + alpha != myAlphas.end(); alpha++) { + + printf("%f %f\n", (*alpha)->getFinalEnergy(), + ((EGS_Float)(*alpha)->getNumSampled()/ishower)*100); + } + if(myGammas.size() > 0) { + printf("Gamma records:\n"); + } + for(vector::iterator gamma = myGammas.begin(); + gamma != myGammas.end(); gamma++) { + + printf("%f %f\n", (*gamma)->getDecayEnergy(), + ((EGS_Float)(*gamma)->getNumSampled()/ishower)*100); + } + if(xrayEnergies.size() > 0) { + printf("X-Ray records:\n"); + } + for(unsigned int i=0; i < xrayEnergies.size(); ++i) { + printf("%f %f\n", xrayEnergies[i], + ((EGS_Float)numSampledXRay[i]/ishower)*100); + } + if(augerEnergies.size() > 0) { + printf("Auger records:\n"); + } + for(unsigned int i=0; i < augerEnergies.size(); ++i) { + printf("%f %f\n", augerEnergies[i], + ((EGS_Float)numSampledAuger[i]/ishower)*100); + } + printf("\n"); + } + +protected: + EGS_Float sample(EGS_RandomGenerator *rndm) { + + // Sample a uniform random number + EGS_Float u = rndm->getUniform(); + + // The energy of the sampled particle + EGS_Float E; + + // If the daughter is in an excited state + // Check for transitions + if(currentLevel && currentLevel->getEnergy() > 0) { +// printf("EGS_RadionuclideSpectrum:sample: excited daughter " +// "%f\n",currentLevel->getEnergy()); + + for(vector::iterator gamma = myGammas.begin(); + gamma != myGammas.end(); gamma++) { + + if((*gamma)->getLevelRecord() == currentLevel) { + + if(u < (*gamma)->getTransitionIntensity()) { + + (*gamma)->incrNumSampled(); + currentQ = (*gamma)->getCharge(); + + currentTime += currentLevel->getHalfLife() / +0.693147180559945309417232121458176568075500134360255254120680009493393 + * log(rndm->getUniform()); + + currentLevel = (*gamma)->getFinalLevel(); + + + + E = (*gamma)->getDecayEnergy(); + return E; + } + } + } + } else { + // Incremember the shower number + ishower++; + + // Uniformly distribute decays over the experiment time + currentTime = rndm->getUniform() * Tmax; + + // Sample which decay occurs + // Betas + for(vector::iterator beta = myBetas.begin(); + beta != myBetas.end(); beta++) { + if(u < (*beta)->getBetaIntensity()) { + + (*beta)->incrNumSampled(); + currentQ = (*beta)->getCharge(); + //printf("EGS_RadionuclideSpectrum: q: %d\n",currentQ); + + // Set the energy level of the daughter + currentLevel = (*beta)->getLevelRecord(); + + // TODO: Generate beta- spectrum + // TODO: Need to implement electron capture + + // For now just uniform up to max! + E = u * (*beta)->getFinalEnergy(); + //printf("\nEGS_RadionuclideSpectrum: E: %f\n",E); + return E; + } + } + + // Alphas + for(vector::iterator alpha = myAlphas.begin(); + alpha != myAlphas.end(); alpha++) { + if(u < (*alpha)->getAlphaIntensity()) { + + (*alpha)->incrNumSampled(); + currentQ = (*alpha)->getCharge(); + + // Set the energy level of the daughter + currentLevel = (*alpha)->getLevelRecord(); + + // For alphas we simulate a disintegration but the + // transport will not be performed + return 0; + } + } + + // XRays + for(unsigned int i=0; i < xrayIntensities.size(); ++i) { + if(u < xrayIntensities[i]) { + + numSampledXRay[i]++; + currentQ = 0; + + E = xrayEnergies[i]; + + return E; + } + } + + // Auger electrons + for(unsigned int i=0; i < augerIntensities.size(); ++i) { + if(u < augerIntensities[i]) { + + numSampledAuger[i]++; + currentQ = -1; + + E = augerEnergies[i]; + + return E; + } + } + } + + // Shouldn't get here + return 0; + }; + + EGS_Float maxEnergy() const { + return Emax; + }; + + EGS_Float expectedAverage() const { + return 0; + }; + +private: + + EGS_Ensdf *decays; + vector myBetas; + vector myAlphas; + vector myGammas; + vector myLevels; + vector xrayIntensities, + xrayEnergies, + augerIntensities, + augerEnergies; + vector numSampledXRay, + numSampledAuger; + const LevelRecord *currentLevel; + int currentQ; + EGS_Float currentTime, + Emax, + Tmax, + spectrumWeight; + EGS_I64 ishower; +}; // // The following function is used to skip potentially present @@ -464,6 +774,7 @@ istream &skipsep(istream &in) { return in; } +static char spec_msg1[] = "EGS_BaseSpectrum::createSpectrum:"; EGS_BaseSpectrum *EGS_BaseSpectrum::createSpectrum(EGS_Input *input) { if (!input) { @@ -792,8 +1103,49 @@ EGS_BaseSpectrum *EGS_BaseSpectrum::createSpectrum(EGS_Input *input) { } } } - } - else { + } else if (inp->compare(stype,"radionuclide")) { + string isotope; + err = inp->getInput("isotope",isotope); + if(err) { + egsWarning("%s wrong/missing 'isotope' input\n",spec_msg1); + return 0; + } + + EGS_Float weight; + err = inp->getInput("weight",weight); + if(err) { + weight = 1; + } + + // For ensdf input, first check for the input argument + string ensdf_file; + err = inp->getInput("ensdf file",ensdf_file); + + // If not passed as input, find the ensdf file in the + // directory $HEN_HOUSE/spectra/lnhb + if (err) { + + EGS_Application *app = EGS_Application::activeApplication(); + if (app) { + ensdf_file = egsJoinPath(app->getHenHouse(),"spectra"); + ensdf_file = egsJoinPath(ensdf_file.c_str(),"lnhb"); + } else { + char *hen_house = getenv("HEN_HOUSE"); + if (!hen_house) { + + egsWarning("EGS_BaseSpectrum::createSpectrum: " + "No active application and HEN_HOUSE not defined.\n" + "Assuming local directory for spectra\n"); + ensdf_file = "./"; + } else { + ensdf_file = egsJoinPath(hen_house,"spectra"); + ensdf_file = egsJoinPath(ensdf_file.c_str(),"lnhb"); + } + } + ensdf_file = egsJoinPath(ensdf_file.c_str(),isotope.append(".txt")); + } + spec = new EGS_RadionuclideSpectrum(isotope, ensdf_file, weight); + } else { egsWarning("%s unknown spectrum type %s\n",spec_msg1,stype.c_str()); } if (delete_it) { diff --git a/HEN_HOUSE/egs++/sources/egs_radionuclide_source/Makefile b/HEN_HOUSE/egs++/sources/egs_radionuclide_source/Makefile new file mode 100644 index 000000000..5bcea893c --- /dev/null +++ b/HEN_HOUSE/egs++/sources/egs_radionuclide_source/Makefile @@ -0,0 +1,44 @@ + +############################################################################### +# +# EGSnrc egs++ makefile to build radionuclide source +# Copyright (C) 2015 National Research Council Canada +# +# This file is part of EGSnrc. +# +# EGSnrc is free software: you can redistribute it and/or modify it under +# the terms of the GNU Affero General Public License as published by the +# Free Software Foundation, either version 3 of the License, or (at your +# option) any later version. +# +# EGSnrc is distributed in the hope that it will be useful, but WITHOUT ANY +# WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS +# FOR A PARTICULAR PURPOSE. See the GNU Affero General Public License for +# more details. +# +# You should have received a copy of the GNU Affero General Public License +# along with EGSnrc. If not, see . +# +############################################################################### +# +# Author: Reid Townson, 2016 +# +# Contributors: +# +############################################################################### + + +include $(EGS_CONFIG) +include $(SPEC_DIR)egspp.spec +include $(SPEC_DIR)egspp_$(my_machine).conf + +DEFS = $(DEF1) -DBUILD_RADIONUCLIDE_SOURCE_DLL + +library = egs_radionuclide_source +lib_files = egs_radionuclide_source +my_deps = $(common_source_deps) +extra_dep = $(addprefix $(DSOLIBS), $(my_deps)) + +include $(SPEC_DIR)egspp_libs.spec + +$(make_depend) diff --git a/HEN_HOUSE/egs++/sources/egs_radionuclide_source/egs_radionuclide_source.cpp b/HEN_HOUSE/egs++/sources/egs_radionuclide_source/egs_radionuclide_source.cpp new file mode 100644 index 000000000..ce5e94ba7 --- /dev/null +++ b/HEN_HOUSE/egs++/sources/egs_radionuclide_source/egs_radionuclide_source.cpp @@ -0,0 +1,298 @@ +/* +############################################################################### +# +# EGSnrc egs++ radionuclide source +# Copyright (C) 2015 National Research Council Canada +# +# This file is part of EGSnrc. +# +# EGSnrc is free software: you can redistribute it and/or modify it under +# the terms of the GNU Affero General Public License as published by the +# Free Software Foundation, either version 3 of the License, or (at your +# option) any later version. +# +# EGSnrc is distributed in the hope that it will be useful, but WITHOUT ANY +# WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS +# FOR A PARTICULAR PURPOSE. See the GNU Affero General Public License for +# more details. +# +# You should have received a copy of the GNU Affero General Public License +# along with EGSnrc. If not, see . +# +############################################################################### +# +# Author: Reid Townson, 2016 +# +# Contributors: +# +############################################################################### +*/ + + +/*! \file egs_radionuclide_source.cpp + * \brief A radionuclide source + * \RT + */ + +#include "egs_radionuclide_source.h" +#include "egs_input.h" +#include "egs_math.h" +#include "egs_application.h" + +EGS_RadionuclideSource::EGS_RadionuclideSource(EGS_Input *input, + EGS_ObjectFactory *f) : EGS_BaseSource(input,f), shape(0), + geom(0), regions(0), nrs(0), min_theta(0), max_theta(M_PI), + min_phi(0), max_phi(2*M_PI), gc(IncludeAll), q_allowed(0), decays(0), + activity(0) { + + int err; + + // TODO: Make use of q_allowed to reject particles? + vector tmp_q; + err = input->getInput("charge", tmp_q); + if (!err) { + q_allowed = tmp_q; + } + + // Create the decay spectra + count = 0; + Emax = 0; + unsigned int i = 0; + EGS_Float spectrumWeightTotal = 0; + while(input->getInputItem("spectrum")) { + + decays.push_back(EGS_BaseSpectrum::createSpectrum(input)); + if (!decays[i]) { + break; + } + + EGS_Float spectrumMaxE = decays[i]->maxEnergy(); + if(spectrumMaxE > Emax) { + Emax = spectrumMaxE; + } + + spectrumWeightTotal += decays[i]->getSpectrumWeight(); + + ++i; + } + if(decays.size() < 1) { + egsWarning("EGS_RadionuclideSource: no spectrum was defined\n"); + } + + // Normalize the spectrum weights + for(i=0; isetSpectrumWeight( + decays[i]->getSpectrumWeight() / spectrumWeightTotal); + + if(i > 0) { + decays[i]->setSpectrumWeight( + decays[i]->getSpectrumWeight() + + decays[i-1]->getSpectrumWeight()); + } + } + + // Get the activity + EGS_Float tmp_A; + err = input->getInput("activity", tmp_A); + if (!err) { + activity = tmp_A; + } + egsWarning("EGS_RadionuclideSource: Activity [disintegrations/s]: %e\n", + activity); + + // Calculate the duration of the experiment + // Based on ncase and activity + EGS_Application *app = EGS_Application::activeApplication(); + EGS_Input *inp = app->getInput(); + EGS_Input *irc = 0; + double ncase_double = 0; + if (inp) { + irc = inp->getInputItem("run control"); + + EGS_Input *icontrol = irc->getInputItem("run control"); + if(!icontrol) { + egsWarning("EGS_RadionuclideSource: no 'run control' " + "input to determine 'ncase'\n"); + } + + err = icontrol->getInput("number of histories", ncase_double); + if(err) { + err = icontrol->getInput("ncase", ncase_double); + if(err) { + egsWarning("EGS_RadionuclideSource: missing/wrong 'ncase' or " + "'number of histories' input\n"); + } + } + } else { + egsWarning("EGS_RadionuclideSource: no 'run control' " + "input to determine 'ncase'\n"); + } + + double Tmax = ncase_double / activity; + egsWarning("EGS_RadionuclideSource: Duration of experiment [s]: %e\n", + Tmax); + for(i=0; isetMaximumTime(Tmax); + } + + // Create the shape for source emissions + vector pos; + EGS_Input *ishape = input->takeInputItem("shape"); + if (ishape) { + shape = EGS_BaseShape::createShape(ishape); + delete ishape; + } + if (!shape) { + string sname; + err = input->getInput("shape name",sname); + if (err) + egsWarning("EGS_RadionuclideSource: missing/wrong inline shape " + "definition and missing wrong 'shape name' input\n"); + else { + shape = EGS_BaseShape::getShape(sname); + if (!shape) egsWarning("EGS_RadionuclideSource: a shape named %s" + " does not exist\n"); + } + } + string geom_name; + err = input->getInput("geometry",geom_name); + if (!err) { + geom = EGS_BaseGeometry::getGeometry(geom_name); + if (!geom) egsWarning("EGS_RadionuclideSource: no geometry named %s\n", + geom_name.c_str()); + else { + vector reg_options; + reg_options.push_back("IncludeAll"); + reg_options.push_back("ExcludeAll"); + reg_options.push_back("IncludeSelected"); + reg_options.push_back("ExcludeSelected"); + gc = (GeometryConfinement) input->getInput("region " + "selection",reg_options,0); + if (gc == IncludeSelected || gc == ExcludeSelected) { + vector regs; + err = input->getInput("selected regions",regs); + if (err || regs.size() < 1) { + egsWarning("EGS_RadionuclideSource: region selection %d " + "used but no 'selected regions' input " + "found\n",gc); + gc = gc == IncludeSelected ? IncludeAll : ExcludeAll; + egsWarning(" using %d\n",gc); + } + nrs = regs.size(); + regions = new int [nrs]; + for (int j=0; jgetInput("min theta", tmp_theta); + if (!err) { + min_theta = tmp_theta/180.0*M_PI; + } + + err = input->getInput("max theta", tmp_theta); + if (!err) { + max_theta = tmp_theta/180.0*M_PI; + } + + err = input->getInput("min phi", tmp_theta); + if (!err) { + min_phi = tmp_theta/180.0*M_PI; + } + + err = input->getInput("max phi", tmp_theta); + if (!err) { + max_phi = tmp_theta/180.0*M_PI; + } + + buf_1 = cos(min_theta); + buf_2 = cos(max_theta); + + setUp(); +} + +EGS_I64 EGS_RadionuclideSource::getNextParticle(EGS_RandomGenerator *rndm, int + &q, int &latch, EGS_Float &E, EGS_Float &wt, EGS_Vector &x, EGS_Vector + &u) { + + // Sample a uniform random number + EGS_Float uRand = rndm->getUniform(); + + // Sample which spectrum to use + unsigned int i; + for(i=0; igetSpectrumWeight()) { + break; + } + } + + E = decays[i]->sampleEnergy(rndm); + q = decays[i]->getCharge(); + time = decays[i]->getTime(); + ishower = decays[i]->getShowerIndex(); + + getPositionDirection(rndm,x,u,wt); + latch = 0; + +// egsWarning("EGS_RadionuclideSource::getNextParticle: E: %f\n", +// E); +// +// egsWarning("EGS_RadionuclideSource::getNextParticle: q: %d\n", +// q); + + return ++count; +} + +// EGS_I64 EGS_RadionuclideSource::getNextParticle(EGS_RandomGenerator *rndm, int +// &q, int &latch, EGS_Float &E, EGS_Float &wt, EGS_Vector &x, EGS_Vector +// &u, EGS_I64 &ishower, EGS_Float &time) { +// +// ishower = count; +// +// getNextParticle(rndm, q, latch, E, wt, x, u); +// +// time = decays->getTime(); +// +// return count; +// } + +void EGS_RadionuclideSource::setUp() { + otype = "EGS_RadionuclideSource"; + if (!isValid()) { + description = "Invalid radionuclide source"; + } + else { + description = "Radionuclide source from a shape of type "; + description += shape->getObjectType(); + description += " with:"; + if (std::find(q_allowed.begin(), q_allowed.end(), -1) != + q_allowed.end()) { + description += " electrons"; + } + if (std::find(q_allowed.begin(), q_allowed.end(), 0) != q_allowed.end()) + { + description += " photons"; + } + if (std::find(q_allowed.begin(), q_allowed.end(), 1) != q_allowed.end()) + { + description += " positrons"; + } + + if (geom) { + geom->ref(); + } + } +} + +extern "C" { + + EGS_RADIONUCLIDE_SOURCE_EXPORT EGS_BaseSource *createSource(EGS_Input + *input, EGS_ObjectFactory *f) { + return + createSourceTemplate(input,f,"radionuclide " + "source"); + } + +} diff --git a/HEN_HOUSE/egs++/sources/egs_radionuclide_source/egs_radionuclide_source.h b/HEN_HOUSE/egs++/sources/egs_radionuclide_source/egs_radionuclide_source.h new file mode 100644 index 000000000..19e188ce9 --- /dev/null +++ b/HEN_HOUSE/egs++/sources/egs_radionuclide_source/egs_radionuclide_source.h @@ -0,0 +1,369 @@ +/* +############################################################################### +# +# EGSnrc egs++ radionuclide source headers +# Copyright (C) 2015 National Research Council Canada +# +# This file is part of EGSnrc. +# +# EGSnrc is free software: you can redistribute it and/or modify it under +# the terms of the GNU Affero General Public License as published by the +# Free Software Foundation, either version 3 of the License, or (at your +# option) any later version. +# +# EGSnrc is distributed in the hope that it will be useful, but WITHOUT ANY +# WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS +# FOR A PARTICULAR PURPOSE. See the GNU Affero General Public License for +# more details. +# +# You should have received a copy of the GNU Affero General Public License +# along with EGSnrc. If not, see . +# +############################################################################### +# +# Author: Reid Townson, 2016 +# +# Contributors: +# +############################################################################### +*/ + + +/*! \file egs_radionuclide_source.h + * \brief A radionuclide source + * \IK + */ + +#ifndef EGS_RADIONUCLIDE_SOURCE_ +#define EGS_RADIONUCLIDE_SOURCE_ + +#include "egs_vector.h" +#include "egs_base_source.h" +#include "egs_rndm.h" +#include "egs_shapes.h" +#include "egs_base_geometry.h" +#include "egs_math.h" + +#include + + +#ifdef WIN32 + + #ifdef BUILD_RADIONUCLIDE_SOURCE_DLL + #define EGS_RADIONUCLIDE_SOURCE_EXPORT __declspec(dllexport) + #else + #define EGS_RADIONUCLIDE_SOURCE_EXPORT __declspec(dllimport) + #endif + #define EGS_RADIONUCLIDE_SOURCE_LOCAL + +#else + + #ifdef HAVE_VISIBILITY + #define EGS_RADIONUCLIDE_SOURCE_EXPORT __attribute__ ((visibility +("default"))) + #define EGS_RADIONUCLIDE_SOURCE_LOCAL __attribute__ ((visibility +("hidden"))) + #else + #define EGS_RADIONUCLIDE_SOURCE_EXPORT + #define EGS_RADIONUCLIDE_SOURCE_LOCAL + #endif + +#endif + +/*! \brief A radionuclide source + + \ingroup Sources + +A radionuclide source is a source that delivers particles with +directions uniformly distributed in \f$4 \pi\f$ emitted from +\link EGS_BaseShape any shape. Emissions are based on decays from the +radionuclide isotope and can be a mix of beta decays, X-radiations, etc. +\endlink +It is defined using the following input +\verbatim +:start source: + library = egs_radionuclide_source + name = some_name + :start shape: + definition of the shape + :stop shape: + :start spectrum: + definition of the spectrum (use the radionuclide type) + :stop spectrum: + charge = list including at least one of -1, 0, 1 for electrons, photons and +positrons + min theta = 80 (degree) + max theta = 100 (degree) +:stop source: +\endverbatim +It is worth noting that the functionality of source 3 in the RZ series +of user codes or source 6 in DOSXYZnrc can be reproduced with +the radionuclide source from the EGSnrc C++ class library. +*/ + +class EGS_RADIONUCLIDE_SOURCE_EXPORT EGS_RadionuclideSource : + public EGS_BaseSource { + +public: + + /*! \brief Geometry confinement options */ + enum GeometryConfinement { + IncludeAll = 0, + ExcludeAll = 1, + IncludeSelected = 2, + ExcludeSelected = 3 + }; + + /*! \brief Constructor + + Construct a radionuclide source with charge array \a Q, spectra array + \a Decays and emitting particles from the shape \a Shape + */ + EGS_RadionuclideSource(vector Q_allowed, vector + Decays, EGS_Float Activity, EGS_BaseShape *Shape, EGS_BaseGeometry + *geometry, const string &Name="", EGS_ObjectFactory *f=0) : + EGS_BaseSource(Name,f), shape(Shape), + min_theta(85.), max_theta(95.), min_phi(0), max_phi(2*M_PI), + buf_1(1), buf_2(-1), + geom(geometry), regions(0), nrs(0), gc(IncludeAll), + q_allowed(Q_allowed), decays(Decays), activity(Activity) { + setUp(); + }; + + /*! \brief Constructor + + Construct a radionuclide source from the information pointed to by \a inp. + */ + EGS_RadionuclideSource(EGS_Input *, EGS_ObjectFactory *f=0); + ~EGS_RadionuclideSource() { + EGS_Object::deleteObject(shape); + if (geom) { + if (!geom->deref()) { + delete geom; + } + } + if (nrs > 0 && regions) { + delete [] regions; + } + }; + + EGS_I64 getNextParticle(EGS_RandomGenerator *rndm, + int &q, int &latch, EGS_Float &E, EGS_Float &wt, + EGS_Vector &x, EGS_Vector &u); + +// EGS_I64 getNextParticle(EGS_RandomGenerator *rndm, +// int &q, int &latch, EGS_Float &E, EGS_Float &wt, +// EGS_Vector &x, EGS_Vector &u, EGS_I64 &ishower, +// EGS_Float &time); + + EGS_Float getEmax() const { + return Emax; + }; + + EGS_Float getFluence() const { + return count; + }; + + double getTime() const { + return time; + }; + + EGS_I64 getShowerIndex() const { + return ishower; + }; + + void printSampledEmissions() { + for(unsigned int i=0; iprintSampledEmissions(); + } + } + + void getPositionDirection(EGS_RandomGenerator *rndm, + EGS_Vector &x, EGS_Vector &u, EGS_Float &wt) { + bool ok = true; + do { + x = shape->getRandomPoint(rndm); + if (geom) { + if (gc == IncludeAll) { + ok = geom->isInside(x); + } + else if (gc == ExcludeAll) { + ok = !geom->isInside(x); + } + else if (gc == IncludeSelected) { + ok = false; + int ireg = geom->isWhere(x); + for (int j=0; jisWhere(x); + for (int j=0; jgetUniform()*(buf_1 - buf_2) - buf_1; + + EGS_Float sinz = 1-u.z*u.z; + if (sinz > 1e-15) { + sinz = sqrt(sinz); + EGS_Float cphi, sphi; + EGS_Float phi = min_phi +(max_phi - min_phi)*rndm->getUniform(); + cphi = cos(phi); + sphi = sin(phi); + u.x = sinz*cphi; + u.y = sinz*sphi; + } + else { + u.x = 0; + u.y = 0; + } + wt = 1; + }; + + bool storeFluenceState(ostream &data) const { + return true; + }; + + bool setFluenceState(istream &data) { + return true; + }; + + bool isValid() const { + return (decays.size() != 0 && shape != 0); + }; + + /*! \brief Store the source state to the data stream \a data_out. + * + * Uses the \link EGS_BaseSpectrum::storeState() storeState() \endlink + * of the spectrum object and the storeFluenceState() virtual function. + */ + bool storeState(ostream &data_out) const { + if (!egsStoreI64(data_out,count)) { + return false; + } + for(unsigned int i=0; istoreState(data_out)) { + return false; + } + } + if (!storeFluenceState(data_out)) { + return false; + } + return true; + }; + + /*! \brief Add the source state from the stream \a data to the + * current state. + * + * Uses the \link EGS_BaseSpectrum::addState() addState() \endlink + * of the spectrum object and the addFluenceData() virtual function. + */ + bool addState(istream &data) { + EGS_I64 count_save = count; + if (!egsGetI64(data,count)) { + return false; + } + for(unsigned int i=0; iaddState(data)) { + return false; + } + } + if (!addFluenceData(data)) { + return false; + } + count += count_save; + return true; + }; + + /*! \brief Reset the source to a state with zero sampled particles. + * + * Uses the \link EGS_BaseSpectrum::resetCounter() resetCounter() \endlink + * function of the spectrum object and the virtual function + * resetFluenceCounter(). + */ + void resetCounter() { + count = 0; + for(unsigned int i=0; iresetCounter(); + } + resetFluenceCounter(); + }; + + /*! \brief Add fluence data from the stream \a data to the current state. + * + * + * \sa storeFluenceState(), setFluenceState(), resetFluenceCounter(), + * setState(), storeState(), resetCounter() and addState(). + */ + bool addFluenceData(istream &data) { + return true; + } + + /*! \brief Reset the data related to the sampling of positions and + * directions to a state with zero sampled particles. + * + * \sa storeFluenceState(), setFluenceState(), addFluenceData(), + * setState(), storeState(), resetCounter() and addState(). + */ + void resetFluenceCounter() { }; + + /*! \brief Set the source state according to the data in the stream \a data. + * + * Uses the \link EGS_BaseSpectrum::setState() setState() \endlink + * method of the spectrum object and the setFluenceState() virtual + * function. + */ + bool setState(istream &data) { + if (!egsGetI64(data,count)) { + return false; + } + for(unsigned int i=0; isetState(data)) { + return false; + } + } + if (!setFluenceState(data)) { + return false; + } + return true; + }; + +protected: + + EGS_BaseShape *shape; //!< The shape from which particles are emitted. + EGS_BaseGeometry *geom; + int *regions; + + EGS_I64 count; + EGS_Float Emax; + + void setUp(); + + EGS_Float min_theta, max_theta; + EGS_Float buf_1, buf_2; //! avoid multi-calculating cos(min_theta) and + // cos(max_theta) + EGS_Float min_phi, max_phi; + int nrs; + GeometryConfinement gc; + + vector decays; //!< The radionuclide decay structure + vector q_allowed; + EGS_Float activity; + double time; + EGS_I64 ishower; +}; + +#endif From 24962e0f0e03d2a518506e8652f4cad8527ab74c Mon Sep 17 00:00:00 2001 From: Reid Townson Date: Wed, 6 Jul 2016 11:14:50 -0400 Subject: [PATCH 02/34] Add radionuclide gamma decays from unknown level Some gamma may be emitted but the energy level is not known. This is reported in the LNHB data as decays from the -1 level. Since we cannot correlate the emission with a change of energy states of the daughter, treat this gamma as an x-ray. --- HEN_HOUSE/egs++/egs_ensdf.cpp | 22 +++++++++++++++++++++- 1 file changed, 21 insertions(+), 1 deletion(-) diff --git a/HEN_HOUSE/egs++/egs_ensdf.cpp b/HEN_HOUSE/egs++/egs_ensdf.cpp index 5c384e8f2..dffab1da4 100644 --- a/HEN_HOUSE/egs++/egs_ensdf.cpp +++ b/HEN_HOUSE/egs++/egs_ensdf.cpp @@ -438,6 +438,26 @@ void EGS_Ensdf::parseEnsdf(vector ensdf) { // Get X-ray and auger emissions from comments getEmissionsFromComments(); + // Search through the gamma records for any with unknown levels + for(vector::iterator it = myGammaRecords.begin(); + it!=myGammaRecords.end(); it++) { + + // Some gamma may be emitted but the energy level is not known + // This is reported in the lnhb data as decays from the -1 level + // Since we cannot correlate the emission with a change of energy + // states of the daughter, we will treat this gamma as an xray + // The halflife will be ignored + if(!(*it)->getLevelRecord()) { + printf("EGS_Ensdf::parseEnsdf: Switching gamma with unknown " + "level to X-Ray for non-correlated sampling\n"); + xrayEnergies.push_back((*it)->getDecayEnergy()); + xrayIntensities.push_back((*it)->getTransitionIntensity()); + + // Erase the gamma record object + myGammaRecords.erase(it); + } + } + for(unsigned int i=0; i < xrayEnergies.size(); ++i) { printf("EGS_Ensdf::parseEnsdf: XRays (E,I): %f %f\n", xrayEnergies[i], xrayIntensities[i]); @@ -1224,7 +1244,7 @@ void GammaRecord::processEnsdf() { } printf("GammaRecord::processEnsdf: %f %f %f\n", decayEnergy, - transitionIntensity, halfLife); + transitionIntensity, halfLife); } double GammaRecord::getDecayEnergy() const { From d8588d43216365638d21774cb41244a465c3d8d5 Mon Sep 17 00:00:00 2001 From: Reid Townson Date: Wed, 6 Jul 2016 15:01:10 -0400 Subject: [PATCH 03/34] Add ENSDF radionuclide spectrum files from LNHB Change the HEN_HOUSE/spectra directory to contain two subdirectories egsnrc and lnhb. The lnhb directory contains spectra in ENSDF format for use with the radionuclide source. --- HEN_HOUSE/egs++/egs_ensdf.cpp | 4 +- .../egs_radionuclide_source.h | 31 +- .../spectra/{ => egsnrc}/10mvalnrcm.spectrum | 0 .../{ => egsnrc}/10mvalnrcmfilt.spectrum | 0 .../spectra/{ => egsnrc}/10mvpbnrcm.spectrum | 0 .../spectra/{ => egsnrc}/15mvalnrcm.spectrum | 0 .../spectra/{ => egsnrc}/15mvbenrcm.spectrum | 0 .../spectra/{ => egsnrc}/15mvpbnrcm.spectrum | 0 .../spectra/{ => egsnrc}/20mvalnrcm.spectrum | 0 .../{ => egsnrc}/20mvalnrcmfilt.spectrum | 0 .../spectra/{ => egsnrc}/20mvpbnrcm.spectrum | 0 HEN_HOUSE/spectra/{ => egsnrc}/250.spectrum | 0 .../spectra/{ => egsnrc}/25mvalnrcm.spectrum | 0 .../spectra/{ => egsnrc}/25mvpbnrcm.spectrum | 0 .../spectra/{ => egsnrc}/30mvalnrcm.spectrum | 0 .../spectra/{ => egsnrc}/30mvpbnrcm.spectrum | 0 .../{ => egsnrc}/Ir192_VariSource.spectrum | 0 .../{ => egsnrc}/Ir192_alpha_omega.spectrum | 0 .../{ => egsnrc}/Ir192_bare_1993.spectrum | 0 .../Ir192_best_industries.spectrum | 0 .../spectra/{ => egsnrc}/Ir192_beta.spectrum | 0 .../Ir192_microSelectron.spectrum | 0 HEN_HOUSE/spectra/{ => egsnrc}/LICENCE.md | 0 HEN_HOUSE/spectra/{ => egsnrc}/README.md | 0 .../spectra/{ => egsnrc}/al10mev.spectrum | 0 .../spectra/{ => egsnrc}/al20mev.spectrum | 0 .../spectra/{ => egsnrc}/al30mev.spectrum | 0 .../spectra/{ => egsnrc}/bareco60.spectrum | 0 HEN_HOUSE/spectra/{ => egsnrc}/co60.spectrum | 0 HEN_HOUSE/spectra/{ => egsnrc}/cs137.spectrum | 0 .../spectra/{ => egsnrc}/ir192bare.spectrum | 0 .../spectra/{ => egsnrc}/mohan10.spectrum | 0 .../spectra/{ => egsnrc}/mohan15.spectrum | 0 .../spectra/{ => egsnrc}/mohan24.spectrum | 0 .../spectra/{ => egsnrc}/mohan4.spectrum | 0 .../spectra/{ => egsnrc}/mohan6.spectrum | 0 .../{ => egsnrc}/mora_10x10_60co_ssd80.ensrc | 0 .../spectra/{ => egsnrc}/nrc10mv.spectrum | 0 .../spectra/{ => egsnrc}/nrc20mv.spectrum | 0 HEN_HOUSE/spectra/{ => egsnrc}/rt30.spectrum | 0 HEN_HOUSE/spectra/{ => egsnrc}/rt50.spectrum | 0 .../spectra/{ => egsnrc}/sr90y90.spectrum | 0 .../spectra/{ => egsnrc}/tritium.spectrum | 0 HEN_HOUSE/spectra/lnhb/Ac-225.txt | 358 ++++++++ HEN_HOUSE/spectra/lnhb/Ac-227.txt | 259 ++++++ HEN_HOUSE/spectra/lnhb/Ac-228.txt | 643 ++++++++++++++ HEN_HOUSE/spectra/lnhb/Ag-108.txt | 92 ++ HEN_HOUSE/spectra/lnhb/Ag-108m.txt | 65 ++ HEN_HOUSE/spectra/lnhb/Ag-110.txt | 92 ++ HEN_HOUSE/spectra/lnhb/Ag-110m.txt | 184 ++++ HEN_HOUSE/spectra/lnhb/Al-26.txt | 30 + HEN_HOUSE/spectra/lnhb/Am-241.txt | 416 +++++++++ HEN_HOUSE/spectra/lnhb/Am-242.txt | 83 ++ HEN_HOUSE/spectra/lnhb/Am-242m.txt | 257 ++++++ HEN_HOUSE/spectra/lnhb/Am-243.txt | 88 ++ HEN_HOUSE/spectra/lnhb/Am-244.txt | 55 ++ HEN_HOUSE/spectra/lnhb/Am-244m.txt | 98 +++ HEN_HOUSE/spectra/lnhb/Ar-37.txt | 29 + HEN_HOUSE/spectra/lnhb/Ar-41.txt | 34 + HEN_HOUSE/spectra/lnhb/At-211.txt | 98 +++ HEN_HOUSE/spectra/lnhb/At-215.txt | 39 + HEN_HOUSE/spectra/lnhb/At-217.txt | 58 ++ HEN_HOUSE/spectra/lnhb/At-218.txt | 25 + HEN_HOUSE/spectra/lnhb/At-219.txt | 57 ++ HEN_HOUSE/spectra/lnhb/Au-195.txt | 60 ++ HEN_HOUSE/spectra/lnhb/Au-198.txt | 61 ++ HEN_HOUSE/spectra/lnhb/Ba-133.txt | 77 ++ HEN_HOUSE/spectra/lnhb/Ba-137m.txt | 30 + HEN_HOUSE/spectra/lnhb/Ba-140.txt | 80 ++ HEN_HOUSE/spectra/lnhb/Be-7.txt | 21 + HEN_HOUSE/spectra/lnhb/Bi-207.txt | 56 ++ HEN_HOUSE/spectra/lnhb/Bi-210.txt | 88 ++ HEN_HOUSE/spectra/lnhb/Bi-211.txt | 72 ++ HEN_HOUSE/spectra/lnhb/Bi-212.txt | 158 ++++ HEN_HOUSE/spectra/lnhb/Bi-213.txt | 119 +++ HEN_HOUSE/spectra/lnhb/Bi-214.txt | 570 ++++++++++++ HEN_HOUSE/spectra/lnhb/Bi-215.txt | 97 +++ HEN_HOUSE/spectra/lnhb/C-11.txt | 11 + HEN_HOUSE/spectra/lnhb/C-14.txt | 14 + HEN_HOUSE/spectra/lnhb/Ca-41.txt | 33 + HEN_HOUSE/spectra/lnhb/Ca-45.txt | 19 + HEN_HOUSE/spectra/lnhb/Cd-109.txt | 49 ++ HEN_HOUSE/spectra/lnhb/Ce-139.txt | 39 + HEN_HOUSE/spectra/lnhb/Ce-141.txt | 46 + HEN_HOUSE/spectra/lnhb/Ce-144.txt | 67 ++ HEN_HOUSE/spectra/lnhb/Cf-252.txt | 51 ++ HEN_HOUSE/spectra/lnhb/Cl-36.txt | 55 ++ HEN_HOUSE/spectra/lnhb/Cm-242.txt | 123 +++ HEN_HOUSE/spectra/lnhb/Cm-243.txt | 196 +++++ HEN_HOUSE/spectra/lnhb/Cm-244.txt | 102 +++ HEN_HOUSE/spectra/lnhb/Cm-245.txt | 87 ++ HEN_HOUSE/spectra/lnhb/Cm-246.txt | 42 + HEN_HOUSE/spectra/lnhb/Co-56.txt | 115 +++ HEN_HOUSE/spectra/lnhb/Co-57.txt | 57 ++ HEN_HOUSE/spectra/lnhb/Co-58.txt | 56 ++ HEN_HOUSE/spectra/lnhb/Co-60.txt | 50 ++ HEN_HOUSE/spectra/lnhb/Cr-51.txt | 47 + HEN_HOUSE/spectra/lnhb/Cs-134.txt | 103 +++ HEN_HOUSE/spectra/lnhb/Cs-137.txt | 45 + HEN_HOUSE/spectra/lnhb/Cu-61.txt | 107 +++ HEN_HOUSE/spectra/lnhb/Cu-64.txt | 57 ++ HEN_HOUSE/spectra/lnhb/Er-169.txt | 37 + HEN_HOUSE/spectra/lnhb/Eu-152.txt | 411 +++++++++ HEN_HOUSE/spectra/lnhb/Eu-154.txt | 443 ++++++++++ HEN_HOUSE/spectra/lnhb/Eu-155.txt | 75 ++ HEN_HOUSE/spectra/lnhb/F-18.txt | 30 + HEN_HOUSE/spectra/lnhb/Fe-52.txt | 44 + HEN_HOUSE/spectra/lnhb/Fe-55.txt | 36 + HEN_HOUSE/spectra/lnhb/Fe-59.txt | 66 ++ HEN_HOUSE/spectra/lnhb/Fr-221.txt | 114 +++ HEN_HOUSE/spectra/lnhb/Fr-223.txt | 345 ++++++++ HEN_HOUSE/spectra/lnhb/Ga-66.txt | 243 ++++++ HEN_HOUSE/spectra/lnhb/Ga-67.txt | 76 ++ HEN_HOUSE/spectra/lnhb/Ga-68.txt | 77 ++ HEN_HOUSE/spectra/lnhb/Gd-153.txt | 67 ++ HEN_HOUSE/spectra/lnhb/Gd-159.txt | 95 ++ HEN_HOUSE/spectra/lnhb/Ge-68.txt | 37 + HEN_HOUSE/spectra/lnhb/H-3.txt | 13 + HEN_HOUSE/spectra/lnhb/Hg-203.txt | 37 + HEN_HOUSE/spectra/lnhb/Hg-206.txt | 55 ++ HEN_HOUSE/spectra/lnhb/Ho-166.txt | 82 ++ HEN_HOUSE/spectra/lnhb/Ho-166m.txt | 175 ++++ HEN_HOUSE/spectra/lnhb/I-123.txt | 126 +++ HEN_HOUSE/spectra/lnhb/I-125.txt | 46 + HEN_HOUSE/spectra/lnhb/I-129.txt | 34 + HEN_HOUSE/spectra/lnhb/I-131.txt | 99 +++ HEN_HOUSE/spectra/lnhb/I-133.txt | 135 +++ HEN_HOUSE/spectra/lnhb/In-111.txt | 52 ++ HEN_HOUSE/spectra/lnhb/Ir-192.txt | 152 ++++ HEN_HOUSE/spectra/lnhb/Ir-194.txt | 212 +++++ HEN_HOUSE/spectra/lnhb/K-40.txt | 67 ++ HEN_HOUSE/spectra/lnhb/Kr-85.txt | 37 + HEN_HOUSE/spectra/lnhb/La-138.txt | 84 ++ HEN_HOUSE/spectra/lnhb/La-140.txt | 168 ++++ HEN_HOUSE/spectra/lnhb/Lu-177.txt | 53 ++ HEN_HOUSE/spectra/lnhb/Mn-54.txt | 46 + HEN_HOUSE/spectra/lnhb/Mn-56.txt | 55 ++ HEN_HOUSE/spectra/lnhb/Mo-99.txt | 120 +++ HEN_HOUSE/spectra/lnhb/N-13.txt | 7 + HEN_HOUSE/spectra/lnhb/Na-22.txt | 33 + HEN_HOUSE/spectra/lnhb/Na-24.txt | 55 ++ HEN_HOUSE/spectra/lnhb/Nb-93m.txt | 41 + HEN_HOUSE/spectra/lnhb/Nb-95.txt | 42 + HEN_HOUSE/spectra/lnhb/Nb-95m.txt | 74 ++ HEN_HOUSE/spectra/lnhb/Nd-147.txt | 125 +++ HEN_HOUSE/spectra/lnhb/Ni-57.txt | 84 ++ HEN_HOUSE/spectra/lnhb/Ni-59.txt | 33 + HEN_HOUSE/spectra/lnhb/Ni-63.txt | 26 + HEN_HOUSE/spectra/lnhb/Np-236.txt | 195 +++++ HEN_HOUSE/spectra/lnhb/Np-236m.txt | 97 +++ HEN_HOUSE/spectra/lnhb/Np-237.txt | 199 +++++ HEN_HOUSE/spectra/lnhb/Np-238.txt | 146 ++++ HEN_HOUSE/spectra/lnhb/Np-239.txt | 141 +++ HEN_HOUSE/spectra/lnhb/O-15.txt | 7 + HEN_HOUSE/spectra/lnhb/P-32.txt | 7 + HEN_HOUSE/spectra/lnhb/P-33.txt | 7 + HEN_HOUSE/spectra/lnhb/Pa-231.txt | 215 +++++ HEN_HOUSE/spectra/lnhb/Pa-233.txt | 161 ++++ HEN_HOUSE/spectra/lnhb/Pa-234.txt | 819 ++++++++++++++++++ HEN_HOUSE/spectra/lnhb/Pa-234m.txt | 358 ++++++++ HEN_HOUSE/spectra/lnhb/Pb-203.txt | 53 ++ HEN_HOUSE/spectra/lnhb/Pb-209.txt | 32 + HEN_HOUSE/spectra/lnhb/Pb-210.txt | 70 ++ HEN_HOUSE/spectra/lnhb/Pb-211.txt | 98 +++ HEN_HOUSE/spectra/lnhb/Pb-212.txt | 60 ++ HEN_HOUSE/spectra/lnhb/Pb-214.txt | 100 +++ HEN_HOUSE/spectra/lnhb/Pd-109.txt | 150 ++++ HEN_HOUSE/spectra/lnhb/Pm-147.txt | 61 ++ HEN_HOUSE/spectra/lnhb/Pm-148.txt | 111 +++ HEN_HOUSE/spectra/lnhb/Pm-148m.txt | 143 +++ HEN_HOUSE/spectra/lnhb/Po-209.txt | 83 ++ HEN_HOUSE/spectra/lnhb/Po-210.txt | 46 + HEN_HOUSE/spectra/lnhb/Po-211.txt | 49 ++ HEN_HOUSE/spectra/lnhb/Po-212.txt | 18 + HEN_HOUSE/spectra/lnhb/Po-213.txt | 19 + HEN_HOUSE/spectra/lnhb/Po-214.txt | 39 + HEN_HOUSE/spectra/lnhb/Po-215.txt | 89 ++ HEN_HOUSE/spectra/lnhb/Po-216.txt | 42 + HEN_HOUSE/spectra/lnhb/Po-218.txt | 63 ++ HEN_HOUSE/spectra/lnhb/Pr-144.txt | 106 +++ HEN_HOUSE/spectra/lnhb/Pr-144m.txt | 97 +++ HEN_HOUSE/spectra/lnhb/Pu-238.txt | 137 +++ HEN_HOUSE/spectra/lnhb/Pu-239.txt | 515 +++++++++++ HEN_HOUSE/spectra/lnhb/Pu-240.txt | 97 +++ HEN_HOUSE/spectra/lnhb/Pu-241.txt | 121 +++ HEN_HOUSE/spectra/lnhb/Pu-242.txt | 50 ++ HEN_HOUSE/spectra/lnhb/Ra-223.txt | 204 +++++ HEN_HOUSE/spectra/lnhb/Ra-224.txt | 58 ++ HEN_HOUSE/spectra/lnhb/Ra-225.txt | 35 + HEN_HOUSE/spectra/lnhb/Ra-226.txt | 54 ++ HEN_HOUSE/spectra/lnhb/Ra-228.txt | 45 + HEN_HOUSE/spectra/lnhb/Rb-82.txt | 155 ++++ HEN_HOUSE/spectra/lnhb/Re-186.txt | 95 ++ HEN_HOUSE/spectra/lnhb/Re-188.txt | 177 ++++ HEN_HOUSE/spectra/lnhb/Rh-106.txt | 268 ++++++ HEN_HOUSE/spectra/lnhb/Rn-217.txt | 15 + HEN_HOUSE/spectra/lnhb/Rn-218.txt | 35 + HEN_HOUSE/spectra/lnhb/Rn-219.txt | 102 +++ HEN_HOUSE/spectra/lnhb/Rn-220.txt | 43 + HEN_HOUSE/spectra/lnhb/Rn-222.txt | 37 + HEN_HOUSE/spectra/lnhb/Ru-106.txt | 29 + HEN_HOUSE/spectra/lnhb/S-35.txt | 20 + HEN_HOUSE/spectra/lnhb/Sb-124.txt | 224 +++++ HEN_HOUSE/spectra/lnhb/Sb-125.txt | 112 +++ HEN_HOUSE/spectra/lnhb/Sb-127.txt | 159 ++++ HEN_HOUSE/spectra/lnhb/Sc-44.txt | 39 + HEN_HOUSE/spectra/lnhb/Sc-46.txt | 47 + HEN_HOUSE/spectra/lnhb/Sc-47.txt | 38 + HEN_HOUSE/spectra/lnhb/Se-73.txt | 173 ++++ HEN_HOUSE/spectra/lnhb/Se-75.txt | 108 +++ HEN_HOUSE/spectra/lnhb/Se-79.txt | 21 + HEN_HOUSE/spectra/lnhb/Sm-151.txt | 43 + HEN_HOUSE/spectra/lnhb/Sm-153.txt | 168 ++++ HEN_HOUSE/spectra/lnhb/Sn-113.txt | 51 ++ HEN_HOUSE/spectra/lnhb/Sr-82.txt | 35 + HEN_HOUSE/spectra/lnhb/Sr-85.txt | 58 ++ HEN_HOUSE/spectra/lnhb/Sr-89.txt | 26 + HEN_HOUSE/spectra/lnhb/Sr-90.txt | 33 + HEN_HOUSE/spectra/lnhb/Ta-182.txt | 164 ++++ HEN_HOUSE/spectra/lnhb/Tc-94m.txt | 190 ++++ HEN_HOUSE/spectra/lnhb/Tc-99.txt | 46 + HEN_HOUSE/spectra/lnhb/Tc-99m.txt | 69 ++ HEN_HOUSE/spectra/lnhb/Te-123m.txt | 42 + HEN_HOUSE/spectra/lnhb/Te-127.txt | 73 ++ HEN_HOUSE/spectra/lnhb/Te-127m.txt | 104 +++ HEN_HOUSE/spectra/lnhb/Te-132.txt | 50 ++ HEN_HOUSE/spectra/lnhb/Th-228.txt | 83 ++ HEN_HOUSE/spectra/lnhb/Th-231.txt | 168 ++++ HEN_HOUSE/spectra/lnhb/Th-232.txt | 45 + HEN_HOUSE/spectra/lnhb/Th-233.txt | 306 +++++++ HEN_HOUSE/spectra/lnhb/Th-234.txt | 79 ++ HEN_HOUSE/spectra/lnhb/Ti-44.txt | 35 + HEN_HOUSE/spectra/lnhb/Tl-201.txt | 61 ++ HEN_HOUSE/spectra/lnhb/Tl-204.txt | 53 ++ HEN_HOUSE/spectra/lnhb/Tl-206.txt | 46 + HEN_HOUSE/spectra/lnhb/Tl-207.txt | 51 ++ HEN_HOUSE/spectra/lnhb/Tl-208.txt | 142 +++ HEN_HOUSE/spectra/lnhb/Tl-209.txt | 102 +++ HEN_HOUSE/spectra/lnhb/Tl-210.txt | 81 ++ HEN_HOUSE/spectra/lnhb/Tm-170.txt | 72 ++ HEN_HOUSE/spectra/lnhb/U-232.txt | 82 ++ HEN_HOUSE/spectra/lnhb/U-234.txt | 66 ++ HEN_HOUSE/spectra/lnhb/U-235.txt | 189 ++++ HEN_HOUSE/spectra/lnhb/U-236.txt | 48 + HEN_HOUSE/spectra/lnhb/U-237.txt | 122 +++ HEN_HOUSE/spectra/lnhb/U-238.txt | 49 ++ HEN_HOUSE/spectra/lnhb/U-239.txt | 313 +++++++ HEN_HOUSE/spectra/lnhb/Xe-127.txt | 57 ++ HEN_HOUSE/spectra/lnhb/Xe-131m.txt | 40 + HEN_HOUSE/spectra/lnhb/Xe-133.txt | 60 ++ HEN_HOUSE/spectra/lnhb/Xe-133m.txt | 38 + HEN_HOUSE/spectra/lnhb/Xe-135m.txt | 88 ++ HEN_HOUSE/spectra/lnhb/Y-88.txt | 62 ++ HEN_HOUSE/spectra/lnhb/Y-90.txt | 52 ++ HEN_HOUSE/spectra/lnhb/Y-90m.txt | 76 ++ HEN_HOUSE/spectra/lnhb/Yb-169.txt | 161 ++++ HEN_HOUSE/spectra/lnhb/Zn-63.txt | 178 ++++ HEN_HOUSE/spectra/lnhb/Zn-65.txt | 45 + HEN_HOUSE/spectra/lnhb/Zr-89.txt | 62 ++ HEN_HOUSE/spectra/lnhb/Zr-93.txt | 40 + HEN_HOUSE/spectra/lnhb/Zr-95.txt | 44 + 261 files changed, 22149 insertions(+), 12 deletions(-) rename HEN_HOUSE/spectra/{ => egsnrc}/10mvalnrcm.spectrum (100%) rename HEN_HOUSE/spectra/{ => egsnrc}/10mvalnrcmfilt.spectrum (100%) rename HEN_HOUSE/spectra/{ => egsnrc}/10mvpbnrcm.spectrum (100%) rename HEN_HOUSE/spectra/{ => egsnrc}/15mvalnrcm.spectrum (100%) rename HEN_HOUSE/spectra/{ => egsnrc}/15mvbenrcm.spectrum (100%) rename HEN_HOUSE/spectra/{ => egsnrc}/15mvpbnrcm.spectrum (100%) rename HEN_HOUSE/spectra/{ => egsnrc}/20mvalnrcm.spectrum (100%) rename HEN_HOUSE/spectra/{ => egsnrc}/20mvalnrcmfilt.spectrum (100%) rename HEN_HOUSE/spectra/{ => egsnrc}/20mvpbnrcm.spectrum (100%) rename HEN_HOUSE/spectra/{ => egsnrc}/250.spectrum (100%) rename HEN_HOUSE/spectra/{ => egsnrc}/25mvalnrcm.spectrum (100%) rename HEN_HOUSE/spectra/{ => egsnrc}/25mvpbnrcm.spectrum (100%) rename HEN_HOUSE/spectra/{ => egsnrc}/30mvalnrcm.spectrum (100%) rename HEN_HOUSE/spectra/{ => egsnrc}/30mvpbnrcm.spectrum (100%) rename HEN_HOUSE/spectra/{ => egsnrc}/Ir192_VariSource.spectrum (100%) rename HEN_HOUSE/spectra/{ => egsnrc}/Ir192_alpha_omega.spectrum (100%) rename HEN_HOUSE/spectra/{ => egsnrc}/Ir192_bare_1993.spectrum (100%) rename HEN_HOUSE/spectra/{ => egsnrc}/Ir192_best_industries.spectrum (100%) rename HEN_HOUSE/spectra/{ => egsnrc}/Ir192_beta.spectrum (100%) rename HEN_HOUSE/spectra/{ => egsnrc}/Ir192_microSelectron.spectrum (100%) rename HEN_HOUSE/spectra/{ => egsnrc}/LICENCE.md (100%) rename HEN_HOUSE/spectra/{ => egsnrc}/README.md (100%) rename HEN_HOUSE/spectra/{ => egsnrc}/al10mev.spectrum (100%) rename HEN_HOUSE/spectra/{ => egsnrc}/al20mev.spectrum (100%) rename HEN_HOUSE/spectra/{ => egsnrc}/al30mev.spectrum (100%) rename HEN_HOUSE/spectra/{ => egsnrc}/bareco60.spectrum (100%) rename HEN_HOUSE/spectra/{ => egsnrc}/co60.spectrum (100%) rename HEN_HOUSE/spectra/{ => egsnrc}/cs137.spectrum (100%) rename HEN_HOUSE/spectra/{ => egsnrc}/ir192bare.spectrum (100%) rename HEN_HOUSE/spectra/{ => egsnrc}/mohan10.spectrum (100%) rename HEN_HOUSE/spectra/{ => egsnrc}/mohan15.spectrum (100%) rename HEN_HOUSE/spectra/{ => egsnrc}/mohan24.spectrum (100%) rename HEN_HOUSE/spectra/{ => egsnrc}/mohan4.spectrum (100%) rename HEN_HOUSE/spectra/{ => egsnrc}/mohan6.spectrum (100%) rename HEN_HOUSE/spectra/{ => egsnrc}/mora_10x10_60co_ssd80.ensrc (100%) rename HEN_HOUSE/spectra/{ => egsnrc}/nrc10mv.spectrum (100%) rename HEN_HOUSE/spectra/{ => egsnrc}/nrc20mv.spectrum (100%) rename HEN_HOUSE/spectra/{ => egsnrc}/rt30.spectrum (100%) rename HEN_HOUSE/spectra/{ => egsnrc}/rt50.spectrum (100%) rename HEN_HOUSE/spectra/{ => egsnrc}/sr90y90.spectrum (100%) rename HEN_HOUSE/spectra/{ => egsnrc}/tritium.spectrum (100%) create mode 100644 HEN_HOUSE/spectra/lnhb/Ac-225.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Ac-227.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Ac-228.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Ag-108.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Ag-108m.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Ag-110.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Ag-110m.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Al-26.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Am-241.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Am-242.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Am-242m.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Am-243.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Am-244.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Am-244m.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Ar-37.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Ar-41.txt create mode 100644 HEN_HOUSE/spectra/lnhb/At-211.txt create mode 100644 HEN_HOUSE/spectra/lnhb/At-215.txt create mode 100644 HEN_HOUSE/spectra/lnhb/At-217.txt create mode 100644 HEN_HOUSE/spectra/lnhb/At-218.txt create mode 100644 HEN_HOUSE/spectra/lnhb/At-219.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Au-195.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Au-198.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Ba-133.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Ba-137m.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Ba-140.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Be-7.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Bi-207.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Bi-210.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Bi-211.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Bi-212.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Bi-213.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Bi-214.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Bi-215.txt create mode 100644 HEN_HOUSE/spectra/lnhb/C-11.txt create mode 100644 HEN_HOUSE/spectra/lnhb/C-14.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Ca-41.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Ca-45.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Cd-109.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Ce-139.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Ce-141.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Ce-144.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Cf-252.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Cl-36.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Cm-242.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Cm-243.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Cm-244.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Cm-245.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Cm-246.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Co-56.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Co-57.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Co-58.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Co-60.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Cr-51.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Cs-134.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Cs-137.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Cu-61.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Cu-64.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Er-169.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Eu-152.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Eu-154.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Eu-155.txt create mode 100644 HEN_HOUSE/spectra/lnhb/F-18.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Fe-52.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Fe-55.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Fe-59.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Fr-221.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Fr-223.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Ga-66.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Ga-67.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Ga-68.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Gd-153.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Gd-159.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Ge-68.txt create mode 100644 HEN_HOUSE/spectra/lnhb/H-3.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Hg-203.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Hg-206.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Ho-166.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Ho-166m.txt create mode 100644 HEN_HOUSE/spectra/lnhb/I-123.txt create mode 100644 HEN_HOUSE/spectra/lnhb/I-125.txt create mode 100644 HEN_HOUSE/spectra/lnhb/I-129.txt create mode 100644 HEN_HOUSE/spectra/lnhb/I-131.txt create mode 100644 HEN_HOUSE/spectra/lnhb/I-133.txt create mode 100644 HEN_HOUSE/spectra/lnhb/In-111.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Ir-192.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Ir-194.txt create mode 100644 HEN_HOUSE/spectra/lnhb/K-40.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Kr-85.txt create mode 100644 HEN_HOUSE/spectra/lnhb/La-138.txt create mode 100644 HEN_HOUSE/spectra/lnhb/La-140.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Lu-177.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Mn-54.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Mn-56.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Mo-99.txt create mode 100644 HEN_HOUSE/spectra/lnhb/N-13.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Na-22.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Na-24.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Nb-93m.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Nb-95.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Nb-95m.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Nd-147.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Ni-57.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Ni-59.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Ni-63.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Np-236.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Np-236m.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Np-237.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Np-238.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Np-239.txt create mode 100644 HEN_HOUSE/spectra/lnhb/O-15.txt create mode 100644 HEN_HOUSE/spectra/lnhb/P-32.txt create mode 100644 HEN_HOUSE/spectra/lnhb/P-33.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Pa-231.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Pa-233.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Pa-234.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Pa-234m.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Pb-203.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Pb-209.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Pb-210.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Pb-211.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Pb-212.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Pb-214.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Pd-109.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Pm-147.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Pm-148.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Pm-148m.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Po-209.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Po-210.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Po-211.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Po-212.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Po-213.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Po-214.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Po-215.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Po-216.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Po-218.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Pr-144.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Pr-144m.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Pu-238.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Pu-239.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Pu-240.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Pu-241.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Pu-242.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Ra-223.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Ra-224.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Ra-225.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Ra-226.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Ra-228.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Rb-82.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Re-186.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Re-188.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Rh-106.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Rn-217.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Rn-218.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Rn-219.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Rn-220.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Rn-222.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Ru-106.txt create mode 100644 HEN_HOUSE/spectra/lnhb/S-35.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Sb-124.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Sb-125.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Sb-127.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Sc-44.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Sc-46.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Sc-47.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Se-73.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Se-75.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Se-79.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Sm-151.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Sm-153.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Sn-113.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Sr-82.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Sr-85.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Sr-89.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Sr-90.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Ta-182.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Tc-94m.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Tc-99.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Tc-99m.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Te-123m.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Te-127.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Te-127m.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Te-132.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Th-228.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Th-231.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Th-232.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Th-233.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Th-234.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Ti-44.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Tl-201.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Tl-204.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Tl-206.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Tl-207.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Tl-208.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Tl-209.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Tl-210.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Tm-170.txt create mode 100644 HEN_HOUSE/spectra/lnhb/U-232.txt create mode 100644 HEN_HOUSE/spectra/lnhb/U-234.txt create mode 100644 HEN_HOUSE/spectra/lnhb/U-235.txt create mode 100644 HEN_HOUSE/spectra/lnhb/U-236.txt create mode 100644 HEN_HOUSE/spectra/lnhb/U-237.txt create mode 100644 HEN_HOUSE/spectra/lnhb/U-238.txt create mode 100644 HEN_HOUSE/spectra/lnhb/U-239.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Xe-127.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Xe-131m.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Xe-133.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Xe-133m.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Xe-135m.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Y-88.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Y-90.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Y-90m.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Yb-169.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Zn-63.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Zn-65.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Zr-89.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Zr-93.txt create mode 100644 HEN_HOUSE/spectra/lnhb/Zr-95.txt diff --git a/HEN_HOUSE/egs++/egs_ensdf.cpp b/HEN_HOUSE/egs++/egs_ensdf.cpp index dffab1da4..98fb75c0c 100644 --- a/HEN_HOUSE/egs++/egs_ensdf.cpp +++ b/HEN_HOUSE/egs++/egs_ensdf.cpp @@ -516,7 +516,7 @@ void EGS_Ensdf::buildRecords() { AlphaRecord(recordStack[i], LastParent, LastNormalization, LastLevel)); } else if(i==11) { - printf("EGS_Ensdf::buildRecords: ERROR: Delayed particle not " + printf("EGS_Ensdf::buildRecords: Warning: Delayed particle not " "supported! Further development required.\n"); } else if(i==12) { myGammaRecords.push_back(new @@ -1244,7 +1244,7 @@ void GammaRecord::processEnsdf() { } printf("GammaRecord::processEnsdf: %f %f %f\n", decayEnergy, - transitionIntensity, halfLife); + transitionIntensity, halfLife); } double GammaRecord::getDecayEnergy() const { diff --git a/HEN_HOUSE/egs++/sources/egs_radionuclide_source/egs_radionuclide_source.h b/HEN_HOUSE/egs++/sources/egs_radionuclide_source/egs_radionuclide_source.h index 19e188ce9..154247ff4 100644 --- a/HEN_HOUSE/egs++/sources/egs_radionuclide_source/egs_radionuclide_source.h +++ b/HEN_HOUSE/egs++/sources/egs_radionuclide_source/egs_radionuclide_source.h @@ -82,23 +82,34 @@ radionuclide isotope and can be a mix of beta decays, X-radiations, etc. It is defined using the following input \verbatim :start source: - library = egs_radionuclide_source - name = some_name + name = my_mixture + library = egs_radionuclide_source + activity = total activity of mixture, assumed constant + charge = list including at least one of -1, 0, 1 to +include electrons, photons and positrons + geometry = my_geometry # see egs_isotropic_source + region selection = geometry confinement option, one of IncludeAll, +ExcludeAll, IncludeSelected, ExcludeSelected + selected regions = regions to apply geometry confinement :start shape: definition of the shape :stop shape: :start spectrum: - definition of the spectrum (use the radionuclide type) + type = radionuclide + isotope = name of the isotope (e.g. Sr-90), used to look up the +ensdf file in $HEN_HOUSE/spectra/lnhb if ensdf file not provided + ensdf file = [optional] path to a spectrum file in ensdf format + weight = [optional] the relative activity (sampling +probability) for this isotope in a mixture + :stop spectrum: + :start spectrum: + type = radionuclide + isotope = name of next isotope in mixture (e.g. Y-90) + weight = ... :stop spectrum: - charge = list including at least one of -1, 0, 1 for electrons, photons and -positrons - min theta = 80 (degree) - max theta = 100 (degree) :stop source: \endverbatim -It is worth noting that the functionality of source 3 in the RZ series -of user codes or source 6 in DOSXYZnrc can be reproduced with -the radionuclide source from the EGSnrc C++ class library. + */ class EGS_RADIONUCLIDE_SOURCE_EXPORT EGS_RadionuclideSource : diff --git a/HEN_HOUSE/spectra/10mvalnrcm.spectrum b/HEN_HOUSE/spectra/egsnrc/10mvalnrcm.spectrum similarity index 100% rename from HEN_HOUSE/spectra/10mvalnrcm.spectrum rename to HEN_HOUSE/spectra/egsnrc/10mvalnrcm.spectrum diff --git a/HEN_HOUSE/spectra/10mvalnrcmfilt.spectrum b/HEN_HOUSE/spectra/egsnrc/10mvalnrcmfilt.spectrum similarity index 100% rename from HEN_HOUSE/spectra/10mvalnrcmfilt.spectrum rename to HEN_HOUSE/spectra/egsnrc/10mvalnrcmfilt.spectrum diff --git a/HEN_HOUSE/spectra/10mvpbnrcm.spectrum b/HEN_HOUSE/spectra/egsnrc/10mvpbnrcm.spectrum similarity index 100% rename from HEN_HOUSE/spectra/10mvpbnrcm.spectrum rename to HEN_HOUSE/spectra/egsnrc/10mvpbnrcm.spectrum diff --git a/HEN_HOUSE/spectra/15mvalnrcm.spectrum b/HEN_HOUSE/spectra/egsnrc/15mvalnrcm.spectrum similarity index 100% rename from HEN_HOUSE/spectra/15mvalnrcm.spectrum rename to HEN_HOUSE/spectra/egsnrc/15mvalnrcm.spectrum diff --git a/HEN_HOUSE/spectra/15mvbenrcm.spectrum b/HEN_HOUSE/spectra/egsnrc/15mvbenrcm.spectrum similarity index 100% rename from HEN_HOUSE/spectra/15mvbenrcm.spectrum rename to HEN_HOUSE/spectra/egsnrc/15mvbenrcm.spectrum diff --git a/HEN_HOUSE/spectra/15mvpbnrcm.spectrum b/HEN_HOUSE/spectra/egsnrc/15mvpbnrcm.spectrum similarity index 100% rename from HEN_HOUSE/spectra/15mvpbnrcm.spectrum rename to HEN_HOUSE/spectra/egsnrc/15mvpbnrcm.spectrum diff --git a/HEN_HOUSE/spectra/20mvalnrcm.spectrum b/HEN_HOUSE/spectra/egsnrc/20mvalnrcm.spectrum similarity index 100% rename from HEN_HOUSE/spectra/20mvalnrcm.spectrum rename to HEN_HOUSE/spectra/egsnrc/20mvalnrcm.spectrum diff --git a/HEN_HOUSE/spectra/20mvalnrcmfilt.spectrum b/HEN_HOUSE/spectra/egsnrc/20mvalnrcmfilt.spectrum similarity index 100% rename from HEN_HOUSE/spectra/20mvalnrcmfilt.spectrum rename to HEN_HOUSE/spectra/egsnrc/20mvalnrcmfilt.spectrum diff --git a/HEN_HOUSE/spectra/20mvpbnrcm.spectrum b/HEN_HOUSE/spectra/egsnrc/20mvpbnrcm.spectrum similarity index 100% rename from HEN_HOUSE/spectra/20mvpbnrcm.spectrum rename to HEN_HOUSE/spectra/egsnrc/20mvpbnrcm.spectrum diff --git a/HEN_HOUSE/spectra/250.spectrum b/HEN_HOUSE/spectra/egsnrc/250.spectrum similarity index 100% rename from HEN_HOUSE/spectra/250.spectrum rename to HEN_HOUSE/spectra/egsnrc/250.spectrum diff --git a/HEN_HOUSE/spectra/25mvalnrcm.spectrum b/HEN_HOUSE/spectra/egsnrc/25mvalnrcm.spectrum similarity index 100% rename from HEN_HOUSE/spectra/25mvalnrcm.spectrum rename to HEN_HOUSE/spectra/egsnrc/25mvalnrcm.spectrum diff --git a/HEN_HOUSE/spectra/25mvpbnrcm.spectrum b/HEN_HOUSE/spectra/egsnrc/25mvpbnrcm.spectrum similarity index 100% rename from HEN_HOUSE/spectra/25mvpbnrcm.spectrum rename to HEN_HOUSE/spectra/egsnrc/25mvpbnrcm.spectrum diff --git a/HEN_HOUSE/spectra/30mvalnrcm.spectrum b/HEN_HOUSE/spectra/egsnrc/30mvalnrcm.spectrum similarity index 100% rename from HEN_HOUSE/spectra/30mvalnrcm.spectrum rename to HEN_HOUSE/spectra/egsnrc/30mvalnrcm.spectrum diff --git a/HEN_HOUSE/spectra/30mvpbnrcm.spectrum b/HEN_HOUSE/spectra/egsnrc/30mvpbnrcm.spectrum similarity index 100% rename from HEN_HOUSE/spectra/30mvpbnrcm.spectrum rename to HEN_HOUSE/spectra/egsnrc/30mvpbnrcm.spectrum diff --git a/HEN_HOUSE/spectra/Ir192_VariSource.spectrum b/HEN_HOUSE/spectra/egsnrc/Ir192_VariSource.spectrum similarity index 100% rename from HEN_HOUSE/spectra/Ir192_VariSource.spectrum rename to HEN_HOUSE/spectra/egsnrc/Ir192_VariSource.spectrum diff --git a/HEN_HOUSE/spectra/Ir192_alpha_omega.spectrum b/HEN_HOUSE/spectra/egsnrc/Ir192_alpha_omega.spectrum similarity index 100% rename from HEN_HOUSE/spectra/Ir192_alpha_omega.spectrum rename to HEN_HOUSE/spectra/egsnrc/Ir192_alpha_omega.spectrum diff --git a/HEN_HOUSE/spectra/Ir192_bare_1993.spectrum b/HEN_HOUSE/spectra/egsnrc/Ir192_bare_1993.spectrum similarity index 100% rename from HEN_HOUSE/spectra/Ir192_bare_1993.spectrum rename to HEN_HOUSE/spectra/egsnrc/Ir192_bare_1993.spectrum diff --git a/HEN_HOUSE/spectra/Ir192_best_industries.spectrum b/HEN_HOUSE/spectra/egsnrc/Ir192_best_industries.spectrum similarity index 100% rename from HEN_HOUSE/spectra/Ir192_best_industries.spectrum rename to HEN_HOUSE/spectra/egsnrc/Ir192_best_industries.spectrum diff --git a/HEN_HOUSE/spectra/Ir192_beta.spectrum b/HEN_HOUSE/spectra/egsnrc/Ir192_beta.spectrum similarity index 100% rename from HEN_HOUSE/spectra/Ir192_beta.spectrum rename to HEN_HOUSE/spectra/egsnrc/Ir192_beta.spectrum diff --git a/HEN_HOUSE/spectra/Ir192_microSelectron.spectrum b/HEN_HOUSE/spectra/egsnrc/Ir192_microSelectron.spectrum similarity index 100% rename from HEN_HOUSE/spectra/Ir192_microSelectron.spectrum rename to HEN_HOUSE/spectra/egsnrc/Ir192_microSelectron.spectrum diff --git a/HEN_HOUSE/spectra/LICENCE.md b/HEN_HOUSE/spectra/egsnrc/LICENCE.md similarity index 100% rename from HEN_HOUSE/spectra/LICENCE.md rename to HEN_HOUSE/spectra/egsnrc/LICENCE.md diff --git a/HEN_HOUSE/spectra/README.md b/HEN_HOUSE/spectra/egsnrc/README.md similarity index 100% rename from HEN_HOUSE/spectra/README.md rename to HEN_HOUSE/spectra/egsnrc/README.md diff --git a/HEN_HOUSE/spectra/al10mev.spectrum b/HEN_HOUSE/spectra/egsnrc/al10mev.spectrum similarity index 100% rename from HEN_HOUSE/spectra/al10mev.spectrum rename to HEN_HOUSE/spectra/egsnrc/al10mev.spectrum diff --git a/HEN_HOUSE/spectra/al20mev.spectrum b/HEN_HOUSE/spectra/egsnrc/al20mev.spectrum similarity index 100% rename from HEN_HOUSE/spectra/al20mev.spectrum rename to HEN_HOUSE/spectra/egsnrc/al20mev.spectrum diff --git a/HEN_HOUSE/spectra/al30mev.spectrum b/HEN_HOUSE/spectra/egsnrc/al30mev.spectrum similarity index 100% rename from HEN_HOUSE/spectra/al30mev.spectrum rename to HEN_HOUSE/spectra/egsnrc/al30mev.spectrum diff --git a/HEN_HOUSE/spectra/bareco60.spectrum b/HEN_HOUSE/spectra/egsnrc/bareco60.spectrum similarity index 100% rename from HEN_HOUSE/spectra/bareco60.spectrum rename to HEN_HOUSE/spectra/egsnrc/bareco60.spectrum diff --git a/HEN_HOUSE/spectra/co60.spectrum b/HEN_HOUSE/spectra/egsnrc/co60.spectrum similarity index 100% rename from HEN_HOUSE/spectra/co60.spectrum rename to HEN_HOUSE/spectra/egsnrc/co60.spectrum diff --git a/HEN_HOUSE/spectra/cs137.spectrum b/HEN_HOUSE/spectra/egsnrc/cs137.spectrum similarity index 100% rename from HEN_HOUSE/spectra/cs137.spectrum rename to HEN_HOUSE/spectra/egsnrc/cs137.spectrum diff --git a/HEN_HOUSE/spectra/ir192bare.spectrum b/HEN_HOUSE/spectra/egsnrc/ir192bare.spectrum similarity index 100% rename from HEN_HOUSE/spectra/ir192bare.spectrum rename to HEN_HOUSE/spectra/egsnrc/ir192bare.spectrum diff --git a/HEN_HOUSE/spectra/mohan10.spectrum b/HEN_HOUSE/spectra/egsnrc/mohan10.spectrum similarity index 100% rename from HEN_HOUSE/spectra/mohan10.spectrum rename to HEN_HOUSE/spectra/egsnrc/mohan10.spectrum diff --git a/HEN_HOUSE/spectra/mohan15.spectrum b/HEN_HOUSE/spectra/egsnrc/mohan15.spectrum similarity index 100% rename from HEN_HOUSE/spectra/mohan15.spectrum rename to HEN_HOUSE/spectra/egsnrc/mohan15.spectrum diff --git a/HEN_HOUSE/spectra/mohan24.spectrum b/HEN_HOUSE/spectra/egsnrc/mohan24.spectrum similarity index 100% rename from HEN_HOUSE/spectra/mohan24.spectrum rename to HEN_HOUSE/spectra/egsnrc/mohan24.spectrum diff --git a/HEN_HOUSE/spectra/mohan4.spectrum b/HEN_HOUSE/spectra/egsnrc/mohan4.spectrum similarity index 100% rename from HEN_HOUSE/spectra/mohan4.spectrum rename to HEN_HOUSE/spectra/egsnrc/mohan4.spectrum diff --git a/HEN_HOUSE/spectra/mohan6.spectrum b/HEN_HOUSE/spectra/egsnrc/mohan6.spectrum similarity index 100% rename from HEN_HOUSE/spectra/mohan6.spectrum rename to HEN_HOUSE/spectra/egsnrc/mohan6.spectrum diff --git a/HEN_HOUSE/spectra/mora_10x10_60co_ssd80.ensrc b/HEN_HOUSE/spectra/egsnrc/mora_10x10_60co_ssd80.ensrc similarity index 100% rename from HEN_HOUSE/spectra/mora_10x10_60co_ssd80.ensrc rename to HEN_HOUSE/spectra/egsnrc/mora_10x10_60co_ssd80.ensrc diff --git a/HEN_HOUSE/spectra/nrc10mv.spectrum b/HEN_HOUSE/spectra/egsnrc/nrc10mv.spectrum similarity index 100% rename from HEN_HOUSE/spectra/nrc10mv.spectrum rename to HEN_HOUSE/spectra/egsnrc/nrc10mv.spectrum diff --git a/HEN_HOUSE/spectra/nrc20mv.spectrum b/HEN_HOUSE/spectra/egsnrc/nrc20mv.spectrum similarity index 100% rename from HEN_HOUSE/spectra/nrc20mv.spectrum rename to HEN_HOUSE/spectra/egsnrc/nrc20mv.spectrum diff --git a/HEN_HOUSE/spectra/rt30.spectrum b/HEN_HOUSE/spectra/egsnrc/rt30.spectrum similarity index 100% rename from HEN_HOUSE/spectra/rt30.spectrum rename to HEN_HOUSE/spectra/egsnrc/rt30.spectrum diff --git a/HEN_HOUSE/spectra/rt50.spectrum b/HEN_HOUSE/spectra/egsnrc/rt50.spectrum similarity index 100% rename from HEN_HOUSE/spectra/rt50.spectrum rename to HEN_HOUSE/spectra/egsnrc/rt50.spectrum diff --git a/HEN_HOUSE/spectra/sr90y90.spectrum b/HEN_HOUSE/spectra/egsnrc/sr90y90.spectrum similarity index 100% rename from HEN_HOUSE/spectra/sr90y90.spectrum rename to HEN_HOUSE/spectra/egsnrc/sr90y90.spectrum diff --git a/HEN_HOUSE/spectra/tritium.spectrum b/HEN_HOUSE/spectra/egsnrc/tritium.spectrum similarity index 100% rename from HEN_HOUSE/spectra/tritium.spectrum rename to HEN_HOUSE/spectra/egsnrc/tritium.spectrum diff --git a/HEN_HOUSE/spectra/lnhb/Ac-225.txt b/HEN_HOUSE/spectra/lnhb/Ac-225.txt new file mode 100644 index 000000000..c440e68f3 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Ac-225.txt @@ -0,0 +1,358 @@ +221FR 225AC A DECAY (10.0 D) +221FR H TYP=Full$AUT=Huang Xiaolong$CUT=31-DEC-2008$ +221FR C Evaluation history: Type=Full;Author=Huang Xiaolong;Cutoff date=31-DEC-2008 +221FR T Auger electrons and ^X ray energies and emission intensities: +221FR T {U Energy (keV)} {U Intensity } {U Line } +221FR T +221FR T 83.23 1.00 8 XKA2 +221FR T 86.1 1.64 12 XKA1 +221FR T +221FR T 96.815 |] XKB3 +221FR T 97.474 |] 0.57 5 XKB1 +221FR T 98.069 |] XKB5II +221FR T +221FR T 100.16 |] XKB2 +221FR T 100.548 |] 0.19 2 XKB4 +221FR T 100.972 |] XKO23 +221FR T +221FR T 10.38-17.799 18.7 9 XL (total) +221FR T 10.38 XLL +221FR T 11.89-12.03 XLA +221FR T 13.254 XLC +221FR T 13.877-15.639 XLB +221FR T 16.752-17.799 XLG +221FR T +221FR T 63.576-70.787 |] KLL AUGER +221FR T 77.72-86.101 |] 0.115 9 ^KLX AUGER +221FR T 91.84-101.12 |] KXY AUGER +221FR T 5.73-18.52 23.8 12 L AUGER +225AC P 0.0 (3/2)- 10.0 D 1 5935.1 14 +221FR N 1.0 1.0 1 1.0 +221FR L 0 5/2- 4.79 M 2 +221FR A 5829.6 1452.4 248.7 +221FR L 25.856 17(1/2,3/2)- +221FR A 5804.2 140.3 1135 +221FR G 26.0 1 0.00159 21E2 5.94E3 15 +221FR2 G KC=$LC=4.39E3 11$MC=1180 30 +221FR L 36.646 11(3/2)- 1.5 NS 2 +221FR A 5793.1 2118.9 2016 +221FR G 10.6 0.015 2 M1 510 7 +221FR2 G KC=$LC=$MC=383 5 +221FR G 36.69 3 0.0181 15E2 1092 16 +221FR2 G KC=$LC=806 12$MC=217 4 +221FR L 38.546 12(9/2)- +221FR A 5791.7 146.2 9 48 +221FR G 38.58 4 0.0107 10E2 854 13 +221FR2 G KC=$LC=630 10$MC=169 3 +221FR L 99.596 13(3/2)- 80 PS 30 +221FR A 5731.9 179.0 5 16.4 +221FR G 62.94 3 0.49 3 M1 10.85 15 +221FR2 G KC=$LC=8.24 12$MC=1.964 28 +221FR G 73.55 9 0.019 5 E2 37.5 6 +221FR2 G KC=$LC=27.6 4$MC=7.48 11 +221FR G 99.67 5 0.76 5 M1+E2 0.19 4 3.06 11 +221FR2 G KC=$LC=2.32 8$MC=0.56 2 +221FR L 99.752 16(3/2)+ 160 PS 30 +221FR A 5731.6 141.24 10119 +221FR G 63.5 3 0.021 3 [E1] 0.360 7 +221FR2 G KC=$LC=0.273 5$MC=0.0660 12 +221FR G 73.85 3 0.309 23E1 0.240 3 +221FR2 G KC=$LC=0.182 3$MC=0.0440 6 +221FR G 99.89 6 1.08 8 E1 0.1073 15 +221FR2 G KC=$LC=0.0814 11$MC=0.0196 3 +221FR L 100.897 11(5/2)- +221FR A 5730.5 141.6 3 91 +221FR G 62.6 3 0.0053 12[E2] 81.2 23 +221FR2 G KC=$LC=59.8 16$MC=16.2 5 +221FR G 64.27 3 0.047 4 M1+E2 0.51 10 23 4 +221FR2 G KC=$LC=17 3$MC=4.4 8 +221FR G 74.82 5 0.015 3 (M1+E2) 0.5 12.15 18 +221FR2 G KC=$LC=9.06 13$MC=2.32 4 +221FR G 100.86 4 0.096 8 M1+E2 0.7 7 4.6 19 +221FR2 G KC=$LC=3.4 14$MC=0.9 4 +221FR L 108.404 11(7/2)- 280 PS +221FR A 5723.1 142.03 2366 +221FR G 69.86 5 0.0047 12E2 47.9 7 +221FR2 G KC=$LC=35.3 5$MC=9.55 14 +221FR G 71.71 4 0.0132 13E2 42.3 6 +221FR2 G KC=$LC=31.1 5$MC=8.43 12 +221FR G 108.38 3 0.255 16M1+E2 0.53 6 10.27 25 +221FR2 G KC=7.2 4$LC=2.30 12$MC=0.58 4 +221FR L 145.755 20(1/2)+ +221FR A 5686.4 140.021 144100 +221FR G 46.24 5 0.0049 7 [E1] 0.841 12 +221FR2 G KC=$LC=0.636 9$MC=0.155 2 +221FR G 119.85 3 0.080 5 [E1] 0.305 4 +221FR2 G KC=0.239 4$LC=0.0503 7$MC=0.01207 17 +221FR L 150.063 13(7/2)+ 80 PS 20 +221FR A 5682.2 141.31 4 62.9 +221FR G 49.12 4 0.0080 8 [E1] 0.715 11 +221FR2 G KC=$LC=0.541 8$MC=0.1320 19 +221FR G 50.2 6200E-7 0 [E2] 236.0 34 +221FR2 G KC=$LC=174.2 25$MC=47.0 7 +221FR G 111.52 3 0.313 21(E1) 0.363 5 +221FR2 G KC=0.282 4$LC=0.0609 9$MC=0.01461 21 +221FR G 150.05 3 0.693 12E1 0.1766 25 +221FR2 G KC=0.1397 20$LC=0.0280 4$MC=0.0067 1 +221FR L 195.789 11(5/2,7/2)- 20 PS 5 +221FR A 5637.3 144.16 2311.6 +221FR G 87.41 3 0.271 19M1 4.16 6 +221FR2 G KC=$LC=3.16 5$MC=0.754 10 +221FR G 94.90 2 0.105 10M1 3.28 5 +221FR2 G KC=$LC=2.49 3$MC=0.594 8 +221FR G 96.16 5 0.033 7 M1+E2 0.8 3 6.0 14 +221FR2 G KC=$LC=4.5 10$MC=1.2 3 +221FR G 157.25 3 0.36 3 M1+E2 0.21 21 3.8 3 +221FR2 G KC=3.1 4$LC=0.59 3$MC=0.143 9 +221FR G 169.9 0.0139 14 +221FR G 195.74 3 0.148 9 M1+E2 0.8 8 1.5 6 +221FR2 G KC=1.1 6$LC=0.314 5$MC=0.079 4 +221FR L 224.567 13(3/2,5/2)+ 35 PS 10 +221FR A 5609.0 141.09 5 31.5 +221FR G 78.8 0.0123 19M1 5.63 8 +221FR2 G KC=$LC=4.27 6$MC=1.019 14 +221FR G 123.75 4 0.087 6 [E1] 0.282 4 +221FR2 G KC=0.221 4$LC=0.0463 7$MC=0.0111 2 +221FR G 124.81 3 0.0292 18M1+E2 0.8 6.010000 +221FR2 G KC=3.87000 0$LC=1.59300 0$MC=0.40900 0 +221FR G 186.1 0.0127 14 +221FR G 187.96 3 0.53 3 E1 0.1023 14 +221FR2 G KC=0.0816 12$LC=0.01571 22$MC=0.00375 6 +221FR G 198.47 230.0188 13[E1] 0.0898 13 +221FR2 G KC=0.0718 11$LC=0.01369 20$MC=0.00327 5 +221FR G 224.59 3 0.112 8 [E1] 0.0669 9 +221FR2 G KC=0.0537 8$LC=0.01005 14$MC=0.00239 4 +221FR L 234.470 18(5/2)+ +221FR A 5599.3 140.114 7 268 +221FR G 126.10 5 0.0079 7 (E1) 0.270 4 +221FR2 G KC=0.212 3$LC=0.0440 7$MC=0.0106 2 +221FR G 133.60 3 0.0196 16(E1) 0.234 3 +221FR2 G KC=0.184 3$LC=0.0379 6$MC=0.00907 13 +221FR G 134.85 3 0.032 3 (E1) 0.229 3 +221FR2 G KC=0.180 3$LC=0.0370 6$MC=0.00885 13 +221FR G 197.7 1 0.038 5 [E1] 0.0906 13 +221FR2 G KC=0.0724 11$LC=0.01382 20$MC=0.00330 5 +221FR L 253.551 12(5/2)+ 35 PS 15 +221FR A 5580.5 140.95 4 25.6 +221FR G 57.71 4 0.0051 8 (E1) 0.465 7 +221FR2 G KC=$LC=0.352 5$MC=0.0854 12 +221FR G 103.48 100.0030 7 [M1E2] 10 3 +221FR2 G KC=5 2$LC=3.7 18$MC=1.0 5 +221FR G 145.15 3 0.146 9 (E1) 0.191 3 +221FR2 G KC=0.1513 22$LC=0.0305 5$MC=0.00730 11 +221FR G 152.64 3 0.0197 13[E1] 0.1694 24 +221FR2 G KC=0.1341 19$LC=0.0268 4$MC=0.00640 9 +221FR G 153.92 3 0.205 13E1 0.1660 23 +221FR2 G KC=0.1315 19$LC=0.0262 4$MC=0.00627 9 +221FR G 216.89 3 0.32 2 (E1) 0.0726 10 +221FR2 G KC=0.0582 9$LC=0.01096 16$MC=0.00261 4 +221FR G 228.2 4 0.0046 12 +221FR G 253.46 3 0.132 8 [E1] 0.0504 7 +221FR2 G KC=0.0405 6$LC=0.00747 11$MC=1776E-6 25 +221FR L 271.14 7 (5/2,7/2,9/2)- +221FR A 5563.3 140.017 7 1160 +221FR G 121.06 7 0.017 5 (E1) 0.298 4 +221FR2 G KC=0.233 4$LC=0.0490 7$MC=0.01176 17 +221FR G 236.0 6 0.0017 3 +221FR L 279.209 17(7/2)+ +221FR A 5555.3 140.084 10213 +221FR G 129.22 7 0.0027 5 [M1E2] 5 2 +221FR2 G KC=3 3$LC=1.5 5$MC=0.39 15 +221FR G 170.77 5 0.013 7 (E1) 0.1290 18 +221FR2 G KC=0.1026 15$LC=0.0201 3$MC=0.00479 7 +221FR G 178.29 3 0.0161 12E1 0.1162 16 +221FR2 G KC=0.0925 13$LC=0.0180 3$MC=0.00429 6 +221FR G 240.68 3 0.0117 10[E1] 0.0568 8 +221FR2 G KC=0.0457 7$LC=0.00847 12$MC=0.00202 3 +221FR G 279.18 3 0.0305 22E1 0.0403 6 +221FR2 G KC=0.0325 5$LC=0.00591 9$MC=1405E-6 20 +221FR L 288.16 3 (9/2)- +221FR A 5546.5 140.055 12292 +221FR G 179.78 4 0.0108 8 (M1E2) 1.8 10 +221FR2 G KC=1.2 10$LC=0.43 3$MC=0.109 14 +221FR G 187.2 0.0103 7 +221FR G 249.60 3 0.0135 10(E2) 0.258 4 +221FR2 G KC=0.1033 15$LC=0.1145 16$MC=0.0305 5 +221FR L 294.69 4 (9/2)+ +221FR A 5540.1 140.0072 8 2060 +221FR G 144.7 2 0.00046 12(M1+E2) 0.8 3.790000 +221FR2 G KC=2.57000 0$LC=0.91400 0$MC=0.23200 0 +221FR G 186.29 3 0.0042 5 E1 0.1045 15 +221FR2 G KC=0.0834 12$LC=0.01607 23$MC=0.00383 6 +221FR G 256.0 2 0.00037 7 [E1] 0.0492 7 +221FR2 G KC=0.0396 6$LC=0.00729 11$MC=1733E-6 25 +221FR L 311.41 8 (5/2,7/2,9/2)+ +221FR A 5523.7 140.013 6 930 +221FR G 161.35 7 0.0036 9 [M1E2] 2.5 13 +221FR2 G KC=1.6 14$LC=0.64 10$MC=0.16 4 +221FR L 320.03 8 (1/2,3/2,5/2)+ +221FR A 5515.2 140.0052 192100 +221FR G 220.43 8 0.0060 18 +221FR L 338.24 8 (1/2,3/2,5/2)- +221FR A 5497.4 140.0022 7 4000 +221FR G 238.64 8 0.0010 3 (M1) 1.225 17 +221FR2 G KC=0.988 14$LC=0.180 3$MC=0.0428 6 +221FR L 348.35 4 (3/2,5/2,7/2)+ +221FR A 5487.4 140.0020 3 3860 +221FR G 348.33 5 0.0030 3 +221FR L 367.74 12 + +221FR A 5468.4 140.00052 1811700 +221FR G 367.74 120.00052 18 +221FR L 393.300 18(5/2,7/2,9/2)+ +221FR A 5443.3 140.098 1945 +221FR G 114 0.00087 13M1 9.86 14 +221FR2 G KC=7.93 12$LC=1.466 21$MC=0.350 5 +221FR G 139.6 0.00139 21M1+E2 3.9 17 +221FR2 G KC=2.4 21$LC=1.1 3$MC=0.29 9 +221FR G 169.18 4 0.012 5 [M1E2] 2.1 11 +221FR2 G KC=1.4 12$LC=0.53 6$MC=0.136 24 +221FR G 197.50 3 0.026 3 E1 0.0908 13 +221FR2 G KC=0.0726 11$LC=0.01386 20$MC=0.00331 5 +221FR G 243.12 5 0.0031 4 [M1] 1.163 16 +221FR2 G KC=0.938 14$LC=0.1707 24$MC=0.0407 6 +221FR G 284.75 3 0.0074 6 [E1] 0.0385 5 +221FR2 G KC=0.0311 5$LC=0.00564 8$MC=1340E-6 19 +221FR G 354.56 6 0.0020 7 [E1] 0.0236 3 +221FR2 G KC=0.0191 3$LC=0.00338 5$MC=8.00E-4 12 +221FR L 400.94 4 (11/2)+ +221FR A 5435.8 140.0083 6 485 +221FR G 112.80 2 0.0021 3 [E1] 0.353 5 +221FR2 G KC=0.275 4$LC=0.0591 9$MC=0.01417 21 +221FR G 362.38 3 0.0054 5 (E1) 0.0225 3 +221FR2 G KC=0.0182 3$LC=0.00321 6$MC=7610E-7 11 +221FR L 406.73 6 (3/2,5/2,7/2)- +221FR A 5430.1 140.0028 8 1340 +221FR G 298.33 5 0.0020 3 (M1E2) 0.4 3 +221FR2 G KC=0.30 24$LC=0.077 20$MC=0.019 4 +221FR L 408.54 13 + +221FR A 5428.3 140.0023 3 1590 +221FR G 137.4 1 0.0023 3 +221FR L 422.65 4 (3/2,5/2,7/2)+ +221FR A 5414.5 140.0030 4 1020 +221FR G 321.77 4 0.0033 4 [E1] 0.0292 4 +221FR2 G KC=0.0237 4$LC=0.00423 6$MC=1003E-6 14 +221FR L 446.31 10(3/2,5/2,7/2)+ +221FR A 5391.2 140.0006 4 3800 +221FR G 446.31 100.0006 4 +221FR L 458.74 6 (3/2,5/2,7/2)+ +221FR A 5379.0 140.0020 5 980 +221FR G 205.07 110.0015 5 +221FR G 458.79 8 0.00053 13 +221FR L 481.98 10 + +221FR A 5356.2 1497000E-92 14960 +221FR G 443.43 101000E-7 0 +221FR L 496.50 7 (5/2,7/2)+ +221FR A 5341.9 140.0027 8 450 +221FR G 388.07 7 0.00125 21 +221FR G 496.9 3 0.0015 7 +221FR L 517.634 25(5/2)+ +221FR A 5321.2 140.007 7 130 +221FR G 321.77 4 +221FR G 417.90 2 0.0056 5 +221FR G 480.85 110.0340 22 +221FR G 491.45 100.00035 14 +221FR G 517.51 3 0.0159 10 +221FR L 551.812 17(3/2,5/2)- +221FR A 5287.6 140.214 102.76 +221FR G 298.33 5 +221FR G 317.23 18 E1 0.0302 4 +221FR2 G KC=0.0244 4$LC=0.00437 7$MC=1037E-6 15 +221FR G 356.6 0.00026 11 +221FR G 405.95 3 0.0078 5 [E1] 0.0175925 +221FR2 G KC=0.01432 20$LC=0.00249 4$MC=5.89E-4 9 +221FR G 443.43 100.0014 5 [E2] 0.0494 7 +221FR2 G KC=0.0310 5$LC=0.0137 2$MC=0.00353 5 +221FR G 451.04 5 0.0030 5 [M1] 0.215 3 +221FR2 G KC=0.1739 25$LC=0.0312 5$MC=0.00742 11 +221FR G 452.23 3 0.107 8 [M1] 0.213 3 +221FR2 G KC=0.1727 25$LC=0.0310 5$MC=0.00737 11 +221FR G 512.5 7 0.00055 21 +221FR G 515.13 3 0.0214 13[M1] 0.1506 21 +221FR2 G KC=0.1219 17$LC=0.0218 3$MC=0.00518 8 +221FR G 525.94 170.0353 22[M1] 0.1425 20 +221FR2 G KC=0.1154 17$LC=0.0206 3$MC=0.00490 7 +221FR G 551.79 3 0.0052 14[M1] 0.1254 17 +221FR2 G KC=0.1016 15$LC=0.0181 3$MC=0.00431 6 +221FR L 570.67 3 (5/2,7/2)+ +221FR A 5269.1 140.048 1910 +221FR G 53.4 4 4000E-6 0 [M1] 17.6 5 +221FR2 G KC=$LC=13.3 4$MC=3.18 8 +221FR G 317.23 180.00042 21M1 0.558 8 +221FR2 G KC=0.451 7$LC=0.0816 12$MC=0.0194 3 +221FR G 374.98 5 0.0019 5 [E1] 0.0209 3 +221FR2 G KC=0.01694 24$LC=0.00297 5$MC=7.04E-4 10 +221FR G 462.43 130.00044 11[E1] 0.0133819 +221FR2 G KC=0.01092 16$LC=0.00187 3$MC=4.42E-4 7 +221FR G 469.48 5 0.0028 4 +221FR G 532.11 9 0.00076 21[E1] 0.0100514 +221FR2 G KC=0.00823 12$LC=1389E-6 20$MC=3.27E-4 5 +221FR G 570.69 3 0.0040 5 [E1] 0.0087412 +221FR2 G KC=0.00716 10$LC=1201E-6 17$MC=2.83E-4 4 +221FR L 600.94 3 (5/2)- +221FR A 5239.3 140.0026 5 119 +221FR G 564.34 110.00022 9 +221FR G 600.92 3 0.0024 5 +221FR L 630.551 23(5/2)- +221FR A 5210.2 140.022 1 9.5 +221FR G 282.1 2 0.00055 5 [M1] 0.771 11 +221FR2 G KC=0.622 9$LC=0.1129 16$MC=0.0269 4 +221FR G 434.82 5 0.0029 3 +221FR G 522.14 4 0.00208 15 +221FR G 529.59 3 0.0076 7 +221FR G 530.87 4 0.0047 5 +221FR G 590.42 5 0.00083 14 +221FR G 593.87 4 0.0029 3 +221FR L 637.60 3 + +221FR A 5203.3 140.0101 1018.9 +221FR G 403.13 100.00019 16 +221FR G 538.1 1 0.0038 10 +221FR G 600.92 3 6000E-6 0 +221FR G 637.1 7 1200E-7 0 +221FR L 645.94 12 + +221FR A 5195.1 140.00015 5 1140 +221FR G 645.94 120.00015 5 +221FR L 679.53 7 (7/2)- +221FR A 5162.1 140.00066 12165 +221FR G 679.36 6 0.00066 12 +221FR L 713.24 6 (1/2,3/2)+ +221FR A 5129.0 140.0058 8 11.9 +221FR G 442.16 8 0.0045 7 +221FR G 567.48 5 0.0012 4 +221FR L 748.83 3 (3/2)+ +221FR A 5094.1 140.015 7 2.8 +221FR G 231.16 7 0.005 3 (M1) 1.338 19 +221FR2 G KC=1.079 16$LC=0.197 3$MC=0.0468 7 +221FR G 603.09 4 0.00173 21 +221FR G 649.03 4 0.0017 5 +221FR L 766.44 5 + +221FR A 5076.8 140.0038 199 +221FR G 657.88 5 0.0014 3 +221FR G 667.14 8 0.0021 18 +221FR G 767.9 3 0.00030 6 +221FR L 779.32 6 + +221FR A 5064.1 140.00114 1824 +221FR G 545.8 6 0.00053 14 +221FR G 628.95 100.00032 7 +221FR G 679.36 6 +221FR G 754.04 130.00023 7 +221FR G 780.6 6 5.5E-5 14 +221FR L 808.48 10 + +221FR A 5035.5 140.0021 3 8.8 +221FR G 808.48 100.0021 3 +221FR L 818.6 6 + +221FR A 5025.5 140.00083 2119 +221FR G 498.6 6 0.00083 21 +221FR L 825.0 3 + +221FR A 5019.3 140.00015 5 98 +221FR G 674.9 3 0.00010 5 +221FR G 824.2 7 4900E-8 0 +221FR L 852.08 7 + +221FR A 4992.7 140.0013 3 7.7 +221FR G 429.80 180.00038 19 +221FR G 656.18 110.00049 21 +221FR G 702.00 140.00016 7 +221FR G 752.46 120.00026 7 +221FR L 942.79 10(3/2)- +221FR A 4903.6 140.0011 4 2.5 +221FR G 747.0 1 0.0011 4 + diff --git a/HEN_HOUSE/spectra/lnhb/Ac-227.txt b/HEN_HOUSE/spectra/lnhb/Ac-227.txt new file mode 100644 index 000000000..cd839a519 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Ac-227.txt @@ -0,0 +1,259 @@ +223FR 227AC A DECAY (21.772 Y) +223FR H TYP=Full$AUT=Chechev. Kuzmenkho$CUT=30-JUN-2008$ +223FR C Evaluation history: Type=Full;Author=Chechev. Kuzmenkho;Cutoff date=30-JUN-2008 +223FR C References: 1950Ho79, 1955To07, 1956Sh43, 1959No41, 1959Ro51, 1963Ei10, +223FR2C 1966Ba19, 1967JoZX, 1970Ki12, 1974Mo05, 1986Ry04, 1991Ry01, 1995Sh03, +223FR3C 1995Li04, 1997Mu08, 2001Br31, 2002Ba85, 2003Au03 +223FR T Auger electrons and ^X ray energies and emission intensities: +223FR T {U Energy (keV)} {U Intensity } {U Line } +223FR T +223FR T 83.23 0.0043 12 XKA2 +223FR T 86.1 0.0070 19 XKA1 +223FR T +223FR T 96.815 |] XKB3 +223FR T 97.474 |] 0.0024 7 XKB1 +223FR T 98.069 |] XKB5II +223FR T +223FR T 100.16 |] XKB2 +223FR T 100.548 |] 0.00079 22 XKB4 +223FR T 100.972 |] XKO23 +223FR T +223FR T 10.381-17.839 0.074 8 XL (total) +223FR T 10.381 0.00097 18 XLL +223FR T 11.896-12.032 0.017 3 XLA +223FR T 13.255 0.0006 1 XLC +223FR T 13.877-14.978 0.044 5 XLB +223FR T 17.302-17.839 0.012 1 XLG +223FR T +223FR T 63.576-70.787 |] KLL AUGER +223FR T 77.72-86.101 |] 0.00050 15 ^KLX AUGER +223FR T 91.84-101.12 |] KXY AUGER +223FR T 5.73-18.52 0.097 10 L AUGER +227AC P 0.0 3/2- 21.772 Y 3 5042.19 14 +223FR N 7.246E1 7.246E1 0.01380 4 7.246E1 +223FR G 219.2 4 1.40E-5 4 +223FR L 0 3/2- 22.00 M 7 +223FR A 4953.23 1447.7 107 +223FR L 12.89 5 (5/2)- +223FR A 4940.57 1539.6 127 +223FR G 12.9 1 1400E-8 0 (E2) 4.99E4 10 +223FR2 G KC=$LC=$MC=3.77E4 8 +223FR L 54.97 7 1/2- +223FR A 4899.23 1510870E-5 1360 +223FR G 55.0 1 0.00044 8 M1+E2 0.05 4 16.4 8 +223FR2 G KC=$LC=12.5 6$MC=2.98 16 +223FR L 82.13 6 (7/2)- +223FR A 4872.55 156.3 5 16 +223FR G 69.28 8 0.0039 6 M1+E2 0.57 18.4 19 +223FR2 G KC=$LC=13.7 14$MC=3.6 4 +223FR G 82.2 1 0.00083 10E2 22.1 5 +223FR2 G KC=$LC=16.25 30$MC=4.40 9 +223FR L 99.63 6 (3/2)- +223FR A 4855.36 155.8 7 13 +223FR G 44.7 1 0.00011 3 [M1+E2] 1 2.2E2 20 +223FR2 G KC=$LC=1.6E2 15$MC=44 40 +223FR G 86.7 2 0.0028 4 [M1+E2] 1 11 7 +223FR2 G KC=$LC=8 5$MC=2.1 14 +223FR G 99.6 1 0.0051 7 M1+E2 1 6 3 +223FR2 G KC=$LC=4.4 22$MC=1.2 7 +223FR L 101.00 6 (5/2)- +223FR A 4854.01 150 +223FR G 88.1 1 0.00069 10[M1+E2] 1 10 6 +223FR2 G KC=$LC=8 5$MC=2.0 13 +223FR G 101.0 1 0.00069 30[M1+E2] 1 6 3 +223FR2 G KC=$LC=4.1 21$MC=1.1 6 +223FR L 134.51 6 (3/2)+ +223FR A 4821.09 1572464E-6 663 +223FR G 33.5 1 0.00011 3 [E1] 1.99 4 +223FR2 G KC=$LC=1.50 3$MC=0.371 8 +223FR G 35.0 2 2.8E-5 10[E1] 1.77 4 +223FR2 G KC=$LC=1.34 3$MC=0.330 7 +223FR G 79.54 8 0.0011 1 E1 0.197 4 +223FR2 G KC=$LC=0.149 3$MC=0.0360 7 +223FR G 121.6 1 0.0012 3 [E1] 0.295 6 +223FR2 G KC=0.231 5$LC=0.0485 10$MC=0.0116 3 +223FR G 134.5 1 0.00055 10E1 0.230 5 +223FR2 G KC=0.182 4$LC=0.0372 8$MC=0.00891 18 +223FR L 149.3 3 (1/2)+ +223FR G 149.3 3 1400E-8 0 +223FR L 160.48 7 (3/2)+ +223FR A 4795.58 151.0 5 31 +223FR G 25.95 550E-9 0 +223FR G 59.4 2 4.1E-5 10[E1] 0.430 9 +223FR2 G KC=$LC=0.326 7$MC=0.0790 16 +223FR G 60.6 3 4.1E-5 10[E1] 0.408 9 +223FR2 G KC=$LC=0.309 6$MC=0.0749 15 +223FR G 147.61 8 0.0025 3 E1 0.184 4 +223FR2 G KC=0.145 3$LC=0.0292 6$MC=0.00699 14 +223FR G 160.49 100.0044 4 E1 0.150 3 +223FR2 G KC=0.119 3$LC=0.0235 5$MC=0.00562 11 +223FR L 172.08 6 (5/2)+ +223FR A 4784.19 1579710E-6 329 +223FR G 72.5 2 6.9E-5 30[E1] 0.252 5 +223FR2 G KC=$LC=0.191 4$MC=0.0462 10 +223FR G 90.0 1 0.00018 7 [E1] 0.142 3 +223FR2 G KC=$LC=0.107 2$MC=0.0259 5 +223FR G 159.2 1 0.00055 10[E1] 0.153 3 +223FR2 G KC=0.121 3$LC=0.0240 5$MC=0.00574 11 +223FR G 172.0 1 0.00097 10E1 0.127 3 +223FR2 G KC=0.101 2$LC=0.0197 4$MC=0.0047 1 +223FR L 187.18 10(5/2)- +223FR A 4769.35 171.8 5 11 +223FR G 52.32 1400E-9 0 +223FR G 86.1 1 4700E-7 0 +223FR G 105.0 2 0.00034 10M1 12.4 25 +223FR2 G KC=9.96 20$LC=1.86 4$MC=0.443 9 +223FR G 174.3 1 0.00028 6 [M1+E2] 1 1.9 11 +223FR2 G KC=1.3 11$LC=0.48 4$MC=0.122 17 +223FR L 189.10 7 (7/2)- +223FR A 4767.47 150 +223FR G 88.1 1 0.00069 10[M1+E2] 1 10 6 +223FR2 G KC=$LC=8 5$MC=2.0 13 +223FR G 106.85 100.0011 1 (+E2) 1 9 3 +223FR2 G KC=5 2$LC=3.2 15$MC=0.8 4 +223FR G 176.1 1 0.00033 6 M1E2 1 1.9 11 +223FR2 G KC=1.3 11$LC=0.46 4$MC=0.117 17 +223FR L 219.61 9 (7/2)+ +223FR A 4737.50 1686957E-6 142 +223FR G 85.0 5 1100E-8 0 +223FR G 118.7 4 4.1E-5 10[E1] 0.312 6 +223FR2 G KC=0.244 5$LC=0.0516 11$MC=0.0124 3 +223FR G 137.4 1 0.00041 10[E1] 0.220 5 +223FR2 G KC=0.172 4$LC=0.0352 7$MC=0.00843 17 +223FR G 206.8 1 0.00097 10E1 0.0814 17 +223FR2 G KC=0.0651 13$LC=0.0124 3$MC=0.00294 6 +223FR L 222.75 10(7/2)+ +223FR A 4734.41 170 +223FR G 51.06 280E-9 0 +223FR G 88.5 6 970E-9 0 +223FR G 140.9 1 0.00021 6 [E1] 0.206 4 +223FR2 G KC=0.162 4$LC=0.0330 7$MC=0.00789 16 +223FR L 242.63 7 (5/2)+ +223FR A 4714.88 150.43 2223 +223FR G 53.7 2 4.1E-5 10[E1] 0.563 11 +223FR2 G KC=$LC=0.427 9$MC=0.104 2 +223FR G 70.6 2 8.3E-5 30[M1+E2] 1 27 19 +223FR2 G KC=$LC=20 14$MC=5 4 +223FR G 108.0 3 4.1E-5 10[M1+E2] 1 9 3 +223FR2 G KC=5 2$LC=3.1 15$MC=0.8 4 +223FR G 143.0 1 0.00028 6 [E1] 0.198 4 +223FR2 G KC=0.157 3$LC=0.0317 7$MC=0.00759 15 +223FR G 229.7 1 0.00041 7 [E1] 0.0634 13 +223FR2 G KC=0.0509 11$LC=0.00951 19$MC=0.00226 5 +223FR G 242.6 2 0.00028 7 [E1] 0.0558 12 +223FR2 G KC=0.0448 9$LC=0.00831 17$MC=0.00198 4 +223FR L 243.85 13(5/2)+ +223FR A 4713.68 190 +223FR G 83.0 1 1400E-9 0 +223FR G 161.4 4 0.00014 4 [M1+E2] 1 2.5 13 +223FR2 G KC=1.6 15$LC=0.64 9$MC=0.16 4 +223FR G 230.9 5 1400E-8 0 [M1+E2] 1 0.8 5 +223FR2 G KC=0.6 5$LC=0.177 24$MC=0.045 4 +223FR G 243.9 4 2.80E-5 8 [E2] 0.279 6 +223FR2 G KC=0.108 2$LC=0.126 3$MC=0.0335 7 +223FR L 244.66 15(7/2)- +223FR A 4712.89 200 +223FR G 55.80 5 3900E-9 0 +223FR G 57.56 5 3200E-9 0 +223FR G 72.5 2 6.9E-5 30[E1] 0.252 5 +223FR2 G KC=$LC=0.191 4$MC=0.0462 10 +223FR G 143.65 5 2600E-8 0 M1 5.11 11 +223FR2 G KC=4.12 8$LC=0.755 15$MC=0.180 4 +223FR G 162.6 2 5.5E-5 30M1E2 1 2.4 13 +223FR2 G KC=1.6 15$LC=0.62 9$MC=0.16 4 +223FR G 231.79 5 7200E-9 0 +223FR L 298.7 3 (9/2)- +223FR G 216.6 3 5.5E-5 30[M1+E2] 1 1.0 7 +223FR2 G KC=0.7 6$LC=0.221 20$MC=0.0556 18 +223FR L 365.47 10 + +223FR A 4594.21 1721739E-6 65 +223FR G 121.6 1 0.0012 3 [E1] 0.295 6 +223FR2 G KC=0.231 5$LC=0.0485 10$MC=0.0116 3 +223FR G 143.0 1 0.00028 6 [M1+E2] 1 3.6 18 +223FR2 G KC=2.2 11$LC=1.0 5$MC=0.26 13 +223FR G 146.0 2 8800E-9 0 +223FR G 176.1 1 0.00033 4 [E1] 0.120 3 +223FR2 G KC=0.095 2$LC=0.0185 4$MC=0.00443 9 +223FR G 283.4 3 5.5E-5 30[E1] 0.0389 8 +223FR2 G KC=0.0314 7$LC=0.00570 12$MC=0.00136 3 +223FR L 379 7 + +223FR A 4581 7 28986E-7 340 +223FR L 449 5 + +223FR A 4512 5 28986E-7 108 +223FR L 503 7 + +223FR A 4459 7 50725E-7 26 +223FR L 515.20 223/2- +223FR A 4447.12 2650725E-6 2.1 +223FR G 415.6 3 0.00021 6 1 0.16 11 +223FR2 G KC=0.13 10$LC=0.028 12$MC=0.007 3 +223FR G 460.2 3 0.00021 6 M1+E2 1 0.12 9 +223FR2 G KC=0.10 8$LC=0.021 10$MC=0.0051 22 +223FR L 540.74 25(5/2)+ +223FR A 4422.03 2857971E-7 12 +223FR G 351.7 3 5.5E-5 30[E1] 0.0240 5 +223FR2 G KC=0.0195 4$LC=0.00344 7$MC=8.15E-4 17 +223FR G 439.60 5 3.4E-5 1 +223FR G 441.0 4 5.5E-5 30[E1] 0.0148 3 +223FR2 G KC=0.0120 3$LC=0.00207 4$MC=0.00049 1 +223FR G 527.6 1 2900E-8 0 +223FR G 540.40 5 7000E-8 0 +223FR L 601 7 (5/2)- +223FR A 4362.83 1528986E-7 8 + +227TH 227AC B- DECAY (21.772 Y) +227TH H TYP=Full$AUT=Chechev. Kuzmenkho$CUT=30-JUN-2008$ +227TH C Evaluation history: Type=Full;Author=Chechev. Kuzmenkho;Cutoff date=30-JUN-2008 +227TH C References: 1950Ho79, 1955To07, 1956Sh43, 1959No41, 1959Ro51, 1963Ei10, +227TH2C 1966Ba19, 1967JoZX, 1970Ki12, 1974Mo05, 1986Ry04, 1991Ry01, 1995Sh03, +227TH3C 1995Li04, 1997Mu08, 2001Br31, 2002Ba85, 2003Au03 +227TH T Auger electrons and ^X ray energies and emission intensities: +227TH T {U Energy (keV)} {U Intensity } {U Line } +227TH T +227TH T 89.954 XKA2 +227TH T 93.351 XKA1 +227TH T +227TH T 104.819 |] XKB3 +227TH T 105.604 |] XKB1 +227TH T 106.239 |] XKB5II +227TH T +227TH T 108.509 |] XKB2 +227TH T 108.955 |] XKB4 +227TH T 109.442 |] XKO23 +227TH T +227TH T 11.118-19.599 2.64 XL (total) +227TH T 11.118 0.044 XLL +227TH T 12.809-12.968 0.147 XLA +227TH T 14.511 0.027 XLC +227TH T 14.97-16.426 1.9 XLB +227TH T 18.98-19.599 0.52 XLG +227TH T +227TH T 68.406-76.745 |] KLL AUGER +227TH T 83.857-93.345 |] ^KLX AUGER +227TH T 99.29-109.64 |] KXY AUGER +227TH T 5.8-20.3 3.9 L AUGER +227AC P 0.0 3/2- 21.772 Y 3 44.8 8 +227TH N 1.014E0 1.014E0 0.98620 4 1.014E0 +227TH G 219.2 4 1.40E-5 4 +227TH L 0 1/2+ 18.718 D 5 +227TH B 44.8 8 53 7.1 1U +227THS B EAV=11.4 3 +227TH L 9.3 1 (5/2)+ +227TH B 35.5 8 35 7 1U +227THS B EAV=9.0 3 +227TH G 9.3 1100E-7 0 E2 326000 0 +227TH2 G KC=$LC=$MC=2.44E5 5 +227TH L 24.5 3/2+ +227TH B 20.5 8 10 6.8 +227THS B EAV=5.1 3 +227TH G 15.2 1 6300E-7 0 M1 238 5 +227TH2 G KC=$LC=$MC=177 4 +227TH G 24.33 5 2800E-5 0 M1+E2 0.100 5 340 11 +227TH2 G KC=$LC=254 8$MC=64.0 23 +227TH L 37.9 3/2- +227TH B 6.9 8 0.3 6.9 +227THS B EAV=1.7 3 +227TH G 28.57 5 4200E-5 0 E1 3.24 7 +227TH2 G KC=$LC=2.42 5$MC=0.616 13 +227TH G 37.90 3 4900E-5 0 E1 1.54 3 +227TH2 G KC=$LC=1.16 3$MC=0.288 6 + diff --git a/HEN_HOUSE/spectra/lnhb/Ac-228.txt b/HEN_HOUSE/spectra/lnhb/Ac-228.txt new file mode 100644 index 000000000..4c8e1b47c --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Ac-228.txt @@ -0,0 +1,643 @@ +224FR 228AC A DECAY (6.15 H) +224FR H TYP=Full$AUT=Andy Pearce$CUT=31-JAN-2009$ +224FR C Evaluation history: Type=Full;Author=Andy Pearce;Cutoff date=31-JAN-2009 +224FR C References: 1931Cu01, 1969Lu12, 1971He23, 1979He23, 1985Sk02, 1987Da28, +224FR2C 1992Li05, 1995Ba42, 1996Sc06, 1997Ar08, 2003Wa32, 2003Au03, 2005KiZT, +224FR3C 2004KiZW +224FR T Auger electrons and ^X ray energies and emission intensities: +224FR T {U Energy (keV)} {U Intensity } {U Line } +224FR T +224FR T 83.23 XKA2 +224FR T 86.1 XKA1 +224FR T +224FR T 96.815 |] XKB3 +224FR T 97.474 |] XKB1 +224FR T 98.069 |] XKB5II +224FR T +224FR T 100.16 |] XKB2 +224FR T 100.548 |] XKB4 +224FR T 100.972 |] XKO23 +224FR T +224FR T +224FR T 63.576-70.787 |] KLL AUGER +224FR T 77.72-86.101 |] ^KLX AUGER +224FR T 91.84-101.12 |] KXY AUGER +224FR T 0.1-18.519 L AUGER +228AC P 0.0 3+ 6.15 H 3 4810 50 +224FR N 1.818E7 1.818E7 5.5E-08 221.818E7 +224FR L 0 1- + +228TH 228AC B- DECAY (6.15 H) +228TH H TYP=Full$AUT=Andy Pearce$CUT=31-JAN-2009$ +228TH C Evaluation history: Type=Full;Author=Andy Pearce;Cutoff date=31-JAN-2009 +228TH C References: 1931Cu01, 1969Lu12, 1971He23, 1979He23, 1985Sk02, 1987Da28, +228TH2C 1992Li05, 1995Ba42, 1996Sc06, 1997Ar08, 2003Wa32, 2003Au03, 2005KiZT, +228TH3C 2004KiZW +228TH T Auger electrons and ^X ray energies and emission intensities: +228TH T {U Energy (keV)} {U Intensity } {U Line } +228TH T +228TH T 89.954 2.5 7 XKA2 +228TH T 93.351 4.1 11 XKA1 +228TH T +228TH T 104.819 |] XKB3 +228TH T 105.604 |] 1.5 4 XKB1 +228TH T 106.239 |] XKB5II +228TH T +228TH T 108.509 |] XKB2 +228TH T 108.955 |] 0.49 13 XKB4 +228TH T 109.442 |] XKO23 +228TH T +228TH T 11.1177-19.5043 37 4 XL (total) +228TH T 11.1177 0.80 5 XLL +228TH T 12.8085-12.967 13.3 8 XLA +228TH T 14.509 0.385 17 XLC +228TH T 14.972-16.4253 18.2 7 XLB +228TH T 18.3633-19.5043 4.23 15 XLG +228TH T +228TH T 68.406-76.745 |] KLL AUGER +228TH T 83.857-93.345 |] 0.27 8 ^KLX AUGER +228TH T 99.29-109.64 |] KXY AUGER +228TH T 5.8-20.3 39.9 21 L AUGER +228AC P 0.0 3+ 6.15 H 3 2123.8 27 +228TH N 1.0 1.0 1 1.0 +228TH L 0 - 1.9126 Y 9 +228TH L 57.759 4 2+ +228TH B 2066.0 276 4 9 +228THS B EAV=742.8 11 +228TH G 57.752 130.470 17E2 153.2 22 +228TH2 G KC=$LC=112.2 16$MC=30.7 5 +228TH L 186.823 4 4+ +228TH B 1937.0 270.6 5 10 +228THS B EAV=690.2 11 +228TH G 129.065 3 2.50 7 E2 3.74 6 +228TH2 G KC=0.264 4$LC=2.54 4$MC=0.697 10 +228TH L 328.003 4 1- +228TH B 1795.8 270.72 23 10.65 1U +228THS B EAV=605.4 11 +228TH G 270.245 7 3.55 10E1 0.0470 7 +228TH2 G KC=0.0376 6$LC=0.00716 10$MC=1717E-6 24 +228TH G 328.004 7 3.04 11E1 0.0305 5 +228TH2 G KC=0.0245 4$LC=0.00455 7$MC=1089E-6 16 +228TH L 378.179 106+ +228TH B 1745.6 270.147 21 12.29 2U +228THS B EAV=587.3 11 +228TH G 191.351 170.133 8 E2 0.776 11 +228TH2 G KC=0.1710 24$LC=0.443 7$MC=0.1209 17 +228TH L 396.078 5 3- +228TH B 1727.7 2712.4 5 8.4 +228THS B EAV=605.7 11 +228TH G 209.248 7 3.97 13E1 0.0848 12 +228TH2 G KC=0.0672 10$LC=0.01333 19$MC=0.00321 5 +228TH G 338.320 5 11.4 4 E1 0.0285 4 +228TH2 G KC=0.0229 4$LC=0.00424 6$MC=1014E-6 15 +228TH L 519.192 6 5- +228TH G 140.999 200.045 9 E1 0.217 3 +228TH2 G KC=0.1690 24$LC=0.0362 5$MC=0.00876 13 +228TH G 332.371 6 0.37 6 E1 0.0297 5 +228TH2 G KC=0.0238 4$LC=0.00441 7$MC=1056E-6 15 +228TH L 831.823 100+ +228TH G 503.819 230.171 19E1 0.0124318 +228TH2 G KC=0.01009 15$LC=1775E-6 25$MC=4.22E-4 6 +228TH G 774.07 100.062 4 E2 0.0164923 +228TH2 G KC=0.01204 17$LC=0.00333 5$MC=8.35E-4 12 +228TH L 874.473 182+ +228TH B 1249.3 270.17 10 9.7 +228THS B EAV=417.2 11 +228TH G 478.40 5 0.224 19E1 0.0137920 +228TH2 G KC=0.01118 16$LC=0.00198 3$MC=4.71E-4 7 +228TH G 546.445 210.199 16E1 0.0105815 +228TH2 G KC=0.00861 12$LC=1500E-6 21$MC=3.57E-4 5 +228TH G 816.82 100.031 4 M1+E2 0.036 21 +228TH2 G KC=0.028 18$LC=0.006 3$MC=0.0014 7 +228TH G 874.45 8 0.050 11E2 0.0129419 +228TH2 G KC=0.00968 14$LC=0.00245 4$MC=6.08E-4 9 +228TH L 938.58 7 0+ +228TH G 610.65 100.024 5 E1 0.0085312 +228TH2 G KC=0.00695 10$LC=1198E-6 17$MC=2.84E-4 4 +228TH G 880.76 100.0065 19E2 0.0127618 +228TH2 G KC=0.00956 14$LC=0.00240 4$MC=5.97E-4 9 +228TH L 944.196 131,2+ +228TH B 1179.6 270.087 16 9.95 2 +228THS B EAV=390.6 11 +228TH G 616.21 3 0.084 7 E1 0.0083812 +228TH2 G KC=0.00683 10$LC=1176E-6 17$MC=2.79E-4 4 +228TH G 944.19 3 0.10 1 E1+M2 0.025 14 +228TH2 G KC=0.020 12$LC=0.0039 19$MC=0.0009 5 +228TH L 968.369 203- +228TH B 1155.4 270.18 3 9.6 +228THS B EAV=381.4 11 +228TH G 449.11 6 0.050 6 E2 0.0554 8 +228TH2 G KC=0.0331 5$LC=0.01653 24$MC=0.00432 6 +228TH G 572.10 5 0.156 18M1+E2 0.09 6 +228TH2 G KC=0.07 5$LC=0.015 7$MC=0.0036 17 +228TH G 640.32 4 0.057 6 E2 0.0245 4 +228TH2 G KC=0.01700 24$LC=0.00556 8$MC=1416E-6 20 +228TH L 968.968 5 2+ +228TH B 1154.8 2731 4 7.37 +228THS B EAV=381.1 11 +228TH G 782.140 6 0.50 4 E2 0.0161523 +228TH2 G KC=0.01182 17$LC=0.00324 5$MC=8.12E-4 12 +228TH G 911.196 6 26.2 8 E2 0.0119417 +228TH2 G KC=0.00900 13$LC=0.00221 3$MC=5.49E-4 8 +228TH G 968.960 9 15.9 5 E2 0.0106115 +228TH2 G KC=0.00806 12$LC=0.00191 3$MC=4.72E-4 7 +228TH L 979.499 142+ +228TH B 1144.3 270.238 20 9.47 +228THS B EAV=377.1 11 +228TH G 583.391 100.120 11E1 0.0093213 +228TH2 G KC=0.00759 11$LC=1313E-6 19$MC=3.12E-4 5 +228TH G 651.53 3 0.094 10E1 0.0075411 +228TH2 G KC=0.00615 9$LC=1053E-6 15$MC=2.50E-4 4 +228TH G 792.69 100.081 5 E2 0.0157222 +228TH2 G KC=0.01154 17$LC=0.00313 5$MC=7.84E-4 11 +228TH G 921.87 120.0154 23M1+E2 0.027 15 +228TH2 G KC=0.021 13$LC=0.0041 20$MC=0.0010 5 +228TH G 979.49 100.028 3 E2 0.0103915 +228TH2 G KC=0.00791 11$LC=0.00186 3$MC=4.59E-4 7 +228TH L 1016.406 212,3,4- +228TH B 1107.4 270.39 6 9.2 1 +228THS B EAV=363.1 11 +228TH G 620.32 7 0.084 7 +228TH G 688.12 4 0.070 7 +228TH G 958.59 4 0.29 5 +228TH G 1016.44 100.019 3 M1+E2 0.021 12 +228TH2 G KC=0.017 10$LC=0.0032 15$MC=0.0008 4 +228TH L 1022.527 6 (3)+ +228TH B 1101.3 273.0 4 8.31 +228THS B EAV=360.8 11 +228TH G 835.704 8 1.70 7 E2 0.0141520 +228TH2 G KC=0.01050 15$LC=0.00274 4$MC=6.83E-4 10 +228TH G 964.786 8 4.99 17E2+M1 -7.2 10 0.0111923 +228TH2 G KC=0.00853 19$LC=0.00199 4$MC=4.92E-4 9 +228TH L 1059.93 3 4- +228TH B 1063.9 270.099 11 9.74 1 +228THS B EAV=346.7 11 +228TH G 540.67 5 0.027 3 M1+E2 0.10 7 +228TH2 G KC=0.08 6$LC=0.017 9$MC=0.0042 19 +228TH G 663.88 8 0.029 6 M1+E2 0.06 4 +228TH2 G KC=0.05 4$LC=0.010 5$MC=0.0024 12 +228TH G 873.10 150.032 7 E1 0.004407 +228TH2 G KC=0.00361 5$LC=6.01E-4 9$MC=1422E-7 20 +228TH L 1091.017 8 4+ +228TH G 904.20 5 0.78 4 E2 0.0121217 +228TH2 G KC=0.00912 13$LC=0.00225 4$MC=5.59E-4 8 +228TH G 1033.244 230.204 12E2 0.0093814 +228TH2 G KC=0.0072 1$LC=1643E-6 23$MC=4.04E-4 6 +228TH L 1122.951 6 2- +228TH B 1000.8 276.67 18 7.81 1 +228THS B EAV=323.2 10 +228TH G 100.41 3 0.114 6 E1+M2 0.23 3.10 5 +228TH2 G KC=$LC=2.27 4$MC=0.615 9 +228TH G 153.967 110.754 23E1 0.1757 25 +228TH2 G KC=0.1375 20$LC=0.0289 4$MC=0.00698 10 +228TH G 726.88 100.68 8 E2 0.0187 3 +228TH2 G KC=0.01349 19$LC=0.00393 6$MC=9.90E-4 14 +228TH G 794.942 144.31 14E2+M1 -4.4 10 0.0179 14 +228TH2 G KC=0.0133 12$LC=0.00340 19$MC=0.00085 5 +228TH G 1065.168 150.135 8 +228TH L 1153.467 102+ 0.29 NS 2 +228TH B 970.3 276 3 7.8 +228THS B EAV=311.9 10 +228TH G 173.96 3 0.036 5 M1+E2 2.5 14 +228TH2 G KC=1.6 15$LC=0.63 5$MC=0.162 22 +228TH G 184.547 190.054 19+M1 100 40 +228TH2 G KC=80 30$LC=$MC= +228TH G 214.89 100.031 5 E2 0.514 8 +228TH2 G KC=0.1399 20$LC=0.274 4$MC=0.0746 11 +228TH G 278.80 150.204 28M1+E2 0.6 4 +228TH2 G KC=0.5 4$LC=0.12 3$MC=0.031 6 +228TH G 321.646 8 0.232 14E2 0.1369 20 +228TH2 G KC=0.0635 9$LC=0.0540 8$MC=0.01444 21 +228TH G 1095.671 230.126 10M1+E2 0.017 9 +228TH2 G KC=0.014 8$LC=0.0026 13$MC=0.0006 3 +228TH G 1153.27 4 0.148 13E1+M2 0.03 3 +228TH2 G KC=0.022 20$LC=0.004 5$MC=0.0011 10 +228TH L 1168.375 5 3- +228TH B 955.4 273.39 13 8.04 +228THS B EAV=306.4 10 +228TH G 77.34 3 0.027 6 E1 0.232 4 +228TH2 G KC=$LC=0.1747 25$MC=0.0426 6 +228TH G 145.842 200.169 6 E1 0.200 3 +228TH2 G KC=0.1562 22$LC=0.0332 5$MC=0.00803 12 +228TH G 199.402 150.299 23E1 0.0950 14 +228TH2 G KC=0.0752 11$LC=0.01502 21$MC=0.00362 5 +228TH G 649.02 120.0332 36E2 0.0238 4 +228TH2 G KC=0.01658 24$LC=0.00536 8$MC=1362E-6 19 +228TH G 772.291 7 1.52 6 M1+E2 2.3 2 0.0244 14 +228TH2 G KC=0.0186 11$LC=0.00437 18$MC=0.00108 5 +228TH G 840.372 9 0.97 4 E2 0.0140 2 +228TH2 G KC=0.01039 15$LC=0.00270 4$MC=6.73E-4 10 +228TH G 1110.604 9 0.284 22E1 0.002884 +228TH2 G KC=0.00237 4$LC=3.88E-4 6$MC=9.15E-5 13 +228TH L 1174.508 18(5)+ +228TH G 987.87 100.14 6 M1+E2 0.022 13 +228TH2 G KC=0.018 10$LC=0.0034 17$MC=0.0008 4 +228TH L 1175.39 5 2+ +228TH B 948.4 270.166 19 9.34 +228THS B EAV=303.9 10 +228TH G 231.42 100.026 4 E2 0.392 6 +228TH2 G KC=0.1211 17$LC=0.199 3$MC=0.0539 8 +228TH G 988.65 200.081 14E2 0.0102115 +228TH2 G KC=0.00778 11$LC=0.00182 3$MC=4.49E-4 7 +228TH G 1117.65 100.061 7 +228TH G 1175.33 100.025 4 E1+M2 0.027 24 +228TH2 G KC=0.021 19$LC=0.004 4$MC=0.001 1 +228TH L 1226.565 7 (4)- +228TH B 897.2 270.67 8 8.65 1 +228THS B EAV=285.1 10 +228TH G 135.507 220.024 6 E1 0.238 4 +228TH2 G KC=0.185 3$LC=0.0401 6$MC=0.00971 14 +228TH G 707.42 5 0.162 18E2 0.0198 3 +228TH2 G KC=0.01417 20$LC=0.00422 6$MC=1067E-6 15 +228TH G 830.481 8 0.61 6 E2+M1 -7.7 9 0.0150 3 +228TH2 G KC=0.01117 22$LC=0.00287 5$MC=7.15E-4 12 +228TH G 1039.83 7 0.056 18 +228TH L 1297.423 10(5)- +228TH B 826.4 271.46 11 8.18 1U +228THS B EAV=259.4 10 +228TH G 204.029 110.114 8 M2 10.65 15 +228TH2 G KC=7.26 11$LC=2.51 4$MC=0.653 10 +228TH G 901.38 3 0.017 4 E2 0.0122017 +228TH2 G KC=0.00917 13$LC=0.00227 4$MC=5.64E-4 8 +228TH G 1110.604 9 0.0272 21E1 0.002884 +228TH2 G KC=0.00237 4$LC=3.88E-4 6$MC=9.15E-5 13 +228TH L 1344.078 113- +228TH B 779.7 270.208 18 8.94 +228THS B EAV=242.7 10 +228TH G 168.53 120.0111 27M1+E2 2.7 15 +228TH2 G KC=1.8 16$LC=0.70 7$MC=0.18 3 +228TH G 824.931 250.053 6 E2 0.0145221 +228TH2 G KC=0.01074 15$LC=0.00283 4$MC=7.06E-4 10 +228TH G 947.976 240.111 10M1+E2 0.025 14 +228TH2 G KC=0.020 12$LC=0.0038 19$MC=0.0009 5 +228TH G 1157.16 150.0073 14E1+M2 0.03 3 +228TH2 G KC=0.022 20$LC=0.004 4$MC=0.0011 10 +228TH G 1286.29 200.052 11E1+M2 +228TH L 1416.11 6 2,3- +228TH B 707.7 270.060 8 9.34 1 +228THS B EAV=217.3 10 +228TH G 471.77 150.034 4 E2 0.0491 7 +228TH2 G KC=0.0301 5$LC=0.01407 20$MC=0.00367 6 +228TH G 1019.88 100.022 5 +228TH G 1088.20 150.0062 14 +228TH G 1229.42 150.0078 25 +228TH L 1431.979 6 4+ +228TH B 691.8 271.6 5 7.88 +228THS B EAV=211.8 10 +228TH G 257.482 210.0286 19M1 1.285 18 +228TH2 G KC=1.029 15$LC=0.194 3$MC=0.0466 7 +228TH G 263.58 100.043 3 E1 0.0498 7 +228TH2 G KC=0.0397 6$LC=0.00760 11$MC=0.00182 3 +228TH G 278.80 150.031 5 E2 0.212 3 +228TH2 G KC=0.0843 12$LC=0.0937 14$MC=0.0252 4 +228TH G 340.969 210.405 20E2+M1 -5.2 18 0.133 21 +228TH2 G KC=0.071 19$LC=0.0451 21$MC=0.0119 5 +228TH G 409.460 132.02 6 E2+M1 0.21 15 +228TH2 G KC=0.16 13$LC=0.038 16$MC=0.009 4 +228TH G 452.50 6 0.0199 19E2 0.0544 8 +228TH2 G KC=0.0326 5$LC=0.01613 23$MC=0.00422 6 +228TH G 463.002 6 4.45 24E2 0.0514 8 +228TH2 G KC=0.0312 5$LC=0.01495 21$MC=0.00390 6 +228TH G 1103.43 100.0102 11E3 0.0195 3 +228TH2 G KC=0.01377 20$LC=0.00429 6$MC=1090E-6 16 +228TH G 1245.15 6 0.110 8 M1+E2 0.013 6 +228TH2 G KC=0.010 5$LC=0.0019 9$MC=0.00046 20 +228TH G 1374.24 7 0.0196 14E2+M3 0.03 3 +228TH2 G KC=0.024 20$LC=0.005 5$MC=0.0014 12 +228TH L 1450.394 104- +228TH G 18.415 120.019 4 E1 6.46 10 +228TH2 G KC=$LC=3.82 6$MC=2.00 3 +228TH G 223.793 210.058 6 M1+E2 -0.18 5 1.85 4 +228TH2 G KC=1.48 4$LC=0.286 5$MC=0.0688 10 +228TH G 282.02 4 0.09 3 M1+E2 0.6 4 +228TH2 G KC=0.4 4$LC=0.12 3$MC=0.030 6 +228TH G 930.99 7 0.0025 23M1+E2 0.026 15 +228TH2 G KC=0.021 12$LC=0.004 2$MC=0.0010 5 +228TH G 1054.13 200.019 6 M1+E2 0.019 10 +228TH2 G KC=0.015 9$LC=0.0029 14$MC=0.0007 4 +228TH G 1451.43 150.0111 22M1+E2 0.009 4 +228TH2 G KC=0.007 3$LC=0.0013 6$MC=0.00031 13 +228TH L 1531.474 6 3+ +228TH G 99.505 121.26 4 M1 3.84 6 +228TH2 G KC=$LC=2.90 4$MC=0.699 10 +228TH G 377.99 100.026 3 M1+E2 0.27 18 +228TH2 G KC=0.20 16$LC=0.049 19$MC=0.012 5 +228TH G 440.450 240.128 10M1 0.295 5 +228TH2 G KC=0.237 4$LC=0.0442 7$MC=0.01061 15 +228TH G 508.955 130.51 4 E2+M1 1.1 0.1130 16 +228TH2 G KC=0.0870 13$LC=0.0196 3$MC=0.00481 7 +228TH G 562.496 7 0.89 4 E2+M1 0.09 6 +228TH2 G KC=0.07 5$LC=0.015 8$MC=0.0038 17 +228TH G 1135.26 150.0102 17 +228TH G 1344.62 150.0094 20M1+E2 0.011 5 +228TH2 G KC=0.008 4$LC=0.0016 7$MC=0.00038 16 +228TH L 1539.21 9 2,3,4+ +228TH B 584.6 270.030 6 9.36 +228THS B EAV=175.0 9 +228TH G 415.96 140.0138 23E1 0.0184 3 +228TH2 G KC=0.01485 21$LC=0.00267 4$MC=6.38E-4 9 +228TH G 1142.87 150.0108 22 +228TH L 1588.335 144- +228TH B 535.5 278.8 23 6.77 1 +228THS B EAV=158.5 9 +228TH G 56.88 5 0.020 5 E1+[M2] 1.0 5 3.6E2 22 +228TH2 G KC=$LC=2.6E2 16$MC=70 50 +228TH G 137.936 220.028 4 M1 7.52 11 +228TH2 G KC=6.00 9$LC=1.146 16$MC=0.276 4 +228TH L 1617.78 7 2,3,4+ +228TH B 506.0 270.071 10 8.78 +228THS B EAV=148.7 9 +228TH G 649.02 120.0086 9 +228TH G 1430.99 100.037 8 +228TH G 1560.02 7 0.021 5 +228TH L 1638.284 9 2+ +228TH B 485.5 271.23 6 7.48 +228THS B EAV=142.0 9 +228TH G 470.21 200.014 3 E1 0.0142820 +228TH2 G KC=0.01157 17$LC=0.00205 3$MC=4.89E-4 7 +228TH G 515.12 7 0.051 6 E1 0.0118917 +228TH2 G KC=0.00966 14$LC=1694E-6 24$MC=4.03E-4 6 +228TH G 1309.76 200.020 7 E1+M2 0.020 18 +228TH2 G KC=0.016 15$LC=0.003 3$MC=0.0008 7 +228TH G 1580.531 250.62 4 M1+E2 0.007 3 +228TH2 G KC=0.0057 24$LC=0.0011 4$MC=0.00025 10 +228TH G 1638.272 230.46 3 E2 0.004106 +228TH2 G KC=0.00319 5$LC=6.08E-4 9$MC=1463E-7 21 +228TH L 1643.125 15(2,3)- +228TH B 480.7 270.82 3 7.64 1 +228THS B EAV=140.4 9 +228TH G 474.79 100.023 4 M1+E2 0.14 10 +228TH2 G KC=0.11 9$LC=0.025 12$MC=0.006 3 +228TH G 520.16 3 0.070 7 M1+E2 0.11 8 +228TH2 G KC=0.09 7$LC=0.019 9$MC=0.0047 21 +228TH G 626.80 220.015 3 +228TH G 674.63 4 0.105 10M1+E2 0.06 4 +228TH2 G KC=0.05 3$LC=0.009 5$MC=0.0023 11 +228TH G 698.99 100.038 6 E2 0.0203 3 +228TH2 G KC=0.01448 21$LC=0.00436 7$MC=1103E-6 16 +228TH G 1247.10 5 0.524 24M1 0.0187 3 +228TH2 G KC=0.01505 21$LC=0.00274 4$MC=6.54E-4 10 +228TH G 1315.33 100.015 3 M1+E2 0.011 6 +228TH2 G KC=0.009 5$LC=0.0017 7$MC=0.00040 17 +228TH L 1645.954 123+ +228TH B 477.8 274.12 20 6.94 +228THS B EAV=139.5 9 +228TH G 114.56 7 0.0102 22M1+E2 9 4 +228TH2 G KC=5 5$LC=3.2 13$MC=0.8 4 +228TH G 419.38 7 0.022 3 E1 0.0181 3 +228TH2 G KC=0.01460 21$LC=0.00263 4$MC=6.26E-4 9 +228TH G 492.29 8 0.025 3 M1+E2 0.13 9 +228TH2 G KC=0.10 8$LC=0.022 11$MC=0.0055 24 +228TH G 523.129 220.129 10E1 0.0115317 +228TH2 G KC=0.00937 14$LC=1641E-6 23$MC=3.90E-4 6 +228TH G 555.07 160.048 6 M1+E2 +228TH G 623.48 220.012 3 M1+E2 0.07 5 +228TH2 G KC=0.06 4$LC=0.012 6$MC=0.0028 13 +228TH G 629.41 5 0.047 5 E2 0.0254 4 +228TH2 G KC=0.01754 25$LC=0.00584 9$MC=1489E-6 21 +228TH G 666.45 5 0.058 6 M1+E2 0.06 4 +228TH2 G KC=0.05 4$LC=0.010 5$MC=0.0024 11 +228TH G 677.08 100.065 6 M1+E2 0.06 4 +228TH2 G KC=0.05 3$LC=0.009 5$MC=0.0023 11 +228TH G 1250.06 5 0.065 6 +228TH G 1459.131 220.87 5 E2 0.004987 +228TH2 G KC=0.00391 6$LC=7.71E-4 11$MC=1.87E-4 3 +228TH G 1588.200 253.06 12E2 0.007 3 +228TH2 G KC=0.0057 23$LC=0.0010 4$MC=0.00025 10 +228TH L 1682.81 3 2,3(),4+ +228TH B 441.0 271.21 4 7.35 +228THS B EAV=127.5 9 +228TH G 660.1 3 0.0054 3 M1+E2 0.06 4 +228TH2 G KC=0.05 4$LC=0.010 5$MC=0.0024 12 +228TH G 1495.904 160.92 3 E2 0.004777 +228TH2 G KC=0.00374 6$LC=7.32E-4 11$MC=1769E-7 25 +228TH G 1625.09 4 0.270 23E2+M3 0.020 17 +228TH2 G KC=0.016 13$LC=0.003 3$MC=0.0008 7 +228TH L 1683.82 5 (4)- +228TH B 440.0 270.20 3 8.13 1 +228THS B EAV=127.2 9 +228TH G 457.18 150.016 3 M1+E2 0.16 11 +228TH2 G KC=0.12 10$LC=0.028 13$MC=0.007 3 +228TH G 1164.55 7 0.067 7 M1+E2 0.015 8 +228TH2 G KC=0.012 6$LC=0.0023 11$MC=0.00055 24 +228TH G 1287.77 8 0.109 25M1+E2 0.012 6 +228TH2 G KC=0.009 5$LC=0.0018 8$MC=0.00042 18 +228TH L 1688.394 112,3+ +228TH B 435.4 272.50 16 7.02 +228THS B EAV=125.7 9 +228TH G 42.46 5 0.009 3 M1 46.3 7 +228TH2 G KC=$LC=35.0 5$MC=8.43 13 +228TH G 671.95 8 0.027 8 +228TH G 813.88 100.0073 17M1+E2 0.036 22 +228TH2 G KC=0.029 18$LC=0.006 3$MC=0.0014 7 +228TH G 1501.59 5 0.513 17 +228TH G 1630.618 201.52 6 M1+E2 0.007 3 +228TH2 G KC=0.0053 22$LC=0.0010 4$MC=0.00023 9 +228TH L 1724.283 6 2+ +228TH B 399.5 271.93 8 7.01 +228THS B EAV=114.3 9 +228TH G 497.64 100.0062 19M2 0.581 9 +228TH2 G KC=0.437 7$LC=0.1074 15$MC=0.0268 4 +228TH G 548.73 110.024 4 M1+E2 0.10 7 +228TH2 G KC=0.08 6$LC=0.017 8$MC=0.0041 18 +228TH G 570.88 4 0.19 5 M1 0.1472 21 +228TH2 G KC=0.1182 17$LC=0.0219 3$MC=0.00525 8 +228TH G 701.742 150.181 15M1 0.0850 12 +228TH2 G KC=0.0684 10$LC=0.01261 18$MC=0.00302 5 +228TH G 755.313 9 1.03 4 M1 0.070 1 +228TH2 G KC=0.0563 8$LC=0.01036 15$MC=0.00248 4 +228TH G 1537.89 100.049 6 E2+M3 0.023 19 +228TH2 G KC=0.018 15$LC=0.004 4$MC=0.0010 8 +228TH G 1666.514 130.173 9 M1 0.0089513 +228TH2 G KC=0.00702 10$LC=1269E-6 18$MC=3.03E-4 5 +228TH G 1724.19 5 0.030 4 E1+M2 +228TH L 1735.450 25(4)+ +228TH B 388.4 270.149 11 8.08 +228THS B EAV=110.7 9 +228TH G 1217.03 100.022 4 +228TH G 1357.81 150.021 5 +228TH G 1548.65 6 0.040 5 +228TH G 1677.66 6 0.057 6 +228TH L 1743.89 3 4+ +228TH B 379.9 270.378 16 7.65 +228THS B EAV=108.1 9 +228TH G 399.83 140.031 4 E1 0.0200 3 +228TH2 G KC=0.01611 23$LC=0.00291 4$MC=6.96E-4 10 +228TH G 1347.50 150.016 4 E1+M2 0.019 17 +228TH2 G KC=0.015 14$LC=0.003 3$MC=0.0007 7 +228TH G 1365.71 120.014 3 E2+M3 0.03 3 +228TH2 G KC=0.025 21$LC=0.006 5$MC=0.0014 12 +228TH G 1415.55 140.022 5 E3 0.0114116 +228TH2 G KC=0.00849 12$LC=0.00218 3$MC=5.43E-4 8 +228TH G 1557.13 7 0.173 9 E2+M1 1.2 2 0.0070 6 +228TH2 G KC=0.0055 5$LC=0.00102 8$MC=2.45E-4 19 +228TH G 1686.22 110.094 7 E2 0.003916 +228TH2 G KC=0.00303 5$LC=5.73E-4 8$MC=1378E-7 20 +228TH L 1758.24 122,3,4+ +228TH B 365.6 270.060 8 8.39 +228THS B EAV=103.6 9 +228TH G 326.04 200.035 6 E2 0.1315 19 +228TH2 G KC=0.0618 9$LC=0.0513 8$MC=0.01372 20 +228TH G 1571.55 200.0059 17 +228TH G 1700.62 200.0105 25 +228TH L 1760.218 242,3()+ +228TH B 363.6 270.139 12 8.02 +228THS B EAV=103.0 9 +228TH G 737.74 5 0.039 5 M1+E2 0.05 3 +228TH2 G KC=0.037 24$LC=0.007 4$MC=0.0018 9 +228TH G 791.43 9 0.010 3 M1+E2 0.039 23 +228TH2 G KC=0.031 19$LC=0.006 3$MC=0.0015 7 +228TH G 1573.389 240.034 4 E2 0.004387 +228TH2 G KC=0.00342 5$LC=0.00066 1$MC=1592E-7 23 +228TH G 1702.40 8 0.055 7 E2+M3 0.018 15 +228TH2 G KC=0.014 11$LC=0.0030 25$MC=0.0007 6 +228TH L 1795.9 1 3,4+ +228TH B 327.9 270.035 6 8.48 +228THS B EAV=91.9 8 +228TH G 1276.72 100.015 3 +228TH G 1738.46 5 0.018 4 +228TH L 1797.65 8 2+ +228TH B 326.2 270.051 8 8.3 +228THS B EAV=91.4 8 +228TH G 1401.52 100.013 3 E1+M2 0.017 15 +228TH2 G KC=0.013 12$LC=0.0026 24$MC=0.0006 6 +228TH G 1469.74 150.021 5 E1+M2 0.015 14 +228TH2 G KC=0.012 11$LC=0.0023 21$MC=0.0006 5 +228TH G 1740.5 3 0.011 4 +228TH G 1797.5 5 0.0022 8 E1+M2 0.009 8 +228TH2 G KC=0.007 7$LC=0.0014 13$MC=0.0003 3 +228TH L 1892.996 173+ +228TH B 230.8 270.109 8 7.5 +228THS B EAV=62.8 8 +228TH G 666.45 5 0.0068 7 E1 0.0072211 +228TH2 G KC=0.00590 9$LC=1007E-6 14$MC=2.39E-4 4 +228TH G 870.47 7 0.046 5 M1 0.0481 7 +228TH2 G KC=0.0387 6$LC=0.0071 1$MC=1699E-6 24 +228TH G 1706.17 7 0.0089 12M1+E2 0.42 40 0.0078 12 +228TH2 G KC=0.0061 10$LC=0.00110 16$MC=0.00026 4 +228TH G 1835.29 100.038 4 E2+M1 2.9 3 0.0038210 +228TH2 G KC=0.00291 8$LC=5.36E-4 14$MC=1.28E-4 4 +228TH L 1899.95 4 2+ +228TH B 223.9 270.069 8 7.65 +228THS B EAV=60.8 8 +228TH G 877.38 7 0.014 3 M1+E2 0.030 18 +228TH2 G KC=0.024 15$LC=0.0047 23$MC=0.0011 6 +228TH G 930.99 7 0.004 1 +228TH G 1713.49 200.0057 11E2+M3 0.018 14 +228TH2 G KC=0.014 11$LC=0.0029 24$MC=0.0007 6 +228TH G 1842.15 8 0.037 6 M1+E2 -0.86 14 0.0055 4 +228TH2 G KC=0.00420 25$LC=0.00076 5$MC=1.82E-4 11 +228TH G 1900.16 200.0030 6 E1+M2 0.008 7 +228TH2 G KC=0.006 6$LC=0.0012 11$MC=0.0003 3 +228TH L 1906.64 10(2)+ +228TH B 217.2 270.025 5 8.05 +228THS B EAV=58.8 8 +228TH G 490.33 150.0116 25E2 0.0447 7 +228TH2 G KC=0.0280 4$LC=0.01242 18$MC=0.00323 5 +228TH G 1074.73 150.011 4 +228TH L 1928.57 6 3+ +228TH B 195.2 270.061 8 7.52 +228THS B EAV=52.5 8 +228TH G 168.53 120.0025 7 M1+E2 2.7 15 +228TH2 G KC=1.8 16$LC=0.70 7$MC=0.18 3 +228TH G 389.32 130.0108 17M1+E2 0.25 17 +228TH2 G KC=0.19 15$LC=0.044 18$MC=0.011 4 +228TH G 1742.1 3 0.0084 25M1+E2 +228TH G 1870.82 9 0.0257 24M1+E2 0.0051 18 +228TH2 G KC=0.0038 14$LC=0.00070 24$MC=0.00017 6 +228TH L 1937.16 9 2,3,4+ +228TH B 186.6 270.053 6 7.52 +228THS B EAV=50.0 8 +228TH G 397.95 100.029 3 +228TH G 1062.57 150.011 4 +228TH G 1750.58 200.0084 9 +228TH G 1879.6 3 0.0013 5 +228TH L 1944.895 113+ +228TH B 178.9 270.307 22 6.7 +228THS B EAV=47.8 8 +228TH G 356.7 3 0.0178 21E1+M2 0.5 0.8 8 +228TH2 G KC=0.6 6$LC=0.17 17$MC=0.04 5 +228TH G 718.30 3 0.019 4 E1 0.006289 +228TH2 G KC=0.00513 8$LC=8.70E-4 13$MC=2.06E-4 3 +228TH G 776.51 3 0.020 6 +228TH G 791.43 9 0.014 4 M1 0.0618 9 +228TH2 G KC=0.0498 7$LC=0.00915 13$MC=0.00219 3 +228TH G 853.96 8 0.0124 20M1+E2 0.032 19 +228TH2 G KC=0.025 16$LC=0.0050 25$MC=0.0012 6 +228TH G 975.98 5 0.052 6 M1 0.0356 5 +228TH2 G KC=0.0287 4$LC=0.00524 8$MC=1254E-6 18 +228TH G 1000.68 100.0054 3 +228TH G 1758.11 5 0.036 4 E2+M1 -9.1 0.003716 +228TH2 G KC=0.00285 4$LC=5.33E-4 8$MC=1281E-7 18 +228TH G 1887.13 5 0.094 7 E2+M1 0.0050 17 +228TH2 G KC=0.0038 13$LC=0.00068 23$MC=0.00016 6 +228TH L 1958.72 222+ +228TH B 165.1 270.0038 8 8.5 +228THS B EAV=43.9 8 +228TH G 1772.2 3 0.0019 5 E2+M3 0.016 13 +228TH2 G KC=0.013 10$LC=0.0027 22$MC=0.0007 6 +228TH G 1958.4 3 0.0016 5 E1+M2 +228TH L 1964.98 7 2,3,4+ +228TH B 158.8 270.0132 14 7.91 +228THS B EAV=42.2 8 +228TH G 1907.14 110.0124 13 +228TH L 1987.46 104+ +228TH B 136.3 270.07 4 7 +228THS B EAV=35.9 8 +228TH G 1017.94 200.03 3 E2+M3 0.07 7 +228TH2 G KC=0.05 5$LC=0.014 12$MC=0.003 3 +228TH G 1609.44 150.0081 17E2 0.004226 +228TH2 G KC=0.00329 5$LC=6.30E-4 9$MC=1518E-7 22 +228TH G 1800.9 2 0.0046 8 +228TH G 1929.78 200.0208 14E2+M3 0.013 10 +228TH2 G KC=0.010 8$LC=0.0021 17$MC=0.0005 5 +228TH L 2010.11 5 2,3,(4)+ +228TH B 113.7 270.238 15 6.2 +228THS B EAV=29.7 8 +228TH G 372.59 3 0.0070 17E2 0.0902 13 +228TH2 G KC=0.0475 7$LC=0.0315 5$MC=0.00834 12 +228TH G 887.26 100.029 3 M1+E2 0.029 17 +228TH2 G KC=0.023 14$LC=0.0046 22$MC=0.0011 6 +228TH G 919.03 120.028 3 +228TH G 1040.94 150.047 10E2+M3 0.07 6 +228TH2 G KC=0.05 5$LC=0.013 12$MC=0.003 3 +228TH G 1823.22 100.046 5 +228TH G 1952.37 100.062 5 E2+M3 0.013 10 +228TH2 G KC=0.010 8$LC=0.0020 17$MC=0.0005 4 +228TH L 2013.6 3 2,3,4+ +228TH B 110.2 270.0032 10 8.03 +228THS B EAV=28.7 7 +228TH G 1826.8 3 0.0022 8 +228TH G 1955.9 5 0.0008 3 +228TH L 2022.84 10 + +228TH B 101.0 270.061 6 6.64 +228THS B EAV=26.2 7 +228TH G 384.47 9 0.0070 17E2 0.0828 12 +228TH2 G KC=0.0447 7$LC=0.0282 4$MC=0.00745 11 +228TH G 1053.11 200.014 4 M1+E2 0.019 10 +228TH2 G KC=0.015 9$LC=0.0029 14$MC=0.0007 4 +228TH G 1148.17 140.0062 14M1+E2 0.015 8 +228TH2 G KC=0.012 7$LC=0.0023 11$MC=0.00057 25 +228TH G 1190.83 200.0065 17M1+E2 0.014 7 +228TH2 G KC=0.011 6$LC=0.0021 10$MC=0.00052 23 +228TH G 1965.22 120.0223 22M1+E2 0.0046 15 +228TH2 G KC=0.0034 12$LC=0.00062 20$MC=0.00015 5 +228TH L 2029.84 161,2+ +228TH B 94.0 270.026 4 6.91 2 +228THS B EAV=24.3 7 +228TH G 939.89 150.009 3 +228TH G 1013.55 130.0097 16 +228TH G 1972.0 3 0.0038 8 +228TH G 2029.4 5 0.0019 5 E1+M2 0.007 6 +228TH2 G KC=0.005 5$LC=0.0010 9$MC=0.00024 22 +228TH L 2036.99 172,3,4+ +228TH B 86.8 270.0069 11 7.38 +228THS B EAV=22.4 8 +228TH G 1850.17 200.0046 8 +228TH G 1979.3 3 0.0019 5 +228TH L 2123.1 3 (2)+ +228TH B 0.7 270.0047 11 3.3 +228THS B EAV=0.18 68 +228TH G 1795.13 6 0.0022 8 +228TH G 1936.3 3 0.0022 6 + diff --git a/HEN_HOUSE/spectra/lnhb/Ag-108.txt b/HEN_HOUSE/spectra/lnhb/Ag-108.txt new file mode 100644 index 000000000..8268793bc --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Ag-108.txt @@ -0,0 +1,92 @@ +108PD 108AG EC DECAY (2.382 M) +108PD H TYP=Update$AUT=V.Chisté$CUT=25-AUG-2006$ +108PD2 H TYP=Full$AUT=V.Chisté$CUT=31-JAN-2005$ +108PD C Evaluation history: Type=Update;Author=V.Chisté;Cutoff date=25-AUG-2006 +108PD2C Type=Full;Author=V.Chisté;Cutoff date=31-JAN-2005 +108PD T Auger electrons and ^X ray energies and emission intensities: +108PD T {U Energy (keV)} {U Intensity } {U Line } +108PD T +108PD T 21.0203 0.44 3 XKA2 +108PD T 21.1774 0.84 6 XKA1 +108PD T +108PD T 23.7914 |] XKB3 +108PD T 23.819 |] 0.230 16 XKB1 +108PD T 24.013 |] XKB5II +108PD T +108PD T 24.2994 |] XKB2 +108PD T 24.344 |] 0.0391 30 XKB4 +108PD T +108PD T +108PD T 17.032-17.884 |] KLL AUGER +108PD T 20.032-21.176 |] 0.341 25 ^KLX AUGER +108PD T 23.011-24.347 |] KXY AUGER +108PD T 1.7-3.6 1.97 4 L AUGER +108AG P 0.0 1+ 2.382 M 11 1922 6 +108PD N 4.049E1 4.049E1 0.0247 4.049E1 +108PD L 0 0+ +108PD E 0.28 2 1.73 124.7 +108PD2 E EAV=401 3$CK=0.8644 14$CL=0.1092 10$CM=0.0221 4$CN=0.0043 2$CO=0 0 +108PD L 433.938 5 2+ 23.9 PS 7 +108PD E 0.0026 3 0.19 8 5.46 +108PD2 E EAV=212 3$CK=0.8636 14$CL=0.1098 10$CM=0.0223 4$CN=0.0043 2$CO=0 0 +108PD G 433.938 5 0.46 7 [E2] 0.0090927 +108PD2 G KC=0.00784 24$LC=1021E-6 31$MC=1.92E-4 6 +108PD L 931.07 122+ 6.2 PS 4 +108PD G 497.13 120.00152 40 +108PD G 931.07 120.00048 8 +108PD L 1052.80 5 0+ 4.0 PS 4 +108PD E 0.243 394.89 +108PD2 E EAV= $CK=0.8611 14$CL=0.1118 11$CM=0.0227 5$CN=0.0044 2$CO=0 0 +108PD G 618.86 5 0.245 39 +108PD L 1314.2 1 0+ +108PD E 0.0038 6 6.37 +108PD2 E EAV= $CK=0.8585 14$CL=0.1138 11$CM=0.0232 5$CN=0.0045 2$CO=0 0 +108PD G 383.13 160.00083 30 +108PD G 880.26 100.00298 48 +108PD L 1441.16 5 2+ 4.8 PS +108PD E 0.0170 215.46 +108PD2 E EAV= $CK=0.8560 14$CL=0.1157 11$CM=0.0237 5$CN=0.0046 2$CO=0 0 +108PD G 388.36 7 0.0017 6 +108PD G 1007.22 5 0.0126 20 +108PD G 1441.15 5 0.00269 44[E2] 4.64E-414 +108PD2 G KC=4.07E-4 12$LC=4.69E-5 14$MC=8.78E-6 26 +108PD L 1539.95 7 (1,2)+ +108PD E 0.00224 276.12 +108PD2 E EAV= $CK=0.8529 15$CL=0.1181 11$CM=0.0242 5$CN=0.0047 3$CO=0 0 +108PD G 1106.01 7 0.00130 22 +108PD G 1539.94 7 0.00094 16 + +108CD 108AG B- DECAY (2.382 M) +108CD H TYP=Update$AUT=V.Chisté$CUT=25-AUG-2006$ +108CD2 H TYP=Full$AUT=V.Chisté$CUT=31-JAN-2005$ +108CD C Evaluation history: Type=Update;Author=V.Chisté;Cutoff date=25-AUG-2006 +108CD2C Type=Full;Author=V.Chisté;Cutoff date=31-JAN-2005 +108CD T Auger electrons and ^X ray energies and emission intensities: +108CD T {U Energy (keV)} {U Intensity } {U Line } +108CD T +108CD T 22.9843 0.00127 6 XKA2 +108CD T 23.1738 0.00239 11 XKA1 +108CD T +108CD T 26.0615 |] XKB3 +108CD T 26.0958 |] 0.00067 4 XKB1 +108CD T 26.304 |] XKB5II +108CD T +108CD T 26.644 |] XKB2 +108CD T 26.702 |] 0.000121 7 XKB4 +108CD T +108CD T +108CD T 18.556-19.507 |] KLL AUGER +108CD T 21.873-23.172 |] 0.00084 5 ^KLX AUGER +108CD T 25.171-26.707 |] KXY AUGER +108CD T 1.8-4 0.00535 7 L AUGER +108AG P 0.0 1+ 2.382 M 11 1649 8 +108CD N 1.025E0 1.025E0 0.9753 1.025E0 +108CD L 0 0+ +108CD B 1649 8 95.9 3 4.43 +108CDS B EAV=628 4 +108CD L 632.98 5 2+ 6.86 PS 7 +108CD B 1016 8 1.63 26 5.35 +108CDS B EAV=355 3 +108CD G 632.98 5 1.62 26E2 0.0034710 +108CD2 G KC=0.00300 9$LC=3.80E-4 11$MC=7.30E-5 22 + diff --git a/HEN_HOUSE/spectra/lnhb/Ag-108m.txt b/HEN_HOUSE/spectra/lnhb/Ag-108m.txt new file mode 100644 index 000000000..480fa1a91 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Ag-108m.txt @@ -0,0 +1,65 @@ +108AG 108AG IT DECAY (438 Y) +108AG C References: 2004Sc04 +108AG T Auger electrons and ^X ray energies and emission intensities: +108AG T {U Energy (keV)} {U Intensity } {U Line } +108AG T +108AG T 21.9906 0.49 4 XKA2 +108AG T 22.16317 0.93 7 XKA1 +108AG T +108AG T 24.9118 |] XKB3 +108AG T 24.9427 |] 0.256 19 XKB1 +108AG T 25.146 |] XKB5II +108AG T +108AG T 25.4567 |] XKB2 +108AG T 25.512 |] 0.045 4 XKB4 +108AG T +108AG T +108AG T 17.79-18.69 |] KLL AUGER +108AG T 20.945-22.16 |] 0.349 27 ^KLX AUGER +108AG T 24.079-25.507 |] KXY AUGER +108AG T 1.9-3.8 8.60 7 L AUGER +108AG P 109.440 7 6+ 438 Y 9 +108AG N 1.099E1 1.099E1 9.100001 1.099E1 +108AG L 0 1+ 2.382 M 11 +108AG L 79.131 3 2- 1 NS +108AG G 79.131 3 6.9 5 E1 0.310 9 +108AG2 G KC=0.269 8$LC=0.0336 10$MC=0.00633 19 +108AG L 109.440 7 6+ 438 Y 8 +108AG G 30.309 8 2.15E-5 18M4 4.25E5 13 +108AG2 G KC=9.77E3 29$LC=3.2E5 1$MC=8.20E4 25 + +108PD 108AG EC DECAY (438 Y) +108PD C References: 2004Sc04 +108PD T Auger electrons and ^X ray energies and emission intensities: +108PD T {U Energy (keV)} {U Intensity } {U Line } +108PD T +108PD T 21.0203 18.38 18 XKA2 +108PD T 21.1774 34.72 30 XKA1 +108PD T +108PD T 23.7914 |] XKB3 +108PD T 23.819 |] 9.53 12 XKB1 +108PD T 24.013 |] XKB5II +108PD T +108PD T 24.2994 |] XKB2 +108PD T 24.344 |] 1.62 6 XKB4 +108PD T +108PD T +108PD T 17.032-17.884 |] KLL AUGER +108PD T 20.032-21.176 |] 14.1 4 ^KLX AUGER +108PD T 23.011-24.347 |] KXY AUGER +108PD T 1.7-3.6 83.1 4 L AUGER +108AG P 109.440 7 6+ 438 Y 9 1922 6 +108PD N 1.10E0 1.10E0 0.909 1.10E0 +108PD L 0 0+ +108PD L 433.938 5 2+ +108PD G 433.938 5 90.1 6 [E2] 0.0090927 +108PD2 G KC=0.00784 24$LC=1021E-6 31$MC=1.92E-4 6 +108PD L 1048.25 5 4+ +108PD G 614.276 4 90.5 16E2 0.0033510 +108PD2 G KC=0.00291 9$LC=3.60E-4 11$MC=6.77E-5 20 +108PD L 1771.162 116+ +108PD E 90.9 6 9.24 +108PD2 E EAV= $CK=0.8457 15$CL=0.1238 12$CM=0.0256 5$CN=0.0050 3$CO=0 0 +108PD G 722.907 1090.8 16E2 0.002197 +108PD2 G KC=0.00191 6$LC=2.31E-4 7$MC=4.34E-5 13 + diff --git a/HEN_HOUSE/spectra/lnhb/Ag-110.txt b/HEN_HOUSE/spectra/lnhb/Ag-110.txt new file mode 100644 index 000000000..b3dd713f8 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Ag-110.txt @@ -0,0 +1,92 @@ +110PD 110AG EC DECAY (24.56 S) +110PD T Auger electrons and ^X ray energies and emission intensities: +110PD T {U Energy (keV)} {U Intensity } {U Line } +110PD T +110PD T 21.0203 0.060 12 XKA2 +110PD T 21.1774 0.114 23 XKA1 +110PD T +110PD T 23.7914 |] XKB3 +110PD T 23.819 |] 0.032 7 XKB1 +110PD T 24.013 |] XKB5II +110PD T +110PD T 24.2994 |] XKB2 +110PD T 24.344 |] 0.0054 10 XKB4 +110PD T +110AG P 0.0 1+ 24.56 S 11 892 11 +110PD N 3.333E2 3.333E2 0.003 3.333E2 +110PD L 0 - STABLE +110PD E 0.30 6 4.1 +110PD2 E EAV= $CK=0.862 $CL=0.111 $CM=0.027 $CN= $CO= + +110CD 110AG B- DECAY (24.56 S) +110CD T Auger electrons and ^X ray energies and emission intensities: +110CD T {U Energy (keV)} {U Intensity } {U Line } +110CD T +110CD T 22.9843 0.0032 3 XKA2 +110CD T 23.1738 0.0061 6 XKA1 +110CD T +110CD T 26.0615 |] XKB3 +110CD T 26.0958 |] 0.00169 15 XKB1 +110CD T 26.304 |] XKB5I +110CD T +110CD T 26.644 |] XKB2 +110CD T 26.702 |] 0.00031 3 XKB4 +110CD T +110AG P 0.0 1+ 24.56 S 11 2892.2 16 +110CD N 1.003E0 1.003E0 0.997 1.003E0 +110CD L 0 0+ STABLE +110CD B 2892.2 1695.2 4 4.66 +110CDS B EAV=1199.0 8 +110CD L 657.7622 112+ 5.39 PS 7 +110CD B 2234.4 164.4 4 5.53 +110CDS B EAV=893.8 8 +110CD G 657.7600 114.6 4 E2 0.003189 +110CD2 G KC=0.00272 8$LC=0.00034 1$MC= +110CD L 1473.27 200+ +110CD B 1419.2 170.038 3 6.81 +110CDS B EAV=527.1 7 +110CD G 815.50 2 0.039 4 E2 0.001856 +110CD2 G KC=0.00159 5$LC=0.00019 1$MC= +110CD L 1475.7894 162+ 0.68 PS 10 +110CD B 1416.5 160.0099 10 7.39 +110CDS B EAV=526.0 7 +110CD G 818.0244 180.0092 9 M1+E2 -1.36 7 0.001946 +110CD2 G KC=0.00167 5$LC=0.00020 1$MC= +110CD G 1475.7792 230.0037 6 E2 0.0051 2 +110CD2 G KC=0.0044 1$LC=7000E-8 0$MC= +110CD L 1731.77 200+ +110CD B 1160.7 170.0009 5 8.1 +110CDS B EAV=415.9 7 +110CD G 1074.0 2 0.0009 5 E2 0.0098 3 +110CD2 G KC=0.0085 3$LC=0.00010 1$MC= +110CD L 1783.469 172+ +110CD B 1108.8 170.0121 17 6.89 +110CDS B EAV=394.1 7 +110CD G 1125.699 200.0156 14M1+E2 0.33 8 0.001053 +110CD2 G KC=0.00089 30$LC=0.00010 1$MC= +110CD G 1783.46 3 0.0046 8 E2 +110CD L 2078.77 200+ +110CD B 813.6 170.0076 14 6.6 +110CDS B EAV=273.3 7 +110CD G 295.3 2 0.0078 16(E1) 0.0080524 +110CD2 G KC=0.00703 21$LC=0.00083 3$MC=0.00016 1 +110CD L 2079.27 203-+ 0.72 PS 30 +110CD B 813.3 170.0022 5 7.54 2 +110CDS B EAV=290.7 7 +110CD G 1421.5 2 0.0023 5 0.0026 1 +110CD2 G KC=0.0023 1$LC=0.00003 1$MC= +110CD L 2287.68 202+ +110CD B 604.8 170.0022 5 6.68 +110CDS B EAV=192.8 6 +110CD G 1629.9 2 0.0023 5 E2(+M1) 0.06 3 +110CD L 2332.08 200+ +110CD B 560.4 170.0072 5 6.05 +110CDS B EAV=176.4 6 +110CD G 1674.3 2 0.007 1 +110CD L 2662.14 150+ +110CD B 230.1 160.0063 8 4.83 +110CDS B EAV=64.2 5 +110CD G 1186.3 2 0.0028 5 [E2] 0.0079 2 +110CD2 G KC=0.0069 2$LC=0.00009 1$MC= +110CD G 2004.40 2 0.0037 6 E2 + diff --git a/HEN_HOUSE/spectra/lnhb/Ag-110m.txt b/HEN_HOUSE/spectra/lnhb/Ag-110m.txt new file mode 100644 index 000000000..454f77ca6 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Ag-110m.txt @@ -0,0 +1,184 @@ +110AG 110AG IT DECAY (249.78 D) +110AG T Auger electrons and ^X ray energies and emission intensities: +110AG T {U Energy (keV)} {U Intensity } {U Line } +110AG T +110AG T 21.9906 0.198 12 XKA2 +110AG T 22.16317 0.372 22 XKA1 +110AG T +110AG T 24.9118 |] XKB3 +110AG T 24.9427 |] 0.103 7 XKB1 +110AG T 25.146 |] XKB5II +110AG T +110AG T 25.4567 |] XKB2 +110AG T 25.512 |] 0.0179 12 XKB4 +110AG T +110AG P 117.59 5 6+ 249.78 D 2 +110AG N 7.353E1 7.353E1 0.0136 7.353E1 +110AG G 264.25 6 0.0060 6 +110AG G 356.43 100.00425 30 +110AG G 647.8 4 0.018 5 +110AG G 666.6 5 0.028 14 +110AG G 676.58 100.14 1 +110AG G 1050.5 5 0.0076 10 +110AG G 1465.6 1 0.0018 2 +110AG G 1572.4 2 0.0011 3 +110AG L 0 0+ 24.56 S 11 +110AG L 1.113 2- 660 NS 40 +110AG G 1.113 E1 +110AG L 117.59 5 6+ 249.78 D 2 +110AG G 116.48 5 0.0080 3 M4 168 5 +110AG2 G KC=105 3$LC=50.1 15$MC=11.0000 0 + +110CD 110AG B- DECAY (249.78 D) +110CD T Auger electrons and ^X ray energies and emission intensities: +110CD T {U Energy (keV)} {U Intensity } {U Line } +110CD T +110CD T 22.9843 0.153 9 XKA2 +110CD T 23.1738 0.288 16 XKA1 +110CD T +110CD T 26.0615 |] XKB3 +110CD T 26.0958 |] 0.080 5 XKB1 +110CD T 26.304 |] XKB5II +110CD T +110CD T 26.644 |] XKB2 +110CD T 26.702 |] 0.0146 9 XKB4 +110CD T +110AG P 117.59 5 6+ 249.78 D 2 2892.2 16 +110CD N 1.014E0 1.014E0 0.9864 1.014E0 +110CD G 264.25 6 0.0060 6 +110CD G 356.43 100.00425 30 +110CD G 647.8 4 0.018 5 +110CD G 666.6 5 0.028 14 +110CD G 676.58 100.14 1 +110CD G 1050.5 5 0.0076 10 +110CD G 1465.6 1 0.0018 2 +110CD G 1572.4 2 0.0011 3 +110CD L 0 0+ STABLE +110CD L 657.7621 112+ 5.39 PS 7 +110CD G 657.7600 1194.38 8 E2 0.003189 +110CD2 G KC=0.00272 8$LC=0.00034 1$MC= +110CD L 1475.7898 232+ 0.68 PS 10 +110CD G 818.0244 187.33 4 M1+E2 -1.36 7 0.001946 +110CD2 G KC=0.00167 5$LC=0.00020 1$MC= +110CD G 1475.7792 234.03 5 E2 0.000512 +110CD2 G KC=0.00044 1$LC=$MC= +110CD L 1542.4440 174+ 0.73 PS 9 +110CD G 884.6781 1374.0 12E2 0.001525 +110CD2 G KC=0.00131 4$LC=0.00016 1$MC= +110CD L 1783.46 3 2+ +110CD G 1125.699 200.0304 14M1+E2 0.33 8 0.001033 +110CD2 G KC=0.00089 30$LC=0.00010 1$MC= +110CD G 1783.46 3 0.0101 5 E2 +110CD L 2078.69 7 3- 0.72 PS 30 +110CD G 603.08 100.011 8 E1 0.0013940 +110CD2 G KC=0.00121 4$LC=0.00014 10$MC= +110CD G 1420.07 5 0.026 4 E1 0.000261 +110CD2 G KC=0.00023 1$LC=$MC= +110CD L 2162.8012 253+ +110CD G 620.3553 172.72 8 M1+E2 -0.50 4 0.0039712 +110CD2 G KC=0.00342 10$LC=0.00041 1$MC= +110CD G 687.0091 186.45 3 M1+E2 -1.76 6 0.002929 +110CD2 G KC=0.00251 8$LC=0.00031 1$MC= +110CD G 1505.028 2 13.16 16M1+E2 -1.21 4 0.000451 +110CD2 G KC=0.00045 1$LC=$MC= +110CD L 2220.0680 264+ +110CD G 677.6217 1210.56 6 M1+E2 0.36 2 0.0032410 +110CD2 G KC=0.00280 8$LC=0.00033 1$MC= +110CD G 744.2755 184.71 3 E2(+M3) 0 0.002327 +110CD2 G KC=0.00199 6$LC=0.00025 1$MC= +110CD G 1562.2940 181.21 3 E2(+M3) -0.10 15 +110CD L 2250.547 134+ +110CD B 759.3 160.06 5 11.5 2 +110CDS B EAV=251.9 7 +110CD G 467.03 4 0.0249 19(E2) 0.0081324 +110CD2 G KC=0.00699 21$LC=0.00092 3$MC=0.00018 1 +110CD G 708.128 200.23 5 M1+E2 -0.15 9 0.002959 +110CD2 G KC=0.00255 8$LC=0.00030 1$MC= +110CD G 774.7 1 0.006 3 (E2) 0.002106 +110CD2 G KC=0.00180 5$LC=0.00022 1$MC= +110CD G 1592.80 150.0207 8 (E2) +110CD L 2287.53 15 + +110CD G 1629.75 150.0040 5 M1+E2 0.06 3 +110CD L 2356.6 2 1+,2++ +110CD G 1698.8 2 0.0017 3 +110CD L 2433.20 4 3+ +110CD G 957.35 100.0093 19M1+E2 -0.9 7 0.0013910 +110CD2 G KC=0.00120 9$LC=0.00014 1$MC= +110CD G 1775.41 4 0.0065 3 M1+E2 +110CD L 2479.933 4 6+ +110CD B 529.9 1630.8 3 8.28 +110CDS B EAV=165.3 6 +110CD G 229.423 230.0119 14 +110CD G 937.485 3 34.51 27E2(+M3) -0.07 0.001334 +110CD2 G KC=0.00115 3$LC=0.00014 1$MC= +110CD L 2539.675 8 5- 0.62 PS 28 +110CD B 470.1 160.060 4 10.8 1 +110CDS B EAV=143.9 6 +110CD G 997.243 150.128 4 E1(+M2) -0.30 46 0.0007 9 +110CD2 G KC=$LC=$MC= +110CD L 2561.281 8 4+ +110CD G 341.3 2 0.0022 5 +110CD G 1018.95 8 0.0141 7 M1+E2 -0.56 35 +110CD G 1085.447 140.072 4 E2 0.000963 +110CD2 G KC=0.00083 3$LC=0.00010 1$MC= +110CD G 1903.52 4 0.0159 7 +110CD L 2659.852 115- +110CD B 349.9 160.031 4 10.7 1 +110CDS B EAV=102.6 6 +110CD G 120.23 3 0.0169 9 M1(+E2) -0.13 33 0.29 8 +110CD2 G KC=0.25 6$LC=0.032 18$MC=0.006 4 +110CD G 409.4 5 6300E-6 0 E1(+M2) -0.029 23 0.0034610 +110CD2 G KC=0.00303 9$LC=0.00036 1$MC= +110CD G 1117.46 3 0.0488 9 E1(+M2) 0.021 44 0.000401 +110CD2 G KC=0.00034 1$LC=$MC= +110CD L 2662.41 103+ +110CD G 1186.7 1 0.00160 5 +110CD G 2004.65 100.0012 4 +110CD L 2705.668 104+ +110CD G 1163.14 8 0.074 24M1+E2 0.03 0.000973 +110CD2 G KC=0.00084 3$LC=9.8E-5 3$MC= +110CD L 2707.397 8 4+ +110CD G 544.55 5 0.018 3 M1+E2 0.0054 2 +110CD2 G KC=0.00464 19$LC=0.00057 2$MC= +110CD G 1164.94 9 0.043 3 M1+E2 0.0 3 0.000903 +110CD2 G KC=0.00077 7$LC=$MC= +110CD L 2793.417 7 4+ +110CD G 360.23 8 0.008 5 +110CD G 572.8 2 0.0173 13 +110CD G 630.62 6 0.033 5 +110CD G 714.9 1 0.0092 24 +110CD G 1251.04 4 0.026 3 +110CD L 2842.51 105- +110CD B 167.3 160.0252 10 9.7 1 +110CDS B EAV=45.4 5 +110CD G 409.4 5 6300E-6 0 E1(+M2) -0.029 23 0.0034610 +110CD2 G KC=0.00303 9$LC=0.00036 1$MC= +110CD G 1300.05 100.0189 7 E1(+M2) 0.0 1 0.000301 +110CD2 G KC=0.00026 1$LC=$MC= +110CD L 2876.803 126+ +110CD B 133.0 160.392 18 8.2 +110CDS B EAV=35.5 5 +110CD G 396.895 230.037 4 +110CD G 626.258 100.214 17E2 0.0036111 +110CD2 G KC=0.00309 9$LC=0.00039 1$MC= +110CD G 1334.326 170.141 5 E2 0.000622 +110CD2 G KC=0.00054 2$LC=$MC= +110CD L 2926.746 3 5+ +110CD B 83.1 1667.5 6 5.36 +110CDS B EAV=21.6 5 +110CD G 133.333 7 0.0736 16 +110CD G 219.348 8 0.072 5 +110CD G 221.079 100.068 10 +110CD G 266.913 120.041 4 +110CD G 365.448 100.092 5 +110CD G 387.073 9 0.0518 9 +110CD G 446.812 3 3.65 5 M1+E2 -0.38 2 0.0089 3 +110CD2 G KC=0.00772 23$LC=0.00094 3$MC=0.00018 1 +110CD G 493.43 100.0095 11 +110CD G 706.6760 1516.48 8 M1+E2 -1.42 7 0.002758 +110CD2 G KC=0.00237 7$LC=0.00029 1$MC= +110CD G 763.9424 1722.31 9 E2+M3 -0.10 15 0.002309 +110CD2 G KC=0.00198 10$LC=0.00024 2$MC= +110CD G 1384.2931 2024.7 5 M1+E2 -0.44 2 0.000652 +110CD2 G KC=0.00056 2$LC=$MC= + diff --git a/HEN_HOUSE/spectra/lnhb/Al-26.txt b/HEN_HOUSE/spectra/lnhb/Al-26.txt new file mode 100644 index 000000000..fa375020c --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Al-26.txt @@ -0,0 +1,30 @@ + 26MG 26AL EC DECAY (717E3 Y) + 26MG T Auger electrons and ^X ray energies and emission intensities: + 26MG T {U Energy (keV)} {U Intensity } {U Line } + 26MG T + 26MG T 1.2536 0.160 6 XKA2 + 26MG T 1.2536 0.318 11 XKA1 + 26MG T + 26MG T + 26MG T + 26MG T + 26MG T 1.102-1.182 |] KLL AUGER + 26MG T 1.214-1.252 |] 16.22 22 ^KLX AUGER + 26MG T 1.301-1.301 |] KXY AUGER + 26MG T 0.0359-0.0359 0.0000022 18 L AUGER + 26AL P 0.0 5+ 717E3 Y 24 4004.19 6 + 26MG N 1.0 1.0 1 1.0 + 26MG L 0 0+ STABLE + 26MG L 1808.72 7 2+ 476 FS 12 + 26MG E 81.73 2115.51 1315.7 2U + 26MG2 E EAV=543.29 4$CK=0.915 4$CL=0.079 4$CM=0.0059 12$CN= $CO= + 26MG G 1808.65 7 99.76 4 E2 6330E-90 + 26MG2 G KC=5890E-9 0$LC=352E-9 0$MC= + 26MG L 2938.41 132+ 141 FS 8 + 26MG E 5.4E-7 4 2.74 2014.6 2U + 26MG2 E EAV=24.78 8$CK=0.915 4$CL=0.079 4$CM=0.0059 12$CN= $CO= + 26MG G 1129.67 102.5 2 M1+E2 -0.12 2 1250E-80 + 26MG2 G KC=1150E-8 0$LC=754E-9 0$MC= + 26MG G 2938 1 0.24 4 E2 2350E-90 + 26MG2 G KC=2160E-9 0$LC=149E-9 0$MC= + diff --git a/HEN_HOUSE/spectra/lnhb/Am-241.txt b/HEN_HOUSE/spectra/lnhb/Am-241.txt new file mode 100644 index 000000000..2e63a42b5 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Am-241.txt @@ -0,0 +1,416 @@ +237NP 241AM A DECAY (432.6 Y) +237NP H TYP=Update$AUT=V.P. Chechev. N.K. Kuzmenco$CUT=01-SEP-2010$ +237NP2 H TYP=update$AUT=Chechev$CUT= -- $ +237NP3 H TYP=Full$AUT=V.P. Chechev. N.K. Kuzmenco$CUT= -- $ +237NP C Evaluation history: Type=Update;Author=V.P. Chechev. N.K. Kuzmenco;Cutoff date=01-SEP-2010 +237NP2C Type=update;Author=Chechev;Cutoff date= -- +237NP3C Type=Full;Author=V.P. Chechev. N.K. Kuzmenco;Cutoff date= -- +237NP C References: 1952Be24, 1955Tu13, 1955Ja01, 1955Da02, 1956Ho38, 1955Go57, +237NP2C 1957Ro20, 1957Ma17, 1959Sa10, 1960As02, 1962LE11, 1964Wo03, 1964Ba26, +237NP3C 1965Mi06, 1965Be38, 1965Mc12, 1966Ya05, 1966Le13, 1967Pa23, 1967Gu08, +237NP4C 1967Br26, 1967Oe01, 1966Ko06, 1968St02, 1968Je01, 1968Br22, 1968Ba25, +237NP5C 1968Ka09, 1969Pe17, 1970Ne11, 1970Gr36, 1971Cl03, 1971Wa28, 1971Gr17, +237NP6C 1971Ka48, 1971Ge11, 1972Jo07, 1974HeYW, 1974Ga40, 1974Ca16, 1974StYG, +237NP7C 1974Po16, 1975Ra35, 1975Le09, 1976Pl05, 1976GuZN, 1978Ge06, 1978Ov01, +237NP8C 1978Ge17, 1979Ar11, 1982Ba56, 1983De11, 1983Hu04, 1983Ah02, 1984Ah06, +237NP9C 1984Ov02, 1987Bo25, 1987De22, 1988ChZL, 1988Co07, 1992Ma16, 1992Bl07, +237NP10C 1994Le37, 1994Bl12, 1995Ak01, 1996Jo28, 1998Ab43, 1998Ko61, 1998Ya17, +237NP11C 2000Ho27, 2000He14, 2001Sc08, 2003Au03, 2005Iw01, 2006Ba41, 2008Le07, +237NP12C 2008Go10, 2008Ki07 +237NP T Auger electrons and ^X ray energies and emission intensities: +237NP T {U Energy (keV)} {U Intensity } {U Line } +237NP T +237NP T 97.069 0.001134 30 XKA2 +237NP T 101.059 0.00181 5 XKA1 +237NP T +237NP T 113.303 |] XKB3 +237NP T 114.234 |] 0.000658 21 XKB1 +237NP T 114.912 |] XKB5II +237NP T +237NP T 117.463 |] XKB2 +237NP T 117.876 |] 0.000226 8 XKB4 +237NP T 118.429 |] XKO23 +237NP T +237NP T 11.89-22.2 37.66 17 XL (total) +237NP T 11.89 0.844 9 XLL +237NP T 13.76-13.944 13.02 10 XLA +237NP T 15.876 0.384 20 XLC +237NP T 16.13-17.79 18.58 13 XLB +237NP T 20.12-22.2 4.83 30 XLG +237NP T +237NP T 73.5-83.13 |] KLL AUGER +237NP T 90.36-97.28 |] 0.000114 16 ^KLX AUGER +237NP T 107.1-114.58 |] KXY AUGER +237NP T 6.04-13.52 33.4 17 L AUGER +241AM P 0.0 5/2- 432.6 Y 6 5637.82 12 +237NP N 1.0 1.0 1 1.0 +237NP G 32.183 0.0174 4 +237NP G 57.85 5 0.0052 15 +237NP G 106.42 5 1500E-8 0 +237NP G 128.05 +237NP G 136.7 +237NP G 156.4 3 +237NP G 190.4 2.2E-6 5 +237NP G 201.70 14800E-9 0 +237NP G 270.63 155E-7 2 +237NP G 271.54 1.44E-6 5 +237NP G 324.69 1.8E-6 3 +237NP G 329.69 1.1E-6 2 +237NP G 350.71 1.39E-6 5 +237NP G 374.83 3.13E-6 6 +237NP G 389.0 3 490E-9 0 +237NP G 390.61 5 5.73E-6 10 +237NP G 411.27 1.8E-7 4 +237NP G 429.9 1 1.09E-6 5 +237NP G 440.63 5.6E-7 3 +237NP G 442.81 7 3.31E-6 8 +237NP G 486.05 1.05E-6 6 +237NP G 494.39 1.0E-7 2 +237NP G 501.39 1.4E-7 2 +237NP G 525.14 1.6E-7 3 +237NP G 532.44 8E-8 2 +237NP G 548.15 5E-8 2 +237NP G 555.25 9E-8 2 +237NP G 582.89 1.01E-6 6 +237NP G 600.26 2.2E-7 3 +237NP G 636.9 2.1E-7 3 +237NP G 693.46 3.54E-6 8 +237NP G 709.42 5 6.41E-6 19 +237NP G 712.5 2.0E-7 3 +237NP G 731.44 4.6E-7 4 +237NP G 736.68 1.28E-6 5 +237NP G 740.51 1.9E-7 3 +237NP G 742.9 3 350E-9 0 +237NP G 745.02 9E-8 2 +237NP G 750.39 6E-8 2 +237NP G 759.5 1 1.81E-6 5 +237NP G 763.31 2.3E-7 2 +237NP G 774.67 1.1E-7 2 +237NP G 777.39 1.5E-7 2 +237NP G 780.53 3.1E-7 2 +237NP G 782.2 5 150E-9 0 +237NP G 789.0 3 4.2E-7 6 +237NP G 792.6 3E-8 1 +237NP G 794.92 20940E-9 0 +237NP G 803.19 1.6E-7 3 +237NP G 811.9 3 6.3E-7 6 +237NP G 819.33 4.3E-7 6 +237NP G 822.21 2.4E-7 6 +237NP G 835.21 3E-8 1 +237NP G 838.88 4E-8 1 +237NP G 841.14 1.0E-7 3 +237NP G 843.7 9.7E-7 8 +237NP G 846.86 1.6E-7 3 +237NP G 847.4 5 2.7E-7 3 +237NP G 851.6 104.1E-7 6 +237NP G 854.95 2.3E-7 4 +237NP G 856.26 1.0E-7 3 +237NP G 870.63 1.50E-6 4 +237NP G 882 4E-8 1 +237NP G 886.53 1.5E-7 3 +237NP G 890.38 3.2E-7 5 +237NP G 894.47 3E-8 1 +237NP G 898.17 6E-8 2 +237NP G 902.61 3.3E-7 3 +237NP G 909.95 5E-8 1 +237NP G 912.4 2.8E-7 3 +237NP G 928.95 9E-8 2 +237NP G 939.2 5E-8 1 +237NP G 952.72 3E-8 1 +237NP G 955.91 6.0E-7 5 +237NP G 969.09 3E-8 1 +237NP G 980.84 3E-8 1 +237NP L 0 5/2+ 2.144E6 Y 7 +237NP A 5544.11 120.38 1 610 +237NP L 33.19629 227/2+ 54 PS 24 +237NP A 5511.46 120.23 1 600 +237NP G 33.1963 3 0.1215 28M1+E2 0.13 3 175 24 +237NP2 G KC=$LC=131 17$MC=33 5 +237NP L 59.54092 105/2- 67 NS 2 +237NP A 5485.56 1284.45 101.3 +237NP G 26.3446 2 2.31 8 E1 8 2 +237NP2 G KC=$LC=6 2$MC=1.6 2 +237NP G 59.5409 1 35.92 17E1 1.16 7 +237NP2 G KC=$LC=0.84 6$MC=0.226 7 +237NP L 75.899 5 9/2+ 56 PS +237NP A 5469.47 120.04 2000 +237NP G 42.704 5 0.0055 11(M1+E2) 0.13 3 75 7 +237NP2 G KC=$LC=56 5$MC=13.9 14 +237NP G 75.90 1 6000E-7 0 (E2) 53.1 11 +237NP2 G KC=$LC=38.6 8$MC=10.76 22 +237NP L 102.959 3 7/2- 80 PS 40 +237NP A 5442.86 1213.23 104.3 +237NP G 27.06 1 +237NP G 43.420 3 0.0669 29M1+E2 0.45 5 180 23 +237NP2 G KC=$LC=132 17$MC=35 5 +237NP G 69.76 3 0.0029 4 (E1) 0.330 7 +237NP2 G KC=$LC=0.248 5$MC=0.0612 12 +237NP G 102.98 2 0.0195 4 E1 0.1189 24 +237NP2 G KC=$LC=0.0895 18$MC=0.0219 4 +237NP L 129.99 3 11/2+ +237NP A 5416.28 130.01 4000 +237NP G 54.09 3 +237NP G 96.79 3 4.7E-5 16 +237NP L 158.497 119/2- +237NP A 5388.25 131.66 3 16.4 +237NP G 55.56 2 0.0181 18M1+E2 0.46 4 65 6 +237NP2 G KC=$LC=48 4$MC=12.6 11 +237NP G 98.97 2 0.0203 4 E2 15.2 3 +237NP2 G KC=$LC=11.07 22$MC=3.08 6 +237NP G 125.30 2 0.0041 2 (E1) 0.299 6 +237NP2 G KC=0.228 5$LC=0.0538 11$MC=0.0132 3 +237NP L 191.53 6 13/2+ +237NP G 61.56 7 +237NP G 115.65 6 +237NP L 225.957 1611/2- +237NP A 5321.87 130.014 3 770 +237NP G 67.50 2 0.00042 10(M1+E2) 0.46 12 29 6 +237NP2 G KC=$LC=22 5$MC=5.7 13 +237NP G 123.05 1 0.00100 4 E2 5.75 12 +237NP2 G KC=0.184 4$LC=4.05 8$MC=1.127 23 +237NP G 150.04 3 7.3E-5 5 [E1] 0.197 4 +237NP2 G KC=0.152 3$LC=0.0339 7$MC=0.00827 17 +237NP L 267.556 123/2- 5.2 NS 2 +237NP A 5280.99 130.0005 12000 +237NP G 164.61 2 6.6E-5 3 E2 1.70 4 +237NP2 G KC=0.195 4$LC=1.095 22$MC=0.304 6 +237NP G 208.005 237.86E-4 9 M1+E2 0.156 5 2.98 6 +237NP2 G KC=2.35 5$LC=0.473 9$MC=0.1149 23 +237NP G 234.40 4 8.7E-7 8 M2 8.24 17 +237NP2 G KC=5.60 11$LC=1.95 4$MC=0.511 10 +237NP G 267.54 4 2.68E-5 6 E1+M2 0.490 15 1.06 6 +237NP2 G KC=0.74 4$LC=0.238 12$MC=0.062 2 +237NP L 281.356 181/2- +237NP G 13.81 2 M1+E2 0.0321 10 494 10 +237NP2 G KC=$LC=$MC=365 7 +237NP L 305.05 3 13/2- +237NP A 5244.13 130.0022 3 1600 +237NP G 79.05 3 +237NP G 146.55 3 0.00046 1 E2 2.73 6 +237NP2 G KC=0.210 4$LC=1.83 4$MC=0.51 1 +237NP G 175.07 4 1.8E-5 3 [E1] 0.137 3 +237NP2 G KC=0.1066 21$LC=0.0230 5$MC=0.00560 11 +237NP L 316.8 2 + +237NP A 5232.6 3 0 +237NP G 316.8 2 +237NP L 324.420 23(7/2)- +237NP A 5225.08 130.0013 2100 +237NP G 56.86 3 +237NP G 165.81 6 2.3E-5 1 [M1+E2] 3.7 22 +237NP2 G KC=2.4 22$LC=0.98 8$MC=0.26 4 +237NP G 221.46 3 4.34E-5 8 [M1+E2] 1.5 10 +237NP2 G KC=1.1 10$LC=0.35 5$MC=0.090 7 +237NP G 248.52 3 1.46E-6 3 [E1] 0.0612 12 +237NP2 G KC=0.0482 10$LC=0.00975 20$MC=0.00236 5 +237NP G 264.88 3 9.43E-6 12[M1+E2] 0.9 7 +237NP2 G KC=0.7 6$LC=0.19 5$MC=0.049 9 +237NP G 291.3 2 3.05E-6 8 [E1] 0.0430 9 +237NP2 G KC=0.0341 7$LC=0.00671 14$MC=0.00162 3 +237NP L 332.376 161/2+ 1 NS +237NP A 5217.26 130 +237NP G 51.01 3 2.6E-5 12E1 0.753 11 +237NP2 G KC=$LC=0.564 11$MC=0.141 3 +237NP G 64.83 2 0.00014 2 E1 0.400 8 +237NP2 G KC=$LC=0.301 6$MC=0.0744 15 +237NP G 332.35 3 1.50E-4 4 E2 0.147 3 +237NP2 G KC=0.0631 13$LC=0.0611 12$MC=0.0165 4 +237NP L 359.7 1 (5/2)- +237NP A 5190.17 230.0006 2700 +237NP G 92.35 20 +237NP G 300.13 6 +237NP L 368.602 205/2+ +237NP A 5181.63 130.0009 1600 +237NP G 292.77 6 1.42E-5 3 [E2] 0.215 4 +237NP2 G KC=0.0796 16$LC=0.0991 20$MC=0.0270 6 +237NP G 309.1 3 2.0E-6 3 [E1] 0.0377 8 +237NP2 G KC=0.0300 6$LC=0.00585 12$MC=0.00142 3 +237NP G 335.37 3 4.96E-4 7 M1+E2 0.46 17 0.69 8 +237NP2 G KC=0.54 7$LC=0.113 8$MC=0.0278 10 +237NP G 368.62 3 2.14E-4 5 (M1) 0.622 12 +237NP2 G KC=0.494 10$LC=0.0963 19$MC=0.0233 5 +237NP L 370.928 233/2+ +237NP A 5179.35 130.0003 4600 +237NP G 38.54 3 M1+E2 472.0000 +237NP2 G KC=$LC=94.0000 0$MC=345.000 0 +237NP G 337.7 2 4.88E-6 9 (E2) 0.140 3 +237NP2 G KC=0.0612 12$LC=0.0575 11$MC=0.0156 3 +237NP G 370.94 3 5.20E-5 8 M1+E2 0.43 21 0.53 7 +237NP2 G KC=0.42 6$LC=0.086 8$MC=0.0211 10 +237NP L 395.53 4 15/2- +237NP A 5155.12 130.0007 1400 +237NP G 169.56 3 0.00017 1 E2 1.51 3 +237NP2 G KC=0.189 4$LC=0.961 19$MC=0.267 6 +237NP G 204.06 6 2.06E-6 6 [E1] 0.0960 19 +237NP2 G KC=0.0752 15$LC=0.0157 3$MC=0.00382 8 +237NP L 418.2 1 + +237NP A 5132.8 2 0 +237NP L 434.12 5 (11/2)- +237NP A 5117.21 130.0004 1400 +237NP G 109.70 7 4900E-9 0 [E2] 9.44 19 +237NP2 G KC=$LC=6.86 14$MC=1.91 4 +237NP G 129.07 6 +237NP G 275.77 8 6.32E-6 10[M1+E2] 0.8 6 +237NP2 G KC=0.6 5$LC=0.17 5$MC=0.043 9 +237NP G 304.21 209.3E-7 2 [E1] 0.0391 8 +237NP2 G KC=0.0310 6$LC=0.00607 12$MC=0.00147 3 +237NP G 358.25 201.29E-6 5 [E1] 0.0275 6 +237NP2 G KC=0.0220 4$LC=0.00419 8$MC=0.00101 2 +237NP L 444.78 10 + +237NP A 5106.72 160 +237NP G 120.36 8 4500E-9 0 +237NP L 452.545 229/2+ +237NP A 5099.08 130.0004 1000 +237NP G 261.00 7 1.29E-6 6 [E2] 0.312 6 +237NP2 G KC=0.0979 20$LC=0.156 3$MC=0.0428 9 +237NP G 322.56 3 1.51E-4 4 (M1+E2) 0.6 0.702 12 +237NP2 G KC=0.541 8$LC=0.1204 17$MC=0.0297 5 +237NP G 376.65 3 1.37E-4 3 (M1) 0.586 12 +237NP2 G KC=0.466 9$LC=0.0908 18$MC=0.0220 5 +237NP G 419.33 4 2.84E-5 4 [M1+E2] 0.26 18 +237NP2 G KC=0.19 16$LC=0.047 21$MC=0.012 5 +237NP G 452.6 2 2.36E-6 7 [E2] 0.0635 13 +237NP2 G KC=0.0357 7$LC=0.0205 4$MC=0.00543 11 +237NP L 459.693 247/2+ +237NP A 5092.06 130.0004 1000 +237NP G 135.27 4 +237NP G 383.81 3 2.81E-5 6 [M1+E2] 0.33 23 +237NP2 G KC=0.25 20$LC=0.06 3$MC=0.015 6 +237NP G 426.47 4 3.1E-5 6 [M1+E2] 0.25 18 +237NP2 G KC=0.19 15$LC=0.045 20$MC=0.011 5 +237NP G 459.68 103.55E-6 7 [M1+E2] 0.20 14 +237NP2 G KC=0.15 12$LC=0.036 17$MC=0.009 4 +237NP L 486.21 9 (9/2)- +237NP A 5065.97 150.00011 2300 +237NP G 161.54 101500E-9 0 [M1] 6.20 12 +237NP2 G KC=4.91 10$LC=0.971 19$MC=0.236 5 +237NP G 260.22 9 +237NP L 497.01 5 17/2- +237NP A 5055.36 130 +237NP G 191.96 4 2.15E-5 10[E2] 0.932 19 +237NP2 G KC=0.162 3$LC=0.561 11$MC=0.155 3 +237NP L 514.19 4 (3/2)- +237NP G 154.27 20500E-9 0 [M1] 7.06 14 +237NP2 G KC=5.59 11$LC=1.108 22$MC=0.269 6 +237NP G 232.81 5 4.82E-6 9 [M1] 2.22 5 +237NP2 G KC=1.76 4$LC=0.345 7$MC=0.0837 17 +237NP G 246.73 102.44E-6 7 [M1] 1.88 4 +237NP2 G KC=1.49 3$LC=0.294 6$MC=0.0711 14 +237NP G 454.66 8 9.53E-6 12[M1] 0.351 7 +237NP2 G KC=0.279 6$LC=0.0542 11$MC=0.0131 3 +237NP G 514.0 5 3.8E-6 2 [E1] 1320E-50 +237NP2 G KC=0.0106 2$LC=0.00194 4$MC=0.00047 1 +237NP L 546.12 6 (5/2)- +237NP A 5007.07 140.0001 1000 +237NP G 31.92 8 +237NP G 264.76 7 +237NP G 278.04 151.15E-6 3 [M1] 1.35 3 +237NP2 G KC=1.072 21$LC=0.210 4$MC=0.0509 10 +237NP G 512.5 3 2.1E-6 4 [E1] 0.0133 3 +237NP2 G KC=0.0107 2$LC=0.00195 4$MC=0.00047 1 +237NP G 546.12 6 2.5E-7 3 [E1] 0.0117 2 +237NP2 G KC=0.00947 19$LC=0.00171 3$MC=0.00041 1 +237NP L 590.09 4 (7/2)- +237NP A 4963.83 130 +237NP G 322.52 4 +237NP G 487.13 4 6.2E-7 5 [M1] 0.291 6 +237NP2 G KC=0.232 6$LC=0.0449 9$MC=0.0109 2 +237NP G 590.09 4 2.80E-6 6 [E1] 0.0101 2 +237NP2 G KC=0.00818 16$LC=0.00147 3$MC=3.51E-4 7 +237NP L 592.33 7 13/2+ +237NP A 4961.63 140 +237NP G 139.44 8 5.3E-6 11[E2] 3.37 7 +237NP2 G KC=0.211 4$LC=2.29 5$MC=0.638 13 +237NP G 159.26 201.4E-6 5 [E1] 0.171 4 +237NP2 G KC=0.132 3$LC=0.0292 6$MC=0.00711 14 +237NP G 196.76 8 490E-9 0 [E1] 0.1045 21 +237NP2 G KC=0.0816 16$LC=0.0172 4$MC=0.00418 9 +237NP G 400.78 101.4E-7 3 [M1+E2] 0.29 21 +237NP2 G KC=0.22 18$LC=0.054 23$MC=0.013 6 +237NP G 462.34 8 1000E-9 0 [M1+E2] 0.20 14 +237NP2 G KC=0.15 12$LC=0.035 17$MC=0.009 4 +237NP L 597.99 9 11/2+ +237NP A 4956.06 150 +237NP G 138.30 9 +237NP G 406.35 151.37E-6 5 [M1+E2] 0.28 20 +237NP2 G KC=0.21 17$LC=0.052 22$MC=0.013 5 +237NP G 468.12 152.69E-6 6 [M1+E2] 0.19 14 +237NP2 G KC=0.15 12$LC=0.034 16$MC=0.008 4 +237NP G 522.06 159.9E-7 5 [M1+E2] 0.14 10 +237NP2 G KC=0.11 9$LC=0.025 13$MC=0.006 3 +237NP L 646.03 17(9/2)- +237NP G 586.59 201.24E-6 5 [E2] 0.0346 7 +237NP2 G KC=0.0224 4$LC=0.00903 18$MC=0.00235 5 +237NP L 666.19 10(5/2,7/2)+ +237NP A 4888.98 150 +237NP G 398.64 15 +237NP G 632.93 151.24E-6 5 +237NP G 666.2 2 9.5E-7 7 +237NP L 721.961 135/2- +237NP A 4834.15 130.0007 9.5 +237NP G 563.46 2 4.4E-7 2 [E2] 0.0378 8 +237NP2 G KC=0.0241 5$LC=0.0102 2$MC=0.00266 5 +237NP G 619.01 2 6.0E-5 2 [M1+E2] 0.09 7 +237NP2 G KC=0.07 5$LC=0.016 8$MC=0.0037 10 +237NP G 662.40 2 3.67E-4 6 (+M1+E2) 0.23 5 +237NP2 G KC=0.18 4$LC=0.045 15$MC= +237NP G 688.72 4 3.23E-5 6 [E1] 0.0075816 +237NP2 G KC=0.00615 12$LC=0.00108 2$MC=2.59E-4 5 +237NP G 721.96 2 1.96E-4 5 [E1] 0.0070 2 +237NP2 G KC=0.0056 1$LC=0.00099 2$MC=0.00024 1 +237NP L 755.685 197/2- +237NP A 4800.99 1386000E-9 44 +237NP G 597.19 2 7.29E-6 11[M1+E2] 0.10 7 +237NP2 G KC=0.08 6$LC=0.017 9$MC=0.0042 20 +237NP G 652.73 2 3.76E-5 9 [M1+E2] 0.08 6 +237NP2 G KC=0.06 5$LC=0.013 7$MC=0.0033 10 +237NP G 679.79 2 3.31E-6 8 [E1] 0.0077616 +237NP2 G KC=0.00630 13$LC=0.00111 2$MC=2.65E-4 5 +237NP G 696.14 2 5.17E-6 8 [M1+E2] 0.07 5 +237NP2 G KC=0.05 4$LC=0.011 6$MC=0.0028 10 +237NP G 755.68 2 7.84E-6 11[E1] 0.0064 1 +237NP2 G KC=0.0052 1$LC=0.00091 1$MC=2.17E-4 4 +237NP L 770.57 5 + +237NP G 446.15 6 1.1E-7 2 +237NP G 737.34 5 7.94E-6 11 +237NP G 770.57 104.81E-6 7 +237NP L 799.82 4 9/2- +237NP A 4757.58 130.00004 3 47 +237NP G 77.86 4 +237NP G 573.94 201.28E-6 5 [M1+E2] 0.11 8 +237NP2 G KC=0.09 7$LC=0.019 10$MC=0.0027 16 +237NP G 641.32 4 7.04E-6 10[M1+E2] 0.08 6 +237NP2 G KC=0.06 5$LC=0.014 8$MC=0.0035 10 +237NP G 669.83 2 5.1E-7 7 [E1] 0.0080 2 +237NP2 G KC=0.00647 13$LC=0.00114 2$MC=0.00073 1 +237NP G 766.62 4 5.01E-6 6 [E1] 0.0062312 +237NP2 G KC=0.00507 10$LC=0.00088 2$MC=2.11E-4 4 +237NP L 805.77 12(7/2,9/2)+ +237NP G 675.78 138.5E-7 5 [E2M1] 0.07 5 +237NP2 G KC=0.06 4$LC=0.012 7$MC=0.0030 15 +237NP G 729.72 151.37E-6 5 [M1] 0.099 2 +237NP2 G KC=0.079 2$LC=0.0151 4$MC=0.0036 1 +237NP G 772.57 122.79E-6 4 [M1] 0.0847 17 +237NP2 G KC=0.0675 14$LC=0.0129 3$MC=0.00312 6 +237NP G 805.77 12310E-9 0 [M1E2] 0.05 3 +237NP2 G KC=0.037 24$LC=0.008 4$MC=0.0019 10 +237NP L 853.36 1511/2- +237NP G 529.17 206.9E-7 5 [E2] 0.0437 9 +237NP2 G KC=0.0269 5$LC=0.0124 2$MC=0.00324 6 +237NP G 627.18 205.1E-7 2 [M1+E2] 0.09 6 +237NP2 G KC=0.07 5$LC=0.015 8$MC=0.0037 10 +237NP L 861.65 19(5/2,7/2)+ +237NP G 786.00 15620E-9 0 +237NP G 801.94 201.23E-6 7 +237NP G 828.60 122.1E-7 4 +237NP G 861.80 126.1E-7 6 +237NP L 920.88 20 + +237NP G 861.34 208E-8 3 +237NP G 887.68 203.3E-7 6 +237NP G 920.88 201.9E-7 3 +237NP L 946 2 + +237NP G 946.06 1.0E-8 2 +237NP L 962 3 + +237NP G 962.19 4E-8 1 +237NP L 1014 3 + +237NP G 1014.33 1.0E-6 2 + diff --git a/HEN_HOUSE/spectra/lnhb/Am-242.txt b/HEN_HOUSE/spectra/lnhb/Am-242.txt new file mode 100644 index 000000000..d0b26f48d --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Am-242.txt @@ -0,0 +1,83 @@ +242PU 242AM EC DECAY (16.01 H) +242PU H TYP=Full$AUT=A.L. Nichols$CUT=30-SEP-2008$ +242PU C Evaluation history: Type=Full;Author=A.L. Nichols;Cutoff date=30-SEP-2008 +242PU C References: 1953Ke38, 1955Ba31, 1955Ho67, 1959Ba22, 1959Ho02, 1960As05, +242PU2C 1961Ma27, 1969Al20, 1969Ga17, 1972Ga35, 1977La19, 1980VyZZ, 1982Wi05, +242PU3C 1996Sc06, 1998ScZM, 1999ScZX, 2002Ak06, 2002Ba85, 2002Ra45, 2003Au03, +242PU4C 2008Ki07 +242PU T Auger electrons and ^X ray energies and emission intensities: +242PU T {U Energy (keV)} {U Intensity } {U Line } +242PU T +242PU T 99.525 3.55 17 XKA2 +242PU T 103.734 5.6 3 XKA1 +242PU T +242PU T 116.244 |] XKB3 +242PU T 117.228 |] 2.06 11 XKB1 +242PU T 117.918 |] XKB5II +242PU T +242PU T 120.54 |] XKB2 +242PU T 120.969 |] 0.72 4 XKB4 +242PU T 121.543 |] XKO23 +242PU T +242PU T 12.124-22.153 10.8 5 XL (total) +242PU T 12.124 0.293 11 XLL +242PU T 14.087-14.282 4.56 16 XLA +242PU T 16.333 0.084 4 XLC +242PU T 16.498-18.541 4.64 15 XLB +242PU T 21.42-22.153 1.03 4 XLG +242PU T +242PU T 75.263-85.357 |] KLL AUGER +242PU T 92.607-103.729 |] 0.36 4 ^KLX AUGER +242PU T 109.93-121.78 |] KXY AUGER +242PU T 6.19-22.99 9.9 5 L AUGER +242AM P 0.0 1- 16.01 H 2 751.3 7 +242PU N 5.917E0 5.917E0 0.169 5.917E0 +242PU L 0 0 0+ 3.73E5 Y 3 +242PU E 6.3 6 7.55 1 +242PU2 E EAV= $CK=0.7303 22$CL=0.1987 15$CM=0.0522 10$CN= $CO= +242PU L 44.54 2 2+ +242PU E 10.6 5 7.26 1 +242PU2 E EAV= $CK=0.7261 23$CL=0.2016 15$CM=0.0532 10$CN=0.0152 7$CO= +242PU G 44.54 2 0.014 1 E2 748 11 +242PU2 G KC=$LC=543 8$MC=151.6 22 + +242CM 242AM B- DECAY (16.01 H) +242CM H TYP=Full$AUT=A.L. Nichols$CUT=30-SEP-2008$ +242CM C Evaluation history: Type=Full;Author=A.L. Nichols;Cutoff date=30-SEP-2008 +242CM C References: 1953Ke38, 1955Ba31, 1955Ho67, 1959Ba22, 1959Ho02, 1960As05, +242CM2C 1961Ma27, 1969Al20, 1969Ga17, 1972Ga35, 1977La19, 1980VyZZ, 1982Wi05, +242CM3C 1996Sc06, 1998ScZM, 1999ScZX, 2002Ak06, 2002Ba85, 2002Ra45, 2003Au03, +242CM4C 2008Ki07 +242CM T Auger electrons and ^X ray energies and emission intensities: +242CM T {U Energy (keV)} {U Intensity } {U Line } +242CM T +242CM T 104.59 XKA2 +242CM T 109.271 XKA1 +242CM T +242CM T 122.304 |] XKB3 +242CM T 123.403 |] XKB1 +242CM T 124.124 |] XKB5II +242CM T +242CM T 126.889 |] XKB2 +242CM T 127.352 |] XKB4 +242CM T 127.97 |] XKO23 +242CM T +242CM T 12.633-23.527 18.0 11 XL (total) +242CM T 12.633 0.451 22 XLL +242CM T 14.746-14.961 6.8 3 XLA +242CM T 17.314 0.194 11 XLC +242CM T 17.286-19.688 8.7 4 XLB +242CM T 22.735-23.527 2.09 10 XLG +242CM T +242CM T 6.19-14.46 15.4 10 L AUGER +242AM P 0.0 1- 16.01 H 2 664.5 4 +242CM N 1.203E0 1.203E0 0.831 1.203E0 +242CM L 0 0+ 162.86 D 8 +242CM B 664.5 4 37.3 23 7.03 1 +242CMS B EAV=200.17 14 +242CM L 42.13 5 2+ +242CM B 622.4 4 45.8 23 6.84 1 +242CMS B EAV=185.92 14 +242CM G 42.13 5 0.040 2 E2 1155 17 +242CM2 G KC=$LC=836 13$MC=235 4 + diff --git a/HEN_HOUSE/spectra/lnhb/Am-242m.txt b/HEN_HOUSE/spectra/lnhb/Am-242m.txt new file mode 100644 index 000000000..9dd66bd43 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Am-242m.txt @@ -0,0 +1,257 @@ +242AM 242AM IT DECAY (143 Y) +242AM H TYP=Full$AUT=A. Nichols$CUT=30-APR-2010$ +242AM C Evaluation history: Type=Full;Author=A. Nichols;Cutoff date=30-APR-2010 +242AM C References: 1950St61, 1959Ba22, 1960As05, 1967Ca04, 1977La19, 1979Ba67, +242AM2C 1979Ze05, 1980VyZZ, 1986Ze06, 1990Ho02, 1996Sc06, 1998Ak04, 1998ScZM, +242AM3C 1999ScZX, 2002Ak06, 2002Ba25, 2002Ch52, 2002Ra45, 2003Au03, 2008Ki07 +242AM T Auger electrons and ^X ray energies and emission intensities: +242AM T {U Energy (keV)} {U Intensity } {U Line } +242AM T +242AM T 102.03 XKA2 +242AM T 106.472 XKA1 +242AM T +242AM T 119.243 |] XKB3 +242AM T 120.284 |] XKB1 +242AM T 120.989 |] XKB5II +242AM T +242AM T 123.58 |] XKB2 +242AM T 124.127 |] XKB4 +242AM T 124.723 |] XKO23 +242AM T +242AM T 12.377-22.836 25.0 11 XL (total) +242AM T 12.377 0.608 18 XLL +242AM T 14.414-14.62 9.33 24 XLA +242AM T 16.819 0.274 9 XLC +242AM T 16.89-19.11 12.2 3 XLB +242AM T 22.072-22.836 2.90 8 XLG +242AM T +242AM T 77.04-85.638 |] KLL AUGER +242AM T 94.891-106.467 |] ^KLX AUGER +242AM T 112.72-124.97 |] KXY AUGER +242AM T 6.26-23.7 22.1 11 L AUGER +242AM P 48.60 5 5- 143 Y 2 +242AM N 1.005E0 1.005E0 0.9954 1.005E0 +242AM G 89.60 5 0.0013 3 +242AM G 160.61 2 0.00041 18 +242AM G 165.97 154.6E-5 23 +242AM G 233.69 100.00013 3 +242AM L 0 1- 16.01 H 2 +242AM L 48.60 5 5- 143 Y 2 +242AM G 48.60 5 1414E-7 22E4 7.04E5 8 +242AM2 G KC=$LC=3.33E5 5$MC=2.66E5 5 + +238NP 242AM A DECAY (143 Y) +238NP H TYP=Full$AUT=A. Nichols$CUT=30-APR-2010$ +238NP C Evaluation history: Type=Full;Author=A. Nichols;Cutoff date=30-APR-2010 +238NP C References: 1950St61, 1959Ba22, 1960As05, 1967Ca04, 1977La19, 1979Ba67, +238NP2C 1979Ze05, 1980VyZZ, 1986Ze06, 1990Ho02, 1996Sc06, 1998Ak04, 1998ScZM, +238NP3C 1999ScZX, 2002Ak06, 2002Ba25, 2002Ch52, 2002Ra45, 2003Au03, 2008Ki07 +238NP T Auger electrons and ^X ray energies and emission intensities: +238NP T {U Energy (keV)} {U Intensity } {U Line } +238NP T +238NP T 97.069 0.019 9 XKA2 +238NP T 101.059 0.030 14 XKA1 +238NP T +238NP T 113.303 |] XKB3 +238NP T 114.234 |] 0.011 5 XKB1 +238NP T 114.912 |] XKB5II +238NP T +238NP T 117.463 |] XKB2 +238NP T 117.876 |] 0.0037 17 XKB4 +238NP T 118.429 |] XKO23 +238NP T +238NP T 11.871-21.491 0.37 4 XL (total) +238NP T 11.871 0.0090 9 XLL +238NP T 13.761-13.946 0.143 13 XLA +238NP T 15.861 0.0022 4 XLC +238NP T 16.109-17.992 0.164 13 XLB +238NP T 20.784-21.491 0.040 3 XLG +238NP T +238NP T 73.501-83.134 |] KLL AUGER +238NP T 90.358-101.054 |] 0.0019 7 ^KLX AUGER +238NP T 107.19-118.66 |] KXY AUGER +238NP T 6.036-13.516 0.35 4 L AUGER +242AM P 48.60 5 5- 143 Y 2 5588.50 25 +238NP N 2.174E2 2.174E2 0.0046 2.174E2 +238NP G 89.60 5 0.0013 3 +238NP G 160.61 2 0.00041 18 +238NP G 165.97 154.6E-5 23 +238NP G 233.69 100.00013 3 +238NP L 0 2+ 2.102 D 5 +238NP L 26.427 2 3+ +238NP A 5517.93 250.003 3 4000000 +238NP G 26.427 2 7080E-7 0 M1+E2 0.1 338 5 +238NP2 G KC=$LC=252 4$MC=63.7 9 +238NP L 62.330 4 4+ +238NP L 86.674 2 3+ +238NP A 5458.68 250.139 3939000 +238NP G 24.34 1 6.4E-5 9 M1+E2 0.01 322 5 +238NP2 G KC=$LC=242 4$MC=59.6 9 +238NP G 60.247 3 0.0055 5 M1+E2 0.07 23.1 4 +238NP2 G KC=$LC=17.34 25$MC=4.23 6 +238NP G 86.674 2 0.0229 7 M1+E2 0.1 7.95 12 +238NP2 G KC=$LC=5.98 9$MC=1.459 21 +238NP L 106.155 155+ +238NP L 121.645 9 4+ +238NP L 136.045 2 3- 6 NS +238NP A 5410.13 251.0 2 2820 +238NP G 49.371 3 0.134 4 E1 0.821 12 +238NP2 G KC=$LC=0.615 9$MC=0.1536 22 +238NP G 73.72 1 0.0079 6 E1 0.285 4 +238NP2 G KC=$LC=0.214 3$MC=0.0529 8 +238NP G 109.618 3 1840E-5 0 E1 0.1010 15 +238NP2 G KC=$LC=0.0760 11$MC=0.0186 3 +238NP G 136.045 2 0.0094 3 E1 0.247 4 +238NP2 G KC=0.190 3$LC=0.0436 6$MC=0.01064 15 +238NP L 161.69 2 6+ +238NP L 165.532 155+ +238NP G 139.11 2 1100E-7 0 E2 3.40 5 +238NP2 G KC=0.211 3$LC=2.32 4$MC=0.646 9 +238NP L 179.154 7 4- +238NP A 5367.73 251.11 201430 +238NP G 43.11 1 6.4E-5 14M1+E2 0.045 61.3 9 +238NP2 G KC=$LC=46.1 7$MC=11.25 16 +238NP G 57.51 1 0.00097 23E1 0.549 8 +238NP2 G KC=$LC=0.412 6$MC=0.1023 15 +238NP G 92.48 1 0.0028 3 E1 0.1574 22 +238NP2 G KC=$LC=0.1184 17$MC=0.0291 4 +238NP G 152.73 1 6900E-7 0 E1 0.189 3 +238NP2 G KC=0.1457 21$LC=0.0324 5$MC=0.00791 11 +238NP L 182.878 2 2- +238NP G 46.833 3 7.4E-6 14M1+E2 0.063 48.8 7 +238NP2 G KC=$LC=36.7 6$MC=8.97 13 +238NP G 156.451 3 0.00027 5 E1 0.1784 25 +238NP2 G KC=0.1379 20$LC=0.0305 5$MC=0.00744 11 +238NP G 182.878 2 0.00092 3 E1 0.1238 18 +238NP2 G KC=0.0965 14$LC=0.0206 3$MC=0.00502 7 +238NP L 215.522 4 3- +238NP A 5331.97 250.15 116400 +238NP G 32.64 1 1.9E-5 3 M1+E2 0.014 136.4 20 +238NP2 G KC=$LC=102.6 15$MC=25.0 4 +238NP G 79.48 1 1.24E-4 23M1+E2 1.0 2 26 4 +238NP2 G KC=$LC=19 3$MC=5.2 8 +238NP G 93.88 1 0.0036 4 E1 0.1513 22 +238NP2 G KC=$LC=0.1138 16$MC=0.0280 4 +238NP G 153.19 1 0.00031 4 E1 0.187 3 +238NP2 G KC=0.1447 21$LC=0.0322 5$MC=0.00785 11 +238NP G 189.10 1 0.00027 5 E1 0.1146 16 +238NP2 G KC=0.0894 13$LC=0.0190 3$MC=0.00462 7 +238NP G 215.522 4 0.00059 10E1 0.0847 12 +238NP2 G KC=0.0664 10$LC=0.01376 20$MC=0.00334 5 +238NP L 218.7 6 (6)+ +238NP L 232.828 8 5- +238NP A 5314.95 250.61 111250 +238NP G 53.67 1 0.0021 3 M1+E2 0.25 46.0 7 +238NP2 G KC=$LC=34.2 5$MC=8.73 13 +238NP G 96.78 1 0.00033 6 E2 16.90 24 +238NP2 G KC=$LC=12.28 18$MC=3.42 5 +238NP G 111.18 1 0.0025 4 E1 0.0974 14 +238NP2 G KC=$LC=0.0733 11$MC=0.0180 3 +238NP L 250.33 3 (1)+ +238NP G 250.33 3 5600E-7 0 (M1+E2) 1.0 2 1.08 16 +238NP2 G KC=0.77 15$LC=0.233 12$MC=0.0595 21 +238NP L 258.853 8 4- +238NP G 43.33 1 8.7E-6 14M1+E2 0.32 126.7 18 +238NP2 G KC=$LC=93.5 14$MC=24.6 4 +238NP G 75.98 1 9.7E-6 14E2 52.8 8 +238NP2 G KC=$LC=38.4 6$MC=10.70 15 +238NP G 122.81 1 0.00004 2 M1+E2 1.0 2 9.6 9 +238NP2 G KC=5.4 12$LC=3.11 22$MC=0.83 7 +238NP G 152.70 2 6900E-7 0 E1 0.189 3 +238NP2 G KC=0.1458 21$LC=0.0325 5$MC=0.00791 11 +238NP G 196.52 1 0.00010 5 E1 0.1048 15 +238NP2 G KC=0.0819 12$LC=0.01725 25$MC=0.00419 6 +238NP G 232.43 1 0.00056 3 E1 0.0712 10 +238NP2 G KC=0.0560 8$LC=0.01145 16$MC=0.00278 4 +238NP L 275.519 9 5+ +238NP A 5272.96 251.00 11414 +238NP G 153.87 1 0.00332 10M1+E2 0.14 7.02 10 +238NP2 G KC=5.53 8$LC=1.123 16$MC=0.273 4 +238NP G 213.19 1 5.5E-5 18M1+E2 1.0 2 1.73 25 +238NP2 G KC=1.19 24$LC=0.401 11$MC=0.1032 17 +238NP L 297.03 5 (6)- +238NP A 5251.80 250.020 1115300 +238NP G 131.50 5 0.00027 6 E1 0.268 4 +238NP2 G KC=0.205 3$LC=0.0475 7$MC=0.01161 17 +238NP G 190.88 5 1.06E-4 24E1 0.1121 16 +238NP2 G KC=0.0875 13$LC=0.0185 3$MC=0.00451 7 +238NP L 299.23 6 (3)+ +238NP A 5249.64 260.020 1114800 +238NP G 236.90 6 4.6E-5 23M1+E2 1.0 2 1.27 19 +238NP2 G KC=0.89 18$LC=0.280 12$MC=0.0717 21 +238NP G 272.80 6 3.7E-5 8 M1+E2 1.0 2 0.85 13 +238NP2 G KC=0.61 12$LC=0.176 11$MC=0.0448 21 +238NP G 299.23 6 2.8E-5 14M1+E2 1.0 2 0.65 10 +238NP2 G KC=0.48 9$LC=0.131 9$MC=0.0332 19 +238NP L 300.68 7 (1 to 4)- +238NP A 5248.21 260.39 11730 +238NP G 85.16 7 0.0010 3 M1+E2 1.0 2 19 3 +238NP2 G KC=$LC=14.3 18$MC=3.9 6 +238NP G 238.35 7 1.6E-5 8 E1 0.0673 10 +238NP2 G KC=0.0530 8$LC=0.01078 16$MC=0.00261 4 +238NP L 300.743 16(6)- +238NP A 5248.15 250.39 11730 +238NP G 67.92 2 0.0040 3 M1+E2 0.35 6 24 3 +238NP2 G KC=$LC=17.7 19$MC=4.6 6 +238NP G 135.21 2 0.0068 4 E1 0.251 4 +238NP2 G KC=0.192 3$LC=0.0443 7$MC=0.01081 16 +238NP G 139.05 3 1100E-7 0 E1 0.235 4 +238NP2 G KC=0.180 3$LC=0.0412 6$MC=0.01006 15 +238NP G 194.59 2 0.00142 5 E1 0.1072 15 +238NP2 G KC=0.0837 12$LC=0.01768 25$MC=0.00430 6 +238NP L 312.70 2 5- +238NP G 53.85 2 2.8E-6 14M1+E2 0.16 37.2 6 +238NP2 G KC=$LC=27.8 4$MC=6.93 10 +238NP G 97.18 2 7E-6 4 E2 16.58 24 +238NP2 G KC=$LC=12.05 17$MC=3.36 5 +238NP G 151.01 3 8.3E-5 18E1 0.194 3 +238NP2 G KC=0.1495 21$LC=0.0334 5$MC=0.00814 12 +238NP G 176.66 2 2.8E-5 14E2 1.285 18 +238NP2 G KC=0.181 3$LC=0.804 12$MC=0.223 4 +238NP G 250.37 2 5600E-7 0 E1 0.0602 9 +238NP2 G KC=0.0475 7$LC=0.00958 14$MC=0.00232 4 +238NP L 328.6 5 6+ +238NP G 163.1 5 1610E-5 0 M1+E2 1.0 2 3.9 5 +238NP2 G KC=2.5 5$LC=1.04 3$MC=0.273 11 +238NP L 334.0 6 (1 to 3)- +238NP A 5215.4 7 0.030 116000 +238NP L 342.439 8 5- +238NP A 5207.15 2588.9 201.8 +238NP G 66.92 1 0.0150 5 E1 0.368 6 +238NP2 G KC=$LC=0.277 4$MC=0.0684 10 +238NP G 109.61 1 1840E-5 0 M1+E2 1.0 2 6.7 7 +238NP2 G KC=$LC=4.9 5$MC=1.32 14 +238NP G 126.92 1 0.00013 7 E2 5.03 7 +238NP2 G KC=0.196 3$LC=3.51 5$MC=0.979 14 +238NP G 163.29 1 1610E-5 0 M1+E2 1.0 2 3.9 5 +238NP2 G KC=2.5 5$LC=1.04 3$MC=0.272 11 +238NP G 206.39 1 0.00156 18E2 0.711 10 +238NP2 G KC=0.1454 21$LC=0.412 6$MC=0.1138 16 +238NP G 280.11 1 6.0E-5 6 E1 0.0468 7 +238NP2 G KC=0.0371 6$LC=0.00735 11$MC=0.00178 3 +238NP L 374.7 10(5)+ +238NP A 5175.4 100.020 115000 +238NP L 376.70 7 (6)- +238NP A 5173.45 260.020 114900 +238NP G 270.55 7 2.9E-5 8 E1 0.0506 7 +238NP2 G KC=0.0400 6$LC=0.00798 12$MC=0.00193 3 +238NP L 389.4 5 7+ +238NP G 170.7 8 0.00063 5 M1+E2 1.0 2 3.4 5 +238NP2 G KC=2.2 5$LC=0.882 23$MC=0.230 9 +238NP L 397.3 15 + +238NP A 5153.2 150.020 113600 +238NP L 407.59 6 6- +238NP A 5143.07 265.61 2411.2 +238NP G 174.76 6 0.00017 4 M1+E2 1.0 2 3.1 4 +238NP2 G KC=2.1 5$LC=0.809 17$MC=0.211 7 +238NP L 459.6 6 (6)+ +238NP A 5091.9 7 0.20 7 146 +238NP L 469.1 12(1 to 4)- +238NP A 5082.6 120.030 11840 +238NP L 484 3 7- +238NP A 5068 3 0.26 7 81 +238NP L 525.3 15(7)+ +238NP A 5027.3 150.020 11540 +238NP L 578 3 + +238NP A 4975 3 0.0020 112400 + diff --git a/HEN_HOUSE/spectra/lnhb/Am-243.txt b/HEN_HOUSE/spectra/lnhb/Am-243.txt new file mode 100644 index 000000000..245a7cadc --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Am-243.txt @@ -0,0 +1,88 @@ +239NP 243AM A DECAY (7367 Y) +239NP H TYP=Update$AUT=M.M. Bé$CUT=30-APR-2009$ +239NP C Evaluation history: Type=Update;Author=M.M. Bé;Cutoff date=30-APR-2009 +239NP C References: 2004BeZQ, 1977La19, 1998Ya17, 2007Ag02, 2008Ki07 +239NP T Auger electrons and ^X ray energies and emission intensities: +239NP T {U Energy (keV)} {U Intensity } {U Line } +239NP T +239NP T 97.069 0.0058 4 XKA2 +239NP T 101.059 0.0092 7 XKA1 +239NP T +239NP T 113.303 |] XKB3 +239NP T 114.234 |] 0.00335 25 XKB1 +239NP T 114.912 |] XKB5II +239NP T +239NP T 117.463 |] XKB2 +239NP T 117.876 |] 0.00115 9 XKB4 +239NP T 118.429 |] XKO23 +239NP T +239NP T 11.871-21.491 18.9 7 XL (total) +239NP T 11.871 0.465 25 XLL +239NP T 13.671-13.946 7.4 4 XLA +239NP T 15.861 0.143 10 XLC +239NP T 16.109-17.992 8.7 4 XLB +239NP T 20.784-21.491 2.10 9 XLG +239NP T +239NP T 73.501-83.134 |] KLL AUGER +239NP T 90.358-101.054 |] 0.00058 9 ^KLX AUGER +239NP T 107.19-118.66 |] KXY AUGER +239NP T 6.04-13.52 18.4 11 L AUGER +243AM P 0.0 5/2- 7367 Y 23 5438.8 10 +239NP N 1.0 1.0 1 1.0 +239NP L 0 5/2+ 2.356 D 3 +239NP A 5349.4 230.240 3 1120 +239NP L 31.130 217/2+ +239NP A 5321 1 0.192 3 95 +239NP G 31.14 3 0.048 11M1+E2 0.17 1 263 13 +239NP2 G KC=$LC=195 10$MC=50 3 +239NP L 71 9/2+ +239NP L 74.660 185/2- 1.39 NS 3 +239NP A 5275.3 1086.74 5 1.14 +239NP G 43.53 2 5.89 10E1 1.143 16 +239NP2 G KC=$LC=0.856 12$MC=0.215 3 +239NP G 74.66 2 67.2 12E1 0.276 4 +239NP2 G KC=$LC=0.207 3$MC=0.0512 8 +239NP L 117.84 3 7/2- 0.04 NS +239NP A 5233.3 1011.46 5 4.71 +239NP G 43.1 6500E-5 0 M1+E2 0.38 4 154 18 +239NP2 G KC=$LC=114 13$MC=30 4 +239NP G 86.71 2 0.346 9 E1 0.186 3 +239NP2 G KC=$LC=0.1401 20$MC=0.0345 5 +239NP G 117.60 150.57 5 E1 0.0842 13 +239NP2 G KC=$LC=0.0634 10$MC=0.01551 23 +239NP L 122.4 10(11/2)+ +239NP L 173.02 4 9/2- +239NP A 5181 1 1.383 7 17.7 +239NP G 50.6 100.0062 10(E1) 0.77 5 +239NP2 G KC=$LC=0.58 4$MC=0.144 9 +239NP G 55.18 5 0.0168 11M1+E2 0.75 10 107 14 +239NP2 G KC=$LC=78 10$MC=21 3 +239NP G 98.5 2 0.0151 21(E2) 15.6 3 +239NP2 G KC=$LC=11.31 20$MC=3.15 6 +239NP G 141.90 6 0.115 8 E1 0.224 4 +239NP2 G KC=0.1723 25$LC=0.0391 6$MC=0.00955 14 +239NP L 240 (11/2)- +239NP A 5113 1 0.010 1 900 +239NP G 169 1200E-6 0 (E1) 0.149 3 +239NP2 G KC=0.1156 23$LC=0.0251 6$MC=0.00612 13 +239NP L 267 3 (5/2)+ +239NP A 5088 5 0.0055 6 1100 +239NP L 317.4 15(13/2)- +239NP A 5035 3 0.0020 6 +239NP G 195.0 188500E-7 0 (E1) 0.107 3 +239NP2 G KC=0.0833 22$LC=0.0176 5$MC=0.00428 12 +239NP L 325 3 (5/2)- +239NP A 5029 3 0.0020 6 700 +239NP L 347 3 (7/2,9/2)+ +239NP A 5008 3 0.0009 4 +239NP L 359 3 (9/2)+ +239NP A 4997 3 0.0009 4 900 +239NP L 411 3 + +239NP A 4946 3 0.00034 2000 +239NP L 427 3 + +239NP A 4930 3 0.00018 3000 +239NP L 438 3 (11/2)+ +239NP A 4919 3 85000E-9 5400 +239NP L 662 3 (5/2)- +239NP A 4695 3 0.0017 5 7.2 + diff --git a/HEN_HOUSE/spectra/lnhb/Am-244.txt b/HEN_HOUSE/spectra/lnhb/Am-244.txt new file mode 100644 index 000000000..7c3d13dab --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Am-244.txt @@ -0,0 +1,55 @@ +244CM 244AM B- DECAY (10.1 H) +244CM H TYP=Full$AUT=A.L. Nichols$CUT=28-FEB-2009$ +244CM C Evaluation history: Type=Full;Author=A.L. Nichols;Cutoff date=28-FEB-2009 +244CM C References: 1962Va08, 1963Ha29, 1967Sc34, 1977La19, 1984Ho02, 1996Sc06, +244CM2C 1998ScZM, 1999ScZX, 2002Ra45, 2002Ba25, 2003Au03, 2003Ak04, 2008Ki07 +244CM T Auger electrons and ^X ray energies and emission intensities: +244CM T {U Energy (keV)} {U Intensity } {U Line } +244CM T +244CM T 104.59 2.2 3 XKA2 +244CM T 109.271 3.4 4 XKA1 +244CM T +244CM T 122.304 |] XKB3 +244CM T 123.403 |] 1.29 16 XKB1 +244CM T 124.124 |] XKB5II +244CM T +244CM T 126.889 |] XKB2 +244CM T 127.352 |] 0.45 6 XKB4 +244CM T 127.97 |] XKO23 +244CM T +244CM T 12.633-23.527 100 10 XL (total) +244CM T 12.633 2.36 24 XLL +244CM T 14.746-14.961 36 4 XLA +244CM T 17.314 1.15 15 XLC +244CM T 17.286-19.688 51 5 XLB +244CM T 22.735-23.527 12 13 XLG +244CM T +244CM T 78.858-89.973 |] KLL AUGER +244CM T 97.226-109.267 |] 0.213 27 ^KLX AUGER +244CM T 115.57-128.23 |] KXY AUGER +244CM T 6.19-14.46 86 9 L AUGER +244AM P 0.0 6- 10.1 H 1 1427.3 10 +244CM N 1.0 1.0 1 1.0 +244CM L 0 0+ 18.11 Y 3 +244CM L 42.965 102+ +244CM G 42.965 100.096 20E2 1050 15 +244CM2 G KC=$LC=760 11$MC=214 3 +244CM L 142.348 114+ +244CM G 99.383 4 5.0 11E2 19.3 3 +244CM2 G KC=$LC=13.93 20$MC=3.94 6 +244CM L 296.211 116+ +244CM G 153.863 2 19 4 E2 2.81 4 +244CM2 G KC=0.1741 25$LC=1.90 3$MC=0.536 8 +244CM L 501.786 128+ +244CM G 205.575 4 0.35 8 E2 0.887 13 +244CM2 G KC=0.1409 20$LC=0.541 8$MC=0.1514 22 +244CM L 1040.188 126+ 34 MS 2 +244CM B 387.1 10100 5.63 +244CMS B EAV=109.6 3 +244CM G 538.402 160.66 19E2 0.0495 7 +244CM2 G KC=0.0292 4$LC=0.01492 21$MC=0.00396 6 +244CM G 743.977 5 66 8 M1+E2 -0.92 8 0.077 5 +244CM2 G KC=0.059 4$LC=0.0130 7$MC=0.00321 15 +244CM G 897.840 7 28 8 E2 0.0169724 +244CM2 G KC=0.01215 17$LC=0.00358 5$MC=9.12E-4 13 + diff --git a/HEN_HOUSE/spectra/lnhb/Am-244m.txt b/HEN_HOUSE/spectra/lnhb/Am-244m.txt new file mode 100644 index 000000000..7802dfde8 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Am-244m.txt @@ -0,0 +1,98 @@ +244PU 244AM EC DECAY (26 M) +244PU C References: 1950St61, 1954Gh24, 1955Fi36, 1962Va08, 1964Va04, 1976Ga31, +244PU2C 1977La19, 1984Vo07, 1984Ho02, 1996Sc06, 1998ScZM, 1999SzZX, 2002Ra45, +244PU3C 2002Ba85, 2003Ak04, 2003Au03, 2008Ki07 +244PU T Auger electrons and X ray energies and emission intensities: +244PU T {U Energy (keV)} {U Intensity} {U Line} +244PU T +244PU T 99.525 XKA2 +244PU T 103.734 XKA1 +244PU T +244PU T 116.244 |] XKB3 +244PU T 117.228 |] XKB1 +244PU T 117.918 |] XKB5II +244PU T +244PU T 120.54 |] XKB2 +244PU T 120.969 |] XKB4 +244PU T 121.543 |] XKO23 +244PU T +244PU T +244PU T 75.263-85.357 |] KLL AUGER +244PU T 92.607-103.729 |] 2.53E-4 45 KLX AUGER +244PU T 109.93-121.78 |] KXY AUGER +244PU T 6.19-22.99 0.0124 11 L AUGER +244AM P 89 2 0+ 26 M 3 75 9 +244PU N 2.778E3 2.778E3 0.00036 2.778E3 +244PU L 0 0+ STABLE +244PU E 0.036 1 6.37 +244PU2 E EAV= $CK=0.24 5$CL=0.53 4$CM=0.168 12$CN=0.050 4$CO= + +244CM 244AM B- DECAY (26 M) +244CM C References: 1950St61, 1954Gh24, 1955Fi36, 1962Va08, 1964Va04, 1976Ga31, +244CM2C 1977La19, 1984Vo07, 1984Ho02, 1996Sc06, 1998ScZM, 1999SzZX, 2002Ra45, +244CM3C 2002Ba85, 2003Ak04, 2003Au03, 2008Ki07 +244CM T Auger electrons and X ray energies and emission intensities: +244CM T {U Energy (keV)} {U Intensity} {U Line} +244CM T +244CM T 104.59 0.013 4 XKA2 +244CM T 109.271 0.020 6 XKA1 +244CM T +244CM T 122.304 |] XKB3 +244CM T 123.403 |] 0.0076 21 XKB1 +244CM T 124.124 |] XKB5II +244CM T +244CM T 126.889 |] XKB2 +244CM T 127.352 |] 0.0027 8 XKB4 +244CM T 127.97 |] XKO23 +244CM T +244CM T 12.633-23.527 12.3 27 XL (total) +244CM T 12.633 0.31 8 XLL +244CM T 14.746-14.961 4.6 11 XLA +244CM T 17.314 0.13 4 XLC +244CM T 17.286-19.688 6.0 14 XLB +244CM T 22.735-23.527 1.4 4 XLG +244CM T +244CM T 78.858-89.973 |] KLL AUGER +244CM T 97.226-109.267 |] 0.00125 27 KLX AUGER +244CM T 115.57-128.23 |] KXY AUGER +244CM T 6.19-14.46 10.6 23 L AUGER +244AM P 89 2 0+ 26 M 3 1427.0 36 +244CM N 1.00E0 1.00E0 0.99964 1.00E0 +244CM L 0 0+ STABLE +244CM B 1516 3 67 9 6.45 +244CMS B EAV=512.3 9 +244CM L 42.965 102+ +244CM B 1473 3 31 9 6.74 2 +244CMS B EAV=495.8 9 +244CM G 42.965 100.030 9 E2 1050 15 +244CM2 G KC=$LC=760 11$MC=214 3 +244CM L 142.348 114+ +244CM L 296.211 116+ +244CM L 501.786 128+ +244CM L 970 4 (2+, 3-)+ +244CM L 984.914 210+ +244CM B 531.1 301.36 16 6.58 +244CMS B EAV=155.7 7 +244CM G 941.95 3 0.35 12E2 0.0154722 +244CM2 G KC=0.01120 16$LC=0.00318 5$MC=8.07E-4 12 +244CM G 984.91 2 +244CM L 1020.76 3 (2)+ +244CM B 496 3 0.08 2 7.7 2 +244CMS B EAV=144.0 7 +244CM G 977.80 4 (+M1+E2) +244CM L 1038 6 (2+, 3-)+ +244CM L 1040.188 126+ +244CM L 1084.181 141, 2+ +244CM B 432 3 0.56 13 6.67 +244CMS B EAV=123.7 7 +244CM G 1041.22 3 0.19 6 (M1+E2) +244CM G 1084.181 140.36 12(E2) 0.041 11 +244CM2 G KC=0.030 8$LC=0.008 2$MC=0.0020 1 +244CM L 1105.91 2 (1, 2)- +244CM B 410 3 0.35 9 6.8 1 +244CMS B EAV=116.9 7 +244CM G 1062.95 3 0.27 8 E1 0.11 3 +244CM2 G KC=0.09 3$LC=0.015 4$MC=0.0032 1 +244CM G 1105.91 2 0.04 2 (E1) 0.17 4 +244CM2 G KC=0.14 3$LC=0.024 6$MC=0.0058 1 + diff --git a/HEN_HOUSE/spectra/lnhb/Ar-37.txt b/HEN_HOUSE/spectra/lnhb/Ar-37.txt new file mode 100644 index 000000000..0ace73dc4 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Ar-37.txt @@ -0,0 +1,29 @@ + 37CL 37AR EC DECAY (35.01 D) + 37CL H TYP=Full$AUT=V.P. Chechev$CUT=30-MAR-2012$ + 37CL C Evaluation history: Type=Full;Author=V.P. Chechev;Cutoff date=30-MAR-2012 + 37CL C References: 1944We**, 1952Mi**, 1959Ki41, 1965St09, 1972Dz09, 1973Co26, + 37CL2C 1975Ki10, 1986BrZQ, 1996Sc06, 1998Bo30, 1998Sc28, 1998En04, 2000Sc47, + 37CL3C 2001Re01, 2003Au03, 2011Ch65, 2012Au06 + 37CL T Auger electrons and ^X ray energies and emission intensities: + 37CL T {U Energy (keV)} {U Intensity } {U Line } + 37CL T + 37CL T 2.6208 2.76 7 XKA2 + 37CL T 2.62241 5.46 14 XKA1 + 37CL T + 37CL T 2.8156 |] 0.71 4 XKB1 + 37CL T + 37CL T + 37CL T 0.1833-0.2681 0.20 4 XL (total) + 37CL T 0.1833 XLL + 37CL T -0.2681 XLB + 37CL T + 37CL T 2.241-2.384 |] KLL AUGER + 37CL T 2.535-2.616 |] 81.3 3 ^KLX AUGER + 37CL T 2.787-2.809 |] KXY AUGER + 37CL T 0.165-0.257 166.49 21 L AUGER + 37AR P 0.0 3/2+ 35.01 D 2 813.87 20 + 37CL N 1.0 1.0 1 1.0 + 37CL L 0 0 3/2+ STABLE + 37CL E 100 5.1 + 37CL2 E EAV= $CK=0.9021 24$CL=0.0872 20$CM=0.0106 7$CN=0 $CO=0 + diff --git a/HEN_HOUSE/spectra/lnhb/Ar-41.txt b/HEN_HOUSE/spectra/lnhb/Ar-41.txt new file mode 100644 index 000000000..1d2d60a00 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Ar-41.txt @@ -0,0 +1,34 @@ + 41K 41AR B- DECAY (1.8268 H) + 41K H TYP=Full$AUT=v. chisté$CUT=28-FEB-2010$ + 41K 2 H TYP=update$AUT=v. chisté$CUT= -- $ + 41K C Evaluation history: Type=Full;Author=v. chisté;Cutoff date=28-FEB-2010 + 41K 2C Type=update;Author=v. chisté;Cutoff date= -- + 41K C References: 1936Sn01, 1946Bl28, 1950Br29, 1951Ha78, 1956Sc91, 1961Ka19, + 41K 2C 1962En05, 1964Pa03, 1965Pr05, 1969Bo11, 1971Ju04, 1978Eg01, 1978En23, + 41K 3C 1986Ru09, 1990En08, 1990Ab06, 1996Sc06, 2001Ca59, 2002Ba85, 2003Au03, + 41K 4C 2008Ki07 + 41K T Auger electrons and ^X ray energies and emission intensities: + 41K T {U Energy (keV)} {U Intensity } {U Line } + 41K T + 41K T 3.3111 0.000270 9 XKA2 + 41K T 3.3138 0.000533 17 XKA1 + 41K T + 41K T 3.5896 |] 0.000098 4 XKB1 + 41K T 3.6028 |] XKB5II + 41K T + 41K T + 41AR P 0.0 7/2- 1.8268 H 6 2491.6 4 + 41K N 1.0 1.0 1 1.0 + 41K L 0 3/2+ STABLE + 41K B 2491.6 4 0.784 19 9.72 3U + 41K S B EAV=1076.6 2 + 41K L 1293.64 4 7/2- 6.7 NS 5 + 41K B 1197.96 4099.165 20 5.05 + 41K S B EAV=459.18 18 + 41K G 1293.64 4 99.157 20M2+E3 0.118 12 7.44E-511 + 41K 2 G KC=6.36E-5 9$LC=5.34E-6 8$MC=5.80E-7 9 + 41K L 1677.0 3 7/2+ + 41K B 814.6 4 0.0515 49 7.68 + 41K S B EAV=293.9 2 + 41K G 1677.0 3 0.0515 49 + diff --git a/HEN_HOUSE/spectra/lnhb/At-211.txt b/HEN_HOUSE/spectra/lnhb/At-211.txt new file mode 100644 index 000000000..c0d5f0186 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/At-211.txt @@ -0,0 +1,98 @@ +211PO 211AT EC DECAY (7.216 H) +211PO H TYP=Full$AUT=A.L. Nichols$CUT=30-AUG-2010$ +211PO C Evaluation history: Type=Full;Author=A.L. Nichols;Cutoff date=30-AUG-2010 +211PO C References: 1951Ne02, 1953Ho49, 1956Gr11, 1959Ra08, 1961Ap01, 1962Th08, +211PO2C 1969Go23, 1970As07, 1970AfZZ, 1975Ja04, 1977La19, 1978Sc12, 1978Ya04, +211PO3C 1983He09, 1985La17, 1991Ry01, 1996Sc06, 1998Ak04, 1998ScZM, 1999ScZX, +211PO4C 2001Ch66, 2002Ba85, 2002Ra45, 2003Au03, 2004Br45, 2008Ki07 +211PO T Auger electrons and ^X ray energies and emission intensities: +211PO T {U Energy (keV)} {U Intensity } {U Line } +211PO T +211PO T 76.864 12.66 9 XKA2 +211PO T 79.293 21.08 12 XKA1 +211PO T +211PO T 89.256 |] XKB3 +211PO T 89.807 |] 7.26 12 XKB1 +211PO T 90.363 |] XKB5II +211PO T +211PO T 92.263 |] XKB2 +211PO T 92.618 |] 2.26 5 XKB4 +211PO T 92.983 |] XKO23 +211PO T +211PO T 9.658-16.213 18.6 8 XL (total) +211PO T 9.658 0.465 12 XLL +211PO T 11.016-11.13 8.53 20 XLA +211PO T 12.085 0.134 4 XLC +211PO T 12.823-13.778 7.76 14 XLB +211PO T 15.742-16.213 1.53 3 XLG +211PO T +211PO T 58.978-65.205 |] KLL AUGER +211PO T 71.902-79.289 |] 1.57 18 ^KLX AUGER +211PO T 84.8-93.1 |] KXY AUGER +211PO T 5.434-10.934 27.6 8 L AUGER +211AT P 0.0 9/2- 7.216 H 7 785.4 25 +211PO N 1.718E0 1.718E0 0.5822 1.718E0 +211PO L 0 9/2+ 0.516 S 3 +211PO E 57.96 8 5.97 +211PO2 E EAV= $CK=0.7731 2$CL=0.1693 1$CM=0.05758 4$CN= $CO= +211PO L 687.2 7 11/2+ +211PO E 0.258 135.77 1U +211PO2 E EAV= $CK=0.015 17$CL=0.684 10$CM=0.301 7$CN= $CO= +211PO G 687.2 7 0.245 12(M1+E2] -0.20 2 0.0536 9 +211PO2 G KC=0.0437 7$LC=0.00752 12$MC=0.00177 3 + +207BI 211AT A DECAY (7.216 H) +207BI H TYP=Full$AUT=A.L. Nichols$CUT=30-AUG-2010$ +207BI C Evaluation history: Type=Full;Author=A.L. Nichols;Cutoff date=30-AUG-2010 +207BI C References: 1951Ne02, 1953Ho49, 1956Gr11, 1959Ra08, 1961Ap01, 1962Th08, +207BI2C 1969Go23, 1970As07, 1970AfZZ, 1975Ja04, 1977La19, 1978Sc12, 1978Ya04, +207BI3C 1983He09, 1985La17, 1991Ry01, 1996Sc06, 1998Ak04, 1998ScZM, 1999ScZX, +207BI4C 2001Ch66, 2002Ba85, 2002Ra45, 2003Au03, 2004Br45, 2008Ki07 +207BI T Auger electrons and ^X ray energies and emission intensities: +207BI T {U Energy (keV)} {U Intensity } {U Line } +207BI T +207BI T 74.8157 0.000098 15 XKA2 +207BI T 77.1088 0.000164 25 XKA1 +207BI T +207BI T 86.835 |] XKB3 +207BI T 87.344 |] 0.000056 9 XKB1 +207BI T 87.862 |] XKB5II +207BI T +207BI T 89.732 |] XKB2 +207BI T 90.074 |] 0.000017 3 XKB4 +207BI T 90.421 |] XKO23 +207BI T +207BI T 9.42-15.709 0.000136 14 XL (total) +207BI T 9.42 0.0000033 4 XLL +207BI T 10.731-10.839 0.000063 7 XLA +207BI T 11.712 0.00000103 15 XLC +207BI T 12.48-13.393 0.000057 6 XLB +207BI T 15.248-15.709 0.0000110 12 XLG +207BI T +207BI T 57.491-63.419 |] KLL AUGER +207BI T 70.025-77.105 |] 0.0000126 24 ^KLX AUGER +207BI T 82.53-90.52 |] KXY AUGER +207BI T 5.35-10.66 0.000211 20 L AUGER +211AT P 0.0 9/2- 7.216 H 7 5982.4 13 +207BI N 2.393E0 2.393E0 0.4178 2.393E0 +207BI L 0 9/2- 32.9 Y 14 +207BI A 5869.0 13100.00 191.59 +207BI L 669.77 7 11/2- +207BI A 5211.9 130.0093 7 7.3 +207BI G 669.77 7 0.0038 3 [M1+E2] 0.25 3 0.0520 9 +207BI2 G KC=0.0426 8$LC=0.00725 12$MC=0.00170 3 +207BI L 742.74 7 7/2- +207BI A 5140.3 130.00263 4810.1 +207BI G 742.74 7 0.00125 19[M1+E2] 0.30 3 0.0391 7 +207BI2 G KC=0.0320 6$LC=0.00544 10$MC=1276E-6 22 +207BI L 892.46 7 9/2- +207BI A 4993.4 1395740E-8 3.8 +207BI G 149.72 105000E-8 0 M1+E2 0.4 2 3.0 3 +207BI2 G KC=2.3 3$LC=0.50 4$MC=0.120 12 +207BI G 222.69 104000E-8 0 M1+E2 0.4 1 0.95 5 +207BI2 G KC=0.76 5$LC=0.1473 23$MC=0.0351 5 +207BI G 892.46 7 1400E-7 0 [M1+E2] 1.4 2 0.0145 13 +207BI2 G KC=0.0117 11$LC=0.00215 16$MC=0.00051 4 +207BI L 992.43 7 7/2- +207BI A 4895.4 1395740E-9 9.6 + diff --git a/HEN_HOUSE/spectra/lnhb/At-215.txt b/HEN_HOUSE/spectra/lnhb/At-215.txt new file mode 100644 index 000000000..18b60c130 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/At-215.txt @@ -0,0 +1,39 @@ +211BI 215AT A DECAY (0.10 MS) +211BI H TYP=Full$AUT=V.P. Chechev$CUT=15-DEC-2010$ +211BI C Evaluation history: Type=Full;Author=V.P. Chechev;Cutoff date=15-DEC-2010 +211BI C References: 1951Me10, 1966Gr07, 1982Bo04, 1991Ry01, 2003Au03, 2004Br45, +211BI2C 2008Ki07 +211BI T Auger electrons and ^X ray energies and emission intensities: +211BI T {U Energy (keV)} {U Intensity } {U Line } +211BI T +211BI T 74.8157 0.0012 5 XKA2 +211BI T 77.1088 0.0020 9 XKA1 +211BI T +211BI T 86.835 |] XKB3 +211BI T 87.344 |] 0.00069 28 XKB1 +211BI T 87.862 |] XKB5II +211BI T +211BI T 89.732 |] XKB2 +211BI T 90.074 |] 0.00021 9 XKB4 +211BI T 90.421 |] XKO23 +211BI T +211BI T 9.4207-15.7084 0.0017 4 XL (total) +211BI T 9.4207 0.000042 13 XLL +211BI T 10.7308-10.8387 0.00078 22 XLA +211BI T 11.7127 0.000013 5 XLC +211BI T 12.4814-13.8066 0.00073 18 XLB +211BI T 14.7735-15.7084 0.00014 4 XLG +211BI T +211BI T 57.491-63.419 |] KLL AUGER +211BI T 70.025-77.105 |] 0.00015 7 ^KLX AUGER +211BI T 82.53-90.52 |] KXY AUGER +211BI T 5.42-16.34 0.0027 5 L AUGER +215AT P 0.0 9/2- 0.10 MS 2 8178 4 +211BI N 1.0 1.0 1 1.0 +211BI L 0 9/2- 2.15 M 2 +211BI A 8026 4 99.95 2 2.8 +211BI L 404.854 9 7/2- 0.317 NS 11 +211BI A 7628 4 0.05 2 390 +211BI G 404.853 9 0.045 18M1+E2 -1.1 1 0.122 8 +211BI2 G KC=0.095 7$LC=0.0206 8$MC=0.00498 17 + diff --git a/HEN_HOUSE/spectra/lnhb/At-217.txt b/HEN_HOUSE/spectra/lnhb/At-217.txt new file mode 100644 index 000000000..59be18fae --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/At-217.txt @@ -0,0 +1,58 @@ +213BI 217AT A DECAY (32.3 MS) +213BI H TYP=Full$AUT=X.Huang$CUT=31-DEC-2007$ +213BI C Evaluation history: Type=Full;Author=X.Huang;Cutoff date=31-DEC-2007 +213BI T Auger electrons and ^X ray energies and emission intensities: +213BI T {U Energy (keV)} {U Intensity } {U Line } +213BI T +213BI T 74.8157 0.00351 20 XKA2 +213BI T 77.1088 0.0059 4 XKA1 +213BI T +213BI T 86.835 |] XKB3 +213BI T 87.344 |] 0.00201 11 XKB1 +213BI T 87.862 |] XKB5II +213BI T +213BI T 89.732 |] XKB2 +213BI T 90.074 |] 0.00062 4 XKB4 +213BI T 90.421 |] XKO23 +213BI T +213BI T 9.421-15.708 0.00497 23 XL (total) +213BI T 9.421 XLL +213BI T -15.708 XLG +213BI T +213BI T 57.491-63.419 |] KLL AUGER +213BI T 70.025-77.105 |] 0.00044 3 ^KLX AUGER +213BI T 82.53-90.52 |] KXY AUGER +213BI T 5.3-16.4 0.0077 4 L AUGER +217AT P 0.0 9/2- 32.3 MS 4 7201.3 12 +213BI N 1.00E0 1.00E0 0.999933241.00E0 +213BI L 0 9/2- 45.59 M 6 +213BI A 7066.9 1699.9387 301.16 +213BI L 257.87 117/2- +213BI A 6813.8 160.0384 15379 +213BI G 257.88 4 0.0287 7 M1+E2 0.64 8 0.555 26 +213BI2 G KC=0.434 17$LC=0.0918 16$MC=0.02212 37 +213BI L 593.18 13(5/2,7/2,9/2)- +213BI A 6484.7 160.0167 8 49 +213BI G 335.33 100.0062 3 +213BI G 593.1 1 0.0115 5 +213BI L 758.9 1 (5/2,13/2)- +213BI A 6322.0 160.0049 4 36 +213BI G 758.9 1 0.0049 4 +213BI L 1050 - +213BI A 6037 3 20001E-7 5.2 +213BI G 455 2000E-6 0 + +217RN 217AT B- DECAY (32.3 MS) +217RN H TYP=Full$AUT=X.Huang$CUT=31-DEC-2007$ +217RN C Evaluation history: Type=Full;Author=X.Huang;Cutoff date=31-DEC-2007 +217RN T Auger electrons and ^X ray energies and emission intensities: +217RN T {U Energy (keV)} {U Intensity } {U Line } +217RN T +217RN T +217RN T +217RN T +217RN T +217AT P 0.0 9/2- 32.3 MS 4 737 6 +217RN N 1.493E4 1.493E4 0.000067 1.493E4 +217RN L 0 - 0.54 MS 5 + diff --git a/HEN_HOUSE/spectra/lnhb/At-218.txt b/HEN_HOUSE/spectra/lnhb/At-218.txt new file mode 100644 index 000000000..eb1a4da7d --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/At-218.txt @@ -0,0 +1,25 @@ +214BI 218AT A DECAY (1.4 S) +214BI H TYP=Full$AUT=V.Chisté$CUT= -- $ +214BI C Evaluation history: Type=Full;Author=V.Chisté;Cutoff date= -- +214BI C References: 1948Wa20, 1949Wa05, 1958Wa16, 1963Wa29, 1964Hy02, 1979Ry03, +214BI2C 1987El12, 1989Bu09, 1991Ry01, 1995El08, 1995El07, 2003Au03, 2006Ja03 +218AT P 0.0 - 1.4 S 2 6874 3 +214BI N 1.001E0 1.001E0 0.999 1.001E0 +214BI L 0 1- 19.8 M 1 +214BI A 6756 5 3.6 1 150 +214BI L 62.7 10 + +214BI A 6694 3 90.09 103.9 +214BI L 103 6 + +214BI A 6653 5 6.41 1038 + +218RN 218AT B- DECAY (1.4 S) +218RN H TYP=Full$AUT=V.Chisté$CUT= -- $ +218RN C Evaluation history: Type=Full;Author=V.Chisté;Cutoff date= -- +218RN C References: 1948Wa20, 1949Wa05, 1958Wa16, 1963Wa29, 1964Hy02, 1979Ry03, +218RN2C 1987El12, 1989Bu09, 1991Ry01, 1995El08, 1995El07, 2003Au03, 2006Ja03 +218AT P 0.0 - 1.4 S 2 2881 12 +218RN N 1.000E3 1.000E3 0.001 1.000E3 +218RN L 0 0+ 36.0 MS 19 +218RN B 2881 120.1 1 +218RNS B EAV=1095 12 + diff --git a/HEN_HOUSE/spectra/lnhb/At-219.txt b/HEN_HOUSE/spectra/lnhb/At-219.txt new file mode 100644 index 000000000..6d7336f36 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/At-219.txt @@ -0,0 +1,57 @@ +215BI 219AT A DECAY (56 S) +215BI H TYP=Full$AUT=A.L. Nichols$CUT=15-SEP-2010$ +215BI C Evaluation history: Type=Full;Author=A.L. Nichols;Cutoff date=15-SEP-2010 +215BI C References: 1953Hy83, 1989Bu09, 1998Ak04, 2001Br31, 2003Au03, 2009AuZZ +215BI T Auger electrons and ^X ray energies and emission intensities: +215BI T {U Energy (keV)} {U Intensity } {U Line } +215BI T +215BI T 74.8157 XKA2 +215BI T 77.1088 XKA1 +215BI T +215BI T 86.835 |] XKB3 +215BI T 87.344 |] XKB1 +215BI T 87.862 |] XKB5II +215BI T +215BI T 89.732 |] XKB2 +215BI T 90.074 |] XKB4 +215BI T 90.421 |] XKO23 +215BI T +215BI T +215BI T 57.491-63.419 |] KLL AUGER +215BI T 70.025-77.105 |] ^KLX AUGER +215BI T 82.53-90.52 |] KXY AUGER +215BI T 0.21-16.3366 L AUGER +219AT P 0.0 (7/2)- 56 S 4 6324 15 +215BI N 1.031E0 1.031E0 0.97 1.031E0 +215BI L 0 (9/2)- 7.6 M 2 +215BI A 6208 15100 1.07 + +219RN 219AT B- DECAY (56 S) +219RN H TYP=Full$AUT=A.L. Nichols$CUT=15-SEP-2010$ +219RN C Evaluation history: Type=Full;Author=A.L. Nichols;Cutoff date=15-SEP-2010 +219RN C References: 1953Hy83, 1989Bu09, 1998Ak04, 2001Br31, 2003Au03, 2009AuZZ +219RN T Auger electrons and ^X ray energies and emission intensities: +219RN T {U Energy (keV)} {U Intensity } {U Line } +219RN T +219RN T 81.07 XKA2 +219RN T 83.78 XKA1 +219RN T +219RN T 94.247 |] XKB3 +219RN T 94.868 |] XKB1 +219RN T 95.449 |] XKB5II +219RN T +219RN T 97.48 |] XKB2 +219RN T 97.853 |] XKB4 +219RN T 98.357 |] XKO23 +219RN T +219RN T +219RN T 62.017-68.885 |] KLL AUGER +219RN T 75.744-83.785 |] ^KLX AUGER +219RN T 89.45-98.39 |] KXY AUGER +219RN T 0.2-17.957 L AUGER +219AT P 0.0 (7/2)- 56 S 4 1566 3 +219RN N 3.333E1 3.333E1 0.03 3.333E1 +219RN L 0 5/2+ 3.98 S 3 +219RN B 1566 3 3 6.2 1U +219RNS B EAV=547 2 + diff --git a/HEN_HOUSE/spectra/lnhb/Au-195.txt b/HEN_HOUSE/spectra/lnhb/Au-195.txt new file mode 100644 index 000000000..cb7482e8e --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Au-195.txt @@ -0,0 +1,60 @@ +195PT 195AU EC DECAY (184.7 D) +195PT H TYP=Full$AUT=V. Chisté$CUT=30-MAY-2012$ +195PT C Evaluation history: Type=Full;Author=V. Chisté;Cutoff date=30-MAY-2012 +195PT C References: 1949Wi08, 1949St17, 1959Mc69, 1959Bi07, 1960Br11, 1962Bo12, +195PT2C 1963Ha17, 1964Go19, 1965Ha13, 1967Sc18, 1969Fi08, 1970To19, 1970Ah05, +195PT3C 1972Ha21, 1973Go05, 1974HeYW, 1982HoZJ, 1996Sc06, 1999Zh11, 2002Un02, +195PT4C 2008Ki07, 2012Au06 +195PT T Auger electrons and ^X ray energies and emission intensities: +195PT T {U Energy (keV)} {U Intensity } {U Line } +195PT T +195PT T 65.123 27.4 17 XKA2 +195PT T 66.833 46.9 29 XKA1 +195PT T +195PT T 75.369 |] XKB3 +195PT T 75.749 |] 15.8 10 XKB1 +195PT T 76.234 |] XKB5II +195PT T +195PT T 77.786 |] XKB2 +195PT T 78.07 |] 4.51 30 XKB4 +195PT T 78.337 |] XKO23 +195PT T +195PT T 8.2683-13.3617 53.1 24 XL (total) +195PT T 8.2683 1.29 9 XLL +195PT T 9.362-9.4423 26.1 16 XLA +195PT T 9.9768 0.309 17 XLC +195PT T 10.8411-11.2344 21.5 8 XLB +195PT T 12.5496-13.3617 3.99 16 XLG +195PT T +195PT T 50.399-55.021 |] KLL AUGER +195PT T 61.116-66.829 |] 4.0 5 ^KLX AUGER +195PT T 71.8-78.39 |] KXY AUGER +195PT T 5.07-14.25 129 8 L AUGER +195AU P 0.0 3/2+ 184.7 D 14 226.8 10 +195PT N 1.0 1.0 1 1.0 +195PT L 0 1/2- STABLE +195PT E 9.5 4 8.1 1U +195PT2 E EAV= $CK=0.6851 10$CL=0.2336 7$CM=0.0813 3$CN= $CO= +195PT L 98.882 4 3/2- +195PT E 57.6 356.5 +195PT2 E EAV= $CK=0.452 6$CL=0.398 4$CM=0.1499 18$CN= $CO= +195PT G 98.882 4 11.21 15M1+E2 -0.122 15 6.86 10 +195PT2 G KC=5.59 8$LC=0.977 16$MC=0.227 4 +195PT L 129.777 5 5,/2- +195PT E 32.8 306.3 1U +195PT2 E EAV= $CK=0.178 12$CL=0.587 9$CM=0.235 4$CN= $CO= +195PT G 30.895 7 0.80 8 M1+E2 -0.013 7 37.3 6 +195PT2 G KC=$LC=28.7 5$MC=6.65 11 +195PT G 129.777 5 0.854 29E2 1.729 25 +195PT2 G KC=0.467 7$LC=0.948 14$MC=0.245 4 +195PT L 199.526 123/2- +195PT E 0.0149 148.1 +195PT2 E EAV= $CK= $CL=0.50 2$CM=0.50 2$CN= $CO= +195PT G 199.526 120.0093 8 M1+E2 1.2 2 0.60 6 +195PT2 G KC=0.42 6$LC=0.1374 25$MC=0.0338 9 +195PT L 211.398 6 3/2- +195PT E 0.0210 187.1 +195PT2 E EAV= $CK= $CL=0.05 5$CM=0.95 5$CN= $CO= +195PT G 211.398 6 0.0121 10M1+E2 0.38 3 0.737 14 +195PT2 G KC=0.595 13$LC=0.1090 16$MC=0.0255 4 + diff --git a/HEN_HOUSE/spectra/lnhb/Au-198.txt b/HEN_HOUSE/spectra/lnhb/Au-198.txt new file mode 100644 index 000000000..0dc353e20 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Au-198.txt @@ -0,0 +1,61 @@ +198HG 198AU B- DECAY (2.6943 D) +198HG H TYP=UPDate$AUT=V.P. Chechev. N.Kuzmenko$CUT=14-JAN-2014$ +198HG2 H TYP=FULL$AUT=E. Schönfeld. R. Dersch$CUT=01-SEP-1998$ +198HG C Evaluation history: Type=UPDate;Author=V.P. Chechev. N.Kuzmenko;Cutoff date=14-JAN-2014 +198HG2C Type=FULL;Author=E. Schönfeld. R. Dersch;Cutoff date=01-SEP-1998 +198HG C References: 1935Am01, 1937Po04, 1937Mc04, 1941Sh08, 1946Di**, 1947Se33, +198HG2C 1948Sa36, 1949Sa18, 1949St17, 1951Si91, 1951Ca06, 1951Si25, 1951Br52, +198HG3C 1951Hu18, 1953Sc19, 1953Sc23, 1953Lo09, 1954Be61, 1954El04, 1954Ma19, +198HG4C 1955DZ41, 1955To07, 1955El11, 1956Jo24, 1956Sa75, 1956Vo20, 1958Ke26, +198HG5C 1960Ro22, 1963Le11, 1963St20, 1964Be33, 1964Sa11, 1965An07, 1965Pa08, +198HG6C 1965Pe05, 1965Ke04, 1965Be07, 1966Uh01, 1967Ko13, 1967BoZZ, 1968Go22, +198HG7C 1968La10, 1968Re04, 1969Ca23, 1969Vu04, 1969BeZR, 1970Co14, 1971Pa06, +198HG8C 1971GoYM, 1971De**, 1971Be09, 1972Ve03, 1972Na22, 1973El10, 1974Ka18, +198HG9C 1976Re**, 1980Iw03, 1982RuZV, 1982HoZJ, 1989Ch45, 1990Ab02, 1992Un01, +198HG10C 1992Ha02, 1994Mi03, 2002Un02, 2002Ba85, 2004Un01, 2004BeZQ, 2005Li66, +198HG11C 2006No10, 2007Go39, 2007Sp01, 2008Ki07, 2008Ru05, 2008Ku09, 2009Hu11, +198HG12C 2010Mo06, 2010Li48, 2010Go25, 2010Fo13, 2011Li52, 2011Ch22, 2012Fi12, +198HG13C 2012Ha23, 2012Wa38, 2014Un** +198HG T Auger electrons and ^X ray energies and emission intensities: +198HG T {U Energy (keV)} {U Intensity } {U Line } +198HG T +198HG T 68.895 0.807 15 XKA2 +198HG T 70.82 1.369 24 XKA1 +198HG T +198HG T 79.823 |] XKB3 +198HG T 80.254 |] 0.465 11 XKB1 +198HG T 80.762 |] XKB5II +198HG T +198HG T 82.435 |] XKB2 +198HG T 82.776 |] 0.136 4 XKB4 +198HG T 83.028 |] XKO23 +198HG T +198HG T 8.7226-14.2672 1.203 22 XL (total) +198HG T 8.7226 0.0270 8 XLL +198HG T 9.8981-9.9886 0.527 14 XLA +198HG T 10.6473 0.01054 29 XLC +198HG T 11.4835-12.5471 0.536 12 XLB +198HG T 13.4081-14.2672 0.1024 23 XLG +198HG T +198HG T 53.178-58.277 |] KLL AUGER +198HG T 64.594-70.811 |] 0.110 12 ^KLX AUGER +198HG T 75.98-83.09 |] KXY AUGER +198HG T 5.161-14.822 2.156 24 L AUGER +198AU P 0.0 2- 2.6943 D 3 1372.8 5 +198HG N 1.0 1.0 1 1.0 +198HG L 0 0+ STABLE +198HG B 1372.8 5 0.025 5 12.4 1U +198HGS B EAV=467.3 2 +198HG L 411.80250 172+ 23.16 PS 12 +198HG B 961.0 5 98.99 6 7.37 +198HGS B EAV=314.7 2 +198HG G 411.80205 1795.62 6 E2 0.0439 7 +198HG2 G KC=0.0300 5$LC=0.01055 15$MC=0.00263 4 +198HG L 1087.6874 5 2+ 2.5 PS 20 +198HG B 285.1 5 0.985 5 7.6 +198HGS B EAV=79.5 2 +198HG G 675.8836 7 0.804 5 M1+E2 1.07 14 0.0267 20 +198HG2 G KC=0.0216 17$LC=0.00389 24$MC=0.00091 6 +198HG G 1087.6842 7 0.1591 21E2 0.005128 +198HG2 G KC=0.00414 6$LC=7.51E-4 11$MC=1766E-7 25 + diff --git a/HEN_HOUSE/spectra/lnhb/Ba-133.txt b/HEN_HOUSE/spectra/lnhb/Ba-133.txt new file mode 100644 index 000000000..2e2f1f39b --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Ba-133.txt @@ -0,0 +1,77 @@ +133CS 133BA EC DECAY (10.539 Y) +133CS H TYP=UPD$AUT=V.P. Chechev. N.K. Kuzmenko$CUT=01-MAY-2015$ +133CS2 H TYP=UPD$AUT=V.P. Chechev. N.K. Kuzmenko$CUT=01-JUL-2014$ +133CS3 H TYP=UPD$AUT=V.P. Chechev. N.K. Kuzmenko$CUT=01-JAN-2004$ +133CS4 H TYP=UPD$AUT=V.P. Chechev. N.K. Kuzmenko$CUT=01-APR-2000$ +133CS5 H TYP=FUL$AUT=V.P. Chechev. N.K. Kuzmenko$CUT=01-MAY-1999$ +133CS C References: 1961Wy01, 1967Bl15, 1967Be65, 1968Do10, 1968Re04, 1968Al16, +133CS2C 1968Na16, 1968No01, 1968La10, 1968BO04, 1969Gu15, 1970Wa19, 1972Em01, +133CS3C 1972Sc08, 1973In06, 1973Le**, 1973Ll01, 1973Mc18, 1974Da09, 1975Ni07, +133CS4C 1977Ge12, 1977Sc31, 1978Vy**, 1978He21, 1979HaYC, 1980Ch**, 1980Ho17, +133CS5C 1980Ro22, 1980RuZY, 1982HoZJ, 1983Si22, 1983Si17, 1983Ch11, 1983Ki08, +133CS6C 1983Wa26, 1983Yo03, 1987La**, 1988BeYQ, 1989Ma60, 1989Eg**, 1989DA11, +133CS7C 1990Da11, 1990Fi03, 1990Bh01, 1990Me15, 1991We08, 1992Sa28, 1992Un01, +133CS8C 1992Ch**, 1993Ni**, 1995Ra12, 1996Mi26, 1996Sc06, 1997Ma75, 1998Hw07, +133CS9C 2000He14, 2002Un02, 2004Sc04, 2004BeZQ, 2008Ki07, 2010Sc08, 2011Kh02, +133CS10C 2012Wa38, 2012Fi12, 2014Ma**, 2014Un01 +133CS T Auger electrons and X ray energies and emission intensities: +133CS T {U Energy (keV)} {U Intensity} {U Line} +133CS T +133CS T 30.6254 33.8 4 XKA2 +133CS T 30.9731 62.4 7 XKA1 +133CS T +133CS T 34.9197 |] XKB3 +133CS T 34.9873 |] 18.24 29 XKB1 +133CS T 35.252 |] XKB5II +133CS T +133CS T 35.822 |] XKB2 +133CS T 35.907 |] 4.45 12 XKB4 +133CS T 35.972 |] XKO23 +133CS T +133CS T 3.7946-5.5525 15.87 26 XL (total) +133CS T 3.7946 0.293 8 XLL +133CS T 4.2729-4.2866 7.63 18 XLA +133CS T 4.1418 0.1117 30 XLC +133CS T 4.62-4.9333 6.76 12 XLB +133CS T 5.1308-5.5525 1.086 20 XLG +133CS T +133CS T 24.411-25.804 |] KLL AUGER +133CS T 28.991-30.961 |] 14.1 6 KLX AUGER +133CS T 33.55-35.96 |] KXY AUGER +133CS T 2.5777-5.559 136.8 8 L AUGER +133BA P 0.0 1/2+ 10.539 Y 6 517.3 10 +133CS N 1.0 1.0 1 1.0 +133CS L 0 7/2+ STABLE +133CS E 0.0005 LT13.9 GT +133CS2 E EAV= $CK=0.77 $CL=0.18 $CM=0.05 $CN= $CO= +133CS L 80.9979 115/2+ 6.283 NS 14 +133CS E 0.7 LT10.9 GT +133CS2 E EAV= $CK=0.84 $CL=0.13 $CM=0.037 $CN= $CO= +133CS G 80.9979 1133.31 30M1+E2 0.158 5 1.703 24 +133CS2 G KC=1.431 20$LC=0.216 4$MC=0.0447 8 +133CS L 160.6121 165/2+ 172 PS 4 +133CS E 0.3 LT10.6 GT +133CS2 E EAV= $CK=0.83 $CL=0.13 $CM=0.037 $CN= $CO= +133CS G 79.6142 192.63 19M1+E2 0.124 15 1.77 3 +133CS2 G KC=1.495 22$LC=0.217 6$MC=0.0447 13 +133CS G 160.6121 160.638 6 M1+E2 0.96 5 0.294 6 +133CS2 G KC=0.234 4$LC=0.0471 13$MC=0.0099 3 +133CS L 383.8491 123/2+ 44 PS 11 +133CS E 14.46 518.03 2 +133CS2 E EAV= $CK=0.7727 9$CL=0.1755 7$CM=0.05174 23$CN= $CO= +133CS G 223.2368 130.450 5 M1+E2 0.114 14 0.0975 14 +133CS2 G KC=0.0836 12$LC=0.01103 16$MC=0.00226 4 +133CS G 302.8508 5 18.31 11M1+E2 0.022 20 0.0434 6 +133CS2 G KC=0.0373 6$LC=0.00484 7$MC=9.88E-4 14 +133CS G 383.8485 128.94 6 E2 0.0202 3 +133CS2 G KC=0.01684 24$LC=0.00270 4$MC=5.60E-4 8 +133CS L 437.0113 131/2+ 150 PS +133CS E 85.41 536.63 +133CS2 E EAV= $CK=0.671 5$CL=0.251 4$CM=0.0777 11$CN= $CO= +133CS G 53.1622 182.14 6 M1+E2 0.08 3 5.66 11 +133CS2 G KC=4.78 7$LC=0.70 5$MC=0.144 12 +133CS G 276.3989 127.13 6 E2 0.0566 8 +133CS2 G KC=0.0460 7$LC=0.00842 12$MC=1763E-6 25 +133CS G 356.0129 7 62.05 19E2 0.0254 4 +133CS2 G KC=0.0211 3$LC=0.00346 5$MC=7.21E-4 10 + diff --git a/HEN_HOUSE/spectra/lnhb/Ba-137m.txt b/HEN_HOUSE/spectra/lnhb/Ba-137m.txt new file mode 100644 index 000000000..beea5f3b2 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Ba-137m.txt @@ -0,0 +1,30 @@ +137BA 137BA IT DECAY (2.552 M) +137BA T Auger electrons and ^X ray energies and emission intensities: +137BA T {U Energy (keV)} {U Intensity } {U Line } +137BA T +137BA T 31.8174 2.06 4 XKA2 +137BA T 32.1939 3.80 7 XKA1 +137BA T +137BA T 36.3045 |] XKB3 +137BA T 36.3786 |] 1.12 2 XKB1 +137BA T 36.654 |] XKB5II +137BA T +137BA T 37.258 |] XKB2 +137BA T 37.312 |] 0.28 1 XKB4 +137BA T 37.425 |] XKO23 +137BA T +137BA T 3.954-5.809 0.95 5 XL (total) +137BA T 3.954 XLL +137BA T -5.809 XLG +137BA T +137BA T 25.31-26.79 |] KLL AUGER +137BA T 30.09-31.36 |] 0.8 1 ^KLX AUGER +137BA T 34.84-37.41 |] KXY AUGER +137BA T 2.6-5.9 7.7 1 L AUGER +137BA P 661.659 3 11/2- 2.552 M 1 +137BA N 1.0 1.0 1 1.0 +137BA L 0 3/2+ STABLE +137BA L 661.659 3 11/2- 2.552 M 1 +137BA G 661.657 3 90.07 20M4 0.1102 19 +137BA2 G KC=0.0896 15$LC=0.0167 5$MC= + diff --git a/HEN_HOUSE/spectra/lnhb/Ba-140.txt b/HEN_HOUSE/spectra/lnhb/Ba-140.txt new file mode 100644 index 000000000..4a79e0c1a --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Ba-140.txt @@ -0,0 +1,80 @@ +140LA 140BA B- DECAY (12.753 D) +140LA H TYP=UPD$AUT=V.P. Chechev. N.K. Kuzmenko$CUT=01-MAR-2015$ +140LA2 H TYP=UPD$AUT=M.M.Bé$CUT=19-JUN-2008$ +140LA3 H TYP=FUL$AUT=R.G. Helmer$CUT=01-JAN-2003$ +140LA C References: 1965Si17, 1966Mo16, 1970Ke09, 1969Ka33, 1971Ba28, 1973Ra10, +140LA2C 1975Ha50, 1976Li06, 1977Ge12, 1977De34, 1982Ad02, 1982HoZJ, 1983Wa26, +140LA3C 1990Me03, 1991Ch05, 1992Un01, 1998Si17, 2002Un02, 2002Ba85, 2004BeZR, +140LA4C 2007Ni07, 2008Ki07, 2014Wa38, 2012Fi12, 2014Un01 +140LA T Auger electrons and X ray energies and emission intensities: +140LA T {U Energy (keV)} {U Intensity} {U Line} +140LA T +140LA T 33.0344 0.562 19 XKA2 +140LA T 33.4421 1.03 4 XKA1 +140LA T +140LA T 37.7206 |] XKB3 +140LA T 37.8015 |] 0.307 11 XKB1 +140LA T 38.075 |] XKB5II +140LA T 39.095 |] XKB5I +140LA T +140LA T 38.7303 |] XKB2 +140LA T 38.828 |] 0.078 3 XKB4 +140LA T 39.91 |] XKO23 +140LA T +140LA T 4.1174-6.0724 13.7 4 XL (total) +140LA T 4.1174 0.148 7 XLL +140LA T 4.6338-4.6504 3.81 15 XLA +140LA T 4.5248 0.0762 30 XLC +140LA T 5.0412-5.3814 7.86 19 XLB +140LA T 5.6198-6.0724 1.76 4 XLG +140LA T +140LA T 26.24-27.795 |] KLL AUGER +140LA T 31.231-33.428 |] 0.208 11 KLX AUGER +140LA T 36.2-38.9 |] KXY AUGER +140LA T 2.7-6.2 99.5 19 L AUGER +140BA P 0.0 0+ 12.753 D 5 1048 8 +140LA N 1.0 1.0 1 1.0 +140LA L 0 3- 1.67858 D 21 +140LA L 29.9641 6 2- 0.25 NS 4 +140LA B 1018 8 25.6 42 8.7 1U +140LAS B EAV=362 3 +140LA G 29.9641 6 14.4 4 M1(+E2) 5.37 8 +140LA2 G KC=$LC=4.26 6$MC=0.885 13 +140LA L 43.844 181- 0.52 NS 14 +140LA B 1004 8 35.6 31 8 1 +140LAS B EAV=345 3 +140LA G 13.880 181.16 4 M1+E2 0.0100 55 54.0 19 +140LA2 G KC=$LC=42.8 15$MC=8.9 4 +140LA L 63.1790 7 4- +140LA G 63.1790 7 3.0E-5 15M1 4.05 6 +140LA2 G KC=3.45 5$LC=0.472 7$MC=0.0983 14 +140LA L 162.6591 192- 0.01 NS +140LA B 885 8 4.14 31 9.3 1U +140LAS B EAV=311 3 +140LA G 99.4801 202.0E-5 12[E2] 2.03 3 +140LA2 G KC=1.235 18$LC=0.620 9$MC=0.1371 20 +140LA G 118.815 180.0610 21M1 0.663 10 +140LA2 G KC=0.566 8$LC=0.0765 11$MC=0.01591 23 +140LA G 132.695 2 0.202 6 M1 0.485 7 +140LA2 G KC=0.415 6$LC=0.0560 8$MC=0.01163 17 +140LA G 162.6591 196.49 27M1(+E2) 0.275 4 +140LA2 G KC=0.235 4$LC=0.0317 5$MC=0.00659 11 +140LA L 467.63 3 1`- 7.7 NS +140LA B 580 8 9.71 12 7.8 1 +140LAS B EAV=181 3 +140LA G 304.971 304.33 9 M1(+E2) 0.1 0.0506 7 +140LA2 G KC=0.0434 6$LC=0.00573 8$MC=1189E-6 17 +140LA G 423.786 353.13 6 M1 0.0217 3 +140LA2 G KC=0.0186 3$LC=0.00243 4$MC=5.03E-4 7 +140LA G 437.666 301.94 4 M1 0.0200 3 +140LA2 G KC=0.01716 24$LC=0.00224 4$MC=4.64E-4 7 +140LA L 581.106 180- +140LA B 467 8 24.94 50 7.1 +140LAS B EAV=141 3 +140LA G 113.48 4 0.0172 13M1 0.755 11 +140LA2 G KC=0.645 9$LC=0.0872 13$MC=0.0181 3 +140LA G 537.261 2524.6 5 M1 0.0119717 +140LA2 G KC=0.01029 15$LC=1332E-6 19$MC=2.76E-4 4 +140LA G 551.141 180.0049 20[E2] 0.0079211 +140LA2 G KC=0.00666 10$LC=9.97E-4 14$MC=2.09E-4 3 + \ No newline at end of file diff --git a/HEN_HOUSE/spectra/lnhb/Be-7.txt b/HEN_HOUSE/spectra/lnhb/Be-7.txt new file mode 100644 index 000000000..a3b635d68 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Be-7.txt @@ -0,0 +1,21 @@ + 7LI 7BE EC DECAY (53.22 D) + 7LI C References: 2000Hu20, 2000Li21 + 7LI T Auger electrons and ^X ray energies and emission intensities: + 7LI T {U Energy (keV)} {U Intensity } {U Line } + 7LI T + 7LI T 0.0543 XKA2 + 7LI T 0.0543 XKA1 + 7LI T + 7LI T + 7LI T + 7BE P 0.0 3/2- 53.22 D 6 861.815 18 + 7LI N 1.0 1.0 1 1.0 + 7LI L 0 3/2- STABLE + 7LI E 89.56 4 3.32 + 7LI2 E EAV= $CK=0.908 12$CL=0.092 12$CM= $CN= $CO= + 7LI L 477.621 2 1/2- 105 FS + 7LI E 10.44 4 3.56 2 + 7LI2 E EAV= $CK=0.908 12$CL=0.092 12$CM= $CN= $CO= + 7LI G 477.6035 2010.44 4 M1+E2 7.3E-7 11 + 7LI2 G KC=$LC=$MC= + diff --git a/HEN_HOUSE/spectra/lnhb/Bi-207.txt b/HEN_HOUSE/spectra/lnhb/Bi-207.txt new file mode 100644 index 000000000..93a2d1416 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Bi-207.txt @@ -0,0 +1,56 @@ +207PB 207BI EC DECAY (32.9 Y) +207PB H TYP=Update$AUT=M.M. Bé$CUT=01-DEC-2009$ +207PB2 H TYP=Full$AUT=M.M.Bé$CUT=01-FEB-1998$ +207PB C Evaluation history: Type=Update;Author=M.M. Bé;Cutoff date=01-DEC-2009 +207PB2C Type=Full;Author=M.M.Bé;Cutoff date=01-FEB-1998 +207PB C References: 1971Al03, 2002Ba85, 2008Ki07 +207PB T Auger electrons and ^X ray energies and emission intensities: +207PB T {U Energy (keV)} {U Intensity } {U Line } +207PB T +207PB T 72.8049 21.75 30 XKA2 +207PB T 74.97 36.6 5 XKA1 +207PB T +207PB T 84.451 |] XKB3 +207PB T 84.937 |] 12.49 25 XKB1 +207PB T 85.47 |] XKB5II +207PB T +207PB T 87.238 |] XKB2 +207PB T 87.58 |] 3.77 10 XKB4 +207PB T 87.911 |] XKO23 +207PB T +207PB T 9.18-15.84 32.9 6 XL (total) +207PB T 9.18 0.822 21 XLL +207PB T 10.4496-10.5516 15.6 4 XLA +207PB T 11.3494 0.226 7 XLC +207PB T 12.143-13.015 13.62 26 XLB +207PB T 15.101-15.84 2.61 5 XLG +207PB T +207PB T 56.028-61.669 |] KLL AUGER +207PB T 68.181-74.969 |] 2.9 4 ^KLX AUGER +207PB T 80.3-88 |] KXY AUGER +207PB T 5.2-15.7 54.8 7 L AUGER +207BI P 0.0 9/2- 32.9 Y 14 2397.5 21 +207PB N 1.0 1.0 1 1.0 +207PB L 0 1/2- STABLE +207PB L 569.703 2 5/2- 130.5 PS 8 +207PB E 0.012 2 8.8 6 12.1 +207PB2 E EAV=383.4 9$CK=0.797 8$CL=0.150 3$CM=0.049 1$CN= $CO= +207PB G 569.698 2 97.76 3 E2 0.0216 3 +207PB2 G KC=0.01583 23$LC=0.00439 7$MC=1081E-6 16 +207PB L 897.80 5 3/2- +207PB G 328.11 100.0044 35[M1] +207PB G 897.8 1 0.1284 47M1+E2 0.3 1 0.0222 9 +207PB2 G KC=0.0182 8$LC=0.00304 12$MC=0.071 3 +207PB L 1633.368 5 13/2+ 0.806 S 6 +207PB E 84.1 6 10.58 3U +207PB2 E EAV= $CK=0.733 7$CL=0.199 4$CM=0.069 1$CN= $CO= +207PB G 1063.656 3 74.58 22M4+E5 0.01 1 0.1278 24 +207PB2 G KC=0.0953 23$LC=0.0247 7$MC=0.00591 33 +207PB L 2339.948 117/2- +207PB E 7.03 238.3 2 +207PB2 E EAV= $CK= $CL=0.651 6$CM=0.349 6$CN= $CO= +207PB G 1442.2 2 0.1315 22E2 0.003375 +207PB2 G KC=0.00271 4$LC=4.68E-4 7$MC=1098E-7 16 +207PB G 1770.228 9 6.871 26M1+E2 0.05 2 0.004427 +207PB2 G KC=0.00342 5$LC=5.56E-4 8$MC=1292E-7 19 + diff --git a/HEN_HOUSE/spectra/lnhb/Bi-210.txt b/HEN_HOUSE/spectra/lnhb/Bi-210.txt new file mode 100644 index 000000000..0480db3e3 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Bi-210.txt @@ -0,0 +1,88 @@ +206TL 210BI A DECAY (5.011 D) +206TL H TYP=UPD$AUT=M.A.Kellett$CUT=01-OCT-2014$ +206TL2 H TYP=FUL$AUT=V. Chiste. M.-M.Be$CUT=31-JAN-2008$ +206TL C Evaluation history: Type=UPD;Author=M.A.Kellett;Cutoff date=01-OCT-2014 +206TL2C Type=FUL;Author=V. Chiste. M.-M.Be;Cutoff date=31-JAN-2008 +206TL C References: 1935Po01, 1935Po01, 1939Fl02, 1939Fl02, 1940Ne04, 1940Ne04, +206TL2C 1944Hole, 1947Br36, 1947Br36, 1952Be22, 1952Be22, 1953Lo09, 1953Lo09, +206TL3C 1954Pl30, 1954Pl30, 1956Fi09, 1956Ro18, 1956Ro18, 1956Fi09, 1959Ro51, +206TL4C 1959Wa05, 1959Wa05, 1959Ro51, 1960Wa14, 1960Wa14, 1961Ru02, 1961Ru02, +206TL5C 1961Nu01, 1961Nu01, 1962Da03, 1962Ka27, 1962Ka27, 1962Da03, 1967Hs01, +206TL6C 1967Hs01, 1969Fl02, 1969Fl02, 1969La18, 1969La18, 1991Ry01, 1991Ry01, +206TL7C 1996Sc06, 1996Sc06, 1999Br39, 2002Ba85, 2002Ba85, 2003Br13, 2003Au03, +206TL8C 2003Br13, 2005Gr41, 2008BeZV, 2008Ki07, 2008Ko21, 2010MoZU, 2012Wa38 +206TL T Auger electrons and ^X ray energies and emission intensities: +206TL T {U Energy (keV)} {U Intensity } {U Line } +206TL T +206TL T 70.8325 0.0000064 7 XKA2 +206TL T 72.8725 0.0000108 11 XKA1 +206TL T +206TL T 82.118 |] XKB3 +206TL T 82.577 |] 0.0000037 4 XKB1 +206TL T 83.115 |] XKB5II +206TL T +206TL T 84.838 |] XKB2 +206TL T 85.134 |] 0.00000110 11 XKB4 +206TL T 85.444 |] XKO23 +206TL T +206TL T 8.9531-14.7362 0.0000090 5 XL (total) +206TL T 8.9531 0.000000213 16 XLL +206TL T 10.1718-10.2679 0.00000409 28 XLA +206TL T 10.9942 0.000000072 6 XLC +206TL T 11.8117-12.9566 0.00000386 23 XLB +206TL T 13.8528-14.7362 0.00000073 5 XLG +206TL T +206TL T 54.587-59.954 |] KLL AUGER +206TL T 66.37-72.86 |] 0.00000085 13 ^KLX AUGER +206TL T 78.12-85.5 |] KXY AUGER +206TL T 5.2493-15.3183 0.0000155 6 L AUGER +210BI P 0.0 1- 5.011 D 5 5036.5 8 +206TL N 7.143E5 7.143E5 0.0000012 7.143E5 +206TL L 0 0- 4.202 M 11 +206TL L 265.832 5 2- 2.29 NS 14 +206TL A 4687 4 40.0 4358 +206TL G 265.832 5 4.8E-5 5 E2 0.1603 23 +206TL2 G KC=0.0855 12$LC=0.0561 8$MC=0.01440 21 +206TL L 304.896 6 1- 4.2 PS 14 +206TL A 4650 4 60 6 49 +206TL G 304.896 6 6.1E-5 7 M1 0.375 6 +206TL2 G KC=0.308 5$LC=0.0519 8$MC=0.01211 17 + +210PO 210BI B- DECAY (5.011 D) +210PO H TYP=UPD$AUT=M.A.Kellett$CUT=01-OCT-2014$ +210PO2 H TYP=FUL$AUT=V. Chiste. M.-M.Be$CUT=31-JAN-2008$ +210PO C Evaluation history: Type=UPD;Author=M.A.Kellett;Cutoff date=01-OCT-2014 +210PO2C Type=FUL;Author=V. Chiste. M.-M.Be;Cutoff date=31-JAN-2008 +210PO C References: 1935Po01, 1935Po01, 1939Fl02, 1939Fl02, 1940Ne04, 1940Ne04, +210PO2C 1944Hole, 1947Br36, 1947Br36, 1952Be22, 1952Be22, 1953Lo09, 1953Lo09, +210PO3C 1954Pl30, 1954Pl30, 1956Fi09, 1956Ro18, 1956Ro18, 1956Fi09, 1959Ro51, +210PO4C 1959Wa05, 1959Wa05, 1959Ro51, 1960Wa14, 1960Wa14, 1961Ru02, 1961Ru02, +210PO5C 1961Nu01, 1961Nu01, 1962Da03, 1962Ka27, 1962Ka27, 1962Da03, 1967Hs01, +210PO6C 1967Hs01, 1969Fl02, 1969Fl02, 1969La18, 1969La18, 1991Ry01, 1991Ry01, +210PO7C 1996Sc06, 1996Sc06, 1999Br39, 2002Ba85, 2002Ba85, 2003Br13, 2003Au03, +210PO8C 2003Br13, 2005Gr41, 2008BeZV, 2008Ki07, 2008Ko21, 2010MoZU, 2012Wa38 +210PO T Auger electrons and ^X ray energies and emission intensities: +210PO T {U Energy (keV)} {U Intensity } {U Line } +210PO T +210PO T 76.864 XKA2 +210PO T 79.293 XKA1 +210PO T +210PO T 89.256 |] XKB3 +210PO T 89.807 |] XKB1 +210PO T 90.363 |] XKB5II +210PO T +210PO T 92.263 |] XKB2 +210PO T 92.618 |] XKB4 +210PO T 92.983 |] XKO23 +210PO T +210PO T +210PO T 58.978-65.205 |] KLL AUGER +210PO T 71.902-79.289 |] ^KLX AUGER +210PO T 84.8-93.1 |] KXY AUGER +210PO T 5.506-16.864 L AUGER +210BI P 0.0 1- 5.011 D 5 1161.2 8 +210PO N 1.00E0 1.00E0 0.9999982 1.00E0 +210PO L 0 0+ 138.3763 D17 +210PO B 1161.2 8 10000E-22 8 1 +210POS B EAV=317 3 + diff --git a/HEN_HOUSE/spectra/lnhb/Bi-211.txt b/HEN_HOUSE/spectra/lnhb/Bi-211.txt new file mode 100644 index 000000000..03b18ab75 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Bi-211.txt @@ -0,0 +1,72 @@ +207TL 211BI A DECAY (2.15 M) +207TL H TYP=Full$AUT=A.Luca$CUT=31-DEC-2008$ +207TL C Evaluation history: Type=Full;Author=A.Luca;Cutoff date=31-DEC-2008 +207TL C References: 1931CU01, 1954SP32, 1962Wa18, 1962Gi04, 1965NU03, 1966Go13, +207TL2C 1967Da10, 1968Br17, 1970MU21, 1971Ko37, 1971Gr17, 1973UrZX, 1975VaYT, +207TL3C 1976Bl13, 1982Mo30, 1988Hi14, 1989It01, 1991Ry01, 1992Sc26, 1993Ma73, +207TL4C 2003Au03, 2004Br45, 2008Ki07 +207TL T Auger electrons and ^X ray energies and emission intensities: +207TL T {U Energy (keV)} {U Intensity } {U Line } +207TL T +207TL T 70.8325 0.726 16 XKA2 +207TL T 72.8725 1.225 27 XKA1 +207TL T +207TL T 82.118 |] XKB3 +207TL T 82.577 |] 0.417 11 XKB1 +207TL T 83.115 |] XKB5II +207TL T +207TL T 84.838 |] XKB2 +207TL T 85.134 |] 0.124 4 XKB4 +207TL T 85.444 |] XKO23 +207TL T +207TL T 8.9531-14.7362 0.929 19 XL (total) +207TL T 8.9531 0.0228 7 XLL +207TL T 10.1718-10.2679 0.438 12 XLA +207TL T 10.9942 0.00696 22 XLC +207TL T 11.8117-12.9566 0.388 9 XLB +207TL T 13.8528-14.7362 0.0724 18 XLG +207TL T +207TL T 54.587-59.954 |] KLL AUGER +207TL T 66.37-72.86 |] 0.096 11 ^KLX AUGER +207TL T 78.12-85.5 |] KXY AUGER +207TL T 5.18-15.31 1.617 21 L AUGER +211BI P 0.0 9/2- 2.15 M 2 6750.33 46 +207TL N 1.003E0 1.003E0 0.99724 4 1.003E0 +207TL L 0 1/2+ 4.774 M 12 +207TL A 6622.4 6 83.79 23187 +207TL L 351.03 4 3/2+ 30 PS 7 +207TL A 6278.5 9 16.20 2343 +207TL G 351.03 4 13.00 19M1+E2 0.271 4 0.243 4 +207TL2 G KC=0.199 3$LC=0.0342 5$MC=0.00801 12 + +211PO 211BI B- DECAY (2.15 M) +211PO H TYP=Full$AUT=A.Luca$CUT=31-DEC-2008$ +211PO C Evaluation history: Type=Full;Author=A.Luca;Cutoff date=31-DEC-2008 +211PO C References: 1931CU01, 1954SP32, 1962Wa18, 1962Gi04, 1965NU03, 1966Go13, +211PO2C 1967Da10, 1968Br17, 1970MU21, 1971Ko37, 1971Gr17, 1973UrZX, 1975VaYT, +211PO3C 1976Bl13, 1982Mo30, 1988Hi14, 1989It01, 1991Ry01, 1992Sc26, 1993Ma73, +211PO4C 2003Au03, 2004Br45, 2008Ki07 +211PO T Auger electrons and ^X ray energies and emission intensities: +211PO T {U Energy (keV)} {U Intensity } {U Line } +211PO T +211PO T 76.864 XKA2 +211PO T 79.293 XKA1 +211PO T +211PO T 89.256 |] XKB3 +211PO T 89.807 |] XKB1 +211PO T 90.363 |] XKB5II +211PO T +211PO T 92.263 |] XKB2 +211PO T 92.618 |] XKB4 +211PO T 92.983 |] XKO23 +211PO T +211PO T +211PO T 58.978-65.205 |] KLL AUGER +211PO T 71.902-79.289 |] ^KLX AUGER +211PO T 84.8-93.1 |] KXY AUGER +211BI P 0.0 9/2- 2.15 M 2 574 5 +211PO N 3.623E2 3.623E2 0.00276 3.623E2 +211PO L 0 9/2+ 0.516 S 3 +211PO B 574 5 0.276 4 5.99 +211POS B EAV=172.9 18 + diff --git a/HEN_HOUSE/spectra/lnhb/Bi-212.txt b/HEN_HOUSE/spectra/lnhb/Bi-212.txt new file mode 100644 index 000000000..ea5d9296e --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Bi-212.txt @@ -0,0 +1,158 @@ +208TL 212BI A DECAY (60.54 M) +208TL H TYP=Update$AUT=A.L. Nichols$CUT=30-MAY-2010$ +208TL2 H TYP=Full$AUT=A.L. Nichols$CUT=30-NOV-2003$ +208TL C Evaluation history: Type=Update;Author=A.L. Nichols;Cutoff date=30-MAY-2010 +208TL2C Type=Full;Author=A.L. Nichols;Cutoff date=30-NOV-2003 +208TL C References: 1914Le01, 1951Ry17, 1957Bu34, 1960Wa14, 1960Em01, 1960Sc07, +208TL2C 1961Ap03, 1962Fl03, 1962Be09, 1965Wa09, 1965Le08, 1966KlZZ, 1967Be19, +208TL3C 1968Yt02, 1972DaZA, 1973Da38, 1977La19, 1978Av01, 1982Be09, 1982Sa36, +208TL4C 1983Sc13, 1983Va22, 1984Ge07, 1992Li05, 1996Sc06, 1998ScZM, 1999ScZX, +208TL5C 2002Ra45, 2002Ba85, 2003Au03, 2005Br03, 2007St23, 2007Ma45, 2008Ki07 +208TL T Auger electrons and ^X ray energies and emission intensities: +208TL T {U Energy (keV)} {U Intensity } {U Line } +208TL T +208TL T 70.8325 0.0525 23 XKA2 +208TL T 72.8725 0.089 4 XKA1 +208TL T +208TL T 82.118 |] XKB3 +208TL T 82.577 |] 0.0301 14 XKB1 +208TL T 83.115 |] XKB5II +208TL T +208TL T 84.838 |] XKB2 +208TL T 85.134 |] 0.0089 5 XKB4 +208TL T 85.444 |] XKO23 +208TL T +208TL T 8.953-14.738 7.1 3 XL (total) +208TL T 8.953 0.171 6 XLL +208TL T 10.172-10.268 3.3 1 XLA +208TL T 10.994 0.0230 7 XLC +208TL T 11.812-12.643 2.76 5 XLB +208TL T 14.291-14.738 0.579 9 XLG +208TL T +208TL T 54.587-59.954 |] KLL AUGER +208TL T 66.37-72.86 |] 0.0069 8 ^KLX AUGER +208TL T 78.12-85.5 |] KXY AUGER +208TL T 5.182-10.132 12.2 4 L AUGER +212BI P 0.0 1- 60.54 M 6 6207.26 3 +208TL N 2.783E0 2.783E0 0.3593 2.783E0 +208TL L 0 5+ 3.058 M 6 +208TL A 0 +208TL A 6090.14 3 27.00 28481 +208TL L 39.858 4 4+ +208TL A 6051.04 3 69.86 28126 +208TL G 39.858 4 1.07 1 [M1] 23.3 4 +208TL2 G KC=$LC=17.81 25$MC=4.17 6 +208TL L 328.04 5 5+ +208TL A 5768.29 6 1.70 8 279 +208TL G 288.18 5 0.32 2 M1+E2 0.08 0.436 7 +208TL2 G KC=0.357 5$LC=0.0605 9$MC=0.01411 20 +208TL G 328.04 5 0.121 3 [M1] 0.308 5 +208TL2 G KC=0.252 4$LC=0.0425 6$MC=0.00991 14 +208TL L 473.4 4 (4)+ +208TL A 5625.7 4 0.167 8 595 +208TL G 433.5 4 0.011 1 [M1] 0.1453 21 +208TL2 G KC=0.1193 17$LC=0.0199 3$MC=0.00465 7 +208TL G 473.4 4 0.044 3 [M1+E2] 1.0 2 0.074 10 +208TL2 G KC=0.059 8$LC=0.0115 10$MC=0.00273 21 +208TL L 492.84 4 (3)+ +208TL A 5606.60 5 1.20 8 67 +208TL G 164.80 6 0.0055 6 (E2) 0.816 12 +208TL2 G KC=0.263 4$LC=0.413 6$MC=0.1078 16 +208TL G 452.98 4 0.34 3 (M1) 0.1293 18 +208TL2 G KC=0.1061 15$LC=0.01772 25$MC=0.00413 6 +208TL G 492.84 4 0.039 10E2 0.0291 4 +208TL2 G KC=0.0207 3$LC=0.00633 9$MC=1567E-6 22 +208TL L 617 2 + +208TL L 620.4 3 (6)+ +208TL A 5481.4 3 0.0139 111380 +208TL G 580.5 3 0.0011 2 E2 0.0198 3 +208TL2 G KC=0.01470 21$LC=0.00388 6$MC=9.50E-4 14 +208TL G 620.4 3 0.0038 4 [M1+E2] 1.0 2 0.037 5 +208TL2 G KC=0.030 4$LC=0.0054 5$MC=0.00129 12 +208TL L 760 2 + +208TL A 5344 2 0.00100 8 3770 +208TL L 803 2 + +208TL A 5302 2 11100E-81120300 + +212PO 212BI B- DECAY (60.54 M) +212PO H TYP=Update$AUT=A.L. Nichols$CUT=30-MAY-2010$ +212PO2 H TYP=Full$AUT=A.L. Nichols$CUT=30-NOV-2003$ +212PO C Evaluation history: Type=Update;Author=A.L. Nichols;Cutoff date=30-MAY-2010 +212PO2C Type=Full;Author=A.L. Nichols;Cutoff date=30-NOV-2003 +212PO C References: 1914Le01, 1951Ry17, 1957Bu34, 1960Wa14, 1960Em01, 1960Sc07, +212PO2C 1961Ap03, 1962Fl03, 1962Be09, 1965Wa09, 1965Le08, 1966KlZZ, 1967Be19, +212PO3C 1968Yt02, 1972DaZA, 1973Da38, 1977La19, 1978Av01, 1982Be09, 1982Sa36, +212PO4C 1983Sc13, 1983Va22, 1984Ge07, 1992Li05, 1996Sc06, 1998ScZM, 1999ScZX, +212PO5C 2002Ra45, 2002Ba85, 2003Au03, 2005Br03, 2007St23, 2007Ma45, 2008Ki07 +212PO T Auger electrons and ^X ray energies and emission intensities: +212PO T {U Energy (keV)} {U Intensity } {U Line } +212PO T +212PO T 76.864 0.0388 8 XKA2 +212PO T 79.293 0.0647 13 XKA1 +212PO T +212PO T 89.256 |] XKB3 +212PO T 89.807 |] 0.0223 6 XKB1 +212PO T 90.363 |] XKB5II +212PO T +212PO T 92.263 |] XKB2 +212PO T 92.618 |] 0.00693 20 XKB4 +212PO T 92.983 |] XKO23 +212PO T +212PO T 9.658-16.213 0.0563 24 XL (total) +212PO T 9.658 0.00138 4 XLL +212PO T 11.016-11.13 0.0253 7 XLA +212PO T 12.085 0.000440 13 XLC +212PO T 12.823-13.778 0.0241 6 XLB +212PO T 15.742-16.213 0.00477 11 XLG +212PO T +212PO T 58.978-65.205 |] KLL AUGER +212PO T 71.902-79.289 |] 0.0048 6 ^KLX AUGER +212PO T 84.8-93.1 |] KXY AUGER +212PO T 5.434-10.934 0.0833 25 L AUGER +212BI P 0.0 1- 60.54 M 6 2252.1 17 +212PO N 1.561E0 1.561E0 0.6407 1.561E0 +212PO L 0 0+ 300 NS 2 +212PO B 2252.1 1755.31 9 7.267 1 +212POS B EAV=834.2 7 +212PO L 727.330 9 2+ +212PO B 1524.8 174.50 6 7.718 1 +212POS B EAV=533.1 7 +212PO G 727.330 9 6.65 4 E2 0.0139320 +212PO2 G KC=0.01054 15$LC=0.00257 4$MC=6.28E-4 9 +212PO L 1512.70 8 2+ +212PO B 739.4 171.44 1 7.094 1 +212POS B EAV=230.8 6 +212PO G 785.37 9 1.11 1 M1+E2 0.09 0.0387 6 +212PO2 G KC=0.0316 5$LC=0.00539 8$MC=1266E-6 18 +212PO G 1512.70 8 0.29 1 E2 0.003445 +212PO2 G KC=0.00274 4$LC=4.83E-4 7$MC=1139E-7 16 +212PO L 1620.738 101+ +212PO B 631.4 171.90 3 6.74 +212POS B EAV=192.7 6 +212PO G 893.408 140.38 1 M1+E2 0.045 0.0278 4 +212PO2 G KC=0.0227 4$LC=0.00386 6$MC=9.06E-4 13 +212PO G 1620.738 101.51 3 [M1] 0.006209 +212PO2 G KC=0.00494 7$LC=8.24E-4 12$MC=1.93E-4 3 +212PO L 1679.450 142+ +212PO B 572.7 170.21 4 7.55 1 +212POS B EAV=172.4 6 +212PO G 952.12 2 0.14 4 M1+E2 0.65 0.0190 3 +212PO2 G KC=0.01548 22$LC=0.00269 4$MC=6.34E-4 9 +212PO G 1679.450 140.07 1 E2 0.002914 +212PO2 G KC=0.00227 4$LC=3.91E-4 6$MC=9.20E-5 13 +212PO L 1800.9 2 0+ +212PO B 451.2 170.032 4 8.03 1 +212POS B EAV=131.7 6 +212PO G 180.2 2 0.0031 12M1 2.08 3 +212PO2 G KC=1.692 25$LC=0.298 5$MC=0.0704 10 +212PO G 1073.6 2 0.0154 6 E2 0.006429 +212PO2 G KC=0.00510 8$LC=1002E-6 14$MC=2.40E-4 4 +212PO G 1800.9 2 +212PO L 1805.96 102+ +212PO B 446.1 170.68 4 6.67 1 +212POS B EAV=130.1 6 +212PO G 1078.63 100.55 2 M1+E2 0.135 0.0169224 +212PO2 G KC=0.01386 20$LC=0.00234 4$MC=5.49E-4 8 +212PO G 1805.96 100.12 3 E2 0.002614 +212PO2 G KC=0.00200 3$LC=3.38E-4 5$MC=7.94E-5 12 + diff --git a/HEN_HOUSE/spectra/lnhb/Bi-213.txt b/HEN_HOUSE/spectra/lnhb/Bi-213.txt new file mode 100644 index 000000000..725d3f152 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Bi-213.txt @@ -0,0 +1,119 @@ +209TL 213BI A DECAY (45.59 M) +209TL H TYP=Full$AUT=X. Huang$CUT=30-JAN-2006$ +209TL C Evaluation history: Type=Full;Author=X. Huang;Cutoff date=30-JAN-2006 +209TL T Auger electrons and ^X ray energies and emission intensities: +209TL T {U Energy (keV)} {U Intensity } {U Line } +209TL T +209TL T 70.8325 0.0058 7 XKA2 +209TL T 72.8725 0.0098 12 XKA1 +209TL T +209TL T 82.118 |] XKB3 +209TL T 82.577 |] 0.0033 5 XKB1 +209TL T 83.115 |] XKB5II +209TL T +209TL T 84.838 |] XKB2 +209TL T 85.134 |] 0.00098 14 XKB4 +209TL T 85.444 |] XKO23 +209TL T +209TL T 8.9531-14.7362 0.0062 8 XL (total) +209TL T 8.9531 XLL +209TL T 10.1718-10.2679 XLA +209TL T 10.9942 XLC +209TL T 11.8117-12.9566 XLB +209TL T 13.8528-14.7362 XLG +209TL T +209TL T 54.587-59.954 |] KLL AUGER +209TL T 66.37-72.86 |] 0.00076 9 ^KLX AUGER +209TL T 78.12-85.5 |] KXY AUGER +209TL T 5.18-10.13 0.0107 13 L AUGER +213BI P 0.0 9/2- 45.59 M 6 5983 6 +209TL N 4.785E1 4.785E1 0.0209 3 4.785E1 +209TL L 0 1/2+ 2.161 M 7 +209TL A 5869 1090.9 19319 +209TL L 323.70 2 3/2+ +209TL A 5549 108.90 24103 +209TL G 323.70 2 0.1584 24M1+E2 1.26 16 0.178 15 +209TL2 G KC=0.134 14$LC=0.0333 13$MC=0.0081 3 + +213PO 213BI B- DECAY (45.59 M) +213PO H TYP=Full$AUT=X. Huang$CUT=30-JAN-2006$ +213PO C Evaluation history: Type=Full;Author=X. Huang;Cutoff date=30-JAN-2006 +213PO T Auger electrons and ^X ray energies and emission intensities: +213PO T {U Energy (keV)} {U Intensity } {U Line } +213PO T +213PO T 76.864 1.103 29 XKA2 +213PO T 79.293 1.84 5 XKA1 +213PO T +213PO T 89.256 |] XKB3 +213PO T 89.807 |] 0.633 19 XKB1 +213PO T 90.363 |] XKB5II +213PO T +213PO T 92.263 |] XKB2 +213PO T 92.618 |] 0.197 7 XKB4 +213PO T 92.983 |] XKO23 +213PO T +213PO T 9.6576-16.2129 1.54 4 XL (total) +213PO T 9.6576 0.0387 13 XLL +213PO T 11.0161-11.1303 0.710 21 XLA +213PO T 12.0847 0.0116 4 XLC +213PO T 12.8239-14.2476 0.653 16 XLB +213PO T 15.251-16.2129 0.128 4 XLG +213PO T +213PO T 58.978-65.205 |] KLL AUGER +213PO T 71.902-79.289 |] 0.137 16 ^KLX AUGER +213PO T 84.8-93.1 |] KXY AUGER +213PO T 5.43-16.86 2.31 4 L AUGER +213BI P 0.0 9/2- 45.59 M 6 1423 5 +213PO N 1.021E0 1.021E0 0.9791 3 1.021E0 +213PO L 0 9/2+ 3.70 US 5 +213PO B 1423 5 66.2 4 6.316 +213POS B EAV=492.2 20 +213PO L 292.796 8 11/2+ 78 PS 14 +213PO B 1130 5 0.21 9 8.45 1U +213POS B EAV=376.8 20 +213PO G 292.80 1 0.421 7 M1+E2 1.2 8 0.30 18 +213PO2 G KC=0.22 17$LC=0.06 2$MC=1.5E-5 3 +213PO L 440.439 9 7/2+ 93 PS 3 +213PO B 983 5 30.8 4 6.07 1U +213POS B EAV=320.4 19 +213PO G 147.70 4 0.0128 8 E2 1.453 21 +213PO2 G KC=0.307 4$LC=0.85 1$MC=2.26E-4 3 +213PO G 440.44 1 26.1 3 M1 0.179 3 +213PO2 G KC=0.146 2$LC=0.0250 4$MC=0.00594 8 +213PO L 600.8 3 (5/2)+ +213PO B 822 5 0.0025 19 9.9 3U +213POS B EAV=260.8 19 +213PO G 600.9 2 0.0026 19 +213PO L 867.961 2013/2+ +213PO B 555 5 0.0129 6 8.597 3U +213POS B EAV=166.4 17 +213PO G 574.9 3 0.00068 16 +213PO G 867.96 2 0.0122 6 +213PO L 1003.593 17(9/2)+ +213PO B 419 5 0.0648 23 7.494 +213POS B EAV=121.4 17 +213PO G 402.8 3 0.00010 4 +213PO G 710.82 3 0.0112 6 +213PO G 1003.58 2 0.0535 22 +213PO L 1045.62 8 (2/9,11/2)+ +213PO B 377 5 0.020 4 7.85 +213POS B EAV=107.9 16 +213PO G 604.93 170.0014 5 +213PO G 1045.67 8 0.019 4 +213PO L 1100.168 8 7/2,9/2,11/2- +213PO B 323 5 0.595 17 6.16 2 +213POS B EAV=90.8 16 +213PO G 659.75 2 0.043 6 +213PO G 807.37 1 0.287 14 +213PO G 1100.16 1 0.265 6 +213PO L 1119.36 4 7/2,9/2,11/2+ +213PO B 304 5 0.0608 20 7.07 1U +213POS B EAV=84.9 16 +213PO G 826.55 4 0.0065 4 +213PO G 1119.42 8 0.0543 20 +213PO L 1328.2 3 (7/2,9/2,11/2)- +213PO B 95 5 0.0014 2 7.68 2 +213POS B EAV=24.6 14 +213PO G 886.66 140.00102 19 +213PO G 1328.2 3 0.00039 13 + diff --git a/HEN_HOUSE/spectra/lnhb/Bi-214.txt b/HEN_HOUSE/spectra/lnhb/Bi-214.txt new file mode 100644 index 000000000..00f26890d --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Bi-214.txt @@ -0,0 +1,570 @@ +210TL 214BI A DECAY (19.8 M) +210TL H TYP=Full$AUT=V.Chisté$CUT=31-JAN-2007$ +210TL C Evaluation history: Type=Full;Author=V.Chisté;Cutoff date=31-JAN-2007 +210TL C References: 1934Le01, 1951Co15, 1954Br07, 1956Da06, 1960Wa14, 1965Le08, +210TL2C 1969Gu15, 1969Li10, 1969Wa27, 1969Gr33, 1974Ha68, 1975Ha31, 1977Zo01, +210TL3C 1978Ro21, 1979He13, 1979Be12, 1981Mo28, 1982Ak03, 1982Fa10, 1983Sc13, +210TL4C 1983Ol01, 1990Mo08, 1990Co08, 1990Mo**, 1991Li11, 1993Di09, 1995El07, +210TL5C 1996Sc06, 1998Mo14, 2000Sa32, 2002Ba85, 2002De03, 2003Br13, 2002MoZP, +210TL6C 2003Au03, 2004Mo07, 2007BeZP +214BI P 0.0 1- 19.8 M 1 5621 3 +210TL N 4.762E3 4.762E3 0.00021 4.762E3 +210TL G 230 1 0.0029 10 0.0585 11 +210TL G 304.2 2 0.0255 23 0.30 19 +210TL G 334.78 8 0.033 5 +210TL G 630.79 7 0.0166 14 +210TL G 1226.7 3 0.018 8 +210TL L 0 + 1.30 M 3 +210TL A 0 +210TL A 5516 3 39.0 24370 +210TL L 62.5 10 + +210TL A 5452 3 55.2 33130 +210TL G 62.5 100.0116 7 (M1) +210TL L 253.6 15 + +210TL A 5273 9 5.95 33130 +210TL G 191.1 180.00125 7 +210TL L 335 3 + +210TL A 5184 3 0.619 48450 +210TL L 499 4 + +210TL A 5023 3 0.214 14160 +210TL L 583 4 + +210TL A 4941 3 0.248 1445 + +214PO 214BI B- DECAY (19.8 M) +214PO H TYP=Full$AUT=V.Chisté$CUT=31-JAN-2007$ +214PO C Evaluation history: Type=Full;Author=V.Chisté;Cutoff date=31-JAN-2007 +214PO C References: 1934Le01, 1951Co15, 1954Br07, 1956Da06, 1960Wa14, 1965Le08, +214PO2C 1969Gu15, 1969Li10, 1969Wa27, 1969Gr33, 1974Ha68, 1975Ha31, 1977Zo01, +214PO3C 1978Ro21, 1979He13, 1979Be12, 1981Mo28, 1982Ak03, 1982Fa10, 1983Sc13, +214PO4C 1983Ol01, 1990Mo08, 1990Co08, 1990Mo**, 1991Li11, 1993Di09, 1995El07, +214PO5C 1996Sc06, 1998Mo14, 2000Sa32, 2002Ba85, 2002De03, 2003Br13, 2002MoZP, +214PO6C 2003Au03, 2004Mo07, 2007BeZP +214PO T Auger electrons and ^X ray energies and emission intensities: +214PO T {U Energy (keV)} {U Intensity } {U Line } +214PO T +214PO T 76.864 0.426 13 XKA2 +214PO T 79.293 0.710 22 XKA1 +214PO T +214PO T 89.256 |] XKB3 +214PO T 89.807 |] 0.244 9 XKB1 +214PO T 90.363 |] XKB5II +214PO T +214PO T 92.263 |] XKB2 +214PO T 92.618 |] 0.0760 29 XKB4 +214PO T 92.983 |] XKO23 +214PO T +214PO T 9.66-16.21 0.627 15 XL (total) +214PO T 9.66 0.0153 6 XLL +214PO T 11.016-11.13 0.281 9 XLA +214PO T 12.085 0.00502 18 XLC +214PO T 12.824-14.248 0.272 7 XLB +214PO T 15.251-16.21 0.0541 14 XLG +214PO T +214PO T 58.97-65.2 |] KLL AUGER +214PO T 71.93-76.6 |] 0.053 7 ^KLX AUGER +214PO T 84.72-93.04 |] KXY AUGER +214PO T 5.43-16.86 0.934 16 L AUGER +214BI P 0.0 1- 19.8 M 1 3270 11 +214PO N 1.00E0 1.00E0 0.99979 1.00E0 +214PO G 230 1 0.0029 10 0.0585 11 +214PO G 304.2 2 0.0255 23 0.30 19 +214PO G 334.78 8 0.033 5 +214PO G 630.79 7 0.0166 14 +214PO G 1226.7 3 0.018 8 +214PO L 0 0+ 162.3 US 12 +214PO B 3270 1119.67 20 7.9 1 +214POS B EAV=1270 5 +214PO L 609.316 7 2+ +214PO B 2661 110.62 20 9 1 +214POS B EAV=1008 5 +214PO G 609.312 7 45.49 19E2 0.0204 3 +214PO2 G KC=0.01487 21$LC=0.00416 6$MC=1030E-6 15 +214PO L 1015.05 4 (4)+ +214PO G 405.74 3 0.171 7 [E2] 0.0541 8 +214PO2 G KC=0.0344 5$LC=0.01478 21$MC=0.00377 6 +214PO L 1274.761 22(3)- +214PO G 665.453 221.530 7 E1 0.005799 +214PO2 G KC=0.00479 7$LC=7.67E-4 11$MC=1.79E-4 3 +214PO L 1377.675 122+ +214PO B 1892 117.45 5 7.4 1 +214POS B EAV=685 5 +214PO G 768.356 104.892 16M1+E2 2.8 7 0.0157 21 +214PO2 G KC=0.0122 18$LC=0.0026 3$MC=0.00063 6 +214PO G 1377.669 123.968 11E2 0.004046 +214PO2 G KC=0.00324 5$LC=5.85E-4 9$MC=1385E-7 20 +214PO L 1415.489 190+ 99 PS 3 +214PO B 1855 110.396 46 8.6 1 +214POS B EAV=669 5 +214PO G 806.174 181.262 6 E2 0.0112716 +214PO2 G KC=0.00867 13$LC=0.00197 3$MC=4.80E-4 7 +214PO L 1543.375 142+ +214PO B 1727 113.12 4 7.6 1 +214POS B EAV=616 5 +214PO G 268.8 2 0.0161 18[E1] 0.0405 6 +214PO2 G KC=0.0329 5$LC=0.00577 9$MC=1359E-6 20 +214PO G 528 1 0.0109 13[E2] 0.0282 5 +214PO2 G KC=0.0198 3$LC=0.00633 10$MC=1584E-6 24 +214PO G 934.061 123.10 1 M1+E2 -0.3 1 0.0234 10 +214PO2 G KC=0.0192 8$LC=0.00327 13$MC=0.00077 3 +214PO G 1543.32 6 0.302 13[E2] 0.003335 +214PO2 G KC=0.00265 4$LC=4.63E-4 7$MC=1093E-7 16 +214PO L 1661.28 3 2+ +214PO B 1609 110.65 6 8.2 1 +214POS B EAV=568 4 +214PO G 1051.96 3 0.324 8 [M1E2] 0.012 6 +214PO2 G KC=0.010 5$LC=0.0018 8$MC=0.00042 17 +214PO G 1661.28 6 1.048 9 E2 0.002965 +214PO2 G KC=0.00232 4$LC=3.99E-4 6$MC=9.40E-5 14 +214PO L 1712.93 20(3)+ +214PO B 1557 110.170 16 8.7 1U +214POS B EAV=547 4 +214PO G 697.90 250.067 4 [M1E2] 0.034 19 +214PO2 G KC=0.027 16$LC=0.0051 23$MC=0.0012 6 +214PO G 1103.64 190.106 15[M1E2] 0.011 5 +214PO2 G KC=0.009 5$LC=0.0016 7$MC=0.00037 15 +214PO L 1729.611 132+ +214PO B 1540 1117.494 36 6.7 1 +214POS B EAV=540 4 +214PO G 454.770 120.288 5 [E1] 0.0125118 +214PO2 G KC=0.01028 15$LC=1706E-6 24$MC=3.99E-4 6 +214PO G 1120.287 1014.91 3 M1+E2 0.18 2 0.0152223 +214PO2 G KC=0.01246 19$LC=0.00210 3$MC=4.94E-4 8 +214PO G 1729.595 152.844 10E2 0.002784 +214PO2 G KC=0.00216 3$LC=3.68E-4 6$MC=8.66E-5 13 +214PO L 1742.98 3 0+ +214PO B 1527 110.116 16 8.8 1 +214POS B EAV=535 4 +214PO G 1133.66 3 0.254 8 [E2] 0.005788 +214PO2 G KC=0.00462 7$LC=8.88E-4 13$MC=2.12E-4 3 +214PO L 1764.498 141+ +214PO B 1506 1117.10 8 6.6 +214POS B EAV=526 4 +214PO G 221 1 0.059 6 [M1E2] 0.8 5 +214PO2 G KC=0.5 5$LC=0.158 10$MC=0.0394 9 +214PO G 348.92 6 0.123 32[M1] 0.335 5 +214PO2 G KC=0.272 4$LC=0.0475 7$MC=0.01118 16 +214PO G 386.77 5 0.296 5 [M1E2] 0.16 10 +214PO2 G KC=0.12 9$LC=0.027 10$MC=0.0065 20 +214PO G 1155.19 2 1.635 7 M1+E2 0.33 6 0.0135 4 +214PO2 G KC=0.0110 3$LC=0.00187 5$MC=4.38E-4 11 +214PO G 1764.494 1415.31 5 M1 0.005118 +214PO2 G KC=0.00397 6$LC=6.61E-4 10$MC=1548E-7 22 +214PO L 1847.431 142+ +214PO B 1423 118.147 28 6.9 1 +214POS B EAV=493 4 +214PO G 469.76 7 0.133 15[M1E2] 0.09 6 +214PO2 G KC=0.07 5$LC=0.015 6$MC=0.0036 14 +214PO G 572.76 7 0.071 8 [E1] 0.0077911 +214PO2 G KC=0.00643 9$LC=1042E-6 15$MC=2.43E-4 4 +214PO G 832.39 110.035 2 [E2] 0.0105715 +214PO2 G KC=0.00816 12$LC=0.00182 4$MC=4.42E-4 7 +214PO G 1238.111 125.831 14M1+E2 -0.03 3 0.0120017 +214PO2 G KC=0.00983 14$LC=1651E-6 24$MC=3.87E-4 6 +214PO G 1847.420 252.025 12 +214PO L 1890.287 212+ +214PO B 1380 111.584 10 7.5 1 +214POS B EAV=476 4 +214PO G 615.73 100.055 7 [E1] 0.0067410 +214PO2 G KC=0.00557 8$LC=8.98E-4 13$MC=2.09E-4 3 +214PO G 1280.96 2 1.435 6 M1 0.0110116 +214PO2 G KC=0.00901 13$LC=1513E-6 22$MC=3.55E-4 5 +214PO G 1890.30 150.078 4 +214PO L 1994.63 3 (2)- +214PO B 1275 111.171 18 7.5 +214POS B EAV=434 4 +214PO G 333.350 420.063 4 [E1] 0.0247 4 +214PO2 G KC=0.0202 3$LC=0.00345 5$MC=8.11E-4 12 +214PO G 617.0 2 0.027 5 [E1] 0.0067210 +214PO2 G KC=0.00555 8$LC=8.94E-4 13$MC=2.09E-4 3 +214PO G 719.86 3 0.393 10E2 0.0142420 +214PO2 G KC=0.01075 15$LC=0.00264 4$MC=6.46E-4 9 +214PO G 1385.31 3 0.795 5 [E1] 1631E-623 +214PO2 G KC=1281E-6 18$LC=1.96E-4 3$MC=4.53E-5 7 +214PO L 2010.81 4 2+ +214PO B 1259 111.430 9 7.4 1 +214POS B EAV=428 4 +214PO G 595.23 7 0.0174 15[M1E2] 0.05 3 +214PO2 G KC=0.04 3$LC=0.008 4$MC=0.0019 8 +214PO G 633.14 100.055 3 [M1E2] 0.044 25 +214PO2 G KC=0.035 21$LC=0.007 3$MC=0.0016 7 +214PO G 1401.50 4 1.330 7 (M1+E2) 1.6 5 0.0053 9 +214PO2 G KC=0.0043 7$LC=0.00074 11$MC=0.00017 3 +214PO G 2010.78 120.0434 17 +214PO L 2017.30 5 0+ +214PO B 1253 112.449 10 7.2 1 +214POS B EAV=425 4 +214PO G 252.80 6 0.0117 18[M1] 0.809 12 +214PO2 G KC=0.658 10$LC=0.1154 17$MC=0.0272 4 +214PO G 639.67 100.034 5 [E2] 0.0183 3 +214PO2 G KC=0.01351 19$LC=0.00363 5$MC=8.95E-4 13 +214PO G 1407.98 4 2.389 8 (E2) 0.003896 +214PO2 G KC=0.00312 5$LC=5.59E-4 8$MC=1323E-7 19 +214PO L 2088.41 12(1-),(1,2)+ +214PO B 1182 110.114 6 8.4 +214POS B EAV=398 4 +214PO G 710.67 100.076 4 +214PO G 1479.15 140.051 4 +214PO L 2118.552 171+ +214PO B 1151 114.339 18 6.8 +214POS B EAV=386 4 +214PO G 388.88 5 0.394 5 (M1) 0.250 4 +214PO2 G KC=0.203 3$LC=0.0353 5$MC=0.00832 12 +214PO G 703.11 4 0.479 11[M1] 0.0519 8 +214PO2 G KC=0.0424 6$LC=0.00724 11$MC=1702E-6 24 +214PO G 740.73 180.0428 21[M1E2] 0.029 16 +214PO2 G KC=0.024 14$LC=0.0044 20$MC=0.0010 5 +214PO G 1509.228 152.128 10M1+E2 -0.053 35 0.0073211 +214PO2 G KC=0.00591 9$LC=9.88E-4 14$MC=2.32E-4 4 +214PO G 2118.55 3 1.158 5 M1 0.003565 +214PO2 G KC=0.00248 4$LC=4.12E-4 6$MC=9.64E-5 14 +214PO L 2147.78 6 1(-),2+ +214PO B 1122 110.433 22 7.8 +214POS B EAV=375 4 +214PO G 873.07 190.019 3 +214PO G 1538.50 6 0.401 22 +214PO G 2147.9 2 0.0134 13 +214PO L 2192.56 4 2+ +214PO B 1077 110.851 10 7.4 1 +214POS B EAV=357 4 +214PO G 649.18 7 0.054 7 [M1E2] 0.041 24 +214PO2 G KC=0.033 20$LC=0.006 3$MC=0.0015 7 +214PO G 815.0 1 0.039 3 [M1E2] 0.023 13 +214PO2 G KC=0.019 11$LC=0.0034 15$MC=0.0008 4 +214PO G 917.8 3 0.005 3 [E1] 0.003175 +214PO2 G KC=0.00263 4$LC=4.11E-4 6$MC=9.56E-5 14 +214PO G 1583.22 4 0.707 5 M1+E2 -0.2 1 0.0064218 +214PO2 G KC=0.00513 14$LC=8.58E-4 23$MC=2.01E-4 6 +214PO G 2192.58 160.038 3 +214PO L 2204.13 9 1+ +214PO B 1066 115.642 43 6.6 +214POS B EAV=353 4 +214PO G 461.0 2 0.058 8 [M1] 0.1581 23 +214PO2 G KC=0.1289 19$LC=0.0223 4$MC=0.00525 8 +214PO G 474.41 5 0.092 6 [M1E2] 0.09 6 +214PO2 G KC=0.07 5$LC=0.015 6$MC=0.0035 14 +214PO G 543.0 2 0.088 21[M1E2] 0.06 4 +214PO2 G KC=0.05 4$LC=0.010 5$MC=0.0024 10 +214PO G 661.1 2 0.054 4 [M1E2] 0.039 22 +214PO2 G KC=0.031 19$LC=0.006 3$MC=0.0014 6 +214PO G 788.6 5 0.015 5 [M1] 0.0385 6 +214PO2 G KC=0.0315 5$LC=0.00536 8$MC=1258E-6 18 +214PO G 826.3 2 0.129 11M1 0.0341 5 +214PO2 G KC=0.0279 4$LC=0.00474 7$MC=1113E-6 16 +214PO G 1594.73 8 0.274 15[M1] 0.006449 +214PO2 G KC=0.00514 8$LC=8.59E-4 12$MC=2.01E-4 3 +214PO G 2204.21 4 4.913 23M1 0.003335 +214PO2 G KC=0.00224 4$LC=3.72E-4 6$MC=8.70E-5 13 +214PO L 2208.67 7 (2,3)+ +214PO G 547.6 3 0.034 3 +214PO G 1599.31 6 0.322 15 +214PO L 2266.39 181(-),2+ +214PO B 1004 110.187 12 8 +214POS B EAV=329 4 +214PO G 501.96 150.0181 22 +214PO G 536.77 4 0.061 8 +214PO G 722.98 120.037 7 +214PO G 991.49 190.011 3 [M1E2] 0.014 7 +214PO2 G KC=0.012 6$LC=0.0021 9$MC=0.00049 21 +214PO G 1657.00 190.047 5 +214PO G 2266.51 130.0165 8 +214PO L 2293.34 5 1(+),2+ +214PO B 977 110.558 8 7.4 +214POS B EAV=319 4 +214PO G 878.03 120.0118 27[M1E2] 0.019 10 +214PO2 G KC=0.016 9$LC=0.0028 13$MC=0.0007 3 +214PO G 915.74 150.023 5 [M1E2] 0.017 9 +214PO2 G KC=0.014 8$LC=0.0025 11$MC=0.0006 3 +214PO G 1683.99 4 0.217 3 +214PO G 2293.40 120.306 4 +214PO L 2348.3 9 (1-),(1,2)+ +214PO B 922 110.0014 9 9.9 +214POS B EAV=298 4 +214PO G 2348.0 130.0014 9 +214PO L 2360.8 4 (1-),(1,2)+ +214PO B 909 110.0030 8 9.6 +214POS B EAV=294 4 +214PO G 1751.4 8 0.0009 5 +214PO G 2361.00 190.0021 6 +214PO L 2423.19 15(1-),(1,2)+ +214PO B 847 110.0620 49 8.1 +214POS B EAV=271 4 +214PO G 658.7 2 0.017 4 +214PO G 693.3 5 0.0059 15 +214PO G 1045.6 2 0.023 3 +214PO G 1813.73 140.0108 9 +214PO G 2423.27 130.0048 6 +214PO L 2447.70 6 1- +214PO B 822 112.76 6 6.5 +214POS B EAV=262 4 +214PO G 452.92 100.031 4 [M1E2] 0.10 7 +214PO2 G KC=0.08 6$LC=0.017 7$MC=0.0040 15 +214PO G 683.22 6 0.084 6 [E1] 0.005518 +214PO2 G KC=0.00456 7$LC=7.28E-4 11$MC=1696E-7 2 +214PO G 704.9 3 0.051 10[E1] 0.005198 +214PO2 G KC=0.00429 6$LC=6.84E-4 10$MC=1593E-7 23 +214PO G 786.1 4 0.31 5 [E1] 0.004226 +214PO2 G KC=0.00350 5$LC=5.53E-4 8$MC=1285E-7 18 +214PO G 904.29 100.066 8 [E1] 0.003265 +214PO2 G KC=0.00271 4$LC=4.23E-4 6$MC=9.83E-5 14 +214PO G 1032.37 8 0.061 4 [E1] 0.002574 +214PO2 G KC=0.00213 3$LC=3.31E-4 5$MC=7.68E-5 11 +214PO G 1069.96 8 0.271 10[E1] 0.002414 +214PO2 G KC=0.00200 3$LC=3.10E-4 5$MC=7.19E-5 10 +214PO G 1172.98 100.055 7 [E2] 0.005428 +214PO2 G KC=0.00434 6$LC=8.24E-4 12$MC=1.96E-4 3 +214PO G 1838.36 5 0.343 10 +214PO G 2447.86 101.548 7 E1 1424E-620 +214PO2 G KC=5.03E-4 7$LC=7.51E-5 11$MC=1735E-8 25 +214PO L 2482.46 4 (2)+ +214PO B 788 111.227 27 6.8 1 +214POS B EAV=249 3 +214PO G 273.80 5 0.120 8 +214PO G 394.05 8 0.0127 18 +214PO G 487.95 130.028 9 [E1] 0.0108016 +214PO2 G KC=0.00889 13$LC=1463E-6 21$MC=3.42E-4 5 +214PO G 634.72 210.0064 23[M1E2] 0.043 25 +214PO2 G KC=0.035 21$LC=0.007 3$MC=0.0016 7 +214PO G 752.84 3 0.126 8 [M1E2] 0.028 16 +214PO2 G KC=0.023 13$LC=0.0042 19$MC=0.0010 5 +214PO G 821.18 3 0.166 10M1 0.0346 5 +214PO2 G KC=0.0283 4$LC=0.00482 7$MC=1131E-6 16 +214PO G 939.6 5 0.016 4 [M1E2] 0.016 8 +214PO2 G KC=0.013 7$LC=0.0024 11$MC=0.00056 24 +214PO G 1104.79 190.073 14[M1E2] 0.011 5 +214PO2 G KC=0.009 5$LC=0.0016 7$MC=0.00037 15 +214PO G 1207.68 3 0.454 12[E1] 0.001963 +214PO2 G KC=1622E-6 23$LC=2.49E-4 4$MC=5.77E-5 8 +214PO G 1873.16 6 0.212 8 +214PO G 2482.8 4 0.00096 18 +214PO L 2505.21 151(-),2+ +214PO B 765 110.169 10 7.6 +214POS B EAV=241 4 +214PO G 961.61 170.0101 14 +214PO G 1230.6 4 0.007 5 +214PO G 1895.92 140.146 8 +214PO G 2505.4 2 0.0056 6 +214PO L 2508.2 2 + +214PO B 762 110.092 9 7.9 +214POS B EAV=240 4 +214PO G 496.90 180.0068 18 +214PO G 1130.29 190.036 3 +214PO G 1898.7 4 0.049 8 +214PO L 2544.9 3 + +214PO B 725 110.044 7 8.1 +214POS B EAV=226 4 +214PO G 1167.3 2 0.0123 17 +214PO G 1935.5 2 0.032 7 +214PO L 2553.0 6 + +214PO L 2562.4 3 + +214PO B 708 110.00018 9 10.5 +214POS B EAV=220 4 +214PO G 2562.0 6 0.00018 9 +214PO L 2604.66 14(2)+ +214PO B 665 110.058 4 7.7 1 +214POS B EAV=205 4 +214PO G 396.01 8 0.0259 18 +214PO G 943.34 120.017 3 +214PO G 1330.0 2 0.0120 14 +214PO G 1994.6 6 0.0024 5 +214PO G 2604.5 5 0.00036 9 +214PO L 2630.85 17(1-),(1,2)+ +214PO B 639 110.0223 21 8.2 +214POS B EAV=196 4 +214PO G 2021.6 2 0.0214 21 +214PO G 2630.9 3 0.00086 23 +214PO L 2662.29 12(2)+ +214PO B 608 110.098 9 7.5 1 +214POS B EAV=185 4 +214PO G 949.8 5 0.0055 23 +214PO G 1118.9 5 0.010 4 +214PO G 1284 1 0.013 6 +214PO G 2052.94 120.069 4 +214PO G 2662.4 102.00E-4 41 +214PO L 2694.6 2 1(-),2+ +214PO B 575 110.231 15 7 +214POS B EAV=174 4 +214PO G 485.92 110.021 4 +214PO G 677.41 150.0055 23 +214PO G 699.82 180.016 5 +214PO G 847.16 110.016 6 +214PO G 930.2 2 0.043 8 +214PO G 952.2 8 0.0059 23 +214PO G 1316.96 150.077 7 +214PO G 1419.7 3 0.0055 10 +214PO G 2085.1 2 0.0082 5 +214PO G 2694.7 2 0.033 3 +214PO L 2698.8 3 (1-,2+)+ +214PO B 571 110.026 4 8 +214POS B EAV=173 4 +214PO G 494.2 4 0.011 3 +214PO G 687.6 3 0.0066 14 +214PO G 1038.0 3 0.0086 15 +214PO L 2699.2 2 1(-),2+ +214PO B 571 110.0471 23 7.7 +214POS B EAV=172 4 +214PO G 2089.7 2 0.0443 22 +214PO G 2699.4 3 0.00282 23 +214PO L 2719.22 9 (1-),(1,2)+ +214PO B 551 110.247 8 6.9 +214POS B EAV=166 4 +214PO G 600.0 5 0.008 4 +214PO G 708.8 3 0.0119 20 +214PO G 976.18 120.0151 21 +214PO G 1303.76 8 0.105 5 +214PO G 1341.49 160.0214 27 +214PO G 2109.92 120.084 3 +214PO G 2719.3 2 0.00170 17 +214PO L 2728.59 4 (1,2)+ +214PO B 541 110.525 16 6.6 +214POS B EAV=162 4 +214PO G 280.95 5 0.062 6 +214PO G 519.90 5 0.0166 17 +214PO G 524.6 2 0.0169 17 +214PO G 733.80 150.038 3 +214PO G 964.08 3 0.363 12 +214PO G 1067.2 3 0.024 7 +214PO G 1351 1 0.0042 11 +214PO L 2769.9 2 (1-),(1,2)+ +214PO B 500 110.038 5 7.6 +214POS B EAV=149 4 +214PO G 1392.5 4 0.0087 19 +214PO G 2160.4 3 0.007 5 +214PO G 2769.9 2 0.0225 8 +214PO L 2785.9 2 (1-),(1,2)+ +214PO B 484 110.0248 31 7.8 +214POS B EAV=143 4 +214PO G 1021.0 5 0.016 3 +214PO G 2176.5 2 0.0033 6 +214PO G 2785.9 2 0.0055 5 +214PO L 2794.1 6 + +214PO L 2802.6 6 + +214PO L 2827.0 2 (1-),(1,2)+ +214PO B 443 110.00218 17 8.7 +214POS B EAV=130 4 +214PO G 2826.98 200.00218 17 +214PO L 2861.1 3 (1-),(1,2)+ +214PO B 409 110.0146 20 7.6 +214POS B EAV=119 4 +214PO G 1013.8 2 0.0087 19 +214PO G 2251.6 2 0.0055 5 +214PO G 2861.08 400.00041 13 +214PO L 2869.6 2 + +214PO B 400 110.0087 4 7.9 +214POS B EAV=116 3 +214PO G 2260.3 2 0.0087 4 +214PO L 2880.3 2 (1-),(1,2)+ +214PO B 390 110.0115 16 7.8 +214POS B EAV=113 3 +214PO G 2270.9 4 0.0014 3 +214PO G 2880.3 2 0.0101 16 +214PO L 2893.6 2 (1-),(1,2)+ +214PO B 376 110.022 3 7.5 +214POS B EAV=108 3 +214PO G 626.4 6 0.0041 14 +214PO G 1515.5 3 0.0072 21 +214PO G 2284.3 2 0.0050 4 +214PO G 2893.5 2 0.0057 5 +214PO L 2897.0 3 + +214PO B 373 110.0046 5 8.1 +214POS B EAV=107 3 +214PO G 2287.65 230.0046 5 +214PO L 2919.5 3 + +214PO B 350 110.0014 9 8.6 +214POS B EAV=100 3 +214PO G 2310.2 3 0.0014 9 +214PO L 2921.8 4 (1-),(1,2)+ +214PO B 348 110.0220 9 7.3 +214POS B EAV=99 3 +214PO G 2312.4 2 0.0086 8 +214PO G 2921.9 2 0.0134 5 +214PO L 2928.6 3 (1-),(1,2)+ +214PO B 341 110.0025 9 8.3 +214POS B EAV=97 3 +214PO G 2319.3 3 0.0014 9 +214PO G 2928.6 3 0.00109 9 +214PO L 2934.5 3 (1-),(1,2)+ +214PO B 336 110.00216 32 8.3 +214POS B EAV=95 3 +214PO G 2325.0 3 0.0017 3 +214PO G 2934.6 3 0.00046 12 +214PO L 2940.6 2 (1,2-),2+ +214PO B 329 110.041 7 7 +214POS B EAV=93 3 +214PO G 1665.8 2 0.015 6 +214PO G 2331.3 2 0.026 4 +214PO L 2962.8 7 + +214PO B 307 110.00036 14 9 +214POS B EAV=87 3 +214PO G 2353.5 7 0.00036 14 +214PO L 2967.6 6 + +214PO L 2978.8 2 (1-),(1,2)+ +214PO B 291 110.0165 6 7.2 +214POS B EAV=82 3 +214PO G 2369.0 4 0.0028 4 +214PO G 2978.9 2 0.0137 4 +214PO L 2986.2 2 (1,2 -),(2)+ +214PO B 284 110.032 5 6.9 +214POS B EAV=80 3 +214PO G 1711.0 8 0.023 5 +214PO G 2376.9 2 0.0086 8 +214PO L 3000.0 2 (1-),(2)+ +214PO B 270 110.0160 16 7.1 +214POS B EAV=75 3 +214PO G 551.9 8 0.0055 14 +214PO G 2390.8 2 0.00156 14 +214PO G 2999.98 200.0089 7 +214PO L 3003 1 + +214PO L 3005.8 6 + +214PO L 3014.1 3 (1-),(1,2)+ +214PO B 256 110.0252 24 6.9 +214POS B EAV=71 3 +214PO G 1353.4 8 0.0036 9 +214PO G 1470.9 3 0.0094 13 +214PO G 1636.3 2 0.0111 16 +214PO G 2405.1 5 0.0011 7 +214PO L 3022.3 3 + +214PO L 3030.3 6 + +214PO L 3039.3 6 + +214PO L 3053.9 2 (1-),(1,2)+ +214PO B 216 110.030 5 6.6 +214POS B EAV=59 3 +214PO G 2444.7 8 0.008 4 +214PO G 3053.88 200.022 3 +214PO L 3068.3 8 + +214PO B 202 110.00141 23 7.8 +214POS B EAV=55 3 +214PO G 2459.0 8 0.00141 23 +214PO L 3078.7 6 + +214PO L 3081.7 3 (1-),(1,2)+ +214PO B 188 110.0052 7 7.1 +214POS B EAV=51 3 +214PO G 3081.7 3 0.0052 7 +214PO L 3094.0 4 (1-),(2)+ +214PO B 176 110.00037 4 8.2 +214POS B EAV=48 3 +214PO G 3093.98 400.00037 4 +214PO L 3139.0 8 + +214PO L 3142.6 4 (1-),(1,2)+ +214PO B 127 110.00118 9 7.3 +214POS B EAV=34 3 +214PO G 3142.58 400.00118 9 +214PO L 3149.2 5 (1-),(1,2)+ +214PO B 121 110.00019 8 +214POS B EAV=32 3 +214PO G 3149.0 5 1900E-7 0 +214PO L 3160.4 6 (1-),(1,2)+ +214PO B 110 110.00079 12 7.2 +214POS B EAV=29 3 +214PO G 2550.7 7 0.00032 9 +214PO G 3160.6 6 0.00047 8 +214PO L 3164.8 8 + +214PO L 3173.3 6 + +214PO B 97 110.00014 9 7.8 +214POS B EAV=26 3 +214PO G 2564.0 6 0.00014 9 +214PO L 3183.6 4 (1-),(1,2)+ +214PO B 86 110.0011 5 6.8 +214POS B EAV=23 3 +214PO G 3183.57 400.0011 5 +214PO L 3262.4 8 + + diff --git a/HEN_HOUSE/spectra/lnhb/Bi-215.txt b/HEN_HOUSE/spectra/lnhb/Bi-215.txt new file mode 100644 index 000000000..4dd58e5d7 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Bi-215.txt @@ -0,0 +1,97 @@ +215PO 215BI B- DECAY (7.6 M) +215PO H TYP=Full$AUT=A.L. Nichols$CUT=30-JUL-2011$ +215PO C Evaluation history: Type=Full;Author=A.L. Nichols;Cutoff date=30-JUL-2011 +215PO C References: 1933Sa01, 1953Hy83, 1955Ev23, 1963KaZZ, 1965Nu03, 1970Da09, +215PO2C 1977La19, 1989Bu09, 1990Ru02, 1991Ma16, 1996Sc06, 1998ScZM, 1999ScZX, +215PO3C 2001Br31, 2002Ra45, 2002Ba85, 2003Ku26, 2003Ak06, 2003Auo3, 2004Br45, +215PO4C 2007Ba19, 2008Ki07 +215PO T Auger electrons and ^X ray energies and emission intensities: +215PO T {U Energy (keV)} {U Intensity } {U Line } +215PO T +215PO T 76.864 1.8 3 XKA2 +215PO T 79.293 3.0 5 XKA1 +215PO T +215PO T 89.256 |] XKB3 +215PO T 89.807 |] 1.02 16 XKB1 +215PO T 90.363 |] XKB5II +215PO T +215PO T 92.263 |] XKB2 +215PO T 92.618 |] 0.32 5 XKB4 +215PO T 92.983 |] XKO23 +215PO T +215PO T 9.658-16.213 2.7 3 XL (total) +215PO T 9.658 0.065 8 XLL +215PO T 11.016-11.13 1.20 13 XLA +215PO T 12.085 0.022 3 XLC +215PO T 12.823-13.778 1.18 11 XLB +215PO T 15.742-16.213 0.24 2 XLG +215PO T +215PO T 58.978-65.205 |] KLL AUGER +215PO T 71.902-79.289 |] 0.22 5 ^KLX AUGER +215PO T 84.8-93.1 |] KXY AUGER +215PO T 5.434-10.934 4.0 4 L AUGER +215BI P 0.0 (9/2)- 7.6 M 2 2189 15 +215PO N 1.0 1.0 1 1.0 +215PO L 0 9/2+ 1.781 MS 4 +215PO B 2189 1561 6 6.28 +215POS B EAV=808 6 +215PO L 271.228 107/2+ +215PO G 271.228 101.95 7 M1+E2 4.0 4 0.201 7 +215PO2 G KC=0.111 6$LC=0.0668 11$MC=0.0173 3 +215PO L 293.56 4 (11/2)+ +215PO B 1895 1530 6 6.35 1U +215POS B EAV=685 6 +215PO G 293.56 4 23.8 9 M1+E2 1.0 2 0.34 5 +215PO2 G KC=0.25 4$LC=0.062 4$MC=0.0152 7 +215PO L 401.812 105/2+ +215PO B 1787 150.5 1 9 3U +215POS B EAV=619 6 +215PO G 130.58 1 0.0093 10M1+E2 0.60 6 4.44 13 +215PO2 G KC=3.19 16$LC=0.94 4$MC=0.234 10 +215PO G 401.81 1 0.48 7 E2 0.0555 8 +215PO2 G KC=0.0351 5$LC=0.01528 22$MC=0.00390 6 +215PO L 517.60 6 7/2, 9/2+ +215PO B 1671 150.3 2 8.1 1U +215POS B EAV=593 6 +215PO G 224.04 7 0.033 5 E2 0.319 5 +215PO2 G KC=0.1296 19$LC=0.1407 20$MC=0.0370 6 +215PO G 517.60 6 1.02 8 M1+E2 1.0 2 0.073 10 +215PO2 G KC=0.058 9$LC=0.0115 11$MC=0.00277 24 +215PO L 608.30 7 (11/2, 13/2)+ +215PO B 1581 150.7 1 7.7 1U +215POS B EAV=556 6 +215PO G 608.30 7 0.67 7 (M1+E2) +215PO L 676.66 7 + +215PO B 1512 150.5 1 7.8 +215POS B EAV=528 6 +215PO G 383.10 8 0.14 7 +215PO G 405.43 7 0.006 1 +215PO G 676.66 7 0.40 7 +215PO L 835.32 22 + +215PO B 1354 151.5 1 7.1 +215POS B EAV=465 6 +215PO G 541.76 220.21 7 +215PO G 564.09 220.67 7 +215PO G 835.32 220.62 7 +215PO L 1077.6 20 + +215PO B 1111 150.7 1 7.1 +215POS B EAV=370 6 +215PO G 784 2 0.33 7 +215PO G 806.4 200.40 7 +215PO L 1176.2 20 + +215PO B 1013 150.2 1 7.5 +215POS B EAV=332 6 +215PO G 905 2 0.21 7 +215PO L 1294.5 1 + +215PO B 895 152.0 2 6.34 +215POS B EAV=287 6 +215PO G 776.9 1 0.81 14 +215PO G 1023.3 1 0.62 7 +215PO G 1294.5 1 0.62 7 +215PO L 1398.8 4 + +215PO B 790 152.8 1 6 +215POS B EAV=249 6 +215PO G 1105.2 4 1.50 7 +215PO G 1127.6 4 0.48 7 +215PO G 1398.8 4 0.81 7 + diff --git a/HEN_HOUSE/spectra/lnhb/C-11.txt b/HEN_HOUSE/spectra/lnhb/C-11.txt new file mode 100644 index 000000000..cb1cb11af --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/C-11.txt @@ -0,0 +1,11 @@ + 11B 11C EC DECAY (20.361 M) + 11B H TYP=Update$AUT=V. Chisté$CUT=01-NOV-2011$ + 11B 2 H TYP=Full$AUT=V. Chisté$CUT=30-MAR-2002$ + 11B C Evaluation history: Type=Update;Author=V. Chisté;Cutoff date=01-NOV-2011 + 11B 2C Type=Full;Author=V. Chisté;Cutoff date=30-MAR-2002 + 11C P 0.0 3/2- 20.361 M 23 1982.5 9 + 11B N 1.0 1.0 1 1.0 + 11B L 0 3/2- STABLE + 11B E 99.750 130.250 13 + 11B 2 E EAV=385.7 4$CK=0.9174 91$CL=0.0826 91$CM= $CN= $CO=0 0 + diff --git a/HEN_HOUSE/spectra/lnhb/C-14.txt b/HEN_HOUSE/spectra/lnhb/C-14.txt new file mode 100644 index 000000000..805f5e38f --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/C-14.txt @@ -0,0 +1,14 @@ + 14N 14C B- DECAY (5700 Y) + 14N H TYP=Update$AUT=M.M. Bé$CUT=01-JAN-2012$ + 14N 2 H TYP=Full$AUT=V.P. Chechev$CUT=01-JAN-1998$ + 14N C Evaluation history: Type=Update;Author=M.M. Bé;Cutoff date=01-JAN-2012 + 14N 2C Type=Full;Author=V.P. Chechev;Cutoff date=01-JAN-1998 + 14N C References: 1952Je11, 1961Wa16, 1961Ma32, 1962Ol04, 1964Hu09, 1968Be47, + 14N 2C 1968Re22, 1972Em01, 1975Sm02, 1990Ho18, 1991Su09, 1995Wi20, 2000Ku25, + 14N 3C 2003Au03, 2012Au06, 2012Mo** + 14C P 0.0 0+ 5700 Y 30 156.476 4 + 14N N 1.0 1.0 1 1.0 + 14N L 0 1+ STABLE + 14N B 156.476 4 100 9.04 + 14N S B EAV=49.16 1 + diff --git a/HEN_HOUSE/spectra/lnhb/Ca-41.txt b/HEN_HOUSE/spectra/lnhb/Ca-41.txt new file mode 100644 index 000000000..e1b8b5137 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Ca-41.txt @@ -0,0 +1,33 @@ + 41K 41CA EC DECAY (1.002E5 Y) + 41K H TYP=Full$AUT=X. Mougeot$CUT=31-JAN-2013$ + 41K C Evaluation history: Type=Full;Author=X. Mougeot;Cutoff date=31-JAN-2013 + 41K C References: 1950RI59, 1951BR94, 1951SA31, 1953BR71, 1962DR03, 1970SI24, + 41K 2C 1973MY03, 1973ZO03, 1974MA30, 1987HO16, 1988JA11, 1990FI13, 1991PA10, + 41K 3C 1991KL06, 1992KA05, 1996SC06, 2001CA59, 2006MUZX, 2008MO18, 2011AUZZ, + 41K 4C 2011BE53, 2012JO04 + 41K T Auger electrons and ^X ray energies and emission intensities: + 41K T {U Energy (keV)} {U Intensity } {U Line } + 41K T + 41K T 3.3111 3.82 12 XKA2 + 41K T 3.3138 7.56 23 XKA1 + 41K T + 41K T 3.5896 |] 1.40 5 XKB1 + 41K T 3.6028 |] XKB5II + 41K T + 41K T + 41K T 0.2604-0.3618 0.27 6 XL (total) + 41K T 0.2604 0.27 6 XLL + 41K T 0.263 XLC + 41K T 0.29654-0.3618 XLB + 41K T 0.29917-0.29917 XLG + 41K T + 41K T 2.615-2.985 |] KLL AUGER + 41K T 3.183-3.296 |] 76.6 9 ^KLX AUGER + 41K T 3.54-3.572 |] KXY AUGER + 41K T 0.226-0.342 156.76 11 L AUGER + 41CA P 0.0 7/2- 1.002E5 Y 17 421.63 14 + 41K N 1.0 1.0 1 1.0 + 41K L 0 3/2+ STABLE + 41K E 100 10.53 3U + 41K 2 E EAV= $CK=0.894 9$CL=0.0916 9$CM=0.01482 15$CN= $CO= + diff --git a/HEN_HOUSE/spectra/lnhb/Ca-45.txt b/HEN_HOUSE/spectra/lnhb/Ca-45.txt new file mode 100644 index 000000000..dcfcf7f24 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Ca-45.txt @@ -0,0 +1,19 @@ + 45SC 45CA B- DECAY (162.64 D) + 45SC H TYP=Full$AUT=M.M.Bé$CUT=15-FEB-2012$ + 45SC2 H TYP=Full$AUT=F.Lagoutine$CUT= -- $ + 45SC C Evaluation history: Type=Full;Author=M.M.Bé;Cutoff date=15-FEB-2012 + 45SC2C Type=Full;Author=F.Lagoutine;Cutoff date= -- + 45SC C References: 1950Ma03, 1950Ke60, 1952Ca10, 1952De01, 1957Th11, 1959Ca12, + 45SC2C 1961Wy01, 1965An07, 1965Fr12, 1967Ha39, 1970Si24, 1994Lo04, 2003Au03, + 45SC3C 2008Ki07, 2012Mo**, 2012Au06 + 45CA P 0.0 7/2- 162.64 D 11 258.0 7 + 45SC N 1.0 1.0 1 1.0 + 45SC L 0 7/2- STABLE + 45SC B 258.0 7 99.9980 7 6 + 45SCS B EAV=76.8 7 + 45SC L 12.40 5 3/2+ 318 MS 7 + 45SC B 245.6 7 0.0020 7 10.3 3U + 45SCS B EAV=91.7 7 + 45SC G 12.40 5 M2 423 9 + 45SC2 G KC=362 8$LC=53.4 12$MC=6.63 15 + diff --git a/HEN_HOUSE/spectra/lnhb/Cd-109.txt b/HEN_HOUSE/spectra/lnhb/Cd-109.txt new file mode 100644 index 000000000..4dd3b04b7 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Cd-109.txt @@ -0,0 +1,49 @@ +109AG 109CD EC DECAY (461.9 D) +109AG H TYP=Full$AUT=M.M. Bé$CUT=31-OCT-2014$ +109AG2 H TYP=update$AUT=M.M.Bé$CUT= -- $ +109AG C Evaluation history: Type=Full;Author=M.M. Bé;Cutoff date=31-OCT-2014 +109AG2C Type=update;Author=M.M.Bé;Cutoff date= -- +109AG C References: 1940Al01, 1941He01, 1945Wi11, 1947Br05, 1950Gu54, 1951Wo15, +109AG2C 1953br73, 1953De26, 1954Be41, 1957Wa05, 1964Bo12, 1965Le06, 1965Se08, +109AG3C 1965Mo06, 1967Mi11, 1966ja01, 1966Fr12, 1966Du01, 1967Pi05, 1967Sc22, +109AG4C 1967Li10, 1967Ab07, 1968Go25, 1968GoZY, 1968Ea01, 1968Re04, 1968Fo03, +109AG5C 1968Fu05, 1969Pl08, 1969HeZY, 1970Gr13, 1970Ra37, 1970ba37, 1970Go39, +109AG6C 1972Ca16, 1972Br02, 1973Co10, 1973Le29, 1975Ma32, 1976Dr07, 1977Va05, +109AG7C 1978Pr**, 1978Mo22, 1978Sh08, 1979Pl04, 1979Va04, 1980Da03, 1981Va11, +109AG8C 1982HoZJ, 1982La25, 1984Ma**, 1985Ho06, 1988Ba60, 1988Il01, 1989Hi01, +109AG9C 1989Eg**, 1989Ne**, 1992ScZZ, 1994Ra37, 1996Sc06, 1997Ma75, 2000He14, +109AG10C 2000Yo07, 2000Sc47, 2002Ba85, 2004Sc04, 2006Bl02, 2006Ko27, 2008Ki07, +109AG11C 2011va02, 2012Fi12, 2012Wa38, 2014Un01 +109AG T Auger electrons and ^X ray energies and emission intensities: +109AG T {U Energy (keV)} {U Intensity } {U Line } +109AG T +109AG T 21.9906 29.21 30 XKA2 +109AG T 22.16317 55.1 5 XKA1 +109AG T +109AG T 24.9118 |] XKB3 +109AG T 24.9427 |] 15.25 20 XKB1 +109AG T 25.146 |] XKB5II +109AG T +109AG T 25.4567 |] XKB2 +109AG T 25.512 |] 2.65 10 XKB4 +109AG T +109AG T 2.634-3.748 10.37 27 XL (total) +109AG T 2.634 0.221 9 XLL +109AG T 2.977-2.985 5.93 21 XLA +109AG T 2.807 0.0849 20 XLC +109AG T 3.151-3.438 3.76 10 XLB +109AG T 3.431-3.748 0.366 8 XLG +109AG T +109AG T 17.79-18.69 |] KLL AUGER +109AG T 20.945-22.16 |] 20.8 6 ^KLX AUGER +109AG T 24.079-25.507 |] KXY AUGER +109AG T 1.8-3.8 167.3 8 L AUGER +109CD P 0.0 5/2+ 461.9 D 4 215.5 18 +109AG N 1.0 1.0 1 1.0 +109AG L 0 1/2- STABLE +109AG L 88.0341 7/2+ 39.7 S 2 +109AG E 100 6 2 +109AG2 E EAV= $CK=0.812 3$CL=0.150 3$CM=0.0321 9$CN=0.0064 4$CO= +109AG G 88.0336 103.66 5 E3 26.3 4 +109AG2 G KC=11.41 16$LC=12.06 17$MC=2.47 4 + diff --git a/HEN_HOUSE/spectra/lnhb/Ce-139.txt b/HEN_HOUSE/spectra/lnhb/Ce-139.txt new file mode 100644 index 000000000..75d12f23a --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Ce-139.txt @@ -0,0 +1,39 @@ +139LA 139CE EC DECAY (137.641 D) +139LA C References: 1968Va08, 1968Ad08, 1975Mo12, 1975Da08, 1977Sc38, 1978SeZS, +139LA2C 1987BeYL, 1988KoZM, 1998Si17, 2001Sc08, 2003Au03, 2005KiZW +139LA T Auger electrons and ^X ray energies and emission intensities: +139LA T {U Energy (keV)} {U Intensity } {U Line } +139LA T +139LA T 33.0344 22.80 24 XKA2 +139LA T 33.4421 41.9 4 XKA1 +139LA T +139LA T 37.7206 |] XKB3 +139LA T 37.8015 |] 12.47 18 XKB1 +139LA T 38.084 |] XKB5II +139LA T +139LA T 38.7303 |] XKB2 +139LA T 38.828 |] 3.16 8 XKB4 +139LA T 38.91 |] XKO23 +139LA T +139LA T 4.117-6.072 12.19 18 XL (total) +139LA T 4.117 0.222 6 XLL +139LA T 4.634-4.65 5.70 13 XLA +139LA T 4.525 0.0842 21 XLC +139LA T 5.041-5.381 5.27 9 XLB +139LA T 5.62-6.072 0.903 16 XLG +139LA T +139LA T 26.24-27.795 |] KLL AUGER +139LA T 31.231-33.428 |] 8.4 4 ^KLX AUGER +139LA T 36.2-38.9 |] KXY AUGER +139LA T 2.7-6.2 90.1 6 L AUGER +139CE P 0.0 3/2+ 137.641 D 20 270 3 +139LA N 1.0 1.0 1 1.0 +139LA L 0 7/2+ STABLE +139LA E 0.008 10.6 +139LA2 E EAV= $CK= $CL= $CM= $CN= $CO= +139LA L 165.8576 115/2+ 1.499 NS 19 +139LA E 99.9973 275.42 2 +139LA2 E EAV= $CK=0.716 7$CL=0.217 5$CM=0.0669 18$CN= $CO= +139LA G 165.8575 1179.90 4 M1 0.2516 7 +139LA2 G KC=0.2146 10$LC=0.0288 6$MC=0.0060 2 + diff --git a/HEN_HOUSE/spectra/lnhb/Ce-141.txt b/HEN_HOUSE/spectra/lnhb/Ce-141.txt new file mode 100644 index 000000000..d9520084c --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Ce-141.txt @@ -0,0 +1,46 @@ +141PR 141CE B- DECAY (32.503 D) +141PR H TYP=Update$AUT=V.P. Chechev$CUT=01-FEB-2012$ +141PR2 H TYP=Full$AUT=E. Schönfeld$CUT=01-JUN-1998$ +141PR C Evaluation history: Type=Update;Author=V.P. Chechev;Cutoff date=01-FEB-2012 +141PR2C Type=Full;Author=E. Schönfeld;Cutoff date=01-JUN-1998 +141PR C References: 1949Wa23, 1950Fr58, 1957Ke26, 1961Ne12, 1962Sc11, 1963Ha07, +141PR2C 1965An07, 1966El02, 1967Ob01, 1971De11, 1971Ba28, 1972Em01, 1973MeYE, +141PR3C 1975Le09, 1976Va30, 1977La19, 1979Ha09, 1979Ha21, 1980Sc07, 1980RuZY, +141PR4C 1983Wa26, 1992Sc24, 1992Un01, 1996Sc06, 2000He14, 2000Sc47, 2001Tu01, +141PR5C 2002Ba85, 2002Un02, 2008Ki07, 2012Au06 +141PR T Auger electrons and ^X ray energies and emission intensities: +141PR T {U Energy (keV)} {U Intensity } {U Line } +141PR T +141PR T 35.5506 4.80 9 XKA2 +141PR T 36.0267 8.76 15 XKA1 +141PR T +141PR T 40.6533 |] XKB3 +141PR T 40.7487 |] 2.67 6 XKB1 +141PR T 41.05 |] XKB5II +141PR T +141PR T 41.774 |] XKB2 +141PR T 41.877 |] 0.682 20 XKB4 +141PR T 41.968 |] XKO23 +141PR T +141PR T 4.458-6.617 2.52 5 XL (total) +141PR T 4.458 0.0485 15 XLL +141PR T 5.0129-5.0343 1.23 4 XLA +141PR T 4.9337 0.0187 6 XLC +141PR T 5.4887-5.9032 1.054 23 XLB +141PR T 6.1375-6.617 0.169 4 XLG +141PR T +141PR T 28.162-29.89 |] KLL AUGER +141PR T 33.576-36.004 |] 1.59 8 ^KLX AUGER +141PR T 38.97-41.95 |] KXY AUGER +141PR T 2.94-6.79 16.15 11 L AUGER +141CE P 0.0 7/2- 32.503 D 11 580.4 11 +141PR N 1.0 1.0 1 1.0 +141PR L 0 0 5/2+ STABLE +141PR B 580.4 1130.03 44 7.76 1U +141PRS B EAV=180.8 6 +141PR L 145.4434 147/2+ +141PR B 435.0 1169.97 44 6.97 +141PRS B EAV=129.7 5 +141PR G 145.4433 1448.29 19M1+E2 0.068 5 0.449 7 +141PR2 G KC=0.383 6$LC=0.0529 8$MC=0.01116 16 + diff --git a/HEN_HOUSE/spectra/lnhb/Ce-144.txt b/HEN_HOUSE/spectra/lnhb/Ce-144.txt new file mode 100644 index 000000000..55276cb02 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Ce-144.txt @@ -0,0 +1,67 @@ +144PR 144CE B- DECAY (284.89 D) +144PR H TYP=FUL$AUT=A.L.Nichols$CUT=01-MAR-2014$ +144PR C Evaluation history: Type=FUL;Author=A.L.Nichols;Cutoff date=01-MAR-2014 +144PR C References: 1954Kr40, 1954Em09, 1954Co60, 1956Pu24, 1956Sc87, 1957Pa51, +144PR2C 1957Me47, 1958Hi76, 1959Se57, 1959Fr54, 1960Ea02, 1960Ge05, 1960Sa22, +144PR3C 1961Ge09, 1962Bu22, 1962Fo04, 1962Bu09, 1962Bl05, 1963Cr11, 1963Kn05, +144PR4C 1963Si10, 1963Fu16, 1963Co18, 1963Bh11, 1963Iw02, 1964Az02, 1964Mc22, +144PR5C 1964Be36, 1965Fl02, 1965Re13, 1965Co19, 1966Da04, 1966Be11, 1967Gu17, +144PR6C 1968La10, 1968Re04, 1968Da12, 1969Ge01, 1969Gu15, 1969Ma24, 1970Fa03, +144PR7C 1970Po09, 1970An15, 1971Sa20, 1975Ba32, 1975De17, 1976Ra22, 1976Ch33, +144PR8C 1977Ge12, 1977La19, 1978Mo22, 1979Bo26, 1980Ho17, 1981Ol04, 1982Yu02, +144PR9C 1983El04, 1983Wa26, 1984Da13, 1986Ol01, 1992Un01, 1996Sc06, 1997Ma75, +144PR10C 1998ScZM, 1999ScZX, 2000Sc47, 2001So16, 2002Un02, 2002Ra45, 2002Ba85, +144PR11C 2008Ki07, 2012Wa38, 2012Fi12, 2014Un01 +144PR T Auger electrons and ^X ray energies and emission intensities: +144PR T {U Energy (keV)} {U Intensity } {U Line } +144PR T +144PR T 35.5506 2.41 5 XKA2 +144PR T 36.0267 4.40 9 XKA1 +144PR T +144PR T 40.6533 |] XKB3 +144PR T 40.7487 |] 1.34 3 XKB1 +144PR T 41.05 |] XKB5II +144PR T +144PR T 41.774 |] XKB2 +144PR T 41.877 |] 0.343 10 XKB4 +144PR T 41.968 |] XKO23 +144PR T +144PR T 4.453-6.617 1.54 4 XL (total) +144PR T 4.453 0.0282 9 XLL +144PR T 5.013-5.033 0.711 21 XLA +144PR T 4.929 0.0107 4 XLC +144PR T 5.489-5.851 0.673 15 XLB +144PR T 6.327-6.617 0.116 3 XLG +144PR T +144PR T 28.162-29.89 |] KLL AUGER +144PR T 33.576-36.004 |] 0.80 4 ^KLX AUGER +144PR T 38.97-41.95 |] KXY AUGER +144PR T 2.9-4.91 9.88 10 L AUGER +144CE P 0.0 0+ 284.89 D 6 318.6 8 +144PR N 1.0 1.0 1.00 1 1.0 +144PR L 0 0- 17.29 M 4 +144PR B 318.6 8 76.9 3 7.424 +144PRS B EAV=91.3 3 +144PR L 59.03 3 3- 7.2 M 2 +144PR G 59.03 3 0.00094 19M3 1221 18 +144PR2 G KC=408 6$LC=618 9$MC=155.0 23 +144PR L 80.120 4 1- 136 PS 11 +144PR B 238.5 8 3.9 2 8.33 1 +144PRS B EAV=66.24 25 +144PR G 80.120 4 1.40 5 M1 2.45 4 +144PR2 G KC=2.08 3$LC=0.288 4$MC=0.0608 9 +144PR L 99.952 9 2- 0.67 NS 6 +144PR G 40.92 3 0.32 5 M1 2.61 4 +144PR2 G KC=$LC=2.06 3$MC=0.434 7 +144PR G 99.952 9 0.041 2 E2 2.12 3 +144PR2 G KC=1.214 17$LC=0.71 1$MC=0.1599 23 +144PR L 133.5152 201- 7 PS 4 +144PR B 185.1 8 19.2 1 7.27 1 +144PRS B EAV=50.29 24 +144PR G 33.563 9 0.225 11M1 4.69 7 +144PR2 G KC=$LC=3.70 6$MC=0.780 11 +144PR G 53.395 5 0.101 5 M1 7.94 12 +144PR2 G KC=6.75 10$LC=0.942 14$MC=0.199 3 +144PR G 133.5152 2010.83 12M1 0.571 8 +144PR2 G KC=0.486 7$LC=0.0668 10$MC=0.01408 20 + diff --git a/HEN_HOUSE/spectra/lnhb/Cf-252.txt b/HEN_HOUSE/spectra/lnhb/Cf-252.txt new file mode 100644 index 000000000..4ab913c23 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Cf-252.txt @@ -0,0 +1,51 @@ +248CM 252CF A DECAY (2.6470 Y) +248CM H TYP=Full$AUT=M.M. Bé$CUT=23-OCT-2007$ +248CM C Evaluation history: Type=Full;Author=M.M. Bé;Cutoff date=23-OCT-2007 +248CM C References: 1955As42, 1963Bj03, 1965Me02, 1969De23, 1970Ba18, 1970Al23, +248CM2C 1971Ba10, 1971Wa28, 1971Ha**, 1973Mi05, 1974Sp02, 1974Sh15, 1976BaZZ, +248CM3C 1976Mo30, 1982La25, 1983Al**, 1984Di08, 1984SmZV, 1985Wi14, 1985Ax**, +248CM4C 1986Ry04, 1987Sh**, 1988Ke**, 1990Po24, 1991Ry01, 1992Sh33, 1993Pa29, +248CM5C 1994KhZW, 1996Sc33, 1999Ak02, 1999Ba03, 2003Au03, 2005KiZW +248CM T Auger electrons and ^X ray energies and emission intensities: +248CM T {U Energy (keV)} {U Intensity } {U Line } +248CM T +248CM T 104.59 0.0000257 7 XKA2 +248CM T 109.271 0.0000402 11 XKA1 +248CM T +248CM T 122.304 |] XKB3 +248CM T 123.403 |] 0.0000151 5 XKB1 +248CM T 124.124 |] XKB5II +248CM T +248CM T 126.889 |] XKB2 +248CM T 127.352 |] 0.00000530 19 XKB4 +248CM T 127.97 |] XKO23 +248CM T +248CM T 12.634-23.319 6.07 14 XL (total) +248CM T 12.634 0.146 5 XLL +248CM T 14.744-14.96 2.25 7 XLA +248CM T 17.315 0.0644 24 XLC +248CM T 17.288-20.515 2.90 9 XLB +248CM T 21.969-23.319 0.702 21 XLG +248CM T +248CM T 78.858-89.973 |] KLL AUGER +248CM T 97.226-109.267 |] 0.0000025 4 ^KLX AUGER +248CM T 115.57-128.23 |] KXY AUGER +248CM T 6.3-24.5 5.02 13 L AUGER +252CF P 0.0 0+ 2.6470 Y 26 6216.87 4 +248CM N 1.032E0 1.032E0 0.96914 1.032E0 +248CM L 0 0+ 348E3 Y 6 +248CM A 6118.1 1 84.30 311 +248CM L 43.40 3 2+ 124 PS 5 +248CM A 6075.64 1115.58 313.2 +248CM G 43.399 250.0152 4 E2 1000 15 +248CM2 G KC=$LC=724 11$MC=204 3 +248CM L 143.6 4 4+ 78 PS 22 +248CM A 5976.6 0.237 4165 +248CM G 100.2 4 0.0119 20E2 18.5 5 +248CM2 G KC=$LC=13.4 4$MC=3.79 9 +248CM L 298.1 5 6+ 33 PS 8 +248CM A 5826.3 19605E-7 1200 +248CM G 154.5 6 5100E-7 0 E2 2.76 6 +248CM2 G KC=0.1741 25$LC=1.87 5$MC=0.526 12 +248CM L 505.0 5 8+ + diff --git a/HEN_HOUSE/spectra/lnhb/Cl-36.txt b/HEN_HOUSE/spectra/lnhb/Cl-36.txt new file mode 100644 index 000000000..3a81f8468 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Cl-36.txt @@ -0,0 +1,55 @@ + 36S 36CL EC DECAY (302E3 Y) + 36S H TYP=Update$AUT=M.M. Bé$CUT=15-JAN-2012$ + 36S 2 H TYP=Full$AUT=V.P. Chechev$CUT=30-APR-1998$ + 36S C Evaluation history: Type=Update;Author=M.M. Bé;Cutoff date=15-JAN-2012 + 36S 2C Type=Full;Author=V.P. Chechev;Cutoff date=30-APR-1998 + 36S C References: 1949Wu15, 1955Dr35, 1955Ba93, 1957Wr37, 1962Do07, 1962Be29, + 36S 2C 1963Ba38, 1965To05, 1966Go07, 1967Pi04, 1976Lj03, 1977La19, 2012Mo** + 36S T Auger electrons and ^X ray energies and emission intensities: + 36S T {U Energy (keV)} {U Intensity } {U Line } + 36S T + 36S T 2.3066 0.044 3 XKA2 + 36S T 2.3078 0.086 5 XKA1 + 36S T + 36S T 2.457 |] XKB3 + 36S T |] 0.008 1 XKB1 + 36S T + 36S T + 36S T + 36S T 1.98-2.12 |] KLL AUGER + 36S T 2.22-2.3 |] 1.58 9 ^KLX AUGER + 36S T 2.44-2.46 |] KXY AUGER + 36S T - 0.163 12 L AUGER + 36CL P 0.0 2+ 302E3 Y 4 1142.14 19 + 36S N 5.263E1 5.263E1 0.019 1 5.263E1 + 36S L 0 0+ STABLE + 36S E 0.00157 301.9 1 13.5 2 + 36S 2 E EAV=54 4$CK=0.904 5$CL=0.086 4$CM=0.010 1$CN= $CO= + + 36AR 36CL B- DECAY (302E3 Y) + 36AR H TYP=Update$AUT=M.M. Bé$CUT=15-JAN-2012$ + 36AR2 H TYP=Full$AUT=V.P. Chechev$CUT=30-APR-1998$ + 36AR C Evaluation history: Type=Update;Author=M.M. Bé;Cutoff date=15-JAN-2012 + 36AR2C Type=Full;Author=V.P. Chechev;Cutoff date=30-APR-1998 + 36AR C References: 1949Wu15, 1955Dr35, 1955Ba93, 1957Wr37, 1962Do07, 1962Be29, + 36AR2C 1963Ba38, 1965To05, 1966Go07, 1967Pi04, 1976Lj03, 1977La19, 2012Mo** + 36AR T Auger electrons and ^X ray energies and emission intensities: + 36AR T {U Energy (keV)} {U Intensity } {U Line } + 36AR T + 36AR T 2.9553 0.0062 10 XKA2 + 36AR T 2.9577 0.0123 19 XKA1 + 36AR T + 36AR T 3.1905 |] XKB3 + 36AR T |] 0.0020 3 XKB1 + 36AR T + 36AR T + 36AR T + 36AR T 2.511-2.669 |] KLL AUGER + 36AR T 2.831-2.942 |] 0.13 2 ^KLX AUGER + 36AR T 3.149-3.174 |] KXY AUGER + 36CL P 0.0 2+ 302E3 Y 4 709.55 5 + 36AR N 1.019E0 1.019E0 0.981 1 1.019E0 + 36AR L 0 0+ STABLE + 36AR B 709.53 5 98.1 1 13.3 2 + 36ARS B EAV=316 16 + diff --git a/HEN_HOUSE/spectra/lnhb/Cm-242.txt b/HEN_HOUSE/spectra/lnhb/Cm-242.txt new file mode 100644 index 000000000..9c80f60bc --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Cm-242.txt @@ -0,0 +1,123 @@ +238PU 242CM A DECAY (162.86 D) +238PU H TYP=Update$AUT=Chechev$CUT= -- $ +238PU2 H TYP=Full$AUT=Chechev$CUT=01-SEP-2005$ +238PU C Evaluation history: Type=Update;Author=Chechev;Cutoff date= -- +238PU2C Type=Full;Author=Chechev;Cutoff date=01-SEP-2005 +238PU C References: 1950Ha14, 1951Ha87, 1952Du12, 1953As14, 1954Gl37, 1954Hu32, +238PU2C 1956Ba95, 1956Sm18, 1958Ko87, 1960As10, 1963Le17, 1963Dz07, 1965Ak02, +238PU3C 1965Fl02, 1966Ba07, 1967Ar09, 1967Be65, 1970By01, 1971Gr17, 1971Po09, +238PU4C 1972Wi22, 1972Ah04, 1971Bb10, 1975Ke02, 1977Di04, 1979Ch41, 1980Di13, +238PU5C 1981Le15, 1981Us03, 1982Ag02, 1982Ba56, 1982Ra33, 1982UmZZ, 1984Wi14, +238PU6C 1986LoZT, 1986Ze06, 1989Us04, 1990Po14, 1991Ry01, 1995Jo23, 1996Sc06, +238PU7C 1998Ya17, 2000Ho27, 2002Ch52, 2003Au03, 2006Ch34, 2008Ki07 +238PU T Auger electrons and ^X ray energies and emission intensities: +238PU T {U Energy (keV)} {U Intensity } {U Line } +238PU T +238PU T 99.525 0.000082 9 XKA2 +238PU T 103.734 0.000130 15 XKA1 +238PU T +238PU T 116.244 |] XKB3 +238PU T 117.228 |] 0.000048 6 XKB1 +238PU T 117.918 |] XKB5II +238PU T +238PU T 120.54 |] XKB2 +238PU T 120.969 |] 0.0000165 19 XKB4 +238PU T 121.543 |] XKO23 +238PU T +238PU T 12.12-23.07 9.92 23 XL (total) +238PU T 12.12 0.243 8 XLL +238PU T 14.087-14.282 3.79 11 XLA +238PU T 16.333 0.103 4 XLC +238PU T 16.5-19.33 4.69 14 XLB +238PU T 20.71-23.07 1.09 4 XLG +238PU T +238PU T 75.2-85.3 |] KLL AUGER +238PU T 92.6-103.6 |] 0.0000082 15 ^KLX AUGER +238PU T 109.8-121.5 |] KXY AUGER +238PU T 6.19-22.99 8.99 21 L AUGER +242CM P 0.0 0+ 162.86 D 8 6215.56 8 +238PU N 1.0 1.0 1 1.0 +238PU L 0 0+ 87.74 Y 3 +238PU A 6112.72 8 74.06 7 1 +238PU L 44.08 3 2+ 177 PS 5 +238PU A 6069.37 9 25.94 7 1.733 +238PU G 44.08 3 0.0330 7 E2 787 16 +238PU2 G KC=$LC=572 12$MC=159.4 32 +238PU L 146.00 5 4+ +238PU A 5969.24 9 0.034 2 390 +238PU G 101.92 4 0.00251 14E2 14.45 21 +238PU2 G KC=$LC=10.48 21$MC=2.94 6 +238PU L 303.42 7 6+ +238PU A 5816.39 110.0046 5 458 +238PU G 157.42 9 0.00145 16[E2] 2.19 4 +238PU2 G KC=0.193 4$LC=1.450 29$MC=0.405 8 +238PU L 513.62 168+ +238PU A 5607.76 160.00002 7500 +238PU G 210.20 141200E-8 0 E2 0.710 14 +238PU2 G KC=0.140 3$LC=0.415 8$MC=0.115 2 +238PU L 605.08 7 1- +238PU A 5517.75 110.00025 5 183 +238PU G 561.02 100.00015 4 E1 0.0115323 +238PU2 G KC=0.00929 18$LC=0.00169 3$MC=4.07E-4 8 +238PU G 605.04 101.05E-4 30E1 0.0099920 +238PU2 G KC=0.00806 16$LC=0.00146 3$MC=3.50E-4 7 +238PU L 661.28 113- +238PU A 5462.47 1413000E-93 1700 +238PU G 515.25 194.5E-6 12E1+M2 0.114 17 0.022 3 +238PU2 G KC=0.0175 21$LC=0.0037 6$MC=0.00092 14 +238PU G 617.20 127.9E-6 21E1+M2 0.077 17 0.0120 12 +238PU2 G KC=0.0095 9$LC=0.00185 22$MC=0.00045 6 +238PU L 763.22 5- +238PU A 5366.22 1522000E-1 24000 +238PU G 459.8 2 6E-8 3 +238PU G 617.22 13160E-9 0 +238PU L 941.44 9 0+ +238PU A 5186.95 1235000E-97 12 +238PU G 336.36 157E-7 3 [E1] 0.0323 6 +238PU2 G KC=0.0257 5$LC=0.00502 10$MC=0.00122 2 +238PU G 897.33 102.2E-5 6 (E2) 0.0152 3 +238PU2 G KC=0.01108 22$LC=0.00308 6$MC=7.78E-4 15 +238PU G 941.5 2 +238PU L 962.72 8 1- +238PU A 5165.95 1611300E-121278 +238PU G 357.64 7 4.5E-8 9 M1+E2 2.43 20 0.214 15 +238PU2 G KC=0.133 12$LC=0.0599 17$MC=0.0158 4 +238PU G 918.7 2 5.4E-7 15E1 0.004699 +238PU2 G KC=0.00382 8$LC=6.63E-4 13$MC=1.58E-4 3 +238PU G 962.8 2 5.3E-7 15E1 0.004328 +238PU2 G KC=0.00352 7$LC=6.09E-4 12$MC=1452E-7 29 +238PU L 983.00 9 2+ +238PU A 5146.07 1217000E-15 137 +238PU G 837.01 151.9E-7 6 [E2] 0.0174 3 +238PU2 G KC=0.01250 25$LC=0.00366 7$MC=9.30E-4 19 +238PU G 938.91 101.8E-7 6 +E2 4.4 4 +238PU2 G KC=$LC=$MC= +238PU G 983.0 3 5.0E-7 18[E2] 0.0127625 +238PU2 G KC=0.00946 18$LC=0.00246 5$MC=6.19E-4 12 +238PU L 1018.6 3 1- +238PU A 5111.1 3 20000E-1 700 +238PU G 974.5 3 200E-9 0 +238PU L 1028.62 5 2+ +238PU A 5101.21 1037000E-11032 +238PU G 882.63 3 6.7E-8 15(E2) 0.0157 3 +238PU2 G KC=0.01141 23$LC=0.00321 6$MC=8.11E-4 16 +238PU G 984.5 1 2.0E-6 6 M1+E2 23 0.0127926 +238PU2 G KC=0.00949 19$LC=0.00247 5$MC=6.19E-4 12 +238PU G 1028.5 2 1.6E-6 5 E2 0.0117123 +238PU2 G KC=0.00875 17$LC=0.00221 4$MC=5.54E-4 11 +238PU L 1125.79 17(4)+ +238PU A 5005.64 1931000E-11088 +238PU G 979.8 2 2.6E-7 8 +238PU G 1081.7 3 5E-8 2 +238PU L 1228.69 220+ +238PU A 4904.44 2355000E-11510 +238PU G 1184.6 3 5.0E-7 15E2 0.0089918 +238PU2 G KC=0.00685 14$LC=0.00160 3$MC=3.97E-4 8 +238PU G 1228.7 3 +238PU L 1264.29 222+ +238PU A 4869.43 2352000E-1146 +238PU G 1118.3 3 1.7E-7 9 [E2] 0.0100120 +238PU2 G KC=0.00757 15$LC=0.00182 3$MC=4.54E-4 9 +238PU G 1220.2 3 2.8E-7 9 +E2+(M1) 0.26 3 +238PU2 G KC=$LC=$MC= + diff --git a/HEN_HOUSE/spectra/lnhb/Cm-243.txt b/HEN_HOUSE/spectra/lnhb/Cm-243.txt new file mode 100644 index 000000000..e4589f6fc --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Cm-243.txt @@ -0,0 +1,196 @@ +243AM 243CM EC DECAY (28.9 Y) +243AM H TYP=Full$AUT=V.P. Chechev$CUT=30-OCT-2010$ +243AM C Evaluation history: Type=Full;Author=V.P. Chechev;Cutoff date=30-OCT-2010 +243AM C References: 1950Th52, 1953As14, 1953As40, 1955Sc08, 1956Ne17, 1957As70, +243AM2C 1957As83, 1958Ch38, 1959Ew90, 1962Iv01, 1963Le17, 1963Dz07, 1964Ba31, +243AM3C 1964Hy02, 1965Ma17, 1966Ba07, 1970By01, 1971Bb10, 1972Po04, 1972Ah02, +243AM4C 1972Kr07, 1973Ah04, 1976BaZZ, 1977VaZW, 1979Bo30, 1982Ah04, 1986Ti03, +243AM5C 1987Po19, 1990Si12, 1991Ry01, 2003Au03, 2003Br12, 2004Ak21, 2005Tr08, +243AM6C 2008BeZV, 2008Ki07, 2009KoZV +243AM T Auger electrons and ^X ray energies and emission intensities: +243AM T {U Energy (keV)} {U Intensity } {U Line } +243AM T +243AM T 102.03 XKA2 +243AM T 106.472 XKA1 +243AM T +243AM T 119.243 |] XKB3 +243AM T 120.284 |] XKB1 +243AM T 120.989 |] XKB5II +243AM T +243AM T 123.58 |] XKB2 +243AM T 124.127 |] XKB4 +243AM T 124.723 |] XKO23 +243AM T +243AM T +243AM T 77.04-85.638 |] KLL AUGER +243AM T 94.891-106.467 |] ^KLX AUGER +243AM T 112.72-124.97 |] KXY AUGER +243AM T 6.26-23.7 L AUGER +243CM P 0.0 5/2+ 28.9 Y 4 7.5 17 +243AM N 3.448E2 3.448E2 0.0029 3 3.448E2 +243AM G 640 +243AM G 680 +243AM G 720 +243AM G 740 +243AM G 760 +243AM L 0 5/2- 7367 Y 23 +243AM E 0.29 3 7.2 +243AM2 E EAV= $CK= $CL= $CM=0.12 12$CN=0.64 15$CO= + +239PU 243CM A DECAY (28.9 Y) +239PU H TYP=Full$AUT=V.P. Chechev$CUT=30-OCT-2010$ +239PU C Evaluation history: Type=Full;Author=V.P. Chechev;Cutoff date=30-OCT-2010 +239PU C References: 1950Th52, 1953As14, 1953As40, 1955Sc08, 1956Ne17, 1957As70, +239PU2C 1957As83, 1958Ch38, 1959Ew90, 1962Iv01, 1963Le17, 1963Dz07, 1964Ba31, +239PU3C 1964Hy02, 1965Ma17, 1966Ba07, 1970By01, 1971Bb10, 1972Po04, 1972Ah02, +239PU4C 1972Kr07, 1973Ah04, 1976BaZZ, 1977VaZW, 1979Bo30, 1982Ah04, 1986Ti03, +239PU5C 1987Po19, 1990Si12, 1991Ry01, 2003Au03, 2003Br12, 2004Ak21, 2005Tr08, +239PU6C 2008BeZV, 2008Ki07, 2009KoZV +239PU T Auger electrons and ^X ray energies and emission intensities: +239PU T {U Energy (keV)} {U Intensity } {U Line } +239PU T +239PU T 99.525 13.34 28 XKA2 +239PU T 103.734 21.1 5 XKA1 +239PU T +239PU T 116.244 |] XKB3 +239PU T 117.228 |] 7.75 21 XKB1 +239PU T 117.918 |] XKB5II +239PU T +239PU T 120.54 |] XKB2 +239PU T 120.969 |] 2.69 8 XKB4 +239PU T 121.543 |] XKO23 +239PU T +239PU T 12.1246-21.9844 52.1 16 XL (total) +239PU T 12.1246 1.40 6 XLL +239PU T 14.0834-14.2791 21.8 8 XLA +239PU T 16.334 0.418 26 XLC +239PU T 16.4987-18.5427 23.2 9 XLB +239PU T 20.7081-21.9844 5.30 22 XLG +239PU T +239PU T 75.263-85.357 |] KLL AUGER +239PU T 92.607-103.729 |] 1.34 19 ^KLX AUGER +239PU T 109.93-121.78 |] KXY AUGER +239PU T 6.19-22.99 49.3 15 L AUGER +243CM P 0.0 5/2+ 28.9 Y 4 6168.8 10 +239PU N 1.003E0 1.003E0 0.9971 3 1.003E0 +239PU G 640 +239PU G 680 +239PU G 720 +239PU G 740 +239PU G 760 +239PU L 0 1/2+ 24100 Y 11 +239PU A 6067.2 101.3 2 2210 +239PU L 7.861 2 3/2+ 36 PS 3 +239PU A 6059.4 104.41 20593 +239PU G 7.861 2 1500E-5 0 M1+E2 0.055 3 5.7E3 4 +239PU2 G KC=$LC=$MC=4.2E3 3 +239PU L 57.275 2 5/2+ 101 PS 5 +239PU A 6010.8 101.05 121410 +239PU G 49.414 2 0.20000 0 M1+E2 0.50 3 126 8 +239PU2 G KC=$LC=92 6$MC=24.8 17 +239PU G 57.273 4 6000E-5 0 E2 222 4 +239PU2 G KC=$LC=161.1 23$MC=45.0 7 +239PU L 75.705 3 7/2+ 83 PS 8 +239PU A 5992.7 105.72 20209 +239PU G 18.430 4 1000E-7 0 (M1+E2) 8E3 6 +239PU2 G KC=$LC=$MC=6E3 6 +239PU G 67.841 7 0.20 5 E2 98.5 14 +239PU2 G KC=$LC=71.5 10$MC=20.0 3 +239PU L 163.76 3 9/2+ 73 PS 4 +239PU A 5906.1 1010029E-5 4230 +239PU G 88.06 3 1800E-6 0 M1+E2 0.5 12.26 18 +239PU2 G KC=$LC=9.07 13$MC=2.36 4 +239PU G 106.47 4 1500E-5 0 E2 11.80 17 +239PU2 G KC=$LC=8.56 12$MC=2.40 4 +239PU L 192.8 1011/2+ +239PU A 5877.6 1470204E-5 427 +239PU G 117.1 108000E-5 0 [E2] 7.6 4 +239PU2 G KC=$LC=5.52 24$MC=1.54 7 +239PU L 285.460 2 5/2+ 1.12 NS 5 +239PU A 5786.4 1073.61 401.32 +239PU G 209.753 2 3.29 10M1+E2 -0.019 15 3.24 5 +239PU2 G KC=2.56 4$LC=0.511 8$MC=0.1241 18 +239PU G 228.183 2 10.6 3 M1+E2 0.009 6 2.56 4 +239PU2 G KC=2.02 3$LC=0.403 6$MC=0.0979 14 +239PU G 277.599 2 14.0 4 M1+E2 0.165 2 1.448 21 +239PU2 G KC=1.142 16$LC=0.230 4$MC=0.0560 8 +239PU G 285.460 2 0.73 2 E2 0.247 4 +239PU2 G KC=0.0843 12$LC=0.1190 17$MC=0.0326 5 +239PU L 330.124 4 7/2+ +239PU A 5742.5 1011.33 204.94 +239PU G 44.663 5 0.131 16M1+E2 0.24 4 96 13 +239PU2 G KC=$LC=72 9$MC=18 3 +239PU G 166.39 6 0.016 7 M1 6.22 9 +239PU2 G KC=4.91 7$LC=0.984 14$MC=0.239 4 +239PU G 254.40 3 0.11 1 M1+E2 -0.159 6 1.85 3 +239PU2 G KC=1.457 21$LC=0.294 5$MC=0.0716 10 +239PU G 272.87 9 0.08 1 M1+E2 0.165 9 1.518 22 +239PU2 G KC=1.198 18$LC=0.241 4$MC=0.0588 9 +239PU G 322.3 2 0.007 1 [E2] 0.1699 24 +239PU2 G KC=0.0679 10$LC=0.0745 11$MC=0.0203 3 +239PU L 387.42 2 9/2+ +239PU A 5686.1 101.6 1 17 +239PU G 57.30 2 8000E-5 0 [M1] 28.6 4 +239PU2 G KC=$LC=21.5 3$MC=5.24 8 +239PU G 101.96 2 8000E-6 0 E2 14.42 21 +239PU2 G KC=$LC=10.46 15$MC=2.93 5 +239PU G 311.7 2 0.017 2 M1+E2 0.1 1 1.06 3 +239PU2 G KC=0.84 3$LC=0.168 4$MC=0.0408 8 +239PU L 391.584 3 7/2- 193 NS 4 +239PU A 5682 1 20058E-5 129 +239PU G 4.16 2 E1 +239PU G 61.460 2 0.0151 13E1 0.473 7 +239PU2 G KC=$LC=0.354 5$MC=0.0881 13 +239PU G 106.125 2 0.296 25E1(+M2) -0.007 7 0.26 4 +239PU2 G KC=$LC=0.19 3$MC=0.050 8 +239PU G 315.880 3 0.018 2 E1(+M2) 0.008 8 0.0372 9 +239PU2 G KC=0.0294 6$LC=0.00583 16$MC=0.00141 4 +239PU G 334.310 3 0.024 2 E1(+M2) 0.006 6 0.0329 6 +239PU2 G KC=0.0261 5$LC=0.00511 10$MC=1238E-6 24 +239PU L 427 3 + +239PU A 5647 3 30087E-6 549 +239PU L 434 3 9/2- +239PU A 5640 3 14041E-5 108 +239PU L 451 5 + +239PU A 5624 5 60175E-6 202 +239PU L 462 3 11/2+ +239PU A 5613 3 30087E-6 351 +239PU L 469.8 4 1/2- +239PU A 5605.1 1110029E-6 951 +239PU G 461.9 5 E1+M2 +239PU G 469.8 5 E1 +239PU L 481 3 + +239PU A 5594 3 10029E-6 823 +239PU L 487 3 11/2- +239PU A 5588 3 20058E-6 381 +239PU L 492.1 3 3/2- +239PU A 5583.2 1090262E-7 792 +239PU G 434.7 5 E1+M2 +239PU G 484.3 5 +239PU G 492.3 5 E1+M2 +239PU L 499 3 + +239PU A 5576 3 70204E-7 930 +239PU L 505.6 2 5/2- +239PU A 5569.9 1070204E-7 854 +239PU G 430.0 3 E1+M2 +239PU G 447.6 5 +239PU G 497.8 3 E1+M2 +239PU L 538 3 + +239PU A 5538 3 20058E-7 1955 +239PU L 543 3 + +239PU A 5533 3 60175E-7 610 +239PU L 556.2 5 7/2- +239PU A 5520.1 1120058E-7 1538 +239PU G 392.4 5 E1+M2 +239PU G 499 E1+M2 +239PU L 746 3 + +239PU A 5333 3 30087E-7 77.9 +239PU L 756 3 + +239PU A 5324 3 30087E-7 67.7 +239PU L 763 3 + +239PU A 5317 3 10029E-7 184 +239PU L 813 3 + +239PU A 5268 3 15044E-7 60.6 +239PU L 850 15 + +239PU A 5231 1539113E-8 137 + diff --git a/HEN_HOUSE/spectra/lnhb/Cm-244.txt b/HEN_HOUSE/spectra/lnhb/Cm-244.txt new file mode 100644 index 000000000..2312fc429 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Cm-244.txt @@ -0,0 +1,102 @@ +240PU 244CM A DECAY (18.11 Y) +240PU H TYP=Update$AUT=V.P. Chechev$CUT=31-OCT-2009$ +240PU2 H TYP=Full$AUT=V.P.Chechev$CUT=31-OCT-2009$ +240PU3 H TYP=Full$AUT=V.P.Chechev$CUT=31-JAN-2005$ +240PU4 H TYP=Full$AUT=V.P.Chechev$CUT=31-JAN-2005$ +240PU5 H TYP=Full$AUT=V.P.Chechev$CUT=31-JAN-2005$ +240PU6 H TYP=Full$AUT=V.P.Chechev$CUT=31-JAN-2005$ +240PU C Evaluation history: Type=Update;Author=V.P. Chechev;Cutoff date=31-OCT-2009 +240PU2C Type=Full;Author=V.P.Chechev;Cutoff date=31-OCT-2009 +240PU3C Type=Full;Author=V.P.Chechev;Cutoff date=31-JAN-2005 +240PU4C Type=Full;Author=V.P.Chechev;Cutoff date=31-JAN-2005 +240PU5C Type=Full;Author=V.P.Chechev;Cutoff date=31-JAN-2005 +240PU6C Type=Full;Author=V.P.Chechev;Cutoff date=31-JAN-2005 +240PU C References: 1952Gh27, 1954Fr19, 1954St33, 1956Hu96, 1956Sm18, 1960As11, +240PU2C 1961Ca01, 1963Bj03, 1963Ma56, 1963Dz07, 1965Me02, 1967Ar09, 1967Be65, +240PU3C 1966Ba07, 1968Be26, 1968Du06, 1969Sc18, 1970Sc39, 1970Ba11, 1971Gr17, +240PU4C 1972Sp06, 1972Ah07, 1972Ha80, 1972Ke29, 1972Sc01, 1978LeZA, 1980Di13, +240PU5C 1981Hs02, 1982Ba56, 1982Po14, 1984BuZJ, 1990Pe03, 1990Po14, 1991ry01, +240PU6C 1992Fr04, 1993Pa29, 1995Jo23, 1996Bu50, 1996Sc09, 1996Sa24, 1997Ka59, +240PU7C 1998Ga19, 1998Ya17, 2002Da21, 2003Au03, 2004Ch64, 2006Ch34, 2008Ki07 +240PU T Auger electrons and ^X ray energies and emission intensities: +240PU T {U Energy (keV)} {U Intensity } {U Line } +240PU T +240PU T 99.525 0.000061 4 XKA2 +240PU T 103.734 0.000097 5 XKA1 +240PU T +240PU T 116.244 |] XKB3 +240PU T 117.228 |] 0.0000354 20 XKB1 +240PU T 117.918 |] XKB5II +240PU T +240PU T 120.54 |] XKB2 +240PU T 120.969 |] 0.0000123 7 XKB4 +240PU T 121.543 |] XKO23 +240PU T +240PU T 12.125-21.984 8.92 23 XL (total) +240PU T 12.125 0.219 8 XLL +240PU T 14.083-14.279 3.42 11 XLA +240PU T 16.334 0.092 4 XLC +240PU T 16.499-19.331 4.21 14 XLB +240PU T 20.708-21.984 0.970 4 XLG +240PU T +240PU T 75.263-85.357 |] KLL AUGER +240PU T 92.607-103.729 |] 0.0000061 9 ^KLX AUGER +240PU T 109.93-121.78 |] KXY AUGER +240PU T 6.19-22.99 8.09 20 L AUGER +244CM P 0.0 0+ 18.11 Y 3 5901.74 5 +240PU N 1.0 1.0 1 1.0 +240PU L 0 0+ 6561 Y 7 +240PU A 5804.77 5 76.7 4 1 +240PU L 42.824 8 2+ 164 PS 5 +240PU A 5762.65 5 23.3 4 1.94 +240PU G 42.824 8 0.0258 7 E2 905 18 +240PU2 G KC=$LC=658 13$MC=183 4 +240PU L 141.690 154+ +240PU A 5665.41 5 0.0204 15636 +240PU G 98.860 130.00136 9 E2 16.6 3 +240PU2 G KC=$LC=12.08 24$MC=3.38 7 +240PU L 294.319 246+ +240PU A 5515.29 6 0.00352 18512 +240PU G 152.63 2 0.00102 5 (E2) 2.48 5 +240PU2 G KC=0.196 4$LC=1.66 3$MC=0.465 9 +240PU L 497.6 8+ +240PU A 5315.3 0.00004 +240PU G 202.4 2200E-8 0 (E2) 0.817 16 +240PU2 G KC=0.148 3$LC=0.487 10$MC=0.135 3 +240PU L 597.34 4 1- +240PU A 5217.24 7 55000E-99 500 +240PU G 554.52 4 8.7E-5 11(E1) 0.0117924 +240PU2 G KC=0.00949 19$LC=0.00174 4$MC=4.17E-4 9 +240PU G 597.34 4 5.3E-5 7 (E1) 0.0102421 +240PU2 G KC=0.00826 17$LC=0.00150 3$MC=3.59E-4 7 +240PU L 648.85 4 3- +240PU A 5166.58 7 42000E-1303100 +240PU G 507.16 5 8.7E-6 28(E1) 0.0140129 +240PU2 G KC=0.01126 23$LC=0.00208 4$MC=0.00050 1 +240PU G 606.03 4 8.1E-6 14 +240PU L 860.71 7 0+ +240PU A 4958.20 9 14900E-8163.5 +240PU G 263.37 8 6.2E-5 9 (E1) 0.0547 11 +240PU2 G KC=0.0433 9$LC=0.00881 18$MC=0.00214 4 +240PU G 817.89 7 6.8E-5 9 (E2) 0.0182 4 +240PU2 G KC=0.0130 3$LC=0.00389 8$MC=9.89E-4 20 +240PU G 860.71 7 8.2E-6 20() +240PU L 900.32 4 2+ +240PU A 4919.24 7 50000E-95 5.6 +240PU G 251.47 6 1.14E-5 23(E1) 0.0606 12 +240PU2 G KC=0.048 1$LC=0.00983 20$MC=0.00239 5 +240PU G 302.98 6 1.9E-5 3 (E1) 0.0405 8 +240PU2 G KC=0.0320 7$LC=0.00637 13$MC=0.00154 3 +240PU G 758.63 5 1.38E-5 19(E2) 0.0212 4 +240PU2 G KC=0.0148 3$LC=0.00473 9$MC=1211E-6 24 +240PU G 857.50 4 5.7E-6 8 +240PU G 900.32 4 1.3E-6 6 +240PU L 938.06 6 1- +240PU A 4882.12 8 47000E-11133 +240PU G 289.21 7 6E-7 3 E2+M3 7 7 +240PU2 G KC=3 4$LC=2.4 23$MC=0.7 7 +240PU G 340.72 7 1.8E-6 9 +240PU G 895.24 6 1.8E-6 6 E1+M2 0.07 7 +240PU2 G KC=0.06 6$LC=0.013 13$MC=0.003 3 +240PU G 938.06 6 4E-7 4 + diff --git a/HEN_HOUSE/spectra/lnhb/Cm-245.txt b/HEN_HOUSE/spectra/lnhb/Cm-245.txt new file mode 100644 index 000000000..4b1e37335 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Cm-245.txt @@ -0,0 +1,87 @@ +241PU 245CM A DECAY (8250 Y) +241PU H TYP=Full$AUT=V.P. Chechev$CUT=30-OCT-2010$ +241PU C Evaluation history: Type=Full;Author=V.P. Chechev;Cutoff date=30-OCT-2010 +241PU C References: 1954HU50, 1954Fr19, 1955Br02, 1955Pe32, 1957HU76, 1960As11, +241PU2C 1961Ca01, 1963DZ07, 1964Hy02, 1966BA07, 1966FR03, 1969Me01, 1971Ma32, +241PU3C 1975BA65, 1976BAZZ, 1977La19, 1980DI13, 1982Po14, 1985DR10, 1989Ho24, +241PU4C 1991PO17, 1991RY01, 1994SH31, 1996Sc06, 1998WH01, 2000Sc47, 2003Au03, +241PU5C 2005MA88, 2008Ki07, 2008KOZP, 2009KOZV +241PU T Auger electrons and ^X ray energies and emission intensities: +241PU T {U Energy (keV)} {U Intensity } {U Line } +241PU T +241PU T 99.525 19.0 5 XKA2 +241PU T 103.734 30.1 7 XKA1 +241PU T +241PU T 116.244 |] XKB3 +241PU T 117.228 |] 11.06 30 XKB1 +241PU T 117.918 |] XKB5II +241PU T +241PU T 120.54 |] XKB2 +241PU T 120.969 |] 3.84 12 XKB4 +241PU T 121.543 |] XKO23 +241PU T +241PU T 12.1246-21.9844 51.7 10 XL (total) +241PU T 12.1246 1.46 4 XLL +241PU T 14.0834-14.2791 22.8 6 XLA +241PU T 16.334 0.334 11 XLC +241PU T 16.4987-19.331 22.1 5 XLB +241PU T 20.7081-21.9844 4.97 10 XLG +241PU T +241PU T 75.263-85.357 |] KLL AUGER +241PU T 92.607-103.729 |] 1.91 27 ^KLX AUGER +241PU T 109.93-121.78 |] KXY AUGER +241PU T 6.19-22.99 50.1 13 L AUGER +245CM P 0.0 7/2+ 8250 Y 70 5622.3 5 +241PU N 1.0 1.0 1 1.0 +241PU G 388.16 5 0.019 1 +241PU L 0 5/2+ 14.33 Y 4 +241PU A 5530.4 4 0.58 1770 +241PU L 41.9722 9 7/2+ +241PU A 5488.5 5 0.83 768 +241PU G 41.972 1 0.369 20M1+E2 0.186 4 102.4 20 +241PU2 G KC=$LC=76.2 15$MC=19.4 4 +241PU L 95.7795 129/2+ +241PU A 5436.1 5 0.04 7130 +241PU G 53.807 1 0.073 4 M1+E2 0.201 8 44.7 11 +241PU2 G KC=$LC=33.3 8$MC=8.42 21 +241PU G 95.7795 120.0109 23E2 19.3 3 +241PU2 G KC=$LC=14.0 2$MC=3.92 6 +241PU L 161.314 4 11/2+ +241PU A 5371.7 5 0.39 22300 +241PU G 65.535 3 0.018 2 M1+E2 0.22 22 24 12 +241PU2 G KC=$LC=18 9$MC=4.5 24 +241PU L 161.6852 9 1/2+ 0.88 US 5 +241PU A 5371.4 5 0.0210 9 5520 +241PU G 161.685 1 0.071 3 E2 1.96 3 +241PU2 G KC=0.190 3$LC=1.289 18$MC=0.360 5 +241PU L 175.0523 147/2+ +241PU A 5361.8 1293.2 5 1.03 +241PU G 79.2728 180.120 7 M1+E2 0.65 25 22 6 +241PU2 G KC=$LC=16 5$MC=4.3 12 +241PU G 133.081 2 2.81 7 M1+E2 0.222 9 11.36 17 +241PU2 G KC=8.80 13$LC=1.92 3$MC=0.473 7 +241PU G 175.0523 149.83 22M1+E2 0.217 19 5.21 8 +241PU2 G KC=4.07 7$LC=0.855 12$MC=0.209 3 +241PU L 231.935 9 9/2+ +241PU A 5303.6 125.0 1 8.7 +241PU G 56.89 3 0.0359 21M1+E2 0.638 50 87 7 +241PU2 G KC=$LC=64 5$MC=17.3 14 +241PU G 136.156 9 0.113 4 M1+E2 0.63 21 9 1 +241PU2 G KC=6.2 12$LC=2.04 15$MC=0.52 5 +241PU G 189.965 100.204 6 M1+E2 0.63 7 3.36 16 +241PU2 G KC=2.46 15$LC=0.665 10$MC=0.1680 25 +241PU G 231.935 9 0.0117 18[E2] 0.498 7 +241PU2 G KC=0.1200 17$LC=0.275 4$MC=0.0760 11 +241PU L 301.172 1611/2+ +241PU A 5234.4 120.32 51 +241PU G 69.237 180.007 3 M1(+E2) 0.433 300 28 14 +241PU2 G KC=$LC=21 10$MC=5 3 +241PU G 126.09 4 0.007 2 [E2] 5.59 8 +241PU2 G KC=0.1705 24$LC=3.94 6$MC=1.101 16 +241PU G 139.858 160.008 1 [M1E2] 7 4 +241PU2 G KC=4 4$LC=2.0 5$MC=0.54 15 +241PU G 205.393 160.009 1 [M1E2] 2.1 14 +241PU2 G KC=1.4 13$LC=0.50 5$MC=0.129 3 +241PU L 385 3 (13/2)+ +241PU A 5152 3 0.005 1000 + diff --git a/HEN_HOUSE/spectra/lnhb/Cm-246.txt b/HEN_HOUSE/spectra/lnhb/Cm-246.txt new file mode 100644 index 000000000..f87212b33 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Cm-246.txt @@ -0,0 +1,42 @@ +242PU 246CM A DECAY (4723 Y) +242PU H TYP=Full$AUT=F.Kondev$CUT=31-OCT-2006$ +242PU C Evaluation history: Type=Full;Author=F.Kondev;Cutoff date=31-OCT-2006 +242PU C References: 1977La19 +242PU T Auger electrons and ^X ray energies and emission intensities: +242PU T {U Energy (keV)} {U Intensity } {U Line } +242PU T +242PU T 99.525 XKA2 +242PU T 103.734 XKA1 +242PU T +242PU T 116.244 |] XKB3 +242PU T 117.228 |] XKB1 +242PU T 117.918 |] XKB5II +242PU T +242PU T 120.54 |] XKB2 +242PU T 120.969 |] XKB4 +242PU T 121.543 |] XKO23 +242PU T +242PU T 12.125-21.984 7.95 24 XL (total) +242PU T 12.125 0.195 8 XLL +242PU T 14.083-14.279 3.03 11 XLA +242PU T 16.334 0.082 4 XLC +242PU T 16.499-19.331 3.76 14 XLB +242PU T 20.708-21.984 0.87 4 XLG +242PU T +242PU T 75.263-85.357 |] KLL AUGER +242PU T 92.607-103.729 |] ^KLX AUGER +242PU T 109.93-121.78 |] KXY AUGER +242PU T 6.19-22.99 7.20 21 L AUGER +246CM P 0.0 0+ 4723 Y 27 5476.7 9 +242PU N 1.00E0 1.00E0 0.999738 1.00E0 +242PU L 0 0+ 3.73E5 Y 3 +242PU A 5387.5 9 79.19 221 +242PU L 44.545 9 2+ +242PU A 5343.7 9 20.82 222.05 +242PU G 44.545 9 0.0279 8 E2 746 22 +242PU2 G KC=$LC=542 16$MC=151.4 45 +242PU L 147.35 104+ +242PU A 5242.5 100.020 2 500 +242PU G 102.8 1 0.00134 14E2 13.86 42 +242PU2 G KC=$LC=10.06 30$MC=2.82 8 + diff --git a/HEN_HOUSE/spectra/lnhb/Co-56.txt b/HEN_HOUSE/spectra/lnhb/Co-56.txt new file mode 100644 index 000000000..4a66cb303 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Co-56.txt @@ -0,0 +1,115 @@ + 56FE 56CO EC DECAY (77.236 D) + 56FE C References: 1977La19, 1979Sc31, 1999Hu04, 2000He14, 2000Ra36, 2002Ba38, + 56FE2C 2003Au03 + 56FE T Auger electrons and ^X ray energies and emission intensities: + 56FE T {U Energy (keV)} {U Intensity } {U Line } + 56FE T + 56FE T 6.39091 7.53 10 XKA2 + 56FE T 6.40391 14.75 17 XKA1 + 56FE T + 56FE T 7.05804 |] 3.05 5 XKB1 + 56FE T 7.1083 |] XKB5II + 56FE T + 56FE T + 56FE T 0.615-0.792 0.581 17 XL (total) + 56FE T 0.615 XLL + 56FE T -0.792 XLB + 56FE T + 56FE T 5.37-5.645 |] KLL AUGER + 56FE T 6.158-6.4 |] 46.04 30 ^KLX AUGER + 56FE T 6.926-7.105 |] KXY AUGER + 56FE T 0.51-0.594 111.8 8 L AUGER + 56CO P 0.0 4+ 77.236 D 26 4566 2 + 56FE N 1.0 1.0 1 1.0 + 56FE L 0 0+ STABLE + 56FE L 846.7700 192+ + 56FE E 0.25 170.005 3 11.6 2 + 56FE2 E EAV=1205.8 10$CK=0.8890 16$CL=0.0951 13$CM=0.0152 5$CN= $CO= + 56FE G 846.7638 1999.9399 23E2 3.03E-49 + 56FE2 G KC=$LC=$MC= + 56FE L 2085.0583 254+ + 56FE E 18.29 162.43 3 8.62 + 56FE2 E EAV=631.2 9$CK=0.8888 16$CL=0.0952 13$CM=0.0152 5$CN= $CO= + 56FE G 1238.2736 2266.41 16E2 + 56FE L 2657.527 4 2+ + 56FE G 1810.726 4 0.639 3 M1+E2 -0.17 3 + 56FE G 2657.4 8 0.0195 20[E2] + 56FE L 2959.905 5 2+ + 56FE E 0.0086 220.023 6 10.26 2 + 56FE2 E EAV=247.1 9$CK=0.8885 16$CL=0.0955 13$CM=0.0153 5$CN= $CO= + 56FE G 2113.092 6 0.376 3 M1+E2 0.27 3 + 56FE L 3122.901 3 4+ + 56FE E 1.04 2 8.99 6 7.58 + 56FE2 E EAV=178.7 8$CK=0.8884 16$CL=0.0955 13$CM=0.0153 5$CN= $CO= + 56FE G 1037.8333 2414.03 5 M1(+E2) 0.00 5 + 56FE G 2276.36 160.118 4 E2 + 56FE L 3369.86 112+ + 56FE E 6.E-6 200.015 5 10.2 2 + 56FE2 E EAV=76.7 8$CK=0.8883 16$CL=0.0957 13$CM=0.0153 5$CN= $CO= + 56FE G 2523.0 8 0.063 4 M1+E2 0.25 15 + 56FE G 3369.69 300.0103 8 E2 + 56FE L 3445.270 3 3+ + 56FE E 0.0080 7 21.40 5 6.98 + 56FE2 E EAV=45.3 9$CK=0.8882 16$CL=0.0957 13$CM=0.0153 5$CN= $CO= + 56FE G 787.7391 230.310 4 M1+E2 0.85 35 + 56FE G 1360.196 4 4.280 13M1+E2 -0.11 1 + 56FE G 2598.438 4 16.96 4 M1+E2 -0.28 2 + 56FE L 3856.415 3 3+ + 56FE E 16.86 5 6.69 + 56FE2 E EAV= $CK=0.8875 16$CL=0.0963 13$CM=0.0154 5$CN= $CO= + 56FE G 411.38 8 0.0269 23 + 56FE G 486.54 110.058 3 + 56FE G 733.5085 230.191 4 M1+E2 -0.02 2 + 56FE G 896.503 7 0.0704 22 + 56FE G 1198.78 200.044 3 + 56FE G 1771.327 3 15.45 4 M1+E2 -0.004 2 + 56FE G 3009.559 4 1.038 19M1+E2 0.065 5 + 56FE L 4048.799 8 3+ + 56FE E 3.965 157.04 + 56FE2 E EAV= $CK=0.8868 16$CL=0.0969 13$CM=0.0155 5$CN= $CO= + 56FE G 1089.03 240.054 4 M1+E2 0.43 12 + 56FE G 1963.703 110.706 4 M1+E2 0.22 3 + 56FE G 3201.930 113.203 13M1+E2 0.50 1 + 56FE L 4100.273 4 4+ 55 FS 25 + 56FE E 12.66 4 6.44 + 56FE2 E EAV= $CK=0.8866 16$CL=0.0971 13$CM=0.0156 5$CN= $CO= + 56FE G 655.0 8 0.038 8 + 56FE G 977.363 4 1.422 7 M1(+E2) 0.07 3 + 56FE G 1140.356 7 0.132 4 + 56FE G 1442.75 8 0.180 4 + 56FE G 2015.176 5 3.017 14M1+E2 0.68 5 + 56FE G 3253.402 5 7.87 3 E2 + 56FE L 4119.849 4 3+ + 56FE E 9.940 186.51 + 56FE2 E EAV= $CK=0.8864 16$CL=0.0972 13$CM=0.0156 5$CN= $CO= + 56FE G 263.41 100.0234 20 + 56FE G 674.7 8 0.035 5 + 56FE G 996.939 5 0.116 6 M1+E2 + 56FE G 1159.933 8 0.088 3 M1+E2 0.064 16 + 56FE G 1462.34 120.0778 9 + 56FE G 2034.752 5 7.741 13M1+E2 -0.073 5 + 56FE G 3272.978 6 1.855 9 M1+E2 0.420 4 + 56FE L 4298.002 3 4+ 110 FS 50 + 56FE E 3.688 136.49 + 56FE2 E EAV= $CK=0.8845 16$CL=0.0989 13$CM=0.0159 5$CN= $CO= + 56FE G 852.78 5 0.049 3 + 56FE G 1175.0878 222.249 9 M1+E2 0.14 4 + 56FE G 1640.450 5 0.0621 21 + 56FE G 2212.898 3 0.385 5 M1+E2 -3 1 + 56FE G 3451.119 4 0.942 6 E2 + 56FE L 4394.82 6 3+ + 56FE E 0.2159 187.32 + 56FE2 E EAV= $CK=0.8816 17$CL=0.1013 13$CM=0.0164 6$CN= $CO= + 56FE G 1272.2 6 0.0202 8 + 56FE G 3547.93 6 0.1956 16M1+E2 -0.30 2 + 56FE L 4447.6 4 (2-,3,4)+ + 56FE E 0.0167 5 8.1 2 + 56FE2 E EAV= $CK=0.8779 17$CL=0.1044 14$CM=0.0169 6$CN= $CO= + 56FE G 3600.71 400.0167 5 + 56FE L 4458.30 3 4+ + 56FE E 0.209 7 6.91 + 56FE2 E EAV= $CK=0.8766 17$CL=0.1055 14$CM=0.0171 6$CN= $CO= + 56FE G 1335.380 290.1228 16 + 56FE G 2373.7 4 0.078 6 + 56FE G 3611.8 8 0.0084 4 [E2] + diff --git a/HEN_HOUSE/spectra/lnhb/Co-57.txt b/HEN_HOUSE/spectra/lnhb/Co-57.txt new file mode 100644 index 000000000..d36e3aa73 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Co-57.txt @@ -0,0 +1,57 @@ + 57FE 57CO EC DECAY (271.80 D) + 57FE C References: 1977La19 + 57FE T Auger electrons and ^X ray energies and emission intensities: + 57FE T {U Energy (keV)} {U Intensity } {U Line } + 57FE T + 57FE T 6.39091 16.8 3 XKA2 + 57FE T 6.40391 33.2 5 XKA1 + 57FE T + 57FE T 7.05804 |] 7.1 2 XKB1 + 57FE T 7.1083 |] XKB5II + 57FE T + 57FE T + 57FE T 0.61-0.79 1.55 13 XL (total) + 57FE T 0.61 XLL + 57FE T -0.79 XLB + 57FE T + 57FE T 5.37-5.64 |] KLL AUGER + 57FE T 6.16-6.4 |] 105.2 13 ^KLX AUGER + 57FE T 6.91-7.1 |] KXY AUGER + 57FE T 0.6-0.7 252 3 L AUGER + 57CO P 0.0 7/2- 271.80 D 5 836.0 4 + 57FE N 1.0 1.0 1 1.0 + 57FE L 0 1/2- STABLE + 57FE E 0.00035 12.9 + 57FE2 E EAV= $CK= $CL= $CM= $CN= $CO= + 57FE L 14.41295 313/2- 98.0 NS 3 + 57FE E 0.003 11.1 + 57FE2 E EAV= $CK= $CL= $CM= $CN= $CO= + 57FE G 14.41295 319.15 17M1+E2 8.58 18 + 57FE2 G KC=7.69 16$LC=0.782 16$MC=0.113 3 + 57FE L 136.47374 295/2- 8.8 NS 5 + 57FE E 99.82 206.45 2 + 57FE2 E EAV= $CK=0.8875 16$CL=0.0963 13$CM=0.0154 5$CN= $CO= + 57FE G 122.06065 1285.51 6 M1+E2 0.0236 5 + 57FE2 G KC=0.0212 5$LC=0.00208 5$MC=3.03E-4 7 + 57FE G 136.47356 2910.71 15E2 0.148 3 + 57FE2 G KC=0.133 3$LC=0.0136 3$MC=0.00196 4 + 57FE L 366.74 3 3/2- + 57FE E 0.002 10.8 + 57FE2 E EAV= $CK= $CL= $CM= $CN= $CO= + 57FE G 230.27 3 0.0004 4 M1+E2 0.004159 + 57FE2 G KC=0.00374 8$LC=3.56E-4 8$MC=5.24E-5 11 + 57FE G 352.34 2 0.0032 4 M1+E2 0.001503 + 57FE2 G KC=0.00135 3$LC=1.29E-4 3$MC=1.88E-5 4 + 57FE G 366.74 3 0.0013 4 M1+E2 0.001786 + 57FE2 G KC=0.00160 5$LC=1.53E-4 5$MC=2.23E-5 7 + 57FE L 706.42 2 5/2- + 57FE E 0.183 7 7.69 2 + 57FE2 E EAV= $CK=0.8789 17$CL=0.1035 14$CM=0.0168 6$CN= $CO= + 57FE G 339.67 3 0.0038 4 M1+E2 0.001654 + 57FE2 G KC=0.00149 3$LC=1.42E-4 3$MC=2.08E-5 5 + 57FE G 569.94 4 0.015 2 M1+E2 5.08E-412 + 57FE2 G KC=4.58E-4 10$LC=4.34E-5 9$MC=6.31E-6 14 + 57FE G 692.01 2 0.159 6 M1+E2 3.64E-412 + 57FE2 G KC=3.28E-4 10$LC=3.1E-5 1$MC=4.52E-6 14 + 57FE G 706.42 2 0.0050 5 (E2) + diff --git a/HEN_HOUSE/spectra/lnhb/Co-58.txt b/HEN_HOUSE/spectra/lnhb/Co-58.txt new file mode 100644 index 000000000..7976e0eeb --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Co-58.txt @@ -0,0 +1,56 @@ + 58FE 58CO EC DECAY (70.85 D) + 58FE H TYP=Full$AUT=M.M. Bé$CUT=31-AUG-2013$ + 58FE2 H TYP=Full$AUT=M.M. Bé$CUT=30-NOV-1998$ + 58FE C Evaluation history: Type=Full;Author=M.M. Bé;Cutoff date=31-AUG-2013 + 58FE2C Type=Full;Author=M.M. Bé;Cutoff date=30-NOV-1998 + 58FE C References: 1946Go01, 1946Go01, 1952Ch31, 1956Fr17, 1956Sc87, 1956Gr**, + 58FE2C 1956Co70, 1956Gr**, 1956Sc87, 1956Co70, 1956Fr17, 1958Ko64, 1958Da03, + 58FE3C 1958Da03, 1958Ko64, 1961Ra13, 1961Ra13, 1962Ma33, 1962Ma33, 1962Fr13, + 58FE4C 1963Mo12, 1964Ma09, 1964Ma09, 1965Hi12, 1965Hi12, 1966Ra22, 1966Ra22, + 58FE5C 1966Bi13, 1966Bi13, 1968Ri03, 1968Ba49, 1968De08, 1968Ri03, 1968Ba49, + 58FE6C 1968De08, 1969GuZV, 1969Fa05, 1969Si13, 1969Sc11, 1969Si13, 1969Fa05, + 58FE7C 1969Sc11, 1969GuZV, 1970Wi14, 1970Wi14, 1971GoYM, 1971Si15, 1971GoYM, + 58FE8C 1971Si15, 1972We17, 1972DyZV, 1972Fo05, 1972DyZV, 1972Cr02, 1972Cr02, + 58FE9C 1972We17, 1972Fo05, 1973ArZI, 1973Ba67, 1973Ba67, 1973ArZI, 1975La16, + 58FE10C 1975La16, 1976Va30, 1976Va30, 1974HeYW, 1974HeYW, 1979Gr01, 1980Ho17, + 58FE11C 1980Ho17, 1982Gr10, 1982HoZJ, 1982HoZJ, 1982Gr10, 1992Sy**, 1992So04, + 58FE12C 1992Sy**, 1992So04, 1996Sc06, 1996Sc06, 2000He14, 2000He14, 2002Ba85, + 58FE13C 2002Ba85, 2003Au03, 2003Au03, 2008Ki07, 2008Ki07, 2010Ne01, 2010Ne01, + 58FE14C 2012Wa38, 2012Fi12, 2012Wa38, 2012Fi12 + 58FE T Auger electrons and ^X ray energies and emission intensities: + 58FE T {U Energy (keV)} {U Intensity } {U Line } + 58FE T + 58FE T 6.39091 7.98 11 XKA2 + 58FE T 6.40391 15.63 19 XKA1 + 58FE T + 58FE T 7.0581 |] 3.23 5 XKB1 + 58FE T 7.1083 |] XKB5II + 58FE T + 58FE T + 58FE T 0.617-0.8454 0.609 18 XL (total) + 58FE T 0.617 0.0309 13 XLL + 58FE T 0.7075-0.7084 0.327 12 XLA + 58FE T 0.6306 0.0197 9 XLC + 58FE T 0.7148-0.8454 0.229 10 XLB + 58FE T 0.7284-0.7284 0.00172 19 XLG + 58FE T + 58FE T 5.37-5.65 |] KLL AUGER + 58FE T 6.16-6.4 |] 48.8 4 ^KLX AUGER + 58FE T 6.93-7.11 |] KXY AUGER + 58FE T 0.52-0.84 116.9 7 L AUGER + 58CO P 0.0 2+ 70.85 D 3 2307.9 11 + 58FE N 1.0 1.0 1 1.0 + 58FE L 0 0+ STABLE + 58FE L 810.7662 202+ 6.54 PS 19 + 58FE E 14.94 1683.83 166.6 + 58FE2 E EAV=201.3 5$CK=0.8885 16$CL=0.0955 13$CM=0.0153 5$CN=0.0007 2$CO= + 58FE G 810.7602 2099.44 2 E2 3.32E-45 + 58FE2 G KC=2.99E-4 5$LC=2.87E-5 4$MC= + 58FE L 1674.731 6 2+ 1.6 PS 4 + 58FE E 1.228 357.7 + 58FE2 E EAV= $CK=0.8873 16$CL=0.0965 13$CM=0.0155 5$CN=0.0007 2$CO= + 58FE G 863.958 6 0.700 22M1+E2 0.643 41 2.31E-44 + 58FE2 G KC=2.08E-4 4$LC=1.99E-5 4$MC= + 58FE G 1674.705 6 0.528 13E2 2.25E-44 + 58FE2 G KC=5.77E-5 8$LC=5.47E-6 8$MC= + diff --git a/HEN_HOUSE/spectra/lnhb/Co-60.txt b/HEN_HOUSE/spectra/lnhb/Co-60.txt new file mode 100644 index 000000000..151f68e4e --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Co-60.txt @@ -0,0 +1,50 @@ + 60NI 60CO B- DECAY (5.2711 Y) + 60NI H TYP=Update$AUT=M.-M.Bé$CUT=16-JAN-2006$ + 60NI2 H TYP=Full$AUT=R.G.Helmer$CUT=01-JAN-1998$ + 60NI C Evaluation history: Type=Update;Author=M.-M.Bé;Cutoff date=16-JAN-2006 + 60NI2C Type=Full;Author=R.G.Helmer;Cutoff date=01-JAN-1998 + 60NI C References: 2002Ba85 + 60NI T Auger electrons and ^X ray energies and emission intensities: + 60NI T {U Energy (keV)} {U Intensity } {U Line } + 60NI T + 60NI T 7.46097 0.00334 12 XKA2 + 60NI T 7.47824 0.0065 3 XKA1 + 60NI T + 60NI T 8.2647 |] XKB3 + 60NI T |] 0.00136 5 XKB1 + 60NI T 8.3287 |] XKB5II + 60NI T + 60NI T + 60NI T 0.74-0.94 0.0002 XL (total) + 60NI T 0.74 XLL + 60NI T -0.94 XLG + 60NI T + 60NI T 6.26-6.54 |] KLL AUGER + 60NI T 7.2-7.47 |] 0.0154 5 ^KLX AUGER + 60NI T 8.1-8.32 |] KXY AUGER + 60NI T 0.7-0.9 0.0392 12 L AUGER + 60CO P 0.0 5+ 5.2711 Y 8 2823.07 21 + 60NI N 1.0 1.0 1 1.0 + 60NI L 0 0+ STABLE + 60NI L 1332.508 4 2+ 0.713 PS 11 + 60NI B 1490.56 210.12 3 14.7 2U + 60NIS B EAV=625.6 1 + 60NI G 1332.492 4 99.9826 6 E2 1.28E-45 + 60NI2 G KC=1.15E-4 5$LC=1.13E-5 3$MC= + 60NI L 2158.61 3 2+ 0.59 PS 17 + 60NI B 664.46 210.002 2U + 60NIS B EAV=274.8 1 + 60NI G 826.10 3 0.0076 8 M1+E2 0.9 3 0.000344 + 60NI2 G KC=0.00030 4$LC=2.91E-5 17$MC= + 60NI G 2158.57 3 0.0012 2 E2 4.95E-515 + 60NI2 G KC=4.45E-5 14$LC=4.3E-6 2$MC= + 60NI L 2505.748 5 4+ 0.30 PS 9 + 60NI B 317.32 2199.88 3 7.51 + 60NIS B EAV=95.6 1 + 60NI G 347.14 7 0.0075 4 [E2] 0.0055717 + 60NI2 G KC=0.00499 15$LC=5.03E-4 15$MC= + 60NI G 1173.228 3 99.85 3 E2(+M3) 1.68E-44 + 60NI2 G KC=1.51E-4 7$LC=1.48E-5 4$MC= + 60NI G 2505.692 5 2.0E-6 4 E4 8.6E-5 3 + 60NI2 G KC=7.80E-5 3$LC=7.6E-6 3$MC= + diff --git a/HEN_HOUSE/spectra/lnhb/Cr-51.txt b/HEN_HOUSE/spectra/lnhb/Cr-51.txt new file mode 100644 index 000000000..2d6790ccf --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Cr-51.txt @@ -0,0 +1,47 @@ + 51V 51CR EC DECAY (27.704 D) + 51V H TYP=UPD$AUT=V.P.Chechev and N.K.Kuzmenko$CUT=31-MAR-2014$ + 51V 2 H TYP=ERR$AUT=M.-M.Be$CUT=28-FEB-2001$ + 51V 3 H TYP=FULL$AUT=R.G.Helmer and E.Schonfeld$CUT=28-FEB-2001$ + 51V C Evaluation history: Type=UPD;Author=V.P.Chechev and N.K.Kuzmenko;Cutoff date=31-MAR-2014 + 51V 2C Type=ERR;Author=M.-M.Be;Cutoff date=28-FEB-2001 + 51V 3C Type=FULL;Author=R.G.Helmer and E.Schonfeld;Cutoff date=28-FEB-2001 + 51V C References: 1940Wa02, 1948Mi12, 1948Ho04, 1952Ly17, 1955Co56, 1956Ka33, + 51V 2C 1956Sc87, 1957Ka65, 1957Wr37, 1960AD01, 1962RI09, 1963Ho17, 1963MeZZ, + 51V 3C 1964Ma56, 1965Dh01, 1965Le24, 1965Sa09, 1967LaZZ, 1968Bo25, 1969MeZV, + 51V 4C 1970MeZQ, 1970Wa**, 1971DaZM, 1972Em01, 1973De60, 1973ArZI, 1973La**, + 51V 5C 1973Vi13, 1974Ts01, 1975La16, 1980Sc07, 1980Ho17, 1982HoZJ, 1982DeYX, + 51V 6C 1982ChZF, 1983Wa26, 1984Fi10, 1991Ba11, 1992Un01, 1994Ko34, 1999Ka65, + 51V 7C 2002Un02, 2002Ba85, 2004BeZR, 2005Ya01, 2006Hu10, 2008Ki07, 2010Mo01, + 51V 8C 2012Wa38, 2012Fi12, 2014Un01 + 51V T Auger electrons and ^X ray energies and emission intensities: + 51V T {U Energy (keV)} {U Intensity } {U Line } + 51V T + 51V T 4.9447 6.79 14 XKA2 + 51V T 4.95224 13.36 27 XKA1 + 51V T + 51V T 5.42735 |] 2.69 7 XKB1 + 51V T 5.463 |] XKB5II + 51V T + 51V T + 51V T 0.4475-0.6268 0.56 12 XL (total) + 51V T 0.4475 XLL + 51V T 0.5135- XLA + 51V T 0.4557 XLC + 51V T 0.51938-0.6268 XLB + 51V T 0.52758-0.52758 XLG + 51V T + 51V T 4.164-4.395 |] KLL AUGER + 51V T 4.755-4.95 |] 66.4 5 ^KLX AUGER + 51V T 5.332-5.461 |] KXY AUGER + 51V T 0.3799-0.6257 146.0 6 L AUGER + 51CR P 0.0 7/2- 27.704 D 4 752.62 24 + 51V N 1.0 1.0 1 1.0 + 51V L 0 7/2- STABLE + 51V E 90.09 2 5.39 + 51V 2 E EAV= $CK=0.8919 17$CL=0.0927 14$CM=0.0154 6$CN= $CO= + 51V L 320.0835 4 5/2- 184 PS 6 + 51V E 9.91 2 5.86 2 + 51V 2 E EAV= $CK=0.8910 17$CL=0.0935 14$CM=0.0156 6$CN= $CO= + 51V G 320.0835 4 9.89 2 M1+E2 0.465 20 0.001815 + 51V 2 G KC=0.00164 5$LC=1.51E-4 4$MC=1.98E-5 6 + diff --git a/HEN_HOUSE/spectra/lnhb/Cs-134.txt b/HEN_HOUSE/spectra/lnhb/Cs-134.txt new file mode 100644 index 000000000..0c467facd --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Cs-134.txt @@ -0,0 +1,103 @@ +134XE 134CS EC DECAY (2.0644 Y) +134XE H TYP=Full$AUT=M.M. Bé$CUT=01-MAY-2012$ +134XE C Evaluation history: Type=Full;Author=M.M. Bé;Cutoff date=01-MAY-2012 +134XE C References: 1967Le18, 1968Ab01, 1972La14, 1973Di11, 1975Va12, 1987Wa28, +134XE2C 1988Ch44, 1997Ma75, 2002Un02, 2002Mi06, 2004So32, 2008Ki07, 2012Au06 +134XE T Auger electrons and ^X ray energies and emission intensities: +134XE T {U Energy (keV)} {U Intensity } {U Line } +134XE T +134XE T 29.459 XKA2 +134XE T 29.779 XKA1 +134XE T +134XE T 33.562 |] XKB3 +134XE T 33.625 |] XKB1 +134XE T 33.881 |] XKB5II +134XE T +134XE T 34.415 |] XKB2 +134XE T 34.496 |] XKB4 +134XE T 34.552 |] XKO23 +134XE T +134XE T +134XE T 23.512-24.842 |] KLL AUGER +134XE T 27.897-29.77 |] ^KLX AUGER +134XE T 32.27-34.54 |] KXY AUGER +134XE T 2.4848-5.3158 L AUGER +134CS P 0.0 4+ 2.0644 Y 14 1233.3 8 +134XE N 3.333E5 3.333E5 0.0000031 3.333E5 +134XE L 0 0+ STABLE +134XE L 847.041 232+ +134XE E 0.0003 1 13 2 +134XE2 E EAV= $CK=0.8361 16$CL=0.1289 11$CM=0.0283 6$CN=0.0066 4$CO= +134XE G 847.00 2 0.0003 1 E2 + +134BA 134CS B- DECAY (2.0644 Y) +134BA H TYP=Full$AUT=M.M. Bé$CUT=01-MAY-2012$ +134BA C Evaluation history: Type=Full;Author=M.M. Bé;Cutoff date=01-MAY-2012 +134BA C References: 1967Le18, 1968Ab01, 1972La14, 1973Di11, 1975Va12, 1987Wa28, +134BA2C 1988Ch44, 1997Ma75, 2002Un02, 2002Mi06, 2004So32, 2008Ki07, 2012Au06 +134BA T Auger electrons and ^X ray energies and emission intensities: +134BA T {U Energy (keV)} {U Intensity } {U Line } +134BA T +134BA T 31.8174 0.2378 26 XKA2 +134BA T 32.1939 0.438 5 XKA1 +134BA T +134BA T 36.3045 |] XKB3 +134BA T 36.3786 |] 0.1289 19 XKB1 +134BA T 36.654 |] XKB5II +134BA T +134BA T 37.258 |] XKB2 +134BA T 37.312 |] 0.0325 8 XKB4 +134BA T 37.425 |] XKO23 +134BA T +134BA T 3.9544-5.8104 0.1058 17 XL (total) +134BA T 3.9544 0.00204 5 XLL +134BA T 4.4515-4.4666 0.0528 12 XLA +134BA T 4.3307 0.000776 20 XLC +134BA T 4.8278-5.207 0.0435 8 XLB +134BA T 5.3715-5.8104 0.00675 14 XLG +134BA T +134BA T 25.314-26.786 |] KLL AUGER +134BA T 30.095-32.179 |] 0.093 4 ^KLX AUGER +134BA T 34.86-37.41 |] KXY AUGER +134BA T 2.66-5.81 0.850 5 L AUGER +134CS P 0.0 4+ 2.0644 Y 14 2058.98 33 +134BA N 1.00E0 1.00E0 0.9999971 1.00E0 +134BA L 0 0+ STABLE +134BA L 604.7223 192+ +134BA B 1454.26 330.06 6 13.1 2 +134BAS B EAV=535 1 +134BA G 604.720 3 97.63 8 E2 0.005939 +134BA2 G KC=0.00503 7$LC=7.21E-4 10$MC=1495E-7 21 +134BA L 1167.968 3 2+ +134BA B 891.01 33 13 2 +134BAS B EAV=300 1 +134BA G 563.246 3 8.342 15E2 0.0071410 +134BA2 G KC=0.00603 9$LC=8.81E-4 13$MC=1.83E-4 3 +134BA G 1167.967 4 1.791 5 E2 1307E-619 +134BA2 G KC=1122E-6 16$LC=1444E-7 21$MC=2.97E-5 5 +134BA L 1400.590 4 4+ +134BA B 658.39 3370.19 8 8.89 +134BAS B EAV=210.3 4 +134BA G 795.86 1 85.47 9 E2 0.003025 +134BA2 G KC=0.00258 4$LC=3.51E-4 5$MC=7.24E-5 11 +134BA L 1643.336 4 3+ +134BA B 415.64 332.498 8 9.65 +134BAS B EAV=123.6 4 +134BA G 242.76 5 0.0241 31(M1+E2) 0.087 3 +134BA2 G KC=0.0722 12$LC=0.0120 25$MC=0.0025 6 +134BA G 475.365 2 1.479 7 M1+()E2 6.0 35 0.0114 5 +134BA2 G KC=0.0096 4$LC=0.00146 3$MC=3.04E-4 6 +134BA G 1038.605 8 0.9909 33M1+()E2 0.71 14 0.002087 +134BA2 G KC=0.00179 6$LC=2.28E-4 7$MC=4.67E-5 13 +134BA L 1969.921 4 4+ +134BA B 89.06 3327.27 3 6.49 +134BAS B EAV=23.2 4 +134BA G 326.585 140.0171 11(M1+E2) 0.0367 22 +134BA2 G KC=0.031 3$LC=0.0047 3$MC=0.00097 8 +134BA G 569.330 2 15.368 21M1+()E2 0.28 2 0.0093614 +134BA2 G KC=0.00805 12$LC=1039E-6 15$MC=2.14E-4 3 +134BA G 801.950 6 8.694 16E2 0.002975 +134BA2 G KC=0.00254 4$LC=3.44E-4 5$MC=7.1E-5 1 +134BA G 1365.194 4 3.019 8 E2 9.87E-414 +134BA2 G KC=8.20E-4 12$LC=1039E-7 15$MC=2.13E-5 3 + diff --git a/HEN_HOUSE/spectra/lnhb/Cs-137.txt b/HEN_HOUSE/spectra/lnhb/Cs-137.txt new file mode 100644 index 000000000..8a2f80486 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Cs-137.txt @@ -0,0 +1,45 @@ +137BA 137CS B- DECAY (30.05 Y) +137BA H TYP=Update$AUT=M.M. Bé$CUT=11-DEC-2007$ +137BA2 H TYP=Update$AUT=V.Chechev$CUT=01-MAR-2006$ +137BA3 H TYP=Full$AUT=R.G.Helmer$CUT=01-JUN-1998$ +137BA C Evaluation history: Type=Update;Author=M.M. Bé;Cutoff date=11-DEC-2007 +137BA2C Type=Update;Author=V.Chechev;Cutoff date=01-MAR-2006 +137BA3C Type=Full;Author=R.G.Helmer;Cutoff date=01-JUN-1998 +137BA T Auger electrons and ^X ray energies and emission intensities: +137BA T {U Energy (keV)} {U Intensity } {U Line } +137BA T +137BA T 31.8174 1.95 4 XKA2 +137BA T 32.1939 3.59 7 XKA1 +137BA T +137BA T 36.3045 |] XKB3 +137BA T 36.3786 |] 1.055 22 XKB1 +137BA T 36.654 |] XKB5II +137BA T +137BA T 37.258 |] XKB2 +137BA T 37.312 |] 0.266 8 XKB4 +137BA T 37.425 |] XKO23 +137BA T +137BA T 3.954-5.809 0.90 5 XL (total) +137BA T 3.954 XLL +137BA T -5.809 XLG +137BA T +137BA T 25.314-26.786 |] KLL AUGER +137BA T 30.095-32.179 |] 0.76 4 ^KLX AUGER +137BA T 34.86-37.41 |] KXY AUGER +137BA T 2.6-5.8 7.28 12 L AUGER +137CS P 0.0 7/2+ 30.05 Y 8 1175.63 17 +137BA N 1.0 1.0 1 1.0 +137BA L 0 3/2+ STABLE +137BA B 1175.63 175.64 28 12.06 +137BAS B EAV=416.26 8 +137BA L 283.5 1 1/2+ +137BA B 892.1 2 0.00061 8 15.64 +137BAS B EAV=300.57 8 +137BA G 283.5 1 0.00058 8 [M1E2] 0.0557 13 +137BA2 G KC=0.046 3$LC=0.0073 10$MC=0.0015 2 +137BA L 661.659 3 11/2- 2.552 M 1 +137BA B 513.97 1794.36 28 9.63 3U +137BAS B EAV=174.32 6 +137BA G 661.657 3 84.99 20M4 0.1102 19 +137BA2 G KC=0.0896 15$LC=0.0165 5$MC=0.00352 7 + diff --git a/HEN_HOUSE/spectra/lnhb/Cu-61.txt b/HEN_HOUSE/spectra/lnhb/Cu-61.txt new file mode 100644 index 000000000..395807229 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Cu-61.txt @@ -0,0 +1,107 @@ + 61NI 61CU EC DECAY (3.366 H) + 61NI H TYP=Full$AUT=M.M. Bé$CUT=31-JUL-2013$ + 61NI C Evaluation history: Type=Full;Author=M.M. Bé;Cutoff date=31-JUL-2013 + 61NI C References: 1954Be84, 1956Nu02, 1967Sc02, 1967Bo01, 1967Be12, 1969Ri04, + 61NI2C 1971Go40, 1972Du09, 1972Cr02, 1973Ne02, 1977Wa03, 1978ME10, 1982Gr10, + 61NI3C 1982Ma41, 1988Sa26, 1996Sc06, 1998Sc28, 1999Bh04, 2000Sc47, 2008Ki07, + 61NI4C 2012Wa38 + 61NI T Auger electrons and ^X ray energies and emission intensities: + 61NI T {U Energy (keV)} {U Intensity } {U Line } + 61NI T + 61NI T 7.46097 4.33 20 XKA2 + 61NI T 7.47824 8.4 4 XKA1 + 61NI T + 61NI T 8.26475 |] 1.76 9 XKB1 + 61NI T 8.3287 |] XKB5II + 61NI T + 61NI T + 61NI T 0.7445-1.0083 0.437 14 XL (total) + 61NI T 0.7445 0.0165 8 XLL + 61NI T 0.8532-0.8539 0.244 10 XLA + 61NI T 0.7622 0.0101 5 XLC + 61NI T 0.86123-1.0083 0.165 8 XLB + 61NI T 0.87898-0.87898 0.0008 1 XLG + 61NI T + 61NI T 6.262-6.567 |] KLL AUGER + 61NI T 7.196-7.475 |] 20.0 9 ^KLX AUGER + 61NI T 8.109-8.326 |] KXY AUGER + 61NI T 0.632-1.01 51.2 9 L AUGER + 61CU P 0.0 3/2- 3.366 H 33 2237.5 10 + 61NI N 1.0 1.0 1 1.0 + 61NI L 0 3/2- STABLE + 61NI E 51.6 2516.3 8 5 + 61NI2 E EAV=523.8 5$CK=0.8867 16$CL=0.0967 13$CM=0.0157 5$CN=0.0009 1$CO= + 61NI L 67.412 3 5/2- 5.34 NS 16 + 61NI E 2.1 5 0.79 206.3 2 + 61NI2 E EAV=493.8 5$CK=0.8866 16$CL=0.0968 13$CM=0.0157 5$CN=0.0009 1$CO= + 61NI G 67.412 3 4.0 6 (M1) 0.1368 20 + 61NI2 G KC=0.1224 18$LC=0.01261 18$MC=1776E-6 25 + 61NI L 282.9568 191/2- 22 PS 4 + 61NI E 5.4 9 4.0 7 5.5 2 + 61NI2 E EAV=398.9 5$CK=0.8866 16$CL=0.0968 13$CM=0.0157 5$CN=0.0009 1$CO= + 61NI G 215.55 180.013 7 + 61NI G 282.956 2 12.0 17(M1) 0.003295 + 61NI2 G KC=0.00295 5$LC=2.93E-4 5$MC=4.13E-5 6 + 61NI L 656.012 3 1/2- 22 PS 4 + 61NI E 2.52 2710.7 124.9 2 + 61NI2 E EAV=238.5 4$CK=0.8864 16$CL=0.0970 13$CM=0.0157 5$CN=0.0009 1$CO= + 61NI G 373.050 5 2.09 30[M1] 0.001702 + 61NI2 G KC=0.00153 2$LC=1.51E-4 2$MC=2.13E-5 3 + 61NI G 588.605 9 1.15 16[E2] + 61NI G 656.008 4 10.4 15(M1+E2) + 61NI L 908.620 115/2- + 61NI E 0.0347 401.32 155.7 2 + 61NI2 E EAV=132.8 4$CK=0.8862 16$CL=0.0971 13$CM=0.0158 5$CN=0.0009 1$CO= + 61NI G 625.605 240.044 7 [E2] + 61NI G 841.211 170.224 34M1+()E2 -1.83 20 + 61NI G 908.631 171.12 16M1+()E2 -0.18 5 + 61NI L 1014.8 4 7/2- + 61NI E 3.2E-5 320.006 6 7.8 + 61NI2 E EAV=88.7 4$CK=0.8861 16$CL=0.0972 13$CM=0.0158 5$CN=0.0009 1$CO= + 61NI G 947.4 4 0.0060 19M1+()E2 -2.46 15 + 61NI G 1014.8 4 0.0103 39E2+()M3 0.03 300 0.0002 6 + 61NI2 G KC=0.0002 6$LC=0.00002 6$MC=3E-6 8 + 61NI L 1099.622 103/2- + 61NI E 0.64 6 5.9 + 61NI2 E EAV= $CK=0.8860 16$CL=0.0973 13$CM=0.0158 5$CN=0.0009 1$CO= + 61NI G 816.692 130.32 5 M1+()E2 -0.23 700 + 61NI G 1032.162 100.053 10 + 61NI G 1099.560 190.257 39 + 61NI L 1132.332 175/2- + 61NI E 0.154 176.5 2 + 61NI2 E EAV= $CK=0.8860 16$CL=0.0973 13$CM=0.0158 5$CN=0.0009 1$CO= + 61NI G 117.5 0.010 6 + 61NI G 1064.896 200.052 9 M1+()E2 -0.14 12 + 61NI G 1132.35 3 0.092 13M1+()E2 0.47 9 + 61NI L 1185.236 113/2- + 61NI E 4.1 5 5 + 61NI2 E EAV= $CK=0.8859 16$CL=0.0974 13$CM=0.0158 5$CN=0.0009 1$CO= + 61NI G 529.169 220.38 5 + 61NI G 902.294 200.084 12 + 61NI G 1117.822 430.039 9 + 61NI G 1185.234 153.6 5 (M1+E2) + 61NI L 1609.639 215/2- + 61NI E 0.063 7 6.5 2 + 61NI2 E EAV= $CK=0.8849 16$CL=0.0982 13$CM=0.0160 5$CN=0.0009 1$CO= + 61NI G 701.1 3 0.0108 28 + 61NI G 1542.204 230.029 5 M1+()E2 0.07 500 + 61NI G 1609.625 480.0236 43M1+()E2 0.33 14 + 61NI L 1729.471 103/2- + 61NI E 0.228 185.7 + 61NI2 E EAV= $CK=0.8843 16$CL=0.0987 13$CM=0.0160 5$CN=0.0009 1$CO= + 61NI G 544.8 0.006 4 + 61NI G 820.89 170.0216 39 + 61NI G 1073.465 250.042 11 + 61NI G 1446.492 190.046 7 + 61NI G 1662.000 190.051 8 + 61NI G 1729.473 180.065 14 + 61NI L 1997.7 9 5/2- + 61NI E 0.0043 146.7 2 + 61NI2 E EAV= $CK=0.8808 17$CL=0.1016 14$CM=0.0166 5$CN=0.0010 1$CO= + 61NI G 1089.11 0.00060 8 + 61NI G 1997.7 9 0.0037 13M1+()E2 0.27 6 + 61NI L 2124 1 1/2- + 61NI E 0.040 5 5 2 + 61NI2 E EAV= $CK=0.8729 22$CL=0.1083 18$CM=0.0178 6$CN=0.0010 2$CO= + 61NI G 2124 1 0.040 6 + diff --git a/HEN_HOUSE/spectra/lnhb/Cu-64.txt b/HEN_HOUSE/spectra/lnhb/Cu-64.txt new file mode 100644 index 000000000..8559a2cf6 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Cu-64.txt @@ -0,0 +1,57 @@ + 64NI 64CU EC DECAY (12.7004 H) + 64NI H TYP=update$AUT=M.-M.Bé$CUT=30-JUN-2011$ + 64NI2 H TYP=Full$AUT=M.-M.Bé$CUT= -- $ + 64NI3 H TYP=Full$AUT=R.G.Helmer$CUT=31-JAN-2002$ + 64NI C Evaluation history: Type=update;Author=M.-M.Bé;Cutoff date=30-JUN-2011 + 64NI2C Type=Full;Author=M.-M.Bé;Cutoff date= -- + 64NI3C Type=Full;Author=R.G.Helmer;Cutoff date=31-JAN-2002 + 64NI C References: 1976Ba63, 1989Ab22, 1996Sc06, 2002WE02, 2003Au03, 2007Qa02, + 64NI2C 2007Si04 + 64NI T Auger electrons and ^X ray energies and emission intensities: + 64NI T {U Energy (keV)} {U Intensity } {U Line } + 64NI T + 64NI T 7.46093 4.90 6 XKA2 + 64NI T 7.47819 9.56 11 XKA1 + 64NI T + 64NI T 8.2647 |] XKB3 + 64NI T |] 1.99 3 XKB1 + 64NI T 8.3287 |] XKB5II + 64NI T + 64NI T + 64NI T 0.7445-1.0083 0.493 10 XL (total) + 64NI T 0.7445 0.0186 6 XLL + 64NI T 0.8532-0.8539 0.276 7 XLA + 64NI T 0.7622 0.0114 4 XLC + 64NI T 0.86123-1.0083 0.187 6 XLB + 64NI T 0.87898-0.87898 0.0009 1 XLG + 64NI T + 64NI T 6.262-6.567 |] KLL AUGER + 64NI T 7.196-7.475 |] 22.62 21 ^KLX AUGER + 64NI T 8.109-8.326 |] KXY AUGER + 64NI T 0.6-0.9 57.9 4 L AUGER + 64CU P 0.0 1+ 12.7004 H 20 1675.03 20 + 64NI N 1.625E0 1.625E0 0.6152 261.625E0 + 64NI L 0 0+ STABLE + 64NI E 17.52 1543.53 204.97 + 64NI2 E EAV=278.21 9$CK=0.888 3$CL=0.095 2$CM=0.0155 5$CN= $CO= + 64NI L 1345.75 5 2+ 1.088 PS 35 + 64NI E 0.4744 335.51 + 64NI2 E EAV= $CK=0.884 3$CL=0.099 2$CM=0.0162 5$CN= $CO= + 64NI G 1345.77 6 0.4748 34E2 1.24E-42 + 64NI2 G KC=1112E-7 2$LC=1.09E-5 2$MC= + + 64ZN 64CU B- DECAY (12.7004 H) + 64ZN H TYP=update$AUT=M.-M.Bé$CUT=30-JUN-2011$ + 64ZN2 H TYP=Full$AUT=M.-M.Bé$CUT= -- $ + 64ZN3 H TYP=Full$AUT=R.G.Helmer$CUT=31-JAN-2002$ + 64ZN C Evaluation history: Type=update;Author=M.-M.Bé;Cutoff date=30-JUN-2011 + 64ZN2C Type=Full;Author=M.-M.Bé;Cutoff date= -- + 64ZN3C Type=Full;Author=R.G.Helmer;Cutoff date=31-JAN-2002 + 64ZN C References: 1976Ba63, 1989Ab22, 1996Sc06, 2002WE02, 2003Au03, 2007Qa02, + 64ZN2C 2007Si04 + 64CU P 0.0 1+ 12.7004 H 20 579.4 7 + 64ZN N 2.599E0 2.599E0 0.3848 262.599E0 + 64ZN L 0 0+ STABLE + 64ZN B 579.4 7 38.48 26 5.29 + 64ZNS B EAV=190.7 3 + diff --git a/HEN_HOUSE/spectra/lnhb/Er-169.txt b/HEN_HOUSE/spectra/lnhb/Er-169.txt new file mode 100644 index 000000000..d6326c209 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Er-169.txt @@ -0,0 +1,37 @@ +169TM 169ER B- DECAY (9.38 D) +169TM H TYP=FUL$AUT=M.M. Bé$CUT=31-DEC-2014$ +169TM C Evaluation history: Type=FUL;Author=M.M. Bé;Cutoff date=31-DEC-2014 +169TM C References: 1948Ke11, 1956Bi30, 1958Pa16, 1958Sh64, 1959Ch31, 1960Wi10, +169TM2C 1961Bj02, 1962Gr16, 1963Mc13, 1963Ra15, 1964Ka02, 1965Du02, 1967Ma42, +169TM3C 1968Ca06, 1968Wa05, 1970Sh09, 1971MaXG, 1977My02, 2001KoZQ, 2002Be05, +169TM4C 2002Ba85, 2004BeZQ, 2004Sc04, 2008Ki07, 2008Ba31, 2012Mo38, 2012Wa38, +169TM5C 2012Le09, 2014Mo20, 2015In02 +169TM T Auger electrons and ^X ray energies and emission intensities: +169TM T {U Energy (keV)} {U Intensity } {U Line } +169TM T +169TM T +169TM T +169TM T +169TM T +169TM T 0.04-0.53 |] KLL AUGER +169TM T 0.31-1.47 |] 74.6 ^KLX AUGER +169TM T 0.85-1.79 |] KXY AUGER +169TM T 0.05-0.186 116.1 L AUGER +169ER P 0.0 1/2- 9.38 D 2 353.0 12 +169TM N 1.0 1.0 1 0 1.0 +169TM L 0 1/2+ STABLE +169TM B 353.0 1256 5 6.3 +169TMS B EAV=99.1 5 +169TM L 8.4102 1 3/2+ 4.09 NS 5 +169TM B 344.6 1244 5 6.5 1U +169TMS B EAV=96.5 5 +169TM G 8.4102 1 0.174 21M1+(E2) 0.0306 16 251 10 +169TM2 G KC=$LC=$MC=199 8 +169TM L 118.1895 1 5/2+ +169TM B 234.8 120.016 9.5 3U +169TMS B EAV=73.0 5 +169TM G 109.77930 140.0045 9 M1+E2 0.15 1 2.37 4 +169TM2 G KC=1.96 3$LC=0.316 5$MC=0.0710 12 +169TM G 118.1895 1 5000E-7 0 E2 1.642 23 +169TM2 G KC=0.70 1$LC=0.721 10$MC=0.1759 25 + diff --git a/HEN_HOUSE/spectra/lnhb/Eu-152.txt b/HEN_HOUSE/spectra/lnhb/Eu-152.txt new file mode 100644 index 000000000..d08c31814 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Eu-152.txt @@ -0,0 +1,411 @@ +152SM 152EU EC DECAY (13.522 Y) +152SM C References: 1977La19 +152SM T Auger electrons and ^X ray energies and emission intensities: +152SM T {U Energy (keV)} {U Intensity } {U Line } +152SM T +152SM T 39.5229 20.8 3 XKA2 +152SM T 40.1186 37.7 5 XKA1 +152SM T +152SM T 45.289 |] XKB3 +152SM T 45.413 |] 11.78 19 XKB1 +152SM T 45.731 |] XKB5II +152SM T +152SM T 46.575 |] XKB2 +152SM T 46.705 |] 3.04 8 XKB4 +152SM T 46.813 |] XKO23 +152SM T +152SM T 5.61-7.18 13.0 4 XL (total) +152SM T 5.61-5.64 XLA +152SM T -7.18 XLG +152SM T +152SM T 31.19-33.218 |] KLL AUGER +152SM T 37.302-40.097 |] 5.9 4 ^KLX AUGER +152SM T 43.39-46.79 |] KXY AUGER +152SM T 3.2-7.7 67.7 7 L AUGER +152EU P 0.0 3- 13.522 Y 16 1874.3 7 +152SM N 1.387E0 1.387E0 0.721 1.387E0 +152SM G 237.31 5 0.0025 8 (E1) 0.0272 8 +152SM G 320.03 150.0017 6 +152SM G 379.37 6 0.00083 21 +152SM G 391.32 140.00125 21 +152SM G 406.74 150.00083 21 +152SM G 535.4 4 0.0060 16(M1+E2) 1 0.0147044 +152SM G 595.61 1 0.0031 17 +152SM G 683.32 110.0031 8 +152SM G 696.87 190.0029 10 +152SM G 735.4 1 0.0058 10 +152SM G 756.12 9 0.0054 8 +152SM G 896.58 9 0.0669 21 +152SM G 1001.1 3 0.0046 10 +152SM G 1084 1 0.244 8 +152SM G 1139 1 0.0013 3 +152SM G 1674.30 6 0.0060 8 +152SM L 0 0+ STABLE +152SM L 121.7818 3 2+ 1.400 NS 11 +152SM E 0.025 151.7 1011.8 1 +152SM2 E EAV=338.1 3$CK=0.8408 15$CL=0.1241 10$CM=0.0281 5$CN=0.0069 4$CO= +152SM G 121.7817 3 28.41 13E2 1.165 35 +152SM2 G KC=0.676 20$LC=0.378 11$MC=0.0875 26 +152SM L 366.4786 8 4+ 57.7 PS 8 +152SM E 0.0024 2 0.77 5 12 1 +152SM2 E EAV=230.7 3$CK=0.8398 15$CL=0.1249 11$CM=0.0283 5$CN=0.0070 4$CO= +152SM G 244.6974 8 7.55 4 E2 0.1080 32 +152SM2 G KC=0.0809 24$LC=0.0211 6$MC=0.00475 14 +152SM L 684.714 200+ +152SM G 562.93 2 0.038 13E2 0.0095028 +152SM2 G KC=0.00780 23$LC=1290E-6 39$MC=2.82E-4 8 +152SM L 706.91 5 6+ +152SM G 340.40 140.031 3 E2 0.0385 12 +152SM2 G KC=0.0304 9$LC=0.00632 19$MC=1410E-6 42 +152SM L 810.4474 202+ 7.4 PS 6 +152SM E 1.28 3 11.4 1 +152SM2 E EAV= $CK=0.8366 15$CL=0.1273 11$CM=0.0290 6$CN=0.0071 4$CO= +152SM G 125.69 130.019 6 (E2) 1.042 31 +152SM2 G KC=0.616 18$LC=0.329 10$MC=0.0760 23 +152SM G 443.965 3 0.32 2 (E2) 0.0178 5 +152SM2 G KC=0.01450 44$LC=0.00263 8$MC=5.79E-4 17 +152SM G 688.670 5 0.841 6 E2+M1+ 0.0434 13 +152SM2 G KC=0.0359 13$LC=$MC= +152SM G 810.451 5 0.317 3 (E2) 0.0040012 +152SM2 G KC=0.0033 1$LC=4.93E-4 15$MC=1070E-7 32 +152SM L 963.360 4 1- +152SM G 841.574 5 0.163 2 E1 1500E-645 +152SM2 G KC=1200E-6 36$LC=1610E-7 48$MC=3.43E-5 10 +152SM G 963.390 120.1341 20E1 1100E-633 +152SM2 G KC=0.00100 3$LC=1230E-7 37$MC=2.63E-5 8 +152SM L 1022.967 5 4- 4.9 PS +152SM E 0.238 5 11.9 +152SM2 E EAV= $CK=0.8338 15$CL=0.1294 11$CM=0.0295 6$CN=0.0073 4$CO= +152SM G 212.568 150.0196 6 E2 0.171 5 +152SM2 G KC=0.1244 37$LC=0.0364 11$MC=0.00825 25 +152SM G 316.2 2 0.0031 10(E2) 0.0481 14 +152SM2 G KC=0.0376 11$LC=0.00819 25$MC=0.00183 5 +152SM G 656.489 5 0.1437 18E2+M1+ 0.0568 20 +152SM2 G KC=0.0497 16$LC=$MC= +152SM G 901.181 110.084 3 E2 0.003109 +152SM2 G KC=0.00260 8$LC=3.82E-4 11$MC=8.24E-5 25 +152SM L 1041.1342 183- 27 FS 5 +152SM E 0.086 7 12.4 +152SM2 E EAV= $CK=0.8335 15$CL=0.1296 11$CM=0.0296 6$CN=0.0073 4$CO= +152SM G 674.675 3 0.170 4 E1 0.002307 +152SM2 G KC=0.00190 6$LC=2.54E-4 8$MC=5.42E-5 16 +152SM G 919.337 4 0.429 5 E1 1200E-636 +152SM2 G KC=0.00100 3$LC=1.35E-4 4$MC=2.88E-5 9 +152SM L 1085.8499 232+ 0.87 PS 4 +152SM E 21.35 119.9 1 +152SM2 E EAV= $CK=0.8327 15$CL=0.1302 11$CM=0.0297 6$CN=0.0073 4$CO= +152SM G 275.449 150.0323 17(M1) 0.1044 31 +152SM2 G KC=0.0887 27$LC=0.01230 37$MC=0.00265 8 +152SM G 719.349 4 0.268 13(E2) 0.0052016 +152SM2 G KC=0.00440 13$LC=6.66E-4 20$MC=1440E-7 43 +152SM G 964.079 1814.50 6 E2(+M1) 0.002708 +152SM2 G KC=0.00230 7$LC=3.27E-4 10$MC=7.03E-5 21 +152SM G 1085.837 1010.13 6 E2 0.002106 +152SM2 G KC=0.00180 5$LC=2.50E-4 8$MC=5.36E-5 16 +152SM L 1233.8656 173+ 3 PS 3 +152SM E 17.16 8 9.8 +152SM2 E EAV= $CK=0.8291 16$CL=0.1329 11$CM=0.0305 6$CN=0.0075 4$CO= +152SM G 148.010 170.035 5 (M1+E2) 1 0.578 17 +152SM2 G KC=0.430 13$LC=0.1150 34$MC=0.0260 8 +152SM G 423.45 4 0.0032 5 (M1+E2) 1 0.0271 8 +152SM2 G KC=0.0226 7$LC=0.0035 1$MC=7.61E-4 23 +152SM G 867.380 3 4.243 23E2+M1 -6.5 0.0035 1 +152SM2 G KC=0.00290 9$LC=4.23E-4 13$MC=9.13E-5 27 +152SM G 1112.076 3 13.41 6 E2(+M1) -8.7 0.002006 +152SM2 G KC=0.00170 5$LC=2.38E-4 7$MC=5.11E-5 15 +152SM L 1292.771 6 (2)+ 8 PS 8 +152SM E 0.644 1011.2 1 +152SM2 E EAV= $CK=0.8271 16$CL=0.1344 11$CM=0.0309 6$CN=0.0076 4$CO= +152SM G 251.633 100.0671 15(E1) 0.0233 7 +152SM2 G KC=0.0198 6$LC=0.00272 8$MC=5.83E-4 17 +152SM G 269.86 6 0.0060 24(E2) 0.0789 24 +152SM2 G KC=0.0602 18$LC=0.01460 44$MC=0.00327 10 +152SM G 329.425 210.129 6 (E1) 0.0117035 +152SM2 G KC=0.0100 3$LC=1360E-6 41$MC=2.90E-4 9 +152SM G 482.31 3 0.0279 16(M1+E2) 1 0.0192 6 +152SM2 G KC=0.01610 48$LC=0.00243 7$MC=5.26E-4 16 +152SM G 926.317 150.273 4 (E2) 0.002909 +152SM2 G KC=0.00250 8$LC=3.58E-4 11$MC=7.72E-5 23 +152SM G 1170.93 110.0365 13(M1+E2) 1 0.002307 +152SM2 G KC=0.00200 6$LC=2.65E-4 8$MC=5.67E-5 17 +152SM G 1292.778 190.104 3 (E2) 1500E-645 +152SM2 G KC=1300E-6 39$LC=1.72E-4 5$MC=3.68E-5 11 +152SM L 1371.691 9 4+ 1.4 PS 4 +152SM E 0.869 2410.9 1 +152SM2 E EAV= $CK=0.8236 16$CL=0.1370 11$CM=0.0316 6$CN=0.0078 4$CO= +152SM G 285.98 3 0.0100 6 (E2) 0.0657 20 +152SM2 G KC=0.0506 15$LC=0.01180 35$MC=0.00263 8 +152SM G 330.54 100.0060 17(E1) 0.0116035 +152SM2 G KC=0.0099 3$LC=0.00134 4$MC=2.88E-4 9 +152SM G 561.2 5 0.00108 21(E2) 0.0096029 +152SM2 G KC=0.00790 24$LC=1300E-6 39$MC=2.85E-4 9 +152SM G 664.78 5 0.010 3 (E2) 0.0063019 +152SM2 G KC=0.00520 16$LC=8.18E-4 25$MC=1.78E-4 5 +152SM G 1005.272 170.665 23 0.002608 +152SM2 G KC=0.00220 7$LC=3.11E-4 9$MC=6.69E-5 20 +152SM G 1249.938 130.186 3 E2 1600E-648 +152SM2 G KC=1400E-6 42$LC=1.84E-4 6$MC=3.95E-5 12 +152SM L 1529.8073 162- 27 FS +152SM E 24.72 119.1 +152SM2 E EAV= $CK=0.8109 17$CL=0.1465 12$CM=0.0341 7$CN=0.0085 4$CO= +152SM G 295.9387 170.442 3 E1 0.0153046 +152SM2 G KC=0.01310 39$LC=0.00178 5$MC=3.81E-4 11 +152SM G 443.965 3 2.80 2 E1(+M2) 0.0060018 +152SM2 G KC=0.00520 16$LC=6.35E-4 19$MC=1390E-7 42 +152SM G 488.6792 200.4139 24M1+E2 0.0140042 +152SM2 G KC=0.01150 34$LC=0.00196 6$MC=4.29E-4 13 +152SM G 566.442 5 0.131 4 M1+E2 -0.74 0.0138041 +152SM2 G KC=0.01170 35$LC=0.00166 5$MC=3.57E-4 11 +152SM G 719.349 4 0.059 7 (E1) 0.002006 +152SM2 G KC=0.00170 5$LC=2.22E-4 7$MC=4.73E-5 14 +152SM G 1408.013 3 20.85 8 E1(+M2) 6.00E-418 +152SM2 G KC=5.00E-4 15$LC=6.15E-5 18$MC=1310E-8 39 +152SM L 1579.365 3 3- +152SM E 2.068 1210 +152SM2 E EAV= $CK=0.8036 17$CL=0.1519 12$CM=0.0356 7$CN=0.0088 5$CO= +152SM G 207.6 3 0.0059 4 (E1) 0.0385 12 +152SM2 G KC=0.0327 10$LC=0.00455 14$MC=9.75E-4 29 +152SM G 493.508 200.0278 30(E1) 0.0045014 +152SM2 G KC=0.00380 11$LC=5.09E-4 15$MC=1090E-7 33 +152SM G 538.29 6 0.0042 6 (M1+E2) 1 0.0145044 +152SM2 G KC=0.01220 37$LC=0.00180 5$MC=3.89E-4 12 +152SM G 556.56 3 0.0177 11(E1) 0.0034 1 +152SM2 G KC=0.00290 9$LC=3.87E-4 12$MC=8.26E-5 25 +152SM G 616.05 3 0.0092 6 (E2) 0.0076023 +152SM2 G KC=0.00630 19$LC=0.00100 3$MC=2.19E-4 7 +152SM G 768.944 9 0.088 3 (E1) 0.001705 +152SM2 G KC=1500E-6 45$LC=1.93E-4 6$MC=4.12E-5 12 +152SM G 1212.948 111.416 9 E1 7.00E-421 +152SM2 G KC=6.00E-4 18$LC=8.02E-5 24$MC=1.70E-5 5 +152SM G 1457.643 110.498 4 E1 5.00E-415 +152SM2 G KC=5.00E-4 15$LC=5.80E-5 17$MC=1230E-8 37 +152SM L 1612.94 6 + +152SM E 0.0208 1411.9 +152SM2 E EAV= $CK=0.7966 18$CL=0.1571 13$CM=0.0370 7$CN=0.0092 5$CO= +152SM G 571.83 8 0.0048 8 +152SM G 906.01 6 0.016 1 +152SM L 1649.910 8 2- +152SM E 0.889 1410.1 +152SM2 E EAV= $CK=0.7859 19$CL=0.1651 13$CM=0.0392 7$CN=0.0098 5$CO= +152SM G 357.26 5 0.0040 5 (E1) 0.0096029 +152SM2 G KC=0.00820 25$LC=1110E-6 33$MC=2.37E-4 7 +152SM G 416.048 8 0.1090 17(E1) 0.0067 2 +152SM2 G KC=0.00570 17$LC=7.62E-4 23$MC=1630E-7 49 +152SM G 563.990 7 0.457 13E1 0.0033 1 +152SM2 G KC=0.00280 8$LC=3.76E-4 11$MC=8.02E-5 24 +152SM G 686.61 5 0.0200 17(M1+E2) 1 0.0079024 +152SM2 G KC=0.0067 2$LC=9.54E-4 29$MC=2.05E-4 6 +152SM G 839.36 4 0.0160 8 (E1) 1500E-645 +152SM2 G KC=1200E-6 36$LC=1620E-7 49$MC=3.45E-5 10 +152SM G 1528.103 180.281 5 E1 5.00E-415 +152SM2 G KC=4.00E-4 12$LC=$MC= +152SM L 1730.241 22(3)- +152SM E 0.0422 1210.9 +152SM2 E EAV= $CK=0.7339 23$CL=0.2036 16$CM=0.0499 9$CN=0.0125 7$CO= +152SM G 496.39 3 0.0049 5 (E1) 0.0044013 +152SM2 G KC=0.00380 11$LC=5.02E-4 15$MC=1070E-7 32 +152SM G 644.37 5 0.0063 6 (E1) 0.002508 +152SM2 G KC=0.00210 6$LC=2.80E-4 8$MC=5.98E-5 18 +152SM G 1363.77 5 0.0256 8 M1(+E2) 0.002006 +152SM2 G KC=0.00170 5$LC=2.22E-4 7$MC=4.74E-5 14 +152SM G 1608.36 8 0.0053 3 (E1) 4.00E-412 +152SM2 G KC=4.00E-4 12$LC=$MC= +152SM L 1757.151 132,3+ +152SM E 0.041 3 10.7 1 +152SM2 E EAV= $CK=0.6903 28$CL=0.2358 20$CM=0.0591 11$CN=0.0149 8$CO= +152SM G 385.69 200.0050 6 (M1+E2) 1 0.0348 10 +152SM2 G KC=0.0290 9$LC=0.00459 14$MC=9.99E-4 30 +152SM G 523.13 5 0.0113 21(M1+E2) 0.0156047 +152SM2 G KC=0.01310 39$LC=0.00194 6$MC=4.21E-4 13 +152SM G 671.155 170.0194 13M1+E2 0.14 0.0105032 +152SM2 G KC=0.00900 27$LC=1220E-6 37$MC=2.60E-4 8 +152SM G 1390.36 160.0048 6 (M1+E2) 1 1600E-648 +152SM2 G KC=1400E-6 42$LC=1.80E-4 5$MC=3.85E-5 12 +152SM G 1635.2 5 0.00015 5 (M1+E2) 1 0.001003 +152SM2 G KC=0.00100 3$LC=$MC= +152SM L 1769.10 3 2+ +152SM E 0.068 5 10.3 1 +152SM2 E EAV= $CK=0.6586 33$CL=0.2591 24$CM=0.0657 12$CN=0.0166 9$CO= +152SM G 239.42 170.008 3 (E1) 0.0265 8 +152SM2 G KC=0.0225 7$LC=0.00311 9$MC=6.65E-4 20 +152SM G 727.99 140.0106 13(E1) 0.001936 +152SM2 G KC=0.00166 5$LC=2.16E-4 6$MC=4.61E-5 14 +152SM G 805.70 7 0.0125 8 (E1) 1600E-648 +152SM2 G KC=1400E-6 42$LC=1.76E-4 5$MC=3.74E-5 11 +152SM G 958.63 5 0.0210 19(M1+E2) 0.0036011 +152SM2 G KC=0.00310 9$LC=$MC= +152SM G 1647.41 140.0064 4 (E2) 8.00E-424 +152SM2 G KC=8.00E-4 24$LC=$MC= +152SM G 1769.09 5 0.0092 3 (E2) 7.00E-421 +152SM2 G KC=7.00E-4 21$LC=$MC= + +152GD 152EU B- DECAY (13.522 Y) +152GD C References: 1977La19 +152GD T Auger electrons and ^X ray energies and emission intensities: +152GD T {U Energy (keV)} {U Intensity } {U Line } +152GD T +152GD T 42.3093 0.243 7 XKA2 +152GD T 42.9967 0.437 12 XKA1 +152GD T +152GD T 48.556 |] XKB3 +152GD T 48.697 |] 0.138 4 XKB1 +152GD T 49.053 |] XKB5II +152GD T +152GD T 49.961 |] XKB2 +152GD T 50.099 |] 0.0363 13 XKB4 +152GD T 50.219 |] XKO23 +152GD T +152GD T 5.3611-8.104 0.177 5 XL (total) +152GD T 5.3611 XLL +152GD T 6.024-6.0578 XLA +152GD T 6.0483 XLC +152GD T 6.6848-7.1888 XLB +152GD T 7.5509-8.104 XLG +152GD T +152GD T 33.31-35.562 |] KLL AUGER +152GD T 39.907-42.976 |] 0.062 4 ^KLX AUGER +152GD T 46.48-50.2 |] KXY AUGER +152GD T 3.4-8.3 0.800 14 L AUGER +152EU P 0.0 3- 13.522 Y 16 1818.8 11 +152GD N 3.584E0 3.584E0 0.279 3.584E0 +152GD G 237.31 5 0.0025 8 (E1) 0.0272 8 +152GD G 320.03 150.0017 6 +152GD G 379.37 6 0.00083 21 +152GD G 391.32 140.00125 21 +152GD G 406.74 150.00083 21 +152GD G 535.4 4 0.0060 16(M1+E2) 1 0.0147044 +152GD G 595.61 1 0.0031 17 +152GD G 683.32 110.0031 8 +152GD G 696.87 190.0029 10 +152GD G 735.4 1 0.0058 10 +152GD G 756.12 9 0.0054 8 +152GD G 896.58 9 0.0669 21 +152GD G 1001.1 3 0.0046 10 +152GD G 1084 1 0.244 8 +152GD G 1139 1 0.0013 3 +152GD G 1674.30 6 0.0060 8 +152GD L 0 0+ STABLE +152GD L 344.2798 122+ 32.4 PS 17 +152GD B 1474.5 118.17 11 12.1 1 +152GDS B EAV=535.4 5 +152GD G 344.2785 1226.59 12E2 0.0399 12 +152GD2 G KC=0.0311 9$LC=0.00687 21$MC=1550E-6 46 +152GD L 615.553 5 0+ +152GD G 271.131 8 0.078 3 E2 0.0831 25 +152GD2 G KC=0.0621 19$LC=0.01620 49$MC=0.00370 11 +152GD L 755.3964 174+ 7.3 PS 4 +152GD B 1063.4 110.904 14 12.5 1 +152GDS B EAV=364.6 5 +152GD G 411.1165 122.238 10E2 0.0239 7 +152GD2 G KC=0.0190 6$LC=0.00379 11$MC=8.49E-4 25 +152GD L 930.562 3 2+ 7.3 PS 6 +152GD B 888.2 110.303 7 12.7 1 +152GDS B EAV=295.1 5 +152GD G 315.174 170.0496 17(E2) 0.0521 16 +152GD2 G KC=0.0400 12$LC=0.00938 28$MC=0.00212 6 +152GD G 586.265 3 0.462 4 E2+M1+ -4.9 0.0243 9 +152GD2 G KC=0.0202 16$LC=$MC= +152GD G 930.58 150.0729 19(E2) 0.0032 1 +152GD2 G KC=0.00270 8$LC=4.00E-4 12$MC=8.72E-5 26 +152GD L 1047.51 6 0+ +152GD G 703.25 6 0.0018 9 (E2) 0.0060018 +152GD2 G KC=0.00500 15$LC=7.96E-4 24$MC=1.75E-4 5 +152GD L 1109.076 5 2+ +152GD B 709.7 110.245 8 12.4 1 +152GDS B EAV=226.9 5 +152GD G 493.508 200.009 2 (E2) 0.0145044 +152GD2 G KC=0.01180 35$LC=0.00214 6$MC=4.76E-4 14 +152GD G 764.900 9 0.190 4 E2+M1 3.8 0.0052016 +152GD2 G KC=0.00440 13$LC=6.69E-4 20$MC=1460E-7 44 +152GD G 1109.174 120.186 4 E2 0.002207 +152GD2 G KC=0.00190 6$LC=2.69E-4 8$MC=5.84E-5 18 +152GD L 1123.184 2 3- +152GD B 695.6 1113.80 15 10.6 +152GDS B EAV=221.7 4 +152GD G 192.6 4 0.0068 2 (E1) 0.0504 15 +152GD2 G KC=0.0426 13$LC=0.00609 18$MC=0.00132 4 +152GD G 367.7891 200.862 5 E1 0.0097029 +152GD2 G KC=0.00830 25$LC=1130E-6 34$MC=2.45E-4 7 +152GD G 778.9045 2412.97 6 E1 0.001906 +152GD2 G KC=1600E-6 48$LC=2.09E-4 6$MC=4.50E-5 14 +152GD L 1282.267 184+ +152GD B 536.5 110.037 8 12.8 1 +152GDS B EAV=164.1 4 +152GD G 351.66 4 0.0140 22E2 0.0375 11 +152GD2 G KC=0.0293 9$LC=0.00639 19$MC=1440E-6 43 +152GD G 526.881 200.0129 6 M1+E2+ 0.094 8 +152GD2 G KC=0.084 9$LC=$MC= +152GD L 1314.71 201- +152GD B 504.1 110.0048 7 13.6 2 +152GDS B EAV=152.7 4 +152GD G 1314.7 2 0.0048 6 E1 7.00E-421 +152GD2 G KC=6.00E-4 18$LC=7.73E-5 23$MC=1.66E-5 5 +152GD L 1318.50 3 2+ +152GD B 500.3 110.0267 17 12.9 1 +152GDS B EAV=151.4 4 +152GD G 387.90 8 0.00296 21(M1+E2+) 0.45 11 +152GD2 G KC=0.38 9$LC=$MC= +152GD G 703.25 6 0.0035 9 (E2) 0.0060018 +152GD2 G KC=0.00500 15$LC=7.96E-4 24$MC=1.75E-4 5 +152GD G 974.09 4 0.0138 8 M1+E2+ 1 0.0056 6 +152GD2 G KC=0.0048 5$LC=$MC= +152GD L 1434.025 4 3+ +152GD B 384.8 112.44 3 10.5 +152GDS B EAV=112.3 4 +152GD G 324.83 3 0.0738 15M1+E2 1 0.0636 19 +152GD2 G KC=0.0521 16$LC=0.00897 27$MC=0.00199 6 +152GD G 503.474 5 0.1533 18(E2) 0.0138041 +152GD2 G KC=0.01120 34$LC=0.00202 6$MC=4.48E-4 13 +152GD G 678.623 5 0.470 4 E2+M1 4.1 0.0069021 +152GD2 G KC=0.00570 17$LC=9.00E-4 27$MC=1.98E-4 6 +152GD G 1089.737 5 1.73 1 (M1)+E2 0.002307 +152GD2 G KC=0.00200 6$LC=$MC= +152GD L 1550.19 3 4+ +152GD B 268.6 110.0536 18 11.7 1 +152GDS B EAV=75.2 4 +152GD G 440.86 100.0133 10(E2) 0.0197 6 +152GD2 G KC=0.01580 47$LC=0.00303 9$MC=6.77E-4 20 +152GD G 794.81 3 0.0263 10M1(+E2) -0.4 0.0077023 +152GD2 G KC=0.0065 2$LC=9.05E-4 27$MC=1.96E-4 6 +152GD G 1206.11 150.0135 8 (E2) 0.001906 +152GD2 G KC=1600E-6 48$LC=2.25E-4 7$MC=4.87E-5 15 +152GD L 1605.255 4 2+ +152GD B 213.5 110.101 3 11.1 1 +152GDS B EAV=58.6 4 +152GD G 482.31 3 0.00139 6 (E1) 0.0051015 +152GD2 G KC=0.00440 13$LC=5.94E-4 18$MC=1280E-7 38 +152GD G 496.39 3 0.0042 4 M1+E2+ 0.097 11 +152GD2 G KC=0.082 9$LC=$MC= +152GD G 557.91 170.0044 7 (E2) 0.0106032 +152GD2 G KC=0.00870 26$LC=1490E-6 45$MC=3.31E-4 10 +152GD G 674.677 3 0.0171 18E2+M1 0.0076023 +152GD2 G KC=0.00630 19$LC=9.80E-4 29$MC=2.15E-4 6 +152GD G 990.19 3 0.0315 13(E2) 0.003009 +152GD2 G KC=0.00240 7$LC=3.47E-4 10$MC=7.55E-5 23 +152GD G 1261.343 230.0336 11M1 0.002708 +152GD2 G KC=0.00230 7$LC=3.13E-4 9$MC=6.76E-5 20 +152GD G 1605.61 7 0.0081 4 (E2) 9.00E-427 +152GD2 G KC=9.00E-4 27$LC=$MC= +152GD L 1643.395 4 2- +152GD B 175.4 111.826 21 9.6 +152GDS B EAV=47.4 4 +152GD G 209.41 130.0055 5 (E1) 0.0404 12 +152GD2 G KC=0.0342 10$LC=0.00486 15$MC=1050E-6 32 +152GD G 520.227 5 0.0536 13(M1+E2) 1 0.0181 5 +152GD2 G KC=0.01520 46$LC=0.00230 7$MC=5.04E-4 15 +152GD G 534.245 7 0.0368 19(E1) 0.0041012 +152GD2 G KC=0.0035 1$LC=4.70E-4 14$MC=1.01E-4 3 +152GD G 712.843 6 0.0961 19(E1) 0.002207 +152GD2 G KC=0.00190 6$LC=2.51E-4 8$MC=5.41E-5 16 +152GD G 1299.142 8 1.633 9 E1(+M2) 0.043 7.00E-421 +152GD2 G KC=6.00E-4 18$LC=8.03E-5 24$MC=1.72E-5 5 +152GD G 1643.6 1 0.0015 4 (M2) 0.0032 1 +152GD2 G KC=0.00280 8$LC=$MC= +152GD L 1692.447 153+ +152GD B 126.4 110.0203 11 11.1 +152GDS B EAV=33.4 3 +152GD G 937.050 150.0027 6 (M1+E2) 1 0.0043013 +152GD2 G KC=0.00370 11$LC=5.16E-4 15$MC=1120E-7 34 +152GD G 1348.10 7 0.0175 8 E2+(M1) -13 1600E-648 +152GD2 G KC=1300E-6 39$LC=1.79E-4 5$MC=3.87E-5 12 + diff --git a/HEN_HOUSE/spectra/lnhb/Eu-154.txt b/HEN_HOUSE/spectra/lnhb/Eu-154.txt new file mode 100644 index 000000000..ccaf70da0 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Eu-154.txt @@ -0,0 +1,443 @@ +154SM 154EU EC DECAY (8.601 Y) +154SM C References: 1952Ka26, 1977La19 +154SM T Auger electrons and ^X ray energies and emission intensities: +154SM T {U Energy (keV)} {U Intensity } {U Line } +154SM T +154SM T 39.5229 0.006 4 XKA2 +154SM T 40.1186 0.010 8 XKA1 +154SM T +154SM T 45.289 |] XKB3 +154SM T 45.413 |] 0.003 2 XKB1 +154SM T 45.731 |] XKB5II +154SM T +154SM T 46.575 |] XKB2 +154SM T 46.705 |] 0.001 XKB4 +154SM T 46.813 |] XKO23 +154SM T +154SM T 4.99-7.49 0.0044 20 XL (total) +154SM T 4.99 XLL +154SM T -7.49 XLG +154SM T +154SM T 31.19-33.22 |] KLL AUGER +154SM T 37.3-40.18 |] 0.0016 13 ^KLX AUGER +154SM T 45.3-46.23 |] KXY AUGER +154SM T 3.2-7.6 0.023 13 L AUGER +154EU P 0.0 3- 8.601 Y 4 717.3 11 +154SM N 5.556E3 5.556E3 0.00018 5.556E3 +154SM G 159.9 0.0010 5 +154SM G 195.5 5 0.002 1 +154SM G 197 0.0016 2 +154SM G 274.0 5 0.0039 2 +154SM G 296 1 0.0014 9 0.0166 3 +154SM G 308.2 0.0024 6 +154SM G 320 1 0.0010 7 +154SM G 414.3 0.0049 6 +154SM G 422.1 0.0022 9 +154SM G 435.9 0.0038 10 +154SM G 484.64 0.0039 2 +154SM G 510 0.059 7 +154SM G 512 0.032 7 +154SM G 737.6 0.0063 24 +154SM G 830.3 0.008 3 +154SM G 919.24 0.012 1 +154SM G 928.4 0.0045 21 +154SM G 984.5 0.0094 21 +154SM G 1033.4 0.0119 7 +154SM G 1049.4 1 0.0172 8 +154SM G 1072.2 0.0035 14 +154SM G 1124.2 0.0069 10 +154SM G 1153.1 5 0.011 4 +154SM G 1216.8 0.0033 10 +154SM G 1232.1 5 0.008 5 +154SM G 1316.4 3 0.017 4 +154SM G 1554 0.0011 5 +154SM L 0 0+ STABLE +154SM L 81.98 2+ 3 NS +154SM E 0.013 1312.7 1 +154SM2 E EAV= $CK=0.8289 16$CL=0.1330 11$CM=0.0305 6$CN= $CO= +154SM G 81.99 2 0.0031 21E2 4.93 10 +154SM2 G KC=1.98 4$LC=2.28 5$MC=0.532 11 +154SM L 266.79 4+ 172 PS +154SM E 0.0047 8 12.9 1 +154SM2 E EAV= $CK=0.8205 16$CL=0.1393 11$CM=0.0322 6$CN= $CO= +154SM G 184.72 0.0037 7 E2 0.275 6 +154SM2 G KC=0.193 4$LC=0.0642 13$MC=0.0146 3 +154SM L 543.73 6+ 23 PS + +154GD 154EU B- DECAY (8.601 Y) +154GD C References: 1952Ka26, 1977La19 +154GD T Auger electrons and ^X ray energies and emission intensities: +154GD T {U Energy (keV)} {U Intensity } {U Line } +154GD T +154GD T 42.3093 7.2 2 XKA2 +154GD T 42.9967 13.0 3 XKA1 +154GD T +154GD T 48.556 |] XKB3 +154GD T 48.697 |] 4.1 1 XKB1 +154GD T 49.053 |] XKB5II +154GD T +154GD T 49.961 |] XKB2 +154GD T 50.099 |] 1.08 3 XKB4 +154GD T 50.219 |] XKO23 +154GD T +154GD T 5.3611-8.104 7.1 3 XL (total) +154GD T 5.3611 XLL +154GD T 6.024-6.0578 XLA +154GD T 6.0483 XLC +154GD T 6.6848-7.1888 XLB +154GD T 7.5509-8.104 XLG +154GD T +154GD T 33.32-35.58 |] KLL AUGER +154GD T 39.98-42.86 |] 1.86 12 ^KLX AUGER +154GD T 47.98-48.91 |] KXY AUGER +154GD T 3.4-8.3 33.2 6 L AUGER +154EU P 0.0 3- 8.601 Y 4 1968.4 11 +154GD N 1.00E0 1.00E0 0.99982 1.00E0 +154GD G 159.9 0.0010 5 +154GD G 195.5 5 0.002 1 +154GD G 197 0.0016 2 +154GD G 274.0 5 0.0039 2 +154GD G 296 1 0.0014 9 0.0166 3 +154GD G 308.2 0.0024 6 +154GD G 320 1 0.0010 7 +154GD G 414.3 0.0049 6 +154GD G 422.1 0.0022 9 +154GD G 435.9 0.0038 10 +154GD G 484.64 0.0039 2 +154GD G 510 0.059 7 +154GD G 512 0.032 7 +154GD G 737.6 0.0063 24 +154GD G 830.3 0.008 3 +154GD G 919.24 0.012 1 +154GD G 928.4 0.0045 21 +154GD G 984.5 0.0094 21 +154GD G 1033.4 0.0119 7 +154GD G 1049.4 1 0.0172 8 +154GD G 1072.2 0.0035 14 +154GD G 1124.2 0.0069 10 +154GD G 1153.1 5 0.011 4 +154GD G 1216.8 0.0033 10 +154GD G 1232.1 5 0.008 5 +154GD G 1316.4 3 0.017 4 +154GD G 1554 0.0011 5 +154GD L 0 0+ STABLE +154GD L 123.071 2+ 1.18 NS +154GD B 1845.3 1110.3 5 12.4 1 +154GDS B EAV=695.6 5 +154GD G 123.0706 9 40.4 5 E2 1.197 19 +154GD2 G KC=0.653 13$LC=0.418 9$MC=0.096 2 +154GD L 371 4+ 40 PS +154GD B 1597.4 110.31 7 13.43 1 +154GDS B EAV=588.0 5 +154GD G 247.9288 7 6.89 7 E2 0.110 2 +154GD2 G KC=0.0810 16$LC=0.0228 5$MC= +154GD L 680.66 0+ +154GD G 557.58 5 0.267 5 E2 0.0106 2 +154GD2 G KC=0.0087 2$LC=0.0015 3$MC= +154GD G 680.72 10 +154GD L 717.7 6+ +154GD G 346.72 5 0.029 1 E2 0.0391 8 +154GD2 G KC=$LC=$MC= +154GD L 815.5 2+ +154GD B 1152.9 110.33 3 12.8 1 +154GDS B EAV=401.0 5 +154GD G 134.84 0.0072 4 E2 0.868 18 +154GD2 G KC=$LC=$MC= +154GD G 444.4924 190.560 8 E2 0.0192 4 +154GD2 G KC=0.0154 3$LC=$MC=6.50E-4 13 +154GD G 692.4205 181.79 3 +M1+E2 0.049 6 +154GD2 G KC=0.040 4$LC=0.0070 7$MC= +154GD G 815.53 5 0.512 7 E2 0.004309 +154GD2 G KC=0.00360 7$LC=5.48E-4 11$MC= +154GD L 996.26 2+ +154GD B 972.1 112.82 18 11.66 1 +154GDS B EAV=328.1 4 +154GD G 180.7 0.0040 5 (M1E2) 0.35 4 +154GD2 G KC=$LC=$MC= +154GD G 315.4 0.007 2 (E2) 0.052 1 +154GD2 G KC=$LC=$MC= +154GD G 625.2556 240.317 5 E2 0.0079716 +154GD2 G KC=0.00658 13$LC=0.00109 2$MC= +154GD G 873.1834 2312.17 12E2+M1+ 0.003738 +154GD2 G KC=0.00313 6$LC=0.00047 1$MC= +154GD G 996.25 5 10.5 1 E2 0.002796 +154GD2 G KC=0.00236 5$LC=3.42E-4 7$MC= +154GD L 1047.6 4+ +154GD B 920.8 110.108 18 13 1 +154GDS B EAV=307.8 4 +154GD G 232.01 5 0.024 1 E2 0.137 3 +154GD2 G KC=$LC=$MC= +154GD G 329.9 7 0.0091 5 E2 0.0454 9 +154GD2 G KC=$LC=$MC= +154GD G 676.596 120.157 11+M1+E2 0.059 6 +154GD2 G KC=0.049 5$LC=0.0080 8$MC= +154GD G 924.63 5 0.062 2 E2 0.003277 +154GD2 G KC=$LC=$MC= +154GD L 1127.8 3+ +154GD B 840.6 1117.33 18 10.64 +154GDS B EAV=276.6 4 +154GD G 80.4 0.0028 14(M1E2) 4.8 10 +154GD2 G KC=$LC=$MC= +154GD G 131.58 5 0.0111 5 M1+E2 0.95 4 +154GD2 G KC=$LC=$MC= +154GD G 312.3 0.018 2 (M1E2) 0.07 2 +154GD2 G KC=$LC=$MC= +154GD G 756.8020 234.53 5 E1+M2 0.0051 12 +154GD2 G KC=0.00431 9$LC=0.00067 2$MC= +154GD G 1004.718 7 17.86 18E1+M2 0.002766 +154GD2 G KC=0.00232 5$LC=3.36E-4 7$MC= +154GD L 1136 1,2+ +154GD G 1012.8 2 0.003 1 +154GD G 1136.1 0.007 1 +154GD L 1233.2 + +154GD G 1110 0.003 2 +154GD L 1241.3 1- +154GD G 1118.52 6 0.108 14E1 0.000932 +154GD2 G KC=7.98E-4 16$LC=1.03E-4 20$MC= +154GD G 1241.43 100.133 6 E1+(M2) 7.71E-415 +154GD2 G KC=6.62E-4 13$LC=8.49E-5 17$MC= +154GD L 1251.6 3- +154GD B 716.8 110.289 6 12.18 +154GDS B EAV=229.5 4 +154GD G 880.60 3 0.081 4 E1+M2 0.001538 +154GD2 G KC=$LC=$MC= +154GD G 1128.552 7 0.317 5 E1 9.15E-418 +154GD2 G KC=7.85E-4 16$LC=1.01E-4 2$MC= +154GD L 1263.78 4+ +154GD B 704.6 110.707 7 11.76 1 +154GDS B EAV=225.0 4 +154GD G 545.6 0.014 2 (E2) 0.0112 2 +154GD2 G KC=$LC=$MC= +154GD G 892.775 6 0.514 7 +E2+M1 0.003698 +154GD2 G KC=$LC=$MC= +154GD G 1140.702 6 0.235 4 E2 0.002114 +154GD2 G KC=$LC=$MC= +154GD L 1277 + +154GD G 229.01 130.0024 8 +154GD G 906.1 0.0118 6 +154GD L 1294.2 (2)+ +154GD G 165.90 210.0025 5 +154GD G 1170.7 5 0.0036 10 +154GD L 1397.5 2- +154GD B 570.9 1136.06 35 9.74 +154GDS B EAV=176.2 4 +154GD G 146.05 5 0.026 1 (M1E2) 0.68 2 +154GD2 G KC=$LC=$MC= +154GD G 156.2 0.0098 4 (M1E2) 0.55 3 +154GD2 G KC=$LC=$MC= +154GD G 260.9 0.0022 7 +154GD G 269.8 0.0070 11E1+M2 0.0209 4 +154GD2 G KC=$LC=$MC= +154GD G 401.259 140.189 3 (E1M2E3) 0.07 2 +154GD2 G KC=$LC=$MC= +154GD G 582.01 5 0.886 11E1 0.003397 +154GD2 G KC=0.00288 6$LC=3.85E-4 8$MC= +154GD G 1274.429 4 34.9 3 E1+M2 7.37E-415 +154GD2 G KC=6.32E-4 13$LC=8.10E-5 16$MC= +154GD L 1414.4 1- +154GD G 600 0.006 4 (E1) 0.003187 +154GD2 G KC=$LC=$MC= +154GD G 1292.0 2 0.0127 5 E1 0.000722 +154GD2 G KC=$LC=$MC= +154GD G 1415.0 5 0.040 2 E1 0.000611 +154GD2 G KC=$LC=$MC= +154GD L 1418 2+ +154GD B 550.0 110.075 2 12.23 1 +154GDS B EAV=168.8 4 +154GD G 125.39 5 0.007 2 +154GD G 370.71 0.0056 14E2 0.0321 7 +154GD2 G KC=$LC=$MC= +154GD G 602.81 5 0.0033 2 +M1+E2 0.048 6 +154GD2 G KC=$LC=$MC= +154GD G 1047.4 1 0.049 3 E2 0.002515 +154GD2 G KC=$LC=$MC= +154GD G 1295.5 2 0.0091 10 +154GD G 1418.6 2 0.011 2 E2 0.001383 +154GD2 G KC=$LC=$MC= +154GD L 1510.1 (1)- +154GD B 458.3 110.021 2 12.66 2 +154GDS B EAV=136.9 4 +154GD G 1387.0 5 0.019 2 (E1) 0.000632 +154GD2 G KC=$LC=$MC= +154GD G 1510.0 5 0.0048 10(E1) 0.000471 +154GD2 G KC=$LC=$MC= +154GD L 1531.3 2+ +154GD B 437.1 110.330 13 11.39 1 +154GDS B EAV=129.8 4 +154GD G 237 0.006 3 0.018 7 +154GD2 G KC=$LC=$MC= +154GD G 267.44 0.0136 7 (E2) 0.087 2 +154GD2 G KC=$LC=$MC= +154GD G 279.9 0.0030 2 (E1) 0.0190 4 +154GD2 G KC=$LC=$MC= +154GD G 290 0.0033 2 (E1) 0.0174 3 +154GD2 G KC=$LC=$MC= +154GD G 403.55 5 0.026 1 (M1E2) 0.035 10 +154GD2 G KC=$LC=$MC= +154GD G 483.74 0.0050 3 (E2) 0.0153 3 +154GD2 G KC=$LC=$MC= +154GD G 715.77 3 0.19 1 (M1E2) 0.013 4 +154GD2 G KC=$LC=$MC= +154GD G 850.64 3 0.241 4 E2 0.003928 +154GD2 G KC=$LC=$MC= +154GD G 1160.36 8 0.0436 21(E2) 0.002044 +154GD2 G KC=$LC=$MC= +154GD G 1408.5 2 0.023 3 (M1E2) 0.0037 14 +154GD2 G KC=$LC=$MC= +154GD G 1531.4 2 0.0060 4 (E2) 0.001012 +154GD2 G KC=$LC=$MC= +154GD L 1560 (4)- +154GD B 408.8 120.100 4 11.81 +154GDS B EAV=120.3 4 +154GD G 162.09 5 0.0011 4 (E2) 0.457 9 +154GD2 G KC=$LC=$MC= +154GD G 295.7 0.0024 2 (E1) 0.0166 3 +154GD2 G KC=$LC=$MC= +154GD G 563.4 0.0028 7 (M2) 0.058 1 +154GD2 G KC=$LC=$MC= +154GD G 1188.34 170.093 7 (E1) 0.000832 +154GD2 G KC=$LC=$MC= +154GD L 1617.13 3- +154GD B 351.3 111.78 3 10.34 +154GDS B EAV=101.4 4 +154GD G 202.50 160.03 1 +154GD G 219.4 0.0023 5 (M1E2) 0.20 4 +154GD2 G KC=$LC=$MC= +154GD G 375.2 5 0.0020 8 (E2) 0.0310 6 +154GD2 G KC=$LC=$MC= +154GD G 480.61 0.0048 3 +154GD G 488.26 0.007 3 (E1) 0.0049810 +154GD2 G KC=$LC=$MC= +154GD G 569.23 0.0100 8 (E1) 0.0036 1 +154GD2 G KC=$LC=$MC= +154GD G 620.52 0.091 5 (E1) 0.002966 +154GD2 G KC=$LC=$MC= +154GD G 801.21 4 0.012 3 (E1) 0.001754 +154GD2 G KC=$LC=$MC= +154GD G 1246.121 4 0.862 11E1 7.66E-415 +154GD2 G KC=6.58E-4 13$LC=8.43E-5 17$MC= +154GD G 1494.048 4 0.698 9 E1 0.000561 +154GD2 G KC=4.81E-4 10$LC=6.11E-5 12$MC= +154GD L 1645.8 4+ +154GD B 322.6 110.148 4 11.31 1 +154GDS B EAV=92.2 4 +154GD G 368.21 0.0030 2 +154GD G 382.00 5 0.0099 4 (E2M1) 0.034 11 +154GD2 G KC=$LC=$MC= +154GD G 518.00 5 0.047 2 (E2M1) 0.013 1 +154GD2 G KC=$LC=$MC= +154GD G 598.3 0.0062 7 M1+E2 0.014 1 +154GD2 G KC=$LC=$MC= +154GD G 649.44 5 0.078 3 E2 0.0073 2 +154GD2 G KC=$LC=$MC= +154GD L 1660.9 3+ +154GD B 307.5 110.849 9 10.48 +154GDS B EAV=87.4 3 +154GD G 129.5 0.014 2 (M1E2) 0.99 3 +154GD2 G KC=$LC=$MC= +154GD G 397.1 0.029 1 (M1E2) 0.036 10 +154GD2 G KC=$LC=$MC= +154GD G 419.4 0.0034 20M2 0.140 3 +154GD2 G KC=$LC=$MC= +154GD G 533.1 0.007 2 +154GD G 613.26 5 0.093 4 (E2M1) 0.012 4 +154GD2 G KC=$LC=$MC= +154GD G 664.68 5 0.029 1 (M1E2) 0.010 3 +154GD2 G KC=$LC=$MC= +154GD G 845.416 7 0.586 9 E2 0.003978 +154GD2 G KC=0.00333 7$LC=5.02E-4 10$MC= +154GD G 1290.5 1 0.025 3 (M1E2) 0.0021 5 +154GD2 G KC=$LC=$MC= +154GD G 1537.81 4 0.053 2 (M1E2) 0.0012 3 +154GD2 G KC=$LC=$MC= +154GD L 1698.5 (4)+ +154GD B 270.2 110.0100 4 12.33 1 +154GDS B EAV=75.7 3 +154GD G 650.6 0.0098 4 (M1E2) 0.026 8 +154GD2 G KC=$LC=$MC= +154GD L 1719.56 2- +154GD B 248.8 1128.32 22 8.66 +154GDS B EAV=69.2 3 +154GD G 58.4 0.0039 4 (E1) 1.23 3 +154GD2 G KC=$LC=$MC= +154GD G 188.24 2 0.239 6 E1 0.0536 11 +154GD2 G KC=0.0453 9$LC=0.0065 2$MC= +154GD G 209.4 4 0.0025 6 +154GD G 301.25 0.0102 4 (E2) 0.0158 3 +154GD2 G KC=$LC=$MC= +154GD G 305.1 0.0174 7 (M1E2) 0.075 18 +154GD2 G KC=$LC=$MC= +154GD G 322.02 5 0.066 3 (M1E2) 0.065 17 +154GD2 G KC=$LC=$MC= +154GD G 467.84 5 0.0604 24(M1E2) 0.024 7 +154GD2 G KC=$LC=$MC= +154GD G 478.27 5 0.224 3 M1 0.0287 6 +154GD2 G KC=0.0245 5$LC=0.00341 7$MC=0.00074 2 +154GD G 591.755 3 4.95 5 E1+(M2) 0.0032910 +154GD2 G KC=0.0028 6$LC=3.74E-4 8$MC=3.72E-5 8 +154GD G 723.3014 2220.05 21E1+M2 0.002155 +154GD2 G KC=0.00184 4$LC=2.44E-4 5$MC= +154GD G 904.064 3 0.890 11E1(+M2) 0.001383 +154GD2 G KC=0.00118 4$LC=1.56E-4 3$MC= +154GD G 1596.4804 281.783 17E1(+M2) 0.000491 +154GD2 G KC=4.30E-4 9$LC=5.46E-5 11$MC= +154GD L 1770.2 5+ +154GD B 197.9 110.0022 4 12.46 1U +154GDS B EAV=53.9 3 +154GD G 506.4 0.0063 14E2 0.0136 3 +154GD2 G KC=$LC=$MC= +154GD G 642.4 0.0044 17(M1E2) 0.011 4 +154GD2 G KC=$LC=$MC= +154GD G 774.4 0.008 4 (M3) 0.053 2 +154GD2 G KC=$LC=$MC= +154GD G 1397.34 5 0.0031 8 (M1E2) 0.0018 4 +154GD2 G KC=$LC=$MC= +154GD L 1790.2 (4)+ +154GD B 178.1 110.022 1 11.31 1 +154GDS B EAV=48.1 3 +154GD G 1419.0 2 0.0020 1 (M1E2) 0.0017 4 +154GD2 G KC=$LC=$MC= +154GD G 1667.3 2 0.0019 3 (E2) +154GD L 1797 3- +154GD B 171.7 120.060 6 10.8 +154GDS B EAV=46.3 3 +154GD G 533.1 0.004 3 E1 0.004128 +154GD2 G KC=$LC=$MC= +154GD G 668.9 0.013 2 E1 0.002535 +154GD2 G KC=$LC=$MC= +154GD G 800.2 0.032 5 E1 0.001754 +154GD2 G KC=$LC=$MC= +154GD G 981.3 5 0.0084 17(E1) 0.001183 +154GD2 G KC=$LC=$MC= +154GD G 1425.9 5 0.0012 7 (E1) 0.000601 +154GD2 G KC=$LC=$MC= +154GD G 1674.0 5 0.0017 4 (E1) +154GD L 1838.6 2+ +154GD B 130.1 120.017 5 10.99 1 +154GDS B EAV=34.5 3 +154GD G 790.2 0.010 3 (E2) 0.004629 +154GD2 G KC=$LC=$MC= +154GD G 1023 1 0.0066 25(M1E2) +154GD G 1716.9 5 0.0006 3 (M1E2) +154GD G 1838.0 5 0.0008 2 (E2) +154GD L 1861.5 4- +154GD B 107.2 110.034 3 10.44 +154GDS B EAV=28.1 3 +154GD G 597.5 0.0055 3 (E1) 0.003217 +154GD2 G KC=$LC=$MC= +154GD G 1489.6 2 0.0029 4 (E1) 0.000561 +154GD2 G KC=$LC=$MC= +154GD L 1878.5 + +154GD B 89.4 110.0042 3 +154GDS B EAV=23.3 3 +154GD G 463.9 0.0042 3 +154GD L 1894.7 5 2+ +154GD B 73.7 110.0035 6 10.92 1 +154GDS B EAV=19.0 3 +154GD G 898.36 0.0020 5 (M1E2) 0.0048 13 +154GD2 G KC=$LC=$MC= +154GD G 1522 1 0.0006 3 (E2) 0.001022 +154GD2 G KC=$LC=$MC= +154GD G 1773 1 0.00035 21(M1E2) +154GD G 1895 1 0.0006 2 (E2) + diff --git a/HEN_HOUSE/spectra/lnhb/Eu-155.txt b/HEN_HOUSE/spectra/lnhb/Eu-155.txt new file mode 100644 index 000000000..274eae1cf --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Eu-155.txt @@ -0,0 +1,75 @@ +155GD 155EU B- DECAY (4.753 Y) +155GD C References: 1977La19 +155GD T Auger electrons and ^X ray energies and emission intensities: +155GD T {U Energy (keV)} {U Intensity } {U Line } +155GD T +155GD T 42.3093 6.70 13 XKA2 +155GD T 42.9967 12.05 23 XKA1 +155GD T +155GD T 48.556 |] XKB3 +155GD T 48.697 |] 3.84 11 XKB1 +155GD T 49.053 |] XKB5II +155GD T +155GD T 49.961 |] XKB2 +155GD T 50.099 |] 0.977 26 XKB4 +155GD T 50.219 |] XKO23 +155GD T +155GD T 5.3611-8.104 7.5 5 XL (total) +155GD T 5.3611 XLL +155GD T 6.024-6.0578 XLA +155GD T 6.0483 XLC +155GD T 6.6848-7.1888 XLB +155GD T 7.5509-8.104 XLG +155GD T +155GD T 33.49-35.75 |] KLL AUGER +155GD T 39.98-42.86 |] 1.71 11 ^KLX AUGER +155GD T 47.98-48.95 |] KXY AUGER +155GD T 3.4-8.3 35.1 20 L AUGER +155EU P 0.0 5/2+ 4.753 Y 14 252.1 11 +155GD N 1.0 1.0 1 1.0 +155GD L 0 3/2- STABLE +155GD B 252.2 1116.6 11 8.65 1U +155GDS B EAV=70.2 3 +155GD L 60.0086 105/2- 0.193 NS 10 +155GD B 192.2 119.2 4 8.54 +155GDS B EAV=52.3 3 +155GD G 60.0086 101.22 5 M1+E2 9.48 11 +155GD2 G KC=7.48 9$LC=1.55 6$MC=0.347 14 +155GD L 86.5479 105/2+ 6.50 NS 4 +155GD B 165.7 1125.5 29 7.89 +155GDS B EAV=44.6 3 +155GD G 26.531 210.316 22E1 1.98 6 +155GD2 G KC=$LC=1.55 5$MC=0.342 11 +155GD G 86.5479 1030.7 3 E1 0.432 7 +155GD2 G KC=0.360 4$LC=0.0561 17$MC=0.0122 4 +155GD L 105.3083 103/2+ 1.16 NS 1 +155GD B 146.9 1146.1 29 7.47 2 +155GDS B EAV=39.2 3 +155GD G 18.763 2 0.048 7 M1+E2 367 22 +155GD2 G KC=$LC=284 22$MC=65.9 30 +155GD G 45.299 1 1.31 5 E1 0.443 11 +155GD2 G KC=$LC=0.347 10$MC=0.0758 23 +155GD G 105.3083 1021.1 6 E1 0.255 3 +155GD2 G KC=0.214 2$LC=0.0323 10$MC=0.00701 21 +155GD L 107.583 5 9/2+ +155GD B 144.6 110.01 11.1 +155GDS B EAV= +155GD G 21.035 4 0.00046 3 E2 2600 70 +155GD2 G KC=$LC=2010 60$MC=471 14 +155GD L 117.998 2 7/2+ +155GD B 134.2 111.85 23 8.75 2 +155GDS B EAV=35.6 3 +155GD G 10.4183 130.0035 4 M1+E2 340 23 +155GD2 G KC=$LC=265 22$MC=59 5 +155GD G 31.444 7 0.0071 15M1+E2 69 14 +155GD2 G KC=$LC=53 13$MC=12.5 30 +155GD G 57.989 1 0.067 6 E1 1.243 11 +155GD2 G KC=1.021 10$LC=0.173 5$MC=0.0377 11 +155GD L 146.0711 107/2- 0.101 NS 120 +155GD B 106.1 110.73 7 8.83 1U +155GDS B EAV=27.8 3 +155GD G 86.0591 100.154 17M1+E2 3.23 4 +155GD2 G KC=2.66 3$LC=0.443 17$MC=0.098 4 +155GD G 146.071 1 0.051 4 E2 0.653 8 +155GD2 G KC=0.397 4$LC=0.198 6$MC=0.0462 14 + diff --git a/HEN_HOUSE/spectra/lnhb/F-18.txt b/HEN_HOUSE/spectra/lnhb/F-18.txt new file mode 100644 index 000000000..b20a0da98 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/F-18.txt @@ -0,0 +1,30 @@ + 18O 18F EC DECAY (1.82890 H) + 18O H TYP=UPD$AUT=N.K. Kuzmenko$CUT=01-JUN-2014$ + 18O 2 H TYP=UPD$AUT=V. Chisté. M.-M. Bé$CUT=01-JUN-2006$ + 18O 3 H TYP=FUL$AUT=V. Chisté. M.-M. Bé$CUT=01-OCT-2002$ + 18O C Evaluation history: Type=UPD;Author=N.K. Kuzmenko;Cutoff date=01-JUN-2014 + 18O 2C Type=UPD;Author=V. Chisté. M.-M. Bé;Cutoff date=01-JUN-2006 + 18O 3C Type=FUL;Author=V. Chisté. M.-M. Bé;Cutoff date=01-OCT-2002 + 18O C References: 1938Br01, 1943Hu02, 1949Bl26, 1951Ru24, 1956Dr38, 1958Be74, + 18O 2C 1958Ma68, 1959Aj76, 1959Ca01, 1960Yu02, 1961Ra06, 1962Ma48, 1963Be47, + 18O 3C 1964Ho28, 1964Ho09, 1964Ma12, 1965Eb01, 1965Bo42, 1970Al11, 1972Aj02, + 18O 4C 1973Ho43, 1977Ba48, 1978Aj03, 1980RuZY, 1987Aj02, 1989Sc17, 2002Un02, + 18O 5C 2004BeZQ, 2004Sc04, 2010Ga04, 2012Ha35, 2012Wa38, 2014Un01 + 18O T Auger electrons and ^X ray energies and emission intensities: + 18O T {U Energy (keV)} {U Intensity } {U Line } + 18O T + 18O T 0.525 0.007 2 XKA2 + 18O T 0.525 0.013 4 XKA1 + 18O T + 18O T + 18O T + 18O T + 18O T 0.456-0.502 |] KLL AUGER + 18O T - |] 2.89 18 ^KLX AUGER + 18O T -0.0143 0.229 21 L AUGER + 18F P 0.0 1+ 1.82890 H 23 1655.9 5 + 18O N 1.0 1.0 1 1.0 + 18O L 0 0+ STABLE + 18O E 96.86 193.14 193.57 + 18O 2 E EAV=249.5 3$CK=0.927 5$CL=0.073 5$CM= $CN= $CO= + diff --git a/HEN_HOUSE/spectra/lnhb/Fe-52.txt b/HEN_HOUSE/spectra/lnhb/Fe-52.txt new file mode 100644 index 000000000..e3de4b46b --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Fe-52.txt @@ -0,0 +1,44 @@ + 52MN 52FE EC DECAY (8.273 H) + 52MN H TYP=FULL$AUT=A.Luca$CUT=30-SEP-2013$ + 52MN C Evaluation history: Type=FULL;Author=A.Luca;Cutoff date=30-SEP-2013 + 52MN C References: 1948Mi12, 1956Ar33, 1959Ju40, 1960Ka20, 1967Pa22, 1971Go40, + 52MN2C 1971Sa21, 1972McYW, 1974Ro18, 1977Ya08, 1996Sc06, 1998Sc28, 2000Sc47, + 52MN3C 2007Hu08, 2008Ki07, 2012Wa38 + 52MN T Auger electrons and ^X ray energies and emission intensities: + 52MN T {U Energy (keV)} {U Intensity } {U Line } + 52MN T + 52MN T 5.88772 3.70 17 XKA2 + 52MN T 5.89881 7.3 4 XKA1 + 52MN T + 52MN T 6.49051 |] 1.49 7 XKB1 + 52MN T 6.5354 |] XKB5II + 52MN T + 52MN T + 52MN T 0.5576-0.7694 0.213 10 XL (total) + 52MN T 0.5576 0.124 8 XLL + 52MN T 0.6394-0.6404 0 0 XLA + 52MN T 0.5695 0.085 6 XLC + 52MN T 0.64636-0.7694 0.00315 18 XLB + 52MN T 0.65826-0.65826 0 0 XLG + 52MN T + 52MN T 4.953-5.21 |] KLL AUGER + 52MN T 5.671-5.895 |] 26.3 11 ^KLX AUGER + 52MN T 6.37-6.532 |] KXY AUGER + 52MN T 0.4725-0.7653 57.1 15 L AUGER + 52FE P 0.0 0+ 8.273 H 8 2375 6 + 52MN N 1.0 1.0 1 1.0 + 52MN L 0 6+ 5.591 D 3 + 52MN L 377.749 5 2+ 21.1 M 2 + 52MN G 377.749 5 1.64 4 E4 0.0399 6 + 52MN2 G KC=0.0356 5$LC=0.00382 6$MC=5.15E-4 8 + 52MN L 546.438 6 1+ + 52MN E 56.1 7 43.8 134.7 + 52MN2 E EAV=339 6$CK=0.8898 16$CL=0.0946 13$CM=0.0150 5$CN=0.0006 2$CO= + 52MN G 168.689 8 99.1 15M1 0.0078311 + 52MN2 G KC=0.00705 10$LC=6.79E-4 10$MC=9.22E-5 13 + 52MN L 1417.688 18 + + 52MN E 0.095 4 5.8 + 52MN2 E EAV= $CK=0.8892 16$CL=0.0950 13$CM=0.0151 5$CN=0.0006 2$CO= + 52MN G 1039.939 190.095 4 M1+E2 1.43E-416 + 52MN2 G KC=1.30E-4 15$LC=1.22E-5 14$MC=1.65E-6 19 + diff --git a/HEN_HOUSE/spectra/lnhb/Fe-55.txt b/HEN_HOUSE/spectra/lnhb/Fe-55.txt new file mode 100644 index 000000000..60612465c --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Fe-55.txt @@ -0,0 +1,36 @@ + 55MN 55FE EC DECAY (2.747 Y) + 55MN H TYP=Updated$AUT=MMBé$CUT=20-DEC-2005$ + 55MN2 H TYP=Full$AUT=MMBé$CUT=01-APR-1998$ + 55MN C Evaluation history: Type=Updated;Author=MMBé;Cutoff date=20-DEC-2005 + 55MN2C Type=Full;Author=MMBé;Cutoff date=01-APR-1998 + 55MN C References: 1977La19 + 55MN T Auger electrons and ^X ray energies and emission intensities: + 55MN T {U Energy (keV)} {U Intensity } {U Line } + 55MN T + 55MN T 5.88765 8.45 14 XKA2 + 55MN T 5.89875 16.57 27 XKA1 + 55MN T + 55MN T 6.49045 |] XKB3 + 55MN T |] 3.40 7 XKB1 + 55MN T 6.5352 |] XKB5II + 55MN T + 55MN T + 55MN T 0.556-0.721 0.524 21 XL (total) + 55MN T 0.556 0.309 17 XLL + 55MN T 0.567 0.204 13 XLC + 55MN T 0.649-0.721 0.0104 5 XLB + 55MN T + 55MN T 4.953-5.21 |] KLL AUGER + 55MN T 5.671-5.895 |] 60.1 5 ^KLX AUGER + 55MN T 6.37-6.532 |] KXY AUGER + 55MN T 0.47-0.67 140.2 8 L AUGER + 55FE P 0.0 3/2- 2.747 Y 8 231.21 18 + 55MN N 1.0 1.0 1 1.0 + 55MN L 0 5/2- STABLE + 55MN E 100 6 2 + 55MN2 E EAV= $CK=0.8853 16$CL=0.0983 13$CM=0.0163 8$CN= $CO= + 55MN L 125.949 107/2- + 55MN E 13000E-11 14.2 + 55MN2 E EAV= $CK= $CL= $CM= $CN= $CO= + 55MN G 125.949 101.3E-7 1 M1+(E2) + diff --git a/HEN_HOUSE/spectra/lnhb/Fe-59.txt b/HEN_HOUSE/spectra/lnhb/Fe-59.txt new file mode 100644 index 000000000..41a53095d --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Fe-59.txt @@ -0,0 +1,66 @@ + 59CO 59FE B- DECAY (44.494 D) + 59CO H TYP=UPD$AUT=V.Chechev$CUT=12-JUL-2014$ + 59CO2 H TYP=UPD$AUT=MM.Be. V.Chiste$CUT=31-MAR-2004$ + 59CO3 H TYP=FUL$AUT=MM.Be. V.Chiste$CUT=01-DEC-2001$ + 59CO C Evaluation history: Type=UPD;Author=V.Chechev;Cutoff date=12-JUL-2014 + 59CO2C Type=UPD;Author=MM.Be. V.Chiste;Cutoff date=31-MAR-2004 + 59CO3C Type=FUL;Author=MM.Be. V.Chiste;Cutoff date=01-DEC-2001 + 59CO C References: 1952Me53, 1953Hi02, 1958Ke26, 1959Pi43, 1959Fe18, 1960Be06, + 59CO2C 1960Fu03, 1960He06, 1960Su10, 1963Wo01, 1964Co34, 1967Be60, 1970Le03, + 59CO3C 1971Ar07, 1972Ga39, 1972Em01, 1973Pa16, 1973Er11, 1973Vi13, 1974Ra13, + 59CO4C 1974Ba**, 1974Mu12, 1975Al02, 1977Kr13, 1980Ho17, 1983Wa26, 1989Mi07, + 59CO5C 1992Un01, 1997Ma75, 2000He14, 2002Ba42, 2002Ba85, 2004BeZR, 2008Ki07, + 59CO6C 2012Fi12, 2012Wa38, 2014Un01 + 59CO T Auger electrons and ^X ray energies and emission intensities: + 59CO T {U Energy (keV)} {U Intensity } {U Line } + 59CO T + 59CO T 6.91538 0.00596 11 XKA2 + 59CO T 6.9304 0.01166 21 XKA1 + 59CO T + 59CO T 7.6495 |] 0.00242 5 XKB1 + 59CO T 7.706 |] XKB5II + 59CO T + 59CO T + 59CO T 0.6793-0.8674 0.000532 13 XL (total) + 59CO T 0.6793 0.0000231 8 XLL + 59CO T 0.7787-0.7795 0.000293 9 XLA + 59CO T 0.6949 0.0000144 6 XLC + 59CO T 0.78642-0.8674 0.000201 8 XLB + 59CO T 0.80198-0.80198 0.00000122 14 XLG + 59CO T + 59CO T 5.81-6.1 |] KLL AUGER + 59CO T 6.67-6.93 |] 0.0316 5 ^KLX AUGER + 59CO T 7.51-7.7 |] KXY AUGER + 59CO T 0.58-0.92 0.0778 6 L AUGER + 59FE P 0.0 3/2- 44.494 D 12 1565.0 4 + 59CO N 1.0 1.0 1 1.0 + 59CO L 0 0 7/2- STABLE + 59CO B 1565.0 4 0.18 4 11.15 + 59COS B EAV=584 + 59CO L 1099.256 3 3/2- 3.1 PS 4 + 59CO B 465.7 4 53.30 31 6.69 + 59COS B EAV=149.2 2 + 59CO G 1099.245 3 56.51 31E2 1744E-725 + 59CO2 G KC=1571E-7 22$LC=1515E-8 22$MC=2.11E-6 3 + 59CO L 1291.605 5 3/2- 551 PS 7 + 59CO B 273.4 4 45.19 34 5.98 + 59COS B EAV=80.9 2 + 59CO G 192.349 5 2.91 5 0.211 9 0.0090018 + 59CO2 G KC=0.00808 17$LC=8.05E-4 17$MC=1120E-7 23 + 59CO G 1291.590 6 43.23 33E2 1483E-721 + 59CO2 G KC=1096E-7 16$LC=1055E-8 15$MC=1470E-9 21 + 59CO L 1434.256 5 1/2- 210 PS 20 + 59CO B 130.7 4 1.25 3 6.49 2 + 59COS B EAV=35.7 1 + 59CO G 142.651 2 0.978 28M1+E2 -0.008 7 0.0159623 + 59CO2 G KC=0.01432 21$LC=1428E-6 20$MC=1.99E-4 3 + 59CO G 335.000 6 0.260 11M1+E2 -0.12 6 0.001988 + 59CO2 G KC=0.00178 7$LC=1.74E-4 7$MC=2.43E-5 9 + 59CO L 1481.72 125/2- + 59CO B 83.3 4 0.080 6 7.08 2 + 59COS B EAV=22.0 1 + 59CO G 382.46 120.0215 23M1+E2 0.1 1 0.001447 + 59CO2 G KC=0.00129 6$LC=1.26E-4 6$MC=1.76E-5 9 + 59CO G 1481.70 120.059 6 M1+E2 -0.19 4 1448E-721 + 59CO2 G KC=7.51E-5 11$LC=7.20E-6 11$MC=1003E-9 15 + diff --git a/HEN_HOUSE/spectra/lnhb/Fr-221.txt b/HEN_HOUSE/spectra/lnhb/Fr-221.txt new file mode 100644 index 000000000..b0a3d91fb --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Fr-221.txt @@ -0,0 +1,114 @@ +217AT 221FR A DECAY (4.79 M) +217AT H TYP=Full$AUT=Huang Xiaolong$CUT= -- $ +217AT C Evaluation history: Type=Full;Author=Huang Xiaolong;Cutoff date= -- +217AT T Auger electrons and ^X ray energies and emission intensities: +217AT T {U Energy (keV)} {U Intensity } {U Line } +217AT T +217AT T 78.94 0.96 5 XKA2 +217AT T 81.51 1.59 9 XKA1 +217AT T +217AT T 91.73 |] XKB3 +217AT T 92.315 |] 0.55 6 XKB1 +217AT T 92.883 |] XKB5II +217AT T +217AT T 94.846 |] XKB2 +217AT T 95.211 |] 0.18 2 XKB4 +217AT T 95.595 |] XKO23 +217AT T +217AT T 9.8964-16.7291 2.18 7 XL (total) +217AT T 9.8964 XLL +217AT T 11.3052-11.426 XLA +217AT T 12.4653 XLC +217AT T 13.1704-14.6997 XLB +217AT T 15.7394-16.7291 XLG +217AT T +217AT T 60.489-67.031 |] KLL AUGER +217AT T 73.811-81.516 |] 0.114 6 ^KLX AUGER +217AT T 87.1-95.72 |] KXY AUGER +217AT T 5.6-17.4 3.05 10 L AUGER +221FR P 0.0 5/2- 4.79 M 2 6457.8 14 +217AT N 1.00E0 1.00E0 0.999952 1.00E0 +217AT L 0 9/2- 32.3 MS 4 +217AT A 6341.0 1382.8 2 3.44 +217AT L 100.25 2 7/2- 0.5 NS +217AT A 6243 2 1.34 7 120 +217AT G 100.25 2 0.156 13M1 11.97 17 +217AT2 G KC=9.66 14$LC=1.758 25$MC=0.416 6 +217AT L 218.12 2 5/2- +217AT A 6126.3 1515.1 2 2.2 +217AT G 117.82 3 0.022 16M1 7.58 11 +217AT2 G KC=6.13 9$LC=1.104 16$MC=0.261 4 +217AT G 218.12 2 11.42 15E2 0.367 5 +217AT2 G KC=0.1375 20$LC=0.1701 24$MC=0.0451 7 +217AT L 272.07 4 3/2- 0.27 NS 2 +217AT A 6075.9 200.15 3 65 +217AT G 53.81 3 0.0145 25M1 14.17 20 +217AT2 G KC=$LC=10.79 15$MC=2.56 4 +217AT G 171.83 3 0.069 9 E2 0.863 12 +217AT2 G KC=0.226 4$LC=0.471 7$MC=0.1257 18 +217AT L 368.23 4 (3/2)- +217AT A 5979.9 200.39 7 27 +217AT G 96.3 3 0.007 3 M1+E2 0.7 7 5.6 24 +217AT2 G KC=$LC=4.1 18$MC=1.1 5 +217AT G 150.21 3 0.0449 25M1 3.80 5 +217AT2 G KC=3.08 5$LC=0.550 8$MC=0.1303 19 +217AT L 382.34 4 (7/2)- +217AT A 5965.9 250.064 16117 +217AT G 282.12 9 0.0069 7 [M1E2] 0.41 25 +217AT2 G KC=0.30 23$LC=0.077 17$MC=0.019 4 +217AT G 382.34 4 0.0340 14M1 0.284 4 +217AT2 G KC=0.231 4$LC=0.0406 6$MC=0.00960 14 +217AT L 410.64 5 13/2- +217AT A 5938.9 200.128 3 36.4 +217AT G 410.64 5 0.1204 25E2 0.0548 8 +217AT2 G KC=0.0344 5$LC=0.01528 22$MC=0.00392 6 +217AT L 424.35 7 (5/2,7/2,9/2)- +217AT A 5925 3 0.0285 24143 +217AT G 324.10 6 0.0174 12M1 0.446 6 +217AT2 G KC=0.362 5$LC=0.0639 9$MC=0.01510 22 +217AT L 537.5 5 (9/2)+ +217AT A 5813 3 0.006 1 197 +217AT G 437.00 5 0.0010 1 +217AT G 537.8 8 0.0045 8 +217AT L 568.5 3 (7/2,9/2)+ +217AT A 5783 4 0.0031 6 290 +217AT G 468.3 7 0.0018 3 +217AT G 568.5 3 0.0012 4 +217AT L 577.5 5 (7/2)- +217AT A 5776 3 0.064 4 11.7 +217AT G 208.3 6 0.0051 10[E2] 0.430 8 +217AT2 G KC=0.1519 24$LC=0.206 4$MC=0.0547 11 +217AT G 359.86 4 0.0385 15M1 0.335 5 +217AT2 G KC=0.272 4$LC=0.0479 7$MC=0.01133 16 +217AT G 576.9 4 0.0030 6 [M1] 0.0948 13 +217AT2 G KC=0.0772 11$LC=0.01342 19$MC=0.00317 5 +217AT L 652 2 + +217AT A 5697 4 30001E-8 828 +217AT G 652 2 0.0004 4 +217AT L 664.4 2 + +217AT A 5689 3 0.0025 5 111 +217AT G 282.12 9 +217AT G 446.30 8 0.0017 4 E1+M2 +217AT G 562.3 120.005 5 +217AT G 665 2 0.0009 9 +217AT L 809.3 2 + +217AT A 5530 250.00010 2 60 +217AT G 809.3 2 0.00010 2 +217AT L 891.9 3 - +217AT A 5500 4038000E-91061 +217AT G 891.9 3 3.8E-5 10 + +221RA 221FR B- DECAY (4.79 M) +221RA H TYP=Full$AUT=Huang Xiaolong$CUT= -- $ +221RA C Evaluation history: Type=Full;Author=Huang Xiaolong;Cutoff date= -- +221RA T Auger electrons and ^X ray energies and emission intensities: +221RA T {U Energy (keV)} {U Intensity } {U Line } +221RA T +221RA T +221RA T +221RA T +221RA T +221FR P 0.0 5/2- 4.79 M 2 314 6 +221RA N 2.083E4 2.083E4 0.000048 2.083E4 +221RA L 0 5/2+ 28 S 2 + diff --git a/HEN_HOUSE/spectra/lnhb/Fr-223.txt b/HEN_HOUSE/spectra/lnhb/Fr-223.txt new file mode 100644 index 000000000..0305152cf --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Fr-223.txt @@ -0,0 +1,345 @@ +219AT 223FR A DECAY (22.00 M) +219AT H TYP=Full$AUT=Huang Xiaolong$CUT=31-DEC-2008$ +219AT C Evaluation history: Type=Full;Author=Huang Xiaolong;Cutoff date=31-DEC-2008 +219AT T Auger electrons and ^X ray energies and emission intensities: +219AT T {U Energy (keV)} {U Intensity } {U Line } +219AT T +219AT T 78.94 0.00056 15 XKA2 +219AT T 81.51 0.00092 25 XKA1 +219AT T +219AT T 91.73 |] XKB3 +219AT T 92.315 |] 0.00031 11 XKB1 +219AT T 92.883 |] XKB5II +219AT T +219AT T 94.846 |] XKB2 +219AT T 95.211 |] 0.00011 6 XKB4 +219AT T 95.595 |] XKO23 +219AT T +219AT T 9.8964-16.7291 0.0054 13 XL (total) +219AT T 9.8964 XLL +219AT T 11.3052-11.426 XLA +219AT T 12.4653 XLC +219AT T 13.1704-14.6997 XLB +219AT T 15.7394-16.7291 XLG +219AT T +219AT T 60.489-67.031 |] KLL AUGER +219AT T 73.811-81.516 |] 0.000065 20 ^KLX AUGER +219AT T 87.1-95.72 |] KXY AUGER +219AT T 5.6-17.4 0.0076 18 L AUGER +223FR P 0.0 3/2- 22.00 M 7 5562 3 +219AT N 5.000E3 5.000E3 0.0002 5.000E3 +219AT L 0 9/2- 56 S 4 +219AT A 5462 3 17 8 +219AT L 58.9 2 (7/2)- +219AT A 5403 3 22 10 +219AT G 58.9 2 0.0008 3 M1 10.87 19 +219AT2 G KC=$LC=8.27 15$MC=1.96 4 +219AT L 150.9 2 5/2- +219AT A 5314 4 27 12 +219AT G 150.9 2 0.0056 5 E2 1.417 21 +219AT2 G KC=0.287 4$LC=0.836 13$MC=0.224 4 +219AT L 175.04 213/2- +219AT A 5291 4 30 13 +219AT G 24.14 3 +219AT L 296.2 4 3/2- +219AT A 5172 5 4.5 25 +219AT G 145.3 3 0.0002 1 M1+(E2) 2.9 13 +219AT2 G KC=1.8 16$LC=0.8 2$MC=0.20 6 + +223RA 223FR B- DECAY (22.00 M) +223RA H TYP=Full$AUT=Huang Xiaolong$CUT=31-DEC-2008$ +223RA C Evaluation history: Type=Full;Author=Huang Xiaolong;Cutoff date=31-DEC-2008 +223RA T Auger electrons and ^X ray energies and emission intensities: +223RA T {U Energy (keV)} {U Intensity } {U Line } +223RA T +223RA T 85.43 1.44 19 XKA2 +223RA T 88.47 2.3 3 XKA1 +223RA T +223RA T 99.432 |] XKB3 +223RA T 100.13 |] 0.83 11 XKB1 +223RA T 100.738 |] XKB5II +223RA T +223RA T 102.89 |] XKB2 +223RA T 103.295 |] 0.27 4 XKB4 +223RA T 103.74 |] XKO23 +223RA T +223RA T 10.6241-18.3539 24 3 XL (total) +223RA T 10.6241 XLL +223RA T 12.1957-12.3381 XLA +223RA T 13.6624 XLC +223RA T 14.2373-16.1261 XLB +223RA T 17.2756-18.3539 XLG +223RA T +223RA T 65.149-72.729 |] KLL AUGER +223RA T 79.721-88.466 |] 0.159 21 ^KLX AUGER +223RA T 94.27-103.91 |] KXY AUGER +223RA T 5.71-12.04 29 4 L AUGER +223FR P 0.0 3/2- 22.00 M 7 1149.2 9 +223RA N 1.00E0 1.00E0 0.9998 1.00E0 +223RA L 0 3/2+ 11.43 D 3 +223RA B 1149.2 9 1 7.6 +223RAS B EAV=380.8 4 +223RA L 29.854 18(5/2)+ +223RA B 1119.3 9 6 6 6.8 1U +223RAS B EAV=369.4 4 +223RA G 29.78 4 0.070 17M1+E2 0.30 3 370 50 +223RA2 G KC=$LC=280 40$MC=72 10 +223RA L 50.101 163/2- +223RA B 1099.1 9 67 13 5.68 +223RAS B EAV=361.7 4 +223RA G 20.27 5 1.4 3 [E1] 7.76 22 +223RA2 G KC=$LC=5.77 16$MC=1.50 3 +223RA G 50.10 2 33 7 E1 0.696 10 +223RA2 G KC=$LC=0.526 8$MC=0.1288 18 +223RA L 61.435 23(7/2)+ +223RA B 1087.8 9 0.27 19 8.1 3U +223RAS B EAV=357.4 4 +223RA G 31.69 5 1350E-6 0 M1+E2 0.28 6 260 80 +223RA2 G KC=$LC=190 60$MC=50 15 +223RA G 61.43 5 0.0035 7 E2 96.5 14 +223RA2 G KC=$LC=71.0 11$MC=19.3 3 +223RA L 79.649 16(5/2)- +223RA B 1069.6 9 15 3 6.29 2 +223RAS B EAV=350.5 4 +223RA G 49.80 5 2.5 6 E1 0.708 10 +223RA2 G KC=$LC=0.535 8$MC=0.1309 19 +223RA G 79.65 2 9.0 18E1 0.202 3 +223RA2 G KC=$LC=0.1530 22$MC=0.0370 6 +223RA L 123.724 23(7/2)- +223RA B 1025.5 9 0.24 6 8.02 +223RAS B EAV=333.9 4 +223RA G 44.0 1 1350E-6 0 M1+E2 0.52 4 131 12 +223RA2 G KC=$LC=97 9$MC=25.5 24 +223RA G 62.31 6 0.016 7 E1 0.389 6 +223RA2 G KC=$LC=0.294 5$MC=0.0716 11 +223RA G 73.5 1 0.0013 9 E2 40.8 6 +223RA2 G KC=$LC=30.0 5$MC=8.16 13 +223RA G 93.88 5 0.059 14E1 0.1305 18 +223RA2 G KC=$LC=0.0989 14$MC=0.0239 4 +223RA L 234.747 20(5/2)+ +223RA B 914.5 9 9.1 17 6.27 1U +223RAS B EAV=292.6 4 +223RA G 111.05 3 0.0049 14 +223RA G 155.5 5 2700E-6 0 +223RA G 173.35 5 0.115 22M1E2 2.1 12 +223RA2 G KC=1.4 12$LC=0.53 5$MC=0.136 20 +223RA G 184.65 5 0.22 5 E1 0.1092 15 +223RA2 G KC=0.0868 13$LC=0.01701 24$MC=0.00407 6 +223RA G 204.85 5 0.92 18M1+E2 -0.12 7 2.02 5 +223RA2 G KC=1.62 4$LC=0.304 5$MC=0.0726 11 +223RA G 234.70 5 2.7 5 M1(+E2) -0.07 2 1.393 16 +223RA2 G KC=1.120 16$LC=0.207 3$MC=0.0495 7 +223RA L 280.19 4 (7/2)+ +223RA B 869.0 9 0.004 4 9.5 3U +223RAS B EAV=275.9 4 +223RA G 200.7 2 0.0027 10 +223RA G 218.80 5 0.0086 17M1 1.701 24 +223RA2 G KC=1.368 20$LC=0.252 4$MC=0.0603 9 +223RA G 250.25 5 1600E-5 0 M1 1.170 16 +223RA2 G KC=0.941 14$LC=0.1733 25$MC=0.0414 6 +223RA G 280.7 5 3000E-7 0 +223RA L 286.07 4 1/2+ +223RA B 863.1 9 0.032 9 8.64 1U +223RAS B EAV=273.8 4 +223RA G 236.05 5 0.027 8 E1 0.0610 9 +223RA2 G KC=0.0489 7$LC=0.00922 13$MC=0.00220 3 +223RA G 256.18 5 0.020 4 E2 0.250 4 +223RA2 G KC=0.0983 14$LC=0.1117 16$MC=0.0299 5 +223RA G 286.0 2 0.0046 10M1+E2 0.5 4 +223RA2 G KC=0.4 3$LC=0.096 24$MC=0.024 5 +223RA L 329.82 3 3/2- +223RA B 819.4 9 0.049 10 8.37 +223RAS B EAV=257.9 4 +223RA G 43.5 2 2200E-6 0 E1 1.015 19 +223RA2 G KC=$LC=0.767 15$MC=0.189 4 +223RA G 205.6 2 0.0059 11E2 0.530 8 +223RA2 G KC=0.1533 22$LC=0.277 4$MC=0.0747 11 +223RA G 250.25 5 3000E-6 0 M1+E2 -2.1 4 0.44 7 +223RA2 G KC=0.26 6$LC=0.132 4$MC=0.0344 8 +223RA G 299.95 5 0.020 4 E1 0.0352 5 +223RA2 G KC=0.0284 4$LC=0.00518 8$MC=1234E-6 18 +223RA G 329.80 5 0.024 5 (E1) 0.0285 4 +223RA2 G KC=0.0230 4$LC=0.00415 6$MC=9.88E-4 14 +223RA L 334.29 4 5/2+ +223RA B 814.9 9 0.042 9 8.43 1U +223RAS B EAV=256.3 4 +223RA G 210.60 5 0.0097 19E1 0.0798 11 +223RA2 G KC=0.0637 9$LC=0.01222 18$MC=0.00292 4 +223RA G 254.6 2 0.0057 12E1 0.0512 7 +223RA2 G KC=0.0411 6$LC=0.00767 11$MC=0.00183 3 +223RA G 272.8 2 0.004 1 M1+E2 0.6 4 +223RA2 G KC=0.4 4$LC=0.112 25$MC=0.028 5 +223RA G 304.40 5 0.0086 17M1+E2(+) 0.26 4 0.647 14 +223RA2 G KC=0.518 12$LC=0.0978 16$MC=0.0234 4 +223RA G 334.30 6 0.0084 17M1+E2 -0.61 4 0.414 13 +223RA2 G KC=0.325 11$LC=0.0674 14$MC=0.0164 3 +223RA L 342.51 4 3/2+ +223RA B 806.7 9 0.037 8 8.47 +223RAS B EAV=253.3 4 +223RA G 262.9 2 0.0035 11E1 0.0475 7 +223RA2 G KC=0.0382 6$LC=0.00709 10$MC=1692E-6 24 +223RA G 280.7 5 3000E-7 0 +223RA G 312.65 5 0.016 4 M1+E2 0.16 3 0.621 10 +223RA2 G KC=0.499 9$LC=0.0924 14$MC=0.0221 4 +223RA G 342.50 7 0.0116 24M1+E2 1.29 2 0.250 5 +223RA2 G KC=0.183 4$LC=0.0501 8$MC=1252E-5 2 +223RA L 350.53 101/2- +223RA G 350.5 2 0.0027 15E1 0.0249 4 +223RA2 G KC=0.0202 3$LC=0.00361 5$MC=8.58E-4 12 +223RA L 369.342 20(5/2)- +223RA B 779.9 9 1.8 4 6.73 2 +223RAS B EAV=243.7 4 +223RA G 89.08 100.054 11 +223RA G 134.60 2 0.5 1 [E1] 0.234 3 +223RA2 G KC=0.184 3$LC=0.0383 6$MC=0.00921 13 +223RA G 245.60 5 0.019 4 +223RA G 289.67 5 0.21000 0 +223RA G 307.93 5 0.0013 13 +223RA G 319.25 5 0.46 9 M1+E2 0.18 3 0.583 10 +223RA2 G KC=0.468 8$LC=0.0869 13$MC=0.0208 3 +223RA G 339.50 5 0.062 13 +223RA G 369.32 5 0.089 18 +223RA L 376.09 15(7/2)- +223RA B 773.1 100.0046 12 9.31 +223RAS B EAV=241.3 4 +223RA G 296.5 2 0.0013 4 M1+E2 -0.13 2 0.723 9 +223RA2 G KC=0.581 9$LC=0.1074 16$MC=0.0257 4 +223RA G 314.6 2 0.0022 7 E1 0.0316 5 +223RA2 G KC=0.0255 4$LC=0.00463 7$MC=1103E-6 16 +223RA L 593.94 6 + +223RA B 555.3 9 0.013 3 8.38 +223RAS B EAV=165.6 4 +223RA G 307.93 5 0.012 3 +223RA G 469.3 2 1000E-6 0 +223RA L 782.54 171/2,3/2+ +223RA B 366.7 100.00111 22 8.85 1U +223RAS B EAV=104.1 3 +223RA G 439.6 3 0.00030 8 +223RA G 452.9 2 8000E-7 0 +223RA L 787.13 5 5/2+ +223RA B 362.1 9 0.019 4 7.6 1U +223RAS B EAV=102.7 3 +223RA G 444.5 3 0.0011 4 +223RA G 452.9 2 8000E-7 0 +223RA G 457.5 2 8000E-7 0 +223RA G 506.9 2 0.0022 7 +223RA G 552.3 2 0.0027 8 +223RA G 663.7 3 0.0011 4 +223RA G 708.3 3 0.0013 4 +223RA G 737.4 3 0.0009 3 +223RA G 757.20 5 0.0076 20 +223RA G 787.6 2 0.0003 3 +223RA L 803.77 3 3/2,5/2+ +223RA B 345.4 9 0.14 3 6.67 +223RAS B EAV=97.5 3 +223RA G 434.4 1 0.0022 7 +223RA G 469.3 2 1000E-6 0 +223RA G 569.03 8 0.049 11 +223RA G 724.15 5 0.014 4 +223RA G 742.4 3 0.0011 4 +223RA G 753.65 5 0.0094 22 +223RA G 803.77 5 0.059 14 +223RA L 805.38 101/2,3/2,5/2+ +223RA B 343.8 9 0.0040 8 8.21 1U +223RAS B EAV=97.0 3 +223RA G 475.4 1 2700E-6 0 +223RA G 806.0 2 0.0013 4 +223RA L 823.22 7 1/2,3/2,5/2+ +223RA B 326.0 9 0.014 3 7.59 1U +223RAS B EAV=91.5 3 +223RA G 480.9 3 0.0013 4 +223RA G 493.4 2 0.0024 7 +223RA G 537.2 2 3200E-6 0 +223RA G 823.20 7 0.0070 16 +223RA L 825.94 4 (3/2)+ +223RA B 323.3 9 0.54 10 5.99 +223RAS B EAV=90.7 3 +223RA G 475.4 1 3000E-6 0 +223RA G 539.8 2 0.0059 18 +223RA G 545.4 4 0.00030 8 +223RA G 746.30 5 0.020 5 +223RA G 775.83 5 0.45 9 +223RA G 825.95 7 0.054 13 +223RA L 842.25 5 3/2,5/2+ +223RA B 306.9 9 0.035 7 7.11 +223RAS B EAV=85.7 3 +223RA G 556.3 3 0.0011 4 +223RA G 607.6 3 0.0022 7 +223RA G 762.6 2 0.0024 7 +223RA G 780.8 1 0.003 1 +223RA G 792.2 3 0.00054 14 +223RA G 812.40 6 0.021 5 +223RA G 842.2 1 0.0049 11 +223RA L 846.37 3 5/2+ +223RA B 302.8 9 0.088 18 6.69 1U +223RAS B EAV=84.4 3 +223RA G 516.7 2 0.0032 8 +223RA G 722.65 5 0.038 9 +223RA G 766.64 5 0.022 5 +223RA G 784.93 5 0.0086 21 +223RA G 796.22 5 0.0108 25 +223RA G 846.85 100.005 3 +223RA L 867.34 6 3/2,5/2+ +223RA B 281.9 9 0.025 5 7.14 +223RAS B EAV=78.1 3 +223RA G 524.8 2 0.0043 12 +223RA G 533.1 3 0.0019 7 +223RA G 537.2 2 1900E-6 0 +223RA G 581.3 4 0.0013 4 +223RA G 632.7 3 0.0022 7 +223RA G 787.6 2 0.0024 7 +223RA G 837.5 1 0.0097 21 +223RA G 867.4 1 0.0016 4 +223RA L 905.9 4 + +223RA B 243.3 100.0011 4 8.29 +223RAS B EAV=66.6 3 +223RA G 576.1 4 0.0011 4 +223RA L 926.56 7 3/2,5/2+ +223RA B 222.6 9 0.106 22 6.18 +223RAS B EAV=60.5 3 +223RA G 592.3 2 0.0032 10 +223RA G 596.9 4 0.0008 3 +223RA G 846.85 100.049 13 +223RA G 876.5 1 0.038 9 +223RA G 896.7 2 0.013 3 +223RA G 926.5 3 0.0016 4 +223RA L 940.78 133/2,5/2- +223RA B 208.4 9 0.0051 12 7.41 +223RAS B EAV=56.3 3 +223RA G 816.5 2 0.0013 4 +223RA G 911.3 3 0.0008 3 +223RA G 941.2 3 0.0030 8 +223RA L 943.26 9 3/2,5/2+ +223RA B 205.9 9 0.0082 18 7.19 +223RAS B EAV=55.6 3 +223RA G 600.7 4 0.00054 14 +223RA G 613.6 4 0.0011 4 +223RA G 863.6 1 0.0038 9 +223RA G 893.1 2 0.0024 7 +223RA G 913.6 3 0.00041 14 +223RA L 957.72 113/2,5/2+ +223RA B 191.5 9 0.020 4 6.7 +223RAS B EAV=51.5 3 +223RA G 671.9 4 0.00054 14 +223RA G 833.9 2 0.0013 4 +223RA G 878.1 2 0.0032 8 +223RA G 907.6 2 0.014 3 +223RA G 958.0 7 0.00035 8 +223RA L 1019.3 4 + +223RA B 129.9 100.00046 12 7.82 +223RAS B EAV=34.1 3 +223RA G 969.2 4 0.00032 8 +223RA G 989.4 5 0.00014 3 +223RA L 1024.59 23 + +223RA B 124.6 100.0004 1 7.82 +223RAS B EAV=32.7 3 +223RA G 975.2 5 0.00016 5 +223RA G 994.3 3 0.00011 3 +223RA G 1025.1 5 0.00014 3 +223RA L 1028.94 25 - +223RA B 120.3 100.0012 3 7.3 +223RAS B EAV=31.5 3 +223RA G 949.3 4 0.00032 8 +223RA G 978.7 4 0.00067 12 +223RA G 999.3 5 0.00019 4 + diff --git a/HEN_HOUSE/spectra/lnhb/Ga-66.txt b/HEN_HOUSE/spectra/lnhb/Ga-66.txt new file mode 100644 index 000000000..07046fed8 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Ga-66.txt @@ -0,0 +1,243 @@ + 66ZN 66GA EC DECAY (9.49 H) + 66ZN T Auger electrons and ^X ray energies and emission intensities: + 66ZN T {U Energy (keV)} {U Intensity } {U Line } + 66ZN T + 66ZN T 8.61587 5.8 3 XKA2 + 66ZN T 8.63896 11.3 6 XKA1 + 66ZN T + 66ZN T 9.5721 |] 2.42 12 XKB1 + 66ZN T 9.6499 |] XKB5II + 66ZN T + 66ZN T 9.6581 |] XKB2 + 66ZN T + 66ZN T 0.884-1.035 0.597 19 XL (total) + 66ZN T 0.884 XLL + 66ZN T -1.035 XLB + 66ZN T + 66ZN T 7.21-7.55 |] KLL AUGER + 66ZN T 8.31-8.63 |] 20.6 10 ^KLX AUGER + 66ZN T 9.39-9.65 |] KXY AUGER + 66ZN T 0.732-0.997 57.2 16 L AUGER + 66GA P 0.0 0+ 9.49 H 7 5175 3 + 66ZN N 1.0 1.0 1 1.0 + 66ZN G 171.9 2 0.0104 9 + 66ZN G 3724.8 100.0024 4 + 66ZN G 3806.3 100.0024 4 + 66ZN G 3827.5 8 0.0069 10 + 66ZN L 0 0+ STABLE + 66ZN E 50 4 0.47 4 7.88 + 66ZN2 E EAV=1904.1 15$CK=0.8850 15$CL=0.0978 12$CM=0.0161 4$CN= $CO= + 66ZN L 1039.2268 212+ 1.65 PS 6 + 66ZN G 1039.220 3 37 3 E2 + 66ZN L 1872.7633 242+ 0.19 PS 7 + 66ZN G 833.5324 215.9 5 M1+E2 -1.6 2 + 66ZN G 1872.740 6 0.0229 24[E2] + 66ZN L 2372.352 4 0+ + 66ZN E 0.30 3 0.038 3 8.46 + 66ZN2 E EAV=781.6 14$CK=0.8847 15$CL=0.0980 12$CM=0.0162 4$CN= $CO= + 66ZN G 499.590 6 0.0048 12E2+M3 + 66ZN G 1333.112 5 1.17 9 E2 + 66ZN L 2780.156 7 2+ 0.26 PS 7 + 66ZN G 907.390 190.0218 23M1+E2 0.13 24 + 66ZN G 1740.904 160.029 4 M1+E2 0.33 28 + 66ZN G 2780.095 160.123 10E2 + 66ZN L 2826.69 5 3- + 66ZN E 0.0053 8 0.0017 3 9.66 3 + 66ZN2 E EAV=575.3 14$CK=0.8846 15$CL=0.0981 12$CM=0.0162 4$CN= $CO= + 66ZN G 953.93 9 0.00100 13 + 66ZN G 1787.44 9 0.0089 10(E1) + 66ZN L 2938.072 3 2+ 0.044 PS 16 + 66ZN G 1065.305 9 0.0023 5 + 66ZN G 1898.823 8 0.39 3 (M1+E2) 0.03 1 + 66ZN L 3105.038 4 0+ + 66ZN G 1232.264 8 0.50 4 + 66ZN G 2065.778 7 0.031 3 + 66ZN L 3212.580 8 2+ + 66ZN G 2173.319 150.084 8 + 66ZN G 3212.499 190.0019 4 + 66ZN L 3228.884 3 1+ 0.12 PS 3 + 66ZN E 3.7 3 3.7 3 6.14 + 66ZN2 E EAV=397.1 14$CK=0.8844 15$CL=0.0982 12$CM=0.0162 4$CN= $CO= + 66ZN G 290.8105 110.049 4 + 66ZN G 448.73 2 0.107 9 M1+E2 -0.02 3 + 66ZN G 856.527 100.111 11 + 66ZN G 1356.104 9 0.36 5 + 66ZN G 2189.616 6 5.3 4 M1+E2 0.12 2 + 66ZN G 3228.800 6 1.51 12M1+E2 + 66ZN L 3331.440 6 2+ 0.083 PS 17 + 66ZN G 551.284 220.0070 8 + 66ZN G 1458.662 120.096 23M1+E2 -0.010 9 + 66ZN G 2292.171 130.0170 18 + 66ZN G 3331.351 140.0023 30 + 66ZN L 3380.942 4 1- + 66ZN E 0.70 6 1.31 116.53 1 + 66ZN2 E EAV=331.1 13$CK=0.8843 15$CL=0.0983 12$CM=0.0162 4$CN= $CO= + 66ZN G 442.873 140.01554 16 + 66ZN G 600.788 210.0135 14 + 66ZN G 1008.588 120.059 9 + 66ZN G 1508.158 7 0.55 4 + 66ZN G 2341.673 110.0032 7 + 66ZN G 3380.850 6 1.46 12 + 66ZN L 3427.404 181,2- + 66ZN E 0.0020 5 0.0047 118.95 1 + 66ZN2 E EAV=311.1 13$CK=0.8843 15$CL=0.0983 12$CM=0.0162 4$CN= $CO= + 66ZN G 1554.62 3 0.0183 18 + 66ZN L 3432.406 4 1- 30 FS 13 + 66ZN E 0.16 2 0.39 4 7.03 1 + 66ZN2 E EAV=308.9 13$CK=0.8843 15$CL=0.0983 12$CM=0.0162 4$CN= $CO= + 66ZN G 494.336 130.0056 9 + 66ZN G 1060.051 110.0155 17 + 66ZN G 1559.627 100.0219 23 + 66ZN G 2393.129 7 0.23 2 E1 + 66ZN G 3432.309 7 0.288 24 + 66ZN L 3507.247 232+ + 66ZN G 680.56 100.0015 4 + 66ZN G 1634.46 7 0.0035 6 + 66ZN G 2467.97 7 0.0084 10 + 66ZN L 3531.691 140+ + 66ZN G 2492.42 3 0.0222 23 + 66ZN L 3576.368 224+ + 66ZN G 749.68 100.0014 4 + 66ZN G 796.21 5 0.0029 7 + 66ZN G 1703.59 5 0.0054 19 + 66ZN G 2537.09 5 0.0051 12 + 66ZN L 3670.72 5 2+ + 66ZN G 1797.94 9 0.0019 5 + 66ZN G 2631.44 9 0.0029 11 + 66ZN L 3738.207 21 + 9.7 FS 25 + 66ZN E 0.0009 3 0.015 6 8.27 + 66ZN2 E EAV=179.2 13$CK=0.8841 15$CL=0.0985 12$CM=0.0163 4$CN= $CO= + 66ZN G 800.13 5 0.0010 5 + 66ZN G 2698.92 5 0.0037 7 + 66ZN G 3738.10 5 0.0138 13 + 66ZN L 3753.01 4 4+ + 66ZN G 2713.73 5 0.0062 19 + 66ZN L 3791.121 3 1+ + 66ZN E 0.94 8 26.0 215 + 66ZN2 E EAV=157.0 13$CK=0.8841 15$CL=0.0985 12$CM=0.0163 4$CN= $CO= + 66ZN G 283.87 3 0.0036 8 + 66ZN G 410.178 120.065 6 + 66ZN G 459.683 140.088 8 + 66ZN G 562.241 100.0066 8 + 66ZN G 578.540 190.059 6 + 66ZN G 686.080 6 0.252 22 + 66ZN G 853.038 8 0.076 6 M1+E2 0.37 18 + 66ZN G 1010.957 190.027 3 + 66ZN G 1418.754 5 0.61 5 + 66ZN G 1918.329 5 1.99 16M1+E2 -0.07 3 + 66ZN G 2751.835 5 22.7 18(M1+E2) + 66ZN G 3791.004 8 1.09 9 M1+E2 + 66ZN L 3825.0 3 0+ + 66ZN E 0.0030 6 8.92 + 66ZN2 E EAV= $CK=0.8840 15$CL=0.0986 12$CM=0.0163 4$CN= $CO= + 66ZN G 2785.7 3 0.0030 6 + 66ZN L 3882.422 10(2)+ + 66ZN E 0.0014 9 9.2 2 + 66ZN2 E EAV= $CK=0.8840 15$CL=0.0986 12$CM=0.0163 4$CN= $CO= + 66ZN G 2009.628 160.0031 7 + 66ZN G 2843.130 160.0017 4 + 66ZN L 4085.982 4 1+ + 66ZN E 1.67 145.99 + 66ZN2 E EAV= $CK=0.8837 15$CL=0.0988 12$CM=0.0163 4$CN= $CO= + 66ZN G 347.77 5 0.0018 6 + 66ZN G 554.28 3 0.0045 6 + 66ZN G 653.568 140.0013 5 + 66ZN G 658.57 3 0.0075 10 + 66ZN G 705.031 150.0038 5 + 66ZN G 857.093 9 0.015 5 + 66ZN G 873.392 210.0170 18 + 66ZN G 980.934 130.048 19 + 66ZN G 1147.896 100.078 9 M1+E2 -0.18 5 + 66ZN G 1305.807 210.0040 5 + 66ZN G 1713.602 120.0243 23 + 66ZN G 2213.181 9 0.131 12M1+E2 -0.23 5 + 66ZN G 3046.684 9 0.057 5 M1+E2 -0.8 2 + 66ZN G 4085.853 9 1.27 10M1+E2 + 66ZN L 4295.337 4 1+ 4.2 FS 13 + 66ZN E 6.2 5 5.23 + 66ZN2 E EAV= $CK=0.8833 15$CL=0.0992 12$CM=0.0164 4$CN= $CO= + 66ZN G 412.916 160.0034 6 + 66ZN G 557.13 5 0.0061 8 M1+E2 + 66ZN G 718.97 5 0.0099 10 + 66ZN G 763.64 3 0.0089 10 + 66ZN G 862.926 130.0152 14 + 66ZN G 867.93 3 0.0043 6 + 66ZN G 914.388 140.027 3 + 66ZN G 963.892 150.0144 16 + 66ZN G 1066.450 120.0024 5 + 66ZN G 1082.75 2 0.0133 13 + 66ZN G 1190.287 7 0.128 13 + 66ZN G 1357.250 120.16 5 M1+E2 -0.18 5 + 66ZN G 1515.162 200.0062 7 + 66ZN G 2422.525 7 1.88 15M1+E2 0.01 3 + 66ZN G 3256.021 9 0.094 8 M1+E2 1.5 2 + 66ZN G 4295.187 103.8 3 + 66ZN L 4461.370 5 1+ 7.0 FS 7 + 66ZN E 1.96 175.54 + 66ZN2 E EAV= $CK=0.8828 15$CL=0.0996 12$CM=0.0165 4$CN= $CO= + 66ZN G 375.398 170.0021 6 + 66ZN G 670.251 140.0041 7 + 66ZN G 708.36 5 0.0087 10 + 66ZN G 723.17 5 0.0034 6 + 66ZN G 885.00 5 0.0019 5 + 66ZN G 929.68 3 0.0046 7 + 66ZN G 954.12 7 0.0045 7 + 66ZN G 1129.923 180.0136 13 + 66ZN G 1232.480 150.056 19 + 66ZN G 1248.779 220.0010 3 + 66ZN G 1356.320 150.122 21 + 66ZN G 1523.279 150.0055 7 + 66ZN G 2088.985 130.011 3 + 66ZN G 2588.553 130.0263 26M1+E2 0.35 27 + 66ZN G 3422.040 8 0.86 7 M1+E2 -0.06 2 + 66ZN G 4461.202 9 0.84 7 + 66ZN L 4638.24 141+ + 66ZN E 0.0042 107.96 + 66ZN2 E EAV= $CK=0.8820 15$CL=0.1003 12$CM=0.0166 4$CN= $CO= + 66ZN G 1106.53 240.0012 4 + 66ZN G 1409.35 240.0016 7 + 66ZN G 2265.84 240.0014 5 + 66ZN L 4675.6 5 1+ + 66ZN E 0.0015 5 8.35 + 66ZN2 E EAV= $CK=0.8817 15$CL=0.1005 12$CM=0.0166 4$CN= $CO= + 66ZN G 2802.8 5 0.0015 4 + 66ZN L 4806.197 5 1+ 3.8 FS 10 + 66ZN E 2.27 194.9 + 66ZN2 E EAV= $CK=0.8804 15$CL=0.1016 13$CM=0.0169 4$CN= $CO= + 66ZN G 1015.081 180.012 3 + 66ZN G 1135.47 9 0.0047 6 + 66ZN G 1274.50 3 0.0070 8 + 66ZN G 1298.95 7 0.0038 5 + 66ZN G 1425.25 2 0.0060 7 + 66ZN G 1577.308 200.0040 7 + 66ZN G 1868.105 200.0027 6 + 66ZN G 2026.016 250.0026 6 + 66ZN G 2433.807 180.0074 9 + 66ZN G 2933.358 9 0.213 17M1+E2 1.6 2 + 66ZN G 3766.850 9 0.149 13M1+E2 0.11 4 + 66ZN G 4806.007 9 1.86 15 + 66ZN L 4849.93 3 1+ + 66ZN E 0.033 4 6.62 + 66ZN2 E EAV= $CK=0.8797 15$CL=0.1021 13$CM=0.0170 5$CN= $CO= + 66ZN G 1468.97 5 0.0014 4 + 66ZN G 2977.08 4 0.023 3 + 66ZN G 3810.59 5 0.0092 11 + 66ZN L 4866.054 161+ + 66ZN E 0.047 6 6.42 + 66ZN2 E EAV= $CK=0.8794 15$CL=0.1024 13$CM=0.0170 5$CN= $CO= + 66ZN G 1195.32 9 0.0009 3 + 66ZN G 1433.63 4 0.0018 4 + 66ZN G 1534.60 4 0.0057 16 + 66ZN G 1927.96 4 0.0022 8 + 66ZN G 2085.86 4 0.0021 15 + 66ZN G 2993.21 3 0.031 4 + 66ZN G 4865.87 4 0.0028 3 + 66ZN L 4958.2 4 1+ + 66ZN E 0.0020 5 7.48 + 66ZN2 E EAV= $CK=0.8768 16$CL=0.1046 13$CM=0.0174 5$CN= $CO= + 66ZN G 3085.4 4 0.0020 5 + 66ZN L 5005.8 3 1+ + 66ZN E 0.00122 157.47 + 66ZN2 E EAV= $CK=0.8742 16$CL=0.1067 13$CM=0.0178 5$CN= $CO= + 66ZN G 5005.6 3 0.00124 18 + diff --git a/HEN_HOUSE/spectra/lnhb/Ga-67.txt b/HEN_HOUSE/spectra/lnhb/Ga-67.txt new file mode 100644 index 000000000..5033f17d3 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Ga-67.txt @@ -0,0 +1,76 @@ + 67ZN 67GA EC DECAY (3.2613 D) + 67ZN H TYP=Ajout$AUT=mmbe$CUT= -- $ + 67ZN2 H TYP=Correction$AUT=mmbe$CUT= -- $ + 67ZN3 H TYP=Hist.$AUT=mmbe$CUT= -- $ + 67ZN C Evaluation history: Type=Ajout;Author=mmbe;Cutoff date= -- + 67ZN2C Type=Correction;Author=mmbe;Cutoff date= -- + 67ZN3C Type=Hist.;Author=mmbe;Cutoff date= -- + 67ZN C References: 1938AL02, 1938MA01, 1948MC32, 1948HO04, 1950HO26, 1953ME52, + 67ZN2C 1955TO27, 1957BU39, 1958CH08, 1961HO05, 1962RI09, 1964RU06, 1964AL28, + 67ZN3C 1966FR12, 1967BE65, 1968LI02, 1967VR03, 1969RA15, 1969LI04, 1969IV02, + 67ZN4C 1969BO41, 1971SU18, 1972CR02, 1972EN08, 1972LE37, 1973BA54, 1973LE18, + 67ZN5C 1974HEYW, 1974AR22, 1974NI01, 1975TH01, 1975WE08, 1975RO25, 1977La19, + 67ZN6C 1977AB02, 1978LA21, 1978DU04, 1978ME10, 1978LO06, 1979DE42, 1980HO17, + 67ZN7C 1982HOZJ, 1988BE55, 1990ME15, 1991BH06, 1992UN01, 1996HW03, 1996SC06, + 67ZN8C 1998AT04, 2000SI03, 2002UN02, 2003AU03, 2003AU02, 2004SC04, 2004DA05, + 67ZN9C 2005YA01, 2005HU18, 2008MO18, 2008KI07 + 67ZN T Auger electrons and ^X ray energies and emission intensities: + 67ZN T {U Energy (keV)} {U Intensity } {U Line } + 67ZN T + 67ZN T 8.61587 17.0 6 XKA2 + 67ZN T 8.63896 33.0 12 XKA1 + 67ZN T + 67ZN T 9.5721 |] 7.08 26 XKB1 + 67ZN T 9.6499 |] XKB5II + 67ZN T + 67ZN T 9.6581 |] XKB2 + 67ZN T + 67ZN T 0.8836-1.1861 1.75 5 XL (total) + 67ZN T 0.8836 0.0504 18 XLL + 67ZN T 1.0119-1.0122 0.97 3 XLA + 67ZN T 0.9065 0.0328 13 XLC + 67ZN T 1.02044-1.1861 0.700 26 XLB + 67ZN T 1.04333-1.04333 0.00228 17 XLG + 67ZN T + 67ZN T 7.21-7.55 |] KLL AUGER + 67ZN T 8.31-8.63 |] 60.4 21 ^KLX AUGER + 67ZN T 9.39-9.65 |] KXY AUGER + 67ZN T 0.732-0.997 167.5 21 L AUGER + 67GA P 0.0 3/2- 3.2613 D 5 1000.8 12 + 67ZN N 1.0 1.0 1 1.0 + 67ZN L 0 5/2- STABLE + 67ZN E 3.3 326.532 2 + 67ZN2 E EAV= $CK=0.8836 15$CL=0.0989 12$CM=0.0164 4$CN=0.0011 1$CO=0 0 + 67ZN L 93.31 1/2- 9.00 US 4 + 67ZN E 50.5 175.261 2 + 67ZN2 E EAV= $CK=0.8834 15$CL=0.0991 12$CM=0.0164 4$CN=0.0011 1$CO= + 67ZN G 93.307 1238.1 7 E2 0.854 12 + 67ZN2 G KC=0.748 11$LC=0.0922 13$MC=0.01300 19 + 67ZN L 184.58 3/2- 1.028 NS 14 + 67ZN E 22.3 275.523 + 67ZN2 E EAV= $CK=0.8832 15$CL=0.0993 12$CM=0.0164 4$CN=0.0011 1$CO= + 67ZN G 91.263 153.09 7 M1+()E2 0.123 25 0.091 6 + 67ZN2 G KC=0.081 5$LC=0.0087 7$MC=0.00125 9 + 67ZN G 184.577 1720.96 44M1+()E2 0.31 7 0.0169 21 + 67ZN2 G KC=0.0151 19$LC=0.00158 20$MC=0.00023 3 + 67ZN L 393.53 3/2- + 67ZN E 23.60 475.239 + 67ZN2 E EAV= $CK=0.8824 15$CL=0.0999 12$CM=0.0165 4$CN=0.0011 1$CO= + 67ZN G 208.939 152.37 5 M1+()E2 0.042 17 0.0090114 + 67ZN2 G KC=0.00806 13$LC=8.27E-4 13$MC=1186E-7 19 + 67ZN G 300.232 2116.60 37M1+()E2 0.178 10 0.003886 + 67ZN2 G KC=0.00348 6$LC=3.54E-4 6$MC=5.08E-5 8 + 67ZN G 393.528 204.59 10M1+()E2 0.051 16 0.001933 + 67ZN2 G KC=1728E-6 25$LC=1748E-7 25$MC=2.51E-5 4 + 67ZN L 887.69 5/2- + 67ZN E 0.280 8 5.648 2 + 67ZN2 E EAV= $CK=0.8680 17$CL=0.1119 14$CM=0.0188 5$CN=0.0013 1$CO= + 67ZN G 494.143 280.0666 29M1+()E2 0.110 34 1149E-618 + 67ZN2 G KC=1030E-6 16$LC=1038E-7 17$MC=1488E-8 24 + 67ZN G 703.11 8 0.0113 9 M1+()E2 0.090 28 5.24E-48 + 67ZN2 G KC=4.70E-4 7$LC=4.70E-5 7$MC=6.74E-6 10 + 67ZN G 794.400 410.0528 17E2+()M3 0.09 11 0.000546 + 67ZN2 G KC=0.00048 5$LC=4.9E-5 6$MC=7.0E-6 8 + 67ZN G 887.676 330.1492 38M1+()E2 0.95 9 3.54E-47 + 67ZN2 G KC=3.18E-4 6$LC=3.18E-5 6$MC=4.56E-6 8 + diff --git a/HEN_HOUSE/spectra/lnhb/Ga-68.txt b/HEN_HOUSE/spectra/lnhb/Ga-68.txt new file mode 100644 index 000000000..78092fd22 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Ga-68.txt @@ -0,0 +1,77 @@ + 68ZN 68GA EC DECAY (67.83 M) + 68ZN H TYP=Full$AUT=M.-M. Bé$CUT=30-NOV-2011$ + 68ZN2 H TYP=Full$AUT=E.Schonfeld$CUT= -- $ + 68ZN C Evaluation history: Type=Full;Author=M.-M. Bé;Cutoff date=30-NOV-2011 + 68ZN2C Type=Full;Author=E.Schonfeld;Cutoff date= -- + 68ZN C References: 1956Cr29, 1959Ho85, 1959Ra04, 1959Ho85, 1960Ra22, 1965Bo42, + 68ZN2C 1965Eb01, 1968Ca15, 1969Va16, 1971Oo01, 1971Sm02, 1972Sl03, 1973La01, + 68ZN3C 1977Kr17, 1983Iw02, 1992Sy**, 1994Vo15, 1994Sc44, 2003Au03, 2012Lu14 + 68ZN T Auger electrons and ^X ray energies and emission intensities: + 68ZN T {U Energy (keV)} {U Intensity } {U Line } + 68ZN T + 68ZN T 8.61587 1.42 6 XKA2 + 68ZN T 8.63896 2.76 11 XKA1 + 68ZN T + 68ZN T 9.5721 |] 0.593 24 XKB1 + 68ZN T 9.6499 |] XKB5II + 68ZN T + 68ZN T + 68ZN T 0.884-1.186 0.146 4 XL (total) + 68ZN T 0.884 0.00421 16 XLL + 68ZN T 1.012-1.012 0.0807 28 XLA + 68ZN T 0.906 0.00273 11 XLC + 68ZN T 1.02-1.186 0.0584 23 XLB + 68ZN T 1.043-1.043 0.000190 14 XLG + 68ZN T + 68ZN T 7.21-7.55 |] KLL AUGER + 68ZN T 8.31-8.63 |] 5.05 20 ^KLX AUGER + 68ZN T 9.39-9.65 |] KXY AUGER + 68ZN T 0.732-0.997 13.98 19 L AUGER + 68GA P 0.0 1+ 67.83 M 20 2921.1 12 + 68ZN N 1.0 1.0 1 1.0 + 68ZN L 0 0+ STABLE + 68ZN E 87.68 418.94 415.2 + 68ZN2 E EAV=836.0 6$CK=0.8847 15$CL=0.0980 12$CM=0.0162 4$CN=0.0011 1$CO=0 0 + 68ZN L 1077.35 5 2+ 1.57 PS 4 + 68ZN E 1.20 4 1.80 5 5.5 + 68ZN2 E EAV=352.6 6$CK=0.8844 15$CL=0.0983 14$CM=0.0162 5$CN= $CO= + 68ZN G 1077.34 5 3.235 30E2 2.47E-44 + 68ZN2 G KC=2.21E-4 4$LC=2.22E-5 4$MC=3.18E-6 5 + 68ZN L 1655.87 140+ 70 PS 35 + 68ZN E 0.00026 2 0.0335 236.9 + 68ZN2 E EAV=107.6 6$CK=0.8839 15$CL=0.0986 14$CM=0.0163 5$CN= $CO= + 68ZN G 1655.87 14 + 68ZN G 578.52 130.0343 23E2 1272E-618 + 68ZN2 G KC=1139E-6 16$LC=1160E-7 17$MC=1.66E-5 3 + 68ZN L 1883.19 6 2+ 1.6 PS 3 + 68ZN E 0.234 5 5.9 + 68ZN2 E EAV= $CK=0.8836 15$CL=0.0989 14$CM=0.0164 5$CN= $CO= + 68ZN G 227.31 151.20E-4 49E2 0.0300 5 + 68ZN2 G KC=0.0268 4$LC=0.00286 4$MC=4.06E-4 6 + 68ZN G 805.83 8 0.0928 27M1+()E2 -1.53 5 4.70E-47 + 68ZN2 G KC=4.21E-4 6$LC=4.24E-5 7$MC=6.07E-6 9 + 68ZN G 1883.16 6 0.1420 35E2 3.33E-45 + 68ZN2 G KC=6.97E-5 10$LC=6.91E-6 10$MC=9.9E-7 2 + 68ZN L 2338.44 8 2+ 0.24 PS + 68ZN E 0.096 3 5.7 + 68ZN2 E EAV= $CK=0.8823 16$CL=0.1000 15$CM=0.0166 5$CN= $CO= + 68ZN G 682.57 163.14E-4 20E2 7.89E-411 + 68ZN2 G KC=7.07E-4 10$LC=7.16E-5 10$MC=1.03E-5 2 + 68ZN G 1261.08 9 0.0954 21M1+()E2 -0.15 2 1725E-725 + 68ZN2 G KC=1418E-7 20$LC=1409E-8 20$MC=2.02E-6 3 + 68ZN G 2338.44 8 0.00113 16E2 5.29E-48 + 68ZN2 G KC=4.71E-5 7$LC=4.67E-6 7$MC=6.7E-7 1 + 68ZN L 2821.79 142+ + 68ZN E 0.0104 5 5.1 + 68ZN2 E EAV= $CK=0.8653 18$CL=0.1141 17$CM=0.0192 5$CN= $CO= + 68ZN G 483.35 162.65E-4 29M1+()E2 1.0 5 0.0017 3 + 68ZN2 G KC=0.0015 3$LC=0.00016 3$MC=2.2E-5 4 + 68ZN G 938.61 201.78E-4 16M1+()E2 -0.7 3 3.04E-412 + 68ZN2 G KC=2.72E-4 11$LC=2.72E-5 11$MC=3.9E-6 2 + 68ZN G 1165.92 151.6E-5 10E2 2.11E-43 + 68ZN2 G KC=1.85E-4 3$LC=1.85E-5 3$MC=2.65E-6 4 + 68ZN G 1744.42 130.0096 5 M1+()E2 0.272 18 2.41E-44 + 68ZN2 G KC=7.70E-5 11$LC=7.63E-6 11$MC=1.09E-6 2 + 68ZN G 2821.73 144.66E-4 36E2 7.40E-411 + 68ZN2 G KC=3.43E-5 5$LC=3.39E-6 5$MC=4.86E-7 7 + diff --git a/HEN_HOUSE/spectra/lnhb/Gd-153.txt b/HEN_HOUSE/spectra/lnhb/Gd-153.txt new file mode 100644 index 000000000..4bc073d6d --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Gd-153.txt @@ -0,0 +1,67 @@ +153EU 153GD EC DECAY (240.4 D) +153EU H TYP=Update$AUT=M.M. Bé$CUT=15-NOV-2011$ +153EU2 H TYP=Full$AUT=R.G. Helmer$CUT=30-JUN-2001$ +153EU C Evaluation history: Type=Update;Author=M.M. Bé;Cutoff date=15-NOV-2011 +153EU2C Type=Full;Author=R.G. Helmer;Cutoff date=30-JUN-2001 +153EU C References: 2002Ba85, 2008Ki07 +153EU T Auger electrons and ^X ray energies and emission intensities: +153EU T {U Energy (keV)} {U Intensity } {U Line } +153EU T +153EU T 40.9024 34.2 9 XKA2 +153EU T 41.5427 61.7 16 XKA1 +153EU T +153EU T 46.904 |] XKB3 +153EU T 47.0384 |] 19.4 6 XKB1 +153EU T 47.373 |] XKB5II +153EU T +153EU T 48.257 |] XKB2 +153EU T 48.386 |] 5.01 17 XKB4 +153EU T 48.497 |] XKO23 +153EU T +153EU T 5.1751-7.791 20.1 5 XL (total) +153EU T 5.1751 0.413 14 XLL +153EU T 5.815-5.8461 10.07 30 XLA +153EU T 5.8149 0.156 5 XLC +153EU T 6.4365-6.9193 8.24 20 XLB +153EU T 7.2538-7.791 1.27 4 XLG +153EU T +153EU T 32.25-34.38 |] KLL AUGER +153EU T 38.59-41.27 |] 9.2 6 ^KLX AUGER +153EU T 44.9-48.2 |] KXY AUGER +153EU T 3.4-7.8 98.4 9 L AUGER +153GD P 0.0 3/2- 240.4 D 10 484.0 7 +153EU N 1.0 1.0 1 1.0 +153EU L 0 5/2+ STABLE +153EU E 4 3 8.9 1U +153EU2 E EAV= $CK=0.8192 17$CL=0.1392 15$CM=0.0324 8$CN= $CO= +153EU L 83.36720 177/2+ 0.77 NS +153EU E 0.05 7 3U +153EU2 E EAV= $CK= $CL= $CM= $CN= $CO= +153EU G 83.36717 210.197 7 M1+E2 0.81 4 3.76 7 +153EU2 G KC=2.33 4$LC=1.11 5$MC=0.257 12 +153EU L 97.43103 175/2- 0.18 NS +153EU E 38.0 117.7 2 +153EU2 E EAV= $CK=0.8116 18$CL=0.1448 16$CM=0.034 8$CN= $CO= +153EU G 14.06383 200.020 5 E1 10.89 16 +153EU2 G KC=$LC=8.54 12$MC=1.90 3 +153EU G 97.43100 2129.0 8 E1 0.305 5 +153EU2 G KC=0.256 4$LC=0.0382 6$MC=0.00823 12 +153EU L 103.18016 133/2+ 3.88 NS +153EU E 42.0 187.7 +153EU2 E EAV= $CK=0.8111 18$CL=0.1452 16$CM=0.0341 8$CN= $CO= +153EU G 19.81296 191400E-7 0 E2 3220 50 +153EU2 G KC=$LC=2490 40$MC=578 8 +153EU G 103.18012 1721.1 6 M1+E2 0.119 3 1.694 24 +153EU2 G KC=1.422 20$LC=0.213 3$MC=0.0462 7 +153EU L 172.85320 135/2+ +153EU E 15.7 6 7.9 1U +153EU2 E EAV= $CK=0.8019 19$CL=0.1519 4$CM=0.0359 9$CN= $CO= +153EU G 69.67300 132.42 7 M1+E2 0.136 4 5.31 8 +153EU2 G KC=4.39 7$LC=0.719 12$MC=0.1572 25 +153EU G 75.42213 230.078 3 E1+M2 0.055 10 0.76 7 +153EU2 G KC=0.62 5$LC=0.112 13$MC=0.025 3 +153EU G 89.48595 220.069 5 M1+E2 0.25 10 2.60 7 +153EU2 G KC=2.11 5$LC=0.38 7$MC=0.085 16 +153EU G 172.85307 210.036 2 M1+E2 0.81 8 0.377 6 +153EU2 G KC=0.296 7$LC=0.0637 22$MC=0.0142 6 + diff --git a/HEN_HOUSE/spectra/lnhb/Gd-159.txt b/HEN_HOUSE/spectra/lnhb/Gd-159.txt new file mode 100644 index 000000000..a210cd754 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Gd-159.txt @@ -0,0 +1,95 @@ +159TB 159GD B- DECAY (18.479 H) +159TB H TYP=Update$AUT=M.M.Bé$CUT= -- $ +159TB2 H TYP=Full$AUT=R.G.Helmer$CUT=30-APR-2004$ +159TB C Evaluation history: Type=Update;Author=M.M.Bé;Cutoff date= -- +159TB2C Type=Full;Author=R.G.Helmer;Cutoff date=30-APR-2004 +159TB T Auger electrons and ^X ray energies and emission intensities: +159TB T {U Energy (keV)} {U Intensity } {U Line } +159TB T +159TB T 43.7447 6.09 25 XKA2 +159TB T 44.4821 10.9 5 XKA1 +159TB T +159TB T 50.23 |] XKB3 +159TB T 50.383 |] 3.49 15 XKB1 +159TB T +159TB T 51.724 |] XKB2 +159TB T 51.849 |] 0.90 5 XKB4 +159TB T +159TB T +159TB T 34.398-36.773 |] KLL AUGER +159TB T 41.243-44.456 |] 1.49 11 ^KLX AUGER +159TB T 48.06-51.95 |] KXY AUGER +159TB T 3.58-8.7 0.195 5 L AUGER +159GD P 0.0 3/2- 18.479 H 7 970.5 7 +159TB N 1.0 1.0 1 1.0 +159TB L 0 3/2+ STABLE +159TB B 970.5 7 57.8 12 6.73 +159TBS B EAV=326.9 3 +159TB L 57.9963 145/2+ 53.6 PS 14 +159TB B 912.5 7 29.6 12 6.99 1U +159TBS B EAV=304.1 3 +159TB G 58.0000 222.49 7 M1+E2 0.119 2 11.1 3 +159TB2 G KC=9.14 27$LC=1.55 5$MC=0.343 10 +159TB L 137.5054 177/2+ 41.4 PS 23 +159TB B 833.0 7 0.012 9 10.6 3U +159TBS B EAV=283.9 3 +159TB G 79.5132 270.0468 11M1+E2 0.126 8 4.41 13 +159TB2 G KC=3.66 11$LC=0.584 18$MC=0.129 4 +159TB G 137.515 5 0.00648 15[E2] 0.833 25 +159TB2 G KC=0.474 14$LC=0.277 8$MC=0.0653 19 +159TB L 348.2830 155/2+ +159TB B 622.2 7 0.315 4 8.39 1U +159TBS B EAV=194.5 3 +159TB G 210.783 3 0.0200 14[M1E2] 0.23 7 +159TB2 G KC=0.18 3$LC=0.039 7$MC=0.0089 16 +159TB G 290.2865 250.0323 5 [M1E2] 0.093 29 +159TB2 G KC=0.075 23$LC=0.014 1$MC=0.0031 1 +159TB G 348.2807 180.2393 25M1+E2 0.43 0.067 2 +159TB2 G KC=0.056 2$LC=0.0084 3$MC=0.00180 5 +159TB L 363.5451 145/2- 15.2 PS 5 +159TB B 607.0 7 12.19 6 6.76 2 +159TBS B EAV=189.0 3 +159TB G 226.0406 180.2170 21E1 0.0343 10 +159TB2 G KC=0.0290 9$LC=0.00414 12$MC=0.00089 3 +159TB G 305.5492 200.0620 7 E1 0.0159 5 +159TB2 G KC=0.0135 4$LC=0.00189 6$MC=4.11E-4 12 +159TB G 363.5430 1811.78 5 E1 0.0104 3 +159TB2 G KC=0.00882 26$LC=0.00123 4$MC=2.66E-4 8 +159TB L 580.808 6 1/2+ 0.76 PS 10 +159TB B 389.7 7 0.0626 8 8.41 1U +159TBS B EAV=113.8 2 +159TB G 580.808 6 0.0693 7 [M1E2] 0.015 5 +159TB2 G KC=0.012 4$LC=0.0018 6$MC= +159TB L 617.619 5 3/2+ +159TB B 352.9 7 0.0300 9 8.58 +159TBS B EAV=101.84 23 +159TB G 559.623 6 0.0221 6 M1+E2 0.67 0.019 3 +159TB2 G KC=0.0152 5$LC=0.0022 2$MC=0.00040 9 +159TB G 617.615 8 0.0159 5 (M1) 0.0166 5 +159TB2 G KC=0.0141 4$LC=0.00196 6$MC=0.00043 2 +159TB L 674.235 175/2+ +159TB B 296.3 7 0.00388 10 9.22 1U +159TBS B EAV=83.82 22 +159TB G 536.730 120.00160 5 M1+E2 0.0236 7 +159TB2 G KC=0.0200 6$LC=0.00280 8$MC=0.00061 2 +159TB G 616.233 180.00188 8 (M1) 0.0167 5 +159TB2 G KC=0.0142 4$LC=0.00197 6$MC=0.00042 2 +159TB G 674.26 5 3.16E-4 22(M1) 0.0133 4 +159TB2 G KC=0.0113 3$LC=0.00157 5$MC=0.00034 1 +159TB L 854.960 7 (1/2)- +159TB B 115.5 7 0.0162 5 7.31 2 +159TBS B EAV=30.43 20 +159TB G 237.341 5 0.00769 16[E1] 0.0302 9 +159TB2 G KC=0.0256 8$LC=0.00364 11$MC=0.00079 2 +159TB G 274.163 190.0057 4 [E1] 0.0209 6 +159TB2 G KC=0.0177 5$LC=0.00250 8$MC=0.00054 2 +159TB G 854.947 200.00246 14[E1] 0.001625 +159TB2 G KC=0.00138 4$LC=1.83E-4 5$MC=4.0E-5 1 +159TB L 891.25 6 (5/2)- +159TB B 79.3 7 0.0009 4 8.08 2 +159TBS B EAV=20.54 19 +159TB G 273.62 120.0007 4 [E1] 0.0210 6 +159TB2 G KC=0.0178 5$LC=0.00251 8$MC=0.00055 2 +159TB G 753.74 6 0.00018 2 [E1] 0.002076 +159TB2 G KC=0.00177 5$LC=2.36E-4 7$MC=5.1E-5 2 + diff --git a/HEN_HOUSE/spectra/lnhb/Ge-68.txt b/HEN_HOUSE/spectra/lnhb/Ge-68.txt new file mode 100644 index 000000000..8f9fedbc2 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Ge-68.txt @@ -0,0 +1,37 @@ + 68GA 68GE EC DECAY (270.95 D) + 68GA H TYP=Update$AUT=M.M Bé$CUT=30-NOV-2011$ + 68GA2 H TYP=Full$AUT=E.Schönfeld$CUT= -- $ + 68GA C Evaluation history: Type=Update;Author=M.M Bé;Cutoff date=30-NOV-2011 + 68GA2C Type=Full;Author=E.Schönfeld;Cutoff date= -- + 68GA C References: 1950Ho26, 1956Ru45, 1956Cr25, 1981Wa26, 1994Sc44, 2002Bu29, + 68GA2C 2003Au03 + 68GA T Auger electrons and ^X ray energies and emission intensities: + 68GA T {U Energy (keV)} {U Intensity } {U Line } + 68GA T + 68GA T 9.22495 13.25 13 XKA2 + 68GA T 9.25184 25.74 22 XKA1 + 68GA T + 68GA T 10.2605 |] XKB3 + 68GA T 10.2644 |] 5.65 7 XKB1 + 68GA T 10.348 |] XKB5II + 68GA T + 68GA T 10.3664 |] XKB2 + 68GA T |] 0.034 9 XKB4 + 68GA T + 68GA T 0.959-1.303 1.490 24 XL (total) + 68GA T 0.959 0.0414 10 XLL + 68GA T 1.098-1.099 0.851 18 XLA + 68GA T 0.985 0.0244 7 XLC + 68GA T 1.114-1.283 0.571 16 XLB + 68GA T 1.141-1.303 0.00211 13 XLG + 68GA T + 68GA T 7.708-8.069 |] KLL AUGER + 68GA T 8.889-9.251 |] 41.7 4 ^KLX AUGER + 68GA T 10.051-10.366 |] KXY AUGER + 68GA T 0.8-1.3 121.8 7 L AUGER + 68GE P 0.0 0+ 270.95 D 26 106.9 24 + 68GA N 1.0 1.0 1 1.0 + 68GA L 0 1+ 67.83 M 20 + 68GA E 100 5.006 + 68GA2 E EAV= $CK=0.8639 24$CL=0.1150 23$CM=0.0196 5$CN=0.0015 2$CO=0 0 + diff --git a/HEN_HOUSE/spectra/lnhb/H-3.txt b/HEN_HOUSE/spectra/lnhb/H-3.txt new file mode 100644 index 000000000..17e9caf0b --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/H-3.txt @@ -0,0 +1,13 @@ + 3HE 3H B- DECAY (12.312 Y) + 3HE H TYP=Full$AUT=V. Chechev$CUT=01-JUN-1998$ + 3HE2 H TYP=Update$AUT=V. Chechev$CUT=01-MAY-1998$ + 3HE C Evaluation history: Type=Full;Author=V. Chechev;Cutoff date=01-JUN-1998 + 3HE2C Type=Update;Author=V. Chechev;Cutoff date=01-MAY-1998 + 3HE C References: 2000Lu17, 2002Bo31, 2003Lo10, 2003Au03, 2004Ak16, 2005Ak04, + 3HE2C 2005Kr03 + 3H P 0.0 1/2+ 12.312 Y 25 18.591 1 + 3HE N 1.0 1.0 1 1.0 + 3HE L 0 1/2+ STABLE + 3HE B 18.564 2 100 3.05 + 3HES B EAV=5.68 1 + diff --git a/HEN_HOUSE/spectra/lnhb/Hg-203.txt b/HEN_HOUSE/spectra/lnhb/Hg-203.txt new file mode 100644 index 000000000..0b45c4426 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Hg-203.txt @@ -0,0 +1,37 @@ +203TL 203HG B- DECAY (46.594 D) +203TL T Auger electrons and ^X ray energies and emission intensities: +203TL T {U Energy (keV)} {U Intensity } {U Line } +203TL T +203TL T 70.8325 3.75 4 XKA2 +203TL T 72.8725 6.33 6 XKA1 +203TL T +203TL T 82.118 |] XKB3 +203TL T 82.577 |] 2.15 4 XKB1 +203TL T 83.115 |] XKB5II +203TL T +203TL T 84.838 |] XKB2 +203TL T 85.134 |] 0.639 16 XKB4 +203TL T 85.444 |] XKO23 +203TL T +203TL T 8.953-14.738 5.43 9 XL (total) +203TL T 8.953 0.126 4 XLL +203TL T 10.172-10.268 2.43 7 XLA +203TL T 10.994 0.0457 12 XLC +203TL T 11.812-12.643 2.37 7 XLB +203TL T 14.291-14.738 0.435 11 XLG +203TL T +203TL T 54.587-59.954 |] KLL AUGER +203TL T 66.37-72.86 |] 0.49 6 ^KLX AUGER +203TL T 78.12-85.5 |] KXY AUGER +203TL T 5.18-15.31 10.1 1 L AUGER +203HG P 0.0 5/2- 46.594 D 12 491.8 12 +203TL N 1.0 1.0 1 1.0 +203TL L 0 1/2+ STABLE +203TL B 491.8 120.01 1 11.6 3U +203TLS B EAV=154.4 4 +203TL L 279.1969 123/2+ +203TL B 212.6 1299.99 1 6.455 1U +203TLS B EAV=57.8 4 +203TL G 279.1952 1081.48 8 M1+E2 1.73 50 0.2271 12 +203TL2 G KC=0.1640 1$LC=0.0476 2$MC=0.0155 2 + diff --git a/HEN_HOUSE/spectra/lnhb/Hg-206.txt b/HEN_HOUSE/spectra/lnhb/Hg-206.txt new file mode 100644 index 000000000..63f1ab1c7 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Hg-206.txt @@ -0,0 +1,55 @@ +206TL 206HG B- DECAY (8.32 M) +206TL H TYP=Full$AUT=F. Kondev$CUT=31-DEC-2010$ +206TL C Evaluation history: Type=Full;Author=F. Kondev;Cutoff date=31-DEC-2010 +206TL C References: 1961Nu01, 1968Wo08, 1969La18, 1970As05, 1969La18, 1976TuZY, +206TL2C 1977La19, 1992Ra08, 1994Ka08, 1996Sc06, 1998Si17, 1998ScZM, 1999ScZX, +206TL3C 1999Br39, 2000Sc47, 2002Ba85, 2003Au03, 2003De44, 2004Ma11, 2008Ki07, +206TL4C 2008Ko21, 2008DuZX +206TL T Auger electrons and ^X ray energies and emission intensities: +206TL T {U Energy (keV)} {U Intensity } {U Line } +206TL T +206TL T 70.8325 2.3 5 XKA2 +206TL T 72.8725 3.9 8 XKA1 +206TL T +206TL T 82.118 |] XKB3 +206TL T 82.577 |] 1.32 25 XKB1 +206TL T 83.115 |] XKB5II +206TL T +206TL T 84.838 |] XKB2 +206TL T 85.134 |] 0.39 8 XKB4 +206TL T 85.444 |] XKO23 +206TL T +206TL T 8.9531-14.7362 2.9 4 XL (total) +206TL T 8.9531 0.072 11 XLL +206TL T 10.1718-10.2679 1.39 19 XLA +206TL T 10.9942 0.022 4 XLC +206TL T 11.8117-12.9566 1.23 15 XLB +206TL T 13.8528-14.7362 0.23 3 XLG +206TL T +206TL T 54.587-59.954 |] KLL AUGER +206TL T 66.37-72.86 |] 0.30 7 ^KLX AUGER +206TL T 78.12-85.5 |] KXY AUGER +206TL T 5.25-15.32 5.1 4 L AUGER +206HG P 0.0 0+ 8.32 M 7 1308 20 +206TL N 1.0 1.0 1 1.0 +206TL L 0 0 0- STABLE +206TL B 1308 2062 7 5.67 +206TLS B EAV=450 8 +206TL L 265.832 5 2- 2.29 NS 14 +206TL G 265.832 5 0.012 6 E2 0.1603 23 +206TL2 G KC=0.0855 12$LC=0.0561 8$MC=0.01440 21 +206TL L 304.896 6 1- 4.2 PS 14 +206TL B 1003 2035 7 5.24 1 +206TLS B EAV=330 8 +206TL G 304.896 6 26 5 M1 0.375 6 +206TL2 G KC=0.308 5$LC=0.0519 8$MC=0.01211 17 +206TL L 649.42 4 1- +206TL B 659 203.0 4 5.41 1 +206TLS B EAV=203 7 +206TL G 344.52 170.55 11M1 0.269 4 +206TL2 G KC=0.221 4$LC=0.0371 6$MC=0.00866 13 +206TL G 383.59 6 0.012 6 M1(+E2) 0.13 8 +206TL2 G KC=0.10 7$LC=0.021 7$MC=0.0050 15 +206TL G 649.42 5 2.2 3 M1 0.0501 7 +206TL2 G KC=0.0412 6$LC=0.00681 10$MC=1585E-6 23 + diff --git a/HEN_HOUSE/spectra/lnhb/Ho-166.txt b/HEN_HOUSE/spectra/lnhb/Ho-166.txt new file mode 100644 index 000000000..77b1443aa --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Ho-166.txt @@ -0,0 +1,82 @@ +166ER 166HO B- DECAY (26.795 H) +166ER C References: 1977La19 +166ER T Auger electrons and ^X ray energies and emission intensities: +166ER T {U Energy (keV)} {U Intensity } {U Line } +166ER T +166ER T 48.2215 2.91 10 XKA2 +166ER T 49.1282 5.16 17 XKA1 +166ER T +166ER T 55.495 |] XKB3 +166ER T 55.682 |] 1.68 6 XKB1 +166ER T 56.04 |] XKB5II +166ER T +166ER T 57.21 |] XKB2 +166ER T 57.313 |] 0.436 18 XKB4 +166ER T 57.456 |] XKO23 +166ER T +166ER T 6.14-9.43 7.91 18 XL (total) +166ER T 6.14 0.151 5 XLL +166ER T 6.9-6.95 3.47 10 XLA +166ER T 7.05 0.0775 27 XLC +166ER T 7.75-8.34 3.62 11 XLB +166ER T 8.81-9.43 0.586 19 XLG +166ER T +166ER T 37.78-40.55 |] KLL AUGER +166ER T 45.52-49.1 |] 0.63 5 ^KLX AUGER +166ER T 53.07-57.84 |] KXY AUGER +166ER T 3.9-7.6 28.0 6 L AUGER +166HO P 0.0 0- 26.795 H 29 1854.5 9 +166ER N 1.0 1.0 1 1.0 +166ER L 0 0+ STABLE +166ER B 1854.5 9 48.2 15 8.1 +166ERS B EAV=693.8 6 +166ER L 80.5725 132+ 1.82 NS 3 +166ER B 1773.9 9 50.5 15 9 1U +166ERS B EAV=651.1 6 +166ER G 80.5725 136.55 8 E2 6.90 14 +166ER2 G KC=1.65 5$LC=4.01 8$MC=0.978 20 +166ER L 264.9832 174+ 118 PS 5 +166ER G 184.4107 110.0015 7 E2 0.333 10 +166ER2 G KC=0.205 6$LC=0.0984 30$MC=0.0236 7 +166ER L 785.78 7 2+ 3.26 PS 11 +166ER B 1068.6 9 0.0072 21 11.6 1U +166ERS B EAV=356 9 +166ER G 520.80 7 0.00035 2 E2 0.0149 5 +166ER2 G KC=0.01192 36$LC=0.00234 7$MC=5.35E-4 16 +166ER G 705.21 7 0.0146 12E2+M1 0.0072122 +166ER2 G KC=0.00591 18$LC=1012E-6 30$MC=2.28E-4 7 +166ER G 785.78 7 0.0120 3 E2 0.0056617 +166ER2 G KC=0.00467 14$LC=7.69E-4 23$MC=1.73E-4 5 +166ER L 1460.025 100+ +166ER B 394.5 9 0.955 16 7.4 +166ERS B EAV=115 3 +166ER G 674.24 7 0.0198 17E2 0.0079924 +166ER2 G KC=0.00653 20$LC=1138E-6 34$MC=2.57E-4 8 +166ER G 1379.446 100.933 35E2 0.001795 +166ER2 G KC=0.00151 5$LC=0.00022 1$MC=4.8E-5 2 +166ER G 1460.018 102000E-7 0 +166ER L 1528.23 152+ +166ER B 326.2 9 0.00276 22 9.5 1U +166ERS B EAV=93 3 +166ER G 1263.24 150.0155 9 E2(+M3) 0.0021 2 +166ER2 G KC=0.0018 2$LC=0.0003 1$MC=5.8E-5 2 +166ER G 1447.66 150.00105 10E2(+) 0.001635 +166ER2 G KC=0.00138 4$LC=1.98E-4 6$MC=4.4E-5 2 +166ER G 1528.23 150.00014 5 E2 0.001474 +166ER2 G KC=0.00125 4$LC=1.78E-4 5$MC= +166ER L 1662.433 151- +166ER B 192.0 9 0.304 7 6.9 +166ERS B EAV=52 1 +166ER G 1581.852 150.186 4 E1+(M2) +166ER G 1662.424 150.118 5 E1 +166ER L 1812.8 5 1- +166ER B 41.7 9 0.00010 3 12.1 +166ERS B EAV=13 2 +166ER G 1732.2 5 4.6E-5 20M1(+E2) +166ER G 1812.8 5 5.6E-5 19E1(+M2) +166ER L 1830.419 241- +166ER B 24.1 9 0.0353 11 5 +166ERS B EAV=7.1 10 +166ER G 1749.837 140.0272 10E1(+M2) +166ER G 1830.408 240.0081 2 E1 + diff --git a/HEN_HOUSE/spectra/lnhb/Ho-166m.txt b/HEN_HOUSE/spectra/lnhb/Ho-166m.txt new file mode 100644 index 000000000..3821f6a94 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Ho-166m.txt @@ -0,0 +1,175 @@ +166ER 166HO B- DECAY (1133 Y) +166ER H TYP=Update$AUT=M.-M.Bé$CUT=01-JUN-2006$ +166ER2 H TYP=Full$AUT=E.Schonfeld$CUT=01-JUN-1999$ +166ER C Evaluation history: Type=Update;Author=M.-M.Bé;Cutoff date=01-JUN-2006 +166ER2C Type=Full;Author=E.Schonfeld;Cutoff date=01-JUN-1999 +166ER T Auger electrons and ^X ray energies and emission intensities: +166ER T {U Energy (keV)} {U Intensity } {U Line } +166ER T +166ER T 48.2215 10.81 21 XKA2 +166ER T 49.1282 19.2 4 XKA1 +166ER T +166ER T 55.495 |] XKB3 +166ER T 55.682 |] 6.24 14 XKB1 +166ER T 56.04 |] XKB5II +166ER T +166ER T 57.21 |] XKB2 +166ER T 57.313 |] 1.62 5 XKB4 +166ER T 57.456 |] XKO23 +166ER T +166ER T 6.14-9.43 20.8 4 XL (total) +166ER T 6.14 0.398 12 XLL +166ER T 6.9-6.95 9.19 24 XLA +166ER T 7.05 0.198 6 XLC +166ER T 7.75-8.34 9.46 24 XLB +166ER T 8.81-9.43 1.54 5 XLG +166ER T +166ER T 37.78-40.55 |] KLL AUGER +166ER T 45.52-49.1 |] 2.33 17 ^KLX AUGER +166ER T 53.07-56.84 |] KXY AUGER +166ER T 3.9-7.6 72.0 7 L AUGER +166HO P 5.98 2 7- 1133 Y 8 1854.5 9 +166ER N 1.0 1.0 1 1.0 +166ER L 0 0+ STABLE +166ER L 80.5725 132+ 1.82 NS +166ER G 80.5725 1312.66 23E2 6.90 14 +166ER2 G KC=1.65 3$LC=4.01 8$MC=0.978 29 +166ER L 264.9832 174+ 118 PS +166ER G 184.4107 1172.5 3 E2 0.334 7 +166ER2 G KC=0.205 6$LC=0.0984 30$MC=0.0236 7 +166ER L 545.4462 296+ +166ER B 1315.1 9 3.4 6 14.3 1 +166ERS B EAV=674.6 9 +166ER G 280.4630 2329.54 25E2 0.0855 17 +166ER2 G KC=0.0613 12$LC=0.0187 4$MC=0.00439 13 +166ER L 785.78 7 2+ 3.26 PS +166ER G 520.80 7 0.153 6 E2 0.0149 3 +166ER2 G KC=0.01192 36$LC=0.00234 7$MC=5.35E-4 16 +166ER G 705.21 7 0.014 7 E2(+M1) 0.0072122 +166ER2 G KC=0.00591 18$LC=1012E-6 30$MC=2.28E-4 7 +166ER G 785.78 7 0.019 4 E2 0.0056617 +166ER2 G KC=0.00467 14$LC=7.69E-4 23$MC=1.73E-4 5 +166ER L 859.400 6 3+ +166ER G 73.62 7 0.0260 16M1+E2 7.14 21 +166ER2 G KC=5.98 18$LC=0.902 27$MC=0.201 6 +166ER G 594.417 6 0.58 6 E2+M1 0.0108933 +166ER2 G KC=0.00881 26$LC=1613E-6 48$MC=3.66E-4 11 +166ER G 778.827 6 3.01 8 E2+M1 0.0057917 +166ER2 G KC=0.00477 14$LC=7.88E-4 24$MC=1.77E-4 5 +166ER L 911.214 7 8+ 4.2 PS +166ER B 949.3 9 1.12 6 14.2 1 +166ERS B EAV=294.3 9 +166ER G 365.768 6 2.46 4 E2 0.0388 8 +166ER2 G KC=0.0294 6$LC=0.00721 15$MC=0.00167 5 +166ER L 956.236 8 4+ +166ER G 691.253 7 1.32 7 E2+M1 0.0075823 +166ER2 G KC=0.00620 19$LC=1069E-6 32$MC=2.41E-4 7 +166ER G 875.663 7 0.721 9 E2 0.0044713 +166ER2 G KC=0.00371 11$LC=5.92E-4 18$MC=1324E-7 40 +166ER L 1075.269 5 5+ 60 PS +166ER G 119.033 100.173 3 E2+M1 1.614 48 +166ER2 G KC=0.888 27$LC=0.556 17$MC=0.1339 40 +166ER G 215.871 7 2.66 17E2 0.197 4 +166ER2 G KC=0.1299 26$LC=0.0516 10$MC=0.01229 37 +166ER G 529.825 4 9.4 4 M1+E2 0.0144 3 +166ER2 G KC=0.01145 26$LC=0.00223 5$MC=5.08E-4 15 +166ER G 810.286 4 57.3 11E2+M1 0.0053 1 +166ER2 G KC=0.00438 9$LC=0.00071 2$MC=1603E-7 48 +166ER L 1215.972 5 6+ +166ER B 644.5 9 2.31 29 13.4 1 +166ERS B EAV=201.2 9 +166ER G 140.703 7 0.0428 22M1+E2 0.938 28 +166ER2 G KC=0.604 18$LC=0.256 8$MC=0.0611 18 +166ER G 259.736 101.078 10E2 0.1087 22 +166ER2 G KC=0.0762 15$LC=0.0249 5$MC=0.00589 18 +166ER G 304.758 9 0.0183 12E2 0.0662 13 +166ER2 G KC=0.0485 10$LC=0.0137 3$MC=0.00322 10 +166ER G 670.526 4 5.34 21E2+M1 0.0081624 +166ER2 G KC=0.00666 20$LC=1161E-6 35$MC=2.62E-4 8 +166ER G 950.988 4 2.744 19E2 0.0037611 +166ER2 G KC=0.00313 9$LC=4.88E-4 15$MC=1089E-7 33 +166ER L 1376.011 5 7+ +166ER B 484.5 9 0.81 26 13 +166ERS B EAV= +166ER G 160.039 7 0.097 5 M1+E2 1.45 11 0.616 18 +166ER2 G KC=0.417 13$LC=0.1530 46$MC=0.0363 11 +166ER G 300.741 3 3.73 3 E2 0.0691 14 +166ER2 G KC=0.0503 10$LC=0.0144 3$MC=0.00338 10 +166ER G 464.798 6 1.25 4 M1+E2 0.0201 6 +166ER2 G KC=0.01579 47$LC=0.0033 1$MC=7.58E-4 23 +166ER G 830.565 4 9.72 18E2+M1 0.0050315 +166ER2 G KC=0.00416 12$LC=6.73E-4 20$MC=1509E-7 45 +166ER L 1555.72 5 8+ +166ER B 304.6 9 0.394 5 12.9 1 +166ERS B EAV= +166ER G 339.75 5 0.1616 23E2 0.048 1 +166ER2 G KC=0.0359 7$LC=0.00930 19$MC=0.00217 7 +166ER G 644.51 7 0.144 4 E2+M1 0.0098930 +166ER2 G KC=0.00810 24$LC=1384E-6 42$MC=3.12E-4 9 +166ER G 1010.27 6 0.0794 16E2 0.0033210 +166ER2 G KC=0.00277 8$LC=4.25E-4 13$MC=9.47E-5 28 +166ER L 1572.22 6 4- +166ER G 496.90 6 0.125 3 E1(+M2) 0.0057117 +166ER2 G KC=0.00483 15$LC=6.79E-4 20$MC=1497E-7 45 +166ER G 615.93 6 0.094 29E4 0.0687 21 +166ER2 G KC=0.0444 13$LC=0.0185 6$MC=0.00449 13 +166ER G 712.89 130.30 9 E1 +166ER G 1307.19 6 0.0055 11E1 8.52E-426 +166ER2 G KC=7.27E-4 22$LC=9.70E-5 29$MC=2.13E-5 6 +166ER L 1596.10 7 4- +166ER G 639.86 6 0.0943 7 E1 0.0033110 +166ER2 G KC=0.00282 8$LC=3.89E-4 12$MC=8.57E-5 26 +166ER G 736.70 7 0.373 6 E1 0.002497 +166ER2 G KC=0.00211 6$LC=2.90E-4 9$MC=6.37E-5 19 +166ER G 1331.12 7 0.0043 12E1 8.25E-425 +166ER2 G KC=7.05E-4 21$LC=9.39E-5 28$MC=2.06E-5 6 +166ER L 1665.79 3 5- +166ER G 1120.32 3 0.199 4 E1 1121E-634 +166ER2 G KC=9.56E-4 29$LC=1283E-7 38$MC=2.81E-5 8 +166ER G 1400.79 2 0.508 6 E1 7.55E-423 +166ER2 G KC=6.45E-4 19$LC=8.59E-5 26$MC=1.88E-5 6 +166ER L 1692.291 125- +166ER G 476.25 4 0.0363 13E1 0.0062719 +166ER2 G KC=0.00531 16$LC=7.48E-4 22$MC=1.65E-4 5 +166ER G 736.02 8 0.14 2 +166ER G 1146.77 3 0.2059 26E1 1075E-632 +166ER2 G KC=9.18E-4 28$LC=1230E-7 37$MC=2.70E-5 8 +166ER G 1427.24 2 0.498 6 E1 7.32E-422 +166ER2 G KC=6.25E-4 19$LC=8.31E-5 25$MC=1.82E-5 5 +166ER L 1786.966 7 6- +166ER B 73.5 9 74.8 12 8.8 +166ERS B EAV=18.6 4 +166ER G 94.675 140.146 4 M1+E2 3.45 10 +166ER2 G KC=2.89 9$LC=0.435 13$MC=0.0967 29 +166ER G 121.175 100.241 7 E2 1.460 44 +166ER2 G KC=0.663 20$LC=0.610 18$MC=0.1480 44 +166ER G 190.86 7 0.215 5 E2 0.297 9 +166ER2 G KC=0.186 6$LC=0.0853 26$MC=0.0204 6 +166ER G 214.79 3 0.445 11E2 0.200 4 +166ER2 G KC=0.1318 40$LC=0.0526 16$MC=0.01254 38 +166ER G 410.956 3 11.35 17E1(+M2) 0.0087826 +166ER2 G KC=0.00743 22$LC=1055E-6 32$MC=2.33E-4 7 +166ER G 570.995 5 5.43 20E1(+M2) 0.0042113 +166ER2 G KC=0.00358 11$LC=4.98E-4 15$MC=1097E-7 33 +166ER G 711.697 3 54.9 9 E1(+M2) 0.002668 +166ER2 G KC=0.00227 7$LC=3.11E-4 9$MC=6.85E-5 21 +166ER G 1241.519 4 0.85 3 E1(+M2) 9.32E-428 +166ER2 G KC=7.96E-4 24$LC=1063E-7 32$MC=2.33E-5 7 +166ER L 1827.551 7 6- +166ER B 32.9 9 17.2 4 8.4 +166ERS B EAV=8.2 2 +166ER G 135.260 140.0979 19E2 0.981 29 +166ER2 G KC=0.493 15$LC=0.373 11$MC=0.0904 27 +166ER G 161.76 3 0.109 4 E2(+M1) 0.522 16 +166ER2 G KC=0.299 9$LC=0.171 5$MC=0.0412 12 +166ER G 231.45 7 0.219 6 E2 0.157 3 +166ER2 G KC=0.1062 21$LC=0.0391 8$MC=0.00928 28 +166ER G 451.540 4 2.915 14E1(+M2) 0.0070721 +166ER2 G KC=0.00599 18$LC=8.46E-4 25$MC=1.87E-4 6 +166ER G 611.579 6 1.31 21E1(+M2) 0.0036411 +166ER2 G KC=0.00309 9$LC=4.29E-4 13$MC=9.44E-5 28 +166ER G 752.280 4 12.2 3 E1(+M2) 0.002387 +166ER2 G KC=0.00203 6$LC=2.78E-4 8$MC=6.11E-5 18 +166ER G 1282.102 5 0.183 7 E1(+M2) 8.81E-426 +166ER2 G KC=7.52E-4 23$LC=1004E-7 30$MC=2.20E-5 7 + diff --git a/HEN_HOUSE/spectra/lnhb/I-123.txt b/HEN_HOUSE/spectra/lnhb/I-123.txt new file mode 100644 index 000000000..a38dcee98 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/I-123.txt @@ -0,0 +1,126 @@ +123TE 123I EC DECAY (13.2234 H) +123TE T Auger electrons and ^X ray energies and emission intensities: +123TE T {U Energy (keV)} {U Intensity } {U Line } +123TE T +123TE T 27.202 24.69 20 XKA2 +123TE T 27.4726 45.98 29 XKA1 +123TE T +123TE T 30.9446 |] XKB3 +123TE T 30.996 |] 13.16 17 XKB1 +123TE T 31.236 |] XKB5II +123TE T 31.241 |] XKB5I +123TE T +123TE T 31.7008 |] XKB2 +123TE T 31.774 |] 2.86 8 XKB4 +123TE T 31.812 |] XKO23 +123TE T +123TE T 3.336-4.82 9.0 4 XL (total) +123TE T 3.336 0.159 5 XLL +123TE T 3.76-3.77 4.22 11 XLA +123TE T 3.606 0.0598 18 XLC +123TE T 4.02-4.37 2.91 7 XLB +123TE T 4.44-4.82 0.366 10 XLG +123TE T +123TE T 21.804-22.989 |] KLL AUGER +123TE T 25.814-27.47 |] 12.4 4 ^KLX AUGER +123TE T 29.8-31.81 |] KXY AUGER +123TE T 2.3-4.8 95.3 6 L AUGER +123I P 0.0 5/2+ 13.2234 H 37 1234 3 +123TE N 1.0 1.0 1 1.0 +123TE L 0 1/2+ 12E12 Y +123TE L 158.99 3 3/2+ 196 PS 9 +123TE E 97.18 325.26 2 +123TE2 E EAV= $CK=0.8533 14$CL=0.1163 10$CM=0.0248 5$CN=0.0056 3$CO=0 0 +123TE G 158.97 5 83.25 21M1+E2 0.111 3 0.1918 19 +123TE2 G KC=0.1648 16$LC=0.02160 22$MC= +123TE L 440.00 4 3/2+ 22 PS 3 +123TE E 0.419 5 7.35 2 +123TE2 E EAV= $CK=0.8510 14$CL=0.1181 10$CM=0.0253 5$CN=0.0056 3$CO=0 0 +123TE G 281.03 5 0.0789 9 M1+E2 -0.39 15 0.0422 33 +123TE2 G KC=0.0362 20$LC=0.0048 11$MC= +123TE G 440.02 5 0.4229 43M1+E2 -2.1 1 0.0121 7 +123TE2 G KC=0.0103 7$LC=1452E-6 18$MC= +123TE L 489.70 8 (7/2)+ 30.7 NS +123TE E 0.0025 109.52 2 +123TE2 E EAV= $CK=0.8503 14$CL=0.1186 10$CM=0.0254 5$CN=0.0057 3$CO=0 0 +123TE G 330.70 8 0.01164 33E2 0.0284 9 +123TE2 G KC=0.0237 7$LC=0.00376 11$MC= +123TE L 505.34 4 (5/2)+ 13.5 PS 25 +123TE E 0.349 427.35 +123TE2 E EAV= $CK=0.8501 14$CL=0.1187 10$CM=0.0254 5$CN=0.0058 3$CO=0 0 +123TE G 346.35 5 0.1257 9 M1+E2 0.07 7 0.0240723 +123TE2 G KC=0.02080 14$LC=0.00262 29$MC= +123TE G 505.33 5 0.266 42M1+E2 0.10 2 0.0093 7 +123TE2 G KC=0.0081 7$LC=1063E-6 27$MC= +123TE L 599.57 151/2+ +123TE G 599.69 160.00266 17 +123TE L 687.95 4 3/2+ +123TE E 1.40 126.49 2 +123TE2 E EAV= $CK=0.8466 14$CL=0.1214 10$CM=0.0261 5$CN=0.0059 3$CO=0 0 +123TE G 182.61 6 0.018 5 M1+E2 1 0.168 38 +123TE2 G KC=0.138 24$LC=0.024 10$MC= +123TE G 198.23 0.0035 7 M1+E2 1 0.130 26 +123TE2 G KC=0.107 17$LC=0.018 7$MC= +123TE G 247.96 5 0.0698 23M1+E2 1 0.065 8 +123TE2 G KC=0.054 5$LC=0.0084 21$MC= +123TE G 528.96 5 1.28 12 +123TE G 687.95 100.0269 6 +123TE L 697.52 5 7/2+ +123TE E 0.419 136.98 2 +123TE2 E EAV= $CK=0.8464 14$CL=0.1216 10$CM=0.0262 5$CN=0.0058 3$CO=0 0 +123TE G 192.17 7 0.0199 7 M1+E2 1 0.143 30 +123TE2 G KC=0.118 20$LC=0.020 8$MC= +123TE G 207.8 0.00112 32M1+E2 1 0.119 20 +123TE2 G KC=0.093 14$LC=0.015 5$MC= +123TE G 257.51 150.0016 2 E2 0.0640 19 +123TE2 G KC=0.0526 16$LC=0.00917 27$MC= +123TE G 538.54 5 0.3788 43E2+M3 1 0.038 31 +123TE2 G KC=0.032 26$LC=0.0049 41$MC= +123TE L 769.26 14 + +123TE E 0.0037 6 8.92 +123TE2 E EAV= $CK=0.8441 14$CL=0.1233 10$CM=0.0266 5$CN=0.0060 3$CO=0 0 +123TE G 329.38 170.0026 6 +123TE G 610.05 230.0011 3 +123TE L 783.60 4 3/2,5/2+ 52 FS 33 +123TE E 0.1461 207.29 2 +123TE2 E EAV= $CK=0.8436 14$CL=0.1237 10$CM=0.0267 5$CN=0.0060 3$CO=0 0 +123TE G 278.36 120.0023 4 M1+E2 1 0.0459 36 +123TE2 G KC=0.0387 22$LC=0.0058 11$MC= +123TE G 343.73 140.0044 3 +123TE G 624.57 5 0.0798 20M1+E2 1.30 35 0.0049 6 +123TE2 G KC=0.0042 5$LC=5.49E-4 40$MC= +123TE G 783.59 6 0.0591 11 +123TE L 894.74 6 3/2,5/2+ 45 FS 24 +123TE E 0.0744 137.32 2 +123TE2 E EAV= $CK=0.8377 15$CL=0.1283 11$CM=0.0278 5$CN=0.0062 3$CO=0 0 +123TE G 197.22 0.00033 17M1+E2 1 0.132 26 +123TE2 G KC=0.109 18$LC=0.018 7$MC= +123TE G 206.79 0.0033 8 M1+E2 1 0.114 21 +123TE2 G KC=0.094 14$LC=0.016 5$MC= +123TE G 295.17 1582E-6 4 +123TE G 405.02 130.00298 23 +123TE G 454.76 150.00412 22 +123TE G 735.78 7 0.0616 8 +123TE G 894.8 2 0.00101 7 +123TE L 996.06 12(5/2)- +123TE E 0.0035 3 8.31 +123TE2 E EAV= $CK=0.8266 16$CL=0.1363 12$CM=0.0300 6$CN=0.0067 4$CO=0 0 +123TE G 556.05 130.0029 3 +123TE G 837.1 2 5.82E-4 8 +123TE L 1036.64 123/2,5/2+ 43 FS 16 +123TE E 0.0025 9 8.27 2 +123TE2 E EAV= $CK=0.8182 18$CL=0.1427 13$CM=0.0316 6$CN=0.0071 4$CO=0 0 +123TE G 437.5 3 0.0007 7 +123TE G 877.52 170.00083 7 +123TE G 1036.63 170.00097 7 +123TE L 1068.18 8 3/2,5/2+ +123TE E 0.0079 4 7.59 2 +123TE2 E EAV= $CK=0.8082 21$CL=0.1503 15$CM=0.0336 7$CN=0.0075 4$CO=0 0 +123TE G 174.2 3 0.00083 25M1+E2 1 0.195 47 +123TE2 G KC=0.159 32$LC=0.029 12$MC= +123TE G 562.79 120.00115 7 +123TE G 578.26 200.00126 8 +123TE G 628.26 220.00164 14 +123TE G 909.12 120.00141 8 +123TE G 1068.12 150.00142 7 + diff --git a/HEN_HOUSE/spectra/lnhb/I-125.txt b/HEN_HOUSE/spectra/lnhb/I-125.txt new file mode 100644 index 000000000..258bd8400 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/I-125.txt @@ -0,0 +1,46 @@ +125TE 125I EC DECAY (59.388 D) +125TE H TYP=Full$AUT=V. Chisté$CUT=30-AUG-2010$ +125TE2 H TYP=Update$AUT=M.M. Bé$CUT= -- $ +125TE3 H TYP=Full$AUT=E.Schönfeld$CUT= -- $ +125TE C Evaluation history: Type=Full;Author=V. Chisté;Cutoff date=30-AUG-2010 +125TE2C Type=Update;Author=M.M. Bé;Cutoff date= -- +125TE3C Type=Full;Author=E.Schönfeld;Cutoff date= -- +125TE C References: 1946Re**, 1951Fr21, 1958Ku82, 1960Ma36, 1963Ge**, 1964Le05, +125TE2C 1965An07, 1966Ri14, 1968La10, 1969Ka08, 1972Em01, 1977Kr13, 1979Ku**, +125TE3C 1980Ho17, 1979CoZG, 1982HoZJ, 1983De11, 1983Ku**, 1987Sc20, 1989Si19, +125TE4C 1990Wo03, 1990Iw04, 1990De09, 1991Al05, 1992ScZZ, 1995Ra32, 1996Sc06, +125TE5C 1999Ka26, 2002Un02, 2003Au03, 2006Da20, 2008Ki07 +125TE T Auger electrons and ^X ray energies and emission intensities: +125TE T {U Energy (keV)} {U Intensity } {U Line } +125TE T +125TE T 27.202 39.3 5 XKA2 +125TE T 27.4726 73.2 8 XKA1 +125TE T +125TE T 30.9446 |] XKB3 +125TE T 30.996 |] 20.9 3 XKB1 +125TE T 31.236 |] XKB5II +125TE T +125TE T 31.7008 |] XKB2 +125TE T 31.774 |] 4.54 13 XKB4 +125TE T 31.812 |] XKO23 +125TE T +125TE T 3.3348-4.8228 14.70 28 XL (total) +125TE T 3.3348 0.281 9 XLL +125TE T 3.7595-3.7697 7.45 20 XLA +125TE T 3.6052 0.108 4 XLC +125TE T 4.0299-4.3661 6.02 13 XLB +125TE T 4.4448-4.8228 0.844 19 XLG +125TE T +125TE T 21.804-22.989 |] KLL AUGER +125TE T 25.814-27.47 |] 19.7 7 ^KLX AUGER +125TE T 29.8-31.81 |] KXY AUGER +125TE T 2.3-4.8 158.2 8 L AUGER +125I P 0.0 5/2+ 59.388 D 28 185.77 6 +125TE N 1.0 1.0 1 1.0 +125TE L 0 1/2+ STABLE +125TE L 35.4922 5 3/2+ 1.48 NS +125TE E 100 5.4 2 +125TE2 E EAV= $CK=0.8011 17$CL=0.1561 13$CM=0.0349 7$CN=0.0079 4$CO=0 0 +125TE G 35.4922 5 6.63 6 M1+E2 0.085 6 14.08 22 +125TE2 G KC=11.70 17$LC=1.91 8$MC=0.386 16 + diff --git a/HEN_HOUSE/spectra/lnhb/I-129.txt b/HEN_HOUSE/spectra/lnhb/I-129.txt new file mode 100644 index 000000000..fa0cde92c --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/I-129.txt @@ -0,0 +1,34 @@ +129XE 129I B- DECAY (16.1E6 Y) +129XE T Auger electrons and ^X ray energies and emission intensities: +129XE T {U Energy (keV)} {U Intensity } {U Line } +129XE T +129XE T 29.459 20.1 3 XKA2 +129XE T 29.779 37.2 6 XKA1 +129XE T +129XE T 33.562 |] XKB3 +129XE T 33.625 |] 10.3 4 XKB1 +129XE T 33.881 |] XKB5II +129XE T +129XE T 34.415 |] XKB2 +129XE T 34.496 |] 2.30 13 XKB4 +129XE T 34.552 |] XKO23 +129XE T +129XE T 3.6-5.4 7.9 4 XL (total) +129XE T 3.6 XLL +129XE T -5.4 XLG +129XE T +129XE T 23.512-24.842 |] KLL AUGER +129XE T 27.897-29.77 |] 8.8 4 ^KLX AUGER +129XE T 32.27-34.54 |] KXY AUGER +129XE T 2.4-5.4 73.9 12 L AUGER +129I P 0.0 7/2+ 16.1E6 Y 7 190.8 11 +129XE N 1.0 1.0 1 1.0 +129XE L 0 1/2+ STABLE +129XE B 190.8 110.5 5 14.9 +129XES B EAV= +129XE L 39.578 4 3/2+ 1 NS +129XE B 151.2 1199.5 5 13.49 +129XES B EAV=37 1 +129XE G 39.578 4 7.42 8 M1+E2 12.41 13 +129XE2 G KC=10.59 11$LC=1.45 5$MC=0.296 10 + diff --git a/HEN_HOUSE/spectra/lnhb/I-131.txt b/HEN_HOUSE/spectra/lnhb/I-131.txt new file mode 100644 index 000000000..b5793ea5f --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/I-131.txt @@ -0,0 +1,99 @@ +131XE 131I B- DECAY (8.0233 D) +131XE H TYP=Full$AUT=M.M. Bé$CUT=30-NOV-2013$ +131XE2 H TYP=Full$AUT=V. Chisté$CUT=01-DEC-2001$ +131XE C Evaluation history: Type=Full;Author=M.M. Bé;Cutoff date=30-NOV-2013 +131XE2C Type=Full;Author=V. Chisté;Cutoff date=01-DEC-2001 +131XE C References: 1938Li05, 1951Si25, 1952Be95, 1952Be55, 1953Lo09, 1953Ba10, +131XE2C 1953Se28, 1958Bu14, 1958Ke26, 1962Wo09, 1963Ju02, 1963Ha08, 1964Da19, +131XE3C 1966Mo10, 1967Yt02, 1967Ya02, 1967Gr05, 1968Ke05, 1970Be46, 1971Zo02, +131XE4C 1972Kr07, 1972Em01, 1974Me21, 1974Ko02, 1974Ka37, 1975Ko15, 1976ba42, +131XE5C 1977Kr13, 1978La21, 1979Ir01, 1980Ho17, 1982HoZF, 1983Wa26, 1989Ch45, +131XE6C 1990Me15, 1994Se10, 1996Sc06, 2002Ba85, 2004Da05, 2004Sc04, 2008Ki07, +131XE7C 2012Wa38, 2012Fi12 +131XE T Auger electrons and ^X ray energies and emission intensities: +131XE T {U Energy (keV)} {U Intensity } {U Line } +131XE T +131XE T 29.459 1.52 4 XKA2 +131XE T 29.779 2.81 6 XKA1 +131XE T +131XE T 33.562 |] XKB3 +131XE T 33.625 |] 0.816 19 XKB1 +131XE T 33.881 |] XKB5II +131XE T +131XE T 34.415 |] XKB2 +131XE T 34.496 |] 0.193 6 XKB4 +131XE T 34.552 |] XKO23 +131XE T +131XE T 3.64-5.3 0.631 13 XL (total) +131XE T 3.64 0.0122 4 XLL +131XE T 4.1-4.11 0.321 9 XLA +131XE T 3.96 0.00461 15 XLC +131XE T 4.42-4.78 0.256 6 XLB +131XE T 4.89-5.3 0.0377 9 XLG +131XE T +131XE T 23.512-24.842 |] KLL AUGER +131XE T 27.897-29.77 |] 0.67 4 ^KLX AUGER +131XE T 32.27-34.54 |] KXY AUGER +131XE T 2.5-5.43 5.87 4 L AUGER +131I P 0.0 7/2+ 8.0233 D 19 970.8 6 +131XE N 1.0 1.0 1 1.0 +131XE L 0 3/2+ STABLE +131XE L 80.1854 191/2+ 0.48 NS 3 +131XE G 80.185 2 2.607 35M1 1.544 46 +131XE2 G KC=1.32 4$LC=0.175 5$MC=0.036 1 +131XE L 163.930 8 11/2- 11.962 D 20 +131XE B 806.9 6 0.386 23 10.03 3U +131XES B EAV=267.91 23 +131XE G 163.930 8 0.0211 3 M4 50.5 7 +131XE2 G KC=31.6 5$LC=14.75 21$MC=3.38 5 +131XE L 341.144 9 9/2- 1.6 NS 4 +131XE B 629.7 6 0.060 12 9.8 1U +131XES B EAV=200.23 22 +131XE G 177.214 200.277 7 M1+()E2 -4.3 4 0.241 7 +131XE2 G KC=0.187 6$LC=0.0427 13$MC=0.00901 27 +131XE L 364.490 4 5/2+ 69 PS 2 +131XE B 606.3 6 89.4 8 6.64 2 +131XES B EAV=191.59 22 +131XE G 284.305 5 6.14 6 E2 0.0497 7 +131XE2 G KC=0.0408 6$LC=0.00714 10$MC=1479E-6 21 +131XE G 364.489 5 81.2 5 M1+()E2 -4.53 11 0.0228 4 +131XE2 G KC=0.0190 3$LC=0.00300 5$MC=6.16E-4 9 +131XE L 404.815 4 3/2+ 18 PS 3 +131XE G 324.651 250.0244 25M1+E2 0.0329 6 +131XE2 G KC=0.0278 10$LC=0.0041 4$MC=0.00083 9 +131XE G 404.814 4 0.0552 17M1+E2 1.0 9 0.0177 12 +131XE2 G KC=0.0151 13$LC=0.00210 4$MC=4.29E-4 11 +131XE L 636.990 4 7/2+ 6.1 PS 5 +131XE B 333.8 6 7.20 7 6.86 +131XES B EAV=96.61 19 +131XE G 232.18 150.0023 9 [E2] 0.097 2 +131XE2 G KC=0.0782 22$LC=0.0151 5$MC=0.0031 1 +131XE G 272.498 170.0581 15M1+()E2 -0.38 17 0.0530 9 +131XE2 G KC=0.0453 7$LC=0.0061 3$MC=0.00125 6 +131XE G 295.8 2 0.0012 6 [E1] 0.0108 3 +131XE2 G KC=0.0093 2$LC=0.00117 3$MC=0.00024 4 +131XE G 636.989 4 7.12 7 E2 0.004707 +131XE2 G KC=0.00401 6$LC=5.51E-4 8$MC=1123E-7 16 +131XE L 666.934 9 7/2- 0.5 NS +131XE B 303.9 6 0.643 27 7.79 +131XES B EAV=86.94 19 +131XE G 302.4 2 0.0046 7 [E1] 0.0102 2 +131XE2 G KC=0.0088 2$LC=0.00111 1$MC=0.00022 1 +131XE G 325.789 4 0.274 8 M1+()E2 -0.8 7 0.0335 10 +131XE2 G KC=0.0288 9$LC=0.00376 11$MC=7.65E-4 23 +131XE G 503.004 4 0.3540 46E2 0.0088313 +131XE2 G KC=0.00748 11$LC=1083E-6 16$MC=2.21E-4 3 +131XE L 722.909 4 5/2++ 0.53 PS 5 +131XE B 247.9 6 2.130 21 6.98 2 +131XES B EAV=69.35 19 +131XE G 85.9 2 0.0051 7 [M1E2] 2.2 1 +131XE2 G KC=1.50 6$LC=0.56 2$MC= +131XE G 318.088 160.0807 20M1+()E2 -0.11 8 0.0350 5 +131XE2 G KC=0.0301 5$LC=0.00388 6$MC=7.86E-4 12 +131XE G 358.4 2 0.017 8 [M1E2] 0.0248 10 +131XE2 G KC=0.0210 12$LC=0.00301 18$MC=0.00061 5 +131XE G 642.719 5 0.2183 26[E2] 0.0046 1 +131XE2 G KC=0.0039 1$LC=0.00054 1$MC=0.00011 2 +131XE G 722.911 5 1.786 19M1+()E2 0.207 5 0.004517 +131XE2 G KC=0.00390 6$LC=4.88E-4 7$MC=9.87E-5 14 + diff --git a/HEN_HOUSE/spectra/lnhb/I-133.txt b/HEN_HOUSE/spectra/lnhb/I-133.txt new file mode 100644 index 000000000..c87d46df4 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/I-133.txt @@ -0,0 +1,135 @@ +133XE 133I B- DECAY (20.87 H) +133XE H TYP=Full$AUT=M.Galan$CUT= -- $ +133XE C Evaluation history: Type=Full;Author=M.Galan;Cutoff date= -- +133XE C References: 1953KA28, 1955WA35, 1959HO97, 1960EI01, 1965AN05, 1966EI01, +133XE2C 1968RE04, 1971SA09, 1972KR07, 1972AC02, 1972BE90, 1974KO26, 1976FU06, +133XE3C 1976ME16, 1977KR13, 1983LO08, 1989RA17, 1995RA12, 1996SC06, 2002BA85, +133XE4C 2003AU03 +133XE T Auger electrons and ^X ray energies and emission intensities: +133XE T {U Energy (keV)} {U Intensity } {U Line } +133XE T +133XE T 29.459 0.163 4 XKA2 +133XE T 29.779 0.303 6 XKA1 +133XE T +133XE T 33.562 |] XKB3 +133XE T 33.625 |] 0.0877 19 XKB1 +133XE T 33.881 |] XKB5II +133XE T +133XE T 34.415 |] XKB2 +133XE T 34.496 |] 0.0207 7 XKB4 +133XE T 34.552 |] XKO23 +133XE T +133XE T 3.6378-5.296 0.0724 14 XL (total) +133XE T 3.6378 0.00149 5 XLL +133XE T 4.0977-4.1103 0.039 1 XLA +133XE T 3.9576 0.000483 15 XLC +133XE T 4.4176-4.7758 0.0275 6 XLB +133XE T 4.895-5.296 0.003890 9 XLG +133XE T +133XE T 23.512-24.842 |] KLL AUGER +133XE T 27.897-29.77 |] 0.072 4 ^KLX AUGER +133XE T 32.27-34.54 |] KXY AUGER +133XE T 2.4-5.2 0.677 4 L AUGER +133I P 0.0 7/2+ 20.87 H 8 1757 4 +133XE N 1.0 1.0 1 1.0 +133XE G 167.97 6 0.078 17 +133XE G 567.1 4 0.003 3 +133XE G 1018.1 5 0.0060 26 +133XE L 0 0 3/2+ 5.2474 D 5 +133XE L 233.219 1511/2- 2.198 D 13 +133XE B 1524 4 1.07 6 9.92 3U +133XES B EAV=572.0 17 +133XE G 233.219 150.293 4 M4 8.84 12 +133XE2 G KC=6.24 9$LC=2.035 29$MC=0.453 6 +133XE L 262.702 601/2+ +133XE G 262.70 6 0.356 12M1+E2 0.0577 8 +133XE2 G KC=0.0497 7$LC=0.00641 9$MC=1300E-6 18 +133XE L 529.872 3 5/2+ +133XE B 1227 4 83.42 21 6.81 2 +133XES B EAV=439.4 17 +133XE G 267.17 6 0.117 7 +133XE G 529.8709 3086.3 2 M1+E2 1.85 20 0.0081014 +133XE2 G KC=0.00691 13$LC=9.56E-4 14$MC=1948E-7 29 +133XE L 680.254 9 3/2+ +133XE G 150.382 9 0.029 6 +133XE G 417.55 6 0.153 10M1+E2 1.0 13 0.0163 11 +133XE2 G KC=0.0139 10$LC=1921E-6 27$MC=3.92E-4 6 +133XE G 680.252 9 0.645 19M1 0.005277 +133XE2 G KC=$LC=5.70E-4 8$MC=1152E-7 16 +133XE L 743.750 16(7/2,9/2,11/2)- +133XE B 1013 4 1.81 6 8.17 +133XES B EAV=350.5 17 +133XE G 510.530 221.81 6 +133XE L 875.331 5 (7/2)+ +133XE B 882 4 4.16 13 7.59 +133XES B EAV=297.4 16 +133XE G 345.459 6 0.104 18 +133XE G 875.328 5 4.47 12E2+M3 0.002183 +133XE2 G KC=1876E-6 26$LC=2.45E-4 3$MC=4.96E-5 7 +133XE L 911.45 3 (1/2,3/2)+ +133XE B 846 4 0.026 18 9.7 +133XES B EAV=283.1 16 +133XE G 381.578 300.045 5 +133XE G 648.75 7 0.056 13M1 0.005908 +133XE2 G KC=0.00510 7$LC=6.39E-4 9$MC=1292E-7 18 +133XE G 911.447 300.046 6 +133XE L 1052.397 175/2+ +133XE B 706 4 0.58 5 8.09 2 +133XES B EAV=228.4 16 +133XE G 372.143 190.009 6 +133XE G 522.524 170.04 5 +133XE G 789.69 6 0.050 4 +133XE G 1052.393 170.551 16 +133XE L 1236.449 5 (7/2)+ +133XE B 521 4 3.12 6 6.91 +133XES B EAV=160.4 15 +133XE G 361.118 7 0.11 4 +133XE G 556.194 100.020 3 +133XE G 706.575 6 1.49 4 M1+E2 0.0042 6 +133XE2 G KC=0.0036 6$LC=0.00047 5$MC=9.5E-5 10 +133XE G 1236.443 5 1.49 4 +133XE L 1298.234 5 5/2+ +133XE B 459 4 3.75 7 6.64 2 +133XES B EAV=138.7 14 +133XE G 245.837 180.035 9 +133XE G 386.784 300.059 5 +133XE G 422.903 7 0.309 10M1+E2 1.8 12 0.0151 13 +133XE2 G KC=0.0128 13$LC=0.00185 3$MC=3.79E-4 6 +133XE G 554.483 170.0004 5 +133XE G 617.978 100.539 15M1+E2 0.0059 8 +133XE2 G KC=0.0050 7$LC=0.00066 6$MC=1.34E-4 12 +133XE G 768.360 6 0.457 15M1+E2 0.6 4 0.0036824 +133XE2 G KC=0.00318 22$LC=4.02E-4 22$MC=8.1E-5 4 +133XE G 1035.53 6 0.0086 18 +133XE G 1298.227 5 2.33 7 M1+E2 4.2 3 9.72E-414 +133XE2 G KC=8.22E-4 12$LC=1026E-7 15$MC=2070E-8 29 +133XE L 1350.380 175/2+ +133XE B 407 4 0.397 12 7.44 2 +133XES B EAV=120.8 14 +133XE G 438.930 340.040 5 +133XE G 670.124 190.042 6 +133XE G 820.505 170.154 6 M1+E2 0.8 8 0.0031 4 +133XE2 G KC=0.0026 3$LC=0.00033 3$MC=6.8E-5 6 +133XE G 1087.67 6 0.0121 18 +133XE G 1350.373 170.148 5 M1+E2 0.0010112 +133XE2 G KC=0.00085 10$LC=1.04E-4 12$MC=2.11E-5 23 +133XE L 1386.153 8 7/2+ +133XE B 371 4 1.25 4 6.81 +133XES B EAV=108.8 14 +133XE G 510.821 9 0.004 5 +133XE G 856.278 9 1.23 4 M1+E2 3.7 3 0.002353 +133XE2 G KC=0.00202 3$LC=2.63E-4 4$MC=5.33E-5 8 +133XE G 1386.145 8 0.0086 26[E2] +133XE L 1589.94 3 5/2+ +133XE B 167 4 0.414 15 6.18 2 +133XES B EAV=45.1 12 +133XE G 203.787 310.00432 8 +133XE G 537.542 340.035 7 +133XE G 678.488 420.022 7 +133XE G 909.683 310.212 9 M1+E2 0.40 6 0.002574 +133XE2 G KC=0.00222 4$LC=2.77E-4 5$MC=5.59E-5 9 +133XE G 1060.063 0.137 7 M1+E2 0.0016523 +133XE2 G KC=0.00143 20$LC=1.79E-4 22$MC=3.6E-5 4 +133XE G 1327.23 7 0.00022 22 +133XE G 1589.93 3 0.0029 4 + diff --git a/HEN_HOUSE/spectra/lnhb/In-111.txt b/HEN_HOUSE/spectra/lnhb/In-111.txt new file mode 100644 index 000000000..e89bdf3cc --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/In-111.txt @@ -0,0 +1,52 @@ +111CD 111IN EC DECAY (2.8049 D) +111CD H TYP=Update$AUT=V. Chechev$CUT=01-MAR-2006$ +111CD2 H TYP=Full$AUT=V. Chechev$CUT=01-JUN-1998$ +111CD C Evaluation history: Type=Update;Author=V. Chechev;Cutoff date=01-MAR-2006 +111CD2C Type=Full;Author=V. Chechev;Cutoff date=01-JUN-1998 +111CD C References: 1945Wi11, 1948Ho37, 1949He06, 1951Mc11, 1956St64, 1957Ma26, +111CD2C 1966Sp04, 1967Be65, 1968Bo28, 1968Li08, 1968Sm08, 1972Gu19, 1972MeZD, +111CD3C 1972Em01, 1973Budz, 1973Path, 1974Kr03, 1974HeYW, 1975Sh29, 1977La19, +111CD4C 1978La21, 1980Ho17, 1982HoZY, 1983Wa26, 1985Ka29, 1986Ru09, 1987Ne01, +111CD5C 1992Un01, 1994Ka08, 1996Sc06, 1997We17, 1998Si17, 2003Bl10, 2003Au03, +111CD6C 2004Sc04, 2005Ya03, 2006Ra03 +111CD T Auger electrons and ^X ray energies and emission intensities: +111CD T {U Energy (keV)} {U Intensity } {U Line } +111CD T +111CD T 22.9843 23.65 18 XKA2 +111CD T 23.1738 44.47 26 XKA1 +111CD T +111CD T 26.0615 |] XKB3 +111CD T 26.0958 |] 12.40 14 XKB1 +111CD T 26.304 |] XKB5II +111CD T +111CD T 26.644 |] XKB2 +111CD T 26.7106 |] 2.26 7 XKB4 +111CD T +111CD T 2.77-3.95 6.78 14 XL (total) +111CD T 2.77 0.147 6 XLL +111CD T 3.127-3.134 3.95 13 XLA +111CD T 2.957 0.0504 12 XLC +111CD T 3.316-3.528 2.39 5 XLB +111CD T 3.718-3.95 0.247 5 XLG +111CD T +111CD T 18.675-19.636 |] KLL AUGER +111CD T 21.923-23.172 |] 15.5 4 ^KLX AUGER +111CD T 25.171-26.028 |] KXY AUGER +111CD T 3.404-3.804 100.5 8 L AUGER +111IN P 0.0 9/2+ 2.8049 D 4 861.8 46 +111CD N 1.0 1.0 1 1.0 +111CD L 0 1/2+ STABLE +111CD L 245.4 5/2+ +111CD G 245.35 4 94.12 6 E2 0.0625 7 +111CD2 G KC=0.0524 10$LC=0.00818 16$MC=0.00159 3 +111CD L 396.15 11/2- 48.50 M 9 +111CD E 0.005 5 9 1U +111CD2 E EAV= $CK=0.8524 2$CL=0.1179 2$CM=0.02975 4$CN= $CO= +111CD G 150.81 3 0.0015 15E3 2.28 5 +111CD2 G KC=1.45 3$LC=0.673 14$MC=0.137 3 +111CD L 416.6 7/2+ +111CD E 99.995 5 5 2 +111CD2 E EAV= $CK=0.8518 2$CL=0.11835 13$CM=0.02989 4$CN= $CO= +111CD G 171.28 3 90.61 20M1+E2 0.1036 24 +111CD2 G KC=0.0897 22$LC=0.0113 3$MC=0.00217 5 + diff --git a/HEN_HOUSE/spectra/lnhb/Ir-192.txt b/HEN_HOUSE/spectra/lnhb/Ir-192.txt new file mode 100644 index 000000000..550120300 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Ir-192.txt @@ -0,0 +1,152 @@ +192OS 192IR EC DECAY (73.827 D) +192OS H TYP=Full$AUT=E. Browne$CUT= -- $ +192OS C Evaluation history: Type=Full;Author=E. Browne;Cutoff date= -- +192OS T Auger electrons and ^X ray energies and emission intensities: +192OS T {U Energy (keV)} {U Intensity } {U Line } +192OS T +192OS T 61.4873 1.211 25 XKA2 +192OS T 63.0011 2.09 5 XKA1 +192OS T +192OS T 71.078 |] XKB3 +192OS T 71.414 |] 0.710 21 XKB1 +192OS T 71.855 |] XKB5II +192OS T +192OS T 73.319 |] XKB2 +192OS T 73.615 |] 0.180 6 XKB4 +192OS T 73.819 |] XKO23 +192OS T +192OS T 7.822-12.92 1.525 25 XL (total) +192OS T 7.822 XLL +192OS T 8.9- XLA +192OS T -12.92 XLG +192OS T +192OS T 47.71-51.892 |] KLL AUGER +192OS T 57.759-62.955 |] 0.196 19 ^KLX AUGER +192OS T 67.77-73.78 |] KXY AUGER +192OS T 4.8-12.86 L AUGER +192IR P 0.0 4+ 73.827 D 13 1046.2 23 +192OS N 2.053E1 2.053E1 0.0487 2.053E1 +192OS G 214.7 5 +192OS G 314.8 3 +192OS G 415.4 5 +192OS G 739 +192OS L 0 0+ STABLE +192OS L 205.79430 9 2+ 0.277 NS 4 +192OS G 205.79430 9 3.34 4 E2 0.305 9 +192OS2 G KC=0.157 5$LC=0.111 3$MC=0.0281 8 +192OS L 489.0602 6 2+ 0.0321 NS 10 +192OS G 283.2668 8 0.266 3 E2+M1 0.123 4 +192OS2 G KC=0.081 4$LC=0.0318 8$MC=0.00785 20 +192OS G 489.06 3 0.438 14E2 0.0243 7 +192OS2 G KC=0.0182 5$LC=0.00471 14$MC=0.00114 3 +192OS L 580.2798 8 4+ 0.0147 NS 4 +192OS E 0.686 9 9.5 +192OS2 E EAV= $CK=0.777 2$CL=0.168 2$CM=0.055 1$CN= $CO= +192OS G 374.4852 8 0.726 6 E2 0.0490 15 +192OS2 G KC=0.0341 10$LC=0.0113 3$MC=0.00276 8 +192OS L 690.3705 4 3+ +192OS E 3.97 3 8.5 +192OS2 E EAV= $CK=0.758 2$CL=0.182 2$CM=0.060 1$CN= $CO= +192OS G 110.4 3 0.0122 11E2+M1 3.65 11 +192OS2 G KC=2.03 6$LC=1.22 4$MC=0.306 9 +192OS G 201.3112 7 0.473 8 E2+M1 0.387 10 +192OS2 G KC=0.228 11$LC=0.120 3$MC=0.0301 8 +192OS G 484.5751 4 3.189 24E2+M1 0.0263 8 +192OS2 G KC=0.0198 6$LC=0.00499 14$MC=0.00120 4 +192OS L 909.58 6 4+ 0.010 NS 5 +192OS E 0.095 4 9.5 +192OS2 E EAV= $CK=0.537 9$CL=0.339 14$CM=0.124 5$CN= $CO= +192OS G 329.17 150.0174 17E2+M1 0.094 7 +192OS2 G KC=0.069 7$LC=0.0195 10$MC=0.00472 24 +192OS G 420.52 6 0.069 7 [E2] 0.0358 11 +192OS2 G KC=0.0258 8$LC=0.00762 23$MC=0.00186 6 + +192PT 192IR B- DECAY (73.827 D) +192PT H TYP=Full$AUT=E. Browne$CUT= -- $ +192PT C Evaluation history: Type=Full;Author=E. Browne;Cutoff date= -- +192PT T Auger electrons and ^X ray energies and emission intensities: +192PT T {U Energy (keV)} {U Intensity } {U Line } +192PT T +192PT T 65.123 2.66 5 XKA2 +192PT T 66.833 4.55 8 XKA1 +192PT T +192PT T 75.369 |] XKB3 +192PT T 75.749 |] 1.58 3 XKB1 +192PT T 76.234 |] XKB5II +192PT T +192PT T 77.786 |] XKB2 +192PT T 78.07 |] 0.411 10 XKB4 +192PT T 78.337 |] XKO23 +192PT T +192PT T 9.4-13.8 3.96 6 XL (total) +192PT T 9.4- XLA +192PT T -13.8 XLG +192PT T +192PT T 50.399-55.021 |] KLL AUGER +192PT T 61.116-66.829 |] 0.39 4 ^KLX AUGER +192PT T 71.8-78.39 |] KXY AUGER +192PT T 4.9-13.9 L AUGER +192IR P 0.0 4+ 73.827 D 13 1459.7 19 +192PT N 1.051E0 1.051E0 0.9513 1.051E0 +192PT G 214.7 5 +192PT G 314.8 3 +192PT G 415.4 5 +192PT G 739 +192PT L 0 0+ STABLE +192PT L 316.0641 212+ 0.0437 NS 12 +192PT G 316.50618 1782.75 21E2 0.0849 25 +192PT2 G KC=0.0537 16$LC=0.0236 7$MC=0.00591 17 +192PT L 612.46283 212+ 0.0265 NS 15 +192PT G 295.95650 1528.72 14E2+M1 0.106 3 +192PT2 G KC=0.0654 20$LC=0.0305 9$MC=0.00767 23 +192PT G 612.4621 3 5.34 8 E2 0.0155 5 +192PT2 G KC=0.0119 4$LC=0.00278 8$MC=6.69E-4 20 +192PT L 784.5757 3 4+ 0.0042 NS 2 +192PT B 675.1 1947.9 3 8.5 +192PTS B EAV=209.9 7 +192PT G 468.0688 3 47.81 24E2 0.0295 9 +192PT2 G KC=0.0213 6$LC=0.00617 19$MC=0.00151 5 +192PT L 920.91815 243+ 0.0213 NS 21 +192PT B 538.8 1941.4 3 8.3 +192PTS B EAV=162.1 7 +192PT G 136.3426 3 0.199 25E2+M1 1.56 6 +192PT2 G KC=0.57 8$LC=0.747 22$MC=0.192 6 +192PT G 308.45507 1729.68 15E2+M1 0.096 3 +192PT2 G KC=0.0608 18$LC=0.0262 8$MC=0.00657 20 +192PT G 604.41105 258.20 4 E2+M1 0.0266 8 +192PT2 G KC=0.0213 6$LC=0.00403 12$MC=0.00095 3 +192PT L 1201.0450 5 4+ +192PT B 258.7 195.59 3 8.1 +192PTS B EAV=71.6 6 +192PT G 280.27 240.009 5 E2+M1 0.16 7 +192PT2 G KC=0.11 7$LC=0.039 11$MC=0.0098 25 +192PT G 416.4688 7 0.669 21E2+M1 0.050 4 +192PT2 G KC=0.037 4$LC=0.0099 6$MC=0.00242 13 +192PT G 588.5810 7 4.517 22E2 0.0170 5 +192PT2 G KC=0.0129 4$LC=0.00311 9$MC=7.51E-4 23 +192PT G 884.5365 7 0.291 7 E2 0.0070721 +192PT2 G KC=0.00566 17$LC=0.00108 3$MC=2.54E-4 8 +192PT L 1378.02 3 3- 0.064 NS 18 +192PT B 81.7 190.1026 23 8.3 1 +192PTS B EAV=21.1 5 +192PT G 176.98 4 0.0043 12[E1] 0.097 3 +192PT2 G KC=0.0786 24$LC=0.0137 4$MC=0.00215 6 +192PT G 593.49 130.0421 17E1+M2 0.0067 4 +192PT2 G KC=0.0055 4$LC=0.00087 6$MC=3.27E-4 14 +192PT G 765.8 3 0.0013 6 E1+M2 0.0052 14 +192PT2 G KC=0.0043 11$LC=0.00070 19$MC=0.00014 4 +192PT G 1061.48 4 0.053 1 E1+M2 0.001979 +192PT2 G KC=0.00166 7$LC=2.43E-4 11$MC=5.8E-5 3 +192PT G 1378.20 150.0012 3 [E3] 0.0062019 +192PT2 G KC=0.00492 15$LC=0.00098 3$MC=2.32E-4 7 +192PT L 1383.99 15(5)- +192PT B 75.7 190.0039 17 9.6 1 +192PTS B EAV=19.5 5 +192PT G 599.41 150.0039 17E1 0.0059018 +192PT2 G KC=0.00481 14$LC=7.52E-4 23$MC=2.84E-4 9 +192PT L 1406.24 11(3)+ +192PT B 53.5 190.0033 5 9.2 +192PTS B EAV=13.6 5 +192PT G 1089.9 3 0.0012 2 E2+M1 0.0063 6 +192PT2 G KC=0.0052 5$LC=0.00087 8$MC=2.01E-4 18 + diff --git a/HEN_HOUSE/spectra/lnhb/Ir-194.txt b/HEN_HOUSE/spectra/lnhb/Ir-194.txt new file mode 100644 index 000000000..2b606727b --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Ir-194.txt @@ -0,0 +1,212 @@ +194PT 194IR B- DECAY (19.3 H) +194PT T Auger electrons and ^X ray energies and emission intensities: +194PT T {U Energy (keV)} {U Intensity } {U Line } +194PT T +194PT T 65.123 0.24 3 XKA2 +194PT T 66.833 0.41 5 XKA1 +194PT T +194PT T 75.369 |] XKB3 +194PT T 75.749 |] 0.00138 19 XKB1 +194PT T 76.234 |] XKB5II +194PT T +194PT T 77.786 |] XKB2 +194PT T 78.07 |] 0.00040 5 XKB4 +194PT T 78.337 |] XKO23 +194PT T +194PT T 8.268-13.361 0.36 6 XL (total) +194PT T 8.268 XLL +194PT T -13.361 XLG +194PT T +194PT T 50.4-55.02 |] KLL AUGER +194PT T 61.12-64.62 |] 0.035 4 ^KLX AUGER +194PT T 71.7-74.1 |] KXY AUGER +194IR P 0.0 1- 19.3 H 1 2246.8 16 +194PT N 1.0 1.0 1 1.0 +194PT G 1675.24 170.00086 18 +194PT G 2207 1 0.0013 4 +194PT L 0 0+ STABLE +194PT B 2246.9 1685.4 19 8.2 1 +194PTS B EAV=845.7 7 +194PT L 328.449 2+ 41.8 PS +194PT B 1918.5 169.3 13 8.9 1 +194PTS B EAV=705.4 7 +194PT G 328.448 1413.1 17E2 0.076 2 +194PT2 G KC=0.049 2$LC=0.020 1$MC=0.0070 2 +194PT L 621.99 2+ 35 PS +194PT B 1624.9 161.28 20 9.5 1 +194PTS B EAV=582.2 7 +194PT G 293.541 142.5 3 E2+M1+ 0.107 3 +194PT2 G KC=0.066 2$LC=0.031 1$MC=0.010 1 +194PT G 621.971 190.33 5 E2 0.0150 5 +194PT2 G KC=0.0115 4$LC=0.0025 1$MC= +194PT L 811.33 4+ +194PT G 482.857 260.046 6 E2 0.0272 8 +194PT2 G KC=0.0200 6$LC=0.0056 2$MC=0.0016 1 +194PT L 922.739 3+ +194PT B 1324.2 160.30 4 10.5 1U +194PTS B EAV=452.4 6 +194PT G 111.4 4 0.0017 6 [M1E2] 4.1 10 +194PT2 G KC=2.4 18$LC=1.3 7$MC=0.40 18 +194PT G 300.741 140.35 5 E2(+M1) 0.103 4 +194PT2 G KC=0.061 2$LC=0.028 1$MC=0.014 1 +194PT G 594.291 190.062 8 E2(+M1) 0.0166 5 +194PT2 G KC=0.0126 4$LC=0.0030 1$MC=0.0010 1 +194PT L 1229.6 4+ +194PT G 607.61 8 0.0039 6 E2 0.0158 5 +194PT2 G KC=0.0121 4$LC=0.0028 1$MC=0.0010 1 +194PT L 1267.145 0+ +194PT B 979.8 161.77 23 8.6 1 +194PTS B EAV=323.1 6 +194PT G 645.146 201.18 16E2 0.0138 4 +194PT2 G KC=0.0106 3$LC=0.0024 1$MC= +194PT G 938.690 250.60 8 E2 0.0062719 +194PT2 G KC=0.0050 2$LC=0.00090 3$MC= +194PT L 1432.49 3- +194PT G 202.91 150.0030 8 E1 0.068 2 +194PT2 G KC=0.056 2$LC=0.0093 3$MC=0.0027 1 +194PT G 621.29 150.0096 18E1+M2 0.0091 18 +194PT2 G KC=0.0074 15$LC=0.0013 3$MC= +194PT G 810.66 190.0025 6 [E1] 0.0032 1 +194PT2 G KC=0.0027 1$LC=$MC= +194PT G 1104.05 5 0.026 4 E1 0.001785 +194PT2 G KC=0.00149 5$LC=$MC= +194PT G 1432.52 120.0011 3 [E3] 0.0057117 +194PT2 G KC=0.00455 14$LC=$MC= +194PT L 1479.2 0+ +194PT B 767.7 160.61 8 8.7 1 +194PTS B EAV=243.4 6 +194PT G 1479.2 +194PT G 857.12 190.0071 12[E2] 0.0075 2 +194PT2 G KC=0.0060 2$LC=$MC= +194PT G 1150.75 5 0.60 8 E2 0.0042013 +194PT2 G KC=0.00342 10$LC=$MC= +194PT L 1511.927 2+ +194PT B 735.0 160.56 7 8.6 1 +194PTS B EAV=231.5 6 +194PT G 244.83 5 0.0077 11E2 0.186 6 +194PT2 G KC=0.102 3$LC=0.063 2$MC=0.020 1 +194PT G 589.179 170.140 18E2+M1 0.0231 24 +194PT2 G KC=0.0181 5$LC=0.0037 3$MC=0.0013 1 +194PT G 700.55 4 0.026 5 E2 0.0115 4 +194PT2 G KC=0.0089 3$LC=0.0019 1$MC= +194PT G 889.98 4 0.051 7 E2+M1 0.0105 17 +194PT2 G KC=0.0085 14$LC=0.0015 2$MC= +194PT G 1183.49 5 0.31 4 E2+M1 0.0057917 +194PT2 G KC=0.00476 14$LC=$MC= +194PT G 1511.98 100.024 4 (E2) 0.002497 +194PT2 G KC=0.00208 6$LC=$MC= +194PT L 1547.24 0+ +194PT B 699.7 160.070 9 9.5 1 +194PTS B EAV=218.7 6 +194PT G 925.26 6 0.0126 18E2 0.0065 2 +194PT2 G KC=0.0052 2$LC=$MC= +194PT G 1218.78 5 0.056 8 E2 0.0037611 +194PT2 G KC=0.00307 9$LC=$MC= +194PT L 1622.13 2+ +194PT B 624.8 160.160 21 8.9 1 +194PTS B EAV=192.0 6 +194PT G 699.5 4 0.0025 13[M1E2] 0.023 11 +194PT2 G KC=0.019 10$LC=0.0032 14$MC= +194PT G 1000.12 4 0.047 6 E2+M1 0.0083 18 +194PT2 G KC=0.0068 15$LC=0.00113 21$MC= +194PT G 1293.67 6 0.046 7 M1+E2 0.02 1 +194PT2 G KC=0.016 8$LC=$MC= +194PT G 1622.20 180.064 9 +194PT L 1670.64 2+ +194PT B 576.3 160.072 10 9.2 1 +194PTS B EAV=175.0 6 +194PT G 859.45 180.0017 8 [E2] 0.0075 2 +194PT2 G KC=0.0060 2$LC=$MC= +194PT G 1048.64 5 0.026 4 M1(+E2) 0.011 1 +194PT2 G KC=0.0077 24$LC=0.0012 40$MC= +194PT G 1342.16 6 0.038 5 M1+E2 0.005 2 +194PT2 G KC=0.0040 15$LC=$MC= +194PT G 1670.72 100.0058 8 +194PT L 1778.67 1,2+ +194PT B 468.2 160.0035 6 10.2 +194PTS B EAV=138.2 5 +194PT G 1156.6 3 0.0018 5 M1(+E2) 0.0088 19 +194PT2 G KC=0.0073 16$LC=$MC= +194PT G 1450.23 110.0016 3 M1+E2 0.0040 3 +194PT2 G KC=0.0033 3$LC=$MC= +194PT L 1797.355 1- +194PT B 449.5 160.33 4 8.2 +194PTS B EAV=132.0 5 +194PT G 364.867 150.041 6 E2 0.0568 17 +194PT2 G KC=0.038 11$LC=0.014 1$MC=0.0050 2 +194PT G 530.173 300.016 2 E1 0.0073522 +194PT2 G KC=0.0061 2$LC=0.00094 3$MC=0.00031 1 +194PT G 1175.38 5 0.061 8 E1 0.001595 +194PT2 G KC=0.00133 4$LC=$MC= +194PT G 1468.91 7 0.19 3 E1 0.001093 +194PT2 G KC=0.00092 3$LC=$MC= +194PT G 1797.48 9 0.0176 2 +194PT L 1893.59 (0)+ +194PT B 353.3 160.021 3 9 1 +194PTS B EAV=10.9 5 +194PT G 1565.15 8 0.021 3 +194PT L 1924.29 1+ +194PT B 322.6 160.0035 5 9.6 +194PTS B EAV=91.2 5 +194PT G 1595.77 100.0016 3 +194PT G 1924.42 140.0018 3 +194PT L 1930.25 (2)+ +194PT B 316.6 160.0032 5 9.7 1 +194PTS B EAV=89.3 5 +194PT G 1308.15 120.00130 22E2(+M1) 0.0039 6 +194PT2 G KC=0.0032 5$LC=$MC= +194PT G 1601.90 120.0020 3 +194PT L 2043.72 1+ +194PT B 203.2 160.0090 13 8.6 +194PTS B EAV=55.1 5 +194PT G 1421.48 280.00063 21M1(+E2) 0.0052 13 +194PT2 G KC=0.0043 10$LC=$MC= +194PT G 1715.28 110.00131 21 +194PT G 2043.72 110.0071 10 +194PT L 2053.08 (<=3)+ +194PT B 193.8 160.0030 8 9 1U +194PTS B EAV=52.4 5 +194PT G 1431.35 340.0022 7 +194PT G 1724.54 150.00076 14 +194PT L 2063.81 1,2+ +194PT B 183.1 160.0040 6 8.8 +194PTS B EAV=49.3 5 +194PT G 1441.78 140.0015 3 M1+E2 0.0041 5 +194PT2 G KC=0.0034 4$LC=$MC= +194PT G 1735.37 120.0025 4 +194PT L 2085.6 0+ +194PT B 161.3 160.0066 15 8.4 1 +194PTS B EAV=43.1 4 +194PT G 1463.50 150.0059 14E2 0.002678 +194PT2 G KC=0.00220 7$LC=$MC= +194PT G 1757.27 190.00042 11 +194PT L 2109.08 1,2+ +194PT B 137.8 160.031 4 7.5 +194PTS B EAV=36.5 5 +194PT G 1186.4 4 0.0084 19E2(+M1) 0.0056 17 +194PT2 G KC=0.0046 14$LC=$MC= +194PT G 1487.05 8 0.0170 23M1(+E2) 0.0045 12 +194PT2 G KC=0.0037 10$LC=$MC= +194PT G 1780.69 110.0052 8 +194PT L 2114.17 1+ +194PT B 132.7 160.0081 11 8.1 +194PTS B EAV=35.0 5 +194PT G 1492.18 130.0015 3 M1(+E2) 0.0045 12 +194PT2 G KC=0.0037 10$LC=$MC= +194PT G 1785.69 110.0040 6 +194PT G 2114.20 140.0026 4 +194PT L 2134.2 (0,1,2)+ +194PT B 112.7 160.046 6 7.1 1 +194PTS B EAV=29.5 4 +194PT G 1512.15 210.0132 18 +194PT G 1805.75 9 0.032 5 +194PT L 2140.83 (0,1,2)+ +194PT B 106.1 160.0021 4 8.4 1 +194PTS B EAV=27.7 4 +194PT G 1518.76 140.0017 3 +194PT G 1812.59 250.00045 14 +194PT L 2158.05 1,2+ +194PT B 88.9 160.0019 3 8.2 +194PTS B EAV=23.0 4 +194PT G 1829.59 150.0019 3 + diff --git a/HEN_HOUSE/spectra/lnhb/K-40.txt b/HEN_HOUSE/spectra/lnhb/K-40.txt new file mode 100644 index 000000000..b3e426dd4 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/K-40.txt @@ -0,0 +1,67 @@ + 40AR 40K EC DECAY (1.2504E9 Y) + 40AR H TYP=Upadte$AUT=M.M. Bé$CUT= -- $ + 40AR2 H TYP=Update$AUT=X. Mougeot$CUT=30-APR-2009$ + 40AR C Evaluation history: Type=Upadte;Author=M.M. Bé;Cutoff date= -- + 40AR2C Type=Update;Author=X. Mougeot;Cutoff date=30-APR-2009 + 40AR C References: 1947GL07, 1950SA52, 1953BU58, 1955BA25, 1955KO21, 1955SU38, + 40AR2C 1956MC20, 1957WE43, 1959KE26, 1959Ti20, 1960SA31, 1961GL07, 1962FL05, + 40AR3C 1962EN01, 1965BR25, 1965LE15, 1966FE09, 1967KI10, 1970JA15, 1977CE04, + 40AR4C 1979HE13, 1990EN08, 2001BE81, 2003AU03, 2004KO09, 2008KI07 + 40AR T Auger electrons and ^X ray energies and emission intensities: + 40AR T {U Energy (keV)} {U Intensity } {U Line } + 40AR T + 40AR T 2.95566 0.299 9 XKA2 + 40AR T 2.95774 0.592 17 XKA1 + 40AR T + 40AR T 3.1905 |] 0.096 4 XKB1 + 40AR T + 40AR T + 40AR T 0.2195-0.3114 0.003 1 XL (total) + 40AR T 0.2195 XLL + 40AR T 0.2215 XLC + 40AR T 0.3112-0.3114 XLB + 40AR T + 40AR T 2.511-2.669 |] KLL AUGER + 40AR T 2.831-2.942 |] 7.24 11 ^KLX AUGER + 40AR T 3.149-3.174 |] KXY AUGER + 40AR T 0.17-0.31 2.22 2 L AUGER + 40K P 0.0 4- 1.2504E9 Y30 1504.69 19 + 40AR N 9.302E0 9.302E0 0.1075 179.302E0 + 40AR L 0 0+ STABLE + 40AR E 0.00100 120.2 1 21.35 3U + 40AR2 E EAV= $CK=0.88 $CL=0.086 $CM=0.013 $CN= $CO= + 40AR L 1460.851 6 2+ 0.00161 NS6 + 40AR E 10.55 1111.55 1U + 40AR2 E EAV= $CK=0.763 $CL=0.209 $CM=0.027 $CN= $CO= + 40AR G 1460.822 6 10.55 11E2 1028E-715 + 40AR2 G KC=2.63E-5 4$LC=2.15E-6 3$MC=2.10E-7 3 + + 40CA 40K B- DECAY (1.2504E9 Y) + 40CA H TYP=Upadte$AUT=M.M. Bé$CUT= -- $ + 40CA2 H TYP=Update$AUT=X. Mougeot$CUT=30-APR-2009$ + 40CA C Evaluation history: Type=Upadte;Author=M.M. Bé;Cutoff date= -- + 40CA2C Type=Update;Author=X. Mougeot;Cutoff date=30-APR-2009 + 40CA C References: 1947GL07, 1950SA52, 1953BU58, 1955BA25, 1955KO21, 1955SU38, + 40CA2C 1956MC20, 1957WE43, 1959KE26, 1959Ti20, 1960SA31, 1961GL07, 1962FL05, + 40CA3C 1962EN01, 1965BR25, 1965LE15, 1966FE09, 1967KI10, 1970JA15, 1977CE04, + 40CA4C 1979HE13, 1990EN08, 2001BE81, 2003AU03, 2004KO09, 2008KI07 + 40CA T Auger electrons and ^X ray energies and emission intensities: + 40CA T {U Energy (keV)} {U Intensity } {U Line } + 40CA T + 40CA T 3.68813 XKA2 + 40CA T 3.69172 XKA1 + 40CA T + 40CA T 4.0128 |] XKB1 + 40CA T 4.0325 |] XKB5II + 40CA T + 40CA T + 40CA T + 40CA T 3.123-3.307 |] KLL AUGER + 40CA T 3.543-3.666 |] ^KLX AUGER + 40CA T 3.951-3.987 |] KXY AUGER + 40K P 0.0 4- 1.2504E9 Y30 1311.07 11 + 40CA N 1.12E0 1.12E0 0.8925 171.12E0 + 40CA L 0 0+ STABLE + 40CA B 1311.07 1189.25 17 20.58 3U + 40CAS B EAV=508.32 6 + diff --git a/HEN_HOUSE/spectra/lnhb/Kr-85.txt b/HEN_HOUSE/spectra/lnhb/Kr-85.txt new file mode 100644 index 000000000..dd35d59d6 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Kr-85.txt @@ -0,0 +1,37 @@ + 85RB 85KR B- DECAY (10.752 Y) + 85RB H TYP=update$AUT=V. Chisté$CUT= -- $ + 85RB C Evaluation history: Type=update;Author=V. Chisté;Cutoff date= -- + 85RB T Auger electrons and ^X ray energies and emission intensities: + 85RB T {U Energy (keV)} {U Intensity } {U Line } + 85RB T + 85RB T 13.3359 0.000540 14 XKA2 + 85RB T 13.3955 0.001040 25 XKA1 + 85RB T + 85RB T 14.9519 |] XKB3 + 85RB T 14.9614 |] 0.000253 7 XKB1 + 85RB T 15.085 |] XKB5II + 85RB T + 85RB T 15.1856 |] XKB2 + 85RB T 15.205 |] 0.0000294 13 XKB4 + 85RB T + 85RB T + 85RB T 10.987-11.503 |] KLL AUGER + 85RB T 12.782-13.381 |] 0.000901 24 ^KLX AUGER + 85RB T 14.556-15.172 |] KXY AUGER + 85RB T 1.1-2 0.00336 6 L AUGER + 85KR P 0.0 9/2+ 10.752 Y 23 687.1 19 + 85RB N 1.0 1.0 1 1.0 + 85RB L 0 5/2- STABLE + 85RB B 687.1 1999.562 10 8.4 3U + 85RBS B EAV=251.4 8 + 85RB L 151.18 3 3/2- 0.71 NS 5 + 85RB G 151.18 3 2.2E-6 13M1+()E2 0.072 8 0.0488 14 + 85RB2 G KC=0.0430 13$LC=0.00485 14$MC=8.17E-4 25 + 85RB L 513.998 5 9/2+ 1.015 US 1 + 85RB B 173.1 190.438 10 9.5 + 85RBS B EAV=47.5 6 + 85RB G 362.81 4 2.18E-6 44(E3) 0.034 1 + 85RB2 G KC=0.0292 9$LC=0.00400 12$MC=0.00067 2 + 85RB G 513.997 5 0.435 10M2 0.0072122 + 85RB2 G KC=0.00635 19$LC=0.00072 2$MC=1.22E-4 4 + diff --git a/HEN_HOUSE/spectra/lnhb/La-138.txt b/HEN_HOUSE/spectra/lnhb/La-138.txt new file mode 100644 index 000000000..0c0d12210 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/La-138.txt @@ -0,0 +1,84 @@ +138BA 138LA EC DECAY (103.6E9 Y) +138BA H TYP=Upd$AUT=X. Mougeot$CUT=01-MAY-2016$ +138BA2 H TYP=Full$AUT=M.M. Bé$CUT=01-NOV-2013$ +138BA C Evaluation history: Type=Upd;Author=X. Mougeot;Cutoff date=01-MAY-2016 +138BA2C Type=Full;Author=M.M. Bé;Cutoff date=01-NOV-2013 +138BA C References: 1956Tu17, 1957Gl20, 1966De04, 1972Ma31, 1972El02, 1979Ta21, +138BA2C 1981Sa42, 1983No02, 1984Ma46, 1997Ni12, 2002Ba85, 2005Be73, 2008Ki07, +138BA3C 2012Qu02, 2012Wa38, 2016Qu01 +138BA T Auger electrons and X ray energies and emission intensities: +138BA T {U Energy (keV)} {U Intensity} {U Line} +138BA T +138BA T 31.8174 10.63 15 XKA2 +138BA T 32.1939 19.58 26 XKA1 +138BA T +138BA T 36.3045 |] XKB3 +138BA T 36.3786 |] 5.76 10 XKB1 +138BA T 36.654 |] XKB5II +138BA T +138BA T 37.258 |] XKB2 +138BA T 37.312 |] 1.45 4 XKB4 +138BA T 37.425 |] XKO23 +138BA T +138BA T 3.9544-5.8104 6.03 10 XL (total) +138BA T 3.9544 0.1201 30 XLL +138BA T 4.4515-4.4666 3.11 8 XLA +138BA T 4.3307 0.0367 10 XLC +138BA T 4.8278-5.207 2.39 5 XLB +138BA T 5.3715-5.8104 0.380 8 XLG +138BA T +138BA T 25.314-26.786 |] KLL AUGER +138BA T 30.095-32.179 |] 4.16 18 KLX AUGER +138BA T 34.86-37.41 |] KXY AUGER +138BA T 2.66-5.81 48.8 4 L AUGER +138LA P 0.0 5+ 103.6E9 Y 20 1740.0 34 +138BA N 1.534E0 1.534E0 0.652 6 1.534E0 +138BA L 0 0+ STABLE +138BA L 1435.816 102+ +138BA E 65.2 6 17.2 2U +138BA2 E EAV= $CK=0.637 5$CL=0.275 3$CM=0.0880 11$CN= $CO= +138BA G 1435.795 1065.1 6 E2 9.17E-413 +138BA2 G KC=7.42E-4 11$LC=9.37E-5 14$MC=1.92E-5 3 + +138CE 138LA B- DECAY (103.6E9 Y) +138CE H TYP=Upd$AUT=X. Mougeot$CUT=01-MAY-2016$ +138CE2 H TYP=Full$AUT=M.M. Bé$CUT=01-NOV-2013$ +138CE C Evaluation history: Type=Upd;Author=X. Mougeot;Cutoff date=01-MAY-2016 +138CE2C Type=Full;Author=M.M. Bé;Cutoff date=01-NOV-2013 +138CE C References: 1956Tu17, 1957Gl20, 1966De04, 1972Ma31, 1972El02, 1979Ta21, +138CE2C 1981Sa42, 1983No02, 1984Ma46, 1997Ni12, 2002Ba85, 2005Be73, 2008Ki07, +138CE3C 2012Qu02, 2012Wa38, 2016Qu01 +138CE T Auger electrons and X ray energies and emission intensities: +138CE T {U Energy (keV)} {U Intensity} {U Line} +138CE T +138CE T 34.2793 0.0261 6 XKA2 +138CE T 34.72 0.0478 11 XKA1 +138CE T +138CE T 39.1705 |] XKB3 +138CE T 39.2578 |] 0.0144 4 XKB1 +138CE T 39.549 |] XKB5II +138CE T +138CE T 40.233 |] XKB2 +138CE T 40.337 |] 0.00365 12 XKB4 +138CE T 40.423 |] XKO23 +138CE T +138CE T 4.2868-6.3412 0.01301 29 XL (total) +138CE T 4.2868 2.52E-4 9 XLL +138CE T 4.822-4.8411 0.00642 20 XLA +138CE T 4.7274 9.54E-5 29 XLC +138CE T 5.2625-5.665 0.00538 12 XLB +138CE T 5.8755-6.3412 0.00085 2 XLG +138CE T +138CE T 27.19-28.828 |] KLL AUGER +138CE T 32.392-34.7 |] 0.0091 5 KLX AUGER +138CE T 37.57-40.4 |] KXY AUGER +138CE T 2.85-6.51 0.0895 7 L AUGER +138LA P 0.0 5+ 103.6E9 Y 20 1051.8 21 +138CE N 2.874E0 2.874E0 0.348 6 2.874E0 +138CE L 0 0+ STABLE +138CE L 788.744 8 2+ +138CE B 263.1 2134.8 6 18.7 2U +138CES B EAV=91.1 11 +138CE G 788.742 8 34.7 6 E2 0.003425 +138CE2 G KC=0.00291 4$LC=4.06E-4 6$MC=8.52E-5 12 + diff --git a/HEN_HOUSE/spectra/lnhb/La-140.txt b/HEN_HOUSE/spectra/lnhb/La-140.txt new file mode 100644 index 000000000..d6dfed752 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/La-140.txt @@ -0,0 +1,168 @@ +140CE 140LA B- DECAY (1.67858 D) +140CE H TYP=Update$AUT=M.M.Bé$CUT=19-JUN-2008$ +140CE C Evaluation history: Type=Update;Author=M.M.Bé;Cutoff date=19-JUN-2008 +140CE C References: 1954Ya02, 1954Ki08, 1957Pe09, 1960Wi10, 1962Ha14, 1964Re09, +140CE2C 1965Si17, 1967Ka12, 1966Dz05, 1968Gu05, 1968Re04, 1968Ba18, 1969GuZV, +140CE3C 1970Ke06, 1970Ka18, 1972GeZG, 1974HeYW, 1975Ha50, 1976Li06, 1977Ge12, +140CE4C 1977DeYO, 1977De34, 1978Ar28, 1978Da21, 1979Bo26, 1980Ho17, 1980Ka32, +140CE5C 1980Ol03, 1982HoZJ, 1982Ad02, 1983Wa26, 1989Ab18, 1991Ch05, 1992Un01, +140CE6C 1998Si17, 2002Ad04, 2002Ba85, 2002Un02, 2004BeZR, 2007Ni07, 2008Ki07, +140CE7C 2012Fi12, 2012Wa38, 2014Un01 +140CE T Auger electrons and ^X ray energies and emission intensities: +140CE T {U Energy (keV)} {U Intensity } {U Line } +140CE T +140CE T 34.2793 0.591 8 XKA2 +140CE T 34.72 1.082 13 XKA1 +140CE T +140CE T 39.1705 |] XKB3 +140CE T 39.2578 |] 0.326 6 XKB1 +140CE T 39.549 |] XKB5II +140CE T +140CE T 40.233 |] XKB2 +140CE T 40.337 |] 0.0828 21 XKB4 +140CE T +140CE T 4.2868-6.3412 0.343 7 XL (total) +140CE T 4.2868 0.00666 20 XLL +140CE T 4.822-4.8411 0.170 5 XLA +140CE T 4.7274 0.00258 6 XLC +140CE T 5.2625-5.6103 0.1422 25 XLB +140CE T 5.8755-6.3412 0.0222 5 XLG +140CE T +140CE T 27.19-28.828 |] KLL AUGER +140CE T 32.392-34.7 |] 0.206 10 ^KLX AUGER +140CE T 37.57-40.4 |] KXY AUGER +140CE T 2.8-6.5 2.360 13 L AUGER +140LA P 0.0 3- 1.67858 D 21 3760.9 18 +140CE N 1.0 1.0 1 1.0 +140CE L 0 0+ STABLE +140CE L 1596.213 132+ 0.0916 PS 19 +140CE B 2164.7 184.5 6 9.4 1 +140CES B EAV=846.4 8 +140CE G 1596.203 1395.40 5 E2 7.87E-413 +140CE2 G KC=6.76E-4 10$LC=8.63E-5 12$MC=1.79E-5 3 +140CE L 1903.29 4 0+ 0.40 NS 3 +140CE G 307.08 4 0.022 5 E2 0.0450 7 +140CE2 G KC=0.0362 6$LC=0.00695 10$MC=1495E-6 21 +140CE G 1903.29 4 +140CE L 2083.236 144+ 3.45 NS 3 +140CE B 1677.7 1820.8 6 8.3 1 +140CES B EAV=629.7 8 +140CE G 487.022 6 46.1 5 E2 0.0115617 +140CE2 G KC=0.00963 14$LC=1526E-6 22$MC=3.24E-4 5 +140CE G 2083.219 140.036 7 E4 1364E-619 +140CE2 G KC=1162E-6 17$LC=1598E-7 23$MC=3.35E-5 5 +140CE L 2107.830 146+ 7.3 US 15 +140CE G 24.595 4 6.89E-4 19E2 696 10 +140CE2 G KC=$LC=545 8$MC=122.0 18 +140CE L 2347.868 142+ +140CE B 1413.0 185.03 12 8.6 1 +140CES B EAV=515.0 8 +140CE G 444.57 4 0.003 1 [E2] 0.0149021 +140CE2 G KC=0.01234 18$LC=0.00202 3$MC=4.29E-4 6 +140CE G 751.653 7 4.39 5 M1+E2 0.38 4 0.005489 +140CE2 G KC=0.00471 8$LC=6.13E-4 10$MC=1277E-7 20 +140CE G 2347.847 140.845 16E2 3.86E-45 +140CE2 G KC=3.33E-4 5$LC=4.15E-5 6$MC=8.60E-6 12 +140CE L 2349.789 145+ +140CE B 1411.1 180.262 22 10.7 1U +140CES B EAV=518.8 8 +140CE G 241.959 6 0.436 10M1+E2 0.60 35 0.1005 18 +140CE2 G KC=0.084 3$LC=0.0130 11$MC=0.00275 25 +140CE G 266.554 5 0.492 9 M1+E2 0.14 12 0.0785 12 +140CE2 G KC=0.0671 11$LC=0.00906 17$MC=0.00190 4 +140CE L 2411.997 143+ 55 PS 15 +140CE B 1348.9 1844.8 4 7.6 +140CES B EAV=487.6 8 +140CE G 64.129 4 0.014 2 M1 4.24 6 +140CE2 G KC=3.61 5$LC=0.499 7$MC=0.1046 15 +140CE G 328.761 4 20.8 3 M1+E2 0.049 6 0.0453 7 +140CE2 G KC=0.0388 6$LC=0.00516 8$MC=1078E-6 15 +140CE G 815.784 6 23.72 20M1+E2 0.03 1 0.004717 +140CE2 G KC=0.00405 6$LC=5.21E-4 8$MC=1085E-7 16 +140CE L 2464.055 213- 0.10 PS 2 +140CE B 1296.8 185.60 7 8.44 +140CES B EAV=465.6 8 +140CE G 867.839 165.58 7 E1+M2 0.044 20 0.001133 +140CE2 G KC=9.77E-4 22$LC=1.22E-4 3$MC=2.53E-5 7 +140CE G 2464.031 200.0097 13[E3] 5.98E-48 +140CE2 G KC=5.15E-4 8$LC=6.61E-5 10$MC=1375E-8 20 +140CE L 2480.910 144+ 3.2 NS 3 +140CE B 1280.0 181.14 2 9.1 1 +140CES B EAV=458.4 8 +140CE G 68.923 5 0.077 2 M1 3.44 5 +140CE2 G KC=2.93 5$LC=0.405 6$MC=0.0848 12 +140CE G 131.121 4 0.47 1 M1+E2 0.13 5 0.552 9 +140CE2 G KC=0.468 7$LC=0.0660 22$MC=0.0139 5 +140CE G 397.674 6 0.075 3 (E2) 0.0205 3 +140CE2 G KC=0.01689 24$LC=0.00288 4$MC=6.15E-4 9 +140CE L 2515.749 163+ +140CE B 1245.2 185.80 4 8.4 +140CES B EAV=443.8 8 +140CE G 432.513 8 3.00 3 M1+E2 0.54 5 0.0210 4 +140CE2 G KC=0.0179 4$LC=0.00245 4$MC=5.14E-4 8 +140CE G 919.533 102.73 3 M1+E2 2.6 4 0.002576 +140CE2 G KC=0.00219 6$LC=2.95E-4 7$MC=6.16E-5 13 +140CE L 2521.414 142+ +140CE B 1239.5 1811.11 9 8.1 1 +140CES B EAV=441.4 8 +140CE G 109.417 4 0.217 6 M1+E2 0.26 2 0.949 15 +140CE2 G KC=0.787 12$LC=0.128 4$MC=0.0271 8 +140CE G 173.546 5 0.126 5 M1 0.251 4 +140CE2 G KC=0.214 3$LC=0.0291 4$MC=0.00609 9 +140CE G 438.178 6 0.017 10M1 0.0217 3 +140CE2 G KC=0.0186 3$LC=0.00244 4$MC=5.10E-4 8 +140CE G 618.12 4 0.041 3 [E2] 0.006179 +140CE2 G KC=0.00520 8$LC=7.68E-4 11$MC=1619E-7 23 +140CE G 925.198 7 7.04 7 M1+E2 0.22 4 0.003446 +140CE2 G KC=0.00296 5$LC=3.81E-4 6$MC=7.92E-5 12 +140CE G 2521.390 143.41 5 E2 3.40E-45 +140CE2 G KC=2.94E-4 5$LC=3.65E-5 6$MC=7.56E-6 11 +140CE L 2547.205 231+ +140CE B 1213.7 180.636 7 10 1U +140CES B EAV=438.4 7 +140CE G 950.988 200.531 7 M1+E2 0.01 7 0.003285 +140CE2 G KC=0.00282 4$LC=3.61E-4 5$MC=7.52E-5 11 +140CE G 2547.180 230.102 2 M1 3.70E-45 +140CE2 G KC=3.20E-4 5$LC=3.98E-5 6$MC=8.24E-6 12 +140CE L 2899.56 7 2+ +140CE B 861.2 180.112 6 9.5 1 +140CES B EAV=287.3 7 +140CE G 1303.34 7 0.045 6 [M1+E2+] 0.0014 2 +140CE2 G KC=0.0012 2$LC=0.00015 2$MC=3.2E-5 5 +140CE G 2899.53 7 0.066 1 E2 2.66E-44 +140CE2 G KC=2.31E-4 4$LC=2.84E-5 4$MC=5.88E-6 9 +140CE L 3000.88 9 2+ +140CE B 760.0 180.085 9 9.4 1 +140CES B EAV=248.0 7 +140CE G 1097.58 9 0.023 5 [E2] 1658E-624 +140CE2 G KC=0.00142 2$LC=1.88E-4 3$MC=3.92E-5 6 +140CE G 1404.66 9 0.062 8 [M1+E2] 0.0011715 +140CE2 G KC=0.00101 15$LC=1.29E-4 18$MC=2.7E-5 4 +140CE L 3118.53 102+ +140CE B 642.5 180.027 1 9.6 1 +140CES B EAV=203.7 7 +140CE G 3118.49 100.026 1 (E2) 2.34E-43 +140CE2 G KC=2.04E-4 3$LC=2.50E-5 4$MC=5.18E-6 8 +140CE L 3319.56 242+ +140CE B 441.3 180.0039 3 9.9 1 +140CES B EAV=132.0 6 +140CE G 3319.52 240.0039 3 E2 2.11E-43 +140CE2 G KC=1.83E-4 3$LC=2.25E-5 4$MC=4.64E-6 7 +140CE L 3394.82 9 4- +140CE B 366.1 180.020 4 9 +140CES B EAV=106.7 6 +140CE G 1045.02 9 0.020 4 [E1] 7.81E-411 +140CE2 G KC=6.75E-4 10$LC=8.37E-5 12$MC=1733E-8 25 +140CE L 3473.55 183- +140CE B 287.4 180.052 7 8.2 +140CES B EAV=81.4 6 +140CE G 992.64 180.010 3 [E1] 8.60E-412 +140CE2 G KC=7.43E-4 11$LC=9.24E-5 13$MC=1.91E-5 3 +140CE G 1877.33 180.041 6 [E1] 2.84E-44 +140CE2 G KC=2.45E-4 4$LC=3.00E-5 5$MC=6.21E-6 9 +140CE L 3520.8 2 4+ +140CE B 240.1 180.011 3 8.6 1 +140CES B EAV=66.7 6 +140CE G 1924.5 2 0.011 3 [E2] 5.54E-48 +140CE2 G KC=4.78E-4 7$LC=6.01E-5 9$MC=1247E-8 18 + diff --git a/HEN_HOUSE/spectra/lnhb/Lu-177.txt b/HEN_HOUSE/spectra/lnhb/Lu-177.txt new file mode 100644 index 000000000..591be9c38 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Lu-177.txt @@ -0,0 +1,53 @@ +177HF 177LU B- DECAY (6.647 D) +177HF T Auger electrons and ^X ray energies and emission intensities: +177HF T {U Energy (keV)} {U Intensity } {U Line } +177HF T +177HF T 54.612 1.59 3 XKA2 +177HF T 55.7909 2.78 6 XKA1 +177HF T +177HF T 62.985 |] XKB3 +177HF T 63.234 |] 0.917 23 XKB1 +177HF T 63.662 |] XKB5II +177HF T +177HF T 64.942 |] XKB2 +177HF T 65.132 |] 0.245 8 XKB4 +177HF T 65.316 |] XKO23 +177HF T +177HF T 6.96-10.89 3.18 6 XL (total) +177HF T 6.96 0.0613 16 XLL +177HF T 7.844-7.899 1.35 3 XLA +177HF T 8.139 0.031 9 XLC +177HF T 8.905-9.342 1.49 5 XLB +177HF T 10.516-10.89 0.254 7 XLG +177HF T +177HF T 42.601-46.007 |] KLL AUGER +177HF T 51.391-55.784 |] 0.28 9 ^KLX AUGER +177HF T 60.15-65.34 |] KXY AUGER +177HF T 4.3-11.2 8.75 20 L AUGER +177LU P 0.0 7/2+ 6.647 D 4 498.3 8 +177HF N 1.0 1.0 1 1.0 +177HF L 0 7/2- STABLE +177HF B 498.3 8 79.3 5 6.7 +177HFS B EAV=149.4 3 +177HF L 112.9499 9/2- 0.506 NS +177HF B 385.4 8 9.1 5 7.3 1U +177HFS B EAV=111.7 3 +177HF G 112.9498 4 6.20 7 M1+E2 2.272 5 +177HF2 G KC=0.817 12$LC=1.104 6$MC=0.2755 14 +177HF L 249.6744 11/2- 105 PS +177HF B 248.6 8 0.012 8 9.2 3U +177HFS B EAV=78.6 3 +177HF G 136.7245 5 0.0470 7 M1+E2 1.158 18 +177HF2 G KC=0.559 21$LC=0.456 7$MC=0.1129 21 +177HF G 249.6742 6 0.2012 21E2 0.141000 +177HF2 G KC=9100E-5 0$LC=3800E-5 0$MC=9000E-6 0 +177HF L 321.3162 9/2+ 0.663 NS +177HF B 177.0 8 11.64 10 6.1 2 +177HFS B EAV=47.66 23 +177HF G 71.6418 6 0.1726 23E1+M2 0.894 22 +177HF2 G KC=0.715 14$LC=0.138 6$MC=0.0317 14 +177HF G 208.3662 4 10.38 7 E1+M2 0.068 5 +177HF2 G KC=0.055 4$LC=0.0094 10$MC=0.00216 24 +177HF G 321.3159 6 0.216 8 E1+M2 0.08 6 +177HF2 G KC=0.06 5$LC=0.012 10$MC=0.0028 22 + diff --git a/HEN_HOUSE/spectra/lnhb/Mn-54.txt b/HEN_HOUSE/spectra/lnhb/Mn-54.txt new file mode 100644 index 000000000..f2d4d3834 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Mn-54.txt @@ -0,0 +1,46 @@ + 54CR 54MN EC DECAY (312.19 D) + 54CR H TYP=Update$AUT=V.Chechev$CUT=31-MAR-2014$ + 54CR2 H TYP=ERR$AUT=M.-M.Bé$CUT= -- $ + 54CR3 H TYP=FUL$AUT=R.G.Helmer and E.Schönfeld$CUT=28-FEB-2001$ + 54CR C Evaluation history: Type=Update;Author=V.Chechev;Cutoff date=31-MAR-2014 + 54CR2C Type=ERR;Author=M.-M.Bé;Cutoff date= -- + 54CR3C Type=FUL;Author=R.G.Helmer and E.Schönfeld;Cutoff date=28-FEB-2001 + 54CR C References: 1955Ba10, 1956Ka33, 1956Sc87, 1961Wy01, 1963Ta19, 1964Be26, + 54CR2C 1964Ma14, 1965Sa09, 1965An07, 1965Le21, 1967PeZZ, 1967Ba50, 1968Zi01, + 54CR3C 1968Ha47, 1968La10, 1968Be01, 1969BoZX, 1973MeYE, 1973Vi13, 1973Mu**, + 54CR4C 1973Ko**, 1974Cr05, 1978Ma06, 1979MeZY, 1980Co22, 1980RuZV, 1982RyZX, + 54CR5C 1982HoZJ, 1982RuZV, 1989Su08, 1992Un01, 1993Da20, 1996Du15, 1997Ma75, + 54CR6C 1998Si17, 2000Hu20, 2002Ba85, 2002Un02, 2004BeZR, 2006Hu08, 2006Da20, + 54CR7C 2008Ki07, 2010Va13, 2012Wa38, 2012Fi12, 2014Un01 + 54CR T Auger electrons and ^X ray energies and emission intensities: + 54CR T {U Energy (keV)} {U Intensity } {U Line } + 54CR T + 54CR T 5.40557 7.65 14 XKA2 + 54CR T 5.41479 15.02 27 XKA1 + 54CR T + 54CR T 5.94677 |] 3.05 7 XKB1 + 54CR T 5.987 |] XKB5II + 54CR T + 54CR T + 54CR T 0.5003-0.69748 0.65 13 XL (total) + 54CR T 0.5003 XLL + 54CR T 0.5729-0.57695 XLA + 54CR T 0.5102 XLC + 54CR T 0.57515-0.69748 XLB + 54CR T 0.58496-0.58496 XLG + 54CR T + 54CR T 4.554-4.794 |] KLL AUGER + 54CR T 5.206-5.412 |] 63.3 5 ^KLX AUGER + 54CR T 5.841-5.985 |] KXY AUGER + 54CR T 0.4-0.7 143.0 6 L AUGER + 54MN P 0.0 3+ 312.19 D 3 1377.2 10 + 54CR N 1.0 1.0 1 1.0 + 54CR L 0 0+ STABLE + 54CR E 5.7E-7 0.0003 3 13.9 2U + 54CR2 E EAV=182 $CK=0.8908 16$CL=0.0938 13$CM=0.0148 6$CN=0.0005 2$CO=0 0 + 54CR L 834.855 3 2+ 0.0079 NS 3 + 54CR E 99.9997 3 6.17 + 54CR2 E EAV= $CK=0.8896 17$CL=0.0948 14$CM=0.0150 6$CN=0.0005 2$CO=0 0 + 54CR G 834.848 3 99.9752 5 E2 2.45E-44 + 54CR2 G KC=2.22E-4 4$LC=2.06E-5 3$MC=2.71E-6 4 + diff --git a/HEN_HOUSE/spectra/lnhb/Mn-56.txt b/HEN_HOUSE/spectra/lnhb/Mn-56.txt new file mode 100644 index 000000000..5325d233c --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Mn-56.txt @@ -0,0 +1,55 @@ + 56FE 56MN B- DECAY (2.57878 H) + 56FE T Auger electrons and ^X ray energies and emission intensities: + 56FE T {U Energy (keV)} {U Intensity } {U Line } + 56FE T + 56FE T 6.39091 0.00295 4 XKA2 + 56FE T 6.40391 0.00578 7 XKA1 + 56FE T + 56FE T 7.05804 |] 0.00119 2 XKB1 + 56FE T 7.1083 |] XKB5II + 56FE T + 56FE T + 56FE T + 56FE T 5.37-5.645 |] KLL AUGER + 56FE T 6.158-6.4 |] 0.0180 1 ^KLX AUGER + 56FE T 6.926-7.105 |] KXY AUGER + 56FE T 0.51-0.594 0.0428 3 L AUGER + 56MN P 0.0 3+ 2.57878 H 46 3695.5 3 + 56FE N 1.0 1.0 1 1.0 + 56FE L 0 0+ STABLE + 56FE L 846.776 5 2+ 6.07 PS + 56FE B 2848.7 3 56.6 7 7.101 + 56FES B EAV=1216.8 2 + 56FE G 846.7638 1998.85 3 E2 3.00E-49 + 56FE2 G KC=2.70E-4 8$LC=2.50E-5 8$MC=3.7E-6 1 + 56FE L 2085.076 7 4+ + 56FE B 1610.4 3 0.057 6 9.06 + 56FES B EAV=636.3 2 + 56FE G 1238.2736 220.097 2 E2 1.20E-44 + 56FE2 G KC=1.10E-4 3$LC=1.00E-5 3$MC=2.00E-6 6 + 56FE L 2657.562 102+ + 56FE B 1037.9 3 27.5 4 5.621 + 56FES B EAV=381.9 2 + 56FE G 1810.726 4 26.9 4 M1+E2 -0.18 1 5.10E-515 + 56FE2 G KC=4.60E-5 14$LC=4.30E-6 13$MC=6.3E-7 2 + 56FE G 2657.56 1 0.645 7 E2 + 56FE L 2959.923 102+ + 56FE B 735.6 3 14.5 3 5.34 + 56FES B EAV=255.2 2 + 56FE G 2113.092 6 14.2 3 M1+E2 + 56FE G 2959.92 1 0.307 5 E2 + 56FE L 3122.927 7 4+ + 56FE B 572.6 3 0.040 4 7.5 + 56FES B EAV=190.4 2 + 56FE G 1037.8333 240.040 4 M1+E2 0.02 1 1500E-745 + 56FE2 G KC=1.30E-4 4$LC=1.20E-5 4$MC=6.0E-6 2 + 56FE L 3369.84 4 2+ + 56FE B 325.7 3 1.20 3 5.17 + 56FES B EAV=99.1 1 + 56FE G 2523.06 5 1.02 2 M1+E2 + 56FE G 3369.84 4 0.17 1 E2 + 56FE L 3445.306 203+ + 56FE B 250.2 3 0.020 2 6.57 + 56FES B EAV=73.5 1 + 56FE G 2598.438 4 0.020 2 M1+E2 + diff --git a/HEN_HOUSE/spectra/lnhb/Mo-99.txt b/HEN_HOUSE/spectra/lnhb/Mo-99.txt new file mode 100644 index 000000000..870decfcc --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Mo-99.txt @@ -0,0 +1,120 @@ + 99TC 99MO B- DECAY (2.7479 D) + 99TC H TYP=update$AUT=mmbe$CUT= -- $ + 99TC2 H TYP=update$AUT=mmbe$CUT= -- $ + 99TC C Evaluation history: Type=update;Author=mmbe;Cutoff date= -- + 99TC2C Type=update;Author=mmbe;Cutoff date= -- + 99TC C References: 1977La19 + 99TC T Auger electrons and ^X ray energies and emission intensities: + 99TC T {U Energy (keV)} {U Intensity } {U Line } + 99TC T + 99TC T 18.251 3.19 9 XKA2 + 99TC T 18.3672 6.06 16 XKA1 + 99TC T + 99TC T 20.599 |] XKB3 + 99TC T 20.619 |] 1.61 5 XKB1 + 99TC T 20.789 |] XKB5II + 99TC T + 99TC T 21.005 |] XKB2 + 99TC T 21.042 |] 0.254 11 XKB4 + 99TC T + 99TC T 2.424-2.537 0.697 17 XL (total) + 99TC T 2.424- 0.430 13 XLA + 99TC T 2.537- 0.231 7 XLB + 99TC T + 99TC T 14.858-15.582 |] KLL AUGER + 99TC T 17.418-18.365 |] 3.1 1 ^KLX AUGER + 99TC T 19.956-21.04 |] KXY AUGER + 99TC T 1.6-3.04 15.87 26 L AUGER + 99MO P 0.0 1/2+ 2.7479 D 6 1357.2 10 + 99TC N 1.0 1.0 1 1.0 + 99TC L 0 9/2+ 211.5E3 Y 11 + 99TC L 140.5106 7/2+ 0.221 NS 20 + 99TC G 140.511 1 89.6 17M1+()E2 0.186 8 0.119 3 + 99TC2 G KC=0.104 3$LC=0.0129 4$MC=0.00236 7 + 99TC L 142.6832 1/2- 6.0067 H 10 + 99TC B 1214.5 1082.1 15 7.1 + 99TCS B EAV=442.7 3 + 99TC G 2.1726 4 700E-11 0 E3 135E8 4 + 99TC2 G KC=$LC=$MC=119E8 3 + 99TC G 142.675 250.0211 17M4 40.9 8 + 99TC2 G KC=29.3 6$LC=9.35 20$MC=1.86 6 + 99TC L 181.0939 5/2+ 3.61 NS 7 + 99TC G 40.58323 171.022 27M1+()E2 -0.119 8 4.18 13 + 99TC2 G KC=3.50 8$LC=0.560 13$MC=0.104 3 + 99TC G 181.068 8 6.01 11E2 0.149 3 + 99TC2 G KC=0.125 3$LC=0.0191 4$MC=0.00353 7 + 99TC L 509.106 (3/2)- + 99TC B 848.1 101.18 3 8.38 1U + 99TCS B EAV=289.7 3 + 99TC G 366.421 151.194 23M1 0.0091518 + 99TC2 G KC=0.00802 16$LC=0.00093 2$MC=1.70E-4 4 + 99TC L 534.41 (3/2)+ + 99TC B 822.8 100.0010 2 2 + 99TCS B EAV=279 2 + 99TC G 391.7 4 0.0025 6 + 99TC L 671.489 (3/2)- + 99TC B 685.7 100.052 5 9.46 1U + 99TCS B EAV=225.4 4 + 99TC G 162.370 150.0114 6 + 99TC G 528.788 150.0541 19M1 0.003788 + 99TC2 G KC=0.00331 7$LC=3.79E-4 8$MC=6930E-8 14 + 99TC L 761.71 5/2+ + 99TC G 580.51 5 0.0036 4 + 99TC G 761.77 8 0.0023 13 + 99TC L 762.243 (3/2)+ + 99TC G 581.30 120.00010 5 + 99TC G 621.773 240.0262 10M1(+E2) 0.002588 + 99TC2 G KC=0.00227 5$LC=2.59E-4 8$MC=4.73E-5 14 + 99TC L 920.591 1/2+ + 99TC B 436.6 1016.45 30 6.21 + 99TCS B EAV=133.0 3 + 99TC G 158.782 150.0145 9 + 99TC G 249.03 3 0.0035 4 + 99TC G 411.491 150.0161 12E1 3.5 0.002575 + 99TC2 G KC=0.00226 5$LC=2.56E-4 5$MC=4.67E-5 9 + 99TC G 739.500 1712.12 15E2+M1 0.001734 + 99TC2 G KC=0.00151 3$LC=1.78E-4 5$MC=3.2E-5 1 + 99TC G 777.921 204.28 8 E1 5.89E-412 + 99TC2 G KC=5.18E-4 10$LC=5.80E-5 12$MC=1057E-8 2 + 99TC L 1004.066 3/2- + 99TC B 353.1 100.134 5 7.97 1U + 99TCS B EAV=104.3 3 + 99TC G 242.29 8 0.0014 3 (E1) 0.0106 2 + 99TC2 G KC=0.0093 2$LC=0.00106 2$MC=1.93E-4 6 + 99TC G 822.972 150.1321 29E1 5.24E-411 + 99TC2 G KC=4.61E-4 9$LC=5.2E-5 1$MC=9.4E-6 2 + 99TC G 861.2 9 0.0007 2 + 99TC L 1072.2 (7/2)+ + 99TC B 285 1 0.0027 7 + 99TCS B EAV=82 1 + 99TC G 537.79 150.0015 5 + 99TC G 1072.2 4 0.0012 5 + 99TC L 1129.116 (1/2,3/2)- + 99TC B 228.1 100.011 1 8.5 + 99TCS B EAV=69.3 3 + 99TC G 457.60 3 0.0074 6 M1+()E2 1.6 0.0063 7 + 99TC2 G KC=0.0054 4$LC=0.00066 5$MC=0.00012 1 + 99TC G 620.03 5 0.0024 6 + 99TC G 986.44 4 0.0014 1 + 99TC L 1141.871 3/2+ + 99TC B 215.3 100.111 3 7.39 2 + 99TCS B EAV=59.8 3 + 99TC G 380.13 8 0.0091 5 M1+()E2 1.3 6 0.0105 8 + 99TC2 G KC=0.0091 7$LC=0.00113 8$MC=0.00021 2 + 99TC G 469.63 7 0.0027 5 + 99TC G 960.754 200.095 3 (M1) 0.0010 1 + 99TC2 G KC=$LC=$MC= + 99TC G 1001.343 180.0043 4 (E2) 0.0008 1 + 99TC2 G KC=$LC=$MC= + 99TC L 1171.98 3/2+ + 99TC B 185.2 100.0016 4 8.91 2 + 99TCS B EAV=51.0 4 + 99TC G 410.27 100.0016 4 M1+()E2 0.5 0.0074 3 + 99TC2 G KC=0.0065 2$LC=$MC=0.00014 1 + 99TC L 1198.88 (3/2)+ + 99TC B 158.3 100.0021 3 8.65 2 + 99TCS B EAV=43.3 4 + 99TC G 689.6 9 0.00042 18 + 99TC G 1017.0 5 0.0007 2 + 99TC G 1056.20 5 0.00103 9 + diff --git a/HEN_HOUSE/spectra/lnhb/N-13.txt b/HEN_HOUSE/spectra/lnhb/N-13.txt new file mode 100644 index 000000000..7384be865 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/N-13.txt @@ -0,0 +1,7 @@ + 13C 13N EC DECAY (9.9670 M) + 13N P 0.0 1/2- 9.9670 M 37 2220.45 27 + 13C N 1.0 1.0 1 1.0 + 13C L 0 1/2- STABLE + 13C E 99.818 130.182 12 + 13C 2 E EAV=493.0 2$CK=0.923 7$CL=0.078 7$CM= $CN= $CO=0 0 + diff --git a/HEN_HOUSE/spectra/lnhb/Na-22.txt b/HEN_HOUSE/spectra/lnhb/Na-22.txt new file mode 100644 index 000000000..8ad9ee14a --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Na-22.txt @@ -0,0 +1,33 @@ + 22NE 22NA EC DECAY (2.6029 Y) + 22NE H TYP=Update$AUT=M. Galan$CUT=30-MAY-2009$ + 22NE2 H TYP=Full$AUT=Helmer. Schönfeld$CUT=18-JAN-1999$ + 22NE C Evaluation history: Type=Update;Author=M. Galan;Cutoff date=30-MAY-2009 + 22NE2C Type=Full;Author=Helmer. Schönfeld;Cutoff date=18-JAN-1999 + 22NE C References: 1953WR13, 1954KR01, 1954SH01, 1954ZW01, 1955Al01, 1957ME47, + 22NE2C 1958KO75, 1959RA09, 1961WY01, 1964WI04, 1965AN07, 1967lE07, 1968VA13, + 22NE3C 1969MC06, 1970WA11, 1973KA50, 1976MA38, 1977BO10, 1977BA48, 1978FI11, + 22NE4C 1979SC31, 1980HO17, 1982RUZV, 1983BA41, 1985HAZA, 1990KU11, 1991BAZS, + 22NE5C 1995SCZY, 1996SC06, 1999BeZS, 1999BeZQ, 2000HE14, 2002UN02, 2002BA85, + 22NE6C 2004MU26, 2009NA08, 2008MU05 + 22NE T Auger electrons and ^X ray energies and emission intensities: + 22NE T {U Energy (keV)} {U Intensity } {U Line } + 22NE T + 22NE T 0.8486 0.0453 25 XKA2 + 22NE T 0.8486 0.090 5 XKA1 + 22NE T + 22NE T + 22NE T + 22NE T + 22NE T 0.75-0.81 |] KLL AUGER + 22NE T - |] 8.8 1 ^KLX AUGER + 22NA P 0.0 3+ 2.6029 Y 8 2843.02 21 + 22NE N 1.0 1.0 1 1.0 + 22NE L 0 0+ STABLE + 22NE E 0.055 140.00098 2514.91 2U + 22NE2 E EAV=835.04 19$CK= $CL= $CM= $CN= $CO= + 22NE L 1274.577 7 2+ 0.00524 NS7 + 22NE E 90.30 9 9.64 9 7.41 + 22NE2 E EAV=215.62 17$CK=0.923 4$CL=0.077 4$CM= $CN= $CO= + 22NE G 1274.537 7 99.94 13E2 6.71E-69 + 22NE2 G KC=6.36E-6 9$LC=$MC= + diff --git a/HEN_HOUSE/spectra/lnhb/Na-24.txt b/HEN_HOUSE/spectra/lnhb/Na-24.txt new file mode 100644 index 000000000..84c2e1472 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Na-24.txt @@ -0,0 +1,55 @@ + 24MG 24NA B- DECAY (14.958 H) + 24MG H TYP=UPDATE$AUT=V.Chechev and N.K.Kuzmenko$CUT=31-MAR-2014$ + 24MG2 H TYP=ERR$AUT=M.-M.Be$CUT=12-FEB-2004$ + 24MG3 H TYP=FULL$AUT=R.G.Helmer and E.Schonfeld$CUT=31-MAR-2000$ + 24MG C Evaluation history: Type=UPDATE;Author=V.Chechev and N.K.Kuzmenko;Cutoff date=31-MAR-2014 + 24MG2C Type=ERR;Author=M.-M.Be;Cutoff date=12-FEB-2004 + 24MG3C Type=FULL;Author=R.G.Helmer and E.Schonfeld;Cutoff date=31-MAR-2000 + 24MG C References: 1950Gr01, 1951Tu12, 1952Sl52, 1955To07, 1958Ca20, 1958Da10, + 24MG2C 1960Ar10, 1961De23, 1961Wy01, 1961De25, 1963Pa20, 1964Le09, 1965Be24, + 24MG3C 1968Va06, 1969Bo48, 1972Gi17, 1973Br16, 1976Ge06, 1977La19, 1980RuZY, + 24MG4C 1982HoZJ, 1982RuZV, 1983Wa26, 1990En08, 1990En02, 1992Un01, 1998Si17, + 24MG5C 2000He14, 2002Ba85, 2002Un02, 2003Ep02, 2004Un01, 2004BeZR, 2005Li66, + 24MG6C 2007Fi14, 2008Ki07, 2012Wa38, 2012Fi12, 2014Un01 + 24MG T Auger electrons and ^X ray energies and emission intensities: + 24MG T {U Energy (keV)} {U Intensity } {U Line } + 24MG T + 24MG T 1.25361 0.0000113 4 XKA2 + 24MG T 1.25361 0.0000225 8 XKA1 + 24MG T + 24MG T 1.3022 |] 0.00000058 14 XKB1 + 24MG T + 24MG T + 24MG T + 24MG T 1.102-1.182 |] KLL AUGER + 24MG T 1.214-1.252 |] 0.001148 14 ^KLX AUGER + 24MG T 1.301-1.301 |] KXY AUGER + 24NA P 0.0 4+ 14.958 H 2 5515.61 4 + 24MG N 1.0 1.0 1 1.0 + 24MG G 511 0.144 2 + 24MG L 0 0 0+ STABLE + 24MG L 1368.672 5 2+ 1.33 PS 6 + 24MG B 4146.94 4 0.003 2 12.7 2 + 24MGS B EAV=1866.70 2 + 24MG G 1368.630 5 99.9934 5 E2 9.91E-613 + 24MG2 G KC=9.29E-6 13$LC=5.97E-7 9$MC=2.21E-8 3 + 24MG L 4122.889 124+ 22 FS 2 + 24MG B 1392.72 4 99.930 3 6.12 + 24MGS B EAV=555.05 2 + 24MG G 2754.049 1399.862 3 E2 2.71E-64 + 24MG2 G KC=2.54E-6 4$LC=163E-9 2$MC=6.05E-9 9 + 24MG L 4238.24 3 2+ 41 FS 4 + 24MG B 1277.37 5 0.001 1 12.3 2 + 24MGS B EAV=503 + 24MG G 2869.38 3 0.00025 3 M1+E2 23 9 2.54E-66 + 24MG2 G KC=2.38E-6 4$LC=153E-9 2$MC=5.67E-9 8 + 24MG G 4237.84 3 0.00084 10E2 1.42E-62 + 24MG2 G KC=1330E-9 19$LC=8.53E-8 12$MC=3.16E-9 5 + 24MG L 5235.12 4 3+ 61 FS 7 + 24MG B 280.49 6 0.066 3 6.69 + 24MGS B EAV=90.00 2 + 24MG G 996.86 5 0.00145 25M1+E2 5.1 12 2.05E-54 + 24MG2 G KC=1.92E-5 4$LC=1233E-9 20$MC=4.56E-8 8 + 24MG G 3866.12 4 0.066 2 M1+E2 17 4 1.62E-62 + 24MG2 G KC=1516E-9 22$LC=9.73E-8 14$MC=3.61E-9 5 + diff --git a/HEN_HOUSE/spectra/lnhb/Nb-93m.txt b/HEN_HOUSE/spectra/lnhb/Nb-93m.txt new file mode 100644 index 000000000..5f6ba41e9 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Nb-93m.txt @@ -0,0 +1,41 @@ + 93NB 93NB IT DECAY (16.12 Y) + 93NB H TYP=UPDate$AUT=M.A.Kellett$CUT=02-OCT-2013$ + 93NB2 H TYP=FULL$AUT=V.Chechev. N.Kuzmenko$CUT=15-JUN-2001$ + 93NB C Evaluation history: Type=UPDate;Author=M.A.Kellett;Cutoff date=02-OCT-2013 + 93NB2C Type=FULL;Author=V.Chechev. N.Kuzmenko;Cutoff date=15-JUN-2001 + 93NB C References: 1954Sc74, 1964Ho08, 1965Fl02, 1967Be65, 1972FlZM, 1972Ko59, + 93NB2C 1976He**, 1976Ju04, 1977La19, 1977La19, 1977Mo07, 1977Ll01, 1978Ba**, + 93NB3C 1980Va**, 1981Ll01, 1982Re09, 1982Al**, 1983Va25, 1985Ge**, 1987La**, + 93NB4C 1990Co17, 1991BaZS, 1996Sc06, 1997Ba13, 1999ScZX, 1999ZhZY, 2000Sc47, + 93NB5C 2008Ki07 + 93NB T Auger electrons and ^X ray energies and emission intensities: + 93NB T {U Energy (keV)} {U Intensity } {U Line } + 93NB T + 93NB T 16.5213 3.32 8 XKA2 + 93NB T 16.6152 6.34 15 XKA1 + 93NB T + 93NB T 18.607 |] XKB3 + 93NB T 18.623 |] 1.64 4 XKB1 + 93NB T 18.78 |] XKB5II + 93NB T + 93NB T 18.952 |] XKB2 + 93NB T 18.982 |] 0.246 11 XKB4 + 93NB T + 93NB T 1.9-2.67 2.88 6 XL (total) + 93NB T 1.9 0.0870 23 XLL + 93NB T 2.16-2.17 2.32 6 XLA + 93NB T 2 0.00877 24 XLC + 93NB T 2.26-2.37 0.446 11 XLB + 93NB T 2.41-2.67 0.0236 4 XLG + 93NB T + 93NB T 13.49-14.14 |] KLL AUGER + 93NB T 15.79-16.58 |] 3.83 11 ^KLX AUGER + 93NB T 18.02-18.91 |] KXY AUGER + 93NB T 1.4-2.7 81.25 28 L AUGER + 93NB P 30.77 2 1/2- 16.12 Y 15 + 93NB N 1.0 1.0 1 1.0 + 93NB L 0 9/2+ STABLE + 93NB L 30.77 2 1/2- 16.12 Y 15 + 93NB G 30.77 2 5.91E-4 9 M4 1.693E525 + 93NB2 G KC=2.60E4 4$LC=1.151E5 17$MC=2.49E4 4 + diff --git a/HEN_HOUSE/spectra/lnhb/Nb-95.txt b/HEN_HOUSE/spectra/lnhb/Nb-95.txt new file mode 100644 index 000000000..7d22c2a83 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Nb-95.txt @@ -0,0 +1,42 @@ + 95MO 95NB B- DECAY (34.991 D) + 95MO H TYP=Full$AUT=R.G.Helmer$CUT= -- $ + 95MO C Evaluation history: Type=Full;Author=R.G.Helmer;Cutoff date= -- + 95MO T Auger electrons and ^X ray energies and emission intensities: + 95MO T {U Energy (keV)} {U Intensity } {U Line } + 95MO T + 95MO T 17.3745 0.0286 9 XKA2 + 95MO T 17.4795 0.0546 18 XKA1 + 95MO T + 95MO T 19.5904 |] XKB3 + 95MO T 19.6085 |] 0.0143 5 XKB1 + 95MO T 19.774 |] XKB5II + 95MO T + 95MO T 19.9653 |] XKB2 + 95MO T 19.998 |] 0.00221 11 XKB4 + 95MO T + 95MO T 2.01-2.83 0.0055 9 XL (total) + 95MO T 2.01 XLL + 95MO T -2.83 XLG + 95MO T + 95MO T 14.268-14.96 |] KLL AUGER + 95MO T 16.628-17.476 |] 0.0303 11 ^KLX AUGER + 95MO T 18.99-19.99 |] KXY AUGER + 95MO T 1.856-2.86 0.143 4 L AUGER + 95NB P 0.0 9/2+ 34.991 D 6 925.6 5 + 95MO N 1.0 1.0 1 1.0 + 95MO L 0 5/2+ STABLE + 95MO B 925.6 5 0.030 5 11.2 + 95MOS B EAV=321.94 21 + 95MO L 204.118 9 3/2+ 0.751 NS 9 + 95MO B 721.5 5 + 95MOS B EAV=283.58 20 + 95MO G 204.117 2 0.028 8 M1+E2 0.0515 22 + 95MO2 G KC=0.045 3$LC=0.0058 4$MC= + 95MO L 765.806 6 7/2+ 0.0044 NS 7 + 95MO B 159.8 5 99.970 6 5.09 2 + 95MOS B EAV=43.36 15 + 95MO G 561.88 2 0.015 3 [E2] 0.0034110 + 95MO2 G KC=0.00298 9$LC=3.54E-4 11$MC= + 95MO G 765.803 6 99.808 7 M1+E2 0.001474 + 95MO2 G KC=0.00129 4$LC=1.45E-4 4$MC= + diff --git a/HEN_HOUSE/spectra/lnhb/Nb-95m.txt b/HEN_HOUSE/spectra/lnhb/Nb-95m.txt new file mode 100644 index 000000000..c5e68a359 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Nb-95m.txt @@ -0,0 +1,74 @@ + 95NB 95NB IT DECAY (3.61 D) + 95NB H TYP=Full$AUT=M.M.Bé. R.G.Helmer$CUT= -- $ + 95NB C Evaluation history: Type=Full;Author=M.M.Bé. R.G.Helmer;Cutoff date= -- + 95NB T Auger electrons and ^X ray energies and emission intensities: + 95NB T {U Energy (keV)} {U Intensity } {U Line } + 95NB T + 95NB T 16.521 12.5 6 XKA2 + 95NB T 16.615 23.9 10 XKA1 + 95NB T + 95NB T 18.607 |] XKB3 + 95NB T 18.623 |] 6.19 27 XKB1 + 95NB T 18.78 |] XKB5II + 95NB T + 95NB T 18.952 |] XKB2 + 95NB T 18.982 |] 0.93 5 XKB4 + 95NB T + 95NB T 1.9-2.66 0.0251 11 XL (total) + 95NB T 1.9 XLL + 95NB T -2.66 XLG + 95NB T + 95NB T 13.49-14.14 |] KLL AUGER + 95NB T 15.79-16.58 |] 14.5 7 ^KLX AUGER + 95NB T 18.02-18.91 |] KXY AUGER + 95NB T 1.4-2.6 69.9 25 L AUGER + 95NB P 235.69 2 1/2- 3.61 D 3 + 95NB N 1.026E0 1.026E0 0.975 1.026E0 + 95NB L 0 9/2+ 34.991 D 6 + 95NB L 235.69 5 1/2- 3.61 D 3 + 95NB G 235.69 2 25.1 3 M4 2.88 9 + 95NB2 G KC=2.31 8$LC=0.468 14$MC=0.10000 0 + + 95MO 95NB B- DECAY (3.61 D) + 95MO H TYP=Full$AUT=M.M.Bé. R.G.Helmer$CUT= -- $ + 95MO C Evaluation history: Type=Full;Author=M.M.Bé. R.G.Helmer;Cutoff date= -- + 95MO T Auger electrons and ^X ray energies and emission intensities: + 95MO T {U Energy (keV)} {U Intensity } {U Line } + 95MO T + 95MO T 17.374 XKA2 + 95MO T 17.479 XKA1 + 95MO T + 95MO T 17.59 |] XKB3 + 95MO T 19.608 |] XKB1 + 95MO T 19.771 |] XKB5II + 95MO T + 95MO T 19.965 |] XKB2 + 95MO T 19.997 |] XKB4 + 95MO T + 95MO T + 95MO T 14.268-14.96 |] KLL AUGER + 95MO T 16.628-17.476 |] ^KLX AUGER + 95MO T 18.99-19.99 |] KXY AUGER + 95MO T 1.86-2.86 L AUGER + 95NB P 235.69 2 1/2- 3.61 D 3 925.6 5 + 95MO N 4.00E1 4.00E1 0.025 4.00E1 + 95MO L 0 5/2+ STABLE + 95MO L 204.118 3/2+ 0.751 NS + 95MO B 957.2 5 2.4 1 8.3 1U + 95MOS B EAV=345 1 + 95MO G 204.117 2 2.28 10M1+E2 0.0515 22 + 95MO2 G KC=0.045 3$LC=0.0058 4$MC= + 95MO L 786.19 1/2+ + 95MO B 375.1 5 0.016 9.1 + 95MOS B EAV=123 1 + 95MO G 786.19 1 0.016 1 E2 0.001315 + 95MO2 G KC=$LC=$MC= + 95MO L 820.61 3/2+ + 95MO B 340.7 5 0.00038 10.6 1U + 95MOS B EAV=123 1 + 95MO G 820.61 1 3800E-7 0 M1+E2 + 95MO L 1039.25 1/2+ + 95MO B 122.0 5 25000E-925 10.2 + 95MOS B EAV=44.0 5 + 95MO G 835.13 1 2500E-8 0 + diff --git a/HEN_HOUSE/spectra/lnhb/Nd-147.txt b/HEN_HOUSE/spectra/lnhb/Nd-147.txt new file mode 100644 index 000000000..c23378120 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Nd-147.txt @@ -0,0 +1,125 @@ +147PM 147ND B- DECAY (10.987 D) +147PM H TYP=Full$AUT=V. Chisté$CUT=30-MAR-2011$ +147PM C Evaluation history: Type=Full;Author=V. Chisté;Cutoff date=30-MAR-2011 +147PM C References: 1946Bo25, 1951EM23, 1951Ko01, 1951Ma**, 1952Ru10, 1957Li40, +147PM2C 1957Bi86, 1957Wr37, 1960Wi10, 1960Ma03, 1960Bo17, 1961Sa13, 1961Ar09, +147PM3C 1961Ew02, 1961We07, 1962Sh08, 1963Ho15, 1963Sp07, 1963Ph02, 1966Go25, +147PM4C 1966Be09, 1967Ja05, 1966Ar16, 1967Ca18, 1967Ba21, 1967Do07, 1967Hi04, +147PM5C 1967Ba06, 1967Ba22, 1968Ra28, 1969Ba32, 1970Bl12, 1971Ba28, 1971Si20, +147PM6C 1971Na11, 1974HeYW, 1974Ra30, 1974Bh02, 1976Si08, 1977Kr13, 1977Al34, +147PM7C 1979Vo09, 1979Se05, 1995Go**, 1996Sc06, 1997Sa53, 1998Po**, 2002Ba85, +147PM8C 2008Ki07, 2009AuZZ, 2009Ni02, 2010Gh** +147PM T Auger electrons and ^X ray energies and emission intensities: +147PM T {U Energy (keV)} {U Intensity } {U Line } +147PM T +147PM T 38.1716 12.9 9 XKA2 +147PM T 38.7251 23.5 15 XKA1 +147PM T +147PM T 43.713 |] XKB3 +147PM T 43.826 |] 7.3 5 XKB1 +147PM T 44.145 |] XKB5II +147PM T +147PM T 44.937 |] XKB2 +147PM T 45.064 |] 1.87 13 XKB4 +147PM T 45.162 |] XKO23 +147PM T +147PM T 4.81-7.1893 7.6 3 XL (total) +147PM T 4.81 0.148 9 XLL +147PM T 5.4061-5.4325 3.68 20 XLA +147PM T 5.363 0.057 4 XLC +147PM T 5.9552-6.3985 3.20 14 XLB +147PM T 6.6814-7.1893 0.517 24 XLG +147PM T +147PM T 30.16-32.08 |] KLL AUGER +147PM T 36.03-37.63 |] 3.9 4 ^KLX AUGER +147PM T 41.84-44.16 |] KXY AUGER +147PM T 3.1-6.27 43.4 18 L AUGER +147ND P 0.0 5/2- 10.987 D 11 895.7 9 +147PM N 1.0 1.0 1 1.0 +147PM L 0 7/2+ 2.6234 Y 4 +147PM B 895.7 9 0 5 7.5 1U +147PMS B EAV=299.45 35 +147PM L 91.1049 205/2+ 2.50 NS 5 +147PM B 804.6 9 81 5 7.4 +147PMS B EAV=263.99 35 +147PM G 91.105 2 28.4 18M1+E2 0.090 5 2.03 3 +147PM2 G KC=1.714 24$LC=0.250 4$MC=0.0535 8 +147PM L 408.54 5 9/2+ +147PM G 408.52 6 0.0178 13M1+E2 0.57 3 0.0304 5 +147PM2 G KC=0.0257 5$LC=0.00368 6$MC=7.89E-4 12 +147PM L 410.512 133/2+ 0.139 NS 14 +147PM B 485.2 9 0.715 34 8.7 1U +147PMS B EAV=146.67 30 +147PM G 319.411 181.991 19M1+E2 -0.378 9 0.0607 9 +147PM2 G KC=0.0514 8$LC=0.00734 11$MC=1572E-6 22 +147PM G 410.48 3 0.137 6 E2 0.0212 3 +147PM2 G KC=0.01724 25$LC=0.00313 5$MC=6.83E-4 10 +147PM L 489.255 167/2+ +147PM B 406.4 9 0.781 15 8.4 1U +147PMS B EAV=119.83 30 +147PM G 80.82 270.00086 11[M1E2] 3.9 11 +147PM2 G KC=2.26 17$LC=1.3 10$MC=0.29 22 +147PM G 398.155 200.855 8 M1+E2 0.297 37 0.0345 5 +147PM2 G KC=0.0293 5$LC=0.00406 6$MC=8.66E-4 13 +147PM G 489.24 3 0.136 11M1+E2 -0.79 35 0.0179 18 +147PM2 G KC=0.0152 16$LC=0.00218 14$MC=0.00047 3 +147PM L 531.012 155/2+ 0.083 NS 15 +147PM B 364.7 9 14.6 9 7 +147PMS B EAV=106.02 30 +147PM G 120.48 5 0.361 14M1+E2 0.116 42 0.914 14 +147PM2 G KC=0.772 11$LC=0.112 4$MC=0.0239 8 +147PM G 439.895 221.203 11M1+E2 0.609 21 0.0248 4 +147PM2 G KC=0.0210 4$LC=0.00300 5$MC=6.41E-4 10 +147PM G 531.016 2212.7 9 M1+E2 -0.407 35 0.0161 3 +147PM2 G KC=0.01374 23$LC=0.00188 3$MC=4.02E-4 6 +147PM L 632.93 7 1/2+ +147PM B 262.8 9 0.0190 27 9.1 3U +147PMS B EAV=85.89 33 +147PM G 541.83 7 0.0188 27[E2] 0.0099414 +147PM2 G KC=0.00824 12$LC=1338E-6 19$MC=2.90E-4 4 +147PM L 641.27 8 + +147PM G 230.77 8 +147PM L 649.03 4 11/2- 27 NS 3 +147PM B 246.7 9 0.296 19 7.5 +147PMS B EAV=91.35 33 +147PM G 117.98 8 0.0152 13E3 14.07 20 +147PM2 G KC=3.15 5$LC=8.41 12$MC=2.02 3 +147PM G 159.7 2 0.00508 38M2 2.74 4 +147PM2 G KC=2.18 4$LC=0.439 7$MC=0.0977 15 +147PM G 240.5 2 0.0406 25E1 0.0250 4 +147PM2 G KC=0.0213 3$LC=0.00290 5$MC=6.15E-4 9 +147PM G 649.04 8 0.00495 38M2 0.0299 5 +147PM2 G KC=0.0251 4$LC=0.00371 6$MC=7.99E-4 12 +147PM L 680.44 4 7/2+ +147PM B 215.3 9 0.0897 28 8.4 1U +147PMS B EAV=59.16 27 +147PM G 31.3 2 [M2] 548 18 +147PM2 G KC=$LC=422 14$MC=100 4 +147PM G 149.3 2 0.00368 38[M1E2] 0.52 3 +147PM2 G KC=0.39 3$LC=0.10 5$MC=0.022 10 +147PM G 191.0 3 0.00356 38[M1E2] 0.244 9 +147PM2 G KC=0.192 22$LC=0.040 11$MC=0.009 3 +147PM G 271.87 6 0.0126 9 M1+E2 0.10 3 0.0964 14 +147PM2 G KC=0.0820 12$LC=0.01133 16$MC=0.00242 4 +147PM G 589.35 4 0.037 2 [M1E2] 0.011 3 +147PM2 G KC=0.0090 23$LC=0.00128 23$MC=0.00027 4 +147PM G 680.52 150.0283 14[M1E2] 0.0074 18 +147PM2 G KC=0.0063 18$LC=0.00088 17$MC=0.00019 4 +147PM L 685.890 155/2+ 0.25 NS 10 +147PM B 209.8 9 2.184 16 7 +147PMS B EAV=57.54 27 +147PM G 36.75 10 [E3] 1.004E422 +147PM2 G KC=$LC=7.60E3 17$MC=1960 50 +147PM G 53.1 2 [E2] 25.1 6 +147PM2 G KC=4.40 7$LC=16.1 4$MC=3.73 9 +147PM G 154.7 2 0.00394 38[M1E2] 0.468 19 +147PM2 G KC=0.36 3$LC=0.09 4$MC=0.020 9 +147PM G 196.64 4 0.1798 18M1+E2 -0.20 8 0.231 4 +147PM2 G KC=0.196 3$LC=0.0281 8$MC=0.00601 18 +147PM G 275.374 150.775 11M1+E2 0.112 5 0.0931 13 +147PM2 G KC=0.0792 11$LC=0.01095 16$MC=0.00234 4 +147PM G 594.80 3 0.2653 36M1+E2 0.55 6 0.0117 3 +147PM2 G KC=0.00995 23$LC=0.00137 3$MC=2.92E-4 6 +147PM G 685.90 4 0.834 9 M1+E2 -0.92 20 0.0074 5 +147PM2 G KC=0.0063 4$LC=0.00088 4$MC=1.88E-4 9 + diff --git a/HEN_HOUSE/spectra/lnhb/Ni-57.txt b/HEN_HOUSE/spectra/lnhb/Ni-57.txt new file mode 100644 index 000000000..c1f6a49e2 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Ni-57.txt @@ -0,0 +1,84 @@ + 57CO 57NI EC DECAY (1.496 D) + 57CO T Auger electrons and ^X ray energies and emission intensities: + 57CO T {U Energy (keV)} {U Intensity } {U Line } + 57CO T + 57CO T 6.91538 5.84 12 XKA2 + 57CO T 6.9304 11.42 23 XKA1 + 57CO T + 57CO T 7.6495 |] 2.37 6 XKB1 + 57CO T 7.706 |] XKB5II + 57CO T + 57CO T + 57CO T 0.678-0.87 0.56 4 XL (total) + 57CO T 0.678 XLL + 57CO T -0.87 XLG + 57CO T + 57CO T 5.81-6.1 |] KLL AUGER + 57CO T 6.67-6.86 |] 31.0 6 ^KLX AUGER + 57CO T 7.5-7.58 |] KXY AUGER + 57CO T 0.564-0.653 76.7 12 L AUGER + 57NI P 0.0 3/2- 1.496 D 23 3264.2 26 + 57CO N 1.0 1.0 1 1.0 + 57CO L 0 7/2- 271.80 D 5 + 57CO L 1223.79 7 9/2- 54 FS 5 + 57CO G 1223.8 3 0.076 13M1+E2 1.20E-44 + 57CO2 G KC=1.08E-4 3$LC=1.03E-5 3$MC= + 57CO L 1377.65 3 3/2- 19 PS 4 + 57CO E 35.3 5 29.3 5 5.6 + 57CO2 E EAV=368.3 $CK=0.8876 16$CL=0.0961 13$CM=0.0155 5$CN= $CO= + 57CO G 1377.62 4 81.2 6 E2 1.05E-43 + 57CO2 G KC=9.5E-5 3$LC=9.1E-6 3$MC= + 57CO L 1504.82 3 1/2- 0.21 NS 2 + 57CO E 6.8 3 9.6 4 6.1 2 + 57CO2 E EAV=313.4 $CK=0.8875 16$CL=0.0962 13$CM=0.0155 5$CN= $CO= + 57CO G 127.164 3 16.0 5 M1+E2 0.0215 6 + 57CO2 G KC=0.0193 6$LC=0.00191 6$MC= + 57CO L 1757.596 243/2- 0.27 PS 2 + 57CO E 0.85 6 5.2 3 6.2 + 57CO2 E EAV=206.1 $CK=0.8874 16$CL=0.0963 13$CM=0.0155 5$CN= $CO= + 57CO G 379.94 2 0.072 6 [M1] 0.001434 + 57CO2 G KC=0.00129 4$LC=1.24E-4 4$MC= + 57CO G 1757.55 3 6.1 4 E2 + 57CO L 1897.24 6 7/2- 110 FS 10 + 57CO G 673.44 4 0.0483 15M1+E2 0.000401 + 57CO2 G KC=0.00036 1$LC=3.4E-5 1$MC= + 57CO G 1897.0 5 0.0252 25M1+E2 + 57CO L 1919.47 4 5/2- 22 FS 3 + 57CO E 0.45 3 12.1 6 5.7 2 + 57CO2 E EAV=138.6 $CK=0.8873 16$CL=0.0964 13$CM=0.0155 5$CN= $CO= + 57CO G 161.86 3 0.0202 24M1 0.0115 3 + 57CO2 G KC=0.0104 3$LC=0.00102 3$MC= + 57CO G 541.9 1 0.0036 5 [E2] 0.001163 + 57CO2 G KC=0.00105 3$LC=1.02E-4 3$MC= + 57CO G 696.0 4 0.0009 6 [E2] 0.000562 + 57CO2 G KC=0.00050 2$LC=4.8E-5 1$MC= + 57CO G 1919.62 1412.5 5 M1+E2 + 57CO L 2133.06 5 5/2- 0.34 PS 6 + 57CO E 0.039 5 8.1 2 + 57CO2 E EAV= $CK=0.8871 16$CL=0.0965 13$CM=0.0156 5$CN= $CO= + 57CO G 755.3 1 0.0054 6 M1+E2 0.000331 + 57CO2 G KC=2.95E-4 9$LC=2.82E-5 8$MC= + 57CO G 2133.04 5 0.033 5 M1 + 57CO L 2730.83 143/2,5/2- 91 FS 12 + 57CO E 0.020 3 7.7 + 57CO2 E EAV= $CK=0.8857 16$CL=0.0977 13$CM=0.0158 5$CN= $CO= + 57CO G 2730.76 140.020 3 + 57CO L 2804.18 6 (3/2,5/2)- 37 FS 7 + 57CO E 0.308 236.4 + 57CO2 E EAV= $CK=0.8853 16$CL=0.0980 13$CM=0.0158 5$CN= $CO= + 57CO G 906.98 5 0.075 14 + 57CO G 1046.68 140.132 3 + 57CO G 2804.08 150.102 17E2 + 57CO L 3108.14 4 (3/2)- 54 FS 7 + 57CO E 0.063 4 6.1 + 57CO2 E EAV= $CK=0.8790 17$CL=0.1033 14$CM=0.0168 5$CN= $CO= + 57CO G 304.1 1 0.0020 6 + 57CO G 1350.52 6 0.002 1 + 57CO G 1603.28 6 0.0039 6 + 57CO G 1730.45 6 0.055 3 + 57CO L 3177.31 5 5/2,7/2- 152 FS 35 + 57CO E 0.025 5 6 2 + 57CO2 E EAV= $CK=0.8706 19$CL=0.1103 15$CM=0.0181 6$CN= $CO= + 57CO G 1279.99 6 0.0096 7 + 57CO G 3177.27 5 0.015 4 + diff --git a/HEN_HOUSE/spectra/lnhb/Ni-59.txt b/HEN_HOUSE/spectra/lnhb/Ni-59.txt new file mode 100644 index 000000000..3ecfe014a --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Ni-59.txt @@ -0,0 +1,33 @@ + 59CO 59NI EC DECAY (76E3 Y) + 59CO H TYP=Full$AUT=M. Galan$CUT=30-NOV-2009$ + 59CO C Evaluation history: Type=Full;Author=M. Galan;Cutoff date=30-NOV-2009 + 59CO C References: 1981MUZQ, 1949PO04, 1951BR05, 1951WI14, 1956SA32, 1976BE02, + 59CO2C 1981NI08, 1988BO30, 1991NO08, 1991JA02, 1994RU19, 1996SC06, 2002BA19, + 59CO3C 2004RA23, 2007WA00, 2009AUZZ + 59CO T Auger electrons and ^X ray energies and emission intensities: + 59CO T {U Energy (keV)} {U Intensity } {U Line } + 59CO T + 59CO T 6.91538 10.24 12 XKA2 + 59CO T 6.9304 20.02 22 XKA1 + 59CO T + 59CO T 7.6495 |] 4.15 6 XKB1 + 59CO T 7.706 |] XKB5II + 59CO T + 59CO T + 59CO T 0.6793-0.9251 0.98 7 XL (total) + 59CO T 0.6793 0.0400 13 XLL + 59CO T 0.7787-0.7795 0.508 15 XLA + 59CO T 0.6949 0.0247 9 XLC + 59CO T 0.78642-0.9251 0.346 12 XLB + 59CO T 0.80198-0.80198 0.00210 23 XLG + 59CO T + 59CO T 5.806-6.099 |] KLL AUGER + 59CO T 6.667-6.927 |] 54.3 4 ^KLX AUGER + 59CO T 7.508-7.703 |] KXY AUGER + 59CO T 0.68-0.83 134.5 8 L AUGER + 59NI P 0.0 3/2- 76E3 Y 5 1072.76 19 + 59CO N 1.0 1.0 1 1.0 + 59CO L 0 0 7/2- STABLE + 59CO E 3.7E-5 1210000E-21 11.89 + 59CO2 E EAV=24.81 9$CK=0.8870 16$CL=0.0966 13$CM=0.0156 5$CN=0.0008 2$CO= + diff --git a/HEN_HOUSE/spectra/lnhb/Ni-63.txt b/HEN_HOUSE/spectra/lnhb/Ni-63.txt new file mode 100644 index 000000000..4acc773e0 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Ni-63.txt @@ -0,0 +1,26 @@ + 63CU 63NI B- DECAY (98.7 Y) + 63CU H TYP=Full$AUT=K.B. Lee$CUT=28-SEP-2009$ + 63CU C Evaluation history: Type=Full;Author=K.B. Lee;Cutoff date=28-SEP-2009 + 63CU C References: 1966Hs01, 1971Ba89, 1987He14, 1992Ka29, 1993Oh02, 1996Co25, + 63CU2C 1996Sc33, 1999Ho09, 2003Au03 + 63CU T Auger electrons and ^X ray energies and emission intensities: + 63CU T {U Energy (keV)} {U Intensity } {U Line } + 63CU T + 63CU T 8.02792 XKA2 + 63CU T 8.04787 XKA1 + 63CU T + 63CU T 8.90539 |] XKB1 + 63CU T 8.9771 |] XKB5II + 63CU T + 63CU T + 63CU T + 63CU T 6.731-7.059 |] KLL AUGER + 63CU T 7.746-8.064 |] ^KLX AUGER + 63CU T 8.739-8.982 |] KXY AUGER + 63CU T 0.03-1.09 L AUGER + 63NI P 0.0 1/2- 98.7 Y 24 66.980 15 + 63CU N 1.0 1.0 1 1.0 + 63CU L 0 3/2- STABLE + 63CU B 66.980 15100 6.7 2 + 63CUS B EAV=17.434 4 + diff --git a/HEN_HOUSE/spectra/lnhb/Np-236.txt b/HEN_HOUSE/spectra/lnhb/Np-236.txt new file mode 100644 index 000000000..97d964bbd --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Np-236.txt @@ -0,0 +1,195 @@ +236U 236NP EC DECAY (1.55E5 Y) +236U H TYP=update$AUT=mmbe$CUT= -- $ +236U 2 H TYP=update$AUT=mmbe$CUT= -- $ +236U 3 H TYP=update$AUT=mmbe$CUT= -- $ +236U 4 H TYP=update$AUT=mmbe$CUT= -- $ +236U 5 H TYP=update$AUT=mmbe$CUT= -- $ +236U 6 H TYP=Full$AUT=V.P. Chechev$CUT=27-JUN-2006$ +236U 7 H TYP=Full$AUT=V.P. Chechev$CUT=27-JUN-2006$ +236U 8 H TYP=Full$AUT=V.P. Chechev$CUT=27-JUN-2006$ +236U 9 H TYP=Full$AUT=V.P. Chechev$CUT=27-JUN-2006$ +236U A H TYP=Full$AUT=V.P. Chechev$CUT=27-JUN-2006$ +236U C Evaluation history: Type=update;Author=mmbe;Cutoff date= -- +236U 2C Type=update;Author=mmbe;Cutoff date= -- +236U 3C Type=update;Author=mmbe;Cutoff date= -- +236U 4C Type=update;Author=mmbe;Cutoff date= -- +236U 5C Type=update;Author=mmbe;Cutoff date= -- +236U 6C Type=Full;Author=V.P. Chechev;Cutoff date=27-JUN-2006 +236U 7C Type=Full;Author=V.P. Chechev;Cutoff date=27-JUN-2006 +236U 8C Type=Full;Author=V.P. Chechev;Cutoff date=27-JUN-2006 +236U 9C Type=Full;Author=V.P. Chechev;Cutoff date=27-JUN-2006 +236U AC Type=Full;Author=V.P. Chechev;Cutoff date=27-JUN-2006 +236U C References: 1969Le05, 1971Dr11, 1971GuZY, 1972Dzh., 1972El21, 1972En06, +236U 2C 1975Dr05, 1975OtZX, 1976GuZN, 1977Po05, 1980Sc26, 1981Li30, 1983Ah02, +236U 3C 1991Sc08, 1996FiZX, 2003Au03, 2006Br20, 2008Ki07 +236U T Auger electrons and ^X ray energies and emission intensities: +236U T {U Energy (keV)} {U Intensity } {U Line } +236U T +236U T 94.666 20.2 3 XKA2 +236U T 98.44 32.4 5 XKA1 +236U T +236U T 110.421 |] XKB3 +236U T 111.298 |] 11.69 25 XKB1 +236U T 111.964 |] XKB5II +236U T +236U T 114.407 |] XKB2 +236U T 115.012 |] 4.00 11 XKB4 +236U T 115.377 |] XKO23 +236U T +236U T 11.619-20.714 117.5 30 XL (total) +236U T 11.619 2.63 7 XLL +236U T 13.438-13.615 42.3 11 XLA +236U T 15.399 1.24 4 XLC +236U T 15.727-18.206 57.7 13 XLB +236U T 19.507-20.714 13.6 3 XLG +236U T +236U T 71.78-80.95 |] KLL AUGER +236U T 88.15-98.43 |] 2.1 3 ^KLX AUGER +236U T 104.51-115.59 |] KXY AUGER +236U T 6.07-21.68 128.8 19 L AUGER +236NP P 0.0 6- 1.55E5 Y 8 930 50 +236U N 1.139E0 1.139E0 0.878 1.139E0 +236U L 0 0+ 23.43E6 Y 6 +236U L 45.244 2 2+ 234 PS 6 +236U G 45.244 2 0.149 3 E2 589 12 +236U 2 G KC=$LC=429 9$MC=118.6 24 +236U L 149.477 6 4+ 124 PS 7 +236U E 4.4 15.9 1U +236U 2 E EAV= $CK=0.74 $CL=0.19 $CM=0.07 $CN=0.0001 $CO= +236U G 104.234 6 7.32 13E2 10.99 22 +236U 2 G KC=$LC=8.00 16$MC=2.22 5 +236U L 309.785 7 6+ 58 PS 3 +236U E 87.8 4314.1 +236U 2 E EAV= $CK=0.726 8$CL=0.201 5$CM=0.073 2$CN=0.0001 $CO= +236U G 160.307 3 31.8 15E2 1.76 4 +236U 2 G KC=0.208 4$LC=1.13 2$MC=0.313 7 +236U L 687.59 4 1- 3.78 NS 9 +236U G 538.1 1 7000E-7 0 E3 0.143 3 +236U 2 G KC=0.0622 13$LC=0.0587 12$MC=0.0160 3 +236U G 642.34 5 5900E-5 0 E1+(M2+E3) 0.15 2 +236U 2 G KC=0.112 10$LC=$MC= +236U G 687.60 5 1600E-5 0 E1+(M2+E3) 0.31 2 +236U 2 G KC=0.219 12$LC=0.068 6$MC= +236U L 744.18 7 3- 0.1 NS +236U G 56.6 5 4000E-7 0 (E2) 199 10 +236U 2 G KC=$LC=145 7$MC=40.1 19 +236U G 594.5 3 8000E-6 0 +236U L 848.1 8 5- +236U E 0.096 14.6 +236U 2 E EAV= $CK= $CL=0.6 $CM=0.4 $CN= $CO= +236U G 104.1 108000E-6 0 E2 11.1 6 +236U 2 G KC=$LC=8.1 4$MC=2.23 11 + +232PA 236NP A DECAY (1.55E5 Y) +232PA H TYP=update$AUT=mmbe$CUT= -- $ +232PA2 H TYP=update$AUT=mmbe$CUT= -- $ +232PA3 H TYP=update$AUT=mmbe$CUT= -- $ +232PA4 H TYP=update$AUT=mmbe$CUT= -- $ +232PA5 H TYP=update$AUT=mmbe$CUT= -- $ +232PA6 H TYP=Full$AUT=V.P. Chechev$CUT=27-JUN-2006$ +232PA7 H TYP=Full$AUT=V.P. Chechev$CUT=27-JUN-2006$ +232PA8 H TYP=Full$AUT=V.P. Chechev$CUT=27-JUN-2006$ +232PA9 H TYP=Full$AUT=V.P. Chechev$CUT=27-JUN-2006$ +232PAA H TYP=Full$AUT=V.P. Chechev$CUT=27-JUN-2006$ +232PA C Evaluation history: Type=update;Author=mmbe;Cutoff date= -- +232PA2C Type=update;Author=mmbe;Cutoff date= -- +232PA3C Type=update;Author=mmbe;Cutoff date= -- +232PA4C Type=update;Author=mmbe;Cutoff date= -- +232PA5C Type=update;Author=mmbe;Cutoff date= -- +232PA6C Type=Full;Author=V.P. Chechev;Cutoff date=27-JUN-2006 +232PA7C Type=Full;Author=V.P. Chechev;Cutoff date=27-JUN-2006 +232PA8C Type=Full;Author=V.P. Chechev;Cutoff date=27-JUN-2006 +232PA9C Type=Full;Author=V.P. Chechev;Cutoff date=27-JUN-2006 +232PAAC Type=Full;Author=V.P. Chechev;Cutoff date=27-JUN-2006 +232PA C References: 1969Le05, 1971Dr11, 1971GuZY, 1972Dzh., 1972El21, 1972En06, +232PA2C 1975Dr05, 1975OtZX, 1976GuZN, 1977Po05, 1980Sc26, 1981Li30, 1983Ah02, +232PA3C 1991Sc08, 1996FiZX, 2003Au03, 2006Br20, 2008Ki07 +232PA T Auger electrons and ^X ray energies and emission intensities: +232PA T {U Energy (keV)} {U Intensity } {U Line } +232PA T +232PA T 92.288 XKA2 +232PA T 95.869 XKA1 +232PA T +232PA T 107.595 |] XKB3 +232PA T 108.422 |] XKB1 +232PA T 109.072 |] XKB5II +232PA T +232PA T 111.405 |] XKB2 +232PA T 111.87 |] XKB4 +232PA T 112.38 |] XKO23 +232PA T +232PA T +232PA T 70.081-78.822 |] KLL AUGER +232PA T 85.989-95.858 |] ^KLX AUGER +232PA T 101.87-112.59 |] KXY AUGER +232PA T 6.011-21.0077 L AUGER +236NP P 0.0 6- 1.55E5 Y 8 5010 50 +232PA N 6.25E2 6.25E2 0.0016 6.25E2 +232PA L 0 - 1.31 D 2 + +236PU 236NP B- DECAY (1.55E5 Y) +236PU H TYP=update$AUT=mmbe$CUT= -- $ +236PU2 H TYP=update$AUT=mmbe$CUT= -- $ +236PU3 H TYP=update$AUT=mmbe$CUT= -- $ +236PU4 H TYP=update$AUT=mmbe$CUT= -- $ +236PU5 H TYP=update$AUT=mmbe$CUT= -- $ +236PU6 H TYP=Full$AUT=V.P. Chechev$CUT=27-JUN-2006$ +236PU7 H TYP=Full$AUT=V.P. Chechev$CUT=27-JUN-2006$ +236PU8 H TYP=Full$AUT=V.P. Chechev$CUT=27-JUN-2006$ +236PU9 H TYP=Full$AUT=V.P. Chechev$CUT=27-JUN-2006$ +236PUA H TYP=Full$AUT=V.P. Chechev$CUT=27-JUN-2006$ +236PU C Evaluation history: Type=update;Author=mmbe;Cutoff date= -- +236PU2C Type=update;Author=mmbe;Cutoff date= -- +236PU3C Type=update;Author=mmbe;Cutoff date= -- +236PU4C Type=update;Author=mmbe;Cutoff date= -- +236PU5C Type=update;Author=mmbe;Cutoff date= -- +236PU6C Type=Full;Author=V.P. Chechev;Cutoff date=27-JUN-2006 +236PU7C Type=Full;Author=V.P. Chechev;Cutoff date=27-JUN-2006 +236PU8C Type=Full;Author=V.P. Chechev;Cutoff date=27-JUN-2006 +236PU9C Type=Full;Author=V.P. Chechev;Cutoff date=27-JUN-2006 +236PUAC Type=Full;Author=V.P. Chechev;Cutoff date=27-JUN-2006 +236PU C References: 1969Le05, 1971Dr11, 1971GuZY, 1972Dzh., 1972El21, 1972En06, +236PU2C 1975Dr05, 1975OtZX, 1976GuZN, 1977Po05, 1980Sc26, 1981Li30, 1983Ah02, +236PU3C 1991Sc08, 1996FiZX, 2003Au03, 2006Br20, 2008Ki07 +236PU T Auger electrons and ^X ray energies and emission intensities: +236PU T {U Energy (keV)} {U Intensity } {U Line } +236PU T +236PU T 99.525 0.212 23 XKA2 +236PU T 103.734 0.33 4 XKA1 +236PU T +236PU T 116.244 |] XKB3 +236PU T 117.228 |] 0.123 14 XKB1 +236PU T 117.918 |] XKB5II +236PU T +236PU T 120.54 |] XKB2 +236PU T 120.969 |] 0.043 5 XKB4 +236PU T 121.543 |] XKO23 +236PU T +236PU T 12.1246-21.984 12.1 4 XL (total) +236PU T 12.1246 0.276 11 XLL +236PU T 14.083-14.279 4.30 16 XLA +236PU T 16.334 0.133 7 XLC +236PU T 16.499-18.543 5.92 24 XLB +236PU T 20.708-21.984 1.42 6 XLG +236PU T +236PU T 75.26-85.36 |] KLL AUGER +236PU T 92.61-103.73 |] 0.021 4 ^KLX AUGER +236PU T 109.93-121.78 |] KXY AUGER +236PU T 6.19-23.1 10.7 3 L AUGER +236NP P 0.0 6- 1.55E5 Y 8 480 50 +236PU N 8.333E0 8.333E0 0.12 8.333E0 +236PU L 0 0+ 2.87 Y 1 +236PU L 44.63 102+ +236PU G 44.63 100.0161 9 E2 741 15 +236PU2 G KC=$LC=538 11$MC=150 3 +236PU L 147.45 104+ +236PU B 333 501.6 16 1U +236PUS B EAV=92 16 +236PU G 102.82 2 0.81 6 E2 13.87 28 +236PU2 G KC=$LC=10.06 20$MC=2.82 6 +236PU L 305.80 116+ +236PU B 174 5011.8 12 14.5 +236PUS B EAV=46 15 +236PU G 158.35 3 3.8 4 E2 2.14 4 +236PU2 G KC=0.193 4$LC=1.41 3$MC=0.394 8 + diff --git a/HEN_HOUSE/spectra/lnhb/Np-236m.txt b/HEN_HOUSE/spectra/lnhb/Np-236m.txt new file mode 100644 index 000000000..eccb96126 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Np-236m.txt @@ -0,0 +1,97 @@ +236U 236NP EC DECAY (22.5 H) +236U H TYP=Full$AUT=V.P.Chechev$CUT=18-JUN-2006$ +236U C Evaluation history: Type=Full;Author=V.P.Chechev;Cutoff date=18-JUN-2006 +236U C References: 1949Ja01, 1956Gr11, 1959Gi58, 1967Be65, 1969Le05, 1971GuZY, +236U 2C 1971Dr11, 1975OtZX, 1975Dr05, 1976GuZN, 1977Po05, 1977La19, 1984Gr33, +236U 3C 1987Lag., 1991Sc08, 1996Sc06, 1996FiZX, 2003Au03 +236U T Auger electrons and X ray energies and emission intensities: +236U T {U Energy (keV)} {U Intensity} {U Line} +236U T +236U T 94.666 9.9 10 XKA2 +236U T 98.44 15.8 15 XKA1 +236U T +236U T 110.421 |] XKB3 +236U T 111.298 |] 5.7 6 XKB1 +236U T 111.964 |] XKB5II +236U T +236U T 114.407 |] XKB2 +236U T 115.012 |] 1.95 15 XKB4 +236U T 115.377 |] XKO23 +236U T +236U T 11.618-20.714 21.3 18 XL (total) +236U T 11.618 0.57 5 XLL +236U T 13.438-13.614 9.1 8 XLA +236U T 15.399 0.166 17 XLC +236U T 15.726-18.206 9.4 6 XLB +236U T 19.507-20.714 2.07 15 XLG +236U T +236U T 71.776-80.954 |] KLL AUGER +236U T 88.153-98.429 |] 1.03 17 KLX AUGER +236U T 104.51-115.59 |] KXY AUGER +236U T 6.4-21.6 21.7 15 L AUGER +236NP P 60 501+ 22.5 H 4 930 50 +236U N 1.887E0 1.887E0 0.53 1.887E0 +236U L 0 0+ STABLE +236U E 43.1 327.1 +236U 2 E EAV= $CK=0.753 1$CL=0.182 1$CM=0.0646 1$CN= $CO= +236U L 45.242 3 2+ 234 PS +236U E 8.3 307.8 +236U 2 E EAV= $CK=0.751 1$CL=0.184 1$CM=0.0652 1$CN= $CO= +236U G 45.242 3 0.016 5 E2 589 12 +236U 2 G KC=$LC=429 9$MC=118.6 24 +236U L 149.476 154+ 124 PS +236U G 104.234 6 0.00119 14E2 11.0 2 +236U 2 G KC=$LC=8.00 16$MC=2.22 5 +236U L 309.783 6+ 58 PS +236U L 687.60 5 1- 3.8 NS +236U E 1.64 9 7.3 +236U 2 E EAV= $CK=0.621 10$CL=0.274 7$CM=0.105 3$CN= $CO= +236U G 538.11 100.0125 15E3 0.143 3 +236U 2 G KC=0.0622 13$LC=0.0587 12$MC=0.0160 4 +236U G 642.35 9 1.08 6 E1+(M2+E3) 0.15 2 +236U 2 G KC=0.112 10$LC=0.031 3$MC=0.0080 8 +236U G 687.60 5 0.292 21E1 0.31 2 +236U 2 G KC=0.219 12$LC=0.068 6$MC=0.018 2 + +236PU 236NP B- DECAY (22.5 H) +236PU H TYP=Full$AUT=V.P.Chechev$CUT=18-JUN-2006$ +236PU C Evaluation history: Type=Full;Author=V.P.Chechev;Cutoff date=18-JUN-2006 +236PU C References: 1949Ja01, 1956Gr11, 1959Gi58, 1967Be65, 1969Le05, 1971GuZY, +236PU2C 1971Dr11, 1975OtZX, 1975Dr05, 1976GuZN, 1977Po05, 1977La19, 1984Gr33, +236PU3C 1987Lag., 1991Sc08, 1996Sc06, 1996FiZX, 2003Au03 +236PU T Auger electrons and X ray energies and emission intensities: +236PU T {U Energy (keV)} {U Intensity} {U Line} +236PU T +236PU T 99.525 XKA2 +236PU T 103.734 XKA1 +236PU T +236PU T 116.244 |] XKB3 +236PU T 117.228 |] XKB1 +236PU T 117.918 |] XKB5II +236PU T +236PU T 120.54 |] XKB2 +236PU T 120.969 |] XKB4 +236PU T 121.543 |] XKO23 +236PU T +236PU T 12.124-21.984 4.2 16 XL (total) +236PU T 12.124 0.10 4 XLL +236PU T 14.083-14.279 1.5 6 XLA +236PU T 16.334 0.046 17 XLC +236PU T 16.498-19.331 2.1 8 XLB +236PU T 20.708-21.984 0.49 18 XLG +236PU T +236PU T 75.263-85.357 |] KLL AUGER +236PU T 92.607-103.729 |] KLX AUGER +236PU T 109.93-121.78 |] KXY AUGER +236PU T 6.19-22.99 3.8 14 L AUGER +236NP P 60 501+ 22.5 H 4 480 50 +236PU N 2.128E0 2.128E0 0.47 2.128E0 +236PU L 0 0+ STABLE +236PU B 537 8 36 4 6.8 +236PUS B EAV=158 3 +236PU L 44.63 102+ +236PU B 492 8 11 4 7.2 +236PUS B EAV=143 3 +236PU G 44.63 100.015 5 E2 743 15 +236PU2 G KC=$LC=540 11$MC=151 3 + diff --git a/HEN_HOUSE/spectra/lnhb/Np-237.txt b/HEN_HOUSE/spectra/lnhb/Np-237.txt new file mode 100644 index 000000000..8b19b354e --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Np-237.txt @@ -0,0 +1,199 @@ +233PA 237NP A DECAY (2.144E6 Y) +233PA H TYP=Full$AUT=V.Chechev$CUT=31-OCT-2007$ +233PA2 H TYP=Full$AUT=V.Chechev$CUT=31-OCT-2007$ +233PA3 H TYP=Full$AUT=V.Chechev$CUT=31-OCT-2007$ +233PA C Evaluation history: Type=Full;Author=V.Chechev;Cutoff date=31-OCT-2007 +233PA2C Type=Full;Author=V.Chechev;Cutoff date=31-OCT-2007 +233PA3C Type=Full;Author=V.Chechev;Cutoff date=31-OCT-2007 +233PA C References: 1949Ma01, 1960Br12, 1960As02, 1961Dr04, 1961Ba44, 1968Br12, +233PA2C 1968Br25, 1969HoXY, 1969Br12, 1971Cl03, 1974HeYW, 1976Sk01, 1979Go12, +233PA3C 1981Ba68, 1984BaYS, 1984Va27, 1986LoZT, 1988Io05, 1988Wo01, 1990Lo04, +233PA4C 1990Bo44, 1992Lo03, 1992Gr16, 2000Sc04, 2000Si02, 2000Wo01, 2002Lu01, +233PA5C 2002Wo03, 2002Ba85, 2003Au03, 2004Sh07, 2005Si15, 2006Ch39, 2008De10, +233PA6C 2008Ki07 +233PA T Auger electrons and ^X ray energies and emission intensities: +233PA T {U Energy (keV)} {U Intensity } {U Line } +233PA T +233PA T 92.288 1.813 20 XKA2 +233PA T 95.869 2.906 20 XKA1 +233PA T +233PA T 107.595 |] XKB3 +233PA T 108.422 |] 1.06 10 XKB1 +233PA T 109.072 |] XKB5II +233PA T +233PA T 111.405 |] XKB2 +233PA T 111.87 |] 0.380 9 XKB4 +233PA T 112.38 |] XKO23 +233PA T +233PA T 11.368-20.113 59.7 32 XL (total) +233PA T 11.368 1.32 8 XLL +233PA T 13.122-13.289 24.0 24 XLA +233PA T 14.949 0.54 4 XLC +233PA T 15.358-17.666 28 2 XLB +233PA T 18.94-20.113 5.8 4 XLG +233PA T +233PA T 70.08-78.82 |] KLL AUGER +233PA T 85.99-95.86 |] 0.167 24 ^KLX AUGER +233PA T 101.87-112.59 |] KXY AUGER +233PA T 5.9-21.01 47.1 20 L AUGER +237NP P 0.0 5/2+ 2.144E6 Y 7 4958.3 12 +233PA N 1.0 1.0 1 1.0 +233PA G 21.5 0.352 13 +233PA G 27.7 0.84 7 +233PA G 29.6 +233PA G 288.3 0.0162 5 +233PA L 0 3/2- 26.98 D 2 +233PA A 4872.7 142.41 3 387 +233PA L 6.654 251/2- +233PA A 4866.4 140.51 3 1570 +233PA A 4550.5 220.011 3 84000 +233PA G 6.65 5 (M1) 3080 90 +233PA2 G KC=$LC=$MC=2280 60 +233PA L 57.101 147/2- +233PA A 4816.8 102.430 17156 +233PA G 57.104 200.381 21E2 176 4 +233PA2 G KC=$LC=128 3$MC=35.3 7 +233PA L 70.510 255/2- +233PA A 4803.5 102.02 2 152 +233PA G 63.9 1 0.0107 4 (E2) 102.3 20 +233PA2 G KC=$LC=74.7 15$MC=20.6 4 +233PA G 70.49 100.0107 4 [M1+E2] 1 1 38 26 +233PA2 G KC=$LC=28 19$MC=8 5 +233PA L 86.469 9 5/2+ 35.8 NS 4 +233PA A 4788.0 9 47.64 6 5 +233PA G 29.374 2014.3 6 E1 3.07 6 +233PA2 G KC=$LC=2.29 5$MC=0.585 12 +233PA G 86.477 1012.26 12E1 1.43 8 +233PA2 G KC=$LC=1.13 5$MC=0.22 6 +233PA L 94.645 163/2+ +233PA G 8.22 5 0.12 5 +233PA G 87.99 3 0.143 3 [E1] 0.169 4 +233PA2 G KC=$LC=0.128 3$MC=0.0312 6 +233PA G 94.64 5 0.66 7 E1 0.140 3 +233PA2 G KC=$LC=0.1054 21$MC=0.0257 5 +233PA L 103.636 207/2+ +233PA A 4771.4 8 23.0 3 7.8 +233PA G 9 +233PA G 17.40 5 M1+E2 +233PA G 46.53 6 0.109 4 [E1] 0.914 18 +233PA2 G KC=$LC=0.687 14$MC=0.171 4 +233PA L 109.04 5 9/2+ +233PA A 4766.5 8 9.5 3 17.9 +233PA G 5.18 0.220 5 +233PA G 22.6 +233PA L 133.2 10(11/2+)+ +233PA A 4741.3 200.019 5932 +233PA G 24.14 10 +233PA L 163.34 10(11/2-)- +233PA A 4712.3 201.174 1351 +233PA G 54.4 1 +233PA G 106.15 250.0509 29[E2] 9.28 19 +233PA2 G KC=$LC=6.78 14$MC=1.87 4 +233PA L 169.152 201/2+ +233PA A 4708.3 200 56 +233PA G 74.54 100.012 3 [M1] 9.84 20 +233PA2 G KC=$LC=7.42 15$MC=1.79 4 +233PA G 162.41 8 0.033 1 [E1] 0.158 3 +233PA2 G KC=0.1232 25$LC=0.0260 5$MC=0.00630 13 +233PA G 169.156 200.0672 3 [E1] 0.143 3 +233PA2 G KC=0.1120 22$LC=0.0235 5$MC=0.00568 11 +233PA L 179.1 4 (9/2-)- +233PA A 4698.2 8 0.535 1099 +233PA G 109.1 1 +233PA L 201.594 193/2+ +233PA A 4676.4 0.38 2 +233PA G 32.46 +233PA G 115.40 350.0026 8 [M1+E2] 10 4 +233PA2 G KC=5 6$LC=3.3 13$MC=0.9 4 +233PA G 131.101 250.084 5 E1 0.262 5 +233PA2 G KC=0.202 4$LC=0.0451 9$MC=0.01094 22 +233PA G 194.95 3 0.174 20E1 0.1024 21 +233PA2 G KC=0.0806 16$LC=0.0164 4$MC=0.00397 8 +233PA G 201.62 5 0.0392 9 E1 0.0946 19 +233PA2 G KC=0.0746 15$LC=0.0151 3$MC=0.00365 7 +233PA L 212.342 185/2+ +233PA A 4665.0 9 3.46 3 8.9 +233PA G 10.7 +233PA G 43.2 +233PA G 108.7 0.071 3 M1+E2 0.22 3.5 6 +233PA2 G KC=$LC=2.7 5$MC=0.65 13 +233PA G 117.702 200.171 4 M1+E2 0.30 9 12.2 6 +233PA2 G KC=9.3 5$LC=2.16 12$MC=0.53 4 +233PA G 141.74 10 +233PA G 155.239 200.088 8 E1 0.176 4 +233PA2 G KC=0.1368 27$LC=0.0292 6$MC=0.00708 14 +233PA G 212.29 5 0.17 1 E1 0.0839 17 +233PA2 G KC=0.0663 13$LC=0.0133 3$MC=0.00321 7 +233PA L 237.895 135/2+ +233PA A 4640 1 6.43 3 3.14 +233PA G 36.32 2 0.005 1 M1+E2 0.11 5 99 20 +233PA2 G KC=$LC=74 15$MC=18 4 +233PA G 134.285 200.069 5 [M1+E2] 0.4 2 8.0 11 +233PA2 G KC=6.1 10$LC=1.5 3$MC=0.37 8 +233PA G 143.249 200.42 4 M1+E2 0.29 3 6.94 14 +233PA2 G KC=5.38 12$LC=1.171 24$MC=0.287 6 +233PA G 151.414 200.234 2 M1+E2 0.70 15 4.9 6 +233PA2 G KC=3.4 5$LC=1.09 4$MC=0.277 14 +233PA G 180.81 100.016 1 [E1] 0.1223 25 +233PA2 G KC=0.0960 19$LC=0.0199 4$MC=0.0048 1 +233PA G 237.86 2 0.0573 6 [E1] 0.0645 13 +233PA2 G KC=0.0511 10$LC=0.01010 15$MC=0.00243 5 +233PA L 257.1 4 5/2- +233PA A 4619.7 210.032 8 46000 +233PA G 153.37 +233PA G 162.41 +233PA G 170.59 +233PA G 186.86 +233PA G 199.95 +233PA G 250.58 +233PA G 257.09 +233PA L 279.71 3 (7/2+)+ +233PA A 4599.1 180.373 9 27 +233PA G 170.59 6 0.020 4 [M1+E2] 0.4 2 4.0 5 +233PA2 G KC=3.1 5$LC=0.70 7$MC=0.17 1 +233PA G 176.12 6 0.015 3 [M1+E2] 0.4 2 3.7 5 +233PA2 G KC=2.8 4$LC=0.63 7$MC=0.16 1 +233PA G 193.26 5 0.044 1 [M1+E2] 0.4 2 2.8 4 +233PA2 G KC=2.2 3$LC=0.48 5$MC=0.12 1 +233PA G 209.19 5 0.0150 15[E1] 0.0868 17 +233PA2 G KC=0.0686 14$LC=0.0138 3$MC=0.00333 7 +233PA G 222.6 2 0.002 2 +233PA L 300.48 3 7/2++ +233PA A 4578.6 140.393 2319.1 +233PA G 62.59 100.006 2 [M1+E2] 1 1 60 50 +233PA2 G KC=$LC=50 40$MC=13 10 +233PA G 191.46 5 0.019 1 [M1+E2] 0.4 2 2.9 4 +233PA2 G KC=2.2 3$LC=0.49 5$MC=0.12 1 +233PA G 196.86 5 0.0210 1 [M1+E2] 0.4 2 2.7 3 +233PA2 G KC=2.1 3$LC=0.45 5$MC=0.11 1 +233PA G 214.01 5 0.037 2 [M1+E2] 0.4 2 2.1 3 +233PA2 G KC=1.64 23$LC=0.35 1$MC=0.09 1 +233PA G 229.94 5 0.014 3 [E1] 0.0697 14 +233PA2 G KC=0.0552 11$LC=0.0110 2$MC=0.00264 5 +233PA L 303.59 7 (9/2+)+ +233PA A 4573 3 0.048 23139 +233PA G 139.9 1 0.0046 4 [E1] 0.225 5 +233PA2 G KC=0.174 3$LC=0.0381 8$MC=0.00925 19 +233PA G 194.67 200.033 1 +233PA G 199.95 6 0.0053 8 [M1] 2.85 6 +233PA2 G KC=2.27 5$LC=0.436 9$MC=0.105 2 +233PA L 306.05 10(7/2+)+ +233PA G 48.96 10 +233PA G 219.8 +233PA G 248.95 100.005 1 [M1+E2] 0.4 2 1.37 16 +233PA2 G KC=1.08 15$LC=0.22 1$MC=0.055 6 +233PA L 365.93 8 9/2+ +233PA A 4515.1 190.038 4 65 +233PA G 153.37 100.007 2 [E2] 1.96 4 +233PA2 G KC=0.226 5$LC=1.267 3$MC=0.349 7 +233PA G 186.86 350.003 3 [E1] 0.1131 23 +233PA2 G KC=0.0889 19$LC=0.0183 4$MC=0.00442 9 +233PA G 202.9 2 0.0048 19[E1] 0.0932 19 +233PA2 G KC=0.074 5$LC=0.0149 3$MC=0.00360 7 +233PA G 257.09 200.02 1 [M1] 1.41 3 +233PA2 G KC=1.125 23$LC=0.215 4$MC=0.0518 11 +233PA G 262.44 200.0048 2 [M1] 1.33 3 +233PA2 G KC=1.063 21$LC=0.203 4$MC=0.0489 10 +233PA G 279.65 200.0108 4 [E2] 0.222 5 +233PA2 G KC=0.0847 17$LC=0.100 2$MC=0.0272 6 + diff --git a/HEN_HOUSE/spectra/lnhb/Np-238.txt b/HEN_HOUSE/spectra/lnhb/Np-238.txt new file mode 100644 index 000000000..5fbf560a5 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Np-238.txt @@ -0,0 +1,146 @@ +238PU 238NP B- DECAY (2.102 D) +238PU H TYP=Full$AUT=V.P Chechev. N.K. Kuzmenko$CUT=30-NOV-2006$ +238PU C Evaluation history: Type=Full;Author=V.P Chechev. N.K. Kuzmenko;Cutoff date=30-NOV-2006 +238PU C References: 1950Fr53, 1952Du12, 1956Ba95, 1956Sm18, 1958Al92, 1960As10, +238PU2C 1960Al29, 1965Ak02, 1966Qa01, 1970Be57, 1972Wi22, 1981Le15, 1990Ch35, +238PU3C 1996Sc06, 2002Ch52, 2003Au03, 2006Re09 +238PU T Auger electrons and ^X ray energies and emission intensities: +238PU T {U Energy (keV)} {U Intensity } {U Line } +238PU T +238PU T 99.525 0.210 8 XKA2 +238PU T 103.734 0.332 12 XKA1 +238PU T +238PU T 116.244 |] XKB3 +238PU T 117.228 |] 0.122 5 XKB1 +238PU T 117.918 |] XKB5II +238PU T +238PU T 120.54 |] XKB2 +238PU T 120.969 |] 0.042 2 XKB4 +238PU T 121.543 |] XKO23 +238PU T +238PU T 12.125-21.984 32.4 14 XL (total) +238PU T 12.125 0.797 25 XLL +238PU T 14.083-14.279 12.5 4 XLA +238PU T 16.334 0.338 12 XLC +238PU T 16.499-19.331 15.4 5 XLB +238PU T 20.708-21.984 3.58 10 XLG +238PU T +238PU T 75.26-85.36 |] KLL AUGER +238PU T 92.607-103.729 |] 0.021 8 ^KLX AUGER +238PU T 109.93-121.78 |] KXY AUGER +238PU T 6.19-22.99 29.7 14 L AUGER +238NP P 0.0 2+ 2.102 D 5 1291.5 4 +238PU N 1.0 1.0 1 1.0 +238PU G 103.74 2 0.312 3 +238PU G 116.27 8 4000E-5 0 +238PU G 117.27 8 7400E-5 0 +238PU G 120.5 2000E-5 0 +238PU G 121.70 8 0.010 1 +238PU G 220.87 110.0030 5 (M2) 11.4 20 +238PU G 885 0.040 5 +238PU L 0 0+ 87.74 Y 3 +238PU L 44.08 2 2+ 177 PS 5 +238PU B 1247.4 4 41.0 25 8.38 +238PUS B EAV=412.2 2 +238PU G 44.07 2 0.1024 21E2 788 16 +238PU2 G KC=$LC=572 12$MC=160 3 +238PU L 145.95 2 4+ +238PU G 101.88 2 0.252 8 E2 14.5 3 +238PU2 G KC=$LC=10.5 2$MC=2.94 6 +238PU L 303.38 6 6+ +238PU G 157.42 5 1000E-6 0 [E2] 2.19 4 +238PU2 G KC=0.193 4$LC=1.45 3$MC=0.405 8 +238PU L 605.14 4 1- +238PU B 686.4 4 0.103 3 10.08 1 +238PUS B EAV=208.4 2 +238PU G 561.14 5 0.106 2 E1 0.0115 2 +238PU2 G KC=0.00929 19$LC=0.00169 4$MC=4.07E-4 8 +238PU G 605.16 5 0.077 2 E1 0.0100 2 +238PU2 G KC=0.00806 16$LC=0.00146 3$MC=3.50E-4 7 +238PU L 661.40 6 3- +238PU B 630.1 4 0.036 3 10.44 1 +238PUS B EAV=189.2 2 +238PU G 515.51 7 0.0378 11E1+M2 0.114 17 0.022 4 +238PU2 G KC=0.017 3$LC=0.0037 7$MC=0.00092 17 +238PU G 617.39 5 5930E-5 0 E1+M2 0.077 17 0.0120 14 +238PU2 G KC=0.0095 11$LC=0.00185 22$MC=0.00045 5 +238PU L 763.24 115- +238PU G 459.8 2 0.0023 15 +238PU G 617.4 8000E-6 0 +238PU L 941.46 8 0+ +238PU G 336.36 150.0002 1 [E1] 0.0324 7 +238PU2 G KC=0.0257 5$LC=0.00503 10$MC=0.00122 3 +238PU G 897.34 100.0073 10(E2) 0.0152 3 +238PU2 G KC=0.0111 2$LC=0.00308 6$MC=0.00078 2 +238PU G 941.5 3 +238PU L 962.78 2 1- +238PU B 328.7 4 1.25 1 7.95 1 +238PUS B EAV=91.8 2 +238PU G 301.37 7 0.0106 10E2 0.208 4 +238PU2 G KC=0.0766 16$LC=0.096 2$MC=0.0264 5 +238PU G 357.64 7 0.0504 13M1+E2 2.43 20 0.214 16 +238PU2 G KC=0.133 12$LC=0.060 5$MC=0.0158 12 +238PU G 918.70 4 0.529 6 E1 0.0047 1 +238PU2 G KC=0.00383 8$LC=0.00066 1$MC=1.58E-4 3 +238PU G 962.76 2 0.645 8 E1 0.004339 +238PU2 G KC=0.00352 7$LC=0.00061 1$MC=1.45E-4 3 +238PU L 968.2 4 (2)- +238PU B 323.3 6 0.082 6 9.11 +238PUS B EAV=90.1 2 +238PU G 924 6500E-5 0 +238PU G 968.9 4 0.015 8 [M2] 0.116 3 +238PU2 G KC=0.089 2$LC=0.0200 4$MC=0.0050 1 +238PU L 983.09 7 2+ +238PU B 308.4 4 0.27 3 8.51 +238PUS B EAV=85.6 2 +238PU G 321.75 200.0013 8 +238PU G 378.05 130.0030 5 +238PU G 836.96 7 0.0206 8 [E2] 0.0174 4 +238PU2 G KC=0.0125 3$LC=0.00366 8$MC=0.00093 2 +238PU G 938.94 100.0327 25+E2 4.4 4 +238PU2 G KC=3.5 4$LC=0.67 7$MC= +238PU G 983.0 3 0.068 20[E2] 0.0128 3 +238PU2 G KC=0.00947 19$LC=0.00247 5$MC=0.00062 1 +238PU L 985.45 5 2- +238PU B 306.0 4 0.49 1 8.25 +238PUS B EAV=84.9 2 +238PU G 324.02 9 0.0146 8 M1+E2 2.8 8 0.26 7 +238PU2 G KC=0.15 6$LC=0.082 7$MC=0.022 2 +238PU G 380.31 100.0111 5 [M1] 0.623 9 +238PU2 G KC=0.493 10$LC=0.098 2$MC=0.0237 5 +238PU G 941.40 4 0.504 6 [E1+M2] +238PU L 1028.54 2 2+ +238PU B 263.0 4 44.75 19 6.09 +238PUS B EAV=72.0 2 +238PU G 882.63 3 0.803 9 (E2) 0.0157 3 +238PU2 G KC=0.0114 2$LC=0.00320 7$MC=0.00081 2 +238PU G 984.45 2 25.18 13M1+E2 0.0125 5 +238PU2 G KC=0.0096 3$LC=0.0022 1$MC=0.0006 1 +238PU G 1028.54 2 18.25 13E2 0.0117 2 +238PU2 G KC=0.00875 18$LC=0.00222 5$MC=0.00055 1 +238PU L 1069.94 2 3+ +238PU B 221.6 4 11.50 7 6.44 +238PUS B EAV=59.9 2 +238PU G 923.99 2 2.604 20(M1+E2) 0.014 1 +238PU2 G KC=0.0099 4$LC=$MC= +238PU G 1025.87 2 8.76 6 M1+E2 0.0120 5 +238PU2 G KC=0.0091 4$LC=0.0021 1$MC=0.0006 1 +238PU L 1082.56 6 (4)- +238PU G 114.4 4 0.0058 10[E2] 8.47 17 +238PU2 G KC=$LC=6.15 12$MC=1.72 14 +238PU G 319.29 110.0083 10M1+E2 1.0 5 0.59 25 +238PU2 G KC=0.43 22$LC=0.118 25$MC=0.030 5 +238PU G 421.1 1 0.021 1 [M1] 0.472 7 +238PU2 G KC=0.374 8$LC=0.0737 15$MC=0.0179 4 +238PU G 936.60 5 0.365 5 [E1+M2] -0.24 4 0.0112 22 +238PU2 G KC=0.0089 17$LC=0.0018 4$MC=0.00044 10 +238PU L 1202.46 8 (3)- +238PU B 89.0 4 0.51 6 6.57 1 +238PUS B EAV=23.0 2 +238PU G 120.11 5 0.101 5 M1(+E2) 3.8 6 +238PU2 G KC=$LC=2.8 6$MC=0.69 6 +238PU G 132.5 1 0.0014 8 [E1] 0.267 5 +238PU2 G KC=0.203 4$LC=0.048 1$MC=0.0118 2 +238PU G 174.08 5 0.0229 8 [E1] 0.142 3 +238PU2 G KC=0.110 2$LC=0.0241 5$MC=0.0059 1 + diff --git a/HEN_HOUSE/spectra/lnhb/Np-239.txt b/HEN_HOUSE/spectra/lnhb/Np-239.txt new file mode 100644 index 000000000..d5a76b7df --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Np-239.txt @@ -0,0 +1,141 @@ +239PU 239NP B- DECAY (2.356 D) +239PU H TYP=Full$AUT=V.P. Chechev. N.K. Kuzmenco$CUT= -- $ +239PU C Evaluation history: Type=Full;Author=V.P. Chechev. N.K. Kuzmenco;Cutoff date= -- +239PU C References: 1952Fr25, 1956Wi25, 1956Ba95, 1959Co93, 1959Co63, 1959Ew90, +239PU2C 1965Ma17, 1966Qa01, 1969Bi12, 1972Po04, 1972Kr07, 1972Ah02, 1974HeYW, +239PU3C 1974Yu04, 1977St35, 1979Mo25, 1979Bo30, 1982Ah04, 1984Va41, 1986Ch17, +239PU4C 1990Ab06, 1990Si12, 1991Sh06, 1991Po17, 1992Ha02, 1996FiZX, 1996Wo05, +239PU5C 1996Sc06, 2003Au03, 2003Br12 +239PU T Auger electrons and ^X ray energies and emission intensities: +239PU T {U Energy (keV)} {U Intensity } {U Line } +239PU T +239PU T 99.525 13.5 4 XKA2 +239PU T 103.734 21.4 6 XKA1 +239PU T +239PU T 116.244 |] XKB3 +239PU T 117.228 |] 7.84 25 XKB1 +239PU T 117.918 |] XKB5II +239PU T +239PU T 120.54 |] XKB2 +239PU T 120.969 |] 2.72 10 XKB4 +239PU T 121.543 |] XKO23 +239PU T +239PU T 12.125-21.984 51.3 24 XL (total) +239PU T 12.125 1.38 6 XLL +239PU T 14.083-14.279 21.5 10 XLA +239PU T 16.334 0.414 28 XLC +239PU T 16.499-19.331 22.8 10 XLB +239PU T 20.708-21.984 5.19 24 XLG +239PU T +239PU T 75.26-85.36 |] KLL AUGER +239PU T 92.61-103.73 |] 1.36 19 ^KLX AUGER +239PU T 109.93-121.78 |] KXY AUGER +239PU T 6.19-22.99 47.9 26 L AUGER +239NP P 0.0 5/2+ 2.356 D 3 722.5 10 +239PU N 1.0 1.0 1 1.0 +239PU L 0 1/2+ 24100 Y 11 +239PU B 722.5 5 +239PUS B EAV= +239PU L 7.861 2 3/2+ 36 PS 3 +239PU B 714.6 5 6.5 10 8.4 2 +239PUS B EAV=218.3 2 +239PU G 7.861 2 0.0122 12M1+E2 0.055 3 5.72E3 40 +239PU2 G KC=$LC=$MC=4.2E3 3 +239PU L 57.276 2 5/2+ 101 PS 5 +239PU B 665.2 5 0.4 72 +239PUS B EAV= +239PU G 49.415 3 0.145 35M1+E2 0.50 3 126 8 +239PU2 G KC=$LC=92 6$MC=24.8 17 +239PU G 57.273 4 0.12 3 E2 222 4 +239PU2 G KC=$LC=161.1 23$MC=45.0 7 +239PU L 75.706 3 7/2+ 83 PS 8 +239PU B 646.8 5 2 +239PUS B EAV= +239PU G 18.430 4 2000E-5 0 [M1+E2] +239PU G 67.841 7 0.10 3 E2 98.5 14 +239PU2 G KC=$LC=71.5 10$MC=20.0 3 +239PU L 163.76 2 9/2+ 73 PS 4 +239PU B 558.7 5 +239PUS B EAV= +239PU G 88.06 3 0.006 2 M1+E2 0.5 2 12 6 +239PU2 G KC=$LC=9 4$MC=2.4 13 +239PU G 106.50 3 0.049 8 E2 11.8 3 +239PU2 G KC=$LC=8.55 17$MC=2.39 5 +239PU L 285.460 2 5/2+ 1.12 NS 5 +239PU B 437.0 5 43.0 22 6.9 +239PUS B EAV=125.6 2 +239PU G 209.753 2 3.42 3 M1+E2 0.37 8 2.93 13 +239PU2 G KC=2.27 12$LC=0.499 9$MC=0.1231 18 +239PU G 228.183 1 11.32 22M1+E2 0.28 7 2.41 9 +239PU2 G KC=1.88 8$LC=0.395 7$MC=0.0967 15 +239PU G 277.599 1 14.4 1 M1+E2 0.23 10 1.42 7 +239PU2 G KC=1.12 6$LC=0.228 6$MC=0.0555 13 +239PU G 285.460 2 0.78 1 E2 0.248 5 +239PU2 G KC=0.0843 17$LC=0.119 3$MC=0.0327 7 +239PU L 330.125 4 7/2+ +239PU B 392.4 5 9.4 14 7.4 2 +239PUS B EAV=111.5 2 +239PU G 44.663 5 0.13 1 M1+E2 0.20 3 86 8 +239PU2 G KC=$LC=64 6$MC=16.2 17 +239PU G 166.39 6 0.016 7 M1(+E2) 0.5 4 6.23 13 +239PU2 G KC=4.92 10$LC=0.987 20$MC=0.240 5 +239PU G 254.40 3 0.110 3 M1+E2 1.85 4 +239PU2 G KC=1.46 3$LC=0.295 6$MC=0.0718 15 +239PU G 272.84 3 0.077 3 M1+E2 0.16 5 1.52 3 +239PU2 G KC=1.20 3$LC=0.242 4$MC=0.0588 9 +239PU G 322.3 2 5200E-6 0 (E2) 0.170 4 +239PU2 G KC=0.0680 14$LC=0.076 4$MC=0.0203 4 +239PU L 387.41 2 9/2+ +239PU B 335.1 5 +239PUS B EAV= +239PU G 57.3 1200E-5 0 M1(+E2) +239PU G 101.96 2 0.008 2 E2 14.42 21 +239PU2 G KC=$LC=10.46 15$MC=2.93 5 +239PU G 311.70 2 0.002 2 (M1+E2) +239PU L 391.586 3 7/2- 193 NS 4 +239PU B 330.9 5 38.8 9 6.3 1U +239PUS B EAV=98.3 2 +239PU G 61.460 2 1.29 2 E1 0.473 7 +239PU2 G KC=$LC=0.354 5$MC=0.0881 13 +239PU G 106.125 2 25.9 3 E1(+M2) -0.007 7 0.26 3 +239PU2 G KC=$LC=0.19 3$MC=0.050 8 +239PU G 227.83 0.5 1 M1+E2 0.0762 15 +239PU2 G KC=0.0597 12$LC=0.0125 3$MC=0.00303 6 +239PU G 315.880 3 1.59 1 E1(+M2) 0.0372 8 +239PU2 G KC=0.0295 6$LC=0.0059 2$MC=0.00141 4 +239PU G 334.310 3 2.04 2 E1(+M2) 0.0329 7 +239PU2 G KC=0.0261 5$LC=0.00515 7$MC=0.0012 3 +239PU L 469.8 4 (1/2)- +239PU B 252.7 5 0.0027 9.9 3U +239PUS B EAV=74.7 2 +239PU G 461.9 5 1600E-6 0 (E1) +239PU G 469.8 5 1100E-6 0 (E1) +239PU L 492.2 3 3/2- +239PU B 230.3 5 0.02 9.3 1U +239PUS B EAV=62.5 2 +239PU G 434.7 5 1300E-5 0 E1(+M2) +239PU G 484.3 5 1000E-6 0 (E1) +239PU G 492.3 5 6000E-6 0 (E1) +239PU L 505.2 (5/2)- +239PU B 217.3 5 0.0074 9.7 +239PUS B EAV=58.7 2 +239PU G 429.5 5 3900E-6 0 +239PU G 447.6 5 2600E-7 0 +239PU G 497.8 5 3200E-6 0 +239PU L 511.81 6 7/2+ +239PU B 210.7 5 1.56 16 7.3 2 +239PUS B EAV=56.8 2 +239PU G 124.4 1000E-5 0 E2 13.6 3 +239PU2 G KC=10.4 2$LC=2.39 5$MC=0.591 12 +239PU G 181.70 3 0.086 2 M1 4.78 10 +239PU2 G KC=3.76 8$LC=0.768 15$MC=0.187 4 +239PU G 226.38 2 0.255 14M1+E2 2.58 8 +239PU2 G KC=2.04 7$LC=0.411 12$MC=0.100 3 +239PU G 454.2 5 8200E-7 0 (M1) +239PU G 504.2 5 7800E-7 0 (E2) +239PU L 556.2 (7/2)- +239PU B 166.3 5 0.0026 9.7 1U +239PUS B EAV=44.2 2 +239PU G 392.4 5 1600E-6 0 (E1) +239PU G 498.7 1000E-6 0 (E1) + diff --git a/HEN_HOUSE/spectra/lnhb/O-15.txt b/HEN_HOUSE/spectra/lnhb/O-15.txt new file mode 100644 index 000000000..1705eafae --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/O-15.txt @@ -0,0 +1,7 @@ + 15N 15O EC DECAY (2.041 M) + 15O P 0.0 1/2- 2.041 M 6 2757.0 13 + 15N N 1.0 1.0 1 1.0 + 15N L 0 1/2- STABLE + 15N E 99.885 6 0.115 6 + 15N 2 E EAV=736.7 6$CK=0.926 6$CL=0.074 6$CM= $CN= $CO=0 0 + diff --git a/HEN_HOUSE/spectra/lnhb/P-32.txt b/HEN_HOUSE/spectra/lnhb/P-32.txt new file mode 100644 index 000000000..3beb96bd9 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/P-32.txt @@ -0,0 +1,7 @@ + 32S 32P B- DECAY (14.284 D) + 32P P 0.0 1+ 14.284 D 36 1710.66 21 + 32S N 1.0 1.0 1 1.0 + 32S L 0 0+ STABLE + 32S B 1710.66 21100 7.9 + 32S S B EAV=695.5 3 + diff --git a/HEN_HOUSE/spectra/lnhb/P-33.txt b/HEN_HOUSE/spectra/lnhb/P-33.txt new file mode 100644 index 000000000..c129fd028 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/P-33.txt @@ -0,0 +1,7 @@ + 33S 33P B- DECAY (25.383 D) + 33P P 0.0 1/2+ 25.383 D 40 248.5 11 + 33S N 1.0 1.0 1 1.0 + 33S L 0 3/2+ STABLE + 33S B 248.5 11100 5 2 + 33S S B EAV=76.4 5 + diff --git a/HEN_HOUSE/spectra/lnhb/Pa-231.txt b/HEN_HOUSE/spectra/lnhb/Pa-231.txt new file mode 100644 index 000000000..842b89879 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Pa-231.txt @@ -0,0 +1,215 @@ +227AC 231PA A DECAY (32670 Y) +227AC H TYP=Full$AUT=A. Arinc$CUT=30-JUN-2009$ +227AC C Evaluation history: Type=Full;Author=A. Arinc;Cutoff date=30-JUN-2009 +227AC C References: 1949Va02, 1953Fa08, 1956Hu96, 1960As02, 1960Fo05, 1961Br32, +227AC2C 1961kI05, 1961Ba42, 1963Su10, 1963aB04, 1966Ba14, 1968Br04, 1968Ba25, +227AC3C 1968Ha22, 1969Ba20, 1969La04, 1969Ro33, 1970De19, 1970Le11, 1971Le10, +227AC4C 1972Ga39, 1974De11, 1976BaZZ, 1979Te02, 1979Bo30, 1982An02, 1985Is03, +227AC5C 1986LOZT, 1990Ho28, 1991Ry01, 1998Ak04, 2001Br31, 2003Au03, 2008kI07 +227AC T Auger electrons and ^X ray energies and emission intensities: +227AC T {U Energy (keV)} {U Intensity } {U Line } +227AC T +227AC T 87.768 0.715 23 XKA2 +227AC T 90.885 1.16 4 XKA1 +227AC T +227AC T 102.101 |] XKB3 +227AC T 102.841 |] 0.410 15 XKB1 +227AC T 103.462 |] XKB5II +227AC T +227AC T 105.679 |] XKB2 +227AC T 106.098 |] 0.136 6 XKB4 +227AC T 106.563 |] XKO23 +227AC T +227AC T 10.8701-18.9228 44.3 13 XL (total) +227AC T 10.8701 1.10 4 XLL +227AC T 12.5002-12.6505 18.7 7 XLA +227AC T 14.0807 0.303 19 XLC +227AC T 14.6024-15.9311 19.7 7 XLB +227AC T 17.813-18.9228 4.45 16 XLG +227AC T +227AC T 66.769-74.715 |] KLL AUGER +227AC T 81.775-90.882 |] 0.078 11 ^KLX AUGER +227AC T 96.76-106.75 |] KXY AUGER +227AC T 5.87-19.69 52.6 15 L AUGER +231PA P 0.0 3/2- 32670 Y 260 5149.9 8 +227AC N 1.0 1.0 1 1.0 +227AC G 70.49 5 0.0051 8 +227AC G 242.18 8 0.0099 10 +227AC G 286.58 100.0104 5 +227AC G 310.0 1 0.00092 20 +227AC G 374.95 100.0045 3 +227AC G 438.72 100.0013 4 +227AC L 0 3/2- 21.772 Y 3 +227AC A 5060.7 8 11.7 5 250 +227AC L 27.37 1 3/2+ 38.3 NS 30 +227AC A 5033.8 8 2.8 3 707 +227AC G 27.37 1 10.8 4 E1 4.5 6 +227AC2 G KC=$LC=3.3 4$MC=0.87 13 +227AC L 29.98 1 5/2- +227AC A 5031.2 8 20 2 95 +227AC G 29.98 1 0.097 4 M1+E2 0.22 2 270 30 +227AC2 G KC=$LC=202 21$MC=52 6 +227AC L 46.35 1 5/2+ +227AC A 5015.1 8 25.3 5 59.5 +227AC G 16.370 140.221 9 E1 8.58 12 +227AC2 G KC=$LC=5.06 7$MC=2.68 4 +227AC G 18.980 140.37 3 M1 113.2 16 +227AC2 G KC=$LC=2.35 4$MC=82.7 12 +227AC G 46.35 1 0.19 1 E1 0.879 13 +227AC2 G KC=$LC=0.663 10$MC=0.1634 23 +227AC L 74.14 1 (7/2)- +227AC A 4987.8 8 1.6 2 629 +227AC G 44.160 140.055 4 M1 37.4 6 +227AC2 G KC=$LC=28.3 4$MC=6.79 10 +227AC G 74.14 1 0.0223 9 E2 42.6 6 +227AC2 G KC=$LC=31.2 5$MC=8.53 12 +227AC L 84.55 1 (7/2)+ +227AC A 4977.6 8 0.4 1 2160 +227AC G 38.200 140.144 6 M1+E2 0.18 5 89 19 +227AC2 G KC=$LC=66 14$MC=17 4 +227AC G 54.570 140.070 4 E1 0.569 8 +227AC2 G KC=$LC=0.430 6$MC=0.1053 15 +227AC G 57.180 140.031 3 E2 148.1 21 +227AC2 G KC=$LC=108.6 16$MC=29.6 5 +227AC L 109.94 2 (9/2)+ +227AC A 4952.6 8 22.5 5 26.5 +227AC G 25.390 220.095 7 M1 191 3 +227AC2 G KC=$LC=144.6 21$MC=34.9 5 +227AC G 35.800 220.0163 10E1 1.746 25 +227AC2 G KC=$LC=1.313 19$MC=0.327 5 +227AC G 63.590 220.0446 17E2 88.8 13 +227AC2 G KC=$LC=65.1 10$MC=17.8 3 +227AC L 126.86 2 (9/2)- +227AC A 4936.0 8 2.9 3 160 +227AC G 52.720 220.076 4 M1 22.2 4 +227AC2 G KC=$LC=16.81 24$MC=4.03 6 +227AC G 96.880 220.084 3 E2 12.02 17 +227AC2 G KC=$LC=8.81 13$MC=2.41 4 +227AC L 160 2 + +227AC A 4903.4 220.002 1 141000 +227AC L 187.32 3 (11/2)+ +227AC G 60.46 4 0.0053 7 E1 0.433 7 +227AC2 G KC=$LC=0.327 5$MC=0.0800 12 +227AC G 77.38 4 0.061 4 M1 7.23 11 +227AC2 G KC=$LC=5.47 8$MC=1.313 19 +227AC G 102.77 3 0.019 4 E2 9.12 13 +227AC2 G KC=$LC=6.69 10$MC=1.83 3 +227AC L 198.71 4 (11/2)- +227AC G 71.85 5 0.0019 7 M1 8.98 13 +227AC2 G KC=$LC=6.79 10$MC=1.630 23 +227AC G 124.57 4 0.0043 4 E2 4.04 6 +227AC2 G KC=0.285 4$LC=2.75 4$MC=0.752 11 +227AC L 210.78 5 (13/2)+ +227AC A 4853.5 8 1.40 1594 +227AC G 23.46 6 0.0048 6 M1 241 4 +227AC2 G KC=$LC=182 3$MC=44.1 7 +227AC G 100.84 5 0.0226 9 E2 9.97 15 +227AC2 G KC=$LC=7.30 11$MC=2.00 3 +227AC L 271.29 6 (13/2)- +227AC A 4794.1 8 0.040 151300 +227AC G 72.58 7 0.0030 7 M1 8.71 13 +227AC2 G KC=$LC=6.59 10$MC=1.582 23 +227AC G 144.43 6 0.0115 9 E2 2.18 3 +227AC2 G KC=0.263 4$LC=1.407 20$MC=0.384 6 +227AC L 273.14 3 (5/2)- +227AC G 199.00 3 0.0030 12 +227AC G 243.16 3 0.036 5 M1+E2 1.1 3 0.80 17 +227AC2 G KC=0.56 16$LC=0.176 10$MC=0.0445 16 +227AC G 245.77 3 0.012 4 E1 0.0570 8 +227AC2 G KC=0.0455 7$LC=0.00867 13$MC=0.00208 3 +227AC G 273.14 3 0.0579 12M1+E2 0.7 2 0.74 11 +227AC2 G KC=0.57 10$LC=0.131 8$MC=0.0323 15 +227AC L 304.73 5 (5/2)+ +227AC A 4761.2 8 0.0032 9 9600 +227AC G 230.59 5 0.0017 8 +227AC G 258.38 5 0.0015 4 +227AC L 330.04 1 3/2- +227AC A 4736.3 8 8.4 4 2.46 +227AC G 56.90 3 0.0047 7 M1+E2 0.41 7 37 6 +227AC2 G KC=$LC=28 5$MC=7.1 12 +227AC G 245.490 140.0067 5 M2 5.24 8 +227AC2 G KC=3.70 6$LC=1.143 16$MC=0.293 5 +227AC G 255.900 140.1059 22E2 0.264 4 +227AC2 G KC=0.0992 14$LC=0.1216 17$MC=0.0327 5 +227AC G 283.690 141.65 3 E1 0.0410 6 +227AC2 G KC=0.0329 5$LC=0.00614 9$MC=1468E-6 21 +227AC G 300.060 142.41 5 M1+E2 -0.12 7 0.764 17 +227AC2 G KC=0.613 15$LC=0.1146 20$MC=0.0275 5 +227AC G 302.670 142.3 3 E1 0.0355 5 +227AC2 G KC=0.0285 4$LC=0.00527 8$MC=1260E-6 18 +227AC G 330.04 1 1.36 3 M1+E2 0.36 6 0.541 19 +227AC2 G KC=0.430 16$LC=0.0836 20$MC=0.0202 5 +227AC L 354.50 4 1/2- +227AC A 4712.3 8 1.20 2211.7 +227AC G 24.46 4 0.0049 10M1 214 4 +227AC2 G KC=$LC=161.3 24$MC=39.0 6 +227AC G 327.13 4 0.0361 11E1 0.0298 5 +227AC2 G KC=0.0240 4$LC=0.00440 7$MC=1050E-6 15 +227AC G 354.50 4 0.0962 20M1+E2 3 0.1375 20 +227AC2 G KC=0.0855 12$LC=0.0386 6$MC=0.01003 14 +227AC L 387.23 2 7/2- +227AC A 4680.1 8 1.8 3 4.6 +227AC G 57.190 220.0046 21E2 148.0 21 +227AC2 G KC=$LC=108.5 16$MC=29.6 5 +227AC G 260.37 3 0.182 4 M1+E2 1.4 3 0.55 11 +227AC2 G KC=0.37 10$LC=0.133 7$MC=0.0340 13 +227AC G 277.29 3 0.0680 15E1+M2 0.4 4 0.5 9 +227AC2 G KC=0.4 7$LC=0.11 19$MC=0.03 5 +227AC G 302.680 220.21 10E1 0.0355 5 +227AC2 G KC=0.0285 4$LC=0.00527 8$MC=1260E-6 18 +227AC G 313.090 220.0987 20M1+E2 1.5 0.31 9 +227AC2 G KC=0.22 8$LC=0.070 8$MC=0.0177 16 +227AC G 340.880 220.177 4 E1+M2 0.22 4 0.11 3 +227AC2 G KC=0.081 22$LC=0.020 6$MC=0.0050 15 +227AC G 357.250 220.168 4 M1+E2 0.4 4 0.43 10 +227AC2 G KC=0.34 9$LC=0.066 10$MC=0.0159 21 +227AC G 359.860 220.0085 3 +227AC G 387.23 2 0.0003 1 E2 0.0773 11 +227AC2 G KC=0.0430 6$LC=0.0254 4$MC=0.00667 10 +227AC L 425.59 3 5/2+ +227AC A 4642.5 8 0.080 6 56 +227AC G 351.45 3 0.0028 12E1 0.0255 4 +227AC2 G KC=0.0206 3$LC=0.00373 6$MC=8.91E-4 13 +227AC G 379.24 3 0.0498 11M1+E2 0.6 6 0.32 11 +227AC2 G KC=0.25 10$LC=0.052 11$MC=0.0125 24 +227AC G 395.61 3 0.00226 22E1 0.0198 3 +227AC2 G KC=0.01601 23$LC=0.00286 4$MC=6.82E-4 10 +227AC G 398.22 3 0.0095 3 +227AC L 435.19 2 (1/2)+ +227AC A 4633.0 8 0.0504 1175.8 +227AC G 407.820 220.0356 8 M1 0.334 5 +227AC2 G KC=0.269 4$LC=0.0496 7$MC=0.01187 17 +227AC G 435.19 2 0.00294 17 +227AC L 437.96 4 (5/2)- +227AC A 4630.3 8 0.078 2147 +227AC G 50.73 5 0.0022 8 M1 24.9 4 +227AC2 G KC=$LC=18.8 3$MC=4.52 7 +227AC G 363.82 4 0.0080 3 +227AC G 391.61 4 0.00673 22E1 0.0202 3 +227AC2 G KC=0.01636 23$LC=0.00293 5$MC=6.97E-4 10 +227AC G 410.59 4 0.00180 22E1 0.0183 3 +227AC2 G KC=0.01482 21$LC=0.00264 4$MC=6.28E-4 9 +227AC G 437.96 4 0.0045 3 +227AC L 469.24 6 (9/2)+ +227AC A 4599.6 8 0.015 7 146 +227AC G 384.69 6 0.00365 22 +227AC L 501.28 7 (3/2,5/2)- +227AC A 4568.1 9 0.008 4 160 +227AC G 427.14 7 0.0007 4 +227AC G 501.28 7 0.00076 18 +227AC L 537.0 1 (3/2)+ +227AC A 4533.0 8 0.00076 20930 +227AC G 490.65 100.0004 1 +227AC G 509.63 100.00036 17 +227AC L 562.8 1 (3/2,5/2)+ +227AC A 4507.6 8 0.0036 3 126 +227AC G 488.66 100.00165 17 +227AC G 516.45 100.00137 15 +227AC G 535.43 100.00061 12 +227AC L 656.4 3 (7/2)+ +227AC A 4415.6 9 0.0021 5 43 +227AC G 546.5 3 0.00083 13 +227AC G 571.9 3 0.00048 20 +227AC G 582.3 3 0.00031 17 +227AC G 610.1 3 0.0005 4 + diff --git a/HEN_HOUSE/spectra/lnhb/Pa-233.txt b/HEN_HOUSE/spectra/lnhb/Pa-233.txt new file mode 100644 index 000000000..e9bccd0a4 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Pa-233.txt @@ -0,0 +1,161 @@ +233U 233PA B- DECAY (26.98 D) +233U H TYP=Corrected$AUT=Chechev$CUT= -- $ +233U 2 H TYP=Corrected$AUT=Chechev$CUT= -- $ +233U 3 H TYP=Corrected$AUT=Chechev$CUT= -- $ +233U 4 H TYP=Corrected$AUT=Chechev$CUT= -- $ +233U 5 H TYP=Corrected$AUT=Chechev$CUT= -- $ +233U 6 H TYP=Corrected$AUT=Chechev$CUT= -- $ +233U 7 H TYP=Corrected$AUT=Chechev$CUT= -- $ +233U 8 H TYP=Corrected$AUT=Chechev$CUT= -- $ +233U 9 H TYP=Corrected$AUT=mmbe$CUT= -- $ +233U A H TYP=Corrected$AUT=mmbe$CUT= -- $ +233U B H TYP=Corrected$AUT=mmbe$CUT= -- $ +233U C H TYP=Corrected$AUT=mmbe$CUT= -- $ +233U D H TYP=Corrected$AUT=mmbe$CUT= -- $ +233U E H TYP=Corrected$AUT=mmbe$CUT= -- $ +233U F H TYP=Corrected$AUT=mmbe$CUT= -- $ +233U G H TYP=Corrected$AUT=mmbe$CUT= -- $ +233U H H TYP=Full$AUT=Chechev$CUT=01-JAN-2005$ +233U I H TYP=Full$AUT=Chechev$CUT=01-JAN-2005$ +233U J H TYP=Full$AUT=Chechev$CUT=01-JAN-2005$ +233U K H TYP=Full$AUT=Chechev$CUT=01-JAN-2005$ +233U L H TYP=Full$AUT=Chechev$CUT=01-JAN-2005$ +233U M H TYP=Full$AUT=Chechev$CUT=01-JAN-2005$ +233U N H TYP=Full$AUT=Chechev$CUT=01-JAN-2005$ +233U C Evaluation history: Type=Corrected;Author=Chechev;Cutoff date= -- +233U 2C Type=Corrected;Author=Chechev;Cutoff date= -- +233U 3C Type=Corrected;Author=Chechev;Cutoff date= -- +233U 4C Type=Corrected;Author=Chechev;Cutoff date= -- +233U 5C Type=Corrected;Author=Chechev;Cutoff date= -- +233U 6C Type=Corrected;Author=Chechev;Cutoff date= -- +233U 7C Type=Corrected;Author=Chechev;Cutoff date= -- +233U 8C Type=Corrected;Author=Chechev;Cutoff date= -- +233U 9C Type=Corrected;Author=mmbe;Cutoff date= -- +233U AC Type=Corrected;Author=mmbe;Cutoff date= -- +233U BC Type=Corrected;Author=mmbe;Cutoff date= -- +233U CC Type=Corrected;Author=mmbe;Cutoff date= -- +233U DC Type=Corrected;Author=mmbe;Cutoff date= -- +233U EC Type=Corrected;Author=mmbe;Cutoff date= -- +233U FC Type=Corrected;Author=mmbe;Cutoff date= -- +233U GC Type=Corrected;Author=mmbe;Cutoff date= -- +233U HC Type=Full;Author=Chechev;Cutoff date=01-JAN-2005 +233U IC Type=Full;Author=Chechev;Cutoff date=01-JAN-2005 +233U JC Type=Full;Author=Chechev;Cutoff date=01-JAN-2005 +233U KC Type=Full;Author=Chechev;Cutoff date=01-JAN-2005 +233U LC Type=Full;Author=Chechev;Cutoff date=01-JAN-2005 +233U MC Type=Full;Author=Chechev;Cutoff date=01-JAN-2005 +233U NC Type=Full;Author=Chechev;Cutoff date=01-JAN-2005 +233U C References: 1941Gr03, 1952Br84, 1954Br37, 1955On05, 1956Mc60, 1957Wr37, +233U 2C 1960Un01, 1961Al19, 1962Sc03, 1963Bj03, 1963Bi03, 1966Ze02, 1967Br20, +233U 3C 1968Ma13, 1971Vo02, 1972De67, 1973Va33, 1979Ge08, 1984Va27, 1985DeZR, +233U 4C 1986Kr10, 1986Jo07, 1988Wo01, 1989Br24, 1990Ak02, 1990Ko41, 1990Pe16, +233U 5C 1992Ra08, 2000Us01, 2000Wo01, 2000Ch01, 2000Sc04, 2000Lu01, 2002Lu01, +233U 6C 2003Au03, 2004Sh07, 2005Hu06, 2005Si15, 2006Ch39, 2006Ha53, 2008Ki07, +233U 7C 2008De10 +233U T Auger electrons and ^X ray energies and emission intensities: +233U T {U Energy (keV)} {U Intensity } {U Line } +233U T +233U T 94.666 9.10 26 XKA2 +233U T 98.44 14.6 4 XKA1 +233U T +233U T 110.421 |] XKB3 +233U T 111.298 |] 5.25 18 XKB1 +233U T 111.964 |] XKB5II +233U T +233U T 114.407 |] XKB2 +233U T 115.012 |] 1.80 7 XKB4 +233U T 115.377 |] XKO23 +233U T +233U T 11.619-20.714 40.6 11 XL (total) +233U T 11.619 1.05 4 XLL +233U T 13.438-13.615 16.9 6 XLA +233U T 15.399 0.272 16 XLC +233U T 15.727-18.206 18.1 6 XLB +233U T 19.507-20.714 4.23 14 XLG +233U T +233U T 71.78-80.95 |] KLL AUGER +233U T 88.15-98.34 |] 0.95 13 ^KLX AUGER +233U T 104.42-115.4 |] KXY AUGER +233U T 5.9-21.6 42.2 13 L AUGER +233PA P 0.0 3/2- 26.98 D 2 570.1 20 +233U N 1.0 1.0 1 1.0 +233U L 0 5/2+ 159.1E3 Y 2 +233U B 570.1 206.3 23 9.1 1U +233U S B EAV=169.6 6 +233U L 40.350 4 7/2+ 0.11 NS 8 +233U B 529.8 200.3 19 10.2 3U +233U S B EAV=156.1 6 +233U G 40.349 5 0.024 2 M1+E2 1.08 12 580 60 +233U 2 G KC=$LC=430 50$MC=117 12 +233U L 92.16 4 9/2+ +233U G 51.81 4 5000E-7 0 [M1+E2] 0.62 108.0000 +233U 2 G KC=$LC=79.0000 0$MC=21.0000 0 +233U G 92.16 4 2400E-6 0 [E2] 19.50000 +233U 2 G KC=$LC=14.2000 0$MC=3.95000 0 +233U L 298.810 4 5/2- +233U B 271.3 200.12 5 9.8 2 +233U S B EAV=74.6 6 +233U G 258.45 2 0.0274 6 [E1] 0.0547 11 +233U 2 G KC=0.0433 9$LC=0.00857 17$MC=0.00207 4 +233U G 298.81 2 0.12 5 [E1] 0.0396 8 +233U 2 G KC=0.0315 6$LC=0.00609 12$MC=0.00147 3 +233U L 301.94 9 5/2- +233U B 268.1 200.010 2 11.8 2 +233U S B EAV=73.7 6 +233U G 301.99 100.010 2 +233U L 311.904 4 3/2+ 0.120 NS 15 +233U B 258.2 2026.6 32 7.3 +233U S B EAV=70.8 6 +233U G 271.555 100.323 3 E2 0.258 5 +233U 2 G KC=0.0904 18$LC=0.1226 25$MC=0.0334 7 +233U G 311.904 5 38.3 5 M1+E2 0.10 1 0.80 2 +233U 2 G KC=0.64 2$LC=0.126 4$MC=0.031 1 +233U L 320.83 4 7/2- +233U B 249.4 200.020 5 10.4 +233U S B EAV=68.2 6 +233U G 228.57 5 0.0042 7 +233U G 280.61 5 0.011 2 +233U G 320.73 100.0051 4 +233U L 340.477 4 5/2+ 52 PS 10 +233U B 229.6 2025.9 32 7.2 1U +233U S B EAV=62.4 6 +233U G 28.559 100.071 8 M1+E2 0.158 10 313 18 +233U 2 G KC=$LC=233 13$MC=60 4 +233U G 41.663 100.014 3 [E1] 1.253 25 +233U 2 G KC=$LC=0.939 19$MC=0.235 5 +233U G 248.38 4 0.0609 11[E2] 0.346 7 +233U 2 G KC=0.1065 21$LC=0.175 4$MC=0.0479 10 +233U G 300.129 5 6.60 21M1+E2 0.08 3 0.87 2 +233U 2 G KC=0.70 2$LC=0.133 4$MC=0.031 1 +233U G 340.476 5 4.47 3 M1+E2 0.23 5 0.62 2 +233U 2 G KC=0.50 2$LC=0.103 3$MC=0.022 1 +233U L 380.43 8 7/2+ +233U B 189.8 200.020 3 9.4 3U +233U S B EAV=50.9 6 +233U G 288.42 100.016 3 +233U G 380.28 100.0037 9 +233U L 398.496 4 1/2+ 55 PS 20 +233U B 171.5 2015.4 8 7 1U +233U S B EAV=45.7 5 +233U G 86.595 5 1.99 10M1+E2 0.056 5 7.08 14 +233U 2 G KC=$LC=5.33 11$MC=1.29 3 +233U G 398.492 5 1.408 14E2 0.0835 17 +233U 2 G KC=0.0439 9$LC=0.0291 6$MC=0.00777 16 +233U L 415.758 4 3/2+ 30 PS +233U B 154.3 2025.4 16 6.7 +233U S B EAV=40.9 5 +233U G 17.262 6 4100E-6 0 M1+E2 503.0000 +233U 2 G KC=$LC=$MC=374.000 0 +233U G 75.269 101.30 3 M1+E2 0.15 8 11.4 12 +233U 2 G KC=$LC=8.6 9$MC=2.11 24 +233U G 103.86 1 0.853 6 M1+(E2) 0.1 1 4.21 21 +233U 2 G KC=$LC=3.17 15$MC=0.77 5 +233U G 375.404 5 0.684 7 E2 0.0981 20 +233U 2 G KC=0.0491 10$LC=0.0360 7$MC=0.00962 19 +233U G 415.764 5 1.747 7 M1+E2 2.2 9 0.13 8 +233U 2 G KC=0.09 6$LC=0.032 9$MC=0.0081 21 +233U L 456.114 6 5/2+ +233U B 114.1 200.0011 2 10.6 1U +233U S B EAV=29.8 5 +233U G 455.96 100.0011 2 + diff --git a/HEN_HOUSE/spectra/lnhb/Pa-234.txt b/HEN_HOUSE/spectra/lnhb/Pa-234.txt new file mode 100644 index 000000000..f004e2915 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Pa-234.txt @@ -0,0 +1,819 @@ +234U 234PA B- DECAY (6.70 H) +234U H TYP=Full$AUT=Huang$CUT=31-DEC-2009$ +234U C Evaluation history: Type=Full;Author=Huang;Cutoff date=31-DEC-2009 +234U T Auger electrons and ^X ray energies and emission intensities: +234U T {U Energy (keV)} {U Intensity } {U Line } +234U T +234U T 94.666 10.5 6 XKA2 +234U T 98.44 16.8 9 XKA1 +234U T +234U T 110.421 |] XKB3 +234U T 111.298 |] 6.1 4 XKB1 +234U T 111.964 |] XKB5II +234U T +234U T 114.407 |] XKB2 +234U T 115.012 |] 2.0 1 XKB4 +234U T 115.377 |] XKO23 +234U T +234U T 11.6185-20.7141 77 10 XL (total) +234U T 11.6185 XLL +234U T 13.4382-13.6146 XLA +234U T 15.399 XLC +234U T 15.7268-18.2061 XLB +234U T 19.5072-20.7141 XLG +234U T +234U T 71.776-80.954 |] KLL AUGER +234U T 88.153-98.429 |] 1.08 6 ^KLX AUGER +234U T 104.51-115.59 |] KXY AUGER +234U T 5.9-21.6 77 10 L AUGER +234PA P 0.0 4+ 6.70 H 5 2195 4 +234U N 1.0 1.0 1 1.0 +234U G 401.8 2 0.036 11 +234U G 425.3 2 0.036 11 +234U G 643.2 2 0.027 9 +234U G 659.8 1 0.27 4 +234U G 711.5 1 0.156 25 +234U G 778.6 2 0.046 10 +234U G 824.2 2 1.25 15 +234U G 846.1 2 0.052 12 +234U G 920.5 2 0.029 8 +234U G 992.0 2 0.083 22 +234U G 1023.6 2 0.062 22 +234U G 1025.3 2 0.052 22 +234U G 1035.9 2 0.026 10 +234U G 1220.4 2 0.062 12 +234U G 1296.4 2 0.029 7 +234U G 1301.2 2 0.018 5 +234U G 1327.0 2 0.018 5 +234U G 1507.3 2 0.020 5 +234U G 1520.7 2 0.0094 9 +234U G 1538.8 2 0.014 4 +234U G 1655.7 1 0.026 4 +234U G 1664.8 3 0.018 7 +234U G 1743.2 2 0.033 8 +234U G 1757.5 1 0.024 6 +234U G 1830.8 3 0.0042 11 +234U G 1849.8 2 0.028 7 +234U G 1927.9 4 0.054 12 +234U G 1935.2 4 9400E-6 0 +234U L 0 0+ 2.455E5 Y 6 +234U L 43.481 152+ 0.252 NS 7 +234U G 43.49 2 0.12 3 E2 713 11 +234U 2 G KC=$LC=520 8$MC=143.7 21 +234U L 143.375 214+ +234U B 2052 4 5 9.2 +234U S B EAV=732.2 17 +234U G 99.86 2 3.2 6 E2 13.42 19 +234U 2 G KC=$LC=9.77 14$MC=2.71 4 +234U L 296.075 246+ +234U G 152.71 2 6.0 7 E2 2.14 3 +234U 2 G KC=0.217 3$LC=1.404 20$MC=0.388 6 +234U L 497.05 4 8+ +234U G 200.97 3 0.90 13E2 0.734 11 +234U 2 G KC=0.1534 22$LC=0.424 6$MC=0.1166 17 +234U L 786.295 151- +234U G 742.813 5 2.08 21E1 0.006369 +234U 2 G KC=0.00518 8$LC=8.95E-4 13$MC=2.13E-4 3 +234U G 786.272 221.21 13(E1) 0.005738 +234U 2 G KC=0.00467 7$LC=8.04E-4 12$MC=1.91E-4 3 +234U L 809.92 8 0+ 0.1 NS +234U G 766.4 2 0.26 5 (E2) 0.0187 3 +234U 2 G KC=0.01336 19$LC=0.00396 6$MC=1003E-6 14 +234U G 810.0 7 +234U L 849.265 233- +234U B 1346 4 0.8 9.3 1 +234U S B EAV=452.1 16 +234U G 705.9 1 2.29 23[E1] 0.0069810 +234U 2 G KC=0.00568 8$LC=9.87E-4 14$MC=2.35E-4 4 +234U G 805.80 5 2.5 3 [E1] 0.005498 +234U 2 G KC=0.00447 7$LC=7.68E-4 11$MC=1.83E-4 3 +234U L 851.73 5 2+ 1.71 PS +234U G 41.82 11 +234U G 708.3 2 0.023 9 [E2] 0.0219 3 +234U 2 G KC=0.01537 22$LC=0.00489 7$MC=1246E-6 18 +234U G 808.4 3 0.036 11+E2 4.200000 +234U 2 G KC=3.30000 7$LC=0.9 10$MC= +234U G 851.8 1 0.073 22[E2] 0.0151322 +234U 2 G KC=0.01109 16$LC=0.00302 5$MC=7.59E-4 11 +234U L 926.744 212+ 1.38 PS 17 +234U G 783.4 1 0.30 4 [E2] 0.0179 3 +234U 2 G KC=0.01285 18$LC=0.00374 6$MC=9.46E-4 14 +234U G 883.24 4 9.7 11E2 0.0140920 +234U 2 G KC=0.01040 15$LC=0.00276 4$MC=6.92E-4 10 +234U G 926.7 1 7.3 12(E2) 0.0128418 +234U 2 G KC=0.00956 14$LC=0.00245 4$MC=6.13E-4 9 +234U L 947.59 5 4+ +234U B 1247 4 0.8 9.2 +234U S B EAV=414.4 16 +234U G 804.1 1 0.62 22+E2 0.370000 +234U 2 G KC=0.1559 8$LC=0.11056 15$MC=0.10254 4 +234U G 904.2 1 0.34 4 [E2] 0.0134619 +234U 2 G KC=0.00998 14$LC=0.00260 4$MC=6.52E-4 10 +234U L 962.55 3 5- +234U B 1232 4 0.4 9.4 1 +234U S B EAV=408.7 16 +234U G 666.5 1 1.18 13[E1] 0.0077711 +234U 2 G KC=0.00631 9$LC=1103E-6 16$MC=2.63E-4 4 +234U G 819.2 1 1.9 2 [E1] 0.005338 +234U 2 G KC=0.00434 6$LC=7.44E-4 11$MC=1770E-7 25 +234U L 968.45 3 3+ +234U B 1227 4 2.5 8.6 +234U S B EAV=406.4 16 +234U G 825.1 2 1.9 2 [E2] 0.0161123 +234U 2 G KC=0.01173 17$LC=0.00327 5$MC=8.25E-4 12 +234U G 925.0 1 7.9 9 (E2) 0.0128818 +234U 2 G KC=0.00959 14$LC=0.00246 4$MC=6.16E-4 9 +234U L 989.444 202- 0.76 NS 4 +234U B 1206 4 3.1 8.5 1U +234U S B EAV=398.5 16 +234U G 62.70 1 1.6 5 E1 0.426 6 +234U 2 G KC=$LC=0.320 5$MC=0.0791 11 +234U G 140.15 2 0.51 7 M1+E2 1.2 6 5.3 18 +234U 2 G KC=2.9 22$LC=1.76 25$MC=0.47 9 +234U G 203.12 3 1.24 15M1+E2 1.5 4 1.4 4 +234U 2 G KC=0.8 4$LC=0.422 10$MC=0.1113 16 +234U G 946.00 3 13.5 15(E1) 0.004126 +234U 2 G KC=0.00337 5$LC=5.71E-4 8$MC=1355E-7 19 +234U L 1023.795 243- +234U B 1171.2 405 8.3 1 +234U S B EAV=385.4 16 +234U G 34.30 4 0.0037 4 (E2) 2270 40 +234U 2 G KC=$LC=1660 30$MC=457 7 +234U G 54.96 109400E-6 0 [E1] 0.603 9 +234U 2 G KC=$LC=0.453 7$MC=0.1123 17 +234U G 97.17 100.24 9 [E1] 0.1343 20 +234U 2 G KC=$LC=0.1012 15$MC=0.0248 4 +234U G 174.55 3 0.17 3 [M1+E2] 2.9 17 +234U 2 G KC=1.9 18$LC=0.74 4$MC=0.193 23 +234U G 880.52 4 4.3 6 [E1] 0.004687 +234U 2 G KC=0.00382 6$LC=6.51E-4 10$MC=1547E-7 22 +234U G 980.3 1 2.70000 0 [E1] 0.003876 +234U 2 G KC=0.00317 5$LC=5.35E-4 8$MC=1270E-7 18 +234U L 1023.92 3 4+ +234U B 1171 4 1.5 13 8.8 +234U S B EAV=385.4 16 +234U G 54.96 109400E-6 0 [M1+E2] 1.3E2 11 +234U 2 G KC=$LC=90 80$MC=26 21 +234U G 727.8 2 0.114 15[E2] 0.0207 3 +234U 2 G KC=0.01464 21$LC=0.00454 7$MC=1156E-6 17 +234U G 880.52 4 6.2 8 [E2] 0.0141820 +234U 2 G KC=0.01046 15$LC=0.00278 4$MC=6.97E-4 10 +234U G 980.3 1 1.77000 0 [E2] 0.0115217 +234U 2 G KC=0.00866 13$LC=0.00214 3$MC=5.34E-4 8 +234U L 1069.297 224- +234U B 1126 4 8 8 +234U S B EAV=368.3 15 +234U G 45.45 5 0.027 9 M1+E2 0.8 4 2.5E2 14 +234U 2 G KC=$LC=1.9E2 10$MC=50 30 +234U G 79.84 2 0.062 22E2 38.4 6 +234U 2 G KC=$LC=28.0 4$MC=7.76 11 +234U G 100.89 2 0.125 24[E1] 0.1218 17 +234U 2 G KC=$LC=0.0917 13$MC=0.0224 4 +234U G 106.68 5 0.036 11[M1] 3.83 6 +234U 2 G KC=$LC=2.89 4$MC=0.699 10 +234U G 220.00 8 0.146 25(M1) 2.37 4 +234U 2 G KC=1.89 3$LC=0.366 6$MC=0.0886 13 +234U G 926.0 2 1.8 13[E1] 0.004286 +234U 2 G KC=0.00350 5$LC=5.94E-4 9$MC=1409E-7 20 +234U L 1085.07 102+ +234U G 233.6 2 +234U G 235.9 300.005 3 +234U G 298.7 2 0.014 6 [E1] 0.0396 6 +234U 2 G KC=0.0315 5$LC=0.00610 9$MC=1470E-6 21 +234U G 942.0 3 0.046 9 [E2] 0.0124418 +234U 2 G KC=0.00929 13$LC=0.00236 4$MC=5.89E-4 9 +234U G 1041.1 2 0.032 11[E2M1] 0.023 13 +234U 2 G KC=0.018 11$LC=0.0036 18$MC=0.0009 4 +234U G 1085.3 3 0.027 8 [E2] 0.0095014 +234U 2 G KC=0.00725 11$LC=1690E-6 24$MC=4.18E-4 6 +234U L 1090.89 4 5+ +234U B 1104 4 0.69 20 9.04 +234U S B EAV=360.2 15 +234U G 794.9 2 0.68 11[E2] 0.0173525 +234U 2 G KC=0.01253 18$LC=0.00360 5$MC=9.10E-4 13 +234U G 947.7 2 1.63 21[E2] 0.0123018 +234U 2 G KC=0.00919 13$LC=0.00232 4$MC=5.80E-4 9 +234U L 1096.12 9 6+ +234U G 799.7 2 +E2 +234U G 952.7 1 0.083 13 +234U L 1125.29 5 7- +234U G 628.1 1 0.24 5 [E1] 0.0086813 +234U 2 G KC=0.00705 10$LC=1239E-6 18$MC=2.96E-4 5 +234U G 829.3 2 0.36 11[E1] 0.005218 +234U 2 G KC=0.00425 6$LC=7.27E-4 11$MC=1729E-7 25 +234U L 1126.65 3 2+ +234U G 137.23 5 0.027 9 [E1] 0.239 4 +234U 2 G KC=0.184 3$LC=0.0413 6$MC=0.01006 15 +234U G 199.95 5 0.073 22(+E2+M1) 2.0 13 +234U 2 G KC=1.4 13$LC=0.483 21$MC=0.124 4 +234U G 275.04 100.094 23[M1E2] 0.8 6 +234U 2 G KC=0.6 5$LC=0.16 4$MC=0.040 8 +234U G 316.7 1 0.104 14[E2] 0.1597 23 +234U 2 G KC=0.0677 10$LC=0.0674 10$MC=0.0182 3 +234U G 340.2 1 0.041 9 [E1] 0.0298 5 +234U 2 G KC=0.0239 4$LC=0.00453 7$MC=1090E-6 16 +234U G 1083.2 1 0.51 6 (M1) 0.0317 5 +234U 2 G KC=0.0254 4$LC=0.00477 7$MC=1147E-6 16 +234U G 1126.8 1 0.30 4 [E2] 0.0088513 +234U 2 G KC=0.00679 10$LC=1552E-6 22$MC=3.83E-4 6 +234U L 1127.535 255- +234U B 1067 4 1.9 10 8.54 1 +234U S B EAV=346.5 15 +234U G 58.20 6 0.0027 9 (E2) 174 3 +234U 2 G KC=$LC=126.9 19$MC=35.1 6 +234U G 103.77 2 0.24 4 (E2) 11.22 16 +234U 2 G KC=$LC=8.17 12$MC=2.27 4 +234U G 164.94 5 0.052 22[E2M1] 3.5 19 +234U 2 G KC=2.2 21$LC=0.91 9$MC=0.24 4 +234U G 278.3 1 0.042 11[E2] 0.238 4 +234U 2 G KC=0.0863 13$LC=0.1112 16$MC=0.0303 5 +234U G 831.5 1 4.2 5 [E1] 0.005188 +234U 2 G KC=0.00423 6$LC=7.24E-4 11$MC=1721E-7 24 +234U G 984.2 1 1.63 21[E1] 0.003856 +234U 2 G KC=0.00315 5$LC=5.31E-4 8$MC=1261E-7 18 +234U L 1165.41 4 3+ +234U G 196.80 5 0.073 22+E2+M1 2.0 13 +234U 2 G KC=1.4 13$LC=0.483 21$MC=0.124 4 +234U G 313.5 1 0.104 14[E2M1] 0.5 4 +234U 2 G KC=0.4 4$LC=0.10 4$MC=0.026 7 +234U G 1021.8 2 0.15 4 [M1] 0.0370 6 +234U 2 G KC=0.0297 5$LC=0.00557 8$MC=1340E-6 19 +234U G 1121.7 1 0.25 4 M1 0.0289 4 +234U 2 G KC=0.0232 4$LC=0.00434 6$MC=1045E-6 15 +234U L 1172.03 3 6+ +234U G 675.1 1 0.101 14[E2] 0.0242 4 +234U 2 G KC=0.01674 24$LC=0.00558 8$MC=1427E-6 20 +234U G 876.0 1 2.55 23(E2) 0.0143220 +234U 2 G KC=0.01055 15$LC=0.00282 4$MC=7.06E-4 10 +234U G 1028.7 1 0.57 6 [E2] 0.0105115 +234U 2 G KC=0.00796 12$LC=0.00191 3$MC=4.75E-4 7 +234U L 1194.761 236- +234U B 1000 4 1.5 8.5 1U +234U S B EAV=312.6 14 +234U G 67.25 100.036 11M1+E2 1.2 3 57 11 +234U 2 G KC=$LC=42 8$MC=11.5 22 +234U G 69.46 5 0.018 8 [E2M1] 40 30 +234U 2 G KC=$LC=32 23$MC=9 7 +234U G 125.46 1 0.79 12E2 4.89 7 +234U 2 G KC=0.216 3$LC=3.41 5$MC=0.945 14 +234U G 232.21 3 0.18 3 [E2M1] 1.2 8 +234U 2 G KC=0.9 8$LC=0.27 5$MC=0.070 7 +234U G 898.67 5 3.3 4 [E1] 0.004517 +234U 2 G KC=0.00369 6$LC=6.27E-4 9$MC=1489E-7 21 +234U L 1214.70 5 4+ +234U B 980 4 0.30 12 9.22 +234U S B EAV=314.2 15 +234U G 267.12 5 0.18 3 [E2M1] 0.8 6 +234U 2 G KC=0.6 5$LC=0.17 5$MC=0.044 8 +234U G 365.0 3 0.018 7 [E1] 0.0257 4 +234U 2 G KC=0.0206 3$LC=0.00387 6$MC=9.30E-4 14 +234U G 918.4 1 0.100 14[E2] 0.0130619 +234U 2 G KC=0.00971 14$LC=0.00251 4$MC=6.27E-4 9 +234U G 1171.3 1 0.090 13[E2] 0.0082412 +234U 2 G KC=0.00634 9$LC=1423E-6 20$MC=3.50E-4 5 +234U L 1237.24 3 1- +234U G 247.79 7 0.00037 4 +234U G 310.52 101.35E-4 15 +234U G 387.94 6 0.00072 6 +234U G 427.4 4 3.1E-5 10 +234U G 450.93 4 0.0040 19M1+E2 0.7 0.241 4 +234U 2 G KC=0.187 3$LC=0.0400 6$MC=0.00980 14 +234U G 1193.77 2 0.021 6 E1 0.002774 +234U 2 G KC=0.00226 4$LC=3.77E-4 6$MC=8.92E-5 13 +234U G 1237.3 3 9400E-6 0 E1 0.002624 +234U 2 G KC=0.00213 3$LC=3.54E-4 5$MC=8.38E-5 12 +234U L 1261.77 3 7+ +234U G 764.8 2 0.20 5 [M1E2] 0.05 3 +234U 2 G KC=0.04 3$LC=0.008 4$MC=0.002 1 +234U G 965.8 1 0.48 6 [M1E2] 0.027 16 +234U 2 G KC=0.022 13$LC=0.0043 22$MC=0.0011 5 +234U L 1274.32 9 (5+)+ +234U G 978.2 3 0.090 23 +234U L 1277.45 3 7- +234U G 149.88 3 0.073 22[E2] 2.31 4 +234U 2 G KC=0.220 3$LC=1.526 22$MC=0.422 6 +234U G 780.4 2 0.90 9 [E1] 0.005819 +234U 2 G KC=0.00474 7$LC=8.15E-4 12$MC=1.94E-4 3 +234U G 981.6 3 0.73 22[E1] 0.003876 +234U 2 G KC=0.00316 5$LC=5.34E-4 8$MC=1267E-7 18 +234U L 1312.20 9 3- +234U B 883 4 0.109 18 9.5 1 +234U S B EAV=278.7 15 +234U G 75.0 3 +234U G 343.8 2 0.034 8 [E1] 0.0292 5 +234U 2 G KC=0.0233 4$LC=0.00442 7$MC=1064E-6 15 +234U G 365.0 3 +234U G 385.4 1 0.042 11[E1] 0.0229 4 +234U 2 G KC=0.0184 3$LC=0.00343 5$MC=8.24E-4 12 +234U L 1341.33 8 (6+)+ +234U G 379.1 1 0.042 11[E1] 0.0237 4 +234U 2 G KC=0.0190 3$LC=0.00356 5$MC=8.54E-4 12 +234U G 1044.4 2 0.031 3 +234U L 1421.252 246- 33.5 US 20 +234U G 143.78 2 0.32 5 (M1+E2) 1 5.310000 +234U 2 G KC=3.24000 0$LC=1.53200 0$MC=0.40300 0 +234U G 159.48 2 0.66 10[E1] 0.1676 24 +234U 2 G KC=0.1303 19$LC=0.0282 4$MC=0.00684 10 +234U G 226.50 3 4.9 6 M1+E2 1.0 3 1.3 3 +234U 2 G KC=0.9 3$LC=0.297 15$MC=0.0759 23 +234U G 249.22 1 2.5 4 E1 0.0594 9 +234U 2 G KC=0.0470 7$LC=0.00935 13$MC=0.00226 4 +234U G 293.79 5 3.0 4 M1+E2 1.7 4 0.42 10 +234U 2 G KC=0.28 9$LC=0.109 9$MC=0.0283 18 +234U G 295.91 8 0.146 25[M1+E2] 0.6 5 +234U 2 G KC=0.5 4$LC=0.12 4$MC=0.031 8 +234U G 330.40 5 0.78 9 [E1] 0.0318 5 +234U 2 G KC=0.0254 4$LC=0.00484 7$MC=1165E-6 17 +234U G 351.9 1 0.42 5 E2 0.1175 17 +234U 2 G KC=0.0555 8$LC=0.0455 7$MC=0.01222 18 +234U G 397.7 3 0.027 7 [M2] 1.349 20 +234U 2 G KC=0.986 14$LC=0.270 4$MC=0.0687 10 +234U G 458.68 5 1.14 12M1+E2 1.4 4 0.14 5 +234U 2 G KC=0.11 4$LC=0.028 5$MC=0.0071 11 +234U G 1125.2 1 0.36 8 [E1] 0.003055 +234U 2 G KC=0.00250 4$LC=4.18E-4 6$MC=9.91E-5 14 +234U G 1277.7 2 0.045 9 [M2] 0.0473 7 +234U 2 G KC=0.0370 6$LC=0.00771 11$MC=0.00188 3 +234U L 1447.89 105- +234U B 747 4 0.11 3 9.25 1 +234U S B EAV=230.3 14 +234U G 320.4 1 0.052 8 [E2M1] 0.5 4 +234U 2 G KC=0.4 3$LC=0.10 4$MC=0.024 7 +234U G 1151.4 3 0.032 10[E1] 0.002945 +234U 2 G KC=0.00240 4$LC=4.02E-4 6$MC=9.51E-5 14 +234U L 1456.54 7 (2-)+ +234U G 669.7 1 6000E-7 0 +234U G 1414.4 2 2800E-6 0 +234U L 1486.17 12(3-)+ +234U B 709 4 0.12 3 9.14 +234U S B EAV=216.9 14 +234U G 559.2 2 0.073 22[E1] 0.0108416 +234U 2 G KC=0.00877 13$LC=1562E-6 22$MC=3.73E-4 6 +234U G 1342.9 2 0.012 5 [E1] 0.002324 +234U 2 G KC=0.00185 3$LC=3.07E-4 5$MC=7.26E-5 11 +234U G 1442.8 2 0.031 7 [E1] 0.002123 +234U 2 G KC=1643E-6 23$LC=2.71E-4 4$MC=6.41E-5 9 +234U L 1496.14 3 3+ +234U B 699 4 2.7 7.8 +234U S B EAV=213.5 14 +234U G 221.83 100.073 22[E2] 0.513 8 +234U 2 G KC=0.1301 19$LC=0.280 4$MC=0.0767 11 +234U G 330.40 5 M1+E2 0.7 0.562 8 +234U 2 G KC=0.431 6$LC=0.0980 14$MC=0.0242 4 +234U G 369.50 5 2.5 3 M1 0.565 8 +234U 2 G KC=0.450 7$LC=0.0866 13$MC=0.0209 3 +234U G 426.95 5 0.46 5 [E1] 0.0185 3 +234U 2 G KC=0.01491 21$LC=0.00274 4$MC=6.58E-4 10 +234U G 472.3 1 0.36 4 [M1] 0.290 4 +234U 2 G KC=0.231 4$LC=0.0443 7$MC=0.01069 15 +234U G 506.75 5 1.30 14[E1] 0.0131419 +234U 2 G KC=0.01061 15$LC=0.00191 3$MC=4.57E-4 7 +234U G 527.9 1 0.40 5 (M1) 0.215 3 +234U 2 G KC=0.1716 24$LC=0.0328 5$MC=0.00790 11 +234U G 569.5 1 9.3 12M1 0.1754 25 +234U 2 G KC=0.1401 20$LC=0.0267 4$MC=0.00643 9 +234U G 646.5 1 0.114 15[E1] 0.0082212 +234U 2 G KC=0.00668 10$LC=1170E-6 17$MC=2.79E-4 4 +234U G 1352.9 1 1.16 12M1 0.0176625 +234U 2 G KC=0.01412 20$LC=0.00263 4$MC=6.33E-4 9 +234U G 1452.7 1 0.81 9 [M1] 0.0146821 +234U 2 G KC=0.01169 17$LC=0.00218 3$MC=5.24E-4 8 +234U L 1502.38 8 3,4++ +234U B 693 4 0.25 4 8.78 +234U S B EAV=211.3 14 +234U G 1359.0 1 0.156 25 +234U G 1458.9 1 0.094 23 +234U L 1533.37 5 (4-)+ +234U B 662 4 0.21 4 8.79 +234U S B EAV=200.6 14 +234U G 464.2 1 0.031 11[M1] 0.304 5 +234U 2 G KC=0.243 4$LC=0.0464 7$MC=0.01120 16 +234U G 543.8 1 0.135 24[E2] 0.0389 6 +234U 2 G KC=0.0247 4$LC=0.01049 15$MC=0.00273 4 +234U G 1389.6 2 0.073 22[E1] 0.002224 +234U 2 G KC=1749E-6 25$LC=2.89E-4 4$MC=6.84E-5 10 +234U L 1537.25 3 4+ +234U B 658 4 0.9 8.1 +234U S B EAV=199.3 14 +234U G 372.0 1 1.23 14M1(+E2) 0.3 0.517 8 +234U 2 G KC=0.410 6$LC=0.0811 12$MC=0.0197 3 +234U G 409.8 1 0.34 5 [E1] 0.0202 3 +234U 2 G KC=0.01620 23$LC=0.00300 5$MC=0.00072 1 +234U G 446.6 1 0.114 15[M1] 0.338 5 +234U 2 G KC=0.269 4$LC=0.0516 8$MC=0.01245 18 +234U G 468.0 1 0.22 3 [E1] 0.0153922 +234U 2 G KC=0.01241 18$LC=0.00226 4$MC=5.41E-4 8 +234U G 513.4 1 0.38000 0 [M1] 0.232 4 +234U 2 G KC=0.185 3$LC=0.0353 5$MC=0.00852 12 +234U G 513.5 1 0.76000 0 [E1] 0.0128018 +234U 2 G KC=0.01035 15$LC=0.00186 3$MC=4.45E-4 7 +234U G 568.9 2 3.6 6 M1 0.1759 25 +234U 2 G KC=0.1404 20$LC=0.0268 4$MC=0.00645 9 +234U G 590.3 100.036 11[E2M1] 0.10 7 +234U 2 G KC=0.07 6$LC=0.016 8$MC=0.0040 19 +234U G 685.1 2 0.15 4 +234U G 1241.2 1 0.23 3 (E2) 0.0074011 +234U 2 G KC=0.00573 8$LC=1251E-6 18$MC=3.07E-4 5 +234U G 1393.9 1 2.08 21M1 0.0163423 +234U 2 G KC=0.01304 19$LC=0.00243 4$MC=5.85E-4 9 +234U G 1493.6 1 0.104 14[E2] 0.005318 +234U 2 G KC=0.00414 6$LC=8.42E-4 12$MC=2.05E-4 3 +234U L 1543.71 5 4+ +234U B 651 4 0.10 9 9.1 +234U S B EAV=197.1 14 +234U G 474.2 2 0.036 11[E1] 0.0149921 +234U 2 G KC=0.01209 17$LC=0.00219 3$MC=5.26E-4 8 +234U G 575.5 1 0.027 9 [E2M1] 0.10 7 +234U 2 G KC=0.08 6$LC=0.017 9$MC=0.0043 20 +234U G 617.0 2 0.052 22[E2] 0.0294 5 +234U 2 G KC=0.0197 3$LC=0.00720 11$MC=0.00186 3 +234U G 1247.8 2 0.022 6 [E2] 0.0073311 +234U 2 G KC=0.00567 8$LC=1237E-6 18$MC=3.04E-4 5 +234U G 1400.3 1 0.18 3 [E2M1] 0.011 6 +234U 2 G KC=0.009 5$LC=0.0017 8$MC=0.00041 18 +234U G 1500.0 2 0.011 4 [E2] 0.005288 +234U 2 G KC=0.00411 6$LC=8.35E-4 12$MC=2.03E-4 3 +234U L 1548.10 8 (5)+ +234U B 647 4 0.078 20 9.18 +234U S B EAV=195.6 14 +234U G 452.4 3 0.027 9 +234U G 478.6 1 0.125 15[E1] 0.0147221 +234U 2 G KC=0.01187 17$LC=0.00215 3$MC=5.16E-4 8 +234U G 1252.6 2 0.018 8 +234U L 1552.554 245+ 2.200 NS 25 +234U B 642 4 19.6 18 6.77 +234U S B EAV=194.0 14 +234U G 131.30 1 18.2 16E1 0.265 4 +234U 2 G KC=0.204 3$LC=0.0463 7$MC=0.01128 16 +234U G 461.5 1 +234U G 529.1 3 0.09 4 [E2M1] 0.13 9 +234U 2 G KC=0.10 8$LC=0.022 11$MC=0.0054 25 +234U G 584.1 1 0.18 30[E2] 0.0331 5 +234U 2 G KC=0.0217 3$LC=0.00845 12$MC=0.00219 3 +234U G 604.6 3 0.052 22[E2M1] 0.09 6 +234U 2 G KC=0.07 5$LC=0.015 8$MC=0.0037 18 +234U G 1256.5 1 0.059 8 [M1E2] 0.014 8 +234U 2 G KC=0.011 6$LC=0.0022 10$MC=0.00054 24 +234U G 1409.1 2 0.045 10 +234U L 1581.67 10(5-)+ +234U B 613 4 0.05 3 9.3 +234U S B EAV=184.1 14 +234U G 558.0 2 0.094 23[E2] 0.0367 6 +234U 2 G KC=0.0236 4$LC=0.00970 14$MC=0.00252 4 +234U G 619.0 2 0.036 11[M1+E2] 0.08 6 +234U 2 G KC=0.07 5$LC=0.014 7$MC=0.0035 17 +234U G 634.3 2 +234U L 1588.84 5 5+ +234U B 606 4 0.7 8.1 +234U S B EAV=181.7 14 +234U G 55.45 5 0.027 9 (E1) 0.589 9 +234U 2 G KC=$LC=0.443 7$MC=0.1097 16 +234U G 394.1 1 0.094 14[E1] 0.0219 3 +234U 2 G KC=0.01755 25$LC=0.00326 5$MC=7.84E-4 11 +234U G 461.5 1 0.034 11[M1] 0.309 5 +234U 2 G KC=0.246 4$LC=0.0472 7$MC=0.01138 16 +234U G 498.0 1 0.062 12[M1] 0.252 4 +234U 2 G KC=0.201 3$LC=0.0384 6$MC=0.00925 13 +234U G 519.6 1 0.40 5 [E1] 0.0125118 +234U 2 G KC=0.01011 15$LC=0.00181 3$MC=4.34E-4 6 +234U G 565.2 1 1.04 11(M1) 0.179 3 +234U 2 G KC=0.1429 20$LC=0.0272 4$MC=0.00656 10 +234U G 1292.8 1 0.47 6 M1 0.0199 3 +234U 2 G KC=0.01592 23$LC=0.00297 5$MC=7.15E-4 10 +234U G 1445.4 1 0.32 5 [M1] 0.0148821 +234U 2 G KC=0.01185 17$LC=0.00221 3$MC=5.31E-4 8 +234U L 1619.46 9 (6+)+ +234U B 576 4 0.035 20 9.36 2 +234U S B EAV=171.4 14 +234U G 357.9 1 0.036 11[M1E2] 0.4 3 +234U 2 G KC=0.27 22$LC=0.07 3$MC=0.017 6 +234U G 446.6 1 +234U G 529.1 3 +234U G 657.4 1 0.40 5 +234U G 1475.8 2 0.008 4 +234U L 1649.99 12(6-)+ +234U B 545 4 0.18 4 8.64 2 +234U S B EAV=164.6 13 +234U G 553.7 1 0.045 16[E1] 0.0110516 +234U 2 G KC=0.00894 13$LC=1594E-6 23$MC=3.81E-4 6 +234U G 1354.6 2 0.14 4 [E1] 0.002294 +234U 2 G KC=0.00183 3$LC=3.02E-4 5$MC=7.15E-5 10 +234U L 1653.35 7 (3+)+ +234U B 542 4 0.95 13 7.84 +234U S B EAV=160.1 14 +234U G 629.4 1 0.35 6 (M1) 0.1342 19 +234U 2 G KC=0.1072 15$LC=0.0204 3$MC=0.00491 7 +234U G 663.9 1 0.54 9 [E1] 0.0078211 +234U 2 G KC=0.00636 9$LC=1111E-6 16$MC=2.65E-4 4 +234U G 1510.1 2 9400E-6 0 +234U L 1693.42 3 5- +234U B 502 4 6.9 8 6.87 1 +234U S B EAV=146.8 14 +234U G 140.91 3 0.31 5 [E1] 0.224 4 +234U 2 G KC=0.1732 25$LC=0.0386 6$MC=0.00940 14 +234U G 272.28 5 1.09 14M1+E2 0.64 1.004 14 +234U 2 G KC=0.766 11$LC=0.1783 25$MC=0.0442 7 +234U G 416.1 1 0.036 11[E2] 0.0746 11 +234U 2 G KC=0.0405 6$LC=0.0251 4$MC=0.00666 10 +234U G 478.6 1 +234U G 498.0 1 +234U G 521.4 1 0.75 9 [E1] 0.0124218 +234U 2 G KC=0.01004 14$LC=0.00180 3$MC=4.31E-4 6 +234U G 565.2 1 +234U G 602.6 1 0.54 6 [E1] 0.0093914 +234U 2 G KC=0.00762 11$LC=1345E-6 19$MC=3.21E-4 5 +234U G 624.2 1 0.35 5 (M1+E2) 0.7 0.1015 15 +234U 2 G KC=0.0799 12$LC=0.01627 23$MC=0.00396 6 +234U G 669.7 1 1.0 1 [E1] 0.0077011 +234U 2 G KC=0.00626 9$LC=1092E-6 16$MC=2.60E-4 4 +234U G 730.9 2 0.63 10[M1E2] 0.06 4 +234U 2 G KC=0.04 3$LC=0.009 5$MC=0.0022 11 +234U G 745.9 1 0.32 5 [E1] 0.006319 +234U 2 G KC=0.00514 8$LC=8.88E-4 13$MC=2.11E-4 3 +234U G 844.1 1 0.43 5 [E2] 0.0154022 +234U 2 G KC=0.01127 16$LC=0.00309 5$MC=7.77E-4 11 +234U G 1397.5 2 0.083 22[E1] 0.002203 +234U 2 G KC=1733E-6 25$LC=2.86E-4 4$MC=6.78E-5 10 +234U G 1550.1 1 0.073 13[E1] 0.001963 +234U 2 G KC=1460E-6 21$LC=2.40E-4 4$MC=5.68E-5 8 +234U L 1722.89 4 3- +234U B 472 4 8.4 9 6.7 1 +234U S B EAV=137.2 13 +234U G 595.4 2 0.094 23[E2] 0.0317 5 +234U 2 G KC=0.0210 3$LC=0.00799 12$MC=0.00207 3 +234U G 653.7 1 0.47 8 M1 0.1213 17 +234U 2 G KC=0.0969 14$LC=0.0184 3$MC=0.00443 7 +234U G 699.03 5 M1 0.1015 15 +234U 2 G KC=0.0811 12$LC=0.01537 22$MC=0.00370 6 +234U G 733.39 5 7.0 8 M1 0.0893 13 +234U 2 G KC=0.0714 10$LC=0.01351 19$MC=0.00325 5 +234U G 761.0 2 0.073 22[E2] 0.0189 3 +234U 2 G KC=0.01353 19$LC=0.00403 6$MC=1023E-6 15 +234U G 874.0 3 0.036 8 [E2M1] 0.035 21 +234U 2 G KC=0.028 18$LC=0.006 3$MC=0.0014 7 +234U G 1679.5 1 0.077 18 +234U L 1723.424 244+ +234U B 472 4 36 5 6.06 +234U S B EAV=137.1 13 +234U G 134.61 2 0.114 23M1 9.50 14 +234U 2 G KC=7.54 11$LC=1.480 21$MC=0.358 5 +234U G 170.85 2 0.51 7 M1 4.83 7 +234U 2 G KC=3.84 6$LC=0.749 11$MC=0.181 3 +234U G 179.80 8 0.045 16[M1] 4.19 6 +234U 2 G KC=3.33 5$LC=0.648 10$MC=0.1567 22 +234U G 186.15 2 1.78 19M1 3.79 6 +234U 2 G KC=3.02 5$LC=0.587 9$MC=0.142 2 +234U G 227.25 3 5.8 6 M1 2.17 3 +234U 2 G KC=1.724 25$LC=0.335 5$MC=0.0809 12 +234U G 558.0 2 +234U G 596.9 1 +234U G 632.6 2 0.036 11[E2M1] 0.08 6 +234U 2 G KC=0.06 5$LC=0.013 7$MC=0.0033 16 +234U G 699.03 5 3.6 4 +234U G 755.0 1 1.23 13(E2M1) 0.05 4 +234U 2 G KC=0.04 3$LC=0.008 5$MC=0.002 1 +234U G 796.1 1 2.6 3 [E2] 0.0173025 +234U 2 G KC=0.01249 18$LC=0.00359 5$MC=9.06E-4 13 +234U G 1426.9 1 0.17 3 +234U G 1579.9 1 0.073 22 +234U L 1737.42 7 3+ +234U B 458 4 1.16 14 7.51 +234U S B EAV=132.5 14 +234U G 713.7 1 0.146 25[E1] 0.0068410 +234U 2 G KC=0.00557 8$LC=9.66E-4 14$MC=2.30E-4 4 +234U G 748.1 3 0.104 23[E1] 0.006289 +234U 2 G KC=0.00511 8$LC=8.83E-4 13$MC=2.10E-4 3 +234U G 1594.0 1 0.31 4 M1E2 0.008 4 +234U 2 G KC=0.006 3$LC=0.0012 5$MC=0.00029 12 +234U G 1693.8 2 0.7 1 +234U L 1738.18 6 (3+)+ +234U B 457 4 0.78 19 7.68 +234U S B EAV=132.3 14 +234U G 612.0 1 0.38 5 (M1) 0.1447 21 +234U 2 G KC=0.1156 17$LC=0.0220 3$MC=0.00530 8 +234U G 811.5 1 0.125 15[M1E2] 0.04 3 +234U 2 G KC=0.033 22$LC=0.007 4$MC=0.0017 9 +234U G 1695.0 3 0.27 7 +234U L 1761.86 6 (4-)+ +234U B 433 4 2.8 4 7.05 +234U S B EAV=124.7 13 +234U G 634.3 2 0.135 24[M1] 0.1315 19 +234U 2 G KC=0.1050 15$LC=0.0200 3$MC=0.00481 7 +234U G 692.6 1 1.25 13(M1) 0.1040 15 +234U 2 G KC=0.0831 12$LC=0.01575 22$MC=0.00379 6 +234U G 738.0 1 1.16 13(M1) 0.0878 13 +234U 2 G KC=0.0702 10$LC=0.01329 19$MC=0.00320 5 +234U G 772.4 2 0.073 22[E2] 0.0184 3 +234U 2 G KC=0.01318 19$LC=0.00388 6$MC=9.83E-4 14 +234U G 792.8 3 0.045 11[E1] 0.005658 +234U 2 G KC=0.00460 7$LC=7.91E-4 11$MC=1.88E-4 3 +234U G 1618.3 2 0.009 4 +234U L 1770.79 9 (3+)+ +234U B 424 4 0.129 17 8.36 +234U S B EAV=121.8 13 +234U G 802.3 2 0.031 9 [M1] 0.0703 10 +234U 2 G KC=0.0563 8$LC=0.01062 15$MC=0.00256 4 +234U G 1627.3 1 0.076 11 +234U G 1727.8 2 0.020 5 +234U L 1782.58 3 5+ +234U B 412 4 8 3 6.53 +234U S B EAV=118.1 13 +234U G 59.19 5 0.032 11[M1+E2] 90 70 +234U 2 G KC=$LC=70 50$MC=18 15 +234U G 193.73 3 0.50 8 [M1+E2] 2.1 13 +234U 2 G KC=1.4 13$LC=0.510 16$MC=0.132 6 +234U G 245.37 2 0.76 11M1 1.749 25 +234U 2 G KC=1.392 20$LC=0.270 4$MC=0.0652 10 +234U G 360.6 3 0.018 7 [E1] 0.0264 4 +234U 2 G KC=0.0211 3$LC=0.00397 6$MC=9.55E-4 14 +234U G 617.0 2 +234U G 655.2 2 0.135 24[E1] 0.0080212 +234U 2 G KC=0.00651 10$LC=1140E-6 16$MC=2.72E-4 4 +234U G 758.9 1 0.25 3 [M1E2] 0.05 4 +234U 2 G KC=0.04 3$LC=0.008 5$MC=0.002 1 +234U G 814.2 1 0.31 4 [E2] 0.0165424 +234U 2 G KC=0.01201 17$LC=0.00338 5$MC=8.54E-4 12 +234U G 1485.4 2 0.030 7 [M1] 0.0138720 +234U 2 G KC=0.01102 16$LC=0.00205 3$MC=4.94E-4 7 +234U G 1638.1 1 0.208 21(M1) 0.0108316 +234U 2 G KC=0.00850 12$LC=1581E-6 23$MC=3.80E-4 6 +234U L 1784.19 134+ +234U B 411 4 0.061 11 8.64 +234U S B EAV=117.6 13 +234U G 857.7 2 0.036 8 [E2] 0.0149321 +234U 2 G KC=0.01095 16$LC=0.00297 5$MC=7.46E-4 11 +234U G 1488.0 2 0.014 6 +234U G 1640.5 3 0.010 4 +234U L 1793.05 6 4+ +234U B 402 4 0.41 8 7.78 +234U S B EAV=114.8 13 +234U G 240.2 1 0.052 22[M1E2] 1.1 8 +234U 2 G KC=0.8 7$LC=0.24 5$MC=0.062 8 +234U G 769.1 1 0.187 20[M1E2] 0.05 3 +234U 2 G KC=0.038 25$LC=0.008 4$MC=0.0019 10 +234U G 1496.0 2 0.036 9 +234U G 1650.2 2 6000E-6 0 +234U G 1750.0 1 0.064 10 +234U L 1811.62 6 4+ +234U B 383 4 1.43 15 7.17 +234U S B EAV=108.9 13 +234U G 596.9 1 0.20 3 [M1] 0.1547 22 +234U 2 G KC=0.1235 18$LC=0.0235 4$MC=0.00566 8 +234U G 683.9 2 0.16 4 [E1] 0.0074011 +234U 2 G KC=0.00602 9$LC=1049E-6 15$MC=2.50E-4 4 +234U G 685.1 2 [E2] 0.0235 4 +234U 2 G KC=0.01631 23$LC=0.00535 8$MC=1369E-6 20 +234U G 848.9 2 0.027 8 [E1] 0.005007 +234U 2 G KC=0.00408 6$LC=6.96E-4 10$MC=1655E-7 24 +234U G 863.2 2 0.073 22[E2M1] 0.036 22 +234U 2 G KC=0.029 18$LC=0.006 3$MC=0.0014 7 +234U G 960.0 1 0.073 13[E2] 0.0119917 +234U 2 G KC=0.00899 13$LC=0.00225 4$MC=5.62E-4 8 +234U G 1515.6 2 0.073 13 +234U G 1668.4 1 0.77 9 (M1) 0.0103515 +234U 2 G KC=0.00809 12$LC=1505E-6 21$MC=3.62E-4 5 +234U G 1768.0 3 0.020 5 +234U L 1843.88 173,4,5-+ +234U B 351 4 0.17 3 7.97 +234U S B EAV=98.9 13 +234U G 994.6 3 0.062 22 +234U G 1700.5 2 0.104 14 +234U L 1863.08 15(5+)+ +234U B 332 4 0.029 7 8.66 +234U S B EAV=93.0 13 +234U G 1567.0 2 0.0114 23 +234U G 1719.7 2 0.018 6 +234U L 1881.75 7 4+ +234U B 313 4 0.25 3 7.65 +234U S B EAV=87.3 13 +234U G 716.5 2 0.031 9 [M1E2] 0.06 4 +234U 2 G KC=0.05 3$LC=0.010 5$MC=0.0023 12 +234U G 755.0 1 +234U G 1585.9 1 0.146 17 +234U G 1737.7 2 0.075 11 +234U G 1838.0 2 +234U L 1916.28 9 3,4++ +234U B 279 4 0.21 3 7.56 +234U S B EAV=76.9 12 +234U G 989.5 1 0.104 14 +234U G 1773.0 2 0.068 17 +234U G 1872.8 2 0.035 9 +234U L 1927.51 7 4+ +234U B 267 4 0.22 4 7.49 +234U S B EAV=73.5 12 +234U G 165.61 5 0.073 22[E1] 0.1533 22 +234U 2 G KC=0.1194 17$LC=0.0256 4$MC=0.00622 9 +234U G 308.6 2 0.021 6 [E2] 0.1726 25 +234U 2 G KC=0.0711 10$LC=0.0744 11$MC=0.0201 3 +234U G 586.3 1 0.073 13[E2] 0.0328 5 +234U 2 G KC=0.0216 3$LC=0.00836 12$MC=0.00216 3 +234U G 653.7 1 +234U G 713.7 1 +234U G 1783.7 2 0.025 7 +234U G 1884.1 3 0.016 5 +234U L 1940.52 9 4+ +234U B 254 4 0.35 5 7.22 +234U S B EAV=69.7 12 +234U G 916.5 2 0.024 7 +234U G 1644.9 2 0.010 4 +234U G 1797.1 1 0.24 3 +234U G 1896.7 2 0.104 23 +234U L 1958.75 4 3- +234U B 236 4 0.44 19 7.01 1 +234U S B EAV=64.3 12 +234U G 221.15 100.052 22[E1] 0.0780 11 +234U 2 G KC=0.0615 9$LC=0.01248 18$MC=0.00302 5 +234U G 235.11 3 0.114 23[E1] 0.0678 10 +234U 2 G KC=0.0536 8$LC=0.01075 15$MC=0.00260 4 +234U G 502.0 1 0.03 9 [E2M1] 0.15 10 +234U 2 G KC=0.11 9$LC=0.026 12$MC=0.006 3 +234U G 890.1 4 0.027 8 +234U G 935.8 2 0.067 10 +234U G 1110.6 1 0.062 12 +234U G 1173.1 1 0.046 9 +234U G 1815.3 3 0.009 4 +234U G 1915.5 3 0.020 5 +234U L 1968.84 104+,5+ +234U B 226 4 0.044 12 7.95 +234U S B EAV=61.3 12 +234U G 1672.8 1 0.034 11 +234U G 1825.1 3 0.009 4 +234U L 1981.22 7 4+ +234U B 214 4 0.59 8 6.75 +234U S B EAV=57.8 12 +234U G 257.2 1 0.052 22[M1E2] 0.9 7 +234U 2 G KC=0.7 6$LC=0.19 5$MC=0.049 8 +234U G 433.1 1 0.094 14 +234U G 1685.7 1 0.31 4 +234U G 1838.0 2 0.0042 11 +234U G 1937.7 3 0.042 11 +234U L 2000.45 13(4+)+ +234U B 195 4 0.122 16 7.31 +234U S B EAV=52.2 12 +234U G 1037.9 2 0.018 7 +234U G 1073.6 2 0.104 14 +234U G 1151.4 3 +234U L 2019.82 134+ +234U B 175 4 0.112 16 7.2 +234U S B EAV=46.7 12 +234U G 1051.4 2 0.062 12 +234U G 1057.8 3 0.0177 16 +234U G 1723.2 2 0.016 4 +234U G 1977.4 4 0.017 5 +234U L 2033.54 5 3+,4++ +234U B 161 4 0.90 15 6.19 +234U S B EAV=42.9 12 +234U G 310.2 1 0.073 13[M1E2] 0.5 4 +234U 2 G KC=0.4 4$LC=0.11 4$MC=0.027 7 +234U G 481.0 1 0.31 4 [M1E2] 0.16 12 +234U 2 G KC=0.13 10$LC=0.029 14$MC=0.007 3 +234U G 537.2 1 0.083 13[M1E2] 0.12 9 +234U 2 G KC=0.09 7$LC=0.021 11$MC=0.0052 24 +234U G 1009.9 3 0.067 12 +234U G 1065.1 1 0.027 8 +234U G 1106.9 2 0.083 13 +234U G 1182.1 2 9400E-6 0 +234U G 1890.1 2 0.146 17 +234U G 1989.6 4 0.007 4 +234U L 2037.06 174+,5+ +234U B 158 4 0.055 8 7.37 +234U S B EAV=41.9 12 +234U G 1741.1 2 0.049 8 +234U G 1893.4 3 6200E-6 0 +234U L 2066.24 10 + +234U B 129 4 0.140 24 6.69 +234U S B EAV=33.8 11 +234U G 975.1 1 0.027 8 +234U G 997.7 3 0.046 12 +234U G 1770.8 2 0.068 17 +234U L 2068.82 113,4,5++ +234U B 126 4 0.40 7 6.21 +234U S B EAV=33.1 11 +234U G 331.4 1 0.073 13 +234U G 1925.4 2 0.30 5 +234U L 2101.42 9 5+ +234U B 94 4 0.064 11 6.6 +234U S B EAV=24.2 11 +234U G 839.5 1 0.031 8 +234U G 1009.9 3 +234U G 1032.8 2 0.018 5 +234U G 1805.8 3 0.0052 22 +234U G 1958.0 4 0.010 3 +234U L 2115.71 114+ +234U B 79 4 0.21 3 5.87 +234U S B EAV=20.4 11 +234U G 534.1 1 0.083 13[E1] 0.0118517 +234U 2 G KC=0.00958 14$LC=1715E-6 24$MC=4.10E-4 6 +234U G 562.8 3 0.036 11[M1E2] 0.11 8 +234U 2 G KC=0.08 6$LC=0.018 9$MC=0.0045 21 +234U G 1019.5 4 0.027 8 +234U G 1153.5 3 0.046 9 +234U G 1819.8 3 0.0042 11 +234U G 1971.2 4 2700E-6 0 +234U G 2072.2 4 0.0042 22 +234U L 2144.04 9 3+,4+- +234U B 51 4 0.42 5 4.98 1 +234U S B EAV=13.0 11 +234U G 869.7 1 0.20 3 +234U G 1217.3 1 0.22 3 + diff --git a/HEN_HOUSE/spectra/lnhb/Pa-234m.txt b/HEN_HOUSE/spectra/lnhb/Pa-234m.txt new file mode 100644 index 000000000..39243ab4d --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Pa-234m.txt @@ -0,0 +1,358 @@ +234PA 234PA IT DECAY (1.159 M) +234PA H TYP=Full$AUT=Huang$CUT=30-JAN-2009$ +234PA C Evaluation history: Type=Full;Author=Huang;Cutoff date=30-JAN-2009 +234PA T Auger electrons and ^X ray energies and emission intensities: +234PA T {U Energy (keV)} {U Intensity } {U Line } +234PA T +234PA T +234PA T +234PA T +234PA T 11.3676-20.1126 0.046 4 XL (total) +234PA T 11.3676 XLL +234PA T 13.1215-13.2887 XLA +234PA T 14.9488 XLC +234PA T 15.3584-17.6655 XLB +234PA T 18.9396-20.1126 XLG +234PA T +234PA T 5.9-20.9 0.048 4 L AUGER +234PA P 73.92 2 (0-)- 1.159 M 11 +234PA N 6.667E2 6.667E2 0.0015 6.667E2 +234PA G 243.5 8 0.00050 9 +234PA G 557.3 100.00072 17 +234PA G 647.7 8 0.00158 15 +234PA G 760.3 100.00158 15 +234PA G 887.29 100.00708 14 +234PA G 1220.37 100.00091 9 +234PA G 1353.0 150.0015 5 +234PA G 1720.5 150.00033 15 +234PA G 1732.2 150.0019 3 +234PA G 1759.81 100.00146 5 +234PA G 2022.24 121.86E-4 3 +234PA G 2041.23 130.00011 1 +234PA G 2065.80 137000E-8 0 +234PA G 2093.19 382000E-8 0 +234PA G 2102.14 156000E-8 0 +234PA G 2136.69 147000E-8 0 +234PA L 0 4+ 6.70 H 5 +234PA L 73.92 2 (3+)+ +234PA G 73.92 2 0.0129 9 (M1+E2) 0.11 3 10.6 4 +234PA2 G KC=$LC=7.96 25$MC=1.94 7 +234PA L 83.92 (0-)- 1.159 M 11 +234PA G 10 + +234U 234PA B- DECAY (1.159 M) +234U H TYP=Full$AUT=Huang$CUT=30-JAN-2009$ +234U C Evaluation history: Type=Full;Author=Huang;Cutoff date=30-JAN-2009 +234U T Auger electrons and ^X ray energies and emission intensities: +234U T {U Energy (keV)} {U Intensity } {U Line } +234U T +234U T 94.666 0.1973 25 XKA2 +234U T 98.44 0.316 4 XKA1 +234U T +234U T 110.421 |] XKB3 +234U T 111.298 |] 0.115 2 XKB1 +234U T 111.964 |] XKB5II +234U T +234U T 114.407 |] XKB2 +234U T 115.012 |] 0.0382 5 XKB4 +234U T 115.377 |] XKO23 +234U T +234U T 11.6185-20.7141 0.856 19 XL (total) +234U T 11.6185 XLL +234U T 13.4382-13.6146 XLA +234U T 15.399 XLC +234U T 15.7268-18.2061 XLB +234U T 19.5072-20.7141 XLG +234U T +234U T 71.776-80.954 |] KLL AUGER +234U T 88.153-98.429 |] 0.0203 3 ^KLX AUGER +234U T 104.51-115.59 |] KXY AUGER +234U T 5.9-21.6 0.856 19 L AUGER +234PA P 73.92 2 (0-)+ 1.159 M 11 2195.1 40 +234U N 1.002E0 1.002E0 0.9985 1.002E0 +234U G 243.5 8 0.00050 9 +234U G 557.3 100.00072 17 +234U G 647.7 8 0.00158 15 +234U G 760.3 100.00158 15 +234U G 887.29 100.00708 14 +234U G 1220.37 100.00091 9 +234U G 1353.0 150.0015 5 +234U G 1720.5 150.00033 15 +234U G 1732.2 150.0019 3 +234U G 1759.81 100.00146 5 +234U G 2022.24 121.86E-4 3 +234U G 2041.23 130.00011 1 +234U G 2065.80 137000E-8 0 +234U G 2093.19 382000E-8 0 +234U G 2102.14 156000E-8 0 +234U G 2136.69 147000E-8 0 +234U L 0 0+ STABLE +234U B 2269 4 97.599 24 5.5 +234U S B EAV=820.5 17 +234U L 43.428 142+ 0.252 NS 7 +234U G 43.49 2 0.00198 2 E2 713 11 +234U 2 G KC=$LC=520 8$MC=143.7 21 +234U L 143.279 244+ +234U G 99.86 2 0.00057 5 E2 13.42 19 +234U 2 G KC=$LC=9.77 14$MC=2.71 4 +234U L 786.243 141- +234U B 1483 4 0.049 3 8 1 +234U S B EAV=505.3 16 +234U G 742.813 5 0.094 3 E1 0.006369 +234U 2 G KC=0.00518 8$LC=8.95E-4 13$MC=2.13E-4 3 +234U G 786.272 220.0536 7 E1+M2 0.005738 +234U 2 G KC=0.00467 7$LC=8.04E-4 12$MC=1.91E-4 3 +234U L 809.786 230+ 0.1 NS +234U B 1459 4 0.945 12 6.8 +234U S B EAV=496.0 16 +234U G 766.361 200.323 4 (E2) 0.0187 3 +234U 2 G KC=0.01336 19$LC=0.00396 6$MC=1004E-6 14 +234U G 810.0 7 +234U L 849.18 7 3- +234U G 705.94 120.0052 6 [E1] 0.0069810 +234U 2 G KC=0.00568 8$LC=9.87E-4 14$MC=2.35E-4 4 +234U G 805.75 100.0062 8 [E1] 0.005498 +234U 2 G KC=0.00447 7$LC=7.68E-4 11$MC=1.83E-4 3 +234U L 851.56 4 2+ 1.74 PS +234U G 41.82 +234U G 708.2 107000E-7 0 [E2] 0.0219 4 +234U 2 G KC=0.01537 22$LC=0.00489 7$MC=1247E-6 19 +234U G 808.2 1 0.00281 17 +234U G 851.6 1 0.00696 15[E2] 0.0151422 +234U 2 G KC=0.01109 16$LC=0.00302 5$MC=7.60E-4 11 +234U L 926.659 202+ 1.38 PS 17 +234U G 783.4 1 3.9E-5 7 [E2] 0.0179 3 +234U 2 G KC=0.01285 18$LC=0.00374 6$MC=9.46E-4 14 +234U G 883.24 3 0.00381 5 E2 0.0140920 +234U 2 G KC=0.01040 15$LC=0.00276 4$MC=6.92E-4 10 +234U G 926.61 100.00125 13(E2) 0.0128418 +234U 2 G KC=0.00956 14$LC=0.00245 4$MC=6.13E-4 9 +234U L 989.359 192- 0.76 NS 4 +234U G 62.70 1 0.0013 4 E1 0.426 6 +234U 2 G KC=$LC=0.320 5$MC=0.0791 11 +234U G 140.1 101270E-6 0 M1+E2 1.2 6 5.3 18 +234U 2 G KC=2.9 22$LC=1.76 25$MC=0.47 9 +234U G 203.3 8 0.00119 9 M1+E2 1.5 4 1.4 4 +234U 2 G KC=0.8 4$LC=0.420 12$MC=0.1109 23 +234U G 945.961 160.01060 14(E1) 0.004126 +234U 2 G KC=0.00337 5$LC=5.71E-4 8$MC=1355E-7 19 +234U L 1044.469 150+ +234U B 1224 4 1.006 13 6.5 +234U S B EAV=405.6 16 +234U G 193.4 8 0.00072 15[E2] 0.847 18 +234U 2 G KC=0.163 3$LC=0.500 12$MC=0.138 4 +234U G 236 1 +234U G 258.227 3 0.0738 8 (E1) 0.0548 8 +234U 2 G KC=0.0434 6$LC=0.00859 12$MC=0.00207 3 +234U G 1001.026 180.847 8 E2 0.0110716 +234U 2 G KC=0.00835 12$LC=0.00204 3$MC=5.07E-4 8 +234U L 1085.04 4 2+ +234U G 233.6 2 +234U G 235.9 3 0.00009 4 [E1] 0.0673 10 +234U 2 G KC=0.0532 8$LC=0.01067 16$MC=0.00258 4 +234U G 299 1 0.00064 13[E1] 0.0395 7 +234U 2 G KC=0.0315 5$LC=0.00608 10$MC=1467E-6 24 +234U G 941.96 100.00250 9 [E2] 0.0124418 +234U 2 G KC=0.00929 13$LC=0.00236 4$MC=5.89E-4 9 +234U G 1041.7 1 0.00119 8 [E2M1] 0.023 13 +234U 2 G KC=0.018 11$LC=0.0036 18$MC=0.0009 4 +234U G 1084.25 100.0008 4 [E2] 0.0095214 +234U 2 G KC=0.00726 11$LC=1694E-6 24$MC=4.19E-4 6 +234U L 1126.32 4 2+ +234U G 137.23 5 4.8E-5 17[E1] 0.239 4 +234U 2 G KC=0.184 3$LC=0.0413 6$MC=0.01006 15 +234U G 199.9 100.00058 12(+E2+M1) 1.9 12 +234U 2 G KC=1.3 12$LC=0.473 22$MC=0.122 4 +234U G 275.5 8 0.00031 6 [M1E2] 0.8 6 +234U 2 G KC=0.5 5$LC=0.16 4$MC=0.039 8 +234U G 316.7 1 0.00019 5 [E2] 0.1597 23 +234U 2 G KC=0.0677 10$LC=0.0674 10$MC=0.0182 3 +234U G 340.2 1 7.2E-5 21[E1] 0.0298 5 +234U 2 G KC=0.0239 4$LC=0.00453 7$MC=1090E-6 16 +234U G 1081.9 100.00091 19(M1) 0.0318 5 +234U 2 G KC=0.0255 4$LC=0.00478 7$MC=1151E-6 17 +234U G 1124.93 100.00039 9 [E2] 0.0088813 +234U 2 G KC=0.00681 10$LC=1558E-6 22$MC=3.85E-4 6 +234U L 1174.2 4 (1,2+)+ +234U B 1095 4 0.0046 3 8.7 +234U S B EAV=356.7 15 +234U G 185.0 4 0.00172 15 +234U G 387.6 8 0.00097 15 +234U G 1174.2 100.00192 19 +234U L 1237.23 3 1- +234U B 1032 4 0.0121 11 8.2 1 +234U S B EAV=333.1 15 +234U G 247.7 8 0.00097 22[M1E2] 1.0 7 +234U 2 G KC=0.7 7$LC=0.22 5$MC=0.056 8 +234U G 311 1 0.00052 11[E1] 0.0363 6 +234U 2 G KC=0.0289 5$LC=0.00556 9$MC=1339E-6 22 +234U G 387.6 8 0.00047 4 [E2] 0.0899 14 +234U 2 G KC=0.0463 7$LC=0.0321 5$MC=0.00858 14 +234U G 427.4 2 2.0E-5 5 [E1] 0.0185 3 +234U 2 G KC=0.01488 21$LC=0.00274 4$MC=6.57E-4 10 +234U G 450.98 100.00310 13M1+E2 0.7 0.241 4 +234U 2 G KC=0.187 3$LC=0.0400 6$MC=0.00979 14 +234U G 1193.77 3 0.01359 18E1 0.002774 +234U 2 G KC=0.00226 4$LC=3.77E-4 6$MC=8.92E-5 13 +234U G 1237.28 100.00528 11E1 0.002624 +234U 2 G KC=0.00213 3$LC=3.54E-4 5$MC=8.38E-5 12 +234U L 1435.05 5 1- +234U B 834 4 0.0092 11 7.9 1 +234U S B EAV=261.1 15 +234U G 197.91 152.7E-5 7 [M1E2] 2.0 12 +234U 2 G KC=1.3 12$LC=0.473 22$MC=0.122 4 +234U G 445.91 103.1E-5 7 [M1E2] 0.20 14 +234U 2 G KC=0.15 12$LC=0.036 16$MC=0.009 4 +234U G 624.6 101.16E-4 12[E1] 0.0087713 +234U 2 G KC=0.00712 11$LC=1252E-6 18$MC=2.99E-4 5 +234U G 649 1 5.9E-5 8 [M1E2] 0.08 5 +234U 2 G KC=0.06 4$LC=0.012 7$MC=0.0031 15 +234U G 1392.6 9 0.0029 11E1 0.002214 +234U 2 G KC=1743E-6 25$LC=2.88E-4 4$MC=6.82E-5 10 +234U G 1434.16 100.00973 16E1 0.002133 +234U 2 G KC=1660E-6 24$LC=2.74E-4 4$MC=6.48E-5 9 +234U L 1457.40 8 (2-)+ +234U G 670.8 100.00037 9 [M1E2] 0.07 5 +234U 2 G KC=0.05 4$LC=0.011 6$MC=0.0028 14 +234U G 1413.89 100.00229 8 [E1] 0.002173 +234U 2 G KC=1700E-6 24$LC=2.81E-4 4$MC=6.64E-5 10 +234U L 1500.8 3 (1)+ +234U B 768 4 0.0131 6 7.7 +234U S B EAV=237.6 15 +234U G 649 1 0.0010 3 +234U G 691.0 3 0.00898 19 +234U G 1458.5 150.0019 5 +234U G 1501 2 1300E-6 0 +234U L 1553.62 6 (1)+ +234U B 715 4 0.0320 6 7.2 +234U S B EAV=219.2 14 +234U G 468.43 100.00206 12 +234U G 509.2 8 0.0022 3 +234U G 702.0 1 0.00721 16 +234U G 1510.22 100.01308 19 +234U G 1553.77 100.00826 14 +234U L 1570.53 4 1+ +234U B 698 4 0.00231 19 8.4 +234U S B EAV=213.3 14 +234U G 135.32 8 4.2E-6 5 [E1] 0.247 4 +234U 2 G KC=0.190 3$LC=0.0428 6$MC=0.01043 15 +234U G 485.44 7 1.87E-5 17[M1E2] 0.16 11 +234U 2 G KC=0.12 10$LC=0.028 13$MC=0.007 3 +234U G 526.02 109E-6 1 [M1] 0.217 3 +234U 2 G KC=0.1732 25$LC=0.0331 5$MC=0.00797 12 +234U G 581.19 108.0E-5 9 [E1] 0.0100614 +234U 2 G KC=0.00815 12$LC=1445E-6 21$MC=3.45E-4 5 +234U G 719.01 7 2.56E-5 20[M1+E2] 0.06 4 +234U 2 G KC=0.05 3$LC=0.009 5$MC=0.0023 12 +234U G 760.53 154.3E-6 9 [M1] 0.0811 12 +234U 2 G KC=0.0648 9$LC=0.01226 18$MC=0.00295 5 +234U G 1527.28 100.00235 8 M1+E2 0.009 4 +234U 2 G KC=0.007 4$LC=0.0014 6$MC=0.00033 14 +234U G 1570.67 100.00110 8 M1 0.0120417 +234U 2 G KC=0.00951 14$LC=1769E-6 25$MC=4.25E-4 6 +234U L 1591.64 7 (1)+ +234U B 677 4 0.0249 5 7.2 +234U S B EAV=205.8 14 +234U G 507.5 100.00158 15 +234U G 740.10 8 0.0118 3 +234U G 781.75 100.00782 18 +234U G 1550.1 100.00137 15 +234U G 1593.5 6 0.00235 12 +234U L 1601.68 4 1+ +234U B 667 4 0.00127 23 8.5 +234U S B EAV=202.5 14 +234U G 166.5 1 2.37E-7 5 [E1] 0.1514 22 +234U 2 G KC=0.1179 17$LC=0.0253 4$MC=0.00613 9 +234U G 516.60 6 1.22E-5 16(M1) 0.228 4 +234U 2 G KC=0.182 3$LC=0.0347 5$MC=0.00837 12 +234U G 557.24 6 8.3E-6 11(M1) 0.186 3 +234U 2 G KC=0.1485 21$LC=0.0283 4$MC=0.00682 10 +234U G 750.12 6 1.7E-5 2 (M1) 0.0841 12 +234U 2 G KC=0.0672 10$LC=0.01272 18$MC=0.00306 5 +234U G 791.94 5 9.9E-6 13[M1] 0.0728 11 +234U 2 G KC=0.0582 9$LC=0.01100 16$MC=0.00265 4 +234U G 1558.4 100.00073 9 M1 0.0122818 +234U 2 G KC=0.00971 14$LC=0.00181 3$MC=4.34E-4 7 +234U G 1601.8 150.00047 22(M1) 0.0114617 +234U 2 G KC=0.00902 13$LC=1679E-6 24$MC=4.03E-4 6 +234U L 1666.77 5 (1-)+ +234U B 602 4 0.0061 3 7.6 +234U S B EAV=180.1 14 +234U G 818.2 5 0.0010 3 +234U G 880.52 4 0.00392 5 +234U G 1667.6 100.00118 6 +234U L 1693.7 6 (1-)+ +234U B 575 4 0.0024 3 8 +234U S B EAV=171.2 14 +234U G 456.7 100.00072 15[M1] 0.318 5 +234U 2 G KC=0.253 4$LC=0.0485 8$MC=0.01171 18 +234U G 844.1 8 0.00109 23 +234U G 1694.1 100.00038 2 +234U L 1781.19 8 (0+,1)+ +234U B 488 4 0.0357 18 6.6 +234U S B EAV=142.3 14 +234U G 209.9 4 0.00132 15 +234U G 543.98 100.00349 15 +234U G 655.3 100.00139 15 +234U G 695.5 100.00164 14 +234U G 996.1 200.0059 17 +234U G 1737.77 100.0214 3 +234U L 1796.4 6 (1)+ +234U B 473 4 0.0021 3 7.7 +234U S B EAV=137.4 14 +234U G 338.1 8 0.00113 23 +234U G 362.8 100.00069 15 +234U G 1796.3 9 0.00031 5 +234U L 1808.97 7 (1-)+ +234U B 460 4 0.0146 7 6.9 +234U S B EAV=133.3 13 +234U G 572 1 0.00087 17[M1] 0.173 3 +234U 2 G KC=0.1384 21$LC=0.0264 4$MC=0.00636 10 +234U G 683.4 100.00058 12[E1] 0.0074111 +234U 2 G KC=0.00603 9$LC=1050E-6 15$MC=2.50E-4 4 +234U G 960 1 0.0009 3 +234U G 1765.44 100.0084 6 +234U G 1809.05 100.00376 7 +234U L 1863.11 7 (1)+ +234U B 406 4 0.00311 19 7.4 +234U S B EAV=116.0 13 +234U G 936.3 100.00102 17 +234U G 1819.69 100.00089 5 +234U G 1863.09 100.00120 5 +234U L 1874.86 8 (1)+ +234U B 394 4 0.0258 3 6.4 +234U S B EAV=112.3 13 +234U G 1831.37 100.01759 23 +234U G 1874.9 1 0.00819 14 +234U L 1911.04 5 (1-)+ +234U B 358 4 0.0452 8 6 +234U S B EAV=101.0 13 +234U G 357.5 100.00080 17 +234U G 453.58 100.00213 12[M1] 0.324 5 +234U 2 G KC=0.258 4$LC=0.0495 7$MC=0.01193 17 +234U G 475.74 100.00237 13[M1] 0.285 4 +234U 2 G KC=0.227 4$LC=0.0434 6$MC=0.01048 15 +234U G 673.9 100.00064 13[M1] 0.1118 17 +234U 2 G KC=0.0894 13$LC=0.01695 25$MC=0.00408 6 +234U G 825.5 2 0.0014 4 +234U G 866.8 100.00116 16 +234U G 921.72 100.01275 20 +234U G 1059.4 8 0.00111 22 +234U G 1061.86 100.00224 9 +234U G 1124.93 100.00347 9 +234U G 1867.7 1 0.00932 12 +234U G 1911.20 110.00628 9 +234U L 1936.68 7 (1)+ +234U B 332 4 0.0108 3 6.6 +234U S B EAV=93.0 13 +234U G 699.02 100.0058 3 +234U G 1893.51 110.00218 6 +234U G 1937.01 130.00285 5 +234U L 1970.0 5 (1-)- +234U B 299 4 0.00389 22 6.8 1 +234U S B EAV=83.0 13 +234U G 732.5 100.00130 15 +234U G 1120.6 8 0.00173 15 +234U G 1926.5 100.00045 4 +234U G 1970.3 8 0.00041 4 + diff --git a/HEN_HOUSE/spectra/lnhb/Pb-203.txt b/HEN_HOUSE/spectra/lnhb/Pb-203.txt new file mode 100644 index 000000000..d123c8167 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Pb-203.txt @@ -0,0 +1,53 @@ +203TL 203PB EC DECAY (51.929 H) +203TL H TYP=Full$AUT=V.Chisté$CUT=01-JUL-2006$ +203TL C Evaluation history: Type=Full;Author=V.Chisté;Cutoff date=01-JUL-2006 +203TL C References: 1941Fa04, 1952He18, 1954Pr04, 1954Th17, 1954Wa12, 1955Az33, +203TL2C 1955Do12, 1955Ma40, 1956No26, 1956Wo09, 1956OF03, 1956Wa30, 1957Be57, +203TL3C 1958Bart, 1958Ni28, 1960Pe16, 1960St21, 1960Ra04, 1960Pe22, 1960Jo15, +203TL4C 1960Go15, 1960Ba16, 1960De04, 1961Ge01, 1961Hu15, 1961Pe12, 1961Sc04, +203TL5C 1961Su10, 1962Ta06, 1962De14, 1963Bu09, 1963Cr14, 1964He19, 1964Ro19, +203TL6C 1965Ka02, 1965Ra12, 1965Wa13, 1967Pa09, 1968Ra26, 1968Sa22, 1969Cl11, +203TL7C 1971Ch54, 1971WaKF, 1974Ha29, 1978He21, 1980Ho17, 1982HoZJ, 1985HaZA, +203TL8C 1989Ne05, 1996Sc06, 2000He14, 2000Sc05, 2001Li17, 2002Un02, 2003Au03, +203TL9C 2005Ko20, 2006Ra03 +203TL T Auger electrons and ^X ray energies and emission intensities: +203TL T {U Energy (keV)} {U Intensity } {U Line } +203TL T +203TL T 70.8325 25.61 19 XKA2 +203TL T 72.8725 43.24 25 XKA1 +203TL T +203TL T 82.118 |] XKB3 +203TL T 82.577 |] 14.70 24 XKB1 +203TL T 83.115 |] XKB5II +203TL T +203TL T 84.838 |] XKB2 +203TL T 85.134 |] 4.37 11 XKB4 +203TL T 85.444 |] XKO23 +203TL T +203TL T 8.9531-14.7362 33.2 6 XL (total) +203TL T 8.9531 0.819 21 XLL +203TL T 10.1718-10.2679 15.8 4 XLA +203TL T 10.9942 0.243 6 XLC +203TL T 11.8117-12.9566 13.79 25 XLB +203TL T 13.8528-14.7362 2.58 5 XLG +203TL T +203TL T 54.587-59.954 |] KLL AUGER +203TL T 66.37-72.86 |] 3.4 4 ^KLX AUGER +203TL T 78.12-85.5 |] KXY AUGER +203TL T 5.18-15.31 57.9 6 L AUGER +203PB P 0.0 5/2- 51.929 H 10 975 6 +203TL N 1.0 1.0 1 1.0 +203TL L 0 1/2+ STABLE +203TL L 279.1958 123/2+ 282.3 PS 37 +203TL E 95.20 126.404 1U +203TL2 E EAV= $CK=0.7786 4$CL=0.1661 3$CM=0.0552 1$CN= $CO=0 0 +203TL G 279.1952 1080.94 5 M1+E2 1.17 6 0.2261 8 +203TL2 G KC=0.164 1$LC=0.04837 48$MC= +203TL L 680.5164 225/2+ 0.88 PS 8 +203TL E 4.80 8 6.812 +203TL2 E EAV= $CK=0.7076 32$CL=0.2168 22$CM=0.0756 9$CN= $CO=0 0 +203TL G 401.320 3 3.43 6 M1+E2 0.030 3 0.1784 25 +203TL2 G KC=0.1464 21$LC=0.0245 4$MC=0.00572 8 +203TL G 680.515 3 0.754 18E2 0.0139320 +203TL2 G KC=0.01065 15$LC=0.00250 4$MC=6.05E-4 9 + diff --git a/HEN_HOUSE/spectra/lnhb/Pb-209.txt b/HEN_HOUSE/spectra/lnhb/Pb-209.txt new file mode 100644 index 000000000..f9520f619 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Pb-209.txt @@ -0,0 +1,32 @@ +209BI 209PB B- DECAY (3.277 H) +209BI H TYP=Full$AUT=F. Kondev$CUT=31-DEC-2010$ +209BI2 H TYP=full$AUT=mmbe$CUT= -- $ +209BI C Evaluation history: Type=Full;Author=F. Kondev;Cutoff date=31-DEC-2010 +209BI2C Type=full;Author=mmbe;Cutoff date= -- +209BI C References: 1940Kr08, 1941Fa04, 1942Ma03, 1959Po64, 1971Go40, 1971Pe03, +209BI2C 1972Be44, 1991Ma16, 2003Au03 +209BI T Auger electrons and ^X ray energies and emission intensities: +209BI T {U Energy (keV)} {U Intensity } {U Line } +209BI T +209BI T 74.8157 XKA2 +209BI T 77.1088 XKA1 +209BI T +209BI T 86.835 |] XKB3 +209BI T 87.344 |] XKB1 +209BI T 87.862 |] XKB5II +209BI T +209BI T 89.732 |] XKB2 +209BI T 90.074 |] XKB4 +209BI T 90.421 |] XKO23 +209BI T +209BI T +209BI T 57.491-63.419 |] KLL AUGER +209BI T 70.025-77.105 |] ^KLX AUGER +209BI T 82.53-90.52 |] KXY AUGER +209BI T 5.4204-16.3366 L AUGER +209PB P 0.0 9/2+ 3.277 H 15 644.0 12 +209BI N 1.0 1.0 1 1.0 +209BI L 0 9/2- STABLE +209BI B 644.0 12100 5.54 +209BIS B EAV=197.35 42 + diff --git a/HEN_HOUSE/spectra/lnhb/Pb-210.txt b/HEN_HOUSE/spectra/lnhb/Pb-210.txt new file mode 100644 index 000000000..75af671f1 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Pb-210.txt @@ -0,0 +1,70 @@ +206HG 210PB A DECAY (22.23 Y) +206HG H TYP=Full$AUT=V. Chisté$CUT= -- $ +206HG C Evaluation history: Type=Full;Author=V. Chisté;Cutoff date= -- +206HG C References: 1951Bu37, 1953Wu28, 1954Da23, 1955To14, 1956St99, 1957To16, +206HG2C 1957Me47, 1957Fi06, 1958Kr71, 1958To10, 1959Pa03, 1959Ha02, 1960Ec01, +206HG3C 1961Nu01, 1962Ka27, 1963Im02, 1964Wo05, 1964Ra12, 1967Vo04, 1969Ho06, +206HG4C 1969Gr33, 1971Ge11, 1981He15, 1983De11, 1987Me17, 1990He18, 1990Sc08, +206HG5C 1990Hi03, 1996Sc06, 1999Br38, 2000He14, 2002Re18, 2002Ba85, 2003Br13, +206HG6C 2003Au03 +206HG T Auger electrons and ^X ray energies and emission intensities: +206HG T {U Energy (keV)} {U Intensity } {U Line } +206HG T +206HG T 68.895 XKA2 +206HG T 70.82 XKA1 +206HG T +206HG T 79.823 |] XKB3 +206HG T 80.254 |] XKB1 +206HG T 80.762 |] XKB5II +206HG T +206HG T 82.435 |] XKB2 +206HG T 82.776 |] XKB4 +206HG T 83.028 |] XKO23 +206HG T +210PB P 0.0 0+ 22.23 Y 12 3792 20 +206HG N 5.263E7 5.263E7 1.9E-08 5.263E7 +206HG L 0 0+ 8.32 M 7 +206HG A 3720 20100 211 + +210BI 210PB B- DECAY (22.23 Y) +210BI H TYP=Full$AUT=V. Chisté$CUT= -- $ +210BI C Evaluation history: Type=Full;Author=V. Chisté;Cutoff date= -- +210BI C References: 1951Bu37, 1953Wu28, 1954Da23, 1955To14, 1956St99, 1957To16, +210BI2C 1957Me47, 1957Fi06, 1958Kr71, 1958To10, 1959Pa03, 1959Ha02, 1960Ec01, +210BI3C 1961Nu01, 1962Ka27, 1963Im02, 1964Wo05, 1964Ra12, 1967Vo04, 1969Ho06, +210BI4C 1969Gr33, 1971Ge11, 1981He15, 1983De11, 1987Me17, 1990He18, 1990Sc08, +210BI5C 1990Hi03, 1996Sc06, 1999Br38, 2000He14, 2002Re18, 2002Ba85, 2003Br13, +210BI6C 2003Au03 +210BI T Auger electrons and ^X ray energies and emission intensities: +210BI T {U Energy (keV)} {U Intensity } {U Line } +210BI T +210BI T 74.8157 XKA2 +210BI T 77.1088 XKA1 +210BI T +210BI T 86.835 |] XKB3 +210BI T 87.344 |] XKB1 +210BI T 87.862 |] XKB5II +210BI T +210BI T 89.732 |] XKB2 +210BI T 90.074 |] XKB4 +210BI T 90.421 |] XKO23 +210BI T +210BI T 9.4207-15.7084 22.0 5 XL (total) +210BI T 9.4207 0.552 17 XLL +210BI T 10.7308-10.8387 10.30 29 XLA +210BI T 11.7127 0.0745 21 XLC +210BI T 12.4814-13.8066 9.05 13 XLB +210BI T 14.7735-15.7084 1.968 28 XLG +210BI T +210BI T 5.3-10.7 36.0 9 L AUGER +210PB P 0.0 0+ 22.23 Y 12 63.5 5 +210BI N 1.0 1.0 1 1.0 +210BI L 0 1- 5.012 D 5 +210BI B 63.5 5 19.8 13 7.8 1 +210BIS B EAV=16.3 1 +210BI L 46.539 1 0- 3 NS +210BI B 17.0 5 80.2 13 5.5 +210BIS B EAV=4.3 1 +210BI G 46.539 1 4.252 40M1 17.86 25 +210BI2 G KC=$LC=13.64 19$MC=3.21 5 + diff --git a/HEN_HOUSE/spectra/lnhb/Pb-211.txt b/HEN_HOUSE/spectra/lnhb/Pb-211.txt new file mode 100644 index 000000000..d9e6b68eb --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Pb-211.txt @@ -0,0 +1,98 @@ +211BI 211PB B- DECAY (36.1 M) +211BI H TYP=Full$AUT=F.G. Kondev$CUT=30-MAY-2011$ +211BI C Evaluation history: Type=Full;Author=F.G. Kondev;Cutoff date=30-MAY-2011 +211BI C References: 1939Sa11, 1962Gi03, 1963Va05, 1965Co06, 1965Me07, 1965Nu03, +211BI2C 1967Da10, 1967Da20, 1968Br17, 1968Go15, 1968Ha21, 1971Da34, 1971Go40, +211BI3C 1976Bl13, 1988Hi14, 1996Sc06, 1998ScZM, 1999ScZX, 2000Sc47, 2003Au03, +211BI4C 2003De44, 2004Br45, 2008DuZX, 2008Ki07, 2011Ko04 +211BI T Auger electrons and ^X ray energies and emission intensities: +211BI T {U Energy (keV)} {U Intensity } {U Line } +211BI T +211BI T 74.8157 0.228 10 XKA2 +211BI T 77.1088 0.381 17 XKA1 +211BI T +211BI T 86.835 |] XKB3 +211BI T 87.344 |] 0.130 6 XKB1 +211BI T 87.862 |] XKB5II +211BI T +211BI T 89.732 |] XKB2 +211BI T 90.074 |] 0.0399 20 XKB4 +211BI T 90.421 |] XKO23 +211BI T +211BI T 9.4207-15.7084 0.494 13 XL (total) +211BI T 9.4207 0.0120 5 XLL +211BI T 10.7308-10.8387 0.225 8 XLA +211BI T 11.7127 0.00330 15 XLC +211BI T 12.4814-13.8066 0.211 6 XLB +211BI T 14.7735-15.7084 0.0427 12 XLG +211BI T +211BI T 57.491-63.419 |] KLL AUGER +211BI T 70.025-77.105 |] 0.029 4 ^KLX AUGER +211BI T 82.53-90.52 |] KXY AUGER +211BI T 5.42-16.34 0.782 18 L AUGER +211PB P 0.0 9/2+ 36.1 M 2 1367 6 +211BI N 1.0 1.0 1 1.0 +211BI L 0 9/2- 2.15 M 2 +211BI B 1367 6 91.28 12 5.99 +211BIS B EAV=470.9 24 +211BI L 404.834 9 7/2- 0.317 NS 11 +211BI B 962 6 1.57 9 7.21 1U +211BIS B EAV=313.3 23 +211BI G 404.834 9 3.83 6 M1+E2 -1.1 1 0.122 8 +211BI2 G KC=0.095 7$LC=0.0206 8$MC=0.00499 17 +211BI L 766.680 13(9/2,11/2)- +211BI B 600 6 0.09 7.7 +211BIS B EAV=182.2 21 +211BI G 361.846 160.042 3 [M1E2] 0.17 11 +211BI2 G KC=0.14 10$LC=0.03 1$MC=0.0072 20 +211BI G 766.680 130.62 4 M1 0.0382 6 +211BI2 G KC=0.0313 5$LC=0.00527 8$MC=1234E-6 18 +211BI L 831.984 129/2- +211BI B 535 6 6.32 9 5.73 +211BIS B EAV=159.8 21 +211BI G 65.304 180.077 4 M1 6.61 10 +211BI2 G KC=$LC=5.05 7$MC=1.188 17 +211BI G 427.150 151.81 4 M1+E2 -0.022 9 0.1783 25 +211BI2 G KC=0.1457 21$LC=0.0249 4$MC=0.00585 9 +211BI G 831.984 123.50 5 M1+E2 0.4 2 0.028 3 +211BI2 G KC=0.0229 23$LC=0.0039 4$MC=0.00092 8 +211BI L 1014.38 4 (7/2,9/2,11/2)- +211BI G 609.55 4 0.033 9 +211BI G 1014.38 4 0.0173 5 +211BI L 1080.64 4 + +211BI B 286 6 0.0570 24 +211BIS B EAV=79.7 19 +211BI G 313.96 4 0.0268 21 +211BI G 675.81 4 0.0181 9 +211BI G 1080.64 4 0.0121 5 +211BI L 1103.52 20 + +211BI B 263 6 0.0047 7 +211BIS B EAV=72.8 18 +211BI G 1103.52 200.0047 7 +211BI L 1109.509 239/2- +211BI B 257 6 1.06 4 5.58 +211BIS B EAV=71.0 18 +211BI G 95.13 5 0.018 3 M1+E2 1.7 6 9.3 4 +211BI2 G KC=2.8 9$LC=4.8 5$MC=1.27 12 +211BI G 342.83 3 0.029 4 [M1E2] 0.20 12 +211BI2 G KC=0.16 11$LC=0.035 11$MC=0.0085 22 +211BI G 704.675 250.47 1 M1+E2 -0.022 7 0.0476 7 +211BI2 G KC=0.0390 6$LC=0.00657 10$MC=1540E-6 22 +211BI G 1109.509 230.116 3 [M1] 0.0147221 +211BI2 G KC=0.01209 17$LC=0.00201 3$MC=4.70E-4 7 +211BI L 1196.33 5 + +211BI B 171 6 0.019 4 +211BIS B EAV=45.6 18 +211BI G 429.65 6 0.008 3 +211BI G 1196.33 5 0.0103 4 +211BI L 1234.3 4 + +211BI B 133 6 0.0009 3 +211BIS B EAV=35.0 17 +211BI G 1234.3 4 0.0009 3 +211BI L 1270.75 6 (7/2,9/2,11/2)+ +211BI B 96 6 0.0172 15 5.93 2 +211BIS B EAV=25.0 17 +211BI G 504.07 6 0.0059 8 +211BI G 865.92 6 0.0046 2 +211BI G 1270.75 6 0.0068 12 + diff --git a/HEN_HOUSE/spectra/lnhb/Pb-212.txt b/HEN_HOUSE/spectra/lnhb/Pb-212.txt new file mode 100644 index 000000000..1501509e2 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Pb-212.txt @@ -0,0 +1,60 @@ +212BI 212PB B- DECAY (10.64 H) +212BI H TYP=Update$AUT=A.L. Nichols$CUT=30-MAY-2010$ +212BI2 H TYP=Full$AUT=A.L. Nichols$CUT=01-JAN-2004$ +212BI C Evaluation history: Type=Update;Author=A.L. Nichols;Cutoff date=30-MAY-2010 +212BI2C Type=Full;Author=A.L. Nichols;Cutoff date=01-JAN-2004 +212BI C References: 1948Ma30, 1952Bu72, 1953Ma26, 1955To11, 1957Kr49, 1957Ni11, +212BI2C 1959Se59, 1960Ro16, 1961Gi02, 1963Da11, 1969Kr06, 1972DaZA, 1973Da38, +212BI3C 1977La19, 1978Av01, 1982Sa36, 1983Va22, 1983Sc13, 1984Ge07, 1992Li05, +212BI4C 1996Sc06, 1999ScZM, 1999ScZX, 2002Ra45, 2002Ba85, 2003Au03, 2005Br03, +212BI5C 2008Ki07 +212BI T Auger electrons and ^X ray energies and emission intensities: +212BI T {U Energy (keV)} {U Intensity } {U Line } +212BI T +212BI T 74.8157 10.07 18 XKA2 +212BI T 77.1088 16.9 3 XKA1 +212BI T +212BI T 86.835 |] XKB3 +212BI T 87.344 |] 5.77 13 XKB1 +212BI T 87.862 |] XKB5II +212BI T +212BI T 89.732 |] XKB2 +212BI T 90.074 |] 1.77 5 XKB4 +212BI T 90.421 |] XKO23 +212BI T +212BI T 9.42-15.709 13.8 6 XL (total) +212BI T 9.42 0.340 9 XLL +212BI T 10.731-10.839 6.36 16 XLA +212BI T 11.712 0.103 3 XLC +212BI T 12.48-13.393 5.76 12 XLB +212BI T 15.248-15.709 1.111 23 XLG +212BI T +212BI T 57.49-63.42 |] KLL AUGER +212BI T 70.03-77.11 |] 1.29 15 ^KLX AUGER +212BI T 82.53-90.52 |] KXY AUGER +212BI T 5.35-10.66 21.4 7 L AUGER +212PB P 0.0 0+ 10.64 H 1 569.9 19 +212BI N 1.0 1.0 1 1.0 +212BI L 0 1- 60.54 M 6 +212BI B 569.9 1913.3 11 6.74 1 +212BIS B EAV=171.7 7 +212BI L 115.183 5 2- +212BI G 115.183 5 0.624 23[M1] 6.8 1 +212BI2 G KC=5.53 8$LC=0.972 14$MC=0.229 4 +212BI L 238.632 2 0- +212BI B 331.3 1981.7 11 5.18 +212BIS B EAV=93.5 6 +212BI G 123.449 5 0.052 5 [E2] 2.80 4 +212BI2 G KC=0.421 6$LC=1.766 25$MC=0.468 7 +212BI G 238.632 2 43.6 5 [M1] 0.872 13 +212BI2 G KC=0.71 1$LC=0.1232 18$MC=0.0290 4 +212BI L 415.272 111- +212BI B 154.6 194.99 21 5.35 1 +212BIS B EAV=41.1 5 +212BI G 176.640 110.052 5 [M1] 2.02 3 +212BI2 G KC=1.646 23$LC=0.287 4$MC=0.0675 10 +212BI G 300.089 123.18 14[M1] 0.464 7 +212BI2 G KC=0.378 6$LC=0.0653 10$MC=0.01534 22 +212BI G 415.272 110.144 22[M1] 0.192 3 +212BI2 G KC=0.1571 22$LC=0.0269 4$MC=0.00632 9 + diff --git a/HEN_HOUSE/spectra/lnhb/Pb-214.txt b/HEN_HOUSE/spectra/lnhb/Pb-214.txt new file mode 100644 index 000000000..dd7091b04 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Pb-214.txt @@ -0,0 +1,100 @@ +214BI 214PB B- DECAY (26.916 M) +214BI H TYP=update$AUT=V.Chisté$CUT= -- $ +214BI2 H TYP=Full$AUT=V.Chisté$CUT= -- $ +214BI C Evaluation history: Type=update;Author=V.Chisté;Cutoff date= -- +214BI2C Type=Full;Author=V.Chisté;Cutoff date= -- +214BI C References: 1931Cu03, 1952Be78, 1953Sa40, 1957Ni11, 1956Da28, 1964Ew04, +214BI2C 1969Li10, 1969Wa27, 1969Gr33, 1970Mo28, 1975Ha31, 1977Zo01, 1978Ro22, +214BI3C 1981Mo28, 1982Ak03, 1982Fa10, 1983Ol01, 1983Sc13, 1984Pe13, 1988Ak01, +214BI4C 1990Mo08, 1991Li11, 1993Di09, 1995El07, 1996Sc06, 1998Mo14, 2000Sa32, +214BI5C 2002De03, 2002MoZP, 2002Ba85, 2003Au03, 2004Mo07, 2007BeZP +214BI T Auger electrons and ^X ray energies and emission intensities: +214BI T {U Energy (keV)} {U Intensity } {U Line } +214BI T +214BI T 74.8157 6.26 12 XKA2 +214BI T 77.1088 10.47 20 XKA1 +214BI T +214BI T 86.835 |] XKB3 +214BI T 87.344 |] 3.59 9 XKB1 +214BI T 87.862 |] XKB5II +214BI T +214BI T 89.732 |] XKB2 +214BI T 90.074 |] 1.10 4 XKB4 +214BI T 90.421 |] XKO23 +214BI T +214BI T 9.42-16.36 12.42 22 XL (total) +214BI T 9.42 0.311 9 XLL +214BI T 10.45-10.55 5.80 15 XLA +214BI T 11.35 0.0770 21 XLC +214BI T 12.13-13.38 5.18 9 XLB +214BI T 14.31-16.36 1.039 18 XLG +214BI T +214BI T 57.49-63.42 |] KLL AUGER +214BI T 70.02-77.1 |] 0.80 9 ^KLX AUGER +214BI T 82.45-90.52 |] KXY AUGER +214BI T 5.3-16.4 19.8 3 L AUGER +214PB P 0.0 0+ 26.916 M 44 1019 11 +214BI N 1.0 1.0 1 1.0 +214BI G 107.22 9 0.0068 14 +214BI G 137.45 300.045 18 +214BI G 141.3 6 0.027 14 +214BI G 170.07 6 0.0146 27 +214BI G 216.47 7 0.0100 23 +214BI G 765.96 9 0.053 8 +214BI L 0 1- 19.8 M 1 +214BI B 1019 119.2 7 6.3 1 +214BIS B EAV=337 4 +214BI L 53.2275 21(2)- 0.52 NS 15 +214BI G 53.2275 211.060 7 M1+E2 0.03 1 12.88 39 +214BI2 G KC=$LC=9.80 29$MC=2.32 7 +214BI L 62.7 1 + +214BI L 258.87 3 (2)- +214BI G 196.20 5 0.069 9 +214BI G 205.68 9 0.0114 23 +214BI G 258.87 3 0.5318 36M1 0.737 22 +214BI2 G KC=0.601 18$LC=0.1037 31$MC=0.0244 7 +214BI L 295.224 2 1- +214BI B 724 1141.09 39 5.2 1 +214BIS B EAV=227 4 +214BI G 241.997 3 7.268 22M1(+E2) 0.00 15 0.888 27 +214BI2 G KC=0.724 22$LC=0.1250 38$MC=0.0295 9 +214BI G 295.224 2 18.414 36M1+E2 0.30 13 0.482 14 +214BI2 G KC=0.390 12$LC=0.0698 21$MC=0.0165 5 +214BI L 351.932 2 (0,1)- +214BI B 667 1146.52 37 5.1 +214BIS B EAV=207 4 +214BI G 351.932 2 35.60 7 M1(+E2) 0.00 35 0.319 10 +214BI2 G KC=0.260 8$LC=0.0445 13$MC=0.01049 31 +214BI L 377.03 4 - +214BI G 314.32 7 0.077 6 +214BI G 323.83 4 0.0287 32 +214BI L 533.67 2 (1)- +214BI B 485 111.047 17 6.2 1 +214BIS B EAV=145 4 +214BI G 274.80 5 0.362 10M1+E2 1 0.392 12 +214BI2 G KC=0.295 9$LC=0.0731 22$MC=0.0179 5 +214BI G 480.43 2 0.3371 41M1(+E2) 0 1 0.1384 42 +214BI2 G KC=0.1132 34$LC=0.0192 6$MC=0.00452 14 +214BI G 533.66 2 0.182 6 [M1E2] 0.06 4 +214BI2 G KC=0.05 3$LC=0.010 4$MC=0.0023 9 +214BI L 797.24 9 + +214BI B 222 110.0196 27 6.9 +214BIS B EAV=62 3 +214BI G 538.41 8 0.0196 27 +214BI L 839.00 4 1+ +214BI B 180 112.762 22 4.5 +214BIS B EAV=50 3 +214BI G 305.26 3 0.0315 21[E1] 0.0295 9 +214BI2 G KC=0.0241 7$LC=0.00413 12$MC=9.71E-4 29 +214BI G 462.00 7 0.213 6 +214BI G 487.09 7 0.433 6 (E1) 0.0105832 +214BI2 G KC=0.00871 26$LC=1423E-6 43$MC=3.33E-4 10 +214BI G 543.81 7 0.050 9 E1+M2 0.0084325 +214BI2 G KC=0.00696 21$LC=1124E-6 34$MC=2.62E-4 8 +214BI G 580.13 3 0.369 6 (E1) 0.0074022 +214BI2 G KC=0.00611 18$LC=9.81E-4 29$MC=2.29E-4 7 +214BI G 785.96 9 1.064 13E1 0.0041012 +214BI2 G KC=0.00341 10$LC=5.33E-4 16$MC=1239E-7 37 +214BI G 839.04 9 0.587 8 (E1) 0.0036311 +214BI2 G KC=0.00302 9$LC=4.70E-4 14$MC=1092E-7 33 + diff --git a/HEN_HOUSE/spectra/lnhb/Pd-109.txt b/HEN_HOUSE/spectra/lnhb/Pd-109.txt new file mode 100644 index 000000000..43d7fee1d --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Pd-109.txt @@ -0,0 +1,150 @@ +109AG 109PD B- DECAY (13.58 H) +109AG H TYP=Full$AUT=A.L. Nichols$CUT=30-JAN-2009$ +109AG C Evaluation history: Type=Full;Author=A.L. Nichols;Cutoff date=30-JAN-2009 +109AG C References: 1940Al01, 1941He03, 1945Br06, 1945Wi11, 1946Br07, 1947Br05, +109AG2C 1951Wo15, 1953Av25, 1953Nu04, 1954Mo38, 1957Wa05, 1957Ma16, 1957Wa05, +109AG3C 1958Gu09, 1959St28, 1962Br15, 1962Ec02, 1966Mi11, 1967Ab07, 1967Bl08, +109AG4C 1968Be22, 1968Gr02, 1968BaZY, 1969Sc12, 1970Bo22, 1970Ba37, 1970Fo01, +109AG5C 1970Ro14, 1973Co10, 1975El10, 1977Bo04, 1977Gi11, 1978Pr08, 1983Ch42, +109AG6C 1990Ab06, 1996Sc06, 1998ScZM, 1999ScZX, 2000He14, 2002Ba25, 2002Ra45, +109AG7C 2003Au03, 2006Bl02, 2008Ki07 +109AG T Auger electrons and ^X ray energies and emission intensities: +109AG T {U Energy (keV)} {U Intensity } {U Line } +109AG T +109AG T 21.9906 9.92 23 XKA2 +109AG T 22.16317 18.7 5 XKA1 +109AG T +109AG T 24.9118 |] XKB3 +109AG T 24.9427 |] 5.18 13 XKB1 +109AG T 25.146 |] XKB5II +109AG T +109AG T 25.4567 |] XKB2 +109AG T 25.512 |] 0.90 4 XKB4 +109AG T +109AG T 2.634-3.75 4.92 13 XL (total) +109AG T 2.634 0.101 4 XLL +109AG T 2.978-2.984 2.71 10 XLA +109AG T 2.806 0.0460 12 XLC +109AG T 3.151-3.348 1.91 6 XLB +109AG T 3.52-3.75 0.184 5 XLG +109AG T +109AG T 17.79-18.69 |] KLL AUGER +109AG T 20.945-22.16 |] 7.06 23 ^KLX AUGER +109AG T 24.079-25.507 |] KXY AUGER +109AG T 1.9-3.8 79.5 5 L AUGER +109PD P 0.0 5/2+ 13.58 H 12 1116.1 20 +109AG N 1.0 1.0 1 1.0 +109AG L 0 1/2- STABLE +109AG L 88.0341 117/2+ 39.7 S 2 +109AG B 1028.1 2099.891 3 6.134 2 +109AGS B EAV=361.0 8 +109AG G 88.03360 103.66 6 E3 26.33 40 +109AG2 G KC=11.41 16$LC=12.06 17$MC=2.47 4 +109AG L 132.74 119/2+ +109AG G 44.7 1 0.00121 15M1+E2 0.533 1 9.00 15 +109AG2 G KC=5.69 9$LC=2.69 5$MC=0.533 10 +109AG L 311.38 8 3/2- +109AG B 804.7 200.0191 22 9.46 1U +109AGS B EAV=270.3 8 +109AG G 311.4 1 0.0314 21M1+E2 0.220 3 0.0201 3 +109AG2 G KC=0.01749 25$LC=0.00213 3$MC=4.05E-4 6 +109AG L 415.21 165/2- +109AG B 700.9 200.0063 2 9.73 +109AGS B EAV=229.7 8 +109AG G 103.8 2 0.00070 11M1+E2 -0.045 0.379 7 +109AG2 G KC=0.329 6$LC=0.0411 7$MC=0.00783 13 +109AG G 327.2 2 1.31E-4 15E1 0.005829 +109AG2 G KC=0.00509 8$LC=5.99E-4 9$MC=1133E-7 17 +109AG G 415.2 2 0.0109 6 E2 0.0109816 +109AG2 G KC=0.00944 14$LC=1257E-6 18$MC=2.40E-4 4 +109AG L 697.8 4 (5/2)+ +109AG B 418.3 200.00016 7 10.55 +109AGS B EAV=125.9 7 +109AG G 565.1 5 1.08E-4 14(E2) 0.004467 +109AG2 G KC=0.00386 6$LC=4.89E-4 7$MC=9.31E-5 14 +109AG G 609.8 4 0.00018 6 (M1+E2) +109AG L 701.91 153/2- +109AG B 414.2 200.00460 21 9.08 1U +109AGS B EAV=124.5 7 +109AG G 286.7 3 1.76E-4 16M1+E2 0.199 3 0.0248 4 +109AG2 G KC=0.0216 3$LC=0.00264 4$MC=5.01E-4 8 +109AG G 390.5 2 0.00093 7 M1+E2 0.190 3 0.0112416 +109AG2 G KC=0.00980 14$LC=1178E-6 17$MC=2.24E-4 4 +109AG G 701.9 2 0.00347 20M1+E2 0.029 2 0.002734 +109AG2 G KC=0.00239 4$LC=2.80E-4 4$MC=5.31E-5 8 +109AG L 707.00 17(3/2)+ +109AG B 409.1 200.00178 12 9.47 2 +109AGS B EAV=122.8 7 +109AG G 395.6 3 6.8E-5 13(E1) 0.003575 +109AG2 G KC=0.00312 5$LC=3.66E-4 6$MC=6.92E-5 10 +109AG G 707.0 2 0.00171 12(E1) 9.21E-413 +109AG2 G KC=8.07E-4 12$LC=9.33E-5 13$MC=1762E-8 25 +109AG L 724.35 10(3/2)+ 3.2 NS 8 +109AG B 391.8 200.0204 9 8.351 2 +109AGS B EAV=116.8 7 +109AG G 309.1 3 0.00413 23(E1) 0.0067710 +109AG2 G KC=0.00591 9$LC=6.97E-4 10$MC=1317E-7 19 +109AG G 413.0 2 0.0068 7 (E1+(M2)) 0.179 4 0.004208 +109AG2 G KC=0.00366 7$LC=4.42E-4 8$MC=8.39E-5 16 +109AG G 636.3 1 0.0101 6 (E2) 0.003235 +109AG2 G KC=0.00281 4$LC=3.50E-4 5$MC=6.65E-5 10 +109AG G 724.4 1 0.00025 3 (E1) 8.74E-413 +109AG2 G KC=7.66E-4 11$LC=8.85E-5 13$MC=1672E-8 24 +109AG L 735.29 9 5/2+ +109AG B 380.8 200.0334 15 8.096 +109AGS B EAV=113.1 7 +109AG G 423.9 2 0.00093 7 E1(+M2) 0.270 2 0.005028 +109AG2 G KC=0.00436 7$LC=5.36E-4 9$MC=1020E-7 16 +109AG G 602.6 2 0.0086 6 E2 0.003746 +109AG2 G KC=0.00324 5$LC=4.07E-4 6$MC=7.74E-5 11 +109AG G 647.3 1 0.0252 14M1+E2 +109AG L 812.0 5 (3/2)+ +109AG B 304.1 2110800E-824 10.3 2 +109AGS B EAV=87.7 7 +109AG G 114.2 9 6.3E-5 21(M1+E2) +109AG G 500.6 6 4.5E-5 11(E1) 0.002013 +109AG2 G KC=1756E-6 25$LC=2.05E-4 3$MC=3.87E-5 6 +109AG L 862.76 205/2- +109AG B 253.3 200.00167 10 8.82 +109AGS B EAV=71.5 6 +109AG G 447.6 4 0.00086 7 M1+E2 0.160 4 0.0080012 +109AG2 G KC=0.00698 10$LC=8.33E-4 12$MC=1580E-7 23 +109AG G 551.4 3 0.00065 7 M1+E2 0.280 3 0.004827 +109AG2 G KC=0.00420 6$LC=5.00E-4 7$MC=9.48E-5 14 +109AG G 862.8 2 1.48E-4 20E2 0.001512 +109AG2 G KC=1313E-6 19$LC=1583E-7 23$MC=3.00E-5 5 +109AG L 869.47 115/2+ +109AG B 246.6 200.0194 9 7.72 +109AGS B EAV=69.4 6 +109AG G 134.2 2 0.00111 10M1+E2 0.150 4 0.192 3 +109AG2 G KC=0.1658 25$LC=0.0212 4$MC=0.00404 6 +109AG G 145.1 2 0.00083 7 (M1+E2) 0.132 5 0.153 2 +109AG2 G KC=0.1326 20$LC=0.01670 25$MC=0.00318 5 +109AG G 454.3 3 0.00050 4 E1 0.002534 +109AG2 G KC=0.00222 4$LC=2.59E-4 4$MC=4.90E-5 7 +109AG G 558.1 2 0.00249 17E1(+M2) 0.260 3 0.002384 +109AG2 G KC=0.00207 4$LC=2.49E-4 4$MC=4.73E-5 8 +109AG G 736.7 2 0.00181 13E2 0.002214 +109AG2 G KC=0.00193 3$LC=2.36E-4 4$MC=4.48E-5 7 +109AG G 781.4 1 0.0123 9 M1+E2 +109AG G 869.5 1 5.3E-5 16M2(+E3) 0.004276 +109AG2 G KC=0.00372 6$LC=4.53E-4 7$MC=8.62E-5 13 +109AG L 911.0 4 7/2+ +109AG B 205.1 200.00166 17 8.53 2 +109AGS B EAV=56.7 6 +109AG G 778.3 5 0.00148 17M1+E2 +109AG G 823.0 4 1.81E-4 18M1+E2 +109AG L 912.1 8 7/2- +109AG B 204.0 2274000E-914 9.87 1U +109AGS B EAV=56.3 7 +109AG G 496.9 107.3E-5 14M1+E2 0.199 3 0.0062 1 +109AG2 G KC=0.00541 8$LC=6.44E-4 10$MC=1222E-7 18 +109AG L 1098.5 2 5/2, 7/2+ +109AG B 17.6 200.00018 3 6.22 +109AGS B EAV=4.5 5 +109AG G 400.7 6 6.3E-5 23(M1+E2) +109AG G 787.1 3 2.16E-5 18(E1) 7.35E-411 +109AG2 G KC=6.44E-4 9$LC=7.43E-5 11$MC=1403E-8 20 +109AG G 965.8 3 6.8E-5 11 +109AG G 1010.5 2 3.0E-5 6 + diff --git a/HEN_HOUSE/spectra/lnhb/Pm-147.txt b/HEN_HOUSE/spectra/lnhb/Pm-147.txt new file mode 100644 index 000000000..a33b085b3 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Pm-147.txt @@ -0,0 +1,61 @@ +147SM 147PM B- DECAY (2.6234 Y) +147SM H TYP=Full$AUT=V. Chisté$CUT=30-MAY-2011$ +147SM2 H TYP=update$AUT=V. Chisté$CUT= -- $ +147SM3 H TYP=update$AUT=V. Chisté$CUT= -- $ +147SM4 H TYP=update$AUT=V. Chisté$CUT= -- $ +147SM5 H TYP=update$AUT=V. Chisté$CUT= -- $ +147SM6 H TYP=update$AUT=V. Chisté$CUT= -- $ +147SM7 H TYP=update$AUT=V. Chisté$CUT= -- $ +147SM C Evaluation history: Type=Full;Author=V. Chisté;Cutoff date=30-MAY-2011 +147SM2C Type=update;Author=V. Chisté;Cutoff date= -- +147SM3C Type=update;Author=V. Chisté;Cutoff date= -- +147SM4C Type=update;Author=V. Chisté;Cutoff date= -- +147SM5C Type=update;Author=V. Chisté;Cutoff date= -- +147SM6C Type=update;Author=V. Chisté;Cutoff date= -- +147SM7C Type=update;Author=V. Chisté;Cutoff date= -- +147SM C References: 1934Li03, 1936Ho**, 1946Cu**, 1949Pi**, 1954Be69, 1955Me52, +147SM2C 1956La17, 1956Le55, 1956Sc87, 1957Me47, 1957St05, 1958Be78, 1958An36, +147SM3C 1959Ca12, 1960Ka23, 1960Ka**, 1961Wy01, 1961Wr02, 1961Ma05, 1962Sc09, +147SM4C 1963Ro20, 1962Al19, 1964Do01, 1965Va16, 1965Fl02, 1965Ei04, 1965An07, +147SM5C 1965Wh04, 1966Go26, 1966Av02, 1967Jo07, 1968Re04, 1969Ba33, 1970Mo02, +147SM6C 1970Gu14, 1970Va38, 1971Be53, 1971Mc09, 1973HaXY, 1987Al28, 1989Ad10, +147SM7C 1990Sc08, 1992Ma56, 1996Sc06, 2001Be81, 2003Au03, 2003Ki26, 2008Ki07, +147SM8C 2009Ko15, 2009Ni02 +147SM T Auger electrons and ^X ray energies and emission intensities: +147SM T {U Energy (keV)} {U Intensity } {U Line } +147SM T +147SM T 39.5229 0.000583 16 XKA2 +147SM T 40.1186 0.001055 29 XKA1 +147SM T +147SM T 45.289 |] XKB3 +147SM T 45.413 |] 0.00033 1 XKB1 +147SM T 45.731 |] XKB5II +147SM T +147SM T 46.575 |] XKB2 +147SM T 46.705 |] 0.0000851 30 XKB4 +147SM T 46.813 |] XKO23 +147SM T +147SM T 4.991-7.487 0.000369 8 XL (total) +147SM T 4.991 0.00000720 24 XLL +147SM T 5.609-5.638 0.000177 6 XLA +147SM T 5.586 0.00000281 9 XLC +147SM T 6.193-6.656 0.000156 4 XLB +147SM T 6.964-7.487 0.0000254 7 XLG +147PM P 0.0 7/2+ 2.6234 Y 4 224.1 3 +147SM N 1.0 1.0 1 1.0 +147SM L 0 7/2- 107.9E9 Y 12 +147SM B 224.1 3 99995E-313 7.4 +147SMS B EAV=61.8 1 +147SM L 121.223 125/2- 0.798 NS 17 +147SM B 102.9 3 0.00542 13 10.6 1U +147SMS B EAV=26.9 1 +147SM G 121.223 120.00272 6 M1+E2 -0.317 19000 0.994 14 +147SM2 G KC=0.815 12$LC=0.141 4$MC=0.0308 8 +147SM L 197.298 113/2- 1.25 NS 3 +147SM B 26.8 3 40000E-17 12.1 3U +147SMS B EAV=6.9 1 +147SM G 76.073 101.1E-8 2 M1+E2 0.655 34 4.53 9 +147SM2 G KC=2.91 5$LC=1.26 7$MC=0.288 15 +147SM G 197.298 113.3E-7 5 E2 0.218 3 +147SM2 G KC=0.1565 22$LC=0.0482 7$MC=0.01092 16 + diff --git a/HEN_HOUSE/spectra/lnhb/Pm-148.txt b/HEN_HOUSE/spectra/lnhb/Pm-148.txt new file mode 100644 index 000000000..dc1ca7b6b --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Pm-148.txt @@ -0,0 +1,111 @@ +148SM 148PM B- DECAY (5.370 D) +148SM H TYP=FULL$AUT=M.A.Kellett$CUT=05-JUN-2013$ +148SM C Evaluation history: Type=FULL;Author=M.A.Kellett;Cutoff date=05-JUN-2013 +148SM C References: 1943Ku**, 1947Pa**, 1948Se40, 1951Fo**, 1952Ki25, 1952Lo01, +148SM2C 1955Fo18, 1955He64, 1955Ma77, 1959Ei31, 1959Bh95, 1960Sc09, 1959Ei31, +148SM3C 1960Sc12, 1961Br41, 1961El02, 1962Gr34, 1962Re03, 1962Sc04, 1963Ew01, +148SM4C 1963Al22, 1963Ba06, 1963Ba31, 1963Ba32, 1963Gr10, 1964Ha17, 1964Ke03, +148SM5C 1965Al16, 1967Cl05, 1968Wy02, 1970Ca09, 1970FoZZ, 1970FoZZ, 1970GrYP, +148SM6C 1971Ca23, 1970Pe22, 1971Sh08, 1971Mo04, 1972AmZX, 1974LoZL, 1974DuZO, +148SM7C 1977Ka14, 1977La19, 1979Dz07, 1984LaZZ, 1988No02, 1989Le01, 1996Sc06, +148SM8C 1996FiZX, 1998ScZM, 1999ScZX, 2000Bh03, 2000Sc47, 2008DuZX, 2008Ki07, +148SM9C 2012Wa38 +148SM T Auger electrons and ^X ray energies and emission intensities: +148SM T {U Energy (keV)} {U Intensity } {U Line } +148SM T +148SM T 39.5229 0.0581 16 XKA2 +148SM T 40.1186 0.1051 28 XKA1 +148SM T +148SM T 45.289 |] XKB3 +148SM T 45.413 |] 0.0328 10 XKB1 +148SM T 45.731 |] XKB5II +148SM T +148SM T 46.575 |] XKB2 +148SM T 46.705 |] 0.00847 30 XKB4 +148SM T 46.813 |] XKO23 +148SM T +148SM T 4.9909-7.4871 0.0363 8 XL (total) +148SM T 4.9909 0.000709 24 XLL +148SM T 5.6088-5.6376 0.0174 6 XLA +148SM T 5.586 0.000277 9 XLC +148SM T 6.1928-6.6557 0.0154 4 XLB +148SM T 6.9644-7.4871 0.00249 6 XLG +148SM T +148SM T 31.19-33.218 |] KLL AUGER +148SM T 37.302-40.097 |] 0.0163 10 ^KLX AUGER +148SM T 43.39-46.79 |] KXY AUGER +148SM T 3.27-7.69 0.1883 16 L AUGER +148PM P 0.0 1- 5.370 D 15 2471 6 +148SM N 1.0 1.0 1 1.0 +148SM L 0 0+ STABLE +148SM B 2471 6 55.5 7 9.1 1 +148SMS B EAV=977.7 28 +148SM L 550.274 172+ +148SM B 1921 6 9.3 6 9.5 1 +148SMS B EAV=731.6 27 +148SM G 550.27 3 22.5 6 E2 0.0099814 +148SM2 G KC=0.00825 12$LC=1360E-6 19$MC=2.96E-4 5 +148SM L 1161.537 243- +148SM G 611.26 3 1.04 4 E1+M2 0.026 13 0.002795 +148SM2 G KC=0.00239 5$LC=3.15E-4 6$MC=6.70E-5 13 +148SM L 1424.46 4 0+ +148SM B 1047 6 0.236 9 10.1 1 +148SMS B EAV=359.1 25 +148SM G 874.18 3 0.24 1 E2 0.003325 +148SM2 G KC=0.00280 4$LC=4.06E-4 6$MC=8.74E-5 13 +148SM L 1454.217 232+ +148SM B 1017 6 0.093 3 10.4 1 +148SMS B EAV=347.1 25 +148SM G 903.94 3 0.042 2 M1+E2 2.32 10 0.003396 +148SM2 G KC=0.00287 5$LC=4.06E-4 7$MC=8.72E-5 14 +148SM G 1454.21 3 0.0511 25E2 1230E-618 +148SM2 G KC=1000E-6 14$LC=1338E-7 19$MC=2.86E-5 4 +148SM L 1465.129 191- +148SM B 1006 6 33.3 6 7.8 +148SMS B EAV=342.7 24 +148SM G 303.59 3 0.0377 45E2 0.0542 8 +148SM2 G KC=0.0423 6$LC=0.00931 13$MC=0.00207 3 +148SM G 914.85 3 12.0 5 E1 1221E-617 +148SM2 G KC=1050E-6 15$LC=1354E-7 19$MC=2.88E-5 4 +148SM G 1465.12 3 22.2 5 E1 7.04E-410 +148SM2 G KC=4.49E-4 7$LC=5.70E-5 8$MC=1208E-8 17 +148SM L 1664.160 212+ +148SM B 807 6 0.018 3 10.8 1 +148SMS B EAV=264.4 23 +148SM G 1113.88 3 0.0222 23M1+E2 -0.565 21 0.002795 +148SM2 G KC=0.00239 4$LC=3.19E-4 5$MC=6.81E-5 10 +148SM G 1664.15 3 0.0113 11E2 1042E-615 +148SM2 G KC=7.75E-4 11$LC=1024E-7 15$MC=2.18E-5 3 +148SM L 1921.58 200+ +148SM B 549 6 0.0138 14 10.3 1 +148SMS B EAV=169.0 22 +148SM G 1371.3 2 0.0138 14E2 1347E-619 +148SM2 G KC=1119E-6 16$LC=1507E-7 22$MC=3.22E-5 5 +148SM L 2057.961 222- +148SM B 413 6 1.360 22 7.9 +148SMS B EAV=121.9 21 +148SM G 393.80 3 0.0155 22E1 0.0075211 +148SM2 G KC=0.00643 9$LC=8.62E-4 12$MC=1.84E-4 3 +148SM G 592.83 3 0.35 1 M1 0.0140420 +148SM2 G KC=0.01198 17$LC=1621E-6 23$MC=3.47E-4 5 +148SM G 896.42 3 0.98 2 M1+E2 1.32 9 0.003869 +148SM2 G KC=0.00328 8$LC=4.56E-4 10$MC=9.77E-5 20 +148SM G 1507.68 3 0.0056 9 E1 7.11E-410 +148SM2 G KC=4.28E-4 6$LC=5.42E-5 8$MC=1150E-8 17 +148SM L 2284.405 211- +148SM B 187 6 0.0965 34 7.9 +148SMS B EAV=50.7 18 +148SM G 819.27 3 0.0133 22M1 0.006359 +148SM2 G KC=0.00542 8$LC=7.26E-4 11$MC=1551E-7 22 +148SM G 1734.12 3 0.0386 11E1 7.77E-411 +148SM2 G KC=3.39E-4 5$LC=4.28E-5 6$MC=9.07E-6 13 +148SM G 2284.39 3 0.0444 24E1 1027E-615 +148SM2 G KC=2.19E-4 3$LC=2.74E-5 4$MC=5.81E-6 9 +148SM L 2314.01 152+ +148SM B 157 6 0.0091 15 8.7 1 +148SMS B EAV=42.1 18 +148SM G 1152.5 2 0.0029 13E1+M2 -0.10 9 0.0008615 +148SM2 G KC=0.00073 13$LC=9.5E-5 18$MC=2.0E-5 4 +148SM G 1763.7 2 0.0062 7 M1+E2 2.2 5 0.001043 +148SM2 G KC=7.32E-4 22$LC=9.6E-5 3$MC=2.05E-5 6 + diff --git a/HEN_HOUSE/spectra/lnhb/Pm-148m.txt b/HEN_HOUSE/spectra/lnhb/Pm-148m.txt new file mode 100644 index 000000000..1a3f93ac5 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Pm-148m.txt @@ -0,0 +1,143 @@ +148PM 148PM IT DECAY (41.29 D) +148PM H TYP=FULL$AUT=M.A.Kellett$CUT=05-JUN-2013$ +148PM C Evaluation history: Type=FULL;Author=M.A.Kellett;Cutoff date=05-JUN-2013 +148PM C References: 1951Fo**, 1952Ki25, 1952Lo01, 1955Ma77, 1955He64, 1955Fo18, +148PM2C 1959Ei31, 1959Bh95, 1960Sc09, 1959Ei31, 1960Sc12, 1961El02, 1961Ha23, +148PM3C 1961Br41, 1962Re03, 1962Sc04, 1962Gr34, 1963Ku09, 1963Ba31, 1963Ba32, +148PM4C 1963Ba06, 1963Ew01, 1963Gr10, 1967Cl05, 1968Wy02, 1970GrYP, 1970FoZZ, +148PM5C 1970Gr09, 1969Gr32, 1970FoZZ, 1971Mo04, 1971Wa05, 1971BaZW, 1974DuZO, +148PM6C 1977La19, 1977Ka14, 1984LaZZ, 1988No02, 1989Le01, 1996FiZX, 1996Sc06, +148PM7C 1998ScZM, 1999ScZX, 2000Bh03, 2000Sc47, 2008DuZX, 2008Ki07, 2012Wa38 +148PM T Auger electrons and ^X ray energies and emission intensities: +148PM T {U Energy (keV)} {U Intensity } {U Line } +148PM T +148PM T 38.1716 0.96 6 XKA2 +148PM T 38.7251 1.75 11 XKA1 +148PM T +148PM T 43.713 |] XKB3 +148PM T 43.826 |] 0.54 4 XKB1 +148PM T 44.145 |] XKB5II +148PM T +148PM T 44.937 |] XKB2 +148PM T 45.064 |] 0.139 9 XKB4 +148PM T 45.162 |] XKO23 +148PM T +148PM T 4.81-7.1893 1.20 4 XL (total) +148PM T 4.81 0.0223 10 XLL +148PM T 5.4061-5.4325 0.554 22 XLA +148PM T 5.363 0.0107 5 XLC +148PM T 5.9552-6.3985 0.526 20 XLB +148PM T 6.6814-7.1893 0.083 4 XLG +148PM T +148PM T 30.162-32.086 |] KLL AUGER +148PM T 36.035-38.703 |] 0.287 23 ^KLX AUGER +148PM T 41.88-45.14 |] KXY AUGER +148PM T 3.16-7.38 6.59 10 L AUGER +148PM P 137 3 6- 41.29 D 13 +148PM N 1.786E1 1.786E1 0.056 5 1.786E1 +148PM L 0 1- 5.370 D 15 +148PM L 75.8 2- +148PM G 75.8 1 1.27 20M1 3.4 5 +148PM2 G KC=2.9 4$LC=0.41 6$MC=0.088 11 +148PM L 137.1 306- 41.29 D 13 +148PM G 61.30 5 0.00040 17E4 1.4E4 6 +148PM2 G KC=30 5$LC=1.0E4 4$MC=2.9E3 12 + +148SM 148PM B- DECAY (41.29 D) +148SM H TYP=FULL$AUT=M.A.Kellett$CUT=05-JUN-2013$ +148SM C Evaluation history: Type=FULL;Author=M.A.Kellett;Cutoff date=05-JUN-2013 +148SM C References: 1951Fo**, 1952Ki25, 1952Lo01, 1955Ma77, 1955He64, 1955Fo18, +148SM2C 1959Ei31, 1959Bh95, 1960Sc09, 1959Ei31, 1960Sc12, 1961El02, 1961Ha23, +148SM3C 1961Br41, 1962Re03, 1962Sc04, 1962Gr34, 1963Ku09, 1963Ba31, 1963Ba32, +148SM4C 1963Ba06, 1963Ew01, 1963Gr10, 1967Cl05, 1968Wy02, 1970GrYP, 1970FoZZ, +148SM5C 1970Gr09, 1969Gr32, 1970FoZZ, 1971Mo04, 1971Wa05, 1971BaZW, 1974DuZO, +148SM6C 1977La19, 1977Ka14, 1984LaZZ, 1988No02, 1989Le01, 1996FiZX, 1996Sc06, +148SM7C 1998ScZM, 1999ScZX, 2000Bh03, 2000Sc47, 2008DuZX, 2008Ki07, 2012Wa38 +148SM T Auger electrons and ^X ray energies and emission intensities: +148SM T {U Energy (keV)} {U Intensity } {U Line } +148SM T +148SM T 39.5229 1.92 11 XKA2 +148SM T 40.1186 3.47 19 XKA1 +148SM T +148SM T 45.289 |] XKB3 +148SM T 45.413 |] 1.09 6 XKB1 +148SM T 45.731 |] XKB5II +148SM T +148SM T 46.575 |] XKB2 +148SM T 46.705 |] 0.280 17 XKB4 +148SM T 46.813 |] XKO23 +148SM T +148SM T 4.9909-7.4871 1.20 4 XL (total) +148SM T 4.9909 0.0234 12 XLL +148SM T 5.6088-5.6376 0.576 27 XLA +148SM T 5.586 0.0091 5 XLC +148SM T 6.1928-6.6557 0.508 19 XLB +148SM T 6.9644-7.4871 0.082 4 XLG +148SM T +148SM T 31.19-33.218 |] KLL AUGER +148SM T 37.302-40.097 |] 0.54 5 ^KLX AUGER +148SM T 43.39-46.79 |] KXY AUGER +148SM T 3.27-7.69 6.23 10 L AUGER +148PM P 137 3 6- 41.29 D 13 2471 7 +148SM N 1.059E0 1.059E0 0.944 5 1.059E0 +148SM L 0 0+ STABLE +148SM L 550.27 3 2+ +148SM G 550.27 3 93.5 14E2 0.0099814 +148SM2 G KC=0.00825 12$LC=1360E-6 19$MC=2.96E-4 5 +148SM L 1161.53 4 3- +148SM G 611.26 3 5.6 2 E1 0.002774 +148SM2 G KC=0.00237 4$LC=3.12E-4 5$MC=6.63E-5 10 +148SM L 1180.24 4 4+ +148SM G 629.97 3 87.8 14E2 0.0071 1 +148SM2 G KC=0.00591 9$LC=9.32E-4 13$MC=2.02E-4 3 +148SM L 1594.31 4 5- +148SM B 1014 6 0.93 45 10.29 +148SMS B EAV=345.9 31 +148SM G 414.07 3 18.35 33E1+M2 -0.013 10 0.0067011 +148SM2 G KC=0.00572 9$LC=7.66E-4 13$MC=1.63E-4 3 +148SM G 432.78 3 5.19 13E2 0.0190 3 +148SM2 G KC=0.01544 22$LC=0.00281 4$MC=6.17E-4 9 +148SM L 1733.48 4 4+ +148SM G 553.24 3 0.35 4 M1+E2 1.66 20 0.0117 4 +148SM2 G KC=0.0098 4$LC=0.00150 4$MC=3.24E-4 8 +148SM G 571.95 3 0.211 7 E1 0.003205 +148SM2 G KC=0.00274 4$LC=3.61E-4 5$MC=7.68E-5 11 +148SM L 1894.93 124+ +148SM G 714.7 2 0.045 5 M1+E2 0.0070 18 +148SM2 G KC=0.0060 16$LC=0.00084 18$MC=0.00018 4 +148SM G 1344.6 2 0.057 5 E2 1392E-620 +148SM2 G KC=1162E-6 17$LC=1570E-7 22$MC=3.35E-5 5 +148SM L 1905.94 5 6+ +148SM B 702 6 21.8 7 8.35 +148SMS B EAV=224.7 29 +148SM G 311.63 3 3.77 11E1 0.0133719 +148SM2 G KC=0.01141 16$LC=1546E-6 22$MC=3.30E-4 5 +148SM G 725.70 3 32.3 6 E2 0.005067 +148SM2 G KC=0.00424 6$LC=6.42E-4 9$MC=1389E-7 20 +148SM L 2095.57 4 6+ +148SM B 513 6 18.1 9 7.96 +148SMS B EAV=156.0 27 +148SM G 189.63 3 1.15 6 E2 0.249 4 +148SM2 G KC=0.1769 25$LC=0.0565 8$MC=0.01284 18 +148SM G 362.09 3 0.171 13E2 0.0318 5 +148SM2 G KC=0.0253 4$LC=0.00504 7$MC=1114E-6 16 +148SM G 501.26 3 6.59 11E1+M2 -0.017 14 0.004318 +148SM2 G KC=0.00369 7$LC=4.89E-4 9$MC=1042E-7 20 +148SM G 915.33 3 17.9 5 E2 0.003005 +148SM2 G KC=0.00254 4$LC=3.64E-4 6$MC=7.83E-5 11 +148SM L 2194.05 4 6+ +148SM B 414 6 54.0 9 7.18 +148SMS B EAV=122.3 26 +148SM G 98.48 3 2.92 26M1+E2 0.18 1.79 3 +148SM2 G KC=1.488 21$LC=0.236 4$MC=0.0511 8 +148SM G 288.11 3 12.0 4 M1+E2 0.088 21 0.0898 13 +148SM2 G KC=0.0763 11$LC=0.01062 15$MC=0.00228 4 +148SM G 299.1 2 0.13 4 E2 0.0567 8 +148SM2 G KC=0.0442 7$LC=0.00982 14$MC=0.00219 3 +148SM G 460.57 3 0.40 1 E2 0.0160123 +148SM2 G KC=0.01306 19$LC=0.00231 4$MC=5.07E-4 7 +148SM G 599.74 3 12.35 22E1+M2 -0.021 11 0.002905 +148SM2 G KC=0.00249 4$LC=3.27E-4 6$MC=6.96E-5 12 +148SM G 1013.81 3 19.8 4 E2+M3 -0.025 14 0.002434 +148SM2 G KC=0.00206 4$LC=2.90E-4 5$MC=6.22E-5 10 + diff --git a/HEN_HOUSE/spectra/lnhb/Po-209.txt b/HEN_HOUSE/spectra/lnhb/Po-209.txt new file mode 100644 index 000000000..66023ea74 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Po-209.txt @@ -0,0 +1,83 @@ +209BI 209PO EC DECAY (115 Y) +209BI H TYP=Full$AUT=V. Chisté$CUT=30-SEP-2009$ +209BI C Evaluation history: Type=Full;Author=V. Chisté;Cutoff date=30-SEP-2009 +209BI C References: 1956An05, 1966Ha29, 1971Jo06, 1980Sc26, 1989Ma05, 1991Ma16, +209BI2C 1996Sc24, 1996Sc06, 2003Au03, 2004Ko28, 2007Co07, 2008Ki07 +209BI T Auger electrons and ^X ray energies and emission intensities: +209BI T {U Energy (keV)} {U Intensity } {U Line } +209BI T +209BI T 74.8157 0.0927 16 XKA2 +209BI T 77.1088 0.1551 25 XKA1 +209BI T +209BI T 86.835 |] XKB3 +209BI T 87.344 |] 0.0531 12 XKB1 +209BI T 87.862 |] XKB5II +209BI T +209BI T 89.732 |] XKB2 +209BI T 90.074 |] 0.0163 5 XKB4 +209BI T 90.421 |] XKO23 +209BI T +209BI T 9.4207-15.7084 0.1411 24 XL (total) +209BI T 9.4207 0.00357 10 XLL +209BI T 10.7308-10.8387 0.0667 16 XLA +209BI T 11.7127 0.000975 27 XLC +209BI T 12.4814-13.8066 0.0585 11 XLB +209BI T 14.7735-15.7084 0.01130 22 XLG +209BI T +209BI T 57.491-63.419 |] KLL AUGER +209BI T 70.025-77.105 |] 0.0118 14 ^KLX AUGER +209BI T 82.53-90.52 |] KXY AUGER +209BI T 5.42-16.34 0.2240 27 L AUGER +209PO P 0.0 1/2- 115 Y 13 1892.5 16 +209BI N 2.203E2 2.203E2 0.00454 2.203E2 +209BI L 0 9/2- 19E18 Y 2 +209BI L 896.29 5 7/2- 9.7 PS 11 +209BI E 0.454 7 14.36 +209BI2 E EAV= $CK=0.70796 22$CL=0.21518 16$CM=0.07686 7$CN= $CO=0 0 +209BI G 896.28 6 0.445 7 M1+E2 -0.62 4 0.0208 6 +209BI2 G KC=0.0170 5$LC=0.00292 7$MC=6.87E-4 16 + +205PB 209PO A DECAY (115 Y) +205PB H TYP=Full$AUT=V. Chisté$CUT=30-SEP-2009$ +205PB C Evaluation history: Type=Full;Author=V. Chisté;Cutoff date=30-SEP-2009 +205PB C References: 1956An05, 1966Ha29, 1971Jo06, 1980Sc26, 1989Ma05, 1991Ma16, +205PB2C 1996Sc24, 1996Sc06, 2003Au03, 2004Ko28, 2007Co07, 2008Ki07 +205PB T Auger electrons and ^X ray energies and emission intensities: +205PB T {U Energy (keV)} {U Intensity } {U Line } +205PB T +205PB T 72.8049 0.0478 11 XKA2 +205PB T 74.97 0.0804 18 XKA1 +205PB T +205PB T 84.451 |] XKB3 +205PB T 84.937 |] 0.0275 8 XKB1 +205PB T 85.47 |] XKB5II +205PB T +205PB T 87.238 |] XKB2 +205PB T 87.58 |] 0.00830 26 XKB4 +205PB T 87.911 |] XKO23 +205PB T +205PB T 9.186-15.2169 0.0631 13 XL (total) +205PB T 9.186 0.00156 5 XLL +205PB T 10.4495-10.5512 0.0296 8 XLA +205PB T 11.3495 0.000473 15 XLC +205PB T 12.1443-12.7953 0.0264 6 XLB +205PB T 14.3078-15.2169 0.00501 12 XLG +205PB T +205PB T 56.028-61.669 |] KLL AUGER +205PB T 68.181-74.969 |] 0.0063 7 ^KLX AUGER +205PB T 80.3-88 |] KXY AUGER +205PB T 5.33-15.82 0.1044 14 L AUGER +209PO P 0.0 1/2- 115 Y 13 4979.2 14 +205PB N 1.005E0 1.005E0 0.99546 1.005E0 +205PB L 0 5/2- 17.3E6 Y 7 +205PB A 4885 2 19.9 326 +205PB L 2.329 7 1/2- 24.2 US 4 +205PB A 4883 2 79.6 321.3 +205PB G 2.328 7 +205PB L 262.833 253/2- +205PB A 4622 5 0.550 7 4.5 +205PB G 260.50 5 0.254 3 M1+E2 0.16 6 0.617 13 +205PB2 G KC=0.503 12$LC=0.0874 14$MC=0.0205 3 +205PB G 262.80 5 0.085 2 M1+E2 0.05 7 0.612 10 +205PB2 G KC=0.500 9$LC=0.0857 13$MC=0.0201 3 + diff --git a/HEN_HOUSE/spectra/lnhb/Po-210.txt b/HEN_HOUSE/spectra/lnhb/Po-210.txt new file mode 100644 index 000000000..a4fdf26f7 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Po-210.txt @@ -0,0 +1,46 @@ +206PB 210PO A DECAY (138.3763 D) +206PB H TYP=Update$AUT=M.A.Kellett$CUT=31-MAR-2014$ +206PB2 H TYP=Full$AUT=V.Chisté$CUT=28-FEB-2008$ +206PB C Evaluation history: Type=Update;Author=M.A.Kellett;Cutoff date=31-MAR-2014 +206PB2C Type=Full;Author=V.Chisté;Cutoff date=28-FEB-2008 +206PB C References: 1927Da**, 1931CU01, 1933Ro03, 1934Le01, 1949Be54, 1951Gr15, +206PB2C 1952De08, 1952Ri14, 1952Ba20, 1952Ba20, 1953Cu46, 1953Gi10, 1953Co64, +206PB3C 1954Ei20, 1954Br07, 1954AL31, 1955Ro30, 1955Ha09, 1956As46, 1956Sh24, +206PB4C 1957Ag15, 1958Wh09, 1957Ag15, 1958Wh09, 1958Ba45, 1960Br20, 1961Ry05, +206PB5C 1961Be13, 1962Br22, 1964EiZZ, 1972KA30, 1972MA63, 1973Go39, 1977DR08, +206PB6C 1989MA05, 1990He18, 1991Ry01, 1996RA16, 1996Sc06, 1999Br39, 2002Ba85, +206PB7C 2003Au03, 2008KI07, 2008Ko21, 2012Wa38 +206PB T Auger electrons and ^X ray energies and emission intensities: +206PB T {U Energy (keV)} {U Intensity } {U Line } +206PB T +206PB T 72.805 0.00000277 11 XKA2 +206PB T 74.97 0.00000466 17 XKA1 +206PB T +206PB T 84.451 |] XKB3 +206PB T 84.937 |] 0.00000159 7 XKB1 +206PB T 85.47 |] XKB5II +206PB T +206PB T 87.238 |] XKB2 +206PB T 87.58 |] 0.000000481 21 XKB4 +206PB T 87.911 |] XKO23 +206PB T +206PB T 9.186-15.217 0.00000384 10 XL (total) +206PB T 9.186 0.000000093 4 XLL +206PB T 10.449-10.551 0.00000175 6 XLA +206PB T 11.349 0.0000000306 12XLC +206PB T 12.144-13.377 0.00000165 5 XLB +206PB T 14.308-15.217 0.000000318 10 XLG +206PB T +206PB T 56.028-61.669 |] KLL AUGER +206PB T 68.181-74.969 |] 0.00000037 5 ^KLX AUGER +206PB T 80.3-88 |] KXY AUGER +206PB T 5.3338-15.8198 0.00000631 11 L AUGER +210PO P 0.0 0+ 138.3763 D17 5407.45 7 +206PB N 1.0 1.0 1 1.0 +206PB L 0 0+ STABLE +206PB A 5304.33 7 99999E-34 1 +206PB L 803.052 242+ 8.30 PS 25 +206PB A 4516.70 9 0.00124 4 1.46 +206PB G 803.052 240.00123 4 E2 0.0103215 +206PB2 G KC=0.00803 12$LC=1742E-6 25$MC=4.19E-4 6 + diff --git a/HEN_HOUSE/spectra/lnhb/Po-211.txt b/HEN_HOUSE/spectra/lnhb/Po-211.txt new file mode 100644 index 000000000..490503c74 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Po-211.txt @@ -0,0 +1,49 @@ +207PB 211PO A DECAY (0.516 S) +207PB H TYP=Full$AUT=A. Luca$CUT=31-DEC-2008$ +207PB2 H TYP=Full$AUT=mmbe$CUT= -- $ +207PB C Evaluation history: Type=Full;Author=A. Luca;Cutoff date=31-DEC-2008 +207PB2C Type=Full;Author=mmbe;Cutoff date= -- +207PB C References: 1931Cu01, 1951Ne02, 1953AsZZ, 1953Ho49, 1954Br07, 1954Mi70, +207PB2C 1954Sp32, 1954Wi26, 1958To25, 1962Wa18, 1963Jo09, 1968GuZX, 1968Br17, +207PB3C 1969Go23, 1969Ha32, 1970Va13, 1974Ba29, 1975Ja04, 1978Ya04, 1982Bo04, +207PB4C 1985La17, 1991Ry01, 1996Sc06, 2003Au03, 2008Ki07 +207PB T Auger electrons and ^X ray energies and emission intensities: +207PB T {U Energy (keV)} {U Intensity } {U Line } +207PB T +207PB T 72.8049 0.00535 14 XKA2 +207PB T 74.97 0.00900 24 XKA1 +207PB T +207PB T 84.451 |] XKB3 +207PB T 84.937 |] 0.00308 10 XKB1 +207PB T 85.47 |] XKB5II +207PB T +207PB T 87.238 |] XKB2 +207PB T 87.58 |] 0.00093 4 XKB4 +207PB T 87.911 |] XKO23 +207PB T +207PB T 9.186-15.2169 0.00740 16 XL (total) +207PB T 9.186 0.000179 6 XLL +207PB T 10.4495-10.5512 0.00339 10 XLA +207PB T 11.3495 0.0000583 19 XLC +207PB T 12.1443-13.3763 0.00317 8 XLB +207PB T 14.3078-15.2169 0.000608 15 XLG +207PB T +207PB T 56.028-61.669 |] KLL AUGER +207PB T 68.181-74.969 |] 0.00071 8 ^KLX AUGER +207PB T 80.3-88 |] KXY AUGER +207PB T 5.33-15.82 0.01216 17 L AUGER +211PO P 0.0 9/2+ 0.516 S 3 7594.5 5 +207PB N 1.0 1.0 1 1.0 +207PB L 0 1/2- STABLE +207PB A 7450.2 3 98.936 19112 +207PB L 569.65 105/2- +207PB A 6891.2 100.541 17272 +207PB G 569.65 150.534 17E2 0.0216 3 +207PB2 G KC=0.01583 23$LC=0.00439 7$MC=1081E-6 16 +207PB L 897.8 1 3/2- +207PB A 6568.4 100.523 9 17.9 +207PB G 328.2 2 0.0032 11M1 0.334 5 +207PB2 G KC=0.273 4$LC=0.0465 7$MC=0.01089 16 +207PB G 897.8 2 0.507 9 M1+E2 0.092 10 0.0233 4 +207PB2 G KC=0.0192 3$LC=0.00318 5$MC=7.41E-4 11 + diff --git a/HEN_HOUSE/spectra/lnhb/Po-212.txt b/HEN_HOUSE/spectra/lnhb/Po-212.txt new file mode 100644 index 000000000..623dd3269 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Po-212.txt @@ -0,0 +1,18 @@ +208PB 212PO A DECAY (300 NS) +208PB H TYP=Update$AUT=A.L. Nichols$CUT=30-MAY-2010$ +208PB2 H TYP=Full$AUT=A.L. Nichols$CUT=30-DEC-2003$ +208PB C Evaluation history: Type=Update;Author=A.L. Nichols;Cutoff date=30-MAY-2010 +208PB2C Type=Full;Author=A.L. Nichols;Cutoff date=30-DEC-2003 +208PB C References: 1949Bu09, 1962Fl03, 1963As02, 1972Mc29, 1975Sa06, 1981Bo29, +208PB2C 2003Au03, 2005Br03 +208PB T Auger electrons and ^X ray energies and emission intensities: +208PB T {U Energy (keV)} {U Intensity } {U Line } +208PB T +208PB T +208PB T +208PB T +212PO P 0.0 0+ 300 NS 2 8954.12 11 +208PB N 1.0 1.0 1 1.0 +208PB L 0 0+ STABLE +208PB A 8785.17 11100 1 + diff --git a/HEN_HOUSE/spectra/lnhb/Po-213.txt b/HEN_HOUSE/spectra/lnhb/Po-213.txt new file mode 100644 index 000000000..89b0ae8df --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Po-213.txt @@ -0,0 +1,19 @@ +209PB 213PO A DECAY (3.70 US) +209PB H TYP=Full$AUT=Huang Xiaolong$CUT=31-DEC-2007$ +209PB C Evaluation history: Type=Full;Author=Huang Xiaolong;Cutoff date=31-DEC-2007 +209PB T Auger electrons and ^X ray energies and emission intensities: +209PB T {U Energy (keV)} {U Intensity } {U Line } +209PB T +209PB T +209PB T +209PB T +209PB T +213PO P 0.0 9/2+ 3.70 US 5 8536.1 26 +209PB N 1.0 1.0 1 1.0 +209PB L 0 9/2+ 3.277 H 15 +209PB A 8375.9 2599.9950 5 1.238 +209PB L 778.8 3 11/2+ +209PB A 7614 100.0050 5 185 +209PB G 778.8 3 0.0048 5 M1 0.0339 5 +209PB2 G KC=0.0278 4$LC=0.00462 7$MC=1079E-6 16 + diff --git a/HEN_HOUSE/spectra/lnhb/Po-214.txt b/HEN_HOUSE/spectra/lnhb/Po-214.txt new file mode 100644 index 000000000..d60fa6f9b --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Po-214.txt @@ -0,0 +1,39 @@ +210PB 214PO A DECAY (162.3 US) +210PB H TYP=full$AUT=V.Chisté$CUT= -- $ +210PB C Evaluation history: Type=full;Author=V.Chisté;Cutoff date= -- +210PB C References: 1942Wa04, 1950Vo02, 1953Ba60, 1960Og01, 1961Ry02, 1961Do02, +210PB2C 1969Pe17, 1971Gr17, 1971Er02, 1976Ku08, 1990Ho28, 1992Br01, 1993Zh30, +210PB3C 1991Ry01, 1995El07, 1996Sc06, 1998Ak04, 2002Ba85, 2003Au03, 2003Br13 +210PB T Auger electrons and ^X ray energies and emission intensities: +210PB T {U Energy (keV)} {U Intensity } {U Line } +210PB T +210PB T 72.8049 0.0000246 15 XKA2 +210PB T 74.97 0.0000414 25 XKA1 +210PB T +210PB T 84.451 |] XKB3 +210PB T 84.937 |] 0.0000141 9 XKB1 +210PB T 85.47 |] XKB5II +210PB T +210PB T 87.238 |] XKB2 +210PB T 87.58 |] 0.00000427 27 XKB4 +210PB T 87.911 |] XKO23 +210PB T +210PB T 9.19-15.22 0.0000347 13 XL (total) +210PB T 9.19 0.00000083 5 XLL +210PB T 10.4495-10.5512 0.0000157 8 XLA +210PB T 11.3495 0.000000279 16 XLC +210PB T 12.1443-12.7953 0.0000150 6 XLB +210PB T 14.3078-15.22 0.00000289 12 XLG +214PO P 0.0 0+ 162.3 US 12 7833.46 6 +210PB N 1.0 1.0 1 1.0 +210PB L 0 0+ 22.23 Y 12 +210PB A 7686.82 6 99.9895 7 1 +210PB L 799.7 2 2+ 17 PS 5 +210PB A 6902.6 3 0.0105 7 27 +210PB G 799.7 1 0.0104 6 E2 0.0104215 +210PB2 G KC=0.00810 12$LC=1763E-6 25$MC=4.25E-4 6 +210PB L 1097.7 104+ 0.6 NS 1 +210PB A 6610.1 1058000E-92 400 +210PB G 298 1 5.2E-5 18E2 0.1180 21 +210PB2 G KC=0.0661 11$LC=0.0389 8$MC=0.00999 20 + diff --git a/HEN_HOUSE/spectra/lnhb/Po-215.txt b/HEN_HOUSE/spectra/lnhb/Po-215.txt new file mode 100644 index 000000000..cbeb00797 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Po-215.txt @@ -0,0 +1,89 @@ +211PB 215PO A DECAY (1.781 MS) +211PB H TYP=Full$AUT=V.P. Chechev$CUT=30-NOV-2010$ +211PB C Evaluation history: Type=Full;Author=V.P. Chechev;Cutoff date=30-NOV-2010 +211PB C References: 1942Wa04, 1950Av61, 1961Vo06, 1962Wa18, 1965Va10, 1968Br17, +211PB2C 1970Da09, 1971Gr17, 1971Er02, 1977Ma29, 1991Ry01, 1998Li53, 2003Au03, +211PB3C 2004Br45, 2008Ki07 +211PB T Auger electrons and ^X ray energies and emission intensities: +211PB T {U Energy (keV)} {U Intensity } {U Line } +211PB T +211PB T 72.8049 0.00045 15 XKA2 +211PB T 74.97 0.00075 25 XKA1 +211PB T +211PB T 84.451 |] XKB3 +211PB T 84.937 |] 0.00026 9 XKB1 +211PB T 85.47 |] XKB5II +211PB T +211PB T 87.238 |] XKB2 +211PB T 87.58 |] 0.000078 26 XKB4 +211PB T 87.911 |] XKO23 +211PB T +211PB T 9.186-15.2169 0.00071 12 XL (total) +211PB T 9.186 0.000016 4 XLL +211PB T 10.4495-10.5512 0.00031 7 XLA +211PB T 11.3495 0.0000063 15 XLC +211PB T 12.1443-13.3763 0.00032 6 XLB +211PB T 14.3078-15.2169 0.000063 12 XLG +211PB T +211PB T 56.028-61.669 |] KLL AUGER +211PB T 68.181-74.969 |] 0.000059 21 ^KLX AUGER +211PB T 80.3-88 |] KXY AUGER +211PB T 5.33-15.82 0.00115 14 L AUGER +215PO P 0.0 9/2+ 1.781 MS 4 7526.3 8 +211PB N 1.00E0 1.00E0 0.999997 1.00E0 +211PB L 0 9/2+ 36.1 M 2 +211PB A 7386.1 8 99.934 201.34 +211PB L 438.9 2 (7/2)+ +211PB A 6955.4 8 0.06 2 82 +211PB G 438.9 2 0.058 19E2 0.0405 6 +211PB2 G KC=0.0275 4$LC=0.00984 14$MC=0.00247 4 +211PB L 584 3 + +211PB A 6813 3 0.0004 2 3800 +211PB G 584 3 +211PB L 598 3 (5/2)+ +211PB A 6799 3 0.0016 5 8500 +211PB G 598 3 +211PB L 643 3 11/2+ +211PB A 6755 3 0.0008 3 1170 +211PB G 643 3 (M1+E2) 0.036 20 +211PB2 G KC=0.029 17$LC=0.0054 23$MC=0.0013 6 +211PB L 733 3 (13/2)+ +211PB A 6667 3 0.0008 3 550 +211PB G 733 3 +211PB L 815 3 (9/2)+ +211PB A 6586 3 0.0020 6 109 +211PB G 815 3 +211PB L 894 3 (11/2)+ +211PB A 6509 3 30000E-8 365 +211PB G 310 4 +211PB G 894 3 + +215AT 215PO B- DECAY (1.781 MS) +215AT H TYP=Full$AUT=V.P. Chechev$CUT=30-NOV-2010$ +215AT C Evaluation history: Type=Full;Author=V.P. Chechev;Cutoff date=30-NOV-2010 +215AT C References: 1942Wa04, 1950Av61, 1961Vo06, 1962Wa18, 1965Va10, 1968Br17, +215AT2C 1970Da09, 1971Gr17, 1971Er02, 1977Ma29, 1991Ry01, 1998Li53, 2003Au03, +215AT3C 2004Br45, 2008Ki07 +215AT T Auger electrons and ^X ray energies and emission intensities: +215AT T {U Energy (keV)} {U Intensity } {U Line } +215AT T +215AT T 78.94 XKA2 +215AT T 81.51 XKA1 +215AT T +215AT T 91.73 |] XKB3 +215AT T 92.315 |] XKB1 +215AT T 92.883 |] XKB5II +215AT T +215AT T 94.846 |] XKB2 +215AT T 95.211 |] XKB4 +215AT T 95.595 |] XKO23 +215AT T +215AT T +215AT T 60.489-67.031 |] KLL AUGER +215AT T 73.811-81.516 |] ^KLX AUGER +215AT T 87.1-95.72 |] KXY AUGER +215AT T 5.58-17.41 L AUGER +215PO P 0.0 9/2+ 1.781 MS 4 715 7 +215AT N 4.348E5 4.348E5 0.000002 4.348E5 +215AT L 0 + 0.10 MS 2 + diff --git a/HEN_HOUSE/spectra/lnhb/Po-216.txt b/HEN_HOUSE/spectra/lnhb/Po-216.txt new file mode 100644 index 000000000..02363c4d2 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Po-216.txt @@ -0,0 +1,42 @@ +212PB 216PO A DECAY (0.148 S) +212PB H TYP=Update$AUT=A.L. Nichols$CUT=30-JAN-2011$ +212PB2 H TYP=Full$AUT=A.L. Nichols$CUT=30-JAN-2004$ +212PB C Evaluation history: Type=Update;Author=A.L. Nichols;Cutoff date=30-JAN-2011 +212PB2C Type=Full;Author=A.L. Nichols;Cutoff date=30-JAN-2004 +212PB C References: 1911Mo11, 1942Wa04, 1962Wa28, 1963Di05, 1977Ku15, 1977La19, +212PB2C 1996Sc06, 1998ScZM, 1998Ak04, 1999ScZX, 2002Ba85, 2002Ra45, 2003Au03, +212PB3C 2003Da24, 2005Br03, 2007Wu02, 2007St23, 2008Ki07 +212PB T Auger electrons and ^X ray energies and emission intensities: +212PB T {U Energy (keV)} {U Intensity } {U Line } +212PB T +212PB T 72.8049 0.0000043 7 XKA2 +212PB T 74.97 0.0000072 12 XKA1 +212PB T +212PB T 84.451 |] XKB3 +212PB T 84.937 |] 0.0000024 4 XKB1 +212PB T 85.47 |] XKB5II +212PB T +212PB T 87.238 |] XKB2 +212PB T 87.58 |] 0.00000074 12 XKB4 +212PB T 87.911 |] XKO23 +212PB T +212PB T 9.184-15.216 0.0000059 6 XL (total) +212PB T 9.184 0.000000142 18 XLL +212PB T 10.45-10.551 0.0000027 3 XLA +212PB T 11.349 0.000000047 7 XLC +212PB T 12.142-13.015 0.00000253 24 XLB +212PB T 14.765-15.216 0.00000049 5 XLG +212PB T +212PB T 56.03-61.67 |] KLL AUGER +212PB T 68.18-74.97 |] 0.00000056 11 ^KLX AUGER +212PB T 80.3-88 |] KXY AUGER +212PB T 5.26-10.4 0.0000097 10 L AUGER +216PO P 0.0 0+ 0.148 S 4 6906.3 5 +212PB N 1.0 1.0 1 1.0 +212PB L 0 0+ 10.64 H 1 +212PB A 6778.4 5 99.9981 3 1 +212PB L 804.9 5 (2)+ +212PB A 5988.4 7 0.0019 3 35 +212PB G 804.9 5 0.0019 3 [E2] 0.0102715 +212PB2 G KC=0.00799 12$LC=1732E-6 25$MC=4.17E-4 6 + diff --git a/HEN_HOUSE/spectra/lnhb/Po-218.txt b/HEN_HOUSE/spectra/lnhb/Po-218.txt new file mode 100644 index 000000000..217850476 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Po-218.txt @@ -0,0 +1,63 @@ +214PB 218PO A DECAY (3.071 M) +214PB H TYP=Update$AUT=V.Chisté$CUT= -- $ +214PB2 H TYP=Full$AUT=V.Chisté$CUT= -- $ +214PB C Evaluation history: Type=Update;Author=V.Chisté;Cutoff date= -- +214PB2C Type=Full;Author=V.Chisté;Cutoff date= -- +214PB C References: 1924Bl02, 1931Cu01, 1949Wa05, 1952Hi60, 1958Wa16, 1963Ba62, +214PB2C 1971Gr17, 1979Ry03, 1982Va09, 1986Po17, 1987El07, 1991Ry01, 1992Ba61, +214PB3C 1995El07, 1995El08, 1998Ak04, 2002Ba85, 2003Au03, 2006Ja03 +214PB T Auger electrons and ^X ray energies and emission intensities: +214PB T {U Energy (keV)} {U Intensity } {U Line } +214PB T +214PB T 72.8049 XKA2 +214PB T 74.97 XKA1 +214PB T +214PB T 84.451 |] XKB3 +214PB T 84.937 |] XKB1 +214PB T 85.47 |] XKB5II +214PB T +214PB T 87.238 |] XKB2 +214PB T 87.58 |] XKB4 +214PB T 87.911 |] XKO23 +214PB T +218PO P 0.0 0+ 3.071 M 22 6114.68 9 +214PB N 1.00E0 1.00E0 0.999779 1.00E0 +214PB L 0 0+ 26.916 M 44 +214PB A 6002.35 9 99.9989 321 +214PB L 837 (2)+ +214PB A 5181 2 0.0011 117.5 +214PB G 836 2 0.0011 11(E2) + +218AT 218PO B- DECAY (3.071 M) +218AT H TYP=Update$AUT=V.Chisté$CUT= -- $ +218AT2 H TYP=Full$AUT=V.Chisté$CUT= -- $ +218AT C Evaluation history: Type=Update;Author=V.Chisté;Cutoff date= -- +218AT2C Type=Full;Author=V.Chisté;Cutoff date= -- +218AT C References: 1924Bl02, 1931Cu01, 1949Wa05, 1952Hi60, 1958Wa16, 1963Ba62, +218AT2C 1971Gr17, 1979Ry03, 1982Va09, 1986Po17, 1987El07, 1991Ry01, 1992Ba61, +218AT3C 1995El07, 1995El08, 1998Ak04, 2002Ba85, 2003Au03, 2006Ja03 +218AT T Auger electrons and ^X ray energies and emission intensities: +218AT T {U Energy (keV)} {U Intensity } {U Line } +218AT T +218AT T 78.94 XKA2 +218AT T 81.51 XKA1 +218AT T +218AT T 91.73 |] XKB3 +218AT T 92.315 |] XKB1 +218AT T 92.883 |] XKB5II +218AT T +218AT T 94.846 |] XKB2 +218AT T 95.211 |] XKB4 +218AT T 95.595 |] XKO23 +218AT T +218AT T 9.8964 XLL +218AT T 11.3052-11.426 XLA +218AT T 12.4653 XLC +218AT T 13.1704-14.6997 XLB +218AT T 15.7394-16.7291 XLG +218PO P 0.0 0+ 3.071 M 22 260 12 +218AT N 4.545E3 4.545E3 0.00022 4.545E3 +218AT L 0 (2)- 1.4 S 2 +218AT B 260 120.022 3 1U +218ATS B EAV=73 4 + diff --git a/HEN_HOUSE/spectra/lnhb/Pr-144.txt b/HEN_HOUSE/spectra/lnhb/Pr-144.txt new file mode 100644 index 000000000..9b02e10d9 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Pr-144.txt @@ -0,0 +1,106 @@ +144ND 144PR B- DECAY (17.29 M) +144ND H TYP=FUL$AUT=A.L. Nichols$CUT=01-APR-2014$ +144ND C Evaluation history: Type=FUL;Author=A.L. Nichols;Cutoff date=01-APR-2014 +144ND C References: 1954Kr40, 1954Wa05, 1956Po16, 1957Pe09, 1958Gr99, 1959Po77, +144ND2C 1961Ma05, 1963Iw02, 1963Kn05, 1963Si10, 1963Ho15, 1963Co18, 1963Cr11, +144ND3C 1965Is01, 1965Co19, 1965Re13, 1966Be11, 1967Gu17, 1968Ra01, 1968Sa05, +144ND4C 1968Da12, 1969Ge01, 1969Gu15, 1969Ma24, 1970Fa03, 1971Na12, 1973Bo43, +144ND5C 1974Be09, 1975De17, 1976CoZX, 1976Ra22, 1977La19, 1977Ge12, 1979Pr11, +144ND6C 1979Gr01, 1981Ol04, 1983Sn04, 1983Kr09, 1985Da16, 1987Al28, 1994Ro13, +144ND7C 1996Sc06, 1998Hi09, 1998ScZM, 1999ScZX, 2000Sc47, 2000He14, 2001So16, +144ND8C 2002Ra45, 2002Ba85, 2008Ki07, 2012Wa38 +144ND T Auger electrons and ^X ray energies and emission intensities: +144ND T {U Energy (keV)} {U Intensity } {U Line } +144ND T +144ND T 36.8478 0.00165 9 XKA2 +144ND T 37.3614 0.00300 15 XKA1 +144ND T +144ND T 42.167 |] XKB3 +144ND T 42.2717 |] 0.00092 5 XKB1 +144ND T 42.58 |] XKB5II +144ND T +144ND T 43.335 |] XKB2 +144ND T 43.451 |] 0.000237 13 XKB4 +144ND T 43.548 |] XKO23 +144ND T +144ND T 4.633-6.901 0.00092 3 XL (total) +144ND T 4.633 0.0000179 9 XLL +144ND T 5.208-5.23 0.000449 20 XLA +144ND T 5.146 0.0000069 4 XLC +144ND T 5.722-6.09 0.000384 14 XLB +144ND T 6.604-6.901 0.0000615 23 XLG +144ND T +144ND T 29.154-30.978 |] KLL AUGER +144ND T 34.798-37.34 |] 0.00052 4 ^KLX AUGER +144ND T 40.42-43.53 |] KXY AUGER +144ND T 3.01-5.1 0.00551 18 L AUGER +144PR P 0.0 0- 17.29 M 4 2997.4 24 +144ND N 1.0 1.0 1 1.0 +144ND L 0 0 0+ 2.3E15 Y 3 +144ND B 2997.4 2497.852 10 6.53 +144NDS B EAV=12220E-1 1 +144ND L 696.561 102+ +144ND B 2300.8 241.116 3 9.17 1U +144NDS B EAV=894.90 11 +144ND G 696.505 4 1.41 7 E2 0.005077 +144ND2 G KC=0.00427 6$LC=6.31E-4 9$MC=1348E-7 19 +144ND L 1314.669 134+ 7.40 PS 9 +144ND L 1510.871 213- 0.56 PS 7 +144ND G 814.308 230.00331 14E1 1391E-620 +144ND2 G KC=1198E-6 17$LC=1528E-7 22$MC=3.21E-5 5 +144ND L 1560.920 132+ +144ND B 1436.5 240.0017 3 10.8 1U +144NDS B EAV=526.25 10 +144ND G 864.356 160.00269 14M1+E2 -0.97 15 0.0039616 +144ND2 G KC=0.00338 14$LC=4.56E-4 16$MC=9.6E-5 4 +144ND G 1560.911 130.00021 3 E2 1014E-615 +144ND2 G KC=7.86E-4 11$LC=1024E-7 15$MC=2.16E-5 3 +144ND L 2072.91 3 2+ 59 FS 10 +144ND B 924.5 240.00065 6 10.2 1U +144NDS B EAV=322.77 9 +144ND G 1376.34 3 0.00041 4 M1+E2 0.34 10 0.001614 +144ND2 G KC=0.00135 3$LC=1.75E-4 4$MC=3.68E-5 8 +144ND G 2072.89 3 0.00024 3 E2 8.65E-413 +144ND2 G KC=4.65E-4 7$LC=5.93E-5 9$MC=1246E-8 18 +144ND L 2084.68 3 0+ 0.12 PS 5 +144ND B 912.7 240.00708 6 8.7 +144NDS B EAV=306.67 10 +144ND G 1388.11 4 0.00706 6 E2 1190E-617 +144ND2 G KC=9.84E-4 14$LC=1297E-7 19$MC=2.74E-5 4 +144ND L 2185.75 3 1- 15 FS 2 +144ND B 811.7 241.021 10 6.32 +144NDS B EAV=267.12 9 +144ND G 624.83 3 0.00118 3 E1 0.002414 +144ND2 G KC=0.00207 3$LC=2.67E-4 4$MC=5.61E-5 8 +144ND G 674.88 4 0.00299 14E2 0.005478 +144ND2 G KC=0.00460 7$LC=6.86E-4 10$MC=1465E-7 21 +144ND G 1489.148 3 0.286 3 E1 6.63E-410 +144ND2 G KC=3.97E-4 6$LC=4.95E-5 7$MC=1038E-8 15 +144ND G 2185.645 5 0.73 1 E1 9.59E-414 +144ND2 G KC=2.13E-4 3$LC=2.64E-5 4$MC=5.52E-6 8 +144ND L 2368.82 4 2+ 39 FS 14 +144ND B 628.6 240.00027 6 9.7 1U +144NDS B EAV=213.04 9 +144ND G 1672.25 4 0.00021 6 M1+E2 0.16 7 1189E-618 +144ND2 G KC=8.92E-4 14$LC=1146E-7 18$MC=2.41E-5 4 +144ND G 2368.80 4 5.1E-5 14E2 8.91E-413 +144ND2 G KC=3.65E-4 6$LC=4.63E-5 7$MC=9.73E-6 14 +144ND L 2582.32 6 (3)+ +144ND L 2655.54 3 1+ 9.9 FS 2 +144ND B 341.9 240.00018 3 8.8 1 +144NDS B EAV=98.68 8 +144ND G 2655.51 3 0.00018 3 M1+E2 +144ND L 2675.61 8 0+ 0.2 PS 1 +144ND B 321.8 240.00096 8 8 +144NDS B EAV=92.21 8 +144ND G 1979.04 8 0.00096 8 E2 8.68E-413 +144ND2 G KC=5.05E-4 7$LC=6.47E-5 9$MC=1360E-8 19 +144ND L 2742.99 7 0+ 64 FS 40 +144ND B 254.4 240.00035 6 8.1 +144NDS B EAV=71.05 8 +144ND G 1182.06 7 0.00006 3 E2 1587E-623 +144ND2 G KC=1353E-6 19$LC=1.82E-4 3$MC=3.84E-5 6 +144ND G 2046.41 7 0.00030 6 E2 8.65E-413 +144ND2 G KC=4.75E-4 7$LC=6.07E-5 9$MC=1277E-8 18 +144ND L 2946.04 10(2,3,4)- + diff --git a/HEN_HOUSE/spectra/lnhb/Pr-144m.txt b/HEN_HOUSE/spectra/lnhb/Pr-144m.txt new file mode 100644 index 000000000..ca929ca6f --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Pr-144m.txt @@ -0,0 +1,97 @@ +144PR 144PR IT DECAY (7.2 M) +144PR H TYP=FUL$AUT=A.L. Nichols$CUT=01-APR-2014$ +144PR C Evaluation history: Type=FUL;Author=A.L. Nichols;Cutoff date=01-APR-2014 +144PR C References: 1960Ge05, 1968Ra01, 1968Sa05, 1969Ge01, 1970An15, 1970Fa03, +144PR2C 1974Be09, 1976CoZX, 1976Ra22, 1977La19, 1979Pr11, 1979Gr01, 1985Da16, +144PR3C 1994Ro13, 1996Sc06, 1998Hi09, 1998ScZM, 1999ScZX, 2000Sc47, 2000He14, +144PR4C 2001So16, 2002Ra45, 2002Ba85, 2008Ki07, 2012Wa38 +144PR T Auger electrons and ^X ray energies and emission intensities: +144PR T {U Energy (keV)} {U Intensity } {U Line } +144PR T +144PR T 33.5506 8.66 19 XKA2 +144PR T 36.0267 15.8 4 XKA1 +144PR T +144PR T 40.6533 |] XKB3 +144PR T 40.7487 |] 4.81 12 XKB1 +144PR T 41.05 |] XKB5II +144PR T +144PR T 41.774 |] XKB2 +144PR T 41.877 |] 1.23 4 XKB4 +144PR T 41.968 |] XKO23 +144PR T +144PR T 4.453-6.617 10.5 5 XL (total) +144PR T 4.453 0.227 7 XLL +144PR T 5.013-5.033 5.74 16 XLA +144PR T 4.929 0.0498 15 XLC +144PR T 5.489-5.851 3.89 7 XLB +144PR T 6.327-6.617 0.625 13 XLG +144PR T +144PR T 28.162-29.89 |] KLL AUGER +144PR T 33.576-36.004 |] 2.87 15 ^KLX AUGER +144PR T 38.97-41.95 |] KXY AUGER +144PR T 2.9-4.91 69 10 L AUGER +144PR P 59.03 3 3- 7.2 M 2 +144PR N 1.001E0 1.001E0 0.9994 2 1.001E0 +144PR L 0 0 0- 17.29 M 4 +144PR L 59.03 3 3- 7.2 M 2 +144PR G 59.03 3 0.0818 12M3 1221 18 +144PR2 G KC=408 6$LC=618 9$MC=155.0 23 + +144ND 144PR B- DECAY (7.2 M) +144ND H TYP=FUL$AUT=A.L. Nichols$CUT=01-APR-2014$ +144ND C Evaluation history: Type=FUL;Author=A.L. Nichols;Cutoff date=01-APR-2014 +144ND C References: 1960Ge05, 1968Ra01, 1968Sa05, 1969Ge01, 1970An15, 1970Fa03, +144ND2C 1974Be09, 1976CoZX, 1976Ra22, 1977La19, 1979Pr11, 1979Gr01, 1985Da16, +144ND3C 1994Ro13, 1996Sc06, 1998Hi09, 1998ScZM, 1999ScZX, 2000Sc47, 2000He14, +144ND4C 2001So16, 2002Ra45, 2002Ba85, 2008Ki07, 2012Wa38 +144ND T Auger electrons and ^X ray energies and emission intensities: +144ND T {U Energy (keV)} {U Intensity } {U Line } +144ND T +144ND T 36.8478 0.000119 23 XKA2 +144ND T 37.3614 0.00022 5 XKA1 +144ND T +144ND T 42.167 |] XKB3 +144ND T 42.2717 |] 0.000067 13 XKB1 +144ND T 42.58 |] XKB5II +144ND T +144ND T 43.335 |] XKB2 +144ND T 43.451 |] 0.000017 4 XKB4 +144ND T 43.548 |] XKO23 +144ND T +144ND T +144ND T 29.154-30.978 |] KLL AUGER +144ND T 34.798-37.34 |] 0.000038 8 ^KLX AUGER +144ND T 40.42-43.53 |] KXY AUGER +144ND T 3.01-5.1 0.00040 5 L AUGER +144PR P 59.03 3 3- 7.2 M 2 2997.4 24 +144ND N 1.667E3 1.667E3 0.0006 2 1.667E3 +144ND L 0 0 0+ 2.3E15 Y 3 +144ND L 696.561 102+ +144ND G 696.505 4 0.06 2 E2 0.005077 +144ND2 G KC=0.00427 6$LC=6.31E-4 9$MC=1348E-7 19 +144ND L 1314.669 134+ 7.4 PS 9 +144ND G 618.107 160.030 3 E2 0.0067910 +144ND2 G KC=0.00568 8$LC=8.69E-4 13$MC=1.86E-4 3 +144ND L 1510.871 213- 0.56 PS 7 +144ND B 1545.5 240.02 1 8.7 +144NDS B EAV=570.0 11 +144ND G 814.308 230.02 1 E1 1391E-620 +144ND2 G KC=1198E-6 17$LC=1528E-7 22$MC=3.21E-5 5 +144ND L 1560.920 132+ +144ND L 2072.91 3 2+ 59 FS 10 +144ND L 2084.68 3 0+ 0.12 PS 5 +144ND L 2185.75 3 1- 15 FS 2 +144ND L 2368.82 4 2+ 39 FS 14 +144ND L 2582.32 6 (3)+ +144ND B 474.1 240.010 3 7.15 +144NDS B EAV=143.0 8 +144ND G 1885.75 6 0.010 3 M1+E2 0.13 5 1052E-615 +144ND2 G KC=6.86E-4 10$LC=8.78E-5 13$MC=1.85E-5 3 +144ND L 2655.54 3 1+ 9.9 FS 2 +144ND L 2675.61 8 0+ 0.2 PS 1 +144ND L 2742.99 7 0+ 64 FS 40 +144ND L 2946.04 10(2,3,4)- +144ND B 110.4 240.030 3 4.65 +144NDS B EAV=29.0 7 +144ND G 1631.36 100.030 3 + diff --git a/HEN_HOUSE/spectra/lnhb/Pu-238.txt b/HEN_HOUSE/spectra/lnhb/Pu-238.txt new file mode 100644 index 000000000..f4b67e4de --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Pu-238.txt @@ -0,0 +1,137 @@ +234U 238PU A DECAY (87.74 Y) +234U H TYP=Update$AUT=V. Chechev$CUT= -- $ +234U C Evaluation history: Type=Update;Author=V. Chechev;Cutoff date= -- +234U C References: 1949Jaf., 1950Jaf., 1952Se67, 1954Jo10, 1954As07, 1955Ch02, +234U 2C 1956Ne17, 1957Ho71, 1957Ko33, 1961Dr04, 1962Le11, 1963Bj03, 1964Le22, +234U 3C 1964Ha14, 1964Le17, 1968By01, 1968Ba25, 1969Am02, 1969LeZX, 1970Ba72, +234U 4C 1971Cl03, 1971So15, 1971Ma68, 1971Gr17, 1971GuZY, 1972Ha11, 1972Sc01, +234U 5C 1974StYG, 1975GaZX, 1976Um01, 1976GuZN, 1976Va23, 1976Po08, 1977Di04, +234U 6C 1977La19, 1978Ro22, 1979Ce04, 1981Ag06, 1982Ba56, 1983Ah02, 1984DrZX, +234U 7C 1984Ov01, 1984He19, 1984Bo41, 1984BaYT, 1984Ah06, 1987Bo25, 1988SeZY, +234U 8C 1990Po14, 1991Jo02, 1991Ry01, 1994Le37, 1994Ba91, 1995Jo23, 1996Sc06, +234U 9C 1998Ya17, 2000He14, 2000Ho27, 2000Ni13, 2003Au03, 2007Br04, 2008Ki07 +234U T Auger electrons and ^X ray energies and emission intensities: +234U T {U Energy (keV)} {U Intensity } {U Line } +234U T +234U T 94.666 0.000106 3 XKA2 +234U T 98.44 0.000169 5 XKA1 +234U T +234U T 110.421 |] XKB3 +234U T 111.298 |] 0.0000609 22 XKB1 +234U T 111.964 |] XKB5II +234U T +234U T 114.407 |] XKB2 +234U T 115.012 |] 0.0000208 6 XKB4 +234U T 115.377 |] XKO23 +234U T +234U T 11.619-20.714 10.63 8 XL (total) +234U T 11.619 0.235 4 XLL +234U T 13.438-13.615 3.80 3 XLA +234U T 15.399 0.119 5 XLC +234U T 15.727-18.206 5.19 4 XLB +234U T 19.507-20.714 1.28 1 XLG +234U T +234U T 71.78-80.95 |] KLL AUGER +234U T 88.15-98.43 |] 0.0000110 15 ^KLX AUGER +234U T 104.51-115.59 |] KXY AUGER +234U T 5.9-21.6 10.6 4 L AUGER +238PU P 0.0 0+ 87.74 Y 3 5593.20 19 +234U N 1.0 1.0 1 1.0 +234U L 0 0+ 2.455E5 Y 60 +234U A 5499.03 2071.04 6 1 +234U L 43.4981 102+ 0.252 NS 7 +234U A 5456.3 2 28.85 6 1.39 +234U G 43.498 1 0.0397 8 E2 713 15 +234U 2 G KC=$LC=520 11$MC=143.5 29 +234U L 143.352 4 4+ +234U A 5358.1 2 0.104 3 102 +234U G 99.852 3 0.00735 8 E2 13.42 27 +234U 2 G KC=$LC=9.77 20$MC=2.71 6 +234U L 296.072 4 6+ +234U A 5208.0 2 0.00292 4 440 +234U G 152.719 2 9.30E-4 7 E2 2.14 4 +234U 2 G KC=0.217 4$LC=1.404 28$MC=0.388 8 +234U L 497.04 3 8+ +234U A 5010.4 2 68000E-12310000 +234U G 200.97 3 3.92E-6 13E2 0.734 15 +234U 2 G KC=0.1534 31$LC=0.424 9$MC=0.1166 23 +234U L 786.288 161- +234U A 4726.0 2 82100E-11689 +234U G 742.813 5 5.10E-6 13E1 0.0063613 +234U 2 G KC=0.00518 10$LC=8.95E-4 18$MC=2.13E-4 4 +234U G 786.27 3 3.20E-6 9 E1 0.0057312 +234U 2 G KC=0.00467 9$LC=8.04E-4 16$MC=1.91E-4 4 +234U L 809.907 180+ +234U A 4702.8 2 0.0001 5 +234U G 766.38 2 2.19E-5 5 E2 0.0187 4 +234U 2 G KC=0.01336 27$LC=0.00396 8$MC=1003E-6 20 +234U G 810.0 5 +234U L 849.266 183- +234U A 4664.1 2 75000E-1223400 +234U G 705.9 1 5.0E-8 13[E1] 0.0069814 +234U 2 G KC=0.00568 12$LC=9.87E-4 20$MC=2.35E-4 5 +234U G 805.80 5 5.6E-8 15[E1] 0.0054911 +234U 2 G KC=0.00447 9$LC=7.68E-4 16$MC=1.83E-4 4 +234U L 851.74 3 2+ 1.74 PS +234U A 4661.7 2 81000E-1 30.5 +234U G 41.82 113.0E-9 16[E2] 863 18 +234U 2 G KC=$LC=630 13$MC=174 4 +234U G 708.3 2 4.9E-7 3 [E2] 0.0219 5 +234U 2 G KC=0.01537 31$LC=0.00489 10$MC=1246E-6 25 +234U G 808.2 1 7.67E-7 25+E2 4.300000 +234U 2 G KC=3.31000 0$LC=0.94000 0$MC= +234U G 851.7 1 1.27E-6 4 [E2] 0.0151330 +234U 2 G KC=0.01109 22$LC=0.00302 6$MC=7.59E-4 16 +234U L 926.720 152+ 1.38 PS 17 +234U A 4587.9 2 13000E-15 53 +234U G 783.4 1 2.2E-8 3 [E2] 0.0179 4 +234U 2 G KC=0.01285 26$LC=0.00374 8$MC=9.46E-4 19 +234U G 883.24 4 7.2E-7 4 E2 0.0140928 +234U 2 G KC=0.01040 21$LC=0.00276 6$MC=6.92E-4 14 +234U G 926.72 1 5.58E-7 25(E2) 0.0128426 +234U 2 G KC=0.00956 20$LC=0.00245 5$MC=6.13E-4 12 +234U L 947.64 6 4+ +234U A 4567.4 2 23000E-1 21 +234U G 804.4 3 1.1E-7 5 +E2 0.570000 +234U 2 G KC=$LC=$MC= +234U G 904.37 156.1E-8 11[E2] 0.0134627 +234U 2 G KC=0.00998 20$LC=0.00260 5$MC=6.52E-4 13 +234U L 989.430 132- 0.76 NS 4 +234U A 4526.3 2 15000E-116155 +234U G 62.70 1 1.1E-8 3 E1 0.426 9 +234U 2 G KC=$LC=0.320 7$MC=0.0791 16 +234U G 140.15 2 3.5E-9 7 M1+E2 1.3 5 5.1 15 +234U 2 G KC=2.6 8$LC=1.79 5$MC=0.48 14 +234U G 203.12 3 8.5E-9 15M1+E2 1.4 4 1.5 3 +234U 2 G KC=0.90 17$LC=0.423 9$MC=0.1113 23 +234U G 946.00 3 9.2E-8 13(E1) 0.004128 +234U 2 G KC=0.00337 7$LC=5.71E-4 12$MC=1355E-7 27 +234U L 1023.77 3 4+ +234U A 4492.5 2 20000E-1 64 +234U G 727.8 2 2.7E-9 3 (E2) 0.0207 4 +234U 2 G KC=0.01464 29$LC=0.00454 9$MC=1156E-6 23 +234U G 880.5 1 1.5E-7 4 (+E2) +234U G 980.3 1 420E-10 0 (E2) 0.0115223 +234U 2 G KC=0.00866 18$LC=0.00214 4$MC=5.34E-4 11 +234U L 1044.536 230+ +234U A 4472.1 2 11700E-17 7.5 +234U G 192.91 7 66E-11 20[E2] 0.856 17 +234U 2 G KC=0.1635 33$LC=0.505 10$MC=0.1391 28 +234U G 234.6 2 +234U G 258.227 3 7.0E-8 11(E1) 0.0548 11 +234U 2 G KC=0.0434 9$LC=0.00859 17$MC=0.00207 4 +234U G 1001.03 3 9.8E-7 4 E2 0.0110722 +234U 2 G KC=0.00835 17$LC=0.00204 4$MC=5.07E-4 11 +234U L 1085.26 4 2+ +234U A 4432.1 2 12000E-1 3.5 +234U G 233.6 2 (+E2) +234U G 235.9 3 9E-9 5 [E1] 0.0673 14 +234U 2 G KC=0.0532 11$LC=0.01067 21$MC=0.00258 5 +234U G 299.1 2 4.4E-8 3 [E1] 0.0395 8 +234U 2 G KC=0.0314 6$LC=0.00608 12$MC=1466E-6 29 +234U G 941.94 104.66E-7 23[E2] 0.0124425 +234U 2 G KC=0.00929 20$LC=0.00236 5$MC=5.89E-4 12 +234U G 1041.7 2 1.97E-7 16(+E2) +234U G 1085.4 2 7.7E-8 9 (E2) 0.0095019 +234U 2 G KC=0.00725 15$LC=0.00169 3$MC=4.18E-4 8 + diff --git a/HEN_HOUSE/spectra/lnhb/Pu-239.txt b/HEN_HOUSE/spectra/lnhb/Pu-239.txt new file mode 100644 index 000000000..c98228681 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Pu-239.txt @@ -0,0 +1,515 @@ +235U 239PU A DECAY (24100 Y) +235U H TYP=Full$AUT=V.P. Chechev$CUT=31-JAN-2007$ +235U C Evaluation history: Type=Full;Author=V.P. Chechev;Cutoff date=31-JAN-2007 +235U C References: 1952As28, 1952Se67, 1957As83, 1957No15, 1961Dz05, 1962Le11, +235U 2C 1963Bj03, 1963Ba09, 1965Ho04, 1965Tr03, 1966Ah02, 1966Ho09, 1967Be65, +235U 3C 1968Cl02, 1968Ba25, 1970OeZZ, 1971GuZY, 1975Ba65, 1975Al15, 1975GlZQ, +235U 4C 1976GuZN, 1976BaZZ, 1977Ja08, 1978Lu10, 1978Ma45, 1978Pr07, 1978Se12, +235U 5C 1979Al03, 1980RyZX, 1981AhZV, 1981UmZZ, 1982Ba56, 1982He02, 1983Ah02, +235U 6C 1984Di08, 1984Iw02, 1984Bo41, 1984Ah06, 1985Dr09, 1986Mi10, 1987Bo25, +235U 7C 1988ChZL, 1989Ho24, 1990GlZZ, 1990An33, 1991Ry01, 1992Bl07, 1992Bl13, +235U 8C 1992Co10, 1992Fr04, 1992Ba08, 1993Ga28, 1993Sc22, 1994Mo36, 1994Ra27, +235U 9C 1994Le37, 1994Le28, 1995Jo23, 1996Sa24, 1996Sc06, 1996Vi07, 1997Bu23, +235U 10C 1997Ko52, 1999ScZX, 1999Sa19, 2002Da21, 2002Ba85, 2003Au03, 2003Br12 +235U T Auger electrons and ^X ray energies and emission intensities: +235U T {U Energy (keV)} {U Intensity } {U Line } +235U T +235U T 94.666 0.00418 4 XKA2 +235U T 98.44 0.00661 9 XKA1 +235U T +235U T 110.421 |] XKB3 +235U T 111.298 |] 0.00239 3 XKB1 +235U T 111.964 |] XKB5II +235U T +235U T 114.407 |] XKB2 +235U T 115.012 |] 0.00131 6 XKB4 +235U T 115.377 |] XKO23 +235U T +235U T 11.619-20.714 4.66 5 XL (total) +235U T 11.619 0.1008 11 XLL +235U T 13.438-13.615 1.65 3 XLA +235U T 15.399 0.0537 19 XLC +235U T 15.727-18.206 2.288 23 XLB +235U T 19.507-20.714 0.569 6 XLG +235U T +235U T 71.78-80.95 |] KLL AUGER +235U T 88.15-98.34 |] 0.00045 6 ^KLX AUGER +235U T 104.42-115.4 |] KXY AUGER +235U T 5.9-21.6 4.66 19 L AUGER +239PU P 0.0 1/2+ 24100 Y 11 5244.51 21 +235U N 1.0 1.0 1 1.0 +235U G 14.22 3 0.0055 4 +235U G 40.41 5 1.63E-4 16 +235U G 74.96 103.8E-5 6 +235U G 184.55 5 2.1E-6 6 [M1] 3.87 8 +235U G 193.13 129.0E-6 9 +235U G 196.87 5 3.7E-6 4 +235U G 350.8 3 1.8E-6 4 +235U G 446.82 208.5E-7 13 +235U G 497.0 5 4.4E-8 25 +235U G 538.8 2 3.09E-7 19 +235U G 557.3 5 3.8E-8 19 +235U G 608.9 2 1.17E-7 12 +235U G 650.53 6 2.7E-7 4 +235U G 685.97 111.26E-6 6 E1 0.0073615 +235U G 688.1 3 1.12E-7 11 +235U G 693.2 5 3.2E-8 13 +235U G 699.6 5 8.0E-8 16 +235U G 712.96 5 5.2E-8 6 +235U G 742.7 5 3.8E-8 11 +235U G 777.1 3 2.8E-8 7 +235U G 786.9 2 8.7E-8 9 E2 0.0177 4 +235U G 788.5 3 3.5E-8 7 +235U G 796.9 3 1.5E-8 3 +235U G 803.2 2 6.4E-8 5 +235U G 826.8 3 1.8E-8 6 +235U G 828.9 2 1.34E-7 8 +235U G 837.3 2 2.0E-8 4 +235U G 895.4 3 7.6E-9 25 +235U G 898.1 3 1.8E-8 4 +235U G 905.5 3 7.6E-9 25 +235U G 911.7 3 1.4E-8 3 +235U G 931.9 3 1.3E-8 4 +235U G 982.7 3 1.07E-8 25 +235U G 1009.4 3 1.39E-8 25 +235U L 0 7/2- 704E6 Y 1 +235U A 5156.65 210.03 6500 +235U L 0.0765 4 1/2+ 26 M +235U A 5156.59 1470.79 102.762 +235U 2 G KC=$LC=$MC= +235U L 13.0400 213/2+ 0.50 NS 3 +235U A 5143.82 2117.14 4 9.47 +235U G 12.975 100.0341 9 M1+()E2 607 17 +235U 2 G KC=$LC=$MC=451 13 +235U L 46.207 109/2- +235U A 5111.21 210.02 5019 +235U G 46.21 5 7.26E-4 13M1+()E2 52.6 27 +235U 2 G KC=$LC=39.4 19$MC=9.8 5 +235U L 51.7007 115/2+ 191 PS 5 +235U A 5105.81 2111.87 3 7.81 +235U G 38.661 2 0.01047 21M1+()E2 339 19 +235U 2 G KC=$LC=249 14$MC=67 4 +235U G 51.624 1 0.02694 26E2 310 6 +235U 2 G KC=$LC=226 5$MC=62.6 13 +235U L 81.741 4 7/2+ +235U A 5076.28 210.052 8 1150 +235U G 30.04 2 2.19E-4 8 (M1) 157 3 +235U 2 G KC=$LC=118.0 24$MC=28.7 6 +235U G 68.696 6 0.00036 10E2 78.6 16 +235U 2 G KC=$LC=57.3 11$MC=15.9 3 +235U L 103.035 1011/2- +235U A 5055.34 210.0375 121160 +235U G 56.828 3 1136E-6 15M1+()E2 32.6 15 +235U 2 G KC=$LC=24.3 11$MC=6.14 30 +235U G 103.06 3 2.17E-4 6 E2 11.58 23 +235U 2 G KC=$LC=8.44 17$MC=2.34 5 +235U L 129.2961 105/2+ +235U A 5029.51 210.013 4 2270 +235U G 47.60 3 6.25E-5 25(M1) 40.4 8 +235U 2 G KC=$LC=30.4 6$MC=7.37 15 +235U G 77.592 143.80E-4 6 M1(+()E2) 17 10 +235U 2 G KC=$LC=12 7$MC=3.2 21 +235U G 116.26 2 5.81E-4 19M1+()E2 12.2 26 +235U 2 G KC=8.4 18$LC=2.9 6$MC=0.74 16 +235U G 129.296 1 0.00631 4 E1 0.275 6 +235U 2 G KC=0.211 4$LC=0.0482 10$MC=0.01173 24 +235U L 150.467 159/2+ +235U A 5008.70 210.0182 271180 +235U G 68.73 2 0.00013 6 (M1+E2) 27.00000 +235U 2 G KC=$LC=20.0000 0$MC=5.20000 0 +235U G 98.78 2 0.00135 11E2 14.1 3 +235U 2 G KC=$LC=10.28 21$MC=2.85 6 +235U L 170.708 1413/2- +235U G 67.674 121.58E-4 5 M1+()E2 16.9 5 +235U 2 G KC=$LC=12.7 4$MC=3.15 9 +235U G 124.51 3 6.81E-5 19E2 5.06 10 +235U 2 G KC=0.214 4$LC=3.53 7$MC=0.978 20 +235U L 171.388 5 7/2+ +235U A 4988.13 210.0034 104600 +235U G 41.93 5 1.63E-4 8 (M1) 58.6 12 +235U 2 G KC=$LC=44.2 9$MC=10.71 21 +235U G 89.64 3 2.7E-5 2 (M1+E2) 14 8 +235U 2 G KC=$LC=11 6$MC=2.8 17 +235U G 119.70 3 2.1E-5 3 (M1+E2) 9 4 +235U 2 G KC=5 5$LC=3.1 11$MC=0.8 3 +235U G 125.21 105.63E-5 16[E1] 0.296 6 +235U 2 G KC=0.227 5$LC=0.0523 10$MC=0.0128 3 +235U G 158.1 3 1.01E-6 10[E2] 1.86 4 +235U 2 G KC=0.211 4$LC=1.200 24$MC=0.333 7 +235U G 171.393 6 1.10E-4 3 [E1] 0.141 3 +235U 2 G KC=0.1103 22$LC=0.0235 5$MC=0.00570 11 +235U L 197.119 1411/2+ +235U A 4962.83 210.007 1 1520 +235U G 46.68 3 5.0E-5 6 M1+()E2 86 24 +235U 2 G KC=$LC=63 17$MC=17 5 +235U G 115.38 5 0.00046 5 E2 6.87 14 +235U 2 G KC=$LC=5.0 1$MC=1.39 3 +235U L 225.423 8 9/2+ +235U A 4935.00 210.0050 7 1380 +235U G 54.039 8 1943E-7 28M1 27.8 6 +235U 2 G KC=$LC=21.0 4$MC=5.08 10 +235U G 96.14 3 3.79E-5 19[E2] 16.0 3 +235U 2 G KC=$LC=11.67 23$MC=3.24 7 +235U G 122.35 129.5E-7 13(E1) 0.312 6 +235U 2 G KC=0.238 5$LC=0.0556 11$MC=0.0135 3 +235U G 143.35 201.74E-5 8 [M1+E2] 5.3 26 +235U 2 G KC=3.3 30$LC=1.5 3$MC=0.41 11 +235U G 173.70 5 3.1E-6 8 [E2] 1.28 3 +235U 2 G KC=0.190 4$LC=0.795 16$MC=0.220 4 +235U G 179.220 126.56E-5 19[E1] 0.127 3 +235U 2 G KC=0.0995 20$LC=0.0210 4$MC=0.00509 10 +235U G 225.42 4 1.50E-5 4 [E1] 0.0747 15 +235U 2 G KC=0.0589 12$LC=0.01190 24$MC=0.00288 6 +235U L 249.130 1215/2- +235U A 4911.69 210.0030 161590 +235U G 78.43 2 1533E-7 28M1(+()E2) 16 10 +235U 2 G KC=$LC=12 7$MC=3.1 20 +235U G 146.094 6 1.21E-4 3 E2 2.57 5 +235U 2 G KC=0.223 4$LC=1.71 3$MC=0.474 10 +235U L 291.144 1911/2+ +235U A 4870.38 210.0007 3 3500 +235U G 65.708 304.73E-5 25M1+()E2 19 6 +235U 2 G KC=$LC=14 5$MC=3.6 13 +235U G 119.76 2 9E-6 2 [E2] 5.99 12 +235U 2 G KC=0.200 4$LC=4.22 8$MC=1.169 23 +235U G 188.23 101.10E-5 11[E1] 0.1140 23 +235U 2 G KC=0.0889 18$LC=0.0186 4$MC=0.00450 9 +235U G 244.92 5 5.1E-6 5 0.0618 12 +235U 2 G KC=0.0485 10$LC=0.00973 19$MC=0.00235 5 +235U L 294.669 1513/2+ +235U A 4866.91 210.0018 5 1300 +235U G 97.6 3 0.00009 6 M1+()E2 7.0 19 +235U 2 G KC=$LC=5.2 14$MC=1.3 4 +235U G 144.201 3 2.85E-4 7 E2 2.72 5 +235U 2 G KC=0.225 5$LC=1.82 4$MC=0.502 10 +235U L 332.845 4 5/2+ +235U A 4829.38 210.00354 7 363 +235U G 161.450 151.22E-4 6 (M1) 5.67 11 +235U 2 G KC=4.51 9$LC=0.880 18$MC=0.213 4 +235U G 203.550 5 5.63E-4 9 M1 2.95 6 +235U 2 G KC=2.35 5$LC=0.456 9$MC=0.1103 22 +235U G 281.2 2 2.1E-6 3 [M1+E2] 0.7 5 +235U 2 G KC=0.5 4$LC=0.14 4$MC=0.036 8 +235U G 319.68 104.9E-6 5 [M1+E2] 0.50 35 +235U 2 G KC=0.37 30$LC=0.10 3$MC=0.024 7 +235U G 332.845 5 4.88E-4 8 E1 0.0313 6 +235U 2 G KC=0.0250 5$LC=0.00476 10$MC=1150E-6 23 +235U L 338.52 6 17/2- +235U A 4823.80 2222000E-9 53000 +235U G 89.39 6 2000E-9 0 [M1] 6.40 13 +235U 2 G KC=$LC=4.82 10$MC=1.167 23 +235U G 167.81 5 3.0E-6 8 [E2] 1.47 3 +235U 2 G KC=0.198 4$LC=0.925 19$MC=0.256 5 +235U L 357.30 6 15/2+ +235U A 4805.33 2217000E-94 51000 +235U G 160.19 5 6.2E-6 13[E2] 1.77 4 +235U 2 G KC=0.208 4$LC=1.140 23$MC=0.314 6 +235U L 367.069 8 7/2+ +235U A 4795.73 2194400E-817788 +235U G 141.657 203.21E-5 10[M1] 8.22 16 +235U 2 G KC=6.52 13$LC=1.28 3$MC=0.309 6 +235U G 195.679 8 1.06E-4 2 M1 3.30 7 +235U 2 G KC=2.62 5$LC=0.51 1$MC=0.123 3 +235U G 237.77 101.45E-5 6 [M1] 1.91 4 +235U 2 G KC=1.52 3$LC=0.295 6$MC=0.0712 14 +235U G 285.3 2 1.9E-6 4 [M1+E2] 0.7 5 +235U 2 G KC=0.5 4$LC=0.14 4$MC=0.035 8 +235U G 320.862 205.40E-5 12[E1] 0.0337 7 +235U 2 G KC=0.0269 5$LC=0.00517 10$MC=0.00125 3 +235U G 354.0 5 7.6E-7 30[E2] 0.1150 23 +235U 2 G KC=0.0549 11$LC=0.0445 9$MC=0.01200 24 +235U G 367.073 258.71E-5 20[E1] 0.0254 5 +235U 2 G KC=0.0203 4$LC=0.00382 8$MC=9.20E-4 18 +235U L 393.225 6 3/2+ +235U A 4770.01 210.00125 3 390 +235U G 263.95 3 2.59E-5 10M1 1.43 3 +235U 2 G KC=1.140 23$LC=0.220 4$MC=0.0532 11 +235U G 341.506 106.50E-5 13M1 0.701 14 +235U 2 G KC=0.559 11$LC=0.1080 22$MC=0.0260 5 +235U G 380.191 6 3.02E-4 4 M1 0.523 10 +235U 2 G KC=0.417 8$LC=0.0801 16$MC=0.0193 4 +235U G 393.14 3 4.19E-4 17M1 0.477 10 +235U 2 G KC=0.380 8$LC=0.0731 15$MC=0.0176 4 +235U L 414.779 119/2+ +235U A 4748.81 210.00075 11460 +235U G 123.62 5 2.37E-5 9 [M1] 12.08 24 +235U 2 G KC=9.57 19$LC=1.89 4$MC=0.457 9 +235U G 189.36 1 8.20E-5 14[M1+E2] 2.3 14 +235U 2 G KC=1.5 13$LC=0.553 11$MC=0.143 8 +235U G 218.0 5 1.2E-6 10 +235U G 243.38 3 2.54E-5 7 [M1+E2] 1.1 7 +235U 2 G KC=0.8 6$LC=0.23 4$MC=0.059 7 +235U G 311.78 4 2.57E-5 8 [E1] 0.0361 7 +235U 2 G KC=0.0287 6$LC=0.00552 11$MC=0.00133 3 +235U G 368.554 208.77E-5 14[E1] 0.0252 5 +235U 2 G KC=0.0202 4$LC=0.00378 8$MC=9.10E-4 18 +235U L 426.755 3 5/2+ +235U A 4737.05 210.00570 5 49.6 +235U G 255.384 157.95E-5 20[M1] 1.57 3 +235U 2 G KC=1.25 3$LC=0.241 5$MC=0.0583 12 +235U G 297.46 3 4.92E-5 13[M1] 1.025 21 +235U 2 G KC=0.816 16$LC=0.158 3$MC=0.0381 8 +235U G 345.013 4 5.48E-4 8 M1 0.682 14 +235U 2 G KC=0.543 11$LC=0.1050 21$MC=0.0253 5 +235U G 375.054 3 1540E-6 21M1 0.543 11 +235U 2 G KC=0.432 9$LC=0.0832 17$MC=0.0201 4 +235U G 413.713 5 1464E-6 21M1 0.415 8 +235U 2 G KC=0.331 7$LC=0.0636 13$MC=0.0153 3 +235U G 426.68 3 2.39E-5 6 [E2] 0.0699 14 +235U 2 G KC=0.0387 8$LC=0.0230 5$MC=0.00610 12 +235U L 445.716 207/2+ +235U A 4718.39 2140000E-9115200 +235U G 316.41 3 1.33E-5 5 M1 0.865 17 +235U 2 G KC=0.689 14$LC=0.133 3$MC=0.0321 6 +235U G 399.53 6 6.12E-6 26[E1] 0.0213 4 +235U 2 G KC=0.0171 3$LC=0.00317 6$MC=7.61E-4 15 +235U G 445.72 3 8.77E-6 26E1 0.0170 3 +235U 2 G KC=0.0137 3$LC=0.00250 5$MC=5.60E-4 11 +235U L 474.297 137/2+ +235U A 4690.29 210.00056 5 230 +235U G 248.95 5 7.0E-6 6 [M1] 1.68 3 +235U 2 G KC=1.34 3$LC=0.259 5$MC=0.0626 14 +235U G 302.87 5 4.9E-6 4 [M1] 0.976 20 +235U 2 G KC=0.777 16$LC=0.150 3$MC=0.0362 7 +235U G 323.84 3 5.30E-5 13M1 0.811 16 +235U 2 G KC=0.646 13$LC=0.1246 25$MC=0.0301 6 +235U G 345.00 2 5000E-8 0 (M1) 0.682 14 +235U 2 G KC=0.543 11$LC=0.1050 21$MC=0.0253 5 +235U G 392.53 3 1.21E-4 16M1 0.479 10 +235U 2 G KC=0.382 8$LC=0.0731 15$MC=0.0177 4 +235U G 422.598 191199E-7 20M1 0.392 8 +235U 2 G KC=0.313 6$LC=0.0560 11$MC=0.0145 3 +235U G 428.4 3 1.01E-6 10[E1] 0.0184 4 +235U 2 G KC=0.0147 3$LC=0.00270 5$MC=6.53E-4 13 +235U G 461.25 5 2.29E-6 5 [E2] 0.0575 12 +235U 2 G KC=0.0334 7$LC=0.0177 4$MC=0.00467 9 +235U G 473.9 5 6E-8 3 [E1] 0.0150 3 +235U 2 G KC=0.01210 24$LC=0.00220 4$MC=5.26E-4 11 +235U L 509.92 17(9/2+)+ +235U A 4655.27 2733000E-17 22000 +235U G 406.8 2 2.9E-6 7 [E1] 0.0204 4 +235U 2 G KC=0.0164 3$LC=0.00304 6$MC=7.31E-4 15 +235U G 463.9 3 2.8E-7 3 [E1] 0.0157 3 +235U 2 G KC=0.0126 3$LC=0.00230 5$MC=5.51E-4 11 +235U L 533.228 109/2+ +235U A 4632.35 210.00086 3 55.8 +235U G 242.08 3 7.4E-6 5 [M1] 1.82 4 +235U 2 G KC=1.45 3$LC=0.280 6$MC=0.0678 14 +235U G 307.85 5 5.2E-6 4 [M1] 0.933 19 +235U 2 G KC=0.743 15$LC=0.143 3$MC=0.0346 7 +235U G 336.113 121111E-7 26M1 0.733 15 +235U 2 G KC=0.583 12$LC=0.1130 23$MC=0.0272 5 +235U G 361.89 5 1.17E-5 7 [M1] 0.598 12 +235U 2 G KC=0.477 10$LC=0.0918 18$MC=0.0222 4 +235U G 382.75 5 2.56E-4 4 M1 0.513 10 +235U 2 G KC=0.409 8$LC=0.0787 16$MC=0.0190 4 +235U G 430.08 104.29E-6 19[E1] 0.0183 4 +235U 2 G KC=0.0147 3$LC=0.00270 5$MC=6.48E-4 13 +235U G 451.481 101.87E-4 3 M1(+E2) 0.19 13 +235U 2 G KC=0.15 11$LC=0.035 16$MC=0.009 4 +235U G 481.66 124.61E-6 10[E2] 0.0517 10 +235U 2 G KC=0.0309 6$LC=0.0154 3$MC=0.00404 8 +235U G 487.06 102.65E-7 19[E1] 0.0142 3 +235U 2 G KC=0.01150 23$LC=0.00208 4$MC=4.97E-4 10 +235U L 608.08 5 11/2+ +235U A 4558.75 2212000E-94 1110 +235U G 411.2 3 6.9E-6 30[M1] 0.422 8 +235U 2 G KC=0.337 7$LC=0.0646 13$MC=0.0156 3 +235U G 457.61 5 1.51E-6 3 [M1] 0.316 6 +235U 2 G KC=0.252 5$LC=0.0483 10$MC=0.01170 23 +235U G 526.4 4 5.7E-8 19[E2] 0.0419 8 +235U 2 G KC=0.0262 5$LC=1160E-5 2$MC=0.00303 6 +235U L 633.17 6 (5/2)- +235U A 4534.08 2228400E-17 3025 +235U G 633.15 6 2.55E-6 6 M1(+E2) 0.122 11 +235U 2 G KC=0.097 8$LC=0.0187 13$MC=0.0045 3 +235U L 637.81 5 3/2- +235U A 4529.52 2232200E-1212460 +235U G 586.3 3 1.53E-7 16[E1] 0.0099 2 +235U 2 G KC=0.00802 16$LC=0.00142 3$MC=3.39E-4 7 +235U G 624.78 5 4.60E-7 19[E1] 0.0087718 +235U 2 G KC=0.00712 14$LC=1250E-6 25$MC=2.99E-4 6 +235U G 637.73 5 6.4E-7 6 [E1] 0.0084417 +235U 2 G KC=0.00684 14$LC=1200E-6 24$MC=2.87E-4 6 +235U G 637.80 5 1.92E-6 19E2 0.0273 5 +235U 2 G KC=0.0185 4$LC=0.00655 13$MC=0.00167 3 +235U L 658.97 4 1/2- +235U A 4508.72 2126400E-96 207 +235U G 265.7 3 1.6E-6 4 [E1] 0.0514 10 +235U 2 G KC=0.0408 8$LC=0.00802 16$MC=0.00194 4 +235U G 645.94 4 1.49E-5 3 E1 0.0082416 +235U 2 G KC=0.00669 13$LC=1170E-6 24$MC=2.80E-4 6 +235U G 658.86 6 9.59E-6 26E1 0.0079416 +235U 2 G KC=0.00645 13$LC=1130E-6 23$MC=2.69E-4 5 +235U L 664.541 23(5/2)- +235U A 4503.24 2163100E-111784 +235U G 493.08 5 8.8E-7 3 [E1] 0.0139 3 +235U 2 G KC=0.01119 22$LC=0.00202 4$MC=4.84E-4 10 +235U G 582.89 106.18E-7 26[E1] 0.0100 2 +235U 2 G KC=0.00811 16$LC=0.00144 3$MC=3.43E-4 7 +235U G 612.83 3 9.5E-7 5 E1 0.0091018 +235U 2 G KC=0.00738 15$LC=0.00130 3$MC=3.10E-4 6 +235U G 618.28 6 2.06E-6 8 (E2) 0.0292 6 +235U 2 G KC=0.0196 4$LC=0.00716 14$MC=0.00184 4 +235U G 664.58 5 1.67E-6 4 E2 0.0251 5 +235U 2 G KC=0.0172 4$LC=0.00583 12$MC=0.00149 3 +235U L 670.99 4 (7/2)- +235U A 4496.90 2134000E-1 130000 +235U G 624.78 3 220E-10 0 (M1) 0.137 3 +235U 2 G KC=0.1090 22$LC=0.0208 4$MC=0.00501 10 +235U G 670.99 4 9E-9 3 [M1+E2] 0.06 4 +235U 2 G KC=0.05 3$LC=0.0033 17$MC=0.0025 12 +235U L 701.02 3 (7/2)- +235U A 4467.37 2170700E-113366 +235U G 550.5 2 4.35E-7 25(E1) 0.0112022 +235U 2 G KC=0.00904 18$LC=0.00161 3$MC=3.85E-4 8 +235U G 597.99 5 1.74E-6 6 [E2] 0.0314 6 +235U 2 G KC=0.0208 4$LC=0.00789 16$MC=0.00204 4 +235U G 619.21 6 1.21E-6 8 [E1] 0.0089218 +235U 2 G KC=0.00724 14$LC=0.00127 3$MC=3.04E-4 6 +235U G 649.32 6 7.2E-7 5 [E1] 0.0081616 +235U 2 G KC=0.00662 13$LC=1160E-6 23$MC=2.77E-4 6 +235U G 654.88 8 2.27E-6 5 (E2) 0.0258 5 +235U 2 G KC=0.0177 4$LC=0.00607 12$MC=0.00156 3 +235U G 701.1 2 5.24E-7 19[M1+E2] 0.06 4 +235U 2 G KC=0.05 3$LC=0.010 5$MC=0.0025 12 +235U L 703.757 193/2- +235U A 4464.68 2111400E-93 216 +235U G 652.05 2 6.63E-6 20E1 0.0080916 +235U 2 G KC=0.00657 13$LC=1150E-6 23$MC=2.74E-4 5 +235U G 690.81 8 5.9E-7 5 E1 0.0072715 +235U 2 G KC=0.00591 12$LC=1030E-6 21$MC=2.45E-4 5 +235U G 703.68 5 4.10E-6 13E1 0.0070214 +235U 2 G KC=0.00571 12$LC=9.93E-4 20$MC=2.37E-4 5 +235U L 720.25 3 (9/2)- +235U A 4448.46 2121300E-19 859 +235U G 617.1 1 1.35E-6 8 [M1] 0.142 3 +235U 2 G KC=0.1130 23$LC=0.0215 4$MC=0.00518 10 +235U G 674.05 3 5.0E-7 2 0.1120 22 +235U 2 G KC=0.0893 18$LC=0.0169 3$MC=0.00408 8 +235U G 720.3 5 2.9E-8 5 +235U L 750.07 16(9/2)- +235U A 4419.14 2634000E-14 3140 +235U G 579.4 3 8.8E-8 19[E2] 0.0337 7 +235U 2 G KC=0.0220 4$LC=0.00867 17$MC=0.00224 4 +235U G 599.6 2 2.02E-7 25[E1] 0.0094819 +235U 2 G KC=0.00769 15$LC=0.00136 3$MC=3.24E-4 6 +235U G 668.2 5 4.0E-8 12[E1] 0.0077315 +235U 2 G KC=0.00628 13$LC=1100E-6 22$MC=2.62E-4 5 +235U L 761.04 5 (1/2)- +235U A 4408.36 2210300E-1178500 +235U G 123.228 5 1.6E-9 4 (M1) 12.19 24 +235U 2 G KC=9.66 19$LC=1.91 4$MC=0.461 9 +235U G 747.4 5 8.1E-8 16E1 0.0062913 +235U 2 G KC=0.00512 10$LC=8.80E-4 18$MC=2.11E-4 4 +235U L 769.27 6 1/2+ +235U A 4400.26 2127000E-93 28 +235U G 639.99 108.46E-6 20[E2] 0.0271 5 +235U 2 G KC=0.0184 4$LC=0.00648 13$MC=0.00167 3 +235U G 756.23 6 2.8E-6 5 [M1+E2] 0.05 3 +235U 2 G KC=0.04 3$LC=0.008 4$MC=0.002 1 +235U G 769.15 8 5.1E-6 10M1+ 2.0 2 +235U 2 G KC=$LC=$MC= +235U L 769.5 3 3/2- +235U A 4400.0 4 10300E-91273 +235U G 718.0 5 2.76E-6 6 E1 0.0067714 +235U 2 G KC=0.00551 11$LC=9.60E-4 19$MC=2.27E-4 5 +235U G 756.4 4 6.9E-7 19[E1] 0.0061512 +235U 2 G KC=0.00501 10$LC=8.65E-4 17$MC=2.06E-4 4 +235U G 769.4 5 6.8E-6 12E1 0.0059612 +235U 2 G KC=0.00486 10$LC=8.37E-4 17$MC=1.99E-4 4 +235U L 777.59 19(11/2)- +235U A 4392.08 2824700E-1192610 +235U G 606.9 2 1.21E-7 13M1(+E2) 0.12 3 +235U 2 G KC=0.09 3$LC=0.019 4$MC=0.0045 9 +235U G 674.4 5 1.0E-7 1 (M1) 0.1120 22 +235U 2 G KC=0.0892 18$LC=0.0169 3$MC=0.00408 8 +235U L 779.51 3 (3/2)+ +235U A 4390.20 2110100E-111616 +235U G 697.8 5 7.4E-8 15 +235U G 727.9 2 1.25E-7 7 M1 0.0911 18 +235U 2 G KC=0.0728 15$LC=0.0138 3$MC=0.00332 7 +235U G 766.47 3 1.3E-7 2 +M1 4.0 4 +235U 2 G KC=$LC=$MC= +235U G 779.43 3 1.37E-7 9 M1 0.0759 15 +235U 2 G KC=0.0607 12$LC=0.01148 23$MC=0.00276 6 +235U L 805.72 6 3/2- +235U A 4364.42 2284000E-1144560 +235U G 172.560 8 300E-11 0 M1 4.70 9 +235U 2 G KC=3.73 8$LC=0.728 15$MC=0.176 4 +235U G 412.49 6 180E-10 0 [E1] 0.0199 4 +235U 2 G KC=0.0160 3$LC=0.00296 6$MC=7.09E-4 14 +235U G 792.68 6 2.0E-8 4 (E1) 0.0056511 +235U 2 G KC=0.00461 9$LC=7.90E-4 16$MC=1.88E-4 4 +235U G 805.65 6 2.8E-8 4 E2 0.0169 3 +235U 2 G KC=0.01220 24$LC=0.00348 7$MC=8.80E-4 18 +235U L 821.25 4 5/2+ +235U A 4349.15 2130000E-13 960 +235U G 596.0 5 3.9E-8 12[E2] 0.0317 6 +235U 2 G KC=0.0209 4$LC=0.00797 16$MC=0.00206 4 +235U G 670.8 5 9E-9 3 +235U G 769.54 4 +235U G 808.21 4 1.22E-7 6 M1 0.0690 14 +235U 2 G KC=0.0552 11$LC=0.01040 21$MC=0.00251 5 +235U G 821.25 4 5.0E-8 11E1+M2 +235U L 843.858 10(1/2)+ +235U A 4326.92 2122800E-112825 +235U G 714.71 147.9E-8 8 E2 0.0215 4 +235U 2 G KC=0.0151 3$LC=0.00477 10$MC=1225E-6 25 +235U G 843.78 1 1.35E-7 8 M1(+) 0.09 1 +235U 2 G KC=$LC=$MC= +235U L 845.3 10(7/2)+ +235U A 4325.5 1042000E-1 4360 +235U G 763.60 15220E-10 0 (+M1) 0.900000 +235U 2 G KC=$LC=$MC= +235U L 865.35 183/2+ +235U A 4305.79 2898000E-1131280 +235U G 693.81 1 1.9E-8 7 (E2) 0.0229 5 +235U 2 G KC=0.0159 3$LC=0.00517 10$MC=0.00132 3 +235U G 736.5 5 3.0E-8 9 M1+()E2 0.0481 10 +235U 2 G KC=0.0374 7$LC=0.00807 16$MC=0.00198 4 +235U G 813.7 2 4.5E-8 5 M1 0.0677 14 +235U 2 G KC=0.0542 11$LC=0.01020 21$MC=0.00246 5 +235U L 891.89 155/2+ +235U A 4279.70 2619900E-112380 +235U G 720.55 3 2.0E-8 2 +235U G 762.6 2 100E-10 0 +235U G 840.4 2 4.9E-8 5 M1(+) 0.14 2 +235U 2 G KC=$LC=$MC= +235U G 879.2 3 3.6E-8 4 [M1+E2] 0.035 20 +235U 2 G KC=0.027 17$LC=0.006 3$MC=0.0014 7 +235U G 891.0 3 7.5E-8 8 [E2] 0.0139 3 +235U 2 G KC=0.0102 2$LC=0.00270 5$MC=6.77E-4 14 +235U L 968.451 203/2+ +235U A 4204.42 2161000E-115281 +235U G 955.41 2 3.1E-8 3 M1+()E2 0.036 4 +235U 2 G KC=0.029 3$LC=0.0055 6$MC=0.00133 13 +235U G 968.37 2 280E-10 0 M1+()E2 0.035 19 +235U 2 G KC=0.0028 15$LC=0.0053 29$MC=0.0013 7 +235U L 970.52 22(5/2,7/2)+ +235U A 4202.4 3 41000E-14 402 +235U G 918.7 3 8.8E-9 30 +235U G 957.6 3 3.2E-8 3 +235U L 986.65 17(13/2-)- +235U A 4186.53 2777000E-17 156 +235U G 816.0 2 2.5E-8 4 [M1+E2] 0.042 25 +235U 2 G KC=0.033 21$LC=0.007 3$MC=0.0016 8 +235U G 940.3 3 5.0E-8 5 [E2] 0.0125025 +235U 2 G KC=0.00932 19$LC=0.00237 5$MC=5.91E-4 12 +235U L 992.72 22(5/2+)+ +235U A 4180.6 3 20000E-13 53 +235U G 767.29 4 1.4E-7 3 +235U G 821.3 2 600E-11 0 +235U G 979.7 3 2.8E-8 5 [M1+E2] 0.026 15 +235U 2 G KC=0.021 12$LC=0.0042 20$MC=0.0010 5 +235U G 992.64 3 2.7E-8 4 +235U L 1057.58 13(7/2)+ +235U A 4116.78 2593000E-19 31 +235U G 832.2 2 3.0E-8 4 +235U G 1005.7 3 1.77E-8 25 +235U G 1057.3 2 4.5E-8 7 +235U L 1116.2 2 (5/2-)- +235U A 4059.1 3 21000E-15 41 +235U G 986.90 4 2.1E-8 5 E1 0.003838 +235U 2 G KC=0.00313 6$LC=5.29E-4 11$MC=1260E-7 25 + diff --git a/HEN_HOUSE/spectra/lnhb/Pu-240.txt b/HEN_HOUSE/spectra/lnhb/Pu-240.txt new file mode 100644 index 000000000..36c29e64b --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Pu-240.txt @@ -0,0 +1,97 @@ +236U 240PU A DECAY (6561 Y) +236U H TYP=Update$AUT=V.P. Chechev$CUT= -- $ +236U C Evaluation history: Type=Update;Author=V.P. Chechev;Cutoff date= -- +236U C References: 1951In03, 1951We21, 1952As28, 1953Ki72, 1954Ba14, 1954Ch74, +236U 2C 1956Bu92, 1956Go43, 1956Ko67, 1957As83, 1958Sa21, 1959Tr37, 1959Mi90, +236U 3C 1962Wa13, 1962Le11, 1963Ma50, 1964Hy02, 1967Be65, 1967Fi13, 1968Oe02, +236U 4C 1969Le05, 1971GuZY, 1972Sc01, 1972ClZS, 1972Go33, 1974HeYW, 1975Dr05, +236U 5C 1975OtZX, 1976GuZN, 1976Um01, 1977Ba69, 1978Ja11, 1979BuZC, 1981He16, +236U 6C 1982Ba56, 1983Ah02, 1984An25, 1984St06, 1984Ru04, 1984Lu04, 1984Be19, +236U 7C 1984Ah06, 1984Bo41, 1986LoZT, 1988SeZY, 1989Dy01, 1991Ry01, 1991Iv01, +236U 8C 1990An33, 1992Ba08, 1992Bl13, 1994Le28, 1994Ba91, 1994Ra27, 1994Sa63, +236U 9C 1994Le37, 1995Jo23, 1996Vi07, 2000Ho27, 2003Au03, 2004BeZQ, 2004Si03, +236U 10C 2005ChZU, 2006Br20, 2007Ah05, 2008Ki07 +236U T Auger electrons and ^X ray energies and emission intensities: +236U T {U Energy (keV)} {U Intensity } {U Line } +236U T +236U T 94.666 0.0000260 6 XKA2 +236U T 98.44 0.0000416 9 XKA1 +236U T +236U T 110.421 |] XKB3 +236U T 111.298 |] 0.0000150 4 XKB1 +236U T 111.964 |] XKB5II +236U T +236U T 114.407 |] XKB2 +236U T 115.012 |] 0.00000513 16 XKB4 +236U T 115.377 |] XKO23 +236U T +236U T 11.619-20.714 10.34 15 XL (total) +236U T 11.619 0.238 4 XLL +236U T 13.438-13.615 3.70 4 XLA +236U T 15.399 0.116 3 XLC +236U T 15.727-18.206 5.01 13 XLB +236U T 19.507-20.714 1.267 22 XLG +236U T +236U T 71.78-80.95 |] KLL AUGER +236U T 88.15-98.43 |] 0.0000027 4 ^KLX AUGER +236U T 104.51-115.59 |] KXY AUGER +236U T 5.01-21.6 10.3 8 L AUGER +240PU P 0.0 0+ 6561 Y 7 5255.75 15 +236U N 1.0 1.0 1 1.0 +236U L 0 0+ 23.43E6 Y 6 +236U A 5168.13 1572.74 181 +236U L 45.244 2 2+ 234 PS 6 +236U A 5123.6 2 27.16 191.4 +236U G 45.244 2 0.0462 9 E2 589 12 +236U 2 G KC=$LC=429 9$MC=118.6 24 +236U L 149.477 6 4+ 124 PS 7 +236U A 5021.1 2 0.0863 1894.6 +236U G 104.233 5 0.00714 7 E2 10.99 22 +236U 2 G KC=$LC=8.00 16$MC=2.22 4 +236U L 309.785 7 6+ 58 PS 3 +236U A 4863.5 2 10820E-718646 +236U G 160.308 3 4045E-7 22E2 1.76 4 +236U 2 G KC=0.208 4$LC=1.132 23$MC=0.313 6 +236U L 522.25 5 8+ 24 PS 2 +236U A 4654.5 2 47000E-95 471 +236U G 212.46 5 2.9E-5 3 E2 0.599 12 +236U 2 G KC=0.140 3$LC=0.335 7$MC=0.0920 18 +236U L 687.59 4 1- 3.78 NS 9 +236U A 4492.0 2 19300E-94 65.9 +236U G 538.1 1 1.47E-7 12E3 0.143 3 +236U 2 G KC=0.0623 12$LC=0.0587 12$MC=0.0160 3 +236U G 642.34 5 1.26E-5 3 E1+(M2+E3) 0.15 2 +236U 2 G KC=0.112 10$LC=0.031 3$MC= +236U G 687.56 103.56E-6 9 E1 0.31 2 +236U 2 G KC=0.219 14$LC=0.069 9$MC= +236U L 744.18 7 3- +236U A 4436.4 2 13000E-17 35000 +236U G 56.6 5 (E2) 199 10 +236U 2 G KC=$LC=145 7$MC=40.1 19 +236U G 594.5 3 +236U G 698.94 250E-10 0 +236U L 919.14 170+ +236U A 4264.3 3 65000E-18 27 +236U G 874.0 2 5.8E-7 6 (E2) 0.0144 3 +236U 2 G KC=0.01060 15$LC=0.00283 6$MC=7.11E-4 14 +236U G 918.9 3 () +236U L 957.90 17(2)+ +236U A 4226.1 3 17000E-1 +236U G 912.4 3 700E-10 0 (M1) 0.050 1 +236U 2 G KC=0.0400 8$LC=0.00753 11$MC=0.00181 4 +236U G 958.0 2 100E-9 0 +236U L 960.3 3 (2)+ +236U A 4223.8 4 13000E-1 +236U G 810.8 430E-10 0 +236U G 915.1 3 630E-10 0 (M1+) +236U G 960.3 500E-10 0 +236U L 966.62 9 1- +236U A 4217.6 2 10000E-1 +236U G 222.44 +236U G 279.0 1 (M1+E2) 0.7 5 +236U 2 G KC=0.5 5$LC=0.15 4$MC=0.038 8 +236U G 921.2 2 220E-10 0 E1 0.004329 +236U 2 G KC=0.00353 7$LC=5.99E-4 12$MC=1.42E-4 3 +236U G 966.9 2 500E-10 0 E1 0.003978 +236U 2 G KC=0.00324 6$LC=5.49E-4 11$MC=1.30E-4 3 + diff --git a/HEN_HOUSE/spectra/lnhb/Pu-241.txt b/HEN_HOUSE/spectra/lnhb/Pu-241.txt new file mode 100644 index 000000000..fe82f1960 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Pu-241.txt @@ -0,0 +1,121 @@ +237U 241PU A DECAY (14.33 Y) +237U H TYP=Full$AUT=V.P.Chechev$CUT=30-SEP-2006$ +237U C Evaluation history: Type=Full;Author=V.P.Chechev;Cutoff date=30-SEP-2006 +237U C References: 1952Fr25, 1953As40, 1956Sh31, 1961Sm03, 1964Dz03, 1965Ba26, +237U 2C 1965Ba35, 1968Oe01, 1968Ah01, 1968Ba25, 1971GuZN, 1976BaZZ, 1976GuZN, +237U 3C 1976Um01, 1977VaYR, 1978DiZU, 1978El02, 1979Ce04, 1980Ma45, 1983DeZX, +237U 4C 1984Gl03, 1985Dr09, 1985He02, 1985Wi04, 1985Ag02, 1986Ti04, 1988ChZL, +237U 5C 1989Pa21, 1991Ry01, 1993Dr05, 1994Ba91, 1995Ak01, 1996FiZX, 1996Sc06, +237U 6C 1997DeZY, 1998Ak04, 1999Dr13, 1999ScZX, 1999YaZX, 2000Dr02, 2003Au03, +237U 7C 2004Fo01, 2005Ma88, 2006Ba41 +237U T Auger electrons and ^X ray energies and emission intensities: +237U T {U Energy (keV)} {U Intensity } {U Line } +237U T +237U T 94.666 0.000300 7 XKA2 +237U T 98.44 0.000479 10 XKA1 +237U T +237U T 110.421 |] XKB3 +237U T 111.298 |] 0.000179 5 XKB1 +237U T 111.964 |] XKB5II +237U T +237U T 114.407 |] XKB2 +237U T 115.012 |] 0.000059 2 XKB4 +237U T 115.377 |] XKO23 +237U T +237U T 11.619-20.714 0.001166 40 XL (total) +237U T 11.619 0.0000336 12 XLL +237U T 13.438-13.615 0.000543 19 XLA +237U T 15.399 0.00000444 13 XLC +237U T 15.727-18.206 0.000477 8 XLB +237U T 19.507-20.714 0.000109 2 XLG +237U T +237U T 71.776-80.954 |] KLL AUGER +237U T 88.153-98.429 |] 0.000031 5 ^KLX AUGER +237U T 104.51-115.59 |] KXY AUGER +237U T 5.9-21.6 0.00117 6 L AUGER +241PU P 0.0 5/2+ 14.33 Y 4 5140.0 5 +237U N 4.098E4 4.098E4 0.000024 4.098E4 +237U L 0 1/2+ 6.749 D 16 +237U A 5054.6 5 0.352 413600 +237U L 11.39 2 3/2+ +237U A 5043.4 5 1.02 8 1000 +237U G 11.39 2 +237U L 56.30 125/2+ +237U A 4999.2 5 0.410 491300 +237U G 44.86 108.4E-7 10[M1+()E2] 131 25 +237U 2 G KC=$LC=96 18$MC=25 4 +237U G 56.30 122.5E-6 2 (E2) 204 4 +237U 2 G KC=$LC=149 3$MC=41.1 8 +237U L 82.97 137/2+ +237U A 4973.1 5 1.31 12276 +237U G 26.66 4 (M1+E2) +237U G 71.64 9 2.9E-6 2 (E2) 64.3 13 +237U 2 G KC=$LC=46.8 10$MC=13.0 3 +237U L 159.96 2 5/2+ 3.1 NS 1 +237U A 4897.3 5 83.2 161.3 +237U G 77.01 4 2.07E-5 4 (M1) 9.86 20 +237U 2 G KC=$LC=7.44 15$MC=1.8 4 +237U G 103.680 5 1.03E-4 2 [M1+()E2] 4.20 9 +237U 2 G KC=$LC=3.16 7$MC=0.767 15 +237U G 148.567 101863E-7 8 [M1+()E2] 7.05 14 +237U 2 G KC=5.55 11$LC=1.13 3$MC=0.275 6 +237U G 159.96 2 6.45E-6 9 (E2) 1.78 3 +237U 2 G KC=0.208 4$LC=1.14 3$MC=0.316 7 +237U L 204.19 147/2+ +237U A 4853.8 5 12.09 334.5 +237U G 44.18 3 4.2E-6 2 M1+()E2 60.4 29 +237U 2 G KC=$LC=45.3 25$MC=11.2 7 +237U G 121.22 5 7.0E-7 7 (M1) 12.8 3 +237U 2 G KC=10.1 2$LC=2.00 4$MC=0.484 10 +237U L 260.95 179/2+ +237U A 4798.0 5 1.19 1218.6 +237U G 56.76 101.0E-6 1 M1+()E2 27 3 +237U 2 G KC=$LC=21 3$MC=5.0 9 +237U G 100.94 11720E-10 0 (E2) 12.8 3 +237U 2 G KC=$LC=9.3 2$MC=2.58 5 +237U L 274 1 (7/2)- 155 NS 6 +237U A 4785.1 110.020 8 90 +237U G 114 1 6.2E-6 12E1 0.0883 17 +237U 2 G KC=$LC=0.0665 13$MC=0.0163 3 +237U L 316 5 (9/2)- +237U A 4744 5 69672E-6 131 +237U L 327 3 11/2+ +237U A 4733 3 28689E-6 254 +237U L 367 3 (11/2)- +237U A 4694 3 28689E-6 132 + +241AM 241PU B- DECAY (14.33 Y) +241AM H TYP=Full$AUT=V.P.Chechev$CUT=30-SEP-2006$ +241AM C Evaluation history: Type=Full;Author=V.P.Chechev;Cutoff date=30-SEP-2006 +241AM C References: 1952Fr25, 1953As40, 1956Sh31, 1961Sm03, 1964Dz03, 1965Ba26, +241AM2C 1965Ba35, 1968Oe01, 1968Ah01, 1968Ba25, 1971GuZN, 1976BaZZ, 1976GuZN, +241AM3C 1976Um01, 1977VaYR, 1978DiZU, 1978El02, 1979Ce04, 1980Ma45, 1983DeZX, +241AM4C 1984Gl03, 1985Dr09, 1985He02, 1985Wi04, 1985Ag02, 1986Ti04, 1988ChZL, +241AM5C 1989Pa21, 1991Ry01, 1993Dr05, 1994Ba91, 1995Ak01, 1996FiZX, 1996Sc06, +241AM6C 1997DeZY, 1998Ak04, 1999Dr13, 1999ScZX, 1999YaZX, 2000Dr02, 2003Au03, +241AM7C 2004Fo01, 2005Ma88, 2006Ba41 +241AM T Auger electrons and ^X ray energies and emission intensities: +241AM T {U Energy (keV)} {U Intensity } {U Line } +241AM T +241AM T 102.03 XKA2 +241AM T 106.472 XKA1 +241AM T +241AM T 119.243 |] XKB3 +241AM T 120.284 |] XKB1 +241AM T 120.989 |] XKB5II +241AM T +241AM T 123.58 |] XKB2 +241AM T 124.127 |] XKB4 +241AM T 124.723 |] XKO23 +241AM T +241AM T +241AM T 77.04-85.638 |] KLL AUGER +241AM T 94.891-106.467 |] ^KLX AUGER +241AM T 112.72-124.97 |] KXY AUGER +241AM T 6.26-23.7 L AUGER +241PU P 0.0 5/2+ 14.33 Y 4 20.8 2 +241AM N 1.00E0 1.00E0 0.999975 1.00E0 +241AM L 0 5/2- 432.6 Y 6 +241AM B 20.8 2 99998E-32 5.8 +241AMS B EAV=5.8 1 + diff --git a/HEN_HOUSE/spectra/lnhb/Pu-242.txt b/HEN_HOUSE/spectra/lnhb/Pu-242.txt new file mode 100644 index 000000000..29ddf42e1 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Pu-242.txt @@ -0,0 +1,50 @@ +238U 242PU A DECAY (3.73E5 Y) +238U H TYP=Update$AUT=V.P. Chechev$CUT= -- $ +238U C Evaluation history: Type=Update;Author=V.P. Chechev;Cutoff date= -- +238U C References: 1956Bu64, 1956Bu92, 1956Hu96, 1956Ko67, 1956Me37, 1961Dr04, +238U 2C 1963Ma50, 1967Be65, 1968Ba25, 1969Be06, 1970Du02, 1972Sc01, 1976Bu23, +238U 3C 1976Os05, 1978MeZL, 1979Ag03, 1980Kh05, 1986LoZT, 1986Va33, 1988SeZY, +238U 4C 1990Po14, 1991Ry01, 1994Le37, 1996Sc06, 2000Ho27, 2002Ch52, 2003Au03, +238U 5C 2004BeZQ, 2005ChZU, 2008Ki07 +238U T Auger electrons and ^X ray energies and emission intensities: +238U T {U Energy (keV)} {U Intensity } {U Line } +238U T +238U T 94.666 0.0000180 13 XKA2 +238U T 98.44 0.0000288 21 XKA1 +238U T +238U T 110.421 |] XKB3 +238U T 111.298 |] 0.0000104 8 XKB1 +238U T 111.964 |] XKB5II +238U T +238U T 114.407 |] XKB2 +238U T 115.012 |] 0.00000355 27 XKB4 +238U T 115.377 |] XKO23 +238U T +238U T 11.62-21.73 8.71 21 XL (total) +238U T 11.62 0.191 7 XLL +238U T 13.44-13.62 3.07 10 XLA +238U T 15.4 0.098 4 XLC +238U T 15.73-18.21 4.33 13 XLB +238U T 19.51-21.73 1.021 30 XLG +238U T +238U T 71.78-80.95 |] KLL AUGER +238U T 88.15-98.43 |] 0.00000188 29 ^KLX AUGER +238U T 104.51-115.59 |] KXY AUGER +238U T 5.9-21.6 8.40 19 L AUGER +242PU P 0.0 0+ 3.73E5 Y 3 4984.5 10 +238U N 1.0 1.0 1 1.0 +238U L 0 0+ 4.468E9 Y 5 +238U A 4902.3 1076.53 171 +238U L 44.915 132+ 206 PS 3 +238U A 4858.2 1023.44 171.62 +238U G 44.915 130.0384 8 E2 610 12 +238U 2 G KC=$LC=445 9$MC=122.8 25 +238U L 148.39 3 4+ +238U A 4756.2 100.0304 13238 +238U G 103.50 4 0.00253 12E2 11.36 23 +238U 2 G KC=$LC=8.27 17$MC=2.29 5 +238U L 307.19 8 6+ +238U A 4600.1 100.00084 6 609 +238U G 158.80 8 2.98E-4 20E2 1.83 4 +238U 2 G KC=0.210 4$LC=1.180 24$MC=0.326 7 + diff --git a/HEN_HOUSE/spectra/lnhb/Ra-223.txt b/HEN_HOUSE/spectra/lnhb/Ra-223.txt new file mode 100644 index 000000000..7c6395ee4 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Ra-223.txt @@ -0,0 +1,204 @@ +219RN 223RA A DECAY (11.43 D) +219RN H TYP=Full$AUT=V.P. Chechev$CUT=30-DEC-2010$ +219RN C Evaluation history: Type=Full;Author=V.P. Chechev;Cutoff date=30-DEC-2010 +219RN C References: 1954Ha60, 1957Pi31, 1957Pa07, 1959Ro51, 1961Ry02, 1962Gi04, +219RN2C 1962Wa18, 1964Wa19, 1965Ki05, 1966Po02, 1967JoZX, 1968Br17, 1969Be67, +219RN3C 1970Da08, 1970Kr01, 1971Gr17, 1972HeYM, 1974Ri05, 1976Bl13, 1977La19, +219RN4C 1977Ma31, 1987Mi10, 1991Ma16, 1991Ry01, 1996Sc06, 1998Sh02, 2000Sc47, +219RN5C 2001Br31, 2003Au03, 2008Ki07 +219RN T Auger electrons and ^X ray energies and emission intensities: +219RN T {U Energy (keV)} {U Intensity } {U Line } +219RN T +219RN T 81.07 14.86 23 XKA2 +219RN T 83.78 24.5 4 XKA1 +219RN T +219RN T 94.247 |] XKB3 +219RN T 94.868 |] 8.50 18 XKB1 +219RN T 95.449 |] XKB5II +219RN T +219RN T 97.48 |] XKB2 +219RN T 97.853 |] 2.72 7 XKB4 +219RN T 98.357 |] XKO23 +219RN T +219RN T 10.1372-17.2578 22.1 4 XL (total) +219RN T 10.1372 0.562 15 XLL +219RN T 11.5981-11.7259 10.00 25 XLA +219RN T 12.8551 0.168 5 XLC +219RN T 13.5219-14.5189 9.44 18 XLB +219RN T 16.2398-17.2578 1.91 4 XLG +219RN T +219RN T 62.017-68.885 |] KLL AUGER +219RN T 75.744-83.785 |] 1.73 21 ^KLX AUGER +219RN T 89.45-98.39 |] KXY AUGER +219RN T 5.66-17.95 30.1 4 L AUGER +223RA P 0.0 3/2+ 11.43 D 3 5978.99 21 +219RN N 1.0 1.0 1 1.0 +219RN G 490.8 3 0.0017 7 +219RN G 523.2 4 0.0014 6 +219RN G 532.9 4 0.0014 6 +219RN G 737.2 8 0.00028 14 +219RN L 0 5/2+ 3.98 S 3 +219RN A 5871.63 211.0 2 2420 +219RN L 4.47 1 (9/2)+ 15.4 NS 13 +219RN G 4.47 1 6400E-9 0 E2 86000000 +219RN2 G KC=$LC=$MC=5100000 0 +219RN L 14.37 1 (7/2)+ 875 PS 30 +219RN A 5857.52 210.32 4 6480 +219RN G 9.90 2 0.0158 20M1+E2 0.050 2 990 40 +219RN2 G KC=$LC=$MC=750 30 +219RN G 14.37 1 0.0185 13M1+E2 0.116 2 539 15 +219RN2 G KC=$LC=$MC=409 11 +219RN L 126.77 2 (11/2)+ 402 PS 20 +219RN A 5747.14 2110.0 3 60 +219RN G 122.319 101.238 19M1+E2 0.132 14 7.34 11 +219RN2 G KC=5.88 9$LC=1.109 17$MC=0.265 4 +219RN L 158.64 1 7/2+ 42.3 PS 50 +219RN A 5715.84 2149.6 128.4 +219RN G 31.87 2 1.05E-4 21(E2) 2010 30 +219RN2 G KC=$LC=1490 22$MC=398 6 +219RN G 144.27 2 3.36 8 M1+E2 -0.12 1 4.59 7 +219RN2 G KC=3.69 6$LC=0.684 10$MC=0.1629 23 +219RN G 154.208 105.84 13M1 3.83 6 +219RN2 G KC=3.09 5$LC=0.560 8$MC=0.1331 19 +219RN G 158.635 100.713 16M1+E2 -0.18 11 3.46 12 +219RN2 G KC=2.77 13$LC=0.523 13$MC=0.125 4 +219RN L 269.48 1 3/2+ 14.2 PS 230 +219RN A 5606.99 2125.8 114.5 +219RN G 110.856 100.058 4 E2 5.36 8 +219RN2 G KC=0.363 5$LC=3.69 6$MC=0.994 14 +219RN G 255.2 2 0.048 7 +219RN G 269.463 1014.23 32M1+E2 0.15 4 0.789 14 +219RN2 G KC=0.637 12$LC=0.1157 17$MC=0.0275 4 +219RN L 338.27 1 (5/2)+ 6.1 PS 28 +219RN A 5539.43 2110.6 104.8 +219RN G 179.54 6 0.154 14M1+E2 0.53 5 2.12 7 +219RN2 G KC=1.62 7$LC=0.376 6$MC=0.0922 16 +219RN G 323.871 104.06 8 M1+E2 0.18 10 0.473 17 +219RN2 G KC=0.382 15$LC=0.0691 17$MC=0.0164 4 +219RN G 334.01 6 0.100 6 (E2) 0.1007 15 +219RN2 G KC=0.0546 8$LC=0.0343 5$MC=0.00895 13 +219RN G 338.282 102.85 6 M1 0.430 6 +219RN2 G KC=0.348 5$LC=0.0622 9$MC=0.01475 21 +219RN L 342.78 2 (5/2,7/2)- +219RN G 328.38 3 0.203 10(E1) 0.0271 4 +219RN2 G KC=0.0220 3$LC=0.00387 6$MC=9.16E-4 13 +219RN G 342.78 2 0.226 13E1 0.0246 4 +219RN2 G KC=0.0200 3$LC=0.00351 5$MC=8.28E-4 12 +219RN L 376.26 2 (9/2)+ 6.9 PS 38 +219RN A 5502.12 210.74 2544 +219RN G 249.49 3 0.038 10M1+E2 0.6 4 +219RN2 G KC=0.5 4$LC=0.125 20$MC=0.031 4 +219RN G 361.89 2 0.028 7 +219RN G 371.676 150.499 11M1 0.333 5 +219RN2 G KC=0.270 4$LC=0.0481 7$MC=0.01139 16 +219RN G 376.26 2 0.013 4 +219RN L 377.33 6 (7/2,9/2)- +219RN G 34.5 2 +219RN G 362.9 2 0.016 7 +219RN G 372.86 6 5100E-5 0 E1 0.0205 3 +219RN2 G KC=0.01667 24$LC=0.00289 4$MC=6.82E-4 10 +219RN L 397.1 4 + +219RN A 5481.7 5 0.008 3150 +219RN G 270.3 4 0.0007 4 +219RN L 445.03 1 (5/2)+ 6.2 PS 31 +219RN A 5434.60 211.60 249 +219RN G 102.2 2 0.0008 4 +219RN G 106.78 3 0.0233 14(M1) 10.89 16 +219RN2 G KC=8.77 13$LC=1.608 23$MC=0.382 6 +219RN G 175.65 150.017 4 +219RN G 430.6 3 0.020 6 +219RN G 445.033 121.28 4 M1 0.205 3 +219RN2 G KC=0.1661 24$LC=0.0295 5$MC=0.00698 10 +219RN L 446.82 3 (5/2)- +219RN A 5432.83 210.50 8 27 +219RN G 69.5 1 0.007 3 M1 7.36 11 +219RN2 G KC=$LC=5.60 9$MC=1.33 2 +219RN G 104.04 4 0.0194 21M1+E2 9.4 24 +219RN2 G KC=5 5$LC=3.3 16$MC=0.9 5 +219RN G 108.5 2 0.006 3 +219RN G 177.3 1 0.047 4 +219RN G 288.18 3 0.161 5 E1 0.0364 6 +219RN2 G KC=0.0295 5$LC=0.00527 8$MC=1249E-6 18 +219RN G 432.45 3 0.0356 29 +219RN L 490.92 2 (5/2,7/2,9/2)- +219RN G 114.7 2 0.010 4 +219RN L 514.5 1 (9/2)+ +219RN A 5366.37 230.13 45 +219RN G 138.3 3 0.0017 7 +219RN G 355.7 2 0.0028 14 +219RN G 387.7 2 0.016 6 +219RN G 500.0 4 0.0014 6 +219RN G 510.0 4 0.0004 3 +219RN L 517.7 + +219RN G 70.9 2 0.0036 11 +219RN L 541.99 2 (7/2)+ +219RN A 5339.37 210.13 32 +219RN G 165.8 2 0.0054 28 +219RN G 383.35 2 0.007 4 +219RN G 527.611 130.073 4 +219RN G 537.6 1 0.0021 7 +219RN G 541.99 2 0.0014 6 +219RN L 594.1 1 (7/2)- +219RN A 5288.19 230.16 4 13 +219RN G 103.2 2 0.006 3 M1+E2 9.6 24 +219RN2 G KC=5 5$LC=3.5 17$MC=0.9 5 +219RN G 147.2 3 0.006 3 +219RN G 251.6 3 0.055 10M1+E2 0.6 4 +219RN2 G KC=0.4 4$LC=0.122 20$MC=0.030 4 +219RN G 255.7 3 0.0055 28 +219RN G 579.6 3 0.0014 6 +219RN G 594.0 3 0.0014 6 +219RN L 598.72 2 (5/3,7/2,9/2)+ +219RN A 5283.65 210.093 21.8 +219RN G 221.32 240.036 6 E1 0.0675 10 +219RN2 G KC=0.0543 8$LC=0.01005 15$MC=0.00239 4 +219RN G 260.4 3 0.0067 28 +219RN G 584.3 3 0.0014 6 +219RN G 598.721 240.092 4 +219RN L 623.68 4 + +219RN A 5259.14 210.042 35 +219RN G 247.2 5 0.0097 28 +219RN G 609.31 4 0.057 3 +219RN G 619.1 4 0.0036 11 +219RN G 623.68 4 0.009 4 +219RN L 646.1 1 + +219RN A 5237.12 230.041 27 +219RN G 131.6 2 0.006 3 +219RN G 199.3 3 0.0030 14 +219RN G 487.5 2 0.011 2 +219RN G 631.7 7 0.0004 3 +219RN G 641.7 4 0.0017 7 +219RN G 646.1 5 0.0004 4 +219RN L 672.6 5 + +219RN A 5211.1 5 0.0053 147 +219RN G 545.8 5 0.0011 6 +219RN L 711.3 1 + +219RN A 5173.10 230.026 17.9 +219RN G 112.6 +219RN G 368.56 120.009 4 +219RN G 696.9 7 0.0007 3 +219RN G 711.3 2 0.0037 10 +219RN L 732.8 1 + +219RN A 5151.98 230.021 16.6 +219RN G 286.0 4 0.0011 6 +219RN G 355.5 2 0.0043 14 +219RN G 390.1 2 0.0046 21 +219RN G 574.1 7 0.0011 6 +219RN G 718.4 4 0.0014 6 +219RN G 728.4 8 0.00028 14 +219RN G 732.8 6 0.0006 3 +219RN L 748 + +219RN A 5137.1 0.0017 168 +219RN L 773 + +219RN A 5112.5 0.0006 339 +219RN L 800 + +219RN A 5086 0.0003 470 +219RN L 830 + +219RN A 5056.5 0.0002 468 +219RN L 851 + +219RN A 5035.9 0.0004 175 +219RN L 861 + +219RN A 5026.1 0.00063 97 +219RN L 873 + +219RN A 5014.3 0.00044 117 + diff --git a/HEN_HOUSE/spectra/lnhb/Ra-224.txt b/HEN_HOUSE/spectra/lnhb/Ra-224.txt new file mode 100644 index 000000000..44360e9a8 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Ra-224.txt @@ -0,0 +1,58 @@ +220RN 224RA A DECAY (3.631 D) +220RN H TYP=Update$AUT=A.L. Nichols$CUT=30-APR-2010$ +220RN2 H TYP=Full$AUT=A.L. Nichols$CUT=30-DEC-2003$ +220RN C Evaluation history: Type=Update;Author=A.L. Nichols;Cutoff date=30-APR-2010 +220RN2C Type=Full;Author=A.L. Nichols;Cutoff date=30-DEC-2003 +220RN C References: 1953As31, 1962Wa28, 1962Ll02, 1969Pe17, 1971Gr07, 1971So15, +220RN2C 1971Jo14, 1972DaZA, 1972Da38, 1977La19, 1977Ku15, 1982Sa36, 1983Va22, +220RN3C 1983Sc13, 1984Ge07, 1984Bo15, 1985Pr01, 1991Ry01, 1991Ho15, 1992Li05, +220RN4C 1993Ba72, 1995Ar33, 1996Sc06, 1997Ar04, 1997Tr17, 1998ScZM, 1999ScZX, +220RN5C 2002Ba85, 2002Ra45, 2003Au03, 2004Sc04, 2007St23, 2008Ki07 +220RN T Auger electrons and ^X ray energies and emission intensities: +220RN T {U Energy (keV)} {U Intensity } {U Line } +220RN T +220RN T 81.07 0.130 3 XKA2 +220RN T 83.78 0.214 4 XKA1 +220RN T +220RN T 94.247 |] XKB3 +220RN T 94.868 |] 0.0743 18 XKB1 +220RN T 95.449 |] XKB5II +220RN T +220RN T 97.48 |] XKB2 +220RN T 97.853 |] 0.0238 7 XKB4 +220RN T 98.357 |] XKO23 +220RN T +220RN T 10.137-17.28 0.373 16 XL (total) +220RN T 10.137 0.00774 20 XLL +220RN T 11.598-11.726 0.138 4 XLA +220RN T 12.855 0.00413 11 XLC +220RN T 13.52-14.565 0.191 5 XLB +220RN T 16.77-17.28 0.0424 9 XLG +220RN T +220RN T 62.017-68.885 |] KLL AUGER +220RN T 75.744-83.785 |] 0.0151 19 ^KLX AUGER +220RN T 89.45-98.39 |] KXY AUGER +220RN T 5.58-11.48 0.498 16 L AUGER +224RA P 0.0 0+ 3.631 D 2 5788.85 15 +220RN N 1.0 1.0 1 1.0 +220RN L 0 0+ 55.8 S 3 +220RN A 5685.48 1594.73 5 1 +220RN L 240.986 6 2+ 0.15 NS +220RN A 5448.80 155.25 5 1.04 +220RN G 240.986 6 4.12 4 E2 0.276 4 +220RN2 G KC=0.1109 16$LC=0.1220 17$MC=0.0324 5 +220RN L 533.69 104+ +220RN A 5161.32 180.0072 8 17.9 +220RN G 292.7 1 0.0063 7 E2 0.1487 21 +220RN2 G KC=0.0727 11$LC=0.0564 8$MC=0.01484 21 +220RN L 645.44 9 1- +220RN A 5051.56 170.0076 103.7 +220RN G 404.45 9 0.0022 5 E1 0.0171724 +220RN2 G KC=0.01401 20$LC=0.00241 4$MC=5.68E-4 8 +220RN G 645.44 9 0.0054 9 E1 0.0066310 +220RN2 G KC=0.00546 8$LC=8.94E-4 13$MC=2.10E-4 3 +220RN L 663.03 10(3)- +220RN A 5034.29 180.0030 5 6.4 +220RN G 422.04 100.0030 5 [E1] 0.0156722 +220RN2 G KC=0.01280 18$LC=0.00219 3$MC=5.16E-4 8 + diff --git a/HEN_HOUSE/spectra/lnhb/Ra-225.txt b/HEN_HOUSE/spectra/lnhb/Ra-225.txt new file mode 100644 index 000000000..71847f180 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Ra-225.txt @@ -0,0 +1,35 @@ +225AC 225RA B- DECAY (14.82 D) +225AC H TYP=full$AUT=X. Huang$CUT=30-MAY-2007$ +225AC C Evaluation history: Type=full;Author=X. Huang;Cutoff date=30-MAY-2007 +225AC C References: 2008Ki07 +225AC T Auger electrons and ^X ray energies and emission intensities: +225AC T {U Energy (keV)} {U Intensity } {U Line } +225AC T +225AC T +225AC T +225AC T +225AC T 10.8701-18.9228 13.6 6 XL (total) +225AC T 10.8701 XLL +225AC T 12.5002-12.6505 XLA +225AC T 14.0807 XLC +225AC T 14.6024-16.6263 XLB +225AC T 17.813-18.9228 XLG +225AC T +225AC T 5.87-19.69 15.7 7 L AUGER +225RA P 0.0 1/2+ 14.82 D 19 356 5 +225AC N 1.0 1.0 1 1.0 +225AC L 0 3/2- 10.0 D 1 +225AC B 356 5 31.2 20 7.38 1U +225ACS B EAV=100.7 16 +225AC L 40.09 5 3/2+ 0.72 NS 3 +225AC B 316 5 68.8 20 6.87 2 +225ACS B EAV=88.3 16 +225AC G 40.09 5 30.0 7 E1 1.293 19 +225AC2 G KC=$LC=0.974 14$MC=0.24 4 +225AC L 120.8 5/2- +225AC B 235 5 0.01 9.9 3U +225ACS B EAV=70.5 16 +225AC L 155.6 5/2+ +225AC B 200 5 0.01 10.1 +225ACS B EAV=54.0 15 + diff --git a/HEN_HOUSE/spectra/lnhb/Ra-226.txt b/HEN_HOUSE/spectra/lnhb/Ra-226.txt new file mode 100644 index 000000000..b096c286e --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Ra-226.txt @@ -0,0 +1,54 @@ +222RN 226RA A DECAY (1600 Y) +222RN H TYP=Update$AUT=V.Chisté$CUT=01-JAN-2007$ +222RN2 H TYP=Full$AUT=M.M.Bé$CUT=31-DEC-2003$ +222RN C Evaluation history: Type=Update;Author=V.Chisté;Cutoff date=01-JAN-2007 +222RN2C Type=Full;Author=M.M.Bé;Cutoff date=31-DEC-2003 +222RN C References: 1929Ward, 1935Gl02, 1949Ko01, 1956Se10, 1959Ma12, 1959Go80, +222RN2C 1960St20, 1963Ba62, 1966Ra13, 1969Wa27, 1969Li10, 1970Mo28, 1969Gr33, +222RN3C 1971Lo19, 1973De50, 1973Alek, 1975Ha31, 1977Zo01, 1981Mo28, 1982Ak03, +222RN4C 1982Fa10, 1983Ol01, 1983Sc13, 1990Ho28, 1991Li11, 1991Ry01, 1996Ak02, +222RN5C 1996El01, 1996Sc06, 1998Mo14, 2000Sa32, 2001La14, 2002De03, 2002Ba85, +222RN6C 2003Au03, 2002MoZP, 2004Mo07, 2007BeZP +222RN T Auger electrons and ^X ray energies and emission intensities: +222RN T {U Energy (keV)} {U Intensity } {U Line } +222RN T +222RN T 81.07 0.192 4 XKA2 +222RN T 83.78 0.317 6 XKA1 +222RN T +222RN T 94.247 |] XKB3 +222RN T 94.868 |] 0.1098 25 XKB1 +222RN T 95.449 |] XKB5II +222RN T +222RN T 97.48 |] XKB2 +222RN T 97.853 |] 0.0351 10 XKB4 +222RN T 98.357 |] XKO23 +222RN T +222RN T 10.14-17.26 0.807 14 XL (total) +222RN T 10.14 0.0156 4 XLL +222RN T 11.5981-11.7259 0.277 7 XLA +222RN T 12.8551 0.00919 24 XLC +222RN T 13.5219-15.1631 0.412 9 XLB +222RN T 16.2398-17.26 0.0927 20 XLG +226RA P 0.0 0+ 1600 Y 7 4870.62 25 +222RN N 1.0 1.0 1 1.0 +222RN L 0 0+ 3.8232 D 8 +222RN A 4784.34 2594.038 401 +222RN L 186.211 132+ 0.32 NS +222RN A 4601 1 5.95 4 0.96 +222RN G 186.211 133.555 19E2 0.677 10 +222RN2 G KC=0.190 3$LC=0.360 5$MC=0.0963 14 +222RN L 448.37 124+ +222RN A 4340 1 0.0066 2210.4 +222RN G 262.27 5 0.0055 18[E2] 0.209 4 +222RN2 G KC=0.0923 14$LC=0.0868 14$MC=0.0230 4 +222RN L 600.66 5 1- +222RN A 4191 2 0.0008 4.5 +222RN G 414.60 5 3000E-7 0 [E1] 0.0162823 +222RN2 G KC=0.01329 19$LC=0.00228 4$MC=5.37E-4 8 +222RN G 600.66 5 5000E-7 0 [E1] 0.0076211 +222RN2 G KC=0.00627 9$LC=1034E-6 15$MC=2.43E-4 4 +222RN L 635.47 153- +222RN A 4160 2 0.0002 8.65 +222RN G 449.37 102000E-7 0 [E1] 0.0137320 +222RN2 G KC=0.01123 16$LC=0.00191 3$MC=4.49E-4 7 + diff --git a/HEN_HOUSE/spectra/lnhb/Ra-228.txt b/HEN_HOUSE/spectra/lnhb/Ra-228.txt new file mode 100644 index 000000000..1eb0cfceb --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Ra-228.txt @@ -0,0 +1,45 @@ +228AC 228RA B- DECAY (5.75 Y) +228AC H TYP=Full$AUT=A.Luca$CUT=31-DEC-2008$ +228AC C Evaluation history: Type=Full;Author=A.Luca;Cutoff date=31-DEC-2008 +228AC C References: 1931Cu01, 1960Du11, 1961To10, 1962Ma58, 1972HeYY, 1995So11, +228AC2C 1997Ar08, 2003Au03 +228AC T Auger electrons and ^X ray energies and emission intensities: +228AC T {U Energy (keV)} {U Intensity } {U Line } +228AC T +228AC T +228AC T +228AC T +228AC T 10.8701-18.9228 9.6 19 XL (total) +228AC T 10.8701 0.24 8 XLL +228AC T 12.5002-12.6505 4.0 11 XLA +228AC T 14.0807 0.046 14 XLC +228AC T 14.6024-16.6263 4.3 7 XLB +228AC T 17.813-18.9228 1.01 17 XLG +228AC T +228AC T 5.87-19.67 12 5 L AUGER +228RA P 0.0 0+ 5.75 Y 4 45.8 7 +228AC N 1.0 1.0 1 1.0 +228AC L 0 3+ 6.15 H 3 +228AC L 6.28 3 1- +228AC B 39.5 7 12 10 7.07 1 +228ACS B EAV=10.0 2 +228AC G 6.28 3 1.8E-6 15M2 6.68E6 19 +228AC2 G KC=$LC=$MC=4.93E6 14 +228AC L 6.67 2 1+ +228AC B 39.1 7 49 10 6.45 +228ACS B EAV=9.9 2 +228AC G 6.67 2 5.7E-5 9 E2 1.56E6 4 +228AC2 G KC=$LC=$MC=1.172E6 24 +228AC L 20.19 3 1- +228AC B 25.6 7 8.7 9 6.2 1 +228ACS B EAV=6.5 2 +228AC G 13.520 361.6 1 E1 5.86 10 +228AC2 G KC=$LC=$MC=4.48 7 +228AC L 33.07 111+ +228AC B 12.7 7 30 10 5.11 +228ACS B EAV=3.2 2 +228AC G 12.88 110.30 6 E1 6.67 18 +228AC2 G KC=$LC=$MC=5.11 14 +228AC G 26.40 110.14 5 M1+E2 0.07 201 4 +228AC2 G KC=$LC=151 3$MC=37.2 7 + diff --git a/HEN_HOUSE/spectra/lnhb/Rb-82.txt b/HEN_HOUSE/spectra/lnhb/Rb-82.txt new file mode 100644 index 000000000..9abe1f1fe --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Rb-82.txt @@ -0,0 +1,155 @@ + 82KR 82RB EC DECAY (1.2652 M) + 82KR H TYP=Full$AUT=M.M. Bé$CUT=30-DEC-2014$ + 82KR C Evaluation history: Type=Full;Author=M.M. Bé;Cutoff date=30-DEC-2014 + 82KR C References: 1953Li27, 1953Kr10, 1962Sa10, 1967Vr07, 1969Ra06, 1970Gr01, + 82KR2C 1970Hr02, 1978Gr17, 1983Me08, 1985Ze03, 1987Ju01, 1987Wo01, 1987Ho06, + 82KR3C 1996Sc06, 1998Sc28, 2000Sc47, 2002Ba85, 2008Ki07, 2012Gr03, 2012Wa38 + 82KR T Auger electrons and ^X ray energies and emission intensities: + 82KR T {U Energy (keV)} {U Intensity } {U Line } + 82KR T + 82KR T 12.599 0.760 9 XKA2 + 82KR T 12.65 1.466 16 XKA1 + 82KR T + 82KR T 14.105 |] XKB3 + 82KR T 14.113 |] 0.351 5 XKB1 + 82KR T 14.238 |] XKB5II + 82KR T + 82KR T 14.315 |] XKB2 + 82KR T 14.328 |] 0.0354 12 XKB4 + 82KR T + 82KR T 1.387-1.911 0.1066 18 XL (total) + 82KR T 1.387 0.00262 7 XLL + 82KR T 1.585-1.586 0.0647 15 XLA + 82KR T 1.439 0.00127 4 XLC + 82KR T 1.637-1.831 0.0377 9 XLB + 82KR T 1.706-1.911 0.000373 7 XLG + 82KR T + 82KR T 10.398-10.885 |] KLL AUGER + 82KR T 12.077-12.637 |] 1.394 20 ^KLX AUGER + 82KR T 13.741-14.298 |] KXY AUGER + 82KR T 1.09-1.91 4.961 25 L AUGER + 82RB P 0.0 1+ 1.2652 M 45 4403 3 + 82KR N 1.0 1.0 1 1.0 + 82KR L 0 0+ STABLE + 82KR E 81.81 243.01 3 4.6 + 82KR2 E EAV=1535.6 15$CK=0.8779 14$CL=0.1014 12$CM=0.0183 4$CN=0.0024 2$CO= + 82KR L 776.522 102+ + 82KR E 13.10 191.06 2 4.8 + 82KR2 E EAV=1168.5 15$CK=0.8778 14$CL=0.1016 12$CM=0.0183 4$CN=0.0024 2$CO= + 82KR G 776.52 1 15.02 19E2 9.23E-413 + 82KR2 G KC=8.19E-4 12$LC=8.84E-5 13$MC=1.43E-5 2 + 82KR L 1474.894 102+ 15 PS + 82KR E 0.135 7 0.0284 146.3 + 82KR2 E EAV=844.1 14$CK=0.8776 14$CL=0.1017 12$CM=0.0183 4$CN=0.0024 2$CO= + 82KR G 698.37 5 0.159 11 + 82KR G 1474.88 1 0.0904 24E2 2.89E-44 + 82KR2 G KC=1.90E-4 3$LC=2.00E-5 3$MC= + 82KR L 1487.62 7 0+ 10 PS + 82KR E 0.0444 410.0096 9 6.7 + 82KR2 E EAV=838.3 14$CK= $CL= $CM= $CN= $CO= + 82KR G 711.2 1 0.060 4 + 82KR L 1820.6 4 4+ + 82KR E 0.00007 7 0.00003 3 11.5 2U + 82KR2 E EAV=735.6 15$CK= $CL= $CM= $CN= $CO= + 82KR G 1044.1 5 0.0009 6 + 82KR L 1956.797 20(2)+ + 82KR E 0.00890 140.0047 8 6.7 + 82KR2 E EAV=624.8 14$CK= $CL= $CM= $CN= $CO= + 82KR G 1180.27 2 0.0165 15 + 82KR G 1956.75 4 0.0068 6 + 82KR L 2171.68 3 0+ + 82KR E 0.317 6 0.283 5 5 + 82KR2 E EAV=528.6 14$CK=0.8773 14$CL=0.1019 12$CM=0.0184 4$CN=0.0024 2$CO= + 82KR G 696.86 150.071 6 + 82KR G 1395.14 3 0.529 8 E2 + 82KR L 2450.09 9 0(+),1,2+ + 82KR E 0.0050 4 0.0105 8 6.3 + 82KR2 E EAV=405.7 14$CK=0.8771 14$CL=0.1021 12$CM=0.0184 4$CN=0.0024 2$CO= + 82KR G 975.2 1 0.0084 11 + 82KR G 1673.55 9 0.0071 5 + 82KR L 2479.72 3 1,2+ + 82KR E 0.0288 7 0.0682 145.5 + 82KR2 E EAV=392.7 14$CK=0.8771 14$CL=0.1021 12$CM=0.0184 4$CN=0.0024 2$CO= + 82KR G 522.8 5 0.0045 15 + 82KR G 992.2 1 0.0018 8 + 82KR G 1703.19 4 0.0505 11 + 82KR G 2479.65 4 0.0401 16 + 82KR L 2509.0 5 + + 82KR E 0.00041 250.0011 6 7.4 + 82KR2 E EAV=380.0 14$CK= $CL= $CM= $CN= $CO= + 82KR G 1021.4 5 0.0015 9 + 82KR L 2556.3 7 (4)+ + 82KR E 0.00007 4 0.00023 1110 2U + 82KR2 E EAV=359.4 14$CK= $CL= $CM= $CN= $CO= + 82KR G 1081.4 7 0.00030 15 + 82KR L 2561.7 5 + + 82KR E 0.00033 190.0011 6 7.3 + 82KR2 E EAV=357.0 14$CK= $CL= $CM= $CN= $CO= + 82KR G 1086.8 5 0.0014 8 + 82KR L 2655.82 101,2(+)+ + 82KR E 0.00284 340.0142 176.1 + 82KR2 E EAV=316.2 13$CK=0.8770 14$CL=0.1022 12$CM=0.0184 4$CN=0.0024 2$CO= + 82KR G 1168.2 2 0.0014 6 + 82KR G 1181.3 0.0030 15 + 82KR G 1879.18 150.0101 6 + 82KR G 2655.85 150.0026 6 + 82KR L 2944.14 4 (2)+ + 82KR E 0.0500 195.4 + 82KR2 E EAV= $CK=0.8766 15$CL=0.1025 12$CM=0.0185 4$CN=0.0024 2$CO= + 82KR G 1123.6 7 0.0008 6 + 82KR G 2167.59 4 0.0431 6 + 82KR G 2944.0 2 0.0075 15 + 82KR L 3186.82 5 0,1,2+ + 82KR E 0.0265 155.5 + 82KR2 E EAV= $CK=0.8763 15$CL=0.1028 12$CM=0.0185 4$CN=0.0024 2$CO= + 82KR G 1698.7 3 0.0015 8 + 82KR G 1711.9 4 0.00165 30 + 82KR G 2410.26 5 0.0233 12 + 82KR L 3355.32 191,2(+)+ + 82KR E 0.00134 136.7 + 82KR2 E EAV= $CK= $CL= $CM= $CN= $CO= + 82KR G 2578.7 2 0.00105 11 + 82KR G 3355.6 5 2.85E-4 30 + 82KR L 3457.5 7 1,2(+)+ + 82KR E 11100E-8237.7 + 82KR2 E EAV= $CK= $CL= $CM= $CN= $CO= + 82KR G 3457.4 7 1.11E-4 23 + 82KR L 3564.6 3 0(+),1,2+ + 82KR E 0.0034 316 + 82KR2 E EAV= $CK= $CL= $CM= $CN= $CO= + 82KR G 1607.7 3 0.00225 30 + 82KR G 2788.4 5 0.00114 8 + 82KR L 3716.83 150(),1,2+ + 82KR E 0.008 3 5.8 + 82KR2 E EAV= $CK= $CL= $CM= $CN= $CO= + 82KR G 2241.98 170.0009 8 + 82KR G 2940.0 3 0.0071 29 + 82KR L 3741.96 8 + + 82KR E 0.0036 6 5.9 + 82KR2 E EAV= $CK= $CL= $CM= $CN= $CO= + 82KR G 1785.13 7 0.0030 6 + 82KR G 2966.3 7 0.00060 5 + 82KR L 3815.1 101,2(+)+ + 82KR E 0.0019 8 5.6 + 82KR2 E EAV= $CK= $CL= $CM= $CN= $CO= + 82KR G 869.3 4 0.0014 8 + 82KR G 3815 1 4.51E-4 31 + 82KR L 3835.8 5 1,2+ + 82KR E 0.00089 5 6.3 + 82KR2 E EAV= $CK= $CL= $CM= $CN= $CO= + 82KR G 3059.2 5 0.00068 5 + 82KR G 3836 1 2.19E-4 23 + 82KR L 3881.1 5 1,2(+)+ + 82KR E 0.00024 5 6.8 + 82KR2 E EAV= $CK= $CL= $CM= $CN= $CO= + 82KR G 3104.5 5 0.00015 5 + 82KR G 3881 1 8.7E-5 21 + 82KR L 3911.1 101,2(+)+ + 82KR E 0.00010 2 7.1 + 82KR2 E EAV= $CK= $CL= $CM= $CN= $CO= + 82KR G 3911 1 1.05E-4 15 + 82KR L 3956.1 101,2(+)+ + 82KR E 0.00009 2 7.1 + 82KR2 E EAV= $CK=0.8722 15$CL=0.1061 12$CM=0.0192 4$CN=0.0025 2$CO= + 82KR G 3956 1 9.0E-5 15 + diff --git a/HEN_HOUSE/spectra/lnhb/Re-186.txt b/HEN_HOUSE/spectra/lnhb/Re-186.txt new file mode 100644 index 000000000..5f9e899a4 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Re-186.txt @@ -0,0 +1,95 @@ +186W 186RE EC DECAY (3.7186 D) +186W T Auger electrons and ^X ray energies and emission intensities: +186W T {U Energy (keV)} {U Intensity } {U Line } +186W T +186W T 57.9823 1.736 30 XKA2 +186W T 59.3189 3.02 5 XKA1 +186W T +186W T 66.952 |] XKB3 +186W T 67.2451 |] 1.000 23 XKB1 +186W T 67.664 |] XKB5II +186W T +186W T 69.033 |] XKB2 +186W T 69.295 |] 0.274 8 XKB4 +186W T 69.484 |] XKO23 +186W T +186W T 7.3881-11.6761 2.00 4 XL (total) +186W T 7.3881 0.0411 13 XLL +186W T 8.3352-8.3976 0.876 24 XLA +186W T 8.725 0.0159 5 XLC +186W T 9.526-10.2903 0.902 18 XLB +186W T 10.9501-11.6761 0.166 4 XLG +186W T +186W T 45.109-48.882 |] KLL AUGER +186W T 54.514-59.312 |] 0.291 26 ^KLX AUGER +186W T 63.89-69.51 |] KXY AUGER +186W T 4.5-12.1 4.96 5 L AUGER +186RE P 0.0 1- 3.7186 D 17 581.6 17 +186W N 1.328E1 1.328E1 0.0753 1.328E1 +186W L 0 0+ STABLE +186W E 5.84 127.5 1 +186W 2 E EAV= $CK=0.7943 18$CL=0.1560 12$CM=0.0382 7$CN= $CO= +186W L 122.33 102+ 1.036 NS +186W E 1.69 3 7.8 1 +186W 2 E EAV= $CK=0.7836 19$CL=0.1638 13$CM=0.0404 8$CN= $CO= +186W G 122.33 100.603 6 E2 1.81 4 +186W 2 G KC=0.585 12$LC=0.927 19$MC=0.234 7 + +186OS 186RE B- DECAY (3.7186 D) +186OS T Auger electrons and ^X ray energies and emission intensities: +186OS T {U Energy (keV)} {U Intensity } {U Line } +186OS T +186OS T 61.4873 1.13 4 XKA2 +186OS T 63.0011 1.94 6 XKA1 +186OS T +186OS T 71.078 |] XKB3 +186OS T 71.414 |] 0.650 23 XKB1 +186OS T 71.855 |] XKB5II +186OS T +186OS T 73.319 |] XKB2 +186OS T 73.615 |] 0.182 8 XKB4 +186OS T 73.819 |] XKO23 +186OS T +186OS T 7.8233-12.4984 2.99 7 XL (total) +186OS T 7.8233 0.0586 18 XLL +186OS T 8.841-8.9119 1.21 4 XLA +186OS T 9.3366 0.0308 10 XLC +186OS T 10.1749-11.0062 1.43 4 XLB +186OS T 11.7306-12.4984 0.262 8 XLG +186OS T +186OS T 47.71-51.892 |] KLL AUGER +186OS T 57.759-62.955 |] 0.175 18 ^KLX AUGER +186OS T 67.77-73.78 |] KXY AUGER +186OS T 4.7-12.9 6.43 8 L AUGER +186RE P 0.0 1- 3.7186 D 17 1069.5 9 +186OS N 1.081E0 1.081E0 0.9247 1.081E0 +186OS L 0 0+ 2E15 Y +186OS B 1069.5 9 70.9 3 7.7 1 +186OSS B EAV=359.6 7 +186OS L 137.157 8 2+ 0.818 NS +186OS B 932.3 9 21.5 3 8 1 +186OSS B EAV=306.7 7 +186OS G 137.157 8 9.42 6 E2 1.290 39 +186OS2 G KC=0.433 13$LC=0.645 19$MC=0.1648 49 +186OS L 434.09 3 4+ 23.9 PS +186OS G 296.93 3 5.3E-5 15E2 0.095 2 +186OS2 G KC=0.0609 12$LC=0.0260 6$MC=0.00645 19 +186OS L 767.48 3 2+ 2.38 PS +186OS B 302.0 9 0.0627 9 8.9 1 +186OSS B EAV=84.7 7 +186OS G 333.39 4 6.2E-5 15[E2] 0.0678 20 +186OS2 G KC=0.0454 14$LC=0.0170 5$MC=0.00418 13 +186OS G 630.32 3 0.0293 6 M1+E2 -14 3 0.0134 1 +186OS2 G KC=0.0105 6$LC=0.0023 2$MC=5.38E-4 16 +186OS G 767.478 300.0327 6 E2 0.0086526 +186OS2 G KC=0.00690 21$LC=1342E-6 40$MC=3.15E-4 9 +186OS L 910.48 3 3+ +186OS B 159.0 9 27000E-99 10.9 1U +186OSS B EAV=42.6 7 +186OS G 143.00 4 7.4E-7 25M1+E2 0.6 1.85 11 +186OS2 G KC=1.39 8$LC=0.35 2$MC=0.0842 25 +186OS G 476.39 4 1.5E-6 5 E2+M1 -22 10 0.0259 8 +186OS2 G KC=0.0193 6$LC=0.00512 15$MC=1235E-6 37 +186OS G 773.32 3 2.2E-5 7 E2+M1 60 20 0.0266 7 +186OS2 G KC=0.0189 6$LC=0.00291 9$MC= + diff --git a/HEN_HOUSE/spectra/lnhb/Re-188.txt b/HEN_HOUSE/spectra/lnhb/Re-188.txt new file mode 100644 index 000000000..5668cac3a --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Re-188.txt @@ -0,0 +1,177 @@ +188OS 188RE B- DECAY (17.005 H) +188OS T Auger electrons and ^X ray energies and emission intensities: +188OS T {U Energy (keV)} {U Intensity } {U Line } +188OS T +188OS T 61.4873 1.36 9 XKA2 +188OS T 63.0011 2.35 16 XKA1 +188OS T +188OS T 71.078 |] XKB3 +188OS T 71.414 |] 0.79 5 XKB1 +188OS T 71.855 |] XKB5II +188OS T +188OS T 73.319 |] XKB2 +188OS T 73.615 |] 0.22 2 XKB4 +188OS T 73.819 |] XKO23 +188OS T +188OS T 7.82-12.92 3.00 15 XL (total) +188OS T 7.82 XLL +188OS T -12.92 XLG +188OS T +188OS T 47.71-51.89 |] KLL AUGER +188OS T 57.79-60.47 |] 0.210 14 ^KLX AUGER +188OS T 67.68-69.95 |] KXY AUGER +188RE P 0.0 1- 17.005 H 4 2120.4 4 +188OS N 1.0 1.0 1 1.0 +188OS G 979.25 170.00104 20 +188OS L 0 0+ STABLE +188OS B 2120.4 4 71.1 22 8.1 1 +188OSS B EAV=795.40 17 +188OS L 155.040 4 2+ 0.70 NS 2 +188OS B 1965.3 4 25.6 20 8.4 1 +188OSS B EAV=728.89 17 +188OS G 155.041 4 15.2 6 E2 0.820 25 +188OS2 G KC=0.323 10$LC=0.375 11$MC=0.122 4 +188OS L 477.97 3 4+ 19.40 PS 9 +188OS G 322.93 4 0.0162 15E2 0.0743 22 +188OS2 G KC=0.0492 15$LC=0.0190 6$MC=0.0061 2 +188OS L 633.024 132+ 6.6 PS 3 +188OS B 1487.4 4 1.65 12 9.2 1 +188OSS B EAV=527.77 17 +188OS G 155 0.0059 6 [E2] 0.820 25 +188OS2 G KC=0.323 10$LC=0.375 11$MC=0.122 4 +188OS G 477.992 251.02 9 E2+M1+ 0.0260 8 +188OS2 G KC=0.0193 6$LC=0.00508 15$MC=0.00126 5 +188OS G 632.981 211.28 10E2 0.0132 4 +188OS2 G KC=0.0103 3$LC=0.00223 7$MC=0.00067 2 +188OS L 789.97 3 3+ +188OS G 312.001 240.043 12E2 0.0822 25 +188OS2 G KC=0.0536 16$LC=0.0216 6$MC=0.00070 21 +188OS G 634.98 7 0.148 12E2+M1 0.0136 4 +188OS2 G KC=0.0106 3$LC=0.00226 7$MC=0.00074 2 +188OS L 1086.382 100+ 12 PS 9 +188OS B 1034.0 4 0.63 4 9 1 +188OSS B EAV=345.33 16 +188OS G 453.34 2 0.073 8 (E2) 0.0294 4 +188OS2 G KC=0.0216 6$LC=0.00597 18$MC=0.00183 5 +188OS G 931.345 100.55 4 E2 0.0057918 +188OS2 G KC=0.00470 14$LC=0.00084 3$MC=0.00025 1 +188OS L 1304.85 7 (2)+ +188OS B 815.5 4 0.0241 17 10 1 +188OSS B EAV=261.94 15 +188OS G 514.88 6 0.0054 5 E2(+M1) 0.0232 18 +188OS2 G KC=0.0177 16$LC=0.00421 23$MC=0.00129 6 +188OS G 1149.7 4 0.015 1 +188OS G 1304.86 200.0028 4 +188OS L 1413.8 3 (3)- +188OS B 706.6 5 0.0024 5 10.8 2 +188OSS B EAV=221.84 18 +188OS G 623.8 3 0.0024 5 +188OS L 1443.52 5 + +188OS B 676.88 5 0.00092 21 11.2 +188OSS B EAV=211.11 14 +188OS G 810.49 4 0.00092 22 +188OS L 1457.55 122+ +188OS B 662.8 5 0.042 3 9.5 1 +188OSS B EAV=206.07 15 +188OS G 825.2 7 0.0176 15M1(+E2) 0.016 5 +188OS2 G KC=0.013 5$LC=0.0021 7$MC=0.0009 2 +188OS G 1302.4 3 0.0057 8 +188OS G 1457.54 130.0186 15 +188OS L 1462.50 3 2- +188OS B 657.9 4 0.44 3 8.5 +188OSS B EAV=204.30 14 +188OS G 672.535 160.112 9 E1 0.0042 1 +188OS2 G KC=0.0035 11$LC=0.00053 2$MC=1.55E-4 5 +188OS G 829.47 4 0.41 3 E1(+M2) 0.0030 9 +188OS2 G KC=0.0025 7$LC=0.00038 11$MC=0.00011 3 +188OS G 984.1 5 0.00034 21 +188OS G 1463.0 6 0.0008 3 +188OS L 1478.09 5 0+ +188OS B 642.3 4 0.018 3 9.8 1 +188OSS B EAV=198.73 14 +188OS G 845.07 4 0.0065 5 +188OS G 1322.91 200.011 3 +188OS L 1685.5 3 + +188OS B 434.9 5 0.00055 17 10.8 +188OSS B EAV=127.46 17 +188OS G 1530.5 3 0.00055 17 +188OS L 1704.32 100+ +188OS B 416.1 5 0.0023 9 10.1 1 +188OSS B EAV=121.28 13 +188OS G 1704 +188OS G 1071.4 3 0.00067 13 +188OS G 1549.26 100.0016 9 +188OS L 1729.68 22(2,3)+ +188OS B 390.7 5 0.00128 21 10.3 1 +188OSS B EAV=113.02 15 +188OS G 1096.8 4 0.00064 17 +188OS G 1574.57 250.00063 11 +188OS L 1765.353 220+ +188OS B 355.0 4 0.181 13 8 1 +188OSS B EAV=101.57 13 +188OS G 1765.1 +188OS G 1132.31 2 0.083 7 (E2) 0.0038712 +188OS2 G KC=0.00322 10$LC=0.00050 3$MC=0.00015 5 +188OS G 1610.40 5 0.098 8 [E2] 1070E-70 +188OS2 G KC=$LC=$MC= +188OS L 1807.60 3 (2)+ +188OS B 312.8 4 0.038 3 8.5 1 +188OSS B EAV=88.27 12 +188OS G 1017.7 1 0.0147 11 +188OS G 1174.57 3 0.0180 15 +188OS G 1652.49 140.0035 4 +188OS G 1807.6 3 0.00086 9 +188OS L 1824.94 6 0+ +188OS B 295.5 4 0.0236 17 8.6 1 +188OSS B EAV=82.90 12 +188OS G 1825 +188OS G 1191.84 120.0134 11 +188OS G 1669.97 7 0.0104 8 [E2] 1320E-70 +188OS2 G KC=$LC=$MC= +188OS L 1842.86 6 (1,2)+ +188OS B 277.5 4 0.00299 22 9.4 +188OSS B EAV=77.41 12 +188OS G 1209.790 240.00300 24M1+E2 0.0072921 +188OS2 G KC=0.00620 19$LC=8.20E-4 25$MC= +188OS L 1936.9 3 + +188OS B 183.5 4 21400E-825 10 +188OSS B EAV=49.46 14 +188OS G 1936.9 3 0.00021 3 +188OS L 1941.03 6 (1,2)+ +188OS B 179.4 4 0.102 7 7.3 +188OSS B EAV=48.27 12 +188OS G 1150.5 4 0.015 1 +188OS G 1308.03 6 0.065 5 +188OS G 1785.95 120.0195 15[E2] 1800E-70 +188OS2 G KC=$LC=$MC= +188OS G 1940.91 230.00185 15(M1E2) 2480E-70 +188OS2 G KC=$LC=$MC= +188OS L 1948.59 3 + +188OS B 171.8 4 0.079 6 7.3 +188OSS B EAV=46.10 11 +188OS G 486.087 110.079 6 +188OS L 1957.08 4 (1,2)+ +188OS B 163.3 4 0.051 4 7.4 +188OSS B EAV=43.68 11 +188OS G 1802.04 4 0.036 3 [E2] 1850E-70 +188OS2 G KC=$LC=$MC= +188OS G 1956.96 170.0150 12(M1E2) 2550E-70 +188OS2 G KC=$LC=$MC= +188OS L 1964.96 7 2+ +188OS B 155.4 4 0.0021 3 8.8 1 +188OSS B EAV=41.44 11 +188OS G 1331.95 7 0.00174 24 +188OS G 1809.54 300.00040 11 +188OS L 2020.18 10 + +188OS B 100.2 5 0.0059 4 7.7 +188OSS B EAV=26.12 11 +188OS G 557.71 100.00095 9 +188OS G 1864.91 250.0050 4 (E2M1) 2130E-70 +188OS2 G KC=$LC=$MC= +188OS L 2022.44 13(1,2)+ +188OS B 98.0 5 0.00198 16 8.2 +188OSS B EAV=25.51 11 +188OS G 1867.20 220.00046 9 +188OS G 2022.53 160.00152 12(M1E2) 2850E-70 +188OS2 G KC=$LC=$MC= + diff --git a/HEN_HOUSE/spectra/lnhb/Rh-106.txt b/HEN_HOUSE/spectra/lnhb/Rh-106.txt new file mode 100644 index 000000000..3382327f4 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Rh-106.txt @@ -0,0 +1,268 @@ +106PD 106RH B- DECAY (30.1 S) +106PD H TYP=Full$AUT=A.Arinc$CUT=31-DEC-2012$ +106PD C Evaluation history: Type=Full;Author=A.Arinc;Cutoff date=31-DEC-2012 +106PD C References: 1946Se30, 1947Pe07, 1950Gl05, 1953Ka47, 1957Fi50, 1958Gr07, +106PD2C 1960Ro12, 1960Se07, 1962Am03, 1963Ke13, 1965Ro09, 1966Ov01, 1966JoZZ, +106PD3C 1966Mi10, 1967Ra11, 1697Fo09, 1968Ha35, 1967Vr05, 1969St03, 1969Od01, +106PD4C 1969KoZW, 1969Be74, 1971Az02, 1972Ma71, 1973Ma35, 1975De17, 1975Ge06, +106PD5C 1975Hs02, 1976Sh25, 1977Ok02, 1982Ka10, 1983Ku03, 1992Gr21, 1993Ch32, +106PD6C 1996Sc06, 2000He14, 2002Ba85, 2005Ki02, 2008Ki07, 2008De09, 2012Wa38 +106PD T Auger electrons and ^X ray energies and emission intensities: +106PD T {U Energy (keV)} {U Intensity } {U Line } +106PD T +106PD T 21.0203 0.0310 5 XKA2 +106PD T 21.1774 0.0586 9 XKA1 +106PD T +106PD T 23.7914 |] XKB3 +106PD T 23.819 |] 0.01608 29 XKB1 +106PD T 24.013 |] XKB5II +106PD T +106PD T 24.2994 |] XKB2 +106PD T 24.344 |] 0.00273 10 XKB4 +106PD T +106PD T 2.5045-3.5545 0.00785 14 XL (total) +106PD T 2.5045 0.000174 5 XLL +106PD T 2.8337-2.839 0.00468 11 XLA +106PD T 2.6611 0.0000608 17 XLC +106PD T 2.9904-3.1715 0.00270 8 XLB +106PD T 3.2464-3.5545 0.000242 6 XLG +106PD T +106PD T 17.032-17.884 |] KLL AUGER +106PD T 20.032-21.176 |] 0.0238 7 ^KLX AUGER +106PD T 23.011-24.347 |] KXY AUGER +106PD T 1.83-3.6 0.1377 8 L AUGER +106RH P 0.0 1+ 30.1 S 3 3546 5 +106PD N 1.0 1.0 1 1.0 +106PD L 0 0+ STABLE +106PD B 3546 5 78.80 24 5.18 +106PDS B EAV=1511.1 24 +106PD L 511.8547 232+ +106PD B 3034 5 8.2 3 5.87 +106PDS B EAV=1269.5 24 +106PD G 511.8534 2320.52 23E2 0.005598 +106PD2 G KC=0.00484 7$LC=6.12E-4 9$MC=1153E-7 17 +106PD L 1128.02 3 2+ +106PD B 2418 5 0.608 21 6.58 +106PDS B EAV=981.6 24 +106PD G 616.16 3 0.731 17M1+E2 -9.4 20 0.003335 +106PD2 G KC=0.00289 4$LC=3.57E-4 5$MC=6.71E-5 10 +106PD G 1128.01 3 0.398 8 E2 7.73E-411 +106PD2 G KC=6.75E-4 10$LC=7.90E-5 11$MC=1479E-8 21 +106PD L 1133.76 4 0+ +106PD B 2412 5 9.82 15 5.37 +106PDS B EAV=978.9 24 +106PD G 621.90 4 9.87 15E2 0.003245 +106PD2 G KC=0.00282 4$LC=3.48E-4 5$MC=6.54E-5 10 +106PD G 1133.75 4 +106PD L 1229.30 4 4+ +106PD B 2317 5 0.0051 5 11 2U +106PDS B EAV=951.8 23 +106PD G 717.44 4 0.0067 4 E2 0.002234 +106PD2 G KC=0.00194 3$LC=2.36E-4 4$MC=4.43E-5 7 +106PD L 1557.68 4 3+ +106PD G 1045.82 4 0.0131 16M1+E2 -3.8 4 9.18E-413 +106PD2 G KC=8.03E-4 12$LC=9.42E-5 14$MC=1766E-8 25 +106PD L 1562.25 3 2+ +106PD B 1984 5 1.67 3 5.79 +106PDS B EAV=781.9 23 +106PD G 428.49 5 0.0704 24E2 0.0094714 +106PD2 G KC=0.00817 12$LC=1063E-6 15$MC=2.00E-4 3 +106PD G 434.23 4 0.020 4 E2 0.0090913 +106PD2 G KC=0.00785 11$LC=1019E-6 15$MC=1.92E-4 3 +106PD G 1050.39 3 1.490 25M1+E2 0.24 1 1007E-615 +106PD2 G KC=8.83E-4 13$LC=1018E-7 15$MC=1.91E-5 3 +106PD G 1562.24 3 0.156 8 +106PD L 1706.44 5 0+ +106PD B 1840 5 0.0664 10 7.06 +106PDS B EAV=716.4 23 +106PD G 578.42 6 0.0090 6 E2 0.003956 +106PD2 G KC=0.00343 5$LC=4.27E-4 6$MC=8.04E-5 12 +106PD G 1194.58 5 0.0573 8 E2 6.89E-410 +106PD2 G KC=5.97E-4 9$LC=6.96E-5 10$MC=1304E-8 19 +106PD L 1909.37 16(1,2)+ +106PD B 1637 5 0.00277 21 8.24 +106PDS B EAV=625.2 23 +106PD G 1397.51 160.00277 21 +106PD L 2001.48 5 0+ +106PD B 1545 5 0.448 9 5.93 +106PDS B EAV=584.3 23 +106PD G 439.23 6 0.0111 16 +106PD G 873.46 6 0.435 8 E2 1375E-620 +106PD2 G KC=1201E-6 17$LC=1432E-7 20$MC=2.69E-5 4 +106PD G 1489.61 5 0.0018 3 +106PD L 2242.48 5 2+ +106PD B 1304 5 0.0372 8 6.72 +106PDS B EAV=478.7 22 +106PD G 680.23 6 0.0103 6 E1+M2 0.4 0.002684 +106PD2 G KC=0.00234 4$LC=2.74E-4 4$MC=5.15E-5 8 +106PD G 684.80 6 0.00552 21 +106PD G 1108.71 6 0.0056 3 +106PD G 1114.45 6 0.0117 3 M1+E2 1.5 8.23E-414 +106PD2 G KC=7.20E-4 12$LC=8.38E-5 14$MC=1570E-8 25 +106PD G 1730.44 200.00209 13 +106PD G 2242.45 5 0.00195 8 +106PD L 2278.11 9 0+ +106PD B 1268 5 0.043 5 6.62 +106PDS B EAV=463.3 22 +106PD G 715.86 9 0.0099 4 +106PD G 1150.08 9 0.00287 17E2 7.42E-411 +106PD2 G KC=6.48E-4 9$LC=7.57E-5 11$MC=1417E-8 20 +106PD G 1766.24 9 0.030 5 E2 5.06E-47 +106PD2 G KC=2.74E-4 4$LC=3.14E-5 5$MC=5.86E-6 9 +106PD L 2308.82 5 2+ +106PD B 1237 5 0.0430 7 6.57 +106PDS B EAV=450.1 22 +106PD G 751.26 200.00121 23 +106PD G 1180.79 6 0.0144 3 M1+E2 -0.06 12 7.90E-412 +106PD2 G KC=6.89E-4 10$LC=7.92E-5 12$MC=1482E-8 22 +106PD G 1796.95 5 0.0274 5 M1+E2 0.25 2 5.16E-48 +106PD2 G KC=2.87E-4 4$LC=3.27E-5 5$MC=6.11E-6 9 +106PD L 2439.10 7 2+ +106PD B 1107 5 0.0208 5 6.71 +106PDS B EAV=394.7 21 +106PD G 1209.79 8 0.00039 8 +106PD G 1305.33 8 0.00109 12 +106PD G 1927.23 7 0.0147 4 M1+E2 -0.07 5.32E-48 +106PD2 G KC=2.50E-4 4$LC=2.85E-5 4$MC=5.33E-6 8 +106PD G 2439.07 7 0.00464 13E2 6.89E-410 +106PD2 G KC=1525E-7 22$LC=1727E-8 25$MC=3.23E-6 5 +106PD L 2484.66 20(1)- +106PD B 1061 5 0.00093 15 7.99 +106PDS B EAV=375.6 21 +106PD G 1973.4 8 0.00017 4 +106PD G 2484.63 200.00076 14 +106PD L 2500.31 8 2- +106PD B 1046 5 0.0284 6 6.48 1 +106PDS B EAV=369.0 21 +106PD G 942.63 9 0.00060 18 +106PD G 1372.28 9 0.00199 15 +106PD G 1988.44 8 0.0258 5 E1+M2 0.05 7.35E-411 +106PD2 G KC=1173E-7 22$LC=1318E-8 25$MC=2.46E-6 5 +106PD L 2624.40 5 0+ +106PD B 922 5 0.090 3 5.78 +106PDS B EAV=317.8 21 +106PD G 1062.14 6 0.0304 19 +106PD G 1496.37 6 0.0240 17 +106PD G 2112.52 5 0.0351 7 E2 5.81E-49 +106PD2 G KC=1.97E-4 3$LC=2.24E-5 4$MC=4.19E-6 6 +106PD L 2705.30 8 (1)+ +106PD B 841 5 0.0106 4 6.56 +106PDS B EAV=285.1 20 +106PD G 702.8 100.00029 18 +106PD G 1572.47 200.00185 19 +106PD G 1577.27 9 0.00105 16 +106PD G 2193.17 100.00495 21M1+E2 -0.17 6 5.94E-49 +106PD2 G KC=1.94E-4 3$LC=2.20E-5 3$MC=4.12E-6 6 +106PD G 2705.26 8 0.00248 13 +106PD L 2717.59 21 + +106PD B 828 5 0.00023 12 +106PDS B EAV= +106PD G 1159.90 210.00023 12 +106PD L 2783.74 212+ +106PD B 762 5 0.00117 8 7.36 +106PDS B EAV=254 2 +106PD G 2271.86 210.00117 8 +106PD L 2820.97 9 2+ +106PD B 725 5 0.0090 3 6.4 +106PDS B EAV=239.4 20 +106PD G 1258.71 9 0.00066 8 +106PD G 1687.2 1 0.00055 16 +106PD G 1693.2 3 0.00082 14 +106PD G 2309.09 9 0.00575 16 +106PD G 2821.2 3 0.00120 4 +106PD L 2828.29 9 0+ +106PD B 718 5 0.00731 19 6.47 +106PDS B EAV=236.6 20 +106PD G 1266.03 9 0.00109 10 +106PD G 2316.41 9 0.00622 16E2 6.46E-49 +106PD2 G KC=1670E-7 24$LC=1.89E-5 3$MC=3.54E-6 5 +106PD L 2877.92 7 0+ +106PD B 668 5 0.0262 9 5.81 +106PDS B EAV=217.5 20 +106PD G 1315.66 8 0.0030 5 E2 5.86E-49 +106PD2 G KC=4.89E-4 7$LC=5.67E-5 8$MC=1061E-8 15 +106PD G 2366.04 7 0.0232 7 E2 6.63E-410 +106PD2 G KC=1608E-7 23$LC=1.82E-5 3$MC=3.41E-6 5 +106PD L 2902.48 102+ +106PD B 644 5 0.00760 18 6.29 +106PDS B EAV=208.1 19 +106PD G 1774.44 100.00094 8 +106PD G 2390.6 1 0.00659 16M1+E2 -0.1 6.54E-410 +106PD2 G KC=1645E-7 24$LC=1.86E-5 3$MC=3.49E-6 5 +106PD G 2902.6 5 6.6E-5 21 +106PD L 2917.86 8 2+ +106PD B 628 5 0.0183 7 5.87 +106PDS B EAV=202.3 19 +106PD G 1355.60 9 0.00060 25 +106PD G 1360.17 9 0.0018 4 +106PD G 1784.08 9 0.00043 12 +106PD G 2405.98 8 0.0145 4 M1+E2 -0.05 6.59E-410 +106PD2 G KC=1626E-7 23$LC=1.84E-5 3$MC=3.44E-6 5 +106PD G 2917.6 3 0.00094 4 +106PD L 2968.68 213- +106PD B 577 5 0.00022 4 7.82 1U +106PDS B EAV=202.8 19 +106PD G 2456.79 210.00022 4 +106PD L 3037.32 171,2+ +106PD B 509 5 0.0022 3 +106PDS B EAV= +106PD G 1909.28 170.00107 25 +106PD G 2525.43 170.00011 3 +106PD G 3037.3 3 0.00105 4 +106PD L 3054.97 9 1+ +106PD B 491 5 0.0101 5 5.76 +106PDS B EAV=151.8 18 +106PD G 1498.73 160.0068 4 +106PD G 2542.79 100.00289 9 M1+E2 0.07 7 7.05E-410 +106PD2 G KC=1464E-7 21$LC=1657E-8 24$MC=3.10E-6 5 +106PD G 3055.0 3 0.00036 4 +106PD L 3083.91 180+ +106PD B 462 5 0.00278 13 +106PDS B EAV= +106PD G 1854.89 200.00125 10 +106PD G 1954.9 4 0.00020 4 +106PD G 2571.16 200.00133 6 +106PD L 3163.7 3 (1,2)+ +106PD B 382 5 0.00070 5 6.55 +106PDS B EAV=113.8 17 +106PD G 2651.39 200.00068 4 +106PD G 3164.6 102.3E-5 12 +106PD L 3221.37 250+ +106PD B 325 5 0.00402 13 5.56 +106PDS B EAV=94.5 17 +106PD G 2093.33 250.00029 6 E2 5.76E-48 +106PD2 G KC=2.00E-4 3$LC=2.28E-5 4$MC=4.26E-6 6 +106PD G 2709.48 250.00373 11E2 7.85E-411 +106PD2 G KC=1271E-7 18$LC=1436E-8 21$MC=2.68E-6 4 +106PD L 3249.9 5 2+ +106PD B 296 5 86000E-916 7.09 +106PDS B EAV=85.2 17 +106PD G 3249.8 5 8.6E-5 16 +106PD L 3252.0 4 2+ +106PD B 294 5 0.00021 4 6.7 +106PDS B EAV=84.5 17 +106PD G 2740.1 4 0.00021 4 +106PD L 3273.5 7 1,2+ +106PD B 272 5 49000E-914 +106PDS B EAV= +106PD G 3273.4 7 4.9E-5 14 +106PD L 3299.2 7 + +106PD B 247 5 82000E-921 +106PDS B EAV= +106PD G 2788.2 5 8.2E-5 21 +106PD L 3320.5 3 0+ +106PD B 226 5 0.00087 8 5.71 +106PDS B EAV=62.9 16 +106PD G 2185.7 5 0.00025 6 +106PD G 2809.1 3 0.00062 4 E2 8.22E-412 +106PD2 G KC=1195E-7 17$LC=1349E-8 19$MC=2.52E-6 4 +106PD L 3376.6 9 + +106PD B 169 5 25000E-99 +106PDS B EAV= +106PD G 2865 1 1.4E-5 8 +106PD G 3375.9 141.13E-5 21 +106PD L 3401.9 6 + +106PD B 144 5 12500E-919 +106PDS B EAV= +106PD G 3401.8 9 1.25E-5 19 + diff --git a/HEN_HOUSE/spectra/lnhb/Rn-217.txt b/HEN_HOUSE/spectra/lnhb/Rn-217.txt new file mode 100644 index 000000000..593948827 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Rn-217.txt @@ -0,0 +1,15 @@ +213PO 217RN A DECAY (0.54 MS) +213PO H TYP=Full$AUT=Huang Xiaolong$CUT=31-DEC-2007$ +213PO C Evaluation history: Type=Full;Author=Huang Xiaolong;Cutoff date=31-DEC-2007 +213PO T Auger electrons and ^X ray energies and emission intensities: +213PO T {U Energy (keV)} {U Intensity } {U Line } +213PO T +213PO T +213PO T +213PO T +213PO T +217RN P 0.0 9/2+ 0.54 MS 5 7887 3 +213PO N 1.0 1.0 1 1.0 +213PO L 0 9/2+ 3.70 US 5 +213PO A 7742 3 100 1.49 + diff --git a/HEN_HOUSE/spectra/lnhb/Rn-218.txt b/HEN_HOUSE/spectra/lnhb/Rn-218.txt new file mode 100644 index 000000000..cdd0db619 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Rn-218.txt @@ -0,0 +1,35 @@ +214PO 218RN A DECAY (36.0 MS) +214PO H TYP=Full$AUT=V.Chisté$CUT= -- $ +214PO C Evaluation history: Type=Full;Author=V.Chisté;Cutoff date= -- +214PO C References: 1956As38, 1958To25, 1961Ru06, 1963Di05, 1969Pe17, 1971Er02, +214PO2C 1976Ku08, 1979Ry03, 1982Bo04, 1987El12, 1991Ry01, 1995El07, 1996Sc06, +214PO3C 1998Ak04, 2002Ba85, 2003Au03 +214PO T Auger electrons and ^X ray energies and emission intensities: +214PO T {U Energy (keV)} {U Intensity } {U Line } +214PO T +214PO T 76.864 0.00052 4 XKA2 +214PO T 79.293 0.00086 6 XKA1 +214PO T +214PO T 89.256 |] XKB3 +214PO T 89.807 |] 0.000296 21 XKB1 +214PO T 90.363 |] XKB5II +214PO T +214PO T 92.263 |] XKB2 +214PO T 92.618 |] 0.000092 7 XKB4 +214PO T 92.983 |] XKO23 +214PO T +214PO T 9.66-16.21 0.00080 3 XL (total) +214PO T 9.66 0.0000190 11 XLL +214PO T 11.0161-11.1303 0.000349 18 XLA +214PO T 12.0847 0.0000067 4 XLC +214PO T 12.8239-13.6358 0.000356 15 XLB +214PO T 15.251-16.21 0.000072 3 XLG +218RN P 0.0 0+ 36.0 MS 19 7262.5 19 +214PO N 1.0 1.0 1 1.0 +214PO L 0 0+ 162.3 US 12 +214PO A 7129.2 1999.873 7 1 +214PO L 609.31 6 2+ +214PO A 6531.1 190.127 7 4.8 +214PO G 609.31 6 0.124 7 E2 0.0204 3 +214PO2 G KC=0.01487 21$LC=0.00416 6$MC=1030E-6 15 + diff --git a/HEN_HOUSE/spectra/lnhb/Rn-219.txt b/HEN_HOUSE/spectra/lnhb/Rn-219.txt new file mode 100644 index 000000000..bfd52d146 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Rn-219.txt @@ -0,0 +1,102 @@ +215PO 219RN A DECAY (3.98 S) +215PO H TYP=Full$AUT=A.L. Nichols$CUT=30-OCT-2010$ +215PO C Evaluation history: Type=Full;Author=A.L. Nichols;Cutoff date=30-OCT-2010 +215PO C References: 1961Ro14, 1962Wa18, 1965Va10, 1966Hu20, 1967Da20, 1968Br17, +215PO2C 1970Da09, 1970Kr08, 1971Gr07, 1976Bl13, 1977La19, 1991Ry01, 1996Sc06, +215PO3C 1998Ak04, 1998ScZM, 1999Li05, 1999ScZX, 2001Br31, 2002Ba85, 2002Ra45, +215PO4C 2003Au03, 2008Ki07 +215PO T Auger electrons and ^X ray energies and emission intensities: +215PO T {U Energy (keV)} {U Intensity } {U Line } +215PO T +215PO T 76.864 0.540 24 XKA2 +215PO T 79.293 0.90 4 XKA1 +215PO T +215PO T 89.256 |] XKB3 +215PO T 89.807 |] 0.309 15 XKB1 +215PO T 90.363 |] XKB5II +215PO T +215PO T 92.263 |] XKB2 +215PO T 92.618 |] 0.096 5 XKB4 +215PO T 92.983 |] XKO23 +215PO T +215PO T 9.658-16.213 1.01 5 XL (total) +215PO T 9.658 0.0229 9 XLL +215PO T 11.016-11.13 0.420 15 XLA +215PO T 12.085 0.0095 4 XLC +215PO T 12.823-13.778 0.475 13 XLB +215PO T 15.742-16.213 0.098 3 XLG +215PO T +215PO T 58.978-65.205 |] KLL AUGER +215PO T 71.902-79.289 |] 0.067 9 ^KLX AUGER +215PO T 84.8-93.1 |] KXY AUGER +215PO T 5.434-10.934 1.50 5 L AUGER +219RN P 0.0 5/2+ 3.98 S 3 6946.1 3 +215PO N 1.0 1.0 1 1.0 +215PO G 665.5 100.00009 5 +215PO L 0 9/2+ 1.781 MS 4 +215PO A 6819.2 3 79.4 1011.2 +215PO L 271.228 107/2+ +215PO A 6553.0 3 12.6 3 6.75 +215PO G 271.228 1011.07 22M1+E2 4.0 4 0.201 7 +215PO2 G KC=0.111 6$LC=0.0668 11$MC=0.0173 3 +215PO L 293.56 4 (11/2)+ +215PO A 6531.0 3 0.098 5 710 +215PO G 293.56 4 0.075 3 M1+E2 1.0 2 0.34 5 +215PO2 G KC=0.25 4$LC=0.062 4$MC=0.0152 7 +215PO L 401.812 105/2+ +215PO A 6424.8 3 7.85 243.31 +215PO G 130.58 1 0.133 11M1+E2 0.60 6 4.44 13 +215PO2 G KC=3.19 16$LC=0.94 4$MC=0.234 10 +215PO G 401.81 1 6.75 22E2 0.0555 8 +215PO2 G KC=0.0351 5$LC=0.01528 22$MC=0.00390 6 +215PO L 517.60 6 7/2,9/2+ +215PO A 6311.1 3 0.048 3 184 +215PO G 224.04 7 0.0014 2 (E2) 0.319 5 +215PO2 G KC=0.1296 19$LC=0.1407 20$MC=0.0370 6 +215PO G 517.60 6 0.043 3 M1+E2 1.0 2 0.073 10 +215PO2 G KC=0.058 9$LC=0.0115 11$MC=0.00277 24 +215PO L 608.30 7 (11/2,13/2)+ +215PO A 6222.0 3 0.0043 10860 +215PO G 608.30 7 0.0044 10(M1+E2) +215PO L 676.66 7 + +215PO A 6154.9 3 0.0184 22103 +215PO G 383.1 1 0.00044 7 +215PO G 405.4 1 0.00025 4 +215PO G 676.66 7 0.018 2 +215PO L 708.1 5 + +215PO A 6124.1 6 0.00064 122170 +215PO G 436.9 5 0.00031 6 +215PO G 708.1 5 0.00033 11 +215PO L 732.7 4 + +215PO A 6099.9 5 0.00123 12880 +215PO G 330.9 4 0.00100 11 +215PO G 461.5 4 0.00017 3 +215PO G 732.7 4 0.00007 4 +215PO L 835.32 22 + +215PO A 5999.2 4 0.0032 5 120 +215PO G 564.1 2 0.0015 3 +215PO G 835.32 220.0017 3 +215PO L 877.2 6 + +215PO A 5958.1 7 0.0003 1 830 +215PO G 877.2 6 0.00033 11 +215PO L 891.1 3 + +215PO A 5944.4 4 0.0021 3 103 +215PO G 373.5 3 0.00025 3 +215PO G 489.3 3 0.00064 9 +215PO G 619.9 3 0.00033 11 +215PO G 891.1 3 0.0009 2 +215PO L 930 1 + +215PO A 5906.2 100.00009 5 1590 +215PO G 322 1 0.00009 5 +215PO L 1073.7 4 (5/2)+ +215PO A 5765.1 5 0.00094 1933 +215PO G 556.1 4 0.00006 4 M1+E2 1.0 2 0.061 8 +215PO2 G KC=0.048 7$LC=0.0095 9$MC=0.00226 21 +215PO G 671.9 4 0.00022 11M1+E2 +215PO G 802.5 4 0.00033 11M1+E2 +215PO G 1073.7 4 0.00033 11E2 0.006419 +215PO2 G KC=0.00510 8$LC=1002E-6 14$MC=2.40E-4 4 +215PO L 1094.2 10 + +215PO A 5745 1 0.00009 5 245 +215PO G 576.6 100.00009 5 + diff --git a/HEN_HOUSE/spectra/lnhb/Rn-220.txt b/HEN_HOUSE/spectra/lnhb/Rn-220.txt new file mode 100644 index 000000000..f0368ec27 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Rn-220.txt @@ -0,0 +1,43 @@ +216PO 220RN A DECAY (55.8 S) +216PO H TYP=Update$AUT=A.L. Nichols$CUT=30-APR-2010$ +216PO2 H TYP=Full$AUT=A.L. Nichols$CUT=30-APR-2003$ +216PO C Evaluation history: Type=Update;Author=A.L. Nichols;Cutoff date=30-APR-2010 +216PO2C Type=Full;Author=A.L. Nichols;Cutoff date=30-APR-2003 +216PO C References: 1955Sc81, 1956Ma28, 1961Ro14, 1962Wa28, 1963Gi17, 1966Hu20, +216PO2C 1972DaZA, 1973Da38, 1977La19, 1977Ku15, 1984Ge07, 1996Sc06, 1997Ar04, +216PO3C 1998ScZM, 1999ScZX, 2002Ba85, 2002Ra45, 2003Au03, 2007St23, 2007Wu02, +216PO4C 2008Ki07 +216PO T Auger electrons and ^X ray energies and emission intensities: +216PO T {U Energy (keV)} {U Intensity } {U Line } +216PO T +216PO T 76.864 0.00059 8 XKA2 +216PO T 79.293 0.00099 13 XKA1 +216PO T +216PO T 89.256 |] XKB3 +216PO T 89.807 |] 0.00034 5 XKB1 +216PO T 90.363 |] XKB5II +216PO T +216PO T 92.263 |] XKB2 +216PO T 92.618 |] 0.000106 15 XKB4 +216PO T 92.983 |] XKO23 +216PO T +216PO T 9.658-16.213 0.00094 8 XL (total) +216PO T 9.658 0.0000222 22 XLL +216PO T 11.016-11.13 0.00041 4 XLA +216PO T 12.085 0.0000081 9 XLC +216PO T 12.823-13.778 0.00042 4 XLB +216PO T 15.742-16.213 0.000086 7 XLG +216PO T +216PO T 58.978-65.205 |] KLL AUGER +216PO T 71.902-79.289 |] 0.000074 13 ^KLX AUGER +216PO T 84.8-93.1 |] KXY AUGER +216PO T 5.434-10.934 0.00140 11 L AUGER +220RN P 0.0 0+ 55.8 S 3 6404.67 10 +216PO N 1.0 1.0 1 1.0 +216PO L 0 0+ 0.148 S 4 +216PO A 6288.22 1099.882 151 +216PO L 549.76 4 2+ +216PO A 5748.46 110.118 153.1 +216PO G 549.76 4 0.115 15E2 0.0257 4 +216PO2 G KC=0.0183 3$LC=0.00561 8$MC=1399E-6 20 + diff --git a/HEN_HOUSE/spectra/lnhb/Rn-222.txt b/HEN_HOUSE/spectra/lnhb/Rn-222.txt new file mode 100644 index 000000000..d73bc2778 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Rn-222.txt @@ -0,0 +1,37 @@ +218PO 222RN A DECAY (3.8232 D) +218PO H TYP=Full$AUT=V.Chisté$CUT= -- $ +218PO C Evaluation history: Type=Full;Author=V.Chisté;Cutoff date= -- +218PO C References: 1951To25, 1956Ma28, 1956Ma64, 1956Ro31, 1958Sh69, 1958Wa16, +218PO2C 1971Gr17, 1972Bu33, 1979Ry03, 1987El12, 1990Ho28, 1991Ry01, 1995El08, +218PO3C 1996El01, 1996Sc06, 2002Ba85, 2003Au03, 2004Sc04, 2006Ja03, 2007BeZP +218PO T Auger electrons and ^X ray energies and emission intensities: +218PO T {U Energy (keV)} {U Intensity } {U Line } +218PO T +218PO T 76.864 0.000469 10 XKA2 +218PO T 79.293 0.000781 16 XKA1 +218PO T +218PO T 89.256 |] XKB3 +218PO T 89.807 |] 0.000269 7 XKB1 +218PO T 90.363 |] XKB5II +218PO T +218PO T 92.263 |] XKB2 +218PO T 92.618 |] 0.0000837 25 XKB4 +218PO T 92.983 |] XKO23 +218PO T +218PO T 9.66-16.21 0.000766 15 XL (total) +218PO T 9.66 0.0000178 5 XLL +218PO T 11.0161-11.1303 0.000326 9 XLA +218PO T 12.0847 0.00000665 19 XLC +218PO T 12.8239-14.2476 0.000345 8 XLB +218PO T 15.251-16.21 0.0000702 16 XLG +222RN P 0.0 0+ 3.8232 D 8 5590.3 3 +218PO N 1.0 1.0 1 1.0 +218PO L 0 0+ 3.071 M 22 +218PO A 5489.48 3099.92 1 1 +218PO L 511 2 2+ +218PO A 4987 1 0.078 1.9 +218PO G 510 2 7600E-5 0 [E2] 0.0306 6 +218PO2 G KC=0.0213 4$LC=0.00704 13$MC=0.00177 4 +218PO L 675 5 + +218PO A 4827 4 0.0005 30 + diff --git a/HEN_HOUSE/spectra/lnhb/Ru-106.txt b/HEN_HOUSE/spectra/lnhb/Ru-106.txt new file mode 100644 index 000000000..69706e280 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Ru-106.txt @@ -0,0 +1,29 @@ +106RH 106RU B- DECAY (371.5 D) +106RH H TYP=Full$AUT=A.Arinc$CUT=31-DEC-2012$ +106RH C Evaluation history: Type=Full;Author=A.Arinc;Cutoff date=31-DEC-2012 +106RH C References: 1950Ag01, 1956Sc87, 1957Me47, 1960Ea02, 1961Wy01, 1965Fl02, +106RH2C 1980Ho17, 1983Wa26, 2004Sc04, 2012Wa38 +106RH T Auger electrons and ^X ray energies and emission intensities: +106RH T {U Energy (keV)} {U Intensity } {U Line } +106RH T +106RH T 20.0739 XKA2 +106RH T 20.2163 XKA1 +106RH T +106RH T 22.6991 |] XKB3 +106RH T 22.7238 |] XKB1 +106RH T 22.914 |] XKB5II +106RH T +106RH T 23.173 |] XKB2 +106RH T 23.217 |] XKB4 +106RH T +106RH T +106RH T 16.289-17.097 |] KLL AUGER +106RH T 19.138-20.214 |] ^KLX AUGER +106RH T 21.966-23.215 |] KXY AUGER +106RH T 1.7496-3.4069 L AUGER +106RU P 0.0 0+ 371.5 D 21 39.40 21 +106RH N 1.0 1.0 1 1.0 +106RH L 0 1+ 30.1 S 3 +106RH B 39.40 21100 4.31 +106RHS B EAV=10.03 6 + diff --git a/HEN_HOUSE/spectra/lnhb/S-35.txt b/HEN_HOUSE/spectra/lnhb/S-35.txt new file mode 100644 index 000000000..bc8bfe587 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/S-35.txt @@ -0,0 +1,20 @@ + 35CL 35S B- DECAY (87.25 D) + 35CL H TYP=Full$AUT=M.M. Bé$CUT=15-JAN-2011$ + 35CL2 H TYP=Full$AUT=V.P.Chechev$CUT=30-SEP-1998$ + 35CL C Evaluation history: Type=Full;Author=M.M. Bé;Cutoff date=15-JAN-2011 + 35CL2C Type=Full;Author=V.P.Chechev;Cutoff date=30-SEP-1998 + 35CL C References: 1940Le**, 1941Ka01, 1943He**, 1949Ma76, 1952Ru23, 1958Se49, + 35CL2C 1959Co56, 1959Ca12, 1961Oz01, 1961Wy01, 1965Fl02, 1968Wo06, 1969La34, + 35CL3C 1999Pa18, 2012Au06 + 35CL T Auger electrons and ^X ray energies and emission intensities: + 35CL T {U Energy (keV)} {U Intensity } {U Line } + 35CL T + 35CL T + 35CL T + 35CL T + 35S P 0.0 3/2+ 87.25 D 15 167.33 3 + 35CL N 1.0 1.0 1 1.0 + 35CL L 0 3/2+ STABLE + 35CL B 167.33 3 100 5.01 + 35CLS B EAV=48.79 1 + diff --git a/HEN_HOUSE/spectra/lnhb/Sb-124.txt b/HEN_HOUSE/spectra/lnhb/Sb-124.txt new file mode 100644 index 000000000..8d836dbed --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Sb-124.txt @@ -0,0 +1,224 @@ +124TE 124SB B- DECAY (60.208 D) +124TE H TYP=Full$AUT=M.M. Bé$CUT=31-DEC-2008$ +124TE C Evaluation history: Type=Full;Author=M.M. Bé;Cutoff date=31-DEC-2008 +124TE C References: 1953La35, 1954Mo83, 1955Az29, 1956Zo06, 1957Ma50, 1956Zo06, +124TE2C 1958Jo01, 1959Ca12, 1965Hs02, 1966Fl01, 1967ST05, 1968Gr24, 1968Re04, +124TE3C 1968Gr24, 1969Me04, 1969Ra31, 1970Si17, 1971GR14, 1972BA38, 1974Jo03, +124TE4C 1979Sh08, 1983RO13, 1984Ma13, 1984Iw03, 1988YO05, 1990Su10, 1990ME15, +124TE5C 1993Go10, 1996Sc06, 2000Kh04, 2000He14, 2000Do11, 2002Ba85, 2003AU03, +124TE6C 2006Pa16, 2008Ki07 +124TE T Auger electrons and ^X ray energies and emission intensities: +124TE T {U Energy (keV)} {U Intensity } {U Line } +124TE T +124TE T 27.202 0.1252 18 XKA2 +124TE T 27.4726 0.233 3 XKA1 +124TE T +124TE T 30.9446 |] XKB3 +124TE T 30.996 |] 0.0667 12 XKB1 +124TE T 31.236 |] XKB5II +124TE T +124TE T 31.7008 |] XKB2 +124TE T 31.774 |] 0.0145 5 XKB4 +124TE T 31.812 |] XKO23 +124TE T +124TE T 3.3348-4.8228 0.0449 9 XL (total) +124TE T 3.3348 0.000873 26 XLL +124TE T 3.7595-3.7697 0.0231 7 XLA +124TE T 3.6052 0.000336 11 XLC +124TE T 4.0299-4.3661 0.0180 4 XLB +124TE T 4.4448-4.8228 0.00247 6 XLG +124TE T +124TE T 21.804-22.989 |] KLL AUGER +124TE T 25.814-27.47 |] 0.0628 22 ^KLX AUGER +124TE T 29.8-31.81 |] KXY AUGER +124TE T 2.3-4.9 0.4829 26 L AUGER +124SB P 0.0 3- 60.208 D 11 2904.3 15 +124TE N 1.0 1.0 1 1.0 +124TE G 159.867 350.0049 6 +124TE G 997.8 3 0.0033 23 +124TE G 1235 1 0.0073 26 +124TE L 0 0+ STABLE +124TE L 602.7278 212+ 6.2 PS 1 +124TE B 2301.6 1523.44 28 10.3 1 +124TES B EAV=918 1 +124TE G 602.7260 2397.775 20E2 0.004907 +124TE2 G KC=0.00420 6$LC=5.66E-4 8$MC=1132E-7 16 +124TE L 1248.582 3 4+ +124TE B 1655.7 152.472 33 10.7 1 +124TES B EAV=627 1 +124TE G 645.8520 197.422 15E2+M3 0.006 6 0.004096 +124TE2 G KC=0.00351 5$LC=4.68E-4 7$MC=9.35E-5 14 +124TE L 1325.512 3 2+ +124TE B 1578.8 154.815 29 10.3 1 +124TES B EAV=593 1 +124TE G 722.782 3 10.708 22M1+E2 -3.4 3 0.003145 +124TE2 G KC=0.00271 4$LC=3.52E-4 5$MC=7.02E-5 10 +124TE G 1325.504 4 1.587 7 E2 8.27E-412 +124TE2 G KC=6.93E-4 10$LC=8.48E-5 12$MC=1685E-8 24 +124TE L 1656.6 3 0+ +124TE B 1247.7 150.0053 10 12.8 3 +124TES B EAV=450 1 +124TE G 1053.9 3 0.0053 10E2 1290E-618 +124TE2 G KC=1117E-6 16$LC=1394E-7 20$MC=2.77E-5 4 +124TE G 1656.6 3 +124TE L 1957.915 164+ +124TE B 946.4 152.295 7 9.8 1 +124TES B EAV=324 1 +124TE G 632.40 2 0.1029 21 +124TE G 709.33 2 1.363 5 M1+E2 -0.18 5 0.004026 +124TE2 G KC=0.00349 5$LC=4.29E-4 7$MC=8.53E-5 13 +124TE G 1355.20 2 1.0412 38E2+M3 -0.32 25 0.0011 5 +124TE2 G KC=0.0009 5$LC=0.00011 6$MC=2.3E-5 11 +124TE L 2039.288 4 2, 3+ +124TE B 865.0 154.143 18 9.4 1 +124TES B EAV=292 1 +124TE G 713.776 4 2.273 7 M1+E2 1.0 5 0.0036 4 +124TE2 G KC=0.0031 4$LC=0.00039 4$MC=7.8E-5 7 +124TE G 790.706 7 0.7415 24E2 0.002488 +124TE2 G KC=0.00214 6$LC=2.76E-4 8$MC=5.5E-5 2 +124TE G 1436.554 7 1.234 8 M1+E2 1.5 8 0.000785 +124TE2 G KC=0.00063 5$LC=7.6E-5 6$MC=1.51E-5 11 +124TE G 2039.27 1 0.0631 5 E2 6.67E-410 +124TE2 G KC=3.05E-4 5$LC=3.64E-5 5$MC=7.21E-6 10 +124TE L 2091.680 212+ +124TE B 812.6 150.688 38 10 1 +124TES B EAV=271.0 6 +124TE G 766.17 2 0.0103 9 M1 0.021 7 +124TE2 G KC=0.019 6$LC=$MC= +124TE G 1488.94 2 0.6770 37M1+E2 0.10 23 8.29E-416 +124TE2 G KC=6.59E-4 14$LC=7.92E-5 16$MC=1.57E-5 3 +124TE L 2182.39 3 2+ +124TE B 721.9 150.47 30 10 1 +124TES B EAV=236.0 6 +124TE G 856.87 3 0.0227 5 +124TE G 1579.65 3 0.412 5 M1+E2 0.000725 +124TE2 G KC=0.00054 5$LC=6.5E-5 6$MC=1.28E-5 11 +124TE G 2182.37 3 0.04147 31 +124TE L 2224.839 254+ +124TE B 679.5 150.0967 34 10.6 1 +124TES B EAV=219.5 6 +124TE G 899.32 3 0.0179 7 +124TE G 976.25 3 0.0832 7 +124TE G 1622.10 3 0.0416 19E2 6.64E-410 +124TE2 G KC=4.67E-4 7$LC=5.64E-5 8$MC=1118E-8 16 +124TE L 2293.712 4 3- +124TE B 610.6 1551.21 19 7.7 +124TES B EAV=193.8 6 +124TE G 254.42 1 0.0142 9 (E1) 0.0146521 +124TE2 G KC=0.01269 18$LC=1575E-6 22$MC=3.12E-4 5 +124TE G 335.80 2 0.0725 9 E1 0.0070610 +124TE2 G KC=0.00612 9$LC=7.54E-4 11$MC=1495E-7 21 +124TE G 968.195 4 1.887 10E1+M2 -0.02 2 6.53E-411 +124TE2 G KC=5.69E-4 9$LC=6.78E-5 11$MC=1343E-8 22 +124TE G 1045.125 4 1.852 14E1+M2 -0.03 2 5.67E-410 +124TE2 G KC=4.94E-4 9$LC=5.87E-5 11$MC=1163E-8 21 +124TE G 1690.971 4 47.46 19E1+M2 0.01 3 6.15E-49 +124TE2 G KC=2.13E-4 4$LC=2.50E-5 4$MC=4.94E-6 8 +124TE G 2293.69 1 0.0327 41 +124TE L 2323.41 3 2+ +124TE B 580.9 150.0686 14 10.5 1 +124TES B EAV=182.8 6 +124TE G 1720.67 3 0.0946 6 M1+E2 0.000684 +124TE2 G KC=0.00045 4$LC=5.4E-5 4$MC=1.07E-5 8 +124TE G 2323.39 3 0.0025 6 +124TE L 2335.26 5 5- +124TE G 1086.67 5 0.0367 9 E1 5.24E-48 +124TE2 G KC=4.57E-4 7$LC=5.43E-5 8$MC=1074E-8 15 +124TE L 2454.96 7 2+ +124TE B 449.3 150.0050 26 11.3 1 +124TES B EAV=135.8 6 +124TE G 1852.22 7 0.0030 9 M1+E2 0.000673 +124TE2 G KC=0.00039 3$LC=4.7E-5 4$MC=9.3E-6 7 +124TE G 2454.93 7 0.00160 12E2 7.68E-411 +124TE2 G KC=2.19E-4 3$LC=2.59E-5 4$MC=5.13E-6 8 +124TE L 2483.277 184+ +124TE B 421.0 150.332 10 9.4 1 +124TES B EAV=126.0 5 +124TE G 148.02 5 0.0037 6 E1+M2 +124TE G 189.57 2 0.0043 5 +124TE G 444.00 2 0.195 16M1+E2 0.06 8 0.0126118 +124TE2 G KC=0.01092 16$LC=1360E-6 19$MC=2.71E-4 4 +124TE G 525.36 3 0.1451 35M1+E2 1.0 4 0.0077 3 +124TE2 G KC=0.0066 3$LC=8.67E-4 18$MC=1.73E-4 4 +124TE L 2512.04 7 4+ +124TE B 392.3 150.0422 19 10.2 1 +124TES B EAV=116.0 5 +124TE G 1263.45 7 0.0422 19 +124TE L 2521.48 6 2+ +124TE B 382.8 150.0529 5 10 1 +124TES B EAV=113.0 5 +124TE G 1918.74 6 0.0529 5 M1(+E2) 0.000673 +124TE2 G KC=3.64E-4 24$LC=4.3E-5 3$MC=8.6E-6 6 +124TE L 2549.73 9 (4)+ +124TE B 354.6 150.0364 22 10 1 +124TES B EAV=103.6 5 +124TE G 1301.14 9 0.0364 22 +124TE L 2619.09 6 (3)+ +124TE B 285.2 150.0098 8 10.4 +124TES B EAV=81.0 5 +124TE G 2016.34 6 0.0098 8 +124TE L 2682.50 132+ +124TE B 221.8 150.0242 22 9.6 1 +124TES B EAV=61.5 5 +124TE G 2079.75 130.0224 22M1+E2 6.91E-420 +124TE2 G KC=3.11E-4 18$LC=3.71E-5 21$MC=7.3E-6 4 +124TE G 2682.47 130.00176 6 +124TE L 2693.679 5 3- +124TE B 210.6 158.663 27 7 +124TES B EAV=58.0 5 +124TE G 210.40 2 0.0053 7 +124TE G 370.27 3 0.0286 11 +124TE G 399.97 1 0.1264 31E2 0.0156622 +124TE2 G KC=0.01323 19$LC=0.00196 3$MC=3.94E-4 6 +124TE G 468.84 3 0.0459 26E1 0.003095 +124TE2 G KC=0.00268 4$LC=3.27E-4 5$MC=6.48E-5 9 +124TE G 1368.157 5 2.620 8 E1+M2 -0.02 1 4.78E-47 +124TE2 G KC=3.03E-4 5$LC=3.58E-5 6$MC=7.09E-6 10 +124TE G 1445.09 1 0.334 7 E1+M2 0.10 9 0.000524 +124TE2 G KC=0.00029 4$LC=3.4E-5 4$MC=6.7E-6 8 +124TE G 2090.930 7 5.493 24E1+M2 0.03 2 8.38E-412 +124TE2 G KC=1522E-7 23$LC=1.78E-5 3$MC=3.52E-6 6 +124TE G 2693.65 1 0.0032 14 +124TE L 2701.622 9 2- +124TE B 202.7 150.571 25 8 +124TES B EAV=55.7 5 +124TE G 662.33 1 0.024 11 +124TE G 1376.10 1 0.4999 43E1+M2 -0.01 3 4.79E-47 +124TE2 G KC=3.00E-4 5$LC=3.54E-5 6$MC=7.01E-6 12 +124TE G 2098.88 1 0.0471 33 +124TE L 2711.012 214+ +124TE B 193.3 150.106 6 8.8 1 +124TES B EAV=52.9 5 +124TE G 1385.49 2 0.062 6 +124TE G 2108.27 2 0.0444 23 +124TE L 2775.070 173,4- +124TE B 129.2 150.653 6 7.5 +124TES B EAV=34.4 4 +124TE G 291.79 3 0.0069 7 +124TE G 481.36 2 0.0232 31 +124TE G 735.78 2 0.1312 16 +124TE G 817.15 3 0.0744 12 +124TE G 1526.48 2 0.414 5 E1 5.35E-48 +124TE2 G KC=2.52E-4 4$LC=2.96E-5 5$MC=5.86E-6 9 +124TE G 2172.32 2 0.0029 16 +124TE L 2807.55 242+ +124TE B 96.8 150.0012 5 9.8 1 +124TES B EAV=25.3 4 +124TE G 2807.52 240.0012 5 E2 8.78E-413 +124TE2 G KC=1730E-7 25$LC=2.04E-5 3$MC=4.04E-6 6 +124TE L 2814.56 7 2 TO 5+ +124TE B 89.7 150.0207 12 8.4 +124TES B EAV=23.4 4 +124TE G 775.27 7 0.0098 4 +124TE G 1565.97 7 0.0109 12 +124TE L 2865.72 5 3- +124TE B 38.6 150.054 9 6.9 +124TES B EAV=9.8 4 +124TE G 530.46 7 0.036 9 +124TE G 572.01 5 0.0176 8 +124TE L 2886.37 6 3- +124TE B 17.9 150.0059 5 6.9 +124TES B EAV=4.5 4 +124TE G 2283.62 6 0.0059 5 E1+M2 0.000915 +124TE2 G KC=0.00033 21$LC=4.0E-5 25$MC=8E-6 5 + diff --git a/HEN_HOUSE/spectra/lnhb/Sb-125.txt b/HEN_HOUSE/spectra/lnhb/Sb-125.txt new file mode 100644 index 000000000..25c53cf33 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Sb-125.txt @@ -0,0 +1,112 @@ +125TE 125SB B- DECAY (2.75855 Y) +125TE H TYP=Full$AUT=R.G.Helmer and E.Browne$CUT=10-NOV-2004$ +125TE2 H TYP=Full$AUT=R.G.Helmer$CUT=01-MAY-2004$ +125TE C Evaluation history: Type=Full;Author=R.G.Helmer and E.Browne;Cutoff date=10-NOV-2004 +125TE2C Type=Full;Author=R.G.Helmer;Cutoff date=01-MAY-2004 +125TE C References: 1990Ne01 +125TE T Auger electrons and ^X ray energies and emission intensities: +125TE T {U Energy (keV)} {U Intensity } {U Line } +125TE T +125TE T 27.202 21.0 9 XKA2 +125TE T 27.4726 39.1 15 XKA1 +125TE T +125TE T 30.9446 |] XKB3 +125TE T 30.996 |] 11.2 5 XKB1 +125TE T 31.236 |] XKB5II +125TE T +125TE T 31.7008 |] XKB2 +125TE T 31.774 |] 2.43 12 XKB4 +125TE T 31.812 |] XKO23 +125TE T +125TE T 3.3348-4.8228 6.56 21 XL (total) +125TE T 3.3348 0.135 6 XLL +125TE T 3.7595-3.7697 3.58 15 XLA +125TE T 3.6052 0.0508 24 XLC +125TE T 4.0299-4.3003 2.48 9 XLB +125TE T 4.4448-4.8228 0.311 13 XLG +125TE T +125TE T 21.804-22.989 |] KLL AUGER +125TE T 25.814-27.47 |] 10.5 6 ^KLX AUGER +125TE T 29.8-31.81 |] KXY AUGER +125TE T 2.3-4.8 70.6 9 L AUGER +125SB P 0.0 7/2+ 2.75855 Y 25 766.7 21 +125TE N 1.0 1.0 1 1.0 +125TE L 0 1/2+ STABLE +125TE L 35.490 3 3/2+ 1.48 NS 1 +125TE G 35.489 5 5.79 18M1+E2 14.3 4 +125TE2 G KC=12.1 4$LC=1.64 5$MC=0.329 10 +125TE L 144.776 1111/2- 57.40 D 15 +125TE B 621.0 2113.4 9 9.77 3U +125TES B EAV=215.5 8 +125TE G 109.276 150.0683 12M4 3.5E2 11 +125TE2 G KC=182 5$LC=135 4$MC=31 1 +125TE L 321.090 119/2- 0.673 NS 13 +125TE B 444.0 217.54 9 9.32 1U +125TES B EAV=134.5 8 +125TE G 176.314 2 6.82 7 M1+E2 0.167 5 +125TE2 G KC=0.139 4$LC=0.0221 7$MC=0.00449 13 +125TE L 402.09 4 7/2+ +125TE L 443.554 6 3/2+ 19.1 PS 6 +125TE B 323.1 210.089 10 10.79 +125TES B EAV=93.3 7 +125TE G 408.065 100.182 2 M1+E2 0.0152 5 +125TE2 G KC=0.0129 4$LC=0.00181 5$MC=0.00036 1 +125TE G 443.555 9 0.305 4 M1+E2 0.0118 4 +125TE2 G KC=0.0100 3$LC=0.00142 4$MC=0.00029 1 +125TE L 463.365 3 5/2+ 13.2 PS 5 +125TE B 303.3 2140.3 4 8.04 2 +125TES B EAV=86.9 7 +125TE G 19.80 6 0.0202 5 [M1] 11.3 3 +125TE2 G KC=$LC=9.1 3$MC=1.82 5 +125TE G 427.874 4 29.55 24M1+E2 0.0138 4 +125TE2 G KC=0.0119 4$LC=0.00154 5$MC=0.00031 1 +125TE G 463.365 4 10.48 9 E2 0.0102 3 +125TE2 G KC=0.0086 3$LC=0.00124 4$MC=0.00025 1 +125TE L 525.227 9 7/2- +125TE B 241.5 211.251 12 9.23 +125TES B EAV=67.5 7 +125TE G 204.138 100.313 15M1+E2 0.128 4 +125TE2 G KC=0.104 3$LC=0.0189 6$MC=0.00386 11 +125TE G 380.452 8 1.520 15E2 0.0183 5 +125TE2 G KC=0.0154 5$LC=0.00233 7$MC=4.73E-4 15 +125TE L 538.60 5 (1/2)+ +125TE L 636.090 4 7/2+ 40 PS 20 +125TE B 130.6 2118.07 19 7.23 +125TES B EAV=34.7 6 +125TE G 110.895 120.00109 9 [E1] 0.147 4 +125TE2 G KC=0.127 4$LC=0.0165 5$MC=0.00328 11 +125TE G 172.719 8 0.192 9 M1(+E2) 0.151 5 +125TE2 G KC=0.129 4$LC=0.0168 5$MC=0.00337 11 +125TE G 314.95 110.0043 3 (E1) 0.0083930 +125TE2 G KC=0.00726 22$LC=0.00089 3$MC=1.79E-4 5 +125TE G 600.597 2 17.76 18E2 0.0049815 +125TE2 G KC=0.00421 13$LC=0.00058 2$MC=1.16E-4 4 +125TE L 642.205 4 7/2+ +125TE B 124.5 215.82 5 7.66 +125TES B EAV=33.0 6 +125TE G 116.955 110.263 4 E1 0.127 4 +125TE2 G KC=0.109 3$LC=0.0141 4$MC=0.00281 8 +125TE G 178.842 5 0.0343 15M1+E2 0.18 4 +125TE2 G KC=0.147 26$LC=0.026 11$MC=0.0054 21 +125TE G 198.654 110.0132 7 [E2] 0.154 5 +125TE2 G KC=0.123 4$LC=0.0245 8$MC=0.00504 15 +125TE G 321.040 4 0.416 4 E1 0.0079824 +125TE2 G KC=0.00691 21$LC=8.56E-4 30$MC=1.70E-4 5 +125TE G 497.37 120.0032 3 [M2] 0.0318 10 +125TE2 G KC=0.0271 8$LC=0.00373 11$MC=0.00075 2 +125TE G 606.713 3 5.02 5 E2 0.0048515 +125TE2 G KC=0.00415 13$LC=0.00056 2$MC=1.13E-4 4 +125TE L 652.9 5 (5/2)+ +125TE L 671.443 4 5/2+ 1.26 PS 6 +125TE B 95.3 2113.58 12 6.93 2 +125TES B EAV=24.9 6 +125TE G 208.077 5 0.246 8 M1+E2 0.092 3 +125TE2 G KC=0.0791 24$LC=0.0102 3$MC=0.00205 6 +125TE G 227.891 100.131 3 (M1+E2) 0.084 13 +125TE2 G KC=0.070 11$LC=0.011 4$MC=0.0023 6 +125TE G 635.950 3 11.32 10M1+E2 0.0052616 +125TE2 G KC=0.00455 14$LC=0.00057 2$MC=1.13E-4 5 +125TE G 671.441 6 1.783 16E2 0.0037311 +125TE2 G KC=0.00319 10$LC=0.00043 1$MC=8.6E-5 2 +125TE L 728.8 5 3/2+ + diff --git a/HEN_HOUSE/spectra/lnhb/Sb-127.txt b/HEN_HOUSE/spectra/lnhb/Sb-127.txt new file mode 100644 index 000000000..5c21664d1 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Sb-127.txt @@ -0,0 +1,159 @@ +127TE 127SB B- DECAY (3.85 D) +127TE H TYP=Full$AUT=A.L. Nichols$CUT=15-MAR-2012$ +127TE C Evaluation history: Type=Full;Author=A.L. Nichols;Cutoff date=15-MAR-2012 +127TE C References: 1939Ab02, 1946Gr06, 1950Sl17, 1957Bo96, 1962Dr01, 1962Uh01, +127TE2C 1967Ha27, 1967Ra13, 1967Ta05, 1972Kr15, 1972Pa13, 1974Sa03, 1977La19, +127TE3C 1977Kr13, 1985De04, 1996Sc06, 1998ScZm, 1999ScZX, 2002Ba25, 2002Ra45, +127TE4C 2003Au03, 2003De44, 2005Ho15, 2008Ki07, 2011Ha31, 2012Au06 +127TE T Auger electrons and ^X ray energies and emission intensities: +127TE T {U Energy (keV)} {U Intensity } {U Line } +127TE T +127TE T 27.202 1.11 4 XKA2 +127TE T 27.4726 2.06 7 XKA1 +127TE T +127TE T 30.9446 |] XKB3 +127TE T 30.996 |] 0.591 21 XKB1 +127TE T 31.232 |] XKB5II +127TE T 31.242 |] XKB5I +127TE T +127TE T 31.7008 |] XKB2 +127TE T 31.774 |] 0.128 6 XKB4 +127TE T 31.182 |] XKO23 +127TE T +127TE T 3.335-4.829 0.462 23 XL (total) +127TE T 3.335 0.0089 4 XLL +127TE T 3.759-3.77 0.235 10 XLA +127TE T 3.605 0.00355 19 XLC +127TE T 4.03-4.302 0.184 7 XLB +127TE T 4.572-4.829 0.0248 10 XLG +127TE T +127TE T 21.804-22.989 |] KLL AUGER +127TE T 25.814-27.47 |] 0.556 26 ^KLX AUGER +127TE T 29.8-31.81 |] KXY AUGER +127TE T 2.29-3.72 4.90 14 L AUGER +127SB P 0.0 7/2+ 3.85 D 7 1582 5 +127TE N 1.0 1.0 1 1.0 +127TE L 0 3/2+ 9.35 H 10 +127TE L 61.161 191/2+ +127TE G 61.16 2 1.140 14M1+E2 0.49 6 4.2 3 +127TE2 G KC=2.93 12$LC=0.99 14$MC=0.21 3 +127TE L 88.23 7 11/2- 106.1 D 7 +127TE B 1494 5 2.0 5 10.21 3U +127TES B EAV=562.4 21 +127TE L 340.87 6 (9/2)- 0.41 NS 2 +127TE B 1241 5 2.4 3 8.98 1U +127TES B EAV=446.9 22 +127TE G 252.64 9 8.28 14M1+E2 -2.1 5 0.0652 17 +127TE2 G KC=0.0541 12$LC=0.0090 4$MC=0.00182 8 +127TE L 473.26 4 5/2+ +127TE B 1109 5 22.6 8 7.826 2 +127TES B EAV=391.2 21 +127TE G 412.10 5 3.43 18E2 0.0143120 +127TE2 G KC=0.01210 17$LC=1775E-6 25$MC=3.57E-4 5 +127TE G 473.26 4 24.8 7 M1+E2 -0.2 1 0.0107216 +127TE2 G KC=0.00928 14$LC=1159E-6 17$MC=2.31E-4 4 +127TE L 501.928 103/2+ +127TE G 440.77 2 0.7 3 M1+E2 0.5 3 0.0126 3 +127TE2 G KC=0.0109 3$LC=1395E-6 22$MC=2.78E-4 5 +127TE G 501.93 1 0.64 11M1+E2 0.34 8 0.0091914 +127TE2 G KC=0.00795 13$LC=9.97E-4 14$MC=1.99E-4 3 +127TE L 631.40 6 7/2- +127TE B 951 5 4.00 21 8.33 +127TES B EAV=326.2 21 +127TE G 290.5 1 1.84 7 M1+E2 0.40 3 0.0379 6 +127TE2 G KC=0.0326 5$LC=0.00430 7$MC=8.59E-4 14 +127TE G 543.2 1 2.62 11E2 0.006489 +127TE2 G KC=0.00553 8$LC=7.61E-4 11$MC=1525E-7 22 +127TE L 685.09 7 7/2+ +127TE B 897 5 34.4 4 7.304 +127TES B EAV=304.5 20 +127TE G 685.09 7 35.4 4 E2 0.003525 +127TE2 G KC=0.00303 5$LC=3.99E-4 6$MC=7.97E-5 12 +127TE L 762.64 5 3/2+ +127TE G 762.7 1 0.07 4 M1+E2 1.0 5 0.0030622 +127TE2 G KC=0.00265 20$LC=3.32E-4 19$MC=6.6E-5 4 +127TE L 782.62 3 5/2+ +127TE B 799 5 17.2 3 7.425 2 +127TES B EAV=265.8 20 +127TE G 280.7 1 0.53 4 M1+E2 -0.09 2 0.0407 6 +127TE2 G KC=0.0351 5$LC=0.00445 7$MC=8.88E-4 13 +127TE G 309.4 1 0.076 13M1+E2 0.10 3 0.0316 5 +127TE2 G KC=0.0273 4$LC=0.00345 5$MC=6.87E-4 10 +127TE G 721.5 1 1.77 7 E2 0.003095 +127TE2 G KC=0.00266 4$LC=3.48E-4 5$MC=6.95E-5 10 +127TE G 782.6 1 14.7 3 M1+E2 0.21 1 0.003195 +127TE2 G KC=0.00277 4$LC=3.39E-4 5$MC=6.73E-5 10 +127TE L 786.13 6 7/2- +127TE B 796 5 7.72 21 7.766 +127TES B EAV=264.4 20 +127TE G 154.7 1 0.12 3 M1+E2 0.3 2 0.214 20 +127TE2 G KC=0.182 14$LC=0.026 5$MC=0.0052 11 +127TE G 445.3 1 4.18 11M1+E2 -1.0 5 0.0120 4 +127TE2 G KC=0.0102 4$LC=1369E-6 23$MC=2.74E-4 5 +127TE G 697.9 1 3.36 18E2 0.003365 +127TE2 G KC=0.00289 4$LC=3.80E-4 6$MC=7.59E-5 11 +127TE L 924.02 187/2+ +127TE B 658 5 1.27 25 8.26 +127TES B EAV=211.5 19 +127TE G 292.6 2 0.28 14E1+M2 0.12 13 0.012 7 +127TE2 G KC=0.010 6$LC=0.00136 16$MC=0.00027 18 +127TE G 450.8 2 0.21 7 M1+E2 0.7 5 0.0118 4 +127TE2 G KC=0.0101 4$LC=1318E-6 20$MC=2.63E-4 5 +127TE G 583.2 2 0.32 18E1 0.001873 +127TE2 G KC=1622E-6 23$LC=1.96E-4 3$MC=3.89E-5 6 +127TE G 924.0 2 0.460 25E2 1725E-625 +127TE2 G KC=1491E-6 21$LC=1.89E-4 3$MC=3.76E-5 6 +127TE L 1077.13 17(5/2,7/2,9/2)+ +127TE B 505 5 5.17 14 7.251 2 +127TES B EAV=155.3 18 +127TE G 392.0 2 0.92 7 M1+E2 0.15 2 0.0172225 +127TE2 G KC=0.01490 21$LC=0.00187 3$MC=3.72E-4 6 +127TE G 603.9 2 4.21 11M1+E2 0.14 8 0.005929 +127TE2 G KC=0.00513 8$LC=6.34E-4 10$MC=1261E-7 18 +127TE L 1140.20 7 5/2+ +127TE B 442 5 1.35 21 7.64 2 +127TES B EAV=133.2 18 +127TE G 455.1 1 0.11 7 M1+E2 1.0 5 0.0113 4 +127TE2 G KC=0.0097 4$LC=1287E-6 19$MC=2.58E-4 4 +127TE G 638.3 1 0.35 4 M1+E2 -0.42 3 0.005068 +127TE2 G KC=0.00438 7$LC=5.44E-4 8$MC=1083E-7 16 +127TE G 666.9 1 0.53 18M1+E2 1.0 5 0.0042 3 +127TE2 G KC=0.0037 3$LC=4.64E-4 23$MC=9.3E-5 5 +127TE G 1140.2 1 0.35 7 M1+E2 -0.14 12 1358E-623 +127TE2 G KC=1179E-6 20$LC=1427E-7 23$MC=2.83E-5 5 +127TE L 1154.70 9 5/2+ +127TE B 427 5 0.85 25 7.79 2 +127TES B EAV=128.2 18 +127TE G 652.8 1 0.28 4 M1+E2 0.24 7 0.004888 +127TE2 G KC=0.00423 7$LC=5.22E-4 8$MC=1038E-7 16 +127TE G 681.4 1 0.53 25M1+E2 1.0 5 0.0040 3 +127TE2 G KC=0.00347 25$LC=4.40E-4 22$MC=8.8E-5 5 +127TE G 1153.99 9 0.039 21M1+E2 +127TE L 1206.3 7 3/2,5/2+ +127TE B 376 5 0.10 4 8.53 +127TES B EAV=110.7 17 +127TE G 423.7 7 0.10 4 M1+E2 1.0 5 0.0137 4 +127TE2 G KC=0.0117 4$LC=0.00158 4$MC=3.16E-4 9 +127TE L 1289.79 8 5/2+ +127TE B 292 5 0.61 4 7.39 2 +127TES B EAV=83.4 16 +127TE G 816.5 1 0.27 3 M1+E2 1.0 5 0.0026019 +127TE2 G KC=0.00225 17$LC=2.82E-4 17$MC=5.6E-5 4 +127TE G 1288.90 8 0.34 3 M1+E2 0.02 8 1055E-615 +127TE2 G KC=9.01E-4 13$LC=1087E-7 16$MC=2.16E-5 3 +127TE L 1309.25 7 3/2,5/2+ +127TE B 273 5 0.06 2 8.3 +127TES B EAV=77.2 16 +127TE G 624.2 1 0.064 21M1+E2 1.0 5 0.0050 4 +127TE2 G KC=0.0043 3$LC=5.50E-4 24$MC=1.10E-4 5 +127TE L 1323.4 8 + +127TE B 259 5 0.12 2 7.93 +127TES B EAV=72.8 16 +127TE G 821.5 8 0.117 22 +127TE L 1378.58 7 5/2+ +127TE B 203 5 0.18 4 7.42 2 +127TES B EAV=55.9 15 +127TE G 747.2 1 0.11 4 E1 1093E-616 +127TE2 G KC=9.51E-4 14$LC=1142E-7 16$MC=2.26E-5 4 +127TE G 1378.6 1 0.07 4 M1+E2 + diff --git a/HEN_HOUSE/spectra/lnhb/Sc-44.txt b/HEN_HOUSE/spectra/lnhb/Sc-44.txt new file mode 100644 index 000000000..70c1f6bce --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Sc-44.txt @@ -0,0 +1,39 @@ + 44CA 44SC EC DECAY (3.97 H) + 44CA T Auger electrons and ^X ray energies and emission intensities: + 44CA T {U Energy (keV)} {U Intensity } {U Line } + 44CA T + 44CA T 3.68813 0.255 7 XKA2 + 44CA T 3.69172 0.504 13 XKA1 + 44CA T + 44CA T 4.0128 |] 0.098 3 XKB1 + 44CA T 4.0325 |] XKB5II + 44CA T + 44CA T + 44CA T 0.35-0.412 0.019 4 XL (total) + 44CA T 0.35 XLL + 44CA T -0.412 XLG + 44CA T + 44CA T 3.123-3.307 |] KLL AUGER + 44CA T 3.543-3.666 |] 4.21 3 ^KLX AUGER + 44CA T 3.951-3.987 |] KXY AUGER + 44CA T 0.044-0.387 8.71 5 L AUGER + 44SC P 0.0 2+ 3.97 H 4 3653.3 19 + 44CA N 1.0 1.0 1 1.0 + 44CA L 0 0+ STABLE + 44CA L 1157.039 152+ 2.61 PS 14 + 44CA E 94.27 5 4.70 5 5.3 + 44CA2 E EAV=632.0 9$CK=0.8970 19$CL=0.0897 16$CM=0.0133 7$CN= $CO= + 44CA G 1157.020 1599.875 3 E2 6.48E-519 + 44CA2 G KC=5.90E-5 18$LC=4.99E-6 15$MC=8.1E-7 2 + 44CA L 2656.530 242+ 30 FS 3 + 44CA E 1.02 2 5.2 + 44CA2 E EAV= $CK=0.8966 19$CL=0.0900 16$CM=0.0134 7$CN= $CO= + 44CA G 1499.46 2 0.908 15M1+E2 0.137 17 3.19E-510 + 44CA2 G KC=2.9E-5 1$LC=2.43E-6 7$MC=4.7E-7 2 + 44CA G 2656.48 7 0.112 3 [E2] + 44CA L 3301.46 6 2+ 35 FS 18 + 44CA E 0.00440 116.6 + 44CA2 E EAV= $CK=0.8954 20$CL=0.0911 16$CM=0.0135 7$CN= $CO= + 44CA G 2144.33 100.0036 7 [M1+E2+] + 44CA G 3301.35 6 0.0017 2 [E2] + diff --git a/HEN_HOUSE/spectra/lnhb/Sc-46.txt b/HEN_HOUSE/spectra/lnhb/Sc-46.txt new file mode 100644 index 000000000..d6f668dff --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Sc-46.txt @@ -0,0 +1,47 @@ + 46TI 46SC B- DECAY (83.787 D) + 46TI H TYP=UPD$AUT=N.K. Kuzmenko$CUT=23-JUN-2014$ + 46TI2 H TYP=FUL$AUT=R.G. Helmer$CUT=01-FEB-2001$ + 46TI C Evaluation history: Type=UPD;Author=N.K. Kuzmenko;Cutoff date=23-JUN-2014 + 46TI2C Type=FUL;Author=R.G. Helmer;Cutoff date=01-FEB-2001 + 46TI C References: 1940Wa01, 1950So57, 1950Mo62, 1954Ke04, 1956Wo09, 1956Sc87, + 46TI2C 1957Ge07, 1957Wr37, 1963Ho17, 1965An07, 1967Wa29, 1972BaWG, 1974Cr05, + 46TI3C 1977MeZP, 1979Sc31, 1980Ho17, 1980Ol03, 1980Fu07, 1980RuZY, 1982HoZJ, + 46TI4C 1982RuZV, 1983Wa26, 1986Al19, 1992Un01, 1998Si17, 2000He14, 2000Wu08, + 46TI5C 2002Ba85, 2004BeZR, 2008Ki07, 2012Fi12, 2012Wa38, 2014Un01 + 46TI T Auger electrons and ^X ray energies and emission intensities: + 46TI T {U Energy (keV)} {U Intensity } {U Line } + 46TI T + 46TI T 4.50491 0.00155 4 XKA2 + 46TI T 4.5109 0.00306 8 XKA1 + 46TI T + 46TI T 4.93186 |] 0.000612 18 XKB1 + 46TI T 4.9623 |] XKB5II + 46TI T + 46TI T + 46TI T 0.3967-0.5614 0.00012 3 XL (total) + 46TI T 0.3967 XLL + 46TI T 0.4556- XLA + 46TI T 0.403 XLC + 46TI T 0.46072-0.5614 XLB + 46TI T 0.46703-0.46703 XLG + 46TI T + 46TI T 3.796-4.014 |] KLL AUGER + 46TI T 4.328-4.507 |] 0.01791 22 ^KLX AUGER + 46TI T 4.846-4.959 |] KXY AUGER + 46TI T 0.3349-0.5596 0.002072 22 L AUGER + 46SC P 0.0 4+ 83.787 D 16 2366.5 7 + 46TI N 1.0 1.0 1 1.0 + 46TI L 0 0+ STABLE + 46TI L 889.280 2 2+ 5.32 PS 15 + 46TI B 1477.2 7 0.02 2 12.2 2 + 46TIS B EAV=580.7 3 + 46TI G 889.271 2 99.9837 2 E2 1625E-723 + 46TI2 G KC=1475E-7 21$LC=1322E-8 19$MC=1690E-9 24 + 46TI L 2009.832 4 4+ 1.62 PS 10 + 46TI B 356.7 7 99.98 2 6.2 + 46TIS B EAV=111.7 3 + 46TI G 1120.537 3 99.97 2 E2 9.41E-514 + 46TI2 G KC=8.39E-5 12$LC=7.50E-6 11$MC=9.59E-7 14 + 46TI G 2009.785 4 1.3E-5 10E4 6.97E-510 + 46TI2 G KC=6.32E-5 9$LC=5.67E-6 8$MC=7.25E-7 11 + diff --git a/HEN_HOUSE/spectra/lnhb/Sc-47.txt b/HEN_HOUSE/spectra/lnhb/Sc-47.txt new file mode 100644 index 000000000..2b9fa5b39 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Sc-47.txt @@ -0,0 +1,38 @@ + 47TI 47SC B- DECAY (3.3485 D) + 47TI H TYP=Full$AUT=X.Mougeot$CUT=30-NOV-2013$ + 47TI C Evaluation history: Type=Full;Author=X.Mougeot;Cutoff date=30-NOV-2013 + 47TI C References: 1945HI04, 1949KR12, 1953MA64, 1953CH16, 1953CO44, 1953DU22, + 47TI2C 1955LY34, 1955NI15, 1956LI38, 1956GR12, 1959PO64, 1963HO17, 1964MI07, + 47TI3C 1967KO01, 1968BA33, 1968ME07, 1969WO02, 1969RA16, 1972GEZG, 1980MO26, + 47TI4C 1986RE12, 1996SC06, 2007BU08, 2008KI07, 2012WA38 + 47TI T Auger electrons and ^X ray energies and emission intensities: + 47TI T {U Energy (keV)} {U Intensity } {U Line } + 47TI T + 47TI T 4.50491 0.0256 9 XKA2 + 47TI T 4.5109 0.0505 16 XKA1 + 47TI T + 47TI T 4.93186 |] 0.0101 4 XKB1 + 47TI T 4.9623 |] XKB5II + 47TI T + 47TI T + 47TI T 0.3967 XLL + 47TI T 0.4556- XLA + 47TI T 0.403 XLC + 47TI T 0.46072-0.5614 XLB + 47TI T 0.46703-0.46703 XLG + 47TI T + 47TI T 3.79-4.01 |] KLL AUGER + 47TI T 4.33-4.48 |] 0.295 7 ^KLX AUGER + 47TI T 4.83-4.9 |] KXY AUGER + 47TI T 0.3-0.5 0.0349 8 L AUGER + 47SC P 0.0 7/2- 3.3485 D 9 600.8 19 + 47TI N 1.0 1.0 1 1.0 + 47TI L 0 5/2- STABLE + 47TI B 600.8 1931.5 5 6.1 2 + 47TIS B EAV=204.2 8 + 47TI L 159.373 127/2- 210 PS 6 + 47TI B 441.4 1968.5 5 5.3 + 47TIS B EAV=142.8 7 + 47TI G 159.373 1268.1 5 M1+()E2 -0.099 9 0.0061813 + 47TI2 G KC=0.00560 12$LC=5.12E-4 11$MC=6.54E-5 14 + diff --git a/HEN_HOUSE/spectra/lnhb/Se-73.txt b/HEN_HOUSE/spectra/lnhb/Se-73.txt new file mode 100644 index 000000000..bdf02b20e --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Se-73.txt @@ -0,0 +1,173 @@ + 73AS 73SE EC DECAY (7.10 H) + 73AS H TYP=FULL$AUT=A.L.Nichols$CUT=23-NOV-2013$ + 73AS C Evaluation history: Type=FULL;Author=A.L.Nichols;Cutoff date=23-NOV-2013 + 73AS C References: 1948Co07, 1951Sc70, 1955Ha85, 1956Ha10, 1957Be46, 1957Ku57, + 73AS2C 1960Ri09, 1960Ku06, 1963Bo26, 1963Bo16, 1966Ol04, 1967Ra08, 1968At04, + 73AS3C 1968Ak03, 1968Iv02, 1969Iv02, 1969Ma21, 1970Me20, 1970MeZZ, 1970Qu03, + 73AS4C 1971Go40, 1972ReZN, 1974Be54, 1975Va03, 1976Sc13, 1976Bo19, 1977La19, + 73AS5C 1977KeZY, 1978TeZY, 1980Te01, 1988Be39, 1992Sc21, 1995ScZY, 1996Sc06, + 73AS6C 1997So08, 1998Sc28, 1998ScZM, 1999ScZX, 2000Sc47, 2002Ba85, 2002Ra45, + 73AS7C 2004Si08, 2008Ki07, 2012Wa38 + 73AS T Auger electrons and ^X ray energies and emission intensities: + 73AS T {U Energy (keV)} {U Intensity } {U Line } + 73AS T + 73AS T 10.50814 8.3 3 XKA2 + 73AS T 10.5438 16.2 6 XKA1 + 73AS T + 73AS T 11.7204 |] XKB3 + 73AS T 11.7263 |] 3.70 14 XKB1 + 73AS T 11.821 |] XKB5II + 73AS T + 73AS T 11.8643 |] XKB2 + 73AS T |] 0.140 7 XKB4 + 73AS T + 73AS T 1.12-1.524 1.05 3 XL (total) + 73AS T 1.12 0.027 1 XLL + 73AS T 1.282- 0.613 21 XLA + 73AS T 1.155 0.0152 7 XLC + 73AS T 1.317-1.388 0.397 17 XLB + 73AS T 1.524- 0.00230 9 XLG + 73AS T + 73AS T 8.746-9.149 |] KLL AUGER + 73AS T 10.114-10.541 |] 21.0 8 ^KLX AUGER + 73AS T 11.46-11.862 |] KXY AUGER + 73AS T 0.9-1.23 65.3 15 L AUGER + 73SE P 0.0 9/2+ 7.10 H 9 2725 7 + 73AS N 1.0 1.0 1 1.0 + 73AS G 600.3 3 0.020 3 + 73AS G 793.0 5 0.064 2 + 73AS G 930.09 150.005 1 + 73AS G 1215.4 8 0.063 10 + 73AS G 1249.9 2 0.004 1 + 73AS G 1323.81 200.007 1 + 73AS G 1738.4 5 0.002 1 + 73AS G 1847.8 3 0.008 1 + 73AS G 1889.57 200.003 1 + 73AS G 2023.9 3 0.002 1 + 73AS G 2170.5 3 0.002 1 + 73AS L 0 0 3/2- 80.30 D 6 + 73AS L 67.039 8 5/2- 4.97 NS 7 + 73AS E 0.69 110.51 9 8.7 3U + 73AS2 E EAV=745 3$CK=0.8811 15$CL=0.1000 12$CM=0.0172 4$CN=0.0017 1$CO= + 73AS G 67.039 8 71 7 M1 0.272 4 + 73AS2 G KC=0.241 4$LC=0.0264 4$MC=0.00404 6 + 73AS L 427.906 219/2+ 5.75 US 20 + 73AS E 63.9 5 33.3 5 5.36 + 73AS2 E EAV=555 3$CK=0.8810 15$CL=0.1001 12$CM=0.0172 4$CN=0.0017 1$CO= + 73AS G 360.866 2396.91 20M2+E3 -0.035 10 0.0131519 + 73AS2 G KC=0.01165 17$LC=1286E-6 18$MC=1.97E-4 3 + 73AS G 427.905 210.078 14E3 0.0135719 + 73AS2 G KC=0.01195 17$LC=1397E-6 20$MC=2.13E-4 3 + 73AS L 510.055 17(5/2)+ + 73AS G 443.015 190.050 3 (E1) 1037E-615 + 73AS2 G KC=9.26E-4 13$LC=9.55E-5 14$MC=1454E-8 21 + 73AS G 510.053 170.26 3 (E1) 7.28E-411 + 73AS2 G KC=0.00065 1$LC=6.7E-5 1$MC=1020E-8 15 + 73AS L 993.766 12(7/2)- + 73AS G 926.721 140.004 1 (M1+E2) + 73AS G 993.759 120.005 1 (E2) 3.92E-46 + 73AS2 G KC=3.50E-4 5$LC=3.63E-5 5$MC=5.52E-6 8 + 73AS L 1037.13 3 (13/2)+ + 73AS G 609.22 4 0.049 4 (E2) 1412E-620 + 73AS2 G KC=1258E-6 18$LC=1327E-7 19$MC=2.02E-5 3 + 73AS L 1178.052 21(7/2)- + 73AS E 0.017 1 0.178 2 7.3 1U + 73AS2 E EAV=228 3$CK=0.8805 15$CL=0.1005 12$CM=0.0173 4$CN=0.0017 1$CO= + 73AS G 1111.004 230.201 2 (M1+E2) + 73AS L 1275.14 7 (7/2)+ + 73AS E 0.0003 1 0.0057 198.7 2 + 73AS2 E EAV=187 3$CK=0.8804 15$CL=0.1006 12$CM=0.0173 4$CN=0.0017 1$CO= + 73AS G 765.09 7 0.127 2 (M1+E2) + 73AS G 847.22 7 0.078 6 (M1+E2) + 73AS G 1208.09 7 0.004 1 (E1) 1700E-724 + 73AS2 G KC=1050E-7 15$LC=1072E-8 15$MC=1632E-9 23 + 73AS G 1275.13 7 0.007 1 (M2) 4.46E-47 + 73AS2 G KC=3.94E-4 6$LC=4.08E-5 6$MC=6.23E-6 9 + 73AS L 1293.09 10(11/2)+ + 73AS E 0.017 2 0.435 196.8 2 + 73AS2 E EAV=179 3$CK=0.8804 15$CL=0.1006 12$CM=0.0173 4$CN=0.0017 1$CO= + 73AS G 865.17 100.50 2 (M1+E2) + 73AS L 1293.37 3 (7/2)+ + 73AS G 783.32 4 0.058 2 (M1+E2) + 73AS G 865.45 3 0.02 1 (M1+E2) + 73AS G 1226.32 3 0.003 2 (E1) 1.79E-43 + 73AS2 G KC=1023E-7 15$LC=1043E-8 15$MC=1589E-9 23 + 73AS L 1328.89 5 (7/2,9/2)+ + 73AS E 0.0034 2 0.129 3 7.3 2 + 73AS2 E EAV=164 3$CK=0.8804 15$CL=0.1006 12$CM=0.0173 4$CN=0.0017 1$CO= + 73AS G 818.84 5 0.036 2 (M1+E2) + 73AS G 900.97 5 0.135 2 (M1+E2) + 73AS L 1850.59 5 (9/2)+ + 73AS E 0.433 116.4 + 73AS2 E EAV= $CK=0.8794 15$CL=0.1014 12$CM=0.0175 4$CN=0.0017 1$CO= + 73AS G 557.50 110.052 2 (M1+E2) + 73AS G 575.45 9 0.146 7 (M1+E2) + 73AS G 813.46 6 0.009 1 (E2) 6.42E-49 + 73AS2 G KC=5.73E-4 8$LC=5.97E-5 9$MC=9.10E-6 13 + 73AS G 856.81 5 0.023 6 (E1) 2.27E-44 + 73AS2 G KC=2.03E-4 3$LC=2.07E-5 3$MC=3.16E-6 5 + 73AS G 1340.53 5 0.069 2 (E2) 2.39E-44 + 73AS2 G KC=1.80E-4 3$LC=1.85E-5 3$MC=2.82E-6 4 + 73AS G 1422.67 6 0.135 5 (M1+E2) + 73AS L 1910.13 12(9/2,11/2)+ + 73AS E 0.060 7 7.2 + 73AS2 E EAV= $CK=0.8792 15$CL=0.1016 13$CM=0.0175 4$CN=0.0017 1$CO= + 73AS G 872.99 120.038 7 (E2) 5.37E-48 + 73AS2 G KC=4.79E-4 7$LC=4.99E-5 7$MC=7.60E-6 11 + 73AS G 1482.20 6 0.022 1 (M1+E2) + 73AS L 1961.8 2 (3/2,5/2,7/2)+ + 73AS E 0.017 5 7.7 + 73AS2 E EAV= $CK=0.8790 15$CL=0.1017 13$CM=0.0176 4$CN=0.0017 1$CO= + 73AS G 968.0 2 0.012 5 + 73AS G 1451.7 2 0.006 2 + 73AS L 1975.41 11(7/2,9/2,11/2)+ + 73AS E 0.094 3 6.9 2 + 73AS2 E EAV= $CK=0.8789 15$CL=0.1018 13$CM=0.0176 4$CN=0.0017 1$CO= + 73AS G 682.04 110.019 2 (E1) 3.69E-46 + 73AS2 G KC=3.30E-4 5$LC=3.38E-5 5$MC=5.15E-6 8 + 73AS G 700.27 130.044 2 (M1+E2) + 73AS G 1547.48 110.031 1 (M1+E2) + 73AS L 2180.66 10(7/2,9/2)+ + 73AS E 0.030 8 7.1 2 + 73AS2 E EAV= $CK=0.8778 15$CL=0.1027 13$CM=0.0178 4$CN=0.0017 1$CO= + 73AS G 887.28 100.011 8 (M1+E2) + 73AS G 1002.6 1 0.004 1 (E1) 1660E-724 + 73AS2 G KC=1484E-7 21$LC=1517E-8 22$MC=2.31E-6 4 + 73AS G 1670.59 100.005 1 (M1+E2) + 73AS G 1752.73 100.011 1 (M1+E2) + 73AS L 2311.63 6 (7/2,9/2)+ + 73AS E 0.157 6 6.2 2 + 73AS2 E EAV= $CK=0.8764 16$CL=0.1038 13$CM=0.0180 4$CN=0.0018 1$CO= + 73AS G 982.73 8 0.034 1 (M1+E2) + 73AS G 1018.25 7 0.053 2 (M1+E2) + 73AS G 1036.48 9 0.015 1 (M1+E2) + 73AS G 1317.85 6 0.006 1 (E1) 2.27E-44 + 73AS2 G KC=9.02E-5 13$LC=9.19E-6 13$MC=1.40E-6 2 + 73AS G 1801.56 6 0.019 5 (M1+E2) + 73AS G 1883.69 6 0.030 2 (M1+E2) + 73AS L 2434.1 4 3/2,5/2+ + 73AS E 0.0048 197.4 + 73AS2 E EAV= $CK=0.8740 16$CL=0.1058 13$CM=0.0184 4$CN=0.0018 1$CO= + 73AS G 1159.0 4 0.003 1 + 73AS G 2006.2 4 0.002 1 + 73AS L 2476.1 2 (11/2,15/2)+ + 73AS E 0.0029 107.5 2 + 73AS2 E EAV= $CK=0.8726 16$CL=0.1070 13$CM=0.0186 4$CN=0.0018 2$CO= + 73AS G 1439.0 2 0.002 1 + 73AS G 2048.2 2 0.001 1 + 73AS L 2482.87 23(7/2,9/2)+ + 73AS E 0.0087 207 2 + 73AS2 E EAV= $CK=0.8723 16$CL=0.1072 13$CM=0.0186 4$CN=0.0018 2$CO= + 73AS G 1153.97 240.005 1 (M1+E2) + 73AS G 1972.79 230.001 1 (M1+E2) + 73AS G 2054.93 230.003 1 (M1+E2) + 73AS L 2584.09 11(7/2,9/2)- + 73AS E 0.0155 206.2 1U + 73AS2 E EAV= $CK=0.8646 19$CL=0.1136 16$CM=0.0199 5$CN=0.0020 2$CO= + 73AS G 1308.94 130.004 1 (E1) 2.22E-44 + 73AS2 G KC=9.12E-5 13$LC=9.30E-6 13$MC=1417E-9 20 + 73AS G 1406.03 110.002 1 (M1+E2) + 73AS G 2156.15 110.005 1 (E1) 7.85E-411 + 73AS2 G KC=4.13E-5 6$LC=4.19E-6 6$MC=6.38E-7 9 + 73AS G 2517.00 110.005 1 (M1+E2) + diff --git a/HEN_HOUSE/spectra/lnhb/Se-75.txt b/HEN_HOUSE/spectra/lnhb/Se-75.txt new file mode 100644 index 000000000..de5cd44c1 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Se-75.txt @@ -0,0 +1,108 @@ + 75AS 75SE EC DECAY (119.781 D) + 75AS H TYP=Update$AUT=M.M. Bé$CUT= -- $ + 75AS2 H TYP=Full$AUT=V. Chisté$CUT=30-JUN-2009$ + 75AS3 H TYP=Full$AUT=Browne$CUT= -- $ + 75AS C Evaluation history: Type=Update;Author=M.M. Bé;Cutoff date= -- + 75AS2C Type=Full;Author=V. Chisté;Cutoff date=30-JUN-2009 + 75AS3C Type=Full;Author=Browne;Cutoff date= -- + 75AS C References: 1947Fr08, 1948Co07, 1950Co58, 1955Sc09, 1957Wr37, 1959Me76, + 75AS2C 1960Ea02, 1960Gr03, 1960De06, 1961Ed02, 1965Br19, 1966Ra09, 1969Pa05, + 75AS3C 1969Pa05, 1970Pr07, 1973Su10, 1973Th07, 1974Ca29, 1975La16, 1976MaZW, + 75AS4C 1971Ge07, 1977Ge12, 1977Pr08, 1977Kr13, 1980Ho17, 1980Sc07, 1982HoZJ, + 75AS5C 1983Si25, 1983Yo03, 1984Si02, 1987JeZZ, 1990Wa03, 1990Me15, 1990Je01, + 75AS6C 1990An07, 1991BaZS, 1992Sc09, 1994Iw04, 1994Mi22, 1996Sa22, 1996Sc06, + 75AS7C 1997Lo10, 1999Fa05, 2002Un02, 2002He19, 2003Au03, 2005Ra29, 2008Ki07 + 75AS T Auger electrons and ^X ray energies and emission intensities: + 75AS T {U Energy (keV)} {U Intensity } {U Line } + 75AS T + 75AS T 10.50814 16.5 6 XKA2 + 75AS T 10.5438 31.9 11 XKA1 + 75AS T + 75AS T 11.7204 |] XKB3 + 75AS T 11.7263 |] 7.30 25 XKB1 + 75AS T 11.821 |] XKB5II + 75AS T + 75AS T 11.8643 |] XKB2 + 75AS T |] 0.276 13 XKB4 + 75AS T + 75AS T 1.1195-1.5312 1.93 5 XL (total) + 75AS T 1.1195 0.0489 18 XLL + 75AS T 1.2816-1.2824 1.11 4 XLA + 75AS T 1.1552 0.0287 12 XLC + 75AS T 1.3152-1.4892 0.742 30 XLB + 75AS T 1.3508-1.5312 0.00393 15 XLG + 75AS T + 75AS T 8.75-9.1 |] KLL AUGER + 75AS T 10.12-10.54 |] 41.4 14 ^KLX AUGER + 75AS T 11.44-11.8 |] KXY AUGER + 75AS T 1.1-1.3 119.6 15 L AUGER + 75SE P 0.0 5/2+ 119.781 D 24 863.6 8 + 75AS N 1.0 1.0 1 1.0 + 75AS L 0 3/2- STABLE + 75AS E 1.42 228.5 1U + 75AS2 E EAV= $CK=0.8794 15$CL=0.1014 12$CM=0.0175 4$CN=0.0017 1$CO=0 0 + 75AS L 198.6063 131/2- 0.885 NS 21 + 75AS G 198.6060 121.46 6 M1+E2 0.315 39 0.0189 11 + 75AS2 G KC=0.0167 9$LC=0.00182 11$MC=2.77E-4 16 + 75AS L 264.6581 103/2- 0.0112 NS 3 + 75AS E 1.4 2 8.2 1U + 75AS2 E EAV= $CK=0.8782 15$CL=0.1024 13$CM=0.0177 4$CN=0.0017 1$CO=0 0 + 75AS G 66.0518 8 1.085 35M1+E2 0.121 33 0.33 3 + 75AS2 G KC=0.29 3$LC=0.034 5$MC=0.0052 7 + 75AS G 264.6576 9 58.75 19M1+E2 -0.095 70 0.0072 3 + 75AS2 G KC=0.00646 25$LC=0.00068 3$MC=1.04E-4 5 + 75AS L 279.5428 115/2- 0.273 NS 3 + 75AS E 2.1 148 + 75AS2 E EAV= $CK=0.8781 15$CL=0.1025 13$CM=0.0177 4$CN=0.0017 1$CO=0 0 + 75AS G 14.8847 130.0206 6 M1(+E2) + 75AS G 80.9365 150.0095 5 [E2] 1.736 25 + 75AS2 G KC=1.486 21$LC=0.216 3$MC=0.0326 5 + 75AS G 279.5422 1024.89 9 M1+E2 -0.578 44 0.0091 4 + 75AS2 G KC=0.0081 4$LC=0.00087 4$MC=1.33E-4 6 + 75AS L 303.9243 119/2+ 17.62 MS 23 + 75AS G 24.3815 140.027 6 M2 204 3 + 75AS2 G KC=165 24$LC=32.6 5$MC=5.13 10 + 75AS G 303.9236 101.308 5 E3 0.0538 8 + 75AS2 G KC=0.0469 7$LC=0.00592 9$MC=8.99E-4 13 + 75AS L 400.6585 8 5/2++ 1.67 NS 5 + 75AS E 94.5 216.1 + 75AS2 E EAV= $CK=0.8770 16$CL=0.1033 13$CM=0.0179 4$CN=0.0018 1$CO=0 0 + 75AS G 96.7340 9 3.35 7 E2 0.893 13 + 75AS2 G KC=0.772 11$LC=0.1044 15$MC=0.01576 22 + 75AS G 121.1155 1116.86 36E1 0.0417 6 + 75AS2 G KC=0.0372 6$LC=0.00388 6$MC=5.88E-4 9 + 75AS G 136.0001 6 57.7 20E1 0.0295 5 + 75AS2 G KC=0.0263 4$LC=0.00274 4$MC=4.15E-4 6 + 75AS G 400.6572 8 11.388 42E1 1346E-619 + 75AS2 G KC=1202E-6 17$LC=1241E-7 18$MC=1.89E-5 3 + 75AS L 468.6 4 1/2,3/2- + 75AS E 0.00036 5 11.1 3U + 75AS2 E EAV= $CK=0.8762 16$CL=0.1041 13$CM=0.0180 4$CN=0.0018 1$CO=0 0 + 75AS G 468.6 4 0.00036 5 [M1E2] 0.0025 7 + 75AS2 G KC=0.0022 6$LC=0.00023 7$MC=3.5E-5 10 + 75AS L 572.22 245/2- 2.9 PS 3 + 75AS E 0.03484 359.1 + 75AS2 E EAV= $CK=0.8740 16$CL=0.1058 13$CM=0.0184 4$CN=0.0018 1$CO=0 0 + 75AS G 373.61 240.00256 11[E2] 0.0065310 + 75AS2 G KC=0.00580 9$LC=6.28E-4 9$MC=9.54E-5 14 + 75AS G 572.22 240.03622 31M1+E2 0.19 1 1165E-617 + 75AS2 G KC=1040E-6 15$LC=1079E-7 16$MC=1646E-8 24 + 75AS L 617.7 4 1/2,3/2- + 75AS E 0.0126 6 8.8 3U + 75AS2 E EAV= $CK=0.8724 16$CL=0.1071 13$CM=0.0186 4$CN=0.0018 2$CO=0 0 + 75AS G 419.1 4 0.0121 6 [M1E2] 0.0034 11 + 75AS2 G KC=0.003 1$LC=0.00032 11$MC=4.9E-5 16 + 75AS G 617.8 4 0.00453 5 [M1E2] 0.0011620 + 75AS2 G KC=0.00103 18$LC=1.08E-4 20$MC=1.7E-5 3 + 75AS L 821.6 2 7/2- 3.0 PS 3 + 75AS E 0.00734 187.9 1U + 75AS2 E EAV= $CK=0.8038 32$CL=0.1633 26$CM=0.0300 8$CN=0.0030 2$CO=0 0 + 75AS G 249.3 3 0.00394 12[M1E2] 0.017 10 + 75AS2 G KC=0.015 9$LC=0.0017 10$MC=0.00026 15 + 75AS G 542.02 184.35E-4 6 [M1E2] 0.0016 4 + 75AS2 G KC=0.0015 3$LC=0.00015 4$MC=2.3E-5 6 + 75AS G 557.8 9 0.00276 12[E2] 0.001833 + 75AS2 G KC=1628E-6 25$LC=1.72E-4 3$MC=2.62E-5 4 + 75AS G 821.56 181.34E-4 8 [E2] 6.26E-49 + 75AS2 G KC=5.58E-4 8$LC=5.82E-5 9$MC=8.87E-6 13 + diff --git a/HEN_HOUSE/spectra/lnhb/Se-79.txt b/HEN_HOUSE/spectra/lnhb/Se-79.txt new file mode 100644 index 000000000..a2d381e2e --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Se-79.txt @@ -0,0 +1,21 @@ + 79BR 79SE B- DECAY (3.56E5 Y) + 79BR H TYP=Full$AUT=M.-M. Bé$CUT=30-JAN-2006$ + 79BR C Evaluation history: Type=Full;Author=M.-M. Bé;Cutoff date=30-JAN-2006 + 79BR T Auger electrons and ^X ray energies and emission intensities: + 79BR T {U Energy (keV)} {U Intensity } {U Line } + 79BR T + 79BR T 11.8778 XKA2 + 79BR T 11.9244 XKA1 + 79BR T + 79BR T 13.2847 |] XKB3 + 79BR T 13.2916 |] XKB1 + 79BR T 13.396 |] XKB5II + 79BR T + 79BR T 13.4696 |] XKB2 + 79BR T + 79SE P 0.0 7/2+ 3.56E5 Y 40 150.9 17 + 79BR N 1.0 1.0 1 1.0 + 79BR L 0 3/2- STABLE + 79BR B 150.9 17100 10.81 3U + 79BRS B EAV=52.9 6 + diff --git a/HEN_HOUSE/spectra/lnhb/Sm-151.txt b/HEN_HOUSE/spectra/lnhb/Sm-151.txt new file mode 100644 index 000000000..3470d120e --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Sm-151.txt @@ -0,0 +1,43 @@ +151EU 151SM B- DECAY (94.7 Y) +151EU H TYP=Full$AUT=M.M. Bé$CUT=30-NOV-2014$ +151EU C Evaluation history: Type=Full;Author=M.M. Bé;Cutoff date=30-NOV-2014 +151EU C References: 1950In01, 1952Ru10, 1952Ka26, 1955Me52, 1959Ac28, 1965Fl02, +151EU2C 1966Av05, 1968Re04, 1968Gr25, 1970Fo02, 1970An17, 1971Ca44, 1975La20, +151EU3C 1975Fr01, 1977Ve01, 1980La02, 1981Ar17, 1981Un02, 2008Ki07, 2009He22, +151EU4C 2012Wa38, 2015Bé** +151EU T Auger electrons and ^X ray energies and emission intensities: +151EU T {U Energy (keV)} {U Intensity } {U Line } +151EU T +151EU T 40.9024 XKA2 +151EU T 41.5427 XKA1 +151EU T +151EU T 46.904 |] XKB3 +151EU T 47.0384 |] XKB1 +151EU T 47.373 |] XKB5II +151EU T +151EU T 48.257 |] XKB2 +151EU T 48.386 |] XKB4 +151EU T 48.497 |] XKO23 +151EU T +151EU T 5.175-7.791 0.121 4 XL (total) +151EU T 5.175 0.00140 7 XLL +151EU T 5.815-5.846 0.0343 15 XLA +151EU T 5.815 0.00074 4 XLC +151EU T 6.436-6.839 0.0695 19 XLB +151EU T 7.254-7.791 0.0154 4 XLG +151EU T +151EU T 32.241-34.378 |] KLL AUGER +151EU T 38.592-41.52 |] ^KLX AUGER +151EU T 44.92-48.48 |] KXY AUGER +151EU T 3.377-7.786 0.581 19 L AUGER +151SM P 0.0 5/2- 94.7 Y 6 76.4 5 +151EU N 1.0 1.0 1 1.0 +151EU L 0 5/2+ STABLE +151EU B 76.4 5 99.07 4 9 +151EUS B EAV=19.7 2 +151EU L 21.541 3 7/2+ 9.6 NS 3 +151EU B 54.9 5 0.93 4 7.5 1U +151EUS B EAV=14.0 2 +151EU G 21.541 3 0.0324 13M1+()E2 0.029 2 27.6 5 +151EU2 G KC=$LC=21.7 4$MC=4.71 8 + diff --git a/HEN_HOUSE/spectra/lnhb/Sm-153.txt b/HEN_HOUSE/spectra/lnhb/Sm-153.txt new file mode 100644 index 000000000..695a48eec --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Sm-153.txt @@ -0,0 +1,168 @@ +153EU 153SM B- DECAY (1.92855 D) +153EU H TYP=Update$AUT=mmbe$CUT= -- $ +153EU2 H TYP=Update$AUT=mmbe$CUT= -- $ +153EU3 H TYP=Full$AUT=mmbe$CUT=01-JUN-2005$ +153EU C Evaluation history: Type=Update;Author=mmbe;Cutoff date= -- +153EU2C Type=Update;Author=mmbe;Cutoff date= -- +153EU3C Type=Full;Author=mmbe;Cutoff date=01-JUN-2005 +153EU T Auger electrons and ^X ray energies and emission intensities: +153EU T {U Energy (keV)} {U Intensity } {U Line } +153EU T +153EU T 40.9024 16.6 4 XKA2 +153EU T 41.5427 30.0 7 XKA1 +153EU T +153EU T 46.904 |] XKB3 +153EU T 47.0384 |] 9.45 25 XKB1 +153EU T 47.373 |] XKB5II +153EU T +153EU T 48.257 |] XKB2 +153EU T 48.386 |] 2.44 8 XKB4 +153EU T 48.497 |] XKO23 +153EU T +153EU T 5.175-7.791 10.88 21 XL (total) +153EU T 5.175 0.213 7 XLL +153EU T 5.815-5.8461 5.20 15 XLA +153EU T 5.8149 0.0825 25 XLC +153EU T 6.4365-6.9193 4.63 10 XLB +153EU T 7.2538-7.791 0.755 17 XLG +153EU T +153EU T 32.24-34.38 |] KLL AUGER +153EU T 38.59-41.52 |] 4.47 28 ^KLX AUGER +153EU T 44.9-48.5 |] KXY AUGER +153EU T 3.4-7.8 53.0 5 L AUGER +153SM P 0.0 3/2+ 1.92855 D 5 807.6 7 +153EU N 1.0 1.0 1 1.0 +153EU L 0 0 5/2+ STABLE +153EU B 807.6 7 19.5 15 7.3 2 +153EUS B EAV=264.3 3 +153EU L 83.36720 177/2+ +153EU G 83.36717 210.193 6 M1+E2 0.81 4 3.74 11 +153EU2 G KC=2.30 7$LC=1.119 34$MC=0.258 8 +153EU L 97.43103 175/2- +153EU B 710.2 7 0.62 8 8.6 1U +153EUS B EAV=227.4 3 +153EU G 14.06383 24 E1 10.78 32 +153EU2 G KC=$LC=8.43 25$MC=1.90 6 +153EU G 97.43100 210.767 14E1 0.302 9 +153EU2 G KC=0.254 8$LC=0.0382 11$MC=0.00823 25 +153EU L 103.18016 133/2+ 3.8 NS +153EU B 704.7 7 49.2 17 6.7 +153EUS B EAV=225.3 3 +153EU G 19.81296 211.05E-4 22E2 3.22E3 10 +153EU2 G KC=$LC=2490 70$MC=578 17 +153EU G 103.18012 1729.19 16M1+E2 0.119 3 1.69 5 +153EU2 G KC=1.417 43$LC=0.213 6$MC=0.0462 14 +153EU L 151.6257 5 7/2- +153EU B 656.0 7 0.042 8 10 3U +153EUS B EAV=221.2 3 +153EU G 54.1936 120.0019 4 M1+E2 18.2 5 +153EU2 G KC=6.19 19$LC=9.30 28$MC=2.17 7 +153EU G 68.2574 120.0013 4 E1 0.781 23 +153EU2 G KC=0.648 19$LC=0.1040 31$MC=0.0225 7 +153EU G 151.6244 120.01033 27E1 0.0916 27 +153EU2 G KC=0.0775 23$LC=0.01112 33$MC=0.00239 7 +153EU L 172.85320 135/2+ 0.14 NS +153EU B 634.7 7 30.4 8 6.7 2 +153EUS B EAV=199.7 3 +153EU G 69.67300 134.691 41M1+E2 0.136 4 5.28 16 +153EU2 G KC=4.37 13$LC=0.719 22$MC=0.1571 47 +153EU G 75.42213 230.169 7 E1+M2 0.055 10 0.752 23 +153EU2 G KC=0.610 18$LC=0.1111 33$MC=0.0245 7 +153EU G 89.48595 220.158 15M1+E2 0.25 10 2.59 8 +153EU2 G KC=2.10 6$LC=0.383 11$MC=0.0845 25 +153EU G 172.85307 210.0736 21M1+E2 0.81 8 0.375 11 +153EU2 G KC=0.293 9$LC=0.0638 19$MC=0.01427 43 +153EU L 269.7370 7 7/2+ +153EU B 537.8 7 0.0216 3 11 +153EUS B EAV=164.7 3 +153EU G 96.8824 7 0.007 1 M1+E2 2.35 10 +153EU2 G KC=1.475 44$LC=0.68 2$MC=0.1570 47 +153EU G 118.1105 100.00023 6 [E1] 0.180 5 +153EU2 G KC=0.1516 45$LC=0.0223 7$MC=0.00479 14 +153EU G 166.5546 150.00061 6 [E2] 0.396 12 +153EU2 G KC=0.263 8$LC=0.1034 31$MC=0.0238 7 +153EU G 172.3032 134000E-7 0 (E1) 0.065 2 +153EU2 G KC=0.0551 17$LC=0.00782 23$MC=0.00168 5 +153EU L 585.02 15 + +153EU B 222.6 8 0.00227 5 9.4 +153EUS B EAV=61.3 3 +153EU G 412.05 200.00191 5 +153EU G 487.75 233600E-7 0 +153EU L 634.59 6 1/2+ +153EU B 172.9 8 0.0565 7 7.6 2 +153EUS B EAV=46.7 2 +153EU G 462.0 3 0.00158 26 +153EU G 531.40 150.0544 7 +153EU G 634.8 3 0.00050 3 +153EU L 636.522 183/2- +153EU B 171.1 7 0.0648 6 7.5 +153EUS B EAV=46.1 2 +153EU G 463.6 2 0.01270 24 +153EU G 533.2 2 0.0294 5 +153EU G 539.1 2 0.02070 21 +153EU G 636.5 2 0.00195 7 +153EU L 657.67 14 + +153EU B 149.9 8 0.00090 6 9.3 +153EUS B EAV=40.1 2 +153EU G 485.0 2 0.00038 3 +153EU G 574.1 3 0.00016 5 +153EU G 657.55 250.00037 2 +153EU L 681.88 8 5/2- +153EU B 125.7 7 0.0085 6 7.9 1U +153EUS B EAV=33.2 2 +153EU G 509.15 200.00190 18 +153EU G 578.75 200.0034 5 +153EU G 584.55 200.00107 3 +153EU G 598.54 100.0020 1 +153EU G 682.0 6 0.00015 12 +153EU L 694.180 235/2+ +153EU B 113.4 7 0.0221 8 7.4 2 +153EUS B EAV=29.8 2 +153EU G 424.4 3 0.00195 6 +153EU G 521.30 250.0067 1 +153EU G 542.7 2 0.00234 10 +153EU G 590.96 200.00122 9 +153EU G 596.7 2 0.0099 8 +153EU G 694.1 3 2.0E-5 6 +153EU L 701.46 24 + +153EU B 106.1 8 0.0076 6 8.8 +153EUS B EAV=27.8 2 +153EU G 598.3 3 0.0020 1 +153EU G 604.03 240.0049 6 +153EU G 617.9 3 0.00067 6 +153EU G 701.8 4 2.9E-5 6 +153EU L 706.622 235/2+ +153EU B 101.0 8 0.0241 7 7.3 2 +153EUS B EAV=26.4 3 +153EU G 436.9 3 0.00158 5 +153EU G 554.94 100.0047 1 +153EU G 603.6 4 0.0049 6 +153EU G 609.5 3 0.0129 4 +153EU G 706.8 5 2.3E-5 12 +153EU L 713.12 20 + +153EU B 94.5 8 0.0141 5 7.4 +153EUS B EAV=24.6 2 +153EU G 443.2 5 0.00041 32 +153EU G 609.95 200.0129 4 +153EU G 615.8 4 0.00050 6 +153EU G 630.5 4 9.9E-5 15 +153EU G 713.9 3 2.31E-4 20 +153EU L 718.69 143/2+ +153EU B 88.9 8 0.00143 10 8.4 +153EUS B EAV=23.1 2 +153EU G 545.75 150.0009 1 +153EU G 615.51 140.00050 6 +153EU G 719.0 4 2.5E-5 5 +153EU L 760.39 17 + +153EU B 47.2 8 0.00098 5 7.9 +153EUS B EAV=12.0 2 +153EU G 587.60 250.00048 4 +153EU G 657.21 7 0.00037 2 +153EU G 662.4 6 0.00007 7 +153EU G 677.0 3 4.4E-5 15 +153EU G 760.5 4 3.2E-5 5 +153EU L 763.8 6 + +153EU B 44.0 7 44000E-912 8.9 +153EUS B EAV=11.1 3 +153EU G 763.8 6 4.4E-5 12 + diff --git a/HEN_HOUSE/spectra/lnhb/Sn-113.txt b/HEN_HOUSE/spectra/lnhb/Sn-113.txt new file mode 100644 index 000000000..088ba4801 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Sn-113.txt @@ -0,0 +1,51 @@ +113IN 113SN EC DECAY (115.09 D) +113IN H TYP=Upadte$AUT=M.M. Bé$CUT= -- $ +113IN2 H TYP=Full$AUT=R.G.Helmer$CUT= -- $ +113IN C Evaluation history: Type=Upadte;Author=M.M. Bé;Cutoff date= -- +113IN2C Type=Full;Author=R.G.Helmer;Cutoff date= -- +113IN C References: 1961Gr11, 1993Mu14, 1994DeZX +113IN T Auger electrons and ^X ray energies and emission intensities: +113IN T {U Energy (keV)} {U Intensity } {U Line } +113IN T +113IN T 24.0023 27.69 21 XKA2 +113IN T 24.21 51.9 3 XKA1 +113IN T +113IN T 27.238 |] XKB3 +113IN T 27.2762 |] 14.58 17 XKB1 +113IN T 27.495 |] XKB5II +113IN T +113IN T 27.861 |] XKB2 +113IN T 27.928 |] 2.77 10 XKB4 +113IN T 27.939 |] XKO23 +113IN T +113IN T 2.9-4.16 8.48 19 XL (total) +113IN T 2.9 0.183 7 XLL +113IN T 3.28-3.29 4.90 15 XLA +113IN T 3.11 0.0621 14 XLC +113IN T 3.49-3.79 3.01 6 XLB +113IN T 3.82-4.16 0.330 7 XLG +113IN T +113IN T 19.34-20.35 |] KLL AUGER +113IN T 22.83-24.19 |] 17.0 5 ^KLX AUGER +113IN T 26.25-27.9 |] KXY AUGER +113IN T 2-4.2 116.3 6 L AUGER +113SN P 0.0 1/2+ 115.09 D 3 1036.0 28 +113IN N 1.0 1.0 1 1.0 +113IN L 0 9/2+ STABLE +113IN L 391.699 3 1/2- 1.6579 H 38 +113IN E 97.79 8 7.01 +113IN2 E EAV= $CK=0.855 1$CL=0.116 1$CM=0.0241 5$CN= $CO= +113IN G 391.698 3 64.97 17M4 0.540 4 +113IN2 G KC=0.437 4$LC=0.0858 26$MC=0.0170 5 +113IN L 646.833 103/2-+ +113IN E 2.21 8 8.2 2 +113IN2 E EAV= $CK=0.8490 14$CL=0.121 1$CM=0.0254 5$CN= $CO= +113IN G 255.134 102.11 8 M1+E2 0.0464 14 +113IN2 G KC=0.0396 12$LC=0.00549 16$MC=1078E-6 32 +113IN G 646.83 1 4E-6 2 [E3] +113IN L 1029.73 8 1/2,3/2+ 0.33 NS +113IN E 0.00103 4 6.5 +113IN2 E EAV= $CK= $CL=0.3 3$CM=0.54 20$CN= $CO= +113IN G 382.90 8 6.0E-5 3 +113IN G 638.03 8 0.00097 4 + diff --git a/HEN_HOUSE/spectra/lnhb/Sr-82.txt b/HEN_HOUSE/spectra/lnhb/Sr-82.txt new file mode 100644 index 000000000..f1d91056b --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Sr-82.txt @@ -0,0 +1,35 @@ + 82RB 82SR EC DECAY (25.347 D) + 82RB H TYP=FuLL$AUT=M.M. Bé$CUT=01-DEC-2014$ + 82RB C Evaluation history: Type=FuLL;Author=M.M. Bé;Cutoff date=01-DEC-2014 + 82RB C References: 1953Li27, 1953Kr10, 1958Sa20, 1978Gr17, 1987Ju02, 1987Ho06, + 82RB2C 1996Sc06, 1998Sc28, 2000Sc47, 2009Pi02, 2012Wa38 + 82RB T Auger electrons and ^X ray energies and emission intensities: + 82RB T {U Energy (keV)} {U Intensity } {U Line } + 82RB T + 82RB T 13.3359 16.79 14 XKA2 + 82RB T 13.3955 32.32 22 XKA1 + 82RB T + 82RB T 14.9519 |] XKB3 + 82RB T 14.9614 |] 7.87 9 XKB1 + 82RB T 15.085 |] XKB5II + 82RB T + 82RB T 15.1856 |] XKB2 + 82RB T 15.205 |] 0.91 4 XKB4 + 82RB T + 82RB T 1.484-2.051 2.52 5 XL (total) + 82RB T 1.484 0.0619 17 XLL + 82RB T 1.693-1.695 1.56 4 XLA + 82RB T 1.543 0.0272 8 XLC + 82RB T 1.752-1.954 0.855 21 XLB + 82RB T 1.831-2.051 0.01242 27 XLG + 82RB T + 82RB T 10.987-11.503 |] KLL AUGER + 82RB T 12.782-13.381 |] 28.0 4 ^KLX AUGER + 82RB T 14.556-15.172 |] KXY AUGER + 82RB T 1.16-2.05 105.7 5 L AUGER + 82SR P 0.0 0+ 25.347 D 17 178 7 + 82RB N 1.0 1.0 1 1.0 + 82RB L 0 1+ STABLE + 82RB E 100 4.7 + 82RB2 E EAV= $CK=0.859 2$CL=0.116 2$CM=0.022 1$CN=0.0031 2$CO= + diff --git a/HEN_HOUSE/spectra/lnhb/Sr-85.txt b/HEN_HOUSE/spectra/lnhb/Sr-85.txt new file mode 100644 index 000000000..4077305ee --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Sr-85.txt @@ -0,0 +1,58 @@ + 85RB 85SR EC DECAY (64.850 D) + 85RB C References: 1977La19 + 85RB T Auger electrons and ^X ray energies and emission intensities: + 85RB T {U Energy (keV)} {U Intensity } {U Line } + 85RB T + 85RB T 13.3359 17.16 17 XKA2 + 85RB T 13.3955 33.04 29 XKA1 + 85RB T + 85RB T 14.9519 |] XKB3 + 85RB T 14.9614 |] 8.04 10 XKB1 + 85RB T 15.085 |] XKB5II + 85RB T + 85RB T 15.1856 |] XKB2 + 85RB T 15.205 |] 0.93 4 XKB4 + 85RB T + 85RB T 1.48-2.05 2.30 5 XL (total) + 85RB T 1.48 0.0559 16 XLL + 85RB T - 1.41 4 XLA + 85RB T 0.0264 7 XLC + 85RB T - 0.800 21 XLB + 85RB T -2.05 0.00801 18 XLG + 85RB T + 85RB T 10.987-11.503 |] KLL AUGER + 85RB T 12.782-13.381 |] 28.6 4 ^KLX AUGER + 85RB T 14.556-15.172 |] KXY AUGER + 85RB T 1.1-2 96.5 4 L AUGER + 85SR P 0.0 9/2+ 64.850 D 7 1065 3 + 85RB N 1.0 1.0 1 1.0 + 85RB L 0 5/2- STABLE + 85RB E 0.8 4 9.3 3U + 85RB2 E EAV= $CK=0.85 3$CL=0.12 3$CM=0.03 1$CN= $CO= + 85RB L 151.161 3/2- 0.71 NS 5 + 85RB E 0.0005 11.5 + 85RB2 E EAV= $CK= $CL= $CM= $CN= $CO= + 85RB G 151.160 6 0.0012 9 M1+E2 0.0488 15 + 85RB2 G KC=0.0430 13$LC=0.00485 15$MC=8.17E-4 25 + 85RB L 280.986 1/2- 40 PS 3 + 85RB E 0.0005 11.8 + 85RB2 E EAV= $CK= $CL= $CM= $CN= $CO= + 85RB G 129.826 105000E-7 0 (M1) 0.0721 22 + 85RB2 G KC=0.0635 19$LC=0.00717 21$MC=1208E-6 36 + 85RB L 514.007 9/2+ 1.015 US 1 + 85RB E 99.2 4 6.2 + 85RB2 E EAV= $CK=0.8718 15$CL=0.1059 12$CM=0.0195 4$CN= $CO= + 85RB G 362.847 6 0.0014 3 (E3) 0.0339 10 + 85RB2 G KC=0.0292 9$LC=0.00397 12$MC=0.00067 2 + 85RB G 514.0048 2298.5 4 M2 0.0072122 + 85RB2 G KC=0.00635 19$LC=7.22E-4 22$MC=1219E-7 37 + 85RB L 868.98 7/2- 2.5 PS 3 + 85RB E 0.0129 4 9.1 1U + 85RB2 E EAV= $CK=0.8610 16$CL=0.1146 13$CM=0.0214 4$CN= $CO= + 85RB G 354.97 5 0.0005 2 (E1) 0.002538 + 85RB2 G KC=0.00225 7$LC=2.42E-4 7$MC=4.05E-5 12 + 85RB G 717.81 5 0.00032 3 (E2) 0.001244 + 85RB2 G KC=0.00109 3$LC=1.20E-4 4$MC=2.02E-5 6 + 85RB G 868.98 5 0.0121 4 M1+E2 0.000733 + 85RB2 G KC=0.00065 2$LC=7.0E-5 2$MC=1176E-8 35 + diff --git a/HEN_HOUSE/spectra/lnhb/Sr-89.txt b/HEN_HOUSE/spectra/lnhb/Sr-89.txt new file mode 100644 index 000000000..f06323229 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Sr-89.txt @@ -0,0 +1,26 @@ + 89Y 89SR B- DECAY (50.57 D) + 89Y C References: 1977La19 + 89Y T Auger electrons and ^X ray energies and emission intensities: + 89Y T {U Energy (keV)} {U Intensity } {U Line } + 89Y T + 89Y T 14.8829 XKA2 + 89Y T 14.9585 0.086 7 XKA1 + 89Y T + 89Y T 16.7259 |] XKB3 + 89Y T 16.7381 |] XKB1 + 89Y T 16.88 |] XKB5II + 89Y T + 89Y T 17.0156 |] XKB2 + 89Y T 17.0362 |] XKB4 + 89Y T + 89SR P 0.0 5/2+ 50.57 D 3 1495.1 22 + 89Y N 1.0 1.0 1 1.0 + 89Y L 0 1/2- STABLE + 89Y B 1495.1 2299990E-34 9.4 3U + 89Y S B EAV=584.6 10 + 89Y L 909 9/2+ 16.05 S 4 + 89Y B 586.1 220.00964 6 11.1 + 89Y S B EAV=189.1 9 + 89Y G 909.0 1 0.00956 6 (M4) 0.0085026 + 89Y 2 G KC=0.00746 23$LC=0.00091 3$MC= + diff --git a/HEN_HOUSE/spectra/lnhb/Sr-90.txt b/HEN_HOUSE/spectra/lnhb/Sr-90.txt new file mode 100644 index 000000000..9eb6be4a9 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Sr-90.txt @@ -0,0 +1,33 @@ + 90Y 90SR B- DECAY (28.80 Y) + 90Y H TYP=Full$AUT=Chisté$CUT= -- $ + 90Y C Evaluation history: Type=Full;Author=Chisté;Cutoff date= -- + 90Y T Auger electrons and ^X ray energies and emission intensities: + 90Y T {U Energy (keV)} {U Intensity } {U Line } + 90Y T + 90Y T 14.883 XKA2 + 90Y T 14.9581 XKA1 + 90Y T + 90Y T 16.7268 |] XKB3 + 90Y T 16.7384 |] XKB1 + 90Y T 16.8792 |] XKB5II + 90Y T 16.8814 |] XKB5I + 90Y T + 90Y T 17.0137 |] XKB2 + 90Y T 17.0409 |] XKB4 + 90Y T + 90Y T 1.6865 XLL + 90Y T 1.9211-1.9233 XLA + 90Y T 1.7617 XLC + 90Y T 1.9962-2.0713 XLB + 90Y T 2.1118-2.3482 XLG + 90Y T + 90Y T 12.205-12.784 |] KLL AUGER + 90Y T 14.238-14.956 |] ^KLX AUGER + 90Y T 16.251-17.034 |] KXY AUGER + 90Y T 0.06-2.3677 L AUGER + 90SR P 0.0 0+ 28.80 Y 7 545.9 14 + 90Y N 1.0 1.0 1 1.0 + 90Y L 0 2- 2.6684 D 13 + 90Y B 545.9 14100 9.4 1U + 90Y S B EAV=195.7 5 + diff --git a/HEN_HOUSE/spectra/lnhb/Ta-182.txt b/HEN_HOUSE/spectra/lnhb/Ta-182.txt new file mode 100644 index 000000000..8c1617cfa --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Ta-182.txt @@ -0,0 +1,164 @@ +182W 182TA B- DECAY (114.61 D) +182W H TYP=Full$AUT=V.Chisté$CUT=30-SEP-2010$ +182W 2 H TYP=update$AUT=v. chisté$CUT= -- $ +182W C Evaluation history: Type=Full;Author=V.Chisté;Cutoff date=30-SEP-2010 +182W 2C Type=update;Author=v. chisté;Cutoff date= -- +182W C References: 1943Zu**, 1947Se33, 1948Me**, 1951Si25, 1952Ei12, 1957Wr37, +182W 2C 1958Ke26, 1958Sp17, 1959Vo27, 1960Gv01, 1961Ry03, 1961Vi07, 1961Vo05, +182W 3C 1964Ba12, 1964Da15, 1964Ba47, 1965He07, 1965Ed01, 1966Dz01, 1966Ko12, +182W 4C 1966Gr21, 1967Ni03, 1967Wa29, 1969Wh03, 1969Sa15, 1969Ga23, 1970Wh03, +182W 5C 1971Ja21, 1971Ml01, 1972Em01, 1972Ga23, 1972Kr05, 1972He10, 1973Vi13, +182W 6C 1974La15, 1975We22, 1975Qu01, 1976He18, 1977Ge12, 1978MeZK, 1980Sc07, +182W 7C 1980Sp01, 1980Ro22, 1981Ka22, 1981Is08, 1983Ji01, 1983Ri05, 1983El02, +182W 8C 1986Wa35, 1988Fi05, 1989Ka20, 1990Me15, 1990Ja02, 1992Ch26, 1992Ke02, +182W 9C 1992Su09, 1996Sc06, 1998Mi17, 2000He14, 2002Ba85, 2003Au03, 2008Ki07, +182W 10C 2010Si13 +182W T Auger electrons and ^X ray energies and emission intensities: +182W T {U Energy (keV)} {U Intensity } {U Line } +182W T +182W T 57.9823 10.06 17 XKA2 +182W T 59.3189 17.48 29 XKA1 +182W T +182W T 66.952 |] XKB3 +182W T 67.2451 |] 5.79 13 XKB1 +182W T 67.664 |] XKB5II +182W T +182W T 69.033 |] XKB2 +182W T 69.295 |] 1.59 5 XKB4 +182W T 69.484 |] XKO23 +182W T +182W T 7.3881-11.6761 24.4 5 XL (total) +182W T 7.3881 0.461 14 XLL +182W T 8.3352-8.3976 9.82 26 XLA +182W T 8.725 0.219 6 XLC +182W T 9.526-9.9485 11.74 24 XLB +182W T 10.9501-11.6761 2.21 5 XLG +182W T +182W T 45.109-48.882 |] KLL AUGER +182W T 54.514-59.312 |] 1.68 15 ^KLX AUGER +182W T 63.89-69.51 |] KXY AUGER +182W T 4.5-12.1 59.5 7 L AUGER +182TA P 0.0 3- 114.61 D 13 1814.3 17 +182W N 1.0 1.0 1 1.0 +182W L 0 0+ STABLE +182W L 100.10598 7 2+ 1.40 NS 2 +182W B 1714.2 170 12.2 1 +182W S B EAV=625.2 70 +182W G 100.10595 7 14.22 16E2 3.89 6 +182W 2 G KC=0.878 13$LC=2.28 4$MC=0.576 8 +182W L 329.4268 6 4+ 62 PS 3 +182W B 1484.9 170 13 1 +182W S B EAV=529.0 7 +182W G 229.3207 6 3.634 36E2 0.196 3 +182W 2 G KC=0.1167 17$LC=0.0605 9$MC=0.01497 21 +182W L 680.45 6 6+ 8.2 PS 9 +182W G 351.02 6 0.01157 37E2 0.0538 8 +182W 2 G KC=0.0380 6$LC=0.01210 17$MC=0.00293 5 +182W L 1135.91 140+ +182W G 1035.80 140.0060 21E2 0.004206 +182W 2 G KC=0.00346 5$LC=5.75E-4 8$MC=1317E-7 19 +182W G 1135.91 14 +182W L 1221.4001 102+ 0.434 PS 11 +182W B 592.9 171.6 22 9.9 1 +182W S B EAV=181.8 6 +182W G 891.9710 120.0570 25E2 0.005698 +182W 2 G KC=0.00464 7$LC=8.10E-4 12$MC=1.87E-4 3 +182W G 1121.290 3 35.17 33M1+E2 30 5 0.003605 +182W 2 G KC=0.00297 5$LC=4.83E-4 7$MC=1104E-7 16 +182W G 1221.395 3 27.27 27E2 0.003055 +182W 2 G KC=0.00252 4$LC=4.02E-4 6$MC=9.15E-5 13 +182W L 1257.4121 112+ 1.71 PS 13 +182W B 556.9 170.22 21 10.7 1 +182W S B EAV=169.2 6 +182W G 121.50 140.0021 7 [E2] 1.83 3 +182W 2 G KC=0.596 9$LC=0.936 15$MC=0.236 4 +182W G 927.9828 130.614 7 E2 0.005248 +182W 2 G KC=0.00429 6$LC=7.38E-4 11$MC=1698E-7 24 +182W G 1157.3022 110.83 13M1+E2 1.3 7 0.0046 13 +182W 2 G KC=0.0039 11$LC=0.00060 15$MC=0.00014 4 +182W G 1257.407 3 1.511 15E2 0.002894 +182W 2 G KC=0.00239 4$LC=3.78E-4 6$MC=8.60E-5 12 +182W L 1289.1498 102- 1.12 NS 4 +182W B 525.2 1745.1 23 8.3 +182W S B EAV=158.2 6 +182W G 31.7377 150.84 6 E1 1.628 23 +182W 2 G KC=$LC=1.259 18$MC=0.293 4 +182W G 67.7497 1 43.6 15E1+M2 0.018 9 0.22 3 +182W 2 G KC=$LC=0.173 21$MC=0.040 6 +182W G 959.7203 120.348 5 M2+E3 -5.48 44 0.0115719 +182W 2 G KC=0.00901 15$LC=0.00196 3$MC=4.63E-4 7 +182W G 1189.040 3 16.58 16E1+M2+E3 4567E-641 +182W 2 G KC=3732E-6 33$LC=6.38E-4 6$MC=1468E-7 14 +182W G 1289.145 3 1.374 17M2 0.0123118 +182W 2 G KC=0.01019 15$LC=1630E-6 23$MC=3.72E-4 6 +182W L 1331.1153 103+ +182W B 483.2 172.39 15 9.5 +182W S B EAV=143.9 6 +182W G 1001.6856 122.07 5 M1+E2 -8.9 20 0.004558 +182W 2 G KC=0.00374 6$LC=6.27E-4 10$MC=1438E-7 23 +182W G 1231.004 3 11.62 11M1+E2 -33 8 0.003015 +182W 2 G KC=0.00249 4$LC=3.95E-4 6$MC=9.01E-5 13 +182W L 1373.8301 103- 78 PS 10 +182W B 440.5 1719.9 7 8.4 +182W S B EAV=129.6 6 +182W G 42.7148 140.269 7 E1 0.72 1 +182W 2 G KC=$LC=0.557 8$MC=0.1286 18 +182W G 84.68024 262.62 6 M1+E2 0.309 12 7.66 11 +182W 2 G KC=5.88 9$LC=1.36 4$MC=0.321 8 +182W G 116.4179 6 0.445 5 E1 0.253 4 +182W 2 G KC=0.207 3$LC=0.0353 5$MC=0.00805 12 +182W G 152.42991 267.01 13E1 0.1258 18 +182W 2 G KC=0.1038 15$LC=0.01703 24$MC=0.00387 6 +182W G 1044.4001 120.2381 42E1+M2 0.48 1 0.0053515 +182W 2 G KC=0.00444 12$LC=7.03E-4 20$MC=1.60E-4 5 +182W G 1273.719 3 0.658 7 E1+M2+E3 2781E-625 +182W 2 G KC=2278E-6 21$LC=3583E-7 31$MC=8.16E-5 8 +182W G 1373.824 3 0.2226 32E3 0.004967 +182W 2 G KC=0.00400 6$LC=7.28E-4 11$MC=1685E-7 24 +182W L 1442.836 9 4+ 0.32 PS 3 +182W B 371.5 170.563 10 9.7 1 +182W S B EAV=107.0 6 +182W G 1113.406 9 0.442 8 M1+E2 -5.6 12 0.0037610 +182W 2 G KC=0.00311 8$LC=5.04E-4 12$MC=1.15E-4 3 +182W G 1342.72 5 0.2562 28E2+M3 -0.11 11 0.0028 6 +182W 2 G KC=0.0023 5$LC=0.00036 9$MC=8.2E-5 21 +182W L 1487.5018 104- +182W B 326.8 171.5 7 9.1 +182W S B EAV=92.8 5 +182W G 113.67170 221.869 20M1+E2 0.338 12 3.19 5 +182W 2 G KC=2.50 5$LC=0.529 16$MC=0.124 4 +182W G 156.3864 3 2.662 27E1 0.1177 17 +182W 2 G KC=0.0972 14$LC=0.01590 23$MC=0.00362 5 +182W G 198.35187 291.461 15E2 0.317 5 +182W 2 G KC=0.1725 25$LC=0.1097 16$MC=0.0273 4 +182W G 1158.0711 120.295 18E1 1377E-620 +182W 2 G KC=1159E-6 17$LC=1632E-7 23$MC=3.66E-5 6 +182W G 1387.390 3 0.0725 11M2+E3 2.6 3 0.0055418 +182W 2 G KC=0.00450 15$LC=7.91E-4 22$MC=1.83E-4 5 +182W L 1510.25 7 4+ +182W B 304.0 170.1414 39 10 1 +182W S B EAV=85.7 5 +182W G 829.80 9 0.0141 25[E2] 0.0066110 +182W 2 G KC=0.00536 8$LC=9.62E-4 14$MC=2.22E-4 4 +182W G 1180.82 7 0.0869 29E2+M1 -2.8 10 0.0036 4 +182W 2 G KC=0.0030 4$LC=0.00047 5$MC=1.08E-4 11 +182W G 1410.14 7 0.0400 8 E2 0.002354 +182W 2 G KC=0.00193 3$LC=2.98E-4 5$MC=6.76E-5 10 +182W L 1553.224 1 4- 1.27 NS 4 +182W B 261.1 1729.0 7 7.5 +182W S B EAV=72.5 5 +182W G 65.72215 152.97 8 M1+E2 0.094 43 2.92 20 +182W 2 G KC=$LC=2.25 15$MC=0.52 4 +182W G 110.388 9 0.1073 33[E1] 0.290 4 +182W 2 G KC=0.238 4$LC=0.0408 6$MC=0.00931 13 +182W G 179.39381 253.099 31M1+E2 1.21 29 0.63 7 +182W 2 G KC=0.44 8$LC=0.148 7$MC=0.0358 21 +182W G 222.1085 3 7.54 7 E1 0.0480 7 +182W 2 G KC=0.0399 6$LC=0.00630 9$MC=1429E-6 20 +182W G 264.0740 3 3.602 36E2 0.1254 18 +182W 2 G KC=0.0799 12$LC=0.0347 5$MC=0.00852 12 +182W G 1223.7928 120.204 21E1+M2 0.38 7 0.0029 6 +182W 2 G KC=0.0024 5$LC=0.00037 8$MC=8.3E-5 17 +182W G 1453.1118 100.037 7 M2+E3 2.1 4 0.0053 4 +182W 2 G KC=0.0043 3$LC=0.00074 5$MC=1.69E-4 10 + diff --git a/HEN_HOUSE/spectra/lnhb/Tc-94m.txt b/HEN_HOUSE/spectra/lnhb/Tc-94m.txt new file mode 100644 index 000000000..3226dfd05 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Tc-94m.txt @@ -0,0 +1,190 @@ + 94MO 94TC EC DECAY (51.9 M) + 94MO H TYP=FUL$AUT=A.L. Nichols$CUT=01-APR-2014$ + 94MO C Evaluation history: Type=FUL;Author=A.L. Nichols;Cutoff date=01-APR-2014 + 94MO C References: 1948Mo19, 1950Me21, 1962Mo06, 1963Ma21, 1965Ba48, 1967Ei01, + 94MO2C 1968Bo27, 1968Ar06, 1969Ba09, 1971Go40, 1976Su04, 1977La19, 1986AgZX, + 94MO3C 1995ScZY, 1996Sc06, 1998Sc28, 1998ScZM, 1999ScZX, 2000Sc47, 2002Ba85, + 94MO4C 2002Ra45, 2003Fr02, 2006Ab37, 2008Ki07, 2012Wa38 + 94MO T Auger electrons and X ray energies and emission intensities: + 94MO T {U Energy (keV)} {U Intensity} {U Line} + 94MO T + 94MO T 17.3745 5.93 11 XKA2 + 94MO T 17.47954 11.31 19 XKA1 + 94MO T + 94MO T 19.5904 |] XKB3 + 94MO T 19.6085 |] 2.97 6 XKB1 + 94MO T 19.774 |] XKB5II + 94MO T + 94MO T 19.9653 |] XKB2 + 94MO T 19.998 |] 0.457 18 XKB4 + 94MO T + 94MO T 2.016-2.831 1.198 22 XL (total) + 94MO T 2.016 0.0279 8 XLL + 94MO T 2.29-2.293 0.750 18 XLA + 94MO T 2.12 0.0100 3 XLC + 94MO T 2.395-2.518 0.389 10 XLB + 94MO T 2.623-2.831 0.0208 4 XLG + 94MO T + 94MO T 14.172-14.855 |] KLL AUGER + 94MO T 16.592-17.478 |] 6.28 15 KLX AUGER + 94MO T 18.99-19.996 |] KXY AUGER + 94MO T 1.48-2.25 29.8 4 L AUGER + 94TC P 76 3 (2)+ 51.9 M 10 4256 6 + 94MO N 1.0 1.0 1 1.0 + 94MO G 1022 0.027 14 + 94MO G 1037.2 3 0.044 14 + 94MO G 1357.4 150.19 8 + 94MO G 3065.6 3 0.011 4 + 94MO G 3085.8 3 0.016 4 + 94MO G 3640.6 3 0.007 2 + 94MO G 4136.2 3 0.007 1 + 94MO L 0 0+ STABLE + 94MO L 871.098 162+ + 94MO E 67.2 4 12.8 1 5.6 + 94MO2 E EAV=1094.4 24$CK=0.8704 14$CL=0.1055 11$CM=0.0205 4$CN=0.0037 2$CO= + 94MO G 871.094 1694.04 21E2 1068E-615 + 94MO2 G KC=9.39E-4 14$LC=1073E-7 15$MC=1.92E-5 3 + 94MO L 1573.76 4 4+ + 94MO G 702.66 4 0.18 2 E2 0.001833 + 94MO2 G KC=1608E-6 23$LC=1.87E-4 3$MC=3.34E-5 5 + 94MO L 1741.65 150+ + 94MO G 870.55 220.26 3 E2 1070E-615 + 94MO2 G KC=9.40E-4 14$LC=1075E-7 15$MC=1.92E-5 3 + 94MO L 1864.31 5 2+ + 94MO E 0.41 100.39 9 6.82 + 94MO2 E EAV=639.6 23$CK=0.8699 14$CL=0.1059 11$CM=0.0206 4$CN=0.0037 2$CO= + 94MO G 993.20 5 2.21 18M1+E2 -2 1 7.91E-415 + 94MO2 G KC=6.96E-4 13$LC=7.86E-5 13$MC=1403E-8 22 + 94MO G 1864.29 5 0.23 3 E2 4.55E-47 + 94MO2 G KC=1.89E-4 3$LC=2.09E-5 3$MC=3.72E-6 6 + 94MO L 2067.35 6 2+ + 94MO E 0.22 3 0.34 5 6.8 + 94MO2 E EAV=548.7 23$CK=0.8697 14$CL=0.1060 11$CM=0.0206 4$CN=0.0037 2$CO= + 94MO G 1196.24 6 0.71 7 M1+E2 0.15 4 5.53E-48 + 94MO2 G KC=4.83E-4 7$LC=5.36E-5 8$MC=9.57E-6 14 + 94MO G 2067.33 6 0.11 1 E2 5.15E-48 + 94MO2 G KC=1562E-7 22$LC=1722E-8 25$MC=3.07E-6 5 + 94MO L 2294.79 164+ + 94MO L 2393.02 6 2+ + 94MO E 0.91 6 4.0 2 5.6 + 94MO2 E EAV=404.8 22$CK=0.8694 14$CL=0.1062 11$CM=0.0207 4$CN=0.0037 2$CO= + 94MO G 325.67 9 0.027 2 M1+E2 1.0 2 0.0147 9 + 94MO2 G KC=0.0128 8$LC=0.00156 11$MC=2.80E-4 19 + 94MO G 528.71 8 0.032 2 M1+E2 1.0 2 0.003719 + 94MO2 G KC=0.00325 8$LC=3.78E-4 11$MC=6.76E-5 19 + 94MO G 1521.91 6 4.48 28M1+E2 -0.12 3 4.11E-46 + 94MO2 G KC=2.95E-4 5$LC=3.26E-5 5$MC=5.81E-6 9 + 94MO G 2392.99 6 0.50 4 E2 6.33E-49 + 94MO2 G KC=1203E-7 17$LC=1322E-8 19$MC=2.35E-6 4 + 94MO L 2423.45 9 6+ + 94MO L 2533.87 123- + 94MO L 2610.57 165- + 94MO L 2739.91 7 1+ + 94MO E 0.427 2110.1 4 5.03 + 94MO2 E EAV=254.3 22$CK=0.8690 14$CL=0.1066 11$CM=0.0207 4$CN=0.0037 2$CO= + 94MO G 672.56 9 0.17 3 M1+E2 1.0 2 0.002003 + 94MO2 G KC=0.00176 3$LC=2.01E-4 4$MC=3.59E-5 7 + 94MO G 875.60 9 1.0 3 M1+E2 -0.10 2 1072E-615 + 94MO2 G KC=9.45E-4 14$LC=1056E-7 15$MC=1.89E-5 3 + 94MO G 998.25 170.24 2 M1 8.06E-412 + 94MO2 G KC=0.00071 1$LC=7.92E-5 11$MC=1413E-8 20 + 94MO G 1868.79 7 5.49 28M1+E2 -0.12 2 4.38E-47 + 94MO2 G KC=1.96E-4 3$LC=2.16E-5 3$MC=3.85E-6 6 + 94MO G 2739.87 7 3.53 20M1 7.25E-411 + 94MO2 G KC=9.59E-5 14$LC=1051E-8 15$MC=1.87E-6 3 + 94MO L 2805.04 193+ + 94MO L 2869.90 8 2+ + 94MO E 0.0024 5 0.15 3 6.8 + 94MO2 E EAV=198.5 22$CK=0.8688 14$CL=0.1067 11$CM=0.0208 4$CN=0.0037 2$CO= + 94MO G 802.55 100.0246 14M1+E2 1.0 2 1303E-619 + 94MO2 G KC=1146E-6 16$LC=1301E-7 19$MC=2.32E-5 4 + 94MO G 1005.58 9 0.09 3 M1+E2 -0.05 4 7.93E-412 + 94MO2 G KC=6.99E-4 10$LC=7.79E-5 11$MC=1.39E-5 2 + 94MO G 1998.78 8 0.0123 6 M1+E2 1.30 9 4.84E-410 + 94MO2 G KC=1.68E-4 3$LC=1.86E-5 3$MC=3.31E-6 6 + 94MO G 2869.85 8 0.016 2 E2 8.16E-412 + 94MO2 G KC=8.81E-5 13$LC=9.64E-6 14$MC=1717E-9 24 + 94MO L 2872.40 116+ + 94MO L 2955.55 13(8)+ + 94MO L 2965.41 6 3+ + 94MO E 0.00058 9 0.093 146.9 + 94MO2 E EAV=157.5 22$CK=0.8686 14$CL=0.1069 11$CM=0.0208 4$CN=0.0037 2$CO= + 94MO G 898.06 9 0.0098 5 M1+E2 2.0 9 9.97E-415 + 94MO2 G KC=8.77E-4 13$LC=9.96E-5 14$MC=1778E-8 25 + 94MO G 1101.09 8 0.042 14M1+E2 -0.09 6 6.53E-410 + 94MO2 G KC=5.76E-4 8$LC=6.40E-5 9$MC=1142E-8 16 + 94MO G 1391.64 7 0.0267 10M1+E2 -0.08 6 4.41E-47 + 94MO2 G KC=3.53E-4 5$LC=3.91E-5 6$MC=6.98E-6 10 + 94MO G 2094.28 6 0.0156 6 M1+E2 1.1 7 5.12E-414 + 94MO2 G KC=1.55E-4 3$LC=1.71E-5 4$MC=3.04E-6 6 + 94MO L 3128.66 7 1+ + 94MO E 1.63 9 5.57 + 94MO2 E EAV= $CK=0.8682 14$CL=0.1072 11$CM=0.0209 4$CN=0.0037 2$CO= + 94MO G 1061.30 9 0.016 2 M1+E2 -0.57 16 6.99E-411 + 94MO2 G KC=6.16E-4 10$LC=6.88E-5 10$MC=1227E-8 18 + 94MO G 1264.34 9 0.22 2 M1+E2 -0.08 3 5.03E-47 + 94MO2 G KC=4.31E-4 6$LC=4.78E-5 7$MC=8.52E-6 12 + 94MO G 2257.53 7 0.057 5 M1+E2 0.74 19 5.61E-49 + 94MO2 G KC=1356E-7 20$LC=1491E-8 22$MC=2.66E-6 4 + 94MO G 3128.60 7 1.34 9 M1 8.71E-413 + 94MO2 G KC=7.58E-5 11$LC=8.29E-6 12$MC=1476E-9 21 + 94MO L 3163.29 19(3)+ + 94MO E 0.058 177 + 94MO2 E EAV= $CK=0.8681 14$CL=0.1073 11$CM=0.0209 4$CN=0.0037 2$CO= + 94MO G 358.3 3 0.0084 7 M1+E2 -0.35 12 0.0092 4 + 94MO2 G KC=0.0080 4$LC=0.00093 5$MC=1.67E-4 8 + 94MO G 2292.16 190.050 17M1+E2 0.17 4 5.62E-48 + 94MO2 G KC=1330E-7 19$LC=1461E-8 21$MC=2.60E-6 4 + 94MO L 3165.77 9 6+ + 94MO L 3331.74 17(3)+ + 94MO E 0.234 206.3 + 94MO2 E EAV= $CK=0.8675 14$CL=0.1078 11$CM=0.0210 4$CN=0.0038 2$CO= + 94MO G 1467.42 180.072 5 M1+E2 0.3 16 4.19E-49 + 94MO2 G KC=3.16E-4 15$LC=3.50E-5 15$MC=6.2E-6 3 + 94MO G 1757.96 170.15 2 M1+E2 -0.10 3 4.18E-46 + 94MO2 G KC=2.21E-4 3$LC=2.44E-5 4$MC=4.35E-6 6 + 94MO G 2460.61 170.011 2 (M1+E2) + 94MO L 3339.54 176+ + 94MO L 3400.83 17 + + 94MO E 0.36 4 6 + 94MO2 E EAV= $CK=0.8672 14$CL=0.1080 11$CM=0.0211 4$CN=0.0038 2$CO= + 94MO G 1536.51 180.014 3 + 94MO G 2529.69 170.34 4 + 94MO G 3400.76 170.005 2 + 94MO L 3447.6 4 (1,2)+ + 94MO E 0.118 196.4 + 94MO2 E EAV= $CK=0.8669 14$CL=0.1082 11$CM=0.0211 4$CN=0.0038 2$CO= + 94MO G 2576.5 4 0.11 2 M1+E2 -1.9 6 6.94E-412 + 94MO2 G KC=1061E-7 15$LC=1164E-8 17$MC=2.07E-6 3 + 94MO G 3447.5 4 0.006 1 + 94MO L 3511.86 141+ + 94MO E 0.121 106.4 + 94MO2 E EAV= $CK=0.8666 15$CL=0.1085 11$CM=0.0212 4$CN=0.0038 2$CO= + 94MO G 1770.19 210.025 6 (M1+E2) + 94MO G 2640.72 140.033 4 (M1+E2) + 94MO G 3511.79 140.063 7 (M1+E2) + 94MO L 3534.32 9 2+ + 94MO E 0.106 3 6.4 + 94MO2 E EAV= $CK=0.8664 15$CL=0.1086 11$CM=0.0212 4$CN=0.0038 2$CO= + 94MO G 1669.99 100.037 2 M1+E2 0.15 19 4.10E-46 + 94MO2 G KC=2.45E-4 4$LC=2.70E-5 4$MC=4.81E-6 7 + 94MO G 2663.18 9 0.066 2 M1+E2 -0.3 2 6.99E-411 + 94MO2 G KC=1009E-7 15$LC=1106E-8 16$MC=1.97E-6 3 + 94MO G 3534.25 9 0.0034 4 E2 1065E-615 + 94MO2 G KC=6.25E-5 9$LC=6.82E-6 10$MC=1215E-9 17 + 94MO L 3792.87 152+ + 94MO E 0.169 205.9 + 94MO2 E EAV= $CK=0.8639 15$CL=0.1106 11$CM=0.0216 4$CN=0.0039 2$CO= + 94MO G 1399.84 160.041 3 M1+E2 + 94MO G 1928.54 160.075 19M1+E2 + 94MO G 3792.79 150.052 5 E2 1149E-616 + 94MO2 G KC=5.59E-5 8$LC=6.09E-6 9$MC=1084E-9 16 + 94MO L 3892.16 7 (2)+ + 94MO E 0.212 135.6 + 94MO2 E EAV= $CK=0.8620 15$CL=0.1121 12$CM=0.0220 4$CN=0.0039 2$CO= + 94MO G 1499.13 9 0.067 11M1+E2 + 94MO G 1824.79 9 0.023 1 (M1+E2) + 94MO G 2027.83 9 0.021 4 (M1+E2) + 94MO G 3021.01 7 0.087 14(M1+E2) + 94MO G 3892.07 7 0.014 2 + diff --git a/HEN_HOUSE/spectra/lnhb/Tc-99.txt b/HEN_HOUSE/spectra/lnhb/Tc-99.txt new file mode 100644 index 000000000..4c7e815e5 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Tc-99.txt @@ -0,0 +1,46 @@ + 99RU 99TC B- DECAY (211.5E3 Y) + 99RU H TYP=Full$AUT=X. Mougeot$CUT=15-MAR-2010$ + 99RU2 H TYP=update$AUT=MMBé$CUT= -- $ + 99RU C Evaluation history: Type=Full;Author=X. Mougeot;Cutoff date=15-MAR-2010 + 99RU2C Type=update;Author=MMBé;Cutoff date= -- + 99RU C References: 1947MO15, 1950KE02, 1951TA05, 1951FR05, 1952FE16, 1954GO69, + 99RU2C 1960BO08, 1961RO33, 1964KI01, 1964BO28, 1965KI01, 1965MA27, 1966GO10, + 99RU3C 1966SN02, 1966KI02, 1967MO20, 1967ST36, 1968HA52, 1971GO40, 1971LE20, + 99RU4C 1970AN12, 1972GU01, 1972WA32, 1973BE72, 1973LE10, 1974RE11, 1974EN02, + 99RU5C 1974HA12, 1976KI02, 1977IS05, 1980LA02, 1984CO30, 1986MU09, 1990GA13, + 99RU6C 1996SC06, 2003AU03, 2008KI07 + 99RU T Auger electrons and ^X ray energies and emission intensities: + 99RU T {U Energy (keV)} {U Intensity } {U Line } + 99RU T + 99RU T 19.1506 0.000155 30 XKA2 + 99RU T 19.2794 0.00029 6 XKA1 + 99RU T + 99RU T 21.6349 |] XKB3 + 99RU T 21.6565 |] 0.000079 15 XKB1 + 99RU T 21.832 |] XKB5II + 99RU T + 99RU T 22.074 |] XKB2 + 99RU T 22.104 |] 0.0000128 25 XKB4 + 99RU T + 99RU T 2.2538-3.1825 0.000039 4 XL (total) + 99RU T 2.2538 0.00000086 12 XLL + 99RU T 2.5542-2.5591 0.0000234 29 XLA + 99RU T 2.3826 0.00000032 6 XLC + 99RU T 2.6831-2.9436 0.0000132 18 XLB + 99RU T 2.8959-3.1825 0.00000091 12 XLG + 99RU T + 99RU T 15.565-16.329 |] KLL AUGER + 99RU T 18.267-19.277 |] 0.000139 27 ^KLX AUGER + 99RU T 20.947-22.113 |] KXY AUGER + 99RU T 1.75-3.12 0.00080 4 L AUGER + 99TC P 0.0 9/2+ 211.5E3 Y 11 293.8 14 + 99RU N 1.0 1.0 1 1.0 + 99RU L 0 5/2+ STABLE + 99RU B 293.8 1499999E-330 12.3 + 99RUS B EAV=94.6 17 + 99RU L 89.52 153/2+ 20.36 NS 25 + 99RU B 204.3 140.00145 30 15.8 + 99RUS B EAV= + 99RU G 89.52 150.00058 11M1+()E2 -1.56 2 1.495 25 + 99RU2 G KC=1.173 19$LC=0.265 5$MC=0.0497 9 + diff --git a/HEN_HOUSE/spectra/lnhb/Tc-99m.txt b/HEN_HOUSE/spectra/lnhb/Tc-99m.txt new file mode 100644 index 000000000..0f0e0cb17 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Tc-99m.txt @@ -0,0 +1,69 @@ + 99TC 99TC IT DECAY (6.0067 H) + 99TC T Auger electrons and ^X ray energies and emission intensities: + 99TC T {U Energy (keV)} {U Intensity } {U Line } + 99TC T + 99TC T 18.251 2.22 7 XKA2 + 99TC T 18.3672 4.21 12 XKA1 + 99TC T + 99TC T 20.599 |] XKB3 + 99TC T 20.619 |] 1.12 4 XKB1 + 99TC T 20.789 |] XKB5II + 99TC T + 99TC T 21.005 |] XKB2 + 99TC T 21.042 |] 0.177 8 XKB4 + 99TC T + 99TC T 2.134-3.002 0.482 12 XL (total) + 99TC T 2.134 0.0110 4 XLL + 99TC T 2.42-2.425 0.298 10 XLA + 99TC T 2.25 0.00395 15 XLC + 99TC T 2.456-2.788 0.159 5 XLB + 99TC T 2.726-3.002 0.00984 26 XLG + 99TC T + 99TC T 14.86-15.58 |] KLL AUGER + 99TC T 17.43-18.33 |] 2.15 8 ^KLX AUGER + 99TC T 19.93-21 |] KXY AUGER + 99TC T 1.6-2.9 10.89 9 L AUGER + 99TC P 142.683 1 1/2- 6.0067 H 10 + 99TC N 1.0 1.0 1 1.0 + 99TC L 0 9/2+ 211.5E3 Y 11 + 99TC L 140.5108 107/2+ 0.221 NS 20 + 99TC G 140.511 1 88.5 2 M1+E2 0.119 3 + 99TC2 G KC=0.104 3$LC=0.01290 39$MC=0.00236 7 + 99TC L 142.6833 111/2- 6.0067 H 10 + 99TC G 2.1726 4 7.4E-9 2 E3 135E8 4 + 99TC2 G KC=$LC=$MC=119E8 3 + 99TC G 142.683 1 0.023 2 M4 40.9 8 + 99TC2 G KC=29.3 6$LC=9.35 20$MC=1.86 6 + + 99RU 99TC B- DECAY (6.0067 H) + 99RU T Auger electrons and ^X ray energies and emission intensities: + 99RU T {U Energy (keV)} {U Intensity } {U Line } + 99RU T + 99RU T 19.1506 XKA2 + 99RU T 19.2794 XKA1 + 99RU T + 99RU T 21.6349 |] XKB3 + 99RU T 21.6565 |] XKB1 + 99RU T 21.832 |] XKB5II + 99RU T + 99RU T 22.074 |] XKB2 + 99RU T 22.104 |] XKB4 + 99RU T + 99TC P 142.683 1 1/2- 6.0067 H 10 293.52 20 + 99RU N 2.50E4 2.50E4 0.00004 2.50E4 + 99RU L 0 5/2+ STABLE + 99RU B 436.3 2 0.0010 3 9.4 3U + 99RUS B EAV=152.3 5 + 99RU L 89.68 5 3/2+ 20.5 NS 1 + 99RU B 346.7 2 0.0026 5 8.7 1U + 99RUS B EAV=102.1 5 + 99RU G 89.6 3 0.00104 20M1+E2 1.49 5 + 99RU2 G KC=1.17 4$LC=0.27 1$MC= + 99RU L 322.38 6 (3/2)+ + 99RU B 113.9 2 10600E-86 8.5 1U + 99RUS B EAV=37.8 6 + 99RU G 232.7 2 8.4E-6 15 0.048 2 + 99RU2 G KC=0.0412 15$LC=$MC= + 99RU G 322.4 1 9.6E-5 6 0.0175 5 + 99RU2 G KC=0.0152 5$LC=$MC= + diff --git a/HEN_HOUSE/spectra/lnhb/Te-123m.txt b/HEN_HOUSE/spectra/lnhb/Te-123m.txt new file mode 100644 index 000000000..fce78a217 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Te-123m.txt @@ -0,0 +1,42 @@ +123TE 123TE IT DECAY (119.3 D) +123TE C References: 1955Fa40, 1955Go21, 1964Ch18, 1964Ch08, 1964Al28, 1966Ha03, +123TE2C 1966Gu02, 1969To02, 1968Ka20, 1970EmZY, 1972Ra07, 1973Ra32, 1973RaZO, +123TE3C 1977Kr13, 1992Ja15, 1992Co11, 1996Sc06, 2002Ba85 +123TE T Auger electrons and ^X ray energies and emission intensities: +123TE T {U Energy (keV)} {U Intensity } {U Line } +123TE T +123TE T 27.202 13.9 5 XKA2 +123TE T 27.4726 26.0 9 XKA1 +123TE T +123TE T 30.9446 |] XKB3 +123TE T 30.996 |] 7.43 26 XKB1 +123TE T 31.236 |] XKB5II +123TE T 31.241 |] XKB5I +123TE T +123TE T 31.7008 |] XKB2 +123TE T 31.774 |] 1.61 7 XKB4 +123TE T 31.812 |] XKO23 +123TE T +123TE T 3.336-4.82 8.25 21 XL (total) +123TE T 3.336 0.174 7 XLL +123TE T 3.76-3.77 4.60 15 XLA +123TE T 3.606 0.0469 18 XLC +123TE T 4.02-4.37 3.02 7 XLB +123TE T 4.44-4.82 0.411 11 XLG +123TE T +123TE T 21.804-22.989 |] KLL AUGER +123TE T 25.814-27.47 |] 7.0 4 ^KLX AUGER +123TE T 29.8-31.81 |] KXY AUGER +123TE T 2.3-4.8 89.7 7 L AUGER +123TE P 247.4 2 11/2- 119.3 D 1 +123TE N 1.0 1.0 1 1.0 +123TE L 0 1/2+ 12E12 Y +123TE L 158.99 3/2+ 196 PS 9 +123TE G 158.97 5 83.99 8 M1+E2 0.0111 0.1918 19 +123TE2 G KC=0.1648 16$LC=0.02160 22$MC=0.00433 13 +123TE L 247.4 11/2- 119.5 D 1 +123TE G 88.46 7 0.0909 27M4 1099 33 +123TE2 G KC=463 14$LC=493 15$MC=118.0 35 +123TE G 247.4 2 3.44E-4 34E5 7.75 30 +123TE2 G KC=3.0 1$LC=3.75 21$MC=0.84 3 + diff --git a/HEN_HOUSE/spectra/lnhb/Te-127.txt b/HEN_HOUSE/spectra/lnhb/Te-127.txt new file mode 100644 index 000000000..91a285054 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Te-127.txt @@ -0,0 +1,73 @@ +127I 127TE B- DECAY (9.35 H) +127I H TYP=Full$AUT=A.L. Nichols$CUT=31-MAY-2012$ +127I C Evaluation history: Type=Full;Author=A.L. Nichols;Cutoff date=31-MAY-2012 +127I C References: 1940Se01, 1956Kn20, 1963Ma20, 1965Au01, 1966Ne02, 1967Ge10, +127I 2C 1968Qa02, 1970Ap02, 1970Bo22, 1977La19, 1977Ge10, 1977Kr13, 1980Kr22, +127I 3C 1996Sc06, 1998ScZM, 1999ScZX, 2002Ba25, 2002Ra45, 2003Au03, 2003De44, +127I 4C 2008Ki07, 2011Ha31, 2012Au06 +127I T Auger electrons and ^X ray energies and emission intensities: +127I T {U Energy (keV)} {U Intensity } {U Line } +127I T +127I T 28.3175 0.0309 7 XKA2 +127I T 28.6123 0.0574 12 XKA1 +127I T +127I T 32.2397 |] XKB3 +127I T 32.2951 |] 0.0165 4 XKB1 +127I T 32.539 |] XKB5II +127I T 32.55 |] XKB5I +127I T +127I T 33.042 |] XKB2 +127I T 33.12 |] 0.00374 12 XKB4 +127I T 33.166 |] XKO23 +127I T +127I T 3.485-5.06 0.0119 6 XL (total) +127I T 3.485 0.000226 8 XLL +127I T 3.927-3.938 0.00597 18 XLA +127I T 3.779 0.000088 3 XLC +127I T 4.221-4.508 0.00476 11 XLB +127I T 4.801-5.06 0.000678 17 XLG +127I T +127I T 22.659-23.909 |] KLL AUGER +127I T 26.853-28.609 |] 0.0145 6 ^KLX AUGER +127I T 31.02-33.16 |] KXY AUGER +127I T 2.38-3.88 0.1174 18 L AUGER +127TE P 0.0 3/2+ 9.35 H 10 702 4 +127I N 1.0 1.0 1 1.0 +127I L 0 5/2+ STABLE +127I B 702 4 98.780 14 5.49 2 +127I S B EAV=227.8 16 +127I L 57.608 117/2+ +127I G 57.608 110.0306 6 M1+E2 -0.083 5 3.72 6 +127I 2 G KC=3.16 5$LC=0.449 8$MC=0.0910 16 +127I L 202.860 8 3/2+ +127I B 499 4 0.025 3 8.57 +127I S B EAV=153.0 15 +127I G 145.252 140.0040 6 E2 0.471 7 +127I 2 G KC=0.357 5$LC=0.0907 13$MC=0.0189 3 +127I G 202.860 8 0.056 2 M1+E2 0.52 5 0.1143 22 +127I 2 G KC=0.0965 17$LC=0.0142 5$MC=0.00289 10 +127I L 374.992 9 1/2+ +127I B 327 4 0.0006 3 9.58 2 +127I S B EAV=94.5 13 +127I G 172.132 120.0003 2 M1+E2 -0.085 6 0.1650 24 +127I 2 G KC=0.1419 20$LC=0.0185 3$MC=0.00373 6 +127I G 374.991 9 0.0003 2 E2 0.0199 3 +127I 2 G KC=0.01671 24$LC=0.00257 4$MC=5.24E-4 8 +127I L 417.99 6 5/2+ +127I B 284 4 1.19 2 6.086 2 +127I S B EAV=80.7 13 +127I G 215.13 6 0.039 2 M1+E2 -0.203 15 0.0910 13 +127I 2 G KC=0.0782 11$LC=0.01031 16$MC=0.00208 4 +127I G 360.38 6 0.136 2 M1+E2 0.194 15 0.0232 4 +127I 2 G KC=0.0201 3$LC=0.00256 4$MC=5.14E-4 8 +127I G 417.99 6 0.997 11M1+E2 -0.08 3 0.0159823 +127I 2 G KC=0.01381 20$LC=1741E-6 25$MC=3.50E-4 5 +127I L 618.31 133/2+ +127I B 84 4 0.00013 2 8.38 +127I S B EAV=21.8 11 +127I G 618.31 130.00013 2 M1+E2 1.0 5 0.0055 4 +127I 2 G KC=0.0047 4$LC=0.00061 3$MC=1.23E-4 6 +127I L 628.69 167/2+ +127I L 650.92 8 9/2+ +127I L 716.50 6 (11/2)+ + diff --git a/HEN_HOUSE/spectra/lnhb/Te-127m.txt b/HEN_HOUSE/spectra/lnhb/Te-127m.txt new file mode 100644 index 000000000..f8fd5851a --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Te-127m.txt @@ -0,0 +1,104 @@ +127TE 127TE IT DECAY (106.1 D) +127TE H TYP=Full$AUT=A.L. Nichols$CUT=31-MAY-2012$ +127TE C Evaluation history: Type=Full;Author=A.L. Nichols;Cutoff date=31-MAY-2012 +127TE C References: 1940Se01, 1951Co34, 1956Kn20, 1965Au01, 1965An05, 1966Ne02, +127TE2C 1967Ge10, 1970Ap02, 1972Ka31, 1972Ka61, 1977So06, 1977Kr13, 1977La19, +127TE3C 1980Kr22, 1996Sc06, 1998ScZM, 1999ScZX, 2002Ba25, 2002Ra45, 2003Au03, +127TE4C 2003De44, 2008Ea01, 2008Ki07, 2011Ha31, 2012Au06 +127TE T Auger electrons and ^X ray energies and emission intensities: +127TE T {U Energy (keV)} {U Intensity } {U Line } +127TE T +127TE T 27.202 10.3 3 XKA2 +127TE T 27.4726 19.3 5 XKA1 +127TE T +127TE T 30.9446 |] XKB3 +127TE T 30.996 |] 5.51 15 XKB1 +127TE T 31.232 |] XKB5II +127TE T 31.242 |] XKB5I +127TE T +127TE T 31.7008 |] XKB2 +127TE T 31.774 |] 1.20 5 XKB4 +127TE T 31.182 |] XKO23 +127TE T +127TE T 3.335-4.829 7.0 3 XL (total) +127TE T 3.335 0.146 5 XLL +127TE T 3.759-3.77 3.86 11 XLA +127TE T 3.605 0.0369 13 XLC +127TE T 4.03-4.302 2.45 5 XLB +127TE T 4.572-4.829 0.333 8 XLG +127TE T +127TE T 21.804-22.989 |] KLL AUGER +127TE T 25.814-27.47 |] 5.19 21 ^KLX AUGER +127TE T 29.8-31.81 |] KXY AUGER +127TE T 2.29-3.72 74.3 10 L AUGER +127TE P 88.23 7 11/2- 106.1 D 7 +127TE N 1.028E0 1.028E0 0.972699 1.028E0 +127TE L 0 3/2+ 9.35 H 10 +127TE L 61.161 191/2+ +127TE L 88.23 7 11/2- 106.1 D 7 +127TE G 88.23 7 0.0854 16M4 1138 17 +127TE2 G KC=486 7$LC=506 8$MC=120.4 18 + +127I 127TE B- DECAY (106.1 D) +127I H TYP=Full$AUT=A.L. Nichols$CUT=31-MAY-2012$ +127I C Evaluation history: Type=Full;Author=A.L. Nichols;Cutoff date=31-MAY-2012 +127I C References: 1940Se01, 1951Co34, 1956Kn20, 1965Au01, 1965An05, 1966Ne02, +127I 2C 1967Ge10, 1970Ap02, 1972Ka31, 1972Ka61, 1977So06, 1977Kr13, 1977La19, +127I 3C 1980Kr22, 1996Sc06, 1998ScZM, 1999ScZX, 2002Ba25, 2002Ra45, 2003Au03, +127I 4C 2003De44, 2008Ea01, 2008Ki07, 2011Ha31, 2012Au06 +127I T Auger electrons and ^X ray energies and emission intensities: +127I T {U Energy (keV)} {U Intensity } {U Line } +127I T +127I T 28.3175 0.459 12 XKA2 +127I T 28.6123 0.852 21 XKA1 +127I T +127I T 32.2397 |] XKB3 +127I T 32.2951 |] 0.245 7 XKB1 +127I T 32.539 |] XKB5II +127I T 32.55 |] XKB5I +127I T +127I T 33.042 |] XKB2 +127I T 33.12 |] 0.0555 19 XKB4 +127I T 33.166 |] XKO23 +127I T +127I T 3.485-5.06 0.177 9 XL (total) +127I T 3.485 0.00336 11 XLL +127I T 3.927-3.938 0.089 3 XLA +127I T 3.779 0.00130 5 XLC +127I T 4.221-4.508 0.0707 17 XLB +127I T 4.801-5.06 0.0101 3 XLG +127I T +127I T 22.659-23.909 |] KLL AUGER +127I T 26.853-28.609 |] 0.216 9 ^KLX AUGER +127I T 31.02-33.16 |] KXY AUGER +127I T 2.37-3.88 1.74 3 L AUGER +127TE P 88.23 7 11/2- 106.1 D 7 701.8 40 +127I N 3.663E1 3.663E1 0.0273 3.663E1 +127I L 0 5/2+ STABLE +127I L 57.608 117/2+ +127I B 732 4 2.71 7 9.873 3U +127I S B EAV=255.9 15 +127I G 57.608 110.578 10M1+E2 -0.083 5 3.72 6 +127I 2 G KC=3.16 5$LC=0.449 8$MC=0.0910 16 +127I L 202.860 8 3/2+ +127I L 374.992 9 1/2+ +127I L 417.99 6 5/2+ +127I L 618.31 133/2+ +127I L 628.69 167/2+ +127I B 161 4 0.00009 2 11.3 3U +127I S B EAV=52.9 14 +127I G 628.69 160.00009 2 M1+E2 1.0 5 0.0052 4 +127I 2 G KC=0.0045 4$LC=0.00058 3$MC=1.17E-4 6 +127I L 650.92 8 9/2+ +127I B 139 4 0.0027 2 10.18 1U +127I S B EAV=37.2 12 +127I G 593.31 8 0.0024 2 M1+E2 -0.23 3 0.0066810 +127I 2 G KC=0.00578 9$LC=7.22E-4 11$MC=1448E-7 21 +127I G 650.92 8 0.0003 2 E2 0.004236 +127I 2 G KC=0.00362 5$LC=4.88E-4 7$MC=9.85E-5 14 +127I L 716.50 6 11/2+ +127I B 74 4 0.0141 6 8.61 +127I S B EAV=19.1 11 +127I G 658.89 6 0.0140 6 E2 0.004106 +127I 2 G KC=0.00351 5$LC=4.72E-4 7$MC=9.53E-5 14 + diff --git a/HEN_HOUSE/spectra/lnhb/Te-132.txt b/HEN_HOUSE/spectra/lnhb/Te-132.txt new file mode 100644 index 000000000..8d53b9509 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Te-132.txt @@ -0,0 +1,50 @@ +132I 132TE B- DECAY (3.230 D) +132I H TYP=Full$AUT=A.Nichols$CUT=31-MAR-2009$ +132I 2 H TYP=Full$AUT=A.Nichols$CUT=31-MAR-2009$ +132I C Evaluation history: Type=Full;Author=A.Nichols;Cutoff date=31-MAR-2009 +132I 2C Type=Full;Author=A.Nichols;Cutoff date=31-MAR-2009 +132I C References: 1956Fl15, 1958Ch28, 1965An05, 1966Fr02, 1971BaZW, 1977La19, +132I 2C 1979Bo26, 1981Yo02, 1983Wa26, 1996Sc06, 1998ScZM, 1999ScZX, 2002Ba85, +132I 3C 2002Ra45, 2003Au03, 2005Kh07, 2008Ki07 +132I T Auger electrons and ^X ray energies and emission intensities: +132I T {U Energy (keV)} {U Intensity } {U Line } +132I T +132I T 28.3175 20.6 5 XKA2 +132I T 28.6123 38.2 9 XKA1 +132I T +132I T 32.2397 |] XKB3 +132I T 32.2951 |] 11.0 3 XKB1 +132I T 32.544 |] XKB5II +132I T +132I T 33.042 |] XKB2 +132I T 33.12 |] 2.49 9 XKB4 +132I T 33.166 |] XKO23 +132I T +132I T 3.485-5.065 7.9 4 XL (total) +132I T 3.485 XLL +132I T 3.926-3.938 3.96 12 XLA +132I T 3.78 0.0583 20 XLC +132I T 4.221-4.508 3.16 8 XLB +132I T 4.802-5.065 0.451 12 XLG +132I T +132I T 22.659-23.909 |] KLL AUGER +132I T 26.853-28.609 |] 9.7 3 ^KLX AUGER +132I T 31.02-33.16 |] KXY AUGER +132I T 2.37-3.88 78.0 13 L AUGER +132TE P 0.0 0+ 3.230 D 13 518 4 +132I N 1.0 1.0 1 1.0 +132I L 0 4+ 2.295 H 13 +132I L 49.72 1 3+ 7.14 NS 14 +132I G 49.72 1 15.1 3 M1 5.62 8 +132I 2 G KC=4.83 7$LC=0.638 9$MC=0.1286 18 +132I L 161.52 7 2+ 3.57 NS 7 +132I G 111.81 8 1.85 18M1+E2 0.58 6 0.71 3 +132I 2 G KC=0.562 17$LC=0.115 9$MC=0.0238 18 +132I L 277.86 6 1+ 1.42 NS 2 +132I B 240 4 100 4.85 +132I S B EAV=67.0 13 +132I G 116.34 131.97 7 M1+E2 0.53 5 0.606 20 +132I 2 G KC=0.489 13$LC=0.093 6$MC=0.0193 13 +132I G 228.327 3 88.12 13E2 0.0990 14 +132I 2 G KC=0.0802 12$LC=0.01507 21$MC=0.00311 5 + diff --git a/HEN_HOUSE/spectra/lnhb/Th-228.txt b/HEN_HOUSE/spectra/lnhb/Th-228.txt new file mode 100644 index 000000000..4d254dd15 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Th-228.txt @@ -0,0 +1,83 @@ +224RA 228TH A DECAY (1.9126 Y) +224RA H TYP=Update$AUT=A.L.Nichols$CUT=30-APR-2010$ +224RA C Evaluation history: Type=Update;Author=A.L.Nichols;Cutoff date=30-APR-2010 +224RA C References: 1918Me01, 1953As31, 1956Ki16, 1962Ma57, 1966Co40, 1968Da21, +224RA2C 1968Du06, 1969Pe17, 1970Ba20, 1970SpZW, 1971Jo14, 1971Gr07, 1976BaZZ, +224RA3C 1977La19, 1977Ku15, 1981Ku02, 1982Sa36, 1984Ge07, 1991Ry01, 1992Un01, +224RA4C 1993Bo20, 1993Ba72, 1995Ar33, 1996Sc06, 1997Ar05, 1997Tr17, 1998Ak04, +224RA5C 1998ScZM, 1999ScZX, 2002Un02, 2002Ba85, 2002Ra45, 2003Au03, 2007BeZP, +224RA6C 2008Ki07 +224RA T Auger electrons and ^X ray energies and emission intensities: +224RA T {U Energy (keV)} {U Intensity } {U Line } +224RA T +224RA T 85.43 0.0180 3 XKA2 +224RA T 88.47 0.0295 5 XKA1 +224RA T +224RA T 99.432 |] XKB3 +224RA T 100.13 |] 0.01034 21 XKB1 +224RA T 100.738 |] XKB5II +224RA T +224RA T 102.89 |] XKB2 +224RA T 103.295 |] 0.00339 9 XKB4 +224RA T 103.74 |] XKO23 +224RA T +224RA T 10.6241-18.3539 8.6 4 XL (total) +224RA T 10.6241 0.166 6 XLL +224RA T 12.1957-12.3381 2.86 9 XLA +224RA T 13.6624 0.109 4 XLC +224RA T 14.2373-16.1261 4.67 15 XLB +224RA T 17.2756-18.3539 1.09 4 XLG +224RA T +224RA T 65.149-72.729 |] KLL AUGER +224RA T 79.721-88.466 |] 0.0020 3 ^KLX AUGER +224RA T 94.27-103.91 |] KXY AUGER +224RA T 5.71-12.04 10.4 4 L AUGER +228TH P 0.0 0+ 1.9126 Y 9 5520.08 22 +224RA N 1.0 1.0 1 1.0 +224RA L 0 0+ 3.631 D 2 +224RA A 5423.24 2273.4 5 1 +224RA L 84.373 3 2+ +224RA A 5340.35 2226.0 5 0.958 +224RA G 84.373 3 1.19 3 E2 21.2 3 +224RA2 G KC=$LC=15.57 22$MC=4.24 6 +224RA L 215.985 4 1- +224RA A 5211.05 220.408 7 10.7 +224RA G 131.612 5 0.127 2 E1 0.247 4 +224RA2 G KC=0.194 3$LC=0.0406 6$MC=0.00977 14 +224RA G 215.985 4 0.246 4 E1 0.0752 11 +224RA2 G KC=0.0600 9$LC=0.01148 16$MC=0.00274 4 +224RA L 250.783 5 4+ +224RA A 5176.86 220.218 4 12.5 +224RA G 166.410 4 0.1004 14E2 1.164 17 +224RA2 G KC=0.225 4$LC=0.691 10$MC=0.187 3 +224RA L 290.36 4 (3)- +224RA A 5137.97 220.036 6 44 +224RA G 74.38 4 0.00039 14[E2] 38.6 6 +224RA2 G KC=$LC=28.3 4$MC=7.71 11 +224RA G 205.99 4 0.0188 5 [E1] 0.0841 12 +224RA2 G KC=0.0671 10$LC=0.01292 18$MC=0.00309 5 +224RA L 433.07 10(5)- +224RA A 4997.76 2410000E-92 21400 +224RA G 142.71 111.3E-6 4 [E2] 2.14 3 +224RA2 G KC=0.279 4$LC=1.368 20$MC=0.372 6 +224RA G 182.29 105.1E-6 18[E1] 0.1126 16 +224RA2 G KC=0.0894 13$LC=0.01757 25$MC=0.00421 6 +224RA L 479.20 18(6)+ +224RA A 4952.5 3 24000E-95 4600 +224RA G 228.42 181.8E-5 4 [E2] 0.366 6 +224RA2 G KC=0.1244 18$LC=0.178 3$MC=0.0479 7 +224RA L 916.34 7 0+ +224RA A 4522.97 2317000E-93 7 +224RA G 700.36 7 3E-6 1 E1 0.006119 +224RA2 G KC=0.00502 7$LC=8.34E-4 12$MC=1.96E-4 3 +224RA G 831.97 7 1.4E-5 2 E2 0.0128918 +224RA2 G KC=0.00970 14$LC=0.00240 4$MC=5.94E-4 9 +224RA L 992.65 6 (2)+ +224RA A 4448.00 2345000E-17 7.2 +224RA G 741.87 6 1.4E-6 4 [E2] 0.0162523 +224RA2 G KC=0.01196 17$LC=0.00322 5$MC=8.03E-4 12 +224RA G 908.28 6 1.7E-6 5 [M1+E2] 1.0 2 0.024 3 +224RA2 G KC=0.0190 24$LC=0.0036 4$MC=0.00087 9 +224RA G 992.65 6 1.4E-6 4 [E2] 0.0091313 +224RA2 G KC=0.00705 10$LC=1569E-6 22$MC=3.84E-4 6 + diff --git a/HEN_HOUSE/spectra/lnhb/Th-231.txt b/HEN_HOUSE/spectra/lnhb/Th-231.txt new file mode 100644 index 000000000..5efc7ebae --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Th-231.txt @@ -0,0 +1,168 @@ +231PA 231TH B- DECAY (25.522 H) +231PA H TYP=Full$AUT=X. Huang$CUT=31-MAY-2007$ +231PA C Evaluation history: Type=Full;Author=X. Huang;Cutoff date=31-MAY-2007 +231PA C References: 2008Ki07 +231PA T Auger electrons and ^X ray energies and emission intensities: +231PA T {U Energy (keV)} {U Intensity } {U Line } +231PA T +231PA T 92.288 0.37 4 XKA2 +231PA T 95.869 0.59 7 XKA1 +231PA T +231PA T 107.595 |] XKB3 +231PA T 108.422 |] 0.21 2 XKB1 +231PA T 109.072 |] XKB5II +231PA T +231PA T 111.405 |] XKB2 +231PA T 111.87 |] 0.071 8 XKB4 +231PA T 112.38 |] XKO23 +231PA T +231PA T 11.3676-20.1126 65 3 XL (total) +231PA T 11.3676 XLL +231PA T 13.1215-13.2887 XLA +231PA T 14.9488 XLC +231PA T 15.3584-17.6655 XLB +231PA T 18.9396-20.1126 XLG +231PA T +231PA T 70.081-78.822 |] KLL AUGER +231PA T 85.989-95.858 |] 0.038 5 ^KLX AUGER +231PA T 101.87-112.59 |] KXY AUGER +231PA T 5.9-21 68 3 L AUGER +231TH P 0.0 5/2+ 25.522 H 10 391.6 15 +231PA N 1.0 1.0 1 1.0 +231PA L 0 3/2- 32670 Y 260 +231PA B 391.6 150.022 7 9.57 1U +231PAS B EAV=111.6 5 +231PA L 9.206 251/2- +231PA G 9.2 +231PA L 58.5699 247/2- 274 PS 10 +231PA B 333.0 150.17 17 8.2 1U +231PAS B EAV=93.4 5 +231PA G 58.5700 240.480 16E2 155.5 22 +231PA2 G KC=$LC=113.6 16$MC=31.3 5 +231PA L 77.685 175/2- +231PA B 313.9 150.43 2 7.97 +231PAS B EAV=87.6 5 +231PA G 68.5 1 0.00590 15E2 73.3 12 +231PA2 G KC=$LC=53.5 8$MC=14.8 3 +231PA G 77.69 0.0042 7 +231PA L 84.2148 135/2+ 45.1 NS 13 +231PA B 307.4 1529 18 6.1 +231PAS B EAV=85.6 5 +231PA G 25.64 2 13.9 7 E1 4.37 7 +231PA2 G KC=$LC=3.26 5$MC=0.843 12 +231PA G 84.2140 136.70 7 E1 2.50 25 +231PA2 G KC=$LC=1.77 2$MC=0.57 10 +231PA L 101.4092 217/2+ 0.7 NS +231PA B 290.2 1541 16 5.88 2 +231PAS B EAV=80.4 5 +231PA G 17.2 (M1) 193.0000 +231PA2 G KC=$LC=$MC=135.700 0 +231PA G 42.86 7 0.0596 15[E1] 1.14 2 +231PA2 G KC=$LC=0.85 2$MC=0.21 1 +231PA L 102.2692 133/2+ 0.7 NS +231PA B 289.3 1513 8 6.4 2 +231PAS B EAV=80.1 5 +231PA G 18.07 M1+E2 0.14 12 800.0000 +231PA2 G KC=$LC=349.000 0$MC=304.000 0 +231PA G 93.02 4 0.040 3 [E1] 0.1463 21 +231PA2 G KC=$LC=0.110 2$MC=0.0269 4 +231PA G 102.2700 130.441 11E1 0.1141 16 +231PA2 G KC=$LC=0.086 1$MC=0.0210 3 +231PA L 111.653 12(9/2)+ +231PA G 10.25 +231PA L 174.161 4 (5/2)- +231PA B 217.4 151.36 24 6.96 +231PAS B EAV=58.9 5 +231PA G 72.7510 250.260 17[E1] 0.280 4 +231PA2 G KC=$LC=0.211 3$MC=0.0517 7 +231PA G 89.95 2 1.01 3 E1 0.1598 22 +231PA2 G KC=$LC=0.121 2$MC=0.0294 4 +231PA G 115.63 3 0.00110 16[M1+E2] 10 4 +231PA2 G KC=5 5$LC=3.3 12$MC=0.9 4 +231PA G 165.00 5 0.00348 14[E2] 1.464 2 +231PA2 G KC=0.209 3$LC=0.917 13$MC=0.252 4 +231PA G 174.15 2 0.0180 6 [M1+E2] 2.7 15 +231PA2 G KC=1.8 16$LC=0.68 5$MC=0.177 22 +231PA L 183.4962 175/2+ 0.19 NS +231PA B 208.1 1512.2 15 5.95 +231PAS B EAV=56.2 5 +231PA G 81.2280 140.905 23M1(+E2) 0.14 14 8.1 14 +231PA2 G KC=$LC=6.1 10$MC=1.5 3 +231PA G 82.0870 130.418 13M1(+E2) 0.14 14 7.9 13 +231PA2 G KC=$LC=5.9 9$MC=1.5 3 +231PA G 99.278 3 0.137 6 M1+E2 0.50 6 6.0 4 +231PA2 G KC=$LC=4.43 24$MC=1.13 7 +231PA G 105.81 3 0.0079 5 [E1] 0.1043 15 +231PA2 G KC=$LC=0.0787 11$MC=0.0192 3 +231PA G 124.914 170.0590 15E1 0.294 4 +231PA2 G KC=0.226 4$LC=0.0511 8$MC=0.01241 18 +231PA G 183.480 250.0335 8 E1 0.1181 17 +231PA2 G KC=0.0928 13$LC=0.0191 3$MC=0.00463 7 +231PA L 218.240 13(7/2)- +231PA B 173.4 150.31 23 7.3 1U +231PAS B EAV=46.2 5 +231PA G 44.08 170.00074 21[M1+E2] 3E2 3 +231PA2 G KC=$LC=2.4E2 21$MC=70 60 +231PA G 106.61 3 0.0179 7 [E1] 0.1023 14 +231PA2 G KC=$LC=0.0772 11$MC=0.0188 3 +231PA G 116.82 2 0.0225 9 E1 0.342 5 +231PA2 G KC=0.262 4$LC=0.0608 9$MC=0.01478 21 +231PA G 134.03 2 0.0255 8 E1 0.249 4 +231PA2 G KC=0.192 3$LC=0.0426 6$MC=0.01033 15 +231PA G 140.54 4 0.00074 7 [M1+E2] 5.3 25 +231PA2 G KC=3 3$LC=1.5 4$MC=0.40 12 +231PA L 247.320 5 7/2+ +231PA B 144.3 152.7 4 6.11 2 +231PAS B EAV=38.1 5 +231PA G 63.86 3 0.0235 21M1+E2 0.52 20 34 15 +231PA2 G KC=$LC=25 11$MC=6.6 31 +231PA G 135.664 110.0797 22M1(+E2) 0.33 33 8.0 11 +231PA2 G KC=6.1 14$LC=1.40 19$MC=0.35 6 +231PA G 145.06 4 0.0058 3 [E2] 2.46 3 +231PA2 G KC=0.237 4$LC=1.627 23$MC=0.448 7 +231PA G 145.94 2 0.0324 12M1+E2 0.82 28 5.1 8 +231PA2 G KC=3.4 10$LC=1.27 10$MC=0.33 4 +231PA G 163.101 4 0.156 5 M1(+E2) 0.2 2 4.9 4 +231PA2 G KC=3.9 4$LC=0.783 22$MC=0.190 9 +231PA G 169.66 3 0.00141 7 [E1] 0.1421 20 +231PA2 G KC=0.1113 16$LC=0.0233 4$MC=0.00564 8 +231PA G 188.76 2 0.0034 3 [E1] 0.1105 15 +231PA2 G KC=0.0869 13$LC=0.01782 25$MC=0.00431 6 +231PA L 317.95 4 (3/2)+ +231PA B 73.6 150.00078 5 8.76 2 +231PAS B EAV=18.9 4 +231PA G 240.27 5 0.00029 4 [E1] 0.0630 9 +231PA2 G KC=0.0500 7$LC=0.00984 14$MC=0.00237 4 +231PA G 308.78 7 3618E-7 18[E1] 0.0358 5 +231PA2 G KC=0.0287 4$LC=0.00544 8$MC=1306E-6 19 +231PA G 317.87 8 1005E-7 5 [E1] 0.0336 5 +231PA2 G KC=0.0269 4$LC=0.00508 8$MC=1221E-6 18 +231PA L 320.209 183/2- +231PA B 71.4 150.066 2 6.79 1U +231PAS B EAV=18.3 4 +231PA G 136.75 7 0.00442 15[E1] 0.237 3 +231PA2 G KC=0.184 3$LC=0.0404 6$MC=0.00981 14 +231PA G 217.94 3 0.0402 8 E1 0.0789 11 +231PA2 G KC=0.0624 9$LC=0.01248 18$MC=0.00301 5 +231PA G 236.01 3 0.0094 3 [E1] 0.0657 9 +231PA2 G KC=0.0521 8$LC=0.01028 15$MC=0.00248 4 +231PA G 242.50 4 0.00082 5 [M1+E2] 1.0 7 +231PA2 G KC=0.7 6$LC=0.22 4$MC=0.055 7 +231PA G 311.00 5 0.00315 14M1+E2 0.8 8 0.6 3 +231PA2 G KC=0.5 3$LC=0.11 3$MC=0.027 6 +231PA G 320.15 8 0.00015 3 [M1+E2] 0.5 4 +231PA2 G KC=0.34 27$LC=0.09 4$MC=0.023 7 +231PA L 351.84 4 (5/2)- +231PA B 39.8 150.0032 2 7.33 +231PAS B EAV=10.1 5 +231PA G 249.60 7 0.00080 7 [E1] 0.0578 8 +231PA2 G KC=0.0459 7$LC=0.00898 13$MC=0.00216 3 +231PA G 250.45 7 0.00067 7 [E1] 0.0573 8 +231PA2 G KC=0.0455 7$LC=0.00891 13$MC=0.00215 3 +231PA G 267.62 8 0.00141 14[E1] 0.0493 7 +231PA2 G KC=0.0393 6$LC=0.00760 11$MC=0.00183 3 +231PA G 274.1 1 3.4E-5 12[M1+E2] 0.7 5 +231PA2 G KC=0.5 4$LC=0.15 4$MC=0.038 8 +231PA G 351.8 1 6.7E-5 13[M1+E2] 0.35 25 +231PA2 G KC=0.26 21$LC=0.066 24$MC=0.016 6 + diff --git a/HEN_HOUSE/spectra/lnhb/Th-232.txt b/HEN_HOUSE/spectra/lnhb/Th-232.txt new file mode 100644 index 000000000..433bf91a7 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Th-232.txt @@ -0,0 +1,45 @@ +228RA 232TH A DECAY (14.02E9 Y) +228RA H TYP=Full$AUT=A. Arinc$CUT=30-APR-2009$ +228RA C Evaluation history: Type=Full;Author=A. Arinc;Cutoff date=30-APR-2009 +228RA C References: 1938Ko01, 1952Du12, 1956Ma43, 1956Al30, 1956Pi42, 1956Se17, +228RA2C 1957Ha08, 1959Ko58, 1960Be25, 1960Fa07, 1961Ko11, 1962Ko12, 1963Le21, +228RA3C 1973Ta25, 1982Sa36, 1983Mi30, 1983Ro23, 1989Sa01, 1990Ho28, 1991Ry01, +228RA4C 1995Bo18, 1996Sc06, 1997Ar08, 2002Ba85, 2003Au03, 2005KiWZ +228RA T Auger electrons and ^X ray energies and emission intensities: +228RA T {U Energy (keV)} {U Intensity } {U Line } +228RA T +228RA T 85.43 0.0017 5 XKA2 +228RA T 88.47 0.0028 8 XKA1 +228RA T +228RA T 99.432 |] XKB3 +228RA T 100.13 |] 0.00097 28 XKB1 +228RA T 100.738 |] XKB5II +228RA T +228RA T 102.89 |] XKB2 +228RA T 103.295 |] 0.00032 10 XKB4 +228RA T 103.74 |] XKO23 +228RA T +228RA T 10.6241-18.3539 7.2 3 XL (total) +228RA T 10.6241 0.141 8 XLL +228RA T 12.1957-12.3381 2.43 13 XLA +228RA T 13.6624 0.084 6 XLC +228RA T 14.2373-16.1261 3.66 20 XLB +228RA T 17.2756-18.3539 0.84 5 XLG +228RA T +228RA T 65.149-72.729 |] KLL AUGER +228RA T 79.721-88.466 |] 0.00019 6 ^KLX AUGER +228RA T 94.27-103.91 |] KXY AUGER +228RA T 5.71-19.09 8.18 29 L AUGER +232TH P 0.0 0+ 14.02E9 Y 6 4081.6 14 +228RA N 1.0 1.0 1 1.0 +228RA L 0 0+ 5.75 Y 3 +228RA A 4011.2 1478.9 131 +228RA L 63.823 202+ 0.55 NS 4 +228RA A 3948.5 1421.0 131.02 +228RA G 63.811 100.259 15E2 80.4 12 +228RA2 G KC=$LC=59.1 9$MC=16.05 23 +228RA L 204.68 3 4+ +228RA A 3810.0 140.068 2016 +228RA G 140.88 1 0.021 6 E2 2.26 4 +228RA2 G KC=0.283 4$LC=1.450 21$MC=0.394 6 + diff --git a/HEN_HOUSE/spectra/lnhb/Th-233.txt b/HEN_HOUSE/spectra/lnhb/Th-233.txt new file mode 100644 index 000000000..d55511826 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Th-233.txt @@ -0,0 +1,306 @@ +233PA 233TH B- DECAY (22.15 M) +233PA H TYP=Full$AUT=V. Chechev$CUT=31-JAN-2009$ +233PA C Evaluation history: Type=Full;Author=V. Chechev;Cutoff date=31-JAN-2009 +233PA C References: 1952Ru10, 1955Je26, 1957Dr46, 1957Fr55, 1968Da24, 1968Br25, +233PA2C 1969HoZY, 1969Va06, 1970Se06, 1972SeZI, 1972Vo08, 1972De67, 1976Sk01, +233PA3C 1976JeZU, 1979Go12, 1979Bo30, 1988Wo01, 1989Ab05, 1998Us01, 2003Au03, +233PA4C 2005Si15, 2008De31, 2008Ki07, 2008Go10, 2008De10 +233PA T Auger electrons and ^X ray energies and emission intensities: +233PA T {U Energy (keV)} {U Intensity } {U Line } +233PA T +233PA T 92.288 0.39 1 XKA2 +233PA T 95.869 0.615 13 XKA1 +233PA T +233PA T 107.595 |] XKB3 +233PA T 108.422 |] 0.235 6 XKB1 +233PA T 109.072 |] XKB5II +233PA T +233PA T 111.405 |] XKB2 +233PA T 111.87 |] 0.079 3 XKB4 +233PA T 112.38 |] XKO23 +233PA T +233PA T 11.366-21.6 8.2 9 XL (total) +233PA T 11.366 0.14 2 XLL +233PA T 13.122-13.291 2.84 32 XLA +233PA T 14.946 XLC +233PA T 15.3-16.7 4.3 5 XLB +233PA T 19.9-21.6 0.95 11 XLG +233PA T +233PA T 70.081-78.822 |] KLL AUGER +233PA T 88.03-95.56 |] 0.041 5 ^KLX AUGER +233PA T 101.78-112.4 |] KXY AUGER +233PA T 5.9-21.6 8.6 10 L AUGER +233TH P 0.0 1/2+ 22.15 M 8 1243.1 14 +233PA N 1.0 1.0 1 1.0 +233PA G 80 +233PA G 105.2 1 4100E-5 0 +233PA G 147.5 0.0018 6 +233PA G 211.3 2 0.0202 9 +233PA G 242.3 0.0029 6 +233PA G 309.9 0.0032 3 +233PA G 383.5 0.0019 6 +233PA G 408.8 5 0.0005 4 +233PA G 418.4 5 0.0091 7 +233PA G 454.2 5 4000E-5 0 +233PA G 464.8 0.0026 3 +233PA G 473.9 5 0.0033 7 +233PA G 497.1 4 0.0128 4 +233PA G 505.5 6 0.0055 3 +233PA G 513.4 4 0.0133 4 +233PA G 517.0 4 0.0046 3 +233PA G 531.8 4 0.0070 7 +233PA G 553.7 0.0030 3 +233PA G 554.9 0.0031 3 +233PA G 578.7 0.0017 5 +233PA G 583.2 0.0016 5 +233PA G 681.2 6 0.0143 4 +233PA G 690 0.0021 5 +233PA G 698.5 6 0.0106 5 +233PA G 703.7 6 0.0091 5 +233PA G 727.8 0.0029 2 +233PA G 744.9 5 0.0053 2 +233PA G 751.6 6 0.0023 4 +233PA G 767.5 0.0032 2 +233PA G 774.0 4 0.0108 5 +233PA G 784.2 5 0.0022 2 +233PA G 832.0 3 7500E-6 0 +233PA G 846.8 7 1300E-6 0 +233PA G 870.7 7 0.0031 2 +233PA G 874.0 5 0.00120 4 +233PA G 918.9 5 6000E-6 0 +233PA G 935.2 7 0.0369 7 +233PA G 941.9 8 0.0048 3 +233PA G 942.8 0.0019 3 +233PA G 955 1 0.0002 3 +233PA G 960.8 8 0.0041 2 +233PA G 962.8 9 0.0015 2 +233PA G 968.2 9 0.0083 3 +233PA G 994 1 0.0006 1 +233PA G 1001 1 0.0008 2 +233PA G 1007 1 0.0014 2 +233PA G 1011 1 0.0019 2 +233PA G 1026.5 107500E-6 0 +233PA G 1092.5 106000E-6 0 +233PA G 1132.1 0.0006 2 +233PA G 1139.1 0.0004 1 +233PA G 1144 1 2700E-6 0 +233PA G 1201 1 6000E-6 0 +233PA L 0 3/2- 26.98 D 2 +233PA B 1243.1 1434 6 6.2 1U +233PAS B EAV=413.8 6 +233PA L 6.65 5 1/2- +233PA B 1236.4 1450 6 6.1 +233PAS B EAV=411.2 6 +233PA G 6.65 5 0.0165 18(M1) 3080 60 +233PA2 G KC=$LC=$MC=2280 50 +233PA L 57.10 2 7/2- +233PA G 57.10 2 0.0498 15E2 176 4 +233PA2 G KC=$LC=128.4 26$MC=35.4 7 +233PA L 70.49 105/2- +233PA G 63.92 6 0.0007 3 (E2) 102.1 21 +233PA2 G KC=$LC=74.6 15$MC=20.6 4 +233PA G 70.49 100.0007 4 [M1+E2] 1 1 40 30 +233PA2 G KC=$LC=28 19$MC=7 6 +233PA L 86.477 105/2+ +233PA G 29.373 102.17 7 E1 3.07 6 +233PA2 G KC=$LC=2.29 5$MC=0.586 12 +233PA G 86.477 101.843 22E1 1.43 8 +233PA2 G KC=$LC=1.13 4$MC=0.22 6 +233PA L 94.65 5 3/2+ +233PA B 1148.4 1410.4 4 6.6 2 +233PAS B EAV=377.8 6 +233PA G 8.22 5 (M1+E2) +233PA G 87.99 3 0.1698 20[E1] 0.169 3 +233PA2 G KC=$LC=0.128 3$MC=0.0312 6 +233PA G 94.65 5 0.775 9 E1 0.140 3 +233PA2 G KC=$LC=0.105 2$MC=0.0257 5 +233PA L 103.8 1 7/2+ +233PA G 17.40 5 +233PA G 46.53 4 +233PA L 169.159 101/2+ +233PA B 1073.9 140.692 12 7.7 +233PAS B EAV=349.7 6 +233PA G 74.51 5 0.0402 17[M1] 9.85 20 +233PA2 G KC=$LC=7.43 15$MC=1.79 4 +233PA G 162.504 120.1674 26[E1] 0.157 3 +233PA2 G KC=0.123 3$LC=0.0260 5$MC=0.0063 1 +233PA G 169.162 100.251 4 [E1] 0.1431 29 +233PA2 G KC=0.1120 22$LC=0.0235 5$MC=0.00568 12 +233PA L 201.62 5 3/2+ +233PA B 1041.4 140.074 8 8.6 2 +233PAS B EAV=337.6 6 +233PA G 115.14 5 0.003 7 [M1+E2] 10 4 +233PA2 G KC=5 6$LC=3.4 13$MC=0.9 4 +233PA G 131.101 250.0508 13E1 0.262 5 +233PA2 G KC=0.202 4$LC=0.0451 9$MC=0.01094 22 +233PA G 194.97 7 0.1073 17E1 0.1024 20 +233PA2 G KC=0.0806 16$LC=0.0164 3$MC=0.00397 8 +233PA G 201.62 5 0.0221 8 E1 0.0946 19 +233PA2 G KC=0.0746 15$LC=0.0151 3$MC=0.00365 7 +233PA L 212.34 5 5/2+ +233PA G 108.5 1 6000E-7 0 M1+E2 0.22 22 3.5 6 +233PA2 G KC=0.00303 5$LC=2.7 5$MC=0.65 13 +233PA G 117.692 200.0029 3 M1+E2 0.30 9 12.2 4 +233PA2 G KC=9.3 5$LC=2.16 12$MC=0.53 4 +233PA G 141.74 10 +233PA G 155.239 200.00023 3 E1 0.176 4 +233PA2 G KC=0.137 3$LC=0.0292 6$MC=0.00708 10 +233PA G 212.34 5 0.0065 6 E1 0.0839 17 +233PA2 G KC=0.0662 12$LC=0.01331 26$MC=0.00321 6 +233PA L 237.86 2 5/2+ +233PA G 134.285 200.0018 5 [M1+E2] 0.4 4 8.0 14 +233PA2 G KC=6.1 17$LC=1.48 24$MC=0.37 8 +233PA G 143.23 2 0.0114 7 M1+E2 0.4 4 6.7 12 +233PA2 G KC=5.0 14$LC=1.21 16$MC=0.30 6 +233PA G 151.409 200.0067 3 [M1+E2] 0.69 20 4.9 6 +233PA2 G KC=3.4 7$LC=1.08 6$MC=0.276 19 +233PA G 180.76 3 0.00011 3 [E1] 0.1223 24 +233PA2 G KC=0.096 2$LC=0.0199 4$MC=0.0048 1 +233PA G 237.86 6 0.0019 4 [E1] 0.0645 13 +233PA2 G KC=0.0511 10$LC=0.0101 2$MC=0.00243 5 +233PA L 257.30 155/2- +233PA B 985.8 140.60 3 8.1 3U +233PAS B EAV=317.0 6 +233PA G 153.49 180.0407 7 [E1] 0.180 4 +233PA2 G KC=0.140 3$LC=0.0301 6$MC=0.00728 14 +233PA G 162.504 0.16000 0 [E1] 0.157 3 +233PA2 G KC=0.1230 18$LC=0.0260 5$MC=0.0063 1 +233PA G 170.60 6 0.507 9 [E1] 0.1403 28 +233PA2 G KC=0.1099 20$LC=0.0230 5$MC=0.00556 11 +233PA G 186.80 180.0209 9 [M1+E2] 2.2 13 +233PA2 G KC=1.5 13$LC=0.531 9$MC=0.137 10 +233PA G 250.65 160.0047 3 [E2] 0.317 6 +233PA2 G KC=0.1043 21$LC=0.156 3$MC=0.0423 8 +233PA G 257.30 150.0524 12[M1+E2] 1 1 0.8 6 +233PA2 G KC=0.6 6$LC=0.18 4$MC=0.045 7 +233PA L 447.762 203/2- +233PA B 795.3 140.821 14 7.2 1U +233PAS B EAV=247.8 5 +233PA G 190.552 140.0861 15M1 3.26 6 +233PA2 G KC=2.60 5$LC=0.499 10$MC=0.1204 24 +233PA G 246.14 6 0.0041 6 [E1] 0.0596 12 +233PA2 G KC=0.0473 9$LC=0.00929 19$MC=0.00224 4 +233PA G 278.7 4 0.0047 6 +233PA G 361.285 220.0218 6 [E1] 0.0255 5 +233PA2 G KC=0.0205 4$LC=0.00380 8$MC=9.12E-4 2 +233PA G 377.27 110.0275 9 [M1+E2] 0.3 3 0.46 8 +233PA2 G KC=0.36 7$LC=0.071 8$MC=0.0172 17 +233PA G 440.94 4 0.1912 23(M1+E2) 0.3 3 0.30 5 +233PA2 G KC=0.24 4$LC=0.046 6$MC=0.0111 13 +233PA G 447.762 200.1043 14[M1+E2] 0.27 27 0.29 4 +233PA2 G KC=0.23 4$LC=0.045 5$MC=0.0108 11 +233PA L 454.40 7 3/2+ +233PA B 788.7 140.217 13 7.7 2 +233PAS B EAV=245.5 5 +233PA G 216.54 8 0.0130 7 (M1+E2) 1 1 1.4 9 +233PA2 G KC=1.0 9$LC=0.32 4$MC=0.081 4 +233PA G 252.78 9 0.0066 3 [M1+E2] 0.4 4 1.3 3 +233PA2 G KC=1.0 3$LC=0.215 20$MC=0.052 4 +233PA G 285.24 7 0.0154 9 [M1+E2] 0.4 4 0.94 22 +233PA2 G KC=0.74 20$LC=0.152 18$MC=0.037 4 +233PA G 359.74 4 0.0869 12M1 0.559 11 +233PA2 G KC=0.446 9$LC=0.0848 19$MC=0.0204 4 +233PA G 367.92 7 0.0037 7 [M1] 0.525 10 +233PA2 G KC=0.420 8$LC=0.0797 16$MC=0.0192 4 +233PA L 553.88 6 1/2,3/2+ +233PA B 689.2 141.23 3 6.8 +233PAS B EAV=210.5 5 +233PA G 316.1 0.0037 4 E1 0.0340 7 +233PA2 G KC=0.0272 4$LC=0.00515 10$MC=0.00124 2 +233PA G 459.222 7 0.989 12M1 0.288 6 +233PA2 G KC=0.230 5$LC=0.0435 9$MC=0.01047 21 +233PA G 467.40 6 0.0144 4 [M1E2] 0.16 11 +233PA2 G KC=0.13 10$LC=0.029 13$MC=7000E-6 0 +233PA L 585.50 5 3/2+ +233PA B 657.6 140.15 3 7.6 2 +233PAS B EAV=199.6 5 +233PA G 347.64 6 0.0145 8 [M1] 0.613 12 +233PA2 G KC=0.49 1$LC=0.0932 18$MC=0.0224 5 +233PA G 490.80 6 0.1078 16M1 0.241 5 +233PA2 G KC=0.193 4$LC=0.0363 7$MC=0.00874 18 +233PA G 499.02 4 0.1576 21M1 0.230 5 +233PA2 G KC=0.184 3$LC=0.0347 5$MC=0.00835 12 +233PA L 669.9 5 (3/2)- +233PA B 573.2 140.0174 22 8.4 1U +233PAS B EAV=170.8 5 +233PA G 412.5 5 0.0083 7 [M1] 0.385 8 +233PA2 G KC=0.308 6$LC=0.0583 12$MC=0.0140 3 +233PA G 663.3 5 0.0037 5 [M1] 0.1075 22 +233PA2 G KC=0.0862 17$LC=0.0161 3$MC=0.00388 8 +233PA G 669.9 5 1800E-6 0 +233PA L 764.55 6 1/2,3/2+ +233PA B 478.5 141.19 3 6.3 +233PAS B EAV=139.5 5 +233PA G 179.05 8 0.0278 7 (M1+E2) 0.4 4 3.5 8 +233PA2 G KC=2.7 8$LC=0.602 15$MC=0.148 10 +233PA G 210.67 8 0.0178 11[M1+E2] 0.97 97 1.5 10 +233PA2 G KC=1.1 9$LC=0.35 3$MC=0.0890 21 +233PA G 526.69 6 0.0463 11[M1E2] 0.12 8 +233PA2 G KC=0.09 7$LC=0.02 1$MC=0.005 3 +233PA G 552.21 8 0.0165 5 (M1) 0.1754 35 +233PA2 G KC=0.1404 28$LC=0.0264 5$MC=0.00635 13 +233PA G 562.93 8 0.0545 7 [M1] 0.167 3 +233PA2 G KC=0.1334 27$LC=0.0251 5$MC=0.00603 12 +233PA G 595.39 6 0.1178 16(M1) 0.143 3 +233PA2 G KC=0.1148 22$LC=0.0216 4$MC=0.00518 10 +233PA G 669.901 160.504 6 [M1] 0.1047 21 +233PA2 G KC=0.0839 17$LC=0.0157 3$MC=0.00377 8 +233PA G 678.04 100.0647 9 [M1E2] 0.06 4 +233PA2 G KC=0.05 4$LC=0.010 5$MC=0.0025 12 +233PA G 757.90 7 0.0324 7 +233PA G 764.55 6 0.0891 13 +233PA L 811.6 2 (3/2)+ +233PA B 431.5 140.385 4 6.6 2 +233PAS B EAV=124.3 5 +233PA G 226.1 2 0.0171 7 M1+(E2) 2.02 4 +233PA2 G KC=1.61 3$LC=0.308 6$MC=0.0743 15 +233PA G 573.7 4 0.0332 10[M1] 0.158 3 +233PA2 G KC=0.1268 25$LC=0.0238 5$MC=0.00573 12 +233PA G 599.3 2 0.0294 5 [M1] 0.141 3 +233PA2 G KC=0.1129 22$LC=0.0212 4$MC=0.00509 10 +233PA G 610.0 3 0.0567 12[M1] 0.134 3 +233PA2 G KC=0.1077 20$LC=0.0202 4$MC=0.00485 9 +233PA G 642.4 2 0.0202 5 [M1] 0.1171 23 +233PA2 G KC=0.0938 19$LC=0.0176 4$MC=0.00422 8 +233PA G 707.8 3 0.0091 5 [E2] 0.0209 4 +233PA2 G KC=0.0148 3$LC=0.00455 9$MC=0.00115 2 +233PA G 717.0 2 0.0421 9 (M1) 0.0874 17 +233PA2 G KC=0.0701 14$LC=0.0131 3$MC=0.00314 6 +233PA G 725.1 2 0.0633 10(M1) 0.0848 17 +233PA2 G KC=0.068 1$LC=0.01271 25$MC=0.00305 6 +233PA G 741.1 2 0.0236 5 [E1] 0.0061512 +233PA2 G KC=0.00502 10$LC=8.60E-4 17$MC=2.04E-4 4 +233PA G 805.0 2 0.0214 6 [E1] 0.0052911 +233PA2 G KC=0.00432 9$LC=0.00073 2$MC=1.74E-4 4 +233PA G 811.6 2 0.0060 2 [E1] 0.0052110 +233PA2 G KC=0.00426 9$LC=7.20E-4 15$MC=1.71E-4 4 +233PA L 984.8 5 (3/2)+ +233PA B 258.3 140.205 2 6.2 2 +233PAS B EAV=70.8 4 +233PA G 398.8 5 0.0111 7 [M1] 0.422 8 +233PA2 G KC=0.337 7$LC=0.0639 13$MC=0.0154 3 +233PA G 430.9 4 0.0178 4 (M1) 0.342 6 +233PA2 G KC=0.273 5$LC=0.0517 10$MC=0.01245 24 +233PA G 783.2 5 0.0056 3 [M1] 0.0692 14 +233PA2 G KC=0.05550 11$LC=0.01034 20$MC=0.00248 5 +233PA G 815.9 4 0.0195 6 [M1] 0.0621 12 +233PA2 G KC=0.0498 10$LC=0.0093 2$MC=0.00223 5 +233PA G 880.9 5 0.0097 4 E2 0.0135 3 +233PA2 G KC=0.0100 2$LC=0.00258 5$MC=6.40E-4 13 +233PA G 890.1 5 0.1052 14[M1] 0.0493 10 +233PA2 G KC=0.0396 8$LC=0.00735 15$MC=0.00176 4 +233PA G 898.3 5 0.0022 4 [M1] 0.0481 10 +233PA2 G KC=0.0386 8$LC=0.00717 14$MC=0.00172 3 +233PA G 978.2 5 0.0058 3 [E1] 0.003747 +233PA2 G KC=0.00306 6$LC=0.00051 1$MC=1.21E-4 2 +233PA G 984.8 5 0.0102 3 [E1] 0.003697 +233PA2 G KC=0.00303 6$LC=0.00051 1$MC=1.20E-4 2 +233PA L 1018.7 5 (3/2)+ +233PA B 224.4 140.0434 9 6.7 2 +233PAS B EAV=60.9 4 +233PA G 433.2 4 0.0117 4 +233PA G 806.4 5 0.0123 5 +233PA G 817.0 6 0.0095 5 +233PA G 849.5 5 0.0039 3 +233PA G 948.3 5 0.0060 3 + diff --git a/HEN_HOUSE/spectra/lnhb/Th-234.txt b/HEN_HOUSE/spectra/lnhb/Th-234.txt new file mode 100644 index 000000000..f36648bff --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Th-234.txt @@ -0,0 +1,79 @@ +234PA 234TH B- DECAY (24.10 D) +234PA H TYP=Update$AUT=A.Luca$CUT= -- $ +234PA2 H TYP=Full$AUT=A. Luca$CUT=31-DEC-2008$ +234PA C Evaluation history: Type=Update;Author=A.Luca;Cutoff date= -- +234PA2C Type=Full;Author=A. Luca;Cutoff date=31-DEC-2008 +234PA C References: 1920KI01, 1931CU01, 1939SA11, 1948KN23, 1961GE13, 1962BR05, +234PA2C 1963BJ02, 1964AB04, 1965FO12, 1973TA25, 1973GO40, 1973SA33, 1978CH06, +234PA3C 1982MO30, 1990SC09, 1990CO08, 1993SU37, 1998AD08, 2003Au03, 2004AB03, +234PA4C 2006AL28, 2007BR04 +234PA T Auger electrons and ^X ray energies and emission intensities: +234PA T {U Energy (keV)} {U Intensity } {U Line } +234PA T +234PA T 92.288 0.013 9 XKA2 +234PA T 95.869 0.021 13 XKA1 +234PA T +234PA T 107.595 |] XKB3 +234PA T 108.422 |] 0.007 5 XKB1 +234PA T 109.072 |] XKB5II +234PA T +234PA T 111.405 |] XKB2 +234PA T 111.87 |] 0.0025 16 XKB4 +234PA T 112.38 |] XKO23 +234PA T +234PA T 11.3676-20.1126 7.1 3 XL (total) +234PA T 11.3676 0.178 12 XLL +234PA T 13.1215-13.2887 2.92 18 XLA +234PA T 14.9488 0.0423 29 XLC +234PA T 15.3584-17.6655 3.21 13 XLB +234PA T 18.9396-20.1126 0.766 29 XLG +234PA T +234PA T 70.081-78.822 |] KLL AUGER +234PA T 85.989-95.858 |] 0.0014 9 ^KLX AUGER +234PA T 101.87-112.59 |] KXY AUGER +234PA T 5.9-21.6 7.7 6 L AUGER +234TH P 0.0 0+ 24.10 D 3 272 10 +234PA N 1.0 1.0 1 1.0 +234PA L 0 4+ 6.70 H 5 +234PA L 73.92 (0)- 1.159 M 11 +234PA B 198 1077.8 15 6.4 +234PAS B EAV=53 3 +234PA G 73.92 2 0.0133 14M1+E2 0.11 3 10.6 4 +234PA2 G KC=$LC=7.96 25$MC=1.94 7 +234PA L 73.92 2 (3)+ +234PA B 198 1077.8 15 6.4 2U +234PAS B EAV=53 3 +234PA G 73.92 2 0.0133 14M1+E2 0.11 3 10.6 4 +234PA2 G KC=$LC=7.96 25$MC=1.94 7 +234PA L 103.42 (2)- 0.5 NS +234PA G 29.50 2 0.00123 14E2 4390 70 +234PA2 G KC=$LC=3210 50$MC=880 13 +234PA L 166.3 (1)- 0.1 NS +234PA B 106 1014.1 12 6.3 1 +234PAS B EAV=28 3 +234PA G 62.88 2 0.0164 28M1+E2 0.33 8 25 5 +234PA2 G KC=$LC=19 4$MC=4.8 9 +234PA G 92.38 1 2.18 19M1 5.27 8 +234PA2 G KC=$LC=3.98 6$MC=0.960 14 +234PA L 166.72 (1)+ 0.55 NS 10 +234PA B 105 106.5 7 6.7 +234PAS B EAV=27 3 +234PA G 63.30 2 3.75 8 E1 0.405 6 +234PA2 G KC=$LC=0.305 5$MC=0.0749 11 +234PA G 92.80 2 2.15 19E1 0.1472 21 +234PA2 G KC=$LC=0.1110 16$MC=0.0271 4 +234PA L 177.27 1- +234PA B 95 100.016 5 9.1 1 +234PAS B EAV=25 3 +234PA G 103.35 100.0032 10M1 3.81 6 +234PA2 G KC=$LC=2.88 5$MC=0.694 10 +234PA L 186.73 (1)+ +234PA B 85 101.6 6 7 +234PAS B EAV=22 3 +234PA G 20.01 2 0.0051 21M1+E2 0.08 2 240 70 +234PA2 G KC=$LC=70 40$MC=124 21 +234PA G 83.31 5 0.061 5 E1 0.196 3 +234PA2 G KC=$LC=0.1475 21$MC=0.0361 5 +234PA G 112.81 5 0.215 22E1 0.23 14 +234PA2 G KC=0.21 13$LC=0.0666 10$MC=0.01620 23 + diff --git a/HEN_HOUSE/spectra/lnhb/Ti-44.txt b/HEN_HOUSE/spectra/lnhb/Ti-44.txt new file mode 100644 index 000000000..58fc11ef3 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Ti-44.txt @@ -0,0 +1,35 @@ + 44SC 44TI EC DECAY (60.0 Y) + 44SC T Auger electrons and ^X ray energies and emission intensities: + 44SC T {U Energy (keV)} {U Intensity } {U Line } + 44SC T + 44SC T 4.0862 5.76 18 XKA2 + 44SC T 4.0906 11.4 4 XKA1 + 44SC T + 44SC T 4.4604 |] 2.26 8 XKB1 + 44SC T 4.4866 |] XKB5II + 44SC T + 44SC T + 44SC T 0.348-0.468 0.45 9 XL (total) + 44SC T 0.348 XLL + 44SC T -0.468 XLG + 44SC T + 44SC T 3.45-3.65 |] KLL AUGER + 44SC T 3.93-4.08 |] 79.5 21 ^KLX AUGER + 44SC T 4.38-4.48 |] KXY AUGER + 44SC T 0.3-0.5 167.5 24 L AUGER + 44TI P 0.0 0+ 60.0 Y 11 267.5 19 + 44SC N 1.0 1.0 1 1.0 + 44SC L 0 2+ 3.97 H 4 + 44SC L 67.8680 141- 154.2 NS 8 + 44SC E 0.4 119.3 1 + 44SC2 E EAV= $CK=0.8917 19$CL=0.0938 16$CM=0.0145 7$CN= $CO= + 44SC G 67.8679 1493.0 15E1 0.0845 25 + 44SC2 G KC=0.0766 23$LC=6650E-6 0$MC=1250E-6 0 + 44SC L 146.22 3 0- 50.4 US 7 + 44SC E 99.6 116.5 + 44SC2 E EAV= $CK=0.8891 20$CL=0.0960 16$CM=0.0149 7$CN= $CO= + 44SC G 78.36 3 96.4 11M1 0.032 1 + 44SC2 G KC=0.0273 8$LC=2440E-6 0$MC=4600E-7 0 + 44SC G 146.22 3 0.092 3 [M2] 0.046 1 + 44SC2 G KC=0.0414 12$LC=3850E-6 0$MC=7500E-7 0 + diff --git a/HEN_HOUSE/spectra/lnhb/Tl-201.txt b/HEN_HOUSE/spectra/lnhb/Tl-201.txt new file mode 100644 index 000000000..15b83f0c6 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Tl-201.txt @@ -0,0 +1,61 @@ +201HG 201TL EC DECAY (3.0421 D) +201HG T Auger electrons and ^X ray energies and emission intensities: +201HG T {U Energy (keV)} {U Intensity } {U Line } +201HG T +201HG T 68.895 27.3 5 XKA2 +201HG T 70.82 46.4 7 XKA1 +201HG T +201HG T 79.823 |] XKB3 +201HG T 80.254 |] 15.7 4 XKB1 +201HG T 80.762 |] XKB5II +201HG T +201HG T 82.435 |] XKB2 +201HG T 82.776 |] 4.61 13 XKB4 +201HG T 83.028 |] XKO23 +201HG T +201HG T 8.72-14.85 42.7 18 XL (total) +201HG T 8.72 0.88 15 XLL +201HG T 9.898-9.989 17.1 27 XLA +201HG T 10.651 0.26 6 XLC +201HG T 11.563-12.56 14.9 21 XLB +201HG T 13.41-14.85 2.8 5 XLG +201HG T +201HG T 53.178-58.277 |] KLL AUGER +201HG T 64.594-68.43 |] 3.7 4 ^KLX AUGER +201HG T 75.98-83.09 |] KXY AUGER +201HG T 5.1-14.8 57.7 7 L AUGER +201TL P 0.0 1/2+ 3.0421 D 17 483 15 +201HG N 1.0 1.0 1 1.0 +201HG L 0 3/2- STABLE +201HG E 21 216.5 1U +201HG2 E EAV= $CK=0.763 3$CL=0.178 3$CM=0.0451 12$CN= $CO= +201HG L 1.565 1/2- +201HG E 25 226.5 +201HG2 E EAV= $CK=0.763 3$CL=0.178 3$CM=0.0451 12$CN= $CO= +201HG G 1.565 6 0.00081 47M1+E2 0.0105 15 4.7E4 7 +201HG2 G KC=$LC=$MC= +201HG L 26.269 5/2- 630 PS +201HG E 0.23 8.5 3U +201HG2 E EAV= $CK= $CL= $CM= $CN= $CO= +201HG G 26.269 7 0.0082 9 M1(+E2) 0.02 76.9 23 +201HG2 G KC=$LC=58.8 18$MC=13.74 41 +201HG L 32.138 3/2- 0.2 NS +201HG E 13.0 5 6.9 1U +201HG2 E EAV= $CK=0.758 3$CL=0.181 3$CM=0.0461 12$CN= $CO= +201HG G 5.869 260.50000 0 [M1+E2] +201HG G 30.573 170.258 5 M1+E2 0.011 4 48.5 2 +201HG2 G KC=$LC=36.9 4$MC=8.79 26 +201HG G 32.138 160.263 5 M1+E2 0.017 40 41.9 2 +201HG2 G KC=$LC=32.0 4$MC=7.62 23 +201HG L 167.45 1/2- 2 NS +201HG E 40.9 9 6.1 +201HG2 E EAV= $CK=0.724 7$CL=0.206 7$CM=0.054 2$CN= $CO= +201HG G 135.312 342.604 22M1+E2 -0.06 1 3.45 10 +201HG2 G KC=2.83 3$LC=0.48 5$MC=0.1138 34 +201HG G 141.18 4 8000E-6 0 [E2] 1.41 4 +201HG2 G KC=0.372 11$LC=0.774 23$MC=0.202 6 +201HG G 165.885 310.147 2 M1(+E2) 0.4 1.86 8 +201HG2 G KC=1.57 3$LC=0.270 5$MC=0.0634 19 +201HG G 167.45 3 10.0 1 M1+E2 0.08 1.89 8 +201HG2 G KC=1.55 3$LC=0.262 5$MC=0.0620 19 + diff --git a/HEN_HOUSE/spectra/lnhb/Tl-204.txt b/HEN_HOUSE/spectra/lnhb/Tl-204.txt new file mode 100644 index 000000000..0b9f03698 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Tl-204.txt @@ -0,0 +1,53 @@ +204HG 204TL EC DECAY (3.788 Y) +204HG T Auger electrons and ^X ray energies and emission intensities: +204HG T {U Energy (keV)} {U Intensity } {U Line } +204HG T +204HG T 68.895 0.474 20 XKA2 +204HG T 70.82 0.812 34 XKA1 +204HG T +204HG T 79.823 |] XKB3 +204HG T 80.254 |] 0.273 10 XKB1 +204HG T 80.762 |] XKB5II +204HG T +204HG T 82.435 |] XKB2 +204HG T 82.776 |] 0.081 3 XKB4 +204HG T 83.028 |] XKO23 +204HG T +204HG T 8.721-14.847 0.787 20 XL (total) +204HG T 8.721 0.0202 8 XLL +204HG T 9.898-9.989 0.395 14 XLA +204HG T 10.647 0.00488 22 XLC +204HG T 11.924-11.822 0.315 9 XLB +204HG T -14.847 0.0574 18 XLG +204HG T +204HG T 53.17-58.28 |] KLL AUGER +204HG T 64.59-70.81 |] 0.065 8 ^KLX AUGER +204HG T 75.92-83.08 |] KXY AUGER +204HG T 5.1-14.8 1.48 3 L AUGER +204TL P 0.0 2- 3.788 Y 15 345.0 13 +204HG N 3.425E1 3.425E1 0.0292 3.425E1 +204HG L 0 0+ STABLE +204HG E 2.92 139.6 1U +204HG2 E EAV= $CK=0.5843 14$CL=0.3024 10$CM=0.1133 5$CN= $CO= + +204PB 204TL B- DECAY (3.788 Y) +204PB T Auger electrons and ^X ray energies and emission intensities: +204PB T {U Energy (keV)} {U Intensity } {U Line } +204PB T +204PB T 72.8049 0.0044 3 XKA2 +204PB T 74.97 0.0061 3 XKA1 +204PB T +204PB T 84.451 |] XKB3 +204PB T 84.937 |] 0.0027 2 XKB1 +204PB T 85.47 |] XKB5II +204PB T +204PB T 87.238 |] XKB2 +204PB T 87.58 |] 0.00073 2 XKB4 +204PB T 87.911 |] XKO23 +204PB T +204TL P 0.0 2- 3.788 Y 15 763.72 18 +204PB N 1.03E0 1.03E0 0.9708 1.03E0 +204PB L 0 0+ STABLE +204PB B 763.7 2 97.08 13 10.1 1U +204PBS B EAV=243.9 1 + diff --git a/HEN_HOUSE/spectra/lnhb/Tl-206.txt b/HEN_HOUSE/spectra/lnhb/Tl-206.txt new file mode 100644 index 000000000..f840f1e8e --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Tl-206.txt @@ -0,0 +1,46 @@ +206PB 206TL B- DECAY (4.202 M) +206PB H TYP=Full$AUT=F. Kondev$CUT=01-OCT-2006$ +206PB C Evaluation history: Type=Full;Author=F. Kondev;Cutoff date=01-OCT-2006 +206PB C References: 1977La19, 2002Ba85, 2003Au03, 2005KiZW +206PB T Auger electrons and ^X ray energies and emission intensities: +206PB T {U Energy (keV)} {U Intensity } {U Line } +206PB T +206PB T 72.8049 0.026 3 XKA2 +206PB T 74.97 0.044 5 XKA1 +206PB T +206PB T 84.451 |] XKB3 +206PB T 84.937 |] 0.0150 17 XKB1 +206PB T 85.47 |] XKB5II +206PB T +206PB T 87.238 |] XKB2 +206PB T 87.58 |] 0.0045 6 XKB4 +206PB T 87.911 |] XKO23 +206PB T +206PB T 9.19-15.217 0.035 4 XL (total) +206PB T 9.19 XLL +206PB T 10.449-10.551 XLA +206PB T 11.349 XLC +206PB T 12.144-12.795 XLB +206PB T 14.308-15.217 XLG +206PB T +206PB T 56.028-61.669 |] KLL AUGER +206PB T 68.181-74.969 |] 0.0034 6 ^KLX AUGER +206PB T 80.3-88 |] KXY AUGER +206PB T 5.2-15.7 L AUGER +206TL P 0.0 0- 4.202 M 11 1532.4 6 +206PB N 1.0 1.0 1 1.0 +206PB L 0 0+ STABLE +206PB B 1532.4 6 99.885 14 5.2 +206PBS B EAV=538.86 25 +206PB L 803.06 3 2+ 8.14 PS 8 +206PB B 729.3 6 0.0051 3 8.6 1U +206PBS B EAV=232.39 21 +206PB G 803.06 3 0.0050 3 E2 0.0103031 +206PB2 G KC=0.00801 24$LC=0.00174 5$MC=4.19E-4 13 +206PB L 1166.4 5 0+ 0.75 NS 4 +206PB B 366.0 8 0.110 14 6 +206PBS B EAV=104.52 25 +206PB G 363.3 5 0.00014 14E2 0.0663 20 +206PB2 G KC=0.0414 12$LC=0.0187 6$MC=0.00476 14 +206PB G 1165 2 + diff --git a/HEN_HOUSE/spectra/lnhb/Tl-207.txt b/HEN_HOUSE/spectra/lnhb/Tl-207.txt new file mode 100644 index 000000000..d357a9f84 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Tl-207.txt @@ -0,0 +1,51 @@ +207PB 207TL B- DECAY (4.774 M) +207PB H TYP=Full$AUT=F.Kondev$CUT=12-DEC-2010$ +207PB C Evaluation history: Type=Full;Author=F.Kondev;Cutoff date=12-DEC-2010 +207PB C References: 1931Cu01, 1940Fa04, 1950Ev03, 1953Sa11, 1961Cu05, 1963Ch09, +207PB2C 1967Da10, 1967Tr01, 1968Br17, 1970Kl03, 1971Go40, 1972Ha59, 1973Ba38, +207PB3C 1974Ha34, 1976Av01, 1977La19, 1988Hi14, 1991Ar04, 1996Sc06, 1998ScZM, +207PB4C 1999ScZX, 2000Sc47, 2000He14, 2003De44, 2003Au03, 2008Ki07, 2008DuZX, +207PB5C 2011Ko04 +207PB T Auger electrons and ^X ray energies and emission intensities: +207PB T {U Energy (keV)} {U Intensity } {U Line } +207PB T +207PB T 72.8049 0.00154 6 XKA2 +207PB T 74.97 0.00258 10 XKA1 +207PB T +207PB T 84.451 |] XKB3 +207PB T 84.937 |] 0.00088 4 XKB1 +207PB T 85.47 |] XKB5II +207PB T +207PB T 87.238 |] XKB2 +207PB T 87.58 |] 0.000266 12 XKB4 +207PB T 87.911 |] XKO23 +207PB T +207PB T 9.186-15.2169 0.00201 6 XL (total) +207PB T 9.186 0.0000500 19 XLL +207PB T 10.4495-10.5512 0.00095 4 XLA +207PB T 11.3495 0.0000150 7 XLC +207PB T 12.1443-13.3763 0.000841 24 XLB +207PB T 14.3078-15.2169 0.000159 5 XLG +207PB T +207PB T 56.028-61.669 |] KLL AUGER +207PB T 68.181-74.969 |] 0.000202 23 ^KLX AUGER +207PB T 80.3-88 |] KXY AUGER +207PB T 5.33-15.82 0.00333 6 L AUGER +207TL P 0.0 1/2+ 4.774 M 12 1418 5 +207PB N 1.0 1.0 1 1.0 +207PB L 0 0 1/2- STABLE +207PB B 1418 5 99.729 10 5.11 +207PBS B EAV=492.5 21 +207PB L 569.6982 205/2- +207PB B 848 5 0.00008 10.8 3U +207PBS B EAV=273.2 18 +207PB G 569.698 2 0.00185 19E2 0.0216 3 +207PB2 G KC=0.01584 23$LC=0.00439 7$MC=1081E-6 16 +207PB L 897.698 173/2- +207PB B 520 5 0.271 10 6.15 1U +207PBS B EAV=155.0 17 +207PB G 328.10 120.00142 14[M1] 0.334 5 +207PB2 G KC=0.273 4$LC=0.0466 7$MC=0.01090 16 +207PB G 897.77 120.263 9 M1+E2 0.091 9000 0.0233 4 +207PB2 G KC=0.0192 3$LC=0.00318 5$MC=7.41E-4 11 + diff --git a/HEN_HOUSE/spectra/lnhb/Tl-208.txt b/HEN_HOUSE/spectra/lnhb/Tl-208.txt new file mode 100644 index 000000000..927182f1d --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Tl-208.txt @@ -0,0 +1,142 @@ +208PB 208TL B- DECAY (3.058 M) +208PB H TYP=Update$AUT=A.L. Nichols$CUT=30-MAY-2011$ +208PB2 H TYP=Full$AUT=A.L. Nichols$CUT=30-AUG-2001$ +208PB C Evaluation history: Type=Update;Author=A.L. Nichols;Cutoff date=30-MAY-2011 +208PB2C Type=Full;Author=A.L. Nichols;Cutoff date=30-AUG-2001 +208PB C References: 1954El07, 1957Ba05, 1957Kr56, 1957Vo22, 1960Em01, 1960Sc07, +208PB2C 1961Si11, 1963Da11, 1967Os01, 1967La20, 1969La23, 1969Au10, 1969Pa02, +208PB3C 1970Mu21, 1971Ac02, 1972Ja25, 1972DaZA, 1973Da38, 1975Ko02, 1976Av03, +208PB4C 1977Ge12, 1977La19, 1978Av01, 1982Sa36, 1983Va22, 1983Sc13, 1984Ge07, +208PB5C 1990Go33, 1992Li05, 1993El08, 1996Sc06, 1997Sc21, 1998ScZM, 1999ScZX, +208PB6C 2000He14, 2002Ba85, 2002Ra45, 2003Au03, 2006Va23, 2007Ma45, 2008Ki07 +208PB T Auger electrons and X ray energies and emission intensities: +208PB T {U Energy (keV)} {U Intensity} {U Line} +208PB T +208PB T 72.8049 2.03 5 XKA2 +208PB T 74.97 3.42 7 XKA1 +208PB T +208PB T 84.451 |] XKB3 +208PB T 84.937 |] 1.17 3 XKB1 +208PB T 85.47 |] XKB5II +208PB T +208PB T 87.238 |] XKB2 +208PB T 87.58 |] 0.353 11 XKB4 +208PB T 87.911 |] XKO23 +208PB T +208PB T 9.184-15.216 2.75 12 XL (total) +208PB T 9.184 0.0671 19 XLL +208PB T 10.45-10.551 1.27 4 XLA +208PB T 11.349 0.0209 7 XLC +208PB T 12.142-13.015 1.155 25 XLB +208PB T 14.765-15.216 0.220 5 XLG +208PB T +208PB T 56.028-61.669 |] KLL AUGER +208PB T 68.181-74.969 |] 0.27 3 KLX AUGER +208PB T 80.3-88 |] KXY AUGER +208PB T 5.262-10.398 4.50 13 L AUGER +208TL P 0.0 5+ 3.058 M 6 4999.0 17 +208PB N 1.0 1.0 1 1.0 +208PB G 808.32 130.030 7 +208PB G 835.90 110.076 11 +208PB L 0 0+ STABLE +208PB L 2614.552 103- +208PB G 2614.511 1099.755 4 E3 0.002464 +208PB2 G KC=1708E-6 24$LC=2.92E-4 4$MC=6.85E-5 10 +208PB L 3197.711 105- +208PB B 1801.3 1749.2 6 5.61 +208PBS B EAV=649.5 7 +208PB G 583.187 2 85.0 3 E2 0.0205 3 +208PB2 G KC=0.01509 22$LC=0.00410 6$MC=1009E-6 15 +208PB L 3475.078 114- +208PB B 1523.9 1722.1 5 5.69 1 +208PBS B EAV=535.4 7 +208PB G 277.37 2 6.6 3 [M1+E2] 0.02 1 0.529 8 +208PB2 G KC=0.432 6$LC=0.0739 11$MC=0.01730 25 +208PB G 860.53 2 12.4 1 [M1+E2] 0.015 0.0262 4 +208PB2 G KC=0.0215 3$LC=0.00356 5$MC=8.31E-4 12 +208PB L 3708.451 125- +208PB B 1290.5 1724.1 2 5.38 +208PBS B EAV=441.5 7 +208PB G 233.37 2 0.31 1 [M1+E2] 0.70 7 0.66 3 +208PB2 G KC=0.51 3$LC=0.1136 18$MC=0.0275 4 +208PB G 510.74 2 22.5 2 [M1+E2] -0.05 5 0.1019 16 +208PB2 G KC=0.0835 13$LC=0.01406 21$MC=0.00329 5 +208PB G 1093.90 2 0.44 1 E2 0.005608 +208PB2 G KC=0.00449 7$LC=8.44E-4 12$MC=2.00E-4 3 +208PB L 3919.966 136- +208PB B 1079.0 170.63 4 6.68 1 +208PBS B EAV=358.6 7 +208PB G 211.52 2 0.18 1 M1+E2 0.18 2 1.096 17 +208PB2 G KC=0.890 14$LC=0.1570 22$MC=0.0369 6 +208PB G 722.26 2 0.24 4 M1+E2 0.31 3 0.0387 7 +208PB2 G KC=0.0317 6$LC=0.00534 10$MC=1248E-6 22 +208PB L 3946.578 144- +208PB B 1052.4 170.048 3 7.76 1 +208PBS B EAV=348.4 7 +208PB G 748.87 2 0.046 3 [M1] 0.0375 6 +208PB2 G KC=0.0308 5$LC=0.00512 8$MC=1196E-6 17 +208PB L 3961.162 135- +208PB B 1037.8 173.17 4 5.92 +208PBS B EAV=342.8 7 +208PB G 252.71 2 0.78 2 [M1+E2] -0.40 4 0.616 15 +208PB2 G KC=0.495 14$LC=0.0926 14$MC=0.0220 4 +208PB G 486.08 2 0.049 4 [M1] 0.1164 17 +208PB2 G KC=0.0954 14$LC=0.01608 23$MC=0.00376 6 +208PB G 763.45 2 1.80 2 [M1+E2] -0.10 1 0.0354 5 +208PB2 G KC=0.0291 4$LC=0.00484 7$MC=1130E-6 16 +208PB L 3995.438 134- +208PB B 1003.6 170.007 3 8.5 1 +208PBS B EAV=329.7 7 +208PB G 1380.89 2 0.007 3 [M1] 0.0078511 +208PB2 G KC=0.00643 9$LC=1050E-6 15$MC=2.45E-4 4 +208PB L 4125.347 125- +208PB B 873.7 170.174 9 6.92 +208PBS B EAV=280.8 6 +208PB G 650.27 2 0.041 5 [M1] 0.0541 8 +208PB2 G KC=0.0444 7$LC=0.00742 11$MC=1733E-6 25 +208PB G 927.64 2 0.128 7 [M1] 0.0216 3 +208PB2 G KC=0.01774 25$LC=0.00293 5$MC=6.84E-4 10 +208PB L 4180.414 145- +208PB B 818.6 170.231 9 6.7 +208PBS B EAV=260.4 6 +208PB G 705.34 2 0.022 4 [M1] 0.0438 7 +208PB2 G KC=0.0360 5$LC=0.00599 9$MC=1399E-6 20 +208PB G 982.70 2 0.204 8 [M1] 0.0186 3 +208PB2 G KC=0.01530 22$LC=0.00253 4$MC=5.89E-4 9 +208PB L 4261.871 134- +208PB B 737.1 170.002 1 8.6 1 +208PBS B EAV=230.8 6 +208PB G 1647.32 2 0.002 1 [M1] 0.005188 +208PB2 G KC=0.00411 6$LC=6.69E-4 10$MC=1556E-7 22 +208PB L 4296.560 135- +208PB B 702.4 170.102 11 6.82 +208PBS B EAV=218.3 6 +208PB G 588.108 180.06 1 [M1] 0.0704 10 +208PB2 G KC=0.0577 8$LC=0.00968 14$MC=0.00226 4 +208PB G 821.48 2 0.041 4 M1 0.0295 5 +208PB2 G KC=0.0242 4$LC=0.00402 6$MC=9.39E-4 14 +208PB L 4323.946 144+ +208PB B 675.1 170.005 2 8.1 +208PBS B EAV=208.6 6 +208PB G 1126.24 2 0.005 2 E1 0.002033 +208PB2 G KC=1691E-6 24$LC=2.56E-4 4$MC=5.90E-5 9 +208PB L 4358.670 134- +208PB B 640.3 170.045 4 7.04 1 +208PBS B EAV=196.4 6 +208PB G 883.59 2 0.031 3 [M1] 0.0244 4 +208PB2 G KC=0.0201 3$LC=0.00333 5$MC=7.76E-4 11 +208PB G 1160.96 2 0.011 3 [M1] 0.0121417 +208PB2 G KC=0.01000 14$LC=1641E-6 23$MC=3.82E-4 6 +208PB G 1744.120 160.002 1 M1+E2 0.004577 +208PB2 G KC=0.00356 5$LC=5.78E-4 8$MC=1344E-7 19 +208PB L 4383.285 176- +208PB B 615.7 170.017 5 7.41 1 +208PBS B EAV=187.7 6 +208PB G 1185.57 2 0.017 5 [M1] 0.0115117 +208PB2 G KC=0.00947 14$LC=1555E-6 22$MC=3.62E-4 5 +208PB L 4480.746 166- +208PB B 518.3 170.052 5 6.67 1 +208PBS B EAV=154.3 6 +208PB G 1283.04 2 0.052 5 [M1] 0.0094314 +208PB2 G KC=0.00775 11$LC=1269E-6 18$MC=2.95E-4 5 + diff --git a/HEN_HOUSE/spectra/lnhb/Tl-209.txt b/HEN_HOUSE/spectra/lnhb/Tl-209.txt new file mode 100644 index 000000000..978251fc2 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Tl-209.txt @@ -0,0 +1,102 @@ +209PB 209TL B- DECAY (2.161 M) +209PB H TYP=Full$AUT=F.G. Kondev$CUT=30-MAY-2011$ +209PB C Evaluation history: Type=Full;Author=F.G. Kondev;Cutoff date=30-MAY-2011 +209PB C References: 1950Ha64, 1971Go40, 1977Vy02, 1980Da15, 1981Di14, 1986He06, +209PB2C 1989Ko26, 1991Ma16, 1993El08, 1996Sc06, 1998ScZM, 1998Ar03, 1999GrZT, +209PB3C 1999ScZX, 2000Sc47, 2000Gr35, 2003Au03, 2003De44, 2003ChZV, 2008Ki07, +209PB4C 2008DuZX +209PB T Auger electrons and ^X ray energies and emission intensities: +209PB T {U Energy (keV)} {U Intensity } {U Line } +209PB T +209PB T 72.8049 5.85 10 XKA2 +209PB T 74.97 9.84 16 XKA1 +209PB T +209PB T 84.451 |] XKB3 +209PB T 84.937 |] 3.36 8 XKB1 +209PB T 85.47 |] XKB5II +209PB T +209PB T 87.238 |] XKB2 +209PB T 87.58 |] 1.016 28 XKB4 +209PB T 87.911 |] XKO23 +209PB T +209PB T 9.186-15.2169 8.04 14 XL (total) +209PB T 9.186 0.196 6 XLL +209PB T 10.4495-10.5512 3.72 9 XLA +209PB T 11.3495 0.0637 18 XLC +209PB T 12.1443-13.3763 3.41 7 XLB +209PB T 14.3078-15.2169 0.648 14 XLG +209PB T +209PB T 56.028-61.669 |] KLL AUGER +209PB T 68.181-74.969 |] 0.77 9 ^KLX AUGER +209PB T 80.3-88 |] KXY AUGER +209PB T 5.34-15.82 13.23 15 L AUGER +209TL P 0.0 1/2+ 2.161 M 7 3976 8 +209PB N 1.0 1.0 1 1.0 +209PB G 469.7 3 0.12 3 +209PB G 860.5 3 0.26 4 +209PB G 890.0 4 0.12 3 +209PB G 902.8 4 0.10 2 +209PB G 970.3 0.054 15 +209PB G 1661.1 5 0.10 2 +209PB G 1673.2 4 0.48 4 +209PB G 1781.7 5 0.04 2 +209PB G 2005.3 2 0.020 5 +209PB G 2032.1 5 1000E-6 0 +209PB G 2548.2 0.015 6 +209PB L 0 9/2+ 3.277 H 15 +209PB L 1566.94 5 5/2+ +209PB G 1566.93 5 99.707 5 E2 0.002945 +209PB2 G KC=0.00234 4$LC=3.96E-4 6$MC=9.26E-5 13 +209PB L 2032.07 6 1/2+ +209PB B 1944 8 0.1 8.3 +209PBS B EAV=709.0 34 +209PB G 465.128 2496.62 5 E2 0.0350 5 +209PB2 G KC=0.0242 4$LC=0.00815 12$MC=0.00204 3 +209PB L 2149.29 6 1/2- +209PB B 1827 8 97.70 15 5.2 +209PBS B EAV=660.0 34 +209PB G 117.224 7 77.22 27E1 0.295 5 +209PB2 G KC=0.235 4$LC=0.0455 7$MC=0.01072 15 +209PB G 582.4 2 0.312 24[M2] 0.200 3 +209PB2 G KC=0.1574 22$LC=0.0322 5$MC=0.00774 11 +209PB G 2149 1 0.015 5 [M4] 0.0152922 +209PB2 G KC=0.01218 18$LC=0.00237 4$MC=5.65E-4 8 +209PB L 2315.68 13(3/2)- +209PB B 1660 8 0.32 11 7.5 1U +209PBS B EAV=591.2 33 +209PB G 284.04 230.14 7 [M1] 0.495 7 +209PB2 G KC=0.405 6$LC=0.0692 10$MC=0.01620 23 +209PB G 748.3 2 0.080 21[E1] 0.004286 +209PB2 G KC=0.00356 5$LC=5.53E-4 8$MC=1280E-7 18 +209PB G 2315.80 210.0288 21[E3] 0.002924 +209PB2 G KC=0.00216 3$LC=3.80E-4 6$MC=8.93E-5 13 +209PB L 2460.8 3 (5/2)- +209PB B 1515 8 0.031 16 9.2 3U +209PBS B EAV=518.1 31 +209PB G 311.5 3 0.028 14[E2] 0.1034 15 +209PB2 G KC=0.0596 9$LC=0.0329 5$MC=0.00842 13 +209PB L 2524.79 21(1/2,3/2)+ +209PB B 1451 8 0.070 15 8 +209PBS B EAV=505.9 33 +209PB G 375.5 2 0.070 15 +209PB L 2905.14 253/2- +209PB B 1071 8 0.70 9 6.5 1U +209PBS B EAV=355.5 31 +209PB G 755.6 3 0.11 2 [M1] 0.0366 6 +209PB2 G KC=0.0301 5$LC=0.00500 7$MC=1168E-6 17 +209PB G 873.5 4 0.59 8 [E1] 0.003205 +209PB2 G KC=0.00267 4$LC=4.10E-4 6$MC=9.47E-5 14 +209PB L 3069.72 133/2- +209PB B 906 8 0.645 16 6.3 1U +209PBS B EAV=292.9 30 +209PB G 920.43 110.631 15[M1] 0.0220 3 +209PB2 G KC=0.0181 3$LC=0.00299 5$MC=6.98E-4 10 +209PB L 3361.36 17(1/2,3/2)+ +209PB B 615 8 0.10 3 +209PBS B EAV=187.4 28 +209PB G 1329.29 160.10 3 +209PB L 3388.96 13(1/2,3/2)+ +209PB B 587 8 0.420 22 +209PBS B EAV=177.8 28 +209PB G 1239.66 110.420 22 + diff --git a/HEN_HOUSE/spectra/lnhb/Tl-210.txt b/HEN_HOUSE/spectra/lnhb/Tl-210.txt new file mode 100644 index 000000000..36e9eb441 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Tl-210.txt @@ -0,0 +1,81 @@ +210PB 210TL B- DECAY (1.30 M) +210PB H TYP=Full$AUT=V.Chisté$CUT=31-AUG-2007$ +210PB C Evaluation history: Type=Full;Author=V.Chisté;Cutoff date=31-AUG-2007 +210PB C References: 1931Cu01, 1957Ko42, 1961St20, 1964We06, 1981Ha54, 1996Sc06, +210PB2C 2002Ba85, 2003Au03, 2003Br13 +210PB T Auger electrons and ^X ray energies and emission intensities: +210PB T {U Energy (keV)} {U Intensity } {U Line } +210PB T +210PB T 72.805 7 4 XKA2 +210PB T 74.97 11 6 XKA1 +210PB T +210PB T 84.451 |] XKB3 +210PB T 84.937 |] 3.8 19 XKB1 +210PB T 85.47 |] XKB5II +210PB T +210PB T 87.238 |] XKB2 +210PB T 87.58 |] 1.1 6 XKB4 +210PB T 87.911 |] XKO23 +210PB T +210PB T 9.186 XLL +210PB T 10.449-10.551 XLA +210PB T 11.349 XLC +210PB T 12.144-13.376 XLB +210PB T 14.308-15.217 XLG +210TL P 0.0 (5)+ 1.30 M 3 5482 12 +210PB N 1.0 1.0 1 1.0 +210PB G 83 301.98 40[E2] 14.00000 +210PB G 356 104 2 [M1] 0.270 22 +210PB G 382 103 2 [M1] 0.223 17 +210PB G 670 202 1 +210PB G 910 303 2 +210PB G 1490 202 1 +210PB G 1540 302 1 +210PB G 1650 302 1 +210PB G 2090 304.9 20 +210PB L 0 0+ 22.23 Y 12 +210PB L 799.6 3 2+ 17 PS 5 +210PB G 799.6 3 98.969 30E2 0.0104231 +210PB2 G KC=0.00811 24$LC=0.00176 5$MC=4.25E-4 13 +210PB L 1096 3 4+ 0.6 NS 1 +210PB B 4386 1213 7.3 +210PBS B EAV=1763 5 +210PB G 296 3 79 10E2 0.120 5 +210PB2 G KC=0.0671 19$LC=0.0399 17$MC=0.0103 5 +210PB L 1192 246+ 49 NS 6 +210PB B 4290 1231 6.9 +210PBS B EAV=1721 11 +210PB G 97 304 2 M1+E2 1 9.000000 +210PB2 G KC=4.00000 0$LC=3.00000 0$MC=0.80000 0 +210PB L 1869 103- +210PB G 1070 2011.9 49[E1] 0.002227 +210PB2 G KC=0.00185 6$LC=2.81E-4 8$MC=6.5E-5 2 +210PB L 2208 13(2)+ +210PB G 1110 206.9 20 +210PB G 1410 204.9 20 +210PB L 2412 13 + +210PB G 1310 2020.8 49 +210PB L 3069 12(2)+ +210PB B 2413 1210 6.4 2U +210PBS B EAV=907 7 +210PB G 860 306.9 20 +210PB G 2280 123 2 +210PB L 3458 22(4)+ +210PB B 2024 1210 6.1 +210PBS B EAV=743 10 +210PB G 1590 302 1 +210PB G 2360 307.9 30 +210PB L 3622 21 + +210PB B 1860 1224 5.6 +210PBS B EAV=674 10 +210PB G 1210 2016.8 40 +210PB G 2430 308.9 30 +210PB L 3879 32 + +210PB B 1603 127 5.9 +210PBS B EAV=568 14 +210PB G 2010 306.9 20 +210PB L 4102 29 + +210PB B 1380 122 6.2 +210PBS B EAV=477 13 +210PB G 480 362 1 + diff --git a/HEN_HOUSE/spectra/lnhb/Tm-170.txt b/HEN_HOUSE/spectra/lnhb/Tm-170.txt new file mode 100644 index 000000000..68484eb54 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Tm-170.txt @@ -0,0 +1,72 @@ +170ER 170TM EC DECAY (127.8 D) +170ER C References: 1962Bo12, 1977La19 +170ER T Auger electrons and ^X ray energies and emission intensities: +170ER T {U Energy (keV)} {U Intensity } {U Line } +170ER T +170ER T 48.2212 0.332 16 XKA2 +170ER T 49.1276 0.0590 24 XKA1 +170ER T +170ER T 55.4797 |] XKB3 +170ER T 55.6737 |] 0.0191 10 XKB1 +170ER T 56.0322 |] XKB5II +170ER T 56.0762 |] XKB5I +170ER T +170ER T 57.142 |] XKB2 +170ER T 57.313 |] 0.0050 3 XKB4 +170ER T 57.456 |] XKO23 +170ER T +170ER T 6.15-9.43 0.0306 19 XL (total) +170ER T 6.15 XLL +170ER T -9.43 XLG +170ER T +170ER T 37.79-40.56 |] KLL AUGER +170ER T 45.47-49.1 |] 0.0072 6 ^KLX AUGER +170ER T 53.02-57.43 |] KXY AUGER +170TM P 0.0 1- 127.8 D 6 314.4 18 +170ER N 6.803E2 6.803E2 0.00147 6.803E2 +170ER L 0 0+ STABLE +170ER E 0.118 7 9.906 1 +170ER2 E EAV= $CK=0.7838 19$CL=0.1645 13$CM=0.0401 8$CN= $CO= +170ER L 78.59 2 2+ +170ER E 0.029 3 10.21 1 +170ER2 E EAV= $CK=0.7595 22$CL=0.1822 15$CM=0.0451 9$CN= $CO= +170ER G 78.59 2 0.0034 3 E2 7.6 5 +170ER2 G KC=1.72 11$LC=4.51 30$MC=1.10 7 + +170YB 170TM B- DECAY (127.8 D) +170YB C References: 1962Bo12, 1977La19 +170YB T Auger electrons and ^X ray energies and emission intensities: +170YB T {U Energy (keV)} {U Intensity } {U Line } +170YB T +170YB T 51.3546 0.95 4 XKA2 +170YB T 52.3895 1.67 7 XKA1 +170YB T +170YB T 59.15 |] XKB3 +170YB T 59.37 |] 0.55 3 XKB1 +170YB T 59.782 |] XKB5II +170YB T +170YB T 60.98 |] XKB2 +170YB T 61.141 |] 0.144 7 XKB4 +170YB T 61.309 |] XKO23 +170YB T +170YB T 6.548-10.142 3.22 13 XL (total) +170YB T 6.548 0.0590 29 XLL +170YB T 7.369-7.416 1.42 7 XLA +170YB T 7.583 XLC +170YB T 8.026-8.756 1.50 7 XLB +170YB T 9.736-10.142 0.242 12 XLG +170YB T +170YB T 40.16-43.23 |] KLL AUGER +170YB T 48.36-52.36 |] 0.182 14 ^KLX AUGER +170YB T 56.48-61.29 |] KXY AUGER +170TM P 0.0 1- 127.8 D 6 968.0 8 +170YB N 1.001E0 1.001E0 0.999 1.001E0 +170YB L 0 0+ STABLE +170YB B 968.0 8 81.6 7 9.432 1 +170YBS B EAV=323.1 3 +170YB L 84.25477 8 2+ +170YB B 883.7 8 18.3 7 8.924 1 +170YBS B EAV=290.5 3 +170YB G 84.25474 8 2.48 9 E2 6.39 10 +170YB2 G KC=1.39 2$LC=3.81 6$MC=0.94 1 + diff --git a/HEN_HOUSE/spectra/lnhb/U-232.txt b/HEN_HOUSE/spectra/lnhb/U-232.txt new file mode 100644 index 000000000..60ea073a8 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/U-232.txt @@ -0,0 +1,82 @@ +228TH 232U A DECAY (70.6 Y) +228TH H TYP=Full$AUT=A.Pearce$CUT=31-JAN-2008$ +228TH C Evaluation history: Type=Full;Author=A.Pearce;Cutoff date=31-JAN-2008 +228TH C References: 1949Go01, 1949Ja01, 1954Se26, 1955Go32, 1955As28, 1963Le17, +228TH2C 1964Ch05, 1965Be15, 1966Ah02, 1966Ba49, 1971He23, 1973Ta25, 1977Ku15, +228TH3C 1979Bo30, 1979He10, 1979Ag04, 1982Ma52, 1984Ge07, 1985Ba18, 1987Da28, +228TH4C 1990Bo16, 1995Ba42, 1996Sc06, 2000Bo46, 2000He14, 2003Wa32, 2003Au03 +228TH T Auger electrons and ^X ray energies and emission intensities: +228TH T {U Energy (keV)} {U Intensity } {U Line } +228TH T +228TH T 89.954 0.00524 11 XKA2 +228TH T 93.351 0.00847 16 XKA1 +228TH T +228TH T 104.819 |] XKB3 +228TH T 105.604 |] 0.00301 7 XKB1 +228TH T 106.239 |] XKB5II +228TH T +228TH T 108.509 |] XKB2 +228TH T 108.955 |] 0.001016 29 XKB4 +228TH T 109.442 |] XKO23 +228TH T +228TH T 11.1177-19.5043 11.00 24 XL (total) +228TH T 11.1177 0.223 7 XLL +228TH T 12.8085-12.967 3.71 11 XLA +228TH T 14.509 0.129 5 XLC +228TH T 14.972-16.4253 5.61 16 XLB +228TH T 18.3633-19.5043 1.32 4 XLG +228TH T +228TH T 68.406-76.745 |] KLL AUGER +228TH T 83.857-93.345 |] 0.00057 8 ^KLX AUGER +228TH T 99.29-109.64 |] KXY AUGER +228TH T 5.8-20.3 11.62 22 L AUGER +232U P 0.0 0+ 70.6 Y 11 5413.63 9 +228TH N 1.0 1.0 1 1.0 +228TH L 0 0+ 1.9126 Y 9 +228TH A 5320.24 9 69.1 6 1 +228TH L 57.759 4 2+ 0.405 NS 7 +228TH A 5263.48 9 30.6 6 1.04 +228TH G 57.752 130.200 4 E2 153.2 22 +228TH2 G KC=$LC=112.2 16$MC=30.7 5 +228TH L 186.823 4 4+ 0.164 NS 4 +228TH A 5136.64 9 0.325 6 16.4 +228TH G 129.065 3 0.0686 7 E2 3.74 6 +228TH2 G KC=0.264 4$LC=2.54 4$MC=0.697 10 +228TH L 328.003 4 1- +228TH A 4997.90 9 0.00622 9 112 +228TH G 270.245 7 0.00317 7 E1 0.0470 7 +228TH2 G KC=0.0376 6$LC=0.00716 10$MC=1717E-6 24 +228TH G 328.004 7 0.00283 7 E1 0.0305 5 +228TH2 G KC=0.0245 4$LC=0.00455 7$MC=1089E-6 16 +228TH L 378.179 106+ +228TH A 4948.59 9 51000E-96 6490 +228TH G 191.351 113.1E-5 3 E2 0.776 11 +228TH2 G KC=0.1710 24$LC=0.443 7$MC=0.1209 17 +228TH L 396.078 103- +228TH A 4931.00 9 48000E-94 5270 +228TH G 209.252 6 1.1E-5 3 E1 0.0848 12 +228TH2 G KC=0.0672 10$LC=0.01333 19$MC=0.00321 5 +228TH G 338.320 5 3.70E-5 18E1 0.0285 4 +228TH2 G KC=0.0229 4$LC=0.00424 6$MC=1014E-6 15 +228TH L 519.192 6 5- +228TH A 4810.01 9 54000E-94 712 +228TH G 140.999 203.1E-6 13E1 0.217 3 +228TH2 G KC=0.1690 24$LC=0.0362 5$MC=0.00876 13 +228TH G 332.371 6 4.9E-5 3 E1 0.0297 5 +228TH2 G KC=0.0238 4$LC=0.00441 7$MC=1056E-6 15 +228TH L 831.823 100+ +228TH A 4502.77 9 21400E-91610.6 +228TH G 503.819 231.45E-5 9 E1 0.0124318 +228TH2 G KC=0.01009 15$LC=1775E-6 25$MC=4.22E-4 6 +228TH G 774.05 9 4.7E-6 8 E2 0.0164923 +228TH2 G KC=0.01204 17$LC=0.00333 5$MC=8.35E-4 12 +228TH G 831.823 10 +228TH L 874.473 182+ +228TH A 4460.86 9 33000E-19 33 +228TH G 478.41 5 1.4E-6 6 E1 0.0137920 +228TH2 G KC=1118E-5 2$LC=0.00198 3$MC=4.71E-4 7 +228TH G 546.454 211.0E-6 6 E1 0.0105815 +228TH2 G KC=0.00861 12$LC=1500E-6 21$MC=3.57E-4 5 +228TH G 816.62 708E-7 3 M1+E2 1 0.0359 5 +228TH2 G KC=0.0284 4$LC=0.00566 8$MC=1369E-6 20 + diff --git a/HEN_HOUSE/spectra/lnhb/U-234.txt b/HEN_HOUSE/spectra/lnhb/U-234.txt new file mode 100644 index 000000000..2582af11a --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/U-234.txt @@ -0,0 +1,66 @@ +230TH 234U A DECAY (2.455E5 Y) +230TH H TYP=Full$AUT=V. Chisté$CUT=07-DEC-2005$ +230TH C Evaluation history: Type=Full;Author=V. Chisté;Cutoff date=07-DEC-2005 +230TH C References: 1939Ni03, 1930Cu02, 1946Ch02, 1949Hy03, 1949Ki26, 1949Go18, +230TH2C 1949Ba41, 1952Fl20, 1952Ki19, 1952Gh27, 1960Ba44, 1961At01, 1961ko11, +230TH3C 1963Bj03, 1965Ne03, 1965Wh05, 1966Ah02, 1970MeZN, 1972DeYN, 1972LoZL, +230TH4C 1972Sc01, 1973Ta25, 1974HeYW, 1980Ge13, 1980Me01, 1981Vo02, 1981HoZI, +230TH5C 1983Ak12, 1984Di08, 1984Va41, 1986LoZT, 1987Bo25, 1987Sh27, 1989Ho24, +230TH6C 1991Ry01, 1993Ak02, 1993Ak05, 1995Jo23, 1996Sc06, 2002Ba85, 2003Au03 +230TH T Auger electrons and ^X ray energies and emission intensities: +230TH T {U Energy (keV)} {U Intensity } {U Line } +230TH T +230TH T 89.954 0.00269 25 XKA2 +230TH T 93.351 0.0044 4 XKA1 +230TH T +230TH T 104.819 |] XKB3 +230TH T 105.604 |] 0.00155 15 XKB1 +230TH T 106.239 |] XKB5II +230TH T +230TH T 108.509 |] XKB2 +230TH T 108.955 |] 0.00052 5 XKB4 +230TH T 109.442 |] XKO23 +230TH T +230TH T 11.118-19.504 10.2 4 XL (total) +230TH T 11.118 0.209 12 XLL +230TH T 12.8085-12.967 3.48 17 XLA +230TH T 14.509 0.118 7 XLC +230TH T 14.972-16.4253 5.16 26 XLB +230TH T 18.3633-19.504 1.21 6 XLG +230TH T +230TH T 68.406-76.745 |] KLL AUGER +230TH T 83.857-93.345 |] 0.00029 5 ^KLX AUGER +230TH T 99.29-109.64 |] KXY AUGER +230TH T 5.8-20.3 10.8 4 L AUGER +234U P 0.0 0+ 2.455E5 Y 6 4857.7 7 +230TH N 1.0 1.0 1 1.0 +230TH L 0 0+ 75.38E3 Y 30 +230TH A 4774.6 7 71.37 2 1 +230TH L 53.20 2 2+ 0.354 NS 9 +230TH A 4722.4 7 28.42 2 1.1 +230TH G 53.20 2 0.1253 40E2+M3 228 7 +230TH2 G KC=$LC=167 5$MC=45.6 14 +230TH L 174.10 4 4+ 0.166 NS 5 +230TH A 4603.5 7 0.210 2 21 +230TH G 120.90 4 0.0386 32E2 4.92 15 +230TH2 G KC=0.244 7$LC=3.42 10$MC=0.940 28 +230TH L 508.16 4 1- +230TH A 4275.2 7 0.00004 1 288 +230TH G 454.96 5 2.5E-5 6 E1 0.0152646 +230TH2 G KC=0.01235 37$LC=0.00220 7$MC=5.25E-4 16 +230TH G 508.16 5 1.50E-5 39E1 0.0122137 +230TH2 G KC=0.00991 30$LC=0.00174 5$MC=4.15E-4 12 +230TH L 634.90 7 0+ +230TH A 4150.6 7 26000E-9 39 +230TH G 581.7 1 1.2E-5 5 E2 0.0300 9 +230TH2 G KC=0.0202 6$LC=0.00734 22$MC=0.00188 6 +230TH G 634.9 1 +230TH L 677.60 6 2+ +230TH A 4108.6 7 70000E-1 63 +230TH G 503.5 1 950E-9 0 [E2] 0.0418 13 +230TH2 G KC=0.0264 8$LC=0.01141 34$MC=0.00296 9 +230TH G 624.4 1 820E-9 0 +E2+M1 5.1 20 +230TH2 G KC=$LC=$MC= +230TH G 677.6 1 1000E-9 0 [E2] 0.0216 6 +230TH2 G KC=0.01526 46$LC=0.00475 14$MC=1204E-6 36 + diff --git a/HEN_HOUSE/spectra/lnhb/U-235.txt b/HEN_HOUSE/spectra/lnhb/U-235.txt new file mode 100644 index 000000000..86eabf8f4 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/U-235.txt @@ -0,0 +1,189 @@ +231TH 235U A DECAY (704E6 Y) +231TH H TYP=Update$AUT=M.M. Bé$CUT= -- $ +231TH2 H TYP=update$AUT=M.M. Bé$CUT= -- $ +231TH3 H TYP=Full$AUT=X. Huang$CUT=30-JUN-2008$ +231TH C Evaluation history: Type=Update;Author=M.M. Bé;Cutoff date= -- +231TH2C Type=update;Author=M.M. Bé;Cutoff date= -- +231TH3C Type=Full;Author=X. Huang;Cutoff date=30-JUN-2008 +231TH C References: 2008Ki07 +231TH T Auger electrons and ^X ray energies and emission intensities: +231TH T {U Energy (keV)} {U Intensity } {U Line } +231TH T +231TH T 89.954 3.56 7 XKA2 +231TH T 93.351 5.75 11 XKA1 +231TH T +231TH T 104.819 |] XKB3 +231TH T 105.604 |] 2.05 5 XKB1 +231TH T 106.239 |] XKB5II +231TH T +231TH T 108.509 |] XKB2 +231TH T 108.955 |] 0.690 19 XKB4 +231TH T 109.442 |] XKO23 +231TH T +231TH T 11.1177-19.5043 40 22 XL (total) +231TH T 11.1177 1.2 10 XLL +231TH T 12.8085-12.967 21 15 XLA +231TH T 14.509 0.243 24 XLC +231TH T 14.972-17.1383 15 4 XLB +231TH T 18.3633-19.5043 2.70 21 XLG +231TH T +231TH T 68.406-76.745 |] KLL AUGER +231TH T 83.857-93.345 |] 0.39 5 ^KLX AUGER +231TH T 99.29-109.64 |] KXY AUGER +231TH T 5.8-20.3 47 22 L AUGER +235U P 0.0 Null+ 704E6 Y 1 4678.3 7 +231TH N 1.0 1.0 1 1.0 +231TH L 0 5/2+ 25.52 H 1 +231TH A 4596.4 134.74 6 2571 +231TH L 41.954 4 7/2+ +231TH A 4556.0 4 3.79 6 1586 +231TH G 42.01 6 0.056 9 M1+E2 1.2 1 440 30 +231TH2 G KC=$LC=325 22$MC=88 6 +231TH L 96.170 129/2+ +231TH A 4502.4 7 1.28 5 1856 +231TH G 54.25 5 2850E-5 0 [M1+E2] 0.60 2 71 3 +231TH2 G KC=$LC=52.7 20$MC=14.0 6 +231TH G 96.09 2 0.091 11[E2] 13.58 19 +231TH2 G KC=$LC=9.93 14$MC=2.73 4 +231TH L 162.06 3 11/2+ +231TH A 4437.9 400.236 253170 +231TH G 120.35 5 2600E-5 0 [M1] 10.95 16 +231TH2 G KC=8.73 13$LC=1.678 24$MC=0.404 6 +231TH L 185.721 4 5/2- 0.77 NS 12 +231TH A 4414.9 5 3.01 16164 +231TH G 143.767 3 10.94 6 E1 0.207 3 +231TH2 G KC=0.1615 23$LC=0.0344 5$MC=0.00833 12 +231TH G 185.720 4 57.0 3 E1 0.1124 16 +231TH2 G KC=0.0887 13$LC=0.0179 3$MC=0.00433 6 +231TH L 205.313 4 7/2- +231TH A 4397.8 1357.19 206.08 +231TH G 19.592 6 0.006 6 [M1+E2] 1E4 1 +231TH2 G KC=$LC=6E3 6$MC=3E3 3 +231TH G 109.19 7 1.66 13[E1] 0.0932 14 +231TH2 G KC=$LC=0.0704 10$MC=0.01708 24 +231TH G 163.356 3 5.08 3 (E1) 0.1526 22 +231TH2 G KC=0.1197 17$LC=0.0248 4$MC=0.00599 9 +231TH G 205.316 4 5.02 3 (E1) 0.0887 13 +231TH2 G KC=0.0703 10$LC=0.01397 20$MC=0.00336 5 +231TH L 221.386 143/2+ +231TH A 4381.1 7 0.106 162460 +231TH G 221.386 140.118 5 M1 1.96 3 +231TH2 G KC=1.566 22$LC=0.296 5$MC=0.0712 10 +231TH L 236.902 7 9/2- +231TH A 4366.1 2018.80 1310.47 +231TH G 31.60 5 0.017 6 M1+E2 0.5 666 11 +231TH2 G KC=$LC=490 8$MC=131.5 21 +231TH G 51.21 4 0.034 7 [E2] 274 4 +231TH2 G KC=$LC=201 3$MC=54.9 8 +231TH G 74.94 3 0.051 6 [E1] 0.252 4 +231TH2 G KC=$LC=0.190 3$MC=0.0464 7 +231TH G 140.76 2 0.20 1 [E1] 0.218 3 +231TH2 G KC=0.1696 24$LC=0.0364 5$MC=0.00879 13 +231TH G 194.940 6 0.63 1 [E1] 0.1002 14 +231TH2 G KC=0.0792 11$LC=0.01589 23$MC=0.00383 6 +231TH L 240.858 145/2+ +231TH A 4361.9 7 0.206 21890 +231TH G 198.894 140.036 2 M1 2.64 4 +231TH2 G KC=2.11 3$LC=0.401 6$MC=0.0963 14 +231TH G 240.88 4 0.074 4 M1(+E2) 0.3 3 1.45 22 +231TH2 G KC=1.14 21$LC=0.228 13$MC=0.0553 21 +231TH L 275.459 197/2+ +231TH A 4327.9 7 0.405 13241 +231TH G 54.1 1 1150E-6 0 [E2] 210 4 +231TH2 G KC=$LC=154 3$MC=42.1 7 +231TH G 233.50 2 0.038 4 M1 1.687 24 +231TH2 G KC=1.350 19$LC=0.255 4$MC=0.0613 9 +231TH G 275.49 6 3200E-5 0 M1(+E2) 0.25 25 1.02 12 +231TH2 G KC=0.81 11$LC=0.157 9$MC=0.0379 18 +231TH L 277.56 6 (11/2)- +231TH A 4322 4 3.33 6 28.1 +231TH G 41.4 3 0.029 11[M1] 49.9 13 +231TH2 G KC=$LC=37.7 10$MC=9.08 24 +231TH G 72.7 2 0.116 20M1+E2 0.4 1 15 3 +231TH2 G KC=$LC=11.4 19$MC=2.9 6 +231TH G 115.45 5 0.03 1 [E1] 0.348 5 +231TH2 G KC=0.267 4$LC=0.0609 9$MC=0.01475 21 +231TH G 182.1 +231TH L 301.7 1 (5/2)+ +231TH A 4302.1 7 0.00959 136260 +231TH G 301.7 1 5300E-6 0 M1 0.829 12 +231TH2 G KC=0.664 10$LC=0.1249 18$MC=0.0300 5 +231TH L 317.15 7 5/2+ +231TH A 4286.9 7 0.065 13690 +231TH G 95.7 +231TH G 275.35 150.051 6 M1+E2 0.6 1 0.84 6 +231TH2 G KC=0.65 5$LC=0.144 5$MC=0.0355 10 +231TH G 317.10 8 1100E-6 0 M1 0.723 11 +231TH2 G KC=0.579 9$LC=0.1088 16$MC=0.0261 4 +231TH L 324.91 4 (9/2)+ +231TH A 4279.3 7 0.0329 5 1185 +231TH G 228.76 5 7400E-6 0 M1 1.79 3 +231TH2 G KC=1.429 20$LC=0.270 4$MC=0.0649 9 +231TH G 282.94 5 6300E-6 0 [M1] 0.990 14 +231TH2 G KC=0.792 12$LC=0.1493 21$MC=0.0359 5 +231TH L 334 4 (13/2)- +231TH A 4266 5 0.22 3 150 +231TH G 97 4 0.016 4 [E2] 13 3 +231TH2 G KC=$LC=9.5 21$MC=2.6 6 +231TH L 351.565 167/2+ +231TH A 4248 5 0.069 10343 +231TH G 255.365 107400E-6 0 M1 1.315 19 +231TH2 G KC=1.052 15$LC=0.199 3$MC=0.0477 7 +231TH G 310.69 6 9400E-6 0 (E2) 0.1517 22 +231TH2 G KC=0.068 1$LC=0.0616 9$MC=0.01650 24 +231TH G 350 5 6000E-6 0 M1 0.552 24 +231TH2 G KC=0.442 19$LC=0.083 4$MC=0.0199 9 +231TH L 377.50 4 (7/2)+ +231TH A 4227.6 7 0.122 6 119 +231TH G 136.55 5 1200E-5 0 [M1] 7.66 11 +231TH2 G KC=6.11 9$LC=1.168 17$MC=0.281 4 +231TH G 173 1 0.006 5 [E1] 0.133 3 +231TH2 G KC=0.1047 21$LC=0.0215 5$MC=0.00518 11 +231TH G 281.42 5 6300E-6 0 M1 1.005 14 +231TH2 G KC=0.804 12$LC=0.1515 22$MC=0.0364 5 +231TH L 385.72 4 (11/2)+ +231TH A 4219.5 7 0.01732 12714 +231TH G 289.56 4 7400E-6 0 [M1] 0.929 13 +231TH2 G KC=0.743 11$LC=0.140 2$MC=0.0336 5 +231TH G 343.5 2 3200E-6 0 +231TH L 387.841 8 7/2- +231TH A 4214.7 195.95 122 +231TH G 147 +231TH G 150.936 150.09 3 [M1] 5.76 8 +231TH2 G KC=4.60 7$LC=0.877 13$MC=0.211 3 +231TH G 182.62 5 0.39 5 [M1] 3.36 5 +231TH2 G KC=2.69 4$LC=0.510 8$MC=0.1226 18 +231TH G 202.12 1 1.08 2 [M1] 2.53 4 +231TH2 G KC=2.02 3$LC=0.383 6$MC=0.0920 13 +231TH G 291.65 3 0.040 6 [E1] 0.0396 6 +231TH2 G KC=0.0317 5$LC=0.00598 9$MC=1433E-6 20 +231TH G 345.92 3 0.040 6 [E1] 0.0272 4 +231TH2 G KC=0.0219 3$LC=0.00403 6$MC=9.64E-4 14 +231TH G 387.84 3 0.040 6 [E1] 0.0213 3 +231TH2 G KC=0.01717 24$LC=0.00312 5$MC=7.45E-4 11 +231TH L 452.182 159/2- +231TH A 4152 5 0.294 1311.6 +231TH G 64.45 5 1800E-5 0 [M1] 13.6 2 +231TH2 G KC=$LC=10.28 15$MC=2.47 4 +231TH G 215.28 4 0.029 3 [M1] 2.12 3 +231TH2 G KC=1.693 24$LC=0.321 5$MC=0.0770 11 +231TH G 246.83 2 0.055 3 [M1] 1.445 21 +231TH2 G KC=1.157 17$LC=0.218 3$MC=0.0525 8 +231TH G 266.47 4 0.0078 6 [E2] 0.245 4 +231TH2 G KC=0.0921 13$LC=0.1121 16$MC=0.0303 5 +231TH G 291.2 +231TH G 356.03 5 5300E-6 0 [E1] 0.0255 4 +231TH2 G KC=0.0206 3$LC=0.00377 6$MC=9.03E-4 13 +231TH G 410.29 4 3200E-6 0 [E1] 0.0189 3 +231TH2 G KC=0.01527 22$LC=0.00275 4$MC=6.57E-4 10 +231TH L 530.24 5 (11/2)- +231TH A 4077.5 7 0.016 1246 +231TH G 142.40 5 5100E-6 0 [E2] 2.48 4 +231TH2 G KC=0.253 4$LC=1.627 23$MC=0.446 7 +231TH L 595.58 205/2- +231TH A 4013.2 8 0.0396 104.86 +231TH G 390.27 200.040 1 +231TH L 634.12 6 7/2- +231TH A 3976 5 0.0011 79 +231TH G 448.40 6 1100E-6 0 + diff --git a/HEN_HOUSE/spectra/lnhb/U-236.txt b/HEN_HOUSE/spectra/lnhb/U-236.txt new file mode 100644 index 000000000..a5b8e0a44 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/U-236.txt @@ -0,0 +1,48 @@ +232TH 236U A DECAY (23.43E6 Y) +232TH H TYP=Full$AUT=A.Luca$CUT=28-FEB-2008$ +232TH C Evaluation history: Type=Full;Author=A.Luca;Cutoff date=28-FEB-2008 +232TH C References: 1951JA09, 1952FL20, 1960KO04, 1971CO35, 1972FL03, 1972Sc01, +232TH2C 1981VO02, 1983BE66, 1988WoZO, 1989Ho24, 1992IT01, 1994Tr12, 2002GE02, +232TH3C 2003AU03, 2006BR19 +232TH T Auger electrons and ^X ray energies and emission intensities: +232TH T {U Energy (keV)} {U Intensity } {U Line } +232TH T +232TH T 89.954 0.00128 22 XKA2 +232TH T 93.351 0.0021 4 XKA1 +232TH T +232TH T 104.819 |] XKB3 +232TH T 105.604 |] 0.00074 13 XKB1 +232TH T 106.239 |] XKB5II +232TH T +232TH T 108.509 |] XKB2 +232TH T 108.955 |] 0.00025 5 XKB4 +232TH T 109.442 |] XKO23 +232TH T +232TH T 11.118-19.599 9.4 10 XL (total) +232TH T 11.118 0.194 26 XLL +232TH T 12.809-12.968 3.2 4 XLA +232TH T 14.511 0.108 17 XLC +232TH T 14.97-16.426 4.7 6 XLB +232TH T 18.98-19.599 1.11 14 XLG +232TH T +232TH T 68.406-76.745 |] KLL AUGER +232TH T 83.857-93.345 |] 0.000139 30 ^KLX AUGER +232TH T 99.29-109.64 |] KXY AUGER +232TH T 5.8-20.3 10.1 12 L AUGER +236U P 0.0 0+ 23.43E6 Y 6 4573.1 9 +232TH N 1.0 1.0 1 1.0 +232TH L 0 0+ 14.02E9 Y 6 +232TH A 4494 3 73.8 401 +232TH L 49.46 102+ 345 PS 15 +232TH A 4445 5 26.1 401.2 +232TH G 49.46 100.081 12E2 324 10 +232TH2 G KC=$LC=237 7$MC=65.0 19 +232TH L 162.25 154+ 164 PS 13 +232TH A 4332 8 0.149 2227.3 +232TH G 112.79 100.0195 31E2 6.67 20 +232TH2 G KC=0.229 7$LC=4.71 14$MC=1.295 39 +232TH L 333.40 256+ 62 PS 4 +232TH A 4168 0.00014 5 1160 +232TH G 171.15 206.5E-5 22E2 1.186 36 +232TH2 G KC=0.204 6$LC=0.719 22$MC=0.197 6 + diff --git a/HEN_HOUSE/spectra/lnhb/U-237.txt b/HEN_HOUSE/spectra/lnhb/U-237.txt new file mode 100644 index 000000000..126017c95 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/U-237.txt @@ -0,0 +1,122 @@ +237NP 237U B- DECAY (6.749 D) +237NP H TYP=Full$AUT=V.P.Chechev$CUT=30-AUG-2005$ +237NP2 H TYP=Full$AUT=V.P.Chechev$CUT=30-AUG-2005$ +237NP3 H TYP=Full$AUT=V.P.Chechev$CUT=30-AUG-2005$ +237NP4 H TYP=Full$AUT=V.P.Chechev$CUT=30-AUG-2005$ +237NP5 H TYP=Full$AUT=V.P.Chechev$CUT=30-AUG-2005$ +237NP6 H TYP=Full$AUT=V.P.Chechev$CUT=30-AUG-2005$ +237NP7 H TYP=Full$AUT=V.P.Chechev$CUT=30-AUG-2005$ +237NP8 H TYP=Full$AUT=V.P.Chechev$CUT=30-AUG-2005$ +237NP C Evaluation history: Type=Full;Author=V.P.Chechev;Cutoff date=30-AUG-2005 +237NP2C Type=Full;Author=V.P.Chechev;Cutoff date=30-AUG-2005 +237NP3C Type=Full;Author=V.P.Chechev;Cutoff date=30-AUG-2005 +237NP4C Type=Full;Author=V.P.Chechev;Cutoff date=30-AUG-2005 +237NP5C Type=Full;Author=V.P.Chechev;Cutoff date=30-AUG-2005 +237NP6C Type=Full;Author=V.P.Chechev;Cutoff date=30-AUG-2005 +237NP7C Type=Full;Author=V.P.Chechev;Cutoff date=30-AUG-2005 +237NP8C Type=Full;Author=V.P.Chechev;Cutoff date=30-AUG-2005 +237NP C References: 1949Me43, 1953Wa05, 1957Ra04, 1958Ca16, 1959Sa10, 1960As02, +237NP2C 1963Ak04, 1964Wo03, 1966Ya05, 1966Le13, 1967Pa23, 1966Ko06, 1968Da24, +237NP3C 1971Cl03, 1970Gr36, 1976GuZN, 1982BuZF, 1984BAYS, 1985He02, 1985Wi04, +237NP4C 1986LoZT, 1996Jo28, 1996Sc06, 1996Ya05, 1998Ko61, 2000He14, 2003Au03, +237NP5C 2006Ba41, 2008Ki07 +237NP T Auger electrons and ^X ray energies and emission intensities: +237NP T {U Energy (keV)} {U Intensity } {U Line } +237NP T +237NP T 97.069 14.8 4 XKA2 +237NP T 101.059 23.5 6 XKA1 +237NP T +237NP T 113.303 |] XKB3 +237NP T 114.234 |] 8.57 27 XKB1 +237NP T 114.912 |] XKB5II +237NP T +237NP T 117.476 |] XKB2 +237NP T 117.876 |] 2.95 10 XKB4 +237NP T 118.429 |] XKO23 +237NP T +237NP T 11.89-22.2 59.0 21 XL (total) +237NP T 11.89 1.56 8 XLL +237NP T 13.76-13.94 24.7 11 XLA +237NP T 15.88 0.433 29 XLC +237NP T 16.13-17.99 26.2 11 XLB +237NP T 20.12-22.2 5.99 25 XLG +237NP T +237NP T 73.5-83.13 |] KLL AUGER +237NP T 90.36-97.28 |] 1.49 21 ^KLX AUGER +237NP T 107.1-114.58 |] KXY AUGER +237NP T 5.04-13.52 58.5 21 L AUGER +237U P 0.0 1/2+ 6.749 D 16 518.6 6 +237NP N 1.0 1.0 1 1.0 +237NP G 114.09 5 +237NP G 340.45 0.0016 3 +237NP L 0 5/2+ 2.144E6 Y 7 +237NP L 33.19629 227/2+ 54 PS +237NP G 33.19629 220.130 5 M1+E2 0.13 3 175 24 +237NP2 G KC=$LC=131 17$MC=33 5 +237NP L 59.54092 105/2- 67 NS 5 +237NP B 459.1 6 7 4 8.1 3U +237NPS B EAV=137.6 2 +237NP G 26.34463 242.43 6 E1 8 2 +237NP2 G KC=$LC=6 2$MC=1.6 2 +237NP G 59.54091 1034.1 9 E1 1.16 7 +237NP2 G KC=$LC=0.84 6$MC=0.226 7 +237NP L 75.899 5 9/2+ 56 PS +237NP G 42.704 5 8500E-6 0 M1+E2 0.13 4 75 9 +237NP2 G KC=$LC=56 7$MC=13.9 19 +237NP G 75.899 5 9100E-7 0 (E2) 53.4 11 +237NP2 G KC=$LC=38.9 8$MC=10.8 2 +237NP L 102.959 3 7/2- 80 PS +237NP G 27.020 7 +237NP G 43.420 3 0.024 2 M1+E2 0.45 5 180 23 +237NP2 G KC=$LC=132 17$MC=35 5 +237NP G 69.76 3 0.00095 19(E1) 0.330 7 +237NP2 G KC=$LC=0.248 5$MC=0.0612 12 +237NP G 102.959 3 0.0064 9 E1 0.119 3 +237NP2 G KC=$LC=0.0894 18$MC=0.0219 4 +237NP L 267.556 123/2- 5.2 NS +237NP B 251.1 6 40.9 31 6.54 1U +237NPS B EAV=68.6 2 +237NP G 164.61 2 1.86 3 E2 1.70 4 +237NP2 G KC=0.195 4$LC=1.095 20$MC=0.304 6 +237NP G 208.00 1 21.3 3 M1+E2 0.156 5 2.98 7 +237NP2 G KC=2.35 5$LC=0.473 10$MC=0.115 3 +237NP G 234.40 4 0.0205 8 M2 8.24 16 +237NP2 G KC=5.560 12$LC=1.95 4$MC=0.511 10 +237NP G 267.556 120.721 10E1+M2 0.490 15 1.06 6 +237NP2 G KC=0.74 4$LC=0.238 12$MC=0.062 3 +237NP L 281.356 181/2- +237NP B 237.2 6 48.2 25 6.39 +237NPS B EAV=64.5 2 +237NP G 13.81 2 0.099 4 M1+E2 0.0321 10 492 16 +237NP2 G KC=$LC=$MC=364 13 +237NP G 221.80 4 0.0204 8 E2 0.547 11 +237NP2 G KC=0.130 3$LC=0.304 6$MC=0.0839 17 +237NP L 332.376 161/2+ 1 NS +237NP B 186.2 6 2.9 9 7.28 +237NPS B EAV=49.8 2 +237NP G 51.01 3 0.340 14E1 0.753 15 +237NP2 G KC=$LC=0.565 12$MC=0.140 3 +237NP G 64.83 2 1.286 17E1 0.400 8 +237NP2 G KC=$LC=0.301 6$MC=0.0744 15 +237NP G 332.376 161.199 16E2 0.146 3 +237NP2 G KC=0.0631 12$LC=0.0611 12$MC=0.0164 4 +237NP L 368.602 205/2+ +237NP G 292.77 6 0.0025 7 (E2) 0.215 4 +237NP2 G KC=0.0796 16$LC=0.0991 19$MC=0.0270 6 +237NP G 309.1 3 2700E-7 0 (E1) 0.0377 8 +237NP2 G KC=0.0300 6$LC=0.00585 12$MC=0.00143 3 +237NP G 335.38 4 0.0958 22M1+E2 0.46 17 0.69 8 +237NP2 G KC=0.54 7$LC=0.113 8$MC=0.0278 17 +237NP G 368.602 200.0416 17M1(+E2) 0.31 0.622 13 +237NP2 G KC=0.494 10$LC=0.0963 20$MC=0.0233 5 +237NP L 370.928 233/2+ +237NP B 147.7 6 1.3 9 7.32 2 +237NPS B EAV=39.0 2 +237NP G 2.3 +237NP G 38.54 3 0.0033 20M1+E2 0.42 25 2.8E2 21 +237NP2 G KC=$LC=2.1E2 16$MC=60 50 +237NP G 337.7 2 0.0089 5 (E2) 0.139 3 +237NP2 G KC=0.0612 12$LC=0.0575 12$MC=0.0157 3 +237NP G 370.928 230.109 2 M1+E2 0.43 21 0.53 7 +237NP2 G KC=0.42 6$LC=0.086 8$MC=0.0211 17 + diff --git a/HEN_HOUSE/spectra/lnhb/U-238.txt b/HEN_HOUSE/spectra/lnhb/U-238.txt new file mode 100644 index 000000000..1faea15b0 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/U-238.txt @@ -0,0 +1,49 @@ +234TH 238U A DECAY (4.468E9 Y) +234TH H TYP=Full$AUT=V. Chisté$CUT=01-APR-2006$ +234TH C Evaluation history: Type=Full;Author=V. Chisté;Cutoff date=01-APR-2006 +234TH C References: 1949Ki26, 1952Se67, 1955Ko13, 1957Le21, 1957Cl16, 1959St45, +234TH2C 1959Ko58, 1959Ku81, 1961Ko11, 1964Fl07, 1967Sp12, 1968Ro15, 1970Ga27, +234TH3C 1971Le11, 1971Th17, 1971Kl14, 1971Ja07, 1973Kh10, 1974Iv01, 1975Wa37, +234TH4C 1975Em03, 1976Th12, 1978Ri07, 1978Ka40, 1980Sp10, 1980Po09, 1981Ba70, +234TH5C 1982De22, 1983El11, 1983Be66, 1984Va35, 1984Va34, 1984Ro21, 1985Iv01, +234TH6C 1987Al28, 1990Ko40, 1991Ry01, 1994Ak05, 1994Du15, 1996Sc06, 1996Ru11, +234TH7C 1998Ad08, 2000Ho27, 2000Ga05, 2002Ba85, 2002Ch52, 2003Au03, 2003Ha06, +234TH8C 2004Sc03 +234TH T Auger electrons and ^X ray energies and emission intensities: +234TH T {U Energy (keV)} {U Intensity } {U Line } +234TH T +234TH T 89.954 0.00109 30 XKA2 +234TH T 93.351 0.0018 5 XKA1 +234TH T +234TH T 104.819 |] XKB3 +234TH T 105.604 |] 0.00063 17 XKB1 +234TH T 106.239 |] XKB5II +234TH T +234TH T 108.509 |] XKB2 +234TH T 108.955 |] 0.00021 6 XKB4 +234TH T 109.442 |] XKO23 +234TH T +234TH T 11.118-19.504 7.94 28 XL (total) +234TH T 11.118 0.164 8 XLL +234TH T 12.8085-12.967 2.74 12 XLA +234TH T 14.509 0.092 5 XLC +234TH T 14.972-17.1383 4.01 18 XLB +234TH T 18.3633-19.504 0.94 4 XLG +234TH T +234TH T 68.406-76.745 |] KLL AUGER +234TH T 83.857-93.345 |] 0.00012 4 ^KLX AUGER +234TH T 99.29-109.64 |] KXY AUGER +234TH T 5.8-20.3 8.43 25 L AUGER +238U P 0.0 0+ 4.468E9 Y 5 4269.7 29 +234TH N 1.0 1.0 1 1.0 +234TH L 0 0 0+ 24.10 D 3 +234TH A 4198 3 77.5 5 1 +234TH L 49.55 6 2+ 0.37 NS 3 +234TH A 4151 5 22.3 5 1.33 +234TH G 49.55 6 0.0697 26E2 321 10 +234TH2 G KC=$LC=235 7$MC=64.4 19 +234TH L 163.0 1 4+ +234TH A 4038 5 0.13 3 24 +234TH G 113.5 1 0.0174 47[E2] 6.47 19 +234TH2 G KC=0.219 7$LC=4.57 14$MC=1.257 38 + diff --git a/HEN_HOUSE/spectra/lnhb/U-239.txt b/HEN_HOUSE/spectra/lnhb/U-239.txt new file mode 100644 index 000000000..26c11d0f3 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/U-239.txt @@ -0,0 +1,313 @@ +239NP 239U B- DECAY (23.46 M) +239NP H TYP=Update$AUT=V.Chechev$CUT=31-MAR-2009$ +239NP2 H TYP=Full$AUT=V. Chechev$CUT=01-AUG-2005$ +239NP3 H TYP=Update$AUT=MMBé$CUT= -- $ +239NP C Evaluation history: Type=Update;Author=V.Chechev;Cutoff date=31-MAR-2009 +239NP2C Type=Full;Author=V. Chechev;Cutoff date=01-AUG-2005 +239NP3C Type=Update;Author=MMBé;Cutoff date= -- +239NP C References: 1943Mi10, 1947Fe05, 1957Ho07, 1964Bl11, 1968Ma06, 1969Hu21, +239NP2C 1969Cl12, 1969En02, 1971Ar47, 1975Pa04, 1979Bo30, 1982Ah04, 1989Ab05, +239NP3C 1996Sa23, 2003Au03, 2003Br12, 2006WoO3, 2008Ki07 +239NP T Auger electrons and ^X ray energies and emission intensities: +239NP T {U Energy (keV)} {U Intensity } {U Line } +239NP T +239NP T 97.069 0.091 3 XKA2 +239NP T 101.059 0.144 5 XKA1 +239NP T +239NP T 113.303 |] XKB3 +239NP T 114.234 |] 0.052 2 XKB1 +239NP T 114.912 |] XKB5II +239NP T +239NP T 117.463 |] XKB2 +239NP T 117.876 |] 0.018 1 XKB4 +239NP T 118.429 |] XKO23 +239NP T +239NP T 11.871-21.491 16.1 5 XL (total) +239NP T 11.871 0.38 2 XLL +239NP T 13.671-13.946 7.0 2 XLA +239NP T 15.861 0.108 4 XLC +239NP T 16.109-17.992 6.9 2 XLB +239NP T 20.784-21.491 1.68 4 XLG +239NP T +239NP T 73.501-83.134 |] KLL AUGER +239NP T 90.358-101.054 |] 0.0091 13 ^KLX AUGER +239NP T 107.19-118.66 |] KXY AUGER +239NP T 6.04-13.12 14.7 7 L AUGER +239U P 0.0 5/2+ 23.46 M 5 1261.5 16 +239NP N 1.0 1.0 1 1.0 +239NP G 46.6 0.009 4 +239NP G 134.71 130.0019 3 +239NP G 142.5 1 0.0045 6 +239NP G 174.07 6 0.0097 3 +239NP G 220.52 4 0.0282 7 +239NP G 236.28 140.00092 18 +239NP G 262.89 190.0008 3 +239NP G 265.44 170.0009 3 +239NP G 330.14 140.00069 13 +239NP G 332.06 140.0012 2 +239NP G 348.23 180.0007 3 +239NP G 351.33 150.0007 2 +239NP G 361.83 8 0.0044 3 +239NP G 393.01 180.0006 2 +239NP G 400.55 150.0009 2 +239NP G 404.84 180.0009 3 +239NP G 445.81 120.0011 2 +239NP G 452.17 120.0016 2 +239NP G 478.13 190.00055 23 +239NP G 479.55 140.0010 2 +239NP G 490.33 130.0007 1 +239NP G 502.12 170.0006 2 +239NP G 506.80 140.0010 2 +239NP G 541.32 100.0029 3 +239NP G 558.46 170.0006 2 +239NP G 567.88 180.0004 1 +239NP G 575.27 5 0.0131 4 +239NP G 577.15 140.0014 3 +239NP G 585.49 140.0012 2 +239NP G 591.82 190.0009 4 +239NP G 599.13 150.0007 2 +239NP G 602.79 8 0.0048 3 +239NP G 604.85 6 0.00096 27 +239NP G 614.53 170.0006 2 +239NP G 618.03 160.0007 2 +239NP G 629.00 110.0027 3 +239NP G 649.79 190.0009 4 +239NP G 668.76 180.00055 18 +239NP G 670.88 200.0006 3 +239NP G 691.01 6 0.0074 3 +239NP G 692.61 130.0016 3 +239NP G 701.21 100.0024 2 +239NP G 714.22 9 0.0030 3 +239NP G 730.95 6 0.0090 3 +239NP G 746.06 110.0043 5 +239NP G 764.04 110.0026 3 +239NP G 768.15 110.0020 2 +239NP G 769.52 170.0004 1 +239NP G 795.13 150.0008 2 +239NP G 829.59 170.00046 13 +239NP G 831.89 9 0.0021 2 +239NP G 862.56 180.0004 1 +239NP G 913.68 9 0.0019 1 +239NP G 948.88 190.00024 10 +239NP G 970.07 140.0009 2 +239NP G 988.51 140.00044 9 +239NP G 1002.40 130.00049 9 +239NP G 1005.27 130.0006 1 +239NP G 1009.38 180.0003 1 +239NP G 1101.99 160.00031 1 +239NP L 0 5/2+ 2.356 D 3 +239NP B 1261.5 1614.4 22 6.7 +239NPS B EAV=418.6 5 +239NP L 31.1310 127/2+ +239NP B 1230.4 169.4 15 6.83 2 +239NPS B EAV=406.8 5 +239NP G 31.1310 120.072 4 M1+E2 0.17 1 263 13 +239NP2 G KC=$LC=195 10$MC=50 3 +239NP L 71.210 2 9/2+ +239NP G 71.210 2 0.00193 4 E2 71.9 14 +239NP2 G KC=$LC=52.3 10$MC=14.6 3 +239NP L 74.664 1 5/2- 1.39 NS 3 +239NP B 1186.5 1672.8 19 5.91 +239NPS B EAV=390.4 5 +239NP G 43.533 1 4.35 28E1 1.14 3 +239NP2 G KC=$LC=0.856 17$MC=0.215 4 +239NP G 74.664 1 51.6 13E1 0.276 6 +239NP2 G KC=$LC=0.207 4$MC=0.0512 10 +239NP L 117.727 207/2- 40 PS +239NP B 1143.9 162.2 4 7.4 1U +239NPS B EAV=374.0 5 +239NP G 43.06 2 0.013 2 M1+E2 0.38 38 154 18 +239NP2 G KC=$LC=114 13$MC=30 4 +239NP G 86.72 7 0.055 5 E1 0.186 4 +239NP2 G KC=$LC=0.140 3$MC=0.0344 7 +239NP G 117.727 200.113 9 E1 0.0841 17 +239NP2 G KC=$LC=0.0632 13$MC=0.0155 3 +239NP L 122.5 10(11/2)+ +239NP L 173.10 4 9/2- +239NP G 55.37 5 8.36E-5 20M1+E2 0.6 2 90 30 +239NP2 G KC=$LC=63 20$MC=17 6 +239NP L 241.36 5 (11/2-)- +239NP G 170.15 5 0.031 1 +239NP L 260.799 17(3/2)- +239NP G 186.15 4 0.0288 7 [M1+E2] 2.6 16 +239NP2 G KC=1.7 16$LC=0.645 13$MC=0.167 14 +239NP G 260.80 2 0.0031 2 [E1] 0.0549 11 +239NP2 G KC=0.0434 9$LC=0.0087 2$MC=0.00211 4 +239NP L 438.83 5 (11/2+)+ +239NP G 197.28 120.0024 3 +239NP L 448.178 16(3/2-)- +239NP G 187.28 8 0.0056 3 [M1+E2] 2.6 16 +239NP2 G KC=1.7 16$LC=0.631 13$MC=0.164 14 +239NP G 373.51 4 0.025 6 [M1+E2] 0.35 22 +239NP2 G KC=0.26 22$LC=0.07 3$MC=0.017 6 +239NP G 448.18 2 0.0090 3 [E1] 0.0173 4 +239NP2 G KC=0.0139 3$LC=0.00258 5$MC=0.00062 1 +239NP L 452.736 2 (5/2+,7/2-)+ +239NP G 378.06 6 0.0101 4 +239NP G 381.27 160.0006 2 +239NP L 474.36 6 + +239NP B 787.1 160.0033 4 +239NPS B EAV=244.0 5 +239NP G 399.13 130.0016 3 +239NP G 474.36 6 0.0017 2 +239NP L 517.998 20(7/2-)- +239NP B 743.5 160.063 2 1U +239NPS B EAV=228.6 5 +239NP G 486.87 3 0.0618 14[E1] 0.0147 4 +239NP2 G KC=0.0118 3$LC=0.00217 5$MC=0.00052 1 +239NP G 518.00 2 0.0045 3 [E1] 0.0130019 +239NP2 G KC=0.01050 15$LC=0.00190 4$MC=0.00046 1 +239NP L 530.29 6 + +239NP B 731.2 160.0029 4 +239NPS B EAV=224.3 5 +239NP G 455.63 6 0.0008 3 +239NP G 499.1 1 0.0021 2 +239NP L 563.89 4 + +239NP B 697.6 160.0247 7 +239NPS B EAV=212.6 5 +239NP G 111.0 2 0.0202 5 +239NP G 492.76 7 0.0050 2 +239NP G 532.86 100.0023 2 +239NP G 563.89 4 0.0004 2 +239NP L 579.40 4 (9/2-)- +239NP G 504.76 8 0.0052 3 [E2] 0.0488 10 +239NP2 G KC=0.0293 6$LC=0.0143 3$MC=0.0038 1 +239NP G 547.99 120.0020 3 [E1] 0.0117024 +239NP2 G KC=0.00941 19$LC=0.00170 4$MC=0.00041 1 +239NP L 662.282 17(5/2-)- +239NP B 599.2 160.261 6 7.35 +239NPS B EAV=179.0 5 +239NP G 544.48 9 0.0036 3 [M1+E2] 0.13 9 +239NP2 G KC=0.10 8$LC=0.022 11$MC=0.005 3 +239NP G 587.62 2 0.0193 5 [M1+E2] 0.11 7 +239NP2 G KC=0.08 6$LC=0.018 9$MC=0.004 2 +239NP G 631.10 3 0.067 2 [E1] 0.0089217 +239NP2 G KC=0.0072 2$LC=0.00128 3$MC=0.00031 1 +239NP G 662.28 2 0.170 5 [E1] 0.0081516 +239NP2 G KC=0.00660 13$LC=1170E-6 17$MC=0.00028 1 +239NP L 695.229 23(7/2-)- +239NP B 566.3 160.0118 11 1U +239NPS B EAV=168.0 5 +239NP G 522.12 100.0024 2 [M1+E2] 0.14 10 +239NP2 G KC=0.11 9$LC=0.025 13$MC=0.006 3 +239NP G 624.11 7 0.0062 3 [E1] 0.0091 2 +239NP2 G KC=0.00737 15$LC=0.00131 3$MC=0.00031 1 +239NP G 664.17 9 0.0054 4 [E1] 0.0081116 +239NP2 G KC=0.00657 13$LC=1160E-6 17$MC=0.00028 1 +239NP G 695.23 2 0.0036 3 [E1] 0.0074515 +239NP2 G KC=0.00604 13$LC=1060E-6 15$MC=0.00025 1 +239NP L 781.93 4 + +239NP G 707.38 9 0.0022 2 +239NP L 784.94 5 + +239NP G 710.35 153000E-6 0 +239NP L 819.26 3 (7/2)+ +239NP B 442.2 160.228 3 2 +239NPS B EAV=127.4 5 +239NP G 239.86 5 0.00087 23 +239NP G 255.37 5 0.0011 2 +239NP G 646.26 100.0029 3 +239NP G 748.09 3 0.0890 4 +239NP G 788.19 7 0.0049 2 +239NP G 819.26 3 0.129 3 +239NP L 844.10 3 (5/2,7/2)+ +239NP B 417.4 160.215 3 +239NPS B EAV=119.6 5 +239NP G 326.21 7 0.0044 2 +239NP G 772.94 9 0.0029 2 +239NP G 812.89 3 0.0685 3 +239NP G 844.10 3 0.139 3 +239NP L 849.44 9 + +239NP B 412.0 160.0264 4 +239NPS B EAV=117.8 5 +239NP G 588.70 8 0.0055 3 +239NP G 607.96 150.0013 3 +239NP G 727.52 100.0026 3 +239NP G 774.77 4 0.015 4 +239NP G 849.44 9 0.0020 2 +239NP L 863.46 6 (3/2,5/2,7/2)+ +239NP B 398.1 160.0005 2 2 +239NPS B EAV=113.4 5 +239NP G 201.18 6 0.0005 2 +239NP L 959.18 3 + +239NP B 302.3 160.0284 7 +239NPS B EAV=83.9 5 +239NP G 296.93 13 [M1+E2] 0.7 5 +239NP2 G KC=0.5 4$LC=0.13 4$MC=0.034 9 +239NP G 395.19 110.0021 2 +239NP G 841.45 4 0.0025 4 +239NP G 884.45 5 0.0086 2 +239NP G 887.97 3 0.0023 2 +239NP G 928.05 3 0.0051 2 +239NP G 959.18 3 0.0078 3 +239NP L 964.234 20(7/2-)- +239NP B 297.3 160.211 3 1U +239NPS B EAV=82.4 5 +239NP G 301.95 3 0.0011 3 [M1+E2] 0.6 5 +239NP2 G KC=0.5 4$LC=0.13 4$MC=0.032 9 +239NP G 703.63 100.0023 2 [E2] 0.0234 5 +239NP2 G KC=0.0162 3$LC=0.00537 11$MC=0.00138 3 +239NP G 722.85 4 0.0270 7 [E2] 0.0222 4 +239NP2 G KC=0.0155 3$LC=0.00499 10$MC=1060E-6 18 +239NP G 791.13 5 0.0075 2 +239NP G 846.39 4 0.0312 8 [M1+E2] 0.04 3 +239NP2 G KC=0.032 21$LC=0.007 4$MC=0.0016 8 +239NP G 889.49 4 0.0209 5 [M1+E2] 0.036 22 +239NP2 G KC=0.029 18$LC=0.006 3$MC=0.0014 7 +239NP G 933.09 3 0.0262 6 [E1] 0.004399 +239NP2 G KC=0.00358 7$LC=0.00061 1$MC=0.00015 1 +239NP G 964.23 2 0.0905 20[E1] 0.004158 +239NP2 G KC=0.00338 7$LC=0.00058 1$MC=0.00014 1 +239NP L 966.55 5 (7/2,9/2-)- +239NP B 295.0 160.0008 2 1U +239NPS B EAV=81.7 5 +239NP G 895.15 150.0008 2 +239NP L 992.158 22(7/2-)- +239NP B 269.3 160.0262 9 1U +239NPS B EAV=74.0 5 +239NP G 296.93 130.0014 2 [M1+E2] 0.7 5 +239NP2 G KC=0.5 4$LC=0.13 4$MC=0.034 9 +239NP G 869.57 9 0.0016 1 +239NP G 874.43 3 0.0033 2 [M1+E2] 0.038 23 +239NP2 G KC=0.030 19$LC=0.006 4$MC=0.0015 8 +239NP G 917.40 8 0.0027 1 [M1+E2] 0.034 22 +239NP2 G KC=0.026 17$LC=0.005 3$MC=0.0013 7 +239NP G 920.95 8 0.0026 1 [E1] 0.004509 +239NP2 G KC=0.00366 6$LC=0.00063 1$MC=0.00015 1 +239NP G 960.99 5 0.0105 3 [E1] 0.004179 +239NP2 G KC=0.00340 7$LC=0.00058 1$MC=0.00014 1 +239NP G 992.16 2 0.0028 1 [E1] 0.003958 +239NP2 G KC=0.00322 7$LC=0.00055 1$MC=0.00013 1 +239NP L 1013.64 8 - +239NP B 247.9 160.0074 4 +239NPS B EAV=67.6 5 +239NP G 560.63 7 0.0058 3 +239NP G 752.84 8 0.0013 3 +239NP G 938.98 8 0.00031 8 +239NP L 1040.37 4 (5/2-,7/2)+ +239NP B 221.1 160.0077 4 +239NPS B EAV=59.9 5 +239NP G 258.44 6 0.00073 18 +239NP G 345.13 8 0.0039 2 +239NP G 779.57 140.0006 1 +239NP G 867.11 110.00076 8 +239NP G 922.83 130.0006 1 +239NP G 1040.37 4 0.0011 1 +239NP L 1049.24 4 (9/2-)- +239NP B 212.3 160.0059 4 3U +239NPS B EAV=57.3 5 +239NP G 931.51 5 0.0053 3 [M1+E2] 0.032 19 +239NP2 G KC=0.026 16$LC=0.005 3$MC=0.0013 7 +239NP G 974.58 4 0.00040 8 [E2] 0.0123 5 +239NP2 G KC=0.00917 18$LC=0.00234 5$MC=0.00059 1 +239NP L 1096.99 3 - +239NP B 164.5 160.0060 5 +239NPS B EAV=43.7 5 +239NP G 312.05 3 6000E-7 0 +239NP G 434.71 4 0.0012 2 (E1) 0.0184 4 +239NP2 G KC=0.0148 3$LC=0.00276 5$MC=0.00066 1 +239NP G 644.253 300.0019 4 +239NP G 1065.76 120.00059 8 [M1+E2] 0.023 13 +239NP2 G KC=0.018 11$LC=0.004 2$MC=0.0009 4 +239NP G 1096.99 3 0.0016 1 [M1+E2] 0.022 13 +239NP2 G KC=0.017 11$LC=0.003 2$MC=0.0008 4 + diff --git a/HEN_HOUSE/spectra/lnhb/Xe-127.txt b/HEN_HOUSE/spectra/lnhb/Xe-127.txt new file mode 100644 index 000000000..349d3958b --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Xe-127.txt @@ -0,0 +1,57 @@ +127I 127XE EC DECAY (36.358 D) +127I C References: 1940CR06, 1950AN05, 1954BA71, 1958F048, 1962TH12, 1964JH02, +127I 2C 1964BR26, 1965LA01, 1965WI12, 1965GE04, 1966LE09, 1966GE13, 1967SV01, +127I 3C 1967GE10, 1968KO01, 1968SC14, 1969GUZV, 1969LA08, 1969BEZH, 1970AP02, +127I 4C 1974CO05, 1975AN19, 1976LE23, 1977GE10, 1979AL14, 2002UN02, 2011HA31, +127I 5C 2012WA38, 2012FI12 +127I T Auger electrons and ^X ray energies and emission intensities: +127I T {U Energy (keV)} {U Intensity } {U Line } +127I T +127I T 28.3175 25.0 4 XKA2 +127I T 28.6123 46.5 8 XKA1 +127I T +127I T 32.2397 |] XKB3 +127I T 32.2951 |] 13.39 25 XKB1 +127I T 32.544 |] XKB5II +127I T +127I T 33.042 |] XKB2 +127I T 33.12 |] 3.03 9 XKB4 +127I T 33.166 |] XKO23 +127I T +127I T 3.4848-5.0595 9.60 19 XL (total) +127I T 3.4848 0.184 6 XLL +127I T 3.9269-3.9382 4.85 13 XLA +127I T 3.7791 0.0706 22 XLC +127I T 4.2212-4.5678 3.93 9 XLB +127I T 4.6668-5.0595 0.569 13 XLG +127I T +127I T 22.66-23.91 |] KLL AUGER +127I T 26.85-28.56 |] 11.8 5 ^KLX AUGER +127I T 30.99-33.07 |] KXY AUGER +127I T 2.4-5.1 96.4 6 L AUGER +127XE P 0.0 1/2+ 36.358 D 31 662.3 20 +127I N 1.0 1.0 1 1.0 +127I L 0 5/2+ STABLE +127I L 57.609 117/2+ 1.95 NS 1 +127I G 57.61 2 1.272 35M1+()E2 -0.083 5 3.72 6 +127I 2 G KC=3.16 5$LC=0.449 8$MC=0.0910 16 +127I L 202.860 8 3/2+ 0.387 NS 6 +127I E 52.7 146.61 2 +127I 2 E EAV= $CK=0.842 8$CL=0.125 1$CM=0.0272 5$CN=0.0062 3$CO= +127I G 145.252 104.23 7 E2 0.471 7 +127I 2 G KC=0.357 5$LC=0.0906 13$MC=0.0189 3 +127I G 202.86 1 68.45 45M1+()E2 0.517 27 0.1142 18 +127I 2 G KC=0.0964 15$LC=0.0142 3$MC=0.00289 6 +127I L 374.992 9 1/2+ 31 PS 8 +127I E 47.3 7 6.21 +127I 2 E EAV= $CK=0.830 8$CL=0.134 1$CM=0.0294 6$CN=0.0067 4$CO= +127I G 172.132 1025.53 38M1+()E2 -0.085 6 0.1649 24 +127I 2 G KC=0.1419 20$LC=0.0185 3$MC=0.00373 6 +127I G 374.991 1217.26 27E2 0.0199 3 +127I 2 G KC=0.01671 24$LC=0.00257 4$MC=5.24E-4 8 +127I L 618.4 3 3/2+ +127I E 0.0142 9 7.42 2 +127I 2 E EAV= $CK=0.31 6$CL=0.523 44$CM=0.137 12$CN=0.0324 32$CO= +127I G 618.41 140.0141 9 M1+()E2 0.081 18 0.006099 +127I 2 G KC=0.00528 8$LC=6.56E-4 10$MC=1316E-7 19 + diff --git a/HEN_HOUSE/spectra/lnhb/Xe-131m.txt b/HEN_HOUSE/spectra/lnhb/Xe-131m.txt new file mode 100644 index 000000000..ee8e5adc7 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Xe-131m.txt @@ -0,0 +1,40 @@ +131XE 131XE IT DECAY (11.962 D) +131XE H TYP=Full$AUT=M.M. Bé$CUT=30-NOV-2013$ +131XE2 H TYP=Full$AUT=V. Chisté$CUT=30-DEC-2002$ +131XE C Evaluation history: Type=Full;Author=M.M. Bé;Cutoff date=30-NOV-2013 +131XE2C Type=Full;Author=V. Chisté;Cutoff date=30-DEC-2002 +131XE C References: 1952Be55, 1954Be36, 1962Ge01, 1964An08, 1966Kn09, 1969fr04, +131XE2C 1972Em09, 1973Be06, 1974Me21, 1975Ho12, 1976Au08, 1990Ta02, 1994Se07, +131XE3C 1996Sc33, 2002Ba85, 2008Ki07, 2012Wa38, 2012Fi12 +131XE T Auger electrons and ^X ray energies and emission intensities: +131XE T {U Energy (keV)} {U Intensity } {U Line } +131XE T +131XE T 29.459 15.5 4 XKA2 +131XE T 29.779 28.7 7 XKA1 +131XE T +131XE T 33.562 |] XKB3 +131XE T 33.625 |] 8.31 22 XKB1 +131XE T 33.881 |] XKB5II +131XE T +131XE T 34.415 |] XKB2 +131XE T 34.496 |] 1.96 7 XKB4 +131XE T 34.552 |] XKO23 +131XE T +131XE T 3.64-5.3 8.12 16 XL (total) +131XE T 3.64 0.160 5 XLL +131XE T 4.1-4.11 4.20 11 XLA +131XE T 3.96 0.0537 17 XLC +131XE T 4.42-4.78 3.22 7 XLB +131XE T 4.89-5.3 0.479 10 XLG +131XE T +131XE T 23.512-24.842 |] KLL AUGER +131XE T 27.897-29.77 |] 6.9 4 ^KLX AUGER +131XE T 32.27-34.54 |] KXY AUGER +131XE T 2.5-5.43 75.8 5 L AUGER +131XE P 163.930 8 11/2- 11.962 D 20 +131XE N 1.0 1.0 1 1.0 +131XE L 0 3/2+ STABLE +131XE L 163.930 8 11/2- 11.962 D 20 +131XE G 163.930 8 1.942 26M4 50.5 7 +131XE2 G KC=31.6 5$LC=14.75 21$MC=3.38 5 + diff --git a/HEN_HOUSE/spectra/lnhb/Xe-133.txt b/HEN_HOUSE/spectra/lnhb/Xe-133.txt new file mode 100644 index 000000000..e78d7d54c --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Xe-133.txt @@ -0,0 +1,60 @@ +133CS 133XE B- DECAY (5.2474 D) +133CS H TYP=Update$AUT=M.Galan$CUT= -- $ +133CS2 H TYP=Full$AUT=M.Galan$CUT=01-AUG-2007$ +133CS C Evaluation history: Type=Update;Author=M.Galan;Cutoff date= -- +133CS2C Type=Full;Author=M.Galan;Cutoff date=01-AUG-2007 +133CS C References: 1940WU05, 1941CL02, 1945WU05, 1950MA01, 1952BE55, 1953GR07, +133CS2C 1954BE36, 1955LE18, 1958AL98, 1959BO56, 1961ER04, 1962TH12, 1963GO17, +133CS3C 1965GE04, 1966TH09, 1968AL16, 1972EM01, 1974CA27, 1974FOZY, 1975HO18, +133CS4C 1975WO10, 1977KR13, 1989RA17, 1992UN01, 1992MA05, 1995RA12, 1996SC06, +133CS5C 2000HE14, 2002BA85, 2002UN02, 2003AU03 +133CS T Auger electrons and ^X ray energies and emission intensities: +133CS T {U Energy (keV)} {U Intensity } {U Line } +133CS T +133CS T 30.6254 13.54 24 XKA2 +133CS T 30.9731 25.0 5 XKA1 +133CS T +133CS T 34.9197 |] XKB3 +133CS T 34.9873 |] 7.31 15 XKB1 +133CS T 35.252 |] XKB5II +133CS T +133CS T 35.822 |] XKB2 +133CS T 35.907 |] 1.78 6 XKB4 +133CS T 35.972 |] XKO23 +133CS T +133CS T 3.795-5.553 5.79 11 XL (total) +133CS T 3.795 0.111 3 XLL +133CS T 4.273-4.287 2.91 8 XLA +133CS T 4.142 0.0429 13 XLC +133CS T 4.62-4.988 2.37 5 XLB +133CS T 5.131-5.553 0.359 8 XLG +133CS T +133CS T 24.411-25.804 |] KLL AUGER +133CS T 28.991-30.961 |] 5.65 24 ^KLX AUGER +133CS T 33.55-35.96 |] KXY AUGER +133CS T 2.5-5.6 49.9 3 L AUGER +133XE P 0.0 3/2+ 5.2474 D 5 427.4 24 +133CS N 1.0 1.0 1 1.0 +133CS L 0 0 7/2+ STABLE +133CS L 80.9979 115/2+ 6.31 NS 6 +133CS B 346.4 2499.12 8 5.62 2 +133CSS B EAV=100.6 8 +133CS G 80.9979 1137.0 3 M1+E2 -0.151 2 1.698 24 +133CS2 G KC=1.429 20$LC=0.214 3$MC=0.0442 6 +133CS L 160.6120 165/2+ +133CS B 266.8 240.87 8 7.31 2 +133CSS B EAV=75.2 8 +133CS G 79.6142 120.28 3 M1+E2 0.124 15 1.768 26 +133CS2 G KC=1.495 21$LC=0.217 6$MC=0.0447 12 +133CS G 160.6120 160.068 8 M1+E2 0.96 5 0.294 5 +133CS2 G KC=0.234 4$LC=0.0471 13$MC=0.0099 3 +133CS L 383.8485 123/2+ +133CS B 43.6 240.0092 9 6.84 +133CSS B EAV=11.1 7 +133CS G 223.2368 130.00017 6 M1+E2 -0.114 14 0.0975 14 +133CS2 G KC=0.0836 12$LC=0.01103 16$MC=0.00226 3 +133CS G 302.8508 5 0.0058 8 M1+E2 0.022 20 0.0434 6 +133CS2 G KC=0.0373 5$LC=0.00484 7$MC=9.88E-4 14 +133CS G 383.8485 120.0028 4 E2 0.0202 3 +133CS2 G KC=0.01684 24$LC=0.00269 4$MC=5.59E-4 8 + diff --git a/HEN_HOUSE/spectra/lnhb/Xe-133m.txt b/HEN_HOUSE/spectra/lnhb/Xe-133m.txt new file mode 100644 index 000000000..f636b6e0d --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Xe-133m.txt @@ -0,0 +1,38 @@ +133XE 133XE IT DECAY (2.198 D) +133XE H TYP=Full$AUT=M.Galan$CUT= -- $ +133XE C Evaluation history: Type=Full;Author=M.Galan;Cutoff date= -- +133XE C References: 1951BE11, 1952BE55, 1954BE36, 1961ER04, 1968AL16, 1969FR09, +133XE2C 1972AC02, 1974FOZY, 1975HO18, 1976ME16, 1989RA17, 1995RA12, 1996SC06, +133XE3C 2002BA85 +133XE T Auger electrons and ^X ray energies and emission intensities: +133XE T {U Energy (keV)} {U Intensity } {U Line } +133XE T +133XE T 29.459 16.0 4 XKA2 +133XE T 29.779 29.7 6 XKA1 +133XE T +133XE T 33.562 |] XKB3 +133XE T 33.625 |] 8.61 20 XKB1 +133XE T 33.881 |] XKB5II +133XE T +133XE T 34.415 |] XKB2 +133XE T 34.496 |] 2.03 7 XKB4 +133XE T 34.552 |] XKO23 +133XE T +133XE T 3.638-5.296 7.6 4 XL (total) +133XE T 3.638 0.146 5 XLL +133XE T 4.098-4.11 3.84 10 XLA +133XE T 3.958 0.0530 16 XLC +133XE T 4.418-4.776 3.07 7 XLB +133XE T 4.895-5.296 0.457 10 XLG +133XE T +133XE T 23.512-24.842 |] KLL AUGER +133XE T 27.897-29.77 |] 7.1 4 ^KLX AUGER +133XE T 32.27-34.54 |] KXY AUGER +133XE T 2.4-5.2 70.4 10 L AUGER +133XE P 233.219 1511/2- 2.198 D 13 +133XE N 1.0 1.0 1 1.0 +133XE L 0 0 3/2+ 5.2474 D 5 +133XE L 233.219 1511/2- 2.198 D 13 +133XE G 233.219 1510.16 13M4 8.84 13 +133XE2 G KC=6.25 9$LC=2.04 3$MC=0.453 7 + diff --git a/HEN_HOUSE/spectra/lnhb/Xe-135m.txt b/HEN_HOUSE/spectra/lnhb/Xe-135m.txt new file mode 100644 index 000000000..4dfdbbe22 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Xe-135m.txt @@ -0,0 +1,88 @@ +135XE 135XE IT DECAY (15.30 M) +135XE H TYP=Full$AUT=M. Galan$CUT=30-MAY-2008$ +135XE C Evaluation history: Type=Full;Author=M. Galan;Cutoff date=30-MAY-2008 +135XE C References: 1960AL12, 1960KO02, 1968HA52, 1968AL16, 1968TO20, 1971GO40, +135XE2C 1971HA13, 1972AC02, 1974FOZY, 1974MEZV, 1975FU12, 1976FE04, 1979BO26, +135XE3C 1982WA21, 1989RA17, 1996SC06, 2002BA85, 2003AU03, 2008SI01 +135XE T Auger electrons and ^X ray energies and emission intensities: +135XE T {U Energy (keV)} {U Intensity } {U Line } +135XE T +135XE T 29.459 3.90 7 XKA2 +135XE T 29.779 7.22 12 XKA1 +135XE T +135XE T 33.562 |] XKB3 +135XE T 33.625 |] 2.09 4 XKB1 +135XE T 33.881 |] XKB5II +135XE T +135XE T 34.415 |] XKB2 +135XE T 34.496 |] 0.494 14 XKB4 +135XE T 34.552 |] XKO23 +135XE T +135XE T 3.638-5.296 1.637 30 XL (total) +135XE T 3.638 0.0313 9 XLL +135XE T 4.0977-4.1103 0.822 21 XLA +135XE T 3.9576 0.0120 4 XLC +135XE T 4.4176-4.7758 0.672 14 XLB +135XE T 4.895-5.296 0.0999 21 XLG +135XE T +135XE T 23.512-24.842 |] KLL AUGER +135XE T 27.897-29.77 |] 1.73 8 ^KLX AUGER +135XE T 32.27-34.54 |] KXY AUGER +135XE T 2.5-5.3 15.21 9 L AUGER +135XE P 526.570 5 11/2- 15.30 M 3 +135XE N 1.00E0 1.00E0 0.99996 1.00E0 +135XE L 0 3/2+ 9.14 H 2 +135XE L 526.570 5 11/2- 15.30 M 3 +135XE G 526.570 5 80.84 20M4 0.237 3 +135XE2 G KC=0.1908 27$LC=0.0364 5$MC=0.0077 1 + +135CS 135XE B- DECAY (15.30 M) +135CS H TYP=Full$AUT=M. Galan$CUT=30-MAY-2008$ +135CS C Evaluation history: Type=Full;Author=M. Galan;Cutoff date=30-MAY-2008 +135CS C References: 1960AL12, 1960KO02, 1968HA52, 1968AL16, 1968TO20, 1971GO40, +135CS2C 1971HA13, 1972AC02, 1974FOZY, 1974MEZV, 1975FU12, 1976FE04, 1979BO26, +135CS3C 1982WA21, 1989RA17, 1996SC06, 2002BA85, 2003AU03, 2008SI01 +135CS T Auger electrons and ^X ray energies and emission intensities: +135CS T {U Energy (keV)} {U Intensity } {U Line } +135CS T +135CS T 30.6254 XKA2 +135CS T 30.9731 XKA1 +135CS T +135CS T 34.9197 |] XKB3 +135CS T 34.9873 |] XKB1 +135CS T 35.252 |] XKB5II +135CS T +135CS T 35.822 |] XKB2 +135CS T 35.907 |] XKB4 +135CS T 35.972 |] XKO23 +135CS T +135CS T 3.7946 XLL +135CS T 4.2729-4.2866 XLA +135CS T 4.1418 XLC +135CS T 4.62-4.9881 XLB +135CS T 5.1308-5.5525 XLG +135CS T +135CS T 24.411-25.804 |] KLL AUGER +135CS T 28.991-30.961 |] ^KLX AUGER +135CS T 33.55-35.96 |] KXY AUGER +135CS T 2.5-5.6 L AUGER +135XE P 526.570 5 11/2- 15.30 M 3 1165.4 40 +135CS N 2.50E4 2.50E4 0.00004 2.50E4 +135CS L 0 7/2+ 2.3E6 Y 3 +135CS L 786.9 11/2+ +135CS B 905.1 400.0036 18 8.7 +135CSS B EAV=306 17 +135CS G 786.89 0.0036 18E2 +135CS L 1133 (9/2)+ +135CS B 559 4 0.00024 9.2 1U +135CSS B EAV=173.9 15 +135CS G 1133 2400E-7 0 +135CS L 1192 (11/2)- +135CS B 500 4 32000E-9 9.9 +135CSS B EAV=152.8 15 +135CS G 1192 3200E-8 0 +135CS L 1358 + +135CS B 334 4 0.00016 8.7 +135CSS B EAV=96.4 13 +135CS G 1358 1600E-7 0 E1 + diff --git a/HEN_HOUSE/spectra/lnhb/Y-88.txt b/HEN_HOUSE/spectra/lnhb/Y-88.txt new file mode 100644 index 000000000..9faca61d2 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Y-88.txt @@ -0,0 +1,62 @@ + 88SR 88Y EC DECAY (106.63 D) + 88SR C References: 1940Du09, 1948Pe13, 1952Me50, 1960Ra20, 1960Pe23, 1961Wy01, + 88SR2C 1964Sh16, 1965An07, 1966Sa08, 1966Ha07, 1969Gr12, 1971Ja21, 1971Go40, + 88SR3C 1971Al06, 1973SC40, 1974BaYZ, 1974Ar12, 1974HeYW, 1975La16, 1976Bo19, + 88SR4C 1977Ko**, 1979An36, 1980Yo05, 1980Ho17, 1982HoZJ, 1982DeYX, 1983Wa26, + 88SR5C 1988Mu09, 1990Sc08, 1992Un01, 1994Ko34, 1997Ma75, 2000Sc47, 2002Ba85, + 88SR6C 2002Un02, 2004BeZR, 2005Am01, 2008Ki07, 2012Fi12, 2012Wa38, 2014Mc01, + 88SR7C 2014Un01 + 88SR T Auger electrons and ^X ray energies and emission intensities: + 88SR T {U Energy (keV)} {U Intensity } {U Line } + 88SR T + 88SR T 14.098 17.55 16 XKA2 + 88SR T 14.1652 33.71 26 XKA1 + 88SR T + 88SR T 15.8252 |] XKB3 + 88SR T 15.8359 |] 8.32 10 XKB1 + 88SR T 15.969 |] XKB5II + 88SR T + 88SR T 16.0847 |] XKB2 + 88SR T 16.104 |] 1.08 4 XKB4 + 88SR T + 88SR T 1.5833-2.1971 2.76 5 XL (total) + 88SR T 1.5833 0.0670 17 XLL + 88SR T 1.8054-1.8071 1.73 4 XLA + 88SR T 1.6501 0.0285 7 XLC + 88SR T 1.8722-1.9466 0.921 22 XLB + 88SR T 1.9707-2.1971 0.01489 29 XLG + 88SR T + 88SR T 11.587-12.134 |] KLL AUGER + 88SR T 13.498-14.145 |] 26.5 4 ^KLX AUGER + 88SR T 15.39-16.065 |] KXY AUGER + 88SR T 1.2246-2.1944 103.8 5 L AUGER + 88Y P 0.0 4- 106.63 D 5 3622.6 15 + 88SR N 1.0 1.0 1 1.0 + 88SR L 0 0+ STABLE + 88SR L 1836.090 8 2+ 0.154 PS 8 + 88SR E 0.21 1 5.7 3 9.8 1U + 88SR2 E EAV=359.5 7$CK=0.8393 3$CL=0.100085 4$CM=0.02206 8$CN= $CO= + 88SR G 1836.070 8 99.346 25E2 1.63E-42 + 88SR2 G KC=1449E-7 21$LC=1550E-8 22$MC=2.60E-6 4 + 88SR L 2734.137 8 3- 0.70 PS 5 + 88SR E 94.3 3 6.9 + 88SR2 E EAV= $CK=0.8726 15$CL=0.1046 14$CM=0.0229 6$CN=0.0030 2$CO=0 0 + 88SR G 898.042 1193.7 3 E1(+M2) -0.002 9 3.07E-45 + 88SR2 G KC=2.73E-4 4$LC=2.92E-5 4$MC=4.89E-6 7 + 88SR G 2734.092 8 0.608 25(E3) 1.24E-42 + 88SR2 G KC=1098E-7 16$LC=1176E-8 17$MC=1.97E-6 3 + 88SR L 3218.489 222+ 0.154 PS 10 + 88SR E 0.023 4 9.5 1U + 88SR2 E EAV= $CK=0.8521 2$CL=0.1209 1$CM=0.02701 3$CN=0.0031 2$CO=0 0 + 88SR G 484.352 230.0009 9 [E1] 1217E-617 + 88SR2 G KC=1079E-6 16$LC=1165E-7 17$MC=1.95E-5 3 + 88SR G 1382.387 230.016 3 M1+E2 0.04 2 2.88E-44 + 88SR2 G KC=2.55E-4 4$LC=2.73E-5 4$MC=4.58E-6 7 + 88SR G 3218.426 220.0071 20E2 6.13E-58 + 88SR2 G KC=5.45E-5 8$LC=5.77E-6 8$MC=9.67E-7 14 + 88SR L 3584.784 195- 0.14 NS 4 + 88SR E 0.048 187 + 88SR2 E EAV= $CK=0.721 12$CL=0.225 10$CM=0.0542 25$CN=0.0072 5$CO=0 0 + 88SR G 850.643 210.048 18E2 8.53E-412 + 88SR2 G KC=7.54E-4 11$LC=8.28E-5 12$MC=1.39E-5 2 + diff --git a/HEN_HOUSE/spectra/lnhb/Y-90.txt b/HEN_HOUSE/spectra/lnhb/Y-90.txt new file mode 100644 index 000000000..d14058e4d --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Y-90.txt @@ -0,0 +1,52 @@ + 90ZR 90Y B- DECAY (2.6684 D) + 90ZR H TYP=Update$AUT=M.M. Bé$CUT= -- $ + 90ZR2 H TYP=Update$AUT=M.M.Bé$CUT= -- $ + 90ZR3 H TYP=Full$AUT=V Chiste$CUT= -- $ + 90ZR C Evaluation history: Type=Update;Author=M.M. Bé;Cutoff date= -- + 90ZR2C Type=Update;Author=M.M.Bé;Cutoff date= -- + 90ZR3C Type=Full;Author=V Chiste;Cutoff date= -- + 90ZR C References: 1937Po04, 1937St01, 1938Sa**, 1940Sa08, 1946Bo09, 1954Ch05, + 90ZR2C 1955Sa13, 1955Vo03, 1956He77, 1957Pe09, 1958Jo33, 1961He09, 1961La07, + 90ZR3C 1961Ni02, 1962Ne02, 1963Vo02, 1964La13, 1964Da16, 1964An12, 1966Ri01, + 90ZR4C 1967Bi02, 1968La10, 1969Gr38, 1971Na09, 1972Le**, 1976Gr16, 1983Ha35, + 90ZR5C 1990Zh20, 1993Gr17, 1996Sc06, 1997Br34, 2002Ba85, 2004Ko18, 2007Se01, + 90ZR6C 2007St**, 2008Ki07, 2012Wa38 + 90ZR T Auger electrons and ^X ray energies and emission intensities: + 90ZR T {U Energy (keV)} {U Intensity } {U Line } + 90ZR T + 90ZR T 15.6906 XKA2 + 90ZR T 15.7749 XKA1 + 90ZR T + 90ZR T 17.6541 |] XKB3 + 90ZR T 17.6674 |] XKB1 + 90ZR T 17.8152 |] XKB5II + 90ZR T 17.818 |] XKB5I + 90ZR T + 90ZR T 17.9691 |] XKB2 + 90ZR T 18.0001 |] XKB4 + 90ZR T + 90ZR T 1.7932 XLL + 90ZR T 2.0403-2.0431 XLA + 90ZR T 1.8774 XLC + 90ZR T 2.1246-2.2252 XLB + 90ZR T 2.2579-2.5044 XLG + 90ZR T + 90ZR T 12.843-13.455 |] KLL AUGER + 90ZR T 15-15.772 |] ^KLX AUGER + 90ZR T 17.137-17.992 |] KXY AUGER + 90ZR T 0.04-2.5256 L AUGER + 90Y P 0.0 2- 2.6684 D 13 2278.7 16 + 90ZR N 1.0 1.0 1 1.0 + 90ZR L 0 0+ STABLE + 90ZR B 2278.7 1699.983 7 8.05 1U + 90ZRS B EAV=926.7 8 + 90ZR L 1760.72 200+ + 90ZR B 518.0 160.017 7 9.4 1U + 90ZRS B EAV=163.7 6 + 90ZR G 1760.7 2 + 90ZR L 2186.282 102+ + 90ZR B 92.4 1614000E-13 11.1 + 90ZRS B EAV=24.5 5 + 90ZR G 2186.254 101.4E-6 3 E2 5.36E-48 + 90ZR2 G KC=$LC=$MC= + diff --git a/HEN_HOUSE/spectra/lnhb/Y-90m.txt b/HEN_HOUSE/spectra/lnhb/Y-90m.txt new file mode 100644 index 000000000..6fec2213d --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Y-90m.txt @@ -0,0 +1,76 @@ + 90Y 90Y IT DECAY (3.19 H) + 90Y H TYP=FULL$AUT=V Chisté$CUT= -- $ + 90Y C Evaluation history: Type=FULL;Author=V Chisté;Cutoff date= -- + 90Y T Auger electrons and X ray energies and emission intensities: + 90Y T {U Energy (keV)} {U Intensity} {U Line} + 90Y T + 90Y T 14.8829 2.02 6 XKA2 + 90Y T 14.9585 3.88 10 XKA1 + 90Y T + 90Y T 16.7259 |] XKB3 + 90Y T 16.7381 |] 0.973 27 XKB1 + 90Y T 16.88 |] XKB5II + 90Y T + 90Y T 17.0156 |] XKB2 + 90Y T 17.0362 |] 0.134 6 XKB4 + 90Y T + 90Y T 1.6865-2.3482 0.343 8 XL (total) + 90Y T 1.6865 0.00823 27 XLL + 90Y T 1.9211-1.9233 0.215 7 XLA + 90Y T 1.7617 0.00343 12 XLC + 90Y T 1.9962-2.0713 0.114 4 XLB + 90Y T 2.1118-2.3482 0.00191 4 XLG + 90Y T + 90Y T 12.205-12.784 |] KLL AUGER + 90Y T 14.238-14.956 |] 2.78 8 KLX AUGER + 90Y T 16.251-17.034 |] KXY AUGER + 90Y T 1.2-2.3 11.56 10 L AUGER + 90Y P 682.04 0 7+ 3.19 H 6 + 90Y N 1.00E0 1.00E0 0.999981 1.00E0 + 90Y L 0 2- 2.6684 D 13 + 90Y L 202.53 3 3+ 250 PS 7 + 90Y G 202.53 3 97.1 14M1+E2 -0.04 4 0.0272 8 + 90Y 2 G KC=0.0240 7$LC=0.00272 8$MC=4.65E-4 14 + 90Y L 682.04 6 7+ 3.18 H 5 + 90Y G 479.51 7 90.97 24M4(+E5) 0.0957 29 + 90Y 2 G KC=0.0818 25$LC=0.01157 35$MC=0.00202 6 + 90Y G 682.04 6 0.322 22E5 0.0225 7 + 90Y 2 G KC=0.0190 6$LC=0.00292 9$MC=5.07E-4 15 + + 90ZR 90Y B- DECAY (3.19 H) + 90ZR H TYP=FULL$AUT=V Chisté$CUT= -- $ + 90ZR C Evaluation history: Type=FULL;Author=V Chisté;Cutoff date= -- + 90ZR T Auger electrons and X ray energies and emission intensities: + 90ZR T {U Energy (keV)} {U Intensity} {U Line} + 90ZR T + 90ZR T 15.6906 1.81E-7 19 XKA2 + 90ZR T 15.7749 3.5E-7 4 XKA1 + 90ZR T + 90ZR T 17.6541 |] XKB3 + 90ZR T 17.6674 |] 8.8E-8 9 XKB1 + 90ZR T 17.8152 |] XKB5II + 90ZR T 17.818 |] XKB5I + 90ZR T + 90ZR T 17.9691 |] XKB2 + 90ZR T 18.0001 |] 1.29E-8 14 XKB4 + 90ZR T + 90ZR T 1.7932-2.5044 3.15E-8 19 XL (total) + 90ZR T 1.7932 75E-11 6 XLL + 90ZR T 2.0403-2.0431 1.99E-8 15 XLA + 90ZR T 1.8774 292E-12 29 XLC + 90ZR T 2.1246-2.2252 1.03E-8 9 XLB + 90ZR T 2.2579-2.5044 320E-12 17 XLG + 90ZR T + 90ZR T 12.843-13.455 |] KLL AUGER + 90ZR T 15-15.772 |] 2.28E-7 23 KLX AUGER + 90ZR T 17.137-17.992 |] KXY AUGER + 90ZR T 1.4-2.1 9.76E-7 27 L AUGER + 90Y P 682.04 0 7+ 3.19 H 6 2279.8 17 + 90ZR N 5.263E4 5.263E4 0.000019 5.263E4 + 90ZR L 0 0+ STABLE + 90ZR L 2318.99 2 5- 809.2 MS 20 + 90ZR B 642.9 170.0019 2 9.6 1U + 90ZRS B EAV=231.9 7 + 90ZR G 2318.958 200.0019 2 E5 4.63E-414 + 90ZR2 G KC=4.08E-4 12$LC=4.63E-5 14$MC=8.04E-6 24 + diff --git a/HEN_HOUSE/spectra/lnhb/Yb-169.txt b/HEN_HOUSE/spectra/lnhb/Yb-169.txt new file mode 100644 index 000000000..03b18eb7d --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Yb-169.txt @@ -0,0 +1,161 @@ +169TM 169YB EC DECAY (32.018 D) +169TM T Auger electrons and ^X ray energies and emission intensities: +169TM T {U Energy (keV)} {U Intensity } {U Line } +169TM T +169TM T 49.7731 52.9 8 XKA2 +169TM T 50.7417 93.5 13 XKA1 +169TM T +169TM T 57.304 |] XKB3 +169TM T 57.516 |] 30.6 6 XKB1 +169TM T 57.925 |] XKB5II +169TM T +169TM T 59.1 |] XKB2 +169TM T 59.21 |] 7.95 21 XKB4 +169TM T 59.357 |] XKO23 +169TM T +169TM T 6.34-9.78 49.4 8 XL (total) +169TM T 6.34 0.956 25 XLL +169TM T 7.13-7.18 21.7 5 XLA +169TM T 7.31 0.437 12 XLC +169TM T 8.18-8.64 22.5 6 XLB +169TM T 9.15-9.78 3.1 1 XLG +169TM T +169TM T 38.96-41.88 |] KLL AUGER +169TM T 46.88-50.71 |] 10.8 8 ^KLX AUGER +169TM T 54.78-59.32 |] KXY AUGER +169TM T 3.85-7.18 168.2 18 L AUGER +169YB P 0.0 7/2+ 32.018 D 5 909 4 +169TM N 1.0 1.0 1 1.0 +169TM G 328 2 0.00672 43 +169TM G 614.1 5 9.7E-5 14 +169TM L 0 1/2+ STABLE +169TM L 8.4102 3/2+ 4.08 NS +169TM G 8.41016 150.347 17M1+E2 273 13 +169TM2 G KC=$LC=$MC=218 11 +169TM L 118.1894 5/2+ 62 PS +169TM G 109.77924 4 17.36 9 M1+E2 2.45 4 +169TM2 G KC=2.03 3$LC=0.327 5$MC=0.0730 11 +169TM G 118.18940 141.87 1 E2 1.66 5 +169TM2 G KC=0.697 21$LC=0.734 22$MC=0.179 6 +169TM L 138.9331 7/2+ 302 PS +169TM G 20.74370 210.1925 43M1+E2 57.3 17 +169TM2 G KC=$LC=44.5 13$MC=10.0 3 +169TM G 130.52293 6 11.38 5 E2 1.15 4 +169TM2 G KC=0.538 17$LC=0.470 15$MC=0.115 4 +169TM L 316.1463 7/2+ 660 NS +169TM E 5.1 198.33 +169TM2 E EAV= $CK=0.8093 17$CL=0.1457 12$CM=0.0349 7$CN= $CO= +169TM G 177.21307 6 22.32 10M1+E2 0.590 9 +169TM2 G KC=0.484 7$LC=0.0868 13$MC=0.0197 3 +169TM G 197.95675 7 35.93 12M1+E2 0.448 7 +169TM2 G KC=0.370 6$LC=0.0603 9$MC=0.0136 2 +169TM G 307.73757 9 10.046 45E2 0.0666 20 +169TM2 G KC=0.0482 15$LC=0.0141 4$MC=0.00333 10 +169TM G 316.2 7 0.0033 3 M3+E4 +169TM L 332.119 9/2+ 18.8 PS +169TM E 0.0142 1610.9 2 +169TM2 E EAV= $CK=0.8085 18$CL=0.1463 12$CM=0.0350 7$CN= $CO= +169TM G 193.15 5 0.0074 10M1+E2 0.50 3 +169TM2 G KC=0.42 2$LC=0.063 5$MC= +169TM G 213.936 170.00291 22E2 0.21 1 +169TM2 G KC=0.135 7$LC=0.072 6$MC= +169TM L 345.031 (5/2)- +169TM E 0.0138 1311 1U +169TM2 E EAV= $CK=0.8078 18$CL=0.1469 12$CM=0.0352 7$CN= $CO= +169TM G 205.99 6 0.0034 8 (E1) 0.050 2 +169TM2 G KC=0.042 2$LC=0.0020 2$MC= +169TM G 226.3 7 0.00025 18 +169TM G 336.621 3 0.0098 9 (E1) 0.0146 15 +169TM2 G KC=0.0123 13$LC=0.00179 18$MC=0.00040 4 +169TM L 367.66 11/2+ 41.6 PS +169TM G 51.51 400.0034 1 E2 48.6 22 +169TM2 G KC=$LC=37.1 15$MC=9.1 4 +169TM L 379.268 7/2- 52.6 NS +169TM E 82.2 187 +169TM2 E EAV= $CK=0.8057 18$CL=0.1484 12$CM=0.0356 7$CN= $CO= +169TM G 63.12044 4 44.05 24E1+M2 1.11 4 +169TM2 G KC=0.899 27$LC=0.163 6$MC=0.0366 12 +169TM G 240.33344 120.115 5 E1+M2 0.045 5 +169TM2 G KC=0.037 4$LC=0.0065 7$MC=0.0009 1 +169TM G 261.07712 9 1.687 8 E1+M2 0.0283 9 +169TM2 G KC=0.0237 7$LC=0.00355 11$MC=0.00079 30 +169TM G 370.85616 290.00085 11[M2] 0.308 9 +169TM2 G KC=0.249 8$LC=0.0460 14$MC=0.0106 3 +169TM G 379.26630 250.00030 12[E3] 0.128 4 +169TM2 G KC=0.0757 23$LC=0.0401 12$MC=0.0098 3 +169TM L 430.124 (9/2)- +169TM E 0.0044 1 11.2 1U +169TM2 E EAV= $CK=0.8020 18$CL=0.1511 13$CM=0.0364 7$CN= $CO= +169TM G 291.190 110.00431 14[E1] 0.021 2 +169TM2 G KC=0.018 1$LC=0.0026 2$MC= +169TM L 433.524 (9/2)+ +169TM E 0.121 149.9 2 +169TM2 E EAV= $CK=0.8017 18$CL=0.1513 13$CM=0.0365 7$CN= $CO= +169TM G 117.377 180.0398 36(M1+E2) 2.03 20 +169TM2 G KC=1.70 17$LC=0.257 26$MC=0.057 6 +169TM G 294.54 110.0011 5 +169TM G 425.0 2 0.00162 29 +169TM L 472.8841 9/2- 0.14 NS +169TM E 12.6 3 7.6 1U +169TM2 E EAV= $CK=0.7980 19$CL=0.1540 13$CM=0.0372 7$CN= $CO= +169TM G 93.61447 8 2.571 17M1+E2 3.89 12 +169TM2 G KC=3.18 10$LC=0.55 2$MC=0.124 4 +169TM G 105.19 100.0026 8 [E1] 0.293 15 +169TM2 G KC=0.24 1$LC=0.039 3$MC= +169TM G 156.73487 9 0.00990 25(E1) 0.102 3 +169TM2 G KC=0.0853 26$LC=0.0132 4$MC=0.0029 1 +169TM G 333.94777 270.00171 9 E1 0.0149 15 +169TM2 G KC=0.0126 13$LC=0.00182 19$MC=0.00040 4 +169TM L 474.973 3/2- +169TM E 34400E-87 12 3U +169TM2 E EAV= $CK= $CL= $CM= $CN= $CO= +169TM G 356.74 5 1.41E-4 6 +169TM G 474.973 9 2.03E-4 9 +169TM L 570.827 3/2+ 10 PS +169TM E 0.00030 6 12 +169TM2 E EAV= $CK= $CL= $CM= $CN= $CO= +169TM G 452.62 8 3.5E-5 19(M1+E2) +169TM G 562.413 120.00014 4 (M1+E2) +169TM G 570.89 3 1.27E-4 26(M1+E2) +169TM L 633.296 5/2+ +169TM E 0.0109 4 10.3 2 +169TM2 E EAV= $CK=0.7692 25$CL=0.1750 18$CM=0.0432 9$CN= $CO= +169TM G 494.360 8 0.00157 12 +169TM G 515.107 6 0.00422 16(M1) 0.036 4 +169TM2 G KC=0.0306 30$LC=0.0045 5$MC=0.00099 10 +169TM G 624.886 4 0.00484 27(M1) 0.0222 22 +169TM2 G KC=0.0187 19$LC=0.0027 3$MC=0.00060 6 +169TM G 633.32 107.0E-6 5 +169TM L 646.763 (7/2)- +169TM E 0.00013 7 12 +169TM2 E EAV= $CK= $CL= $CM= $CN= $CO= +169TM G 507.8 3 1.5E-6 8 +169TM G 528.572 100.00013 6 +169TM L 718.791 (7/2)+ +169TM E 0.0037 2 10.3 +169TM2 E EAV= $CK=0.725 5$CL=0.2073 35$CM=0.0526 13$CN= $CO= +169TM G 386.673 130.00038 4 [M1E2] +169TM G 579.854 5 0.00204 16(M1) 0.027 2 +169TM2 G KC=0.023 1$LC=0.0033 3$MC= +169TM G 600.607 8 0.00114 7 (M1) +169TM G 710.358 153.13E-5 22 +169TM L 781.803 5/2+ +169TM E 0.0045 3 10.5 2 +169TM2 E EAV= $CK=0.623 15$CL=0.280 11$CM=0.0743 32$CN= $CO= +169TM G 465.657 6 2.31E-4 24 +169TM G 642.877 9 8.1E-5 5 +169TM G 663.603 7 0.00203 15 +169TM G 773.390 140.00219 11 +169TM G 781.64 8 3.0E-6 3 +169TM L 832.41 (9/2)+ +169TM E 17500E-95 11.2 2 +169TM2 E EAV= $CK= $CL= $CM= $CN= $CO= +169TM G 500.35 108.8E-6 8 +169TM G 693.46 8 8.7E-6 4 +169TM L 878.35 (7/2)+ +169TM E 40000E-11 10.8 +169TM2 E EAV= $CK= $CL= $CM= $CN= $CO= +169TM G 546.16 221.5E-6 4 +169TM G 739.42 111.83E-6 22 +169TM G 760.24 248.3E-7 22 + diff --git a/HEN_HOUSE/spectra/lnhb/Zn-63.txt b/HEN_HOUSE/spectra/lnhb/Zn-63.txt new file mode 100644 index 000000000..2ce62d4b1 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Zn-63.txt @@ -0,0 +1,178 @@ + 63CU 63ZN EC DECAY (38.33 M) + 63CU H TYP=Full$AUT=A.L. Nichols$CUT=30-MAR-2013$ + 63CU C Evaluation history: Type=Full;Author=A.L. Nichols;Cutoff date=30-MAR-2013 + 63CU C References: 1938St05, 1939Bo05, 1939De01, 1947Hu20, 1948Wa13, 1959Ha10, + 63CU2C 1959Ri38, 1960Pr05, 1961Cu02, 1961Va08, 1961Ra06, 1965Pa18, 1967De08, + 63CU3C 1968Go10, 1969Bo11, 1969Bo15, 1970Ki06, 1971Go40, 1971GiZS, 1971Gi03, + 63CU4C 1972Ro21, 1972Cr02, 1974Kl02, 1974Co16, 1976Fu06, 1977La19, 1980Ku08, + 63CU5C 1982Gr10, 1995ScZY, 1996Sc06, 1998Si25, 1998ScZM, 1998Sc28, 1999ScZX, + 63CU6C 2000Sc47, 2001Ba27, 2002Le02, 2002Ba85, 2002Ra45, 2008Ki07, 2011StZZ, + 63CU7C 2012Wa38 + 63CU T Auger electrons and ^X ray energies and emission intensities: + 63CU T {U Energy (keV)} {U Intensity } {U Line } + 63CU T + 63CU T 8.02792 0.865 12 XKA2 + 63CU T 8.04787 1.686 22 XKA1 + 63CU T + 63CU T 8.90541 |] XKB3 + 63CU T 8.90539 |] 0.355 6 XKB1 + 63CU T 8.9771 |] XKB5II + 63CU T + 63CU T + 63CU T 0.811-1.022 0.0958 16 XL (total) + 63CU T 0.811 0.00311 8 XLL + 63CU T 0.929-0.93 0.0547 13 XLA + 63CU T 0.831 0.00186 5 XLC + 63CU T 0.949-1.022 0.0361 10 XLB + 63CU T 0.952- 0.000052 8 XLG + 63CU T + 63CU T 6.731-7.059 |] KLL AUGER + 63CU T 7.746-8.064 |] 3.50 5 ^KLX AUGER + 63CU T 8.739-8.982 |] KXY AUGER + 63CU T 0.68-0.8 9.30 9 L AUGER + 63ZN P 0.0 3/2- 38.33 M 10 3366.2 15 + 63CU N 1.0 1.0 1 1.0 + 63CU G 1696.6 100.002 1 + 63CU G 2181.8 7 0.0013 8 + 63CU L 0 3/2- STABLE + 63CU E 80.3 6 3.75 5 5.397 + 63CU2 E EAV=1041.9 7$CK=0.8860 16$CL=0.0971 13$CM=0.0158 5$CN=0.0010 1$CO=0 0 + 63CU L 669.93 4 1/2- + 63CU E 7.00 2 0.92 1 5.814 2 + 63CU2 E EAV=732.0 7$CK=0.8859 16$CL=0.0972 13$CM=0.0159 5$CN=0.0010 1$CO= + 63CU G 669.93 4 8.19 32M1+E2 0.11 2 5.19E-48 + 63CU2 G KC=4.66E-4 7$LC=4.62E-5 7$MC=6.5E-6 1 + 63CU L 962.02 3 5/2- + 63CU E 4.96 131.19 3 5.602 2 + 63CU2 E EAV=599.5 7$CK=0.8858 16$CL=0.0973 13$CM=0.0159 5$CN=0.0010 1$CO= + 63CU G 962.01 3 6.50 16M1+E2 -0.48 2 2.51E-44 + 63CU2 G KC=2.26E-4 4$LC=2.23E-5 4$MC=3.14E-6 5 + 63CU L 1326.76 5 7/2- + 63CU G 364.74 6 0.0115 25M1+E2 -0.060 5 0.002053 + 63CU2 G KC=0.00184 3$LC=1.84E-4 3$MC=2.59E-5 4 + 63CU G 1326.75 5 0.069 4 E2 1757E-725 + 63CU2 G KC=1268E-7 18$LC=1251E-8 18$MC=1758E-9 25 + 63CU L 1412.16 4 5/2- + 63CU E 0.49 2 0.42 2 5.87 2 + 63CU2 E EAV=399.7 7$CK=0.8857 16$CL=0.0974 13$CM=0.0159 5$CN=0.0010 1$CO= + 63CU G 450.14 5 0.229 16M1+E2 0.115 100 0.001275 + 63CU2 G KC=0.00114 4$LC=1.13E-4 5$MC=1.60E-5 6 + 63CU G 742.23 6 0.067 8 E2 5.71E-48 + 63CU2 G KC=5.12E-4 8$LC=5.11E-5 8$MC=7.18E-6 10 + 63CU G 1412.14 4 0.74 3 M1+E2 0.76 7 1.66E-43 + 63CU2 G KC=1055E-7 16$LC=1038E-8 15$MC=1460E-9 22 + 63CU L 1547.00 5 3/2- + 63CU E 0.042 4 0.060 7 6.65 + 63CU2 E EAV=341.0 7$CK=0.8856 16$CL=0.0975 13$CM=0.0159 5$CN=0.0010 1$CO= + 63CU G 584.98 6 0.033 4 M1+E2 + 63CU G 877.06 6 0.003 2 M1+E2 + 63CU G 1546.98 5 0.124 5 M1+E2 0.39 7 1.81E-43 + 63CU2 G KC=8.70E-5 13$LC=8.54E-6 13$MC=1201E-9 18 + 63CU L 1860.63 6 7/2- + 63CU G 898.60 7 0.009 3 M1+E2 + 63CU G 1860.60 6 0.011 3 E2 3.16E-45 + 63CU2 G KC=6.46E-5 9$LC=6.35E-6 9$MC=8.92E-7 13 + 63CU L 2012.92 113/2- + 63CU E 0.00039 2 0.0130 3 7.063 + 63CU2 E EAV=143.6 6$CK=0.8853 16$CL=0.0977 13$CM=0.0160 5$CN=0.0010 1$CO= + 63CU G 1050.89 110.0044 11M1+E2 + 63CU G 1342.97 120.0025 8 M1+E2 + 63CU G 2012.89 110.011 2 M1+E2 + 63CU L 2062.45 8 (1/2)- + 63CU E 0.0025 2 0.153 135.96 2 + 63CU2 E EAV=123.0 6$CK=0.8853 16$CL=0.0978 13$CM=0.0160 5$CN=0.0010 1$CO= + 63CU G 515.45 9 0.021 8 (M1+E2) + 63CU G 1392.50 9 0.10 1 (M1+E2) 1.0 2 1.67E-44 + 63CU2 G KC=1098E-7 19$LC=1080E-8 19$MC=1.52E-6 3 + 63CU G 2062.41 8 0.034 3 (M1+E2) + 63CU L 2081.32 225/2- + 63CU E 0.00043 9 0.035 7 6.59 2 + 63CU2 E EAV=115.1 6$CK=0.8853 16$CL=0.0978 13$CM=0.0160 5$CN=0.0010 1$CO= + 63CU G 534.32 230.005 2 (M1+E2) + 63CU G 754.56 230.016 6 M1+E2 + 63CU G 2081.28 220.015 2 (M1+E2) + 63CU L 2092.13 107/2- + 63CU G 765.37 110.007 3 M1+E2 + 63CU G 1130.1 1 0.013 2 M1+E2 + 63CU G 2092.09 100.005 3 E2 + 63CU L 2336.54 125/2- + 63CU E 0.141 9 5.79 2 + 63CU2 E EAV= $CK=0.8849 16$CL=0.0980 13$CM=0.0160 5$CN=0.0010 1$CO= + 63CU G 475.91 130.006 3 M1+E2 + 63CU G 924.37 130.0099 20M1+E2 + 63CU G 1374.50 120.034 2 M1+E2 + 63CU G 1666.59 130.0014 6 E2 + 63CU G 2336.49 120.077 5 M1+E2 + 63CU L 2497.19 9 (3/2)- + 63CU E 0.0247 206.4 + 63CU2 E EAV= $CK=0.8846 16$CL=0.0983 13$CM=0.0161 5$CN=0.0010 1$CO= + 63CU G 1827.23 100.0042 11(M1+E2) + 63CU G 2497.14 9 0.020 2 (M1+E2) + 63CU L 2511.06 6 1/2,3/2,5/2- + 63CU E 0.011 2 6.73 2 + 63CU2 E EAV= $CK=0.8846 16$CL=0.0983 13$CM=0.0161 5$CN=0.0010 1$CO= + 63CU G 2511.01 6 0.011 2 [M1+E2] + 63CU L 2535.83 7 (5/2)- + 63CU E 0.261 145.33 2 + 63CU2 E EAV= $CK=0.8846 16$CL=0.0984 13$CM=0.0161 5$CN=0.0010 1$CO= + 63CU G 443.70 120.013 4 (M1+E2) 1.0 2 0.0019816 + 63CU2 G KC=0.00177 14$LC=1.79E-4 14$MC=2.51E-5 20 + 63CU G 675.20 9 0.015 3 (M1+E2) + 63CU G 988.82 9 0.0038 11(M1+E2) + 63CU G 1123.66 8 0.112 11M1+E2 1.0 2 1.92E-44 + 63CU2 G KC=1.71E-4 4$LC=1.69E-5 4$MC=2.37E-6 5 + 63CU G 1209.06 9 0.014 3 (M1+E2) + 63CU G 1573.79 8 0.016 2 (M1+E2) + 63CU G 1865.87 8 0.0200 21(E2) 3.19E-45 + 63CU2 G KC=6.43E-5 9$LC=6.31E-6 9$MC=8.87E-7 13 + 63CU G 2535.78 7 0.067 3 (M1+E2) + 63CU L 2696.66 131/2,3/2- + 63CU E 0.122 6 5.47 2 + 63CU2 E EAV= $CK=0.8841 16$CL=0.0988 13$CM=0.0161 5$CN=0.0010 1$CO= + 63CU G 683.74 170.004 2 M1+E2 + 63CU G 1149.65 140.019 2 M1+E2 + 63CU G 2026.70 140.060 4 M1+E2 + 63CU G 2696.60 130.039 3 M1+E2 + 63CU L 2716.47 9 3/2,5/2- + 63CU E 0.082 7 5.62 + 63CU2 E EAV= $CK=0.8840 16$CL=0.0988 13$CM=0.0162 5$CN=0.0010 1$CO= + 63CU G 624.13 130.011 4 (E2) + 63CU G 1169.46 100.0077 16M1+E2 + 63CU G 1388.68 100.043 6 (E2) + 63CU G 1754.42 9 0.0043 11M1+E2 + 63CU G 2046.5 1 0.0035 11M1+E2 + 63CU G 2716.41 9 0.012 1 M1+E2 + 63CU L 2780.23 21(1/2,3/2)- + 63CU E 0.0298 215.97 2 + 63CU2 E EAV= $CK=0.8837 16$CL=0.0991 13$CM=0.0162 5$CN=0.0010 1$CO= + 63CU G 244.40 220.0053 8 (E2) 0.0213 3 + 63CU2 G KC=0.0190 3$LC=0.00198 3$MC=2.77E-4 4 + 63CU G 1233.22 220.0025 8 M1+E2 + 63CU G 2110.26 210.0065 13M1+E2 + 63CU G 2780.16 210.0154 12M1+E2 + 63CU L 2808.10 8 3/2- + 63CU E 0.0052 106.68 + 63CU2 E EAV= $CK=0.8836 16$CL=0.0992 13$CM=0.0162 5$CN=0.0010 1$CO= + 63CU G 1481.32 9 0.0016 8 E2 + 63CU G 2808.03 8 0.0036 6 M1+E2 + 63CU L 2857.9 3 (1/2,3/2)- + 63CU E 0.0069 126.48 2 + 63CU2 E EAV= $CK=0.8833 16$CL=0.0994 13$CM=0.0163 5$CN=0.0010 1$CO= + 63CU G 1445.7 3 0.0025 8 (E2) + 63CU G 2188.0 3 0.0016 8 M1+E2 + 63CU G 2857.8 3 0.0028 5 M1+E2 + 63CU L 2888.9 4 1/2,3/2,5/2- + 63CU E 0.0104 146.24 2 + 63CU2 E EAV= $CK=0.8831 16$CL=0.0996 13$CM=0.0163 5$CN=0.0010 1$CO= + 63CU G 1926.9 4 0.0053 11(E2) + 63CU G 2219.0 4 0.0029 8 M1+E2 + 63CU G 2888.8 4 0.0021 2 M1+E2 + 63CU L 3042.59 8 (5/2)- + 63CU E 0.0048 8 6.24 2 + 63CU2 E EAV= $CK=0.8814 16$CL=0.1010 13$CM=0.0166 5$CN=0.0010 1$CO= + 63CU G 3042.51 8 0.0048 8 M1+E2 + 63CU L 3101.4 4 1/2,3/2- + 63CU E 0.0007 2 6.89 2 + 63CU2 E EAV= $CK=0.8802 16$CL=0.1020 13$CM=0.0168 5$CN=0.0011 1$CO=0 0 + 63CU G 3101.3 4 0.0007 2 M1+E2 + diff --git a/HEN_HOUSE/spectra/lnhb/Zn-65.txt b/HEN_HOUSE/spectra/lnhb/Zn-65.txt new file mode 100644 index 000000000..c930487ba --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Zn-65.txt @@ -0,0 +1,45 @@ + 65CU 65ZN EC DECAY (244.01 D) + 65CU C References: 1953Pe14, 1953To17, 1957Wr37, 1957Ge07, 1959Gl55, 1960Ri06, + 65CU2C 1962Be28, 1963Ta19, 1963Ta04, 1965An07, 1966Ha07, 1966Ra21, 1968St05, + 65CU3C 1968Ha47, 1972Cr02, 1972De24, 1973Ra10, 1973Vi13, 1973Po10, 1974Cr05, + 65CU4C 1975La16, 1976Kr09, 1977Bo10, 1979Sc31, 1982HoZJ, 1982DeYX, 1983Wa26, + 65CU5C 1984ScZP, 1985HaZA, 1990Sc08, 1990Ku11, 1992Un01, 1993Bh04, 1995ScZY, + 65CU6C 1996Sc06, 2000He14, 2002Un02, 2002Ba85, 2003Lu06, 2003Au03, 2004Sc04, + 65CU7C 2004Va02, 2005BeZX, 2006Be34 + 65CU T Auger electrons and ^X ray energies and emission intensities: + 65CU T {U Energy (keV)} {U Intensity } {U Line } + 65CU T + 65CU T 8.02792 11.76 13 XKA2 + 65CU T 8.04787 22.91 22 XKA1 + 65CU T + 65CU T 8.90539 |] 4.82 7 XKB1 + 65CU T 8.9771 |] XKB5II + 65CU T + 65CU T + 65CU T 0.811-1.022 1.305 21 XL (total) + 65CU T 0.811 0.0424 11 XLL + 65CU T 0.929-0.93 0.745 16 XLA + 65CU T 0.831 0.0253 7 XLC + 65CU T 0.932-1.022 0.491 13 XLB + 65CU T 0.952-0.952 0.00070 11 XLG + 65CU T + 65CU T 6.76-7.12 |] KLL AUGER + 65CU T 7.76-8.05 |] 47.5 4 ^KLX AUGER + 65CU T 8.73-8.9 |] KXY AUGER + 65CU T 0.7-1 126.6 7 L AUGER + 65ZN P 0.0 5/2- 244.01 D 9 1352.1 3 + 65CU N 1.0 1.0 1 1.0 + 65CU L 0 3/2- STABLE + 65CU E 1.421 7 48.35 117.46 2 + 65CU2 E EAV=143.1 1$CK=0.8853 16$CL=0.0977 15$CM=0.017 $CN= $CO= + 65CU L 770.64 9 1/2- 0.099 PS 5 + 65CU G 770.64 9 0.00269 22M1+E2 0.096 7 3.84E-412 + 65CU2 G KC=3.45E-4 10$LC=3.43E-5 10$MC= + 65CU L 1115.556 4 5/2- 0.285 PS 9 + 65CU E 50.23 115.89 + 65CU2 E EAV= $CK=0.8794 17$CL=0.1027 16$CM=0.0179 $CN= $CO= + 65CU G 344.95 200.00254 18[E2] 0.0062019 + 65CU2 G KC=0.00555 17$LC=5.69E-4 19$MC= + 65CU G 1115.539 2 50.22 11M1+E2 -0.437 15 1.84E-47 + 65CU2 G KC=1.66E-4 6$LC=1.62E-5 5$MC= + diff --git a/HEN_HOUSE/spectra/lnhb/Zr-89.txt b/HEN_HOUSE/spectra/lnhb/Zr-89.txt new file mode 100644 index 000000000..446ba0600 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Zr-89.txt @@ -0,0 +1,62 @@ + 89Y 89ZR EC DECAY (78.42 H) + 89Y H TYP=FUL$AUT=A.L. Nichols$CUT=31-MAY-2014$ + 89Y C Evaluation history: Type=FUL;Author=A.L. Nichols;Cutoff date=31-MAY-2014 + 89Y C References: 1938Sa01, 1940Du05, 1940Sa08, 1951Go42, 1951Hy24, 1951Sh24, + 89Y 2C 1951Sh89, 1953Ka11, 1953Sh48, 1955Sw92, 1957Ku57, 1960Ha26, 1961Mo12, + 89Y 3C 1961Ra06, 1962Br42, 1962Ho10, 1964Aw02, 1964Va03, 1966Du07, 1967Yu01, + 89Y 4C 1968Bo52, 1968Dr02, 1968Hi10, 1968Hi12, 1969GuZV, 1969Ro02, 1970Ga03, + 89Y 5C 1971Go40, 1971Ar18, 1973Le13, 1973BeYD, 1974HeYW, 1977La19, 1977Ba48, + 89Y 6C 1977Ba48, 1979Ba46, 1984Sk01, 1984HaZC, 1985HaZI, 1992KaZM, 1992Fu04, + 89Y 7C 1995ItZY, 1995ScZY, 1996Sc06, 1996Sc06, 1997La20, 1998ScZM, 1998Sc28, + 89Y 8C 1999ScZX, 2000Sc47, 2002Ba85, 2002Ra45, 2003Au03, 2008Ki07, 2012Wa38, + 89Y 9C 2013Si03 + 89Y T Auger electrons and ^X ray energies and emission intensities: + 89Y T {U Energy (keV)} {U Intensity } {U Line } + 89Y T + 89Y T 14.8829 14.08 13 XKA2 + 89Y T 14.9585 27.01 20 XKA1 + 89Y T + 89Y T 16.7259 |] XKB3 + 89Y T 16.7381 |] 6.78 8 XKB1 + 89Y T 16.88 |] XKB5II + 89Y T + 89Y T 17.0156 |] XKB2 + 89Y T 17.0362 |] 0.94 4 XKB4 + 89Y T + 89Y T 1.686-2.347 2.36 5 XL (total) + 89Y T 1.686 0.0568 15 XLL + 89Y T 1.92-1.923 1.48 4 XLA + 89Y T 1.762 0.0234 7 XLC + 89Y T 1.996-2.078 0.778 19 XLB + 89Y T 2.153-2.347 0.01331 24 XLG + 89Y T + 89Y T 12.205-12.784 |] KLL AUGER + 89Y T 14.238-14.956 |] 19.4 3 ^KLX AUGER + 89Y T 16.251-17.034 |] KXY AUGER + 89Y T 1.27-1.89 79.5 7 L AUGER + 89ZR P 0.0 9/2+ 78.42 H 13 2832.8 28 + 89Y N 1.0 1.0 1 1.0 + 89Y L 0 1/2- STABLE + 89Y L 908.97 3 9/2+ 15.84 S 18 + 89Y E 22.8 3 76.2 3 6.152 + 89Y 2 E EAV=395.7 14$CK=0.8731 15$CL=0.1041 12$CM=0.0196 4$CN=0.0032 2$CO= + 89Y G 908.97 3 99.03 2 M4 0.0085112 + 89Y 2 G KC=0.00743 11$LC=9.06E-4 13$MC=1561E-7 22 + 89Y L 1744.74 185/2- 0.62 PS 14 + 89Y E 0.123 4 9.09 3U + 89Y 2 E EAV= $CK=0.8677 15$CL=0.1082 12$CM=0.0208 4$CN=0.0033 2$CO= + 89Y G 1744.72 180.123 4 E2 3.82E-46 + 89Y 2 G KC=1722E-7 25$LC=1.86E-5 3$MC=3.17E-6 5 + 89Y L 2529.8 2 7/2+ 0.08 PS 3 + 89Y E 0.074 5 7.52 2 + 89Y 2 E EAV= $CK=0.8632 16$CL=0.1120 13$CM=0.0213 4$CN=0.0035 2$CO= + 89Y G 1620.81 200.074 5 M1+E2 + 89Y L 2566.55 1511/2+ + 89Y E 0.106 5 7.25 2 + 89Y 2 E EAV= $CK=0.8615 16$CL=0.1134 13$CM=0.0216 5$CN=0.0035 2$CO= + 89Y G 1657.56 150.106 5 M1+E2 + 89Y L 2622.1 3 9/2+ 0.21 PS 10 + 89Y E 0.745 106.18 + 89Y 2 E EAV= $CK=0.8575 17$CL=0.1165 13$CM=0.0223 5$CN=0.0036 2$CO= + 89Y G 1713.1 3 0.745 10M1+E2 + diff --git a/HEN_HOUSE/spectra/lnhb/Zr-93.txt b/HEN_HOUSE/spectra/lnhb/Zr-93.txt new file mode 100644 index 000000000..1c4852f30 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Zr-93.txt @@ -0,0 +1,40 @@ + 93NB 93ZR B- DECAY (1.61E6 Y) + 93NB H TYP=Full$AUT=M.A. Kellett$CUT=17-SEP-2013$ + 93NB C Evaluation history: Type=Full;Author=M.A. Kellett;Cutoff date=17-SEP-2013 + 93NB C References: 1950St90, 1952Gl**, 1953Gl31, 1972FlZM, 2004BeZQ, 2008DuZX, + 93NB2C 2010Ca01, 2010Ya01, 2012Wa38 + 93NB T Auger electrons and ^X ray energies and emission intensities: + 93NB T {U Energy (keV)} {U Intensity } {U Line } + 93NB T + 93NB T 16.5213 2.41 18 XKA2 + 93NB T 16.6152 4.6 4 XKA1 + 93NB T + 93NB T 18.607 |] XKB3 + 93NB T 18.623 |] 1.19 9 XKB1 + 93NB T 18.78 |] XKB5II + 93NB T + 93NB T 18.953 |] XKB2 + 93NB T 18.981 |] 0.179 15 XKB4 + 93NB T + 93NB T 1.9-2.67 2.1 1 XL (total) + 93NB T 1.9 0.063 4 XLL + 93NB T 2.16-2.17 1.69 9 XLA + 93NB T 2 0.0064 4 XLC + 93NB T 2.26-2.49 0.325 13 XLB + 93NB T 2.41-2.67 0.0172 6 XLG + 93NB T + 93NB T 13.49-14.14 |] KLL AUGER + 93NB T 15.78-16.61 |] 2.78 21 ^KLX AUGER + 93NB T 18.05-18.98 |] KXY AUGER + 93NB T 1.4-2.7 59.1 4 L AUGER + 93ZR P 0.0 5/2+ 1.61E6 Y 6 90.3 15 + 93NB N 1.0 1.0 1 1.0 + 93NB L 0 9/2+ STABLE + 93NB B 90.3 1527 5 12.09 + 93NBS B EAV=23.64 42 + 93NB L 30.77 2 1/2- 16.12 Y 15 + 93NB B 59.5 1573 5 10.16 3U + 93NBS B EAV=18.75 54 + 93NB G 30.77 2 0.00043 3 M4 1.693E525 + 93NB2 G KC=2.60E4 4$LC=1.151E5 17$MC=2.49E4 4 + diff --git a/HEN_HOUSE/spectra/lnhb/Zr-95.txt b/HEN_HOUSE/spectra/lnhb/Zr-95.txt new file mode 100644 index 000000000..ebb11c5e4 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Zr-95.txt @@ -0,0 +1,44 @@ + 95NB 95ZR B- DECAY (64.032 D) + 95NB H TYP=update$AUT=M.M. Bé$CUT= -- $ + 95NB2 H TYP=Full$AUT=R.G.Helmer$CUT= -- $ + 95NB C Evaluation history: Type=update;Author=M.M. Bé;Cutoff date= -- + 95NB2C Type=Full;Author=R.G.Helmer;Cutoff date= -- + 95NB T Auger electrons and ^X ray energies and emission intensities: + 95NB T {U Energy (keV)} {U Intensity } {U Line } + 95NB T + 95NB T 16.5213 0.167 11 XKA2 + 95NB T 16.6152 0.319 20 XKA1 + 95NB T + 95NB T 18.6065 |] XKB3 + 95NB T 18.6227 |] 0.082 6 XKB1 + 95NB T 18.78 |] XKB5II + 95NB T + 95NB T 18.953 |] XKB2 + 95NB T 18.981 |] 0.0124 9 XKB4 + 95NB T + 95NB T + 95NB T 13.49-14.14 |] KLL AUGER + 95NB T 15.79-16.58 |] 0.192 13 ^KLX AUGER + 95NB T 18.02-18.91 |] KXY AUGER + 95NB T 1.4-2.6 0.92 5 L AUGER + 95ZR P 0.0 5/2+ 64.032 D 6 1124.8 19 + 95NB N 1.0 1.0 1 1.0 + 95NB L 0 9/2+ 34.991 D 6 + 95NB B 1124.8 190.10 3 11.22 + 95NBS B EAV=406.0 8 + 95NB L 235.69 2 1/2- 3.61 D 3 + 95NB B 889.1 191.08 7 10.28 3U + 95NBS B EAV=327.6 8 + 95NB G 235.69 2 0.27 2 M4 2.88 9 + 95NB2 G KC=2.31 8$LC=0.468 14$MC=0.10000 0 + 95NB L 724.195 4 7/2+ + 95NB B 400.6 1944.34 22 6.98 2 + 95NBS B EAV=120.9 7 + 95NB G 724.193 3 44.27 22M1+E2 0.001575 + 95NB2 G KC=0.00132 4$LC=1.47E-4 4$MC= + 95NB L 756.732 127/2+ + 95NB B 368.1 1954.46 22 6.77 2 + 95NBS B EAV=109.7 7 + 95NB G 756.729 1254.38 22M1+E2 0.001424 + 95NB2 G KC=0.00120 4$LC=1.33E-4 4$MC= + From 0d27f46cc3649062d66c4cdfe10875c09ee3d79b Mon Sep 17 00:00:00 2001 From: Reid Townson Date: Thu, 7 Jul 2016 08:32:50 -0400 Subject: [PATCH 04/34] Apply EGSnrc code style standard with astyle --- HEN_HOUSE/egs++/egs_base_source.h | 34 +- HEN_HOUSE/egs++/egs_ensdf.cpp | 867 ++++++++++-------- HEN_HOUSE/egs++/egs_ensdf.h | 193 ++-- HEN_HOUSE/egs++/egs_spectra.cpp | 253 ++--- .../egs_radionuclide_source.cpp | 129 ++- .../egs_radionuclide_source.h | 92 +- 6 files changed, 814 insertions(+), 754 deletions(-) diff --git a/HEN_HOUSE/egs++/egs_base_source.h b/HEN_HOUSE/egs++/egs_base_source.h index af5006e1d..8f19844d3 100644 --- a/HEN_HOUSE/egs++/egs_base_source.h +++ b/HEN_HOUSE/egs++/egs_base_source.h @@ -138,8 +138,8 @@ class EGS_EXPORT EGS_BaseSource : public EGS_Object { // EGS_Float &E, EGS_Float &wt, // energy and weight // EGS_Vector &x, EGS_Vector &u, // position and direction // EGS_I64 &ishower, EGS_Float &time -// ) {}; - +// ) {}; + /*! \brief Set the next simulation chunk to start at \a nstart and to consist of \a nrun particles. @@ -175,21 +175,21 @@ class EGS_EXPORT EGS_BaseSource : public EGS_Object { * simulation source). */ virtual EGS_Float getFluence() const = 0; - + /*! \brief Get the time of emission for the most recently sampled particle * - * This method is only reimplemented by EGS_RadionuclideSource. It + * This method is only reimplemented by EGS_RadionuclideSource. It * returns the emission time of the particle that was most recently sampled. */ virtual double getTime() const {}; - + /*! \brief Get the shower index for radionuclide emissions * * This method is only reimplemented by EGS_RadionuclideSource. It * gets the index of the most recent shower. */ virtual EGS_I64 getShowerIndex() const {}; - + /*! \brief Prints out the sampled emissions for radionuclide spectra * * This method is only reimplemented by EGS_RadionuclideSource. It @@ -379,23 +379,23 @@ class EGS_EXPORT EGS_BaseSpectrum { sum_E2 += e*e; return e; }; - + /*! \brief Get the charge for the most recently sampled particle * - * This method is only reimplemented by EGS_RadionuclideSpectrum. It - * returns the charge of the particle that was most recently sampled + * This method is only reimplemented by EGS_RadionuclideSpectrum. It + * returns the charge of the particle that was most recently sampled * using sampleEnergy(). */ virtual int getCharge() const {}; - + /*! \brief Get the time of emission for the most recently sampled particle * - * This method is only reimplemented by EGS_RadionuclideSpectrum. It - * returns the emission time of the particle that was most recently sampled + * This method is only reimplemented by EGS_RadionuclideSpectrum. It + * returns the emission time of the particle that was most recently sampled * using sampleEnergy(). */ virtual double getTime() const {}; - + /*! \brief Set the maximum time of emission * * This method is only reimplemented by EGS_RadionuclideSpectrum. It @@ -403,14 +403,14 @@ class EGS_EXPORT EGS_BaseSpectrum { * simulations using the time variable. */ virtual void setMaximumTime(double maxTime) {}; - + /*! \brief Get the shower index for radionuclide emissions * * This method is only reimplemented by EGS_RadionuclideSpectrum. It * gets the index of the most recent shower produced using sampleEnergy(). */ virtual EGS_I64 getShowerIndex() const {}; - + /*! \brief Get the spectrum weight for radionuclide spectra * * This method is only reimplemented by EGS_RadionuclideSpectrum. It @@ -418,7 +418,7 @@ class EGS_EXPORT EGS_BaseSpectrum { * spectra. */ virtual EGS_Float getSpectrumWeight() const {}; - + /*! \brief Set the spectrum weight for radionuclide spectra * * This method is only reimplemented by EGS_RadionuclideSpectrum. It @@ -426,7 +426,7 @@ class EGS_EXPORT EGS_BaseSpectrum { * spectra. This allows a source to normalize the spectrum weights. */ virtual void setSpectrumWeight(EGS_Float newWeight) {}; - + /*! \brief Prints out the sampled emissions for radionuclide spectra * * This method is only reimplemented by EGS_RadionuclideSpectrum. It diff --git a/HEN_HOUSE/egs++/egs_ensdf.cpp b/HEN_HOUSE/egs++/egs_ensdf.cpp index 98fb75c0c..769988687 100644 --- a/HEN_HOUSE/egs++/egs_ensdf.cpp +++ b/HEN_HOUSE/egs++/egs_ensdf.cpp @@ -31,26 +31,26 @@ /*! \file egs_ensdf.cpp * \brief The ensdf implementation * \RT - * + * */ #include "egs_ensdf.h" EGS_Ensdf::EGS_Ensdf(const string isotope, const string ensdf_filename) { - - if(ensdf_file.is_open()) { + + if (ensdf_file.is_open()) { ensdf_file.close(); } - + radionuclide = isotope.substr(0, isotope.find_last_of(".")); - + printf("EGS_Ensdf::EGS_Ensdf: Isotope: " "%s\n",isotope.c_str()); printf("EGS_Ensdf::EGS_Ensdf: Now loading ensdf file: " "\"%s\"\n",ensdf_filename.c_str()); - + ensdf_file.open(ensdf_filename.c_str(),ios::in); - if(!ensdf_file.is_open()) { + if (!ensdf_file.is_open()) { egsWarning("EGS_Ensdf::EGS_Ensdf: failed to open ensdf file %s" " for reading\n",ensdf_filename.c_str()); return; @@ -58,70 +58,70 @@ EGS_Ensdf::EGS_Ensdf(const string isotope, const string ensdf_filename) { string line; vector ensdf; - while(getline(ensdf_file, line)) { + while (getline(ensdf_file, line)) { ensdf.push_back(line); } - - if(ensdf_file.is_open()) { + + if (ensdf_file.is_open()) { ensdf_file.close(); } - + // Get the isotope - if(!createIsotope(ensdf)) { + if (!createIsotope(ensdf)) { egsWarning("EGS_Ensdf::EGS_Ensdf: error reading ensdf isotope data\n"); return; } - + } EGS_Ensdf::~EGS_Ensdf() { - if(ensdf_file.is_open()) { + if (ensdf_file.is_open()) { ensdf_file.close(); } - - for(vector::iterator it = myParentRecords.begin(); + + for (vector::iterator it = myParentRecords.begin(); it!=myParentRecords.end(); it++) { delete *it; *it=0; } myParentRecords.clear(); - for(vector::iterator it = - myNormalizationRecords.begin(); + for (vector::iterator it = + myNormalizationRecords.begin(); it!=myNormalizationRecords.end(); it++) { delete *it; *it=0; } myNormalizationRecords.clear(); - for(vector::iterator it = - myLevelRecords.begin(); + for (vector::iterator it = + myLevelRecords.begin(); it!=myLevelRecords.end(); it++) { delete *it; *it=0; } myLevelRecords.clear(); - for(vector::iterator it = - myBetaMinusRecords.begin(); + for (vector::iterator it = + myBetaMinusRecords.begin(); it!=myBetaMinusRecords.end(); it++) { delete *it; *it=0; } myBetaMinusRecords.clear(); - for(vector::iterator it = - myBetaPlusRecords.begin(); + for (vector::iterator it = + myBetaPlusRecords.begin(); it!=myBetaPlusRecords.end(); it++) { delete *it; *it=0; } myBetaPlusRecords.clear(); - for(vector::iterator it = - myGammaRecords.begin(); + for (vector::iterator it = + myGammaRecords.begin(); it!=myGammaRecords.end(); it++) { delete *it; *it=0; } myGammaRecords.clear(); - for(vector::iterator it = - myAlphaRecords.begin(); + for (vector::iterator it = + myAlphaRecords.begin(); it!=myAlphaRecords.end(); it++) { delete *it; *it=0; @@ -131,41 +131,41 @@ EGS_Ensdf::~EGS_Ensdf() { string egsRemoveWhite(string myString) { string result = ""; - - for(unsigned int i = 0; i ensdf) { - + // The daughter isotope name string id = ensdf.front().substr(0,5); string daughter = egsRemoveWhite(id); - + // The parent element string element = radionuclide.substr(0, radionuclide.find("-")); - + // The atomic weight A = findAtomicWeight(element); - if(A == 0) { + if (A == 0) { egsWarning("EGS_Ensdf::createIsotope: element does not exist in our " "data (%s)\n", element.c_str()); return false; } - + // Parse the ensdf data parseEnsdf(ensdf); @@ -292,18 +292,19 @@ map EGS_Ensdf::getElementMap() { elementTable["UUH"] = 116; elementTable["UUS"] = 117; elementTable["UUO"] = 118; - + return elementTable; } unsigned short int EGS_Ensdf::findAtomicWeight(string element) { transform(element.begin(), element.end(), element.begin(), ::toupper); - + map elementMap = getElementMap(); - if(elementMap.find(element) != elementMap.end()) { + if (elementMap.find(element) != elementMap.end()) { return elementMap[element]; - } else { + } + else { return 0; } } @@ -326,203 +327,227 @@ void EGS_Ensdf::parseEnsdf(vector ensdf) { * 12 Gamma * 13 Reference (not used) * */ - for(int i = 0; i < 14; i++) { + for (int i = 0; i < 14; i++) { recordStack.push_back(vector()); } - + // Loop over each line // When we recognize a line as containing an important record, // add it to the recordStack // Any time we get to a new record (line[5]==' '), call buildRecords() - for(vector::iterator it = ensdf.begin(); it!=ensdf.end();it++) { - + for (vector::iterator it = ensdf.begin(); it!=ensdf.end(); it++) { + string line = *it; printf("ENSDF::parseEnsdf: %s\n", line.c_str()); // Identification - if(line[6]==' ' && line[7]==' ' && line[8]==' ') { - - // History - } else if(line[6]==' ' && line[7]=='H' && line[8]==' ') { - - // Q-value - } else if(line[6]== ' ' && line[7]=='Q' && line[8]==' ') { - - // Cross-Reference - } else if(line[6]==' ' && line[7]=='X') { - - // Comment - } else if((line[6]=='C' || line[6]=='D' || line[6]=='T' || - line[6]=='c' || line[6]=='d' || line[6]=='t')) { - if(line[5]==' ') { + if (line[6]==' ' && line[7]==' ' && line[8]==' ') { + + // History + } + else if (line[6]==' ' && line[7]=='H' && line[8]==' ') { + + // Q-value + } + else if (line[6]== ' ' && line[7]=='Q' && line[8]==' ') { + + // Cross-Reference + } + else if (line[6]==' ' && line[7]=='X') { + + // Comment + } + else if ((line[6]=='C' || line[6]=='D' || line[6]=='T' || + line[6]=='c' || line[6]=='d' || line[6]=='t')) { + if (line[5]==' ') { buildRecords(); } recordStack[4].push_back(line); - - //Parent - } else if(line[6]==' ' && line[7]=='P') { - if(line[5]==' ') { + + //Parent + } + else if (line[6]==' ' && line[7]=='P') { + if (line[5]==' ') { buildRecords(); } recordStack[5].push_back(line); - - // Normalization - } else if(line[6]==' ' && line[7]=='N') { - if(line[5]==' ') { + + // Normalization + } + else if (line[6]==' ' && line[7]=='N') { + if (line[5]==' ') { buildRecords(); } recordStack[6].push_back(line); - - // Level - } if(line[6]==' ' && line[7]=='L' && line[8]== ' ') { - if(line[5]==' ') { + + // Level + } + if (line[6]==' ' && line[7]=='L' && line[8]== ' ') { + if (line[5]==' ') { buildRecords(); } recordStack[7].push_back(line); - - // Beta- - } else if(line[6]==' ' && line[7]=='B' && line[8]==' ') { - if(line[5]==' ') { + + // Beta- + } + else if (line[6]==' ' && line[7]=='B' && line[8]==' ') { + if (line[5]==' ') { buildRecords(); } recordStack[8].push_back(line); - - // Beta+ and Electron Capture - } else if(line[6]==' ' && line[7]=='E' && line[8]==' ') { - if(line[5]==' ') { + + // Beta+ and Electron Capture + } + else if (line[6]==' ' && line[7]=='E' && line[8]==' ') { + if (line[5]==' ') { buildRecords(); } recordStack[9].push_back(line); - - // Alpha - } else if(line[6]==' ' && line[7]=='A' && line[8]==' ') { - if(line[5]==' ') { + + // Alpha + } + else if (line[6]==' ' && line[7]=='A' && line[8]==' ') { + if (line[5]==' ') { buildRecords(); } recordStack[10].push_back(line); - - // Delayed Particle - } else if(line[6]==' ' && (line[7]=='D' || line[7]==' ') && + + // Delayed Particle + } + else if (line[6]==' ' && (line[7]=='D' || line[7]==' ') && (line[8]=='N' || line[8]=='P' || line[8]=='A')) { - if(line[5]==' ') { + if (line[5]==' ') { buildRecords(); } recordStack[11].push_back(line); - // Gamma - } else if(line[6]==' ' && line[7]=='G' && line[8]==' ') { - if(line[5]==' ') { + // Gamma + } + else if (line[6]==' ' && line[7]=='G' && line[8]==' ') { + if (line[5]==' ') { buildRecords(); } recordStack[12].push_back(line); } } - + // Build the records into objects - if(!recordStack.empty()) { + if (!recordStack.empty()) { buildRecords(); } - + // Combine the beta- and beta+ records together - for(vector::iterator it = myBetaMinusRecords.begin(); + for (vector::iterator it = myBetaMinusRecords.begin(); it!=myBetaMinusRecords.end(); it++) { - + myBetaRecords.push_back(*it); } - - for(vector::iterator it = myBetaPlusRecords.begin(); + + for (vector::iterator it = myBetaPlusRecords.begin(); it!=myBetaPlusRecords.end(); it++) { - + myBetaRecords.push_back(*it); } - + // Get X-ray and auger emissions from comments getEmissionsFromComments(); - + // Search through the gamma records for any with unknown levels - for(vector::iterator it = myGammaRecords.begin(); + for (vector::iterator it = myGammaRecords.begin(); it!=myGammaRecords.end(); it++) { - + // Some gamma may be emitted but the energy level is not known // This is reported in the lnhb data as decays from the -1 level // Since we cannot correlate the emission with a change of energy // states of the daughter, we will treat this gamma as an xray // The halflife will be ignored - if(!(*it)->getLevelRecord()) { + if (!(*it)->getLevelRecord()) { printf("EGS_Ensdf::parseEnsdf: Switching gamma with unknown " - "level to X-Ray for non-correlated sampling\n"); + "level to X-Ray for non-correlated sampling\n"); xrayEnergies.push_back((*it)->getDecayEnergy()); xrayIntensities.push_back((*it)->getTransitionIntensity()); - + // Erase the gamma record object myGammaRecords.erase(it); } } - - for(unsigned int i=0; i < xrayEnergies.size(); ++i) { - printf("EGS_Ensdf::parseEnsdf: XRays (E,I): %f %f\n", - xrayEnergies[i], xrayIntensities[i]); + + for (unsigned int i=0; i < xrayEnergies.size(); ++i) { + printf("EGS_Ensdf::parseEnsdf: XRays (E,I): %f %f\n", + xrayEnergies[i], xrayIntensities[i]); } - for(unsigned int i=0; i < augerEnergies.size(); ++i) { - printf("EGS_Ensdf::parseEnsdf: Auger (E,I): %f %f\n", - augerEnergies[i], augerIntensities[i]); + for (unsigned int i=0; i < augerEnergies.size(); ++i) { + printf("EGS_Ensdf::parseEnsdf: Auger (E,I): %f %f\n", + augerEnergies[i], augerIntensities[i]); } } // Create record objects from the arrays void EGS_Ensdf::buildRecords() { ParentRecord *LastParent = 0; - if(!myParentRecords.empty()) { + if (!myParentRecords.empty()) { LastParent = myParentRecords.back(); } NormalizationRecord *LastNormalization = 0; - if(!myNormalizationRecords.empty()) { + if (!myNormalizationRecords.empty()) { LastNormalization = myNormalizationRecords.back(); } LevelRecord *LastLevel = 0; - if(!myLevelRecords.empty()) { - LastLevel = myLevelRecords.back(); + if (!myLevelRecords.empty()) { + LastLevel = myLevelRecords.back(); } - - for(int i = 0; i < recordStack.size(); i++) { + + for (int i = 0; i < recordStack.size(); i++) { // printf("EGS_Ensdf::buildRecords:test %d\n",i); - if(!recordStack[i].empty()) { - if(i==0) { - - } else if(i==1) { - - } else if(i==2) { - - } else if(i==3) { - - } else if(i==4) { + if (!recordStack[i].empty()) { + if (i==0) { + + } + else if (i==1) { + + } + else if (i==2) { + + } + else if (i==3) { + + } + else if (i==4) { myCommentRecords.push_back(new CommentRecord(recordStack[i])); - } else if(i==5) { + } + else if (i==5) { myParentRecords.push_back(new ParentRecord(recordStack[i])); - } else if(i==6) { - myNormalizationRecords.push_back(new - NormalizationRecord(recordStack[i], LastParent)); - } else if(i==7) { + } + else if (i==6) { + myNormalizationRecords.push_back(new + NormalizationRecord(recordStack[i], LastParent)); + } + else if (i==7) { myLevelRecords.push_back(new LevelRecord(recordStack[i])); - } else if(i==8) { - myBetaMinusRecords.push_back(new - BetaMinusRecord(recordStack[i], LastParent, - LastNormalization, LastLevel)); - } else if(i==9) { - myBetaPlusRecords.push_back(new - BetaPlusRecord(recordStack[i], LastParent, - LastNormalization, LastLevel)); - } else if(i==10) { - myAlphaRecords.push_back(new - AlphaRecord(recordStack[i], LastParent, - LastNormalization, LastLevel)); - } else if(i==11) { + } + else if (i==8) { + myBetaMinusRecords.push_back(new + BetaMinusRecord(recordStack[i], LastParent, + LastNormalization, LastLevel)); + } + else if (i==9) { + myBetaPlusRecords.push_back(new + BetaPlusRecord(recordStack[i], LastParent, + LastNormalization, LastLevel)); + } + else if (i==10) { + myAlphaRecords.push_back(new + AlphaRecord(recordStack[i], LastParent, + LastNormalization, LastLevel)); + } + else if (i==11) { printf("EGS_Ensdf::buildRecords: Warning: Delayed particle not " - "supported! Further development required.\n"); - } else if(i==12) { - myGammaRecords.push_back(new - GammaRecord(recordStack[i], LastNormalization, LastLevel)); + "supported! Further development required.\n"); + } + else if (i==12) { + myGammaRecords.push_back(new + GammaRecord(recordStack[i], LastNormalization, LastLevel)); } - + recordStack[i].clear(); } } @@ -530,191 +555,195 @@ void EGS_Ensdf::buildRecords() { // Normalize intensities for alpha, beta, gamma objects void EGS_Ensdf::normalizeIntensities() { - + // Add up the beta, alpha, xray and auger decay intensities double totalDecayIntensity = 0; double lastIntensity = 0; - for(vector::iterator beta = myBetaRecords.begin(); + for (vector::iterator beta = myBetaRecords.begin(); beta != myBetaRecords.end(); beta++) { - - printf("EGS_Ensdf::normalizeIntensities: Beta (E,I): %f %f\n", - (*beta)->getFinalEnergy(), (*beta)->getBetaIntensity()); - + + printf("EGS_Ensdf::normalizeIntensities: Beta (E,I): %f %f\n", + (*beta)->getFinalEnergy(), (*beta)->getBetaIntensity()); + totalDecayIntensity += (*beta)->getBetaIntensity(); } - for(vector::iterator alpha = myAlphaRecords.begin(); + for (vector::iterator alpha = myAlphaRecords.begin(); alpha != myAlphaRecords.end(); alpha++) { - - printf("EGS_Ensdf::normalizeIntensities: Alpha (E,I): %f %f\n", - (*alpha)->getFinalEnergy(), (*alpha)->getAlphaIntensity()); - + + printf("EGS_Ensdf::normalizeIntensities: Alpha (E,I): %f %f\n", + (*alpha)->getFinalEnergy(), (*alpha)->getAlphaIntensity()); + totalDecayIntensity += (*alpha)->getAlphaIntensity(); } - for(unsigned int i=0; i < xrayIntensities.size(); ++i) { - printf("EGS_Ensdf::normalizeIntensities: XRay (E,I): %f %f\n", - xrayEnergies[i], xrayIntensities[i]); - + for (unsigned int i=0; i < xrayIntensities.size(); ++i) { + printf("EGS_Ensdf::normalizeIntensities: XRay (E,I): %f %f\n", + xrayEnergies[i], xrayIntensities[i]); + totalDecayIntensity += xrayIntensities[i]; } - for(unsigned int i=0; i < augerIntensities.size(); ++i) { - printf("EGS_Ensdf::normalizeIntensities: Auger (E,I): %f %f\n", - augerEnergies[i], augerIntensities[i]); - + for (unsigned int i=0; i < augerIntensities.size(); ++i) { + printf("EGS_Ensdf::normalizeIntensities: Auger (E,I): %f %f\n", + augerEnergies[i], augerIntensities[i]); + totalDecayIntensity += augerIntensities[i]; } - + printf("EGS_Ensdf::normalizeIntensities: totalDecayIntensity: " - "%f\n",totalDecayIntensity); - + "%f\n",totalDecayIntensity); + // Normalize beta emission intensities - for(vector::iterator beta = myBetaRecords.begin(); + for (vector::iterator beta = myBetaRecords.begin(); beta != myBetaRecords.end(); beta++) { - + (*beta)->setBetaIntensity( (*beta)->getBetaIntensity() / totalDecayIntensity); - - if((beta - myBetaRecords.begin()) > 0) { + + if ((beta - myBetaRecords.begin()) > 0) { (*beta)->setBetaIntensity( (*beta)->getBetaIntensity() + (*(beta-1))->getBetaIntensity()); } lastIntensity = (*beta)->getBetaIntensity(); - - printf("EGS_Ensdf::normalizeIntensities: Beta (E,I): %f %f\n", - (*beta)->getFinalEnergy(), (*beta)->getBetaIntensity()); + + printf("EGS_Ensdf::normalizeIntensities: Beta (E,I): %f %f\n", + (*beta)->getFinalEnergy(), (*beta)->getBetaIntensity()); } - + // Normalize alpha emission intensities - for(vector::iterator alpha = myAlphaRecords.begin(); + for (vector::iterator alpha = myAlphaRecords.begin(); alpha != myAlphaRecords.end(); alpha++) { - + (*alpha)->setAlphaIntensity( (*alpha)->getAlphaIntensity() / totalDecayIntensity); - - if((alpha - myAlphaRecords.begin()) == 0 && lastIntensity > 0) { + + if ((alpha - myAlphaRecords.begin()) == 0 && lastIntensity > 0) { (*alpha)->setAlphaIntensity( (*alpha)->getAlphaIntensity() + lastIntensity); - } else if((alpha - myAlphaRecords.begin()) > 0) { + } + else if ((alpha - myAlphaRecords.begin()) > 0) { (*alpha)->setAlphaIntensity( - (*alpha)->getAlphaIntensity() + + (*alpha)->getAlphaIntensity() + (*(alpha-1))->getAlphaIntensity()); } lastIntensity = (*alpha)->getAlphaIntensity(); } - + // Normalize XRay emission intensities - for(unsigned int i=0; i < xrayIntensities.size(); ++i) { + for (unsigned int i=0; i < xrayIntensities.size(); ++i) { xrayIntensities[i] /= totalDecayIntensity; - - if(i==0 && lastIntensity > 0) { + + if (i==0 && lastIntensity > 0) { xrayIntensities[i] += lastIntensity; - } else if(i > 0) { + } + else if (i > 0) { xrayIntensities[i] += xrayIntensities[i-1]; } lastIntensity = xrayIntensities[i]; } - + // Normalize auger emission intensities - for(unsigned int i=0; i < augerIntensities.size(); ++i) { + for (unsigned int i=0; i < augerIntensities.size(); ++i) { augerIntensities[i] /= totalDecayIntensity; - - if(i==0 && lastIntensity > 0) { + + if (i==0 && lastIntensity > 0) { augerIntensities[i] += lastIntensity; - } else if(i > 0) { + } + else if (i > 0) { augerIntensities[i] += augerIntensities[i-1]; } lastIntensity = augerIntensities[i]; } - + // Get the gamma transition intensities // and the total intensity for each level unsigned int j = 0; vector totalLevelIntensity; totalLevelIntensity.resize(myLevelRecords.size()); - for(vector::iterator it = myLevelRecords.begin(); + for (vector::iterator it = myLevelRecords.begin(); it!=myLevelRecords.end(); it++) { - + totalLevelIntensity[j] = 0; - for(vector::iterator gamma = myGammaRecords.begin(); + for (vector::iterator gamma = myGammaRecords.begin(); gamma != myGammaRecords.end(); gamma++) { - - if((*gamma)->getLevelRecord() == (*it)) { + + if ((*gamma)->getLevelRecord() == (*it)) { totalLevelIntensity[j] += (*gamma)->getTransitionIntensity(); - printf("EGS_Ensdf::normalizeIntensities: %d %f %f\n", j, - (*gamma)->getTransitionIntensity(), - totalLevelIntensity[j]); + printf("EGS_Ensdf::normalizeIntensities: %d %f %f\n", j, + (*gamma)->getTransitionIntensity(), + totalLevelIntensity[j]); } } ++j; } - + // Normalize transition intensities over each level j = 0; - for(vector::iterator it = myLevelRecords.begin(); + for (vector::iterator it = myLevelRecords.begin(); it!=myLevelRecords.end(); it++) { - + unsigned int i = 0; - for(vector::iterator gamma = myGammaRecords.begin(); + for (vector::iterator gamma = myGammaRecords.begin(); gamma != myGammaRecords.end(); gamma++) { - - if((*gamma)->getLevelRecord() == (*it)) { - + + if ((*gamma)->getLevelRecord() == (*it)) { + (*gamma)->setTransitionIntensity( - (*gamma)->getTransitionIntensity() / + (*gamma)->getTransitionIntensity() / totalLevelIntensity[j]); - - if(i > 0) { + + if (i > 0) { (*gamma)->setTransitionIntensity( - (*gamma)->getTransitionIntensity() + + (*gamma)->getTransitionIntensity() + (*(gamma-1))->getTransitionIntensity()); } ++i; - + printf("EGS_Ensdf::normalizeIntensities: Gamma intensities: " - "%f\n",(*gamma)->getTransitionIntensity()); + "%f\n",(*gamma)->getTransitionIntensity()); } } ++j; } - + // Determine the final level that the gammas decay towards // We have to use the gamma decay energy to guess at the resulting // energy state of the radionuclide - for(vector::iterator gamma = myGammaRecords.begin(); + for (vector::iterator gamma = myGammaRecords.begin(); gamma != myGammaRecords.end(); gamma++) { - + double energy = (*gamma)->getDecayEnergy(); - double guessedLevelEnergy = + double guessedLevelEnergy = ((*gamma)->getLevelRecord()->getEnergy() - energy); - + printf("EGS_Ensdf::normalizeIntensities: Gamma (LE,E,GE): " - "%f %f %f\n",(*gamma)->getLevelRecord()->getEnergy(), - energy, guessedLevelEnergy); - + "%f %f %f\n",(*gamma)->getLevelRecord()->getEnergy(), + energy, guessedLevelEnergy); + double bestMatch = 1E10; LevelRecord *level; - for(vector::iterator it = myLevelRecords.begin(); + for (vector::iterator it = myLevelRecords.begin(); it!=myLevelRecords.end(); it++) { - + double testMatch = fabs((*it)->getEnergy()-guessedLevelEnergy); - - if(testMatch < bestMatch && - (testMatch < guessedLevelEnergy*0.3 || testMatch < 20 )) { - + + if (testMatch < bestMatch && + (testMatch < guessedLevelEnergy*0.3 || testMatch < 20)) { + bestMatch = testMatch; level = (*it); } } - if(bestMatch == 1E10) { + if (bestMatch == 1E10) { printf("EGS_Ensdf::normalizeIntensities: Warning: Could not find a " - "level with energy matching decay of gamma with energy E=%f, " - "assuming ground state\n",energy); + "level with energy matching decay of gamma with energy E=%f, " + "assuming ground state\n",energy); (*gamma)->setFinalLevel(myLevelRecords.front()); - } else { + } + else { (*gamma)->setFinalLevel(level); } - + printf("EGS_Ensdf::normalizeIntensities: Gamma (final level E): " - "%f\n",level->getEnergy()); + "%f\n",level->getEnergy()); } } @@ -723,144 +752,150 @@ void EGS_Ensdf::getEmissionsFromComments() { bool augerContinues = false; bool gotTotal = false; vector multilineEnergies, - multilineIntensities; - - for(vector::iterator comment = myCommentRecords.begin(); + multilineIntensities; + + for (vector::iterator comment = myCommentRecords.begin(); comment != myCommentRecords.end(); comment++) { - + string line = (*comment)->getComment(); - + // Check for the end of multi-line records // and average them together - if(line.length() < 48 || - ((xrayContinues || augerContinues) && line.at(30) != '|')) { - - if(gotTotal) { + if (line.length() < 48 || + ((xrayContinues || augerContinues) && line.at(30) != '|')) { + + if (gotTotal) { gotTotal = false; } - - if((xrayContinues || augerContinues) + + if ((xrayContinues || augerContinues) && multilineEnergies.size() > 0) { - + double energySum = 0; double intensitySum = 0; unsigned int numNonzeroE = 0; unsigned int numNonzeroI = 0; - for(unsigned int i=0; i < multilineEnergies.size(); ++i) { - if(multilineEnergies[i] > 0) { + for (unsigned int i=0; i < multilineEnergies.size(); ++i) { + if (multilineEnergies[i] > 0) { energySum += multilineEnergies[i]; numNonzeroE++; } } - for(unsigned int i=0; i < multilineIntensities.size(); ++i) { - if(multilineIntensities[i] > 0) { + for (unsigned int i=0; i < multilineIntensities.size(); ++i) { + if (multilineIntensities[i] > 0) { intensitySum += multilineIntensities[i]; numNonzeroI++; } } double energy; - if(numNonzeroE > 0) { + if (numNonzeroE > 0) { energy = energySum / numNonzeroE; } double intensity; - if(numNonzeroI > 0) { + if (numNonzeroI > 0) { intensity = intensitySum / numNonzeroI; } - - if(numNonzeroE > 0 && numNonzeroI > 0) { - if(xrayContinues) { + + if (numNonzeroE > 0 && numNonzeroI > 0) { + if (xrayContinues) { xrayEnergies.push_back(energy); xrayIntensities.push_back(intensity); - } else { + } + else { augerEnergies.push_back(energy); augerIntensities.push_back(intensity); } } - + multilineEnergies.clear(); multilineIntensities.clear(); } - + xrayContinues = false; augerContinues = false; } - + // Check for records containing XRays or Auger electrons - if(line.length() > 48) { - + if (line.length() > 48) { + // Skip this line if we already recorded the total // emission for the line - if(gotTotal) { + if (gotTotal) { continue; } - + string emissionLine = egsTrimString(line.substr(47)); - + // See if the line is an XRay or Auger - if(emissionLine.at(0) != 'X' && + if (emissionLine.at(0) != 'X' && emissionLine.find("AUGER") == std::string::npos) { continue; } - -// printf("EGS_Ensdf::getEmissionsFromComments: %s\n", + +// printf("EGS_Ensdf::getEmissionsFromComments: %s\n", // emissionLine.c_str()); - + string eStr = egsTrimString(line.substr(13, 15)); - + // If we have a range in energy (e.g. 0.1-0.3) // Find the average size_t eDash = eStr.find('-'); double energy; - if(eDash!=std::string::npos) { - if(eStr.length() > eDash+1) { + if (eDash!=std::string::npos) { + if (eStr.length() > eDash+1) { double e1 = atof(eStr.substr(0, eDash).c_str()); double e2 = atof(eStr.substr(eDash+1).c_str()); energy = (e1 + e2) / 2; - } else { + } + else { energy = atof(eStr.substr(0, eDash).c_str()); } - } else { - energy = atof(eStr.c_str()); } - + else { + energy = atof(eStr.c_str()); + } + // Convert the energy from keV to MeV energy /= 100; - + // Get the intensity string iStr = egsTrimString(line.substr(32, 9)); double intensity = atof(iStr.c_str()); - + // If this line is the total of the next lines, we will // skip the next lines and just use this one - if(emissionLine.find("(total)") != std::string::npos) { + if (emissionLine.find("(total)") != std::string::npos) { gotTotal = true; } - + // Multi-line records have a bar '|' at 30 // We will store the data and average them later - if(line.at(30) == '|') { - if(emissionLine.at(0) == 'X') { + if (line.at(30) == '|') { + if (emissionLine.at(0) == 'X') { xrayContinues = true; - } else if(emissionLine.find("AUGER") != std::string::npos) { + } + else if (emissionLine.find("AUGER") != std::string::npos) { augerContinues = true; } - + multilineEnergies.push_back(energy); multilineIntensities.push_back(intensity); - - } else { - if(emissionLine.at(0) == 'X') { - if(energy > 0 && intensity > 0) { + + } + else { + if (emissionLine.at(0) == 'X') { + if (energy > 0 && intensity > 0) { xrayEnergies.push_back(energy); xrayIntensities.push_back(intensity); } - } else if(emissionLine.find("AUGER") != std::string::npos) { + } + else if (emissionLine.find("AUGER") != std::string::npos) { augerEnergies.push_back(energy); augerIntensities.push_back(intensity); } } - -// printf("EGS_Ensdf::getEmissionsFromComments: (E,I) %f %f\n", + +// printf("EGS_Ensdf::getEmissionsFromComments: (E,I) %f %f\n", // energy, intensity); } } @@ -882,34 +917,34 @@ vector EGS_Ensdf::getAugerEnergies() const { return augerEnergies; } -vector EGS_Ensdf::getParentRecords() const { +vector EGS_Ensdf::getParentRecords() const { return myParentRecords; } -vector EGS_Ensdf::getLevelRecords() const { +vector EGS_Ensdf::getLevelRecords() const { return myLevelRecords; } -vector EGS_Ensdf::getBetaRecords() const { +vector EGS_Ensdf::getBetaRecords() const { return myBetaRecords; } -vector EGS_Ensdf::getGammaRecords() const { +vector EGS_Ensdf::getGammaRecords() const { return myGammaRecords; } -vector EGS_Ensdf::getAlphaRecords() const { +vector EGS_Ensdf::getAlphaRecords() const { return myAlphaRecords; } Record::Record(vector ensdf) { - if(!ensdf.empty()) { + if (!ensdf.empty()) { lines = ensdf; } } Record::~Record() { - + } vector Record::getRecords() const { @@ -917,95 +952,115 @@ vector Record::getRecords() const { } double Record::recordToDouble(int startPos, int endPos) { - if(!lines.empty()) { - string record = lines.front().substr(startPos-1, - endPos-startPos+1); + if (!lines.empty()) { + string record = lines.front().substr(startPos-1, + endPos-startPos+1); return atof(record.c_str()); - } else { + } + else { printf("Record::recordToDouble: Error: Record is empty\n"); return -1; } } double Record::parseHalfLife(int startPos, int endPos) { - if(lines.empty()) { + if (lines.empty()) { printf("Record::parseHalfLife: Error: Record is empty\n"); return -5; } - - string halfLifeStr = egsTrimString(lines.front().substr(startPos-1, - endPos-startPos+1)); + + string halfLifeStr = egsTrimString(lines.front().substr(startPos-1, + endPos-startPos+1)); printf("Record::parseHalfLife: %s\n", halfLifeStr.c_str()); // Return -1 for stable - if(halfLifeStr.substr(0,5).compare("STABLE") == 0) { + if (halfLifeStr.substr(0,5).compare("STABLE") == 0) { return -1; } - + // Store the length of the numeric part of the string in i unsigned int numLength; - for(numLength = 0; numLength < halfLifeStr.length(); numLength++) { - if(!isdigit(halfLifeStr[numLength]) + for (numLength = 0; numLength < halfLifeStr.length(); numLength++) { + if (!isdigit(halfLifeStr[numLength]) && halfLifeStr.at(numLength) != '.') { - + break; } } - + // If there was no numeric component return -2 - if(halfLifeStr.size() < numLength+2) { + if (halfLifeStr.size() < numLength+2) { return -2; } - + // Get the numeric part double hl = atof(halfLifeStr.substr(0, numLength).c_str()); - + // Convert to units of seconds - if(halfLifeStr.size()>numLength+2) { + if (halfLifeStr.size()>numLength+2) { string units = halfLifeStr.substr(numLength+1, 2); - if(units.compare("Y ") == 0) + if (units.compare("Y ") == 0) { hl *= 31556925.26; - else if(units.compare("D ") == 0) + } + else if (units.compare("D ") == 0) { hl *= 86400; - else if(units.compare("H ") == 0) + } + else if (units.compare("H ") == 0) { hl *= 3600; - else if(units.compare("M ") == 0) + } + else if (units.compare("M ") == 0) { hl *= 60; - else if(units.compare("S ") == 0) + } + else if (units.compare("S ") == 0) { hl *= 1; - else if(units.compare("MS") == 0) + } + else if (units.compare("MS") == 0) { hl *= 1E-3; - else if(units.compare("US") == 0) + } + else if (units.compare("US") == 0) { hl *= 1E-6; - else if(units.compare("NS") == 0) + } + else if (units.compare("NS") == 0) { hl *= 1E-9; - else if(units.compare("PS") == 0) + } + else if (units.compare("PS") == 0) { hl *= 1E-12; - else if(units.compare("FS") == 0) + } + else if (units.compare("FS") == 0) { hl *= 1E-15; - else if(units.compare("AS") == 0) + } + else if (units.compare("AS") == 0) { hl *= 1E-18; - else + } + else { return -3; - } else if(halfLifeStr.size()>numLength+1) { + } + } + else if (halfLifeStr.size()>numLength+1) { string units = halfLifeStr.substr(numLength+1, 1); - if(units.compare("Y") == 0) + if (units.compare("Y") == 0) { hl *= 31556925.26; - else if(units.compare("D") == 0) + } + else if (units.compare("D") == 0) { hl *= 86400; - else if(units.compare("H") == 0) + } + else if (units.compare("H") == 0) { hl *= 3600; - else if(units.compare("M") == 0) + } + else if (units.compare("M") == 0) { hl *= 60; - else if(units.compare("S") == 0) + } + else if (units.compare("S") == 0) { hl *= 1; + } else { return -3; } - } else { + } + else { hl = -4; } - + return hl; } @@ -1015,8 +1070,8 @@ CommentRecord::CommentRecord(vector ensdf):Record(ensdf) { } void CommentRecord::processEnsdf() { - if(!lines.empty()) { - + if (!lines.empty()) { + comment = lines.front(); } } @@ -1039,17 +1094,17 @@ double ParentRecord::getHalfLife() const { return halfLife; } -const ParentRecord * ParentRecordLeaf::getParentRecord() const { +const ParentRecord *ParentRecordLeaf::getParentRecord() const { return getBranch(); } -ParentRecordLeaf::ParentRecordLeaf(ParentRecord - *myRecord):Leaf(myRecord) { - +ParentRecordLeaf::ParentRecordLeaf(ParentRecord + *myRecord):Leaf(myRecord) { + } // Normalization Record -NormalizationRecord::NormalizationRecord(vector ensdf, +NormalizationRecord::NormalizationRecord(vector ensdf, ParentRecord *myParent):Record(ensdf), ParentRecordLeaf(myParent) { processEnsdf(); } @@ -1059,20 +1114,20 @@ void NormalizationRecord::processEnsdf() { normalizeTransition = recordToDouble(22, 29); normalizeBranch = recordToDouble(32, 39); normalizeBeta = recordToDouble(42, 49); - printf("NormalizationRecord::processEnsdf: %f %f %f %f\n", - normalizeRelative, normalizeTransition, normalizeBranch, normalizeBeta); + printf("NormalizationRecord::processEnsdf: %f %f %f %f\n", + normalizeRelative, normalizeTransition, normalizeBranch, normalizeBeta); } -// Multiplier for converting relative photon intensity to photons per 100 -// decays in the parent through the decay branch or to photons per 100 neutron -// captures in an (n,gamma) reaction. Required if the absolute photon intensity +// Multiplier for converting relative photon intensity to photons per 100 +// decays in the parent through the decay branch or to photons per 100 neutron +// captures in an (n,gamma) reaction. Required if the absolute photon intensity // can be calculated double NormalizationRecord::getRelativeMultiplier() const { return normalizeRelative; } -// Multiplier for convert relative transition intensity (including conversion -// electrons) to transitions per 100 decays of the parent through this decay +// Multiplier for convert relative transition intensity (including conversion +// electrons) to transitions per 100 decays of the parent through this decay // branch or per 100 neutron captures in an (n,gamma) reaction double NormalizationRecord::getTransitionMultiplier() const { return normalizeTransition; @@ -1084,20 +1139,20 @@ double NormalizationRecord::getBranchMultiplier() const { return normalizeBranch; } -// Multiplier for converting relative beta- and electron capture intensities to +// Multiplier for converting relative beta- and electron capture intensities to // intensities per 100 decays through this decay branch. Required if known double NormalizationRecord::getBetaMultiplier() const { return normalizeBeta; } -const NormalizationRecord * NormalizationRecordLeaf::getNormalizationRecord() - const { +const NormalizationRecord *NormalizationRecordLeaf::getNormalizationRecord() +const { return getBranch(); } -NormalizationRecordLeaf::NormalizationRecordLeaf(NormalizationRecord +NormalizationRecordLeaf::NormalizationRecordLeaf(NormalizationRecord *myRecord):Leaf(myRecord) { - + } // Level Record @@ -1119,23 +1174,23 @@ double LevelRecord::getHalfLife() const { return halfLife; } -const LevelRecord * LevelRecordLeaf::getLevelRecord() const { +const LevelRecord *LevelRecordLeaf::getLevelRecord() const { return getBranch(); } -LevelRecordLeaf::LevelRecordLeaf(LevelRecord - *myRecord):Leaf(myRecord) { - +LevelRecordLeaf::LevelRecordLeaf(LevelRecord + *myRecord):Leaf(myRecord) { + } // Beta Record -BetaRecordLeaf::BetaRecordLeaf(vector ensdf, - ParentRecord *myParent, NormalizationRecord *myNormalization, - LevelRecord *myLevel): - ParentRecordLeaf(myParent), - NormalizationRecordLeaf(myNormalization), - LevelRecordLeaf(myLevel), - Record(ensdf) { +BetaRecordLeaf::BetaRecordLeaf(vector ensdf, + ParentRecord *myParent, NormalizationRecord *myNormalization, + LevelRecord *myLevel): + ParentRecordLeaf(myParent), + NormalizationRecordLeaf(myNormalization), + LevelRecordLeaf(myLevel), + Record(ensdf) { numSampled = 0; } int BetaRecordLeaf::getCharge() const { @@ -1151,10 +1206,10 @@ EGS_I64 BetaRecordLeaf::getNumSampled() const { } // Beta- Record -BetaMinusRecord::BetaMinusRecord(vector ensdf, - ParentRecord *myParent, NormalizationRecord *myNormalization, - LevelRecord *myLevel):BetaRecordLeaf(ensdf, myParent, - myNormalization, myLevel) { +BetaMinusRecord::BetaMinusRecord(vector ensdf, + ParentRecord *myParent, NormalizationRecord *myNormalization, + LevelRecord *myLevel):BetaRecordLeaf(ensdf, myParent, + myNormalization, myLevel) { processEnsdf(); q = -1; } @@ -1162,12 +1217,12 @@ BetaMinusRecord::BetaMinusRecord(vector ensdf, void BetaMinusRecord::processEnsdf() { finalEnergy = recordToDouble(10, 19) / 1000; // Convert keV to MeV betaIntensity = recordToDouble(22, 29); - if(getNormalizationRecord()) { + if (getNormalizationRecord()) { betaIntensity *= getNormalizationRecord()->getBetaMultiplier() * - getNormalizationRecord()->getBranchMultiplier(); + getNormalizationRecord()->getBranchMultiplier(); } - printf("BetaMinusRecord::processEnsdf: %f %f\n", finalEnergy, - betaIntensity); + printf("BetaMinusRecord::processEnsdf: %f %f\n", finalEnergy, + betaIntensity); } double BetaMinusRecord::getFinalEnergy() const { @@ -1183,10 +1238,10 @@ void BetaMinusRecord::setBetaIntensity(double newIntensity) { } // Beta+ Record (and Electron Capture) -BetaPlusRecord::BetaPlusRecord(vector ensdf, - ParentRecord *myParent, NormalizationRecord *myNormalization, - LevelRecord *myLevel):BetaRecordLeaf(ensdf, myParent, - myNormalization, myLevel) { +BetaPlusRecord::BetaPlusRecord(vector ensdf, + ParentRecord *myParent, NormalizationRecord *myNormalization, + LevelRecord *myLevel):BetaRecordLeaf(ensdf, myParent, + myNormalization, myLevel) { processEnsdf(); q = 1; } @@ -1195,12 +1250,12 @@ void BetaPlusRecord::processEnsdf() { finalEnergy = recordToDouble(10, 19) / 1000; // Convert keV to MeV betaIntensity = recordToDouble(22, 29); ecIntensity = recordToDouble(32, 39); - if(getNormalizationRecord()) { + if (getNormalizationRecord()) { betaIntensity *= getNormalizationRecord()->getBetaMultiplier() * - getNormalizationRecord()->getBranchMultiplier(); + getNormalizationRecord()->getBranchMultiplier(); } - printf("BetaPlusRecord::processEnsdf: %f %f %f\n", finalEnergy, - betaIntensity, ecIntensity); + printf("BetaPlusRecord::processEnsdf: %f %f %f\n", finalEnergy, + betaIntensity, ecIntensity); } double BetaPlusRecord::getFinalEnergy() const { @@ -1224,8 +1279,8 @@ void BetaPlusRecord::setECIntensity(double newIntensity) { } // Gamma Record -GammaRecord::GammaRecord(vector ensdf, NormalizationRecord - *myNormalization, LevelRecord *myLevel):Record(ensdf), +GammaRecord::GammaRecord(vector ensdf, NormalizationRecord + *myNormalization, LevelRecord *myLevel):Record(ensdf), NormalizationRecordLeaf(myNormalization), LevelRecordLeaf(myLevel) { processEnsdf(); q = 0; @@ -1236,15 +1291,15 @@ void GammaRecord::processEnsdf() { decayEnergy = recordToDouble(10, 19) / 1000; // Convert keV to MeV transitionIntensity = recordToDouble(22, 29); halfLife = parseHalfLife(40, 49); - - if(getNormalizationRecord()) { - transitionIntensity *= + + if (getNormalizationRecord()) { + transitionIntensity *= getNormalizationRecord()->getRelativeMultiplier() * getNormalizationRecord()->getBranchMultiplier(); } - - printf("GammaRecord::processEnsdf: %f %f %f\n", decayEnergy, - transitionIntensity, halfLife); + + printf("GammaRecord::processEnsdf: %f %f %f\n", decayEnergy, + transitionIntensity, halfLife); } double GammaRecord::getDecayEnergy() const { @@ -1271,7 +1326,7 @@ EGS_I64 GammaRecord::getNumSampled() const { return numSampled; } -LevelRecord * GammaRecord::getFinalLevel() const { +LevelRecord *GammaRecord::getFinalLevel() const { return finalLevel; } @@ -1284,11 +1339,11 @@ double GammaRecord::getHalfLife() const { } // Alpha Record -AlphaRecord::AlphaRecord(vector ensdf, - ParentRecord *myParent, NormalizationRecord *myNormalization, - LevelRecord *myLevel):Record(ensdf), - ParentRecordLeaf(myParent), NormalizationRecordLeaf(myNormalization), - LevelRecordLeaf(myLevel) { +AlphaRecord::AlphaRecord(vector ensdf, + ParentRecord *myParent, NormalizationRecord *myNormalization, + LevelRecord *myLevel):Record(ensdf), + ParentRecordLeaf(myParent), NormalizationRecordLeaf(myNormalization), + LevelRecordLeaf(myLevel) { processEnsdf(); q = 2; numSampled = 0; @@ -1297,8 +1352,8 @@ AlphaRecord::AlphaRecord(vector ensdf, void AlphaRecord::processEnsdf() { finalEnergy = recordToDouble(10, 19) / 1000; // Convert keV to MeV alphaIntensity = recordToDouble(22, 29); - printf("AlphaRecord::processEnsdf: %f %f\n", finalEnergy, - alphaIntensity); + printf("AlphaRecord::processEnsdf: %f %f\n", finalEnergy, + alphaIntensity); } double AlphaRecord::getFinalEnergy() const { diff --git a/HEN_HOUSE/egs++/egs_ensdf.h b/HEN_HOUSE/egs++/egs_ensdf.h index d6b0c98e4..0a1a6981e 100644 --- a/HEN_HOUSE/egs++/egs_ensdf.h +++ b/HEN_HOUSE/egs++/egs_ensdf.h @@ -56,74 +56,73 @@ template class Branch { Branch() {} ~Branch() { - for(typename vector::iterator it = branchLeaves.begin(); + for (typename vector::iterator it = branchLeaves.begin(); it!=branchLeaves.end(); it++) { (*it)->removeBranch(); } branchLeaves.clear(); } - void addLeaf(T * leaf) { + void addLeaf(T *leaf) { branchLeaves.push_back(leaf); } - void removeLeaf(T * leaf) { - branchLeaves.erase(std::remove(branchLeaves.begin(), - branchLeaves.end(), - leaf), branchLeaves.end()); + void removeLeaf(T *leaf) { + branchLeaves.erase(std::remove(branchLeaves.begin(), + branchLeaves.end(), + leaf), branchLeaves.end()); } - - vector getLeaves() const { + + vector getLeaves() const { return branchLeaves; } // A new == operator for this class - bool operator==(const Branch & rhs) const { - for(typename vector::const_iterator it = branchLeaves.begin(); + bool operator==(const Branch &rhs) const { + for (typename vector::const_iterator it = branchLeaves.begin(); it!=branchLeaves.end(); it++) { - + bool foundLeaf = false; - for(typename vector::const_iterator irhs = - rhs.branchLeaves.begin(); + for (typename vector::const_iterator irhs = + rhs.branchLeaves.begin(); irhs!=rhs.branchLeaves.end(); irhs++) { - - if(*irhs != 0 && *it != 0) { - if(*irhs == *it) { + + if (*irhs != 0 && *it != 0) { + if (*irhs == *it) { foundLeaf = true; } } } - - if(!foundLeaf) { + + if (!foundLeaf) { return false; } } return true; } - + protected: - vector branchLeaves; + vector branchLeaves; }; template class Leaf { public: - - Leaf(T * existingTree) { + + Leaf(T *existingTree) { tree = existingTree; - if(tree) { + if (tree) { tree->addLeaf(this); } } ~Leaf() { - if(tree) { + if (tree) { tree->removeLeaf(this); } tree = 0; } - virtual T * getBranch() const - { + virtual T *getBranch() const { return tree; } @@ -132,21 +131,23 @@ template class Leaf { } // A new == operator for this class - bool operator== (const T& rhs) const - { - if(tree==0 && rhs.tree==0) { + bool operator== (const T &rhs) const { + if (tree==0 && rhs.tree==0) { return true; - } else if((tree==0) && rhs.tree!=0) { + } + else if ((tree==0) && rhs.tree!=0) { return false; - } else if((tree!=0) && rhs.tree==0) { + } + else if ((tree!=0) && rhs.tree==0) { return false; - } else if(tree!=0 && rhs.tree!=0) { + } + else if (tree!=0 && rhs.tree!=0) { return *tree == *(rhs.tree); } } private: - T * tree; + T *tree; }; // The Record class @@ -159,7 +160,7 @@ class Record { protected: double recordToDouble(int startPos, int endPos); double parseHalfLife(int startPos, int endPos); - + // All the lines corresponding to this record type vector lines; }; @@ -169,7 +170,7 @@ class CommentRecord : public Record { public: CommentRecord(vector ensdf); string getComment(); - + private: string comment; void processEnsdf(); @@ -183,20 +184,20 @@ class ParentRecord : public Record, public Branch > { protected: double halfLife; - + private: void processEnsdf(); }; class ParentRecordLeaf : public Leaf { public: - ParentRecordLeaf(ParentRecord * myRecord); - virtual const ParentRecord * getParentRecord() const; + ParentRecordLeaf(ParentRecord *myRecord); + virtual const ParentRecord *getParentRecord() const; }; // Normalization Record -class NormalizationRecord : public Record, public - Branch >, public ParentRecordLeaf { +class NormalizationRecord : public Record, public + Branch >, public ParentRecordLeaf { public: NormalizationRecord(vector ensdf, ParentRecord *parent); double getRelativeMultiplier() const; @@ -209,15 +210,15 @@ class NormalizationRecord : public Record, public double normalizeTransition; double normalizeBeta; double normalizeBranch; - + private: void processEnsdf(); }; class NormalizationRecordLeaf : public Leaf { public: - NormalizationRecordLeaf(NormalizationRecord * myRecord); - virtual const NormalizationRecord * getNormalizationRecord() const; + NormalizationRecordLeaf(NormalizationRecord *myRecord); + virtual const NormalizationRecord *getNormalizationRecord() const; }; // Level Record @@ -230,24 +231,24 @@ class LevelRecord : public Record, public Branch > { protected: double energy; double halfLife; - + private: void processEnsdf(); }; class LevelRecordLeaf : public Leaf { public: - LevelRecordLeaf(LevelRecord * myRecord); - virtual const LevelRecord * getLevelRecord() const; + LevelRecordLeaf(LevelRecord *myRecord); + virtual const LevelRecord *getLevelRecord() const; }; // Generic beta record -class BetaRecordLeaf : public Record, public ParentRecordLeaf, public - NormalizationRecordLeaf, public LevelRecordLeaf { +class BetaRecordLeaf : public Record, public ParentRecordLeaf, public + NormalizationRecordLeaf, public LevelRecordLeaf { public: - BetaRecordLeaf(vector ensdf, ParentRecord *myParent, - NormalizationRecord *myNormalization, LevelRecord *myLevel); - + BetaRecordLeaf(vector ensdf, ParentRecord *myParent, + NormalizationRecord *myNormalization, LevelRecord *myLevel); + virtual double getFinalEnergy() const = 0; virtual double getBetaIntensity() const = 0; virtual void setBetaIntensity(double newIntensity) = 0; @@ -265,13 +266,13 @@ class BetaRecordLeaf : public Record, public ParentRecordLeaf, public // Beta- record class BetaMinusRecord : public BetaRecordLeaf { public: - BetaMinusRecord(vector ensdf, ParentRecord *myParent, - NormalizationRecord *myNormalization, LevelRecord *myLevel); - + BetaMinusRecord(vector ensdf, ParentRecord *myParent, + NormalizationRecord *myNormalization, LevelRecord *myLevel); + double getFinalEnergy() const; double getBetaIntensity() const; void setBetaIntensity(double newIntensity); - + private: void processEnsdf(); }; @@ -279,9 +280,9 @@ class BetaMinusRecord : public BetaRecordLeaf { // Beta+ Record (and Electron Capture) class BetaPlusRecord : public BetaRecordLeaf { public: - BetaPlusRecord(vector ensdf, ParentRecord *myParent, - NormalizationRecord *myNormalization, LevelRecord *myLevel); - + BetaPlusRecord(vector ensdf, ParentRecord *myParent, + NormalizationRecord *myNormalization, LevelRecord *myLevel); + double getFinalEnergy() const; double getBetaIntensity() const; double getECIntensity() const; @@ -290,23 +291,23 @@ class BetaPlusRecord : public BetaRecordLeaf { protected: double ecIntensity; - + private: void processEnsdf(); }; // Gamma record -class GammaRecord : public Record, public NormalizationRecordLeaf, public +class GammaRecord : public Record, public NormalizationRecordLeaf, public LevelRecordLeaf { public: - GammaRecord(vector ensdf, NormalizationRecord *myNormalization, - LevelRecord *myLevel); - + GammaRecord(vector ensdf, NormalizationRecord *myNormalization, + LevelRecord *myLevel); + double getDecayEnergy() const; double getTransitionIntensity() const; void setTransitionIntensity(double newIntensity); int getCharge() const; - LevelRecord * getFinalLevel() const; + LevelRecord *getFinalLevel() const; void setFinalLevel(LevelRecord *newLevel); double getHalfLife() const; void incrNumSampled(); @@ -319,17 +320,17 @@ class GammaRecord : public Record, public NormalizationRecordLeaf, public double halfLife; int q; LevelRecord *finalLevel; - + private: void processEnsdf(); }; // Alpha record -class AlphaRecord : public Record, public ParentRecordLeaf, public - NormalizationRecordLeaf, public LevelRecordLeaf { +class AlphaRecord : public Record, public ParentRecordLeaf, public + NormalizationRecordLeaf, public LevelRecordLeaf { public: - AlphaRecord(vector ensdf, ParentRecord *myParent, - NormalizationRecord *myNormalization, LevelRecord *myLevel); + AlphaRecord(vector ensdf, ParentRecord *myParent, + NormalizationRecord *myNormalization, LevelRecord *myLevel); double getFinalEnergy() const; double getAlphaIntensity() const; @@ -337,13 +338,13 @@ class AlphaRecord : public Record, public ParentRecordLeaf, public void setAlphaIntensity(double newIntensity); void incrNumSampled(); EGS_I64 getNumSampled() const; - + protected: EGS_I64 numSampled; double finalEnergy; double alphaIntensity; int q; - + private: void processEnsdf(); }; @@ -357,29 +358,29 @@ class AlphaRecord : public Record, public ParentRecordLeaf, public */ class EGS_EXPORT EGS_Ensdf { - + public: - + /*! \brief Construct an ensdf object * */ EGS_Ensdf(const string isotope, const string ensdf_filename=""); - + /*! \brief Destructor. Deallocates all allocated memory */ ~EGS_Ensdf(); - + vector getRecords() const; vector getBetaRecords() const; - vector getParentRecords() const; - vector getLevelRecords() const; - vector getAlphaRecords() const; - vector getGammaRecords() const; + vector getParentRecords() const; + vector getLevelRecords() const; + vector getAlphaRecords() const; + vector getGammaRecords() const; vector getXRayIntensities() const; vector getXRayEnergies() const; vector getAugerIntensities() const; vector getAugerEnergies() const; string radionuclide; - + void normalizeIntensities(); protected: @@ -389,31 +390,31 @@ class EGS_EXPORT EGS_Ensdf { unsigned short int findAtomicWeight(string element); void parseEnsdf(vector ensdf); void buildRecords(); - + void getEmissionsFromComments(); - + ifstream ensdf_file; unsigned short int A; - vector myRecords; - vector myCommentRecords; - vector myParentRecords; - vector myNormalizationRecords; - vector myLevelRecords; + vector myRecords; + vector myCommentRecords; + vector myParentRecords; + vector myNormalizationRecords; + vector myLevelRecords; vector myBetaRecords; - vector myBetaMinusRecords; - vector myBetaPlusRecords; - vector myAlphaRecords; - vector myGammaRecords; - + vector myBetaMinusRecords; + vector myBetaPlusRecords; + vector myAlphaRecords; + vector myGammaRecords; + private: - + vector > recordStack; vector commentLines; vector xrayEnergies, - xrayIntensities, - augerEnergies, - augerIntensities; + xrayIntensities, + augerEnergies, + augerIntensities; }; diff --git a/HEN_HOUSE/egs++/egs_spectra.cpp b/HEN_HOUSE/egs++/egs_spectra.cpp index c7968aa4e..876453bf4 100644 --- a/HEN_HOUSE/egs++/egs_spectra.cpp +++ b/HEN_HOUSE/egs++/egs_spectra.cpp @@ -442,7 +442,7 @@ class EGS_EXPORT EGS_TabulatedSpectrum : public EGS_BaseSpectrum { * * \ingroup egspp_main * - + */ @@ -452,17 +452,17 @@ class EGS_EXPORT EGS_RadionuclideSpectrum : public EGS_BaseSpectrum { /*! \brief Construct a radionuclide spectrum. */ - EGS_RadionuclideSpectrum(const string isotope, const string ensdf_file, -const EGS_Float weight) : - EGS_BaseSpectrum() { - + EGS_RadionuclideSpectrum(const string isotope, const string ensdf_file, + const EGS_Float weight) : + EGS_BaseSpectrum() { + // Read in the data file for the isotope // and build the decay structure decays = new EGS_Ensdf(isotope, ensdf_file); - + // Normalize the emission and transition intensities decays->normalizeIntensities(); - + // Get the particle records from the decay scheme myBetas = decays->getBetaRecords(); myAlphas = decays->getAlphaRecords(); @@ -472,54 +472,54 @@ const EGS_Float weight) : xrayEnergies = decays->getXRayEnergies(); augerIntensities = decays->getAugerIntensities(); augerEnergies = decays->getAugerEnergies(); - + // Initialization currentLevel = 0; Emax = 0; currentTime = 0; ishower = -1; // Start with ishower -1 so first shower has index 0 - + // Get the maximum energy for emissions - for(vector::iterator beta = myBetas.begin(); + for (vector::iterator beta = myBetas.begin(); beta != myBetas.end(); beta++) { - + double energy = (*beta)->getFinalEnergy(); - if(Emax < energy) { + if (Emax < energy) { Emax = energy; } } - for(vector::iterator alpha = myAlphas.begin(); + for (vector::iterator alpha = myAlphas.begin(); alpha != myAlphas.end(); alpha++) { - + double energy = (*alpha)->getFinalEnergy(); - if(Emax < energy) { + if (Emax < energy) { Emax = energy; } } - for(vector::iterator gamma = myGammas.begin(); + for (vector::iterator gamma = myGammas.begin(); gamma != myGammas.end(); gamma++) { - + double energy = (*gamma)->getDecayEnergy(); - if(Emax < energy) { + if (Emax < energy) { Emax = energy; } } - for(unsigned int i=0; i < xrayEnergies.size(); ++i) { + for (unsigned int i=0; i < xrayEnergies.size(); ++i) { numSampledXRay.push_back(0); - if(Emax < xrayEnergies[i]) { + if (Emax < xrayEnergies[i]) { Emax = xrayEnergies[i]; } } - for(unsigned int i=0; i < augerEnergies.size(); ++i) { + for (unsigned int i=0; i < augerEnergies.size(); ++i) { numSampledAuger.push_back(0); - if(Emax < augerEnergies[i]) { + if (Emax < augerEnergies[i]) { Emax = augerEnergies[i]; } } - + // Set the weight of the spectrum spectrumWeight = weight; - + printf("EGS_RadionuclideSpectrum: Emax: %f\n",Emax); printf("EGS_RadionuclideSpectrum: Weight: %f\n",weight); }; @@ -527,199 +527,200 @@ const EGS_Float weight) : ~EGS_RadionuclideSpectrum() { delete decays; }; - + int getCharge() const { return currentQ; } - + double getTime() const { return currentTime; } - + void setMaximumTime(double maxTime) { Tmax = maxTime; } - + EGS_I64 getShowerIndex() const { return ishower; } - + EGS_Float getSpectrumWeight() const { return spectrumWeight; } - + void setSpectrumWeight(EGS_Float newWeight) { spectrumWeight = newWeight; } - + void printSampledEmissions() { printf("\nSampled %s emissions:\n", decays->radionuclide.c_str()); printf("========================\n"); printf("Energy | Intensity per 100 emissions\n"); - if(myBetas.size() > 0) { + if (myBetas.size() > 0) { printf("Beta records:\n"); } - for(vector::iterator beta = myBetas.begin(); + for (vector::iterator beta = myBetas.begin(); beta != myBetas.end(); beta++) { - - printf("%f %f\n", (*beta)->getFinalEnergy(), - ((EGS_Float)(*beta)->getNumSampled()/ishower)*100); + + printf("%f %f\n", (*beta)->getFinalEnergy(), + ((EGS_Float)(*beta)->getNumSampled()/ishower)*100); } - if(myAlphas.size() > 0) { + if (myAlphas.size() > 0) { printf("Alpha records:\n"); } - for(vector::iterator alpha = myAlphas.begin(); + for (vector::iterator alpha = myAlphas.begin(); alpha != myAlphas.end(); alpha++) { - - printf("%f %f\n", (*alpha)->getFinalEnergy(), - ((EGS_Float)(*alpha)->getNumSampled()/ishower)*100); + + printf("%f %f\n", (*alpha)->getFinalEnergy(), + ((EGS_Float)(*alpha)->getNumSampled()/ishower)*100); } - if(myGammas.size() > 0) { + if (myGammas.size() > 0) { printf("Gamma records:\n"); } - for(vector::iterator gamma = myGammas.begin(); + for (vector::iterator gamma = myGammas.begin(); gamma != myGammas.end(); gamma++) { - - printf("%f %f\n", (*gamma)->getDecayEnergy(), - ((EGS_Float)(*gamma)->getNumSampled()/ishower)*100); + + printf("%f %f\n", (*gamma)->getDecayEnergy(), + ((EGS_Float)(*gamma)->getNumSampled()/ishower)*100); } - if(xrayEnergies.size() > 0) { + if (xrayEnergies.size() > 0) { printf("X-Ray records:\n"); } - for(unsigned int i=0; i < xrayEnergies.size(); ++i) { - printf("%f %f\n", xrayEnergies[i], - ((EGS_Float)numSampledXRay[i]/ishower)*100); + for (unsigned int i=0; i < xrayEnergies.size(); ++i) { + printf("%f %f\n", xrayEnergies[i], + ((EGS_Float)numSampledXRay[i]/ishower)*100); } - if(augerEnergies.size() > 0) { + if (augerEnergies.size() > 0) { printf("Auger records:\n"); } - for(unsigned int i=0; i < augerEnergies.size(); ++i) { - printf("%f %f\n", augerEnergies[i], - ((EGS_Float)numSampledAuger[i]/ishower)*100); + for (unsigned int i=0; i < augerEnergies.size(); ++i) { + printf("%f %f\n", augerEnergies[i], + ((EGS_Float)numSampledAuger[i]/ishower)*100); } printf("\n"); } - + protected: EGS_Float sample(EGS_RandomGenerator *rndm) { - + // Sample a uniform random number EGS_Float u = rndm->getUniform(); - + // The energy of the sampled particle EGS_Float E; - + // If the daughter is in an excited state // Check for transitions - if(currentLevel && currentLevel->getEnergy() > 0) { + if (currentLevel && currentLevel->getEnergy() > 0) { // printf("EGS_RadionuclideSpectrum:sample: excited daughter " // "%f\n",currentLevel->getEnergy()); - - for(vector::iterator gamma = myGammas.begin(); + + for (vector::iterator gamma = myGammas.begin(); gamma != myGammas.end(); gamma++) { - - if((*gamma)->getLevelRecord() == currentLevel) { - - if(u < (*gamma)->getTransitionIntensity()) { - + + if ((*gamma)->getLevelRecord() == currentLevel) { + + if (u < (*gamma)->getTransitionIntensity()) { + (*gamma)->incrNumSampled(); currentQ = (*gamma)->getCharge(); - - currentTime += currentLevel->getHalfLife() / -0.693147180559945309417232121458176568075500134360255254120680009493393 - * log(rndm->getUniform()); - + + currentTime += currentLevel->getHalfLife() / + 0.693147180559945309417232121458176568075500134360255254120680009493393 + * log(rndm->getUniform()); + currentLevel = (*gamma)->getFinalLevel(); - - - + + + E = (*gamma)->getDecayEnergy(); return E; } } } - } else { + } + else { // Incremember the shower number ishower++; - + // Uniformly distribute decays over the experiment time currentTime = rndm->getUniform() * Tmax; - + // Sample which decay occurs // Betas - for(vector::iterator beta = myBetas.begin(); + for (vector::iterator beta = myBetas.begin(); beta != myBetas.end(); beta++) { - if(u < (*beta)->getBetaIntensity()) { - + if (u < (*beta)->getBetaIntensity()) { + (*beta)->incrNumSampled(); currentQ = (*beta)->getCharge(); //printf("EGS_RadionuclideSpectrum: q: %d\n",currentQ); - + // Set the energy level of the daughter currentLevel = (*beta)->getLevelRecord(); - + // TODO: Generate beta- spectrum // TODO: Need to implement electron capture - + // For now just uniform up to max! E = u * (*beta)->getFinalEnergy(); //printf("\nEGS_RadionuclideSpectrum: E: %f\n",E); return E; } } - + // Alphas - for(vector::iterator alpha = myAlphas.begin(); + for (vector::iterator alpha = myAlphas.begin(); alpha != myAlphas.end(); alpha++) { - if(u < (*alpha)->getAlphaIntensity()) { - + if (u < (*alpha)->getAlphaIntensity()) { + (*alpha)->incrNumSampled(); currentQ = (*alpha)->getCharge(); - + // Set the energy level of the daughter currentLevel = (*alpha)->getLevelRecord(); - - // For alphas we simulate a disintegration but the + + // For alphas we simulate a disintegration but the // transport will not be performed return 0; } } - + // XRays - for(unsigned int i=0; i < xrayIntensities.size(); ++i) { - if(u < xrayIntensities[i]) { - + for (unsigned int i=0; i < xrayIntensities.size(); ++i) { + if (u < xrayIntensities[i]) { + numSampledXRay[i]++; currentQ = 0; - + E = xrayEnergies[i]; - + return E; } } - + // Auger electrons - for(unsigned int i=0; i < augerIntensities.size(); ++i) { - if(u < augerIntensities[i]) { - + for (unsigned int i=0; i < augerIntensities.size(); ++i) { + if (u < augerIntensities[i]) { + numSampledAuger[i]++; currentQ = -1; - + E = augerEnergies[i]; - + return E; } } } - + // Shouldn't get here return 0; }; - + EGS_Float maxEnergy() const { return Emax; }; - + EGS_Float expectedAverage() const { return 0; }; @@ -732,16 +733,16 @@ const EGS_Float weight) : vector myGammas; vector myLevels; vector xrayIntensities, - xrayEnergies, - augerIntensities, - augerEnergies; + xrayEnergies, + augerIntensities, + augerEnergies; vector numSampledXRay, - numSampledAuger; + numSampledAuger; const LevelRecord *currentLevel; int currentQ; - EGS_Float currentTime, - Emax, - Tmax, + EGS_Float currentTime, + Emax, + Tmax, spectrumWeight; EGS_I64 ishower; }; @@ -1103,24 +1104,25 @@ EGS_BaseSpectrum *EGS_BaseSpectrum::createSpectrum(EGS_Input *input) { } } } - } else if (inp->compare(stype,"radionuclide")) { + } + else if (inp->compare(stype,"radionuclide")) { string isotope; err = inp->getInput("isotope",isotope); - if(err) { + if (err) { egsWarning("%s wrong/missing 'isotope' input\n",spec_msg1); return 0; } - + EGS_Float weight; err = inp->getInput("weight",weight); - if(err) { + if (err) { weight = 1; } - + // For ensdf input, first check for the input argument string ensdf_file; err = inp->getInput("ensdf file",ensdf_file); - + // If not passed as input, find the ensdf file in the // directory $HEN_HOUSE/spectra/lnhb if (err) { @@ -1129,15 +1131,17 @@ EGS_BaseSpectrum *EGS_BaseSpectrum::createSpectrum(EGS_Input *input) { if (app) { ensdf_file = egsJoinPath(app->getHenHouse(),"spectra"); ensdf_file = egsJoinPath(ensdf_file.c_str(),"lnhb"); - } else { + } + else { char *hen_house = getenv("HEN_HOUSE"); if (!hen_house) { - + egsWarning("EGS_BaseSpectrum::createSpectrum: " - "No active application and HEN_HOUSE not defined.\n" - "Assuming local directory for spectra\n"); + "No active application and HEN_HOUSE not defined.\n" + "Assuming local directory for spectra\n"); ensdf_file = "./"; - } else { + } + else { ensdf_file = egsJoinPath(hen_house,"spectra"); ensdf_file = egsJoinPath(ensdf_file.c_str(),"lnhb"); } @@ -1145,7 +1149,8 @@ EGS_BaseSpectrum *EGS_BaseSpectrum::createSpectrum(EGS_Input *input) { ensdf_file = egsJoinPath(ensdf_file.c_str(),isotope.append(".txt")); } spec = new EGS_RadionuclideSpectrum(isotope, ensdf_file, weight); - } else { + } + else { egsWarning("%s unknown spectrum type %s\n",spec_msg1,stype.c_str()); } if (delete_it) { diff --git a/HEN_HOUSE/egs++/sources/egs_radionuclide_source/egs_radionuclide_source.cpp b/HEN_HOUSE/egs++/sources/egs_radionuclide_source/egs_radionuclide_source.cpp index ce5e94ba7..3af21587e 100644 --- a/HEN_HOUSE/egs++/sources/egs_radionuclide_source/egs_radionuclide_source.cpp +++ b/HEN_HOUSE/egs++/sources/egs_radionuclide_source/egs_radionuclide_source.cpp @@ -40,66 +40,66 @@ #include "egs_application.h" EGS_RadionuclideSource::EGS_RadionuclideSource(EGS_Input *input, - EGS_ObjectFactory *f) : EGS_BaseSource(input,f), shape(0), - geom(0), regions(0), nrs(0), min_theta(0), max_theta(M_PI), - min_phi(0), max_phi(2*M_PI), gc(IncludeAll), q_allowed(0), decays(0), - activity(0) { - + EGS_ObjectFactory *f) : EGS_BaseSource(input,f), shape(0), + geom(0), regions(0), nrs(0), min_theta(0), max_theta(M_PI), + min_phi(0), max_phi(2*M_PI), gc(IncludeAll), q_allowed(0), decays(0), + activity(0) { + int err; - + // TODO: Make use of q_allowed to reject particles? vector tmp_q; err = input->getInput("charge", tmp_q); if (!err) { q_allowed = tmp_q; } - + // Create the decay spectra count = 0; Emax = 0; unsigned int i = 0; EGS_Float spectrumWeightTotal = 0; - while(input->getInputItem("spectrum")) { - + while (input->getInputItem("spectrum")) { + decays.push_back(EGS_BaseSpectrum::createSpectrum(input)); if (!decays[i]) { break; } - + EGS_Float spectrumMaxE = decays[i]->maxEnergy(); - if(spectrumMaxE > Emax) { + if (spectrumMaxE > Emax) { Emax = spectrumMaxE; } - + spectrumWeightTotal += decays[i]->getSpectrumWeight(); - + ++i; } - if(decays.size() < 1) { + if (decays.size() < 1) { egsWarning("EGS_RadionuclideSource: no spectrum was defined\n"); } - + // Normalize the spectrum weights - for(i=0; isetSpectrumWeight( decays[i]->getSpectrumWeight() / spectrumWeightTotal); - - if(i > 0) { + + if (i > 0) { decays[i]->setSpectrumWeight( - decays[i]->getSpectrumWeight() + + decays[i]->getSpectrumWeight() + decays[i-1]->getSpectrumWeight()); } } - + // Get the activity EGS_Float tmp_A; err = input->getInput("activity", tmp_A); if (!err) { activity = tmp_A; } - egsWarning("EGS_RadionuclideSource: Activity [disintegrations/s]: %e\n", - activity); - + egsWarning("EGS_RadionuclideSource: Activity [disintegrations/s]: %e\n", + activity); + // Calculate the duration of the experiment // Based on ncase and activity EGS_Application *app = EGS_Application::activeApplication(); @@ -108,33 +108,34 @@ EGS_RadionuclideSource::EGS_RadionuclideSource(EGS_Input *input, double ncase_double = 0; if (inp) { irc = inp->getInputItem("run control"); - + EGS_Input *icontrol = irc->getInputItem("run control"); - if(!icontrol) { + if (!icontrol) { egsWarning("EGS_RadionuclideSource: no 'run control' " "input to determine 'ncase'\n"); } - + err = icontrol->getInput("number of histories", ncase_double); - if(err) { + if (err) { err = icontrol->getInput("ncase", ncase_double); - if(err) { + if (err) { egsWarning("EGS_RadionuclideSource: missing/wrong 'ncase' or " - "'number of histories' input\n"); + "'number of histories' input\n"); } } - } else { + } + else { egsWarning("EGS_RadionuclideSource: no 'run control' " "input to determine 'ncase'\n"); } - + double Tmax = ncase_double / activity; - egsWarning("EGS_RadionuclideSource: Duration of experiment [s]: %e\n", - Tmax); - for(i=0; isetMaximumTime(Tmax); } - + // Create the shape for source emissions vector pos; EGS_Input *ishape = input->takeInputItem("shape"); @@ -151,7 +152,7 @@ EGS_RadionuclideSource::EGS_RadionuclideSource(EGS_Input *input, else { shape = EGS_BaseShape::getShape(sname); if (!shape) egsWarning("EGS_RadionuclideSource: a shape named %s" - " does not exist\n"); + " does not exist\n"); } } string geom_name; @@ -167,14 +168,14 @@ EGS_RadionuclideSource::EGS_RadionuclideSource(EGS_Input *input, reg_options.push_back("IncludeSelected"); reg_options.push_back("ExcludeSelected"); gc = (GeometryConfinement) input->getInput("region " - "selection",reg_options,0); + "selection",reg_options,0); if (gc == IncludeSelected || gc == ExcludeSelected) { vector regs; err = input->getInput("selected regions",regs); if (err || regs.size() < 1) { egsWarning("EGS_RadionuclideSource: region selection %d " - "used but no 'selected regions' input " - "found\n",gc); + "used but no 'selected regions' input " + "found\n",gc); gc = gc == IncludeSelected ? IncludeAll : ExcludeAll; egsWarning(" using %d\n",gc); } @@ -213,48 +214,48 @@ EGS_RadionuclideSource::EGS_RadionuclideSource(EGS_Input *input, setUp(); } -EGS_I64 EGS_RadionuclideSource::getNextParticle(EGS_RandomGenerator *rndm, int - &q, int &latch, EGS_Float &E, EGS_Float &wt, EGS_Vector &x, EGS_Vector +EGS_I64 EGS_RadionuclideSource::getNextParticle(EGS_RandomGenerator *rndm, int + &q, int &latch, EGS_Float &E, EGS_Float &wt, EGS_Vector &x, EGS_Vector &u) { - + // Sample a uniform random number EGS_Float uRand = rndm->getUniform(); - + // Sample which spectrum to use unsigned int i; - for(i=0; igetSpectrumWeight()) { + for (i=0; igetSpectrumWeight()) { break; } } - + E = decays[i]->sampleEnergy(rndm); q = decays[i]->getCharge(); time = decays[i]->getTime(); ishower = decays[i]->getShowerIndex(); - + getPositionDirection(rndm,x,u,wt); latch = 0; - -// egsWarning("EGS_RadionuclideSource::getNextParticle: E: %f\n", + +// egsWarning("EGS_RadionuclideSource::getNextParticle: E: %f\n", // E); -// -// egsWarning("EGS_RadionuclideSource::getNextParticle: q: %d\n", +// +// egsWarning("EGS_RadionuclideSource::getNextParticle: q: %d\n", // q); - + return ++count; } -// EGS_I64 EGS_RadionuclideSource::getNextParticle(EGS_RandomGenerator *rndm, int -// &q, int &latch, EGS_Float &E, EGS_Float &wt, EGS_Vector &x, EGS_Vector +// EGS_I64 EGS_RadionuclideSource::getNextParticle(EGS_RandomGenerator *rndm, int +// &q, int &latch, EGS_Float &E, EGS_Float &wt, EGS_Vector &x, EGS_Vector // &u, EGS_I64 &ishower, EGS_Float &time) { -// +// // ishower = count; -// +// // getNextParticle(rndm, q, latch, E, wt, x, u); -// +// // time = decays->getTime(); -// +// // return count; // } @@ -267,16 +268,14 @@ void EGS_RadionuclideSource::setUp() { description = "Radionuclide source from a shape of type "; description += shape->getObjectType(); description += " with:"; - if (std::find(q_allowed.begin(), q_allowed.end(), -1) != + if (std::find(q_allowed.begin(), q_allowed.end(), -1) != q_allowed.end()) { description += " electrons"; } - if (std::find(q_allowed.begin(), q_allowed.end(), 0) != q_allowed.end()) - { + if (std::find(q_allowed.begin(), q_allowed.end(), 0) != q_allowed.end()) { description += " photons"; } - if (std::find(q_allowed.begin(), q_allowed.end(), 1) != q_allowed.end()) - { + if (std::find(q_allowed.begin(), q_allowed.end(), 1) != q_allowed.end()) { description += " positrons"; } @@ -288,11 +287,11 @@ void EGS_RadionuclideSource::setUp() { extern "C" { - EGS_RADIONUCLIDE_SOURCE_EXPORT EGS_BaseSource *createSource(EGS_Input + EGS_RADIONUCLIDE_SOURCE_EXPORT EGS_BaseSource *createSource(EGS_Input *input, EGS_ObjectFactory *f) { return createSourceTemplate(input,f,"radionuclide " - "source"); + "source"); } } diff --git a/HEN_HOUSE/egs++/sources/egs_radionuclide_source/egs_radionuclide_source.h b/HEN_HOUSE/egs++/sources/egs_radionuclide_source/egs_radionuclide_source.h index 154247ff4..33a1849ff 100644 --- a/HEN_HOUSE/egs++/sources/egs_radionuclide_source/egs_radionuclide_source.h +++ b/HEN_HOUSE/egs++/sources/egs_radionuclide_source/egs_radionuclide_source.h @@ -23,7 +23,7 @@ # # Author: Reid Townson, 2016 # -# Contributors: +# Contributors: # ############################################################################### */ @@ -49,24 +49,24 @@ #ifdef WIN32 - #ifdef BUILD_RADIONUCLIDE_SOURCE_DLL - #define EGS_RADIONUCLIDE_SOURCE_EXPORT __declspec(dllexport) - #else - #define EGS_RADIONUCLIDE_SOURCE_EXPORT __declspec(dllimport) - #endif - #define EGS_RADIONUCLIDE_SOURCE_LOCAL +#ifdef BUILD_RADIONUCLIDE_SOURCE_DLL + #define EGS_RADIONUCLIDE_SOURCE_EXPORT __declspec(dllexport) +#else + #define EGS_RADIONUCLIDE_SOURCE_EXPORT __declspec(dllimport) +#endif +#define EGS_RADIONUCLIDE_SOURCE_LOCAL #else - #ifdef HAVE_VISIBILITY - #define EGS_RADIONUCLIDE_SOURCE_EXPORT __attribute__ ((visibility +#ifdef HAVE_VISIBILITY +#define EGS_RADIONUCLIDE_SOURCE_EXPORT __attribute__ ((visibility ("default"))) - #define EGS_RADIONUCLIDE_SOURCE_LOCAL __attribute__ ((visibility +#define EGS_RADIONUCLIDE_SOURCE_LOCAL __attribute__ ((visibility ("hidden"))) - #else - #define EGS_RADIONUCLIDE_SOURCE_EXPORT - #define EGS_RADIONUCLIDE_SOURCE_LOCAL - #endif +#else +#define EGS_RADIONUCLIDE_SOURCE_EXPORT +#define EGS_RADIONUCLIDE_SOURCE_LOCAL +#endif #endif @@ -76,8 +76,8 @@ A radionuclide source is a source that delivers particles with directions uniformly distributed in \f$4 \pi\f$ emitted from -\link EGS_BaseShape any shape. Emissions are based on decays from the -radionuclide isotope and can be a mix of beta decays, X-radiations, etc. +\link EGS_BaseShape any shape. Emissions are based on decays from the +radionuclide isotope and can be a mix of beta decays, X-radiations, etc. \endlink It is defined using the following input \verbatim @@ -85,10 +85,10 @@ It is defined using the following input name = my_mixture library = egs_radionuclide_source activity = total activity of mixture, assumed constant - charge = list including at least one of -1, 0, 1 to + charge = list including at least one of -1, 0, 1 to include electrons, photons and positrons geometry = my_geometry # see egs_isotropic_source - region selection = geometry confinement option, one of IncludeAll, + region selection = geometry confinement option, one of IncludeAll, ExcludeAll, IncludeSelected, ExcludeSelected selected regions = regions to apply geometry confinement :start shape: @@ -96,10 +96,10 @@ ExcludeAll, IncludeSelected, ExcludeSelected :stop shape: :start spectrum: type = radionuclide - isotope = name of the isotope (e.g. Sr-90), used to look up the + isotope = name of the isotope (e.g. Sr-90), used to look up the ensdf file in $HEN_HOUSE/spectra/lnhb if ensdf file not provided ensdf file = [optional] path to a spectrum file in ensdf format - weight = [optional] the relative activity (sampling + weight = [optional] the relative activity (sampling probability) for this isotope in a mixture :stop spectrum: :start spectrum: @@ -130,14 +130,14 @@ class EGS_RADIONUCLIDE_SOURCE_EXPORT EGS_RadionuclideSource : Construct a radionuclide source with charge array \a Q, spectra array \a Decays and emitting particles from the shape \a Shape */ - EGS_RadionuclideSource(vector Q_allowed, vector - Decays, EGS_Float Activity, EGS_BaseShape *Shape, EGS_BaseGeometry - *geometry, const string &Name="", EGS_ObjectFactory *f=0) : - EGS_BaseSource(Name,f), shape(Shape), - min_theta(85.), max_theta(95.), min_phi(0), max_phi(2*M_PI), - buf_1(1), buf_2(-1), - geom(geometry), regions(0), nrs(0), gc(IncludeAll), - q_allowed(Q_allowed), decays(Decays), activity(Activity) { + EGS_RadionuclideSource(vector Q_allowed, vector + Decays, EGS_Float Activity, EGS_BaseShape *Shape, EGS_BaseGeometry + *geometry, const string &Name="", EGS_ObjectFactory *f=0) : + EGS_BaseSource(Name,f), shape(Shape), + min_theta(85.), max_theta(95.), min_phi(0), max_phi(2*M_PI), + buf_1(1), buf_2(-1), + geom(geometry), regions(0), nrs(0), gc(IncludeAll), + q_allowed(Q_allowed), decays(Decays), activity(Activity) { setUp(); }; @@ -157,34 +157,34 @@ class EGS_RADIONUCLIDE_SOURCE_EXPORT EGS_RadionuclideSource : delete [] regions; } }; - + EGS_I64 getNextParticle(EGS_RandomGenerator *rndm, int &q, int &latch, EGS_Float &E, EGS_Float &wt, EGS_Vector &x, EGS_Vector &u); - + // EGS_I64 getNextParticle(EGS_RandomGenerator *rndm, // int &q, int &latch, EGS_Float &E, EGS_Float &wt, // EGS_Vector &x, EGS_Vector &u, EGS_I64 &ishower, // EGS_Float &time); - + EGS_Float getEmax() const { return Emax; }; - + EGS_Float getFluence() const { return count; }; - + double getTime() const { return time; }; - + EGS_I64 getShowerIndex() const { return ishower; }; - + void printSampledEmissions() { - for(unsigned int i=0; iprintSampledEmissions(); } } @@ -255,7 +255,7 @@ class EGS_RADIONUCLIDE_SOURCE_EXPORT EGS_RadionuclideSource : bool isValid() const { return (decays.size() != 0 && shape != 0); }; - + /*! \brief Store the source state to the data stream \a data_out. * * Uses the \link EGS_BaseSpectrum::storeState() storeState() \endlink @@ -265,7 +265,7 @@ class EGS_RADIONUCLIDE_SOURCE_EXPORT EGS_RadionuclideSource : if (!egsStoreI64(data_out,count)) { return false; } - for(unsigned int i=0; istoreState(data_out)) { return false; } @@ -287,7 +287,7 @@ class EGS_RADIONUCLIDE_SOURCE_EXPORT EGS_RadionuclideSource : if (!egsGetI64(data,count)) { return false; } - for(unsigned int i=0; iaddState(data)) { return false; } @@ -307,7 +307,7 @@ class EGS_RADIONUCLIDE_SOURCE_EXPORT EGS_RadionuclideSource : */ void resetCounter() { count = 0; - for(unsigned int i=0; iresetCounter(); } resetFluenceCounter(); @@ -341,7 +341,7 @@ class EGS_RADIONUCLIDE_SOURCE_EXPORT EGS_RadionuclideSource : if (!egsGetI64(data,count)) { return false; } - for(unsigned int i=0; isetState(data)) { return false; } @@ -357,20 +357,20 @@ class EGS_RADIONUCLIDE_SOURCE_EXPORT EGS_RadionuclideSource : EGS_BaseShape *shape; //!< The shape from which particles are emitted. EGS_BaseGeometry *geom; int *regions; - + EGS_I64 count; EGS_Float Emax; void setUp(); EGS_Float min_theta, max_theta; - EGS_Float buf_1, buf_2; //! avoid multi-calculating cos(min_theta) and - // cos(max_theta) + EGS_Float buf_1, buf_2; //! avoid multi-calculating cos(min_theta) and + // cos(max_theta) EGS_Float min_phi, max_phi; int nrs; GeometryConfinement gc; - - vector decays; //!< The radionuclide decay structure + + vector decays; //!< The radionuclide decay structure vector q_allowed; EGS_Float activity; double time; From f14cb17a8c20745d46512f0ee1a4f0b5544c3835 Mon Sep 17 00:00:00 2001 From: Reid Townson Date: Thu, 14 Jul 2016 10:49:06 -0400 Subject: [PATCH 05/34] Add radionuclide beta spectrum, update LNHB files Add beta spectrum calculations to the initialization of a radionuclide source. Only the required spectra are calculated, and tabulated using alias tables. These are now used for sampling the energies of radionuclide beta emissions. Caution: not all radionuclides have been tested. Also update the ENSDF files from LNHB, since there were some errors in the previous version. --- HEN_HOUSE/egs++/egs_ensdf.cpp | 369 +++++----- HEN_HOUSE/egs++/egs_ensdf.h | 14 + HEN_HOUSE/egs++/egs_spectra.cpp | 346 +++++++++- HEN_HOUSE/spectra/lnhb/Ac-225.txt | 406 +++++------ HEN_HOUSE/spectra/lnhb/Ac-227.txt | 338 ++++----- HEN_HOUSE/spectra/lnhb/Ac-228.txt | 854 +++++++++++------------ HEN_HOUSE/spectra/lnhb/Ag-108.txt | 78 +-- HEN_HOUSE/spectra/lnhb/Ag-108m.txt | 72 +- HEN_HOUSE/spectra/lnhb/Ag-110.txt | 98 +-- HEN_HOUSE/spectra/lnhb/Ag-110m.txt | 233 ++++--- HEN_HOUSE/spectra/lnhb/Al-26.txt | 34 +- HEN_HOUSE/spectra/lnhb/Am-241.txt | 568 +++++++-------- HEN_HOUSE/spectra/lnhb/Am-242.txt | 86 +-- HEN_HOUSE/spectra/lnhb/Am-242m.txt | 316 ++++----- HEN_HOUSE/spectra/lnhb/Am-243.txt | 84 +-- HEN_HOUSE/spectra/lnhb/Am-244.txt | 66 +- HEN_HOUSE/spectra/lnhb/Am-244m.txt | 60 +- HEN_HOUSE/spectra/lnhb/Ar-37.txt | 22 +- HEN_HOUSE/spectra/lnhb/Ar-41.txt | 16 +- HEN_HOUSE/spectra/lnhb/At-211.txt | 112 +-- HEN_HOUSE/spectra/lnhb/At-215.txt | 44 +- HEN_HOUSE/spectra/lnhb/At-217.txt | 44 +- HEN_HOUSE/spectra/lnhb/At-218.txt | 2 +- HEN_HOUSE/spectra/lnhb/At-219.txt | 46 +- HEN_HOUSE/spectra/lnhb/Au-195.txt | 68 +- HEN_HOUSE/spectra/lnhb/Au-198.txt | 58 +- HEN_HOUSE/spectra/lnhb/Ba-133.txt | 89 +-- HEN_HOUSE/spectra/lnhb/Ba-137m.txt | 32 +- HEN_HOUSE/spectra/lnhb/Ba-140.txt | 69 +- HEN_HOUSE/spectra/lnhb/Be-7.txt | 15 +- HEN_HOUSE/spectra/lnhb/Bi-207.txt | 70 +- HEN_HOUSE/spectra/lnhb/Bi-210.txt | 72 +- HEN_HOUSE/spectra/lnhb/Bi-211.txt | 68 +- HEN_HOUSE/spectra/lnhb/Bi-212.txt | 178 ++--- HEN_HOUSE/spectra/lnhb/Bi-213.txt | 122 ++-- HEN_HOUSE/spectra/lnhb/Bi-214.txt | 574 +++++++-------- HEN_HOUSE/spectra/lnhb/Bi-215.txt | 114 +-- HEN_HOUSE/spectra/lnhb/C-11.txt | 2 +- HEN_HOUSE/spectra/lnhb/Ca-41.txt | 28 +- HEN_HOUSE/spectra/lnhb/Ca-45.txt | 8 +- HEN_HOUSE/spectra/lnhb/Cd-109.txt | 46 +- HEN_HOUSE/spectra/lnhb/Ce-139.txt | 51 +- HEN_HOUSE/spectra/lnhb/Ce-141.txt | 46 +- HEN_HOUSE/spectra/lnhb/Ce-144.txt | 72 +- HEN_HOUSE/spectra/lnhb/Cf-252.txt | 52 +- HEN_HOUSE/spectra/lnhb/Cl-36.txt | 44 +- HEN_HOUSE/spectra/lnhb/Cm-242.txt | 128 ++-- HEN_HOUSE/spectra/lnhb/Cm-243.txt | 160 ++--- HEN_HOUSE/spectra/lnhb/Cm-244.txt | 100 +-- HEN_HOUSE/spectra/lnhb/Cm-245.txt | 102 +-- HEN_HOUSE/spectra/lnhb/Cm-246.txt | 42 +- HEN_HOUSE/spectra/lnhb/Co-56.txt | 139 ++-- HEN_HOUSE/spectra/lnhb/Co-57.txt | 75 +- HEN_HOUSE/spectra/lnhb/Co-58.txt | 48 +- HEN_HOUSE/spectra/lnhb/Co-60.txt | 52 +- HEN_HOUSE/spectra/lnhb/Cr-51.txt | 34 +- HEN_HOUSE/spectra/lnhb/Cs-134.txt | 116 ++-- HEN_HOUSE/spectra/lnhb/Cs-137.txt | 42 +- HEN_HOUSE/spectra/lnhb/Cu-61.txt | 130 ++-- HEN_HOUSE/spectra/lnhb/Cu-64.txt | 42 +- HEN_HOUSE/spectra/lnhb/Er-169.txt | 28 +- HEN_HOUSE/spectra/lnhb/Eu-152.txt | 512 +++++++------- HEN_HOUSE/spectra/lnhb/Eu-154.txt | 568 +++++++-------- HEN_HOUSE/spectra/lnhb/Eu-155.txt | 88 +-- HEN_HOUSE/spectra/lnhb/F-18.txt | 16 +- HEN_HOUSE/spectra/lnhb/Fe-52.txt | 46 +- HEN_HOUSE/spectra/lnhb/Fe-55.txt | 39 +- HEN_HOUSE/spectra/lnhb/Fe-59.txt | 54 +- HEN_HOUSE/spectra/lnhb/Fr-221.txt | 104 +-- HEN_HOUSE/spectra/lnhb/Fr-223.txt | 394 +++++------ HEN_HOUSE/spectra/lnhb/Ga-66.txt | 290 ++++---- HEN_HOUSE/spectra/lnhb/Ga-67.txt | 80 +-- HEN_HOUSE/spectra/lnhb/Ga-68.txt | 100 +-- HEN_HOUSE/spectra/lnhb/Gd-153.txt | 93 ++- HEN_HOUSE/spectra/lnhb/Gd-159.txt | 116 ++-- HEN_HOUSE/spectra/lnhb/Ge-68.txt | 40 +- HEN_HOUSE/spectra/lnhb/Hg-203.txt | 48 +- HEN_HOUSE/spectra/lnhb/Hg-206.txt | 66 +- HEN_HOUSE/spectra/lnhb/Ho-166.txt | 92 +-- HEN_HOUSE/spectra/lnhb/Ho-166m.txt | 210 +++--- HEN_HOUSE/spectra/lnhb/I-123.txt | 182 ++--- HEN_HOUSE/spectra/lnhb/I-125.txt | 48 +- HEN_HOUSE/spectra/lnhb/I-129.txt | 38 +- HEN_HOUSE/spectra/lnhb/I-131.txt | 126 ++-- HEN_HOUSE/spectra/lnhb/I-133.txt | 160 ++--- HEN_HOUSE/spectra/lnhb/In-111.txt | 56 +- HEN_HOUSE/spectra/lnhb/Ir-192.txt | 178 ++--- HEN_HOUSE/spectra/lnhb/Ir-194.txt | 254 +++---- HEN_HOUSE/spectra/lnhb/K-40.txt | 46 +- HEN_HOUSE/spectra/lnhb/Kr-85.txt | 34 +- HEN_HOUSE/spectra/lnhb/La-138.txt | 72 +- HEN_HOUSE/spectra/lnhb/La-140.txt | 216 +++--- HEN_HOUSE/spectra/lnhb/Lu-177.txt | 70 +- HEN_HOUSE/spectra/lnhb/Mn-54.txt | 32 +- HEN_HOUSE/spectra/lnhb/Mn-56.txt | 62 +- HEN_HOUSE/spectra/lnhb/Mo-99.txt | 142 ++-- HEN_HOUSE/spectra/lnhb/N-13.txt | 2 +- HEN_HOUSE/spectra/lnhb/Na-22.txt | 22 +- HEN_HOUSE/spectra/lnhb/Na-24.txt | 50 +- HEN_HOUSE/spectra/lnhb/Nb-93m.txt | 42 +- HEN_HOUSE/spectra/lnhb/Nb-95.txt | 46 +- HEN_HOUSE/spectra/lnhb/Nb-95m.txt | 67 +- HEN_HOUSE/spectra/lnhb/Nd-147.txt | 146 ++-- HEN_HOUSE/spectra/lnhb/Ni-57.txt | 114 +-- HEN_HOUSE/spectra/lnhb/Ni-59.txt | 36 +- HEN_HOUSE/spectra/lnhb/Ni-63.txt | 16 +- HEN_HOUSE/spectra/lnhb/Np-236.txt | 150 ++-- HEN_HOUSE/spectra/lnhb/Np-236m.txt | 60 +- HEN_HOUSE/spectra/lnhb/Np-237.txt | 222 +++--- HEN_HOUSE/spectra/lnhb/Np-238.txt | 196 +++--- HEN_HOUSE/spectra/lnhb/Np-239.txt | 188 ++--- HEN_HOUSE/spectra/lnhb/O-15.txt | 4 +- HEN_HOUSE/spectra/lnhb/P-33.txt | 2 +- HEN_HOUSE/spectra/lnhb/Pa-231.txt | 258 +++---- HEN_HOUSE/spectra/lnhb/Pa-233.txt | 144 ++-- HEN_HOUSE/spectra/lnhb/Pa-234.txt | 1038 ++++++++++++++-------------- HEN_HOUSE/spectra/lnhb/Pa-234m.txt | 414 +++++------ HEN_HOUSE/spectra/lnhb/Pb-203.txt | 58 +- HEN_HOUSE/spectra/lnhb/Pb-209.txt | 22 +- HEN_HOUSE/spectra/lnhb/Pb-210.txt | 48 +- HEN_HOUSE/spectra/lnhb/Pb-211.txt | 112 +-- HEN_HOUSE/spectra/lnhb/Pb-212.txt | 64 +- HEN_HOUSE/spectra/lnhb/Pb-214.txt | 90 +-- HEN_HOUSE/spectra/lnhb/Pd-109.txt | 182 ++--- HEN_HOUSE/spectra/lnhb/Pm-147.txt | 50 +- HEN_HOUSE/spectra/lnhb/Pm-148.txt | 132 ++-- HEN_HOUSE/spectra/lnhb/Pm-148m.txt | 172 ++--- HEN_HOUSE/spectra/lnhb/Po-209.txt | 96 +-- HEN_HOUSE/spectra/lnhb/Po-210.txt | 44 +- HEN_HOUSE/spectra/lnhb/Po-211.txt | 52 +- HEN_HOUSE/spectra/lnhb/Po-212.txt | 4 +- HEN_HOUSE/spectra/lnhb/Po-213.txt | 8 +- HEN_HOUSE/spectra/lnhb/Po-214.txt | 40 +- HEN_HOUSE/spectra/lnhb/Po-215.txt | 68 +- HEN_HOUSE/spectra/lnhb/Po-216.txt | 44 +- HEN_HOUSE/spectra/lnhb/Po-218.txt | 34 +- HEN_HOUSE/spectra/lnhb/Pr-144.txt | 118 ++-- HEN_HOUSE/spectra/lnhb/Pr-144m.txt | 94 +-- HEN_HOUSE/spectra/lnhb/Pu-238.txt | 141 ++-- HEN_HOUSE/spectra/lnhb/Pu-239.txt | 689 +++++++++--------- HEN_HOUSE/spectra/lnhb/Pu-240.txt | 100 +-- HEN_HOUSE/spectra/lnhb/Pu-241.txt | 110 +-- HEN_HOUSE/spectra/lnhb/Pu-242.txt | 50 +- HEN_HOUSE/spectra/lnhb/Ra-223.txt | 216 +++--- HEN_HOUSE/spectra/lnhb/Ra-224.txt | 60 +- HEN_HOUSE/spectra/lnhb/Ra-225.txt | 20 +- HEN_HOUSE/spectra/lnhb/Ra-226.txt | 50 +- HEN_HOUSE/spectra/lnhb/Ra-228.txt | 38 +- HEN_HOUSE/spectra/lnhb/Rb-82.txt | 193 +++--- HEN_HOUSE/spectra/lnhb/Re-186.txt | 128 ++-- HEN_HOUSE/spectra/lnhb/Re-188.txt | 164 +++-- HEN_HOUSE/spectra/lnhb/Rh-106.txt | 258 +++---- HEN_HOUSE/spectra/lnhb/Rn-217.txt | 4 +- HEN_HOUSE/spectra/lnhb/Rn-218.txt | 36 +- HEN_HOUSE/spectra/lnhb/Rn-219.txt | 98 +-- HEN_HOUSE/spectra/lnhb/Rn-220.txt | 44 +- HEN_HOUSE/spectra/lnhb/Rn-222.txt | 36 +- HEN_HOUSE/spectra/lnhb/Ru-106.txt | 20 +- HEN_HOUSE/spectra/lnhb/S-35.txt | 4 +- HEN_HOUSE/spectra/lnhb/Sb-124.txt | 236 +++---- HEN_HOUSE/spectra/lnhb/Sb-125.txt | 138 ++-- HEN_HOUSE/spectra/lnhb/Sb-127.txt | 198 +++--- HEN_HOUSE/spectra/lnhb/Sc-44.txt | 46 +- HEN_HOUSE/spectra/lnhb/Sc-46.txt | 34 +- HEN_HOUSE/spectra/lnhb/Sc-47.txt | 26 +- HEN_HOUSE/spectra/lnhb/Se-73.txt | 252 +++---- HEN_HOUSE/spectra/lnhb/Se-75.txt | 134 ++-- HEN_HOUSE/spectra/lnhb/Se-79.txt | 14 +- HEN_HOUSE/spectra/lnhb/Sm-151.txt | 44 +- HEN_HOUSE/spectra/lnhb/Sm-153.txt | 212 +++--- HEN_HOUSE/spectra/lnhb/Sn-113.txt | 64 +- HEN_HOUSE/spectra/lnhb/Sr-82.txt | 40 +- HEN_HOUSE/spectra/lnhb/Sr-85.txt | 78 +-- HEN_HOUSE/spectra/lnhb/Sr-89.txt | 24 +- HEN_HOUSE/spectra/lnhb/Sr-90.txt | 22 +- HEN_HOUSE/spectra/lnhb/Ta-182.txt | 198 +++--- HEN_HOUSE/spectra/lnhb/Tc-94m.txt | 228 +++--- HEN_HOUSE/spectra/lnhb/Tc-99.txt | 44 +- HEN_HOUSE/spectra/lnhb/Tc-99m.txt | 82 +-- HEN_HOUSE/spectra/lnhb/Te-123m.txt | 48 +- HEN_HOUSE/spectra/lnhb/Te-127.txt | 86 +-- HEN_HOUSE/spectra/lnhb/Te-127m.txt | 114 +-- HEN_HOUSE/spectra/lnhb/Te-132.txt | 52 +- HEN_HOUSE/spectra/lnhb/Th-228.txt | 92 +-- HEN_HOUSE/spectra/lnhb/Th-231.txt | 222 +++--- HEN_HOUSE/spectra/lnhb/Th-232.txt | 46 +- HEN_HOUSE/spectra/lnhb/Th-233.txt | 480 ++++++------- HEN_HOUSE/spectra/lnhb/Th-234.txt | 80 +-- HEN_HOUSE/spectra/lnhb/Ti-44.txt | 36 +- HEN_HOUSE/spectra/lnhb/Tl-201.txt | 88 ++- HEN_HOUSE/spectra/lnhb/Tl-204.txt | 62 +- HEN_HOUSE/spectra/lnhb/Tl-206.txt | 36 +- HEN_HOUSE/spectra/lnhb/Tl-207.txt | 56 +- HEN_HOUSE/spectra/lnhb/Tl-208.txt | 152 ++-- HEN_HOUSE/spectra/lnhb/Tl-209.txt | 122 ++-- HEN_HOUSE/spectra/lnhb/Tl-210.txt | 56 +- HEN_HOUSE/spectra/lnhb/Tm-170.txt | 86 +-- HEN_HOUSE/spectra/lnhb/U-232.txt | 96 +-- HEN_HOUSE/spectra/lnhb/U-234.txt | 67 +- HEN_HOUSE/spectra/lnhb/U-235.txt | 238 +++---- HEN_HOUSE/spectra/lnhb/U-236.txt | 48 +- HEN_HOUSE/spectra/lnhb/U-237.txt | 140 ++-- HEN_HOUSE/spectra/lnhb/U-238.txt | 44 +- HEN_HOUSE/spectra/lnhb/U-239.txt | 452 ++++++------ HEN_HOUSE/spectra/lnhb/Xe-127.txt | 72 +- HEN_HOUSE/spectra/lnhb/Xe-131m.txt | 44 +- HEN_HOUSE/spectra/lnhb/Xe-133.txt | 70 +- HEN_HOUSE/spectra/lnhb/Xe-133m.txt | 42 +- HEN_HOUSE/spectra/lnhb/Xe-135m.txt | 76 +- HEN_HOUSE/spectra/lnhb/Y-88.txt | 78 +-- HEN_HOUSE/spectra/lnhb/Y-90.txt | 31 +- HEN_HOUSE/spectra/lnhb/Y-90m.txt | 36 +- HEN_HOUSE/spectra/lnhb/Yb-169.txt | 225 +++--- HEN_HOUSE/spectra/lnhb/Zn-63.txt | 242 +++---- HEN_HOUSE/spectra/lnhb/Zn-65.txt | 46 +- HEN_HOUSE/spectra/lnhb/Zr-89.txt | 66 +- HEN_HOUSE/spectra/lnhb/Zr-93.txt | 46 +- HEN_HOUSE/spectra/lnhb/Zr-95.txt | 46 +- 218 files changed, 12902 insertions(+), 12635 deletions(-) diff --git a/HEN_HOUSE/egs++/egs_ensdf.cpp b/HEN_HOUSE/egs++/egs_ensdf.cpp index 769988687..d58bb6e61 100644 --- a/HEN_HOUSE/egs++/egs_ensdf.cpp +++ b/HEN_HOUSE/egs++/egs_ensdf.cpp @@ -43,6 +43,9 @@ EGS_Ensdf::EGS_Ensdf(const string isotope, const string ensdf_filename) { } radionuclide = isotope.substr(0, isotope.find_last_of(".")); + + // The parent element + //string element = radionuclide.substr(0, radionuclide.find("-")); printf("EGS_Ensdf::EGS_Ensdf: Isotope: " "%s\n",isotope.c_str()); @@ -65,13 +68,9 @@ EGS_Ensdf::EGS_Ensdf(const string isotope, const string ensdf_filename) { if (ensdf_file.is_open()) { ensdf_file.close(); } - - // Get the isotope - if (!createIsotope(ensdf)) { - egsWarning("EGS_Ensdf::EGS_Ensdf: error reading ensdf isotope data\n"); - return; - } - + + // Parse the ensdf data + parseEnsdf(ensdf); } EGS_Ensdf::~EGS_Ensdf() { @@ -149,166 +148,6 @@ string egsTrimString(string myString) { return myString.substr(start,end-start+1); } -bool EGS_Ensdf::createIsotope(vector ensdf) { - - // The daughter isotope name - string id = ensdf.front().substr(0,5); - string daughter = egsRemoveWhite(id); - - // The parent element - string element = radionuclide.substr(0, radionuclide.find("-")); - - // The atomic weight - A = findAtomicWeight(element); - if (A == 0) { - egsWarning("EGS_Ensdf::createIsotope: element does not exist in our " - "data (%s)\n", element.c_str()); - return false; - } - - // Parse the ensdf data - parseEnsdf(ensdf); - - return true; -} - -map EGS_Ensdf::getElementMap() { - map elementTable; - elementTable["H"] = 1; - elementTable["HE"] = 2; - elementTable["LI"] = 3; - elementTable["BE"] = 4; - elementTable["B"] = 5; - elementTable["C"] = 6; - elementTable["N"] = 7; - elementTable["O"] = 8; - elementTable["F"] = 9; - elementTable["NE"] = 10; - elementTable["NA"] = 11; - elementTable["MG"] = 12; - elementTable["AL"] = 13; - elementTable["SI"] = 14; - elementTable["P"] = 15; - elementTable["S"] = 16; - elementTable["CL"] = 17; - elementTable["AR"] = 18; - elementTable["K"] = 19; - elementTable["CA"] = 20; - elementTable["SC"] = 21; - elementTable["TI"] = 22; - elementTable["V"] = 23; - elementTable["CR"] = 24; - elementTable["MN"] = 25; - elementTable["FE"] = 26; - elementTable["CO"] = 27; - elementTable["NI"] = 28; - elementTable["CU"] = 29; - elementTable["ZN"] = 30; - elementTable["GA"] = 31; - elementTable["GE"] = 32; - elementTable["AS"] = 33; - elementTable["SE"] = 34; - elementTable["BR"] = 35; - elementTable["KR"] = 36; - elementTable["RB"] = 37; - elementTable["SR"] = 38; - elementTable["Y"] = 39; - elementTable["ZR"] = 40; - elementTable["NB"] = 41; - elementTable["MO"] = 42; - elementTable["TC"] = 43; - elementTable["RU"] = 44; - elementTable["RH"] = 45; - elementTable["PD"] = 46; - elementTable["AG"] = 47; - elementTable["CD"] = 48; - elementTable["IN"] = 49; - elementTable["SN"] = 50; - elementTable["SB"] = 51; - elementTable["TE"] = 52; - elementTable["I"] = 53; - elementTable["XE"] = 54; - elementTable["CS"] = 55; - elementTable["BA"] = 56; - elementTable["LA"] = 57; - elementTable["CE"] = 58; - elementTable["PR"] = 59; - elementTable["ND"] = 60; - elementTable["PM"] = 61; - elementTable["SM"] = 62; - elementTable["EU"] = 63; - elementTable["GD"] = 64; - elementTable["TB"] = 65; - elementTable["DY"] = 66; - elementTable["HO"] = 67; - elementTable["ER"] = 68; - elementTable["TM"] = 69; - elementTable["YB"] = 70; - elementTable["LU"] = 71; - elementTable["HF"] = 72; - elementTable["TA"] = 73; - elementTable["W"] = 74; - elementTable["RE"] = 75; - elementTable["OS"] = 76; - elementTable["IR"] = 77; - elementTable["PT"] = 78; - elementTable["AU"] = 79; - elementTable["HG"] = 80; - elementTable["TL"] = 81; - elementTable["PB"] = 82; - elementTable["BI"] = 83; - elementTable["PO"] = 84; - elementTable["AT"] = 85; - elementTable["RN"] = 86; - elementTable["FR"] = 87; - elementTable["RA"] = 88; - elementTable["AC"] = 89; - elementTable["TH"] = 90; - elementTable["PA"] = 91; - elementTable["U"] = 92; - elementTable["NP"] = 93; - elementTable["PU"] = 94; - elementTable["AM"] = 95; - elementTable["CM"] = 96; - elementTable["BK"] = 97; - elementTable["CF"] = 98; - elementTable["ES"] = 99; - elementTable["FM"] = 100; - elementTable["MD"] = 101; - elementTable["NO"] = 102; - elementTable["LR"] = 103; - elementTable["RF"] = 104; - elementTable["DB"] = 105; - elementTable["SG"] = 106; - elementTable["BH"] = 107; - elementTable["HS"] = 108; - elementTable["MT"] = 109; - elementTable["DS"] = 110; - elementTable["RG"] = 111; - elementTable["CN"] = 112; - elementTable["UUT"] = 113; - elementTable["UUQ"] = 114; - elementTable["UUP"] = 115; - elementTable["UUH"] = 116; - elementTable["UUS"] = 117; - elementTable["UUO"] = 118; - - return elementTable; -} - -unsigned short int EGS_Ensdf::findAtomicWeight(string element) { - transform(element.begin(), element.end(), element.begin(), ::toupper); - - map elementMap = getElementMap(); - - if (elementMap.find(element) != elementMap.end()) { - return elementMap[element]; - } - else { - return 0; - } -} - // Parse an ensdf file to create a decay structure void EGS_Ensdf::parseEnsdf(vector ensdf) { /* IDs of recordStack @@ -1064,6 +903,162 @@ double Record::parseHalfLife(int startPos, int endPos) { return hl; } +unsigned short int Record::setZ(string id) { + + string element; + for (unsigned int i=0; i < id.length(); ++i) { + if (!isdigit(id[i])) { + element.push_back(id[i]); + } + } + + unsigned short int Z = findZ(element); + if (Z == 0) { + egsWarning("EGS_Ensdf::createIsotope: element does not exist in our " + "data (%s)\n", element.c_str()); + } + + return Z; +} + +map Record::getElementMap() { + map elementTable; + elementTable["H"] = 1; + elementTable["HE"] = 2; + elementTable["LI"] = 3; + elementTable["BE"] = 4; + elementTable["B"] = 5; + elementTable["C"] = 6; + elementTable["N"] = 7; + elementTable["O"] = 8; + elementTable["F"] = 9; + elementTable["NE"] = 10; + elementTable["NA"] = 11; + elementTable["MG"] = 12; + elementTable["AL"] = 13; + elementTable["SI"] = 14; + elementTable["P"] = 15; + elementTable["S"] = 16; + elementTable["CL"] = 17; + elementTable["AR"] = 18; + elementTable["K"] = 19; + elementTable["CA"] = 20; + elementTable["SC"] = 21; + elementTable["TI"] = 22; + elementTable["V"] = 23; + elementTable["CR"] = 24; + elementTable["MN"] = 25; + elementTable["FE"] = 26; + elementTable["CO"] = 27; + elementTable["NI"] = 28; + elementTable["CU"] = 29; + elementTable["ZN"] = 30; + elementTable["GA"] = 31; + elementTable["GE"] = 32; + elementTable["AS"] = 33; + elementTable["SE"] = 34; + elementTable["BR"] = 35; + elementTable["KR"] = 36; + elementTable["RB"] = 37; + elementTable["SR"] = 38; + elementTable["Y"] = 39; + elementTable["ZR"] = 40; + elementTable["NB"] = 41; + elementTable["MO"] = 42; + elementTable["TC"] = 43; + elementTable["RU"] = 44; + elementTable["RH"] = 45; + elementTable["PD"] = 46; + elementTable["AG"] = 47; + elementTable["CD"] = 48; + elementTable["IN"] = 49; + elementTable["SN"] = 50; + elementTable["SB"] = 51; + elementTable["TE"] = 52; + elementTable["I"] = 53; + elementTable["XE"] = 54; + elementTable["CS"] = 55; + elementTable["BA"] = 56; + elementTable["LA"] = 57; + elementTable["CE"] = 58; + elementTable["PR"] = 59; + elementTable["ND"] = 60; + elementTable["PM"] = 61; + elementTable["SM"] = 62; + elementTable["EU"] = 63; + elementTable["GD"] = 64; + elementTable["TB"] = 65; + elementTable["DY"] = 66; + elementTable["HO"] = 67; + elementTable["ER"] = 68; + elementTable["TM"] = 69; + elementTable["YB"] = 70; + elementTable["LU"] = 71; + elementTable["HF"] = 72; + elementTable["TA"] = 73; + elementTable["W"] = 74; + elementTable["RE"] = 75; + elementTable["OS"] = 76; + elementTable["IR"] = 77; + elementTable["PT"] = 78; + elementTable["AU"] = 79; + elementTable["HG"] = 80; + elementTable["TL"] = 81; + elementTable["PB"] = 82; + elementTable["BI"] = 83; + elementTable["PO"] = 84; + elementTable["AT"] = 85; + elementTable["RN"] = 86; + elementTable["FR"] = 87; + elementTable["RA"] = 88; + elementTable["AC"] = 89; + elementTable["TH"] = 90; + elementTable["PA"] = 91; + elementTable["U"] = 92; + elementTable["NP"] = 93; + elementTable["PU"] = 94; + elementTable["AM"] = 95; + elementTable["CM"] = 96; + elementTable["BK"] = 97; + elementTable["CF"] = 98; + elementTable["ES"] = 99; + elementTable["FM"] = 100; + elementTable["MD"] = 101; + elementTable["NO"] = 102; + elementTable["LR"] = 103; + elementTable["RF"] = 104; + elementTable["DB"] = 105; + elementTable["SG"] = 106; + elementTable["BH"] = 107; + elementTable["HS"] = 108; + elementTable["MT"] = 109; + elementTable["DS"] = 110; + elementTable["RG"] = 111; + elementTable["CN"] = 112; + elementTable["UUT"] = 113; + elementTable["UUQ"] = 114; + elementTable["UUP"] = 115; + elementTable["UUH"] = 116; + elementTable["UUS"] = 117; + elementTable["UUO"] = 118; + + return elementTable; +} + +unsigned short int Record::findZ(string element) { + + transform(element.begin(), element.end(), element.begin(), ::toupper); + + map elementMap = getElementMap(); + + if (elementMap.find(element) != elementMap.end()) { + return elementMap[element]; + } + else { + return 0; + } +} + // Comment Record CommentRecord::CommentRecord(vector ensdf):Record(ensdf) { processEnsdf(); @@ -1191,7 +1186,27 @@ BetaRecordLeaf::BetaRecordLeaf(vector ensdf, NormalizationRecordLeaf(myNormalization), LevelRecordLeaf(myLevel), Record(ensdf) { + numSampled = 0; + + // Set the Z and atomic weight for the daughter of this decay + string id = egsRemoveWhite(lines.front().substr(0,5)); + Z = setZ(id); + + string atomicWeight; + for (unsigned int i=0; i < id.length(); ++i) { + if (!isdigit(id[i])) { + break; + } else { + atomicWeight.push_back(id[i]); + } + } + A = atoi(atomicWeight.c_str()); + + // Get the forbiddenness + string lambda; + lambda.push_back(lines.front().at(77)); + forbidden = atoi(lambda.c_str()); } int BetaRecordLeaf::getCharge() const { return q; @@ -1205,6 +1220,26 @@ EGS_I64 BetaRecordLeaf::getNumSampled() const { return numSampled; } +unsigned short int BetaRecordLeaf::getZ() const { + return Z; +} + +unsigned short int BetaRecordLeaf::getAtomicWeight() const { + return A; +} + +unsigned short int BetaRecordLeaf::getForbidden() const { + return forbidden; +} + +void BetaRecordLeaf::setSpectrum(EGS_AliasTable *bspec) { + spectrum = bspec; +} + +EGS_AliasTable* BetaRecordLeaf::getSpectrum() const { + return spectrum; +} + // Beta- Record BetaMinusRecord::BetaMinusRecord(vector ensdf, ParentRecord *myParent, NormalizationRecord *myNormalization, diff --git a/HEN_HOUSE/egs++/egs_ensdf.h b/HEN_HOUSE/egs++/egs_ensdf.h index 0a1a6981e..b6192077c 100644 --- a/HEN_HOUSE/egs++/egs_ensdf.h +++ b/HEN_HOUSE/egs++/egs_ensdf.h @@ -41,6 +41,7 @@ #include "egs_libconfig.h" #include "egs_functions.h" #include "egs_math.h" +#include "egs_alias_table.h" #include #include @@ -160,6 +161,9 @@ class Record { protected: double recordToDouble(int startPos, int endPos); double parseHalfLife(int startPos, int endPos); + unsigned short int setZ(string id); + map getElementMap(); + unsigned short int findZ(string element); // All the lines corresponding to this record type vector lines; @@ -255,12 +259,21 @@ class BetaRecordLeaf : public Record, public ParentRecordLeaf, public int getCharge() const; void incrNumSampled(); EGS_I64 getNumSampled() const; + unsigned short int getZ() const; + unsigned short int getAtomicWeight() const; + unsigned short int getForbidden() const; + void setSpectrum(EGS_AliasTable *bspec); + EGS_AliasTable* getSpectrum() const; protected: EGS_I64 numSampled; double finalEnergy; double betaIntensity; int q; + unsigned short int Z; + unsigned short int A; + unsigned short int forbidden; + EGS_AliasTable *spectrum; }; // Beta- record @@ -379,6 +392,7 @@ class EGS_EXPORT EGS_Ensdf { vector getXRayEnergies() const; vector getAugerIntensities() const; vector getAugerEnergies() const; + string radionuclide; void normalizeIntensities(); diff --git a/HEN_HOUSE/egs++/egs_spectra.cpp b/HEN_HOUSE/egs++/egs_spectra.cpp index 876453bf4..61bf71ae4 100644 --- a/HEN_HOUSE/egs++/egs_spectra.cpp +++ b/HEN_HOUSE/egs++/egs_spectra.cpp @@ -42,6 +42,9 @@ #include "egs_ensdf.h" #include "egs_application.h" +#include +#include + #include #include "egs_math.h" #include @@ -53,6 +56,7 @@ #define S_STREAM std::istrstream #endif +#include using namespace std; @@ -438,6 +442,332 @@ class EGS_EXPORT EGS_TabulatedSpectrum : public EGS_BaseSpectrum { }; + +/*! \brief Beta spectrum generation for radionuclide spectra + * + * \ingroup egspp_main + * + * + * L. VanderZwan + * March 7,1985. + * Oct. 14,1994 Converted to Microsoft Fortran v5.1 + * PRBS, August 2002. Convert to subroutine for sampling spectrum. + * PRBS, SEPT 2003. Make double precision. replace (ln)gamma calls with + * cernlib calls + * PRBS 7 Oct, 2014 - port to C++ ! +*/ +class EGS_EXPORT EGS_RadionuclideBetaSpectrum { + +public: + /*! \brief Construct beta spectra for a radionuclide + */ + EGS_RadionuclideBetaSpectrum(EGS_Ensdf *decays) { + + vector myBetas = decays->getBetaRecords(); + + for (vector::iterator beta = myBetas.begin(); + beta != myBetas.end(); beta++) { + + printf("EGS_RadionuclideBetaSpectrum: Energy, Z, A, forbidden: %f " + "%d %d %d\n", + (*beta)->getFinalEnergy(), (*beta)->getZ(), + (*beta)->getAtomicWeight(), (*beta)->getForbidden() + ); + + const int nbin=1000; + EGS_Float *e = new EGS_Float [nbin]; + EGS_Float *spec = new EGS_Float [nbin]; + EGS_Float *spec_y = new EGS_Float [nbin]; + EGS_Float *spec_sr = new EGS_Float [nbin]; + + double de, s_y, s_sr, factor, e1, e2, se_y, se_sr; + int isrc; + + ncomps=1; // if we increase this, then we must fill the remainder + area[0]=1.0; + rel[0]=1.0; + + emax = (*beta)->getFinalEnergy(); + zzz[0] = (double)(*beta)->getZ(); + rmass = (*beta)->getAtomicWeight(); + lamda[0] = (*beta)->getForbidden(); + + etop[0]=emax; + + // prbs july 9, 2007 moved here from before src loop. + // also, now tabulate based on + // endpoint, using roughly nbin bins across spectrum. Do this by + // rounding + // endpoint E0 up to nearest 100 keV, and dividing by NBIN to get + // binwidth. + + e1=0.001; // may be too low for some spectra (e.g. Tl-204) + de=((int)(etop[0]*10.0+1)/10.)/nbin; // round up to nearest 100kev; + // /= NBIN +// cout << "Binwidth " << de << endl; + + for (int ib=0; ibsetSpectrum(bspec); + } + } + +protected: + + // Complex gamma function approximation + complex cgamma(complex z) { + + static const int g=7; + static const double pi = 3.1415926535897932384626433832795028841972; + static const double p[g+2] = {0.99999999999980993, 676.5203681218851, + -1259.1392167224028, 771.32342877765313, -176.61502916214059, + 12.507343278686905, -0.13857109526572012, 9.9843695780195716e-6, + 1.5056327351493116e-7 + }; + + if (real(z)<0.5) { + return pi / (sin(pi*z)*cgamma(1.0-z)); + } + + z -= 1.0; + complex x=p[0]; + for (int i=1; i(i,0)); + } + complex t = z + (g + 0.5); + return sqrt(2*pi) * pow(t,z+0.5) * exp(-t) * x; + } + + void slfact(double p, double z, double radf, double xl[4]) { + + double ff[4]; + double dfac[4]= {1.0, 3.0, 15.0, 105.0}; + double pi,c137,az,g1,w,rad,pr,y,x1,gk,bb,cc,dd,x2; + + complex aa; + + pi=acos(-1.0); + c137=137.036; // 1/ fine structure constant + az=z/c137; + g1=sqrt(1.0-az*az); + w =sqrt(p*p+1.0); + rad=radf/386.159; + pr=p*rad; + y =az*w/p; + + for (int k=1; k<=4; k++) { + + gk=sqrt(k*k-az*az); + x1=pow((pow(p,k-1)/dfac[k-1]) ,2); + + // Fortran original was: + // aa=complex(gk,y) + // aa=clgama(aa) ! (using CERNLIB's log gamma function) + // ! for complex arguments + // Now use gnu scientific library's function: + // int gsl_sf_lngamma_complex_e (double zr, double zi, + // gsl_sf_result * lnr, gsl_sf_result * arg) + // returned pars are lnr = \log|\Gamma(z)| + // arg = \arg(\Gamma(z)) in (-\pi,\pi]. + // If we assume the Gamma function has complex form Rexp(i*phi) + // then log(Gamma) is just log(R) + i*phi. The former is purely real + // and the latter purely imaginary, hence the last two arguments + // return the real and the imaginary parts of ln(gamma(aa)), and it + // is only the former which is used below. + // Note that gsl_sf_result is a structure with elements val and err. + + gsl_sf_result gr_aa_real, gr_aa_imag; + gsl_sf_lngamma_complex_e(gk, y, &gr_aa_real, &gr_aa_imag); + double aa_real=gr_aa_real.val; + + // Now use cmath's lgamma function + bb=lgamma((double)k); + cc=lgamma(2.0*k +1.0); + dd=lgamma(2.0*gk+1.0); + + ff[k-1] = + pow(2.0*pr, 2.0*(gk-k)) * + exp(pi*y+2.0*(aa_real+cc-bb-dd)) * + (k+gk)/(2.0*k); + + x2 = + 1.0 - + az*pr*(2.0*w*(2.0*k+1.0)/(p*k*(2.0*gk+1.0)) - + 2.0*p*gk/(w*k*(2.0*gk+1.0))) - + 2.0*k*pr*pr/((2.0*k+1.0)*(k+gk)); + xl[k-1] = x1*ff[k-1]/ff[0]*x2; + } + + return; + } + + void bsp(double e, double &bspec, double &factor) { + + // ***************************************************************** + // Calculates n(e) (unnormalized) for one spectral component, + // specified by:zz,emax,lamda, where + // + // lamda = 1 first forbidden + // lamda = 2 second forbidden + // lamda = 3 third forbidden + // lamda = 0 otherwise + // lamda = 4 for a few nuclides whose experimental shape don't + // fit theory. fudge factors are applied to the allowed + // shape. + // zz charge of the daughter nucleus + // emax maximum beta energy in mev. + // w and tsq in mc**2 units + // e and emax in mev units. + // v is the screening correction for atomi// electrons + // for the thomas-fermi model of the atom + // v = 1.13 * (alpha)**2 * z**(4/3) + // + // + + double pi,c137,zab,v,z,x,w,psq,p,y,qsq,g,cab,f,radf; + + double xl[4]; + complex c,a; + + bspec=0.0; + if (e>emax) { + return; + } + + pi=acos(-1.); + c137=137.036; // 1/ fine structure constant + + zab=abs(zz); + v=1.13*pow(zab,1.333)/pow(c137,2); // Screening correction + v=copysign(v,zz); + z=zab/c137; + x=sqrt(1.0-z*z); // s parameter + w=1.0+(e/0.51097)-v; // Total energy of b particle + if (w<1.00001) { + w=1.00001; + } + psq= w*w-1.0; + p =sqrt(psq); // Momemtum of beta particle + y = z*w/p; // eta = alpha * z * e / p + y =copysign(y,zz); + qsq=3.83*pow(emax-e,2); + + if (e <= 1.0e-5) { + g=0.0; // Low energy approximation + if (zz>=0.0) { + g = qsq*2.0*pi*pow(z,(2.0*x-1.0)); + } + } + else { + a=complex(x,y); + c=cgamma(a); + cab=abs(c); + f=pow(psq,x-1.0)*exp(pi*y)*pow(cab,2); + g=f*p*w*qsq; + } + + factor=1.0; // Necessary to calculate kurie plot (not done) + bspec=g; + if (lam == 0) { + return; + } + + radf=1.2*pow(rmass,0.333); // Nuclear radius + slfact(p,zz,radf,xl); + + if (lam==1) { + bspec=g*(qsq*xl[0]+9.0*xl[1]); + return; + } + else if (lam==2) { + bspec=g*(pow(qsq,2)*xl[0]+30.0*qsq*xl[1]+225.0*xl[2]); + return; + } + else if (lam==3) { + bspec=g*(pow(qsq,3.0)*xl[0]+63.0*pow(qsq,2)*xl[1]+ + 1575.0*qsq*xl[2] + 11025.0*xl[3]); + return; + } + else { // lam==4 + + // Fudge factors for nuclides whose experimental spectra don't + // seem to fit theory. + + // for cl36 (ref: nuc. phys. 99a, 625,(67)) + if (zab == 18.0) { + bspec=bspec*(qsq*xl[0]+20.07*xl[1]); + } + + // for i129 (ref: phys. rev. 95, 458, 54)) + if (zab == 54.) { + bspec=bspec*(psq+10.0*qsq); + } + + // for cs-ba137 (ref: nuc. phys. 112a, 156, (68)) + if (zab == 56.) { + bspec=bspec*(qsq*xl[0]+0.045*xl[1]); + } + + // for tl204 (ref: can. j. phys., 45, 2621, (67)) + if (zab == 82.) { + bspec=bspec*(1.0-1.677*e+ 2.77*e*e); + } + + // for bi210 (ref: nuc. phys., 31, 293, (62)) + if (zab == 84.) { + bspec=bspec*(1.78-2.35*e+e*e); + } + + return; + } + } + + // Sums weighted, normalized spectral components to give total spectrum + void sp(double e, double &spec, double &factor) { + + double bspec; + + spec=0.0; + for (int icomp=0; icompnormalizeIntensities(); + // Get the beta energy spectra + betaSpectra = new EGS_RadionuclideBetaSpectrum(decays); + // Get the particle records from the decay scheme myBetas = decays->getBetaRecords(); myAlphas = decays->getAlphaRecords(); @@ -551,7 +884,7 @@ class EGS_EXPORT EGS_RadionuclideSpectrum : public EGS_BaseSpectrum { void setSpectrumWeight(EGS_Float newWeight) { spectrumWeight = newWeight; } - + void printSampledEmissions() { printf("\nSampled %s emissions:\n", decays->radionuclide.c_str()); printf("========================\n"); @@ -631,9 +964,8 @@ class EGS_EXPORT EGS_RadionuclideSpectrum : public EGS_BaseSpectrum { currentLevel = (*gamma)->getFinalLevel(); - - E = (*gamma)->getDecayEnergy(); + return E; } } @@ -654,17 +986,17 @@ class EGS_EXPORT EGS_RadionuclideSpectrum : public EGS_BaseSpectrum { (*beta)->incrNumSampled(); currentQ = (*beta)->getCharge(); - //printf("EGS_RadionuclideSpectrum: q: %d\n",currentQ); // Set the energy level of the daughter currentLevel = (*beta)->getLevelRecord(); - // TODO: Generate beta- spectrum // TODO: Need to implement electron capture // For now just uniform up to max! - E = u * (*beta)->getFinalEnergy(); + //E = u * (*beta)->getFinalEnergy(); + E = (*beta)->getSpectrum()->sample(rndm); //printf("\nEGS_RadionuclideSpectrum: E: %f\n",E); + return E; } } @@ -745,6 +1077,8 @@ class EGS_EXPORT EGS_RadionuclideSpectrum : public EGS_BaseSpectrum { Tmax, spectrumWeight; EGS_I64 ishower; + + EGS_RadionuclideBetaSpectrum *betaSpectra; }; // diff --git a/HEN_HOUSE/spectra/lnhb/Ac-225.txt b/HEN_HOUSE/spectra/lnhb/Ac-225.txt index c440e68f3..c067cd0e0 100644 --- a/HEN_HOUSE/spectra/lnhb/Ac-225.txt +++ b/HEN_HOUSE/spectra/lnhb/Ac-225.txt @@ -1,358 +1,358 @@ 221FR 225AC A DECAY (10.0 D) 221FR H TYP=Full$AUT=Huang Xiaolong$CUT=31-DEC-2008$ 221FR C Evaluation history: Type=Full;Author=Huang Xiaolong;Cutoff date=31-DEC-2008 -221FR T Auger electrons and ^X ray energies and emission intensities: -221FR T {U Energy (keV)} {U Intensity } {U Line } +221FR T Auger electrons and X ray energies and emission intensities: +221FR T {U Energy (keV)} {U Intensity} {U Line} 221FR T -221FR T 83.23 1.00 8 XKA2 -221FR T 86.1 1.64 12 XKA1 +221FR T 83.23 1.00 8 XKA2 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9 -221FR G 153.92 3 0.205 13E1 0.1660 23 -221FR2 G KC=0.1315 19$LC=0.0262 4$MC=0.00627 9 -221FR G 216.89 3 0.32 2 (E1) 0.0726 10 -221FR2 G KC=0.0582 9$LC=0.01096 16$MC=0.00261 4 +221FR2 G KC=0.1341 19$LC=0.0268 4$MC=0.00640 9 +221FR G 153.920 300.205 13E1 0.1660 23 +221FR2 G KC=0.1315 19$LC=0.0262 4$MC=0.00627 9 +221FR G 216.89 3 0.32 2(E1) 0.0726 10 +221FR2 G KC=0.0582 9$LC=0.01096 16$MC=0.00261 4 221FR G 228.2 4 0.0046 12 -221FR G 253.46 3 0.132 8 [E1] 0.0504 7 -221FR2 G KC=0.0405 6$LC=0.00747 11$MC=1776E-6 25 +221FR G 253.46 3 0.132 8[E1] 0.0504 7 +221FR2 G KC=0.0405 6$LC=0.00747 11$MC=1776E-6 25 221FR L 271.14 7 (5/2,7/2,9/2)- 221FR A 5563.3 140.017 7 1160 -221FR G 121.06 7 0.017 5 (E1) 0.298 4 -221FR2 G KC=0.233 4$LC=0.0490 7$MC=0.01176 17 -221FR G 236.0 6 0.0017 3 +221FR G 121.06 7 0.017 5(E1) 0.298 4 +221FR2 G KC=0.233 4$LC=0.0490 7$MC=0.01176 17 +221FR G 236.0 6 0.0017 3 221FR L 279.209 17(7/2)+ 221FR A 5555.3 140.084 10213 -221FR G 129.22 7 0.0027 5 [M1E2] 5 2 -221FR2 G KC=3 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KC=1.6 14$LC=0.64 10$MC=0.16 4 221FR L 320.03 8 (1/2,3/2,5/2)+ 221FR A 5515.2 140.0052 192100 221FR G 220.43 8 0.0060 18 221FR L 338.24 8 (1/2,3/2,5/2)- 221FR A 5497.4 140.0022 7 4000 -221FR G 238.64 8 0.0010 3 (M1) 1.225 17 -221FR2 G KC=0.988 14$LC=0.180 3$MC=0.0428 6 +221FR G 238.64 8 0.0010 3(M1) 1.225 17 +221FR2 G KC=0.988 14$LC=0.180 3$MC=0.0428 6 221FR L 348.35 4 (3/2,5/2,7/2)+ 221FR A 5487.4 140.0020 3 3860 -221FR G 348.33 5 0.0030 3 +221FR G 348.33 5 0.0030 3 221FR L 367.74 12 + 221FR A 5468.4 140.00052 1811700 221FR G 367.74 120.00052 18 221FR L 393.300 18(5/2,7/2,9/2)+ 221FR A 5443.3 140.098 1945 221FR G 114 0.00087 13M1 9.86 14 -221FR2 G KC=7.93 12$LC=1.466 21$MC=0.350 5 +221FR2 G KC=7.93 12$LC=1.466 21$MC=0.350 5 221FR G 139.6 0.00139 21M1+E2 3.9 17 -221FR2 G KC=2.4 21$LC=1.1 3$MC=0.29 9 -221FR G 169.18 4 0.012 5 [M1E2] 2.1 11 -221FR2 G KC=1.4 12$LC=0.53 6$MC=0.136 24 -221FR G 197.50 3 0.026 3 E1 0.0908 13 -221FR2 G KC=0.0726 11$LC=0.01386 20$MC=0.00331 5 -221FR G 243.12 5 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5356.2 1497000E-92 14960 -221FR G 443.43 101000E-7 0 +221FR G 443.43 100.0001 221FR L 496.50 7 (5/2,7/2)+ 221FR A 5341.9 140.0027 8 450 221FR G 388.07 7 0.00125 21 -221FR G 496.9 3 0.0015 7 +221FR G 496.9 3 0.0015 7 221FR L 517.634 25(5/2)+ 221FR A 5321.2 140.007 7 130 221FR G 321.77 4 -221FR G 417.90 2 0.0056 5 +221FR G 417.90 2 0.0056 5 221FR G 480.85 110.0340 22 221FR G 491.45 100.00035 14 221FR G 517.51 3 0.0159 10 221FR L 551.812 17(3/2,5/2)- 221FR A 5287.6 140.214 102.76 221FR G 298.33 5 -221FR G 317.23 18 E1 0.0302 4 -221FR2 G KC=0.0244 4$LC=0.00437 7$MC=1037E-6 15 +221FR G 317.23 18 E1 0.0302 4 +221FR2 G KC=0.0244 4$LC=0.00437 7$MC=1037E-6 15 221FR G 356.6 0.00026 11 -221FR G 405.95 3 0.0078 5 [E1] 0.0175925 -221FR2 G KC=0.01432 20$LC=0.00249 4$MC=5.89E-4 9 -221FR G 443.43 100.0014 5 [E2] 0.0494 7 -221FR2 G KC=0.0310 5$LC=0.0137 2$MC=0.00353 5 -221FR G 451.04 5 0.0030 5 [M1] 0.215 3 -221FR2 G KC=0.1739 25$LC=0.0312 5$MC=0.00742 11 -221FR G 452.23 3 0.107 8 [M1] 0.213 3 -221FR2 G KC=0.1727 25$LC=0.0310 5$MC=0.00737 11 +221FR G 405.95 3 0.0078 5[E1] 0.0175925 +221FR2 G KC=0.01432 20$LC=0.00249 4$MC=5.89E-4 9 +221FR G 443.43 100.0014 5[E2] 0.0494 7 +221FR2 G KC=0.0310 5$LC=0.0137 2$MC=0.00353 5 +221FR G 451.04 5 0.0030 5[M1] 0.215 3 +221FR2 G KC=0.1739 25$LC=0.0312 5$MC=0.00742 11 +221FR G 452.23 3 0.107 8[M1] 0.213 3 +221FR2 G KC=0.1727 25$LC=0.0310 5$MC=0.00737 11 221FR G 512.5 7 0.00055 21 221FR G 515.13 3 0.0214 13[M1] 0.1506 21 -221FR2 G KC=0.1219 17$LC=0.0218 3$MC=0.00518 8 +221FR2 G KC=0.1219 17$LC=0.0218 3$MC=0.00518 8 221FR G 525.94 170.0353 22[M1] 0.1425 20 -221FR2 G KC=0.1154 17$LC=0.0206 3$MC=0.00490 7 +221FR2 G KC=0.1154 17$LC=0.0206 3$MC=0.00490 7 221FR G 551.79 3 0.0052 14[M1] 0.1254 17 -221FR2 G KC=0.1016 15$LC=0.0181 3$MC=0.00431 6 +221FR2 G KC=0.1016 15$LC=0.0181 3$MC=0.00431 6 221FR L 570.67 3 (5/2,7/2)+ 221FR A 5269.1 140.048 1910 -221FR G 53.4 4 4000E-6 0 [M1] 17.6 5 -221FR2 G KC=$LC=13.3 4$MC=3.18 8 -221FR G 317.23 180.00042 21M1 0.558 8 -221FR2 G KC=0.451 7$LC=0.0816 12$MC=0.0194 3 -221FR G 374.98 5 0.0019 5 [E1] 0.0209 3 -221FR2 G KC=0.01694 24$LC=0.00297 5$MC=7.04E-4 10 +221FR G 53.4 4 0.004 [M1] 17.6 5 +221FR2 G LC=13.3 4$MC=3.18 8 +221FR G 317.23 180.00042 21M1 0.558 8 +221FR2 G KC=0.451 7$LC=0.0816 12$MC=0.0194 3 +221FR G 374.98 5 0.0019 5[E1] 0.0209 3 +221FR2 G KC=0.01694 24$LC=0.00297 5$MC=7.04E-4 10 221FR G 462.43 130.00044 11[E1] 0.0133819 -221FR2 G KC=0.01092 16$LC=0.00187 3$MC=4.42E-4 7 -221FR G 469.48 5 0.0028 4 +221FR2 G KC=0.01092 16$LC=0.00187 3$MC=4.42E-4 7 +221FR G 469.48 5 0.0028 4 221FR G 532.11 9 0.00076 21[E1] 0.0100514 -221FR2 G KC=0.00823 12$LC=1389E-6 20$MC=3.27E-4 5 -221FR G 570.69 3 0.0040 5 [E1] 0.0087412 -221FR2 G KC=0.00716 10$LC=1201E-6 17$MC=2.83E-4 4 +221FR2 G KC=0.00823 12$LC=1389E-6 20$MC=3.27E-4 5 +221FR G 570.69 3 0.0040 5[E1] 0.0087412 +221FR2 G KC=0.00716 10$LC=1201E-6 17$MC=2.83E-4 4 221FR L 600.94 3 (5/2)- 221FR A 5239.3 140.0026 5 119 -221FR G 564.34 110.00022 9 -221FR G 600.92 3 0.0024 5 +221FR G 564.34 110.00022 9 +221FR G 600.92 3 0.0024 5 221FR L 630.551 23(5/2)- 221FR A 5210.2 140.022 1 9.5 -221FR G 282.1 2 0.00055 5 [M1] 0.771 11 -221FR2 G KC=0.622 9$LC=0.1129 16$MC=0.0269 4 -221FR G 434.82 5 0.0029 3 +221FR G 282.10 200.00055 5[M1] 0.771 11 +221FR2 G KC=0.622 9$LC=0.1129 16$MC=0.0269 4 +221FR G 434.82 5 0.0029 3 221FR G 522.14 4 0.00208 15 -221FR G 529.59 3 0.0076 7 -221FR G 530.87 4 0.0047 5 +221FR G 529.59 3 0.0076 7 +221FR G 530.87 4 0.0047 5 221FR G 590.42 5 0.00083 14 -221FR G 593.87 4 0.0029 3 +221FR G 593.87 4 0.0029 3 221FR L 637.60 3 + 221FR A 5203.3 140.0101 1018.9 221FR G 403.13 100.00019 16 221FR G 538.1 1 0.0038 10 -221FR G 600.92 3 6000E-6 0 -221FR G 637.1 7 1200E-7 0 +221FR G 600.92 3 0.006 +221FR G 637.1 7 0.00012 221FR L 645.94 12 + 221FR A 5195.1 140.00015 5 1140 -221FR G 645.94 120.00015 5 +221FR G 645.94 120.00015 5 221FR L 679.53 7 (7/2)- 221FR A 5162.1 140.00066 12165 221FR G 679.36 6 0.00066 12 221FR L 713.24 6 (1/2,3/2)+ 221FR A 5129.0 140.0058 8 11.9 -221FR G 442.16 8 0.0045 7 -221FR G 567.48 5 0.0012 4 +221FR G 442.16 8 0.0045 7 +221FR G 567.48 5 0.0012 4 221FR L 748.83 3 (3/2)+ 221FR A 5094.1 140.015 7 2.8 -221FR G 231.16 7 0.005 3 (M1) 1.338 19 -221FR2 G KC=1.079 16$LC=0.197 3$MC=0.0468 7 +221FR G 231.16 7 0.005 3(M1) 1.338 19 +221FR2 G KC=1.079 16$LC=0.197 3$MC=0.0468 7 221FR G 603.09 4 0.00173 21 -221FR G 649.03 4 0.0017 5 +221FR G 649.03 4 0.0017 5 221FR L 766.44 5 + 221FR A 5076.8 140.0038 199 -221FR G 657.88 5 0.0014 3 +221FR G 657.88 5 0.0014 3 221FR G 667.14 8 0.0021 18 -221FR G 767.9 3 0.00030 6 +221FR G 767.9 3 0.00030 6 221FR L 779.32 6 + 221FR A 5064.1 140.00114 1824 221FR G 545.8 6 0.00053 14 -221FR G 628.95 100.00032 7 +221FR G 628.95 100.00032 7 221FR G 679.36 6 -221FR G 754.04 130.00023 7 -221FR G 780.6 6 5.5E-5 14 +221FR G 754.04 130.00023 7 +221FR G 780.6 6 0.00005514 221FR L 808.48 10 + 221FR A 5035.5 140.0021 3 8.8 -221FR G 808.48 100.0021 3 +221FR G 808.48 100.0021 3 221FR L 818.6 6 + 221FR A 5025.5 140.00083 2119 221FR G 498.6 6 0.00083 21 221FR L 825.0 3 + 221FR A 5019.3 140.00015 5 98 -221FR G 674.9 3 0.00010 5 -221FR G 824.2 7 4900E-8 0 +221FR G 674.9 3 0.00010 5 +221FR G 824.2 7 0.000049 221FR L 852.08 7 + 221FR A 4992.7 140.0013 3 7.7 221FR G 429.80 180.00038 19 221FR G 656.18 110.00049 21 -221FR G 702.00 140.00016 7 -221FR G 752.46 120.00026 7 +221FR G 702.00 140.00016 7 +221FR G 752.46 120.00026 7 221FR L 942.79 10(3/2)- 221FR A 4903.6 140.0011 4 2.5 -221FR G 747.0 1 0.0011 4 +221FR G 747.0 1 0.0011 4 diff --git a/HEN_HOUSE/spectra/lnhb/Ac-227.txt b/HEN_HOUSE/spectra/lnhb/Ac-227.txt index cd839a519..8613c2ce5 100644 --- a/HEN_HOUSE/spectra/lnhb/Ac-227.txt +++ b/HEN_HOUSE/spectra/lnhb/Ac-227.txt @@ -4,178 +4,178 @@ 223FR C References: 1950Ho79, 1955To07, 1956Sh43, 1959No41, 1959Ro51, 1963Ei10, 223FR2C 1966Ba19, 1967JoZX, 1970Ki12, 1974Mo05, 1986Ry04, 1991Ry01, 1995Sh03, 223FR3C 1995Li04, 1997Mu08, 2001Br31, 2002Ba85, 2003Au03 -223FR T Auger electrons and ^X ray energies and emission intensities: -223FR T {U Energy (keV)} {U Intensity } {U Line } +223FR T Auger electrons and X ray energies and emission intensities: +223FR T {U Energy (keV)} {U Intensity} {U Line} 223FR T -223FR T 83.23 0.0043 12 XKA2 -223FR T 86.1 0.0070 19 XKA1 +223FR T 83.23 0.0043 12 XKA2 +223FR T 86.1 0.0070 19 XKA1 223FR T -223FR T 96.815 |] XKB3 -223FR T 97.474 |] 0.0024 7 XKB1 -223FR T 98.069 |] XKB5II +223FR T 96.815 |] XKB3 +223FR T 97.474 |] 0.0024 7 XKB1 +223FR T 98.069 |] XKB5II 223FR T -223FR T 100.16 |] XKB2 -223FR T 100.548 |] 0.00079 22 XKB4 -223FR T 100.972 |] XKO23 +223FR T 100.16 |] XKB2 +223FR T 100.548 |] 0.00079 22 XKB4 +223FR T 100.972 |] XKO23 223FR T -223FR T 10.381-17.839 0.074 8 XL (total) -223FR T 10.381 0.00097 18 XLL -223FR T 11.896-12.032 0.017 3 XLA -223FR T 13.255 0.0006 1 XLC -223FR T 13.877-14.978 0.044 5 XLB -223FR T 17.302-17.839 0.012 1 XLG +223FR T 10.381-17.839 0.074 8 XL (total) +223FR T 10.381 0.00097 18 XLL +223FR T 11.896-12.032 0.017 3 XLA +223FR T 13.255 0.0006 1 XLC +223FR T 13.877-14.978 0.044 5 XLB +223FR T 17.302-17.839 0.012 1 XLG 223FR T -223FR T 63.576-70.787 |] KLL AUGER -223FR T 77.72-86.101 |] 0.00050 15 ^KLX AUGER -223FR T 91.84-101.12 |] KXY AUGER -223FR T 5.73-18.52 0.097 10 L AUGER +223FR T 63.576-70.787 |] KLL AUGER +223FR T 77.72-86.101 |] 0.00050 15 KLX AUGER +223FR T 91.84-101.12 |] KXY AUGER +223FR T 5.73-18.52 0.097 10 L AUGER 227AC P 0.0 3/2- 21.772 Y 3 5042.19 14 223FR N 7.246E1 7.246E1 0.01380 4 7.246E1 -223FR G 219.2 4 1.40E-5 4 +223FR G 219.2 4 1.40E-5 4 223FR L 0 3/2- 22.00 M 7 223FR A 4953.23 1447.7 107 223FR L 12.89 5 (5/2)- 223FR A 4940.57 1539.6 127 -223FR G 12.9 1 1400E-8 0 (E2) 4.99E4 10 -223FR2 G KC=$LC=$MC=3.77E4 8 +223FR G 12.9 1 0.000014 (E2) 4.99E4 10 +223FR2 G MC=3.77E4 8 223FR L 54.97 7 1/2- 223FR A 4899.23 1510870E-5 1360 -223FR G 55.0 1 0.00044 8 M1+E2 0.05 4 16.4 8 -223FR2 G KC=$LC=12.5 6$MC=2.98 16 +223FR G 55.0 1 0.00044 8M1+E2 0.05 4 16.4 8 +223FR2 G LC=12.5 6$MC=2.98 16 223FR L 82.13 6 (7/2)- 223FR A 4872.55 156.3 5 16 -223FR G 69.28 8 0.0039 6 M1+E2 0.57 18.4 19 -223FR2 G KC=$LC=13.7 14$MC=3.6 4 -223FR G 82.2 1 0.00083 10E2 22.1 5 -223FR2 G KC=$LC=16.25 30$MC=4.40 9 +223FR G 69.28 8 0.0039 6M1+E2 0.57 18.4 19 +223FR2 G LC=13.7 14$MC=3.6 4 +223FR G 82.2 1 0.00083 10E2 22.1 5 +223FR2 G LC=16.25 30$MC=4.40 9 223FR L 99.63 6 (3/2)- 223FR A 4855.36 155.8 7 13 -223FR G 44.7 1 0.00011 3 [M1+E2] 1 2.2E2 20 -223FR2 G KC=$LC=1.6E2 15$MC=44 40 -223FR G 86.7 2 0.0028 4 [M1+E2] 1 11 7 -223FR2 G KC=$LC=8 5$MC=2.1 14 -223FR G 99.6 1 0.0051 7 M1+E2 1 6 3 -223FR2 G KC=$LC=4.4 22$MC=1.2 7 +223FR G 44.7 1 0.00011 3[M1+E2] 1 2.2E2 20 +223FR2 G LC=1.6E2 15$MC=44 40 +223FR G 86.7 2 0.0028 4[M1+E2] 1 11 7 +223FR2 G LC=8 5$MC=2.1 14 +223FR G 99.6 1 0.0051 7M1+E2 1 6 3 +223FR2 G LC=4.4 22$MC=1.2 7 223FR L 101.00 6 (5/2)- 223FR A 4854.01 150 -223FR G 88.1 1 0.00069 10[M1+E2] 1 10 6 -223FR2 G KC=$LC=8 5$MC=2.0 13 -223FR G 101.0 1 0.00069 30[M1+E2] 1 6 3 -223FR2 G KC=$LC=4.1 21$MC=1.1 6 +223FR G 88.1 1 0.00069 10[M1+E2] 1 10 6 +223FR2 G LC=8 5$MC=2.0 13 +223FR G 101.0 1 0.00069 30[M1+E2] 1 6 3 +223FR2 G LC=4.1 21$MC=1.1 6 223FR L 134.51 6 (3/2)+ 223FR A 4821.09 1572464E-6 663 -223FR G 33.5 1 0.00011 3 [E1] 1.99 4 -223FR2 G KC=$LC=1.50 3$MC=0.371 8 -223FR G 35.0 2 2.8E-5 10[E1] 1.77 4 -223FR2 G KC=$LC=1.34 3$MC=0.330 7 -223FR G 79.54 8 0.0011 1 E1 0.197 4 -223FR2 G KC=$LC=0.149 3$MC=0.0360 7 -223FR G 121.6 1 0.0012 3 [E1] 0.295 6 -223FR2 G KC=0.231 5$LC=0.0485 10$MC=0.0116 3 -223FR G 134.5 1 0.00055 10E1 0.230 5 -223FR2 G KC=0.182 4$LC=0.0372 8$MC=0.00891 18 +223FR G 33.5 1 0.00011 3[E1] 1.99 4 +223FR2 G LC=1.50 3$MC=0.371 8 +223FR G 35.0 2 0.00002810[E1] 1.77 4 +223FR2 G LC=1.34 3$MC=0.330 7 +223FR G 79.54 8 0.0011 1E1 0.197 4 +223FR2 G LC=0.149 3$MC=0.0360 7 +223FR G 121.6 1 0.0012 3[E1] 0.295 6 +223FR2 G KC=0.231 5$LC=0.0485 10$MC=0.0116 3 +223FR G 134.5 1 0.00055 10E1 0.230 5 +223FR2 G KC=0.182 4$LC=0.0372 8$MC=0.00891 18 223FR L 149.3 3 (1/2)+ -223FR G 149.3 3 1400E-8 0 +223FR G 149.3 3 0.000014 223FR L 160.48 7 (3/2)+ 223FR A 4795.58 151.0 5 31 -223FR G 25.95 550E-9 0 -223FR G 59.4 2 4.1E-5 10[E1] 0.430 9 -223FR2 G KC=$LC=0.326 7$MC=0.0790 16 -223FR G 60.6 3 4.1E-5 10[E1] 0.408 9 -223FR2 G KC=$LC=0.309 6$MC=0.0749 15 -223FR G 147.61 8 0.0025 3 E1 0.184 4 -223FR2 G KC=0.145 3$LC=0.0292 6$MC=0.00699 14 -223FR G 160.49 100.0044 4 E1 0.150 3 -223FR2 G KC=0.119 3$LC=0.0235 5$MC=0.00562 11 +223FR G 25.95 5.5E-7 +223FR G 59.4 2 0.00004110[E1] 0.430 9 +223FR2 G LC=0.326 7$MC=0.0790 16 +223FR G 60.6 3 0.00004110[E1] 0.408 9 +223FR2 G LC=0.309 6$MC=0.0749 15 +223FR G 147.61 8 0.0025 3E1 0.184 4 +223FR2 G KC=0.145 3$LC=0.0292 6$MC=0.00699 14 +223FR G 160.49 100.0044 4E1 0.150 3 +223FR2 G KC=0.119 3$LC=0.0235 5$MC=0.00562 11 223FR L 172.08 6 (5/2)+ 223FR A 4784.19 1579710E-6 329 -223FR G 72.5 2 6.9E-5 30[E1] 0.252 5 -223FR2 G KC=$LC=0.191 4$MC=0.0462 10 -223FR G 90.0 1 0.00018 7 [E1] 0.142 3 -223FR2 G KC=$LC=0.107 2$MC=0.0259 5 -223FR G 159.2 1 0.00055 10[E1] 0.153 3 -223FR2 G KC=0.121 3$LC=0.0240 5$MC=0.00574 11 -223FR G 172.0 1 0.00097 10E1 0.127 3 -223FR2 G KC=0.101 2$LC=0.0197 4$MC=0.0047 1 +223FR G 72.5 2 0.00006930[E1] 0.252 5 +223FR2 G LC=0.191 4$MC=0.0462 10 +223FR G 90.0 1 0.00018 7[E1] 0.142 3 +223FR2 G LC=0.107 2$MC=0.0259 5 +223FR G 159.2 1 0.00055 10[E1] 0.153 3 +223FR2 G KC=0.121 3$LC=0.0240 5$MC=0.00574 11 +223FR G 172.0 1 0.00097 10E1 0.127 3 +223FR2 G KC=0.101 2$LC=0.0197 4$MC=0.0047 1 223FR L 187.18 10(5/2)- 223FR A 4769.35 171.8 5 11 -223FR G 52.32 1400E-9 0 -223FR G 86.1 1 4700E-7 0 +223FR G 52.32 1.4E-6 +223FR G 86.1 1 0.00047 223FR G 105.0 2 0.00034 10M1 12.4 25 -223FR2 G KC=9.96 20$LC=1.86 4$MC=0.443 9 -223FR G 174.3 1 0.00028 6 [M1+E2] 1 1.9 11 -223FR2 G KC=1.3 11$LC=0.48 4$MC=0.122 17 +223FR2 G KC=9.96 20$LC=1.86 4$MC=0.443 9 +223FR G 174.3 1 0.00028 6[M1+E2] 1 1.9 11 +223FR2 G KC=1.3 11$LC=0.48 4$MC=0.122 17 223FR L 189.10 7 (7/2)- 223FR A 4767.47 150 -223FR G 88.1 1 0.00069 10[M1+E2] 1 10 6 -223FR2 G KC=$LC=8 5$MC=2.0 13 -223FR G 106.85 100.0011 1 (+E2) 1 9 3 -223FR2 G KC=5 2$LC=3.2 15$MC=0.8 4 -223FR G 176.1 1 0.00033 6 M1E2 1 1.9 11 -223FR2 G KC=1.3 11$LC=0.46 4$MC=0.117 17 +223FR G 88.1 1 0.00069 10[M1+E2] 1 10 6 +223FR2 G LC=8 5$MC=2.0 13 +223FR G 106.85 100.0011 1(+E2) 1 9 3 +223FR2 G KC=5 2$LC=3.2 15$MC=0.8 4 +223FR G 176.1 1 0.00033 6M1E2 1 1.9 11 +223FR2 G KC=1.3 11$LC=0.46 4$MC=0.117 17 223FR L 219.61 9 (7/2)+ 223FR A 4737.50 1686957E-6 142 -223FR G 85.0 5 1100E-8 0 -223FR G 118.7 4 4.1E-5 10[E1] 0.312 6 -223FR2 G KC=0.244 5$LC=0.0516 11$MC=0.0124 3 -223FR G 137.4 1 0.00041 10[E1] 0.220 5 -223FR2 G KC=0.172 4$LC=0.0352 7$MC=0.00843 17 +223FR G 85.0 5 0.000011 +223FR G 118.7 4 0.00004110[E1] 0.312 6 +223FR2 G KC=0.244 5$LC=0.0516 11$MC=0.0124 3 +223FR G 137.4 1 0.00041 10[E1] 0.220 5 +223FR2 G KC=0.172 4$LC=0.0352 7$MC=0.00843 17 223FR G 206.8 1 0.00097 10E1 0.0814 17 -223FR2 G KC=0.0651 13$LC=0.0124 3$MC=0.00294 6 +223FR2 G KC=0.0651 13$LC=0.0124 3$MC=0.00294 6 223FR L 222.75 10(7/2)+ 223FR A 4734.41 170 -223FR G 51.06 280E-9 0 -223FR G 88.5 6 970E-9 0 -223FR G 140.9 1 0.00021 6 [E1] 0.206 4 -223FR2 G KC=0.162 4$LC=0.0330 7$MC=0.00789 16 +223FR G 51.06 2.8E-7 +223FR G 88.5 6 9.7E-7 +223FR G 140.9 1 0.00021 6[E1] 0.206 4 +223FR2 G KC=0.162 4$LC=0.0330 7$MC=0.00789 16 223FR L 242.63 7 (5/2)+ 223FR A 4714.88 150.43 2223 -223FR G 53.7 2 4.1E-5 10[E1] 0.563 11 -223FR2 G KC=$LC=0.427 9$MC=0.104 2 -223FR G 70.6 2 8.3E-5 30[M1+E2] 1 27 19 -223FR2 G KC=$LC=20 14$MC=5 4 -223FR G 108.0 3 4.1E-5 10[M1+E2] 1 9 3 -223FR2 G KC=5 2$LC=3.1 15$MC=0.8 4 -223FR G 143.0 1 0.00028 6 [E1] 0.198 4 -223FR2 G KC=0.157 3$LC=0.0317 7$MC=0.00759 15 -223FR G 229.7 1 0.00041 7 [E1] 0.0634 13 -223FR2 G KC=0.0509 11$LC=0.00951 19$MC=0.00226 5 -223FR G 242.6 2 0.00028 7 [E1] 0.0558 12 -223FR2 G KC=0.0448 9$LC=0.00831 17$MC=0.00198 4 +223FR G 53.7 2 0.00004110[E1] 0.563 11 +223FR2 G LC=0.427 9$MC=0.104 2 +223FR G 70.6 2 0.00008330[M1+E2] 1 27 19 +223FR2 G LC=20 14$MC=5 4 +223FR G 108.0 3 0.00004110[M1+E2] 1 9 3 +223FR2 G KC=5 2$LC=3.1 15$MC=0.8 4 +223FR G 143.0 1 0.00028 6[E1] 0.198 4 +223FR2 G KC=0.157 3$LC=0.0317 7$MC=0.00759 15 +223FR G 229.7 1 0.00041 7[E1] 0.0634 13 +223FR2 G KC=0.0509 11$LC=0.00951 19$MC=0.00226 5 +223FR G 242.6 2 0.00028 7[E1] 0.0558 12 +223FR2 G KC=0.0448 9$LC=0.00831 17$MC=0.00198 4 223FR L 243.85 13(5/2)+ 223FR A 4713.68 190 -223FR G 83.0 1 1400E-9 0 -223FR G 161.4 4 0.00014 4 [M1+E2] 1 2.5 13 -223FR2 G KC=1.6 15$LC=0.64 9$MC=0.16 4 -223FR G 230.9 5 1400E-8 0 [M1+E2] 1 0.8 5 -223FR2 G KC=0.6 5$LC=0.177 24$MC=0.045 4 -223FR G 243.9 4 2.80E-5 8 [E2] 0.279 6 -223FR2 G KC=0.108 2$LC=0.126 3$MC=0.0335 7 +223FR G 83.0 1 1.4E-6 +223FR G 161.4 4 0.00014 4[M1+E2] 1 2.5 13 +223FR2 G KC=1.6 15$LC=0.64 9$MC=0.16 4 +223FR G 230.9 5 0.000014 [M1+E2] 1 0.8 5 +223FR2 G KC=0.6 5$LC=0.177 24$MC=0.045 4 +223FR G 243.9 4 2.80E-5 8[E2] 0.279 6 +223FR2 G KC=0.108 2$LC=0.126 3$MC=0.0335 7 223FR L 244.66 15(7/2)- 223FR A 4712.89 200 -223FR G 55.80 5 3900E-9 0 -223FR G 57.56 5 3200E-9 0 -223FR G 72.5 2 6.9E-5 30[E1] 0.252 5 -223FR2 G KC=$LC=0.191 4$MC=0.0462 10 -223FR G 143.65 5 2600E-8 0 M1 5.11 11 -223FR2 G KC=4.12 8$LC=0.755 15$MC=0.180 4 -223FR G 162.6 2 5.5E-5 30M1E2 1 2.4 13 -223FR2 G KC=1.6 15$LC=0.62 9$MC=0.16 4 -223FR G 231.79 5 7200E-9 0 +223FR G 55.80 5 3.9E-6 +223FR G 57.56 5 3.2E-6 +223FR G 72.5 2 0.00006930[E1] 0.252 5 +223FR2 G LC=0.191 4$MC=0.0462 10 +223FR G 143.65 5 0.000026 M1 5.11 11 +223FR2 G KC=4.12 8$LC=0.755 15$MC=0.180 4 +223FR G 162.6 2 0.00005530M1E2 1 2.4 13 +223FR2 G KC=1.6 15$LC=0.62 9$MC=0.16 4 +223FR G 231.79 5 7.2E-6 223FR L 298.7 3 (9/2)- -223FR G 216.6 3 5.5E-5 30[M1+E2] 1 1.0 7 -223FR2 G KC=0.7 6$LC=0.221 20$MC=0.0556 18 +223FR G 216.6 3 0.00005530[M1+E2] 1 1.0 7 +223FR2 G KC=0.7 6$LC=0.221 20$MC=0.0556 18 223FR L 365.47 10 + 223FR A 4594.21 1721739E-6 65 -223FR G 121.6 1 0.0012 3 [E1] 0.295 6 -223FR2 G KC=0.231 5$LC=0.0485 10$MC=0.0116 3 -223FR G 143.0 1 0.00028 6 [M1+E2] 1 3.6 18 -223FR2 G KC=2.2 11$LC=1.0 5$MC=0.26 13 -223FR G 146.0 2 8800E-9 0 -223FR G 176.1 1 0.00033 4 [E1] 0.120 3 -223FR2 G KC=0.095 2$LC=0.0185 4$MC=0.00443 9 -223FR G 283.4 3 5.5E-5 30[E1] 0.0389 8 -223FR2 G KC=0.0314 7$LC=0.00570 12$MC=0.00136 3 +223FR G 121.6 1 0.0012 3[E1] 0.295 6 +223FR2 G KC=0.231 5$LC=0.0485 10$MC=0.0116 3 +223FR G 143.0 1 0.00028 6[M1+E2] 1 3.6 18 +223FR2 G KC=2.2 11$LC=1.0 5$MC=0.26 13 +223FR G 146.0 2 8.8E-6 +223FR G 176.1 1 0.00033 4[E1] 0.120 3 +223FR2 G KC=0.095 2$LC=0.0185 4$MC=0.00443 9 +223FR G 283.4 3 0.00005530[E1] 0.0389 8 +223FR2 G KC=0.0314 7$LC=0.00570 12$MC=0.00136 3 223FR L 379 7 + 223FR A 4581 7 28986E-7 340 223FR L 449 5 + @@ -184,19 +184,19 @@ 223FR A 4459 7 50725E-7 26 223FR L 515.20 223/2- 223FR A 4447.12 2650725E-6 2.1 -223FR G 415.6 3 0.00021 6 1 0.16 11 -223FR2 G KC=0.13 10$LC=0.028 12$MC=0.007 3 -223FR G 460.2 3 0.00021 6 M1+E2 1 0.12 9 -223FR2 G KC=0.10 8$LC=0.021 10$MC=0.0051 22 +223FR G 415.6 3 0.00021 6 1 0.16 11 +223FR2 G KC=0.13 10$LC=0.028 12$MC=0.007 3 +223FR G 460.2 3 0.00021 6M1+E2 1 0.12 9 +223FR2 G KC=0.10 8$LC=0.021 10$MC=0.0051 22 223FR L 540.74 25(5/2)+ 223FR A 4422.03 2857971E-7 12 -223FR G 351.7 3 5.5E-5 30[E1] 0.0240 5 -223FR2 G KC=0.0195 4$LC=0.00344 7$MC=8.15E-4 17 -223FR G 439.60 5 3.4E-5 1 -223FR G 441.0 4 5.5E-5 30[E1] 0.0148 3 -223FR2 G KC=0.0120 3$LC=0.00207 4$MC=0.00049 1 -223FR G 527.6 1 2900E-8 0 -223FR G 540.40 5 7000E-8 0 +223FR G 351.7 3 0.00005530[E1] 0.0240 5 +223FR2 G KC=0.0195 4$LC=0.00344 7$MC=8.15E-4 17 +223FR G 439.60 5 0.000034 1 +223FR G 441.0 4 0.00005530[E1] 0.0148 3 +223FR2 G KC=0.0120 3$LC=0.00207 4$MC=0.00049 1 +223FR G 527.6 1 0.000029 +223FR G 540.40 5 0.00007 223FR L 601 7 (5/2)- 223FR A 4362.83 1528986E-7 8 @@ -206,54 +206,54 @@ 227TH C References: 1950Ho79, 1955To07, 1956Sh43, 1959No41, 1959Ro51, 1963Ei10, 227TH2C 1966Ba19, 1967JoZX, 1970Ki12, 1974Mo05, 1986Ry04, 1991Ry01, 1995Sh03, 227TH3C 1995Li04, 1997Mu08, 2001Br31, 2002Ba85, 2003Au03 -227TH T Auger electrons and ^X ray energies and emission intensities: -227TH T {U Energy (keV)} {U Intensity } {U Line } +227TH T Auger electrons and X ray energies and emission intensities: +227TH T {U Energy (keV)} {U Intensity} {U Line} 227TH T 227TH T 89.954 XKA2 227TH T 93.351 XKA1 227TH T -227TH T 104.819 |] XKB3 -227TH T 105.604 |] XKB1 -227TH T 106.239 |] XKB5II +227TH T 104.819 |] XKB3 +227TH T 105.604 |] XKB1 +227TH T 106.239 |] XKB5II 227TH T -227TH T 108.509 |] XKB2 -227TH T 108.955 |] XKB4 -227TH T 109.442 |] XKO23 +227TH T 108.509 |] XKB2 +227TH T 108.955 |] XKB4 +227TH T 109.442 |] XKO23 227TH T -227TH T 11.118-19.599 2.64 XL (total) -227TH T 11.118 0.044 XLL -227TH T 12.809-12.968 0.147 XLA -227TH T 14.511 0.027 XLC -227TH T 14.97-16.426 1.9 XLB -227TH T 18.98-19.599 0.52 XLG +227TH T 11.118-19.599 2.64 XL (total) +227TH T 11.118 0.044 XLL +227TH T 12.809-12.968 0.147 XLA +227TH T 14.511 0.027 XLC +227TH T 14.97-16.426 1.9 XLB +227TH T 18.98-19.599 0.52 XLG 227TH T -227TH T 68.406-76.745 |] KLL AUGER -227TH T 83.857-93.345 |] ^KLX AUGER -227TH T 99.29-109.64 |] KXY AUGER -227TH T 5.8-20.3 3.9 L AUGER +227TH T 68.406-76.745 |] KLL AUGER +227TH T 83.857-93.345 |] KLX AUGER +227TH T 99.29-109.64 |] KXY AUGER +227TH T 5.8-20.3 3.9 L AUGER 227AC P 0.0 3/2- 21.772 Y 3 44.8 8 227TH N 1.014E0 1.014E0 0.98620 4 1.014E0 -227TH G 219.2 4 1.40E-5 4 +227TH G 219.2 4 1.40E-5 4 227TH L 0 1/2+ 18.718 D 5 -227TH B 44.8 8 53 7.1 1U +227TH B 44.8 8 53 7.1 1 227THS B EAV=11.4 3 227TH L 9.3 1 (5/2)+ -227TH B 35.5 8 35 7 1U +227TH B 35.5 8 35 7 1 227THS B EAV=9.0 3 -227TH G 9.3 1100E-7 0 E2 326000 0 -227TH2 G KC=$LC=$MC=2.44E5 5 +227TH G 9.3 0.00011 E2 326000 +227TH2 G MC=2.44E5 5 227TH L 24.5 3/2+ 227TH B 20.5 8 10 6.8 227THS B EAV=5.1 3 -227TH G 15.2 1 6300E-7 0 M1 238 5 -227TH2 G KC=$LC=$MC=177 4 -227TH G 24.33 5 2800E-5 0 M1+E2 0.100 5 340 11 -227TH2 G KC=$LC=254 8$MC=64.0 23 +227TH G 15.2 1 0.00063 M1 238 5 +227TH2 G MC=177 4 +227TH G 24.33 5 0.028 M1+E2 0.100 5 340 11 +227TH2 G LC=254 8$MC=64.0 23 227TH L 37.9 3/2- 227TH B 6.9 8 0.3 6.9 227THS B EAV=1.7 3 -227TH G 28.57 5 4200E-5 0 E1 3.24 7 -227TH2 G KC=$LC=2.42 5$MC=0.616 13 -227TH G 37.90 3 4900E-5 0 E1 1.54 3 -227TH2 G KC=$LC=1.16 3$MC=0.288 6 +227TH G 28.57 5 0.042 E1 3.24 7 +227TH2 G LC=2.42 5$MC=0.616 13 +227TH G 37.90 3 0.049 E1 1.54 3 +227TH2 G LC=1.16 3$MC=0.288 6 diff --git a/HEN_HOUSE/spectra/lnhb/Ac-228.txt b/HEN_HOUSE/spectra/lnhb/Ac-228.txt index 4c8e1b47c..099620c5b 100644 --- a/HEN_HOUSE/spectra/lnhb/Ac-228.txt +++ b/HEN_HOUSE/spectra/lnhb/Ac-228.txt @@ -4,24 +4,24 @@ 224FR C References: 1931Cu01, 1969Lu12, 1971He23, 1979He23, 1985Sk02, 1987Da28, 224FR2C 1992Li05, 1995Ba42, 1996Sc06, 1997Ar08, 2003Wa32, 2003Au03, 2005KiZT, 224FR3C 2004KiZW -224FR T Auger electrons and ^X ray energies and emission intensities: -224FR T {U Energy (keV)} {U Intensity } {U Line } +224FR T Auger electrons and X ray energies and emission intensities: +224FR T {U Energy (keV)} {U Intensity} {U Line} 224FR T 224FR T 83.23 XKA2 224FR T 86.1 XKA1 224FR T -224FR T 96.815 |] XKB3 -224FR T 97.474 |] XKB1 -224FR T 98.069 |] XKB5II +224FR T 96.815 |] XKB3 +224FR T 97.474 |] XKB1 +224FR T 98.069 |] XKB5II 224FR T -224FR T 100.16 |] XKB2 -224FR T 100.548 |] XKB4 -224FR T 100.972 |] XKO23 +224FR T 100.16 |] XKB2 +224FR T 100.548 |] XKB4 +224FR T 100.972 |] XKO23 224FR T 224FR T -224FR T 63.576-70.787 |] KLL AUGER -224FR T 77.72-86.101 |] ^KLX AUGER -224FR T 91.84-101.12 |] KXY AUGER +224FR T 63.576-70.787 |] KLL AUGER +224FR T 77.72-86.101 |] KLX AUGER +224FR T 91.84-101.12 |] KXY AUGER 224FR T 0.1-18.519 L AUGER 228AC P 0.0 3+ 6.15 H 3 4810 50 224FR N 1.818E7 1.818E7 5.5E-08 221.818E7 @@ -33,611 +33,611 @@ 228TH C References: 1931Cu01, 1969Lu12, 1971He23, 1979He23, 1985Sk02, 1987Da28, 228TH2C 1992Li05, 1995Ba42, 1996Sc06, 1997Ar08, 2003Wa32, 2003Au03, 2005KiZT, 228TH3C 2004KiZW -228TH T Auger electrons and ^X ray energies and emission intensities: -228TH T {U Energy (keV)} {U Intensity } {U Line } +228TH T Auger electrons and X ray energies and emission intensities: +228TH T {U Energy (keV)} {U Intensity} {U Line} 228TH T -228TH T 89.954 2.5 7 XKA2 -228TH T 93.351 4.1 11 XKA1 +228TH T 89.954 2.5 7 XKA2 +228TH T 93.351 4.1 11 XKA1 228TH T -228TH T 104.819 |] XKB3 -228TH T 105.604 |] 1.5 4 XKB1 -228TH T 106.239 |] XKB5II +228TH T 104.819 |] XKB3 +228TH T 105.604 |] 1.5 4 XKB1 +228TH T 106.239 |] XKB5II 228TH T -228TH T 108.509 |] XKB2 -228TH T 108.955 |] 0.49 13 XKB4 -228TH T 109.442 |] XKO23 +228TH T 108.509 |] XKB2 +228TH T 108.955 |] 0.49 13 XKB4 +228TH T 109.442 |] XKO23 228TH T -228TH T 11.1177-19.5043 37 4 XL (total) -228TH T 11.1177 0.80 5 XLL -228TH T 12.8085-12.967 13.3 8 XLA -228TH T 14.509 0.385 17 XLC -228TH T 14.972-16.4253 18.2 7 XLB -228TH T 18.3633-19.5043 4.23 15 XLG +228TH T 11.1177-19.5043 37 4 XL (total) +228TH T 11.1177 0.80 5 XLL +228TH T 12.8085-12.967 13.3 8 XLA +228TH T 14.509 0.385 17 XLC +228TH T 14.972-16.4253 18.2 7 XLB +228TH T 18.3633-19.5043 4.23 15 XLG 228TH T -228TH T 68.406-76.745 |] KLL AUGER -228TH T 83.857-93.345 |] 0.27 8 ^KLX AUGER -228TH T 99.29-109.64 |] KXY AUGER -228TH T 5.8-20.3 39.9 21 L AUGER +228TH T 68.406-76.745 |] KLL AUGER +228TH T 83.857-93.345 |] 0.27 8 KLX AUGER +228TH T 99.29-109.64 |] KXY AUGER +228TH T 5.8-20.3 39.9 21 L AUGER 228AC P 0.0 3+ 6.15 H 3 2123.8 27 228TH N 1.0 1.0 1 1.0 228TH L 0 - 1.9126 Y 9 228TH L 57.759 4 2+ -228TH B 2066.0 276 4 9 +228TH B 2066.0 276 4 9 228THS B EAV=742.8 11 228TH G 57.752 130.470 17E2 153.2 22 -228TH2 G KC=$LC=112.2 16$MC=30.7 5 +228TH2 G LC=112.2 16$MC=30.7 5 228TH L 186.823 4 4+ -228TH B 1937.0 270.6 5 10 +228TH B 1937.0 270.6 5 10 228THS B EAV=690.2 11 -228TH G 129.065 3 2.50 7 E2 3.74 6 -228TH2 G KC=0.264 4$LC=2.54 4$MC=0.697 10 +228TH G 129.065 3 2.50 7E2 3.74 6 +228TH2 G KC=0.264 4$LC=2.54 4$MC=0.697 10 228TH L 328.003 4 1- 228TH B 1795.8 270.72 23 10.65 1U 228THS B EAV=605.4 11 -228TH G 270.245 7 3.55 10E1 0.0470 7 -228TH2 G KC=0.0376 6$LC=0.00716 10$MC=1717E-6 24 -228TH G 328.004 7 3.04 11E1 0.0305 5 -228TH2 G KC=0.0245 4$LC=0.00455 7$MC=1089E-6 16 +228TH G 270.245 7 3.55 10E1 0.0470 7 +228TH2 G KC=0.0376 6$LC=0.00716 10$MC=1717E-6 24 +228TH G 328.004 7 3.04 11E1 0.0305 5 +228TH2 G KC=0.0245 4$LC=0.00455 7$MC=1089E-6 16 228TH L 378.179 106+ 228TH B 1745.6 270.147 21 12.29 2U 228THS B EAV=587.3 11 -228TH G 191.351 170.133 8 E2 0.776 11 -228TH2 G KC=0.1710 24$LC=0.443 7$MC=0.1209 17 +228TH G 191.351 170.133 8E2 0.776 11 +228TH2 G KC=0.1710 24$LC=0.443 7$MC=0.1209 17 228TH L 396.078 5 3- -228TH B 1727.7 2712.4 5 8.4 +228TH B 1727.7 2712.4 5 8.4 228THS B EAV=605.7 11 228TH G 209.248 7 3.97 13E1 0.0848 12 -228TH2 G KC=0.0672 10$LC=0.01333 19$MC=0.00321 5 -228TH G 338.320 5 11.4 4 E1 0.0285 4 -228TH2 G KC=0.0229 4$LC=0.00424 6$MC=1014E-6 15 +228TH2 G KC=0.0672 10$LC=0.01333 19$MC=0.00321 5 +228TH G 338.320 5 11.4 4E1 0.0285 4 +228TH2 G KC=0.0229 4$LC=0.00424 6$MC=1014E-6 15 228TH L 519.192 6 5- -228TH G 140.999 200.045 9 E1 0.217 3 -228TH2 G KC=0.1690 24$LC=0.0362 5$MC=0.00876 13 -228TH G 332.371 6 0.37 6 E1 0.0297 5 -228TH2 G KC=0.0238 4$LC=0.00441 7$MC=1056E-6 15 +228TH G 140.999 200.045 9E1 0.217 3 +228TH2 G KC=0.1690 24$LC=0.0362 5$MC=0.00876 13 +228TH G 332.371 6 0.37 6E1 0.0297 5 +228TH2 G KC=0.0238 4$LC=0.00441 7$MC=1056E-6 15 228TH L 831.823 100+ 228TH G 503.819 230.171 19E1 0.0124318 -228TH2 G KC=0.01009 15$LC=1775E-6 25$MC=4.22E-4 6 -228TH G 774.07 100.062 4 E2 0.0164923 -228TH2 G KC=0.01204 17$LC=0.00333 5$MC=8.35E-4 12 +228TH2 G KC=0.01009 15$LC=1775E-6 25$MC=4.22E-4 6 +228TH G 774.07 100.062 4E2 0.0164923 +228TH2 G KC=0.01204 17$LC=0.00333 5$MC=8.35E-4 12 228TH L 874.473 182+ 228TH B 1249.3 270.17 10 9.7 228THS B EAV=417.2 11 228TH G 478.40 5 0.224 19E1 0.0137920 -228TH2 G KC=0.01118 16$LC=0.00198 3$MC=4.71E-4 7 +228TH2 G KC=0.01118 16$LC=0.00198 3$MC=4.71E-4 7 228TH G 546.445 210.199 16E1 0.0105815 -228TH2 G KC=0.00861 12$LC=1500E-6 21$MC=3.57E-4 5 -228TH G 816.82 100.031 4 M1+E2 0.036 21 -228TH2 G KC=0.028 18$LC=0.006 3$MC=0.0014 7 +228TH2 G KC=0.00861 12$LC=1500E-6 21$MC=3.57E-4 5 +228TH G 816.82 100.031 4M1+E2 0.036 21 +228TH2 G KC=0.028 18$LC=0.006 3$MC=0.0014 7 228TH G 874.45 8 0.050 11E2 0.0129419 -228TH2 G KC=0.00968 14$LC=0.00245 4$MC=6.08E-4 9 +228TH2 G KC=0.00968 14$LC=0.00245 4$MC=6.08E-4 9 228TH L 938.58 7 0+ -228TH G 610.65 100.024 5 E1 0.0085312 -228TH2 G KC=0.00695 10$LC=1198E-6 17$MC=2.84E-4 4 +228TH G 610.65 100.024 5E1 0.0085312 +228TH2 G KC=0.00695 10$LC=1198E-6 17$MC=2.84E-4 4 228TH G 880.76 100.0065 19E2 0.0127618 -228TH2 G KC=0.00956 14$LC=0.00240 4$MC=5.97E-4 9 +228TH2 G KC=0.00956 14$LC=0.00240 4$MC=5.97E-4 9 228TH L 944.196 131,2+ 228TH B 1179.6 270.087 16 9.95 2 228THS B EAV=390.6 11 -228TH G 616.21 3 0.084 7 E1 0.0083812 -228TH2 G KC=0.00683 10$LC=1176E-6 17$MC=2.79E-4 4 -228TH G 944.19 3 0.10 1 E1+M2 0.025 14 -228TH2 G KC=0.020 12$LC=0.0039 19$MC=0.0009 5 +228TH G 616.210 300.084 7E1 0.0083812 +228TH2 G KC=0.00683 10$LC=1176E-6 17$MC=2.79E-4 4 +228TH G 944.190 300.10 1E1+M2 0.025 14 +228TH2 G KC=0.020 12$LC=0.0039 19$MC=0.0009 5 228TH L 968.369 203- -228TH B 1155.4 270.18 3 9.6 +228TH B 1155.4 270.18 3 9.6 228THS B EAV=381.4 11 -228TH G 449.11 6 0.050 6 E2 0.0554 8 -228TH2 G KC=0.0331 5$LC=0.01653 24$MC=0.00432 6 -228TH G 572.10 5 0.156 18M1+E2 0.09 6 -228TH2 G KC=0.07 5$LC=0.015 7$MC=0.0036 17 -228TH G 640.32 4 0.057 6 E2 0.0245 4 -228TH2 G KC=0.01700 24$LC=0.00556 8$MC=1416E-6 20 +228TH G 449.11 6 0.050 6E2 0.0554 8 +228TH2 G KC=0.0331 5$LC=0.01653 24$MC=0.00432 6 +228TH G 572.10 5 0.156 18M1+E2 0.09 6 +228TH2 G KC=0.07 5$LC=0.015 7$MC=0.0036 17 +228TH G 640.320 400.057 6E2 0.0245 4 +228TH2 G KC=0.01700 24$LC=0.00556 8$MC=1416E-6 20 228TH L 968.968 5 2+ -228TH B 1154.8 2731 4 7.37 +228TH B 1154.8 2731 4 7.37 228THS B EAV=381.1 11 -228TH G 782.140 6 0.50 4 E2 0.0161523 -228TH2 G KC=0.01182 17$LC=0.00324 5$MC=8.12E-4 12 -228TH G 911.196 6 26.2 8 E2 0.0119417 -228TH2 G KC=0.00900 13$LC=0.00221 3$MC=5.49E-4 8 -228TH G 968.960 9 15.9 5 E2 0.0106115 -228TH2 G KC=0.00806 12$LC=0.00191 3$MC=4.72E-4 7 +228TH G 782.140 6 0.50 4E2 0.0161523 +228TH2 G KC=0.01182 17$LC=0.00324 5$MC=8.12E-4 12 +228TH G 911.196 6 26.2 8E2 0.0119417 +228TH2 G KC=0.00900 13$LC=0.00221 3$MC=5.49E-4 8 +228TH G 968.960 9 15.9 5E2 0.0106115 +228TH2 G KC=0.00806 12$LC=0.00191 3$MC=4.72E-4 7 228TH L 979.499 142+ 228TH B 1144.3 270.238 20 9.47 228THS B EAV=377.1 11 228TH G 583.391 100.120 11E1 0.0093213 -228TH2 G KC=0.00759 11$LC=1313E-6 19$MC=3.12E-4 5 -228TH G 651.53 3 0.094 10E1 0.0075411 -228TH2 G KC=0.00615 9$LC=1053E-6 15$MC=2.50E-4 4 -228TH G 792.69 100.081 5 E2 0.0157222 -228TH2 G KC=0.01154 17$LC=0.00313 5$MC=7.84E-4 11 +228TH2 G KC=0.00759 11$LC=1313E-6 19$MC=3.12E-4 5 +228TH G 651.530 300.094 10E1 0.0075411 +228TH2 G KC=0.00615 9$LC=1053E-6 15$MC=2.50E-4 4 +228TH G 792.69 100.081 5E2 0.0157222 +228TH2 G KC=0.01154 17$LC=0.00313 5$MC=7.84E-4 11 228TH G 921.87 120.0154 23M1+E2 0.027 15 -228TH2 G KC=0.021 13$LC=0.0041 20$MC=0.0010 5 -228TH G 979.49 100.028 3 E2 0.0103915 -228TH2 G KC=0.00791 11$LC=0.00186 3$MC=4.59E-4 7 +228TH2 G KC=0.021 13$LC=0.0041 20$MC=0.0010 5 +228TH G 979.49 100.028 3E2 0.0103915 +228TH2 G KC=0.00791 11$LC=0.00186 3$MC=4.59E-4 7 228TH L 1016.406 212,3,4- -228TH B 1107.4 270.39 6 9.2 1 +228TH B 1107.4 270.39 6 9.2 1 228THS B EAV=363.1 11 -228TH G 620.32 7 0.084 7 -228TH G 688.12 4 0.070 7 -228TH G 958.59 4 0.29 5 -228TH G 1016.44 100.019 3 M1+E2 0.021 12 -228TH2 G KC=0.017 10$LC=0.0032 15$MC=0.0008 4 +228TH G 620.32 7 0.084 7 +228TH G 688.120 400.070 7 +228TH G 958.590 400.29 5 +228TH G 1016.44 100.019 3M1+E2 0.021 12 +228TH2 G KC=0.017 10$LC=0.0032 15$MC=0.0008 4 228TH L 1022.527 6 (3)+ -228TH B 1101.3 273.0 4 8.31 +228TH B 1101.3 273.0 4 8.31 228THS B EAV=360.8 11 -228TH G 835.704 8 1.70 7 E2 0.0141520 -228TH2 G KC=0.01050 15$LC=0.00274 4$MC=6.83E-4 10 +228TH G 835.704 8 1.70 7E2 0.0141520 +228TH2 G KC=0.01050 15$LC=0.00274 4$MC=6.83E-4 10 228TH G 964.786 8 4.99 17E2+M1 -7.2 10 0.0111923 -228TH2 G KC=0.00853 19$LC=0.00199 4$MC=4.92E-4 9 +228TH2 G KC=0.00853 19$LC=0.00199 4$MC=4.92E-4 9 228TH L 1059.93 3 4- 228TH B 1063.9 270.099 11 9.74 1 228THS B EAV=346.7 11 -228TH G 540.67 5 0.027 3 M1+E2 0.10 7 -228TH2 G KC=0.08 6$LC=0.017 9$MC=0.0042 19 -228TH G 663.88 8 0.029 6 M1+E2 0.06 4 -228TH2 G KC=0.05 4$LC=0.010 5$MC=0.0024 12 -228TH G 873.10 150.032 7 E1 0.004407 -228TH2 G KC=0.00361 5$LC=6.01E-4 9$MC=1422E-7 20 +228TH G 540.67 5 0.027 3M1+E2 0.10 7 +228TH2 G KC=0.08 6$LC=0.017 9$MC=0.0042 19 +228TH G 663.88 8 0.029 6M1+E2 0.06 4 +228TH2 G KC=0.05 4$LC=0.010 5$MC=0.0024 12 +228TH G 873.10 150.032 7E1 0.00440 7 +228TH2 G KC=0.00361 5$LC=6.01E-4 9$MC=1422E-7 20 228TH L 1091.017 8 4+ -228TH G 904.20 5 0.78 4 E2 0.0121217 -228TH2 G KC=0.00912 13$LC=0.00225 4$MC=5.59E-4 8 +228TH G 904.20 5 0.78 4E2 0.0121217 +228TH2 G KC=0.00912 13$LC=0.00225 4$MC=5.59E-4 8 228TH G 1033.244 230.204 12E2 0.0093814 -228TH2 G KC=0.0072 1$LC=1643E-6 23$MC=4.04E-4 6 +228TH2 G KC=0.0072 1$LC=1643E-6 23$MC=4.04E-4 6 228TH L 1122.951 6 2- 228TH B 1000.8 276.67 18 7.81 1 228THS B EAV=323.2 10 -228TH G 100.41 3 0.114 6 E1+M2 0.23 3.10 5 -228TH2 G KC=$LC=2.27 4$MC=0.615 9 +228TH G 100.41 3 0.114 6E1+M2 0.23 3.10 5 +228TH2 G LC=2.27 4$MC=0.615 9 228TH G 153.967 110.754 23E1 0.1757 25 -228TH2 G KC=0.1375 20$LC=0.0289 4$MC=0.00698 10 -228TH G 726.88 100.68 8 E2 0.0187 3 -228TH2 G KC=0.01349 19$LC=0.00393 6$MC=9.90E-4 14 +228TH2 G KC=0.1375 20$LC=0.0289 4$MC=0.00698 10 +228TH G 726.88 100.68 8E2 0.0187 3 +228TH2 G KC=0.01349 19$LC=0.00393 6$MC=9.90E-4 14 228TH G 794.942 144.31 14E2+M1 -4.4 10 0.0179 14 -228TH2 G KC=0.0133 12$LC=0.00340 19$MC=0.00085 5 -228TH G 1065.168 150.135 8 +228TH2 G KC=0.0133 12$LC=0.00340 19$MC=0.00085 5 +228TH G 1065.168 150.135 8 228TH L 1153.467 102+ 0.29 NS 2 -228TH B 970.3 276 3 7.8 +228TH B 970.3 276 3 7.8 228THS B EAV=311.9 10 -228TH G 173.96 3 0.036 5 M1+E2 2.5 14 -228TH2 G KC=1.6 15$LC=0.63 5$MC=0.162 22 +228TH G 173.960 300.036 5M1+E2 2.5 14 +228TH2 G KC=1.6 15$LC=0.63 5$MC=0.162 22 228TH G 184.547 190.054 19+M1 100 40 -228TH2 G KC=80 30$LC=$MC= -228TH G 214.89 100.031 5 E2 0.514 8 -228TH2 G KC=0.1399 20$LC=0.274 4$MC=0.0746 11 -228TH G 278.80 150.204 28M1+E2 0.6 4 -228TH2 G KC=0.5 4$LC=0.12 3$MC=0.031 6 +228TH2 G KC=80 30 +228TH G 214.89 100.031 5E2 0.514 8 +228TH2 G KC=0.1399 20$LC=0.274 4$MC=0.0746 11 +228TH G 278.80 150.204 28M1+E2 0.6 4 +228TH2 G KC=0.5 4$LC=0.12 3$MC=0.031 6 228TH G 321.646 8 0.232 14E2 0.1369 20 -228TH2 G KC=0.0635 9$LC=0.0540 8$MC=0.01444 21 -228TH G 1095.671 230.126 10M1+E2 0.017 9 -228TH2 G KC=0.014 8$LC=0.0026 13$MC=0.0006 3 -228TH G 1153.27 4 0.148 13E1+M2 0.03 3 -228TH2 G KC=0.022 20$LC=0.004 5$MC=0.0011 10 +228TH2 G KC=0.0635 9$LC=0.0540 8$MC=0.01444 21 +228TH G 1095.671 230.126 10M1+E2 0.017 9 +228TH2 G KC=0.014 8$LC=0.0026 13$MC=0.0006 3 +228TH G 1153.270 400.148 13E1+M2 0.03 3 +228TH2 G KC=0.022 20$LC=0.004 5$MC=0.0011 10 228TH L 1168.375 5 3- 228TH B 955.4 273.39 13 8.04 228THS B EAV=306.4 10 -228TH G 77.34 3 0.027 6 E1 0.232 4 -228TH2 G KC=$LC=0.1747 25$MC=0.0426 6 -228TH G 145.842 200.169 6 E1 0.200 3 -228TH2 G KC=0.1562 22$LC=0.0332 5$MC=0.00803 12 +228TH G 77.34 3 0.027 6E1 0.232 4 +228TH2 G LC=0.1747 25$MC=0.0426 6 +228TH G 145.842 200.169 6E1 0.200 3 +228TH2 G KC=0.1562 22$LC=0.0332 5$MC=0.00803 12 228TH G 199.402 150.299 23E1 0.0950 14 -228TH2 G KC=0.0752 11$LC=0.01502 21$MC=0.00362 5 -228TH G 649.02 120.0332 36E2 0.0238 4 -228TH2 G KC=0.01658 24$LC=0.00536 8$MC=1362E-6 19 -228TH G 772.291 7 1.52 6 M1+E2 2.3 2 0.0244 14 -228TH2 G KC=0.0186 11$LC=0.00437 18$MC=0.00108 5 -228TH G 840.372 9 0.97 4 E2 0.0140 2 -228TH2 G KC=0.01039 15$LC=0.00270 4$MC=6.73E-4 10 -228TH G 1110.604 9 0.284 22E1 0.002884 -228TH2 G KC=0.00237 4$LC=3.88E-4 6$MC=9.15E-5 13 +228TH2 G KC=0.0752 11$LC=0.01502 21$MC=0.00362 5 +228TH G 649.02 120.0332 36E2 0.0238 4 +228TH2 G KC=0.01658 24$LC=0.00536 8$MC=1362E-6 19 +228TH G 772.291 7 1.52 6M1+E2 2.3 2 0.0244 14 +228TH2 G KC=0.0186 11$LC=0.00437 18$MC=0.00108 5 +228TH G 840.372 9 0.97 4E2 0.0140 2 +228TH2 G KC=0.01039 15$LC=0.00270 4$MC=6.73E-4 10 +228TH G 1110.604 9 0.284 22E1 0.00288 4 +228TH2 G KC=0.00237 4$LC=3.88E-4 6$MC=9.15E-5 13 228TH L 1174.508 18(5)+ -228TH G 987.87 100.14 6 M1+E2 0.022 13 -228TH2 G KC=0.018 10$LC=0.0034 17$MC=0.0008 4 +228TH G 987.87 100.14 6M1+E2 0.022 13 +228TH2 G KC=0.018 10$LC=0.0034 17$MC=0.0008 4 228TH L 1175.39 5 2+ 228TH B 948.4 270.166 19 9.34 228THS B EAV=303.9 10 -228TH G 231.42 100.026 4 E2 0.392 6 -228TH2 G KC=0.1211 17$LC=0.199 3$MC=0.0539 8 +228TH G 231.42 100.026 4E2 0.392 6 +228TH2 G KC=0.1211 17$LC=0.199 3$MC=0.0539 8 228TH G 988.65 200.081 14E2 0.0102115 -228TH2 G KC=0.00778 11$LC=0.00182 3$MC=4.49E-4 7 -228TH G 1117.65 100.061 7 -228TH G 1175.33 100.025 4 E1+M2 0.027 24 -228TH2 G KC=0.021 19$LC=0.004 4$MC=0.001 1 +228TH2 G KC=0.00778 11$LC=0.00182 3$MC=4.49E-4 7 +228TH G 1117.65 100.061 7 +228TH G 1175.33 100.025 4E1+M2 0.027 24 +228TH2 G KC=0.021 19$LC=0.004 4$MC=0.001 1 228TH L 1226.565 7 (4)- -228TH B 897.2 270.67 8 8.65 1 +228TH B 897.2 270.67 8 8.65 1 228THS B EAV=285.1 10 -228TH G 135.507 220.024 6 E1 0.238 4 -228TH2 G KC=0.185 3$LC=0.0401 6$MC=0.00971 14 -228TH G 707.42 5 0.162 18E2 0.0198 3 -228TH2 G KC=0.01417 20$LC=0.00422 6$MC=1067E-6 15 -228TH G 830.481 8 0.61 6 E2+M1 -7.7 9 0.0150 3 -228TH2 G KC=0.01117 22$LC=0.00287 5$MC=7.15E-4 12 +228TH G 135.507 220.024 6E1 0.238 4 +228TH2 G KC=0.185 3$LC=0.0401 6$MC=0.00971 14 +228TH G 707.42 5 0.162 18E2 0.0198 3 +228TH2 G KC=0.01417 20$LC=0.00422 6$MC=1067E-6 15 +228TH G 830.481 8 0.61 6E2+M1 -7.7 9 0.0150 3 +228TH2 G KC=0.01117 22$LC=0.00287 5$MC=7.15E-4 12 228TH G 1039.83 7 0.056 18 228TH L 1297.423 10(5)- 228TH B 826.4 271.46 11 8.18 1U 228THS B EAV=259.4 10 -228TH G 204.029 110.114 8 M2 10.65 15 -228TH2 G KC=7.26 11$LC=2.51 4$MC=0.653 10 -228TH G 901.38 3 0.017 4 E2 0.0122017 -228TH2 G KC=0.00917 13$LC=0.00227 4$MC=5.64E-4 8 -228TH G 1110.604 9 0.0272 21E1 0.002884 -228TH2 G KC=0.00237 4$LC=3.88E-4 6$MC=9.15E-5 13 +228TH G 204.029 110.114 8M2 10.65 15 +228TH2 G KC=7.26 11$LC=2.51 4$MC=0.653 10 +228TH G 901.380 300.017 4E2 0.0122017 +228TH2 G KC=0.00917 13$LC=0.00227 4$MC=5.64E-4 8 +228TH G 1110.604 9 0.0272 21E1 0.00288 4 +228TH2 G KC=0.00237 4$LC=3.88E-4 6$MC=9.15E-5 13 228TH L 1344.078 113- 228TH B 779.7 270.208 18 8.94 228THS B EAV=242.7 10 228TH G 168.53 120.0111 27M1+E2 2.7 15 -228TH2 G KC=1.8 16$LC=0.70 7$MC=0.18 3 -228TH G 824.931 250.053 6 E2 0.0145221 -228TH2 G KC=0.01074 15$LC=0.00283 4$MC=7.06E-4 10 +228TH2 G KC=1.8 16$LC=0.70 7$MC=0.18 3 +228TH G 824.931 250.053 6E2 0.0145221 +228TH2 G KC=0.01074 15$LC=0.00283 4$MC=7.06E-4 10 228TH G 947.976 240.111 10M1+E2 0.025 14 -228TH2 G KC=0.020 12$LC=0.0038 19$MC=0.0009 5 -228TH G 1157.16 150.0073 14E1+M2 0.03 3 -228TH2 G KC=0.022 20$LC=0.004 4$MC=0.0011 10 +228TH2 G KC=0.020 12$LC=0.0038 19$MC=0.0009 5 +228TH G 1157.16 150.0073 14E1+M2 0.03 3 +228TH2 G KC=0.022 20$LC=0.004 4$MC=0.0011 10 228TH G 1286.29 200.052 11E1+M2 228TH L 1416.11 6 2,3- -228TH B 707.7 270.060 8 9.34 1 +228TH B 707.7 270.060 8 9.34 1 228THS B EAV=217.3 10 -228TH G 471.77 150.034 4 E2 0.0491 7 -228TH2 G KC=0.0301 5$LC=0.01407 20$MC=0.00367 6 -228TH G 1019.88 100.022 5 +228TH G 471.77 150.034 4E2 0.0491 7 +228TH2 G KC=0.0301 5$LC=0.01407 20$MC=0.00367 6 +228TH G 1019.88 100.022 5 228TH G 1088.20 150.0062 14 228TH G 1229.42 150.0078 25 228TH L 1431.979 6 4+ -228TH B 691.8 271.6 5 7.88 +228TH B 691.8 271.6 5 7.88 228THS B EAV=211.8 10 228TH G 257.482 210.0286 19M1 1.285 18 -228TH2 G KC=1.029 15$LC=0.194 3$MC=0.0466 7 -228TH G 263.58 100.043 3 E1 0.0498 7 -228TH2 G KC=0.0397 6$LC=0.00760 11$MC=0.00182 3 -228TH G 278.80 150.031 5 E2 0.212 3 -228TH2 G KC=0.0843 12$LC=0.0937 14$MC=0.0252 4 +228TH2 G KC=1.029 15$LC=0.194 3$MC=0.0466 7 +228TH G 263.58 100.043 3E1 0.0498 7 +228TH2 G KC=0.0397 6$LC=0.00760 11$MC=0.00182 3 +228TH G 278.80 150.031 5E2 0.212 3 +228TH2 G KC=0.0843 12$LC=0.0937 14$MC=0.0252 4 228TH G 340.969 210.405 20E2+M1 -5.2 18 0.133 21 -228TH2 G KC=0.071 19$LC=0.0451 21$MC=0.0119 5 -228TH G 409.460 132.02 6 E2+M1 0.21 15 -228TH2 G KC=0.16 13$LC=0.038 16$MC=0.009 4 -228TH G 452.50 6 0.0199 19E2 0.0544 8 -228TH2 G KC=0.0326 5$LC=0.01613 23$MC=0.00422 6 -228TH G 463.002 6 4.45 24E2 0.0514 8 -228TH2 G KC=0.0312 5$LC=0.01495 21$MC=0.00390 6 -228TH G 1103.43 100.0102 11E3 0.0195 3 -228TH2 G KC=0.01377 20$LC=0.00429 6$MC=1090E-6 16 -228TH G 1245.15 6 0.110 8 M1+E2 0.013 6 -228TH2 G KC=0.010 5$LC=0.0019 9$MC=0.00046 20 -228TH G 1374.24 7 0.0196 14E2+M3 0.03 3 -228TH2 G KC=0.024 20$LC=0.005 5$MC=0.0014 12 +228TH2 G KC=0.071 19$LC=0.0451 21$MC=0.0119 5 +228TH G 409.460 132.02 6E2+M1 0.21 15 +228TH2 G KC=0.16 13$LC=0.038 16$MC=0.009 4 +228TH G 452.50 6 0.0199 19E2 0.0544 8 +228TH2 G KC=0.0326 5$LC=0.01613 23$MC=0.00422 6 +228TH G 463.002 6 4.45 24E2 0.0514 8 +228TH2 G KC=0.0312 5$LC=0.01495 21$MC=0.00390 6 +228TH G 1103.43 100.0102 11E3 0.0195 3 +228TH2 G KC=0.01377 20$LC=0.00429 6$MC=1090E-6 16 +228TH G 1245.15 6 0.110 8M1+E2 0.013 6 +228TH2 G KC=0.010 5$LC=0.0019 9$MC=0.00046 20 +228TH G 1374.24 7 0.0196 14E2+M3 0.03 3 +228TH2 G KC=0.024 20$LC=0.005 5$MC=0.0014 12 228TH L 1450.394 104- -228TH G 18.415 120.019 4 E1 6.46 10 -228TH2 G KC=$LC=3.82 6$MC=2.00 3 -228TH G 223.793 210.058 6 M1+E2 -0.18 5 1.85 4 -228TH2 G KC=1.48 4$LC=0.286 5$MC=0.0688 10 -228TH G 282.02 4 0.09 3 M1+E2 0.6 4 -228TH2 G KC=0.4 4$LC=0.12 3$MC=0.030 6 +228TH G 18.415 120.019 4E1 6.46 10 +228TH2 G LC=3.82 6$MC=2.00 3 +228TH G 223.793 210.058 6M1+E2 -0.18 5 1.85 4 +228TH2 G KC=1.48 4$LC=0.286 5$MC=0.0688 10 +228TH G 282.020 400.09 3M1+E2 0.6 4 +228TH2 G KC=0.4 4$LC=0.12 3$MC=0.030 6 228TH G 930.99 7 0.0025 23M1+E2 0.026 15 -228TH2 G KC=0.021 12$LC=0.004 2$MC=0.0010 5 -228TH G 1054.13 200.019 6 M1+E2 0.019 10 -228TH2 G KC=0.015 9$LC=0.0029 14$MC=0.0007 4 -228TH G 1451.43 150.0111 22M1+E2 0.009 4 -228TH2 G KC=0.007 3$LC=0.0013 6$MC=0.00031 13 +228TH2 G KC=0.021 12$LC=0.004 2$MC=0.0010 5 +228TH G 1054.13 200.019 6M1+E2 0.019 10 +228TH2 G KC=0.015 9$LC=0.0029 14$MC=0.0007 4 +228TH G 1451.43 150.0111 22M1+E2 0.009 4 +228TH2 G KC=0.007 3$LC=0.0013 6$MC=0.00031 13 228TH L 1531.474 6 3+ -228TH G 99.505 121.26 4 M1 3.84 6 -228TH2 G KC=$LC=2.90 4$MC=0.699 10 -228TH G 377.99 100.026 3 M1+E2 0.27 18 -228TH2 G KC=0.20 16$LC=0.049 19$MC=0.012 5 -228TH G 440.450 240.128 10M1 0.295 5 -228TH2 G KC=0.237 4$LC=0.0442 7$MC=0.01061 15 -228TH G 508.955 130.51 4 E2+M1 1.1 0.1130 16 -228TH2 G KC=0.0870 13$LC=0.0196 3$MC=0.00481 7 -228TH G 562.496 7 0.89 4 E2+M1 0.09 6 -228TH2 G KC=0.07 5$LC=0.015 8$MC=0.0038 17 +228TH G 99.505 121.26 4M1 3.84 6 +228TH2 G LC=2.90 4$MC=0.699 10 +228TH G 377.99 100.026 3M1+E2 0.27 18 +228TH2 G KC=0.20 16$LC=0.049 19$MC=0.012 5 +228TH G 440.450 240.128 10M1 0.295 5 +228TH2 G KC=0.237 4$LC=0.0442 7$MC=0.01061 15 +228TH G 508.955 130.51 4E2+M1 1.1 0.1130 16 +228TH2 G KC=0.0870 13$LC=0.0196 3$MC=0.00481 7 +228TH G 562.496 7 0.89 4E2+M1 0.09 6 +228TH2 G KC=0.07 5$LC=0.015 8$MC=0.0038 17 228TH G 1135.26 150.0102 17 -228TH G 1344.62 150.0094 20M1+E2 0.011 5 -228TH2 G KC=0.008 4$LC=0.0016 7$MC=0.00038 16 +228TH G 1344.62 150.0094 20M1+E2 0.011 5 +228TH2 G KC=0.008 4$LC=0.0016 7$MC=0.00038 16 228TH L 1539.21 9 2,3,4+ -228TH B 584.6 270.030 6 9.36 +228TH B 584.6 270.030 6 9.36 228THS B EAV=175.0 9 -228TH G 415.96 140.0138 23E1 0.0184 3 -228TH2 G KC=0.01485 21$LC=0.00267 4$MC=6.38E-4 9 +228TH G 415.96 140.0138 23E1 0.0184 3 +228TH2 G KC=0.01485 21$LC=0.00267 4$MC=6.38E-4 9 228TH G 1142.87 150.0108 22 228TH L 1588.335 144- 228TH B 535.5 278.8 23 6.77 1 228THS B EAV=158.5 9 -228TH G 56.88 5 0.020 5 E1+[M2] 1.0 5 3.6E2 22 -228TH2 G KC=$LC=2.6E2 16$MC=70 50 -228TH G 137.936 220.028 4 M1 7.52 11 -228TH2 G KC=6.00 9$LC=1.146 16$MC=0.276 4 +228TH G 56.88 5 0.020 5E1+[M2] 1.0 5 3.6E2 22 +228TH2 G LC=2.6E2 16$MC=70 50 +228TH G 137.936 220.028 4M1 7.52 11 +228TH2 G KC=6.00 9$LC=1.146 16$MC=0.276 4 228TH L 1617.78 7 2,3,4+ 228TH B 506.0 270.071 10 8.78 228THS B EAV=148.7 9 -228TH G 649.02 120.0086 9 -228TH G 1430.99 100.037 8 -228TH G 1560.02 7 0.021 5 +228TH G 649.02 120.0086 9 +228TH G 1430.99 100.037 8 +228TH G 1560.02 7 0.021 5 228TH L 1638.284 9 2+ -228TH B 485.5 271.23 6 7.48 +228TH B 485.5 271.23 6 7.48 228THS B EAV=142.0 9 -228TH G 470.21 200.014 3 E1 0.0142820 -228TH2 G KC=0.01157 17$LC=0.00205 3$MC=4.89E-4 7 -228TH G 515.12 7 0.051 6 E1 0.0118917 -228TH2 G KC=0.00966 14$LC=1694E-6 24$MC=4.03E-4 6 -228TH G 1309.76 200.020 7 E1+M2 0.020 18 -228TH2 G KC=0.016 15$LC=0.003 3$MC=0.0008 7 -228TH G 1580.531 250.62 4 M1+E2 0.007 3 -228TH2 G KC=0.0057 24$LC=0.0011 4$MC=0.00025 10 -228TH G 1638.272 230.46 3 E2 0.004106 -228TH2 G KC=0.00319 5$LC=6.08E-4 9$MC=1463E-7 21 +228TH G 470.21 200.014 3E1 0.0142820 +228TH2 G KC=0.01157 17$LC=0.00205 3$MC=4.89E-4 7 +228TH G 515.12 7 0.051 6E1 0.0118917 +228TH2 G KC=0.00966 14$LC=1694E-6 24$MC=4.03E-4 6 +228TH G 1309.76 200.020 7E1+M2 0.020 18 +228TH2 G KC=0.016 15$LC=0.003 3$MC=0.0008 7 +228TH G 1580.531 250.62 4M1+E2 0.007 3 +228TH2 G KC=0.0057 24$LC=0.0011 4$MC=0.00025 10 +228TH G 1638.272 230.46 3E2 0.00410 6 +228TH2 G KC=0.00319 5$LC=6.08E-4 9$MC=1463E-7 21 228TH L 1643.125 15(2,3)- -228TH B 480.7 270.82 3 7.64 1 +228TH B 480.7 270.82 3 7.64 1 228THS B EAV=140.4 9 -228TH G 474.79 100.023 4 M1+E2 0.14 10 -228TH2 G KC=0.11 9$LC=0.025 12$MC=0.006 3 -228TH G 520.16 3 0.070 7 M1+E2 0.11 8 -228TH2 G KC=0.09 7$LC=0.019 9$MC=0.0047 21 -228TH G 626.80 220.015 3 -228TH G 674.63 4 0.105 10M1+E2 0.06 4 -228TH2 G KC=0.05 3$LC=0.009 5$MC=0.0023 11 -228TH G 698.99 100.038 6 E2 0.0203 3 -228TH2 G KC=0.01448 21$LC=0.00436 7$MC=1103E-6 16 -228TH G 1247.10 5 0.524 24M1 0.0187 3 -228TH2 G KC=0.01505 21$LC=0.00274 4$MC=6.54E-4 10 -228TH G 1315.33 100.015 3 M1+E2 0.011 6 -228TH2 G KC=0.009 5$LC=0.0017 7$MC=0.00040 17 +228TH G 474.79 100.023 4M1+E2 0.14 10 +228TH2 G KC=0.11 9$LC=0.025 12$MC=0.006 3 +228TH G 520.160 300.070 7M1+E2 0.11 8 +228TH2 G KC=0.09 7$LC=0.019 9$MC=0.0047 21 +228TH G 626.80 220.015 3 +228TH G 674.630 400.105 10M1+E2 0.06 4 +228TH2 G KC=0.05 3$LC=0.009 5$MC=0.0023 11 +228TH G 698.99 100.038 6E2 0.0203 3 +228TH2 G KC=0.01448 21$LC=0.00436 7$MC=1103E-6 16 +228TH G 1247.10 5 0.524 24M1 0.0187 3 +228TH2 G KC=0.01505 21$LC=0.00274 4$MC=6.54E-4 10 +228TH G 1315.33 100.015 3M1+E2 0.011 6 +228TH2 G KC=0.009 5$LC=0.0017 7$MC=0.00040 17 228TH L 1645.954 123+ 228TH B 477.8 274.12 20 6.94 228THS B EAV=139.5 9 -228TH G 114.56 7 0.0102 22M1+E2 9 4 -228TH2 G KC=5 5$LC=3.2 13$MC=0.8 4 -228TH G 419.38 7 0.022 3 E1 0.0181 3 -228TH2 G KC=0.01460 21$LC=0.00263 4$MC=6.26E-4 9 -228TH G 492.29 8 0.025 3 M1+E2 0.13 9 -228TH2 G KC=0.10 8$LC=0.022 11$MC=0.0055 24 +228TH G 114.56 7 0.0102 22M1+E2 9 4 +228TH2 G KC=5 5$LC=3.2 13$MC=0.8 4 +228TH G 419.38 7 0.022 3E1 0.0181 3 +228TH2 G KC=0.01460 21$LC=0.00263 4$MC=6.26E-4 9 +228TH G 492.29 8 0.025 3M1+E2 0.13 9 +228TH2 G KC=0.10 8$LC=0.022 11$MC=0.0055 24 228TH G 523.129 220.129 10E1 0.0115317 -228TH2 G KC=0.00937 14$LC=1641E-6 23$MC=3.90E-4 6 -228TH G 555.07 160.048 6 M1+E2 -228TH G 623.48 220.012 3 M1+E2 0.07 5 -228TH2 G KC=0.06 4$LC=0.012 6$MC=0.0028 13 -228TH G 629.41 5 0.047 5 E2 0.0254 4 -228TH2 G KC=0.01754 25$LC=0.00584 9$MC=1489E-6 21 -228TH G 666.45 5 0.058 6 M1+E2 0.06 4 -228TH2 G KC=0.05 4$LC=0.010 5$MC=0.0024 11 -228TH G 677.08 100.065 6 M1+E2 0.06 4 -228TH2 G KC=0.05 3$LC=0.009 5$MC=0.0023 11 -228TH G 1250.06 5 0.065 6 -228TH G 1459.131 220.87 5 E2 0.004987 -228TH2 G KC=0.00391 6$LC=7.71E-4 11$MC=1.87E-4 3 -228TH G 1588.200 253.06 12E2 0.007 3 -228TH2 G KC=0.0057 23$LC=0.0010 4$MC=0.00025 10 +228TH2 G KC=0.00937 14$LC=1641E-6 23$MC=3.90E-4 6 +228TH G 555.07 160.048 6M1+E2 +228TH G 623.48 220.012 3M1+E2 0.07 5 +228TH2 G KC=0.06 4$LC=0.012 6$MC=0.0028 13 +228TH G 629.41 5 0.047 5E2 0.0254 4 +228TH2 G KC=0.01754 25$LC=0.00584 9$MC=1489E-6 21 +228TH G 666.45 5 0.058 6M1+E2 0.06 4 +228TH2 G KC=0.05 4$LC=0.010 5$MC=0.0024 11 +228TH G 677.08 100.065 6M1+E2 0.06 4 +228TH2 G KC=0.05 3$LC=0.009 5$MC=0.0023 11 +228TH G 1250.06 5 0.065 6 +228TH G 1459.131 220.87 5E2 0.00498 7 +228TH2 G KC=0.00391 6$LC=7.71E-4 11$MC=1.87E-4 3 +228TH G 1588.200 253.06 12E2 0.007 3 +228TH2 G KC=0.0057 23$LC=0.0010 4$MC=0.00025 10 228TH L 1682.81 3 2,3(),4+ -228TH B 441.0 271.21 4 7.35 +228TH B 441.0 271.21 4 7.35 228THS B EAV=127.5 9 -228TH G 660.1 3 0.0054 3 M1+E2 0.06 4 -228TH2 G KC=0.05 4$LC=0.010 5$MC=0.0024 12 -228TH G 1495.904 160.92 3 E2 0.004777 -228TH2 G KC=0.00374 6$LC=7.32E-4 11$MC=1769E-7 25 -228TH G 1625.09 4 0.270 23E2+M3 0.020 17 -228TH2 G KC=0.016 13$LC=0.003 3$MC=0.0008 7 +228TH G 660.10 300.0054 3M1+E2 0.06 4 +228TH2 G KC=0.05 4$LC=0.010 5$MC=0.0024 12 +228TH G 1495.904 160.92 3E2 0.00477 7 +228TH2 G KC=0.00374 6$LC=7.32E-4 11$MC=1769E-7 25 +228TH G 1625.090 400.270 23E2+M3 0.020 17 +228TH2 G KC=0.016 13$LC=0.003 3$MC=0.0008 7 228TH L 1683.82 5 (4)- -228TH B 440.0 270.20 3 8.13 1 +228TH B 440.0 270.20 3 8.13 1 228THS B EAV=127.2 9 -228TH G 457.18 150.016 3 M1+E2 0.16 11 -228TH2 G KC=0.12 10$LC=0.028 13$MC=0.007 3 -228TH G 1164.55 7 0.067 7 M1+E2 0.015 8 -228TH2 G KC=0.012 6$LC=0.0023 11$MC=0.00055 24 -228TH G 1287.77 8 0.109 25M1+E2 0.012 6 -228TH2 G KC=0.009 5$LC=0.0018 8$MC=0.00042 18 +228TH G 457.18 150.016 3M1+E2 0.16 11 +228TH2 G KC=0.12 10$LC=0.028 13$MC=0.007 3 +228TH G 1164.55 7 0.067 7M1+E2 0.015 8 +228TH2 G KC=0.012 6$LC=0.0023 11$MC=0.00055 24 +228TH G 1287.77 8 0.109 25M1+E2 0.012 6 +228TH2 G KC=0.009 5$LC=0.0018 8$MC=0.00042 18 228TH L 1688.394 112,3+ 228TH B 435.4 272.50 16 7.02 228THS B EAV=125.7 9 -228TH G 42.46 5 0.009 3 M1 46.3 7 -228TH2 G KC=$LC=35.0 5$MC=8.43 13 -228TH G 671.95 8 0.027 8 +228TH G 42.46 5 0.009 3M1 46.3 7 +228TH2 G LC=35.0 5$MC=8.43 13 +228TH G 671.95 8 0.027 8 228TH G 813.88 100.0073 17M1+E2 0.036 22 -228TH2 G KC=0.029 18$LC=0.006 3$MC=0.0014 7 +228TH2 G KC=0.029 18$LC=0.006 3$MC=0.0014 7 228TH G 1501.59 5 0.513 17 -228TH G 1630.618 201.52 6 M1+E2 0.007 3 -228TH2 G KC=0.0053 22$LC=0.0010 4$MC=0.00023 9 +228TH G 1630.618 201.52 6M1+E2 0.007 3 +228TH2 G KC=0.0053 22$LC=0.0010 4$MC=0.00023 9 228TH L 1724.283 6 2+ -228TH B 399.5 271.93 8 7.01 +228TH B 399.5 271.93 8 7.01 228THS B EAV=114.3 9 -228TH G 497.64 100.0062 19M2 0.581 9 -228TH2 G KC=0.437 7$LC=0.1074 15$MC=0.0268 4 -228TH G 548.73 110.024 4 M1+E2 0.10 7 -228TH2 G KC=0.08 6$LC=0.017 8$MC=0.0041 18 -228TH G 570.88 4 0.19 5 M1 0.1472 21 -228TH2 G KC=0.1182 17$LC=0.0219 3$MC=0.00525 8 +228TH G 497.64 100.0062 19M2 0.581 9 +228TH2 G KC=0.437 7$LC=0.1074 15$MC=0.0268 4 +228TH G 548.73 110.024 4M1+E2 0.10 7 +228TH2 G KC=0.08 6$LC=0.017 8$MC=0.0041 18 +228TH G 570.880 400.19 5M1 0.1472 21 +228TH2 G KC=0.1182 17$LC=0.0219 3$MC=0.00525 8 228TH G 701.742 150.181 15M1 0.0850 12 -228TH2 G KC=0.0684 10$LC=0.01261 18$MC=0.00302 5 -228TH G 755.313 9 1.03 4 M1 0.070 1 -228TH2 G KC=0.0563 8$LC=0.01036 15$MC=0.00248 4 -228TH G 1537.89 100.049 6 E2+M3 0.023 19 -228TH2 G KC=0.018 15$LC=0.004 4$MC=0.0010 8 -228TH G 1666.514 130.173 9 M1 0.0089513 -228TH2 G KC=0.00702 10$LC=1269E-6 18$MC=3.03E-4 5 -228TH G 1724.19 5 0.030 4 E1+M2 +228TH2 G KC=0.0684 10$LC=0.01261 18$MC=0.00302 5 +228TH G 755.313 9 1.03 4M1 0.070 1 +228TH2 G KC=0.0563 8$LC=0.01036 15$MC=0.00248 4 +228TH G 1537.89 100.049 6E2+M3 0.023 19 +228TH2 G KC=0.018 15$LC=0.004 4$MC=0.0010 8 +228TH G 1666.514 130.173 9M1 0.0089513 +228TH2 G KC=0.00702 10$LC=1269E-6 18$MC=3.03E-4 5 +228TH G 1724.19 5 0.030 4E1+M2 228TH L 1735.450 25(4)+ 228TH B 388.4 270.149 11 8.08 228THS B EAV=110.7 9 -228TH G 1217.03 100.022 4 -228TH G 1357.81 150.021 5 -228TH G 1548.65 6 0.040 5 -228TH G 1677.66 6 0.057 6 +228TH G 1217.03 100.022 4 +228TH G 1357.81 150.021 5 +228TH G 1548.65 6 0.040 5 +228TH G 1677.66 6 0.057 6 228TH L 1743.89 3 4+ 228TH B 379.9 270.378 16 7.65 228THS B EAV=108.1 9 -228TH G 399.83 140.031 4 E1 0.0200 3 -228TH2 G KC=0.01611 23$LC=0.00291 4$MC=6.96E-4 10 -228TH G 1347.50 150.016 4 E1+M2 0.019 17 -228TH2 G KC=0.015 14$LC=0.003 3$MC=0.0007 7 -228TH G 1365.71 120.014 3 E2+M3 0.03 3 -228TH2 G KC=0.025 21$LC=0.006 5$MC=0.0014 12 -228TH G 1415.55 140.022 5 E3 0.0114116 -228TH2 G KC=0.00849 12$LC=0.00218 3$MC=5.43E-4 8 -228TH G 1557.13 7 0.173 9 E2+M1 1.2 2 0.0070 6 -228TH2 G KC=0.0055 5$LC=0.00102 8$MC=2.45E-4 19 -228TH G 1686.22 110.094 7 E2 0.003916 -228TH2 G KC=0.00303 5$LC=5.73E-4 8$MC=1378E-7 20 +228TH G 399.83 140.031 4E1 0.0200 3 +228TH2 G KC=0.01611 23$LC=0.00291 4$MC=6.96E-4 10 +228TH G 1347.50 150.016 4E1+M2 0.019 17 +228TH2 G KC=0.015 14$LC=0.003 3$MC=0.0007 7 +228TH G 1365.71 120.014 3E2+M3 0.03 3 +228TH2 G KC=0.025 21$LC=0.006 5$MC=0.0014 12 +228TH G 1415.55 140.022 5E3 0.0114116 +228TH2 G KC=0.00849 12$LC=0.00218 3$MC=5.43E-4 8 +228TH G 1557.13 7 0.173 9E2+M1 1.2 2 0.0070 6 +228TH2 G KC=0.0055 5$LC=0.00102 8$MC=2.45E-4 19 +228TH G 1686.22 110.094 7E2 0.00391 6 +228TH2 G KC=0.00303 5$LC=5.73E-4 8$MC=1378E-7 20 228TH L 1758.24 122,3,4+ -228TH B 365.6 270.060 8 8.39 +228TH B 365.6 270.060 8 8.39 228THS B EAV=103.6 9 -228TH G 326.04 200.035 6 E2 0.1315 19 -228TH2 G KC=0.0618 9$LC=0.0513 8$MC=0.01372 20 +228TH G 326.04 200.035 6E2 0.1315 19 +228TH2 G KC=0.0618 9$LC=0.0513 8$MC=0.01372 20 228TH G 1571.55 200.0059 17 228TH G 1700.62 200.0105 25 228TH L 1760.218 242,3()+ 228TH B 363.6 270.139 12 8.02 228THS B EAV=103.0 9 -228TH G 737.74 5 0.039 5 M1+E2 0.05 3 -228TH2 G KC=0.037 24$LC=0.007 4$MC=0.0018 9 -228TH G 791.43 9 0.010 3 M1+E2 0.039 23 -228TH2 G KC=0.031 19$LC=0.006 3$MC=0.0015 7 -228TH G 1573.389 240.034 4 E2 0.004387 -228TH2 G KC=0.00342 5$LC=0.00066 1$MC=1592E-7 23 -228TH G 1702.40 8 0.055 7 E2+M3 0.018 15 -228TH2 G KC=0.014 11$LC=0.0030 25$MC=0.0007 6 +228TH G 737.74 5 0.039 5M1+E2 0.05 3 +228TH2 G KC=0.037 24$LC=0.007 4$MC=0.0018 9 +228TH G 791.43 9 0.010 3M1+E2 0.039 23 +228TH2 G KC=0.031 19$LC=0.006 3$MC=0.0015 7 +228TH G 1573.389 240.034 4E2 0.00438 7 +228TH2 G KC=0.00342 5$LC=0.00066 1$MC=1592E-7 23 +228TH G 1702.40 8 0.055 7E2+M3 0.018 15 +228TH2 G KC=0.014 11$LC=0.0030 25$MC=0.0007 6 228TH L 1795.9 1 3,4+ -228TH B 327.9 270.035 6 8.48 +228TH B 327.9 270.035 6 8.48 228THS B EAV=91.9 8 -228TH G 1276.72 100.015 3 -228TH G 1738.46 5 0.018 4 +228TH G 1276.72 100.015 3 +228TH G 1738.46 5 0.018 4 228TH L 1797.65 8 2+ -228TH B 326.2 270.051 8 8.3 +228TH B 326.2 270.051 8 8.3 228THS B EAV=91.4 8 -228TH G 1401.52 100.013 3 E1+M2 0.017 15 -228TH2 G KC=0.013 12$LC=0.0026 24$MC=0.0006 6 -228TH G 1469.74 150.021 5 E1+M2 0.015 14 -228TH2 G KC=0.012 11$LC=0.0023 21$MC=0.0006 5 -228TH G 1740.5 3 0.011 4 -228TH G 1797.5 5 0.0022 8 E1+M2 0.009 8 -228TH2 G KC=0.007 7$LC=0.0014 13$MC=0.0003 3 +228TH G 1401.52 100.013 3E1+M2 0.017 15 +228TH2 G KC=0.013 12$LC=0.0026 24$MC=0.0006 6 +228TH G 1469.74 150.021 5E1+M2 0.015 14 +228TH2 G KC=0.012 11$LC=0.0023 21$MC=0.0006 5 +228TH G 1740.5 3 0.011 4 +228TH G 1797.5 5 0.0022 8E1+M2 0.009 8 +228TH2 G KC=0.007 7$LC=0.0014 13$MC=0.0003 3 228TH L 1892.996 173+ -228TH B 230.8 270.109 8 7.5 +228TH B 230.8 270.109 8 7.5 228THS B EAV=62.8 8 -228TH G 666.45 5 0.0068 7 E1 0.0072211 -228TH2 G KC=0.00590 9$LC=1007E-6 14$MC=2.39E-4 4 -228TH G 870.47 7 0.046 5 M1 0.0481 7 -228TH2 G KC=0.0387 6$LC=0.0071 1$MC=1699E-6 24 +228TH G 666.45 5 0.0068 7E1 0.0072211 +228TH2 G KC=0.00590 9$LC=1007E-6 14$MC=2.39E-4 4 +228TH G 870.47 7 0.046 5M1 0.0481 7 +228TH2 G KC=0.0387 6$LC=0.0071 1$MC=1699E-6 24 228TH G 1706.17 7 0.0089 12M1+E2 0.42 40 0.0078 12 -228TH2 G KC=0.0061 10$LC=0.00110 16$MC=0.00026 4 -228TH G 1835.29 100.038 4 E2+M1 2.9 3 0.0038210 -228TH2 G KC=0.00291 8$LC=5.36E-4 14$MC=1.28E-4 4 +228TH2 G KC=0.0061 10$LC=0.00110 16$MC=0.00026 4 +228TH G 1835.29 100.038 4E2+M1 2.9 3 0.0038210 +228TH2 G KC=0.00291 8$LC=5.36E-4 14$MC=1.28E-4 4 228TH L 1899.95 4 2+ -228TH B 223.9 270.069 8 7.65 +228TH B 223.9 270.069 8 7.65 228THS B EAV=60.8 8 -228TH G 877.38 7 0.014 3 M1+E2 0.030 18 -228TH2 G KC=0.024 15$LC=0.0047 23$MC=0.0011 6 -228TH G 930.99 7 0.004 1 +228TH G 877.38 7 0.014 3M1+E2 0.030 18 +228TH2 G KC=0.024 15$LC=0.0047 23$MC=0.0011 6 +228TH G 930.99 7 0.004 1 228TH G 1713.49 200.0057 11E2+M3 0.018 14 -228TH2 G KC=0.014 11$LC=0.0029 24$MC=0.0007 6 -228TH G 1842.15 8 0.037 6 M1+E2 -0.86 14 0.0055 4 -228TH2 G KC=0.00420 25$LC=0.00076 5$MC=1.82E-4 11 -228TH G 1900.16 200.0030 6 E1+M2 0.008 7 -228TH2 G KC=0.006 6$LC=0.0012 11$MC=0.0003 3 +228TH2 G KC=0.014 11$LC=0.0029 24$MC=0.0007 6 +228TH G 1842.15 8 0.037 6M1+E2 -0.86 14 0.0055 4 +228TH2 G KC=0.00420 25$LC=0.00076 5$MC=1.82E-4 11 +228TH G 1900.16 200.0030 6E1+M2 0.008 7 +228TH2 G KC=0.006 6$LC=0.0012 11$MC=0.0003 3 228TH L 1906.64 10(2)+ -228TH B 217.2 270.025 5 8.05 +228TH B 217.2 270.025 5 8.05 228THS B EAV=58.8 8 -228TH G 490.33 150.0116 25E2 0.0447 7 -228TH2 G KC=0.0280 4$LC=0.01242 18$MC=0.00323 5 -228TH G 1074.73 150.011 4 +228TH G 490.33 150.0116 25E2 0.0447 7 +228TH2 G KC=0.0280 4$LC=0.01242 18$MC=0.00323 5 +228TH G 1074.73 150.011 4 228TH L 1928.57 6 3+ -228TH B 195.2 270.061 8 7.52 +228TH B 195.2 270.061 8 7.52 228THS B EAV=52.5 8 -228TH G 168.53 120.0025 7 M1+E2 2.7 15 -228TH2 G KC=1.8 16$LC=0.70 7$MC=0.18 3 +228TH G 168.53 120.0025 7M1+E2 2.7 15 +228TH2 G KC=1.8 16$LC=0.70 7$MC=0.18 3 228TH G 389.32 130.0108 17M1+E2 0.25 17 -228TH2 G KC=0.19 15$LC=0.044 18$MC=0.011 4 +228TH2 G KC=0.19 15$LC=0.044 18$MC=0.011 4 228TH G 1742.1 3 0.0084 25M1+E2 228TH G 1870.82 9 0.0257 24M1+E2 0.0051 18 -228TH2 G KC=0.0038 14$LC=0.00070 24$MC=0.00017 6 +228TH2 G KC=0.0038 14$LC=0.00070 24$MC=0.00017 6 228TH L 1937.16 9 2,3,4+ -228TH B 186.6 270.053 6 7.52 +228TH B 186.6 270.053 6 7.52 228THS B EAV=50.0 8 -228TH G 397.95 100.029 3 -228TH G 1062.57 150.011 4 -228TH G 1750.58 200.0084 9 -228TH G 1879.6 3 0.0013 5 +228TH G 397.95 100.029 3 +228TH G 1062.57 150.011 4 +228TH G 1750.58 200.0084 9 +228TH G 1879.6 3 0.0013 5 228TH L 1944.895 113+ 228TH B 178.9 270.307 22 6.7 228THS B EAV=47.8 8 -228TH G 356.7 3 0.0178 21E1+M2 0.5 0.8 8 -228TH2 G KC=0.6 6$LC=0.17 17$MC=0.04 5 -228TH G 718.30 3 0.019 4 E1 0.006289 -228TH2 G KC=0.00513 8$LC=8.70E-4 13$MC=2.06E-4 3 -228TH G 776.51 3 0.020 6 -228TH G 791.43 9 0.014 4 M1 0.0618 9 -228TH2 G KC=0.0498 7$LC=0.00915 13$MC=0.00219 3 +228TH G 356.70 300.0178 21E1+M2 0.5 0.8 8 +228TH2 G KC=0.6 6$LC=0.17 17$MC=0.04 5 +228TH G 718.300 300.019 4E1 0.00628 9 +228TH2 G KC=0.00513 8$LC=8.70E-4 13$MC=2.06E-4 3 +228TH G 776.510 300.020 6 +228TH G 791.43 9 0.014 4M1 0.0618 9 +228TH2 G KC=0.0498 7$LC=0.00915 13$MC=0.00219 3 228TH G 853.96 8 0.0124 20M1+E2 0.032 19 -228TH2 G KC=0.025 16$LC=0.0050 25$MC=0.0012 6 -228TH G 975.98 5 0.052 6 M1 0.0356 5 -228TH2 G KC=0.0287 4$LC=0.00524 8$MC=1254E-6 18 -228TH G 1000.68 100.0054 3 -228TH G 1758.11 5 0.036 4 E2+M1 -9.1 0.003716 -228TH2 G KC=0.00285 4$LC=5.33E-4 8$MC=1281E-7 18 -228TH G 1887.13 5 0.094 7 E2+M1 0.0050 17 -228TH2 G KC=0.0038 13$LC=0.00068 23$MC=0.00016 6 +228TH2 G KC=0.025 16$LC=0.0050 25$MC=0.0012 6 +228TH G 975.98 5 0.052 6M1 0.0356 5 +228TH2 G KC=0.0287 4$LC=0.00524 8$MC=1254E-6 18 +228TH G 1000.68 100.0054 3 +228TH G 1758.11 5 0.036 4E2+M1 -9.1 0.00371 6 +228TH2 G KC=0.00285 4$LC=5.33E-4 8$MC=1281E-7 18 +228TH G 1887.13 5 0.094 7E2+M1 0.0050 17 +228TH2 G KC=0.0038 13$LC=0.00068 23$MC=0.00016 6 228TH L 1958.72 222+ -228TH B 165.1 270.0038 8 8.5 +228TH B 165.1 270.0038 8 8.5 228THS B EAV=43.9 8 -228TH G 1772.2 3 0.0019 5 E2+M3 0.016 13 -228TH2 G KC=0.013 10$LC=0.0027 22$MC=0.0007 6 -228TH G 1958.4 3 0.0016 5 E1+M2 +228TH G 1772.20 300.0019 5E2+M3 0.016 13 +228TH2 G KC=0.013 10$LC=0.0027 22$MC=0.0007 6 +228TH G 1958.40 300.0016 5E1+M2 228TH L 1964.98 7 2,3,4+ 228TH B 158.8 270.0132 14 7.91 228THS B EAV=42.2 8 228TH G 1907.14 110.0124 13 228TH L 1987.46 104+ -228TH B 136.3 270.07 4 7 +228TH B 136.3 270.07 4 7 228THS B EAV=35.9 8 -228TH G 1017.94 200.03 3 E2+M3 0.07 7 -228TH2 G KC=0.05 5$LC=0.014 12$MC=0.003 3 -228TH G 1609.44 150.0081 17E2 0.004226 -228TH2 G KC=0.00329 5$LC=6.30E-4 9$MC=1518E-7 22 -228TH G 1800.9 2 0.0046 8 +228TH G 1017.94 200.03 3E2+M3 0.07 7 +228TH2 G KC=0.05 5$LC=0.014 12$MC=0.003 3 +228TH G 1609.44 150.0081 17E2 0.00422 6 +228TH2 G KC=0.00329 5$LC=6.30E-4 9$MC=1518E-7 22 +228TH G 1800.90 200.0046 8 228TH G 1929.78 200.0208 14E2+M3 0.013 10 -228TH2 G KC=0.010 8$LC=0.0021 17$MC=0.0005 5 +228TH2 G KC=0.010 8$LC=0.0021 17$MC=0.0005 5 228TH L 2010.11 5 2,3,(4)+ 228TH B 113.7 270.238 15 6.2 228THS B EAV=29.7 8 228TH G 372.59 3 0.0070 17E2 0.0902 13 -228TH2 G KC=0.0475 7$LC=0.0315 5$MC=0.00834 12 -228TH G 887.26 100.029 3 M1+E2 0.029 17 -228TH2 G KC=0.023 14$LC=0.0046 22$MC=0.0011 6 -228TH G 919.03 120.028 3 -228TH G 1040.94 150.047 10E2+M3 0.07 6 -228TH2 G KC=0.05 5$LC=0.013 12$MC=0.003 3 -228TH G 1823.22 100.046 5 -228TH G 1952.37 100.062 5 E2+M3 0.013 10 -228TH2 G KC=0.010 8$LC=0.0020 17$MC=0.0005 4 +228TH2 G KC=0.0475 7$LC=0.0315 5$MC=0.00834 12 +228TH G 887.26 100.029 3M1+E2 0.029 17 +228TH2 G KC=0.023 14$LC=0.0046 22$MC=0.0011 6 +228TH G 919.03 120.028 3 +228TH G 1040.94 150.047 10E2+M3 0.07 6 +228TH2 G KC=0.05 5$LC=0.013 12$MC=0.003 3 +228TH G 1823.22 100.046 5 +228TH G 1952.37 100.062 5E2+M3 0.013 10 +228TH2 G KC=0.010 8$LC=0.0020 17$MC=0.0005 4 228TH L 2013.6 3 2,3,4+ 228TH B 110.2 270.0032 10 8.03 228THS B EAV=28.7 7 -228TH G 1826.8 3 0.0022 8 -228TH G 1955.9 5 0.0008 3 +228TH G 1826.80 300.0022 8 +228TH G 1955.9 5 0.0008 3 228TH L 2022.84 10 + -228TH B 101.0 270.061 6 6.64 +228TH B 101.0 270.061 6 6.64 228THS B EAV=26.2 7 228TH G 384.47 9 0.0070 17E2 0.0828 12 -228TH2 G KC=0.0447 7$LC=0.0282 4$MC=0.00745 11 -228TH G 1053.11 200.014 4 M1+E2 0.019 10 -228TH2 G KC=0.015 9$LC=0.0029 14$MC=0.0007 4 -228TH G 1148.17 140.0062 14M1+E2 0.015 8 -228TH2 G KC=0.012 7$LC=0.0023 11$MC=0.00057 25 -228TH G 1190.83 200.0065 17M1+E2 0.014 7 -228TH2 G KC=0.011 6$LC=0.0021 10$MC=0.00052 23 +228TH2 G KC=0.0447 7$LC=0.0282 4$MC=0.00745 11 +228TH G 1053.11 200.014 4M1+E2 0.019 10 +228TH2 G KC=0.015 9$LC=0.0029 14$MC=0.0007 4 +228TH G 1148.17 140.0062 14M1+E2 0.015 8 +228TH2 G KC=0.012 7$LC=0.0023 11$MC=0.00057 25 +228TH G 1190.83 200.0065 17M1+E2 0.014 7 +228TH2 G KC=0.011 6$LC=0.0021 10$MC=0.00052 23 228TH G 1965.22 120.0223 22M1+E2 0.0046 15 -228TH2 G KC=0.0034 12$LC=0.00062 20$MC=0.00015 5 +228TH2 G KC=0.0034 12$LC=0.00062 20$MC=0.00015 5 228TH L 2029.84 161,2+ -228TH B 94.0 270.026 4 6.91 2 +228TH B 94.0 270.026 4 6.91 2 228THS B EAV=24.3 7 -228TH G 939.89 150.009 3 +228TH G 939.89 150.009 3 228TH G 1013.55 130.0097 16 -228TH G 1972.0 3 0.0038 8 -228TH G 2029.4 5 0.0019 5 E1+M2 0.007 6 -228TH2 G KC=0.005 5$LC=0.0010 9$MC=0.00024 22 +228TH G 1972.00 300.0038 8 +228TH G 2029.4 5 0.0019 5E1+M2 0.007 6 +228TH2 G KC=0.005 5$LC=0.0010 9$MC=0.00024 22 228TH L 2036.99 172,3,4+ 228TH B 86.8 270.0069 11 7.38 228THS B EAV=22.4 8 -228TH G 1850.17 200.0046 8 -228TH G 1979.3 3 0.0019 5 +228TH G 1850.17 200.0046 8 +228TH G 1979.30 300.0019 5 228TH L 2123.1 3 (2)+ 228TH B 0.7 270.0047 11 3.3 228THS B EAV=0.18 68 -228TH G 1795.13 6 0.0022 8 -228TH G 1936.3 3 0.0022 6 +228TH G 1795.13 6 0.0022 8 +228TH G 1936.30 300.0022 6 diff --git a/HEN_HOUSE/spectra/lnhb/Ag-108.txt b/HEN_HOUSE/spectra/lnhb/Ag-108.txt index 8268793bc..c46dd7a2d 100644 --- a/HEN_HOUSE/spectra/lnhb/Ag-108.txt +++ b/HEN_HOUSE/spectra/lnhb/Ag-108.txt @@ -3,56 +3,56 @@ 108PD2 H TYP=Full$AUT=V.Chisté$CUT=31-JAN-2005$ 108PD C Evaluation history: Type=Update;Author=V.Chisté;Cutoff date=25-AUG-2006 108PD2C Type=Full;Author=V.Chisté;Cutoff date=31-JAN-2005 -108PD T Auger electrons and ^X ray energies and emission intensities: -108PD T {U Energy (keV)} {U Intensity } {U Line } +108PD T Auger electrons and X ray energies and emission intensities: +108PD T {U Energy (keV)} {U Intensity} {U Line} 108PD T -108PD T 21.0203 0.44 3 XKA2 -108PD T 21.1774 0.84 6 XKA1 +108PD T 21.0203 0.44 3 XKA2 +108PD T 21.1774 0.84 6 XKA1 108PD T -108PD T 23.7914 |] XKB3 -108PD T 23.819 |] 0.230 16 XKB1 -108PD T 24.013 |] XKB5II +108PD T 23.7914 |] XKB3 +108PD T 23.819 |] 0.230 16 XKB1 +108PD T 24.013 |] XKB5II 108PD T -108PD T 24.2994 |] XKB2 -108PD T 24.344 |] 0.0391 30 XKB4 +108PD T 24.2994 |] XKB2 +108PD T 24.344 |] 0.0391 30 XKB4 108PD T 108PD T -108PD T 17.032-17.884 |] KLL AUGER -108PD T 20.032-21.176 |] 0.341 25 ^KLX AUGER -108PD T 23.011-24.347 |] KXY AUGER -108PD T 1.7-3.6 1.97 4 L AUGER +108PD T 17.032-17.884 |] KLL AUGER +108PD T 20.032-21.176 |] 0.341 25 KLX AUGER +108PD T 23.011-24.347 |] KXY AUGER +108PD T 1.7-3.6 1.97 4 L AUGER 108AG P 0.0 1+ 2.382 M 11 1922 6 108PD N 4.049E1 4.049E1 0.0247 4.049E1 108PD L 0 0+ -108PD E 0.28 2 1.73 124.7 +108PD E 0.28 21.73 124.7 108PD2 E EAV=401 3$CK=0.8644 14$CL=0.1092 10$CM=0.0221 4$CN=0.0043 2$CO=0 0 108PD L 433.938 5 2+ 23.9 PS 7 -108PD E 0.0026 3 0.19 8 5.46 +108PD E 0.0026 30.19 85.46 108PD2 E EAV=212 3$CK=0.8636 14$CL=0.1098 10$CM=0.0223 4$CN=0.0043 2$CO=0 0 -108PD G 433.938 5 0.46 7 [E2] 0.0090927 -108PD2 G KC=0.00784 24$LC=1021E-6 31$MC=1.92E-4 6 +108PD G 433.938 5 0.46 7[E2] 0.0090927 +108PD2 G KC=0.00784 24$LC=1021E-6 31$MC=1.92E-4 6 108PD L 931.07 122+ 6.2 PS 4 108PD G 497.13 120.00152 40 -108PD G 931.07 120.00048 8 +108PD G 931.07 120.00048 8 108PD L 1052.80 5 0+ 4.0 PS 4 108PD E 0.243 394.89 -108PD2 E EAV= $CK=0.8611 14$CL=0.1118 11$CM=0.0227 5$CN=0.0044 2$CO=0 0 +108PD2 E CK=0.8611 14$CL=0.1118 11$CM=0.0227 5$CN=0.0044 2$CO=0 0 108PD G 618.86 5 0.245 39 108PD L 1314.2 1 0+ -108PD E 0.0038 6 6.37 -108PD2 E EAV= $CK=0.8585 14$CL=0.1138 11$CM=0.0232 5$CN=0.0045 2$CO=0 0 +108PD E 0.0038 66.37 +108PD2 E CK=0.8585 14$CL=0.1138 11$CM=0.0232 5$CN=0.0045 2$CO=0 0 108PD G 383.13 160.00083 30 108PD G 880.26 100.00298 48 108PD L 1441.16 5 2+ 4.8 PS 108PD E 0.0170 215.46 -108PD2 E EAV= $CK=0.8560 14$CL=0.1157 11$CM=0.0237 5$CN=0.0046 2$CO=0 0 -108PD G 388.36 7 0.0017 6 +108PD2 E CK=0.8560 14$CL=0.1157 11$CM=0.0237 5$CN=0.0046 2$CO=0 0 +108PD G 388.36 7 0.0017 6 108PD G 1007.22 5 0.0126 20 108PD G 1441.15 5 0.00269 44[E2] 4.64E-414 108PD2 G KC=4.07E-4 12$LC=4.69E-5 14$MC=8.78E-6 26 108PD L 1539.95 7 (1,2)+ 108PD E 0.00224 276.12 -108PD2 E EAV= $CK=0.8529 15$CL=0.1181 11$CM=0.0242 5$CN=0.0047 3$CO=0 0 +108PD2 E CK=0.8529 15$CL=0.1181 11$CM=0.0242 5$CN=0.0047 3$CO=0 0 108PD G 1106.01 7 0.00130 22 108PD G 1539.94 7 0.00094 16 @@ -61,32 +61,32 @@ 108CD2 H TYP=Full$AUT=V.Chisté$CUT=31-JAN-2005$ 108CD C Evaluation history: Type=Update;Author=V.Chisté;Cutoff date=25-AUG-2006 108CD2C Type=Full;Author=V.Chisté;Cutoff date=31-JAN-2005 -108CD T Auger electrons and ^X ray energies and emission intensities: -108CD T {U Energy (keV)} {U Intensity } {U Line } +108CD T Auger electrons and X ray energies and emission intensities: +108CD T {U Energy (keV)} {U Intensity} {U Line} 108CD T -108CD T 22.9843 0.00127 6 XKA2 -108CD T 23.1738 0.00239 11 XKA1 +108CD T 22.9843 0.00127 6 XKA2 +108CD T 23.1738 0.00239 11 XKA1 108CD T -108CD T 26.0615 |] XKB3 -108CD T 26.0958 |] 0.00067 4 XKB1 -108CD T 26.304 |] XKB5II +108CD T 26.0615 |] XKB3 +108CD T 26.0958 |] 0.00067 4 XKB1 +108CD T 26.304 |] XKB5II 108CD T -108CD T 26.644 |] XKB2 -108CD T 26.702 |] 0.000121 7 XKB4 +108CD T 26.644 |] XKB2 +108CD T 26.702 |] 0.000121 7 XKB4 108CD T 108CD T -108CD T 18.556-19.507 |] KLL AUGER -108CD T 21.873-23.172 |] 0.00084 5 ^KLX AUGER -108CD T 25.171-26.707 |] KXY AUGER -108CD T 1.8-4 0.00535 7 L AUGER +108CD T 18.556-19.507 |] KLL AUGER +108CD T 21.873-23.172 |] 0.00084 5 KLX AUGER +108CD T 25.171-26.707 |] KXY AUGER +108CD T 1.8-4 0.00535 7 L AUGER 108AG P 0.0 1+ 2.382 M 11 1649 8 108CD N 1.025E0 1.025E0 0.9753 1.025E0 108CD L 0 0+ -108CD B 1649 8 95.9 3 4.43 +108CD B 1649 8 95.9 3 4.43 108CDS B EAV=628 4 108CD L 632.98 5 2+ 6.86 PS 7 108CD B 1016 8 1.63 26 5.35 108CDS B EAV=355 3 108CD G 632.98 5 1.62 26E2 0.0034710 -108CD2 G KC=0.00300 9$LC=3.80E-4 11$MC=7.30E-5 22 +108CD2 G KC=0.00300 9$LC=3.80E-4 11$MC=7.30E-5 22 diff --git a/HEN_HOUSE/spectra/lnhb/Ag-108m.txt b/HEN_HOUSE/spectra/lnhb/Ag-108m.txt index 480fa1a91..f07966df7 100644 --- a/HEN_HOUSE/spectra/lnhb/Ag-108m.txt +++ b/HEN_HOUSE/spectra/lnhb/Ag-108m.txt @@ -1,65 +1,65 @@ 108AG 108AG IT DECAY (438 Y) 108AG C References: 2004Sc04 -108AG T Auger electrons and ^X ray energies and emission intensities: -108AG T {U Energy (keV)} {U Intensity } {U Line } +108AG T Auger electrons and X ray energies and emission intensities: +108AG T {U Energy (keV)} {U Intensity} {U Line} 108AG T -108AG T 21.9906 0.49 4 XKA2 -108AG T 22.16317 0.93 7 XKA1 +108AG T 21.9906 0.49 4 XKA2 +108AG T 22.16317 0.93 7 XKA1 108AG T -108AG T 24.9118 |] XKB3 -108AG T 24.9427 |] 0.256 19 XKB1 -108AG T 25.146 |] XKB5II +108AG T 24.9118 |] XKB3 +108AG T 24.9427 |] 0.256 19 XKB1 +108AG T 25.146 |] XKB5II 108AG T -108AG T 25.4567 |] XKB2 -108AG T 25.512 |] 0.045 4 XKB4 +108AG T 25.4567 |] XKB2 +108AG T 25.512 |] 0.045 4 XKB4 108AG T 108AG T -108AG T 17.79-18.69 |] KLL AUGER -108AG T 20.945-22.16 |] 0.349 27 ^KLX AUGER -108AG T 24.079-25.507 |] KXY AUGER -108AG T 1.9-3.8 8.60 7 L AUGER +108AG T 17.79-18.69 |] KLL AUGER +108AG T 20.945-22.16 |] 0.349 27 KLX AUGER +108AG T 24.079-25.507 |] KXY AUGER +108AG T 1.9-3.8 8.60 7 L AUGER 108AG P 109.440 7 6+ 438 Y 9 108AG N 1.099E1 1.099E1 9.100001 1.099E1 108AG L 0 1+ 2.382 M 11 108AG L 79.131 3 2- 1 NS -108AG G 79.131 3 6.9 5 E1 0.310 9 -108AG2 G KC=0.269 8$LC=0.0336 10$MC=0.00633 19 +108AG G 79.131 3 6.9 5E1 0.310 9 +108AG2 G KC=0.269 8$LC=0.0336 10$MC=0.00633 19 108AG L 109.440 7 6+ 438 Y 8 108AG G 30.309 8 2.15E-5 18M4 4.25E5 13 -108AG2 G KC=9.77E3 29$LC=3.2E5 1$MC=8.20E4 25 +108AG2 G KC=9.77E3 29$LC=3.2E5 1$MC=8.20E4 25 108PD 108AG EC DECAY (438 Y) 108PD C References: 2004Sc04 -108PD T Auger electrons and ^X ray energies and emission intensities: -108PD T {U Energy (keV)} {U Intensity } {U Line } +108PD T Auger electrons and X ray energies and emission intensities: +108PD T {U Energy (keV)} {U Intensity} {U Line} 108PD T -108PD T 21.0203 18.38 18 XKA2 -108PD T 21.1774 34.72 30 XKA1 +108PD T 21.0203 18.38 18 XKA2 +108PD T 21.1774 34.72 30 XKA1 108PD T -108PD T 23.7914 |] XKB3 -108PD T 23.819 |] 9.53 12 XKB1 -108PD T 24.013 |] XKB5II +108PD T 23.7914 |] XKB3 +108PD T 23.819 |] 9.53 12 XKB1 +108PD T 24.013 |] XKB5II 108PD T -108PD T 24.2994 |] XKB2 -108PD T 24.344 |] 1.62 6 XKB4 +108PD T 24.2994 |] XKB2 +108PD T 24.344 |] 1.62 6 XKB4 108PD T 108PD T -108PD T 17.032-17.884 |] KLL AUGER -108PD T 20.032-21.176 |] 14.1 4 ^KLX AUGER -108PD T 23.011-24.347 |] KXY AUGER -108PD T 1.7-3.6 83.1 4 L AUGER +108PD T 17.032-17.884 |] KLL AUGER +108PD T 20.032-21.176 |] 14.1 4 KLX AUGER +108PD T 23.011-24.347 |] KXY AUGER +108PD T 1.7-3.6 83.1 4 L AUGER 108AG P 109.440 7 6+ 438 Y 9 1922 6 108PD N 1.10E0 1.10E0 0.909 1.10E0 108PD L 0 0+ 108PD L 433.938 5 2+ -108PD G 433.938 5 90.1 6 [E2] 0.0090927 -108PD2 G KC=0.00784 24$LC=1021E-6 31$MC=1.92E-4 6 +108PD G 433.938 5 90.1 6[E2] 0.0090927 +108PD2 G KC=0.00784 24$LC=1021E-6 31$MC=1.92E-4 6 108PD L 1048.25 5 4+ 108PD G 614.276 4 90.5 16E2 0.0033510 -108PD2 G KC=0.00291 9$LC=3.60E-4 11$MC=6.77E-5 20 +108PD2 G KC=0.00291 9$LC=3.60E-4 11$MC=6.77E-5 20 108PD L 1771.162 116+ -108PD E 90.9 6 9.24 -108PD2 E EAV= $CK=0.8457 15$CL=0.1238 12$CM=0.0256 5$CN=0.0050 3$CO=0 0 -108PD G 722.907 1090.8 16E2 0.002197 -108PD2 G KC=0.00191 6$LC=2.31E-4 7$MC=4.34E-5 13 +108PD E 90.9 69.24 +108PD2 E CK=0.8457 15$CL=0.1238 12$CM=0.0256 5$CN=0.0050 3$CO=0 0 +108PD G 722.907 1090.8 16E2 0.00219 7 +108PD2 G KC=0.00191 6$LC=2.31E-4 7$MC=4.34E-5 13 diff --git a/HEN_HOUSE/spectra/lnhb/Ag-110.txt b/HEN_HOUSE/spectra/lnhb/Ag-110.txt index b3dd713f8..c0e8e94d0 100644 --- a/HEN_HOUSE/spectra/lnhb/Ag-110.txt +++ b/HEN_HOUSE/spectra/lnhb/Ag-110.txt @@ -1,92 +1,92 @@ 110PD 110AG EC DECAY (24.56 S) -110PD T Auger electrons and ^X ray energies and emission intensities: -110PD T {U Energy (keV)} {U Intensity } {U Line } +110PD T Auger electrons and X ray energies and emission intensities: +110PD T {U Energy (keV)} {U Intensity} {U Line} 110PD T -110PD T 21.0203 0.060 12 XKA2 -110PD T 21.1774 0.114 23 XKA1 +110PD T 21.0203 0.060 12 XKA2 +110PD T 21.1774 0.114 23 XKA1 110PD T -110PD T 23.7914 |] XKB3 -110PD T 23.819 |] 0.032 7 XKB1 -110PD T 24.013 |] XKB5II +110PD T 23.7914 |] XKB3 +110PD T 23.819 |] 0.032 7 XKB1 +110PD T 24.013 |] XKB5II 110PD T -110PD T 24.2994 |] XKB2 -110PD T 24.344 |] 0.0054 10 XKB4 +110PD T 24.2994 |] XKB2 +110PD T 24.344 |] 0.0054 10 XKB4 110PD T 110AG P 0.0 1+ 24.56 S 11 892 11 110PD N 3.333E2 3.333E2 0.003 3.333E2 110PD L 0 - STABLE -110PD E 0.30 6 4.1 -110PD2 E EAV= $CK=0.862 $CL=0.111 $CM=0.027 $CN= $CO= +110PD E 0.30 64.1 +110PD2 E CK=0.862 $CL=0.111 $CM=0.027 110CD 110AG B- DECAY (24.56 S) -110CD T Auger electrons and ^X ray energies and emission intensities: -110CD T {U Energy (keV)} {U Intensity } {U Line } +110CD T Auger electrons and X ray energies and emission intensities: +110CD T {U Energy (keV)} {U Intensity} {U Line} 110CD T -110CD T 22.9843 0.0032 3 XKA2 -110CD T 23.1738 0.0061 6 XKA1 +110CD T 22.9843 0.0032 3 XKA2 +110CD T 23.1738 0.0061 6 XKA1 110CD T -110CD T 26.0615 |] XKB3 -110CD T 26.0958 |] 0.00169 15 XKB1 -110CD T 26.304 |] XKB5I +110CD T 26.0615 |] XKB3 +110CD T 26.0958 |] 0.00169 15 XKB1 +110CD T 26.304 |] XKB5I 110CD T -110CD T 26.644 |] XKB2 -110CD T 26.702 |] 0.00031 3 XKB4 +110CD T 26.644 |] XKB2 +110CD T 26.702 |] 0.00031 3 XKB4 110CD T 110AG P 0.0 1+ 24.56 S 11 2892.2 16 110CD N 1.003E0 1.003E0 0.997 1.003E0 110CD L 0 0+ STABLE -110CD B 2892.2 1695.2 4 4.66 +110CD B 2892.2 1695.2 4 4.66 110CDS B EAV=1199.0 8 110CD L 657.7622 112+ 5.39 PS 7 -110CD B 2234.4 164.4 4 5.53 +110CD B 2234.4 164.4 4 5.53 110CDS B EAV=893.8 8 -110CD G 657.7600 114.6 4 E2 0.003189 -110CD2 G KC=0.00272 8$LC=0.00034 1$MC= +110CD G 657.7600 114.6 4E2 0.00318 9 +110CD2 G KC=0.00272 8$LC=0.00034 1 110CD L 1473.27 200+ -110CD B 1419.2 170.038 3 6.81 +110CD B 1419.2 170.038 3 6.81 110CDS B EAV=527.1 7 -110CD G 815.50 2 0.039 4 E2 0.001856 -110CD2 G KC=0.00159 5$LC=0.00019 1$MC= +110CD G 815.50 2 0.039 4E2 0.00185 6 +110CD2 G KC=0.00159 5$LC=0.00019 1 110CD L 1475.7894 162+ 0.68 PS 10 110CD B 1416.5 160.0099 10 7.39 110CDS B EAV=526.0 7 -110CD G 818.0244 180.0092 9 M1+E2 -1.36 7 0.001946 -110CD2 G KC=0.00167 5$LC=0.00020 1$MC= -110CD G 1475.7792 230.0037 6 E2 0.0051 2 -110CD2 G KC=0.0044 1$LC=7000E-8 0$MC= +110CD G 818.0244 180.0092 9M1+E2 -1.36 7 0.00194 6 +110CD2 G KC=0.00167 5$LC=0.00020 1 +110CD G 1475.7792 230.0037 6E2 0.0051 2 +110CD2 G KC=0.0044 1$LC=0.00007 110CD L 1731.77 200+ -110CD B 1160.7 170.0009 5 8.1 +110CD B 1160.7 170.0009 5 8.1 110CDS B EAV=415.9 7 -110CD G 1074.0 2 0.0009 5 E2 0.0098 3 -110CD2 G KC=0.0085 3$LC=0.00010 1$MC= +110CD G 1074.0 2 0.0009 5E2 0.0098 3 +110CD2 G KC=0.0085 3$LC=0.00010 1 110CD L 1783.469 172+ 110CD B 1108.8 170.0121 17 6.89 110CDS B EAV=394.1 7 -110CD G 1125.699 200.0156 14M1+E2 0.33 8 0.001053 -110CD2 G KC=0.00089 30$LC=0.00010 1$MC= -110CD G 1783.46 3 0.0046 8 E2 +110CD G 1125.699 200.0156 14M1+E2 0.33 8 0.00105 3 +110CD2 G KC=0.00089 30$LC=0.00010 1 +110CD G 1783.46 3 0.0046 8E2 110CD L 2078.77 200+ 110CD B 813.6 170.0076 14 6.6 110CDS B EAV=273.3 7 110CD G 295.3 2 0.0078 16(E1) 0.0080524 -110CD2 G KC=0.00703 21$LC=0.00083 3$MC=0.00016 1 +110CD2 G KC=0.00703 21$LC=0.00083 3$MC=0.00016 1 110CD L 2079.27 203-+ 0.72 PS 30 -110CD B 813.3 170.0022 5 7.54 2 +110CD B 813.3 170.0022 5 7.54 2 110CDS B EAV=290.7 7 -110CD G 1421.5 2 0.0023 5 0.0026 1 -110CD2 G KC=0.0023 1$LC=0.00003 1$MC= +110CD G 1421.5 2 0.0023 5 0.0026 1 +110CD2 G KC=0.0023 1$LC=0.00003 1 110CD L 2287.68 202+ -110CD B 604.8 170.0022 5 6.68 +110CD B 604.8 170.0022 5 6.68 110CDS B EAV=192.8 6 -110CD G 1629.9 2 0.0023 5 E2(+M1) 0.06 3 +110CD G 1629.9 2 0.0023 5E2(+M1) 0.06 3 110CD L 2332.08 200+ -110CD B 560.4 170.0072 5 6.05 +110CD B 560.4 170.0072 5 6.05 110CDS B EAV=176.4 6 -110CD G 1674.3 2 0.007 1 +110CD G 1674.3 2 0.007 1 110CD L 2662.14 150+ -110CD B 230.1 160.0063 8 4.83 +110CD B 230.1 160.0063 8 4.83 110CDS B EAV=64.2 5 -110CD G 1186.3 2 0.0028 5 [E2] 0.0079 2 -110CD2 G KC=0.0069 2$LC=0.00009 1$MC= -110CD G 2004.40 2 0.0037 6 E2 +110CD G 1186.3 2 0.0028 5[E2] 0.0079 2 +110CD2 G KC=0.0069 2$LC=0.00009 1 +110CD G 2004.40 2 0.0037 6E2 diff --git a/HEN_HOUSE/spectra/lnhb/Ag-110m.txt b/HEN_HOUSE/spectra/lnhb/Ag-110m.txt index 454f77ca6..afb21ca46 100644 --- a/HEN_HOUSE/spectra/lnhb/Ag-110m.txt +++ b/HEN_HOUSE/spectra/lnhb/Ag-110m.txt @@ -1,184 +1,183 @@ 110AG 110AG IT DECAY (249.78 D) -110AG T Auger electrons and ^X ray energies and emission intensities: -110AG T {U Energy (keV)} {U Intensity } {U Line } +110AG T Auger electrons and X ray energies and emission intensities: +110AG T {U Energy (keV)} {U Intensity} {U Line} 110AG T -110AG T 21.9906 0.198 12 XKA2 -110AG T 22.16317 0.372 22 XKA1 +110AG T 21.9906 0.198 12 XKA2 +110AG T 22.16317 0.372 22 XKA1 110AG T -110AG T 24.9118 |] XKB3 -110AG T 24.9427 |] 0.103 7 XKB1 -110AG T 25.146 |] XKB5II +110AG T 24.9118 |] XKB3 +110AG T 24.9427 |] 0.103 7 XKB1 +110AG T 25.146 |] XKB5II 110AG T -110AG T 25.4567 |] XKB2 -110AG T 25.512 |] 0.0179 12 XKB4 +110AG T 25.4567 |] XKB2 +110AG T 25.512 |] 0.0179 12 XKB4 110AG T 110AG P 117.59 5 6+ 249.78 D 2 110AG N 7.353E1 7.353E1 0.0136 7.353E1 -110AG G 264.25 6 0.0060 6 +110AG G 264.25 6 0.0060 6 110AG G 356.43 100.00425 30 -110AG G 647.8 4 0.018 5 +110AG G 647.8 4 0.018 5 110AG G 666.6 5 0.028 14 -110AG G 676.58 100.14 1 +110AG G 676.58 100.14 1 110AG G 1050.5 5 0.0076 10 -110AG G 1465.6 1 0.0018 2 -110AG G 1572.4 2 0.0011 3 +110AG G 1465.6 1 0.0018 2 +110AG G 1572.4 2 0.0011 3 110AG L 0 0+ 24.56 S 11 110AG L 1.113 2- 660 NS 40 110AG G 1.113 E1 110AG L 117.59 5 6+ 249.78 D 2 -110AG G 116.48 5 0.0080 3 M4 168 5 -110AG2 G KC=105 3$LC=50.1 15$MC=11.0000 0 +110AG G 116.48 5 0.0080 3M4 168 5 +110AG2 G KC=105 3$LC=50.1 15$MC=11 110CD 110AG B- DECAY (249.78 D) -110CD T Auger electrons and ^X ray energies and emission intensities: -110CD T {U Energy (keV)} {U Intensity } {U Line } +110CD T Auger electrons and X ray energies and emission intensities: +110CD T {U Energy (keV)} {U Intensity} {U Line} 110CD T -110CD T 22.9843 0.153 9 XKA2 -110CD T 23.1738 0.288 16 XKA1 +110CD T 22.9843 0.153 9 XKA2 +110CD T 23.1738 0.288 16 XKA1 110CD T -110CD T 26.0615 |] XKB3 -110CD T 26.0958 |] 0.080 5 XKB1 -110CD T 26.304 |] XKB5II +110CD T 26.0615 |] XKB3 +110CD T 26.0958 |] 0.080 5 XKB1 +110CD T 26.304 |] XKB5II 110CD T -110CD T 26.644 |] XKB2 -110CD T 26.702 |] 0.0146 9 XKB4 +110CD T 26.644 |] XKB2 +110CD T 26.702 |] 0.0146 9 XKB4 110CD T 110AG P 117.59 5 6+ 249.78 D 2 2892.2 16 110CD N 1.014E0 1.014E0 0.9864 1.014E0 -110CD G 264.25 6 0.0060 6 +110CD G 264.25 6 0.0060 6 110CD G 356.43 100.00425 30 -110CD G 647.8 4 0.018 5 +110CD G 647.8 4 0.018 5 110CD G 666.6 5 0.028 14 -110CD G 676.58 100.14 1 +110CD G 676.58 100.14 1 110CD G 1050.5 5 0.0076 10 -110CD G 1465.6 1 0.0018 2 -110CD G 1572.4 2 0.0011 3 +110CD G 1465.6 1 0.0018 2 +110CD G 1572.4 2 0.0011 3 110CD L 0 0+ STABLE 110CD L 657.7621 112+ 5.39 PS 7 -110CD G 657.7600 1194.38 8 E2 0.003189 -110CD2 G KC=0.00272 8$LC=0.00034 1$MC= +110CD G 657.7600 1194.38 8E2 0.00318 9 +110CD2 G KC=0.00272 8$LC=0.00034 1 110CD L 1475.7898 232+ 0.68 PS 10 -110CD G 818.0244 187.33 4 M1+E2 -1.36 7 0.001946 -110CD2 G KC=0.00167 5$LC=0.00020 1$MC= -110CD G 1475.7792 234.03 5 E2 0.000512 -110CD2 G KC=0.00044 1$LC=$MC= +110CD G 818.0244 187.33 4M1+E2 -1.36 7 0.00194 6 +110CD2 G KC=0.00167 5$LC=0.00020 1 +110CD G 1475.7792 234.03 5E2 0.00051 2 +110CD2 G KC=0.00044 1 110CD L 1542.4440 174+ 0.73 PS 9 -110CD G 884.6781 1374.0 12E2 0.001525 -110CD2 G KC=0.00131 4$LC=0.00016 1$MC= +110CD G 884.6781 1374.0 12E2 0.00152 5 +110CD2 G KC=0.00131 4$LC=0.00016 1 110CD L 1783.46 3 2+ -110CD G 1125.699 200.0304 14M1+E2 0.33 8 0.001033 -110CD2 G KC=0.00089 30$LC=0.00010 1$MC= -110CD G 1783.46 3 0.0101 5 E2 +110CD G 1125.699 200.0304 14M1+E2 0.33 8 0.00103 3 +110CD2 G KC=0.00089 30$LC=0.00010 1 +110CD G 1783.46 3 0.0101 5E2 110CD L 2078.69 7 3- 0.72 PS 30 -110CD G 603.08 100.011 8 E1 0.0013940 -110CD2 G KC=0.00121 4$LC=0.00014 10$MC= -110CD G 1420.07 5 0.026 4 E1 0.000261 -110CD2 G KC=0.00023 1$LC=$MC= +110CD G 603.08 100.011 8E1 0.0013940 +110CD2 G KC=0.00121 4$LC=0.00014 10 +110CD G 1420.07 5 0.026 4E1 0.00026 1 +110CD2 G KC=0.00023 1 110CD L 2162.8012 253+ -110CD G 620.3553 172.72 8 M1+E2 -0.50 4 0.0039712 -110CD2 G KC=0.00342 10$LC=0.00041 1$MC= -110CD G 687.0091 186.45 3 M1+E2 -1.76 6 0.002929 -110CD2 G KC=0.00251 8$LC=0.00031 1$MC= -110CD G 1505.028 2 13.16 16M1+E2 -1.21 4 0.000451 -110CD2 G KC=0.00045 1$LC=$MC= +110CD G 620.3553 172.72 8M1+E2 -0.50 4 0.0039712 +110CD2 G KC=0.00342 10$LC=0.00041 1 +110CD G 687.0091 186.45 3M1+E2 -1.76 6 0.00292 9 +110CD2 G KC=0.00251 8$LC=0.00031 1 +110CD G 1505.028 2 13.16 16M1+E2 -1.21 4 0.00045 1 +110CD2 G KC=0.00045 1 110CD L 2220.0680 264+ -110CD G 677.6217 1210.56 6 M1+E2 0.36 2 0.0032410 -110CD2 G KC=0.00280 8$LC=0.00033 1$MC= -110CD G 744.2755 184.71 3 E2(+M3) 0 0.002327 -110CD2 G KC=0.00199 6$LC=0.00025 1$MC= -110CD G 1562.2940 181.21 3 E2(+M3) -0.10 15 +110CD G 677.6217 1210.56 6M1+E2 0.36 2 0.0032410 +110CD2 G KC=0.00280 8$LC=0.00033 1 +110CD G 744.2755 184.71 3E2(+M3) 0 0.00232 7 +110CD2 G KC=0.00199 6$LC=0.00025 1 +110CD G 1562.2940 181.21 3E2(+M3) -0.10 15 110CD L 2250.547 134+ -110CD B 759.3 160.06 5 11.5 2 +110CD B 759.3 160.06 5 11.5 2 110CDS B EAV=251.9 7 110CD G 467.03 4 0.0249 19(E2) 0.0081324 -110CD2 G KC=0.00699 21$LC=0.00092 3$MC=0.00018 1 -110CD G 708.128 200.23 5 M1+E2 -0.15 9 0.002959 -110CD2 G KC=0.00255 8$LC=0.00030 1$MC= -110CD G 774.7 1 0.006 3 (E2) 0.002106 -110CD2 G KC=0.00180 5$LC=0.00022 1$MC= -110CD G 1592.80 150.0207 8 (E2) +110CD2 G KC=0.00699 21$LC=0.00092 3$MC=0.00018 1 +110CD G 708.128 200.23 5M1+E2 -0.15 9 0.00295 9 +110CD2 G KC=0.00255 8$LC=0.00030 1 +110CD G 774.7 1 0.006 3(E2) 0.00210 6 +110CD2 G KC=0.00180 5$LC=0.00022 1 +110CD G 1592.80 150.0207 8(E2) 110CD L 2287.53 15 + -110CD G 1629.75 150.0040 5 M1+E2 0.06 3 +110CD G 1629.75 150.0040 5M1+E2 0.06 3 110CD L 2356.6 2 1+,2++ -110CD G 1698.8 2 0.0017 3 +110CD G 1698.8 2 0.0017 3 110CD L 2433.20 4 3+ 110CD G 957.35 100.0093 19M1+E2 -0.9 7 0.0013910 -110CD2 G KC=0.00120 9$LC=0.00014 1$MC= -110CD G 1775.41 4 0.0065 3 M1+E2 +110CD2 G KC=0.00120 9$LC=0.00014 1 +110CD G 1775.41 4 0.0065 3M1+E2 110CD L 2479.933 4 6+ -110CD B 529.9 1630.8 3 8.28 +110CD B 529.9 1630.8 3 8.28 110CDS B EAV=165.3 6 110CD G 229.423 230.0119 14 -110CD G 937.485 3 34.51 27E2(+M3) -0.07 0.001334 -110CD2 G KC=0.00115 3$LC=0.00014 1$MC= +110CD G 937.485 3 34.51 27E2(+M3) -0.07 0.00133 4 +110CD2 G KC=0.00115 3$LC=0.00014 1 110CD L 2539.675 8 5- 0.62 PS 28 -110CD B 470.1 160.060 4 10.8 1 +110CD B 470.1 160.060 4 10.8 1 110CDS B EAV=143.9 6 -110CD G 997.243 150.128 4 E1(+M2) -0.30 46 0.0007 9 -110CD2 G KC=$LC=$MC= +110CD G 997.243 150.128 4E1(+M2) -0.30 46 0.0007 9 110CD L 2561.281 8 4+ -110CD G 341.3 2 0.0022 5 -110CD G 1018.95 8 0.0141 7 M1+E2 -0.56 35 -110CD G 1085.447 140.072 4 E2 0.000963 -110CD2 G KC=0.00083 3$LC=0.00010 1$MC= -110CD G 1903.52 4 0.0159 7 +110CD G 341.3 2 0.0022 5 +110CD G 1018.95 8 0.0141 7M1+E2 -0.56 35 +110CD G 1085.447 140.072 4E2 0.00096 3 +110CD2 G KC=0.00083 3$LC=0.00010 1 +110CD G 1903.52 4 0.0159 7 110CD L 2659.852 115- -110CD B 349.9 160.031 4 10.7 1 +110CD B 349.9 160.031 4 10.7 1 110CDS B EAV=102.6 6 -110CD G 120.23 3 0.0169 9 M1(+E2) -0.13 33 0.29 8 -110CD2 G KC=0.25 6$LC=0.032 18$MC=0.006 4 -110CD G 409.4 5 6300E-6 0 E1(+M2) -0.029 23 0.0034610 -110CD2 G KC=0.00303 9$LC=0.00036 1$MC= -110CD G 1117.46 3 0.0488 9 E1(+M2) 0.021 44 0.000401 -110CD2 G KC=0.00034 1$LC=$MC= +110CD G 120.23 3 0.0169 9M1(+E2) -0.13 33 0.29 8 +110CD2 G KC=0.25 6$LC=0.032 18$MC=0.006 4 +110CD G 409.4 5 0.0063 E1(+M2) -0.029 23 0.0034610 +110CD2 G KC=0.00303 9$LC=0.00036 1 +110CD G 1117.46 3 0.0488 9E1(+M2) 0.021 44 0.00040 1 +110CD2 G KC=0.00034 1 110CD L 2662.41 103+ -110CD G 1186.7 1 0.00160 5 -110CD G 2004.65 100.0012 4 +110CD G 1186.7 1 0.00160 5 +110CD G 2004.65 100.0012 4 110CD L 2705.668 104+ -110CD G 1163.14 8 0.074 24M1+E2 0.03 0.000973 -110CD2 G KC=0.00084 3$LC=9.8E-5 3$MC= +110CD G 1163.14 8 0.074 24M1+E2 0.03 0.00097 3 +110CD2 G KC=0.00084 3$LC=9.8E-5 3 110CD L 2707.397 8 4+ -110CD G 544.55 5 0.018 3 M1+E2 0.0054 2 -110CD2 G KC=0.00464 19$LC=0.00057 2$MC= -110CD G 1164.94 9 0.043 3 M1+E2 0.0 3 0.000903 -110CD2 G KC=0.00077 7$LC=$MC= +110CD G 544.55 5 0.018 3M1+E2 0.0054 2 +110CD2 G KC=0.00464 19$LC=0.00057 2 +110CD G 1164.94 9 0.043 3M1+E2 0.0 3 0.00090 3 +110CD2 G KC=0.00077 7 110CD L 2793.417 7 4+ -110CD G 360.23 8 0.008 5 +110CD G 360.23 8 0.008 5 110CD G 572.8 2 0.0173 13 -110CD G 630.62 6 0.033 5 +110CD G 630.62 6 0.033 5 110CD G 714.9 1 0.0092 24 -110CD G 1251.04 4 0.026 3 +110CD G 1251.04 4 0.026 3 110CD L 2842.51 105- 110CD B 167.3 160.0252 10 9.7 1 110CDS B EAV=45.4 5 -110CD G 409.4 5 6300E-6 0 E1(+M2) -0.029 23 0.0034610 -110CD2 G KC=0.00303 9$LC=0.00036 1$MC= -110CD G 1300.05 100.0189 7 E1(+M2) 0.0 1 0.000301 -110CD2 G KC=0.00026 1$LC=$MC= +110CD G 409.4 5 0.0063 E1(+M2) -0.029 23 0.0034610 +110CD2 G KC=0.00303 9$LC=0.00036 1 +110CD G 1300.05 100.0189 7E1(+M2) 0.0 1 0.00030 1 +110CD2 G KC=0.00026 1 110CD L 2876.803 126+ 110CD B 133.0 160.392 18 8.2 110CDS B EAV=35.5 5 -110CD G 396.895 230.037 4 +110CD G 396.895 230.037 4 110CD G 626.258 100.214 17E2 0.0036111 -110CD2 G KC=0.00309 9$LC=0.00039 1$MC= -110CD G 1334.326 170.141 5 E2 0.000622 -110CD2 G KC=0.00054 2$LC=$MC= +110CD2 G KC=0.00309 9$LC=0.00039 1 +110CD G 1334.326 170.141 5E2 0.00062 2 +110CD2 G KC=0.00054 2 110CD L 2926.746 3 5+ -110CD B 83.1 1667.5 6 5.36 +110CD B 83.1 1667.5 6 5.36 110CDS B EAV=21.6 5 110CD G 133.333 7 0.0736 16 -110CD G 219.348 8 0.072 5 +110CD G 219.348 8 0.072 5 110CD G 221.079 100.068 10 -110CD G 266.913 120.041 4 -110CD G 365.448 100.092 5 -110CD G 387.073 9 0.0518 9 -110CD G 446.812 3 3.65 5 M1+E2 -0.38 2 0.0089 3 -110CD2 G KC=0.00772 23$LC=0.00094 3$MC=0.00018 1 +110CD G 266.913 120.041 4 +110CD G 365.448 100.092 5 +110CD G 387.073 9 0.0518 9 +110CD G 446.812 3 3.65 5M1+E2 -0.38 2 0.0089 3 +110CD2 G KC=0.00772 23$LC=0.00094 3$MC=0.00018 1 110CD G 493.43 100.0095 11 -110CD G 706.6760 1516.48 8 M1+E2 -1.42 7 0.002758 -110CD2 G KC=0.00237 7$LC=0.00029 1$MC= -110CD G 763.9424 1722.31 9 E2+M3 -0.10 15 0.002309 -110CD2 G KC=0.00198 10$LC=0.00024 2$MC= -110CD G 1384.2931 2024.7 5 M1+E2 -0.44 2 0.000652 -110CD2 G KC=0.00056 2$LC=$MC= +110CD G 706.6760 1516.48 8M1+E2 -1.42 7 0.00275 8 +110CD2 G KC=0.00237 7$LC=0.00029 1 +110CD G 763.9424 1722.31 9E2+M3 -0.10 15 0.00230 9 +110CD2 G KC=0.00198 10$LC=0.00024 2 +110CD G 1384.2931 2024.7 5M1+E2 -0.44 2 0.00065 2 +110CD2 G KC=0.00056 2 diff --git a/HEN_HOUSE/spectra/lnhb/Al-26.txt b/HEN_HOUSE/spectra/lnhb/Al-26.txt index fa375020c..bd84e3381 100644 --- a/HEN_HOUSE/spectra/lnhb/Al-26.txt +++ b/HEN_HOUSE/spectra/lnhb/Al-26.txt @@ -1,30 +1,30 @@ 26MG 26AL EC DECAY (717E3 Y) - 26MG T Auger electrons and ^X ray energies and emission intensities: - 26MG T {U Energy (keV)} {U Intensity } {U Line } + 26MG T Auger electrons and X ray energies and emission intensities: + 26MG T {U Energy (keV)} {U Intensity} {U Line} 26MG T - 26MG T 1.2536 0.160 6 XKA2 - 26MG T 1.2536 0.318 11 XKA1 + 26MG T 1.2536 0.160 6 XKA2 + 26MG T 1.2536 0.318 11 XKA1 26MG T 26MG T 26MG T 26MG T - 26MG T 1.102-1.182 |] KLL AUGER - 26MG T 1.214-1.252 |] 16.22 22 ^KLX AUGER - 26MG T 1.301-1.301 |] KXY AUGER - 26MG T 0.0359-0.0359 0.0000022 18 L AUGER + 26MG T 1.102-1.182 |] KLL AUGER + 26MG T 1.214-1.252 |] 16.22 22 KLX AUGER + 26MG T 1.301-1.301 |] KXY AUGER + 26MG T 0.0359-0.0359 2.2E-6 18 L AUGER 26AL P 0.0 5+ 717E3 Y 24 4004.19 6 26MG N 1.0 1.0 1 1.0 26MG L 0 0+ STABLE 26MG L 1808.72 7 2+ 476 FS 12 26MG E 81.73 2115.51 1315.7 2U - 26MG2 E EAV=543.29 4$CK=0.915 4$CL=0.079 4$CM=0.0059 12$CN= $CO= - 26MG G 1808.65 7 99.76 4 E2 6330E-90 - 26MG2 G KC=5890E-9 0$LC=352E-9 0$MC= + 26MG2 E EAV=543.29 4$CK=0.915 4$CL=0.079 4$CM=0.0059 12 + 26MG G 1808.65 7 99.76 4E2 6.33E-6 + 26MG2 G KC=5.89E-6 $LC=3.52E-7 26MG L 2938.41 132+ 141 FS 8 - 26MG E 5.4E-7 4 2.74 2014.6 2U - 26MG2 E EAV=24.78 8$CK=0.915 4$CL=0.079 4$CM=0.0059 12$CN= $CO= - 26MG G 1129.67 102.5 2 M1+E2 -0.12 2 1250E-80 - 26MG2 G KC=1150E-8 0$LC=754E-9 0$MC= - 26MG G 2938 1 0.24 4 E2 2350E-90 - 26MG2 G KC=2160E-9 0$LC=149E-9 0$MC= + 26MG E 5.4E-7 42.74 2014.6 2U + 26MG2 E EAV=24.78 8$CK=0.915 4$CL=0.079 4$CM=0.0059 12 + 26MG G 1129.67 102.5 2M1+E2 -0.12 2 1.25E-5 + 26MG2 G KC=1.15E-5 $LC=7.54E-7 + 26MG G 2938 1 0.24 4E2 2.35E-6 + 26MG2 G KC=2.16E-6 $LC=1.49E-7 diff --git a/HEN_HOUSE/spectra/lnhb/Am-241.txt b/HEN_HOUSE/spectra/lnhb/Am-241.txt index 2e63a42b5..962899042 100644 --- a/HEN_HOUSE/spectra/lnhb/Am-241.txt +++ b/HEN_HOUSE/spectra/lnhb/Am-241.txt @@ -17,400 +17,400 @@ 237NP10C 1994Le37, 1994Bl12, 1995Ak01, 1996Jo28, 1998Ab43, 1998Ko61, 1998Ya17, 237NP11C 2000Ho27, 2000He14, 2001Sc08, 2003Au03, 2005Iw01, 2006Ba41, 2008Le07, 237NP12C 2008Go10, 2008Ki07 -237NP T Auger electrons and ^X ray energies and emission intensities: -237NP T {U Energy (keV)} {U Intensity } {U Line } +237NP T Auger electrons and X ray energies and emission intensities: +237NP T {U Energy (keV)} {U Intensity} {U Line} 237NP T -237NP T 97.069 0.001134 30 XKA2 -237NP T 101.059 0.00181 5 XKA1 +237NP T 97.069 0.00113430 XKA2 +237NP T 101.059 0.00181 5 XKA1 237NP T -237NP T 113.303 |] XKB3 -237NP T 114.234 |] 0.000658 21 XKB1 -237NP T 114.912 |] XKB5II +237NP T 113.303 |] XKB3 +237NP T 114.234 |] 0.00065821 XKB1 +237NP T 114.912 |] XKB5II 237NP T -237NP T 117.463 |] XKB2 -237NP T 117.876 |] 0.000226 8 XKB4 -237NP T 118.429 |] XKO23 +237NP T 117.463 |] XKB2 +237NP T 117.876 |] 0.000226 8 XKB4 +237NP T 118.429 |] XKO23 237NP T -237NP T 11.89-22.2 37.66 17 XL (total) -237NP T 11.89 0.844 9 XLL -237NP T 13.76-13.944 13.02 10 XLA -237NP T 15.876 0.384 20 XLC -237NP T 16.13-17.79 18.58 13 XLB -237NP T 20.12-22.2 4.83 30 XLG +237NP T 11.89-22.2 37.66 17 XL (total) +237NP T 11.89 0.844 9 XLL +237NP T 13.76-13.944 13.02 10 XLA +237NP T 15.876 0.384 20 XLC +237NP T 16.13-17.79 18.58 13 XLB +237NP T 20.12-22.2 4.83 30 XLG 237NP T -237NP T 73.5-83.13 |] KLL AUGER -237NP T 90.36-97.28 |] 0.000114 16 ^KLX AUGER -237NP T 107.1-114.58 |] KXY AUGER -237NP T 6.04-13.52 33.4 17 L AUGER +237NP T 73.5-83.13 |] KLL AUGER +237NP T 90.36-97.28 |] 0.00011416 KLX AUGER +237NP T 107.1-114.58 |] KXY AUGER +237NP T 6.04-13.52 33.4 17 L AUGER 241AM P 0.0 5/2- 432.6 Y 6 5637.82 12 237NP N 1.0 1.0 1 1.0 -237NP G 32.183 0.0174 4 +237NP G 32.183 0.0174 4 237NP G 57.85 5 0.0052 15 -237NP G 106.42 5 1500E-8 0 +237NP G 106.42 5 0.000015 237NP G 128.05 237NP G 136.7 237NP G 156.4 3 -237NP G 190.4 2.2E-6 5 -237NP G 201.70 14800E-9 0 -237NP G 270.63 155E-7 2 -237NP G 271.54 1.44E-6 5 -237NP G 324.69 1.8E-6 3 -237NP G 329.69 1.1E-6 2 -237NP G 350.71 1.39E-6 5 -237NP G 374.83 3.13E-6 6 -237NP G 389.0 3 490E-9 0 +237NP G 190.4 2.2E-6 5 +237NP G 201.70 148E-7 +237NP G 270.63 155E-7 2 +237NP G 271.54 1.44E-6 5 +237NP G 324.69 1.8E-6 3 +237NP G 329.69 1.1E-6 2 +237NP G 350.71 1.39E-6 5 +237NP G 374.83 3.13E-6 6 +237NP G 389.0 3 4.9E-7 237NP G 390.61 5 5.73E-6 10 -237NP G 411.27 1.8E-7 4 -237NP G 429.9 1 1.09E-6 5 -237NP G 440.63 5.6E-7 3 -237NP G 442.81 7 3.31E-6 8 -237NP G 486.05 1.05E-6 6 -237NP G 494.39 1.0E-7 2 -237NP G 501.39 1.4E-7 2 -237NP G 525.14 1.6E-7 3 -237NP G 532.44 8E-8 2 -237NP G 548.15 5E-8 2 -237NP G 555.25 9E-8 2 -237NP G 582.89 1.01E-6 6 -237NP G 600.26 2.2E-7 3 -237NP G 636.9 2.1E-7 3 -237NP G 693.46 3.54E-6 8 +237NP G 411.27 1.8E-7 4 +237NP G 429.9 1 1.09E-6 5 +237NP G 440.63 5.6E-7 3 +237NP G 442.81 7 3.31E-6 8 +237NP G 486.05 1.05E-6 6 +237NP G 494.39 1.0E-7 2 +237NP G 501.39 1.4E-7 2 +237NP G 525.14 1.6E-7 3 +237NP G 532.44 8E-8 2 +237NP G 548.15 5E-8 2 +237NP G 555.25 9E-8 2 +237NP G 582.89 1.01E-6 6 +237NP G 600.26 2.2E-7 3 +237NP G 636.9 2.1E-7 3 +237NP G 693.46 3.54E-6 8 237NP G 709.42 5 6.41E-6 19 -237NP G 712.5 2.0E-7 3 -237NP G 731.44 4.6E-7 4 -237NP G 736.68 1.28E-6 5 -237NP G 740.51 1.9E-7 3 -237NP G 742.9 3 350E-9 0 -237NP G 745.02 9E-8 2 -237NP G 750.39 6E-8 2 -237NP G 759.5 1 1.81E-6 5 -237NP G 763.31 2.3E-7 2 -237NP G 774.67 1.1E-7 2 -237NP G 777.39 1.5E-7 2 -237NP G 780.53 3.1E-7 2 -237NP G 782.2 5 150E-9 0 -237NP G 789.0 3 4.2E-7 6 -237NP G 792.6 3E-8 1 -237NP G 794.92 20940E-9 0 -237NP G 803.19 1.6E-7 3 -237NP G 811.9 3 6.3E-7 6 -237NP G 819.33 4.3E-7 6 -237NP G 822.21 2.4E-7 6 -237NP G 835.21 3E-8 1 -237NP G 838.88 4E-8 1 -237NP G 841.14 1.0E-7 3 -237NP G 843.7 9.7E-7 8 -237NP G 846.86 1.6E-7 3 -237NP G 847.4 5 2.7E-7 3 -237NP G 851.6 104.1E-7 6 -237NP G 854.95 2.3E-7 4 -237NP G 856.26 1.0E-7 3 -237NP G 870.63 1.50E-6 4 -237NP G 882 4E-8 1 -237NP G 886.53 1.5E-7 3 -237NP G 890.38 3.2E-7 5 -237NP G 894.47 3E-8 1 -237NP G 898.17 6E-8 2 -237NP G 902.61 3.3E-7 3 -237NP G 909.95 5E-8 1 -237NP G 912.4 2.8E-7 3 -237NP G 928.95 9E-8 2 -237NP G 939.2 5E-8 1 -237NP G 952.72 3E-8 1 -237NP G 955.91 6.0E-7 5 -237NP G 969.09 3E-8 1 -237NP G 980.84 3E-8 1 +237NP G 712.5 2.0E-7 3 +237NP G 731.44 4.6E-7 4 +237NP G 736.68 1.28E-6 5 +237NP G 740.51 1.9E-7 3 +237NP G 742.9 3 3.5E-7 +237NP G 745.02 9E-8 2 +237NP G 750.39 6E-8 2 +237NP G 759.5 1 1.81E-6 5 +237NP G 763.31 2.3E-7 2 +237NP G 774.67 1.1E-7 2 +237NP G 777.39 1.5E-7 2 +237NP G 780.53 3.1E-7 2 +237NP G 782.2 5 1.5E-7 +237NP G 789.0 3 4.2E-7 6 +237NP G 792.6 3E-8 1 +237NP G 794.92 209.4E-7 +237NP G 803.19 1.6E-7 3 +237NP G 811.9 3 6.3E-7 6 +237NP G 819.33 4.3E-7 6 +237NP G 822.21 2.4E-7 6 +237NP G 835.21 3E-8 1 +237NP G 838.88 4E-8 1 +237NP G 841.14 1.0E-7 3 +237NP G 843.7 9.7E-7 8 +237NP G 846.86 1.6E-7 3 +237NP G 847.4 5 2.7E-7 3 +237NP G 851.6 104.1E-7 6 +237NP G 854.95 2.3E-7 4 +237NP G 856.26 1.0E-7 3 +237NP G 870.63 1.50E-6 4 +237NP G 882 4E-8 1 +237NP G 886.53 1.5E-7 3 +237NP G 890.38 3.2E-7 5 +237NP G 894.47 3E-8 1 +237NP G 898.17 6E-8 2 +237NP G 902.61 3.3E-7 3 +237NP G 909.95 5E-8 1 +237NP G 912.4 2.8E-7 3 +237NP G 928.95 9E-8 2 +237NP G 939.2 5E-8 1 +237NP G 952.72 3E-8 1 +237NP G 955.91 6.0E-7 5 +237NP G 969.09 3E-8 1 +237NP G 980.84 3E-8 1 237NP L 0 5/2+ 2.144E6 Y 7 237NP A 5544.11 120.38 1 610 237NP L 33.19629 227/2+ 54 PS 24 237NP A 5511.46 120.23 1 600 237NP G 33.1963 3 0.1215 28M1+E2 0.13 3 175 24 -237NP2 G KC=$LC=131 17$MC=33 5 +237NP2 G LC=131 17$MC=33 5 237NP L 59.54092 105/2- 67 NS 2 237NP A 5485.56 1284.45 101.3 -237NP G 26.3446 2 2.31 8 E1 8 2 -237NP2 G KC=$LC=6 2$MC=1.6 2 -237NP G 59.5409 1 35.92 17E1 1.16 7 -237NP2 G KC=$LC=0.84 6$MC=0.226 7 +237NP G 26.34460 202.31 8E1 8 2 +237NP2 G LC=6 2$MC=1.6 2 +237NP G 59.5409 1 35.92 17E1 1.16 7 +237NP2 G LC=0.84 6$MC=0.226 7 237NP L 75.899 5 9/2+ 56 PS 237NP A 5469.47 120.04 2000 -237NP G 42.704 5 0.0055 11(M1+E2) 0.13 3 75 7 -237NP2 G KC=$LC=56 5$MC=13.9 14 -237NP G 75.90 1 6000E-7 0 (E2) 53.1 11 -237NP2 G KC=$LC=38.6 8$MC=10.76 22 +237NP G 42.704 5 0.0055 11(M1+E2) 0.13 3 75 7 +237NP2 G LC=56 5$MC=13.9 14 +237NP G 75.90 1 0.0006 (E2) 53.1 11 +237NP2 G LC=38.6 8$MC=10.76 22 237NP L 102.959 3 7/2- 80 PS 40 237NP A 5442.86 1213.23 104.3 237NP G 27.06 1 237NP G 43.420 3 0.0669 29M1+E2 0.45 5 180 23 -237NP2 G KC=$LC=132 17$MC=35 5 -237NP G 69.76 3 0.0029 4 (E1) 0.330 7 -237NP2 G KC=$LC=0.248 5$MC=0.0612 12 -237NP G 102.98 2 0.0195 4 E1 0.1189 24 -237NP2 G KC=$LC=0.0895 18$MC=0.0219 4 +237NP2 G LC=132 17$MC=35 5 +237NP G 69.76 3 0.0029 4(E1) 0.330 7 +237NP2 G LC=0.248 5$MC=0.0612 12 +237NP G 102.98 2 0.0195 4E1 0.1189 24 +237NP2 G LC=0.0895 18$MC=0.0219 4 237NP L 129.99 3 11/2+ 237NP A 5416.28 130.01 4000 237NP G 54.09 3 -237NP G 96.79 3 4.7E-5 16 +237NP G 96.79 3 0.00004716 237NP L 158.497 119/2- 237NP A 5388.25 131.66 3 16.4 -237NP G 55.56 2 0.0181 18M1+E2 0.46 4 65 6 -237NP2 G KC=$LC=48 4$MC=12.6 11 -237NP G 98.97 2 0.0203 4 E2 15.2 3 -237NP2 G KC=$LC=11.07 22$MC=3.08 6 -237NP G 125.30 2 0.0041 2 (E1) 0.299 6 -237NP2 G KC=0.228 5$LC=0.0538 11$MC=0.0132 3 +237NP G 55.56 2 0.0181 18M1+E2 0.46 4 65 6 +237NP2 G LC=48 4$MC=12.6 11 +237NP G 98.97 2 0.0203 4E2 15.2 3 +237NP2 G LC=11.07 22$MC=3.08 6 +237NP G 125.30 2 0.0041 2(E1) 0.299 6 +237NP2 G KC=0.228 5$LC=0.0538 11$MC=0.0132 3 237NP L 191.53 6 13/2+ 237NP G 61.56 7 237NP G 115.65 6 237NP L 225.957 1611/2- 237NP A 5321.87 130.014 3 770 -237NP G 67.50 2 0.00042 10(M1+E2) 0.46 12 29 6 -237NP2 G KC=$LC=22 5$MC=5.7 13 -237NP G 123.05 1 0.00100 4 E2 5.75 12 -237NP2 G KC=0.184 4$LC=4.05 8$MC=1.127 23 -237NP G 150.04 3 7.3E-5 5 [E1] 0.197 4 -237NP2 G KC=0.152 3$LC=0.0339 7$MC=0.00827 17 +237NP G 67.50 2 0.00042 10(M1+E2) 0.46 12 29 6 +237NP2 G LC=22 5$MC=5.7 13 +237NP G 123.05 1 0.00100 4E2 5.75 12 +237NP2 G KC=0.184 4$LC=4.05 8$MC=1.127 23 +237NP G 150.04 3 0.000073 5[E1] 0.197 4 +237NP2 G KC=0.152 3$LC=0.0339 7$MC=0.00827 17 237NP L 267.556 123/2- 5.2 NS 2 237NP A 5280.99 130.0005 12000 -237NP G 164.61 2 6.6E-5 3 E2 1.70 4 -237NP2 G KC=0.195 4$LC=1.095 22$MC=0.304 6 -237NP G 208.005 237.86E-4 9 M1+E2 0.156 5 2.98 6 -237NP2 G KC=2.35 5$LC=0.473 9$MC=0.1149 23 -237NP G 234.40 4 8.7E-7 8 M2 8.24 17 -237NP2 G KC=5.60 11$LC=1.95 4$MC=0.511 10 -237NP G 267.54 4 2.68E-5 6 E1+M2 0.490 15 1.06 6 -237NP2 G KC=0.74 4$LC=0.238 12$MC=0.062 2 +237NP G 164.61 2 0.000066 3E2 1.70 4 +237NP2 G KC=0.195 4$LC=1.095 22$MC=0.304 6 +237NP G 208.005 230.000786 9M1+E2 0.156 5 2.98 6 +237NP2 G KC=2.35 5$LC=0.473 9$MC=0.1149 23 +237NP G 234.40 4 8.7E-7 8M2 8.24 17 +237NP2 G KC=5.60 11$LC=1.95 4$MC=0.511 10 +237NP G 267.54 4 2.68E-5 6E1+M2 0.490 15 1.06 6 +237NP2 G KC=0.74 4$LC=0.238 12$MC=0.062 2 237NP L 281.356 181/2- 237NP G 13.81 2 M1+E2 0.0321 10 494 10 -237NP2 G KC=$LC=$MC=365 7 +237NP2 G MC=365 7 237NP L 305.05 3 13/2- 237NP A 5244.13 130.0022 3 1600 237NP G 79.05 3 -237NP G 146.55 3 0.00046 1 E2 2.73 6 -237NP2 G KC=0.210 4$LC=1.83 4$MC=0.51 1 -237NP G 175.07 4 1.8E-5 3 [E1] 0.137 3 -237NP2 G KC=0.1066 21$LC=0.0230 5$MC=0.00560 11 +237NP G 146.55 3 0.00046 1E2 2.73 6 +237NP2 G KC=0.210 4$LC=1.83 4$MC=0.51 1 +237NP G 175.07 4 0.000018 3[E1] 0.137 3 +237NP2 G KC=0.1066 21$LC=0.0230 5$MC=0.00560 11 237NP L 316.8 2 + 237NP A 5232.6 3 0 237NP G 316.8 2 237NP L 324.420 23(7/2)- 237NP A 5225.08 130.0013 2100 237NP G 56.86 3 -237NP G 165.81 6 2.3E-5 1 [M1+E2] 3.7 22 -237NP2 G KC=2.4 22$LC=0.98 8$MC=0.26 4 -237NP G 221.46 3 4.34E-5 8 [M1+E2] 1.5 10 -237NP2 G KC=1.1 10$LC=0.35 5$MC=0.090 7 -237NP G 248.52 3 1.46E-6 3 [E1] 0.0612 12 -237NP2 G KC=0.0482 10$LC=0.00975 20$MC=0.00236 5 -237NP G 264.88 3 9.43E-6 12[M1+E2] 0.9 7 -237NP2 G KC=0.7 6$LC=0.19 5$MC=0.049 9 -237NP G 291.3 2 3.05E-6 8 [E1] 0.0430 9 -237NP2 G KC=0.0341 7$LC=0.00671 14$MC=0.00162 3 +237NP G 165.81 6 0.000023 1[M1+E2] 3.7 22 +237NP2 G KC=2.4 22$LC=0.98 8$MC=0.26 4 +237NP G 221.46 3 4.34E-5 8[M1+E2] 1.5 10 +237NP2 G KC=1.1 10$LC=0.35 5$MC=0.090 7 +237NP G 248.52 3 1.46E-6 3[E1] 0.0612 12 +237NP2 G KC=0.0482 10$LC=0.00975 20$MC=0.00236 5 +237NP G 264.88 3 9.43E-6 12[M1+E2] 0.9 7 +237NP2 G KC=0.7 6$LC=0.19 5$MC=0.049 9 +237NP G 291.3 2 3.05E-6 8[E1] 0.0430 9 +237NP2 G KC=0.0341 7$LC=0.00671 14$MC=0.00162 3 237NP L 332.376 161/2+ 1 NS 237NP A 5217.26 130 -237NP G 51.01 3 2.6E-5 12E1 0.753 11 -237NP2 G KC=$LC=0.564 11$MC=0.141 3 -237NP G 64.83 2 0.00014 2 E1 0.400 8 -237NP2 G KC=$LC=0.301 6$MC=0.0744 15 -237NP G 332.35 3 1.50E-4 4 E2 0.147 3 -237NP2 G KC=0.0631 13$LC=0.0611 12$MC=0.0165 4 +237NP G 51.01 3 0.00002612E1 0.753 11 +237NP2 G LC=0.564 11$MC=0.141 3 +237NP G 64.83 2 0.00014 2E1 0.400 8 +237NP2 G LC=0.301 6$MC=0.0744 15 +237NP G 332.35 3 0.000150 4E2 0.147 3 +237NP2 G KC=0.0631 13$LC=0.0611 12$MC=0.0165 4 237NP L 359.7 1 (5/2)- 237NP A 5190.17 230.0006 2700 237NP G 92.35 20 237NP G 300.13 6 237NP L 368.602 205/2+ 237NP A 5181.63 130.0009 1600 -237NP G 292.77 6 1.42E-5 3 [E2] 0.215 4 -237NP2 G KC=0.0796 16$LC=0.0991 20$MC=0.0270 6 -237NP G 309.1 3 2.0E-6 3 [E1] 0.0377 8 -237NP2 G KC=0.0300 6$LC=0.00585 12$MC=0.00142 3 -237NP G 335.37 3 4.96E-4 7 M1+E2 0.46 17 0.69 8 -237NP2 G KC=0.54 7$LC=0.113 8$MC=0.0278 10 -237NP G 368.62 3 2.14E-4 5 (M1) 0.622 12 -237NP2 G KC=0.494 10$LC=0.0963 19$MC=0.0233 5 +237NP G 292.77 6 1.42E-5 3[E2] 0.215 4 +237NP2 G KC=0.0796 16$LC=0.0991 20$MC=0.0270 6 +237NP G 309.1 3 2.0E-6 3[E1] 0.0377 8 +237NP2 G KC=0.0300 6$LC=0.00585 12$MC=0.00142 3 +237NP G 335.37 3 0.000496 7M1+E2 0.46 17 0.69 8 +237NP2 G KC=0.54 7$LC=0.113 8$MC=0.0278 10 +237NP G 368.62 3 0.000214 5(M1) 0.622 12 +237NP2 G KC=0.494 10$LC=0.0963 19$MC=0.0233 5 237NP L 370.928 233/2+ 237NP A 5179.35 130.0003 4600 -237NP G 38.54 3 M1+E2 472.0000 -237NP2 G KC=$LC=94.0000 0$MC=345.000 0 -237NP G 337.7 2 4.88E-6 9 (E2) 0.140 3 -237NP2 G KC=0.0612 12$LC=0.0575 11$MC=0.0156 3 -237NP G 370.94 3 5.20E-5 8 M1+E2 0.43 21 0.53 7 -237NP2 G KC=0.42 6$LC=0.086 8$MC=0.0211 10 +237NP G 38.54 3 M1+E2 472 +237NP2 G LC=94 $MC=345 +237NP G 337.7 2 4.88E-6 9(E2) 0.140 3 +237NP2 G KC=0.0612 12$LC=0.0575 11$MC=0.0156 3 +237NP G 370.94 3 5.20E-5 8M1+E2 0.43 21 0.53 7 +237NP2 G KC=0.42 6$LC=0.086 8$MC=0.0211 10 237NP L 395.53 4 15/2- 237NP A 5155.12 130.0007 1400 -237NP G 169.56 3 0.00017 1 E2 1.51 3 -237NP2 G KC=0.189 4$LC=0.961 19$MC=0.267 6 -237NP G 204.06 6 2.06E-6 6 [E1] 0.0960 19 -237NP2 G KC=0.0752 15$LC=0.0157 3$MC=0.00382 8 +237NP G 169.56 3 0.00017 1E2 1.51 3 +237NP2 G KC=0.189 4$LC=0.961 19$MC=0.267 6 +237NP G 204.06 6 2.06E-6 6[E1] 0.0960 19 +237NP2 G KC=0.0752 15$LC=0.0157 3$MC=0.00382 8 237NP L 418.2 1 + 237NP A 5132.8 2 0 237NP L 434.12 5 (11/2)- 237NP A 5117.21 130.0004 1400 -237NP G 109.70 7 4900E-9 0 [E2] 9.44 19 -237NP2 G KC=$LC=6.86 14$MC=1.91 4 +237NP G 109.70 7 4.9E-6 [E2] 9.44 19 +237NP2 G LC=6.86 14$MC=1.91 4 237NP G 129.07 6 -237NP G 275.77 8 6.32E-6 10[M1+E2] 0.8 6 -237NP2 G KC=0.6 5$LC=0.17 5$MC=0.043 9 -237NP G 304.21 209.3E-7 2 [E1] 0.0391 8 -237NP2 G KC=0.0310 6$LC=0.00607 12$MC=0.00147 3 -237NP G 358.25 201.29E-6 5 [E1] 0.0275 6 -237NP2 G KC=0.0220 4$LC=0.00419 8$MC=0.00101 2 +237NP G 275.77 8 6.32E-6 10[M1+E2] 0.8 6 +237NP2 G KC=0.6 5$LC=0.17 5$MC=0.043 9 +237NP G 304.21 209.3E-7 2[E1] 0.0391 8 +237NP2 G KC=0.0310 6$LC=0.00607 12$MC=0.00147 3 +237NP G 358.25 201.29E-6 5[E1] 0.0275 6 +237NP2 G KC=0.0220 4$LC=0.00419 8$MC=0.00101 2 237NP L 444.78 10 + 237NP A 5106.72 160 -237NP G 120.36 8 4500E-9 0 +237NP G 120.36 8 4.5E-6 237NP L 452.545 229/2+ 237NP A 5099.08 130.0004 1000 -237NP G 261.00 7 1.29E-6 6 [E2] 0.312 6 -237NP2 G KC=0.0979 20$LC=0.156 3$MC=0.0428 9 -237NP G 322.56 3 1.51E-4 4 (M1+E2) 0.6 0.702 12 -237NP2 G KC=0.541 8$LC=0.1204 17$MC=0.0297 5 -237NP G 376.65 3 1.37E-4 3 (M1) 0.586 12 -237NP2 G KC=0.466 9$LC=0.0908 18$MC=0.0220 5 -237NP G 419.33 4 2.84E-5 4 [M1+E2] 0.26 18 -237NP2 G KC=0.19 16$LC=0.047 21$MC=0.012 5 -237NP G 452.6 2 2.36E-6 7 [E2] 0.0635 13 -237NP2 G KC=0.0357 7$LC=0.0205 4$MC=0.00543 11 +237NP G 261.00 7 1.29E-6 6[E2] 0.312 6 +237NP2 G KC=0.0979 20$LC=0.156 3$MC=0.0428 9 +237NP G 322.56 3 0.000151 4(M1+E2) 0.6 0.702 12 +237NP2 G KC=0.541 8$LC=0.1204 17$MC=0.0297 5 +237NP G 376.65 3 0.000137 3(M1) 0.586 12 +237NP2 G KC=0.466 9$LC=0.0908 18$MC=0.0220 5 +237NP G 419.33 4 2.84E-5 4[M1+E2] 0.26 18 +237NP2 G KC=0.19 16$LC=0.047 21$MC=0.012 5 +237NP G 452.6 2 2.36E-6 7[E2] 0.0635 13 +237NP2 G KC=0.0357 7$LC=0.0205 4$MC=0.00543 11 237NP L 459.693 247/2+ 237NP A 5092.06 130.0004 1000 237NP G 135.27 4 -237NP G 383.81 3 2.81E-5 6 [M1+E2] 0.33 23 -237NP2 G KC=0.25 20$LC=0.06 3$MC=0.015 6 -237NP G 426.47 4 3.1E-5 6 [M1+E2] 0.25 18 -237NP2 G KC=0.19 15$LC=0.045 20$MC=0.011 5 -237NP G 459.68 103.55E-6 7 [M1+E2] 0.20 14 -237NP2 G KC=0.15 12$LC=0.036 17$MC=0.009 4 +237NP G 383.81 3 2.81E-5 6[M1+E2] 0.33 23 +237NP2 G KC=0.25 20$LC=0.06 3$MC=0.015 6 +237NP G 426.47 4 0.000031 6[M1+E2] 0.25 18 +237NP2 G KC=0.19 15$LC=0.045 20$MC=0.011 5 +237NP G 459.68 103.55E-6 7[M1+E2] 0.20 14 +237NP2 G KC=0.15 12$LC=0.036 17$MC=0.009 4 237NP L 486.21 9 (9/2)- 237NP A 5065.97 150.00011 2300 -237NP G 161.54 101500E-9 0 [M1] 6.20 12 -237NP2 G KC=4.91 10$LC=0.971 19$MC=0.236 5 +237NP G 161.54 101.5E-6 [M1] 6.20 12 +237NP2 G KC=4.91 10$LC=0.971 19$MC=0.236 5 237NP G 260.22 9 237NP L 497.01 5 17/2- 237NP A 5055.36 130 237NP G 191.96 4 2.15E-5 10[E2] 0.932 19 -237NP2 G KC=0.162 3$LC=0.561 11$MC=0.155 3 +237NP2 G KC=0.162 3$LC=0.561 11$MC=0.155 3 237NP L 514.19 4 (3/2)- -237NP G 154.27 20500E-9 0 [M1] 7.06 14 -237NP2 G KC=5.59 11$LC=1.108 22$MC=0.269 6 -237NP G 232.81 5 4.82E-6 9 [M1] 2.22 5 -237NP2 G KC=1.76 4$LC=0.345 7$MC=0.0837 17 -237NP G 246.73 102.44E-6 7 [M1] 1.88 4 -237NP2 G KC=1.49 3$LC=0.294 6$MC=0.0711 14 -237NP G 454.66 8 9.53E-6 12[M1] 0.351 7 -237NP2 G KC=0.279 6$LC=0.0542 11$MC=0.0131 3 -237NP G 514.0 5 3.8E-6 2 [E1] 1320E-50 -237NP2 G KC=0.0106 2$LC=0.00194 4$MC=0.00047 1 +237NP G 154.27 205E-7 [M1] 7.06 14 +237NP2 G KC=5.59 11$LC=1.108 22$MC=0.269 6 +237NP G 232.81 5 4.82E-6 9[M1] 2.22 5 +237NP2 G KC=1.76 4$LC=0.345 7$MC=0.0837 17 +237NP G 246.73 102.44E-6 7[M1] 1.88 4 +237NP2 G KC=1.49 3$LC=0.294 6$MC=0.0711 14 +237NP G 454.66 8 9.53E-6 12[M1] 0.351 7 +237NP2 G KC=0.279 6$LC=0.0542 11$MC=0.0131 3 +237NP G 514.0 5 3.8E-6 2[E1] 0.0132 +237NP2 G KC=0.0106 2$LC=0.00194 4$MC=0.00047 1 237NP L 546.12 6 (5/2)- 237NP A 5007.07 140.0001 1000 237NP G 31.92 8 237NP G 264.76 7 -237NP G 278.04 151.15E-6 3 [M1] 1.35 3 -237NP2 G KC=1.072 21$LC=0.210 4$MC=0.0509 10 -237NP G 512.5 3 2.1E-6 4 [E1] 0.0133 3 -237NP2 G KC=0.0107 2$LC=0.00195 4$MC=0.00047 1 -237NP G 546.12 6 2.5E-7 3 [E1] 0.0117 2 -237NP2 G KC=0.00947 19$LC=0.00171 3$MC=0.00041 1 +237NP G 278.04 151.15E-6 3[M1] 1.35 3 +237NP2 G KC=1.072 21$LC=0.210 4$MC=0.0509 10 +237NP G 512.5 3 2.1E-6 4[E1] 0.0133 3 +237NP2 G KC=0.0107 2$LC=0.00195 4$MC=0.00047 1 +237NP G 546.12 6 2.5E-7 3[E1] 0.0117 2 +237NP2 G KC=0.00947 19$LC=0.00171 3$MC=0.00041 1 237NP L 590.09 4 (7/2)- 237NP A 4963.83 130 237NP G 322.52 4 -237NP G 487.13 4 6.2E-7 5 [M1] 0.291 6 -237NP2 G KC=0.232 6$LC=0.0449 9$MC=0.0109 2 -237NP G 590.09 4 2.80E-6 6 [E1] 0.0101 2 -237NP2 G KC=0.00818 16$LC=0.00147 3$MC=3.51E-4 7 +237NP G 487.13 4 6.2E-7 5[M1] 0.291 6 +237NP2 G KC=0.232 6$LC=0.0449 9$MC=0.0109 2 +237NP G 590.09 4 2.80E-6 6[E1] 0.0101 2 +237NP2 G KC=0.00818 16$LC=0.00147 3$MC=3.51E-4 7 237NP L 592.33 7 13/2+ 237NP A 4961.63 140 -237NP G 139.44 8 5.3E-6 11[E2] 3.37 7 -237NP2 G KC=0.211 4$LC=2.29 5$MC=0.638 13 -237NP G 159.26 201.4E-6 5 [E1] 0.171 4 -237NP2 G KC=0.132 3$LC=0.0292 6$MC=0.00711 14 -237NP G 196.76 8 490E-9 0 [E1] 0.1045 21 -237NP2 G KC=0.0816 16$LC=0.0172 4$MC=0.00418 9 -237NP G 400.78 101.4E-7 3 [M1+E2] 0.29 21 -237NP2 G KC=0.22 18$LC=0.054 23$MC=0.013 6 -237NP G 462.34 8 1000E-9 0 [M1+E2] 0.20 14 -237NP2 G KC=0.15 12$LC=0.035 17$MC=0.009 4 +237NP G 139.44 8 5.3E-6 11[E2] 3.37 7 +237NP2 G KC=0.211 4$LC=2.29 5$MC=0.638 13 +237NP G 159.26 201.4E-6 5[E1] 0.171 4 +237NP2 G KC=0.132 3$LC=0.0292 6$MC=0.00711 14 +237NP G 196.76 8 4.9E-7 [E1] 0.1045 21 +237NP2 G KC=0.0816 16$LC=0.0172 4$MC=0.00418 9 +237NP G 400.78 101.4E-7 3[M1+E2] 0.29 21 +237NP2 G KC=0.22 18$LC=0.054 23$MC=0.013 6 +237NP G 462.34 8 0.000001 [M1+E2] 0.20 14 +237NP2 G KC=0.15 12$LC=0.035 17$MC=0.009 4 237NP L 597.99 9 11/2+ 237NP A 4956.06 150 237NP G 138.30 9 -237NP G 406.35 151.37E-6 5 [M1+E2] 0.28 20 -237NP2 G KC=0.21 17$LC=0.052 22$MC=0.013 5 -237NP G 468.12 152.69E-6 6 [M1+E2] 0.19 14 -237NP2 G KC=0.15 12$LC=0.034 16$MC=0.008 4 -237NP G 522.06 159.9E-7 5 [M1+E2] 0.14 10 -237NP2 G KC=0.11 9$LC=0.025 13$MC=0.006 3 +237NP G 406.35 151.37E-6 5[M1+E2] 0.28 20 +237NP2 G KC=0.21 17$LC=0.052 22$MC=0.013 5 +237NP G 468.12 152.69E-6 6[M1+E2] 0.19 14 +237NP2 G KC=0.15 12$LC=0.034 16$MC=0.008 4 +237NP G 522.06 159.9E-7 5[M1+E2] 0.14 10 +237NP2 G KC=0.11 9$LC=0.025 13$MC=0.006 3 237NP L 646.03 17(9/2)- -237NP G 586.59 201.24E-6 5 [E2] 0.0346 7 -237NP2 G KC=0.0224 4$LC=0.00903 18$MC=0.00235 5 +237NP G 586.59 201.24E-6 5[E2] 0.0346 7 +237NP2 G KC=0.0224 4$LC=0.00903 18$MC=0.00235 5 237NP L 666.19 10(5/2,7/2)+ 237NP A 4888.98 150 237NP G 398.64 15 -237NP G 632.93 151.24E-6 5 -237NP G 666.2 2 9.5E-7 7 +237NP G 632.93 151.24E-6 5 +237NP G 666.2 2 9.5E-7 7 237NP L 721.961 135/2- 237NP A 4834.15 130.0007 9.5 -237NP G 563.46 2 4.4E-7 2 [E2] 0.0378 8 -237NP2 G KC=0.0241 5$LC=0.0102 2$MC=0.00266 5 -237NP G 619.01 2 6.0E-5 2 [M1+E2] 0.09 7 -237NP2 G KC=0.07 5$LC=0.016 8$MC=0.0037 10 -237NP G 662.40 2 3.67E-4 6 (+M1+E2) 0.23 5 -237NP2 G KC=0.18 4$LC=0.045 15$MC= -237NP G 688.72 4 3.23E-5 6 [E1] 0.0075816 -237NP2 G KC=0.00615 12$LC=0.00108 2$MC=2.59E-4 5 -237NP G 721.96 2 1.96E-4 5 [E1] 0.0070 2 -237NP2 G KC=0.0056 1$LC=0.00099 2$MC=0.00024 1 +237NP G 563.46 2 4.4E-7 2[E2] 0.0378 8 +237NP2 G KC=0.0241 5$LC=0.0102 2$MC=0.00266 5 +237NP G 619.01 2 0.000060 2[M1+E2] 0.09 7 +237NP2 G KC=0.07 5$LC=0.016 8$MC=0.0037 10 +237NP G 662.40 2 0.000367 6(+M1+E2) 0.23 5 +237NP2 G KC=0.18 4$LC=0.045 15 +237NP G 688.72 4 3.23E-5 6[E1] 0.0075816 +237NP2 G KC=0.00615 12$LC=0.00108 2$MC=2.59E-4 5 +237NP G 721.96 2 0.000196 5[E1] 0.0070 2 +237NP2 G KC=0.0056 1$LC=0.00099 2$MC=0.00024 1 237NP L 755.685 197/2- 237NP A 4800.99 1386000E-9 44 -237NP G 597.19 2 7.29E-6 11[M1+E2] 0.10 7 -237NP2 G KC=0.08 6$LC=0.017 9$MC=0.0042 20 -237NP G 652.73 2 3.76E-5 9 [M1+E2] 0.08 6 -237NP2 G KC=0.06 5$LC=0.013 7$MC=0.0033 10 -237NP G 679.79 2 3.31E-6 8 [E1] 0.0077616 -237NP2 G KC=0.00630 13$LC=0.00111 2$MC=2.65E-4 5 -237NP G 696.14 2 5.17E-6 8 [M1+E2] 0.07 5 -237NP2 G KC=0.05 4$LC=0.011 6$MC=0.0028 10 -237NP G 755.68 2 7.84E-6 11[E1] 0.0064 1 -237NP2 G KC=0.0052 1$LC=0.00091 1$MC=2.17E-4 4 +237NP G 597.19 2 7.29E-6 11[M1+E2] 0.10 7 +237NP2 G KC=0.08 6$LC=0.017 9$MC=0.0042 20 +237NP G 652.73 2 3.76E-5 9[M1+E2] 0.08 6 +237NP2 G KC=0.06 5$LC=0.013 7$MC=0.0033 10 +237NP G 679.79 2 3.31E-6 8[E1] 0.0077616 +237NP2 G KC=0.00630 13$LC=0.00111 2$MC=2.65E-4 5 +237NP G 696.14 2 5.17E-6 8[M1+E2] 0.07 5 +237NP2 G KC=0.05 4$LC=0.011 6$MC=0.0028 10 +237NP G 755.68 2 7.84E-6 11[E1] 0.0064 1 +237NP2 G KC=0.0052 1$LC=0.00091 1$MC=2.17E-4 4 237NP L 770.57 5 + -237NP G 446.15 6 1.1E-7 2 +237NP G 446.15 6 1.1E-7 2 237NP G 737.34 5 7.94E-6 11 -237NP G 770.57 104.81E-6 7 +237NP G 770.57 104.81E-6 7 237NP L 799.82 4 9/2- 237NP A 4757.58 130.00004 3 47 237NP G 77.86 4 -237NP G 573.94 201.28E-6 5 [M1+E2] 0.11 8 -237NP2 G KC=0.09 7$LC=0.019 10$MC=0.0027 16 -237NP G 641.32 4 7.04E-6 10[M1+E2] 0.08 6 -237NP2 G KC=0.06 5$LC=0.014 8$MC=0.0035 10 -237NP G 669.83 2 5.1E-7 7 [E1] 0.0080 2 -237NP2 G KC=0.00647 13$LC=0.00114 2$MC=0.00073 1 -237NP G 766.62 4 5.01E-6 6 [E1] 0.0062312 -237NP2 G KC=0.00507 10$LC=0.00088 2$MC=2.11E-4 4 +237NP G 573.94 201.28E-6 5[M1+E2] 0.11 8 +237NP2 G KC=0.09 7$LC=0.019 10$MC=0.0027 16 +237NP G 641.32 4 7.04E-6 10[M1+E2] 0.08 6 +237NP2 G KC=0.06 5$LC=0.014 8$MC=0.0035 10 +237NP G 669.83 2 5.1E-7 7[E1] 0.0080 2 +237NP2 G KC=0.00647 13$LC=0.00114 2$MC=0.00073 1 +237NP G 766.62 4 5.01E-6 6[E1] 0.0062312 +237NP2 G KC=0.00507 10$LC=0.00088 2$MC=2.11E-4 4 237NP L 805.77 12(7/2,9/2)+ -237NP G 675.78 138.5E-7 5 [E2M1] 0.07 5 -237NP2 G KC=0.06 4$LC=0.012 7$MC=0.0030 15 -237NP G 729.72 151.37E-6 5 [M1] 0.099 2 -237NP2 G KC=0.079 2$LC=0.0151 4$MC=0.0036 1 -237NP G 772.57 122.79E-6 4 [M1] 0.0847 17 -237NP2 G KC=0.0675 14$LC=0.0129 3$MC=0.00312 6 -237NP G 805.77 12310E-9 0 [M1E2] 0.05 3 -237NP2 G KC=0.037 24$LC=0.008 4$MC=0.0019 10 +237NP G 675.78 138.5E-7 5[E2M1] 0.07 5 +237NP2 G KC=0.06 4$LC=0.012 7$MC=0.0030 15 +237NP G 729.72 151.37E-6 5[M1] 0.099 2 +237NP2 G KC=0.079 2$LC=0.0151 4$MC=0.0036 1 +237NP G 772.57 122.79E-6 4[M1] 0.0847 17 +237NP2 G KC=0.0675 14$LC=0.0129 3$MC=0.00312 6 +237NP G 805.77 123.1E-7 [M1E2] 0.05 3 +237NP2 G KC=0.037 24$LC=0.008 4$MC=0.0019 10 237NP L 853.36 1511/2- -237NP G 529.17 206.9E-7 5 [E2] 0.0437 9 -237NP2 G KC=0.0269 5$LC=0.0124 2$MC=0.00324 6 -237NP G 627.18 205.1E-7 2 [M1+E2] 0.09 6 -237NP2 G KC=0.07 5$LC=0.015 8$MC=0.0037 10 +237NP G 529.17 206.9E-7 5[E2] 0.0437 9 +237NP2 G KC=0.0269 5$LC=0.0124 2$MC=0.00324 6 +237NP G 627.18 205.1E-7 2[M1+E2] 0.09 6 +237NP2 G KC=0.07 5$LC=0.015 8$MC=0.0037 10 237NP L 861.65 19(5/2,7/2)+ -237NP G 786.00 15620E-9 0 -237NP G 801.94 201.23E-6 7 -237NP G 828.60 122.1E-7 4 -237NP G 861.80 126.1E-7 6 +237NP G 786.00 156.2E-7 +237NP G 801.94 201.23E-6 7 +237NP G 828.60 122.1E-7 4 +237NP G 861.80 126.1E-7 6 237NP L 920.88 20 + -237NP G 861.34 208E-8 3 -237NP G 887.68 203.3E-7 6 -237NP G 920.88 201.9E-7 3 +237NP G 861.34 208E-8 3 +237NP G 887.68 203.3E-7 6 +237NP G 920.88 201.9E-7 3 237NP L 946 2 + -237NP G 946.06 1.0E-8 2 +237NP G 946.06 1.0E-8 2 237NP L 962 3 + -237NP G 962.19 4E-8 1 +237NP G 962.19 4E-8 1 237NP L 1014 3 + -237NP G 1014.33 1.0E-6 2 +237NP G 1014.33 1.0E-6 2 diff --git a/HEN_HOUSE/spectra/lnhb/Am-242.txt b/HEN_HOUSE/spectra/lnhb/Am-242.txt index d0b26f48d..e057f312b 100644 --- a/HEN_HOUSE/spectra/lnhb/Am-242.txt +++ b/HEN_HOUSE/spectra/lnhb/Am-242.txt @@ -5,41 +5,41 @@ 242PU2C 1961Ma27, 1969Al20, 1969Ga17, 1972Ga35, 1977La19, 1980VyZZ, 1982Wi05, 242PU3C 1996Sc06, 1998ScZM, 1999ScZX, 2002Ak06, 2002Ba85, 2002Ra45, 2003Au03, 242PU4C 2008Ki07 -242PU T Auger electrons and ^X ray energies and emission intensities: -242PU T {U Energy (keV)} {U Intensity } {U Line } +242PU T Auger electrons and X ray energies and emission intensities: +242PU T {U Energy (keV)} {U Intensity} {U Line} 242PU T -242PU T 99.525 3.55 17 XKA2 -242PU T 103.734 5.6 3 XKA1 +242PU T 99.525 3.55 17 XKA2 +242PU T 103.734 5.6 3 XKA1 242PU T -242PU T 116.244 |] XKB3 -242PU T 117.228 |] 2.06 11 XKB1 -242PU T 117.918 |] XKB5II +242PU T 116.244 |] XKB3 +242PU T 117.228 |] 2.06 11 XKB1 +242PU T 117.918 |] XKB5II 242PU T -242PU T 120.54 |] XKB2 -242PU T 120.969 |] 0.72 4 XKB4 -242PU T 121.543 |] XKO23 +242PU T 120.54 |] XKB2 +242PU T 120.969 |] 0.72 4 XKB4 +242PU T 121.543 |] XKO23 242PU T -242PU T 12.124-22.153 10.8 5 XL (total) -242PU T 12.124 0.293 11 XLL -242PU T 14.087-14.282 4.56 16 XLA -242PU T 16.333 0.084 4 XLC -242PU T 16.498-18.541 4.64 15 XLB -242PU T 21.42-22.153 1.03 4 XLG +242PU T 12.124-22.153 10.8 5 XL (total) +242PU T 12.124 0.293 11 XLL +242PU T 14.087-14.282 4.56 16 XLA +242PU T 16.333 0.084 4 XLC +242PU T 16.498-18.541 4.64 15 XLB +242PU T 21.42-22.153 1.03 4 XLG 242PU T -242PU T 75.263-85.357 |] KLL AUGER -242PU T 92.607-103.729 |] 0.36 4 ^KLX AUGER -242PU T 109.93-121.78 |] KXY AUGER -242PU T 6.19-22.99 9.9 5 L AUGER +242PU T 75.263-85.357 |] KLL AUGER +242PU T 92.607-103.729 |] 0.36 4 KLX AUGER +242PU T 109.93-121.78 |] KXY AUGER +242PU T 6.19-22.99 9.9 5 L AUGER 242AM P 0.0 1- 16.01 H 2 751.3 7 242PU N 5.917E0 5.917E0 0.169 5.917E0 242PU L 0 0 0+ 3.73E5 Y 3 -242PU E 6.3 6 7.55 1 -242PU2 E EAV= $CK=0.7303 22$CL=0.1987 15$CM=0.0522 10$CN= $CO= +242PU E 6.3 67.55 1 +242PU2 E CK=0.7303 22$CL=0.1987 15$CM=0.0522 10 242PU L 44.54 2 2+ -242PU E 10.6 5 7.26 1 -242PU2 E EAV= $CK=0.7261 23$CL=0.2016 15$CM=0.0532 10$CN=0.0152 7$CO= -242PU G 44.54 2 0.014 1 E2 748 11 -242PU2 G KC=$LC=543 8$MC=151.6 22 +242PU E 10.6 57.26 1 +242PU2 E CK=0.7261 23$CL=0.2016 15$CM=0.0532 10$CN=0.0152 7 +242PU G 44.54 2 0.014 1E2 748 11 +242PU2 G LC=543 8$MC=151.6 22 242CM 242AM B- DECAY (16.01 H) 242CM H TYP=Full$AUT=A.L. Nichols$CUT=30-SEP-2008$ @@ -48,28 +48,28 @@ 242CM2C 1961Ma27, 1969Al20, 1969Ga17, 1972Ga35, 1977La19, 1980VyZZ, 1982Wi05, 242CM3C 1996Sc06, 1998ScZM, 1999ScZX, 2002Ak06, 2002Ba85, 2002Ra45, 2003Au03, 242CM4C 2008Ki07 -242CM T Auger electrons and ^X ray energies and emission intensities: -242CM T {U Energy (keV)} {U Intensity } {U Line } +242CM T Auger electrons and X ray energies and emission intensities: +242CM T {U Energy (keV)} {U Intensity} {U Line} 242CM T 242CM T 104.59 XKA2 242CM T 109.271 XKA1 242CM T -242CM T 122.304 |] XKB3 -242CM T 123.403 |] XKB1 -242CM T 124.124 |] XKB5II +242CM T 122.304 |] XKB3 +242CM T 123.403 |] XKB1 +242CM T 124.124 |] XKB5II 242CM T -242CM T 126.889 |] XKB2 -242CM T 127.352 |] XKB4 -242CM T 127.97 |] XKO23 +242CM T 126.889 |] XKB2 +242CM T 127.352 |] XKB4 +242CM T 127.97 |] XKO23 242CM T -242CM T 12.633-23.527 18.0 11 XL (total) -242CM T 12.633 0.451 22 XLL -242CM T 14.746-14.961 6.8 3 XLA -242CM T 17.314 0.194 11 XLC -242CM T 17.286-19.688 8.7 4 XLB -242CM T 22.735-23.527 2.09 10 XLG +242CM T 12.633-23.527 18.0 11 XL (total) +242CM T 12.633 0.451 22 XLL +242CM T 14.746-14.961 6.8 3 XLA +242CM T 17.314 0.194 11 XLC +242CM T 17.286-19.688 8.7 4 XLB +242CM T 22.735-23.527 2.09 10 XLG 242CM T -242CM T 6.19-14.46 15.4 10 L AUGER +242CM T 6.19-14.46 15.4 10 L AUGER 242AM P 0.0 1- 16.01 H 2 664.5 4 242CM N 1.203E0 1.203E0 0.831 1.203E0 242CM L 0 0+ 162.86 D 8 @@ -78,6 +78,6 @@ 242CM L 42.13 5 2+ 242CM B 622.4 4 45.8 23 6.84 1 242CMS B EAV=185.92 14 -242CM G 42.13 5 0.040 2 E2 1155 17 -242CM2 G KC=$LC=836 13$MC=235 4 +242CM G 42.13 5 0.040 2E2 1155 17 +242CM2 G LC=836 13$MC=235 4 diff --git a/HEN_HOUSE/spectra/lnhb/Am-242m.txt b/HEN_HOUSE/spectra/lnhb/Am-242m.txt index 9dd66bd43..e8251b40a 100644 --- a/HEN_HOUSE/spectra/lnhb/Am-242m.txt +++ b/HEN_HOUSE/spectra/lnhb/Am-242m.txt @@ -4,41 +4,41 @@ 242AM C References: 1950St61, 1959Ba22, 1960As05, 1967Ca04, 1977La19, 1979Ba67, 242AM2C 1979Ze05, 1980VyZZ, 1986Ze06, 1990Ho02, 1996Sc06, 1998Ak04, 1998ScZM, 242AM3C 1999ScZX, 2002Ak06, 2002Ba25, 2002Ch52, 2002Ra45, 2003Au03, 2008Ki07 -242AM T Auger electrons and ^X ray energies and emission intensities: -242AM T {U Energy (keV)} {U Intensity } {U Line } +242AM T Auger electrons and X ray energies and emission intensities: +242AM T {U Energy (keV)} {U Intensity} {U Line} 242AM T 242AM T 102.03 XKA2 242AM T 106.472 XKA1 242AM T -242AM T 119.243 |] XKB3 -242AM T 120.284 |] XKB1 -242AM T 120.989 |] XKB5II +242AM T 119.243 |] XKB3 +242AM T 120.284 |] XKB1 +242AM T 120.989 |] XKB5II 242AM T -242AM T 123.58 |] XKB2 -242AM T 124.127 |] XKB4 -242AM T 124.723 |] XKO23 +242AM T 123.58 |] XKB2 +242AM T 124.127 |] XKB4 +242AM T 124.723 |] XKO23 242AM T -242AM T 12.377-22.836 25.0 11 XL (total) -242AM T 12.377 0.608 18 XLL -242AM T 14.414-14.62 9.33 24 XLA -242AM T 16.819 0.274 9 XLC -242AM T 16.89-19.11 12.2 3 XLB -242AM T 22.072-22.836 2.90 8 XLG +242AM T 12.377-22.836 25.0 11 XL (total) +242AM T 12.377 0.608 18 XLL +242AM T 14.414-14.62 9.33 24 XLA +242AM T 16.819 0.274 9 XLC +242AM T 16.89-19.11 12.2 3 XLB +242AM T 22.072-22.836 2.90 8 XLG 242AM T -242AM T 77.04-85.638 |] KLL AUGER -242AM T 94.891-106.467 |] ^KLX AUGER -242AM T 112.72-124.97 |] KXY AUGER -242AM T 6.26-23.7 22.1 11 L AUGER +242AM T 77.04-85.638 |] KLL AUGER +242AM T 94.891-106.467 |] KLX AUGER +242AM T 112.72-124.97 |] KXY AUGER +242AM T 6.26-23.7 22.1 11 L AUGER 242AM P 48.60 5 5- 143 Y 2 242AM N 1.005E0 1.005E0 0.9954 1.005E0 -242AM G 89.60 5 0.0013 3 +242AM G 89.60 5 0.0013 3 242AM G 160.61 2 0.00041 18 -242AM G 165.97 154.6E-5 23 -242AM G 233.69 100.00013 3 +242AM G 165.97 150.00004623 +242AM G 233.69 100.00013 3 242AM L 0 1- 16.01 H 2 242AM L 48.60 5 5- 143 Y 2 -242AM G 48.60 5 1414E-7 22E4 7.04E5 8 -242AM2 G KC=$LC=3.33E5 5$MC=2.66E5 5 +242AM G 48.60 5 1.414E-422E4 7.04E5 8 +242AM2 G LC=3.33E5 5$MC=2.66E5 5 238NP 242AM A DECAY (143 Y) 238NP H TYP=Full$AUT=A. Nichols$CUT=30-APR-2010$ @@ -46,204 +46,204 @@ 238NP C References: 1950St61, 1959Ba22, 1960As05, 1967Ca04, 1977La19, 1979Ba67, 238NP2C 1979Ze05, 1980VyZZ, 1986Ze06, 1990Ho02, 1996Sc06, 1998Ak04, 1998ScZM, 238NP3C 1999ScZX, 2002Ak06, 2002Ba25, 2002Ch52, 2002Ra45, 2003Au03, 2008Ki07 -238NP T Auger electrons and ^X ray energies and emission intensities: -238NP T {U Energy (keV)} {U Intensity } {U Line } +238NP T Auger electrons and X ray energies and emission intensities: +238NP T {U Energy (keV)} {U Intensity} {U Line} 238NP T -238NP T 97.069 0.019 9 XKA2 -238NP T 101.059 0.030 14 XKA1 +238NP T 97.069 0.019 9 XKA2 +238NP T 101.059 0.030 14 XKA1 238NP T -238NP T 113.303 |] XKB3 -238NP T 114.234 |] 0.011 5 XKB1 -238NP T 114.912 |] XKB5II +238NP T 113.303 |] XKB3 +238NP T 114.234 |] 0.011 5 XKB1 +238NP T 114.912 |] XKB5II 238NP T -238NP T 117.463 |] XKB2 -238NP T 117.876 |] 0.0037 17 XKB4 -238NP T 118.429 |] XKO23 +238NP T 117.463 |] XKB2 +238NP T 117.876 |] 0.0037 17 XKB4 +238NP T 118.429 |] XKO23 238NP T -238NP T 11.871-21.491 0.37 4 XL (total) -238NP T 11.871 0.0090 9 XLL -238NP T 13.761-13.946 0.143 13 XLA -238NP T 15.861 0.0022 4 XLC -238NP T 16.109-17.992 0.164 13 XLB -238NP T 20.784-21.491 0.040 3 XLG +238NP T 11.871-21.491 0.37 4 XL (total) +238NP T 11.871 0.0090 9 XLL +238NP T 13.761-13.946 0.143 13 XLA +238NP T 15.861 0.0022 4 XLC +238NP T 16.109-17.992 0.164 13 XLB +238NP T 20.784-21.491 0.040 3 XLG 238NP T -238NP T 73.501-83.134 |] KLL AUGER -238NP T 90.358-101.054 |] 0.0019 7 ^KLX AUGER -238NP T 107.19-118.66 |] KXY AUGER -238NP T 6.036-13.516 0.35 4 L AUGER +238NP T 73.501-83.134 |] KLL AUGER +238NP T 90.358-101.054 |] 0.0019 7 KLX AUGER +238NP T 107.19-118.66 |] KXY AUGER +238NP T 6.036-13.516 0.35 4 L AUGER 242AM P 48.60 5 5- 143 Y 2 5588.50 25 238NP N 2.174E2 2.174E2 0.0046 2.174E2 -238NP G 89.60 5 0.0013 3 +238NP G 89.60 5 0.0013 3 238NP G 160.61 2 0.00041 18 -238NP G 165.97 154.6E-5 23 -238NP G 233.69 100.00013 3 +238NP G 165.97 150.00004623 +238NP G 233.69 100.00013 3 238NP L 0 2+ 2.102 D 5 238NP L 26.427 2 3+ 238NP A 5517.93 250.003 3 4000000 -238NP G 26.427 2 7080E-7 0 M1+E2 0.1 338 5 -238NP2 G KC=$LC=252 4$MC=63.7 9 +238NP G 26.427 2 0.000708 M1+E2 0.1 338 5 +238NP2 G LC=252 4$MC=63.7 9 238NP L 62.330 4 4+ 238NP L 86.674 2 3+ 238NP A 5458.68 250.139 3939000 -238NP G 24.34 1 6.4E-5 9 M1+E2 0.01 322 5 -238NP2 G KC=$LC=242 4$MC=59.6 9 -238NP G 60.247 3 0.0055 5 M1+E2 0.07 23.1 4 -238NP2 G KC=$LC=17.34 25$MC=4.23 6 -238NP G 86.674 2 0.0229 7 M1+E2 0.1 7.95 12 -238NP2 G KC=$LC=5.98 9$MC=1.459 21 +238NP G 24.34 1 0.000064 9M1+E2 0.01 322 5 +238NP2 G LC=242 4$MC=59.6 9 +238NP G 60.247 3 0.0055 5M1+E2 0.07 23.1 4 +238NP2 G LC=17.34 25$MC=4.23 6 +238NP G 86.674 2 0.0229 7M1+E2 0.1 7.95 12 +238NP2 G LC=5.98 9$MC=1.459 21 238NP L 106.155 155+ 238NP L 121.645 9 4+ 238NP L 136.045 2 3- 6 NS 238NP A 5410.13 251.0 2 2820 -238NP G 49.371 3 0.134 4 E1 0.821 12 -238NP2 G KC=$LC=0.615 9$MC=0.1536 22 -238NP G 73.72 1 0.0079 6 E1 0.285 4 -238NP2 G KC=$LC=0.214 3$MC=0.0529 8 -238NP G 109.618 3 1840E-5 0 E1 0.1010 15 -238NP2 G KC=$LC=0.0760 11$MC=0.0186 3 -238NP G 136.045 2 0.0094 3 E1 0.247 4 -238NP2 G KC=0.190 3$LC=0.0436 6$MC=0.01064 15 +238NP G 49.371 3 0.134 4E1 0.821 12 +238NP2 G LC=0.615 9$MC=0.1536 22 +238NP G 73.72 1 0.0079 6E1 0.285 4 +238NP2 G LC=0.214 3$MC=0.0529 8 +238NP G 109.618 3 0.0184 E1 0.1010 15 +238NP2 G LC=0.0760 11$MC=0.0186 3 +238NP G 136.045 2 0.0094 3E1 0.247 4 +238NP2 G KC=0.190 3$LC=0.0436 6$MC=0.01064 15 238NP L 161.69 2 6+ 238NP L 165.532 155+ -238NP G 139.11 2 1100E-7 0 E2 3.40 5 -238NP2 G KC=0.211 3$LC=2.32 4$MC=0.646 9 +238NP G 139.11 2 0.00011 E2 3.40 5 +238NP2 G KC=0.211 3$LC=2.32 4$MC=0.646 9 238NP L 179.154 7 4- 238NP A 5367.73 251.11 201430 -238NP G 43.11 1 6.4E-5 14M1+E2 0.045 61.3 9 -238NP2 G KC=$LC=46.1 7$MC=11.25 16 -238NP G 57.51 1 0.00097 23E1 0.549 8 -238NP2 G KC=$LC=0.412 6$MC=0.1023 15 -238NP G 92.48 1 0.0028 3 E1 0.1574 22 -238NP2 G KC=$LC=0.1184 17$MC=0.0291 4 -238NP G 152.73 1 6900E-7 0 E1 0.189 3 -238NP2 G KC=0.1457 21$LC=0.0324 5$MC=0.00791 11 +238NP G 43.11 1 0.00006414M1+E2 0.045 61.3 9 +238NP2 G LC=46.1 7$MC=11.25 16 +238NP G 57.51 1 0.00097 23E1 0.549 8 +238NP2 G LC=0.412 6$MC=0.1023 15 +238NP G 92.48 1 0.0028 3E1 0.1574 22 +238NP2 G LC=0.1184 17$MC=0.0291 4 +238NP G 152.73 1 0.00069 E1 0.189 3 +238NP2 G KC=0.1457 21$LC=0.0324 5$MC=0.00791 11 238NP L 182.878 2 2- -238NP G 46.833 3 7.4E-6 14M1+E2 0.063 48.8 7 -238NP2 G KC=$LC=36.7 6$MC=8.97 13 -238NP G 156.451 3 0.00027 5 E1 0.1784 25 -238NP2 G KC=0.1379 20$LC=0.0305 5$MC=0.00744 11 -238NP G 182.878 2 0.00092 3 E1 0.1238 18 -238NP2 G KC=0.0965 14$LC=0.0206 3$MC=0.00502 7 +238NP G 46.833 3 7.4E-6 14M1+E2 0.063 48.8 7 +238NP2 G LC=36.7 6$MC=8.97 13 +238NP G 156.451 3 0.00027 5E1 0.1784 25 +238NP2 G KC=0.1379 20$LC=0.0305 5$MC=0.00744 11 +238NP G 182.878 2 0.00092 3E1 0.1238 18 +238NP2 G KC=0.0965 14$LC=0.0206 3$MC=0.00502 7 238NP L 215.522 4 3- 238NP A 5331.97 250.15 116400 -238NP G 32.64 1 1.9E-5 3 M1+E2 0.014 136.4 20 -238NP2 G KC=$LC=102.6 15$MC=25.0 4 -238NP G 79.48 1 1.24E-4 23M1+E2 1.0 2 26 4 -238NP2 G KC=$LC=19 3$MC=5.2 8 -238NP G 93.88 1 0.0036 4 E1 0.1513 22 -238NP2 G KC=$LC=0.1138 16$MC=0.0280 4 -238NP G 153.19 1 0.00031 4 E1 0.187 3 -238NP2 G KC=0.1447 21$LC=0.0322 5$MC=0.00785 11 -238NP G 189.10 1 0.00027 5 E1 0.1146 16 -238NP2 G KC=0.0894 13$LC=0.0190 3$MC=0.00462 7 +238NP G 32.64 1 0.000019 3M1+E2 0.014 136.4 20 +238NP2 G LC=102.6 15$MC=25.0 4 +238NP G 79.48 1 0.00012423M1+E2 1.0 2 26 4 +238NP2 G LC=19 3$MC=5.2 8 +238NP G 93.88 1 0.0036 4E1 0.1513 22 +238NP2 G LC=0.1138 16$MC=0.0280 4 +238NP G 153.19 1 0.00031 4E1 0.187 3 +238NP2 G KC=0.1447 21$LC=0.0322 5$MC=0.00785 11 +238NP G 189.10 1 0.00027 5E1 0.1146 16 +238NP2 G KC=0.0894 13$LC=0.0190 3$MC=0.00462 7 238NP G 215.522 4 0.00059 10E1 0.0847 12 -238NP2 G KC=0.0664 10$LC=0.01376 20$MC=0.00334 5 +238NP2 G KC=0.0664 10$LC=0.01376 20$MC=0.00334 5 238NP L 218.7 6 (6)+ 238NP L 232.828 8 5- 238NP A 5314.95 250.61 111250 -238NP G 53.67 1 0.0021 3 M1+E2 0.25 46.0 7 -238NP2 G KC=$LC=34.2 5$MC=8.73 13 -238NP G 96.78 1 0.00033 6 E2 16.90 24 -238NP2 G KC=$LC=12.28 18$MC=3.42 5 -238NP G 111.18 1 0.0025 4 E1 0.0974 14 -238NP2 G KC=$LC=0.0733 11$MC=0.0180 3 +238NP G 53.67 1 0.0021 3M1+E2 0.25 46.0 7 +238NP2 G LC=34.2 5$MC=8.73 13 +238NP G 96.78 1 0.00033 6E2 16.90 24 +238NP2 G LC=12.28 18$MC=3.42 5 +238NP G 111.18 1 0.0025 4E1 0.0974 14 +238NP2 G LC=0.0733 11$MC=0.0180 3 238NP L 250.33 3 (1)+ -238NP G 250.33 3 5600E-7 0 (M1+E2) 1.0 2 1.08 16 +238NP G 250.33 3 0.00056 (M1+E2) 1.0 2 1.08 16 238NP2 G KC=0.77 15$LC=0.233 12$MC=0.0595 21 238NP L 258.853 8 4- 238NP G 43.33 1 8.7E-6 14M1+E2 0.32 126.7 18 -238NP2 G KC=$LC=93.5 14$MC=24.6 4 -238NP G 75.98 1 9.7E-6 14E2 52.8 8 -238NP2 G KC=$LC=38.4 6$MC=10.70 15 -238NP G 122.81 1 0.00004 2 M1+E2 1.0 2 9.6 9 -238NP2 G KC=5.4 12$LC=3.11 22$MC=0.83 7 -238NP G 152.70 2 6900E-7 0 E1 0.189 3 -238NP2 G KC=0.1458 21$LC=0.0325 5$MC=0.00791 11 -238NP G 196.52 1 0.00010 5 E1 0.1048 15 -238NP2 G KC=0.0819 12$LC=0.01725 25$MC=0.00419 6 -238NP G 232.43 1 0.00056 3 E1 0.0712 10 -238NP2 G KC=0.0560 8$LC=0.01145 16$MC=0.00278 4 +238NP2 G LC=93.5 14$MC=24.6 4 +238NP G 75.98 1 9.7E-6 14E2 52.8 8 +238NP2 G LC=38.4 6$MC=10.70 15 +238NP G 122.81 1 0.00004 2M1+E2 1.0 2 9.6 9 +238NP2 G KC=5.4 12$LC=3.11 22$MC=0.83 7 +238NP G 152.70 2 0.00069 E1 0.189 3 +238NP2 G KC=0.1458 21$LC=0.0325 5$MC=0.00791 11 +238NP G 196.52 1 0.00010 5E1 0.1048 15 +238NP2 G KC=0.0819 12$LC=0.01725 25$MC=0.00419 6 +238NP G 232.43 1 0.00056 3E1 0.0712 10 +238NP2 G KC=0.0560 8$LC=0.01145 16$MC=0.00278 4 238NP L 275.519 9 5+ 238NP A 5272.96 251.00 11414 238NP G 153.87 1 0.00332 10M1+E2 0.14 7.02 10 -238NP2 G KC=5.53 8$LC=1.123 16$MC=0.273 4 -238NP G 213.19 1 5.5E-5 18M1+E2 1.0 2 1.73 25 +238NP2 G KC=5.53 8$LC=1.123 16$MC=0.273 4 +238NP G 213.19 1 0.00005518M1+E2 1.0 2 1.73 25 238NP2 G KC=1.19 24$LC=0.401 11$MC=0.1032 17 238NP L 297.03 5 (6)- 238NP A 5251.80 250.020 1115300 -238NP G 131.50 5 0.00027 6 E1 0.268 4 -238NP2 G KC=0.205 3$LC=0.0475 7$MC=0.01161 17 -238NP G 190.88 5 1.06E-4 24E1 0.1121 16 -238NP2 G KC=0.0875 13$LC=0.0185 3$MC=0.00451 7 +238NP G 131.50 5 0.00027 6E1 0.268 4 +238NP2 G KC=0.205 3$LC=0.0475 7$MC=0.01161 17 +238NP G 190.88 5 0.00010624E1 0.1121 16 +238NP2 G KC=0.0875 13$LC=0.0185 3$MC=0.00451 7 238NP L 299.23 6 (3)+ 238NP A 5249.64 260.020 1114800 -238NP G 236.90 6 4.6E-5 23M1+E2 1.0 2 1.27 19 +238NP G 236.90 6 0.00004623M1+E2 1.0 2 1.27 19 238NP2 G KC=0.89 18$LC=0.280 12$MC=0.0717 21 -238NP G 272.80 6 3.7E-5 8 M1+E2 1.0 2 0.85 13 +238NP G 272.80 6 0.000037 8M1+E2 1.0 2 0.85 13 238NP2 G KC=0.61 12$LC=0.176 11$MC=0.0448 21 -238NP G 299.23 6 2.8E-5 14M1+E2 1.0 2 0.65 10 -238NP2 G KC=0.48 9$LC=0.131 9$MC=0.0332 19 +238NP G 299.23 6 0.00002814M1+E2 1.0 2 0.65 10 +238NP2 G KC=0.48 9$LC=0.131 9$MC=0.0332 19 238NP L 300.68 7 (1 to 4)- 238NP A 5248.21 260.39 11730 -238NP G 85.16 7 0.0010 3 M1+E2 1.0 2 19 3 -238NP2 G KC=$LC=14.3 18$MC=3.9 6 -238NP G 238.35 7 1.6E-5 8 E1 0.0673 10 -238NP2 G KC=0.0530 8$LC=0.01078 16$MC=0.00261 4 +238NP G 85.16 7 0.0010 3M1+E2 1.0 2 19 3 +238NP2 G LC=14.3 18$MC=3.9 6 +238NP G 238.35 7 0.000016 8E1 0.0673 10 +238NP2 G KC=0.0530 8$LC=0.01078 16$MC=0.00261 4 238NP L 300.743 16(6)- 238NP A 5248.15 250.39 11730 -238NP G 67.92 2 0.0040 3 M1+E2 0.35 6 24 3 -238NP2 G KC=$LC=17.7 19$MC=4.6 6 -238NP G 135.21 2 0.0068 4 E1 0.251 4 -238NP2 G KC=0.192 3$LC=0.0443 7$MC=0.01081 16 -238NP G 139.05 3 1100E-7 0 E1 0.235 4 -238NP2 G KC=0.180 3$LC=0.0412 6$MC=0.01006 15 -238NP G 194.59 2 0.00142 5 E1 0.1072 15 -238NP2 G KC=0.0837 12$LC=0.01768 25$MC=0.00430 6 +238NP G 67.92 2 0.0040 3M1+E2 0.35 6 24 3 +238NP2 G LC=17.7 19$MC=4.6 6 +238NP G 135.21 2 0.0068 4E1 0.251 4 +238NP2 G KC=0.192 3$LC=0.0443 7$MC=0.01081 16 +238NP G 139.05 3 0.00011 E1 0.235 4 +238NP2 G KC=0.180 3$LC=0.0412 6$MC=0.01006 15 +238NP G 194.59 2 0.00142 5E1 0.1072 15 +238NP2 G KC=0.0837 12$LC=0.01768 25$MC=0.00430 6 238NP L 312.70 2 5- -238NP G 53.85 2 2.8E-6 14M1+E2 0.16 37.2 6 -238NP2 G KC=$LC=27.8 4$MC=6.93 10 -238NP G 97.18 2 7E-6 4 E2 16.58 24 -238NP2 G KC=$LC=12.05 17$MC=3.36 5 -238NP G 151.01 3 8.3E-5 18E1 0.194 3 -238NP2 G KC=0.1495 21$LC=0.0334 5$MC=0.00814 12 -238NP G 176.66 2 2.8E-5 14E2 1.285 18 -238NP2 G KC=0.181 3$LC=0.804 12$MC=0.223 4 -238NP G 250.37 2 5600E-7 0 E1 0.0602 9 -238NP2 G KC=0.0475 7$LC=0.00958 14$MC=0.00232 4 +238NP G 53.85 2 2.8E-6 14M1+E2 0.16 37.2 6 +238NP2 G LC=27.8 4$MC=6.93 10 +238NP G 97.18 2 0.000007 4E2 16.58 24 +238NP2 G LC=12.05 17$MC=3.36 5 +238NP G 151.01 3 0.00008318E1 0.194 3 +238NP2 G KC=0.1495 21$LC=0.0334 5$MC=0.00814 12 +238NP G 176.66 2 0.00002814E2 1.285 18 +238NP2 G KC=0.181 3$LC=0.804 12$MC=0.223 4 +238NP G 250.37 2 0.00056 E1 0.0602 9 +238NP2 G KC=0.0475 7$LC=0.00958 14$MC=0.00232 4 238NP L 328.6 5 6+ -238NP G 163.1 5 1610E-5 0 M1+E2 1.0 2 3.9 5 -238NP2 G KC=2.5 5$LC=1.04 3$MC=0.273 11 +238NP G 163.1 5 0.0161 M1+E2 1.0 2 3.9 5 +238NP2 G KC=2.5 5$LC=1.04 3$MC=0.273 11 238NP L 334.0 6 (1 to 3)- 238NP A 5215.4 7 0.030 116000 238NP L 342.439 8 5- 238NP A 5207.15 2588.9 201.8 -238NP G 66.92 1 0.0150 5 E1 0.368 6 -238NP2 G KC=$LC=0.277 4$MC=0.0684 10 -238NP G 109.61 1 1840E-5 0 M1+E2 1.0 2 6.7 7 -238NP2 G KC=$LC=4.9 5$MC=1.32 14 -238NP G 126.92 1 0.00013 7 E2 5.03 7 -238NP2 G KC=0.196 3$LC=3.51 5$MC=0.979 14 -238NP G 163.29 1 1610E-5 0 M1+E2 1.0 2 3.9 5 -238NP2 G KC=2.5 5$LC=1.04 3$MC=0.272 11 +238NP G 66.92 1 0.0150 5E1 0.368 6 +238NP2 G LC=0.277 4$MC=0.0684 10 +238NP G 109.61 1 0.0184 M1+E2 1.0 2 6.7 7 +238NP2 G LC=4.9 5$MC=1.32 14 +238NP G 126.92 1 0.00013 7E2 5.03 7 +238NP2 G KC=0.196 3$LC=3.51 5$MC=0.979 14 +238NP G 163.29 1 0.0161 M1+E2 1.0 2 3.9 5 +238NP2 G KC=2.5 5$LC=1.04 3$MC=0.272 11 238NP G 206.39 1 0.00156 18E2 0.711 10 -238NP2 G KC=0.1454 21$LC=0.412 6$MC=0.1138 16 -238NP G 280.11 1 6.0E-5 6 E1 0.0468 7 -238NP2 G KC=0.0371 6$LC=0.00735 11$MC=0.00178 3 +238NP2 G KC=0.1454 21$LC=0.412 6$MC=0.1138 16 +238NP G 280.11 1 0.000060 6E1 0.0468 7 +238NP2 G KC=0.0371 6$LC=0.00735 11$MC=0.00178 3 238NP L 374.7 10(5)+ 238NP A 5175.4 100.020 115000 238NP L 376.70 7 (6)- 238NP A 5173.45 260.020 114900 -238NP G 270.55 7 2.9E-5 8 E1 0.0506 7 -238NP2 G KC=0.0400 6$LC=0.00798 12$MC=0.00193 3 +238NP G 270.55 7 0.000029 8E1 0.0506 7 +238NP2 G KC=0.0400 6$LC=0.00798 12$MC=0.00193 3 238NP L 389.4 5 7+ -238NP G 170.7 8 0.00063 5 M1+E2 1.0 2 3.4 5 -238NP2 G KC=2.2 5$LC=0.882 23$MC=0.230 9 +238NP G 170.7 8 0.00063 5M1+E2 1.0 2 3.4 5 +238NP2 G KC=2.2 5$LC=0.882 23$MC=0.230 9 238NP L 397.3 15 + 238NP A 5153.2 150.020 113600 238NP L 407.59 6 6- 238NP A 5143.07 265.61 2411.2 -238NP G 174.76 6 0.00017 4 M1+E2 1.0 2 3.1 4 -238NP2 G KC=2.1 5$LC=0.809 17$MC=0.211 7 +238NP G 174.76 6 0.00017 4M1+E2 1.0 2 3.1 4 +238NP2 G KC=2.1 5$LC=0.809 17$MC=0.211 7 238NP L 459.6 6 (6)+ 238NP A 5091.9 7 0.20 7 146 238NP L 469.1 12(1 to 4)- diff --git a/HEN_HOUSE/spectra/lnhb/Am-243.txt b/HEN_HOUSE/spectra/lnhb/Am-243.txt index 245a7cadc..dec53f06d 100644 --- a/HEN_HOUSE/spectra/lnhb/Am-243.txt +++ b/HEN_HOUSE/spectra/lnhb/Am-243.txt @@ -2,75 +2,75 @@ 239NP H TYP=Update$AUT=M.M. Bé$CUT=30-APR-2009$ 239NP C Evaluation history: Type=Update;Author=M.M. Bé;Cutoff date=30-APR-2009 239NP C References: 2004BeZQ, 1977La19, 1998Ya17, 2007Ag02, 2008Ki07 -239NP T Auger electrons and ^X ray energies and emission intensities: -239NP T {U Energy (keV)} {U Intensity } {U Line } +239NP T Auger electrons and X ray energies and emission intensities: +239NP T {U Energy (keV)} {U Intensity} {U Line} 239NP T -239NP T 97.069 0.0058 4 XKA2 -239NP T 101.059 0.0092 7 XKA1 +239NP T 97.069 0.0058 4 XKA2 +239NP T 101.059 0.0092 7 XKA1 239NP T -239NP T 113.303 |] XKB3 -239NP T 114.234 |] 0.00335 25 XKB1 -239NP T 114.912 |] XKB5II +239NP T 113.303 |] XKB3 +239NP T 114.234 |] 0.00335 25 XKB1 +239NP T 114.912 |] XKB5II 239NP T -239NP T 117.463 |] XKB2 -239NP T 117.876 |] 0.00115 9 XKB4 -239NP T 118.429 |] XKO23 +239NP T 117.463 |] XKB2 +239NP T 117.876 |] 0.00115 9 XKB4 +239NP T 118.429 |] XKO23 239NP T -239NP T 11.871-21.491 18.9 7 XL (total) -239NP T 11.871 0.465 25 XLL -239NP T 13.671-13.946 7.4 4 XLA -239NP T 15.861 0.143 10 XLC -239NP T 16.109-17.992 8.7 4 XLB -239NP T 20.784-21.491 2.10 9 XLG +239NP T 11.871-21.491 18.9 7 XL (total) +239NP T 11.871 0.465 25 XLL +239NP T 13.671-13.946 7.4 4 XLA +239NP T 15.861 0.143 10 XLC +239NP T 16.109-17.992 8.7 4 XLB +239NP T 20.784-21.491 2.10 9 XLG 239NP T -239NP T 73.501-83.134 |] KLL AUGER -239NP T 90.358-101.054 |] 0.00058 9 ^KLX AUGER -239NP T 107.19-118.66 |] KXY AUGER -239NP T 6.04-13.52 18.4 11 L AUGER +239NP T 73.501-83.134 |] KLL AUGER +239NP T 90.358-101.054 |] 0.00058 9 KLX AUGER +239NP T 107.19-118.66 |] KXY AUGER +239NP T 6.04-13.52 18.4 11 L AUGER 243AM P 0.0 5/2- 7367 Y 23 5438.8 10 239NP N 1.0 1.0 1 1.0 239NP L 0 5/2+ 2.356 D 3 239NP A 5349.4 230.240 3 1120 239NP L 31.130 217/2+ 239NP A 5321 1 0.192 3 95 -239NP G 31.14 3 0.048 11M1+E2 0.17 1 263 13 -239NP2 G KC=$LC=195 10$MC=50 3 +239NP G 31.140 300.048 11M1+E2 0.17 1 263 13 +239NP2 G LC=195 10$MC=50 3 239NP L 71 9/2+ 239NP L 74.660 185/2- 1.39 NS 3 239NP A 5275.3 1086.74 5 1.14 239NP G 43.53 2 5.89 10E1 1.143 16 -239NP2 G KC=$LC=0.856 12$MC=0.215 3 -239NP G 74.66 2 67.2 12E1 0.276 4 -239NP2 G KC=$LC=0.207 3$MC=0.0512 8 +239NP2 G LC=0.856 12$MC=0.215 3 +239NP G 74.66 2 67.2 12E1 0.276 4 +239NP2 G LC=0.207 3$MC=0.0512 8 239NP L 117.84 3 7/2- 0.04 NS 239NP A 5233.3 1011.46 5 4.71 -239NP G 43.1 6500E-5 0 M1+E2 0.38 4 154 18 -239NP2 G KC=$LC=114 13$MC=30 4 -239NP G 86.71 2 0.346 9 E1 0.186 3 -239NP2 G KC=$LC=0.1401 20$MC=0.0345 5 -239NP G 117.60 150.57 5 E1 0.0842 13 -239NP2 G KC=$LC=0.0634 10$MC=0.01551 23 +239NP G 43.1 0.065 M1+E2 0.38 4 154 18 +239NP2 G LC=114 13$MC=30 4 +239NP G 86.71 2 0.346 9E1 0.186 3 +239NP2 G LC=0.1401 20$MC=0.0345 5 +239NP G 117.60 150.57 5E1 0.0842 13 +239NP2 G LC=0.0634 10$MC=0.01551 23 239NP L 122.4 10(11/2)+ 239NP L 173.02 4 9/2- 239NP A 5181 1 1.383 7 17.7 -239NP G 50.6 100.0062 10(E1) 0.77 5 -239NP2 G KC=$LC=0.58 4$MC=0.144 9 +239NP G 50.6 100.0062 10(E1) 0.77 5 +239NP2 G LC=0.58 4$MC=0.144 9 239NP G 55.18 5 0.0168 11M1+E2 0.75 10 107 14 -239NP2 G KC=$LC=78 10$MC=21 3 -239NP G 98.5 2 0.0151 21(E2) 15.6 3 -239NP2 G KC=$LC=11.31 20$MC=3.15 6 -239NP G 141.90 6 0.115 8 E1 0.224 4 -239NP2 G KC=0.1723 25$LC=0.0391 6$MC=0.00955 14 +239NP2 G LC=78 10$MC=21 3 +239NP G 98.50 200.0151 21(E2) 15.6 3 +239NP2 G LC=11.31 20$MC=3.15 6 +239NP G 141.90 6 0.115 8E1 0.224 4 +239NP2 G KC=0.1723 25$LC=0.0391 6$MC=0.00955 14 239NP L 240 (11/2)- 239NP A 5113 1 0.010 1 900 -239NP G 169 1200E-6 0 (E1) 0.149 3 -239NP2 G KC=0.1156 23$LC=0.0251 6$MC=0.00612 13 +239NP G 169 0.0012 (E1) 0.149 3 +239NP2 G KC=0.1156 23$LC=0.0251 6$MC=0.00612 13 239NP L 267 3 (5/2)+ 239NP A 5088 5 0.0055 6 1100 239NP L 317.4 15(13/2)- 239NP A 5035 3 0.0020 6 -239NP G 195.0 188500E-7 0 (E1) 0.107 3 -239NP2 G KC=0.0833 22$LC=0.0176 5$MC=0.00428 12 +239NP G 195.0 180.00085 (E1) 0.107 3 +239NP2 G KC=0.0833 22$LC=0.0176 5$MC=0.00428 12 239NP L 325 3 (5/2)- 239NP A 5029 3 0.0020 6 700 239NP L 347 3 (7/2,9/2)+ diff --git a/HEN_HOUSE/spectra/lnhb/Am-244.txt b/HEN_HOUSE/spectra/lnhb/Am-244.txt index 7c3d13dab..ef073d21b 100644 --- a/HEN_HOUSE/spectra/lnhb/Am-244.txt +++ b/HEN_HOUSE/spectra/lnhb/Am-244.txt @@ -3,53 +3,53 @@ 244CM C Evaluation history: Type=Full;Author=A.L. Nichols;Cutoff date=28-FEB-2009 244CM C References: 1962Va08, 1963Ha29, 1967Sc34, 1977La19, 1984Ho02, 1996Sc06, 244CM2C 1998ScZM, 1999ScZX, 2002Ra45, 2002Ba25, 2003Au03, 2003Ak04, 2008Ki07 -244CM T Auger electrons and ^X ray energies and emission intensities: -244CM T {U Energy (keV)} {U Intensity } {U Line } +244CM T Auger electrons and X ray energies and emission intensities: +244CM T {U Energy (keV)} {U Intensity} {U Line} 244CM T -244CM T 104.59 2.2 3 XKA2 -244CM T 109.271 3.4 4 XKA1 +244CM T 104.59 2.2 3 XKA2 +244CM T 109.271 3.4 4 XKA1 244CM T -244CM T 122.304 |] XKB3 -244CM T 123.403 |] 1.29 16 XKB1 -244CM T 124.124 |] XKB5II +244CM T 122.304 |] XKB3 +244CM T 123.403 |] 1.29 16 XKB1 +244CM T 124.124 |] XKB5II 244CM T -244CM T 126.889 |] XKB2 -244CM T 127.352 |] 0.45 6 XKB4 -244CM T 127.97 |] XKO23 +244CM T 126.889 |] XKB2 +244CM T 127.352 |] 0.45 6 XKB4 +244CM T 127.97 |] XKO23 244CM T -244CM T 12.633-23.527 100 10 XL (total) -244CM T 12.633 2.36 24 XLL -244CM T 14.746-14.961 36 4 XLA -244CM T 17.314 1.15 15 XLC -244CM T 17.286-19.688 51 5 XLB -244CM T 22.735-23.527 12 13 XLG +244CM T 12.633-23.527 100 10 XL (total) +244CM T 12.633 2.36 24 XLL +244CM T 14.746-14.961 36 4 XLA +244CM T 17.314 1.15 15 XLC +244CM T 17.286-19.688 51 5 XLB +244CM T 22.735-23.527 12 13 XLG 244CM T -244CM T 78.858-89.973 |] KLL AUGER -244CM T 97.226-109.267 |] 0.213 27 ^KLX AUGER -244CM T 115.57-128.23 |] KXY AUGER -244CM T 6.19-14.46 86 9 L AUGER +244CM T 78.858-89.973 |] KLL AUGER +244CM T 97.226-109.267 |] 0.213 27 KLX AUGER +244CM T 115.57-128.23 |] KXY AUGER +244CM T 6.19-14.46 86 9 L AUGER 244AM P 0.0 6- 10.1 H 1 1427.3 10 244CM N 1.0 1.0 1 1.0 244CM L 0 0+ 18.11 Y 3 244CM L 42.965 102+ 244CM G 42.965 100.096 20E2 1050 15 -244CM2 G KC=$LC=760 11$MC=214 3 +244CM2 G LC=760 11$MC=214 3 244CM L 142.348 114+ -244CM G 99.383 4 5.0 11E2 19.3 3 -244CM2 G KC=$LC=13.93 20$MC=3.94 6 +244CM G 99.383 4 5.0 11E2 19.3 3 +244CM2 G LC=13.93 20$MC=3.94 6 244CM L 296.211 116+ -244CM G 153.863 2 19 4 E2 2.81 4 -244CM2 G KC=0.1741 25$LC=1.90 3$MC=0.536 8 +244CM G 153.863 2 19 4E2 2.81 4 +244CM2 G KC=0.1741 25$LC=1.90 3$MC=0.536 8 244CM L 501.786 128+ -244CM G 205.575 4 0.35 8 E2 0.887 13 -244CM2 G KC=0.1409 20$LC=0.541 8$MC=0.1514 22 +244CM G 205.575 4 0.35 8E2 0.887 13 +244CM2 G KC=0.1409 20$LC=0.541 8$MC=0.1514 22 244CM L 1040.188 126+ 34 MS 2 244CM B 387.1 10100 5.63 244CMS B EAV=109.6 3 -244CM G 538.402 160.66 19E2 0.0495 7 -244CM2 G KC=0.0292 4$LC=0.01492 21$MC=0.00396 6 -244CM G 743.977 5 66 8 M1+E2 -0.92 8 0.077 5 -244CM2 G KC=0.059 4$LC=0.0130 7$MC=0.00321 15 -244CM G 897.840 7 28 8 E2 0.0169724 -244CM2 G KC=0.01215 17$LC=0.00358 5$MC=9.12E-4 13 +244CM G 538.402 160.66 19E2 0.0495 7 +244CM2 G KC=0.0292 4$LC=0.01492 21$MC=0.00396 6 +244CM G 743.977 5 66 8M1+E2 -0.92 8 0.077 5 +244CM2 G KC=0.059 4$LC=0.0130 7$MC=0.00321 15 +244CM G 897.840 7 28 8E2 0.0169724 +244CM2 G KC=0.01215 17$LC=0.00358 5$MC=9.12E-4 13 diff --git a/HEN_HOUSE/spectra/lnhb/Am-244m.txt b/HEN_HOUSE/spectra/lnhb/Am-244m.txt index 7802dfde8..e3da61b32 100644 --- a/HEN_HOUSE/spectra/lnhb/Am-244m.txt +++ b/HEN_HOUSE/spectra/lnhb/Am-244m.txt @@ -1,7 +1,7 @@ 244PU 244AM EC DECAY (26 M) 244PU C References: 1950St61, 1954Gh24, 1955Fi36, 1962Va08, 1964Va04, 1976Ga31, -244PU2C 1977La19, 1984Vo07, 1984Ho02, 1996Sc06, 1998ScZM, 1999SzZX, 2002Ra45, -244PU3C 2002Ba85, 2003Ak04, 2003Au03, 2008Ki07 +244PU2C 1977La19, 1984Vo07, 1984Ho02, 1996Sc06, 1998ScZM, 1999SzZX, 2002Ba85, +244PU3C 2002Ra45, 2003Ak04, 2003Au03, 2008Ki07 244PU T Auger electrons and X ray energies and emission intensities: 244PU T {U Energy (keV)} {U Intensity} {U Line} 244PU T @@ -18,54 +18,54 @@ 244PU T 244PU T 244PU T 75.263-85.357 |] KLL AUGER -244PU T 92.607-103.729 |] 2.53E-4 45 KLX AUGER +244PU T 92.607-103.729 |] 0.00025345 KLX AUGER 244PU T 109.93-121.78 |] KXY AUGER 244PU T 6.19-22.99 0.0124 11 L AUGER -244AM P 89 2 0+ 26 M 3 75 9 +244AM P 0.0 0+ 26 M 3 164 9 244PU N 2.778E3 2.778E3 0.00036 2.778E3 -244PU L 0 0+ STABLE -244PU E 0.036 1 6.37 -244PU2 E EAV= $CK=0.24 5$CL=0.53 4$CM=0.168 12$CN=0.050 4$CO= +244PU L 0 0+ 80.0E6 Y 9 +244PU E 0.036 16.37 +244PU2 E CK=0.24 5$CL=0.53 4$CM=0.168 12$CN=0.050 4 244CM 244AM B- DECAY (26 M) 244CM C References: 1950St61, 1954Gh24, 1955Fi36, 1962Va08, 1964Va04, 1976Ga31, -244CM2C 1977La19, 1984Vo07, 1984Ho02, 1996Sc06, 1998ScZM, 1999SzZX, 2002Ra45, -244CM3C 2002Ba85, 2003Ak04, 2003Au03, 2008Ki07 +244CM2C 1977La19, 1984Vo07, 1984Ho02, 1996Sc06, 1998ScZM, 1999SzZX, 2002Ba85, +244CM3C 2002Ra45, 2003Ak04, 2003Au03, 2008Ki07 244CM T Auger electrons and X ray energies and emission intensities: 244CM T {U Energy (keV)} {U Intensity} {U Line} 244CM T -244CM T 104.59 0.013 4 XKA2 -244CM T 109.271 0.020 6 XKA1 +244CM T 104.59 0.013 4 XKA2 +244CM T 109.271 0.020 6 XKA1 244CM T 244CM T 122.304 |] XKB3 244CM T 123.403 |] 0.0076 21 XKB1 244CM T 124.124 |] XKB5II 244CM T 244CM T 126.889 |] XKB2 -244CM T 127.352 |] 0.0027 8 XKB4 +244CM T 127.352 |] 0.0027 8 XKB4 244CM T 127.97 |] XKO23 244CM T 244CM T 12.633-23.527 12.3 27 XL (total) -244CM T 12.633 0.31 8 XLL +244CM T 12.633 0.31 8 XLL 244CM T 14.746-14.961 4.6 11 XLA -244CM T 17.314 0.13 4 XLC +244CM T 17.314 0.13 4 XLC 244CM T 17.286-19.688 6.0 14 XLB -244CM T 22.735-23.527 1.4 4 XLG +244CM T 22.735-23.527 1.4 4 XLG 244CM T 244CM T 78.858-89.973 |] KLL AUGER 244CM T 97.226-109.267 |] 0.00125 27 KLX AUGER 244CM T 115.57-128.23 |] KXY AUGER 244CM T 6.19-14.46 10.6 23 L AUGER -244AM P 89 2 0+ 26 M 3 1427.0 36 +244AM P 0.0 0+ 26 M 3 1516 3 244CM N 1.00E0 1.00E0 0.99964 1.00E0 -244CM L 0 0+ STABLE -244CM B 1516 3 67 9 6.45 +244CM L 0 0+ 18.11 Y 3 +244CM B 1516 3 67 9 6.45 244CMS B EAV=512.3 9 244CM L 42.965 102+ -244CM B 1473 3 31 9 6.74 2 +244CM B 1473 3 31 9 6.74 2 244CMS B EAV=495.8 9 -244CM G 42.965 100.030 9 E2 1050 15 -244CM2 G KC=$LC=760 11$MC=214 3 +244CM G 42.965 100.030 9E2 1050 15 +244CM2 G LC=760 11$MC=214 3 244CM L 142.348 114+ 244CM L 296.211 116+ 244CM L 501.786 128+ @@ -74,10 +74,10 @@ 244CM B 531.1 301.36 16 6.58 244CMS B EAV=155.7 7 244CM G 941.95 3 0.35 12E2 0.0154722 -244CM2 G KC=0.01120 16$LC=0.00318 5$MC=8.07E-4 12 +244CM2 G KC=0.01120 16$LC=0.00318 5$MC=8.07E-4 12 244CM G 984.91 2 244CM L 1020.76 3 (2)+ -244CM B 496 3 0.08 2 7.7 2 +244CM B 496 3 0.08 2 7.7 2 244CMS B EAV=144.0 7 244CM G 977.80 4 (+M1+E2) 244CM L 1038 6 (2+, 3-)+ @@ -85,14 +85,14 @@ 244CM L 1084.181 141, 2+ 244CM B 432 3 0.56 13 6.67 244CMS B EAV=123.7 7 -244CM G 1041.22 3 0.19 6 (M1+E2) +244CM G 1041.22 3 0.19 6(M1+E2) 244CM G 1084.181 140.36 12(E2) 0.041 11 -244CM2 G KC=0.030 8$LC=0.008 2$MC=0.0020 1 +244CM2 G KC=0.030 8$LC=0.008 2$MC=0.0020 1 244CM L 1105.91 2 (1, 2)- -244CM B 410 3 0.35 9 6.8 1 +244CM B 410 3 0.35 9 6.8 1 244CMS B EAV=116.9 7 -244CM G 1062.95 3 0.27 8 E1 0.11 3 -244CM2 G KC=0.09 3$LC=0.015 4$MC=0.0032 1 -244CM G 1105.91 2 0.04 2 (E1) 0.17 4 -244CM2 G KC=0.14 3$LC=0.024 6$MC=0.0058 1 +244CM G 1062.95 3 0.27 8E1 0.11 3 +244CM2 G KC=0.09 3$LC=0.015 4$MC=0.0032 1 +244CM G 1105.91 2 0.04 2(E1) 0.17 4 +244CM2 G KC=0.14 3$LC=0.024 6$MC=0.0058 1 diff --git a/HEN_HOUSE/spectra/lnhb/Ar-37.txt b/HEN_HOUSE/spectra/lnhb/Ar-37.txt index 0ace73dc4..b28ccea7a 100644 --- a/HEN_HOUSE/spectra/lnhb/Ar-37.txt +++ b/HEN_HOUSE/spectra/lnhb/Ar-37.txt @@ -4,26 +4,26 @@ 37CL C References: 1944We**, 1952Mi**, 1959Ki41, 1965St09, 1972Dz09, 1973Co26, 37CL2C 1975Ki10, 1986BrZQ, 1996Sc06, 1998Bo30, 1998Sc28, 1998En04, 2000Sc47, 37CL3C 2001Re01, 2003Au03, 2011Ch65, 2012Au06 - 37CL T Auger electrons and ^X ray energies and emission intensities: - 37CL T {U Energy (keV)} {U Intensity } {U Line } + 37CL T Auger electrons and X ray energies and emission intensities: + 37CL T {U Energy (keV)} {U Intensity} {U Line} 37CL T - 37CL T 2.6208 2.76 7 XKA2 - 37CL T 2.62241 5.46 14 XKA1 + 37CL T 2.6208 2.76 7 XKA2 + 37CL T 2.62241 5.46 14 XKA1 37CL T - 37CL T 2.8156 |] 0.71 4 XKB1 + 37CL T 2.8156 |] 0.71 4 XKB1 37CL T 37CL T - 37CL T 0.1833-0.2681 0.20 4 XL (total) + 37CL T 0.1833-0.2681 0.20 4 XL (total) 37CL T 0.1833 XLL 37CL T -0.2681 XLB 37CL T - 37CL T 2.241-2.384 |] KLL AUGER - 37CL T 2.535-2.616 |] 81.3 3 ^KLX AUGER - 37CL T 2.787-2.809 |] KXY AUGER - 37CL T 0.165-0.257 166.49 21 L AUGER + 37CL T 2.241-2.384 |] KLL AUGER + 37CL T 2.535-2.616 |] 81.3 3 KLX AUGER + 37CL T 2.787-2.809 |] KXY AUGER + 37CL T 0.165-0.257 166.49 21 L AUGER 37AR P 0.0 3/2+ 35.01 D 2 813.87 20 37CL N 1.0 1.0 1 1.0 37CL L 0 0 3/2+ STABLE 37CL E 100 5.1 - 37CL2 E EAV= $CK=0.9021 24$CL=0.0872 20$CM=0.0106 7$CN=0 $CO=0 + 37CL2 E CK=0.9021 24$CL=0.0872 20$CM=0.0106 7$CN=0 $CO=0 diff --git a/HEN_HOUSE/spectra/lnhb/Ar-41.txt b/HEN_HOUSE/spectra/lnhb/Ar-41.txt index 1d2d60a00..eeb31be61 100644 --- a/HEN_HOUSE/spectra/lnhb/Ar-41.txt +++ b/HEN_HOUSE/spectra/lnhb/Ar-41.txt @@ -7,26 +7,26 @@ 41K 2C 1962En05, 1964Pa03, 1965Pr05, 1969Bo11, 1971Ju04, 1978Eg01, 1978En23, 41K 3C 1986Ru09, 1990En08, 1990Ab06, 1996Sc06, 2001Ca59, 2002Ba85, 2003Au03, 41K 4C 2008Ki07 - 41K T Auger electrons and ^X ray energies and emission intensities: - 41K T {U Energy (keV)} {U Intensity } {U Line } + 41K T Auger electrons and X ray energies and emission intensities: + 41K T {U Energy (keV)} {U Intensity} {U Line} 41K T - 41K T 3.3111 0.000270 9 XKA2 - 41K T 3.3138 0.000533 17 XKA1 + 41K T 3.3111 0.000270 9 XKA2 + 41K T 3.3138 0.00053317 XKA1 41K T - 41K T 3.5896 |] 0.000098 4 XKB1 - 41K T 3.6028 |] XKB5II + 41K T 3.5896 |] 0.000098 4 XKB1 + 41K T 3.6028 |] XKB5II 41K T 41K T 41AR P 0.0 7/2- 1.8268 H 6 2491.6 4 41K N 1.0 1.0 1 1.0 41K L 0 3/2+ STABLE - 41K B 2491.6 4 0.784 19 9.72 3U + 41K B 2491.6 4 0.78 19 9.72 1U 41K S B EAV=1076.6 2 41K L 1293.64 4 7/2- 6.7 NS 5 41K B 1197.96 4099.165 20 5.05 41K S B EAV=459.18 18 41K G 1293.64 4 99.157 20M2+E3 0.118 12 7.44E-511 - 41K 2 G KC=6.36E-5 9$LC=5.34E-6 8$MC=5.80E-7 9 + 41K 2 G KC=6.36E-5 9$LC=5.34E-6 8$MC=5.80E-7 9 41K L 1677.0 3 7/2+ 41K B 814.6 4 0.0515 49 7.68 41K S B EAV=293.9 2 diff --git a/HEN_HOUSE/spectra/lnhb/At-211.txt b/HEN_HOUSE/spectra/lnhb/At-211.txt index c0d5f0186..bad7c3b76 100644 --- a/HEN_HOUSE/spectra/lnhb/At-211.txt +++ b/HEN_HOUSE/spectra/lnhb/At-211.txt @@ -5,41 +5,41 @@ 211PO2C 1969Go23, 1970As07, 1970AfZZ, 1975Ja04, 1977La19, 1978Sc12, 1978Ya04, 211PO3C 1983He09, 1985La17, 1991Ry01, 1996Sc06, 1998Ak04, 1998ScZM, 1999ScZX, 211PO4C 2001Ch66, 2002Ba85, 2002Ra45, 2003Au03, 2004Br45, 2008Ki07 -211PO T Auger electrons and ^X ray energies and emission intensities: -211PO T {U Energy (keV)} {U Intensity } {U Line } +211PO T Auger electrons and X ray energies and emission intensities: +211PO T {U Energy (keV)} {U Intensity} {U Line} 211PO T -211PO T 76.864 12.66 9 XKA2 -211PO T 79.293 21.08 12 XKA1 +211PO T 76.864 12.66 9 XKA2 +211PO T 79.293 21.08 12 XKA1 211PO T -211PO T 89.256 |] XKB3 -211PO T 89.807 |] 7.26 12 XKB1 -211PO T 90.363 |] XKB5II +211PO T 89.256 |] XKB3 +211PO T 89.807 |] 7.26 12 XKB1 +211PO T 90.363 |] XKB5II 211PO T -211PO T 92.263 |] XKB2 -211PO T 92.618 |] 2.26 5 XKB4 -211PO T 92.983 |] XKO23 +211PO T 92.263 |] XKB2 +211PO T 92.618 |] 2.26 5 XKB4 +211PO T 92.983 |] XKO23 211PO T -211PO T 9.658-16.213 18.6 8 XL (total) -211PO T 9.658 0.465 12 XLL -211PO T 11.016-11.13 8.53 20 XLA -211PO T 12.085 0.134 4 XLC -211PO T 12.823-13.778 7.76 14 XLB -211PO T 15.742-16.213 1.53 3 XLG +211PO T 9.658-16.213 18.6 8 XL (total) +211PO T 9.658 0.465 12 XLL +211PO T 11.016-11.13 8.53 20 XLA +211PO T 12.085 0.134 4 XLC +211PO T 12.823-13.778 7.76 14 XLB +211PO T 15.742-16.213 1.53 3 XLG 211PO T -211PO T 58.978-65.205 |] KLL AUGER -211PO T 71.902-79.289 |] 1.57 18 ^KLX AUGER -211PO T 84.8-93.1 |] KXY AUGER -211PO T 5.434-10.934 27.6 8 L AUGER +211PO T 58.978-65.205 |] KLL AUGER +211PO T 71.902-79.289 |] 1.57 18 KLX AUGER +211PO T 84.8-93.1 |] KXY AUGER +211PO T 5.434-10.934 27.6 8 L AUGER 211AT P 0.0 9/2- 7.216 H 7 785.4 25 211PO N 1.718E0 1.718E0 0.5822 1.718E0 211PO L 0 9/2+ 0.516 S 3 -211PO E 57.96 8 5.97 -211PO2 E EAV= $CK=0.7731 2$CL=0.1693 1$CM=0.05758 4$CN= $CO= +211PO E 57.96 85.97 +211PO2 E CK=0.7731 2$CL=0.1693 1$CM=0.05758 4 211PO L 687.2 7 11/2+ -211PO E 0.258 135.77 1U -211PO2 E EAV= $CK=0.015 17$CL=0.684 10$CM=0.301 7$CN= $CO= -211PO G 687.2 7 0.245 12(M1+E2] -0.20 2 0.0536 9 -211PO2 G KC=0.0437 7$LC=0.00752 12$MC=0.00177 3 +211PO E 0.258 135.77 1 +211PO2 E CK=0.015 17$CL=0.684 10$CM=0.301 7 +211PO G 687.2 7 0.245 12(M1+E2] -0.20 2 0.0536 9 +211PO2 G KC=0.0437 7$LC=0.00752 12$MC=0.00177 3 207BI 211AT A DECAY (7.216 H) 207BI H TYP=Full$AUT=A.L. Nichols$CUT=30-AUG-2010$ @@ -48,51 +48,51 @@ 207BI2C 1969Go23, 1970As07, 1970AfZZ, 1975Ja04, 1977La19, 1978Sc12, 1978Ya04, 207BI3C 1983He09, 1985La17, 1991Ry01, 1996Sc06, 1998Ak04, 1998ScZM, 1999ScZX, 207BI4C 2001Ch66, 2002Ba85, 2002Ra45, 2003Au03, 2004Br45, 2008Ki07 -207BI T Auger electrons and ^X ray energies and emission intensities: -207BI T {U Energy (keV)} {U Intensity } {U Line } +207BI T Auger electrons and X ray energies and emission intensities: +207BI T {U Energy (keV)} {U Intensity} {U Line} 207BI T -207BI T 74.8157 0.000098 15 XKA2 -207BI T 77.1088 0.000164 25 XKA1 +207BI T 74.8157 0.00009815 XKA2 +207BI T 77.1088 0.00016425 XKA1 207BI T -207BI T 86.835 |] XKB3 -207BI T 87.344 |] 0.000056 9 XKB1 -207BI T 87.862 |] XKB5II +207BI T 86.835 |] XKB3 +207BI T 87.344 |] 0.000056 9 XKB1 +207BI T 87.862 |] XKB5II 207BI T -207BI T 89.732 |] XKB2 -207BI T 90.074 |] 0.000017 3 XKB4 -207BI T 90.421 |] XKO23 +207BI T 89.732 |] XKB2 +207BI T 90.074 |] 0.000017 3 XKB4 +207BI T 90.421 |] XKO23 207BI T -207BI T 9.42-15.709 0.000136 14 XL (total) -207BI T 9.42 0.0000033 4 XLL -207BI T 10.731-10.839 0.000063 7 XLA -207BI T 11.712 0.00000103 15 XLC -207BI T 12.48-13.393 0.000057 6 XLB -207BI T 15.248-15.709 0.0000110 12 XLG +207BI T 9.42-15.709 0.00013614 XL (total) +207BI T 9.42 3.3E-6 4 XLL +207BI T 10.731-10.839 0.000063 7 XLA +207BI T 11.712 1.03E-6 15 XLC +207BI T 12.48-13.393 0.000057 6 XLB +207BI T 15.248-15.709 1.10E-5 12 XLG 207BI T -207BI T 57.491-63.419 |] KLL AUGER -207BI T 70.025-77.105 |] 0.0000126 24 ^KLX AUGER -207BI T 82.53-90.52 |] KXY AUGER -207BI T 5.35-10.66 0.000211 20 L AUGER +207BI T 57.491-63.419 |] KLL AUGER +207BI T 70.025-77.105 |] 1.26E-5 24 KLX AUGER +207BI T 82.53-90.52 |] KXY AUGER +207BI T 5.35-10.66 0.00021120 L AUGER 211AT P 0.0 9/2- 7.216 H 7 5982.4 13 207BI N 2.393E0 2.393E0 0.4178 2.393E0 207BI L 0 9/2- 32.9 Y 14 207BI A 5869.0 13100.00 191.59 207BI L 669.77 7 11/2- 207BI A 5211.9 130.0093 7 7.3 -207BI G 669.77 7 0.0038 3 [M1+E2] 0.25 3 0.0520 9 -207BI2 G KC=0.0426 8$LC=0.00725 12$MC=0.00170 3 +207BI G 669.77 7 0.0038 3[M1+E2] 0.25 3 0.0520 9 +207BI2 G KC=0.0426 8$LC=0.00725 12$MC=0.00170 3 207BI L 742.74 7 7/2- 207BI A 5140.3 130.00263 4810.1 -207BI G 742.74 7 0.00125 19[M1+E2] 0.30 3 0.0391 7 -207BI2 G KC=0.0320 6$LC=0.00544 10$MC=1276E-6 22 +207BI G 742.74 7 0.00125 19[M1+E2] 0.30 3 0.0391 7 +207BI2 G KC=0.0320 6$LC=0.00544 10$MC=1276E-6 22 207BI L 892.46 7 9/2- 207BI A 4993.4 1395740E-8 3.8 -207BI G 149.72 105000E-8 0 M1+E2 0.4 2 3.0 3 -207BI2 G KC=2.3 3$LC=0.50 4$MC=0.120 12 -207BI G 222.69 104000E-8 0 M1+E2 0.4 1 0.95 5 -207BI2 G KC=0.76 5$LC=0.1473 23$MC=0.0351 5 -207BI G 892.46 7 1400E-7 0 [M1+E2] 1.4 2 0.0145 13 -207BI2 G KC=0.0117 11$LC=0.00215 16$MC=0.00051 4 +207BI G 149.72 100.00005 M1+E2 0.4 2 3.0 3 +207BI2 G KC=2.3 3$LC=0.50 4$MC=0.120 12 +207BI G 222.69 100.00004 M1+E2 0.4 1 0.95 5 +207BI2 G KC=0.76 5$LC=0.1473 23$MC=0.0351 5 +207BI G 892.46 7 0.00014 [M1+E2] 1.4 2 0.0145 13 +207BI2 G KC=0.0117 11$LC=0.00215 16$MC=0.00051 4 207BI L 992.43 7 7/2- 207BI A 4895.4 1395740E-9 9.6 diff --git a/HEN_HOUSE/spectra/lnhb/At-215.txt b/HEN_HOUSE/spectra/lnhb/At-215.txt index 18b60c130..701e6ec00 100644 --- a/HEN_HOUSE/spectra/lnhb/At-215.txt +++ b/HEN_HOUSE/spectra/lnhb/At-215.txt @@ -3,37 +3,37 @@ 211BI C Evaluation history: Type=Full;Author=V.P. Chechev;Cutoff date=15-DEC-2010 211BI C References: 1951Me10, 1966Gr07, 1982Bo04, 1991Ry01, 2003Au03, 2004Br45, 211BI2C 2008Ki07 -211BI T Auger electrons and ^X ray energies and emission intensities: -211BI T {U Energy (keV)} {U Intensity } {U Line } +211BI T Auger electrons and X ray energies and emission intensities: +211BI T {U Energy (keV)} {U Intensity} {U Line} 211BI T -211BI T 74.8157 0.0012 5 XKA2 -211BI T 77.1088 0.0020 9 XKA1 +211BI T 74.8157 0.0012 5 XKA2 +211BI T 77.1088 0.0020 9 XKA1 211BI T -211BI T 86.835 |] XKB3 -211BI T 87.344 |] 0.00069 28 XKB1 -211BI T 87.862 |] XKB5II +211BI T 86.835 |] XKB3 +211BI T 87.344 |] 0.00069 28 XKB1 +211BI T 87.862 |] XKB5II 211BI T -211BI T 89.732 |] XKB2 -211BI T 90.074 |] 0.00021 9 XKB4 -211BI T 90.421 |] XKO23 +211BI T 89.732 |] XKB2 +211BI T 90.074 |] 0.00021 9 XKB4 +211BI T 90.421 |] XKO23 211BI T -211BI T 9.4207-15.7084 0.0017 4 XL (total) -211BI T 9.4207 0.000042 13 XLL -211BI T 10.7308-10.8387 0.00078 22 XLA -211BI T 11.7127 0.000013 5 XLC -211BI T 12.4814-13.8066 0.00073 18 XLB -211BI T 14.7735-15.7084 0.00014 4 XLG +211BI T 9.4207-15.7084 0.0017 4 XL (total) +211BI T 9.4207 0.00004213 XLL +211BI T 10.7308-10.8387 0.00078 22 XLA +211BI T 11.7127 0.000013 5 XLC +211BI T 12.4814-13.8066 0.00073 18 XLB +211BI T 14.7735-15.7084 0.00014 4 XLG 211BI T -211BI T 57.491-63.419 |] KLL AUGER -211BI T 70.025-77.105 |] 0.00015 7 ^KLX AUGER -211BI T 82.53-90.52 |] KXY AUGER -211BI T 5.42-16.34 0.0027 5 L AUGER +211BI T 57.491-63.419 |] KLL AUGER +211BI T 70.025-77.105 |] 0.00015 7 KLX AUGER +211BI T 82.53-90.52 |] KXY AUGER +211BI T 5.42-16.34 0.0027 5 L AUGER 215AT P 0.0 9/2- 0.10 MS 2 8178 4 211BI N 1.0 1.0 1 1.0 211BI L 0 9/2- 2.15 M 2 211BI A 8026 4 99.95 2 2.8 211BI L 404.854 9 7/2- 0.317 NS 11 211BI A 7628 4 0.05 2 390 -211BI G 404.853 9 0.045 18M1+E2 -1.1 1 0.122 8 -211BI2 G KC=0.095 7$LC=0.0206 8$MC=0.00498 17 +211BI G 404.853 9 0.045 18M1+E2 -1.1 1 0.122 8 +211BI2 G KC=0.095 7$LC=0.0206 8$MC=0.00498 17 diff --git a/HEN_HOUSE/spectra/lnhb/At-217.txt b/HEN_HOUSE/spectra/lnhb/At-217.txt index 59be18fae..1cc4541bd 100644 --- a/HEN_HOUSE/spectra/lnhb/At-217.txt +++ b/HEN_HOUSE/spectra/lnhb/At-217.txt @@ -1,52 +1,52 @@ 213BI 217AT A DECAY (32.3 MS) 213BI H TYP=Full$AUT=X.Huang$CUT=31-DEC-2007$ 213BI C Evaluation history: Type=Full;Author=X.Huang;Cutoff date=31-DEC-2007 -213BI T Auger electrons and ^X ray energies and emission intensities: -213BI T {U Energy (keV)} {U Intensity } {U Line } +213BI T Auger electrons and X ray energies and emission intensities: +213BI T {U Energy (keV)} {U Intensity} {U Line} 213BI T -213BI T 74.8157 0.00351 20 XKA2 -213BI T 77.1088 0.0059 4 XKA1 +213BI T 74.8157 0.00351 20 XKA2 +213BI T 77.1088 0.0059 4 XKA1 213BI T -213BI T 86.835 |] XKB3 -213BI T 87.344 |] 0.00201 11 XKB1 -213BI T 87.862 |] XKB5II +213BI T 86.835 |] XKB3 +213BI T 87.344 |] 0.00201 11 XKB1 +213BI T 87.862 |] XKB5II 213BI T -213BI T 89.732 |] XKB2 -213BI T 90.074 |] 0.00062 4 XKB4 -213BI T 90.421 |] XKO23 +213BI T 89.732 |] XKB2 +213BI T 90.074 |] 0.00062 4 XKB4 +213BI T 90.421 |] XKO23 213BI T -213BI T 9.421-15.708 0.00497 23 XL (total) +213BI T 9.421-15.708 0.00497 23 XL (total) 213BI T 9.421 XLL 213BI T -15.708 XLG 213BI T -213BI T 57.491-63.419 |] KLL AUGER -213BI T 70.025-77.105 |] 0.00044 3 ^KLX AUGER -213BI T 82.53-90.52 |] KXY AUGER -213BI T 5.3-16.4 0.0077 4 L AUGER +213BI T 57.491-63.419 |] KLL AUGER +213BI T 70.025-77.105 |] 0.00044 3 KLX AUGER +213BI T 82.53-90.52 |] KXY AUGER +213BI T 5.3-16.4 0.0077 4 L AUGER 217AT P 0.0 9/2- 32.3 MS 4 7201.3 12 213BI N 1.00E0 1.00E0 0.999933241.00E0 213BI L 0 9/2- 45.59 M 6 213BI A 7066.9 1699.9387 301.16 213BI L 257.87 117/2- 213BI A 6813.8 160.0384 15379 -213BI G 257.88 4 0.0287 7 M1+E2 0.64 8 0.555 26 +213BI G 257.88 4 0.0287 7M1+E2 0.64 8 0.555 26 213BI2 G KC=0.434 17$LC=0.0918 16$MC=0.02212 37 213BI L 593.18 13(5/2,7/2,9/2)- 213BI A 6484.7 160.0167 8 49 -213BI G 335.33 100.0062 3 -213BI G 593.1 1 0.0115 5 +213BI G 335.33 100.0062 3 +213BI G 593.1 1 0.0115 5 213BI L 758.9 1 (5/2,13/2)- 213BI A 6322.0 160.0049 4 36 -213BI G 758.9 1 0.0049 4 +213BI G 758.9 1 0.0049 4 213BI L 1050 - 213BI A 6037 3 20001E-7 5.2 -213BI G 455 2000E-6 0 +213BI G 455 0.002 217RN 217AT B- DECAY (32.3 MS) 217RN H TYP=Full$AUT=X.Huang$CUT=31-DEC-2007$ 217RN C Evaluation history: Type=Full;Author=X.Huang;Cutoff date=31-DEC-2007 -217RN T Auger electrons and ^X ray energies and emission intensities: -217RN T {U Energy (keV)} {U Intensity } {U Line } +217RN T Auger electrons and X ray energies and emission intensities: +217RN T {U Energy (keV)} {U Intensity} {U Line} 217RN T 217RN T 217RN T diff --git a/HEN_HOUSE/spectra/lnhb/At-218.txt b/HEN_HOUSE/spectra/lnhb/At-218.txt index eb1a4da7d..2059c9f57 100644 --- a/HEN_HOUSE/spectra/lnhb/At-218.txt +++ b/HEN_HOUSE/spectra/lnhb/At-218.txt @@ -20,6 +20,6 @@ 218AT P 0.0 - 1.4 S 2 2881 12 218RN N 1.000E3 1.000E3 0.001 1.000E3 218RN L 0 0+ 36.0 MS 19 -218RN B 2881 120.1 1 +218RN B 2881 120.1 1 218RNS B EAV=1095 12 diff --git a/HEN_HOUSE/spectra/lnhb/At-219.txt b/HEN_HOUSE/spectra/lnhb/At-219.txt index 6d7336f36..e6662f9ef 100644 --- a/HEN_HOUSE/spectra/lnhb/At-219.txt +++ b/HEN_HOUSE/spectra/lnhb/At-219.txt @@ -2,24 +2,24 @@ 215BI H TYP=Full$AUT=A.L. Nichols$CUT=15-SEP-2010$ 215BI C Evaluation history: Type=Full;Author=A.L. Nichols;Cutoff date=15-SEP-2010 215BI C References: 1953Hy83, 1989Bu09, 1998Ak04, 2001Br31, 2003Au03, 2009AuZZ -215BI T Auger electrons and ^X ray energies and emission intensities: -215BI T {U Energy (keV)} {U Intensity } {U Line } +215BI T Auger electrons and X ray energies and emission intensities: +215BI T {U Energy (keV)} {U Intensity} {U Line} 215BI T 215BI T 74.8157 XKA2 215BI T 77.1088 XKA1 215BI T -215BI T 86.835 |] XKB3 -215BI T 87.344 |] XKB1 -215BI T 87.862 |] XKB5II +215BI T 86.835 |] XKB3 +215BI T 87.344 |] XKB1 +215BI T 87.862 |] XKB5II 215BI T -215BI T 89.732 |] XKB2 -215BI T 90.074 |] XKB4 -215BI T 90.421 |] XKO23 +215BI T 89.732 |] XKB2 +215BI T 90.074 |] XKB4 +215BI T 90.421 |] XKO23 215BI T 215BI T -215BI T 57.491-63.419 |] KLL AUGER -215BI T 70.025-77.105 |] ^KLX AUGER -215BI T 82.53-90.52 |] KXY AUGER +215BI T 57.491-63.419 |] KLL AUGER +215BI T 70.025-77.105 |] KLX AUGER +215BI T 82.53-90.52 |] KXY AUGER 215BI T 0.21-16.3366 L AUGER 219AT P 0.0 (7/2)- 56 S 4 6324 15 215BI N 1.031E0 1.031E0 0.97 1.031E0 @@ -30,28 +30,28 @@ 219RN H TYP=Full$AUT=A.L. Nichols$CUT=15-SEP-2010$ 219RN C Evaluation history: Type=Full;Author=A.L. Nichols;Cutoff date=15-SEP-2010 219RN C References: 1953Hy83, 1989Bu09, 1998Ak04, 2001Br31, 2003Au03, 2009AuZZ -219RN T Auger electrons and ^X ray energies and emission intensities: -219RN T {U Energy (keV)} {U Intensity } {U Line } +219RN T Auger electrons and X ray energies and emission intensities: +219RN T {U Energy (keV)} {U Intensity} {U Line} 219RN T 219RN T 81.07 XKA2 219RN T 83.78 XKA1 219RN T -219RN T 94.247 |] XKB3 -219RN T 94.868 |] XKB1 -219RN T 95.449 |] XKB5II +219RN T 94.247 |] XKB3 +219RN T 94.868 |] XKB1 +219RN T 95.449 |] XKB5II 219RN T -219RN T 97.48 |] XKB2 -219RN T 97.853 |] XKB4 -219RN T 98.357 |] XKO23 +219RN T 97.48 |] XKB2 +219RN T 97.853 |] XKB4 +219RN T 98.357 |] XKO23 219RN T 219RN T -219RN T 62.017-68.885 |] KLL AUGER -219RN T 75.744-83.785 |] ^KLX AUGER -219RN T 89.45-98.39 |] KXY AUGER +219RN T 62.017-68.885 |] KLL AUGER +219RN T 75.744-83.785 |] KLX AUGER +219RN T 89.45-98.39 |] KXY AUGER 219RN T 0.2-17.957 L AUGER 219AT P 0.0 (7/2)- 56 S 4 1566 3 219RN N 3.333E1 3.333E1 0.03 3.333E1 219RN L 0 5/2+ 3.98 S 3 -219RN B 1566 3 3 6.2 1U +219RN B 1566 3 3 6.2 1 219RNS B EAV=547 2 diff --git a/HEN_HOUSE/spectra/lnhb/Au-195.txt b/HEN_HOUSE/spectra/lnhb/Au-195.txt index cb7482e8e..c828ebc88 100644 --- a/HEN_HOUSE/spectra/lnhb/Au-195.txt +++ b/HEN_HOUSE/spectra/lnhb/Au-195.txt @@ -5,56 +5,56 @@ 195PT2C 1963Ha17, 1964Go19, 1965Ha13, 1967Sc18, 1969Fi08, 1970To19, 1970Ah05, 195PT3C 1972Ha21, 1973Go05, 1974HeYW, 1982HoZJ, 1996Sc06, 1999Zh11, 2002Un02, 195PT4C 2008Ki07, 2012Au06 -195PT T Auger electrons and ^X ray energies and emission intensities: -195PT T {U Energy (keV)} {U Intensity } {U Line } +195PT T Auger electrons and X ray energies and emission intensities: +195PT T {U Energy (keV)} {U Intensity} {U Line} 195PT T -195PT T 65.123 27.4 17 XKA2 -195PT T 66.833 46.9 29 XKA1 +195PT T 65.123 27.4 17 XKA2 +195PT T 66.833 46.9 29 XKA1 195PT T -195PT T 75.369 |] XKB3 -195PT T 75.749 |] 15.8 10 XKB1 -195PT T 76.234 |] XKB5II +195PT T 75.369 |] XKB3 +195PT T 75.749 |] 15.8 10 XKB1 +195PT T 76.234 |] XKB5II 195PT T -195PT T 77.786 |] XKB2 -195PT T 78.07 |] 4.51 30 XKB4 -195PT T 78.337 |] XKO23 +195PT T 77.786 |] XKB2 +195PT T 78.07 |] 4.51 30 XKB4 +195PT T 78.337 |] XKO23 195PT T -195PT T 8.2683-13.3617 53.1 24 XL (total) -195PT T 8.2683 1.29 9 XLL -195PT T 9.362-9.4423 26.1 16 XLA -195PT T 9.9768 0.309 17 XLC -195PT T 10.8411-11.2344 21.5 8 XLB -195PT T 12.5496-13.3617 3.99 16 XLG +195PT T 8.2683-13.3617 53.1 24 XL (total) +195PT T 8.2683 1.29 9 XLL +195PT T 9.362-9.4423 26.1 16 XLA +195PT T 9.9768 0.309 17 XLC +195PT T 10.8411-11.2344 21.5 8 XLB +195PT T 12.5496-13.3617 3.99 16 XLG 195PT T -195PT T 50.399-55.021 |] KLL AUGER -195PT T 61.116-66.829 |] 4.0 5 ^KLX AUGER -195PT T 71.8-78.39 |] KXY AUGER -195PT T 5.07-14.25 129 8 L AUGER +195PT T 50.399-55.021 |] KLL AUGER +195PT T 61.116-66.829 |] 4.0 5 KLX AUGER +195PT T 71.8-78.39 |] KXY AUGER +195PT T 5.07-14.25 129 8 L AUGER 195AU P 0.0 3/2+ 184.7 D 14 226.8 10 195PT N 1.0 1.0 1 1.0 195PT L 0 1/2- STABLE -195PT E 9.5 4 8.1 1U -195PT2 E EAV= $CK=0.6851 10$CL=0.2336 7$CM=0.0813 3$CN= $CO= +195PT E 9.5 48.1 1 +195PT2 E CK=0.6851 10$CL=0.2336 7$CM=0.0813 3 195PT L 98.882 4 3/2- 195PT E 57.6 356.5 -195PT2 E EAV= $CK=0.452 6$CL=0.398 4$CM=0.1499 18$CN= $CO= +195PT2 E CK=0.452 6$CL=0.398 4$CM=0.1499 18 195PT G 98.882 4 11.21 15M1+E2 -0.122 15 6.86 10 -195PT2 G KC=5.59 8$LC=0.977 16$MC=0.227 4 +195PT2 G KC=5.59 8$LC=0.977 16$MC=0.227 4 195PT L 129.777 5 5,/2- -195PT E 32.8 306.3 1U -195PT2 E EAV= $CK=0.178 12$CL=0.587 9$CM=0.235 4$CN= $CO= -195PT G 30.895 7 0.80 8 M1+E2 -0.013 7 37.3 6 -195PT2 G KC=$LC=28.7 5$MC=6.65 11 +195PT E 32.8 306.3 1 +195PT2 E CK=0.178 12$CL=0.587 9$CM=0.235 4 +195PT G 30.895 7 0.80 8M1+E2 -0.013 7 37.3 6 +195PT2 G LC=28.7 5$MC=6.65 11 195PT G 129.777 5 0.854 29E2 1.729 25 -195PT2 G KC=0.467 7$LC=0.948 14$MC=0.245 4 +195PT2 G KC=0.467 7$LC=0.948 14$MC=0.245 4 195PT L 199.526 123/2- 195PT E 0.0149 148.1 -195PT2 E EAV= $CK= $CL=0.50 2$CM=0.50 2$CN= $CO= -195PT G 199.526 120.0093 8 M1+E2 1.2 2 0.60 6 -195PT2 G KC=0.42 6$LC=0.1374 25$MC=0.0338 9 +195PT2 E CL=0.50 2$CM=0.50 2 +195PT G 199.526 120.0093 8M1+E2 1.2 2 0.60 6 +195PT2 G KC=0.42 6$LC=0.1374 25$MC=0.0338 9 195PT L 211.398 6 3/2- 195PT E 0.0210 187.1 -195PT2 E EAV= $CK= $CL=0.05 5$CM=0.95 5$CN= $CO= +195PT2 E CL=0.05 5$CM=0.95 5 195PT G 211.398 6 0.0121 10M1+E2 0.38 3 0.737 14 -195PT2 G KC=0.595 13$LC=0.1090 16$MC=0.0255 4 +195PT2 G KC=0.595 13$LC=0.1090 16$MC=0.0255 4 diff --git a/HEN_HOUSE/spectra/lnhb/Au-198.txt b/HEN_HOUSE/spectra/lnhb/Au-198.txt index 0dc353e20..79c00f882 100644 --- a/HEN_HOUSE/spectra/lnhb/Au-198.txt +++ b/HEN_HOUSE/spectra/lnhb/Au-198.txt @@ -16,46 +16,46 @@ 198HG11C 2006No10, 2007Go39, 2007Sp01, 2008Ki07, 2008Ru05, 2008Ku09, 2009Hu11, 198HG12C 2010Mo06, 2010Li48, 2010Go25, 2010Fo13, 2011Li52, 2011Ch22, 2012Fi12, 198HG13C 2012Ha23, 2012Wa38, 2014Un** -198HG T Auger electrons and ^X ray energies and emission intensities: -198HG T {U Energy (keV)} {U Intensity } {U Line } +198HG T Auger electrons and X ray energies and emission intensities: +198HG T {U Energy (keV)} {U Intensity} {U Line} 198HG T -198HG T 68.895 0.807 15 XKA2 -198HG T 70.82 1.369 24 XKA1 +198HG T 68.895 0.807 15 XKA2 +198HG T 70.82 1.369 24 XKA1 198HG T -198HG T 79.823 |] XKB3 -198HG T 80.254 |] 0.465 11 XKB1 -198HG T 80.762 |] XKB5II +198HG T 79.823 |] XKB3 +198HG T 80.254 |] 0.465 11 XKB1 +198HG T 80.762 |] XKB5II 198HG T -198HG T 82.435 |] XKB2 -198HG T 82.776 |] 0.136 4 XKB4 -198HG T 83.028 |] XKO23 +198HG T 82.435 |] XKB2 +198HG T 82.776 |] 0.136 4 XKB4 +198HG T 83.028 |] XKO23 198HG T -198HG T 8.7226-14.2672 1.203 22 XL (total) -198HG T 8.7226 0.0270 8 XLL -198HG T 9.8981-9.9886 0.527 14 XLA -198HG T 10.6473 0.01054 29 XLC -198HG T 11.4835-12.5471 0.536 12 XLB -198HG T 13.4081-14.2672 0.1024 23 XLG +198HG T 8.7226-14.2672 1.203 22 XL (total) +198HG T 8.7226 0.0270 8 XLL +198HG T 9.8981-9.9886 0.527 14 XLA +198HG T 10.6473 0.01054 29 XLC +198HG T 11.4835-12.5471 0.536 12 XLB +198HG T 13.4081-14.2672 0.1024 23 XLG 198HG T -198HG T 53.178-58.277 |] KLL AUGER -198HG T 64.594-70.811 |] 0.110 12 ^KLX AUGER -198HG T 75.98-83.09 |] KXY AUGER -198HG T 5.161-14.822 2.156 24 L AUGER +198HG T 53.178-58.277 |] KLL AUGER +198HG T 64.594-70.811 |] 0.110 12 KLX AUGER +198HG T 75.98-83.09 |] KXY AUGER +198HG T 5.161-14.822 2.156 24 L AUGER 198AU P 0.0 2- 2.6943 D 3 1372.8 5 198HG N 1.0 1.0 1 1.0 198HG L 0 0+ STABLE -198HG B 1372.8 5 0.025 5 12.4 1U +198HG B 1372.8 5 0.025 5 12.4 1U 198HGS B EAV=467.3 2 198HG L 411.80250 172+ 23.16 PS 12 -198HG B 961.0 5 98.99 6 7.37 +198HG B 961.0 5 98.99 6 7.37 198HGS B EAV=314.7 2 -198HG G 411.80205 1795.62 6 E2 0.0439 7 -198HG2 G KC=0.0300 5$LC=0.01055 15$MC=0.00263 4 +198HG G 411.80205 1795.62 6E2 0.0439 7 +198HG2 G KC=0.0300 5$LC=0.01055 15$MC=0.00263 4 198HG L 1087.6874 5 2+ 2.5 PS 20 -198HG B 285.1 5 0.985 5 7.6 +198HG B 285.1 5 0.985 5 7.6 198HGS B EAV=79.5 2 -198HG G 675.8836 7 0.804 5 M1+E2 1.07 14 0.0267 20 -198HG2 G KC=0.0216 17$LC=0.00389 24$MC=0.00091 6 -198HG G 1087.6842 7 0.1591 21E2 0.005128 -198HG2 G KC=0.00414 6$LC=7.51E-4 11$MC=1766E-7 25 +198HG G 675.8836 7 0.804 5M1+E2 1.07 14 0.0267 20 +198HG2 G KC=0.0216 17$LC=0.00389 24$MC=0.00091 6 +198HG G 1087.6842 7 0.1591 21E2 0.00512 8 +198HG2 G KC=0.00414 6$LC=7.51E-4 11$MC=1766E-7 25 diff --git a/HEN_HOUSE/spectra/lnhb/Ba-133.txt b/HEN_HOUSE/spectra/lnhb/Ba-133.txt index 2e2f1f39b..09aba21c5 100644 --- a/HEN_HOUSE/spectra/lnhb/Ba-133.txt +++ b/HEN_HOUSE/spectra/lnhb/Ba-133.txt @@ -4,21 +4,26 @@ 133CS3 H TYP=UPD$AUT=V.P. Chechev. N.K. Kuzmenko$CUT=01-JAN-2004$ 133CS4 H TYP=UPD$AUT=V.P. Chechev. N.K. Kuzmenko$CUT=01-APR-2000$ 133CS5 H TYP=FUL$AUT=V.P. Chechev. N.K. Kuzmenko$CUT=01-MAY-1999$ -133CS C References: 1961Wy01, 1967Bl15, 1967Be65, 1968Do10, 1968Re04, 1968Al16, -133CS2C 1968Na16, 1968No01, 1968La10, 1968BO04, 1969Gu15, 1970Wa19, 1972Em01, -133CS3C 1972Sc08, 1973In06, 1973Le**, 1973Ll01, 1973Mc18, 1974Da09, 1975Ni07, -133CS4C 1977Ge12, 1977Sc31, 1978Vy**, 1978He21, 1979HaYC, 1980Ch**, 1980Ho17, -133CS5C 1980Ro22, 1980RuZY, 1982HoZJ, 1983Si22, 1983Si17, 1983Ch11, 1983Ki08, -133CS6C 1983Wa26, 1983Yo03, 1987La**, 1988BeYQ, 1989Ma60, 1989Eg**, 1989DA11, -133CS7C 1990Da11, 1990Fi03, 1990Bh01, 1990Me15, 1991We08, 1992Sa28, 1992Un01, -133CS8C 1992Ch**, 1993Ni**, 1995Ra12, 1996Mi26, 1996Sc06, 1997Ma75, 1998Hw07, -133CS9C 2000He14, 2002Un02, 2004Sc04, 2004BeZQ, 2008Ki07, 2010Sc08, 2011Kh02, -133CS10C 2012Wa38, 2012Fi12, 2014Ma**, 2014Un01 +133CS C Evaluation history: Type=UPD;Author=V.P. Chechev. N.K. Kuzmenko;Cutoff date=01-MAY-2015 +133CS2C Type=UPD;Author=V.P. Chechev. N.K. Kuzmenko;Cutoff date=01-JUL-2014 +133CS3C Type=UPD;Author=V.P. Chechev. N.K. Kuzmenko;Cutoff date=01-JAN-2004 +133CS4C Type=UPD;Author=V.P. Chechev. N.K. Kuzmenko;Cutoff date=01-APR-2000 +133CS5C Type=FUL;Author=V.P. Chechev. N.K. Kuzmenko;Cutoff date=01-MAY-1999 +133CS C References: 1961Wy01, 1967Bl15, 1967Be65, 1968BO04, 1968Re04, 1968No01, +133CS2C 1968Na16, 1968La10, 1968Al16, 1968Do10, 1969Gu15, 1970Wa19, 1972Sc08, +133CS3C 1972Em01, 1973Le**, 1973Ll01, 1973Mc18, 1973In06, 1974Da09, 1975Ni07, +133CS4C 1977La19, 1977Ge12, 1977Sc31, 1978He21, 1978Vy**, 1979HaYC, 1980Ro22, +133CS5C 1980Ho17, 1980Ch**, 1980RuZY, 1982HoZJ, 1983Si17, 1983Ki08, 1983Si22, +133CS6C 1983Wa26, 1983Yo03, 1983Ch11, 1987La**, 1988BeYQ, 1989Ma60, 1989Eg**, +133CS7C 1989DA11, 1990Da11, 1990Me15, 1990Fi03, 1990Bh01, 1991We08, 1992Sa28, +133CS8C 1992Ch**, 1992Un01, 1993Ni**, 1995Ra12, 1996Mi26, 1996Sc06, 1997Ma75, +133CS9C 1998Hw07, 2000He14, 2002Un02, 2004BeZQ, 2004Sc04, 2008Ki07, 2010Sc08, +133CS10C 2011Kh02, 2012Fi12, 2012Wa38, 2014Ma**, 2014Un01 133CS T Auger electrons and X ray energies and emission intensities: 133CS T {U Energy (keV)} {U Intensity} {U Line} 133CS T -133CS T 30.6254 33.8 4 XKA2 -133CS T 30.9731 62.4 7 XKA1 +133CS T 30.6254 33.8 4 XKA2 +133CS T 30.9731 62.4 7 XKA1 133CS T 133CS T 34.9197 |] XKB3 133CS T 34.9873 |] 18.24 29 XKB1 @@ -29,49 +34,49 @@ 133CS T 35.972 |] XKO23 133CS T 133CS T 3.7946-5.5525 15.87 26 XL (total) -133CS T 3.7946 0.293 8 XLL +133CS T 3.7946 0.293 8 XLL 133CS T 4.2729-4.2866 7.63 18 XLA 133CS T 4.1418 0.1117 30 XLC 133CS T 4.62-4.9333 6.76 12 XLB 133CS T 5.1308-5.5525 1.086 20 XLG 133CS T 133CS T 24.411-25.804 |] KLL AUGER -133CS T 28.991-30.961 |] 14.1 6 KLX AUGER +133CS T 28.991-30.961 |] 14.1 6 KLX AUGER 133CS T 33.55-35.96 |] KXY AUGER -133CS T 2.5777-5.559 136.8 8 L AUGER +133CS T 2.5777-5.559 136.8 8 L AUGER 133BA P 0.0 1/2+ 10.539 Y 6 517.3 10 133CS N 1.0 1.0 1 1.0 133CS L 0 7/2+ STABLE -133CS E 0.0005 LT13.9 GT -133CS2 E EAV= $CK=0.77 $CL=0.18 $CM=0.05 $CN= $CO= +133CS E 0.0005 13.9 2U +133CS2 E CK=0.77 $CL=0.18 $CM=0.05 133CS L 80.9979 115/2+ 6.283 NS 14 -133CS E 0.7 LT10.9 GT -133CS2 E EAV= $CK=0.84 $CL=0.13 $CM=0.037 $CN= $CO= +133CS E 0.7 10.9 2 +133CS2 E CK=0.84 $CL=0.13 $CM=0.037 133CS G 80.9979 1133.31 30M1+E2 0.158 5 1.703 24 -133CS2 G KC=1.431 20$LC=0.216 4$MC=0.0447 8 +133CS2 G KC=1.431 20$LC=0.216 4$MC=0.0447 8 133CS L 160.6121 165/2+ 172 PS 4 -133CS E 0.3 LT10.6 GT -133CS2 E EAV= $CK=0.83 $CL=0.13 $CM=0.037 $CN= $CO= -133CS G 79.6142 192.63 19M1+E2 0.124 15 1.77 3 -133CS2 G KC=1.495 22$LC=0.217 6$MC=0.0447 13 -133CS G 160.6121 160.638 6 M1+E2 0.96 5 0.294 6 -133CS2 G KC=0.234 4$LC=0.0471 13$MC=0.0099 3 +133CS E 0.3 10.6 2 +133CS2 E CK=0.83 $CL=0.13 $CM=0.037 +133CS G 79.6142 192.63 19M1+E2 0.124 15 1.77 3 +133CS2 G KC=1.495 22$LC=0.217 6$MC=0.0447 13 +133CS G 160.6121 160.638 6M1+E2 0.96 5 0.294 6 +133CS2 G KC=0.234 4$LC=0.0471 13$MC=0.0099 3 133CS L 383.8491 123/2+ 44 PS 11 -133CS E 14.46 518.03 2 -133CS2 E EAV= $CK=0.7727 9$CL=0.1755 7$CM=0.05174 23$CN= $CO= -133CS G 223.2368 130.450 5 M1+E2 0.114 14 0.0975 14 -133CS2 G KC=0.0836 12$LC=0.01103 16$MC=0.00226 4 -133CS G 302.8508 5 18.31 11M1+E2 0.022 20 0.0434 6 -133CS2 G KC=0.0373 6$LC=0.00484 7$MC=9.88E-4 14 -133CS G 383.8485 128.94 6 E2 0.0202 3 -133CS2 G KC=0.01684 24$LC=0.00270 4$MC=5.60E-4 8 +133CS E 14.5 58.03 +133CS2 E CK=0.7727 9$CL=0.1755 7$CM=0.05174 23 +133CS G 223.2368 130.450 5M1+E2 0.114 14 0.0975 14 +133CS2 G KC=0.0836 12$LC=0.01103 16$MC=0.00226 4 +133CS G 302.8508 5 18.31 11M1+E2 0.022 20 0.0434 6 +133CS2 G KC=0.0373 6$LC=0.00484 7$MC=9.88E-4 14 +133CS G 383.8485 128.94 6E2 0.0202 3 +133CS2 G KC=0.01684 24$LC=0.00270 4$MC=5.60E-4 8 133CS L 437.0113 131/2+ 150 PS -133CS E 85.41 536.63 -133CS2 E EAV= $CK=0.671 5$CL=0.251 4$CM=0.0777 11$CN= $CO= -133CS G 53.1622 182.14 6 M1+E2 0.08 3 5.66 11 -133CS2 G KC=4.78 7$LC=0.70 5$MC=0.144 12 -133CS G 276.3989 127.13 6 E2 0.0566 8 -133CS2 G KC=0.0460 7$LC=0.00842 12$MC=1763E-6 25 -133CS G 356.0129 7 62.05 19E2 0.0254 4 -133CS2 G KC=0.0211 3$LC=0.00346 5$MC=7.21E-4 10 +133CS E 85.4 56.63 +133CS2 E CK=0.671 5$CL=0.251 4$CM=0.0777 11 +133CS G 53.1622 182.14 6M1+E2 0.08 3 5.66 11 +133CS2 G KC=4.78 7$LC=0.70 5$MC=0.144 12 +133CS G 276.3989 127.13 6E2 0.0566 8 +133CS2 G KC=0.0460 7$LC=0.00842 12$MC=1763E-6 25 +133CS G 356.0129 7 62.05 19E2 0.0254 4 +133CS2 G KC=0.0211 3$LC=0.00346 5$MC=7.21E-4 10 diff --git a/HEN_HOUSE/spectra/lnhb/Ba-137m.txt b/HEN_HOUSE/spectra/lnhb/Ba-137m.txt index beea5f3b2..4cf927d63 100644 --- a/HEN_HOUSE/spectra/lnhb/Ba-137m.txt +++ b/HEN_HOUSE/spectra/lnhb/Ba-137m.txt @@ -1,30 +1,30 @@ 137BA 137BA IT DECAY (2.552 M) -137BA T Auger electrons and ^X ray energies and emission intensities: -137BA T {U Energy (keV)} {U Intensity } {U Line } +137BA T Auger electrons and X ray energies and emission intensities: +137BA T {U Energy (keV)} {U Intensity} {U Line} 137BA T -137BA T 31.8174 2.06 4 XKA2 -137BA T 32.1939 3.80 7 XKA1 +137BA T 31.8174 2.06 4 XKA2 +137BA T 32.1939 3.80 7 XKA1 137BA T -137BA T 36.3045 |] XKB3 -137BA T 36.3786 |] 1.12 2 XKB1 -137BA T 36.654 |] XKB5II +137BA T 36.3045 |] XKB3 +137BA T 36.3786 |] 1.12 2 XKB1 +137BA T 36.654 |] XKB5II 137BA T -137BA T 37.258 |] XKB2 -137BA T 37.312 |] 0.28 1 XKB4 -137BA T 37.425 |] XKO23 +137BA T 37.258 |] XKB2 +137BA T 37.312 |] 0.28 1 XKB4 +137BA T 37.425 |] XKO23 137BA T -137BA T 3.954-5.809 0.95 5 XL (total) +137BA T 3.954-5.809 0.95 5 XL (total) 137BA T 3.954 XLL 137BA T -5.809 XLG 137BA T -137BA T 25.31-26.79 |] KLL AUGER -137BA T 30.09-31.36 |] 0.8 1 ^KLX AUGER -137BA T 34.84-37.41 |] KXY AUGER -137BA T 2.6-5.9 7.7 1 L AUGER +137BA T 25.31-26.79 |] KLL AUGER +137BA T 30.09-31.36 |] 0.8 1 KLX AUGER +137BA T 34.84-37.41 |] KXY AUGER +137BA T 2.6-5.9 7.7 1 L AUGER 137BA P 661.659 3 11/2- 2.552 M 1 137BA N 1.0 1.0 1 1.0 137BA L 0 3/2+ STABLE 137BA L 661.659 3 11/2- 2.552 M 1 137BA G 661.657 3 90.07 20M4 0.1102 19 -137BA2 G KC=0.0896 15$LC=0.0167 5$MC= +137BA2 G KC=0.0896 15$LC=0.0167 5 diff --git a/HEN_HOUSE/spectra/lnhb/Ba-140.txt b/HEN_HOUSE/spectra/lnhb/Ba-140.txt index 4a79e0c1a..fe1538d69 100644 --- a/HEN_HOUSE/spectra/lnhb/Ba-140.txt +++ b/HEN_HOUSE/spectra/lnhb/Ba-140.txt @@ -2,15 +2,18 @@ 140LA H TYP=UPD$AUT=V.P. Chechev. N.K. Kuzmenko$CUT=01-MAR-2015$ 140LA2 H TYP=UPD$AUT=M.M.Bé$CUT=19-JUN-2008$ 140LA3 H TYP=FUL$AUT=R.G. Helmer$CUT=01-JAN-2003$ -140LA C References: 1965Si17, 1966Mo16, 1970Ke09, 1969Ka33, 1971Ba28, 1973Ra10, -140LA2C 1975Ha50, 1976Li06, 1977Ge12, 1977De34, 1982Ad02, 1982HoZJ, 1983Wa26, +140LA C Evaluation history: Type=UPD;Author=V.P. Chechev. N.K. Kuzmenko;Cutoff date=01-MAR-2015 +140LA2C Type=UPD;Author=M.M.Bé;Cutoff date=19-JUN-2008 +140LA3C Type=FUL;Author=R.G. Helmer;Cutoff date=01-JAN-2003 +140LA C References: 1965Si17, 1966Mo16, 1969Ka33, 1970Ke09, 1971Ba28, 1973Ra10, +140LA2C 1975Ha50, 1976Li06, 1977De34, 1977Ge12, 1982HoZJ, 1982Ad02, 1983Wa26, 140LA3C 1990Me03, 1991Ch05, 1992Un01, 1998Si17, 2002Un02, 2002Ba85, 2004BeZR, -140LA4C 2007Ni07, 2008Ki07, 2014Wa38, 2012Fi12, 2014Un01 +140LA4C 2007Ni07, 2008Ki07, 2012Fi12, 2014Wa38, 2014Un01 140LA T Auger electrons and X ray energies and emission intensities: 140LA T {U Energy (keV)} {U Intensity} {U Line} 140LA T 140LA T 33.0344 0.562 19 XKA2 -140LA T 33.4421 1.03 4 XKA1 +140LA T 33.4421 1.03 4 XKA1 140LA T 140LA T 37.7206 |] XKB3 140LA T 37.8015 |] 0.307 11 XKB1 @@ -18,15 +21,15 @@ 140LA T 39.095 |] XKB5I 140LA T 140LA T 38.7303 |] XKB2 -140LA T 38.828 |] 0.078 3 XKB4 +140LA T 38.828 |] 0.078 3 XKB4 140LA T 39.91 |] XKO23 140LA T -140LA T 4.1174-6.0724 13.7 4 XL (total) -140LA T 4.1174 0.148 7 XLL +140LA T 4.1174-6.0724 13.7 4 XL (total) +140LA T 4.1174 0.148 7 XLL 140LA T 4.6338-4.6504 3.81 15 XLA 140LA T 4.5248 0.0762 30 XLC 140LA T 5.0412-5.3814 7.86 19 XLB -140LA T 5.6198-6.0724 1.76 4 XLG +140LA T 5.6198-6.0724 1.76 4 XLG 140LA T 140LA T 26.24-27.795 |] KLL AUGER 140LA T 31.231-33.428 |] 0.208 11 KLX AUGER @@ -38,43 +41,43 @@ 140LA L 29.9641 6 2- 0.25 NS 4 140LA B 1018 8 25.6 42 8.7 1U 140LAS B EAV=362 3 -140LA G 29.9641 6 14.4 4 M1(+E2) 5.37 8 -140LA2 G KC=$LC=4.26 6$MC=0.885 13 +140LA G 29.9641 6 14.4 4M1(+E2) 5.37 8 +140LA2 G LC=4.26 6$MC=0.885 13 140LA L 43.844 181- 0.52 NS 14 140LA B 1004 8 35.6 31 8 1 140LAS B EAV=345 3 -140LA G 13.880 181.16 4 M1+E2 0.0100 55 54.0 19 -140LA2 G KC=$LC=42.8 15$MC=8.9 4 +140LA G 13.880 181.16 4M1+E2 0.0100 55 54.0 19 +140LA2 G LC=42.8 15$MC=8.9 4 140LA L 63.1790 7 4- -140LA G 63.1790 7 3.0E-5 15M1 4.05 6 -140LA2 G KC=3.45 5$LC=0.472 7$MC=0.0983 14 +140LA G 63.1790 7 0.00003015M1 4.05 6 +140LA2 G KC=3.45 5$LC=0.472 7$MC=0.0983 14 140LA L 162.6591 192- 0.01 NS 140LA B 885 8 4.14 31 9.3 1U 140LAS B EAV=311 3 -140LA G 99.4801 202.0E-5 12[E2] 2.03 3 -140LA2 G KC=1.235 18$LC=0.620 9$MC=0.1371 20 +140LA G 99.4801 200.00002012[E2] 2.03 3 +140LA2 G KC=1.235 18$LC=0.620 9$MC=0.1371 20 140LA G 118.815 180.0610 21M1 0.663 10 -140LA2 G KC=0.566 8$LC=0.0765 11$MC=0.01591 23 -140LA G 132.695 2 0.202 6 M1 0.485 7 -140LA2 G KC=0.415 6$LC=0.0560 8$MC=0.01163 17 -140LA G 162.6591 196.49 27M1(+E2) 0.275 4 -140LA2 G KC=0.235 4$LC=0.0317 5$MC=0.00659 11 +140LA2 G KC=0.566 8$LC=0.0765 11$MC=0.01591 23 +140LA G 132.695 2 0.202 6M1 0.485 7 +140LA2 G KC=0.415 6$LC=0.0560 8$MC=0.01163 17 +140LA G 162.6591 196.49 27M1(+E2) 0.275 4 +140LA2 G KC=0.235 4$LC=0.0317 5$MC=0.00659 11 140LA L 467.63 3 1`- 7.7 NS 140LA B 580 8 9.71 12 7.8 1 140LAS B EAV=181 3 -140LA G 304.971 304.33 9 M1(+E2) 0.1 0.0506 7 -140LA2 G KC=0.0434 6$LC=0.00573 8$MC=1189E-6 17 -140LA G 423.786 353.13 6 M1 0.0217 3 -140LA2 G KC=0.0186 3$LC=0.00243 4$MC=5.03E-4 7 -140LA G 437.666 301.94 4 M1 0.0200 3 -140LA2 G KC=0.01716 24$LC=0.00224 4$MC=4.64E-4 7 +140LA G 304.971 304.33 9M1(+E2) 0.1 0.0506 7 +140LA2 G KC=0.0434 6$LC=0.00573 8$MC=1189E-6 17 +140LA G 423.786 353.13 6M1 0.0217 3 +140LA2 G KC=0.0186 3$LC=0.00243 4$MC=5.03E-4 7 +140LA G 437.666 301.94 4M1 0.0200 3 +140LA2 G KC=0.01716 24$LC=0.00224 4$MC=4.64E-4 7 140LA L 581.106 180- -140LA B 467 8 24.94 50 7.1 +140LA B 467 8 24.9 5 7.1 140LAS B EAV=141 3 140LA G 113.48 4 0.0172 13M1 0.755 11 -140LA2 G KC=0.645 9$LC=0.0872 13$MC=0.0181 3 -140LA G 537.261 2524.6 5 M1 0.0119717 -140LA2 G KC=0.01029 15$LC=1332E-6 19$MC=2.76E-4 4 +140LA2 G KC=0.645 9$LC=0.0872 13$MC=0.0181 3 +140LA G 537.261 2524.6 5M1 0.0119717 +140LA2 G KC=0.01029 15$LC=1332E-6 19$MC=2.76E-4 4 140LA G 551.141 180.0049 20[E2] 0.0079211 -140LA2 G KC=0.00666 10$LC=9.97E-4 14$MC=2.09E-4 3 - \ No newline at end of file +140LA2 G KC=0.00666 10$LC=9.97E-4 14$MC=2.09E-4 3 + diff --git a/HEN_HOUSE/spectra/lnhb/Be-7.txt b/HEN_HOUSE/spectra/lnhb/Be-7.txt index a3b635d68..7c018a427 100644 --- a/HEN_HOUSE/spectra/lnhb/Be-7.txt +++ b/HEN_HOUSE/spectra/lnhb/Be-7.txt @@ -1,7 +1,7 @@ 7LI 7BE EC DECAY (53.22 D) 7LI C References: 2000Hu20, 2000Li21 - 7LI T Auger electrons and ^X ray energies and emission intensities: - 7LI T {U Energy (keV)} {U Intensity } {U Line } + 7LI T Auger electrons and X ray energies and emission intensities: + 7LI T {U Energy (keV)} {U Intensity} {U Line} 7LI T 7LI T 0.0543 XKA2 7LI T 0.0543 XKA1 @@ -11,11 +11,10 @@ 7BE P 0.0 3/2- 53.22 D 6 861.815 18 7LI N 1.0 1.0 1 1.0 7LI L 0 3/2- STABLE - 7LI E 89.56 4 3.32 - 7LI2 E EAV= $CK=0.908 12$CL=0.092 12$CM= $CN= $CO= + 7LI E 89.56 43.32 + 7LI2 E CK=0.908 12$CL=0.092 12 7LI L 477.621 2 1/2- 105 FS - 7LI E 10.44 4 3.56 2 - 7LI2 E EAV= $CK=0.908 12$CL=0.092 12$CM= $CN= $CO= - 7LI G 477.6035 2010.44 4 M1+E2 7.3E-7 11 - 7LI2 G KC=$LC=$MC= + 7LI E 10.44 43.56 + 7LI2 E CK=0.908 12$CL=0.092 12 + 7LI G 477.6035 2010.44 4M1+E2 7.3E-7 11 diff --git a/HEN_HOUSE/spectra/lnhb/Bi-207.txt b/HEN_HOUSE/spectra/lnhb/Bi-207.txt index 93a2d1416..de0ab643f 100644 --- a/HEN_HOUSE/spectra/lnhb/Bi-207.txt +++ b/HEN_HOUSE/spectra/lnhb/Bi-207.txt @@ -4,53 +4,53 @@ 207PB C Evaluation history: Type=Update;Author=M.M. Bé;Cutoff date=01-DEC-2009 207PB2C Type=Full;Author=M.M.Bé;Cutoff date=01-FEB-1998 207PB C References: 1971Al03, 2002Ba85, 2008Ki07 -207PB T Auger electrons and ^X ray energies and emission intensities: -207PB T {U Energy (keV)} {U Intensity } {U Line } +207PB T Auger electrons and X ray energies and emission intensities: +207PB T {U Energy (keV)} {U Intensity} {U Line} 207PB T -207PB T 72.8049 21.75 30 XKA2 -207PB T 74.97 36.6 5 XKA1 +207PB T 72.8049 21.75 30 XKA2 +207PB T 74.97 36.6 5 XKA1 207PB T -207PB T 84.451 |] XKB3 -207PB T 84.937 |] 12.49 25 XKB1 -207PB T 85.47 |] XKB5II +207PB T 84.451 |] XKB3 +207PB T 84.937 |] 12.49 25 XKB1 +207PB T 85.47 |] XKB5II 207PB T -207PB T 87.238 |] XKB2 -207PB T 87.58 |] 3.77 10 XKB4 -207PB T 87.911 |] XKO23 +207PB T 87.238 |] XKB2 +207PB T 87.58 |] 3.77 10 XKB4 +207PB T 87.911 |] XKO23 207PB T -207PB T 9.18-15.84 32.9 6 XL (total) -207PB T 9.18 0.822 21 XLL -207PB T 10.4496-10.5516 15.6 4 XLA -207PB T 11.3494 0.226 7 XLC -207PB T 12.143-13.015 13.62 26 XLB -207PB T 15.101-15.84 2.61 5 XLG +207PB T 9.18-15.84 32.9 6 XL (total) +207PB T 9.18 0.822 21 XLL +207PB T 10.4496-10.5516 15.6 4 XLA +207PB T 11.3494 0.226 7 XLC +207PB T 12.143-13.015 13.62 26 XLB +207PB T 15.101-15.84 2.61 5 XLG 207PB T -207PB T 56.028-61.669 |] KLL AUGER -207PB T 68.181-74.969 |] 2.9 4 ^KLX AUGER -207PB T 80.3-88 |] KXY AUGER -207PB T 5.2-15.7 54.8 7 L AUGER +207PB T 56.028-61.669 |] KLL AUGER +207PB T 68.181-74.969 |] 2.9 4 KLX AUGER +207PB T 80.3-88 |] KXY AUGER +207PB T 5.2-15.7 54.8 7 L AUGER 207BI P 0.0 9/2- 32.9 Y 14 2397.5 21 207PB N 1.0 1.0 1 1.0 207PB L 0 1/2- STABLE 207PB L 569.703 2 5/2- 130.5 PS 8 -207PB E 0.012 2 8.8 6 12.1 -207PB2 E EAV=383.4 9$CK=0.797 8$CL=0.150 3$CM=0.049 1$CN= $CO= -207PB G 569.698 2 97.76 3 E2 0.0216 3 -207PB2 G KC=0.01583 23$LC=0.00439 7$MC=1081E-6 16 +207PB E 0.012 28.8 612.1 2 +207PB2 E EAV=383.4 9$CK=0.797 8$CL=0.150 3$CM=0.049 1 +207PB G 569.698 2 97.76 3E2 0.0216 3 +207PB2 G KC=0.01583 23$LC=0.00439 7$MC=1081E-6 16 207PB L 897.80 5 3/2- 207PB G 328.11 100.0044 35[M1] -207PB G 897.8 1 0.1284 47M1+E2 0.3 1 0.0222 9 -207PB2 G KC=0.0182 8$LC=0.00304 12$MC=0.071 3 +207PB G 897.8 1 0.1284 47M1+E2 0.3 1 0.0222 9 +207PB2 G KC=0.0182 8$LC=0.00304 12$MC=0.071 3 207PB L 1633.368 5 13/2+ 0.806 S 6 -207PB E 84.1 6 10.58 3U -207PB2 E EAV= $CK=0.733 7$CL=0.199 4$CM=0.069 1$CN= $CO= +207PB E 84.1 610.58 1U +207PB2 E CK=0.733 7$CL=0.199 4$CM=0.069 1 207PB G 1063.656 3 74.58 22M4+E5 0.01 1 0.1278 24 -207PB2 G KC=0.0953 23$LC=0.0247 7$MC=0.00591 33 +207PB2 G KC=0.0953 23$LC=0.0247 7$MC=0.00591 33 207PB L 2339.948 117/2- -207PB E 7.03 238.3 2 -207PB2 E EAV= $CK= $CL=0.651 6$CM=0.349 6$CN= $CO= -207PB G 1442.2 2 0.1315 22E2 0.003375 -207PB2 G KC=0.00271 4$LC=4.68E-4 7$MC=1098E-7 16 -207PB G 1770.228 9 6.871 26M1+E2 0.05 2 0.004427 -207PB2 G KC=0.00342 5$LC=5.56E-4 8$MC=1292E-7 19 +207PB E 7.03 238.3 +207PB2 E CL=0.651 6$CM=0.349 6 +207PB G 1442.2 2 0.1315 22E2 0.00337 5 +207PB2 G KC=0.00271 4$LC=4.68E-4 7$MC=1098E-7 16 +207PB G 1770.228 9 6.871 26M1+E2 0.05 2 0.00442 7 +207PB2 G KC=0.00342 5$LC=5.56E-4 8$MC=1292E-7 19 diff --git a/HEN_HOUSE/spectra/lnhb/Bi-210.txt b/HEN_HOUSE/spectra/lnhb/Bi-210.txt index 0480db3e3..896809746 100644 --- a/HEN_HOUSE/spectra/lnhb/Bi-210.txt +++ b/HEN_HOUSE/spectra/lnhb/Bi-210.txt @@ -11,42 +11,42 @@ 206TL6C 1967Hs01, 1969Fl02, 1969Fl02, 1969La18, 1969La18, 1991Ry01, 1991Ry01, 206TL7C 1996Sc06, 1996Sc06, 1999Br39, 2002Ba85, 2002Ba85, 2003Br13, 2003Au03, 206TL8C 2003Br13, 2005Gr41, 2008BeZV, 2008Ki07, 2008Ko21, 2010MoZU, 2012Wa38 -206TL T Auger electrons and ^X ray energies and emission intensities: -206TL T {U Energy (keV)} {U Intensity } {U Line } +206TL T Auger electrons and X ray energies and emission intensities: +206TL T {U Energy (keV)} {U Intensity} {U Line} 206TL T -206TL T 70.8325 0.0000064 7 XKA2 -206TL T 72.8725 0.0000108 11 XKA1 +206TL T 70.8325 6.4E-6 7 XKA2 +206TL T 72.8725 1.08E-5 11 XKA1 206TL T -206TL T 82.118 |] XKB3 -206TL T 82.577 |] 0.0000037 4 XKB1 -206TL T 83.115 |] XKB5II +206TL T 82.118 |] XKB3 +206TL T 82.577 |] 3.7E-6 4 XKB1 +206TL T 83.115 |] XKB5II 206TL T -206TL T 84.838 |] XKB2 -206TL T 85.134 |] 0.00000110 11 XKB4 -206TL T 85.444 |] XKO23 +206TL T 84.838 |] XKB2 +206TL T 85.134 |] 1.10E-6 11 XKB4 +206TL T 85.444 |] XKO23 206TL T -206TL T 8.9531-14.7362 0.0000090 5 XL (total) -206TL T 8.9531 0.000000213 16 XLL -206TL T 10.1718-10.2679 0.00000409 28 XLA -206TL T 10.9942 0.000000072 6 XLC -206TL T 11.8117-12.9566 0.00000386 23 XLB -206TL T 13.8528-14.7362 0.00000073 5 XLG +206TL T 8.9531-14.7362 9.0E-6 5 XL (total) +206TL T 8.9531 2.13E-7 16 XLL +206TL T 10.1718-10.2679 4.09E-6 28 XLA +206TL T 10.9942 7.2E-8 6 XLC +206TL T 11.8117-12.9566 3.86E-6 23 XLB +206TL T 13.8528-14.7362 7.3E-7 5 XLG 206TL T -206TL T 54.587-59.954 |] KLL AUGER -206TL T 66.37-72.86 |] 0.00000085 13 ^KLX AUGER -206TL T 78.12-85.5 |] KXY AUGER -206TL T 5.2493-15.3183 0.0000155 6 L AUGER +206TL T 54.587-59.954 |] KLL AUGER +206TL T 66.37-72.86 |] 8.5E-7 13 KLX AUGER +206TL T 78.12-85.5 |] KXY AUGER +206TL T 5.2493-15.3183 1.55E-5 6 L AUGER 210BI P 0.0 1- 5.011 D 5 5036.5 8 206TL N 7.143E5 7.143E5 0.0000012 7.143E5 206TL L 0 0- 4.202 M 11 206TL L 265.832 5 2- 2.29 NS 14 206TL A 4687 4 40.0 4358 -206TL G 265.832 5 4.8E-5 5 E2 0.1603 23 -206TL2 G KC=0.0855 12$LC=0.0561 8$MC=0.01440 21 +206TL G 265.832 5 0.000048 5E2 0.1603 23 +206TL2 G KC=0.0855 12$LC=0.0561 8$MC=0.01440 21 206TL L 304.896 6 1- 4.2 PS 14 206TL A 4650 4 60 6 49 -206TL G 304.896 6 6.1E-5 7 M1 0.375 6 -206TL2 G KC=0.308 5$LC=0.0519 8$MC=0.01211 17 +206TL G 304.896 6 0.000061 7M1 0.375 6 +206TL2 G KC=0.308 5$LC=0.0519 8$MC=0.01211 17 210PO 210BI B- DECAY (5.011 D) 210PO H TYP=UPD$AUT=M.A.Kellett$CUT=01-OCT-2014$ @@ -61,28 +61,28 @@ 210PO6C 1967Hs01, 1969Fl02, 1969Fl02, 1969La18, 1969La18, 1991Ry01, 1991Ry01, 210PO7C 1996Sc06, 1996Sc06, 1999Br39, 2002Ba85, 2002Ba85, 2003Br13, 2003Au03, 210PO8C 2003Br13, 2005Gr41, 2008BeZV, 2008Ki07, 2008Ko21, 2010MoZU, 2012Wa38 -210PO T Auger electrons and ^X ray energies and emission intensities: -210PO T {U Energy (keV)} {U Intensity } {U Line } +210PO T Auger electrons and X ray energies and emission intensities: +210PO T {U Energy (keV)} {U Intensity} {U Line} 210PO T 210PO T 76.864 XKA2 210PO T 79.293 XKA1 210PO T -210PO T 89.256 |] XKB3 -210PO T 89.807 |] XKB1 -210PO T 90.363 |] XKB5II +210PO T 89.256 |] XKB3 +210PO T 89.807 |] XKB1 +210PO T 90.363 |] XKB5II 210PO T -210PO T 92.263 |] XKB2 -210PO T 92.618 |] XKB4 -210PO T 92.983 |] XKO23 +210PO T 92.263 |] XKB2 +210PO T 92.618 |] XKB4 +210PO T 92.983 |] XKO23 210PO T 210PO T -210PO T 58.978-65.205 |] KLL AUGER -210PO T 71.902-79.289 |] ^KLX AUGER -210PO T 84.8-93.1 |] KXY AUGER +210PO T 58.978-65.205 |] KLL AUGER +210PO T 71.902-79.289 |] KLX AUGER +210PO T 84.8-93.1 |] KXY AUGER 210PO T 5.506-16.864 L AUGER 210BI P 0.0 1- 5.011 D 5 1161.2 8 210PO N 1.00E0 1.00E0 0.9999982 1.00E0 210PO L 0 0+ 138.3763 D17 -210PO B 1161.2 8 10000E-22 8 1 +210PO B 1161.2 8 99.99986 2 8 1 210POS B EAV=317 3 diff --git a/HEN_HOUSE/spectra/lnhb/Bi-211.txt b/HEN_HOUSE/spectra/lnhb/Bi-211.txt index 03b18ab75..b31aaaf83 100644 --- a/HEN_HOUSE/spectra/lnhb/Bi-211.txt +++ b/HEN_HOUSE/spectra/lnhb/Bi-211.txt @@ -5,39 +5,39 @@ 207TL2C 1967Da10, 1968Br17, 1970MU21, 1971Ko37, 1971Gr17, 1973UrZX, 1975VaYT, 207TL3C 1976Bl13, 1982Mo30, 1988Hi14, 1989It01, 1991Ry01, 1992Sc26, 1993Ma73, 207TL4C 2003Au03, 2004Br45, 2008Ki07 -207TL T Auger electrons and ^X ray energies and emission intensities: -207TL T {U Energy (keV)} {U Intensity } {U Line } +207TL T Auger electrons and X ray energies and emission intensities: +207TL T {U Energy (keV)} {U Intensity} {U Line} 207TL T -207TL T 70.8325 0.726 16 XKA2 -207TL T 72.8725 1.225 27 XKA1 +207TL T 70.8325 0.726 16 XKA2 +207TL T 72.8725 1.225 27 XKA1 207TL T -207TL T 82.118 |] XKB3 -207TL T 82.577 |] 0.417 11 XKB1 -207TL T 83.115 |] XKB5II +207TL T 82.118 |] XKB3 +207TL T 82.577 |] 0.417 11 XKB1 +207TL T 83.115 |] XKB5II 207TL T -207TL T 84.838 |] XKB2 -207TL T 85.134 |] 0.124 4 XKB4 -207TL T 85.444 |] XKO23 +207TL T 84.838 |] XKB2 +207TL T 85.134 |] 0.124 4 XKB4 +207TL T 85.444 |] XKO23 207TL T -207TL T 8.9531-14.7362 0.929 19 XL (total) -207TL T 8.9531 0.0228 7 XLL -207TL T 10.1718-10.2679 0.438 12 XLA -207TL T 10.9942 0.00696 22 XLC -207TL T 11.8117-12.9566 0.388 9 XLB -207TL T 13.8528-14.7362 0.0724 18 XLG +207TL T 8.9531-14.7362 0.929 19 XL (total) +207TL T 8.9531 0.0228 7 XLL +207TL T 10.1718-10.2679 0.438 12 XLA +207TL T 10.9942 0.00696 22 XLC +207TL T 11.8117-12.9566 0.388 9 XLB +207TL T 13.8528-14.7362 0.0724 18 XLG 207TL T -207TL T 54.587-59.954 |] KLL AUGER -207TL T 66.37-72.86 |] 0.096 11 ^KLX AUGER -207TL T 78.12-85.5 |] KXY AUGER -207TL T 5.18-15.31 1.617 21 L AUGER +207TL T 54.587-59.954 |] KLL AUGER +207TL T 66.37-72.86 |] 0.096 11 KLX AUGER +207TL T 78.12-85.5 |] KXY AUGER +207TL T 5.18-15.31 1.617 21 L AUGER 211BI P 0.0 9/2- 2.15 M 2 6750.33 46 207TL N 1.003E0 1.003E0 0.99724 4 1.003E0 207TL L 0 1/2+ 4.774 M 12 207TL A 6622.4 6 83.79 23187 207TL L 351.03 4 3/2+ 30 PS 7 207TL A 6278.5 9 16.20 2343 -207TL G 351.03 4 13.00 19M1+E2 0.271 4 0.243 4 -207TL2 G KC=0.199 3$LC=0.0342 5$MC=0.00801 12 +207TL G 351.03 4 13.00 19M1+E2 0.271 4 0.243 4 +207TL2 G KC=0.199 3$LC=0.0342 5$MC=0.00801 12 211PO 211BI B- DECAY (2.15 M) 211PO H TYP=Full$AUT=A.Luca$CUT=31-DEC-2008$ @@ -46,27 +46,27 @@ 211PO2C 1967Da10, 1968Br17, 1970MU21, 1971Ko37, 1971Gr17, 1973UrZX, 1975VaYT, 211PO3C 1976Bl13, 1982Mo30, 1988Hi14, 1989It01, 1991Ry01, 1992Sc26, 1993Ma73, 211PO4C 2003Au03, 2004Br45, 2008Ki07 -211PO T Auger electrons and ^X ray energies and emission intensities: -211PO T {U Energy (keV)} {U Intensity } {U Line } +211PO T Auger electrons and X ray energies and emission intensities: +211PO T {U Energy (keV)} {U Intensity} {U Line} 211PO T 211PO T 76.864 XKA2 211PO T 79.293 XKA1 211PO T -211PO T 89.256 |] XKB3 -211PO T 89.807 |] XKB1 -211PO T 90.363 |] XKB5II +211PO T 89.256 |] XKB3 +211PO T 89.807 |] XKB1 +211PO T 90.363 |] XKB5II 211PO T -211PO T 92.263 |] XKB2 -211PO T 92.618 |] XKB4 -211PO T 92.983 |] XKO23 +211PO T 92.263 |] XKB2 +211PO T 92.618 |] XKB4 +211PO T 92.983 |] XKO23 211PO T 211PO T -211PO T 58.978-65.205 |] KLL AUGER -211PO T 71.902-79.289 |] ^KLX AUGER -211PO T 84.8-93.1 |] KXY AUGER +211PO T 58.978-65.205 |] KLL AUGER +211PO T 71.902-79.289 |] KLX AUGER +211PO T 84.8-93.1 |] KXY AUGER 211BI P 0.0 9/2- 2.15 M 2 574 5 211PO N 3.623E2 3.623E2 0.00276 3.623E2 211PO L 0 9/2+ 0.516 S 3 -211PO B 574 5 0.276 4 5.99 +211PO B 574 5 0.276 4 5.99 211POS B EAV=172.9 18 diff --git a/HEN_HOUSE/spectra/lnhb/Bi-212.txt b/HEN_HOUSE/spectra/lnhb/Bi-212.txt index ea5d9296e..5681883bb 100644 --- a/HEN_HOUSE/spectra/lnhb/Bi-212.txt +++ b/HEN_HOUSE/spectra/lnhb/Bi-212.txt @@ -8,31 +8,31 @@ 208TL3C 1968Yt02, 1972DaZA, 1973Da38, 1977La19, 1978Av01, 1982Be09, 1982Sa36, 208TL4C 1983Sc13, 1983Va22, 1984Ge07, 1992Li05, 1996Sc06, 1998ScZM, 1999ScZX, 208TL5C 2002Ra45, 2002Ba85, 2003Au03, 2005Br03, 2007St23, 2007Ma45, 2008Ki07 -208TL T Auger electrons and ^X ray energies and emission intensities: -208TL T {U Energy (keV)} {U Intensity } {U Line } +208TL T Auger electrons and X ray energies and emission intensities: +208TL T {U Energy (keV)} {U Intensity} {U Line} 208TL T -208TL T 70.8325 0.0525 23 XKA2 -208TL T 72.8725 0.089 4 XKA1 +208TL T 70.8325 0.0525 23 XKA2 +208TL T 72.8725 0.089 4 XKA1 208TL T -208TL T 82.118 |] XKB3 -208TL T 82.577 |] 0.0301 14 XKB1 -208TL T 83.115 |] XKB5II +208TL T 82.118 |] XKB3 +208TL T 82.577 |] 0.0301 14 XKB1 +208TL T 83.115 |] XKB5II 208TL T -208TL T 84.838 |] XKB2 -208TL T 85.134 |] 0.0089 5 XKB4 -208TL T 85.444 |] XKO23 +208TL T 84.838 |] XKB2 +208TL T 85.134 |] 0.0089 5 XKB4 +208TL T 85.444 |] XKO23 208TL T -208TL T 8.953-14.738 7.1 3 XL (total) -208TL T 8.953 0.171 6 XLL -208TL T 10.172-10.268 3.3 1 XLA -208TL T 10.994 0.0230 7 XLC -208TL T 11.812-12.643 2.76 5 XLB -208TL T 14.291-14.738 0.579 9 XLG +208TL T 8.953-14.738 7.1 3 XL (total) +208TL T 8.953 0.171 6 XLL +208TL T 10.172-10.268 3.3 1 XLA +208TL T 10.994 0.0230 7 XLC +208TL T 11.812-12.643 2.76 5 XLB +208TL T 14.291-14.738 0.579 9 XLG 208TL T -208TL T 54.587-59.954 |] KLL AUGER -208TL T 66.37-72.86 |] 0.0069 8 ^KLX AUGER -208TL T 78.12-85.5 |] KXY AUGER -208TL T 5.182-10.132 12.2 4 L AUGER +208TL T 54.587-59.954 |] KLL AUGER +208TL T 66.37-72.86 |] 0.0069 8 KLX AUGER +208TL T 78.12-85.5 |] KXY AUGER +208TL T 5.182-10.132 12.2 4 L AUGER 212BI P 0.0 1- 60.54 M 6 6207.26 3 208TL N 2.783E0 2.783E0 0.3593 2.783E0 208TL L 0 5+ 3.058 M 6 @@ -40,35 +40,35 @@ 208TL A 6090.14 3 27.00 28481 208TL L 39.858 4 4+ 208TL A 6051.04 3 69.86 28126 -208TL G 39.858 4 1.07 1 [M1] 23.3 4 -208TL2 G KC=$LC=17.81 25$MC=4.17 6 +208TL G 39.858 4 1.07 1[M1] 23.3 4 +208TL2 G LC=17.81 25$MC=4.17 6 208TL L 328.04 5 5+ 208TL A 5768.29 6 1.70 8 279 -208TL G 288.18 5 0.32 2 M1+E2 0.08 0.436 7 -208TL2 G KC=0.357 5$LC=0.0605 9$MC=0.01411 20 -208TL G 328.04 5 0.121 3 [M1] 0.308 5 -208TL2 G KC=0.252 4$LC=0.0425 6$MC=0.00991 14 +208TL G 288.18 5 0.32 2M1+E2 0.08 0.436 7 +208TL2 G KC=0.357 5$LC=0.0605 9$MC=0.01411 20 +208TL G 328.04 5 0.121 3[M1] 0.308 5 +208TL2 G KC=0.252 4$LC=0.0425 6$MC=0.00991 14 208TL L 473.4 4 (4)+ 208TL A 5625.7 4 0.167 8 595 -208TL G 433.5 4 0.011 1 [M1] 0.1453 21 -208TL2 G KC=0.1193 17$LC=0.0199 3$MC=0.00465 7 -208TL G 473.4 4 0.044 3 [M1+E2] 1.0 2 0.074 10 -208TL2 G KC=0.059 8$LC=0.0115 10$MC=0.00273 21 +208TL G 433.5 4 0.011 1[M1] 0.1453 21 +208TL2 G KC=0.1193 17$LC=0.0199 3$MC=0.00465 7 +208TL G 473.4 4 0.044 3[M1+E2] 1.0 2 0.074 10 +208TL2 G KC=0.059 8$LC=0.0115 10$MC=0.00273 21 208TL L 492.84 4 (3)+ 208TL A 5606.60 5 1.20 8 67 -208TL G 164.80 6 0.0055 6 (E2) 0.816 12 -208TL2 G KC=0.263 4$LC=0.413 6$MC=0.1078 16 -208TL G 452.98 4 0.34 3 (M1) 0.1293 18 -208TL2 G KC=0.1061 15$LC=0.01772 25$MC=0.00413 6 -208TL G 492.84 4 0.039 10E2 0.0291 4 -208TL2 G KC=0.0207 3$LC=0.00633 9$MC=1567E-6 22 +208TL G 164.80 6 0.0055 6(E2) 0.816 12 +208TL2 G KC=0.263 4$LC=0.413 6$MC=0.1078 16 +208TL G 452.98 4 0.34 3(M1) 0.1293 18 +208TL2 G KC=0.1061 15$LC=0.01772 25$MC=0.00413 6 +208TL G 492.84 4 0.039 10E2 0.0291 4 +208TL2 G KC=0.0207 3$LC=0.00633 9$MC=1567E-6 22 208TL L 617 2 + 208TL L 620.4 3 (6)+ 208TL A 5481.4 3 0.0139 111380 -208TL G 580.5 3 0.0011 2 E2 0.0198 3 -208TL2 G KC=0.01470 21$LC=0.00388 6$MC=9.50E-4 14 -208TL G 620.4 3 0.0038 4 [M1+E2] 1.0 2 0.037 5 -208TL2 G KC=0.030 4$LC=0.0054 5$MC=0.00129 12 +208TL G 580.5 3 0.0011 2E2 0.0198 3 +208TL2 G KC=0.01470 21$LC=0.00388 6$MC=9.50E-4 14 +208TL G 620.4 3 0.0038 4[M1+E2] 1.0 2 0.037 5 +208TL2 G KC=0.030 4$LC=0.0054 5$MC=0.00129 12 208TL L 760 2 + 208TL A 5344 2 0.00100 8 3770 208TL L 803 2 + @@ -84,75 +84,75 @@ 212PO3C 1968Yt02, 1972DaZA, 1973Da38, 1977La19, 1978Av01, 1982Be09, 1982Sa36, 212PO4C 1983Sc13, 1983Va22, 1984Ge07, 1992Li05, 1996Sc06, 1998ScZM, 1999ScZX, 212PO5C 2002Ra45, 2002Ba85, 2003Au03, 2005Br03, 2007St23, 2007Ma45, 2008Ki07 -212PO T Auger electrons and ^X ray energies and emission intensities: -212PO T {U Energy (keV)} {U Intensity } {U Line } +212PO T Auger electrons and X ray energies and emission intensities: +212PO T {U Energy (keV)} {U Intensity} {U Line} 212PO T -212PO T 76.864 0.0388 8 XKA2 -212PO T 79.293 0.0647 13 XKA1 +212PO T 76.864 0.0388 8 XKA2 +212PO T 79.293 0.0647 13 XKA1 212PO T -212PO T 89.256 |] XKB3 -212PO T 89.807 |] 0.0223 6 XKB1 -212PO T 90.363 |] XKB5II +212PO T 89.256 |] XKB3 +212PO T 89.807 |] 0.0223 6 XKB1 +212PO T 90.363 |] XKB5II 212PO T -212PO T 92.263 |] XKB2 -212PO T 92.618 |] 0.00693 20 XKB4 -212PO T 92.983 |] XKO23 +212PO T 92.263 |] XKB2 +212PO T 92.618 |] 0.00693 20 XKB4 +212PO T 92.983 |] XKO23 212PO T -212PO T 9.658-16.213 0.0563 24 XL (total) -212PO T 9.658 0.00138 4 XLL -212PO T 11.016-11.13 0.0253 7 XLA -212PO T 12.085 0.000440 13 XLC -212PO T 12.823-13.778 0.0241 6 XLB -212PO T 15.742-16.213 0.00477 11 XLG +212PO T 9.658-16.213 0.0563 24 XL (total) +212PO T 9.658 0.00138 4 XLL +212PO T 11.016-11.13 0.0253 7 XLA +212PO T 12.085 0.00044013 XLC +212PO T 12.823-13.778 0.0241 6 XLB +212PO T 15.742-16.213 0.00477 11 XLG 212PO T -212PO T 58.978-65.205 |] KLL AUGER -212PO T 71.902-79.289 |] 0.0048 6 ^KLX AUGER -212PO T 84.8-93.1 |] KXY AUGER -212PO T 5.434-10.934 0.0833 25 L AUGER +212PO T 58.978-65.205 |] KLL AUGER +212PO T 71.902-79.289 |] 0.0048 6 KLX AUGER +212PO T 84.8-93.1 |] KXY AUGER +212PO T 5.434-10.934 0.0833 25 L AUGER 212BI P 0.0 1- 60.54 M 6 2252.1 17 212PO N 1.561E0 1.561E0 0.6407 1.561E0 212PO L 0 0+ 300 NS 2 -212PO B 2252.1 1755.31 9 7.267 1 +212PO B 2252.1 1755.31 9 7.267 1 212POS B EAV=834.2 7 212PO L 727.330 9 2+ -212PO B 1524.8 174.50 6 7.718 1 +212PO B 1524.8 174.50 6 7.718 1 212POS B EAV=533.1 7 -212PO G 727.330 9 6.65 4 E2 0.0139320 -212PO2 G KC=0.01054 15$LC=0.00257 4$MC=6.28E-4 9 +212PO G 727.330 9 6.65 4E2 0.0139320 +212PO2 G KC=0.01054 15$LC=0.00257 4$MC=6.28E-4 9 212PO L 1512.70 8 2+ -212PO B 739.4 171.44 1 7.094 1 +212PO B 739.4 171.44 1 7.094 1 212POS B EAV=230.8 6 -212PO G 785.37 9 1.11 1 M1+E2 0.09 0.0387 6 -212PO2 G KC=0.0316 5$LC=0.00539 8$MC=1266E-6 18 -212PO G 1512.70 8 0.29 1 E2 0.003445 -212PO2 G KC=0.00274 4$LC=4.83E-4 7$MC=1139E-7 16 +212PO G 785.37 9 1.11 1M1+E2 0.09 0.0387 6 +212PO2 G KC=0.0316 5$LC=0.00539 8$MC=1266E-6 18 +212PO G 1512.70 8 0.29 1E2 0.00344 5 +212PO2 G KC=0.00274 4$LC=4.83E-4 7$MC=1139E-7 16 212PO L 1620.738 101+ -212PO B 631.4 171.90 3 6.74 +212PO B 631.4 171.90 3 6.74 212POS B EAV=192.7 6 -212PO G 893.408 140.38 1 M1+E2 0.045 0.0278 4 -212PO2 G KC=0.0227 4$LC=0.00386 6$MC=9.06E-4 13 -212PO G 1620.738 101.51 3 [M1] 0.006209 -212PO2 G KC=0.00494 7$LC=8.24E-4 12$MC=1.93E-4 3 +212PO G 893.408 140.38 1M1+E2 0.045 0.0278 4 +212PO2 G KC=0.0227 4$LC=0.00386 6$MC=9.06E-4 13 +212PO G 1620.738 101.51 3[M1] 0.00620 9 +212PO2 G KC=0.00494 7$LC=8.24E-4 12$MC=1.93E-4 3 212PO L 1679.450 142+ -212PO B 572.7 170.21 4 7.55 1 +212PO B 572.7 170.21 4 7.55 1 212POS B EAV=172.4 6 -212PO G 952.12 2 0.14 4 M1+E2 0.65 0.0190 3 -212PO2 G KC=0.01548 22$LC=0.00269 4$MC=6.34E-4 9 -212PO G 1679.450 140.07 1 E2 0.002914 -212PO2 G KC=0.00227 4$LC=3.91E-4 6$MC=9.20E-5 13 +212PO G 952.12 2 0.14 4M1+E2 0.65 0.0190 3 +212PO2 G KC=0.01548 22$LC=0.00269 4$MC=6.34E-4 9 +212PO G 1679.450 140.07 1E2 0.00291 4 +212PO2 G KC=0.00227 4$LC=3.91E-4 6$MC=9.20E-5 13 212PO L 1800.9 2 0+ -212PO B 451.2 170.032 4 8.03 1 +212PO B 451.2 170.032 4 8.03 1 212POS B EAV=131.7 6 -212PO G 180.2 2 0.0031 12M1 2.08 3 -212PO2 G KC=1.692 25$LC=0.298 5$MC=0.0704 10 -212PO G 1073.6 2 0.0154 6 E2 0.006429 -212PO2 G KC=0.00510 8$LC=1002E-6 14$MC=2.40E-4 4 +212PO G 180.2 2 0.0031 12M1 2.08 3 +212PO2 G KC=1.692 25$LC=0.298 5$MC=0.0704 10 +212PO G 1073.6 2 0.0154 6E2 0.00642 9 +212PO2 G KC=0.00510 8$LC=1002E-6 14$MC=2.40E-4 4 212PO G 1800.9 2 212PO L 1805.96 102+ -212PO B 446.1 170.68 4 6.67 1 +212PO B 446.1 170.68 4 6.67 1 212POS B EAV=130.1 6 -212PO G 1078.63 100.55 2 M1+E2 0.135 0.0169224 -212PO2 G KC=0.01386 20$LC=0.00234 4$MC=5.49E-4 8 -212PO G 1805.96 100.12 3 E2 0.002614 -212PO2 G KC=0.00200 3$LC=3.38E-4 5$MC=7.94E-5 12 +212PO G 1078.63 100.55 2M1+E2 0.135 0.0169224 +212PO2 G KC=0.01386 20$LC=0.00234 4$MC=5.49E-4 8 +212PO G 1805.96 100.12 3E2 0.00261 4 +212PO2 G KC=0.00200 3$LC=3.38E-4 5$MC=7.94E-5 12 diff --git a/HEN_HOUSE/spectra/lnhb/Bi-213.txt b/HEN_HOUSE/spectra/lnhb/Bi-213.txt index 725d3f152..2f565bb22 100644 --- a/HEN_HOUSE/spectra/lnhb/Bi-213.txt +++ b/HEN_HOUSE/spectra/lnhb/Bi-213.txt @@ -1,31 +1,31 @@ 209TL 213BI A DECAY (45.59 M) 209TL H TYP=Full$AUT=X. Huang$CUT=30-JAN-2006$ 209TL C Evaluation history: Type=Full;Author=X. Huang;Cutoff date=30-JAN-2006 -209TL T Auger electrons and ^X ray energies and emission intensities: -209TL T {U Energy (keV)} {U Intensity } {U Line } +209TL T Auger electrons and X ray energies and emission intensities: +209TL T {U Energy (keV)} {U Intensity} {U Line} 209TL T -209TL T 70.8325 0.0058 7 XKA2 -209TL T 72.8725 0.0098 12 XKA1 +209TL T 70.8325 0.0058 7 XKA2 +209TL T 72.8725 0.0098 12 XKA1 209TL T -209TL T 82.118 |] XKB3 -209TL T 82.577 |] 0.0033 5 XKB1 -209TL T 83.115 |] XKB5II +209TL T 82.118 |] XKB3 +209TL T 82.577 |] 0.0033 5 XKB1 +209TL T 83.115 |] XKB5II 209TL T -209TL T 84.838 |] XKB2 -209TL T 85.134 |] 0.00098 14 XKB4 -209TL T 85.444 |] XKO23 +209TL T 84.838 |] XKB2 +209TL T 85.134 |] 0.00098 14 XKB4 +209TL T 85.444 |] XKO23 209TL T -209TL T 8.9531-14.7362 0.0062 8 XL (total) +209TL T 8.9531-14.7362 0.0062 8 XL (total) 209TL T 8.9531 XLL 209TL T 10.1718-10.2679 XLA 209TL T 10.9942 XLC 209TL T 11.8117-12.9566 XLB 209TL T 13.8528-14.7362 XLG 209TL T -209TL T 54.587-59.954 |] KLL AUGER -209TL T 66.37-72.86 |] 0.00076 9 ^KLX AUGER -209TL T 78.12-85.5 |] KXY AUGER -209TL T 5.18-10.13 0.0107 13 L AUGER +209TL T 54.587-59.954 |] KLL AUGER +209TL T 66.37-72.86 |] 0.00076 9 KLX AUGER +209TL T 78.12-85.5 |] KXY AUGER +209TL T 5.18-10.13 0.0107 13 L AUGER 213BI P 0.0 9/2- 45.59 M 6 5983 6 209TL N 4.785E1 4.785E1 0.0209 3 4.785E1 209TL L 0 1/2+ 2.161 M 7 @@ -33,86 +33,86 @@ 209TL L 323.70 2 3/2+ 209TL A 5549 108.90 24103 209TL G 323.70 2 0.1584 24M1+E2 1.26 16 0.178 15 -209TL2 G KC=0.134 14$LC=0.0333 13$MC=0.0081 3 +209TL2 G KC=0.134 14$LC=0.0333 13$MC=0.0081 3 213PO 213BI B- DECAY (45.59 M) 213PO H TYP=Full$AUT=X. Huang$CUT=30-JAN-2006$ 213PO C Evaluation history: Type=Full;Author=X. Huang;Cutoff date=30-JAN-2006 -213PO T Auger electrons and ^X ray energies and emission intensities: -213PO T {U Energy (keV)} {U Intensity } {U Line } +213PO T Auger electrons and X ray energies and emission intensities: +213PO T {U Energy (keV)} {U Intensity} {U Line} 213PO T -213PO T 76.864 1.103 29 XKA2 -213PO T 79.293 1.84 5 XKA1 +213PO T 76.864 1.103 29 XKA2 +213PO T 79.293 1.84 5 XKA1 213PO T -213PO T 89.256 |] XKB3 -213PO T 89.807 |] 0.633 19 XKB1 -213PO T 90.363 |] XKB5II +213PO T 89.256 |] XKB3 +213PO T 89.807 |] 0.633 19 XKB1 +213PO T 90.363 |] XKB5II 213PO T -213PO T 92.263 |] XKB2 -213PO T 92.618 |] 0.197 7 XKB4 -213PO T 92.983 |] XKO23 +213PO T 92.263 |] XKB2 +213PO T 92.618 |] 0.197 7 XKB4 +213PO T 92.983 |] XKO23 213PO T -213PO T 9.6576-16.2129 1.54 4 XL (total) -213PO T 9.6576 0.0387 13 XLL -213PO T 11.0161-11.1303 0.710 21 XLA -213PO T 12.0847 0.0116 4 XLC -213PO T 12.8239-14.2476 0.653 16 XLB -213PO T 15.251-16.2129 0.128 4 XLG +213PO T 9.6576-16.2129 1.54 4 XL (total) +213PO T 9.6576 0.0387 13 XLL +213PO T 11.0161-11.1303 0.710 21 XLA +213PO T 12.0847 0.0116 4 XLC +213PO T 12.8239-14.2476 0.653 16 XLB +213PO T 15.251-16.2129 0.128 4 XLG 213PO T -213PO T 58.978-65.205 |] KLL AUGER -213PO T 71.902-79.289 |] 0.137 16 ^KLX AUGER -213PO T 84.8-93.1 |] KXY AUGER -213PO T 5.43-16.86 2.31 4 L AUGER +213PO T 58.978-65.205 |] KLL AUGER +213PO T 71.902-79.289 |] 0.137 16 KLX AUGER +213PO T 84.8-93.1 |] KXY AUGER +213PO T 5.43-16.86 2.31 4 L AUGER 213BI P 0.0 9/2- 45.59 M 6 1423 5 213PO N 1.021E0 1.021E0 0.9791 3 1.021E0 213PO L 0 9/2+ 3.70 US 5 -213PO B 1423 5 66.2 4 6.316 +213PO B 1423 5 66.2 4 6.316 213POS B EAV=492.2 20 213PO L 292.796 8 11/2+ 78 PS 14 -213PO B 1130 5 0.21 9 8.45 1U +213PO B 1130 5 0.21 9 8.45 1 213POS B EAV=376.8 20 -213PO G 292.80 1 0.421 7 M1+E2 1.2 8 0.30 18 -213PO2 G KC=0.22 17$LC=0.06 2$MC=1.5E-5 3 +213PO G 292.80 1 0.421 7M1+E2 1.2 8 0.30 18 +213PO2 G KC=0.22 17$LC=0.06 2$MC=1.5E-5 3 213PO L 440.439 9 7/2+ 93 PS 3 -213PO B 983 5 30.8 4 6.07 1U +213PO B 983 5 30.8 4 6.07 1 213POS B EAV=320.4 19 -213PO G 147.70 4 0.0128 8 E2 1.453 21 -213PO2 G KC=0.307 4$LC=0.85 1$MC=2.26E-4 3 -213PO G 440.44 1 26.1 3 M1 0.179 3 -213PO2 G KC=0.146 2$LC=0.0250 4$MC=0.00594 8 +213PO G 147.70 4 0.0128 8E2 1.453 21 +213PO2 G KC=0.307 4$LC=0.85 1$MC=2.26E-4 3 +213PO G 440.44 1 26.1 3M1 0.179 3 +213PO2 G KC=0.146 2$LC=0.0250 4$MC=0.00594 8 213PO L 600.8 3 (5/2)+ -213PO B 822 5 0.0025 19 9.9 3U +213PO B 822 5 0.0025 19 9.9 1U 213POS B EAV=260.8 19 213PO G 600.9 2 0.0026 19 213PO L 867.961 2013/2+ -213PO B 555 5 0.0129 6 8.597 3U +213PO B 555 5 0.0129 6 8.597 1U 213POS B EAV=166.4 17 213PO G 574.9 3 0.00068 16 -213PO G 867.96 2 0.0122 6 +213PO G 867.960 200.0122 6 213PO L 1003.593 17(9/2)+ 213PO B 419 5 0.0648 23 7.494 213POS B EAV=121.4 17 -213PO G 402.8 3 0.00010 4 -213PO G 710.82 3 0.0112 6 -213PO G 1003.58 2 0.0535 22 +213PO G 402.8 3 0.00010 4 +213PO G 710.82 3 0.0112 6 +213PO G 1003.580 200.0535 22 213PO L 1045.62 8 (2/9,11/2)+ -213PO B 377 5 0.020 4 7.85 +213PO B 377 5 0.020 4 7.85 213POS B EAV=107.9 16 -213PO G 604.93 170.0014 5 -213PO G 1045.67 8 0.019 4 +213PO G 604.93 170.0014 5 +213PO G 1045.67 8 0.019 4 213PO L 1100.168 8 7/2,9/2,11/2- -213PO B 323 5 0.595 17 6.16 2 +213PO B 323 5 0.595 17 6.16 213POS B EAV=90.8 16 -213PO G 659.75 2 0.043 6 -213PO G 807.37 1 0.287 14 -213PO G 1100.16 1 0.265 6 +213PO G 659.750 200.043 6 +213PO G 807.370 100.287 14 +213PO G 1100.16 1 0.265 6 213PO L 1119.36 4 7/2,9/2,11/2+ -213PO B 304 5 0.0608 20 7.07 1U +213PO B 304 5 0.0608 20 7.07 1 213POS B EAV=84.9 16 -213PO G 826.55 4 0.0065 4 +213PO G 826.550 400.0065 4 213PO G 1119.42 8 0.0543 20 213PO L 1328.2 3 (7/2,9/2,11/2)- -213PO B 95 5 0.0014 2 7.68 2 +213PO B 95 5 0.0014 2 7.68 213POS B EAV=24.6 14 213PO G 886.66 140.00102 19 213PO G 1328.2 3 0.00039 13 diff --git a/HEN_HOUSE/spectra/lnhb/Bi-214.txt b/HEN_HOUSE/spectra/lnhb/Bi-214.txt index 00f26890d..6a3fd762d 100644 --- a/HEN_HOUSE/spectra/lnhb/Bi-214.txt +++ b/HEN_HOUSE/spectra/lnhb/Bi-214.txt @@ -11,18 +11,18 @@ 210TL N 4.762E3 4.762E3 0.00021 4.762E3 210TL G 230 1 0.0029 10 0.0585 11 210TL G 304.2 2 0.0255 23 0.30 19 -210TL G 334.78 8 0.033 5 +210TL G 334.78 8 0.033 5 210TL G 630.79 7 0.0166 14 -210TL G 1226.7 3 0.018 8 +210TL G 1226.7 3 0.018 8 210TL L 0 + 1.30 M 3 210TL A 0 210TL A 5516 3 39.0 24370 210TL L 62.5 10 + 210TL A 5452 3 55.2 33130 -210TL G 62.5 100.0116 7 (M1) +210TL G 62.5 100.0116 7(M1) 210TL L 253.6 15 + 210TL A 5273 9 5.95 33130 -210TL G 191.1 180.00125 7 +210TL G 191.1 180.00125 7 210TL L 335 3 + 210TL A 5184 3 0.619 48450 210TL L 499 4 + @@ -39,364 +39,364 @@ 214PO4C 1983Ol01, 1990Mo08, 1990Co08, 1990Mo**, 1991Li11, 1993Di09, 1995El07, 214PO5C 1996Sc06, 1998Mo14, 2000Sa32, 2002Ba85, 2002De03, 2003Br13, 2002MoZP, 214PO6C 2003Au03, 2004Mo07, 2007BeZP -214PO T Auger electrons and ^X ray energies and emission intensities: -214PO T {U Energy (keV)} {U Intensity } {U Line } +214PO T Auger electrons and X ray energies and emission intensities: +214PO T {U Energy (keV)} {U Intensity} {U Line} 214PO T -214PO T 76.864 0.426 13 XKA2 -214PO T 79.293 0.710 22 XKA1 +214PO T 76.864 0.426 13 XKA2 +214PO T 79.293 0.710 22 XKA1 214PO T -214PO T 89.256 |] XKB3 -214PO T 89.807 |] 0.244 9 XKB1 -214PO T 90.363 |] XKB5II +214PO T 89.256 |] XKB3 +214PO T 89.807 |] 0.244 9 XKB1 +214PO T 90.363 |] XKB5II 214PO T -214PO T 92.263 |] XKB2 -214PO T 92.618 |] 0.0760 29 XKB4 -214PO T 92.983 |] XKO23 +214PO T 92.263 |] XKB2 +214PO T 92.618 |] 0.0760 29 XKB4 +214PO T 92.983 |] XKO23 214PO T -214PO T 9.66-16.21 0.627 15 XL (total) -214PO T 9.66 0.0153 6 XLL -214PO T 11.016-11.13 0.281 9 XLA -214PO T 12.085 0.00502 18 XLC -214PO T 12.824-14.248 0.272 7 XLB -214PO T 15.251-16.21 0.0541 14 XLG +214PO T 9.66-16.21 0.627 15 XL (total) +214PO T 9.66 0.0153 6 XLL +214PO T 11.016-11.13 0.281 9 XLA +214PO T 12.085 0.00502 18 XLC +214PO T 12.824-14.248 0.272 7 XLB +214PO T 15.251-16.21 0.0541 14 XLG 214PO T -214PO T 58.97-65.2 |] KLL AUGER -214PO T 71.93-76.6 |] 0.053 7 ^KLX AUGER -214PO T 84.72-93.04 |] KXY AUGER -214PO T 5.43-16.86 0.934 16 L AUGER +214PO T 58.97-65.2 |] KLL AUGER +214PO T 71.93-76.6 |] 0.053 7 KLX AUGER +214PO T 84.72-93.04 |] KXY AUGER +214PO T 5.43-16.86 0.934 16 L AUGER 214BI P 0.0 1- 19.8 M 1 3270 11 214PO N 1.00E0 1.00E0 0.99979 1.00E0 214PO G 230 1 0.0029 10 0.0585 11 214PO G 304.2 2 0.0255 23 0.30 19 -214PO G 334.78 8 0.033 5 +214PO G 334.78 8 0.033 5 214PO G 630.79 7 0.0166 14 -214PO G 1226.7 3 0.018 8 +214PO G 1226.7 3 0.018 8 214PO L 0 0+ 162.3 US 12 214PO B 3270 1119.67 20 7.9 1 214POS B EAV=1270 5 214PO L 609.316 7 2+ 214PO B 2661 110.62 20 9 1 214POS B EAV=1008 5 -214PO G 609.312 7 45.49 19E2 0.0204 3 -214PO2 G KC=0.01487 21$LC=0.00416 6$MC=1030E-6 15 +214PO G 609.312 7 45.49 19E2 0.0204 3 +214PO2 G KC=0.01487 21$LC=0.00416 6$MC=1030E-6 15 214PO L 1015.05 4 (4)+ -214PO G 405.74 3 0.171 7 [E2] 0.0541 8 -214PO2 G KC=0.0344 5$LC=0.01478 21$MC=0.00377 6 +214PO G 405.74 3 0.171 7[E2] 0.0541 8 +214PO2 G KC=0.0344 5$LC=0.01478 21$MC=0.00377 6 214PO L 1274.761 22(3)- -214PO G 665.453 221.530 7 E1 0.005799 -214PO2 G KC=0.00479 7$LC=7.67E-4 11$MC=1.79E-4 3 +214PO G 665.453 221.530 7E1 0.00579 9 +214PO2 G KC=0.00479 7$LC=7.67E-4 11$MC=1.79E-4 3 214PO L 1377.675 122+ -214PO B 1892 117.45 5 7.4 1 +214PO B 1892 117.45 5 7.4 1 214POS B EAV=685 5 214PO G 768.356 104.892 16M1+E2 2.8 7 0.0157 21 -214PO2 G KC=0.0122 18$LC=0.0026 3$MC=0.00063 6 -214PO G 1377.669 123.968 11E2 0.004046 -214PO2 G KC=0.00324 5$LC=5.85E-4 9$MC=1385E-7 20 +214PO2 G KC=0.0122 18$LC=0.0026 3$MC=0.00063 6 +214PO G 1377.669 123.968 11E2 0.00404 6 +214PO2 G KC=0.00324 5$LC=5.85E-4 9$MC=1385E-7 20 214PO L 1415.489 190+ 99 PS 3 214PO B 1855 110.396 46 8.6 1 214POS B EAV=669 5 -214PO G 806.174 181.262 6 E2 0.0112716 -214PO2 G KC=0.00867 13$LC=0.00197 3$MC=4.80E-4 7 +214PO G 806.174 181.262 6E2 0.0112716 +214PO2 G KC=0.00867 13$LC=0.00197 3$MC=4.80E-4 7 214PO L 1543.375 142+ -214PO B 1727 113.12 4 7.6 1 +214PO B 1727 113.12 4 7.6 1 214POS B EAV=616 5 -214PO G 268.8 2 0.0161 18[E1] 0.0405 6 -214PO2 G KC=0.0329 5$LC=0.00577 9$MC=1359E-6 20 -214PO G 528 1 0.0109 13[E2] 0.0282 5 -214PO2 G KC=0.0198 3$LC=0.00633 10$MC=1584E-6 24 -214PO G 934.061 123.10 1 M1+E2 -0.3 1 0.0234 10 -214PO2 G KC=0.0192 8$LC=0.00327 13$MC=0.00077 3 -214PO G 1543.32 6 0.302 13[E2] 0.003335 -214PO2 G KC=0.00265 4$LC=4.63E-4 7$MC=1093E-7 16 +214PO G 268.80 200.0161 18[E1] 0.0405 6 +214PO2 G KC=0.0329 5$LC=0.00577 9$MC=1359E-6 20 +214PO G 528 1 0.0109 13[E2] 0.0282 5 +214PO2 G KC=0.0198 3$LC=0.00633 10$MC=1584E-6 24 +214PO G 934.061 123.10 1M1+E2 -0.3 1 0.0234 10 +214PO2 G KC=0.0192 8$LC=0.00327 13$MC=0.00077 3 +214PO G 1543.32 6 0.302 13[E2] 0.00333 5 +214PO2 G KC=0.00265 4$LC=4.63E-4 7$MC=1093E-7 16 214PO L 1661.28 3 2+ -214PO B 1609 110.65 6 8.2 1 +214PO B 1609 110.65 6 8.2 1 214POS B EAV=568 4 -214PO G 1051.96 3 0.324 8 [M1E2] 0.012 6 -214PO2 G KC=0.010 5$LC=0.0018 8$MC=0.00042 17 -214PO G 1661.28 6 1.048 9 E2 0.002965 -214PO2 G KC=0.00232 4$LC=3.99E-4 6$MC=9.40E-5 14 +214PO G 1051.960 300.324 8[M1E2] 0.012 6 +214PO2 G KC=0.010 5$LC=0.0018 8$MC=0.00042 17 +214PO G 1661.28 6 1.048 9E2 0.00296 5 +214PO2 G KC=0.00232 4$LC=3.99E-4 6$MC=9.40E-5 14 214PO L 1712.93 20(3)+ 214PO B 1557 110.170 16 8.7 1U 214POS B EAV=547 4 -214PO G 697.90 250.067 4 [M1E2] 0.034 19 -214PO2 G KC=0.027 16$LC=0.0051 23$MC=0.0012 6 -214PO G 1103.64 190.106 15[M1E2] 0.011 5 -214PO2 G KC=0.009 5$LC=0.0016 7$MC=0.00037 15 +214PO G 697.90 250.067 4[M1E2] 0.034 19 +214PO2 G KC=0.027 16$LC=0.0051 23$MC=0.0012 6 +214PO G 1103.64 190.106 15[M1E2] 0.011 5 +214PO2 G KC=0.009 5$LC=0.0016 7$MC=0.00037 15 214PO L 1729.611 132+ 214PO B 1540 1117.494 36 6.7 1 214POS B EAV=540 4 -214PO G 454.770 120.288 5 [E1] 0.0125118 -214PO2 G KC=0.01028 15$LC=1706E-6 24$MC=3.99E-4 6 -214PO G 1120.287 1014.91 3 M1+E2 0.18 2 0.0152223 -214PO2 G KC=0.01246 19$LC=0.00210 3$MC=4.94E-4 8 -214PO G 1729.595 152.844 10E2 0.002784 -214PO2 G KC=0.00216 3$LC=3.68E-4 6$MC=8.66E-5 13 +214PO G 454.770 120.288 5[E1] 0.0125118 +214PO2 G KC=0.01028 15$LC=1706E-6 24$MC=3.99E-4 6 +214PO G 1120.287 1014.91 3M1+E2 0.18 2 0.0152223 +214PO2 G KC=0.01246 19$LC=0.00210 3$MC=4.94E-4 8 +214PO G 1729.595 152.844 10E2 0.00278 4 +214PO2 G KC=0.00216 3$LC=3.68E-4 6$MC=8.66E-5 13 214PO L 1742.98 3 0+ 214PO B 1527 110.116 16 8.8 1 214POS B EAV=535 4 -214PO G 1133.66 3 0.254 8 [E2] 0.005788 -214PO2 G KC=0.00462 7$LC=8.88E-4 13$MC=2.12E-4 3 +214PO G 1133.660 300.254 8[E2] 0.00578 8 +214PO2 G KC=0.00462 7$LC=8.88E-4 13$MC=2.12E-4 3 214PO L 1764.498 141+ -214PO B 1506 1117.10 8 6.6 +214PO B 1506 1117.10 8 6.6 214POS B EAV=526 4 -214PO G 221 1 0.059 6 [M1E2] 0.8 5 -214PO2 G KC=0.5 5$LC=0.158 10$MC=0.0394 9 -214PO G 348.92 6 0.123 32[M1] 0.335 5 -214PO2 G KC=0.272 4$LC=0.0475 7$MC=0.01118 16 -214PO G 386.77 5 0.296 5 [M1E2] 0.16 10 -214PO2 G KC=0.12 9$LC=0.027 10$MC=0.0065 20 -214PO G 1155.19 2 1.635 7 M1+E2 0.33 6 0.0135 4 -214PO2 G KC=0.0110 3$LC=0.00187 5$MC=4.38E-4 11 -214PO G 1764.494 1415.31 5 M1 0.005118 -214PO2 G KC=0.00397 6$LC=6.61E-4 10$MC=1548E-7 22 +214PO G 221 1 0.059 6[M1E2] 0.8 5 +214PO2 G KC=0.5 5$LC=0.158 10$MC=0.0394 9 +214PO G 348.92 6 0.123 32[M1] 0.335 5 +214PO2 G KC=0.272 4$LC=0.0475 7$MC=0.01118 16 +214PO G 386.77 5 0.296 5[M1E2] 0.16 10 +214PO2 G KC=0.12 9$LC=0.027 10$MC=0.0065 20 +214PO G 1155.190 201.635 7M1+E2 0.33 6 0.0135 4 +214PO2 G KC=0.0110 3$LC=0.00187 5$MC=4.38E-4 11 +214PO G 1764.494 1415.31 5M1 0.00511 8 +214PO2 G KC=0.00397 6$LC=6.61E-4 10$MC=1548E-7 22 214PO L 1847.431 142+ 214PO B 1423 118.147 28 6.9 1 214POS B EAV=493 4 -214PO G 469.76 7 0.133 15[M1E2] 0.09 6 -214PO2 G KC=0.07 5$LC=0.015 6$MC=0.0036 14 -214PO G 572.76 7 0.071 8 [E1] 0.0077911 -214PO2 G KC=0.00643 9$LC=1042E-6 15$MC=2.43E-4 4 -214PO G 832.39 110.035 2 [E2] 0.0105715 -214PO2 G KC=0.00816 12$LC=0.00182 4$MC=4.42E-4 7 +214PO G 469.76 7 0.133 15[M1E2] 0.09 6 +214PO2 G KC=0.07 5$LC=0.015 6$MC=0.0036 14 +214PO G 572.76 7 0.071 8[E1] 0.0077911 +214PO2 G KC=0.00643 9$LC=1042E-6 15$MC=2.43E-4 4 +214PO G 832.39 110.035 2[E2] 0.0105715 +214PO2 G KC=0.00816 12$LC=0.00182 4$MC=4.42E-4 7 214PO G 1238.111 125.831 14M1+E2 -0.03 3 0.0120017 -214PO2 G KC=0.00983 14$LC=1651E-6 24$MC=3.87E-4 6 +214PO2 G KC=0.00983 14$LC=1651E-6 24$MC=3.87E-4 6 214PO G 1847.420 252.025 12 214PO L 1890.287 212+ 214PO B 1380 111.584 10 7.5 1 214POS B EAV=476 4 -214PO G 615.73 100.055 7 [E1] 0.0067410 -214PO2 G KC=0.00557 8$LC=8.98E-4 13$MC=2.09E-4 3 -214PO G 1280.96 2 1.435 6 M1 0.0110116 -214PO2 G KC=0.00901 13$LC=1513E-6 22$MC=3.55E-4 5 -214PO G 1890.30 150.078 4 +214PO G 615.73 100.055 7[E1] 0.0067410 +214PO2 G KC=0.00557 8$LC=8.98E-4 13$MC=2.09E-4 3 +214PO G 1280.96 2 1.435 6M1 0.0110116 +214PO2 G KC=0.00901 13$LC=1513E-6 22$MC=3.55E-4 5 +214PO G 1890.30 150.078 4 214PO L 1994.63 3 (2)- 214PO B 1275 111.171 18 7.5 214POS B EAV=434 4 -214PO G 333.350 420.063 4 [E1] 0.0247 4 -214PO2 G KC=0.0202 3$LC=0.00345 5$MC=8.11E-4 12 -214PO G 617.0 2 0.027 5 [E1] 0.0067210 -214PO2 G KC=0.00555 8$LC=8.94E-4 13$MC=2.09E-4 3 -214PO G 719.86 3 0.393 10E2 0.0142420 -214PO2 G KC=0.01075 15$LC=0.00264 4$MC=6.46E-4 9 -214PO G 1385.31 3 0.795 5 [E1] 1631E-623 -214PO2 G KC=1281E-6 18$LC=1.96E-4 3$MC=4.53E-5 7 +214PO G 333.350 420.063 4[E1] 0.0247 4 +214PO2 G KC=0.0202 3$LC=0.00345 5$MC=8.11E-4 12 +214PO G 617.0 2 0.027 5[E1] 0.0067210 +214PO2 G KC=0.00555 8$LC=8.94E-4 13$MC=2.09E-4 3 +214PO G 719.860 300.393 10E2 0.0142420 +214PO2 G KC=0.01075 15$LC=0.00264 4$MC=6.46E-4 9 +214PO G 1385.310 300.795 5[E1] 1631E-623 +214PO2 G KC=1281E-6 18$LC=1.96E-4 3$MC=4.53E-5 7 214PO L 2010.81 4 2+ -214PO B 1259 111.430 9 7.4 1 +214PO B 1259 111.430 9 7.4 1 214POS B EAV=428 4 -214PO G 595.23 7 0.0174 15[M1E2] 0.05 3 -214PO2 G KC=0.04 3$LC=0.008 4$MC=0.0019 8 -214PO G 633.14 100.055 3 [M1E2] 0.044 25 -214PO2 G KC=0.035 21$LC=0.007 3$MC=0.0016 7 -214PO G 1401.50 4 1.330 7 (M1+E2) 1.6 5 0.0053 9 -214PO2 G KC=0.0043 7$LC=0.00074 11$MC=0.00017 3 +214PO G 595.23 7 0.0174 15[M1E2] 0.05 3 +214PO2 G KC=0.04 3$LC=0.008 4$MC=0.0019 8 +214PO G 633.14 100.055 3[M1E2] 0.044 25 +214PO2 G KC=0.035 21$LC=0.007 3$MC=0.0016 7 +214PO G 1401.500 401.330 7(M1+E2) 1.6 5 0.0053 9 +214PO2 G KC=0.0043 7$LC=0.00074 11$MC=0.00017 3 214PO G 2010.78 120.0434 17 214PO L 2017.30 5 0+ 214PO B 1253 112.449 10 7.2 1 214POS B EAV=425 4 214PO G 252.80 6 0.0117 18[M1] 0.809 12 -214PO2 G KC=0.658 10$LC=0.1154 17$MC=0.0272 4 -214PO G 639.67 100.034 5 [E2] 0.0183 3 -214PO2 G KC=0.01351 19$LC=0.00363 5$MC=8.95E-4 13 -214PO G 1407.98 4 2.389 8 (E2) 0.003896 -214PO2 G KC=0.00312 5$LC=5.59E-4 8$MC=1323E-7 19 +214PO2 G KC=0.658 10$LC=0.1154 17$MC=0.0272 4 +214PO G 639.67 100.034 5[E2] 0.0183 3 +214PO2 G KC=0.01351 19$LC=0.00363 5$MC=8.95E-4 13 +214PO G 1407.98 4 2.389 8(E2) 0.00389 6 +214PO2 G KC=0.00312 5$LC=5.59E-4 8$MC=1323E-7 19 214PO L 2088.41 12(1-),(1,2)+ -214PO B 1182 110.114 6 8.4 +214PO B 1182 110.114 6 8.4 214POS B EAV=398 4 -214PO G 710.67 100.076 4 -214PO G 1479.15 140.051 4 +214PO G 710.67 100.076 4 +214PO G 1479.15 140.051 4 214PO L 2118.552 171+ 214PO B 1151 114.339 18 6.8 214POS B EAV=386 4 -214PO G 388.88 5 0.394 5 (M1) 0.250 4 -214PO2 G KC=0.203 3$LC=0.0353 5$MC=0.00832 12 -214PO G 703.11 4 0.479 11[M1] 0.0519 8 -214PO2 G KC=0.0424 6$LC=0.00724 11$MC=1702E-6 24 +214PO G 388.88 5 0.394 5(M1) 0.250 4 +214PO2 G KC=0.203 3$LC=0.0353 5$MC=0.00832 12 +214PO G 703.11 4 0.479 11[M1] 0.0519 8 +214PO2 G KC=0.0424 6$LC=0.00724 11$MC=1702E-6 24 214PO G 740.73 180.0428 21[M1E2] 0.029 16 -214PO2 G KC=0.024 14$LC=0.0044 20$MC=0.0010 5 +214PO2 G KC=0.024 14$LC=0.0044 20$MC=0.0010 5 214PO G 1509.228 152.128 10M1+E2 -0.053 35 0.0073211 -214PO2 G KC=0.00591 9$LC=9.88E-4 14$MC=2.32E-4 4 -214PO G 2118.55 3 1.158 5 M1 0.003565 -214PO2 G KC=0.00248 4$LC=4.12E-4 6$MC=9.64E-5 14 +214PO2 G KC=0.00591 9$LC=9.88E-4 14$MC=2.32E-4 4 +214PO G 2118.550 301.158 5M1 0.00356 5 +214PO2 G KC=0.00248 4$LC=4.12E-4 6$MC=9.64E-5 14 214PO L 2147.78 6 1(-),2+ 214PO B 1122 110.433 22 7.8 214POS B EAV=375 4 -214PO G 873.07 190.019 3 +214PO G 873.07 190.019 3 214PO G 1538.50 6 0.401 22 214PO G 2147.9 2 0.0134 13 214PO L 2192.56 4 2+ 214PO B 1077 110.851 10 7.4 1 214POS B EAV=357 4 -214PO G 649.18 7 0.054 7 [M1E2] 0.041 24 -214PO2 G KC=0.033 20$LC=0.006 3$MC=0.0015 7 -214PO G 815.0 1 0.039 3 [M1E2] 0.023 13 -214PO2 G KC=0.019 11$LC=0.0034 15$MC=0.0008 4 -214PO G 917.8 3 0.005 3 [E1] 0.003175 -214PO2 G KC=0.00263 4$LC=4.11E-4 6$MC=9.56E-5 14 -214PO G 1583.22 4 0.707 5 M1+E2 -0.2 1 0.0064218 -214PO2 G KC=0.00513 14$LC=8.58E-4 23$MC=2.01E-4 6 -214PO G 2192.58 160.038 3 +214PO G 649.18 7 0.054 7[M1E2] 0.041 24 +214PO2 G KC=0.033 20$LC=0.006 3$MC=0.0015 7 +214PO G 815.00 100.039 3[M1E2] 0.023 13 +214PO2 G KC=0.019 11$LC=0.0034 15$MC=0.0008 4 +214PO G 917.8 3 0.005 3[E1] 0.00317 5 +214PO2 G KC=0.00263 4$LC=4.11E-4 6$MC=9.56E-5 14 +214PO G 1583.220 400.707 5M1+E2 -0.2 1 0.0064218 +214PO2 G KC=0.00513 14$LC=8.58E-4 23$MC=2.01E-4 6 +214PO G 2192.58 160.038 3 214PO L 2204.13 9 1+ 214PO B 1066 115.642 43 6.6 214POS B EAV=353 4 -214PO G 461.0 2 0.058 8 [M1] 0.1581 23 -214PO2 G KC=0.1289 19$LC=0.0223 4$MC=0.00525 8 -214PO G 474.41 5 0.092 6 [M1E2] 0.09 6 -214PO2 G KC=0.07 5$LC=0.015 6$MC=0.0035 14 -214PO G 543.0 2 0.088 21[M1E2] 0.06 4 -214PO2 G KC=0.05 4$LC=0.010 5$MC=0.0024 10 -214PO G 661.1 2 0.054 4 [M1E2] 0.039 22 -214PO2 G KC=0.031 19$LC=0.006 3$MC=0.0014 6 -214PO G 788.6 5 0.015 5 [M1] 0.0385 6 -214PO2 G KC=0.0315 5$LC=0.00536 8$MC=1258E-6 18 -214PO G 826.3 2 0.129 11M1 0.0341 5 -214PO2 G KC=0.0279 4$LC=0.00474 7$MC=1113E-6 16 -214PO G 1594.73 8 0.274 15[M1] 0.006449 -214PO2 G KC=0.00514 8$LC=8.59E-4 12$MC=2.01E-4 3 -214PO G 2204.21 4 4.913 23M1 0.003335 -214PO2 G KC=0.00224 4$LC=3.72E-4 6$MC=8.70E-5 13 +214PO G 461.00 200.058 8[M1] 0.1581 23 +214PO2 G KC=0.1289 19$LC=0.0223 4$MC=0.00525 8 +214PO G 474.41 5 0.092 6[M1E2] 0.09 6 +214PO2 G KC=0.07 5$LC=0.015 6$MC=0.0035 14 +214PO G 543.0 2 0.088 21[M1E2] 0.06 4 +214PO2 G KC=0.05 4$LC=0.010 5$MC=0.0024 10 +214PO G 661.1 2 0.054 4[M1E2] 0.039 22 +214PO2 G KC=0.031 19$LC=0.006 3$MC=0.0014 6 +214PO G 788.6 5 0.015 5[M1] 0.0385 6 +214PO2 G KC=0.0315 5$LC=0.00536 8$MC=1258E-6 18 +214PO G 826.30 200.129 11M1 0.0341 5 +214PO2 G KC=0.0279 4$LC=0.00474 7$MC=1113E-6 16 +214PO G 1594.73 8 0.274 15[M1] 0.00644 9 +214PO2 G KC=0.00514 8$LC=8.59E-4 12$MC=2.01E-4 3 +214PO G 2204.21 4 4.913 23M1 0.00333 5 +214PO2 G KC=0.00224 4$LC=3.72E-4 6$MC=8.70E-5 13 214PO L 2208.67 7 (2,3)+ -214PO G 547.6 3 0.034 3 +214PO G 547.6 3 0.034 3 214PO G 1599.31 6 0.322 15 214PO L 2266.39 181(-),2+ 214PO B 1004 110.187 12 8 214POS B EAV=329 4 214PO G 501.96 150.0181 22 -214PO G 536.77 4 0.061 8 -214PO G 722.98 120.037 7 -214PO G 991.49 190.011 3 [M1E2] 0.014 7 -214PO2 G KC=0.012 6$LC=0.0021 9$MC=0.00049 21 -214PO G 1657.00 190.047 5 -214PO G 2266.51 130.0165 8 +214PO G 536.77 4 0.061 8 +214PO G 722.98 120.037 7 +214PO G 991.49 190.011 3[M1E2] 0.014 7 +214PO2 G KC=0.012 6$LC=0.0021 9$MC=0.00049 21 +214PO G 1657.00 190.047 5 +214PO G 2266.51 130.0165 8 214PO L 2293.34 5 1(+),2+ -214PO B 977 110.558 8 7.4 +214PO B 977 110.558 8 7.4 214POS B EAV=319 4 214PO G 878.03 120.0118 27[M1E2] 0.019 10 -214PO2 G KC=0.016 9$LC=0.0028 13$MC=0.0007 3 -214PO G 915.74 150.023 5 [M1E2] 0.017 9 -214PO2 G KC=0.014 8$LC=0.0025 11$MC=0.0006 3 -214PO G 1683.99 4 0.217 3 -214PO G 2293.40 120.306 4 +214PO2 G KC=0.016 9$LC=0.0028 13$MC=0.0007 3 +214PO G 915.74 150.023 5[M1E2] 0.017 9 +214PO2 G KC=0.014 8$LC=0.0025 11$MC=0.0006 3 +214PO G 1683.99 4 0.217 3 +214PO G 2293.40 120.306 4 214PO L 2348.3 9 (1-),(1,2)+ -214PO B 922 110.0014 9 9.9 +214PO B 922 110.0014 9 9.9 214POS B EAV=298 4 -214PO G 2348.0 130.0014 9 +214PO G 2348.0 130.0014 9 214PO L 2360.8 4 (1-),(1,2)+ -214PO B 909 110.0030 8 9.6 +214PO B 909 110.0030 8 9.6 214POS B EAV=294 4 -214PO G 1751.4 8 0.0009 5 -214PO G 2361.00 190.0021 6 +214PO G 1751.4 8 0.0009 5 +214PO G 2361.00 190.0021 6 214PO L 2423.19 15(1-),(1,2)+ 214PO B 847 110.0620 49 8.1 214POS B EAV=271 4 -214PO G 658.7 2 0.017 4 +214PO G 658.7 2 0.017 4 214PO G 693.3 5 0.0059 15 -214PO G 1045.6 2 0.023 3 -214PO G 1813.73 140.0108 9 -214PO G 2423.27 130.0048 6 +214PO G 1045.6 2 0.023 3 +214PO G 1813.73 140.0108 9 +214PO G 2423.27 130.0048 6 214PO L 2447.70 6 1- -214PO B 822 112.76 6 6.5 +214PO B 822 112.76 6 6.5 214POS B EAV=262 4 -214PO G 452.92 100.031 4 [M1E2] 0.10 7 -214PO2 G KC=0.08 6$LC=0.017 7$MC=0.0040 15 -214PO G 683.22 6 0.084 6 [E1] 0.005518 -214PO2 G KC=0.00456 7$LC=7.28E-4 11$MC=1696E-7 2 -214PO G 704.9 3 0.051 10[E1] 0.005198 -214PO2 G KC=0.00429 6$LC=6.84E-4 10$MC=1593E-7 23 -214PO G 786.1 4 0.31 5 [E1] 0.004226 -214PO2 G KC=0.00350 5$LC=5.53E-4 8$MC=1285E-7 18 -214PO G 904.29 100.066 8 [E1] 0.003265 -214PO2 G KC=0.00271 4$LC=4.23E-4 6$MC=9.83E-5 14 -214PO G 1032.37 8 0.061 4 [E1] 0.002574 -214PO2 G KC=0.00213 3$LC=3.31E-4 5$MC=7.68E-5 11 -214PO G 1069.96 8 0.271 10[E1] 0.002414 -214PO2 G KC=0.00200 3$LC=3.10E-4 5$MC=7.19E-5 10 -214PO G 1172.98 100.055 7 [E2] 0.005428 -214PO2 G KC=0.00434 6$LC=8.24E-4 12$MC=1.96E-4 3 +214PO G 452.92 100.031 4[M1E2] 0.10 7 +214PO2 G KC=0.08 6$LC=0.017 7$MC=0.0040 15 +214PO G 683.22 6 0.084 6[E1] 0.00551 8 +214PO2 G KC=0.00456 7$LC=7.28E-4 11$MC=1696E-7 2 +214PO G 704.9 3 0.051 10[E1] 0.00519 8 +214PO2 G KC=0.00429 6$LC=6.84E-4 10$MC=1593E-7 23 +214PO G 786.1 4 0.31 5[E1] 0.00422 6 +214PO2 G KC=0.00350 5$LC=5.53E-4 8$MC=1285E-7 18 +214PO G 904.29 100.066 8[E1] 0.00326 5 +214PO2 G KC=0.00271 4$LC=4.23E-4 6$MC=9.83E-5 14 +214PO G 1032.37 8 0.061 4[E1] 0.00257 4 +214PO2 G KC=0.00213 3$LC=3.31E-4 5$MC=7.68E-5 11 +214PO G 1069.96 8 0.271 10[E1] 0.00241 4 +214PO2 G KC=0.00200 3$LC=3.10E-4 5$MC=7.19E-5 10 +214PO G 1172.98 100.055 7[E2] 0.00542 8 +214PO2 G KC=0.00434 6$LC=8.24E-4 12$MC=1.96E-4 3 214PO G 1838.36 5 0.343 10 -214PO G 2447.86 101.548 7 E1 1424E-620 -214PO2 G KC=5.03E-4 7$LC=7.51E-5 11$MC=1735E-8 25 +214PO G 2447.86 101.548 7E1 1424E-620 +214PO2 G KC=5.03E-4 7$LC=7.51E-5 11$MC=1735E-8 25 214PO L 2482.46 4 (2)+ 214PO B 788 111.227 27 6.8 1 214POS B EAV=249 3 -214PO G 273.80 5 0.120 8 +214PO G 273.80 5 0.120 8 214PO G 394.05 8 0.0127 18 -214PO G 487.95 130.028 9 [E1] 0.0108016 -214PO2 G KC=0.00889 13$LC=1463E-6 21$MC=3.42E-4 5 +214PO G 487.95 130.028 9[E1] 0.0108016 +214PO2 G KC=0.00889 13$LC=1463E-6 21$MC=3.42E-4 5 214PO G 634.72 210.0064 23[M1E2] 0.043 25 -214PO2 G KC=0.035 21$LC=0.007 3$MC=0.0016 7 -214PO G 752.84 3 0.126 8 [M1E2] 0.028 16 -214PO2 G KC=0.023 13$LC=0.0042 19$MC=0.0010 5 -214PO G 821.18 3 0.166 10M1 0.0346 5 -214PO2 G KC=0.0283 4$LC=0.00482 7$MC=1131E-6 16 -214PO G 939.6 5 0.016 4 [M1E2] 0.016 8 -214PO2 G KC=0.013 7$LC=0.0024 11$MC=0.00056 24 -214PO G 1104.79 190.073 14[M1E2] 0.011 5 -214PO2 G KC=0.009 5$LC=0.0016 7$MC=0.00037 15 -214PO G 1207.68 3 0.454 12[E1] 0.001963 -214PO2 G KC=1622E-6 23$LC=2.49E-4 4$MC=5.77E-5 8 -214PO G 1873.16 6 0.212 8 +214PO2 G KC=0.035 21$LC=0.007 3$MC=0.0016 7 +214PO G 752.84 3 0.126 8[M1E2] 0.028 16 +214PO2 G KC=0.023 13$LC=0.0042 19$MC=0.0010 5 +214PO G 821.18 3 0.166 10M1 0.0346 5 +214PO2 G KC=0.0283 4$LC=0.00482 7$MC=1131E-6 16 +214PO G 939.6 5 0.016 4[M1E2] 0.016 8 +214PO2 G KC=0.013 7$LC=0.0024 11$MC=0.00056 24 +214PO G 1104.79 190.073 14[M1E2] 0.011 5 +214PO2 G KC=0.009 5$LC=0.0016 7$MC=0.00037 15 +214PO G 1207.68 3 0.454 12[E1] 0.00196 3 +214PO2 G KC=1622E-6 23$LC=2.49E-4 4$MC=5.77E-5 8 +214PO G 1873.16 6 0.212 8 214PO G 2482.8 4 0.00096 18 214PO L 2505.21 151(-),2+ 214PO B 765 110.169 10 7.6 214POS B EAV=241 4 214PO G 961.61 170.0101 14 -214PO G 1230.6 4 0.007 5 -214PO G 1895.92 140.146 8 -214PO G 2505.4 2 0.0056 6 +214PO G 1230.6 4 0.007 5 +214PO G 1895.92 140.146 8 +214PO G 2505.4 2 0.0056 6 214PO L 2508.2 2 + -214PO B 762 110.092 9 7.9 +214PO B 762 110.092 9 7.9 214POS B EAV=240 4 214PO G 496.90 180.0068 18 -214PO G 1130.29 190.036 3 -214PO G 1898.7 4 0.049 8 +214PO G 1130.29 190.036 3 +214PO G 1898.7 4 0.049 8 214PO L 2544.9 3 + -214PO B 725 110.044 7 8.1 +214PO B 725 110.044 7 8.1 214POS B EAV=226 4 214PO G 1167.3 2 0.0123 17 -214PO G 1935.5 2 0.032 7 +214PO G 1935.5 2 0.032 7 214PO L 2553.0 6 + 214PO L 2562.4 3 + -214PO B 708 110.00018 9 10.5 +214PO B 708 110.00018 9 10.5 214POS B EAV=220 4 -214PO G 2562.0 6 0.00018 9 +214PO G 2562.0 6 0.00018 9 214PO L 2604.66 14(2)+ -214PO B 665 110.058 4 7.7 1 +214PO B 665 110.058 4 7.7 1 214POS B EAV=205 4 214PO G 396.01 8 0.0259 18 -214PO G 943.34 120.017 3 +214PO G 943.34 120.017 3 214PO G 1330.0 2 0.0120 14 -214PO G 1994.6 6 0.0024 5 -214PO G 2604.5 5 0.00036 9 +214PO G 1994.6 6 0.0024 5 +214PO G 2604.5 5 0.00036 9 214PO L 2630.85 17(1-),(1,2)+ 214PO B 639 110.0223 21 8.2 214POS B EAV=196 4 214PO G 2021.6 2 0.0214 21 214PO G 2630.9 3 0.00086 23 214PO L 2662.29 12(2)+ -214PO B 608 110.098 9 7.5 1 +214PO B 608 110.098 9 7.5 1 214POS B EAV=185 4 214PO G 949.8 5 0.0055 23 -214PO G 1118.9 5 0.010 4 -214PO G 1284 1 0.013 6 -214PO G 2052.94 120.069 4 -214PO G 2662.4 102.00E-4 41 +214PO G 1118.9 5 0.010 4 +214PO G 1284 1 0.013 6 +214PO G 2052.94 120.069 4 +214PO G 2662.4 100.00020041 214PO L 2694.6 2 1(-),2+ 214PO B 575 110.231 15 7 214POS B EAV=174 4 -214PO G 485.92 110.021 4 +214PO G 485.92 110.021 4 214PO G 677.41 150.0055 23 -214PO G 699.82 180.016 5 -214PO G 847.16 110.016 6 -214PO G 930.2 2 0.043 8 +214PO G 699.82 180.016 5 +214PO G 847.16 110.016 6 +214PO G 930.2 2 0.043 8 214PO G 952.2 8 0.0059 23 -214PO G 1316.96 150.077 7 +214PO G 1316.96 150.077 7 214PO G 1419.7 3 0.0055 10 -214PO G 2085.1 2 0.0082 5 -214PO G 2694.7 2 0.033 3 +214PO G 2085.1 2 0.0082 5 +214PO G 2694.7 2 0.033 3 214PO L 2698.8 3 (1-,2+)+ -214PO B 571 110.026 4 8 +214PO B 571 110.026 4 8 214POS B EAV=173 4 -214PO G 494.2 4 0.011 3 +214PO G 494.2 4 0.011 3 214PO G 687.6 3 0.0066 14 214PO G 1038.0 3 0.0086 15 214PO L 2699.2 2 1(-),2+ @@ -405,37 +405,37 @@ 214PO G 2089.7 2 0.0443 22 214PO G 2699.4 3 0.00282 23 214PO L 2719.22 9 (1-),(1,2)+ -214PO B 551 110.247 8 6.9 +214PO B 551 110.247 8 6.9 214POS B EAV=166 4 -214PO G 600.0 5 0.008 4 +214PO G 600.0 5 0.008 4 214PO G 708.8 3 0.0119 20 214PO G 976.18 120.0151 21 -214PO G 1303.76 8 0.105 5 +214PO G 1303.76 8 0.105 5 214PO G 1341.49 160.0214 27 -214PO G 2109.92 120.084 3 +214PO G 2109.92 120.084 3 214PO G 2719.3 2 0.00170 17 214PO L 2728.59 4 (1,2)+ 214PO B 541 110.525 16 6.6 214POS B EAV=162 4 -214PO G 280.95 5 0.062 6 +214PO G 280.95 5 0.062 6 214PO G 519.90 5 0.0166 17 214PO G 524.6 2 0.0169 17 -214PO G 733.80 150.038 3 +214PO G 733.80 150.038 3 214PO G 964.08 3 0.363 12 -214PO G 1067.2 3 0.024 7 +214PO G 1067.2 3 0.024 7 214PO G 1351 1 0.0042 11 214PO L 2769.9 2 (1-),(1,2)+ -214PO B 500 110.038 5 7.6 +214PO B 500 110.038 5 7.6 214POS B EAV=149 4 214PO G 1392.5 4 0.0087 19 -214PO G 2160.4 3 0.007 5 -214PO G 2769.9 2 0.0225 8 +214PO G 2160.4 3 0.007 5 +214PO G 2769.9 2 0.0225 8 214PO L 2785.9 2 (1-),(1,2)+ 214PO B 484 110.0248 31 7.8 214POS B EAV=143 4 -214PO G 1021.0 5 0.016 3 -214PO G 2176.5 2 0.0033 6 -214PO G 2785.9 2 0.0055 5 +214PO G 1021.0 5 0.016 3 +214PO G 2176.5 2 0.0033 6 +214PO G 2785.9 2 0.0055 5 214PO L 2794.1 6 + 214PO L 2802.6 6 + 214PO L 2827.0 2 (1-),(1,2)+ @@ -446,125 +446,125 @@ 214PO B 409 110.0146 20 7.6 214POS B EAV=119 4 214PO G 1013.8 2 0.0087 19 -214PO G 2251.6 2 0.0055 5 +214PO G 2251.6 2 0.0055 5 214PO G 2861.08 400.00041 13 214PO L 2869.6 2 + -214PO B 400 110.0087 4 7.9 +214PO B 400 110.0087 4 7.9 214POS B EAV=116 3 -214PO G 2260.3 2 0.0087 4 +214PO G 2260.3 2 0.0087 4 214PO L 2880.3 2 (1-),(1,2)+ 214PO B 390 110.0115 16 7.8 214POS B EAV=113 3 -214PO G 2270.9 4 0.0014 3 +214PO G 2270.9 4 0.0014 3 214PO G 2880.3 2 0.0101 16 214PO L 2893.6 2 (1-),(1,2)+ -214PO B 376 110.022 3 7.5 +214PO B 376 110.022 3 7.5 214POS B EAV=108 3 214PO G 626.4 6 0.0041 14 214PO G 1515.5 3 0.0072 21 -214PO G 2284.3 2 0.0050 4 -214PO G 2893.5 2 0.0057 5 +214PO G 2284.3 2 0.0050 4 +214PO G 2893.5 2 0.0057 5 214PO L 2897.0 3 + -214PO B 373 110.0046 5 8.1 +214PO B 373 110.0046 5 8.1 214POS B EAV=107 3 -214PO G 2287.65 230.0046 5 +214PO G 2287.65 230.0046 5 214PO L 2919.5 3 + -214PO B 350 110.0014 9 8.6 +214PO B 350 110.0014 9 8.6 214POS B EAV=100 3 -214PO G 2310.2 3 0.0014 9 +214PO G 2310.2 3 0.0014 9 214PO L 2921.8 4 (1-),(1,2)+ -214PO B 348 110.0220 9 7.3 +214PO B 348 110.0220 9 7.3 214POS B EAV=99 3 -214PO G 2312.4 2 0.0086 8 -214PO G 2921.9 2 0.0134 5 +214PO G 2312.4 2 0.0086 8 +214PO G 2921.9 2 0.0134 5 214PO L 2928.6 3 (1-),(1,2)+ -214PO B 341 110.0025 9 8.3 +214PO B 341 110.0025 9 8.3 214POS B EAV=97 3 -214PO G 2319.3 3 0.0014 9 -214PO G 2928.6 3 0.00109 9 +214PO G 2319.3 3 0.0014 9 +214PO G 2928.6 3 0.00109 9 214PO L 2934.5 3 (1-),(1,2)+ 214PO B 336 110.00216 32 8.3 214POS B EAV=95 3 -214PO G 2325.0 3 0.0017 3 +214PO G 2325.0 3 0.0017 3 214PO G 2934.6 3 0.00046 12 214PO L 2940.6 2 (1,2-),2+ -214PO B 329 110.041 7 7 +214PO B 329 110.041 7 7 214POS B EAV=93 3 -214PO G 1665.8 2 0.015 6 -214PO G 2331.3 2 0.026 4 +214PO G 1665.8 2 0.015 6 +214PO G 2331.3 2 0.026 4 214PO L 2962.8 7 + 214PO B 307 110.00036 14 9 214POS B EAV=87 3 214PO G 2353.5 7 0.00036 14 214PO L 2967.6 6 + 214PO L 2978.8 2 (1-),(1,2)+ -214PO B 291 110.0165 6 7.2 +214PO B 291 110.0165 6 7.2 214POS B EAV=82 3 -214PO G 2369.0 4 0.0028 4 -214PO G 2978.9 2 0.0137 4 +214PO G 2369.0 4 0.0028 4 +214PO G 2978.9 2 0.0137 4 214PO L 2986.2 2 (1,2 -),(2)+ -214PO B 284 110.032 5 6.9 +214PO B 284 110.032 5 6.9 214POS B EAV=80 3 -214PO G 1711.0 8 0.023 5 -214PO G 2376.9 2 0.0086 8 +214PO G 1711.0 8 0.023 5 +214PO G 2376.9 2 0.0086 8 214PO L 3000.0 2 (1-),(2)+ 214PO B 270 110.0160 16 7.1 214POS B EAV=75 3 214PO G 551.9 8 0.0055 14 214PO G 2390.8 2 0.00156 14 -214PO G 2999.98 200.0089 7 +214PO G 2999.98 200.0089 7 214PO L 3003 1 + 214PO L 3005.8 6 + 214PO L 3014.1 3 (1-),(1,2)+ 214PO B 256 110.0252 24 6.9 214POS B EAV=71 3 -214PO G 1353.4 8 0.0036 9 +214PO G 1353.4 8 0.0036 9 214PO G 1470.9 3 0.0094 13 214PO G 1636.3 2 0.0111 16 -214PO G 2405.1 5 0.0011 7 +214PO G 2405.1 5 0.0011 7 214PO L 3022.3 3 + 214PO L 3030.3 6 + 214PO L 3039.3 6 + 214PO L 3053.9 2 (1-),(1,2)+ -214PO B 216 110.030 5 6.6 +214PO B 216 110.030 5 6.6 214POS B EAV=59 3 -214PO G 2444.7 8 0.008 4 -214PO G 3053.88 200.022 3 +214PO G 2444.7 8 0.008 4 +214PO G 3053.88 200.022 3 214PO L 3068.3 8 + 214PO B 202 110.00141 23 7.8 214POS B EAV=55 3 214PO G 2459.0 8 0.00141 23 214PO L 3078.7 6 + 214PO L 3081.7 3 (1-),(1,2)+ -214PO B 188 110.0052 7 7.1 +214PO B 188 110.0052 7 7.1 214POS B EAV=51 3 -214PO G 3081.7 3 0.0052 7 +214PO G 3081.7 3 0.0052 7 214PO L 3094.0 4 (1-),(2)+ -214PO B 176 110.00037 4 8.2 +214PO B 176 110.00037 4 8.2 214POS B EAV=48 3 -214PO G 3093.98 400.00037 4 +214PO G 3093.98 400.00037 4 214PO L 3139.0 8 + 214PO L 3142.6 4 (1-),(1,2)+ -214PO B 127 110.00118 9 7.3 +214PO B 127 110.00118 9 7.3 214POS B EAV=34 3 -214PO G 3142.58 400.00118 9 +214PO G 3142.58 400.00118 9 214PO L 3149.2 5 (1-),(1,2)+ 214PO B 121 110.00019 8 214POS B EAV=32 3 -214PO G 3149.0 5 1900E-7 0 +214PO G 3149.0 5 0.00019 214PO L 3160.4 6 (1-),(1,2)+ 214PO B 110 110.00079 12 7.2 214POS B EAV=29 3 -214PO G 2550.7 7 0.00032 9 -214PO G 3160.6 6 0.00047 8 +214PO G 2550.7 7 0.00032 9 +214PO G 3160.6 6 0.00047 8 214PO L 3164.8 8 + 214PO L 3173.3 6 + -214PO B 97 110.00014 9 7.8 +214PO B 97 110.00014 9 7.8 214POS B EAV=26 3 -214PO G 2564.0 6 0.00014 9 +214PO G 2564.0 6 0.00014 9 214PO L 3183.6 4 (1-),(1,2)+ -214PO B 86 110.0011 5 6.8 +214PO B 86 110.0011 5 6.8 214POS B EAV=23 3 -214PO G 3183.57 400.0011 5 +214PO G 3183.57 400.0011 5 214PO L 3262.4 8 + diff --git a/HEN_HOUSE/spectra/lnhb/Bi-215.txt b/HEN_HOUSE/spectra/lnhb/Bi-215.txt index 4dd58e5d7..f63a7d1b6 100644 --- a/HEN_HOUSE/spectra/lnhb/Bi-215.txt +++ b/HEN_HOUSE/spectra/lnhb/Bi-215.txt @@ -5,93 +5,93 @@ 215PO2C 1977La19, 1989Bu09, 1990Ru02, 1991Ma16, 1996Sc06, 1998ScZM, 1999ScZX, 215PO3C 2001Br31, 2002Ra45, 2002Ba85, 2003Ku26, 2003Ak06, 2003Auo3, 2004Br45, 215PO4C 2007Ba19, 2008Ki07 -215PO T Auger electrons and ^X ray energies and emission intensities: -215PO T {U Energy (keV)} {U Intensity } {U Line } +215PO T Auger electrons and X ray energies and emission intensities: +215PO T {U Energy (keV)} {U Intensity} {U Line} 215PO T -215PO T 76.864 1.8 3 XKA2 -215PO T 79.293 3.0 5 XKA1 +215PO T 76.864 1.8 3 XKA2 +215PO T 79.293 3.0 5 XKA1 215PO T -215PO T 89.256 |] XKB3 -215PO T 89.807 |] 1.02 16 XKB1 -215PO T 90.363 |] XKB5II +215PO T 89.256 |] XKB3 +215PO T 89.807 |] 1.02 16 XKB1 +215PO T 90.363 |] XKB5II 215PO T -215PO T 92.263 |] XKB2 -215PO T 92.618 |] 0.32 5 XKB4 -215PO T 92.983 |] XKO23 +215PO T 92.263 |] XKB2 +215PO T 92.618 |] 0.32 5 XKB4 +215PO T 92.983 |] XKO23 215PO T -215PO T 9.658-16.213 2.7 3 XL (total) -215PO T 9.658 0.065 8 XLL -215PO T 11.016-11.13 1.20 13 XLA -215PO T 12.085 0.022 3 XLC -215PO T 12.823-13.778 1.18 11 XLB -215PO T 15.742-16.213 0.24 2 XLG +215PO T 9.658-16.213 2.7 3 XL (total) +215PO T 9.658 0.065 8 XLL +215PO T 11.016-11.13 1.20 13 XLA +215PO T 12.085 0.022 3 XLC +215PO T 12.823-13.778 1.18 11 XLB +215PO T 15.742-16.213 0.24 2 XLG 215PO T -215PO T 58.978-65.205 |] KLL AUGER -215PO T 71.902-79.289 |] 0.22 5 ^KLX AUGER -215PO T 84.8-93.1 |] KXY AUGER -215PO T 5.434-10.934 4.0 4 L AUGER +215PO T 58.978-65.205 |] KLL AUGER +215PO T 71.902-79.289 |] 0.22 5 KLX AUGER +215PO T 84.8-93.1 |] KXY AUGER +215PO T 5.434-10.934 4.0 4 L AUGER 215BI P 0.0 (9/2)- 7.6 M 2 2189 15 215PO N 1.0 1.0 1 1.0 215PO L 0 9/2+ 1.781 MS 4 -215PO B 2189 1561 6 6.28 +215PO B 2189 1561 6 6.28 215POS B EAV=808 6 215PO L 271.228 107/2+ -215PO G 271.228 101.95 7 M1+E2 4.0 4 0.201 7 -215PO2 G KC=0.111 6$LC=0.0668 11$MC=0.0173 3 +215PO G 271.228 101.95 7M1+E2 4.0 4 0.201 7 +215PO2 G KC=0.111 6$LC=0.0668 11$MC=0.0173 3 215PO L 293.56 4 (11/2)+ -215PO B 1895 1530 6 6.35 1U +215PO B 1895 1530 6 6.35 1 215POS B EAV=685 6 -215PO G 293.56 4 23.8 9 M1+E2 1.0 2 0.34 5 -215PO2 G KC=0.25 4$LC=0.062 4$MC=0.0152 7 +215PO G 293.56 4 23.8 9M1+E2 1.0 2 0.34 5 +215PO2 G KC=0.25 4$LC=0.062 4$MC=0.0152 7 215PO L 401.812 105/2+ -215PO B 1787 150.5 1 9 3U +215PO B 1787 150.5 1 9 1U 215POS B EAV=619 6 215PO G 130.58 1 0.0093 10M1+E2 0.60 6 4.44 13 -215PO2 G KC=3.19 16$LC=0.94 4$MC=0.234 10 -215PO G 401.81 1 0.48 7 E2 0.0555 8 -215PO2 G KC=0.0351 5$LC=0.01528 22$MC=0.00390 6 +215PO2 G KC=3.19 16$LC=0.94 4$MC=0.234 10 +215PO G 401.81 1 0.48 7E2 0.0555 8 +215PO2 G KC=0.0351 5$LC=0.01528 22$MC=0.00390 6 215PO L 517.60 6 7/2, 9/2+ -215PO B 1671 150.3 2 8.1 1U +215PO B 1671 150.3 2 8.1 1 215POS B EAV=593 6 -215PO G 224.04 7 0.033 5 E2 0.319 5 -215PO2 G KC=0.1296 19$LC=0.1407 20$MC=0.0370 6 -215PO G 517.60 6 1.02 8 M1+E2 1.0 2 0.073 10 -215PO2 G KC=0.058 9$LC=0.0115 11$MC=0.00277 24 +215PO G 224.04 7 0.033 5E2 0.319 5 +215PO2 G KC=0.1296 19$LC=0.1407 20$MC=0.0370 6 +215PO G 517.60 6 1.02 8M1+E2 1.0 2 0.073 10 +215PO2 G KC=0.058 9$LC=0.0115 11$MC=0.00277 24 215PO L 608.30 7 (11/2, 13/2)+ -215PO B 1581 150.7 1 7.7 1U +215PO B 1581 150.7 1 7.7 1 215POS B EAV=556 6 -215PO G 608.30 7 0.67 7 (M1+E2) +215PO G 608.30 7 0.67 7(M1+E2) 215PO L 676.66 7 + -215PO B 1512 150.5 1 7.8 +215PO B 1512 150.5 1 7.8 215POS B EAV=528 6 -215PO G 383.10 8 0.14 7 -215PO G 405.43 7 0.006 1 -215PO G 676.66 7 0.40 7 +215PO G 383.10 8 0.14 7 +215PO G 405.43 7 0.006 1 +215PO G 676.66 7 0.40 7 215PO L 835.32 22 + -215PO B 1354 151.5 1 7.1 +215PO B 1354 151.5 1 7.1 215POS B EAV=465 6 -215PO G 541.76 220.21 7 -215PO G 564.09 220.67 7 -215PO G 835.32 220.62 7 +215PO G 541.76 220.21 7 +215PO G 564.09 220.67 7 +215PO G 835.32 220.62 7 215PO L 1077.6 20 + -215PO B 1111 150.7 1 7.1 +215PO B 1111 150.7 1 7.1 215POS B EAV=370 6 -215PO G 784 2 0.33 7 -215PO G 806.4 200.40 7 +215PO G 784 2 0.33 7 +215PO G 806.4 200.40 7 215PO L 1176.2 20 + -215PO B 1013 150.2 1 7.5 +215PO B 1013 150.2 1 7.5 215POS B EAV=332 6 -215PO G 905 2 0.21 7 +215PO G 905 2 0.21 7 215PO L 1294.5 1 + -215PO B 895 152.0 2 6.34 +215PO B 895 152.0 2 6.34 215POS B EAV=287 6 215PO G 776.9 1 0.81 14 -215PO G 1023.3 1 0.62 7 -215PO G 1294.5 1 0.62 7 +215PO G 1023.3 1 0.62 7 +215PO G 1294.5 1 0.62 7 215PO L 1398.8 4 + -215PO B 790 152.8 1 6 +215PO B 790 152.8 1 6 215POS B EAV=249 6 -215PO G 1105.2 4 1.50 7 -215PO G 1127.6 4 0.48 7 -215PO G 1398.8 4 0.81 7 +215PO G 1105.2 4 1.50 7 +215PO G 1127.6 4 0.48 7 +215PO G 1398.8 4 0.81 7 diff --git a/HEN_HOUSE/spectra/lnhb/C-11.txt b/HEN_HOUSE/spectra/lnhb/C-11.txt index cb1cb11af..cfdc51a84 100644 --- a/HEN_HOUSE/spectra/lnhb/C-11.txt +++ b/HEN_HOUSE/spectra/lnhb/C-11.txt @@ -7,5 +7,5 @@ 11B N 1.0 1.0 1 1.0 11B L 0 3/2- STABLE 11B E 99.750 130.250 13 - 11B 2 E EAV=385.7 4$CK=0.9174 91$CL=0.0826 91$CM= $CN= $CO=0 0 + 11B 2 E EAV=385.7 4$CK=0.9174 91$CL=0.0826 91$CO=0 0 diff --git a/HEN_HOUSE/spectra/lnhb/Ca-41.txt b/HEN_HOUSE/spectra/lnhb/Ca-41.txt index e1b8b5137..214d42ac7 100644 --- a/HEN_HOUSE/spectra/lnhb/Ca-41.txt +++ b/HEN_HOUSE/spectra/lnhb/Ca-41.txt @@ -5,29 +5,29 @@ 41K 2C 1973MY03, 1973ZO03, 1974MA30, 1987HO16, 1988JA11, 1990FI13, 1991PA10, 41K 3C 1991KL06, 1992KA05, 1996SC06, 2001CA59, 2006MUZX, 2008MO18, 2011AUZZ, 41K 4C 2011BE53, 2012JO04 - 41K T Auger electrons and ^X ray energies and emission intensities: - 41K T {U Energy (keV)} {U Intensity } {U Line } + 41K T Auger electrons and X ray energies and emission intensities: + 41K T {U Energy (keV)} {U Intensity} {U Line} 41K T - 41K T 3.3111 3.82 12 XKA2 - 41K T 3.3138 7.56 23 XKA1 + 41K T 3.3111 3.82 12 XKA2 + 41K T 3.3138 7.56 23 XKA1 41K T - 41K T 3.5896 |] 1.40 5 XKB1 - 41K T 3.6028 |] XKB5II + 41K T 3.5896 |] 1.40 5 XKB1 + 41K T 3.6028 |] XKB5II 41K T 41K T - 41K T 0.2604-0.3618 0.27 6 XL (total) - 41K T 0.2604 0.27 6 XLL + 41K T 0.2604-0.3618 0.27 6 XL (total) + 41K T 0.2604 0.27 6 XLL 41K T 0.263 XLC 41K T 0.29654-0.3618 XLB 41K T 0.29917-0.29917 XLG 41K T - 41K T 2.615-2.985 |] KLL AUGER - 41K T 3.183-3.296 |] 76.6 9 ^KLX AUGER - 41K T 3.54-3.572 |] KXY AUGER - 41K T 0.226-0.342 156.76 11 L AUGER + 41K T 2.615-2.985 |] KLL AUGER + 41K T 3.183-3.296 |] 76.6 9 KLX AUGER + 41K T 3.54-3.572 |] KXY AUGER + 41K T 0.226-0.342 156.76 11 L AUGER 41CA P 0.0 7/2- 1.002E5 Y 17 421.63 14 41K N 1.0 1.0 1 1.0 41K L 0 3/2+ STABLE - 41K E 100 10.53 3U - 41K 2 E EAV= $CK=0.894 9$CL=0.0916 9$CM=0.01482 15$CN= $CO= + 41K E 100 10.53 1U + 41K 2 E CK=0.894 9$CL=0.0916 9$CM=0.01482 15 diff --git a/HEN_HOUSE/spectra/lnhb/Ca-45.txt b/HEN_HOUSE/spectra/lnhb/Ca-45.txt index dcfcf7f24..07c4097b2 100644 --- a/HEN_HOUSE/spectra/lnhb/Ca-45.txt +++ b/HEN_HOUSE/spectra/lnhb/Ca-45.txt @@ -9,11 +9,11 @@ 45CA P 0.0 7/2- 162.64 D 11 258.0 7 45SC N 1.0 1.0 1 1.0 45SC L 0 7/2- STABLE - 45SC B 258.0 7 99.9980 7 6 + 45SC B 258.0 7 99.9980 7 6 45SCS B EAV=76.8 7 45SC L 12.40 5 3/2+ 318 MS 7 - 45SC B 245.6 7 0.0020 7 10.3 3U + 45SC B 245.6 7 0.0020 7 10.3 1U 45SCS B EAV=91.7 7 - 45SC G 12.40 5 M2 423 9 - 45SC2 G KC=362 8$LC=53.4 12$MC=6.63 15 + 45SC G 12.40 5 M2 423 9 + 45SC2 G KC=362 8$LC=53.4 12$MC=6.63 15 diff --git a/HEN_HOUSE/spectra/lnhb/Cd-109.txt b/HEN_HOUSE/spectra/lnhb/Cd-109.txt index 4dd3b04b7..0776a2bff 100644 --- a/HEN_HOUSE/spectra/lnhb/Cd-109.txt +++ b/HEN_HOUSE/spectra/lnhb/Cd-109.txt @@ -14,36 +14,36 @@ 109AG9C 1989Eg**, 1989Ne**, 1992ScZZ, 1994Ra37, 1996Sc06, 1997Ma75, 2000He14, 109AG10C 2000Yo07, 2000Sc47, 2002Ba85, 2004Sc04, 2006Bl02, 2006Ko27, 2008Ki07, 109AG11C 2011va02, 2012Fi12, 2012Wa38, 2014Un01 -109AG T Auger electrons and ^X ray energies and emission intensities: -109AG T {U Energy (keV)} {U Intensity } {U Line } +109AG T Auger electrons and X ray energies and emission intensities: +109AG T {U Energy (keV)} {U Intensity} {U Line} 109AG T -109AG T 21.9906 29.21 30 XKA2 -109AG T 22.16317 55.1 5 XKA1 +109AG T 21.9906 29.21 30 XKA2 +109AG T 22.16317 55.1 5 XKA1 109AG T -109AG T 24.9118 |] XKB3 -109AG T 24.9427 |] 15.25 20 XKB1 -109AG T 25.146 |] XKB5II +109AG T 24.9118 |] XKB3 +109AG T 24.9427 |] 15.25 20 XKB1 +109AG T 25.146 |] XKB5II 109AG T -109AG T 25.4567 |] XKB2 -109AG T 25.512 |] 2.65 10 XKB4 +109AG T 25.4567 |] XKB2 +109AG T 25.512 |] 2.65 10 XKB4 109AG T -109AG T 2.634-3.748 10.37 27 XL (total) -109AG T 2.634 0.221 9 XLL -109AG T 2.977-2.985 5.93 21 XLA -109AG T 2.807 0.0849 20 XLC -109AG T 3.151-3.438 3.76 10 XLB -109AG T 3.431-3.748 0.366 8 XLG +109AG T 2.634-3.748 10.37 27 XL (total) +109AG T 2.634 0.221 9 XLL +109AG T 2.977-2.985 5.93 21 XLA +109AG T 2.807 0.0849 20 XLC +109AG T 3.151-3.438 3.76 10 XLB +109AG T 3.431-3.748 0.366 8 XLG 109AG T -109AG T 17.79-18.69 |] KLL AUGER -109AG T 20.945-22.16 |] 20.8 6 ^KLX AUGER -109AG T 24.079-25.507 |] KXY AUGER -109AG T 1.8-3.8 167.3 8 L AUGER +109AG T 17.79-18.69 |] KLL AUGER +109AG T 20.945-22.16 |] 20.8 6 KLX AUGER +109AG T 24.079-25.507 |] KXY AUGER +109AG T 1.8-3.8 167.3 8 L AUGER 109CD P 0.0 5/2+ 461.9 D 4 215.5 18 109AG N 1.0 1.0 1 1.0 109AG L 0 1/2- STABLE 109AG L 88.0341 7/2+ 39.7 S 2 -109AG E 100 6 2 -109AG2 E EAV= $CK=0.812 3$CL=0.150 3$CM=0.0321 9$CN=0.0064 4$CO= -109AG G 88.0336 103.66 5 E3 26.3 4 -109AG2 G KC=11.41 16$LC=12.06 17$MC=2.47 4 +109AG E 100 6 +109AG2 E CK=0.812 3$CL=0.150 3$CM=0.0321 9$CN=0.0064 4 +109AG G 88.0336 103.66 5E3 26.3 4 +109AG2 G KC=11.41 16$LC=12.06 17$MC=2.47 4 diff --git a/HEN_HOUSE/spectra/lnhb/Ce-139.txt b/HEN_HOUSE/spectra/lnhb/Ce-139.txt index 75d12f23a..380b91e4c 100644 --- a/HEN_HOUSE/spectra/lnhb/Ce-139.txt +++ b/HEN_HOUSE/spectra/lnhb/Ce-139.txt @@ -1,39 +1,38 @@ 139LA 139CE EC DECAY (137.641 D) 139LA C References: 1968Va08, 1968Ad08, 1975Mo12, 1975Da08, 1977Sc38, 1978SeZS, 139LA2C 1987BeYL, 1988KoZM, 1998Si17, 2001Sc08, 2003Au03, 2005KiZW -139LA T Auger electrons and ^X ray energies and emission intensities: -139LA T {U Energy (keV)} {U Intensity } {U Line } +139LA T Auger electrons and X ray energies and emission intensities: +139LA T {U Energy (keV)} {U Intensity} {U Line} 139LA T -139LA T 33.0344 22.80 24 XKA2 -139LA T 33.4421 41.9 4 XKA1 +139LA T 33.0344 22.80 24 XKA2 +139LA T 33.4421 41.9 4 XKA1 139LA T -139LA T 37.7206 |] XKB3 -139LA T 37.8015 |] 12.47 18 XKB1 -139LA T 38.084 |] XKB5II +139LA T 37.7206 |] XKB3 +139LA T 37.8015 |] 12.47 18 XKB1 +139LA T 38.084 |] XKB5II 139LA T -139LA T 38.7303 |] XKB2 -139LA T 38.828 |] 3.16 8 XKB4 -139LA T 38.91 |] XKO23 +139LA T 38.7303 |] XKB2 +139LA T 38.828 |] 3.16 8 XKB4 +139LA T 38.91 |] XKO23 139LA T -139LA T 4.117-6.072 12.19 18 XL (total) -139LA T 4.117 0.222 6 XLL -139LA T 4.634-4.65 5.70 13 XLA -139LA T 4.525 0.0842 21 XLC -139LA T 5.041-5.381 5.27 9 XLB -139LA T 5.62-6.072 0.903 16 XLG +139LA T 4.117-6.072 12.19 18 XL (total) +139LA T 4.117 0.222 6 XLL +139LA T 4.634-4.65 5.70 13 XLA +139LA T 4.525 0.0842 21 XLC +139LA T 5.041-5.381 5.27 9 XLB +139LA T 5.62-6.072 0.903 16 XLG 139LA T -139LA T 26.24-27.795 |] KLL AUGER -139LA T 31.231-33.428 |] 8.4 4 ^KLX AUGER -139LA T 36.2-38.9 |] KXY AUGER -139LA T 2.7-6.2 90.1 6 L AUGER +139LA T 26.24-27.795 |] KLL AUGER +139LA T 31.231-33.428 |] 8.4 4 KLX AUGER +139LA T 36.2-38.9 |] KXY AUGER +139LA T 2.7-6.2 90.1 6 L AUGER 139CE P 0.0 3/2+ 137.641 D 20 270 3 139LA N 1.0 1.0 1 1.0 139LA L 0 7/2+ STABLE -139LA E 0.008 10.6 -139LA2 E EAV= $CK= $CL= $CM= $CN= $CO= +139LA E 0.008 10.6 2 139LA L 165.8576 115/2+ 1.499 NS 19 -139LA E 99.9973 275.42 2 -139LA2 E EAV= $CK=0.716 7$CL=0.217 5$CM=0.0669 18$CN= $CO= -139LA G 165.8575 1179.90 4 M1 0.2516 7 -139LA2 G KC=0.2146 10$LC=0.0288 6$MC=0.0060 2 +139LA E 99.9973 275.42 +139LA2 E CK=0.716 7$CL=0.217 5$CM=0.0669 18 +139LA G 165.8575 1179.90 4M1 0.2516 7 +139LA2 G KC=0.2146 10$LC=0.0288 6$MC=0.0060 2 diff --git a/HEN_HOUSE/spectra/lnhb/Ce-141.txt b/HEN_HOUSE/spectra/lnhb/Ce-141.txt index d9520084c..a3ccbaacf 100644 --- a/HEN_HOUSE/spectra/lnhb/Ce-141.txt +++ b/HEN_HOUSE/spectra/lnhb/Ce-141.txt @@ -8,39 +8,39 @@ 141PR3C 1975Le09, 1976Va30, 1977La19, 1979Ha09, 1979Ha21, 1980Sc07, 1980RuZY, 141PR4C 1983Wa26, 1992Sc24, 1992Un01, 1996Sc06, 2000He14, 2000Sc47, 2001Tu01, 141PR5C 2002Ba85, 2002Un02, 2008Ki07, 2012Au06 -141PR T Auger electrons and ^X ray energies and emission intensities: -141PR T {U Energy (keV)} {U Intensity } {U Line } +141PR T Auger electrons and X ray energies and emission intensities: +141PR T {U Energy (keV)} {U Intensity} {U Line} 141PR T -141PR T 35.5506 4.80 9 XKA2 -141PR T 36.0267 8.76 15 XKA1 +141PR T 35.5506 4.80 9 XKA2 +141PR T 36.0267 8.76 15 XKA1 141PR T -141PR T 40.6533 |] XKB3 -141PR T 40.7487 |] 2.67 6 XKB1 -141PR T 41.05 |] XKB5II +141PR T 40.6533 |] XKB3 +141PR T 40.7487 |] 2.67 6 XKB1 +141PR T 41.05 |] XKB5II 141PR T -141PR T 41.774 |] XKB2 -141PR T 41.877 |] 0.682 20 XKB4 -141PR T 41.968 |] XKO23 +141PR T 41.774 |] XKB2 +141PR T 41.877 |] 0.682 20 XKB4 +141PR T 41.968 |] XKO23 141PR T -141PR T 4.458-6.617 2.52 5 XL (total) -141PR T 4.458 0.0485 15 XLL -141PR T 5.0129-5.0343 1.23 4 XLA -141PR T 4.9337 0.0187 6 XLC -141PR T 5.4887-5.9032 1.054 23 XLB -141PR T 6.1375-6.617 0.169 4 XLG +141PR T 4.458-6.617 2.52 5 XL (total) +141PR T 4.458 0.0485 15 XLL +141PR T 5.0129-5.0343 1.23 4 XLA +141PR T 4.9337 0.0187 6 XLC +141PR T 5.4887-5.9032 1.054 23 XLB +141PR T 6.1375-6.617 0.169 4 XLG 141PR T -141PR T 28.162-29.89 |] KLL AUGER -141PR T 33.576-36.004 |] 1.59 8 ^KLX AUGER -141PR T 38.97-41.95 |] KXY AUGER -141PR T 2.94-6.79 16.15 11 L AUGER +141PR T 28.162-29.89 |] KLL AUGER +141PR T 33.576-36.004 |] 1.59 8 KLX AUGER +141PR T 38.97-41.95 |] KXY AUGER +141PR T 2.94-6.79 16.15 11 L AUGER 141CE P 0.0 7/2- 32.503 D 11 580.4 11 141PR N 1.0 1.0 1 1.0 141PR L 0 0 5/2+ STABLE -141PR B 580.4 1130.03 44 7.76 1U +141PR B 580.4 1130.03 44 7.76 1 141PRS B EAV=180.8 6 141PR L 145.4434 147/2+ 141PR B 435.0 1169.97 44 6.97 141PRS B EAV=129.7 5 -141PR G 145.4433 1448.29 19M1+E2 0.068 5 0.449 7 -141PR2 G KC=0.383 6$LC=0.0529 8$MC=0.01116 16 +141PR G 145.4433 1448.29 19M1+E2 0.068 5 0.449 7 +141PR2 G KC=0.383 6$LC=0.0529 8$MC=0.01116 16 diff --git a/HEN_HOUSE/spectra/lnhb/Ce-144.txt b/HEN_HOUSE/spectra/lnhb/Ce-144.txt index 55276cb02..884c193d9 100644 --- a/HEN_HOUSE/spectra/lnhb/Ce-144.txt +++ b/HEN_HOUSE/spectra/lnhb/Ce-144.txt @@ -12,56 +12,56 @@ 144PR9C 1983El04, 1983Wa26, 1984Da13, 1986Ol01, 1992Un01, 1996Sc06, 1997Ma75, 144PR10C 1998ScZM, 1999ScZX, 2000Sc47, 2001So16, 2002Un02, 2002Ra45, 2002Ba85, 144PR11C 2008Ki07, 2012Wa38, 2012Fi12, 2014Un01 -144PR T Auger electrons and ^X ray energies and emission intensities: -144PR T {U Energy (keV)} {U Intensity } {U Line } +144PR T Auger electrons and X ray energies and emission intensities: +144PR T {U Energy (keV)} {U Intensity} {U Line} 144PR T -144PR T 35.5506 2.41 5 XKA2 -144PR T 36.0267 4.40 9 XKA1 +144PR T 35.5506 2.41 5 XKA2 +144PR T 36.0267 4.40 9 XKA1 144PR T -144PR T 40.6533 |] XKB3 -144PR T 40.7487 |] 1.34 3 XKB1 -144PR T 41.05 |] XKB5II +144PR T 40.6533 |] XKB3 +144PR T 40.7487 |] 1.34 3 XKB1 +144PR T 41.05 |] XKB5II 144PR T -144PR T 41.774 |] XKB2 -144PR T 41.877 |] 0.343 10 XKB4 -144PR T 41.968 |] XKO23 +144PR T 41.774 |] XKB2 +144PR T 41.877 |] 0.343 10 XKB4 +144PR T 41.968 |] XKO23 144PR T -144PR T 4.453-6.617 1.54 4 XL (total) -144PR T 4.453 0.0282 9 XLL -144PR T 5.013-5.033 0.711 21 XLA -144PR T 4.929 0.0107 4 XLC -144PR T 5.489-5.851 0.673 15 XLB -144PR T 6.327-6.617 0.116 3 XLG +144PR T 4.453-6.617 1.54 4 XL (total) +144PR T 4.453 0.0282 9 XLL +144PR T 5.013-5.033 0.711 21 XLA +144PR T 4.929 0.0107 4 XLC +144PR T 5.489-5.851 0.673 15 XLB +144PR T 6.327-6.617 0.116 3 XLG 144PR T -144PR T 28.162-29.89 |] KLL AUGER -144PR T 33.576-36.004 |] 0.80 4 ^KLX AUGER -144PR T 38.97-41.95 |] KXY AUGER -144PR T 2.9-4.91 9.88 10 L AUGER +144PR T 28.162-29.89 |] KLL AUGER +144PR T 33.576-36.004 |] 0.80 4 KLX AUGER +144PR T 38.97-41.95 |] KXY AUGER +144PR T 2.9-4.91 9.88 10 L AUGER 144CE P 0.0 0+ 284.89 D 6 318.6 8 144PR N 1.0 1.0 1.00 1 1.0 144PR L 0 0- 17.29 M 4 -144PR B 318.6 8 76.9 3 7.424 +144PR B 318.6 8 76.9 3 7.424 144PRS B EAV=91.3 3 144PR L 59.03 3 3- 7.2 M 2 144PR G 59.03 3 0.00094 19M3 1221 18 -144PR2 G KC=408 6$LC=618 9$MC=155.0 23 +144PR2 G KC=408 6$LC=618 9$MC=155.0 23 144PR L 80.120 4 1- 136 PS 11 -144PR B 238.5 8 3.9 2 8.33 1 +144PR B 238.5 8 3.9 2 8.33 1 144PRS B EAV=66.24 25 -144PR G 80.120 4 1.40 5 M1 2.45 4 -144PR2 G KC=2.08 3$LC=0.288 4$MC=0.0608 9 +144PR G 80.120 4 1.40 5M1 2.45 4 +144PR2 G KC=2.08 3$LC=0.288 4$MC=0.0608 9 144PR L 99.952 9 2- 0.67 NS 6 -144PR G 40.92 3 0.32 5 M1 2.61 4 -144PR2 G KC=$LC=2.06 3$MC=0.434 7 -144PR G 99.952 9 0.041 2 E2 2.12 3 -144PR2 G KC=1.214 17$LC=0.71 1$MC=0.1599 23 +144PR G 40.92 3 0.32 5M1 2.61 4 +144PR2 G LC=2.06 3$MC=0.434 7 +144PR G 99.952 9 0.041 2E2 2.12 3 +144PR2 G KC=1.214 17$LC=0.71 1$MC=0.1599 23 144PR L 133.5152 201- 7 PS 4 -144PR B 185.1 8 19.2 1 7.27 1 +144PR B 185.1 8 19.2 1 7.27 1 144PRS B EAV=50.29 24 -144PR G 33.563 9 0.225 11M1 4.69 7 -144PR2 G KC=$LC=3.70 6$MC=0.780 11 -144PR G 53.395 5 0.101 5 M1 7.94 12 -144PR2 G KC=6.75 10$LC=0.942 14$MC=0.199 3 -144PR G 133.5152 2010.83 12M1 0.571 8 -144PR2 G KC=0.486 7$LC=0.0668 10$MC=0.01408 20 +144PR G 33.563 9 0.225 11M1 4.69 7 +144PR2 G LC=3.70 6$MC=0.780 11 +144PR G 53.395 5 0.101 5M1 7.94 12 +144PR2 G KC=6.75 10$LC=0.942 14$MC=0.199 3 +144PR G 133.5152 2010.83 12M1 0.571 8 +144PR2 G KC=0.486 7$LC=0.0668 10$MC=0.01408 20 diff --git a/HEN_HOUSE/spectra/lnhb/Cf-252.txt b/HEN_HOUSE/spectra/lnhb/Cf-252.txt index 4ab913c23..2b46a30bb 100644 --- a/HEN_HOUSE/spectra/lnhb/Cf-252.txt +++ b/HEN_HOUSE/spectra/lnhb/Cf-252.txt @@ -6,46 +6,46 @@ 248CM3C 1976Mo30, 1982La25, 1983Al**, 1984Di08, 1984SmZV, 1985Wi14, 1985Ax**, 248CM4C 1986Ry04, 1987Sh**, 1988Ke**, 1990Po24, 1991Ry01, 1992Sh33, 1993Pa29, 248CM5C 1994KhZW, 1996Sc33, 1999Ak02, 1999Ba03, 2003Au03, 2005KiZW -248CM T Auger electrons and ^X ray energies and emission intensities: -248CM T {U Energy (keV)} {U Intensity } {U Line } +248CM T Auger electrons and X ray energies and emission intensities: +248CM T {U Energy (keV)} {U Intensity} {U Line} 248CM T -248CM T 104.59 0.0000257 7 XKA2 -248CM T 109.271 0.0000402 11 XKA1 +248CM T 104.59 2.57E-5 7 XKA2 +248CM T 109.271 4.02E-5 11 XKA1 248CM T -248CM T 122.304 |] XKB3 -248CM T 123.403 |] 0.0000151 5 XKB1 -248CM T 124.124 |] XKB5II +248CM T 122.304 |] XKB3 +248CM T 123.403 |] 1.51E-5 5 XKB1 +248CM T 124.124 |] XKB5II 248CM T -248CM T 126.889 |] XKB2 -248CM T 127.352 |] 0.00000530 19 XKB4 -248CM T 127.97 |] XKO23 +248CM T 126.889 |] XKB2 +248CM T 127.352 |] 5.30E-6 19 XKB4 +248CM T 127.97 |] XKO23 248CM T -248CM T 12.634-23.319 6.07 14 XL (total) -248CM T 12.634 0.146 5 XLL -248CM T 14.744-14.96 2.25 7 XLA -248CM T 17.315 0.0644 24 XLC -248CM T 17.288-20.515 2.90 9 XLB -248CM T 21.969-23.319 0.702 21 XLG +248CM T 12.634-23.319 6.07 14 XL (total) +248CM T 12.634 0.146 5 XLL +248CM T 14.744-14.96 2.25 7 XLA +248CM T 17.315 0.0644 24 XLC +248CM T 17.288-20.515 2.90 9 XLB +248CM T 21.969-23.319 0.702 21 XLG 248CM T -248CM T 78.858-89.973 |] KLL AUGER -248CM T 97.226-109.267 |] 0.0000025 4 ^KLX AUGER -248CM T 115.57-128.23 |] KXY AUGER -248CM T 6.3-24.5 5.02 13 L AUGER +248CM T 78.858-89.973 |] KLL AUGER +248CM T 97.226-109.267 |] 2.5E-6 4 KLX AUGER +248CM T 115.57-128.23 |] KXY AUGER +248CM T 6.3-24.5 5.02 13 L AUGER 252CF P 0.0 0+ 2.6470 Y 26 6216.87 4 248CM N 1.032E0 1.032E0 0.96914 1.032E0 248CM L 0 0+ 348E3 Y 6 248CM A 6118.1 1 84.30 311 248CM L 43.40 3 2+ 124 PS 5 248CM A 6075.64 1115.58 313.2 -248CM G 43.399 250.0152 4 E2 1000 15 -248CM2 G KC=$LC=724 11$MC=204 3 +248CM G 43.399 250.0152 4E2 1000 15 +248CM2 G LC=724 11$MC=204 3 248CM L 143.6 4 4+ 78 PS 22 248CM A 5976.6 0.237 4165 -248CM G 100.2 4 0.0119 20E2 18.5 5 -248CM2 G KC=$LC=13.4 4$MC=3.79 9 +248CM G 100.2 4 0.0119 20E2 18.5 5 +248CM2 G LC=13.4 4$MC=3.79 9 248CM L 298.1 5 6+ 33 PS 8 248CM A 5826.3 19605E-7 1200 -248CM G 154.5 6 5100E-7 0 E2 2.76 6 -248CM2 G KC=0.1741 25$LC=1.87 5$MC=0.526 12 +248CM G 154.5 6 0.00051 E2 2.76 6 +248CM2 G KC=0.1741 25$LC=1.87 5$MC=0.526 12 248CM L 505.0 5 8+ diff --git a/HEN_HOUSE/spectra/lnhb/Cl-36.txt b/HEN_HOUSE/spectra/lnhb/Cl-36.txt index 3a81f8468..908403cac 100644 --- a/HEN_HOUSE/spectra/lnhb/Cl-36.txt +++ b/HEN_HOUSE/spectra/lnhb/Cl-36.txt @@ -5,26 +5,26 @@ 36S 2C Type=Full;Author=V.P. Chechev;Cutoff date=30-APR-1998 36S C References: 1949Wu15, 1955Dr35, 1955Ba93, 1957Wr37, 1962Do07, 1962Be29, 36S 2C 1963Ba38, 1965To05, 1966Go07, 1967Pi04, 1976Lj03, 1977La19, 2012Mo** - 36S T Auger electrons and ^X ray energies and emission intensities: - 36S T {U Energy (keV)} {U Intensity } {U Line } + 36S T Auger electrons and X ray energies and emission intensities: + 36S T {U Energy (keV)} {U Intensity} {U Line} 36S T - 36S T 2.3066 0.044 3 XKA2 - 36S T 2.3078 0.086 5 XKA1 + 36S T 2.3066 0.044 3 XKA2 + 36S T 2.3078 0.086 5 XKA1 36S T - 36S T 2.457 |] XKB3 - 36S T |] 0.008 1 XKB1 + 36S T 2.457 |] XKB3 + 36S T |] 0.008 1 XKB1 36S T 36S T 36S T - 36S T 1.98-2.12 |] KLL AUGER - 36S T 2.22-2.3 |] 1.58 9 ^KLX AUGER - 36S T 2.44-2.46 |] KXY AUGER - 36S T - 0.163 12 L AUGER + 36S T 1.98-2.12 |] KLL AUGER + 36S T 2.22-2.3 |] 1.58 9 KLX AUGER + 36S T 2.44-2.46 |] KXY AUGER + 36S T - 0.163 12 L AUGER 36CL P 0.0 2+ 302E3 Y 4 1142.14 19 36S N 5.263E1 5.263E1 0.019 1 5.263E1 36S L 0 0+ STABLE - 36S E 0.00157 301.9 1 13.5 2 - 36S 2 E EAV=54 4$CK=0.904 5$CL=0.086 4$CM=0.010 1$CN= $CO= + 36S E 0.00157 301.9 113.5 2 + 36S 2 E EAV=54 4$CK=0.904 5$CL=0.086 4$CM=0.010 1 36AR 36CL B- DECAY (302E3 Y) 36AR H TYP=Update$AUT=M.M. Bé$CUT=15-JAN-2012$ @@ -33,23 +33,23 @@ 36AR2C Type=Full;Author=V.P. Chechev;Cutoff date=30-APR-1998 36AR C References: 1949Wu15, 1955Dr35, 1955Ba93, 1957Wr37, 1962Do07, 1962Be29, 36AR2C 1963Ba38, 1965To05, 1966Go07, 1967Pi04, 1976Lj03, 1977La19, 2012Mo** - 36AR T Auger electrons and ^X ray energies and emission intensities: - 36AR T {U Energy (keV)} {U Intensity } {U Line } + 36AR T Auger electrons and X ray energies and emission intensities: + 36AR T {U Energy (keV)} {U Intensity} {U Line} 36AR T - 36AR T 2.9553 0.0062 10 XKA2 - 36AR T 2.9577 0.0123 19 XKA1 + 36AR T 2.9553 0.0062 10 XKA2 + 36AR T 2.9577 0.0123 19 XKA1 36AR T - 36AR T 3.1905 |] XKB3 - 36AR T |] 0.0020 3 XKB1 + 36AR T 3.1905 |] XKB3 + 36AR T |] 0.0020 3 XKB1 36AR T 36AR T 36AR T - 36AR T 2.511-2.669 |] KLL AUGER - 36AR T 2.831-2.942 |] 0.13 2 ^KLX AUGER - 36AR T 3.149-3.174 |] KXY AUGER + 36AR T 2.511-2.669 |] KLL AUGER + 36AR T 2.831-2.942 |] 0.13 2 KLX AUGER + 36AR T 3.149-3.174 |] KXY AUGER 36CL P 0.0 2+ 302E3 Y 4 709.55 5 36AR N 1.019E0 1.019E0 0.981 1 1.019E0 36AR L 0 0+ STABLE - 36AR B 709.53 5 98.1 1 13.3 2 + 36AR B 709.53 5 98.1 1 13.3 2 36ARS B EAV=316 16 diff --git a/HEN_HOUSE/spectra/lnhb/Cm-242.txt b/HEN_HOUSE/spectra/lnhb/Cm-242.txt index 9c80f60bc..ecbce4068 100644 --- a/HEN_HOUSE/spectra/lnhb/Cm-242.txt +++ b/HEN_HOUSE/spectra/lnhb/Cm-242.txt @@ -10,114 +10,112 @@ 238PU5C 1981Le15, 1981Us03, 1982Ag02, 1982Ba56, 1982Ra33, 1982UmZZ, 1984Wi14, 238PU6C 1986LoZT, 1986Ze06, 1989Us04, 1990Po14, 1991Ry01, 1995Jo23, 1996Sc06, 238PU7C 1998Ya17, 2000Ho27, 2002Ch52, 2003Au03, 2006Ch34, 2008Ki07 -238PU T Auger electrons and ^X ray energies and emission intensities: -238PU T {U Energy (keV)} {U Intensity } {U Line } +238PU T Auger electrons and X ray energies and emission intensities: +238PU T {U Energy (keV)} {U Intensity} {U Line} 238PU T -238PU T 99.525 0.000082 9 XKA2 -238PU T 103.734 0.000130 15 XKA1 +238PU T 99.525 0.000082 9 XKA2 +238PU T 103.734 0.00013015 XKA1 238PU T -238PU T 116.244 |] XKB3 -238PU T 117.228 |] 0.000048 6 XKB1 -238PU T 117.918 |] XKB5II +238PU T 116.244 |] XKB3 +238PU T 117.228 |] 0.000048 6 XKB1 +238PU T 117.918 |] XKB5II 238PU T -238PU T 120.54 |] XKB2 -238PU T 120.969 |] 0.0000165 19 XKB4 -238PU T 121.543 |] XKO23 +238PU T 120.54 |] XKB2 +238PU T 120.969 |] 1.65E-5 19 XKB4 +238PU T 121.543 |] XKO23 238PU T -238PU T 12.12-23.07 9.92 23 XL (total) -238PU T 12.12 0.243 8 XLL -238PU T 14.087-14.282 3.79 11 XLA -238PU T 16.333 0.103 4 XLC -238PU T 16.5-19.33 4.69 14 XLB -238PU T 20.71-23.07 1.09 4 XLG +238PU T 12.12-23.07 9.92 23 XL (total) +238PU T 12.12 0.243 8 XLL +238PU T 14.087-14.282 3.79 11 XLA +238PU T 16.333 0.103 4 XLC +238PU T 16.5-19.33 4.69 14 XLB +238PU T 20.71-23.07 1.09 4 XLG 238PU T -238PU T 75.2-85.3 |] KLL AUGER -238PU T 92.6-103.6 |] 0.0000082 15 ^KLX AUGER -238PU T 109.8-121.5 |] KXY AUGER -238PU T 6.19-22.99 8.99 21 L AUGER +238PU T 75.2-85.3 |] KLL AUGER +238PU T 92.6-103.6 |] 8.2E-6 15 KLX AUGER +238PU T 109.8-121.5 |] KXY AUGER +238PU T 6.19-22.99 8.99 21 L AUGER 242CM P 0.0 0+ 162.86 D 8 6215.56 8 238PU N 1.0 1.0 1 1.0 238PU L 0 0+ 87.74 Y 3 238PU A 6112.72 8 74.06 7 1 238PU L 44.08 3 2+ 177 PS 5 238PU A 6069.37 9 25.94 7 1.733 -238PU G 44.08 3 0.0330 7 E2 787 16 -238PU2 G KC=$LC=572 12$MC=159.4 32 +238PU G 44.08 3 0.0330 7E2 787 16 +238PU2 G LC=572 12$MC=159.4 32 238PU L 146.00 5 4+ 238PU A 5969.24 9 0.034 2 390 238PU G 101.92 4 0.00251 14E2 14.45 21 -238PU2 G KC=$LC=10.48 21$MC=2.94 6 +238PU2 G LC=10.48 21$MC=2.94 6 238PU L 303.42 7 6+ 238PU A 5816.39 110.0046 5 458 -238PU G 157.42 9 0.00145 16[E2] 2.19 4 -238PU2 G KC=0.193 4$LC=1.450 29$MC=0.405 8 +238PU G 157.42 9 0.00145 16[E2] 2.19 4 +238PU2 G KC=0.193 4$LC=1.450 29$MC=0.405 8 238PU L 513.62 168+ 238PU A 5607.76 160.00002 7500 -238PU G 210.20 141200E-8 0 E2 0.710 14 -238PU2 G KC=0.140 3$LC=0.415 8$MC=0.115 2 +238PU G 210.20 140.000012 E2 0.710 14 +238PU2 G KC=0.140 3$LC=0.415 8$MC=0.115 2 238PU L 605.08 7 1- 238PU A 5517.75 110.00025 5 183 -238PU G 561.02 100.00015 4 E1 0.0115323 -238PU2 G KC=0.00929 18$LC=0.00169 3$MC=4.07E-4 8 -238PU G 605.04 101.05E-4 30E1 0.0099920 -238PU2 G KC=0.00806 16$LC=0.00146 3$MC=3.50E-4 7 +238PU G 561.02 100.00015 4E1 0.0115323 +238PU2 G KC=0.00929 18$LC=0.00169 3$MC=4.07E-4 8 +238PU G 605.04 100.00010530E1 0.0099920 +238PU2 G KC=0.00806 16$LC=0.00146 3$MC=3.50E-4 7 238PU L 661.28 113- 238PU A 5462.47 1413000E-93 1700 -238PU G 515.25 194.5E-6 12E1+M2 0.114 17 0.022 3 -238PU2 G KC=0.0175 21$LC=0.0037 6$MC=0.00092 14 +238PU G 515.25 194.5E-6 12E1+M2 0.114 17 0.022 3 +238PU2 G KC=0.0175 21$LC=0.0037 6$MC=0.00092 14 238PU G 617.20 127.9E-6 21E1+M2 0.077 17 0.0120 12 -238PU2 G KC=0.0095 9$LC=0.00185 22$MC=0.00045 6 +238PU2 G KC=0.0095 9$LC=0.00185 22$MC=0.00045 6 238PU L 763.22 5- 238PU A 5366.22 1522000E-1 24000 -238PU G 459.8 2 6E-8 3 -238PU G 617.22 13160E-9 0 +238PU G 459.8 2 6E-8 3 +238PU G 617.22 131.6E-7 238PU L 941.44 9 0+ 238PU A 5186.95 1235000E-97 12 -238PU G 336.36 157E-7 3 [E1] 0.0323 6 -238PU2 G KC=0.0257 5$LC=0.00502 10$MC=0.00122 2 -238PU G 897.33 102.2E-5 6 (E2) 0.0152 3 -238PU2 G KC=0.01108 22$LC=0.00308 6$MC=7.78E-4 15 +238PU G 336.36 157E-7 3[E1] 0.0323 6 +238PU2 G KC=0.0257 5$LC=0.00502 10$MC=0.00122 2 +238PU G 897.33 100.000022 6(E2) 0.0152 3 +238PU2 G KC=0.01108 22$LC=0.00308 6$MC=7.78E-4 15 238PU G 941.5 2 238PU L 962.72 8 1- 238PU A 5165.95 1611300E-121278 -238PU G 357.64 7 4.5E-8 9 M1+E2 2.43 20 0.214 15 -238PU2 G KC=0.133 12$LC=0.0599 17$MC=0.0158 4 -238PU G 918.7 2 5.4E-7 15E1 0.004699 -238PU2 G KC=0.00382 8$LC=6.63E-4 13$MC=1.58E-4 3 -238PU G 962.8 2 5.3E-7 15E1 0.004328 -238PU2 G KC=0.00352 7$LC=6.09E-4 12$MC=1452E-7 29 +238PU G 357.64 7 4.5E-8 9M1+E2 2.43 20 0.214 15 +238PU2 G KC=0.133 12$LC=0.0599 17$MC=0.0158 4 +238PU G 918.7 2 5.4E-7 15E1 0.00469 9 +238PU2 G KC=0.00382 8$LC=6.63E-4 13$MC=1.58E-4 3 +238PU G 962.8 2 5.3E-7 15E1 0.00432 8 +238PU2 G KC=0.00352 7$LC=6.09E-4 12$MC=1452E-7 29 238PU L 983.00 9 2+ 238PU A 5146.07 1217000E-15 137 -238PU G 837.01 151.9E-7 6 [E2] 0.0174 3 -238PU2 G KC=0.01250 25$LC=0.00366 7$MC=9.30E-4 19 -238PU G 938.91 101.8E-7 6 +E2 4.4 4 -238PU2 G KC=$LC=$MC= +238PU G 837.01 151.9E-7 6[E2] 0.0174 3 +238PU2 G KC=0.01250 25$LC=0.00366 7$MC=9.30E-4 19 +238PU G 938.91 101.8E-7 6+E2 4.4 4 238PU G 983.0 3 5.0E-7 18[E2] 0.0127625 -238PU2 G KC=0.00946 18$LC=0.00246 5$MC=6.19E-4 12 +238PU2 G KC=0.00946 18$LC=0.00246 5$MC=6.19E-4 12 238PU L 1018.6 3 1- 238PU A 5111.1 3 20000E-1 700 -238PU G 974.5 3 200E-9 0 +238PU G 974.5 3 2E-7 238PU L 1028.62 5 2+ 238PU A 5101.21 1037000E-11032 -238PU G 882.63 3 6.7E-8 15(E2) 0.0157 3 -238PU2 G KC=0.01141 23$LC=0.00321 6$MC=8.11E-4 16 -238PU G 984.5 1 2.0E-6 6 M1+E2 23 0.0127926 -238PU2 G KC=0.00949 19$LC=0.00247 5$MC=6.19E-4 12 -238PU G 1028.5 2 1.6E-6 5 E2 0.0117123 -238PU2 G KC=0.00875 17$LC=0.00221 4$MC=5.54E-4 11 +238PU G 882.63 3 6.7E-8 15(E2) 0.0157 3 +238PU2 G KC=0.01141 23$LC=0.00321 6$MC=8.11E-4 16 +238PU G 984.5 1 2.0E-6 6M1+E2 23 0.0127926 +238PU2 G KC=0.00949 19$LC=0.00247 5$MC=6.19E-4 12 +238PU G 1028.5 2 1.6E-6 5E2 0.0117123 +238PU2 G KC=0.00875 17$LC=0.00221 4$MC=5.54E-4 11 238PU L 1125.79 17(4)+ 238PU A 5005.64 1931000E-11088 -238PU G 979.8 2 2.6E-7 8 -238PU G 1081.7 3 5E-8 2 +238PU G 979.8 2 2.6E-7 8 +238PU G 1081.7 3 5E-8 2 238PU L 1228.69 220+ 238PU A 4904.44 2355000E-11510 238PU G 1184.6 3 5.0E-7 15E2 0.0089918 -238PU2 G KC=0.00685 14$LC=0.00160 3$MC=3.97E-4 8 +238PU2 G KC=0.00685 14$LC=0.00160 3$MC=3.97E-4 8 238PU G 1228.7 3 238PU L 1264.29 222+ 238PU A 4869.43 2352000E-1146 -238PU G 1118.3 3 1.7E-7 9 [E2] 0.0100120 -238PU2 G KC=0.00757 15$LC=0.00182 3$MC=4.54E-4 9 -238PU G 1220.2 3 2.8E-7 9 +E2+(M1) 0.26 3 -238PU2 G KC=$LC=$MC= +238PU G 1118.3 3 1.7E-7 9[E2] 0.0100120 +238PU2 G KC=0.00757 15$LC=0.00182 3$MC=4.54E-4 9 +238PU G 1220.2 3 2.8E-7 9+E2+(M1) 0.26 3 diff --git a/HEN_HOUSE/spectra/lnhb/Cm-243.txt b/HEN_HOUSE/spectra/lnhb/Cm-243.txt index e4589f6fc..41329ec3c 100644 --- a/HEN_HOUSE/spectra/lnhb/Cm-243.txt +++ b/HEN_HOUSE/spectra/lnhb/Cm-243.txt @@ -7,24 +7,24 @@ 243AM4C 1972Kr07, 1973Ah04, 1976BaZZ, 1977VaZW, 1979Bo30, 1982Ah04, 1986Ti03, 243AM5C 1987Po19, 1990Si12, 1991Ry01, 2003Au03, 2003Br12, 2004Ak21, 2005Tr08, 243AM6C 2008BeZV, 2008Ki07, 2009KoZV -243AM T Auger electrons and ^X ray energies and emission intensities: -243AM T {U Energy (keV)} {U Intensity } {U Line } +243AM T Auger electrons and X ray energies and emission intensities: +243AM T {U Energy (keV)} {U Intensity} {U Line} 243AM T 243AM T 102.03 XKA2 243AM T 106.472 XKA1 243AM T -243AM T 119.243 |] XKB3 -243AM T 120.284 |] XKB1 -243AM T 120.989 |] XKB5II +243AM T 119.243 |] XKB3 +243AM T 120.284 |] XKB1 +243AM T 120.989 |] XKB5II 243AM T -243AM T 123.58 |] XKB2 -243AM T 124.127 |] XKB4 -243AM T 124.723 |] XKO23 +243AM T 123.58 |] XKB2 +243AM T 124.127 |] XKB4 +243AM T 124.723 |] XKO23 243AM T 243AM T -243AM T 77.04-85.638 |] KLL AUGER -243AM T 94.891-106.467 |] ^KLX AUGER -243AM T 112.72-124.97 |] KXY AUGER +243AM T 77.04-85.638 |] KLL AUGER +243AM T 94.891-106.467 |] KLX AUGER +243AM T 112.72-124.97 |] KXY AUGER 243AM T 6.26-23.7 L AUGER 243CM P 0.0 5/2+ 28.9 Y 4 7.5 17 243AM N 3.448E2 3.448E2 0.0029 3 3.448E2 @@ -34,8 +34,8 @@ 243AM G 740 243AM G 760 243AM L 0 5/2- 7367 Y 23 -243AM E 0.29 3 7.2 -243AM2 E EAV= $CK= $CL= $CM=0.12 12$CN=0.64 15$CO= +243AM E 0.29 37.2 +243AM2 E CM=0.12 12$CN=0.64 15 239PU 243CM A DECAY (28.9 Y) 239PU H TYP=Full$AUT=V.P. Chechev$CUT=30-OCT-2010$ @@ -46,31 +46,31 @@ 239PU4C 1972Kr07, 1973Ah04, 1976BaZZ, 1977VaZW, 1979Bo30, 1982Ah04, 1986Ti03, 239PU5C 1987Po19, 1990Si12, 1991Ry01, 2003Au03, 2003Br12, 2004Ak21, 2005Tr08, 239PU6C 2008BeZV, 2008Ki07, 2009KoZV -239PU T Auger electrons and ^X ray energies and emission intensities: -239PU T {U Energy (keV)} {U Intensity } {U Line } +239PU T Auger electrons and X ray energies and emission intensities: +239PU T {U Energy (keV)} {U Intensity} {U Line} 239PU T -239PU T 99.525 13.34 28 XKA2 -239PU T 103.734 21.1 5 XKA1 +239PU T 99.525 13.34 28 XKA2 +239PU T 103.734 21.1 5 XKA1 239PU T -239PU T 116.244 |] XKB3 -239PU T 117.228 |] 7.75 21 XKB1 -239PU T 117.918 |] XKB5II +239PU T 116.244 |] XKB3 +239PU T 117.228 |] 7.75 21 XKB1 +239PU T 117.918 |] XKB5II 239PU T -239PU T 120.54 |] XKB2 -239PU T 120.969 |] 2.69 8 XKB4 -239PU T 121.543 |] XKO23 +239PU T 120.54 |] XKB2 +239PU T 120.969 |] 2.69 8 XKB4 +239PU T 121.543 |] XKO23 239PU T -239PU T 12.1246-21.9844 52.1 16 XL (total) -239PU T 12.1246 1.40 6 XLL -239PU T 14.0834-14.2791 21.8 8 XLA -239PU T 16.334 0.418 26 XLC -239PU T 16.4987-18.5427 23.2 9 XLB -239PU T 20.7081-21.9844 5.30 22 XLG +239PU T 12.1246-21.9844 52.1 16 XL (total) +239PU T 12.1246 1.40 6 XLL +239PU T 14.0834-14.2791 21.8 8 XLA +239PU T 16.334 0.418 26 XLC +239PU T 16.4987-18.5427 23.2 9 XLB +239PU T 20.7081-21.9844 5.30 22 XLG 239PU T -239PU T 75.263-85.357 |] KLL AUGER -239PU T 92.607-103.729 |] 1.34 19 ^KLX AUGER -239PU T 109.93-121.78 |] KXY AUGER -239PU T 6.19-22.99 49.3 15 L AUGER +239PU T 75.263-85.357 |] KLL AUGER +239PU T 92.607-103.729 |] 1.34 19 KLX AUGER +239PU T 109.93-121.78 |] KXY AUGER +239PU T 6.19-22.99 49.3 15 L AUGER 243CM P 0.0 5/2+ 28.9 Y 4 6168.8 10 239PU N 1.003E0 1.003E0 0.9971 3 1.003E0 239PU G 640 @@ -82,71 +82,71 @@ 239PU A 6067.2 101.3 2 2210 239PU L 7.861 2 3/2+ 36 PS 3 239PU A 6059.4 104.41 20593 -239PU G 7.861 2 1500E-5 0 M1+E2 0.055 3 5.7E3 4 -239PU2 G KC=$LC=$MC=4.2E3 3 +239PU G 7.861 2 0.015 M1+E2 0.055 3 5.7E3 4 +239PU2 G MC=4.2E3 3 239PU L 57.275 2 5/2+ 101 PS 5 239PU A 6010.8 101.05 121410 -239PU G 49.414 2 0.20000 0 M1+E2 0.50 3 126 8 -239PU2 G KC=$LC=92 6$MC=24.8 17 -239PU G 57.273 4 6000E-5 0 E2 222 4 -239PU2 G KC=$LC=161.1 23$MC=45.0 7 +239PU G 49.414 2 0.2 M1+E2 0.50 3 126 8 +239PU2 G LC=92 6$MC=24.8 17 +239PU G 57.273 4 0.06 E2 222 4 +239PU2 G LC=161.1 23$MC=45.0 7 239PU L 75.705 3 7/2+ 83 PS 8 239PU A 5992.7 105.72 20209 -239PU G 18.430 4 1000E-7 0 (M1+E2) 8E3 6 -239PU2 G KC=$LC=$MC=6E3 6 -239PU G 67.841 7 0.20 5 E2 98.5 14 -239PU2 G KC=$LC=71.5 10$MC=20.0 3 +239PU G 18.430 4 0.0001 (M1+E2) 8E3 6 +239PU2 G MC=6E3 6 +239PU G 67.841 7 0.20 5E2 98.5 14 +239PU2 G LC=71.5 10$MC=20.0 3 239PU L 163.76 3 9/2+ 73 PS 4 239PU A 5906.1 1010029E-5 4230 -239PU G 88.06 3 1800E-6 0 M1+E2 0.5 12.26 18 -239PU2 G KC=$LC=9.07 13$MC=2.36 4 -239PU G 106.47 4 1500E-5 0 E2 11.80 17 -239PU2 G KC=$LC=8.56 12$MC=2.40 4 +239PU G 88.06 3 0.0018 M1+E2 0.5 12.26 18 +239PU2 G LC=9.07 13$MC=2.36 4 +239PU G 106.47 4 0.015 E2 11.80 17 +239PU2 G LC=8.56 12$MC=2.40 4 239PU L 192.8 1011/2+ 239PU A 5877.6 1470204E-5 427 -239PU G 117.1 108000E-5 0 [E2] 7.6 4 -239PU2 G KC=$LC=5.52 24$MC=1.54 7 +239PU G 117.1 100.08 [E2] 7.6 4 +239PU2 G LC=5.52 24$MC=1.54 7 239PU L 285.460 2 5/2+ 1.12 NS 5 239PU A 5786.4 1073.61 401.32 -239PU G 209.753 2 3.29 10M1+E2 -0.019 15 3.24 5 -239PU2 G KC=2.56 4$LC=0.511 8$MC=0.1241 18 -239PU G 228.183 2 10.6 3 M1+E2 0.009 6 2.56 4 -239PU2 G KC=2.02 3$LC=0.403 6$MC=0.0979 14 -239PU G 277.599 2 14.0 4 M1+E2 0.165 2 1.448 21 -239PU2 G KC=1.142 16$LC=0.230 4$MC=0.0560 8 -239PU G 285.460 2 0.73 2 E2 0.247 4 -239PU2 G KC=0.0843 12$LC=0.1190 17$MC=0.0326 5 +239PU G 209.753 2 3.29 10M1+E2 -0.019 15 3.24 5 +239PU2 G KC=2.56 4$LC=0.511 8$MC=0.1241 18 +239PU G 228.183 2 10.6 3M1+E2 0.009 6 2.56 4 +239PU2 G KC=2.02 3$LC=0.403 6$MC=0.0979 14 +239PU G 277.599 2 14.0 4M1+E2 0.165 2 1.448 21 +239PU2 G KC=1.142 16$LC=0.230 4$MC=0.0560 8 +239PU G 285.460 2 0.73 2E2 0.247 4 +239PU2 G KC=0.0843 12$LC=0.1190 17$MC=0.0326 5 239PU L 330.124 4 7/2+ 239PU A 5742.5 1011.33 204.94 239PU G 44.663 5 0.131 16M1+E2 0.24 4 96 13 -239PU2 G KC=$LC=72 9$MC=18 3 -239PU G 166.39 6 0.016 7 M1 6.22 9 -239PU2 G KC=4.91 7$LC=0.984 14$MC=0.239 4 -239PU G 254.40 3 0.11 1 M1+E2 -0.159 6 1.85 3 -239PU2 G KC=1.457 21$LC=0.294 5$MC=0.0716 10 -239PU G 272.87 9 0.08 1 M1+E2 0.165 9 1.518 22 -239PU2 G KC=1.198 18$LC=0.241 4$MC=0.0588 9 -239PU G 322.3 2 0.007 1 [E2] 0.1699 24 -239PU2 G KC=0.0679 10$LC=0.0745 11$MC=0.0203 3 +239PU2 G LC=72 9$MC=18 3 +239PU G 166.39 6 0.016 7M1 6.22 9 +239PU2 G KC=4.91 7$LC=0.984 14$MC=0.239 4 +239PU G 254.40 3 0.11 1M1+E2 -0.159 6 1.85 3 +239PU2 G KC=1.457 21$LC=0.294 5$MC=0.0716 10 +239PU G 272.87 9 0.08 1M1+E2 0.165 9 1.518 22 +239PU2 G KC=1.198 18$LC=0.241 4$MC=0.0588 9 +239PU G 322.3 2 0.007 1[E2] 0.1699 24 +239PU2 G KC=0.0679 10$LC=0.0745 11$MC=0.0203 3 239PU L 387.42 2 9/2+ 239PU A 5686.1 101.6 1 17 -239PU G 57.30 2 8000E-5 0 [M1] 28.6 4 -239PU2 G KC=$LC=21.5 3$MC=5.24 8 -239PU G 101.96 2 8000E-6 0 E2 14.42 21 -239PU2 G KC=$LC=10.46 15$MC=2.93 5 -239PU G 311.7 2 0.017 2 M1+E2 0.1 1 1.06 3 -239PU2 G KC=0.84 3$LC=0.168 4$MC=0.0408 8 +239PU G 57.30 2 0.08 [M1] 28.6 4 +239PU2 G LC=21.5 3$MC=5.24 8 +239PU G 101.96 2 0.008 E2 14.42 21 +239PU2 G LC=10.46 15$MC=2.93 5 +239PU G 311.7 2 0.017 2M1+E2 0.1 1 1.06 3 +239PU2 G KC=0.84 3$LC=0.168 4$MC=0.0408 8 239PU L 391.584 3 7/2- 193 NS 4 239PU A 5682 1 20058E-5 129 239PU G 4.16 2 E1 -239PU G 61.460 2 0.0151 13E1 0.473 7 -239PU2 G KC=$LC=0.354 5$MC=0.0881 13 -239PU G 106.125 2 0.296 25E1(+M2) -0.007 7 0.26 4 -239PU2 G KC=$LC=0.19 3$MC=0.050 8 -239PU G 315.880 3 0.018 2 E1(+M2) 0.008 8 0.0372 9 -239PU2 G KC=0.0294 6$LC=0.00583 16$MC=0.00141 4 -239PU G 334.310 3 0.024 2 E1(+M2) 0.006 6 0.0329 6 -239PU2 G KC=0.0261 5$LC=0.00511 10$MC=1238E-6 24 +239PU G 61.460 2 0.0151 13E1 0.473 7 +239PU2 G LC=0.354 5$MC=0.0881 13 +239PU G 106.125 2 0.296 25E1(+M2) -0.007 7 0.26 4 +239PU2 G LC=0.19 3$MC=0.050 8 +239PU G 315.880 3 0.018 2E1(+M2) 0.008 8 0.0372 9 +239PU2 G KC=0.0294 6$LC=0.00583 16$MC=0.00141 4 +239PU G 334.310 3 0.024 2E1(+M2) 0.006 6 0.0329 6 +239PU2 G KC=0.0261 5$LC=0.00511 10$MC=1238E-6 24 239PU L 427 3 + 239PU A 5647 3 30087E-6 549 239PU L 434 3 9/2- diff --git a/HEN_HOUSE/spectra/lnhb/Cm-244.txt b/HEN_HOUSE/spectra/lnhb/Cm-244.txt index 2312fc429..c307f0472 100644 --- a/HEN_HOUSE/spectra/lnhb/Cm-244.txt +++ b/HEN_HOUSE/spectra/lnhb/Cm-244.txt @@ -18,85 +18,85 @@ 240PU5C 1981Hs02, 1982Ba56, 1982Po14, 1984BuZJ, 1990Pe03, 1990Po14, 1991ry01, 240PU6C 1992Fr04, 1993Pa29, 1995Jo23, 1996Bu50, 1996Sc09, 1996Sa24, 1997Ka59, 240PU7C 1998Ga19, 1998Ya17, 2002Da21, 2003Au03, 2004Ch64, 2006Ch34, 2008Ki07 -240PU T Auger electrons and ^X ray energies and emission intensities: -240PU T {U Energy (keV)} {U Intensity } {U Line } +240PU T Auger electrons and X ray energies and emission intensities: +240PU T {U Energy (keV)} {U Intensity} {U Line} 240PU T -240PU T 99.525 0.000061 4 XKA2 -240PU T 103.734 0.000097 5 XKA1 +240PU T 99.525 0.000061 4 XKA2 +240PU T 103.734 0.000097 5 XKA1 240PU T -240PU T 116.244 |] XKB3 -240PU T 117.228 |] 0.0000354 20 XKB1 -240PU T 117.918 |] XKB5II +240PU T 116.244 |] XKB3 +240PU T 117.228 |] 3.54E-5 20 XKB1 +240PU T 117.918 |] XKB5II 240PU T -240PU T 120.54 |] XKB2 -240PU T 120.969 |] 0.0000123 7 XKB4 -240PU T 121.543 |] XKO23 +240PU T 120.54 |] XKB2 +240PU T 120.969 |] 1.23E-5 7 XKB4 +240PU T 121.543 |] XKO23 240PU T -240PU T 12.125-21.984 8.92 23 XL (total) -240PU T 12.125 0.219 8 XLL -240PU T 14.083-14.279 3.42 11 XLA -240PU T 16.334 0.092 4 XLC -240PU T 16.499-19.331 4.21 14 XLB -240PU T 20.708-21.984 0.970 4 XLG +240PU T 12.125-21.984 8.92 23 XL (total) +240PU T 12.125 0.219 8 XLL +240PU T 14.083-14.279 3.42 11 XLA +240PU T 16.334 0.092 4 XLC +240PU T 16.499-19.331 4.21 14 XLB +240PU T 20.708-21.984 0.970 4 XLG 240PU T -240PU T 75.263-85.357 |] KLL AUGER -240PU T 92.607-103.729 |] 0.0000061 9 ^KLX AUGER -240PU T 109.93-121.78 |] KXY AUGER -240PU T 6.19-22.99 8.09 20 L AUGER +240PU T 75.263-85.357 |] KLL AUGER +240PU T 92.607-103.729 |] 6.1E-6 9 KLX AUGER +240PU T 109.93-121.78 |] KXY AUGER +240PU T 6.19-22.99 8.09 20 L AUGER 244CM P 0.0 0+ 18.11 Y 3 5901.74 5 240PU N 1.0 1.0 1 1.0 240PU L 0 0+ 6561 Y 7 240PU A 5804.77 5 76.7 4 1 240PU L 42.824 8 2+ 164 PS 5 240PU A 5762.65 5 23.3 4 1.94 -240PU G 42.824 8 0.0258 7 E2 905 18 -240PU2 G KC=$LC=658 13$MC=183 4 +240PU G 42.824 8 0.0258 7E2 905 18 +240PU2 G LC=658 13$MC=183 4 240PU L 141.690 154+ 240PU A 5665.41 5 0.0204 15636 -240PU G 98.860 130.00136 9 E2 16.6 3 -240PU2 G KC=$LC=12.08 24$MC=3.38 7 +240PU G 98.860 130.00136 9E2 16.6 3 +240PU2 G LC=12.08 24$MC=3.38 7 240PU L 294.319 246+ 240PU A 5515.29 6 0.00352 18512 -240PU G 152.63 2 0.00102 5 (E2) 2.48 5 -240PU2 G KC=0.196 4$LC=1.66 3$MC=0.465 9 +240PU G 152.63 2 0.00102 5(E2) 2.48 5 +240PU2 G KC=0.196 4$LC=1.66 3$MC=0.465 9 240PU L 497.6 8+ 240PU A 5315.3 0.00004 -240PU G 202.4 2200E-8 0 (E2) 0.817 16 -240PU2 G KC=0.148 3$LC=0.487 10$MC=0.135 3 +240PU G 202.4 0.000022 (E2) 0.817 16 +240PU2 G KC=0.148 3$LC=0.487 10$MC=0.135 3 240PU L 597.34 4 1- 240PU A 5217.24 7 55000E-99 500 -240PU G 554.52 4 8.7E-5 11(E1) 0.0117924 -240PU2 G KC=0.00949 19$LC=0.00174 4$MC=4.17E-4 9 -240PU G 597.34 4 5.3E-5 7 (E1) 0.0102421 -240PU2 G KC=0.00826 17$LC=0.00150 3$MC=3.59E-4 7 +240PU G 554.52 4 0.00008711(E1) 0.0117924 +240PU2 G KC=0.00949 19$LC=0.00174 4$MC=4.17E-4 9 +240PU G 597.34 4 0.000053 7(E1) 0.0102421 +240PU2 G KC=0.00826 17$LC=0.00150 3$MC=3.59E-4 7 240PU L 648.85 4 3- 240PU A 5166.58 7 42000E-1303100 240PU G 507.16 5 8.7E-6 28(E1) 0.0140129 -240PU2 G KC=0.01126 23$LC=0.00208 4$MC=0.00050 1 +240PU2 G KC=0.01126 23$LC=0.00208 4$MC=0.00050 1 240PU G 606.03 4 8.1E-6 14 240PU L 860.71 7 0+ 240PU A 4958.20 9 14900E-8163.5 -240PU G 263.37 8 6.2E-5 9 (E1) 0.0547 11 -240PU2 G KC=0.0433 9$LC=0.00881 18$MC=0.00214 4 -240PU G 817.89 7 6.8E-5 9 (E2) 0.0182 4 -240PU2 G KC=0.0130 3$LC=0.00389 8$MC=9.89E-4 20 +240PU G 263.37 8 0.000062 9(E1) 0.0547 11 +240PU2 G KC=0.0433 9$LC=0.00881 18$MC=0.00214 4 +240PU G 817.89 7 0.000068 9(E2) 0.0182 4 +240PU2 G KC=0.0130 3$LC=0.00389 8$MC=9.89E-4 20 240PU G 860.71 7 8.2E-6 20() 240PU L 900.32 4 2+ 240PU A 4919.24 7 50000E-95 5.6 240PU G 251.47 6 1.14E-5 23(E1) 0.0606 12 -240PU2 G KC=0.048 1$LC=0.00983 20$MC=0.00239 5 -240PU G 302.98 6 1.9E-5 3 (E1) 0.0405 8 -240PU2 G KC=0.0320 7$LC=0.00637 13$MC=0.00154 3 -240PU G 758.63 5 1.38E-5 19(E2) 0.0212 4 -240PU2 G KC=0.0148 3$LC=0.00473 9$MC=1211E-6 24 -240PU G 857.50 4 5.7E-6 8 -240PU G 900.32 4 1.3E-6 6 +240PU2 G KC=0.048 1$LC=0.00983 20$MC=0.00239 5 +240PU G 302.98 6 0.000019 3(E1) 0.0405 8 +240PU2 G KC=0.0320 7$LC=0.00637 13$MC=0.00154 3 +240PU G 758.63 5 1.38E-5 19(E2) 0.0212 4 +240PU2 G KC=0.0148 3$LC=0.00473 9$MC=1211E-6 24 +240PU G 857.50 4 5.7E-6 8 +240PU G 900.32 4 1.3E-6 6 240PU L 938.06 6 1- 240PU A 4882.12 8 47000E-11133 -240PU G 289.21 7 6E-7 3 E2+M3 7 7 -240PU2 G KC=3 4$LC=2.4 23$MC=0.7 7 -240PU G 340.72 7 1.8E-6 9 -240PU G 895.24 6 1.8E-6 6 E1+M2 0.07 7 -240PU2 G KC=0.06 6$LC=0.013 13$MC=0.003 3 -240PU G 938.06 6 4E-7 4 +240PU G 289.21 7 6E-7 3E2+M3 7 7 +240PU2 G KC=3 4$LC=2.4 23$MC=0.7 7 +240PU G 340.72 7 1.8E-6 9 +240PU G 895.24 6 1.8E-6 6E1+M2 0.07 7 +240PU2 G KC=0.06 6$LC=0.013 13$MC=0.003 3 +240PU G 938.06 6 4E-7 4 diff --git a/HEN_HOUSE/spectra/lnhb/Cm-245.txt b/HEN_HOUSE/spectra/lnhb/Cm-245.txt index 4b1e37335..5c26d06b0 100644 --- a/HEN_HOUSE/spectra/lnhb/Cm-245.txt +++ b/HEN_HOUSE/spectra/lnhb/Cm-245.txt @@ -6,82 +6,82 @@ 241PU3C 1975BA65, 1976BAZZ, 1977La19, 1980DI13, 1982Po14, 1985DR10, 1989Ho24, 241PU4C 1991PO17, 1991RY01, 1994SH31, 1996Sc06, 1998WH01, 2000Sc47, 2003Au03, 241PU5C 2005MA88, 2008Ki07, 2008KOZP, 2009KOZV -241PU T Auger electrons and ^X ray energies and emission intensities: -241PU T {U Energy (keV)} {U Intensity } {U Line } +241PU T Auger electrons and X ray energies and emission intensities: +241PU T {U Energy (keV)} {U Intensity} {U Line} 241PU T -241PU T 99.525 19.0 5 XKA2 -241PU T 103.734 30.1 7 XKA1 +241PU T 99.525 19.0 5 XKA2 +241PU T 103.734 30.1 7 XKA1 241PU T -241PU T 116.244 |] XKB3 -241PU T 117.228 |] 11.06 30 XKB1 -241PU T 117.918 |] XKB5II +241PU T 116.244 |] XKB3 +241PU T 117.228 |] 11.06 30 XKB1 +241PU T 117.918 |] XKB5II 241PU T -241PU T 120.54 |] XKB2 -241PU T 120.969 |] 3.84 12 XKB4 -241PU T 121.543 |] XKO23 +241PU T 120.54 |] XKB2 +241PU T 120.969 |] 3.84 12 XKB4 +241PU T 121.543 |] XKO23 241PU T -241PU T 12.1246-21.9844 51.7 10 XL (total) -241PU T 12.1246 1.46 4 XLL -241PU T 14.0834-14.2791 22.8 6 XLA -241PU T 16.334 0.334 11 XLC -241PU T 16.4987-19.331 22.1 5 XLB -241PU T 20.7081-21.9844 4.97 10 XLG +241PU T 12.1246-21.9844 51.7 10 XL (total) +241PU T 12.1246 1.46 4 XLL +241PU T 14.0834-14.2791 22.8 6 XLA +241PU T 16.334 0.334 11 XLC +241PU T 16.4987-19.331 22.1 5 XLB +241PU T 20.7081-21.9844 4.97 10 XLG 241PU T -241PU T 75.263-85.357 |] KLL AUGER -241PU T 92.607-103.729 |] 1.91 27 ^KLX AUGER -241PU T 109.93-121.78 |] KXY AUGER -241PU T 6.19-22.99 50.1 13 L AUGER +241PU T 75.263-85.357 |] KLL AUGER +241PU T 92.607-103.729 |] 1.91 27 KLX AUGER +241PU T 109.93-121.78 |] KXY AUGER +241PU T 6.19-22.99 50.1 13 L AUGER 245CM P 0.0 7/2+ 8250 Y 70 5622.3 5 241PU N 1.0 1.0 1 1.0 -241PU G 388.16 5 0.019 1 +241PU G 388.16 5 0.019 1 241PU L 0 5/2+ 14.33 Y 4 241PU A 5530.4 4 0.58 1770 241PU L 41.9722 9 7/2+ 241PU A 5488.5 5 0.83 768 241PU G 41.972 1 0.369 20M1+E2 0.186 4 102.4 20 -241PU2 G KC=$LC=76.2 15$MC=19.4 4 +241PU2 G LC=76.2 15$MC=19.4 4 241PU L 95.7795 129/2+ 241PU A 5436.1 5 0.04 7130 -241PU G 53.807 1 0.073 4 M1+E2 0.201 8 44.7 11 -241PU2 G KC=$LC=33.3 8$MC=8.42 21 -241PU G 95.7795 120.0109 23E2 19.3 3 -241PU2 G KC=$LC=14.0 2$MC=3.92 6 +241PU G 53.807 1 0.073 4M1+E2 0.201 8 44.7 11 +241PU2 G LC=33.3 8$MC=8.42 21 +241PU G 95.7795 120.0109 23E2 19.3 3 +241PU2 G LC=14.0 2$MC=3.92 6 241PU L 161.314 4 11/2+ 241PU A 5371.7 5 0.39 22300 -241PU G 65.535 3 0.018 2 M1+E2 0.22 22 24 12 -241PU2 G KC=$LC=18 9$MC=4.5 24 +241PU G 65.535 3 0.018 2M1+E2 0.22 22 24 12 +241PU2 G LC=18 9$MC=4.5 24 241PU L 161.6852 9 1/2+ 0.88 US 5 241PU A 5371.4 5 0.0210 9 5520 -241PU G 161.685 1 0.071 3 E2 1.96 3 -241PU2 G KC=0.190 3$LC=1.289 18$MC=0.360 5 +241PU G 161.685 1 0.071 3E2 1.96 3 +241PU2 G KC=0.190 3$LC=1.289 18$MC=0.360 5 241PU L 175.0523 147/2+ 241PU A 5361.8 1293.2 5 1.03 -241PU G 79.2728 180.120 7 M1+E2 0.65 25 22 6 -241PU2 G KC=$LC=16 5$MC=4.3 12 -241PU G 133.081 2 2.81 7 M1+E2 0.222 9 11.36 17 -241PU2 G KC=8.80 13$LC=1.92 3$MC=0.473 7 -241PU G 175.0523 149.83 22M1+E2 0.217 19 5.21 8 -241PU2 G KC=4.07 7$LC=0.855 12$MC=0.209 3 +241PU G 79.2728 180.120 7M1+E2 0.65 25 22 6 +241PU2 G LC=16 5$MC=4.3 12 +241PU G 133.081 2 2.81 7M1+E2 0.222 9 11.36 17 +241PU2 G KC=8.80 13$LC=1.92 3$MC=0.473 7 +241PU G 175.0523 149.83 22M1+E2 0.217 19 5.21 8 +241PU2 G KC=4.07 7$LC=0.855 12$MC=0.209 3 241PU L 231.935 9 9/2+ 241PU A 5303.6 125.0 1 8.7 -241PU G 56.89 3 0.0359 21M1+E2 0.638 50 87 7 -241PU2 G KC=$LC=64 5$MC=17.3 14 -241PU G 136.156 9 0.113 4 M1+E2 0.63 21 9 1 -241PU2 G KC=6.2 12$LC=2.04 15$MC=0.52 5 -241PU G 189.965 100.204 6 M1+E2 0.63 7 3.36 16 +241PU G 56.89 3 0.0359 21M1+E2 0.638 50 87 7 +241PU2 G LC=64 5$MC=17.3 14 +241PU G 136.156 9 0.113 4M1+E2 0.63 21 9 1 +241PU2 G KC=6.2 12$LC=2.04 15$MC=0.52 5 +241PU G 189.965 100.204 6M1+E2 0.63 7 3.36 16 241PU2 G KC=2.46 15$LC=0.665 10$MC=0.1680 25 -241PU G 231.935 9 0.0117 18[E2] 0.498 7 -241PU2 G KC=0.1200 17$LC=0.275 4$MC=0.0760 11 +241PU G 231.935 9 0.0117 18[E2] 0.498 7 +241PU2 G KC=0.1200 17$LC=0.275 4$MC=0.0760 11 241PU L 301.172 1611/2+ 241PU A 5234.4 120.32 51 -241PU G 69.237 180.007 3 M1(+E2) 0.433 300 28 14 -241PU2 G KC=$LC=21 10$MC=5 3 -241PU G 126.09 4 0.007 2 [E2] 5.59 8 -241PU2 G KC=0.1705 24$LC=3.94 6$MC=1.101 16 -241PU G 139.858 160.008 1 [M1E2] 7 4 -241PU2 G KC=4 4$LC=2.0 5$MC=0.54 15 -241PU G 205.393 160.009 1 [M1E2] 2.1 14 -241PU2 G KC=1.4 13$LC=0.50 5$MC=0.129 3 +241PU G 69.237 180.007 3M1(+E2) 0.433 300 28 14 +241PU2 G LC=21 10$MC=5 3 +241PU G 126.09 4 0.007 2[E2] 5.59 8 +241PU2 G KC=0.1705 24$LC=3.94 6$MC=1.101 16 +241PU G 139.858 160.008 1[M1E2] 7 4 +241PU2 G KC=4 4$LC=2.0 5$MC=0.54 15 +241PU G 205.393 160.009 1[M1E2] 2.1 14 +241PU2 G KC=1.4 13$LC=0.50 5$MC=0.129 3 241PU L 385 3 (13/2)+ 241PU A 5152 3 0.005 1000 diff --git a/HEN_HOUSE/spectra/lnhb/Cm-246.txt b/HEN_HOUSE/spectra/lnhb/Cm-246.txt index f87212b33..c3770faae 100644 --- a/HEN_HOUSE/spectra/lnhb/Cm-246.txt +++ b/HEN_HOUSE/spectra/lnhb/Cm-246.txt @@ -2,41 +2,41 @@ 242PU H TYP=Full$AUT=F.Kondev$CUT=31-OCT-2006$ 242PU C Evaluation history: Type=Full;Author=F.Kondev;Cutoff date=31-OCT-2006 242PU C References: 1977La19 -242PU T Auger electrons and ^X ray energies and emission intensities: -242PU T {U Energy (keV)} {U Intensity } {U Line } +242PU T Auger electrons and X ray energies and emission intensities: +242PU T {U Energy (keV)} {U Intensity} {U Line} 242PU T 242PU T 99.525 XKA2 242PU T 103.734 XKA1 242PU T -242PU T 116.244 |] XKB3 -242PU T 117.228 |] XKB1 -242PU T 117.918 |] XKB5II +242PU T 116.244 |] XKB3 +242PU T 117.228 |] XKB1 +242PU T 117.918 |] XKB5II 242PU T -242PU T 120.54 |] XKB2 -242PU T 120.969 |] XKB4 -242PU T 121.543 |] XKO23 +242PU T 120.54 |] XKB2 +242PU T 120.969 |] XKB4 +242PU T 121.543 |] XKO23 242PU T -242PU T 12.125-21.984 7.95 24 XL (total) -242PU T 12.125 0.195 8 XLL -242PU T 14.083-14.279 3.03 11 XLA -242PU T 16.334 0.082 4 XLC -242PU T 16.499-19.331 3.76 14 XLB -242PU T 20.708-21.984 0.87 4 XLG +242PU T 12.125-21.984 7.95 24 XL (total) +242PU T 12.125 0.195 8 XLL +242PU T 14.083-14.279 3.03 11 XLA +242PU T 16.334 0.082 4 XLC +242PU T 16.499-19.331 3.76 14 XLB +242PU T 20.708-21.984 0.87 4 XLG 242PU T -242PU T 75.263-85.357 |] KLL AUGER -242PU T 92.607-103.729 |] ^KLX AUGER -242PU T 109.93-121.78 |] KXY AUGER -242PU T 6.19-22.99 7.20 21 L AUGER +242PU T 75.263-85.357 |] KLL AUGER +242PU T 92.607-103.729 |] KLX AUGER +242PU T 109.93-121.78 |] KXY AUGER +242PU T 6.19-22.99 7.20 21 L AUGER 246CM P 0.0 0+ 4723 Y 27 5476.7 9 242PU N 1.00E0 1.00E0 0.999738 1.00E0 242PU L 0 0+ 3.73E5 Y 3 242PU A 5387.5 9 79.19 221 242PU L 44.545 9 2+ 242PU A 5343.7 9 20.82 222.05 -242PU G 44.545 9 0.0279 8 E2 746 22 -242PU2 G KC=$LC=542 16$MC=151.4 45 +242PU G 44.545 9 0.0279 8E2 746 22 +242PU2 G LC=542 16$MC=151.4 45 242PU L 147.35 104+ 242PU A 5242.5 100.020 2 500 242PU G 102.8 1 0.00134 14E2 13.86 42 -242PU2 G KC=$LC=10.06 30$MC=2.82 8 +242PU2 G LC=10.06 30$MC=2.82 8 diff --git a/HEN_HOUSE/spectra/lnhb/Co-56.txt b/HEN_HOUSE/spectra/lnhb/Co-56.txt index 4a66cb303..5a9f85e9b 100644 --- a/HEN_HOUSE/spectra/lnhb/Co-56.txt +++ b/HEN_HOUSE/spectra/lnhb/Co-56.txt @@ -1,115 +1,114 @@ 56FE 56CO EC DECAY (77.236 D) 56FE C References: 1977La19, 1979Sc31, 1999Hu04, 2000He14, 2000Ra36, 2002Ba38, 56FE2C 2003Au03 - 56FE T Auger electrons and ^X ray energies and emission intensities: - 56FE T {U Energy (keV)} {U Intensity } {U Line } + 56FE T Auger electrons and X ray energies and emission intensities: + 56FE T {U Energy (keV)} {U Intensity} {U Line} 56FE T - 56FE T 6.39091 7.53 10 XKA2 - 56FE T 6.40391 14.75 17 XKA1 + 56FE T 6.39091 7.53 10 XKA2 + 56FE T 6.40391 14.75 17 XKA1 56FE T - 56FE T 7.05804 |] 3.05 5 XKB1 - 56FE T 7.1083 |] XKB5II + 56FE T 7.05804 |] 3.05 5 XKB1 + 56FE T 7.1083 |] XKB5II 56FE T 56FE T - 56FE T 0.615-0.792 0.581 17 XL (total) + 56FE T 0.615-0.792 0.581 17 XL (total) 56FE T 0.615 XLL 56FE T -0.792 XLB 56FE T - 56FE T 5.37-5.645 |] KLL AUGER - 56FE T 6.158-6.4 |] 46.04 30 ^KLX AUGER - 56FE T 6.926-7.105 |] KXY AUGER - 56FE T 0.51-0.594 111.8 8 L AUGER + 56FE T 5.37-5.645 |] KLL AUGER + 56FE T 6.158-6.4 |] 46.04 30 KLX AUGER + 56FE T 6.926-7.105 |] KXY AUGER + 56FE T 0.51-0.594 111.8 8 L AUGER 56CO P 0.0 4+ 77.236 D 26 4566 2 56FE N 1.0 1.0 1 1.0 56FE L 0 0+ STABLE 56FE L 846.7700 192+ - 56FE E 0.25 170.005 3 11.6 2 - 56FE2 E EAV=1205.8 10$CK=0.8890 16$CL=0.0951 13$CM=0.0152 5$CN= $CO= - 56FE G 846.7638 1999.9399 23E2 3.03E-49 - 56FE2 G KC=$LC=$MC= + 56FE E 0.25 170.005 311.6 2 + 56FE2 E EAV=1205.8 10$CK=0.8890 16$CL=0.0951 13$CM=0.0152 5 + 56FE G 846.7638 1999.9399 23E2 3.03E-4 9 56FE L 2085.0583 254+ - 56FE E 18.29 162.43 3 8.62 - 56FE2 E EAV=631.2 9$CK=0.8888 16$CL=0.0952 13$CM=0.0152 5$CN= $CO= + 56FE E 18.29 162.43 38.62 + 56FE2 E EAV=631.2 9$CK=0.8888 16$CL=0.0952 13$CM=0.0152 5 56FE G 1238.2736 2266.41 16E2 56FE L 2657.527 4 2+ - 56FE G 1810.726 4 0.639 3 M1+E2 -0.17 3 + 56FE G 1810.726 4 0.639 3M1+E2 -0.17 3 56FE G 2657.4 8 0.0195 20[E2] 56FE L 2959.905 5 2+ - 56FE E 0.0086 220.023 6 10.26 2 - 56FE2 E EAV=247.1 9$CK=0.8885 16$CL=0.0955 13$CM=0.0153 5$CN= $CO= - 56FE G 2113.092 6 0.376 3 M1+E2 0.27 3 + 56FE E 0.0086 220.023 610.26 2 + 56FE2 E EAV=247.1 9$CK=0.8885 16$CL=0.0955 13$CM=0.0153 5 + 56FE G 2113.092 6 0.376 3M1+E2 0.27 3 56FE L 3122.901 3 4+ - 56FE E 1.04 2 8.99 6 7.58 - 56FE2 E EAV=178.7 8$CK=0.8884 16$CL=0.0955 13$CM=0.0153 5$CN= $CO= - 56FE G 1037.8333 2414.03 5 M1(+E2) 0.00 5 - 56FE G 2276.36 160.118 4 E2 + 56FE E 1.04 28.99 67.58 + 56FE2 E EAV=178.7 8$CK=0.8884 16$CL=0.0955 13$CM=0.0153 5 + 56FE G 1037.8333 2414.03 5M1(+E2) 0.00 5 + 56FE G 2276.36 160.118 4E2 56FE L 3369.86 112+ - 56FE E 6.E-6 200.015 5 10.2 2 - 56FE2 E EAV=76.7 8$CK=0.8883 16$CL=0.0957 13$CM=0.0153 5$CN= $CO= - 56FE G 2523.0 8 0.063 4 M1+E2 0.25 15 - 56FE G 3369.69 300.0103 8 E2 + 56FE E 0.000006200.015 510.2 2 + 56FE2 E EAV=76.7 8$CK=0.8883 16$CL=0.0957 13$CM=0.0153 5 + 56FE G 2523.0 8 0.063 4M1+E2 0.25 15 + 56FE G 3369.69 300.0103 8E2 56FE L 3445.270 3 3+ - 56FE E 0.0080 7 21.40 5 6.98 - 56FE2 E EAV=45.3 9$CK=0.8882 16$CL=0.0957 13$CM=0.0153 5$CN= $CO= - 56FE G 787.7391 230.310 4 M1+E2 0.85 35 - 56FE G 1360.196 4 4.280 13M1+E2 -0.11 1 - 56FE G 2598.438 4 16.96 4 M1+E2 -0.28 2 + 56FE E 0.0080 721.40 56.98 + 56FE2 E EAV=45.3 9$CK=0.8882 16$CL=0.0957 13$CM=0.0153 5 + 56FE G 787.7391 230.310 4M1+E2 0.85 35 + 56FE G 1360.1960 404.280 13M1+E2 -0.11 1 + 56FE G 2598.438 4 16.96 4M1+E2 -0.28 2 56FE L 3856.415 3 3+ - 56FE E 16.86 5 6.69 - 56FE2 E EAV= $CK=0.8875 16$CL=0.0963 13$CM=0.0154 5$CN= $CO= + 56FE E 16.86 56.69 + 56FE2 E CK=0.8875 16$CL=0.0963 13$CM=0.0154 5 56FE G 411.38 8 0.0269 23 - 56FE G 486.54 110.058 3 - 56FE G 733.5085 230.191 4 M1+E2 -0.02 2 + 56FE G 486.54 110.058 3 + 56FE G 733.5085 230.191 4M1+E2 -0.02 2 56FE G 896.503 7 0.0704 22 - 56FE G 1198.78 200.044 3 - 56FE G 1771.327 3 15.45 4 M1+E2 -0.004 2 + 56FE G 1198.78 200.044 3 + 56FE G 1771.3270 3015.45 4M1+E2 -0.004 2 56FE G 3009.559 4 1.038 19M1+E2 0.065 5 56FE L 4048.799 8 3+ 56FE E 3.965 157.04 - 56FE2 E EAV= $CK=0.8868 16$CL=0.0969 13$CM=0.0155 5$CN= $CO= - 56FE G 1089.03 240.054 4 M1+E2 0.43 12 - 56FE G 1963.703 110.706 4 M1+E2 0.22 3 + 56FE2 E CK=0.8868 16$CL=0.0969 13$CM=0.0155 5 + 56FE G 1089.03 240.054 4M1+E2 0.43 12 + 56FE G 1963.703 110.706 4M1+E2 0.22 3 56FE G 3201.930 113.203 13M1+E2 0.50 1 56FE L 4100.273 4 4+ 55 FS 25 - 56FE E 12.66 4 6.44 - 56FE2 E EAV= $CK=0.8866 16$CL=0.0971 13$CM=0.0156 5$CN= $CO= - 56FE G 655.0 8 0.038 8 - 56FE G 977.363 4 1.422 7 M1(+E2) 0.07 3 - 56FE G 1140.356 7 0.132 4 - 56FE G 1442.75 8 0.180 4 + 56FE E 12.66 46.44 + 56FE2 E CK=0.8866 16$CL=0.0971 13$CM=0.0156 5 + 56FE G 655.0 8 0.038 8 + 56FE G 977.363 4 1.422 7M1(+E2) 0.07 3 + 56FE G 1140.356 7 0.132 4 + 56FE G 1442.75 8 0.180 4 56FE G 2015.176 5 3.017 14M1+E2 0.68 5 - 56FE G 3253.402 5 7.87 3 E2 + 56FE G 3253.402 5 7.87 3E2 56FE L 4119.849 4 3+ 56FE E 9.940 186.51 - 56FE2 E EAV= $CK=0.8864 16$CL=0.0972 13$CM=0.0156 5$CN= $CO= + 56FE2 E CK=0.8864 16$CL=0.0972 13$CM=0.0156 5 56FE G 263.41 100.0234 20 - 56FE G 674.7 8 0.035 5 - 56FE G 996.939 5 0.116 6 M1+E2 - 56FE G 1159.933 8 0.088 3 M1+E2 0.064 16 - 56FE G 1462.34 120.0778 9 + 56FE G 674.7 8 0.035 5 + 56FE G 996.939 5 0.116 6M1+E2 + 56FE G 1159.933 8 0.088 3M1+E2 0.064 16 + 56FE G 1462.34 120.0778 9 56FE G 2034.752 5 7.741 13M1+E2 -0.073 5 - 56FE G 3272.978 6 1.855 9 M1+E2 0.420 4 + 56FE G 3272.978 6 1.855 9M1+E2 0.420 4 56FE L 4298.002 3 4+ 110 FS 50 56FE E 3.688 136.49 - 56FE2 E EAV= $CK=0.8845 16$CL=0.0989 13$CM=0.0159 5$CN= $CO= - 56FE G 852.78 5 0.049 3 - 56FE G 1175.0878 222.249 9 M1+E2 0.14 4 + 56FE2 E CK=0.8845 16$CL=0.0989 13$CM=0.0159 5 + 56FE G 852.78 5 0.049 3 + 56FE G 1175.0878 222.249 9M1+E2 0.14 4 56FE G 1640.450 5 0.0621 21 - 56FE G 2212.898 3 0.385 5 M1+E2 -3 1 - 56FE G 3451.119 4 0.942 6 E2 + 56FE G 2212.8980 300.385 5M1+E2 -3 1 + 56FE G 3451.119 4 0.942 6E2 56FE L 4394.82 6 3+ 56FE E 0.2159 187.32 - 56FE2 E EAV= $CK=0.8816 17$CL=0.1013 13$CM=0.0164 6$CN= $CO= - 56FE G 1272.2 6 0.0202 8 + 56FE2 E CK=0.8816 17$CL=0.1013 13$CM=0.0164 6 + 56FE G 1272.2 6 0.0202 8 56FE G 3547.93 6 0.1956 16M1+E2 -0.30 2 56FE L 4447.6 4 (2-,3,4)+ - 56FE E 0.0167 5 8.1 2 - 56FE2 E EAV= $CK=0.8779 17$CL=0.1044 14$CM=0.0169 6$CN= $CO= - 56FE G 3600.71 400.0167 5 + 56FE E 0.0167 58.1 2 + 56FE2 E CK=0.8779 17$CL=0.1044 14$CM=0.0169 6 + 56FE G 3600.71 400.0167 5 56FE L 4458.30 3 4+ - 56FE E 0.209 7 6.91 - 56FE2 E EAV= $CK=0.8766 17$CL=0.1055 14$CM=0.0171 6$CN= $CO= + 56FE E 0.209 76.91 + 56FE2 E CK=0.8766 17$CL=0.1055 14$CM=0.0171 6 56FE G 1335.380 290.1228 16 - 56FE G 2373.7 4 0.078 6 - 56FE G 3611.8 8 0.0084 4 [E2] + 56FE G 2373.70 400.078 6 + 56FE G 3611.8 8 0.0084 4[E2] diff --git a/HEN_HOUSE/spectra/lnhb/Co-57.txt b/HEN_HOUSE/spectra/lnhb/Co-57.txt index d36e3aa73..aff841dfa 100644 --- a/HEN_HOUSE/spectra/lnhb/Co-57.txt +++ b/HEN_HOUSE/spectra/lnhb/Co-57.txt @@ -1,57 +1,54 @@ 57FE 57CO EC DECAY (271.80 D) 57FE C References: 1977La19 - 57FE T Auger electrons and ^X ray energies and emission intensities: - 57FE T {U Energy (keV)} {U Intensity } {U Line } + 57FE T Auger electrons and X ray energies and emission intensities: + 57FE T {U Energy (keV)} {U Intensity} {U Line} 57FE T - 57FE T 6.39091 16.8 3 XKA2 - 57FE T 6.40391 33.2 5 XKA1 + 57FE T 6.39091 16.8 3 XKA2 + 57FE T 6.40391 33.2 5 XKA1 57FE T - 57FE T 7.05804 |] 7.1 2 XKB1 - 57FE T 7.1083 |] XKB5II + 57FE T 7.05804 |] 7.1 2 XKB1 + 57FE T 7.1083 |] XKB5II 57FE T 57FE T - 57FE T 0.61-0.79 1.55 13 XL (total) + 57FE T 0.61-0.79 1.55 13 XL (total) 57FE T 0.61 XLL 57FE T -0.79 XLB 57FE T - 57FE T 5.37-5.64 |] KLL AUGER - 57FE T 6.16-6.4 |] 105.2 13 ^KLX AUGER - 57FE T 6.91-7.1 |] KXY AUGER - 57FE T 0.6-0.7 252 3 L AUGER + 57FE T 5.37-5.64 |] KLL AUGER + 57FE T 6.16-6.4 |] 105.2 13 KLX AUGER + 57FE T 6.91-7.1 |] KXY AUGER + 57FE T 0.6-0.7 252 3 L AUGER 57CO P 0.0 7/2- 271.80 D 5 836.0 4 57FE N 1.0 1.0 1 1.0 57FE L 0 1/2- STABLE - 57FE E 0.00035 12.9 - 57FE2 E EAV= $CK= $CL= $CM= $CN= $CO= + 57FE E 0.00035 12.9 2U 57FE L 14.41295 313/2- 98.0 NS 3 - 57FE E 0.003 11.1 - 57FE2 E EAV= $CK= $CL= $CM= $CN= $CO= + 57FE E 0.003 11.1 2 57FE G 14.41295 319.15 17M1+E2 8.58 18 - 57FE2 G KC=7.69 16$LC=0.782 16$MC=0.113 3 + 57FE2 G KC=7.69 16$LC=0.782 16$MC=0.113 3 57FE L 136.47374 295/2- 8.8 NS 5 - 57FE E 99.82 206.45 2 - 57FE2 E EAV= $CK=0.8875 16$CL=0.0963 13$CM=0.0154 5$CN= $CO= - 57FE G 122.06065 1285.51 6 M1+E2 0.0236 5 - 57FE2 G KC=0.0212 5$LC=0.00208 5$MC=3.03E-4 7 - 57FE G 136.47356 2910.71 15E2 0.148 3 - 57FE2 G KC=0.133 3$LC=0.0136 3$MC=0.00196 4 + 57FE E 99.82 206.45 + 57FE2 E CK=0.8875 16$CL=0.0963 13$CM=0.0154 5 + 57FE G 122.06065 1285.51 6M1+E2 0.0236 5 + 57FE2 G KC=0.0212 5$LC=0.00208 5$MC=3.03E-4 7 + 57FE G 136.47356 2910.71 15E2 0.148 3 + 57FE2 G KC=0.133 3$LC=0.0136 3$MC=0.00196 4 57FE L 366.74 3 3/2- - 57FE E 0.002 10.8 - 57FE2 E EAV= $CK= $CL= $CM= $CN= $CO= - 57FE G 230.27 3 0.0004 4 M1+E2 0.004159 - 57FE2 G KC=0.00374 8$LC=3.56E-4 8$MC=5.24E-5 11 - 57FE G 352.34 2 0.0032 4 M1+E2 0.001503 - 57FE2 G KC=0.00135 3$LC=1.29E-4 3$MC=1.88E-5 4 - 57FE G 366.74 3 0.0013 4 M1+E2 0.001786 - 57FE2 G KC=0.00160 5$LC=1.53E-4 5$MC=2.23E-5 7 + 57FE E 0.002 10.8 2 + 57FE G 230.27 3 0.0004 4M1+E2 0.00415 9 + 57FE2 G KC=0.00374 8$LC=3.56E-4 8$MC=5.24E-5 11 + 57FE G 352.34 2 0.0032 4M1+E2 0.00150 3 + 57FE2 G KC=0.00135 3$LC=1.29E-4 3$MC=1.88E-5 4 + 57FE G 366.74 3 0.0013 4M1+E2 0.00178 6 + 57FE2 G KC=0.00160 5$LC=1.53E-4 5$MC=2.23E-5 7 57FE L 706.42 2 5/2- - 57FE E 0.183 7 7.69 2 - 57FE2 E EAV= $CK=0.8789 17$CL=0.1035 14$CM=0.0168 6$CN= $CO= - 57FE G 339.67 3 0.0038 4 M1+E2 0.001654 - 57FE2 G KC=0.00149 3$LC=1.42E-4 3$MC=2.08E-5 5 - 57FE G 569.94 4 0.015 2 M1+E2 5.08E-412 - 57FE2 G KC=4.58E-4 10$LC=4.34E-5 9$MC=6.31E-6 14 - 57FE G 692.01 2 0.159 6 M1+E2 3.64E-412 - 57FE2 G KC=3.28E-4 10$LC=3.1E-5 1$MC=4.52E-6 14 - 57FE G 706.42 2 0.0050 5 (E2) + 57FE E 0.183 77.69 + 57FE2 E CK=0.8789 17$CL=0.1035 14$CM=0.0168 6 + 57FE G 339.67 3 0.0038 4M1+E2 0.00165 4 + 57FE2 G KC=0.00149 3$LC=1.42E-4 3$MC=2.08E-5 5 + 57FE G 569.94 4 0.015 2M1+E2 5.08E-412 + 57FE2 G KC=4.58E-4 10$LC=4.34E-5 9$MC=6.31E-6 14 + 57FE G 692.01 2 0.159 6M1+E2 3.64E-412 + 57FE2 G KC=3.28E-4 10$LC=3.1E-5 1$MC=4.52E-6 14 + 57FE G 706.42 2 0.0050 5(E2) diff --git a/HEN_HOUSE/spectra/lnhb/Co-58.txt b/HEN_HOUSE/spectra/lnhb/Co-58.txt index 7976e0eeb..fd26cd890 100644 --- a/HEN_HOUSE/spectra/lnhb/Co-58.txt +++ b/HEN_HOUSE/spectra/lnhb/Co-58.txt @@ -17,40 +17,40 @@ 58FE12C 1992Sy**, 1992So04, 1996Sc06, 1996Sc06, 2000He14, 2000He14, 2002Ba85, 58FE13C 2002Ba85, 2003Au03, 2003Au03, 2008Ki07, 2008Ki07, 2010Ne01, 2010Ne01, 58FE14C 2012Wa38, 2012Fi12, 2012Wa38, 2012Fi12 - 58FE T Auger electrons and ^X ray energies and emission intensities: - 58FE T {U Energy (keV)} {U Intensity } {U Line } + 58FE T Auger electrons and X ray energies and emission intensities: + 58FE T {U Energy (keV)} {U Intensity} {U Line} 58FE T - 58FE T 6.39091 7.98 11 XKA2 - 58FE T 6.40391 15.63 19 XKA1 + 58FE T 6.39091 7.98 11 XKA2 + 58FE T 6.40391 15.63 19 XKA1 58FE T - 58FE T 7.0581 |] 3.23 5 XKB1 - 58FE T 7.1083 |] XKB5II + 58FE T 7.0581 |] 3.23 5 XKB1 + 58FE T 7.1083 |] XKB5II 58FE T 58FE T - 58FE T 0.617-0.8454 0.609 18 XL (total) - 58FE T 0.617 0.0309 13 XLL - 58FE T 0.7075-0.7084 0.327 12 XLA - 58FE T 0.6306 0.0197 9 XLC - 58FE T 0.7148-0.8454 0.229 10 XLB - 58FE T 0.7284-0.7284 0.00172 19 XLG + 58FE T 0.617-0.8454 0.609 18 XL (total) + 58FE T 0.617 0.0309 13 XLL + 58FE T 0.7075-0.7084 0.327 12 XLA + 58FE T 0.6306 0.0197 9 XLC + 58FE T 0.7148-0.8454 0.229 10 XLB + 58FE T 0.7284-0.7284 0.00172 19 XLG 58FE T - 58FE T 5.37-5.65 |] KLL AUGER - 58FE T 6.16-6.4 |] 48.8 4 ^KLX AUGER - 58FE T 6.93-7.11 |] KXY AUGER - 58FE T 0.52-0.84 116.9 7 L AUGER + 58FE T 5.37-5.65 |] KLL AUGER + 58FE T 6.16-6.4 |] 48.8 4 KLX AUGER + 58FE T 6.93-7.11 |] KXY AUGER + 58FE T 0.52-0.84 116.9 7 L AUGER 58CO P 0.0 2+ 70.85 D 3 2307.9 11 58FE N 1.0 1.0 1 1.0 58FE L 0 0+ STABLE 58FE L 810.7662 202+ 6.54 PS 19 58FE E 14.94 1683.83 166.6 - 58FE2 E EAV=201.3 5$CK=0.8885 16$CL=0.0955 13$CM=0.0153 5$CN=0.0007 2$CO= - 58FE G 810.7602 2099.44 2 E2 3.32E-45 - 58FE2 G KC=2.99E-4 5$LC=2.87E-5 4$MC= + 58FE2 E EAV=201.3 5$CK=0.8885 16$CL=0.0955 13$CM=0.0153 5$CN=0.0007 2 + 58FE G 810.7602 2099.44 2E2 3.32E-4 5 + 58FE2 G KC=2.99E-4 5$LC=2.87E-5 4 58FE L 1674.731 6 2+ 1.6 PS 4 58FE E 1.228 357.7 - 58FE2 E EAV= $CK=0.8873 16$CL=0.0965 13$CM=0.0155 5$CN=0.0007 2$CO= - 58FE G 863.958 6 0.700 22M1+E2 0.643 41 2.31E-44 - 58FE2 G KC=2.08E-4 4$LC=1.99E-5 4$MC= - 58FE G 1674.705 6 0.528 13E2 2.25E-44 - 58FE2 G KC=5.77E-5 8$LC=5.47E-6 8$MC= + 58FE2 E CK=0.8873 16$CL=0.0965 13$CM=0.0155 5$CN=0.0007 2 + 58FE G 863.958 6 0.700 22M1+E2 0.643 41 2.31E-4 4 + 58FE2 G KC=2.08E-4 4$LC=1.99E-5 4 + 58FE G 1674.705 6 0.528 13E2 2.25E-4 4 + 58FE2 G KC=5.77E-5 8$LC=5.47E-6 8 diff --git a/HEN_HOUSE/spectra/lnhb/Co-60.txt b/HEN_HOUSE/spectra/lnhb/Co-60.txt index 151f68e4e..d7e48e9f7 100644 --- a/HEN_HOUSE/spectra/lnhb/Co-60.txt +++ b/HEN_HOUSE/spectra/lnhb/Co-60.txt @@ -4,47 +4,47 @@ 60NI C Evaluation history: Type=Update;Author=M.-M.Bé;Cutoff date=16-JAN-2006 60NI2C Type=Full;Author=R.G.Helmer;Cutoff date=01-JAN-1998 60NI C References: 2002Ba85 - 60NI T Auger electrons and ^X ray energies and emission intensities: - 60NI T {U Energy (keV)} {U Intensity } {U Line } + 60NI T Auger electrons and X ray energies and emission intensities: + 60NI T {U Energy (keV)} {U Intensity} {U Line} 60NI T - 60NI T 7.46097 0.00334 12 XKA2 - 60NI T 7.47824 0.0065 3 XKA1 + 60NI T 7.46097 0.00334 12 XKA2 + 60NI T 7.47824 0.0065 3 XKA1 60NI T - 60NI T 8.2647 |] XKB3 - 60NI T |] 0.00136 5 XKB1 - 60NI T 8.3287 |] XKB5II + 60NI T 8.2647 |] XKB3 + 60NI T |] 0.00136 5 XKB1 + 60NI T 8.3287 |] XKB5II 60NI T 60NI T - 60NI T 0.74-0.94 0.0002 XL (total) + 60NI T 0.74-0.94 0.0002 XL (total) 60NI T 0.74 XLL 60NI T -0.94 XLG 60NI T - 60NI T 6.26-6.54 |] KLL AUGER - 60NI T 7.2-7.47 |] 0.0154 5 ^KLX AUGER - 60NI T 8.1-8.32 |] KXY AUGER - 60NI T 0.7-0.9 0.0392 12 L AUGER + 60NI T 6.26-6.54 |] KLL AUGER + 60NI T 7.2-7.47 |] 0.0154 5 KLX AUGER + 60NI T 8.1-8.32 |] KXY AUGER + 60NI T 0.7-0.9 0.0392 12 L AUGER 60CO P 0.0 5+ 5.2711 Y 8 2823.07 21 60NI N 1.0 1.0 1 1.0 60NI L 0 0+ STABLE 60NI L 1332.508 4 2+ 0.713 PS 11 - 60NI B 1490.56 210.12 3 14.7 2U + 60NI B 1490.56 210.12 3 14.7 2U 60NIS B EAV=625.6 1 - 60NI G 1332.492 4 99.9826 6 E2 1.28E-45 - 60NI2 G KC=1.15E-4 5$LC=1.13E-5 3$MC= + 60NI G 1332.492 4 99.9826 6E2 1.28E-4 5 + 60NI2 G KC=1.15E-4 5$LC=1.13E-5 3 60NI L 2158.61 3 2+ 0.59 PS 17 60NI B 664.46 210.002 2U 60NIS B EAV=274.8 1 - 60NI G 826.10 3 0.0076 8 M1+E2 0.9 3 0.000344 - 60NI2 G KC=0.00030 4$LC=2.91E-5 17$MC= - 60NI G 2158.57 3 0.0012 2 E2 4.95E-515 - 60NI2 G KC=4.45E-5 14$LC=4.3E-6 2$MC= + 60NI G 826.10 3 0.0076 8M1+E2 0.9 3 0.00034 4 + 60NI2 G KC=0.00030 4$LC=2.91E-5 17 + 60NI G 2158.57 3 0.0012 2E2 4.95E-515 + 60NI2 G KC=4.45E-5 14$LC=4.3E-6 2 60NI L 2505.748 5 4+ 0.30 PS 9 - 60NI B 317.32 2199.88 3 7.51 + 60NI B 317.32 2199.88 3 7.51 60NIS B EAV=95.6 1 - 60NI G 347.14 7 0.0075 4 [E2] 0.0055717 - 60NI2 G KC=0.00499 15$LC=5.03E-4 15$MC= - 60NI G 1173.228 3 99.85 3 E2(+M3) 1.68E-44 - 60NI2 G KC=1.51E-4 7$LC=1.48E-5 4$MC= - 60NI G 2505.692 5 2.0E-6 4 E4 8.6E-5 3 - 60NI2 G KC=7.80E-5 3$LC=7.6E-6 3$MC= + 60NI G 347.14 7 0.0075 4[E2] 0.0055717 + 60NI2 G KC=0.00499 15$LC=5.03E-4 15 + 60NI G 1173.228 3 99.85 3E2(+M3) 1.68E-4 4 + 60NI2 G KC=1.51E-4 7$LC=1.48E-5 4 + 60NI G 2505.692 5 2.0E-6 4E4 8.6E-5 3 + 60NI2 G KC=7.80E-5 3$LC=7.6E-6 3 diff --git a/HEN_HOUSE/spectra/lnhb/Cr-51.txt b/HEN_HOUSE/spectra/lnhb/Cr-51.txt index 2d6790ccf..ce4c6170a 100644 --- a/HEN_HOUSE/spectra/lnhb/Cr-51.txt +++ b/HEN_HOUSE/spectra/lnhb/Cr-51.txt @@ -13,35 +13,35 @@ 51V 6C 1982ChZF, 1983Wa26, 1984Fi10, 1991Ba11, 1992Un01, 1994Ko34, 1999Ka65, 51V 7C 2002Un02, 2002Ba85, 2004BeZR, 2005Ya01, 2006Hu10, 2008Ki07, 2010Mo01, 51V 8C 2012Wa38, 2012Fi12, 2014Un01 - 51V T Auger electrons and ^X ray energies and emission intensities: - 51V T {U Energy (keV)} {U Intensity } {U Line } + 51V T Auger electrons and X ray energies and emission intensities: + 51V T {U Energy (keV)} {U Intensity} {U Line} 51V T - 51V T 4.9447 6.79 14 XKA2 - 51V T 4.95224 13.36 27 XKA1 + 51V T 4.9447 6.79 14 XKA2 + 51V T 4.95224 13.36 27 XKA1 51V T - 51V T 5.42735 |] 2.69 7 XKB1 - 51V T 5.463 |] XKB5II + 51V T 5.42735 |] 2.69 7 XKB1 + 51V T 5.463 |] XKB5II 51V T 51V T - 51V T 0.4475-0.6268 0.56 12 XL (total) + 51V T 0.4475-0.6268 0.56 12 XL (total) 51V T 0.4475 XLL 51V T 0.5135- XLA 51V T 0.4557 XLC 51V T 0.51938-0.6268 XLB 51V T 0.52758-0.52758 XLG 51V T - 51V T 4.164-4.395 |] KLL AUGER - 51V T 4.755-4.95 |] 66.4 5 ^KLX AUGER - 51V T 5.332-5.461 |] KXY AUGER - 51V T 0.3799-0.6257 146.0 6 L AUGER + 51V T 4.164-4.395 |] KLL AUGER + 51V T 4.755-4.95 |] 66.4 5 KLX AUGER + 51V T 5.332-5.461 |] KXY AUGER + 51V T 0.3799-0.6257 146.0 6 L AUGER 51CR P 0.0 7/2- 27.704 D 4 752.62 24 51V N 1.0 1.0 1 1.0 51V L 0 7/2- STABLE - 51V E 90.09 2 5.39 - 51V 2 E EAV= $CK=0.8919 17$CL=0.0927 14$CM=0.0154 6$CN= $CO= + 51V E 90.09 25.39 + 51V 2 E CK=0.8919 17$CL=0.0927 14$CM=0.0154 6 51V L 320.0835 4 5/2- 184 PS 6 - 51V E 9.91 2 5.86 2 - 51V 2 E EAV= $CK=0.8910 17$CL=0.0935 14$CM=0.0156 6$CN= $CO= - 51V G 320.0835 4 9.89 2 M1+E2 0.465 20 0.001815 - 51V 2 G KC=0.00164 5$LC=1.51E-4 4$MC=1.98E-5 6 + 51V E 9.91 25.86 + 51V 2 E CK=0.8910 17$CL=0.0935 14$CM=0.0156 6 + 51V G 320.0835 4 9.89 2M1+E2 0.465 20 0.00181 5 + 51V 2 G KC=0.00164 5$LC=1.51E-4 4$MC=1.98E-5 6 diff --git a/HEN_HOUSE/spectra/lnhb/Cs-134.txt b/HEN_HOUSE/spectra/lnhb/Cs-134.txt index 0c467facd..0695ee9ba 100644 --- a/HEN_HOUSE/spectra/lnhb/Cs-134.txt +++ b/HEN_HOUSE/spectra/lnhb/Cs-134.txt @@ -3,101 +3,101 @@ 134XE C Evaluation history: Type=Full;Author=M.M. Bé;Cutoff date=01-MAY-2012 134XE C References: 1967Le18, 1968Ab01, 1972La14, 1973Di11, 1975Va12, 1987Wa28, 134XE2C 1988Ch44, 1997Ma75, 2002Un02, 2002Mi06, 2004So32, 2008Ki07, 2012Au06 -134XE T Auger electrons and ^X ray energies and emission intensities: -134XE T {U Energy (keV)} {U Intensity } {U Line } +134XE T Auger electrons and X ray energies and emission intensities: +134XE T {U Energy (keV)} {U Intensity} {U Line} 134XE T 134XE T 29.459 XKA2 134XE T 29.779 XKA1 134XE T -134XE T 33.562 |] XKB3 -134XE T 33.625 |] XKB1 -134XE T 33.881 |] XKB5II +134XE T 33.562 |] XKB3 +134XE T 33.625 |] XKB1 +134XE T 33.881 |] XKB5II 134XE T -134XE T 34.415 |] XKB2 -134XE T 34.496 |] XKB4 -134XE T 34.552 |] XKO23 +134XE T 34.415 |] XKB2 +134XE T 34.496 |] XKB4 +134XE T 34.552 |] XKO23 134XE T 134XE T -134XE T 23.512-24.842 |] KLL AUGER -134XE T 27.897-29.77 |] ^KLX AUGER -134XE T 32.27-34.54 |] KXY AUGER +134XE T 23.512-24.842 |] KLL AUGER +134XE T 27.897-29.77 |] KLX AUGER +134XE T 32.27-34.54 |] KXY AUGER 134XE T 2.4848-5.3158 L AUGER 134CS P 0.0 4+ 2.0644 Y 14 1233.3 8 134XE N 3.333E5 3.333E5 0.0000031 3.333E5 134XE L 0 0+ STABLE 134XE L 847.041 232+ -134XE E 0.0003 1 13 2 -134XE2 E EAV= $CK=0.8361 16$CL=0.1289 11$CM=0.0283 6$CN=0.0066 4$CO= -134XE G 847.00 2 0.0003 1 E2 +134XE E 0.0003 113 2 +134XE2 E CK=0.8361 16$CL=0.1289 11$CM=0.0283 6$CN=0.0066 4 +134XE G 847.000 200.0003 1E2 134BA 134CS B- DECAY (2.0644 Y) 134BA H TYP=Full$AUT=M.M. Bé$CUT=01-MAY-2012$ 134BA C Evaluation history: Type=Full;Author=M.M. Bé;Cutoff date=01-MAY-2012 134BA C References: 1967Le18, 1968Ab01, 1972La14, 1973Di11, 1975Va12, 1987Wa28, 134BA2C 1988Ch44, 1997Ma75, 2002Un02, 2002Mi06, 2004So32, 2008Ki07, 2012Au06 -134BA T Auger electrons and ^X ray energies and emission intensities: -134BA T {U Energy (keV)} {U Intensity } {U Line } +134BA T Auger electrons and X ray energies and emission intensities: +134BA T {U Energy (keV)} {U Intensity} {U Line} 134BA T -134BA T 31.8174 0.2378 26 XKA2 -134BA T 32.1939 0.438 5 XKA1 +134BA T 31.8174 0.2378 26 XKA2 +134BA T 32.1939 0.438 5 XKA1 134BA T -134BA T 36.3045 |] XKB3 -134BA T 36.3786 |] 0.1289 19 XKB1 -134BA T 36.654 |] XKB5II +134BA T 36.3045 |] XKB3 +134BA T 36.3786 |] 0.1289 19 XKB1 +134BA T 36.654 |] XKB5II 134BA T -134BA T 37.258 |] XKB2 -134BA T 37.312 |] 0.0325 8 XKB4 -134BA T 37.425 |] XKO23 +134BA T 37.258 |] XKB2 +134BA T 37.312 |] 0.0325 8 XKB4 +134BA T 37.425 |] XKO23 134BA T -134BA T 3.9544-5.8104 0.1058 17 XL (total) -134BA T 3.9544 0.00204 5 XLL -134BA T 4.4515-4.4666 0.0528 12 XLA -134BA T 4.3307 0.000776 20 XLC -134BA T 4.8278-5.207 0.0435 8 XLB -134BA T 5.3715-5.8104 0.00675 14 XLG +134BA T 3.9544-5.8104 0.1058 17 XL (total) +134BA T 3.9544 0.00204 5 XLL +134BA T 4.4515-4.4666 0.0528 12 XLA +134BA T 4.3307 0.00077620 XLC +134BA T 4.8278-5.207 0.0435 8 XLB +134BA T 5.3715-5.8104 0.00675 14 XLG 134BA T -134BA T 25.314-26.786 |] KLL AUGER -134BA T 30.095-32.179 |] 0.093 4 ^KLX AUGER -134BA T 34.86-37.41 |] KXY AUGER -134BA T 2.66-5.81 0.850 5 L AUGER +134BA T 25.314-26.786 |] KLL AUGER +134BA T 30.095-32.179 |] 0.093 4 KLX AUGER +134BA T 34.86-37.41 |] KXY AUGER +134BA T 2.66-5.81 0.850 5 L AUGER 134CS P 0.0 4+ 2.0644 Y 14 2058.98 33 134BA N 1.00E0 1.00E0 0.9999971 1.00E0 134BA L 0 0+ STABLE 134BA L 604.7223 192+ -134BA B 1454.26 330.06 6 13.1 2 +134BA B 1454.26 330.06 6 13.1 2 134BAS B EAV=535 1 -134BA G 604.720 3 97.63 8 E2 0.005939 -134BA2 G KC=0.00503 7$LC=7.21E-4 10$MC=1495E-7 21 +134BA G 604.7200 3097.63 8E2 0.00593 9 +134BA2 G KC=0.00503 7$LC=7.21E-4 10$MC=1495E-7 21 134BA L 1167.968 3 2+ 134BA B 891.01 33 13 2 134BAS B EAV=300 1 -134BA G 563.246 3 8.342 15E2 0.0071410 -134BA2 G KC=0.00603 9$LC=8.81E-4 13$MC=1.83E-4 3 -134BA G 1167.967 4 1.791 5 E2 1307E-619 -134BA2 G KC=1122E-6 16$LC=1444E-7 21$MC=2.97E-5 5 +134BA G 563.2460 308.342 15E2 0.0071410 +134BA2 G KC=0.00603 9$LC=8.81E-4 13$MC=1.83E-4 3 +134BA G 1167.967 4 1.791 5E2 1307E-619 +134BA2 G KC=1122E-6 16$LC=1444E-7 21$MC=2.97E-5 5 134BA L 1400.590 4 4+ -134BA B 658.39 3370.19 8 8.89 +134BA B 658.39 3370.19 8 8.89 134BAS B EAV=210.3 4 -134BA G 795.86 1 85.47 9 E2 0.003025 -134BA2 G KC=0.00258 4$LC=3.51E-4 5$MC=7.24E-5 11 +134BA G 795.860 1085.47 9E2 0.00302 5 +134BA2 G KC=0.00258 4$LC=3.51E-4 5$MC=7.24E-5 11 134BA L 1643.336 4 3+ -134BA B 415.64 332.498 8 9.65 +134BA B 415.64 332.498 8 9.65 134BAS B EAV=123.6 4 -134BA G 242.76 5 0.0241 31(M1+E2) 0.087 3 -134BA2 G KC=0.0722 12$LC=0.0120 25$MC=0.0025 6 -134BA G 475.365 2 1.479 7 M1+()E2 6.0 35 0.0114 5 -134BA2 G KC=0.0096 4$LC=0.00146 3$MC=3.04E-4 6 -134BA G 1038.605 8 0.9909 33M1+()E2 0.71 14 0.002087 -134BA2 G KC=0.00179 6$LC=2.28E-4 7$MC=4.67E-5 13 +134BA G 242.76 5 0.0241 31(M1+E2) 0.087 3 +134BA2 G KC=0.0722 12$LC=0.0120 25$MC=0.0025 6 +134BA G 475.365 2 1.479 7M1+()E2 6.0 35 0.0114 5 +134BA2 G KC=0.0096 4$LC=0.00146 3$MC=3.04E-4 6 +134BA G 1038.605 8 0.9909 33M1+()E2 0.71 14 0.00208 7 +134BA2 G KC=0.00179 6$LC=2.28E-4 7$MC=4.67E-5 13 134BA L 1969.921 4 4+ -134BA B 89.06 3327.27 3 6.49 +134BA B 89.06 3327.27 3 6.49 134BAS B EAV=23.2 4 134BA G 326.585 140.0171 11(M1+E2) 0.0367 22 -134BA2 G KC=0.031 3$LC=0.0047 3$MC=0.00097 8 +134BA2 G KC=0.031 3$LC=0.0047 3$MC=0.00097 8 134BA G 569.330 2 15.368 21M1+()E2 0.28 2 0.0093614 -134BA2 G KC=0.00805 12$LC=1039E-6 15$MC=2.14E-4 3 -134BA G 801.950 6 8.694 16E2 0.002975 -134BA2 G KC=0.00254 4$LC=3.44E-4 5$MC=7.1E-5 1 -134BA G 1365.194 4 3.019 8 E2 9.87E-414 -134BA2 G KC=8.20E-4 12$LC=1039E-7 15$MC=2.13E-5 3 +134BA2 G KC=0.00805 12$LC=1039E-6 15$MC=2.14E-4 3 +134BA G 801.950 6 8.694 16E2 0.00297 5 +134BA2 G KC=0.00254 4$LC=3.44E-4 5$MC=7.1E-5 1 +134BA G 1365.1940 403.019 8E2 9.87E-414 +134BA2 G KC=8.20E-4 12$LC=1039E-7 15$MC=2.13E-5 3 diff --git a/HEN_HOUSE/spectra/lnhb/Cs-137.txt b/HEN_HOUSE/spectra/lnhb/Cs-137.txt index 8a2f80486..12726780d 100644 --- a/HEN_HOUSE/spectra/lnhb/Cs-137.txt +++ b/HEN_HOUSE/spectra/lnhb/Cs-137.txt @@ -5,41 +5,41 @@ 137BA C Evaluation history: Type=Update;Author=M.M. Bé;Cutoff date=11-DEC-2007 137BA2C Type=Update;Author=V.Chechev;Cutoff date=01-MAR-2006 137BA3C Type=Full;Author=R.G.Helmer;Cutoff date=01-JUN-1998 -137BA T Auger electrons and ^X ray energies and emission intensities: -137BA T {U Energy (keV)} {U Intensity } {U Line } +137BA T Auger electrons and X ray energies and emission intensities: +137BA T {U Energy (keV)} {U Intensity} {U Line} 137BA T -137BA T 31.8174 1.95 4 XKA2 -137BA T 32.1939 3.59 7 XKA1 +137BA T 31.8174 1.95 4 XKA2 +137BA T 32.1939 3.59 7 XKA1 137BA T -137BA T 36.3045 |] XKB3 -137BA T 36.3786 |] 1.055 22 XKB1 -137BA T 36.654 |] XKB5II +137BA T 36.3045 |] XKB3 +137BA T 36.3786 |] 1.055 22 XKB1 +137BA T 36.654 |] XKB5II 137BA T -137BA T 37.258 |] XKB2 -137BA T 37.312 |] 0.266 8 XKB4 -137BA T 37.425 |] XKO23 +137BA T 37.258 |] XKB2 +137BA T 37.312 |] 0.266 8 XKB4 +137BA T 37.425 |] XKO23 137BA T -137BA T 3.954-5.809 0.90 5 XL (total) +137BA T 3.954-5.809 0.90 5 XL (total) 137BA T 3.954 XLL 137BA T -5.809 XLG 137BA T -137BA T 25.314-26.786 |] KLL AUGER -137BA T 30.095-32.179 |] 0.76 4 ^KLX AUGER -137BA T 34.86-37.41 |] KXY AUGER -137BA T 2.6-5.8 7.28 12 L AUGER +137BA T 25.314-26.786 |] KLL AUGER +137BA T 30.095-32.179 |] 0.76 4 KLX AUGER +137BA T 34.86-37.41 |] KXY AUGER +137BA T 2.6-5.8 7.28 12 L AUGER 137CS P 0.0 7/2+ 30.05 Y 8 1175.63 17 137BA N 1.0 1.0 1 1.0 137BA L 0 3/2+ STABLE -137BA B 1175.63 175.64 28 12.06 +137BA B 1175.63 175.64 28 12.06 2 137BAS B EAV=416.26 8 137BA L 283.5 1 1/2+ -137BA B 892.1 2 0.00061 8 15.64 +137BA B 892.13 200.00061 8 15.64 2U 137BAS B EAV=300.57 8 -137BA G 283.5 1 0.00058 8 [M1E2] 0.0557 13 -137BA2 G KC=0.046 3$LC=0.0073 10$MC=0.0015 2 +137BA G 283.5 1 0.00058 8[M1E2] 0.0557 13 +137BA2 G KC=0.046 3$LC=0.0073 10$MC=0.0015 2 137BA L 661.659 3 11/2- 2.552 M 1 -137BA B 513.97 1794.36 28 9.63 3U +137BA B 513.97 1794.36 28 9.63 1U 137BAS B EAV=174.32 6 137BA G 661.657 3 84.99 20M4 0.1102 19 -137BA2 G KC=0.0896 15$LC=0.0165 5$MC=0.00352 7 +137BA2 G KC=0.0896 15$LC=0.0165 5$MC=0.00352 7 diff --git a/HEN_HOUSE/spectra/lnhb/Cu-61.txt b/HEN_HOUSE/spectra/lnhb/Cu-61.txt index 395807229..972dfb17b 100644 --- a/HEN_HOUSE/spectra/lnhb/Cu-61.txt +++ b/HEN_HOUSE/spectra/lnhb/Cu-61.txt @@ -5,103 +5,103 @@ 61NI2C 1971Go40, 1972Du09, 1972Cr02, 1973Ne02, 1977Wa03, 1978ME10, 1982Gr10, 61NI3C 1982Ma41, 1988Sa26, 1996Sc06, 1998Sc28, 1999Bh04, 2000Sc47, 2008Ki07, 61NI4C 2012Wa38 - 61NI T Auger electrons and ^X ray energies and emission intensities: - 61NI T {U Energy (keV)} {U Intensity } {U Line } + 61NI T Auger electrons and X ray energies and emission intensities: + 61NI T {U Energy (keV)} {U Intensity} {U Line} 61NI T - 61NI T 7.46097 4.33 20 XKA2 - 61NI T 7.47824 8.4 4 XKA1 + 61NI T 7.46097 4.33 20 XKA2 + 61NI T 7.47824 8.4 4 XKA1 61NI T - 61NI T 8.26475 |] 1.76 9 XKB1 - 61NI T 8.3287 |] XKB5II + 61NI T 8.26475 |] 1.76 9 XKB1 + 61NI T 8.3287 |] XKB5II 61NI T 61NI T - 61NI T 0.7445-1.0083 0.437 14 XL (total) - 61NI T 0.7445 0.0165 8 XLL - 61NI T 0.8532-0.8539 0.244 10 XLA - 61NI T 0.7622 0.0101 5 XLC - 61NI T 0.86123-1.0083 0.165 8 XLB - 61NI T 0.87898-0.87898 0.0008 1 XLG + 61NI T 0.7445-1.0083 0.437 14 XL (total) + 61NI T 0.7445 0.0165 8 XLL + 61NI T 0.8532-0.8539 0.244 10 XLA + 61NI T 0.7622 0.0101 5 XLC + 61NI T 0.86123-1.0083 0.165 8 XLB + 61NI T 0.87898-0.87898 0.0008 1 XLG 61NI T - 61NI T 6.262-6.567 |] KLL AUGER - 61NI T 7.196-7.475 |] 20.0 9 ^KLX AUGER - 61NI T 8.109-8.326 |] KXY AUGER - 61NI T 0.632-1.01 51.2 9 L AUGER + 61NI T 6.262-6.567 |] KLL AUGER + 61NI T 7.196-7.475 |] 20.0 9 KLX AUGER + 61NI T 8.109-8.326 |] KXY AUGER + 61NI T 0.632-1.01 51.2 9 L AUGER 61CU P 0.0 3/2- 3.366 H 33 2237.5 10 61NI N 1.0 1.0 1 1.0 61NI L 0 3/2- STABLE - 61NI E 51.6 2516.3 8 5 - 61NI2 E EAV=523.8 5$CK=0.8867 16$CL=0.0967 13$CM=0.0157 5$CN=0.0009 1$CO= + 61NI E 51.6 2516.3 85 + 61NI2 E EAV=523.8 5$CK=0.8867 16$CL=0.0967 13$CM=0.0157 5$CN=0.0009 1 61NI L 67.412 3 5/2- 5.34 NS 16 - 61NI E 2.1 5 0.79 206.3 2 - 61NI2 E EAV=493.8 5$CK=0.8866 16$CL=0.0968 13$CM=0.0157 5$CN=0.0009 1$CO= - 61NI G 67.412 3 4.0 6 (M1) 0.1368 20 + 61NI E 2.1 50.79 206.3 + 61NI2 E EAV=493.8 5$CK=0.8866 16$CL=0.0968 13$CM=0.0157 5$CN=0.0009 1 + 61NI G 67.412 3 4.0 6(M1) 0.1368 20 61NI2 G KC=0.1224 18$LC=0.01261 18$MC=1776E-6 25 61NI L 282.9568 191/2- 22 PS 4 - 61NI E 5.4 9 4.0 7 5.5 2 - 61NI2 E EAV=398.9 5$CK=0.8866 16$CL=0.0968 13$CM=0.0157 5$CN=0.0009 1$CO= - 61NI G 215.55 180.013 7 - 61NI G 282.956 2 12.0 17(M1) 0.003295 - 61NI2 G KC=0.00295 5$LC=2.93E-4 5$MC=4.13E-5 6 + 61NI E 5.4 94.0 75.5 + 61NI2 E EAV=398.9 5$CK=0.8866 16$CL=0.0968 13$CM=0.0157 5$CN=0.0009 1 + 61NI G 215.55 180.013 7 + 61NI G 282.9560 2012.0 17(M1) 0.00329 5 + 61NI2 G KC=0.00295 5$LC=2.93E-4 5$MC=4.13E-5 6 61NI L 656.012 3 1/2- 22 PS 4 - 61NI E 2.52 2710.7 124.9 2 - 61NI2 E EAV=238.5 4$CK=0.8864 16$CL=0.0970 13$CM=0.0157 5$CN=0.0009 1$CO= - 61NI G 373.050 5 2.09 30[M1] 0.001702 - 61NI2 G KC=0.00153 2$LC=1.51E-4 2$MC=2.13E-5 3 + 61NI E 2.52 2710.7 124.9 + 61NI2 E EAV=238.5 4$CK=0.8864 16$CL=0.0970 13$CM=0.0157 5$CN=0.0009 1 + 61NI G 373.050 5 2.09 30[M1] 0.00170 2 + 61NI2 G KC=0.00153 2$LC=1.51E-4 2$MC=2.13E-5 3 61NI G 588.605 9 1.15 16[E2] 61NI G 656.008 4 10.4 15(M1+E2) 61NI L 908.620 115/2- - 61NI E 0.0347 401.32 155.7 2 - 61NI2 E EAV=132.8 4$CK=0.8862 16$CL=0.0971 13$CM=0.0158 5$CN=0.0009 1$CO= - 61NI G 625.605 240.044 7 [E2] + 61NI E 0.0347 401.32 155.7 + 61NI2 E EAV=132.8 4$CK=0.8862 16$CL=0.0971 13$CM=0.0158 5$CN=0.0009 1 + 61NI G 625.605 240.044 7[E2] 61NI G 841.211 170.224 34M1+()E2 -1.83 20 61NI G 908.631 171.12 16M1+()E2 -0.18 5 61NI L 1014.8 4 7/2- - 61NI E 3.2E-5 320.006 6 7.8 - 61NI2 E EAV=88.7 4$CK=0.8861 16$CL=0.0972 13$CM=0.0158 5$CN=0.0009 1$CO= - 61NI G 947.4 4 0.0060 19M1+()E2 -2.46 15 - 61NI G 1014.8 4 0.0103 39E2+()M3 0.03 300 0.0002 6 - 61NI2 G KC=0.0002 6$LC=0.00002 6$MC=3E-6 8 + 61NI E 0.000032320.006 67.8 2 + 61NI2 E EAV=88.7 4$CK=0.8861 16$CL=0.0972 13$CM=0.0158 5$CN=0.0009 1 + 61NI G 947.40 400.0060 19M1+()E2 -2.46 15 + 61NI G 1014.8 4 0.0103 39E2+()M3 0.03 300 0.0002 6 + 61NI2 G KC=0.0002 6$LC=0.00002 6$MC=3E-6 8 61NI L 1099.622 103/2- - 61NI E 0.64 6 5.9 - 61NI2 E EAV= $CK=0.8860 16$CL=0.0973 13$CM=0.0158 5$CN=0.0009 1$CO= - 61NI G 816.692 130.32 5 M1+()E2 -0.23 700 + 61NI E 0.64 65.9 + 61NI2 E CK=0.8860 16$CL=0.0973 13$CM=0.0158 5$CN=0.0009 1 + 61NI G 816.692 130.32 5M1+()E2 -0.23 700 61NI G 1032.162 100.053 10 61NI G 1099.560 190.257 39 61NI L 1132.332 175/2- - 61NI E 0.154 176.5 2 - 61NI2 E EAV= $CK=0.8860 16$CL=0.0973 13$CM=0.0158 5$CN=0.0009 1$CO= - 61NI G 117.5 0.010 6 - 61NI G 1064.896 200.052 9 M1+()E2 -0.14 12 - 61NI G 1132.35 3 0.092 13M1+()E2 0.47 9 + 61NI E 0.154 176.5 + 61NI2 E CK=0.8860 16$CL=0.0973 13$CM=0.0158 5$CN=0.0009 1 + 61NI G 117.5 0.010 6 + 61NI G 1064.896 200.052 9M1+()E2 -0.14 12 + 61NI G 1132.350 300.092 13M1+()E2 0.47 9 61NI L 1185.236 113/2- - 61NI E 4.1 5 5 - 61NI2 E EAV= $CK=0.8859 16$CL=0.0974 13$CM=0.0158 5$CN=0.0009 1$CO= - 61NI G 529.169 220.38 5 + 61NI E 4.1 55 + 61NI2 E CK=0.8859 16$CL=0.0974 13$CM=0.0158 5$CN=0.0009 1 + 61NI G 529.169 220.38 5 61NI G 902.294 200.084 12 - 61NI G 1117.822 430.039 9 - 61NI G 1185.234 153.6 5 (M1+E2) + 61NI G 1117.822 430.039 9 + 61NI G 1185.234 153.6 5(M1+E2) 61NI L 1609.639 215/2- - 61NI E 0.063 7 6.5 2 - 61NI2 E EAV= $CK=0.8849 16$CL=0.0982 13$CM=0.0160 5$CN=0.0009 1$CO= - 61NI G 701.1 3 0.0108 28 - 61NI G 1542.204 230.029 5 M1+()E2 0.07 500 + 61NI E 0.063 76.5 + 61NI2 E CK=0.8849 16$CL=0.0982 13$CM=0.0160 5$CN=0.0009 1 + 61NI G 701.10 300.0108 28 + 61NI G 1542.204 230.029 5M1+()E2 0.07 500 61NI G 1609.625 480.0236 43M1+()E2 0.33 14 61NI L 1729.471 103/2- 61NI E 0.228 185.7 - 61NI2 E EAV= $CK=0.8843 16$CL=0.0987 13$CM=0.0160 5$CN=0.0009 1$CO= - 61NI G 544.8 0.006 4 + 61NI2 E CK=0.8843 16$CL=0.0987 13$CM=0.0160 5$CN=0.0009 1 + 61NI G 544.8 0.006 4 61NI G 820.89 170.0216 39 61NI G 1073.465 250.042 11 - 61NI G 1446.492 190.046 7 - 61NI G 1662.000 190.051 8 + 61NI G 1446.492 190.046 7 + 61NI G 1662.000 190.051 8 61NI G 1729.473 180.065 14 61NI L 1997.7 9 5/2- - 61NI E 0.0043 146.7 2 - 61NI2 E EAV= $CK=0.8808 17$CL=0.1016 14$CM=0.0166 5$CN=0.0010 1$CO= - 61NI G 1089.11 0.00060 8 + 61NI E 0.0043 146.7 + 61NI2 E CK=0.8808 17$CL=0.1016 14$CM=0.0166 5$CN=0.0010 1 + 61NI G 1089.11 0.00060 8 61NI G 1997.7 9 0.0037 13M1+()E2 0.27 6 61NI L 2124 1 1/2- - 61NI E 0.040 5 5 2 - 61NI2 E EAV= $CK=0.8729 22$CL=0.1083 18$CM=0.0178 6$CN=0.0010 2$CO= - 61NI G 2124 1 0.040 6 + 61NI E 0.040 55 + 61NI2 E CK=0.8729 22$CL=0.1083 18$CM=0.0178 6$CN=0.0010 2 + 61NI G 2124 1 0.040 6 diff --git a/HEN_HOUSE/spectra/lnhb/Cu-64.txt b/HEN_HOUSE/spectra/lnhb/Cu-64.txt index 8559a2cf6..3cab20f48 100644 --- a/HEN_HOUSE/spectra/lnhb/Cu-64.txt +++ b/HEN_HOUSE/spectra/lnhb/Cu-64.txt @@ -7,38 +7,38 @@ 64NI3C Type=Full;Author=R.G.Helmer;Cutoff date=31-JAN-2002 64NI C References: 1976Ba63, 1989Ab22, 1996Sc06, 2002WE02, 2003Au03, 2007Qa02, 64NI2C 2007Si04 - 64NI T Auger electrons and ^X ray energies and emission intensities: - 64NI T {U Energy (keV)} {U Intensity } {U Line } + 64NI T Auger electrons and X ray energies and emission intensities: + 64NI T {U Energy (keV)} {U Intensity} {U Line} 64NI T - 64NI T 7.46093 4.90 6 XKA2 - 64NI T 7.47819 9.56 11 XKA1 + 64NI T 7.46093 4.90 6 XKA2 + 64NI T 7.47819 9.56 11 XKA1 64NI T - 64NI T 8.2647 |] XKB3 - 64NI T |] 1.99 3 XKB1 - 64NI T 8.3287 |] XKB5II + 64NI T 8.2647 |] XKB3 + 64NI T |] 1.99 3 XKB1 + 64NI T 8.3287 |] XKB5II 64NI T 64NI T - 64NI T 0.7445-1.0083 0.493 10 XL (total) - 64NI T 0.7445 0.0186 6 XLL - 64NI T 0.8532-0.8539 0.276 7 XLA - 64NI T 0.7622 0.0114 4 XLC - 64NI T 0.86123-1.0083 0.187 6 XLB - 64NI T 0.87898-0.87898 0.0009 1 XLG + 64NI T 0.7445-1.0083 0.493 10 XL (total) + 64NI T 0.7445 0.0186 6 XLL + 64NI T 0.8532-0.8539 0.276 7 XLA + 64NI T 0.7622 0.0114 4 XLC + 64NI T 0.86123-1.0083 0.187 6 XLB + 64NI T 0.87898-0.87898 0.0009 1 XLG 64NI T - 64NI T 6.262-6.567 |] KLL AUGER - 64NI T 7.196-7.475 |] 22.62 21 ^KLX AUGER - 64NI T 8.109-8.326 |] KXY AUGER - 64NI T 0.6-0.9 57.9 4 L AUGER + 64NI T 6.262-6.567 |] KLL AUGER + 64NI T 7.196-7.475 |] 22.62 21 KLX AUGER + 64NI T 8.109-8.326 |] KXY AUGER + 64NI T 0.6-0.9 57.9 4 L AUGER 64CU P 0.0 1+ 12.7004 H 20 1675.03 20 64NI N 1.625E0 1.625E0 0.6152 261.625E0 64NI L 0 0+ STABLE 64NI E 17.52 1543.53 204.97 - 64NI2 E EAV=278.21 9$CK=0.888 3$CL=0.095 2$CM=0.0155 5$CN= $CO= + 64NI2 E EAV=278.21 9$CK=0.888 3$CL=0.095 2$CM=0.0155 5 64NI L 1345.75 5 2+ 1.088 PS 35 64NI E 0.4744 335.51 - 64NI2 E EAV= $CK=0.884 3$CL=0.099 2$CM=0.0162 5$CN= $CO= - 64NI G 1345.77 6 0.4748 34E2 1.24E-42 - 64NI2 G KC=1112E-7 2$LC=1.09E-5 2$MC= + 64NI2 E CK=0.884 3$CL=0.099 2$CM=0.0162 5 + 64NI G 1345.77 6 0.4748 34E2 1.24E-4 2 + 64NI2 G KC=1112E-7 2$LC=1.09E-5 2 64ZN 64CU B- DECAY (12.7004 H) 64ZN H TYP=update$AUT=M.-M.Bé$CUT=30-JUN-2011$ diff --git a/HEN_HOUSE/spectra/lnhb/Er-169.txt b/HEN_HOUSE/spectra/lnhb/Er-169.txt index d6326c209..faaef923f 100644 --- a/HEN_HOUSE/spectra/lnhb/Er-169.txt +++ b/HEN_HOUSE/spectra/lnhb/Er-169.txt @@ -6,32 +6,32 @@ 169TM3C 1968Ca06, 1968Wa05, 1970Sh09, 1971MaXG, 1977My02, 2001KoZQ, 2002Be05, 169TM4C 2002Ba85, 2004BeZQ, 2004Sc04, 2008Ki07, 2008Ba31, 2012Mo38, 2012Wa38, 169TM5C 2012Le09, 2014Mo20, 2015In02 -169TM T Auger electrons and ^X ray energies and emission intensities: -169TM T {U Energy (keV)} {U Intensity } {U Line } +169TM T Auger electrons and X ray energies and emission intensities: +169TM T {U Energy (keV)} {U Intensity} {U Line} 169TM T 169TM T 169TM T 169TM T 169TM T -169TM T 0.04-0.53 |] KLL AUGER -169TM T 0.31-1.47 |] 74.6 ^KLX AUGER -169TM T 0.85-1.79 |] KXY AUGER -169TM T 0.05-0.186 116.1 L AUGER +169TM T 0.04-0.53 |] KLL AUGER +169TM T 0.31-1.47 |] 74.6 KLX AUGER +169TM T 0.85-1.79 |] KXY AUGER +169TM T 0.05-0.186 116.1 L AUGER 169ER P 0.0 1/2- 9.38 D 2 353.0 12 169TM N 1.0 1.0 1 0 1.0 169TM L 0 1/2+ STABLE -169TM B 353.0 1256 5 6.3 +169TM B 353.0 1256 5 6.3 169TMS B EAV=99.1 5 169TM L 8.4102 1 3/2+ 4.09 NS 5 -169TM B 344.6 1244 5 6.5 1U +169TM B 344.6 1244 5 6.5 1 169TMS B EAV=96.5 5 169TM G 8.4102 1 0.174 21M1+(E2) 0.0306 16 251 10 -169TM2 G KC=$LC=$MC=199 8 +169TM2 G MC=199 8 169TM L 118.1895 1 5/2+ -169TM B 234.8 120.016 9.5 3U +169TM B 234.8 120.016 9.5 1U 169TMS B EAV=73.0 5 -169TM G 109.77930 140.0045 9 M1+E2 0.15 1 2.37 4 -169TM2 G KC=1.96 3$LC=0.316 5$MC=0.0710 12 -169TM G 118.1895 1 5000E-7 0 E2 1.642 23 -169TM2 G KC=0.70 1$LC=0.721 10$MC=0.1759 25 +169TM G 109.77930 140.0045 9M1+E2 0.15 1 2.37 4 +169TM2 G KC=1.96 3$LC=0.316 5$MC=0.0710 12 +169TM G 118.1895 1 0.0005 E2 1.642 23 +169TM2 G KC=0.70 1$LC=0.721 10$MC=0.1759 25 diff --git a/HEN_HOUSE/spectra/lnhb/Eu-152.txt b/HEN_HOUSE/spectra/lnhb/Eu-152.txt index d08c31814..e590ed60b 100644 --- a/HEN_HOUSE/spectra/lnhb/Eu-152.txt +++ b/HEN_HOUSE/spectra/lnhb/Eu-152.txt @@ -1,411 +1,411 @@ 152SM 152EU EC DECAY (13.522 Y) 152SM C References: 1977La19 -152SM T Auger electrons and ^X ray energies and emission intensities: -152SM T {U Energy (keV)} {U Intensity } {U Line } +152SM T Auger electrons and X ray energies and emission intensities: +152SM T {U Energy (keV)} {U Intensity} {U Line} 152SM T -152SM T 39.5229 20.8 3 XKA2 -152SM T 40.1186 37.7 5 XKA1 +152SM T 39.5229 20.8 3 XKA2 +152SM T 40.1186 37.7 5 XKA1 152SM T -152SM T 45.289 |] XKB3 -152SM T 45.413 |] 11.78 19 XKB1 -152SM T 45.731 |] XKB5II +152SM T 45.289 |] XKB3 +152SM T 45.413 |] 11.78 19 XKB1 +152SM T 45.731 |] XKB5II 152SM T -152SM T 46.575 |] XKB2 -152SM T 46.705 |] 3.04 8 XKB4 -152SM T 46.813 |] XKO23 +152SM T 46.575 |] XKB2 +152SM T 46.705 |] 3.04 8 XKB4 +152SM T 46.813 |] XKO23 152SM T -152SM T 5.61-7.18 13.0 4 XL (total) +152SM T 5.61-7.18 13.0 4 XL (total) 152SM T 5.61-5.64 XLA 152SM T -7.18 XLG 152SM T -152SM T 31.19-33.218 |] KLL AUGER -152SM T 37.302-40.097 |] 5.9 4 ^KLX AUGER -152SM T 43.39-46.79 |] KXY AUGER -152SM T 3.2-7.7 67.7 7 L AUGER +152SM T 31.19-33.218 |] KLL AUGER +152SM T 37.302-40.097 |] 5.9 4 KLX AUGER +152SM T 43.39-46.79 |] KXY AUGER +152SM T 3.2-7.7 67.7 7 L AUGER 152EU P 0.0 3- 13.522 Y 16 1874.3 7 152SM N 1.387E0 1.387E0 0.721 1.387E0 -152SM G 237.31 5 0.0025 8 (E1) 0.0272 8 -152SM G 320.03 150.0017 6 +152SM G 237.31 5 0.0025 8(E1) 0.0272 8 +152SM G 320.03 150.0017 6 152SM G 379.37 6 0.00083 21 152SM G 391.32 140.00125 21 152SM G 406.74 150.00083 21 152SM G 535.4 4 0.0060 16(M1+E2) 1 0.0147044 152SM G 595.61 1 0.0031 17 -152SM G 683.32 110.0031 8 +152SM G 683.32 110.0031 8 152SM G 696.87 190.0029 10 152SM G 735.4 1 0.0058 10 -152SM G 756.12 9 0.0054 8 +152SM G 756.12 9 0.0054 8 152SM G 896.58 9 0.0669 21 152SM G 1001.1 3 0.0046 10 -152SM G 1084 1 0.244 8 -152SM G 1139 1 0.0013 3 -152SM G 1674.30 6 0.0060 8 +152SM G 1084 1 0.244 8 +152SM G 1139 1 0.0013 3 +152SM G 1674.30 6 0.0060 8 152SM L 0 0+ STABLE 152SM L 121.7818 3 2+ 1.400 NS 11 152SM E 0.025 151.7 1011.8 1 -152SM2 E EAV=338.1 3$CK=0.8408 15$CL=0.1241 10$CM=0.0281 5$CN=0.0069 4$CO= +152SM2 E EAV=338.1 3$CK=0.8408 15$CL=0.1241 10$CM=0.0281 5$CN=0.0069 4 152SM G 121.7817 3 28.41 13E2 1.165 35 152SM2 G KC=0.676 20$LC=0.378 11$MC=0.0875 26 152SM L 366.4786 8 4+ 57.7 PS 8 -152SM E 0.0024 2 0.77 5 12 1 -152SM2 E EAV=230.7 3$CK=0.8398 15$CL=0.1249 11$CM=0.0283 5$CN=0.0070 4$CO= -152SM G 244.6974 8 7.55 4 E2 0.1080 32 -152SM2 G KC=0.0809 24$LC=0.0211 6$MC=0.00475 14 +152SM E 0.0024 20.77 512 1 +152SM2 E EAV=230.7 3$CK=0.8398 15$CL=0.1249 11$CM=0.0283 5$CN=0.0070 4 +152SM G 244.6974 8 7.55 4E2 0.1080 32 +152SM2 G KC=0.0809 24$LC=0.0211 6$MC=0.00475 14 152SM L 684.714 200+ 152SM G 562.93 2 0.038 13E2 0.0095028 -152SM2 G KC=0.00780 23$LC=1290E-6 39$MC=2.82E-4 8 +152SM2 G KC=0.00780 23$LC=1290E-6 39$MC=2.82E-4 8 152SM L 706.91 5 6+ -152SM G 340.40 140.031 3 E2 0.0385 12 -152SM2 G KC=0.0304 9$LC=0.00632 19$MC=1410E-6 42 +152SM G 340.40 140.031 3E2 0.0385 12 +152SM2 G KC=0.0304 9$LC=0.00632 19$MC=1410E-6 42 152SM L 810.4474 202+ 7.4 PS 6 -152SM E 1.28 3 11.4 1 -152SM2 E EAV= $CK=0.8366 15$CL=0.1273 11$CM=0.0290 6$CN=0.0071 4$CO= -152SM G 125.69 130.019 6 (E2) 1.042 31 +152SM E 1.28 311.4 1 +152SM2 E CK=0.8366 15$CL=0.1273 11$CM=0.0290 6$CN=0.0071 4 +152SM G 125.69 130.019 6(E2) 1.042 31 152SM2 G KC=0.616 18$LC=0.329 10$MC=0.0760 23 -152SM G 443.965 3 0.32 2 (E2) 0.0178 5 -152SM2 G KC=0.01450 44$LC=0.00263 8$MC=5.79E-4 17 -152SM G 688.670 5 0.841 6 E2+M1+ 0.0434 13 -152SM2 G KC=0.0359 13$LC=$MC= -152SM G 810.451 5 0.317 3 (E2) 0.0040012 -152SM2 G KC=0.0033 1$LC=4.93E-4 15$MC=1070E-7 32 +152SM G 443.965 3 0.32 2(E2) 0.0178 5 +152SM2 G KC=0.01450 44$LC=0.00263 8$MC=5.79E-4 17 +152SM G 688.670 5 0.841 6E2+M1+ 0.0434 13 +152SM2 G KC=0.0359 13 +152SM G 810.451 5 0.317 3(E2) 0.0040012 +152SM2 G KC=0.0033 1$LC=4.93E-4 15$MC=1070E-7 32 152SM L 963.360 4 1- -152SM G 841.574 5 0.163 2 E1 1500E-645 +152SM G 841.574 5 0.163 2E1 1500E-645 152SM2 G KC=1200E-6 36$LC=1610E-7 48$MC=3.43E-5 10 152SM G 963.390 120.1341 20E1 1100E-633 -152SM2 G KC=0.00100 3$LC=1230E-7 37$MC=2.63E-5 8 +152SM2 G KC=0.00100 3$LC=1230E-7 37$MC=2.63E-5 8 152SM L 1022.967 5 4- 4.9 PS -152SM E 0.238 5 11.9 -152SM2 E EAV= $CK=0.8338 15$CL=0.1294 11$CM=0.0295 6$CN=0.0073 4$CO= -152SM G 212.568 150.0196 6 E2 0.171 5 +152SM E 0.238 511.9 +152SM2 E CK=0.8338 15$CL=0.1294 11$CM=0.0295 6$CN=0.0073 4 +152SM G 212.568 150.0196 6E2 0.171 5 152SM2 G KC=0.1244 37$LC=0.0364 11$MC=0.00825 25 152SM G 316.2 2 0.0031 10(E2) 0.0481 14 -152SM2 G KC=0.0376 11$LC=0.00819 25$MC=0.00183 5 +152SM2 G KC=0.0376 11$LC=0.00819 25$MC=0.00183 5 152SM G 656.489 5 0.1437 18E2+M1+ 0.0568 20 -152SM2 G KC=0.0497 16$LC=$MC= -152SM G 901.181 110.084 3 E2 0.003109 -152SM2 G KC=0.00260 8$LC=3.82E-4 11$MC=8.24E-5 25 +152SM2 G KC=0.0497 16 +152SM G 901.181 110.084 3E2 0.00310 9 +152SM2 G KC=0.00260 8$LC=3.82E-4 11$MC=8.24E-5 25 152SM L 1041.1342 183- 27 FS 5 -152SM E 0.086 7 12.4 -152SM2 E EAV= $CK=0.8335 15$CL=0.1296 11$CM=0.0296 6$CN=0.0073 4$CO= -152SM G 674.675 3 0.170 4 E1 0.002307 -152SM2 G KC=0.00190 6$LC=2.54E-4 8$MC=5.42E-5 16 -152SM G 919.337 4 0.429 5 E1 1200E-636 -152SM2 G KC=0.00100 3$LC=1.35E-4 4$MC=2.88E-5 9 +152SM E 0.086 712.4 +152SM2 E CK=0.8335 15$CL=0.1296 11$CM=0.0296 6$CN=0.0073 4 +152SM G 674.675 3 0.170 4E1 0.00230 7 +152SM2 G KC=0.00190 6$LC=2.54E-4 8$MC=5.42E-5 16 +152SM G 919.337 4 0.429 5E1 1200E-636 +152SM2 G KC=0.00100 3$LC=1.35E-4 4$MC=2.88E-5 9 152SM L 1085.8499 232+ 0.87 PS 4 152SM E 21.35 119.9 1 -152SM2 E EAV= $CK=0.8327 15$CL=0.1302 11$CM=0.0297 6$CN=0.0073 4$CO= +152SM2 E CK=0.8327 15$CL=0.1302 11$CM=0.0297 6$CN=0.0073 4 152SM G 275.449 150.0323 17(M1) 0.1044 31 -152SM2 G KC=0.0887 27$LC=0.01230 37$MC=0.00265 8 +152SM2 G KC=0.0887 27$LC=0.01230 37$MC=0.00265 8 152SM G 719.349 4 0.268 13(E2) 0.0052016 152SM2 G KC=0.00440 13$LC=6.66E-4 20$MC=1440E-7 43 -152SM G 964.079 1814.50 6 E2(+M1) 0.002708 -152SM2 G KC=0.00230 7$LC=3.27E-4 10$MC=7.03E-5 21 -152SM G 1085.837 1010.13 6 E2 0.002106 -152SM2 G KC=0.00180 5$LC=2.50E-4 8$MC=5.36E-5 16 +152SM G 964.079 1814.50 6E2(+M1) 0.00270 8 +152SM2 G KC=0.00230 7$LC=3.27E-4 10$MC=7.03E-5 21 +152SM G 1085.837 1010.13 6E2 0.00210 6 +152SM2 G KC=0.00180 5$LC=2.50E-4 8$MC=5.36E-5 16 152SM L 1233.8656 173+ 3 PS 3 -152SM E 17.16 8 9.8 -152SM2 E EAV= $CK=0.8291 16$CL=0.1329 11$CM=0.0305 6$CN=0.0075 4$CO= -152SM G 148.010 170.035 5 (M1+E2) 1 0.578 17 -152SM2 G KC=0.430 13$LC=0.1150 34$MC=0.0260 8 -152SM G 423.45 4 0.0032 5 (M1+E2) 1 0.0271 8 -152SM2 G KC=0.0226 7$LC=0.0035 1$MC=7.61E-4 23 -152SM G 867.380 3 4.243 23E2+M1 -6.5 0.0035 1 -152SM2 G KC=0.00290 9$LC=4.23E-4 13$MC=9.13E-5 27 -152SM G 1112.076 3 13.41 6 E2(+M1) -8.7 0.002006 -152SM2 G KC=0.00170 5$LC=2.38E-4 7$MC=5.11E-5 15 +152SM E 17.16 89.8 +152SM2 E CK=0.8291 16$CL=0.1329 11$CM=0.0305 6$CN=0.0075 4 +152SM G 148.010 170.035 5(M1+E2) 1 0.578 17 +152SM2 G KC=0.430 13$LC=0.1150 34$MC=0.0260 8 +152SM G 423.45 4 0.0032 5(M1+E2) 1 0.0271 8 +152SM2 G KC=0.0226 7$LC=0.0035 1$MC=7.61E-4 23 +152SM G 867.380 3 4.243 23E2+M1 -6.5 0.0035 1 +152SM2 G KC=0.00290 9$LC=4.23E-4 13$MC=9.13E-5 27 +152SM G 1112.076 3 13.41 6E2(+M1) -8.7 0.00200 6 +152SM2 G KC=0.00170 5$LC=2.38E-4 7$MC=5.11E-5 15 152SM L 1292.771 6 (2)+ 8 PS 8 152SM E 0.644 1011.2 1 -152SM2 E EAV= $CK=0.8271 16$CL=0.1344 11$CM=0.0309 6$CN=0.0076 4$CO= -152SM G 251.633 100.0671 15(E1) 0.0233 7 -152SM2 G KC=0.0198 6$LC=0.00272 8$MC=5.83E-4 17 +152SM2 E CK=0.8271 16$CL=0.1344 11$CM=0.0309 6$CN=0.0076 4 +152SM G 251.633 100.0671 15(E1) 0.0233 7 +152SM2 G KC=0.0198 6$LC=0.00272 8$MC=5.83E-4 17 152SM G 269.86 6 0.0060 24(E2) 0.0789 24 152SM2 G KC=0.0602 18$LC=0.01460 44$MC=0.00327 10 -152SM G 329.425 210.129 6 (E1) 0.0117035 -152SM2 G KC=0.0100 3$LC=1360E-6 41$MC=2.90E-4 9 -152SM G 482.31 3 0.0279 16(M1+E2) 1 0.0192 6 -152SM2 G KC=0.01610 48$LC=0.00243 7$MC=5.26E-4 16 -152SM G 926.317 150.273 4 (E2) 0.002909 -152SM2 G KC=0.00250 8$LC=3.58E-4 11$MC=7.72E-5 23 -152SM G 1170.93 110.0365 13(M1+E2) 1 0.002307 -152SM2 G KC=0.00200 6$LC=2.65E-4 8$MC=5.67E-5 17 -152SM G 1292.778 190.104 3 (E2) 1500E-645 -152SM2 G KC=1300E-6 39$LC=1.72E-4 5$MC=3.68E-5 11 +152SM G 329.425 210.129 6(E1) 0.0117035 +152SM2 G KC=0.0100 3$LC=1360E-6 41$MC=2.90E-4 9 +152SM G 482.31 3 0.0279 16(M1+E2) 1 0.0192 6 +152SM2 G KC=0.01610 48$LC=0.00243 7$MC=5.26E-4 16 +152SM G 926.317 150.273 4(E2) 0.00290 9 +152SM2 G KC=0.00250 8$LC=3.58E-4 11$MC=7.72E-5 23 +152SM G 1170.93 110.0365 13(M1+E2) 1 0.00230 7 +152SM2 G KC=0.00200 6$LC=2.65E-4 8$MC=5.67E-5 17 +152SM G 1292.778 190.104 3(E2) 1500E-645 +152SM2 G KC=1300E-6 39$LC=1.72E-4 5$MC=3.68E-5 11 152SM L 1371.691 9 4+ 1.4 PS 4 152SM E 0.869 2410.9 1 -152SM2 E EAV= $CK=0.8236 16$CL=0.1370 11$CM=0.0316 6$CN=0.0078 4$CO= -152SM G 285.98 3 0.0100 6 (E2) 0.0657 20 -152SM2 G KC=0.0506 15$LC=0.01180 35$MC=0.00263 8 +152SM2 E CK=0.8236 16$CL=0.1370 11$CM=0.0316 6$CN=0.0078 4 +152SM G 285.98 3 0.0100 6(E2) 0.0657 20 +152SM2 G KC=0.0506 15$LC=0.01180 35$MC=0.00263 8 152SM G 330.54 100.0060 17(E1) 0.0116035 -152SM2 G KC=0.0099 3$LC=0.00134 4$MC=2.88E-4 9 +152SM2 G KC=0.0099 3$LC=0.00134 4$MC=2.88E-4 9 152SM G 561.2 5 0.00108 21(E2) 0.0096029 -152SM2 G KC=0.00790 24$LC=1300E-6 39$MC=2.85E-4 9 -152SM G 664.78 5 0.010 3 (E2) 0.0063019 -152SM2 G KC=0.00520 16$LC=8.18E-4 25$MC=1.78E-4 5 -152SM G 1005.272 170.665 23 0.002608 -152SM2 G KC=0.00220 7$LC=3.11E-4 9$MC=6.69E-5 20 -152SM G 1249.938 130.186 3 E2 1600E-648 -152SM2 G KC=1400E-6 42$LC=1.84E-4 6$MC=3.95E-5 12 +152SM2 G KC=0.00790 24$LC=1300E-6 39$MC=2.85E-4 9 +152SM G 664.78 5 0.010 3(E2) 0.0063019 +152SM2 G KC=0.00520 16$LC=8.18E-4 25$MC=1.78E-4 5 +152SM G 1005.272 170.665 23 0.00260 8 +152SM2 G KC=0.00220 7$LC=3.11E-4 9$MC=6.69E-5 20 +152SM G 1249.938 130.186 3E2 1600E-648 +152SM2 G KC=1400E-6 42$LC=1.84E-4 6$MC=3.95E-5 12 152SM L 1529.8073 162- 27 FS 152SM E 24.72 119.1 -152SM2 E EAV= $CK=0.8109 17$CL=0.1465 12$CM=0.0341 7$CN=0.0085 4$CO= -152SM G 295.9387 170.442 3 E1 0.0153046 -152SM2 G KC=0.01310 39$LC=0.00178 5$MC=3.81E-4 11 -152SM G 443.965 3 2.80 2 E1(+M2) 0.0060018 +152SM2 E CK=0.8109 17$CL=0.1465 12$CM=0.0341 7$CN=0.0085 4 +152SM G 295.9387 170.442 3E1 0.0153046 +152SM2 G KC=0.01310 39$LC=0.00178 5$MC=3.81E-4 11 +152SM G 443.965 3 2.80 2E1(+M2) 0.0060018 152SM2 G KC=0.00520 16$LC=6.35E-4 19$MC=1390E-7 42 152SM G 488.6792 200.4139 24M1+E2 0.0140042 -152SM2 G KC=0.01150 34$LC=0.00196 6$MC=4.29E-4 13 -152SM G 566.442 5 0.131 4 M1+E2 -0.74 0.0138041 -152SM2 G KC=0.01170 35$LC=0.00166 5$MC=3.57E-4 11 -152SM G 719.349 4 0.059 7 (E1) 0.002006 -152SM2 G KC=0.00170 5$LC=2.22E-4 7$MC=4.73E-5 14 -152SM G 1408.013 3 20.85 8 E1(+M2) 6.00E-418 +152SM2 G KC=0.01150 34$LC=0.00196 6$MC=4.29E-4 13 +152SM G 566.442 5 0.131 4M1+E2 -0.74 0.0138041 +152SM2 G KC=0.01170 35$LC=0.00166 5$MC=3.57E-4 11 +152SM G 719.349 4 0.059 7(E1) 0.00200 6 +152SM2 G KC=0.00170 5$LC=2.22E-4 7$MC=4.73E-5 14 +152SM G 1408.013 3 20.85 8E1(+M2) 6.00E-418 152SM2 G KC=5.00E-4 15$LC=6.15E-5 18$MC=1310E-8 39 152SM L 1579.365 3 3- 152SM E 2.068 1210 -152SM2 E EAV= $CK=0.8036 17$CL=0.1519 12$CM=0.0356 7$CN=0.0088 5$CO= -152SM G 207.6 3 0.0059 4 (E1) 0.0385 12 +152SM2 E CK=0.8036 17$CL=0.1519 12$CM=0.0356 7$CN=0.0088 5 +152SM G 207.6 3 0.0059 4(E1) 0.0385 12 152SM2 G KC=0.0327 10$LC=0.00455 14$MC=9.75E-4 29 152SM G 493.508 200.0278 30(E1) 0.0045014 152SM2 G KC=0.00380 11$LC=5.09E-4 15$MC=1090E-7 33 -152SM G 538.29 6 0.0042 6 (M1+E2) 1 0.0145044 -152SM2 G KC=0.01220 37$LC=0.00180 5$MC=3.89E-4 12 -152SM G 556.56 3 0.0177 11(E1) 0.0034 1 -152SM2 G KC=0.00290 9$LC=3.87E-4 12$MC=8.26E-5 25 -152SM G 616.05 3 0.0092 6 (E2) 0.0076023 -152SM2 G KC=0.00630 19$LC=0.00100 3$MC=2.19E-4 7 -152SM G 768.944 9 0.088 3 (E1) 0.001705 -152SM2 G KC=1500E-6 45$LC=1.93E-4 6$MC=4.12E-5 12 -152SM G 1212.948 111.416 9 E1 7.00E-421 -152SM2 G KC=6.00E-4 18$LC=8.02E-5 24$MC=1.70E-5 5 -152SM G 1457.643 110.498 4 E1 5.00E-415 +152SM G 538.29 6 0.0042 6(M1+E2) 1 0.0145044 +152SM2 G KC=0.01220 37$LC=0.00180 5$MC=3.89E-4 12 +152SM G 556.56 3 0.0177 11(E1) 0.0034 1 +152SM2 G KC=0.00290 9$LC=3.87E-4 12$MC=8.26E-5 25 +152SM G 616.05 3 0.0092 6(E2) 0.0076023 +152SM2 G KC=0.00630 19$LC=0.00100 3$MC=2.19E-4 7 +152SM G 768.944 9 0.088 3(E1) 0.00170 5 +152SM2 G KC=1500E-6 45$LC=1.93E-4 6$MC=4.12E-5 12 +152SM G 1212.948 111.416 9E1 7.00E-421 +152SM2 G KC=6.00E-4 18$LC=8.02E-5 24$MC=1.70E-5 5 +152SM G 1457.643 110.498 4E1 5.00E-415 152SM2 G KC=5.00E-4 15$LC=5.80E-5 17$MC=1230E-8 37 152SM L 1612.94 6 + 152SM E 0.0208 1411.9 -152SM2 E EAV= $CK=0.7966 18$CL=0.1571 13$CM=0.0370 7$CN=0.0092 5$CO= -152SM G 571.83 8 0.0048 8 -152SM G 906.01 6 0.016 1 +152SM2 E CK=0.7966 18$CL=0.1571 13$CM=0.0370 7$CN=0.0092 5 +152SM G 571.83 8 0.0048 8 +152SM G 906.01 6 0.016 1 152SM L 1649.910 8 2- 152SM E 0.889 1410.1 -152SM2 E EAV= $CK=0.7859 19$CL=0.1651 13$CM=0.0392 7$CN=0.0098 5$CO= -152SM G 357.26 5 0.0040 5 (E1) 0.0096029 -152SM2 G KC=0.00820 25$LC=1110E-6 33$MC=2.37E-4 7 -152SM G 416.048 8 0.1090 17(E1) 0.0067 2 +152SM2 E CK=0.7859 19$CL=0.1651 13$CM=0.0392 7$CN=0.0098 5 +152SM G 357.26 5 0.0040 5(E1) 0.0096029 +152SM2 G KC=0.00820 25$LC=1110E-6 33$MC=2.37E-4 7 +152SM G 416.048 8 0.1090 17(E1) 0.0067 2 152SM2 G KC=0.00570 17$LC=7.62E-4 23$MC=1630E-7 49 -152SM G 563.990 7 0.457 13E1 0.0033 1 -152SM2 G KC=0.00280 8$LC=3.76E-4 11$MC=8.02E-5 24 +152SM G 563.990 7 0.457 13E1 0.0033 1 +152SM2 G KC=0.00280 8$LC=3.76E-4 11$MC=8.02E-5 24 152SM G 686.61 5 0.0200 17(M1+E2) 1 0.0079024 -152SM2 G KC=0.0067 2$LC=9.54E-4 29$MC=2.05E-4 6 -152SM G 839.36 4 0.0160 8 (E1) 1500E-645 +152SM2 G KC=0.0067 2$LC=9.54E-4 29$MC=2.05E-4 6 +152SM G 839.36 4 0.0160 8(E1) 1500E-645 152SM2 G KC=1200E-6 36$LC=1620E-7 49$MC=3.45E-5 10 -152SM G 1528.103 180.281 5 E1 5.00E-415 -152SM2 G KC=4.00E-4 12$LC=$MC= +152SM G 1528.103 180.281 5E1 5.00E-415 +152SM2 G KC=4.00E-4 12 152SM L 1730.241 22(3)- 152SM E 0.0422 1210.9 -152SM2 E EAV= $CK=0.7339 23$CL=0.2036 16$CM=0.0499 9$CN=0.0125 7$CO= -152SM G 496.39 3 0.0049 5 (E1) 0.0044013 +152SM2 E CK=0.7339 23$CL=0.2036 16$CM=0.0499 9$CN=0.0125 7 +152SM G 496.39 3 0.0049 5(E1) 0.0044013 152SM2 G KC=0.00380 11$LC=5.02E-4 15$MC=1070E-7 32 -152SM G 644.37 5 0.0063 6 (E1) 0.002508 -152SM2 G KC=0.00210 6$LC=2.80E-4 8$MC=5.98E-5 18 -152SM G 1363.77 5 0.0256 8 M1(+E2) 0.002006 -152SM2 G KC=0.00170 5$LC=2.22E-4 7$MC=4.74E-5 14 -152SM G 1608.36 8 0.0053 3 (E1) 4.00E-412 -152SM2 G KC=4.00E-4 12$LC=$MC= +152SM G 644.37 5 0.0063 6(E1) 0.00250 8 +152SM2 G KC=0.00210 6$LC=2.80E-4 8$MC=5.98E-5 18 +152SM G 1363.77 5 0.0256 8M1(+E2) 0.00200 6 +152SM2 G KC=0.00170 5$LC=2.22E-4 7$MC=4.74E-5 14 +152SM G 1608.36 8 0.0053 3(E1) 4.00E-412 +152SM2 G KC=4.00E-4 12 152SM L 1757.151 132,3+ -152SM E 0.041 3 10.7 1 -152SM2 E EAV= $CK=0.6903 28$CL=0.2358 20$CM=0.0591 11$CN=0.0149 8$CO= -152SM G 385.69 200.0050 6 (M1+E2) 1 0.0348 10 -152SM2 G KC=0.0290 9$LC=0.00459 14$MC=9.99E-4 30 +152SM E 0.041 310.7 1 +152SM2 E CK=0.6903 28$CL=0.2358 20$CM=0.0591 11$CN=0.0149 8 +152SM G 385.69 200.0050 6(M1+E2) 1 0.0348 10 +152SM2 G KC=0.0290 9$LC=0.00459 14$MC=9.99E-4 30 152SM G 523.13 5 0.0113 21(M1+E2) 0.0156047 -152SM2 G KC=0.01310 39$LC=0.00194 6$MC=4.21E-4 13 +152SM2 G KC=0.01310 39$LC=0.00194 6$MC=4.21E-4 13 152SM G 671.155 170.0194 13M1+E2 0.14 0.0105032 -152SM2 G KC=0.00900 27$LC=1220E-6 37$MC=2.60E-4 8 -152SM G 1390.36 160.0048 6 (M1+E2) 1 1600E-648 -152SM2 G KC=1400E-6 42$LC=1.80E-4 5$MC=3.85E-5 12 -152SM G 1635.2 5 0.00015 5 (M1+E2) 1 0.001003 -152SM2 G KC=0.00100 3$LC=$MC= +152SM2 G KC=0.00900 27$LC=1220E-6 37$MC=2.60E-4 8 +152SM G 1390.36 160.0048 6(M1+E2) 1 1600E-648 +152SM2 G KC=1400E-6 42$LC=1.80E-4 5$MC=3.85E-5 12 +152SM G 1635.2 5 0.00015 5(M1+E2) 1 0.00100 3 +152SM2 G KC=0.00100 3 152SM L 1769.10 3 2+ -152SM E 0.068 5 10.3 1 -152SM2 E EAV= $CK=0.6586 33$CL=0.2591 24$CM=0.0657 12$CN=0.0166 9$CO= -152SM G 239.42 170.008 3 (E1) 0.0265 8 -152SM2 G KC=0.0225 7$LC=0.00311 9$MC=6.65E-4 20 -152SM G 727.99 140.0106 13(E1) 0.001936 -152SM2 G KC=0.00166 5$LC=2.16E-4 6$MC=4.61E-5 14 -152SM G 805.70 7 0.0125 8 (E1) 1600E-648 -152SM2 G KC=1400E-6 42$LC=1.76E-4 5$MC=3.74E-5 11 +152SM E 0.068 510.3 1 +152SM2 E CK=0.6586 33$CL=0.2591 24$CM=0.0657 12$CN=0.0166 9 +152SM G 239.42 170.008 3(E1) 0.0265 8 +152SM2 G KC=0.0225 7$LC=0.00311 9$MC=6.65E-4 20 +152SM G 727.99 140.0106 13(E1) 0.00193 6 +152SM2 G KC=0.00166 5$LC=2.16E-4 6$MC=4.61E-5 14 +152SM G 805.70 7 0.0125 8(E1) 1600E-648 +152SM2 G KC=1400E-6 42$LC=1.76E-4 5$MC=3.74E-5 11 152SM G 958.63 5 0.0210 19(M1+E2) 0.0036011 -152SM2 G KC=0.00310 9$LC=$MC= -152SM G 1647.41 140.0064 4 (E2) 8.00E-424 -152SM2 G KC=8.00E-4 24$LC=$MC= -152SM G 1769.09 5 0.0092 3 (E2) 7.00E-421 -152SM2 G KC=7.00E-4 21$LC=$MC= +152SM2 G KC=0.00310 9 +152SM G 1647.41 140.0064 4(E2) 8.00E-424 +152SM2 G KC=8.00E-4 24 +152SM G 1769.09 5 0.0092 3(E2) 7.00E-421 +152SM2 G KC=7.00E-4 21 152GD 152EU B- DECAY (13.522 Y) 152GD C References: 1977La19 -152GD T Auger electrons and ^X ray energies and emission intensities: -152GD T {U Energy (keV)} {U Intensity } {U Line } +152GD T Auger electrons and X ray energies and emission intensities: +152GD T {U Energy (keV)} {U Intensity} {U Line} 152GD T -152GD T 42.3093 0.243 7 XKA2 -152GD T 42.9967 0.437 12 XKA1 +152GD T 42.3093 0.243 7 XKA2 +152GD T 42.9967 0.437 12 XKA1 152GD T -152GD T 48.556 |] XKB3 -152GD T 48.697 |] 0.138 4 XKB1 -152GD T 49.053 |] XKB5II +152GD T 48.556 |] XKB3 +152GD T 48.697 |] 0.138 4 XKB1 +152GD T 49.053 |] XKB5II 152GD T -152GD T 49.961 |] XKB2 -152GD T 50.099 |] 0.0363 13 XKB4 -152GD T 50.219 |] XKO23 +152GD T 49.961 |] XKB2 +152GD T 50.099 |] 0.0363 13 XKB4 +152GD T 50.219 |] XKO23 152GD T -152GD T 5.3611-8.104 0.177 5 XL (total) +152GD T 5.3611-8.104 0.177 5 XL (total) 152GD T 5.3611 XLL 152GD T 6.024-6.0578 XLA 152GD T 6.0483 XLC 152GD T 6.6848-7.1888 XLB 152GD T 7.5509-8.104 XLG 152GD T -152GD T 33.31-35.562 |] KLL AUGER -152GD T 39.907-42.976 |] 0.062 4 ^KLX AUGER -152GD T 46.48-50.2 |] KXY AUGER -152GD T 3.4-8.3 0.800 14 L AUGER +152GD T 33.31-35.562 |] KLL AUGER +152GD T 39.907-42.976 |] 0.062 4 KLX AUGER +152GD T 46.48-50.2 |] KXY AUGER +152GD T 3.4-8.3 0.800 14 L AUGER 152EU P 0.0 3- 13.522 Y 16 1818.8 11 152GD N 3.584E0 3.584E0 0.279 3.584E0 -152GD G 237.31 5 0.0025 8 (E1) 0.0272 8 -152GD G 320.03 150.0017 6 +152GD G 237.31 5 0.0025 8(E1) 0.0272 8 +152GD G 320.03 150.0017 6 152GD G 379.37 6 0.00083 21 152GD G 391.32 140.00125 21 152GD G 406.74 150.00083 21 152GD G 535.4 4 0.0060 16(M1+E2) 1 0.0147044 152GD G 595.61 1 0.0031 17 -152GD G 683.32 110.0031 8 +152GD G 683.32 110.0031 8 152GD G 696.87 190.0029 10 152GD G 735.4 1 0.0058 10 -152GD G 756.12 9 0.0054 8 +152GD G 756.12 9 0.0054 8 152GD G 896.58 9 0.0669 21 152GD G 1001.1 3 0.0046 10 -152GD G 1084 1 0.244 8 -152GD G 1139 1 0.0013 3 -152GD G 1674.30 6 0.0060 8 +152GD G 1084 1 0.244 8 +152GD G 1139 1 0.0013 3 +152GD G 1674.30 6 0.0060 8 152GD L 0 0+ STABLE 152GD L 344.2798 122+ 32.4 PS 17 152GD B 1474.5 118.17 11 12.1 1 152GDS B EAV=535.4 5 152GD G 344.2785 1226.59 12E2 0.0399 12 -152GD2 G KC=0.0311 9$LC=0.00687 21$MC=1550E-6 46 +152GD2 G KC=0.0311 9$LC=0.00687 21$MC=1550E-6 46 152GD L 615.553 5 0+ -152GD G 271.131 8 0.078 3 E2 0.0831 25 +152GD G 271.131 8 0.078 3E2 0.0831 25 152GD2 G KC=0.0621 19$LC=0.01620 49$MC=0.00370 11 152GD L 755.3964 174+ 7.3 PS 4 152GD B 1063.4 110.904 14 12.5 1 152GDS B EAV=364.6 5 -152GD G 411.1165 122.238 10E2 0.0239 7 -152GD2 G KC=0.0190 6$LC=0.00379 11$MC=8.49E-4 25 +152GD G 411.1165 122.238 10E2 0.0239 7 +152GD2 G KC=0.0190 6$LC=0.00379 11$MC=8.49E-4 25 152GD L 930.562 3 2+ 7.3 PS 6 -152GD B 888.2 110.303 7 12.7 1 +152GD B 888.2 110.303 7 12.7 1 152GDS B EAV=295.1 5 152GD G 315.174 170.0496 17(E2) 0.0521 16 -152GD2 G KC=0.0400 12$LC=0.00938 28$MC=0.00212 6 -152GD G 586.265 3 0.462 4 E2+M1+ -4.9 0.0243 9 -152GD2 G KC=0.0202 16$LC=$MC= -152GD G 930.58 150.0729 19(E2) 0.0032 1 -152GD2 G KC=0.00270 8$LC=4.00E-4 12$MC=8.72E-5 26 +152GD2 G KC=0.0400 12$LC=0.00938 28$MC=0.00212 6 +152GD G 586.265 3 0.462 4E2+M1+ -4.9 0.0243 9 +152GD2 G KC=0.0202 16 +152GD G 930.58 150.0729 19(E2) 0.0032 1 +152GD2 G KC=0.00270 8$LC=4.00E-4 12$MC=8.72E-5 26 152GD L 1047.51 6 0+ -152GD G 703.25 6 0.0018 9 (E2) 0.0060018 -152GD2 G KC=0.00500 15$LC=7.96E-4 24$MC=1.75E-4 5 +152GD G 703.25 6 0.0018 9(E2) 0.0060018 +152GD2 G KC=0.00500 15$LC=7.96E-4 24$MC=1.75E-4 5 152GD L 1109.076 5 2+ -152GD B 709.7 110.245 8 12.4 1 +152GD B 709.7 110.245 8 12.4 1 152GDS B EAV=226.9 5 -152GD G 493.508 200.009 2 (E2) 0.0145044 -152GD2 G KC=0.01180 35$LC=0.00214 6$MC=4.76E-4 14 -152GD G 764.900 9 0.190 4 E2+M1 3.8 0.0052016 +152GD G 493.508 200.009 2(E2) 0.0145044 +152GD2 G KC=0.01180 35$LC=0.00214 6$MC=4.76E-4 14 +152GD G 764.900 9 0.190 4E2+M1 3.8 0.0052016 152GD2 G KC=0.00440 13$LC=6.69E-4 20$MC=1460E-7 44 -152GD G 1109.174 120.186 4 E2 0.002207 -152GD2 G KC=0.00190 6$LC=2.69E-4 8$MC=5.84E-5 18 +152GD G 1109.174 120.186 4E2 0.00220 7 +152GD2 G KC=0.00190 6$LC=2.69E-4 8$MC=5.84E-5 18 152GD L 1123.184 2 3- 152GD B 695.6 1113.80 15 10.6 152GDS B EAV=221.7 4 -152GD G 192.6 4 0.0068 2 (E1) 0.0504 15 -152GD2 G KC=0.0426 13$LC=0.00609 18$MC=0.00132 4 -152GD G 367.7891 200.862 5 E1 0.0097029 -152GD2 G KC=0.00830 25$LC=1130E-6 34$MC=2.45E-4 7 -152GD G 778.9045 2412.97 6 E1 0.001906 -152GD2 G KC=1600E-6 48$LC=2.09E-4 6$MC=4.50E-5 14 +152GD G 192.6 4 0.0068 2(E1) 0.0504 15 +152GD2 G KC=0.0426 13$LC=0.00609 18$MC=0.00132 4 +152GD G 367.7891 200.862 5E1 0.0097029 +152GD2 G KC=0.00830 25$LC=1130E-6 34$MC=2.45E-4 7 +152GD G 778.9045 2412.97 6E1 0.00190 6 +152GD2 G KC=1600E-6 48$LC=2.09E-4 6$MC=4.50E-5 14 152GD L 1282.267 184+ -152GD B 536.5 110.037 8 12.8 1 +152GD B 536.5 110.037 8 12.8 1 152GDS B EAV=164.1 4 152GD G 351.66 4 0.0140 22E2 0.0375 11 -152GD2 G KC=0.0293 9$LC=0.00639 19$MC=1440E-6 43 -152GD G 526.881 200.0129 6 M1+E2+ 0.094 8 -152GD2 G KC=0.084 9$LC=$MC= +152GD2 G KC=0.0293 9$LC=0.00639 19$MC=1440E-6 43 +152GD G 526.881 200.0129 6M1+E2+ 0.094 8 +152GD2 G KC=0.084 9 152GD L 1314.71 201- -152GD B 504.1 110.0048 7 13.6 2 +152GD B 504.1 110.0048 7 13.6 2 152GDS B EAV=152.7 4 -152GD G 1314.7 2 0.0048 6 E1 7.00E-421 -152GD2 G KC=6.00E-4 18$LC=7.73E-5 23$MC=1.66E-5 5 +152GD G 1314.7 2 0.0048 6E1 7.00E-421 +152GD2 G KC=6.00E-4 18$LC=7.73E-5 23$MC=1.66E-5 5 152GD L 1318.50 3 2+ 152GD B 500.3 110.0267 17 12.9 1 152GDS B EAV=151.4 4 152GD G 387.90 8 0.00296 21(M1+E2+) 0.45 11 -152GD2 G KC=0.38 9$LC=$MC= -152GD G 703.25 6 0.0035 9 (E2) 0.0060018 -152GD2 G KC=0.00500 15$LC=7.96E-4 24$MC=1.75E-4 5 -152GD G 974.09 4 0.0138 8 M1+E2+ 1 0.0056 6 -152GD2 G KC=0.0048 5$LC=$MC= +152GD2 G KC=0.38 9 +152GD G 703.25 6 0.0035 9(E2) 0.0060018 +152GD2 G KC=0.00500 15$LC=7.96E-4 24$MC=1.75E-4 5 +152GD G 974.09 4 0.0138 8M1+E2+ 1 0.0056 6 +152GD2 G KC=0.0048 5 152GD L 1434.025 4 3+ -152GD B 384.8 112.44 3 10.5 +152GD B 384.8 112.44 3 10.5 152GDS B EAV=112.3 4 152GD G 324.83 3 0.0738 15M1+E2 1 0.0636 19 -152GD2 G KC=0.0521 16$LC=0.00897 27$MC=0.00199 6 +152GD2 G KC=0.0521 16$LC=0.00897 27$MC=0.00199 6 152GD G 503.474 5 0.1533 18(E2) 0.0138041 -152GD2 G KC=0.01120 34$LC=0.00202 6$MC=4.48E-4 13 -152GD G 678.623 5 0.470 4 E2+M1 4.1 0.0069021 -152GD2 G KC=0.00570 17$LC=9.00E-4 27$MC=1.98E-4 6 -152GD G 1089.737 5 1.73 1 (M1)+E2 0.002307 -152GD2 G KC=0.00200 6$LC=$MC= +152GD2 G KC=0.01120 34$LC=0.00202 6$MC=4.48E-4 13 +152GD G 678.623 5 0.470 4E2+M1 4.1 0.0069021 +152GD2 G KC=0.00570 17$LC=9.00E-4 27$MC=1.98E-4 6 +152GD G 1089.737 5 1.73 1(M1)+E2 0.00230 7 +152GD2 G KC=0.00200 6 152GD L 1550.19 3 4+ 152GD B 268.6 110.0536 18 11.7 1 152GDS B EAV=75.2 4 -152GD G 440.86 100.0133 10(E2) 0.0197 6 -152GD2 G KC=0.01580 47$LC=0.00303 9$MC=6.77E-4 20 +152GD G 440.86 100.0133 10(E2) 0.0197 6 +152GD2 G KC=0.01580 47$LC=0.00303 9$MC=6.77E-4 20 152GD G 794.81 3 0.0263 10M1(+E2) -0.4 0.0077023 -152GD2 G KC=0.0065 2$LC=9.05E-4 27$MC=1.96E-4 6 -152GD G 1206.11 150.0135 8 (E2) 0.001906 -152GD2 G KC=1600E-6 48$LC=2.25E-4 7$MC=4.87E-5 15 +152GD2 G KC=0.0065 2$LC=9.05E-4 27$MC=1.96E-4 6 +152GD G 1206.11 150.0135 8(E2) 0.00190 6 +152GD2 G KC=1600E-6 48$LC=2.25E-4 7$MC=4.87E-5 15 152GD L 1605.255 4 2+ -152GD B 213.5 110.101 3 11.1 1 +152GD B 213.5 110.101 3 11.1 1 152GDS B EAV=58.6 4 -152GD G 482.31 3 0.00139 6 (E1) 0.0051015 +152GD G 482.31 3 0.00139 6(E1) 0.0051015 152GD2 G KC=0.00440 13$LC=5.94E-4 18$MC=1280E-7 38 -152GD G 496.39 3 0.0042 4 M1+E2+ 0.097 11 -152GD2 G KC=0.082 9$LC=$MC= -152GD G 557.91 170.0044 7 (E2) 0.0106032 +152GD G 496.39 3 0.0042 4M1+E2+ 0.097 11 +152GD2 G KC=0.082 9 +152GD G 557.91 170.0044 7(E2) 0.0106032 152GD2 G KC=0.00870 26$LC=1490E-6 45$MC=3.31E-4 10 152GD G 674.677 3 0.0171 18E2+M1 0.0076023 -152GD2 G KC=0.00630 19$LC=9.80E-4 29$MC=2.15E-4 6 -152GD G 990.19 3 0.0315 13(E2) 0.003009 -152GD2 G KC=0.00240 7$LC=3.47E-4 10$MC=7.55E-5 23 -152GD G 1261.343 230.0336 11M1 0.002708 -152GD2 G KC=0.00230 7$LC=3.13E-4 9$MC=6.76E-5 20 -152GD G 1605.61 7 0.0081 4 (E2) 9.00E-427 -152GD2 G KC=9.00E-4 27$LC=$MC= +152GD2 G KC=0.00630 19$LC=9.80E-4 29$MC=2.15E-4 6 +152GD G 990.19 3 0.0315 13(E2) 0.00300 9 +152GD2 G KC=0.00240 7$LC=3.47E-4 10$MC=7.55E-5 23 +152GD G 1261.343 230.0336 11M1 0.00270 8 +152GD2 G KC=0.00230 7$LC=3.13E-4 9$MC=6.76E-5 20 +152GD G 1605.61 7 0.0081 4(E2) 9.00E-427 +152GD2 G KC=9.00E-4 27 152GD L 1643.395 4 2- 152GD B 175.4 111.826 21 9.6 152GDS B EAV=47.4 4 -152GD G 209.41 130.0055 5 (E1) 0.0404 12 +152GD G 209.41 130.0055 5(E1) 0.0404 12 152GD2 G KC=0.0342 10$LC=0.00486 15$MC=1050E-6 32 -152GD G 520.227 5 0.0536 13(M1+E2) 1 0.0181 5 -152GD2 G KC=0.01520 46$LC=0.00230 7$MC=5.04E-4 15 +152GD G 520.227 5 0.0536 13(M1+E2) 1 0.0181 5 +152GD2 G KC=0.01520 46$LC=0.00230 7$MC=5.04E-4 15 152GD G 534.245 7 0.0368 19(E1) 0.0041012 -152GD2 G KC=0.0035 1$LC=4.70E-4 14$MC=1.01E-4 3 -152GD G 712.843 6 0.0961 19(E1) 0.002207 -152GD2 G KC=0.00190 6$LC=2.51E-4 8$MC=5.41E-5 16 -152GD G 1299.142 8 1.633 9 E1(+M2) 0.043 7.00E-421 -152GD2 G KC=6.00E-4 18$LC=8.03E-5 24$MC=1.72E-5 5 -152GD G 1643.6 1 0.0015 4 (M2) 0.0032 1 -152GD2 G KC=0.00280 8$LC=$MC= +152GD2 G KC=0.0035 1$LC=4.70E-4 14$MC=1.01E-4 3 +152GD G 712.843 6 0.0961 19(E1) 0.00220 7 +152GD2 G KC=0.00190 6$LC=2.51E-4 8$MC=5.41E-5 16 +152GD G 1299.142 8 1.633 9E1(+M2) 0.043 7.00E-421 +152GD2 G KC=6.00E-4 18$LC=8.03E-5 24$MC=1.72E-5 5 +152GD G 1643.6 1 0.0015 4(M2) 0.0032 1 +152GD2 G KC=0.00280 8 152GD L 1692.447 153+ 152GD B 126.4 110.0203 11 11.1 152GDS B EAV=33.4 3 -152GD G 937.050 150.0027 6 (M1+E2) 1 0.0043013 +152GD G 937.050 150.0027 6(M1+E2) 1 0.0043013 152GD2 G KC=0.00370 11$LC=5.16E-4 15$MC=1120E-7 34 -152GD G 1348.10 7 0.0175 8 E2+(M1) -13 1600E-648 -152GD2 G KC=1300E-6 39$LC=1.79E-4 5$MC=3.87E-5 12 +152GD G 1348.10 7 0.0175 8E2+(M1) -13 1600E-648 +152GD2 G KC=1300E-6 39$LC=1.79E-4 5$MC=3.87E-5 12 diff --git a/HEN_HOUSE/spectra/lnhb/Eu-154.txt b/HEN_HOUSE/spectra/lnhb/Eu-154.txt index ccaf70da0..c16aca015 100644 --- a/HEN_HOUSE/spectra/lnhb/Eu-154.txt +++ b/HEN_HOUSE/spectra/lnhb/Eu-154.txt @@ -1,443 +1,363 @@ 154SM 154EU EC DECAY (8.601 Y) 154SM C References: 1952Ka26, 1977La19 -154SM T Auger electrons and ^X ray energies and emission intensities: -154SM T {U Energy (keV)} {U Intensity } {U Line } +154SM T Auger electrons and X ray energies and emission intensities: +154SM T {U Energy (keV)} {U Intensity} {U Line} 154SM T -154SM T 39.5229 0.006 4 XKA2 -154SM T 40.1186 0.010 8 XKA1 +154SM T 39.5229 0.006 4 XKA2 +154SM T 40.1186 0.010 8 XKA1 154SM T -154SM T 45.289 |] XKB3 -154SM T 45.413 |] 0.003 2 XKB1 -154SM T 45.731 |] XKB5II +154SM T 45.289 |] XKB3 +154SM T 45.413 |] 0.003 2 XKB1 +154SM T 45.731 |] XKB5II 154SM T -154SM T 46.575 |] XKB2 -154SM T 46.705 |] 0.001 XKB4 -154SM T 46.813 |] XKO23 +154SM T 46.575 |] XKB2 +154SM T 46.705 |] 0.001 XKB4 +154SM T 46.813 |] XKO23 154SM T -154SM T 4.99-7.49 0.0044 20 XL (total) +154SM T 4.99-7.49 0.0044 20 XL (total) 154SM T 4.99 XLL 154SM T -7.49 XLG 154SM T -154SM T 31.19-33.22 |] KLL AUGER -154SM T 37.3-40.18 |] 0.0016 13 ^KLX AUGER -154SM T 45.3-46.23 |] KXY AUGER -154SM T 3.2-7.6 0.023 13 L AUGER +154SM T 31.19-33.22 |] KLL AUGER +154SM T 37.3-40.18 |] 0.0016 13 KLX AUGER +154SM T 45.3-46.23 |] KXY AUGER +154SM T 3.2-7.6 0.023 13 L AUGER 154EU P 0.0 3- 8.601 Y 4 717.3 11 154SM N 5.556E3 5.556E3 0.00018 5.556E3 -154SM G 159.9 0.0010 5 -154SM G 195.5 5 0.002 1 -154SM G 197 0.0016 2 -154SM G 274.0 5 0.0039 2 -154SM G 296 1 0.0014 9 0.0166 3 -154SM G 308.2 0.0024 6 -154SM G 320 1 0.0010 7 -154SM G 414.3 0.0049 6 -154SM G 422.1 0.0022 9 +154SM G 159.9 0.0010 5 +154SM G 195.5 5 0.002 1 +154SM G 197 0.0016 2 +154SM G 274.0 5 0.0039 2 +154SM G 296 1 0.0014 9 0.0166 3 +154SM G 308.2 0.0024 6 +154SM G 320 1 0.0010 7 +154SM G 414.3 0.0049 6 +154SM G 422.1 0.0022 9 154SM G 435.9 0.0038 10 -154SM G 484.64 0.0039 2 -154SM G 510 0.059 7 -154SM G 512 0.032 7 +154SM G 484.64 0.0039 2 +154SM G 510 0.059 7 +154SM G 512 0.032 7 154SM G 737.6 0.0063 24 -154SM G 830.3 0.008 3 -154SM G 919.24 0.012 1 +154SM G 830.3 0.008 3 +154SM G 919.24 0.012 1 154SM G 928.4 0.0045 21 154SM G 984.5 0.0094 21 -154SM G 1033.4 0.0119 7 -154SM G 1049.4 1 0.0172 8 +154SM G 1033.4 0.0119 7 +154SM G 1049.4 1 0.0172 8 154SM G 1072.2 0.0035 14 154SM G 1124.2 0.0069 10 -154SM G 1153.1 5 0.011 4 +154SM G 1153.1 5 0.011 4 154SM G 1216.8 0.0033 10 -154SM G 1232.1 5 0.008 5 -154SM G 1316.4 3 0.017 4 -154SM G 1554 0.0011 5 +154SM G 1232.1 5 0.008 5 +154SM G 1316.4 3 0.017 4 +154SM G 1554 0.0011 5 154SM L 0 0+ STABLE 154SM L 81.98 2+ 3 NS 154SM E 0.013 1312.7 1 -154SM2 E EAV= $CK=0.8289 16$CL=0.1330 11$CM=0.0305 6$CN= $CO= +154SM2 E CK=0.8289 16$CL=0.1330 11$CM=0.0305 6 154SM G 81.99 2 0.0031 21E2 4.93 10 -154SM2 G KC=1.98 4$LC=2.28 5$MC=0.532 11 +154SM2 G KC=1.98 4$LC=2.28 5$MC=0.532 11 154SM L 266.79 4+ 172 PS -154SM E 0.0047 8 12.9 1 -154SM2 E EAV= $CK=0.8205 16$CL=0.1393 11$CM=0.0322 6$CN= $CO= -154SM G 184.72 0.0037 7 E2 0.275 6 -154SM2 G KC=0.193 4$LC=0.0642 13$MC=0.0146 3 +154SM E 0.0047 812.9 1 +154SM2 E CK=0.8205 16$CL=0.1393 11$CM=0.0322 6 +154SM G 184.72 0.0037 7E2 0.275 6 +154SM2 G KC=0.193 4$LC=0.0642 13$MC=0.0146 3 154SM L 543.73 6+ 23 PS 154GD 154EU B- DECAY (8.601 Y) 154GD C References: 1952Ka26, 1977La19 -154GD T Auger electrons and ^X ray energies and emission intensities: -154GD T {U Energy (keV)} {U Intensity } {U Line } +154GD T Auger electrons and X ray energies and emission intensities: +154GD T {U Energy (keV)} {U Intensity} {U Line} 154GD T -154GD T 42.3093 7.2 2 XKA2 -154GD T 42.9967 13.0 3 XKA1 +154GD T 42.3093 7.2 2 XKA2 +154GD T 42.9967 13.0 3 XKA1 154GD T -154GD T 48.556 |] XKB3 -154GD T 48.697 |] 4.1 1 XKB1 -154GD T 49.053 |] XKB5II +154GD T 48.556 |] XKB3 +154GD T 48.697 |] 4.1 1 XKB1 +154GD T 49.053 |] XKB5II 154GD T -154GD T 49.961 |] XKB2 -154GD T 50.099 |] 1.08 3 XKB4 -154GD T 50.219 |] XKO23 +154GD T 49.961 |] XKB2 +154GD T 50.099 |] 1.08 3 XKB4 +154GD T 50.219 |] XKO23 154GD T -154GD T 5.3611-8.104 7.1 3 XL (total) +154GD T 5.3611-8.104 7.1 3 XL (total) 154GD T 5.3611 XLL 154GD T 6.024-6.0578 XLA 154GD T 6.0483 XLC 154GD T 6.6848-7.1888 XLB 154GD T 7.5509-8.104 XLG 154GD T -154GD T 33.32-35.58 |] KLL AUGER -154GD T 39.98-42.86 |] 1.86 12 ^KLX AUGER -154GD T 47.98-48.91 |] KXY AUGER -154GD T 3.4-8.3 33.2 6 L AUGER +154GD T 33.32-35.58 |] KLL AUGER +154GD T 39.98-42.86 |] 1.86 12 KLX AUGER +154GD T 47.98-48.91 |] KXY AUGER +154GD T 3.4-8.3 33.2 6 L AUGER 154EU P 0.0 3- 8.601 Y 4 1968.4 11 154GD N 1.00E0 1.00E0 0.99982 1.00E0 -154GD G 159.9 0.0010 5 -154GD G 195.5 5 0.002 1 -154GD G 197 0.0016 2 -154GD G 274.0 5 0.0039 2 -154GD G 296 1 0.0014 9 0.0166 3 -154GD G 308.2 0.0024 6 -154GD G 320 1 0.0010 7 -154GD G 414.3 0.0049 6 -154GD G 422.1 0.0022 9 +154GD G 159.9 0.0010 5 +154GD G 195.5 5 0.002 1 +154GD G 197 0.0016 2 +154GD G 274.0 5 0.0039 2 +154GD G 296 1 0.0014 9 0.0166 3 +154GD G 308.2 0.0024 6 +154GD G 320 1 0.0010 7 +154GD G 414.3 0.0049 6 +154GD G 422.1 0.0022 9 154GD G 435.9 0.0038 10 -154GD G 484.64 0.0039 2 -154GD G 510 0.059 7 -154GD G 512 0.032 7 +154GD G 484.64 0.0039 2 +154GD G 510 0.059 7 +154GD G 512 0.032 7 154GD G 737.6 0.0063 24 -154GD G 830.3 0.008 3 -154GD G 919.24 0.012 1 +154GD G 830.3 0.008 3 +154GD G 919.24 0.012 1 154GD G 928.4 0.0045 21 154GD G 984.5 0.0094 21 -154GD G 1033.4 0.0119 7 -154GD G 1049.4 1 0.0172 8 +154GD G 1033.4 0.0119 7 +154GD G 1049.4 1 0.0172 8 154GD G 1072.2 0.0035 14 154GD G 1124.2 0.0069 10 -154GD G 1153.1 5 0.011 4 +154GD G 1153.1 5 0.011 4 154GD G 1216.8 0.0033 10 -154GD G 1232.1 5 0.008 5 -154GD G 1316.4 3 0.017 4 -154GD G 1554 0.0011 5 +154GD G 1232.1 5 0.008 5 +154GD G 1316.4 3 0.017 4 +154GD G 1554 0.0011 5 154GD L 0 0+ STABLE 154GD L 123.071 2+ 1.18 NS -154GD B 1845.3 1110.3 5 12.4 1 +154GD B 1845.3 1110.3 5 12.4 1 154GDS B EAV=695.6 5 -154GD G 123.0706 9 40.4 5 E2 1.197 19 -154GD2 G KC=0.653 13$LC=0.418 9$MC=0.096 2 +154GD G 123.0706 9 40.4 5E2 1.197 19 +154GD2 G KC=0.653 13$LC=0.418 9$MC=0.096 2 154GD L 371 4+ 40 PS -154GD B 1597.4 110.31 7 13.43 1 +154GD B 1597.4 110.31 7 13.43 1 154GDS B EAV=588.0 5 -154GD G 247.9288 7 6.89 7 E2 0.110 2 -154GD2 G KC=0.0810 16$LC=0.0228 5$MC= +154GD G 247.9288 7 6.89 7E2 0.110 2 +154GD2 G KC=0.0810 16$LC=0.0228 5 154GD L 680.66 0+ -154GD G 557.58 5 0.267 5 E2 0.0106 2 -154GD2 G KC=0.0087 2$LC=0.0015 3$MC= +154GD G 557.58 5 0.267 5E2 0.0106 2 +154GD2 G KC=0.0087 2$LC=0.0015 3 154GD G 680.72 10 154GD L 717.7 6+ -154GD G 346.72 5 0.029 1 E2 0.0391 8 -154GD2 G KC=$LC=$MC= +154GD G 346.72 5 0.029 1E2 0.0391 8 154GD L 815.5 2+ -154GD B 1152.9 110.33 3 12.8 1 +154GD B 1152.9 110.33 3 12.8 1 154GDS B EAV=401.0 5 -154GD G 134.84 0.0072 4 E2 0.868 18 -154GD2 G KC=$LC=$MC= -154GD G 444.4924 190.560 8 E2 0.0192 4 -154GD2 G KC=0.0154 3$LC=$MC=6.50E-4 13 -154GD G 692.4205 181.79 3 +M1+E2 0.049 6 -154GD2 G KC=0.040 4$LC=0.0070 7$MC= -154GD G 815.53 5 0.512 7 E2 0.004309 -154GD2 G KC=0.00360 7$LC=5.48E-4 11$MC= +154GD G 134.84 0.0072 4E2 0.868 18 +154GD G 444.4924 190.560 8E2 0.0192 4 +154GD2 G KC=0.0154 3$LC=$MC=6.50E-4 13 +154GD G 692.4205 181.79 3+M1+E2 0.049 6 +154GD2 G KC=0.040 4$LC=0.0070 7 +154GD G 815.53 5 0.512 7E2 0.00430 9 +154GD2 G KC=0.00360 7$LC=5.48E-4 11 154GD L 996.26 2+ 154GD B 972.1 112.82 18 11.66 1 154GDS B EAV=328.1 4 -154GD G 180.7 0.0040 5 (M1E2) 0.35 4 -154GD2 G KC=$LC=$MC= -154GD G 315.4 0.007 2 (E2) 0.052 1 -154GD2 G KC=$LC=$MC= -154GD G 625.2556 240.317 5 E2 0.0079716 -154GD2 G KC=0.00658 13$LC=0.00109 2$MC= -154GD G 873.1834 2312.17 12E2+M1+ 0.003738 -154GD2 G KC=0.00313 6$LC=0.00047 1$MC= -154GD G 996.25 5 10.5 1 E2 0.002796 -154GD2 G KC=0.00236 5$LC=3.42E-4 7$MC= +154GD G 180.7 0.0040 5(M1E2) 0.35 4 +154GD G 315.4 0.007 2(E2) 0.052 1 +154GD G 625.2556 240.317 5E2 0.0079716 +154GD2 G KC=0.00658 13$LC=0.00109 2 +154GD G 873.1834 2312.17 12E2+M1+ 0.00373 8 +154GD2 G KC=0.00313 6$LC=0.00047 1 +154GD G 996.25 5 10.5 1E2 0.00279 6 +154GD2 G KC=0.00236 5$LC=3.42E-4 7 154GD L 1047.6 4+ 154GD B 920.8 110.108 18 13 1 154GDS B EAV=307.8 4 -154GD G 232.01 5 0.024 1 E2 0.137 3 -154GD2 G KC=$LC=$MC= -154GD G 329.9 7 0.0091 5 E2 0.0454 9 -154GD2 G KC=$LC=$MC= -154GD G 676.596 120.157 11+M1+E2 0.059 6 -154GD2 G KC=0.049 5$LC=0.0080 8$MC= -154GD G 924.63 5 0.062 2 E2 0.003277 -154GD2 G KC=$LC=$MC= +154GD G 232.01 5 0.024 1E2 0.137 3 +154GD G 329.9 7 0.0091 5E2 0.0454 9 +154GD G 676.596 120.157 11+M1+E2 0.059 6 +154GD2 G KC=0.049 5$LC=0.0080 8 +154GD G 924.63 5 0.062 2E2 0.00327 7 154GD L 1127.8 3+ 154GD B 840.6 1117.33 18 10.64 154GDS B EAV=276.6 4 154GD G 80.4 0.0028 14(M1E2) 4.8 10 -154GD2 G KC=$LC=$MC= -154GD G 131.58 5 0.0111 5 M1+E2 0.95 4 -154GD2 G KC=$LC=$MC= -154GD G 312.3 0.018 2 (M1E2) 0.07 2 -154GD2 G KC=$LC=$MC= -154GD G 756.8020 234.53 5 E1+M2 0.0051 12 -154GD2 G KC=0.00431 9$LC=0.00067 2$MC= -154GD G 1004.718 7 17.86 18E1+M2 0.002766 -154GD2 G KC=0.00232 5$LC=3.36E-4 7$MC= +154GD G 131.58 5 0.0111 5M1+E2 0.95 4 +154GD G 312.3 0.018 2(M1E2) 0.07 2 +154GD G 756.8020 234.53 5E1+M2 0.0051 12 +154GD2 G KC=0.00431 9$LC=0.00067 2 +154GD G 1004.718 7 17.86 18E1+M2 0.00276 6 +154GD2 G KC=0.00232 5$LC=3.36E-4 7 154GD L 1136 1,2+ -154GD G 1012.8 2 0.003 1 -154GD G 1136.1 0.007 1 +154GD G 1012.8 2 0.003 1 +154GD G 1136.1 0.007 1 154GD L 1233.2 + -154GD G 1110 0.003 2 +154GD G 1110 0.003 2 154GD L 1241.3 1- -154GD G 1118.52 6 0.108 14E1 0.000932 -154GD2 G KC=7.98E-4 16$LC=1.03E-4 20$MC= -154GD G 1241.43 100.133 6 E1+(M2) 7.71E-415 -154GD2 G KC=6.62E-4 13$LC=8.49E-5 17$MC= +154GD G 1118.52 6 0.108 14E1 0.00093 2 +154GD2 G KC=7.98E-4 16$LC=1.03E-4 20 +154GD G 1241.43 100.133 6E1+(M2) 7.71E-415 +154GD2 G KC=6.62E-4 13$LC=8.49E-5 17 154GD L 1251.6 3- -154GD B 716.8 110.289 6 12.18 +154GD B 716.8 110.289 6 12.18 154GDS B EAV=229.5 4 -154GD G 880.60 3 0.081 4 E1+M2 0.001538 -154GD2 G KC=$LC=$MC= -154GD G 1128.552 7 0.317 5 E1 9.15E-418 -154GD2 G KC=7.85E-4 16$LC=1.01E-4 2$MC= +154GD G 880.60 3 0.081 4E1+M2 0.00153 8 +154GD G 1128.552 7 0.317 5E1 9.15E-418 +154GD2 G KC=7.85E-4 16$LC=1.01E-4 2 154GD L 1263.78 4+ -154GD B 704.6 110.707 7 11.76 1 +154GD B 704.6 110.707 7 11.76 1 154GDS B EAV=225.0 4 -154GD G 545.6 0.014 2 (E2) 0.0112 2 -154GD2 G KC=$LC=$MC= -154GD G 892.775 6 0.514 7 +E2+M1 0.003698 -154GD2 G KC=$LC=$MC= -154GD G 1140.702 6 0.235 4 E2 0.002114 -154GD2 G KC=$LC=$MC= +154GD G 545.6 0.014 2(E2) 0.0112 2 +154GD G 892.775 6 0.514 7+E2+M1 0.00369 8 +154GD G 1140.702 6 0.235 4E2 0.00211 4 154GD L 1277 + -154GD G 229.01 130.0024 8 -154GD G 906.1 0.0118 6 +154GD G 229.01 130.0024 8 +154GD G 906.1 0.0118 6 154GD L 1294.2 (2)+ -154GD G 165.90 210.0025 5 +154GD G 165.90 210.0025 5 154GD G 1170.7 5 0.0036 10 154GD L 1397.5 2- 154GD B 570.9 1136.06 35 9.74 154GDS B EAV=176.2 4 -154GD G 146.05 5 0.026 1 (M1E2) 0.68 2 -154GD2 G KC=$LC=$MC= -154GD G 156.2 0.0098 4 (M1E2) 0.55 3 -154GD2 G KC=$LC=$MC= -154GD G 260.9 0.0022 7 -154GD G 269.8 0.0070 11E1+M2 0.0209 4 -154GD2 G KC=$LC=$MC= -154GD G 401.259 140.189 3 (E1M2E3) 0.07 2 -154GD2 G KC=$LC=$MC= -154GD G 582.01 5 0.886 11E1 0.003397 -154GD2 G KC=0.00288 6$LC=3.85E-4 8$MC= -154GD G 1274.429 4 34.9 3 E1+M2 7.37E-415 -154GD2 G KC=6.32E-4 13$LC=8.10E-5 16$MC= +154GD G 146.05 5 0.026 1(M1E2) 0.68 2 +154GD G 156.2 0.0098 4(M1E2) 0.55 3 +154GD G 260.9 0.0022 7 +154GD G 269.8 0.0070 11E1+M2 0.0209 4 +154GD G 401.259 140.189 3(E1M2E3) 0.07 2 +154GD G 582.01 5 0.886 11E1 0.00339 7 +154GD2 G KC=0.00288 6$LC=3.85E-4 8 +154GD G 1274.429 4 34.9 3E1+M2 7.37E-415 +154GD2 G KC=6.32E-4 13$LC=8.10E-5 16 154GD L 1414.4 1- -154GD G 600 0.006 4 (E1) 0.003187 -154GD2 G KC=$LC=$MC= -154GD G 1292.0 2 0.0127 5 E1 0.000722 -154GD2 G KC=$LC=$MC= -154GD G 1415.0 5 0.040 2 E1 0.000611 -154GD2 G KC=$LC=$MC= +154GD G 600 0.006 4(E1) 0.00318 7 +154GD G 1292.0 2 0.0127 5E1 0.00072 2 +154GD G 1415.0 5 0.040 2E1 0.00061 1 154GD L 1418 2+ -154GD B 550.0 110.075 2 12.23 1 +154GD B 550.0 110.075 2 12.23 1 154GDS B EAV=168.8 4 -154GD G 125.39 5 0.007 2 -154GD G 370.71 0.0056 14E2 0.0321 7 -154GD2 G KC=$LC=$MC= -154GD G 602.81 5 0.0033 2 +M1+E2 0.048 6 -154GD2 G KC=$LC=$MC= -154GD G 1047.4 1 0.049 3 E2 0.002515 -154GD2 G KC=$LC=$MC= +154GD G 125.39 5 0.007 2 +154GD G 370.71 0.0056 14E2 0.0321 7 +154GD G 602.81 5 0.0033 2+M1+E2 0.048 6 +154GD G 1047.4 1 0.049 3E2 0.00251 5 154GD G 1295.5 2 0.0091 10 -154GD G 1418.6 2 0.011 2 E2 0.001383 -154GD2 G KC=$LC=$MC= +154GD G 1418.6 2 0.011 2E2 0.00138 3 154GD L 1510.1 (1)- -154GD B 458.3 110.021 2 12.66 2 +154GD B 458.3 110.021 2 12.66 2 154GDS B EAV=136.9 4 -154GD G 1387.0 5 0.019 2 (E1) 0.000632 -154GD2 G KC=$LC=$MC= -154GD G 1510.0 5 0.0048 10(E1) 0.000471 -154GD2 G KC=$LC=$MC= +154GD G 1387.0 5 0.019 2(E1) 0.00063 2 +154GD G 1510.0 5 0.0048 10(E1) 0.00047 1 154GD L 1531.3 2+ 154GD B 437.1 110.330 13 11.39 1 154GDS B EAV=129.8 4 -154GD G 237 0.006 3 0.018 7 -154GD2 G KC=$LC=$MC= -154GD G 267.44 0.0136 7 (E2) 0.087 2 -154GD2 G KC=$LC=$MC= -154GD G 279.9 0.0030 2 (E1) 0.0190 4 -154GD2 G KC=$LC=$MC= -154GD G 290 0.0033 2 (E1) 0.0174 3 -154GD2 G KC=$LC=$MC= -154GD G 403.55 5 0.026 1 (M1E2) 0.035 10 -154GD2 G KC=$LC=$MC= -154GD G 483.74 0.0050 3 (E2) 0.0153 3 -154GD2 G KC=$LC=$MC= -154GD G 715.77 3 0.19 1 (M1E2) 0.013 4 -154GD2 G KC=$LC=$MC= -154GD G 850.64 3 0.241 4 E2 0.003928 -154GD2 G KC=$LC=$MC= -154GD G 1160.36 8 0.0436 21(E2) 0.002044 -154GD2 G KC=$LC=$MC= -154GD G 1408.5 2 0.023 3 (M1E2) 0.0037 14 -154GD2 G KC=$LC=$MC= -154GD G 1531.4 2 0.0060 4 (E2) 0.001012 -154GD2 G KC=$LC=$MC= +154GD G 237 0.006 3 0.018 7 +154GD G 267.44 0.0136 7(E2) 0.087 2 +154GD G 279.9 0.0030 2(E1) 0.0190 4 +154GD G 290 0.0033 2(E1) 0.0174 3 +154GD G 403.55 5 0.026 1(M1E2) 0.035 10 +154GD G 483.74 0.0050 3(E2) 0.0153 3 +154GD G 715.77 3 0.19 1(M1E2) 0.013 4 +154GD G 850.64 3 0.241 4E2 0.00392 8 +154GD G 1160.36 8 0.0436 21(E2) 0.00204 4 +154GD G 1408.5 2 0.023 3(M1E2) 0.0037 14 +154GD G 1531.4 2 0.0060 4(E2) 0.00101 2 154GD L 1560 (4)- -154GD B 408.8 120.100 4 11.81 +154GD B 408.8 120.100 4 11.81 154GDS B EAV=120.3 4 -154GD G 162.09 5 0.0011 4 (E2) 0.457 9 -154GD2 G KC=$LC=$MC= -154GD G 295.7 0.0024 2 (E1) 0.0166 3 -154GD2 G KC=$LC=$MC= -154GD G 563.4 0.0028 7 (M2) 0.058 1 -154GD2 G KC=$LC=$MC= -154GD G 1188.34 170.093 7 (E1) 0.000832 -154GD2 G KC=$LC=$MC= +154GD G 162.09 5 0.0011 4(E2) 0.457 9 +154GD G 295.7 0.0024 2(E1) 0.0166 3 +154GD G 563.4 0.0028 7(M2) 0.058 1 +154GD G 1188.34 170.093 7(E1) 0.00083 2 154GD L 1617.13 3- -154GD B 351.3 111.78 3 10.34 +154GD B 351.3 111.78 3 10.34 154GDS B EAV=101.4 4 -154GD G 202.50 160.03 1 -154GD G 219.4 0.0023 5 (M1E2) 0.20 4 -154GD2 G KC=$LC=$MC= -154GD G 375.2 5 0.0020 8 (E2) 0.0310 6 -154GD2 G KC=$LC=$MC= -154GD G 480.61 0.0048 3 -154GD G 488.26 0.007 3 (E1) 0.0049810 -154GD2 G KC=$LC=$MC= -154GD G 569.23 0.0100 8 (E1) 0.0036 1 -154GD2 G KC=$LC=$MC= -154GD G 620.52 0.091 5 (E1) 0.002966 -154GD2 G KC=$LC=$MC= -154GD G 801.21 4 0.012 3 (E1) 0.001754 -154GD2 G KC=$LC=$MC= +154GD G 202.50 160.03 1 +154GD G 219.4 0.0023 5(M1E2) 0.20 4 +154GD G 375.2 5 0.0020 8(E2) 0.0310 6 +154GD G 480.61 0.0048 3 +154GD G 488.26 0.007 3(E1) 0.0049810 +154GD G 569.23 0.0100 8(E1) 0.0036 1 +154GD G 620.52 0.091 5(E1) 0.00296 6 +154GD G 801.21 4 0.012 3(E1) 0.00175 4 154GD G 1246.121 4 0.862 11E1 7.66E-415 -154GD2 G KC=6.58E-4 13$LC=8.43E-5 17$MC= -154GD G 1494.048 4 0.698 9 E1 0.000561 -154GD2 G KC=4.81E-4 10$LC=6.11E-5 12$MC= +154GD2 G KC=6.58E-4 13$LC=8.43E-5 17 +154GD G 1494.048 4 0.698 9E1 0.00056 1 +154GD2 G KC=4.81E-4 10$LC=6.11E-5 12 154GD L 1645.8 4+ -154GD B 322.6 110.148 4 11.31 1 +154GD B 322.6 110.148 4 11.31 1 154GDS B EAV=92.2 4 -154GD G 368.21 0.0030 2 -154GD G 382.00 5 0.0099 4 (E2M1) 0.034 11 -154GD2 G KC=$LC=$MC= -154GD G 518.00 5 0.047 2 (E2M1) 0.013 1 -154GD2 G KC=$LC=$MC= -154GD G 598.3 0.0062 7 M1+E2 0.014 1 -154GD2 G KC=$LC=$MC= -154GD G 649.44 5 0.078 3 E2 0.0073 2 -154GD2 G KC=$LC=$MC= +154GD G 368.21 0.0030 2 +154GD G 382.00 5 0.0099 4(E2M1) 0.034 11 +154GD G 518.00 5 0.047 2(E2M1) 0.013 1 +154GD G 598.3 0.0062 7M1+E2 0.014 1 +154GD G 649.44 5 0.078 3E2 0.0073 2 154GD L 1660.9 3+ -154GD B 307.5 110.849 9 10.48 +154GD B 307.5 110.849 9 10.48 154GDS B EAV=87.4 3 -154GD G 129.5 0.014 2 (M1E2) 0.99 3 -154GD2 G KC=$LC=$MC= -154GD G 397.1 0.029 1 (M1E2) 0.036 10 -154GD2 G KC=$LC=$MC= -154GD G 419.4 0.0034 20M2 0.140 3 -154GD2 G KC=$LC=$MC= -154GD G 533.1 0.007 2 -154GD G 613.26 5 0.093 4 (E2M1) 0.012 4 -154GD2 G KC=$LC=$MC= -154GD G 664.68 5 0.029 1 (M1E2) 0.010 3 -154GD2 G KC=$LC=$MC= -154GD G 845.416 7 0.586 9 E2 0.003978 -154GD2 G KC=0.00333 7$LC=5.02E-4 10$MC= -154GD G 1290.5 1 0.025 3 (M1E2) 0.0021 5 -154GD2 G KC=$LC=$MC= -154GD G 1537.81 4 0.053 2 (M1E2) 0.0012 3 -154GD2 G KC=$LC=$MC= +154GD G 129.5 0.014 2(M1E2) 0.99 3 +154GD G 397.1 0.029 1(M1E2) 0.036 10 +154GD G 419.4 0.0034 20M2 0.140 3 +154GD G 533.1 0.007 2 +154GD G 613.26 5 0.093 4(E2M1) 0.012 4 +154GD G 664.68 5 0.029 1(M1E2) 0.010 3 +154GD G 845.416 7 0.586 9E2 0.00397 8 +154GD2 G KC=0.00333 7$LC=5.02E-4 10 +154GD G 1290.50 100.025 3(M1E2) 0.0021 5 +154GD G 1537.81 4 0.053 2(M1E2) 0.0012 3 154GD L 1698.5 (4)+ -154GD B 270.2 110.0100 4 12.33 1 +154GD B 270.2 110.0100 4 12.33 1 154GDS B EAV=75.7 3 -154GD G 650.6 0.0098 4 (M1E2) 0.026 8 -154GD2 G KC=$LC=$MC= +154GD G 650.6 0.0098 4(M1E2) 0.026 8 154GD L 1719.56 2- 154GD B 248.8 1128.32 22 8.66 154GDS B EAV=69.2 3 -154GD G 58.4 0.0039 4 (E1) 1.23 3 -154GD2 G KC=$LC=$MC= -154GD G 188.24 2 0.239 6 E1 0.0536 11 -154GD2 G KC=0.0453 9$LC=0.0065 2$MC= -154GD G 209.4 4 0.0025 6 -154GD G 301.25 0.0102 4 (E2) 0.0158 3 -154GD2 G KC=$LC=$MC= -154GD G 305.1 0.0174 7 (M1E2) 0.075 18 -154GD2 G KC=$LC=$MC= -154GD G 322.02 5 0.066 3 (M1E2) 0.065 17 -154GD2 G KC=$LC=$MC= -154GD G 467.84 5 0.0604 24(M1E2) 0.024 7 -154GD2 G KC=$LC=$MC= -154GD G 478.27 5 0.224 3 M1 0.0287 6 -154GD2 G KC=0.0245 5$LC=0.00341 7$MC=0.00074 2 -154GD G 591.755 3 4.95 5 E1+(M2) 0.0032910 -154GD2 G KC=0.0028 6$LC=3.74E-4 8$MC=3.72E-5 8 -154GD G 723.3014 2220.05 21E1+M2 0.002155 -154GD2 G KC=0.00184 4$LC=2.44E-4 5$MC= -154GD G 904.064 3 0.890 11E1(+M2) 0.001383 -154GD2 G KC=0.00118 4$LC=1.56E-4 3$MC= -154GD G 1596.4804 281.783 17E1(+M2) 0.000491 -154GD2 G KC=4.30E-4 9$LC=5.46E-5 11$MC= +154GD G 58.4 0.0039 4(E1) 1.23 3 +154GD G 188.24 2 0.239 6E1 0.0536 11 +154GD2 G KC=0.0453 9$LC=0.0065 2 +154GD G 209.4 4 0.0025 6 +154GD G 301.25 0.0102 4(E2) 0.0158 3 +154GD G 305.1 0.0174 7(M1E2) 0.075 18 +154GD G 322.02 5 0.066 3(M1E2) 0.065 17 +154GD G 467.84 5 0.0604 24(M1E2) 0.024 7 +154GD G 478.27 5 0.224 3M1 0.0287 6 +154GD2 G KC=0.0245 5$LC=0.00341 7$MC=0.00074 2 +154GD G 591.755 3 4.95 5E1+(M2) 0.0032910 +154GD2 G KC=0.0028 6$LC=3.74E-4 8$MC=3.72E-5 8 +154GD G 723.3014 2220.05 21E1+M2 0.00215 5 +154GD2 G KC=0.00184 4$LC=2.44E-4 5 +154GD G 904.064 3 0.890 11E1(+M2) 0.00138 3 +154GD2 G KC=0.00118 4$LC=1.56E-4 3 +154GD G 1596.4804 281.783 17E1(+M2) 0.00049 1 +154GD2 G KC=4.30E-4 9$LC=5.46E-5 11 154GD L 1770.2 5+ -154GD B 197.9 110.0022 4 12.46 1U +154GD B 197.9 110.0022 4 12.46 1U 154GDS B EAV=53.9 3 -154GD G 506.4 0.0063 14E2 0.0136 3 -154GD2 G KC=$LC=$MC= -154GD G 642.4 0.0044 17(M1E2) 0.011 4 -154GD2 G KC=$LC=$MC= -154GD G 774.4 0.008 4 (M3) 0.053 2 -154GD2 G KC=$LC=$MC= -154GD G 1397.34 5 0.0031 8 (M1E2) 0.0018 4 -154GD2 G KC=$LC=$MC= +154GD G 506.4 0.0063 14E2 0.0136 3 +154GD G 642.4 0.0044 17(M1E2) 0.011 4 +154GD G 774.4 0.008 4(M3) 0.053 2 +154GD G 1397.34 5 0.0031 8(M1E2) 0.0018 4 154GD L 1790.2 (4)+ -154GD B 178.1 110.022 1 11.31 1 +154GD B 178.1 110.022 1 11.31 1 154GDS B EAV=48.1 3 -154GD G 1419.0 2 0.0020 1 (M1E2) 0.0017 4 -154GD2 G KC=$LC=$MC= -154GD G 1667.3 2 0.0019 3 (E2) +154GD G 1419.0 2 0.0020 1(M1E2) 0.0017 4 +154GD G 1667.3 2 0.0019 3(E2) 154GD L 1797 3- -154GD B 171.7 120.060 6 10.8 +154GD B 171.7 120.060 6 10.8 154GDS B EAV=46.3 3 -154GD G 533.1 0.004 3 E1 0.004128 -154GD2 G KC=$LC=$MC= -154GD G 668.9 0.013 2 E1 0.002535 -154GD2 G KC=$LC=$MC= -154GD G 800.2 0.032 5 E1 0.001754 -154GD2 G KC=$LC=$MC= -154GD G 981.3 5 0.0084 17(E1) 0.001183 -154GD2 G KC=$LC=$MC= -154GD G 1425.9 5 0.0012 7 (E1) 0.000601 -154GD2 G KC=$LC=$MC= -154GD G 1674.0 5 0.0017 4 (E1) +154GD G 533.1 0.004 3E1 0.00412 8 +154GD G 668.9 0.013 2E1 0.00253 5 +154GD G 800.2 0.032 5E1 0.00175 4 +154GD G 981.3 5 0.0084 17(E1) 0.00118 3 +154GD G 1425.9 5 0.0012 7(E1) 0.00060 1 +154GD G 1674.0 5 0.0017 4(E1) 154GD L 1838.6 2+ -154GD B 130.1 120.017 5 10.99 1 +154GD B 130.1 120.017 5 10.99 1 154GDS B EAV=34.5 3 -154GD G 790.2 0.010 3 (E2) 0.004629 -154GD2 G KC=$LC=$MC= +154GD G 790.2 0.010 3(E2) 0.00462 9 154GD G 1023 1 0.0066 25(M1E2) -154GD G 1716.9 5 0.0006 3 (M1E2) -154GD G 1838.0 5 0.0008 2 (E2) +154GD G 1716.9 5 0.0006 3(M1E2) +154GD G 1838.0 5 0.0008 2(E2) 154GD L 1861.5 4- -154GD B 107.2 110.034 3 10.44 +154GD B 107.2 110.034 3 10.44 154GDS B EAV=28.1 3 -154GD G 597.5 0.0055 3 (E1) 0.003217 -154GD2 G KC=$LC=$MC= -154GD G 1489.6 2 0.0029 4 (E1) 0.000561 -154GD2 G KC=$LC=$MC= +154GD G 597.5 0.0055 3(E1) 0.00321 7 +154GD G 1489.6 2 0.0029 4(E1) 0.00056 1 154GD L 1878.5 + -154GD B 89.4 110.0042 3 +154GD B 89.4 110.0042 3 154GDS B EAV=23.3 3 -154GD G 463.9 0.0042 3 +154GD G 463.9 0.0042 3 154GD L 1894.7 5 2+ -154GD B 73.7 110.0035 6 10.92 1 +154GD B 73.7 110.0035 6 10.92 1 154GDS B EAV=19.0 3 -154GD G 898.36 0.0020 5 (M1E2) 0.0048 13 -154GD2 G KC=$LC=$MC= -154GD G 1522 1 0.0006 3 (E2) 0.001022 -154GD2 G KC=$LC=$MC= +154GD G 898.36 0.0020 5(M1E2) 0.0048 13 +154GD G 1522 1 0.0006 3(E2) 0.00102 2 154GD G 1773 1 0.00035 21(M1E2) -154GD G 1895 1 0.0006 2 (E2) +154GD G 1895 1 0.0006 2(E2) diff --git a/HEN_HOUSE/spectra/lnhb/Eu-155.txt b/HEN_HOUSE/spectra/lnhb/Eu-155.txt index 274eae1cf..22e2df417 100644 --- a/HEN_HOUSE/spectra/lnhb/Eu-155.txt +++ b/HEN_HOUSE/spectra/lnhb/Eu-155.txt @@ -1,75 +1,75 @@ 155GD 155EU B- DECAY (4.753 Y) 155GD C References: 1977La19 -155GD T Auger electrons and ^X ray energies and emission intensities: -155GD T {U Energy (keV)} {U Intensity } {U Line } +155GD T Auger electrons and X ray energies and emission intensities: +155GD T {U Energy (keV)} {U Intensity} {U Line} 155GD T -155GD T 42.3093 6.70 13 XKA2 -155GD T 42.9967 12.05 23 XKA1 +155GD T 42.3093 6.70 13 XKA2 +155GD T 42.9967 12.05 23 XKA1 155GD T -155GD T 48.556 |] XKB3 -155GD T 48.697 |] 3.84 11 XKB1 -155GD T 49.053 |] XKB5II +155GD T 48.556 |] XKB3 +155GD T 48.697 |] 3.84 11 XKB1 +155GD T 49.053 |] XKB5II 155GD T -155GD T 49.961 |] XKB2 -155GD T 50.099 |] 0.977 26 XKB4 -155GD T 50.219 |] XKO23 +155GD T 49.961 |] XKB2 +155GD T 50.099 |] 0.977 26 XKB4 +155GD T 50.219 |] XKO23 155GD T -155GD T 5.3611-8.104 7.5 5 XL (total) +155GD T 5.3611-8.104 7.5 5 XL (total) 155GD T 5.3611 XLL 155GD T 6.024-6.0578 XLA 155GD T 6.0483 XLC 155GD T 6.6848-7.1888 XLB 155GD T 7.5509-8.104 XLG 155GD T -155GD T 33.49-35.75 |] KLL AUGER -155GD T 39.98-42.86 |] 1.71 11 ^KLX AUGER -155GD T 47.98-48.95 |] KXY AUGER -155GD T 3.4-8.3 35.1 20 L AUGER +155GD T 33.49-35.75 |] KLL AUGER +155GD T 39.98-42.86 |] 1.71 11 KLX AUGER +155GD T 47.98-48.95 |] KXY AUGER +155GD T 3.4-8.3 35.1 20 L AUGER 155EU P 0.0 5/2+ 4.753 Y 14 252.1 11 155GD N 1.0 1.0 1 1.0 155GD L 0 3/2- STABLE -155GD B 252.2 1116.6 11 8.65 1U +155GD B 252.2 1116.6 11 8.65 1 155GDS B EAV=70.2 3 155GD L 60.0086 105/2- 0.193 NS 10 -155GD B 192.2 119.2 4 8.54 +155GD B 192.2 119.2 4 8.54 155GDS B EAV=52.3 3 -155GD G 60.0086 101.22 5 M1+E2 9.48 11 -155GD2 G KC=7.48 9$LC=1.55 6$MC=0.347 14 +155GD G 60.0086 101.22 5M1+E2 9.48 11 +155GD2 G KC=7.48 9$LC=1.55 6$MC=0.347 14 155GD L 86.5479 105/2+ 6.50 NS 4 155GD B 165.7 1125.5 29 7.89 155GDS B EAV=44.6 3 -155GD G 26.531 210.316 22E1 1.98 6 -155GD2 G KC=$LC=1.55 5$MC=0.342 11 -155GD G 86.5479 1030.7 3 E1 0.432 7 -155GD2 G KC=0.360 4$LC=0.0561 17$MC=0.0122 4 +155GD G 26.531 210.316 22E1 1.98 6 +155GD2 G LC=1.55 5$MC=0.342 11 +155GD G 86.5479 1030.7 3E1 0.432 7 +155GD2 G KC=0.360 4$LC=0.0561 17$MC=0.0122 4 155GD L 105.3083 103/2+ 1.16 NS 1 -155GD B 146.9 1146.1 29 7.47 2 +155GD B 146.9 1146.1 29 7.47 155GDS B EAV=39.2 3 -155GD G 18.763 2 0.048 7 M1+E2 367 22 -155GD2 G KC=$LC=284 22$MC=65.9 30 -155GD G 45.299 1 1.31 5 E1 0.443 11 -155GD2 G KC=$LC=0.347 10$MC=0.0758 23 -155GD G 105.3083 1021.1 6 E1 0.255 3 -155GD2 G KC=0.214 2$LC=0.0323 10$MC=0.00701 21 +155GD G 18.763 2 0.048 7M1+E2 367 22 +155GD2 G LC=284 22$MC=65.9 30 +155GD G 45.299 1 1.31 5E1 0.443 11 +155GD2 G LC=0.347 10$MC=0.0758 23 +155GD G 105.3083 1021.1 6E1 0.255 3 +155GD2 G KC=0.214 2$LC=0.0323 10$MC=0.00701 21 155GD L 107.583 5 9/2+ -155GD B 144.6 110.01 11.1 +155GD B 144.6 110.01 11.1 2 155GDS B EAV= -155GD G 21.035 4 0.00046 3 E2 2600 70 -155GD2 G KC=$LC=2010 60$MC=471 14 +155GD G 21.035 4 0.00046 3E2 2600 70 +155GD2 G LC=2010 60$MC=471 14 155GD L 117.998 2 7/2+ -155GD B 134.2 111.85 23 8.75 2 +155GD B 134.2 111.85 23 8.75 155GDS B EAV=35.6 3 -155GD G 10.4183 130.0035 4 M1+E2 340 23 -155GD2 G KC=$LC=265 22$MC=59 5 +155GD G 10.4183 130.0035 4M1+E2 340 23 +155GD2 G LC=265 22$MC=59 5 155GD G 31.444 7 0.0071 15M1+E2 69 14 -155GD2 G KC=$LC=53 13$MC=12.5 30 -155GD G 57.989 1 0.067 6 E1 1.243 11 -155GD2 G KC=1.021 10$LC=0.173 5$MC=0.0377 11 +155GD2 G LC=53 13$MC=12.5 30 +155GD G 57.989 1 0.067 6E1 1.243 11 +155GD2 G KC=1.021 10$LC=0.173 5$MC=0.0377 11 155GD L 146.0711 107/2- 0.101 NS 120 -155GD B 106.1 110.73 7 8.83 1U +155GD B 106.1 110.73 7 8.83 1 155GDS B EAV=27.8 3 -155GD G 86.0591 100.154 17M1+E2 3.23 4 -155GD2 G KC=2.66 3$LC=0.443 17$MC=0.098 4 -155GD G 146.071 1 0.051 4 E2 0.653 8 -155GD2 G KC=0.397 4$LC=0.198 6$MC=0.0462 14 +155GD G 86.0591 100.154 17M1+E2 3.23 4 +155GD2 G KC=2.66 3$LC=0.443 17$MC=0.098 4 +155GD G 146.071 1 0.051 4E2 0.653 8 +155GD2 G KC=0.397 4$LC=0.198 6$MC=0.0462 14 diff --git a/HEN_HOUSE/spectra/lnhb/F-18.txt b/HEN_HOUSE/spectra/lnhb/F-18.txt index b20a0da98..a3e8adb3f 100644 --- a/HEN_HOUSE/spectra/lnhb/F-18.txt +++ b/HEN_HOUSE/spectra/lnhb/F-18.txt @@ -10,21 +10,21 @@ 18O 3C 1964Ho28, 1964Ho09, 1964Ma12, 1965Eb01, 1965Bo42, 1970Al11, 1972Aj02, 18O 4C 1973Ho43, 1977Ba48, 1978Aj03, 1980RuZY, 1987Aj02, 1989Sc17, 2002Un02, 18O 5C 2004BeZQ, 2004Sc04, 2010Ga04, 2012Ha35, 2012Wa38, 2014Un01 - 18O T Auger electrons and ^X ray energies and emission intensities: - 18O T {U Energy (keV)} {U Intensity } {U Line } + 18O T Auger electrons and X ray energies and emission intensities: + 18O T {U Energy (keV)} {U Intensity} {U Line} 18O T - 18O T 0.525 0.007 2 XKA2 - 18O T 0.525 0.013 4 XKA1 + 18O T 0.525 0.007 2 XKA2 + 18O T 0.525 0.013 4 XKA1 18O T 18O T 18O T 18O T - 18O T 0.456-0.502 |] KLL AUGER - 18O T - |] 2.89 18 ^KLX AUGER - 18O T -0.0143 0.229 21 L AUGER + 18O T 0.456-0.502 |] KLL AUGER + 18O T - |] 2.89 18 KLX AUGER + 18O T -0.0143 0.229 21 L AUGER 18F P 0.0 1+ 1.82890 H 23 1655.9 5 18O N 1.0 1.0 1 1.0 18O L 0 0+ STABLE 18O E 96.86 193.14 193.57 - 18O 2 E EAV=249.5 3$CK=0.927 5$CL=0.073 5$CM= $CN= $CO= + 18O 2 E EAV=249.5 3$CK=0.927 5$CL=0.073 5 diff --git a/HEN_HOUSE/spectra/lnhb/Fe-52.txt b/HEN_HOUSE/spectra/lnhb/Fe-52.txt index e3de4b46b..647d1330a 100644 --- a/HEN_HOUSE/spectra/lnhb/Fe-52.txt +++ b/HEN_HOUSE/spectra/lnhb/Fe-52.txt @@ -4,41 +4,41 @@ 52MN C References: 1948Mi12, 1956Ar33, 1959Ju40, 1960Ka20, 1967Pa22, 1971Go40, 52MN2C 1971Sa21, 1972McYW, 1974Ro18, 1977Ya08, 1996Sc06, 1998Sc28, 2000Sc47, 52MN3C 2007Hu08, 2008Ki07, 2012Wa38 - 52MN T Auger electrons and ^X ray energies and emission intensities: - 52MN T {U Energy (keV)} {U Intensity } {U Line } + 52MN T Auger electrons and X ray energies and emission intensities: + 52MN T {U Energy (keV)} {U Intensity} {U Line} 52MN T - 52MN T 5.88772 3.70 17 XKA2 - 52MN T 5.89881 7.3 4 XKA1 + 52MN T 5.88772 3.70 17 XKA2 + 52MN T 5.89881 7.3 4 XKA1 52MN T - 52MN T 6.49051 |] 1.49 7 XKB1 - 52MN T 6.5354 |] XKB5II + 52MN T 6.49051 |] 1.49 7 XKB1 + 52MN T 6.5354 |] XKB5II 52MN T 52MN T - 52MN T 0.5576-0.7694 0.213 10 XL (total) - 52MN T 0.5576 0.124 8 XLL - 52MN T 0.6394-0.6404 0 0 XLA - 52MN T 0.5695 0.085 6 XLC - 52MN T 0.64636-0.7694 0.00315 18 XLB - 52MN T 0.65826-0.65826 0 0 XLG + 52MN T 0.5576-0.7694 0.213 10 XL (total) + 52MN T 0.5576 0.124 8 XLL + 52MN T 0.6394-0.6404 XLA + 52MN T 0.5695 0.085 6 XLC + 52MN T 0.64636-0.7694 0.00315 18 XLB + 52MN T 0.65826-0.65826 XLG 52MN T - 52MN T 4.953-5.21 |] KLL AUGER - 52MN T 5.671-5.895 |] 26.3 11 ^KLX AUGER - 52MN T 6.37-6.532 |] KXY AUGER - 52MN T 0.4725-0.7653 57.1 15 L AUGER + 52MN T 4.953-5.21 |] KLL AUGER + 52MN T 5.671-5.895 |] 26.3 11 KLX AUGER + 52MN T 6.37-6.532 |] KXY AUGER + 52MN T 0.4725-0.7653 57.1 15 L AUGER 52FE P 0.0 0+ 8.273 H 8 2375 6 52MN N 1.0 1.0 1 1.0 52MN L 0 6+ 5.591 D 3 52MN L 377.749 5 2+ 21.1 M 2 - 52MN G 377.749 5 1.64 4 E4 0.0399 6 - 52MN2 G KC=0.0356 5$LC=0.00382 6$MC=5.15E-4 8 + 52MN G 377.749 5 1.64 4E4 0.0399 6 + 52MN2 G KC=0.0356 5$LC=0.00382 6$MC=5.15E-4 8 52MN L 546.438 6 1+ - 52MN E 56.1 7 43.8 134.7 - 52MN2 E EAV=339 6$CK=0.8898 16$CL=0.0946 13$CM=0.0150 5$CN=0.0006 2$CO= + 52MN E 56.1 743.8 134.7 + 52MN2 E EAV=339 6$CK=0.8898 16$CL=0.0946 13$CM=0.0150 5$CN=0.0006 2 52MN G 168.689 8 99.1 15M1 0.0078311 52MN2 G KC=0.00705 10$LC=6.79E-4 10$MC=9.22E-5 13 52MN L 1417.688 18 + - 52MN E 0.095 4 5.8 - 52MN2 E EAV= $CK=0.8892 16$CL=0.0950 13$CM=0.0151 5$CN=0.0006 2$CO= - 52MN G 1039.939 190.095 4 M1+E2 1.43E-416 + 52MN E 0.095 45.8 + 52MN2 E CK=0.8892 16$CL=0.0950 13$CM=0.0151 5$CN=0.0006 2 + 52MN G 1039.939 190.095 4M1+E2 1.43E-416 52MN2 G KC=1.30E-4 15$LC=1.22E-5 14$MC=1.65E-6 19 diff --git a/HEN_HOUSE/spectra/lnhb/Fe-55.txt b/HEN_HOUSE/spectra/lnhb/Fe-55.txt index 60612465c..bca375b27 100644 --- a/HEN_HOUSE/spectra/lnhb/Fe-55.txt +++ b/HEN_HOUSE/spectra/lnhb/Fe-55.txt @@ -4,33 +4,32 @@ 55MN C Evaluation history: Type=Updated;Author=MMBé;Cutoff date=20-DEC-2005 55MN2C Type=Full;Author=MMBé;Cutoff date=01-APR-1998 55MN C References: 1977La19 - 55MN T Auger electrons and ^X ray energies and emission intensities: - 55MN T {U Energy (keV)} {U Intensity } {U Line } + 55MN T Auger electrons and X ray energies and emission intensities: + 55MN T {U Energy (keV)} {U Intensity} {U Line} 55MN T - 55MN T 5.88765 8.45 14 XKA2 - 55MN T 5.89875 16.57 27 XKA1 + 55MN T 5.88765 8.45 14 XKA2 + 55MN T 5.89875 16.57 27 XKA1 55MN T - 55MN T 6.49045 |] XKB3 - 55MN T |] 3.40 7 XKB1 - 55MN T 6.5352 |] XKB5II + 55MN T 6.49045 |] XKB3 + 55MN T |] 3.40 7 XKB1 + 55MN T 6.5352 |] XKB5II 55MN T 55MN T - 55MN T 0.556-0.721 0.524 21 XL (total) - 55MN T 0.556 0.309 17 XLL - 55MN T 0.567 0.204 13 XLC - 55MN T 0.649-0.721 0.0104 5 XLB + 55MN T 0.556-0.721 0.524 21 XL (total) + 55MN T 0.556 0.309 17 XLL + 55MN T 0.567 0.204 13 XLC + 55MN T 0.649-0.721 0.0104 5 XLB 55MN T - 55MN T 4.953-5.21 |] KLL AUGER - 55MN T 5.671-5.895 |] 60.1 5 ^KLX AUGER - 55MN T 6.37-6.532 |] KXY AUGER - 55MN T 0.47-0.67 140.2 8 L AUGER + 55MN T 4.953-5.21 |] KLL AUGER + 55MN T 5.671-5.895 |] 60.1 5 KLX AUGER + 55MN T 6.37-6.532 |] KXY AUGER + 55MN T 0.47-0.67 140.2 8 L AUGER 55FE P 0.0 3/2- 2.747 Y 8 231.21 18 55MN N 1.0 1.0 1 1.0 55MN L 0 5/2- STABLE - 55MN E 100 6 2 - 55MN2 E EAV= $CK=0.8853 16$CL=0.0983 13$CM=0.0163 8$CN= $CO= + 55MN E 100 6 + 55MN2 E CK=0.8853 16$CL=0.0983 13$CM=0.0163 8 55MN L 125.949 107/2- - 55MN E 13000E-11 14.2 - 55MN2 E EAV= $CK= $CL= $CM= $CN= $CO= - 55MN G 125.949 101.3E-7 1 M1+(E2) + 55MN E 1.3E-7 114.2 2 + 55MN G 125.949 101.3E-7 1M1+(E2) diff --git a/HEN_HOUSE/spectra/lnhb/Fe-59.txt b/HEN_HOUSE/spectra/lnhb/Fe-59.txt index 41a53095d..867d4bf38 100644 --- a/HEN_HOUSE/spectra/lnhb/Fe-59.txt +++ b/HEN_HOUSE/spectra/lnhb/Fe-59.txt @@ -11,56 +11,56 @@ 59CO4C 1974Ba**, 1974Mu12, 1975Al02, 1977Kr13, 1980Ho17, 1983Wa26, 1989Mi07, 59CO5C 1992Un01, 1997Ma75, 2000He14, 2002Ba42, 2002Ba85, 2004BeZR, 2008Ki07, 59CO6C 2012Fi12, 2012Wa38, 2014Un01 - 59CO T Auger electrons and ^X ray energies and emission intensities: - 59CO T {U Energy (keV)} {U Intensity } {U Line } + 59CO T Auger electrons and X ray energies and emission intensities: + 59CO T {U Energy (keV)} {U Intensity} {U Line} 59CO T - 59CO T 6.91538 0.00596 11 XKA2 - 59CO T 6.9304 0.01166 21 XKA1 + 59CO T 6.91538 0.00596 11 XKA2 + 59CO T 6.9304 0.01166 21 XKA1 59CO T - 59CO T 7.6495 |] 0.00242 5 XKB1 - 59CO T 7.706 |] XKB5II + 59CO T 7.6495 |] 0.00242 5 XKB1 + 59CO T 7.706 |] XKB5II 59CO T 59CO T - 59CO T 0.6793-0.8674 0.000532 13 XL (total) - 59CO T 0.6793 0.0000231 8 XLL - 59CO T 0.7787-0.7795 0.000293 9 XLA - 59CO T 0.6949 0.0000144 6 XLC - 59CO T 0.78642-0.8674 0.000201 8 XLB - 59CO T 0.80198-0.80198 0.00000122 14 XLG + 59CO T 0.6793-0.8674 0.00053213 XL (total) + 59CO T 0.6793 2.31E-5 8 XLL + 59CO T 0.7787-0.7795 0.000293 9 XLA + 59CO T 0.6949 1.44E-5 6 XLC + 59CO T 0.78642-0.8674 0.000201 8 XLB + 59CO T 0.80198-0.80198 1.22E-6 14 XLG 59CO T - 59CO T 5.81-6.1 |] KLL AUGER - 59CO T 6.67-6.93 |] 0.0316 5 ^KLX AUGER - 59CO T 7.51-7.7 |] KXY AUGER - 59CO T 0.58-0.92 0.0778 6 L AUGER + 59CO T 5.81-6.1 |] KLL AUGER + 59CO T 6.67-6.93 |] 0.0316 5 KLX AUGER + 59CO T 7.51-7.7 |] KXY AUGER + 59CO T 0.58-0.92 0.0778 6 L AUGER 59FE P 0.0 3/2- 44.494 D 12 1565.0 4 59CO N 1.0 1.0 1 1.0 59CO L 0 0 7/2- STABLE - 59CO B 1565.0 4 0.18 4 11.15 + 59CO B 1565.0 4 0.18 4 11.15 2 59COS B EAV=584 59CO L 1099.256 3 3/2- 3.1 PS 4 59CO B 465.7 4 53.30 31 6.69 59COS B EAV=149.2 2 59CO G 1099.245 3 56.51 31E2 1744E-725 - 59CO2 G KC=1571E-7 22$LC=1515E-8 22$MC=2.11E-6 3 + 59CO2 G KC=1571E-7 22$LC=1515E-8 22$MC=2.11E-6 3 59CO L 1291.605 5 3/2- 551 PS 7 59CO B 273.4 4 45.19 34 5.98 59COS B EAV=80.9 2 - 59CO G 192.349 5 2.91 5 0.211 9 0.0090018 + 59CO G 192.349 5 2.91 5 0.211 9 0.0090018 59CO2 G KC=0.00808 17$LC=8.05E-4 17$MC=1120E-7 23 59CO G 1291.590 6 43.23 33E2 1483E-721 59CO2 G KC=1096E-7 16$LC=1055E-8 15$MC=1470E-9 21 59CO L 1434.256 5 1/2- 210 PS 20 - 59CO B 130.7 4 1.25 3 6.49 2 + 59CO B 130.7 4 1.25 3 6.49 59COS B EAV=35.7 1 59CO G 142.651 2 0.978 28M1+E2 -0.008 7 0.0159623 - 59CO2 G KC=0.01432 21$LC=1428E-6 20$MC=1.99E-4 3 - 59CO G 335.000 6 0.260 11M1+E2 -0.12 6 0.001988 - 59CO2 G KC=0.00178 7$LC=1.74E-4 7$MC=2.43E-5 9 + 59CO2 G KC=0.01432 21$LC=1428E-6 20$MC=1.99E-4 3 + 59CO G 335.000 6 0.260 11M1+E2 -0.12 6 0.00198 8 + 59CO2 G KC=0.00178 7$LC=1.74E-4 7$MC=2.43E-5 9 59CO L 1481.72 125/2- - 59CO B 83.3 4 0.080 6 7.08 2 + 59CO B 83.3 4 0.080 6 7.08 59COS B EAV=22.0 1 - 59CO G 382.46 120.0215 23M1+E2 0.1 1 0.001447 - 59CO2 G KC=0.00129 6$LC=1.26E-4 6$MC=1.76E-5 9 - 59CO G 1481.70 120.059 6 M1+E2 -0.19 4 1448E-721 + 59CO G 382.46 120.0215 23M1+E2 0.1 1 0.00144 7 + 59CO2 G KC=0.00129 6$LC=1.26E-4 6$MC=1.76E-5 9 + 59CO G 1481.70 120.059 6M1+E2 -0.19 4 1448E-721 59CO2 G KC=7.51E-5 11$LC=7.20E-6 11$MC=1003E-9 15 diff --git a/HEN_HOUSE/spectra/lnhb/Fr-221.txt b/HEN_HOUSE/spectra/lnhb/Fr-221.txt index b0a3d91fb..499a8c2f5 100644 --- a/HEN_HOUSE/spectra/lnhb/Fr-221.txt +++ b/HEN_HOUSE/spectra/lnhb/Fr-221.txt @@ -1,31 +1,31 @@ 217AT 221FR A DECAY (4.79 M) 217AT H TYP=Full$AUT=Huang Xiaolong$CUT= -- $ 217AT C Evaluation history: Type=Full;Author=Huang Xiaolong;Cutoff date= -- -217AT T Auger electrons and ^X ray energies and emission intensities: -217AT T {U Energy (keV)} {U Intensity } {U Line } +217AT T Auger electrons and X ray energies and emission intensities: +217AT T {U Energy (keV)} {U Intensity} {U Line} 217AT T -217AT T 78.94 0.96 5 XKA2 -217AT T 81.51 1.59 9 XKA1 +217AT T 78.94 0.96 5 XKA2 +217AT T 81.51 1.59 9 XKA1 217AT T -217AT T 91.73 |] XKB3 -217AT T 92.315 |] 0.55 6 XKB1 -217AT T 92.883 |] XKB5II +217AT T 91.73 |] XKB3 +217AT T 92.315 |] 0.55 6 XKB1 +217AT T 92.883 |] XKB5II 217AT T -217AT T 94.846 |] XKB2 -217AT T 95.211 |] 0.18 2 XKB4 -217AT T 95.595 |] XKO23 +217AT T 94.846 |] XKB2 +217AT T 95.211 |] 0.18 2 XKB4 +217AT T 95.595 |] XKO23 217AT T -217AT T 9.8964-16.7291 2.18 7 XL (total) +217AT T 9.8964-16.7291 2.18 7 XL (total) 217AT T 9.8964 XLL 217AT T 11.3052-11.426 XLA 217AT T 12.4653 XLC 217AT T 13.1704-14.6997 XLB 217AT T 15.7394-16.7291 XLG 217AT T -217AT T 60.489-67.031 |] KLL AUGER -217AT T 73.811-81.516 |] 0.114 6 ^KLX AUGER -217AT T 87.1-95.72 |] KXY AUGER -217AT T 5.6-17.4 3.05 10 L AUGER +217AT T 60.489-67.031 |] KLL AUGER +217AT T 73.811-81.516 |] 0.114 6 KLX AUGER +217AT T 87.1-95.72 |] KXY AUGER +217AT T 5.6-17.4 3.05 10 L AUGER 221FR P 0.0 5/2- 4.79 M 2 6457.8 14 217AT N 1.00E0 1.00E0 0.999952 1.00E0 217AT L 0 9/2- 32.3 MS 4 @@ -33,76 +33,76 @@ 217AT L 100.25 2 7/2- 0.5 NS 217AT A 6243 2 1.34 7 120 217AT G 100.25 2 0.156 13M1 11.97 17 -217AT2 G KC=9.66 14$LC=1.758 25$MC=0.416 6 +217AT2 G KC=9.66 14$LC=1.758 25$MC=0.416 6 217AT L 218.12 2 5/2- 217AT A 6126.3 1515.1 2 2.2 217AT G 117.82 3 0.022 16M1 7.58 11 -217AT2 G KC=6.13 9$LC=1.104 16$MC=0.261 4 -217AT G 218.12 2 11.42 15E2 0.367 5 -217AT2 G KC=0.1375 20$LC=0.1701 24$MC=0.0451 7 +217AT2 G KC=6.13 9$LC=1.104 16$MC=0.261 4 +217AT G 218.12 2 11.42 15E2 0.367 5 +217AT2 G KC=0.1375 20$LC=0.1701 24$MC=0.0451 7 217AT L 272.07 4 3/2- 0.27 NS 2 217AT A 6075.9 200.15 3 65 217AT G 53.81 3 0.0145 25M1 14.17 20 -217AT2 G KC=$LC=10.79 15$MC=2.56 4 -217AT G 171.83 3 0.069 9 E2 0.863 12 -217AT2 G KC=0.226 4$LC=0.471 7$MC=0.1257 18 +217AT2 G LC=10.79 15$MC=2.56 4 +217AT G 171.83 3 0.069 9E2 0.863 12 +217AT2 G KC=0.226 4$LC=0.471 7$MC=0.1257 18 217AT L 368.23 4 (3/2)- 217AT A 5979.9 200.39 7 27 -217AT G 96.3 3 0.007 3 M1+E2 0.7 7 5.6 24 -217AT2 G KC=$LC=4.1 18$MC=1.1 5 -217AT G 150.21 3 0.0449 25M1 3.80 5 -217AT2 G KC=3.08 5$LC=0.550 8$MC=0.1303 19 +217AT G 96.3 3 0.007 3M1+E2 0.7 7 5.6 24 +217AT2 G LC=4.1 18$MC=1.1 5 +217AT G 150.21 3 0.0449 25M1 3.80 5 +217AT2 G KC=3.08 5$LC=0.550 8$MC=0.1303 19 217AT L 382.34 4 (7/2)- 217AT A 5965.9 250.064 16117 -217AT G 282.12 9 0.0069 7 [M1E2] 0.41 25 -217AT2 G KC=0.30 23$LC=0.077 17$MC=0.019 4 -217AT G 382.34 4 0.0340 14M1 0.284 4 -217AT2 G KC=0.231 4$LC=0.0406 6$MC=0.00960 14 +217AT G 282.12 9 0.0069 7[M1E2] 0.41 25 +217AT2 G KC=0.30 23$LC=0.077 17$MC=0.019 4 +217AT G 382.34 4 0.0340 14M1 0.284 4 +217AT2 G KC=0.231 4$LC=0.0406 6$MC=0.00960 14 217AT L 410.64 5 13/2- 217AT A 5938.9 200.128 3 36.4 -217AT G 410.64 5 0.1204 25E2 0.0548 8 -217AT2 G KC=0.0344 5$LC=0.01528 22$MC=0.00392 6 +217AT G 410.64 5 0.1204 25E2 0.0548 8 +217AT2 G KC=0.0344 5$LC=0.01528 22$MC=0.00392 6 217AT L 424.35 7 (5/2,7/2,9/2)- 217AT A 5925 3 0.0285 24143 -217AT G 324.10 6 0.0174 12M1 0.446 6 -217AT2 G KC=0.362 5$LC=0.0639 9$MC=0.01510 22 +217AT G 324.10 6 0.0174 12M1 0.446 6 +217AT2 G KC=0.362 5$LC=0.0639 9$MC=0.01510 22 217AT L 537.5 5 (9/2)+ 217AT A 5813 3 0.006 1 197 -217AT G 437.00 5 0.0010 1 -217AT G 537.8 8 0.0045 8 +217AT G 437.00 5 0.0010 1 +217AT G 537.8 8 0.0045 8 217AT L 568.5 3 (7/2,9/2)+ 217AT A 5783 4 0.0031 6 290 -217AT G 468.3 7 0.0018 3 -217AT G 568.5 3 0.0012 4 +217AT G 468.3 7 0.0018 3 +217AT G 568.5 3 0.0012 4 217AT L 577.5 5 (7/2)- 217AT A 5776 3 0.064 4 11.7 -217AT G 208.3 6 0.0051 10[E2] 0.430 8 -217AT2 G KC=0.1519 24$LC=0.206 4$MC=0.0547 11 -217AT G 359.86 4 0.0385 15M1 0.335 5 -217AT2 G KC=0.272 4$LC=0.0479 7$MC=0.01133 16 -217AT G 576.9 4 0.0030 6 [M1] 0.0948 13 -217AT2 G KC=0.0772 11$LC=0.01342 19$MC=0.00317 5 +217AT G 208.3 6 0.0051 10[E2] 0.430 8 +217AT2 G KC=0.1519 24$LC=0.206 4$MC=0.0547 11 +217AT G 359.86 4 0.0385 15M1 0.335 5 +217AT2 G KC=0.272 4$LC=0.0479 7$MC=0.01133 16 +217AT G 576.9 4 0.0030 6[M1] 0.0948 13 +217AT2 G KC=0.0772 11$LC=0.01342 19$MC=0.00317 5 217AT L 652 2 + 217AT A 5697 4 30001E-8 828 -217AT G 652 2 0.0004 4 +217AT G 652 2 0.0004 4 217AT L 664.4 2 + 217AT A 5689 3 0.0025 5 111 217AT G 282.12 9 -217AT G 446.30 8 0.0017 4 E1+M2 -217AT G 562.3 120.005 5 -217AT G 665 2 0.0009 9 +217AT G 446.30 8 0.0017 4E1+M2 +217AT G 562.3 120.005 5 +217AT G 665 2 0.0009 9 217AT L 809.3 2 + 217AT A 5530 250.00010 2 60 -217AT G 809.3 2 0.00010 2 +217AT G 809.3 2 0.00010 2 217AT L 891.9 3 - 217AT A 5500 4038000E-91061 -217AT G 891.9 3 3.8E-5 10 +217AT G 891.9 3 0.00003810 221RA 221FR B- DECAY (4.79 M) 221RA H TYP=Full$AUT=Huang Xiaolong$CUT= -- $ 221RA C Evaluation history: Type=Full;Author=Huang Xiaolong;Cutoff date= -- -221RA T Auger electrons and ^X ray energies and emission intensities: -221RA T {U Energy (keV)} {U Intensity } {U Line } +221RA T Auger electrons and X ray energies and emission intensities: +221RA T {U Energy (keV)} {U Intensity} {U Line} 221RA T 221RA T 221RA T diff --git a/HEN_HOUSE/spectra/lnhb/Fr-223.txt b/HEN_HOUSE/spectra/lnhb/Fr-223.txt index 0305152cf..7a8a8d8a6 100644 --- a/HEN_HOUSE/spectra/lnhb/Fr-223.txt +++ b/HEN_HOUSE/spectra/lnhb/Fr-223.txt @@ -1,345 +1,345 @@ 219AT 223FR A DECAY (22.00 M) 219AT H TYP=Full$AUT=Huang Xiaolong$CUT=31-DEC-2008$ 219AT C Evaluation history: Type=Full;Author=Huang Xiaolong;Cutoff date=31-DEC-2008 -219AT T Auger electrons and ^X ray energies and emission intensities: -219AT T {U Energy (keV)} {U Intensity } {U Line } +219AT T Auger electrons and X ray energies and emission intensities: +219AT T {U Energy (keV)} {U Intensity} {U Line} 219AT T -219AT T 78.94 0.00056 15 XKA2 -219AT T 81.51 0.00092 25 XKA1 +219AT T 78.94 0.00056 15 XKA2 +219AT T 81.51 0.00092 25 XKA1 219AT T -219AT T 91.73 |] XKB3 -219AT T 92.315 |] 0.00031 11 XKB1 -219AT T 92.883 |] XKB5II +219AT T 91.73 |] XKB3 +219AT T 92.315 |] 0.00031 11 XKB1 +219AT T 92.883 |] XKB5II 219AT T -219AT T 94.846 |] XKB2 -219AT T 95.211 |] 0.00011 6 XKB4 -219AT T 95.595 |] XKO23 +219AT T 94.846 |] XKB2 +219AT T 95.211 |] 0.00011 6 XKB4 +219AT T 95.595 |] XKO23 219AT T -219AT T 9.8964-16.7291 0.0054 13 XL (total) +219AT T 9.8964-16.7291 0.0054 13 XL (total) 219AT T 9.8964 XLL 219AT T 11.3052-11.426 XLA 219AT T 12.4653 XLC 219AT T 13.1704-14.6997 XLB 219AT T 15.7394-16.7291 XLG 219AT T -219AT T 60.489-67.031 |] KLL AUGER -219AT T 73.811-81.516 |] 0.000065 20 ^KLX AUGER -219AT T 87.1-95.72 |] KXY AUGER -219AT T 5.6-17.4 0.0076 18 L AUGER +219AT T 60.489-67.031 |] KLL AUGER +219AT T 73.811-81.516 |] 0.00006520 KLX AUGER +219AT T 87.1-95.72 |] KXY AUGER +219AT T 5.6-17.4 0.0076 18 L AUGER 223FR P 0.0 3/2- 22.00 M 7 5562 3 219AT N 5.000E3 5.000E3 0.0002 5.000E3 219AT L 0 9/2- 56 S 4 219AT A 5462 3 17 8 219AT L 58.9 2 (7/2)- 219AT A 5403 3 22 10 -219AT G 58.9 2 0.0008 3 M1 10.87 19 -219AT2 G KC=$LC=8.27 15$MC=1.96 4 +219AT G 58.9 2 0.0008 3M1 10.87 19 +219AT2 G LC=8.27 15$MC=1.96 4 219AT L 150.9 2 5/2- 219AT A 5314 4 27 12 -219AT G 150.9 2 0.0056 5 E2 1.417 21 -219AT2 G KC=0.287 4$LC=0.836 13$MC=0.224 4 +219AT G 150.9 2 0.0056 5E2 1.417 21 +219AT2 G KC=0.287 4$LC=0.836 13$MC=0.224 4 219AT L 175.04 213/2- 219AT A 5291 4 30 13 219AT G 24.14 3 219AT L 296.2 4 3/2- 219AT A 5172 5 4.5 25 -219AT G 145.3 3 0.0002 1 M1+(E2) 2.9 13 -219AT2 G KC=1.8 16$LC=0.8 2$MC=0.20 6 +219AT G 145.3 3 0.0002 1M1+(E2) 2.9 13 +219AT2 G KC=1.8 16$LC=0.8 2$MC=0.20 6 223RA 223FR B- DECAY (22.00 M) 223RA H TYP=Full$AUT=Huang Xiaolong$CUT=31-DEC-2008$ 223RA C Evaluation history: Type=Full;Author=Huang Xiaolong;Cutoff date=31-DEC-2008 -223RA T Auger electrons and ^X ray energies and emission intensities: -223RA T {U Energy (keV)} {U Intensity } {U Line } +223RA T Auger electrons and X ray energies and emission intensities: +223RA T {U Energy (keV)} {U Intensity} {U Line} 223RA T -223RA T 85.43 1.44 19 XKA2 -223RA T 88.47 2.3 3 XKA1 +223RA T 85.43 1.44 19 XKA2 +223RA T 88.47 2.3 3 XKA1 223RA T -223RA T 99.432 |] XKB3 -223RA T 100.13 |] 0.83 11 XKB1 -223RA T 100.738 |] XKB5II +223RA T 99.432 |] XKB3 +223RA T 100.13 |] 0.83 11 XKB1 +223RA T 100.738 |] XKB5II 223RA T -223RA T 102.89 |] XKB2 -223RA T 103.295 |] 0.27 4 XKB4 -223RA T 103.74 |] XKO23 +223RA T 102.89 |] XKB2 +223RA T 103.295 |] 0.27 4 XKB4 +223RA T 103.74 |] XKO23 223RA T -223RA T 10.6241-18.3539 24 3 XL (total) +223RA T 10.6241-18.3539 24 3 XL (total) 223RA T 10.6241 XLL 223RA T 12.1957-12.3381 XLA 223RA T 13.6624 XLC 223RA T 14.2373-16.1261 XLB 223RA T 17.2756-18.3539 XLG 223RA T -223RA T 65.149-72.729 |] KLL AUGER -223RA T 79.721-88.466 |] 0.159 21 ^KLX AUGER -223RA T 94.27-103.91 |] KXY AUGER -223RA T 5.71-12.04 29 4 L AUGER +223RA T 65.149-72.729 |] KLL AUGER +223RA T 79.721-88.466 |] 0.159 21 KLX AUGER +223RA T 94.27-103.91 |] KXY AUGER +223RA T 5.71-12.04 29 4 L AUGER 223FR P 0.0 3/2- 22.00 M 7 1149.2 9 223RA N 1.00E0 1.00E0 0.9998 1.00E0 223RA L 0 3/2+ 11.43 D 3 223RA B 1149.2 9 1 7.6 223RAS B EAV=380.8 4 223RA L 29.854 18(5/2)+ -223RA B 1119.3 9 6 6 6.8 1U +223RA B 1119.3 9 6 6 6.8 1 223RAS B EAV=369.4 4 223RA G 29.78 4 0.070 17M1+E2 0.30 3 370 50 -223RA2 G KC=$LC=280 40$MC=72 10 +223RA2 G LC=280 40$MC=72 10 223RA L 50.101 163/2- 223RA B 1099.1 9 67 13 5.68 223RAS B EAV=361.7 4 -223RA G 20.27 5 1.4 3 [E1] 7.76 22 -223RA2 G KC=$LC=5.77 16$MC=1.50 3 -223RA G 50.10 2 33 7 E1 0.696 10 -223RA2 G KC=$LC=0.526 8$MC=0.1288 18 +223RA G 20.27 5 1.4 3[E1] 7.76 22 +223RA2 G LC=5.77 16$MC=1.50 3 +223RA G 50.10 2 33 7E1 0.696 10 +223RA2 G LC=0.526 8$MC=0.1288 18 223RA L 61.435 23(7/2)+ -223RA B 1087.8 9 0.27 19 8.1 3U +223RA B 1087.8 9 0.27 19 8.1 1U 223RAS B EAV=357.4 4 -223RA G 31.69 5 1350E-6 0 M1+E2 0.28 6 260 80 -223RA2 G KC=$LC=190 60$MC=50 15 -223RA G 61.43 5 0.0035 7 E2 96.5 14 -223RA2 G KC=$LC=71.0 11$MC=19.3 3 +223RA G 31.69 5 0.00135 M1+E2 0.28 6 260 80 +223RA2 G LC=190 60$MC=50 15 +223RA G 61.43 5 0.0035 7E2 96.5 14 +223RA2 G LC=71.0 11$MC=19.3 3 223RA L 79.649 16(5/2)- -223RA B 1069.6 9 15 3 6.29 2 +223RA B 1069.6 9 15 3 6.29 223RAS B EAV=350.5 4 -223RA G 49.80 5 2.5 6 E1 0.708 10 -223RA2 G KC=$LC=0.535 8$MC=0.1309 19 -223RA G 79.65 2 9.0 18E1 0.202 3 -223RA2 G KC=$LC=0.1530 22$MC=0.0370 6 +223RA G 49.80 5 2.5 6E1 0.708 10 +223RA2 G LC=0.535 8$MC=0.1309 19 +223RA G 79.65 2 9.0 18E1 0.202 3 +223RA2 G LC=0.1530 22$MC=0.0370 6 223RA L 123.724 23(7/2)- -223RA B 1025.5 9 0.24 6 8.02 +223RA B 1025.5 9 0.24 6 8.02 2 223RAS B EAV=333.9 4 -223RA G 44.0 1 1350E-6 0 M1+E2 0.52 4 131 12 -223RA2 G KC=$LC=97 9$MC=25.5 24 -223RA G 62.31 6 0.016 7 E1 0.389 6 -223RA2 G KC=$LC=0.294 5$MC=0.0716 11 -223RA G 73.5 1 0.0013 9 E2 40.8 6 -223RA2 G KC=$LC=30.0 5$MC=8.16 13 +223RA G 44.0 1 0.00135 M1+E2 0.52 4 131 12 +223RA2 G LC=97 9$MC=25.5 24 +223RA G 62.31 6 0.016 7E1 0.389 6 +223RA2 G LC=0.294 5$MC=0.0716 11 +223RA G 73.5 1 0.0013 9E2 40.8 6 +223RA2 G LC=30.0 5$MC=8.16 13 223RA G 93.88 5 0.059 14E1 0.1305 18 -223RA2 G KC=$LC=0.0989 14$MC=0.0239 4 +223RA2 G LC=0.0989 14$MC=0.0239 4 223RA L 234.747 20(5/2)+ -223RA B 914.5 9 9.1 17 6.27 1U +223RA B 914.5 9 9.1 17 6.27 1 223RAS B EAV=292.6 4 223RA G 111.05 3 0.0049 14 -223RA G 155.5 5 2700E-6 0 +223RA G 155.5 5 0.0027 223RA G 173.35 5 0.115 22M1E2 2.1 12 -223RA2 G KC=1.4 12$LC=0.53 5$MC=0.136 20 -223RA G 184.65 5 0.22 5 E1 0.1092 15 -223RA2 G KC=0.0868 13$LC=0.01701 24$MC=0.00407 6 -223RA G 204.85 5 0.92 18M1+E2 -0.12 7 2.02 5 -223RA2 G KC=1.62 4$LC=0.304 5$MC=0.0726 11 -223RA G 234.70 5 2.7 5 M1(+E2) -0.07 2 1.393 16 -223RA2 G KC=1.120 16$LC=0.207 3$MC=0.0495 7 +223RA2 G KC=1.4 12$LC=0.53 5$MC=0.136 20 +223RA G 184.65 5 0.22 5E1 0.1092 15 +223RA2 G KC=0.0868 13$LC=0.01701 24$MC=0.00407 6 +223RA G 204.85 5 0.92 18M1+E2 -0.12 7 2.02 5 +223RA2 G KC=1.62 4$LC=0.304 5$MC=0.0726 11 +223RA G 234.70 5 2.7 5M1(+E2) -0.07 2 1.393 16 +223RA2 G KC=1.120 16$LC=0.207 3$MC=0.0495 7 223RA L 280.19 4 (7/2)+ -223RA B 869.0 9 0.004 4 9.5 3U +223RA B 869.0 9 0.004 4 9.5 1U 223RAS B EAV=275.9 4 223RA G 200.7 2 0.0027 10 223RA G 218.80 5 0.0086 17M1 1.701 24 -223RA2 G KC=1.368 20$LC=0.252 4$MC=0.0603 9 -223RA G 250.25 5 1600E-5 0 M1 1.170 16 -223RA2 G KC=0.941 14$LC=0.1733 25$MC=0.0414 6 -223RA G 280.7 5 3000E-7 0 +223RA2 G KC=1.368 20$LC=0.252 4$MC=0.0603 9 +223RA G 250.25 5 0.016 M1 1.170 16 +223RA2 G KC=0.941 14$LC=0.1733 25$MC=0.0414 6 +223RA G 280.7 5 0.0003 223RA L 286.07 4 1/2+ -223RA B 863.1 9 0.032 9 8.64 1U +223RA B 863.1 9 0.032 9 8.64 1 223RAS B EAV=273.8 4 -223RA G 236.05 5 0.027 8 E1 0.0610 9 -223RA2 G KC=0.0489 7$LC=0.00922 13$MC=0.00220 3 -223RA G 256.18 5 0.020 4 E2 0.250 4 -223RA2 G KC=0.0983 14$LC=0.1117 16$MC=0.0299 5 -223RA G 286.0 2 0.0046 10M1+E2 0.5 4 -223RA2 G KC=0.4 3$LC=0.096 24$MC=0.024 5 +223RA G 236.05 5 0.027 8E1 0.0610 9 +223RA2 G KC=0.0489 7$LC=0.00922 13$MC=0.00220 3 +223RA G 256.18 5 0.020 4E2 0.250 4 +223RA2 G KC=0.0983 14$LC=0.1117 16$MC=0.0299 5 +223RA G 286.0 2 0.0046 10M1+E2 0.5 4 +223RA2 G KC=0.4 3$LC=0.096 24$MC=0.024 5 223RA L 329.82 3 3/2- 223RA B 819.4 9 0.049 10 8.37 223RAS B EAV=257.9 4 -223RA G 43.5 2 2200E-6 0 E1 1.015 19 -223RA2 G KC=$LC=0.767 15$MC=0.189 4 -223RA G 205.6 2 0.0059 11E2 0.530 8 -223RA2 G KC=0.1533 22$LC=0.277 4$MC=0.0747 11 -223RA G 250.25 5 3000E-6 0 M1+E2 -2.1 4 0.44 7 -223RA2 G KC=0.26 6$LC=0.132 4$MC=0.0344 8 -223RA G 299.95 5 0.020 4 E1 0.0352 5 -223RA2 G KC=0.0284 4$LC=0.00518 8$MC=1234E-6 18 -223RA G 329.80 5 0.024 5 (E1) 0.0285 4 -223RA2 G KC=0.0230 4$LC=0.00415 6$MC=9.88E-4 14 +223RA G 43.5 2 0.0022 E1 1.015 19 +223RA2 G LC=0.767 15$MC=0.189 4 +223RA G 205.6 2 0.0059 11E2 0.530 8 +223RA2 G KC=0.1533 22$LC=0.277 4$MC=0.0747 11 +223RA G 250.25 5 0.003 M1+E2 -2.1 4 0.44 7 +223RA2 G KC=0.26 6$LC=0.132 4$MC=0.0344 8 +223RA G 299.95 5 0.020 4E1 0.0352 5 +223RA2 G KC=0.0284 4$LC=0.00518 8$MC=1234E-6 18 +223RA G 329.80 5 0.024 5(E1) 0.0285 4 +223RA2 G KC=0.0230 4$LC=0.00415 6$MC=9.88E-4 14 223RA L 334.29 4 5/2+ -223RA B 814.9 9 0.042 9 8.43 1U +223RA B 814.9 9 0.042 9 8.43 1 223RAS B EAV=256.3 4 223RA G 210.60 5 0.0097 19E1 0.0798 11 -223RA2 G KC=0.0637 9$LC=0.01222 18$MC=0.00292 4 -223RA G 254.6 2 0.0057 12E1 0.0512 7 -223RA2 G KC=0.0411 6$LC=0.00767 11$MC=0.00183 3 -223RA G 272.8 2 0.004 1 M1+E2 0.6 4 -223RA2 G KC=0.4 4$LC=0.112 25$MC=0.028 5 +223RA2 G KC=0.0637 9$LC=0.01222 18$MC=0.00292 4 +223RA G 254.6 2 0.0057 12E1 0.0512 7 +223RA2 G KC=0.0411 6$LC=0.00767 11$MC=0.00183 3 +223RA G 272.8 2 0.004 1M1+E2 0.6 4 +223RA2 G KC=0.4 4$LC=0.112 25$MC=0.028 5 223RA G 304.40 5 0.0086 17M1+E2(+) 0.26 4 0.647 14 -223RA2 G KC=0.518 12$LC=0.0978 16$MC=0.0234 4 +223RA2 G KC=0.518 12$LC=0.0978 16$MC=0.0234 4 223RA G 334.30 6 0.0084 17M1+E2 -0.61 4 0.414 13 -223RA2 G KC=0.325 11$LC=0.0674 14$MC=0.0164 3 +223RA2 G KC=0.325 11$LC=0.0674 14$MC=0.0164 3 223RA L 342.51 4 3/2+ -223RA B 806.7 9 0.037 8 8.47 +223RA B 806.7 9 0.037 8 8.47 223RAS B EAV=253.3 4 -223RA G 262.9 2 0.0035 11E1 0.0475 7 -223RA2 G KC=0.0382 6$LC=0.00709 10$MC=1692E-6 24 -223RA G 280.7 5 3000E-7 0 -223RA G 312.65 5 0.016 4 M1+E2 0.16 3 0.621 10 -223RA2 G KC=0.499 9$LC=0.0924 14$MC=0.0221 4 -223RA G 342.50 7 0.0116 24M1+E2 1.29 2 0.250 5 -223RA2 G KC=0.183 4$LC=0.0501 8$MC=1252E-5 2 +223RA G 262.9 2 0.0035 11E1 0.0475 7 +223RA2 G KC=0.0382 6$LC=0.00709 10$MC=1692E-6 24 +223RA G 280.7 5 0.0003 +223RA G 312.65 5 0.016 4M1+E2 0.16 3 0.621 10 +223RA2 G KC=0.499 9$LC=0.0924 14$MC=0.0221 4 +223RA G 342.50 7 0.0116 24M1+E2 1.29 2 0.250 5 +223RA2 G KC=0.183 4$LC=0.0501 8$MC=1252E-5 2 223RA L 350.53 101/2- -223RA G 350.5 2 0.0027 15E1 0.0249 4 -223RA2 G KC=0.0202 3$LC=0.00361 5$MC=8.58E-4 12 +223RA G 350.5 2 0.0027 15E1 0.0249 4 +223RA2 G KC=0.0202 3$LC=0.00361 5$MC=8.58E-4 12 223RA L 369.342 20(5/2)- -223RA B 779.9 9 1.8 4 6.73 2 +223RA B 779.9 9 1.8 4 6.73 223RAS B EAV=243.7 4 223RA G 89.08 100.054 11 -223RA G 134.60 2 0.5 1 [E1] 0.234 3 -223RA2 G KC=0.184 3$LC=0.0383 6$MC=0.00921 13 -223RA G 245.60 5 0.019 4 -223RA G 289.67 5 0.21000 0 +223RA G 134.60 2 0.5 1[E1] 0.234 3 +223RA2 G KC=0.184 3$LC=0.0383 6$MC=0.00921 13 +223RA G 245.60 5 0.019 4 +223RA G 289.67 5 0.21 223RA G 307.93 5 0.0013 13 -223RA G 319.25 5 0.46 9 M1+E2 0.18 3 0.583 10 -223RA2 G KC=0.468 8$LC=0.0869 13$MC=0.0208 3 +223RA G 319.25 5 0.46 9M1+E2 0.18 3 0.583 10 +223RA2 G KC=0.468 8$LC=0.0869 13$MC=0.0208 3 223RA G 339.50 5 0.062 13 223RA G 369.32 5 0.089 18 223RA L 376.09 15(7/2)- -223RA B 773.1 100.0046 12 9.31 +223RA B 773.1 100.0046 12 9.31 2 223RAS B EAV=241.3 4 -223RA G 296.5 2 0.0013 4 M1+E2 -0.13 2 0.723 9 -223RA2 G KC=0.581 9$LC=0.1074 16$MC=0.0257 4 -223RA G 314.6 2 0.0022 7 E1 0.0316 5 -223RA2 G KC=0.0255 4$LC=0.00463 7$MC=1103E-6 16 +223RA G 296.5 2 0.0013 4M1+E2 -0.13 2 0.723 9 +223RA2 G KC=0.581 9$LC=0.1074 16$MC=0.0257 4 +223RA G 314.6 2 0.0022 7E1 0.0316 5 +223RA2 G KC=0.0255 4$LC=0.00463 7$MC=1103E-6 16 223RA L 593.94 6 + -223RA B 555.3 9 0.013 3 8.38 +223RA B 555.3 9 0.013 3 8.38 223RAS B EAV=165.6 4 -223RA G 307.93 5 0.012 3 -223RA G 469.3 2 1000E-6 0 +223RA G 307.93 5 0.012 3 +223RA G 469.3 2 0.001 223RA L 782.54 171/2,3/2+ -223RA B 366.7 100.00111 22 8.85 1U +223RA B 366.7 100.00111 22 8.85 1 223RAS B EAV=104.1 3 -223RA G 439.6 3 0.00030 8 -223RA G 452.9 2 8000E-7 0 +223RA G 439.6 3 0.00030 8 +223RA G 452.9 2 0.0008 223RA L 787.13 5 5/2+ -223RA B 362.1 9 0.019 4 7.6 1U +223RA B 362.1 9 0.019 4 7.6 1 223RAS B EAV=102.7 3 -223RA G 444.5 3 0.0011 4 -223RA G 452.9 2 8000E-7 0 -223RA G 457.5 2 8000E-7 0 -223RA G 506.9 2 0.0022 7 -223RA G 552.3 2 0.0027 8 -223RA G 663.7 3 0.0011 4 -223RA G 708.3 3 0.0013 4 -223RA G 737.4 3 0.0009 3 +223RA G 444.5 3 0.0011 4 +223RA G 452.9 2 0.0008 +223RA G 457.5 2 0.0008 +223RA G 506.9 2 0.0022 7 +223RA G 552.3 2 0.0027 8 +223RA G 663.7 3 0.0011 4 +223RA G 708.3 3 0.0013 4 +223RA G 737.4 3 0.0009 3 223RA G 757.20 5 0.0076 20 -223RA G 787.6 2 0.0003 3 +223RA G 787.6 2 0.0003 3 223RA L 803.77 3 3/2,5/2+ -223RA B 345.4 9 0.14 3 6.67 +223RA B 345.4 9 0.14 3 6.67 223RAS B EAV=97.5 3 -223RA G 434.4 1 0.0022 7 -223RA G 469.3 2 1000E-6 0 +223RA G 434.4 1 0.0022 7 +223RA G 469.3 2 0.001 223RA G 569.03 8 0.049 11 -223RA G 724.15 5 0.014 4 -223RA G 742.4 3 0.0011 4 +223RA G 724.15 5 0.014 4 +223RA G 742.4 3 0.0011 4 223RA G 753.65 5 0.0094 22 223RA G 803.77 5 0.059 14 223RA L 805.38 101/2,3/2,5/2+ -223RA B 343.8 9 0.0040 8 8.21 1U +223RA B 343.8 9 0.0040 8 8.21 1 223RAS B EAV=97.0 3 -223RA G 475.4 1 2700E-6 0 -223RA G 806.0 2 0.0013 4 +223RA G 475.4 1 0.0027 +223RA G 806.0 2 0.0013 4 223RA L 823.22 7 1/2,3/2,5/2+ -223RA B 326.0 9 0.014 3 7.59 1U +223RA B 326.0 9 0.014 3 7.59 1 223RAS B EAV=91.5 3 -223RA G 480.9 3 0.0013 4 -223RA G 493.4 2 0.0024 7 -223RA G 537.2 2 3200E-6 0 +223RA G 480.9 3 0.0013 4 +223RA G 493.4 2 0.0024 7 +223RA G 537.2 2 0.0032 223RA G 823.20 7 0.0070 16 223RA L 825.94 4 (3/2)+ 223RA B 323.3 9 0.54 10 5.99 223RAS B EAV=90.7 3 -223RA G 475.4 1 3000E-6 0 +223RA G 475.4 1 0.003 223RA G 539.8 2 0.0059 18 -223RA G 545.4 4 0.00030 8 -223RA G 746.30 5 0.020 5 -223RA G 775.83 5 0.45 9 +223RA G 545.4 4 0.00030 8 +223RA G 746.30 5 0.020 5 +223RA G 775.83 5 0.45 9 223RA G 825.95 7 0.054 13 223RA L 842.25 5 3/2,5/2+ -223RA B 306.9 9 0.035 7 7.11 +223RA B 306.9 9 0.035 7 7.11 223RAS B EAV=85.7 3 -223RA G 556.3 3 0.0011 4 -223RA G 607.6 3 0.0022 7 -223RA G 762.6 2 0.0024 7 -223RA G 780.8 1 0.003 1 +223RA G 556.3 3 0.0011 4 +223RA G 607.6 3 0.0022 7 +223RA G 762.6 2 0.0024 7 +223RA G 780.8 1 0.003 1 223RA G 792.2 3 0.00054 14 -223RA G 812.40 6 0.021 5 +223RA G 812.40 6 0.021 5 223RA G 842.2 1 0.0049 11 223RA L 846.37 3 5/2+ -223RA B 302.8 9 0.088 18 6.69 1U +223RA B 302.8 9 0.088 18 6.69 1 223RAS B EAV=84.4 3 -223RA G 516.7 2 0.0032 8 -223RA G 722.65 5 0.038 9 -223RA G 766.64 5 0.022 5 +223RA G 516.7 2 0.0032 8 +223RA G 722.65 5 0.038 9 +223RA G 766.64 5 0.022 5 223RA G 784.93 5 0.0086 21 223RA G 796.22 5 0.0108 25 -223RA G 846.85 100.005 3 +223RA G 846.85 100.005 3 223RA L 867.34 6 3/2,5/2+ -223RA B 281.9 9 0.025 5 7.14 +223RA B 281.9 9 0.025 5 7.14 223RAS B EAV=78.1 3 223RA G 524.8 2 0.0043 12 -223RA G 533.1 3 0.0019 7 -223RA G 537.2 2 1900E-6 0 -223RA G 581.3 4 0.0013 4 -223RA G 632.7 3 0.0022 7 -223RA G 787.6 2 0.0024 7 +223RA G 533.1 3 0.0019 7 +223RA G 537.2 2 0.0019 +223RA G 581.3 4 0.0013 4 +223RA G 632.7 3 0.0022 7 +223RA G 787.6 2 0.0024 7 223RA G 837.5 1 0.0097 21 -223RA G 867.4 1 0.0016 4 +223RA G 867.4 1 0.0016 4 223RA L 905.9 4 + -223RA B 243.3 100.0011 4 8.29 +223RA B 243.3 100.0011 4 8.29 223RAS B EAV=66.6 3 -223RA G 576.1 4 0.0011 4 +223RA G 576.1 4 0.0011 4 223RA L 926.56 7 3/2,5/2+ 223RA B 222.6 9 0.106 22 6.18 223RAS B EAV=60.5 3 223RA G 592.3 2 0.0032 10 -223RA G 596.9 4 0.0008 3 +223RA G 596.9 4 0.0008 3 223RA G 846.85 100.049 13 -223RA G 876.5 1 0.038 9 -223RA G 896.7 2 0.013 3 -223RA G 926.5 3 0.0016 4 +223RA G 876.5 1 0.038 9 +223RA G 896.7 2 0.013 3 +223RA G 926.5 3 0.0016 4 223RA L 940.78 133/2,5/2- 223RA B 208.4 9 0.0051 12 7.41 223RAS B EAV=56.3 3 -223RA G 816.5 2 0.0013 4 -223RA G 911.3 3 0.0008 3 -223RA G 941.2 3 0.0030 8 +223RA G 816.5 2 0.0013 4 +223RA G 911.3 3 0.0008 3 +223RA G 941.2 3 0.0030 8 223RA L 943.26 9 3/2,5/2+ 223RA B 205.9 9 0.0082 18 7.19 223RAS B EAV=55.6 3 223RA G 600.7 4 0.00054 14 -223RA G 613.6 4 0.0011 4 -223RA G 863.6 1 0.0038 9 -223RA G 893.1 2 0.0024 7 +223RA G 613.6 4 0.0011 4 +223RA G 863.6 1 0.0038 9 +223RA G 893.1 2 0.0024 7 223RA G 913.6 3 0.00041 14 223RA L 957.72 113/2,5/2+ -223RA B 191.5 9 0.020 4 6.7 +223RA B 191.5 9 0.020 4 6.7 223RAS B EAV=51.5 3 223RA G 671.9 4 0.00054 14 -223RA G 833.9 2 0.0013 4 -223RA G 878.1 2 0.0032 8 -223RA G 907.6 2 0.014 3 -223RA G 958.0 7 0.00035 8 +223RA G 833.9 2 0.0013 4 +223RA G 878.1 2 0.0032 8 +223RA G 907.6 2 0.014 3 +223RA G 958.0 7 0.00035 8 223RA L 1019.3 4 + 223RA B 129.9 100.00046 12 7.82 223RAS B EAV=34.1 3 -223RA G 969.2 4 0.00032 8 -223RA G 989.4 5 0.00014 3 +223RA G 969.2 4 0.00032 8 +223RA G 989.4 5 0.00014 3 223RA L 1024.59 23 + -223RA B 124.6 100.0004 1 7.82 +223RA B 124.6 100.0004 1 7.82 223RAS B EAV=32.7 3 -223RA G 975.2 5 0.00016 5 -223RA G 994.3 3 0.00011 3 -223RA G 1025.1 5 0.00014 3 +223RA G 975.2 5 0.00016 5 +223RA G 994.3 3 0.00011 3 +223RA G 1025.1 5 0.00014 3 223RA L 1028.94 25 - -223RA B 120.3 100.0012 3 7.3 +223RA B 120.3 100.0012 3 7.3 223RAS B EAV=31.5 3 -223RA G 949.3 4 0.00032 8 +223RA G 949.3 4 0.00032 8 223RA G 978.7 4 0.00067 12 -223RA G 999.3 5 0.00019 4 +223RA G 999.3 5 0.00019 4 diff --git a/HEN_HOUSE/spectra/lnhb/Ga-66.txt b/HEN_HOUSE/spectra/lnhb/Ga-66.txt index 07046fed8..d38ab0bad 100644 --- a/HEN_HOUSE/spectra/lnhb/Ga-66.txt +++ b/HEN_HOUSE/spectra/lnhb/Ga-66.txt @@ -1,243 +1,243 @@ 66ZN 66GA EC DECAY (9.49 H) - 66ZN T Auger electrons and ^X ray energies and emission intensities: - 66ZN T {U Energy (keV)} {U Intensity } {U Line } + 66ZN T Auger electrons and X ray energies and emission intensities: + 66ZN T {U Energy (keV)} {U Intensity} {U Line} 66ZN T - 66ZN T 8.61587 5.8 3 XKA2 - 66ZN T 8.63896 11.3 6 XKA1 + 66ZN T 8.61587 5.8 3 XKA2 + 66ZN T 8.63896 11.3 6 XKA1 66ZN T - 66ZN T 9.5721 |] 2.42 12 XKB1 - 66ZN T 9.6499 |] XKB5II + 66ZN T 9.5721 |] 2.42 12 XKB1 + 66ZN T 9.6499 |] XKB5II 66ZN T - 66ZN T 9.6581 |] XKB2 + 66ZN T 9.6581 |] XKB2 66ZN T - 66ZN T 0.884-1.035 0.597 19 XL (total) + 66ZN T 0.884-1.035 0.597 19 XL (total) 66ZN T 0.884 XLL 66ZN T -1.035 XLB 66ZN T - 66ZN T 7.21-7.55 |] KLL AUGER - 66ZN T 8.31-8.63 |] 20.6 10 ^KLX AUGER - 66ZN T 9.39-9.65 |] KXY AUGER - 66ZN T 0.732-0.997 57.2 16 L AUGER + 66ZN T 7.21-7.55 |] KLL AUGER + 66ZN T 8.31-8.63 |] 20.6 10 KLX AUGER + 66ZN T 9.39-9.65 |] KXY AUGER + 66ZN T 0.732-0.997 57.2 16 L AUGER 66GA P 0.0 0+ 9.49 H 7 5175 3 66ZN N 1.0 1.0 1 1.0 - 66ZN G 171.9 2 0.0104 9 - 66ZN G 3724.8 100.0024 4 - 66ZN G 3806.3 100.0024 4 + 66ZN G 171.9 2 0.0104 9 + 66ZN G 3724.8 100.0024 4 + 66ZN G 3806.3 100.0024 4 66ZN G 3827.5 8 0.0069 10 66ZN L 0 0+ STABLE - 66ZN E 50 4 0.47 4 7.88 - 66ZN2 E EAV=1904.1 15$CK=0.8850 15$CL=0.0978 12$CM=0.0161 4$CN= $CO= + 66ZN E 50 40.47 47.88 + 66ZN2 E EAV=1904.1 15$CK=0.8850 15$CL=0.0978 12$CM=0.0161 4 66ZN L 1039.2268 212+ 1.65 PS 6 - 66ZN G 1039.220 3 37 3 E2 + 66ZN G 1039.2200 3037 3E2 66ZN L 1872.7633 242+ 0.19 PS 7 - 66ZN G 833.5324 215.9 5 M1+E2 -1.6 2 + 66ZN G 833.5324 215.9 5M1+E2 -1.6 2 66ZN G 1872.740 6 0.0229 24[E2] 66ZN L 2372.352 4 0+ - 66ZN E 0.30 3 0.038 3 8.46 - 66ZN2 E EAV=781.6 14$CK=0.8847 15$CL=0.0980 12$CM=0.0162 4$CN= $CO= + 66ZN E 0.30 30.038 38.46 + 66ZN2 E EAV=781.6 14$CK=0.8847 15$CL=0.0980 12$CM=0.0162 4 66ZN G 499.590 6 0.0048 12E2+M3 - 66ZN G 1333.112 5 1.17 9 E2 + 66ZN G 1333.112 5 1.17 9E2 66ZN L 2780.156 7 2+ 0.26 PS 7 66ZN G 907.390 190.0218 23M1+E2 0.13 24 - 66ZN G 1740.904 160.029 4 M1+E2 0.33 28 + 66ZN G 1740.904 160.029 4M1+E2 0.33 28 66ZN G 2780.095 160.123 10E2 66ZN L 2826.69 5 3- - 66ZN E 0.0053 8 0.0017 3 9.66 3 - 66ZN2 E EAV=575.3 14$CK=0.8846 15$CL=0.0981 12$CM=0.0162 4$CN= $CO= + 66ZN E 0.0053 80.0017 39.66 3 + 66ZN2 E EAV=575.3 14$CK=0.8846 15$CL=0.0981 12$CM=0.0162 4 66ZN G 953.93 9 0.00100 13 66ZN G 1787.44 9 0.0089 10(E1) 66ZN L 2938.072 3 2+ 0.044 PS 16 - 66ZN G 1065.305 9 0.0023 5 - 66ZN G 1898.823 8 0.39 3 (M1+E2) 0.03 1 + 66ZN G 1065.305 9 0.0023 5 + 66ZN G 1898.823 8 0.39 3(M1+E2) 0.03 1 66ZN L 3105.038 4 0+ - 66ZN G 1232.264 8 0.50 4 - 66ZN G 2065.778 7 0.031 3 + 66ZN G 1232.264 8 0.50 4 + 66ZN G 2065.778 7 0.031 3 66ZN L 3212.580 8 2+ - 66ZN G 2173.319 150.084 8 - 66ZN G 3212.499 190.0019 4 + 66ZN G 2173.319 150.084 8 + 66ZN G 3212.499 190.0019 4 66ZN L 3228.884 3 1+ 0.12 PS 3 - 66ZN E 3.7 3 3.7 3 6.14 - 66ZN2 E EAV=397.1 14$CK=0.8844 15$CL=0.0982 12$CM=0.0162 4$CN= $CO= - 66ZN G 290.8105 110.049 4 - 66ZN G 448.73 2 0.107 9 M1+E2 -0.02 3 + 66ZN E 3.7 33.7 36.14 + 66ZN2 E EAV=397.1 14$CK=0.8844 15$CL=0.0982 12$CM=0.0162 4 + 66ZN G 290.8105 110.049 4 + 66ZN G 448.730 200.107 9M1+E2 -0.02 3 66ZN G 856.527 100.111 11 - 66ZN G 1356.104 9 0.36 5 - 66ZN G 2189.616 6 5.3 4 M1+E2 0.12 2 + 66ZN G 1356.104 9 0.36 5 + 66ZN G 2189.616 6 5.3 4M1+E2 0.12 2 66ZN G 3228.800 6 1.51 12M1+E2 66ZN L 3331.440 6 2+ 0.083 PS 17 - 66ZN G 551.284 220.0070 8 + 66ZN G 551.284 220.0070 8 66ZN G 1458.662 120.096 23M1+E2 -0.010 9 66ZN G 2292.171 130.0170 18 66ZN G 3331.351 140.0023 30 66ZN L 3380.942 4 1- - 66ZN E 0.70 6 1.31 116.53 1 - 66ZN2 E EAV=331.1 13$CK=0.8843 15$CL=0.0983 12$CM=0.0162 4$CN= $CO= + 66ZN E 0.70 61.31 116.53 1 + 66ZN2 E EAV=331.1 13$CK=0.8843 15$CL=0.0983 12$CM=0.0162 4 66ZN G 442.873 140.01554 16 66ZN G 600.788 210.0135 14 - 66ZN G 1008.588 120.059 9 - 66ZN G 1508.158 7 0.55 4 - 66ZN G 2341.673 110.0032 7 + 66ZN G 1008.588 120.059 9 + 66ZN G 1508.158 7 0.55 4 + 66ZN G 2341.673 110.0032 7 66ZN G 3380.850 6 1.46 12 66ZN L 3427.404 181,2- - 66ZN E 0.0020 5 0.0047 118.95 1 - 66ZN2 E EAV=311.1 13$CK=0.8843 15$CL=0.0983 12$CM=0.0162 4$CN= $CO= + 66ZN E 0.0020 50.0047 118.95 1 + 66ZN2 E EAV=311.1 13$CK=0.8843 15$CL=0.0983 12$CM=0.0162 4 66ZN G 1554.62 3 0.0183 18 66ZN L 3432.406 4 1- 30 FS 13 - 66ZN E 0.16 2 0.39 4 7.03 1 - 66ZN2 E EAV=308.9 13$CK=0.8843 15$CL=0.0983 12$CM=0.0162 4$CN= $CO= - 66ZN G 494.336 130.0056 9 + 66ZN E 0.16 20.39 47.03 1 + 66ZN2 E EAV=308.9 13$CK=0.8843 15$CL=0.0983 12$CM=0.0162 4 + 66ZN G 494.336 130.0056 9 66ZN G 1060.051 110.0155 17 66ZN G 1559.627 100.0219 23 - 66ZN G 2393.129 7 0.23 2 E1 + 66ZN G 2393.129 7 0.23 2E1 66ZN G 3432.309 7 0.288 24 66ZN L 3507.247 232+ - 66ZN G 680.56 100.0015 4 - 66ZN G 1634.46 7 0.0035 6 + 66ZN G 680.56 100.0015 4 + 66ZN G 1634.46 7 0.0035 6 66ZN G 2467.97 7 0.0084 10 66ZN L 3531.691 140+ 66ZN G 2492.42 3 0.0222 23 66ZN L 3576.368 224+ - 66ZN G 749.68 100.0014 4 - 66ZN G 796.21 5 0.0029 7 + 66ZN G 749.68 100.0014 4 + 66ZN G 796.21 5 0.0029 7 66ZN G 1703.59 5 0.0054 19 66ZN G 2537.09 5 0.0051 12 66ZN L 3670.72 5 2+ - 66ZN G 1797.94 9 0.0019 5 + 66ZN G 1797.94 9 0.0019 5 66ZN G 2631.44 9 0.0029 11 66ZN L 3738.207 21 + 9.7 FS 25 - 66ZN E 0.0009 3 0.015 6 8.27 - 66ZN2 E EAV=179.2 13$CK=0.8841 15$CL=0.0985 12$CM=0.0163 4$CN= $CO= - 66ZN G 800.13 5 0.0010 5 - 66ZN G 2698.92 5 0.0037 7 + 66ZN E 0.0009 30.015 68.27 + 66ZN2 E EAV=179.2 13$CK=0.8841 15$CL=0.0985 12$CM=0.0163 4 + 66ZN G 800.13 5 0.0010 5 + 66ZN G 2698.92 5 0.0037 7 66ZN G 3738.10 5 0.0138 13 66ZN L 3753.01 4 4+ 66ZN G 2713.73 5 0.0062 19 66ZN L 3791.121 3 1+ - 66ZN E 0.94 8 26.0 215 - 66ZN2 E EAV=157.0 13$CK=0.8841 15$CL=0.0985 12$CM=0.0163 4$CN= $CO= - 66ZN G 283.87 3 0.0036 8 - 66ZN G 410.178 120.065 6 - 66ZN G 459.683 140.088 8 - 66ZN G 562.241 100.0066 8 - 66ZN G 578.540 190.059 6 + 66ZN E 0.94 826.0 215 + 66ZN2 E EAV=157.0 13$CK=0.8841 15$CL=0.0985 12$CM=0.0163 4 + 66ZN G 283.87 3 0.0036 8 + 66ZN G 410.178 120.065 6 + 66ZN G 459.683 140.088 8 + 66ZN G 562.241 100.0066 8 + 66ZN G 578.540 190.059 6 66ZN G 686.080 6 0.252 22 - 66ZN G 853.038 8 0.076 6 M1+E2 0.37 18 - 66ZN G 1010.957 190.027 3 - 66ZN G 1418.754 5 0.61 5 + 66ZN G 853.038 8 0.076 6M1+E2 0.37 18 + 66ZN G 1010.957 190.027 3 + 66ZN G 1418.754 5 0.61 5 66ZN G 1918.329 5 1.99 16M1+E2 -0.07 3 66ZN G 2751.835 5 22.7 18(M1+E2) - 66ZN G 3791.004 8 1.09 9 M1+E2 + 66ZN G 3791.004 8 1.09 9M1+E2 66ZN L 3825.0 3 0+ - 66ZN E 0.0030 6 8.92 - 66ZN2 E EAV= $CK=0.8840 15$CL=0.0986 12$CM=0.0163 4$CN= $CO= - 66ZN G 2785.7 3 0.0030 6 + 66ZN E 0.0030 68.92 + 66ZN2 E CK=0.8840 15$CL=0.0986 12$CM=0.0163 4 + 66ZN G 2785.7 3 0.0030 6 66ZN L 3882.422 10(2)+ - 66ZN E 0.0014 9 9.2 2 - 66ZN2 E EAV= $CK=0.8840 15$CL=0.0986 12$CM=0.0163 4$CN= $CO= - 66ZN G 2009.628 160.0031 7 - 66ZN G 2843.130 160.0017 4 + 66ZN E 0.0014 99.2 2 + 66ZN2 E CK=0.8840 15$CL=0.0986 12$CM=0.0163 4 + 66ZN G 2009.628 160.0031 7 + 66ZN G 2843.130 160.0017 4 66ZN L 4085.982 4 1+ 66ZN E 1.67 145.99 - 66ZN2 E EAV= $CK=0.8837 15$CL=0.0988 12$CM=0.0163 4$CN= $CO= - 66ZN G 347.77 5 0.0018 6 - 66ZN G 554.28 3 0.0045 6 - 66ZN G 653.568 140.0013 5 - 66ZN G 658.57 3 0.0075 10 - 66ZN G 705.031 150.0038 5 - 66ZN G 857.093 9 0.015 5 + 66ZN2 E CK=0.8837 15$CL=0.0988 12$CM=0.0163 4 + 66ZN G 347.77 5 0.0018 6 + 66ZN G 554.280 300.0045 6 + 66ZN G 653.568 140.0013 5 + 66ZN G 658.570 300.0075 10 + 66ZN G 705.031 150.0038 5 + 66ZN G 857.093 9 0.015 5 66ZN G 873.392 210.0170 18 66ZN G 980.934 130.048 19 - 66ZN G 1147.896 100.078 9 M1+E2 -0.18 5 - 66ZN G 1305.807 210.0040 5 + 66ZN G 1147.896 100.078 9M1+E2 -0.18 5 + 66ZN G 1305.807 210.0040 5 66ZN G 1713.602 120.0243 23 66ZN G 2213.181 9 0.131 12M1+E2 -0.23 5 - 66ZN G 3046.684 9 0.057 5 M1+E2 -0.8 2 + 66ZN G 3046.684 9 0.057 5M1+E2 -0.8 2 66ZN G 4085.853 9 1.27 10M1+E2 66ZN L 4295.337 4 1+ 4.2 FS 13 - 66ZN E 6.2 5 5.23 - 66ZN2 E EAV= $CK=0.8833 15$CL=0.0992 12$CM=0.0164 4$CN= $CO= - 66ZN G 412.916 160.0034 6 - 66ZN G 557.13 5 0.0061 8 M1+E2 + 66ZN E 6.2 55.23 + 66ZN2 E CK=0.8833 15$CL=0.0992 12$CM=0.0164 4 + 66ZN G 412.916 160.0034 6 + 66ZN G 557.13 5 0.0061 8M1+E2 66ZN G 718.97 5 0.0099 10 - 66ZN G 763.64 3 0.0089 10 + 66ZN G 763.640 300.0089 10 66ZN G 862.926 130.0152 14 - 66ZN G 867.93 3 0.0043 6 - 66ZN G 914.388 140.027 3 + 66ZN G 867.930 300.0043 6 + 66ZN G 914.388 140.027 3 66ZN G 963.892 150.0144 16 - 66ZN G 1066.450 120.0024 5 - 66ZN G 1082.75 2 0.0133 13 + 66ZN G 1066.450 120.0024 5 + 66ZN G 1082.750 200.0133 13 66ZN G 1190.287 7 0.128 13 - 66ZN G 1357.250 120.16 5 M1+E2 -0.18 5 - 66ZN G 1515.162 200.0062 7 + 66ZN G 1357.250 120.16 5M1+E2 -0.18 5 + 66ZN G 1515.162 200.0062 7 66ZN G 2422.525 7 1.88 15M1+E2 0.01 3 - 66ZN G 3256.021 9 0.094 8 M1+E2 1.5 2 - 66ZN G 4295.187 103.8 3 + 66ZN G 3256.021 9 0.094 8M1+E2 1.5 2 + 66ZN G 4295.187 103.8 3 66ZN L 4461.370 5 1+ 7.0 FS 7 66ZN E 1.96 175.54 - 66ZN2 E EAV= $CK=0.8828 15$CL=0.0996 12$CM=0.0165 4$CN= $CO= - 66ZN G 375.398 170.0021 6 - 66ZN G 670.251 140.0041 7 + 66ZN2 E CK=0.8828 15$CL=0.0996 12$CM=0.0165 4 + 66ZN G 375.398 170.0021 6 + 66ZN G 670.251 140.0041 7 66ZN G 708.36 5 0.0087 10 - 66ZN G 723.17 5 0.0034 6 - 66ZN G 885.00 5 0.0019 5 - 66ZN G 929.68 3 0.0046 7 - 66ZN G 954.12 7 0.0045 7 + 66ZN G 723.17 5 0.0034 6 + 66ZN G 885.00 5 0.0019 5 + 66ZN G 929.680 300.0046 7 + 66ZN G 954.12 7 0.0045 7 66ZN G 1129.923 180.0136 13 66ZN G 1232.480 150.056 19 - 66ZN G 1248.779 220.0010 3 + 66ZN G 1248.779 220.0010 3 66ZN G 1356.320 150.122 21 - 66ZN G 1523.279 150.0055 7 - 66ZN G 2088.985 130.011 3 + 66ZN G 1523.279 150.0055 7 + 66ZN G 2088.985 130.011 3 66ZN G 2588.553 130.0263 26M1+E2 0.35 27 - 66ZN G 3422.040 8 0.86 7 M1+E2 -0.06 2 - 66ZN G 4461.202 9 0.84 7 + 66ZN G 3422.040 8 0.86 7M1+E2 -0.06 2 + 66ZN G 4461.202 9 0.84 7 66ZN L 4638.24 141+ 66ZN E 0.0042 107.96 - 66ZN2 E EAV= $CK=0.8820 15$CL=0.1003 12$CM=0.0166 4$CN= $CO= - 66ZN G 1106.53 240.0012 4 - 66ZN G 1409.35 240.0016 7 - 66ZN G 2265.84 240.0014 5 + 66ZN2 E CK=0.8820 15$CL=0.1003 12$CM=0.0166 4 + 66ZN G 1106.53 240.0012 4 + 66ZN G 1409.35 240.0016 7 + 66ZN G 2265.84 240.0014 5 66ZN L 4675.6 5 1+ - 66ZN E 0.0015 5 8.35 - 66ZN2 E EAV= $CK=0.8817 15$CL=0.1005 12$CM=0.0166 4$CN= $CO= - 66ZN G 2802.8 5 0.0015 4 + 66ZN E 0.0015 58.35 + 66ZN2 E CK=0.8817 15$CL=0.1005 12$CM=0.0166 4 + 66ZN G 2802.8 5 0.0015 4 66ZN L 4806.197 5 1+ 3.8 FS 10 66ZN E 2.27 194.9 - 66ZN2 E EAV= $CK=0.8804 15$CL=0.1016 13$CM=0.0169 4$CN= $CO= - 66ZN G 1015.081 180.012 3 - 66ZN G 1135.47 9 0.0047 6 - 66ZN G 1274.50 3 0.0070 8 - 66ZN G 1298.95 7 0.0038 5 - 66ZN G 1425.25 2 0.0060 7 - 66ZN G 1577.308 200.0040 7 - 66ZN G 1868.105 200.0027 6 - 66ZN G 2026.016 250.0026 6 - 66ZN G 2433.807 180.0074 9 + 66ZN2 E CK=0.8804 15$CL=0.1016 13$CM=0.0169 4 + 66ZN G 1015.081 180.012 3 + 66ZN G 1135.47 9 0.0047 6 + 66ZN G 1274.500 300.0070 8 + 66ZN G 1298.95 7 0.0038 5 + 66ZN G 1425.25 2 0.0060 7 + 66ZN G 1577.308 200.0040 7 + 66ZN G 1868.105 200.0027 6 + 66ZN G 2026.016 250.0026 6 + 66ZN G 2433.807 180.0074 9 66ZN G 2933.358 9 0.213 17M1+E2 1.6 2 66ZN G 3766.850 9 0.149 13M1+E2 0.11 4 66ZN G 4806.007 9 1.86 15 66ZN L 4849.93 3 1+ - 66ZN E 0.033 4 6.62 - 66ZN2 E EAV= $CK=0.8797 15$CL=0.1021 13$CM=0.0170 5$CN= $CO= - 66ZN G 1468.97 5 0.0014 4 - 66ZN G 2977.08 4 0.023 3 + 66ZN E 0.033 46.62 + 66ZN2 E CK=0.8797 15$CL=0.1021 13$CM=0.0170 5 + 66ZN G 1468.97 5 0.0014 4 + 66ZN G 2977.08 4 0.023 3 66ZN G 3810.59 5 0.0092 11 66ZN L 4866.054 161+ - 66ZN E 0.047 6 6.42 - 66ZN2 E EAV= $CK=0.8794 15$CL=0.1024 13$CM=0.0170 5$CN= $CO= - 66ZN G 1195.32 9 0.0009 3 - 66ZN G 1433.63 4 0.0018 4 - 66ZN G 1534.60 4 0.0057 16 - 66ZN G 1927.96 4 0.0022 8 - 66ZN G 2085.86 4 0.0021 15 - 66ZN G 2993.21 3 0.031 4 - 66ZN G 4865.87 4 0.0028 3 + 66ZN E 0.047 66.42 + 66ZN2 E CK=0.8794 15$CL=0.1024 13$CM=0.0170 5 + 66ZN G 1195.32 9 0.0009 3 + 66ZN G 1433.630 400.0018 4 + 66ZN G 1534.600 400.0057 16 + 66ZN G 1927.96 4 0.0022 8 + 66ZN G 2085.860 400.0021 15 + 66ZN G 2993.21 3 0.031 4 + 66ZN G 4865.87 4 0.0028 3 66ZN L 4958.2 4 1+ - 66ZN E 0.0020 5 7.48 - 66ZN2 E EAV= $CK=0.8768 16$CL=0.1046 13$CM=0.0174 5$CN= $CO= - 66ZN G 3085.4 4 0.0020 5 + 66ZN E 0.0020 57.48 + 66ZN2 E CK=0.8768 16$CL=0.1046 13$CM=0.0174 5 + 66ZN G 3085.4 4 0.0020 5 66ZN L 5005.8 3 1+ 66ZN E 0.00122 157.47 - 66ZN2 E EAV= $CK=0.8742 16$CL=0.1067 13$CM=0.0178 5$CN= $CO= + 66ZN2 E CK=0.8742 16$CL=0.1067 13$CM=0.0178 5 66ZN G 5005.6 3 0.00124 18 diff --git a/HEN_HOUSE/spectra/lnhb/Ga-67.txt b/HEN_HOUSE/spectra/lnhb/Ga-67.txt index 5033f17d3..4032a317f 100644 --- a/HEN_HOUSE/spectra/lnhb/Ga-67.txt +++ b/HEN_HOUSE/spectra/lnhb/Ga-67.txt @@ -14,63 +14,63 @@ 67ZN7C 1982HOZJ, 1988BE55, 1990ME15, 1991BH06, 1992UN01, 1996HW03, 1996SC06, 67ZN8C 1998AT04, 2000SI03, 2002UN02, 2003AU03, 2003AU02, 2004SC04, 2004DA05, 67ZN9C 2005YA01, 2005HU18, 2008MO18, 2008KI07 - 67ZN T Auger electrons and ^X ray energies and emission intensities: - 67ZN T {U Energy (keV)} {U Intensity } {U Line } + 67ZN T Auger electrons and X ray energies and emission intensities: + 67ZN T {U Energy (keV)} {U Intensity} {U Line} 67ZN T - 67ZN T 8.61587 17.0 6 XKA2 - 67ZN T 8.63896 33.0 12 XKA1 + 67ZN T 8.61587 17.0 6 XKA2 + 67ZN T 8.63896 33.0 12 XKA1 67ZN T - 67ZN T 9.5721 |] 7.08 26 XKB1 - 67ZN T 9.6499 |] XKB5II + 67ZN T 9.5721 |] 7.08 26 XKB1 + 67ZN T 9.6499 |] XKB5II 67ZN T - 67ZN T 9.6581 |] XKB2 + 67ZN T 9.6581 |] XKB2 67ZN T - 67ZN T 0.8836-1.1861 1.75 5 XL (total) - 67ZN T 0.8836 0.0504 18 XLL - 67ZN T 1.0119-1.0122 0.97 3 XLA - 67ZN T 0.9065 0.0328 13 XLC - 67ZN T 1.02044-1.1861 0.700 26 XLB - 67ZN T 1.04333-1.04333 0.00228 17 XLG + 67ZN T 0.8836-1.1861 1.75 5 XL (total) + 67ZN T 0.8836 0.0504 18 XLL + 67ZN T 1.0119-1.0122 0.97 3 XLA + 67ZN T 0.9065 0.0328 13 XLC + 67ZN T 1.02044-1.1861 0.700 26 XLB + 67ZN T 1.04333-1.04333 0.00228 17 XLG 67ZN T - 67ZN T 7.21-7.55 |] KLL AUGER - 67ZN T 8.31-8.63 |] 60.4 21 ^KLX AUGER - 67ZN T 9.39-9.65 |] KXY AUGER - 67ZN T 0.732-0.997 167.5 21 L AUGER + 67ZN T 7.21-7.55 |] KLL AUGER + 67ZN T 8.31-8.63 |] 60.4 21 KLX AUGER + 67ZN T 9.39-9.65 |] KXY AUGER + 67ZN T 0.732-0.997 167.5 21 L AUGER 67GA P 0.0 3/2- 3.2613 D 5 1000.8 12 67ZN N 1.0 1.0 1 1.0 67ZN L 0 5/2- STABLE - 67ZN E 3.3 326.532 2 - 67ZN2 E EAV= $CK=0.8836 15$CL=0.0989 12$CM=0.0164 4$CN=0.0011 1$CO=0 0 + 67ZN E 3.3 326.532 + 67ZN2 E CK=0.8836 15$CL=0.0989 12$CM=0.0164 4$CN=0.0011 1$CO=0 0 67ZN L 93.31 1/2- 9.00 US 4 - 67ZN E 50.5 175.261 2 - 67ZN2 E EAV= $CK=0.8834 15$CL=0.0991 12$CM=0.0164 4$CN=0.0011 1$CO= - 67ZN G 93.307 1238.1 7 E2 0.854 12 + 67ZN E 50.5 175.261 + 67ZN2 E CK=0.8834 15$CL=0.0991 12$CM=0.0164 4$CN=0.0011 1 + 67ZN G 93.307 1238.1 7E2 0.854 12 67ZN2 G KC=0.748 11$LC=0.0922 13$MC=0.01300 19 67ZN L 184.58 3/2- 1.028 NS 14 67ZN E 22.3 275.523 - 67ZN2 E EAV= $CK=0.8832 15$CL=0.0993 12$CM=0.0164 4$CN=0.0011 1$CO= - 67ZN G 91.263 153.09 7 M1+()E2 0.123 25 0.091 6 - 67ZN2 G KC=0.081 5$LC=0.0087 7$MC=0.00125 9 + 67ZN2 E CK=0.8832 15$CL=0.0993 12$CM=0.0164 4$CN=0.0011 1 + 67ZN G 91.263 153.09 7M1+()E2 0.123 25 0.091 6 + 67ZN2 G KC=0.081 5$LC=0.0087 7$MC=0.00125 9 67ZN G 184.577 1720.96 44M1+()E2 0.31 7 0.0169 21 - 67ZN2 G KC=0.0151 19$LC=0.00158 20$MC=0.00023 3 + 67ZN2 G KC=0.0151 19$LC=0.00158 20$MC=0.00023 3 67ZN L 393.53 3/2- 67ZN E 23.60 475.239 - 67ZN2 E EAV= $CK=0.8824 15$CL=0.0999 12$CM=0.0165 4$CN=0.0011 1$CO= - 67ZN G 208.939 152.37 5 M1+()E2 0.042 17 0.0090114 + 67ZN2 E CK=0.8824 15$CL=0.0999 12$CM=0.0165 4$CN=0.0011 1 + 67ZN G 208.939 152.37 5M1+()E2 0.042 17 0.0090114 67ZN2 G KC=0.00806 13$LC=8.27E-4 13$MC=1186E-7 19 - 67ZN G 300.232 2116.60 37M1+()E2 0.178 10 0.003886 - 67ZN2 G KC=0.00348 6$LC=3.54E-4 6$MC=5.08E-5 8 - 67ZN G 393.528 204.59 10M1+()E2 0.051 16 0.001933 - 67ZN2 G KC=1728E-6 25$LC=1748E-7 25$MC=2.51E-5 4 + 67ZN G 300.232 2116.60 37M1+()E2 0.178 10 0.00388 6 + 67ZN2 G KC=0.00348 6$LC=3.54E-4 6$MC=5.08E-5 8 + 67ZN G 393.528 204.59 10M1+()E2 0.051 16 0.00193 3 + 67ZN2 G KC=1728E-6 25$LC=1748E-7 25$MC=2.51E-5 4 67ZN L 887.69 5/2- - 67ZN E 0.280 8 5.648 2 - 67ZN2 E EAV= $CK=0.8680 17$CL=0.1119 14$CM=0.0188 5$CN=0.0013 1$CO= + 67ZN E 0.280 85.648 + 67ZN2 E CK=0.8680 17$CL=0.1119 14$CM=0.0188 5$CN=0.0013 1 67ZN G 494.143 280.0666 29M1+()E2 0.110 34 1149E-618 67ZN2 G KC=1030E-6 16$LC=1038E-7 17$MC=1488E-8 24 - 67ZN G 703.11 8 0.0113 9 M1+()E2 0.090 28 5.24E-48 - 67ZN2 G KC=4.70E-4 7$LC=4.70E-5 7$MC=6.74E-6 10 - 67ZN G 794.400 410.0528 17E2+()M3 0.09 11 0.000546 - 67ZN2 G KC=0.00048 5$LC=4.9E-5 6$MC=7.0E-6 8 - 67ZN G 887.676 330.1492 38M1+()E2 0.95 9 3.54E-47 - 67ZN2 G KC=3.18E-4 6$LC=3.18E-5 6$MC=4.56E-6 8 + 67ZN G 703.11 8 0.0113 9M1+()E2 0.090 28 5.24E-4 8 + 67ZN2 G KC=4.70E-4 7$LC=4.70E-5 7$MC=6.74E-6 10 + 67ZN G 794.400 410.0528 17E2+()M3 0.09 11 0.00054 6 + 67ZN2 G KC=0.00048 5$LC=4.9E-5 6$MC=7.0E-6 8 + 67ZN G 887.676 330.1492 38M1+()E2 0.95 9 3.54E-4 7 + 67ZN2 G KC=3.18E-4 6$LC=3.18E-5 6$MC=4.56E-6 8 diff --git a/HEN_HOUSE/spectra/lnhb/Ga-68.txt b/HEN_HOUSE/spectra/lnhb/Ga-68.txt index 78092fd22..4f2556b29 100644 --- a/HEN_HOUSE/spectra/lnhb/Ga-68.txt +++ b/HEN_HOUSE/spectra/lnhb/Ga-68.txt @@ -6,72 +6,72 @@ 68ZN C References: 1956Cr29, 1959Ho85, 1959Ra04, 1959Ho85, 1960Ra22, 1965Bo42, 68ZN2C 1965Eb01, 1968Ca15, 1969Va16, 1971Oo01, 1971Sm02, 1972Sl03, 1973La01, 68ZN3C 1977Kr17, 1983Iw02, 1992Sy**, 1994Vo15, 1994Sc44, 2003Au03, 2012Lu14 - 68ZN T Auger electrons and ^X ray energies and emission intensities: - 68ZN T {U Energy (keV)} {U Intensity } {U Line } + 68ZN T Auger electrons and X ray energies and emission intensities: + 68ZN T {U Energy (keV)} {U Intensity} {U Line} 68ZN T - 68ZN T 8.61587 1.42 6 XKA2 - 68ZN T 8.63896 2.76 11 XKA1 + 68ZN T 8.61587 1.42 6 XKA2 + 68ZN T 8.63896 2.76 11 XKA1 68ZN T - 68ZN T 9.5721 |] 0.593 24 XKB1 - 68ZN T 9.6499 |] XKB5II + 68ZN T 9.5721 |] 0.593 24 XKB1 + 68ZN T 9.6499 |] XKB5II 68ZN T 68ZN T - 68ZN T 0.884-1.186 0.146 4 XL (total) - 68ZN T 0.884 0.00421 16 XLL - 68ZN T 1.012-1.012 0.0807 28 XLA - 68ZN T 0.906 0.00273 11 XLC - 68ZN T 1.02-1.186 0.0584 23 XLB - 68ZN T 1.043-1.043 0.000190 14 XLG + 68ZN T 0.884-1.186 0.146 4 XL (total) + 68ZN T 0.884 0.00421 16 XLL + 68ZN T 1.012-1.012 0.0807 28 XLA + 68ZN T 0.906 0.00273 11 XLC + 68ZN T 1.02-1.186 0.0584 23 XLB + 68ZN T 1.043-1.043 0.00019014 XLG 68ZN T - 68ZN T 7.21-7.55 |] KLL AUGER - 68ZN T 8.31-8.63 |] 5.05 20 ^KLX AUGER - 68ZN T 9.39-9.65 |] KXY AUGER - 68ZN T 0.732-0.997 13.98 19 L AUGER + 68ZN T 7.21-7.55 |] KLL AUGER + 68ZN T 8.31-8.63 |] 5.05 20 KLX AUGER + 68ZN T 9.39-9.65 |] KXY AUGER + 68ZN T 0.732-0.997 13.98 19 L AUGER 68GA P 0.0 1+ 67.83 M 20 2921.1 12 68ZN N 1.0 1.0 1 1.0 68ZN L 0 0+ STABLE 68ZN E 87.68 418.94 415.2 68ZN2 E EAV=836.0 6$CK=0.8847 15$CL=0.0980 12$CM=0.0162 4$CN=0.0011 1$CO=0 0 68ZN L 1077.35 5 2+ 1.57 PS 4 - 68ZN E 1.20 4 1.80 5 5.5 - 68ZN2 E EAV=352.6 6$CK=0.8844 15$CL=0.0983 14$CM=0.0162 5$CN= $CO= - 68ZN G 1077.34 5 3.235 30E2 2.47E-44 - 68ZN2 G KC=2.21E-4 4$LC=2.22E-5 4$MC=3.18E-6 5 + 68ZN E 1.20 41.80 55.5 + 68ZN2 E EAV=352.6 6$CK=0.8844 15$CL=0.0983 14$CM=0.0162 5 + 68ZN G 1077.34 5 3.235 30E2 2.47E-4 4 + 68ZN2 G KC=2.21E-4 4$LC=2.22E-5 4$MC=3.18E-6 5 68ZN L 1655.87 140+ 70 PS 35 - 68ZN E 0.00026 2 0.0335 236.9 - 68ZN2 E EAV=107.6 6$CK=0.8839 15$CL=0.0986 14$CM=0.0163 5$CN= $CO= + 68ZN E 0.00026 20.0335 236.9 + 68ZN2 E EAV=107.6 6$CK=0.8839 15$CL=0.0986 14$CM=0.0163 5 68ZN G 1655.87 14 68ZN G 578.52 130.0343 23E2 1272E-618 - 68ZN2 G KC=1139E-6 16$LC=1160E-7 17$MC=1.66E-5 3 + 68ZN2 G KC=1139E-6 16$LC=1160E-7 17$MC=1.66E-5 3 68ZN L 1883.19 6 2+ 1.6 PS 3 - 68ZN E 0.234 5 5.9 - 68ZN2 E EAV= $CK=0.8836 15$CL=0.0989 14$CM=0.0164 5$CN= $CO= - 68ZN G 227.31 151.20E-4 49E2 0.0300 5 - 68ZN2 G KC=0.0268 4$LC=0.00286 4$MC=4.06E-4 6 - 68ZN G 805.83 8 0.0928 27M1+()E2 -1.53 5 4.70E-47 - 68ZN2 G KC=4.21E-4 6$LC=4.24E-5 7$MC=6.07E-6 9 - 68ZN G 1883.16 6 0.1420 35E2 3.33E-45 - 68ZN2 G KC=6.97E-5 10$LC=6.91E-6 10$MC=9.9E-7 2 + 68ZN E 0.234 55.9 + 68ZN2 E CK=0.8836 15$CL=0.0989 14$CM=0.0164 5 + 68ZN G 227.31 150.00012049E2 0.0300 5 + 68ZN2 G KC=0.0268 4$LC=0.00286 4$MC=4.06E-4 6 + 68ZN G 805.83 8 0.0928 27M1+()E2 -1.53 5 4.70E-4 7 + 68ZN2 G KC=4.21E-4 6$LC=4.24E-5 7$MC=6.07E-6 9 + 68ZN G 1883.16 6 0.1420 35E2 3.33E-4 5 + 68ZN2 G KC=6.97E-5 10$LC=6.91E-6 10$MC=9.9E-7 2 68ZN L 2338.44 8 2+ 0.24 PS - 68ZN E 0.096 3 5.7 - 68ZN2 E EAV= $CK=0.8823 16$CL=0.1000 15$CM=0.0166 5$CN= $CO= - 68ZN G 682.57 163.14E-4 20E2 7.89E-411 - 68ZN2 G KC=7.07E-4 10$LC=7.16E-5 10$MC=1.03E-5 2 + 68ZN E 0.096 35.7 + 68ZN2 E CK=0.8823 16$CL=0.1000 15$CM=0.0166 5 + 68ZN G 682.57 160.00031420E2 7.89E-411 + 68ZN2 G KC=7.07E-4 10$LC=7.16E-5 10$MC=1.03E-5 2 68ZN G 1261.08 9 0.0954 21M1+()E2 -0.15 2 1725E-725 - 68ZN2 G KC=1418E-7 20$LC=1409E-8 20$MC=2.02E-6 3 - 68ZN G 2338.44 8 0.00113 16E2 5.29E-48 - 68ZN2 G KC=4.71E-5 7$LC=4.67E-6 7$MC=6.7E-7 1 + 68ZN2 G KC=1418E-7 20$LC=1409E-8 20$MC=2.02E-6 3 + 68ZN G 2338.44 8 0.00113 16E2 5.29E-4 8 + 68ZN2 G KC=4.71E-5 7$LC=4.67E-6 7$MC=6.7E-7 1 68ZN L 2821.79 142+ - 68ZN E 0.0104 5 5.1 - 68ZN2 E EAV= $CK=0.8653 18$CL=0.1141 17$CM=0.0192 5$CN= $CO= - 68ZN G 483.35 162.65E-4 29M1+()E2 1.0 5 0.0017 3 - 68ZN2 G KC=0.0015 3$LC=0.00016 3$MC=2.2E-5 4 - 68ZN G 938.61 201.78E-4 16M1+()E2 -0.7 3 3.04E-412 - 68ZN2 G KC=2.72E-4 11$LC=2.72E-5 11$MC=3.9E-6 2 - 68ZN G 1165.92 151.6E-5 10E2 2.11E-43 - 68ZN2 G KC=1.85E-4 3$LC=1.85E-5 3$MC=2.65E-6 4 - 68ZN G 1744.42 130.0096 5 M1+()E2 0.272 18 2.41E-44 - 68ZN2 G KC=7.70E-5 11$LC=7.63E-6 11$MC=1.09E-6 2 - 68ZN G 2821.73 144.66E-4 36E2 7.40E-411 - 68ZN2 G KC=3.43E-5 5$LC=3.39E-6 5$MC=4.86E-7 7 + 68ZN E 0.0104 55.1 + 68ZN2 E CK=0.8653 18$CL=0.1141 17$CM=0.0192 5 + 68ZN G 483.35 160.00026529M1+()E2 1.0 5 0.0017 3 + 68ZN2 G KC=0.0015 3$LC=0.00016 3$MC=2.2E-5 4 + 68ZN G 938.61 200.00017816M1+()E2 -0.7 3 3.04E-412 + 68ZN2 G KC=2.72E-4 11$LC=2.72E-5 11$MC=3.9E-6 2 + 68ZN G 1165.92 150.00001610E2 2.11E-4 3 + 68ZN2 G KC=1.85E-4 3$LC=1.85E-5 3$MC=2.65E-6 4 + 68ZN G 1744.42 130.0096 5M1+()E2 0.272 18 2.41E-4 4 + 68ZN2 G KC=7.70E-5 11$LC=7.63E-6 11$MC=1.09E-6 2 + 68ZN G 2821.73 140.00046636E2 7.40E-411 + 68ZN2 G KC=3.43E-5 5$LC=3.39E-6 5$MC=4.86E-7 7 diff --git a/HEN_HOUSE/spectra/lnhb/Gd-153.txt b/HEN_HOUSE/spectra/lnhb/Gd-153.txt index 4bc073d6d..d2cbf10f7 100644 --- a/HEN_HOUSE/spectra/lnhb/Gd-153.txt +++ b/HEN_HOUSE/spectra/lnhb/Gd-153.txt @@ -4,64 +4,63 @@ 153EU C Evaluation history: Type=Update;Author=M.M. Bé;Cutoff date=15-NOV-2011 153EU2C Type=Full;Author=R.G. Helmer;Cutoff date=30-JUN-2001 153EU C References: 2002Ba85, 2008Ki07 -153EU T Auger electrons and ^X ray energies and emission intensities: -153EU T {U Energy (keV)} {U Intensity } {U Line } +153EU T Auger electrons and X ray energies and emission intensities: +153EU T {U Energy (keV)} {U Intensity} {U Line} 153EU T -153EU T 40.9024 34.2 9 XKA2 -153EU T 41.5427 61.7 16 XKA1 +153EU T 40.9024 34.2 9 XKA2 +153EU T 41.5427 61.7 16 XKA1 153EU T -153EU T 46.904 |] XKB3 -153EU T 47.0384 |] 19.4 6 XKB1 -153EU T 47.373 |] XKB5II +153EU T 46.904 |] XKB3 +153EU T 47.0384 |] 19.4 6 XKB1 +153EU T 47.373 |] XKB5II 153EU T -153EU T 48.257 |] XKB2 -153EU T 48.386 |] 5.01 17 XKB4 -153EU T 48.497 |] XKO23 +153EU T 48.257 |] XKB2 +153EU T 48.386 |] 5.01 17 XKB4 +153EU T 48.497 |] XKO23 153EU T -153EU T 5.1751-7.791 20.1 5 XL (total) -153EU T 5.1751 0.413 14 XLL -153EU T 5.815-5.8461 10.07 30 XLA -153EU T 5.8149 0.156 5 XLC -153EU T 6.4365-6.9193 8.24 20 XLB -153EU T 7.2538-7.791 1.27 4 XLG +153EU T 5.1751-7.791 20.1 5 XL (total) +153EU T 5.1751 0.413 14 XLL +153EU T 5.815-5.8461 10.07 30 XLA +153EU T 5.8149 0.156 5 XLC +153EU T 6.4365-6.9193 8.24 20 XLB +153EU T 7.2538-7.791 1.27 4 XLG 153EU T -153EU T 32.25-34.38 |] KLL AUGER -153EU T 38.59-41.27 |] 9.2 6 ^KLX AUGER -153EU T 44.9-48.2 |] KXY AUGER -153EU T 3.4-7.8 98.4 9 L AUGER +153EU T 32.25-34.38 |] KLL AUGER +153EU T 38.59-41.27 |] 9.2 6 KLX AUGER +153EU T 44.9-48.2 |] KXY AUGER +153EU T 3.4-7.8 98.4 9 L AUGER 153GD P 0.0 3/2- 240.4 D 10 484.0 7 153EU N 1.0 1.0 1 1.0 153EU L 0 5/2+ STABLE -153EU E 4 3 8.9 1U -153EU2 E EAV= $CK=0.8192 17$CL=0.1392 15$CM=0.0324 8$CN= $CO= +153EU E 4 38.9 1 +153EU2 E CK=0.8192 17$CL=0.1392 15$CM=0.0324 8 153EU L 83.36720 177/2+ 0.77 NS -153EU E 0.05 7 3U -153EU2 E EAV= $CK= $CL= $CM= $CN= $CO= -153EU G 83.36717 210.197 7 M1+E2 0.81 4 3.76 7 -153EU2 G KC=2.33 4$LC=1.11 5$MC=0.257 12 +153EU E 0.05 7 1U +153EU G 83.36717 210.197 7M1+E2 0.81 4 3.76 7 +153EU2 G KC=2.33 4$LC=1.11 5$MC=0.257 12 153EU L 97.43103 175/2- 0.18 NS -153EU E 38.0 117.7 2 -153EU2 E EAV= $CK=0.8116 18$CL=0.1448 16$CM=0.034 8$CN= $CO= -153EU G 14.06383 200.020 5 E1 10.89 16 -153EU2 G KC=$LC=8.54 12$MC=1.90 3 -153EU G 97.43100 2129.0 8 E1 0.305 5 -153EU2 G KC=0.256 4$LC=0.0382 6$MC=0.00823 12 +153EU E 38.0 117.7 +153EU2 E CK=0.8116 18$CL=0.1448 16$CM=0.034 8 +153EU G 14.06383 200.020 5E1 10.89 16 +153EU2 G LC=8.54 12$MC=1.90 3 +153EU G 97.43100 2129.0 8E1 0.305 5 +153EU2 G KC=0.256 4$LC=0.0382 6$MC=0.00823 12 153EU L 103.18016 133/2+ 3.88 NS 153EU E 42.0 187.7 -153EU2 E EAV= $CK=0.8111 18$CL=0.1452 16$CM=0.0341 8$CN= $CO= -153EU G 19.81296 191400E-7 0 E2 3220 50 -153EU2 G KC=$LC=2490 40$MC=578 8 -153EU G 103.18012 1721.1 6 M1+E2 0.119 3 1.694 24 -153EU2 G KC=1.422 20$LC=0.213 3$MC=0.0462 7 +153EU2 E CK=0.8111 18$CL=0.1452 16$CM=0.0341 8 +153EU G 19.81296 190.00014 E2 3220 50 +153EU2 G LC=2490 40$MC=578 8 +153EU G 103.18012 1721.1 6M1+E2 0.119 3 1.694 24 +153EU2 G KC=1.422 20$LC=0.213 3$MC=0.0462 7 153EU L 172.85320 135/2+ -153EU E 15.7 6 7.9 1U -153EU2 E EAV= $CK=0.8019 19$CL=0.1519 4$CM=0.0359 9$CN= $CO= -153EU G 69.67300 132.42 7 M1+E2 0.136 4 5.31 8 -153EU2 G KC=4.39 7$LC=0.719 12$MC=0.1572 25 -153EU G 75.42213 230.078 3 E1+M2 0.055 10 0.76 7 -153EU2 G KC=0.62 5$LC=0.112 13$MC=0.025 3 -153EU G 89.48595 220.069 5 M1+E2 0.25 10 2.60 7 -153EU2 G KC=2.11 5$LC=0.38 7$MC=0.085 16 -153EU G 172.85307 210.036 2 M1+E2 0.81 8 0.377 6 -153EU2 G KC=0.296 7$LC=0.0637 22$MC=0.0142 6 +153EU E 15.7 67.9 1 +153EU2 E CK=0.8019 19$CL=0.1519 4$CM=0.0359 9 +153EU G 69.67300 132.42 7M1+E2 0.136 4 5.31 8 +153EU2 G KC=4.39 7$LC=0.719 12$MC=0.1572 25 +153EU G 75.42213 230.078 3E1+M2 0.055 10 0.76 7 +153EU2 G KC=0.62 5$LC=0.112 13$MC=0.025 3 +153EU G 89.48595 220.069 5M1+E2 0.25 10 2.60 7 +153EU2 G KC=2.11 5$LC=0.38 7$MC=0.085 16 +153EU G 172.85307 210.036 2M1+E2 0.81 8 0.377 6 +153EU2 G KC=0.296 7$LC=0.0637 22$MC=0.0142 6 diff --git a/HEN_HOUSE/spectra/lnhb/Gd-159.txt b/HEN_HOUSE/spectra/lnhb/Gd-159.txt index a210cd754..555096410 100644 --- a/HEN_HOUSE/spectra/lnhb/Gd-159.txt +++ b/HEN_HOUSE/spectra/lnhb/Gd-159.txt @@ -3,93 +3,93 @@ 159TB2 H TYP=Full$AUT=R.G.Helmer$CUT=30-APR-2004$ 159TB C Evaluation history: Type=Update;Author=M.M.Bé;Cutoff date= -- 159TB2C Type=Full;Author=R.G.Helmer;Cutoff date=30-APR-2004 -159TB T Auger electrons and ^X ray energies and emission intensities: -159TB T {U Energy (keV)} {U Intensity } {U Line } +159TB T Auger electrons and X ray energies and emission intensities: +159TB T {U Energy (keV)} {U Intensity} {U Line} 159TB T -159TB T 43.7447 6.09 25 XKA2 -159TB T 44.4821 10.9 5 XKA1 +159TB T 43.7447 6.09 25 XKA2 +159TB T 44.4821 10.9 5 XKA1 159TB T -159TB T 50.23 |] XKB3 -159TB T 50.383 |] 3.49 15 XKB1 +159TB T 50.23 |] XKB3 +159TB T 50.383 |] 3.49 15 XKB1 159TB T -159TB T 51.724 |] XKB2 -159TB T 51.849 |] 0.90 5 XKB4 +159TB T 51.724 |] XKB2 +159TB T 51.849 |] 0.90 5 XKB4 159TB T 159TB T -159TB T 34.398-36.773 |] KLL AUGER -159TB T 41.243-44.456 |] 1.49 11 ^KLX AUGER -159TB T 48.06-51.95 |] KXY AUGER -159TB T 3.58-8.7 0.195 5 L AUGER +159TB T 34.398-36.773 |] KLL AUGER +159TB T 41.243-44.456 |] 1.49 11 KLX AUGER +159TB T 48.06-51.95 |] KXY AUGER +159TB T 3.58-8.7 0.195 5 L AUGER 159GD P 0.0 3/2- 18.479 H 7 970.5 7 159TB N 1.0 1.0 1 1.0 159TB L 0 3/2+ STABLE 159TB B 970.5 7 57.8 12 6.73 159TBS B EAV=326.9 3 159TB L 57.9963 145/2+ 53.6 PS 14 -159TB B 912.5 7 29.6 12 6.99 1U +159TB B 912.5 7 29.6 12 6.99 1 159TBS B EAV=304.1 3 -159TB G 58.0000 222.49 7 M1+E2 0.119 2 11.1 3 -159TB2 G KC=9.14 27$LC=1.55 5$MC=0.343 10 +159TB G 58.0000 222.49 7M1+E2 0.119 2 11.1 3 +159TB2 G KC=9.14 27$LC=1.55 5$MC=0.343 10 159TB L 137.5054 177/2+ 41.4 PS 23 -159TB B 833.0 7 0.012 9 10.6 3U +159TB B 833.0 7 0.012 9 10.6 1U 159TBS B EAV=283.9 3 159TB G 79.5132 270.0468 11M1+E2 0.126 8 4.41 13 -159TB2 G KC=3.66 11$LC=0.584 18$MC=0.129 4 +159TB2 G KC=3.66 11$LC=0.584 18$MC=0.129 4 159TB G 137.515 5 0.00648 15[E2] 0.833 25 -159TB2 G KC=0.474 14$LC=0.277 8$MC=0.0653 19 +159TB2 G KC=0.474 14$LC=0.277 8$MC=0.0653 19 159TB L 348.2830 155/2+ -159TB B 622.2 7 0.315 4 8.39 1U +159TB B 622.2 7 0.315 4 8.39 1 159TBS B EAV=194.5 3 -159TB G 210.783 3 0.0200 14[M1E2] 0.23 7 -159TB2 G KC=0.18 3$LC=0.039 7$MC=0.0089 16 -159TB G 290.2865 250.0323 5 [M1E2] 0.093 29 -159TB2 G KC=0.075 23$LC=0.014 1$MC=0.0031 1 -159TB G 348.2807 180.2393 25M1+E2 0.43 0.067 2 -159TB2 G KC=0.056 2$LC=0.0084 3$MC=0.00180 5 +159TB G 210.783 3 0.0200 14[M1E2] 0.23 7 +159TB2 G KC=0.18 3$LC=0.039 7$MC=0.0089 16 +159TB G 290.2865 250.0323 5[M1E2] 0.093 29 +159TB2 G KC=0.075 23$LC=0.014 1$MC=0.0031 1 +159TB G 348.2807 180.2393 25M1+E2 0.43 0.067 2 +159TB2 G KC=0.056 2$LC=0.0084 3$MC=0.00180 5 159TB L 363.5451 145/2- 15.2 PS 5 -159TB B 607.0 7 12.19 6 6.76 2 +159TB B 607.0 7 12.19 6 6.76 159TBS B EAV=189.0 3 159TB G 226.0406 180.2170 21E1 0.0343 10 -159TB2 G KC=0.0290 9$LC=0.00414 12$MC=0.00089 3 -159TB G 305.5492 200.0620 7 E1 0.0159 5 -159TB2 G KC=0.0135 4$LC=0.00189 6$MC=4.11E-4 12 -159TB G 363.5430 1811.78 5 E1 0.0104 3 -159TB2 G KC=0.00882 26$LC=0.00123 4$MC=2.66E-4 8 +159TB2 G KC=0.0290 9$LC=0.00414 12$MC=0.00089 3 +159TB G 305.5492 200.0620 7E1 0.0159 5 +159TB2 G KC=0.0135 4$LC=0.00189 6$MC=4.11E-4 12 +159TB G 363.5430 1811.78 5E1 0.0104 3 +159TB2 G KC=0.00882 26$LC=0.00123 4$MC=2.66E-4 8 159TB L 580.808 6 1/2+ 0.76 PS 10 -159TB B 389.7 7 0.0626 8 8.41 1U +159TB B 389.7 7 0.0626 8 8.41 1 159TBS B EAV=113.8 2 -159TB G 580.808 6 0.0693 7 [M1E2] 0.015 5 -159TB2 G KC=0.012 4$LC=0.0018 6$MC= +159TB G 580.808 6 0.0693 7[M1E2] 0.015 5 +159TB2 G KC=0.012 4$LC=0.0018 6 159TB L 617.619 5 3/2+ -159TB B 352.9 7 0.0300 9 8.58 +159TB B 352.9 7 0.0300 9 8.58 159TBS B EAV=101.84 23 -159TB G 559.623 6 0.0221 6 M1+E2 0.67 0.019 3 -159TB2 G KC=0.0152 5$LC=0.0022 2$MC=0.00040 9 -159TB G 617.615 8 0.0159 5 (M1) 0.0166 5 -159TB2 G KC=0.0141 4$LC=0.00196 6$MC=0.00043 2 +159TB G 559.623 6 0.0221 6M1+E2 0.67 0.019 3 +159TB2 G KC=0.0152 5$LC=0.0022 2$MC=0.00040 9 +159TB G 617.615 8 0.0159 5(M1) 0.0166 5 +159TB2 G KC=0.0141 4$LC=0.00196 6$MC=0.00043 2 159TB L 674.235 175/2+ -159TB B 296.3 7 0.00388 10 9.22 1U +159TB B 296.3 7 0.00388 10 9.22 1 159TBS B EAV=83.82 22 -159TB G 536.730 120.00160 5 M1+E2 0.0236 7 -159TB2 G KC=0.0200 6$LC=0.00280 8$MC=0.00061 2 -159TB G 616.233 180.00188 8 (M1) 0.0167 5 -159TB2 G KC=0.0142 4$LC=0.00197 6$MC=0.00042 2 -159TB G 674.26 5 3.16E-4 22(M1) 0.0133 4 -159TB2 G KC=0.0113 3$LC=0.00157 5$MC=0.00034 1 +159TB G 536.730 120.00160 5M1+E2 0.0236 7 +159TB2 G KC=0.0200 6$LC=0.00280 8$MC=0.00061 2 +159TB G 616.233 180.00188 8(M1) 0.0167 5 +159TB2 G KC=0.0142 4$LC=0.00197 6$MC=0.00042 2 +159TB G 674.26 5 0.00031622(M1) 0.0133 4 +159TB2 G KC=0.0113 3$LC=0.00157 5$MC=0.00034 1 159TB L 854.960 7 (1/2)- -159TB B 115.5 7 0.0162 5 7.31 2 +159TB B 115.5 7 0.0162 5 7.31 159TBS B EAV=30.43 20 -159TB G 237.341 5 0.00769 16[E1] 0.0302 9 -159TB2 G KC=0.0256 8$LC=0.00364 11$MC=0.00079 2 -159TB G 274.163 190.0057 4 [E1] 0.0209 6 -159TB2 G KC=0.0177 5$LC=0.00250 8$MC=0.00054 2 -159TB G 854.947 200.00246 14[E1] 0.001625 -159TB2 G KC=0.00138 4$LC=1.83E-4 5$MC=4.0E-5 1 +159TB G 237.341 5 0.00769 16[E1] 0.0302 9 +159TB2 G KC=0.0256 8$LC=0.00364 11$MC=0.00079 2 +159TB G 274.163 190.0057 4[E1] 0.0209 6 +159TB2 G KC=0.0177 5$LC=0.00250 8$MC=0.00054 2 +159TB G 854.947 200.00246 14[E1] 0.00162 5 +159TB2 G KC=0.00138 4$LC=1.83E-4 5$MC=4.0E-5 1 159TB L 891.25 6 (5/2)- -159TB B 79.3 7 0.0009 4 8.08 2 +159TB B 79.3 7 0.0009 4 8.08 159TBS B EAV=20.54 19 -159TB G 273.62 120.0007 4 [E1] 0.0210 6 -159TB2 G KC=0.0178 5$LC=0.00251 8$MC=0.00055 2 -159TB G 753.74 6 0.00018 2 [E1] 0.002076 -159TB2 G KC=0.00177 5$LC=2.36E-4 7$MC=5.1E-5 2 +159TB G 273.62 120.0007 4[E1] 0.0210 6 +159TB2 G KC=0.0178 5$LC=0.00251 8$MC=0.00055 2 +159TB G 753.74 6 0.00018 2[E1] 0.00207 6 +159TB2 G KC=0.00177 5$LC=2.36E-4 7$MC=5.1E-5 2 diff --git a/HEN_HOUSE/spectra/lnhb/Ge-68.txt b/HEN_HOUSE/spectra/lnhb/Ge-68.txt index 8f9fedbc2..73083e2d1 100644 --- a/HEN_HOUSE/spectra/lnhb/Ge-68.txt +++ b/HEN_HOUSE/spectra/lnhb/Ge-68.txt @@ -5,33 +5,33 @@ 68GA2C Type=Full;Author=E.Schönfeld;Cutoff date= -- 68GA C References: 1950Ho26, 1956Ru45, 1956Cr25, 1981Wa26, 1994Sc44, 2002Bu29, 68GA2C 2003Au03 - 68GA T Auger electrons and ^X ray energies and emission intensities: - 68GA T {U Energy (keV)} {U Intensity } {U Line } + 68GA T Auger electrons and X ray energies and emission intensities: + 68GA T {U Energy (keV)} {U Intensity} {U Line} 68GA T - 68GA T 9.22495 13.25 13 XKA2 - 68GA T 9.25184 25.74 22 XKA1 + 68GA T 9.22495 13.25 13 XKA2 + 68GA T 9.25184 25.74 22 XKA1 68GA T - 68GA T 10.2605 |] XKB3 - 68GA T 10.2644 |] 5.65 7 XKB1 - 68GA T 10.348 |] XKB5II + 68GA T 10.2605 |] XKB3 + 68GA T 10.2644 |] 5.65 7 XKB1 + 68GA T 10.348 |] XKB5II 68GA T - 68GA T 10.3664 |] XKB2 - 68GA T |] 0.034 9 XKB4 + 68GA T 10.3664 |] XKB2 + 68GA T |] 0.034 9 XKB4 68GA T - 68GA T 0.959-1.303 1.490 24 XL (total) - 68GA T 0.959 0.0414 10 XLL - 68GA T 1.098-1.099 0.851 18 XLA - 68GA T 0.985 0.0244 7 XLC - 68GA T 1.114-1.283 0.571 16 XLB - 68GA T 1.141-1.303 0.00211 13 XLG + 68GA T 0.959-1.303 1.490 24 XL (total) + 68GA T 0.959 0.0414 10 XLL + 68GA T 1.098-1.099 0.851 18 XLA + 68GA T 0.985 0.0244 7 XLC + 68GA T 1.114-1.283 0.571 16 XLB + 68GA T 1.141-1.303 0.00211 13 XLG 68GA T - 68GA T 7.708-8.069 |] KLL AUGER - 68GA T 8.889-9.251 |] 41.7 4 ^KLX AUGER - 68GA T 10.051-10.366 |] KXY AUGER - 68GA T 0.8-1.3 121.8 7 L AUGER + 68GA T 7.708-8.069 |] KLL AUGER + 68GA T 8.889-9.251 |] 41.7 4 KLX AUGER + 68GA T 10.051-10.366 |] KXY AUGER + 68GA T 0.8-1.3 121.8 7 L AUGER 68GE P 0.0 0+ 270.95 D 26 106.9 24 68GA N 1.0 1.0 1 1.0 68GA L 0 1+ 67.83 M 20 68GA E 100 5.006 - 68GA2 E EAV= $CK=0.8639 24$CL=0.1150 23$CM=0.0196 5$CN=0.0015 2$CO=0 0 + 68GA2 E CK=0.8639 24$CL=0.1150 23$CM=0.0196 5$CN=0.0015 2$CO=0 0 diff --git a/HEN_HOUSE/spectra/lnhb/Hg-203.txt b/HEN_HOUSE/spectra/lnhb/Hg-203.txt index 0b45c4426..600c1c5e5 100644 --- a/HEN_HOUSE/spectra/lnhb/Hg-203.txt +++ b/HEN_HOUSE/spectra/lnhb/Hg-203.txt @@ -1,37 +1,37 @@ 203TL 203HG B- DECAY (46.594 D) -203TL T Auger electrons and ^X ray energies and emission intensities: -203TL T {U Energy (keV)} {U Intensity } {U Line } +203TL T Auger electrons and X ray energies and emission intensities: +203TL T {U Energy (keV)} {U Intensity} {U Line} 203TL T -203TL T 70.8325 3.75 4 XKA2 -203TL T 72.8725 6.33 6 XKA1 +203TL T 70.8325 3.75 4 XKA2 +203TL T 72.8725 6.33 6 XKA1 203TL T -203TL T 82.118 |] XKB3 -203TL T 82.577 |] 2.15 4 XKB1 -203TL T 83.115 |] XKB5II +203TL T 82.118 |] XKB3 +203TL T 82.577 |] 2.15 4 XKB1 +203TL T 83.115 |] XKB5II 203TL T -203TL T 84.838 |] XKB2 -203TL T 85.134 |] 0.639 16 XKB4 -203TL T 85.444 |] XKO23 +203TL T 84.838 |] XKB2 +203TL T 85.134 |] 0.639 16 XKB4 +203TL T 85.444 |] XKO23 203TL T -203TL T 8.953-14.738 5.43 9 XL (total) -203TL T 8.953 0.126 4 XLL -203TL T 10.172-10.268 2.43 7 XLA -203TL T 10.994 0.0457 12 XLC -203TL T 11.812-12.643 2.37 7 XLB -203TL T 14.291-14.738 0.435 11 XLG +203TL T 8.953-14.738 5.43 9 XL (total) +203TL T 8.953 0.126 4 XLL +203TL T 10.172-10.268 2.43 7 XLA +203TL T 10.994 0.0457 12 XLC +203TL T 11.812-12.643 2.37 7 XLB +203TL T 14.291-14.738 0.435 11 XLG 203TL T -203TL T 54.587-59.954 |] KLL AUGER -203TL T 66.37-72.86 |] 0.49 6 ^KLX AUGER -203TL T 78.12-85.5 |] KXY AUGER -203TL T 5.18-15.31 10.1 1 L AUGER +203TL T 54.587-59.954 |] KLL AUGER +203TL T 66.37-72.86 |] 0.49 6 KLX AUGER +203TL T 78.12-85.5 |] KXY AUGER +203TL T 5.18-15.31 10.1 1 L AUGER 203HG P 0.0 5/2- 46.594 D 12 491.8 12 203TL N 1.0 1.0 1 1.0 203TL L 0 1/2+ STABLE -203TL B 491.8 120.01 1 11.6 3U +203TL B 491.8 120.01 1 11.6 1U 203TLS B EAV=154.4 4 203TL L 279.1969 123/2+ -203TL B 212.6 1299.99 1 6.455 1U +203TL B 212.6 1299.99 1 6.455 1 203TLS B EAV=57.8 4 -203TL G 279.1952 1081.48 8 M1+E2 1.73 50 0.2271 12 -203TL2 G KC=0.1640 1$LC=0.0476 2$MC=0.0155 2 +203TL G 279.1952 1081.48 8M1+E2 1.73 50 0.2271 12 +203TL2 G KC=0.1640 1$LC=0.0476 2$MC=0.0155 2 diff --git a/HEN_HOUSE/spectra/lnhb/Hg-206.txt b/HEN_HOUSE/spectra/lnhb/Hg-206.txt index 63f1ab1c7..133dbb61d 100644 --- a/HEN_HOUSE/spectra/lnhb/Hg-206.txt +++ b/HEN_HOUSE/spectra/lnhb/Hg-206.txt @@ -5,51 +5,51 @@ 206TL2C 1977La19, 1992Ra08, 1994Ka08, 1996Sc06, 1998Si17, 1998ScZM, 1999ScZX, 206TL3C 1999Br39, 2000Sc47, 2002Ba85, 2003Au03, 2003De44, 2004Ma11, 2008Ki07, 206TL4C 2008Ko21, 2008DuZX -206TL T Auger electrons and ^X ray energies and emission intensities: -206TL T {U Energy (keV)} {U Intensity } {U Line } +206TL T Auger electrons and X ray energies and emission intensities: +206TL T {U Energy (keV)} {U Intensity} {U Line} 206TL T -206TL T 70.8325 2.3 5 XKA2 -206TL T 72.8725 3.9 8 XKA1 +206TL T 70.8325 2.3 5 XKA2 +206TL T 72.8725 3.9 8 XKA1 206TL T -206TL T 82.118 |] XKB3 -206TL T 82.577 |] 1.32 25 XKB1 -206TL T 83.115 |] XKB5II +206TL T 82.118 |] XKB3 +206TL T 82.577 |] 1.32 25 XKB1 +206TL T 83.115 |] XKB5II 206TL T -206TL T 84.838 |] XKB2 -206TL T 85.134 |] 0.39 8 XKB4 -206TL T 85.444 |] XKO23 +206TL T 84.838 |] XKB2 +206TL T 85.134 |] 0.39 8 XKB4 +206TL T 85.444 |] XKO23 206TL T -206TL T 8.9531-14.7362 2.9 4 XL (total) -206TL T 8.9531 0.072 11 XLL -206TL T 10.1718-10.2679 1.39 19 XLA -206TL T 10.9942 0.022 4 XLC -206TL T 11.8117-12.9566 1.23 15 XLB -206TL T 13.8528-14.7362 0.23 3 XLG +206TL T 8.9531-14.7362 2.9 4 XL (total) +206TL T 8.9531 0.072 11 XLL +206TL T 10.1718-10.2679 1.39 19 XLA +206TL T 10.9942 0.022 4 XLC +206TL T 11.8117-12.9566 1.23 15 XLB +206TL T 13.8528-14.7362 0.23 3 XLG 206TL T -206TL T 54.587-59.954 |] KLL AUGER -206TL T 66.37-72.86 |] 0.30 7 ^KLX AUGER -206TL T 78.12-85.5 |] KXY AUGER -206TL T 5.25-15.32 5.1 4 L AUGER +206TL T 54.587-59.954 |] KLL AUGER +206TL T 66.37-72.86 |] 0.30 7 KLX AUGER +206TL T 78.12-85.5 |] KXY AUGER +206TL T 5.25-15.32 5.1 4 L AUGER 206HG P 0.0 0+ 8.32 M 7 1308 20 206TL N 1.0 1.0 1 1.0 206TL L 0 0 0- STABLE -206TL B 1308 2062 7 5.67 +206TL B 1308 2062 7 5.67 206TLS B EAV=450 8 206TL L 265.832 5 2- 2.29 NS 14 -206TL G 265.832 5 0.012 6 E2 0.1603 23 -206TL2 G KC=0.0855 12$LC=0.0561 8$MC=0.01440 21 +206TL G 265.832 5 0.012 6E2 0.1603 23 +206TL2 G KC=0.0855 12$LC=0.0561 8$MC=0.01440 21 206TL L 304.896 6 1- 4.2 PS 14 -206TL B 1003 2035 7 5.24 1 +206TL B 1003 2035 7 5.24 1 206TLS B EAV=330 8 -206TL G 304.896 6 26 5 M1 0.375 6 -206TL2 G KC=0.308 5$LC=0.0519 8$MC=0.01211 17 +206TL G 304.896 6 26 5M1 0.375 6 +206TL2 G KC=0.308 5$LC=0.0519 8$MC=0.01211 17 206TL L 649.42 4 1- -206TL B 659 203.0 4 5.41 1 +206TL B 659 203.0 4 5.41 1 206TLS B EAV=203 7 -206TL G 344.52 170.55 11M1 0.269 4 -206TL2 G KC=0.221 4$LC=0.0371 6$MC=0.00866 13 -206TL G 383.59 6 0.012 6 M1(+E2) 0.13 8 -206TL2 G KC=0.10 7$LC=0.021 7$MC=0.0050 15 -206TL G 649.42 5 2.2 3 M1 0.0501 7 -206TL2 G KC=0.0412 6$LC=0.00681 10$MC=1585E-6 23 +206TL G 344.52 170.55 11M1 0.269 4 +206TL2 G KC=0.221 4$LC=0.0371 6$MC=0.00866 13 +206TL G 383.59 6 0.012 6M1(+E2) 0.13 8 +206TL2 G KC=0.10 7$LC=0.021 7$MC=0.0050 15 +206TL G 649.42 5 2.2 3M1 0.0501 7 +206TL2 G KC=0.0412 6$LC=0.00681 10$MC=1585E-6 23 diff --git a/HEN_HOUSE/spectra/lnhb/Ho-166.txt b/HEN_HOUSE/spectra/lnhb/Ho-166.txt index 77b1443aa..4c9fddbc6 100644 --- a/HEN_HOUSE/spectra/lnhb/Ho-166.txt +++ b/HEN_HOUSE/spectra/lnhb/Ho-166.txt @@ -1,30 +1,30 @@ 166ER 166HO B- DECAY (26.795 H) 166ER C References: 1977La19 -166ER T Auger electrons and ^X ray energies and emission intensities: -166ER T {U Energy (keV)} {U Intensity } {U Line } +166ER T Auger electrons and X ray energies and emission intensities: +166ER T {U Energy (keV)} {U Intensity} {U Line} 166ER T -166ER T 48.2215 2.91 10 XKA2 -166ER T 49.1282 5.16 17 XKA1 +166ER T 48.2215 2.91 10 XKA2 +166ER T 49.1282 5.16 17 XKA1 166ER T -166ER T 55.495 |] XKB3 -166ER T 55.682 |] 1.68 6 XKB1 -166ER T 56.04 |] XKB5II +166ER T 55.495 |] XKB3 +166ER T 55.682 |] 1.68 6 XKB1 +166ER T 56.04 |] XKB5II 166ER T -166ER T 57.21 |] XKB2 -166ER T 57.313 |] 0.436 18 XKB4 -166ER T 57.456 |] XKO23 +166ER T 57.21 |] XKB2 +166ER T 57.313 |] 0.436 18 XKB4 +166ER T 57.456 |] XKO23 166ER T -166ER T 6.14-9.43 7.91 18 XL (total) -166ER T 6.14 0.151 5 XLL -166ER T 6.9-6.95 3.47 10 XLA -166ER T 7.05 0.0775 27 XLC -166ER T 7.75-8.34 3.62 11 XLB -166ER T 8.81-9.43 0.586 19 XLG +166ER T 6.14-9.43 7.91 18 XL (total) +166ER T 6.14 0.151 5 XLL +166ER T 6.9-6.95 3.47 10 XLA +166ER T 7.05 0.0775 27 XLC +166ER T 7.75-8.34 3.62 11 XLB +166ER T 8.81-9.43 0.586 19 XLG 166ER T -166ER T 37.78-40.55 |] KLL AUGER -166ER T 45.52-49.1 |] 0.63 5 ^KLX AUGER -166ER T 53.07-57.84 |] KXY AUGER -166ER T 3.9-7.6 28.0 6 L AUGER +166ER T 37.78-40.55 |] KLL AUGER +166ER T 45.52-49.1 |] 0.63 5 KLX AUGER +166ER T 53.07-57.84 |] KXY AUGER +166ER T 3.9-7.6 28.0 6 L AUGER 166HO P 0.0 0- 26.795 H 29 1854.5 9 166ER N 1.0 1.0 1 1.0 166ER L 0 0+ STABLE @@ -33,50 +33,50 @@ 166ER L 80.5725 132+ 1.82 NS 3 166ER B 1773.9 9 50.5 15 9 1U 166ERS B EAV=651.1 6 -166ER G 80.5725 136.55 8 E2 6.90 14 -166ER2 G KC=1.65 5$LC=4.01 8$MC=0.978 20 +166ER G 80.5725 136.55 8E2 6.90 14 +166ER2 G KC=1.65 5$LC=4.01 8$MC=0.978 20 166ER L 264.9832 174+ 118 PS 5 -166ER G 184.4107 110.0015 7 E2 0.333 10 -166ER2 G KC=0.205 6$LC=0.0984 30$MC=0.0236 7 +166ER G 184.4107 110.0015 7E2 0.333 10 +166ER2 G KC=0.205 6$LC=0.0984 30$MC=0.0236 7 166ER L 785.78 7 2+ 3.26 PS 11 166ER B 1068.6 9 0.0072 21 11.6 1U 166ERS B EAV=356 9 -166ER G 520.80 7 0.00035 2 E2 0.0149 5 -166ER2 G KC=0.01192 36$LC=0.00234 7$MC=5.35E-4 16 +166ER G 520.80 7 0.00035 2E2 0.0149 5 +166ER2 G KC=0.01192 36$LC=0.00234 7$MC=5.35E-4 16 166ER G 705.21 7 0.0146 12E2+M1 0.0072122 -166ER2 G KC=0.00591 18$LC=1012E-6 30$MC=2.28E-4 7 -166ER G 785.78 7 0.0120 3 E2 0.0056617 -166ER2 G KC=0.00467 14$LC=7.69E-4 23$MC=1.73E-4 5 +166ER2 G KC=0.00591 18$LC=1012E-6 30$MC=2.28E-4 7 +166ER G 785.78 7 0.0120 3E2 0.0056617 +166ER2 G KC=0.00467 14$LC=7.69E-4 23$MC=1.73E-4 5 166ER L 1460.025 100+ 166ER B 394.5 9 0.955 16 7.4 166ERS B EAV=115 3 166ER G 674.24 7 0.0198 17E2 0.0079924 -166ER2 G KC=0.00653 20$LC=1138E-6 34$MC=2.57E-4 8 -166ER G 1379.446 100.933 35E2 0.001795 -166ER2 G KC=0.00151 5$LC=0.00022 1$MC=4.8E-5 2 -166ER G 1460.018 102000E-7 0 +166ER2 G KC=0.00653 20$LC=1138E-6 34$MC=2.57E-4 8 +166ER G 1379.446 100.933 35E2 0.00179 5 +166ER2 G KC=0.00151 5$LC=0.00022 1$MC=4.8E-5 2 +166ER G 1460.018 100.0002 166ER L 1528.23 152+ 166ER B 326.2 9 0.00276 22 9.5 1U 166ERS B EAV=93 3 -166ER G 1263.24 150.0155 9 E2(+M3) 0.0021 2 -166ER2 G KC=0.0018 2$LC=0.0003 1$MC=5.8E-5 2 -166ER G 1447.66 150.00105 10E2(+) 0.001635 -166ER2 G KC=0.00138 4$LC=1.98E-4 6$MC=4.4E-5 2 -166ER G 1528.23 150.00014 5 E2 0.001474 -166ER2 G KC=0.00125 4$LC=1.78E-4 5$MC= +166ER G 1263.24 150.0155 9E2(+M3) 0.0021 2 +166ER2 G KC=0.0018 2$LC=0.0003 1$MC=5.8E-5 2 +166ER G 1447.66 150.00105 10E2(+) 0.00163 5 +166ER2 G KC=0.00138 4$LC=1.98E-4 6$MC=4.4E-5 2 +166ER G 1528.23 150.00014 5E2 0.00147 4 +166ER2 G KC=0.00125 4$LC=1.78E-4 5 166ER L 1662.433 151- -166ER B 192.0 9 0.304 7 6.9 +166ER B 192.0 9 0.304 7 6.9 166ERS B EAV=52 1 -166ER G 1581.852 150.186 4 E1+(M2) -166ER G 1662.424 150.118 5 E1 +166ER G 1581.852 150.186 4E1+(M2) +166ER G 1662.424 150.118 5E1 166ER L 1812.8 5 1- -166ER B 41.7 9 0.00010 3 12.1 +166ER B 41.7 9 0.00010 3 12.1 166ERS B EAV=13 2 -166ER G 1732.2 5 4.6E-5 20M1(+E2) -166ER G 1812.8 5 5.6E-5 19E1(+M2) +166ER G 1732.2 5 0.00004620M1(+E2) +166ER G 1812.8 5 0.00005619E1(+M2) 166ER L 1830.419 241- 166ER B 24.1 9 0.0353 11 5 166ERS B EAV=7.1 10 166ER G 1749.837 140.0272 10E1(+M2) -166ER G 1830.408 240.0081 2 E1 +166ER G 1830.408 240.0081 2E1 diff --git a/HEN_HOUSE/spectra/lnhb/Ho-166m.txt b/HEN_HOUSE/spectra/lnhb/Ho-166m.txt index 3821f6a94..2f8971ec9 100644 --- a/HEN_HOUSE/spectra/lnhb/Ho-166m.txt +++ b/HEN_HOUSE/spectra/lnhb/Ho-166m.txt @@ -3,173 +3,173 @@ 166ER2 H TYP=Full$AUT=E.Schonfeld$CUT=01-JUN-1999$ 166ER C Evaluation history: Type=Update;Author=M.-M.Bé;Cutoff date=01-JUN-2006 166ER2C Type=Full;Author=E.Schonfeld;Cutoff date=01-JUN-1999 -166ER T Auger electrons and ^X ray energies and emission intensities: -166ER T {U Energy (keV)} {U Intensity } {U Line } +166ER T Auger electrons and X ray energies and emission intensities: +166ER T {U Energy (keV)} {U Intensity} {U Line} 166ER T -166ER T 48.2215 10.81 21 XKA2 -166ER T 49.1282 19.2 4 XKA1 +166ER T 48.2215 10.81 21 XKA2 +166ER T 49.1282 19.2 4 XKA1 166ER T -166ER T 55.495 |] XKB3 -166ER T 55.682 |] 6.24 14 XKB1 -166ER T 56.04 |] XKB5II +166ER T 55.495 |] XKB3 +166ER T 55.682 |] 6.24 14 XKB1 +166ER T 56.04 |] XKB5II 166ER T -166ER T 57.21 |] XKB2 -166ER T 57.313 |] 1.62 5 XKB4 -166ER T 57.456 |] XKO23 +166ER T 57.21 |] XKB2 +166ER T 57.313 |] 1.62 5 XKB4 +166ER T 57.456 |] XKO23 166ER T -166ER T 6.14-9.43 20.8 4 XL (total) -166ER T 6.14 0.398 12 XLL -166ER T 6.9-6.95 9.19 24 XLA -166ER T 7.05 0.198 6 XLC -166ER T 7.75-8.34 9.46 24 XLB -166ER T 8.81-9.43 1.54 5 XLG +166ER T 6.14-9.43 20.8 4 XL (total) +166ER T 6.14 0.398 12 XLL +166ER T 6.9-6.95 9.19 24 XLA +166ER T 7.05 0.198 6 XLC +166ER T 7.75-8.34 9.46 24 XLB +166ER T 8.81-9.43 1.54 5 XLG 166ER T -166ER T 37.78-40.55 |] KLL AUGER -166ER T 45.52-49.1 |] 2.33 17 ^KLX AUGER -166ER T 53.07-56.84 |] KXY AUGER -166ER T 3.9-7.6 72.0 7 L AUGER +166ER T 37.78-40.55 |] KLL AUGER +166ER T 45.52-49.1 |] 2.33 17 KLX AUGER +166ER T 53.07-56.84 |] KXY AUGER +166ER T 3.9-7.6 72.0 7 L AUGER 166HO P 5.98 2 7- 1133 Y 8 1854.5 9 166ER N 1.0 1.0 1 1.0 166ER L 0 0+ STABLE 166ER L 80.5725 132+ 1.82 NS 166ER G 80.5725 1312.66 23E2 6.90 14 -166ER2 G KC=1.65 3$LC=4.01 8$MC=0.978 29 +166ER2 G KC=1.65 3$LC=4.01 8$MC=0.978 29 166ER L 264.9832 174+ 118 PS -166ER G 184.4107 1172.5 3 E2 0.334 7 -166ER2 G KC=0.205 6$LC=0.0984 30$MC=0.0236 7 +166ER G 184.4107 1172.5 3E2 0.334 7 +166ER2 G KC=0.205 6$LC=0.0984 30$MC=0.0236 7 166ER L 545.4462 296+ -166ER B 1315.1 9 3.4 6 14.3 1 +166ER B 1315.1 9 3.4 6 14.3 1 166ERS B EAV=674.6 9 166ER G 280.4630 2329.54 25E2 0.0855 17 -166ER2 G KC=0.0613 12$LC=0.0187 4$MC=0.00439 13 +166ER2 G KC=0.0613 12$LC=0.0187 4$MC=0.00439 13 166ER L 785.78 7 2+ 3.26 PS -166ER G 520.80 7 0.153 6 E2 0.0149 3 -166ER2 G KC=0.01192 36$LC=0.00234 7$MC=5.35E-4 16 -166ER G 705.21 7 0.014 7 E2(+M1) 0.0072122 -166ER2 G KC=0.00591 18$LC=1012E-6 30$MC=2.28E-4 7 -166ER G 785.78 7 0.019 4 E2 0.0056617 -166ER2 G KC=0.00467 14$LC=7.69E-4 23$MC=1.73E-4 5 +166ER G 520.80 7 0.153 6E2 0.0149 3 +166ER2 G KC=0.01192 36$LC=0.00234 7$MC=5.35E-4 16 +166ER G 705.21 7 0.014 7E2(+M1) 0.0072122 +166ER2 G KC=0.00591 18$LC=1012E-6 30$MC=2.28E-4 7 +166ER G 785.78 7 0.019 4E2 0.0056617 +166ER2 G KC=0.00467 14$LC=7.69E-4 23$MC=1.73E-4 5 166ER L 859.400 6 3+ 166ER G 73.62 7 0.0260 16M1+E2 7.14 21 -166ER2 G KC=5.98 18$LC=0.902 27$MC=0.201 6 -166ER G 594.417 6 0.58 6 E2+M1 0.0108933 +166ER2 G KC=5.98 18$LC=0.902 27$MC=0.201 6 +166ER G 594.417 6 0.58 6E2+M1 0.0108933 166ER2 G KC=0.00881 26$LC=1613E-6 48$MC=3.66E-4 11 -166ER G 778.827 6 3.01 8 E2+M1 0.0057917 -166ER2 G KC=0.00477 14$LC=7.88E-4 24$MC=1.77E-4 5 +166ER G 778.827 6 3.01 8E2+M1 0.0057917 +166ER2 G KC=0.00477 14$LC=7.88E-4 24$MC=1.77E-4 5 166ER L 911.214 7 8+ 4.2 PS -166ER B 949.3 9 1.12 6 14.2 1 +166ER B 949.3 9 1.12 6 14.2 1 166ERS B EAV=294.3 9 -166ER G 365.768 6 2.46 4 E2 0.0388 8 -166ER2 G KC=0.0294 6$LC=0.00721 15$MC=0.00167 5 +166ER G 365.768 6 2.46 4E2 0.0388 8 +166ER2 G KC=0.0294 6$LC=0.00721 15$MC=0.00167 5 166ER L 956.236 8 4+ -166ER G 691.253 7 1.32 7 E2+M1 0.0075823 -166ER2 G KC=0.00620 19$LC=1069E-6 32$MC=2.41E-4 7 -166ER G 875.663 7 0.721 9 E2 0.0044713 +166ER G 691.253 7 1.32 7E2+M1 0.0075823 +166ER2 G KC=0.00620 19$LC=1069E-6 32$MC=2.41E-4 7 +166ER G 875.663 7 0.721 9E2 0.0044713 166ER2 G KC=0.00371 11$LC=5.92E-4 18$MC=1324E-7 40 166ER L 1075.269 5 5+ 60 PS -166ER G 119.033 100.173 3 E2+M1 1.614 48 +166ER G 119.033 100.173 3E2+M1 1.614 48 166ER2 G KC=0.888 27$LC=0.556 17$MC=0.1339 40 -166ER G 215.871 7 2.66 17E2 0.197 4 +166ER G 215.871 7 2.66 17E2 0.197 4 166ER2 G KC=0.1299 26$LC=0.0516 10$MC=0.01229 37 -166ER G 529.825 4 9.4 4 M1+E2 0.0144 3 -166ER2 G KC=0.01145 26$LC=0.00223 5$MC=5.08E-4 15 -166ER G 810.286 4 57.3 11E2+M1 0.0053 1 -166ER2 G KC=0.00438 9$LC=0.00071 2$MC=1603E-7 48 +166ER G 529.825 4 9.4 4M1+E2 0.0144 3 +166ER2 G KC=0.01145 26$LC=0.00223 5$MC=5.08E-4 15 +166ER G 810.286 4 57.3 11E2+M1 0.0053 1 +166ER2 G KC=0.00438 9$LC=0.00071 2$MC=1603E-7 48 166ER L 1215.972 5 6+ 166ER B 644.5 9 2.31 29 13.4 1 166ERS B EAV=201.2 9 166ER G 140.703 7 0.0428 22M1+E2 0.938 28 -166ER2 G KC=0.604 18$LC=0.256 8$MC=0.0611 18 +166ER2 G KC=0.604 18$LC=0.256 8$MC=0.0611 18 166ER G 259.736 101.078 10E2 0.1087 22 -166ER2 G KC=0.0762 15$LC=0.0249 5$MC=0.00589 18 +166ER2 G KC=0.0762 15$LC=0.0249 5$MC=0.00589 18 166ER G 304.758 9 0.0183 12E2 0.0662 13 -166ER2 G KC=0.0485 10$LC=0.0137 3$MC=0.00322 10 +166ER2 G KC=0.0485 10$LC=0.0137 3$MC=0.00322 10 166ER G 670.526 4 5.34 21E2+M1 0.0081624 -166ER2 G KC=0.00666 20$LC=1161E-6 35$MC=2.62E-4 8 +166ER2 G KC=0.00666 20$LC=1161E-6 35$MC=2.62E-4 8 166ER G 950.988 4 2.744 19E2 0.0037611 -166ER2 G KC=0.00313 9$LC=4.88E-4 15$MC=1089E-7 33 +166ER2 G KC=0.00313 9$LC=4.88E-4 15$MC=1089E-7 33 166ER L 1376.011 5 7+ 166ER B 484.5 9 0.81 26 13 166ERS B EAV= -166ER G 160.039 7 0.097 5 M1+E2 1.45 11 0.616 18 +166ER G 160.039 7 0.097 5M1+E2 1.45 11 0.616 18 166ER2 G KC=0.417 13$LC=0.1530 46$MC=0.0363 11 -166ER G 300.741 3 3.73 3 E2 0.0691 14 -166ER2 G KC=0.0503 10$LC=0.0144 3$MC=0.00338 10 -166ER G 464.798 6 1.25 4 M1+E2 0.0201 6 -166ER2 G KC=0.01579 47$LC=0.0033 1$MC=7.58E-4 23 +166ER G 300.741 3 3.73 3E2 0.0691 14 +166ER2 G KC=0.0503 10$LC=0.0144 3$MC=0.00338 10 +166ER G 464.798 6 1.25 4M1+E2 0.0201 6 +166ER2 G KC=0.01579 47$LC=0.0033 1$MC=7.58E-4 23 166ER G 830.565 4 9.72 18E2+M1 0.0050315 166ER2 G KC=0.00416 12$LC=6.73E-4 20$MC=1509E-7 45 166ER L 1555.72 5 8+ -166ER B 304.6 9 0.394 5 12.9 1 +166ER B 304.6 9 0.394 5 12.9 1 166ERS B EAV= -166ER G 339.75 5 0.1616 23E2 0.048 1 -166ER2 G KC=0.0359 7$LC=0.00930 19$MC=0.00217 7 -166ER G 644.51 7 0.144 4 E2+M1 0.0098930 -166ER2 G KC=0.00810 24$LC=1384E-6 42$MC=3.12E-4 9 +166ER G 339.75 5 0.1616 23E2 0.048 1 +166ER2 G KC=0.0359 7$LC=0.00930 19$MC=0.00217 7 +166ER G 644.51 7 0.144 4E2+M1 0.0098930 +166ER2 G KC=0.00810 24$LC=1384E-6 42$MC=3.12E-4 9 166ER G 1010.27 6 0.0794 16E2 0.0033210 -166ER2 G KC=0.00277 8$LC=4.25E-4 13$MC=9.47E-5 28 +166ER2 G KC=0.00277 8$LC=4.25E-4 13$MC=9.47E-5 28 166ER L 1572.22 6 4- -166ER G 496.90 6 0.125 3 E1(+M2) 0.0057117 +166ER G 496.90 6 0.125 3E1(+M2) 0.0057117 166ER2 G KC=0.00483 15$LC=6.79E-4 20$MC=1497E-7 45 166ER G 615.93 6 0.094 29E4 0.0687 21 -166ER2 G KC=0.0444 13$LC=0.0185 6$MC=0.00449 13 -166ER G 712.89 130.30 9 E1 +166ER2 G KC=0.0444 13$LC=0.0185 6$MC=0.00449 13 +166ER G 712.89 130.30 9E1 166ER G 1307.19 6 0.0055 11E1 8.52E-426 -166ER2 G KC=7.27E-4 22$LC=9.70E-5 29$MC=2.13E-5 6 +166ER2 G KC=7.27E-4 22$LC=9.70E-5 29$MC=2.13E-5 6 166ER L 1596.10 7 4- -166ER G 639.86 6 0.0943 7 E1 0.0033110 -166ER2 G KC=0.00282 8$LC=3.89E-4 12$MC=8.57E-5 26 -166ER G 736.70 7 0.373 6 E1 0.002497 -166ER2 G KC=0.00211 6$LC=2.90E-4 9$MC=6.37E-5 19 +166ER G 639.86 6 0.0943 7E1 0.0033110 +166ER2 G KC=0.00282 8$LC=3.89E-4 12$MC=8.57E-5 26 +166ER G 736.70 7 0.373 6E1 0.00249 7 +166ER2 G KC=0.00211 6$LC=2.90E-4 9$MC=6.37E-5 19 166ER G 1331.12 7 0.0043 12E1 8.25E-425 -166ER2 G KC=7.05E-4 21$LC=9.39E-5 28$MC=2.06E-5 6 +166ER2 G KC=7.05E-4 21$LC=9.39E-5 28$MC=2.06E-5 6 166ER L 1665.79 3 5- -166ER G 1120.32 3 0.199 4 E1 1121E-634 -166ER2 G KC=9.56E-4 29$LC=1283E-7 38$MC=2.81E-5 8 -166ER G 1400.79 2 0.508 6 E1 7.55E-423 -166ER2 G KC=6.45E-4 19$LC=8.59E-5 26$MC=1.88E-5 6 +166ER G 1120.320 300.199 4E1 1121E-634 +166ER2 G KC=9.56E-4 29$LC=1283E-7 38$MC=2.81E-5 8 +166ER G 1400.79 2 0.508 6E1 7.55E-423 +166ER2 G KC=6.45E-4 19$LC=8.59E-5 26$MC=1.88E-5 6 166ER L 1692.291 125- -166ER G 476.25 4 0.0363 13E1 0.0062719 -166ER2 G KC=0.00531 16$LC=7.48E-4 22$MC=1.65E-4 5 -166ER G 736.02 8 0.14 2 -166ER G 1146.77 3 0.2059 26E1 1075E-632 -166ER2 G KC=9.18E-4 28$LC=1230E-7 37$MC=2.70E-5 8 -166ER G 1427.24 2 0.498 6 E1 7.32E-422 -166ER2 G KC=6.25E-4 19$LC=8.31E-5 25$MC=1.82E-5 5 +166ER G 476.250 400.0363 13E1 0.0062719 +166ER2 G KC=0.00531 16$LC=7.48E-4 22$MC=1.65E-4 5 +166ER G 736.02 8 0.14 2 +166ER G 1146.770 300.2059 26E1 1075E-632 +166ER2 G KC=9.18E-4 28$LC=1230E-7 37$MC=2.70E-5 8 +166ER G 1427.24 2 0.498 6E1 7.32E-422 +166ER2 G KC=6.25E-4 19$LC=8.31E-5 25$MC=1.82E-5 5 166ER L 1786.966 7 6- 166ER B 73.5 9 74.8 12 8.8 166ERS B EAV=18.6 4 -166ER G 94.675 140.146 4 M1+E2 3.45 10 -166ER2 G KC=2.89 9$LC=0.435 13$MC=0.0967 29 -166ER G 121.175 100.241 7 E2 1.460 44 +166ER G 94.675 140.146 4M1+E2 3.45 10 +166ER2 G KC=2.89 9$LC=0.435 13$MC=0.0967 29 +166ER G 121.175 100.241 7E2 1.460 44 166ER2 G KC=0.663 20$LC=0.610 18$MC=0.1480 44 -166ER G 190.86 7 0.215 5 E2 0.297 9 -166ER2 G KC=0.186 6$LC=0.0853 26$MC=0.0204 6 -166ER G 214.79 3 0.445 11E2 0.200 4 +166ER G 190.86 7 0.215 5E2 0.297 9 +166ER2 G KC=0.186 6$LC=0.0853 26$MC=0.0204 6 +166ER G 214.79 3 0.445 11E2 0.200 4 166ER2 G KC=0.1318 40$LC=0.0526 16$MC=0.01254 38 166ER G 410.956 3 11.35 17E1(+M2) 0.0087826 -166ER2 G KC=0.00743 22$LC=1055E-6 32$MC=2.33E-4 7 +166ER2 G KC=0.00743 22$LC=1055E-6 32$MC=2.33E-4 7 166ER G 570.995 5 5.43 20E1(+M2) 0.0042113 166ER2 G KC=0.00358 11$LC=4.98E-4 15$MC=1097E-7 33 -166ER G 711.697 3 54.9 9 E1(+M2) 0.002668 -166ER2 G KC=0.00227 7$LC=3.11E-4 9$MC=6.85E-5 21 -166ER G 1241.519 4 0.85 3 E1(+M2) 9.32E-428 -166ER2 G KC=7.96E-4 24$LC=1063E-7 32$MC=2.33E-5 7 +166ER G 711.697 3 54.9 9E1(+M2) 0.00266 8 +166ER2 G KC=0.00227 7$LC=3.11E-4 9$MC=6.85E-5 21 +166ER G 1241.519 4 0.85 3E1(+M2) 9.32E-428 +166ER2 G KC=7.96E-4 24$LC=1063E-7 32$MC=2.33E-5 7 166ER L 1827.551 7 6- -166ER B 32.9 9 17.2 4 8.4 +166ER B 32.9 9 17.2 4 8.4 166ERS B EAV=8.2 2 166ER G 135.260 140.0979 19E2 0.981 29 166ER2 G KC=0.493 15$LC=0.373 11$MC=0.0904 27 -166ER G 161.76 3 0.109 4 E2(+M1) 0.522 16 -166ER2 G KC=0.299 9$LC=0.171 5$MC=0.0412 12 -166ER G 231.45 7 0.219 6 E2 0.157 3 -166ER2 G KC=0.1062 21$LC=0.0391 8$MC=0.00928 28 +166ER G 161.76 3 0.109 4E2(+M1) 0.522 16 +166ER2 G KC=0.299 9$LC=0.171 5$MC=0.0412 12 +166ER G 231.45 7 0.219 6E2 0.157 3 +166ER2 G KC=0.1062 21$LC=0.0391 8$MC=0.00928 28 166ER G 451.540 4 2.915 14E1(+M2) 0.0070721 -166ER2 G KC=0.00599 18$LC=8.46E-4 25$MC=1.87E-4 6 +166ER2 G KC=0.00599 18$LC=8.46E-4 25$MC=1.87E-4 6 166ER G 611.579 6 1.31 21E1(+M2) 0.0036411 -166ER2 G KC=0.00309 9$LC=4.29E-4 13$MC=9.44E-5 28 -166ER G 752.280 4 12.2 3 E1(+M2) 0.002387 -166ER2 G KC=0.00203 6$LC=2.78E-4 8$MC=6.11E-5 18 -166ER G 1282.102 5 0.183 7 E1(+M2) 8.81E-426 -166ER2 G KC=7.52E-4 23$LC=1004E-7 30$MC=2.20E-5 7 +166ER2 G KC=0.00309 9$LC=4.29E-4 13$MC=9.44E-5 28 +166ER G 752.280 4 12.2 3E1(+M2) 0.00238 7 +166ER2 G KC=0.00203 6$LC=2.78E-4 8$MC=6.11E-5 18 +166ER G 1282.102 5 0.183 7E1(+M2) 8.81E-426 +166ER2 G KC=7.52E-4 23$LC=1004E-7 30$MC=2.20E-5 7 diff --git a/HEN_HOUSE/spectra/lnhb/I-123.txt b/HEN_HOUSE/spectra/lnhb/I-123.txt index a38dcee98..aad2feafb 100644 --- a/HEN_HOUSE/spectra/lnhb/I-123.txt +++ b/HEN_HOUSE/spectra/lnhb/I-123.txt @@ -1,126 +1,126 @@ 123TE 123I EC DECAY (13.2234 H) -123TE T Auger electrons and ^X ray energies and emission intensities: -123TE T {U Energy (keV)} {U Intensity } {U Line } +123TE T Auger electrons and X ray energies and emission intensities: +123TE T {U Energy (keV)} {U Intensity} {U Line} 123TE T -123TE T 27.202 24.69 20 XKA2 -123TE T 27.4726 45.98 29 XKA1 +123TE T 27.202 24.69 20 XKA2 +123TE T 27.4726 45.98 29 XKA1 123TE T -123TE T 30.9446 |] XKB3 -123TE T 30.996 |] 13.16 17 XKB1 -123TE T 31.236 |] XKB5II -123TE T 31.241 |] XKB5I +123TE T 30.9446 |] XKB3 +123TE T 30.996 |] 13.16 17 XKB1 +123TE T 31.236 |] XKB5II +123TE T 31.241 |] XKB5I 123TE T -123TE T 31.7008 |] XKB2 -123TE T 31.774 |] 2.86 8 XKB4 -123TE T 31.812 |] XKO23 +123TE T 31.7008 |] XKB2 +123TE T 31.774 |] 2.86 8 XKB4 +123TE T 31.812 |] XKO23 123TE T -123TE T 3.336-4.82 9.0 4 XL (total) -123TE T 3.336 0.159 5 XLL -123TE T 3.76-3.77 4.22 11 XLA -123TE T 3.606 0.0598 18 XLC -123TE T 4.02-4.37 2.91 7 XLB -123TE T 4.44-4.82 0.366 10 XLG +123TE T 3.336-4.82 9.0 4 XL (total) +123TE T 3.336 0.159 5 XLL +123TE T 3.76-3.77 4.22 11 XLA +123TE T 3.606 0.0598 18 XLC +123TE T 4.02-4.37 2.91 7 XLB +123TE T 4.44-4.82 0.366 10 XLG 123TE T -123TE T 21.804-22.989 |] KLL AUGER -123TE T 25.814-27.47 |] 12.4 4 ^KLX AUGER -123TE T 29.8-31.81 |] KXY AUGER -123TE T 2.3-4.8 95.3 6 L AUGER +123TE T 21.804-22.989 |] KLL AUGER +123TE T 25.814-27.47 |] 12.4 4 KLX AUGER +123TE T 29.8-31.81 |] KXY AUGER +123TE T 2.3-4.8 95.3 6 L AUGER 123I P 0.0 5/2+ 13.2234 H 37 1234 3 123TE N 1.0 1.0 1 1.0 123TE L 0 1/2+ 12E12 Y 123TE L 158.99 3 3/2+ 196 PS 9 -123TE E 97.18 325.26 2 -123TE2 E EAV= $CK=0.8533 14$CL=0.1163 10$CM=0.0248 5$CN=0.0056 3$CO=0 0 +123TE E 97.18 325.26 +123TE2 E CK=0.8533 14$CL=0.1163 10$CM=0.0248 5$CN=0.0056 3$CO=0 0 123TE G 158.97 5 83.25 21M1+E2 0.111 3 0.1918 19 -123TE2 G KC=0.1648 16$LC=0.02160 22$MC= +123TE2 G KC=0.1648 16$LC=0.02160 22 123TE L 440.00 4 3/2+ 22 PS 3 -123TE E 0.419 5 7.35 2 -123TE2 E EAV= $CK=0.8510 14$CL=0.1181 10$CM=0.0253 5$CN=0.0056 3$CO=0 0 -123TE G 281.03 5 0.0789 9 M1+E2 -0.39 15 0.0422 33 -123TE2 G KC=0.0362 20$LC=0.0048 11$MC= -123TE G 440.02 5 0.4229 43M1+E2 -2.1 1 0.0121 7 -123TE2 G KC=0.0103 7$LC=1452E-6 18$MC= +123TE E 0.419 57.35 +123TE2 E CK=0.8510 14$CL=0.1181 10$CM=0.0253 5$CN=0.0056 3$CO=0 0 +123TE G 281.03 5 0.0789 9M1+E2 -0.39 15 0.0422 33 +123TE2 G KC=0.0362 20$LC=0.0048 11 +123TE G 440.02 5 0.4229 43M1+E2 -2.1 1 0.0121 7 +123TE2 G KC=0.0103 7$LC=1452E-6 18 123TE L 489.70 8 (7/2)+ 30.7 NS -123TE E 0.0025 109.52 2 -123TE2 E EAV= $CK=0.8503 14$CL=0.1186 10$CM=0.0254 5$CN=0.0057 3$CO=0 0 -123TE G 330.70 8 0.01164 33E2 0.0284 9 -123TE2 G KC=0.0237 7$LC=0.00376 11$MC= +123TE E 0.0025 109.52 +123TE2 E CK=0.8503 14$CL=0.1186 10$CM=0.0254 5$CN=0.0057 3$CO=0 0 +123TE G 330.70 8 0.01164 33E2 0.0284 9 +123TE2 G KC=0.0237 7$LC=0.00376 11 123TE L 505.34 4 (5/2)+ 13.5 PS 25 123TE E 0.349 427.35 -123TE2 E EAV= $CK=0.8501 14$CL=0.1187 10$CM=0.0254 5$CN=0.0058 3$CO=0 0 -123TE G 346.35 5 0.1257 9 M1+E2 0.07 7 0.0240723 -123TE2 G KC=0.02080 14$LC=0.00262 29$MC= -123TE G 505.33 5 0.266 42M1+E2 0.10 2 0.0093 7 -123TE2 G KC=0.0081 7$LC=1063E-6 27$MC= +123TE2 E CK=0.8501 14$CL=0.1187 10$CM=0.0254 5$CN=0.0058 3$CO=0 0 +123TE G 346.35 5 0.1257 9M1+E2 0.07 7 0.0240723 +123TE2 G KC=0.02080 14$LC=0.00262 29 +123TE G 505.33 5 0.266 42M1+E2 0.10 2 0.0093 7 +123TE2 G KC=0.0081 7$LC=1063E-6 27 123TE L 599.57 151/2+ 123TE G 599.69 160.00266 17 123TE L 687.95 4 3/2+ -123TE E 1.40 126.49 2 -123TE2 E EAV= $CK=0.8466 14$CL=0.1214 10$CM=0.0261 5$CN=0.0059 3$CO=0 0 -123TE G 182.61 6 0.018 5 M1+E2 1 0.168 38 -123TE2 G KC=0.138 24$LC=0.024 10$MC= -123TE G 198.23 0.0035 7 M1+E2 1 0.130 26 -123TE2 G KC=0.107 17$LC=0.018 7$MC= -123TE G 247.96 5 0.0698 23M1+E2 1 0.065 8 -123TE2 G KC=0.054 5$LC=0.0084 21$MC= +123TE E 1.40 126.49 +123TE2 E CK=0.8466 14$CL=0.1214 10$CM=0.0261 5$CN=0.0059 3$CO=0 0 +123TE G 182.61 6 0.018 5M1+E2 1 0.168 38 +123TE2 G KC=0.138 24$LC=0.024 10 +123TE G 198.23 0.0035 7M1+E2 1 0.130 26 +123TE2 G KC=0.107 17$LC=0.018 7 +123TE G 247.96 5 0.0698 23M1+E2 1 0.065 8 +123TE2 G KC=0.054 5$LC=0.0084 21 123TE G 528.96 5 1.28 12 -123TE G 687.95 100.0269 6 +123TE G 687.95 100.0269 6 123TE L 697.52 5 7/2+ -123TE E 0.419 136.98 2 -123TE2 E EAV= $CK=0.8464 14$CL=0.1216 10$CM=0.0262 5$CN=0.0058 3$CO=0 0 -123TE G 192.17 7 0.0199 7 M1+E2 1 0.143 30 -123TE2 G KC=0.118 20$LC=0.020 8$MC= +123TE E 0.419 136.98 +123TE2 E CK=0.8464 14$CL=0.1216 10$CM=0.0262 5$CN=0.0058 3$CO=0 0 +123TE G 192.17 7 0.0199 7M1+E2 1 0.143 30 +123TE2 G KC=0.118 20$LC=0.020 8 123TE G 207.8 0.00112 32M1+E2 1 0.119 20 -123TE2 G KC=0.093 14$LC=0.015 5$MC= -123TE G 257.51 150.0016 2 E2 0.0640 19 -123TE2 G KC=0.0526 16$LC=0.00917 27$MC= +123TE2 G KC=0.093 14$LC=0.015 5 +123TE G 257.51 150.0016 2E2 0.0640 19 +123TE2 G KC=0.0526 16$LC=0.00917 27 123TE G 538.54 5 0.3788 43E2+M3 1 0.038 31 -123TE2 G KC=0.032 26$LC=0.0049 41$MC= +123TE2 G KC=0.032 26$LC=0.0049 41 123TE L 769.26 14 + -123TE E 0.0037 6 8.92 -123TE2 E EAV= $CK=0.8441 14$CL=0.1233 10$CM=0.0266 5$CN=0.0060 3$CO=0 0 -123TE G 329.38 170.0026 6 -123TE G 610.05 230.0011 3 +123TE E 0.0037 68.92 +123TE2 E CK=0.8441 14$CL=0.1233 10$CM=0.0266 5$CN=0.0060 3$CO=0 0 +123TE G 329.38 170.0026 6 +123TE G 610.05 230.0011 3 123TE L 783.60 4 3/2,5/2+ 52 FS 33 -123TE E 0.1461 207.29 2 -123TE2 E EAV= $CK=0.8436 14$CL=0.1237 10$CM=0.0267 5$CN=0.0060 3$CO=0 0 -123TE G 278.36 120.0023 4 M1+E2 1 0.0459 36 -123TE2 G KC=0.0387 22$LC=0.0058 11$MC= -123TE G 343.73 140.0044 3 -123TE G 624.57 5 0.0798 20M1+E2 1.30 35 0.0049 6 -123TE2 G KC=0.0042 5$LC=5.49E-4 40$MC= +123TE E 0.1461 207.29 +123TE2 E CK=0.8436 14$CL=0.1237 10$CM=0.0267 5$CN=0.0060 3$CO=0 0 +123TE G 278.36 120.0023 4M1+E2 1 0.0459 36 +123TE2 G KC=0.0387 22$LC=0.0058 11 +123TE G 343.73 140.0044 3 +123TE G 624.57 5 0.0798 20M1+E2 1.30 35 0.0049 6 +123TE2 G KC=0.0042 5$LC=5.49E-4 40 123TE G 783.59 6 0.0591 11 123TE L 894.74 6 3/2,5/2+ 45 FS 24 -123TE E 0.0744 137.32 2 -123TE2 E EAV= $CK=0.8377 15$CL=0.1283 11$CM=0.0278 5$CN=0.0062 3$CO=0 0 +123TE E 0.0744 137.32 +123TE2 E CK=0.8377 15$CL=0.1283 11$CM=0.0278 5$CN=0.0062 3$CO=0 0 123TE G 197.22 0.00033 17M1+E2 1 0.132 26 -123TE2 G KC=0.109 18$LC=0.018 7$MC= -123TE G 206.79 0.0033 8 M1+E2 1 0.114 21 -123TE2 G KC=0.094 14$LC=0.016 5$MC= -123TE G 295.17 1582E-6 4 +123TE2 G KC=0.109 18$LC=0.018 7 +123TE G 206.79 0.0033 8M1+E2 1 0.114 21 +123TE2 G KC=0.094 14$LC=0.016 5 +123TE G 295.17 0.001582 4 123TE G 405.02 130.00298 23 123TE G 454.76 150.00412 22 -123TE G 735.78 7 0.0616 8 -123TE G 894.8 2 0.00101 7 +123TE G 735.78 7 0.0616 8 +123TE G 894.8 2 0.00101 7 123TE L 996.06 12(5/2)- -123TE E 0.0035 3 8.31 -123TE2 E EAV= $CK=0.8266 16$CL=0.1363 12$CM=0.0300 6$CN=0.0067 4$CO=0 0 -123TE G 556.05 130.0029 3 -123TE G 837.1 2 5.82E-4 8 +123TE E 0.0035 38.31 +123TE2 E CK=0.8266 16$CL=0.1363 12$CM=0.0300 6$CN=0.0067 4$CO=0 0 +123TE G 556.05 130.0029 3 +123TE G 837.1 2 0.000582 8 123TE L 1036.64 123/2,5/2+ 43 FS 16 -123TE E 0.0025 9 8.27 2 -123TE2 E EAV= $CK=0.8182 18$CL=0.1427 13$CM=0.0316 6$CN=0.0071 4$CO=0 0 -123TE G 437.5 3 0.0007 7 -123TE G 877.52 170.00083 7 -123TE G 1036.63 170.00097 7 +123TE E 0.0025 98.27 +123TE2 E CK=0.8182 18$CL=0.1427 13$CM=0.0316 6$CN=0.0071 4$CO=0 0 +123TE G 437.5 3 0.0007 7 +123TE G 877.52 170.00083 7 +123TE G 1036.63 170.00097 7 123TE L 1068.18 8 3/2,5/2+ -123TE E 0.0079 4 7.59 2 -123TE2 E EAV= $CK=0.8082 21$CL=0.1503 15$CM=0.0336 7$CN=0.0075 4$CO=0 0 +123TE E 0.0079 47.59 +123TE2 E CK=0.8082 21$CL=0.1503 15$CM=0.0336 7$CN=0.0075 4$CO=0 0 123TE G 174.2 3 0.00083 25M1+E2 1 0.195 47 -123TE2 G KC=0.159 32$LC=0.029 12$MC= -123TE G 562.79 120.00115 7 -123TE G 578.26 200.00126 8 +123TE2 G KC=0.159 32$LC=0.029 12 +123TE G 562.79 120.00115 7 +123TE G 578.26 200.00126 8 123TE G 628.26 220.00164 14 -123TE G 909.12 120.00141 8 -123TE G 1068.12 150.00142 7 +123TE G 909.12 120.00141 8 +123TE G 1068.12 150.00142 7 diff --git a/HEN_HOUSE/spectra/lnhb/I-125.txt b/HEN_HOUSE/spectra/lnhb/I-125.txt index 258bd8400..776eae791 100644 --- a/HEN_HOUSE/spectra/lnhb/I-125.txt +++ b/HEN_HOUSE/spectra/lnhb/I-125.txt @@ -10,37 +10,37 @@ 125TE3C 1980Ho17, 1979CoZG, 1982HoZJ, 1983De11, 1983Ku**, 1987Sc20, 1989Si19, 125TE4C 1990Wo03, 1990Iw04, 1990De09, 1991Al05, 1992ScZZ, 1995Ra32, 1996Sc06, 125TE5C 1999Ka26, 2002Un02, 2003Au03, 2006Da20, 2008Ki07 -125TE T Auger electrons and ^X ray energies and emission intensities: -125TE T {U Energy (keV)} {U Intensity } {U Line } +125TE T Auger electrons and X ray energies and emission intensities: +125TE T {U Energy (keV)} {U Intensity} {U Line} 125TE T -125TE T 27.202 39.3 5 XKA2 -125TE T 27.4726 73.2 8 XKA1 +125TE T 27.202 39.3 5 XKA2 +125TE T 27.4726 73.2 8 XKA1 125TE T -125TE T 30.9446 |] XKB3 -125TE T 30.996 |] 20.9 3 XKB1 -125TE T 31.236 |] XKB5II +125TE T 30.9446 |] XKB3 +125TE T 30.996 |] 20.9 3 XKB1 +125TE T 31.236 |] XKB5II 125TE T -125TE T 31.7008 |] XKB2 -125TE T 31.774 |] 4.54 13 XKB4 -125TE T 31.812 |] XKO23 +125TE T 31.7008 |] XKB2 +125TE T 31.774 |] 4.54 13 XKB4 +125TE T 31.812 |] XKO23 125TE T -125TE T 3.3348-4.8228 14.70 28 XL (total) -125TE T 3.3348 0.281 9 XLL -125TE T 3.7595-3.7697 7.45 20 XLA -125TE T 3.6052 0.108 4 XLC -125TE T 4.0299-4.3661 6.02 13 XLB -125TE T 4.4448-4.8228 0.844 19 XLG +125TE T 3.3348-4.8228 14.70 28 XL (total) +125TE T 3.3348 0.281 9 XLL +125TE T 3.7595-3.7697 7.45 20 XLA +125TE T 3.6052 0.108 4 XLC +125TE T 4.0299-4.3661 6.02 13 XLB +125TE T 4.4448-4.8228 0.844 19 XLG 125TE T -125TE T 21.804-22.989 |] KLL AUGER -125TE T 25.814-27.47 |] 19.7 7 ^KLX AUGER -125TE T 29.8-31.81 |] KXY AUGER -125TE T 2.3-4.8 158.2 8 L AUGER +125TE T 21.804-22.989 |] KLL AUGER +125TE T 25.814-27.47 |] 19.7 7 KLX AUGER +125TE T 29.8-31.81 |] KXY AUGER +125TE T 2.3-4.8 158.2 8 L AUGER 125I P 0.0 5/2+ 59.388 D 28 185.77 6 125TE N 1.0 1.0 1 1.0 125TE L 0 1/2+ STABLE 125TE L 35.4922 5 3/2+ 1.48 NS -125TE E 100 5.4 2 -125TE2 E EAV= $CK=0.8011 17$CL=0.1561 13$CM=0.0349 7$CN=0.0079 4$CO=0 0 -125TE G 35.4922 5 6.63 6 M1+E2 0.085 6 14.08 22 -125TE2 G KC=11.70 17$LC=1.91 8$MC=0.386 16 +125TE E 100 5.4 +125TE2 E CK=0.8011 17$CL=0.1561 13$CM=0.0349 7$CN=0.0079 4$CO=0 0 +125TE G 35.4922 5 6.63 6M1+E2 0.085 6 14.08 22 +125TE2 G KC=11.70 17$LC=1.91 8$MC=0.386 16 diff --git a/HEN_HOUSE/spectra/lnhb/I-129.txt b/HEN_HOUSE/spectra/lnhb/I-129.txt index fa0cde92c..c8a5792cd 100644 --- a/HEN_HOUSE/spectra/lnhb/I-129.txt +++ b/HEN_HOUSE/spectra/lnhb/I-129.txt @@ -1,34 +1,34 @@ 129XE 129I B- DECAY (16.1E6 Y) -129XE T Auger electrons and ^X ray energies and emission intensities: -129XE T {U Energy (keV)} {U Intensity } {U Line } +129XE T Auger electrons and X ray energies and emission intensities: +129XE T {U Energy (keV)} {U Intensity} {U Line} 129XE T -129XE T 29.459 20.1 3 XKA2 -129XE T 29.779 37.2 6 XKA1 +129XE T 29.459 20.1 3 XKA2 +129XE T 29.779 37.2 6 XKA1 129XE T -129XE T 33.562 |] XKB3 -129XE T 33.625 |] 10.3 4 XKB1 -129XE T 33.881 |] XKB5II +129XE T 33.562 |] XKB3 +129XE T 33.625 |] 10.3 4 XKB1 +129XE T 33.881 |] XKB5II 129XE T -129XE T 34.415 |] XKB2 -129XE T 34.496 |] 2.30 13 XKB4 -129XE T 34.552 |] XKO23 +129XE T 34.415 |] XKB2 +129XE T 34.496 |] 2.30 13 XKB4 +129XE T 34.552 |] XKO23 129XE T -129XE T 3.6-5.4 7.9 4 XL (total) +129XE T 3.6-5.4 7.9 4 XL (total) 129XE T 3.6 XLL 129XE T -5.4 XLG 129XE T -129XE T 23.512-24.842 |] KLL AUGER -129XE T 27.897-29.77 |] 8.8 4 ^KLX AUGER -129XE T 32.27-34.54 |] KXY AUGER -129XE T 2.4-5.4 73.9 12 L AUGER +129XE T 23.512-24.842 |] KLL AUGER +129XE T 27.897-29.77 |] 8.8 4 KLX AUGER +129XE T 32.27-34.54 |] KXY AUGER +129XE T 2.4-5.4 73.9 12 L AUGER 129I P 0.0 7/2+ 16.1E6 Y 7 190.8 11 129XE N 1.0 1.0 1 1.0 129XE L 0 1/2+ STABLE -129XE B 190.8 110.5 5 14.9 +129XE B 190.8 110.5 5 14.9 2U 129XES B EAV= 129XE L 39.578 4 3/2+ 1 NS -129XE B 151.2 1199.5 5 13.49 +129XE B 151.2 1199.5 5 13.49 2 129XES B EAV=37 1 -129XE G 39.578 4 7.42 8 M1+E2 12.41 13 -129XE2 G KC=10.59 11$LC=1.45 5$MC=0.296 10 +129XE G 39.578 4 7.42 8M1+E2 12.41 13 +129XE2 G KC=10.59 11$LC=1.45 5$MC=0.296 10 diff --git a/HEN_HOUSE/spectra/lnhb/I-131.txt b/HEN_HOUSE/spectra/lnhb/I-131.txt index b5793ea5f..450622e34 100644 --- a/HEN_HOUSE/spectra/lnhb/I-131.txt +++ b/HEN_HOUSE/spectra/lnhb/I-131.txt @@ -10,90 +10,90 @@ 131XE5C 1977Kr13, 1978La21, 1979Ir01, 1980Ho17, 1982HoZF, 1983Wa26, 1989Ch45, 131XE6C 1990Me15, 1994Se10, 1996Sc06, 2002Ba85, 2004Da05, 2004Sc04, 2008Ki07, 131XE7C 2012Wa38, 2012Fi12 -131XE T Auger electrons and ^X ray energies and emission intensities: -131XE T {U Energy (keV)} {U Intensity } {U Line } +131XE T Auger electrons and X ray energies and emission intensities: +131XE T {U Energy (keV)} {U Intensity} {U Line} 131XE T -131XE T 29.459 1.52 4 XKA2 -131XE T 29.779 2.81 6 XKA1 +131XE T 29.459 1.52 4 XKA2 +131XE T 29.779 2.81 6 XKA1 131XE T -131XE T 33.562 |] XKB3 -131XE T 33.625 |] 0.816 19 XKB1 -131XE T 33.881 |] XKB5II +131XE T 33.562 |] XKB3 +131XE T 33.625 |] 0.816 19 XKB1 +131XE T 33.881 |] XKB5II 131XE T -131XE T 34.415 |] XKB2 -131XE T 34.496 |] 0.193 6 XKB4 -131XE T 34.552 |] XKO23 +131XE T 34.415 |] XKB2 +131XE T 34.496 |] 0.193 6 XKB4 +131XE T 34.552 |] XKO23 131XE T -131XE T 3.64-5.3 0.631 13 XL (total) -131XE T 3.64 0.0122 4 XLL -131XE T 4.1-4.11 0.321 9 XLA -131XE T 3.96 0.00461 15 XLC -131XE T 4.42-4.78 0.256 6 XLB -131XE T 4.89-5.3 0.0377 9 XLG +131XE T 3.64-5.3 0.631 13 XL (total) +131XE T 3.64 0.0122 4 XLL +131XE T 4.1-4.11 0.321 9 XLA +131XE T 3.96 0.00461 15 XLC +131XE T 4.42-4.78 0.256 6 XLB +131XE T 4.89-5.3 0.0377 9 XLG 131XE T -131XE T 23.512-24.842 |] KLL AUGER -131XE T 27.897-29.77 |] 0.67 4 ^KLX AUGER -131XE T 32.27-34.54 |] KXY AUGER -131XE T 2.5-5.43 5.87 4 L AUGER +131XE T 23.512-24.842 |] KLL AUGER +131XE T 27.897-29.77 |] 0.67 4 KLX AUGER +131XE T 32.27-34.54 |] KXY AUGER +131XE T 2.5-5.43 5.87 4 L AUGER 131I P 0.0 7/2+ 8.0233 D 19 970.8 6 131XE N 1.0 1.0 1 1.0 131XE L 0 3/2+ STABLE 131XE L 80.1854 191/2+ 0.48 NS 3 -131XE G 80.185 2 2.607 35M1 1.544 46 -131XE2 G KC=1.32 4$LC=0.175 5$MC=0.036 1 +131XE G 80.1850 202.607 35M1 1.544 46 +131XE2 G KC=1.32 4$LC=0.175 5$MC=0.036 1 131XE L 163.930 8 11/2- 11.962 D 20 -131XE B 806.9 6 0.386 23 10.03 3U +131XE B 806.9 6 0.386 23 10.03 1U 131XES B EAV=267.91 23 -131XE G 163.930 8 0.0211 3 M4 50.5 7 -131XE2 G KC=31.6 5$LC=14.75 21$MC=3.38 5 +131XE G 163.930 8 0.0211 3M4 50.5 7 +131XE2 G KC=31.6 5$LC=14.75 21$MC=3.38 5 131XE L 341.144 9 9/2- 1.6 NS 4 -131XE B 629.7 6 0.060 12 9.8 1U +131XE B 629.7 6 0.060 12 9.8 1 131XES B EAV=200.23 22 -131XE G 177.214 200.277 7 M1+()E2 -4.3 4 0.241 7 -131XE2 G KC=0.187 6$LC=0.0427 13$MC=0.00901 27 +131XE G 177.214 200.277 7M1+()E2 -4.3 4 0.241 7 +131XE2 G KC=0.187 6$LC=0.0427 13$MC=0.00901 27 131XE L 364.490 4 5/2+ 69 PS 2 -131XE B 606.3 6 89.4 8 6.64 2 +131XE B 606.3 6 89.4 8 6.64 131XES B EAV=191.59 22 -131XE G 284.305 5 6.14 6 E2 0.0497 7 -131XE2 G KC=0.0408 6$LC=0.00714 10$MC=1479E-6 21 -131XE G 364.489 5 81.2 5 M1+()E2 -4.53 11 0.0228 4 -131XE2 G KC=0.0190 3$LC=0.00300 5$MC=6.16E-4 9 +131XE G 284.305 5 6.14 6E2 0.0497 7 +131XE2 G KC=0.0408 6$LC=0.00714 10$MC=1479E-6 21 +131XE G 364.489 5 81.2 5M1+()E2 -4.53 11 0.0228 4 +131XE2 G KC=0.0190 3$LC=0.00300 5$MC=6.16E-4 9 131XE L 404.815 4 3/2+ 18 PS 3 -131XE G 324.651 250.0244 25M1+E2 0.0329 6 -131XE2 G KC=0.0278 10$LC=0.0041 4$MC=0.00083 9 +131XE G 324.651 250.0244 25M1+E2 0.0329 6 +131XE2 G KC=0.0278 10$LC=0.0041 4$MC=0.00083 9 131XE G 404.814 4 0.0552 17M1+E2 1.0 9 0.0177 12 -131XE2 G KC=0.0151 13$LC=0.00210 4$MC=4.29E-4 11 +131XE2 G KC=0.0151 13$LC=0.00210 4$MC=4.29E-4 11 131XE L 636.990 4 7/2+ 6.1 PS 5 -131XE B 333.8 6 7.20 7 6.86 +131XE B 333.8 6 7.20 7 6.86 131XES B EAV=96.61 19 -131XE G 232.18 150.0023 9 [E2] 0.097 2 -131XE2 G KC=0.0782 22$LC=0.0151 5$MC=0.0031 1 -131XE G 272.498 170.0581 15M1+()E2 -0.38 17 0.0530 9 -131XE2 G KC=0.0453 7$LC=0.0061 3$MC=0.00125 6 -131XE G 295.8 2 0.0012 6 [E1] 0.0108 3 -131XE2 G KC=0.0093 2$LC=0.00117 3$MC=0.00024 4 -131XE G 636.989 4 7.12 7 E2 0.004707 -131XE2 G KC=0.00401 6$LC=5.51E-4 8$MC=1123E-7 16 +131XE G 232.18 150.0023 9[E2] 0.097 2 +131XE2 G KC=0.0782 22$LC=0.0151 5$MC=0.0031 1 +131XE G 272.498 170.0581 15M1+()E2 -0.38 17 0.0530 9 +131XE2 G KC=0.0453 7$LC=0.0061 3$MC=0.00125 6 +131XE G 295.80 200.0012 6[E1] 0.0108 3 +131XE2 G KC=0.0093 2$LC=0.00117 3$MC=0.00024 4 +131XE G 636.989 4 7.12 7E2 0.00470 7 +131XE2 G KC=0.00401 6$LC=5.51E-4 8$MC=1123E-7 16 131XE L 666.934 9 7/2- 0.5 NS 131XE B 303.9 6 0.643 27 7.79 131XES B EAV=86.94 19 -131XE G 302.4 2 0.0046 7 [E1] 0.0102 2 -131XE2 G KC=0.0088 2$LC=0.00111 1$MC=0.00022 1 -131XE G 325.789 4 0.274 8 M1+()E2 -0.8 7 0.0335 10 -131XE2 G KC=0.0288 9$LC=0.00376 11$MC=7.65E-4 23 -131XE G 503.004 4 0.3540 46E2 0.0088313 -131XE2 G KC=0.00748 11$LC=1083E-6 16$MC=2.21E-4 3 -131XE L 722.909 4 5/2++ 0.53 PS 5 -131XE B 247.9 6 2.130 21 6.98 2 +131XE G 302.40 200.0046 7[E1] 0.0102 2 +131XE2 G KC=0.0088 2$LC=0.00111 1$MC=0.00022 1 +131XE G 325.7890 400.274 8M1+()E2 -0.8 7 0.0335 10 +131XE2 G KC=0.0288 9$LC=0.00376 11$MC=7.65E-4 23 +131XE G 503.0040 400.3540 46E2 0.0088313 +131XE2 G KC=0.00748 11$LC=1083E-6 16$MC=2.21E-4 3 +131XE L 722.909 4 5/2+ 0.53 PS 5 +131XE B 247.9 6 2.130 21 6.98 131XES B EAV=69.35 19 -131XE G 85.9 2 0.0051 7 [M1E2] 2.2 1 -131XE2 G KC=1.50 6$LC=0.56 2$MC= -131XE G 318.088 160.0807 20M1+()E2 -0.11 8 0.0350 5 -131XE2 G KC=0.0301 5$LC=0.00388 6$MC=7.86E-4 12 -131XE G 358.4 2 0.017 8 [M1E2] 0.0248 10 -131XE2 G KC=0.0210 12$LC=0.00301 18$MC=0.00061 5 -131XE G 642.719 5 0.2183 26[E2] 0.0046 1 -131XE2 G KC=0.0039 1$LC=0.00054 1$MC=0.00011 2 -131XE G 722.911 5 1.786 19M1+()E2 0.207 5 0.004517 -131XE2 G KC=0.00390 6$LC=4.88E-4 7$MC=9.87E-5 14 +131XE G 85.9 2 0.0051 7[M1E2] 2.2 1 +131XE2 G KC=1.50 6$LC=0.56 2 +131XE G 318.088 160.0807 20M1+()E2 -0.11 8 0.0350 5 +131XE2 G KC=0.0301 5$LC=0.00388 6$MC=7.86E-4 12 +131XE G 358.4 2 0.017 8[M1E2] 0.0248 10 +131XE2 G KC=0.0210 12$LC=0.00301 18$MC=0.00061 5 +131XE G 642.719 5 0.2183 26[E2] 0.0046 1 +131XE2 G KC=0.0039 1$LC=0.00054 1$MC=0.00011 2 +131XE G 722.911 5 1.786 19M1+()E2 0.207 5 0.00451 7 +131XE2 G KC=0.00390 6$LC=4.88E-4 7$MC=9.87E-5 14 diff --git a/HEN_HOUSE/spectra/lnhb/I-133.txt b/HEN_HOUSE/spectra/lnhb/I-133.txt index c87d46df4..f6237b12b 100644 --- a/HEN_HOUSE/spectra/lnhb/I-133.txt +++ b/HEN_HOUSE/spectra/lnhb/I-133.txt @@ -5,131 +5,131 @@ 133XE2C 1968RE04, 1971SA09, 1972KR07, 1972AC02, 1972BE90, 1974KO26, 1976FU06, 133XE3C 1976ME16, 1977KR13, 1983LO08, 1989RA17, 1995RA12, 1996SC06, 2002BA85, 133XE4C 2003AU03 -133XE T Auger electrons and ^X ray energies and emission intensities: -133XE T {U Energy (keV)} {U Intensity } {U Line } +133XE T Auger electrons and X ray energies and emission intensities: +133XE T {U Energy (keV)} {U Intensity} {U Line} 133XE T -133XE T 29.459 0.163 4 XKA2 -133XE T 29.779 0.303 6 XKA1 +133XE T 29.459 0.163 4 XKA2 +133XE T 29.779 0.303 6 XKA1 133XE T -133XE T 33.562 |] XKB3 -133XE T 33.625 |] 0.0877 19 XKB1 -133XE T 33.881 |] XKB5II +133XE T 33.562 |] XKB3 +133XE T 33.625 |] 0.0877 19 XKB1 +133XE T 33.881 |] XKB5II 133XE T -133XE T 34.415 |] XKB2 -133XE T 34.496 |] 0.0207 7 XKB4 -133XE T 34.552 |] XKO23 +133XE T 34.415 |] XKB2 +133XE T 34.496 |] 0.0207 7 XKB4 +133XE T 34.552 |] XKO23 133XE T -133XE T 3.6378-5.296 0.0724 14 XL (total) -133XE T 3.6378 0.00149 5 XLL -133XE T 4.0977-4.1103 0.039 1 XLA -133XE T 3.9576 0.000483 15 XLC -133XE T 4.4176-4.7758 0.0275 6 XLB -133XE T 4.895-5.296 0.003890 9 XLG +133XE T 3.6378-5.296 0.0724 14 XL (total) +133XE T 3.6378 0.00149 5 XLL +133XE T 4.0977-4.1103 0.039 1 XLA +133XE T 3.9576 0.00048315 XLC +133XE T 4.4176-4.7758 0.0275 6 XLB +133XE T 4.895-5.296 0.003890 9 XLG 133XE T -133XE T 23.512-24.842 |] KLL AUGER -133XE T 27.897-29.77 |] 0.072 4 ^KLX AUGER -133XE T 32.27-34.54 |] KXY AUGER -133XE T 2.4-5.2 0.677 4 L AUGER +133XE T 23.512-24.842 |] KLL AUGER +133XE T 27.897-29.77 |] 0.072 4 KLX AUGER +133XE T 32.27-34.54 |] KXY AUGER +133XE T 2.4-5.2 0.677 4 L AUGER 133I P 0.0 7/2+ 20.87 H 8 1757 4 133XE N 1.0 1.0 1 1.0 133XE G 167.97 6 0.078 17 -133XE G 567.1 4 0.003 3 +133XE G 567.1 4 0.003 3 133XE G 1018.1 5 0.0060 26 133XE L 0 0 3/2+ 5.2474 D 5 133XE L 233.219 1511/2- 2.198 D 13 -133XE B 1524 4 1.07 6 9.92 3U +133XE B 1524 4 1.07 6 9.92 1U 133XES B EAV=572.0 17 -133XE G 233.219 150.293 4 M4 8.84 12 -133XE2 G KC=6.24 9$LC=2.035 29$MC=0.453 6 +133XE G 233.219 150.293 4M4 8.84 12 +133XE2 G KC=6.24 9$LC=2.035 29$MC=0.453 6 133XE L 262.702 601/2+ -133XE G 262.70 6 0.356 12M1+E2 0.0577 8 -133XE2 G KC=0.0497 7$LC=0.00641 9$MC=1300E-6 18 +133XE G 262.70 6 0.356 12M1+E2 0.0577 8 +133XE2 G KC=0.0497 7$LC=0.00641 9$MC=1300E-6 18 133XE L 529.872 3 5/2+ -133XE B 1227 4 83.42 21 6.81 2 +133XE B 1227 4 83.42 21 6.81 133XES B EAV=439.4 17 -133XE G 267.17 6 0.117 7 -133XE G 529.8709 3086.3 2 M1+E2 1.85 20 0.0081014 +133XE G 267.17 6 0.117 7 +133XE G 529.8709 3086.3 2M1+E2 1.85 20 0.0081014 133XE2 G KC=0.00691 13$LC=9.56E-4 14$MC=1948E-7 29 133XE L 680.254 9 3/2+ -133XE G 150.382 9 0.029 6 +133XE G 150.382 9 0.029 6 133XE G 417.55 6 0.153 10M1+E2 1.0 13 0.0163 11 -133XE2 G KC=0.0139 10$LC=1921E-6 27$MC=3.92E-4 6 -133XE G 680.252 9 0.645 19M1 0.005277 -133XE2 G KC=$LC=5.70E-4 8$MC=1152E-7 16 +133XE2 G KC=0.0139 10$LC=1921E-6 27$MC=3.92E-4 6 +133XE G 680.252 9 0.645 19M1 0.00527 7 +133XE2 G KC=$LC=5.70E-4 8$MC=1152E-7 16 133XE L 743.750 16(7/2,9/2,11/2)- -133XE B 1013 4 1.81 6 8.17 +133XE B 1013 4 1.81 6 8.17 133XES B EAV=350.5 17 -133XE G 510.530 221.81 6 +133XE G 510.530 221.81 6 133XE L 875.331 5 (7/2)+ 133XE B 882 4 4.16 13 7.59 133XES B EAV=297.4 16 133XE G 345.459 6 0.104 18 -133XE G 875.328 5 4.47 12E2+M3 0.002183 -133XE2 G KC=1876E-6 26$LC=2.45E-4 3$MC=4.96E-5 7 +133XE G 875.328 5 4.47 12E2+M3 0.00218 3 +133XE2 G KC=1876E-6 26$LC=2.45E-4 3$MC=4.96E-5 7 133XE L 911.45 3 (1/2,3/2)+ -133XE B 846 4 0.026 18 9.7 +133XE B 846 4 0.026 18 9.7 2U 133XES B EAV=283.1 16 -133XE G 381.578 300.045 5 -133XE G 648.75 7 0.056 13M1 0.005908 -133XE2 G KC=0.00510 7$LC=6.39E-4 9$MC=1292E-7 18 -133XE G 911.447 300.046 6 +133XE G 381.578 300.045 5 +133XE G 648.75 7 0.056 13M1 0.00590 8 +133XE2 G KC=0.00510 7$LC=6.39E-4 9$MC=1292E-7 18 +133XE G 911.447 300.046 6 133XE L 1052.397 175/2+ -133XE B 706 4 0.58 5 8.09 2 +133XE B 706 4 0.58 5 8.09 133XES B EAV=228.4 16 -133XE G 372.143 190.009 6 -133XE G 522.524 170.04 5 -133XE G 789.69 6 0.050 4 +133XE G 372.143 190.009 6 +133XE G 522.524 170.04 5 +133XE G 789.69 6 0.050 4 133XE G 1052.393 170.551 16 133XE L 1236.449 5 (7/2)+ -133XE B 521 4 3.12 6 6.91 +133XE B 521 4 3.12 6 6.91 133XES B EAV=160.4 15 -133XE G 361.118 7 0.11 4 -133XE G 556.194 100.020 3 -133XE G 706.575 6 1.49 4 M1+E2 0.0042 6 -133XE2 G KC=0.0036 6$LC=0.00047 5$MC=9.5E-5 10 -133XE G 1236.443 5 1.49 4 +133XE G 361.118 7 0.11 4 +133XE G 556.194 100.020 3 +133XE G 706.575 6 1.49 4M1+E2 0.0042 6 +133XE2 G KC=0.0036 6$LC=0.00047 5$MC=9.5E-5 10 +133XE G 1236.443 5 1.49 4 133XE L 1298.234 5 5/2+ -133XE B 459 4 3.75 7 6.64 2 +133XE B 459 4 3.75 7 6.64 133XES B EAV=138.7 14 -133XE G 245.837 180.035 9 -133XE G 386.784 300.059 5 +133XE G 245.837 180.035 9 +133XE G 386.784 300.059 5 133XE G 422.903 7 0.309 10M1+E2 1.8 12 0.0151 13 -133XE2 G KC=0.0128 13$LC=0.00185 3$MC=3.79E-4 6 -133XE G 554.483 170.0004 5 -133XE G 617.978 100.539 15M1+E2 0.0059 8 -133XE2 G KC=0.0050 7$LC=0.00066 6$MC=1.34E-4 12 +133XE2 G KC=0.0128 13$LC=0.00185 3$MC=3.79E-4 6 +133XE G 554.483 170.0004 5 +133XE G 617.978 100.539 15M1+E2 0.0059 8 +133XE2 G KC=0.0050 7$LC=0.00066 6$MC=1.34E-4 12 133XE G 768.360 6 0.457 15M1+E2 0.6 4 0.0036824 -133XE2 G KC=0.00318 22$LC=4.02E-4 22$MC=8.1E-5 4 +133XE2 G KC=0.00318 22$LC=4.02E-4 22$MC=8.1E-5 4 133XE G 1035.53 6 0.0086 18 -133XE G 1298.227 5 2.33 7 M1+E2 4.2 3 9.72E-414 +133XE G 1298.227 5 2.33 7M1+E2 4.2 3 9.72E-414 133XE2 G KC=8.22E-4 12$LC=1026E-7 15$MC=2070E-8 29 133XE L 1350.380 175/2+ -133XE B 407 4 0.397 12 7.44 2 +133XE B 407 4 0.397 12 7.44 133XES B EAV=120.8 14 -133XE G 438.930 340.040 5 -133XE G 670.124 190.042 6 -133XE G 820.505 170.154 6 M1+E2 0.8 8 0.0031 4 -133XE2 G KC=0.0026 3$LC=0.00033 3$MC=6.8E-5 6 +133XE G 438.930 340.040 5 +133XE G 670.124 190.042 6 +133XE G 820.505 170.154 6M1+E2 0.8 8 0.0031 4 +133XE2 G KC=0.0026 3$LC=0.00033 3$MC=6.8E-5 6 133XE G 1087.67 6 0.0121 18 -133XE G 1350.373 170.148 5 M1+E2 0.0010112 +133XE G 1350.373 170.148 5M1+E2 0.0010112 133XE2 G KC=0.00085 10$LC=1.04E-4 12$MC=2.11E-5 23 133XE L 1386.153 8 7/2+ -133XE B 371 4 1.25 4 6.81 +133XE B 371 4 1.25 4 6.81 133XES B EAV=108.8 14 -133XE G 510.821 9 0.004 5 -133XE G 856.278 9 1.23 4 M1+E2 3.7 3 0.002353 -133XE2 G KC=0.00202 3$LC=2.63E-4 4$MC=5.33E-5 8 +133XE G 510.821 9 0.004 5 +133XE G 856.278 9 1.23 4M1+E2 3.7 3 0.00235 3 +133XE2 G KC=0.00202 3$LC=2.63E-4 4$MC=5.33E-5 8 133XE G 1386.145 8 0.0086 26[E2] 133XE L 1589.94 3 5/2+ -133XE B 167 4 0.414 15 6.18 2 +133XE B 167 4 0.414 15 6.18 133XES B EAV=45.1 12 -133XE G 203.787 310.00432 8 -133XE G 537.542 340.035 7 -133XE G 678.488 420.022 7 -133XE G 909.683 310.212 9 M1+E2 0.40 6 0.002574 -133XE2 G KC=0.00222 4$LC=2.77E-4 5$MC=5.59E-5 9 -133XE G 1060.063 0.137 7 M1+E2 0.0016523 -133XE2 G KC=0.00143 20$LC=1.79E-4 22$MC=3.6E-5 4 +133XE G 203.787 310.00432 8 +133XE G 537.542 340.035 7 +133XE G 678.488 420.022 7 +133XE G 909.683 310.212 9M1+E2 0.40 6 0.00257 4 +133XE2 G KC=0.00222 4$LC=2.77E-4 5$MC=5.59E-5 9 +133XE G 1060.063 0.137 7M1+E2 0.0016523 +133XE2 G KC=0.00143 20$LC=1.79E-4 22$MC=3.6E-5 4 133XE G 1327.23 7 0.00022 22 -133XE G 1589.93 3 0.0029 4 +133XE G 1589.93 3 0.0029 4 diff --git a/HEN_HOUSE/spectra/lnhb/In-111.txt b/HEN_HOUSE/spectra/lnhb/In-111.txt index e89bdf3cc..e45e59b20 100644 --- a/HEN_HOUSE/spectra/lnhb/In-111.txt +++ b/HEN_HOUSE/spectra/lnhb/In-111.txt @@ -9,44 +9,44 @@ 111CD4C 1978La21, 1980Ho17, 1982HoZY, 1983Wa26, 1985Ka29, 1986Ru09, 1987Ne01, 111CD5C 1992Un01, 1994Ka08, 1996Sc06, 1997We17, 1998Si17, 2003Bl10, 2003Au03, 111CD6C 2004Sc04, 2005Ya03, 2006Ra03 -111CD T Auger electrons and ^X ray energies and emission intensities: -111CD T {U Energy (keV)} {U Intensity } {U Line } +111CD T Auger electrons and X ray energies and emission intensities: +111CD T {U Energy (keV)} {U Intensity} {U Line} 111CD T -111CD T 22.9843 23.65 18 XKA2 -111CD T 23.1738 44.47 26 XKA1 +111CD T 22.9843 23.65 18 XKA2 +111CD T 23.1738 44.47 26 XKA1 111CD T -111CD T 26.0615 |] XKB3 -111CD T 26.0958 |] 12.40 14 XKB1 -111CD T 26.304 |] XKB5II +111CD T 26.0615 |] XKB3 +111CD T 26.0958 |] 12.40 14 XKB1 +111CD T 26.304 |] XKB5II 111CD T -111CD T 26.644 |] XKB2 -111CD T 26.7106 |] 2.26 7 XKB4 +111CD T 26.644 |] XKB2 +111CD T 26.7106 |] 2.26 7 XKB4 111CD T -111CD T 2.77-3.95 6.78 14 XL (total) -111CD T 2.77 0.147 6 XLL -111CD T 3.127-3.134 3.95 13 XLA -111CD T 2.957 0.0504 12 XLC -111CD T 3.316-3.528 2.39 5 XLB -111CD T 3.718-3.95 0.247 5 XLG +111CD T 2.77-3.95 6.78 14 XL (total) +111CD T 2.77 0.147 6 XLL +111CD T 3.127-3.134 3.95 13 XLA +111CD T 2.957 0.0504 12 XLC +111CD T 3.316-3.528 2.39 5 XLB +111CD T 3.718-3.95 0.247 5 XLG 111CD T -111CD T 18.675-19.636 |] KLL AUGER -111CD T 21.923-23.172 |] 15.5 4 ^KLX AUGER -111CD T 25.171-26.028 |] KXY AUGER -111CD T 3.404-3.804 100.5 8 L AUGER +111CD T 18.675-19.636 |] KLL AUGER +111CD T 21.923-23.172 |] 15.5 4 KLX AUGER +111CD T 25.171-26.028 |] KXY AUGER +111CD T 3.404-3.804 100.5 8 L AUGER 111IN P 0.0 9/2+ 2.8049 D 4 861.8 46 111CD N 1.0 1.0 1 1.0 111CD L 0 1/2+ STABLE 111CD L 245.4 5/2+ -111CD G 245.35 4 94.12 6 E2 0.0625 7 -111CD2 G KC=0.0524 10$LC=0.00818 16$MC=0.00159 3 +111CD G 245.35 4 94.12 6E2 0.0625 7 +111CD2 G KC=0.0524 10$LC=0.00818 16$MC=0.00159 3 111CD L 396.15 11/2- 48.50 M 9 -111CD E 0.005 5 9 1U -111CD2 E EAV= $CK=0.8524 2$CL=0.1179 2$CM=0.02975 4$CN= $CO= -111CD G 150.81 3 0.0015 15E3 2.28 5 -111CD2 G KC=1.45 3$LC=0.673 14$MC=0.137 3 +111CD E 0.005 59 1 +111CD2 E CK=0.8524 2$CL=0.1179 2$CM=0.02975 4 +111CD G 150.81 3 0.0015 15E3 2.28 5 +111CD2 G KC=1.45 3$LC=0.673 14$MC=0.137 3 111CD L 416.6 7/2+ -111CD E 99.995 5 5 2 -111CD2 E EAV= $CK=0.8518 2$CL=0.11835 13$CM=0.02989 4$CN= $CO= +111CD E 99.995 55 +111CD2 E CK=0.8518 2$CL=0.11835 13$CM=0.02989 4 111CD G 171.28 3 90.61 20M1+E2 0.1036 24 -111CD2 G KC=0.0897 22$LC=0.0113 3$MC=0.00217 5 +111CD2 G KC=0.0897 22$LC=0.0113 3$MC=0.00217 5 diff --git a/HEN_HOUSE/spectra/lnhb/Ir-192.txt b/HEN_HOUSE/spectra/lnhb/Ir-192.txt index 550120300..adedd014c 100644 --- a/HEN_HOUSE/spectra/lnhb/Ir-192.txt +++ b/HEN_HOUSE/spectra/lnhb/Ir-192.txt @@ -1,28 +1,28 @@ 192OS 192IR EC DECAY (73.827 D) 192OS H TYP=Full$AUT=E. Browne$CUT= -- $ 192OS C Evaluation history: Type=Full;Author=E. Browne;Cutoff date= -- -192OS T Auger electrons and ^X ray energies and emission intensities: -192OS T {U Energy (keV)} {U Intensity } {U Line } +192OS T Auger electrons and X ray energies and emission intensities: +192OS T {U Energy (keV)} {U Intensity} {U Line} 192OS T -192OS T 61.4873 1.211 25 XKA2 -192OS T 63.0011 2.09 5 XKA1 +192OS T 61.4873 1.211 25 XKA2 +192OS T 63.0011 2.09 5 XKA1 192OS T -192OS T 71.078 |] XKB3 -192OS T 71.414 |] 0.710 21 XKB1 -192OS T 71.855 |] XKB5II +192OS T 71.078 |] XKB3 +192OS T 71.414 |] 0.710 21 XKB1 +192OS T 71.855 |] XKB5II 192OS T -192OS T 73.319 |] XKB2 -192OS T 73.615 |] 0.180 6 XKB4 -192OS T 73.819 |] XKO23 +192OS T 73.319 |] XKB2 +192OS T 73.615 |] 0.180 6 XKB4 +192OS T 73.819 |] XKO23 192OS T -192OS T 7.822-12.92 1.525 25 XL (total) +192OS T 7.822-12.92 1.525 25 XL (total) 192OS T 7.822 XLL 192OS T 8.9- XLA 192OS T -12.92 XLG 192OS T -192OS T 47.71-51.892 |] KLL AUGER -192OS T 57.759-62.955 |] 0.196 19 ^KLX AUGER -192OS T 67.77-73.78 |] KXY AUGER +192OS T 47.71-51.892 |] KLL AUGER +192OS T 57.759-62.955 |] 0.196 19 KLX AUGER +192OS T 67.77-73.78 |] KXY AUGER 192OS T 4.8-12.86 L AUGER 192IR P 0.0 4+ 73.827 D 13 1046.2 23 192OS N 2.053E1 2.053E1 0.0487 2.053E1 @@ -32,59 +32,59 @@ 192OS G 739 192OS L 0 0+ STABLE 192OS L 205.79430 9 2+ 0.277 NS 4 -192OS G 205.79430 9 3.34 4 E2 0.305 9 -192OS2 G KC=0.157 5$LC=0.111 3$MC=0.0281 8 +192OS G 205.79430 9 3.34 4E2 0.305 9 +192OS2 G KC=0.157 5$LC=0.111 3$MC=0.0281 8 192OS L 489.0602 6 2+ 0.0321 NS 10 -192OS G 283.2668 8 0.266 3 E2+M1 0.123 4 -192OS2 G KC=0.081 4$LC=0.0318 8$MC=0.00785 20 -192OS G 489.06 3 0.438 14E2 0.0243 7 -192OS2 G KC=0.0182 5$LC=0.00471 14$MC=0.00114 3 +192OS G 283.2668 8 0.266 3E2+M1 0.123 4 +192OS2 G KC=0.081 4$LC=0.0318 8$MC=0.00785 20 +192OS G 489.06 3 0.438 14E2 0.0243 7 +192OS2 G KC=0.0182 5$LC=0.00471 14$MC=0.00114 3 192OS L 580.2798 8 4+ 0.0147 NS 4 -192OS E 0.686 9 9.5 -192OS2 E EAV= $CK=0.777 2$CL=0.168 2$CM=0.055 1$CN= $CO= -192OS G 374.4852 8 0.726 6 E2 0.0490 15 -192OS2 G KC=0.0341 10$LC=0.0113 3$MC=0.00276 8 +192OS E 0.686 99.5 +192OS2 E CK=0.777 2$CL=0.168 2$CM=0.055 1 +192OS G 374.4852 8 0.726 6E2 0.0490 15 +192OS2 G KC=0.0341 10$LC=0.0113 3$MC=0.00276 8 192OS L 690.3705 4 3+ -192OS E 3.97 3 8.5 -192OS2 E EAV= $CK=0.758 2$CL=0.182 2$CM=0.060 1$CN= $CO= +192OS E 3.97 38.5 +192OS2 E CK=0.758 2$CL=0.182 2$CM=0.060 1 192OS G 110.4 3 0.0122 11E2+M1 3.65 11 -192OS2 G KC=2.03 6$LC=1.22 4$MC=0.306 9 -192OS G 201.3112 7 0.473 8 E2+M1 0.387 10 -192OS2 G KC=0.228 11$LC=0.120 3$MC=0.0301 8 -192OS G 484.5751 4 3.189 24E2+M1 0.0263 8 -192OS2 G KC=0.0198 6$LC=0.00499 14$MC=0.00120 4 +192OS2 G KC=2.03 6$LC=1.22 4$MC=0.306 9 +192OS G 201.3112 7 0.473 8E2+M1 0.387 10 +192OS2 G KC=0.228 11$LC=0.120 3$MC=0.0301 8 +192OS G 484.5751 4 3.189 24E2+M1 0.0263 8 +192OS2 G KC=0.0198 6$LC=0.00499 14$MC=0.00120 4 192OS L 909.58 6 4+ 0.010 NS 5 -192OS E 0.095 4 9.5 -192OS2 E EAV= $CK=0.537 9$CL=0.339 14$CM=0.124 5$CN= $CO= -192OS G 329.17 150.0174 17E2+M1 0.094 7 -192OS2 G KC=0.069 7$LC=0.0195 10$MC=0.00472 24 -192OS G 420.52 6 0.069 7 [E2] 0.0358 11 -192OS2 G KC=0.0258 8$LC=0.00762 23$MC=0.00186 6 +192OS E 0.095 49.5 +192OS2 E CK=0.537 9$CL=0.339 14$CM=0.124 5 +192OS G 329.17 150.0174 17E2+M1 0.094 7 +192OS2 G KC=0.069 7$LC=0.0195 10$MC=0.00472 24 +192OS G 420.52 6 0.069 7[E2] 0.0358 11 +192OS2 G KC=0.0258 8$LC=0.00762 23$MC=0.00186 6 192PT 192IR B- DECAY (73.827 D) 192PT H TYP=Full$AUT=E. Browne$CUT= -- $ 192PT C Evaluation history: Type=Full;Author=E. Browne;Cutoff date= -- -192PT T Auger electrons and ^X ray energies and emission intensities: -192PT T {U Energy (keV)} {U Intensity } {U Line } +192PT T Auger electrons and X ray energies and emission intensities: +192PT T {U Energy (keV)} {U Intensity} {U Line} 192PT T -192PT T 65.123 2.66 5 XKA2 -192PT T 66.833 4.55 8 XKA1 +192PT T 65.123 2.66 5 XKA2 +192PT T 66.833 4.55 8 XKA1 192PT T -192PT T 75.369 |] XKB3 -192PT T 75.749 |] 1.58 3 XKB1 -192PT T 76.234 |] XKB5II +192PT T 75.369 |] XKB3 +192PT T 75.749 |] 1.58 3 XKB1 +192PT T 76.234 |] XKB5II 192PT T -192PT T 77.786 |] XKB2 -192PT T 78.07 |] 0.411 10 XKB4 -192PT T 78.337 |] XKO23 +192PT T 77.786 |] XKB2 +192PT T 78.07 |] 0.411 10 XKB4 +192PT T 78.337 |] XKO23 192PT T -192PT T 9.4-13.8 3.96 6 XL (total) +192PT T 9.4-13.8 3.96 6 XL (total) 192PT T 9.4- XLA 192PT T -13.8 XLG 192PT T -192PT T 50.399-55.021 |] KLL AUGER -192PT T 61.116-66.829 |] 0.39 4 ^KLX AUGER -192PT T 71.8-78.39 |] KXY AUGER +192PT T 50.399-55.021 |] KLL AUGER +192PT T 61.116-66.829 |] 0.39 4 KLX AUGER +192PT T 71.8-78.39 |] KXY AUGER 192PT T 4.9-13.9 L AUGER 192IR P 0.0 4+ 73.827 D 13 1459.7 19 192PT N 1.051E0 1.051E0 0.9513 1.051E0 @@ -95,58 +95,58 @@ 192PT L 0 0+ STABLE 192PT L 316.0641 212+ 0.0437 NS 12 192PT G 316.50618 1782.75 21E2 0.0849 25 -192PT2 G KC=0.0537 16$LC=0.0236 7$MC=0.00591 17 +192PT2 G KC=0.0537 16$LC=0.0236 7$MC=0.00591 17 192PT L 612.46283 212+ 0.0265 NS 15 -192PT G 295.95650 1528.72 14E2+M1 0.106 3 -192PT2 G KC=0.0654 20$LC=0.0305 9$MC=0.00767 23 -192PT G 612.4621 3 5.34 8 E2 0.0155 5 -192PT2 G KC=0.0119 4$LC=0.00278 8$MC=6.69E-4 20 +192PT G 295.95650 1528.72 14E2+M1 0.106 3 +192PT2 G KC=0.0654 20$LC=0.0305 9$MC=0.00767 23 +192PT G 612.4621 3 5.34 8E2 0.0155 5 +192PT2 G KC=0.0119 4$LC=0.00278 8$MC=6.69E-4 20 192PT L 784.5757 3 4+ 0.0042 NS 2 -192PT B 675.1 1947.9 3 8.5 +192PT B 675.1 1947.9 3 8.5 192PTS B EAV=209.9 7 -192PT G 468.0688 3 47.81 24E2 0.0295 9 -192PT2 G KC=0.0213 6$LC=0.00617 19$MC=0.00151 5 +192PT G 468.0688 3 47.81 24E2 0.0295 9 +192PT2 G KC=0.0213 6$LC=0.00617 19$MC=0.00151 5 192PT L 920.91815 243+ 0.0213 NS 21 -192PT B 538.8 1941.4 3 8.3 +192PT B 538.8 1941.4 3 8.3 192PTS B EAV=162.1 7 -192PT G 136.3426 3 0.199 25E2+M1 1.56 6 -192PT2 G KC=0.57 8$LC=0.747 22$MC=0.192 6 -192PT G 308.45507 1729.68 15E2+M1 0.096 3 -192PT2 G KC=0.0608 18$LC=0.0262 8$MC=0.00657 20 -192PT G 604.41105 258.20 4 E2+M1 0.0266 8 -192PT2 G KC=0.0213 6$LC=0.00403 12$MC=0.00095 3 +192PT G 136.3426 3 0.199 25E2+M1 1.56 6 +192PT2 G KC=0.57 8$LC=0.747 22$MC=0.192 6 +192PT G 308.45507 1729.68 15E2+M1 0.096 3 +192PT2 G KC=0.0608 18$LC=0.0262 8$MC=0.00657 20 +192PT G 604.41105 258.20 4E2+M1 0.0266 8 +192PT2 G KC=0.0213 6$LC=0.00403 12$MC=0.00095 3 192PT L 1201.0450 5 4+ -192PT B 258.7 195.59 3 8.1 +192PT B 258.7 195.59 3 8.1 192PTS B EAV=71.6 6 -192PT G 280.27 240.009 5 E2+M1 0.16 7 -192PT2 G KC=0.11 7$LC=0.039 11$MC=0.0098 25 -192PT G 416.4688 7 0.669 21E2+M1 0.050 4 -192PT2 G KC=0.037 4$LC=0.0099 6$MC=0.00242 13 -192PT G 588.5810 7 4.517 22E2 0.0170 5 -192PT2 G KC=0.0129 4$LC=0.00311 9$MC=7.51E-4 23 -192PT G 884.5365 7 0.291 7 E2 0.0070721 -192PT2 G KC=0.00566 17$LC=0.00108 3$MC=2.54E-4 8 +192PT G 280.27 240.009 5E2+M1 0.16 7 +192PT2 G KC=0.11 7$LC=0.039 11$MC=0.0098 25 +192PT G 416.4688 7 0.669 21E2+M1 0.050 4 +192PT2 G KC=0.037 4$LC=0.0099 6$MC=0.00242 13 +192PT G 588.5810 7 4.517 22E2 0.0170 5 +192PT2 G KC=0.0129 4$LC=0.00311 9$MC=7.51E-4 23 +192PT G 884.5365 7 0.291 7E2 0.0070721 +192PT2 G KC=0.00566 17$LC=0.00108 3$MC=2.54E-4 8 192PT L 1378.02 3 3- 0.064 NS 18 192PT B 81.7 190.1026 23 8.3 1 192PTS B EAV=21.1 5 -192PT G 176.98 4 0.0043 12[E1] 0.097 3 -192PT2 G KC=0.0786 24$LC=0.0137 4$MC=0.00215 6 -192PT G 593.49 130.0421 17E1+M2 0.0067 4 -192PT2 G KC=0.0055 4$LC=0.00087 6$MC=3.27E-4 14 -192PT G 765.8 3 0.0013 6 E1+M2 0.0052 14 -192PT2 G KC=0.0043 11$LC=0.00070 19$MC=0.00014 4 -192PT G 1061.48 4 0.053 1 E1+M2 0.001979 -192PT2 G KC=0.00166 7$LC=2.43E-4 11$MC=5.8E-5 3 -192PT G 1378.20 150.0012 3 [E3] 0.0062019 -192PT2 G KC=0.00492 15$LC=0.00098 3$MC=2.32E-4 7 +192PT G 176.98 4 0.0043 12[E1] 0.097 3 +192PT2 G KC=0.0786 24$LC=0.0137 4$MC=0.00215 6 +192PT G 593.49 130.0421 17E1+M2 0.0067 4 +192PT2 G KC=0.0055 4$LC=0.00087 6$MC=3.27E-4 14 +192PT G 765.8 3 0.0013 6E1+M2 0.0052 14 +192PT2 G KC=0.0043 11$LC=0.00070 19$MC=0.00014 4 +192PT G 1061.48 4 0.053 1E1+M2 0.00197 9 +192PT2 G KC=0.00166 7$LC=2.43E-4 11$MC=5.8E-5 3 +192PT G 1378.20 150.0012 3[E3] 0.0062019 +192PT2 G KC=0.00492 15$LC=0.00098 3$MC=2.32E-4 7 192PT L 1383.99 15(5)- 192PT B 75.7 190.0039 17 9.6 1 192PTS B EAV=19.5 5 192PT G 599.41 150.0039 17E1 0.0059018 -192PT2 G KC=0.00481 14$LC=7.52E-4 23$MC=2.84E-4 9 +192PT2 G KC=0.00481 14$LC=7.52E-4 23$MC=2.84E-4 9 192PT L 1406.24 11(3)+ -192PT B 53.5 190.0033 5 9.2 +192PT B 53.5 190.0033 5 9.2 192PTS B EAV=13.6 5 -192PT G 1089.9 3 0.0012 2 E2+M1 0.0063 6 -192PT2 G KC=0.0052 5$LC=0.00087 8$MC=2.01E-4 18 +192PT G 1089.9 3 0.0012 2E2+M1 0.0063 6 +192PT2 G KC=0.0052 5$LC=0.00087 8$MC=2.01E-4 18 diff --git a/HEN_HOUSE/spectra/lnhb/Ir-194.txt b/HEN_HOUSE/spectra/lnhb/Ir-194.txt index 2b606727b..5bd4179a7 100644 --- a/HEN_HOUSE/spectra/lnhb/Ir-194.txt +++ b/HEN_HOUSE/spectra/lnhb/Ir-194.txt @@ -1,212 +1,212 @@ 194PT 194IR B- DECAY (19.3 H) -194PT T Auger electrons and ^X ray energies and emission intensities: -194PT T {U Energy (keV)} {U Intensity } {U Line } +194PT T Auger electrons and X ray energies and emission intensities: +194PT T {U Energy (keV)} {U Intensity} {U Line} 194PT T -194PT T 65.123 0.24 3 XKA2 -194PT T 66.833 0.41 5 XKA1 +194PT T 65.123 0.24 3 XKA2 +194PT T 66.833 0.41 5 XKA1 194PT T -194PT T 75.369 |] XKB3 -194PT T 75.749 |] 0.00138 19 XKB1 -194PT T 76.234 |] XKB5II +194PT T 75.369 |] XKB3 +194PT T 75.749 |] 0.00138 19 XKB1 +194PT T 76.234 |] XKB5II 194PT T -194PT T 77.786 |] XKB2 -194PT T 78.07 |] 0.00040 5 XKB4 -194PT T 78.337 |] XKO23 +194PT T 77.786 |] XKB2 +194PT T 78.07 |] 0.00040 5 XKB4 +194PT T 78.337 |] XKO23 194PT T -194PT T 8.268-13.361 0.36 6 XL (total) +194PT T 8.268-13.361 0.36 6 XL (total) 194PT T 8.268 XLL 194PT T -13.361 XLG 194PT T -194PT T 50.4-55.02 |] KLL AUGER -194PT T 61.12-64.62 |] 0.035 4 ^KLX AUGER -194PT T 71.7-74.1 |] KXY AUGER +194PT T 50.4-55.02 |] KLL AUGER +194PT T 61.12-64.62 |] 0.035 4 KLX AUGER +194PT T 71.7-74.1 |] KXY AUGER 194IR P 0.0 1- 19.3 H 1 2246.8 16 194PT N 1.0 1.0 1 1.0 194PT G 1675.24 170.00086 18 -194PT G 2207 1 0.0013 4 +194PT G 2207 1 0.0013 4 194PT L 0 0+ STABLE 194PT B 2246.9 1685.4 19 8.2 1 194PTS B EAV=845.7 7 194PT L 328.449 2+ 41.8 PS 194PT B 1918.5 169.3 13 8.9 1 194PTS B EAV=705.4 7 -194PT G 328.448 1413.1 17E2 0.076 2 -194PT2 G KC=0.049 2$LC=0.020 1$MC=0.0070 2 +194PT G 328.448 1413.1 17E2 0.076 2 +194PT2 G KC=0.049 2$LC=0.020 1$MC=0.0070 2 194PT L 621.99 2+ 35 PS 194PT B 1624.9 161.28 20 9.5 1 194PTS B EAV=582.2 7 -194PT G 293.541 142.5 3 E2+M1+ 0.107 3 -194PT2 G KC=0.066 2$LC=0.031 1$MC=0.010 1 -194PT G 621.971 190.33 5 E2 0.0150 5 -194PT2 G KC=0.0115 4$LC=0.0025 1$MC= +194PT G 293.541 142.5 3E2+M1+ 0.107 3 +194PT2 G KC=0.066 2$LC=0.031 1$MC=0.010 1 +194PT G 621.971 190.33 5E2 0.0150 5 +194PT2 G KC=0.0115 4$LC=0.0025 1 194PT L 811.33 4+ -194PT G 482.857 260.046 6 E2 0.0272 8 -194PT2 G KC=0.0200 6$LC=0.0056 2$MC=0.0016 1 +194PT G 482.857 260.046 6E2 0.0272 8 +194PT2 G KC=0.0200 6$LC=0.0056 2$MC=0.0016 1 194PT L 922.739 3+ -194PT B 1324.2 160.30 4 10.5 1U +194PT B 1324.2 160.30 4 10.5 1U 194PTS B EAV=452.4 6 -194PT G 111.4 4 0.0017 6 [M1E2] 4.1 10 -194PT2 G KC=2.4 18$LC=1.3 7$MC=0.40 18 -194PT G 300.741 140.35 5 E2(+M1) 0.103 4 -194PT2 G KC=0.061 2$LC=0.028 1$MC=0.014 1 -194PT G 594.291 190.062 8 E2(+M1) 0.0166 5 -194PT2 G KC=0.0126 4$LC=0.0030 1$MC=0.0010 1 +194PT G 111.4 4 0.0017 6[M1E2] 4.1 10 +194PT2 G KC=2.4 18$LC=1.3 7$MC=0.40 18 +194PT G 300.741 140.35 5E2(+M1) 0.103 4 +194PT2 G KC=0.061 2$LC=0.028 1$MC=0.014 1 +194PT G 594.291 190.062 8E2(+M1) 0.0166 5 +194PT2 G KC=0.0126 4$LC=0.0030 1$MC=0.0010 1 194PT L 1229.6 4+ -194PT G 607.61 8 0.0039 6 E2 0.0158 5 -194PT2 G KC=0.0121 4$LC=0.0028 1$MC=0.0010 1 +194PT G 607.61 8 0.0039 6E2 0.0158 5 +194PT2 G KC=0.0121 4$LC=0.0028 1$MC=0.0010 1 194PT L 1267.145 0+ 194PT B 979.8 161.77 23 8.6 1 194PTS B EAV=323.1 6 -194PT G 645.146 201.18 16E2 0.0138 4 -194PT2 G KC=0.0106 3$LC=0.0024 1$MC= -194PT G 938.690 250.60 8 E2 0.0062719 -194PT2 G KC=0.0050 2$LC=0.00090 3$MC= +194PT G 645.146 201.18 16E2 0.0138 4 +194PT2 G KC=0.0106 3$LC=0.0024 1 +194PT G 938.690 250.60 8E2 0.0062719 +194PT2 G KC=0.0050 2$LC=0.00090 3 194PT L 1432.49 3- -194PT G 202.91 150.0030 8 E1 0.068 2 -194PT2 G KC=0.056 2$LC=0.0093 3$MC=0.0027 1 +194PT G 202.91 150.0030 8E1 0.068 2 +194PT2 G KC=0.056 2$LC=0.0093 3$MC=0.0027 1 194PT G 621.29 150.0096 18E1+M2 0.0091 18 -194PT2 G KC=0.0074 15$LC=0.0013 3$MC= -194PT G 810.66 190.0025 6 [E1] 0.0032 1 -194PT2 G KC=0.0027 1$LC=$MC= -194PT G 1104.05 5 0.026 4 E1 0.001785 -194PT2 G KC=0.00149 5$LC=$MC= -194PT G 1432.52 120.0011 3 [E3] 0.0057117 -194PT2 G KC=0.00455 14$LC=$MC= +194PT2 G KC=0.0074 15$LC=0.0013 3 +194PT G 810.66 190.0025 6[E1] 0.0032 1 +194PT2 G KC=0.0027 1 +194PT G 1104.05 5 0.026 4E1 0.00178 5 +194PT2 G KC=0.00149 5 +194PT G 1432.52 120.0011 3[E3] 0.0057117 +194PT2 G KC=0.00455 14 194PT L 1479.2 0+ -194PT B 767.7 160.61 8 8.7 1 +194PT B 767.7 160.61 8 8.7 1 194PTS B EAV=243.4 6 194PT G 1479.2 -194PT G 857.12 190.0071 12[E2] 0.0075 2 -194PT2 G KC=0.0060 2$LC=$MC= -194PT G 1150.75 5 0.60 8 E2 0.0042013 -194PT2 G KC=0.00342 10$LC=$MC= +194PT G 857.12 190.0071 12[E2] 0.0075 2 +194PT2 G KC=0.0060 2 +194PT G 1150.75 5 0.60 8E2 0.0042013 +194PT2 G KC=0.00342 10 194PT L 1511.927 2+ -194PT B 735.0 160.56 7 8.6 1 +194PT B 735.0 160.56 7 8.6 1 194PTS B EAV=231.5 6 -194PT G 244.83 5 0.0077 11E2 0.186 6 -194PT2 G KC=0.102 3$LC=0.063 2$MC=0.020 1 +194PT G 244.83 5 0.0077 11E2 0.186 6 +194PT2 G KC=0.102 3$LC=0.063 2$MC=0.020 1 194PT G 589.179 170.140 18E2+M1 0.0231 24 -194PT2 G KC=0.0181 5$LC=0.0037 3$MC=0.0013 1 -194PT G 700.55 4 0.026 5 E2 0.0115 4 -194PT2 G KC=0.0089 3$LC=0.0019 1$MC= -194PT G 889.98 4 0.051 7 E2+M1 0.0105 17 -194PT2 G KC=0.0085 14$LC=0.0015 2$MC= -194PT G 1183.49 5 0.31 4 E2+M1 0.0057917 -194PT2 G KC=0.00476 14$LC=$MC= -194PT G 1511.98 100.024 4 (E2) 0.002497 -194PT2 G KC=0.00208 6$LC=$MC= +194PT2 G KC=0.0181 5$LC=0.0037 3$MC=0.0013 1 +194PT G 700.55 4 0.026 5E2 0.0115 4 +194PT2 G KC=0.0089 3$LC=0.0019 1 +194PT G 889.98 4 0.051 7E2+M1 0.0105 17 +194PT2 G KC=0.0085 14$LC=0.0015 2 +194PT G 1183.49 5 0.31 4E2+M1 0.0057917 +194PT2 G KC=0.00476 14 +194PT G 1511.98 100.024 4(E2) 0.00249 7 +194PT2 G KC=0.00208 6 194PT L 1547.24 0+ -194PT B 699.7 160.070 9 9.5 1 +194PT B 699.7 160.070 9 9.5 1 194PTS B EAV=218.7 6 -194PT G 925.26 6 0.0126 18E2 0.0065 2 -194PT2 G KC=0.0052 2$LC=$MC= -194PT G 1218.78 5 0.056 8 E2 0.0037611 -194PT2 G KC=0.00307 9$LC=$MC= +194PT G 925.26 6 0.0126 18E2 0.0065 2 +194PT2 G KC=0.0052 2 +194PT G 1218.78 5 0.056 8E2 0.0037611 +194PT2 G KC=0.00307 9 194PT L 1622.13 2+ 194PT B 624.8 160.160 21 8.9 1 194PTS B EAV=192.0 6 194PT G 699.5 4 0.0025 13[M1E2] 0.023 11 -194PT2 G KC=0.019 10$LC=0.0032 14$MC= -194PT G 1000.12 4 0.047 6 E2+M1 0.0083 18 -194PT2 G KC=0.0068 15$LC=0.00113 21$MC= -194PT G 1293.67 6 0.046 7 M1+E2 0.02 1 -194PT2 G KC=0.016 8$LC=$MC= -194PT G 1622.20 180.064 9 +194PT2 G KC=0.019 10$LC=0.0032 14 +194PT G 1000.12 4 0.047 6E2+M1 0.0083 18 +194PT2 G KC=0.0068 15$LC=0.00113 21 +194PT G 1293.67 6 0.046 7M1+E2 0.02 1 +194PT2 G KC=0.016 8 +194PT G 1622.20 180.064 9 194PT L 1670.64 2+ 194PT B 576.3 160.072 10 9.2 1 194PTS B EAV=175.0 6 -194PT G 859.45 180.0017 8 [E2] 0.0075 2 -194PT2 G KC=0.0060 2$LC=$MC= -194PT G 1048.64 5 0.026 4 M1(+E2) 0.011 1 -194PT2 G KC=0.0077 24$LC=0.0012 40$MC= -194PT G 1342.16 6 0.038 5 M1+E2 0.005 2 -194PT2 G KC=0.0040 15$LC=$MC= -194PT G 1670.72 100.0058 8 +194PT G 859.45 180.0017 8[E2] 0.0075 2 +194PT2 G KC=0.0060 2 +194PT G 1048.64 5 0.026 4M1(+E2) 0.011 1 +194PT2 G KC=0.0077 24$LC=0.0012 40 +194PT G 1342.16 6 0.038 5M1+E2 0.005 2 +194PT2 G KC=0.0040 15 +194PT G 1670.72 100.0058 8 194PT L 1778.67 1,2+ -194PT B 468.2 160.0035 6 10.2 +194PT B 468.2 160.0035 6 10.2 194PTS B EAV=138.2 5 -194PT G 1156.6 3 0.0018 5 M1(+E2) 0.0088 19 -194PT2 G KC=0.0073 16$LC=$MC= -194PT G 1450.23 110.0016 3 M1+E2 0.0040 3 -194PT2 G KC=0.0033 3$LC=$MC= +194PT G 1156.6 3 0.0018 5M1(+E2) 0.0088 19 +194PT2 G KC=0.0073 16 +194PT G 1450.23 110.0016 3M1+E2 0.0040 3 +194PT2 G KC=0.0033 3 194PT L 1797.355 1- -194PT B 449.5 160.33 4 8.2 +194PT B 449.5 160.33 4 8.2 194PTS B EAV=132.0 5 -194PT G 364.867 150.041 6 E2 0.0568 17 -194PT2 G KC=0.038 11$LC=0.014 1$MC=0.0050 2 -194PT G 530.173 300.016 2 E1 0.0073522 -194PT2 G KC=0.0061 2$LC=0.00094 3$MC=0.00031 1 -194PT G 1175.38 5 0.061 8 E1 0.001595 -194PT2 G KC=0.00133 4$LC=$MC= -194PT G 1468.91 7 0.19 3 E1 0.001093 -194PT2 G KC=0.00092 3$LC=$MC= -194PT G 1797.48 9 0.0176 2 +194PT G 364.867 150.041 6E2 0.0568 17 +194PT2 G KC=0.038 11$LC=0.014 1$MC=0.0050 2 +194PT G 530.173 300.016 2E1 0.0073522 +194PT2 G KC=0.0061 2$LC=0.00094 3$MC=0.00031 1 +194PT G 1175.38 5 0.061 8E1 0.00159 5 +194PT2 G KC=0.00133 4 +194PT G 1468.91 7 0.19 3E1 0.00109 3 +194PT2 G KC=0.00092 3 +194PT G 1797.48 9 0.0176 2 194PT L 1893.59 (0)+ -194PT B 353.3 160.021 3 9 1 +194PT B 353.3 160.021 3 9 1 194PTS B EAV=10.9 5 -194PT G 1565.15 8 0.021 3 +194PT G 1565.15 8 0.021 3 194PT L 1924.29 1+ -194PT B 322.6 160.0035 5 9.6 +194PT B 322.6 160.0035 5 9.6 194PTS B EAV=91.2 5 -194PT G 1595.77 100.0016 3 -194PT G 1924.42 140.0018 3 +194PT G 1595.77 100.0016 3 +194PT G 1924.42 140.0018 3 194PT L 1930.25 (2)+ -194PT B 316.6 160.0032 5 9.7 1 +194PT B 316.6 160.0032 5 9.7 1 194PTS B EAV=89.3 5 -194PT G 1308.15 120.00130 22E2(+M1) 0.0039 6 -194PT2 G KC=0.0032 5$LC=$MC= -194PT G 1601.90 120.0020 3 +194PT G 1308.15 120.00130 22E2(+M1) 0.0039 6 +194PT2 G KC=0.0032 5 +194PT G 1601.90 120.0020 3 194PT L 2043.72 1+ 194PT B 203.2 160.0090 13 8.6 194PTS B EAV=55.1 5 194PT G 1421.48 280.00063 21M1(+E2) 0.0052 13 -194PT2 G KC=0.0043 10$LC=$MC= +194PT2 G KC=0.0043 10 194PT G 1715.28 110.00131 21 194PT G 2043.72 110.0071 10 194PT L 2053.08 (<=3)+ -194PT B 193.8 160.0030 8 9 1U +194PT B 193.8 160.0030 8 9 1U 194PTS B EAV=52.4 5 -194PT G 1431.35 340.0022 7 +194PT G 1431.35 340.0022 7 194PT G 1724.54 150.00076 14 194PT L 2063.81 1,2+ -194PT B 183.1 160.0040 6 8.8 +194PT B 183.1 160.0040 6 8.8 194PTS B EAV=49.3 5 -194PT G 1441.78 140.0015 3 M1+E2 0.0041 5 -194PT2 G KC=0.0034 4$LC=$MC= -194PT G 1735.37 120.0025 4 +194PT G 1441.78 140.0015 3M1+E2 0.0041 5 +194PT2 G KC=0.0034 4 +194PT G 1735.37 120.0025 4 194PT L 2085.6 0+ 194PT B 161.3 160.0066 15 8.4 1 194PTS B EAV=43.1 4 -194PT G 1463.50 150.0059 14E2 0.002678 -194PT2 G KC=0.00220 7$LC=$MC= +194PT G 1463.50 150.0059 14E2 0.00267 8 +194PT2 G KC=0.00220 7 194PT G 1757.27 190.00042 11 194PT L 2109.08 1,2+ -194PT B 137.8 160.031 4 7.5 +194PT B 137.8 160.031 4 7.5 194PTS B EAV=36.5 5 194PT G 1186.4 4 0.0084 19E2(+M1) 0.0056 17 -194PT2 G KC=0.0046 14$LC=$MC= +194PT2 G KC=0.0046 14 194PT G 1487.05 8 0.0170 23M1(+E2) 0.0045 12 -194PT2 G KC=0.0037 10$LC=$MC= -194PT G 1780.69 110.0052 8 +194PT2 G KC=0.0037 10 +194PT G 1780.69 110.0052 8 194PT L 2114.17 1+ 194PT B 132.7 160.0081 11 8.1 194PTS B EAV=35.0 5 -194PT G 1492.18 130.0015 3 M1(+E2) 0.0045 12 -194PT2 G KC=0.0037 10$LC=$MC= -194PT G 1785.69 110.0040 6 -194PT G 2114.20 140.0026 4 +194PT G 1492.18 130.0015 3M1(+E2) 0.0045 12 +194PT2 G KC=0.0037 10 +194PT G 1785.69 110.0040 6 +194PT G 2114.20 140.0026 4 194PT L 2134.2 (0,1,2)+ -194PT B 112.7 160.046 6 7.1 1 +194PT B 112.7 160.046 6 7.1 1 194PTS B EAV=29.5 4 194PT G 1512.15 210.0132 18 -194PT G 1805.75 9 0.032 5 +194PT G 1805.75 9 0.032 5 194PT L 2140.83 (0,1,2)+ -194PT B 106.1 160.0021 4 8.4 1 +194PT B 106.1 160.0021 4 8.4 1 194PTS B EAV=27.7 4 -194PT G 1518.76 140.0017 3 +194PT G 1518.76 140.0017 3 194PT G 1812.59 250.00045 14 194PT L 2158.05 1,2+ -194PT B 88.9 160.0019 3 8.2 +194PT B 88.9 160.0019 3 8.2 194PTS B EAV=23.0 4 -194PT G 1829.59 150.0019 3 +194PT G 1829.59 150.0019 3 diff --git a/HEN_HOUSE/spectra/lnhb/K-40.txt b/HEN_HOUSE/spectra/lnhb/K-40.txt index b3e426dd4..d275c0bbd 100644 --- a/HEN_HOUSE/spectra/lnhb/K-40.txt +++ b/HEN_HOUSE/spectra/lnhb/K-40.txt @@ -7,34 +7,34 @@ 40AR2C 1956MC20, 1957WE43, 1959KE26, 1959Ti20, 1960SA31, 1961GL07, 1962FL05, 40AR3C 1962EN01, 1965BR25, 1965LE15, 1966FE09, 1967KI10, 1970JA15, 1977CE04, 40AR4C 1979HE13, 1990EN08, 2001BE81, 2003AU03, 2004KO09, 2008KI07 - 40AR T Auger electrons and ^X ray energies and emission intensities: - 40AR T {U Energy (keV)} {U Intensity } {U Line } + 40AR T Auger electrons and X ray energies and emission intensities: + 40AR T {U Energy (keV)} {U Intensity} {U Line} 40AR T - 40AR T 2.95566 0.299 9 XKA2 - 40AR T 2.95774 0.592 17 XKA1 + 40AR T 2.95566 0.299 9 XKA2 + 40AR T 2.95774 0.592 17 XKA1 40AR T - 40AR T 3.1905 |] 0.096 4 XKB1 + 40AR T 3.1905 |] 0.096 4 XKB1 40AR T 40AR T - 40AR T 0.2195-0.3114 0.003 1 XL (total) + 40AR T 0.2195-0.3114 0.003 1 XL (total) 40AR T 0.2195 XLL 40AR T 0.2215 XLC 40AR T 0.3112-0.3114 XLB 40AR T - 40AR T 2.511-2.669 |] KLL AUGER - 40AR T 2.831-2.942 |] 7.24 11 ^KLX AUGER - 40AR T 3.149-3.174 |] KXY AUGER - 40AR T 0.17-0.31 2.22 2 L AUGER + 40AR T 2.511-2.669 |] KLL AUGER + 40AR T 2.831-2.942 |] 7.24 11 KLX AUGER + 40AR T 3.149-3.174 |] KXY AUGER + 40AR T 0.17-0.31 2.22 2 L AUGER 40K P 0.0 4- 1.2504E9 Y30 1504.69 19 - 40AR N 9.302E0 9.302E0 0.1075 179.302E0 + 40AR N 9.302E0 9.302E0 0.1075 9.302E0 40AR L 0 0+ STABLE - 40AR E 0.00100 120.2 1 21.35 3U - 40AR2 E EAV= $CK=0.88 $CL=0.086 $CM=0.013 $CN= $CO= + 40AR E 0.00100 120.2 121.35 3U + 40AR2 E CK=0.88 $CL=0.086 $CM=0.013 40AR L 1460.851 6 2+ 0.00161 NS6 40AR E 10.55 1111.55 1U - 40AR2 E EAV= $CK=0.763 $CL=0.209 $CM=0.027 $CN= $CO= + 40AR2 E CK=0.763 $CL=0.209 $CM=0.027 40AR G 1460.822 6 10.55 11E2 1028E-715 - 40AR2 G KC=2.63E-5 4$LC=2.15E-6 3$MC=2.10E-7 3 + 40AR2 G KC=2.63E-5 4$LC=2.15E-6 3$MC=2.10E-7 3 40CA 40K B- DECAY (1.2504E9 Y) 40CA H TYP=Upadte$AUT=M.M. Bé$CUT= -- $ @@ -45,22 +45,22 @@ 40CA2C 1956MC20, 1957WE43, 1959KE26, 1959Ti20, 1960SA31, 1961GL07, 1962FL05, 40CA3C 1962EN01, 1965BR25, 1965LE15, 1966FE09, 1967KI10, 1970JA15, 1977CE04, 40CA4C 1979HE13, 1990EN08, 2001BE81, 2003AU03, 2004KO09, 2008KI07 - 40CA T Auger electrons and ^X ray energies and emission intensities: - 40CA T {U Energy (keV)} {U Intensity } {U Line } + 40CA T Auger electrons and X ray energies and emission intensities: + 40CA T {U Energy (keV)} {U Intensity} {U Line} 40CA T 40CA T 3.68813 XKA2 40CA T 3.69172 XKA1 40CA T - 40CA T 4.0128 |] XKB1 - 40CA T 4.0325 |] XKB5II + 40CA T 4.0128 |] XKB1 + 40CA T 4.0325 |] XKB5II 40CA T 40CA T 40CA T - 40CA T 3.123-3.307 |] KLL AUGER - 40CA T 3.543-3.666 |] ^KLX AUGER - 40CA T 3.951-3.987 |] KXY AUGER + 40CA T 3.123-3.307 |] KLL AUGER + 40CA T 3.543-3.666 |] KLX AUGER + 40CA T 3.951-3.987 |] KXY AUGER 40K P 0.0 4- 1.2504E9 Y30 1311.07 11 - 40CA N 1.12E0 1.12E0 0.8925 171.12E0 + 40CA N 1.12E0 1.12E0 0.8925 1.12E0 40CA L 0 0+ STABLE 40CA B 1311.07 1189.25 17 20.58 3U 40CAS B EAV=508.32 6 diff --git a/HEN_HOUSE/spectra/lnhb/Kr-85.txt b/HEN_HOUSE/spectra/lnhb/Kr-85.txt index dd35d59d6..cf87e69d1 100644 --- a/HEN_HOUSE/spectra/lnhb/Kr-85.txt +++ b/HEN_HOUSE/spectra/lnhb/Kr-85.txt @@ -1,28 +1,28 @@ 85RB 85KR B- DECAY (10.752 Y) 85RB H TYP=update$AUT=V. Chisté$CUT= -- $ 85RB C Evaluation history: Type=update;Author=V. Chisté;Cutoff date= -- - 85RB T Auger electrons and ^X ray energies and emission intensities: - 85RB T {U Energy (keV)} {U Intensity } {U Line } + 85RB T Auger electrons and X ray energies and emission intensities: + 85RB T {U Energy (keV)} {U Intensity} {U Line} 85RB T - 85RB T 13.3359 0.000540 14 XKA2 - 85RB T 13.3955 0.001040 25 XKA1 + 85RB T 13.3359 0.00054014 XKA2 + 85RB T 13.3955 0.00104025 XKA1 85RB T - 85RB T 14.9519 |] XKB3 - 85RB T 14.9614 |] 0.000253 7 XKB1 - 85RB T 15.085 |] XKB5II + 85RB T 14.9519 |] XKB3 + 85RB T 14.9614 |] 0.000253 7 XKB1 + 85RB T 15.085 |] XKB5II 85RB T - 85RB T 15.1856 |] XKB2 - 85RB T 15.205 |] 0.0000294 13 XKB4 + 85RB T 15.1856 |] XKB2 + 85RB T 15.205 |] 2.94E-5 13 XKB4 85RB T 85RB T - 85RB T 10.987-11.503 |] KLL AUGER - 85RB T 12.782-13.381 |] 0.000901 24 ^KLX AUGER - 85RB T 14.556-15.172 |] KXY AUGER - 85RB T 1.1-2 0.00336 6 L AUGER + 85RB T 10.987-11.503 |] KLL AUGER + 85RB T 12.782-13.381 |] 0.00090124 KLX AUGER + 85RB T 14.556-15.172 |] KXY AUGER + 85RB T 1.1-2 0.00336 6 L AUGER 85KR P 0.0 9/2+ 10.752 Y 23 687.1 19 85RB N 1.0 1.0 1 1.0 85RB L 0 5/2- STABLE - 85RB B 687.1 1999.562 10 8.4 3U + 85RB B 687.1 1999.562 10 8.4 1U 85RBS B EAV=251.4 8 85RB L 151.18 3 3/2- 0.71 NS 5 85RB G 151.18 3 2.2E-6 13M1+()E2 0.072 8 0.0488 14 @@ -30,8 +30,8 @@ 85RB L 513.998 5 9/2+ 1.015 US 1 85RB B 173.1 190.438 10 9.5 85RBS B EAV=47.5 6 - 85RB G 362.81 4 2.18E-6 44(E3) 0.034 1 - 85RB2 G KC=0.0292 9$LC=0.00400 12$MC=0.00067 2 + 85RB G 362.81 4 2.18E-6 44(E3) 0.034 1 + 85RB2 G KC=0.0292 9$LC=0.00400 12$MC=0.00067 2 85RB G 513.997 5 0.435 10M2 0.0072122 - 85RB2 G KC=0.00635 19$LC=0.00072 2$MC=1.22E-4 4 + 85RB2 G KC=0.00635 19$LC=0.00072 2$MC=1.22E-4 4 diff --git a/HEN_HOUSE/spectra/lnhb/La-138.txt b/HEN_HOUSE/spectra/lnhb/La-138.txt index 0c0d12210..549076cfb 100644 --- a/HEN_HOUSE/spectra/lnhb/La-138.txt +++ b/HEN_HOUSE/spectra/lnhb/La-138.txt @@ -1,11 +1,13 @@ 138BA 138LA EC DECAY (103.6E9 Y) -138BA H TYP=Upd$AUT=X. Mougeot$CUT=01-MAY-2016$ -138BA2 H TYP=Full$AUT=M.M. Bé$CUT=01-NOV-2013$ -138BA C Evaluation history: Type=Upd;Author=X. Mougeot;Cutoff date=01-MAY-2016 -138BA2C Type=Full;Author=M.M. Bé;Cutoff date=01-NOV-2013 -138BA C References: 1956Tu17, 1957Gl20, 1966De04, 1972Ma31, 1972El02, 1979Ta21, -138BA2C 1981Sa42, 1983No02, 1984Ma46, 1997Ni12, 2002Ba85, 2005Be73, 2008Ki07, -138BA3C 2012Qu02, 2012Wa38, 2016Qu01 +138BA H TYP=UPD$AUT=X. Mougeot$CUT=01-MAY-2016$ +138BA2 H TYP=FUL$AUT=M.M. Bé$CUT=01-NOV-2013$ +138BA C Evaluation history: Type=UPD;Author=X. Mougeot;Cutoff date=01-MAY-2016 +138BA2C Type=FUL;Author=M.M. Bé;Cutoff date=01-NOV-2013 +138BA C References: 1956Tu17, 1956Tu17, 1957Gl20, 1957Gl20, 1966De04, 1966De04, +138BA2C 1972El02, 1972Ma31, 1972El02, 1972Ma31, 1979Ta21, 1979Ta21, 1981Sa42, +138BA3C 1981Sa42, 1983No02, 1983No02, 1984Ma46, 1984Ma46, 1997Ni12, 1997Ni12, +138BA4C 2002Ba85, 2002Ba85, 2005Be73, 2005Be73, 2008Ki07, 2008Ki07, 2012Qu02, +138BA5C 2012Wa38, 2012Qu02, 2012Wa38, 2016Qu01 138BA T Auger electrons and X ray energies and emission intensities: 138BA T {U Energy (keV)} {U Intensity} {U Line} 138BA T @@ -17,45 +19,47 @@ 138BA T 36.654 |] XKB5II 138BA T 138BA T 37.258 |] XKB2 -138BA T 37.312 |] 1.45 4 XKB4 +138BA T 37.312 |] 1.45 4 XKB4 138BA T 37.425 |] XKO23 138BA T 138BA T 3.9544-5.8104 6.03 10 XL (total) 138BA T 3.9544 0.1201 30 XLL -138BA T 4.4515-4.4666 3.11 8 XLA +138BA T 4.4515-4.4666 3.11 8 XLA 138BA T 4.3307 0.0367 10 XLC -138BA T 4.8278-5.207 2.39 5 XLB -138BA T 5.3715-5.8104 0.380 8 XLG +138BA T 4.8278-5.207 2.39 5 XLB +138BA T 5.3715-5.8104 0.380 8 XLG 138BA T 138BA T 25.314-26.786 |] KLL AUGER 138BA T 30.095-32.179 |] 4.16 18 KLX AUGER 138BA T 34.86-37.41 |] KXY AUGER -138BA T 2.66-5.81 48.8 4 L AUGER +138BA T 2.66-5.81 48.8 4 L AUGER 138LA P 0.0 5+ 103.6E9 Y 20 1740.0 34 138BA N 1.534E0 1.534E0 0.652 6 1.534E0 138BA L 0 0+ STABLE 138BA L 1435.816 102+ -138BA E 65.2 6 17.2 2U -138BA2 E EAV= $CK=0.637 5$CL=0.275 3$CM=0.0880 11$CN= $CO= -138BA G 1435.795 1065.1 6 E2 9.17E-413 -138BA2 G KC=7.42E-4 11$LC=9.37E-5 14$MC=1.92E-5 3 +138BA E 65.2 617.2 2U +138BA2 E CK=0.637 5$CL=0.275 3$CM=0.0880 11 +138BA G 1435.795 1065.1 6E2 9.17E-413 +138BA2 G KC=7.42E-4 11$LC=9.37E-5 14$MC=1.92E-5 3 138CE 138LA B- DECAY (103.6E9 Y) -138CE H TYP=Upd$AUT=X. Mougeot$CUT=01-MAY-2016$ -138CE2 H TYP=Full$AUT=M.M. Bé$CUT=01-NOV-2013$ -138CE C Evaluation history: Type=Upd;Author=X. Mougeot;Cutoff date=01-MAY-2016 -138CE2C Type=Full;Author=M.M. Bé;Cutoff date=01-NOV-2013 -138CE C References: 1956Tu17, 1957Gl20, 1966De04, 1972Ma31, 1972El02, 1979Ta21, -138CE2C 1981Sa42, 1983No02, 1984Ma46, 1997Ni12, 2002Ba85, 2005Be73, 2008Ki07, -138CE3C 2012Qu02, 2012Wa38, 2016Qu01 +138CE H TYP=UPD$AUT=X. Mougeot$CUT=01-MAY-2016$ +138CE2 H TYP=FUL$AUT=M.M. Bé$CUT=01-NOV-2013$ +138CE C Evaluation history: Type=UPD;Author=X. Mougeot;Cutoff date=01-MAY-2016 +138CE2C Type=FUL;Author=M.M. Bé;Cutoff date=01-NOV-2013 +138CE C References: 1956Tu17, 1956Tu17, 1957Gl20, 1957Gl20, 1966De04, 1966De04, +138CE2C 1972El02, 1972Ma31, 1972El02, 1972Ma31, 1979Ta21, 1979Ta21, 1981Sa42, +138CE3C 1981Sa42, 1983No02, 1983No02, 1984Ma46, 1984Ma46, 1997Ni12, 1997Ni12, +138CE4C 2002Ba85, 2002Ba85, 2005Be73, 2005Be73, 2008Ki07, 2008Ki07, 2012Qu02, +138CE5C 2012Wa38, 2012Qu02, 2012Wa38, 2016Qu01 138CE T Auger electrons and X ray energies and emission intensities: 138CE T {U Energy (keV)} {U Intensity} {U Line} 138CE T -138CE T 34.2793 0.0261 6 XKA2 +138CE T 34.2793 0.0261 6 XKA2 138CE T 34.72 0.0478 11 XKA1 138CE T 138CE T 39.1705 |] XKB3 -138CE T 39.2578 |] 0.0144 4 XKB1 +138CE T 39.2578 |] 0.0144 4 XKB1 138CE T 39.549 |] XKB5II 138CE T 138CE T 40.233 |] XKB2 @@ -63,22 +67,22 @@ 138CE T 40.423 |] XKO23 138CE T 138CE T 4.2868-6.3412 0.01301 29 XL (total) -138CE T 4.2868 2.52E-4 9 XLL +138CE T 4.2868 0.000252 9 XLL 138CE T 4.822-4.8411 0.00642 20 XLA 138CE T 4.7274 9.54E-5 29 XLC 138CE T 5.2625-5.665 0.00538 12 XLB -138CE T 5.8755-6.3412 0.00085 2 XLG +138CE T 5.8755-6.3412 0.00085 2 XLG 138CE T 138CE T 27.19-28.828 |] KLL AUGER -138CE T 32.392-34.7 |] 0.0091 5 KLX AUGER +138CE T 32.392-34.7 |] 0.0091 5 KLX AUGER 138CE T 37.57-40.4 |] KXY AUGER -138CE T 2.85-6.51 0.0895 7 L AUGER -138LA P 0.0 5+ 103.6E9 Y 20 1051.8 21 +138CE T 2.85-6.51 0.0895 7 L AUGER +138LA P 0.0 5+ 103.6E9 Y 20 1051.7 40 138CE N 2.874E0 2.874E0 0.348 6 2.874E0 138CE L 0 0+ STABLE 138CE L 788.744 8 2+ -138CE B 263.1 2134.8 6 18.7 2U -138CES B EAV=91.1 11 -138CE G 788.742 8 34.7 6 E2 0.003425 -138CE2 G KC=0.00291 4$LC=4.06E-4 6$MC=8.52E-5 12 +138CE B 263 4 34.8 6 18.7 2U +138CES B EAV=91.1 21 +138CE G 788.742 8 34.7 6E2 0.00342 5 +138CE2 G KC=0.00291 4$LC=4.06E-4 6$MC=8.52E-5 12 diff --git a/HEN_HOUSE/spectra/lnhb/La-140.txt b/HEN_HOUSE/spectra/lnhb/La-140.txt index d6dfed752..de2e27cd3 100644 --- a/HEN_HOUSE/spectra/lnhb/La-140.txt +++ b/HEN_HOUSE/spectra/lnhb/La-140.txt @@ -8,161 +8,161 @@ 140CE5C 1980Ol03, 1982HoZJ, 1982Ad02, 1983Wa26, 1989Ab18, 1991Ch05, 1992Un01, 140CE6C 1998Si17, 2002Ad04, 2002Ba85, 2002Un02, 2004BeZR, 2007Ni07, 2008Ki07, 140CE7C 2012Fi12, 2012Wa38, 2014Un01 -140CE T Auger electrons and ^X ray energies and emission intensities: -140CE T {U Energy (keV)} {U Intensity } {U Line } +140CE T Auger electrons and X ray energies and emission intensities: +140CE T {U Energy (keV)} {U Intensity} {U Line} 140CE T -140CE T 34.2793 0.591 8 XKA2 -140CE T 34.72 1.082 13 XKA1 +140CE T 34.2793 0.591 8 XKA2 +140CE T 34.72 1.082 13 XKA1 140CE T -140CE T 39.1705 |] XKB3 -140CE T 39.2578 |] 0.326 6 XKB1 -140CE T 39.549 |] XKB5II +140CE T 39.1705 |] XKB3 +140CE T 39.2578 |] 0.326 6 XKB1 +140CE T 39.549 |] XKB5II 140CE T -140CE T 40.233 |] XKB2 -140CE T 40.337 |] 0.0828 21 XKB4 +140CE T 40.233 |] XKB2 +140CE T 40.337 |] 0.0828 21 XKB4 140CE T -140CE T 4.2868-6.3412 0.343 7 XL (total) -140CE T 4.2868 0.00666 20 XLL -140CE T 4.822-4.8411 0.170 5 XLA -140CE T 4.7274 0.00258 6 XLC -140CE T 5.2625-5.6103 0.1422 25 XLB -140CE T 5.8755-6.3412 0.0222 5 XLG +140CE T 4.2868-6.3412 0.343 7 XL (total) +140CE T 4.2868 0.00666 20 XLL +140CE T 4.822-4.8411 0.170 5 XLA +140CE T 4.7274 0.00258 6 XLC +140CE T 5.2625-5.6103 0.1422 25 XLB +140CE T 5.8755-6.3412 0.0222 5 XLG 140CE T -140CE T 27.19-28.828 |] KLL AUGER -140CE T 32.392-34.7 |] 0.206 10 ^KLX AUGER -140CE T 37.57-40.4 |] KXY AUGER -140CE T 2.8-6.5 2.360 13 L AUGER +140CE T 27.19-28.828 |] KLL AUGER +140CE T 32.392-34.7 |] 0.206 10 KLX AUGER +140CE T 37.57-40.4 |] KXY AUGER +140CE T 2.8-6.5 2.360 13 L AUGER 140LA P 0.0 3- 1.67858 D 21 3760.9 18 140CE N 1.0 1.0 1 1.0 140CE L 0 0+ STABLE 140CE L 1596.213 132+ 0.0916 PS 19 -140CE B 2164.7 184.5 6 9.4 1 +140CE B 2164.7 184.5 6 9.4 1 140CES B EAV=846.4 8 -140CE G 1596.203 1395.40 5 E2 7.87E-413 -140CE2 G KC=6.76E-4 10$LC=8.63E-5 12$MC=1.79E-5 3 +140CE G 1596.203 1395.40 5E2 7.87E-413 +140CE2 G KC=6.76E-4 10$LC=8.63E-5 12$MC=1.79E-5 3 140CE L 1903.29 4 0+ 0.40 NS 3 -140CE G 307.08 4 0.022 5 E2 0.0450 7 -140CE2 G KC=0.0362 6$LC=0.00695 10$MC=1495E-6 21 +140CE G 307.08 4 0.022 5E2 0.0450 7 +140CE2 G KC=0.0362 6$LC=0.00695 10$MC=1495E-6 21 140CE G 1903.29 4 140CE L 2083.236 144+ 3.45 NS 3 -140CE B 1677.7 1820.8 6 8.3 1 +140CE B 1677.7 1820.8 6 8.3 1 140CES B EAV=629.7 8 -140CE G 487.022 6 46.1 5 E2 0.0115617 -140CE2 G KC=0.00963 14$LC=1526E-6 22$MC=3.24E-4 5 -140CE G 2083.219 140.036 7 E4 1364E-619 -140CE2 G KC=1162E-6 17$LC=1598E-7 23$MC=3.35E-5 5 +140CE G 487.022 6 46.1 5E2 0.0115617 +140CE2 G KC=0.00963 14$LC=1526E-6 22$MC=3.24E-4 5 +140CE G 2083.219 140.036 7E4 1364E-619 +140CE2 G KC=1162E-6 17$LC=1598E-7 23$MC=3.35E-5 5 140CE L 2107.830 146+ 7.3 US 15 -140CE G 24.595 4 6.89E-4 19E2 696 10 -140CE2 G KC=$LC=545 8$MC=122.0 18 +140CE G 24.595 4 0.00068919E2 696 10 +140CE2 G LC=545 8$MC=122.0 18 140CE L 2347.868 142+ 140CE B 1413.0 185.03 12 8.6 1 140CES B EAV=515.0 8 -140CE G 444.57 4 0.003 1 [E2] 0.0149021 -140CE2 G KC=0.01234 18$LC=0.00202 3$MC=4.29E-4 6 -140CE G 751.653 7 4.39 5 M1+E2 0.38 4 0.005489 -140CE2 G KC=0.00471 8$LC=6.13E-4 10$MC=1277E-7 20 -140CE G 2347.847 140.845 16E2 3.86E-45 -140CE2 G KC=3.33E-4 5$LC=4.15E-5 6$MC=8.60E-6 12 +140CE G 444.57 4 0.003 1[E2] 0.0149021 +140CE2 G KC=0.01234 18$LC=0.00202 3$MC=4.29E-4 6 +140CE G 751.653 7 4.39 5M1+E2 0.38 4 0.00548 9 +140CE2 G KC=0.00471 8$LC=6.13E-4 10$MC=1277E-7 20 +140CE G 2347.847 140.845 16E2 3.86E-4 5 +140CE2 G KC=3.33E-4 5$LC=4.15E-5 6$MC=8.60E-6 12 140CE L 2349.789 145+ 140CE B 1411.1 180.262 22 10.7 1U 140CES B EAV=518.8 8 140CE G 241.959 6 0.436 10M1+E2 0.60 35 0.1005 18 -140CE2 G KC=0.084 3$LC=0.0130 11$MC=0.00275 25 -140CE G 266.554 5 0.492 9 M1+E2 0.14 12 0.0785 12 -140CE2 G KC=0.0671 11$LC=0.00906 17$MC=0.00190 4 +140CE2 G KC=0.084 3$LC=0.0130 11$MC=0.00275 25 +140CE G 266.554 5 0.492 9M1+E2 0.14 12 0.0785 12 +140CE2 G KC=0.0671 11$LC=0.00906 17$MC=0.00190 4 140CE L 2411.997 143+ 55 PS 15 -140CE B 1348.9 1844.8 4 7.6 +140CE B 1348.9 1844.8 4 7.6 140CES B EAV=487.6 8 -140CE G 64.129 4 0.014 2 M1 4.24 6 -140CE2 G KC=3.61 5$LC=0.499 7$MC=0.1046 15 -140CE G 328.761 4 20.8 3 M1+E2 0.049 6 0.0453 7 -140CE2 G KC=0.0388 6$LC=0.00516 8$MC=1078E-6 15 -140CE G 815.784 6 23.72 20M1+E2 0.03 1 0.004717 -140CE2 G KC=0.00405 6$LC=5.21E-4 8$MC=1085E-7 16 +140CE G 64.129 4 0.014 2M1 4.24 6 +140CE2 G KC=3.61 5$LC=0.499 7$MC=0.1046 15 +140CE G 328.761 4 20.8 3M1+E2 0.049 6 0.0453 7 +140CE2 G KC=0.0388 6$LC=0.00516 8$MC=1078E-6 15 +140CE G 815.784 6 23.72 20M1+E2 0.03 1 0.00471 7 +140CE2 G KC=0.00405 6$LC=5.21E-4 8$MC=1085E-7 16 140CE L 2464.055 213- 0.10 PS 2 -140CE B 1296.8 185.60 7 8.44 +140CE B 1296.8 185.60 7 8.44 140CES B EAV=465.6 8 -140CE G 867.839 165.58 7 E1+M2 0.044 20 0.001133 -140CE2 G KC=9.77E-4 22$LC=1.22E-4 3$MC=2.53E-5 7 -140CE G 2464.031 200.0097 13[E3] 5.98E-48 -140CE2 G KC=5.15E-4 8$LC=6.61E-5 10$MC=1375E-8 20 +140CE G 867.839 165.58 7E1+M2 0.044 20 0.00113 3 +140CE2 G KC=9.77E-4 22$LC=1.22E-4 3$MC=2.53E-5 7 +140CE G 2464.031 200.0097 13[E3] 5.98E-4 8 +140CE2 G KC=5.15E-4 8$LC=6.61E-5 10$MC=1375E-8 20 140CE L 2480.910 144+ 3.2 NS 3 -140CE B 1280.0 181.14 2 9.1 1 +140CE B 1280.0 181.14 2 9.1 1 140CES B EAV=458.4 8 -140CE G 68.923 5 0.077 2 M1 3.44 5 -140CE2 G KC=2.93 5$LC=0.405 6$MC=0.0848 12 -140CE G 131.121 4 0.47 1 M1+E2 0.13 5 0.552 9 -140CE2 G KC=0.468 7$LC=0.0660 22$MC=0.0139 5 -140CE G 397.674 6 0.075 3 (E2) 0.0205 3 -140CE2 G KC=0.01689 24$LC=0.00288 4$MC=6.15E-4 9 +140CE G 68.923 5 0.077 2M1 3.44 5 +140CE2 G KC=2.93 5$LC=0.405 6$MC=0.0848 12 +140CE G 131.121 4 0.47 1M1+E2 0.13 5 0.552 9 +140CE2 G KC=0.468 7$LC=0.0660 22$MC=0.0139 5 +140CE G 397.674 6 0.075 3(E2) 0.0205 3 +140CE2 G KC=0.01689 24$LC=0.00288 4$MC=6.15E-4 9 140CE L 2515.749 163+ -140CE B 1245.2 185.80 4 8.4 +140CE B 1245.2 185.80 4 8.4 140CES B EAV=443.8 8 -140CE G 432.513 8 3.00 3 M1+E2 0.54 5 0.0210 4 -140CE2 G KC=0.0179 4$LC=0.00245 4$MC=5.14E-4 8 -140CE G 919.533 102.73 3 M1+E2 2.6 4 0.002576 -140CE2 G KC=0.00219 6$LC=2.95E-4 7$MC=6.16E-5 13 +140CE G 432.513 8 3.00 3M1+E2 0.54 5 0.0210 4 +140CE2 G KC=0.0179 4$LC=0.00245 4$MC=5.14E-4 8 +140CE G 919.533 102.73 3M1+E2 2.6 4 0.00257 6 +140CE2 G KC=0.00219 6$LC=2.95E-4 7$MC=6.16E-5 13 140CE L 2521.414 142+ -140CE B 1239.5 1811.11 9 8.1 1 +140CE B 1239.5 1811.11 9 8.1 1 140CES B EAV=441.4 8 -140CE G 109.417 4 0.217 6 M1+E2 0.26 2 0.949 15 -140CE2 G KC=0.787 12$LC=0.128 4$MC=0.0271 8 -140CE G 173.546 5 0.126 5 M1 0.251 4 -140CE2 G KC=0.214 3$LC=0.0291 4$MC=0.00609 9 -140CE G 438.178 6 0.017 10M1 0.0217 3 -140CE2 G KC=0.0186 3$LC=0.00244 4$MC=5.10E-4 8 -140CE G 618.12 4 0.041 3 [E2] 0.006179 -140CE2 G KC=0.00520 8$LC=7.68E-4 11$MC=1619E-7 23 -140CE G 925.198 7 7.04 7 M1+E2 0.22 4 0.003446 -140CE2 G KC=0.00296 5$LC=3.81E-4 6$MC=7.92E-5 12 -140CE G 2521.390 143.41 5 E2 3.40E-45 -140CE2 G KC=2.94E-4 5$LC=3.65E-5 6$MC=7.56E-6 11 +140CE G 109.417 4 0.217 6M1+E2 0.26 2 0.949 15 +140CE2 G KC=0.787 12$LC=0.128 4$MC=0.0271 8 +140CE G 173.546 5 0.126 5M1 0.251 4 +140CE2 G KC=0.214 3$LC=0.0291 4$MC=0.00609 9 +140CE G 438.178 6 0.017 10M1 0.0217 3 +140CE2 G KC=0.0186 3$LC=0.00244 4$MC=5.10E-4 8 +140CE G 618.12 4 0.041 3[E2] 0.00617 9 +140CE2 G KC=0.00520 8$LC=7.68E-4 11$MC=1619E-7 23 +140CE G 925.198 7 7.04 7M1+E2 0.22 4 0.00344 6 +140CE2 G KC=0.00296 5$LC=3.81E-4 6$MC=7.92E-5 12 +140CE G 2521.390 143.41 5E2 3.40E-4 5 +140CE2 G KC=2.94E-4 5$LC=3.65E-5 6$MC=7.56E-6 11 140CE L 2547.205 231+ -140CE B 1213.7 180.636 7 10 1U +140CE B 1213.7 180.636 7 10 1U 140CES B EAV=438.4 7 -140CE G 950.988 200.531 7 M1+E2 0.01 7 0.003285 -140CE2 G KC=0.00282 4$LC=3.61E-4 5$MC=7.52E-5 11 -140CE G 2547.180 230.102 2 M1 3.70E-45 -140CE2 G KC=3.20E-4 5$LC=3.98E-5 6$MC=8.24E-6 12 +140CE G 950.988 200.531 7M1+E2 0.01 7 0.00328 5 +140CE2 G KC=0.00282 4$LC=3.61E-4 5$MC=7.52E-5 11 +140CE G 2547.180 230.102 2M1 3.70E-4 5 +140CE2 G KC=3.20E-4 5$LC=3.98E-5 6$MC=8.24E-6 12 140CE L 2899.56 7 2+ -140CE B 861.2 180.112 6 9.5 1 +140CE B 861.2 180.112 6 9.5 1 140CES B EAV=287.3 7 -140CE G 1303.34 7 0.045 6 [M1+E2+] 0.0014 2 -140CE2 G KC=0.0012 2$LC=0.00015 2$MC=3.2E-5 5 -140CE G 2899.53 7 0.066 1 E2 2.66E-44 -140CE2 G KC=2.31E-4 4$LC=2.84E-5 4$MC=5.88E-6 9 +140CE G 1303.34 7 0.045 6[M1+E2+] 0.0014 2 +140CE2 G KC=0.0012 2$LC=0.00015 2$MC=3.2E-5 5 +140CE G 2899.53 7 0.066 1E2 2.66E-4 4 +140CE2 G KC=2.31E-4 4$LC=2.84E-5 4$MC=5.88E-6 9 140CE L 3000.88 9 2+ -140CE B 760.0 180.085 9 9.4 1 +140CE B 760.0 180.085 9 9.4 1 140CES B EAV=248.0 7 -140CE G 1097.58 9 0.023 5 [E2] 1658E-624 -140CE2 G KC=0.00142 2$LC=1.88E-4 3$MC=3.92E-5 6 -140CE G 1404.66 9 0.062 8 [M1+E2] 0.0011715 -140CE2 G KC=0.00101 15$LC=1.29E-4 18$MC=2.7E-5 4 +140CE G 1097.58 9 0.023 5[E2] 1658E-624 +140CE2 G KC=0.00142 2$LC=1.88E-4 3$MC=3.92E-5 6 +140CE G 1404.66 9 0.062 8[M1+E2] 0.0011715 +140CE2 G KC=0.00101 15$LC=1.29E-4 18$MC=2.7E-5 4 140CE L 3118.53 102+ -140CE B 642.5 180.027 1 9.6 1 +140CE B 642.5 180.027 1 9.6 1 140CES B EAV=203.7 7 -140CE G 3118.49 100.026 1 (E2) 2.34E-43 -140CE2 G KC=2.04E-4 3$LC=2.50E-5 4$MC=5.18E-6 8 +140CE G 3118.49 100.026 1(E2) 2.34E-4 3 +140CE2 G KC=2.04E-4 3$LC=2.50E-5 4$MC=5.18E-6 8 140CE L 3319.56 242+ -140CE B 441.3 180.0039 3 9.9 1 +140CE B 441.3 180.0039 3 9.9 1 140CES B EAV=132.0 6 -140CE G 3319.52 240.0039 3 E2 2.11E-43 -140CE2 G KC=1.83E-4 3$LC=2.25E-5 4$MC=4.64E-6 7 +140CE G 3319.52 240.0039 3E2 2.11E-4 3 +140CE2 G KC=1.83E-4 3$LC=2.25E-5 4$MC=4.64E-6 7 140CE L 3394.82 9 4- -140CE B 366.1 180.020 4 9 +140CE B 366.1 180.020 4 9 140CES B EAV=106.7 6 -140CE G 1045.02 9 0.020 4 [E1] 7.81E-411 +140CE G 1045.02 9 0.020 4[E1] 7.81E-411 140CE2 G KC=6.75E-4 10$LC=8.37E-5 12$MC=1733E-8 25 140CE L 3473.55 183- -140CE B 287.4 180.052 7 8.2 +140CE B 287.4 180.052 7 8.2 140CES B EAV=81.4 6 -140CE G 992.64 180.010 3 [E1] 8.60E-412 -140CE2 G KC=7.43E-4 11$LC=9.24E-5 13$MC=1.91E-5 3 -140CE G 1877.33 180.041 6 [E1] 2.84E-44 -140CE2 G KC=2.45E-4 4$LC=3.00E-5 5$MC=6.21E-6 9 +140CE G 992.64 180.010 3[E1] 8.60E-412 +140CE2 G KC=7.43E-4 11$LC=9.24E-5 13$MC=1.91E-5 3 +140CE G 1877.33 180.041 6[E1] 2.84E-4 4 +140CE2 G KC=2.45E-4 4$LC=3.00E-5 5$MC=6.21E-6 9 140CE L 3520.8 2 4+ -140CE B 240.1 180.011 3 8.6 1 +140CE B 240.1 180.011 3 8.6 1 140CES B EAV=66.7 6 -140CE G 1924.5 2 0.011 3 [E2] 5.54E-48 -140CE2 G KC=4.78E-4 7$LC=6.01E-5 9$MC=1247E-8 18 +140CE G 1924.5 2 0.011 3[E2] 5.54E-4 8 +140CE2 G KC=4.78E-4 7$LC=6.01E-5 9$MC=1247E-8 18 diff --git a/HEN_HOUSE/spectra/lnhb/Lu-177.txt b/HEN_HOUSE/spectra/lnhb/Lu-177.txt index 591be9c38..23db7959a 100644 --- a/HEN_HOUSE/spectra/lnhb/Lu-177.txt +++ b/HEN_HOUSE/spectra/lnhb/Lu-177.txt @@ -1,53 +1,53 @@ 177HF 177LU B- DECAY (6.647 D) -177HF T Auger electrons and ^X ray energies and emission intensities: -177HF T {U Energy (keV)} {U Intensity } {U Line } +177HF T Auger electrons and X ray energies and emission intensities: +177HF T {U Energy (keV)} {U Intensity} {U Line} 177HF T -177HF T 54.612 1.59 3 XKA2 -177HF T 55.7909 2.78 6 XKA1 +177HF T 54.612 1.59 3 XKA2 +177HF T 55.7909 2.78 6 XKA1 177HF T -177HF T 62.985 |] XKB3 -177HF T 63.234 |] 0.917 23 XKB1 -177HF T 63.662 |] XKB5II +177HF T 62.985 |] XKB3 +177HF T 63.234 |] 0.917 23 XKB1 +177HF T 63.662 |] XKB5II 177HF T -177HF T 64.942 |] XKB2 -177HF T 65.132 |] 0.245 8 XKB4 -177HF T 65.316 |] XKO23 +177HF T 64.942 |] XKB2 +177HF T 65.132 |] 0.245 8 XKB4 +177HF T 65.316 |] XKO23 177HF T -177HF T 6.96-10.89 3.18 6 XL (total) -177HF T 6.96 0.0613 16 XLL -177HF T 7.844-7.899 1.35 3 XLA -177HF T 8.139 0.031 9 XLC -177HF T 8.905-9.342 1.49 5 XLB -177HF T 10.516-10.89 0.254 7 XLG +177HF T 6.96-10.89 3.18 6 XL (total) +177HF T 6.96 0.0613 16 XLL +177HF T 7.844-7.899 1.35 3 XLA +177HF T 8.139 0.031 9 XLC +177HF T 8.905-9.342 1.49 5 XLB +177HF T 10.516-10.89 0.254 7 XLG 177HF T -177HF T 42.601-46.007 |] KLL AUGER -177HF T 51.391-55.784 |] 0.28 9 ^KLX AUGER -177HF T 60.15-65.34 |] KXY AUGER -177HF T 4.3-11.2 8.75 20 L AUGER +177HF T 42.601-46.007 |] KLL AUGER +177HF T 51.391-55.784 |] 0.28 9 KLX AUGER +177HF T 60.15-65.34 |] KXY AUGER +177HF T 4.3-11.2 8.75 20 L AUGER 177LU P 0.0 7/2+ 6.647 D 4 498.3 8 177HF N 1.0 1.0 1 1.0 177HF L 0 7/2- STABLE -177HF B 498.3 8 79.3 5 6.7 +177HF B 498.3 8 79.3 5 6.7 177HFS B EAV=149.4 3 177HF L 112.9499 9/2- 0.506 NS -177HF B 385.4 8 9.1 5 7.3 1U +177HF B 385.4 8 9.1 5 7.3 1 177HFS B EAV=111.7 3 -177HF G 112.9498 4 6.20 7 M1+E2 2.272 5 -177HF2 G KC=0.817 12$LC=1.104 6$MC=0.2755 14 +177HF G 112.9498 4 6.20 7M1+E2 2.272 5 +177HF2 G KC=0.817 12$LC=1.104 6$MC=0.2755 14 177HF L 249.6744 11/2- 105 PS -177HF B 248.6 8 0.012 8 9.2 3U +177HF B 248.6 8 0.012 8 9.2 1U 177HFS B EAV=78.6 3 -177HF G 136.7245 5 0.0470 7 M1+E2 1.158 18 -177HF2 G KC=0.559 21$LC=0.456 7$MC=0.1129 21 -177HF G 249.6742 6 0.2012 21E2 0.141000 -177HF2 G KC=9100E-5 0$LC=3800E-5 0$MC=9000E-6 0 +177HF G 136.7245 5 0.0470 7M1+E2 1.158 18 +177HF2 G KC=0.559 21$LC=0.456 7$MC=0.1129 21 +177HF G 249.6742 6 0.2012 21E2 0.141 +177HF2 G KC=0.091 $LC=0.038 $MC=0.009 177HF L 321.3162 9/2+ 0.663 NS -177HF B 177.0 8 11.64 10 6.1 2 +177HF B 177.0 8 11.64 10 6.1 177HFS B EAV=47.66 23 177HF G 71.6418 6 0.1726 23E1+M2 0.894 22 -177HF2 G KC=0.715 14$LC=0.138 6$MC=0.0317 14 -177HF G 208.3662 4 10.38 7 E1+M2 0.068 5 -177HF2 G KC=0.055 4$LC=0.0094 10$MC=0.00216 24 -177HF G 321.3159 6 0.216 8 E1+M2 0.08 6 -177HF2 G KC=0.06 5$LC=0.012 10$MC=0.0028 22 +177HF2 G KC=0.715 14$LC=0.138 6$MC=0.0317 14 +177HF G 208.3662 4 10.38 7E1+M2 0.068 5 +177HF2 G KC=0.055 4$LC=0.0094 10$MC=0.00216 24 +177HF G 321.3159 6 0.216 8E1+M2 0.08 6 +177HF2 G KC=0.06 5$LC=0.012 10$MC=0.0028 22 diff --git a/HEN_HOUSE/spectra/lnhb/Mn-54.txt b/HEN_HOUSE/spectra/lnhb/Mn-54.txt index f2d4d3834..ae1a6a38e 100644 --- a/HEN_HOUSE/spectra/lnhb/Mn-54.txt +++ b/HEN_HOUSE/spectra/lnhb/Mn-54.txt @@ -12,35 +12,35 @@ 54CR5C 1982HoZJ, 1982RuZV, 1989Su08, 1992Un01, 1993Da20, 1996Du15, 1997Ma75, 54CR6C 1998Si17, 2000Hu20, 2002Ba85, 2002Un02, 2004BeZR, 2006Hu08, 2006Da20, 54CR7C 2008Ki07, 2010Va13, 2012Wa38, 2012Fi12, 2014Un01 - 54CR T Auger electrons and ^X ray energies and emission intensities: - 54CR T {U Energy (keV)} {U Intensity } {U Line } + 54CR T Auger electrons and X ray energies and emission intensities: + 54CR T {U Energy (keV)} {U Intensity} {U Line} 54CR T - 54CR T 5.40557 7.65 14 XKA2 - 54CR T 5.41479 15.02 27 XKA1 + 54CR T 5.40557 7.65 14 XKA2 + 54CR T 5.41479 15.02 27 XKA1 54CR T - 54CR T 5.94677 |] 3.05 7 XKB1 - 54CR T 5.987 |] XKB5II + 54CR T 5.94677 |] 3.05 7 XKB1 + 54CR T 5.987 |] XKB5II 54CR T 54CR T - 54CR T 0.5003-0.69748 0.65 13 XL (total) + 54CR T 0.5003-0.69748 0.65 13 XL (total) 54CR T 0.5003 XLL 54CR T 0.5729-0.57695 XLA 54CR T 0.5102 XLC 54CR T 0.57515-0.69748 XLB 54CR T 0.58496-0.58496 XLG 54CR T - 54CR T 4.554-4.794 |] KLL AUGER - 54CR T 5.206-5.412 |] 63.3 5 ^KLX AUGER - 54CR T 5.841-5.985 |] KXY AUGER - 54CR T 0.4-0.7 143.0 6 L AUGER + 54CR T 4.554-4.794 |] KLL AUGER + 54CR T 5.206-5.412 |] 63.3 5 KLX AUGER + 54CR T 5.841-5.985 |] KXY AUGER + 54CR T 0.4-0.7 143.0 6 L AUGER 54MN P 0.0 3+ 312.19 D 3 1377.2 10 54CR N 1.0 1.0 1 1.0 54CR L 0 0+ STABLE - 54CR E 5.7E-7 0.0003 3 13.9 2U + 54CR E 5.7E-7 0.0003 313.9 2U 54CR2 E EAV=182 $CK=0.8908 16$CL=0.0938 13$CM=0.0148 6$CN=0.0005 2$CO=0 0 54CR L 834.855 3 2+ 0.0079 NS 3 - 54CR E 99.9997 3 6.17 - 54CR2 E EAV= $CK=0.8896 17$CL=0.0948 14$CM=0.0150 6$CN=0.0005 2$CO=0 0 - 54CR G 834.848 3 99.9752 5 E2 2.45E-44 - 54CR2 G KC=2.22E-4 4$LC=2.06E-5 3$MC=2.71E-6 4 + 54CR E 99.9997 36.17 + 54CR2 E CK=0.8896 17$CL=0.0948 14$CM=0.0150 6$CN=0.0005 2$CO=0 0 + 54CR G 834.848 3 99.9752 5E2 2.45E-4 4 + 54CR2 G KC=2.22E-4 4$LC=2.06E-5 3$MC=2.71E-6 4 diff --git a/HEN_HOUSE/spectra/lnhb/Mn-56.txt b/HEN_HOUSE/spectra/lnhb/Mn-56.txt index 5325d233c..bf2c6ba82 100644 --- a/HEN_HOUSE/spectra/lnhb/Mn-56.txt +++ b/HEN_HOUSE/spectra/lnhb/Mn-56.txt @@ -1,55 +1,55 @@ 56FE 56MN B- DECAY (2.57878 H) - 56FE T Auger electrons and ^X ray energies and emission intensities: - 56FE T {U Energy (keV)} {U Intensity } {U Line } + 56FE T Auger electrons and X ray energies and emission intensities: + 56FE T {U Energy (keV)} {U Intensity} {U Line} 56FE T - 56FE T 6.39091 0.00295 4 XKA2 - 56FE T 6.40391 0.00578 7 XKA1 + 56FE T 6.39091 0.00295 4 XKA2 + 56FE T 6.40391 0.00578 7 XKA1 56FE T - 56FE T 7.05804 |] 0.00119 2 XKB1 - 56FE T 7.1083 |] XKB5II + 56FE T 7.05804 |] 0.00119 2 XKB1 + 56FE T 7.1083 |] XKB5II 56FE T 56FE T 56FE T - 56FE T 5.37-5.645 |] KLL AUGER - 56FE T 6.158-6.4 |] 0.0180 1 ^KLX AUGER - 56FE T 6.926-7.105 |] KXY AUGER - 56FE T 0.51-0.594 0.0428 3 L AUGER + 56FE T 5.37-5.645 |] KLL AUGER + 56FE T 6.158-6.4 |] 0.0180 1 KLX AUGER + 56FE T 6.926-7.105 |] KXY AUGER + 56FE T 0.51-0.594 0.0428 3 L AUGER 56MN P 0.0 3+ 2.57878 H 46 3695.5 3 56FE N 1.0 1.0 1 1.0 56FE L 0 0+ STABLE 56FE L 846.776 5 2+ 6.07 PS - 56FE B 2848.7 3 56.6 7 7.101 + 56FE B 2848.7 3 56.6 7 7.101 56FES B EAV=1216.8 2 - 56FE G 846.7638 1998.85 3 E2 3.00E-49 - 56FE2 G KC=2.70E-4 8$LC=2.50E-5 8$MC=3.7E-6 1 + 56FE G 846.7638 1998.85 3E2 3.00E-4 9 + 56FE2 G KC=2.70E-4 8$LC=2.50E-5 8$MC=3.7E-6 1 56FE L 2085.076 7 4+ - 56FE B 1610.4 3 0.057 6 9.06 + 56FE B 1610.4 3 0.057 6 9.06 56FES B EAV=636.3 2 - 56FE G 1238.2736 220.097 2 E2 1.20E-44 - 56FE2 G KC=1.10E-4 3$LC=1.00E-5 3$MC=2.00E-6 6 + 56FE G 1238.2736 220.097 2E2 1.20E-4 4 + 56FE2 G KC=1.10E-4 3$LC=1.00E-5 3$MC=2.00E-6 6 56FE L 2657.562 102+ - 56FE B 1037.9 3 27.5 4 5.621 + 56FE B 1037.9 3 27.5 4 5.621 56FES B EAV=381.9 2 - 56FE G 1810.726 4 26.9 4 M1+E2 -0.18 1 5.10E-515 - 56FE2 G KC=4.60E-5 14$LC=4.30E-6 13$MC=6.3E-7 2 - 56FE G 2657.56 1 0.645 7 E2 + 56FE G 1810.7260 4026.9 4M1+E2 -0.18 1 5.10E-515 + 56FE2 G KC=4.60E-5 14$LC=4.30E-6 13$MC=6.3E-7 2 + 56FE G 2657.56 1 0.645 7E2 56FE L 2959.923 102+ - 56FE B 735.6 3 14.5 3 5.34 + 56FE B 735.6 3 14.5 3 5.34 56FES B EAV=255.2 2 - 56FE G 2113.092 6 14.2 3 M1+E2 - 56FE G 2959.92 1 0.307 5 E2 + 56FE G 2113.092 6 14.2 3M1+E2 + 56FE G 2959.92 1 0.307 5E2 56FE L 3122.927 7 4+ - 56FE B 572.6 3 0.040 4 7.5 + 56FE B 572.6 3 0.040 4 7.5 56FES B EAV=190.4 2 - 56FE G 1037.8333 240.040 4 M1+E2 0.02 1 1500E-745 - 56FE2 G KC=1.30E-4 4$LC=1.20E-5 4$MC=6.0E-6 2 + 56FE G 1037.8333 240.040 4M1+E2 0.02 1 1500E-745 + 56FE2 G KC=1.30E-4 4$LC=1.20E-5 4$MC=6.0E-6 2 56FE L 3369.84 4 2+ - 56FE B 325.7 3 1.20 3 5.17 + 56FE B 325.7 3 1.20 3 5.17 56FES B EAV=99.1 1 - 56FE G 2523.06 5 1.02 2 M1+E2 - 56FE G 3369.84 4 0.17 1 E2 + 56FE G 2523.06 5 1.02 2M1+E2 + 56FE G 3369.84 4 0.17 1E2 56FE L 3445.306 203+ - 56FE B 250.2 3 0.020 2 6.57 + 56FE B 250.2 3 0.020 2 6.57 56FES B EAV=73.5 1 - 56FE G 2598.438 4 0.020 2 M1+E2 + 56FE G 2598.438 4 0.020 2M1+E2 diff --git a/HEN_HOUSE/spectra/lnhb/Mo-99.txt b/HEN_HOUSE/spectra/lnhb/Mo-99.txt index 870decfcc..101248770 100644 --- a/HEN_HOUSE/spectra/lnhb/Mo-99.txt +++ b/HEN_HOUSE/spectra/lnhb/Mo-99.txt @@ -4,117 +4,115 @@ 99TC C Evaluation history: Type=update;Author=mmbe;Cutoff date= -- 99TC2C Type=update;Author=mmbe;Cutoff date= -- 99TC C References: 1977La19 - 99TC T Auger electrons and ^X ray energies and emission intensities: - 99TC T {U Energy (keV)} {U Intensity } {U Line } + 99TC T Auger electrons and X ray energies and emission intensities: + 99TC T {U Energy (keV)} {U Intensity} {U Line} 99TC T - 99TC T 18.251 3.19 9 XKA2 - 99TC T 18.3672 6.06 16 XKA1 + 99TC T 18.251 3.19 9 XKA2 + 99TC T 18.3672 6.06 16 XKA1 99TC T - 99TC T 20.599 |] XKB3 - 99TC T 20.619 |] 1.61 5 XKB1 - 99TC T 20.789 |] XKB5II + 99TC T 20.599 |] XKB3 + 99TC T 20.619 |] 1.61 5 XKB1 + 99TC T 20.789 |] XKB5II 99TC T - 99TC T 21.005 |] XKB2 - 99TC T 21.042 |] 0.254 11 XKB4 + 99TC T 21.005 |] XKB2 + 99TC T 21.042 |] 0.254 11 XKB4 99TC T - 99TC T 2.424-2.537 0.697 17 XL (total) - 99TC T 2.424- 0.430 13 XLA - 99TC T 2.537- 0.231 7 XLB + 99TC T 2.424-2.537 0.697 17 XL (total) + 99TC T 2.424- 0.430 13 XLA + 99TC T 2.537- 0.231 7 XLB 99TC T - 99TC T 14.858-15.582 |] KLL AUGER - 99TC T 17.418-18.365 |] 3.1 1 ^KLX AUGER - 99TC T 19.956-21.04 |] KXY AUGER - 99TC T 1.6-3.04 15.87 26 L AUGER + 99TC T 14.858-15.582 |] KLL AUGER + 99TC T 17.418-18.365 |] 3.1 1 KLX AUGER + 99TC T 19.956-21.04 |] KXY AUGER + 99TC T 1.6-3.04 15.87 26 L AUGER 99MO P 0.0 1/2+ 2.7479 D 6 1357.2 10 99TC N 1.0 1.0 1 1.0 99TC L 0 9/2+ 211.5E3 Y 11 99TC L 140.5106 7/2+ 0.221 NS 20 - 99TC G 140.511 1 89.6 17M1+()E2 0.186 8 0.119 3 - 99TC2 G KC=0.104 3$LC=0.0129 4$MC=0.00236 7 + 99TC G 140.511 1 89.6 17M1+()E2 0.186 8 0.119 3 + 99TC2 G KC=0.104 3$LC=0.0129 4$MC=0.00236 7 99TC L 142.6832 1/2- 6.0067 H 10 99TC B 1214.5 1082.1 15 7.1 99TCS B EAV=442.7 3 - 99TC G 2.1726 4 700E-11 0 E3 135E8 4 - 99TC2 G KC=$LC=$MC=119E8 3 - 99TC G 142.675 250.0211 17M4 40.9 8 - 99TC2 G KC=29.3 6$LC=9.35 20$MC=1.86 6 + 99TC G 2.1726 4 7E-9 E3 135E8 4 + 99TC2 G MC=119E8 3 + 99TC G 142.675 250.0211 17M4 40.9 8 + 99TC2 G KC=29.3 6$LC=9.35 20$MC=1.86 6 99TC L 181.0939 5/2+ 3.61 NS 7 99TC G 40.58323 171.022 27M1+()E2 -0.119 8 4.18 13 - 99TC2 G KC=3.50 8$LC=0.560 13$MC=0.104 3 - 99TC G 181.068 8 6.01 11E2 0.149 3 - 99TC2 G KC=0.125 3$LC=0.0191 4$MC=0.00353 7 + 99TC2 G KC=3.50 8$LC=0.560 13$MC=0.104 3 + 99TC G 181.068 8 6.01 11E2 0.149 3 + 99TC2 G KC=0.125 3$LC=0.0191 4$MC=0.00353 7 99TC L 509.106 (3/2)- - 99TC B 848.1 101.18 3 8.38 1U + 99TC B 848.1 101.18 3 8.38 1 99TCS B EAV=289.7 3 99TC G 366.421 151.194 23M1 0.0091518 - 99TC2 G KC=0.00802 16$LC=0.00093 2$MC=1.70E-4 4 + 99TC2 G KC=0.00802 16$LC=0.00093 2$MC=1.70E-4 4 99TC L 534.41 (3/2)+ - 99TC B 822.8 100.0010 2 2 + 99TC B 822.8 100.0010 2 99TCS B EAV=279 2 - 99TC G 391.7 4 0.0025 6 + 99TC G 391.7 4 0.0025 6 99TC L 671.489 (3/2)- - 99TC B 685.7 100.052 5 9.46 1U + 99TC B 685.7 100.052 5 9.46 1 99TCS B EAV=225.4 4 - 99TC G 162.370 150.0114 6 - 99TC G 528.788 150.0541 19M1 0.003788 - 99TC2 G KC=0.00331 7$LC=3.79E-4 8$MC=6930E-8 14 + 99TC G 162.370 150.0114 6 + 99TC G 528.788 150.0541 19M1 0.00378 8 + 99TC2 G KC=0.00331 7$LC=3.79E-4 8$MC=6930E-8 14 99TC L 761.71 5/2+ - 99TC G 580.51 5 0.0036 4 + 99TC G 580.51 5 0.0036 4 99TC G 761.77 8 0.0023 13 99TC L 762.243 (3/2)+ - 99TC G 581.30 120.00010 5 - 99TC G 621.773 240.0262 10M1(+E2) 0.002588 - 99TC2 G KC=0.00227 5$LC=2.59E-4 8$MC=4.73E-5 14 + 99TC G 581.30 120.00010 5 + 99TC G 621.773 240.0262 10M1(+E2) 0.00258 8 + 99TC2 G KC=0.00227 5$LC=2.59E-4 8$MC=4.73E-5 14 99TC L 920.591 1/2+ 99TC B 436.6 1016.45 30 6.21 99TCS B EAV=133.0 3 - 99TC G 158.782 150.0145 9 - 99TC G 249.03 3 0.0035 4 - 99TC G 411.491 150.0161 12E1 3.5 0.002575 - 99TC2 G KC=0.00226 5$LC=2.56E-4 5$MC=4.67E-5 9 - 99TC G 739.500 1712.12 15E2+M1 0.001734 - 99TC2 G KC=0.00151 3$LC=1.78E-4 5$MC=3.2E-5 1 - 99TC G 777.921 204.28 8 E1 5.89E-412 - 99TC2 G KC=5.18E-4 10$LC=5.80E-5 12$MC=1057E-8 2 + 99TC G 158.782 150.0145 9 + 99TC G 249.03 3 0.0035 4 + 99TC G 411.491 150.0161 12E1 3.5 0.00257 5 + 99TC2 G KC=0.00226 5$LC=2.56E-4 5$MC=4.67E-5 9 + 99TC G 739.500 1712.12 15E2+M1 0.00173 4 + 99TC2 G KC=0.00151 3$LC=1.78E-4 5$MC=3.2E-5 1 + 99TC G 777.921 204.28 8E1 5.89E-412 + 99TC2 G KC=5.18E-4 10$LC=5.80E-5 12$MC=1057E-8 2 99TC L 1004.066 3/2- - 99TC B 353.1 100.134 5 7.97 1U + 99TC B 353.1 100.134 5 7.97 1 99TCS B EAV=104.3 3 - 99TC G 242.29 8 0.0014 3 (E1) 0.0106 2 - 99TC2 G KC=0.0093 2$LC=0.00106 2$MC=1.93E-4 6 + 99TC G 242.29 8 0.0014 3(E1) 0.0106 2 + 99TC2 G KC=0.0093 2$LC=0.00106 2$MC=1.93E-4 6 99TC G 822.972 150.1321 29E1 5.24E-411 - 99TC2 G KC=4.61E-4 9$LC=5.2E-5 1$MC=9.4E-6 2 - 99TC G 861.2 9 0.0007 2 + 99TC2 G KC=4.61E-4 9$LC=5.2E-5 1$MC=9.4E-6 2 + 99TC G 861.2 9 0.0007 2 99TC L 1072.2 (7/2)+ - 99TC B 285 1 0.0027 7 + 99TC B 285 1 0.0027 7 2U 99TCS B EAV=82 1 - 99TC G 537.79 150.0015 5 - 99TC G 1072.2 4 0.0012 5 + 99TC G 537.79 150.0015 5 + 99TC G 1072.2 4 0.0012 5 99TC L 1129.116 (1/2,3/2)- - 99TC B 228.1 100.011 1 8.5 + 99TC B 228.1 100.011 1 8.5 99TCS B EAV=69.3 3 - 99TC G 457.60 3 0.0074 6 M1+()E2 1.6 0.0063 7 - 99TC2 G KC=0.0054 4$LC=0.00066 5$MC=0.00012 1 - 99TC G 620.03 5 0.0024 6 - 99TC G 986.44 4 0.0014 1 + 99TC G 457.60 3 0.0074 6M1+()E2 1.6 0.0063 7 + 99TC2 G KC=0.0054 4$LC=0.00066 5$MC=0.00012 1 + 99TC G 620.03 5 0.0024 6 + 99TC G 986.44 4 0.0014 1 99TC L 1141.871 3/2+ - 99TC B 215.3 100.111 3 7.39 2 + 99TC B 215.3 100.111 3 7.39 99TCS B EAV=59.8 3 - 99TC G 380.13 8 0.0091 5 M1+()E2 1.3 6 0.0105 8 - 99TC2 G KC=0.0091 7$LC=0.00113 8$MC=0.00021 2 - 99TC G 469.63 7 0.0027 5 - 99TC G 960.754 200.095 3 (M1) 0.0010 1 - 99TC2 G KC=$LC=$MC= - 99TC G 1001.343 180.0043 4 (E2) 0.0008 1 - 99TC2 G KC=$LC=$MC= + 99TC G 380.13 8 0.0091 5M1+()E2 1.3 6 0.0105 8 + 99TC2 G KC=0.0091 7$LC=0.00113 8$MC=0.00021 2 + 99TC G 469.63 7 0.0027 5 + 99TC G 960.754 200.095 3(M1) 0.0010 1 + 99TC G 1001.343 180.0043 4(E2) 0.0008 1 99TC L 1171.98 3/2+ - 99TC B 185.2 100.0016 4 8.91 2 + 99TC B 185.2 100.0016 4 8.91 99TCS B EAV=51.0 4 - 99TC G 410.27 100.0016 4 M1+()E2 0.5 0.0074 3 - 99TC2 G KC=0.0065 2$LC=$MC=0.00014 1 + 99TC G 410.27 100.0016 4M1+()E2 0.5 0.0074 3 + 99TC2 G KC=0.0065 2$LC=$MC=0.00014 1 99TC L 1198.88 (3/2)+ - 99TC B 158.3 100.0021 3 8.65 2 + 99TC B 158.3 100.0021 3 8.65 99TCS B EAV=43.3 4 99TC G 689.6 9 0.00042 18 - 99TC G 1017.0 5 0.0007 2 - 99TC G 1056.20 5 0.00103 9 + 99TC G 1017.0 5 0.0007 2 + 99TC G 1056.20 5 0.00103 9 diff --git a/HEN_HOUSE/spectra/lnhb/N-13.txt b/HEN_HOUSE/spectra/lnhb/N-13.txt index 7384be865..4852f932b 100644 --- a/HEN_HOUSE/spectra/lnhb/N-13.txt +++ b/HEN_HOUSE/spectra/lnhb/N-13.txt @@ -3,5 +3,5 @@ 13C N 1.0 1.0 1 1.0 13C L 0 1/2- STABLE 13C E 99.818 130.182 12 - 13C 2 E EAV=493.0 2$CK=0.923 7$CL=0.078 7$CM= $CN= $CO=0 0 + 13C 2 E EAV=493.0 2$CK=0.923 7$CL=0.078 7$CO=0 0 diff --git a/HEN_HOUSE/spectra/lnhb/Na-22.txt b/HEN_HOUSE/spectra/lnhb/Na-22.txt index 8ad9ee14a..d200a6dcd 100644 --- a/HEN_HOUSE/spectra/lnhb/Na-22.txt +++ b/HEN_HOUSE/spectra/lnhb/Na-22.txt @@ -9,25 +9,25 @@ 22NE4C 1979SC31, 1980HO17, 1982RUZV, 1983BA41, 1985HAZA, 1990KU11, 1991BAZS, 22NE5C 1995SCZY, 1996SC06, 1999BeZS, 1999BeZQ, 2000HE14, 2002UN02, 2002BA85, 22NE6C 2004MU26, 2009NA08, 2008MU05 - 22NE T Auger electrons and ^X ray energies and emission intensities: - 22NE T {U Energy (keV)} {U Intensity } {U Line } + 22NE T Auger electrons and X ray energies and emission intensities: + 22NE T {U Energy (keV)} {U Intensity} {U Line} 22NE T - 22NE T 0.8486 0.0453 25 XKA2 - 22NE T 0.8486 0.090 5 XKA1 + 22NE T 0.8486 0.0453 25 XKA2 + 22NE T 0.8486 0.090 5 XKA1 22NE T 22NE T 22NE T 22NE T - 22NE T 0.75-0.81 |] KLL AUGER - 22NE T - |] 8.8 1 ^KLX AUGER + 22NE T 0.75-0.81 |] KLL AUGER + 22NE T - |] 8.8 1 KLX AUGER 22NA P 0.0 3+ 2.6029 Y 8 2843.02 21 22NE N 1.0 1.0 1 1.0 22NE L 0 0+ STABLE 22NE E 0.055 140.00098 2514.91 2U - 22NE2 E EAV=835.04 19$CK= $CL= $CM= $CN= $CO= + 22NE2 E EAV=835.04 19 22NE L 1274.577 7 2+ 0.00524 NS7 - 22NE E 90.30 9 9.64 9 7.41 - 22NE2 E EAV=215.62 17$CK=0.923 4$CL=0.077 4$CM= $CN= $CO= - 22NE G 1274.537 7 99.94 13E2 6.71E-69 - 22NE2 G KC=6.36E-6 9$LC=$MC= + 22NE E 90.30 99.64 97.41 + 22NE2 E EAV=215.62 17$CK=0.923 4$CL=0.077 4 + 22NE G 1274.537 7 99.94 13E2 6.71E-6 9 + 22NE2 G KC=6.36E-6 9 diff --git a/HEN_HOUSE/spectra/lnhb/Na-24.txt b/HEN_HOUSE/spectra/lnhb/Na-24.txt index 84c2e1472..fc5648236 100644 --- a/HEN_HOUSE/spectra/lnhb/Na-24.txt +++ b/HEN_HOUSE/spectra/lnhb/Na-24.txt @@ -11,45 +11,45 @@ 24MG4C 1982HoZJ, 1982RuZV, 1983Wa26, 1990En08, 1990En02, 1992Un01, 1998Si17, 24MG5C 2000He14, 2002Ba85, 2002Un02, 2003Ep02, 2004Un01, 2004BeZR, 2005Li66, 24MG6C 2007Fi14, 2008Ki07, 2012Wa38, 2012Fi12, 2014Un01 - 24MG T Auger electrons and ^X ray energies and emission intensities: - 24MG T {U Energy (keV)} {U Intensity } {U Line } + 24MG T Auger electrons and X ray energies and emission intensities: + 24MG T {U Energy (keV)} {U Intensity} {U Line} 24MG T - 24MG T 1.25361 0.0000113 4 XKA2 - 24MG T 1.25361 0.0000225 8 XKA1 + 24MG T 1.25361 1.13E-5 4 XKA2 + 24MG T 1.25361 2.25E-5 8 XKA1 24MG T - 24MG T 1.3022 |] 0.00000058 14 XKB1 + 24MG T 1.3022 |] 5.8E-7 14 XKB1 24MG T 24MG T 24MG T - 24MG T 1.102-1.182 |] KLL AUGER - 24MG T 1.214-1.252 |] 0.001148 14 ^KLX AUGER - 24MG T 1.301-1.301 |] KXY AUGER + 24MG T 1.102-1.182 |] KLL AUGER + 24MG T 1.214-1.252 |] 0.00114814 KLX AUGER + 24MG T 1.301-1.301 |] KXY AUGER 24NA P 0.0 4+ 14.958 H 2 5515.61 4 24MG N 1.0 1.0 1 1.0 - 24MG G 511 0.144 2 + 24MG G 511 0.144 2 24MG L 0 0 0+ STABLE 24MG L 1368.672 5 2+ 1.33 PS 6 - 24MG B 4146.94 4 0.003 2 12.7 2 + 24MG B 4146.94 4 0.003 2 12.7 2 24MGS B EAV=1866.70 2 - 24MG G 1368.630 5 99.9934 5 E2 9.91E-613 - 24MG2 G KC=9.29E-6 13$LC=5.97E-7 9$MC=2.21E-8 3 + 24MG G 1368.630 5 99.9934 5E2 9.91E-613 + 24MG2 G KC=9.29E-6 13$LC=5.97E-7 9$MC=2.21E-8 3 24MG L 4122.889 124+ 22 FS 2 - 24MG B 1392.72 4 99.930 3 6.12 + 24MG B 1392.72 4 99.930 3 6.12 24MGS B EAV=555.05 2 - 24MG G 2754.049 1399.862 3 E2 2.71E-64 - 24MG2 G KC=2.54E-6 4$LC=163E-9 2$MC=6.05E-9 9 + 24MG G 2754.049 1399.862 3E2 2.71E-6 4 + 24MG2 G KC=2.54E-6 4$LC=163E-9 2$MC=6.05E-9 9 24MG L 4238.24 3 2+ 41 FS 4 - 24MG B 1277.37 5 0.001 1 12.3 2 + 24MG B 1277.37 5 0.001 1 12.3 2 24MGS B EAV=503 - 24MG G 2869.38 3 0.00025 3 M1+E2 23 9 2.54E-66 - 24MG2 G KC=2.38E-6 4$LC=153E-9 2$MC=5.67E-9 8 - 24MG G 4237.84 3 0.00084 10E2 1.42E-62 - 24MG2 G KC=1330E-9 19$LC=8.53E-8 12$MC=3.16E-9 5 + 24MG G 2869.38 3 0.00025 3M1+E2 23 9 2.54E-6 6 + 24MG2 G KC=2.38E-6 4$LC=153E-9 2$MC=5.67E-9 8 + 24MG G 4237.84 3 0.00084 10E2 1.42E-6 2 + 24MG2 G KC=1330E-9 19$LC=8.53E-8 12$MC=3.16E-9 5 24MG L 5235.12 4 3+ 61 FS 7 - 24MG B 280.49 6 0.066 3 6.69 + 24MG B 280.49 6 0.066 3 6.69 24MGS B EAV=90.00 2 - 24MG G 996.86 5 0.00145 25M1+E2 5.1 12 2.05E-54 - 24MG2 G KC=1.92E-5 4$LC=1233E-9 20$MC=4.56E-8 8 - 24MG G 3866.12 4 0.066 2 M1+E2 17 4 1.62E-62 - 24MG2 G KC=1516E-9 22$LC=9.73E-8 14$MC=3.61E-9 5 + 24MG G 996.86 5 0.00145 25M1+E2 5.1 12 2.05E-5 4 + 24MG2 G KC=1.92E-5 4$LC=1233E-9 20$MC=4.56E-8 8 + 24MG G 3866.12 4 0.066 2M1+E2 17 4 1.62E-6 2 + 24MG2 G KC=1516E-9 22$LC=9.73E-8 14$MC=3.61E-9 5 diff --git a/HEN_HOUSE/spectra/lnhb/Nb-93m.txt b/HEN_HOUSE/spectra/lnhb/Nb-93m.txt index 5f6ba41e9..1cdde237b 100644 --- a/HEN_HOUSE/spectra/lnhb/Nb-93m.txt +++ b/HEN_HOUSE/spectra/lnhb/Nb-93m.txt @@ -8,34 +8,34 @@ 93NB3C 1980Va**, 1981Ll01, 1982Re09, 1982Al**, 1983Va25, 1985Ge**, 1987La**, 93NB4C 1990Co17, 1991BaZS, 1996Sc06, 1997Ba13, 1999ScZX, 1999ZhZY, 2000Sc47, 93NB5C 2008Ki07 - 93NB T Auger electrons and ^X ray energies and emission intensities: - 93NB T {U Energy (keV)} {U Intensity } {U Line } + 93NB T Auger electrons and X ray energies and emission intensities: + 93NB T {U Energy (keV)} {U Intensity} {U Line} 93NB T - 93NB T 16.5213 3.32 8 XKA2 - 93NB T 16.6152 6.34 15 XKA1 + 93NB T 16.5213 3.32 8 XKA2 + 93NB T 16.6152 6.34 15 XKA1 93NB T - 93NB T 18.607 |] XKB3 - 93NB T 18.623 |] 1.64 4 XKB1 - 93NB T 18.78 |] XKB5II + 93NB T 18.607 |] XKB3 + 93NB T 18.623 |] 1.64 4 XKB1 + 93NB T 18.78 |] XKB5II 93NB T - 93NB T 18.952 |] XKB2 - 93NB T 18.982 |] 0.246 11 XKB4 + 93NB T 18.952 |] XKB2 + 93NB T 18.982 |] 0.246 11 XKB4 93NB T - 93NB T 1.9-2.67 2.88 6 XL (total) - 93NB T 1.9 0.0870 23 XLL - 93NB T 2.16-2.17 2.32 6 XLA - 93NB T 2 0.00877 24 XLC - 93NB T 2.26-2.37 0.446 11 XLB - 93NB T 2.41-2.67 0.0236 4 XLG + 93NB T 1.9-2.67 2.88 6 XL (total) + 93NB T 1.9 0.0870 23 XLL + 93NB T 2.16-2.17 2.32 6 XLA + 93NB T 2 0.00877 24 XLC + 93NB T 2.26-2.37 0.446 11 XLB + 93NB T 2.41-2.67 0.0236 4 XLG 93NB T - 93NB T 13.49-14.14 |] KLL AUGER - 93NB T 15.79-16.58 |] 3.83 11 ^KLX AUGER - 93NB T 18.02-18.91 |] KXY AUGER - 93NB T 1.4-2.7 81.25 28 L AUGER + 93NB T 13.49-14.14 |] KLL AUGER + 93NB T 15.79-16.58 |] 3.83 11 KLX AUGER + 93NB T 18.02-18.91 |] KXY AUGER + 93NB T 1.4-2.7 81.25 28 L AUGER 93NB P 30.77 2 1/2- 16.12 Y 15 93NB N 1.0 1.0 1 1.0 93NB L 0 9/2+ STABLE 93NB L 30.77 2 1/2- 16.12 Y 15 - 93NB G 30.77 2 5.91E-4 9 M4 1.693E525 - 93NB2 G KC=2.60E4 4$LC=1.151E5 17$MC=2.49E4 4 + 93NB G 30.77 2 0.000591 9M4 1.693E525 + 93NB2 G KC=2.60E4 4$LC=1.151E5 17$MC=2.49E4 4 diff --git a/HEN_HOUSE/spectra/lnhb/Nb-95.txt b/HEN_HOUSE/spectra/lnhb/Nb-95.txt index 7d22c2a83..13245ac70 100644 --- a/HEN_HOUSE/spectra/lnhb/Nb-95.txt +++ b/HEN_HOUSE/spectra/lnhb/Nb-95.txt @@ -1,42 +1,42 @@ 95MO 95NB B- DECAY (34.991 D) 95MO H TYP=Full$AUT=R.G.Helmer$CUT= -- $ 95MO C Evaluation history: Type=Full;Author=R.G.Helmer;Cutoff date= -- - 95MO T Auger electrons and ^X ray energies and emission intensities: - 95MO T {U Energy (keV)} {U Intensity } {U Line } + 95MO T Auger electrons and X ray energies and emission intensities: + 95MO T {U Energy (keV)} {U Intensity} {U Line} 95MO T - 95MO T 17.3745 0.0286 9 XKA2 - 95MO T 17.4795 0.0546 18 XKA1 + 95MO T 17.3745 0.0286 9 XKA2 + 95MO T 17.4795 0.0546 18 XKA1 95MO T - 95MO T 19.5904 |] XKB3 - 95MO T 19.6085 |] 0.0143 5 XKB1 - 95MO T 19.774 |] XKB5II + 95MO T 19.5904 |] XKB3 + 95MO T 19.6085 |] 0.0143 5 XKB1 + 95MO T 19.774 |] XKB5II 95MO T - 95MO T 19.9653 |] XKB2 - 95MO T 19.998 |] 0.00221 11 XKB4 + 95MO T 19.9653 |] XKB2 + 95MO T 19.998 |] 0.00221 11 XKB4 95MO T - 95MO T 2.01-2.83 0.0055 9 XL (total) + 95MO T 2.01-2.83 0.0055 9 XL (total) 95MO T 2.01 XLL 95MO T -2.83 XLG 95MO T - 95MO T 14.268-14.96 |] KLL AUGER - 95MO T 16.628-17.476 |] 0.0303 11 ^KLX AUGER - 95MO T 18.99-19.99 |] KXY AUGER - 95MO T 1.856-2.86 0.143 4 L AUGER + 95MO T 14.268-14.96 |] KLL AUGER + 95MO T 16.628-17.476 |] 0.0303 11 KLX AUGER + 95MO T 18.99-19.99 |] KXY AUGER + 95MO T 1.856-2.86 0.143 4 L AUGER 95NB P 0.0 9/2+ 34.991 D 6 925.6 5 95MO N 1.0 1.0 1 1.0 95MO L 0 5/2+ STABLE - 95MO B 925.6 5 0.030 5 11.2 + 95MO B 925.6 5 0.030 5 11.2 2 95MOS B EAV=321.94 21 95MO L 204.118 9 3/2+ 0.751 NS 9 - 95MO B 721.5 5 + 95MO B 721.5 5 2U 95MOS B EAV=283.58 20 - 95MO G 204.117 2 0.028 8 M1+E2 0.0515 22 - 95MO2 G KC=0.045 3$LC=0.0058 4$MC= + 95MO G 204.117 2 0.028 8M1+E2 0.0515 22 + 95MO2 G KC=0.045 3$LC=0.0058 4 95MO L 765.806 6 7/2+ 0.0044 NS 7 - 95MO B 159.8 5 99.970 6 5.09 2 + 95MO B 159.8 5 99.970 6 5.09 95MOS B EAV=43.36 15 - 95MO G 561.88 2 0.015 3 [E2] 0.0034110 - 95MO2 G KC=0.00298 9$LC=3.54E-4 11$MC= - 95MO G 765.803 6 99.808 7 M1+E2 0.001474 - 95MO2 G KC=0.00129 4$LC=1.45E-4 4$MC= + 95MO G 561.88 2 0.015 3[E2] 0.0034110 + 95MO2 G KC=0.00298 9$LC=3.54E-4 11 + 95MO G 765.803 6 99.808 7M1+E2 0.00147 4 + 95MO2 G KC=0.00129 4$LC=1.45E-4 4 diff --git a/HEN_HOUSE/spectra/lnhb/Nb-95m.txt b/HEN_HOUSE/spectra/lnhb/Nb-95m.txt index c5e68a359..93b1e9df0 100644 --- a/HEN_HOUSE/spectra/lnhb/Nb-95m.txt +++ b/HEN_HOUSE/spectra/lnhb/Nb-95m.txt @@ -1,74 +1,73 @@ 95NB 95NB IT DECAY (3.61 D) 95NB H TYP=Full$AUT=M.M.Bé. R.G.Helmer$CUT= -- $ 95NB C Evaluation history: Type=Full;Author=M.M.Bé. R.G.Helmer;Cutoff date= -- - 95NB T Auger electrons and ^X ray energies and emission intensities: - 95NB T {U Energy (keV)} {U Intensity } {U Line } + 95NB T Auger electrons and X ray energies and emission intensities: + 95NB T {U Energy (keV)} {U Intensity} {U Line} 95NB T - 95NB T 16.521 12.5 6 XKA2 - 95NB T 16.615 23.9 10 XKA1 + 95NB T 16.521 12.5 6 XKA2 + 95NB T 16.615 23.9 10 XKA1 95NB T - 95NB T 18.607 |] XKB3 - 95NB T 18.623 |] 6.19 27 XKB1 - 95NB T 18.78 |] XKB5II + 95NB T 18.607 |] XKB3 + 95NB T 18.623 |] 6.19 27 XKB1 + 95NB T 18.78 |] XKB5II 95NB T - 95NB T 18.952 |] XKB2 - 95NB T 18.982 |] 0.93 5 XKB4 + 95NB T 18.952 |] XKB2 + 95NB T 18.982 |] 0.93 5 XKB4 95NB T - 95NB T 1.9-2.66 0.0251 11 XL (total) + 95NB T 1.9-2.66 0.0251 11 XL (total) 95NB T 1.9 XLL 95NB T -2.66 XLG 95NB T - 95NB T 13.49-14.14 |] KLL AUGER - 95NB T 15.79-16.58 |] 14.5 7 ^KLX AUGER - 95NB T 18.02-18.91 |] KXY AUGER - 95NB T 1.4-2.6 69.9 25 L AUGER + 95NB T 13.49-14.14 |] KLL AUGER + 95NB T 15.79-16.58 |] 14.5 7 KLX AUGER + 95NB T 18.02-18.91 |] KXY AUGER + 95NB T 1.4-2.6 69.9 25 L AUGER 95NB P 235.69 2 1/2- 3.61 D 3 95NB N 1.026E0 1.026E0 0.975 1.026E0 95NB L 0 9/2+ 34.991 D 6 95NB L 235.69 5 1/2- 3.61 D 3 - 95NB G 235.69 2 25.1 3 M4 2.88 9 - 95NB2 G KC=2.31 8$LC=0.468 14$MC=0.10000 0 + 95NB G 235.69 2 25.1 3M4 2.88 9 + 95NB2 G KC=2.31 8$LC=0.468 14$MC=0.1 95MO 95NB B- DECAY (3.61 D) 95MO H TYP=Full$AUT=M.M.Bé. R.G.Helmer$CUT= -- $ 95MO C Evaluation history: Type=Full;Author=M.M.Bé. R.G.Helmer;Cutoff date= -- - 95MO T Auger electrons and ^X ray energies and emission intensities: - 95MO T {U Energy (keV)} {U Intensity } {U Line } + 95MO T Auger electrons and X ray energies and emission intensities: + 95MO T {U Energy (keV)} {U Intensity} {U Line} 95MO T 95MO T 17.374 XKA2 95MO T 17.479 XKA1 95MO T - 95MO T 17.59 |] XKB3 - 95MO T 19.608 |] XKB1 - 95MO T 19.771 |] XKB5II + 95MO T 17.59 |] XKB3 + 95MO T 19.608 |] XKB1 + 95MO T 19.771 |] XKB5II 95MO T - 95MO T 19.965 |] XKB2 - 95MO T 19.997 |] XKB4 + 95MO T 19.965 |] XKB2 + 95MO T 19.997 |] XKB4 95MO T 95MO T - 95MO T 14.268-14.96 |] KLL AUGER - 95MO T 16.628-17.476 |] ^KLX AUGER - 95MO T 18.99-19.99 |] KXY AUGER + 95MO T 14.268-14.96 |] KLL AUGER + 95MO T 16.628-17.476 |] KLX AUGER + 95MO T 18.99-19.99 |] KXY AUGER 95MO T 1.86-2.86 L AUGER 95NB P 235.69 2 1/2- 3.61 D 3 925.6 5 95MO N 4.00E1 4.00E1 0.025 4.00E1 95MO L 0 5/2+ STABLE 95MO L 204.118 3/2+ 0.751 NS - 95MO B 957.2 5 2.4 1 8.3 1U + 95MO B 957.2 5 2.4 1 8.3 1 95MOS B EAV=345 1 95MO G 204.117 2 2.28 10M1+E2 0.0515 22 - 95MO2 G KC=0.045 3$LC=0.0058 4$MC= + 95MO2 G KC=0.045 3$LC=0.0058 4 95MO L 786.19 1/2+ 95MO B 375.1 5 0.016 9.1 95MOS B EAV=123 1 - 95MO G 786.19 1 0.016 1 E2 0.001315 - 95MO2 G KC=$LC=$MC= + 95MO G 786.19 1 0.016 1E2 0.00131 5 95MO L 820.61 3/2+ - 95MO B 340.7 5 0.00038 10.6 1U + 95MO B 340.7 5 0.00038 10.6 1 95MOS B EAV=123 1 - 95MO G 820.61 1 3800E-7 0 M1+E2 + 95MO G 820.61 1 0.00038 M1+E2 95MO L 1039.25 1/2+ - 95MO B 122.0 5 25000E-925 10.2 + 95MO B 122.0 5 0.00002525 10.2 95MOS B EAV=44.0 5 - 95MO G 835.13 1 2500E-8 0 + 95MO G 835.13 1 0.000025 diff --git a/HEN_HOUSE/spectra/lnhb/Nd-147.txt b/HEN_HOUSE/spectra/lnhb/Nd-147.txt index c23378120..8092e9c75 100644 --- a/HEN_HOUSE/spectra/lnhb/Nd-147.txt +++ b/HEN_HOUSE/spectra/lnhb/Nd-147.txt @@ -9,117 +9,117 @@ 147PM6C 1971Na11, 1974HeYW, 1974Ra30, 1974Bh02, 1976Si08, 1977Kr13, 1977Al34, 147PM7C 1979Vo09, 1979Se05, 1995Go**, 1996Sc06, 1997Sa53, 1998Po**, 2002Ba85, 147PM8C 2008Ki07, 2009AuZZ, 2009Ni02, 2010Gh** -147PM T Auger electrons and ^X ray energies and emission intensities: -147PM T {U Energy (keV)} {U Intensity } {U Line } +147PM T Auger electrons and X ray energies and emission intensities: +147PM T {U Energy (keV)} {U Intensity} {U Line} 147PM T -147PM T 38.1716 12.9 9 XKA2 -147PM T 38.7251 23.5 15 XKA1 +147PM T 38.1716 12.9 9 XKA2 +147PM T 38.7251 23.5 15 XKA1 147PM T -147PM T 43.713 |] XKB3 -147PM T 43.826 |] 7.3 5 XKB1 -147PM T 44.145 |] XKB5II +147PM T 43.713 |] XKB3 +147PM T 43.826 |] 7.3 5 XKB1 +147PM T 44.145 |] XKB5II 147PM T -147PM T 44.937 |] XKB2 -147PM T 45.064 |] 1.87 13 XKB4 -147PM T 45.162 |] XKO23 +147PM T 44.937 |] XKB2 +147PM T 45.064 |] 1.87 13 XKB4 +147PM T 45.162 |] XKO23 147PM T -147PM T 4.81-7.1893 7.6 3 XL (total) -147PM T 4.81 0.148 9 XLL -147PM T 5.4061-5.4325 3.68 20 XLA -147PM T 5.363 0.057 4 XLC -147PM T 5.9552-6.3985 3.20 14 XLB -147PM T 6.6814-7.1893 0.517 24 XLG +147PM T 4.81-7.1893 7.6 3 XL (total) +147PM T 4.81 0.148 9 XLL +147PM T 5.4061-5.4325 3.68 20 XLA +147PM T 5.363 0.057 4 XLC +147PM T 5.9552-6.3985 3.20 14 XLB +147PM T 6.6814-7.1893 0.517 24 XLG 147PM T -147PM T 30.16-32.08 |] KLL AUGER -147PM T 36.03-37.63 |] 3.9 4 ^KLX AUGER -147PM T 41.84-44.16 |] KXY AUGER -147PM T 3.1-6.27 43.4 18 L AUGER +147PM T 30.16-32.08 |] KLL AUGER +147PM T 36.03-37.63 |] 3.9 4 KLX AUGER +147PM T 41.84-44.16 |] KXY AUGER +147PM T 3.1-6.27 43.4 18 L AUGER 147ND P 0.0 5/2- 10.987 D 11 895.7 9 147PM N 1.0 1.0 1 1.0 147PM L 0 7/2+ 2.6234 Y 4 -147PM B 895.7 9 0 5 7.5 1U +147PM B 895.7 9 7.5 1 147PMS B EAV=299.45 35 147PM L 91.1049 205/2+ 2.50 NS 5 -147PM B 804.6 9 81 5 7.4 +147PM B 804.6 9 81 5 7.4 147PMS B EAV=263.99 35 -147PM G 91.105 2 28.4 18M1+E2 0.090 5 2.03 3 -147PM2 G KC=1.714 24$LC=0.250 4$MC=0.0535 8 +147PM G 91.105 2 28.4 18M1+E2 0.090 5 2.03 3 +147PM2 G KC=1.714 24$LC=0.250 4$MC=0.0535 8 147PM L 408.54 5 9/2+ -147PM G 408.52 6 0.0178 13M1+E2 0.57 3 0.0304 5 -147PM2 G KC=0.0257 5$LC=0.00368 6$MC=7.89E-4 12 +147PM G 408.52 6 0.0178 13M1+E2 0.57 3 0.0304 5 +147PM2 G KC=0.0257 5$LC=0.00368 6$MC=7.89E-4 12 147PM L 410.512 133/2+ 0.139 NS 14 -147PM B 485.2 9 0.715 34 8.7 1U +147PM B 485.2 9 0.715 34 8.7 1 147PMS B EAV=146.67 30 -147PM G 319.411 181.991 19M1+E2 -0.378 9 0.0607 9 -147PM2 G KC=0.0514 8$LC=0.00734 11$MC=1572E-6 22 -147PM G 410.48 3 0.137 6 E2 0.0212 3 -147PM2 G KC=0.01724 25$LC=0.00313 5$MC=6.83E-4 10 +147PM G 319.411 181.991 19M1+E2 -0.378 9 0.0607 9 +147PM2 G KC=0.0514 8$LC=0.00734 11$MC=1572E-6 22 +147PM G 410.48 3 0.137 6E2 0.0212 3 +147PM2 G KC=0.01724 25$LC=0.00313 5$MC=6.83E-4 10 147PM L 489.255 167/2+ -147PM B 406.4 9 0.781 15 8.4 1U +147PM B 406.4 9 0.781 15 8.4 1 147PMS B EAV=119.83 30 147PM G 80.82 270.00086 11[M1E2] 3.9 11 147PM2 G KC=2.26 17$LC=1.3 10$MC=0.29 22 -147PM G 398.155 200.855 8 M1+E2 0.297 37 0.0345 5 -147PM2 G KC=0.0293 5$LC=0.00406 6$MC=8.66E-4 13 +147PM G 398.155 200.855 8M1+E2 0.297 37 0.0345 5 +147PM2 G KC=0.0293 5$LC=0.00406 6$MC=8.66E-4 13 147PM G 489.24 3 0.136 11M1+E2 -0.79 35 0.0179 18 -147PM2 G KC=0.0152 16$LC=0.00218 14$MC=0.00047 3 +147PM2 G KC=0.0152 16$LC=0.00218 14$MC=0.00047 3 147PM L 531.012 155/2+ 0.083 NS 15 -147PM B 364.7 9 14.6 9 7 +147PM B 364.7 9 14.6 9 7 147PMS B EAV=106.02 30 147PM G 120.48 5 0.361 14M1+E2 0.116 42 0.914 14 -147PM2 G KC=0.772 11$LC=0.112 4$MC=0.0239 8 -147PM G 439.895 221.203 11M1+E2 0.609 21 0.0248 4 -147PM2 G KC=0.0210 4$LC=0.00300 5$MC=6.41E-4 10 -147PM G 531.016 2212.7 9 M1+E2 -0.407 35 0.0161 3 -147PM2 G KC=0.01374 23$LC=0.00188 3$MC=4.02E-4 6 +147PM2 G KC=0.772 11$LC=0.112 4$MC=0.0239 8 +147PM G 439.895 221.203 11M1+E2 0.609 21 0.0248 4 +147PM2 G KC=0.0210 4$LC=0.00300 5$MC=6.41E-4 10 +147PM G 531.016 2212.7 9M1+E2 -0.407 35 0.0161 3 +147PM2 G KC=0.01374 23$LC=0.00188 3$MC=4.02E-4 6 147PM L 632.93 7 1/2+ -147PM B 262.8 9 0.0190 27 9.1 3U +147PM B 262.8 9 0.0190 27 9.1 1U 147PMS B EAV=85.89 33 147PM G 541.83 7 0.0188 27[E2] 0.0099414 -147PM2 G KC=0.00824 12$LC=1338E-6 19$MC=2.90E-4 4 +147PM2 G KC=0.00824 12$LC=1338E-6 19$MC=2.90E-4 4 147PM L 641.27 8 + 147PM G 230.77 8 147PM L 649.03 4 11/2- 27 NS 3 -147PM B 246.7 9 0.296 19 7.5 +147PM B 246.7 9 0.296 19 7.5 2U 147PMS B EAV=91.35 33 147PM G 117.98 8 0.0152 13E3 14.07 20 -147PM2 G KC=3.15 5$LC=8.41 12$MC=2.02 3 -147PM G 159.7 2 0.00508 38M2 2.74 4 -147PM2 G KC=2.18 4$LC=0.439 7$MC=0.0977 15 -147PM G 240.5 2 0.0406 25E1 0.0250 4 -147PM2 G KC=0.0213 3$LC=0.00290 5$MC=6.15E-4 9 -147PM G 649.04 8 0.00495 38M2 0.0299 5 -147PM2 G KC=0.0251 4$LC=0.00371 6$MC=7.99E-4 12 +147PM2 G KC=3.15 5$LC=8.41 12$MC=2.02 3 +147PM G 159.7 2 0.00508 38M2 2.74 4 +147PM2 G KC=2.18 4$LC=0.439 7$MC=0.0977 15 +147PM G 240.5 2 0.0406 25E1 0.0250 4 +147PM2 G KC=0.0213 3$LC=0.00290 5$MC=6.15E-4 9 +147PM G 649.04 8 0.00495 38M2 0.0299 5 +147PM2 G KC=0.0251 4$LC=0.00371 6$MC=7.99E-4 12 147PM L 680.44 4 7/2+ -147PM B 215.3 9 0.0897 28 8.4 1U +147PM B 215.3 9 0.0897 28 8.4 1 147PMS B EAV=59.16 27 147PM G 31.3 2 [M2] 548 18 -147PM2 G KC=$LC=422 14$MC=100 4 -147PM G 149.3 2 0.00368 38[M1E2] 0.52 3 -147PM2 G KC=0.39 3$LC=0.10 5$MC=0.022 10 -147PM G 191.0 3 0.00356 38[M1E2] 0.244 9 -147PM2 G KC=0.192 22$LC=0.040 11$MC=0.009 3 -147PM G 271.87 6 0.0126 9 M1+E2 0.10 3 0.0964 14 -147PM2 G KC=0.0820 12$LC=0.01133 16$MC=0.00242 4 -147PM G 589.35 4 0.037 2 [M1E2] 0.011 3 -147PM2 G KC=0.0090 23$LC=0.00128 23$MC=0.00027 4 +147PM2 G LC=422 14$MC=100 4 +147PM G 149.3 2 0.00368 38[M1E2] 0.52 3 +147PM2 G KC=0.39 3$LC=0.10 5$MC=0.022 10 +147PM G 191.0 3 0.00356 38[M1E2] 0.244 9 +147PM2 G KC=0.192 22$LC=0.040 11$MC=0.009 3 +147PM G 271.87 6 0.0126 9M1+E2 0.10 3 0.0964 14 +147PM2 G KC=0.0820 12$LC=0.01133 16$MC=0.00242 4 +147PM G 589.35 4 0.037 2[M1E2] 0.011 3 +147PM2 G KC=0.0090 23$LC=0.00128 23$MC=0.00027 4 147PM G 680.52 150.0283 14[M1E2] 0.0074 18 -147PM2 G KC=0.0063 18$LC=0.00088 17$MC=0.00019 4 +147PM2 G KC=0.0063 18$LC=0.00088 17$MC=0.00019 4 147PM L 685.890 155/2+ 0.25 NS 10 147PM B 209.8 9 2.184 16 7 147PMS B EAV=57.54 27 147PM G 36.75 10 [E3] 1.004E422 -147PM2 G KC=$LC=7.60E3 17$MC=1960 50 -147PM G 53.1 2 [E2] 25.1 6 -147PM2 G KC=4.40 7$LC=16.1 4$MC=3.73 9 +147PM2 G LC=7.60E3 17$MC=1960 50 +147PM G 53.1 2 [E2] 25.1 6 +147PM2 G KC=4.40 7$LC=16.1 4$MC=3.73 9 147PM G 154.7 2 0.00394 38[M1E2] 0.468 19 -147PM2 G KC=0.36 3$LC=0.09 4$MC=0.020 9 -147PM G 196.64 4 0.1798 18M1+E2 -0.20 8 0.231 4 -147PM2 G KC=0.196 3$LC=0.0281 8$MC=0.00601 18 +147PM2 G KC=0.36 3$LC=0.09 4$MC=0.020 9 +147PM G 196.64 4 0.1798 18M1+E2 -0.20 8 0.231 4 +147PM2 G KC=0.196 3$LC=0.0281 8$MC=0.00601 18 147PM G 275.374 150.775 11M1+E2 0.112 5 0.0931 13 -147PM2 G KC=0.0792 11$LC=0.01095 16$MC=0.00234 4 -147PM G 594.80 3 0.2653 36M1+E2 0.55 6 0.0117 3 -147PM2 G KC=0.00995 23$LC=0.00137 3$MC=2.92E-4 6 -147PM G 685.90 4 0.834 9 M1+E2 -0.92 20 0.0074 5 -147PM2 G KC=0.0063 4$LC=0.00088 4$MC=1.88E-4 9 +147PM2 G KC=0.0792 11$LC=0.01095 16$MC=0.00234 4 +147PM G 594.80 3 0.2653 36M1+E2 0.55 6 0.0117 3 +147PM2 G KC=0.00995 23$LC=0.00137 3$MC=2.92E-4 6 +147PM G 685.90 4 0.834 9M1+E2 -0.92 20 0.0074 5 +147PM2 G KC=0.0063 4$LC=0.00088 4$MC=1.88E-4 9 diff --git a/HEN_HOUSE/spectra/lnhb/Ni-57.txt b/HEN_HOUSE/spectra/lnhb/Ni-57.txt index c1f6a49e2..28407bef2 100644 --- a/HEN_HOUSE/spectra/lnhb/Ni-57.txt +++ b/HEN_HOUSE/spectra/lnhb/Ni-57.txt @@ -1,84 +1,84 @@ 57CO 57NI EC DECAY (1.496 D) - 57CO T Auger electrons and ^X ray energies and emission intensities: - 57CO T {U Energy (keV)} {U Intensity } {U Line } + 57CO T Auger electrons and X ray energies and emission intensities: + 57CO T {U Energy (keV)} {U Intensity} {U Line} 57CO T - 57CO T 6.91538 5.84 12 XKA2 - 57CO T 6.9304 11.42 23 XKA1 + 57CO T 6.91538 5.84 12 XKA2 + 57CO T 6.9304 11.42 23 XKA1 57CO T - 57CO T 7.6495 |] 2.37 6 XKB1 - 57CO T 7.706 |] XKB5II + 57CO T 7.6495 |] 2.37 6 XKB1 + 57CO T 7.706 |] XKB5II 57CO T 57CO T - 57CO T 0.678-0.87 0.56 4 XL (total) + 57CO T 0.678-0.87 0.56 4 XL (total) 57CO T 0.678 XLL 57CO T -0.87 XLG 57CO T - 57CO T 5.81-6.1 |] KLL AUGER - 57CO T 6.67-6.86 |] 31.0 6 ^KLX AUGER - 57CO T 7.5-7.58 |] KXY AUGER - 57CO T 0.564-0.653 76.7 12 L AUGER + 57CO T 5.81-6.1 |] KLL AUGER + 57CO T 6.67-6.86 |] 31.0 6 KLX AUGER + 57CO T 7.5-7.58 |] KXY AUGER + 57CO T 0.564-0.653 76.7 12 L AUGER 57NI P 0.0 3/2- 1.496 D 23 3264.2 26 57CO N 1.0 1.0 1 1.0 57CO L 0 7/2- 271.80 D 5 57CO L 1223.79 7 9/2- 54 FS 5 - 57CO G 1223.8 3 0.076 13M1+E2 1.20E-44 - 57CO2 G KC=1.08E-4 3$LC=1.03E-5 3$MC= + 57CO G 1223.8 3 0.076 13M1+E2 1.20E-4 4 + 57CO2 G KC=1.08E-4 3$LC=1.03E-5 3 57CO L 1377.65 3 3/2- 19 PS 4 - 57CO E 35.3 5 29.3 5 5.6 - 57CO2 E EAV=368.3 $CK=0.8876 16$CL=0.0961 13$CM=0.0155 5$CN= $CO= - 57CO G 1377.62 4 81.2 6 E2 1.05E-43 - 57CO2 G KC=9.5E-5 3$LC=9.1E-6 3$MC= + 57CO E 35.3 529.3 55.6 + 57CO2 E EAV=368.3 $CK=0.8876 16$CL=0.0961 13$CM=0.0155 5 + 57CO G 1377.62 4 81.2 6E2 1.05E-4 3 + 57CO2 G KC=9.5E-5 3$LC=9.1E-6 3 57CO L 1504.82 3 1/2- 0.21 NS 2 - 57CO E 6.8 3 9.6 4 6.1 2 - 57CO2 E EAV=313.4 $CK=0.8875 16$CL=0.0962 13$CM=0.0155 5$CN= $CO= - 57CO G 127.164 3 16.0 5 M1+E2 0.0215 6 - 57CO2 G KC=0.0193 6$LC=0.00191 6$MC= + 57CO E 6.8 39.6 46.1 + 57CO2 E EAV=313.4 $CK=0.8875 16$CL=0.0962 13$CM=0.0155 5 + 57CO G 127.164 3 16.0 5M1+E2 0.0215 6 + 57CO2 G KC=0.0193 6$LC=0.00191 6 57CO L 1757.596 243/2- 0.27 PS 2 - 57CO E 0.85 6 5.2 3 6.2 - 57CO2 E EAV=206.1 $CK=0.8874 16$CL=0.0963 13$CM=0.0155 5$CN= $CO= - 57CO G 379.94 2 0.072 6 [M1] 0.001434 - 57CO2 G KC=0.00129 4$LC=1.24E-4 4$MC= - 57CO G 1757.55 3 6.1 4 E2 + 57CO E 0.85 65.2 36.2 + 57CO2 E EAV=206.1 $CK=0.8874 16$CL=0.0963 13$CM=0.0155 5 + 57CO G 379.940 200.072 6[M1] 0.00143 4 + 57CO2 G KC=0.00129 4$LC=1.24E-4 4 + 57CO G 1757.55 3 6.1 4E2 57CO L 1897.24 6 7/2- 110 FS 10 - 57CO G 673.44 4 0.0483 15M1+E2 0.000401 - 57CO2 G KC=0.00036 1$LC=3.4E-5 1$MC= + 57CO G 673.44 4 0.0483 15M1+E2 0.00040 1 + 57CO2 G KC=0.00036 1$LC=3.4E-5 1 57CO G 1897.0 5 0.0252 25M1+E2 57CO L 1919.47 4 5/2- 22 FS 3 - 57CO E 0.45 3 12.1 6 5.7 2 - 57CO2 E EAV=138.6 $CK=0.8873 16$CL=0.0964 13$CM=0.0155 5$CN= $CO= - 57CO G 161.86 3 0.0202 24M1 0.0115 3 - 57CO2 G KC=0.0104 3$LC=0.00102 3$MC= - 57CO G 541.9 1 0.0036 5 [E2] 0.001163 - 57CO2 G KC=0.00105 3$LC=1.02E-4 3$MC= - 57CO G 696.0 4 0.0009 6 [E2] 0.000562 - 57CO2 G KC=0.00050 2$LC=4.8E-5 1$MC= - 57CO G 1919.62 1412.5 5 M1+E2 + 57CO E 0.45 312.1 65.7 + 57CO2 E EAV=138.6 $CK=0.8873 16$CL=0.0964 13$CM=0.0155 5 + 57CO G 161.86 3 0.0202 24M1 0.0115 3 + 57CO2 G KC=0.0104 3$LC=0.00102 3 + 57CO G 541.9 1 0.0036 5[E2] 0.00116 3 + 57CO2 G KC=0.00105 3$LC=1.02E-4 3 + 57CO G 696.0 4 0.0009 6[E2] 0.00056 2 + 57CO2 G KC=0.00050 2$LC=4.8E-5 1 + 57CO G 1919.62 1412.5 5M1+E2 57CO L 2133.06 5 5/2- 0.34 PS 6 - 57CO E 0.039 5 8.1 2 - 57CO2 E EAV= $CK=0.8871 16$CL=0.0965 13$CM=0.0156 5$CN= $CO= - 57CO G 755.3 1 0.0054 6 M1+E2 0.000331 - 57CO2 G KC=2.95E-4 9$LC=2.82E-5 8$MC= - 57CO G 2133.04 5 0.033 5 M1 + 57CO E 0.039 58.1 + 57CO2 E CK=0.8871 16$CL=0.0965 13$CM=0.0156 5 + 57CO G 755.30 100.0054 6M1+E2 0.00033 1 + 57CO2 G KC=2.95E-4 9$LC=2.82E-5 8 + 57CO G 2133.04 5 0.033 5M1 57CO L 2730.83 143/2,5/2- 91 FS 12 - 57CO E 0.020 3 7.7 - 57CO2 E EAV= $CK=0.8857 16$CL=0.0977 13$CM=0.0158 5$CN= $CO= - 57CO G 2730.76 140.020 3 + 57CO E 0.020 37.7 + 57CO2 E CK=0.8857 16$CL=0.0977 13$CM=0.0158 5 + 57CO G 2730.76 140.020 3 57CO L 2804.18 6 (3/2,5/2)- 37 FS 7 57CO E 0.308 236.4 - 57CO2 E EAV= $CK=0.8853 16$CL=0.0980 13$CM=0.0158 5$CN= $CO= + 57CO2 E CK=0.8853 16$CL=0.0980 13$CM=0.0158 5 57CO G 906.98 5 0.075 14 - 57CO G 1046.68 140.132 3 + 57CO G 1046.68 140.132 3 57CO G 2804.08 150.102 17E2 57CO L 3108.14 4 (3/2)- 54 FS 7 - 57CO E 0.063 4 6.1 - 57CO2 E EAV= $CK=0.8790 17$CL=0.1033 14$CM=0.0168 5$CN= $CO= - 57CO G 304.1 1 0.0020 6 - 57CO G 1350.52 6 0.002 1 - 57CO G 1603.28 6 0.0039 6 - 57CO G 1730.45 6 0.055 3 + 57CO E 0.063 46.1 + 57CO2 E CK=0.8790 17$CL=0.1033 14$CM=0.0168 5 + 57CO G 304.1 1 0.0020 6 + 57CO G 1350.52 6 0.002 1 + 57CO G 1603.28 6 0.0039 6 + 57CO G 1730.45 6 0.055 3 57CO L 3177.31 5 5/2,7/2- 152 FS 35 - 57CO E 0.025 5 6 2 - 57CO2 E EAV= $CK=0.8706 19$CL=0.1103 15$CM=0.0181 6$CN= $CO= - 57CO G 1279.99 6 0.0096 7 - 57CO G 3177.27 5 0.015 4 + 57CO E 0.025 56 + 57CO2 E CK=0.8706 19$CL=0.1103 15$CM=0.0181 6 + 57CO G 1279.99 6 0.0096 7 + 57CO G 3177.27 5 0.015 4 diff --git a/HEN_HOUSE/spectra/lnhb/Ni-59.txt b/HEN_HOUSE/spectra/lnhb/Ni-59.txt index 3ecfe014a..e9e49a196 100644 --- a/HEN_HOUSE/spectra/lnhb/Ni-59.txt +++ b/HEN_HOUSE/spectra/lnhb/Ni-59.txt @@ -4,30 +4,30 @@ 59CO C References: 1981MUZQ, 1949PO04, 1951BR05, 1951WI14, 1956SA32, 1976BE02, 59CO2C 1981NI08, 1988BO30, 1991NO08, 1991JA02, 1994RU19, 1996SC06, 2002BA19, 59CO3C 2004RA23, 2007WA00, 2009AUZZ - 59CO T Auger electrons and ^X ray energies and emission intensities: - 59CO T {U Energy (keV)} {U Intensity } {U Line } + 59CO T Auger electrons and X ray energies and emission intensities: + 59CO T {U Energy (keV)} {U Intensity} {U Line} 59CO T - 59CO T 6.91538 10.24 12 XKA2 - 59CO T 6.9304 20.02 22 XKA1 + 59CO T 6.91538 10.24 12 XKA2 + 59CO T 6.9304 20.02 22 XKA1 59CO T - 59CO T 7.6495 |] 4.15 6 XKB1 - 59CO T 7.706 |] XKB5II + 59CO T 7.6495 |] 4.15 6 XKB1 + 59CO T 7.706 |] XKB5II 59CO T 59CO T - 59CO T 0.6793-0.9251 0.98 7 XL (total) - 59CO T 0.6793 0.0400 13 XLL - 59CO T 0.7787-0.7795 0.508 15 XLA - 59CO T 0.6949 0.0247 9 XLC - 59CO T 0.78642-0.9251 0.346 12 XLB - 59CO T 0.80198-0.80198 0.00210 23 XLG + 59CO T 0.6793-0.9251 0.98 7 XL (total) + 59CO T 0.6793 0.0400 13 XLL + 59CO T 0.7787-0.7795 0.508 15 XLA + 59CO T 0.6949 0.0247 9 XLC + 59CO T 0.78642-0.9251 0.346 12 XLB + 59CO T 0.80198-0.80198 0.00210 23 XLG 59CO T - 59CO T 5.806-6.099 |] KLL AUGER - 59CO T 6.667-6.927 |] 54.3 4 ^KLX AUGER - 59CO T 7.508-7.703 |] KXY AUGER - 59CO T 0.68-0.83 134.5 8 L AUGER + 59CO T 5.806-6.099 |] KLL AUGER + 59CO T 6.667-6.927 |] 54.3 4 KLX AUGER + 59CO T 7.508-7.703 |] KXY AUGER + 59CO T 0.68-0.83 134.5 8 L AUGER 59NI P 0.0 3/2- 76E3 Y 5 1072.76 19 59CO N 1.0 1.0 1 1.0 59CO L 0 0 7/2- STABLE - 59CO E 3.7E-5 1210000E-21 11.89 - 59CO2 E EAV=24.81 9$CK=0.8870 16$CL=0.0966 13$CM=0.0156 5$CN=0.0008 2$CO= + 59CO E 0.0000371299.99996 111.89 2 + 59CO2 E EAV=24.81 9$CK=0.8870 16$CL=0.0966 13$CM=0.0156 5$CN=0.0008 2 diff --git a/HEN_HOUSE/spectra/lnhb/Ni-63.txt b/HEN_HOUSE/spectra/lnhb/Ni-63.txt index 4acc773e0..5838f38fb 100644 --- a/HEN_HOUSE/spectra/lnhb/Ni-63.txt +++ b/HEN_HOUSE/spectra/lnhb/Ni-63.txt @@ -3,24 +3,24 @@ 63CU C Evaluation history: Type=Full;Author=K.B. Lee;Cutoff date=28-SEP-2009 63CU C References: 1966Hs01, 1971Ba89, 1987He14, 1992Ka29, 1993Oh02, 1996Co25, 63CU2C 1996Sc33, 1999Ho09, 2003Au03 - 63CU T Auger electrons and ^X ray energies and emission intensities: - 63CU T {U Energy (keV)} {U Intensity } {U Line } + 63CU T Auger electrons and X ray energies and emission intensities: + 63CU T {U Energy (keV)} {U Intensity} {U Line} 63CU T 63CU T 8.02792 XKA2 63CU T 8.04787 XKA1 63CU T - 63CU T 8.90539 |] XKB1 - 63CU T 8.9771 |] XKB5II + 63CU T 8.90539 |] XKB1 + 63CU T 8.9771 |] XKB5II 63CU T 63CU T 63CU T - 63CU T 6.731-7.059 |] KLL AUGER - 63CU T 7.746-8.064 |] ^KLX AUGER - 63CU T 8.739-8.982 |] KXY AUGER + 63CU T 6.731-7.059 |] KLL AUGER + 63CU T 7.746-8.064 |] KLX AUGER + 63CU T 8.739-8.982 |] KXY AUGER 63CU T 0.03-1.09 L AUGER 63NI P 0.0 1/2- 98.7 Y 24 66.980 15 63CU N 1.0 1.0 1 1.0 63CU L 0 3/2- STABLE - 63CU B 66.980 15100 6.7 2 + 63CU B 66.980 15100 6.7 63CUS B EAV=17.434 4 diff --git a/HEN_HOUSE/spectra/lnhb/Np-236.txt b/HEN_HOUSE/spectra/lnhb/Np-236.txt index 97d964bbd..8a16f1cf7 100644 --- a/HEN_HOUSE/spectra/lnhb/Np-236.txt +++ b/HEN_HOUSE/spectra/lnhb/Np-236.txt @@ -22,63 +22,63 @@ 236U C References: 1969Le05, 1971Dr11, 1971GuZY, 1972Dzh., 1972El21, 1972En06, 236U 2C 1975Dr05, 1975OtZX, 1976GuZN, 1977Po05, 1980Sc26, 1981Li30, 1983Ah02, 236U 3C 1991Sc08, 1996FiZX, 2003Au03, 2006Br20, 2008Ki07 -236U T Auger electrons and ^X ray energies and emission intensities: -236U T {U Energy (keV)} {U Intensity } {U Line } +236U T Auger electrons and X ray energies and emission intensities: +236U T {U Energy (keV)} {U Intensity} {U Line} 236U T -236U T 94.666 20.2 3 XKA2 -236U T 98.44 32.4 5 XKA1 +236U T 94.666 20.2 3 XKA2 +236U T 98.44 32.4 5 XKA1 236U T -236U T 110.421 |] XKB3 -236U T 111.298 |] 11.69 25 XKB1 -236U T 111.964 |] XKB5II +236U T 110.421 |] XKB3 +236U T 111.298 |] 11.69 25 XKB1 +236U T 111.964 |] XKB5II 236U T -236U T 114.407 |] XKB2 -236U T 115.012 |] 4.00 11 XKB4 -236U T 115.377 |] XKO23 +236U T 114.407 |] XKB2 +236U T 115.012 |] 4.00 11 XKB4 +236U T 115.377 |] XKO23 236U T -236U T 11.619-20.714 117.5 30 XL (total) -236U T 11.619 2.63 7 XLL -236U T 13.438-13.615 42.3 11 XLA -236U T 15.399 1.24 4 XLC -236U T 15.727-18.206 57.7 13 XLB -236U T 19.507-20.714 13.6 3 XLG +236U T 11.619-20.714 117.5 30 XL (total) +236U T 11.619 2.63 7 XLL +236U T 13.438-13.615 42.3 11 XLA +236U T 15.399 1.24 4 XLC +236U T 15.727-18.206 57.7 13 XLB +236U T 19.507-20.714 13.6 3 XLG 236U T -236U T 71.78-80.95 |] KLL AUGER -236U T 88.15-98.43 |] 2.1 3 ^KLX AUGER -236U T 104.51-115.59 |] KXY AUGER -236U T 6.07-21.68 128.8 19 L AUGER +236U T 71.78-80.95 |] KLL AUGER +236U T 88.15-98.43 |] 2.1 3 KLX AUGER +236U T 104.51-115.59 |] KXY AUGER +236U T 6.07-21.68 128.8 19 L AUGER 236NP P 0.0 6- 1.55E5 Y 8 930 50 236U N 1.139E0 1.139E0 0.878 1.139E0 236U L 0 0+ 23.43E6 Y 6 236U L 45.244 2 2+ 234 PS 6 -236U G 45.244 2 0.149 3 E2 589 12 -236U 2 G KC=$LC=429 9$MC=118.6 24 +236U G 45.244 2 0.149 3E2 589 12 +236U 2 G LC=429 9$MC=118.6 24 236U L 149.477 6 4+ 124 PS 7 236U E 4.4 15.9 1U -236U 2 E EAV= $CK=0.74 $CL=0.19 $CM=0.07 $CN=0.0001 $CO= +236U 2 E CK=0.74 $CL=0.19 $CM=0.07 $CN=0.0001 236U G 104.234 6 7.32 13E2 10.99 22 -236U 2 G KC=$LC=8.00 16$MC=2.22 5 +236U 2 G LC=8.00 16$MC=2.22 5 236U L 309.785 7 6+ 58 PS 3 236U E 87.8 4314.1 -236U 2 E EAV= $CK=0.726 8$CL=0.201 5$CM=0.073 2$CN=0.0001 $CO= -236U G 160.307 3 31.8 15E2 1.76 4 -236U 2 G KC=0.208 4$LC=1.13 2$MC=0.313 7 +236U 2 E CK=0.726 8$CL=0.201 5$CM=0.073 2$CN=0.0001 +236U G 160.307 3 31.8 15E2 1.76 4 +236U 2 G KC=0.208 4$LC=1.13 2$MC=0.313 7 236U L 687.59 4 1- 3.78 NS 9 -236U G 538.1 1 7000E-7 0 E3 0.143 3 -236U 2 G KC=0.0622 13$LC=0.0587 12$MC=0.0160 3 -236U G 642.34 5 5900E-5 0 E1+(M2+E3) 0.15 2 +236U G 538.1 1 0.0007 E3 0.143 3 +236U 2 G KC=0.0622 13$LC=0.0587 12$MC=0.0160 3 +236U G 642.34 5 0.059 E1+(M2+E3) 0.15 2 236U 2 G KC=0.112 10$LC=$MC= -236U G 687.60 5 1600E-5 0 E1+(M2+E3) 0.31 2 -236U 2 G KC=0.219 12$LC=0.068 6$MC= +236U G 687.60 5 0.016 E1+(M2+E3) 0.31 2 +236U 2 G KC=0.219 12$LC=0.068 6$MC= 236U L 744.18 7 3- 0.1 NS -236U G 56.6 5 4000E-7 0 (E2) 199 10 -236U 2 G KC=$LC=145 7$MC=40.1 19 -236U G 594.5 3 8000E-6 0 +236U G 56.6 5 0.0004 (E2) 199 10 +236U 2 G LC=145 7$MC=40.1 19 +236U G 594.5 3 0.008 236U L 848.1 8 5- 236U E 0.096 14.6 -236U 2 E EAV= $CK= $CL=0.6 $CM=0.4 $CN= $CO= -236U G 104.1 108000E-6 0 E2 11.1 6 -236U 2 G KC=$LC=8.1 4$MC=2.23 11 +236U 2 E CL=0.6 $CM=0.4 +236U G 104.1 100.008 E2 11.1 6 +236U 2 G LC=8.1 4$MC=2.23 11 232PA 236NP A DECAY (1.55E5 Y) 232PA H TYP=update$AUT=mmbe$CUT= -- $ @@ -104,24 +104,24 @@ 232PA C References: 1969Le05, 1971Dr11, 1971GuZY, 1972Dzh., 1972El21, 1972En06, 232PA2C 1975Dr05, 1975OtZX, 1976GuZN, 1977Po05, 1980Sc26, 1981Li30, 1983Ah02, 232PA3C 1991Sc08, 1996FiZX, 2003Au03, 2006Br20, 2008Ki07 -232PA T Auger electrons and ^X ray energies and emission intensities: -232PA T {U Energy (keV)} {U Intensity } {U Line } +232PA T Auger electrons and X ray energies and emission intensities: +232PA T {U Energy (keV)} {U Intensity} {U Line} 232PA T 232PA T 92.288 XKA2 232PA T 95.869 XKA1 232PA T -232PA T 107.595 |] XKB3 -232PA T 108.422 |] XKB1 -232PA T 109.072 |] XKB5II +232PA T 107.595 |] XKB3 +232PA T 108.422 |] XKB1 +232PA T 109.072 |] XKB5II 232PA T -232PA T 111.405 |] XKB2 -232PA T 111.87 |] XKB4 -232PA T 112.38 |] XKO23 +232PA T 111.405 |] XKB2 +232PA T 111.87 |] XKB4 +232PA T 112.38 |] XKO23 232PA T 232PA T -232PA T 70.081-78.822 |] KLL AUGER -232PA T 85.989-95.858 |] ^KLX AUGER -232PA T 101.87-112.59 |] KXY AUGER +232PA T 70.081-78.822 |] KLL AUGER +232PA T 85.989-95.858 |] KLX AUGER +232PA T 101.87-112.59 |] KXY AUGER 232PA T 6.011-21.0077 L AUGER 236NP P 0.0 6- 1.55E5 Y 8 5010 50 232PA N 6.25E2 6.25E2 0.0016 6.25E2 @@ -151,45 +151,45 @@ 236PU C References: 1969Le05, 1971Dr11, 1971GuZY, 1972Dzh., 1972El21, 1972En06, 236PU2C 1975Dr05, 1975OtZX, 1976GuZN, 1977Po05, 1980Sc26, 1981Li30, 1983Ah02, 236PU3C 1991Sc08, 1996FiZX, 2003Au03, 2006Br20, 2008Ki07 -236PU T Auger electrons and ^X ray energies and emission intensities: -236PU T {U Energy (keV)} {U Intensity } {U Line } +236PU T Auger electrons and X ray energies and emission intensities: +236PU T {U Energy (keV)} {U Intensity} {U Line} 236PU T -236PU T 99.525 0.212 23 XKA2 -236PU T 103.734 0.33 4 XKA1 +236PU T 99.525 0.212 23 XKA2 +236PU T 103.734 0.33 4 XKA1 236PU T -236PU T 116.244 |] XKB3 -236PU T 117.228 |] 0.123 14 XKB1 -236PU T 117.918 |] XKB5II +236PU T 116.244 |] XKB3 +236PU T 117.228 |] 0.123 14 XKB1 +236PU T 117.918 |] XKB5II 236PU T -236PU T 120.54 |] XKB2 -236PU T 120.969 |] 0.043 5 XKB4 -236PU T 121.543 |] XKO23 +236PU T 120.54 |] XKB2 +236PU T 120.969 |] 0.043 5 XKB4 +236PU T 121.543 |] XKO23 236PU T -236PU T 12.1246-21.984 12.1 4 XL (total) -236PU T 12.1246 0.276 11 XLL -236PU T 14.083-14.279 4.30 16 XLA -236PU T 16.334 0.133 7 XLC -236PU T 16.499-18.543 5.92 24 XLB -236PU T 20.708-21.984 1.42 6 XLG +236PU T 12.1246-21.984 12.1 4 XL (total) +236PU T 12.1246 0.276 11 XLL +236PU T 14.083-14.279 4.30 16 XLA +236PU T 16.334 0.133 7 XLC +236PU T 16.499-18.543 5.92 24 XLB +236PU T 20.708-21.984 1.42 6 XLG 236PU T -236PU T 75.26-85.36 |] KLL AUGER -236PU T 92.61-103.73 |] 0.021 4 ^KLX AUGER -236PU T 109.93-121.78 |] KXY AUGER -236PU T 6.19-23.1 10.7 3 L AUGER +236PU T 75.26-85.36 |] KLL AUGER +236PU T 92.61-103.73 |] 0.021 4 KLX AUGER +236PU T 109.93-121.78 |] KXY AUGER +236PU T 6.19-23.1 10.7 3 L AUGER 236NP P 0.0 6- 1.55E5 Y 8 480 50 236PU N 8.333E0 8.333E0 0.12 8.333E0 236PU L 0 0+ 2.87 Y 1 236PU L 44.63 102+ -236PU G 44.63 100.0161 9 E2 741 15 -236PU2 G KC=$LC=538 11$MC=150 3 +236PU G 44.63 100.0161 9E2 741 15 +236PU2 G LC=538 11$MC=150 3 236PU L 147.45 104+ 236PU B 333 501.6 16 1U 236PUS B EAV=92 16 -236PU G 102.82 2 0.81 6 E2 13.87 28 -236PU2 G KC=$LC=10.06 20$MC=2.82 6 +236PU G 102.82 2 0.81 6E2 13.87 28 +236PU2 G LC=10.06 20$MC=2.82 6 236PU L 305.80 116+ 236PU B 174 5011.8 12 14.5 236PUS B EAV=46 15 -236PU G 158.35 3 3.8 4 E2 2.14 4 -236PU2 G KC=0.193 4$LC=1.41 3$MC=0.394 8 +236PU G 158.35 3 3.8 4E2 2.14 4 +236PU2 G KC=0.193 4$LC=1.41 3$MC=0.394 8 diff --git a/HEN_HOUSE/spectra/lnhb/Np-236m.txt b/HEN_HOUSE/spectra/lnhb/Np-236m.txt index eccb96126..bfe2af6b2 100644 --- a/HEN_HOUSE/spectra/lnhb/Np-236m.txt +++ b/HEN_HOUSE/spectra/lnhb/Np-236m.txt @@ -2,7 +2,7 @@ 236U H TYP=Full$AUT=V.P.Chechev$CUT=18-JUN-2006$ 236U C Evaluation history: Type=Full;Author=V.P.Chechev;Cutoff date=18-JUN-2006 236U C References: 1949Ja01, 1956Gr11, 1959Gi58, 1967Be65, 1969Le05, 1971GuZY, -236U 2C 1971Dr11, 1975OtZX, 1975Dr05, 1976GuZN, 1977Po05, 1977La19, 1984Gr33, +236U 2C 1971Dr11, 1975Dr05, 1975OtZX, 1976GuZN, 1977Po05, 1977La19, 1984Gr33, 236U 3C 1987Lag., 1991Sc08, 1996Sc06, 1996FiZX, 2003Au03 236U T Auger electrons and X ray energies and emission intensities: 236U T {U Energy (keV)} {U Intensity} {U Line} @@ -11,7 +11,7 @@ 236U T 98.44 15.8 15 XKA1 236U T 236U T 110.421 |] XKB3 -236U T 111.298 |] 5.7 6 XKB1 +236U T 111.298 |] 5.7 6 XKB1 236U T 111.964 |] XKB5II 236U T 236U T 114.407 |] XKB2 @@ -19,45 +19,45 @@ 236U T 115.377 |] XKO23 236U T 236U T 11.618-20.714 21.3 18 XL (total) -236U T 11.618 0.57 5 XLL -236U T 13.438-13.614 9.1 8 XLA +236U T 11.618 0.57 5 XLL +236U T 13.438-13.614 9.1 8 XLA 236U T 15.399 0.166 17 XLC -236U T 15.726-18.206 9.4 6 XLB +236U T 15.726-18.206 9.4 6 XLB 236U T 19.507-20.714 2.07 15 XLG 236U T 236U T 71.776-80.954 |] KLL AUGER 236U T 88.153-98.429 |] 1.03 17 KLX AUGER 236U T 104.51-115.59 |] KXY AUGER 236U T 6.4-21.6 21.7 15 L AUGER -236NP P 60 501+ 22.5 H 4 930 50 +236NP P 0.0 1+ 22.5 H 4 993 13 236U N 1.887E0 1.887E0 0.53 1.887E0 -236U L 0 0+ STABLE +236U L 0 0+ 23.43E6 Y 6 236U E 43.1 327.1 -236U 2 E EAV= $CK=0.753 1$CL=0.182 1$CM=0.0646 1$CN= $CO= +236U 2 E CK=0.753 1$CL=0.182 1$CM=0.0646 1 236U L 45.242 3 2+ 234 PS 236U E 8.3 307.8 -236U 2 E EAV= $CK=0.751 1$CL=0.184 1$CM=0.0652 1$CN= $CO= -236U G 45.242 3 0.016 5 E2 589 12 -236U 2 G KC=$LC=429 9$MC=118.6 24 +236U 2 E CK=0.751 1$CL=0.184 1$CM=0.0652 1 +236U G 45.242 3 0.016 5E2 589 12 +236U 2 G LC=429 9$MC=118.6 24 236U L 149.476 154+ 124 PS -236U G 104.234 6 0.00119 14E2 11.0 2 -236U 2 G KC=$LC=8.00 16$MC=2.22 5 +236U G 104.234 6 0.00119 14E2 11.0 2 +236U 2 G LC=8.00 16$MC=2.22 5 236U L 309.783 6+ 58 PS 236U L 687.60 5 1- 3.8 NS -236U E 1.64 9 7.3 -236U 2 E EAV= $CK=0.621 10$CL=0.274 7$CM=0.105 3$CN= $CO= -236U G 538.11 100.0125 15E3 0.143 3 -236U 2 G KC=0.0622 13$LC=0.0587 12$MC=0.0160 4 -236U G 642.35 9 1.08 6 E1+(M2+E3) 0.15 2 -236U 2 G KC=0.112 10$LC=0.031 3$MC=0.0080 8 -236U G 687.60 5 0.292 21E1 0.31 2 -236U 2 G KC=0.219 12$LC=0.068 6$MC=0.018 2 +236U E 1.64 97.3 +236U 2 E CK=0.621 10$CL=0.274 7$CM=0.105 3 +236U G 538.11 100.0125 15E3 0.143 3 +236U 2 G KC=0.0622 13$LC=0.0587 12$MC=0.0160 4 +236U G 642.35 9 1.08 6E1+(M2+E3) 0.15 2 +236U 2 G KC=0.112 10$LC=0.031 3$MC=0.0080 8 +236U G 687.60 5 0.292 21E1 0.31 2 +236U 2 G KC=0.219 12$LC=0.068 6$MC=0.018 2 236PU 236NP B- DECAY (22.5 H) 236PU H TYP=Full$AUT=V.P.Chechev$CUT=18-JUN-2006$ 236PU C Evaluation history: Type=Full;Author=V.P.Chechev;Cutoff date=18-JUN-2006 236PU C References: 1949Ja01, 1956Gr11, 1959Gi58, 1967Be65, 1969Le05, 1971GuZY, -236PU2C 1971Dr11, 1975OtZX, 1975Dr05, 1976GuZN, 1977Po05, 1977La19, 1984Gr33, +236PU2C 1971Dr11, 1975Dr05, 1975OtZX, 1976GuZN, 1977Po05, 1977La19, 1984Gr33, 236PU3C 1987Lag., 1991Sc08, 1996Sc06, 1996FiZX, 2003Au03 236PU T Auger electrons and X ray energies and emission intensities: 236PU T {U Energy (keV)} {U Intensity} {U Line} @@ -74,24 +74,24 @@ 236PU T 121.543 |] XKO23 236PU T 236PU T 12.124-21.984 4.2 16 XL (total) -236PU T 12.124 0.10 4 XLL -236PU T 14.083-14.279 1.5 6 XLA +236PU T 12.124 0.10 4 XLL +236PU T 14.083-14.279 1.5 6 XLA 236PU T 16.334 0.046 17 XLC -236PU T 16.498-19.331 2.1 8 XLB +236PU T 16.498-19.331 2.1 8 XLB 236PU T 20.708-21.984 0.49 18 XLG 236PU T 236PU T 75.263-85.357 |] KLL AUGER 236PU T 92.607-103.729 |] KLX AUGER 236PU T 109.93-121.78 |] KXY AUGER 236PU T 6.19-22.99 3.8 14 L AUGER -236NP P 60 501+ 22.5 H 4 480 50 +236NP P 0.0 1+ 22.5 H 4 537 8 236PU N 2.128E0 2.128E0 0.47 2.128E0 236PU L 0 0+ STABLE -236PU B 537 8 36 4 6.8 +236PU B 537 8 36 4 6.8 236PUS B EAV=158 3 236PU L 44.63 102+ -236PU B 492 8 11 4 7.2 +236PU B 492 8 11 4 7.2 236PUS B EAV=143 3 -236PU G 44.63 100.015 5 E2 743 15 -236PU2 G KC=$LC=540 11$MC=151 3 +236PU G 44.63 100.015 5E2 743 15 +236PU2 G LC=540 11$MC=151 3 diff --git a/HEN_HOUSE/spectra/lnhb/Np-237.txt b/HEN_HOUSE/spectra/lnhb/Np-237.txt index 8b19b354e..9ad2fb4ee 100644 --- a/HEN_HOUSE/spectra/lnhb/Np-237.txt +++ b/HEN_HOUSE/spectra/lnhb/Np-237.txt @@ -11,75 +11,75 @@ 233PA4C 1990Bo44, 1992Lo03, 1992Gr16, 2000Sc04, 2000Si02, 2000Wo01, 2002Lu01, 233PA5C 2002Wo03, 2002Ba85, 2003Au03, 2004Sh07, 2005Si15, 2006Ch39, 2008De10, 233PA6C 2008Ki07 -233PA T Auger electrons and ^X ray energies and emission intensities: -233PA T {U Energy (keV)} {U Intensity } {U Line } +233PA T Auger electrons and X ray energies and emission intensities: +233PA T {U Energy (keV)} {U Intensity} {U Line} 233PA T -233PA T 92.288 1.813 20 XKA2 -233PA T 95.869 2.906 20 XKA1 +233PA T 92.288 1.813 20 XKA2 +233PA T 95.869 2.906 20 XKA1 233PA T -233PA T 107.595 |] XKB3 -233PA T 108.422 |] 1.06 10 XKB1 -233PA T 109.072 |] XKB5II +233PA T 107.595 |] XKB3 +233PA T 108.422 |] 1.06 10 XKB1 +233PA T 109.072 |] XKB5II 233PA T -233PA T 111.405 |] XKB2 -233PA T 111.87 |] 0.380 9 XKB4 -233PA T 112.38 |] XKO23 +233PA T 111.405 |] XKB2 +233PA T 111.87 |] 0.380 9 XKB4 +233PA T 112.38 |] XKO23 233PA T -233PA T 11.368-20.113 59.7 32 XL (total) -233PA T 11.368 1.32 8 XLL -233PA T 13.122-13.289 24.0 24 XLA -233PA T 14.949 0.54 4 XLC -233PA T 15.358-17.666 28 2 XLB -233PA T 18.94-20.113 5.8 4 XLG +233PA T 11.368-20.113 59.7 32 XL (total) +233PA T 11.368 1.32 8 XLL +233PA T 13.122-13.289 24.0 24 XLA +233PA T 14.949 0.54 4 XLC +233PA T 15.358-17.666 28 2 XLB +233PA T 18.94-20.113 5.8 4 XLG 233PA T -233PA T 70.08-78.82 |] KLL AUGER -233PA T 85.99-95.86 |] 0.167 24 ^KLX AUGER -233PA T 101.87-112.59 |] KXY AUGER -233PA T 5.9-21.01 47.1 20 L AUGER +233PA T 70.08-78.82 |] KLL AUGER +233PA T 85.99-95.86 |] 0.167 24 KLX AUGER +233PA T 101.87-112.59 |] KXY AUGER +233PA T 5.9-21.01 47.1 20 L AUGER 237NP P 0.0 5/2+ 2.144E6 Y 7 4958.3 12 233PA N 1.0 1.0 1 1.0 233PA G 21.5 0.352 13 -233PA G 27.7 0.84 7 +233PA G 27.7 0.84 7 233PA G 29.6 -233PA G 288.3 0.0162 5 +233PA G 288.3 0.0162 5 233PA L 0 3/2- 26.98 D 2 233PA A 4872.7 142.41 3 387 233PA L 6.654 251/2- 233PA A 4866.4 140.51 3 1570 233PA A 4550.5 220.011 3 84000 233PA G 6.65 5 (M1) 3080 90 -233PA2 G KC=$LC=$MC=2280 60 +233PA2 G MC=2280 60 233PA L 57.101 147/2- 233PA A 4816.8 102.430 17156 -233PA G 57.104 200.381 21E2 176 4 -233PA2 G KC=$LC=128 3$MC=35.3 7 +233PA G 57.104 200.381 21E2 176 4 +233PA2 G LC=128 3$MC=35.3 7 233PA L 70.510 255/2- 233PA A 4803.5 102.02 2 152 -233PA G 63.9 1 0.0107 4 (E2) 102.3 20 -233PA2 G KC=$LC=74.7 15$MC=20.6 4 -233PA G 70.49 100.0107 4 [M1+E2] 1 1 38 26 -233PA2 G KC=$LC=28 19$MC=8 5 +233PA G 63.9 1 0.0107 4(E2) 102.3 20 +233PA2 G LC=74.7 15$MC=20.6 4 +233PA G 70.49 100.0107 4[M1+E2] 1 1 38 26 +233PA2 G LC=28 19$MC=8 5 233PA L 86.469 9 5/2+ 35.8 NS 4 233PA A 4788.0 9 47.64 6 5 -233PA G 29.374 2014.3 6 E1 3.07 6 -233PA2 G KC=$LC=2.29 5$MC=0.585 12 -233PA G 86.477 1012.26 12E1 1.43 8 -233PA2 G KC=$LC=1.13 5$MC=0.22 6 +233PA G 29.374 2014.3 6E1 3.07 6 +233PA2 G LC=2.29 5$MC=0.585 12 +233PA G 86.477 1012.26 12E1 1.43 8 +233PA2 G LC=1.13 5$MC=0.22 6 233PA L 94.645 163/2+ -233PA G 8.22 5 0.12 5 -233PA G 87.99 3 0.143 3 [E1] 0.169 4 -233PA2 G KC=$LC=0.128 3$MC=0.0312 6 -233PA G 94.64 5 0.66 7 E1 0.140 3 -233PA2 G KC=$LC=0.1054 21$MC=0.0257 5 +233PA G 8.22 5 0.12 5 +233PA G 87.99 3 0.143 3[E1] 0.169 4 +233PA2 G LC=0.128 3$MC=0.0312 6 +233PA G 94.64 5 0.66 7E1 0.140 3 +233PA2 G LC=0.1054 21$MC=0.0257 5 233PA L 103.636 207/2+ 233PA A 4771.4 8 23.0 3 7.8 233PA G 9 233PA G 17.40 5 M1+E2 -233PA G 46.53 6 0.109 4 [E1] 0.914 18 -233PA2 G KC=$LC=0.687 14$MC=0.171 4 +233PA G 46.53 6 0.109 4[E1] 0.914 18 +233PA2 G LC=0.687 14$MC=0.171 4 233PA L 109.04 5 9/2+ 233PA A 4766.5 8 9.5 3 17.9 -233PA G 5.18 0.220 5 +233PA G 5.18 0.220 5 233PA G 22.6 233PA L 133.2 10(11/2+)+ 233PA A 4741.3 200.019 5932 @@ -88,56 +88,56 @@ 233PA A 4712.3 201.174 1351 233PA G 54.4 1 233PA G 106.15 250.0509 29[E2] 9.28 19 -233PA2 G KC=$LC=6.78 14$MC=1.87 4 +233PA2 G LC=6.78 14$MC=1.87 4 233PA L 169.152 201/2+ 233PA A 4708.3 200 56 -233PA G 74.54 100.012 3 [M1] 9.84 20 -233PA2 G KC=$LC=7.42 15$MC=1.79 4 -233PA G 162.41 8 0.033 1 [E1] 0.158 3 -233PA2 G KC=0.1232 25$LC=0.0260 5$MC=0.00630 13 -233PA G 169.156 200.0672 3 [E1] 0.143 3 -233PA2 G KC=0.1120 22$LC=0.0235 5$MC=0.00568 11 +233PA G 74.54 100.012 3[M1] 9.84 20 +233PA2 G LC=7.42 15$MC=1.79 4 +233PA G 162.41 8 0.033 1[E1] 0.158 3 +233PA2 G KC=0.1232 25$LC=0.0260 5$MC=0.00630 13 +233PA G 169.156 200.0672 3[E1] 0.143 3 +233PA2 G KC=0.1120 22$LC=0.0235 5$MC=0.00568 11 233PA L 179.1 4 (9/2-)- 233PA A 4698.2 8 0.535 1099 233PA G 109.1 1 233PA L 201.594 193/2+ 233PA A 4676.4 0.38 2 233PA G 32.46 -233PA G 115.40 350.0026 8 [M1+E2] 10 4 -233PA2 G KC=5 6$LC=3.3 13$MC=0.9 4 -233PA G 131.101 250.084 5 E1 0.262 5 -233PA2 G KC=0.202 4$LC=0.0451 9$MC=0.01094 22 +233PA G 115.40 350.0026 8[M1+E2] 10 4 +233PA2 G KC=5 6$LC=3.3 13$MC=0.9 4 +233PA G 131.101 250.084 5E1 0.262 5 +233PA2 G KC=0.202 4$LC=0.0451 9$MC=0.01094 22 233PA G 194.95 3 0.174 20E1 0.1024 21 -233PA2 G KC=0.0806 16$LC=0.0164 4$MC=0.00397 8 -233PA G 201.62 5 0.0392 9 E1 0.0946 19 -233PA2 G KC=0.0746 15$LC=0.0151 3$MC=0.00365 7 +233PA2 G KC=0.0806 16$LC=0.0164 4$MC=0.00397 8 +233PA G 201.62 5 0.0392 9E1 0.0946 19 +233PA2 G KC=0.0746 15$LC=0.0151 3$MC=0.00365 7 233PA L 212.342 185/2+ 233PA A 4665.0 9 3.46 3 8.9 233PA G 10.7 233PA G 43.2 -233PA G 108.7 0.071 3 M1+E2 0.22 3.5 6 -233PA2 G KC=$LC=2.7 5$MC=0.65 13 -233PA G 117.702 200.171 4 M1+E2 0.30 9 12.2 6 -233PA2 G KC=9.3 5$LC=2.16 12$MC=0.53 4 +233PA G 108.7 0.071 3M1+E2 0.22 3.5 6 +233PA2 G LC=2.7 5$MC=0.65 13 +233PA G 117.702 200.171 4M1+E2 0.30 9 12.2 6 +233PA2 G KC=9.3 5$LC=2.16 12$MC=0.53 4 233PA G 141.74 10 -233PA G 155.239 200.088 8 E1 0.176 4 -233PA2 G KC=0.1368 27$LC=0.0292 6$MC=0.00708 14 -233PA G 212.29 5 0.17 1 E1 0.0839 17 -233PA2 G KC=0.0663 13$LC=0.0133 3$MC=0.00321 7 +233PA G 155.239 200.088 8E1 0.176 4 +233PA2 G KC=0.1368 27$LC=0.0292 6$MC=0.00708 14 +233PA G 212.29 5 0.17 1E1 0.0839 17 +233PA2 G KC=0.0663 13$LC=0.0133 3$MC=0.00321 7 233PA L 237.895 135/2+ 233PA A 4640 1 6.43 3 3.14 -233PA G 36.32 2 0.005 1 M1+E2 0.11 5 99 20 -233PA2 G KC=$LC=74 15$MC=18 4 -233PA G 134.285 200.069 5 [M1+E2] 0.4 2 8.0 11 -233PA2 G KC=6.1 10$LC=1.5 3$MC=0.37 8 -233PA G 143.249 200.42 4 M1+E2 0.29 3 6.94 14 -233PA2 G KC=5.38 12$LC=1.171 24$MC=0.287 6 -233PA G 151.414 200.234 2 M1+E2 0.70 15 4.9 6 -233PA2 G KC=3.4 5$LC=1.09 4$MC=0.277 14 -233PA G 180.81 100.016 1 [E1] 0.1223 25 -233PA2 G KC=0.0960 19$LC=0.0199 4$MC=0.0048 1 -233PA G 237.86 2 0.0573 6 [E1] 0.0645 13 -233PA2 G KC=0.0511 10$LC=0.01010 15$MC=0.00243 5 +233PA G 36.32 2 0.005 1M1+E2 0.11 5 99 20 +233PA2 G LC=74 15$MC=18 4 +233PA G 134.285 200.069 5[M1+E2] 0.4 2 8.0 11 +233PA2 G KC=6.1 10$LC=1.5 3$MC=0.37 8 +233PA G 143.249 200.42 4M1+E2 0.29 3 6.94 14 +233PA2 G KC=5.38 12$LC=1.171 24$MC=0.287 6 +233PA G 151.414 200.234 2M1+E2 0.70 15 4.9 6 +233PA2 G KC=3.4 5$LC=1.09 4$MC=0.277 14 +233PA G 180.81 100.016 1[E1] 0.1223 25 +233PA2 G KC=0.0960 19$LC=0.0199 4$MC=0.0048 1 +233PA G 237.86 2 0.0573 6[E1] 0.0645 13 +233PA2 G KC=0.0511 10$LC=0.01010 15$MC=0.00243 5 233PA L 257.1 4 5/2- 233PA A 4619.7 210.032 8 46000 233PA G 153.37 @@ -149,51 +149,51 @@ 233PA G 257.09 233PA L 279.71 3 (7/2+)+ 233PA A 4599.1 180.373 9 27 -233PA G 170.59 6 0.020 4 [M1+E2] 0.4 2 4.0 5 -233PA2 G KC=3.1 5$LC=0.70 7$MC=0.17 1 -233PA G 176.12 6 0.015 3 [M1+E2] 0.4 2 3.7 5 -233PA2 G KC=2.8 4$LC=0.63 7$MC=0.16 1 -233PA G 193.26 5 0.044 1 [M1+E2] 0.4 2 2.8 4 -233PA2 G KC=2.2 3$LC=0.48 5$MC=0.12 1 +233PA G 170.59 6 0.020 4[M1+E2] 0.4 2 4.0 5 +233PA2 G KC=3.1 5$LC=0.70 7$MC=0.17 1 +233PA G 176.12 6 0.015 3[M1+E2] 0.4 2 3.7 5 +233PA2 G KC=2.8 4$LC=0.63 7$MC=0.16 1 +233PA G 193.26 5 0.044 1[M1+E2] 0.4 2 2.8 4 +233PA2 G KC=2.2 3$LC=0.48 5$MC=0.12 1 233PA G 209.19 5 0.0150 15[E1] 0.0868 17 -233PA2 G KC=0.0686 14$LC=0.0138 3$MC=0.00333 7 -233PA G 222.6 2 0.002 2 +233PA2 G KC=0.0686 14$LC=0.0138 3$MC=0.00333 7 +233PA G 222.6 2 0.002 2 233PA L 300.48 3 7/2++ 233PA A 4578.6 140.393 2319.1 -233PA G 62.59 100.006 2 [M1+E2] 1 1 60 50 -233PA2 G KC=$LC=50 40$MC=13 10 -233PA G 191.46 5 0.019 1 [M1+E2] 0.4 2 2.9 4 -233PA2 G KC=2.2 3$LC=0.49 5$MC=0.12 1 -233PA G 196.86 5 0.0210 1 [M1+E2] 0.4 2 2.7 3 -233PA2 G KC=2.1 3$LC=0.45 5$MC=0.11 1 -233PA G 214.01 5 0.037 2 [M1+E2] 0.4 2 2.1 3 -233PA2 G KC=1.64 23$LC=0.35 1$MC=0.09 1 -233PA G 229.94 5 0.014 3 [E1] 0.0697 14 -233PA2 G KC=0.0552 11$LC=0.0110 2$MC=0.00264 5 +233PA G 62.59 100.006 2[M1+E2] 1 1 60 50 +233PA2 G LC=50 40$MC=13 10 +233PA G 191.46 5 0.019 1[M1+E2] 0.4 2 2.9 4 +233PA2 G KC=2.2 3$LC=0.49 5$MC=0.12 1 +233PA G 196.86 5 0.0210 1[M1+E2] 0.4 2 2.7 3 +233PA2 G KC=2.1 3$LC=0.45 5$MC=0.11 1 +233PA G 214.01 5 0.037 2[M1+E2] 0.4 2 2.1 3 +233PA2 G KC=1.64 23$LC=0.35 1$MC=0.09 1 +233PA G 229.94 5 0.014 3[E1] 0.0697 14 +233PA2 G KC=0.0552 11$LC=0.0110 2$MC=0.00264 5 233PA L 303.59 7 (9/2+)+ 233PA A 4573 3 0.048 23139 -233PA G 139.9 1 0.0046 4 [E1] 0.225 5 -233PA2 G KC=0.174 3$LC=0.0381 8$MC=0.00925 19 -233PA G 194.67 200.033 1 -233PA G 199.95 6 0.0053 8 [M1] 2.85 6 -233PA2 G KC=2.27 5$LC=0.436 9$MC=0.105 2 +233PA G 139.9 1 0.0046 4[E1] 0.225 5 +233PA2 G KC=0.174 3$LC=0.0381 8$MC=0.00925 19 +233PA G 194.67 200.033 1 +233PA G 199.95 6 0.0053 8[M1] 2.85 6 +233PA2 G KC=2.27 5$LC=0.436 9$MC=0.105 2 233PA L 306.05 10(7/2+)+ 233PA G 48.96 10 233PA G 219.8 -233PA G 248.95 100.005 1 [M1+E2] 0.4 2 1.37 16 -233PA2 G KC=1.08 15$LC=0.22 1$MC=0.055 6 +233PA G 248.95 100.005 1[M1+E2] 0.4 2 1.37 16 +233PA2 G KC=1.08 15$LC=0.22 1$MC=0.055 6 233PA L 365.93 8 9/2+ 233PA A 4515.1 190.038 4 65 -233PA G 153.37 100.007 2 [E2] 1.96 4 -233PA2 G KC=0.226 5$LC=1.267 3$MC=0.349 7 -233PA G 186.86 350.003 3 [E1] 0.1131 23 -233PA2 G KC=0.0889 19$LC=0.0183 4$MC=0.00442 9 +233PA G 153.37 100.007 2[E2] 1.96 4 +233PA2 G KC=0.226 5$LC=1.267 3$MC=0.349 7 +233PA G 186.86 350.003 3[E1] 0.1131 23 +233PA2 G KC=0.0889 19$LC=0.0183 4$MC=0.00442 9 233PA G 202.9 2 0.0048 19[E1] 0.0932 19 -233PA2 G KC=0.074 5$LC=0.0149 3$MC=0.00360 7 -233PA G 257.09 200.02 1 [M1] 1.41 3 -233PA2 G KC=1.125 23$LC=0.215 4$MC=0.0518 11 -233PA G 262.44 200.0048 2 [M1] 1.33 3 -233PA2 G KC=1.063 21$LC=0.203 4$MC=0.0489 10 -233PA G 279.65 200.0108 4 [E2] 0.222 5 -233PA2 G KC=0.0847 17$LC=0.100 2$MC=0.0272 6 +233PA2 G KC=0.074 5$LC=0.0149 3$MC=0.00360 7 +233PA G 257.09 200.02 1[M1] 1.41 3 +233PA2 G KC=1.125 23$LC=0.215 4$MC=0.0518 11 +233PA G 262.44 200.0048 2[M1] 1.33 3 +233PA2 G KC=1.063 21$LC=0.203 4$MC=0.0489 10 +233PA G 279.65 200.0108 4[E2] 0.222 5 +233PA2 G KC=0.0847 17$LC=0.100 2$MC=0.0272 6 diff --git a/HEN_HOUSE/spectra/lnhb/Np-238.txt b/HEN_HOUSE/spectra/lnhb/Np-238.txt index 5fbf560a5..0686fac57 100644 --- a/HEN_HOUSE/spectra/lnhb/Np-238.txt +++ b/HEN_HOUSE/spectra/lnhb/Np-238.txt @@ -4,143 +4,143 @@ 238PU C References: 1950Fr53, 1952Du12, 1956Ba95, 1956Sm18, 1958Al92, 1960As10, 238PU2C 1960Al29, 1965Ak02, 1966Qa01, 1970Be57, 1972Wi22, 1981Le15, 1990Ch35, 238PU3C 1996Sc06, 2002Ch52, 2003Au03, 2006Re09 -238PU T Auger electrons and ^X ray energies and emission intensities: -238PU T {U Energy (keV)} {U Intensity } {U Line } +238PU T Auger electrons and X ray energies and emission intensities: +238PU T {U Energy (keV)} {U Intensity} {U Line} 238PU T -238PU T 99.525 0.210 8 XKA2 -238PU T 103.734 0.332 12 XKA1 +238PU T 99.525 0.210 8 XKA2 +238PU T 103.734 0.332 12 XKA1 238PU T -238PU T 116.244 |] XKB3 -238PU T 117.228 |] 0.122 5 XKB1 -238PU T 117.918 |] XKB5II +238PU T 116.244 |] XKB3 +238PU T 117.228 |] 0.122 5 XKB1 +238PU T 117.918 |] XKB5II 238PU T -238PU T 120.54 |] XKB2 -238PU T 120.969 |] 0.042 2 XKB4 -238PU T 121.543 |] XKO23 +238PU T 120.54 |] XKB2 +238PU T 120.969 |] 0.042 2 XKB4 +238PU T 121.543 |] XKO23 238PU T -238PU T 12.125-21.984 32.4 14 XL (total) -238PU T 12.125 0.797 25 XLL -238PU T 14.083-14.279 12.5 4 XLA -238PU T 16.334 0.338 12 XLC -238PU T 16.499-19.331 15.4 5 XLB -238PU T 20.708-21.984 3.58 10 XLG +238PU T 12.125-21.984 32.4 14 XL (total) +238PU T 12.125 0.797 25 XLL +238PU T 14.083-14.279 12.5 4 XLA +238PU T 16.334 0.338 12 XLC +238PU T 16.499-19.331 15.4 5 XLB +238PU T 20.708-21.984 3.58 10 XLG 238PU T -238PU T 75.26-85.36 |] KLL AUGER -238PU T 92.607-103.729 |] 0.021 8 ^KLX AUGER -238PU T 109.93-121.78 |] KXY AUGER -238PU T 6.19-22.99 29.7 14 L AUGER +238PU T 75.26-85.36 |] KLL AUGER +238PU T 92.607-103.729 |] 0.021 8 KLX AUGER +238PU T 109.93-121.78 |] KXY AUGER +238PU T 6.19-22.99 29.7 14 L AUGER 238NP P 0.0 2+ 2.102 D 5 1291.5 4 238PU N 1.0 1.0 1 1.0 -238PU G 103.74 2 0.312 3 -238PU G 116.27 8 4000E-5 0 -238PU G 117.27 8 7400E-5 0 -238PU G 120.5 2000E-5 0 -238PU G 121.70 8 0.010 1 -238PU G 220.87 110.0030 5 (M2) 11.4 20 -238PU G 885 0.040 5 +238PU G 103.74 2 0.312 3 +238PU G 116.27 8 0.04 +238PU G 117.27 8 0.074 +238PU G 120.5 0.02 +238PU G 121.70 8 0.010 1 +238PU G 220.87 110.0030 5(M2) 11.4 20 +238PU G 885 0.040 5 238PU L 0 0+ 87.74 Y 3 238PU L 44.08 2 2+ 177 PS 5 238PU B 1247.4 4 41.0 25 8.38 238PUS B EAV=412.2 2 238PU G 44.07 2 0.1024 21E2 788 16 -238PU2 G KC=$LC=572 12$MC=160 3 +238PU2 G LC=572 12$MC=160 3 238PU L 145.95 2 4+ -238PU G 101.88 2 0.252 8 E2 14.5 3 -238PU2 G KC=$LC=10.5 2$MC=2.94 6 +238PU G 101.88 2 0.252 8E2 14.5 3 +238PU2 G LC=10.5 2$MC=2.94 6 238PU L 303.38 6 6+ -238PU G 157.42 5 1000E-6 0 [E2] 2.19 4 -238PU2 G KC=0.193 4$LC=1.45 3$MC=0.405 8 +238PU G 157.42 5 0.001 [E2] 2.19 4 +238PU2 G KC=0.193 4$LC=1.45 3$MC=0.405 8 238PU L 605.14 4 1- -238PU B 686.4 4 0.103 3 10.08 1 +238PU B 686.4 4 0.103 3 10.08 1 238PUS B EAV=208.4 2 -238PU G 561.14 5 0.106 2 E1 0.0115 2 -238PU2 G KC=0.00929 19$LC=0.00169 4$MC=4.07E-4 8 -238PU G 605.16 5 0.077 2 E1 0.0100 2 -238PU2 G KC=0.00806 16$LC=0.00146 3$MC=3.50E-4 7 +238PU G 561.14 5 0.106 2E1 0.0115 2 +238PU2 G KC=0.00929 19$LC=0.00169 4$MC=4.07E-4 8 +238PU G 605.16 5 0.077 2E1 0.0100 2 +238PU2 G KC=0.00806 16$LC=0.00146 3$MC=3.50E-4 7 238PU L 661.40 6 3- -238PU B 630.1 4 0.036 3 10.44 1 +238PU B 630.1 4 0.036 3 10.44 1 238PUS B EAV=189.2 2 -238PU G 515.51 7 0.0378 11E1+M2 0.114 17 0.022 4 -238PU2 G KC=0.017 3$LC=0.0037 7$MC=0.00092 17 -238PU G 617.39 5 5930E-5 0 E1+M2 0.077 17 0.0120 14 -238PU2 G KC=0.0095 11$LC=0.00185 22$MC=0.00045 5 +238PU G 515.51 7 0.0378 11E1+M2 0.114 17 0.022 4 +238PU2 G KC=0.017 3$LC=0.0037 7$MC=0.00092 17 +238PU G 617.39 5 0.0593 E1+M2 0.077 17 0.0120 14 +238PU2 G KC=0.0095 11$LC=0.00185 22$MC=0.00045 5 238PU L 763.24 115- 238PU G 459.8 2 0.0023 15 -238PU G 617.4 8000E-6 0 +238PU G 617.4 0.008 238PU L 941.46 8 0+ -238PU G 336.36 150.0002 1 [E1] 0.0324 7 -238PU2 G KC=0.0257 5$LC=0.00503 10$MC=0.00122 3 -238PU G 897.34 100.0073 10(E2) 0.0152 3 -238PU2 G KC=0.0111 2$LC=0.00308 6$MC=0.00078 2 +238PU G 336.36 150.0002 1[E1] 0.0324 7 +238PU2 G KC=0.0257 5$LC=0.00503 10$MC=0.00122 3 +238PU G 897.34 100.0073 10(E2) 0.0152 3 +238PU2 G KC=0.0111 2$LC=0.00308 6$MC=0.00078 2 238PU G 941.5 3 238PU L 962.78 2 1- -238PU B 328.7 4 1.25 1 7.95 1 +238PU B 328.7 4 1.25 1 7.95 1 238PUS B EAV=91.8 2 -238PU G 301.37 7 0.0106 10E2 0.208 4 -238PU2 G KC=0.0766 16$LC=0.096 2$MC=0.0264 5 +238PU G 301.37 7 0.0106 10E2 0.208 4 +238PU2 G KC=0.0766 16$LC=0.096 2$MC=0.0264 5 238PU G 357.64 7 0.0504 13M1+E2 2.43 20 0.214 16 -238PU2 G KC=0.133 12$LC=0.060 5$MC=0.0158 12 -238PU G 918.70 4 0.529 6 E1 0.0047 1 -238PU2 G KC=0.00383 8$LC=0.00066 1$MC=1.58E-4 3 -238PU G 962.76 2 0.645 8 E1 0.004339 -238PU2 G KC=0.00352 7$LC=0.00061 1$MC=1.45E-4 3 +238PU2 G KC=0.133 12$LC=0.060 5$MC=0.0158 12 +238PU G 918.70 4 0.529 6E1 0.0047 1 +238PU2 G KC=0.00383 8$LC=0.00066 1$MC=1.58E-4 3 +238PU G 962.76 2 0.645 8E1 0.00433 9 +238PU2 G KC=0.00352 7$LC=0.00061 1$MC=1.45E-4 3 238PU L 968.2 4 (2)- -238PU B 323.3 6 0.082 6 9.11 +238PU B 323.3 6 0.082 6 9.11 238PUS B EAV=90.1 2 -238PU G 924 6500E-5 0 -238PU G 968.9 4 0.015 8 [M2] 0.116 3 -238PU2 G KC=0.089 2$LC=0.0200 4$MC=0.0050 1 +238PU G 924 0.065 +238PU G 968.9 4 0.015 8[M2] 0.116 3 +238PU2 G KC=0.089 2$LC=0.0200 4$MC=0.0050 1 238PU L 983.09 7 2+ -238PU B 308.4 4 0.27 3 8.51 +238PU B 308.4 4 0.27 3 8.51 238PUS B EAV=85.6 2 -238PU G 321.75 200.0013 8 -238PU G 378.05 130.0030 5 -238PU G 836.96 7 0.0206 8 [E2] 0.0174 4 -238PU2 G KC=0.0125 3$LC=0.00366 8$MC=0.00093 2 -238PU G 938.94 100.0327 25+E2 4.4 4 -238PU2 G KC=3.5 4$LC=0.67 7$MC= -238PU G 983.0 3 0.068 20[E2] 0.0128 3 -238PU2 G KC=0.00947 19$LC=0.00247 5$MC=0.00062 1 +238PU G 321.75 200.0013 8 +238PU G 378.05 130.0030 5 +238PU G 836.96 7 0.0206 8[E2] 0.0174 4 +238PU2 G KC=0.0125 3$LC=0.00366 8$MC=0.00093 2 +238PU G 938.94 100.0327 25+E2 4.4 4 +238PU2 G KC=3.5 4$LC=0.67 7 +238PU G 983.0 3 0.068 20[E2] 0.0128 3 +238PU2 G KC=0.00947 19$LC=0.00247 5$MC=0.00062 1 238PU L 985.45 5 2- -238PU B 306.0 4 0.49 1 8.25 +238PU B 306.0 4 0.49 1 8.25 238PUS B EAV=84.9 2 -238PU G 324.02 9 0.0146 8 M1+E2 2.8 8 0.26 7 -238PU2 G KC=0.15 6$LC=0.082 7$MC=0.022 2 -238PU G 380.31 100.0111 5 [M1] 0.623 9 -238PU2 G KC=0.493 10$LC=0.098 2$MC=0.0237 5 -238PU G 941.40 4 0.504 6 [E1+M2] +238PU G 324.02 9 0.0146 8M1+E2 2.8 8 0.26 7 +238PU2 G KC=0.15 6$LC=0.082 7$MC=0.022 2 +238PU G 380.31 100.0111 5[M1] 0.623 9 +238PU2 G KC=0.493 10$LC=0.098 2$MC=0.0237 5 +238PU G 941.40 4 0.504 6[E1+M2] 238PU L 1028.54 2 2+ 238PU B 263.0 4 44.75 19 6.09 238PUS B EAV=72.0 2 -238PU G 882.63 3 0.803 9 (E2) 0.0157 3 -238PU2 G KC=0.0114 2$LC=0.00320 7$MC=0.00081 2 -238PU G 984.45 2 25.18 13M1+E2 0.0125 5 -238PU2 G KC=0.0096 3$LC=0.0022 1$MC=0.0006 1 -238PU G 1028.54 2 18.25 13E2 0.0117 2 -238PU2 G KC=0.00875 18$LC=0.00222 5$MC=0.00055 1 +238PU G 882.63 3 0.803 9(E2) 0.0157 3 +238PU2 G KC=0.0114 2$LC=0.00320 7$MC=0.00081 2 +238PU G 984.45 2 25.18 13M1+E2 0.0125 5 +238PU2 G KC=0.0096 3$LC=0.0022 1$MC=0.0006 1 +238PU G 1028.54 2 18.25 13E2 0.0117 2 +238PU2 G KC=0.00875 18$LC=0.00222 5$MC=0.00055 1 238PU L 1069.94 2 3+ -238PU B 221.6 4 11.50 7 6.44 +238PU B 221.6 4 11.50 7 6.44 238PUS B EAV=59.9 2 -238PU G 923.99 2 2.604 20(M1+E2) 0.014 1 -238PU2 G KC=0.0099 4$LC=$MC= -238PU G 1025.87 2 8.76 6 M1+E2 0.0120 5 -238PU2 G KC=0.0091 4$LC=0.0021 1$MC=0.0006 1 +238PU G 923.99 2 2.604 20(M1+E2) 0.014 1 +238PU2 G KC=0.0099 4 +238PU G 1025.87 2 8.76 6M1+E2 0.0120 5 +238PU2 G KC=0.0091 4$LC=0.0021 1$MC=0.0006 1 238PU L 1082.56 6 (4)- 238PU G 114.4 4 0.0058 10[E2] 8.47 17 -238PU2 G KC=$LC=6.15 12$MC=1.72 14 +238PU2 G LC=6.15 12$MC=1.72 14 238PU G 319.29 110.0083 10M1+E2 1.0 5 0.59 25 -238PU2 G KC=0.43 22$LC=0.118 25$MC=0.030 5 -238PU G 421.1 1 0.021 1 [M1] 0.472 7 -238PU2 G KC=0.374 8$LC=0.0737 15$MC=0.0179 4 -238PU G 936.60 5 0.365 5 [E1+M2] -0.24 4 0.0112 22 -238PU2 G KC=0.0089 17$LC=0.0018 4$MC=0.00044 10 +238PU2 G KC=0.43 22$LC=0.118 25$MC=0.030 5 +238PU G 421.1 1 0.021 1[M1] 0.472 7 +238PU2 G KC=0.374 8$LC=0.0737 15$MC=0.0179 4 +238PU G 936.60 5 0.365 5[E1+M2] -0.24 4 0.0112 22 +238PU2 G KC=0.0089 17$LC=0.0018 4$MC=0.00044 10 238PU L 1202.46 8 (3)- -238PU B 89.0 4 0.51 6 6.57 1 +238PU B 89.0 4 0.51 6 6.57 1 238PUS B EAV=23.0 2 -238PU G 120.11 5 0.101 5 M1(+E2) 3.8 6 -238PU2 G KC=$LC=2.8 6$MC=0.69 6 -238PU G 132.5 1 0.0014 8 [E1] 0.267 5 -238PU2 G KC=0.203 4$LC=0.048 1$MC=0.0118 2 -238PU G 174.08 5 0.0229 8 [E1] 0.142 3 -238PU2 G KC=0.110 2$LC=0.0241 5$MC=0.0059 1 +238PU G 120.11 5 0.101 5M1(+E2) 3.8 6 +238PU2 G LC=2.8 6$MC=0.69 6 +238PU G 132.5 1 0.0014 8[E1] 0.267 5 +238PU2 G KC=0.203 4$LC=0.048 1$MC=0.0118 2 +238PU G 174.08 5 0.0229 8[E1] 0.142 3 +238PU2 G KC=0.110 2$LC=0.0241 5$MC=0.0059 1 diff --git a/HEN_HOUSE/spectra/lnhb/Np-239.txt b/HEN_HOUSE/spectra/lnhb/Np-239.txt index d5a76b7df..021dc2e33 100644 --- a/HEN_HOUSE/spectra/lnhb/Np-239.txt +++ b/HEN_HOUSE/spectra/lnhb/Np-239.txt @@ -6,136 +6,136 @@ 239PU3C 1974Yu04, 1977St35, 1979Mo25, 1979Bo30, 1982Ah04, 1984Va41, 1986Ch17, 239PU4C 1990Ab06, 1990Si12, 1991Sh06, 1991Po17, 1992Ha02, 1996FiZX, 1996Wo05, 239PU5C 1996Sc06, 2003Au03, 2003Br12 -239PU T Auger electrons and ^X ray energies and emission intensities: -239PU T {U Energy (keV)} {U Intensity } {U Line } +239PU T Auger electrons and X ray energies and emission intensities: +239PU T {U Energy (keV)} {U Intensity} {U Line} 239PU T -239PU T 99.525 13.5 4 XKA2 -239PU T 103.734 21.4 6 XKA1 +239PU T 99.525 13.5 4 XKA2 +239PU T 103.734 21.4 6 XKA1 239PU T -239PU T 116.244 |] XKB3 -239PU T 117.228 |] 7.84 25 XKB1 -239PU T 117.918 |] XKB5II +239PU T 116.244 |] XKB3 +239PU T 117.228 |] 7.84 25 XKB1 +239PU T 117.918 |] XKB5II 239PU T -239PU T 120.54 |] XKB2 -239PU T 120.969 |] 2.72 10 XKB4 -239PU T 121.543 |] XKO23 +239PU T 120.54 |] XKB2 +239PU T 120.969 |] 2.72 10 XKB4 +239PU T 121.543 |] XKO23 239PU T -239PU T 12.125-21.984 51.3 24 XL (total) -239PU T 12.125 1.38 6 XLL -239PU T 14.083-14.279 21.5 10 XLA -239PU T 16.334 0.414 28 XLC -239PU T 16.499-19.331 22.8 10 XLB -239PU T 20.708-21.984 5.19 24 XLG +239PU T 12.125-21.984 51.3 24 XL (total) +239PU T 12.125 1.38 6 XLL +239PU T 14.083-14.279 21.5 10 XLA +239PU T 16.334 0.414 28 XLC +239PU T 16.499-19.331 22.8 10 XLB +239PU T 20.708-21.984 5.19 24 XLG 239PU T -239PU T 75.26-85.36 |] KLL AUGER -239PU T 92.61-103.73 |] 1.36 19 ^KLX AUGER -239PU T 109.93-121.78 |] KXY AUGER -239PU T 6.19-22.99 47.9 26 L AUGER +239PU T 75.26-85.36 |] KLL AUGER +239PU T 92.61-103.73 |] 1.36 19 KLX AUGER +239PU T 109.93-121.78 |] KXY AUGER +239PU T 6.19-22.99 47.9 26 L AUGER 239NP P 0.0 5/2+ 2.356 D 3 722.5 10 239PU N 1.0 1.0 1 1.0 239PU L 0 1/2+ 24100 Y 11 -239PU B 722.5 5 +239PU B 722.5 5 2 239PUS B EAV= 239PU L 7.861 2 3/2+ 36 PS 3 -239PU B 714.6 5 6.5 10 8.4 2 +239PU B 714.6 5 6.5 10 8.4 239PUS B EAV=218.3 2 239PU G 7.861 2 0.0122 12M1+E2 0.055 3 5.72E3 40 -239PU2 G KC=$LC=$MC=4.2E3 3 +239PU2 G MC=4.2E3 3 239PU L 57.276 2 5/2+ 101 PS 5 -239PU B 665.2 5 0.4 72 +239PU B 665.2 5 0 7 239PUS B EAV= -239PU G 49.415 3 0.145 35M1+E2 0.50 3 126 8 -239PU2 G KC=$LC=92 6$MC=24.8 17 -239PU G 57.273 4 0.12 3 E2 222 4 -239PU2 G KC=$LC=161.1 23$MC=45.0 7 +239PU G 49.415 3 0.145 35M1+E2 0.50 3 126 8 +239PU2 G LC=92 6$MC=24.8 17 +239PU G 57.273 4 0.12 3E2 222 4 +239PU2 G LC=161.1 23$MC=45.0 7 239PU L 75.706 3 7/2+ 83 PS 8 -239PU B 646.8 5 2 +239PU B 646.8 5 239PUS B EAV= -239PU G 18.430 4 2000E-5 0 [M1+E2] -239PU G 67.841 7 0.10 3 E2 98.5 14 -239PU2 G KC=$LC=71.5 10$MC=20.0 3 +239PU G 18.430 4 0.02 [M1+E2] +239PU G 67.841 7 0.10 3E2 98.5 14 +239PU2 G LC=71.5 10$MC=20.0 3 239PU L 163.76 2 9/2+ 73 PS 4 -239PU B 558.7 5 +239PU B 558.7 5 2 239PUS B EAV= -239PU G 88.06 3 0.006 2 M1+E2 0.5 2 12 6 -239PU2 G KC=$LC=9 4$MC=2.4 13 -239PU G 106.50 3 0.049 8 E2 11.8 3 -239PU2 G KC=$LC=8.55 17$MC=2.39 5 +239PU G 88.06 3 0.006 2M1+E2 0.5 2 12 6 +239PU2 G LC=9 4$MC=2.4 13 +239PU G 106.50 3 0.049 8E2 11.8 3 +239PU2 G LC=8.55 17$MC=2.39 5 239PU L 285.460 2 5/2+ 1.12 NS 5 239PU B 437.0 5 43.0 22 6.9 239PUS B EAV=125.6 2 -239PU G 209.753 2 3.42 3 M1+E2 0.37 8 2.93 13 -239PU2 G KC=2.27 12$LC=0.499 9$MC=0.1231 18 -239PU G 228.183 1 11.32 22M1+E2 0.28 7 2.41 9 -239PU2 G KC=1.88 8$LC=0.395 7$MC=0.0967 15 -239PU G 277.599 1 14.4 1 M1+E2 0.23 10 1.42 7 -239PU2 G KC=1.12 6$LC=0.228 6$MC=0.0555 13 -239PU G 285.460 2 0.78 1 E2 0.248 5 -239PU2 G KC=0.0843 17$LC=0.119 3$MC=0.0327 7 +239PU G 209.753 2 3.42 3M1+E2 0.37 8 2.93 13 +239PU2 G KC=2.27 12$LC=0.499 9$MC=0.1231 18 +239PU G 228.183 1 11.32 22M1+E2 0.28 7 2.41 9 +239PU2 G KC=1.88 8$LC=0.395 7$MC=0.0967 15 +239PU G 277.599 1 14.4 1M1+E2 0.23 10 1.42 7 +239PU2 G KC=1.12 6$LC=0.228 6$MC=0.0555 13 +239PU G 285.460 2 0.78 1E2 0.248 5 +239PU2 G KC=0.0843 17$LC=0.119 3$MC=0.0327 7 239PU L 330.125 4 7/2+ -239PU B 392.4 5 9.4 14 7.4 2 +239PU B 392.4 5 9.4 14 7.4 239PUS B EAV=111.5 2 -239PU G 44.663 5 0.13 1 M1+E2 0.20 3 86 8 -239PU2 G KC=$LC=64 6$MC=16.2 17 -239PU G 166.39 6 0.016 7 M1(+E2) 0.5 4 6.23 13 -239PU2 G KC=4.92 10$LC=0.987 20$MC=0.240 5 -239PU G 254.40 3 0.110 3 M1+E2 1.85 4 -239PU2 G KC=1.46 3$LC=0.295 6$MC=0.0718 15 -239PU G 272.84 3 0.077 3 M1+E2 0.16 5 1.52 3 -239PU2 G KC=1.20 3$LC=0.242 4$MC=0.0588 9 -239PU G 322.3 2 5200E-6 0 (E2) 0.170 4 -239PU2 G KC=0.0680 14$LC=0.076 4$MC=0.0203 4 +239PU G 44.663 5 0.13 1M1+E2 0.20 3 86 8 +239PU2 G LC=64 6$MC=16.2 17 +239PU G 166.39 6 0.016 7M1(+E2) 0.5 4 6.23 13 +239PU2 G KC=4.92 10$LC=0.987 20$MC=0.240 5 +239PU G 254.40 3 0.110 3M1+E2 1.85 4 +239PU2 G KC=1.46 3$LC=0.295 6$MC=0.0718 15 +239PU G 272.84 3 0.077 3M1+E2 0.16 5 1.52 3 +239PU2 G KC=1.20 3$LC=0.242 4$MC=0.0588 9 +239PU G 322.3 2 0.0052 (E2) 0.170 4 +239PU2 G KC=0.0680 14$LC=0.076 4$MC=0.0203 4 239PU L 387.41 2 9/2+ -239PU B 335.1 5 +239PU B 335.1 5 2 239PUS B EAV= -239PU G 57.3 1200E-5 0 M1(+E2) -239PU G 101.96 2 0.008 2 E2 14.42 21 -239PU2 G KC=$LC=10.46 15$MC=2.93 5 -239PU G 311.70 2 0.002 2 (M1+E2) +239PU G 57.3 0.012 M1(+E2) +239PU G 101.96 2 0.008 2E2 14.42 21 +239PU2 G LC=10.46 15$MC=2.93 5 +239PU G 311.70 2 0.002 2(M1+E2) 239PU L 391.586 3 7/2- 193 NS 4 -239PU B 330.9 5 38.8 9 6.3 1U +239PU B 330.9 5 38.8 9 6.3 1 239PUS B EAV=98.3 2 -239PU G 61.460 2 1.29 2 E1 0.473 7 -239PU2 G KC=$LC=0.354 5$MC=0.0881 13 -239PU G 106.125 2 25.9 3 E1(+M2) -0.007 7 0.26 3 -239PU2 G KC=$LC=0.19 3$MC=0.050 8 -239PU G 227.83 0.5 1 M1+E2 0.0762 15 -239PU2 G KC=0.0597 12$LC=0.0125 3$MC=0.00303 6 -239PU G 315.880 3 1.59 1 E1(+M2) 0.0372 8 -239PU2 G KC=0.0295 6$LC=0.0059 2$MC=0.00141 4 -239PU G 334.310 3 2.04 2 E1(+M2) 0.0329 7 -239PU2 G KC=0.0261 5$LC=0.00515 7$MC=0.0012 3 +239PU G 61.460 2 1.29 2E1 0.473 7 +239PU2 G LC=0.354 5$MC=0.0881 13 +239PU G 106.125 2 25.9 3E1(+M2) -0.007 7 0.26 3 +239PU2 G LC=0.19 3$MC=0.050 8 +239PU G 227.83 0.5 1M1+E2 0.0762 15 +239PU2 G KC=0.0597 12$LC=0.0125 3$MC=0.00303 6 +239PU G 315.880 3 1.59 1E1(+M2) 0.0372 8 +239PU2 G KC=0.0295 6$LC=0.0059 2$MC=0.00141 4 +239PU G 334.310 3 2.04 2E1(+M2) 0.0329 7 +239PU2 G KC=0.0261 5$LC=0.00515 7$MC=0.0012 3 239PU L 469.8 4 (1/2)- -239PU B 252.7 5 0.0027 9.9 3U +239PU B 252.7 5 0.0027 9.9 1U 239PUS B EAV=74.7 2 -239PU G 461.9 5 1600E-6 0 (E1) -239PU G 469.8 5 1100E-6 0 (E1) +239PU G 461.9 5 0.0016 (E1) +239PU G 469.8 5 0.0011 (E1) 239PU L 492.2 3 3/2- -239PU B 230.3 5 0.02 9.3 1U +239PU B 230.3 5 0.02 9.3 1 239PUS B EAV=62.5 2 -239PU G 434.7 5 1300E-5 0 E1(+M2) -239PU G 484.3 5 1000E-6 0 (E1) -239PU G 492.3 5 6000E-6 0 (E1) +239PU G 434.7 5 0.013 E1(+M2) +239PU G 484.3 5 0.001 (E1) +239PU G 492.3 5 0.006 (E1) 239PU L 505.2 (5/2)- 239PU B 217.3 5 0.0074 9.7 239PUS B EAV=58.7 2 -239PU G 429.5 5 3900E-6 0 -239PU G 447.6 5 2600E-7 0 -239PU G 497.8 5 3200E-6 0 +239PU G 429.5 5 0.0039 +239PU G 447.6 5 0.00026 +239PU G 497.8 5 0.0032 239PU L 511.81 6 7/2+ -239PU B 210.7 5 1.56 16 7.3 2 +239PU B 210.7 5 1.56 16 7.3 239PUS B EAV=56.8 2 -239PU G 124.4 1000E-5 0 E2 13.6 3 -239PU2 G KC=10.4 2$LC=2.39 5$MC=0.591 12 -239PU G 181.70 3 0.086 2 M1 4.78 10 -239PU2 G KC=3.76 8$LC=0.768 15$MC=0.187 4 -239PU G 226.38 2 0.255 14M1+E2 2.58 8 -239PU2 G KC=2.04 7$LC=0.411 12$MC=0.100 3 -239PU G 454.2 5 8200E-7 0 (M1) -239PU G 504.2 5 7800E-7 0 (E2) +239PU G 124.4 0.01 E2 13.6 3 +239PU2 G KC=10.4 2$LC=2.39 5$MC=0.591 12 +239PU G 181.70 3 0.086 2M1 4.78 10 +239PU2 G KC=3.76 8$LC=0.768 15$MC=0.187 4 +239PU G 226.38 2 0.255 14M1+E2 2.58 8 +239PU2 G KC=2.04 7$LC=0.411 12$MC=0.100 3 +239PU G 454.2 5 0.00082 (M1) +239PU G 504.2 5 0.00078 (E2) 239PU L 556.2 (7/2)- -239PU B 166.3 5 0.0026 9.7 1U +239PU B 166.3 5 0.0026 9.7 1 239PUS B EAV=44.2 2 -239PU G 392.4 5 1600E-6 0 (E1) -239PU G 498.7 1000E-6 0 (E1) +239PU G 392.4 5 0.0016 (E1) +239PU G 498.7 0.001 (E1) diff --git a/HEN_HOUSE/spectra/lnhb/O-15.txt b/HEN_HOUSE/spectra/lnhb/O-15.txt index 1705eafae..ac5565517 100644 --- a/HEN_HOUSE/spectra/lnhb/O-15.txt +++ b/HEN_HOUSE/spectra/lnhb/O-15.txt @@ -2,6 +2,6 @@ 15O P 0.0 1/2- 2.041 M 6 2757.0 13 15N N 1.0 1.0 1 1.0 15N L 0 1/2- STABLE - 15N E 99.885 6 0.115 6 - 15N 2 E EAV=736.7 6$CK=0.926 6$CL=0.074 6$CM= $CN= $CO=0 0 + 15N E 99.885 60.115 6 + 15N 2 E EAV=736.7 6$CK=0.926 6$CL=0.074 6$CO=0 0 diff --git a/HEN_HOUSE/spectra/lnhb/P-33.txt b/HEN_HOUSE/spectra/lnhb/P-33.txt index c129fd028..fd5f9a3d4 100644 --- a/HEN_HOUSE/spectra/lnhb/P-33.txt +++ b/HEN_HOUSE/spectra/lnhb/P-33.txt @@ -2,6 +2,6 @@ 33P P 0.0 1/2+ 25.383 D 40 248.5 11 33S N 1.0 1.0 1 1.0 33S L 0 3/2+ STABLE - 33S B 248.5 11100 5 2 + 33S B 248.5 11100 5 33S S B EAV=76.4 5 diff --git a/HEN_HOUSE/spectra/lnhb/Pa-231.txt b/HEN_HOUSE/spectra/lnhb/Pa-231.txt index 842b89879..caa4e703c 100644 --- a/HEN_HOUSE/spectra/lnhb/Pa-231.txt +++ b/HEN_HOUSE/spectra/lnhb/Pa-231.txt @@ -6,200 +6,200 @@ 227AC3C 1968Ha22, 1969Ba20, 1969La04, 1969Ro33, 1970De19, 1970Le11, 1971Le10, 227AC4C 1972Ga39, 1974De11, 1976BaZZ, 1979Te02, 1979Bo30, 1982An02, 1985Is03, 227AC5C 1986LOZT, 1990Ho28, 1991Ry01, 1998Ak04, 2001Br31, 2003Au03, 2008kI07 -227AC T Auger electrons and ^X ray energies and emission intensities: -227AC T {U Energy (keV)} {U Intensity } {U Line } +227AC T Auger electrons and X ray energies and emission intensities: +227AC T {U Energy (keV)} {U Intensity} {U Line} 227AC T -227AC T 87.768 0.715 23 XKA2 -227AC T 90.885 1.16 4 XKA1 +227AC T 87.768 0.715 23 XKA2 +227AC T 90.885 1.16 4 XKA1 227AC T -227AC T 102.101 |] XKB3 -227AC T 102.841 |] 0.410 15 XKB1 -227AC T 103.462 |] XKB5II +227AC T 102.101 |] XKB3 +227AC T 102.841 |] 0.410 15 XKB1 +227AC T 103.462 |] XKB5II 227AC T -227AC T 105.679 |] XKB2 -227AC T 106.098 |] 0.136 6 XKB4 -227AC T 106.563 |] XKO23 +227AC T 105.679 |] XKB2 +227AC T 106.098 |] 0.136 6 XKB4 +227AC T 106.563 |] XKO23 227AC T -227AC T 10.8701-18.9228 44.3 13 XL (total) -227AC T 10.8701 1.10 4 XLL -227AC T 12.5002-12.6505 18.7 7 XLA -227AC T 14.0807 0.303 19 XLC -227AC T 14.6024-15.9311 19.7 7 XLB -227AC T 17.813-18.9228 4.45 16 XLG +227AC T 10.8701-18.9228 44.3 13 XL (total) +227AC T 10.8701 1.10 4 XLL +227AC T 12.5002-12.6505 18.7 7 XLA +227AC T 14.0807 0.303 19 XLC +227AC T 14.6024-15.9311 19.7 7 XLB +227AC T 17.813-18.9228 4.45 16 XLG 227AC T -227AC T 66.769-74.715 |] KLL AUGER -227AC T 81.775-90.882 |] 0.078 11 ^KLX AUGER -227AC T 96.76-106.75 |] KXY AUGER -227AC T 5.87-19.69 52.6 15 L AUGER +227AC T 66.769-74.715 |] KLL AUGER +227AC T 81.775-90.882 |] 0.078 11 KLX AUGER +227AC T 96.76-106.75 |] KXY AUGER +227AC T 5.87-19.69 52.6 15 L AUGER 231PA P 0.0 3/2- 32670 Y 260 5149.9 8 227AC N 1.0 1.0 1 1.0 -227AC G 70.49 5 0.0051 8 +227AC G 70.49 5 0.0051 8 227AC G 242.18 8 0.0099 10 -227AC G 286.58 100.0104 5 +227AC G 286.58 100.0104 5 227AC G 310.0 1 0.00092 20 -227AC G 374.95 100.0045 3 -227AC G 438.72 100.0013 4 +227AC G 374.95 100.0045 3 +227AC G 438.72 100.0013 4 227AC L 0 3/2- 21.772 Y 3 227AC A 5060.7 8 11.7 5 250 227AC L 27.37 1 3/2+ 38.3 NS 30 227AC A 5033.8 8 2.8 3 707 -227AC G 27.37 1 10.8 4 E1 4.5 6 -227AC2 G KC=$LC=3.3 4$MC=0.87 13 +227AC G 27.37 1 10.8 4E1 4.5 6 +227AC2 G LC=3.3 4$MC=0.87 13 227AC L 29.98 1 5/2- 227AC A 5031.2 8 20 2 95 -227AC G 29.98 1 0.097 4 M1+E2 0.22 2 270 30 -227AC2 G KC=$LC=202 21$MC=52 6 +227AC G 29.98 1 0.097 4M1+E2 0.22 2 270 30 +227AC2 G LC=202 21$MC=52 6 227AC L 46.35 1 5/2+ 227AC A 5015.1 8 25.3 5 59.5 -227AC G 16.370 140.221 9 E1 8.58 12 -227AC2 G KC=$LC=5.06 7$MC=2.68 4 -227AC G 18.980 140.37 3 M1 113.2 16 -227AC2 G KC=$LC=2.35 4$MC=82.7 12 -227AC G 46.35 1 0.19 1 E1 0.879 13 -227AC2 G KC=$LC=0.663 10$MC=0.1634 23 +227AC G 16.370 140.221 9E1 8.58 12 +227AC2 G LC=5.06 7$MC=2.68 4 +227AC G 18.980 140.37 3M1 113.2 16 +227AC2 G LC=2.35 4$MC=82.7 12 +227AC G 46.35 1 0.19 1E1 0.879 13 +227AC2 G LC=0.663 10$MC=0.1634 23 227AC L 74.14 1 (7/2)- 227AC A 4987.8 8 1.6 2 629 -227AC G 44.160 140.055 4 M1 37.4 6 -227AC2 G KC=$LC=28.3 4$MC=6.79 10 -227AC G 74.14 1 0.0223 9 E2 42.6 6 -227AC2 G KC=$LC=31.2 5$MC=8.53 12 +227AC G 44.160 140.055 4M1 37.4 6 +227AC2 G LC=28.3 4$MC=6.79 10 +227AC G 74.14 1 0.0223 9E2 42.6 6 +227AC2 G LC=31.2 5$MC=8.53 12 227AC L 84.55 1 (7/2)+ 227AC A 4977.6 8 0.4 1 2160 -227AC G 38.200 140.144 6 M1+E2 0.18 5 89 19 -227AC2 G KC=$LC=66 14$MC=17 4 -227AC G 54.570 140.070 4 E1 0.569 8 -227AC2 G KC=$LC=0.430 6$MC=0.1053 15 -227AC G 57.180 140.031 3 E2 148.1 21 -227AC2 G KC=$LC=108.6 16$MC=29.6 5 +227AC G 38.200 140.144 6M1+E2 0.18 5 89 19 +227AC2 G LC=66 14$MC=17 4 +227AC G 54.570 140.070 4E1 0.569 8 +227AC2 G LC=0.430 6$MC=0.1053 15 +227AC G 57.180 140.031 3E2 148.1 21 +227AC2 G LC=108.6 16$MC=29.6 5 227AC L 109.94 2 (9/2)+ 227AC A 4952.6 8 22.5 5 26.5 -227AC G 25.390 220.095 7 M1 191 3 -227AC2 G KC=$LC=144.6 21$MC=34.9 5 +227AC G 25.390 220.095 7M1 191 3 +227AC2 G LC=144.6 21$MC=34.9 5 227AC G 35.800 220.0163 10E1 1.746 25 -227AC2 G KC=$LC=1.313 19$MC=0.327 5 +227AC2 G LC=1.313 19$MC=0.327 5 227AC G 63.590 220.0446 17E2 88.8 13 -227AC2 G KC=$LC=65.1 10$MC=17.8 3 +227AC2 G LC=65.1 10$MC=17.8 3 227AC L 126.86 2 (9/2)- 227AC A 4936.0 8 2.9 3 160 -227AC G 52.720 220.076 4 M1 22.2 4 -227AC2 G KC=$LC=16.81 24$MC=4.03 6 -227AC G 96.880 220.084 3 E2 12.02 17 -227AC2 G KC=$LC=8.81 13$MC=2.41 4 +227AC G 52.720 220.076 4M1 22.2 4 +227AC2 G LC=16.81 24$MC=4.03 6 +227AC G 96.880 220.084 3E2 12.02 17 +227AC2 G LC=8.81 13$MC=2.41 4 227AC L 160 2 + 227AC A 4903.4 220.002 1 141000 227AC L 187.32 3 (11/2)+ -227AC G 60.46 4 0.0053 7 E1 0.433 7 -227AC2 G KC=$LC=0.327 5$MC=0.0800 12 -227AC G 77.38 4 0.061 4 M1 7.23 11 -227AC2 G KC=$LC=5.47 8$MC=1.313 19 -227AC G 102.77 3 0.019 4 E2 9.12 13 -227AC2 G KC=$LC=6.69 10$MC=1.83 3 +227AC G 60.46 4 0.0053 7E1 0.433 7 +227AC2 G LC=0.327 5$MC=0.0800 12 +227AC G 77.38 4 0.061 4M1 7.23 11 +227AC2 G LC=5.47 8$MC=1.313 19 +227AC G 102.77 3 0.019 4E2 9.12 13 +227AC2 G LC=6.69 10$MC=1.83 3 227AC L 198.71 4 (11/2)- -227AC G 71.85 5 0.0019 7 M1 8.98 13 -227AC2 G KC=$LC=6.79 10$MC=1.630 23 -227AC G 124.57 4 0.0043 4 E2 4.04 6 -227AC2 G KC=0.285 4$LC=2.75 4$MC=0.752 11 +227AC G 71.85 5 0.0019 7M1 8.98 13 +227AC2 G LC=6.79 10$MC=1.630 23 +227AC G 124.57 4 0.0043 4E2 4.04 6 +227AC2 G KC=0.285 4$LC=2.75 4$MC=0.752 11 227AC L 210.78 5 (13/2)+ 227AC A 4853.5 8 1.40 1594 -227AC G 23.46 6 0.0048 6 M1 241 4 -227AC2 G KC=$LC=182 3$MC=44.1 7 -227AC G 100.84 5 0.0226 9 E2 9.97 15 -227AC2 G KC=$LC=7.30 11$MC=2.00 3 +227AC G 23.46 6 0.0048 6M1 241 4 +227AC2 G LC=182 3$MC=44.1 7 +227AC G 100.84 5 0.0226 9E2 9.97 15 +227AC2 G LC=7.30 11$MC=2.00 3 227AC L 271.29 6 (13/2)- 227AC A 4794.1 8 0.040 151300 -227AC G 72.58 7 0.0030 7 M1 8.71 13 -227AC2 G KC=$LC=6.59 10$MC=1.582 23 -227AC G 144.43 6 0.0115 9 E2 2.18 3 -227AC2 G KC=0.263 4$LC=1.407 20$MC=0.384 6 +227AC G 72.58 7 0.0030 7M1 8.71 13 +227AC2 G LC=6.59 10$MC=1.582 23 +227AC G 144.43 6 0.0115 9E2 2.18 3 +227AC2 G KC=0.263 4$LC=1.407 20$MC=0.384 6 227AC L 273.14 3 (5/2)- 227AC G 199.00 3 0.0030 12 -227AC G 243.16 3 0.036 5 M1+E2 1.1 3 0.80 17 +227AC G 243.16 3 0.036 5M1+E2 1.1 3 0.80 17 227AC2 G KC=0.56 16$LC=0.176 10$MC=0.0445 16 -227AC G 245.77 3 0.012 4 E1 0.0570 8 -227AC2 G KC=0.0455 7$LC=0.00867 13$MC=0.00208 3 +227AC G 245.77 3 0.012 4E1 0.0570 8 +227AC2 G KC=0.0455 7$LC=0.00867 13$MC=0.00208 3 227AC G 273.14 3 0.0579 12M1+E2 0.7 2 0.74 11 -227AC2 G KC=0.57 10$LC=0.131 8$MC=0.0323 15 +227AC2 G KC=0.57 10$LC=0.131 8$MC=0.0323 15 227AC L 304.73 5 (5/2)+ 227AC A 4761.2 8 0.0032 9 9600 -227AC G 230.59 5 0.0017 8 -227AC G 258.38 5 0.0015 4 +227AC G 230.59 5 0.0017 8 +227AC G 258.38 5 0.0015 4 227AC L 330.04 1 3/2- 227AC A 4736.3 8 8.4 4 2.46 -227AC G 56.90 3 0.0047 7 M1+E2 0.41 7 37 6 -227AC2 G KC=$LC=28 5$MC=7.1 12 -227AC G 245.490 140.0067 5 M2 5.24 8 -227AC2 G KC=3.70 6$LC=1.143 16$MC=0.293 5 -227AC G 255.900 140.1059 22E2 0.264 4 -227AC2 G KC=0.0992 14$LC=0.1216 17$MC=0.0327 5 -227AC G 283.690 141.65 3 E1 0.0410 6 -227AC2 G KC=0.0329 5$LC=0.00614 9$MC=1468E-6 21 -227AC G 300.060 142.41 5 M1+E2 -0.12 7 0.764 17 -227AC2 G KC=0.613 15$LC=0.1146 20$MC=0.0275 5 -227AC G 302.670 142.3 3 E1 0.0355 5 -227AC2 G KC=0.0285 4$LC=0.00527 8$MC=1260E-6 18 -227AC G 330.04 1 1.36 3 M1+E2 0.36 6 0.541 19 -227AC2 G KC=0.430 16$LC=0.0836 20$MC=0.0202 5 +227AC G 56.90 3 0.0047 7M1+E2 0.41 7 37 6 +227AC2 G LC=28 5$MC=7.1 12 +227AC G 245.490 140.0067 5M2 5.24 8 +227AC2 G KC=3.70 6$LC=1.143 16$MC=0.293 5 +227AC G 255.900 140.1059 22E2 0.264 4 +227AC2 G KC=0.0992 14$LC=0.1216 17$MC=0.0327 5 +227AC G 283.690 141.65 3E1 0.0410 6 +227AC2 G KC=0.0329 5$LC=0.00614 9$MC=1468E-6 21 +227AC G 300.060 142.41 5M1+E2 -0.12 7 0.764 17 +227AC2 G KC=0.613 15$LC=0.1146 20$MC=0.0275 5 +227AC G 302.670 142.3 3E1 0.0355 5 +227AC2 G KC=0.0285 4$LC=0.00527 8$MC=1260E-6 18 +227AC G 330.04 1 1.36 3M1+E2 0.36 6 0.541 19 +227AC2 G KC=0.430 16$LC=0.0836 20$MC=0.0202 5 227AC L 354.50 4 1/2- 227AC A 4712.3 8 1.20 2211.7 -227AC G 24.46 4 0.0049 10M1 214 4 -227AC2 G KC=$LC=161.3 24$MC=39.0 6 -227AC G 327.13 4 0.0361 11E1 0.0298 5 -227AC2 G KC=0.0240 4$LC=0.00440 7$MC=1050E-6 15 +227AC G 24.46 4 0.0049 10M1 214 4 +227AC2 G LC=161.3 24$MC=39.0 6 +227AC G 327.13 4 0.0361 11E1 0.0298 5 +227AC2 G KC=0.0240 4$LC=0.00440 7$MC=1050E-6 15 227AC G 354.50 4 0.0962 20M1+E2 3 0.1375 20 -227AC2 G KC=0.0855 12$LC=0.0386 6$MC=0.01003 14 +227AC2 G KC=0.0855 12$LC=0.0386 6$MC=0.01003 14 227AC L 387.23 2 7/2- 227AC A 4680.1 8 1.8 3 4.6 227AC G 57.190 220.0046 21E2 148.0 21 -227AC2 G KC=$LC=108.5 16$MC=29.6 5 -227AC G 260.37 3 0.182 4 M1+E2 1.4 3 0.55 11 -227AC2 G KC=0.37 10$LC=0.133 7$MC=0.0340 13 -227AC G 277.29 3 0.0680 15E1+M2 0.4 4 0.5 9 -227AC2 G KC=0.4 7$LC=0.11 19$MC=0.03 5 -227AC G 302.680 220.21 10E1 0.0355 5 -227AC2 G KC=0.0285 4$LC=0.00527 8$MC=1260E-6 18 -227AC G 313.090 220.0987 20M1+E2 1.5 0.31 9 -227AC2 G KC=0.22 8$LC=0.070 8$MC=0.0177 16 -227AC G 340.880 220.177 4 E1+M2 0.22 4 0.11 3 -227AC2 G KC=0.081 22$LC=0.020 6$MC=0.0050 15 -227AC G 357.250 220.168 4 M1+E2 0.4 4 0.43 10 -227AC2 G KC=0.34 9$LC=0.066 10$MC=0.0159 21 -227AC G 359.860 220.0085 3 -227AC G 387.23 2 0.0003 1 E2 0.0773 11 -227AC2 G KC=0.0430 6$LC=0.0254 4$MC=0.00667 10 +227AC2 G LC=108.5 16$MC=29.6 5 +227AC G 260.37 3 0.182 4M1+E2 1.4 3 0.55 11 +227AC2 G KC=0.37 10$LC=0.133 7$MC=0.0340 13 +227AC G 277.29 3 0.0680 15E1+M2 0.4 4 0.5 9 +227AC2 G KC=0.4 7$LC=0.11 19$MC=0.03 5 +227AC G 302.680 220.21 10E1 0.0355 5 +227AC2 G KC=0.0285 4$LC=0.00527 8$MC=1260E-6 18 +227AC G 313.090 220.0987 20M1+E2 1.5 0.31 9 +227AC2 G KC=0.22 8$LC=0.070 8$MC=0.0177 16 +227AC G 340.880 220.177 4E1+M2 0.22 4 0.11 3 +227AC2 G KC=0.081 22$LC=0.020 6$MC=0.0050 15 +227AC G 357.250 220.168 4M1+E2 0.4 4 0.43 10 +227AC2 G KC=0.34 9$LC=0.066 10$MC=0.0159 21 +227AC G 359.860 220.0085 3 +227AC G 387.23 2 0.0003 1E2 0.0773 11 +227AC2 G KC=0.0430 6$LC=0.0254 4$MC=0.00667 10 227AC L 425.59 3 5/2+ 227AC A 4642.5 8 0.080 6 56 -227AC G 351.45 3 0.0028 12E1 0.0255 4 -227AC2 G KC=0.0206 3$LC=0.00373 6$MC=8.91E-4 13 +227AC G 351.45 3 0.0028 12E1 0.0255 4 +227AC2 G KC=0.0206 3$LC=0.00373 6$MC=8.91E-4 13 227AC G 379.24 3 0.0498 11M1+E2 0.6 6 0.32 11 227AC2 G KC=0.25 10$LC=0.052 11$MC=0.0125 24 -227AC G 395.61 3 0.00226 22E1 0.0198 3 -227AC2 G KC=0.01601 23$LC=0.00286 4$MC=6.82E-4 10 -227AC G 398.22 3 0.0095 3 +227AC G 395.61 3 0.00226 22E1 0.0198 3 +227AC2 G KC=0.01601 23$LC=0.00286 4$MC=6.82E-4 10 +227AC G 398.22 3 0.0095 3 227AC L 435.19 2 (1/2)+ 227AC A 4633.0 8 0.0504 1175.8 -227AC G 407.820 220.0356 8 M1 0.334 5 -227AC2 G KC=0.269 4$LC=0.0496 7$MC=0.01187 17 +227AC G 407.820 220.0356 8M1 0.334 5 +227AC2 G KC=0.269 4$LC=0.0496 7$MC=0.01187 17 227AC G 435.19 2 0.00294 17 227AC L 437.96 4 (5/2)- 227AC A 4630.3 8 0.078 2147 -227AC G 50.73 5 0.0022 8 M1 24.9 4 -227AC2 G KC=$LC=18.8 3$MC=4.52 7 -227AC G 363.82 4 0.0080 3 -227AC G 391.61 4 0.00673 22E1 0.0202 3 -227AC2 G KC=0.01636 23$LC=0.00293 5$MC=6.97E-4 10 -227AC G 410.59 4 0.00180 22E1 0.0183 3 -227AC2 G KC=0.01482 21$LC=0.00264 4$MC=6.28E-4 9 -227AC G 437.96 4 0.0045 3 +227AC G 50.73 5 0.0022 8M1 24.9 4 +227AC2 G LC=18.8 3$MC=4.52 7 +227AC G 363.82 4 0.0080 3 +227AC G 391.61 4 0.00673 22E1 0.0202 3 +227AC2 G KC=0.01636 23$LC=0.00293 5$MC=6.97E-4 10 +227AC G 410.59 4 0.00180 22E1 0.0183 3 +227AC2 G KC=0.01482 21$LC=0.00264 4$MC=6.28E-4 9 +227AC G 437.96 4 0.0045 3 227AC L 469.24 6 (9/2)+ 227AC A 4599.6 8 0.015 7 146 227AC G 384.69 6 0.00365 22 227AC L 501.28 7 (3/2,5/2)- 227AC A 4568.1 9 0.008 4 160 -227AC G 427.14 7 0.0007 4 +227AC G 427.14 7 0.0007 4 227AC G 501.28 7 0.00076 18 227AC L 537.0 1 (3/2)+ 227AC A 4533.0 8 0.00076 20930 -227AC G 490.65 100.0004 1 +227AC G 490.65 100.0004 1 227AC G 509.63 100.00036 17 227AC L 562.8 1 (3/2,5/2)+ 227AC A 4507.6 8 0.0036 3 126 @@ -211,5 +211,5 @@ 227AC G 546.5 3 0.00083 13 227AC G 571.9 3 0.00048 20 227AC G 582.3 3 0.00031 17 -227AC G 610.1 3 0.0005 4 +227AC G 610.1 3 0.0005 4 diff --git a/HEN_HOUSE/spectra/lnhb/Pa-233.txt b/HEN_HOUSE/spectra/lnhb/Pa-233.txt index e9bccd0a4..4cc20eea2 100644 --- a/HEN_HOUSE/spectra/lnhb/Pa-233.txt +++ b/HEN_HOUSE/spectra/lnhb/Pa-233.txt @@ -52,110 +52,110 @@ 233U 5C 1992Ra08, 2000Us01, 2000Wo01, 2000Ch01, 2000Sc04, 2000Lu01, 2002Lu01, 233U 6C 2003Au03, 2004Sh07, 2005Hu06, 2005Si15, 2006Ch39, 2006Ha53, 2008Ki07, 233U 7C 2008De10 -233U T Auger electrons and ^X ray energies and emission intensities: -233U T {U Energy (keV)} {U Intensity } {U Line } +233U T Auger electrons and X ray energies and emission intensities: +233U T {U Energy (keV)} {U Intensity} {U Line} 233U T -233U T 94.666 9.10 26 XKA2 -233U T 98.44 14.6 4 XKA1 +233U T 94.666 9.10 26 XKA2 +233U T 98.44 14.6 4 XKA1 233U T -233U T 110.421 |] XKB3 -233U T 111.298 |] 5.25 18 XKB1 -233U T 111.964 |] XKB5II +233U T 110.421 |] XKB3 +233U T 111.298 |] 5.25 18 XKB1 +233U T 111.964 |] XKB5II 233U T -233U T 114.407 |] XKB2 -233U T 115.012 |] 1.80 7 XKB4 -233U T 115.377 |] XKO23 +233U T 114.407 |] XKB2 +233U T 115.012 |] 1.80 7 XKB4 +233U T 115.377 |] XKO23 233U T -233U T 11.619-20.714 40.6 11 XL (total) -233U T 11.619 1.05 4 XLL -233U T 13.438-13.615 16.9 6 XLA -233U T 15.399 0.272 16 XLC -233U T 15.727-18.206 18.1 6 XLB -233U T 19.507-20.714 4.23 14 XLG +233U T 11.619-20.714 40.6 11 XL (total) +233U T 11.619 1.05 4 XLL +233U T 13.438-13.615 16.9 6 XLA +233U T 15.399 0.272 16 XLC +233U T 15.727-18.206 18.1 6 XLB +233U T 19.507-20.714 4.23 14 XLG 233U T -233U T 71.78-80.95 |] KLL AUGER -233U T 88.15-98.34 |] 0.95 13 ^KLX AUGER -233U T 104.42-115.4 |] KXY AUGER -233U T 5.9-21.6 42.2 13 L AUGER +233U T 71.78-80.95 |] KLL AUGER +233U T 88.15-98.34 |] 0.95 13 KLX AUGER +233U T 104.42-115.4 |] KXY AUGER +233U T 5.9-21.6 42.2 13 L AUGER 233PA P 0.0 3/2- 26.98 D 2 570.1 20 233U N 1.0 1.0 1 1.0 233U L 0 5/2+ 159.1E3 Y 2 -233U B 570.1 206.3 23 9.1 1U +233U B 570.1 206.3 23 9.1 1 233U S B EAV=169.6 6 233U L 40.350 4 7/2+ 0.11 NS 8 -233U B 529.8 200.3 19 10.2 3U +233U B 529.8 200.3 19 10.2 1U 233U S B EAV=156.1 6 -233U G 40.349 5 0.024 2 M1+E2 1.08 12 580 60 -233U 2 G KC=$LC=430 50$MC=117 12 +233U G 40.349 5 0.024 2M1+E2 1.08 12 580 60 +233U 2 G LC=430 50$MC=117 12 233U L 92.16 4 9/2+ -233U G 51.81 4 5000E-7 0 [M1+E2] 0.62 108.0000 -233U 2 G KC=$LC=79.0000 0$MC=21.0000 0 -233U G 92.16 4 2400E-6 0 [E2] 19.50000 -233U 2 G KC=$LC=14.2000 0$MC=3.95000 0 +233U G 51.81 4 0.0005 [M1+E2] 0.62 108 +233U 2 G LC=79 $MC=21 +233U G 92.16 4 0.0024 [E2] 19.5 +233U 2 G LC=14.2 $MC=3.95 233U L 298.810 4 5/2- -233U B 271.3 200.12 5 9.8 2 +233U B 271.3 200.12 5 9.8 233U S B EAV=74.6 6 -233U G 258.45 2 0.0274 6 [E1] 0.0547 11 -233U 2 G KC=0.0433 9$LC=0.00857 17$MC=0.00207 4 -233U G 298.81 2 0.12 5 [E1] 0.0396 8 -233U 2 G KC=0.0315 6$LC=0.00609 12$MC=0.00147 3 +233U G 258.45 2 0.0274 6[E1] 0.0547 11 +233U 2 G KC=0.0433 9$LC=0.00857 17$MC=0.00207 4 +233U G 298.81 2 0.12 5[E1] 0.0396 8 +233U 2 G KC=0.0315 6$LC=0.00609 12$MC=0.00147 3 233U L 301.94 9 5/2- -233U B 268.1 200.010 2 11.8 2 +233U B 268.1 200.010 2 11.8 233U S B EAV=73.7 6 -233U G 301.99 100.010 2 +233U G 301.99 100.010 2 233U L 311.904 4 3/2+ 0.120 NS 15 233U B 258.2 2026.6 32 7.3 233U S B EAV=70.8 6 -233U G 271.555 100.323 3 E2 0.258 5 -233U 2 G KC=0.0904 18$LC=0.1226 25$MC=0.0334 7 -233U G 311.904 5 38.3 5 M1+E2 0.10 1 0.80 2 -233U 2 G KC=0.64 2$LC=0.126 4$MC=0.031 1 +233U G 271.555 100.323 3E2 0.258 5 +233U 2 G KC=0.0904 18$LC=0.1226 25$MC=0.0334 7 +233U G 311.904 5 38.3 5M1+E2 0.10 1 0.80 2 +233U 2 G KC=0.64 2$LC=0.126 4$MC=0.031 1 233U L 320.83 4 7/2- -233U B 249.4 200.020 5 10.4 +233U B 249.4 200.020 5 10.4 2 233U S B EAV=68.2 6 -233U G 228.57 5 0.0042 7 -233U G 280.61 5 0.011 2 -233U G 320.73 100.0051 4 +233U G 228.57 5 0.0042 7 +233U G 280.61 5 0.011 2 +233U G 320.73 100.0051 4 233U L 340.477 4 5/2+ 52 PS 10 -233U B 229.6 2025.9 32 7.2 1U +233U B 229.6 2025.9 32 7.2 1 233U S B EAV=62.4 6 -233U G 28.559 100.071 8 M1+E2 0.158 10 313 18 -233U 2 G KC=$LC=233 13$MC=60 4 -233U G 41.663 100.014 3 [E1] 1.253 25 -233U 2 G KC=$LC=0.939 19$MC=0.235 5 -233U G 248.38 4 0.0609 11[E2] 0.346 7 -233U 2 G KC=0.1065 21$LC=0.175 4$MC=0.0479 10 -233U G 300.129 5 6.60 21M1+E2 0.08 3 0.87 2 -233U 2 G KC=0.70 2$LC=0.133 4$MC=0.031 1 -233U G 340.476 5 4.47 3 M1+E2 0.23 5 0.62 2 -233U 2 G KC=0.50 2$LC=0.103 3$MC=0.022 1 +233U G 28.559 100.071 8M1+E2 0.158 10 313 18 +233U 2 G LC=233 13$MC=60 4 +233U G 41.663 100.014 3[E1] 1.253 25 +233U 2 G LC=0.939 19$MC=0.235 5 +233U G 248.38 4 0.0609 11[E2] 0.346 7 +233U 2 G KC=0.1065 21$LC=0.175 4$MC=0.0479 10 +233U G 300.129 5 6.60 21M1+E2 0.08 3 0.87 2 +233U 2 G KC=0.70 2$LC=0.133 4$MC=0.031 1 +233U G 340.476 5 4.47 3M1+E2 0.23 5 0.62 2 +233U 2 G KC=0.50 2$LC=0.103 3$MC=0.022 1 233U L 380.43 8 7/2+ -233U B 189.8 200.020 3 9.4 3U +233U B 189.8 200.020 3 9.4 1U 233U S B EAV=50.9 6 -233U G 288.42 100.016 3 -233U G 380.28 100.0037 9 +233U G 288.42 100.016 3 +233U G 380.28 100.0037 9 233U L 398.496 4 1/2+ 55 PS 20 -233U B 171.5 2015.4 8 7 1U +233U B 171.5 2015.4 8 7 1 233U S B EAV=45.7 5 233U G 86.595 5 1.99 10M1+E2 0.056 5 7.08 14 -233U 2 G KC=$LC=5.33 11$MC=1.29 3 +233U 2 G LC=5.33 11$MC=1.29 3 233U G 398.492 5 1.408 14E2 0.0835 17 -233U 2 G KC=0.0439 9$LC=0.0291 6$MC=0.00777 16 +233U 2 G KC=0.0439 9$LC=0.0291 6$MC=0.00777 16 233U L 415.758 4 3/2+ 30 PS 233U B 154.3 2025.4 16 6.7 233U S B EAV=40.9 5 -233U G 17.262 6 4100E-6 0 M1+E2 503.0000 -233U 2 G KC=$LC=$MC=374.000 0 -233U G 75.269 101.30 3 M1+E2 0.15 8 11.4 12 -233U 2 G KC=$LC=8.6 9$MC=2.11 24 -233U G 103.86 1 0.853 6 M1+(E2) 0.1 1 4.21 21 -233U 2 G KC=$LC=3.17 15$MC=0.77 5 -233U G 375.404 5 0.684 7 E2 0.0981 20 -233U 2 G KC=0.0491 10$LC=0.0360 7$MC=0.00962 19 -233U G 415.764 5 1.747 7 M1+E2 2.2 9 0.13 8 -233U 2 G KC=0.09 6$LC=0.032 9$MC=0.0081 21 +233U G 17.262 6 0.0041 M1+E2 503 +233U 2 G MC=374 +233U G 75.269 101.30 3M1+E2 0.15 8 11.4 12 +233U 2 G LC=8.6 9$MC=2.11 24 +233U G 103.86 1 0.853 6M1+(E2) 0.1 1 4.21 21 +233U 2 G LC=3.17 15$MC=0.77 5 +233U G 375.404 5 0.684 7E2 0.0981 20 +233U 2 G KC=0.0491 10$LC=0.0360 7$MC=0.00962 19 +233U G 415.764 5 1.747 7M1+E2 2.2 9 0.13 8 +233U 2 G KC=0.09 6$LC=0.032 9$MC=0.0081 21 233U L 456.114 6 5/2+ -233U B 114.1 200.0011 2 10.6 1U +233U B 114.1 200.0011 2 10.6 1 233U S B EAV=29.8 5 -233U G 455.96 100.0011 2 +233U G 455.96 100.0011 2 diff --git a/HEN_HOUSE/spectra/lnhb/Pa-234.txt b/HEN_HOUSE/spectra/lnhb/Pa-234.txt index f004e2915..3d5427164 100644 --- a/HEN_HOUSE/spectra/lnhb/Pa-234.txt +++ b/HEN_HOUSE/spectra/lnhb/Pa-234.txt @@ -1,756 +1,756 @@ 234U 234PA B- DECAY (6.70 H) 234U H TYP=Full$AUT=Huang$CUT=31-DEC-2009$ 234U C Evaluation history: Type=Full;Author=Huang;Cutoff date=31-DEC-2009 -234U T Auger electrons and ^X ray energies and emission intensities: -234U T {U Energy (keV)} {U Intensity } {U Line } +234U T Auger electrons and X ray energies and emission intensities: +234U T {U Energy (keV)} {U Intensity} {U Line} 234U T -234U T 94.666 10.5 6 XKA2 -234U T 98.44 16.8 9 XKA1 +234U T 94.666 10.5 6 XKA2 +234U T 98.44 16.8 9 XKA1 234U T -234U T 110.421 |] XKB3 -234U T 111.298 |] 6.1 4 XKB1 -234U T 111.964 |] XKB5II +234U T 110.421 |] XKB3 +234U T 111.298 |] 6.1 4 XKB1 +234U T 111.964 |] XKB5II 234U T -234U T 114.407 |] XKB2 -234U T 115.012 |] 2.0 1 XKB4 -234U T 115.377 |] XKO23 +234U T 114.407 |] XKB2 +234U T 115.012 |] 2.0 1 XKB4 +234U T 115.377 |] XKO23 234U T -234U T 11.6185-20.7141 77 10 XL (total) +234U T 11.6185-20.7141 77 10 XL (total) 234U T 11.6185 XLL 234U T 13.4382-13.6146 XLA 234U T 15.399 XLC 234U T 15.7268-18.2061 XLB 234U T 19.5072-20.7141 XLG 234U T -234U T 71.776-80.954 |] KLL AUGER -234U T 88.153-98.429 |] 1.08 6 ^KLX AUGER -234U T 104.51-115.59 |] KXY AUGER -234U T 5.9-21.6 77 10 L AUGER +234U T 71.776-80.954 |] KLL AUGER +234U T 88.153-98.429 |] 1.08 6 KLX AUGER +234U T 104.51-115.59 |] KXY AUGER +234U T 5.9-21.6 77 10 L AUGER 234PA P 0.0 4+ 6.70 H 5 2195 4 234U N 1.0 1.0 1 1.0 234U G 401.8 2 0.036 11 234U G 425.3 2 0.036 11 -234U G 643.2 2 0.027 9 -234U G 659.8 1 0.27 4 +234U G 643.2 2 0.027 9 +234U G 659.8 1 0.27 4 234U G 711.5 1 0.156 25 234U G 778.6 2 0.046 10 234U G 824.2 2 1.25 15 234U G 846.1 2 0.052 12 -234U G 920.5 2 0.029 8 +234U G 920.5 2 0.029 8 234U G 992.0 2 0.083 22 234U G 1023.6 2 0.062 22 234U G 1025.3 2 0.052 22 234U G 1035.9 2 0.026 10 234U G 1220.4 2 0.062 12 -234U G 1296.4 2 0.029 7 -234U G 1301.2 2 0.018 5 -234U G 1327.0 2 0.018 5 -234U G 1507.3 2 0.020 5 -234U G 1520.7 2 0.0094 9 -234U G 1538.8 2 0.014 4 -234U G 1655.7 1 0.026 4 -234U G 1664.8 3 0.018 7 -234U G 1743.2 2 0.033 8 -234U G 1757.5 1 0.024 6 +234U G 1296.4 2 0.029 7 +234U G 1301.2 2 0.018 5 +234U G 1327.0 2 0.018 5 +234U G 1507.3 2 0.020 5 +234U G 1520.7 2 0.0094 9 +234U G 1538.8 2 0.014 4 +234U G 1655.7 1 0.026 4 +234U G 1664.8 3 0.018 7 +234U G 1743.2 2 0.033 8 +234U G 1757.5 1 0.024 6 234U G 1830.8 3 0.0042 11 -234U G 1849.8 2 0.028 7 +234U G 1849.8 2 0.028 7 234U G 1927.9 4 0.054 12 -234U G 1935.2 4 9400E-6 0 +234U G 1935.2 4 0.0094 234U L 0 0+ 2.455E5 Y 6 234U L 43.481 152+ 0.252 NS 7 -234U G 43.49 2 0.12 3 E2 713 11 -234U 2 G KC=$LC=520 8$MC=143.7 21 +234U G 43.49 2 0.12 3E2 713 11 +234U 2 G LC=520 8$MC=143.7 21 234U L 143.375 214+ 234U B 2052 4 5 9.2 234U S B EAV=732.2 17 -234U G 99.86 2 3.2 6 E2 13.42 19 -234U 2 G KC=$LC=9.77 14$MC=2.71 4 +234U G 99.86 2 3.2 6E2 13.42 19 +234U 2 G LC=9.77 14$MC=2.71 4 234U L 296.075 246+ -234U G 152.71 2 6.0 7 E2 2.14 3 -234U 2 G KC=0.217 3$LC=1.404 20$MC=0.388 6 +234U G 152.71 2 6.0 7E2 2.14 3 +234U 2 G KC=0.217 3$LC=1.404 20$MC=0.388 6 234U L 497.05 4 8+ 234U G 200.97 3 0.90 13E2 0.734 11 -234U 2 G KC=0.1534 22$LC=0.424 6$MC=0.1166 17 +234U 2 G KC=0.1534 22$LC=0.424 6$MC=0.1166 17 234U L 786.295 151- -234U G 742.813 5 2.08 21E1 0.006369 -234U 2 G KC=0.00518 8$LC=8.95E-4 13$MC=2.13E-4 3 -234U G 786.272 221.21 13(E1) 0.005738 -234U 2 G KC=0.00467 7$LC=8.04E-4 12$MC=1.91E-4 3 +234U G 742.813 5 2.08 21E1 0.00636 9 +234U 2 G KC=0.00518 8$LC=8.95E-4 13$MC=2.13E-4 3 +234U G 786.272 221.21 13(E1) 0.00573 8 +234U 2 G KC=0.00467 7$LC=8.04E-4 12$MC=1.91E-4 3 234U L 809.92 8 0+ 0.1 NS -234U G 766.4 2 0.26 5 (E2) 0.0187 3 -234U 2 G KC=0.01336 19$LC=0.00396 6$MC=1003E-6 14 +234U G 766.4 2 0.26 5(E2) 0.0187 3 +234U 2 G KC=0.01336 19$LC=0.00396 6$MC=1003E-6 14 234U G 810.0 7 234U L 849.265 233- 234U B 1346 4 0.8 9.3 1 234U S B EAV=452.1 16 234U G 705.9 1 2.29 23[E1] 0.0069810 -234U 2 G KC=0.00568 8$LC=9.87E-4 14$MC=2.35E-4 4 -234U G 805.80 5 2.5 3 [E1] 0.005498 -234U 2 G KC=0.00447 7$LC=7.68E-4 11$MC=1.83E-4 3 +234U 2 G KC=0.00568 8$LC=9.87E-4 14$MC=2.35E-4 4 +234U G 805.80 5 2.5 3[E1] 0.00549 8 +234U 2 G KC=0.00447 7$LC=7.68E-4 11$MC=1.83E-4 3 234U L 851.73 5 2+ 1.71 PS 234U G 41.82 11 -234U G 708.3 2 0.023 9 [E2] 0.0219 3 -234U 2 G KC=0.01537 22$LC=0.00489 7$MC=1246E-6 18 -234U G 808.4 3 0.036 11+E2 4.200000 -234U 2 G KC=3.30000 7$LC=0.9 10$MC= +234U G 708.3 2 0.023 9[E2] 0.0219 3 +234U 2 G KC=0.01537 22$LC=0.00489 7$MC=1246E-6 18 +234U G 808.4 3 0.036 11+E2 4.2 +234U 2 G KC=3.30000 7$LC=0.9 10 234U G 851.8 1 0.073 22[E2] 0.0151322 -234U 2 G KC=0.01109 16$LC=0.00302 5$MC=7.59E-4 11 +234U 2 G KC=0.01109 16$LC=0.00302 5$MC=7.59E-4 11 234U L 926.744 212+ 1.38 PS 17 -234U G 783.4 1 0.30 4 [E2] 0.0179 3 -234U 2 G KC=0.01285 18$LC=0.00374 6$MC=9.46E-4 14 +234U G 783.4 1 0.30 4[E2] 0.0179 3 +234U 2 G KC=0.01285 18$LC=0.00374 6$MC=9.46E-4 14 234U G 883.24 4 9.7 11E2 0.0140920 -234U 2 G KC=0.01040 15$LC=0.00276 4$MC=6.92E-4 10 +234U 2 G KC=0.01040 15$LC=0.00276 4$MC=6.92E-4 10 234U G 926.7 1 7.3 12(E2) 0.0128418 -234U 2 G KC=0.00956 14$LC=0.00245 4$MC=6.13E-4 9 +234U 2 G KC=0.00956 14$LC=0.00245 4$MC=6.13E-4 9 234U L 947.59 5 4+ 234U B 1247 4 0.8 9.2 234U S B EAV=414.4 16 -234U G 804.1 1 0.62 22+E2 0.370000 -234U 2 G KC=0.1559 8$LC=0.11056 15$MC=0.10254 4 -234U G 904.2 1 0.34 4 [E2] 0.0134619 -234U 2 G KC=0.00998 14$LC=0.00260 4$MC=6.52E-4 10 +234U G 804.1 1 0.62 22+E2 0.37 +234U 2 G KC=0.1559 8$LC=0.11056 15$MC=0.10254 4 +234U G 904.2 1 0.34 4[E2] 0.0134619 +234U 2 G KC=0.00998 14$LC=0.00260 4$MC=6.52E-4 10 234U L 962.55 3 5- 234U B 1232 4 0.4 9.4 1 234U S B EAV=408.7 16 234U G 666.5 1 1.18 13[E1] 0.0077711 -234U 2 G KC=0.00631 9$LC=1103E-6 16$MC=2.63E-4 4 -234U G 819.2 1 1.9 2 [E1] 0.005338 -234U 2 G KC=0.00434 6$LC=7.44E-4 11$MC=1770E-7 25 +234U 2 G KC=0.00631 9$LC=1103E-6 16$MC=2.63E-4 4 +234U G 819.2 1 1.9 2[E1] 0.00533 8 +234U 2 G KC=0.00434 6$LC=7.44E-4 11$MC=1770E-7 25 234U L 968.45 3 3+ 234U B 1227 4 2.5 8.6 234U S B EAV=406.4 16 -234U G 825.1 2 1.9 2 [E2] 0.0161123 -234U 2 G KC=0.01173 17$LC=0.00327 5$MC=8.25E-4 12 -234U G 925.0 1 7.9 9 (E2) 0.0128818 -234U 2 G KC=0.00959 14$LC=0.00246 4$MC=6.16E-4 9 +234U G 825.1 2 1.9 2[E2] 0.0161123 +234U 2 G KC=0.01173 17$LC=0.00327 5$MC=8.25E-4 12 +234U G 925.0 1 7.9 9(E2) 0.0128818 +234U 2 G KC=0.00959 14$LC=0.00246 4$MC=6.16E-4 9 234U L 989.444 202- 0.76 NS 4 234U B 1206 4 3.1 8.5 1U 234U S B EAV=398.5 16 -234U G 62.70 1 1.6 5 E1 0.426 6 -234U 2 G KC=$LC=0.320 5$MC=0.0791 11 -234U G 140.15 2 0.51 7 M1+E2 1.2 6 5.3 18 -234U 2 G KC=2.9 22$LC=1.76 25$MC=0.47 9 -234U G 203.12 3 1.24 15M1+E2 1.5 4 1.4 4 -234U 2 G KC=0.8 4$LC=0.422 10$MC=0.1113 16 -234U G 946.00 3 13.5 15(E1) 0.004126 -234U 2 G KC=0.00337 5$LC=5.71E-4 8$MC=1355E-7 19 +234U G 62.70 1 1.6 5E1 0.426 6 +234U 2 G LC=0.320 5$MC=0.0791 11 +234U G 140.15 2 0.51 7M1+E2 1.2 6 5.3 18 +234U 2 G KC=2.9 22$LC=1.76 25$MC=0.47 9 +234U G 203.12 3 1.24 15M1+E2 1.5 4 1.4 4 +234U 2 G KC=0.8 4$LC=0.422 10$MC=0.1113 16 +234U G 946.00 3 13.5 15(E1) 0.00412 6 +234U 2 G KC=0.00337 5$LC=5.71E-4 8$MC=1355E-7 19 234U L 1023.795 243- 234U B 1171.2 405 8.3 1 234U S B EAV=385.4 16 -234U G 34.30 4 0.0037 4 (E2) 2270 40 -234U 2 G KC=$LC=1660 30$MC=457 7 -234U G 54.96 109400E-6 0 [E1] 0.603 9 -234U 2 G KC=$LC=0.453 7$MC=0.1123 17 -234U G 97.17 100.24 9 [E1] 0.1343 20 -234U 2 G KC=$LC=0.1012 15$MC=0.0248 4 -234U G 174.55 3 0.17 3 [M1+E2] 2.9 17 -234U 2 G KC=1.9 18$LC=0.74 4$MC=0.193 23 -234U G 880.52 4 4.3 6 [E1] 0.004687 -234U 2 G KC=0.00382 6$LC=6.51E-4 10$MC=1547E-7 22 -234U G 980.3 1 2.70000 0 [E1] 0.003876 -234U 2 G KC=0.00317 5$LC=5.35E-4 8$MC=1270E-7 18 +234U G 34.30 4 0.0037 4(E2) 2270 40 +234U 2 G LC=1660 30$MC=457 7 +234U G 54.96 100.0094 [E1] 0.603 9 +234U 2 G LC=0.453 7$MC=0.1123 17 +234U G 97.17 100.24 9[E1] 0.1343 20 +234U 2 G LC=0.1012 15$MC=0.0248 4 +234U G 174.55 3 0.17 3[M1+E2] 2.9 17 +234U 2 G KC=1.9 18$LC=0.74 4$MC=0.193 23 +234U G 880.52 4 4.3 6[E1] 0.00468 7 +234U 2 G KC=0.00382 6$LC=6.51E-4 10$MC=1547E-7 22 +234U G 980.3 1 2.7 [E1] 0.00387 6 +234U 2 G KC=0.00317 5$LC=5.35E-4 8$MC=1270E-7 18 234U L 1023.92 3 4+ 234U B 1171 4 1.5 13 8.8 234U S B EAV=385.4 16 -234U G 54.96 109400E-6 0 [M1+E2] 1.3E2 11 -234U 2 G KC=$LC=90 80$MC=26 21 -234U G 727.8 2 0.114 15[E2] 0.0207 3 -234U 2 G KC=0.01464 21$LC=0.00454 7$MC=1156E-6 17 -234U G 880.52 4 6.2 8 [E2] 0.0141820 -234U 2 G KC=0.01046 15$LC=0.00278 4$MC=6.97E-4 10 -234U G 980.3 1 1.77000 0 [E2] 0.0115217 -234U 2 G KC=0.00866 13$LC=0.00214 3$MC=5.34E-4 8 +234U G 54.96 100.0094 [M1+E2] 1.3E2 11 +234U 2 G LC=90 80$MC=26 21 +234U G 727.8 2 0.114 15[E2] 0.0207 3 +234U 2 G KC=0.01464 21$LC=0.00454 7$MC=1156E-6 17 +234U G 880.52 4 6.2 8[E2] 0.0141820 +234U 2 G KC=0.01046 15$LC=0.00278 4$MC=6.97E-4 10 +234U G 980.3 1 1.77 [E2] 0.0115217 +234U 2 G KC=0.00866 13$LC=0.00214 3$MC=5.34E-4 8 234U L 1069.297 224- 234U B 1126 4 8 8 234U S B EAV=368.3 15 -234U G 45.45 5 0.027 9 M1+E2 0.8 4 2.5E2 14 -234U 2 G KC=$LC=1.9E2 10$MC=50 30 -234U G 79.84 2 0.062 22E2 38.4 6 -234U 2 G KC=$LC=28.0 4$MC=7.76 11 +234U G 45.45 5 0.027 9M1+E2 0.8 4 2.5E2 14 +234U 2 G LC=1.9E2 10$MC=50 30 +234U G 79.84 2 0.062 22E2 38.4 6 +234U 2 G LC=28.0 4$MC=7.76 11 234U G 100.89 2 0.125 24[E1] 0.1218 17 -234U 2 G KC=$LC=0.0917 13$MC=0.0224 4 -234U G 106.68 5 0.036 11[M1] 3.83 6 -234U 2 G KC=$LC=2.89 4$MC=0.699 10 -234U G 220.00 8 0.146 25(M1) 2.37 4 -234U 2 G KC=1.89 3$LC=0.366 6$MC=0.0886 13 -234U G 926.0 2 1.8 13[E1] 0.004286 -234U 2 G KC=0.00350 5$LC=5.94E-4 9$MC=1409E-7 20 +234U 2 G LC=0.0917 13$MC=0.0224 4 +234U G 106.68 5 0.036 11[M1] 3.83 6 +234U 2 G LC=2.89 4$MC=0.699 10 +234U G 220.00 8 0.146 25(M1) 2.37 4 +234U 2 G KC=1.89 3$LC=0.366 6$MC=0.0886 13 +234U G 926.0 2 1.8 13[E1] 0.00428 6 +234U 2 G KC=0.00350 5$LC=5.94E-4 9$MC=1409E-7 20 234U L 1085.07 102+ 234U G 233.6 2 -234U G 235.9 300.005 3 -234U G 298.7 2 0.014 6 [E1] 0.0396 6 -234U 2 G KC=0.0315 5$LC=0.00610 9$MC=1470E-6 21 -234U G 942.0 3 0.046 9 [E2] 0.0124418 -234U 2 G KC=0.00929 13$LC=0.00236 4$MC=5.89E-4 9 +234U G 235.9 300.005 3 +234U G 298.7 2 0.014 6[E1] 0.0396 6 +234U 2 G KC=0.0315 5$LC=0.00610 9$MC=1470E-6 21 +234U G 942.0 3 0.046 9[E2] 0.0124418 +234U 2 G KC=0.00929 13$LC=0.00236 4$MC=5.89E-4 9 234U G 1041.1 2 0.032 11[E2M1] 0.023 13 -234U 2 G KC=0.018 11$LC=0.0036 18$MC=0.0009 4 -234U G 1085.3 3 0.027 8 [E2] 0.0095014 -234U 2 G KC=0.00725 11$LC=1690E-6 24$MC=4.18E-4 6 +234U 2 G KC=0.018 11$LC=0.0036 18$MC=0.0009 4 +234U G 1085.3 3 0.027 8[E2] 0.0095014 +234U 2 G KC=0.00725 11$LC=1690E-6 24$MC=4.18E-4 6 234U L 1090.89 4 5+ 234U B 1104 4 0.69 20 9.04 234U S B EAV=360.2 15 234U G 794.9 2 0.68 11[E2] 0.0173525 -234U 2 G KC=0.01253 18$LC=0.00360 5$MC=9.10E-4 13 +234U 2 G KC=0.01253 18$LC=0.00360 5$MC=9.10E-4 13 234U G 947.7 2 1.63 21[E2] 0.0123018 -234U 2 G KC=0.00919 13$LC=0.00232 4$MC=5.80E-4 9 +234U 2 G KC=0.00919 13$LC=0.00232 4$MC=5.80E-4 9 234U L 1096.12 9 6+ 234U G 799.7 2 +E2 234U G 952.7 1 0.083 13 234U L 1125.29 5 7- -234U G 628.1 1 0.24 5 [E1] 0.0086813 -234U 2 G KC=0.00705 10$LC=1239E-6 18$MC=2.96E-4 5 -234U G 829.3 2 0.36 11[E1] 0.005218 -234U 2 G KC=0.00425 6$LC=7.27E-4 11$MC=1729E-7 25 +234U G 628.1 1 0.24 5[E1] 0.0086813 +234U 2 G KC=0.00705 10$LC=1239E-6 18$MC=2.96E-4 5 +234U G 829.3 2 0.36 11[E1] 0.00521 8 +234U 2 G KC=0.00425 6$LC=7.27E-4 11$MC=1729E-7 25 234U L 1126.65 3 2+ -234U G 137.23 5 0.027 9 [E1] 0.239 4 -234U 2 G KC=0.184 3$LC=0.0413 6$MC=0.01006 15 +234U G 137.23 5 0.027 9[E1] 0.239 4 +234U 2 G KC=0.184 3$LC=0.0413 6$MC=0.01006 15 234U G 199.95 5 0.073 22(+E2+M1) 2.0 13 -234U 2 G KC=1.4 13$LC=0.483 21$MC=0.124 4 -234U G 275.04 100.094 23[M1E2] 0.8 6 -234U 2 G KC=0.6 5$LC=0.16 4$MC=0.040 8 +234U 2 G KC=1.4 13$LC=0.483 21$MC=0.124 4 +234U G 275.04 100.094 23[M1E2] 0.8 6 +234U 2 G KC=0.6 5$LC=0.16 4$MC=0.040 8 234U G 316.7 1 0.104 14[E2] 0.1597 23 -234U 2 G KC=0.0677 10$LC=0.0674 10$MC=0.0182 3 -234U G 340.2 1 0.041 9 [E1] 0.0298 5 -234U 2 G KC=0.0239 4$LC=0.00453 7$MC=1090E-6 16 -234U G 1083.2 1 0.51 6 (M1) 0.0317 5 -234U 2 G KC=0.0254 4$LC=0.00477 7$MC=1147E-6 16 -234U G 1126.8 1 0.30 4 [E2] 0.0088513 -234U 2 G KC=0.00679 10$LC=1552E-6 22$MC=3.83E-4 6 +234U 2 G KC=0.0677 10$LC=0.0674 10$MC=0.0182 3 +234U G 340.2 1 0.041 9[E1] 0.0298 5 +234U 2 G KC=0.0239 4$LC=0.00453 7$MC=1090E-6 16 +234U G 1083.2 1 0.51 6(M1) 0.0317 5 +234U 2 G KC=0.0254 4$LC=0.00477 7$MC=1147E-6 16 +234U G 1126.8 1 0.30 4[E2] 0.0088513 +234U 2 G KC=0.00679 10$LC=1552E-6 22$MC=3.83E-4 6 234U L 1127.535 255- 234U B 1067 4 1.9 10 8.54 1 234U S B EAV=346.5 15 -234U G 58.20 6 0.0027 9 (E2) 174 3 -234U 2 G KC=$LC=126.9 19$MC=35.1 6 -234U G 103.77 2 0.24 4 (E2) 11.22 16 -234U 2 G KC=$LC=8.17 12$MC=2.27 4 +234U G 58.20 6 0.0027 9(E2) 174 3 +234U 2 G LC=126.9 19$MC=35.1 6 +234U G 103.77 2 0.24 4(E2) 11.22 16 +234U 2 G LC=8.17 12$MC=2.27 4 234U G 164.94 5 0.052 22[E2M1] 3.5 19 -234U 2 G KC=2.2 21$LC=0.91 9$MC=0.24 4 -234U G 278.3 1 0.042 11[E2] 0.238 4 -234U 2 G KC=0.0863 13$LC=0.1112 16$MC=0.0303 5 -234U G 831.5 1 4.2 5 [E1] 0.005188 -234U 2 G KC=0.00423 6$LC=7.24E-4 11$MC=1721E-7 24 -234U G 984.2 1 1.63 21[E1] 0.003856 -234U 2 G KC=0.00315 5$LC=5.31E-4 8$MC=1261E-7 18 +234U 2 G KC=2.2 21$LC=0.91 9$MC=0.24 4 +234U G 278.3 1 0.042 11[E2] 0.238 4 +234U 2 G KC=0.0863 13$LC=0.1112 16$MC=0.0303 5 +234U G 831.5 1 4.2 5[E1] 0.00518 8 +234U 2 G KC=0.00423 6$LC=7.24E-4 11$MC=1721E-7 24 +234U G 984.2 1 1.63 21[E1] 0.00385 6 +234U 2 G KC=0.00315 5$LC=5.31E-4 8$MC=1261E-7 18 234U L 1165.41 4 3+ 234U G 196.80 5 0.073 22+E2+M1 2.0 13 -234U 2 G KC=1.4 13$LC=0.483 21$MC=0.124 4 -234U G 313.5 1 0.104 14[E2M1] 0.5 4 -234U 2 G KC=0.4 4$LC=0.10 4$MC=0.026 7 -234U G 1021.8 2 0.15 4 [M1] 0.0370 6 -234U 2 G KC=0.0297 5$LC=0.00557 8$MC=1340E-6 19 -234U G 1121.7 1 0.25 4 M1 0.0289 4 -234U 2 G KC=0.0232 4$LC=0.00434 6$MC=1045E-6 15 +234U 2 G KC=1.4 13$LC=0.483 21$MC=0.124 4 +234U G 313.5 1 0.104 14[E2M1] 0.5 4 +234U 2 G KC=0.4 4$LC=0.10 4$MC=0.026 7 +234U G 1021.8 2 0.15 4[M1] 0.0370 6 +234U 2 G KC=0.0297 5$LC=0.00557 8$MC=1340E-6 19 +234U G 1121.7 1 0.25 4M1 0.0289 4 +234U 2 G KC=0.0232 4$LC=0.00434 6$MC=1045E-6 15 234U L 1172.03 3 6+ -234U G 675.1 1 0.101 14[E2] 0.0242 4 -234U 2 G KC=0.01674 24$LC=0.00558 8$MC=1427E-6 20 +234U G 675.1 1 0.101 14[E2] 0.0242 4 +234U 2 G KC=0.01674 24$LC=0.00558 8$MC=1427E-6 20 234U G 876.0 1 2.55 23(E2) 0.0143220 -234U 2 G KC=0.01055 15$LC=0.00282 4$MC=7.06E-4 10 -234U G 1028.7 1 0.57 6 [E2] 0.0105115 -234U 2 G KC=0.00796 12$LC=0.00191 3$MC=4.75E-4 7 +234U 2 G KC=0.01055 15$LC=0.00282 4$MC=7.06E-4 10 +234U G 1028.7 1 0.57 6[E2] 0.0105115 +234U 2 G KC=0.00796 12$LC=0.00191 3$MC=4.75E-4 7 234U L 1194.761 236- 234U B 1000 4 1.5 8.5 1U 234U S B EAV=312.6 14 234U G 67.25 100.036 11M1+E2 1.2 3 57 11 -234U 2 G KC=$LC=42 8$MC=11.5 22 -234U G 69.46 5 0.018 8 [E2M1] 40 30 -234U 2 G KC=$LC=32 23$MC=9 7 -234U G 125.46 1 0.79 12E2 4.89 7 -234U 2 G KC=0.216 3$LC=3.41 5$MC=0.945 14 -234U G 232.21 3 0.18 3 [E2M1] 1.2 8 -234U 2 G KC=0.9 8$LC=0.27 5$MC=0.070 7 -234U G 898.67 5 3.3 4 [E1] 0.004517 -234U 2 G KC=0.00369 6$LC=6.27E-4 9$MC=1489E-7 21 +234U 2 G LC=42 8$MC=11.5 22 +234U G 69.46 5 0.018 8[E2M1] 40 30 +234U 2 G LC=32 23$MC=9 7 +234U G 125.46 1 0.79 12E2 4.89 7 +234U 2 G KC=0.216 3$LC=3.41 5$MC=0.945 14 +234U G 232.21 3 0.18 3[E2M1] 1.2 8 +234U 2 G KC=0.9 8$LC=0.27 5$MC=0.070 7 +234U G 898.67 5 3.3 4[E1] 0.00451 7 +234U 2 G KC=0.00369 6$LC=6.27E-4 9$MC=1489E-7 21 234U L 1214.70 5 4+ 234U B 980 4 0.30 12 9.22 234U S B EAV=314.2 15 -234U G 267.12 5 0.18 3 [E2M1] 0.8 6 -234U 2 G KC=0.6 5$LC=0.17 5$MC=0.044 8 -234U G 365.0 3 0.018 7 [E1] 0.0257 4 -234U 2 G KC=0.0206 3$LC=0.00387 6$MC=9.30E-4 14 +234U G 267.12 5 0.18 3[E2M1] 0.8 6 +234U 2 G KC=0.6 5$LC=0.17 5$MC=0.044 8 +234U G 365.0 3 0.018 7[E1] 0.0257 4 +234U 2 G KC=0.0206 3$LC=0.00387 6$MC=9.30E-4 14 234U G 918.4 1 0.100 14[E2] 0.0130619 -234U 2 G KC=0.00971 14$LC=0.00251 4$MC=6.27E-4 9 +234U 2 G KC=0.00971 14$LC=0.00251 4$MC=6.27E-4 9 234U G 1171.3 1 0.090 13[E2] 0.0082412 -234U 2 G KC=0.00634 9$LC=1423E-6 20$MC=3.50E-4 5 +234U 2 G KC=0.00634 9$LC=1423E-6 20$MC=3.50E-4 5 234U L 1237.24 3 1- -234U G 247.79 7 0.00037 4 -234U G 310.52 101.35E-4 15 -234U G 387.94 6 0.00072 6 -234U G 427.4 4 3.1E-5 10 -234U G 450.93 4 0.0040 19M1+E2 0.7 0.241 4 -234U 2 G KC=0.187 3$LC=0.0400 6$MC=0.00980 14 -234U G 1193.77 2 0.021 6 E1 0.002774 -234U 2 G KC=0.00226 4$LC=3.77E-4 6$MC=8.92E-5 13 -234U G 1237.3 3 9400E-6 0 E1 0.002624 -234U 2 G KC=0.00213 3$LC=3.54E-4 5$MC=8.38E-5 12 +234U G 247.79 7 0.00037 4 +234U G 310.52 100.00013515 +234U G 387.94 6 0.00072 6 +234U G 427.4 4 0.00003110 +234U G 450.93 4 0.0040 19M1+E2 0.7 0.241 4 +234U 2 G KC=0.187 3$LC=0.0400 6$MC=0.00980 14 +234U G 1193.77 2 0.021 6E1 0.00277 4 +234U 2 G KC=0.00226 4$LC=3.77E-4 6$MC=8.92E-5 13 +234U G 1237.3 3 0.0094 E1 0.00262 4 +234U 2 G KC=0.00213 3$LC=3.54E-4 5$MC=8.38E-5 12 234U L 1261.77 3 7+ -234U G 764.8 2 0.20 5 [M1E2] 0.05 3 -234U 2 G KC=0.04 3$LC=0.008 4$MC=0.002 1 -234U G 965.8 1 0.48 6 [M1E2] 0.027 16 -234U 2 G KC=0.022 13$LC=0.0043 22$MC=0.0011 5 +234U G 764.8 2 0.20 5[M1E2] 0.05 3 +234U 2 G KC=0.04 3$LC=0.008 4$MC=0.002 1 +234U G 965.8 1 0.48 6[M1E2] 0.027 16 +234U 2 G KC=0.022 13$LC=0.0043 22$MC=0.0011 5 234U L 1274.32 9 (5+)+ 234U G 978.2 3 0.090 23 234U L 1277.45 3 7- -234U G 149.88 3 0.073 22[E2] 2.31 4 -234U 2 G KC=0.220 3$LC=1.526 22$MC=0.422 6 -234U G 780.4 2 0.90 9 [E1] 0.005819 -234U 2 G KC=0.00474 7$LC=8.15E-4 12$MC=1.94E-4 3 -234U G 981.6 3 0.73 22[E1] 0.003876 -234U 2 G KC=0.00316 5$LC=5.34E-4 8$MC=1267E-7 18 +234U G 149.88 3 0.073 22[E2] 2.31 4 +234U 2 G KC=0.220 3$LC=1.526 22$MC=0.422 6 +234U G 780.4 2 0.90 9[E1] 0.00581 9 +234U 2 G KC=0.00474 7$LC=8.15E-4 12$MC=1.94E-4 3 +234U G 981.6 3 0.73 22[E1] 0.00387 6 +234U 2 G KC=0.00316 5$LC=5.34E-4 8$MC=1267E-7 18 234U L 1312.20 9 3- 234U B 883 4 0.109 18 9.5 1 234U S B EAV=278.7 15 234U G 75.0 3 -234U G 343.8 2 0.034 8 [E1] 0.0292 5 -234U 2 G KC=0.0233 4$LC=0.00442 7$MC=1064E-6 15 +234U G 343.8 2 0.034 8[E1] 0.0292 5 +234U 2 G KC=0.0233 4$LC=0.00442 7$MC=1064E-6 15 234U G 365.0 3 -234U G 385.4 1 0.042 11[E1] 0.0229 4 -234U 2 G KC=0.0184 3$LC=0.00343 5$MC=8.24E-4 12 +234U G 385.4 1 0.042 11[E1] 0.0229 4 +234U 2 G KC=0.0184 3$LC=0.00343 5$MC=8.24E-4 12 234U L 1341.33 8 (6+)+ -234U G 379.1 1 0.042 11[E1] 0.0237 4 -234U 2 G KC=0.0190 3$LC=0.00356 5$MC=8.54E-4 12 -234U G 1044.4 2 0.031 3 +234U G 379.1 1 0.042 11[E1] 0.0237 4 +234U 2 G KC=0.0190 3$LC=0.00356 5$MC=8.54E-4 12 +234U G 1044.4 2 0.031 3 234U L 1421.252 246- 33.5 US 20 -234U G 143.78 2 0.32 5 (M1+E2) 1 5.310000 -234U 2 G KC=3.24000 0$LC=1.53200 0$MC=0.40300 0 +234U G 143.78 2 0.32 5(M1+E2) 1 5.31 +234U 2 G KC=3.24 $LC=1.532 $MC=0.403 234U G 159.48 2 0.66 10[E1] 0.1676 24 -234U 2 G KC=0.1303 19$LC=0.0282 4$MC=0.00684 10 -234U G 226.50 3 4.9 6 M1+E2 1.0 3 1.3 3 -234U 2 G KC=0.9 3$LC=0.297 15$MC=0.0759 23 -234U G 249.22 1 2.5 4 E1 0.0594 9 -234U 2 G KC=0.0470 7$LC=0.00935 13$MC=0.00226 4 -234U G 293.79 5 3.0 4 M1+E2 1.7 4 0.42 10 -234U 2 G KC=0.28 9$LC=0.109 9$MC=0.0283 18 -234U G 295.91 8 0.146 25[M1+E2] 0.6 5 -234U 2 G KC=0.5 4$LC=0.12 4$MC=0.031 8 -234U G 330.40 5 0.78 9 [E1] 0.0318 5 -234U 2 G KC=0.0254 4$LC=0.00484 7$MC=1165E-6 17 -234U G 351.9 1 0.42 5 E2 0.1175 17 -234U 2 G KC=0.0555 8$LC=0.0455 7$MC=0.01222 18 -234U G 397.7 3 0.027 7 [M2] 1.349 20 -234U 2 G KC=0.986 14$LC=0.270 4$MC=0.0687 10 -234U G 458.68 5 1.14 12M1+E2 1.4 4 0.14 5 -234U 2 G KC=0.11 4$LC=0.028 5$MC=0.0071 11 -234U G 1125.2 1 0.36 8 [E1] 0.003055 -234U 2 G KC=0.00250 4$LC=4.18E-4 6$MC=9.91E-5 14 -234U G 1277.7 2 0.045 9 [M2] 0.0473 7 -234U 2 G KC=0.0370 6$LC=0.00771 11$MC=0.00188 3 +234U 2 G KC=0.1303 19$LC=0.0282 4$MC=0.00684 10 +234U G 226.50 3 4.9 6M1+E2 1.0 3 1.3 3 +234U 2 G KC=0.9 3$LC=0.297 15$MC=0.0759 23 +234U G 249.22 1 2.5 4E1 0.0594 9 +234U 2 G KC=0.0470 7$LC=0.00935 13$MC=0.00226 4 +234U G 293.79 5 3.0 4M1+E2 1.7 4 0.42 10 +234U 2 G KC=0.28 9$LC=0.109 9$MC=0.0283 18 +234U G 295.91 8 0.146 25[M1+E2] 0.6 5 +234U 2 G KC=0.5 4$LC=0.12 4$MC=0.031 8 +234U G 330.40 5 0.78 9[E1] 0.0318 5 +234U 2 G KC=0.0254 4$LC=0.00484 7$MC=1165E-6 17 +234U G 351.9 1 0.42 5E2 0.1175 17 +234U 2 G KC=0.0555 8$LC=0.0455 7$MC=0.01222 18 +234U G 397.7 3 0.027 7[M2] 1.349 20 +234U 2 G KC=0.986 14$LC=0.270 4$MC=0.0687 10 +234U G 458.68 5 1.14 12M1+E2 1.4 4 0.14 5 +234U 2 G KC=0.11 4$LC=0.028 5$MC=0.0071 11 +234U G 1125.2 1 0.36 8[E1] 0.00305 5 +234U 2 G KC=0.00250 4$LC=4.18E-4 6$MC=9.91E-5 14 +234U G 1277.7 2 0.045 9[M2] 0.0473 7 +234U 2 G KC=0.0370 6$LC=0.00771 11$MC=0.00188 3 234U L 1447.89 105- -234U B 747 4 0.11 3 9.25 1 +234U B 747 4 0.11 3 9.25 1 234U S B EAV=230.3 14 -234U G 320.4 1 0.052 8 [E2M1] 0.5 4 -234U 2 G KC=0.4 3$LC=0.10 4$MC=0.024 7 -234U G 1151.4 3 0.032 10[E1] 0.002945 -234U 2 G KC=0.00240 4$LC=4.02E-4 6$MC=9.51E-5 14 +234U G 320.4 1 0.052 8[E2M1] 0.5 4 +234U 2 G KC=0.4 3$LC=0.10 4$MC=0.024 7 +234U G 1151.4 3 0.032 10[E1] 0.00294 5 +234U 2 G KC=0.00240 4$LC=4.02E-4 6$MC=9.51E-5 14 234U L 1456.54 7 (2-)+ -234U G 669.7 1 6000E-7 0 -234U G 1414.4 2 2800E-6 0 +234U G 669.7 1 0.0006 +234U G 1414.4 2 0.0028 234U L 1486.17 12(3-)+ -234U B 709 4 0.12 3 9.14 +234U B 709 4 0.12 3 9.14 234U S B EAV=216.9 14 234U G 559.2 2 0.073 22[E1] 0.0108416 -234U 2 G KC=0.00877 13$LC=1562E-6 22$MC=3.73E-4 6 -234U G 1342.9 2 0.012 5 [E1] 0.002324 -234U 2 G KC=0.00185 3$LC=3.07E-4 5$MC=7.26E-5 11 -234U G 1442.8 2 0.031 7 [E1] 0.002123 -234U 2 G KC=1643E-6 23$LC=2.71E-4 4$MC=6.41E-5 9 +234U 2 G KC=0.00877 13$LC=1562E-6 22$MC=3.73E-4 6 +234U G 1342.9 2 0.012 5[E1] 0.00232 4 +234U 2 G KC=0.00185 3$LC=3.07E-4 5$MC=7.26E-5 11 +234U G 1442.8 2 0.031 7[E1] 0.00212 3 +234U 2 G KC=1643E-6 23$LC=2.71E-4 4$MC=6.41E-5 9 234U L 1496.14 3 3+ 234U B 699 4 2.7 7.8 234U S B EAV=213.5 14 -234U G 221.83 100.073 22[E2] 0.513 8 -234U 2 G KC=0.1301 19$LC=0.280 4$MC=0.0767 11 -234U G 330.40 5 M1+E2 0.7 0.562 8 -234U 2 G KC=0.431 6$LC=0.0980 14$MC=0.0242 4 -234U G 369.50 5 2.5 3 M1 0.565 8 -234U 2 G KC=0.450 7$LC=0.0866 13$MC=0.0209 3 -234U G 426.95 5 0.46 5 [E1] 0.0185 3 -234U 2 G KC=0.01491 21$LC=0.00274 4$MC=6.58E-4 10 -234U G 472.3 1 0.36 4 [M1] 0.290 4 -234U 2 G KC=0.231 4$LC=0.0443 7$MC=0.01069 15 +234U G 221.83 100.073 22[E2] 0.513 8 +234U 2 G KC=0.1301 19$LC=0.280 4$MC=0.0767 11 +234U G 330.40 5 M1+E2 0.7 0.562 8 +234U 2 G KC=0.431 6$LC=0.0980 14$MC=0.0242 4 +234U G 369.50 5 2.5 3M1 0.565 8 +234U 2 G KC=0.450 7$LC=0.0866 13$MC=0.0209 3 +234U G 426.95 5 0.46 5[E1] 0.0185 3 +234U 2 G KC=0.01491 21$LC=0.00274 4$MC=6.58E-4 10 +234U G 472.3 1 0.36 4[M1] 0.290 4 +234U 2 G KC=0.231 4$LC=0.0443 7$MC=0.01069 15 234U G 506.75 5 1.30 14[E1] 0.0131419 -234U 2 G KC=0.01061 15$LC=0.00191 3$MC=4.57E-4 7 -234U G 527.9 1 0.40 5 (M1) 0.215 3 -234U 2 G KC=0.1716 24$LC=0.0328 5$MC=0.00790 11 +234U 2 G KC=0.01061 15$LC=0.00191 3$MC=4.57E-4 7 +234U G 527.90 100.40 5(M1) 0.215 3 +234U 2 G KC=0.1716 24$LC=0.0328 5$MC=0.00790 11 234U G 569.5 1 9.3 12M1 0.1754 25 -234U 2 G KC=0.1401 20$LC=0.0267 4$MC=0.00643 9 +234U 2 G KC=0.1401 20$LC=0.0267 4$MC=0.00643 9 234U G 646.5 1 0.114 15[E1] 0.0082212 -234U 2 G KC=0.00668 10$LC=1170E-6 17$MC=2.79E-4 4 +234U 2 G KC=0.00668 10$LC=1170E-6 17$MC=2.79E-4 4 234U G 1352.9 1 1.16 12M1 0.0176625 -234U 2 G KC=0.01412 20$LC=0.00263 4$MC=6.33E-4 9 -234U G 1452.7 1 0.81 9 [M1] 0.0146821 -234U 2 G KC=0.01169 17$LC=0.00218 3$MC=5.24E-4 8 +234U 2 G KC=0.01412 20$LC=0.00263 4$MC=6.33E-4 9 +234U G 1452.7 1 0.81 9[M1] 0.0146821 +234U 2 G KC=0.01169 17$LC=0.00218 3$MC=5.24E-4 8 234U L 1502.38 8 3,4++ -234U B 693 4 0.25 4 8.78 +234U B 693 4 0.25 4 8.78 234U S B EAV=211.3 14 234U G 1359.0 1 0.156 25 234U G 1458.9 1 0.094 23 234U L 1533.37 5 (4-)+ -234U B 662 4 0.21 4 8.79 +234U B 662 4 0.21 4 8.79 234U S B EAV=200.6 14 -234U G 464.2 1 0.031 11[M1] 0.304 5 -234U 2 G KC=0.243 4$LC=0.0464 7$MC=0.01120 16 -234U G 543.8 1 0.135 24[E2] 0.0389 6 -234U 2 G KC=0.0247 4$LC=0.01049 15$MC=0.00273 4 -234U G 1389.6 2 0.073 22[E1] 0.002224 -234U 2 G KC=1749E-6 25$LC=2.89E-4 4$MC=6.84E-5 10 +234U G 464.2 1 0.031 11[M1] 0.304 5 +234U 2 G KC=0.243 4$LC=0.0464 7$MC=0.01120 16 +234U G 543.8 1 0.135 24[E2] 0.0389 6 +234U 2 G KC=0.0247 4$LC=0.01049 15$MC=0.00273 4 +234U G 1389.6 2 0.073 22[E1] 0.00222 4 +234U 2 G KC=1749E-6 25$LC=2.89E-4 4$MC=6.84E-5 10 234U L 1537.25 3 4+ 234U B 658 4 0.9 8.1 234U S B EAV=199.3 14 -234U G 372.0 1 1.23 14M1(+E2) 0.3 0.517 8 -234U 2 G KC=0.410 6$LC=0.0811 12$MC=0.0197 3 -234U G 409.8 1 0.34 5 [E1] 0.0202 3 -234U 2 G KC=0.01620 23$LC=0.00300 5$MC=0.00072 1 -234U G 446.6 1 0.114 15[M1] 0.338 5 -234U 2 G KC=0.269 4$LC=0.0516 8$MC=0.01245 18 -234U G 468.0 1 0.22 3 [E1] 0.0153922 -234U 2 G KC=0.01241 18$LC=0.00226 4$MC=5.41E-4 8 -234U G 513.4 1 0.38000 0 [M1] 0.232 4 -234U 2 G KC=0.185 3$LC=0.0353 5$MC=0.00852 12 -234U G 513.5 1 0.76000 0 [E1] 0.0128018 -234U 2 G KC=0.01035 15$LC=0.00186 3$MC=4.45E-4 7 -234U G 568.9 2 3.6 6 M1 0.1759 25 -234U 2 G KC=0.1404 20$LC=0.0268 4$MC=0.00645 9 -234U G 590.3 100.036 11[E2M1] 0.10 7 -234U 2 G KC=0.07 6$LC=0.016 8$MC=0.0040 19 -234U G 685.1 2 0.15 4 -234U G 1241.2 1 0.23 3 (E2) 0.0074011 -234U 2 G KC=0.00573 8$LC=1251E-6 18$MC=3.07E-4 5 +234U G 372.0 1 1.23 14M1(+E2) 0.3 0.517 8 +234U 2 G KC=0.410 6$LC=0.0811 12$MC=0.0197 3 +234U G 409.8 1 0.34 5[E1] 0.0202 3 +234U 2 G KC=0.01620 23$LC=0.00300 5$MC=0.00072 1 +234U G 446.6 1 0.114 15[M1] 0.338 5 +234U 2 G KC=0.269 4$LC=0.0516 8$MC=0.01245 18 +234U G 468.0 1 0.22 3[E1] 0.0153922 +234U 2 G KC=0.01241 18$LC=0.00226 4$MC=5.41E-4 8 +234U G 513.4 1 0.38 [M1] 0.232 4 +234U 2 G KC=0.185 3$LC=0.0353 5$MC=0.00852 12 +234U G 513.5 1 0.76 [E1] 0.0128018 +234U 2 G KC=0.01035 15$LC=0.00186 3$MC=4.45E-4 7 +234U G 568.9 2 3.6 6M1 0.1759 25 +234U 2 G KC=0.1404 20$LC=0.0268 4$MC=0.00645 9 +234U G 590.3 100.036 11[E2M1] 0.10 7 +234U 2 G KC=0.07 6$LC=0.016 8$MC=0.0040 19 +234U G 685.1 2 0.15 4 +234U G 1241.2 1 0.23 3(E2) 0.0074011 +234U 2 G KC=0.00573 8$LC=1251E-6 18$MC=3.07E-4 5 234U G 1393.9 1 2.08 21M1 0.0163423 -234U 2 G KC=0.01304 19$LC=0.00243 4$MC=5.85E-4 9 -234U G 1493.6 1 0.104 14[E2] 0.005318 -234U 2 G KC=0.00414 6$LC=8.42E-4 12$MC=2.05E-4 3 +234U 2 G KC=0.01304 19$LC=0.00243 4$MC=5.85E-4 9 +234U G 1493.6 1 0.104 14[E2] 0.00531 8 +234U 2 G KC=0.00414 6$LC=8.42E-4 12$MC=2.05E-4 3 234U L 1543.71 5 4+ -234U B 651 4 0.10 9 9.1 +234U B 651 4 0.10 9 9.1 234U S B EAV=197.1 14 234U G 474.2 2 0.036 11[E1] 0.0149921 -234U 2 G KC=0.01209 17$LC=0.00219 3$MC=5.26E-4 8 -234U G 575.5 1 0.027 9 [E2M1] 0.10 7 -234U 2 G KC=0.08 6$LC=0.017 9$MC=0.0043 20 -234U G 617.0 2 0.052 22[E2] 0.0294 5 -234U 2 G KC=0.0197 3$LC=0.00720 11$MC=0.00186 3 -234U G 1247.8 2 0.022 6 [E2] 0.0073311 -234U 2 G KC=0.00567 8$LC=1237E-6 18$MC=3.04E-4 5 -234U G 1400.3 1 0.18 3 [E2M1] 0.011 6 -234U 2 G KC=0.009 5$LC=0.0017 8$MC=0.00041 18 -234U G 1500.0 2 0.011 4 [E2] 0.005288 -234U 2 G KC=0.00411 6$LC=8.35E-4 12$MC=2.03E-4 3 +234U 2 G KC=0.01209 17$LC=0.00219 3$MC=5.26E-4 8 +234U G 575.5 1 0.027 9[E2M1] 0.10 7 +234U 2 G KC=0.08 6$LC=0.017 9$MC=0.0043 20 +234U G 617.0 2 0.052 22[E2] 0.0294 5 +234U 2 G KC=0.0197 3$LC=0.00720 11$MC=0.00186 3 +234U G 1247.8 2 0.022 6[E2] 0.0073311 +234U 2 G KC=0.00567 8$LC=1237E-6 18$MC=3.04E-4 5 +234U G 1400.3 1 0.18 3[E2M1] 0.011 6 +234U 2 G KC=0.009 5$LC=0.0017 8$MC=0.00041 18 +234U G 1500.0 2 0.011 4[E2] 0.00528 8 +234U 2 G KC=0.00411 6$LC=8.35E-4 12$MC=2.03E-4 3 234U L 1548.10 8 (5)+ 234U B 647 4 0.078 20 9.18 234U S B EAV=195.6 14 -234U G 452.4 3 0.027 9 +234U G 452.4 3 0.027 9 234U G 478.6 1 0.125 15[E1] 0.0147221 -234U 2 G KC=0.01187 17$LC=0.00215 3$MC=5.16E-4 8 -234U G 1252.6 2 0.018 8 +234U 2 G KC=0.01187 17$LC=0.00215 3$MC=5.16E-4 8 +234U G 1252.6 2 0.018 8 234U L 1552.554 245+ 2.200 NS 25 234U B 642 4 19.6 18 6.77 234U S B EAV=194.0 14 -234U G 131.30 1 18.2 16E1 0.265 4 -234U 2 G KC=0.204 3$LC=0.0463 7$MC=0.01128 16 +234U G 131.30 1 18.2 16E1 0.265 4 +234U 2 G KC=0.204 3$LC=0.0463 7$MC=0.01128 16 234U G 461.5 1 -234U G 529.1 3 0.09 4 [E2M1] 0.13 9 -234U 2 G KC=0.10 8$LC=0.022 11$MC=0.0054 25 -234U G 584.1 1 0.18 30[E2] 0.0331 5 -234U 2 G KC=0.0217 3$LC=0.00845 12$MC=0.00219 3 -234U G 604.6 3 0.052 22[E2M1] 0.09 6 -234U 2 G KC=0.07 5$LC=0.015 8$MC=0.0037 18 -234U G 1256.5 1 0.059 8 [M1E2] 0.014 8 -234U 2 G KC=0.011 6$LC=0.0022 10$MC=0.00054 24 +234U G 529.1 3 0.09 4[E2M1] 0.13 9 +234U 2 G KC=0.10 8$LC=0.022 11$MC=0.0054 25 +234U G 584.1 1 0.18 30[E2] 0.0331 5 +234U 2 G KC=0.0217 3$LC=0.00845 12$MC=0.00219 3 +234U G 604.6 3 0.052 22[E2M1] 0.09 6 +234U 2 G KC=0.07 5$LC=0.015 8$MC=0.0037 18 +234U G 1256.5 1 0.059 8[M1E2] 0.014 8 +234U 2 G KC=0.011 6$LC=0.0022 10$MC=0.00054 24 234U G 1409.1 2 0.045 10 234U L 1581.67 10(5-)+ -234U B 613 4 0.05 3 9.3 +234U B 613 4 0.05 3 9.3 234U S B EAV=184.1 14 -234U G 558.0 2 0.094 23[E2] 0.0367 6 -234U 2 G KC=0.0236 4$LC=0.00970 14$MC=0.00252 4 -234U G 619.0 2 0.036 11[M1+E2] 0.08 6 -234U 2 G KC=0.07 5$LC=0.014 7$MC=0.0035 17 +234U G 558.0 2 0.094 23[E2] 0.0367 6 +234U 2 G KC=0.0236 4$LC=0.00970 14$MC=0.00252 4 +234U G 619.0 2 0.036 11[M1+E2] 0.08 6 +234U 2 G KC=0.07 5$LC=0.014 7$MC=0.0035 17 234U G 634.3 2 234U L 1588.84 5 5+ 234U B 606 4 0.7 8.1 234U S B EAV=181.7 14 -234U G 55.45 5 0.027 9 (E1) 0.589 9 -234U 2 G KC=$LC=0.443 7$MC=0.1097 16 -234U G 394.1 1 0.094 14[E1] 0.0219 3 -234U 2 G KC=0.01755 25$LC=0.00326 5$MC=7.84E-4 11 -234U G 461.5 1 0.034 11[M1] 0.309 5 -234U 2 G KC=0.246 4$LC=0.0472 7$MC=0.01138 16 -234U G 498.0 1 0.062 12[M1] 0.252 4 -234U 2 G KC=0.201 3$LC=0.0384 6$MC=0.00925 13 -234U G 519.6 1 0.40 5 [E1] 0.0125118 -234U 2 G KC=0.01011 15$LC=0.00181 3$MC=4.34E-4 6 -234U G 565.2 1 1.04 11(M1) 0.179 3 -234U 2 G KC=0.1429 20$LC=0.0272 4$MC=0.00656 10 -234U G 1292.8 1 0.47 6 M1 0.0199 3 -234U 2 G KC=0.01592 23$LC=0.00297 5$MC=7.15E-4 10 -234U G 1445.4 1 0.32 5 [M1] 0.0148821 -234U 2 G KC=0.01185 17$LC=0.00221 3$MC=5.31E-4 8 +234U G 55.45 5 0.027 9(E1) 0.589 9 +234U 2 G LC=0.443 7$MC=0.1097 16 +234U G 394.1 1 0.094 14[E1] 0.0219 3 +234U 2 G KC=0.01755 25$LC=0.00326 5$MC=7.84E-4 11 +234U G 461.5 1 0.034 11[M1] 0.309 5 +234U 2 G KC=0.246 4$LC=0.0472 7$MC=0.01138 16 +234U G 498.0 1 0.062 12[M1] 0.252 4 +234U 2 G KC=0.201 3$LC=0.0384 6$MC=0.00925 13 +234U G 519.60 100.40 5[E1] 0.0125118 +234U 2 G KC=0.01011 15$LC=0.00181 3$MC=4.34E-4 6 +234U G 565.2 1 1.04 11(M1) 0.179 3 +234U 2 G KC=0.1429 20$LC=0.0272 4$MC=0.00656 10 +234U G 1292.8 1 0.47 6M1 0.0199 3 +234U 2 G KC=0.01592 23$LC=0.00297 5$MC=7.15E-4 10 +234U G 1445.4 1 0.32 5[M1] 0.0148821 +234U 2 G KC=0.01185 17$LC=0.00221 3$MC=5.31E-4 8 234U L 1619.46 9 (6+)+ 234U B 576 4 0.035 20 9.36 2 234U S B EAV=171.4 14 -234U G 357.9 1 0.036 11[M1E2] 0.4 3 -234U 2 G KC=0.27 22$LC=0.07 3$MC=0.017 6 +234U G 357.9 1 0.036 11[M1E2] 0.4 3 +234U 2 G KC=0.27 22$LC=0.07 3$MC=0.017 6 234U G 446.6 1 234U G 529.1 3 -234U G 657.4 1 0.40 5 -234U G 1475.8 2 0.008 4 +234U G 657.4 1 0.40 5 +234U G 1475.8 2 0.008 4 234U L 1649.99 12(6-)+ -234U B 545 4 0.18 4 8.64 2 +234U B 545 4 0.18 4 8.64 2 234U S B EAV=164.6 13 -234U G 553.7 1 0.045 16[E1] 0.0110516 -234U 2 G KC=0.00894 13$LC=1594E-6 23$MC=3.81E-4 6 -234U G 1354.6 2 0.14 4 [E1] 0.002294 -234U 2 G KC=0.00183 3$LC=3.02E-4 5$MC=7.15E-5 10 +234U G 553.70 100.045 16[E1] 0.0110516 +234U 2 G KC=0.00894 13$LC=1594E-6 23$MC=3.81E-4 6 +234U G 1354.6 2 0.14 4[E1] 0.00229 4 +234U 2 G KC=0.00183 3$LC=3.02E-4 5$MC=7.15E-5 10 234U L 1653.35 7 (3+)+ 234U B 542 4 0.95 13 7.84 234U S B EAV=160.1 14 -234U G 629.4 1 0.35 6 (M1) 0.1342 19 -234U 2 G KC=0.1072 15$LC=0.0204 3$MC=0.00491 7 -234U G 663.9 1 0.54 9 [E1] 0.0078211 -234U 2 G KC=0.00636 9$LC=1111E-6 16$MC=2.65E-4 4 -234U G 1510.1 2 9400E-6 0 +234U G 629.4 1 0.35 6(M1) 0.1342 19 +234U 2 G KC=0.1072 15$LC=0.0204 3$MC=0.00491 7 +234U G 663.9 1 0.54 9[E1] 0.0078211 +234U 2 G KC=0.00636 9$LC=1111E-6 16$MC=2.65E-4 4 +234U G 1510.1 2 0.0094 234U L 1693.42 3 5- -234U B 502 4 6.9 8 6.87 1 +234U B 502 4 6.9 8 6.87 1 234U S B EAV=146.8 14 -234U G 140.91 3 0.31 5 [E1] 0.224 4 -234U 2 G KC=0.1732 25$LC=0.0386 6$MC=0.00940 14 +234U G 140.91 3 0.31 5[E1] 0.224 4 +234U 2 G KC=0.1732 25$LC=0.0386 6$MC=0.00940 14 234U G 272.28 5 1.09 14M1+E2 0.64 1.004 14 -234U 2 G KC=0.766 11$LC=0.1783 25$MC=0.0442 7 +234U 2 G KC=0.766 11$LC=0.1783 25$MC=0.0442 7 234U G 416.1 1 0.036 11[E2] 0.0746 11 -234U 2 G KC=0.0405 6$LC=0.0251 4$MC=0.00666 10 +234U 2 G KC=0.0405 6$LC=0.0251 4$MC=0.00666 10 234U G 478.6 1 234U G 498.0 1 -234U G 521.4 1 0.75 9 [E1] 0.0124218 -234U 2 G KC=0.01004 14$LC=0.00180 3$MC=4.31E-4 6 +234U G 521.40 100.75 9[E1] 0.0124218 +234U 2 G KC=0.01004 14$LC=0.00180 3$MC=4.31E-4 6 234U G 565.2 1 -234U G 602.6 1 0.54 6 [E1] 0.0093914 -234U 2 G KC=0.00762 11$LC=1345E-6 19$MC=3.21E-4 5 -234U G 624.2 1 0.35 5 (M1+E2) 0.7 0.1015 15 -234U 2 G KC=0.0799 12$LC=0.01627 23$MC=0.00396 6 -234U G 669.7 1 1.0 1 [E1] 0.0077011 -234U 2 G KC=0.00626 9$LC=1092E-6 16$MC=2.60E-4 4 -234U G 730.9 2 0.63 10[M1E2] 0.06 4 -234U 2 G KC=0.04 3$LC=0.009 5$MC=0.0022 11 -234U G 745.9 1 0.32 5 [E1] 0.006319 -234U 2 G KC=0.00514 8$LC=8.88E-4 13$MC=2.11E-4 3 -234U G 844.1 1 0.43 5 [E2] 0.0154022 -234U 2 G KC=0.01127 16$LC=0.00309 5$MC=7.77E-4 11 -234U G 1397.5 2 0.083 22[E1] 0.002203 -234U 2 G KC=1733E-6 25$LC=2.86E-4 4$MC=6.78E-5 10 -234U G 1550.1 1 0.073 13[E1] 0.001963 -234U 2 G KC=1460E-6 21$LC=2.40E-4 4$MC=5.68E-5 8 +234U G 602.6 1 0.54 6[E1] 0.0093914 +234U 2 G KC=0.00762 11$LC=1345E-6 19$MC=3.21E-4 5 +234U G 624.2 1 0.35 5(M1+E2) 0.7 0.1015 15 +234U 2 G KC=0.0799 12$LC=0.01627 23$MC=0.00396 6 +234U G 669.7 1 1.0 1[E1] 0.0077011 +234U 2 G KC=0.00626 9$LC=1092E-6 16$MC=2.60E-4 4 +234U G 730.9 2 0.63 10[M1E2] 0.06 4 +234U 2 G KC=0.04 3$LC=0.009 5$MC=0.0022 11 +234U G 745.9 1 0.32 5[E1] 0.00631 9 +234U 2 G KC=0.00514 8$LC=8.88E-4 13$MC=2.11E-4 3 +234U G 844.1 1 0.43 5[E2] 0.0154022 +234U 2 G KC=0.01127 16$LC=0.00309 5$MC=7.77E-4 11 +234U G 1397.5 2 0.083 22[E1] 0.00220 3 +234U 2 G KC=1733E-6 25$LC=2.86E-4 4$MC=6.78E-5 10 +234U G 1550.1 1 0.073 13[E1] 0.00196 3 +234U 2 G KC=1460E-6 21$LC=2.40E-4 4$MC=5.68E-5 8 234U L 1722.89 4 3- -234U B 472 4 8.4 9 6.7 1 +234U B 472 4 8.4 9 6.7 1 234U S B EAV=137.2 13 -234U G 595.4 2 0.094 23[E2] 0.0317 5 -234U 2 G KC=0.0210 3$LC=0.00799 12$MC=0.00207 3 -234U G 653.7 1 0.47 8 M1 0.1213 17 -234U 2 G KC=0.0969 14$LC=0.0184 3$MC=0.00443 7 +234U G 595.4 2 0.094 23[E2] 0.0317 5 +234U 2 G KC=0.0210 3$LC=0.00799 12$MC=0.00207 3 +234U G 653.7 1 0.47 8M1 0.1213 17 +234U 2 G KC=0.0969 14$LC=0.0184 3$MC=0.00443 7 234U G 699.03 5 M1 0.1015 15 -234U 2 G KC=0.0811 12$LC=0.01537 22$MC=0.00370 6 -234U G 733.39 5 7.0 8 M1 0.0893 13 -234U 2 G KC=0.0714 10$LC=0.01351 19$MC=0.00325 5 -234U G 761.0 2 0.073 22[E2] 0.0189 3 -234U 2 G KC=0.01353 19$LC=0.00403 6$MC=1023E-6 15 -234U G 874.0 3 0.036 8 [E2M1] 0.035 21 -234U 2 G KC=0.028 18$LC=0.006 3$MC=0.0014 7 +234U 2 G KC=0.0811 12$LC=0.01537 22$MC=0.00370 6 +234U G 733.39 5 7.0 8M1 0.0893 13 +234U 2 G KC=0.0714 10$LC=0.01351 19$MC=0.00325 5 +234U G 761.0 2 0.073 22[E2] 0.0189 3 +234U 2 G KC=0.01353 19$LC=0.00403 6$MC=1023E-6 15 +234U G 874.0 3 0.036 8[E2M1] 0.035 21 +234U 2 G KC=0.028 18$LC=0.006 3$MC=0.0014 7 234U G 1679.5 1 0.077 18 234U L 1723.424 244+ -234U B 472 4 36 5 6.06 +234U B 472 4 36 5 6.06 234U S B EAV=137.1 13 234U G 134.61 2 0.114 23M1 9.50 14 -234U 2 G KC=7.54 11$LC=1.480 21$MC=0.358 5 -234U G 170.85 2 0.51 7 M1 4.83 7 -234U 2 G KC=3.84 6$LC=0.749 11$MC=0.181 3 -234U G 179.80 8 0.045 16[M1] 4.19 6 -234U 2 G KC=3.33 5$LC=0.648 10$MC=0.1567 22 -234U G 186.15 2 1.78 19M1 3.79 6 -234U 2 G KC=3.02 5$LC=0.587 9$MC=0.142 2 -234U G 227.25 3 5.8 6 M1 2.17 3 -234U 2 G KC=1.724 25$LC=0.335 5$MC=0.0809 12 +234U 2 G KC=7.54 11$LC=1.480 21$MC=0.358 5 +234U G 170.85 2 0.51 7M1 4.83 7 +234U 2 G KC=3.84 6$LC=0.749 11$MC=0.181 3 +234U G 179.80 8 0.045 16[M1] 4.19 6 +234U 2 G KC=3.33 5$LC=0.648 10$MC=0.1567 22 +234U G 186.15 2 1.78 19M1 3.79 6 +234U 2 G KC=3.02 5$LC=0.587 9$MC=0.142 2 +234U G 227.25 3 5.8 6M1 2.17 3 +234U 2 G KC=1.724 25$LC=0.335 5$MC=0.0809 12 234U G 558.0 2 234U G 596.9 1 -234U G 632.6 2 0.036 11[E2M1] 0.08 6 -234U 2 G KC=0.06 5$LC=0.013 7$MC=0.0033 16 -234U G 699.03 5 3.6 4 -234U G 755.0 1 1.23 13(E2M1) 0.05 4 -234U 2 G KC=0.04 3$LC=0.008 5$MC=0.002 1 -234U G 796.1 1 2.6 3 [E2] 0.0173025 -234U 2 G KC=0.01249 18$LC=0.00359 5$MC=9.06E-4 13 -234U G 1426.9 1 0.17 3 +234U G 632.6 2 0.036 11[E2M1] 0.08 6 +234U 2 G KC=0.06 5$LC=0.013 7$MC=0.0033 16 +234U G 699.03 5 3.6 4 +234U G 755.0 1 1.23 13(E2M1) 0.05 4 +234U 2 G KC=0.04 3$LC=0.008 5$MC=0.002 1 +234U G 796.1 1 2.6 3[E2] 0.0173025 +234U 2 G KC=0.01249 18$LC=0.00359 5$MC=9.06E-4 13 +234U G 1426.9 1 0.17 3 234U G 1579.9 1 0.073 22 234U L 1737.42 7 3+ 234U B 458 4 1.16 14 7.51 234U S B EAV=132.5 14 234U G 713.7 1 0.146 25[E1] 0.0068410 -234U 2 G KC=0.00557 8$LC=9.66E-4 14$MC=2.30E-4 4 -234U G 748.1 3 0.104 23[E1] 0.006289 -234U 2 G KC=0.00511 8$LC=8.83E-4 13$MC=2.10E-4 3 -234U G 1594.0 1 0.31 4 M1E2 0.008 4 -234U 2 G KC=0.006 3$LC=0.0012 5$MC=0.00029 12 -234U G 1693.8 2 0.7 1 +234U 2 G KC=0.00557 8$LC=9.66E-4 14$MC=2.30E-4 4 +234U G 748.1 3 0.104 23[E1] 0.00628 9 +234U 2 G KC=0.00511 8$LC=8.83E-4 13$MC=2.10E-4 3 +234U G 1594.0 1 0.31 4M1E2 0.008 4 +234U 2 G KC=0.006 3$LC=0.0012 5$MC=0.00029 12 +234U G 1693.8 2 0.7 1 234U L 1738.18 6 (3+)+ 234U B 457 4 0.78 19 7.68 234U S B EAV=132.3 14 -234U G 612.0 1 0.38 5 (M1) 0.1447 21 -234U 2 G KC=0.1156 17$LC=0.0220 3$MC=0.00530 8 -234U G 811.5 1 0.125 15[M1E2] 0.04 3 -234U 2 G KC=0.033 22$LC=0.007 4$MC=0.0017 9 -234U G 1695.0 3 0.27 7 +234U G 612.0 1 0.38 5(M1) 0.1447 21 +234U 2 G KC=0.1156 17$LC=0.0220 3$MC=0.00530 8 +234U G 811.5 1 0.125 15[M1E2] 0.04 3 +234U 2 G KC=0.033 22$LC=0.007 4$MC=0.0017 9 +234U G 1695.0 3 0.27 7 234U L 1761.86 6 (4-)+ -234U B 433 4 2.8 4 7.05 +234U B 433 4 2.8 4 7.05 234U S B EAV=124.7 13 234U G 634.3 2 0.135 24[M1] 0.1315 19 -234U 2 G KC=0.1050 15$LC=0.0200 3$MC=0.00481 7 +234U 2 G KC=0.1050 15$LC=0.0200 3$MC=0.00481 7 234U G 692.6 1 1.25 13(M1) 0.1040 15 -234U 2 G KC=0.0831 12$LC=0.01575 22$MC=0.00379 6 +234U 2 G KC=0.0831 12$LC=0.01575 22$MC=0.00379 6 234U G 738.0 1 1.16 13(M1) 0.0878 13 -234U 2 G KC=0.0702 10$LC=0.01329 19$MC=0.00320 5 -234U G 772.4 2 0.073 22[E2] 0.0184 3 -234U 2 G KC=0.01318 19$LC=0.00388 6$MC=9.83E-4 14 -234U G 792.8 3 0.045 11[E1] 0.005658 -234U 2 G KC=0.00460 7$LC=7.91E-4 11$MC=1.88E-4 3 -234U G 1618.3 2 0.009 4 +234U 2 G KC=0.0702 10$LC=0.01329 19$MC=0.00320 5 +234U G 772.4 2 0.073 22[E2] 0.0184 3 +234U 2 G KC=0.01318 19$LC=0.00388 6$MC=9.83E-4 14 +234U G 792.8 3 0.045 11[E1] 0.00565 8 +234U 2 G KC=0.00460 7$LC=7.91E-4 11$MC=1.88E-4 3 +234U G 1618.3 2 0.009 4 234U L 1770.79 9 (3+)+ 234U B 424 4 0.129 17 8.36 234U S B EAV=121.8 13 -234U G 802.3 2 0.031 9 [M1] 0.0703 10 -234U 2 G KC=0.0563 8$LC=0.01062 15$MC=0.00256 4 +234U G 802.3 2 0.031 9[M1] 0.0703 10 +234U 2 G KC=0.0563 8$LC=0.01062 15$MC=0.00256 4 234U G 1627.3 1 0.076 11 -234U G 1727.8 2 0.020 5 +234U G 1727.8 2 0.020 5 234U L 1782.58 3 5+ -234U B 412 4 8 3 6.53 +234U B 412 4 8 3 6.53 234U S B EAV=118.1 13 234U G 59.19 5 0.032 11[M1+E2] 90 70 -234U 2 G KC=$LC=70 50$MC=18 15 -234U G 193.73 3 0.50 8 [M1+E2] 2.1 13 -234U 2 G KC=1.4 13$LC=0.510 16$MC=0.132 6 +234U 2 G LC=70 50$MC=18 15 +234U G 193.73 3 0.50 8[M1+E2] 2.1 13 +234U 2 G KC=1.4 13$LC=0.510 16$MC=0.132 6 234U G 245.37 2 0.76 11M1 1.749 25 -234U 2 G KC=1.392 20$LC=0.270 4$MC=0.0652 10 -234U G 360.6 3 0.018 7 [E1] 0.0264 4 -234U 2 G KC=0.0211 3$LC=0.00397 6$MC=9.55E-4 14 +234U 2 G KC=1.392 20$LC=0.270 4$MC=0.0652 10 +234U G 360.6 3 0.018 7[E1] 0.0264 4 +234U 2 G KC=0.0211 3$LC=0.00397 6$MC=9.55E-4 14 234U G 617.0 2 234U G 655.2 2 0.135 24[E1] 0.0080212 -234U 2 G KC=0.00651 10$LC=1140E-6 16$MC=2.72E-4 4 -234U G 758.9 1 0.25 3 [M1E2] 0.05 4 -234U 2 G KC=0.04 3$LC=0.008 5$MC=0.002 1 -234U G 814.2 1 0.31 4 [E2] 0.0165424 -234U 2 G KC=0.01201 17$LC=0.00338 5$MC=8.54E-4 12 -234U G 1485.4 2 0.030 7 [M1] 0.0138720 -234U 2 G KC=0.01102 16$LC=0.00205 3$MC=4.94E-4 7 +234U 2 G KC=0.00651 10$LC=1140E-6 16$MC=2.72E-4 4 +234U G 758.9 1 0.25 3[M1E2] 0.05 4 +234U 2 G KC=0.04 3$LC=0.008 5$MC=0.002 1 +234U G 814.2 1 0.31 4[E2] 0.0165424 +234U 2 G KC=0.01201 17$LC=0.00338 5$MC=8.54E-4 12 +234U G 1485.4 2 0.030 7[M1] 0.0138720 +234U 2 G KC=0.01102 16$LC=0.00205 3$MC=4.94E-4 7 234U G 1638.1 1 0.208 21(M1) 0.0108316 -234U 2 G KC=0.00850 12$LC=1581E-6 23$MC=3.80E-4 6 +234U 2 G KC=0.00850 12$LC=1581E-6 23$MC=3.80E-4 6 234U L 1784.19 134+ 234U B 411 4 0.061 11 8.64 234U S B EAV=117.6 13 -234U G 857.7 2 0.036 8 [E2] 0.0149321 -234U 2 G KC=0.01095 16$LC=0.00297 5$MC=7.46E-4 11 -234U G 1488.0 2 0.014 6 -234U G 1640.5 3 0.010 4 +234U G 857.7 2 0.036 8[E2] 0.0149321 +234U 2 G KC=0.01095 16$LC=0.00297 5$MC=7.46E-4 11 +234U G 1488.0 2 0.014 6 +234U G 1640.5 3 0.010 4 234U L 1793.05 6 4+ -234U B 402 4 0.41 8 7.78 +234U B 402 4 0.41 8 7.78 234U S B EAV=114.8 13 -234U G 240.2 1 0.052 22[M1E2] 1.1 8 -234U 2 G KC=0.8 7$LC=0.24 5$MC=0.062 8 -234U G 769.1 1 0.187 20[M1E2] 0.05 3 -234U 2 G KC=0.038 25$LC=0.008 4$MC=0.0019 10 -234U G 1496.0 2 0.036 9 -234U G 1650.2 2 6000E-6 0 +234U G 240.2 1 0.052 22[M1E2] 1.1 8 +234U 2 G KC=0.8 7$LC=0.24 5$MC=0.062 8 +234U G 769.1 1 0.187 20[M1E2] 0.05 3 +234U 2 G KC=0.038 25$LC=0.008 4$MC=0.0019 10 +234U G 1496.0 2 0.036 9 +234U G 1650.2 2 0.006 234U G 1750.0 1 0.064 10 234U L 1811.62 6 4+ 234U B 383 4 1.43 15 7.17 234U S B EAV=108.9 13 -234U G 596.9 1 0.20 3 [M1] 0.1547 22 -234U 2 G KC=0.1235 18$LC=0.0235 4$MC=0.00566 8 -234U G 683.9 2 0.16 4 [E1] 0.0074011 -234U 2 G KC=0.00602 9$LC=1049E-6 15$MC=2.50E-4 4 -234U G 685.1 2 [E2] 0.0235 4 -234U 2 G KC=0.01631 23$LC=0.00535 8$MC=1369E-6 20 -234U G 848.9 2 0.027 8 [E1] 0.005007 -234U 2 G KC=0.00408 6$LC=6.96E-4 10$MC=1655E-7 24 +234U G 596.9 1 0.20 3[M1] 0.1547 22 +234U 2 G KC=0.1235 18$LC=0.0235 4$MC=0.00566 8 +234U G 683.9 2 0.16 4[E1] 0.0074011 +234U 2 G KC=0.00602 9$LC=1049E-6 15$MC=2.50E-4 4 +234U G 685.1 2 [E2] 0.0235 4 +234U 2 G KC=0.01631 23$LC=0.00535 8$MC=1369E-6 20 +234U G 848.9 2 0.027 8[E1] 0.00500 7 +234U 2 G KC=0.00408 6$LC=6.96E-4 10$MC=1655E-7 24 234U G 863.2 2 0.073 22[E2M1] 0.036 22 -234U 2 G KC=0.029 18$LC=0.006 3$MC=0.0014 7 +234U 2 G KC=0.029 18$LC=0.006 3$MC=0.0014 7 234U G 960.0 1 0.073 13[E2] 0.0119917 -234U 2 G KC=0.00899 13$LC=0.00225 4$MC=5.62E-4 8 +234U 2 G KC=0.00899 13$LC=0.00225 4$MC=5.62E-4 8 234U G 1515.6 2 0.073 13 -234U G 1668.4 1 0.77 9 (M1) 0.0103515 -234U 2 G KC=0.00809 12$LC=1505E-6 21$MC=3.62E-4 5 -234U G 1768.0 3 0.020 5 +234U G 1668.4 1 0.77 9(M1) 0.0103515 +234U 2 G KC=0.00809 12$LC=1505E-6 21$MC=3.62E-4 5 +234U G 1768.0 3 0.020 5 234U L 1843.88 173,4,5-+ -234U B 351 4 0.17 3 7.97 +234U B 351 4 0.17 3 7.97 234U S B EAV=98.9 13 234U G 994.6 3 0.062 22 234U G 1700.5 2 0.104 14 234U L 1863.08 15(5+)+ -234U B 332 4 0.029 7 8.66 +234U B 332 4 0.029 7 8.66 234U S B EAV=93.0 13 234U G 1567.0 2 0.0114 23 -234U G 1719.7 2 0.018 6 +234U G 1719.7 2 0.018 6 234U L 1881.75 7 4+ -234U B 313 4 0.25 3 7.65 +234U B 313 4 0.25 3 7.65 234U S B EAV=87.3 13 -234U G 716.5 2 0.031 9 [M1E2] 0.06 4 -234U 2 G KC=0.05 3$LC=0.010 5$MC=0.0023 12 +234U G 716.5 2 0.031 9[M1E2] 0.06 4 +234U 2 G KC=0.05 3$LC=0.010 5$MC=0.0023 12 234U G 755.0 1 234U G 1585.9 1 0.146 17 234U G 1737.7 2 0.075 11 234U G 1838.0 2 234U L 1916.28 9 3,4++ -234U B 279 4 0.21 3 7.56 +234U B 279 4 0.21 3 7.56 234U S B EAV=76.9 12 234U G 989.5 1 0.104 14 234U G 1773.0 2 0.068 17 -234U G 1872.8 2 0.035 9 +234U G 1872.8 2 0.035 9 234U L 1927.51 7 4+ -234U B 267 4 0.22 4 7.49 +234U B 267 4 0.22 4 7.49 234U S B EAV=73.5 12 234U G 165.61 5 0.073 22[E1] 0.1533 22 -234U 2 G KC=0.1194 17$LC=0.0256 4$MC=0.00622 9 -234U G 308.6 2 0.021 6 [E2] 0.1726 25 -234U 2 G KC=0.0711 10$LC=0.0744 11$MC=0.0201 3 -234U G 586.3 1 0.073 13[E2] 0.0328 5 -234U 2 G KC=0.0216 3$LC=0.00836 12$MC=0.00216 3 +234U 2 G KC=0.1194 17$LC=0.0256 4$MC=0.00622 9 +234U G 308.6 2 0.021 6[E2] 0.1726 25 +234U 2 G KC=0.0711 10$LC=0.0744 11$MC=0.0201 3 +234U G 586.3 1 0.073 13[E2] 0.0328 5 +234U 2 G KC=0.0216 3$LC=0.00836 12$MC=0.00216 3 234U G 653.7 1 234U G 713.7 1 -234U G 1783.7 2 0.025 7 -234U G 1884.1 3 0.016 5 +234U G 1783.7 2 0.025 7 +234U G 1884.1 3 0.016 5 234U L 1940.52 9 4+ -234U B 254 4 0.35 5 7.22 +234U B 254 4 0.35 5 7.22 234U S B EAV=69.7 12 -234U G 916.5 2 0.024 7 -234U G 1644.9 2 0.010 4 -234U G 1797.1 1 0.24 3 +234U G 916.5 2 0.024 7 +234U G 1644.9 2 0.010 4 +234U G 1797.1 1 0.24 3 234U G 1896.7 2 0.104 23 234U L 1958.75 4 3- 234U B 236 4 0.44 19 7.01 1 234U S B EAV=64.3 12 234U G 221.15 100.052 22[E1] 0.0780 11 -234U 2 G KC=0.0615 9$LC=0.01248 18$MC=0.00302 5 +234U 2 G KC=0.0615 9$LC=0.01248 18$MC=0.00302 5 234U G 235.11 3 0.114 23[E1] 0.0678 10 -234U 2 G KC=0.0536 8$LC=0.01075 15$MC=0.00260 4 -234U G 502.0 1 0.03 9 [E2M1] 0.15 10 -234U 2 G KC=0.11 9$LC=0.026 12$MC=0.006 3 -234U G 890.1 4 0.027 8 +234U 2 G KC=0.0536 8$LC=0.01075 15$MC=0.00260 4 +234U G 502.0 1 0.03 9[E2M1] 0.15 10 +234U 2 G KC=0.11 9$LC=0.026 12$MC=0.006 3 +234U G 890.1 4 0.027 8 234U G 935.8 2 0.067 10 234U G 1110.6 1 0.062 12 -234U G 1173.1 1 0.046 9 -234U G 1815.3 3 0.009 4 -234U G 1915.5 3 0.020 5 +234U G 1173.1 1 0.046 9 +234U G 1815.3 3 0.009 4 +234U G 1915.5 3 0.020 5 234U L 1968.84 104+,5+ 234U B 226 4 0.044 12 7.95 234U S B EAV=61.3 12 234U G 1672.8 1 0.034 11 -234U G 1825.1 3 0.009 4 +234U G 1825.1 3 0.009 4 234U L 1981.22 7 4+ -234U B 214 4 0.59 8 6.75 +234U B 214 4 0.59 8 6.75 234U S B EAV=57.8 12 -234U G 257.2 1 0.052 22[M1E2] 0.9 7 -234U 2 G KC=0.7 6$LC=0.19 5$MC=0.049 8 +234U G 257.2 1 0.052 22[M1E2] 0.9 7 +234U 2 G KC=0.7 6$LC=0.19 5$MC=0.049 8 234U G 433.1 1 0.094 14 -234U G 1685.7 1 0.31 4 +234U G 1685.7 1 0.31 4 234U G 1838.0 2 0.0042 11 234U G 1937.7 3 0.042 11 234U L 2000.45 13(4+)+ 234U B 195 4 0.122 16 7.31 234U S B EAV=52.2 12 -234U G 1037.9 2 0.018 7 +234U G 1037.9 2 0.018 7 234U G 1073.6 2 0.104 14 234U G 1151.4 3 234U L 2019.82 134+ @@ -758,62 +758,62 @@ 234U S B EAV=46.7 12 234U G 1051.4 2 0.062 12 234U G 1057.8 3 0.0177 16 -234U G 1723.2 2 0.016 4 -234U G 1977.4 4 0.017 5 +234U G 1723.2 2 0.016 4 +234U G 1977.4 4 0.017 5 234U L 2033.54 5 3+,4++ 234U B 161 4 0.90 15 6.19 234U S B EAV=42.9 12 -234U G 310.2 1 0.073 13[M1E2] 0.5 4 -234U 2 G KC=0.4 4$LC=0.11 4$MC=0.027 7 -234U G 481.0 1 0.31 4 [M1E2] 0.16 12 -234U 2 G KC=0.13 10$LC=0.029 14$MC=0.007 3 -234U G 537.2 1 0.083 13[M1E2] 0.12 9 -234U 2 G KC=0.09 7$LC=0.021 11$MC=0.0052 24 +234U G 310.2 1 0.073 13[M1E2] 0.5 4 +234U 2 G KC=0.4 4$LC=0.11 4$MC=0.027 7 +234U G 481.0 1 0.31 4[M1E2] 0.16 12 +234U 2 G KC=0.13 10$LC=0.029 14$MC=0.007 3 +234U G 537.2 1 0.083 13[M1E2] 0.12 9 +234U 2 G KC=0.09 7$LC=0.021 11$MC=0.0052 24 234U G 1009.9 3 0.067 12 -234U G 1065.1 1 0.027 8 +234U G 1065.1 1 0.027 8 234U G 1106.9 2 0.083 13 -234U G 1182.1 2 9400E-6 0 +234U G 1182.1 2 0.0094 234U G 1890.1 2 0.146 17 -234U G 1989.6 4 0.007 4 +234U G 1989.6 4 0.007 4 234U L 2037.06 174+,5+ -234U B 158 4 0.055 8 7.37 +234U B 158 4 0.055 8 7.37 234U S B EAV=41.9 12 -234U G 1741.1 2 0.049 8 -234U G 1893.4 3 6200E-6 0 +234U G 1741.1 2 0.049 8 +234U G 1893.4 3 0.0062 234U L 2066.24 10 + 234U B 129 4 0.140 24 6.69 234U S B EAV=33.8 11 -234U G 975.1 1 0.027 8 +234U G 975.1 1 0.027 8 234U G 997.7 3 0.046 12 234U G 1770.8 2 0.068 17 234U L 2068.82 113,4,5++ -234U B 126 4 0.40 7 6.21 +234U B 126 4 0.40 7 6.21 234U S B EAV=33.1 11 234U G 331.4 1 0.073 13 -234U G 1925.4 2 0.30 5 +234U G 1925.4 2 0.30 5 234U L 2101.42 9 5+ 234U B 94 4 0.064 11 6.6 234U S B EAV=24.2 11 -234U G 839.5 1 0.031 8 +234U G 839.5 1 0.031 8 234U G 1009.9 3 -234U G 1032.8 2 0.018 5 +234U G 1032.8 2 0.018 5 234U G 1805.8 3 0.0052 22 -234U G 1958.0 4 0.010 3 +234U G 1958.0 4 0.010 3 234U L 2115.71 114+ -234U B 79 4 0.21 3 5.87 +234U B 79 4 0.21 3 5.87 234U S B EAV=20.4 11 234U G 534.1 1 0.083 13[E1] 0.0118517 -234U 2 G KC=0.00958 14$LC=1715E-6 24$MC=4.10E-4 6 -234U G 562.8 3 0.036 11[M1E2] 0.11 8 -234U 2 G KC=0.08 6$LC=0.018 9$MC=0.0045 21 -234U G 1019.5 4 0.027 8 -234U G 1153.5 3 0.046 9 +234U 2 G KC=0.00958 14$LC=1715E-6 24$MC=4.10E-4 6 +234U G 562.8 3 0.036 11[M1E2] 0.11 8 +234U 2 G KC=0.08 6$LC=0.018 9$MC=0.0045 21 +234U G 1019.5 4 0.027 8 +234U G 1153.5 3 0.046 9 234U G 1819.8 3 0.0042 11 -234U G 1971.2 4 2700E-6 0 +234U G 1971.2 4 0.0027 234U G 2072.2 4 0.0042 22 234U L 2144.04 9 3+,4+- -234U B 51 4 0.42 5 4.98 1 +234U B 51 4 0.42 5 4.98 1 234U S B EAV=13.0 11 -234U G 869.7 1 0.20 3 -234U G 1217.3 1 0.22 3 +234U G 869.7 1 0.20 3 +234U G 1217.3 1 0.22 3 diff --git a/HEN_HOUSE/spectra/lnhb/Pa-234m.txt b/HEN_HOUSE/spectra/lnhb/Pa-234m.txt index 39243ab4d..a9b6bc0dd 100644 --- a/HEN_HOUSE/spectra/lnhb/Pa-234m.txt +++ b/HEN_HOUSE/spectra/lnhb/Pa-234m.txt @@ -1,180 +1,180 @@ 234PA 234PA IT DECAY (1.159 M) 234PA H TYP=Full$AUT=Huang$CUT=30-JAN-2009$ 234PA C Evaluation history: Type=Full;Author=Huang;Cutoff date=30-JAN-2009 -234PA T Auger electrons and ^X ray energies and emission intensities: -234PA T {U Energy (keV)} {U Intensity } {U Line } +234PA T Auger electrons and X ray energies and emission intensities: +234PA T {U Energy (keV)} {U Intensity} {U Line} 234PA T 234PA T 234PA T 234PA T -234PA T 11.3676-20.1126 0.046 4 XL (total) +234PA T 11.3676-20.1126 0.046 4 XL (total) 234PA T 11.3676 XLL 234PA T 13.1215-13.2887 XLA 234PA T 14.9488 XLC 234PA T 15.3584-17.6655 XLB 234PA T 18.9396-20.1126 XLG 234PA T -234PA T 5.9-20.9 0.048 4 L AUGER +234PA T 5.9-20.9 0.048 4 L AUGER 234PA P 73.92 2 (0-)- 1.159 M 11 234PA N 6.667E2 6.667E2 0.0015 6.667E2 -234PA G 243.5 8 0.00050 9 +234PA G 243.5 8 0.00050 9 234PA G 557.3 100.00072 17 234PA G 647.7 8 0.00158 15 234PA G 760.3 100.00158 15 234PA G 887.29 100.00708 14 -234PA G 1220.37 100.00091 9 -234PA G 1353.0 150.0015 5 +234PA G 1220.37 100.00091 9 +234PA G 1353.0 150.0015 5 234PA G 1720.5 150.00033 15 -234PA G 1732.2 150.0019 3 -234PA G 1759.81 100.00146 5 -234PA G 2022.24 121.86E-4 3 -234PA G 2041.23 130.00011 1 -234PA G 2065.80 137000E-8 0 -234PA G 2093.19 382000E-8 0 -234PA G 2102.14 156000E-8 0 -234PA G 2136.69 147000E-8 0 +234PA G 1732.2 150.0019 3 +234PA G 1759.81 100.00146 5 +234PA G 2022.24 120.000186 3 +234PA G 2041.23 130.00011 1 +234PA G 2065.80 130.00007 +234PA G 2093.19 380.00002 +234PA G 2102.14 150.00006 +234PA G 2136.69 140.00007 234PA L 0 4+ 6.70 H 5 234PA L 73.92 2 (3+)+ -234PA G 73.92 2 0.0129 9 (M1+E2) 0.11 3 10.6 4 -234PA2 G KC=$LC=7.96 25$MC=1.94 7 +234PA G 73.92 2 0.0129 9(M1+E2) 0.11 3 10.6 4 +234PA2 G LC=7.96 25$MC=1.94 7 234PA L 83.92 (0-)- 1.159 M 11 234PA G 10 234U 234PA B- DECAY (1.159 M) 234U H TYP=Full$AUT=Huang$CUT=30-JAN-2009$ 234U C Evaluation history: Type=Full;Author=Huang;Cutoff date=30-JAN-2009 -234U T Auger electrons and ^X ray energies and emission intensities: -234U T {U Energy (keV)} {U Intensity } {U Line } +234U T Auger electrons and X ray energies and emission intensities: +234U T {U Energy (keV)} {U Intensity} {U Line} 234U T -234U T 94.666 0.1973 25 XKA2 -234U T 98.44 0.316 4 XKA1 +234U T 94.666 0.1973 25 XKA2 +234U T 98.44 0.316 4 XKA1 234U T -234U T 110.421 |] XKB3 -234U T 111.298 |] 0.115 2 XKB1 -234U T 111.964 |] XKB5II +234U T 110.421 |] XKB3 +234U T 111.298 |] 0.115 2 XKB1 +234U T 111.964 |] XKB5II 234U T -234U T 114.407 |] XKB2 -234U T 115.012 |] 0.0382 5 XKB4 -234U T 115.377 |] XKO23 +234U T 114.407 |] XKB2 +234U T 115.012 |] 0.0382 5 XKB4 +234U T 115.377 |] XKO23 234U T -234U T 11.6185-20.7141 0.856 19 XL (total) +234U T 11.6185-20.7141 0.856 19 XL (total) 234U T 11.6185 XLL 234U T 13.4382-13.6146 XLA 234U T 15.399 XLC 234U T 15.7268-18.2061 XLB 234U T 19.5072-20.7141 XLG 234U T -234U T 71.776-80.954 |] KLL AUGER -234U T 88.153-98.429 |] 0.0203 3 ^KLX AUGER -234U T 104.51-115.59 |] KXY AUGER -234U T 5.9-21.6 0.856 19 L AUGER +234U T 71.776-80.954 |] KLL AUGER +234U T 88.153-98.429 |] 0.0203 3 KLX AUGER +234U T 104.51-115.59 |] KXY AUGER +234U T 5.9-21.6 0.856 19 L AUGER 234PA P 73.92 2 (0-)+ 1.159 M 11 2195.1 40 234U N 1.002E0 1.002E0 0.9985 1.002E0 -234U G 243.5 8 0.00050 9 +234U G 243.5 8 0.00050 9 234U G 557.3 100.00072 17 234U G 647.7 8 0.00158 15 234U G 760.3 100.00158 15 234U G 887.29 100.00708 14 -234U G 1220.37 100.00091 9 -234U G 1353.0 150.0015 5 +234U G 1220.37 100.00091 9 +234U G 1353.0 150.0015 5 234U G 1720.5 150.00033 15 -234U G 1732.2 150.0019 3 -234U G 1759.81 100.00146 5 -234U G 2022.24 121.86E-4 3 -234U G 2041.23 130.00011 1 -234U G 2065.80 137000E-8 0 -234U G 2093.19 382000E-8 0 -234U G 2102.14 156000E-8 0 -234U G 2136.69 147000E-8 0 +234U G 1732.2 150.0019 3 +234U G 1759.81 100.00146 5 +234U G 2022.24 120.000186 3 +234U G 2041.23 130.00011 1 +234U G 2065.80 130.00007 +234U G 2093.19 380.00002 +234U G 2102.14 150.00006 +234U G 2136.69 140.00007 234U L 0 0+ STABLE 234U B 2269 4 97.599 24 5.5 234U S B EAV=820.5 17 234U L 43.428 142+ 0.252 NS 7 -234U G 43.49 2 0.00198 2 E2 713 11 -234U 2 G KC=$LC=520 8$MC=143.7 21 +234U G 43.49 2 0.00198 2E2 713 11 +234U 2 G LC=520 8$MC=143.7 21 234U L 143.279 244+ -234U G 99.86 2 0.00057 5 E2 13.42 19 -234U 2 G KC=$LC=9.77 14$MC=2.71 4 +234U G 99.86 2 0.00057 5E2 13.42 19 +234U 2 G LC=9.77 14$MC=2.71 4 234U L 786.243 141- -234U B 1483 4 0.049 3 8 1 +234U B 1483 4 0.049 3 8 1 234U S B EAV=505.3 16 -234U G 742.813 5 0.094 3 E1 0.006369 -234U 2 G KC=0.00518 8$LC=8.95E-4 13$MC=2.13E-4 3 -234U G 786.272 220.0536 7 E1+M2 0.005738 -234U 2 G KC=0.00467 7$LC=8.04E-4 12$MC=1.91E-4 3 +234U G 742.813 5 0.094 3E1 0.00636 9 +234U 2 G KC=0.00518 8$LC=8.95E-4 13$MC=2.13E-4 3 +234U G 786.272 220.0536 7E1+M2 0.00573 8 +234U 2 G KC=0.00467 7$LC=8.04E-4 12$MC=1.91E-4 3 234U L 809.786 230+ 0.1 NS 234U B 1459 4 0.945 12 6.8 234U S B EAV=496.0 16 -234U G 766.361 200.323 4 (E2) 0.0187 3 -234U 2 G KC=0.01336 19$LC=0.00396 6$MC=1004E-6 14 +234U G 766.361 200.323 4(E2) 0.0187 3 +234U 2 G KC=0.01336 19$LC=0.00396 6$MC=1004E-6 14 234U G 810.0 7 234U L 849.18 7 3- -234U G 705.94 120.0052 6 [E1] 0.0069810 -234U 2 G KC=0.00568 8$LC=9.87E-4 14$MC=2.35E-4 4 -234U G 805.75 100.0062 8 [E1] 0.005498 -234U 2 G KC=0.00447 7$LC=7.68E-4 11$MC=1.83E-4 3 +234U G 705.94 120.0052 6[E1] 0.0069810 +234U 2 G KC=0.00568 8$LC=9.87E-4 14$MC=2.35E-4 4 +234U G 805.75 100.0062 8[E1] 0.00549 8 +234U 2 G KC=0.00447 7$LC=7.68E-4 11$MC=1.83E-4 3 234U L 851.56 4 2+ 1.74 PS 234U G 41.82 -234U G 708.2 107000E-7 0 [E2] 0.0219 4 -234U 2 G KC=0.01537 22$LC=0.00489 7$MC=1247E-6 19 -234U G 808.2 1 0.00281 17 +234U G 708.2 100.0007 [E2] 0.0219 4 +234U 2 G KC=0.01537 22$LC=0.00489 7$MC=1247E-6 19 +234U G 808.20 100.00281 17 234U G 851.6 1 0.00696 15[E2] 0.0151422 -234U 2 G KC=0.01109 16$LC=0.00302 5$MC=7.60E-4 11 +234U 2 G KC=0.01109 16$LC=0.00302 5$MC=7.60E-4 11 234U L 926.659 202+ 1.38 PS 17 -234U G 783.4 1 3.9E-5 7 [E2] 0.0179 3 -234U 2 G KC=0.01285 18$LC=0.00374 6$MC=9.46E-4 14 -234U G 883.24 3 0.00381 5 E2 0.0140920 -234U 2 G KC=0.01040 15$LC=0.00276 4$MC=6.92E-4 10 +234U G 783.4 1 0.000039 7[E2] 0.0179 3 +234U 2 G KC=0.01285 18$LC=0.00374 6$MC=9.46E-4 14 +234U G 883.24 3 0.00381 5E2 0.0140920 +234U 2 G KC=0.01040 15$LC=0.00276 4$MC=6.92E-4 10 234U G 926.61 100.00125 13(E2) 0.0128418 -234U 2 G KC=0.00956 14$LC=0.00245 4$MC=6.13E-4 9 +234U 2 G KC=0.00956 14$LC=0.00245 4$MC=6.13E-4 9 234U L 989.359 192- 0.76 NS 4 -234U G 62.70 1 0.0013 4 E1 0.426 6 -234U 2 G KC=$LC=0.320 5$MC=0.0791 11 -234U G 140.1 101270E-6 0 M1+E2 1.2 6 5.3 18 -234U 2 G KC=2.9 22$LC=1.76 25$MC=0.47 9 -234U G 203.3 8 0.00119 9 M1+E2 1.5 4 1.4 4 -234U 2 G KC=0.8 4$LC=0.420 12$MC=0.1109 23 -234U G 945.961 160.01060 14(E1) 0.004126 -234U 2 G KC=0.00337 5$LC=5.71E-4 8$MC=1355E-7 19 +234U G 62.70 1 0.0013 4E1 0.426 6 +234U 2 G LC=0.320 5$MC=0.0791 11 +234U G 140.1 100.00127 M1+E2 1.2 6 5.3 18 +234U 2 G KC=2.9 22$LC=1.76 25$MC=0.47 9 +234U G 203.3 8 0.00119 9M1+E2 1.5 4 1.4 4 +234U 2 G KC=0.8 4$LC=0.420 12$MC=0.1109 23 +234U G 945.961 160.01060 14(E1) 0.00412 6 +234U 2 G KC=0.00337 5$LC=5.71E-4 8$MC=1355E-7 19 234U L 1044.469 150+ 234U B 1224 4 1.006 13 6.5 234U S B EAV=405.6 16 234U G 193.4 8 0.00072 15[E2] 0.847 18 -234U 2 G KC=0.163 3$LC=0.500 12$MC=0.138 4 +234U 2 G KC=0.163 3$LC=0.500 12$MC=0.138 4 234U G 236 1 -234U G 258.227 3 0.0738 8 (E1) 0.0548 8 -234U 2 G KC=0.0434 6$LC=0.00859 12$MC=0.00207 3 -234U G 1001.026 180.847 8 E2 0.0110716 -234U 2 G KC=0.00835 12$LC=0.00204 3$MC=5.07E-4 8 +234U G 258.227 3 0.0738 8(E1) 0.0548 8 +234U 2 G KC=0.0434 6$LC=0.00859 12$MC=0.00207 3 +234U G 1001.026 180.847 8E2 0.0110716 +234U 2 G KC=0.00835 12$LC=0.00204 3$MC=5.07E-4 8 234U L 1085.04 4 2+ 234U G 233.6 2 -234U G 235.9 3 0.00009 4 [E1] 0.0673 10 -234U 2 G KC=0.0532 8$LC=0.01067 16$MC=0.00258 4 -234U G 299 1 0.00064 13[E1] 0.0395 7 -234U 2 G KC=0.0315 5$LC=0.00608 10$MC=1467E-6 24 -234U G 941.96 100.00250 9 [E2] 0.0124418 -234U 2 G KC=0.00929 13$LC=0.00236 4$MC=5.89E-4 9 -234U G 1041.7 1 0.00119 8 [E2M1] 0.023 13 -234U 2 G KC=0.018 11$LC=0.0036 18$MC=0.0009 4 -234U G 1084.25 100.0008 4 [E2] 0.0095214 -234U 2 G KC=0.00726 11$LC=1694E-6 24$MC=4.19E-4 6 +234U G 235.9 3 0.00009 4[E1] 0.0673 10 +234U 2 G KC=0.0532 8$LC=0.01067 16$MC=0.00258 4 +234U G 299 1 0.00064 13[E1] 0.0395 7 +234U 2 G KC=0.0315 5$LC=0.00608 10$MC=1467E-6 24 +234U G 941.96 100.00250 9[E2] 0.0124418 +234U 2 G KC=0.00929 13$LC=0.00236 4$MC=5.89E-4 9 +234U G 1041.7 1 0.00119 8[E2M1] 0.023 13 +234U 2 G KC=0.018 11$LC=0.0036 18$MC=0.0009 4 +234U G 1084.25 100.0008 4[E2] 0.0095214 +234U 2 G KC=0.00726 11$LC=1694E-6 24$MC=4.19E-4 6 234U L 1126.32 4 2+ -234U G 137.23 5 4.8E-5 17[E1] 0.239 4 -234U 2 G KC=0.184 3$LC=0.0413 6$MC=0.01006 15 +234U G 137.23 5 0.00004817[E1] 0.239 4 +234U 2 G KC=0.184 3$LC=0.0413 6$MC=0.01006 15 234U G 199.9 100.00058 12(+E2+M1) 1.9 12 -234U 2 G KC=1.3 12$LC=0.473 22$MC=0.122 4 -234U G 275.5 8 0.00031 6 [M1E2] 0.8 6 -234U 2 G KC=0.5 5$LC=0.16 4$MC=0.039 8 -234U G 316.7 1 0.00019 5 [E2] 0.1597 23 -234U 2 G KC=0.0677 10$LC=0.0674 10$MC=0.0182 3 -234U G 340.2 1 7.2E-5 21[E1] 0.0298 5 -234U 2 G KC=0.0239 4$LC=0.00453 7$MC=1090E-6 16 -234U G 1081.9 100.00091 19(M1) 0.0318 5 -234U 2 G KC=0.0255 4$LC=0.00478 7$MC=1151E-6 17 -234U G 1124.93 100.00039 9 [E2] 0.0088813 -234U 2 G KC=0.00681 10$LC=1558E-6 22$MC=3.85E-4 6 +234U 2 G KC=1.3 12$LC=0.473 22$MC=0.122 4 +234U G 275.5 8 0.00031 6[M1E2] 0.8 6 +234U 2 G KC=0.5 5$LC=0.16 4$MC=0.039 8 +234U G 316.7 1 0.00019 5[E2] 0.1597 23 +234U 2 G KC=0.0677 10$LC=0.0674 10$MC=0.0182 3 +234U G 340.2 1 0.00007221[E1] 0.0298 5 +234U 2 G KC=0.0239 4$LC=0.00453 7$MC=1090E-6 16 +234U G 1081.9 100.00091 19(M1) 0.0318 5 +234U 2 G KC=0.0255 4$LC=0.00478 7$MC=1151E-6 17 +234U G 1124.93 100.00039 9[E2] 0.0088813 +234U 2 G KC=0.00681 10$LC=1558E-6 22$MC=3.85E-4 6 234U L 1174.2 4 (1,2+)+ -234U B 1095 4 0.0046 3 8.7 +234U B 1095 4 0.0046 3 8.7 234U S B EAV=356.7 15 234U G 185.0 4 0.00172 15 234U G 387.6 8 0.00097 15 @@ -182,112 +182,112 @@ 234U L 1237.23 3 1- 234U B 1032 4 0.0121 11 8.2 1 234U S B EAV=333.1 15 -234U G 247.7 8 0.00097 22[M1E2] 1.0 7 -234U 2 G KC=0.7 7$LC=0.22 5$MC=0.056 8 -234U G 311 1 0.00052 11[E1] 0.0363 6 -234U 2 G KC=0.0289 5$LC=0.00556 9$MC=1339E-6 22 -234U G 387.6 8 0.00047 4 [E2] 0.0899 14 -234U 2 G KC=0.0463 7$LC=0.0321 5$MC=0.00858 14 -234U G 427.4 2 2.0E-5 5 [E1] 0.0185 3 -234U 2 G KC=0.01488 21$LC=0.00274 4$MC=6.57E-4 10 -234U G 450.98 100.00310 13M1+E2 0.7 0.241 4 -234U 2 G KC=0.187 3$LC=0.0400 6$MC=0.00979 14 -234U G 1193.77 3 0.01359 18E1 0.002774 -234U 2 G KC=0.00226 4$LC=3.77E-4 6$MC=8.92E-5 13 -234U G 1237.28 100.00528 11E1 0.002624 -234U 2 G KC=0.00213 3$LC=3.54E-4 5$MC=8.38E-5 12 +234U G 247.7 8 0.00097 22[M1E2] 1.0 7 +234U 2 G KC=0.7 7$LC=0.22 5$MC=0.056 8 +234U G 311 1 0.00052 11[E1] 0.0363 6 +234U 2 G KC=0.0289 5$LC=0.00556 9$MC=1339E-6 22 +234U G 387.6 8 0.00047 4[E2] 0.0899 14 +234U 2 G KC=0.0463 7$LC=0.0321 5$MC=0.00858 14 +234U G 427.4 2 0.000020 5[E1] 0.0185 3 +234U 2 G KC=0.01488 21$LC=0.00274 4$MC=6.57E-4 10 +234U G 450.98 100.00310 13M1+E2 0.7 0.241 4 +234U 2 G KC=0.187 3$LC=0.0400 6$MC=0.00979 14 +234U G 1193.77 3 0.01359 18E1 0.00277 4 +234U 2 G KC=0.00226 4$LC=3.77E-4 6$MC=8.92E-5 13 +234U G 1237.28 100.00528 11E1 0.00262 4 +234U 2 G KC=0.00213 3$LC=3.54E-4 5$MC=8.38E-5 12 234U L 1435.05 5 1- 234U B 834 4 0.0092 11 7.9 1 234U S B EAV=261.1 15 -234U G 197.91 152.7E-5 7 [M1E2] 2.0 12 -234U 2 G KC=1.3 12$LC=0.473 22$MC=0.122 4 -234U G 445.91 103.1E-5 7 [M1E2] 0.20 14 -234U 2 G KC=0.15 12$LC=0.036 16$MC=0.009 4 -234U G 624.6 101.16E-4 12[E1] 0.0087713 -234U 2 G KC=0.00712 11$LC=1252E-6 18$MC=2.99E-4 5 -234U G 649 1 5.9E-5 8 [M1E2] 0.08 5 -234U 2 G KC=0.06 4$LC=0.012 7$MC=0.0031 15 -234U G 1392.6 9 0.0029 11E1 0.002214 -234U 2 G KC=1743E-6 25$LC=2.88E-4 4$MC=6.82E-5 10 -234U G 1434.16 100.00973 16E1 0.002133 -234U 2 G KC=1660E-6 24$LC=2.74E-4 4$MC=6.48E-5 9 +234U G 197.91 150.000027 7[M1E2] 2.0 12 +234U 2 G KC=1.3 12$LC=0.473 22$MC=0.122 4 +234U G 445.91 100.000031 7[M1E2] 0.20 14 +234U 2 G KC=0.15 12$LC=0.036 16$MC=0.009 4 +234U G 624.6 100.00011612[E1] 0.0087713 +234U 2 G KC=0.00712 11$LC=1252E-6 18$MC=2.99E-4 5 +234U G 649.0 100.000059 8[M1E2] 0.08 5 +234U 2 G KC=0.06 4$LC=0.012 7$MC=0.0031 15 +234U G 1392.6 9 0.0029 11E1 0.00221 4 +234U 2 G KC=1743E-6 25$LC=2.88E-4 4$MC=6.82E-5 10 +234U G 1434.16 100.00973 16E1 0.00213 3 +234U 2 G KC=1660E-6 24$LC=2.74E-4 4$MC=6.48E-5 9 234U L 1457.40 8 (2-)+ -234U G 670.8 100.00037 9 [M1E2] 0.07 5 -234U 2 G KC=0.05 4$LC=0.011 6$MC=0.0028 14 -234U G 1413.89 100.00229 8 [E1] 0.002173 -234U 2 G KC=1700E-6 24$LC=2.81E-4 4$MC=6.64E-5 10 +234U G 670.8 100.00037 9[M1E2] 0.07 5 +234U 2 G KC=0.05 4$LC=0.011 6$MC=0.0028 14 +234U G 1413.89 100.00229 8[E1] 0.00217 3 +234U 2 G KC=1700E-6 24$LC=2.81E-4 4$MC=6.64E-5 10 234U L 1500.8 3 (1)+ -234U B 768 4 0.0131 6 7.7 +234U B 768 4 0.0131 6 7.7 234U S B EAV=237.6 15 -234U G 649 1 0.0010 3 +234U G 649.0 100.0010 3 234U G 691.0 3 0.00898 19 -234U G 1458.5 150.0019 5 -234U G 1501 2 1300E-6 0 +234U G 1458.5 150.0019 5 +234U G 1501.0 200.0013 234U L 1553.62 6 (1)+ -234U B 715 4 0.0320 6 7.2 +234U B 715 4 0.0320 6 7.2 234U S B EAV=219.2 14 234U G 468.43 100.00206 12 -234U G 509.2 8 0.0022 3 -234U G 702.0 1 0.00721 16 +234U G 509.2 8 0.0022 3 +234U G 702.00 100.00721 16 234U G 1510.22 100.01308 19 234U G 1553.77 100.00826 14 234U L 1570.53 4 1+ 234U B 698 4 0.00231 19 8.4 234U S B EAV=213.3 14 -234U G 135.32 8 4.2E-6 5 [E1] 0.247 4 -234U 2 G KC=0.190 3$LC=0.0428 6$MC=0.01043 15 +234U G 135.32 8 4.2E-6 5[E1] 0.247 4 +234U 2 G KC=0.190 3$LC=0.0428 6$MC=0.01043 15 234U G 485.44 7 1.87E-5 17[M1E2] 0.16 11 -234U 2 G KC=0.12 10$LC=0.028 13$MC=0.007 3 -234U G 526.02 109E-6 1 [M1] 0.217 3 -234U 2 G KC=0.1732 25$LC=0.0331 5$MC=0.00797 12 -234U G 581.19 108.0E-5 9 [E1] 0.0100614 -234U 2 G KC=0.00815 12$LC=1445E-6 21$MC=3.45E-4 5 -234U G 719.01 7 2.56E-5 20[M1+E2] 0.06 4 -234U 2 G KC=0.05 3$LC=0.009 5$MC=0.0023 12 -234U G 760.53 154.3E-6 9 [M1] 0.0811 12 -234U 2 G KC=0.0648 9$LC=0.01226 18$MC=0.00295 5 -234U G 1527.28 100.00235 8 M1+E2 0.009 4 -234U 2 G KC=0.007 4$LC=0.0014 6$MC=0.00033 14 -234U G 1570.67 100.00110 8 M1 0.0120417 -234U 2 G KC=0.00951 14$LC=1769E-6 25$MC=4.25E-4 6 +234U 2 G KC=0.12 10$LC=0.028 13$MC=0.007 3 +234U G 526.02 100.000009 1[M1] 0.217 3 +234U 2 G KC=0.1732 25$LC=0.0331 5$MC=0.00797 12 +234U G 581.19 100.000080 9[E1] 0.0100614 +234U 2 G KC=0.00815 12$LC=1445E-6 21$MC=3.45E-4 5 +234U G 719.01 7 2.56E-5 20[M1+E2] 0.06 4 +234U 2 G KC=0.05 3$LC=0.009 5$MC=0.0023 12 +234U G 760.53 154.3E-6 9[M1] 0.0811 12 +234U 2 G KC=0.0648 9$LC=0.01226 18$MC=0.00295 5 +234U G 1527.28 100.00235 8M1+E2 0.009 4 +234U 2 G KC=0.007 4$LC=0.0014 6$MC=0.00033 14 +234U G 1570.67 100.00110 8M1 0.0120417 +234U 2 G KC=0.00951 14$LC=1769E-6 25$MC=4.25E-4 6 234U L 1591.64 7 (1)+ -234U B 677 4 0.0249 5 7.2 +234U B 677 4 0.0249 5 7.2 234U S B EAV=205.8 14 234U G 507.5 100.00158 15 -234U G 740.10 8 0.0118 3 +234U G 740.10 8 0.0118 3 234U G 781.75 100.00782 18 234U G 1550.1 100.00137 15 234U G 1593.5 6 0.00235 12 234U L 1601.68 4 1+ 234U B 667 4 0.00127 23 8.5 234U S B EAV=202.5 14 -234U G 166.5 1 2.37E-7 5 [E1] 0.1514 22 -234U 2 G KC=0.1179 17$LC=0.0253 4$MC=0.00613 9 -234U G 516.60 6 1.22E-5 16(M1) 0.228 4 -234U 2 G KC=0.182 3$LC=0.0347 5$MC=0.00837 12 -234U G 557.24 6 8.3E-6 11(M1) 0.186 3 -234U 2 G KC=0.1485 21$LC=0.0283 4$MC=0.00682 10 -234U G 750.12 6 1.7E-5 2 (M1) 0.0841 12 -234U 2 G KC=0.0672 10$LC=0.01272 18$MC=0.00306 5 +234U G 166.5 1 2.37E-7 5[E1] 0.1514 22 +234U 2 G KC=0.1179 17$LC=0.0253 4$MC=0.00613 9 +234U G 516.60 6 1.22E-5 16(M1) 0.228 4 +234U 2 G KC=0.182 3$LC=0.0347 5$MC=0.00837 12 +234U G 557.24 6 8.3E-6 11(M1) 0.186 3 +234U 2 G KC=0.1485 21$LC=0.0283 4$MC=0.00682 10 +234U G 750.12 6 0.000017 2(M1) 0.0841 12 +234U 2 G KC=0.0672 10$LC=0.01272 18$MC=0.00306 5 234U G 791.94 5 9.9E-6 13[M1] 0.0728 11 -234U 2 G KC=0.0582 9$LC=0.01100 16$MC=0.00265 4 -234U G 1558.4 100.00073 9 M1 0.0122818 -234U 2 G KC=0.00971 14$LC=0.00181 3$MC=4.34E-4 7 +234U 2 G KC=0.0582 9$LC=0.01100 16$MC=0.00265 4 +234U G 1558.4 100.00073 9M1 0.0122818 +234U 2 G KC=0.00971 14$LC=0.00181 3$MC=4.34E-4 7 234U G 1601.8 150.00047 22(M1) 0.0114617 -234U 2 G KC=0.00902 13$LC=1679E-6 24$MC=4.03E-4 6 +234U 2 G KC=0.00902 13$LC=1679E-6 24$MC=4.03E-4 6 234U L 1666.77 5 (1-)+ -234U B 602 4 0.0061 3 7.6 +234U B 602 4 0.0061 3 7.6 234U S B EAV=180.1 14 -234U G 818.2 5 0.0010 3 -234U G 880.52 4 0.00392 5 -234U G 1667.6 100.00118 6 +234U G 818.2 5 0.0010 3 +234U G 880.52 4 0.00392 5 +234U G 1667.6 100.00118 6 234U L 1693.7 6 (1-)+ -234U B 575 4 0.0024 3 8 +234U B 575 4 0.0024 3 8 234U S B EAV=171.2 14 -234U G 456.7 100.00072 15[M1] 0.318 5 -234U 2 G KC=0.253 4$LC=0.0485 8$MC=0.01171 18 +234U G 456.7 100.00072 15[M1] 0.318 5 +234U 2 G KC=0.253 4$LC=0.0485 8$MC=0.01171 18 234U G 844.1 8 0.00109 23 -234U G 1694.1 100.00038 2 +234U G 1694.1 100.00038 2 234U L 1781.19 8 (0+,1)+ 234U B 488 4 0.0357 18 6.6 234U S B EAV=142.3 14 @@ -296,63 +296,63 @@ 234U G 655.3 100.00139 15 234U G 695.5 100.00164 14 234U G 996.1 200.0059 17 -234U G 1737.77 100.0214 3 +234U G 1737.77 100.0214 3 234U L 1796.4 6 (1)+ -234U B 473 4 0.0021 3 7.7 +234U B 473 4 0.0021 3 7.7 234U S B EAV=137.4 14 234U G 338.1 8 0.00113 23 234U G 362.8 100.00069 15 -234U G 1796.3 9 0.00031 5 +234U G 1796.3 9 0.00031 5 234U L 1808.97 7 (1-)+ -234U B 460 4 0.0146 7 6.9 +234U B 460 4 0.0146 7 6.9 234U S B EAV=133.3 13 -234U G 572 1 0.00087 17[M1] 0.173 3 -234U 2 G KC=0.1384 21$LC=0.0264 4$MC=0.00636 10 +234U G 572.0 100.00087 17[M1] 0.173 3 +234U 2 G KC=0.1384 21$LC=0.0264 4$MC=0.00636 10 234U G 683.4 100.00058 12[E1] 0.0074111 -234U 2 G KC=0.00603 9$LC=1050E-6 15$MC=2.50E-4 4 -234U G 960 1 0.0009 3 -234U G 1765.44 100.0084 6 -234U G 1809.05 100.00376 7 +234U 2 G KC=0.00603 9$LC=1050E-6 15$MC=2.50E-4 4 +234U G 960.0 100.0009 3 +234U G 1765.44 100.0084 6 +234U G 1809.05 100.00376 7 234U L 1863.11 7 (1)+ 234U B 406 4 0.00311 19 7.4 234U S B EAV=116.0 13 234U G 936.3 100.00102 17 -234U G 1819.69 100.00089 5 -234U G 1863.09 100.00120 5 +234U G 1819.69 100.00089 5 +234U G 1863.09 100.00120 5 234U L 1874.86 8 (1)+ -234U B 394 4 0.0258 3 6.4 +234U B 394 4 0.0258 3 6.4 234U S B EAV=112.3 13 234U G 1831.37 100.01759 23 234U G 1874.9 1 0.00819 14 234U L 1911.04 5 (1-)+ -234U B 358 4 0.0452 8 6 +234U B 358 4 0.0452 8 6 234U S B EAV=101.0 13 234U G 357.5 100.00080 17 -234U G 453.58 100.00213 12[M1] 0.324 5 -234U 2 G KC=0.258 4$LC=0.0495 7$MC=0.01193 17 -234U G 475.74 100.00237 13[M1] 0.285 4 -234U 2 G KC=0.227 4$LC=0.0434 6$MC=0.01048 15 +234U G 453.58 100.00213 12[M1] 0.324 5 +234U 2 G KC=0.258 4$LC=0.0495 7$MC=0.01193 17 +234U G 475.74 100.00237 13[M1] 0.285 4 +234U 2 G KC=0.227 4$LC=0.0434 6$MC=0.01048 15 234U G 673.9 100.00064 13[M1] 0.1118 17 -234U 2 G KC=0.0894 13$LC=0.01695 25$MC=0.00408 6 -234U G 825.5 2 0.0014 4 +234U 2 G KC=0.0894 13$LC=0.01695 25$MC=0.00408 6 +234U G 825.5 2 0.0014 4 234U G 866.8 100.00116 16 234U G 921.72 100.01275 20 234U G 1059.4 8 0.00111 22 -234U G 1061.86 100.00224 9 -234U G 1124.93 100.00347 9 +234U G 1061.86 100.00224 9 +234U G 1124.93 100.00347 9 234U G 1867.7 1 0.00932 12 -234U G 1911.20 110.00628 9 +234U G 1911.20 110.00628 9 234U L 1936.68 7 (1)+ -234U B 332 4 0.0108 3 6.6 +234U B 332 4 0.0108 3 6.6 234U S B EAV=93.0 13 -234U G 699.02 100.0058 3 -234U G 1893.51 110.00218 6 -234U G 1937.01 130.00285 5 +234U G 699.02 100.0058 3 +234U G 1893.51 110.00218 6 +234U G 1937.01 130.00285 5 234U L 1970.0 5 (1-)- 234U B 299 4 0.00389 22 6.8 1 234U S B EAV=83.0 13 234U G 732.5 100.00130 15 234U G 1120.6 8 0.00173 15 -234U G 1926.5 100.00045 4 -234U G 1970.3 8 0.00041 4 +234U G 1926.5 100.00045 4 +234U G 1970.3 8 0.00041 4 diff --git a/HEN_HOUSE/spectra/lnhb/Pb-203.txt b/HEN_HOUSE/spectra/lnhb/Pb-203.txt index d123c8167..8128d7fcb 100644 --- a/HEN_HOUSE/spectra/lnhb/Pb-203.txt +++ b/HEN_HOUSE/spectra/lnhb/Pb-203.txt @@ -10,44 +10,44 @@ 203TL7C 1971Ch54, 1971WaKF, 1974Ha29, 1978He21, 1980Ho17, 1982HoZJ, 1985HaZA, 203TL8C 1989Ne05, 1996Sc06, 2000He14, 2000Sc05, 2001Li17, 2002Un02, 2003Au03, 203TL9C 2005Ko20, 2006Ra03 -203TL T Auger electrons and ^X ray energies and emission intensities: -203TL T {U Energy (keV)} {U Intensity } {U Line } +203TL T Auger electrons and X ray energies and emission intensities: +203TL T {U Energy (keV)} {U Intensity} {U Line} 203TL T -203TL T 70.8325 25.61 19 XKA2 -203TL T 72.8725 43.24 25 XKA1 +203TL T 70.8325 25.61 19 XKA2 +203TL T 72.8725 43.24 25 XKA1 203TL T -203TL T 82.118 |] XKB3 -203TL T 82.577 |] 14.70 24 XKB1 -203TL T 83.115 |] XKB5II +203TL T 82.118 |] XKB3 +203TL T 82.577 |] 14.70 24 XKB1 +203TL T 83.115 |] XKB5II 203TL T -203TL T 84.838 |] XKB2 -203TL T 85.134 |] 4.37 11 XKB4 -203TL T 85.444 |] XKO23 +203TL T 84.838 |] XKB2 +203TL T 85.134 |] 4.37 11 XKB4 +203TL T 85.444 |] XKO23 203TL T -203TL T 8.9531-14.7362 33.2 6 XL (total) -203TL T 8.9531 0.819 21 XLL -203TL T 10.1718-10.2679 15.8 4 XLA -203TL T 10.9942 0.243 6 XLC -203TL T 11.8117-12.9566 13.79 25 XLB -203TL T 13.8528-14.7362 2.58 5 XLG +203TL T 8.9531-14.7362 33.2 6 XL (total) +203TL T 8.9531 0.819 21 XLL +203TL T 10.1718-10.2679 15.8 4 XLA +203TL T 10.9942 0.243 6 XLC +203TL T 11.8117-12.9566 13.79 25 XLB +203TL T 13.8528-14.7362 2.58 5 XLG 203TL T -203TL T 54.587-59.954 |] KLL AUGER -203TL T 66.37-72.86 |] 3.4 4 ^KLX AUGER -203TL T 78.12-85.5 |] KXY AUGER -203TL T 5.18-15.31 57.9 6 L AUGER +203TL T 54.587-59.954 |] KLL AUGER +203TL T 66.37-72.86 |] 3.4 4 KLX AUGER +203TL T 78.12-85.5 |] KXY AUGER +203TL T 5.18-15.31 57.9 6 L AUGER 203PB P 0.0 5/2- 51.929 H 10 975 6 203TL N 1.0 1.0 1 1.0 203TL L 0 1/2+ STABLE 203TL L 279.1958 123/2+ 282.3 PS 37 -203TL E 95.20 126.404 1U -203TL2 E EAV= $CK=0.7786 4$CL=0.1661 3$CM=0.0552 1$CN= $CO=0 0 -203TL G 279.1952 1080.94 5 M1+E2 1.17 6 0.2261 8 -203TL2 G KC=0.164 1$LC=0.04837 48$MC= +203TL E 95.20 126.404 1 +203TL2 E CK=0.7786 4$CL=0.1661 3$CM=0.0552 1$CO=0 0 +203TL G 279.1952 1080.94 5M1+E2 1.17 6 0.2261 8 +203TL2 G KC=0.164 1$LC=0.04837 48 203TL L 680.5164 225/2+ 0.88 PS 8 -203TL E 4.80 8 6.812 -203TL2 E EAV= $CK=0.7076 32$CL=0.2168 22$CM=0.0756 9$CN= $CO=0 0 -203TL G 401.320 3 3.43 6 M1+E2 0.030 3 0.1784 25 -203TL2 G KC=0.1464 21$LC=0.0245 4$MC=0.00572 8 +203TL E 4.80 86.812 +203TL2 E CK=0.7076 32$CL=0.2168 22$CM=0.0756 9$CO=0 0 +203TL G 401.320 3 3.43 6M1+E2 0.030 3 0.1784 25 +203TL2 G KC=0.1464 21$LC=0.0245 4$MC=0.00572 8 203TL G 680.515 3 0.754 18E2 0.0139320 -203TL2 G KC=0.01065 15$LC=0.00250 4$MC=6.05E-4 9 +203TL2 G KC=0.01065 15$LC=0.00250 4$MC=6.05E-4 9 diff --git a/HEN_HOUSE/spectra/lnhb/Pb-209.txt b/HEN_HOUSE/spectra/lnhb/Pb-209.txt index f9520f619..d12ff0b68 100644 --- a/HEN_HOUSE/spectra/lnhb/Pb-209.txt +++ b/HEN_HOUSE/spectra/lnhb/Pb-209.txt @@ -5,24 +5,24 @@ 209BI2C Type=full;Author=mmbe;Cutoff date= -- 209BI C References: 1940Kr08, 1941Fa04, 1942Ma03, 1959Po64, 1971Go40, 1971Pe03, 209BI2C 1972Be44, 1991Ma16, 2003Au03 -209BI T Auger electrons and ^X ray energies and emission intensities: -209BI T {U Energy (keV)} {U Intensity } {U Line } +209BI T Auger electrons and X ray energies and emission intensities: +209BI T {U Energy (keV)} {U Intensity} {U Line} 209BI T 209BI T 74.8157 XKA2 209BI T 77.1088 XKA1 209BI T -209BI T 86.835 |] XKB3 -209BI T 87.344 |] XKB1 -209BI T 87.862 |] XKB5II +209BI T 86.835 |] XKB3 +209BI T 87.344 |] XKB1 +209BI T 87.862 |] XKB5II 209BI T -209BI T 89.732 |] XKB2 -209BI T 90.074 |] XKB4 -209BI T 90.421 |] XKO23 +209BI T 89.732 |] XKB2 +209BI T 90.074 |] XKB4 +209BI T 90.421 |] XKO23 209BI T 209BI T -209BI T 57.491-63.419 |] KLL AUGER -209BI T 70.025-77.105 |] ^KLX AUGER -209BI T 82.53-90.52 |] KXY AUGER +209BI T 57.491-63.419 |] KLL AUGER +209BI T 70.025-77.105 |] KLX AUGER +209BI T 82.53-90.52 |] KXY AUGER 209BI T 5.4204-16.3366 L AUGER 209PB P 0.0 9/2+ 3.277 H 15 644.0 12 209BI N 1.0 1.0 1 1.0 diff --git a/HEN_HOUSE/spectra/lnhb/Pb-210.txt b/HEN_HOUSE/spectra/lnhb/Pb-210.txt index 75af671f1..83634f900 100644 --- a/HEN_HOUSE/spectra/lnhb/Pb-210.txt +++ b/HEN_HOUSE/spectra/lnhb/Pb-210.txt @@ -7,19 +7,19 @@ 206HG4C 1969Gr33, 1971Ge11, 1981He15, 1983De11, 1987Me17, 1990He18, 1990Sc08, 206HG5C 1990Hi03, 1996Sc06, 1999Br38, 2000He14, 2002Re18, 2002Ba85, 2003Br13, 206HG6C 2003Au03 -206HG T Auger electrons and ^X ray energies and emission intensities: -206HG T {U Energy (keV)} {U Intensity } {U Line } +206HG T Auger electrons and X ray energies and emission intensities: +206HG T {U Energy (keV)} {U Intensity} {U Line} 206HG T 206HG T 68.895 XKA2 206HG T 70.82 XKA1 206HG T -206HG T 79.823 |] XKB3 -206HG T 80.254 |] XKB1 -206HG T 80.762 |] XKB5II +206HG T 79.823 |] XKB3 +206HG T 80.254 |] XKB1 +206HG T 80.762 |] XKB5II 206HG T -206HG T 82.435 |] XKB2 -206HG T 82.776 |] XKB4 -206HG T 83.028 |] XKO23 +206HG T 82.435 |] XKB2 +206HG T 82.776 |] XKB4 +206HG T 83.028 |] XKO23 206HG T 210PB P 0.0 0+ 22.23 Y 12 3792 20 206HG N 5.263E7 5.263E7 1.9E-08 5.263E7 @@ -35,28 +35,28 @@ 210BI4C 1969Gr33, 1971Ge11, 1981He15, 1983De11, 1987Me17, 1990He18, 1990Sc08, 210BI5C 1990Hi03, 1996Sc06, 1999Br38, 2000He14, 2002Re18, 2002Ba85, 2003Br13, 210BI6C 2003Au03 -210BI T Auger electrons and ^X ray energies and emission intensities: -210BI T {U Energy (keV)} {U Intensity } {U Line } +210BI T Auger electrons and X ray energies and emission intensities: +210BI T {U Energy (keV)} {U Intensity} {U Line} 210BI T 210BI T 74.8157 XKA2 210BI T 77.1088 XKA1 210BI T -210BI T 86.835 |] XKB3 -210BI T 87.344 |] XKB1 -210BI T 87.862 |] XKB5II +210BI T 86.835 |] XKB3 +210BI T 87.344 |] XKB1 +210BI T 87.862 |] XKB5II 210BI T -210BI T 89.732 |] XKB2 -210BI T 90.074 |] XKB4 -210BI T 90.421 |] XKO23 +210BI T 89.732 |] XKB2 +210BI T 90.074 |] XKB4 +210BI T 90.421 |] XKO23 210BI T -210BI T 9.4207-15.7084 22.0 5 XL (total) -210BI T 9.4207 0.552 17 XLL -210BI T 10.7308-10.8387 10.30 29 XLA -210BI T 11.7127 0.0745 21 XLC -210BI T 12.4814-13.8066 9.05 13 XLB -210BI T 14.7735-15.7084 1.968 28 XLG +210BI T 9.4207-15.7084 22.0 5 XL (total) +210BI T 9.4207 0.552 17 XLL +210BI T 10.7308-10.8387 10.30 29 XLA +210BI T 11.7127 0.0745 21 XLC +210BI T 12.4814-13.8066 9.05 13 XLB +210BI T 14.7735-15.7084 1.968 28 XLG 210BI T -210BI T 5.3-10.7 36.0 9 L AUGER +210BI T 5.3-10.7 36.0 9 L AUGER 210PB P 0.0 0+ 22.23 Y 12 63.5 5 210BI N 1.0 1.0 1 1.0 210BI L 0 1- 5.012 D 5 @@ -66,5 +66,5 @@ 210BI B 17.0 5 80.2 13 5.5 210BIS B EAV=4.3 1 210BI G 46.539 1 4.252 40M1 17.86 25 -210BI2 G KC=$LC=13.64 19$MC=3.21 5 +210BI2 G LC=13.64 19$MC=3.21 5 diff --git a/HEN_HOUSE/spectra/lnhb/Pb-211.txt b/HEN_HOUSE/spectra/lnhb/Pb-211.txt index d9e6b68eb..46377e156 100644 --- a/HEN_HOUSE/spectra/lnhb/Pb-211.txt +++ b/HEN_HOUSE/spectra/lnhb/Pb-211.txt @@ -5,94 +5,94 @@ 211BI2C 1967Da10, 1967Da20, 1968Br17, 1968Go15, 1968Ha21, 1971Da34, 1971Go40, 211BI3C 1976Bl13, 1988Hi14, 1996Sc06, 1998ScZM, 1999ScZX, 2000Sc47, 2003Au03, 211BI4C 2003De44, 2004Br45, 2008DuZX, 2008Ki07, 2011Ko04 -211BI T Auger electrons and ^X ray energies and emission intensities: -211BI T {U Energy (keV)} {U Intensity } {U Line } +211BI T Auger electrons and X ray energies and emission intensities: +211BI T {U Energy (keV)} {U Intensity} {U Line} 211BI T -211BI T 74.8157 0.228 10 XKA2 -211BI T 77.1088 0.381 17 XKA1 +211BI T 74.8157 0.228 10 XKA2 +211BI T 77.1088 0.381 17 XKA1 211BI T -211BI T 86.835 |] XKB3 -211BI T 87.344 |] 0.130 6 XKB1 -211BI T 87.862 |] XKB5II +211BI T 86.835 |] XKB3 +211BI T 87.344 |] 0.130 6 XKB1 +211BI T 87.862 |] XKB5II 211BI T -211BI T 89.732 |] XKB2 -211BI T 90.074 |] 0.0399 20 XKB4 -211BI T 90.421 |] XKO23 +211BI T 89.732 |] XKB2 +211BI T 90.074 |] 0.0399 20 XKB4 +211BI T 90.421 |] XKO23 211BI T -211BI T 9.4207-15.7084 0.494 13 XL (total) -211BI T 9.4207 0.0120 5 XLL -211BI T 10.7308-10.8387 0.225 8 XLA -211BI T 11.7127 0.00330 15 XLC -211BI T 12.4814-13.8066 0.211 6 XLB -211BI T 14.7735-15.7084 0.0427 12 XLG +211BI T 9.4207-15.7084 0.494 13 XL (total) +211BI T 9.4207 0.0120 5 XLL +211BI T 10.7308-10.8387 0.225 8 XLA +211BI T 11.7127 0.00330 15 XLC +211BI T 12.4814-13.8066 0.211 6 XLB +211BI T 14.7735-15.7084 0.0427 12 XLG 211BI T -211BI T 57.491-63.419 |] KLL AUGER -211BI T 70.025-77.105 |] 0.029 4 ^KLX AUGER -211BI T 82.53-90.52 |] KXY AUGER -211BI T 5.42-16.34 0.782 18 L AUGER +211BI T 57.491-63.419 |] KLL AUGER +211BI T 70.025-77.105 |] 0.029 4 KLX AUGER +211BI T 82.53-90.52 |] KXY AUGER +211BI T 5.42-16.34 0.782 18 L AUGER 211PB P 0.0 9/2+ 36.1 M 2 1367 6 211BI N 1.0 1.0 1 1.0 211BI L 0 9/2- 2.15 M 2 211BI B 1367 6 91.28 12 5.99 211BIS B EAV=470.9 24 211BI L 404.834 9 7/2- 0.317 NS 11 -211BI B 962 6 1.57 9 7.21 1U +211BI B 962 6 1.57 9 7.21 1 211BIS B EAV=313.3 23 -211BI G 404.834 9 3.83 6 M1+E2 -1.1 1 0.122 8 -211BI2 G KC=0.095 7$LC=0.0206 8$MC=0.00499 17 +211BI G 404.834 9 3.83 6M1+E2 -1.1 1 0.122 8 +211BI2 G KC=0.095 7$LC=0.0206 8$MC=0.00499 17 211BI L 766.680 13(9/2,11/2)- 211BI B 600 6 0.09 7.7 211BIS B EAV=182.2 21 -211BI G 361.846 160.042 3 [M1E2] 0.17 11 -211BI2 G KC=0.14 10$LC=0.03 1$MC=0.0072 20 -211BI G 766.680 130.62 4 M1 0.0382 6 -211BI2 G KC=0.0313 5$LC=0.00527 8$MC=1234E-6 18 +211BI G 361.846 160.042 3[M1E2] 0.17 11 +211BI2 G KC=0.14 10$LC=0.03 1$MC=0.0072 20 +211BI G 766.680 130.62 4M1 0.0382 6 +211BI2 G KC=0.0313 5$LC=0.00527 8$MC=1234E-6 18 211BI L 831.984 129/2- -211BI B 535 6 6.32 9 5.73 +211BI B 535 6 6.32 9 5.73 211BIS B EAV=159.8 21 -211BI G 65.304 180.077 4 M1 6.61 10 -211BI2 G KC=$LC=5.05 7$MC=1.188 17 -211BI G 427.150 151.81 4 M1+E2 -0.022 9 0.1783 25 -211BI2 G KC=0.1457 21$LC=0.0249 4$MC=0.00585 9 -211BI G 831.984 123.50 5 M1+E2 0.4 2 0.028 3 -211BI2 G KC=0.0229 23$LC=0.0039 4$MC=0.00092 8 +211BI G 65.304 180.077 4M1 6.61 10 +211BI2 G LC=5.05 7$MC=1.188 17 +211BI G 427.150 151.81 4M1+E2 -0.022 9 0.1783 25 +211BI2 G KC=0.1457 21$LC=0.0249 4$MC=0.00585 9 +211BI G 831.984 123.50 5M1+E2 0.4 2 0.028 3 +211BI2 G KC=0.0229 23$LC=0.0039 4$MC=0.00092 8 211BI L 1014.38 4 (7/2,9/2,11/2)- -211BI G 609.55 4 0.033 9 -211BI G 1014.38 4 0.0173 5 +211BI G 609.55 4 0.033 9 +211BI G 1014.38 4 0.0173 5 211BI L 1080.64 4 + 211BI B 286 6 0.0570 24 211BIS B EAV=79.7 19 211BI G 313.96 4 0.0268 21 -211BI G 675.81 4 0.0181 9 -211BI G 1080.64 4 0.0121 5 +211BI G 675.81 4 0.0181 9 +211BI G 1080.64 4 0.0121 5 211BI L 1103.52 20 + -211BI B 263 6 0.0047 7 +211BI B 263 6 0.0047 7 211BIS B EAV=72.8 18 -211BI G 1103.52 200.0047 7 +211BI G 1103.52 200.0047 7 211BI L 1109.509 239/2- -211BI B 257 6 1.06 4 5.58 +211BI B 257 6 1.06 4 5.58 211BIS B EAV=71.0 18 -211BI G 95.13 5 0.018 3 M1+E2 1.7 6 9.3 4 -211BI2 G KC=2.8 9$LC=4.8 5$MC=1.27 12 -211BI G 342.83 3 0.029 4 [M1E2] 0.20 12 +211BI G 95.13 5 0.018 3M1+E2 1.7 6 9.3 4 +211BI2 G KC=2.8 9$LC=4.8 5$MC=1.27 12 +211BI G 342.83 3 0.029 4[M1E2] 0.20 12 211BI2 G KC=0.16 11$LC=0.035 11$MC=0.0085 22 -211BI G 704.675 250.47 1 M1+E2 -0.022 7 0.0476 7 -211BI2 G KC=0.0390 6$LC=0.00657 10$MC=1540E-6 22 -211BI G 1109.509 230.116 3 [M1] 0.0147221 -211BI2 G KC=0.01209 17$LC=0.00201 3$MC=4.70E-4 7 +211BI G 704.675 250.47 1M1+E2 -0.022 7 0.0476 7 +211BI2 G KC=0.0390 6$LC=0.00657 10$MC=1540E-6 22 +211BI G 1109.509 230.116 3[M1] 0.0147221 +211BI2 G KC=0.01209 17$LC=0.00201 3$MC=4.70E-4 7 211BI L 1196.33 5 + -211BI B 171 6 0.019 4 +211BI B 171 6 0.019 4 211BIS B EAV=45.6 18 -211BI G 429.65 6 0.008 3 -211BI G 1196.33 5 0.0103 4 +211BI G 429.65 6 0.008 3 +211BI G 1196.33 5 0.0103 4 211BI L 1234.3 4 + -211BI B 133 6 0.0009 3 +211BI B 133 6 0.0009 3 211BIS B EAV=35.0 17 -211BI G 1234.3 4 0.0009 3 +211BI G 1234.3 4 0.0009 3 211BI L 1270.75 6 (7/2,9/2,11/2)+ -211BI B 96 6 0.0172 15 5.93 2 +211BI B 96 6 0.0172 15 5.93 211BIS B EAV=25.0 17 -211BI G 504.07 6 0.0059 8 -211BI G 865.92 6 0.0046 2 +211BI G 504.07 6 0.0059 8 +211BI G 865.92 6 0.0046 2 211BI G 1270.75 6 0.0068 12 diff --git a/HEN_HOUSE/spectra/lnhb/Pb-212.txt b/HEN_HOUSE/spectra/lnhb/Pb-212.txt index 1501509e2..bd7d962f4 100644 --- a/HEN_HOUSE/spectra/lnhb/Pb-212.txt +++ b/HEN_HOUSE/spectra/lnhb/Pb-212.txt @@ -8,53 +8,53 @@ 212BI3C 1977La19, 1978Av01, 1982Sa36, 1983Va22, 1983Sc13, 1984Ge07, 1992Li05, 212BI4C 1996Sc06, 1999ScZM, 1999ScZX, 2002Ra45, 2002Ba85, 2003Au03, 2005Br03, 212BI5C 2008Ki07 -212BI T Auger electrons and ^X ray energies and emission intensities: -212BI T {U Energy (keV)} {U Intensity } {U Line } +212BI T Auger electrons and X ray energies and emission intensities: +212BI T {U Energy (keV)} {U Intensity} {U Line} 212BI T -212BI T 74.8157 10.07 18 XKA2 -212BI T 77.1088 16.9 3 XKA1 +212BI T 74.8157 10.07 18 XKA2 +212BI T 77.1088 16.9 3 XKA1 212BI T -212BI T 86.835 |] XKB3 -212BI T 87.344 |] 5.77 13 XKB1 -212BI T 87.862 |] XKB5II +212BI T 86.835 |] XKB3 +212BI T 87.344 |] 5.77 13 XKB1 +212BI T 87.862 |] XKB5II 212BI T -212BI T 89.732 |] XKB2 -212BI T 90.074 |] 1.77 5 XKB4 -212BI T 90.421 |] XKO23 +212BI T 89.732 |] XKB2 +212BI T 90.074 |] 1.77 5 XKB4 +212BI T 90.421 |] XKO23 212BI T -212BI T 9.42-15.709 13.8 6 XL (total) -212BI T 9.42 0.340 9 XLL -212BI T 10.731-10.839 6.36 16 XLA -212BI T 11.712 0.103 3 XLC -212BI T 12.48-13.393 5.76 12 XLB -212BI T 15.248-15.709 1.111 23 XLG +212BI T 9.42-15.709 13.8 6 XL (total) +212BI T 9.42 0.340 9 XLL +212BI T 10.731-10.839 6.36 16 XLA +212BI T 11.712 0.103 3 XLC +212BI T 12.48-13.393 5.76 12 XLB +212BI T 15.248-15.709 1.111 23 XLG 212BI T -212BI T 57.49-63.42 |] KLL AUGER -212BI T 70.03-77.11 |] 1.29 15 ^KLX AUGER -212BI T 82.53-90.52 |] KXY AUGER -212BI T 5.35-10.66 21.4 7 L AUGER +212BI T 57.49-63.42 |] KLL AUGER +212BI T 70.03-77.11 |] 1.29 15 KLX AUGER +212BI T 82.53-90.52 |] KXY AUGER +212BI T 5.35-10.66 21.4 7 L AUGER 212PB P 0.0 0+ 10.64 H 1 569.9 19 212BI N 1.0 1.0 1 1.0 212BI L 0 1- 60.54 M 6 212BI B 569.9 1913.3 11 6.74 1 212BIS B EAV=171.7 7 212BI L 115.183 5 2- -212BI G 115.183 5 0.624 23[M1] 6.8 1 -212BI2 G KC=5.53 8$LC=0.972 14$MC=0.229 4 +212BI G 115.183 5 0.624 23[M1] 6.8 1 +212BI2 G KC=5.53 8$LC=0.972 14$MC=0.229 4 212BI L 238.632 2 0- 212BI B 331.3 1981.7 11 5.18 212BIS B EAV=93.5 6 -212BI G 123.449 5 0.052 5 [E2] 2.80 4 -212BI2 G KC=0.421 6$LC=1.766 25$MC=0.468 7 -212BI G 238.632 2 43.6 5 [M1] 0.872 13 -212BI2 G KC=0.71 1$LC=0.1232 18$MC=0.0290 4 +212BI G 123.449 5 0.052 5[E2] 2.80 4 +212BI2 G KC=0.421 6$LC=1.766 25$MC=0.468 7 +212BI G 238.632 2 43.6 5[M1] 0.872 13 +212BI2 G KC=0.71 1$LC=0.1232 18$MC=0.0290 4 212BI L 415.272 111- 212BI B 154.6 194.99 21 5.35 1 212BIS B EAV=41.1 5 -212BI G 176.640 110.052 5 [M1] 2.02 3 -212BI2 G KC=1.646 23$LC=0.287 4$MC=0.0675 10 -212BI G 300.089 123.18 14[M1] 0.464 7 -212BI2 G KC=0.378 6$LC=0.0653 10$MC=0.01534 22 -212BI G 415.272 110.144 22[M1] 0.192 3 -212BI2 G KC=0.1571 22$LC=0.0269 4$MC=0.00632 9 +212BI G 176.640 110.052 5[M1] 2.02 3 +212BI2 G KC=1.646 23$LC=0.287 4$MC=0.0675 10 +212BI G 300.089 123.18 14[M1] 0.464 7 +212BI2 G KC=0.378 6$LC=0.0653 10$MC=0.01534 22 +212BI G 415.272 110.144 22[M1] 0.192 3 +212BI2 G KC=0.1571 22$LC=0.0269 4$MC=0.00632 9 diff --git a/HEN_HOUSE/spectra/lnhb/Pb-214.txt b/HEN_HOUSE/spectra/lnhb/Pb-214.txt index dd7091b04..902b62611 100644 --- a/HEN_HOUSE/spectra/lnhb/Pb-214.txt +++ b/HEN_HOUSE/spectra/lnhb/Pb-214.txt @@ -8,31 +8,31 @@ 214BI3C 1981Mo28, 1982Ak03, 1982Fa10, 1983Ol01, 1983Sc13, 1984Pe13, 1988Ak01, 214BI4C 1990Mo08, 1991Li11, 1993Di09, 1995El07, 1996Sc06, 1998Mo14, 2000Sa32, 214BI5C 2002De03, 2002MoZP, 2002Ba85, 2003Au03, 2004Mo07, 2007BeZP -214BI T Auger electrons and ^X ray energies and emission intensities: -214BI T {U Energy (keV)} {U Intensity } {U Line } +214BI T Auger electrons and X ray energies and emission intensities: +214BI T {U Energy (keV)} {U Intensity} {U Line} 214BI T -214BI T 74.8157 6.26 12 XKA2 -214BI T 77.1088 10.47 20 XKA1 +214BI T 74.8157 6.26 12 XKA2 +214BI T 77.1088 10.47 20 XKA1 214BI T -214BI T 86.835 |] XKB3 -214BI T 87.344 |] 3.59 9 XKB1 -214BI T 87.862 |] XKB5II +214BI T 86.835 |] XKB3 +214BI T 87.344 |] 3.59 9 XKB1 +214BI T 87.862 |] XKB5II 214BI T -214BI T 89.732 |] XKB2 -214BI T 90.074 |] 1.10 4 XKB4 -214BI T 90.421 |] XKO23 +214BI T 89.732 |] XKB2 +214BI T 90.074 |] 1.10 4 XKB4 +214BI T 90.421 |] XKO23 214BI T -214BI T 9.42-16.36 12.42 22 XL (total) -214BI T 9.42 0.311 9 XLL -214BI T 10.45-10.55 5.80 15 XLA -214BI T 11.35 0.0770 21 XLC -214BI T 12.13-13.38 5.18 9 XLB -214BI T 14.31-16.36 1.039 18 XLG +214BI T 9.42-16.36 12.42 22 XL (total) +214BI T 9.42 0.311 9 XLL +214BI T 10.45-10.55 5.80 15 XLA +214BI T 11.35 0.0770 21 XLC +214BI T 12.13-13.38 5.18 9 XLB +214BI T 14.31-16.36 1.039 18 XLG 214BI T -214BI T 57.49-63.42 |] KLL AUGER -214BI T 70.02-77.1 |] 0.80 9 ^KLX AUGER -214BI T 82.45-90.52 |] KXY AUGER -214BI T 5.3-16.4 19.8 3 L AUGER +214BI T 57.49-63.42 |] KLL AUGER +214BI T 70.02-77.1 |] 0.80 9 KLX AUGER +214BI T 82.45-90.52 |] KXY AUGER +214BI T 5.3-16.4 19.8 3 L AUGER 214PB P 0.0 0+ 26.916 M 44 1019 11 214BI N 1.0 1.0 1 1.0 214BI G 107.22 9 0.0068 14 @@ -40,43 +40,43 @@ 214BI G 141.3 6 0.027 14 214BI G 170.07 6 0.0146 27 214BI G 216.47 7 0.0100 23 -214BI G 765.96 9 0.053 8 +214BI G 765.96 9 0.053 8 214BI L 0 1- 19.8 M 1 -214BI B 1019 119.2 7 6.3 1 +214BI B 1019 119.2 7 6.3 1 214BIS B EAV=337 4 214BI L 53.2275 21(2)- 0.52 NS 15 -214BI G 53.2275 211.060 7 M1+E2 0.03 1 12.88 39 -214BI2 G KC=$LC=9.80 29$MC=2.32 7 +214BI G 53.2275 211.060 7M1+E2 0.03 1 12.88 39 +214BI2 G LC=9.80 29$MC=2.32 7 214BI L 62.7 1 + 214BI L 258.87 3 (2)- -214BI G 196.20 5 0.069 9 +214BI G 196.20 5 0.069 9 214BI G 205.68 9 0.0114 23 214BI G 258.87 3 0.5318 36M1 0.737 22 -214BI2 G KC=0.601 18$LC=0.1037 31$MC=0.0244 7 +214BI2 G KC=0.601 18$LC=0.1037 31$MC=0.0244 7 214BI L 295.224 2 1- 214BI B 724 1141.09 39 5.2 1 214BIS B EAV=227 4 214BI G 241.997 3 7.268 22M1(+E2) 0.00 15 0.888 27 -214BI2 G KC=0.724 22$LC=0.1250 38$MC=0.0295 9 +214BI2 G KC=0.724 22$LC=0.1250 38$MC=0.0295 9 214BI G 295.224 2 18.414 36M1+E2 0.30 13 0.482 14 -214BI2 G KC=0.390 12$LC=0.0698 21$MC=0.0165 5 +214BI2 G KC=0.390 12$LC=0.0698 21$MC=0.0165 5 214BI L 351.932 2 (0,1)- 214BI B 667 1146.52 37 5.1 214BIS B EAV=207 4 -214BI G 351.932 2 35.60 7 M1(+E2) 0.00 35 0.319 10 -214BI2 G KC=0.260 8$LC=0.0445 13$MC=0.01049 31 +214BI G 351.932 2 35.60 7M1(+E2) 0.00 35 0.319 10 +214BI2 G KC=0.260 8$LC=0.0445 13$MC=0.01049 31 214BI L 377.03 4 - -214BI G 314.32 7 0.077 6 +214BI G 314.32 7 0.077 6 214BI G 323.83 4 0.0287 32 214BI L 533.67 2 (1)- 214BI B 485 111.047 17 6.2 1 214BIS B EAV=145 4 214BI G 274.80 5 0.362 10M1+E2 1 0.392 12 -214BI2 G KC=0.295 9$LC=0.0731 22$MC=0.0179 5 +214BI2 G KC=0.295 9$LC=0.0731 22$MC=0.0179 5 214BI G 480.43 2 0.3371 41M1(+E2) 0 1 0.1384 42 -214BI2 G KC=0.1132 34$LC=0.0192 6$MC=0.00452 14 -214BI G 533.66 2 0.182 6 [M1E2] 0.06 4 -214BI2 G KC=0.05 3$LC=0.010 4$MC=0.0023 9 +214BI2 G KC=0.1132 34$LC=0.0192 6$MC=0.00452 14 +214BI G 533.66 2 0.182 6[M1E2] 0.06 4 +214BI2 G KC=0.05 3$LC=0.010 4$MC=0.0023 9 214BI L 797.24 9 + 214BI B 222 110.0196 27 6.9 214BIS B EAV=62 3 @@ -84,17 +84,17 @@ 214BI L 839.00 4 1+ 214BI B 180 112.762 22 4.5 214BIS B EAV=50 3 -214BI G 305.26 3 0.0315 21[E1] 0.0295 9 -214BI2 G KC=0.0241 7$LC=0.00413 12$MC=9.71E-4 29 -214BI G 462.00 7 0.213 6 -214BI G 487.09 7 0.433 6 (E1) 0.0105832 +214BI G 305.26 3 0.0315 21[E1] 0.0295 9 +214BI2 G KC=0.0241 7$LC=0.00413 12$MC=9.71E-4 29 +214BI G 462.00 7 0.213 6 +214BI G 487.09 7 0.433 6(E1) 0.0105832 214BI2 G KC=0.00871 26$LC=1423E-6 43$MC=3.33E-4 10 -214BI G 543.81 7 0.050 9 E1+M2 0.0084325 -214BI2 G KC=0.00696 21$LC=1124E-6 34$MC=2.62E-4 8 -214BI G 580.13 3 0.369 6 (E1) 0.0074022 -214BI2 G KC=0.00611 18$LC=9.81E-4 29$MC=2.29E-4 7 +214BI G 543.81 7 0.050 9E1+M2 0.0084325 +214BI2 G KC=0.00696 21$LC=1124E-6 34$MC=2.62E-4 8 +214BI G 580.13 3 0.369 6(E1) 0.0074022 +214BI2 G KC=0.00611 18$LC=9.81E-4 29$MC=2.29E-4 7 214BI G 785.96 9 1.064 13E1 0.0041012 214BI2 G KC=0.00341 10$LC=5.33E-4 16$MC=1239E-7 37 -214BI G 839.04 9 0.587 8 (E1) 0.0036311 -214BI2 G KC=0.00302 9$LC=4.70E-4 14$MC=1092E-7 33 +214BI G 839.04 9 0.587 8(E1) 0.0036311 +214BI2 G KC=0.00302 9$LC=4.70E-4 14$MC=1092E-7 33 diff --git a/HEN_HOUSE/spectra/lnhb/Pd-109.txt b/HEN_HOUSE/spectra/lnhb/Pd-109.txt index 43d7fee1d..b0a0e69db 100644 --- a/HEN_HOUSE/spectra/lnhb/Pd-109.txt +++ b/HEN_HOUSE/spectra/lnhb/Pd-109.txt @@ -8,143 +8,143 @@ 109AG5C 1970Ro14, 1973Co10, 1975El10, 1977Bo04, 1977Gi11, 1978Pr08, 1983Ch42, 109AG6C 1990Ab06, 1996Sc06, 1998ScZM, 1999ScZX, 2000He14, 2002Ba25, 2002Ra45, 109AG7C 2003Au03, 2006Bl02, 2008Ki07 -109AG T Auger electrons and ^X ray energies and emission intensities: -109AG T {U Energy (keV)} {U Intensity } {U Line } +109AG T Auger electrons and X ray energies and emission intensities: +109AG T {U Energy (keV)} {U Intensity} {U Line} 109AG T -109AG T 21.9906 9.92 23 XKA2 -109AG T 22.16317 18.7 5 XKA1 +109AG T 21.9906 9.92 23 XKA2 +109AG T 22.16317 18.7 5 XKA1 109AG T -109AG T 24.9118 |] XKB3 -109AG T 24.9427 |] 5.18 13 XKB1 -109AG T 25.146 |] XKB5II +109AG T 24.9118 |] XKB3 +109AG T 24.9427 |] 5.18 13 XKB1 +109AG T 25.146 |] XKB5II 109AG T -109AG T 25.4567 |] XKB2 -109AG T 25.512 |] 0.90 4 XKB4 +109AG T 25.4567 |] XKB2 +109AG T 25.512 |] 0.90 4 XKB4 109AG T -109AG T 2.634-3.75 4.92 13 XL (total) -109AG T 2.634 0.101 4 XLL -109AG T 2.978-2.984 2.71 10 XLA -109AG T 2.806 0.0460 12 XLC -109AG T 3.151-3.348 1.91 6 XLB -109AG T 3.52-3.75 0.184 5 XLG +109AG T 2.634-3.75 4.92 13 XL (total) +109AG T 2.634 0.101 4 XLL +109AG T 2.978-2.984 2.71 10 XLA +109AG T 2.806 0.0460 12 XLC +109AG T 3.151-3.348 1.91 6 XLB +109AG T 3.52-3.75 0.184 5 XLG 109AG T -109AG T 17.79-18.69 |] KLL AUGER -109AG T 20.945-22.16 |] 7.06 23 ^KLX AUGER -109AG T 24.079-25.507 |] KXY AUGER -109AG T 1.9-3.8 79.5 5 L AUGER +109AG T 17.79-18.69 |] KLL AUGER +109AG T 20.945-22.16 |] 7.06 23 KLX AUGER +109AG T 24.079-25.507 |] KXY AUGER +109AG T 1.9-3.8 79.5 5 L AUGER 109PD P 0.0 5/2+ 13.58 H 12 1116.1 20 109AG N 1.0 1.0 1 1.0 109AG L 0 1/2- STABLE 109AG L 88.0341 117/2+ 39.7 S 2 -109AG B 1028.1 2099.891 3 6.134 2 +109AG B 1028.1 2099.891 3 6.134 109AGS B EAV=361.0 8 -109AG G 88.03360 103.66 6 E3 26.33 40 -109AG2 G KC=11.41 16$LC=12.06 17$MC=2.47 4 +109AG G 88.0336 103.66 6E3 26.33 40 +109AG2 G KC=11.41 16$LC=12.06 17$MC=2.47 4 109AG L 132.74 119/2+ 109AG G 44.7 1 0.00121 15M1+E2 0.533 1 9.00 15 -109AG2 G KC=5.69 9$LC=2.69 5$MC=0.533 10 +109AG2 G KC=5.69 9$LC=2.69 5$MC=0.533 10 109AG L 311.38 8 3/2- -109AG B 804.7 200.0191 22 9.46 1U +109AG B 804.7 200.0191 22 9.46 1 109AGS B EAV=270.3 8 -109AG G 311.4 1 0.0314 21M1+E2 0.220 3 0.0201 3 -109AG2 G KC=0.01749 25$LC=0.00213 3$MC=4.05E-4 6 +109AG G 311.4 1 0.0314 21M1+E2 0.220 3 0.0201 3 +109AG2 G KC=0.01749 25$LC=0.00213 3$MC=4.05E-4 6 109AG L 415.21 165/2- -109AG B 700.9 200.0063 2 9.73 +109AG B 700.9 200.0063 2 9.73 109AGS B EAV=229.7 8 -109AG G 103.8 2 0.00070 11M1+E2 -0.045 0.379 7 -109AG2 G KC=0.329 6$LC=0.0411 7$MC=0.00783 13 -109AG G 327.2 2 1.31E-4 15E1 0.005829 -109AG2 G KC=0.00509 8$LC=5.99E-4 9$MC=1133E-7 17 -109AG G 415.2 2 0.0109 6 E2 0.0109816 -109AG2 G KC=0.00944 14$LC=1257E-6 18$MC=2.40E-4 4 +109AG G 103.8 2 0.00070 11M1+E2 -0.045 0.379 7 +109AG2 G KC=0.329 6$LC=0.0411 7$MC=0.00783 13 +109AG G 327.2 2 0.00013115E1 0.00582 9 +109AG2 G KC=0.00509 8$LC=5.99E-4 9$MC=1133E-7 17 +109AG G 415.2 2 0.0109 6E2 0.0109816 +109AG2 G KC=0.00944 14$LC=1257E-6 18$MC=2.40E-4 4 109AG L 697.8 4 (5/2)+ -109AG B 418.3 200.00016 7 10.55 +109AG B 418.3 200.00016 7 10.55 109AGS B EAV=125.9 7 -109AG G 565.1 5 1.08E-4 14(E2) 0.004467 -109AG2 G KC=0.00386 6$LC=4.89E-4 7$MC=9.31E-5 14 -109AG G 609.8 4 0.00018 6 (M1+E2) +109AG G 565.1 5 0.00010814(E2) 0.00446 7 +109AG2 G KC=0.00386 6$LC=4.89E-4 7$MC=9.31E-5 14 +109AG G 609.8 4 0.00018 6(M1+E2) 109AG L 701.91 153/2- -109AG B 414.2 200.00460 21 9.08 1U +109AG B 414.2 200.00460 21 9.08 1 109AGS B EAV=124.5 7 -109AG G 286.7 3 1.76E-4 16M1+E2 0.199 3 0.0248 4 -109AG2 G KC=0.0216 3$LC=0.00264 4$MC=5.01E-4 8 -109AG G 390.5 2 0.00093 7 M1+E2 0.190 3 0.0112416 -109AG2 G KC=0.00980 14$LC=1178E-6 17$MC=2.24E-4 4 -109AG G 701.9 2 0.00347 20M1+E2 0.029 2 0.002734 -109AG2 G KC=0.00239 4$LC=2.80E-4 4$MC=5.31E-5 8 +109AG G 286.7 3 0.00017616M1+E2 0.199 3 0.0248 4 +109AG2 G KC=0.0216 3$LC=0.00264 4$MC=5.01E-4 8 +109AG G 390.5 2 0.00093 7M1+E2 0.190 3 0.0112416 +109AG2 G KC=0.00980 14$LC=1178E-6 17$MC=2.24E-4 4 +109AG G 701.9 2 0.00347 20M1+E2 0.029 2 0.00273 4 +109AG2 G KC=0.00239 4$LC=2.80E-4 4$MC=5.31E-5 8 109AG L 707.00 17(3/2)+ -109AG B 409.1 200.00178 12 9.47 2 +109AG B 409.1 200.00178 12 9.47 109AGS B EAV=122.8 7 -109AG G 395.6 3 6.8E-5 13(E1) 0.003575 -109AG2 G KC=0.00312 5$LC=3.66E-4 6$MC=6.92E-5 10 +109AG G 395.6 3 0.00006813(E1) 0.00357 5 +109AG2 G KC=0.00312 5$LC=3.66E-4 6$MC=6.92E-5 10 109AG G 707.0 2 0.00171 12(E1) 9.21E-413 109AG2 G KC=8.07E-4 12$LC=9.33E-5 13$MC=1762E-8 25 109AG L 724.35 10(3/2)+ 3.2 NS 8 -109AG B 391.8 200.0204 9 8.351 2 +109AG B 391.8 200.0204 9 8.351 109AGS B EAV=116.8 7 109AG G 309.1 3 0.00413 23(E1) 0.0067710 -109AG2 G KC=0.00591 9$LC=6.97E-4 10$MC=1317E-7 19 -109AG G 413.0 2 0.0068 7 (E1+(M2)) 0.179 4 0.004208 -109AG2 G KC=0.00366 7$LC=4.42E-4 8$MC=8.39E-5 16 -109AG G 636.3 1 0.0101 6 (E2) 0.003235 -109AG2 G KC=0.00281 4$LC=3.50E-4 5$MC=6.65E-5 10 -109AG G 724.4 1 0.00025 3 (E1) 8.74E-413 +109AG2 G KC=0.00591 9$LC=6.97E-4 10$MC=1317E-7 19 +109AG G 413.0 2 0.0068 7(E1+(M2)) 0.179 4 0.00420 8 +109AG2 G KC=0.00366 7$LC=4.42E-4 8$MC=8.39E-5 16 +109AG G 636.3 1 0.0101 6(E2) 0.00323 5 +109AG2 G KC=0.00281 4$LC=3.50E-4 5$MC=6.65E-5 10 +109AG G 724.4 1 0.00025 3(E1) 8.74E-413 109AG2 G KC=7.66E-4 11$LC=8.85E-5 13$MC=1672E-8 24 109AG L 735.29 9 5/2+ 109AG B 380.8 200.0334 15 8.096 109AGS B EAV=113.1 7 -109AG G 423.9 2 0.00093 7 E1(+M2) 0.270 2 0.005028 -109AG2 G KC=0.00436 7$LC=5.36E-4 9$MC=1020E-7 16 -109AG G 602.6 2 0.0086 6 E2 0.003746 -109AG2 G KC=0.00324 5$LC=4.07E-4 6$MC=7.74E-5 11 +109AG G 423.9 2 0.00093 7E1(+M2) 0.270 2 0.00502 8 +109AG2 G KC=0.00436 7$LC=5.36E-4 9$MC=1020E-7 16 +109AG G 602.6 2 0.0086 6E2 0.00374 6 +109AG2 G KC=0.00324 5$LC=4.07E-4 6$MC=7.74E-5 11 109AG G 647.3 1 0.0252 14M1+E2 109AG L 812.0 5 (3/2)+ -109AG B 304.1 2110800E-824 10.3 2 +109AG B 304.1 210.00010824 10.3 109AGS B EAV=87.7 7 -109AG G 114.2 9 6.3E-5 21(M1+E2) -109AG G 500.6 6 4.5E-5 11(E1) 0.002013 -109AG2 G KC=1756E-6 25$LC=2.05E-4 3$MC=3.87E-5 6 +109AG G 114.2 9 0.00006321(M1+E2) +109AG G 500.6 6 0.00004511(E1) 0.00201 3 +109AG2 G KC=1756E-6 25$LC=2.05E-4 3$MC=3.87E-5 6 109AG L 862.76 205/2- 109AG B 253.3 200.00167 10 8.82 109AGS B EAV=71.5 6 -109AG G 447.6 4 0.00086 7 M1+E2 0.160 4 0.0080012 +109AG G 447.6 4 0.00086 7M1+E2 0.160 4 0.0080012 109AG2 G KC=0.00698 10$LC=8.33E-4 12$MC=1580E-7 23 -109AG G 551.4 3 0.00065 7 M1+E2 0.280 3 0.004827 -109AG2 G KC=0.00420 6$LC=5.00E-4 7$MC=9.48E-5 14 -109AG G 862.8 2 1.48E-4 20E2 0.001512 -109AG2 G KC=1313E-6 19$LC=1583E-7 23$MC=3.00E-5 5 +109AG G 551.4 3 0.00065 7M1+E2 0.280 3 0.00482 7 +109AG2 G KC=0.00420 6$LC=5.00E-4 7$MC=9.48E-5 14 +109AG G 862.8 2 0.00014820E2 0.00151 2 +109AG2 G KC=1313E-6 19$LC=1583E-7 23$MC=3.00E-5 5 109AG L 869.47 115/2+ -109AG B 246.6 200.0194 9 7.72 +109AG B 246.6 200.0194 9 7.72 109AGS B EAV=69.4 6 -109AG G 134.2 2 0.00111 10M1+E2 0.150 4 0.192 3 -109AG2 G KC=0.1658 25$LC=0.0212 4$MC=0.00404 6 -109AG G 145.1 2 0.00083 7 (M1+E2) 0.132 5 0.153 2 -109AG2 G KC=0.1326 20$LC=0.01670 25$MC=0.00318 5 -109AG G 454.3 3 0.00050 4 E1 0.002534 -109AG2 G KC=0.00222 4$LC=2.59E-4 4$MC=4.90E-5 7 -109AG G 558.1 2 0.00249 17E1(+M2) 0.260 3 0.002384 -109AG2 G KC=0.00207 4$LC=2.49E-4 4$MC=4.73E-5 8 -109AG G 736.7 2 0.00181 13E2 0.002214 -109AG2 G KC=0.00193 3$LC=2.36E-4 4$MC=4.48E-5 7 -109AG G 781.4 1 0.0123 9 M1+E2 -109AG G 869.5 1 5.3E-5 16M2(+E3) 0.004276 -109AG2 G KC=0.00372 6$LC=4.53E-4 7$MC=8.62E-5 13 +109AG G 134.2 2 0.00111 10M1+E2 0.150 4 0.192 3 +109AG2 G KC=0.1658 25$LC=0.0212 4$MC=0.00404 6 +109AG G 145.1 2 0.00083 7(M1+E2) 0.132 5 0.153 2 +109AG2 G KC=0.1326 20$LC=0.01670 25$MC=0.00318 5 +109AG G 454.3 3 0.00050 4E1 0.00253 4 +109AG2 G KC=0.00222 4$LC=2.59E-4 4$MC=4.90E-5 7 +109AG G 558.1 2 0.00249 17E1(+M2) 0.260 3 0.00238 4 +109AG2 G KC=0.00207 4$LC=2.49E-4 4$MC=4.73E-5 8 +109AG G 736.7 2 0.00181 13E2 0.00221 4 +109AG2 G KC=0.00193 3$LC=2.36E-4 4$MC=4.48E-5 7 +109AG G 781.4 1 0.0123 9M1+E2 +109AG G 869.5 1 0.00005316M2(+E3) 0.00427 6 +109AG2 G KC=0.00372 6$LC=4.53E-4 7$MC=8.62E-5 13 109AG L 911.0 4 7/2+ -109AG B 205.1 200.00166 17 8.53 2 +109AG B 205.1 200.00166 17 8.53 109AGS B EAV=56.7 6 109AG G 778.3 5 0.00148 17M1+E2 -109AG G 823.0 4 1.81E-4 18M1+E2 +109AG G 823.0 4 0.00018118M1+E2 109AG L 912.1 8 7/2- -109AG B 204.0 2274000E-914 9.87 1U +109AG B 204.0 220.00007414 9.87 1 109AGS B EAV=56.3 7 -109AG G 496.9 107.3E-5 14M1+E2 0.199 3 0.0062 1 -109AG2 G KC=0.00541 8$LC=6.44E-4 10$MC=1222E-7 18 +109AG G 496.9 100.00007314M1+E2 0.199 3 0.0062 1 +109AG2 G KC=0.00541 8$LC=6.44E-4 10$MC=1222E-7 18 109AG L 1098.5 2 5/2, 7/2+ -109AG B 17.6 200.00018 3 6.22 +109AG B 17.6 200.00018 3 6.22 109AGS B EAV=4.5 5 -109AG G 400.7 6 6.3E-5 23(M1+E2) +109AG G 400.7 6 0.00006323(M1+E2) 109AG G 787.1 3 2.16E-5 18(E1) 7.35E-411 -109AG2 G KC=6.44E-4 9$LC=7.43E-5 11$MC=1403E-8 20 -109AG G 965.8 3 6.8E-5 11 -109AG G 1010.5 2 3.0E-5 6 +109AG2 G KC=6.44E-4 9$LC=7.43E-5 11$MC=1403E-8 20 +109AG G 965.8 3 0.00006811 +109AG G 1010.5 2 0.000030 6 diff --git a/HEN_HOUSE/spectra/lnhb/Pm-147.txt b/HEN_HOUSE/spectra/lnhb/Pm-147.txt index a33b085b3..e38b1f914 100644 --- a/HEN_HOUSE/spectra/lnhb/Pm-147.txt +++ b/HEN_HOUSE/spectra/lnhb/Pm-147.txt @@ -21,41 +21,41 @@ 147SM6C 1970Gu14, 1970Va38, 1971Be53, 1971Mc09, 1973HaXY, 1987Al28, 1989Ad10, 147SM7C 1990Sc08, 1992Ma56, 1996Sc06, 2001Be81, 2003Au03, 2003Ki26, 2008Ki07, 147SM8C 2009Ko15, 2009Ni02 -147SM T Auger electrons and ^X ray energies and emission intensities: -147SM T {U Energy (keV)} {U Intensity } {U Line } +147SM T Auger electrons and X ray energies and emission intensities: +147SM T {U Energy (keV)} {U Intensity} {U Line} 147SM T -147SM T 39.5229 0.000583 16 XKA2 -147SM T 40.1186 0.001055 29 XKA1 +147SM T 39.5229 0.00058316 XKA2 +147SM T 40.1186 0.00105529 XKA1 147SM T -147SM T 45.289 |] XKB3 -147SM T 45.413 |] 0.00033 1 XKB1 -147SM T 45.731 |] XKB5II +147SM T 45.289 |] XKB3 +147SM T 45.413 |] 0.00033 1 XKB1 +147SM T 45.731 |] XKB5II 147SM T -147SM T 46.575 |] XKB2 -147SM T 46.705 |] 0.0000851 30 XKB4 -147SM T 46.813 |] XKO23 +147SM T 46.575 |] XKB2 +147SM T 46.705 |] 8.51E-5 30 XKB4 +147SM T 46.813 |] XKO23 147SM T -147SM T 4.991-7.487 0.000369 8 XL (total) -147SM T 4.991 0.00000720 24 XLL -147SM T 5.609-5.638 0.000177 6 XLA -147SM T 5.586 0.00000281 9 XLC -147SM T 6.193-6.656 0.000156 4 XLB -147SM T 6.964-7.487 0.0000254 7 XLG +147SM T 4.991-7.487 0.000369 8 XL (total) +147SM T 4.991 7.20E-6 24 XLL +147SM T 5.609-5.638 0.000177 6 XLA +147SM T 5.586 2.81E-6 9 XLC +147SM T 6.193-6.656 0.000156 4 XLB +147SM T 6.964-7.487 2.54E-5 7 XLG 147PM P 0.0 7/2+ 2.6234 Y 4 224.1 3 147SM N 1.0 1.0 1 1.0 147SM L 0 7/2- 107.9E9 Y 12 -147SM B 224.1 3 99995E-313 7.4 +147SM B 224.1 3 99.9945613 7.4 147SMS B EAV=61.8 1 147SM L 121.223 125/2- 0.798 NS 17 -147SM B 102.9 3 0.00542 13 10.6 1U +147SM B 102.9 3 0.00542 13 10.6 1 147SMS B EAV=26.9 1 -147SM G 121.223 120.00272 6 M1+E2 -0.317 19000 0.994 14 -147SM2 G KC=0.815 12$LC=0.141 4$MC=0.0308 8 +147SM G 121.223 120.00272 6M1+E2 -0.317 19000 0.994 14 +147SM2 G KC=0.815 12$LC=0.141 4$MC=0.0308 8 147SM L 197.298 113/2- 1.25 NS 3 -147SM B 26.8 3 40000E-17 12.1 3U +147SM B 26.8 3 4.0E-7 7 12.1 1U 147SMS B EAV=6.9 1 -147SM G 76.073 101.1E-8 2 M1+E2 0.655 34 4.53 9 -147SM2 G KC=2.91 5$LC=1.26 7$MC=0.288 15 -147SM G 197.298 113.3E-7 5 E2 0.218 3 -147SM2 G KC=0.1565 22$LC=0.0482 7$MC=0.01092 16 +147SM G 76.073 101.1E-8 2M1+E2 0.655 34 4.53 9 +147SM2 G KC=2.91 5$LC=1.26 7$MC=0.288 15 +147SM G 197.298 113.3E-7 5E2 0.218 3 +147SM2 G KC=0.1565 22$LC=0.0482 7$MC=0.01092 16 diff --git a/HEN_HOUSE/spectra/lnhb/Pm-148.txt b/HEN_HOUSE/spectra/lnhb/Pm-148.txt index dc1ca7b6b..81e464252 100644 --- a/HEN_HOUSE/spectra/lnhb/Pm-148.txt +++ b/HEN_HOUSE/spectra/lnhb/Pm-148.txt @@ -10,102 +10,102 @@ 148SM7C 1977Ka14, 1977La19, 1979Dz07, 1984LaZZ, 1988No02, 1989Le01, 1996Sc06, 148SM8C 1996FiZX, 1998ScZM, 1999ScZX, 2000Bh03, 2000Sc47, 2008DuZX, 2008Ki07, 148SM9C 2012Wa38 -148SM T Auger electrons and ^X ray energies and emission intensities: -148SM T {U Energy (keV)} {U Intensity } {U Line } +148SM T Auger electrons and X ray energies and emission intensities: +148SM T {U Energy (keV)} {U Intensity} {U Line} 148SM T -148SM T 39.5229 0.0581 16 XKA2 -148SM T 40.1186 0.1051 28 XKA1 +148SM T 39.5229 0.0581 16 XKA2 +148SM T 40.1186 0.1051 28 XKA1 148SM T -148SM T 45.289 |] XKB3 -148SM T 45.413 |] 0.0328 10 XKB1 -148SM T 45.731 |] XKB5II +148SM T 45.289 |] XKB3 +148SM T 45.413 |] 0.0328 10 XKB1 +148SM T 45.731 |] XKB5II 148SM T -148SM T 46.575 |] XKB2 -148SM T 46.705 |] 0.00847 30 XKB4 -148SM T 46.813 |] XKO23 +148SM T 46.575 |] XKB2 +148SM T 46.705 |] 0.00847 30 XKB4 +148SM T 46.813 |] XKO23 148SM T -148SM T 4.9909-7.4871 0.0363 8 XL (total) -148SM T 4.9909 0.000709 24 XLL -148SM T 5.6088-5.6376 0.0174 6 XLA -148SM T 5.586 0.000277 9 XLC -148SM T 6.1928-6.6557 0.0154 4 XLB -148SM T 6.9644-7.4871 0.00249 6 XLG +148SM T 4.9909-7.4871 0.0363 8 XL (total) +148SM T 4.9909 0.00070924 XLL +148SM T 5.6088-5.6376 0.0174 6 XLA +148SM T 5.586 0.000277 9 XLC +148SM T 6.1928-6.6557 0.0154 4 XLB +148SM T 6.9644-7.4871 0.00249 6 XLG 148SM T -148SM T 31.19-33.218 |] KLL AUGER -148SM T 37.302-40.097 |] 0.0163 10 ^KLX AUGER -148SM T 43.39-46.79 |] KXY AUGER -148SM T 3.27-7.69 0.1883 16 L AUGER +148SM T 31.19-33.218 |] KLL AUGER +148SM T 37.302-40.097 |] 0.0163 10 KLX AUGER +148SM T 43.39-46.79 |] KXY AUGER +148SM T 3.27-7.69 0.1883 16 L AUGER 148PM P 0.0 1- 5.370 D 15 2471 6 148SM N 1.0 1.0 1 1.0 148SM L 0 0+ STABLE -148SM B 2471 6 55.5 7 9.1 1 +148SM B 2471 6 55.5 7 9.1 1 148SMS B EAV=977.7 28 148SM L 550.274 172+ -148SM B 1921 6 9.3 6 9.5 1 +148SM B 1921 6 9.3 6 9.5 1 148SMS B EAV=731.6 27 -148SM G 550.27 3 22.5 6 E2 0.0099814 -148SM2 G KC=0.00825 12$LC=1360E-6 19$MC=2.96E-4 5 +148SM G 550.270 3022.5 6E2 0.0099814 +148SM2 G KC=0.00825 12$LC=1360E-6 19$MC=2.96E-4 5 148SM L 1161.537 243- -148SM G 611.26 3 1.04 4 E1+M2 0.026 13 0.002795 -148SM2 G KC=0.00239 5$LC=3.15E-4 6$MC=6.70E-5 13 +148SM G 611.260 301.04 4E1+M2 0.026 13 0.00279 5 +148SM2 G KC=0.00239 5$LC=3.15E-4 6$MC=6.70E-5 13 148SM L 1424.46 4 0+ -148SM B 1047 6 0.236 9 10.1 1 +148SM B 1047 6 0.236 9 10.1 1 148SMS B EAV=359.1 25 -148SM G 874.18 3 0.24 1 E2 0.003325 -148SM2 G KC=0.00280 4$LC=4.06E-4 6$MC=8.74E-5 13 +148SM G 874.180 300.24 1E2 0.00332 5 +148SM2 G KC=0.00280 4$LC=4.06E-4 6$MC=8.74E-5 13 148SM L 1454.217 232+ -148SM B 1017 6 0.093 3 10.4 1 +148SM B 1017 6 0.093 3 10.4 1 148SMS B EAV=347.1 25 -148SM G 903.94 3 0.042 2 M1+E2 2.32 10 0.003396 -148SM2 G KC=0.00287 5$LC=4.06E-4 7$MC=8.72E-5 14 -148SM G 1454.21 3 0.0511 25E2 1230E-618 -148SM2 G KC=1000E-6 14$LC=1338E-7 19$MC=2.86E-5 4 +148SM G 903.940 300.042 2M1+E2 2.32 10 0.00339 6 +148SM2 G KC=0.00287 5$LC=4.06E-4 7$MC=8.72E-5 14 +148SM G 1454.210 300.0511 25E2 1230E-618 +148SM2 G KC=1000E-6 14$LC=1338E-7 19$MC=2.86E-5 4 148SM L 1465.129 191- -148SM B 1006 6 33.3 6 7.8 +148SM B 1006 6 33.3 6 7.8 148SMS B EAV=342.7 24 -148SM G 303.59 3 0.0377 45E2 0.0542 8 -148SM2 G KC=0.0423 6$LC=0.00931 13$MC=0.00207 3 -148SM G 914.85 3 12.0 5 E1 1221E-617 -148SM2 G KC=1050E-6 15$LC=1354E-7 19$MC=2.88E-5 4 -148SM G 1465.12 3 22.2 5 E1 7.04E-410 -148SM2 G KC=4.49E-4 7$LC=5.70E-5 8$MC=1208E-8 17 +148SM G 303.590 300.0377 45E2 0.0542 8 +148SM2 G KC=0.0423 6$LC=0.00931 13$MC=0.00207 3 +148SM G 914.850 3012.0 5E1 1221E-617 +148SM2 G KC=1050E-6 15$LC=1354E-7 19$MC=2.88E-5 4 +148SM G 1465.120 3022.2 5E1 7.04E-410 +148SM2 G KC=4.49E-4 7$LC=5.70E-5 8$MC=1208E-8 17 148SM L 1664.160 212+ -148SM B 807 6 0.018 3 10.8 1 +148SM B 807 6 0.018 3 10.8 1 148SMS B EAV=264.4 23 -148SM G 1113.88 3 0.0222 23M1+E2 -0.565 21 0.002795 -148SM2 G KC=0.00239 4$LC=3.19E-4 5$MC=6.81E-5 10 -148SM G 1664.15 3 0.0113 11E2 1042E-615 -148SM2 G KC=7.75E-4 11$LC=1024E-7 15$MC=2.18E-5 3 +148SM G 1113.880 300.0222 23M1+E2 -0.565 21 0.00279 5 +148SM2 G KC=0.00239 4$LC=3.19E-4 5$MC=6.81E-5 10 +148SM G 1664.150 300.0113 11E2 1042E-615 +148SM2 G KC=7.75E-4 11$LC=1024E-7 15$MC=2.18E-5 3 148SM L 1921.58 200+ 148SM B 549 6 0.0138 14 10.3 1 148SMS B EAV=169.0 22 -148SM G 1371.3 2 0.0138 14E2 1347E-619 -148SM2 G KC=1119E-6 16$LC=1507E-7 22$MC=3.22E-5 5 +148SM G 1371.30 200.0138 14E2 1347E-619 +148SM2 G KC=1119E-6 16$LC=1507E-7 22$MC=3.22E-5 5 148SM L 2057.961 222- 148SM B 413 6 1.360 22 7.9 148SMS B EAV=121.9 21 -148SM G 393.80 3 0.0155 22E1 0.0075211 -148SM2 G KC=0.00643 9$LC=8.62E-4 12$MC=1.84E-4 3 -148SM G 592.83 3 0.35 1 M1 0.0140420 -148SM2 G KC=0.01198 17$LC=1621E-6 23$MC=3.47E-4 5 -148SM G 896.42 3 0.98 2 M1+E2 1.32 9 0.003869 -148SM2 G KC=0.00328 8$LC=4.56E-4 10$MC=9.77E-5 20 -148SM G 1507.68 3 0.0056 9 E1 7.11E-410 -148SM2 G KC=4.28E-4 6$LC=5.42E-5 8$MC=1150E-8 17 +148SM G 393.800 300.0155 22E1 0.0075211 +148SM2 G KC=0.00643 9$LC=8.62E-4 12$MC=1.84E-4 3 +148SM G 592.830 300.35 1M1 0.0140420 +148SM2 G KC=0.01198 17$LC=1621E-6 23$MC=3.47E-4 5 +148SM G 896.420 300.98 2M1+E2 1.32 9 0.00386 9 +148SM2 G KC=0.00328 8$LC=4.56E-4 10$MC=9.77E-5 20 +148SM G 1507.680 300.0056 9E1 7.11E-410 +148SM2 G KC=4.28E-4 6$LC=5.42E-5 8$MC=1150E-8 17 148SM L 2284.405 211- 148SM B 187 6 0.0965 34 7.9 148SMS B EAV=50.7 18 -148SM G 819.27 3 0.0133 22M1 0.006359 -148SM2 G KC=0.00542 8$LC=7.26E-4 11$MC=1551E-7 22 -148SM G 1734.12 3 0.0386 11E1 7.77E-411 -148SM2 G KC=3.39E-4 5$LC=4.28E-5 6$MC=9.07E-6 13 -148SM G 2284.39 3 0.0444 24E1 1027E-615 -148SM2 G KC=2.19E-4 3$LC=2.74E-5 4$MC=5.81E-6 9 +148SM G 819.270 300.0133 22M1 0.00635 9 +148SM2 G KC=0.00542 8$LC=7.26E-4 11$MC=1551E-7 22 +148SM G 1734.120 300.0386 11E1 7.77E-411 +148SM2 G KC=3.39E-4 5$LC=4.28E-5 6$MC=9.07E-6 13 +148SM G 2284.390 300.0444 24E1 1027E-615 +148SM2 G KC=2.19E-4 3$LC=2.74E-5 4$MC=5.81E-6 9 148SM L 2314.01 152+ 148SM B 157 6 0.0091 15 8.7 1 148SMS B EAV=42.1 18 -148SM G 1152.5 2 0.0029 13E1+M2 -0.10 9 0.0008615 -148SM2 G KC=0.00073 13$LC=9.5E-5 18$MC=2.0E-5 4 -148SM G 1763.7 2 0.0062 7 M1+E2 2.2 5 0.001043 -148SM2 G KC=7.32E-4 22$LC=9.6E-5 3$MC=2.05E-5 6 +148SM G 1152.50 200.0029 13E1+M2 -0.10 9 0.0008615 +148SM2 G KC=0.00073 13$LC=9.5E-5 18$MC=2.0E-5 4 +148SM G 1763.70 200.0062 7M1+E2 2.2 5 0.00104 3 +148SM2 G KC=7.32E-4 22$LC=9.6E-5 3$MC=2.05E-5 6 diff --git a/HEN_HOUSE/spectra/lnhb/Pm-148m.txt b/HEN_HOUSE/spectra/lnhb/Pm-148m.txt index 1a3f93ac5..f1f147b74 100644 --- a/HEN_HOUSE/spectra/lnhb/Pm-148m.txt +++ b/HEN_HOUSE/spectra/lnhb/Pm-148m.txt @@ -8,40 +8,40 @@ 148PM5C 1970Gr09, 1969Gr32, 1970FoZZ, 1971Mo04, 1971Wa05, 1971BaZW, 1974DuZO, 148PM6C 1977La19, 1977Ka14, 1984LaZZ, 1988No02, 1989Le01, 1996FiZX, 1996Sc06, 148PM7C 1998ScZM, 1999ScZX, 2000Bh03, 2000Sc47, 2008DuZX, 2008Ki07, 2012Wa38 -148PM T Auger electrons and ^X ray energies and emission intensities: -148PM T {U Energy (keV)} {U Intensity } {U Line } +148PM T Auger electrons and X ray energies and emission intensities: +148PM T {U Energy (keV)} {U Intensity} {U Line} 148PM T -148PM T 38.1716 0.96 6 XKA2 -148PM T 38.7251 1.75 11 XKA1 +148PM T 38.1716 0.96 6 XKA2 +148PM T 38.7251 1.75 11 XKA1 148PM T -148PM T 43.713 |] XKB3 -148PM T 43.826 |] 0.54 4 XKB1 -148PM T 44.145 |] XKB5II +148PM T 43.713 |] XKB3 +148PM T 43.826 |] 0.54 4 XKB1 +148PM T 44.145 |] XKB5II 148PM T -148PM T 44.937 |] XKB2 -148PM T 45.064 |] 0.139 9 XKB4 -148PM T 45.162 |] XKO23 +148PM T 44.937 |] XKB2 +148PM T 45.064 |] 0.139 9 XKB4 +148PM T 45.162 |] XKO23 148PM T -148PM T 4.81-7.1893 1.20 4 XL (total) -148PM T 4.81 0.0223 10 XLL -148PM T 5.4061-5.4325 0.554 22 XLA -148PM T 5.363 0.0107 5 XLC -148PM T 5.9552-6.3985 0.526 20 XLB -148PM T 6.6814-7.1893 0.083 4 XLG +148PM T 4.81-7.1893 1.20 4 XL (total) +148PM T 4.81 0.0223 10 XLL +148PM T 5.4061-5.4325 0.554 22 XLA +148PM T 5.363 0.0107 5 XLC +148PM T 5.9552-6.3985 0.526 20 XLB +148PM T 6.6814-7.1893 0.083 4 XLG 148PM T -148PM T 30.162-32.086 |] KLL AUGER -148PM T 36.035-38.703 |] 0.287 23 ^KLX AUGER -148PM T 41.88-45.14 |] KXY AUGER -148PM T 3.16-7.38 6.59 10 L AUGER +148PM T 30.162-32.086 |] KLL AUGER +148PM T 36.035-38.703 |] 0.287 23 KLX AUGER +148PM T 41.88-45.14 |] KXY AUGER +148PM T 3.16-7.38 6.59 10 L AUGER 148PM P 137 3 6- 41.29 D 13 148PM N 1.786E1 1.786E1 0.056 5 1.786E1 148PM L 0 1- 5.370 D 15 148PM L 75.8 2- -148PM G 75.8 1 1.27 20M1 3.4 5 -148PM2 G KC=2.9 4$LC=0.41 6$MC=0.088 11 +148PM G 75.8 1 1.27 20M1 3.4 5 +148PM2 G KC=2.9 4$LC=0.41 6$MC=0.088 11 148PM L 137.1 306- 41.29 D 13 -148PM G 61.30 5 0.00040 17E4 1.4E4 6 -148PM2 G KC=30 5$LC=1.0E4 4$MC=2.9E3 12 +148PM G 61.30 5 0.00040 17E4 1.4E4 6 +148PM2 G KC=30 5$LC=1.0E4 4$MC=2.9E3 12 148SM 148PM B- DECAY (41.29 D) 148SM H TYP=FULL$AUT=M.A.Kellett$CUT=05-JUN-2013$ @@ -53,91 +53,91 @@ 148SM5C 1970Gr09, 1969Gr32, 1970FoZZ, 1971Mo04, 1971Wa05, 1971BaZW, 1974DuZO, 148SM6C 1977La19, 1977Ka14, 1984LaZZ, 1988No02, 1989Le01, 1996FiZX, 1996Sc06, 148SM7C 1998ScZM, 1999ScZX, 2000Bh03, 2000Sc47, 2008DuZX, 2008Ki07, 2012Wa38 -148SM T Auger electrons and ^X ray energies and emission intensities: -148SM T {U Energy (keV)} {U Intensity } {U Line } +148SM T Auger electrons and X ray energies and emission intensities: +148SM T {U Energy (keV)} {U Intensity} {U Line} 148SM T -148SM T 39.5229 1.92 11 XKA2 -148SM T 40.1186 3.47 19 XKA1 +148SM T 39.5229 1.92 11 XKA2 +148SM T 40.1186 3.47 19 XKA1 148SM T -148SM T 45.289 |] XKB3 -148SM T 45.413 |] 1.09 6 XKB1 -148SM T 45.731 |] XKB5II +148SM T 45.289 |] XKB3 +148SM T 45.413 |] 1.09 6 XKB1 +148SM T 45.731 |] XKB5II 148SM T -148SM T 46.575 |] XKB2 -148SM T 46.705 |] 0.280 17 XKB4 -148SM T 46.813 |] XKO23 +148SM T 46.575 |] XKB2 +148SM T 46.705 |] 0.280 17 XKB4 +148SM T 46.813 |] XKO23 148SM T -148SM T 4.9909-7.4871 1.20 4 XL (total) -148SM T 4.9909 0.0234 12 XLL -148SM T 5.6088-5.6376 0.576 27 XLA -148SM T 5.586 0.0091 5 XLC -148SM T 6.1928-6.6557 0.508 19 XLB -148SM T 6.9644-7.4871 0.082 4 XLG +148SM T 4.9909-7.4871 1.20 4 XL (total) +148SM T 4.9909 0.0234 12 XLL +148SM T 5.6088-5.6376 0.576 27 XLA +148SM T 5.586 0.0091 5 XLC +148SM T 6.1928-6.6557 0.508 19 XLB +148SM T 6.9644-7.4871 0.082 4 XLG 148SM T -148SM T 31.19-33.218 |] KLL AUGER -148SM T 37.302-40.097 |] 0.54 5 ^KLX AUGER -148SM T 43.39-46.79 |] KXY AUGER -148SM T 3.27-7.69 6.23 10 L AUGER +148SM T 31.19-33.218 |] KLL AUGER +148SM T 37.302-40.097 |] 0.54 5 KLX AUGER +148SM T 43.39-46.79 |] KXY AUGER +148SM T 3.27-7.69 6.23 10 L AUGER 148PM P 137 3 6- 41.29 D 13 2471 7 148SM N 1.059E0 1.059E0 0.944 5 1.059E0 148SM L 0 0+ STABLE 148SM L 550.27 3 2+ 148SM G 550.27 3 93.5 14E2 0.0099814 -148SM2 G KC=0.00825 12$LC=1360E-6 19$MC=2.96E-4 5 +148SM2 G KC=0.00825 12$LC=1360E-6 19$MC=2.96E-4 5 148SM L 1161.53 4 3- -148SM G 611.26 3 5.6 2 E1 0.002774 -148SM2 G KC=0.00237 4$LC=3.12E-4 5$MC=6.63E-5 10 +148SM G 611.26 3 5.6 2E1 0.00277 4 +148SM2 G KC=0.00237 4$LC=3.12E-4 5$MC=6.63E-5 10 148SM L 1180.24 4 4+ -148SM G 629.97 3 87.8 14E2 0.0071 1 -148SM2 G KC=0.00591 9$LC=9.32E-4 13$MC=2.02E-4 3 +148SM G 629.97 3 87.8 14E2 0.0071 1 +148SM2 G KC=0.00591 9$LC=9.32E-4 13$MC=2.02E-4 3 148SM L 1594.31 4 5- 148SM B 1014 6 0.93 45 10.29 148SMS B EAV=345.9 31 148SM G 414.07 3 18.35 33E1+M2 -0.013 10 0.0067011 -148SM2 G KC=0.00572 9$LC=7.66E-4 13$MC=1.63E-4 3 -148SM G 432.78 3 5.19 13E2 0.0190 3 -148SM2 G KC=0.01544 22$LC=0.00281 4$MC=6.17E-4 9 +148SM2 G KC=0.00572 9$LC=7.66E-4 13$MC=1.63E-4 3 +148SM G 432.78 3 5.19 13E2 0.0190 3 +148SM2 G KC=0.01544 22$LC=0.00281 4$MC=6.17E-4 9 148SM L 1733.48 4 4+ -148SM G 553.24 3 0.35 4 M1+E2 1.66 20 0.0117 4 -148SM2 G KC=0.0098 4$LC=0.00150 4$MC=3.24E-4 8 -148SM G 571.95 3 0.211 7 E1 0.003205 -148SM2 G KC=0.00274 4$LC=3.61E-4 5$MC=7.68E-5 11 +148SM G 553.24 3 0.35 4M1+E2 1.66 20 0.0117 4 +148SM2 G KC=0.0098 4$LC=0.00150 4$MC=3.24E-4 8 +148SM G 571.95 3 0.211 7E1 0.00320 5 +148SM2 G KC=0.00274 4$LC=3.61E-4 5$MC=7.68E-5 11 148SM L 1894.93 124+ -148SM G 714.7 2 0.045 5 M1+E2 0.0070 18 -148SM2 G KC=0.0060 16$LC=0.00084 18$MC=0.00018 4 -148SM G 1344.6 2 0.057 5 E2 1392E-620 -148SM2 G KC=1162E-6 17$LC=1570E-7 22$MC=3.35E-5 5 +148SM G 714.70 200.045 5M1+E2 0.0070 18 +148SM2 G KC=0.0060 16$LC=0.00084 18$MC=0.00018 4 +148SM G 1344.60 200.057 5E2 1392E-620 +148SM2 G KC=1162E-6 17$LC=1570E-7 22$MC=3.35E-5 5 148SM L 1905.94 5 6+ -148SM B 702 6 21.8 7 8.35 +148SM B 702 6 21.8 7 8.35 148SMS B EAV=224.7 29 148SM G 311.63 3 3.77 11E1 0.0133719 -148SM2 G KC=0.01141 16$LC=1546E-6 22$MC=3.30E-4 5 -148SM G 725.70 3 32.3 6 E2 0.005067 -148SM2 G KC=0.00424 6$LC=6.42E-4 9$MC=1389E-7 20 +148SM2 G KC=0.01141 16$LC=1546E-6 22$MC=3.30E-4 5 +148SM G 725.70 3 32.3 6E2 0.00506 7 +148SM2 G KC=0.00424 6$LC=6.42E-4 9$MC=1389E-7 20 148SM L 2095.57 4 6+ -148SM B 513 6 18.1 9 7.96 +148SM B 513 6 18.1 9 7.96 148SMS B EAV=156.0 27 -148SM G 189.63 3 1.15 6 E2 0.249 4 -148SM2 G KC=0.1769 25$LC=0.0565 8$MC=0.01284 18 -148SM G 362.09 3 0.171 13E2 0.0318 5 -148SM2 G KC=0.0253 4$LC=0.00504 7$MC=1114E-6 16 -148SM G 501.26 3 6.59 11E1+M2 -0.017 14 0.004318 -148SM2 G KC=0.00369 7$LC=4.89E-4 9$MC=1042E-7 20 -148SM G 915.33 3 17.9 5 E2 0.003005 -148SM2 G KC=0.00254 4$LC=3.64E-4 6$MC=7.83E-5 11 +148SM G 189.63 3 1.15 6E2 0.249 4 +148SM2 G KC=0.1769 25$LC=0.0565 8$MC=0.01284 18 +148SM G 362.09 3 0.171 13E2 0.0318 5 +148SM2 G KC=0.0253 4$LC=0.00504 7$MC=1114E-6 16 +148SM G 501.26 3 6.59 11E1+M2 -0.017 14 0.00431 8 +148SM2 G KC=0.00369 7$LC=4.89E-4 9$MC=1042E-7 20 +148SM G 915.33 3 17.9 5E2 0.00300 5 +148SM2 G KC=0.00254 4$LC=3.64E-4 6$MC=7.83E-5 11 148SM L 2194.05 4 6+ -148SM B 414 6 54.0 9 7.18 +148SM B 414 6 54.0 9 7.18 148SMS B EAV=122.3 26 -148SM G 98.48 3 2.92 26M1+E2 0.18 1.79 3 -148SM2 G KC=1.488 21$LC=0.236 4$MC=0.0511 8 -148SM G 288.11 3 12.0 4 M1+E2 0.088 21 0.0898 13 -148SM2 G KC=0.0763 11$LC=0.01062 15$MC=0.00228 4 -148SM G 299.1 2 0.13 4 E2 0.0567 8 -148SM2 G KC=0.0442 7$LC=0.00982 14$MC=0.00219 3 -148SM G 460.57 3 0.40 1 E2 0.0160123 -148SM2 G KC=0.01306 19$LC=0.00231 4$MC=5.07E-4 7 -148SM G 599.74 3 12.35 22E1+M2 -0.021 11 0.002905 -148SM2 G KC=0.00249 4$LC=3.27E-4 6$MC=6.96E-5 12 -148SM G 1013.81 3 19.8 4 E2+M3 -0.025 14 0.002434 -148SM2 G KC=0.00206 4$LC=2.90E-4 5$MC=6.22E-5 10 +148SM G 98.48 3 2.92 26M1+E2 0.18 1.79 3 +148SM2 G KC=1.488 21$LC=0.236 4$MC=0.0511 8 +148SM G 288.11 3 12.0 4M1+E2 0.088 21 0.0898 13 +148SM2 G KC=0.0763 11$LC=0.01062 15$MC=0.00228 4 +148SM G 299.10 200.13 4E2 0.0567 8 +148SM2 G KC=0.0442 7$LC=0.00982 14$MC=0.00219 3 +148SM G 460.57 3 0.40 1E2 0.0160123 +148SM2 G KC=0.01306 19$LC=0.00231 4$MC=5.07E-4 7 +148SM G 599.74 3 12.35 22E1+M2 -0.021 11 0.00290 5 +148SM2 G KC=0.00249 4$LC=3.27E-4 6$MC=6.96E-5 12 +148SM G 1013.81 3 19.8 4E2+M3 -0.025 14 0.00243 4 +148SM2 G KC=0.00206 4$LC=2.90E-4 5$MC=6.22E-5 10 diff --git a/HEN_HOUSE/spectra/lnhb/Po-209.txt b/HEN_HOUSE/spectra/lnhb/Po-209.txt index 66023ea74..0303dc125 100644 --- a/HEN_HOUSE/spectra/lnhb/Po-209.txt +++ b/HEN_HOUSE/spectra/lnhb/Po-209.txt @@ -3,70 +3,70 @@ 209BI C Evaluation history: Type=Full;Author=V. Chisté;Cutoff date=30-SEP-2009 209BI C References: 1956An05, 1966Ha29, 1971Jo06, 1980Sc26, 1989Ma05, 1991Ma16, 209BI2C 1996Sc24, 1996Sc06, 2003Au03, 2004Ko28, 2007Co07, 2008Ki07 -209BI T Auger electrons and ^X ray energies and emission intensities: -209BI T {U Energy (keV)} {U Intensity } {U Line } +209BI T Auger electrons and X ray energies and emission intensities: +209BI T {U Energy (keV)} {U Intensity} {U Line} 209BI T -209BI T 74.8157 0.0927 16 XKA2 -209BI T 77.1088 0.1551 25 XKA1 +209BI T 74.8157 0.0927 16 XKA2 +209BI T 77.1088 0.1551 25 XKA1 209BI T -209BI T 86.835 |] XKB3 -209BI T 87.344 |] 0.0531 12 XKB1 -209BI T 87.862 |] XKB5II +209BI T 86.835 |] XKB3 +209BI T 87.344 |] 0.0531 12 XKB1 +209BI T 87.862 |] XKB5II 209BI T -209BI T 89.732 |] XKB2 -209BI T 90.074 |] 0.0163 5 XKB4 -209BI T 90.421 |] XKO23 +209BI T 89.732 |] XKB2 +209BI T 90.074 |] 0.0163 5 XKB4 +209BI T 90.421 |] XKO23 209BI T -209BI T 9.4207-15.7084 0.1411 24 XL (total) -209BI T 9.4207 0.00357 10 XLL -209BI T 10.7308-10.8387 0.0667 16 XLA -209BI T 11.7127 0.000975 27 XLC -209BI T 12.4814-13.8066 0.0585 11 XLB -209BI T 14.7735-15.7084 0.01130 22 XLG +209BI T 9.4207-15.7084 0.1411 24 XL (total) +209BI T 9.4207 0.00357 10 XLL +209BI T 10.7308-10.8387 0.0667 16 XLA +209BI T 11.7127 0.00097527 XLC +209BI T 12.4814-13.8066 0.0585 11 XLB +209BI T 14.7735-15.7084 0.01130 22 XLG 209BI T -209BI T 57.491-63.419 |] KLL AUGER -209BI T 70.025-77.105 |] 0.0118 14 ^KLX AUGER -209BI T 82.53-90.52 |] KXY AUGER -209BI T 5.42-16.34 0.2240 27 L AUGER +209BI T 57.491-63.419 |] KLL AUGER +209BI T 70.025-77.105 |] 0.0118 14 KLX AUGER +209BI T 82.53-90.52 |] KXY AUGER +209BI T 5.42-16.34 0.2240 27 L AUGER 209PO P 0.0 1/2- 115 Y 13 1892.5 16 209BI N 2.203E2 2.203E2 0.00454 2.203E2 209BI L 0 9/2- 19E18 Y 2 209BI L 896.29 5 7/2- 9.7 PS 11 -209BI E 0.454 7 14.36 -209BI2 E EAV= $CK=0.70796 22$CL=0.21518 16$CM=0.07686 7$CN= $CO=0 0 -209BI G 896.28 6 0.445 7 M1+E2 -0.62 4 0.0208 6 -209BI2 G KC=0.0170 5$LC=0.00292 7$MC=6.87E-4 16 +209BI E 0.454 714.36 2U +209BI2 E CK=0.70796 22$CL=0.21518 16$CM=0.07686 7$CO=0 0 +209BI G 896.28 6 0.445 7M1+E2 -0.62 4 0.0208 6 +209BI2 G KC=0.0170 5$LC=0.00292 7$MC=6.87E-4 16 205PB 209PO A DECAY (115 Y) 205PB H TYP=Full$AUT=V. Chisté$CUT=30-SEP-2009$ 205PB C Evaluation history: Type=Full;Author=V. Chisté;Cutoff date=30-SEP-2009 205PB C References: 1956An05, 1966Ha29, 1971Jo06, 1980Sc26, 1989Ma05, 1991Ma16, 205PB2C 1996Sc24, 1996Sc06, 2003Au03, 2004Ko28, 2007Co07, 2008Ki07 -205PB T Auger electrons and ^X ray energies and emission intensities: -205PB T {U Energy (keV)} {U Intensity } {U Line } +205PB T Auger electrons and X ray energies and emission intensities: +205PB T {U Energy (keV)} {U Intensity} {U Line} 205PB T -205PB T 72.8049 0.0478 11 XKA2 -205PB T 74.97 0.0804 18 XKA1 +205PB T 72.8049 0.0478 11 XKA2 +205PB T 74.97 0.0804 18 XKA1 205PB T -205PB T 84.451 |] XKB3 -205PB T 84.937 |] 0.0275 8 XKB1 -205PB T 85.47 |] XKB5II +205PB T 84.451 |] XKB3 +205PB T 84.937 |] 0.0275 8 XKB1 +205PB T 85.47 |] XKB5II 205PB T -205PB T 87.238 |] XKB2 -205PB T 87.58 |] 0.00830 26 XKB4 -205PB T 87.911 |] XKO23 +205PB T 87.238 |] XKB2 +205PB T 87.58 |] 0.00830 26 XKB4 +205PB T 87.911 |] XKO23 205PB T -205PB T 9.186-15.2169 0.0631 13 XL (total) -205PB T 9.186 0.00156 5 XLL -205PB T 10.4495-10.5512 0.0296 8 XLA -205PB T 11.3495 0.000473 15 XLC -205PB T 12.1443-12.7953 0.0264 6 XLB -205PB T 14.3078-15.2169 0.00501 12 XLG +205PB T 9.186-15.2169 0.0631 13 XL (total) +205PB T 9.186 0.00156 5 XLL +205PB T 10.4495-10.5512 0.0296 8 XLA +205PB T 11.3495 0.00047315 XLC +205PB T 12.1443-12.7953 0.0264 6 XLB +205PB T 14.3078-15.2169 0.00501 12 XLG 205PB T -205PB T 56.028-61.669 |] KLL AUGER -205PB T 68.181-74.969 |] 0.0063 7 ^KLX AUGER -205PB T 80.3-88 |] KXY AUGER -205PB T 5.33-15.82 0.1044 14 L AUGER +205PB T 56.028-61.669 |] KLL AUGER +205PB T 68.181-74.969 |] 0.0063 7 KLX AUGER +205PB T 80.3-88 |] KXY AUGER +205PB T 5.33-15.82 0.1044 14 L AUGER 209PO P 0.0 1/2- 115 Y 13 4979.2 14 205PB N 1.005E0 1.005E0 0.99546 1.005E0 205PB L 0 5/2- 17.3E6 Y 7 @@ -76,8 +76,8 @@ 205PB G 2.328 7 205PB L 262.833 253/2- 205PB A 4622 5 0.550 7 4.5 -205PB G 260.50 5 0.254 3 M1+E2 0.16 6 0.617 13 -205PB2 G KC=0.503 12$LC=0.0874 14$MC=0.0205 3 -205PB G 262.80 5 0.085 2 M1+E2 0.05 7 0.612 10 -205PB2 G KC=0.500 9$LC=0.0857 13$MC=0.0201 3 +205PB G 260.50 5 0.254 3M1+E2 0.16 6 0.617 13 +205PB2 G KC=0.503 12$LC=0.0874 14$MC=0.0205 3 +205PB G 262.80 5 0.085 2M1+E2 0.05 7 0.612 10 +205PB2 G KC=0.500 9$LC=0.0857 13$MC=0.0201 3 diff --git a/HEN_HOUSE/spectra/lnhb/Po-210.txt b/HEN_HOUSE/spectra/lnhb/Po-210.txt index a4fdf26f7..54746d775 100644 --- a/HEN_HOUSE/spectra/lnhb/Po-210.txt +++ b/HEN_HOUSE/spectra/lnhb/Po-210.txt @@ -10,37 +10,37 @@ 206PB5C 1961Be13, 1962Br22, 1964EiZZ, 1972KA30, 1972MA63, 1973Go39, 1977DR08, 206PB6C 1989MA05, 1990He18, 1991Ry01, 1996RA16, 1996Sc06, 1999Br39, 2002Ba85, 206PB7C 2003Au03, 2008KI07, 2008Ko21, 2012Wa38 -206PB T Auger electrons and ^X ray energies and emission intensities: -206PB T {U Energy (keV)} {U Intensity } {U Line } +206PB T Auger electrons and X ray energies and emission intensities: +206PB T {U Energy (keV)} {U Intensity} {U Line} 206PB T -206PB T 72.805 0.00000277 11 XKA2 -206PB T 74.97 0.00000466 17 XKA1 +206PB T 72.805 2.77E-6 11 XKA2 +206PB T 74.97 4.66E-6 17 XKA1 206PB T -206PB T 84.451 |] XKB3 -206PB T 84.937 |] 0.00000159 7 XKB1 -206PB T 85.47 |] XKB5II +206PB T 84.451 |] XKB3 +206PB T 84.937 |] 1.59E-6 7 XKB1 +206PB T 85.47 |] XKB5II 206PB T -206PB T 87.238 |] XKB2 -206PB T 87.58 |] 0.000000481 21 XKB4 -206PB T 87.911 |] XKO23 +206PB T 87.238 |] XKB2 +206PB T 87.58 |] 4.81E-7 21 XKB4 +206PB T 87.911 |] XKO23 206PB T -206PB T 9.186-15.217 0.00000384 10 XL (total) -206PB T 9.186 0.000000093 4 XLL -206PB T 10.449-10.551 0.00000175 6 XLA -206PB T 11.349 0.0000000306 12XLC -206PB T 12.144-13.377 0.00000165 5 XLB -206PB T 14.308-15.217 0.000000318 10 XLG +206PB T 9.186-15.217 3.84E-6 10 XL (total) +206PB T 9.186 9.3E-8 4 XLL +206PB T 10.449-10.551 1.75E-6 6 XLA +206PB T 11.349 3.06E-8 12 XLC +206PB T 12.144-13.377 1.65E-6 5 XLB +206PB T 14.308-15.217 3.18E-7 10 XLG 206PB T -206PB T 56.028-61.669 |] KLL AUGER -206PB T 68.181-74.969 |] 0.00000037 5 ^KLX AUGER -206PB T 80.3-88 |] KXY AUGER -206PB T 5.3338-15.8198 0.00000631 11 L AUGER +206PB T 56.028-61.669 |] KLL AUGER +206PB T 68.181-74.969 |] 3.7E-7 5 KLX AUGER +206PB T 80.3-88 |] KXY AUGER +206PB T 5.3338-15.8198 6.31E-6 11 L AUGER 210PO P 0.0 0+ 138.3763 D17 5407.45 7 206PB N 1.0 1.0 1 1.0 206PB L 0 0+ STABLE 206PB A 5304.33 7 99999E-34 1 206PB L 803.052 242+ 8.30 PS 25 206PB A 4516.70 9 0.00124 4 1.46 -206PB G 803.052 240.00123 4 E2 0.0103215 -206PB2 G KC=0.00803 12$LC=1742E-6 25$MC=4.19E-4 6 +206PB G 803.052 240.00123 4E2 0.0103215 +206PB2 G KC=0.00803 12$LC=1742E-6 25$MC=4.19E-4 6 diff --git a/HEN_HOUSE/spectra/lnhb/Po-211.txt b/HEN_HOUSE/spectra/lnhb/Po-211.txt index 490503c74..fed40a242 100644 --- a/HEN_HOUSE/spectra/lnhb/Po-211.txt +++ b/HEN_HOUSE/spectra/lnhb/Po-211.txt @@ -7,43 +7,43 @@ 207PB2C 1954Sp32, 1954Wi26, 1958To25, 1962Wa18, 1963Jo09, 1968GuZX, 1968Br17, 207PB3C 1969Go23, 1969Ha32, 1970Va13, 1974Ba29, 1975Ja04, 1978Ya04, 1982Bo04, 207PB4C 1985La17, 1991Ry01, 1996Sc06, 2003Au03, 2008Ki07 -207PB T Auger electrons and ^X ray energies and emission intensities: -207PB T {U Energy (keV)} {U Intensity } {U Line } +207PB T Auger electrons and X ray energies and emission intensities: +207PB T {U Energy (keV)} {U Intensity} {U Line} 207PB T -207PB T 72.8049 0.00535 14 XKA2 -207PB T 74.97 0.00900 24 XKA1 +207PB T 72.8049 0.00535 14 XKA2 +207PB T 74.97 0.00900 24 XKA1 207PB T -207PB T 84.451 |] XKB3 -207PB T 84.937 |] 0.00308 10 XKB1 -207PB T 85.47 |] XKB5II +207PB T 84.451 |] XKB3 +207PB T 84.937 |] 0.00308 10 XKB1 +207PB T 85.47 |] XKB5II 207PB T -207PB T 87.238 |] XKB2 -207PB T 87.58 |] 0.00093 4 XKB4 -207PB T 87.911 |] XKO23 +207PB T 87.238 |] XKB2 +207PB T 87.58 |] 0.00093 4 XKB4 +207PB T 87.911 |] XKO23 207PB T -207PB T 9.186-15.2169 0.00740 16 XL (total) -207PB T 9.186 0.000179 6 XLL -207PB T 10.4495-10.5512 0.00339 10 XLA -207PB T 11.3495 0.0000583 19 XLC -207PB T 12.1443-13.3763 0.00317 8 XLB -207PB T 14.3078-15.2169 0.000608 15 XLG +207PB T 9.186-15.2169 0.00740 16 XL (total) +207PB T 9.186 0.000179 6 XLL +207PB T 10.4495-10.5512 0.00339 10 XLA +207PB T 11.3495 5.83E-5 19 XLC +207PB T 12.1443-13.3763 0.00317 8 XLB +207PB T 14.3078-15.2169 0.00060815 XLG 207PB T -207PB T 56.028-61.669 |] KLL AUGER -207PB T 68.181-74.969 |] 0.00071 8 ^KLX AUGER -207PB T 80.3-88 |] KXY AUGER -207PB T 5.33-15.82 0.01216 17 L AUGER +207PB T 56.028-61.669 |] KLL AUGER +207PB T 68.181-74.969 |] 0.00071 8 KLX AUGER +207PB T 80.3-88 |] KXY AUGER +207PB T 5.33-15.82 0.01216 17 L AUGER 211PO P 0.0 9/2+ 0.516 S 3 7594.5 5 207PB N 1.0 1.0 1 1.0 207PB L 0 1/2- STABLE 207PB A 7450.2 3 98.936 19112 207PB L 569.65 105/2- 207PB A 6891.2 100.541 17272 -207PB G 569.65 150.534 17E2 0.0216 3 -207PB2 G KC=0.01583 23$LC=0.00439 7$MC=1081E-6 16 +207PB G 569.65 150.534 17E2 0.0216 3 +207PB2 G KC=0.01583 23$LC=0.00439 7$MC=1081E-6 16 207PB L 897.8 1 3/2- 207PB A 6568.4 100.523 9 17.9 -207PB G 328.2 2 0.0032 11M1 0.334 5 -207PB2 G KC=0.273 4$LC=0.0465 7$MC=0.01089 16 -207PB G 897.8 2 0.507 9 M1+E2 0.092 10 0.0233 4 -207PB2 G KC=0.0192 3$LC=0.00318 5$MC=7.41E-4 11 +207PB G 328.2 2 0.0032 11M1 0.334 5 +207PB2 G KC=0.273 4$LC=0.0465 7$MC=0.01089 16 +207PB G 897.8 2 0.507 9M1+E2 0.092 10 0.0233 4 +207PB2 G KC=0.0192 3$LC=0.00318 5$MC=7.41E-4 11 diff --git a/HEN_HOUSE/spectra/lnhb/Po-212.txt b/HEN_HOUSE/spectra/lnhb/Po-212.txt index 623dd3269..330be907c 100644 --- a/HEN_HOUSE/spectra/lnhb/Po-212.txt +++ b/HEN_HOUSE/spectra/lnhb/Po-212.txt @@ -5,8 +5,8 @@ 208PB2C Type=Full;Author=A.L. Nichols;Cutoff date=30-DEC-2003 208PB C References: 1949Bu09, 1962Fl03, 1963As02, 1972Mc29, 1975Sa06, 1981Bo29, 208PB2C 2003Au03, 2005Br03 -208PB T Auger electrons and ^X ray energies and emission intensities: -208PB T {U Energy (keV)} {U Intensity } {U Line } +208PB T Auger electrons and X ray energies and emission intensities: +208PB T {U Energy (keV)} {U Intensity} {U Line} 208PB T 208PB T 208PB T diff --git a/HEN_HOUSE/spectra/lnhb/Po-213.txt b/HEN_HOUSE/spectra/lnhb/Po-213.txt index 89b0ae8df..ca76d14bd 100644 --- a/HEN_HOUSE/spectra/lnhb/Po-213.txt +++ b/HEN_HOUSE/spectra/lnhb/Po-213.txt @@ -1,8 +1,8 @@ 209PB 213PO A DECAY (3.70 US) 209PB H TYP=Full$AUT=Huang Xiaolong$CUT=31-DEC-2007$ 209PB C Evaluation history: Type=Full;Author=Huang Xiaolong;Cutoff date=31-DEC-2007 -209PB T Auger electrons and ^X ray energies and emission intensities: -209PB T {U Energy (keV)} {U Intensity } {U Line } +209PB T Auger electrons and X ray energies and emission intensities: +209PB T {U Energy (keV)} {U Intensity} {U Line} 209PB T 209PB T 209PB T @@ -14,6 +14,6 @@ 209PB A 8375.9 2599.9950 5 1.238 209PB L 778.8 3 11/2+ 209PB A 7614 100.0050 5 185 -209PB G 778.8 3 0.0048 5 M1 0.0339 5 -209PB2 G KC=0.0278 4$LC=0.00462 7$MC=1079E-6 16 +209PB G 778.8 3 0.0048 5M1 0.0339 5 +209PB2 G KC=0.0278 4$LC=0.00462 7$MC=1079E-6 16 diff --git a/HEN_HOUSE/spectra/lnhb/Po-214.txt b/HEN_HOUSE/spectra/lnhb/Po-214.txt index d60fa6f9b..39fdc16f0 100644 --- a/HEN_HOUSE/spectra/lnhb/Po-214.txt +++ b/HEN_HOUSE/spectra/lnhb/Po-214.txt @@ -4,36 +4,36 @@ 210PB C References: 1942Wa04, 1950Vo02, 1953Ba60, 1960Og01, 1961Ry02, 1961Do02, 210PB2C 1969Pe17, 1971Gr17, 1971Er02, 1976Ku08, 1990Ho28, 1992Br01, 1993Zh30, 210PB3C 1991Ry01, 1995El07, 1996Sc06, 1998Ak04, 2002Ba85, 2003Au03, 2003Br13 -210PB T Auger electrons and ^X ray energies and emission intensities: -210PB T {U Energy (keV)} {U Intensity } {U Line } +210PB T Auger electrons and X ray energies and emission intensities: +210PB T {U Energy (keV)} {U Intensity} {U Line} 210PB T -210PB T 72.8049 0.0000246 15 XKA2 -210PB T 74.97 0.0000414 25 XKA1 +210PB T 72.8049 2.46E-5 15 XKA2 +210PB T 74.97 4.14E-5 25 XKA1 210PB T -210PB T 84.451 |] XKB3 -210PB T 84.937 |] 0.0000141 9 XKB1 -210PB T 85.47 |] XKB5II +210PB T 84.451 |] XKB3 +210PB T 84.937 |] 1.41E-5 9 XKB1 +210PB T 85.47 |] XKB5II 210PB T -210PB T 87.238 |] XKB2 -210PB T 87.58 |] 0.00000427 27 XKB4 -210PB T 87.911 |] XKO23 +210PB T 87.238 |] XKB2 +210PB T 87.58 |] 4.27E-6 27 XKB4 +210PB T 87.911 |] XKO23 210PB T -210PB T 9.19-15.22 0.0000347 13 XL (total) -210PB T 9.19 0.00000083 5 XLL -210PB T 10.4495-10.5512 0.0000157 8 XLA -210PB T 11.3495 0.000000279 16 XLC -210PB T 12.1443-12.7953 0.0000150 6 XLB -210PB T 14.3078-15.22 0.00000289 12 XLG +210PB T 9.19-15.22 3.47E-5 13 XL (total) +210PB T 9.19 8.3E-7 5 XLL +210PB T 10.4495-10.5512 1.57E-5 8 XLA +210PB T 11.3495 2.79E-7 16 XLC +210PB T 12.1443-12.7953 1.50E-5 6 XLB +210PB T 14.3078-15.22 2.89E-6 12 XLG 214PO P 0.0 0+ 162.3 US 12 7833.46 6 210PB N 1.0 1.0 1 1.0 210PB L 0 0+ 22.23 Y 12 210PB A 7686.82 6 99.9895 7 1 210PB L 799.7 2 2+ 17 PS 5 210PB A 6902.6 3 0.0105 7 27 -210PB G 799.7 1 0.0104 6 E2 0.0104215 -210PB2 G KC=0.00810 12$LC=1763E-6 25$MC=4.25E-4 6 +210PB G 799.7 1 0.0104 6E2 0.0104215 +210PB2 G KC=0.00810 12$LC=1763E-6 25$MC=4.25E-4 6 210PB L 1097.7 104+ 0.6 NS 1 210PB A 6610.1 1058000E-92 400 -210PB G 298 1 5.2E-5 18E2 0.1180 21 -210PB2 G KC=0.0661 11$LC=0.0389 8$MC=0.00999 20 +210PB G 298 1 0.00005218E2 0.1180 21 +210PB2 G KC=0.0661 11$LC=0.0389 8$MC=0.00999 20 diff --git a/HEN_HOUSE/spectra/lnhb/Po-215.txt b/HEN_HOUSE/spectra/lnhb/Po-215.txt index cbeb00797..0955c0de6 100644 --- a/HEN_HOUSE/spectra/lnhb/Po-215.txt +++ b/HEN_HOUSE/spectra/lnhb/Po-215.txt @@ -4,39 +4,39 @@ 211PB C References: 1942Wa04, 1950Av61, 1961Vo06, 1962Wa18, 1965Va10, 1968Br17, 211PB2C 1970Da09, 1971Gr17, 1971Er02, 1977Ma29, 1991Ry01, 1998Li53, 2003Au03, 211PB3C 2004Br45, 2008Ki07 -211PB T Auger electrons and ^X ray energies and emission intensities: -211PB T {U Energy (keV)} {U Intensity } {U Line } +211PB T Auger electrons and X ray energies and emission intensities: +211PB T {U Energy (keV)} {U Intensity} {U Line} 211PB T -211PB T 72.8049 0.00045 15 XKA2 -211PB T 74.97 0.00075 25 XKA1 +211PB T 72.8049 0.00045 15 XKA2 +211PB T 74.97 0.00075 25 XKA1 211PB T -211PB T 84.451 |] XKB3 -211PB T 84.937 |] 0.00026 9 XKB1 -211PB T 85.47 |] XKB5II +211PB T 84.451 |] XKB3 +211PB T 84.937 |] 0.00026 9 XKB1 +211PB T 85.47 |] XKB5II 211PB T -211PB T 87.238 |] XKB2 -211PB T 87.58 |] 0.000078 26 XKB4 -211PB T 87.911 |] XKO23 +211PB T 87.238 |] XKB2 +211PB T 87.58 |] 0.00007826 XKB4 +211PB T 87.911 |] XKO23 211PB T -211PB T 9.186-15.2169 0.00071 12 XL (total) -211PB T 9.186 0.000016 4 XLL -211PB T 10.4495-10.5512 0.00031 7 XLA -211PB T 11.3495 0.0000063 15 XLC -211PB T 12.1443-13.3763 0.00032 6 XLB -211PB T 14.3078-15.2169 0.000063 12 XLG +211PB T 9.186-15.2169 0.00071 12 XL (total) +211PB T 9.186 0.000016 4 XLL +211PB T 10.4495-10.5512 0.00031 7 XLA +211PB T 11.3495 6.3E-6 15 XLC +211PB T 12.1443-13.3763 0.00032 6 XLB +211PB T 14.3078-15.2169 0.00006312 XLG 211PB T -211PB T 56.028-61.669 |] KLL AUGER -211PB T 68.181-74.969 |] 0.000059 21 ^KLX AUGER -211PB T 80.3-88 |] KXY AUGER -211PB T 5.33-15.82 0.00115 14 L AUGER +211PB T 56.028-61.669 |] KLL AUGER +211PB T 68.181-74.969 |] 0.00005921 KLX AUGER +211PB T 80.3-88 |] KXY AUGER +211PB T 5.33-15.82 0.00115 14 L AUGER 215PO P 0.0 9/2+ 1.781 MS 4 7526.3 8 211PB N 1.00E0 1.00E0 0.999997 1.00E0 211PB L 0 9/2+ 36.1 M 2 211PB A 7386.1 8 99.934 201.34 211PB L 438.9 2 (7/2)+ 211PB A 6955.4 8 0.06 2 82 -211PB G 438.9 2 0.058 19E2 0.0405 6 -211PB2 G KC=0.0275 4$LC=0.00984 14$MC=0.00247 4 +211PB G 438.9 2 0.058 19E2 0.0405 6 +211PB2 G KC=0.0275 4$LC=0.00984 14$MC=0.00247 4 211PB L 584 3 + 211PB A 6813 3 0.0004 2 3800 211PB G 584 3 @@ -46,7 +46,7 @@ 211PB L 643 3 11/2+ 211PB A 6755 3 0.0008 3 1170 211PB G 643 3 (M1+E2) 0.036 20 -211PB2 G KC=0.029 17$LC=0.0054 23$MC=0.0013 6 +211PB2 G KC=0.029 17$LC=0.0054 23$MC=0.0013 6 211PB L 733 3 (13/2)+ 211PB A 6667 3 0.0008 3 550 211PB G 733 3 @@ -64,24 +64,24 @@ 215AT C References: 1942Wa04, 1950Av61, 1961Vo06, 1962Wa18, 1965Va10, 1968Br17, 215AT2C 1970Da09, 1971Gr17, 1971Er02, 1977Ma29, 1991Ry01, 1998Li53, 2003Au03, 215AT3C 2004Br45, 2008Ki07 -215AT T Auger electrons and ^X ray energies and emission intensities: -215AT T {U Energy (keV)} {U Intensity } {U Line } +215AT T Auger electrons and X ray energies and emission intensities: +215AT T {U Energy (keV)} {U Intensity} {U Line} 215AT T 215AT T 78.94 XKA2 215AT T 81.51 XKA1 215AT T -215AT T 91.73 |] XKB3 -215AT T 92.315 |] XKB1 -215AT T 92.883 |] XKB5II +215AT T 91.73 |] XKB3 +215AT T 92.315 |] XKB1 +215AT T 92.883 |] XKB5II 215AT T -215AT T 94.846 |] XKB2 -215AT T 95.211 |] XKB4 -215AT T 95.595 |] XKO23 +215AT T 94.846 |] XKB2 +215AT T 95.211 |] XKB4 +215AT T 95.595 |] XKO23 215AT T 215AT T -215AT T 60.489-67.031 |] KLL AUGER -215AT T 73.811-81.516 |] ^KLX AUGER -215AT T 87.1-95.72 |] KXY AUGER +215AT T 60.489-67.031 |] KLL AUGER +215AT T 73.811-81.516 |] KLX AUGER +215AT T 87.1-95.72 |] KXY AUGER 215AT T 5.58-17.41 L AUGER 215PO P 0.0 9/2+ 1.781 MS 4 715 7 215AT N 4.348E5 4.348E5 0.000002 4.348E5 diff --git a/HEN_HOUSE/spectra/lnhb/Po-216.txt b/HEN_HOUSE/spectra/lnhb/Po-216.txt index 02363c4d2..b1be173e3 100644 --- a/HEN_HOUSE/spectra/lnhb/Po-216.txt +++ b/HEN_HOUSE/spectra/lnhb/Po-216.txt @@ -6,37 +6,37 @@ 212PB C References: 1911Mo11, 1942Wa04, 1962Wa28, 1963Di05, 1977Ku15, 1977La19, 212PB2C 1996Sc06, 1998ScZM, 1998Ak04, 1999ScZX, 2002Ba85, 2002Ra45, 2003Au03, 212PB3C 2003Da24, 2005Br03, 2007Wu02, 2007St23, 2008Ki07 -212PB T Auger electrons and ^X ray energies and emission intensities: -212PB T {U Energy (keV)} {U Intensity } {U Line } +212PB T Auger electrons and X ray energies and emission intensities: +212PB T {U Energy (keV)} {U Intensity} {U Line} 212PB T -212PB T 72.8049 0.0000043 7 XKA2 -212PB T 74.97 0.0000072 12 XKA1 +212PB T 72.8049 4.3E-6 7 XKA2 +212PB T 74.97 7.2E-6 12 XKA1 212PB T -212PB T 84.451 |] XKB3 -212PB T 84.937 |] 0.0000024 4 XKB1 -212PB T 85.47 |] XKB5II +212PB T 84.451 |] XKB3 +212PB T 84.937 |] 2.4E-6 4 XKB1 +212PB T 85.47 |] XKB5II 212PB T -212PB T 87.238 |] XKB2 -212PB T 87.58 |] 0.00000074 12 XKB4 -212PB T 87.911 |] XKO23 +212PB T 87.238 |] XKB2 +212PB T 87.58 |] 7.4E-7 12 XKB4 +212PB T 87.911 |] XKO23 212PB T -212PB T 9.184-15.216 0.0000059 6 XL (total) -212PB T 9.184 0.000000142 18 XLL -212PB T 10.45-10.551 0.0000027 3 XLA -212PB T 11.349 0.000000047 7 XLC -212PB T 12.142-13.015 0.00000253 24 XLB -212PB T 14.765-15.216 0.00000049 5 XLG +212PB T 9.184-15.216 5.9E-6 6 XL (total) +212PB T 9.184 1.42E-7 18 XLL +212PB T 10.45-10.551 2.7E-6 3 XLA +212PB T 11.349 4.7E-8 7 XLC +212PB T 12.142-13.015 2.53E-6 24 XLB +212PB T 14.765-15.216 4.9E-7 5 XLG 212PB T -212PB T 56.03-61.67 |] KLL AUGER -212PB T 68.18-74.97 |] 0.00000056 11 ^KLX AUGER -212PB T 80.3-88 |] KXY AUGER -212PB T 5.26-10.4 0.0000097 10 L AUGER +212PB T 56.03-61.67 |] KLL AUGER +212PB T 68.18-74.97 |] 5.6E-7 11 KLX AUGER +212PB T 80.3-88 |] KXY AUGER +212PB T 5.26-10.4 9.7E-6 10 L AUGER 216PO P 0.0 0+ 0.148 S 4 6906.3 5 212PB N 1.0 1.0 1 1.0 212PB L 0 0+ 10.64 H 1 212PB A 6778.4 5 99.9981 3 1 212PB L 804.9 5 (2)+ 212PB A 5988.4 7 0.0019 3 35 -212PB G 804.9 5 0.0019 3 [E2] 0.0102715 -212PB2 G KC=0.00799 12$LC=1732E-6 25$MC=4.17E-4 6 +212PB G 804.9 5 0.0019 3[E2] 0.0102715 +212PB2 G KC=0.00799 12$LC=1732E-6 25$MC=4.17E-4 6 diff --git a/HEN_HOUSE/spectra/lnhb/Po-218.txt b/HEN_HOUSE/spectra/lnhb/Po-218.txt index 217850476..29a74848b 100644 --- a/HEN_HOUSE/spectra/lnhb/Po-218.txt +++ b/HEN_HOUSE/spectra/lnhb/Po-218.txt @@ -6,19 +6,19 @@ 214PB C References: 1924Bl02, 1931Cu01, 1949Wa05, 1952Hi60, 1958Wa16, 1963Ba62, 214PB2C 1971Gr17, 1979Ry03, 1982Va09, 1986Po17, 1987El07, 1991Ry01, 1992Ba61, 214PB3C 1995El07, 1995El08, 1998Ak04, 2002Ba85, 2003Au03, 2006Ja03 -214PB T Auger electrons and ^X ray energies and emission intensities: -214PB T {U Energy (keV)} {U Intensity } {U Line } +214PB T Auger electrons and X ray energies and emission intensities: +214PB T {U Energy (keV)} {U Intensity} {U Line} 214PB T 214PB T 72.8049 XKA2 214PB T 74.97 XKA1 214PB T -214PB T 84.451 |] XKB3 -214PB T 84.937 |] XKB1 -214PB T 85.47 |] XKB5II +214PB T 84.451 |] XKB3 +214PB T 84.937 |] XKB1 +214PB T 85.47 |] XKB5II 214PB T -214PB T 87.238 |] XKB2 -214PB T 87.58 |] XKB4 -214PB T 87.911 |] XKO23 +214PB T 87.238 |] XKB2 +214PB T 87.58 |] XKB4 +214PB T 87.911 |] XKO23 214PB T 218PO P 0.0 0+ 3.071 M 22 6114.68 9 214PB N 1.00E0 1.00E0 0.999779 1.00E0 @@ -36,19 +36,19 @@ 218AT C References: 1924Bl02, 1931Cu01, 1949Wa05, 1952Hi60, 1958Wa16, 1963Ba62, 218AT2C 1971Gr17, 1979Ry03, 1982Va09, 1986Po17, 1987El07, 1991Ry01, 1992Ba61, 218AT3C 1995El07, 1995El08, 1998Ak04, 2002Ba85, 2003Au03, 2006Ja03 -218AT T Auger electrons and ^X ray energies and emission intensities: -218AT T {U Energy (keV)} {U Intensity } {U Line } +218AT T Auger electrons and X ray energies and emission intensities: +218AT T {U Energy (keV)} {U Intensity} {U Line} 218AT T 218AT T 78.94 XKA2 218AT T 81.51 XKA1 218AT T -218AT T 91.73 |] XKB3 -218AT T 92.315 |] XKB1 -218AT T 92.883 |] XKB5II +218AT T 91.73 |] XKB3 +218AT T 92.315 |] XKB1 +218AT T 92.883 |] XKB5II 218AT T -218AT T 94.846 |] XKB2 -218AT T 95.211 |] XKB4 -218AT T 95.595 |] XKO23 +218AT T 94.846 |] XKB2 +218AT T 95.211 |] XKB4 +218AT T 95.595 |] XKO23 218AT T 218AT T 9.8964 XLL 218AT T 11.3052-11.426 XLA @@ -58,6 +58,6 @@ 218PO P 0.0 0+ 3.071 M 22 260 12 218AT N 4.545E3 4.545E3 0.00022 4.545E3 218AT L 0 (2)- 1.4 S 2 -218AT B 260 120.022 3 1U +218AT B 260 120.022 3 1U 218ATS B EAV=73 4 diff --git a/HEN_HOUSE/spectra/lnhb/Pr-144.txt b/HEN_HOUSE/spectra/lnhb/Pr-144.txt index 9b02e10d9..842221fc2 100644 --- a/HEN_HOUSE/spectra/lnhb/Pr-144.txt +++ b/HEN_HOUSE/spectra/lnhb/Pr-144.txt @@ -9,98 +9,98 @@ 144ND6C 1979Gr01, 1981Ol04, 1983Sn04, 1983Kr09, 1985Da16, 1987Al28, 1994Ro13, 144ND7C 1996Sc06, 1998Hi09, 1998ScZM, 1999ScZX, 2000Sc47, 2000He14, 2001So16, 144ND8C 2002Ra45, 2002Ba85, 2008Ki07, 2012Wa38 -144ND T Auger electrons and ^X ray energies and emission intensities: -144ND T {U Energy (keV)} {U Intensity } {U Line } +144ND T Auger electrons and X ray energies and emission intensities: +144ND T {U Energy (keV)} {U Intensity} {U Line} 144ND T -144ND T 36.8478 0.00165 9 XKA2 -144ND T 37.3614 0.00300 15 XKA1 +144ND T 36.8478 0.00165 9 XKA2 +144ND T 37.3614 0.00300 15 XKA1 144ND T -144ND T 42.167 |] XKB3 -144ND T 42.2717 |] 0.00092 5 XKB1 -144ND T 42.58 |] XKB5II +144ND T 42.167 |] XKB3 +144ND T 42.2717 |] 0.00092 5 XKB1 +144ND T 42.58 |] XKB5II 144ND T -144ND T 43.335 |] XKB2 -144ND T 43.451 |] 0.000237 13 XKB4 -144ND T 43.548 |] XKO23 +144ND T 43.335 |] XKB2 +144ND T 43.451 |] 0.00023713 XKB4 +144ND T 43.548 |] XKO23 144ND T -144ND T 4.633-6.901 0.00092 3 XL (total) -144ND T 4.633 0.0000179 9 XLL -144ND T 5.208-5.23 0.000449 20 XLA -144ND T 5.146 0.0000069 4 XLC -144ND T 5.722-6.09 0.000384 14 XLB -144ND T 6.604-6.901 0.0000615 23 XLG +144ND T 4.633-6.901 0.00092 3 XL (total) +144ND T 4.633 1.79E-5 9 XLL +144ND T 5.208-5.23 0.00044920 XLA +144ND T 5.146 6.9E-6 4 XLC +144ND T 5.722-6.09 0.00038414 XLB +144ND T 6.604-6.901 6.15E-5 23 XLG 144ND T -144ND T 29.154-30.978 |] KLL AUGER -144ND T 34.798-37.34 |] 0.00052 4 ^KLX AUGER -144ND T 40.42-43.53 |] KXY AUGER -144ND T 3.01-5.1 0.00551 18 L AUGER +144ND T 29.154-30.978 |] KLL AUGER +144ND T 34.798-37.34 |] 0.00052 4 KLX AUGER +144ND T 40.42-43.53 |] KXY AUGER +144ND T 3.01-5.1 0.00551 18 L AUGER 144PR P 0.0 0- 17.29 M 4 2997.4 24 144ND N 1.0 1.0 1 1.0 144ND L 0 0 0+ 2.3E15 Y 3 144ND B 2997.4 2497.852 10 6.53 144NDS B EAV=12220E-1 1 144ND L 696.561 102+ -144ND B 2300.8 241.116 3 9.17 1U +144ND B 2300.8 241.116 3 9.17 1U 144NDS B EAV=894.90 11 -144ND G 696.505 4 1.41 7 E2 0.005077 -144ND2 G KC=0.00427 6$LC=6.31E-4 9$MC=1348E-7 19 +144ND G 696.505 4 1.41 7E2 0.00507 7 +144ND2 G KC=0.00427 6$LC=6.31E-4 9$MC=1348E-7 19 144ND L 1314.669 134+ 7.40 PS 9 144ND L 1510.871 213- 0.56 PS 7 144ND G 814.308 230.00331 14E1 1391E-620 -144ND2 G KC=1198E-6 17$LC=1528E-7 22$MC=3.21E-5 5 +144ND2 G KC=1198E-6 17$LC=1528E-7 22$MC=3.21E-5 5 144ND L 1560.920 132+ -144ND B 1436.5 240.0017 3 10.8 1U +144ND B 1436.5 240.0017 3 10.8 1U 144NDS B EAV=526.25 10 144ND G 864.356 160.00269 14M1+E2 -0.97 15 0.0039616 -144ND2 G KC=0.00338 14$LC=4.56E-4 16$MC=9.6E-5 4 -144ND G 1560.911 130.00021 3 E2 1014E-615 -144ND2 G KC=7.86E-4 11$LC=1024E-7 15$MC=2.16E-5 3 +144ND2 G KC=0.00338 14$LC=4.56E-4 16$MC=9.6E-5 4 +144ND G 1560.911 130.00021 3E2 1014E-615 +144ND2 G KC=7.86E-4 11$LC=1024E-7 15$MC=2.16E-5 3 144ND L 2072.91 3 2+ 59 FS 10 -144ND B 924.5 240.00065 6 10.2 1U +144ND B 924.5 240.00065 6 10.2 1U 144NDS B EAV=322.77 9 -144ND G 1376.34 3 0.00041 4 M1+E2 0.34 10 0.001614 -144ND2 G KC=0.00135 3$LC=1.75E-4 4$MC=3.68E-5 8 -144ND G 2072.89 3 0.00024 3 E2 8.65E-413 -144ND2 G KC=4.65E-4 7$LC=5.93E-5 9$MC=1246E-8 18 +144ND G 1376.34 3 0.00041 4M1+E2 0.34 10 0.00161 4 +144ND2 G KC=0.00135 3$LC=1.75E-4 4$MC=3.68E-5 8 +144ND G 2072.89 3 0.00024 3E2 8.65E-413 +144ND2 G KC=4.65E-4 7$LC=5.93E-5 9$MC=1246E-8 18 144ND L 2084.68 3 0+ 0.12 PS 5 -144ND B 912.7 240.00708 6 8.7 +144ND B 912.7 240.00708 6 8.7 144NDS B EAV=306.67 10 -144ND G 1388.11 4 0.00706 6 E2 1190E-617 -144ND2 G KC=9.84E-4 14$LC=1297E-7 19$MC=2.74E-5 4 +144ND G 1388.11 4 0.00706 6E2 1190E-617 +144ND2 G KC=9.84E-4 14$LC=1297E-7 19$MC=2.74E-5 4 144ND L 2185.75 3 1- 15 FS 2 144ND B 811.7 241.021 10 6.32 144NDS B EAV=267.12 9 -144ND G 624.83 3 0.00118 3 E1 0.002414 -144ND2 G KC=0.00207 3$LC=2.67E-4 4$MC=5.61E-5 8 -144ND G 674.88 4 0.00299 14E2 0.005478 -144ND2 G KC=0.00460 7$LC=6.86E-4 10$MC=1465E-7 21 -144ND G 1489.148 3 0.286 3 E1 6.63E-410 -144ND2 G KC=3.97E-4 6$LC=4.95E-5 7$MC=1038E-8 15 -144ND G 2185.645 5 0.73 1 E1 9.59E-414 -144ND2 G KC=2.13E-4 3$LC=2.64E-5 4$MC=5.52E-6 8 +144ND G 624.83 3 0.00118 3E1 0.00241 4 +144ND2 G KC=0.00207 3$LC=2.67E-4 4$MC=5.61E-5 8 +144ND G 674.88 4 0.00299 14E2 0.00547 8 +144ND2 G KC=0.00460 7$LC=6.86E-4 10$MC=1465E-7 21 +144ND G 1489.148 3 0.286 3E1 6.63E-410 +144ND2 G KC=3.97E-4 6$LC=4.95E-5 7$MC=1038E-8 15 +144ND G 2185.645 5 0.73 1E1 9.59E-414 +144ND2 G KC=2.13E-4 3$LC=2.64E-5 4$MC=5.52E-6 8 144ND L 2368.82 4 2+ 39 FS 14 -144ND B 628.6 240.00027 6 9.7 1U +144ND B 628.6 240.00027 6 9.7 1U 144NDS B EAV=213.04 9 -144ND G 1672.25 4 0.00021 6 M1+E2 0.16 7 1189E-618 -144ND2 G KC=8.92E-4 14$LC=1146E-7 18$MC=2.41E-5 4 -144ND G 2368.80 4 5.1E-5 14E2 8.91E-413 -144ND2 G KC=3.65E-4 6$LC=4.63E-5 7$MC=9.73E-6 14 +144ND G 1672.25 4 0.00021 6M1+E2 0.16 7 1189E-618 +144ND2 G KC=8.92E-4 14$LC=1146E-7 18$MC=2.41E-5 4 +144ND G 2368.80 4 0.00005114E2 8.91E-413 +144ND2 G KC=3.65E-4 6$LC=4.63E-5 7$MC=9.73E-6 14 144ND L 2582.32 6 (3)+ 144ND L 2655.54 3 1+ 9.9 FS 2 -144ND B 341.9 240.00018 3 8.8 1 +144ND B 341.9 240.00018 3 8.8 1 144NDS B EAV=98.68 8 -144ND G 2655.51 3 0.00018 3 M1+E2 +144ND G 2655.51 3 0.00018 3M1+E2 144ND L 2675.61 8 0+ 0.2 PS 1 -144ND B 321.8 240.00096 8 8 +144ND B 321.8 240.00096 8 8 144NDS B EAV=92.21 8 -144ND G 1979.04 8 0.00096 8 E2 8.68E-413 -144ND2 G KC=5.05E-4 7$LC=6.47E-5 9$MC=1360E-8 19 +144ND G 1979.04 8 0.00096 8E2 8.68E-413 +144ND2 G KC=5.05E-4 7$LC=6.47E-5 9$MC=1360E-8 19 144ND L 2742.99 7 0+ 64 FS 40 -144ND B 254.4 240.00035 6 8.1 +144ND B 254.4 240.00035 6 8.1 144NDS B EAV=71.05 8 -144ND G 1182.06 7 0.00006 3 E2 1587E-623 -144ND2 G KC=1353E-6 19$LC=1.82E-4 3$MC=3.84E-5 6 -144ND G 2046.41 7 0.00030 6 E2 8.65E-413 -144ND2 G KC=4.75E-4 7$LC=6.07E-5 9$MC=1277E-8 18 +144ND G 1182.06 7 0.00006 3E2 1587E-623 +144ND2 G KC=1353E-6 19$LC=1.82E-4 3$MC=3.84E-5 6 +144ND G 2046.41 7 0.00030 6E2 8.65E-413 +144ND2 G KC=4.75E-4 7$LC=6.07E-5 9$MC=1277E-8 18 144ND L 2946.04 10(2,3,4)- diff --git a/HEN_HOUSE/spectra/lnhb/Pr-144m.txt b/HEN_HOUSE/spectra/lnhb/Pr-144m.txt index ca929ca6f..6736a7399 100644 --- a/HEN_HOUSE/spectra/lnhb/Pr-144m.txt +++ b/HEN_HOUSE/spectra/lnhb/Pr-144m.txt @@ -5,37 +5,37 @@ 144PR2C 1974Be09, 1976CoZX, 1976Ra22, 1977La19, 1979Pr11, 1979Gr01, 1985Da16, 144PR3C 1994Ro13, 1996Sc06, 1998Hi09, 1998ScZM, 1999ScZX, 2000Sc47, 2000He14, 144PR4C 2001So16, 2002Ra45, 2002Ba85, 2008Ki07, 2012Wa38 -144PR T Auger electrons and ^X ray energies and emission intensities: -144PR T {U Energy (keV)} {U Intensity } {U Line } +144PR T Auger electrons and X ray energies and emission intensities: +144PR T {U Energy (keV)} {U Intensity} {U Line} 144PR T -144PR T 33.5506 8.66 19 XKA2 -144PR T 36.0267 15.8 4 XKA1 +144PR T 33.5506 8.66 19 XKA2 +144PR T 36.0267 15.8 4 XKA1 144PR T -144PR T 40.6533 |] XKB3 -144PR T 40.7487 |] 4.81 12 XKB1 -144PR T 41.05 |] XKB5II +144PR T 40.6533 |] XKB3 +144PR T 40.7487 |] 4.81 12 XKB1 +144PR T 41.05 |] XKB5II 144PR T -144PR T 41.774 |] XKB2 -144PR T 41.877 |] 1.23 4 XKB4 -144PR T 41.968 |] XKO23 +144PR T 41.774 |] XKB2 +144PR T 41.877 |] 1.23 4 XKB4 +144PR T 41.968 |] XKO23 144PR T -144PR T 4.453-6.617 10.5 5 XL (total) -144PR T 4.453 0.227 7 XLL -144PR T 5.013-5.033 5.74 16 XLA -144PR T 4.929 0.0498 15 XLC -144PR T 5.489-5.851 3.89 7 XLB -144PR T 6.327-6.617 0.625 13 XLG +144PR T 4.453-6.617 10.5 5 XL (total) +144PR T 4.453 0.227 7 XLL +144PR T 5.013-5.033 5.74 16 XLA +144PR T 4.929 0.0498 15 XLC +144PR T 5.489-5.851 3.89 7 XLB +144PR T 6.327-6.617 0.625 13 XLG 144PR T -144PR T 28.162-29.89 |] KLL AUGER -144PR T 33.576-36.004 |] 2.87 15 ^KLX AUGER -144PR T 38.97-41.95 |] KXY AUGER -144PR T 2.9-4.91 69 10 L AUGER +144PR T 28.162-29.89 |] KLL AUGER +144PR T 33.576-36.004 |] 2.87 15 KLX AUGER +144PR T 38.97-41.95 |] KXY AUGER +144PR T 2.9-4.91 69 10 L AUGER 144PR P 59.03 3 3- 7.2 M 2 144PR N 1.001E0 1.001E0 0.9994 2 1.001E0 144PR L 0 0 0- 17.29 M 4 144PR L 59.03 3 3- 7.2 M 2 144PR G 59.03 3 0.0818 12M3 1221 18 -144PR2 G KC=408 6$LC=618 9$MC=155.0 23 +144PR2 G KC=408 6$LC=618 9$MC=155.0 23 144ND 144PR B- DECAY (7.2 M) 144ND H TYP=FUL$AUT=A.L. Nichols$CUT=01-APR-2014$ @@ -44,54 +44,54 @@ 144ND2C 1974Be09, 1976CoZX, 1976Ra22, 1977La19, 1979Pr11, 1979Gr01, 1985Da16, 144ND3C 1994Ro13, 1996Sc06, 1998Hi09, 1998ScZM, 1999ScZX, 2000Sc47, 2000He14, 144ND4C 2001So16, 2002Ra45, 2002Ba85, 2008Ki07, 2012Wa38 -144ND T Auger electrons and ^X ray energies and emission intensities: -144ND T {U Energy (keV)} {U Intensity } {U Line } +144ND T Auger electrons and X ray energies and emission intensities: +144ND T {U Energy (keV)} {U Intensity} {U Line} 144ND T -144ND T 36.8478 0.000119 23 XKA2 -144ND T 37.3614 0.00022 5 XKA1 +144ND T 36.8478 0.00011923 XKA2 +144ND T 37.3614 0.00022 5 XKA1 144ND T -144ND T 42.167 |] XKB3 -144ND T 42.2717 |] 0.000067 13 XKB1 -144ND T 42.58 |] XKB5II +144ND T 42.167 |] XKB3 +144ND T 42.2717 |] 0.00006713 XKB1 +144ND T 42.58 |] XKB5II 144ND T -144ND T 43.335 |] XKB2 -144ND T 43.451 |] 0.000017 4 XKB4 -144ND T 43.548 |] XKO23 +144ND T 43.335 |] XKB2 +144ND T 43.451 |] 0.000017 4 XKB4 +144ND T 43.548 |] XKO23 144ND T 144ND T -144ND T 29.154-30.978 |] KLL AUGER -144ND T 34.798-37.34 |] 0.000038 8 ^KLX AUGER -144ND T 40.42-43.53 |] KXY AUGER -144ND T 3.01-5.1 0.00040 5 L AUGER +144ND T 29.154-30.978 |] KLL AUGER +144ND T 34.798-37.34 |] 0.000038 8 KLX AUGER +144ND T 40.42-43.53 |] KXY AUGER +144ND T 3.01-5.1 0.00040 5 L AUGER 144PR P 59.03 3 3- 7.2 M 2 2997.4 24 144ND N 1.667E3 1.667E3 0.0006 2 1.667E3 144ND L 0 0 0+ 2.3E15 Y 3 144ND L 696.561 102+ -144ND G 696.505 4 0.06 2 E2 0.005077 -144ND2 G KC=0.00427 6$LC=6.31E-4 9$MC=1348E-7 19 +144ND G 696.505 4 0.06 2E2 0.00507 7 +144ND2 G KC=0.00427 6$LC=6.31E-4 9$MC=1348E-7 19 144ND L 1314.669 134+ 7.4 PS 9 -144ND G 618.107 160.030 3 E2 0.0067910 -144ND2 G KC=0.00568 8$LC=8.69E-4 13$MC=1.86E-4 3 +144ND G 618.107 160.030 3E2 0.0067910 +144ND2 G KC=0.00568 8$LC=8.69E-4 13$MC=1.86E-4 3 144ND L 1510.871 213- 0.56 PS 7 -144ND B 1545.5 240.02 1 8.7 +144ND B 1545.5 240.02 1 8.7 144NDS B EAV=570.0 11 -144ND G 814.308 230.02 1 E1 1391E-620 -144ND2 G KC=1198E-6 17$LC=1528E-7 22$MC=3.21E-5 5 +144ND G 814.308 230.02 1E1 1391E-620 +144ND2 G KC=1198E-6 17$LC=1528E-7 22$MC=3.21E-5 5 144ND L 1560.920 132+ 144ND L 2072.91 3 2+ 59 FS 10 144ND L 2084.68 3 0+ 0.12 PS 5 144ND L 2185.75 3 1- 15 FS 2 144ND L 2368.82 4 2+ 39 FS 14 144ND L 2582.32 6 (3)+ -144ND B 474.1 240.010 3 7.15 +144ND B 474.1 240.010 3 7.15 144NDS B EAV=143.0 8 -144ND G 1885.75 6 0.010 3 M1+E2 0.13 5 1052E-615 -144ND2 G KC=6.86E-4 10$LC=8.78E-5 13$MC=1.85E-5 3 +144ND G 1885.75 6 0.010 3M1+E2 0.13 5 1052E-615 +144ND2 G KC=6.86E-4 10$LC=8.78E-5 13$MC=1.85E-5 3 144ND L 2655.54 3 1+ 9.9 FS 2 144ND L 2675.61 8 0+ 0.2 PS 1 144ND L 2742.99 7 0+ 64 FS 40 144ND L 2946.04 10(2,3,4)- -144ND B 110.4 240.030 3 4.65 +144ND B 110.4 240.030 3 4.65 144NDS B EAV=29.0 7 -144ND G 1631.36 100.030 3 +144ND G 1631.36 100.030 3 diff --git a/HEN_HOUSE/spectra/lnhb/Pu-238.txt b/HEN_HOUSE/spectra/lnhb/Pu-238.txt index f4b67e4de..ff84840bd 100644 --- a/HEN_HOUSE/spectra/lnhb/Pu-238.txt +++ b/HEN_HOUSE/spectra/lnhb/Pu-238.txt @@ -10,128 +10,127 @@ 234U 7C 1984Ov01, 1984He19, 1984Bo41, 1984BaYT, 1984Ah06, 1987Bo25, 1988SeZY, 234U 8C 1990Po14, 1991Jo02, 1991Ry01, 1994Le37, 1994Ba91, 1995Jo23, 1996Sc06, 234U 9C 1998Ya17, 2000He14, 2000Ho27, 2000Ni13, 2003Au03, 2007Br04, 2008Ki07 -234U T Auger electrons and ^X ray energies and emission intensities: -234U T {U Energy (keV)} {U Intensity } {U Line } +234U T Auger electrons and X ray energies and emission intensities: +234U T {U Energy (keV)} {U Intensity} {U Line} 234U T -234U T 94.666 0.000106 3 XKA2 -234U T 98.44 0.000169 5 XKA1 +234U T 94.666 0.000106 3 XKA2 +234U T 98.44 0.000169 5 XKA1 234U T -234U T 110.421 |] XKB3 -234U T 111.298 |] 0.0000609 22 XKB1 -234U T 111.964 |] XKB5II +234U T 110.421 |] XKB3 +234U T 111.298 |] 6.09E-5 22 XKB1 +234U T 111.964 |] XKB5II 234U T -234U T 114.407 |] XKB2 -234U T 115.012 |] 0.0000208 6 XKB4 -234U T 115.377 |] XKO23 +234U T 114.407 |] XKB2 +234U T 115.012 |] 2.08E-5 6 XKB4 +234U T 115.377 |] XKO23 234U T -234U T 11.619-20.714 10.63 8 XL (total) -234U T 11.619 0.235 4 XLL -234U T 13.438-13.615 3.80 3 XLA -234U T 15.399 0.119 5 XLC -234U T 15.727-18.206 5.19 4 XLB -234U T 19.507-20.714 1.28 1 XLG +234U T 11.619-20.714 10.63 8 XL (total) +234U T 11.619 0.235 4 XLL +234U T 13.438-13.615 3.80 3 XLA +234U T 15.399 0.119 5 XLC +234U T 15.727-18.206 5.19 4 XLB +234U T 19.507-20.714 1.28 1 XLG 234U T -234U T 71.78-80.95 |] KLL AUGER -234U T 88.15-98.43 |] 0.0000110 15 ^KLX AUGER -234U T 104.51-115.59 |] KXY AUGER -234U T 5.9-21.6 10.6 4 L AUGER +234U T 71.78-80.95 |] KLL AUGER +234U T 88.15-98.43 |] 1.10E-5 15 KLX AUGER +234U T 104.51-115.59 |] KXY AUGER +234U T 5.9-21.6 10.6 4 L AUGER 238PU P 0.0 0+ 87.74 Y 3 5593.20 19 234U N 1.0 1.0 1 1.0 234U L 0 0+ 2.455E5 Y 60 234U A 5499.03 2071.04 6 1 234U L 43.4981 102+ 0.252 NS 7 234U A 5456.3 2 28.85 6 1.39 -234U G 43.498 1 0.0397 8 E2 713 15 -234U 2 G KC=$LC=520 11$MC=143.5 29 +234U G 43.498 1 0.0397 8E2 713 15 +234U 2 G LC=520 11$MC=143.5 29 234U L 143.352 4 4+ 234U A 5358.1 2 0.104 3 102 -234U G 99.852 3 0.00735 8 E2 13.42 27 -234U 2 G KC=$LC=9.77 20$MC=2.71 6 +234U G 99.852 3 0.00735 8E2 13.42 27 +234U 2 G LC=9.77 20$MC=2.71 6 234U L 296.072 4 6+ 234U A 5208.0 2 0.00292 4 440 -234U G 152.719 2 9.30E-4 7 E2 2.14 4 -234U 2 G KC=0.217 4$LC=1.404 28$MC=0.388 8 +234U G 152.719 2 0.000930 7E2 2.14 4 +234U 2 G KC=0.217 4$LC=1.404 28$MC=0.388 8 234U L 497.04 3 8+ 234U A 5010.4 2 68000E-12310000 234U G 200.97 3 3.92E-6 13E2 0.734 15 -234U 2 G KC=0.1534 31$LC=0.424 9$MC=0.1166 23 +234U 2 G KC=0.1534 31$LC=0.424 9$MC=0.1166 23 234U L 786.288 161- 234U A 4726.0 2 82100E-11689 234U G 742.813 5 5.10E-6 13E1 0.0063613 -234U 2 G KC=0.00518 10$LC=8.95E-4 18$MC=2.13E-4 4 -234U G 786.27 3 3.20E-6 9 E1 0.0057312 -234U 2 G KC=0.00467 9$LC=8.04E-4 16$MC=1.91E-4 4 +234U 2 G KC=0.00518 10$LC=8.95E-4 18$MC=2.13E-4 4 +234U G 786.27 3 3.20E-6 9E1 0.0057312 +234U 2 G KC=0.00467 9$LC=8.04E-4 16$MC=1.91E-4 4 234U L 809.907 180+ 234U A 4702.8 2 0.0001 5 -234U G 766.38 2 2.19E-5 5 E2 0.0187 4 -234U 2 G KC=0.01336 27$LC=0.00396 8$MC=1003E-6 20 +234U G 766.38 2 2.19E-5 5E2 0.0187 4 +234U 2 G KC=0.01336 27$LC=0.00396 8$MC=1003E-6 20 234U G 810.0 5 234U L 849.266 183- 234U A 4664.1 2 75000E-1223400 234U G 705.9 1 5.0E-8 13[E1] 0.0069814 -234U 2 G KC=0.00568 12$LC=9.87E-4 20$MC=2.35E-4 5 +234U 2 G KC=0.00568 12$LC=9.87E-4 20$MC=2.35E-4 5 234U G 805.80 5 5.6E-8 15[E1] 0.0054911 -234U 2 G KC=0.00447 9$LC=7.68E-4 16$MC=1.83E-4 4 +234U 2 G KC=0.00447 9$LC=7.68E-4 16$MC=1.83E-4 4 234U L 851.74 3 2+ 1.74 PS 234U A 4661.7 2 81000E-1 30.5 234U G 41.82 113.0E-9 16[E2] 863 18 -234U 2 G KC=$LC=630 13$MC=174 4 -234U G 708.3 2 4.9E-7 3 [E2] 0.0219 5 +234U 2 G LC=630 13$MC=174 4 +234U G 708.3 2 4.9E-7 3[E2] 0.0219 5 234U 2 G KC=0.01537 31$LC=0.00489 10$MC=1246E-6 25 -234U G 808.2 1 7.67E-7 25+E2 4.300000 -234U 2 G KC=3.31000 0$LC=0.94000 0$MC= -234U G 851.7 1 1.27E-6 4 [E2] 0.0151330 -234U 2 G KC=0.01109 22$LC=0.00302 6$MC=7.59E-4 16 +234U G 808.2 1 7.67E-7 25+E2 4.3 +234U 2 G KC=3.31 $LC=0.94 +234U G 851.7 1 1.27E-6 4[E2] 0.0151330 +234U 2 G KC=0.01109 22$LC=0.00302 6$MC=7.59E-4 16 234U L 926.720 152+ 1.38 PS 17 234U A 4587.9 2 13000E-15 53 -234U G 783.4 1 2.2E-8 3 [E2] 0.0179 4 -234U 2 G KC=0.01285 26$LC=0.00374 8$MC=9.46E-4 19 -234U G 883.24 4 7.2E-7 4 E2 0.0140928 -234U 2 G KC=0.01040 21$LC=0.00276 6$MC=6.92E-4 14 +234U G 783.4 1 2.2E-8 3[E2] 0.0179 4 +234U 2 G KC=0.01285 26$LC=0.00374 8$MC=9.46E-4 19 +234U G 883.24 4 7.2E-7 4E2 0.0140928 +234U 2 G KC=0.01040 21$LC=0.00276 6$MC=6.92E-4 14 234U G 926.72 1 5.58E-7 25(E2) 0.0128426 -234U 2 G KC=0.00956 20$LC=0.00245 5$MC=6.13E-4 12 +234U 2 G KC=0.00956 20$LC=0.00245 5$MC=6.13E-4 12 234U L 947.64 6 4+ 234U A 4567.4 2 23000E-1 21 -234U G 804.4 3 1.1E-7 5 +E2 0.570000 -234U 2 G KC=$LC=$MC= +234U G 804.4 3 1.1E-7 5+E2 0.57 234U G 904.37 156.1E-8 11[E2] 0.0134627 -234U 2 G KC=0.00998 20$LC=0.00260 5$MC=6.52E-4 13 +234U 2 G KC=0.00998 20$LC=0.00260 5$MC=6.52E-4 13 234U L 989.430 132- 0.76 NS 4 234U A 4526.3 2 15000E-116155 -234U G 62.70 1 1.1E-8 3 E1 0.426 9 -234U 2 G KC=$LC=0.320 7$MC=0.0791 16 -234U G 140.15 2 3.5E-9 7 M1+E2 1.3 5 5.1 15 -234U 2 G KC=2.6 8$LC=1.79 5$MC=0.48 14 -234U G 203.12 3 8.5E-9 15M1+E2 1.4 4 1.5 3 -234U 2 G KC=0.90 17$LC=0.423 9$MC=0.1113 23 -234U G 946.00 3 9.2E-8 13(E1) 0.004128 -234U 2 G KC=0.00337 7$LC=5.71E-4 12$MC=1355E-7 27 +234U G 62.70 1 1.1E-8 3E1 0.426 9 +234U 2 G LC=0.320 7$MC=0.0791 16 +234U G 140.15 2 3.5E-9 7M1+E2 1.3 5 5.1 15 +234U 2 G KC=2.6 8$LC=1.79 5$MC=0.48 14 +234U G 203.12 3 8.5E-9 15M1+E2 1.4 4 1.5 3 +234U 2 G KC=0.90 17$LC=0.423 9$MC=0.1113 23 +234U G 946.00 3 9.2E-8 13(E1) 0.00412 8 +234U 2 G KC=0.00337 7$LC=5.71E-4 12$MC=1355E-7 27 234U L 1023.77 3 4+ 234U A 4492.5 2 20000E-1 64 -234U G 727.8 2 2.7E-9 3 (E2) 0.0207 4 -234U 2 G KC=0.01464 29$LC=0.00454 9$MC=1156E-6 23 -234U G 880.5 1 1.5E-7 4 (+E2) -234U G 980.3 1 420E-10 0 (E2) 0.0115223 -234U 2 G KC=0.00866 18$LC=0.00214 4$MC=5.34E-4 11 +234U G 727.8 2 2.7E-9 3(E2) 0.0207 4 +234U 2 G KC=0.01464 29$LC=0.00454 9$MC=1156E-6 23 +234U G 880.5 1 1.5E-7 4(+E2) +234U G 980.3 1 4.2E-8 (E2) 0.0115223 +234U 2 G KC=0.00866 18$LC=0.00214 4$MC=5.34E-4 11 234U L 1044.536 230+ 234U A 4472.1 2 11700E-17 7.5 234U G 192.91 7 66E-11 20[E2] 0.856 17 234U 2 G KC=0.1635 33$LC=0.505 10$MC=0.1391 28 234U G 234.6 2 234U G 258.227 3 7.0E-8 11(E1) 0.0548 11 -234U 2 G KC=0.0434 9$LC=0.00859 17$MC=0.00207 4 -234U G 1001.03 3 9.8E-7 4 E2 0.0110722 -234U 2 G KC=0.00835 17$LC=0.00204 4$MC=5.07E-4 11 +234U 2 G KC=0.0434 9$LC=0.00859 17$MC=0.00207 4 +234U G 1001.03 3 9.8E-7 4E2 0.0110722 +234U 2 G KC=0.00835 17$LC=0.00204 4$MC=5.07E-4 11 234U L 1085.26 4 2+ 234U A 4432.1 2 12000E-1 3.5 234U G 233.6 2 (+E2) -234U G 235.9 3 9E-9 5 [E1] 0.0673 14 -234U 2 G KC=0.0532 11$LC=0.01067 21$MC=0.00258 5 -234U G 299.1 2 4.4E-8 3 [E1] 0.0395 8 -234U 2 G KC=0.0314 6$LC=0.00608 12$MC=1466E-6 29 +234U G 235.9 3 9E-9 5[E1] 0.0673 14 +234U 2 G KC=0.0532 11$LC=0.01067 21$MC=0.00258 5 +234U G 299.1 2 4.4E-8 3[E1] 0.0395 8 +234U 2 G KC=0.0314 6$LC=0.00608 12$MC=1466E-6 29 234U G 941.94 104.66E-7 23[E2] 0.0124425 -234U 2 G KC=0.00929 20$LC=0.00236 5$MC=5.89E-4 12 +234U 2 G KC=0.00929 20$LC=0.00236 5$MC=5.89E-4 12 234U G 1041.7 2 1.97E-7 16(+E2) -234U G 1085.4 2 7.7E-8 9 (E2) 0.0095019 -234U 2 G KC=0.00725 15$LC=0.00169 3$MC=4.18E-4 8 +234U G 1085.4 2 7.7E-8 9(E2) 0.0095019 +234U 2 G KC=0.00725 15$LC=0.00169 3$MC=4.18E-4 8 diff --git a/HEN_HOUSE/spectra/lnhb/Pu-239.txt b/HEN_HOUSE/spectra/lnhb/Pu-239.txt index c98228681..9440b4dac 100644 --- a/HEN_HOUSE/spectra/lnhb/Pu-239.txt +++ b/HEN_HOUSE/spectra/lnhb/Pu-239.txt @@ -11,505 +11,500 @@ 235U 8C 1992Co10, 1992Fr04, 1992Ba08, 1993Ga28, 1993Sc22, 1994Mo36, 1994Ra27, 235U 9C 1994Le37, 1994Le28, 1995Jo23, 1996Sa24, 1996Sc06, 1996Vi07, 1997Bu23, 235U 10C 1997Ko52, 1999ScZX, 1999Sa19, 2002Da21, 2002Ba85, 2003Au03, 2003Br12 -235U T Auger electrons and ^X ray energies and emission intensities: -235U T {U Energy (keV)} {U Intensity } {U Line } +235U T Auger electrons and X ray energies and emission intensities: +235U T {U Energy (keV)} {U Intensity} {U Line} 235U T -235U T 94.666 0.00418 4 XKA2 -235U T 98.44 0.00661 9 XKA1 +235U T 94.666 0.00418 4 XKA2 +235U T 98.44 0.00661 9 XKA1 235U T -235U T 110.421 |] XKB3 -235U T 111.298 |] 0.00239 3 XKB1 -235U T 111.964 |] XKB5II +235U T 110.421 |] XKB3 +235U T 111.298 |] 0.00239 3 XKB1 +235U T 111.964 |] XKB5II 235U T -235U T 114.407 |] XKB2 -235U T 115.012 |] 0.00131 6 XKB4 -235U T 115.377 |] XKO23 +235U T 114.407 |] XKB2 +235U T 115.012 |] 0.00131 6 XKB4 +235U T 115.377 |] XKO23 235U T -235U T 11.619-20.714 4.66 5 XL (total) -235U T 11.619 0.1008 11 XLL -235U T 13.438-13.615 1.65 3 XLA -235U T 15.399 0.0537 19 XLC -235U T 15.727-18.206 2.288 23 XLB -235U T 19.507-20.714 0.569 6 XLG +235U T 11.619-20.714 4.66 5 XL (total) +235U T 11.619 0.1008 11 XLL +235U T 13.438-13.615 1.65 3 XLA +235U T 15.399 0.0537 19 XLC +235U T 15.727-18.206 2.288 23 XLB +235U T 19.507-20.714 0.569 6 XLG 235U T -235U T 71.78-80.95 |] KLL AUGER -235U T 88.15-98.34 |] 0.00045 6 ^KLX AUGER -235U T 104.42-115.4 |] KXY AUGER -235U T 5.9-21.6 4.66 19 L AUGER +235U T 71.78-80.95 |] KLL AUGER +235U T 88.15-98.34 |] 0.00045 6 KLX AUGER +235U T 104.42-115.4 |] KXY AUGER +235U T 5.9-21.6 4.66 19 L AUGER 239PU P 0.0 1/2+ 24100 Y 11 5244.51 21 235U N 1.0 1.0 1 1.0 -235U G 14.22 3 0.0055 4 -235U G 40.41 5 1.63E-4 16 -235U G 74.96 103.8E-5 6 -235U G 184.55 5 2.1E-6 6 [M1] 3.87 8 -235U G 193.13 129.0E-6 9 -235U G 196.87 5 3.7E-6 4 -235U G 350.8 3 1.8E-6 4 +235U G 14.22 3 0.0055 4 +235U G 40.41 5 0.00016316 +235U G 74.96 100.000038 6 +235U G 184.55 5 2.1E-6 6[M1] 3.87 8 +235U G 193.13 129.0E-6 9 +235U G 196.87 5 3.7E-6 4 +235U G 350.8 3 1.8E-6 4 235U G 446.82 208.5E-7 13 235U G 497.0 5 4.4E-8 25 235U G 538.8 2 3.09E-7 19 235U G 557.3 5 3.8E-8 19 235U G 608.9 2 1.17E-7 12 -235U G 650.53 6 2.7E-7 4 -235U G 685.97 111.26E-6 6 E1 0.0073615 +235U G 650.53 6 2.7E-7 4 +235U G 685.97 111.26E-6 6E1 0.0073615 235U G 688.1 3 1.12E-7 11 235U G 693.2 5 3.2E-8 13 235U G 699.6 5 8.0E-8 16 -235U G 712.96 5 5.2E-8 6 +235U G 712.96 5 5.2E-8 6 235U G 742.7 5 3.8E-8 11 -235U G 777.1 3 2.8E-8 7 -235U G 786.9 2 8.7E-8 9 E2 0.0177 4 -235U G 788.5 3 3.5E-8 7 -235U G 796.9 3 1.5E-8 3 -235U G 803.2 2 6.4E-8 5 -235U G 826.8 3 1.8E-8 6 -235U G 828.9 2 1.34E-7 8 -235U G 837.3 2 2.0E-8 4 +235U G 777.1 3 2.8E-8 7 +235U G 786.9 2 8.7E-8 9E2 0.0177 4 +235U G 788.5 3 3.5E-8 7 +235U G 796.9 3 1.5E-8 3 +235U G 803.2 2 6.4E-8 5 +235U G 826.8 3 1.8E-8 6 +235U G 828.9 2 1.34E-7 8 +235U G 837.3 2 2.0E-8 4 235U G 895.4 3 7.6E-9 25 -235U G 898.1 3 1.8E-8 4 +235U G 898.1 3 1.8E-8 4 235U G 905.5 3 7.6E-9 25 -235U G 911.7 3 1.4E-8 3 -235U G 931.9 3 1.3E-8 4 +235U G 911.7 3 1.4E-8 3 +235U G 931.9 3 1.3E-8 4 235U G 982.7 3 1.07E-8 25 235U G 1009.4 3 1.39E-8 25 235U L 0 7/2- 704E6 Y 1 235U A 5156.65 210.03 6500 235U L 0.0765 4 1/2+ 26 M 235U A 5156.59 1470.79 102.762 -235U 2 G KC=$LC=$MC= +235U G 0.0765 4 1E-8 E3 10E9 235U L 13.0400 213/2+ 0.50 NS 3 235U A 5143.82 2117.14 4 9.47 -235U G 12.975 100.0341 9 M1+()E2 607 17 -235U 2 G KC=$LC=$MC=451 13 +235U G 12.975 100.0341 9M1+()E2 607 17 +235U 2 G MC=451 13 235U L 46.207 109/2- 235U A 5111.21 210.02 5019 -235U G 46.21 5 7.26E-4 13M1+()E2 52.6 27 -235U 2 G KC=$LC=39.4 19$MC=9.8 5 +235U G 46.21 5 0.00072613M1+()E2 52.6 27 +235U 2 G LC=39.4 19$MC=9.8 5 235U L 51.7007 115/2+ 191 PS 5 235U A 5105.81 2111.87 3 7.81 235U G 38.661 2 0.01047 21M1+()E2 339 19 -235U 2 G KC=$LC=249 14$MC=67 4 -235U G 51.624 1 0.02694 26E2 310 6 -235U 2 G KC=$LC=226 5$MC=62.6 13 +235U 2 G LC=249 14$MC=67 4 +235U G 51.624 1 0.02694 26E2 310 6 +235U 2 G LC=226 5$MC=62.6 13 235U L 81.741 4 7/2+ 235U A 5076.28 210.052 8 1150 -235U G 30.04 2 2.19E-4 8 (M1) 157 3 -235U 2 G KC=$LC=118.0 24$MC=28.7 6 +235U G 30.04 2 0.000219 8(M1) 157 3 +235U 2 G LC=118.0 24$MC=28.7 6 235U G 68.696 6 0.00036 10E2 78.6 16 -235U 2 G KC=$LC=57.3 11$MC=15.9 3 +235U 2 G LC=57.3 11$MC=15.9 3 235U L 103.035 1011/2- 235U A 5055.34 210.0375 121160 -235U G 56.828 3 1136E-6 15M1+()E2 32.6 15 -235U 2 G KC=$LC=24.3 11$MC=6.14 30 -235U G 103.06 3 2.17E-4 6 E2 11.58 23 -235U 2 G KC=$LC=8.44 17$MC=2.34 5 +235U G 56.828 3 0.00113615M1+()E2 32.6 15 +235U 2 G LC=24.3 11$MC=6.14 30 +235U G 103.06 3 0.000217 6E2 11.58 23 +235U 2 G LC=8.44 17$MC=2.34 5 235U L 129.2961 105/2+ 235U A 5029.51 210.013 4 2270 -235U G 47.60 3 6.25E-5 25(M1) 40.4 8 -235U 2 G KC=$LC=30.4 6$MC=7.37 15 -235U G 77.592 143.80E-4 6 M1(+()E2) 17 10 -235U 2 G KC=$LC=12 7$MC=3.2 21 -235U G 116.26 2 5.81E-4 19M1+()E2 12.2 26 -235U 2 G KC=8.4 18$LC=2.9 6$MC=0.74 16 -235U G 129.296 1 0.00631 4 E1 0.275 6 -235U 2 G KC=0.211 4$LC=0.0482 10$MC=0.01173 24 +235U G 47.60 3 6.25E-5 25(M1) 40.4 8 +235U 2 G LC=30.4 6$MC=7.37 15 +235U G 77.592 140.000380 6M1(+()E2) 17 10 +235U 2 G LC=12 7$MC=3.2 21 +235U G 116.26 2 0.00058119M1+()E2 12.2 26 +235U 2 G KC=8.4 18$LC=2.9 6$MC=0.74 16 +235U G 129.296 1 0.00631 4E1 0.275 6 +235U 2 G KC=0.211 4$LC=0.0482 10$MC=0.01173 24 235U L 150.467 159/2+ 235U A 5008.70 210.0182 271180 -235U G 68.73 2 0.00013 6 (M1+E2) 27.00000 -235U 2 G KC=$LC=20.0000 0$MC=5.20000 0 -235U G 98.78 2 0.00135 11E2 14.1 3 -235U 2 G KC=$LC=10.28 21$MC=2.85 6 +235U G 68.73 2 0.00013 6(M1+E2) 27 +235U 2 G LC=20 $MC=5.2 +235U G 98.78 2 0.00135 11E2 14.1 3 +235U 2 G LC=10.28 21$MC=2.85 6 235U L 170.708 1413/2- -235U G 67.674 121.58E-4 5 M1+()E2 16.9 5 -235U 2 G KC=$LC=12.7 4$MC=3.15 9 +235U G 67.674 120.000158 5M1+()E2 16.9 5 +235U 2 G LC=12.7 4$MC=3.15 9 235U G 124.51 3 6.81E-5 19E2 5.06 10 -235U 2 G KC=0.214 4$LC=3.53 7$MC=0.978 20 +235U 2 G KC=0.214 4$LC=3.53 7$MC=0.978 20 235U L 171.388 5 7/2+ 235U A 4988.13 210.0034 104600 -235U G 41.93 5 1.63E-4 8 (M1) 58.6 12 -235U 2 G KC=$LC=44.2 9$MC=10.71 21 -235U G 89.64 3 2.7E-5 2 (M1+E2) 14 8 -235U 2 G KC=$LC=11 6$MC=2.8 17 -235U G 119.70 3 2.1E-5 3 (M1+E2) 9 4 -235U 2 G KC=5 5$LC=3.1 11$MC=0.8 3 -235U G 125.21 105.63E-5 16[E1] 0.296 6 -235U 2 G KC=0.227 5$LC=0.0523 10$MC=0.0128 3 -235U G 158.1 3 1.01E-6 10[E2] 1.86 4 -235U 2 G KC=0.211 4$LC=1.200 24$MC=0.333 7 -235U G 171.393 6 1.10E-4 3 [E1] 0.141 3 -235U 2 G KC=0.1103 22$LC=0.0235 5$MC=0.00570 11 +235U G 41.93 5 0.000163 8(M1) 58.6 12 +235U 2 G LC=44.2 9$MC=10.71 21 +235U G 89.64 3 0.000027 2(M1+E2) 14 8 +235U 2 G LC=11 6$MC=2.8 17 +235U G 119.70 3 0.000021 3(M1+E2) 9 4 +235U 2 G KC=5 5$LC=3.1 11$MC=0.8 3 +235U G 125.21 105.63E-5 16[E1] 0.296 6 +235U 2 G KC=0.227 5$LC=0.0523 10$MC=0.0128 3 +235U G 158.1 3 1.01E-6 10[E2] 1.86 4 +235U 2 G KC=0.211 4$LC=1.200 24$MC=0.333 7 +235U G 171.393 6 0.000110 3[E1] 0.141 3 +235U 2 G KC=0.1103 22$LC=0.0235 5$MC=0.00570 11 235U L 197.119 1411/2+ 235U A 4962.83 210.007 1 1520 -235U G 46.68 3 5.0E-5 6 M1+()E2 86 24 -235U 2 G KC=$LC=63 17$MC=17 5 -235U G 115.38 5 0.00046 5 E2 6.87 14 -235U 2 G KC=$LC=5.0 1$MC=1.39 3 +235U G 46.68 3 0.000050 6M1+()E2 86 24 +235U 2 G LC=63 17$MC=17 5 +235U G 115.38 5 0.00046 5E2 6.87 14 +235U 2 G LC=5.0 1$MC=1.39 3 235U L 225.423 8 9/2+ 235U A 4935.00 210.0050 7 1380 -235U G 54.039 8 1943E-7 28M1 27.8 6 -235U 2 G KC=$LC=21.0 4$MC=5.08 10 -235U G 96.14 3 3.79E-5 19[E2] 16.0 3 -235U 2 G KC=$LC=11.67 23$MC=3.24 7 -235U G 122.35 129.5E-7 13(E1) 0.312 6 -235U 2 G KC=0.238 5$LC=0.0556 11$MC=0.0135 3 -235U G 143.35 201.74E-5 8 [M1+E2] 5.3 26 -235U 2 G KC=3.3 30$LC=1.5 3$MC=0.41 11 -235U G 173.70 5 3.1E-6 8 [E2] 1.28 3 -235U 2 G KC=0.190 4$LC=0.795 16$MC=0.220 4 -235U G 179.220 126.56E-5 19[E1] 0.127 3 -235U 2 G KC=0.0995 20$LC=0.0210 4$MC=0.00509 10 -235U G 225.42 4 1.50E-5 4 [E1] 0.0747 15 -235U 2 G KC=0.0589 12$LC=0.01190 24$MC=0.00288 6 +235U G 54.039 8 1.943E-428M1 27.8 6 +235U 2 G LC=21.0 4$MC=5.08 10 +235U G 96.14 3 3.79E-5 19[E2] 16.0 3 +235U 2 G LC=11.67 23$MC=3.24 7 +235U G 122.35 129.5E-7 13(E1) 0.312 6 +235U 2 G KC=0.238 5$LC=0.0556 11$MC=0.0135 3 +235U G 143.35 201.74E-5 8[M1+E2] 5.3 26 +235U 2 G KC=3.3 30$LC=1.5 3$MC=0.41 11 +235U G 173.70 5 3.1E-6 8[E2] 1.28 3 +235U 2 G KC=0.190 4$LC=0.795 16$MC=0.220 4 +235U G 179.220 126.56E-5 19[E1] 0.127 3 +235U 2 G KC=0.0995 20$LC=0.0210 4$MC=0.00509 10 +235U G 225.42 4 1.50E-5 4[E1] 0.0747 15 +235U 2 G KC=0.0589 12$LC=0.01190 24$MC=0.00288 6 235U L 249.130 1215/2- 235U A 4911.69 210.0030 161590 -235U G 78.43 2 1533E-7 28M1(+()E2) 16 10 -235U 2 G KC=$LC=12 7$MC=3.1 20 -235U G 146.094 6 1.21E-4 3 E2 2.57 5 -235U 2 G KC=0.223 4$LC=1.71 3$MC=0.474 10 +235U G 78.43 2 1.533E-428M1(+()E2) 16 10 +235U 2 G LC=12 7$MC=3.1 20 +235U G 146.094 6 0.000121 3E2 2.57 5 +235U 2 G KC=0.223 4$LC=1.71 3$MC=0.474 10 235U L 291.144 1911/2+ 235U A 4870.38 210.0007 3 3500 -235U G 65.708 304.73E-5 25M1+()E2 19 6 -235U 2 G KC=$LC=14 5$MC=3.6 13 -235U G 119.76 2 9E-6 2 [E2] 5.99 12 -235U 2 G KC=0.200 4$LC=4.22 8$MC=1.169 23 +235U G 65.708 304.73E-5 25M1+()E2 19 6 +235U 2 G LC=14 5$MC=3.6 13 +235U G 119.76 2 0.000009 2[E2] 5.99 12 +235U 2 G KC=0.200 4$LC=4.22 8$MC=1.169 23 235U G 188.23 101.10E-5 11[E1] 0.1140 23 -235U 2 G KC=0.0889 18$LC=0.0186 4$MC=0.00450 9 -235U G 244.92 5 5.1E-6 5 0.0618 12 -235U 2 G KC=0.0485 10$LC=0.00973 19$MC=0.00235 5 +235U 2 G KC=0.0889 18$LC=0.0186 4$MC=0.00450 9 +235U G 244.92 5 5.1E-6 5 0.0618 12 +235U 2 G KC=0.0485 10$LC=0.00973 19$MC=0.00235 5 235U L 294.669 1513/2+ 235U A 4866.91 210.0018 5 1300 -235U G 97.6 3 0.00009 6 M1+()E2 7.0 19 -235U 2 G KC=$LC=5.2 14$MC=1.3 4 -235U G 144.201 3 2.85E-4 7 E2 2.72 5 -235U 2 G KC=0.225 5$LC=1.82 4$MC=0.502 10 +235U G 97.6 3 0.00009 6M1+()E2 7.0 19 +235U 2 G LC=5.2 14$MC=1.3 4 +235U G 144.201 3 0.000285 7E2 2.72 5 +235U 2 G KC=0.225 5$LC=1.82 4$MC=0.502 10 235U L 332.845 4 5/2+ 235U A 4829.38 210.00354 7 363 -235U G 161.450 151.22E-4 6 (M1) 5.67 11 -235U 2 G KC=4.51 9$LC=0.880 18$MC=0.213 4 -235U G 203.550 5 5.63E-4 9 M1 2.95 6 -235U 2 G KC=2.35 5$LC=0.456 9$MC=0.1103 22 -235U G 281.2 2 2.1E-6 3 [M1+E2] 0.7 5 -235U 2 G KC=0.5 4$LC=0.14 4$MC=0.036 8 -235U G 319.68 104.9E-6 5 [M1+E2] 0.50 35 -235U 2 G KC=0.37 30$LC=0.10 3$MC=0.024 7 -235U G 332.845 5 4.88E-4 8 E1 0.0313 6 -235U 2 G KC=0.0250 5$LC=0.00476 10$MC=1150E-6 23 +235U G 161.450 150.000122 6(M1) 5.67 11 +235U 2 G KC=4.51 9$LC=0.880 18$MC=0.213 4 +235U G 203.550 5 0.000563 9M1 2.95 6 +235U 2 G KC=2.35 5$LC=0.456 9$MC=0.1103 22 +235U G 281.2 2 2.1E-6 3[M1+E2] 0.7 5 +235U 2 G KC=0.5 4$LC=0.14 4$MC=0.036 8 +235U G 319.68 104.9E-6 5[M1+E2] 0.50 35 +235U 2 G KC=0.37 30$LC=0.10 3$MC=0.024 7 +235U G 332.845 5 0.000488 8E1 0.0313 6 +235U 2 G KC=0.0250 5$LC=0.00476 10$MC=1150E-6 23 235U L 338.52 6 17/2- 235U A 4823.80 2222000E-9 53000 -235U G 89.39 6 2000E-9 0 [M1] 6.40 13 -235U 2 G KC=$LC=4.82 10$MC=1.167 23 -235U G 167.81 5 3.0E-6 8 [E2] 1.47 3 -235U 2 G KC=0.198 4$LC=0.925 19$MC=0.256 5 +235U G 89.39 6 0.000002 [M1] 6.40 13 +235U 2 G LC=4.82 10$MC=1.167 23 +235U G 167.81 5 3.0E-6 8[E2] 1.47 3 +235U 2 G KC=0.198 4$LC=0.925 19$MC=0.256 5 235U L 357.30 6 15/2+ 235U A 4805.33 2217000E-94 51000 -235U G 160.19 5 6.2E-6 13[E2] 1.77 4 -235U 2 G KC=0.208 4$LC=1.140 23$MC=0.314 6 +235U G 160.19 5 6.2E-6 13[E2] 1.77 4 +235U 2 G KC=0.208 4$LC=1.140 23$MC=0.314 6 235U L 367.069 8 7/2+ 235U A 4795.73 2194400E-817788 235U G 141.657 203.21E-5 10[M1] 8.22 16 -235U 2 G KC=6.52 13$LC=1.28 3$MC=0.309 6 -235U G 195.679 8 1.06E-4 2 M1 3.30 7 -235U 2 G KC=2.62 5$LC=0.51 1$MC=0.123 3 -235U G 237.77 101.45E-5 6 [M1] 1.91 4 -235U 2 G KC=1.52 3$LC=0.295 6$MC=0.0712 14 -235U G 285.3 2 1.9E-6 4 [M1+E2] 0.7 5 -235U 2 G KC=0.5 4$LC=0.14 4$MC=0.035 8 -235U G 320.862 205.40E-5 12[E1] 0.0337 7 -235U 2 G KC=0.0269 5$LC=0.00517 10$MC=0.00125 3 +235U 2 G KC=6.52 13$LC=1.28 3$MC=0.309 6 +235U G 195.679 8 0.000106 2M1 3.30 7 +235U 2 G KC=2.62 5$LC=0.51 1$MC=0.123 3 +235U G 237.77 101.45E-5 6[M1] 1.91 4 +235U 2 G KC=1.52 3$LC=0.295 6$MC=0.0712 14 +235U G 285.3 2 1.9E-6 4[M1+E2] 0.7 5 +235U 2 G KC=0.5 4$LC=0.14 4$MC=0.035 8 +235U G 320.862 205.40E-5 12[E1] 0.0337 7 +235U 2 G KC=0.0269 5$LC=0.00517 10$MC=0.00125 3 235U G 354.0 5 7.6E-7 30[E2] 0.1150 23 -235U 2 G KC=0.0549 11$LC=0.0445 9$MC=0.01200 24 -235U G 367.073 258.71E-5 20[E1] 0.0254 5 -235U 2 G KC=0.0203 4$LC=0.00382 8$MC=9.20E-4 18 +235U 2 G KC=0.0549 11$LC=0.0445 9$MC=0.01200 24 +235U G 367.073 258.71E-5 20[E1] 0.0254 5 +235U 2 G KC=0.0203 4$LC=0.00382 8$MC=9.20E-4 18 235U L 393.225 6 3/2+ 235U A 4770.01 210.00125 3 390 -235U G 263.95 3 2.59E-5 10M1 1.43 3 -235U 2 G KC=1.140 23$LC=0.220 4$MC=0.0532 11 +235U G 263.95 3 2.59E-5 10M1 1.43 3 +235U 2 G KC=1.140 23$LC=0.220 4$MC=0.0532 11 235U G 341.506 106.50E-5 13M1 0.701 14 -235U 2 G KC=0.559 11$LC=0.1080 22$MC=0.0260 5 -235U G 380.191 6 3.02E-4 4 M1 0.523 10 -235U 2 G KC=0.417 8$LC=0.0801 16$MC=0.0193 4 -235U G 393.14 3 4.19E-4 17M1 0.477 10 -235U 2 G KC=0.380 8$LC=0.0731 15$MC=0.0176 4 +235U 2 G KC=0.559 11$LC=0.1080 22$MC=0.0260 5 +235U G 380.191 6 0.000302 4M1 0.523 10 +235U 2 G KC=0.417 8$LC=0.0801 16$MC=0.0193 4 +235U G 393.14 3 0.00041917M1 0.477 10 +235U 2 G KC=0.380 8$LC=0.0731 15$MC=0.0176 4 235U L 414.779 119/2+ 235U A 4748.81 210.00075 11460 -235U G 123.62 5 2.37E-5 9 [M1] 12.08 24 -235U 2 G KC=9.57 19$LC=1.89 4$MC=0.457 9 +235U G 123.62 5 2.37E-5 9[M1] 12.08 24 +235U 2 G KC=9.57 19$LC=1.89 4$MC=0.457 9 235U G 189.36 1 8.20E-5 14[M1+E2] 2.3 14 -235U 2 G KC=1.5 13$LC=0.553 11$MC=0.143 8 +235U 2 G KC=1.5 13$LC=0.553 11$MC=0.143 8 235U G 218.0 5 1.2E-6 10 -235U G 243.38 3 2.54E-5 7 [M1+E2] 1.1 7 -235U 2 G KC=0.8 6$LC=0.23 4$MC=0.059 7 -235U G 311.78 4 2.57E-5 8 [E1] 0.0361 7 -235U 2 G KC=0.0287 6$LC=0.00552 11$MC=0.00133 3 -235U G 368.554 208.77E-5 14[E1] 0.0252 5 -235U 2 G KC=0.0202 4$LC=0.00378 8$MC=9.10E-4 18 +235U G 243.38 3 2.54E-5 7[M1+E2] 1.1 7 +235U 2 G KC=0.8 6$LC=0.23 4$MC=0.059 7 +235U G 311.78 4 2.57E-5 8[E1] 0.0361 7 +235U 2 G KC=0.0287 6$LC=0.00552 11$MC=0.00133 3 +235U G 368.554 208.77E-5 14[E1] 0.0252 5 +235U 2 G KC=0.0202 4$LC=0.00378 8$MC=9.10E-4 18 235U L 426.755 3 5/2+ 235U A 4737.05 210.00570 5 49.6 -235U G 255.384 157.95E-5 20[M1] 1.57 3 -235U 2 G KC=1.25 3$LC=0.241 5$MC=0.0583 12 +235U G 255.384 157.95E-5 20[M1] 1.57 3 +235U 2 G KC=1.25 3$LC=0.241 5$MC=0.0583 12 235U G 297.46 3 4.92E-5 13[M1] 1.025 21 -235U 2 G KC=0.816 16$LC=0.158 3$MC=0.0381 8 -235U G 345.013 4 5.48E-4 8 M1 0.682 14 -235U 2 G KC=0.543 11$LC=0.1050 21$MC=0.0253 5 -235U G 375.054 3 1540E-6 21M1 0.543 11 -235U 2 G KC=0.432 9$LC=0.0832 17$MC=0.0201 4 -235U G 413.713 5 1464E-6 21M1 0.415 8 -235U 2 G KC=0.331 7$LC=0.0636 13$MC=0.0153 3 -235U G 426.68 3 2.39E-5 6 [E2] 0.0699 14 -235U 2 G KC=0.0387 8$LC=0.0230 5$MC=0.00610 12 +235U 2 G KC=0.816 16$LC=0.158 3$MC=0.0381 8 +235U G 345.013 4 0.000548 8M1 0.682 14 +235U 2 G KC=0.543 11$LC=0.1050 21$MC=0.0253 5 +235U G 375.054 3 0.00154021M1 0.543 11 +235U 2 G KC=0.432 9$LC=0.0832 17$MC=0.0201 4 +235U G 413.713 5 0.00146421M1 0.415 8 +235U 2 G KC=0.331 7$LC=0.0636 13$MC=0.0153 3 +235U G 426.68 3 2.39E-5 6[E2] 0.0699 14 +235U 2 G KC=0.0387 8$LC=0.0230 5$MC=0.00610 12 235U L 445.716 207/2+ 235U A 4718.39 2140000E-9115200 -235U G 316.41 3 1.33E-5 5 M1 0.865 17 -235U 2 G KC=0.689 14$LC=0.133 3$MC=0.0321 6 -235U G 399.53 6 6.12E-6 26[E1] 0.0213 4 -235U 2 G KC=0.0171 3$LC=0.00317 6$MC=7.61E-4 15 -235U G 445.72 3 8.77E-6 26E1 0.0170 3 -235U 2 G KC=0.0137 3$LC=0.00250 5$MC=5.60E-4 11 +235U G 316.41 3 1.33E-5 5M1 0.865 17 +235U 2 G KC=0.689 14$LC=0.133 3$MC=0.0321 6 +235U G 399.53 6 6.12E-6 26[E1] 0.0213 4 +235U 2 G KC=0.0171 3$LC=0.00317 6$MC=7.61E-4 15 +235U G 445.72 3 8.77E-6 26E1 0.0170 3 +235U 2 G KC=0.0137 3$LC=0.00250 5$MC=5.60E-4 11 235U L 474.297 137/2+ 235U A 4690.29 210.00056 5 230 -235U G 248.95 5 7.0E-6 6 [M1] 1.68 3 -235U 2 G KC=1.34 3$LC=0.259 5$MC=0.0626 14 -235U G 302.87 5 4.9E-6 4 [M1] 0.976 20 -235U 2 G KC=0.777 16$LC=0.150 3$MC=0.0362 7 +235U G 248.95 5 7.0E-6 6[M1] 1.68 3 +235U 2 G KC=1.34 3$LC=0.259 5$MC=0.0626 14 +235U G 302.87 5 4.9E-6 4[M1] 0.976 20 +235U 2 G KC=0.777 16$LC=0.150 3$MC=0.0362 7 235U G 323.84 3 5.30E-5 13M1 0.811 16 -235U 2 G KC=0.646 13$LC=0.1246 25$MC=0.0301 6 -235U G 345.00 2 5000E-8 0 (M1) 0.682 14 -235U 2 G KC=0.543 11$LC=0.1050 21$MC=0.0253 5 -235U G 392.53 3 1.21E-4 16M1 0.479 10 -235U 2 G KC=0.382 8$LC=0.0731 15$MC=0.0177 4 -235U G 422.598 191199E-7 20M1 0.392 8 -235U 2 G KC=0.313 6$LC=0.0560 11$MC=0.0145 3 -235U G 428.4 3 1.01E-6 10[E1] 0.0184 4 -235U 2 G KC=0.0147 3$LC=0.00270 5$MC=6.53E-4 13 -235U G 461.25 5 2.29E-6 5 [E2] 0.0575 12 -235U 2 G KC=0.0334 7$LC=0.0177 4$MC=0.00467 9 -235U G 473.9 5 6E-8 3 [E1] 0.0150 3 -235U 2 G KC=0.01210 24$LC=0.00220 4$MC=5.26E-4 11 +235U 2 G KC=0.646 13$LC=0.1246 25$MC=0.0301 6 +235U G 345.00 2 0.00005 (M1) 0.682 14 +235U 2 G KC=0.543 11$LC=0.1050 21$MC=0.0253 5 +235U G 392.53 3 0.00012116M1 0.479 10 +235U 2 G KC=0.382 8$LC=0.0731 15$MC=0.0177 4 +235U G 422.598 191.199E-420M1 0.392 8 +235U 2 G KC=0.313 6$LC=0.0560 11$MC=0.0145 3 +235U G 428.4 3 1.01E-6 10[E1] 0.0184 4 +235U 2 G KC=0.0147 3$LC=0.00270 5$MC=6.53E-4 13 +235U G 461.25 5 2.29E-6 5[E2] 0.0575 12 +235U 2 G KC=0.0334 7$LC=0.0177 4$MC=0.00467 9 +235U G 473.9 5 6E-8 3[E1] 0.0150 3 +235U 2 G KC=0.01210 24$LC=0.00220 4$MC=5.26E-4 11 235U L 509.92 17(9/2+)+ 235U A 4655.27 2733000E-17 22000 -235U G 406.8 2 2.9E-6 7 [E1] 0.0204 4 -235U 2 G KC=0.0164 3$LC=0.00304 6$MC=7.31E-4 15 -235U G 463.9 3 2.8E-7 3 [E1] 0.0157 3 -235U 2 G KC=0.0126 3$LC=0.00230 5$MC=5.51E-4 11 +235U G 406.8 2 2.9E-6 7[E1] 0.0204 4 +235U 2 G KC=0.0164 3$LC=0.00304 6$MC=7.31E-4 15 +235U G 463.9 3 2.8E-7 3[E1] 0.0157 3 +235U 2 G KC=0.0126 3$LC=0.00230 5$MC=5.51E-4 11 235U L 533.228 109/2+ 235U A 4632.35 210.00086 3 55.8 -235U G 242.08 3 7.4E-6 5 [M1] 1.82 4 -235U 2 G KC=1.45 3$LC=0.280 6$MC=0.0678 14 -235U G 307.85 5 5.2E-6 4 [M1] 0.933 19 -235U 2 G KC=0.743 15$LC=0.143 3$MC=0.0346 7 -235U G 336.113 121111E-7 26M1 0.733 15 -235U 2 G KC=0.583 12$LC=0.1130 23$MC=0.0272 5 -235U G 361.89 5 1.17E-5 7 [M1] 0.598 12 -235U 2 G KC=0.477 10$LC=0.0918 18$MC=0.0222 4 -235U G 382.75 5 2.56E-4 4 M1 0.513 10 -235U 2 G KC=0.409 8$LC=0.0787 16$MC=0.0190 4 -235U G 430.08 104.29E-6 19[E1] 0.0183 4 -235U 2 G KC=0.0147 3$LC=0.00270 5$MC=6.48E-4 13 -235U G 451.481 101.87E-4 3 M1(+E2) 0.19 13 -235U 2 G KC=0.15 11$LC=0.035 16$MC=0.009 4 +235U G 242.08 3 7.4E-6 5[M1] 1.82 4 +235U 2 G KC=1.45 3$LC=0.280 6$MC=0.0678 14 +235U G 307.85 5 5.2E-6 4[M1] 0.933 19 +235U 2 G KC=0.743 15$LC=0.143 3$MC=0.0346 7 +235U G 336.113 121.111E-426M1 0.733 15 +235U 2 G KC=0.583 12$LC=0.1130 23$MC=0.0272 5 +235U G 361.89 5 1.17E-5 7[M1] 0.598 12 +235U 2 G KC=0.477 10$LC=0.0918 18$MC=0.0222 4 +235U G 382.75 5 0.000256 4M1 0.513 10 +235U 2 G KC=0.409 8$LC=0.0787 16$MC=0.0190 4 +235U G 430.08 104.29E-6 19[E1] 0.0183 4 +235U 2 G KC=0.0147 3$LC=0.00270 5$MC=6.48E-4 13 +235U G 451.481 100.000187 3M1(+E2) 0.19 13 +235U 2 G KC=0.15 11$LC=0.035 16$MC=0.009 4 235U G 481.66 124.61E-6 10[E2] 0.0517 10 -235U 2 G KC=0.0309 6$LC=0.0154 3$MC=0.00404 8 -235U G 487.06 102.65E-7 19[E1] 0.0142 3 -235U 2 G KC=0.01150 23$LC=0.00208 4$MC=4.97E-4 10 +235U 2 G KC=0.0309 6$LC=0.0154 3$MC=0.00404 8 +235U G 487.06 102.65E-7 19[E1] 0.0142 3 +235U 2 G KC=0.01150 23$LC=0.00208 4$MC=4.97E-4 10 235U L 608.08 5 11/2+ 235U A 4558.75 2212000E-94 1110 -235U G 411.2 3 6.9E-6 30[M1] 0.422 8 -235U 2 G KC=0.337 7$LC=0.0646 13$MC=0.0156 3 -235U G 457.61 5 1.51E-6 3 [M1] 0.316 6 -235U 2 G KC=0.252 5$LC=0.0483 10$MC=0.01170 23 -235U G 526.4 4 5.7E-8 19[E2] 0.0419 8 -235U 2 G KC=0.0262 5$LC=1160E-5 2$MC=0.00303 6 +235U G 411.2 3 6.9E-6 30[M1] 0.422 8 +235U 2 G KC=0.337 7$LC=0.0646 13$MC=0.0156 3 +235U G 457.61 5 1.51E-6 3[M1] 0.316 6 +235U 2 G KC=0.252 5$LC=0.0483 10$MC=0.01170 23 +235U G 526.4 4 5.7E-8 19[E2] 0.0419 8 +235U 2 G KC=0.0262 5$LC=1160E-5 2$MC=0.00303 6 235U L 633.17 6 (5/2)- 235U A 4534.08 2228400E-17 3025 -235U G 633.15 6 2.55E-6 6 M1(+E2) 0.122 11 -235U 2 G KC=0.097 8$LC=0.0187 13$MC=0.0045 3 +235U G 633.15 6 2.55E-6 6M1(+E2) 0.122 11 +235U 2 G KC=0.097 8$LC=0.0187 13$MC=0.0045 3 235U L 637.81 5 3/2- 235U A 4529.52 2232200E-1212460 -235U G 586.3 3 1.53E-7 16[E1] 0.0099 2 -235U 2 G KC=0.00802 16$LC=0.00142 3$MC=3.39E-4 7 +235U G 586.3 3 1.53E-7 16[E1] 0.0099 2 +235U 2 G KC=0.00802 16$LC=0.00142 3$MC=3.39E-4 7 235U G 624.78 5 4.60E-7 19[E1] 0.0087718 -235U 2 G KC=0.00712 14$LC=1250E-6 25$MC=2.99E-4 6 -235U G 637.73 5 6.4E-7 6 [E1] 0.0084417 -235U 2 G KC=0.00684 14$LC=1200E-6 24$MC=2.87E-4 6 -235U G 637.80 5 1.92E-6 19E2 0.0273 5 -235U 2 G KC=0.0185 4$LC=0.00655 13$MC=0.00167 3 +235U 2 G KC=0.00712 14$LC=1250E-6 25$MC=2.99E-4 6 +235U G 637.73 5 6.4E-7 6[E1] 0.0084417 +235U 2 G KC=0.00684 14$LC=1200E-6 24$MC=2.87E-4 6 +235U G 637.80 5 1.92E-6 19E2 0.0273 5 +235U 2 G KC=0.0185 4$LC=0.00655 13$MC=0.00167 3 235U L 658.97 4 1/2- 235U A 4508.72 2126400E-96 207 -235U G 265.7 3 1.6E-6 4 [E1] 0.0514 10 -235U 2 G KC=0.0408 8$LC=0.00802 16$MC=0.00194 4 -235U G 645.94 4 1.49E-5 3 E1 0.0082416 -235U 2 G KC=0.00669 13$LC=1170E-6 24$MC=2.80E-4 6 +235U G 265.7 3 1.6E-6 4[E1] 0.0514 10 +235U 2 G KC=0.0408 8$LC=0.00802 16$MC=0.00194 4 +235U G 645.94 4 1.49E-5 3E1 0.0082416 +235U 2 G KC=0.00669 13$LC=1170E-6 24$MC=2.80E-4 6 235U G 658.86 6 9.59E-6 26E1 0.0079416 -235U 2 G KC=0.00645 13$LC=1130E-6 23$MC=2.69E-4 5 +235U 2 G KC=0.00645 13$LC=1130E-6 23$MC=2.69E-4 5 235U L 664.541 23(5/2)- 235U A 4503.24 2163100E-111784 -235U G 493.08 5 8.8E-7 3 [E1] 0.0139 3 -235U 2 G KC=0.01119 22$LC=0.00202 4$MC=4.84E-4 10 -235U G 582.89 106.18E-7 26[E1] 0.0100 2 -235U 2 G KC=0.00811 16$LC=0.00144 3$MC=3.43E-4 7 -235U G 612.83 3 9.5E-7 5 E1 0.0091018 -235U 2 G KC=0.00738 15$LC=0.00130 3$MC=3.10E-4 6 -235U G 618.28 6 2.06E-6 8 (E2) 0.0292 6 -235U 2 G KC=0.0196 4$LC=0.00716 14$MC=0.00184 4 -235U G 664.58 5 1.67E-6 4 E2 0.0251 5 -235U 2 G KC=0.0172 4$LC=0.00583 12$MC=0.00149 3 +235U G 493.08 5 8.8E-7 3[E1] 0.0139 3 +235U 2 G KC=0.01119 22$LC=0.00202 4$MC=4.84E-4 10 +235U G 582.89 106.18E-7 26[E1] 0.0100 2 +235U 2 G KC=0.00811 16$LC=0.00144 3$MC=3.43E-4 7 +235U G 612.83 3 9.5E-7 5E1 0.0091018 +235U 2 G KC=0.00738 15$LC=0.00130 3$MC=3.10E-4 6 +235U G 618.28 6 2.06E-6 8(E2) 0.0292 6 +235U 2 G KC=0.0196 4$LC=0.00716 14$MC=0.00184 4 +235U G 664.58 5 1.67E-6 4E2 0.0251 5 +235U 2 G KC=0.0172 4$LC=0.00583 12$MC=0.00149 3 235U L 670.99 4 (7/2)- 235U A 4496.90 2134000E-1 130000 -235U G 624.78 3 220E-10 0 (M1) 0.137 3 -235U 2 G KC=0.1090 22$LC=0.0208 4$MC=0.00501 10 -235U G 670.99 4 9E-9 3 [M1+E2] 0.06 4 -235U 2 G KC=0.05 3$LC=0.0033 17$MC=0.0025 12 +235U G 624.78 3 2.2E-8 (M1) 0.137 3 +235U 2 G KC=0.1090 22$LC=0.0208 4$MC=0.00501 10 +235U G 670.99 4 9E-9 3[M1+E2] 0.06 4 +235U 2 G KC=0.05 3$LC=0.0033 17$MC=0.0025 12 235U L 701.02 3 (7/2)- 235U A 4467.37 2170700E-113366 235U G 550.5 2 4.35E-7 25(E1) 0.0112022 -235U 2 G KC=0.00904 18$LC=0.00161 3$MC=3.85E-4 8 -235U G 597.99 5 1.74E-6 6 [E2] 0.0314 6 -235U 2 G KC=0.0208 4$LC=0.00789 16$MC=0.00204 4 -235U G 619.21 6 1.21E-6 8 [E1] 0.0089218 -235U 2 G KC=0.00724 14$LC=0.00127 3$MC=3.04E-4 6 -235U G 649.32 6 7.2E-7 5 [E1] 0.0081616 -235U 2 G KC=0.00662 13$LC=1160E-6 23$MC=2.77E-4 6 -235U G 654.88 8 2.27E-6 5 (E2) 0.0258 5 -235U 2 G KC=0.0177 4$LC=0.00607 12$MC=0.00156 3 -235U G 701.1 2 5.24E-7 19[M1+E2] 0.06 4 -235U 2 G KC=0.05 3$LC=0.010 5$MC=0.0025 12 +235U 2 G KC=0.00904 18$LC=0.00161 3$MC=3.85E-4 8 +235U G 597.99 5 1.74E-6 6[E2] 0.0314 6 +235U 2 G KC=0.0208 4$LC=0.00789 16$MC=0.00204 4 +235U G 619.21 6 1.21E-6 8[E1] 0.0089218 +235U 2 G KC=0.00724 14$LC=0.00127 3$MC=3.04E-4 6 +235U G 649.32 6 7.2E-7 5[E1] 0.0081616 +235U 2 G KC=0.00662 13$LC=1160E-6 23$MC=2.77E-4 6 +235U G 654.88 8 2.27E-6 5(E2) 0.0258 5 +235U 2 G KC=0.0177 4$LC=0.00607 12$MC=0.00156 3 +235U G 701.1 2 5.24E-7 19[M1+E2] 0.06 4 +235U 2 G KC=0.05 3$LC=0.010 5$MC=0.0025 12 235U L 703.757 193/2- 235U A 4464.68 2111400E-93 216 235U G 652.05 2 6.63E-6 20E1 0.0080916 -235U 2 G KC=0.00657 13$LC=1150E-6 23$MC=2.74E-4 5 -235U G 690.81 8 5.9E-7 5 E1 0.0072715 -235U 2 G KC=0.00591 12$LC=1030E-6 21$MC=2.45E-4 5 +235U 2 G KC=0.00657 13$LC=1150E-6 23$MC=2.74E-4 5 +235U G 690.81 8 5.9E-7 5E1 0.0072715 +235U 2 G KC=0.00591 12$LC=1030E-6 21$MC=2.45E-4 5 235U G 703.68 5 4.10E-6 13E1 0.0070214 -235U 2 G KC=0.00571 12$LC=9.93E-4 20$MC=2.37E-4 5 +235U 2 G KC=0.00571 12$LC=9.93E-4 20$MC=2.37E-4 5 235U L 720.25 3 (9/2)- 235U A 4448.46 2121300E-19 859 -235U G 617.1 1 1.35E-6 8 [M1] 0.142 3 -235U 2 G KC=0.1130 23$LC=0.0215 4$MC=0.00518 10 -235U G 674.05 3 5.0E-7 2 0.1120 22 -235U 2 G KC=0.0893 18$LC=0.0169 3$MC=0.00408 8 -235U G 720.3 5 2.9E-8 5 +235U G 617.1 1 1.35E-6 8[M1] 0.142 3 +235U 2 G KC=0.1130 23$LC=0.0215 4$MC=0.00518 10 +235U G 674.050 305.0E-7 2 0.1120 22 +235U 2 G KC=0.0893 18$LC=0.0169 3$MC=0.00408 8 +235U G 720.3 5 2.9E-8 5 235U L 750.07 16(9/2)- 235U A 4419.14 2634000E-14 3140 -235U G 579.4 3 8.8E-8 19[E2] 0.0337 7 -235U 2 G KC=0.0220 4$LC=0.00867 17$MC=0.00224 4 +235U G 579.4 3 8.8E-8 19[E2] 0.0337 7 +235U 2 G KC=0.0220 4$LC=0.00867 17$MC=0.00224 4 235U G 599.6 2 2.02E-7 25[E1] 0.0094819 -235U 2 G KC=0.00769 15$LC=0.00136 3$MC=3.24E-4 6 +235U 2 G KC=0.00769 15$LC=0.00136 3$MC=3.24E-4 6 235U G 668.2 5 4.0E-8 12[E1] 0.0077315 -235U 2 G KC=0.00628 13$LC=1100E-6 22$MC=2.62E-4 5 +235U 2 G KC=0.00628 13$LC=1100E-6 22$MC=2.62E-4 5 235U L 761.04 5 (1/2)- 235U A 4408.36 2210300E-1178500 -235U G 123.228 5 1.6E-9 4 (M1) 12.19 24 -235U 2 G KC=9.66 19$LC=1.91 4$MC=0.461 9 +235U G 123.228 5 1.6E-9 4(M1) 12.19 24 +235U 2 G KC=9.66 19$LC=1.91 4$MC=0.461 9 235U G 747.4 5 8.1E-8 16E1 0.0062913 -235U 2 G KC=0.00512 10$LC=8.80E-4 18$MC=2.11E-4 4 +235U 2 G KC=0.00512 10$LC=8.80E-4 18$MC=2.11E-4 4 235U L 769.27 6 1/2+ 235U A 4400.26 2127000E-93 28 -235U G 639.99 108.46E-6 20[E2] 0.0271 5 -235U 2 G KC=0.0184 4$LC=0.00648 13$MC=0.00167 3 -235U G 756.23 6 2.8E-6 5 [M1+E2] 0.05 3 -235U 2 G KC=0.04 3$LC=0.008 4$MC=0.002 1 -235U G 769.15 8 5.1E-6 10M1+ 2.0 2 -235U 2 G KC=$LC=$MC= +235U G 639.99 108.46E-6 20[E2] 0.0271 5 +235U 2 G KC=0.0184 4$LC=0.00648 13$MC=0.00167 3 +235U G 756.23 6 2.8E-6 5[M1+E2] 0.05 3 +235U 2 G KC=0.04 3$LC=0.008 4$MC=0.002 1 +235U G 769.15 8 5.1E-6 10M1+ 2.0 2 235U L 769.5 3 3/2- 235U A 4400.0 4 10300E-91273 -235U G 718.0 5 2.76E-6 6 E1 0.0067714 -235U 2 G KC=0.00551 11$LC=9.60E-4 19$MC=2.27E-4 5 +235U G 718.0 5 2.76E-6 6E1 0.0067714 +235U 2 G KC=0.00551 11$LC=9.60E-4 19$MC=2.27E-4 5 235U G 756.4 4 6.9E-7 19[E1] 0.0061512 -235U 2 G KC=0.00501 10$LC=8.65E-4 17$MC=2.06E-4 4 +235U 2 G KC=0.00501 10$LC=8.65E-4 17$MC=2.06E-4 4 235U G 769.4 5 6.8E-6 12E1 0.0059612 -235U 2 G KC=0.00486 10$LC=8.37E-4 17$MC=1.99E-4 4 +235U 2 G KC=0.00486 10$LC=8.37E-4 17$MC=1.99E-4 4 235U L 777.59 19(11/2)- 235U A 4392.08 2824700E-1192610 -235U G 606.9 2 1.21E-7 13M1(+E2) 0.12 3 -235U 2 G KC=0.09 3$LC=0.019 4$MC=0.0045 9 -235U G 674.4 5 1.0E-7 1 (M1) 0.1120 22 -235U 2 G KC=0.0892 18$LC=0.0169 3$MC=0.00408 8 +235U G 606.9 2 1.21E-7 13M1(+E2) 0.12 3 +235U 2 G KC=0.09 3$LC=0.019 4$MC=0.0045 9 +235U G 674.4 5 1.0E-7 1(M1) 0.1120 22 +235U 2 G KC=0.0892 18$LC=0.0169 3$MC=0.00408 8 235U L 779.51 3 (3/2)+ 235U A 4390.20 2110100E-111616 235U G 697.8 5 7.4E-8 15 -235U G 727.9 2 1.25E-7 7 M1 0.0911 18 -235U 2 G KC=0.0728 15$LC=0.0138 3$MC=0.00332 7 -235U G 766.47 3 1.3E-7 2 +M1 4.0 4 -235U 2 G KC=$LC=$MC= -235U G 779.43 3 1.37E-7 9 M1 0.0759 15 -235U 2 G KC=0.0607 12$LC=0.01148 23$MC=0.00276 6 +235U G 727.9 2 1.25E-7 7M1 0.0911 18 +235U 2 G KC=0.0728 15$LC=0.0138 3$MC=0.00332 7 +235U G 766.47 3 1.3E-7 2+M1 4.0 4 +235U G 779.43 3 1.37E-7 9M1 0.0759 15 +235U 2 G KC=0.0607 12$LC=0.01148 23$MC=0.00276 6 235U L 805.72 6 3/2- 235U A 4364.42 2284000E-1144560 -235U G 172.560 8 300E-11 0 M1 4.70 9 -235U 2 G KC=3.73 8$LC=0.728 15$MC=0.176 4 -235U G 412.49 6 180E-10 0 [E1] 0.0199 4 -235U 2 G KC=0.0160 3$LC=0.00296 6$MC=7.09E-4 14 -235U G 792.68 6 2.0E-8 4 (E1) 0.0056511 -235U 2 G KC=0.00461 9$LC=7.90E-4 16$MC=1.88E-4 4 -235U G 805.65 6 2.8E-8 4 E2 0.0169 3 -235U 2 G KC=0.01220 24$LC=0.00348 7$MC=8.80E-4 18 +235U G 172.560 8 3E-9 M1 4.70 9 +235U 2 G KC=3.73 8$LC=0.728 15$MC=0.176 4 +235U G 412.49 6 1.8E-8 [E1] 0.0199 4 +235U 2 G KC=0.0160 3$LC=0.00296 6$MC=7.09E-4 14 +235U G 792.68 6 2.0E-8 4(E1) 0.0056511 +235U 2 G KC=0.00461 9$LC=7.90E-4 16$MC=1.88E-4 4 +235U G 805.65 6 2.8E-8 4E2 0.0169 3 +235U 2 G KC=0.01220 24$LC=0.00348 7$MC=8.80E-4 18 235U L 821.25 4 5/2+ 235U A 4349.15 2130000E-13 960 -235U G 596.0 5 3.9E-8 12[E2] 0.0317 6 -235U 2 G KC=0.0209 4$LC=0.00797 16$MC=0.00206 4 -235U G 670.8 5 9E-9 3 +235U G 596.0 5 3.9E-8 12[E2] 0.0317 6 +235U 2 G KC=0.0209 4$LC=0.00797 16$MC=0.00206 4 +235U G 670.8 5 9E-9 3 235U G 769.54 4 -235U G 808.21 4 1.22E-7 6 M1 0.0690 14 -235U 2 G KC=0.0552 11$LC=0.01040 21$MC=0.00251 5 +235U G 808.21 4 1.22E-7 6M1 0.0690 14 +235U 2 G KC=0.0552 11$LC=0.01040 21$MC=0.00251 5 235U G 821.25 4 5.0E-8 11E1+M2 235U L 843.858 10(1/2)+ 235U A 4326.92 2122800E-112825 -235U G 714.71 147.9E-8 8 E2 0.0215 4 -235U 2 G KC=0.0151 3$LC=0.00477 10$MC=1225E-6 25 -235U G 843.78 1 1.35E-7 8 M1(+) 0.09 1 -235U 2 G KC=$LC=$MC= +235U G 714.71 147.9E-8 8E2 0.0215 4 +235U 2 G KC=0.0151 3$LC=0.00477 10$MC=1225E-6 25 +235U G 843.78 1 1.35E-7 8M1(+) 0.09 1 235U L 845.3 10(7/2)+ 235U A 4325.5 1042000E-1 4360 -235U G 763.60 15220E-10 0 (+M1) 0.900000 -235U 2 G KC=$LC=$MC= +235U G 763.60 152.2E-8 (+M1) 0.9 235U L 865.35 183/2+ 235U A 4305.79 2898000E-1131280 -235U G 693.81 1 1.9E-8 7 (E2) 0.0229 5 -235U 2 G KC=0.0159 3$LC=0.00517 10$MC=0.00132 3 -235U G 736.5 5 3.0E-8 9 M1+()E2 0.0481 10 -235U 2 G KC=0.0374 7$LC=0.00807 16$MC=0.00198 4 -235U G 813.7 2 4.5E-8 5 M1 0.0677 14 -235U 2 G KC=0.0542 11$LC=0.01020 21$MC=0.00246 5 +235U G 693.81 1 1.9E-8 7(E2) 0.0229 5 +235U 2 G KC=0.0159 3$LC=0.00517 10$MC=0.00132 3 +235U G 736.5 5 3.0E-8 9M1+()E2 0.0481 10 +235U 2 G KC=0.0374 7$LC=0.00807 16$MC=0.00198 4 +235U G 813.7 2 4.5E-8 5M1 0.0677 14 +235U 2 G KC=0.0542 11$LC=0.01020 21$MC=0.00246 5 235U L 891.89 155/2+ 235U A 4279.70 2619900E-112380 -235U G 720.55 3 2.0E-8 2 -235U G 762.6 2 100E-10 0 -235U G 840.4 2 4.9E-8 5 M1(+) 0.14 2 -235U 2 G KC=$LC=$MC= -235U G 879.2 3 3.6E-8 4 [M1+E2] 0.035 20 -235U 2 G KC=0.027 17$LC=0.006 3$MC=0.0014 7 -235U G 891.0 3 7.5E-8 8 [E2] 0.0139 3 -235U 2 G KC=0.0102 2$LC=0.00270 5$MC=6.77E-4 14 +235U G 720.55 3 2.0E-8 2 +235U G 762.6 2 1E-8 +235U G 840.4 2 4.9E-8 5M1(+) 0.14 2 +235U G 879.2 3 3.6E-8 4[M1+E2] 0.035 20 +235U 2 G KC=0.027 17$LC=0.006 3$MC=0.0014 7 +235U G 891.0 3 7.5E-8 8[E2] 0.0139 3 +235U 2 G KC=0.0102 2$LC=0.00270 5$MC=6.77E-4 14 235U L 968.451 203/2+ 235U A 4204.42 2161000E-115281 -235U G 955.41 2 3.1E-8 3 M1+()E2 0.036 4 -235U 2 G KC=0.029 3$LC=0.0055 6$MC=0.00133 13 -235U G 968.37 2 280E-10 0 M1+()E2 0.035 19 -235U 2 G KC=0.0028 15$LC=0.0053 29$MC=0.0013 7 +235U G 955.41 2 3.1E-8 3M1+()E2 0.036 4 +235U 2 G KC=0.029 3$LC=0.0055 6$MC=0.00133 13 +235U G 968.37 2 2.8E-8 M1+()E2 0.035 19 +235U 2 G KC=0.0028 15$LC=0.0053 29$MC=0.0013 7 235U L 970.52 22(5/2,7/2)+ 235U A 4202.4 3 41000E-14 402 235U G 918.7 3 8.8E-9 30 -235U G 957.6 3 3.2E-8 3 +235U G 957.6 3 3.2E-8 3 235U L 986.65 17(13/2-)- 235U A 4186.53 2777000E-17 156 -235U G 816.0 2 2.5E-8 4 [M1+E2] 0.042 25 -235U 2 G KC=0.033 21$LC=0.007 3$MC=0.0016 8 -235U G 940.3 3 5.0E-8 5 [E2] 0.0125025 -235U 2 G KC=0.00932 19$LC=0.00237 5$MC=5.91E-4 12 +235U G 816.0 2 2.5E-8 4[M1+E2] 0.042 25 +235U 2 G KC=0.033 21$LC=0.007 3$MC=0.0016 8 +235U G 940.3 3 5.0E-8 5[E2] 0.0125025 +235U 2 G KC=0.00932 19$LC=0.00237 5$MC=5.91E-4 12 235U L 992.72 22(5/2+)+ 235U A 4180.6 3 20000E-13 53 -235U G 767.29 4 1.4E-7 3 -235U G 821.3 2 600E-11 0 -235U G 979.7 3 2.8E-8 5 [M1+E2] 0.026 15 -235U 2 G KC=0.021 12$LC=0.0042 20$MC=0.0010 5 -235U G 992.64 3 2.7E-8 4 +235U G 767.29 4 1.4E-7 3 +235U G 821.3 2 6E-9 +235U G 979.7 3 2.8E-8 5[M1+E2] 0.026 15 +235U 2 G KC=0.021 12$LC=0.0042 20$MC=0.0010 5 +235U G 992.64 3 2.7E-8 4 235U L 1057.58 13(7/2)+ 235U A 4116.78 2593000E-19 31 -235U G 832.2 2 3.0E-8 4 +235U G 832.2 2 3.0E-8 4 235U G 1005.7 3 1.77E-8 25 -235U G 1057.3 2 4.5E-8 7 +235U G 1057.3 2 4.5E-8 7 235U L 1116.2 2 (5/2-)- 235U A 4059.1 3 21000E-15 41 -235U G 986.90 4 2.1E-8 5 E1 0.003838 -235U 2 G KC=0.00313 6$LC=5.29E-4 11$MC=1260E-7 25 +235U G 986.90 4 2.1E-8 5E1 0.00383 8 +235U 2 G KC=0.00313 6$LC=5.29E-4 11$MC=1260E-7 25 diff --git a/HEN_HOUSE/spectra/lnhb/Pu-240.txt b/HEN_HOUSE/spectra/lnhb/Pu-240.txt index 36c29e64b..bb1f7d3f2 100644 --- a/HEN_HOUSE/spectra/lnhb/Pu-240.txt +++ b/HEN_HOUSE/spectra/lnhb/Pu-240.txt @@ -11,87 +11,87 @@ 236U 8C 1990An33, 1992Ba08, 1992Bl13, 1994Le28, 1994Ba91, 1994Ra27, 1994Sa63, 236U 9C 1994Le37, 1995Jo23, 1996Vi07, 2000Ho27, 2003Au03, 2004BeZQ, 2004Si03, 236U 10C 2005ChZU, 2006Br20, 2007Ah05, 2008Ki07 -236U T Auger electrons and ^X ray energies and emission intensities: -236U T {U Energy (keV)} {U Intensity } {U Line } +236U T Auger electrons and X ray energies and emission intensities: +236U T {U Energy (keV)} {U Intensity} {U Line} 236U T -236U T 94.666 0.0000260 6 XKA2 -236U T 98.44 0.0000416 9 XKA1 +236U T 94.666 2.60E-5 6 XKA2 +236U T 98.44 4.16E-5 9 XKA1 236U T -236U T 110.421 |] XKB3 -236U T 111.298 |] 0.0000150 4 XKB1 -236U T 111.964 |] XKB5II +236U T 110.421 |] XKB3 +236U T 111.298 |] 1.50E-5 4 XKB1 +236U T 111.964 |] XKB5II 236U T -236U T 114.407 |] XKB2 -236U T 115.012 |] 0.00000513 16 XKB4 -236U T 115.377 |] XKO23 +236U T 114.407 |] XKB2 +236U T 115.012 |] 5.13E-6 16 XKB4 +236U T 115.377 |] XKO23 236U T -236U T 11.619-20.714 10.34 15 XL (total) -236U T 11.619 0.238 4 XLL -236U T 13.438-13.615 3.70 4 XLA -236U T 15.399 0.116 3 XLC -236U T 15.727-18.206 5.01 13 XLB -236U T 19.507-20.714 1.267 22 XLG +236U T 11.619-20.714 10.34 15 XL (total) +236U T 11.619 0.238 4 XLL +236U T 13.438-13.615 3.70 4 XLA +236U T 15.399 0.116 3 XLC +236U T 15.727-18.206 5.01 13 XLB +236U T 19.507-20.714 1.267 22 XLG 236U T -236U T 71.78-80.95 |] KLL AUGER -236U T 88.15-98.43 |] 0.0000027 4 ^KLX AUGER -236U T 104.51-115.59 |] KXY AUGER -236U T 5.01-21.6 10.3 8 L AUGER +236U T 71.78-80.95 |] KLL AUGER +236U T 88.15-98.43 |] 2.7E-6 4 KLX AUGER +236U T 104.51-115.59 |] KXY AUGER +236U T 5.01-21.6 10.3 8 L AUGER 240PU P 0.0 0+ 6561 Y 7 5255.75 15 236U N 1.0 1.0 1 1.0 236U L 0 0+ 23.43E6 Y 6 236U A 5168.13 1572.74 181 236U L 45.244 2 2+ 234 PS 6 236U A 5123.6 2 27.16 191.4 -236U G 45.244 2 0.0462 9 E2 589 12 -236U 2 G KC=$LC=429 9$MC=118.6 24 +236U G 45.244 2 0.0462 9E2 589 12 +236U 2 G LC=429 9$MC=118.6 24 236U L 149.477 6 4+ 124 PS 7 236U A 5021.1 2 0.0863 1894.6 -236U G 104.233 5 0.00714 7 E2 10.99 22 -236U 2 G KC=$LC=8.00 16$MC=2.22 4 +236U G 104.233 5 0.00714 7E2 10.99 22 +236U 2 G LC=8.00 16$MC=2.22 4 236U L 309.785 7 6+ 58 PS 3 236U A 4863.5 2 10820E-718646 -236U G 160.308 3 4045E-7 22E2 1.76 4 -236U 2 G KC=0.208 4$LC=1.132 23$MC=0.313 6 +236U G 160.308 3 4.045E-422E2 1.76 4 +236U 2 G KC=0.208 4$LC=1.132 23$MC=0.313 6 236U L 522.25 5 8+ 24 PS 2 236U A 4654.5 2 47000E-95 471 -236U G 212.46 5 2.9E-5 3 E2 0.599 12 -236U 2 G KC=0.140 3$LC=0.335 7$MC=0.0920 18 +236U G 212.46 5 0.000029 3E2 0.599 12 +236U 2 G KC=0.140 3$LC=0.335 7$MC=0.0920 18 236U L 687.59 4 1- 3.78 NS 9 236U A 4492.0 2 19300E-94 65.9 -236U G 538.1 1 1.47E-7 12E3 0.143 3 -236U 2 G KC=0.0623 12$LC=0.0587 12$MC=0.0160 3 -236U G 642.34 5 1.26E-5 3 E1+(M2+E3) 0.15 2 -236U 2 G KC=0.112 10$LC=0.031 3$MC= -236U G 687.56 103.56E-6 9 E1 0.31 2 -236U 2 G KC=0.219 14$LC=0.069 9$MC= +236U G 538.1 1 1.47E-7 12E3 0.143 3 +236U 2 G KC=0.0623 12$LC=0.0587 12$MC=0.0160 3 +236U G 642.34 5 1.26E-5 3E1+(M2+E3) 0.15 2 +236U 2 G KC=0.112 10$LC=0.031 3 +236U G 687.56 103.56E-6 9E1 0.31 2 +236U 2 G KC=0.219 14$LC=0.069 9 236U L 744.18 7 3- 236U A 4436.4 2 13000E-17 35000 236U G 56.6 5 (E2) 199 10 -236U 2 G KC=$LC=145 7$MC=40.1 19 +236U 2 G LC=145 7$MC=40.1 19 236U G 594.5 3 -236U G 698.94 250E-10 0 +236U G 698.94 2.5E-8 236U L 919.14 170+ 236U A 4264.3 3 65000E-18 27 -236U G 874.0 2 5.8E-7 6 (E2) 0.0144 3 -236U 2 G KC=0.01060 15$LC=0.00283 6$MC=7.11E-4 14 +236U G 874.0 2 5.8E-7 6(E2) 0.0144 3 +236U 2 G KC=0.01060 15$LC=0.00283 6$MC=7.11E-4 14 236U G 918.9 3 () 236U L 957.90 17(2)+ 236U A 4226.1 3 17000E-1 -236U G 912.4 3 700E-10 0 (M1) 0.050 1 -236U 2 G KC=0.0400 8$LC=0.00753 11$MC=0.00181 4 -236U G 958.0 2 100E-9 0 +236U G 912.4 3 7E-8 (M1) 0.050 1 +236U 2 G KC=0.0400 8$LC=0.00753 11$MC=0.00181 4 +236U G 958.0 2 1E-7 236U L 960.3 3 (2)+ 236U A 4223.8 4 13000E-1 -236U G 810.8 430E-10 0 -236U G 915.1 3 630E-10 0 (M1+) -236U G 960.3 500E-10 0 +236U G 810.8 4.3E-8 +236U G 915.1 3 6.3E-8 (M1+) +236U G 960.3 5E-8 236U L 966.62 9 1- 236U A 4217.6 2 10000E-1 236U G 222.44 -236U G 279.0 1 (M1+E2) 0.7 5 -236U 2 G KC=0.5 5$LC=0.15 4$MC=0.038 8 -236U G 921.2 2 220E-10 0 E1 0.004329 -236U 2 G KC=0.00353 7$LC=5.99E-4 12$MC=1.42E-4 3 -236U G 966.9 2 500E-10 0 E1 0.003978 -236U 2 G KC=0.00324 6$LC=5.49E-4 11$MC=1.30E-4 3 +236U G 279.0 1 (M1+E2) 0.7 5 +236U 2 G KC=0.5 5$LC=0.15 4$MC=0.038 8 +236U G 921.2 2 2.2E-8 E1 0.00432 9 +236U 2 G KC=0.00353 7$LC=5.99E-4 12$MC=1.42E-4 3 +236U G 966.9 2 5E-8 E1 0.00397 8 +236U 2 G KC=0.00324 6$LC=5.49E-4 11$MC=1.30E-4 3 diff --git a/HEN_HOUSE/spectra/lnhb/Pu-241.txt b/HEN_HOUSE/spectra/lnhb/Pu-241.txt index fe82f1960..5a136c3b9 100644 --- a/HEN_HOUSE/spectra/lnhb/Pu-241.txt +++ b/HEN_HOUSE/spectra/lnhb/Pu-241.txt @@ -8,31 +8,31 @@ 237U 5C 1989Pa21, 1991Ry01, 1993Dr05, 1994Ba91, 1995Ak01, 1996FiZX, 1996Sc06, 237U 6C 1997DeZY, 1998Ak04, 1999Dr13, 1999ScZX, 1999YaZX, 2000Dr02, 2003Au03, 237U 7C 2004Fo01, 2005Ma88, 2006Ba41 -237U T Auger electrons and ^X ray energies and emission intensities: -237U T {U Energy (keV)} {U Intensity } {U Line } +237U T Auger electrons and X ray energies and emission intensities: +237U T {U Energy (keV)} {U Intensity} {U Line} 237U T -237U T 94.666 0.000300 7 XKA2 -237U T 98.44 0.000479 10 XKA1 +237U T 94.666 0.000300 7 XKA2 +237U T 98.44 0.00047910 XKA1 237U T -237U T 110.421 |] XKB3 -237U T 111.298 |] 0.000179 5 XKB1 -237U T 111.964 |] XKB5II +237U T 110.421 |] XKB3 +237U T 111.298 |] 0.000179 5 XKB1 +237U T 111.964 |] XKB5II 237U T -237U T 114.407 |] XKB2 -237U T 115.012 |] 0.000059 2 XKB4 -237U T 115.377 |] XKO23 +237U T 114.407 |] XKB2 +237U T 115.012 |] 0.000059 2 XKB4 +237U T 115.377 |] XKO23 237U T -237U T 11.619-20.714 0.001166 40 XL (total) -237U T 11.619 0.0000336 12 XLL -237U T 13.438-13.615 0.000543 19 XLA -237U T 15.399 0.00000444 13 XLC -237U T 15.727-18.206 0.000477 8 XLB -237U T 19.507-20.714 0.000109 2 XLG +237U T 11.619-20.714 0.00116640 XL (total) +237U T 11.619 3.36E-5 12 XLL +237U T 13.438-13.615 0.00054319 XLA +237U T 15.399 4.44E-6 13 XLC +237U T 15.727-18.206 0.000477 8 XLB +237U T 19.507-20.714 0.000109 2 XLG 237U T -237U T 71.776-80.954 |] KLL AUGER -237U T 88.153-98.429 |] 0.000031 5 ^KLX AUGER -237U T 104.51-115.59 |] KXY AUGER -237U T 5.9-21.6 0.00117 6 L AUGER +237U T 71.776-80.954 |] KLL AUGER +237U T 88.153-98.429 |] 0.000031 5 KLX AUGER +237U T 104.51-115.59 |] KXY AUGER +237U T 5.9-21.6 0.00117 6 L AUGER 241PU P 0.0 5/2+ 14.33 Y 4 5140.0 5 237U N 4.098E4 4.098E4 0.000024 4.098E4 237U L 0 1/2+ 6.749 D 16 @@ -43,40 +43,40 @@ 237U L 56.30 125/2+ 237U A 4999.2 5 0.410 491300 237U G 44.86 108.4E-7 10[M1+()E2] 131 25 -237U 2 G KC=$LC=96 18$MC=25 4 -237U G 56.30 122.5E-6 2 (E2) 204 4 -237U 2 G KC=$LC=149 3$MC=41.1 8 +237U 2 G LC=96 18$MC=25 4 +237U G 56.30 122.5E-6 2(E2) 204 4 +237U 2 G LC=149 3$MC=41.1 8 237U L 82.97 137/2+ 237U A 4973.1 5 1.31 12276 -237U G 26.66 4 (M1+E2) -237U G 71.64 9 2.9E-6 2 (E2) 64.3 13 -237U 2 G KC=$LC=46.8 10$MC=13.0 3 +237U G 26.660 40 (M1+E2) +237U G 71.64 9 2.9E-6 2(E2) 64.3 13 +237U 2 G LC=46.8 10$MC=13.0 3 237U L 159.96 2 5/2+ 3.1 NS 1 237U A 4897.3 5 83.2 161.3 -237U G 77.01 4 2.07E-5 4 (M1) 9.86 20 -237U 2 G KC=$LC=7.44 15$MC=1.8 4 -237U G 103.680 5 1.03E-4 2 [M1+()E2] 4.20 9 -237U 2 G KC=$LC=3.16 7$MC=0.767 15 -237U G 148.567 101863E-7 8 [M1+()E2] 7.05 14 -237U 2 G KC=5.55 11$LC=1.13 3$MC=0.275 6 -237U G 159.96 2 6.45E-6 9 (E2) 1.78 3 -237U 2 G KC=0.208 4$LC=1.14 3$MC=0.316 7 +237U G 77.010 402.07E-5 4(M1) 9.86 20 +237U 2 G LC=7.44 15$MC=1.8 4 +237U G 103.680 5 0.000103 2[M1+()E2] 4.20 9 +237U 2 G LC=3.16 7$MC=0.767 15 +237U G 148.567 101.863E-4 8[M1+()E2] 7.05 14 +237U 2 G KC=5.55 11$LC=1.13 3$MC=0.275 6 +237U G 159.96 2 6.45E-6 9(E2) 1.78 3 +237U 2 G KC=0.208 4$LC=1.14 3$MC=0.316 7 237U L 204.19 147/2+ 237U A 4853.8 5 12.09 334.5 -237U G 44.18 3 4.2E-6 2 M1+()E2 60.4 29 -237U 2 G KC=$LC=45.3 25$MC=11.2 7 -237U G 121.22 5 7.0E-7 7 (M1) 12.8 3 -237U 2 G KC=10.1 2$LC=2.00 4$MC=0.484 10 +237U G 44.180 304.2E-6 2M1+()E2 60.4 29 +237U 2 G LC=45.3 25$MC=11.2 7 +237U G 121.22 5 7.0E-7 7(M1) 12.8 3 +237U 2 G KC=10.1 2$LC=2.00 4$MC=0.484 10 237U L 260.95 179/2+ 237U A 4798.0 5 1.19 1218.6 -237U G 56.76 101.0E-6 1 M1+()E2 27 3 -237U 2 G KC=$LC=21 3$MC=5.0 9 -237U G 100.94 11720E-10 0 (E2) 12.8 3 -237U 2 G KC=$LC=9.3 2$MC=2.58 5 +237U G 56.76 101.0E-6 1M1+()E2 27 3 +237U 2 G LC=21 3$MC=5.0 9 +237U G 100.94 117.2E-8 (E2) 12.8 3 +237U 2 G LC=9.3 2$MC=2.58 5 237U L 274 1 (7/2)- 155 NS 6 237U A 4785.1 110.020 8 90 237U G 114 1 6.2E-6 12E1 0.0883 17 -237U 2 G KC=$LC=0.0665 13$MC=0.0163 3 +237U 2 G LC=0.0665 13$MC=0.0163 3 237U L 316 5 (9/2)- 237U A 4744 5 69672E-6 131 237U L 327 3 11/2+ @@ -94,28 +94,28 @@ 241AM5C 1989Pa21, 1991Ry01, 1993Dr05, 1994Ba91, 1995Ak01, 1996FiZX, 1996Sc06, 241AM6C 1997DeZY, 1998Ak04, 1999Dr13, 1999ScZX, 1999YaZX, 2000Dr02, 2003Au03, 241AM7C 2004Fo01, 2005Ma88, 2006Ba41 -241AM T Auger electrons and ^X ray energies and emission intensities: -241AM T {U Energy (keV)} {U Intensity } {U Line } +241AM T Auger electrons and X ray energies and emission intensities: +241AM T {U Energy (keV)} {U Intensity} {U Line} 241AM T 241AM T 102.03 XKA2 241AM T 106.472 XKA1 241AM T -241AM T 119.243 |] XKB3 -241AM T 120.284 |] XKB1 -241AM T 120.989 |] XKB5II +241AM T 119.243 |] XKB3 +241AM T 120.284 |] XKB1 +241AM T 120.989 |] XKB5II 241AM T -241AM T 123.58 |] XKB2 -241AM T 124.127 |] XKB4 -241AM T 124.723 |] XKO23 +241AM T 123.58 |] XKB2 +241AM T 124.127 |] XKB4 +241AM T 124.723 |] XKO23 241AM T 241AM T -241AM T 77.04-85.638 |] KLL AUGER -241AM T 94.891-106.467 |] ^KLX AUGER -241AM T 112.72-124.97 |] KXY AUGER +241AM T 77.04-85.638 |] KLL AUGER +241AM T 94.891-106.467 |] KLX AUGER +241AM T 112.72-124.97 |] KXY AUGER 241AM T 6.26-23.7 L AUGER 241PU P 0.0 5/2+ 14.33 Y 4 20.8 2 241AM N 1.00E0 1.00E0 0.999975 1.00E0 241AM L 0 5/2- 432.6 Y 6 -241AM B 20.8 2 99998E-32 5.8 +241AM B 20.8 2 99.99756 2 5.8 241AMS B EAV=5.8 1 diff --git a/HEN_HOUSE/spectra/lnhb/Pu-242.txt b/HEN_HOUSE/spectra/lnhb/Pu-242.txt index 29ddf42e1..5eceeb289 100644 --- a/HEN_HOUSE/spectra/lnhb/Pu-242.txt +++ b/HEN_HOUSE/spectra/lnhb/Pu-242.txt @@ -6,45 +6,45 @@ 238U 3C 1976Os05, 1978MeZL, 1979Ag03, 1980Kh05, 1986LoZT, 1986Va33, 1988SeZY, 238U 4C 1990Po14, 1991Ry01, 1994Le37, 1996Sc06, 2000Ho27, 2002Ch52, 2003Au03, 238U 5C 2004BeZQ, 2005ChZU, 2008Ki07 -238U T Auger electrons and ^X ray energies and emission intensities: -238U T {U Energy (keV)} {U Intensity } {U Line } +238U T Auger electrons and X ray energies and emission intensities: +238U T {U Energy (keV)} {U Intensity} {U Line} 238U T -238U T 94.666 0.0000180 13 XKA2 -238U T 98.44 0.0000288 21 XKA1 +238U T 94.666 1.80E-5 13 XKA2 +238U T 98.44 2.88E-5 21 XKA1 238U T -238U T 110.421 |] XKB3 -238U T 111.298 |] 0.0000104 8 XKB1 -238U T 111.964 |] XKB5II +238U T 110.421 |] XKB3 +238U T 111.298 |] 1.04E-5 8 XKB1 +238U T 111.964 |] XKB5II 238U T -238U T 114.407 |] XKB2 -238U T 115.012 |] 0.00000355 27 XKB4 -238U T 115.377 |] XKO23 +238U T 114.407 |] XKB2 +238U T 115.012 |] 3.55E-6 27 XKB4 +238U T 115.377 |] XKO23 238U T -238U T 11.62-21.73 8.71 21 XL (total) -238U T 11.62 0.191 7 XLL -238U T 13.44-13.62 3.07 10 XLA -238U T 15.4 0.098 4 XLC -238U T 15.73-18.21 4.33 13 XLB -238U T 19.51-21.73 1.021 30 XLG +238U T 11.62-21.73 8.71 21 XL (total) +238U T 11.62 0.191 7 XLL +238U T 13.44-13.62 3.07 10 XLA +238U T 15.4 0.098 4 XLC +238U T 15.73-18.21 4.33 13 XLB +238U T 19.51-21.73 1.021 30 XLG 238U T -238U T 71.78-80.95 |] KLL AUGER -238U T 88.15-98.43 |] 0.00000188 29 ^KLX AUGER -238U T 104.51-115.59 |] KXY AUGER -238U T 5.9-21.6 8.40 19 L AUGER +238U T 71.78-80.95 |] KLL AUGER +238U T 88.15-98.43 |] 1.88E-6 29 KLX AUGER +238U T 104.51-115.59 |] KXY AUGER +238U T 5.9-21.6 8.40 19 L AUGER 242PU P 0.0 0+ 3.73E5 Y 3 4984.5 10 238U N 1.0 1.0 1 1.0 238U L 0 0+ 4.468E9 Y 5 238U A 4902.3 1076.53 171 238U L 44.915 132+ 206 PS 3 238U A 4858.2 1023.44 171.62 -238U G 44.915 130.0384 8 E2 610 12 -238U 2 G KC=$LC=445 9$MC=122.8 25 +238U G 44.915 130.0384 8E2 610 12 +238U 2 G LC=445 9$MC=122.8 25 238U L 148.39 3 4+ 238U A 4756.2 100.0304 13238 238U G 103.50 4 0.00253 12E2 11.36 23 -238U 2 G KC=$LC=8.27 17$MC=2.29 5 +238U 2 G LC=8.27 17$MC=2.29 5 238U L 307.19 8 6+ 238U A 4600.1 100.00084 6 609 -238U G 158.80 8 2.98E-4 20E2 1.83 4 -238U 2 G KC=0.210 4$LC=1.180 24$MC=0.326 7 +238U G 158.80 8 0.00029820E2 1.83 4 +238U 2 G KC=0.210 4$LC=1.180 24$MC=0.326 7 diff --git a/HEN_HOUSE/spectra/lnhb/Ra-223.txt b/HEN_HOUSE/spectra/lnhb/Ra-223.txt index 7c6395ee4..3b0c0f58f 100644 --- a/HEN_HOUSE/spectra/lnhb/Ra-223.txt +++ b/HEN_HOUSE/spectra/lnhb/Ra-223.txt @@ -6,187 +6,187 @@ 219RN3C 1970Da08, 1970Kr01, 1971Gr17, 1972HeYM, 1974Ri05, 1976Bl13, 1977La19, 219RN4C 1977Ma31, 1987Mi10, 1991Ma16, 1991Ry01, 1996Sc06, 1998Sh02, 2000Sc47, 219RN5C 2001Br31, 2003Au03, 2008Ki07 -219RN T Auger electrons and ^X ray energies and emission intensities: -219RN T {U Energy (keV)} {U Intensity } {U Line } +219RN T Auger electrons and X ray energies and emission intensities: +219RN T {U Energy (keV)} {U Intensity} {U Line} 219RN T -219RN T 81.07 14.86 23 XKA2 -219RN T 83.78 24.5 4 XKA1 +219RN T 81.07 14.86 23 XKA2 +219RN T 83.78 24.5 4 XKA1 219RN T -219RN T 94.247 |] XKB3 -219RN T 94.868 |] 8.50 18 XKB1 -219RN T 95.449 |] XKB5II +219RN T 94.247 |] XKB3 +219RN T 94.868 |] 8.50 18 XKB1 +219RN T 95.449 |] XKB5II 219RN T -219RN T 97.48 |] XKB2 -219RN T 97.853 |] 2.72 7 XKB4 -219RN T 98.357 |] XKO23 +219RN T 97.48 |] XKB2 +219RN T 97.853 |] 2.72 7 XKB4 +219RN T 98.357 |] XKO23 219RN T -219RN T 10.1372-17.2578 22.1 4 XL (total) -219RN T 10.1372 0.562 15 XLL -219RN T 11.5981-11.7259 10.00 25 XLA -219RN T 12.8551 0.168 5 XLC -219RN T 13.5219-14.5189 9.44 18 XLB -219RN T 16.2398-17.2578 1.91 4 XLG +219RN T 10.1372-17.2578 22.1 4 XL (total) +219RN T 10.1372 0.562 15 XLL +219RN T 11.5981-11.7259 10.00 25 XLA +219RN T 12.8551 0.168 5 XLC +219RN T 13.5219-14.5189 9.44 18 XLB +219RN T 16.2398-17.2578 1.91 4 XLG 219RN T -219RN T 62.017-68.885 |] KLL AUGER -219RN T 75.744-83.785 |] 1.73 21 ^KLX AUGER -219RN T 89.45-98.39 |] KXY AUGER -219RN T 5.66-17.95 30.1 4 L AUGER +219RN T 62.017-68.885 |] KLL AUGER +219RN T 75.744-83.785 |] 1.73 21 KLX AUGER +219RN T 89.45-98.39 |] KXY AUGER +219RN T 5.66-17.95 30.1 4 L AUGER 223RA P 0.0 3/2+ 11.43 D 3 5978.99 21 219RN N 1.0 1.0 1 1.0 -219RN G 490.8 3 0.0017 7 -219RN G 523.2 4 0.0014 6 -219RN G 532.9 4 0.0014 6 +219RN G 490.8 3 0.0017 7 +219RN G 523.2 4 0.0014 6 +219RN G 532.9 4 0.0014 6 219RN G 737.2 8 0.00028 14 219RN L 0 5/2+ 3.98 S 3 219RN A 5871.63 211.0 2 2420 219RN L 4.47 1 (9/2)+ 15.4 NS 13 -219RN G 4.47 1 6400E-9 0 E2 86000000 -219RN2 G KC=$LC=$MC=5100000 0 +219RN G 4.47 1 6.4E-6 E2 8600000 +219RN2 G MC=5100000 219RN L 14.37 1 (7/2)+ 875 PS 30 219RN A 5857.52 210.32 4 6480 219RN G 9.90 2 0.0158 20M1+E2 0.050 2 990 40 -219RN2 G KC=$LC=$MC=750 30 +219RN2 G MC=750 30 219RN G 14.37 1 0.0185 13M1+E2 0.116 2 539 15 -219RN2 G KC=$LC=$MC=409 11 +219RN2 G MC=409 11 219RN L 126.77 2 (11/2)+ 402 PS 20 219RN A 5747.14 2110.0 3 60 219RN G 122.319 101.238 19M1+E2 0.132 14 7.34 11 -219RN2 G KC=5.88 9$LC=1.109 17$MC=0.265 4 +219RN2 G KC=5.88 9$LC=1.109 17$MC=0.265 4 219RN L 158.64 1 7/2+ 42.3 PS 50 219RN A 5715.84 2149.6 128.4 -219RN G 31.87 2 1.05E-4 21(E2) 2010 30 -219RN2 G KC=$LC=1490 22$MC=398 6 -219RN G 144.27 2 3.36 8 M1+E2 -0.12 1 4.59 7 -219RN2 G KC=3.69 6$LC=0.684 10$MC=0.1629 23 -219RN G 154.208 105.84 13M1 3.83 6 -219RN2 G KC=3.09 5$LC=0.560 8$MC=0.1331 19 +219RN G 31.87 2 0.00010521(E2) 2010 30 +219RN2 G LC=1490 22$MC=398 6 +219RN G 144.27 2 3.36 8M1+E2 -0.12 1 4.59 7 +219RN2 G KC=3.69 6$LC=0.684 10$MC=0.1629 23 +219RN G 154.208 105.84 13M1 3.83 6 +219RN2 G KC=3.09 5$LC=0.560 8$MC=0.1331 19 219RN G 158.635 100.713 16M1+E2 -0.18 11 3.46 12 -219RN2 G KC=2.77 13$LC=0.523 13$MC=0.125 4 +219RN2 G KC=2.77 13$LC=0.523 13$MC=0.125 4 219RN L 269.48 1 3/2+ 14.2 PS 230 219RN A 5606.99 2125.8 114.5 -219RN G 110.856 100.058 4 E2 5.36 8 -219RN2 G KC=0.363 5$LC=3.69 6$MC=0.994 14 -219RN G 255.2 2 0.048 7 +219RN G 110.856 100.058 4E2 5.36 8 +219RN2 G KC=0.363 5$LC=3.69 6$MC=0.994 14 +219RN G 255.2 2 0.048 7 219RN G 269.463 1014.23 32M1+E2 0.15 4 0.789 14 -219RN2 G KC=0.637 12$LC=0.1157 17$MC=0.0275 4 +219RN2 G KC=0.637 12$LC=0.1157 17$MC=0.0275 4 219RN L 338.27 1 (5/2)+ 6.1 PS 28 219RN A 5539.43 2110.6 104.8 -219RN G 179.54 6 0.154 14M1+E2 0.53 5 2.12 7 -219RN2 G KC=1.62 7$LC=0.376 6$MC=0.0922 16 -219RN G 323.871 104.06 8 M1+E2 0.18 10 0.473 17 -219RN2 G KC=0.382 15$LC=0.0691 17$MC=0.0164 4 -219RN G 334.01 6 0.100 6 (E2) 0.1007 15 -219RN2 G KC=0.0546 8$LC=0.0343 5$MC=0.00895 13 -219RN G 338.282 102.85 6 M1 0.430 6 -219RN2 G KC=0.348 5$LC=0.0622 9$MC=0.01475 21 +219RN G 179.54 6 0.154 14M1+E2 0.53 5 2.12 7 +219RN2 G KC=1.62 7$LC=0.376 6$MC=0.0922 16 +219RN G 323.871 104.06 8M1+E2 0.18 10 0.473 17 +219RN2 G KC=0.382 15$LC=0.0691 17$MC=0.0164 4 +219RN G 334.01 6 0.100 6(E2) 0.1007 15 +219RN2 G KC=0.0546 8$LC=0.0343 5$MC=0.00895 13 +219RN G 338.282 102.85 6M1 0.430 6 +219RN2 G KC=0.348 5$LC=0.0622 9$MC=0.01475 21 219RN L 342.78 2 (5/2,7/2)- -219RN G 328.38 3 0.203 10(E1) 0.0271 4 -219RN2 G KC=0.0220 3$LC=0.00387 6$MC=9.16E-4 13 -219RN G 342.78 2 0.226 13E1 0.0246 4 -219RN2 G KC=0.0200 3$LC=0.00351 5$MC=8.28E-4 12 +219RN G 328.38 3 0.203 10(E1) 0.0271 4 +219RN2 G KC=0.0220 3$LC=0.00387 6$MC=9.16E-4 13 +219RN G 342.78 2 0.226 13E1 0.0246 4 +219RN2 G KC=0.0200 3$LC=0.00351 5$MC=8.28E-4 12 219RN L 376.26 2 (9/2)+ 6.9 PS 38 219RN A 5502.12 210.74 2544 -219RN G 249.49 3 0.038 10M1+E2 0.6 4 -219RN2 G KC=0.5 4$LC=0.125 20$MC=0.031 4 -219RN G 361.89 2 0.028 7 -219RN G 371.676 150.499 11M1 0.333 5 -219RN2 G KC=0.270 4$LC=0.0481 7$MC=0.01139 16 -219RN G 376.26 2 0.013 4 +219RN G 249.49 3 0.038 10M1+E2 0.6 4 +219RN2 G KC=0.5 4$LC=0.125 20$MC=0.031 4 +219RN G 361.89 2 0.028 7 +219RN G 371.676 150.499 11M1 0.333 5 +219RN2 G KC=0.270 4$LC=0.0481 7$MC=0.01139 16 +219RN G 376.26 2 0.013 4 219RN L 377.33 6 (7/2,9/2)- 219RN G 34.5 2 -219RN G 362.9 2 0.016 7 -219RN G 372.86 6 5100E-5 0 E1 0.0205 3 -219RN2 G KC=0.01667 24$LC=0.00289 4$MC=6.82E-4 10 +219RN G 362.9 2 0.016 7 +219RN G 372.86 6 0.051 E1 0.0205 3 +219RN2 G KC=0.01667 24$LC=0.00289 4$MC=6.82E-4 10 219RN L 397.1 4 + 219RN A 5481.7 5 0.008 3150 -219RN G 270.3 4 0.0007 4 +219RN G 270.3 4 0.0007 4 219RN L 445.03 1 (5/2)+ 6.2 PS 31 219RN A 5434.60 211.60 249 -219RN G 102.2 2 0.0008 4 +219RN G 102.2 2 0.0008 4 219RN G 106.78 3 0.0233 14(M1) 10.89 16 -219RN2 G KC=8.77 13$LC=1.608 23$MC=0.382 6 -219RN G 175.65 150.017 4 -219RN G 430.6 3 0.020 6 -219RN G 445.033 121.28 4 M1 0.205 3 -219RN2 G KC=0.1661 24$LC=0.0295 5$MC=0.00698 10 +219RN2 G KC=8.77 13$LC=1.608 23$MC=0.382 6 +219RN G 175.65 150.017 4 +219RN G 430.6 3 0.020 6 +219RN G 445.033 121.28 4M1 0.205 3 +219RN2 G KC=0.1661 24$LC=0.0295 5$MC=0.00698 10 219RN L 446.82 3 (5/2)- 219RN A 5432.83 210.50 8 27 -219RN G 69.5 1 0.007 3 M1 7.36 11 -219RN2 G KC=$LC=5.60 9$MC=1.33 2 +219RN G 69.5 1 0.007 3M1 7.36 11 +219RN2 G LC=5.60 9$MC=1.33 2 219RN G 104.04 4 0.0194 21M1+E2 9.4 24 -219RN2 G KC=5 5$LC=3.3 16$MC=0.9 5 -219RN G 108.5 2 0.006 3 -219RN G 177.3 1 0.047 4 -219RN G 288.18 3 0.161 5 E1 0.0364 6 -219RN2 G KC=0.0295 5$LC=0.00527 8$MC=1249E-6 18 +219RN2 G KC=5 5$LC=3.3 16$MC=0.9 5 +219RN G 108.5 2 0.006 3 +219RN G 177.3 1 0.047 4 +219RN G 288.18 3 0.161 5E1 0.0364 6 +219RN2 G KC=0.0295 5$LC=0.00527 8$MC=1249E-6 18 219RN G 432.45 3 0.0356 29 219RN L 490.92 2 (5/2,7/2,9/2)- -219RN G 114.7 2 0.010 4 +219RN G 114.7 2 0.010 4 219RN L 514.5 1 (9/2)+ 219RN A 5366.37 230.13 45 -219RN G 138.3 3 0.0017 7 +219RN G 138.3 3 0.0017 7 219RN G 355.7 2 0.0028 14 -219RN G 387.7 2 0.016 6 -219RN G 500.0 4 0.0014 6 -219RN G 510.0 4 0.0004 3 +219RN G 387.7 2 0.016 6 +219RN G 500.0 4 0.0014 6 +219RN G 510.0 4 0.0004 3 219RN L 517.7 + 219RN G 70.9 2 0.0036 11 219RN L 541.99 2 (7/2)+ 219RN A 5339.37 210.13 32 219RN G 165.8 2 0.0054 28 -219RN G 383.35 2 0.007 4 -219RN G 527.611 130.073 4 -219RN G 537.6 1 0.0021 7 -219RN G 541.99 2 0.0014 6 +219RN G 383.35 2 0.007 4 +219RN G 527.611 130.073 4 +219RN G 537.6 1 0.0021 7 +219RN G 541.99 2 0.0014 6 219RN L 594.1 1 (7/2)- 219RN A 5288.19 230.16 4 13 -219RN G 103.2 2 0.006 3 M1+E2 9.6 24 -219RN2 G KC=5 5$LC=3.5 17$MC=0.9 5 -219RN G 147.2 3 0.006 3 -219RN G 251.6 3 0.055 10M1+E2 0.6 4 -219RN2 G KC=0.4 4$LC=0.122 20$MC=0.030 4 +219RN G 103.2 2 0.006 3M1+E2 9.6 24 +219RN2 G KC=5 5$LC=3.5 17$MC=0.9 5 +219RN G 147.2 3 0.006 3 +219RN G 251.6 3 0.055 10M1+E2 0.6 4 +219RN2 G KC=0.4 4$LC=0.122 20$MC=0.030 4 219RN G 255.7 3 0.0055 28 -219RN G 579.6 3 0.0014 6 -219RN G 594.0 3 0.0014 6 +219RN G 579.6 3 0.0014 6 +219RN G 594.0 3 0.0014 6 219RN L 598.72 2 (5/3,7/2,9/2)+ 219RN A 5283.65 210.093 21.8 -219RN G 221.32 240.036 6 E1 0.0675 10 -219RN2 G KC=0.0543 8$LC=0.01005 15$MC=0.00239 4 +219RN G 221.32 240.036 6E1 0.0675 10 +219RN2 G KC=0.0543 8$LC=0.01005 15$MC=0.00239 4 219RN G 260.4 3 0.0067 28 -219RN G 584.3 3 0.0014 6 -219RN G 598.721 240.092 4 +219RN G 584.3 3 0.0014 6 +219RN G 598.721 240.092 4 219RN L 623.68 4 + 219RN A 5259.14 210.042 35 219RN G 247.2 5 0.0097 28 -219RN G 609.31 4 0.057 3 +219RN G 609.31 4 0.057 3 219RN G 619.1 4 0.0036 11 -219RN G 623.68 4 0.009 4 +219RN G 623.68 4 0.009 4 219RN L 646.1 1 + 219RN A 5237.12 230.041 27 -219RN G 131.6 2 0.006 3 +219RN G 131.6 2 0.006 3 219RN G 199.3 3 0.0030 14 -219RN G 487.5 2 0.011 2 -219RN G 631.7 7 0.0004 3 -219RN G 641.7 4 0.0017 7 -219RN G 646.1 5 0.0004 4 +219RN G 487.5 2 0.011 2 +219RN G 631.7 7 0.0004 3 +219RN G 641.7 4 0.0017 7 +219RN G 646.1 5 0.0004 4 219RN L 672.6 5 + 219RN A 5211.1 5 0.0053 147 -219RN G 545.8 5 0.0011 6 +219RN G 545.8 5 0.0011 6 219RN L 711.3 1 + 219RN A 5173.10 230.026 17.9 219RN G 112.6 -219RN G 368.56 120.009 4 -219RN G 696.9 7 0.0007 3 +219RN G 368.56 120.009 4 +219RN G 696.9 7 0.0007 3 219RN G 711.3 2 0.0037 10 219RN L 732.8 1 + 219RN A 5151.98 230.021 16.6 -219RN G 286.0 4 0.0011 6 +219RN G 286.0 4 0.0011 6 219RN G 355.5 2 0.0043 14 219RN G 390.1 2 0.0046 21 -219RN G 574.1 7 0.0011 6 -219RN G 718.4 4 0.0014 6 +219RN G 574.1 7 0.0011 6 +219RN G 718.4 4 0.0014 6 219RN G 728.4 8 0.00028 14 -219RN G 732.8 6 0.0006 3 +219RN G 732.8 6 0.0006 3 219RN L 748 + 219RN A 5137.1 0.0017 168 219RN L 773 + diff --git a/HEN_HOUSE/spectra/lnhb/Ra-224.txt b/HEN_HOUSE/spectra/lnhb/Ra-224.txt index 44360e9a8..b9bf1ca76 100644 --- a/HEN_HOUSE/spectra/lnhb/Ra-224.txt +++ b/HEN_HOUSE/spectra/lnhb/Ra-224.txt @@ -8,51 +8,51 @@ 220RN3C 1983Sc13, 1984Ge07, 1984Bo15, 1985Pr01, 1991Ry01, 1991Ho15, 1992Li05, 220RN4C 1993Ba72, 1995Ar33, 1996Sc06, 1997Ar04, 1997Tr17, 1998ScZM, 1999ScZX, 220RN5C 2002Ba85, 2002Ra45, 2003Au03, 2004Sc04, 2007St23, 2008Ki07 -220RN T Auger electrons and ^X ray energies and emission intensities: -220RN T {U Energy (keV)} {U Intensity } {U Line } +220RN T Auger electrons and X ray energies and emission intensities: +220RN T {U Energy (keV)} {U Intensity} {U Line} 220RN T -220RN T 81.07 0.130 3 XKA2 -220RN T 83.78 0.214 4 XKA1 +220RN T 81.07 0.130 3 XKA2 +220RN T 83.78 0.214 4 XKA1 220RN T -220RN T 94.247 |] XKB3 -220RN T 94.868 |] 0.0743 18 XKB1 -220RN T 95.449 |] XKB5II +220RN T 94.247 |] XKB3 +220RN T 94.868 |] 0.0743 18 XKB1 +220RN T 95.449 |] XKB5II 220RN T -220RN T 97.48 |] XKB2 -220RN T 97.853 |] 0.0238 7 XKB4 -220RN T 98.357 |] XKO23 +220RN T 97.48 |] XKB2 +220RN T 97.853 |] 0.0238 7 XKB4 +220RN T 98.357 |] XKO23 220RN T -220RN T 10.137-17.28 0.373 16 XL (total) -220RN T 10.137 0.00774 20 XLL -220RN T 11.598-11.726 0.138 4 XLA -220RN T 12.855 0.00413 11 XLC -220RN T 13.52-14.565 0.191 5 XLB -220RN T 16.77-17.28 0.0424 9 XLG +220RN T 10.137-17.28 0.373 16 XL (total) +220RN T 10.137 0.00774 20 XLL +220RN T 11.598-11.726 0.138 4 XLA +220RN T 12.855 0.00413 11 XLC +220RN T 13.52-14.565 0.191 5 XLB +220RN T 16.77-17.28 0.0424 9 XLG 220RN T -220RN T 62.017-68.885 |] KLL AUGER -220RN T 75.744-83.785 |] 0.0151 19 ^KLX AUGER -220RN T 89.45-98.39 |] KXY AUGER -220RN T 5.58-11.48 0.498 16 L AUGER +220RN T 62.017-68.885 |] KLL AUGER +220RN T 75.744-83.785 |] 0.0151 19 KLX AUGER +220RN T 89.45-98.39 |] KXY AUGER +220RN T 5.58-11.48 0.498 16 L AUGER 224RA P 0.0 0+ 3.631 D 2 5788.85 15 220RN N 1.0 1.0 1 1.0 220RN L 0 0+ 55.8 S 3 220RN A 5685.48 1594.73 5 1 220RN L 240.986 6 2+ 0.15 NS 220RN A 5448.80 155.25 5 1.04 -220RN G 240.986 6 4.12 4 E2 0.276 4 -220RN2 G KC=0.1109 16$LC=0.1220 17$MC=0.0324 5 +220RN G 240.986 6 4.12 4E2 0.276 4 +220RN2 G KC=0.1109 16$LC=0.1220 17$MC=0.0324 5 220RN L 533.69 104+ 220RN A 5161.32 180.0072 8 17.9 -220RN G 292.7 1 0.0063 7 E2 0.1487 21 -220RN2 G KC=0.0727 11$LC=0.0564 8$MC=0.01484 21 +220RN G 292.7 1 0.0063 7E2 0.1487 21 +220RN2 G KC=0.0727 11$LC=0.0564 8$MC=0.01484 21 220RN L 645.44 9 1- 220RN A 5051.56 170.0076 103.7 -220RN G 404.45 9 0.0022 5 E1 0.0171724 -220RN2 G KC=0.01401 20$LC=0.00241 4$MC=5.68E-4 8 -220RN G 645.44 9 0.0054 9 E1 0.0066310 -220RN2 G KC=0.00546 8$LC=8.94E-4 13$MC=2.10E-4 3 +220RN G 404.45 9 0.0022 5E1 0.0171724 +220RN2 G KC=0.01401 20$LC=0.00241 4$MC=5.68E-4 8 +220RN G 645.44 9 0.0054 9E1 0.0066310 +220RN2 G KC=0.00546 8$LC=8.94E-4 13$MC=2.10E-4 3 220RN L 663.03 10(3)- 220RN A 5034.29 180.0030 5 6.4 -220RN G 422.04 100.0030 5 [E1] 0.0156722 -220RN2 G KC=0.01280 18$LC=0.00219 3$MC=5.16E-4 8 +220RN G 422.04 100.0030 5[E1] 0.0156722 +220RN2 G KC=0.01280 18$LC=0.00219 3$MC=5.16E-4 8 diff --git a/HEN_HOUSE/spectra/lnhb/Ra-225.txt b/HEN_HOUSE/spectra/lnhb/Ra-225.txt index 71847f180..ffaa1daa4 100644 --- a/HEN_HOUSE/spectra/lnhb/Ra-225.txt +++ b/HEN_HOUSE/spectra/lnhb/Ra-225.txt @@ -2,34 +2,34 @@ 225AC H TYP=full$AUT=X. Huang$CUT=30-MAY-2007$ 225AC C Evaluation history: Type=full;Author=X. Huang;Cutoff date=30-MAY-2007 225AC C References: 2008Ki07 -225AC T Auger electrons and ^X ray energies and emission intensities: -225AC T {U Energy (keV)} {U Intensity } {U Line } +225AC T Auger electrons and X ray energies and emission intensities: +225AC T {U Energy (keV)} {U Intensity} {U Line} 225AC T 225AC T 225AC T 225AC T -225AC T 10.8701-18.9228 13.6 6 XL (total) +225AC T 10.8701-18.9228 13.6 6 XL (total) 225AC T 10.8701 XLL 225AC T 12.5002-12.6505 XLA 225AC T 14.0807 XLC 225AC T 14.6024-16.6263 XLB 225AC T 17.813-18.9228 XLG 225AC T -225AC T 5.87-19.69 15.7 7 L AUGER +225AC T 5.87-19.69 15.7 7 L AUGER 225RA P 0.0 1/2+ 14.82 D 19 356 5 225AC N 1.0 1.0 1 1.0 225AC L 0 3/2- 10.0 D 1 -225AC B 356 5 31.2 20 7.38 1U +225AC B 356 5 31.2 20 7.38 1 225ACS B EAV=100.7 16 225AC L 40.09 5 3/2+ 0.72 NS 3 -225AC B 316 5 68.8 20 6.87 2 +225AC B 316 5 68.8 20 6.87 225ACS B EAV=88.3 16 -225AC G 40.09 5 30.0 7 E1 1.293 19 -225AC2 G KC=$LC=0.974 14$MC=0.24 4 +225AC G 40.09 5 30.0 7E1 1.293 19 +225AC2 G LC=0.974 14$MC=0.24 4 225AC L 120.8 5/2- -225AC B 235 5 0.01 9.9 3U +225AC B 235 5 0.01 9.9 1U 225ACS B EAV=70.5 16 225AC L 155.6 5/2+ -225AC B 200 5 0.01 10.1 +225AC B 200 5 0.01 10.1 2 225ACS B EAV=54.0 15 diff --git a/HEN_HOUSE/spectra/lnhb/Ra-226.txt b/HEN_HOUSE/spectra/lnhb/Ra-226.txt index b096c286e..979e01350 100644 --- a/HEN_HOUSE/spectra/lnhb/Ra-226.txt +++ b/HEN_HOUSE/spectra/lnhb/Ra-226.txt @@ -9,26 +9,26 @@ 222RN4C 1982Fa10, 1983Ol01, 1983Sc13, 1990Ho28, 1991Li11, 1991Ry01, 1996Ak02, 222RN5C 1996El01, 1996Sc06, 1998Mo14, 2000Sa32, 2001La14, 2002De03, 2002Ba85, 222RN6C 2003Au03, 2002MoZP, 2004Mo07, 2007BeZP -222RN T Auger electrons and ^X ray energies and emission intensities: -222RN T {U Energy (keV)} {U Intensity } {U Line } +222RN T Auger electrons and X ray energies and emission intensities: +222RN T {U Energy (keV)} {U Intensity} {U Line} 222RN T -222RN T 81.07 0.192 4 XKA2 -222RN T 83.78 0.317 6 XKA1 +222RN T 81.07 0.192 4 XKA2 +222RN T 83.78 0.317 6 XKA1 222RN T -222RN T 94.247 |] XKB3 -222RN T 94.868 |] 0.1098 25 XKB1 -222RN T 95.449 |] XKB5II +222RN T 94.247 |] XKB3 +222RN T 94.868 |] 0.1098 25 XKB1 +222RN T 95.449 |] XKB5II 222RN T -222RN T 97.48 |] XKB2 -222RN T 97.853 |] 0.0351 10 XKB4 -222RN T 98.357 |] XKO23 +222RN T 97.48 |] XKB2 +222RN T 97.853 |] 0.0351 10 XKB4 +222RN T 98.357 |] XKO23 222RN T -222RN T 10.14-17.26 0.807 14 XL (total) -222RN T 10.14 0.0156 4 XLL -222RN T 11.5981-11.7259 0.277 7 XLA -222RN T 12.8551 0.00919 24 XLC -222RN T 13.5219-15.1631 0.412 9 XLB -222RN T 16.2398-17.26 0.0927 20 XLG +222RN T 10.14-17.26 0.807 14 XL (total) +222RN T 10.14 0.0156 4 XLL +222RN T 11.5981-11.7259 0.277 7 XLA +222RN T 12.8551 0.00919 24 XLC +222RN T 13.5219-15.1631 0.412 9 XLB +222RN T 16.2398-17.26 0.0927 20 XLG 226RA P 0.0 0+ 1600 Y 7 4870.62 25 222RN N 1.0 1.0 1 1.0 222RN L 0 0+ 3.8232 D 8 @@ -36,19 +36,19 @@ 222RN L 186.211 132+ 0.32 NS 222RN A 4601 1 5.95 4 0.96 222RN G 186.211 133.555 19E2 0.677 10 -222RN2 G KC=0.190 3$LC=0.360 5$MC=0.0963 14 +222RN2 G KC=0.190 3$LC=0.360 5$MC=0.0963 14 222RN L 448.37 124+ 222RN A 4340 1 0.0066 2210.4 -222RN G 262.27 5 0.0055 18[E2] 0.209 4 -222RN2 G KC=0.0923 14$LC=0.0868 14$MC=0.0230 4 +222RN G 262.27 5 0.0055 18[E2] 0.209 4 +222RN2 G KC=0.0923 14$LC=0.0868 14$MC=0.0230 4 222RN L 600.66 5 1- 222RN A 4191 2 0.0008 4.5 -222RN G 414.60 5 3000E-7 0 [E1] 0.0162823 -222RN2 G KC=0.01329 19$LC=0.00228 4$MC=5.37E-4 8 -222RN G 600.66 5 5000E-7 0 [E1] 0.0076211 -222RN2 G KC=0.00627 9$LC=1034E-6 15$MC=2.43E-4 4 +222RN G 414.60 5 0.0003 [E1] 0.0162823 +222RN2 G KC=0.01329 19$LC=0.00228 4$MC=5.37E-4 8 +222RN G 600.66 5 0.0005 [E1] 0.0076211 +222RN2 G KC=0.00627 9$LC=1034E-6 15$MC=2.43E-4 4 222RN L 635.47 153- 222RN A 4160 2 0.0002 8.65 -222RN G 449.37 102000E-7 0 [E1] 0.0137320 -222RN2 G KC=0.01123 16$LC=0.00191 3$MC=4.49E-4 7 +222RN G 449.37 100.0002 [E1] 0.0137320 +222RN2 G KC=0.01123 16$LC=0.00191 3$MC=4.49E-4 7 diff --git a/HEN_HOUSE/spectra/lnhb/Ra-228.txt b/HEN_HOUSE/spectra/lnhb/Ra-228.txt index 1eb0cfceb..f91b2915c 100644 --- a/HEN_HOUSE/spectra/lnhb/Ra-228.txt +++ b/HEN_HOUSE/spectra/lnhb/Ra-228.txt @@ -3,20 +3,20 @@ 228AC C Evaluation history: Type=Full;Author=A.Luca;Cutoff date=31-DEC-2008 228AC C References: 1931Cu01, 1960Du11, 1961To10, 1962Ma58, 1972HeYY, 1995So11, 228AC2C 1997Ar08, 2003Au03 -228AC T Auger electrons and ^X ray energies and emission intensities: -228AC T {U Energy (keV)} {U Intensity } {U Line } +228AC T Auger electrons and X ray energies and emission intensities: +228AC T {U Energy (keV)} {U Intensity} {U Line} 228AC T 228AC T 228AC T 228AC T -228AC T 10.8701-18.9228 9.6 19 XL (total) -228AC T 10.8701 0.24 8 XLL -228AC T 12.5002-12.6505 4.0 11 XLA -228AC T 14.0807 0.046 14 XLC -228AC T 14.6024-16.6263 4.3 7 XLB -228AC T 17.813-18.9228 1.01 17 XLG +228AC T 10.8701-18.9228 9.6 19 XL (total) +228AC T 10.8701 0.24 8 XLL +228AC T 12.5002-12.6505 4.0 11 XLA +228AC T 14.0807 0.046 14 XLC +228AC T 14.6024-16.6263 4.3 7 XLB +228AC T 17.813-18.9228 1.01 17 XLG 228AC T -228AC T 5.87-19.67 12 5 L AUGER +228AC T 5.87-19.67 12 5 L AUGER 228RA P 0.0 0+ 5.75 Y 4 45.8 7 228AC N 1.0 1.0 1 1.0 228AC L 0 3+ 6.15 H 3 @@ -24,22 +24,22 @@ 228AC B 39.5 7 12 10 7.07 1 228ACS B EAV=10.0 2 228AC G 6.28 3 1.8E-6 15M2 6.68E6 19 -228AC2 G KC=$LC=$MC=4.93E6 14 +228AC2 G MC=4.93E6 14 228AC L 6.67 2 1+ 228AC B 39.1 7 49 10 6.45 228ACS B EAV=9.9 2 -228AC G 6.67 2 5.7E-5 9 E2 1.56E6 4 -228AC2 G KC=$LC=$MC=1.172E6 24 +228AC G 6.67 2 0.000057 9E2 1.56E6 4 +228AC2 G MC=1.172E6 24 228AC L 20.19 3 1- -228AC B 25.6 7 8.7 9 6.2 1 +228AC B 25.6 7 8.7 9 6.2 1 228ACS B EAV=6.5 2 -228AC G 13.520 361.6 1 E1 5.86 10 -228AC2 G KC=$LC=$MC=4.48 7 +228AC G 13.520 361.6 1E1 5.86 10 +228AC2 G MC=4.48 7 228AC L 33.07 111+ 228AC B 12.7 7 30 10 5.11 228ACS B EAV=3.2 2 -228AC G 12.88 110.30 6 E1 6.67 18 -228AC2 G KC=$LC=$MC=5.11 14 -228AC G 26.40 110.14 5 M1+E2 0.07 201 4 -228AC2 G KC=$LC=151 3$MC=37.2 7 +228AC G 12.88 110.30 6E1 6.67 18 +228AC2 G MC=5.11 14 +228AC G 26.40 110.14 5M1+E2 0.07 201 4 +228AC2 G LC=151 3$MC=37.2 7 diff --git a/HEN_HOUSE/spectra/lnhb/Rb-82.txt b/HEN_HOUSE/spectra/lnhb/Rb-82.txt index 9abe1f1fe..ec9f69e79 100644 --- a/HEN_HOUSE/spectra/lnhb/Rb-82.txt +++ b/HEN_HOUSE/spectra/lnhb/Rb-82.txt @@ -4,152 +4,143 @@ 82KR C References: 1953Li27, 1953Kr10, 1962Sa10, 1967Vr07, 1969Ra06, 1970Gr01, 82KR2C 1970Hr02, 1978Gr17, 1983Me08, 1985Ze03, 1987Ju01, 1987Wo01, 1987Ho06, 82KR3C 1996Sc06, 1998Sc28, 2000Sc47, 2002Ba85, 2008Ki07, 2012Gr03, 2012Wa38 - 82KR T Auger electrons and ^X ray energies and emission intensities: - 82KR T {U Energy (keV)} {U Intensity } {U Line } + 82KR T Auger electrons and X ray energies and emission intensities: + 82KR T {U Energy (keV)} {U Intensity} {U Line} 82KR T - 82KR T 12.599 0.760 9 XKA2 - 82KR T 12.65 1.466 16 XKA1 + 82KR T 12.599 0.760 9 XKA2 + 82KR T 12.65 1.466 16 XKA1 82KR T - 82KR T 14.105 |] XKB3 - 82KR T 14.113 |] 0.351 5 XKB1 - 82KR T 14.238 |] XKB5II + 82KR T 14.105 |] XKB3 + 82KR T 14.113 |] 0.351 5 XKB1 + 82KR T 14.238 |] XKB5II 82KR T - 82KR T 14.315 |] XKB2 - 82KR T 14.328 |] 0.0354 12 XKB4 + 82KR T 14.315 |] XKB2 + 82KR T 14.328 |] 0.0354 12 XKB4 82KR T - 82KR T 1.387-1.911 0.1066 18 XL (total) - 82KR T 1.387 0.00262 7 XLL - 82KR T 1.585-1.586 0.0647 15 XLA - 82KR T 1.439 0.00127 4 XLC - 82KR T 1.637-1.831 0.0377 9 XLB - 82KR T 1.706-1.911 0.000373 7 XLG + 82KR T 1.387-1.911 0.1066 18 XL (total) + 82KR T 1.387 0.00262 7 XLL + 82KR T 1.585-1.586 0.0647 15 XLA + 82KR T 1.439 0.00127 4 XLC + 82KR T 1.637-1.831 0.0377 9 XLB + 82KR T 1.706-1.911 0.000373 7 XLG 82KR T - 82KR T 10.398-10.885 |] KLL AUGER - 82KR T 12.077-12.637 |] 1.394 20 ^KLX AUGER - 82KR T 13.741-14.298 |] KXY AUGER - 82KR T 1.09-1.91 4.961 25 L AUGER + 82KR T 10.398-10.885 |] KLL AUGER + 82KR T 12.077-12.637 |] 1.394 20 KLX AUGER + 82KR T 13.741-14.298 |] KXY AUGER + 82KR T 1.09-1.91 4.961 25 L AUGER 82RB P 0.0 1+ 1.2652 M 45 4403 3 82KR N 1.0 1.0 1 1.0 82KR L 0 0+ STABLE - 82KR E 81.81 243.01 3 4.6 - 82KR2 E EAV=1535.6 15$CK=0.8779 14$CL=0.1014 12$CM=0.0183 4$CN=0.0024 2$CO= + 82KR E 81.81 243.01 34.6 + 82KR2 E EAV=1535.6 15$CK=0.8779 14$CL=0.1014 12$CM=0.0183 4$CN=0.0024 2 82KR L 776.522 102+ - 82KR E 13.10 191.06 2 4.8 - 82KR2 E EAV=1168.5 15$CK=0.8778 14$CL=0.1016 12$CM=0.0183 4$CN=0.0024 2$CO= - 82KR G 776.52 1 15.02 19E2 9.23E-413 - 82KR2 G KC=8.19E-4 12$LC=8.84E-5 13$MC=1.43E-5 2 + 82KR E 13.10 191.06 24.8 + 82KR2 E EAV=1168.5 15$CK=0.8778 14$CL=0.1016 12$CM=0.0183 4$CN=0.0024 2 + 82KR G 776.520 1015.02 19E2 9.23E-413 + 82KR2 G KC=8.19E-4 12$LC=8.84E-5 13$MC=1.43E-5 2 82KR L 1474.894 102+ 15 PS - 82KR E 0.135 7 0.0284 146.3 - 82KR2 E EAV=844.1 14$CK=0.8776 14$CL=0.1017 12$CM=0.0183 4$CN=0.0024 2$CO= + 82KR E 0.135 70.0284 146.3 + 82KR2 E EAV=844.1 14$CK=0.8776 14$CL=0.1017 12$CM=0.0183 4$CN=0.0024 2 82KR G 698.37 5 0.159 11 - 82KR G 1474.88 1 0.0904 24E2 2.89E-44 - 82KR2 G KC=1.90E-4 3$LC=2.00E-5 3$MC= + 82KR G 1474.880 100.0904 24E2 2.89E-4 4 + 82KR2 G KC=1.90E-4 3$LC=2.00E-5 3 82KR L 1487.62 7 0+ 10 PS - 82KR E 0.0444 410.0096 9 6.7 - 82KR2 E EAV=838.3 14$CK= $CL= $CM= $CN= $CO= - 82KR G 711.2 1 0.060 4 + 82KR E 0.0444 410.0096 96.7 + 82KR2 E EAV=838.3 14 + 82KR G 711.2 1 0.060 4 82KR L 1820.6 4 4+ - 82KR E 0.00007 7 0.00003 3 11.5 2U - 82KR2 E EAV=735.6 15$CK= $CL= $CM= $CN= $CO= - 82KR G 1044.1 5 0.0009 6 + 82KR E 0.00007 70.00003 311.5 2U + 82KR2 E EAV=735.6 15 + 82KR G 1044.1 5 0.0009 6 82KR L 1956.797 20(2)+ - 82KR E 0.00890 140.0047 8 6.7 - 82KR2 E EAV=624.8 14$CK= $CL= $CM= $CN= $CO= - 82KR G 1180.27 2 0.0165 15 - 82KR G 1956.75 4 0.0068 6 + 82KR E 0.00890 140.0047 86.7 + 82KR2 E EAV=624.8 14 + 82KR G 1180.270 200.0165 15 + 82KR G 1956.750 400.0068 6 82KR L 2171.68 3 0+ - 82KR E 0.317 6 0.283 5 5 - 82KR2 E EAV=528.6 14$CK=0.8773 14$CL=0.1019 12$CM=0.0184 4$CN=0.0024 2$CO= - 82KR G 696.86 150.071 6 - 82KR G 1395.14 3 0.529 8 E2 + 82KR E 0.317 60.283 55 + 82KR2 E EAV=528.6 14$CK=0.8773 14$CL=0.1019 12$CM=0.0184 4$CN=0.0024 2 + 82KR G 696.86 150.071 6 + 82KR G 1395.140 300.529 8E2 82KR L 2450.09 9 0(+),1,2+ - 82KR E 0.0050 4 0.0105 8 6.3 - 82KR2 E EAV=405.7 14$CK=0.8771 14$CL=0.1021 12$CM=0.0184 4$CN=0.0024 2$CO= + 82KR E 0.0050 40.0105 86.3 + 82KR2 E EAV=405.7 14$CK=0.8771 14$CL=0.1021 12$CM=0.0184 4$CN=0.0024 2 82KR G 975.2 1 0.0084 11 - 82KR G 1673.55 9 0.0071 5 + 82KR G 1673.55 9 0.0071 5 82KR L 2479.72 3 1,2+ - 82KR E 0.0288 7 0.0682 145.5 - 82KR2 E EAV=392.7 14$CK=0.8771 14$CL=0.1021 12$CM=0.0184 4$CN=0.0024 2$CO= + 82KR E 0.0288 70.0682 145.5 + 82KR2 E EAV=392.7 14$CK=0.8771 14$CL=0.1021 12$CM=0.0184 4$CN=0.0024 2 82KR G 522.8 5 0.0045 15 - 82KR G 992.2 1 0.0018 8 - 82KR G 1703.19 4 0.0505 11 + 82KR G 992.2 1 0.0018 8 + 82KR G 1703.190 400.0505 11 82KR G 2479.65 4 0.0401 16 82KR L 2509.0 5 + - 82KR E 0.00041 250.0011 6 7.4 - 82KR2 E EAV=380.0 14$CK= $CL= $CM= $CN= $CO= - 82KR G 1021.4 5 0.0015 9 + 82KR E 0.00041 250.0011 67.4 + 82KR2 E EAV=380.0 14 + 82KR G 1021.4 5 0.0015 9 82KR L 2556.3 7 (4)+ - 82KR E 0.00007 4 0.00023 1110 2U - 82KR2 E EAV=359.4 14$CK= $CL= $CM= $CN= $CO= + 82KR E 0.00007 40.00023 1110 2U + 82KR2 E EAV=359.4 14 82KR G 1081.4 7 0.00030 15 82KR L 2561.7 5 + - 82KR E 0.00033 190.0011 6 7.3 - 82KR2 E EAV=357.0 14$CK= $CL= $CM= $CN= $CO= - 82KR G 1086.8 5 0.0014 8 + 82KR E 0.00033 190.0011 67.3 + 82KR2 E EAV=357.0 14 + 82KR G 1086.8 5 0.0014 8 82KR L 2655.82 101,2(+)+ 82KR E 0.00284 340.0142 176.1 - 82KR2 E EAV=316.2 13$CK=0.8770 14$CL=0.1022 12$CM=0.0184 4$CN=0.0024 2$CO= - 82KR G 1168.2 2 0.0014 6 + 82KR2 E EAV=316.2 13$CK=0.8770 14$CL=0.1022 12$CM=0.0184 4$CN=0.0024 2 + 82KR G 1168.20 200.0014 6 82KR G 1181.3 0.0030 15 - 82KR G 1879.18 150.0101 6 - 82KR G 2655.85 150.0026 6 + 82KR G 1879.18 150.0101 6 + 82KR G 2655.85 150.0026 6 82KR L 2944.14 4 (2)+ 82KR E 0.0500 195.4 - 82KR2 E EAV= $CK=0.8766 15$CL=0.1025 12$CM=0.0185 4$CN=0.0024 2$CO= - 82KR G 1123.6 7 0.0008 6 - 82KR G 2167.59 4 0.0431 6 + 82KR2 E CK=0.8766 15$CL=0.1025 12$CM=0.0185 4$CN=0.0024 2 + 82KR G 1123.6 7 0.0008 6 + 82KR G 2167.590 400.0431 6 82KR G 2944.0 2 0.0075 15 82KR L 3186.82 5 0,1,2+ 82KR E 0.0265 155.5 - 82KR2 E EAV= $CK=0.8763 15$CL=0.1028 12$CM=0.0185 4$CN=0.0024 2$CO= - 82KR G 1698.7 3 0.0015 8 + 82KR2 E CK=0.8763 15$CL=0.1028 12$CM=0.0185 4$CN=0.0024 2 + 82KR G 1698.7 3 0.0015 8 82KR G 1711.9 4 0.00165 30 82KR G 2410.26 5 0.0233 12 82KR L 3355.32 191,2(+)+ 82KR E 0.00134 136.7 - 82KR2 E EAV= $CK= $CL= $CM= $CN= $CO= - 82KR G 2578.7 2 0.00105 11 - 82KR G 3355.6 5 2.85E-4 30 + 82KR G 2578.70 200.00105 11 + 82KR G 3355.6 5 0.00028530 82KR L 3457.5 7 1,2(+)+ - 82KR E 11100E-8237.7 - 82KR2 E EAV= $CK= $CL= $CM= $CN= $CO= - 82KR G 3457.4 7 1.11E-4 23 + 82KR E 0.000111237.7 + 82KR G 3457.4 7 0.00011123 82KR L 3564.6 3 0(+),1,2+ 82KR E 0.0034 316 - 82KR2 E EAV= $CK= $CL= $CM= $CN= $CO= 82KR G 1607.7 3 0.00225 30 - 82KR G 2788.4 5 0.00114 8 + 82KR G 2788.4 5 0.00114 8 82KR L 3716.83 150(),1,2+ - 82KR E 0.008 3 5.8 - 82KR2 E EAV= $CK= $CL= $CM= $CN= $CO= - 82KR G 2241.98 170.0009 8 - 82KR G 2940.0 3 0.0071 29 + 82KR E 0.008 35.8 + 82KR G 2241.98 170.0009 8 + 82KR G 2940.00 300.0071 29 82KR L 3741.96 8 + - 82KR E 0.0036 6 5.9 - 82KR2 E EAV= $CK= $CL= $CM= $CN= $CO= - 82KR G 1785.13 7 0.0030 6 - 82KR G 2966.3 7 0.00060 5 + 82KR E 0.0036 65.9 + 82KR G 1785.13 7 0.0030 6 + 82KR G 2966.3 7 0.00060 5 82KR L 3815.1 101,2(+)+ - 82KR E 0.0019 8 5.6 - 82KR2 E EAV= $CK= $CL= $CM= $CN= $CO= - 82KR G 869.3 4 0.0014 8 - 82KR G 3815 1 4.51E-4 31 + 82KR E 0.0019 85.6 + 82KR G 869.3 4 0.0014 8 + 82KR G 3815.0 100.00045131 82KR L 3835.8 5 1,2+ - 82KR E 0.00089 5 6.3 - 82KR2 E EAV= $CK= $CL= $CM= $CN= $CO= - 82KR G 3059.2 5 0.00068 5 - 82KR G 3836 1 2.19E-4 23 + 82KR E 0.00089 56.3 + 82KR G 3059.2 5 0.00068 5 + 82KR G 3836 1 0.00021923 82KR L 3881.1 5 1,2(+)+ - 82KR E 0.00024 5 6.8 - 82KR2 E EAV= $CK= $CL= $CM= $CN= $CO= - 82KR G 3104.5 5 0.00015 5 - 82KR G 3881 1 8.7E-5 21 + 82KR E 0.00024 56.8 + 82KR G 3104.5 5 0.00015 5 + 82KR G 3881 1 0.00008721 82KR L 3911.1 101,2(+)+ - 82KR E 0.00010 2 7.1 - 82KR2 E EAV= $CK= $CL= $CM= $CN= $CO= - 82KR G 3911 1 1.05E-4 15 + 82KR E 0.00010 27.1 + 82KR G 3911.0 100.00010515 82KR L 3956.1 101,2(+)+ - 82KR E 0.00009 2 7.1 - 82KR2 E EAV= $CK=0.8722 15$CL=0.1061 12$CM=0.0192 4$CN=0.0025 2$CO= - 82KR G 3956 1 9.0E-5 15 + 82KR E 0.00009 27.1 + 82KR2 E CK=0.8722 15$CL=0.1061 12$CM=0.0192 4$CN=0.0025 2 + 82KR G 3956.0 100.00009015 diff --git a/HEN_HOUSE/spectra/lnhb/Re-186.txt b/HEN_HOUSE/spectra/lnhb/Re-186.txt index 5f9e899a4..11c6cbe7d 100644 --- a/HEN_HOUSE/spectra/lnhb/Re-186.txt +++ b/HEN_HOUSE/spectra/lnhb/Re-186.txt @@ -1,95 +1,95 @@ 186W 186RE EC DECAY (3.7186 D) -186W T Auger electrons and ^X ray energies and emission intensities: -186W T {U Energy (keV)} {U Intensity } {U Line } +186W T Auger electrons and X ray energies and emission intensities: +186W T {U Energy (keV)} {U Intensity} {U Line} 186W T -186W T 57.9823 1.736 30 XKA2 -186W T 59.3189 3.02 5 XKA1 +186W T 57.9823 1.736 30 XKA2 +186W T 59.3189 3.02 5 XKA1 186W T -186W T 66.952 |] XKB3 -186W T 67.2451 |] 1.000 23 XKB1 -186W T 67.664 |] XKB5II +186W T 66.952 |] XKB3 +186W T 67.2451 |] 1.000 23 XKB1 +186W T 67.664 |] XKB5II 186W T -186W T 69.033 |] XKB2 -186W T 69.295 |] 0.274 8 XKB4 -186W T 69.484 |] XKO23 +186W T 69.033 |] XKB2 +186W T 69.295 |] 0.274 8 XKB4 +186W T 69.484 |] XKO23 186W T -186W T 7.3881-11.6761 2.00 4 XL (total) -186W T 7.3881 0.0411 13 XLL -186W T 8.3352-8.3976 0.876 24 XLA -186W T 8.725 0.0159 5 XLC -186W T 9.526-10.2903 0.902 18 XLB -186W T 10.9501-11.6761 0.166 4 XLG +186W T 7.3881-11.6761 2.00 4 XL (total) +186W T 7.3881 0.0411 13 XLL +186W T 8.3352-8.3976 0.876 24 XLA +186W T 8.725 0.0159 5 XLC +186W T 9.526-10.2903 0.902 18 XLB +186W T 10.9501-11.6761 0.166 4 XLG 186W T -186W T 45.109-48.882 |] KLL AUGER -186W T 54.514-59.312 |] 0.291 26 ^KLX AUGER -186W T 63.89-69.51 |] KXY AUGER -186W T 4.5-12.1 4.96 5 L AUGER +186W T 45.109-48.882 |] KLL AUGER +186W T 54.514-59.312 |] 0.291 26 KLX AUGER +186W T 63.89-69.51 |] KXY AUGER +186W T 4.5-12.1 4.96 5 L AUGER 186RE P 0.0 1- 3.7186 D 17 581.6 17 186W N 1.328E1 1.328E1 0.0753 1.328E1 186W L 0 0+ STABLE 186W E 5.84 127.5 1 -186W 2 E EAV= $CK=0.7943 18$CL=0.1560 12$CM=0.0382 7$CN= $CO= +186W 2 E CK=0.7943 18$CL=0.1560 12$CM=0.0382 7 186W L 122.33 102+ 1.036 NS -186W E 1.69 3 7.8 1 -186W 2 E EAV= $CK=0.7836 19$CL=0.1638 13$CM=0.0404 8$CN= $CO= -186W G 122.33 100.603 6 E2 1.81 4 -186W 2 G KC=0.585 12$LC=0.927 19$MC=0.234 7 +186W E 1.69 37.8 1 +186W 2 E CK=0.7836 19$CL=0.1638 13$CM=0.0404 8 +186W G 122.33 100.603 6E2 1.81 4 +186W 2 G KC=0.585 12$LC=0.927 19$MC=0.234 7 186OS 186RE B- DECAY (3.7186 D) -186OS T Auger electrons and ^X ray energies and emission intensities: -186OS T {U Energy (keV)} {U Intensity } {U Line } +186OS T Auger electrons and X ray energies and emission intensities: +186OS T {U Energy (keV)} {U Intensity} {U Line} 186OS T -186OS T 61.4873 1.13 4 XKA2 -186OS T 63.0011 1.94 6 XKA1 +186OS T 61.4873 1.13 4 XKA2 +186OS T 63.0011 1.94 6 XKA1 186OS T -186OS T 71.078 |] XKB3 -186OS T 71.414 |] 0.650 23 XKB1 -186OS T 71.855 |] XKB5II +186OS T 71.078 |] XKB3 +186OS T 71.414 |] 0.650 23 XKB1 +186OS T 71.855 |] XKB5II 186OS T -186OS T 73.319 |] XKB2 -186OS T 73.615 |] 0.182 8 XKB4 -186OS T 73.819 |] XKO23 +186OS T 73.319 |] XKB2 +186OS T 73.615 |] 0.182 8 XKB4 +186OS T 73.819 |] XKO23 186OS T -186OS T 7.8233-12.4984 2.99 7 XL (total) -186OS T 7.8233 0.0586 18 XLL -186OS T 8.841-8.9119 1.21 4 XLA -186OS T 9.3366 0.0308 10 XLC -186OS T 10.1749-11.0062 1.43 4 XLB -186OS T 11.7306-12.4984 0.262 8 XLG +186OS T 7.8233-12.4984 2.99 7 XL (total) +186OS T 7.8233 0.0586 18 XLL +186OS T 8.841-8.9119 1.21 4 XLA +186OS T 9.3366 0.0308 10 XLC +186OS T 10.1749-11.0062 1.43 4 XLB +186OS T 11.7306-12.4984 0.262 8 XLG 186OS T -186OS T 47.71-51.892 |] KLL AUGER -186OS T 57.759-62.955 |] 0.175 18 ^KLX AUGER -186OS T 67.77-73.78 |] KXY AUGER -186OS T 4.7-12.9 6.43 8 L AUGER +186OS T 47.71-51.892 |] KLL AUGER +186OS T 57.759-62.955 |] 0.175 18 KLX AUGER +186OS T 67.77-73.78 |] KXY AUGER +186OS T 4.7-12.9 6.43 8 L AUGER 186RE P 0.0 1- 3.7186 D 17 1069.5 9 186OS N 1.081E0 1.081E0 0.9247 1.081E0 186OS L 0 0+ 2E15 Y -186OS B 1069.5 9 70.9 3 7.7 1 +186OS B 1069.5 9 70.9 3 7.7 1 186OSS B EAV=359.6 7 186OS L 137.157 8 2+ 0.818 NS -186OS B 932.3 9 21.5 3 8 1 +186OS B 932.3 9 21.5 3 8 1 186OSS B EAV=306.7 7 -186OS G 137.157 8 9.42 6 E2 1.290 39 +186OS G 137.157 8 9.42 6E2 1.290 39 186OS2 G KC=0.433 13$LC=0.645 19$MC=0.1648 49 186OS L 434.09 3 4+ 23.9 PS -186OS G 296.93 3 5.3E-5 15E2 0.095 2 -186OS2 G KC=0.0609 12$LC=0.0260 6$MC=0.00645 19 +186OS G 296.930 300.00005315E2 0.095 2 +186OS2 G KC=0.0609 12$LC=0.0260 6$MC=0.00645 19 186OS L 767.48 3 2+ 2.38 PS -186OS B 302.0 9 0.0627 9 8.9 1 +186OS B 302.0 9 0.0627 9 8.9 1 186OSS B EAV=84.7 7 -186OS G 333.39 4 6.2E-5 15[E2] 0.0678 20 -186OS2 G KC=0.0454 14$LC=0.0170 5$MC=0.00418 13 -186OS G 630.32 3 0.0293 6 M1+E2 -14 3 0.0134 1 -186OS2 G KC=0.0105 6$LC=0.0023 2$MC=5.38E-4 16 -186OS G 767.478 300.0327 6 E2 0.0086526 -186OS2 G KC=0.00690 21$LC=1342E-6 40$MC=3.15E-4 9 +186OS G 333.390 400.00006215[E2] 0.0678 20 +186OS2 G KC=0.0454 14$LC=0.0170 5$MC=0.00418 13 +186OS G 630.320 300.0293 6M1+E2 -14 3 0.0134 1 +186OS2 G KC=0.0105 6$LC=0.0023 2$MC=5.38E-4 16 +186OS G 767.478 300.0327 6E2 0.0086526 +186OS2 G KC=0.00690 21$LC=1342E-6 40$MC=3.15E-4 9 186OS L 910.48 3 3+ -186OS B 159.0 9 27000E-99 10.9 1U +186OS B 159.0 9 0.000027 9 10.9 1U 186OSS B EAV=42.6 7 -186OS G 143.00 4 7.4E-7 25M1+E2 0.6 1.85 11 -186OS2 G KC=1.39 8$LC=0.35 2$MC=0.0842 25 -186OS G 476.39 4 1.5E-6 5 E2+M1 -22 10 0.0259 8 -186OS2 G KC=0.0193 6$LC=0.00512 15$MC=1235E-6 37 -186OS G 773.32 3 2.2E-5 7 E2+M1 60 20 0.0266 7 -186OS2 G KC=0.0189 6$LC=0.00291 9$MC= +186OS G 143.000 407.4E-7 25M1+E2 0.6 1.85 11 +186OS2 G KC=1.39 8$LC=0.35 2$MC=0.0842 25 +186OS G 476.390 401.5E-6 5E2+M1 -22 10 0.0259 8 +186OS2 G KC=0.0193 6$LC=0.00512 15$MC=1235E-6 37 +186OS G 773.320 300.000022 7E2+M1 60 20 0.0266 7 +186OS2 G KC=0.0189 6$LC=0.00291 9 diff --git a/HEN_HOUSE/spectra/lnhb/Re-188.txt b/HEN_HOUSE/spectra/lnhb/Re-188.txt index 5668cac3a..8fb758abd 100644 --- a/HEN_HOUSE/spectra/lnhb/Re-188.txt +++ b/HEN_HOUSE/spectra/lnhb/Re-188.txt @@ -1,25 +1,25 @@ 188OS 188RE B- DECAY (17.005 H) -188OS T Auger electrons and ^X ray energies and emission intensities: -188OS T {U Energy (keV)} {U Intensity } {U Line } +188OS T Auger electrons and X ray energies and emission intensities: +188OS T {U Energy (keV)} {U Intensity} {U Line} 188OS T -188OS T 61.4873 1.36 9 XKA2 -188OS T 63.0011 2.35 16 XKA1 +188OS T 61.4873 1.36 9 XKA2 +188OS T 63.0011 2.35 16 XKA1 188OS T -188OS T 71.078 |] XKB3 -188OS T 71.414 |] 0.79 5 XKB1 -188OS T 71.855 |] XKB5II +188OS T 71.078 |] XKB3 +188OS T 71.414 |] 0.79 5 XKB1 +188OS T 71.855 |] XKB5II 188OS T -188OS T 73.319 |] XKB2 -188OS T 73.615 |] 0.22 2 XKB4 -188OS T 73.819 |] XKO23 +188OS T 73.319 |] XKB2 +188OS T 73.615 |] 0.22 2 XKB4 +188OS T 73.819 |] XKO23 188OS T -188OS T 7.82-12.92 3.00 15 XL (total) +188OS T 7.82-12.92 3.00 15 XL (total) 188OS T 7.82 XLL 188OS T -12.92 XLG 188OS T -188OS T 47.71-51.89 |] KLL AUGER -188OS T 57.79-60.47 |] 0.210 14 ^KLX AUGER -188OS T 67.68-69.95 |] KXY AUGER +188OS T 47.71-51.89 |] KLL AUGER +188OS T 57.79-60.47 |] 0.210 14 KLX AUGER +188OS T 67.68-69.95 |] KXY AUGER 188RE P 0.0 1- 17.005 H 4 2120.4 4 188OS N 1.0 1.0 1 1.0 188OS G 979.25 170.00104 20 @@ -29,78 +29,78 @@ 188OS L 155.040 4 2+ 0.70 NS 2 188OS B 1965.3 4 25.6 20 8.4 1 188OSS B EAV=728.89 17 -188OS G 155.041 4 15.2 6 E2 0.820 25 -188OS2 G KC=0.323 10$LC=0.375 11$MC=0.122 4 +188OS G 155.041 4 15.2 6E2 0.820 25 +188OS2 G KC=0.323 10$LC=0.375 11$MC=0.122 4 188OS L 477.97 3 4+ 19.40 PS 9 188OS G 322.93 4 0.0162 15E2 0.0743 22 -188OS2 G KC=0.0492 15$LC=0.0190 6$MC=0.0061 2 +188OS2 G KC=0.0492 15$LC=0.0190 6$MC=0.0061 2 188OS L 633.024 132+ 6.6 PS 3 188OS B 1487.4 4 1.65 12 9.2 1 188OSS B EAV=527.77 17 -188OS G 155 0.0059 6 [E2] 0.820 25 -188OS2 G KC=0.323 10$LC=0.375 11$MC=0.122 4 -188OS G 477.992 251.02 9 E2+M1+ 0.0260 8 -188OS2 G KC=0.0193 6$LC=0.00508 15$MC=0.00126 5 -188OS G 632.981 211.28 10E2 0.0132 4 -188OS2 G KC=0.0103 3$LC=0.00223 7$MC=0.00067 2 +188OS G 155 0.0059 6[E2] 0.820 25 +188OS2 G KC=0.323 10$LC=0.375 11$MC=0.122 4 +188OS G 477.992 251.02 9E2+M1+ 0.0260 8 +188OS2 G KC=0.0193 6$LC=0.00508 15$MC=0.00126 5 +188OS G 632.981 211.28 10E2 0.0132 4 +188OS2 G KC=0.0103 3$LC=0.00223 7$MC=0.00067 2 188OS L 789.97 3 3+ 188OS G 312.001 240.043 12E2 0.0822 25 -188OS2 G KC=0.0536 16$LC=0.0216 6$MC=0.00070 21 -188OS G 634.98 7 0.148 12E2+M1 0.0136 4 -188OS2 G KC=0.0106 3$LC=0.00226 7$MC=0.00074 2 +188OS2 G KC=0.0536 16$LC=0.0216 6$MC=0.00070 21 +188OS G 634.98 7 0.148 12E2+M1 0.0136 4 +188OS2 G KC=0.0106 3$LC=0.00226 7$MC=0.00074 2 188OS L 1086.382 100+ 12 PS 9 -188OS B 1034.0 4 0.63 4 9 1 +188OS B 1034.0 4 0.63 4 9 1 188OSS B EAV=345.33 16 -188OS G 453.34 2 0.073 8 (E2) 0.0294 4 -188OS2 G KC=0.0216 6$LC=0.00597 18$MC=0.00183 5 -188OS G 931.345 100.55 4 E2 0.0057918 -188OS2 G KC=0.00470 14$LC=0.00084 3$MC=0.00025 1 +188OS G 453.34 2 0.073 8(E2) 0.0294 4 +188OS2 G KC=0.0216 6$LC=0.00597 18$MC=0.00183 5 +188OS G 931.345 100.55 4E2 0.0057918 +188OS2 G KC=0.00470 14$LC=0.00084 3$MC=0.00025 1 188OS L 1304.85 7 (2)+ 188OS B 815.5 4 0.0241 17 10 1 188OSS B EAV=261.94 15 -188OS G 514.88 6 0.0054 5 E2(+M1) 0.0232 18 -188OS2 G KC=0.0177 16$LC=0.00421 23$MC=0.00129 6 -188OS G 1149.7 4 0.015 1 -188OS G 1304.86 200.0028 4 +188OS G 514.88 6 0.0054 5E2(+M1) 0.0232 18 +188OS2 G KC=0.0177 16$LC=0.00421 23$MC=0.00129 6 +188OS G 1149.7 4 0.015 1 +188OS G 1304.86 200.0028 4 188OS L 1413.8 3 (3)- -188OS B 706.6 5 0.0024 5 10.8 2 +188OS B 706.6 5 0.0024 5 10.8 2 188OSS B EAV=221.84 18 -188OS G 623.8 3 0.0024 5 +188OS G 623.8 3 0.0024 5 188OS L 1443.52 5 + 188OS B 676.88 5 0.00092 21 11.2 188OSS B EAV=211.11 14 188OS G 810.49 4 0.00092 22 188OS L 1457.55 122+ -188OS B 662.8 5 0.042 3 9.5 1 +188OS B 662.8 5 0.042 3 9.5 1 188OSS B EAV=206.07 15 -188OS G 825.2 7 0.0176 15M1(+E2) 0.016 5 -188OS2 G KC=0.013 5$LC=0.0021 7$MC=0.0009 2 -188OS G 1302.4 3 0.0057 8 +188OS G 825.2 7 0.0176 15M1(+E2) 0.016 5 +188OS2 G KC=0.013 5$LC=0.0021 7$MC=0.0009 2 +188OS G 1302.4 3 0.0057 8 188OS G 1457.54 130.0186 15 188OS L 1462.50 3 2- -188OS B 657.9 4 0.44 3 8.5 +188OS B 657.9 4 0.44 3 8.5 188OSS B EAV=204.30 14 -188OS G 672.535 160.112 9 E1 0.0042 1 -188OS2 G KC=0.0035 11$LC=0.00053 2$MC=1.55E-4 5 -188OS G 829.47 4 0.41 3 E1(+M2) 0.0030 9 -188OS2 G KC=0.0025 7$LC=0.00038 11$MC=0.00011 3 +188OS G 672.535 160.112 9E1 0.0042 1 +188OS2 G KC=0.0035 11$LC=0.00053 2$MC=1.55E-4 5 +188OS G 829.47 4 0.41 3E1(+M2) 0.0030 9 +188OS2 G KC=0.0025 7$LC=0.00038 11$MC=0.00011 3 188OS G 984.1 5 0.00034 21 -188OS G 1463.0 6 0.0008 3 +188OS G 1463.0 6 0.0008 3 188OS L 1478.09 5 0+ -188OS B 642.3 4 0.018 3 9.8 1 +188OS B 642.3 4 0.018 3 9.8 1 188OSS B EAV=198.73 14 -188OS G 845.07 4 0.0065 5 -188OS G 1322.91 200.011 3 +188OS G 845.07 4 0.0065 5 +188OS G 1322.91 200.011 3 188OS L 1685.5 3 + 188OS B 434.9 5 0.00055 17 10.8 188OSS B EAV=127.46 17 188OS G 1530.5 3 0.00055 17 188OS L 1704.32 100+ -188OS B 416.1 5 0.0023 9 10.1 1 +188OS B 416.1 5 0.0023 9 10.1 1 188OSS B EAV=121.28 13 188OS G 1704 188OS G 1071.4 3 0.00067 13 -188OS G 1549.26 100.0016 9 +188OS G 1549.26 100.0016 9 188OS L 1729.68 22(2,3)+ 188OS B 390.7 5 0.00128 21 10.3 1 188OSS B EAV=113.02 15 @@ -110,68 +110,60 @@ 188OS B 355.0 4 0.181 13 8 1 188OSS B EAV=101.57 13 188OS G 1765.1 -188OS G 1132.31 2 0.083 7 (E2) 0.0038712 -188OS2 G KC=0.00322 10$LC=0.00050 3$MC=0.00015 5 -188OS G 1610.40 5 0.098 8 [E2] 1070E-70 -188OS2 G KC=$LC=$MC= +188OS G 1132.31 2 0.083 7(E2) 0.0038712 +188OS2 G KC=0.00322 10$LC=0.00050 3$MC=0.00015 5 +188OS G 1610.40 5 0.098 8[E2] 1.07E-4 188OS L 1807.60 3 (2)+ -188OS B 312.8 4 0.038 3 8.5 1 +188OS B 312.8 4 0.038 3 8.5 1 188OSS B EAV=88.27 12 188OS G 1017.7 1 0.0147 11 188OS G 1174.57 3 0.0180 15 -188OS G 1652.49 140.0035 4 -188OS G 1807.6 3 0.00086 9 +188OS G 1652.49 140.0035 4 +188OS G 1807.6 3 0.00086 9 188OS L 1824.94 6 0+ 188OS B 295.5 4 0.0236 17 8.6 1 188OSS B EAV=82.90 12 188OS G 1825 188OS G 1191.84 120.0134 11 -188OS G 1669.97 7 0.0104 8 [E2] 1320E-70 -188OS2 G KC=$LC=$MC= +188OS G 1669.97 7 0.0104 8[E2] 1.32E-4 188OS L 1842.86 6 (1,2)+ 188OS B 277.5 4 0.00299 22 9.4 188OSS B EAV=77.41 12 188OS G 1209.790 240.00300 24M1+E2 0.0072921 -188OS2 G KC=0.00620 19$LC=8.20E-4 25$MC= +188OS2 G KC=0.00620 19$LC=8.20E-4 25 188OS L 1936.9 3 + -188OS B 183.5 4 21400E-825 10 +188OS B 183.5 4 0.00021425 10 188OSS B EAV=49.46 14 -188OS G 1936.9 3 0.00021 3 +188OS G 1936.9 3 0.00021 3 188OS L 1941.03 6 (1,2)+ -188OS B 179.4 4 0.102 7 7.3 +188OS B 179.4 4 0.102 7 7.3 188OSS B EAV=48.27 12 -188OS G 1150.5 4 0.015 1 -188OS G 1308.03 6 0.065 5 -188OS G 1785.95 120.0195 15[E2] 1800E-70 -188OS2 G KC=$LC=$MC= -188OS G 1940.91 230.00185 15(M1E2) 2480E-70 -188OS2 G KC=$LC=$MC= +188OS G 1150.5 4 0.015 1 +188OS G 1308.03 6 0.065 5 +188OS G 1785.95 120.0195 15[E2] 0.00018 +188OS G 1940.91 230.00185 15(M1E2) 2.48E-4 188OS L 1948.59 3 + -188OS B 171.8 4 0.079 6 7.3 +188OS B 171.8 4 0.079 6 7.3 188OSS B EAV=46.10 11 -188OS G 486.087 110.079 6 +188OS G 486.087 110.079 6 188OS L 1957.08 4 (1,2)+ -188OS B 163.3 4 0.051 4 7.4 +188OS B 163.3 4 0.051 4 7.4 188OSS B EAV=43.68 11 -188OS G 1802.04 4 0.036 3 [E2] 1850E-70 -188OS2 G KC=$LC=$MC= -188OS G 1956.96 170.0150 12(M1E2) 2550E-70 -188OS2 G KC=$LC=$MC= +188OS G 1802.04 4 0.036 3[E2] 1.85E-4 +188OS G 1956.96 170.0150 12(M1E2) 2.55E-4 188OS L 1964.96 7 2+ -188OS B 155.4 4 0.0021 3 8.8 1 +188OS B 155.4 4 0.0021 3 8.8 1 188OSS B EAV=41.44 11 188OS G 1331.95 7 0.00174 24 188OS G 1809.54 300.00040 11 188OS L 2020.18 10 + -188OS B 100.2 5 0.0059 4 7.7 +188OS B 100.2 5 0.0059 4 7.7 188OSS B EAV=26.12 11 -188OS G 557.71 100.00095 9 -188OS G 1864.91 250.0050 4 (E2M1) 2130E-70 -188OS2 G KC=$LC=$MC= +188OS G 557.71 100.00095 9 +188OS G 1864.91 250.0050 4(E2M1) 2.13E-4 188OS L 2022.44 13(1,2)+ 188OS B 98.0 5 0.00198 16 8.2 188OSS B EAV=25.51 11 -188OS G 1867.20 220.00046 9 -188OS G 2022.53 160.00152 12(M1E2) 2850E-70 -188OS2 G KC=$LC=$MC= +188OS G 1867.20 220.00046 9 +188OS G 2022.53 160.00152 12(M1E2) 2.85E-4 diff --git a/HEN_HOUSE/spectra/lnhb/Rh-106.txt b/HEN_HOUSE/spectra/lnhb/Rh-106.txt index 3382327f4..9cfee7c31 100644 --- a/HEN_HOUSE/spectra/lnhb/Rh-106.txt +++ b/HEN_HOUSE/spectra/lnhb/Rh-106.txt @@ -7,262 +7,262 @@ 106PD4C 1969KoZW, 1969Be74, 1971Az02, 1972Ma71, 1973Ma35, 1975De17, 1975Ge06, 106PD5C 1975Hs02, 1976Sh25, 1977Ok02, 1982Ka10, 1983Ku03, 1992Gr21, 1993Ch32, 106PD6C 1996Sc06, 2000He14, 2002Ba85, 2005Ki02, 2008Ki07, 2008De09, 2012Wa38 -106PD T Auger electrons and ^X ray energies and emission intensities: -106PD T {U Energy (keV)} {U Intensity } {U Line } +106PD T Auger electrons and X ray energies and emission intensities: +106PD T {U Energy (keV)} {U Intensity} {U Line} 106PD T -106PD T 21.0203 0.0310 5 XKA2 -106PD T 21.1774 0.0586 9 XKA1 +106PD T 21.0203 0.0310 5 XKA2 +106PD T 21.1774 0.0586 9 XKA1 106PD T -106PD T 23.7914 |] XKB3 -106PD T 23.819 |] 0.01608 29 XKB1 -106PD T 24.013 |] XKB5II +106PD T 23.7914 |] XKB3 +106PD T 23.819 |] 0.01608 29 XKB1 +106PD T 24.013 |] XKB5II 106PD T -106PD T 24.2994 |] XKB2 -106PD T 24.344 |] 0.00273 10 XKB4 +106PD T 24.2994 |] XKB2 +106PD T 24.344 |] 0.00273 10 XKB4 106PD T -106PD T 2.5045-3.5545 0.00785 14 XL (total) -106PD T 2.5045 0.000174 5 XLL -106PD T 2.8337-2.839 0.00468 11 XLA -106PD T 2.6611 0.0000608 17 XLC -106PD T 2.9904-3.1715 0.00270 8 XLB -106PD T 3.2464-3.5545 0.000242 6 XLG +106PD T 2.5045-3.5545 0.00785 14 XL (total) +106PD T 2.5045 0.000174 5 XLL +106PD T 2.8337-2.839 0.00468 11 XLA +106PD T 2.6611 6.08E-5 17 XLC +106PD T 2.9904-3.1715 0.00270 8 XLB +106PD T 3.2464-3.5545 0.000242 6 XLG 106PD T -106PD T 17.032-17.884 |] KLL AUGER -106PD T 20.032-21.176 |] 0.0238 7 ^KLX AUGER -106PD T 23.011-24.347 |] KXY AUGER -106PD T 1.83-3.6 0.1377 8 L AUGER +106PD T 17.032-17.884 |] KLL AUGER +106PD T 20.032-21.176 |] 0.0238 7 KLX AUGER +106PD T 23.011-24.347 |] KXY AUGER +106PD T 1.83-3.6 0.1377 8 L AUGER 106RH P 0.0 1+ 30.1 S 3 3546 5 106PD N 1.0 1.0 1 1.0 106PD L 0 0+ STABLE 106PD B 3546 5 78.80 24 5.18 106PDS B EAV=1511.1 24 106PD L 511.8547 232+ -106PD B 3034 5 8.2 3 5.87 +106PD B 3034 5 8.2 3 5.87 106PDS B EAV=1269.5 24 -106PD G 511.8534 2320.52 23E2 0.005598 -106PD2 G KC=0.00484 7$LC=6.12E-4 9$MC=1153E-7 17 +106PD G 511.8534 2320.52 23E2 0.00559 8 +106PD2 G KC=0.00484 7$LC=6.12E-4 9$MC=1153E-7 17 106PD L 1128.02 3 2+ 106PD B 2418 5 0.608 21 6.58 106PDS B EAV=981.6 24 -106PD G 616.16 3 0.731 17M1+E2 -9.4 20 0.003335 -106PD2 G KC=0.00289 4$LC=3.57E-4 5$MC=6.71E-5 10 -106PD G 1128.01 3 0.398 8 E2 7.73E-411 +106PD G 616.16 3 0.731 17M1+E2 -9.4 20 0.00333 5 +106PD2 G KC=0.00289 4$LC=3.57E-4 5$MC=6.71E-5 10 +106PD G 1128.01 3 0.398 8E2 7.73E-411 106PD2 G KC=6.75E-4 10$LC=7.90E-5 11$MC=1479E-8 21 106PD L 1133.76 4 0+ 106PD B 2412 5 9.82 15 5.37 106PDS B EAV=978.9 24 -106PD G 621.90 4 9.87 15E2 0.003245 -106PD2 G KC=0.00282 4$LC=3.48E-4 5$MC=6.54E-5 10 +106PD G 621.90 4 9.87 15E2 0.00324 5 +106PD2 G KC=0.00282 4$LC=3.48E-4 5$MC=6.54E-5 10 106PD G 1133.75 4 106PD L 1229.30 4 4+ -106PD B 2317 5 0.0051 5 11 2U +106PD B 2317 5 0.0051 5 11 2U 106PDS B EAV=951.8 23 -106PD G 717.44 4 0.0067 4 E2 0.002234 -106PD2 G KC=0.00194 3$LC=2.36E-4 4$MC=4.43E-5 7 +106PD G 717.44 4 0.0067 4E2 0.00223 4 +106PD2 G KC=0.00194 3$LC=2.36E-4 4$MC=4.43E-5 7 106PD L 1557.68 4 3+ 106PD G 1045.82 4 0.0131 16M1+E2 -3.8 4 9.18E-413 106PD2 G KC=8.03E-4 12$LC=9.42E-5 14$MC=1766E-8 25 106PD L 1562.25 3 2+ -106PD B 1984 5 1.67 3 5.79 +106PD B 1984 5 1.67 3 5.79 106PDS B EAV=781.9 23 106PD G 428.49 5 0.0704 24E2 0.0094714 -106PD2 G KC=0.00817 12$LC=1063E-6 15$MC=2.00E-4 3 -106PD G 434.23 4 0.020 4 E2 0.0090913 -106PD2 G KC=0.00785 11$LC=1019E-6 15$MC=1.92E-4 3 +106PD2 G KC=0.00817 12$LC=1063E-6 15$MC=2.00E-4 3 +106PD G 434.23 4 0.020 4E2 0.0090913 +106PD2 G KC=0.00785 11$LC=1019E-6 15$MC=1.92E-4 3 106PD G 1050.39 3 1.490 25M1+E2 0.24 1 1007E-615 -106PD2 G KC=8.83E-4 13$LC=1018E-7 15$MC=1.91E-5 3 -106PD G 1562.24 3 0.156 8 +106PD2 G KC=8.83E-4 13$LC=1018E-7 15$MC=1.91E-5 3 +106PD G 1562.24 3 0.156 8 106PD L 1706.44 5 0+ 106PD B 1840 5 0.0664 10 7.06 106PDS B EAV=716.4 23 -106PD G 578.42 6 0.0090 6 E2 0.003956 -106PD2 G KC=0.00343 5$LC=4.27E-4 6$MC=8.04E-5 12 -106PD G 1194.58 5 0.0573 8 E2 6.89E-410 -106PD2 G KC=5.97E-4 9$LC=6.96E-5 10$MC=1304E-8 19 +106PD G 578.42 6 0.0090 6E2 0.00395 6 +106PD2 G KC=0.00343 5$LC=4.27E-4 6$MC=8.04E-5 12 +106PD G 1194.58 5 0.0573 8E2 6.89E-410 +106PD2 G KC=5.97E-4 9$LC=6.96E-5 10$MC=1304E-8 19 106PD L 1909.37 16(1,2)+ 106PD B 1637 5 0.00277 21 8.24 106PDS B EAV=625.2 23 106PD G 1397.51 160.00277 21 106PD L 2001.48 5 0+ -106PD B 1545 5 0.448 9 5.93 +106PD B 1545 5 0.448 9 5.93 106PDS B EAV=584.3 23 106PD G 439.23 6 0.0111 16 -106PD G 873.46 6 0.435 8 E2 1375E-620 -106PD2 G KC=1201E-6 17$LC=1432E-7 20$MC=2.69E-5 4 -106PD G 1489.61 5 0.0018 3 +106PD G 873.46 6 0.435 8E2 1375E-620 +106PD2 G KC=1201E-6 17$LC=1432E-7 20$MC=2.69E-5 4 +106PD G 1489.61 5 0.0018 3 106PD L 2242.48 5 2+ -106PD B 1304 5 0.0372 8 6.72 +106PD B 1304 5 0.0372 8 6.72 106PDS B EAV=478.7 22 -106PD G 680.23 6 0.0103 6 E1+M2 0.4 0.002684 -106PD2 G KC=0.00234 4$LC=2.74E-4 4$MC=5.15E-5 8 +106PD G 680.23 6 0.0103 6E1+M2 0.4 0.00268 4 +106PD2 G KC=0.00234 4$LC=2.74E-4 4$MC=5.15E-5 8 106PD G 684.80 6 0.00552 21 -106PD G 1108.71 6 0.0056 3 -106PD G 1114.45 6 0.0117 3 M1+E2 1.5 8.23E-414 +106PD G 1108.71 6 0.0056 3 +106PD G 1114.45 6 0.0117 3M1+E2 1.5 8.23E-414 106PD2 G KC=7.20E-4 12$LC=8.38E-5 14$MC=1570E-8 25 106PD G 1730.44 200.00209 13 -106PD G 2242.45 5 0.00195 8 +106PD G 2242.45 5 0.00195 8 106PD L 2278.11 9 0+ -106PD B 1268 5 0.043 5 6.62 +106PD B 1268 5 0.043 5 6.62 106PDS B EAV=463.3 22 -106PD G 715.86 9 0.0099 4 +106PD G 715.86 9 0.0099 4 106PD G 1150.08 9 0.00287 17E2 7.42E-411 -106PD2 G KC=6.48E-4 9$LC=7.57E-5 11$MC=1417E-8 20 -106PD G 1766.24 9 0.030 5 E2 5.06E-47 -106PD2 G KC=2.74E-4 4$LC=3.14E-5 5$MC=5.86E-6 9 +106PD2 G KC=6.48E-4 9$LC=7.57E-5 11$MC=1417E-8 20 +106PD G 1766.24 9 0.030 5E2 5.06E-4 7 +106PD2 G KC=2.74E-4 4$LC=3.14E-5 5$MC=5.86E-6 9 106PD L 2308.82 5 2+ -106PD B 1237 5 0.0430 7 6.57 +106PD B 1237 5 0.0430 7 6.57 106PDS B EAV=450.1 22 106PD G 751.26 200.00121 23 -106PD G 1180.79 6 0.0144 3 M1+E2 -0.06 12 7.90E-412 +106PD G 1180.79 6 0.0144 3M1+E2 -0.06 12 7.90E-412 106PD2 G KC=6.89E-4 10$LC=7.92E-5 12$MC=1482E-8 22 -106PD G 1796.95 5 0.0274 5 M1+E2 0.25 2 5.16E-48 -106PD2 G KC=2.87E-4 4$LC=3.27E-5 5$MC=6.11E-6 9 +106PD G 1796.95 5 0.0274 5M1+E2 0.25 2 5.16E-4 8 +106PD2 G KC=2.87E-4 4$LC=3.27E-5 5$MC=6.11E-6 9 106PD L 2439.10 7 2+ -106PD B 1107 5 0.0208 5 6.71 +106PD B 1107 5 0.0208 5 6.71 106PDS B EAV=394.7 21 -106PD G 1209.79 8 0.00039 8 +106PD G 1209.79 8 0.00039 8 106PD G 1305.33 8 0.00109 12 -106PD G 1927.23 7 0.0147 4 M1+E2 -0.07 5.32E-48 -106PD2 G KC=2.50E-4 4$LC=2.85E-5 4$MC=5.33E-6 8 +106PD G 1927.23 7 0.0147 4M1+E2 -0.07 5.32E-4 8 +106PD2 G KC=2.50E-4 4$LC=2.85E-5 4$MC=5.33E-6 8 106PD G 2439.07 7 0.00464 13E2 6.89E-410 -106PD2 G KC=1525E-7 22$LC=1727E-8 25$MC=3.23E-6 5 +106PD2 G KC=1525E-7 22$LC=1727E-8 25$MC=3.23E-6 5 106PD L 2484.66 20(1)- 106PD B 1061 5 0.00093 15 7.99 106PDS B EAV=375.6 21 -106PD G 1973.4 8 0.00017 4 +106PD G 1973.4 8 0.00017 4 106PD G 2484.63 200.00076 14 106PD L 2500.31 8 2- -106PD B 1046 5 0.0284 6 6.48 1 +106PD B 1046 5 0.0284 6 6.48 1 106PDS B EAV=369.0 21 106PD G 942.63 9 0.00060 18 106PD G 1372.28 9 0.00199 15 -106PD G 1988.44 8 0.0258 5 E1+M2 0.05 7.35E-411 -106PD2 G KC=1173E-7 22$LC=1318E-8 25$MC=2.46E-6 5 +106PD G 1988.44 8 0.0258 5E1+M2 0.05 7.35E-411 +106PD2 G KC=1173E-7 22$LC=1318E-8 25$MC=2.46E-6 5 106PD L 2624.40 5 0+ -106PD B 922 5 0.090 3 5.78 +106PD B 922 5 0.090 3 5.78 106PDS B EAV=317.8 21 106PD G 1062.14 6 0.0304 19 106PD G 1496.37 6 0.0240 17 -106PD G 2112.52 5 0.0351 7 E2 5.81E-49 -106PD2 G KC=1.97E-4 3$LC=2.24E-5 4$MC=4.19E-6 6 +106PD G 2112.52 5 0.0351 7E2 5.81E-4 9 +106PD2 G KC=1.97E-4 3$LC=2.24E-5 4$MC=4.19E-6 6 106PD L 2705.30 8 (1)+ -106PD B 841 5 0.0106 4 6.56 +106PD B 841 5 0.0106 4 6.56 106PDS B EAV=285.1 20 106PD G 702.8 100.00029 18 106PD G 1572.47 200.00185 19 106PD G 1577.27 9 0.00105 16 -106PD G 2193.17 100.00495 21M1+E2 -0.17 6 5.94E-49 -106PD2 G KC=1.94E-4 3$LC=2.20E-5 3$MC=4.12E-6 6 +106PD G 2193.17 100.00495 21M1+E2 -0.17 6 5.94E-4 9 +106PD2 G KC=1.94E-4 3$LC=2.20E-5 3$MC=4.12E-6 6 106PD G 2705.26 8 0.00248 13 106PD L 2717.59 21 + 106PD B 828 5 0.00023 12 106PDS B EAV= 106PD G 1159.90 210.00023 12 106PD L 2783.74 212+ -106PD B 762 5 0.00117 8 7.36 +106PD B 762 5 0.00117 8 7.36 106PDS B EAV=254 2 -106PD G 2271.86 210.00117 8 +106PD G 2271.86 210.00117 8 106PD L 2820.97 9 2+ -106PD B 725 5 0.0090 3 6.4 +106PD B 725 5 0.0090 3 6.4 106PDS B EAV=239.4 20 -106PD G 1258.71 9 0.00066 8 -106PD G 1687.2 1 0.00055 16 +106PD G 1258.71 9 0.00066 8 +106PD G 1687.20 100.00055 16 106PD G 1693.2 3 0.00082 14 106PD G 2309.09 9 0.00575 16 -106PD G 2821.2 3 0.00120 4 +106PD G 2821.2 3 0.00120 4 106PD L 2828.29 9 0+ 106PD B 718 5 0.00731 19 6.47 106PDS B EAV=236.6 20 106PD G 1266.03 9 0.00109 10 -106PD G 2316.41 9 0.00622 16E2 6.46E-49 -106PD2 G KC=1670E-7 24$LC=1.89E-5 3$MC=3.54E-6 5 +106PD G 2316.41 9 0.00622 16E2 6.46E-4 9 +106PD2 G KC=1670E-7 24$LC=1.89E-5 3$MC=3.54E-6 5 106PD L 2877.92 7 0+ -106PD B 668 5 0.0262 9 5.81 +106PD B 668 5 0.0262 9 5.81 106PDS B EAV=217.5 20 -106PD G 1315.66 8 0.0030 5 E2 5.86E-49 -106PD2 G KC=4.89E-4 7$LC=5.67E-5 8$MC=1061E-8 15 -106PD G 2366.04 7 0.0232 7 E2 6.63E-410 -106PD2 G KC=1608E-7 23$LC=1.82E-5 3$MC=3.41E-6 5 +106PD G 1315.66 8 0.0030 5E2 5.86E-4 9 +106PD2 G KC=4.89E-4 7$LC=5.67E-5 8$MC=1061E-8 15 +106PD G 2366.04 7 0.0232 7E2 6.63E-410 +106PD2 G KC=1608E-7 23$LC=1.82E-5 3$MC=3.41E-6 5 106PD L 2902.48 102+ 106PD B 644 5 0.00760 18 6.29 106PDS B EAV=208.1 19 -106PD G 1774.44 100.00094 8 -106PD G 2390.6 1 0.00659 16M1+E2 -0.1 6.54E-410 -106PD2 G KC=1645E-7 24$LC=1.86E-5 3$MC=3.49E-6 5 -106PD G 2902.6 5 6.6E-5 21 +106PD G 1774.44 100.00094 8 +106PD G 2390.60 100.00659 16M1+E2 -0.1 6.54E-410 +106PD2 G KC=1645E-7 24$LC=1.86E-5 3$MC=3.49E-6 5 +106PD G 2902.6 5 0.00006621 106PD L 2917.86 8 2+ -106PD B 628 5 0.0183 7 5.87 +106PD B 628 5 0.0183 7 5.87 106PDS B EAV=202.3 19 106PD G 1355.60 9 0.00060 25 -106PD G 1360.17 9 0.0018 4 +106PD G 1360.17 9 0.0018 4 106PD G 1784.08 9 0.00043 12 -106PD G 2405.98 8 0.0145 4 M1+E2 -0.05 6.59E-410 -106PD2 G KC=1626E-7 23$LC=1.84E-5 3$MC=3.44E-6 5 -106PD G 2917.6 3 0.00094 4 +106PD G 2405.98 8 0.0145 4M1+E2 -0.05 6.59E-410 +106PD2 G KC=1626E-7 23$LC=1.84E-5 3$MC=3.44E-6 5 +106PD G 2917.6 3 0.00094 4 106PD L 2968.68 213- -106PD B 577 5 0.00022 4 7.82 1U +106PD B 577 5 0.00022 4 7.82 1U 106PDS B EAV=202.8 19 -106PD G 2456.79 210.00022 4 +106PD G 2456.79 210.00022 4 106PD L 3037.32 171,2+ -106PD B 509 5 0.0022 3 +106PD B 509 5 0.0022 3 106PDS B EAV= 106PD G 1909.28 170.00107 25 -106PD G 2525.43 170.00011 3 -106PD G 3037.3 3 0.00105 4 +106PD G 2525.43 170.00011 3 +106PD G 3037.3 3 0.00105 4 106PD L 3054.97 9 1+ -106PD B 491 5 0.0101 5 5.76 +106PD B 491 5 0.0101 5 5.76 106PDS B EAV=151.8 18 -106PD G 1498.73 160.0068 4 -106PD G 2542.79 100.00289 9 M1+E2 0.07 7 7.05E-410 -106PD2 G KC=1464E-7 21$LC=1657E-8 24$MC=3.10E-6 5 -106PD G 3055.0 3 0.00036 4 +106PD G 1498.73 160.0068 4 +106PD G 2542.79 100.00289 9M1+E2 0.07 7 7.05E-410 +106PD2 G KC=1464E-7 21$LC=1657E-8 24$MC=3.10E-6 5 +106PD G 3055.0 3 0.00036 4 106PD L 3083.91 180+ 106PD B 462 5 0.00278 13 106PDS B EAV= 106PD G 1854.89 200.00125 10 -106PD G 1954.9 4 0.00020 4 -106PD G 2571.16 200.00133 6 +106PD G 1954.9 4 0.00020 4 +106PD G 2571.16 200.00133 6 106PD L 3163.7 3 (1,2)+ -106PD B 382 5 0.00070 5 6.55 +106PD B 382 5 0.00070 5 6.55 106PDS B EAV=113.8 17 -106PD G 2651.39 200.00068 4 -106PD G 3164.6 102.3E-5 12 +106PD G 2651.39 200.00068 4 +106PD G 3164.6 100.00002312 106PD L 3221.37 250+ 106PD B 325 5 0.00402 13 5.56 106PDS B EAV=94.5 17 -106PD G 2093.33 250.00029 6 E2 5.76E-48 -106PD2 G KC=2.00E-4 3$LC=2.28E-5 4$MC=4.26E-6 6 +106PD G 2093.33 250.00029 6E2 5.76E-4 8 +106PD2 G KC=2.00E-4 3$LC=2.28E-5 4$MC=4.26E-6 6 106PD G 2709.48 250.00373 11E2 7.85E-411 -106PD2 G KC=1271E-7 18$LC=1436E-8 21$MC=2.68E-6 4 +106PD2 G KC=1271E-7 18$LC=1436E-8 21$MC=2.68E-6 4 106PD L 3249.9 5 2+ -106PD B 296 5 86000E-916 7.09 +106PD B 296 5 0.00008616 7.09 106PDS B EAV=85.2 17 -106PD G 3249.8 5 8.6E-5 16 +106PD G 3249.8 5 0.00008616 106PD L 3252.0 4 2+ -106PD B 294 5 0.00021 4 6.7 +106PD B 294 5 0.00021 4 6.7 106PDS B EAV=84.5 17 -106PD G 2740.1 4 0.00021 4 +106PD G 2740.1 4 0.00021 4 106PD L 3273.5 7 1,2+ -106PD B 272 5 49000E-914 +106PD B 272 5 0.00004914 106PDS B EAV= -106PD G 3273.4 7 4.9E-5 14 +106PD G 3273.4 7 0.00004914 106PD L 3299.2 7 + -106PD B 247 5 82000E-921 +106PD B 247 5 0.00008221 106PDS B EAV= -106PD G 2788.2 5 8.2E-5 21 +106PD G 2788.2 5 0.00008221 106PD L 3320.5 3 0+ -106PD B 226 5 0.00087 8 5.71 +106PD B 226 5 0.00087 8 5.71 106PDS B EAV=62.9 16 -106PD G 2185.7 5 0.00025 6 -106PD G 2809.1 3 0.00062 4 E2 8.22E-412 -106PD2 G KC=1195E-7 17$LC=1349E-8 19$MC=2.52E-6 4 +106PD G 2185.7 5 0.00025 6 +106PD G 2809.1 3 0.00062 4E2 8.22E-412 +106PD2 G KC=1195E-7 17$LC=1349E-8 19$MC=2.52E-6 4 106PD L 3376.6 9 + -106PD B 169 5 25000E-99 +106PD B 169 5 0.000025 9 106PDS B EAV= -106PD G 2865 1 1.4E-5 8 +106PD G 2865 1 0.000014 8 106PD G 3375.9 141.13E-5 21 106PD L 3401.9 6 + -106PD B 144 5 12500E-919 +106PD B 144 5 1.25E-5 19 106PDS B EAV= 106PD G 3401.8 9 1.25E-5 19 diff --git a/HEN_HOUSE/spectra/lnhb/Rn-217.txt b/HEN_HOUSE/spectra/lnhb/Rn-217.txt index 593948827..1c4cc9c85 100644 --- a/HEN_HOUSE/spectra/lnhb/Rn-217.txt +++ b/HEN_HOUSE/spectra/lnhb/Rn-217.txt @@ -1,8 +1,8 @@ 213PO 217RN A DECAY (0.54 MS) 213PO H TYP=Full$AUT=Huang Xiaolong$CUT=31-DEC-2007$ 213PO C Evaluation history: Type=Full;Author=Huang Xiaolong;Cutoff date=31-DEC-2007 -213PO T Auger electrons and ^X ray energies and emission intensities: -213PO T {U Energy (keV)} {U Intensity } {U Line } +213PO T Auger electrons and X ray energies and emission intensities: +213PO T {U Energy (keV)} {U Intensity} {U Line} 213PO T 213PO T 213PO T diff --git a/HEN_HOUSE/spectra/lnhb/Rn-218.txt b/HEN_HOUSE/spectra/lnhb/Rn-218.txt index cdd0db619..1b50b18c6 100644 --- a/HEN_HOUSE/spectra/lnhb/Rn-218.txt +++ b/HEN_HOUSE/spectra/lnhb/Rn-218.txt @@ -4,32 +4,32 @@ 214PO C References: 1956As38, 1958To25, 1961Ru06, 1963Di05, 1969Pe17, 1971Er02, 214PO2C 1976Ku08, 1979Ry03, 1982Bo04, 1987El12, 1991Ry01, 1995El07, 1996Sc06, 214PO3C 1998Ak04, 2002Ba85, 2003Au03 -214PO T Auger electrons and ^X ray energies and emission intensities: -214PO T {U Energy (keV)} {U Intensity } {U Line } +214PO T Auger electrons and X ray energies and emission intensities: +214PO T {U Energy (keV)} {U Intensity} {U Line} 214PO T -214PO T 76.864 0.00052 4 XKA2 -214PO T 79.293 0.00086 6 XKA1 +214PO T 76.864 0.00052 4 XKA2 +214PO T 79.293 0.00086 6 XKA1 214PO T -214PO T 89.256 |] XKB3 -214PO T 89.807 |] 0.000296 21 XKB1 -214PO T 90.363 |] XKB5II +214PO T 89.256 |] XKB3 +214PO T 89.807 |] 0.00029621 XKB1 +214PO T 90.363 |] XKB5II 214PO T -214PO T 92.263 |] XKB2 -214PO T 92.618 |] 0.000092 7 XKB4 -214PO T 92.983 |] XKO23 +214PO T 92.263 |] XKB2 +214PO T 92.618 |] 0.000092 7 XKB4 +214PO T 92.983 |] XKO23 214PO T -214PO T 9.66-16.21 0.00080 3 XL (total) -214PO T 9.66 0.0000190 11 XLL -214PO T 11.0161-11.1303 0.000349 18 XLA -214PO T 12.0847 0.0000067 4 XLC -214PO T 12.8239-13.6358 0.000356 15 XLB -214PO T 15.251-16.21 0.000072 3 XLG +214PO T 9.66-16.21 0.00080 3 XL (total) +214PO T 9.66 1.90E-5 11 XLL +214PO T 11.0161-11.1303 0.00034918 XLA +214PO T 12.0847 6.7E-6 4 XLC +214PO T 12.8239-13.6358 0.00035615 XLB +214PO T 15.251-16.21 0.000072 3 XLG 218RN P 0.0 0+ 36.0 MS 19 7262.5 19 214PO N 1.0 1.0 1 1.0 214PO L 0 0+ 162.3 US 12 214PO A 7129.2 1999.873 7 1 214PO L 609.31 6 2+ 214PO A 6531.1 190.127 7 4.8 -214PO G 609.31 6 0.124 7 E2 0.0204 3 -214PO2 G KC=0.01487 21$LC=0.00416 6$MC=1030E-6 15 +214PO G 609.31 6 0.124 7E2 0.0204 3 +214PO2 G KC=0.01487 21$LC=0.00416 6$MC=1030E-6 15 diff --git a/HEN_HOUSE/spectra/lnhb/Rn-219.txt b/HEN_HOUSE/spectra/lnhb/Rn-219.txt index bfd52d146..dab5ec463 100644 --- a/HEN_HOUSE/spectra/lnhb/Rn-219.txt +++ b/HEN_HOUSE/spectra/lnhb/Rn-219.txt @@ -5,98 +5,98 @@ 215PO2C 1970Da09, 1970Kr08, 1971Gr07, 1976Bl13, 1977La19, 1991Ry01, 1996Sc06, 215PO3C 1998Ak04, 1998ScZM, 1999Li05, 1999ScZX, 2001Br31, 2002Ba85, 2002Ra45, 215PO4C 2003Au03, 2008Ki07 -215PO T Auger electrons and ^X ray energies and emission intensities: -215PO T {U Energy (keV)} {U Intensity } {U Line } +215PO T Auger electrons and X ray energies and emission intensities: +215PO T {U Energy (keV)} {U Intensity} {U Line} 215PO T -215PO T 76.864 0.540 24 XKA2 -215PO T 79.293 0.90 4 XKA1 +215PO T 76.864 0.540 24 XKA2 +215PO T 79.293 0.90 4 XKA1 215PO T -215PO T 89.256 |] XKB3 -215PO T 89.807 |] 0.309 15 XKB1 -215PO T 90.363 |] XKB5II +215PO T 89.256 |] XKB3 +215PO T 89.807 |] 0.309 15 XKB1 +215PO T 90.363 |] XKB5II 215PO T -215PO T 92.263 |] XKB2 -215PO T 92.618 |] 0.096 5 XKB4 -215PO T 92.983 |] XKO23 +215PO T 92.263 |] XKB2 +215PO T 92.618 |] 0.096 5 XKB4 +215PO T 92.983 |] XKO23 215PO T -215PO T 9.658-16.213 1.01 5 XL (total) -215PO T 9.658 0.0229 9 XLL -215PO T 11.016-11.13 0.420 15 XLA -215PO T 12.085 0.0095 4 XLC -215PO T 12.823-13.778 0.475 13 XLB -215PO T 15.742-16.213 0.098 3 XLG +215PO T 9.658-16.213 1.01 5 XL (total) +215PO T 9.658 0.0229 9 XLL +215PO T 11.016-11.13 0.420 15 XLA +215PO T 12.085 0.0095 4 XLC +215PO T 12.823-13.778 0.475 13 XLB +215PO T 15.742-16.213 0.098 3 XLG 215PO T -215PO T 58.978-65.205 |] KLL AUGER -215PO T 71.902-79.289 |] 0.067 9 ^KLX AUGER -215PO T 84.8-93.1 |] KXY AUGER -215PO T 5.434-10.934 1.50 5 L AUGER +215PO T 58.978-65.205 |] KLL AUGER +215PO T 71.902-79.289 |] 0.067 9 KLX AUGER +215PO T 84.8-93.1 |] KXY AUGER +215PO T 5.434-10.934 1.50 5 L AUGER 219RN P 0.0 5/2+ 3.98 S 3 6946.1 3 215PO N 1.0 1.0 1 1.0 -215PO G 665.5 100.00009 5 +215PO G 665.5 100.00009 5 215PO L 0 9/2+ 1.781 MS 4 215PO A 6819.2 3 79.4 1011.2 215PO L 271.228 107/2+ 215PO A 6553.0 3 12.6 3 6.75 -215PO G 271.228 1011.07 22M1+E2 4.0 4 0.201 7 -215PO2 G KC=0.111 6$LC=0.0668 11$MC=0.0173 3 +215PO G 271.228 1011.07 22M1+E2 4.0 4 0.201 7 +215PO2 G KC=0.111 6$LC=0.0668 11$MC=0.0173 3 215PO L 293.56 4 (11/2)+ 215PO A 6531.0 3 0.098 5 710 -215PO G 293.56 4 0.075 3 M1+E2 1.0 2 0.34 5 -215PO2 G KC=0.25 4$LC=0.062 4$MC=0.0152 7 +215PO G 293.56 4 0.075 3M1+E2 1.0 2 0.34 5 +215PO2 G KC=0.25 4$LC=0.062 4$MC=0.0152 7 215PO L 401.812 105/2+ 215PO A 6424.8 3 7.85 243.31 215PO G 130.58 1 0.133 11M1+E2 0.60 6 4.44 13 -215PO2 G KC=3.19 16$LC=0.94 4$MC=0.234 10 -215PO G 401.81 1 6.75 22E2 0.0555 8 -215PO2 G KC=0.0351 5$LC=0.01528 22$MC=0.00390 6 +215PO2 G KC=3.19 16$LC=0.94 4$MC=0.234 10 +215PO G 401.81 1 6.75 22E2 0.0555 8 +215PO2 G KC=0.0351 5$LC=0.01528 22$MC=0.00390 6 215PO L 517.60 6 7/2,9/2+ 215PO A 6311.1 3 0.048 3 184 -215PO G 224.04 7 0.0014 2 (E2) 0.319 5 -215PO2 G KC=0.1296 19$LC=0.1407 20$MC=0.0370 6 -215PO G 517.60 6 0.043 3 M1+E2 1.0 2 0.073 10 -215PO2 G KC=0.058 9$LC=0.0115 11$MC=0.00277 24 +215PO G 224.04 7 0.0014 2(E2) 0.319 5 +215PO2 G KC=0.1296 19$LC=0.1407 20$MC=0.0370 6 +215PO G 517.60 6 0.043 3M1+E2 1.0 2 0.073 10 +215PO2 G KC=0.058 9$LC=0.0115 11$MC=0.00277 24 215PO L 608.30 7 (11/2,13/2)+ 215PO A 6222.0 3 0.0043 10860 215PO G 608.30 7 0.0044 10(M1+E2) 215PO L 676.66 7 + 215PO A 6154.9 3 0.0184 22103 -215PO G 383.1 1 0.00044 7 -215PO G 405.4 1 0.00025 4 -215PO G 676.66 7 0.018 2 +215PO G 383.1 1 0.00044 7 +215PO G 405.4 1 0.00025 4 +215PO G 676.66 7 0.018 2 215PO L 708.1 5 + 215PO A 6124.1 6 0.00064 122170 -215PO G 436.9 5 0.00031 6 +215PO G 436.9 5 0.00031 6 215PO G 708.1 5 0.00033 11 215PO L 732.7 4 + 215PO A 6099.9 5 0.00123 12880 215PO G 330.9 4 0.00100 11 -215PO G 461.5 4 0.00017 3 -215PO G 732.7 4 0.00007 4 +215PO G 461.5 4 0.00017 3 +215PO G 732.7 4 0.00007 4 215PO L 835.32 22 + 215PO A 5999.2 4 0.0032 5 120 -215PO G 564.1 2 0.0015 3 -215PO G 835.32 220.0017 3 +215PO G 564.1 2 0.0015 3 +215PO G 835.32 220.0017 3 215PO L 877.2 6 + 215PO A 5958.1 7 0.0003 1 830 215PO G 877.2 6 0.00033 11 215PO L 891.1 3 + 215PO A 5944.4 4 0.0021 3 103 -215PO G 373.5 3 0.00025 3 -215PO G 489.3 3 0.00064 9 +215PO G 373.5 3 0.00025 3 +215PO G 489.3 3 0.00064 9 215PO G 619.9 3 0.00033 11 -215PO G 891.1 3 0.0009 2 +215PO G 891.1 3 0.0009 2 215PO L 930 1 + 215PO A 5906.2 100.00009 5 1590 -215PO G 322 1 0.00009 5 +215PO G 322 1 0.00009 5 215PO L 1073.7 4 (5/2)+ 215PO A 5765.1 5 0.00094 1933 -215PO G 556.1 4 0.00006 4 M1+E2 1.0 2 0.061 8 -215PO2 G KC=0.048 7$LC=0.0095 9$MC=0.00226 21 +215PO G 556.1 4 0.00006 4M1+E2 1.0 2 0.061 8 +215PO2 G KC=0.048 7$LC=0.0095 9$MC=0.00226 21 215PO G 671.9 4 0.00022 11M1+E2 215PO G 802.5 4 0.00033 11M1+E2 -215PO G 1073.7 4 0.00033 11E2 0.006419 -215PO2 G KC=0.00510 8$LC=1002E-6 14$MC=2.40E-4 4 +215PO G 1073.7 4 0.00033 11E2 0.00641 9 +215PO2 G KC=0.00510 8$LC=1002E-6 14$MC=2.40E-4 4 215PO L 1094.2 10 + 215PO A 5745 1 0.00009 5 245 -215PO G 576.6 100.00009 5 +215PO G 576.6 100.00009 5 diff --git a/HEN_HOUSE/spectra/lnhb/Rn-220.txt b/HEN_HOUSE/spectra/lnhb/Rn-220.txt index f0368ec27..0dc9b12cf 100644 --- a/HEN_HOUSE/spectra/lnhb/Rn-220.txt +++ b/HEN_HOUSE/spectra/lnhb/Rn-220.txt @@ -7,37 +7,37 @@ 216PO2C 1972DaZA, 1973Da38, 1977La19, 1977Ku15, 1984Ge07, 1996Sc06, 1997Ar04, 216PO3C 1998ScZM, 1999ScZX, 2002Ba85, 2002Ra45, 2003Au03, 2007St23, 2007Wu02, 216PO4C 2008Ki07 -216PO T Auger electrons and ^X ray energies and emission intensities: -216PO T {U Energy (keV)} {U Intensity } {U Line } +216PO T Auger electrons and X ray energies and emission intensities: +216PO T {U Energy (keV)} {U Intensity} {U Line} 216PO T -216PO T 76.864 0.00059 8 XKA2 -216PO T 79.293 0.00099 13 XKA1 +216PO T 76.864 0.00059 8 XKA2 +216PO T 79.293 0.00099 13 XKA1 216PO T -216PO T 89.256 |] XKB3 -216PO T 89.807 |] 0.00034 5 XKB1 -216PO T 90.363 |] XKB5II +216PO T 89.256 |] XKB3 +216PO T 89.807 |] 0.00034 5 XKB1 +216PO T 90.363 |] XKB5II 216PO T -216PO T 92.263 |] XKB2 -216PO T 92.618 |] 0.000106 15 XKB4 -216PO T 92.983 |] XKO23 +216PO T 92.263 |] XKB2 +216PO T 92.618 |] 0.00010615 XKB4 +216PO T 92.983 |] XKO23 216PO T -216PO T 9.658-16.213 0.00094 8 XL (total) -216PO T 9.658 0.0000222 22 XLL -216PO T 11.016-11.13 0.00041 4 XLA -216PO T 12.085 0.0000081 9 XLC -216PO T 12.823-13.778 0.00042 4 XLB -216PO T 15.742-16.213 0.000086 7 XLG +216PO T 9.658-16.213 0.00094 8 XL (total) +216PO T 9.658 2.22E-5 22 XLL +216PO T 11.016-11.13 0.00041 4 XLA +216PO T 12.085 8.1E-6 9 XLC +216PO T 12.823-13.778 0.00042 4 XLB +216PO T 15.742-16.213 0.000086 7 XLG 216PO T -216PO T 58.978-65.205 |] KLL AUGER -216PO T 71.902-79.289 |] 0.000074 13 ^KLX AUGER -216PO T 84.8-93.1 |] KXY AUGER -216PO T 5.434-10.934 0.00140 11 L AUGER +216PO T 58.978-65.205 |] KLL AUGER +216PO T 71.902-79.289 |] 0.00007413 KLX AUGER +216PO T 84.8-93.1 |] KXY AUGER +216PO T 5.434-10.934 0.00140 11 L AUGER 220RN P 0.0 0+ 55.8 S 3 6404.67 10 216PO N 1.0 1.0 1 1.0 216PO L 0 0+ 0.148 S 4 216PO A 6288.22 1099.882 151 216PO L 549.76 4 2+ 216PO A 5748.46 110.118 153.1 -216PO G 549.76 4 0.115 15E2 0.0257 4 -216PO2 G KC=0.0183 3$LC=0.00561 8$MC=1399E-6 20 +216PO G 549.76 4 0.115 15E2 0.0257 4 +216PO2 G KC=0.0183 3$LC=0.00561 8$MC=1399E-6 20 diff --git a/HEN_HOUSE/spectra/lnhb/Rn-222.txt b/HEN_HOUSE/spectra/lnhb/Rn-222.txt index d73bc2778..9d7a1e6ff 100644 --- a/HEN_HOUSE/spectra/lnhb/Rn-222.txt +++ b/HEN_HOUSE/spectra/lnhb/Rn-222.txt @@ -4,34 +4,34 @@ 218PO C References: 1951To25, 1956Ma28, 1956Ma64, 1956Ro31, 1958Sh69, 1958Wa16, 218PO2C 1971Gr17, 1972Bu33, 1979Ry03, 1987El12, 1990Ho28, 1991Ry01, 1995El08, 218PO3C 1996El01, 1996Sc06, 2002Ba85, 2003Au03, 2004Sc04, 2006Ja03, 2007BeZP -218PO T Auger electrons and ^X ray energies and emission intensities: -218PO T {U Energy (keV)} {U Intensity } {U Line } +218PO T Auger electrons and X ray energies and emission intensities: +218PO T {U Energy (keV)} {U Intensity} {U Line} 218PO T -218PO T 76.864 0.000469 10 XKA2 -218PO T 79.293 0.000781 16 XKA1 +218PO T 76.864 0.00046910 XKA2 +218PO T 79.293 0.00078116 XKA1 218PO T -218PO T 89.256 |] XKB3 -218PO T 89.807 |] 0.000269 7 XKB1 -218PO T 90.363 |] XKB5II +218PO T 89.256 |] XKB3 +218PO T 89.807 |] 0.000269 7 XKB1 +218PO T 90.363 |] XKB5II 218PO T -218PO T 92.263 |] XKB2 -218PO T 92.618 |] 0.0000837 25 XKB4 -218PO T 92.983 |] XKO23 +218PO T 92.263 |] XKB2 +218PO T 92.618 |] 8.37E-5 25 XKB4 +218PO T 92.983 |] XKO23 218PO T -218PO T 9.66-16.21 0.000766 15 XL (total) -218PO T 9.66 0.0000178 5 XLL -218PO T 11.0161-11.1303 0.000326 9 XLA -218PO T 12.0847 0.00000665 19 XLC -218PO T 12.8239-14.2476 0.000345 8 XLB -218PO T 15.251-16.21 0.0000702 16 XLG +218PO T 9.66-16.21 0.00076615 XL (total) +218PO T 9.66 1.78E-5 5 XLL +218PO T 11.0161-11.1303 0.000326 9 XLA +218PO T 12.0847 6.65E-6 19 XLC +218PO T 12.8239-14.2476 0.000345 8 XLB +218PO T 15.251-16.21 7.02E-5 16 XLG 222RN P 0.0 0+ 3.8232 D 8 5590.3 3 218PO N 1.0 1.0 1 1.0 218PO L 0 0+ 3.071 M 22 218PO A 5489.48 3099.92 1 1 218PO L 511 2 2+ 218PO A 4987 1 0.078 1.9 -218PO G 510 2 7600E-5 0 [E2] 0.0306 6 -218PO2 G KC=0.0213 4$LC=0.00704 13$MC=0.00177 4 +218PO G 510 2 0.076 [E2] 0.0306 6 +218PO2 G KC=0.0213 4$LC=0.00704 13$MC=0.00177 4 218PO L 675 5 + 218PO A 4827 4 0.0005 30 diff --git a/HEN_HOUSE/spectra/lnhb/Ru-106.txt b/HEN_HOUSE/spectra/lnhb/Ru-106.txt index 69706e280..591b01db9 100644 --- a/HEN_HOUSE/spectra/lnhb/Ru-106.txt +++ b/HEN_HOUSE/spectra/lnhb/Ru-106.txt @@ -3,23 +3,23 @@ 106RH C Evaluation history: Type=Full;Author=A.Arinc;Cutoff date=31-DEC-2012 106RH C References: 1950Ag01, 1956Sc87, 1957Me47, 1960Ea02, 1961Wy01, 1965Fl02, 106RH2C 1980Ho17, 1983Wa26, 2004Sc04, 2012Wa38 -106RH T Auger electrons and ^X ray energies and emission intensities: -106RH T {U Energy (keV)} {U Intensity } {U Line } +106RH T Auger electrons and X ray energies and emission intensities: +106RH T {U Energy (keV)} {U Intensity} {U Line} 106RH T 106RH T 20.0739 XKA2 106RH T 20.2163 XKA1 106RH T -106RH T 22.6991 |] XKB3 -106RH T 22.7238 |] XKB1 -106RH T 22.914 |] XKB5II +106RH T 22.6991 |] XKB3 +106RH T 22.7238 |] XKB1 +106RH T 22.914 |] XKB5II 106RH T -106RH T 23.173 |] XKB2 -106RH T 23.217 |] XKB4 +106RH T 23.173 |] XKB2 +106RH T 23.217 |] XKB4 106RH T 106RH T -106RH T 16.289-17.097 |] KLL AUGER -106RH T 19.138-20.214 |] ^KLX AUGER -106RH T 21.966-23.215 |] KXY AUGER +106RH T 16.289-17.097 |] KLL AUGER +106RH T 19.138-20.214 |] KLX AUGER +106RH T 21.966-23.215 |] KXY AUGER 106RH T 1.7496-3.4069 L AUGER 106RU P 0.0 0+ 371.5 D 21 39.40 21 106RH N 1.0 1.0 1 1.0 diff --git a/HEN_HOUSE/spectra/lnhb/S-35.txt b/HEN_HOUSE/spectra/lnhb/S-35.txt index bc8bfe587..7ed27fc87 100644 --- a/HEN_HOUSE/spectra/lnhb/S-35.txt +++ b/HEN_HOUSE/spectra/lnhb/S-35.txt @@ -6,8 +6,8 @@ 35CL C References: 1940Le**, 1941Ka01, 1943He**, 1949Ma76, 1952Ru23, 1958Se49, 35CL2C 1959Co56, 1959Ca12, 1961Oz01, 1961Wy01, 1965Fl02, 1968Wo06, 1969La34, 35CL3C 1999Pa18, 2012Au06 - 35CL T Auger electrons and ^X ray energies and emission intensities: - 35CL T {U Energy (keV)} {U Intensity } {U Line } + 35CL T Auger electrons and X ray energies and emission intensities: + 35CL T {U Energy (keV)} {U Intensity} {U Line} 35CL T 35CL T 35CL T diff --git a/HEN_HOUSE/spectra/lnhb/Sb-124.txt b/HEN_HOUSE/spectra/lnhb/Sb-124.txt index 8d836dbed..565882f65 100644 --- a/HEN_HOUSE/spectra/lnhb/Sb-124.txt +++ b/HEN_HOUSE/spectra/lnhb/Sb-124.txt @@ -7,218 +7,218 @@ 124TE4C 1979Sh08, 1983RO13, 1984Ma13, 1984Iw03, 1988YO05, 1990Su10, 1990ME15, 124TE5C 1993Go10, 1996Sc06, 2000Kh04, 2000He14, 2000Do11, 2002Ba85, 2003AU03, 124TE6C 2006Pa16, 2008Ki07 -124TE T Auger electrons and ^X ray energies and emission intensities: -124TE T {U Energy (keV)} {U Intensity } {U Line } +124TE T Auger electrons and X ray energies and emission intensities: +124TE T {U Energy (keV)} {U Intensity} {U Line} 124TE T -124TE T 27.202 0.1252 18 XKA2 -124TE T 27.4726 0.233 3 XKA1 +124TE T 27.202 0.1252 18 XKA2 +124TE T 27.4726 0.233 3 XKA1 124TE T -124TE T 30.9446 |] XKB3 -124TE T 30.996 |] 0.0667 12 XKB1 -124TE T 31.236 |] XKB5II +124TE T 30.9446 |] XKB3 +124TE T 30.996 |] 0.0667 12 XKB1 +124TE T 31.236 |] XKB5II 124TE T -124TE T 31.7008 |] XKB2 -124TE T 31.774 |] 0.0145 5 XKB4 -124TE T 31.812 |] XKO23 +124TE T 31.7008 |] XKB2 +124TE T 31.774 |] 0.0145 5 XKB4 +124TE T 31.812 |] XKO23 124TE T -124TE T 3.3348-4.8228 0.0449 9 XL (total) -124TE T 3.3348 0.000873 26 XLL -124TE T 3.7595-3.7697 0.0231 7 XLA -124TE T 3.6052 0.000336 11 XLC -124TE T 4.0299-4.3661 0.0180 4 XLB -124TE T 4.4448-4.8228 0.00247 6 XLG +124TE T 3.3348-4.8228 0.0449 9 XL (total) +124TE T 3.3348 0.00087326 XLL +124TE T 3.7595-3.7697 0.0231 7 XLA +124TE T 3.6052 0.00033611 XLC +124TE T 4.0299-4.3661 0.0180 4 XLB +124TE T 4.4448-4.8228 0.00247 6 XLG 124TE T -124TE T 21.804-22.989 |] KLL AUGER -124TE T 25.814-27.47 |] 0.0628 22 ^KLX AUGER -124TE T 29.8-31.81 |] KXY AUGER -124TE T 2.3-4.9 0.4829 26 L AUGER +124TE T 21.804-22.989 |] KLL AUGER +124TE T 25.814-27.47 |] 0.0628 22 KLX AUGER +124TE T 29.8-31.81 |] KXY AUGER +124TE T 2.3-4.9 0.4829 26 L AUGER 124SB P 0.0 3- 60.208 D 11 2904.3 15 124TE N 1.0 1.0 1 1.0 -124TE G 159.867 350.0049 6 +124TE G 159.867 350.0049 6 124TE G 997.8 3 0.0033 23 124TE G 1235 1 0.0073 26 124TE L 0 0+ STABLE 124TE L 602.7278 212+ 6.2 PS 1 124TE B 2301.6 1523.44 28 10.3 1 124TES B EAV=918 1 -124TE G 602.7260 2397.775 20E2 0.004907 -124TE2 G KC=0.00420 6$LC=5.66E-4 8$MC=1132E-7 16 +124TE G 602.7260 2397.775 20E2 0.00490 7 +124TE2 G KC=0.00420 6$LC=5.66E-4 8$MC=1132E-7 16 124TE L 1248.582 3 4+ 124TE B 1655.7 152.472 33 10.7 1 124TES B EAV=627 1 -124TE G 645.8520 197.422 15E2+M3 0.006 6 0.004096 -124TE2 G KC=0.00351 5$LC=4.68E-4 7$MC=9.35E-5 14 +124TE G 645.8520 197.422 15E2+M3 0.006 6 0.00409 6 +124TE2 G KC=0.00351 5$LC=4.68E-4 7$MC=9.35E-5 14 124TE L 1325.512 3 2+ 124TE B 1578.8 154.815 29 10.3 1 124TES B EAV=593 1 -124TE G 722.782 3 10.708 22M1+E2 -3.4 3 0.003145 -124TE2 G KC=0.00271 4$LC=3.52E-4 5$MC=7.02E-5 10 -124TE G 1325.504 4 1.587 7 E2 8.27E-412 +124TE G 722.7820 3010.708 22M1+E2 -3.4 3 0.00314 5 +124TE2 G KC=0.00271 4$LC=3.52E-4 5$MC=7.02E-5 10 +124TE G 1325.504 4 1.587 7E2 8.27E-412 124TE2 G KC=6.93E-4 10$LC=8.48E-5 12$MC=1685E-8 24 124TE L 1656.6 3 0+ 124TE B 1247.7 150.0053 10 12.8 3 124TES B EAV=450 1 -124TE G 1053.9 3 0.0053 10E2 1290E-618 -124TE2 G KC=1117E-6 16$LC=1394E-7 20$MC=2.77E-5 4 +124TE G 1053.90 300.0053 10E2 1290E-618 +124TE2 G KC=1117E-6 16$LC=1394E-7 20$MC=2.77E-5 4 124TE G 1656.6 3 124TE L 1957.915 164+ -124TE B 946.4 152.295 7 9.8 1 +124TE B 946.4 152.295 7 9.8 1 124TES B EAV=324 1 -124TE G 632.40 2 0.1029 21 -124TE G 709.33 2 1.363 5 M1+E2 -0.18 5 0.004026 -124TE2 G KC=0.00349 5$LC=4.29E-4 7$MC=8.53E-5 13 -124TE G 1355.20 2 1.0412 38E2+M3 -0.32 25 0.0011 5 -124TE2 G KC=0.0009 5$LC=0.00011 6$MC=2.3E-5 11 +124TE G 632.400 200.1029 21 +124TE G 709.330 201.363 5M1+E2 -0.18 5 0.00402 6 +124TE2 G KC=0.00349 5$LC=4.29E-4 7$MC=8.53E-5 13 +124TE G 1355.200 201.0412 38E2+M3 -0.32 25 0.0011 5 +124TE2 G KC=0.0009 5$LC=0.00011 6$MC=2.3E-5 11 124TE L 2039.288 4 2, 3+ 124TE B 865.0 154.143 18 9.4 1 124TES B EAV=292 1 -124TE G 713.776 4 2.273 7 M1+E2 1.0 5 0.0036 4 -124TE2 G KC=0.0031 4$LC=0.00039 4$MC=7.8E-5 7 -124TE G 790.706 7 0.7415 24E2 0.002488 -124TE2 G KC=0.00214 6$LC=2.76E-4 8$MC=5.5E-5 2 -124TE G 1436.554 7 1.234 8 M1+E2 1.5 8 0.000785 -124TE2 G KC=0.00063 5$LC=7.6E-5 6$MC=1.51E-5 11 -124TE G 2039.27 1 0.0631 5 E2 6.67E-410 -124TE2 G KC=3.05E-4 5$LC=3.64E-5 5$MC=7.21E-6 10 +124TE G 713.776 4 2.273 7M1+E2 1.0 5 0.0036 4 +124TE2 G KC=0.0031 4$LC=0.00039 4$MC=7.8E-5 7 +124TE G 790.706 7 0.7415 24E2 0.00248 8 +124TE2 G KC=0.00214 6$LC=2.76E-4 8$MC=5.5E-5 2 +124TE G 1436.554 7 1.234 8M1+E2 1.5 8 0.00078 5 +124TE2 G KC=0.00063 5$LC=7.6E-5 6$MC=1.51E-5 11 +124TE G 2039.27 1 0.0631 5E2 6.67E-410 +124TE2 G KC=3.05E-4 5$LC=3.64E-5 5$MC=7.21E-6 10 124TE L 2091.680 212+ 124TE B 812.6 150.688 38 10 1 124TES B EAV=271.0 6 -124TE G 766.17 2 0.0103 9 M1 0.021 7 -124TE2 G KC=0.019 6$LC=$MC= -124TE G 1488.94 2 0.6770 37M1+E2 0.10 23 8.29E-416 -124TE2 G KC=6.59E-4 14$LC=7.92E-5 16$MC=1.57E-5 3 +124TE G 766.170 200.0103 9M1 0.021 7 +124TE2 G KC=0.019 6 +124TE G 1488.940 200.6770 37M1+E2 0.10 23 8.29E-416 +124TE2 G KC=6.59E-4 14$LC=7.92E-5 16$MC=1.57E-5 3 124TE L 2182.39 3 2+ 124TE B 721.9 150.47 30 10 1 124TES B EAV=236.0 6 -124TE G 856.87 3 0.0227 5 -124TE G 1579.65 3 0.412 5 M1+E2 0.000725 -124TE2 G KC=0.00054 5$LC=6.5E-5 6$MC=1.28E-5 11 +124TE G 856.870 300.0227 5 +124TE G 1579.650 300.412 5M1+E2 0.00072 5 +124TE2 G KC=0.00054 5$LC=6.5E-5 6$MC=1.28E-5 11 124TE G 2182.37 3 0.04147 31 124TE L 2224.839 254+ 124TE B 679.5 150.0967 34 10.6 1 124TES B EAV=219.5 6 -124TE G 899.32 3 0.0179 7 -124TE G 976.25 3 0.0832 7 -124TE G 1622.10 3 0.0416 19E2 6.64E-410 -124TE2 G KC=4.67E-4 7$LC=5.64E-5 8$MC=1118E-8 16 +124TE G 899.320 300.0179 7 +124TE G 976.250 300.0832 7 +124TE G 1622.100 300.0416 19E2 6.64E-410 +124TE2 G KC=4.67E-4 7$LC=5.64E-5 8$MC=1118E-8 16 124TE L 2293.712 4 3- 124TE B 610.6 1551.21 19 7.7 124TES B EAV=193.8 6 -124TE G 254.42 1 0.0142 9 (E1) 0.0146521 -124TE2 G KC=0.01269 18$LC=1575E-6 22$MC=3.12E-4 5 -124TE G 335.80 2 0.0725 9 E1 0.0070610 -124TE2 G KC=0.00612 9$LC=7.54E-4 11$MC=1495E-7 21 +124TE G 254.42 1 0.0142 9(E1) 0.0146521 +124TE2 G KC=0.01269 18$LC=1575E-6 22$MC=3.12E-4 5 +124TE G 335.800 200.0725 9E1 0.0070610 +124TE2 G KC=0.00612 9$LC=7.54E-4 11$MC=1495E-7 21 124TE G 968.195 4 1.887 10E1+M2 -0.02 2 6.53E-411 -124TE2 G KC=5.69E-4 9$LC=6.78E-5 11$MC=1343E-8 22 +124TE2 G KC=5.69E-4 9$LC=6.78E-5 11$MC=1343E-8 22 124TE G 1045.125 4 1.852 14E1+M2 -0.03 2 5.67E-410 -124TE2 G KC=4.94E-4 9$LC=5.87E-5 11$MC=1163E-8 21 -124TE G 1690.971 4 47.46 19E1+M2 0.01 3 6.15E-49 -124TE2 G KC=2.13E-4 4$LC=2.50E-5 4$MC=4.94E-6 8 +124TE2 G KC=4.94E-4 9$LC=5.87E-5 11$MC=1163E-8 21 +124TE G 1690.9710 4047.46 19E1+M2 0.01 3 6.15E-4 9 +124TE2 G KC=2.13E-4 4$LC=2.50E-5 4$MC=4.94E-6 8 124TE G 2293.69 1 0.0327 41 124TE L 2323.41 3 2+ 124TE B 580.9 150.0686 14 10.5 1 124TES B EAV=182.8 6 -124TE G 1720.67 3 0.0946 6 M1+E2 0.000684 -124TE2 G KC=0.00045 4$LC=5.4E-5 4$MC=1.07E-5 8 -124TE G 2323.39 3 0.0025 6 +124TE G 1720.670 300.0946 6M1+E2 0.00068 4 +124TE2 G KC=0.00045 4$LC=5.4E-5 4$MC=1.07E-5 8 +124TE G 2323.39 3 0.0025 6 124TE L 2335.26 5 5- -124TE G 1086.67 5 0.0367 9 E1 5.24E-48 -124TE2 G KC=4.57E-4 7$LC=5.43E-5 8$MC=1074E-8 15 +124TE G 1086.67 5 0.0367 9E1 5.24E-4 8 +124TE2 G KC=4.57E-4 7$LC=5.43E-5 8$MC=1074E-8 15 124TE L 2454.96 7 2+ 124TE B 449.3 150.0050 26 11.3 1 124TES B EAV=135.8 6 -124TE G 1852.22 7 0.0030 9 M1+E2 0.000673 -124TE2 G KC=0.00039 3$LC=4.7E-5 4$MC=9.3E-6 7 +124TE G 1852.22 7 0.0030 9M1+E2 0.00067 3 +124TE2 G KC=0.00039 3$LC=4.7E-5 4$MC=9.3E-6 7 124TE G 2454.93 7 0.00160 12E2 7.68E-411 -124TE2 G KC=2.19E-4 3$LC=2.59E-5 4$MC=5.13E-6 8 +124TE2 G KC=2.19E-4 3$LC=2.59E-5 4$MC=5.13E-6 8 124TE L 2483.277 184+ 124TE B 421.0 150.332 10 9.4 1 124TES B EAV=126.0 5 -124TE G 148.02 5 0.0037 6 E1+M2 -124TE G 189.57 2 0.0043 5 -124TE G 444.00 2 0.195 16M1+E2 0.06 8 0.0126118 -124TE2 G KC=0.01092 16$LC=1360E-6 19$MC=2.71E-4 4 -124TE G 525.36 3 0.1451 35M1+E2 1.0 4 0.0077 3 -124TE2 G KC=0.0066 3$LC=8.67E-4 18$MC=1.73E-4 4 +124TE G 148.02 5 0.0037 6E1+M2 +124TE G 189.570 200.0043 5 +124TE G 444.000 200.195 16M1+E2 0.06 8 0.0126118 +124TE2 G KC=0.01092 16$LC=1360E-6 19$MC=2.71E-4 4 +124TE G 525.360 300.1451 35M1+E2 1.0 4 0.0077 3 +124TE2 G KC=0.0066 3$LC=8.67E-4 18$MC=1.73E-4 4 124TE L 2512.04 7 4+ 124TE B 392.3 150.0422 19 10.2 1 124TES B EAV=116.0 5 124TE G 1263.45 7 0.0422 19 124TE L 2521.48 6 2+ -124TE B 382.8 150.0529 5 10 1 +124TE B 382.8 150.0529 5 10 1 124TES B EAV=113.0 5 -124TE G 1918.74 6 0.0529 5 M1(+E2) 0.000673 -124TE2 G KC=3.64E-4 24$LC=4.3E-5 3$MC=8.6E-6 6 +124TE G 1918.74 6 0.0529 5M1(+E2) 0.00067 3 +124TE2 G KC=3.64E-4 24$LC=4.3E-5 3$MC=8.6E-6 6 124TE L 2549.73 9 (4)+ 124TE B 354.6 150.0364 22 10 1 124TES B EAV=103.6 5 124TE G 1301.14 9 0.0364 22 124TE L 2619.09 6 (3)+ -124TE B 285.2 150.0098 8 10.4 +124TE B 285.2 150.0098 8 10.4 124TES B EAV=81.0 5 -124TE G 2016.34 6 0.0098 8 +124TE G 2016.34 6 0.0098 8 124TE L 2682.50 132+ 124TE B 221.8 150.0242 22 9.6 1 124TES B EAV=61.5 5 124TE G 2079.75 130.0224 22M1+E2 6.91E-420 -124TE2 G KC=3.11E-4 18$LC=3.71E-5 21$MC=7.3E-6 4 -124TE G 2682.47 130.00176 6 +124TE2 G KC=3.11E-4 18$LC=3.71E-5 21$MC=7.3E-6 4 +124TE G 2682.47 130.00176 6 124TE L 2693.679 5 3- 124TE B 210.6 158.663 27 7 124TES B EAV=58.0 5 -124TE G 210.40 2 0.0053 7 -124TE G 370.27 3 0.0286 11 +124TE G 210.400 200.0053 7 +124TE G 370.270 300.0286 11 124TE G 399.97 1 0.1264 31E2 0.0156622 -124TE2 G KC=0.01323 19$LC=0.00196 3$MC=3.94E-4 6 -124TE G 468.84 3 0.0459 26E1 0.003095 -124TE2 G KC=0.00268 4$LC=3.27E-4 5$MC=6.48E-5 9 -124TE G 1368.157 5 2.620 8 E1+M2 -0.02 1 4.78E-47 -124TE2 G KC=3.03E-4 5$LC=3.58E-5 6$MC=7.09E-6 10 -124TE G 1445.09 1 0.334 7 E1+M2 0.10 9 0.000524 -124TE2 G KC=0.00029 4$LC=3.4E-5 4$MC=6.7E-6 8 +124TE2 G KC=0.01323 19$LC=0.00196 3$MC=3.94E-4 6 +124TE G 468.840 300.0459 26E1 0.00309 5 +124TE2 G KC=0.00268 4$LC=3.27E-4 5$MC=6.48E-5 9 +124TE G 1368.157 5 2.620 8E1+M2 -0.02 1 4.78E-4 7 +124TE2 G KC=3.03E-4 5$LC=3.58E-5 6$MC=7.09E-6 10 +124TE G 1445.09 1 0.334 7E1+M2 0.10 9 0.00052 4 +124TE2 G KC=0.00029 4$LC=3.4E-5 4$MC=6.7E-6 8 124TE G 2090.930 7 5.493 24E1+M2 0.03 2 8.38E-412 -124TE2 G KC=1522E-7 23$LC=1.78E-5 3$MC=3.52E-6 6 -124TE G 2693.65 1 0.0032 14 +124TE2 G KC=1522E-7 23$LC=1.78E-5 3$MC=3.52E-6 6 +124TE G 2693.650 100.0032 14 124TE L 2701.622 9 2- 124TE B 202.7 150.571 25 8 124TES B EAV=55.7 5 -124TE G 662.33 1 0.024 11 -124TE G 1376.10 1 0.4999 43E1+M2 -0.01 3 4.79E-47 -124TE2 G KC=3.00E-4 5$LC=3.54E-5 6$MC=7.01E-6 12 +124TE G 662.330 100.024 11 +124TE G 1376.10 1 0.4999 43E1+M2 -0.01 3 4.79E-4 7 +124TE2 G KC=3.00E-4 5$LC=3.54E-5 6$MC=7.01E-6 12 124TE G 2098.88 1 0.0471 33 124TE L 2711.012 214+ -124TE B 193.3 150.106 6 8.8 1 +124TE B 193.3 150.106 6 8.8 1 124TES B EAV=52.9 5 -124TE G 1385.49 2 0.062 6 -124TE G 2108.27 2 0.0444 23 +124TE G 1385.490 200.062 6 +124TE G 2108.270 200.0444 23 124TE L 2775.070 173,4- -124TE B 129.2 150.653 6 7.5 +124TE B 129.2 150.653 6 7.5 124TES B EAV=34.4 4 -124TE G 291.79 3 0.0069 7 +124TE G 291.790 300.0069 7 124TE G 481.36 2 0.0232 31 -124TE G 735.78 2 0.1312 16 -124TE G 817.15 3 0.0744 12 -124TE G 1526.48 2 0.414 5 E1 5.35E-48 -124TE2 G KC=2.52E-4 4$LC=2.96E-5 5$MC=5.86E-6 9 -124TE G 2172.32 2 0.0029 16 +124TE G 735.780 200.1312 16 +124TE G 817.150 300.0744 12 +124TE G 1526.480 200.414 5E1 5.35E-4 8 +124TE2 G KC=2.52E-4 4$LC=2.96E-5 5$MC=5.86E-6 9 +124TE G 2172.320 200.0029 16 124TE L 2807.55 242+ -124TE B 96.8 150.0012 5 9.8 1 +124TE B 96.8 150.0012 5 9.8 1 124TES B EAV=25.3 4 -124TE G 2807.52 240.0012 5 E2 8.78E-413 -124TE2 G KC=1730E-7 25$LC=2.04E-5 3$MC=4.04E-6 6 +124TE G 2807.52 240.0012 5E2 8.78E-413 +124TE2 G KC=1730E-7 25$LC=2.04E-5 3$MC=4.04E-6 6 124TE L 2814.56 7 2 TO 5+ 124TE B 89.7 150.0207 12 8.4 124TES B EAV=23.4 4 -124TE G 775.27 7 0.0098 4 +124TE G 775.27 7 0.0098 4 124TE G 1565.97 7 0.0109 12 124TE L 2865.72 5 3- -124TE B 38.6 150.054 9 6.9 +124TE B 38.6 150.054 9 6.9 124TES B EAV=9.8 4 -124TE G 530.46 7 0.036 9 -124TE G 572.01 5 0.0176 8 +124TE G 530.46 7 0.036 9 +124TE G 572.01 5 0.0176 8 124TE L 2886.37 6 3- -124TE B 17.9 150.0059 5 6.9 +124TE B 17.9 150.0059 5 6.9 124TES B EAV=4.5 4 -124TE G 2283.62 6 0.0059 5 E1+M2 0.000915 -124TE2 G KC=0.00033 21$LC=4.0E-5 25$MC=8E-6 5 +124TE G 2283.62 6 0.0059 5E1+M2 0.00091 5 +124TE2 G KC=0.00033 21$LC=4.0E-5 25$MC=8E-6 5 diff --git a/HEN_HOUSE/spectra/lnhb/Sb-125.txt b/HEN_HOUSE/spectra/lnhb/Sb-125.txt index 25c53cf33..e038de209 100644 --- a/HEN_HOUSE/spectra/lnhb/Sb-125.txt +++ b/HEN_HOUSE/spectra/lnhb/Sb-125.txt @@ -4,109 +4,109 @@ 125TE C Evaluation history: Type=Full;Author=R.G.Helmer and E.Browne;Cutoff date=10-NOV-2004 125TE2C Type=Full;Author=R.G.Helmer;Cutoff date=01-MAY-2004 125TE C References: 1990Ne01 -125TE T Auger electrons and ^X ray energies and emission intensities: -125TE T {U Energy (keV)} {U Intensity } {U Line } +125TE T Auger electrons and X ray energies and emission intensities: +125TE T {U Energy (keV)} {U Intensity} {U Line} 125TE T -125TE T 27.202 21.0 9 XKA2 -125TE T 27.4726 39.1 15 XKA1 +125TE T 27.202 21.0 9 XKA2 +125TE T 27.4726 39.1 15 XKA1 125TE T -125TE T 30.9446 |] XKB3 -125TE T 30.996 |] 11.2 5 XKB1 -125TE T 31.236 |] XKB5II +125TE T 30.9446 |] XKB3 +125TE T 30.996 |] 11.2 5 XKB1 +125TE T 31.236 |] XKB5II 125TE T -125TE T 31.7008 |] XKB2 -125TE T 31.774 |] 2.43 12 XKB4 -125TE T 31.812 |] XKO23 +125TE T 31.7008 |] XKB2 +125TE T 31.774 |] 2.43 12 XKB4 +125TE T 31.812 |] XKO23 125TE T -125TE T 3.3348-4.8228 6.56 21 XL (total) -125TE T 3.3348 0.135 6 XLL -125TE T 3.7595-3.7697 3.58 15 XLA -125TE T 3.6052 0.0508 24 XLC -125TE T 4.0299-4.3003 2.48 9 XLB -125TE T 4.4448-4.8228 0.311 13 XLG +125TE T 3.3348-4.8228 6.56 21 XL (total) +125TE T 3.3348 0.135 6 XLL +125TE T 3.7595-3.7697 3.58 15 XLA +125TE T 3.6052 0.0508 24 XLC +125TE T 4.0299-4.3003 2.48 9 XLB +125TE T 4.4448-4.8228 0.311 13 XLG 125TE T -125TE T 21.804-22.989 |] KLL AUGER -125TE T 25.814-27.47 |] 10.5 6 ^KLX AUGER -125TE T 29.8-31.81 |] KXY AUGER -125TE T 2.3-4.8 70.6 9 L AUGER +125TE T 21.804-22.989 |] KLL AUGER +125TE T 25.814-27.47 |] 10.5 6 KLX AUGER +125TE T 29.8-31.81 |] KXY AUGER +125TE T 2.3-4.8 70.6 9 L AUGER 125SB P 0.0 7/2+ 2.75855 Y 25 766.7 21 125TE N 1.0 1.0 1 1.0 125TE L 0 1/2+ STABLE 125TE L 35.490 3 3/2+ 1.48 NS 1 -125TE G 35.489 5 5.79 18M1+E2 14.3 4 -125TE2 G KC=12.1 4$LC=1.64 5$MC=0.329 10 +125TE G 35.489 5 5.79 18M1+E2 14.3 4 +125TE2 G KC=12.1 4$LC=1.64 5$MC=0.329 10 125TE L 144.776 1111/2- 57.40 D 15 -125TE B 621.0 2113.4 9 9.77 3U +125TE B 621.0 2113.4 9 9.77 1U 125TES B EAV=215.5 8 125TE G 109.276 150.0683 12M4 3.5E2 11 -125TE2 G KC=182 5$LC=135 4$MC=31 1 +125TE2 G KC=182 5$LC=135 4$MC=31 1 125TE L 321.090 119/2- 0.673 NS 13 -125TE B 444.0 217.54 9 9.32 1U +125TE B 444.0 217.54 9 9.32 1 125TES B EAV=134.5 8 -125TE G 176.314 2 6.82 7 M1+E2 0.167 5 -125TE2 G KC=0.139 4$LC=0.0221 7$MC=0.00449 13 +125TE G 176.314 2 6.82 7M1+E2 0.167 5 +125TE2 G KC=0.139 4$LC=0.0221 7$MC=0.00449 13 125TE L 402.09 4 7/2+ 125TE L 443.554 6 3/2+ 19.1 PS 6 -125TE B 323.1 210.089 10 10.79 +125TE B 323.1 210.089 10 10.79 2 125TES B EAV=93.3 7 -125TE G 408.065 100.182 2 M1+E2 0.0152 5 -125TE2 G KC=0.0129 4$LC=0.00181 5$MC=0.00036 1 -125TE G 443.555 9 0.305 4 M1+E2 0.0118 4 -125TE2 G KC=0.0100 3$LC=0.00142 4$MC=0.00029 1 +125TE G 408.065 100.182 2M1+E2 0.0152 5 +125TE2 G KC=0.0129 4$LC=0.00181 5$MC=0.00036 1 +125TE G 443.555 9 0.305 4M1+E2 0.0118 4 +125TE2 G KC=0.0100 3$LC=0.00142 4$MC=0.00029 1 125TE L 463.365 3 5/2+ 13.2 PS 5 -125TE B 303.3 2140.3 4 8.04 2 +125TE B 303.3 2140.3 4 8.04 125TES B EAV=86.9 7 -125TE G 19.80 6 0.0202 5 [M1] 11.3 3 -125TE2 G KC=$LC=9.1 3$MC=1.82 5 -125TE G 427.874 4 29.55 24M1+E2 0.0138 4 -125TE2 G KC=0.0119 4$LC=0.00154 5$MC=0.00031 1 -125TE G 463.365 4 10.48 9 E2 0.0102 3 -125TE2 G KC=0.0086 3$LC=0.00124 4$MC=0.00025 1 +125TE G 19.80 6 0.0202 5[M1] 11.3 3 +125TE2 G LC=9.1 3$MC=1.82 5 +125TE G 427.874 4 29.55 24M1+E2 0.0138 4 +125TE2 G KC=0.0119 4$LC=0.00154 5$MC=0.00031 1 +125TE G 463.365 4 10.48 9E2 0.0102 3 +125TE2 G KC=0.0086 3$LC=0.00124 4$MC=0.00025 1 125TE L 525.227 9 7/2- 125TE B 241.5 211.251 12 9.23 125TES B EAV=67.5 7 -125TE G 204.138 100.313 15M1+E2 0.128 4 -125TE2 G KC=0.104 3$LC=0.0189 6$MC=0.00386 11 -125TE G 380.452 8 1.520 15E2 0.0183 5 -125TE2 G KC=0.0154 5$LC=0.00233 7$MC=4.73E-4 15 +125TE G 204.138 100.313 15M1+E2 0.128 4 +125TE2 G KC=0.104 3$LC=0.0189 6$MC=0.00386 11 +125TE G 380.452 8 1.520 15E2 0.0183 5 +125TE2 G KC=0.0154 5$LC=0.00233 7$MC=4.73E-4 15 125TE L 538.60 5 (1/2)+ 125TE L 636.090 4 7/2+ 40 PS 20 125TE B 130.6 2118.07 19 7.23 125TES B EAV=34.7 6 -125TE G 110.895 120.00109 9 [E1] 0.147 4 -125TE2 G KC=0.127 4$LC=0.0165 5$MC=0.00328 11 -125TE G 172.719 8 0.192 9 M1(+E2) 0.151 5 -125TE2 G KC=0.129 4$LC=0.0168 5$MC=0.00337 11 -125TE G 314.95 110.0043 3 (E1) 0.0083930 -125TE2 G KC=0.00726 22$LC=0.00089 3$MC=1.79E-4 5 +125TE G 110.895 120.00109 9[E1] 0.147 4 +125TE2 G KC=0.127 4$LC=0.0165 5$MC=0.00328 11 +125TE G 172.719 8 0.192 9M1(+E2) 0.151 5 +125TE2 G KC=0.129 4$LC=0.0168 5$MC=0.00337 11 +125TE G 314.95 110.0043 3(E1) 0.0083930 +125TE2 G KC=0.00726 22$LC=0.00089 3$MC=1.79E-4 5 125TE G 600.597 2 17.76 18E2 0.0049815 -125TE2 G KC=0.00421 13$LC=0.00058 2$MC=1.16E-4 4 +125TE2 G KC=0.00421 13$LC=0.00058 2$MC=1.16E-4 4 125TE L 642.205 4 7/2+ -125TE B 124.5 215.82 5 7.66 +125TE B 124.5 215.82 5 7.66 125TES B EAV=33.0 6 -125TE G 116.955 110.263 4 E1 0.127 4 -125TE2 G KC=0.109 3$LC=0.0141 4$MC=0.00281 8 -125TE G 178.842 5 0.0343 15M1+E2 0.18 4 +125TE G 116.955 110.263 4E1 0.127 4 +125TE2 G KC=0.109 3$LC=0.0141 4$MC=0.00281 8 +125TE G 178.842 5 0.0343 15M1+E2 0.18 4 125TE2 G KC=0.147 26$LC=0.026 11$MC=0.0054 21 -125TE G 198.654 110.0132 7 [E2] 0.154 5 -125TE2 G KC=0.123 4$LC=0.0245 8$MC=0.00504 15 -125TE G 321.040 4 0.416 4 E1 0.0079824 -125TE2 G KC=0.00691 21$LC=8.56E-4 30$MC=1.70E-4 5 -125TE G 497.37 120.0032 3 [M2] 0.0318 10 -125TE2 G KC=0.0271 8$LC=0.00373 11$MC=0.00075 2 -125TE G 606.713 3 5.02 5 E2 0.0048515 -125TE2 G KC=0.00415 13$LC=0.00056 2$MC=1.13E-4 4 +125TE G 198.654 110.0132 7[E2] 0.154 5 +125TE2 G KC=0.123 4$LC=0.0245 8$MC=0.00504 15 +125TE G 321.040 4 0.416 4E1 0.0079824 +125TE2 G KC=0.00691 21$LC=8.56E-4 30$MC=1.70E-4 5 +125TE G 497.37 120.0032 3[M2] 0.0318 10 +125TE2 G KC=0.0271 8$LC=0.00373 11$MC=0.00075 2 +125TE G 606.713 3 5.02 5E2 0.0048515 +125TE2 G KC=0.00415 13$LC=0.00056 2$MC=1.13E-4 4 125TE L 652.9 5 (5/2)+ 125TE L 671.443 4 5/2+ 1.26 PS 6 -125TE B 95.3 2113.58 12 6.93 2 +125TE B 95.3 2113.58 12 6.93 125TES B EAV=24.9 6 -125TE G 208.077 5 0.246 8 M1+E2 0.092 3 -125TE2 G KC=0.0791 24$LC=0.0102 3$MC=0.00205 6 -125TE G 227.891 100.131 3 (M1+E2) 0.084 13 -125TE2 G KC=0.070 11$LC=0.011 4$MC=0.0023 6 +125TE G 208.077 5 0.246 8M1+E2 0.092 3 +125TE2 G KC=0.0791 24$LC=0.0102 3$MC=0.00205 6 +125TE G 227.891 100.131 3(M1+E2) 0.084 13 +125TE2 G KC=0.070 11$LC=0.011 4$MC=0.0023 6 125TE G 635.950 3 11.32 10M1+E2 0.0052616 -125TE2 G KC=0.00455 14$LC=0.00057 2$MC=1.13E-4 5 +125TE2 G KC=0.00455 14$LC=0.00057 2$MC=1.13E-4 5 125TE G 671.441 6 1.783 16E2 0.0037311 -125TE2 G KC=0.00319 10$LC=0.00043 1$MC=8.6E-5 2 +125TE2 G KC=0.00319 10$LC=0.00043 1$MC=8.6E-5 2 125TE L 728.8 5 3/2+ diff --git a/HEN_HOUSE/spectra/lnhb/Sb-127.txt b/HEN_HOUSE/spectra/lnhb/Sb-127.txt index 5c21664d1..e90e67878 100644 --- a/HEN_HOUSE/spectra/lnhb/Sb-127.txt +++ b/HEN_HOUSE/spectra/lnhb/Sb-127.txt @@ -5,155 +5,155 @@ 127TE2C 1967Ha27, 1967Ra13, 1967Ta05, 1972Kr15, 1972Pa13, 1974Sa03, 1977La19, 127TE3C 1977Kr13, 1985De04, 1996Sc06, 1998ScZm, 1999ScZX, 2002Ba25, 2002Ra45, 127TE4C 2003Au03, 2003De44, 2005Ho15, 2008Ki07, 2011Ha31, 2012Au06 -127TE T Auger electrons and ^X ray energies and emission intensities: -127TE T {U Energy (keV)} {U Intensity } {U Line } +127TE T Auger electrons and X ray energies and emission intensities: +127TE T {U Energy (keV)} {U Intensity} {U Line} 127TE T -127TE T 27.202 1.11 4 XKA2 -127TE T 27.4726 2.06 7 XKA1 +127TE T 27.202 1.11 4 XKA2 +127TE T 27.4726 2.06 7 XKA1 127TE T -127TE T 30.9446 |] XKB3 -127TE T 30.996 |] 0.591 21 XKB1 -127TE T 31.232 |] XKB5II -127TE T 31.242 |] XKB5I +127TE T 30.9446 |] XKB3 +127TE T 30.996 |] 0.591 21 XKB1 +127TE T 31.232 |] XKB5II +127TE T 31.242 |] XKB5I 127TE T -127TE T 31.7008 |] XKB2 -127TE T 31.774 |] 0.128 6 XKB4 -127TE T 31.182 |] XKO23 +127TE T 31.7008 |] XKB2 +127TE T 31.774 |] 0.128 6 XKB4 +127TE T 31.182 |] XKO23 127TE T -127TE T 3.335-4.829 0.462 23 XL (total) -127TE T 3.335 0.0089 4 XLL -127TE T 3.759-3.77 0.235 10 XLA -127TE T 3.605 0.00355 19 XLC -127TE T 4.03-4.302 0.184 7 XLB -127TE T 4.572-4.829 0.0248 10 XLG +127TE T 3.335-4.829 0.462 23 XL (total) +127TE T 3.335 0.0089 4 XLL +127TE T 3.759-3.77 0.235 10 XLA +127TE T 3.605 0.00355 19 XLC +127TE T 4.03-4.302 0.184 7 XLB +127TE T 4.572-4.829 0.0248 10 XLG 127TE T -127TE T 21.804-22.989 |] KLL AUGER -127TE T 25.814-27.47 |] 0.556 26 ^KLX AUGER -127TE T 29.8-31.81 |] KXY AUGER -127TE T 2.29-3.72 4.90 14 L AUGER +127TE T 21.804-22.989 |] KLL AUGER +127TE T 25.814-27.47 |] 0.556 26 KLX AUGER +127TE T 29.8-31.81 |] KXY AUGER +127TE T 2.29-3.72 4.90 14 L AUGER 127SB P 0.0 7/2+ 3.85 D 7 1582 5 127TE N 1.0 1.0 1 1.0 127TE L 0 3/2+ 9.35 H 10 127TE L 61.161 191/2+ -127TE G 61.16 2 1.140 14M1+E2 0.49 6 4.2 3 -127TE2 G KC=2.93 12$LC=0.99 14$MC=0.21 3 +127TE G 61.16 2 1.140 14M1+E2 0.49 6 4.2 3 +127TE2 G KC=2.93 12$LC=0.99 14$MC=0.21 3 127TE L 88.23 7 11/2- 106.1 D 7 -127TE B 1494 5 2.0 5 10.21 3U +127TE B 1494 5 2.0 5 10.21 1U 127TES B EAV=562.4 21 127TE L 340.87 6 (9/2)- 0.41 NS 2 -127TE B 1241 5 2.4 3 8.98 1U +127TE B 1241 5 2.4 3 8.98 1 127TES B EAV=446.9 22 127TE G 252.64 9 8.28 14M1+E2 -2.1 5 0.0652 17 -127TE2 G KC=0.0541 12$LC=0.0090 4$MC=0.00182 8 +127TE2 G KC=0.0541 12$LC=0.0090 4$MC=0.00182 8 127TE L 473.26 4 5/2+ -127TE B 1109 5 22.6 8 7.826 2 +127TE B 1109 5 22.6 8 7.826 127TES B EAV=391.2 21 127TE G 412.10 5 3.43 18E2 0.0143120 -127TE2 G KC=0.01210 17$LC=1775E-6 25$MC=3.57E-4 5 -127TE G 473.26 4 24.8 7 M1+E2 -0.2 1 0.0107216 -127TE2 G KC=0.00928 14$LC=1159E-6 17$MC=2.31E-4 4 +127TE2 G KC=0.01210 17$LC=1775E-6 25$MC=3.57E-4 5 +127TE G 473.26 4 24.8 7M1+E2 -0.2 1 0.0107216 +127TE2 G KC=0.00928 14$LC=1159E-6 17$MC=2.31E-4 4 127TE L 501.928 103/2+ -127TE G 440.77 2 0.7 3 M1+E2 0.5 3 0.0126 3 -127TE2 G KC=0.0109 3$LC=1395E-6 22$MC=2.78E-4 5 +127TE G 440.77 2 0.7 3M1+E2 0.5 3 0.0126 3 +127TE2 G KC=0.0109 3$LC=1395E-6 22$MC=2.78E-4 5 127TE G 501.93 1 0.64 11M1+E2 0.34 8 0.0091914 -127TE2 G KC=0.00795 13$LC=9.97E-4 14$MC=1.99E-4 3 +127TE2 G KC=0.00795 13$LC=9.97E-4 14$MC=1.99E-4 3 127TE L 631.40 6 7/2- 127TE B 951 5 4.00 21 8.33 127TES B EAV=326.2 21 -127TE G 290.5 1 1.84 7 M1+E2 0.40 3 0.0379 6 -127TE2 G KC=0.0326 5$LC=0.00430 7$MC=8.59E-4 14 -127TE G 543.2 1 2.62 11E2 0.006489 -127TE2 G KC=0.00553 8$LC=7.61E-4 11$MC=1525E-7 22 +127TE G 290.5 1 1.84 7M1+E2 0.40 3 0.0379 6 +127TE2 G KC=0.0326 5$LC=0.00430 7$MC=8.59E-4 14 +127TE G 543.2 1 2.62 11E2 0.00648 9 +127TE2 G KC=0.00553 8$LC=7.61E-4 11$MC=1525E-7 22 127TE L 685.09 7 7/2+ -127TE B 897 5 34.4 4 7.304 +127TE B 897 5 34.4 4 7.304 127TES B EAV=304.5 20 -127TE G 685.09 7 35.4 4 E2 0.003525 -127TE2 G KC=0.00303 5$LC=3.99E-4 6$MC=7.97E-5 12 +127TE G 685.09 7 35.4 4E2 0.00352 5 +127TE2 G KC=0.00303 5$LC=3.99E-4 6$MC=7.97E-5 12 127TE L 762.64 5 3/2+ -127TE G 762.7 1 0.07 4 M1+E2 1.0 5 0.0030622 -127TE2 G KC=0.00265 20$LC=3.32E-4 19$MC=6.6E-5 4 +127TE G 762.7 1 0.07 4M1+E2 1.0 5 0.0030622 +127TE2 G KC=0.00265 20$LC=3.32E-4 19$MC=6.6E-5 4 127TE L 782.62 3 5/2+ -127TE B 799 5 17.2 3 7.425 2 +127TE B 799 5 17.2 3 7.425 127TES B EAV=265.8 20 -127TE G 280.7 1 0.53 4 M1+E2 -0.09 2 0.0407 6 -127TE2 G KC=0.0351 5$LC=0.00445 7$MC=8.88E-4 13 -127TE G 309.4 1 0.076 13M1+E2 0.10 3 0.0316 5 -127TE2 G KC=0.0273 4$LC=0.00345 5$MC=6.87E-4 10 -127TE G 721.5 1 1.77 7 E2 0.003095 -127TE2 G KC=0.00266 4$LC=3.48E-4 5$MC=6.95E-5 10 -127TE G 782.6 1 14.7 3 M1+E2 0.21 1 0.003195 -127TE2 G KC=0.00277 4$LC=3.39E-4 5$MC=6.73E-5 10 +127TE G 280.7 1 0.53 4M1+E2 -0.09 2 0.0407 6 +127TE2 G KC=0.0351 5$LC=0.00445 7$MC=8.88E-4 13 +127TE G 309.4 1 0.076 13M1+E2 0.10 3 0.0316 5 +127TE2 G KC=0.0273 4$LC=0.00345 5$MC=6.87E-4 10 +127TE G 721.5 1 1.77 7E2 0.00309 5 +127TE2 G KC=0.00266 4$LC=3.48E-4 5$MC=6.95E-5 10 +127TE G 782.6 1 14.7 3M1+E2 0.21 1 0.00319 5 +127TE2 G KC=0.00277 4$LC=3.39E-4 5$MC=6.73E-5 10 127TE L 786.13 6 7/2- 127TE B 796 5 7.72 21 7.766 127TES B EAV=264.4 20 -127TE G 154.7 1 0.12 3 M1+E2 0.3 2 0.214 20 -127TE2 G KC=0.182 14$LC=0.026 5$MC=0.0052 11 -127TE G 445.3 1 4.18 11M1+E2 -1.0 5 0.0120 4 -127TE2 G KC=0.0102 4$LC=1369E-6 23$MC=2.74E-4 5 -127TE G 697.9 1 3.36 18E2 0.003365 -127TE2 G KC=0.00289 4$LC=3.80E-4 6$MC=7.59E-5 11 +127TE G 154.7 1 0.12 3M1+E2 0.3 2 0.214 20 +127TE2 G KC=0.182 14$LC=0.026 5$MC=0.0052 11 +127TE G 445.3 1 4.18 11M1+E2 -1.0 5 0.0120 4 +127TE2 G KC=0.0102 4$LC=1369E-6 23$MC=2.74E-4 5 +127TE G 697.9 1 3.36 18E2 0.00336 5 +127TE2 G KC=0.00289 4$LC=3.80E-4 6$MC=7.59E-5 11 127TE L 924.02 187/2+ 127TE B 658 5 1.27 25 8.26 127TES B EAV=211.5 19 -127TE G 292.6 2 0.28 14E1+M2 0.12 13 0.012 7 -127TE2 G KC=0.010 6$LC=0.00136 16$MC=0.00027 18 -127TE G 450.8 2 0.21 7 M1+E2 0.7 5 0.0118 4 -127TE2 G KC=0.0101 4$LC=1318E-6 20$MC=2.63E-4 5 -127TE G 583.2 2 0.32 18E1 0.001873 -127TE2 G KC=1622E-6 23$LC=1.96E-4 3$MC=3.89E-5 6 +127TE G 292.6 2 0.28 14E1+M2 0.12 13 0.012 7 +127TE2 G KC=0.010 6$LC=0.00136 16$MC=0.00027 18 +127TE G 450.8 2 0.21 7M1+E2 0.7 5 0.0118 4 +127TE2 G KC=0.0101 4$LC=1318E-6 20$MC=2.63E-4 5 +127TE G 583.2 2 0.32 18E1 0.00187 3 +127TE2 G KC=1622E-6 23$LC=1.96E-4 3$MC=3.89E-5 6 127TE G 924.0 2 0.460 25E2 1725E-625 -127TE2 G KC=1491E-6 21$LC=1.89E-4 3$MC=3.76E-5 6 +127TE2 G KC=1491E-6 21$LC=1.89E-4 3$MC=3.76E-5 6 127TE L 1077.13 17(5/2,7/2,9/2)+ -127TE B 505 5 5.17 14 7.251 2 +127TE B 505 5 5.17 14 7.251 127TES B EAV=155.3 18 -127TE G 392.0 2 0.92 7 M1+E2 0.15 2 0.0172225 -127TE2 G KC=0.01490 21$LC=0.00187 3$MC=3.72E-4 6 -127TE G 603.9 2 4.21 11M1+E2 0.14 8 0.005929 -127TE2 G KC=0.00513 8$LC=6.34E-4 10$MC=1261E-7 18 +127TE G 392.0 2 0.92 7M1+E2 0.15 2 0.0172225 +127TE2 G KC=0.01490 21$LC=0.00187 3$MC=3.72E-4 6 +127TE G 603.9 2 4.21 11M1+E2 0.14 8 0.00592 9 +127TE2 G KC=0.00513 8$LC=6.34E-4 10$MC=1261E-7 18 127TE L 1140.20 7 5/2+ -127TE B 442 5 1.35 21 7.64 2 +127TE B 442 5 1.35 21 7.64 127TES B EAV=133.2 18 -127TE G 455.1 1 0.11 7 M1+E2 1.0 5 0.0113 4 -127TE2 G KC=0.0097 4$LC=1287E-6 19$MC=2.58E-4 4 -127TE G 638.3 1 0.35 4 M1+E2 -0.42 3 0.005068 -127TE2 G KC=0.00438 7$LC=5.44E-4 8$MC=1083E-7 16 -127TE G 666.9 1 0.53 18M1+E2 1.0 5 0.0042 3 -127TE2 G KC=0.0037 3$LC=4.64E-4 23$MC=9.3E-5 5 -127TE G 1140.2 1 0.35 7 M1+E2 -0.14 12 1358E-623 -127TE2 G KC=1179E-6 20$LC=1427E-7 23$MC=2.83E-5 5 +127TE G 455.1 1 0.11 7M1+E2 1.0 5 0.0113 4 +127TE2 G KC=0.0097 4$LC=1287E-6 19$MC=2.58E-4 4 +127TE G 638.3 1 0.35 4M1+E2 -0.42 3 0.00506 8 +127TE2 G KC=0.00438 7$LC=5.44E-4 8$MC=1083E-7 16 +127TE G 666.9 1 0.53 18M1+E2 1.0 5 0.0042 3 +127TE2 G KC=0.0037 3$LC=4.64E-4 23$MC=9.3E-5 5 +127TE G 1140.2 1 0.35 7M1+E2 -0.14 12 1358E-623 +127TE2 G KC=1179E-6 20$LC=1427E-7 23$MC=2.83E-5 5 127TE L 1154.70 9 5/2+ -127TE B 427 5 0.85 25 7.79 2 +127TE B 427 5 0.85 25 7.79 127TES B EAV=128.2 18 -127TE G 652.8 1 0.28 4 M1+E2 0.24 7 0.004888 -127TE2 G KC=0.00423 7$LC=5.22E-4 8$MC=1038E-7 16 -127TE G 681.4 1 0.53 25M1+E2 1.0 5 0.0040 3 -127TE2 G KC=0.00347 25$LC=4.40E-4 22$MC=8.8E-5 5 +127TE G 652.8 1 0.28 4M1+E2 0.24 7 0.00488 8 +127TE2 G KC=0.00423 7$LC=5.22E-4 8$MC=1038E-7 16 +127TE G 681.4 1 0.53 25M1+E2 1.0 5 0.0040 3 +127TE2 G KC=0.00347 25$LC=4.40E-4 22$MC=8.8E-5 5 127TE G 1153.99 9 0.039 21M1+E2 127TE L 1206.3 7 3/2,5/2+ -127TE B 376 5 0.10 4 8.53 +127TE B 376 5 0.10 4 8.53 2 127TES B EAV=110.7 17 -127TE G 423.7 7 0.10 4 M1+E2 1.0 5 0.0137 4 -127TE2 G KC=0.0117 4$LC=0.00158 4$MC=3.16E-4 9 +127TE G 423.7 7 0.10 4M1+E2 1.0 5 0.0137 4 +127TE2 G KC=0.0117 4$LC=0.00158 4$MC=3.16E-4 9 127TE L 1289.79 8 5/2+ -127TE B 292 5 0.61 4 7.39 2 +127TE B 292 5 0.61 4 7.39 127TES B EAV=83.4 16 -127TE G 816.5 1 0.27 3 M1+E2 1.0 5 0.0026019 -127TE2 G KC=0.00225 17$LC=2.82E-4 17$MC=5.6E-5 4 -127TE G 1288.90 8 0.34 3 M1+E2 0.02 8 1055E-615 -127TE2 G KC=9.01E-4 13$LC=1087E-7 16$MC=2.16E-5 3 +127TE G 816.5 1 0.27 3M1+E2 1.0 5 0.0026019 +127TE2 G KC=0.00225 17$LC=2.82E-4 17$MC=5.6E-5 4 +127TE G 1288.90 8 0.34 3M1+E2 0.02 8 1055E-615 +127TE2 G KC=9.01E-4 13$LC=1087E-7 16$MC=2.16E-5 3 127TE L 1309.25 7 3/2,5/2+ -127TE B 273 5 0.06 2 8.3 +127TE B 273 5 0.06 2 8.3 2 127TES B EAV=77.2 16 -127TE G 624.2 1 0.064 21M1+E2 1.0 5 0.0050 4 -127TE2 G KC=0.0043 3$LC=5.50E-4 24$MC=1.10E-4 5 +127TE G 624.2 1 0.064 21M1+E2 1.0 5 0.0050 4 +127TE2 G KC=0.0043 3$LC=5.50E-4 24$MC=1.10E-4 5 127TE L 1323.4 8 + -127TE B 259 5 0.12 2 7.93 +127TE B 259 5 0.12 2 7.93 127TES B EAV=72.8 16 127TE G 821.5 8 0.117 22 127TE L 1378.58 7 5/2+ -127TE B 203 5 0.18 4 7.42 2 +127TE B 203 5 0.18 4 7.42 127TES B EAV=55.9 15 -127TE G 747.2 1 0.11 4 E1 1093E-616 -127TE2 G KC=9.51E-4 14$LC=1142E-7 16$MC=2.26E-5 4 -127TE G 1378.6 1 0.07 4 M1+E2 +127TE G 747.2 1 0.11 4E1 1093E-616 +127TE2 G KC=9.51E-4 14$LC=1142E-7 16$MC=2.26E-5 4 +127TE G 1378.6 1 0.07 4M1+E2 diff --git a/HEN_HOUSE/spectra/lnhb/Sc-44.txt b/HEN_HOUSE/spectra/lnhb/Sc-44.txt index 70c1f6bce..a7f186c3b 100644 --- a/HEN_HOUSE/spectra/lnhb/Sc-44.txt +++ b/HEN_HOUSE/spectra/lnhb/Sc-44.txt @@ -1,39 +1,39 @@ 44CA 44SC EC DECAY (3.97 H) - 44CA T Auger electrons and ^X ray energies and emission intensities: - 44CA T {U Energy (keV)} {U Intensity } {U Line } + 44CA T Auger electrons and X ray energies and emission intensities: + 44CA T {U Energy (keV)} {U Intensity} {U Line} 44CA T - 44CA T 3.68813 0.255 7 XKA2 - 44CA T 3.69172 0.504 13 XKA1 + 44CA T 3.68813 0.255 7 XKA2 + 44CA T 3.69172 0.504 13 XKA1 44CA T - 44CA T 4.0128 |] 0.098 3 XKB1 - 44CA T 4.0325 |] XKB5II + 44CA T 4.0128 |] 0.098 3 XKB1 + 44CA T 4.0325 |] XKB5II 44CA T 44CA T - 44CA T 0.35-0.412 0.019 4 XL (total) + 44CA T 0.35-0.412 0.019 4 XL (total) 44CA T 0.35 XLL 44CA T -0.412 XLG 44CA T - 44CA T 3.123-3.307 |] KLL AUGER - 44CA T 3.543-3.666 |] 4.21 3 ^KLX AUGER - 44CA T 3.951-3.987 |] KXY AUGER - 44CA T 0.044-0.387 8.71 5 L AUGER + 44CA T 3.123-3.307 |] KLL AUGER + 44CA T 3.543-3.666 |] 4.21 3 KLX AUGER + 44CA T 3.951-3.987 |] KXY AUGER + 44CA T 0.044-0.387 8.71 5 L AUGER 44SC P 0.0 2+ 3.97 H 4 3653.3 19 44CA N 1.0 1.0 1 1.0 44CA L 0 0+ STABLE 44CA L 1157.039 152+ 2.61 PS 14 - 44CA E 94.27 5 4.70 5 5.3 - 44CA2 E EAV=632.0 9$CK=0.8970 19$CL=0.0897 16$CM=0.0133 7$CN= $CO= - 44CA G 1157.020 1599.875 3 E2 6.48E-519 - 44CA2 G KC=5.90E-5 18$LC=4.99E-6 15$MC=8.1E-7 2 + 44CA E 94.27 54.70 55.3 + 44CA2 E EAV=632.0 9$CK=0.8970 19$CL=0.0897 16$CM=0.0133 7 + 44CA G 1157.020 1599.875 3E2 6.48E-519 + 44CA2 G KC=5.90E-5 18$LC=4.99E-6 15$MC=8.1E-7 2 44CA L 2656.530 242+ 30 FS 3 - 44CA E 1.02 2 5.2 - 44CA2 E EAV= $CK=0.8966 19$CL=0.0900 16$CM=0.0134 7$CN= $CO= - 44CA G 1499.46 2 0.908 15M1+E2 0.137 17 3.19E-510 - 44CA2 G KC=2.9E-5 1$LC=2.43E-6 7$MC=4.7E-7 2 - 44CA G 2656.48 7 0.112 3 [E2] + 44CA E 1.02 25.2 + 44CA2 E CK=0.8966 19$CL=0.0900 16$CM=0.0134 7 + 44CA G 1499.460 200.908 15M1+E2 0.137 17 3.19E-510 + 44CA2 G KC=2.9E-5 1$LC=2.43E-6 7$MC=4.7E-7 2 + 44CA G 2656.48 7 0.112 3[E2] 44CA L 3301.46 6 2+ 35 FS 18 44CA E 0.00440 116.6 - 44CA2 E EAV= $CK=0.8954 20$CL=0.0911 16$CM=0.0135 7$CN= $CO= - 44CA G 2144.33 100.0036 7 [M1+E2+] - 44CA G 3301.35 6 0.0017 2 [E2] + 44CA2 E CK=0.8954 20$CL=0.0911 16$CM=0.0135 7 + 44CA G 2144.33 100.0036 7[M1+E2+] + 44CA G 3301.35 6 0.0017 2[E2] diff --git a/HEN_HOUSE/spectra/lnhb/Sc-46.txt b/HEN_HOUSE/spectra/lnhb/Sc-46.txt index d6f668dff..b41dbdfa5 100644 --- a/HEN_HOUSE/spectra/lnhb/Sc-46.txt +++ b/HEN_HOUSE/spectra/lnhb/Sc-46.txt @@ -8,40 +8,40 @@ 46TI3C 1977MeZP, 1979Sc31, 1980Ho17, 1980Ol03, 1980Fu07, 1980RuZY, 1982HoZJ, 46TI4C 1982RuZV, 1983Wa26, 1986Al19, 1992Un01, 1998Si17, 2000He14, 2000Wu08, 46TI5C 2002Ba85, 2004BeZR, 2008Ki07, 2012Fi12, 2012Wa38, 2014Un01 - 46TI T Auger electrons and ^X ray energies and emission intensities: - 46TI T {U Energy (keV)} {U Intensity } {U Line } + 46TI T Auger electrons and X ray energies and emission intensities: + 46TI T {U Energy (keV)} {U Intensity} {U Line} 46TI T - 46TI T 4.50491 0.00155 4 XKA2 - 46TI T 4.5109 0.00306 8 XKA1 + 46TI T 4.50491 0.00155 4 XKA2 + 46TI T 4.5109 0.00306 8 XKA1 46TI T - 46TI T 4.93186 |] 0.000612 18 XKB1 - 46TI T 4.9623 |] XKB5II + 46TI T 4.93186 |] 0.00061218 XKB1 + 46TI T 4.9623 |] XKB5II 46TI T 46TI T - 46TI T 0.3967-0.5614 0.00012 3 XL (total) + 46TI T 0.3967-0.5614 0.00012 3 XL (total) 46TI T 0.3967 XLL 46TI T 0.4556- XLA 46TI T 0.403 XLC 46TI T 0.46072-0.5614 XLB 46TI T 0.46703-0.46703 XLG 46TI T - 46TI T 3.796-4.014 |] KLL AUGER - 46TI T 4.328-4.507 |] 0.01791 22 ^KLX AUGER - 46TI T 4.846-4.959 |] KXY AUGER - 46TI T 0.3349-0.5596 0.002072 22 L AUGER + 46TI T 3.796-4.014 |] KLL AUGER + 46TI T 4.328-4.507 |] 0.01791 22 KLX AUGER + 46TI T 4.846-4.959 |] KXY AUGER + 46TI T 0.3349-0.5596 0.00207222 L AUGER 46SC P 0.0 4+ 83.787 D 16 2366.5 7 46TI N 1.0 1.0 1 1.0 46TI L 0 0+ STABLE 46TI L 889.280 2 2+ 5.32 PS 15 - 46TI B 1477.2 7 0.02 2 12.2 2 + 46TI B 1477.2 7 0.02 2 12.2 2 46TIS B EAV=580.7 3 - 46TI G 889.271 2 99.9837 2 E2 1625E-723 + 46TI G 889.271 2 99.9837425E2 1625E-723 46TI2 G KC=1475E-7 21$LC=1322E-8 19$MC=1690E-9 24 46TI L 2009.832 4 4+ 1.62 PS 10 - 46TI B 356.7 7 99.98 2 6.2 + 46TI B 356.7 7 99.98 2 6.2 46TIS B EAV=111.7 3 - 46TI G 1120.537 3 99.97 2 E2 9.41E-514 + 46TI G 1120.537 3 99.97 2E2 9.41E-514 46TI2 G KC=8.39E-5 12$LC=7.50E-6 11$MC=9.59E-7 14 - 46TI G 2009.785 4 1.3E-5 10E4 6.97E-510 - 46TI2 G KC=6.32E-5 9$LC=5.67E-6 8$MC=7.25E-7 11 + 46TI G 2009.785 4 0.00001310E4 6.97E-510 + 46TI2 G KC=6.32E-5 9$LC=5.67E-6 8$MC=7.25E-7 11 diff --git a/HEN_HOUSE/spectra/lnhb/Sc-47.txt b/HEN_HOUSE/spectra/lnhb/Sc-47.txt index 2b9fa5b39..1f29ca6a2 100644 --- a/HEN_HOUSE/spectra/lnhb/Sc-47.txt +++ b/HEN_HOUSE/spectra/lnhb/Sc-47.txt @@ -5,14 +5,14 @@ 47TI2C 1955LY34, 1955NI15, 1956LI38, 1956GR12, 1959PO64, 1963HO17, 1964MI07, 47TI3C 1967KO01, 1968BA33, 1968ME07, 1969WO02, 1969RA16, 1972GEZG, 1980MO26, 47TI4C 1986RE12, 1996SC06, 2007BU08, 2008KI07, 2012WA38 - 47TI T Auger electrons and ^X ray energies and emission intensities: - 47TI T {U Energy (keV)} {U Intensity } {U Line } + 47TI T Auger electrons and X ray energies and emission intensities: + 47TI T {U Energy (keV)} {U Intensity} {U Line} 47TI T - 47TI T 4.50491 0.0256 9 XKA2 - 47TI T 4.5109 0.0505 16 XKA1 + 47TI T 4.50491 0.0256 9 XKA2 + 47TI T 4.5109 0.0505 16 XKA1 47TI T - 47TI T 4.93186 |] 0.0101 4 XKB1 - 47TI T 4.9623 |] XKB5II + 47TI T 4.93186 |] 0.0101 4 XKB1 + 47TI T 4.9623 |] XKB5II 47TI T 47TI T 47TI T 0.3967 XLL @@ -21,18 +21,18 @@ 47TI T 0.46072-0.5614 XLB 47TI T 0.46703-0.46703 XLG 47TI T - 47TI T 3.79-4.01 |] KLL AUGER - 47TI T 4.33-4.48 |] 0.295 7 ^KLX AUGER - 47TI T 4.83-4.9 |] KXY AUGER - 47TI T 0.3-0.5 0.0349 8 L AUGER + 47TI T 3.79-4.01 |] KLL AUGER + 47TI T 4.33-4.48 |] 0.295 7 KLX AUGER + 47TI T 4.83-4.9 |] KXY AUGER + 47TI T 0.3-0.5 0.0349 8 L AUGER 47SC P 0.0 7/2- 3.3485 D 9 600.8 19 47TI N 1.0 1.0 1 1.0 47TI L 0 5/2- STABLE - 47TI B 600.8 1931.5 5 6.1 2 + 47TI B 600.8 1931.5 5 6.1 47TIS B EAV=204.2 8 47TI L 159.373 127/2- 210 PS 6 - 47TI B 441.4 1968.5 5 5.3 + 47TI B 441.4 1968.5 5 5.3 47TIS B EAV=142.8 7 - 47TI G 159.373 1268.1 5 M1+()E2 -0.099 9 0.0061813 + 47TI G 159.373 1268.1 5M1+()E2 -0.099 9 0.0061813 47TI2 G KC=0.00560 12$LC=5.12E-4 11$MC=6.54E-5 14 diff --git a/HEN_HOUSE/spectra/lnhb/Se-73.txt b/HEN_HOUSE/spectra/lnhb/Se-73.txt index bdf02b20e..99b52a136 100644 --- a/HEN_HOUSE/spectra/lnhb/Se-73.txt +++ b/HEN_HOUSE/spectra/lnhb/Se-73.txt @@ -8,166 +8,166 @@ 73AS5C 1977KeZY, 1978TeZY, 1980Te01, 1988Be39, 1992Sc21, 1995ScZY, 1996Sc06, 73AS6C 1997So08, 1998Sc28, 1998ScZM, 1999ScZX, 2000Sc47, 2002Ba85, 2002Ra45, 73AS7C 2004Si08, 2008Ki07, 2012Wa38 - 73AS T Auger electrons and ^X ray energies and emission intensities: - 73AS T {U Energy (keV)} {U Intensity } {U Line } + 73AS T Auger electrons and X ray energies and emission intensities: + 73AS T {U Energy (keV)} {U Intensity} {U Line} 73AS T - 73AS T 10.50814 8.3 3 XKA2 - 73AS T 10.5438 16.2 6 XKA1 + 73AS T 10.50814 8.3 3 XKA2 + 73AS T 10.5438 16.2 6 XKA1 73AS T - 73AS T 11.7204 |] XKB3 - 73AS T 11.7263 |] 3.70 14 XKB1 - 73AS T 11.821 |] XKB5II + 73AS T 11.7204 |] XKB3 + 73AS T 11.7263 |] 3.70 14 XKB1 + 73AS T 11.821 |] XKB5II 73AS T - 73AS T 11.8643 |] XKB2 - 73AS T |] 0.140 7 XKB4 + 73AS T 11.8643 |] XKB2 + 73AS T |] 0.140 7 XKB4 73AS T - 73AS T 1.12-1.524 1.05 3 XL (total) - 73AS T 1.12 0.027 1 XLL - 73AS T 1.282- 0.613 21 XLA - 73AS T 1.155 0.0152 7 XLC - 73AS T 1.317-1.388 0.397 17 XLB - 73AS T 1.524- 0.00230 9 XLG + 73AS T 1.12-1.524 1.05 3 XL (total) + 73AS T 1.12 0.027 1 XLL + 73AS T 1.282- 0.613 21 XLA + 73AS T 1.155 0.0152 7 XLC + 73AS T 1.317-1.388 0.397 17 XLB + 73AS T 1.524- 0.00230 9 XLG 73AS T - 73AS T 8.746-9.149 |] KLL AUGER - 73AS T 10.114-10.541 |] 21.0 8 ^KLX AUGER - 73AS T 11.46-11.862 |] KXY AUGER - 73AS T 0.9-1.23 65.3 15 L AUGER + 73AS T 8.746-9.149 |] KLL AUGER + 73AS T 10.114-10.541 |] 21.0 8 KLX AUGER + 73AS T 11.46-11.862 |] KXY AUGER + 73AS T 0.9-1.23 65.3 15 L AUGER 73SE P 0.0 9/2+ 7.10 H 9 2725 7 73AS N 1.0 1.0 1 1.0 - 73AS G 600.3 3 0.020 3 - 73AS G 793.0 5 0.064 2 - 73AS G 930.09 150.005 1 + 73AS G 600.3 3 0.020 3 + 73AS G 793.0 5 0.064 2 + 73AS G 930.09 150.005 1 73AS G 1215.4 8 0.063 10 - 73AS G 1249.9 2 0.004 1 - 73AS G 1323.81 200.007 1 - 73AS G 1738.4 5 0.002 1 - 73AS G 1847.8 3 0.008 1 - 73AS G 1889.57 200.003 1 - 73AS G 2023.9 3 0.002 1 - 73AS G 2170.5 3 0.002 1 + 73AS G 1249.9 2 0.004 1 + 73AS G 1323.81 200.007 1 + 73AS G 1738.4 5 0.002 1 + 73AS G 1847.8 3 0.008 1 + 73AS G 1889.57 200.003 1 + 73AS G 2023.9 3 0.002 1 + 73AS G 2170.5 3 0.002 1 73AS L 0 0 3/2- 80.30 D 6 73AS L 67.039 8 5/2- 4.97 NS 7 - 73AS E 0.69 110.51 9 8.7 3U - 73AS2 E EAV=745 3$CK=0.8811 15$CL=0.1000 12$CM=0.0172 4$CN=0.0017 1$CO= - 73AS G 67.039 8 71 7 M1 0.272 4 - 73AS2 G KC=0.241 4$LC=0.0264 4$MC=0.00404 6 + 73AS E 0.69 110.51 98.7 1U + 73AS2 E EAV=745 3$CK=0.8811 15$CL=0.1000 12$CM=0.0172 4$CN=0.0017 1 + 73AS G 67.039 8 71 7M1 0.272 4 + 73AS2 G KC=0.241 4$LC=0.0264 4$MC=0.00404 6 73AS L 427.906 219/2+ 5.75 US 20 - 73AS E 63.9 5 33.3 5 5.36 - 73AS2 E EAV=555 3$CK=0.8810 15$CL=0.1001 12$CM=0.0172 4$CN=0.0017 1$CO= + 73AS E 63.9 533.3 55.36 + 73AS2 E EAV=555 3$CK=0.8810 15$CL=0.1001 12$CM=0.0172 4$CN=0.0017 1 73AS G 360.866 2396.91 20M2+E3 -0.035 10 0.0131519 - 73AS2 G KC=0.01165 17$LC=1286E-6 18$MC=1.97E-4 3 + 73AS2 G KC=0.01165 17$LC=1286E-6 18$MC=1.97E-4 3 73AS G 427.905 210.078 14E3 0.0135719 - 73AS2 G KC=0.01195 17$LC=1397E-6 20$MC=2.13E-4 3 + 73AS2 G KC=0.01195 17$LC=1397E-6 20$MC=2.13E-4 3 73AS L 510.055 17(5/2)+ - 73AS G 443.015 190.050 3 (E1) 1037E-615 + 73AS G 443.015 190.050 3(E1) 1037E-615 73AS2 G KC=9.26E-4 13$LC=9.55E-5 14$MC=1454E-8 21 - 73AS G 510.053 170.26 3 (E1) 7.28E-411 - 73AS2 G KC=0.00065 1$LC=6.7E-5 1$MC=1020E-8 15 + 73AS G 510.053 170.26 3(E1) 7.28E-411 + 73AS2 G KC=0.00065 1$LC=6.7E-5 1$MC=1020E-8 15 73AS L 993.766 12(7/2)- - 73AS G 926.721 140.004 1 (M1+E2) - 73AS G 993.759 120.005 1 (E2) 3.92E-46 - 73AS2 G KC=3.50E-4 5$LC=3.63E-5 5$MC=5.52E-6 8 + 73AS G 926.721 140.004 1(M1+E2) + 73AS G 993.759 120.005 1(E2) 3.92E-4 6 + 73AS2 G KC=3.50E-4 5$LC=3.63E-5 5$MC=5.52E-6 8 73AS L 1037.13 3 (13/2)+ - 73AS G 609.22 4 0.049 4 (E2) 1412E-620 - 73AS2 G KC=1258E-6 18$LC=1327E-7 19$MC=2.02E-5 3 + 73AS G 609.22 4 0.049 4(E2) 1412E-620 + 73AS2 G KC=1258E-6 18$LC=1327E-7 19$MC=2.02E-5 3 73AS L 1178.052 21(7/2)- - 73AS E 0.017 1 0.178 2 7.3 1U - 73AS2 E EAV=228 3$CK=0.8805 15$CL=0.1005 12$CM=0.0173 4$CN=0.0017 1$CO= - 73AS G 1111.004 230.201 2 (M1+E2) + 73AS E 0.017 10.178 27.3 1 + 73AS2 E EAV=228 3$CK=0.8805 15$CL=0.1005 12$CM=0.0173 4$CN=0.0017 1 + 73AS G 1111.004 230.201 2(M1+E2) 73AS L 1275.14 7 (7/2)+ - 73AS E 0.0003 1 0.0057 198.7 2 - 73AS2 E EAV=187 3$CK=0.8804 15$CL=0.1006 12$CM=0.0173 4$CN=0.0017 1$CO= - 73AS G 765.09 7 0.127 2 (M1+E2) - 73AS G 847.22 7 0.078 6 (M1+E2) - 73AS G 1208.09 7 0.004 1 (E1) 1700E-724 + 73AS E 0.0003 10.0057 198.7 + 73AS2 E EAV=187 3$CK=0.8804 15$CL=0.1006 12$CM=0.0173 4$CN=0.0017 1 + 73AS G 765.09 7 0.127 2(M1+E2) + 73AS G 847.22 7 0.078 6(M1+E2) + 73AS G 1208.09 7 0.004 1(E1) 1700E-724 73AS2 G KC=1050E-7 15$LC=1072E-8 15$MC=1632E-9 23 - 73AS G 1275.13 7 0.007 1 (M2) 4.46E-47 - 73AS2 G KC=3.94E-4 6$LC=4.08E-5 6$MC=6.23E-6 9 + 73AS G 1275.13 7 0.007 1(M2) 4.46E-4 7 + 73AS2 G KC=3.94E-4 6$LC=4.08E-5 6$MC=6.23E-6 9 73AS L 1293.09 10(11/2)+ - 73AS E 0.017 2 0.435 196.8 2 - 73AS2 E EAV=179 3$CK=0.8804 15$CL=0.1006 12$CM=0.0173 4$CN=0.0017 1$CO= - 73AS G 865.17 100.50 2 (M1+E2) + 73AS E 0.017 20.435 196.8 + 73AS2 E EAV=179 3$CK=0.8804 15$CL=0.1006 12$CM=0.0173 4$CN=0.0017 1 + 73AS G 865.17 100.50 2(M1+E2) 73AS L 1293.37 3 (7/2)+ - 73AS G 783.32 4 0.058 2 (M1+E2) - 73AS G 865.45 3 0.02 1 (M1+E2) - 73AS G 1226.32 3 0.003 2 (E1) 1.79E-43 + 73AS G 783.32 4 0.058 2(M1+E2) + 73AS G 865.45 3 0.02 1(M1+E2) + 73AS G 1226.32 3 0.003 2(E1) 1.79E-4 3 73AS2 G KC=1023E-7 15$LC=1043E-8 15$MC=1589E-9 23 73AS L 1328.89 5 (7/2,9/2)+ - 73AS E 0.0034 2 0.129 3 7.3 2 - 73AS2 E EAV=164 3$CK=0.8804 15$CL=0.1006 12$CM=0.0173 4$CN=0.0017 1$CO= - 73AS G 818.84 5 0.036 2 (M1+E2) - 73AS G 900.97 5 0.135 2 (M1+E2) + 73AS E 0.0034 20.129 37.3 + 73AS2 E EAV=164 3$CK=0.8804 15$CL=0.1006 12$CM=0.0173 4$CN=0.0017 1 + 73AS G 818.84 5 0.036 2(M1+E2) + 73AS G 900.97 5 0.135 2(M1+E2) 73AS L 1850.59 5 (9/2)+ 73AS E 0.433 116.4 - 73AS2 E EAV= $CK=0.8794 15$CL=0.1014 12$CM=0.0175 4$CN=0.0017 1$CO= - 73AS G 557.50 110.052 2 (M1+E2) - 73AS G 575.45 9 0.146 7 (M1+E2) - 73AS G 813.46 6 0.009 1 (E2) 6.42E-49 - 73AS2 G KC=5.73E-4 8$LC=5.97E-5 9$MC=9.10E-6 13 - 73AS G 856.81 5 0.023 6 (E1) 2.27E-44 - 73AS2 G KC=2.03E-4 3$LC=2.07E-5 3$MC=3.16E-6 5 - 73AS G 1340.53 5 0.069 2 (E2) 2.39E-44 - 73AS2 G KC=1.80E-4 3$LC=1.85E-5 3$MC=2.82E-6 4 - 73AS G 1422.67 6 0.135 5 (M1+E2) + 73AS2 E CK=0.8794 15$CL=0.1014 12$CM=0.0175 4$CN=0.0017 1 + 73AS G 557.50 110.052 2(M1+E2) + 73AS G 575.45 9 0.146 7(M1+E2) + 73AS G 813.46 6 0.009 1(E2) 6.42E-4 9 + 73AS2 G KC=5.73E-4 8$LC=5.97E-5 9$MC=9.10E-6 13 + 73AS G 856.81 5 0.023 6(E1) 2.27E-4 4 + 73AS2 G KC=2.03E-4 3$LC=2.07E-5 3$MC=3.16E-6 5 + 73AS G 1340.53 5 0.069 2(E2) 2.39E-4 4 + 73AS2 G KC=1.80E-4 3$LC=1.85E-5 3$MC=2.82E-6 4 + 73AS G 1422.67 6 0.135 5(M1+E2) 73AS L 1910.13 12(9/2,11/2)+ - 73AS E 0.060 7 7.2 - 73AS2 E EAV= $CK=0.8792 15$CL=0.1016 13$CM=0.0175 4$CN=0.0017 1$CO= - 73AS G 872.99 120.038 7 (E2) 5.37E-48 - 73AS2 G KC=4.79E-4 7$LC=4.99E-5 7$MC=7.60E-6 11 - 73AS G 1482.20 6 0.022 1 (M1+E2) + 73AS E 0.060 77.2 + 73AS2 E CK=0.8792 15$CL=0.1016 13$CM=0.0175 4$CN=0.0017 1 + 73AS G 872.99 120.038 7(E2) 5.37E-4 8 + 73AS2 G KC=4.79E-4 7$LC=4.99E-5 7$MC=7.60E-6 11 + 73AS G 1482.20 6 0.022 1(M1+E2) 73AS L 1961.8 2 (3/2,5/2,7/2)+ - 73AS E 0.017 5 7.7 - 73AS2 E EAV= $CK=0.8790 15$CL=0.1017 13$CM=0.0176 4$CN=0.0017 1$CO= - 73AS G 968.0 2 0.012 5 - 73AS G 1451.7 2 0.006 2 + 73AS E 0.017 57.7 2U + 73AS2 E CK=0.8790 15$CL=0.1017 13$CM=0.0176 4$CN=0.0017 1 + 73AS G 968.0 2 0.012 5 + 73AS G 1451.7 2 0.006 2 73AS L 1975.41 11(7/2,9/2,11/2)+ - 73AS E 0.094 3 6.9 2 - 73AS2 E EAV= $CK=0.8789 15$CL=0.1018 13$CM=0.0176 4$CN=0.0017 1$CO= - 73AS G 682.04 110.019 2 (E1) 3.69E-46 - 73AS2 G KC=3.30E-4 5$LC=3.38E-5 5$MC=5.15E-6 8 - 73AS G 700.27 130.044 2 (M1+E2) - 73AS G 1547.48 110.031 1 (M1+E2) + 73AS E 0.094 36.9 + 73AS2 E CK=0.8789 15$CL=0.1018 13$CM=0.0176 4$CN=0.0017 1 + 73AS G 682.04 110.019 2(E1) 3.69E-4 6 + 73AS2 G KC=3.30E-4 5$LC=3.38E-5 5$MC=5.15E-6 8 + 73AS G 700.27 130.044 2(M1+E2) + 73AS G 1547.48 110.031 1(M1+E2) 73AS L 2180.66 10(7/2,9/2)+ - 73AS E 0.030 8 7.1 2 - 73AS2 E EAV= $CK=0.8778 15$CL=0.1027 13$CM=0.0178 4$CN=0.0017 1$CO= - 73AS G 887.28 100.011 8 (M1+E2) - 73AS G 1002.6 1 0.004 1 (E1) 1660E-724 - 73AS2 G KC=1484E-7 21$LC=1517E-8 22$MC=2.31E-6 4 - 73AS G 1670.59 100.005 1 (M1+E2) - 73AS G 1752.73 100.011 1 (M1+E2) + 73AS E 0.030 87.1 + 73AS2 E CK=0.8778 15$CL=0.1027 13$CM=0.0178 4$CN=0.0017 1 + 73AS G 887.28 100.011 8(M1+E2) + 73AS G 1002.60 100.004 1(E1) 1660E-724 + 73AS2 G KC=1484E-7 21$LC=1517E-8 22$MC=2.31E-6 4 + 73AS G 1670.59 100.005 1(M1+E2) + 73AS G 1752.73 100.011 1(M1+E2) 73AS L 2311.63 6 (7/2,9/2)+ - 73AS E 0.157 6 6.2 2 - 73AS2 E EAV= $CK=0.8764 16$CL=0.1038 13$CM=0.0180 4$CN=0.0018 1$CO= - 73AS G 982.73 8 0.034 1 (M1+E2) - 73AS G 1018.25 7 0.053 2 (M1+E2) - 73AS G 1036.48 9 0.015 1 (M1+E2) - 73AS G 1317.85 6 0.006 1 (E1) 2.27E-44 - 73AS2 G KC=9.02E-5 13$LC=9.19E-6 13$MC=1.40E-6 2 - 73AS G 1801.56 6 0.019 5 (M1+E2) - 73AS G 1883.69 6 0.030 2 (M1+E2) + 73AS E 0.157 66.2 + 73AS2 E CK=0.8764 16$CL=0.1038 13$CM=0.0180 4$CN=0.0018 1 + 73AS G 982.73 8 0.034 1(M1+E2) + 73AS G 1018.25 7 0.053 2(M1+E2) + 73AS G 1036.48 9 0.015 1(M1+E2) + 73AS G 1317.85 6 0.006 1(E1) 2.27E-4 4 + 73AS2 G KC=9.02E-5 13$LC=9.19E-6 13$MC=1.40E-6 2 + 73AS G 1801.56 6 0.019 5(M1+E2) + 73AS G 1883.69 6 0.030 2(M1+E2) 73AS L 2434.1 4 3/2,5/2+ - 73AS E 0.0048 197.4 - 73AS2 E EAV= $CK=0.8740 16$CL=0.1058 13$CM=0.0184 4$CN=0.0018 1$CO= - 73AS G 1159.0 4 0.003 1 - 73AS G 2006.2 4 0.002 1 + 73AS E 0.0048 197.4 2U + 73AS2 E CK=0.8740 16$CL=0.1058 13$CM=0.0184 4$CN=0.0018 1 + 73AS G 1159.0 4 0.003 1 + 73AS G 2006.2 4 0.002 1 73AS L 2476.1 2 (11/2,15/2)+ - 73AS E 0.0029 107.5 2 - 73AS2 E EAV= $CK=0.8726 16$CL=0.1070 13$CM=0.0186 4$CN=0.0018 2$CO= - 73AS G 1439.0 2 0.002 1 - 73AS G 2048.2 2 0.001 1 + 73AS E 0.0029 107.5 + 73AS2 E CK=0.8726 16$CL=0.1070 13$CM=0.0186 4$CN=0.0018 2 + 73AS G 1439.0 2 0.002 1 + 73AS G 2048.2 2 0.001 1 73AS L 2482.87 23(7/2,9/2)+ - 73AS E 0.0087 207 2 - 73AS2 E EAV= $CK=0.8723 16$CL=0.1072 13$CM=0.0186 4$CN=0.0018 2$CO= - 73AS G 1153.97 240.005 1 (M1+E2) - 73AS G 1972.79 230.001 1 (M1+E2) - 73AS G 2054.93 230.003 1 (M1+E2) + 73AS E 0.0087 207 + 73AS2 E CK=0.8723 16$CL=0.1072 13$CM=0.0186 4$CN=0.0018 2 + 73AS G 1153.97 240.005 1(M1+E2) + 73AS G 1972.79 230.001 1(M1+E2) + 73AS G 2054.93 230.003 1(M1+E2) 73AS L 2584.09 11(7/2,9/2)- - 73AS E 0.0155 206.2 1U - 73AS2 E EAV= $CK=0.8646 19$CL=0.1136 16$CM=0.0199 5$CN=0.0020 2$CO= - 73AS G 1308.94 130.004 1 (E1) 2.22E-44 + 73AS E 0.0155 206.2 1 + 73AS2 E CK=0.8646 19$CL=0.1136 16$CM=0.0199 5$CN=0.0020 2 + 73AS G 1308.94 130.004 1(E1) 2.22E-4 4 73AS2 G KC=9.12E-5 13$LC=9.30E-6 13$MC=1417E-9 20 - 73AS G 1406.03 110.002 1 (M1+E2) - 73AS G 2156.15 110.005 1 (E1) 7.85E-411 - 73AS2 G KC=4.13E-5 6$LC=4.19E-6 6$MC=6.38E-7 9 - 73AS G 2517.00 110.005 1 (M1+E2) + 73AS G 1406.03 110.002 1(M1+E2) + 73AS G 2156.15 110.005 1(E1) 7.85E-411 + 73AS2 G KC=4.13E-5 6$LC=4.19E-6 6$MC=6.38E-7 9 + 73AS G 2517.00 110.005 1(M1+E2) diff --git a/HEN_HOUSE/spectra/lnhb/Se-75.txt b/HEN_HOUSE/spectra/lnhb/Se-75.txt index de5cd44c1..2ed86ba6c 100644 --- a/HEN_HOUSE/spectra/lnhb/Se-75.txt +++ b/HEN_HOUSE/spectra/lnhb/Se-75.txt @@ -12,97 +12,97 @@ 75AS5C 1983Si25, 1983Yo03, 1984Si02, 1987JeZZ, 1990Wa03, 1990Me15, 1990Je01, 75AS6C 1990An07, 1991BaZS, 1992Sc09, 1994Iw04, 1994Mi22, 1996Sa22, 1996Sc06, 75AS7C 1997Lo10, 1999Fa05, 2002Un02, 2002He19, 2003Au03, 2005Ra29, 2008Ki07 - 75AS T Auger electrons and ^X ray energies and emission intensities: - 75AS T {U Energy (keV)} {U Intensity } {U Line } + 75AS T Auger electrons and X ray energies and emission intensities: + 75AS T {U Energy (keV)} {U Intensity} {U Line} 75AS T - 75AS T 10.50814 16.5 6 XKA2 - 75AS T 10.5438 31.9 11 XKA1 + 75AS T 10.50814 16.5 6 XKA2 + 75AS T 10.5438 31.9 11 XKA1 75AS T - 75AS T 11.7204 |] XKB3 - 75AS T 11.7263 |] 7.30 25 XKB1 - 75AS T 11.821 |] XKB5II + 75AS T 11.7204 |] XKB3 + 75AS T 11.7263 |] 7.30 25 XKB1 + 75AS T 11.821 |] XKB5II 75AS T - 75AS T 11.8643 |] XKB2 - 75AS T |] 0.276 13 XKB4 + 75AS T 11.8643 |] XKB2 + 75AS T |] 0.276 13 XKB4 75AS T - 75AS T 1.1195-1.5312 1.93 5 XL (total) - 75AS T 1.1195 0.0489 18 XLL - 75AS T 1.2816-1.2824 1.11 4 XLA - 75AS T 1.1552 0.0287 12 XLC - 75AS T 1.3152-1.4892 0.742 30 XLB - 75AS T 1.3508-1.5312 0.00393 15 XLG + 75AS T 1.1195-1.5312 1.93 5 XL (total) + 75AS T 1.1195 0.0489 18 XLL + 75AS T 1.2816-1.2824 1.11 4 XLA + 75AS T 1.1552 0.0287 12 XLC + 75AS T 1.3152-1.4892 0.742 30 XLB + 75AS T 1.3508-1.5312 0.00393 15 XLG 75AS T - 75AS T 8.75-9.1 |] KLL AUGER - 75AS T 10.12-10.54 |] 41.4 14 ^KLX AUGER - 75AS T 11.44-11.8 |] KXY AUGER - 75AS T 1.1-1.3 119.6 15 L AUGER + 75AS T 8.75-9.1 |] KLL AUGER + 75AS T 10.12-10.54 |] 41.4 14 KLX AUGER + 75AS T 11.44-11.8 |] KXY AUGER + 75AS T 1.1-1.3 119.6 15 L AUGER 75SE P 0.0 5/2+ 119.781 D 24 863.6 8 75AS N 1.0 1.0 1 1.0 75AS L 0 3/2- STABLE - 75AS E 1.42 228.5 1U - 75AS2 E EAV= $CK=0.8794 15$CL=0.1014 12$CM=0.0175 4$CN=0.0017 1$CO=0 0 + 75AS E 1.42 228.5 1 + 75AS2 E CK=0.8794 15$CL=0.1014 12$CM=0.0175 4$CN=0.0017 1$CO=0 0 75AS L 198.6063 131/2- 0.885 NS 21 - 75AS G 198.6060 121.46 6 M1+E2 0.315 39 0.0189 11 - 75AS2 G KC=0.0167 9$LC=0.00182 11$MC=2.77E-4 16 + 75AS G 198.6060 121.46 6M1+E2 0.315 39 0.0189 11 + 75AS2 G KC=0.0167 9$LC=0.00182 11$MC=2.77E-4 16 75AS L 264.6581 103/2- 0.0112 NS 3 - 75AS E 1.4 2 8.2 1U - 75AS2 E EAV= $CK=0.8782 15$CL=0.1024 13$CM=0.0177 4$CN=0.0017 1$CO=0 0 - 75AS G 66.0518 8 1.085 35M1+E2 0.121 33 0.33 3 - 75AS2 G KC=0.29 3$LC=0.034 5$MC=0.0052 7 - 75AS G 264.6576 9 58.75 19M1+E2 -0.095 70 0.0072 3 - 75AS2 G KC=0.00646 25$LC=0.00068 3$MC=1.04E-4 5 + 75AS E 1.4 28.2 1 + 75AS2 E CK=0.8782 15$CL=0.1024 13$CM=0.0177 4$CN=0.0017 1$CO=0 0 + 75AS G 66.0518 8 1.085 35M1+E2 0.121 33 0.33 3 + 75AS2 G KC=0.29 3$LC=0.034 5$MC=0.0052 7 + 75AS G 264.6576 9 58.75 19M1+E2 -0.095 70 0.0072 3 + 75AS2 G KC=0.00646 25$LC=0.00068 3$MC=1.04E-4 5 75AS L 279.5428 115/2- 0.273 NS 3 75AS E 2.1 148 - 75AS2 E EAV= $CK=0.8781 15$CL=0.1025 13$CM=0.0177 4$CN=0.0017 1$CO=0 0 - 75AS G 14.8847 130.0206 6 M1(+E2) - 75AS G 80.9365 150.0095 5 [E2] 1.736 25 - 75AS2 G KC=1.486 21$LC=0.216 3$MC=0.0326 5 - 75AS G 279.5422 1024.89 9 M1+E2 -0.578 44 0.0091 4 - 75AS2 G KC=0.0081 4$LC=0.00087 4$MC=1.33E-4 6 + 75AS2 E CK=0.8781 15$CL=0.1025 13$CM=0.0177 4$CN=0.0017 1$CO=0 0 + 75AS G 14.8847 130.0206 6M1(+E2) + 75AS G 80.9365 150.0095 5[E2] 1.736 25 + 75AS2 G KC=1.486 21$LC=0.216 3$MC=0.0326 5 + 75AS G 279.5422 1024.89 9M1+E2 -0.578 44 0.0091 4 + 75AS2 G KC=0.0081 4$LC=0.00087 4$MC=1.33E-4 6 75AS L 303.9243 119/2+ 17.62 MS 23 - 75AS G 24.3815 140.027 6 M2 204 3 - 75AS2 G KC=165 24$LC=32.6 5$MC=5.13 10 - 75AS G 303.9236 101.308 5 E3 0.0538 8 - 75AS2 G KC=0.0469 7$LC=0.00592 9$MC=8.99E-4 13 + 75AS G 24.3815 140.027 6M2 204 3 + 75AS2 G KC=165 24$LC=32.6 5$MC=5.13 10 + 75AS G 303.9236 101.308 5E3 0.0538 8 + 75AS2 G KC=0.0469 7$LC=0.00592 9$MC=8.99E-4 13 75AS L 400.6585 8 5/2++ 1.67 NS 5 75AS E 94.5 216.1 - 75AS2 E EAV= $CK=0.8770 16$CL=0.1033 13$CM=0.0179 4$CN=0.0018 1$CO=0 0 - 75AS G 96.7340 9 3.35 7 E2 0.893 13 + 75AS2 E CK=0.8770 16$CL=0.1033 13$CM=0.0179 4$CN=0.0018 1$CO=0 0 + 75AS G 96.7340 9 3.35 7E2 0.893 13 75AS2 G KC=0.772 11$LC=0.1044 15$MC=0.01576 22 - 75AS G 121.1155 1116.86 36E1 0.0417 6 - 75AS2 G KC=0.0372 6$LC=0.00388 6$MC=5.88E-4 9 - 75AS G 136.0001 6 57.7 20E1 0.0295 5 - 75AS2 G KC=0.0263 4$LC=0.00274 4$MC=4.15E-4 6 + 75AS G 121.1155 1116.86 36E1 0.0417 6 + 75AS2 G KC=0.0372 6$LC=0.00388 6$MC=5.88E-4 9 + 75AS G 136.0001 6 57.7 20E1 0.0295 5 + 75AS2 G KC=0.0263 4$LC=0.00274 4$MC=4.15E-4 6 75AS G 400.6572 8 11.388 42E1 1346E-619 - 75AS2 G KC=1202E-6 17$LC=1241E-7 18$MC=1.89E-5 3 + 75AS2 G KC=1202E-6 17$LC=1241E-7 18$MC=1.89E-5 3 75AS L 468.6 4 1/2,3/2- - 75AS E 0.00036 5 11.1 3U - 75AS2 E EAV= $CK=0.8762 16$CL=0.1041 13$CM=0.0180 4$CN=0.0018 1$CO=0 0 - 75AS G 468.6 4 0.00036 5 [M1E2] 0.0025 7 - 75AS2 G KC=0.0022 6$LC=0.00023 7$MC=3.5E-5 10 + 75AS E 0.00036 511.1 1U + 75AS2 E CK=0.8762 16$CL=0.1041 13$CM=0.0180 4$CN=0.0018 1$CO=0 0 + 75AS G 468.6 4 0.00036 5[M1E2] 0.0025 7 + 75AS2 G KC=0.0022 6$LC=0.00023 7$MC=3.5E-5 10 75AS L 572.22 245/2- 2.9 PS 3 75AS E 0.03484 359.1 - 75AS2 E EAV= $CK=0.8740 16$CL=0.1058 13$CM=0.0184 4$CN=0.0018 1$CO=0 0 + 75AS2 E CK=0.8740 16$CL=0.1058 13$CM=0.0184 4$CN=0.0018 1$CO=0 0 75AS G 373.61 240.00256 11[E2] 0.0065310 - 75AS2 G KC=0.00580 9$LC=6.28E-4 9$MC=9.54E-5 14 + 75AS2 G KC=0.00580 9$LC=6.28E-4 9$MC=9.54E-5 14 75AS G 572.22 240.03622 31M1+E2 0.19 1 1165E-617 75AS2 G KC=1040E-6 15$LC=1079E-7 16$MC=1646E-8 24 75AS L 617.7 4 1/2,3/2- - 75AS E 0.0126 6 8.8 3U - 75AS2 E EAV= $CK=0.8724 16$CL=0.1071 13$CM=0.0186 4$CN=0.0018 2$CO=0 0 - 75AS G 419.1 4 0.0121 6 [M1E2] 0.0034 11 - 75AS2 G KC=0.003 1$LC=0.00032 11$MC=4.9E-5 16 - 75AS G 617.8 4 0.00453 5 [M1E2] 0.0011620 - 75AS2 G KC=0.00103 18$LC=1.08E-4 20$MC=1.7E-5 3 + 75AS E 0.0126 68.8 1U + 75AS2 E CK=0.8724 16$CL=0.1071 13$CM=0.0186 4$CN=0.0018 2$CO=0 0 + 75AS G 419.1 4 0.0121 6[M1E2] 0.0034 11 + 75AS2 G KC=0.003 1$LC=0.00032 11$MC=4.9E-5 16 + 75AS G 617.8 4 0.00453 5[M1E2] 0.0011620 + 75AS2 G KC=0.00103 18$LC=1.08E-4 20$MC=1.7E-5 3 75AS L 821.6 2 7/2- 3.0 PS 3 - 75AS E 0.00734 187.9 1U - 75AS2 E EAV= $CK=0.8038 32$CL=0.1633 26$CM=0.0300 8$CN=0.0030 2$CO=0 0 + 75AS E 0.00734 187.9 1 + 75AS2 E CK=0.8038 32$CL=0.1633 26$CM=0.0300 8$CN=0.0030 2$CO=0 0 75AS G 249.3 3 0.00394 12[M1E2] 0.017 10 - 75AS2 G KC=0.015 9$LC=0.0017 10$MC=0.00026 15 - 75AS G 542.02 184.35E-4 6 [M1E2] 0.0016 4 - 75AS2 G KC=0.0015 3$LC=0.00015 4$MC=2.3E-5 6 - 75AS G 557.8 9 0.00276 12[E2] 0.001833 - 75AS2 G KC=1628E-6 25$LC=1.72E-4 3$MC=2.62E-5 4 - 75AS G 821.56 181.34E-4 8 [E2] 6.26E-49 - 75AS2 G KC=5.58E-4 8$LC=5.82E-5 9$MC=8.87E-6 13 + 75AS2 G KC=0.015 9$LC=0.0017 10$MC=0.00026 15 + 75AS G 542.02 180.000435 6[M1E2] 0.0016 4 + 75AS2 G KC=0.0015 3$LC=0.00015 4$MC=2.3E-5 6 + 75AS G 557.8 9 0.00276 12[E2] 0.00183 3 + 75AS2 G KC=1628E-6 25$LC=1.72E-4 3$MC=2.62E-5 4 + 75AS G 821.56 180.000134 8[E2] 6.26E-4 9 + 75AS2 G KC=5.58E-4 8$LC=5.82E-5 9$MC=8.87E-6 13 diff --git a/HEN_HOUSE/spectra/lnhb/Se-79.txt b/HEN_HOUSE/spectra/lnhb/Se-79.txt index a2d381e2e..1d9b9c303 100644 --- a/HEN_HOUSE/spectra/lnhb/Se-79.txt +++ b/HEN_HOUSE/spectra/lnhb/Se-79.txt @@ -1,21 +1,21 @@ 79BR 79SE B- DECAY (3.56E5 Y) 79BR H TYP=Full$AUT=M.-M. Bé$CUT=30-JAN-2006$ 79BR C Evaluation history: Type=Full;Author=M.-M. Bé;Cutoff date=30-JAN-2006 - 79BR T Auger electrons and ^X ray energies and emission intensities: - 79BR T {U Energy (keV)} {U Intensity } {U Line } + 79BR T Auger electrons and X ray energies and emission intensities: + 79BR T {U Energy (keV)} {U Intensity} {U Line} 79BR T 79BR T 11.8778 XKA2 79BR T 11.9244 XKA1 79BR T - 79BR T 13.2847 |] XKB3 - 79BR T 13.2916 |] XKB1 - 79BR T 13.396 |] XKB5II + 79BR T 13.2847 |] XKB3 + 79BR T 13.2916 |] XKB1 + 79BR T 13.396 |] XKB5II 79BR T - 79BR T 13.4696 |] XKB2 + 79BR T 13.4696 |] XKB2 79BR T 79SE P 0.0 7/2+ 3.56E5 Y 40 150.9 17 79BR N 1.0 1.0 1 1.0 79BR L 0 3/2- STABLE - 79BR B 150.9 17100 10.81 3U + 79BR B 150.9 17100 10.81 1U 79BRS B EAV=52.9 6 diff --git a/HEN_HOUSE/spectra/lnhb/Sm-151.txt b/HEN_HOUSE/spectra/lnhb/Sm-151.txt index 3470d120e..e23e483f6 100644 --- a/HEN_HOUSE/spectra/lnhb/Sm-151.txt +++ b/HEN_HOUSE/spectra/lnhb/Sm-151.txt @@ -5,39 +5,39 @@ 151EU2C 1966Av05, 1968Re04, 1968Gr25, 1970Fo02, 1970An17, 1971Ca44, 1975La20, 151EU3C 1975Fr01, 1977Ve01, 1980La02, 1981Ar17, 1981Un02, 2008Ki07, 2009He22, 151EU4C 2012Wa38, 2015Bé** -151EU T Auger electrons and ^X ray energies and emission intensities: -151EU T {U Energy (keV)} {U Intensity } {U Line } +151EU T Auger electrons and X ray energies and emission intensities: +151EU T {U Energy (keV)} {U Intensity} {U Line} 151EU T 151EU T 40.9024 XKA2 151EU T 41.5427 XKA1 151EU T -151EU T 46.904 |] XKB3 -151EU T 47.0384 |] XKB1 -151EU T 47.373 |] XKB5II +151EU T 46.904 |] XKB3 +151EU T 47.0384 |] XKB1 +151EU T 47.373 |] XKB5II 151EU T -151EU T 48.257 |] XKB2 -151EU T 48.386 |] XKB4 -151EU T 48.497 |] XKO23 +151EU T 48.257 |] XKB2 +151EU T 48.386 |] XKB4 +151EU T 48.497 |] XKO23 151EU T -151EU T 5.175-7.791 0.121 4 XL (total) -151EU T 5.175 0.00140 7 XLL -151EU T 5.815-5.846 0.0343 15 XLA -151EU T 5.815 0.00074 4 XLC -151EU T 6.436-6.839 0.0695 19 XLB -151EU T 7.254-7.791 0.0154 4 XLG +151EU T 5.175-7.791 0.121 4 XL (total) +151EU T 5.175 0.00140 7 XLL +151EU T 5.815-5.846 0.0343 15 XLA +151EU T 5.815 0.00074 4 XLC +151EU T 6.436-6.839 0.0695 19 XLB +151EU T 7.254-7.791 0.0154 4 XLG 151EU T -151EU T 32.241-34.378 |] KLL AUGER -151EU T 38.592-41.52 |] ^KLX AUGER -151EU T 44.92-48.48 |] KXY AUGER -151EU T 3.377-7.786 0.581 19 L AUGER +151EU T 32.241-34.378 |] KLL AUGER +151EU T 38.592-41.52 |] KLX AUGER +151EU T 44.92-48.48 |] KXY AUGER +151EU T 3.377-7.786 0.581 19 L AUGER 151SM P 0.0 5/2- 94.7 Y 6 76.4 5 151EU N 1.0 1.0 1 1.0 151EU L 0 5/2+ STABLE -151EU B 76.4 5 99.07 4 9 +151EU B 76.4 5 99.07 4 9 151EUS B EAV=19.7 2 151EU L 21.541 3 7/2+ 9.6 NS 3 -151EU B 54.9 5 0.93 4 7.5 1U +151EU B 54.9 5 0.93 4 7.5 1 151EUS B EAV=14.0 2 -151EU G 21.541 3 0.0324 13M1+()E2 0.029 2 27.6 5 -151EU2 G KC=$LC=21.7 4$MC=4.71 8 +151EU G 21.541 3 0.0324 13M1+()E2 0.029 2 27.6 5 +151EU2 G LC=21.7 4$MC=4.71 8 diff --git a/HEN_HOUSE/spectra/lnhb/Sm-153.txt b/HEN_HOUSE/spectra/lnhb/Sm-153.txt index 695a48eec..e3a43a742 100644 --- a/HEN_HOUSE/spectra/lnhb/Sm-153.txt +++ b/HEN_HOUSE/spectra/lnhb/Sm-153.txt @@ -5,164 +5,164 @@ 153EU C Evaluation history: Type=Update;Author=mmbe;Cutoff date= -- 153EU2C Type=Update;Author=mmbe;Cutoff date= -- 153EU3C Type=Full;Author=mmbe;Cutoff date=01-JUN-2005 -153EU T Auger electrons and ^X ray energies and emission intensities: -153EU T {U Energy (keV)} {U Intensity } {U Line } +153EU T Auger electrons and X ray energies and emission intensities: +153EU T {U Energy (keV)} {U Intensity} {U Line} 153EU T -153EU T 40.9024 16.6 4 XKA2 -153EU T 41.5427 30.0 7 XKA1 +153EU T 40.9024 16.6 4 XKA2 +153EU T 41.5427 30.0 7 XKA1 153EU T -153EU T 46.904 |] XKB3 -153EU T 47.0384 |] 9.45 25 XKB1 -153EU T 47.373 |] XKB5II +153EU T 46.904 |] XKB3 +153EU T 47.0384 |] 9.45 25 XKB1 +153EU T 47.373 |] XKB5II 153EU T -153EU T 48.257 |] XKB2 -153EU T 48.386 |] 2.44 8 XKB4 -153EU T 48.497 |] XKO23 +153EU T 48.257 |] XKB2 +153EU T 48.386 |] 2.44 8 XKB4 +153EU T 48.497 |] XKO23 153EU T -153EU T 5.175-7.791 10.88 21 XL (total) -153EU T 5.175 0.213 7 XLL -153EU T 5.815-5.8461 5.20 15 XLA -153EU T 5.8149 0.0825 25 XLC -153EU T 6.4365-6.9193 4.63 10 XLB -153EU T 7.2538-7.791 0.755 17 XLG +153EU T 5.175-7.791 10.88 21 XL (total) +153EU T 5.175 0.213 7 XLL +153EU T 5.815-5.8461 5.20 15 XLA +153EU T 5.8149 0.0825 25 XLC +153EU T 6.4365-6.9193 4.63 10 XLB +153EU T 7.2538-7.791 0.755 17 XLG 153EU T -153EU T 32.24-34.38 |] KLL AUGER -153EU T 38.59-41.52 |] 4.47 28 ^KLX AUGER -153EU T 44.9-48.5 |] KXY AUGER -153EU T 3.4-7.8 53.0 5 L AUGER +153EU T 32.24-34.38 |] KLL AUGER +153EU T 38.59-41.52 |] 4.47 28 KLX AUGER +153EU T 44.9-48.5 |] KXY AUGER +153EU T 3.4-7.8 53.0 5 L AUGER 153SM P 0.0 3/2+ 1.92855 D 5 807.6 7 153EU N 1.0 1.0 1 1.0 153EU L 0 0 5/2+ STABLE -153EU B 807.6 7 19.5 15 7.3 2 +153EU B 807.6 7 19.5 15 7.3 153EUS B EAV=264.3 3 153EU L 83.36720 177/2+ -153EU G 83.36717 210.193 6 M1+E2 0.81 4 3.74 11 -153EU2 G KC=2.30 7$LC=1.119 34$MC=0.258 8 +153EU G 83.36717 210.193 6M1+E2 0.81 4 3.74 11 +153EU2 G KC=2.30 7$LC=1.119 34$MC=0.258 8 153EU L 97.43103 175/2- -153EU B 710.2 7 0.62 8 8.6 1U +153EU B 710.2 7 0.62 8 8.6 1 153EUS B EAV=227.4 3 153EU G 14.06383 24 E1 10.78 32 -153EU2 G KC=$LC=8.43 25$MC=1.90 6 -153EU G 97.43100 210.767 14E1 0.302 9 -153EU2 G KC=0.254 8$LC=0.0382 11$MC=0.00823 25 +153EU2 G LC=8.43 25$MC=1.90 6 +153EU G 97.43100 210.767 14E1 0.302 9 +153EU2 G KC=0.254 8$LC=0.0382 11$MC=0.00823 25 153EU L 103.18016 133/2+ 3.8 NS 153EU B 704.7 7 49.2 17 6.7 153EUS B EAV=225.3 3 -153EU G 19.81296 211.05E-4 22E2 3.22E3 10 -153EU2 G KC=$LC=2490 70$MC=578 17 -153EU G 103.18012 1729.19 16M1+E2 0.119 3 1.69 5 -153EU2 G KC=1.417 43$LC=0.213 6$MC=0.0462 14 +153EU G 19.81296 210.00010522E2 3.22E3 10 +153EU2 G LC=2490 70$MC=578 17 +153EU G 103.18012 1729.19 16M1+E2 0.119 3 1.69 5 +153EU2 G KC=1.417 43$LC=0.213 6$MC=0.0462 14 153EU L 151.6257 5 7/2- -153EU B 656.0 7 0.042 8 10 3U +153EU B 656.0 7 0.042 8 10 1U 153EUS B EAV=221.2 3 -153EU G 54.1936 120.0019 4 M1+E2 18.2 5 -153EU2 G KC=6.19 19$LC=9.30 28$MC=2.17 7 -153EU G 68.2574 120.0013 4 E1 0.781 23 -153EU2 G KC=0.648 19$LC=0.1040 31$MC=0.0225 7 +153EU G 54.1936 120.0019 4M1+E2 18.2 5 +153EU2 G KC=6.19 19$LC=9.30 28$MC=2.17 7 +153EU G 68.2574 120.0013 4E1 0.781 23 +153EU2 G KC=0.648 19$LC=0.1040 31$MC=0.0225 7 153EU G 151.6244 120.01033 27E1 0.0916 27 -153EU2 G KC=0.0775 23$LC=0.01112 33$MC=0.00239 7 +153EU2 G KC=0.0775 23$LC=0.01112 33$MC=0.00239 7 153EU L 172.85320 135/2+ 0.14 NS -153EU B 634.7 7 30.4 8 6.7 2 +153EU B 634.7 7 30.4 8 6.7 153EUS B EAV=199.7 3 153EU G 69.67300 134.691 41M1+E2 0.136 4 5.28 16 153EU2 G KC=4.37 13$LC=0.719 22$MC=0.1571 47 -153EU G 75.42213 230.169 7 E1+M2 0.055 10 0.752 23 -153EU2 G KC=0.610 18$LC=0.1111 33$MC=0.0245 7 -153EU G 89.48595 220.158 15M1+E2 0.25 10 2.59 8 -153EU2 G KC=2.10 6$LC=0.383 11$MC=0.0845 25 +153EU G 75.42213 230.169 7E1+M2 0.055 10 0.752 23 +153EU2 G KC=0.610 18$LC=0.1111 33$MC=0.0245 7 +153EU G 89.48595 220.158 15M1+E2 0.25 10 2.59 8 +153EU2 G KC=2.10 6$LC=0.383 11$MC=0.0845 25 153EU G 172.85307 210.0736 21M1+E2 0.81 8 0.375 11 -153EU2 G KC=0.293 9$LC=0.0638 19$MC=0.01427 43 +153EU2 G KC=0.293 9$LC=0.0638 19$MC=0.01427 43 153EU L 269.7370 7 7/2+ -153EU B 537.8 7 0.0216 3 11 +153EU B 537.8 7 0.0216 3 11 2 153EUS B EAV=164.7 3 -153EU G 96.8824 7 0.007 1 M1+E2 2.35 10 -153EU2 G KC=1.475 44$LC=0.68 2$MC=0.1570 47 -153EU G 118.1105 100.00023 6 [E1] 0.180 5 -153EU2 G KC=0.1516 45$LC=0.0223 7$MC=0.00479 14 -153EU G 166.5546 150.00061 6 [E2] 0.396 12 -153EU2 G KC=0.263 8$LC=0.1034 31$MC=0.0238 7 -153EU G 172.3032 134000E-7 0 (E1) 0.065 2 -153EU2 G KC=0.0551 17$LC=0.00782 23$MC=0.00168 5 +153EU G 96.8824 7 0.007 1M1+E2 2.35 10 +153EU2 G KC=1.475 44$LC=0.68 2$MC=0.1570 47 +153EU G 118.1105 100.00023 6[E1] 0.180 5 +153EU2 G KC=0.1516 45$LC=0.0223 7$MC=0.00479 14 +153EU G 166.5546 150.00061 6[E2] 0.396 12 +153EU2 G KC=0.263 8$LC=0.1034 31$MC=0.0238 7 +153EU G 172.3032 130.0004 (E1) 0.065 2 +153EU2 G KC=0.0551 17$LC=0.00782 23$MC=0.00168 5 153EU L 585.02 15 + -153EU B 222.6 8 0.00227 5 9.4 +153EU B 222.6 8 0.00227 5 9.4 153EUS B EAV=61.3 3 -153EU G 412.05 200.00191 5 -153EU G 487.75 233600E-7 0 +153EU G 412.05 200.00191 5 +153EU G 487.75 230.00036 153EU L 634.59 6 1/2+ -153EU B 172.9 8 0.0565 7 7.6 2 +153EU B 172.9 8 0.0565 7 7.6 153EUS B EAV=46.7 2 -153EU G 462.0 3 0.00158 26 -153EU G 531.40 150.0544 7 -153EU G 634.8 3 0.00050 3 +153EU G 462.00 300.00158 26 +153EU G 531.40 150.0544 7 +153EU G 634.80 300.00050 3 153EU L 636.522 183/2- -153EU B 171.1 7 0.0648 6 7.5 +153EU B 171.1 7 0.0648 6 7.5 153EUS B EAV=46.1 2 -153EU G 463.6 2 0.01270 24 -153EU G 533.2 2 0.0294 5 -153EU G 539.1 2 0.02070 21 -153EU G 636.5 2 0.00195 7 +153EU G 463.60 200.01270 24 +153EU G 533.20 200.0294 5 +153EU G 539.10 200.02070 21 +153EU G 636.50 200.00195 7 153EU L 657.67 14 + -153EU B 149.9 8 0.00090 6 9.3 +153EU B 149.9 8 0.00090 6 9.3 153EUS B EAV=40.1 2 -153EU G 485.0 2 0.00038 3 -153EU G 574.1 3 0.00016 5 -153EU G 657.55 250.00037 2 +153EU G 485.00 200.00038 3 +153EU G 574.10 300.00016 5 +153EU G 657.55 250.00037 2 153EU L 681.88 8 5/2- -153EU B 125.7 7 0.0085 6 7.9 1U +153EU B 125.7 7 0.0085 6 7.9 1 153EUS B EAV=33.2 2 153EU G 509.15 200.00190 18 -153EU G 578.75 200.0034 5 -153EU G 584.55 200.00107 3 -153EU G 598.54 100.0020 1 +153EU G 578.75 200.0034 5 +153EU G 584.55 200.00107 3 +153EU G 598.54 100.0020 1 153EU G 682.0 6 0.00015 12 153EU L 694.180 235/2+ -153EU B 113.4 7 0.0221 8 7.4 2 +153EU B 113.4 7 0.0221 8 7.4 153EUS B EAV=29.8 2 -153EU G 424.4 3 0.00195 6 -153EU G 521.30 250.0067 1 -153EU G 542.7 2 0.00234 10 -153EU G 590.96 200.00122 9 -153EU G 596.7 2 0.0099 8 -153EU G 694.1 3 2.0E-5 6 +153EU G 424.40 300.00195 6 +153EU G 521.30 250.0067 1 +153EU G 542.70 200.00234 10 +153EU G 590.96 200.00122 9 +153EU G 596.70 200.0099 8 +153EU G 694.10 300.000020 6 153EU L 701.46 24 + -153EU B 106.1 8 0.0076 6 8.8 +153EU B 106.1 8 0.0076 6 8.8 153EUS B EAV=27.8 2 -153EU G 598.3 3 0.0020 1 -153EU G 604.03 240.0049 6 -153EU G 617.9 3 0.00067 6 -153EU G 701.8 4 2.9E-5 6 +153EU G 598.30 300.0020 1 +153EU G 604.03 240.0049 6 +153EU G 617.90 300.00067 6 +153EU G 701.80 400.000029 6 153EU L 706.622 235/2+ -153EU B 101.0 8 0.0241 7 7.3 2 +153EU B 101.0 8 0.0241 7 7.3 153EUS B EAV=26.4 3 -153EU G 436.9 3 0.00158 5 -153EU G 554.94 100.0047 1 -153EU G 603.6 4 0.0049 6 -153EU G 609.5 3 0.0129 4 -153EU G 706.8 5 2.3E-5 12 +153EU G 436.9 3 0.00158 5 +153EU G 554.94 100.0047 1 +153EU G 603.6 4 0.0049 6 +153EU G 609.5 3 0.0129 4 +153EU G 706.8 5 0.00002312 153EU L 713.12 20 + -153EU B 94.5 8 0.0141 5 7.4 +153EU B 94.5 8 0.0141 5 7.4 153EUS B EAV=24.6 2 153EU G 443.2 5 0.00041 32 -153EU G 609.95 200.0129 4 -153EU G 615.8 4 0.00050 6 -153EU G 630.5 4 9.9E-5 15 -153EU G 713.9 3 2.31E-4 20 +153EU G 609.95 200.0129 4 +153EU G 615.80 400.00050 6 +153EU G 630.50 400.00009915 +153EU G 713.9 3 0.00023120 153EU L 718.69 143/2+ 153EU B 88.9 8 0.00143 10 8.4 153EUS B EAV=23.1 2 -153EU G 545.75 150.0009 1 -153EU G 615.51 140.00050 6 -153EU G 719.0 4 2.5E-5 5 +153EU G 545.75 150.0009 1 +153EU G 615.51 140.00050 6 +153EU G 719.00 400.000025 5 153EU L 760.39 17 + -153EU B 47.2 8 0.00098 5 7.9 +153EU B 47.2 8 0.00098 5 7.9 153EUS B EAV=12.0 2 -153EU G 587.60 250.00048 4 -153EU G 657.21 7 0.00037 2 -153EU G 662.4 6 0.00007 7 -153EU G 677.0 3 4.4E-5 15 -153EU G 760.5 4 3.2E-5 5 +153EU G 587.60 250.00048 4 +153EU G 657.21 7 0.00037 2 +153EU G 662.4 6 0.00007 7 +153EU G 677.00 300.00004415 +153EU G 760.50 400.000032 5 153EU L 763.8 6 + -153EU B 44.0 7 44000E-912 8.9 +153EU B 44.0 7 0.00004412 8.9 153EUS B EAV=11.1 3 -153EU G 763.8 6 4.4E-5 12 +153EU G 763.8 6 0.00004412 diff --git a/HEN_HOUSE/spectra/lnhb/Sn-113.txt b/HEN_HOUSE/spectra/lnhb/Sn-113.txt index 088ba4801..a5c35a251 100644 --- a/HEN_HOUSE/spectra/lnhb/Sn-113.txt +++ b/HEN_HOUSE/spectra/lnhb/Sn-113.txt @@ -4,48 +4,48 @@ 113IN C Evaluation history: Type=Upadte;Author=M.M. Bé;Cutoff date= -- 113IN2C Type=Full;Author=R.G.Helmer;Cutoff date= -- 113IN C References: 1961Gr11, 1993Mu14, 1994DeZX -113IN T Auger electrons and ^X ray energies and emission intensities: -113IN T {U Energy (keV)} {U Intensity } {U Line } +113IN T Auger electrons and X ray energies and emission intensities: +113IN T {U Energy (keV)} {U Intensity} {U Line} 113IN T -113IN T 24.0023 27.69 21 XKA2 -113IN T 24.21 51.9 3 XKA1 +113IN T 24.0023 27.69 21 XKA2 +113IN T 24.21 51.9 3 XKA1 113IN T -113IN T 27.238 |] XKB3 -113IN T 27.2762 |] 14.58 17 XKB1 -113IN T 27.495 |] XKB5II +113IN T 27.238 |] XKB3 +113IN T 27.2762 |] 14.58 17 XKB1 +113IN T 27.495 |] XKB5II 113IN T -113IN T 27.861 |] XKB2 -113IN T 27.928 |] 2.77 10 XKB4 -113IN T 27.939 |] XKO23 +113IN T 27.861 |] XKB2 +113IN T 27.928 |] 2.77 10 XKB4 +113IN T 27.939 |] XKO23 113IN T -113IN T 2.9-4.16 8.48 19 XL (total) -113IN T 2.9 0.183 7 XLL -113IN T 3.28-3.29 4.90 15 XLA -113IN T 3.11 0.0621 14 XLC -113IN T 3.49-3.79 3.01 6 XLB -113IN T 3.82-4.16 0.330 7 XLG +113IN T 2.9-4.16 8.48 19 XL (total) +113IN T 2.9 0.183 7 XLL +113IN T 3.28-3.29 4.90 15 XLA +113IN T 3.11 0.0621 14 XLC +113IN T 3.49-3.79 3.01 6 XLB +113IN T 3.82-4.16 0.330 7 XLG 113IN T -113IN T 19.34-20.35 |] KLL AUGER -113IN T 22.83-24.19 |] 17.0 5 ^KLX AUGER -113IN T 26.25-27.9 |] KXY AUGER -113IN T 2-4.2 116.3 6 L AUGER +113IN T 19.34-20.35 |] KLL AUGER +113IN T 22.83-24.19 |] 17.0 5 KLX AUGER +113IN T 26.25-27.9 |] KXY AUGER +113IN T 2-4.2 116.3 6 L AUGER 113SN P 0.0 1/2+ 115.09 D 3 1036.0 28 113IN N 1.0 1.0 1 1.0 113IN L 0 9/2+ STABLE 113IN L 391.699 3 1/2- 1.6579 H 38 -113IN E 97.79 8 7.01 -113IN2 E EAV= $CK=0.855 1$CL=0.116 1$CM=0.0241 5$CN= $CO= -113IN G 391.698 3 64.97 17M4 0.540 4 -113IN2 G KC=0.437 4$LC=0.0858 26$MC=0.0170 5 +113IN E 97.79 87.01 +113IN2 E CK=0.855 1$CL=0.116 1$CM=0.0241 5 +113IN G 391.698 3 64.97 17M4 0.540 4 +113IN2 G KC=0.437 4$LC=0.0858 26$MC=0.0170 5 113IN L 646.833 103/2-+ -113IN E 2.21 8 8.2 2 -113IN2 E EAV= $CK=0.8490 14$CL=0.121 1$CM=0.0254 5$CN= $CO= -113IN G 255.134 102.11 8 M1+E2 0.0464 14 +113IN E 2.21 88.2 +113IN2 E CK=0.8490 14$CL=0.121 1$CM=0.0254 5 +113IN G 255.134 102.11 8M1+E2 0.0464 14 113IN2 G KC=0.0396 12$LC=0.00549 16$MC=1078E-6 32 -113IN G 646.83 1 4E-6 2 [E3] +113IN G 646.83 1 0.000004 2[E3] 113IN L 1029.73 8 1/2,3/2+ 0.33 NS -113IN E 0.00103 4 6.5 -113IN2 E EAV= $CK= $CL=0.3 3$CM=0.54 20$CN= $CO= -113IN G 382.90 8 6.0E-5 3 -113IN G 638.03 8 0.00097 4 +113IN E 0.00103 46.5 +113IN2 E CL=0.3 3$CM=0.54 20 +113IN G 382.90 8 0.000060 3 +113IN G 638.03 8 0.00097 4 diff --git a/HEN_HOUSE/spectra/lnhb/Sr-82.txt b/HEN_HOUSE/spectra/lnhb/Sr-82.txt index f1d91056b..5c1c0a7e9 100644 --- a/HEN_HOUSE/spectra/lnhb/Sr-82.txt +++ b/HEN_HOUSE/spectra/lnhb/Sr-82.txt @@ -3,33 +3,33 @@ 82RB C Evaluation history: Type=FuLL;Author=M.M. Bé;Cutoff date=01-DEC-2014 82RB C References: 1953Li27, 1953Kr10, 1958Sa20, 1978Gr17, 1987Ju02, 1987Ho06, 82RB2C 1996Sc06, 1998Sc28, 2000Sc47, 2009Pi02, 2012Wa38 - 82RB T Auger electrons and ^X ray energies and emission intensities: - 82RB T {U Energy (keV)} {U Intensity } {U Line } + 82RB T Auger electrons and X ray energies and emission intensities: + 82RB T {U Energy (keV)} {U Intensity} {U Line} 82RB T - 82RB T 13.3359 16.79 14 XKA2 - 82RB T 13.3955 32.32 22 XKA1 + 82RB T 13.3359 16.79 14 XKA2 + 82RB T 13.3955 32.32 22 XKA1 82RB T - 82RB T 14.9519 |] XKB3 - 82RB T 14.9614 |] 7.87 9 XKB1 - 82RB T 15.085 |] XKB5II + 82RB T 14.9519 |] XKB3 + 82RB T 14.9614 |] 7.87 9 XKB1 + 82RB T 15.085 |] XKB5II 82RB T - 82RB T 15.1856 |] XKB2 - 82RB T 15.205 |] 0.91 4 XKB4 + 82RB T 15.1856 |] XKB2 + 82RB T 15.205 |] 0.91 4 XKB4 82RB T - 82RB T 1.484-2.051 2.52 5 XL (total) - 82RB T 1.484 0.0619 17 XLL - 82RB T 1.693-1.695 1.56 4 XLA - 82RB T 1.543 0.0272 8 XLC - 82RB T 1.752-1.954 0.855 21 XLB - 82RB T 1.831-2.051 0.01242 27 XLG + 82RB T 1.484-2.051 2.52 5 XL (total) + 82RB T 1.484 0.0619 17 XLL + 82RB T 1.693-1.695 1.56 4 XLA + 82RB T 1.543 0.0272 8 XLC + 82RB T 1.752-1.954 0.855 21 XLB + 82RB T 1.831-2.051 0.01242 27 XLG 82RB T - 82RB T 10.987-11.503 |] KLL AUGER - 82RB T 12.782-13.381 |] 28.0 4 ^KLX AUGER - 82RB T 14.556-15.172 |] KXY AUGER - 82RB T 1.16-2.05 105.7 5 L AUGER + 82RB T 10.987-11.503 |] KLL AUGER + 82RB T 12.782-13.381 |] 28.0 4 KLX AUGER + 82RB T 14.556-15.172 |] KXY AUGER + 82RB T 1.16-2.05 105.7 5 L AUGER 82SR P 0.0 0+ 25.347 D 17 178 7 82RB N 1.0 1.0 1 1.0 82RB L 0 1+ STABLE 82RB E 100 4.7 - 82RB2 E EAV= $CK=0.859 2$CL=0.116 2$CM=0.022 1$CN=0.0031 2$CO= + 82RB2 E CK=0.859 2$CL=0.116 2$CM=0.022 1$CN=0.0031 2 diff --git a/HEN_HOUSE/spectra/lnhb/Sr-85.txt b/HEN_HOUSE/spectra/lnhb/Sr-85.txt index 4077305ee..f011b6b07 100644 --- a/HEN_HOUSE/spectra/lnhb/Sr-85.txt +++ b/HEN_HOUSE/spectra/lnhb/Sr-85.txt @@ -1,58 +1,56 @@ 85RB 85SR EC DECAY (64.850 D) 85RB C References: 1977La19 - 85RB T Auger electrons and ^X ray energies and emission intensities: - 85RB T {U Energy (keV)} {U Intensity } {U Line } + 85RB T Auger electrons and X ray energies and emission intensities: + 85RB T {U Energy (keV)} {U Intensity} {U Line} 85RB T - 85RB T 13.3359 17.16 17 XKA2 - 85RB T 13.3955 33.04 29 XKA1 + 85RB T 13.3359 17.16 17 XKA2 + 85RB T 13.3955 33.04 29 XKA1 85RB T - 85RB T 14.9519 |] XKB3 - 85RB T 14.9614 |] 8.04 10 XKB1 - 85RB T 15.085 |] XKB5II + 85RB T 14.9519 |] XKB3 + 85RB T 14.9614 |] 8.04 10 XKB1 + 85RB T 15.085 |] XKB5II 85RB T - 85RB T 15.1856 |] XKB2 - 85RB T 15.205 |] 0.93 4 XKB4 + 85RB T 15.1856 |] XKB2 + 85RB T 15.205 |] 0.93 4 XKB4 85RB T - 85RB T 1.48-2.05 2.30 5 XL (total) - 85RB T 1.48 0.0559 16 XLL - 85RB T - 1.41 4 XLA - 85RB T 0.0264 7 XLC - 85RB T - 0.800 21 XLB - 85RB T -2.05 0.00801 18 XLG + 85RB T 1.48-2.05 2.30 5 XL (total) + 85RB T 1.48 0.0559 16 XLL + 85RB T - 1.41 4 XLA + 85RB T 0.0264 7 XLC + 85RB T - 0.800 21 XLB + 85RB T -2.05 0.00801 18 XLG 85RB T - 85RB T 10.987-11.503 |] KLL AUGER - 85RB T 12.782-13.381 |] 28.6 4 ^KLX AUGER - 85RB T 14.556-15.172 |] KXY AUGER - 85RB T 1.1-2 96.5 4 L AUGER + 85RB T 10.987-11.503 |] KLL AUGER + 85RB T 12.782-13.381 |] 28.6 4 KLX AUGER + 85RB T 14.556-15.172 |] KXY AUGER + 85RB T 1.1-2 96.5 4 L AUGER 85SR P 0.0 9/2+ 64.850 D 7 1065 3 85RB N 1.0 1.0 1 1.0 85RB L 0 5/2- STABLE - 85RB E 0.8 4 9.3 3U - 85RB2 E EAV= $CK=0.85 3$CL=0.12 3$CM=0.03 1$CN= $CO= + 85RB E 0.8 49.3 1U + 85RB2 E CK=0.85 3$CL=0.12 3$CM=0.03 1 85RB L 151.161 3/2- 0.71 NS 5 - 85RB E 0.0005 11.5 - 85RB2 E EAV= $CK= $CL= $CM= $CN= $CO= - 85RB G 151.160 6 0.0012 9 M1+E2 0.0488 15 + 85RB E 0.0005 11.5 3 + 85RB G 151.160 6 0.0012 9M1+E2 0.0488 15 85RB2 G KC=0.0430 13$LC=0.00485 15$MC=8.17E-4 25 85RB L 280.986 1/2- 40 PS 3 - 85RB E 0.0005 11.8 - 85RB2 E EAV= $CK= $CL= $CM= $CN= $CO= - 85RB G 129.826 105000E-7 0 (M1) 0.0721 22 + 85RB E 0.0005 11.8 3U + 85RB G 129.826 100.0005 (M1) 0.0721 22 85RB2 G KC=0.0635 19$LC=0.00717 21$MC=1208E-6 36 85RB L 514.007 9/2+ 1.015 US 1 - 85RB E 99.2 4 6.2 - 85RB2 E EAV= $CK=0.8718 15$CL=0.1059 12$CM=0.0195 4$CN= $CO= - 85RB G 362.847 6 0.0014 3 (E3) 0.0339 10 - 85RB2 G KC=0.0292 9$LC=0.00397 12$MC=0.00067 2 - 85RB G 514.0048 2298.5 4 M2 0.0072122 + 85RB E 99.2 46.2 + 85RB2 E CK=0.8718 15$CL=0.1059 12$CM=0.0195 4 + 85RB G 362.847 6 0.0014 3(E3) 0.0339 10 + 85RB2 G KC=0.0292 9$LC=0.00397 12$MC=0.00067 2 + 85RB G 514.0048 2298.5 4M2 0.0072122 85RB2 G KC=0.00635 19$LC=7.22E-4 22$MC=1219E-7 37 85RB L 868.98 7/2- 2.5 PS 3 - 85RB E 0.0129 4 9.1 1U - 85RB2 E EAV= $CK=0.8610 16$CL=0.1146 13$CM=0.0214 4$CN= $CO= - 85RB G 354.97 5 0.0005 2 (E1) 0.002538 - 85RB2 G KC=0.00225 7$LC=2.42E-4 7$MC=4.05E-5 12 - 85RB G 717.81 5 0.00032 3 (E2) 0.001244 - 85RB2 G KC=0.00109 3$LC=1.20E-4 4$MC=2.02E-5 6 - 85RB G 868.98 5 0.0121 4 M1+E2 0.000733 - 85RB2 G KC=0.00065 2$LC=7.0E-5 2$MC=1176E-8 35 + 85RB E 0.0129 49.1 1 + 85RB2 E CK=0.8610 16$CL=0.1146 13$CM=0.0214 4 + 85RB G 354.97 5 0.0005 2(E1) 0.00253 8 + 85RB2 G KC=0.00225 7$LC=2.42E-4 7$MC=4.05E-5 12 + 85RB G 717.81 5 0.00032 3(E2) 0.00124 4 + 85RB2 G KC=0.00109 3$LC=1.20E-4 4$MC=2.02E-5 6 + 85RB G 868.98 5 0.0121 4M1+E2 0.00073 3 + 85RB2 G KC=0.00065 2$LC=7.0E-5 2$MC=1176E-8 35 diff --git a/HEN_HOUSE/spectra/lnhb/Sr-89.txt b/HEN_HOUSE/spectra/lnhb/Sr-89.txt index f06323229..c991f236e 100644 --- a/HEN_HOUSE/spectra/lnhb/Sr-89.txt +++ b/HEN_HOUSE/spectra/lnhb/Sr-89.txt @@ -1,26 +1,26 @@ 89Y 89SR B- DECAY (50.57 D) 89Y C References: 1977La19 - 89Y T Auger electrons and ^X ray energies and emission intensities: - 89Y T {U Energy (keV)} {U Intensity } {U Line } + 89Y T Auger electrons and X ray energies and emission intensities: + 89Y T {U Energy (keV)} {U Intensity} {U Line} 89Y T 89Y T 14.8829 XKA2 - 89Y T 14.9585 0.086 7 XKA1 + 89Y T 14.9585 0.086 7 XKA1 89Y T - 89Y T 16.7259 |] XKB3 - 89Y T 16.7381 |] XKB1 - 89Y T 16.88 |] XKB5II + 89Y T 16.7259 |] XKB3 + 89Y T 16.7381 |] XKB1 + 89Y T 16.88 |] XKB5II 89Y T - 89Y T 17.0156 |] XKB2 - 89Y T 17.0362 |] XKB4 + 89Y T 17.0156 |] XKB2 + 89Y T 17.0362 |] XKB4 89Y T 89SR P 0.0 5/2+ 50.57 D 3 1495.1 22 89Y N 1.0 1.0 1 1.0 89Y L 0 1/2- STABLE - 89Y B 1495.1 2299990E-34 9.4 3U + 89Y B 1495.1 2299.99036 4 9.4 1U 89Y S B EAV=584.6 10 89Y L 909 9/2+ 16.05 S 4 - 89Y B 586.1 220.00964 6 11.1 + 89Y B 586.1 220.00964 6 11.1 2 89Y S B EAV=189.1 9 - 89Y G 909.0 1 0.00956 6 (M4) 0.0085026 - 89Y 2 G KC=0.00746 23$LC=0.00091 3$MC= + 89Y G 909.0 1 0.00956 6(M4) 0.0085026 + 89Y 2 G KC=0.00746 23$LC=0.00091 3 diff --git a/HEN_HOUSE/spectra/lnhb/Sr-90.txt b/HEN_HOUSE/spectra/lnhb/Sr-90.txt index 9eb6be4a9..22b90cc2a 100644 --- a/HEN_HOUSE/spectra/lnhb/Sr-90.txt +++ b/HEN_HOUSE/spectra/lnhb/Sr-90.txt @@ -1,19 +1,19 @@ 90Y 90SR B- DECAY (28.80 Y) 90Y H TYP=Full$AUT=Chisté$CUT= -- $ 90Y C Evaluation history: Type=Full;Author=Chisté;Cutoff date= -- - 90Y T Auger electrons and ^X ray energies and emission intensities: - 90Y T {U Energy (keV)} {U Intensity } {U Line } + 90Y T Auger electrons and X ray energies and emission intensities: + 90Y T {U Energy (keV)} {U Intensity} {U Line} 90Y T 90Y T 14.883 XKA2 90Y T 14.9581 XKA1 90Y T - 90Y T 16.7268 |] XKB3 - 90Y T 16.7384 |] XKB1 - 90Y T 16.8792 |] XKB5II - 90Y T 16.8814 |] XKB5I + 90Y T 16.7268 |] XKB3 + 90Y T 16.7384 |] XKB1 + 90Y T 16.8792 |] XKB5II + 90Y T 16.8814 |] XKB5I 90Y T - 90Y T 17.0137 |] XKB2 - 90Y T 17.0409 |] XKB4 + 90Y T 17.0137 |] XKB2 + 90Y T 17.0409 |] XKB4 90Y T 90Y T 1.6865 XLL 90Y T 1.9211-1.9233 XLA @@ -21,9 +21,9 @@ 90Y T 1.9962-2.0713 XLB 90Y T 2.1118-2.3482 XLG 90Y T - 90Y T 12.205-12.784 |] KLL AUGER - 90Y T 14.238-14.956 |] ^KLX AUGER - 90Y T 16.251-17.034 |] KXY AUGER + 90Y T 12.205-12.784 |] KLL AUGER + 90Y T 14.238-14.956 |] KLX AUGER + 90Y T 16.251-17.034 |] KXY AUGER 90Y T 0.06-2.3677 L AUGER 90SR P 0.0 0+ 28.80 Y 7 545.9 14 90Y N 1.0 1.0 1 1.0 diff --git a/HEN_HOUSE/spectra/lnhb/Ta-182.txt b/HEN_HOUSE/spectra/lnhb/Ta-182.txt index 8c1617cfa..d1965cd4b 100644 --- a/HEN_HOUSE/spectra/lnhb/Ta-182.txt +++ b/HEN_HOUSE/spectra/lnhb/Ta-182.txt @@ -13,152 +13,152 @@ 182W 8C 1986Wa35, 1988Fi05, 1989Ka20, 1990Me15, 1990Ja02, 1992Ch26, 1992Ke02, 182W 9C 1992Su09, 1996Sc06, 1998Mi17, 2000He14, 2002Ba85, 2003Au03, 2008Ki07, 182W 10C 2010Si13 -182W T Auger electrons and ^X ray energies and emission intensities: -182W T {U Energy (keV)} {U Intensity } {U Line } +182W T Auger electrons and X ray energies and emission intensities: +182W T {U Energy (keV)} {U Intensity} {U Line} 182W T -182W T 57.9823 10.06 17 XKA2 -182W T 59.3189 17.48 29 XKA1 +182W T 57.9823 10.06 17 XKA2 +182W T 59.3189 17.48 29 XKA1 182W T -182W T 66.952 |] XKB3 -182W T 67.2451 |] 5.79 13 XKB1 -182W T 67.664 |] XKB5II +182W T 66.952 |] XKB3 +182W T 67.2451 |] 5.79 13 XKB1 +182W T 67.664 |] XKB5II 182W T -182W T 69.033 |] XKB2 -182W T 69.295 |] 1.59 5 XKB4 -182W T 69.484 |] XKO23 +182W T 69.033 |] XKB2 +182W T 69.295 |] 1.59 5 XKB4 +182W T 69.484 |] XKO23 182W T -182W T 7.3881-11.6761 24.4 5 XL (total) -182W T 7.3881 0.461 14 XLL -182W T 8.3352-8.3976 9.82 26 XLA -182W T 8.725 0.219 6 XLC -182W T 9.526-9.9485 11.74 24 XLB -182W T 10.9501-11.6761 2.21 5 XLG +182W T 7.3881-11.6761 24.4 5 XL (total) +182W T 7.3881 0.461 14 XLL +182W T 8.3352-8.3976 9.82 26 XLA +182W T 8.725 0.219 6 XLC +182W T 9.526-9.9485 11.74 24 XLB +182W T 10.9501-11.6761 2.21 5 XLG 182W T -182W T 45.109-48.882 |] KLL AUGER -182W T 54.514-59.312 |] 1.68 15 ^KLX AUGER -182W T 63.89-69.51 |] KXY AUGER -182W T 4.5-12.1 59.5 7 L AUGER +182W T 45.109-48.882 |] KLL AUGER +182W T 54.514-59.312 |] 1.68 15 KLX AUGER +182W T 63.89-69.51 |] KXY AUGER +182W T 4.5-12.1 59.5 7 L AUGER 182TA P 0.0 3- 114.61 D 13 1814.3 17 182W N 1.0 1.0 1 1.0 182W L 0 0+ STABLE 182W L 100.10598 7 2+ 1.40 NS 2 -182W B 1714.2 170 12.2 1 +182W B 1714.2 17 12.2 1 182W S B EAV=625.2 70 -182W G 100.10595 7 14.22 16E2 3.89 6 -182W 2 G KC=0.878 13$LC=2.28 4$MC=0.576 8 +182W G 100.10595 7 14.22 16E2 3.89 6 +182W 2 G KC=0.878 13$LC=2.28 4$MC=0.576 8 182W L 329.4268 6 4+ 62 PS 3 -182W B 1484.9 170 13 1 +182W B 1484.9 17 13 1 182W S B EAV=529.0 7 -182W G 229.3207 6 3.634 36E2 0.196 3 -182W 2 G KC=0.1167 17$LC=0.0605 9$MC=0.01497 21 +182W G 229.3207 6 3.634 36E2 0.196 3 +182W 2 G KC=0.1167 17$LC=0.0605 9$MC=0.01497 21 182W L 680.45 6 6+ 8.2 PS 9 -182W G 351.02 6 0.01157 37E2 0.0538 8 -182W 2 G KC=0.0380 6$LC=0.01210 17$MC=0.00293 5 +182W G 351.02 6 0.01157 37E2 0.0538 8 +182W 2 G KC=0.0380 6$LC=0.01210 17$MC=0.00293 5 182W L 1135.91 140+ -182W G 1035.80 140.0060 21E2 0.004206 -182W 2 G KC=0.00346 5$LC=5.75E-4 8$MC=1317E-7 19 +182W G 1035.80 140.0060 21E2 0.00420 6 +182W 2 G KC=0.00346 5$LC=5.75E-4 8$MC=1317E-7 19 182W G 1135.91 14 182W L 1221.4001 102+ 0.434 PS 11 182W B 592.9 171.6 22 9.9 1 182W S B EAV=181.8 6 -182W G 891.9710 120.0570 25E2 0.005698 -182W 2 G KC=0.00464 7$LC=8.10E-4 12$MC=1.87E-4 3 -182W G 1121.290 3 35.17 33M1+E2 30 5 0.003605 -182W 2 G KC=0.00297 5$LC=4.83E-4 7$MC=1104E-7 16 -182W G 1221.395 3 27.27 27E2 0.003055 -182W 2 G KC=0.00252 4$LC=4.02E-4 6$MC=9.15E-5 13 +182W G 891.9710 120.0570 25E2 0.00569 8 +182W 2 G KC=0.00464 7$LC=8.10E-4 12$MC=1.87E-4 3 +182W G 1121.290 3 35.17 33M1+E2 30 5 0.00360 5 +182W 2 G KC=0.00297 5$LC=4.83E-4 7$MC=1104E-7 16 +182W G 1221.395 3 27.27 27E2 0.00305 5 +182W 2 G KC=0.00252 4$LC=4.02E-4 6$MC=9.15E-5 13 182W L 1257.4121 112+ 1.71 PS 13 182W B 556.9 170.22 21 10.7 1 182W S B EAV=169.2 6 -182W G 121.50 140.0021 7 [E2] 1.83 3 -182W 2 G KC=0.596 9$LC=0.936 15$MC=0.236 4 -182W G 927.9828 130.614 7 E2 0.005248 -182W 2 G KC=0.00429 6$LC=7.38E-4 11$MC=1698E-7 24 +182W G 121.50 140.0021 7[E2] 1.83 3 +182W 2 G KC=0.596 9$LC=0.936 15$MC=0.236 4 +182W G 927.9828 130.614 7E2 0.00524 8 +182W 2 G KC=0.00429 6$LC=7.38E-4 11$MC=1698E-7 24 182W G 1157.3022 110.83 13M1+E2 1.3 7 0.0046 13 -182W 2 G KC=0.0039 11$LC=0.00060 15$MC=0.00014 4 -182W G 1257.407 3 1.511 15E2 0.002894 -182W 2 G KC=0.00239 4$LC=3.78E-4 6$MC=8.60E-5 12 +182W 2 G KC=0.0039 11$LC=0.00060 15$MC=0.00014 4 +182W G 1257.407 3 1.511 15E2 0.00289 4 +182W 2 G KC=0.00239 4$LC=3.78E-4 6$MC=8.60E-5 12 182W L 1289.1498 102- 1.12 NS 4 182W B 525.2 1745.1 23 8.3 182W S B EAV=158.2 6 -182W G 31.7377 150.84 6 E1 1.628 23 -182W 2 G KC=$LC=1.259 18$MC=0.293 4 -182W G 67.7497 1 43.6 15E1+M2 0.018 9 0.22 3 -182W 2 G KC=$LC=0.173 21$MC=0.040 6 -182W G 959.7203 120.348 5 M2+E3 -5.48 44 0.0115719 -182W 2 G KC=0.00901 15$LC=0.00196 3$MC=4.63E-4 7 +182W G 31.7377 150.84 6E1 1.628 23 +182W 2 G LC=1.259 18$MC=0.293 4 +182W G 67.7497 1 43.6 15E1+M2 0.018 9 0.22 3 +182W 2 G LC=0.173 21$MC=0.040 6 +182W G 959.7203 120.348 5M2+E3 -5.48 44 0.0115719 +182W 2 G KC=0.00901 15$LC=0.00196 3$MC=4.63E-4 7 182W G 1189.040 3 16.58 16E1+M2+E3 4567E-641 -182W 2 G KC=3732E-6 33$LC=6.38E-4 6$MC=1468E-7 14 +182W 2 G KC=3732E-6 33$LC=6.38E-4 6$MC=1468E-7 14 182W G 1289.145 3 1.374 17M2 0.0123118 -182W 2 G KC=0.01019 15$LC=1630E-6 23$MC=3.72E-4 6 +182W 2 G KC=0.01019 15$LC=1630E-6 23$MC=3.72E-4 6 182W L 1331.1153 103+ 182W B 483.2 172.39 15 9.5 182W S B EAV=143.9 6 -182W G 1001.6856 122.07 5 M1+E2 -8.9 20 0.004558 -182W 2 G KC=0.00374 6$LC=6.27E-4 10$MC=1438E-7 23 -182W G 1231.004 3 11.62 11M1+E2 -33 8 0.003015 -182W 2 G KC=0.00249 4$LC=3.95E-4 6$MC=9.01E-5 13 +182W G 1001.6856 122.07 5M1+E2 -8.9 20 0.00455 8 +182W 2 G KC=0.00374 6$LC=6.27E-4 10$MC=1438E-7 23 +182W G 1231.004 3 11.62 11M1+E2 -33 8 0.00301 5 +182W 2 G KC=0.00249 4$LC=3.95E-4 6$MC=9.01E-5 13 182W L 1373.8301 103- 78 PS 10 -182W B 440.5 1719.9 7 8.4 +182W B 440.5 1719.9 7 8.4 182W S B EAV=129.6 6 -182W G 42.7148 140.269 7 E1 0.72 1 -182W 2 G KC=$LC=0.557 8$MC=0.1286 18 -182W G 84.68024 262.62 6 M1+E2 0.309 12 7.66 11 -182W 2 G KC=5.88 9$LC=1.36 4$MC=0.321 8 -182W G 116.4179 6 0.445 5 E1 0.253 4 -182W 2 G KC=0.207 3$LC=0.0353 5$MC=0.00805 12 +182W G 42.7148 140.269 7E1 0.72 1 +182W 2 G LC=0.557 8$MC=0.1286 18 +182W G 84.68024 262.62 6M1+E2 0.309 12 7.66 11 +182W 2 G KC=5.88 9$LC=1.36 4$MC=0.321 8 +182W G 116.4179 6 0.445 5E1 0.253 4 +182W 2 G KC=0.207 3$LC=0.0353 5$MC=0.00805 12 182W G 152.42991 267.01 13E1 0.1258 18 -182W 2 G KC=0.1038 15$LC=0.01703 24$MC=0.00387 6 +182W 2 G KC=0.1038 15$LC=0.01703 24$MC=0.00387 6 182W G 1044.4001 120.2381 42E1+M2 0.48 1 0.0053515 -182W 2 G KC=0.00444 12$LC=7.03E-4 20$MC=1.60E-4 5 -182W G 1273.719 3 0.658 7 E1+M2+E3 2781E-625 -182W 2 G KC=2278E-6 21$LC=3583E-7 31$MC=8.16E-5 8 -182W G 1373.824 3 0.2226 32E3 0.004967 -182W 2 G KC=0.00400 6$LC=7.28E-4 11$MC=1685E-7 24 +182W 2 G KC=0.00444 12$LC=7.03E-4 20$MC=1.60E-4 5 +182W G 1273.719 3 0.658 7E1+M2+E3 2781E-625 +182W 2 G KC=2278E-6 21$LC=3583E-7 31$MC=8.16E-5 8 +182W G 1373.824 3 0.2226 32E3 0.00496 7 +182W 2 G KC=0.00400 6$LC=7.28E-4 11$MC=1685E-7 24 182W L 1442.836 9 4+ 0.32 PS 3 182W B 371.5 170.563 10 9.7 1 182W S B EAV=107.0 6 -182W G 1113.406 9 0.442 8 M1+E2 -5.6 12 0.0037610 -182W 2 G KC=0.00311 8$LC=5.04E-4 12$MC=1.15E-4 3 -182W G 1342.72 5 0.2562 28E2+M3 -0.11 11 0.0028 6 -182W 2 G KC=0.0023 5$LC=0.00036 9$MC=8.2E-5 21 +182W G 1113.406 9 0.442 8M1+E2 -5.6 12 0.0037610 +182W 2 G KC=0.00311 8$LC=5.04E-4 12$MC=1.15E-4 3 +182W G 1342.72 5 0.2562 28E2+M3 -0.11 11 0.0028 6 +182W 2 G KC=0.0023 5$LC=0.00036 9$MC=8.2E-5 21 182W L 1487.5018 104- -182W B 326.8 171.5 7 9.1 +182W B 326.8 171.5 7 9.1 182W S B EAV=92.8 5 -182W G 113.67170 221.869 20M1+E2 0.338 12 3.19 5 -182W 2 G KC=2.50 5$LC=0.529 16$MC=0.124 4 +182W G 113.67170 221.869 20M1+E2 0.338 12 3.19 5 +182W 2 G KC=2.50 5$LC=0.529 16$MC=0.124 4 182W G 156.3864 3 2.662 27E1 0.1177 17 -182W 2 G KC=0.0972 14$LC=0.01590 23$MC=0.00362 5 -182W G 198.35187 291.461 15E2 0.317 5 -182W 2 G KC=0.1725 25$LC=0.1097 16$MC=0.0273 4 +182W 2 G KC=0.0972 14$LC=0.01590 23$MC=0.00362 5 +182W G 198.35187 291.461 15E2 0.317 5 +182W 2 G KC=0.1725 25$LC=0.1097 16$MC=0.0273 4 182W G 1158.0711 120.295 18E1 1377E-620 -182W 2 G KC=1159E-6 17$LC=1632E-7 23$MC=3.66E-5 6 +182W 2 G KC=1159E-6 17$LC=1632E-7 23$MC=3.66E-5 6 182W G 1387.390 3 0.0725 11M2+E3 2.6 3 0.0055418 -182W 2 G KC=0.00450 15$LC=7.91E-4 22$MC=1.83E-4 5 +182W 2 G KC=0.00450 15$LC=7.91E-4 22$MC=1.83E-4 5 182W L 1510.25 7 4+ 182W B 304.0 170.1414 39 10 1 182W S B EAV=85.7 5 182W G 829.80 9 0.0141 25[E2] 0.0066110 -182W 2 G KC=0.00536 8$LC=9.62E-4 14$MC=2.22E-4 4 -182W G 1180.82 7 0.0869 29E2+M1 -2.8 10 0.0036 4 -182W 2 G KC=0.0030 4$LC=0.00047 5$MC=1.08E-4 11 -182W G 1410.14 7 0.0400 8 E2 0.002354 -182W 2 G KC=0.00193 3$LC=2.98E-4 5$MC=6.76E-5 10 +182W 2 G KC=0.00536 8$LC=9.62E-4 14$MC=2.22E-4 4 +182W G 1180.82 7 0.0869 29E2+M1 -2.8 10 0.0036 4 +182W 2 G KC=0.0030 4$LC=0.00047 5$MC=1.08E-4 11 +182W G 1410.14 7 0.0400 8E2 0.00235 4 +182W 2 G KC=0.00193 3$LC=2.98E-4 5$MC=6.76E-5 10 182W L 1553.224 1 4- 1.27 NS 4 -182W B 261.1 1729.0 7 7.5 +182W B 261.1 1729.0 7 7.5 182W S B EAV=72.5 5 -182W G 65.72215 152.97 8 M1+E2 0.094 43 2.92 20 -182W 2 G KC=$LC=2.25 15$MC=0.52 4 -182W G 110.388 9 0.1073 33[E1] 0.290 4 -182W 2 G KC=0.238 4$LC=0.0408 6$MC=0.00931 13 -182W G 179.39381 253.099 31M1+E2 1.21 29 0.63 7 -182W 2 G KC=0.44 8$LC=0.148 7$MC=0.0358 21 -182W G 222.1085 3 7.54 7 E1 0.0480 7 -182W 2 G KC=0.0399 6$LC=0.00630 9$MC=1429E-6 20 +182W G 65.72215 152.97 8M1+E2 0.094 43 2.92 20 +182W 2 G LC=2.25 15$MC=0.52 4 +182W G 110.388 9 0.1073 33[E1] 0.290 4 +182W 2 G KC=0.238 4$LC=0.0408 6$MC=0.00931 13 +182W G 179.39381 253.099 31M1+E2 1.21 29 0.63 7 +182W 2 G KC=0.44 8$LC=0.148 7$MC=0.0358 21 +182W G 222.1085 3 7.54 7E1 0.0480 7 +182W 2 G KC=0.0399 6$LC=0.00630 9$MC=1429E-6 20 182W G 264.0740 3 3.602 36E2 0.1254 18 -182W 2 G KC=0.0799 12$LC=0.0347 5$MC=0.00852 12 -182W G 1223.7928 120.204 21E1+M2 0.38 7 0.0029 6 -182W 2 G KC=0.0024 5$LC=0.00037 8$MC=8.3E-5 17 -182W G 1453.1118 100.037 7 M2+E3 2.1 4 0.0053 4 -182W 2 G KC=0.0043 3$LC=0.00074 5$MC=1.69E-4 10 +182W 2 G KC=0.0799 12$LC=0.0347 5$MC=0.00852 12 +182W G 1223.7928 120.204 21E1+M2 0.38 7 0.0029 6 +182W 2 G KC=0.0024 5$LC=0.00037 8$MC=8.3E-5 17 +182W G 1453.1118 100.037 7M2+E3 2.1 4 0.0053 4 +182W 2 G KC=0.0043 3$LC=0.00074 5$MC=1.69E-4 10 diff --git a/HEN_HOUSE/spectra/lnhb/Tc-94m.txt b/HEN_HOUSE/spectra/lnhb/Tc-94m.txt index 3226dfd05..6d0938300 100644 --- a/HEN_HOUSE/spectra/lnhb/Tc-94m.txt +++ b/HEN_HOUSE/spectra/lnhb/Tc-94m.txt @@ -3,7 +3,7 @@ 94MO C Evaluation history: Type=FUL;Author=A.L. Nichols;Cutoff date=01-APR-2014 94MO C References: 1948Mo19, 1950Me21, 1962Mo06, 1963Ma21, 1965Ba48, 1967Ei01, 94MO2C 1968Bo27, 1968Ar06, 1969Ba09, 1971Go40, 1976Su04, 1977La19, 1986AgZX, - 94MO3C 1995ScZY, 1996Sc06, 1998Sc28, 1998ScZM, 1999ScZX, 2000Sc47, 2002Ba85, + 94MO3C 1995ScZY, 1996Sc06, 1998ScZM, 1998Sc28, 1999ScZX, 2000Sc47, 2002Ba85, 94MO4C 2002Ra45, 2003Fr02, 2006Ab37, 2008Ki07, 2012Wa38 94MO T Auger electrons and X ray energies and emission intensities: 94MO T {U Energy (keV)} {U Intensity} {U Line} @@ -12,179 +12,179 @@ 94MO T 17.47954 11.31 19 XKA1 94MO T 94MO T 19.5904 |] XKB3 - 94MO T 19.6085 |] 2.97 6 XKB1 + 94MO T 19.6085 |] 2.97 6 XKB1 94MO T 19.774 |] XKB5II 94MO T 94MO T 19.9653 |] XKB2 94MO T 19.998 |] 0.457 18 XKB4 94MO T 94MO T 2.016-2.831 1.198 22 XL (total) - 94MO T 2.016 0.0279 8 XLL + 94MO T 2.016 0.0279 8 XLL 94MO T 2.29-2.293 0.750 18 XLA - 94MO T 2.12 0.0100 3 XLC + 94MO T 2.12 0.0100 3 XLC 94MO T 2.395-2.518 0.389 10 XLB - 94MO T 2.623-2.831 0.0208 4 XLG + 94MO T 2.623-2.831 0.0208 4 XLG 94MO T 94MO T 14.172-14.855 |] KLL AUGER 94MO T 16.592-17.478 |] 6.28 15 KLX AUGER 94MO T 18.99-19.996 |] KXY AUGER - 94MO T 1.48-2.25 29.8 4 L AUGER - 94TC P 76 3 (2)+ 51.9 M 10 4256 6 + 94MO T 1.48-2.25 29.8 4 L AUGER + 94TC P 0.0 (2)+ 51.9 M 10 4332 5 94MO N 1.0 1.0 1 1.0 94MO G 1022 0.027 14 94MO G 1037.2 3 0.044 14 - 94MO G 1357.4 150.19 8 - 94MO G 3065.6 3 0.011 4 - 94MO G 3085.8 3 0.016 4 - 94MO G 3640.6 3 0.007 2 - 94MO G 4136.2 3 0.007 1 + 94MO G 1357.4 150.19 8 + 94MO G 3065.6 3 0.011 4 + 94MO G 3085.8 3 0.016 4 + 94MO G 3640.6 3 0.007 2 + 94MO G 4136.2 3 0.007 1 94MO L 0 0+ STABLE 94MO L 871.098 162+ - 94MO E 67.2 4 12.8 1 5.6 - 94MO2 E EAV=1094.4 24$CK=0.8704 14$CL=0.1055 11$CM=0.0205 4$CN=0.0037 2$CO= + 94MO E 67.2 412.8 15.6 + 94MO2 E EAV=1094.4 24$CK=0.8704 14$CL=0.1055 11$CM=0.0205 4$CN=0.0037 2 94MO G 871.094 1694.04 21E2 1068E-615 - 94MO2 G KC=9.39E-4 14$LC=1073E-7 15$MC=1.92E-5 3 + 94MO2 G KC=9.39E-4 14$LC=1073E-7 15$MC=1.92E-5 3 94MO L 1573.76 4 4+ - 94MO G 702.66 4 0.18 2 E2 0.001833 - 94MO2 G KC=1608E-6 23$LC=1.87E-4 3$MC=3.34E-5 5 + 94MO G 702.66 4 0.18 2E2 0.00183 3 + 94MO2 G KC=1608E-6 23$LC=1.87E-4 3$MC=3.34E-5 5 94MO L 1741.65 150+ - 94MO G 870.55 220.26 3 E2 1070E-615 - 94MO2 G KC=9.40E-4 14$LC=1075E-7 15$MC=1.92E-5 3 + 94MO G 870.55 220.26 3E2 1070E-615 + 94MO2 G KC=9.40E-4 14$LC=1075E-7 15$MC=1.92E-5 3 94MO L 1864.31 5 2+ - 94MO E 0.41 100.39 9 6.82 - 94MO2 E EAV=639.6 23$CK=0.8699 14$CL=0.1059 11$CM=0.0206 4$CN=0.0037 2$CO= + 94MO E 0.41 100.39 96.82 + 94MO2 E EAV=639.6 23$CK=0.8699 14$CL=0.1059 11$CM=0.0206 4$CN=0.0037 2 94MO G 993.20 5 2.21 18M1+E2 -2 1 7.91E-415 94MO2 G KC=6.96E-4 13$LC=7.86E-5 13$MC=1403E-8 22 - 94MO G 1864.29 5 0.23 3 E2 4.55E-47 - 94MO2 G KC=1.89E-4 3$LC=2.09E-5 3$MC=3.72E-6 6 + 94MO G 1864.29 5 0.23 3E2 4.55E-4 7 + 94MO2 G KC=1.89E-4 3$LC=2.09E-5 3$MC=3.72E-6 6 94MO L 2067.35 6 2+ - 94MO E 0.22 3 0.34 5 6.8 - 94MO2 E EAV=548.7 23$CK=0.8697 14$CL=0.1060 11$CM=0.0206 4$CN=0.0037 2$CO= - 94MO G 1196.24 6 0.71 7 M1+E2 0.15 4 5.53E-48 - 94MO2 G KC=4.83E-4 7$LC=5.36E-5 8$MC=9.57E-6 14 - 94MO G 2067.33 6 0.11 1 E2 5.15E-48 - 94MO2 G KC=1562E-7 22$LC=1722E-8 25$MC=3.07E-6 5 + 94MO E 0.22 30.34 56.8 + 94MO2 E EAV=548.7 23$CK=0.8697 14$CL=0.1060 11$CM=0.0206 4$CN=0.0037 2 + 94MO G 1196.24 6 0.71 7M1+E2 0.15 4 5.53E-4 8 + 94MO2 G KC=4.83E-4 7$LC=5.36E-5 8$MC=9.57E-6 14 + 94MO G 2067.33 6 0.11 1E2 5.15E-4 8 + 94MO2 G KC=1562E-7 22$LC=1722E-8 25$MC=3.07E-6 5 94MO L 2294.79 164+ 94MO L 2393.02 6 2+ - 94MO E 0.91 6 4.0 2 5.6 - 94MO2 E EAV=404.8 22$CK=0.8694 14$CL=0.1062 11$CM=0.0207 4$CN=0.0037 2$CO= - 94MO G 325.67 9 0.027 2 M1+E2 1.0 2 0.0147 9 - 94MO2 G KC=0.0128 8$LC=0.00156 11$MC=2.80E-4 19 - 94MO G 528.71 8 0.032 2 M1+E2 1.0 2 0.003719 - 94MO2 G KC=0.00325 8$LC=3.78E-4 11$MC=6.76E-5 19 - 94MO G 1521.91 6 4.48 28M1+E2 -0.12 3 4.11E-46 - 94MO2 G KC=2.95E-4 5$LC=3.26E-5 5$MC=5.81E-6 9 - 94MO G 2392.99 6 0.50 4 E2 6.33E-49 - 94MO2 G KC=1203E-7 17$LC=1322E-8 19$MC=2.35E-6 4 + 94MO E 0.91 64.0 25.6 + 94MO2 E EAV=404.8 22$CK=0.8694 14$CL=0.1062 11$CM=0.0207 4$CN=0.0037 2 + 94MO G 325.67 9 0.027 2M1+E2 1.0 2 0.0147 9 + 94MO2 G KC=0.0128 8$LC=0.00156 11$MC=2.80E-4 19 + 94MO G 528.71 8 0.032 2M1+E2 1.0 2 0.00371 9 + 94MO2 G KC=0.00325 8$LC=3.78E-4 11$MC=6.76E-5 19 + 94MO G 1521.91 6 4.48 28M1+E2 -0.12 3 4.11E-4 6 + 94MO2 G KC=2.95E-4 5$LC=3.26E-5 5$MC=5.81E-6 9 + 94MO G 2392.99 6 0.50 4E2 6.33E-4 9 + 94MO2 G KC=1203E-7 17$LC=1322E-8 19$MC=2.35E-6 4 94MO L 2423.45 9 6+ 94MO L 2533.87 123- 94MO L 2610.57 165- 94MO L 2739.91 7 1+ - 94MO E 0.427 2110.1 4 5.03 - 94MO2 E EAV=254.3 22$CK=0.8690 14$CL=0.1066 11$CM=0.0207 4$CN=0.0037 2$CO= - 94MO G 672.56 9 0.17 3 M1+E2 1.0 2 0.002003 - 94MO2 G KC=0.00176 3$LC=2.01E-4 4$MC=3.59E-5 7 - 94MO G 875.60 9 1.0 3 M1+E2 -0.10 2 1072E-615 - 94MO2 G KC=9.45E-4 14$LC=1056E-7 15$MC=1.89E-5 3 - 94MO G 998.25 170.24 2 M1 8.06E-412 - 94MO2 G KC=0.00071 1$LC=7.92E-5 11$MC=1413E-8 20 - 94MO G 1868.79 7 5.49 28M1+E2 -0.12 2 4.38E-47 - 94MO2 G KC=1.96E-4 3$LC=2.16E-5 3$MC=3.85E-6 6 + 94MO E 0.427 2110.1 45.03 + 94MO2 E EAV=254.3 22$CK=0.8690 14$CL=0.1066 11$CM=0.0207 4$CN=0.0037 2 + 94MO G 672.56 9 0.17 3M1+E2 1.0 2 0.00200 3 + 94MO2 G KC=0.00176 3$LC=2.01E-4 4$MC=3.59E-5 7 + 94MO G 875.60 9 1.0 3M1+E2 -0.10 2 1072E-615 + 94MO2 G KC=9.45E-4 14$LC=1056E-7 15$MC=1.89E-5 3 + 94MO G 998.25 170.24 2M1 8.06E-412 + 94MO2 G KC=0.00071 1$LC=7.92E-5 11$MC=1413E-8 20 + 94MO G 1868.79 7 5.49 28M1+E2 -0.12 2 4.38E-4 7 + 94MO2 G KC=1.96E-4 3$LC=2.16E-5 3$MC=3.85E-6 6 94MO G 2739.87 7 3.53 20M1 7.25E-411 - 94MO2 G KC=9.59E-5 14$LC=1051E-8 15$MC=1.87E-6 3 + 94MO2 G KC=9.59E-5 14$LC=1051E-8 15$MC=1.87E-6 3 94MO L 2805.04 193+ 94MO L 2869.90 8 2+ - 94MO E 0.0024 5 0.15 3 6.8 - 94MO2 E EAV=198.5 22$CK=0.8688 14$CL=0.1067 11$CM=0.0208 4$CN=0.0037 2$CO= + 94MO E 0.0024 50.15 36.8 + 94MO2 E EAV=198.5 22$CK=0.8688 14$CL=0.1067 11$CM=0.0208 4$CN=0.0037 2 94MO G 802.55 100.0246 14M1+E2 1.0 2 1303E-619 - 94MO2 G KC=1146E-6 16$LC=1301E-7 19$MC=2.32E-5 4 - 94MO G 1005.58 9 0.09 3 M1+E2 -0.05 4 7.93E-412 - 94MO2 G KC=6.99E-4 10$LC=7.79E-5 11$MC=1.39E-5 2 - 94MO G 1998.78 8 0.0123 6 M1+E2 1.30 9 4.84E-410 - 94MO2 G KC=1.68E-4 3$LC=1.86E-5 3$MC=3.31E-6 6 - 94MO G 2869.85 8 0.016 2 E2 8.16E-412 + 94MO2 G KC=1146E-6 16$LC=1301E-7 19$MC=2.32E-5 4 + 94MO G 1005.58 9 0.09 3M1+E2 -0.05 4 7.93E-412 + 94MO2 G KC=6.99E-4 10$LC=7.79E-5 11$MC=1.39E-5 2 + 94MO G 1998.78 8 0.0123 6M1+E2 1.30 9 4.84E-410 + 94MO2 G KC=1.68E-4 3$LC=1.86E-5 3$MC=3.31E-6 6 + 94MO G 2869.85 8 0.016 2E2 8.16E-412 94MO2 G KC=8.81E-5 13$LC=9.64E-6 14$MC=1717E-9 24 94MO L 2872.40 116+ 94MO L 2955.55 13(8)+ 94MO L 2965.41 6 3+ - 94MO E 0.00058 9 0.093 146.9 - 94MO2 E EAV=157.5 22$CK=0.8686 14$CL=0.1069 11$CM=0.0208 4$CN=0.0037 2$CO= - 94MO G 898.06 9 0.0098 5 M1+E2 2.0 9 9.97E-415 + 94MO E 0.00058 90.093 146.9 + 94MO2 E EAV=157.5 22$CK=0.8686 14$CL=0.1069 11$CM=0.0208 4$CN=0.0037 2 + 94MO G 898.06 9 0.0098 5M1+E2 2.0 9 9.97E-415 94MO2 G KC=8.77E-4 13$LC=9.96E-5 14$MC=1778E-8 25 94MO G 1101.09 8 0.042 14M1+E2 -0.09 6 6.53E-410 - 94MO2 G KC=5.76E-4 8$LC=6.40E-5 9$MC=1142E-8 16 - 94MO G 1391.64 7 0.0267 10M1+E2 -0.08 6 4.41E-47 - 94MO2 G KC=3.53E-4 5$LC=3.91E-5 6$MC=6.98E-6 10 - 94MO G 2094.28 6 0.0156 6 M1+E2 1.1 7 5.12E-414 - 94MO2 G KC=1.55E-4 3$LC=1.71E-5 4$MC=3.04E-6 6 + 94MO2 G KC=5.76E-4 8$LC=6.40E-5 9$MC=1142E-8 16 + 94MO G 1391.64 7 0.0267 10M1+E2 -0.08 6 4.41E-4 7 + 94MO2 G KC=3.53E-4 5$LC=3.91E-5 6$MC=6.98E-6 10 + 94MO G 2094.28 6 0.0156 6M1+E2 1.1 7 5.12E-414 + 94MO2 G KC=1.55E-4 3$LC=1.71E-5 4$MC=3.04E-6 6 94MO L 3128.66 7 1+ - 94MO E 1.63 9 5.57 - 94MO2 E EAV= $CK=0.8682 14$CL=0.1072 11$CM=0.0209 4$CN=0.0037 2$CO= - 94MO G 1061.30 9 0.016 2 M1+E2 -0.57 16 6.99E-411 + 94MO E 1.63 95.57 + 94MO2 E CK=0.8682 14$CL=0.1072 11$CM=0.0209 4$CN=0.0037 2 + 94MO G 1061.30 9 0.016 2M1+E2 -0.57 16 6.99E-411 94MO2 G KC=6.16E-4 10$LC=6.88E-5 10$MC=1227E-8 18 - 94MO G 1264.34 9 0.22 2 M1+E2 -0.08 3 5.03E-47 - 94MO2 G KC=4.31E-4 6$LC=4.78E-5 7$MC=8.52E-6 12 - 94MO G 2257.53 7 0.057 5 M1+E2 0.74 19 5.61E-49 - 94MO2 G KC=1356E-7 20$LC=1491E-8 22$MC=2.66E-6 4 - 94MO G 3128.60 7 1.34 9 M1 8.71E-413 + 94MO G 1264.34 9 0.22 2M1+E2 -0.08 3 5.03E-4 7 + 94MO2 G KC=4.31E-4 6$LC=4.78E-5 7$MC=8.52E-6 12 + 94MO G 2257.53 7 0.057 5M1+E2 0.74 19 5.61E-4 9 + 94MO2 G KC=1356E-7 20$LC=1491E-8 22$MC=2.66E-6 4 + 94MO G 3128.60 7 1.34 9M1 8.71E-413 94MO2 G KC=7.58E-5 11$LC=8.29E-6 12$MC=1476E-9 21 94MO L 3163.29 19(3)+ 94MO E 0.058 177 - 94MO2 E EAV= $CK=0.8681 14$CL=0.1073 11$CM=0.0209 4$CN=0.0037 2$CO= - 94MO G 358.3 3 0.0084 7 M1+E2 -0.35 12 0.0092 4 - 94MO2 G KC=0.0080 4$LC=0.00093 5$MC=1.67E-4 8 - 94MO G 2292.16 190.050 17M1+E2 0.17 4 5.62E-48 - 94MO2 G KC=1330E-7 19$LC=1461E-8 21$MC=2.60E-6 4 + 94MO2 E CK=0.8681 14$CL=0.1073 11$CM=0.0209 4$CN=0.0037 2 + 94MO G 358.3 3 0.0084 7M1+E2 -0.35 12 0.0092 4 + 94MO2 G KC=0.0080 4$LC=0.00093 5$MC=1.67E-4 8 + 94MO G 2292.16 190.050 17M1+E2 0.17 4 5.62E-4 8 + 94MO2 G KC=1330E-7 19$LC=1461E-8 21$MC=2.60E-6 4 94MO L 3165.77 9 6+ 94MO L 3331.74 17(3)+ 94MO E 0.234 206.3 - 94MO2 E EAV= $CK=0.8675 14$CL=0.1078 11$CM=0.0210 4$CN=0.0038 2$CO= - 94MO G 1467.42 180.072 5 M1+E2 0.3 16 4.19E-49 - 94MO2 G KC=3.16E-4 15$LC=3.50E-5 15$MC=6.2E-6 3 - 94MO G 1757.96 170.15 2 M1+E2 -0.10 3 4.18E-46 - 94MO2 G KC=2.21E-4 3$LC=2.44E-5 4$MC=4.35E-6 6 - 94MO G 2460.61 170.011 2 (M1+E2) + 94MO2 E CK=0.8675 14$CL=0.1078 11$CM=0.0210 4$CN=0.0038 2 + 94MO G 1467.42 180.072 5M1+E2 0.3 16 4.19E-4 9 + 94MO2 G KC=3.16E-4 15$LC=3.50E-5 15$MC=6.2E-6 3 + 94MO G 1757.96 170.15 2M1+E2 -0.10 3 4.18E-4 6 + 94MO2 G KC=2.21E-4 3$LC=2.44E-5 4$MC=4.35E-6 6 + 94MO G 2460.61 170.011 2(M1+E2) 94MO L 3339.54 176+ 94MO L 3400.83 17 + - 94MO E 0.36 4 6 - 94MO2 E EAV= $CK=0.8672 14$CL=0.1080 11$CM=0.0211 4$CN=0.0038 2$CO= - 94MO G 1536.51 180.014 3 - 94MO G 2529.69 170.34 4 - 94MO G 3400.76 170.005 2 + 94MO E 0.36 46 + 94MO2 E CK=0.8672 14$CL=0.1080 11$CM=0.0211 4$CN=0.0038 2 + 94MO G 1536.51 180.014 3 + 94MO G 2529.69 170.34 4 + 94MO G 3400.76 170.005 2 94MO L 3447.6 4 (1,2)+ 94MO E 0.118 196.4 - 94MO2 E EAV= $CK=0.8669 14$CL=0.1082 11$CM=0.0211 4$CN=0.0038 2$CO= - 94MO G 2576.5 4 0.11 2 M1+E2 -1.9 6 6.94E-412 - 94MO2 G KC=1061E-7 15$LC=1164E-8 17$MC=2.07E-6 3 - 94MO G 3447.5 4 0.006 1 + 94MO2 E CK=0.8669 14$CL=0.1082 11$CM=0.0211 4$CN=0.0038 2 + 94MO G 2576.5 4 0.11 2M1+E2 -1.9 6 6.94E-412 + 94MO2 G KC=1061E-7 15$LC=1164E-8 17$MC=2.07E-6 3 + 94MO G 3447.5 4 0.006 1 94MO L 3511.86 141+ 94MO E 0.121 106.4 - 94MO2 E EAV= $CK=0.8666 15$CL=0.1085 11$CM=0.0212 4$CN=0.0038 2$CO= - 94MO G 1770.19 210.025 6 (M1+E2) - 94MO G 2640.72 140.033 4 (M1+E2) - 94MO G 3511.79 140.063 7 (M1+E2) + 94MO2 E CK=0.8666 15$CL=0.1085 11$CM=0.0212 4$CN=0.0038 2 + 94MO G 1770.19 210.025 6(M1+E2) + 94MO G 2640.72 140.033 4(M1+E2) + 94MO G 3511.79 140.063 7(M1+E2) 94MO L 3534.32 9 2+ - 94MO E 0.106 3 6.4 - 94MO2 E EAV= $CK=0.8664 15$CL=0.1086 11$CM=0.0212 4$CN=0.0038 2$CO= - 94MO G 1669.99 100.037 2 M1+E2 0.15 19 4.10E-46 - 94MO2 G KC=2.45E-4 4$LC=2.70E-5 4$MC=4.81E-6 7 - 94MO G 2663.18 9 0.066 2 M1+E2 -0.3 2 6.99E-411 - 94MO2 G KC=1009E-7 15$LC=1106E-8 16$MC=1.97E-6 3 - 94MO G 3534.25 9 0.0034 4 E2 1065E-615 - 94MO2 G KC=6.25E-5 9$LC=6.82E-6 10$MC=1215E-9 17 + 94MO E 0.106 36.4 + 94MO2 E CK=0.8664 15$CL=0.1086 11$CM=0.0212 4$CN=0.0038 2 + 94MO G 1669.99 100.037 2M1+E2 0.15 19 4.10E-4 6 + 94MO2 G KC=2.45E-4 4$LC=2.70E-5 4$MC=4.81E-6 7 + 94MO G 2663.18 9 0.066 2M1+E2 -0.3 2 6.99E-411 + 94MO2 G KC=1009E-7 15$LC=1106E-8 16$MC=1.97E-6 3 + 94MO G 3534.25 9 0.0034 4E2 1065E-615 + 94MO2 G KC=6.25E-5 9$LC=6.82E-6 10$MC=1215E-9 17 94MO L 3792.87 152+ 94MO E 0.169 205.9 - 94MO2 E EAV= $CK=0.8639 15$CL=0.1106 11$CM=0.0216 4$CN=0.0039 2$CO= - 94MO G 1399.84 160.041 3 M1+E2 + 94MO2 E CK=0.8639 15$CL=0.1106 11$CM=0.0216 4$CN=0.0039 2 + 94MO G 1399.84 160.041 3M1+E2 94MO G 1928.54 160.075 19M1+E2 - 94MO G 3792.79 150.052 5 E2 1149E-616 - 94MO2 G KC=5.59E-5 8$LC=6.09E-6 9$MC=1084E-9 16 + 94MO G 3792.79 150.052 5E2 1149E-616 + 94MO2 G KC=5.59E-5 8$LC=6.09E-6 9$MC=1084E-9 16 94MO L 3892.16 7 (2)+ 94MO E 0.212 135.6 - 94MO2 E EAV= $CK=0.8620 15$CL=0.1121 12$CM=0.0220 4$CN=0.0039 2$CO= + 94MO2 E CK=0.8620 15$CL=0.1121 12$CM=0.0220 4$CN=0.0039 2 94MO G 1499.13 9 0.067 11M1+E2 - 94MO G 1824.79 9 0.023 1 (M1+E2) - 94MO G 2027.83 9 0.021 4 (M1+E2) + 94MO G 1824.79 9 0.023 1(M1+E2) + 94MO G 2027.83 9 0.021 4(M1+E2) 94MO G 3021.01 7 0.087 14(M1+E2) - 94MO G 3892.07 7 0.014 2 + 94MO G 3892.07 7 0.014 2 diff --git a/HEN_HOUSE/spectra/lnhb/Tc-99.txt b/HEN_HOUSE/spectra/lnhb/Tc-99.txt index 4c7e815e5..b9a855a55 100644 --- a/HEN_HOUSE/spectra/lnhb/Tc-99.txt +++ b/HEN_HOUSE/spectra/lnhb/Tc-99.txt @@ -9,38 +9,38 @@ 99RU4C 1970AN12, 1972GU01, 1972WA32, 1973BE72, 1973LE10, 1974RE11, 1974EN02, 99RU5C 1974HA12, 1976KI02, 1977IS05, 1980LA02, 1984CO30, 1986MU09, 1990GA13, 99RU6C 1996SC06, 2003AU03, 2008KI07 - 99RU T Auger electrons and ^X ray energies and emission intensities: - 99RU T {U Energy (keV)} {U Intensity } {U Line } + 99RU T Auger electrons and X ray energies and emission intensities: + 99RU T {U Energy (keV)} {U Intensity} {U Line} 99RU T - 99RU T 19.1506 0.000155 30 XKA2 - 99RU T 19.2794 0.00029 6 XKA1 + 99RU T 19.1506 0.00015530 XKA2 + 99RU T 19.2794 0.00029 6 XKA1 99RU T - 99RU T 21.6349 |] XKB3 - 99RU T 21.6565 |] 0.000079 15 XKB1 - 99RU T 21.832 |] XKB5II + 99RU T 21.6349 |] XKB3 + 99RU T 21.6565 |] 0.00007915 XKB1 + 99RU T 21.832 |] XKB5II 99RU T - 99RU T 22.074 |] XKB2 - 99RU T 22.104 |] 0.0000128 25 XKB4 + 99RU T 22.074 |] XKB2 + 99RU T 22.104 |] 1.28E-5 25 XKB4 99RU T - 99RU T 2.2538-3.1825 0.000039 4 XL (total) - 99RU T 2.2538 0.00000086 12 XLL - 99RU T 2.5542-2.5591 0.0000234 29 XLA - 99RU T 2.3826 0.00000032 6 XLC - 99RU T 2.6831-2.9436 0.0000132 18 XLB - 99RU T 2.8959-3.1825 0.00000091 12 XLG + 99RU T 2.2538-3.1825 0.000039 4 XL (total) + 99RU T 2.2538 8.6E-7 12 XLL + 99RU T 2.5542-2.5591 2.34E-5 29 XLA + 99RU T 2.3826 3.2E-7 6 XLC + 99RU T 2.6831-2.9436 1.32E-5 18 XLB + 99RU T 2.8959-3.1825 9.1E-7 12 XLG 99RU T - 99RU T 15.565-16.329 |] KLL AUGER - 99RU T 18.267-19.277 |] 0.000139 27 ^KLX AUGER - 99RU T 20.947-22.113 |] KXY AUGER - 99RU T 1.75-3.12 0.00080 4 L AUGER + 99RU T 15.565-16.329 |] KLL AUGER + 99RU T 18.267-19.277 |] 0.00013927 KLX AUGER + 99RU T 20.947-22.113 |] KXY AUGER + 99RU T 1.75-3.12 0.00080 4 L AUGER 99TC P 0.0 9/2+ 211.5E3 Y 11 293.8 14 99RU N 1.0 1.0 1 1.0 99RU L 0 5/2+ STABLE - 99RU B 293.8 1499999E-330 12.3 + 99RU B 293.8 1499.9985530 12.3 2 99RUS B EAV=94.6 17 99RU L 89.52 153/2+ 20.36 NS 25 - 99RU B 204.3 140.00145 30 15.8 + 99RU B 204.3 140.00145 30 15.8 2U 99RUS B EAV= 99RU G 89.52 150.00058 11M1+()E2 -1.56 2 1.495 25 - 99RU2 G KC=1.173 19$LC=0.265 5$MC=0.0497 9 + 99RU2 G KC=1.173 19$LC=0.265 5$MC=0.0497 9 diff --git a/HEN_HOUSE/spectra/lnhb/Tc-99m.txt b/HEN_HOUSE/spectra/lnhb/Tc-99m.txt index 0f0e0cb17..5dac3985f 100644 --- a/HEN_HOUSE/spectra/lnhb/Tc-99m.txt +++ b/HEN_HOUSE/spectra/lnhb/Tc-99m.txt @@ -1,69 +1,69 @@ 99TC 99TC IT DECAY (6.0067 H) - 99TC T Auger electrons and ^X ray energies and emission intensities: - 99TC T {U Energy (keV)} {U Intensity } {U Line } + 99TC T Auger electrons and X ray energies and emission intensities: + 99TC T {U Energy (keV)} {U Intensity} {U Line} 99TC T - 99TC T 18.251 2.22 7 XKA2 - 99TC T 18.3672 4.21 12 XKA1 + 99TC T 18.251 2.22 7 XKA2 + 99TC T 18.3672 4.21 12 XKA1 99TC T - 99TC T 20.599 |] XKB3 - 99TC T 20.619 |] 1.12 4 XKB1 - 99TC T 20.789 |] XKB5II + 99TC T 20.599 |] XKB3 + 99TC T 20.619 |] 1.12 4 XKB1 + 99TC T 20.789 |] XKB5II 99TC T - 99TC T 21.005 |] XKB2 - 99TC T 21.042 |] 0.177 8 XKB4 + 99TC T 21.005 |] XKB2 + 99TC T 21.042 |] 0.177 8 XKB4 99TC T - 99TC T 2.134-3.002 0.482 12 XL (total) - 99TC T 2.134 0.0110 4 XLL - 99TC T 2.42-2.425 0.298 10 XLA - 99TC T 2.25 0.00395 15 XLC - 99TC T 2.456-2.788 0.159 5 XLB - 99TC T 2.726-3.002 0.00984 26 XLG + 99TC T 2.134-3.002 0.482 12 XL (total) + 99TC T 2.134 0.0110 4 XLL + 99TC T 2.42-2.425 0.298 10 XLA + 99TC T 2.25 0.00395 15 XLC + 99TC T 2.456-2.788 0.159 5 XLB + 99TC T 2.726-3.002 0.00984 26 XLG 99TC T - 99TC T 14.86-15.58 |] KLL AUGER - 99TC T 17.43-18.33 |] 2.15 8 ^KLX AUGER - 99TC T 19.93-21 |] KXY AUGER - 99TC T 1.6-2.9 10.89 9 L AUGER + 99TC T 14.86-15.58 |] KLL AUGER + 99TC T 17.43-18.33 |] 2.15 8 KLX AUGER + 99TC T 19.93-21 |] KXY AUGER + 99TC T 1.6-2.9 10.89 9 L AUGER 99TC P 142.683 1 1/2- 6.0067 H 10 99TC N 1.0 1.0 1 1.0 99TC L 0 9/2+ 211.5E3 Y 11 99TC L 140.5108 107/2+ 0.221 NS 20 - 99TC G 140.511 1 88.5 2 M1+E2 0.119 3 - 99TC2 G KC=0.104 3$LC=0.01290 39$MC=0.00236 7 + 99TC G 140.511 1 88.5 2M1+E2 0.119 3 + 99TC2 G KC=0.104 3$LC=0.01290 39$MC=0.00236 7 99TC L 142.6833 111/2- 6.0067 H 10 - 99TC G 2.1726 4 7.4E-9 2 E3 135E8 4 - 99TC2 G KC=$LC=$MC=119E8 3 - 99TC G 142.683 1 0.023 2 M4 40.9 8 - 99TC2 G KC=29.3 6$LC=9.35 20$MC=1.86 6 + 99TC G 2.1726 4 7.4E-9 2E3 135E8 4 + 99TC2 G MC=119E8 3 + 99TC G 142.6830 100.023 2M4 40.9 8 + 99TC2 G KC=29.3 6$LC=9.35 20$MC=1.86 6 99RU 99TC B- DECAY (6.0067 H) - 99RU T Auger electrons and ^X ray energies and emission intensities: - 99RU T {U Energy (keV)} {U Intensity } {U Line } + 99RU T Auger electrons and X ray energies and emission intensities: + 99RU T {U Energy (keV)} {U Intensity} {U Line} 99RU T 99RU T 19.1506 XKA2 99RU T 19.2794 XKA1 99RU T - 99RU T 21.6349 |] XKB3 - 99RU T 21.6565 |] XKB1 - 99RU T 21.832 |] XKB5II + 99RU T 21.6349 |] XKB3 + 99RU T 21.6565 |] XKB1 + 99RU T 21.832 |] XKB5II 99RU T - 99RU T 22.074 |] XKB2 - 99RU T 22.104 |] XKB4 + 99RU T 22.074 |] XKB2 + 99RU T 22.104 |] XKB4 99RU T 99TC P 142.683 1 1/2- 6.0067 H 10 293.52 20 99RU N 2.50E4 2.50E4 0.00004 2.50E4 99RU L 0 5/2+ STABLE - 99RU B 436.3 2 0.0010 3 9.4 3U + 99RU B 436.3 2 0.0010 3 9.4 1U 99RUS B EAV=152.3 5 99RU L 89.68 5 3/2+ 20.5 NS 1 - 99RU B 346.7 2 0.0026 5 8.7 1U + 99RU B 346.7 2 0.0026 5 8.7 1 99RUS B EAV=102.1 5 - 99RU G 89.6 3 0.00104 20M1+E2 1.49 5 - 99RU2 G KC=1.17 4$LC=0.27 1$MC= + 99RU G 89.6 3 0.00104 20M1+E2 1.49 5 + 99RU2 G KC=1.17 4$LC=0.27 1 99RU L 322.38 6 (3/2)+ - 99RU B 113.9 2 10600E-86 8.5 1U + 99RU B 113.9 2 0.000106 6 8.5 1 99RUS B EAV=37.8 6 - 99RU G 232.7 2 8.4E-6 15 0.048 2 - 99RU2 G KC=0.0412 15$LC=$MC= - 99RU G 322.4 1 9.6E-5 6 0.0175 5 - 99RU2 G KC=0.0152 5$LC=$MC= + 99RU G 232.7 2 8.4E-6 15 0.048 2 + 99RU2 G KC=0.0412 15 + 99RU G 322.4 1 0.000096 6 0.0175 5 + 99RU2 G KC=0.0152 5 diff --git a/HEN_HOUSE/spectra/lnhb/Te-123m.txt b/HEN_HOUSE/spectra/lnhb/Te-123m.txt index fce78a217..b6b005b4f 100644 --- a/HEN_HOUSE/spectra/lnhb/Te-123m.txt +++ b/HEN_HOUSE/spectra/lnhb/Te-123m.txt @@ -2,41 +2,41 @@ 123TE C References: 1955Fa40, 1955Go21, 1964Ch18, 1964Ch08, 1964Al28, 1966Ha03, 123TE2C 1966Gu02, 1969To02, 1968Ka20, 1970EmZY, 1972Ra07, 1973Ra32, 1973RaZO, 123TE3C 1977Kr13, 1992Ja15, 1992Co11, 1996Sc06, 2002Ba85 -123TE T Auger electrons and ^X ray energies and emission intensities: -123TE T {U Energy (keV)} {U Intensity } {U Line } +123TE T Auger electrons and X ray energies and emission intensities: +123TE T {U Energy (keV)} {U Intensity} {U Line} 123TE T -123TE T 27.202 13.9 5 XKA2 -123TE T 27.4726 26.0 9 XKA1 +123TE T 27.202 13.9 5 XKA2 +123TE T 27.4726 26.0 9 XKA1 123TE T -123TE T 30.9446 |] XKB3 -123TE T 30.996 |] 7.43 26 XKB1 -123TE T 31.236 |] XKB5II -123TE T 31.241 |] XKB5I +123TE T 30.9446 |] XKB3 +123TE T 30.996 |] 7.43 26 XKB1 +123TE T 31.236 |] XKB5II +123TE T 31.241 |] XKB5I 123TE T -123TE T 31.7008 |] XKB2 -123TE T 31.774 |] 1.61 7 XKB4 -123TE T 31.812 |] XKO23 +123TE T 31.7008 |] XKB2 +123TE T 31.774 |] 1.61 7 XKB4 +123TE T 31.812 |] XKO23 123TE T -123TE T 3.336-4.82 8.25 21 XL (total) -123TE T 3.336 0.174 7 XLL -123TE T 3.76-3.77 4.60 15 XLA -123TE T 3.606 0.0469 18 XLC -123TE T 4.02-4.37 3.02 7 XLB -123TE T 4.44-4.82 0.411 11 XLG +123TE T 3.336-4.82 8.25 21 XL (total) +123TE T 3.336 0.174 7 XLL +123TE T 3.76-3.77 4.60 15 XLA +123TE T 3.606 0.0469 18 XLC +123TE T 4.02-4.37 3.02 7 XLB +123TE T 4.44-4.82 0.411 11 XLG 123TE T -123TE T 21.804-22.989 |] KLL AUGER -123TE T 25.814-27.47 |] 7.0 4 ^KLX AUGER -123TE T 29.8-31.81 |] KXY AUGER -123TE T 2.3-4.8 89.7 7 L AUGER +123TE T 21.804-22.989 |] KLL AUGER +123TE T 25.814-27.47 |] 7.0 4 KLX AUGER +123TE T 29.8-31.81 |] KXY AUGER +123TE T 2.3-4.8 89.7 7 L AUGER 123TE P 247.4 2 11/2- 119.3 D 1 123TE N 1.0 1.0 1 1.0 123TE L 0 1/2+ 12E12 Y 123TE L 158.99 3/2+ 196 PS 9 -123TE G 158.97 5 83.99 8 M1+E2 0.0111 0.1918 19 +123TE G 158.97 5 83.99 8M1+E2 0.0111 0.1918 19 123TE2 G KC=0.1648 16$LC=0.02160 22$MC=0.00433 13 123TE L 247.4 11/2- 119.5 D 1 123TE G 88.46 7 0.0909 27M4 1099 33 123TE2 G KC=463 14$LC=493 15$MC=118.0 35 -123TE G 247.4 2 3.44E-4 34E5 7.75 30 -123TE2 G KC=3.0 1$LC=3.75 21$MC=0.84 3 +123TE G 247.4 2 0.00034434E5 7.75 30 +123TE2 G KC=3.0 1$LC=3.75 21$MC=0.84 3 diff --git a/HEN_HOUSE/spectra/lnhb/Te-127.txt b/HEN_HOUSE/spectra/lnhb/Te-127.txt index 91a285054..5eabefd58 100644 --- a/HEN_HOUSE/spectra/lnhb/Te-127.txt +++ b/HEN_HOUSE/spectra/lnhb/Te-127.txt @@ -5,68 +5,68 @@ 127I 2C 1968Qa02, 1970Ap02, 1970Bo22, 1977La19, 1977Ge10, 1977Kr13, 1980Kr22, 127I 3C 1996Sc06, 1998ScZM, 1999ScZX, 2002Ba25, 2002Ra45, 2003Au03, 2003De44, 127I 4C 2008Ki07, 2011Ha31, 2012Au06 -127I T Auger electrons and ^X ray energies and emission intensities: -127I T {U Energy (keV)} {U Intensity } {U Line } +127I T Auger electrons and X ray energies and emission intensities: +127I T {U Energy (keV)} {U Intensity} {U Line} 127I T -127I T 28.3175 0.0309 7 XKA2 -127I T 28.6123 0.0574 12 XKA1 +127I T 28.3175 0.0309 7 XKA2 +127I T 28.6123 0.0574 12 XKA1 127I T -127I T 32.2397 |] XKB3 -127I T 32.2951 |] 0.0165 4 XKB1 -127I T 32.539 |] XKB5II -127I T 32.55 |] XKB5I +127I T 32.2397 |] XKB3 +127I T 32.2951 |] 0.0165 4 XKB1 +127I T 32.539 |] XKB5II +127I T 32.55 |] XKB5I 127I T -127I T 33.042 |] XKB2 -127I T 33.12 |] 0.00374 12 XKB4 -127I T 33.166 |] XKO23 +127I T 33.042 |] XKB2 +127I T 33.12 |] 0.00374 12 XKB4 +127I T 33.166 |] XKO23 127I T -127I T 3.485-5.06 0.0119 6 XL (total) -127I T 3.485 0.000226 8 XLL -127I T 3.927-3.938 0.00597 18 XLA -127I T 3.779 0.000088 3 XLC -127I T 4.221-4.508 0.00476 11 XLB -127I T 4.801-5.06 0.000678 17 XLG +127I T 3.485-5.06 0.0119 6 XL (total) +127I T 3.485 0.000226 8 XLL +127I T 3.927-3.938 0.00597 18 XLA +127I T 3.779 0.000088 3 XLC +127I T 4.221-4.508 0.00476 11 XLB +127I T 4.801-5.06 0.00067817 XLG 127I T -127I T 22.659-23.909 |] KLL AUGER -127I T 26.853-28.609 |] 0.0145 6 ^KLX AUGER -127I T 31.02-33.16 |] KXY AUGER -127I T 2.38-3.88 0.1174 18 L AUGER +127I T 22.659-23.909 |] KLL AUGER +127I T 26.853-28.609 |] 0.0145 6 KLX AUGER +127I T 31.02-33.16 |] KXY AUGER +127I T 2.38-3.88 0.1174 18 L AUGER 127TE P 0.0 3/2+ 9.35 H 10 702 4 127I N 1.0 1.0 1 1.0 127I L 0 5/2+ STABLE -127I B 702 4 98.780 14 5.49 2 +127I B 702 4 98.780 14 5.49 127I S B EAV=227.8 16 127I L 57.608 117/2+ -127I G 57.608 110.0306 6 M1+E2 -0.083 5 3.72 6 -127I 2 G KC=3.16 5$LC=0.449 8$MC=0.0910 16 +127I G 57.608 110.0306 6M1+E2 -0.083 5 3.72 6 +127I 2 G KC=3.16 5$LC=0.449 8$MC=0.0910 16 127I L 202.860 8 3/2+ -127I B 499 4 0.025 3 8.57 +127I B 499 4 0.025 3 8.57 127I S B EAV=153.0 15 -127I G 145.252 140.0040 6 E2 0.471 7 -127I 2 G KC=0.357 5$LC=0.0907 13$MC=0.0189 3 -127I G 202.860 8 0.056 2 M1+E2 0.52 5 0.1143 22 -127I 2 G KC=0.0965 17$LC=0.0142 5$MC=0.00289 10 +127I G 145.252 140.0040 6E2 0.471 7 +127I 2 G KC=0.357 5$LC=0.0907 13$MC=0.0189 3 +127I G 202.860 8 0.056 2M1+E2 0.52 5 0.1143 22 +127I 2 G KC=0.0965 17$LC=0.0142 5$MC=0.00289 10 127I L 374.992 9 1/2+ -127I B 327 4 0.0006 3 9.58 2 +127I B 327 4 0.0006 3 9.58 127I S B EAV=94.5 13 -127I G 172.132 120.0003 2 M1+E2 -0.085 6 0.1650 24 -127I 2 G KC=0.1419 20$LC=0.0185 3$MC=0.00373 6 -127I G 374.991 9 0.0003 2 E2 0.0199 3 -127I 2 G KC=0.01671 24$LC=0.00257 4$MC=5.24E-4 8 +127I G 172.132 120.0003 2M1+E2 -0.085 6 0.1650 24 +127I 2 G KC=0.1419 20$LC=0.0185 3$MC=0.00373 6 +127I G 374.991 9 0.0003 2E2 0.0199 3 +127I 2 G KC=0.01671 24$LC=0.00257 4$MC=5.24E-4 8 127I L 417.99 6 5/2+ -127I B 284 4 1.19 2 6.086 2 +127I B 284 4 1.19 2 6.086 127I S B EAV=80.7 13 -127I G 215.13 6 0.039 2 M1+E2 -0.203 15 0.0910 13 -127I 2 G KC=0.0782 11$LC=0.01031 16$MC=0.00208 4 -127I G 360.38 6 0.136 2 M1+E2 0.194 15 0.0232 4 -127I 2 G KC=0.0201 3$LC=0.00256 4$MC=5.14E-4 8 +127I G 215.13 6 0.039 2M1+E2 -0.203 15 0.0910 13 +127I 2 G KC=0.0782 11$LC=0.01031 16$MC=0.00208 4 +127I G 360.38 6 0.136 2M1+E2 0.194 15 0.0232 4 +127I 2 G KC=0.0201 3$LC=0.00256 4$MC=5.14E-4 8 127I G 417.99 6 0.997 11M1+E2 -0.08 3 0.0159823 -127I 2 G KC=0.01381 20$LC=1741E-6 25$MC=3.50E-4 5 +127I 2 G KC=0.01381 20$LC=1741E-6 25$MC=3.50E-4 5 127I L 618.31 133/2+ -127I B 84 4 0.00013 2 8.38 +127I B 84 4 0.00013 2 8.38 127I S B EAV=21.8 11 -127I G 618.31 130.00013 2 M1+E2 1.0 5 0.0055 4 -127I 2 G KC=0.0047 4$LC=0.00061 3$MC=1.23E-4 6 +127I G 618.31 130.00013 2M1+E2 1.0 5 0.0055 4 +127I 2 G KC=0.0047 4$LC=0.00061 3$MC=1.23E-4 6 127I L 628.69 167/2+ 127I L 650.92 8 9/2+ 127I L 716.50 6 (11/2)+ diff --git a/HEN_HOUSE/spectra/lnhb/Te-127m.txt b/HEN_HOUSE/spectra/lnhb/Te-127m.txt index f8fd5851a..db89df7d7 100644 --- a/HEN_HOUSE/spectra/lnhb/Te-127m.txt +++ b/HEN_HOUSE/spectra/lnhb/Te-127m.txt @@ -5,39 +5,39 @@ 127TE2C 1967Ge10, 1970Ap02, 1972Ka31, 1972Ka61, 1977So06, 1977Kr13, 1977La19, 127TE3C 1980Kr22, 1996Sc06, 1998ScZM, 1999ScZX, 2002Ba25, 2002Ra45, 2003Au03, 127TE4C 2003De44, 2008Ea01, 2008Ki07, 2011Ha31, 2012Au06 -127TE T Auger electrons and ^X ray energies and emission intensities: -127TE T {U Energy (keV)} {U Intensity } {U Line } +127TE T Auger electrons and X ray energies and emission intensities: +127TE T {U Energy (keV)} {U Intensity} {U Line} 127TE T -127TE T 27.202 10.3 3 XKA2 -127TE T 27.4726 19.3 5 XKA1 +127TE T 27.202 10.3 3 XKA2 +127TE T 27.4726 19.3 5 XKA1 127TE T -127TE T 30.9446 |] XKB3 -127TE T 30.996 |] 5.51 15 XKB1 -127TE T 31.232 |] XKB5II -127TE T 31.242 |] XKB5I +127TE T 30.9446 |] XKB3 +127TE T 30.996 |] 5.51 15 XKB1 +127TE T 31.232 |] XKB5II +127TE T 31.242 |] XKB5I 127TE T -127TE T 31.7008 |] XKB2 -127TE T 31.774 |] 1.20 5 XKB4 -127TE T 31.182 |] XKO23 +127TE T 31.7008 |] XKB2 +127TE T 31.774 |] 1.20 5 XKB4 +127TE T 31.182 |] XKO23 127TE T -127TE T 3.335-4.829 7.0 3 XL (total) -127TE T 3.335 0.146 5 XLL -127TE T 3.759-3.77 3.86 11 XLA -127TE T 3.605 0.0369 13 XLC -127TE T 4.03-4.302 2.45 5 XLB -127TE T 4.572-4.829 0.333 8 XLG +127TE T 3.335-4.829 7.0 3 XL (total) +127TE T 3.335 0.146 5 XLL +127TE T 3.759-3.77 3.86 11 XLA +127TE T 3.605 0.0369 13 XLC +127TE T 4.03-4.302 2.45 5 XLB +127TE T 4.572-4.829 0.333 8 XLG 127TE T -127TE T 21.804-22.989 |] KLL AUGER -127TE T 25.814-27.47 |] 5.19 21 ^KLX AUGER -127TE T 29.8-31.81 |] KXY AUGER -127TE T 2.29-3.72 74.3 10 L AUGER +127TE T 21.804-22.989 |] KLL AUGER +127TE T 25.814-27.47 |] 5.19 21 KLX AUGER +127TE T 29.8-31.81 |] KXY AUGER +127TE T 2.29-3.72 74.3 10 L AUGER 127TE P 88.23 7 11/2- 106.1 D 7 127TE N 1.028E0 1.028E0 0.972699 1.028E0 127TE L 0 3/2+ 9.35 H 10 127TE L 61.161 191/2+ 127TE L 88.23 7 11/2- 106.1 D 7 127TE G 88.23 7 0.0854 16M4 1138 17 -127TE2 G KC=486 7$LC=506 8$MC=120.4 18 +127TE2 G KC=486 7$LC=506 8$MC=120.4 18 127I 127TE B- DECAY (106.1 D) 127I H TYP=Full$AUT=A.L. Nichols$CUT=31-MAY-2012$ @@ -46,59 +46,59 @@ 127I 2C 1967Ge10, 1970Ap02, 1972Ka31, 1972Ka61, 1977So06, 1977Kr13, 1977La19, 127I 3C 1980Kr22, 1996Sc06, 1998ScZM, 1999ScZX, 2002Ba25, 2002Ra45, 2003Au03, 127I 4C 2003De44, 2008Ea01, 2008Ki07, 2011Ha31, 2012Au06 -127I T Auger electrons and ^X ray energies and emission intensities: -127I T {U Energy (keV)} {U Intensity } {U Line } +127I T Auger electrons and X ray energies and emission intensities: +127I T {U Energy (keV)} {U Intensity} {U Line} 127I T -127I T 28.3175 0.459 12 XKA2 -127I T 28.6123 0.852 21 XKA1 +127I T 28.3175 0.459 12 XKA2 +127I T 28.6123 0.852 21 XKA1 127I T -127I T 32.2397 |] XKB3 -127I T 32.2951 |] 0.245 7 XKB1 -127I T 32.539 |] XKB5II -127I T 32.55 |] XKB5I +127I T 32.2397 |] XKB3 +127I T 32.2951 |] 0.245 7 XKB1 +127I T 32.539 |] XKB5II +127I T 32.55 |] XKB5I 127I T -127I T 33.042 |] XKB2 -127I T 33.12 |] 0.0555 19 XKB4 -127I T 33.166 |] XKO23 +127I T 33.042 |] XKB2 +127I T 33.12 |] 0.0555 19 XKB4 +127I T 33.166 |] XKO23 127I T -127I T 3.485-5.06 0.177 9 XL (total) -127I T 3.485 0.00336 11 XLL -127I T 3.927-3.938 0.089 3 XLA -127I T 3.779 0.00130 5 XLC -127I T 4.221-4.508 0.0707 17 XLB -127I T 4.801-5.06 0.0101 3 XLG +127I T 3.485-5.06 0.177 9 XL (total) +127I T 3.485 0.00336 11 XLL +127I T 3.927-3.938 0.089 3 XLA +127I T 3.779 0.00130 5 XLC +127I T 4.221-4.508 0.0707 17 XLB +127I T 4.801-5.06 0.0101 3 XLG 127I T -127I T 22.659-23.909 |] KLL AUGER -127I T 26.853-28.609 |] 0.216 9 ^KLX AUGER -127I T 31.02-33.16 |] KXY AUGER -127I T 2.37-3.88 1.74 3 L AUGER +127I T 22.659-23.909 |] KLL AUGER +127I T 26.853-28.609 |] 0.216 9 KLX AUGER +127I T 31.02-33.16 |] KXY AUGER +127I T 2.37-3.88 1.74 3 L AUGER 127TE P 88.23 7 11/2- 106.1 D 7 701.8 40 127I N 3.663E1 3.663E1 0.0273 3.663E1 127I L 0 5/2+ STABLE 127I L 57.608 117/2+ -127I B 732 4 2.71 7 9.873 3U +127I B 732 4 2.71 7 9.873 1U 127I S B EAV=255.9 15 -127I G 57.608 110.578 10M1+E2 -0.083 5 3.72 6 -127I 2 G KC=3.16 5$LC=0.449 8$MC=0.0910 16 +127I G 57.608 110.578 10M1+E2 -0.083 5 3.72 6 +127I 2 G KC=3.16 5$LC=0.449 8$MC=0.0910 16 127I L 202.860 8 3/2+ 127I L 374.992 9 1/2+ 127I L 417.99 6 5/2+ 127I L 618.31 133/2+ 127I L 628.69 167/2+ -127I B 161 4 0.00009 2 11.3 3U +127I B 161 4 0.00009 2 11.3 1U 127I S B EAV=52.9 14 -127I G 628.69 160.00009 2 M1+E2 1.0 5 0.0052 4 -127I 2 G KC=0.0045 4$LC=0.00058 3$MC=1.17E-4 6 +127I G 628.69 160.00009 2M1+E2 1.0 5 0.0052 4 +127I 2 G KC=0.0045 4$LC=0.00058 3$MC=1.17E-4 6 127I L 650.92 8 9/2+ -127I B 139 4 0.0027 2 10.18 1U +127I B 139 4 0.0027 2 10.18 1 127I S B EAV=37.2 12 -127I G 593.31 8 0.0024 2 M1+E2 -0.23 3 0.0066810 -127I 2 G KC=0.00578 9$LC=7.22E-4 11$MC=1448E-7 21 -127I G 650.92 8 0.0003 2 E2 0.004236 -127I 2 G KC=0.00362 5$LC=4.88E-4 7$MC=9.85E-5 14 +127I G 593.31 8 0.0024 2M1+E2 -0.23 3 0.0066810 +127I 2 G KC=0.00578 9$LC=7.22E-4 11$MC=1448E-7 21 +127I G 650.92 8 0.0003 2E2 0.00423 6 +127I 2 G KC=0.00362 5$LC=4.88E-4 7$MC=9.85E-5 14 127I L 716.50 6 11/2+ -127I B 74 4 0.0141 6 8.61 +127I B 74 4 0.0141 6 8.61 127I S B EAV=19.1 11 -127I G 658.89 6 0.0140 6 E2 0.004106 -127I 2 G KC=0.00351 5$LC=4.72E-4 7$MC=9.53E-5 14 +127I G 658.89 6 0.0140 6E2 0.00410 6 +127I 2 G KC=0.00351 5$LC=4.72E-4 7$MC=9.53E-5 14 diff --git a/HEN_HOUSE/spectra/lnhb/Te-132.txt b/HEN_HOUSE/spectra/lnhb/Te-132.txt index 8d53b9509..8d60b0b3c 100644 --- a/HEN_HOUSE/spectra/lnhb/Te-132.txt +++ b/HEN_HOUSE/spectra/lnhb/Te-132.txt @@ -6,45 +6,45 @@ 132I C References: 1956Fl15, 1958Ch28, 1965An05, 1966Fr02, 1971BaZW, 1977La19, 132I 2C 1979Bo26, 1981Yo02, 1983Wa26, 1996Sc06, 1998ScZM, 1999ScZX, 2002Ba85, 132I 3C 2002Ra45, 2003Au03, 2005Kh07, 2008Ki07 -132I T Auger electrons and ^X ray energies and emission intensities: -132I T {U Energy (keV)} {U Intensity } {U Line } +132I T Auger electrons and X ray energies and emission intensities: +132I T {U Energy (keV)} {U Intensity} {U Line} 132I T -132I T 28.3175 20.6 5 XKA2 -132I T 28.6123 38.2 9 XKA1 +132I T 28.3175 20.6 5 XKA2 +132I T 28.6123 38.2 9 XKA1 132I T -132I T 32.2397 |] XKB3 -132I T 32.2951 |] 11.0 3 XKB1 -132I T 32.544 |] XKB5II +132I T 32.2397 |] XKB3 +132I T 32.2951 |] 11.0 3 XKB1 +132I T 32.544 |] XKB5II 132I T -132I T 33.042 |] XKB2 -132I T 33.12 |] 2.49 9 XKB4 -132I T 33.166 |] XKO23 +132I T 33.042 |] XKB2 +132I T 33.12 |] 2.49 9 XKB4 +132I T 33.166 |] XKO23 132I T -132I T 3.485-5.065 7.9 4 XL (total) +132I T 3.485-5.065 7.9 4 XL (total) 132I T 3.485 XLL -132I T 3.926-3.938 3.96 12 XLA -132I T 3.78 0.0583 20 XLC -132I T 4.221-4.508 3.16 8 XLB -132I T 4.802-5.065 0.451 12 XLG +132I T 3.926-3.938 3.96 12 XLA +132I T 3.78 0.0583 20 XLC +132I T 4.221-4.508 3.16 8 XLB +132I T 4.802-5.065 0.451 12 XLG 132I T -132I T 22.659-23.909 |] KLL AUGER -132I T 26.853-28.609 |] 9.7 3 ^KLX AUGER -132I T 31.02-33.16 |] KXY AUGER -132I T 2.37-3.88 78.0 13 L AUGER +132I T 22.659-23.909 |] KLL AUGER +132I T 26.853-28.609 |] 9.7 3 KLX AUGER +132I T 31.02-33.16 |] KXY AUGER +132I T 2.37-3.88 78.0 13 L AUGER 132TE P 0.0 0+ 3.230 D 13 518 4 132I N 1.0 1.0 1 1.0 132I L 0 4+ 2.295 H 13 132I L 49.72 1 3+ 7.14 NS 14 -132I G 49.72 1 15.1 3 M1 5.62 8 -132I 2 G KC=4.83 7$LC=0.638 9$MC=0.1286 18 +132I G 49.72 1 15.1 3M1 5.62 8 +132I 2 G KC=4.83 7$LC=0.638 9$MC=0.1286 18 132I L 161.52 7 2+ 3.57 NS 7 -132I G 111.81 8 1.85 18M1+E2 0.58 6 0.71 3 -132I 2 G KC=0.562 17$LC=0.115 9$MC=0.0238 18 +132I G 111.81 8 1.85 18M1+E2 0.58 6 0.71 3 +132I 2 G KC=0.562 17$LC=0.115 9$MC=0.0238 18 132I L 277.86 6 1+ 1.42 NS 2 132I B 240 4 100 4.85 132I S B EAV=67.0 13 -132I G 116.34 131.97 7 M1+E2 0.53 5 0.606 20 -132I 2 G KC=0.489 13$LC=0.093 6$MC=0.0193 13 +132I G 116.34 131.97 7M1+E2 0.53 5 0.606 20 +132I 2 G KC=0.489 13$LC=0.093 6$MC=0.0193 13 132I G 228.327 3 88.12 13E2 0.0990 14 -132I 2 G KC=0.0802 12$LC=0.01507 21$MC=0.00311 5 +132I 2 G KC=0.0802 12$LC=0.01507 21$MC=0.00311 5 diff --git a/HEN_HOUSE/spectra/lnhb/Th-228.txt b/HEN_HOUSE/spectra/lnhb/Th-228.txt index 4d254dd15..121c11713 100644 --- a/HEN_HOUSE/spectra/lnhb/Th-228.txt +++ b/HEN_HOUSE/spectra/lnhb/Th-228.txt @@ -7,77 +7,77 @@ 224RA4C 1993Bo20, 1993Ba72, 1995Ar33, 1996Sc06, 1997Ar05, 1997Tr17, 1998Ak04, 224RA5C 1998ScZM, 1999ScZX, 2002Un02, 2002Ba85, 2002Ra45, 2003Au03, 2007BeZP, 224RA6C 2008Ki07 -224RA T Auger electrons and ^X ray energies and emission intensities: -224RA T {U Energy (keV)} {U Intensity } {U Line } +224RA T Auger electrons and X ray energies and emission intensities: +224RA T {U Energy (keV)} {U Intensity} {U Line} 224RA T -224RA T 85.43 0.0180 3 XKA2 -224RA T 88.47 0.0295 5 XKA1 +224RA T 85.43 0.0180 3 XKA2 +224RA T 88.47 0.0295 5 XKA1 224RA T -224RA T 99.432 |] XKB3 -224RA T 100.13 |] 0.01034 21 XKB1 -224RA T 100.738 |] XKB5II +224RA T 99.432 |] XKB3 +224RA T 100.13 |] 0.01034 21 XKB1 +224RA T 100.738 |] XKB5II 224RA T -224RA T 102.89 |] XKB2 -224RA T 103.295 |] 0.00339 9 XKB4 -224RA T 103.74 |] XKO23 +224RA T 102.89 |] XKB2 +224RA T 103.295 |] 0.00339 9 XKB4 +224RA T 103.74 |] XKO23 224RA T -224RA T 10.6241-18.3539 8.6 4 XL (total) -224RA T 10.6241 0.166 6 XLL -224RA T 12.1957-12.3381 2.86 9 XLA -224RA T 13.6624 0.109 4 XLC -224RA T 14.2373-16.1261 4.67 15 XLB -224RA T 17.2756-18.3539 1.09 4 XLG +224RA T 10.6241-18.3539 8.6 4 XL (total) +224RA T 10.6241 0.166 6 XLL +224RA T 12.1957-12.3381 2.86 9 XLA +224RA T 13.6624 0.109 4 XLC +224RA T 14.2373-16.1261 4.67 15 XLB +224RA T 17.2756-18.3539 1.09 4 XLG 224RA T -224RA T 65.149-72.729 |] KLL AUGER -224RA T 79.721-88.466 |] 0.0020 3 ^KLX AUGER -224RA T 94.27-103.91 |] KXY AUGER -224RA T 5.71-12.04 10.4 4 L AUGER +224RA T 65.149-72.729 |] KLL AUGER +224RA T 79.721-88.466 |] 0.0020 3 KLX AUGER +224RA T 94.27-103.91 |] KXY AUGER +224RA T 5.71-12.04 10.4 4 L AUGER 228TH P 0.0 0+ 1.9126 Y 9 5520.08 22 224RA N 1.0 1.0 1 1.0 224RA L 0 0+ 3.631 D 2 224RA A 5423.24 2273.4 5 1 224RA L 84.373 3 2+ 224RA A 5340.35 2226.0 5 0.958 -224RA G 84.373 3 1.19 3 E2 21.2 3 -224RA2 G KC=$LC=15.57 22$MC=4.24 6 +224RA G 84.373 3 1.19 3E2 21.2 3 +224RA2 G LC=15.57 22$MC=4.24 6 224RA L 215.985 4 1- 224RA A 5211.05 220.408 7 10.7 -224RA G 131.612 5 0.127 2 E1 0.247 4 -224RA2 G KC=0.194 3$LC=0.0406 6$MC=0.00977 14 -224RA G 215.985 4 0.246 4 E1 0.0752 11 -224RA2 G KC=0.0600 9$LC=0.01148 16$MC=0.00274 4 +224RA G 131.612 5 0.127 2E1 0.247 4 +224RA2 G KC=0.194 3$LC=0.0406 6$MC=0.00977 14 +224RA G 215.985 4 0.246 4E1 0.0752 11 +224RA2 G KC=0.0600 9$LC=0.01148 16$MC=0.00274 4 224RA L 250.783 5 4+ 224RA A 5176.86 220.218 4 12.5 224RA G 166.410 4 0.1004 14E2 1.164 17 -224RA2 G KC=0.225 4$LC=0.691 10$MC=0.187 3 +224RA2 G KC=0.225 4$LC=0.691 10$MC=0.187 3 224RA L 290.36 4 (3)- 224RA A 5137.97 220.036 6 44 -224RA G 74.38 4 0.00039 14[E2] 38.6 6 -224RA2 G KC=$LC=28.3 4$MC=7.71 11 -224RA G 205.99 4 0.0188 5 [E1] 0.0841 12 -224RA2 G KC=0.0671 10$LC=0.01292 18$MC=0.00309 5 +224RA G 74.38 4 0.00039 14[E2] 38.6 6 +224RA2 G LC=28.3 4$MC=7.71 11 +224RA G 205.99 4 0.0188 5[E1] 0.0841 12 +224RA2 G KC=0.0671 10$LC=0.01292 18$MC=0.00309 5 224RA L 433.07 10(5)- 224RA A 4997.76 2410000E-92 21400 -224RA G 142.71 111.3E-6 4 [E2] 2.14 3 -224RA2 G KC=0.279 4$LC=1.368 20$MC=0.372 6 +224RA G 142.71 111.3E-6 4[E2] 2.14 3 +224RA2 G KC=0.279 4$LC=1.368 20$MC=0.372 6 224RA G 182.29 105.1E-6 18[E1] 0.1126 16 -224RA2 G KC=0.0894 13$LC=0.01757 25$MC=0.00421 6 +224RA2 G KC=0.0894 13$LC=0.01757 25$MC=0.00421 6 224RA L 479.20 18(6)+ 224RA A 4952.5 3 24000E-95 4600 -224RA G 228.42 181.8E-5 4 [E2] 0.366 6 -224RA2 G KC=0.1244 18$LC=0.178 3$MC=0.0479 7 +224RA G 228.42 180.000018 4[E2] 0.366 6 +224RA2 G KC=0.1244 18$LC=0.178 3$MC=0.0479 7 224RA L 916.34 7 0+ 224RA A 4522.97 2317000E-93 7 -224RA G 700.36 7 3E-6 1 E1 0.006119 -224RA2 G KC=0.00502 7$LC=8.34E-4 12$MC=1.96E-4 3 -224RA G 831.97 7 1.4E-5 2 E2 0.0128918 -224RA2 G KC=0.00970 14$LC=0.00240 4$MC=5.94E-4 9 +224RA G 700.36 7 0.000003 1E1 0.00611 9 +224RA2 G KC=0.00502 7$LC=8.34E-4 12$MC=1.96E-4 3 +224RA G 831.97 7 0.000014 2E2 0.0128918 +224RA2 G KC=0.00970 14$LC=0.00240 4$MC=5.94E-4 9 224RA L 992.65 6 (2)+ 224RA A 4448.00 2345000E-17 7.2 -224RA G 741.87 6 1.4E-6 4 [E2] 0.0162523 -224RA2 G KC=0.01196 17$LC=0.00322 5$MC=8.03E-4 12 -224RA G 908.28 6 1.7E-6 5 [M1+E2] 1.0 2 0.024 3 -224RA2 G KC=0.0190 24$LC=0.0036 4$MC=0.00087 9 -224RA G 992.65 6 1.4E-6 4 [E2] 0.0091313 -224RA2 G KC=0.00705 10$LC=1569E-6 22$MC=3.84E-4 6 +224RA G 741.87 6 1.4E-6 4[E2] 0.0162523 +224RA2 G KC=0.01196 17$LC=0.00322 5$MC=8.03E-4 12 +224RA G 908.28 6 1.7E-6 5[M1+E2] 1.0 2 0.024 3 +224RA2 G KC=0.0190 24$LC=0.0036 4$MC=0.00087 9 +224RA G 992.65 6 1.4E-6 4[E2] 0.0091313 +224RA2 G KC=0.00705 10$LC=1569E-6 22$MC=3.84E-4 6 diff --git a/HEN_HOUSE/spectra/lnhb/Th-231.txt b/HEN_HOUSE/spectra/lnhb/Th-231.txt index 5efc7ebae..d7e624e52 100644 --- a/HEN_HOUSE/spectra/lnhb/Th-231.txt +++ b/HEN_HOUSE/spectra/lnhb/Th-231.txt @@ -2,167 +2,167 @@ 231PA H TYP=Full$AUT=X. Huang$CUT=31-MAY-2007$ 231PA C Evaluation history: Type=Full;Author=X. Huang;Cutoff date=31-MAY-2007 231PA C References: 2008Ki07 -231PA T Auger electrons and ^X ray energies and emission intensities: -231PA T {U Energy (keV)} {U Intensity } {U Line } +231PA T Auger electrons and X ray energies and emission intensities: +231PA T {U Energy (keV)} {U Intensity} {U Line} 231PA T -231PA T 92.288 0.37 4 XKA2 -231PA T 95.869 0.59 7 XKA1 +231PA T 92.288 0.37 4 XKA2 +231PA T 95.869 0.59 7 XKA1 231PA T -231PA T 107.595 |] XKB3 -231PA T 108.422 |] 0.21 2 XKB1 -231PA T 109.072 |] XKB5II +231PA T 107.595 |] XKB3 +231PA T 108.422 |] 0.21 2 XKB1 +231PA T 109.072 |] XKB5II 231PA T -231PA T 111.405 |] XKB2 -231PA T 111.87 |] 0.071 8 XKB4 -231PA T 112.38 |] XKO23 +231PA T 111.405 |] XKB2 +231PA T 111.87 |] 0.071 8 XKB4 +231PA T 112.38 |] XKO23 231PA T -231PA T 11.3676-20.1126 65 3 XL (total) +231PA T 11.3676-20.1126 65 3 XL (total) 231PA T 11.3676 XLL 231PA T 13.1215-13.2887 XLA 231PA T 14.9488 XLC 231PA T 15.3584-17.6655 XLB 231PA T 18.9396-20.1126 XLG 231PA T -231PA T 70.081-78.822 |] KLL AUGER -231PA T 85.989-95.858 |] 0.038 5 ^KLX AUGER -231PA T 101.87-112.59 |] KXY AUGER -231PA T 5.9-21 68 3 L AUGER +231PA T 70.081-78.822 |] KLL AUGER +231PA T 85.989-95.858 |] 0.038 5 KLX AUGER +231PA T 101.87-112.59 |] KXY AUGER +231PA T 5.9-21 68 3 L AUGER 231TH P 0.0 5/2+ 25.522 H 10 391.6 15 231PA N 1.0 1.0 1 1.0 231PA L 0 3/2- 32670 Y 260 -231PA B 391.6 150.022 7 9.57 1U +231PA B 391.6 150.022 7 9.57 1 231PAS B EAV=111.6 5 231PA L 9.206 251/2- 231PA G 9.2 231PA L 58.5699 247/2- 274 PS 10 -231PA B 333.0 150.17 17 8.2 1U +231PA B 333.0 150.17 17 8.2 1 231PAS B EAV=93.4 5 231PA G 58.5700 240.480 16E2 155.5 22 -231PA2 G KC=$LC=113.6 16$MC=31.3 5 +231PA2 G LC=113.6 16$MC=31.3 5 231PA L 77.685 175/2- -231PA B 313.9 150.43 2 7.97 +231PA B 313.9 150.43 2 7.97 231PAS B EAV=87.6 5 231PA G 68.5 1 0.00590 15E2 73.3 12 -231PA2 G KC=$LC=53.5 8$MC=14.8 3 -231PA G 77.69 0.0042 7 +231PA2 G LC=53.5 8$MC=14.8 3 +231PA G 77.69 0.0042 7 231PA L 84.2148 135/2+ 45.1 NS 13 231PA B 307.4 1529 18 6.1 231PAS B EAV=85.6 5 -231PA G 25.64 2 13.9 7 E1 4.37 7 -231PA2 G KC=$LC=3.26 5$MC=0.843 12 -231PA G 84.2140 136.70 7 E1 2.50 25 -231PA2 G KC=$LC=1.77 2$MC=0.57 10 +231PA G 25.64 2 13.9 7E1 4.37 7 +231PA2 G LC=3.26 5$MC=0.843 12 +231PA G 84.2140 136.70 7E1 2.50 25 +231PA2 G LC=1.77 2$MC=0.57 10 231PA L 101.4092 217/2+ 0.7 NS -231PA B 290.2 1541 16 5.88 2 +231PA B 290.2 1541 16 5.88 231PAS B EAV=80.4 5 -231PA G 17.2 (M1) 193.0000 -231PA2 G KC=$LC=$MC=135.700 0 -231PA G 42.86 7 0.0596 15[E1] 1.14 2 -231PA2 G KC=$LC=0.85 2$MC=0.21 1 +231PA G 17.2 (M1) 193 +231PA2 G MC=135.7 +231PA G 42.86 7 0.0596 15[E1] 1.14 2 +231PA2 G LC=0.85 2$MC=0.21 1 231PA L 102.2692 133/2+ 0.7 NS -231PA B 289.3 1513 8 6.4 2 +231PA B 289.3 1513 8 6.4 231PAS B EAV=80.1 5 -231PA G 18.07 M1+E2 0.14 12 800.0000 -231PA2 G KC=$LC=349.000 0$MC=304.000 0 -231PA G 93.02 4 0.040 3 [E1] 0.1463 21 -231PA2 G KC=$LC=0.110 2$MC=0.0269 4 +231PA G 18.07 M1+E2 0.14 12 800 +231PA2 G LC=349 $MC=304 +231PA G 93.02 4 0.040 3[E1] 0.1463 21 +231PA2 G LC=0.110 2$MC=0.0269 4 231PA G 102.2700 130.441 11E1 0.1141 16 -231PA2 G KC=$LC=0.086 1$MC=0.0210 3 +231PA2 G LC=0.086 1$MC=0.0210 3 231PA L 111.653 12(9/2)+ 231PA G 10.25 231PA L 174.161 4 (5/2)- 231PA B 217.4 151.36 24 6.96 231PAS B EAV=58.9 5 -231PA G 72.7510 250.260 17[E1] 0.280 4 -231PA2 G KC=$LC=0.211 3$MC=0.0517 7 -231PA G 89.95 2 1.01 3 E1 0.1598 22 -231PA2 G KC=$LC=0.121 2$MC=0.0294 4 -231PA G 115.63 3 0.00110 16[M1+E2] 10 4 -231PA2 G KC=5 5$LC=3.3 12$MC=0.9 4 -231PA G 165.00 5 0.00348 14[E2] 1.464 2 -231PA2 G KC=0.209 3$LC=0.917 13$MC=0.252 4 -231PA G 174.15 2 0.0180 6 [M1+E2] 2.7 15 -231PA2 G KC=1.8 16$LC=0.68 5$MC=0.177 22 +231PA G 72.7510 250.260 17[E1] 0.280 4 +231PA2 G LC=0.211 3$MC=0.0517 7 +231PA G 89.95 2 1.01 3E1 0.1598 22 +231PA2 G LC=0.121 2$MC=0.0294 4 +231PA G 115.63 3 0.00110 16[M1+E2] 10 4 +231PA2 G KC=5 5$LC=3.3 12$MC=0.9 4 +231PA G 165.00 5 0.00348 14[E2] 1.464 2 +231PA2 G KC=0.209 3$LC=0.917 13$MC=0.252 4 +231PA G 174.15 2 0.0180 6[M1+E2] 2.7 15 +231PA2 G KC=1.8 16$LC=0.68 5$MC=0.177 22 231PA L 183.4962 175/2+ 0.19 NS 231PA B 208.1 1512.2 15 5.95 231PAS B EAV=56.2 5 231PA G 81.2280 140.905 23M1(+E2) 0.14 14 8.1 14 -231PA2 G KC=$LC=6.1 10$MC=1.5 3 +231PA2 G LC=6.1 10$MC=1.5 3 231PA G 82.0870 130.418 13M1(+E2) 0.14 14 7.9 13 -231PA2 G KC=$LC=5.9 9$MC=1.5 3 -231PA G 99.278 3 0.137 6 M1+E2 0.50 6 6.0 4 -231PA2 G KC=$LC=4.43 24$MC=1.13 7 -231PA G 105.81 3 0.0079 5 [E1] 0.1043 15 -231PA2 G KC=$LC=0.0787 11$MC=0.0192 3 -231PA G 124.914 170.0590 15E1 0.294 4 -231PA2 G KC=0.226 4$LC=0.0511 8$MC=0.01241 18 -231PA G 183.480 250.0335 8 E1 0.1181 17 -231PA2 G KC=0.0928 13$LC=0.0191 3$MC=0.00463 7 +231PA2 G LC=5.9 9$MC=1.5 3 +231PA G 99.2780 300.137 6M1+E2 0.50 6 6.0 4 +231PA2 G LC=4.43 24$MC=1.13 7 +231PA G 105.81 3 0.0079 5[E1] 0.1043 15 +231PA2 G LC=0.0787 11$MC=0.0192 3 +231PA G 124.914 170.0590 15E1 0.294 4 +231PA2 G KC=0.226 4$LC=0.0511 8$MC=0.01241 18 +231PA G 183.480 250.0335 8E1 0.1181 17 +231PA2 G KC=0.0928 13$LC=0.0191 3$MC=0.00463 7 231PA L 218.240 13(7/2)- -231PA B 173.4 150.31 23 7.3 1U +231PA B 173.4 150.31 23 7.3 1 231PAS B EAV=46.2 5 -231PA G 44.08 170.00074 21[M1+E2] 3E2 3 -231PA2 G KC=$LC=2.4E2 21$MC=70 60 -231PA G 106.61 3 0.0179 7 [E1] 0.1023 14 -231PA2 G KC=$LC=0.0772 11$MC=0.0188 3 -231PA G 116.82 2 0.0225 9 E1 0.342 5 -231PA2 G KC=0.262 4$LC=0.0608 9$MC=0.01478 21 -231PA G 134.03 2 0.0255 8 E1 0.249 4 -231PA2 G KC=0.192 3$LC=0.0426 6$MC=0.01033 15 -231PA G 140.54 4 0.00074 7 [M1+E2] 5.3 25 -231PA2 G KC=3 3$LC=1.5 4$MC=0.40 12 +231PA G 44.08 170.00074 21[M1+E2] 3E2 3 +231PA2 G LC=2.4E2 21$MC=70 60 +231PA G 106.61 3 0.0179 7[E1] 0.1023 14 +231PA2 G LC=0.0772 11$MC=0.0188 3 +231PA G 116.820 200.0225 9E1 0.342 5 +231PA2 G KC=0.262 4$LC=0.0608 9$MC=0.01478 21 +231PA G 134.03 2 0.0255 8E1 0.249 4 +231PA2 G KC=0.192 3$LC=0.0426 6$MC=0.01033 15 +231PA G 140.54 4 0.00074 7[M1+E2] 5.3 25 +231PA2 G KC=3 3$LC=1.5 4$MC=0.40 12 231PA L 247.320 5 7/2+ -231PA B 144.3 152.7 4 6.11 2 +231PA B 144.3 152.7 4 6.11 231PAS B EAV=38.1 5 231PA G 63.86 3 0.0235 21M1+E2 0.52 20 34 15 -231PA2 G KC=$LC=25 11$MC=6.6 31 +231PA2 G LC=25 11$MC=6.6 31 231PA G 135.664 110.0797 22M1(+E2) 0.33 33 8.0 11 -231PA2 G KC=6.1 14$LC=1.40 19$MC=0.35 6 -231PA G 145.06 4 0.0058 3 [E2] 2.46 3 -231PA2 G KC=0.237 4$LC=1.627 23$MC=0.448 7 -231PA G 145.94 2 0.0324 12M1+E2 0.82 28 5.1 8 -231PA2 G KC=3.4 10$LC=1.27 10$MC=0.33 4 -231PA G 163.101 4 0.156 5 M1(+E2) 0.2 2 4.9 4 -231PA2 G KC=3.9 4$LC=0.783 22$MC=0.190 9 -231PA G 169.66 3 0.00141 7 [E1] 0.1421 20 -231PA2 G KC=0.1113 16$LC=0.0233 4$MC=0.00564 8 -231PA G 188.76 2 0.0034 3 [E1] 0.1105 15 -231PA2 G KC=0.0869 13$LC=0.01782 25$MC=0.00431 6 +231PA2 G KC=6.1 14$LC=1.40 19$MC=0.35 6 +231PA G 145.060 400.0058 3[E2] 2.46 3 +231PA2 G KC=0.237 4$LC=1.627 23$MC=0.448 7 +231PA G 145.940 200.0324 12M1+E2 0.82 28 5.1 8 +231PA2 G KC=3.4 10$LC=1.27 10$MC=0.33 4 +231PA G 163.101 4 0.156 5M1(+E2) 0.2 2 4.9 4 +231PA2 G KC=3.9 4$LC=0.783 22$MC=0.190 9 +231PA G 169.66 3 0.00141 7[E1] 0.1421 20 +231PA2 G KC=0.1113 16$LC=0.0233 4$MC=0.00564 8 +231PA G 188.76 2 0.0034 3[E1] 0.1105 15 +231PA2 G KC=0.0869 13$LC=0.01782 25$MC=0.00431 6 231PA L 317.95 4 (3/2)+ -231PA B 73.6 150.00078 5 8.76 2 +231PA B 73.6 150.00078 5 8.76 231PAS B EAV=18.9 4 -231PA G 240.27 5 0.00029 4 [E1] 0.0630 9 -231PA2 G KC=0.0500 7$LC=0.00984 14$MC=0.00237 4 -231PA G 308.78 7 3618E-7 18[E1] 0.0358 5 -231PA2 G KC=0.0287 4$LC=0.00544 8$MC=1306E-6 19 -231PA G 317.87 8 1005E-7 5 [E1] 0.0336 5 -231PA2 G KC=0.0269 4$LC=0.00508 8$MC=1221E-6 18 +231PA G 240.27 5 0.00029 4[E1] 0.0630 9 +231PA2 G KC=0.0500 7$LC=0.00984 14$MC=0.00237 4 +231PA G 308.78 7 3.618E-418[E1] 0.0358 5 +231PA2 G KC=0.0287 4$LC=0.00544 8$MC=1306E-6 19 +231PA G 317.87 8 1.005E-4 5[E1] 0.0336 5 +231PA2 G KC=0.0269 4$LC=0.00508 8$MC=1221E-6 18 231PA L 320.209 183/2- -231PA B 71.4 150.066 2 6.79 1U +231PA B 71.4 150.066 2 6.79 1 231PAS B EAV=18.3 4 -231PA G 136.75 7 0.00442 15[E1] 0.237 3 -231PA2 G KC=0.184 3$LC=0.0404 6$MC=0.00981 14 -231PA G 217.94 3 0.0402 8 E1 0.0789 11 -231PA2 G KC=0.0624 9$LC=0.01248 18$MC=0.00301 5 -231PA G 236.01 3 0.0094 3 [E1] 0.0657 9 -231PA2 G KC=0.0521 8$LC=0.01028 15$MC=0.00248 4 -231PA G 242.50 4 0.00082 5 [M1+E2] 1.0 7 -231PA2 G KC=0.7 6$LC=0.22 4$MC=0.055 7 -231PA G 311.00 5 0.00315 14M1+E2 0.8 8 0.6 3 -231PA2 G KC=0.5 3$LC=0.11 3$MC=0.027 6 -231PA G 320.15 8 0.00015 3 [M1+E2] 0.5 4 -231PA2 G KC=0.34 27$LC=0.09 4$MC=0.023 7 +231PA G 136.75 7 0.00442 15[E1] 0.237 3 +231PA2 G KC=0.184 3$LC=0.0404 6$MC=0.00981 14 +231PA G 217.94 3 0.0402 8E1 0.0789 11 +231PA2 G KC=0.0624 9$LC=0.01248 18$MC=0.00301 5 +231PA G 236.01 3 0.0094 3[E1] 0.0657 9 +231PA2 G KC=0.0521 8$LC=0.01028 15$MC=0.00248 4 +231PA G 242.50 4 0.00082 5[M1+E2] 1.0 7 +231PA2 G KC=0.7 6$LC=0.22 4$MC=0.055 7 +231PA G 311.00 5 0.00315 14M1+E2 0.8 8 0.6 3 +231PA2 G KC=0.5 3$LC=0.11 3$MC=0.027 6 +231PA G 320.15 8 0.00015 3[M1+E2] 0.5 4 +231PA2 G KC=0.34 27$LC=0.09 4$MC=0.023 7 231PA L 351.84 4 (5/2)- -231PA B 39.8 150.0032 2 7.33 +231PA B 39.8 150.0032 2 7.33 231PAS B EAV=10.1 5 -231PA G 249.60 7 0.00080 7 [E1] 0.0578 8 -231PA2 G KC=0.0459 7$LC=0.00898 13$MC=0.00216 3 -231PA G 250.45 7 0.00067 7 [E1] 0.0573 8 -231PA2 G KC=0.0455 7$LC=0.00891 13$MC=0.00215 3 -231PA G 267.62 8 0.00141 14[E1] 0.0493 7 -231PA2 G KC=0.0393 6$LC=0.00760 11$MC=0.00183 3 -231PA G 274.1 1 3.4E-5 12[M1+E2] 0.7 5 -231PA2 G KC=0.5 4$LC=0.15 4$MC=0.038 8 -231PA G 351.8 1 6.7E-5 13[M1+E2] 0.35 25 -231PA2 G KC=0.26 21$LC=0.066 24$MC=0.016 6 +231PA G 249.60 7 0.00080 7[E1] 0.0578 8 +231PA2 G KC=0.0459 7$LC=0.00898 13$MC=0.00216 3 +231PA G 250.45 7 0.00067 7[E1] 0.0573 8 +231PA2 G KC=0.0455 7$LC=0.00891 13$MC=0.00215 3 +231PA G 267.62 8 0.00141 14[E1] 0.0493 7 +231PA2 G KC=0.0393 6$LC=0.00760 11$MC=0.00183 3 +231PA G 274.1 1 0.00003412[M1+E2] 0.7 5 +231PA2 G KC=0.5 4$LC=0.15 4$MC=0.038 8 +231PA G 351.80 100.00006713[M1+E2] 0.35 25 +231PA2 G KC=0.26 21$LC=0.066 24$MC=0.016 6 diff --git a/HEN_HOUSE/spectra/lnhb/Th-232.txt b/HEN_HOUSE/spectra/lnhb/Th-232.txt index 433bf91a7..b9b2c9288 100644 --- a/HEN_HOUSE/spectra/lnhb/Th-232.txt +++ b/HEN_HOUSE/spectra/lnhb/Th-232.txt @@ -5,31 +5,31 @@ 228RA2C 1957Ha08, 1959Ko58, 1960Be25, 1960Fa07, 1961Ko11, 1962Ko12, 1963Le21, 228RA3C 1973Ta25, 1982Sa36, 1983Mi30, 1983Ro23, 1989Sa01, 1990Ho28, 1991Ry01, 228RA4C 1995Bo18, 1996Sc06, 1997Ar08, 2002Ba85, 2003Au03, 2005KiWZ -228RA T Auger electrons and ^X ray energies and emission intensities: -228RA T {U Energy (keV)} {U Intensity } {U Line } +228RA T Auger electrons and X ray energies and emission intensities: +228RA T {U Energy (keV)} {U Intensity} {U Line} 228RA T -228RA T 85.43 0.0017 5 XKA2 -228RA T 88.47 0.0028 8 XKA1 +228RA T 85.43 0.0017 5 XKA2 +228RA T 88.47 0.0028 8 XKA1 228RA T -228RA T 99.432 |] XKB3 -228RA T 100.13 |] 0.00097 28 XKB1 -228RA T 100.738 |] XKB5II +228RA T 99.432 |] XKB3 +228RA T 100.13 |] 0.00097 28 XKB1 +228RA T 100.738 |] XKB5II 228RA T -228RA T 102.89 |] XKB2 -228RA T 103.295 |] 0.00032 10 XKB4 -228RA T 103.74 |] XKO23 +228RA T 102.89 |] XKB2 +228RA T 103.295 |] 0.00032 10 XKB4 +228RA T 103.74 |] XKO23 228RA T -228RA T 10.6241-18.3539 7.2 3 XL (total) -228RA T 10.6241 0.141 8 XLL -228RA T 12.1957-12.3381 2.43 13 XLA -228RA T 13.6624 0.084 6 XLC -228RA T 14.2373-16.1261 3.66 20 XLB -228RA T 17.2756-18.3539 0.84 5 XLG +228RA T 10.6241-18.3539 7.2 3 XL (total) +228RA T 10.6241 0.141 8 XLL +228RA T 12.1957-12.3381 2.43 13 XLA +228RA T 13.6624 0.084 6 XLC +228RA T 14.2373-16.1261 3.66 20 XLB +228RA T 17.2756-18.3539 0.84 5 XLG 228RA T -228RA T 65.149-72.729 |] KLL AUGER -228RA T 79.721-88.466 |] 0.00019 6 ^KLX AUGER -228RA T 94.27-103.91 |] KXY AUGER -228RA T 5.71-19.09 8.18 29 L AUGER +228RA T 65.149-72.729 |] KLL AUGER +228RA T 79.721-88.466 |] 0.00019 6 KLX AUGER +228RA T 94.27-103.91 |] KXY AUGER +228RA T 5.71-19.09 8.18 29 L AUGER 232TH P 0.0 0+ 14.02E9 Y 6 4081.6 14 228RA N 1.0 1.0 1 1.0 228RA L 0 0+ 5.75 Y 3 @@ -37,9 +37,9 @@ 228RA L 63.823 202+ 0.55 NS 4 228RA A 3948.5 1421.0 131.02 228RA G 63.811 100.259 15E2 80.4 12 -228RA2 G KC=$LC=59.1 9$MC=16.05 23 +228RA2 G LC=59.1 9$MC=16.05 23 228RA L 204.68 3 4+ 228RA A 3810.0 140.068 2016 -228RA G 140.88 1 0.021 6 E2 2.26 4 -228RA2 G KC=0.283 4$LC=1.450 21$MC=0.394 6 +228RA G 140.88 1 0.021 6E2 2.26 4 +228RA2 G KC=0.283 4$LC=1.450 21$MC=0.394 6 diff --git a/HEN_HOUSE/spectra/lnhb/Th-233.txt b/HEN_HOUSE/spectra/lnhb/Th-233.txt index d55511826..b8326feda 100644 --- a/HEN_HOUSE/spectra/lnhb/Th-233.txt +++ b/HEN_HOUSE/spectra/lnhb/Th-233.txt @@ -5,115 +5,115 @@ 233PA2C 1969HoZY, 1969Va06, 1970Se06, 1972SeZI, 1972Vo08, 1972De67, 1976Sk01, 233PA3C 1976JeZU, 1979Go12, 1979Bo30, 1988Wo01, 1989Ab05, 1998Us01, 2003Au03, 233PA4C 2005Si15, 2008De31, 2008Ki07, 2008Go10, 2008De10 -233PA T Auger electrons and ^X ray energies and emission intensities: -233PA T {U Energy (keV)} {U Intensity } {U Line } +233PA T Auger electrons and X ray energies and emission intensities: +233PA T {U Energy (keV)} {U Intensity} {U Line} 233PA T -233PA T 92.288 0.39 1 XKA2 -233PA T 95.869 0.615 13 XKA1 +233PA T 92.288 0.39 1 XKA2 +233PA T 95.869 0.615 13 XKA1 233PA T -233PA T 107.595 |] XKB3 -233PA T 108.422 |] 0.235 6 XKB1 -233PA T 109.072 |] XKB5II +233PA T 107.595 |] XKB3 +233PA T 108.422 |] 0.235 6 XKB1 +233PA T 109.072 |] XKB5II 233PA T -233PA T 111.405 |] XKB2 -233PA T 111.87 |] 0.079 3 XKB4 -233PA T 112.38 |] XKO23 +233PA T 111.405 |] XKB2 +233PA T 111.87 |] 0.079 3 XKB4 +233PA T 112.38 |] XKO23 233PA T -233PA T 11.366-21.6 8.2 9 XL (total) -233PA T 11.366 0.14 2 XLL -233PA T 13.122-13.291 2.84 32 XLA +233PA T 11.366-21.6 8.2 9 XL (total) +233PA T 11.366 0.14 2 XLL +233PA T 13.122-13.291 2.84 32 XLA 233PA T 14.946 XLC -233PA T 15.3-16.7 4.3 5 XLB -233PA T 19.9-21.6 0.95 11 XLG +233PA T 15.3-16.7 4.3 5 XLB +233PA T 19.9-21.6 0.95 11 XLG 233PA T -233PA T 70.081-78.822 |] KLL AUGER -233PA T 88.03-95.56 |] 0.041 5 ^KLX AUGER -233PA T 101.78-112.4 |] KXY AUGER -233PA T 5.9-21.6 8.6 10 L AUGER +233PA T 70.081-78.822 |] KLL AUGER +233PA T 88.03-95.56 |] 0.041 5 KLX AUGER +233PA T 101.78-112.4 |] KXY AUGER +233PA T 5.9-21.6 8.6 10 L AUGER 233TH P 0.0 1/2+ 22.15 M 8 1243.1 14 233PA N 1.0 1.0 1 1.0 233PA G 80 -233PA G 105.2 1 4100E-5 0 -233PA G 147.5 0.0018 6 -233PA G 211.3 2 0.0202 9 -233PA G 242.3 0.0029 6 -233PA G 309.9 0.0032 3 -233PA G 383.5 0.0019 6 -233PA G 408.8 5 0.0005 4 -233PA G 418.4 5 0.0091 7 -233PA G 454.2 5 4000E-5 0 -233PA G 464.8 0.0026 3 -233PA G 473.9 5 0.0033 7 -233PA G 497.1 4 0.0128 4 -233PA G 505.5 6 0.0055 3 -233PA G 513.4 4 0.0133 4 -233PA G 517.0 4 0.0046 3 -233PA G 531.8 4 0.0070 7 -233PA G 553.7 0.0030 3 -233PA G 554.9 0.0031 3 -233PA G 578.7 0.0017 5 -233PA G 583.2 0.0016 5 -233PA G 681.2 6 0.0143 4 -233PA G 690 0.0021 5 -233PA G 698.5 6 0.0106 5 -233PA G 703.7 6 0.0091 5 -233PA G 727.8 0.0029 2 -233PA G 744.9 5 0.0053 2 -233PA G 751.6 6 0.0023 4 -233PA G 767.5 0.0032 2 -233PA G 774.0 4 0.0108 5 -233PA G 784.2 5 0.0022 2 -233PA G 832.0 3 7500E-6 0 -233PA G 846.8 7 1300E-6 0 -233PA G 870.7 7 0.0031 2 -233PA G 874.0 5 0.00120 4 -233PA G 918.9 5 6000E-6 0 -233PA G 935.2 7 0.0369 7 -233PA G 941.9 8 0.0048 3 -233PA G 942.8 0.0019 3 -233PA G 955 1 0.0002 3 -233PA G 960.8 8 0.0041 2 -233PA G 962.8 9 0.0015 2 -233PA G 968.2 9 0.0083 3 -233PA G 994 1 0.0006 1 -233PA G 1001 1 0.0008 2 -233PA G 1007 1 0.0014 2 -233PA G 1011 1 0.0019 2 -233PA G 1026.5 107500E-6 0 -233PA G 1092.5 106000E-6 0 -233PA G 1132.1 0.0006 2 -233PA G 1139.1 0.0004 1 -233PA G 1144 1 2700E-6 0 -233PA G 1201 1 6000E-6 0 +233PA G 105.2 1 0.041 +233PA G 147.5 0.0018 6 +233PA G 211.3 2 0.0202 9 +233PA G 242.3 0.0029 6 +233PA G 309.9 0.0032 3 +233PA G 383.5 0.0019 6 +233PA G 408.8 5 0.0005 4 +233PA G 418.4 5 0.0091 7 +233PA G 454.2 5 0.04 +233PA G 464.8 0.0026 3 +233PA G 473.9 5 0.0033 7 +233PA G 497.1 4 0.0128 4 +233PA G 505.5 6 0.0055 3 +233PA G 513.4 4 0.0133 4 +233PA G 517.0 4 0.0046 3 +233PA G 531.8 4 0.0070 7 +233PA G 553.7 0.0030 3 +233PA G 554.9 0.0031 3 +233PA G 578.7 0.0017 5 +233PA G 583.2 0.0016 5 +233PA G 681.2 6 0.0143 4 +233PA G 690 0.0021 5 +233PA G 698.5 6 0.0106 5 +233PA G 703.7 6 0.0091 5 +233PA G 727.8 0.0029 2 +233PA G 744.9 5 0.0053 2 +233PA G 751.6 6 0.0023 4 +233PA G 767.5 0.0032 2 +233PA G 774.0 4 0.0108 5 +233PA G 784.2 5 0.0022 2 +233PA G 832.0 3 0.0075 +233PA G 846.8 7 0.0013 +233PA G 870.7 7 0.0031 2 +233PA G 874.0 5 0.00120 4 +233PA G 918.9 5 0.006 +233PA G 935.2 7 0.0369 7 +233PA G 941.9 8 0.0048 3 +233PA G 942.8 0.0019 3 +233PA G 955 1 0.0002 3 +233PA G 960.8 8 0.0041 2 +233PA G 962.8 9 0.0015 2 +233PA G 968.2 9 0.0083 3 +233PA G 994 1 0.0006 1 +233PA G 1001 1 0.0008 2 +233PA G 1007 1 0.0014 2 +233PA G 1011 1 0.0019 2 +233PA G 1026.5 100.0075 +233PA G 1092.5 100.006 +233PA G 1132.1 0.0006 2 +233PA G 1139.1 0.0004 1 +233PA G 1144 1 0.0027 +233PA G 1201 1 0.006 233PA L 0 3/2- 26.98 D 2 -233PA B 1243.1 1434 6 6.2 1U +233PA B 1243.1 1434 6 6.2 1 233PAS B EAV=413.8 6 233PA L 6.65 5 1/2- -233PA B 1236.4 1450 6 6.1 +233PA B 1236.4 1450 6 6.1 233PAS B EAV=411.2 6 233PA G 6.65 5 0.0165 18(M1) 3080 60 -233PA2 G KC=$LC=$MC=2280 50 +233PA2 G MC=2280 50 233PA L 57.10 2 7/2- -233PA G 57.10 2 0.0498 15E2 176 4 -233PA2 G KC=$LC=128.4 26$MC=35.4 7 +233PA G 57.10 2 0.0498 15E2 176 4 +233PA2 G LC=128.4 26$MC=35.4 7 233PA L 70.49 105/2- -233PA G 63.92 6 0.0007 3 (E2) 102.1 21 -233PA2 G KC=$LC=74.6 15$MC=20.6 4 -233PA G 70.49 100.0007 4 [M1+E2] 1 1 40 30 -233PA2 G KC=$LC=28 19$MC=7 6 +233PA G 63.92 6 0.0007 3(E2) 102.1 21 +233PA2 G LC=74.6 15$MC=20.6 4 +233PA G 70.49 100.0007 4[M1+E2] 1 1 40 30 +233PA2 G LC=28 19$MC=7 6 233PA L 86.477 105/2+ -233PA G 29.373 102.17 7 E1 3.07 6 -233PA2 G KC=$LC=2.29 5$MC=0.586 12 -233PA G 86.477 101.843 22E1 1.43 8 -233PA2 G KC=$LC=1.13 4$MC=0.22 6 +233PA G 29.373 102.17 7E1 3.07 6 +233PA2 G LC=2.29 5$MC=0.586 12 +233PA G 86.477 101.843 22E1 1.43 8 +233PA2 G LC=1.13 4$MC=0.22 6 233PA L 94.65 5 3/2+ -233PA B 1148.4 1410.4 4 6.6 2 +233PA B 1148.4 1410.4 4 6.6 233PAS B EAV=377.8 6 233PA G 8.22 5 (M1+E2) -233PA G 87.99 3 0.1698 20[E1] 0.169 3 -233PA2 G KC=$LC=0.128 3$MC=0.0312 6 -233PA G 94.65 5 0.775 9 E1 0.140 3 -233PA2 G KC=$LC=0.105 2$MC=0.0257 5 +233PA G 87.99 3 0.1698 20[E1] 0.169 3 +233PA2 G LC=0.128 3$MC=0.0312 6 +233PA G 94.65 5 0.775 9E1 0.140 3 +233PA2 G LC=0.105 2$MC=0.0257 5 233PA L 103.8 1 7/2+ 233PA G 17.40 5 233PA G 46.53 4 @@ -121,186 +121,186 @@ 233PA B 1073.9 140.692 12 7.7 233PAS B EAV=349.7 6 233PA G 74.51 5 0.0402 17[M1] 9.85 20 -233PA2 G KC=$LC=7.43 15$MC=1.79 4 -233PA G 162.504 120.1674 26[E1] 0.157 3 -233PA2 G KC=0.123 3$LC=0.0260 5$MC=0.0063 1 -233PA G 169.162 100.251 4 [E1] 0.1431 29 -233PA2 G KC=0.1120 22$LC=0.0235 5$MC=0.00568 12 +233PA2 G LC=7.43 15$MC=1.79 4 +233PA G 162.504 120.1674 26[E1] 0.157 3 +233PA2 G KC=0.123 3$LC=0.0260 5$MC=0.0063 1 +233PA G 169.162 100.251 4[E1] 0.1431 29 +233PA2 G KC=0.1120 22$LC=0.0235 5$MC=0.00568 12 233PA L 201.62 5 3/2+ -233PA B 1041.4 140.074 8 8.6 2 +233PA B 1041.4 140.074 8 8.6 233PAS B EAV=337.6 6 -233PA G 115.14 5 0.003 7 [M1+E2] 10 4 -233PA2 G KC=5 6$LC=3.4 13$MC=0.9 4 -233PA G 131.101 250.0508 13E1 0.262 5 -233PA2 G KC=0.202 4$LC=0.0451 9$MC=0.01094 22 +233PA G 115.14 5 0.003 7[M1+E2] 10 4 +233PA2 G KC=5 6$LC=3.4 13$MC=0.9 4 +233PA G 131.101 250.0508 13E1 0.262 5 +233PA2 G KC=0.202 4$LC=0.0451 9$MC=0.01094 22 233PA G 194.97 7 0.1073 17E1 0.1024 20 -233PA2 G KC=0.0806 16$LC=0.0164 3$MC=0.00397 8 -233PA G 201.62 5 0.0221 8 E1 0.0946 19 -233PA2 G KC=0.0746 15$LC=0.0151 3$MC=0.00365 7 +233PA2 G KC=0.0806 16$LC=0.0164 3$MC=0.00397 8 +233PA G 201.62 5 0.0221 8E1 0.0946 19 +233PA2 G KC=0.0746 15$LC=0.0151 3$MC=0.00365 7 233PA L 212.34 5 5/2+ -233PA G 108.5 1 6000E-7 0 M1+E2 0.22 22 3.5 6 -233PA2 G KC=0.00303 5$LC=2.7 5$MC=0.65 13 -233PA G 117.692 200.0029 3 M1+E2 0.30 9 12.2 4 -233PA2 G KC=9.3 5$LC=2.16 12$MC=0.53 4 +233PA G 108.5 1 0.0006 M1+E2 0.22 22 3.5 6 +233PA2 G KC=0.00303 5$LC=2.7 5$MC=0.65 13 +233PA G 117.692 200.0029 3M1+E2 0.30 9 12.2 4 +233PA2 G KC=9.3 5$LC=2.16 12$MC=0.53 4 233PA G 141.74 10 -233PA G 155.239 200.00023 3 E1 0.176 4 -233PA2 G KC=0.137 3$LC=0.0292 6$MC=0.00708 10 -233PA G 212.34 5 0.0065 6 E1 0.0839 17 -233PA2 G KC=0.0662 12$LC=0.01331 26$MC=0.00321 6 +233PA G 155.239 200.00023 3E1 0.176 4 +233PA2 G KC=0.137 3$LC=0.0292 6$MC=0.00708 10 +233PA G 212.34 5 0.0065 6E1 0.0839 17 +233PA2 G KC=0.0662 12$LC=0.01331 26$MC=0.00321 6 233PA L 237.86 2 5/2+ -233PA G 134.285 200.0018 5 [M1+E2] 0.4 4 8.0 14 -233PA2 G KC=6.1 17$LC=1.48 24$MC=0.37 8 -233PA G 143.23 2 0.0114 7 M1+E2 0.4 4 6.7 12 -233PA2 G KC=5.0 14$LC=1.21 16$MC=0.30 6 -233PA G 151.409 200.0067 3 [M1+E2] 0.69 20 4.9 6 -233PA2 G KC=3.4 7$LC=1.08 6$MC=0.276 19 -233PA G 180.76 3 0.00011 3 [E1] 0.1223 24 -233PA2 G KC=0.096 2$LC=0.0199 4$MC=0.0048 1 -233PA G 237.86 6 0.0019 4 [E1] 0.0645 13 -233PA2 G KC=0.0511 10$LC=0.0101 2$MC=0.00243 5 +233PA G 134.285 200.0018 5[M1+E2] 0.4 4 8.0 14 +233PA2 G KC=6.1 17$LC=1.48 24$MC=0.37 8 +233PA G 143.23 2 0.0114 7M1+E2 0.4 4 6.7 12 +233PA2 G KC=5.0 14$LC=1.21 16$MC=0.30 6 +233PA G 151.409 200.0067 3[M1+E2] 0.69 20 4.9 6 +233PA2 G KC=3.4 7$LC=1.08 6$MC=0.276 19 +233PA G 180.76 3 0.00011 3[E1] 0.1223 24 +233PA2 G KC=0.096 2$LC=0.0199 4$MC=0.0048 1 +233PA G 237.86 6 0.0019 4[E1] 0.0645 13 +233PA2 G KC=0.0511 10$LC=0.0101 2$MC=0.00243 5 233PA L 257.30 155/2- -233PA B 985.8 140.60 3 8.1 3U +233PA B 985.8 140.60 3 8.1 1U 233PAS B EAV=317.0 6 -233PA G 153.49 180.0407 7 [E1] 0.180 4 -233PA2 G KC=0.140 3$LC=0.0301 6$MC=0.00728 14 -233PA G 162.504 0.16000 0 [E1] 0.157 3 -233PA2 G KC=0.1230 18$LC=0.0260 5$MC=0.0063 1 -233PA G 170.60 6 0.507 9 [E1] 0.1403 28 -233PA2 G KC=0.1099 20$LC=0.0230 5$MC=0.00556 11 -233PA G 186.80 180.0209 9 [M1+E2] 2.2 13 -233PA2 G KC=1.5 13$LC=0.531 9$MC=0.137 10 -233PA G 250.65 160.0047 3 [E2] 0.317 6 -233PA2 G KC=0.1043 21$LC=0.156 3$MC=0.0423 8 -233PA G 257.30 150.0524 12[M1+E2] 1 1 0.8 6 -233PA2 G KC=0.6 6$LC=0.18 4$MC=0.045 7 +233PA G 153.49 180.0407 7[E1] 0.180 4 +233PA2 G KC=0.140 3$LC=0.0301 6$MC=0.00728 14 +233PA G 162.504 0.16 [E1] 0.157 3 +233PA2 G KC=0.1230 18$LC=0.0260 5$MC=0.0063 1 +233PA G 170.60 6 0.507 9[E1] 0.1403 28 +233PA2 G KC=0.1099 20$LC=0.0230 5$MC=0.00556 11 +233PA G 186.80 180.0209 9[M1+E2] 2.2 13 +233PA2 G KC=1.5 13$LC=0.531 9$MC=0.137 10 +233PA G 250.65 160.0047 3[E2] 0.317 6 +233PA2 G KC=0.1043 21$LC=0.156 3$MC=0.0423 8 +233PA G 257.30 150.0524 12[M1+E2] 1 1 0.8 6 +233PA2 G KC=0.6 6$LC=0.18 4$MC=0.045 7 233PA L 447.762 203/2- -233PA B 795.3 140.821 14 7.2 1U +233PA B 795.3 140.821 14 7.2 1 233PAS B EAV=247.8 5 -233PA G 190.552 140.0861 15M1 3.26 6 -233PA2 G KC=2.60 5$LC=0.499 10$MC=0.1204 24 -233PA G 246.14 6 0.0041 6 [E1] 0.0596 12 -233PA2 G KC=0.0473 9$LC=0.00929 19$MC=0.00224 4 -233PA G 278.7 4 0.0047 6 -233PA G 361.285 220.0218 6 [E1] 0.0255 5 -233PA2 G KC=0.0205 4$LC=0.00380 8$MC=9.12E-4 2 -233PA G 377.27 110.0275 9 [M1+E2] 0.3 3 0.46 8 -233PA2 G KC=0.36 7$LC=0.071 8$MC=0.0172 17 -233PA G 440.94 4 0.1912 23(M1+E2) 0.3 3 0.30 5 -233PA2 G KC=0.24 4$LC=0.046 6$MC=0.0111 13 -233PA G 447.762 200.1043 14[M1+E2] 0.27 27 0.29 4 -233PA2 G KC=0.23 4$LC=0.045 5$MC=0.0108 11 +233PA G 190.552 140.0861 15M1 3.26 6 +233PA2 G KC=2.60 5$LC=0.499 10$MC=0.1204 24 +233PA G 246.14 6 0.0041 6[E1] 0.0596 12 +233PA2 G KC=0.0473 9$LC=0.00929 19$MC=0.00224 4 +233PA G 278.7 4 0.0047 6 +233PA G 361.285 220.0218 6[E1] 0.0255 5 +233PA2 G KC=0.0205 4$LC=0.00380 8$MC=9.12E-4 2 +233PA G 377.27 110.0275 9[M1+E2] 0.3 3 0.46 8 +233PA2 G KC=0.36 7$LC=0.071 8$MC=0.0172 17 +233PA G 440.94 4 0.1912 23(M1+E2) 0.3 3 0.30 5 +233PA2 G KC=0.24 4$LC=0.046 6$MC=0.0111 13 +233PA G 447.762 200.1043 14[M1+E2] 0.27 27 0.29 4 +233PA2 G KC=0.23 4$LC=0.045 5$MC=0.0108 11 233PA L 454.40 7 3/2+ -233PA B 788.7 140.217 13 7.7 2 +233PA B 788.7 140.217 13 7.7 233PAS B EAV=245.5 5 -233PA G 216.54 8 0.0130 7 (M1+E2) 1 1 1.4 9 -233PA2 G KC=1.0 9$LC=0.32 4$MC=0.081 4 -233PA G 252.78 9 0.0066 3 [M1+E2] 0.4 4 1.3 3 -233PA2 G KC=1.0 3$LC=0.215 20$MC=0.052 4 -233PA G 285.24 7 0.0154 9 [M1+E2] 0.4 4 0.94 22 -233PA2 G KC=0.74 20$LC=0.152 18$MC=0.037 4 +233PA G 216.54 8 0.0130 7(M1+E2) 1 1 1.4 9 +233PA2 G KC=1.0 9$LC=0.32 4$MC=0.081 4 +233PA G 252.78 9 0.0066 3[M1+E2] 0.4 4 1.3 3 +233PA2 G KC=1.0 3$LC=0.215 20$MC=0.052 4 +233PA G 285.24 7 0.0154 9[M1+E2] 0.4 4 0.94 22 +233PA2 G KC=0.74 20$LC=0.152 18$MC=0.037 4 233PA G 359.74 4 0.0869 12M1 0.559 11 -233PA2 G KC=0.446 9$LC=0.0848 19$MC=0.0204 4 -233PA G 367.92 7 0.0037 7 [M1] 0.525 10 -233PA2 G KC=0.420 8$LC=0.0797 16$MC=0.0192 4 +233PA2 G KC=0.446 9$LC=0.0848 19$MC=0.0204 4 +233PA G 367.92 7 0.0037 7[M1] 0.525 10 +233PA2 G KC=0.420 8$LC=0.0797 16$MC=0.0192 4 233PA L 553.88 6 1/2,3/2+ -233PA B 689.2 141.23 3 6.8 +233PA B 689.2 141.23 3 6.8 233PAS B EAV=210.5 5 -233PA G 316.1 0.0037 4 E1 0.0340 7 -233PA2 G KC=0.0272 4$LC=0.00515 10$MC=0.00124 2 -233PA G 459.222 7 0.989 12M1 0.288 6 -233PA2 G KC=0.230 5$LC=0.0435 9$MC=0.01047 21 -233PA G 467.40 6 0.0144 4 [M1E2] 0.16 11 -233PA2 G KC=0.13 10$LC=0.029 13$MC=7000E-6 0 +233PA G 316.1 0.0037 4E1 0.0340 7 +233PA2 G KC=0.0272 4$LC=0.00515 10$MC=0.00124 2 +233PA G 459.222 7 0.989 12M1 0.288 6 +233PA2 G KC=0.230 5$LC=0.0435 9$MC=0.01047 21 +233PA G 467.40 6 0.0144 4[M1E2] 0.16 11 +233PA2 G KC=0.13 10$LC=0.029 13$MC=0.007 233PA L 585.50 5 3/2+ -233PA B 657.6 140.15 3 7.6 2 +233PA B 657.6 140.15 3 7.6 233PAS B EAV=199.6 5 -233PA G 347.64 6 0.0145 8 [M1] 0.613 12 -233PA2 G KC=0.49 1$LC=0.0932 18$MC=0.0224 5 -233PA G 490.80 6 0.1078 16M1 0.241 5 -233PA2 G KC=0.193 4$LC=0.0363 7$MC=0.00874 18 -233PA G 499.02 4 0.1576 21M1 0.230 5 -233PA2 G KC=0.184 3$LC=0.0347 5$MC=0.00835 12 +233PA G 347.64 6 0.0145 8[M1] 0.613 12 +233PA2 G KC=0.49 1$LC=0.0932 18$MC=0.0224 5 +233PA G 490.80 6 0.1078 16M1 0.241 5 +233PA2 G KC=0.193 4$LC=0.0363 7$MC=0.00874 18 +233PA G 499.02 4 0.1576 21M1 0.230 5 +233PA2 G KC=0.184 3$LC=0.0347 5$MC=0.00835 12 233PA L 669.9 5 (3/2)- -233PA B 573.2 140.0174 22 8.4 1U +233PA B 573.2 140.0174 22 8.4 1 233PAS B EAV=170.8 5 -233PA G 412.5 5 0.0083 7 [M1] 0.385 8 -233PA2 G KC=0.308 6$LC=0.0583 12$MC=0.0140 3 -233PA G 663.3 5 0.0037 5 [M1] 0.1075 22 -233PA2 G KC=0.0862 17$LC=0.0161 3$MC=0.00388 8 -233PA G 669.9 5 1800E-6 0 +233PA G 412.5 5 0.0083 7[M1] 0.385 8 +233PA2 G KC=0.308 6$LC=0.0583 12$MC=0.0140 3 +233PA G 663.3 5 0.0037 5[M1] 0.1075 22 +233PA2 G KC=0.0862 17$LC=0.0161 3$MC=0.00388 8 +233PA G 669.9 5 0.0018 233PA L 764.55 6 1/2,3/2+ -233PA B 478.5 141.19 3 6.3 +233PA B 478.5 141.19 3 6.3 233PAS B EAV=139.5 5 -233PA G 179.05 8 0.0278 7 (M1+E2) 0.4 4 3.5 8 -233PA2 G KC=2.7 8$LC=0.602 15$MC=0.148 10 +233PA G 179.05 8 0.0278 7(M1+E2) 0.4 4 3.5 8 +233PA2 G KC=2.7 8$LC=0.602 15$MC=0.148 10 233PA G 210.67 8 0.0178 11[M1+E2] 0.97 97 1.5 10 -233PA2 G KC=1.1 9$LC=0.35 3$MC=0.0890 21 -233PA G 526.69 6 0.0463 11[M1E2] 0.12 8 -233PA2 G KC=0.09 7$LC=0.02 1$MC=0.005 3 -233PA G 552.21 8 0.0165 5 (M1) 0.1754 35 -233PA2 G KC=0.1404 28$LC=0.0264 5$MC=0.00635 13 -233PA G 562.93 8 0.0545 7 [M1] 0.167 3 -233PA2 G KC=0.1334 27$LC=0.0251 5$MC=0.00603 12 -233PA G 595.39 6 0.1178 16(M1) 0.143 3 -233PA2 G KC=0.1148 22$LC=0.0216 4$MC=0.00518 10 -233PA G 669.901 160.504 6 [M1] 0.1047 21 -233PA2 G KC=0.0839 17$LC=0.0157 3$MC=0.00377 8 -233PA G 678.04 100.0647 9 [M1E2] 0.06 4 -233PA2 G KC=0.05 4$LC=0.010 5$MC=0.0025 12 -233PA G 757.90 7 0.0324 7 +233PA2 G KC=1.1 9$LC=0.35 3$MC=0.0890 21 +233PA G 526.69 6 0.0463 11[M1E2] 0.12 8 +233PA2 G KC=0.09 7$LC=0.02 1$MC=0.005 3 +233PA G 552.21 8 0.0165 5(M1) 0.1754 35 +233PA2 G KC=0.1404 28$LC=0.0264 5$MC=0.00635 13 +233PA G 562.93 8 0.0545 7[M1] 0.167 3 +233PA2 G KC=0.1334 27$LC=0.0251 5$MC=0.00603 12 +233PA G 595.39 6 0.1178 16(M1) 0.143 3 +233PA2 G KC=0.1148 22$LC=0.0216 4$MC=0.00518 10 +233PA G 669.901 160.504 6[M1] 0.1047 21 +233PA2 G KC=0.0839 17$LC=0.0157 3$MC=0.00377 8 +233PA G 678.04 100.0647 9[M1E2] 0.06 4 +233PA2 G KC=0.05 4$LC=0.010 5$MC=0.0025 12 +233PA G 757.90 7 0.0324 7 233PA G 764.55 6 0.0891 13 233PA L 811.6 2 (3/2)+ -233PA B 431.5 140.385 4 6.6 2 +233PA B 431.5 140.385 4 6.6 233PAS B EAV=124.3 5 -233PA G 226.1 2 0.0171 7 M1+(E2) 2.02 4 -233PA2 G KC=1.61 3$LC=0.308 6$MC=0.0743 15 -233PA G 573.7 4 0.0332 10[M1] 0.158 3 -233PA2 G KC=0.1268 25$LC=0.0238 5$MC=0.00573 12 -233PA G 599.3 2 0.0294 5 [M1] 0.141 3 -233PA2 G KC=0.1129 22$LC=0.0212 4$MC=0.00509 10 -233PA G 610.0 3 0.0567 12[M1] 0.134 3 -233PA2 G KC=0.1077 20$LC=0.0202 4$MC=0.00485 9 -233PA G 642.4 2 0.0202 5 [M1] 0.1171 23 -233PA2 G KC=0.0938 19$LC=0.0176 4$MC=0.00422 8 -233PA G 707.8 3 0.0091 5 [E2] 0.0209 4 -233PA2 G KC=0.0148 3$LC=0.00455 9$MC=0.00115 2 -233PA G 717.0 2 0.0421 9 (M1) 0.0874 17 -233PA2 G KC=0.0701 14$LC=0.0131 3$MC=0.00314 6 +233PA G 226.1 2 0.0171 7M1+(E2) 2.02 4 +233PA2 G KC=1.61 3$LC=0.308 6$MC=0.0743 15 +233PA G 573.7 4 0.0332 10[M1] 0.158 3 +233PA2 G KC=0.1268 25$LC=0.0238 5$MC=0.00573 12 +233PA G 599.3 2 0.0294 5[M1] 0.141 3 +233PA2 G KC=0.1129 22$LC=0.0212 4$MC=0.00509 10 +233PA G 610.0 3 0.0567 12[M1] 0.134 3 +233PA2 G KC=0.1077 20$LC=0.0202 4$MC=0.00485 9 +233PA G 642.4 2 0.0202 5[M1] 0.1171 23 +233PA2 G KC=0.0938 19$LC=0.0176 4$MC=0.00422 8 +233PA G 707.8 3 0.0091 5[E2] 0.0209 4 +233PA2 G KC=0.0148 3$LC=0.00455 9$MC=0.00115 2 +233PA G 717.0 2 0.0421 9(M1) 0.0874 17 +233PA2 G KC=0.0701 14$LC=0.0131 3$MC=0.00314 6 233PA G 725.1 2 0.0633 10(M1) 0.0848 17 -233PA2 G KC=0.068 1$LC=0.01271 25$MC=0.00305 6 -233PA G 741.1 2 0.0236 5 [E1] 0.0061512 -233PA2 G KC=0.00502 10$LC=8.60E-4 17$MC=2.04E-4 4 -233PA G 805.0 2 0.0214 6 [E1] 0.0052911 -233PA2 G KC=0.00432 9$LC=0.00073 2$MC=1.74E-4 4 -233PA G 811.6 2 0.0060 2 [E1] 0.0052110 -233PA2 G KC=0.00426 9$LC=7.20E-4 15$MC=1.71E-4 4 +233PA2 G KC=0.068 1$LC=0.01271 25$MC=0.00305 6 +233PA G 741.1 2 0.0236 5[E1] 0.0061512 +233PA2 G KC=0.00502 10$LC=8.60E-4 17$MC=2.04E-4 4 +233PA G 805.0 2 0.0214 6[E1] 0.0052911 +233PA2 G KC=0.00432 9$LC=0.00073 2$MC=1.74E-4 4 +233PA G 811.6 2 0.0060 2[E1] 0.0052110 +233PA2 G KC=0.00426 9$LC=7.20E-4 15$MC=1.71E-4 4 233PA L 984.8 5 (3/2)+ -233PA B 258.3 140.205 2 6.2 2 +233PA B 258.3 140.205 2 6.2 233PAS B EAV=70.8 4 -233PA G 398.8 5 0.0111 7 [M1] 0.422 8 -233PA2 G KC=0.337 7$LC=0.0639 13$MC=0.0154 3 -233PA G 430.9 4 0.0178 4 (M1) 0.342 6 -233PA2 G KC=0.273 5$LC=0.0517 10$MC=0.01245 24 -233PA G 783.2 5 0.0056 3 [M1] 0.0692 14 -233PA2 G KC=0.05550 11$LC=0.01034 20$MC=0.00248 5 -233PA G 815.9 4 0.0195 6 [M1] 0.0621 12 -233PA2 G KC=0.0498 10$LC=0.0093 2$MC=0.00223 5 -233PA G 880.9 5 0.0097 4 E2 0.0135 3 -233PA2 G KC=0.0100 2$LC=0.00258 5$MC=6.40E-4 13 +233PA G 398.8 5 0.0111 7[M1] 0.422 8 +233PA2 G KC=0.337 7$LC=0.0639 13$MC=0.0154 3 +233PA G 430.9 4 0.0178 4(M1) 0.342 6 +233PA2 G KC=0.273 5$LC=0.0517 10$MC=0.01245 24 +233PA G 783.2 5 0.0056 3[M1] 0.0692 14 +233PA2 G KC=0.05550 11$LC=0.01034 20$MC=0.00248 5 +233PA G 815.9 4 0.0195 6[M1] 0.0621 12 +233PA2 G KC=0.0498 10$LC=0.0093 2$MC=0.00223 5 +233PA G 880.9 5 0.0097 4E2 0.0135 3 +233PA2 G KC=0.0100 2$LC=0.00258 5$MC=6.40E-4 13 233PA G 890.1 5 0.1052 14[M1] 0.0493 10 -233PA2 G KC=0.0396 8$LC=0.00735 15$MC=0.00176 4 -233PA G 898.3 5 0.0022 4 [M1] 0.0481 10 -233PA2 G KC=0.0386 8$LC=0.00717 14$MC=0.00172 3 -233PA G 978.2 5 0.0058 3 [E1] 0.003747 -233PA2 G KC=0.00306 6$LC=0.00051 1$MC=1.21E-4 2 -233PA G 984.8 5 0.0102 3 [E1] 0.003697 -233PA2 G KC=0.00303 6$LC=0.00051 1$MC=1.20E-4 2 +233PA2 G KC=0.0396 8$LC=0.00735 15$MC=0.00176 4 +233PA G 898.3 5 0.0022 4[M1] 0.0481 10 +233PA2 G KC=0.0386 8$LC=0.00717 14$MC=0.00172 3 +233PA G 978.2 5 0.0058 3[E1] 0.00374 7 +233PA2 G KC=0.00306 6$LC=0.00051 1$MC=1.21E-4 2 +233PA G 984.8 5 0.0102 3[E1] 0.00369 7 +233PA2 G KC=0.00303 6$LC=0.00051 1$MC=1.20E-4 2 233PA L 1018.7 5 (3/2)+ -233PA B 224.4 140.0434 9 6.7 2 +233PA B 224.4 140.0434 9 6.7 233PAS B EAV=60.9 4 -233PA G 433.2 4 0.0117 4 -233PA G 806.4 5 0.0123 5 -233PA G 817.0 6 0.0095 5 -233PA G 849.5 5 0.0039 3 -233PA G 948.3 5 0.0060 3 +233PA G 433.2 4 0.0117 4 +233PA G 806.4 5 0.0123 5 +233PA G 817.0 6 0.0095 5 +233PA G 849.5 5 0.0039 3 +233PA G 948.3 5 0.0060 3 diff --git a/HEN_HOUSE/spectra/lnhb/Th-234.txt b/HEN_HOUSE/spectra/lnhb/Th-234.txt index f36648bff..07457478e 100644 --- a/HEN_HOUSE/spectra/lnhb/Th-234.txt +++ b/HEN_HOUSE/spectra/lnhb/Th-234.txt @@ -7,73 +7,73 @@ 234PA2C 1963BJ02, 1964AB04, 1965FO12, 1973TA25, 1973GO40, 1973SA33, 1978CH06, 234PA3C 1982MO30, 1990SC09, 1990CO08, 1993SU37, 1998AD08, 2003Au03, 2004AB03, 234PA4C 2006AL28, 2007BR04 -234PA T Auger electrons and ^X ray energies and emission intensities: -234PA T {U Energy (keV)} {U Intensity } {U Line } +234PA T Auger electrons and X ray energies and emission intensities: +234PA T {U Energy (keV)} {U Intensity} {U Line} 234PA T -234PA T 92.288 0.013 9 XKA2 -234PA T 95.869 0.021 13 XKA1 +234PA T 92.288 0.013 9 XKA2 +234PA T 95.869 0.021 13 XKA1 234PA T -234PA T 107.595 |] XKB3 -234PA T 108.422 |] 0.007 5 XKB1 -234PA T 109.072 |] XKB5II +234PA T 107.595 |] XKB3 +234PA T 108.422 |] 0.007 5 XKB1 +234PA T 109.072 |] XKB5II 234PA T -234PA T 111.405 |] XKB2 -234PA T 111.87 |] 0.0025 16 XKB4 -234PA T 112.38 |] XKO23 +234PA T 111.405 |] XKB2 +234PA T 111.87 |] 0.0025 16 XKB4 +234PA T 112.38 |] XKO23 234PA T -234PA T 11.3676-20.1126 7.1 3 XL (total) -234PA T 11.3676 0.178 12 XLL -234PA T 13.1215-13.2887 2.92 18 XLA -234PA T 14.9488 0.0423 29 XLC -234PA T 15.3584-17.6655 3.21 13 XLB -234PA T 18.9396-20.1126 0.766 29 XLG +234PA T 11.3676-20.1126 7.1 3 XL (total) +234PA T 11.3676 0.178 12 XLL +234PA T 13.1215-13.2887 2.92 18 XLA +234PA T 14.9488 0.0423 29 XLC +234PA T 15.3584-17.6655 3.21 13 XLB +234PA T 18.9396-20.1126 0.766 29 XLG 234PA T -234PA T 70.081-78.822 |] KLL AUGER -234PA T 85.989-95.858 |] 0.0014 9 ^KLX AUGER -234PA T 101.87-112.59 |] KXY AUGER -234PA T 5.9-21.6 7.7 6 L AUGER +234PA T 70.081-78.822 |] KLL AUGER +234PA T 85.989-95.858 |] 0.0014 9 KLX AUGER +234PA T 101.87-112.59 |] KXY AUGER +234PA T 5.9-21.6 7.7 6 L AUGER 234TH P 0.0 0+ 24.10 D 3 272 10 234PA N 1.0 1.0 1 1.0 234PA L 0 4+ 6.70 H 5 234PA L 73.92 (0)- 1.159 M 11 234PA B 198 1077.8 15 6.4 234PAS B EAV=53 3 -234PA G 73.92 2 0.0133 14M1+E2 0.11 3 10.6 4 -234PA2 G KC=$LC=7.96 25$MC=1.94 7 +234PA G 73.92 2 0.0133 14M1+E2 0.11 3 10.6 4 +234PA2 G LC=7.96 25$MC=1.94 7 234PA L 73.92 2 (3)+ 234PA B 198 1077.8 15 6.4 2U 234PAS B EAV=53 3 -234PA G 73.92 2 0.0133 14M1+E2 0.11 3 10.6 4 -234PA2 G KC=$LC=7.96 25$MC=1.94 7 +234PA G 73.92 2 0.0133 14M1+E2 0.11 3 10.6 4 +234PA2 G LC=7.96 25$MC=1.94 7 234PA L 103.42 (2)- 0.5 NS 234PA G 29.50 2 0.00123 14E2 4390 70 -234PA2 G KC=$LC=3210 50$MC=880 13 +234PA2 G LC=3210 50$MC=880 13 234PA L 166.3 (1)- 0.1 NS 234PA B 106 1014.1 12 6.3 1 234PAS B EAV=28 3 -234PA G 62.88 2 0.0164 28M1+E2 0.33 8 25 5 -234PA2 G KC=$LC=19 4$MC=4.8 9 -234PA G 92.38 1 2.18 19M1 5.27 8 -234PA2 G KC=$LC=3.98 6$MC=0.960 14 +234PA G 62.88 2 0.0164 28M1+E2 0.33 8 25 5 +234PA2 G LC=19 4$MC=4.8 9 +234PA G 92.38 1 2.18 19M1 5.27 8 +234PA2 G LC=3.98 6$MC=0.960 14 234PA L 166.72 (1)+ 0.55 NS 10 -234PA B 105 106.5 7 6.7 +234PA B 105 106.5 7 6.7 234PAS B EAV=27 3 -234PA G 63.30 2 3.75 8 E1 0.405 6 -234PA2 G KC=$LC=0.305 5$MC=0.0749 11 +234PA G 63.30 2 3.75 8E1 0.405 6 +234PA2 G LC=0.305 5$MC=0.0749 11 234PA G 92.80 2 2.15 19E1 0.1472 21 -234PA2 G KC=$LC=0.1110 16$MC=0.0271 4 +234PA2 G LC=0.1110 16$MC=0.0271 4 234PA L 177.27 1- -234PA B 95 100.016 5 9.1 1 +234PA B 95 100.016 5 9.1 1 234PAS B EAV=25 3 -234PA G 103.35 100.0032 10M1 3.81 6 -234PA2 G KC=$LC=2.88 5$MC=0.694 10 +234PA G 103.35 100.0032 10M1 3.81 6 +234PA2 G LC=2.88 5$MC=0.694 10 234PA L 186.73 (1)+ -234PA B 85 101.6 6 7 +234PA B 85 101.6 6 7 234PAS B EAV=22 3 234PA G 20.01 2 0.0051 21M1+E2 0.08 2 240 70 -234PA2 G KC=$LC=70 40$MC=124 21 -234PA G 83.31 5 0.061 5 E1 0.196 3 -234PA2 G KC=$LC=0.1475 21$MC=0.0361 5 +234PA2 G LC=70 40$MC=124 21 +234PA G 83.31 5 0.061 5E1 0.196 3 +234PA2 G LC=0.1475 21$MC=0.0361 5 234PA G 112.81 5 0.215 22E1 0.23 14 234PA2 G KC=0.21 13$LC=0.0666 10$MC=0.01620 23 diff --git a/HEN_HOUSE/spectra/lnhb/Ti-44.txt b/HEN_HOUSE/spectra/lnhb/Ti-44.txt index 58fc11ef3..677de8965 100644 --- a/HEN_HOUSE/spectra/lnhb/Ti-44.txt +++ b/HEN_HOUSE/spectra/lnhb/Ti-44.txt @@ -1,35 +1,35 @@ 44SC 44TI EC DECAY (60.0 Y) - 44SC T Auger electrons and ^X ray energies and emission intensities: - 44SC T {U Energy (keV)} {U Intensity } {U Line } + 44SC T Auger electrons and X ray energies and emission intensities: + 44SC T {U Energy (keV)} {U Intensity} {U Line} 44SC T - 44SC T 4.0862 5.76 18 XKA2 - 44SC T 4.0906 11.4 4 XKA1 + 44SC T 4.0862 5.76 18 XKA2 + 44SC T 4.0906 11.4 4 XKA1 44SC T - 44SC T 4.4604 |] 2.26 8 XKB1 - 44SC T 4.4866 |] XKB5II + 44SC T 4.4604 |] 2.26 8 XKB1 + 44SC T 4.4866 |] XKB5II 44SC T 44SC T - 44SC T 0.348-0.468 0.45 9 XL (total) + 44SC T 0.348-0.468 0.45 9 XL (total) 44SC T 0.348 XLL 44SC T -0.468 XLG 44SC T - 44SC T 3.45-3.65 |] KLL AUGER - 44SC T 3.93-4.08 |] 79.5 21 ^KLX AUGER - 44SC T 4.38-4.48 |] KXY AUGER - 44SC T 0.3-0.5 167.5 24 L AUGER + 44SC T 3.45-3.65 |] KLL AUGER + 44SC T 3.93-4.08 |] 79.5 21 KLX AUGER + 44SC T 4.38-4.48 |] KXY AUGER + 44SC T 0.3-0.5 167.5 24 L AUGER 44TI P 0.0 0+ 60.0 Y 11 267.5 19 44SC N 1.0 1.0 1 1.0 44SC L 0 2+ 3.97 H 4 44SC L 67.8680 141- 154.2 NS 8 44SC E 0.4 119.3 1 - 44SC2 E EAV= $CK=0.8917 19$CL=0.0938 16$CM=0.0145 7$CN= $CO= + 44SC2 E CK=0.8917 19$CL=0.0938 16$CM=0.0145 7 44SC G 67.8679 1493.0 15E1 0.0845 25 - 44SC2 G KC=0.0766 23$LC=6650E-6 0$MC=1250E-6 0 + 44SC2 G KC=0.0766 23$LC=0.00665 $MC=0.00125 44SC L 146.22 3 0- 50.4 US 7 44SC E 99.6 116.5 - 44SC2 E EAV= $CK=0.8891 20$CL=0.0960 16$CM=0.0149 7$CN= $CO= - 44SC G 78.36 3 96.4 11M1 0.032 1 - 44SC2 G KC=0.0273 8$LC=2440E-6 0$MC=4600E-7 0 - 44SC G 146.22 3 0.092 3 [M2] 0.046 1 - 44SC2 G KC=0.0414 12$LC=3850E-6 0$MC=7500E-7 0 + 44SC2 E CK=0.8891 20$CL=0.0960 16$CM=0.0149 7 + 44SC G 78.36 3 96.4 11M1 0.032 1 + 44SC2 G KC=0.0273 8$LC=0.00244 $MC=0.00046 + 44SC G 146.22 3 0.092 3[M2] 0.046 1 + 44SC2 G KC=0.0414 12$LC=0.00385 $MC=0.00075 diff --git a/HEN_HOUSE/spectra/lnhb/Tl-201.txt b/HEN_HOUSE/spectra/lnhb/Tl-201.txt index 15b83f0c6..2acb724e8 100644 --- a/HEN_HOUSE/spectra/lnhb/Tl-201.txt +++ b/HEN_HOUSE/spectra/lnhb/Tl-201.txt @@ -1,61 +1,59 @@ 201HG 201TL EC DECAY (3.0421 D) -201HG T Auger electrons and ^X ray energies and emission intensities: -201HG T {U Energy (keV)} {U Intensity } {U Line } +201HG T Auger electrons and X ray energies and emission intensities: +201HG T {U Energy (keV)} {U Intensity} {U Line} 201HG T -201HG T 68.895 27.3 5 XKA2 -201HG T 70.82 46.4 7 XKA1 +201HG T 68.895 27.3 5 XKA2 +201HG T 70.82 46.4 7 XKA1 201HG T -201HG T 79.823 |] XKB3 -201HG T 80.254 |] 15.7 4 XKB1 -201HG T 80.762 |] XKB5II +201HG T 79.823 |] XKB3 +201HG T 80.254 |] 15.7 4 XKB1 +201HG T 80.762 |] XKB5II 201HG T -201HG T 82.435 |] XKB2 -201HG T 82.776 |] 4.61 13 XKB4 -201HG T 83.028 |] XKO23 +201HG T 82.435 |] XKB2 +201HG T 82.776 |] 4.61 13 XKB4 +201HG T 83.028 |] XKO23 201HG T -201HG T 8.72-14.85 42.7 18 XL (total) -201HG T 8.72 0.88 15 XLL -201HG T 9.898-9.989 17.1 27 XLA -201HG T 10.651 0.26 6 XLC -201HG T 11.563-12.56 14.9 21 XLB -201HG T 13.41-14.85 2.8 5 XLG +201HG T 8.72-14.85 42.7 18 XL (total) +201HG T 8.72 0.88 15 XLL +201HG T 9.898-9.989 17.1 27 XLA +201HG T 10.651 0.26 6 XLC +201HG T 11.563-12.56 14.9 21 XLB +201HG T 13.41-14.85 2.8 5 XLG 201HG T -201HG T 53.178-58.277 |] KLL AUGER -201HG T 64.594-68.43 |] 3.7 4 ^KLX AUGER -201HG T 75.98-83.09 |] KXY AUGER -201HG T 5.1-14.8 57.7 7 L AUGER +201HG T 53.178-58.277 |] KLL AUGER +201HG T 64.594-68.43 |] 3.7 4 KLX AUGER +201HG T 75.98-83.09 |] KXY AUGER +201HG T 5.1-14.8 57.7 7 L AUGER 201TL P 0.0 1/2+ 3.0421 D 17 483 15 201HG N 1.0 1.0 1 1.0 201HG L 0 3/2- STABLE -201HG E 21 216.5 1U -201HG2 E EAV= $CK=0.763 3$CL=0.178 3$CM=0.0451 12$CN= $CO= +201HG E 21 216.5 1 +201HG2 E CK=0.763 3$CL=0.178 3$CM=0.0451 12 201HG L 1.565 1/2- 201HG E 25 226.5 -201HG2 E EAV= $CK=0.763 3$CL=0.178 3$CM=0.0451 12$CN= $CO= -201HG G 1.565 6 0.00081 47M1+E2 0.0105 15 4.7E4 7 -201HG2 G KC=$LC=$MC= +201HG2 E CK=0.763 3$CL=0.178 3$CM=0.0451 12 +201HG G 1.565 6 0.00081 47M1+E2 0.0105 15 4.7E4 7 201HG L 26.269 5/2- 630 PS -201HG E 0.23 8.5 3U -201HG2 E EAV= $CK= $CL= $CM= $CN= $CO= -201HG G 26.269 7 0.0082 9 M1(+E2) 0.02 76.9 23 -201HG2 G KC=$LC=58.8 18$MC=13.74 41 +201HG E 0.23 8.5 1U +201HG G 26.269 7 0.0082 9M1(+E2) 0.02 76.9 23 +201HG2 G LC=58.8 18$MC=13.74 41 201HG L 32.138 3/2- 0.2 NS -201HG E 13.0 5 6.9 1U -201HG2 E EAV= $CK=0.758 3$CL=0.181 3$CM=0.0461 12$CN= $CO= -201HG G 5.869 260.50000 0 [M1+E2] -201HG G 30.573 170.258 5 M1+E2 0.011 4 48.5 2 -201HG2 G KC=$LC=36.9 4$MC=8.79 26 -201HG G 32.138 160.263 5 M1+E2 0.017 40 41.9 2 -201HG2 G KC=$LC=32.0 4$MC=7.62 23 +201HG E 13.0 56.9 1 +201HG2 E CK=0.758 3$CL=0.181 3$CM=0.0461 12 +201HG G 5.869 260.5 [M1+E2] +201HG G 30.573 170.258 5M1+E2 0.011 4 48.5 2 +201HG2 G LC=36.9 4$MC=8.79 26 +201HG G 32.138 160.263 5M1+E2 0.017 40 41.9 2 +201HG2 G LC=32.0 4$MC=7.62 23 201HG L 167.45 1/2- 2 NS -201HG E 40.9 9 6.1 -201HG2 E EAV= $CK=0.724 7$CL=0.206 7$CM=0.054 2$CN= $CO= +201HG E 40.9 96.1 +201HG2 E CK=0.724 7$CL=0.206 7$CM=0.054 2 201HG G 135.312 342.604 22M1+E2 -0.06 1 3.45 10 -201HG2 G KC=2.83 3$LC=0.48 5$MC=0.1138 34 -201HG G 141.18 4 8000E-6 0 [E2] 1.41 4 -201HG2 G KC=0.372 11$LC=0.774 23$MC=0.202 6 -201HG G 165.885 310.147 2 M1(+E2) 0.4 1.86 8 -201HG2 G KC=1.57 3$LC=0.270 5$MC=0.0634 19 -201HG G 167.45 3 10.0 1 M1+E2 0.08 1.89 8 -201HG2 G KC=1.55 3$LC=0.262 5$MC=0.0620 19 +201HG2 G KC=2.83 3$LC=0.48 5$MC=0.1138 34 +201HG G 141.18 4 0.008 [E2] 1.41 4 +201HG2 G KC=0.372 11$LC=0.774 23$MC=0.202 6 +201HG G 165.885 310.147 2M1(+E2) 0.4 1.86 8 +201HG2 G KC=1.57 3$LC=0.270 5$MC=0.0634 19 +201HG G 167.45 3 10.0 1M1+E2 0.08 1.89 8 +201HG2 G KC=1.55 3$LC=0.262 5$MC=0.0620 19 diff --git a/HEN_HOUSE/spectra/lnhb/Tl-204.txt b/HEN_HOUSE/spectra/lnhb/Tl-204.txt index 0b9f03698..f2530b8cd 100644 --- a/HEN_HOUSE/spectra/lnhb/Tl-204.txt +++ b/HEN_HOUSE/spectra/lnhb/Tl-204.txt @@ -1,49 +1,49 @@ 204HG 204TL EC DECAY (3.788 Y) -204HG T Auger electrons and ^X ray energies and emission intensities: -204HG T {U Energy (keV)} {U Intensity } {U Line } +204HG T Auger electrons and X ray energies and emission intensities: +204HG T {U Energy (keV)} {U Intensity} {U Line} 204HG T -204HG T 68.895 0.474 20 XKA2 -204HG T 70.82 0.812 34 XKA1 +204HG T 68.895 0.474 20 XKA2 +204HG T 70.82 0.812 34 XKA1 204HG T -204HG T 79.823 |] XKB3 -204HG T 80.254 |] 0.273 10 XKB1 -204HG T 80.762 |] XKB5II +204HG T 79.823 |] XKB3 +204HG T 80.254 |] 0.273 10 XKB1 +204HG T 80.762 |] XKB5II 204HG T -204HG T 82.435 |] XKB2 -204HG T 82.776 |] 0.081 3 XKB4 -204HG T 83.028 |] XKO23 +204HG T 82.435 |] XKB2 +204HG T 82.776 |] 0.081 3 XKB4 +204HG T 83.028 |] XKO23 204HG T -204HG T 8.721-14.847 0.787 20 XL (total) -204HG T 8.721 0.0202 8 XLL -204HG T 9.898-9.989 0.395 14 XLA -204HG T 10.647 0.00488 22 XLC -204HG T 11.924-11.822 0.315 9 XLB -204HG T -14.847 0.0574 18 XLG +204HG T 8.721-14.847 0.787 20 XL (total) +204HG T 8.721 0.0202 8 XLL +204HG T 9.898-9.989 0.395 14 XLA +204HG T 10.647 0.00488 22 XLC +204HG T 11.924-11.822 0.315 9 XLB +204HG T -14.847 0.0574 18 XLG 204HG T -204HG T 53.17-58.28 |] KLL AUGER -204HG T 64.59-70.81 |] 0.065 8 ^KLX AUGER -204HG T 75.92-83.08 |] KXY AUGER -204HG T 5.1-14.8 1.48 3 L AUGER +204HG T 53.17-58.28 |] KLL AUGER +204HG T 64.59-70.81 |] 0.065 8 KLX AUGER +204HG T 75.92-83.08 |] KXY AUGER +204HG T 5.1-14.8 1.48 3 L AUGER 204TL P 0.0 2- 3.788 Y 15 345.0 13 204HG N 3.425E1 3.425E1 0.0292 3.425E1 204HG L 0 0+ STABLE 204HG E 2.92 139.6 1U -204HG2 E EAV= $CK=0.5843 14$CL=0.3024 10$CM=0.1133 5$CN= $CO= +204HG2 E CK=0.5843 14$CL=0.3024 10$CM=0.1133 5 204PB 204TL B- DECAY (3.788 Y) -204PB T Auger electrons and ^X ray energies and emission intensities: -204PB T {U Energy (keV)} {U Intensity } {U Line } +204PB T Auger electrons and X ray energies and emission intensities: +204PB T {U Energy (keV)} {U Intensity} {U Line} 204PB T -204PB T 72.8049 0.0044 3 XKA2 -204PB T 74.97 0.0061 3 XKA1 +204PB T 72.8049 0.0044 3 XKA2 +204PB T 74.97 0.0061 3 XKA1 204PB T -204PB T 84.451 |] XKB3 -204PB T 84.937 |] 0.0027 2 XKB1 -204PB T 85.47 |] XKB5II +204PB T 84.451 |] XKB3 +204PB T 84.937 |] 0.0027 2 XKB1 +204PB T 85.47 |] XKB5II 204PB T -204PB T 87.238 |] XKB2 -204PB T 87.58 |] 0.00073 2 XKB4 -204PB T 87.911 |] XKO23 +204PB T 87.238 |] XKB2 +204PB T 87.58 |] 0.00073 2 XKB4 +204PB T 87.911 |] XKO23 204PB T 204TL P 0.0 2- 3.788 Y 15 763.72 18 204PB N 1.03E0 1.03E0 0.9708 1.03E0 diff --git a/HEN_HOUSE/spectra/lnhb/Tl-206.txt b/HEN_HOUSE/spectra/lnhb/Tl-206.txt index f840f1e8e..62cd0fe00 100644 --- a/HEN_HOUSE/spectra/lnhb/Tl-206.txt +++ b/HEN_HOUSE/spectra/lnhb/Tl-206.txt @@ -2,30 +2,30 @@ 206PB H TYP=Full$AUT=F. Kondev$CUT=01-OCT-2006$ 206PB C Evaluation history: Type=Full;Author=F. Kondev;Cutoff date=01-OCT-2006 206PB C References: 1977La19, 2002Ba85, 2003Au03, 2005KiZW -206PB T Auger electrons and ^X ray energies and emission intensities: -206PB T {U Energy (keV)} {U Intensity } {U Line } +206PB T Auger electrons and X ray energies and emission intensities: +206PB T {U Energy (keV)} {U Intensity} {U Line} 206PB T -206PB T 72.8049 0.026 3 XKA2 -206PB T 74.97 0.044 5 XKA1 +206PB T 72.8049 0.026 3 XKA2 +206PB T 74.97 0.044 5 XKA1 206PB T -206PB T 84.451 |] XKB3 -206PB T 84.937 |] 0.0150 17 XKB1 -206PB T 85.47 |] XKB5II +206PB T 84.451 |] XKB3 +206PB T 84.937 |] 0.0150 17 XKB1 +206PB T 85.47 |] XKB5II 206PB T -206PB T 87.238 |] XKB2 -206PB T 87.58 |] 0.0045 6 XKB4 -206PB T 87.911 |] XKO23 +206PB T 87.238 |] XKB2 +206PB T 87.58 |] 0.0045 6 XKB4 +206PB T 87.911 |] XKO23 206PB T -206PB T 9.19-15.217 0.035 4 XL (total) +206PB T 9.19-15.217 0.035 4 XL (total) 206PB T 9.19 XLL 206PB T 10.449-10.551 XLA 206PB T 11.349 XLC 206PB T 12.144-12.795 XLB 206PB T 14.308-15.217 XLG 206PB T -206PB T 56.028-61.669 |] KLL AUGER -206PB T 68.181-74.969 |] 0.0034 6 ^KLX AUGER -206PB T 80.3-88 |] KXY AUGER +206PB T 56.028-61.669 |] KLL AUGER +206PB T 68.181-74.969 |] 0.0034 6 KLX AUGER +206PB T 80.3-88 |] KXY AUGER 206PB T 5.2-15.7 L AUGER 206TL P 0.0 0- 4.202 M 11 1532.4 6 206PB N 1.0 1.0 1 1.0 @@ -33,14 +33,14 @@ 206PB B 1532.4 6 99.885 14 5.2 206PBS B EAV=538.86 25 206PB L 803.06 3 2+ 8.14 PS 8 -206PB B 729.3 6 0.0051 3 8.6 1U +206PB B 729.3 6 0.0051 3 8.6 1U 206PBS B EAV=232.39 21 -206PB G 803.06 3 0.0050 3 E2 0.0103031 -206PB2 G KC=0.00801 24$LC=0.00174 5$MC=4.19E-4 13 +206PB G 803.06 3 0.0050 3E2 0.0103031 +206PB2 G KC=0.00801 24$LC=0.00174 5$MC=4.19E-4 13 206PB L 1166.4 5 0+ 0.75 NS 4 206PB B 366.0 8 0.110 14 6 206PBS B EAV=104.52 25 206PB G 363.3 5 0.00014 14E2 0.0663 20 -206PB2 G KC=0.0414 12$LC=0.0187 6$MC=0.00476 14 +206PB2 G KC=0.0414 12$LC=0.0187 6$MC=0.00476 14 206PB G 1165 2 diff --git a/HEN_HOUSE/spectra/lnhb/Tl-207.txt b/HEN_HOUSE/spectra/lnhb/Tl-207.txt index d357a9f84..811772020 100644 --- a/HEN_HOUSE/spectra/lnhb/Tl-207.txt +++ b/HEN_HOUSE/spectra/lnhb/Tl-207.txt @@ -6,46 +6,46 @@ 207PB3C 1974Ha34, 1976Av01, 1977La19, 1988Hi14, 1991Ar04, 1996Sc06, 1998ScZM, 207PB4C 1999ScZX, 2000Sc47, 2000He14, 2003De44, 2003Au03, 2008Ki07, 2008DuZX, 207PB5C 2011Ko04 -207PB T Auger electrons and ^X ray energies and emission intensities: -207PB T {U Energy (keV)} {U Intensity } {U Line } +207PB T Auger electrons and X ray energies and emission intensities: +207PB T {U Energy (keV)} {U Intensity} {U Line} 207PB T -207PB T 72.8049 0.00154 6 XKA2 -207PB T 74.97 0.00258 10 XKA1 +207PB T 72.8049 0.00154 6 XKA2 +207PB T 74.97 0.00258 10 XKA1 207PB T -207PB T 84.451 |] XKB3 -207PB T 84.937 |] 0.00088 4 XKB1 -207PB T 85.47 |] XKB5II +207PB T 84.451 |] XKB3 +207PB T 84.937 |] 0.00088 4 XKB1 +207PB T 85.47 |] XKB5II 207PB T -207PB T 87.238 |] XKB2 -207PB T 87.58 |] 0.000266 12 XKB4 -207PB T 87.911 |] XKO23 +207PB T 87.238 |] XKB2 +207PB T 87.58 |] 0.00026612 XKB4 +207PB T 87.911 |] XKO23 207PB T -207PB T 9.186-15.2169 0.00201 6 XL (total) -207PB T 9.186 0.0000500 19 XLL -207PB T 10.4495-10.5512 0.00095 4 XLA -207PB T 11.3495 0.0000150 7 XLC -207PB T 12.1443-13.3763 0.000841 24 XLB -207PB T 14.3078-15.2169 0.000159 5 XLG +207PB T 9.186-15.2169 0.00201 6 XL (total) +207PB T 9.186 5.00E-5 19 XLL +207PB T 10.4495-10.5512 0.00095 4 XLA +207PB T 11.3495 1.50E-5 7 XLC +207PB T 12.1443-13.3763 0.00084124 XLB +207PB T 14.3078-15.2169 0.000159 5 XLG 207PB T -207PB T 56.028-61.669 |] KLL AUGER -207PB T 68.181-74.969 |] 0.000202 23 ^KLX AUGER -207PB T 80.3-88 |] KXY AUGER -207PB T 5.33-15.82 0.00333 6 L AUGER +207PB T 56.028-61.669 |] KLL AUGER +207PB T 68.181-74.969 |] 0.00020223 KLX AUGER +207PB T 80.3-88 |] KXY AUGER +207PB T 5.33-15.82 0.00333 6 L AUGER 207TL P 0.0 1/2+ 4.774 M 12 1418 5 207PB N 1.0 1.0 1 1.0 207PB L 0 0 1/2- STABLE 207PB B 1418 5 99.729 10 5.11 207PBS B EAV=492.5 21 207PB L 569.6982 205/2- -207PB B 848 5 0.00008 10.8 3U +207PB B 848 5 0.00008 10.8 1U 207PBS B EAV=273.2 18 -207PB G 569.698 2 0.00185 19E2 0.0216 3 -207PB2 G KC=0.01584 23$LC=0.00439 7$MC=1081E-6 16 +207PB G 569.698 2 0.00185 19E2 0.0216 3 +207PB2 G KC=0.01584 23$LC=0.00439 7$MC=1081E-6 16 207PB L 897.698 173/2- -207PB B 520 5 0.271 10 6.15 1U +207PB B 520 5 0.271 10 6.15 1 207PBS B EAV=155.0 17 -207PB G 328.10 120.00142 14[M1] 0.334 5 -207PB2 G KC=0.273 4$LC=0.0466 7$MC=0.01090 16 -207PB G 897.77 120.263 9 M1+E2 0.091 9000 0.0233 4 -207PB2 G KC=0.0192 3$LC=0.00318 5$MC=7.41E-4 11 +207PB G 328.10 120.00142 14[M1] 0.334 5 +207PB2 G KC=0.273 4$LC=0.0466 7$MC=0.01090 16 +207PB G 897.77 120.263 9M1+E2 0.091 9000 0.0233 4 +207PB2 G KC=0.0192 3$LC=0.00318 5$MC=7.41E-4 11 diff --git a/HEN_HOUSE/spectra/lnhb/Tl-208.txt b/HEN_HOUSE/spectra/lnhb/Tl-208.txt index 927182f1d..75c1cfe73 100644 --- a/HEN_HOUSE/spectra/lnhb/Tl-208.txt +++ b/HEN_HOUSE/spectra/lnhb/Tl-208.txt @@ -12,11 +12,11 @@ 208PB T Auger electrons and X ray energies and emission intensities: 208PB T {U Energy (keV)} {U Intensity} {U Line} 208PB T -208PB T 72.8049 2.03 5 XKA2 -208PB T 74.97 3.42 7 XKA1 +208PB T 72.8049 2.03 5 XKA2 +208PB T 74.97 3.42 7 XKA1 208PB T 208PB T 84.451 |] XKB3 -208PB T 84.937 |] 1.17 3 XKB1 +208PB T 84.937 |] 1.17 3 XKB1 208PB T 85.47 |] XKB5II 208PB T 208PB T 87.238 |] XKB2 @@ -25,118 +25,118 @@ 208PB T 208PB T 9.184-15.216 2.75 12 XL (total) 208PB T 9.184 0.0671 19 XLL -208PB T 10.45-10.551 1.27 4 XLA -208PB T 11.349 0.0209 7 XLC +208PB T 10.45-10.551 1.27 4 XLA +208PB T 11.349 0.0209 7 XLC 208PB T 12.142-13.015 1.155 25 XLB -208PB T 14.765-15.216 0.220 5 XLG +208PB T 14.765-15.216 0.220 5 XLG 208PB T 208PB T 56.028-61.669 |] KLL AUGER -208PB T 68.181-74.969 |] 0.27 3 KLX AUGER +208PB T 68.181-74.969 |] 0.27 3 KLX AUGER 208PB T 80.3-88 |] KXY AUGER 208PB T 5.262-10.398 4.50 13 L AUGER 208TL P 0.0 5+ 3.058 M 6 4999.0 17 208PB N 1.0 1.0 1 1.0 -208PB G 808.32 130.030 7 +208PB G 808.32 130.030 7 208PB G 835.90 110.076 11 208PB L 0 0+ STABLE 208PB L 2614.552 103- -208PB G 2614.511 1099.755 4 E3 0.002464 -208PB2 G KC=1708E-6 24$LC=2.92E-4 4$MC=6.85E-5 10 +208PB G 2614.511 1099.755 4E3 0.00246 4 +208PB2 G KC=1708E-6 24$LC=2.92E-4 4$MC=6.85E-5 10 208PB L 3197.711 105- -208PB B 1801.3 1749.2 6 5.61 +208PB B 1801.3 1749.2 6 5.61 208PBS B EAV=649.5 7 -208PB G 583.187 2 85.0 3 E2 0.0205 3 -208PB2 G KC=0.01509 22$LC=0.00410 6$MC=1009E-6 15 +208PB G 583.187 2 85.0 3E2 0.0205 3 +208PB2 G KC=0.01509 22$LC=0.00410 6$MC=1009E-6 15 208PB L 3475.078 114- -208PB B 1523.9 1722.1 5 5.69 1 +208PB B 1523.9 1722.1 5 5.69 1 208PBS B EAV=535.4 7 -208PB G 277.37 2 6.6 3 [M1+E2] 0.02 1 0.529 8 -208PB2 G KC=0.432 6$LC=0.0739 11$MC=0.01730 25 -208PB G 860.53 2 12.4 1 [M1+E2] 0.015 0.0262 4 -208PB2 G KC=0.0215 3$LC=0.00356 5$MC=8.31E-4 12 +208PB G 277.37 2 6.6 3[M1+E2] 0.02 1 0.529 8 +208PB2 G KC=0.432 6$LC=0.0739 11$MC=0.01730 25 +208PB G 860.53 2 12.4 1[M1+E2] 0.015 0.0262 4 +208PB2 G KC=0.0215 3$LC=0.00356 5$MC=8.31E-4 12 208PB L 3708.451 125- -208PB B 1290.5 1724.1 2 5.38 +208PB B 1290.5 1724.1 2 5.38 208PBS B EAV=441.5 7 -208PB G 233.37 2 0.31 1 [M1+E2] 0.70 7 0.66 3 -208PB2 G KC=0.51 3$LC=0.1136 18$MC=0.0275 4 -208PB G 510.74 2 22.5 2 [M1+E2] -0.05 5 0.1019 16 -208PB2 G KC=0.0835 13$LC=0.01406 21$MC=0.00329 5 -208PB G 1093.90 2 0.44 1 E2 0.005608 -208PB2 G KC=0.00449 7$LC=8.44E-4 12$MC=2.00E-4 3 +208PB G 233.37 2 0.31 1[M1+E2] 0.70 7 0.66 3 +208PB2 G KC=0.51 3$LC=0.1136 18$MC=0.0275 4 +208PB G 510.74 2 22.5 2[M1+E2] -0.05 5 0.1019 16 +208PB2 G KC=0.0835 13$LC=0.01406 21$MC=0.00329 5 +208PB G 1093.90 2 0.44 1E2 0.00560 8 +208PB2 G KC=0.00449 7$LC=8.44E-4 12$MC=2.00E-4 3 208PB L 3919.966 136- -208PB B 1079.0 170.63 4 6.68 1 +208PB B 1079.0 170.63 4 6.68 1 208PBS B EAV=358.6 7 -208PB G 211.52 2 0.18 1 M1+E2 0.18 2 1.096 17 -208PB2 G KC=0.890 14$LC=0.1570 22$MC=0.0369 6 -208PB G 722.26 2 0.24 4 M1+E2 0.31 3 0.0387 7 -208PB2 G KC=0.0317 6$LC=0.00534 10$MC=1248E-6 22 +208PB G 211.52 2 0.18 1M1+E2 0.18 2 1.096 17 +208PB2 G KC=0.890 14$LC=0.1570 22$MC=0.0369 6 +208PB G 722.26 2 0.24 4M1+E2 0.31 3 0.0387 7 +208PB2 G KC=0.0317 6$LC=0.00534 10$MC=1248E-6 22 208PB L 3946.578 144- -208PB B 1052.4 170.048 3 7.76 1 +208PB B 1052.4 170.048 3 7.76 1 208PBS B EAV=348.4 7 -208PB G 748.87 2 0.046 3 [M1] 0.0375 6 -208PB2 G KC=0.0308 5$LC=0.00512 8$MC=1196E-6 17 +208PB G 748.87 2 0.046 3[M1] 0.0375 6 +208PB2 G KC=0.0308 5$LC=0.00512 8$MC=1196E-6 17 208PB L 3961.162 135- -208PB B 1037.8 173.17 4 5.92 +208PB B 1037.8 173.17 4 5.92 208PBS B EAV=342.8 7 -208PB G 252.71 2 0.78 2 [M1+E2] -0.40 4 0.616 15 -208PB2 G KC=0.495 14$LC=0.0926 14$MC=0.0220 4 -208PB G 486.08 2 0.049 4 [M1] 0.1164 17 -208PB2 G KC=0.0954 14$LC=0.01608 23$MC=0.00376 6 -208PB G 763.45 2 1.80 2 [M1+E2] -0.10 1 0.0354 5 -208PB2 G KC=0.0291 4$LC=0.00484 7$MC=1130E-6 16 +208PB G 252.71 2 0.78 2[M1+E2] -0.40 4 0.616 15 +208PB2 G KC=0.495 14$LC=0.0926 14$MC=0.0220 4 +208PB G 486.08 2 0.049 4[M1] 0.1164 17 +208PB2 G KC=0.0954 14$LC=0.01608 23$MC=0.00376 6 +208PB G 763.45 2 1.80 2[M1+E2] -0.10 1 0.0354 5 +208PB2 G KC=0.0291 4$LC=0.00484 7$MC=1130E-6 16 208PB L 3995.438 134- -208PB B 1003.6 170.007 3 8.5 1 +208PB B 1003.6 170.007 3 8.5 1 208PBS B EAV=329.7 7 -208PB G 1380.89 2 0.007 3 [M1] 0.0078511 -208PB2 G KC=0.00643 9$LC=1050E-6 15$MC=2.45E-4 4 +208PB G 1380.89 2 0.007 3[M1] 0.0078511 +208PB2 G KC=0.00643 9$LC=1050E-6 15$MC=2.45E-4 4 208PB L 4125.347 125- -208PB B 873.7 170.174 9 6.92 +208PB B 873.7 170.174 9 6.92 208PBS B EAV=280.8 6 -208PB G 650.27 2 0.041 5 [M1] 0.0541 8 -208PB2 G KC=0.0444 7$LC=0.00742 11$MC=1733E-6 25 -208PB G 927.64 2 0.128 7 [M1] 0.0216 3 -208PB2 G KC=0.01774 25$LC=0.00293 5$MC=6.84E-4 10 +208PB G 650.27 2 0.041 5[M1] 0.0541 8 +208PB2 G KC=0.0444 7$LC=0.00742 11$MC=1733E-6 25 +208PB G 927.64 2 0.128 7[M1] 0.0216 3 +208PB2 G KC=0.01774 25$LC=0.00293 5$MC=6.84E-4 10 208PB L 4180.414 145- -208PB B 818.6 170.231 9 6.7 +208PB B 818.6 170.231 9 6.7 208PBS B EAV=260.4 6 -208PB G 705.34 2 0.022 4 [M1] 0.0438 7 -208PB2 G KC=0.0360 5$LC=0.00599 9$MC=1399E-6 20 -208PB G 982.70 2 0.204 8 [M1] 0.0186 3 -208PB2 G KC=0.01530 22$LC=0.00253 4$MC=5.89E-4 9 +208PB G 705.34 2 0.022 4[M1] 0.0438 7 +208PB2 G KC=0.0360 5$LC=0.00599 9$MC=1399E-6 20 +208PB G 982.70 2 0.204 8[M1] 0.0186 3 +208PB2 G KC=0.01530 22$LC=0.00253 4$MC=5.89E-4 9 208PB L 4261.871 134- -208PB B 737.1 170.002 1 8.6 1 +208PB B 737.1 170.002 1 8.6 1 208PBS B EAV=230.8 6 -208PB G 1647.32 2 0.002 1 [M1] 0.005188 -208PB2 G KC=0.00411 6$LC=6.69E-4 10$MC=1556E-7 22 +208PB G 1647.32 2 0.002 1[M1] 0.00518 8 +208PB2 G KC=0.00411 6$LC=6.69E-4 10$MC=1556E-7 22 208PB L 4296.560 135- 208PB B 702.4 170.102 11 6.82 208PBS B EAV=218.3 6 -208PB G 588.108 180.06 1 [M1] 0.0704 10 -208PB2 G KC=0.0577 8$LC=0.00968 14$MC=0.00226 4 -208PB G 821.48 2 0.041 4 M1 0.0295 5 -208PB2 G KC=0.0242 4$LC=0.00402 6$MC=9.39E-4 14 +208PB G 588.108 180.06 1[M1] 0.0704 10 +208PB2 G KC=0.0577 8$LC=0.00968 14$MC=0.00226 4 +208PB G 821.48 2 0.041 4M1 0.0295 5 +208PB2 G KC=0.0242 4$LC=0.00402 6$MC=9.39E-4 14 208PB L 4323.946 144+ -208PB B 675.1 170.005 2 8.1 +208PB B 675.1 170.005 2 8.1 208PBS B EAV=208.6 6 -208PB G 1126.24 2 0.005 2 E1 0.002033 -208PB2 G KC=1691E-6 24$LC=2.56E-4 4$MC=5.90E-5 9 +208PB G 1126.24 2 0.005 2E1 0.00203 3 +208PB2 G KC=1691E-6 24$LC=2.56E-4 4$MC=5.90E-5 9 208PB L 4358.670 134- -208PB B 640.3 170.045 4 7.04 1 +208PB B 640.3 170.045 4 7.04 1 208PBS B EAV=196.4 6 -208PB G 883.59 2 0.031 3 [M1] 0.0244 4 -208PB2 G KC=0.0201 3$LC=0.00333 5$MC=7.76E-4 11 -208PB G 1160.96 2 0.011 3 [M1] 0.0121417 -208PB2 G KC=0.01000 14$LC=1641E-6 23$MC=3.82E-4 6 -208PB G 1744.120 160.002 1 M1+E2 0.004577 -208PB2 G KC=0.00356 5$LC=5.78E-4 8$MC=1344E-7 19 +208PB G 883.59 2 0.031 3[M1] 0.0244 4 +208PB2 G KC=0.0201 3$LC=0.00333 5$MC=7.76E-4 11 +208PB G 1160.96 2 0.011 3[M1] 0.0121417 +208PB2 G KC=0.01000 14$LC=1641E-6 23$MC=3.82E-4 6 +208PB G 1744.120 160.002 1M1+E2 0.00457 7 +208PB2 G KC=0.00356 5$LC=5.78E-4 8$MC=1344E-7 19 208PB L 4383.285 176- -208PB B 615.7 170.017 5 7.41 1 +208PB B 615.7 170.017 5 7.41 1 208PBS B EAV=187.7 6 -208PB G 1185.57 2 0.017 5 [M1] 0.0115117 -208PB2 G KC=0.00947 14$LC=1555E-6 22$MC=3.62E-4 5 +208PB G 1185.57 2 0.017 5[M1] 0.0115117 +208PB2 G KC=0.00947 14$LC=1555E-6 22$MC=3.62E-4 5 208PB L 4480.746 166- -208PB B 518.3 170.052 5 6.67 1 +208PB B 518.3 170.052 5 6.67 1 208PBS B EAV=154.3 6 -208PB G 1283.04 2 0.052 5 [M1] 0.0094314 -208PB2 G KC=0.00775 11$LC=1269E-6 18$MC=2.95E-4 5 +208PB G 1283.04 2 0.052 5[M1] 0.0094314 +208PB2 G KC=0.00775 11$LC=1269E-6 18$MC=2.95E-4 5 diff --git a/HEN_HOUSE/spectra/lnhb/Tl-209.txt b/HEN_HOUSE/spectra/lnhb/Tl-209.txt index 978251fc2..1bfcff467 100644 --- a/HEN_HOUSE/spectra/lnhb/Tl-209.txt +++ b/HEN_HOUSE/spectra/lnhb/Tl-209.txt @@ -5,96 +5,96 @@ 209PB2C 1989Ko26, 1991Ma16, 1993El08, 1996Sc06, 1998ScZM, 1998Ar03, 1999GrZT, 209PB3C 1999ScZX, 2000Sc47, 2000Gr35, 2003Au03, 2003De44, 2003ChZV, 2008Ki07, 209PB4C 2008DuZX -209PB T Auger electrons and ^X ray energies and emission intensities: -209PB T {U Energy (keV)} {U Intensity } {U Line } +209PB T Auger electrons and X ray energies and emission intensities: +209PB T {U Energy (keV)} {U Intensity} {U Line} 209PB T -209PB T 72.8049 5.85 10 XKA2 -209PB T 74.97 9.84 16 XKA1 +209PB T 72.8049 5.85 10 XKA2 +209PB T 74.97 9.84 16 XKA1 209PB T -209PB T 84.451 |] XKB3 -209PB T 84.937 |] 3.36 8 XKB1 -209PB T 85.47 |] XKB5II +209PB T 84.451 |] XKB3 +209PB T 84.937 |] 3.36 8 XKB1 +209PB T 85.47 |] XKB5II 209PB T -209PB T 87.238 |] XKB2 -209PB T 87.58 |] 1.016 28 XKB4 -209PB T 87.911 |] XKO23 +209PB T 87.238 |] XKB2 +209PB T 87.58 |] 1.016 28 XKB4 +209PB T 87.911 |] XKO23 209PB T -209PB T 9.186-15.2169 8.04 14 XL (total) -209PB T 9.186 0.196 6 XLL -209PB T 10.4495-10.5512 3.72 9 XLA -209PB T 11.3495 0.0637 18 XLC -209PB T 12.1443-13.3763 3.41 7 XLB -209PB T 14.3078-15.2169 0.648 14 XLG +209PB T 9.186-15.2169 8.04 14 XL (total) +209PB T 9.186 0.196 6 XLL +209PB T 10.4495-10.5512 3.72 9 XLA +209PB T 11.3495 0.0637 18 XLC +209PB T 12.1443-13.3763 3.41 7 XLB +209PB T 14.3078-15.2169 0.648 14 XLG 209PB T -209PB T 56.028-61.669 |] KLL AUGER -209PB T 68.181-74.969 |] 0.77 9 ^KLX AUGER -209PB T 80.3-88 |] KXY AUGER -209PB T 5.34-15.82 13.23 15 L AUGER +209PB T 56.028-61.669 |] KLL AUGER +209PB T 68.181-74.969 |] 0.77 9 KLX AUGER +209PB T 80.3-88 |] KXY AUGER +209PB T 5.34-15.82 13.23 15 L AUGER 209TL P 0.0 1/2+ 2.161 M 7 3976 8 209PB N 1.0 1.0 1 1.0 -209PB G 469.7 3 0.12 3 -209PB G 860.5 3 0.26 4 -209PB G 890.0 4 0.12 3 -209PB G 902.8 4 0.10 2 +209PB G 469.7 3 0.12 3 +209PB G 860.5 3 0.26 4 +209PB G 890.0 4 0.12 3 +209PB G 902.8 4 0.10 2 209PB G 970.3 0.054 15 -209PB G 1661.1 5 0.10 2 -209PB G 1673.2 4 0.48 4 -209PB G 1781.7 5 0.04 2 -209PB G 2005.3 2 0.020 5 -209PB G 2032.1 5 1000E-6 0 -209PB G 2548.2 0.015 6 +209PB G 1661.1 5 0.10 2 +209PB G 1673.2 4 0.48 4 +209PB G 1781.7 5 0.04 2 +209PB G 2005.3 2 0.020 5 +209PB G 2032.1 5 0.001 +209PB G 2548.2 0.015 6 209PB L 0 9/2+ 3.277 H 15 209PB L 1566.94 5 5/2+ -209PB G 1566.93 5 99.707 5 E2 0.002945 -209PB2 G KC=0.00234 4$LC=3.96E-4 6$MC=9.26E-5 13 +209PB G 1566.93 5 99.707 5E2 0.00294 5 +209PB2 G KC=0.00234 4$LC=3.96E-4 6$MC=9.26E-5 13 209PB L 2032.07 6 1/2+ 209PB B 1944 8 0.1 8.3 209PBS B EAV=709.0 34 -209PB G 465.128 2496.62 5 E2 0.0350 5 -209PB2 G KC=0.0242 4$LC=0.00815 12$MC=0.00204 3 +209PB G 465.128 2496.62 5E2 0.0350 5 +209PB2 G KC=0.0242 4$LC=0.00815 12$MC=0.00204 3 209PB L 2149.29 6 1/2- 209PB B 1827 8 97.70 15 5.2 209PBS B EAV=660.0 34 -209PB G 117.224 7 77.22 27E1 0.295 5 -209PB2 G KC=0.235 4$LC=0.0455 7$MC=0.01072 15 -209PB G 582.4 2 0.312 24[M2] 0.200 3 -209PB2 G KC=0.1574 22$LC=0.0322 5$MC=0.00774 11 -209PB G 2149 1 0.015 5 [M4] 0.0152922 -209PB2 G KC=0.01218 18$LC=0.00237 4$MC=5.65E-4 8 +209PB G 117.224 7 77.22 27E1 0.295 5 +209PB2 G KC=0.235 4$LC=0.0455 7$MC=0.01072 15 +209PB G 582.4 2 0.312 24[M2] 0.200 3 +209PB2 G KC=0.1574 22$LC=0.0322 5$MC=0.00774 11 +209PB G 2149 1 0.015 5[M4] 0.0152922 +209PB2 G KC=0.01218 18$LC=0.00237 4$MC=5.65E-4 8 209PB L 2315.68 13(3/2)- -209PB B 1660 8 0.32 11 7.5 1U +209PB B 1660 8 0.32 11 7.5 1 209PBS B EAV=591.2 33 -209PB G 284.04 230.14 7 [M1] 0.495 7 -209PB2 G KC=0.405 6$LC=0.0692 10$MC=0.01620 23 -209PB G 748.3 2 0.080 21[E1] 0.004286 -209PB2 G KC=0.00356 5$LC=5.53E-4 8$MC=1280E-7 18 -209PB G 2315.80 210.0288 21[E3] 0.002924 -209PB2 G KC=0.00216 3$LC=3.80E-4 6$MC=8.93E-5 13 +209PB G 284.04 230.14 7[M1] 0.495 7 +209PB2 G KC=0.405 6$LC=0.0692 10$MC=0.01620 23 +209PB G 748.30 200.080 21[E1] 0.00428 6 +209PB2 G KC=0.00356 5$LC=5.53E-4 8$MC=1280E-7 18 +209PB G 2315.80 210.0288 21[E3] 0.00292 4 +209PB2 G KC=0.00216 3$LC=3.80E-4 6$MC=8.93E-5 13 209PB L 2460.8 3 (5/2)- -209PB B 1515 8 0.031 16 9.2 3U +209PB B 1515 8 0.031 16 9.2 1U 209PBS B EAV=518.1 31 -209PB G 311.5 3 0.028 14[E2] 0.1034 15 -209PB2 G KC=0.0596 9$LC=0.0329 5$MC=0.00842 13 +209PB G 311.50 300.028 14[E2] 0.1034 15 +209PB2 G KC=0.0596 9$LC=0.0329 5$MC=0.00842 13 209PB L 2524.79 21(1/2,3/2)+ 209PB B 1451 8 0.070 15 8 209PBS B EAV=505.9 33 -209PB G 375.5 2 0.070 15 +209PB G 375.50 200.070 15 209PB L 2905.14 253/2- -209PB B 1071 8 0.70 9 6.5 1U +209PB B 1071 8 0.70 9 6.5 1 209PBS B EAV=355.5 31 -209PB G 755.6 3 0.11 2 [M1] 0.0366 6 -209PB2 G KC=0.0301 5$LC=0.00500 7$MC=1168E-6 17 -209PB G 873.5 4 0.59 8 [E1] 0.003205 -209PB2 G KC=0.00267 4$LC=4.10E-4 6$MC=9.47E-5 14 +209PB G 755.60 300.11 2[M1] 0.0366 6 +209PB2 G KC=0.0301 5$LC=0.00500 7$MC=1168E-6 17 +209PB G 873.50 400.59 8[E1] 0.00320 5 +209PB2 G KC=0.00267 4$LC=4.10E-4 6$MC=9.47E-5 14 209PB L 3069.72 133/2- -209PB B 906 8 0.645 16 6.3 1U +209PB B 906 8 0.645 16 6.3 1 209PBS B EAV=292.9 30 -209PB G 920.43 110.631 15[M1] 0.0220 3 -209PB2 G KC=0.0181 3$LC=0.00299 5$MC=6.98E-4 10 +209PB G 920.43 110.631 15[M1] 0.0220 3 +209PB2 G KC=0.0181 3$LC=0.00299 5$MC=6.98E-4 10 209PB L 3361.36 17(1/2,3/2)+ -209PB B 615 8 0.10 3 +209PB B 615 8 0.10 3 209PBS B EAV=187.4 28 -209PB G 1329.29 160.10 3 +209PB G 1329.29 160.10 3 209PB L 3388.96 13(1/2,3/2)+ 209PB B 587 8 0.420 22 209PBS B EAV=177.8 28 diff --git a/HEN_HOUSE/spectra/lnhb/Tl-210.txt b/HEN_HOUSE/spectra/lnhb/Tl-210.txt index 36e9eb441..c4b00f849 100644 --- a/HEN_HOUSE/spectra/lnhb/Tl-210.txt +++ b/HEN_HOUSE/spectra/lnhb/Tl-210.txt @@ -3,19 +3,19 @@ 210PB C Evaluation history: Type=Full;Author=V.Chisté;Cutoff date=31-AUG-2007 210PB C References: 1931Cu01, 1957Ko42, 1961St20, 1964We06, 1981Ha54, 1996Sc06, 210PB2C 2002Ba85, 2003Au03, 2003Br13 -210PB T Auger electrons and ^X ray energies and emission intensities: -210PB T {U Energy (keV)} {U Intensity } {U Line } +210PB T Auger electrons and X ray energies and emission intensities: +210PB T {U Energy (keV)} {U Intensity} {U Line} 210PB T -210PB T 72.805 7 4 XKA2 -210PB T 74.97 11 6 XKA1 +210PB T 72.805 7 4 XKA2 +210PB T 74.97 11 6 XKA1 210PB T -210PB T 84.451 |] XKB3 -210PB T 84.937 |] 3.8 19 XKB1 -210PB T 85.47 |] XKB5II +210PB T 84.451 |] XKB3 +210PB T 84.937 |] 3.8 19 XKB1 +210PB T 85.47 |] XKB5II 210PB T -210PB T 87.238 |] XKB2 -210PB T 87.58 |] 1.1 6 XKB4 -210PB T 87.911 |] XKO23 +210PB T 87.238 |] XKB2 +210PB T 87.58 |] 1.1 6 XKB4 +210PB T 87.911 |] XKO23 210PB T 210PB T 9.186 XLL 210PB T 10.449-10.551 XLA @@ -24,32 +24,32 @@ 210PB T 14.308-15.217 XLG 210TL P 0.0 (5)+ 1.30 M 3 5482 12 210PB N 1.0 1.0 1 1.0 -210PB G 83 301.98 40[E2] 14.00000 -210PB G 356 104 2 [M1] 0.270 22 -210PB G 382 103 2 [M1] 0.223 17 -210PB G 670 202 1 -210PB G 910 303 2 -210PB G 1490 202 1 -210PB G 1540 302 1 -210PB G 1650 302 1 +210PB G 83 301.98 40[E2] 14 +210PB G 356 104 2[M1] 0.270 22 +210PB G 382 103 2[M1] 0.223 17 +210PB G 670 202 1 +210PB G 910 303 2 +210PB G 1490 202 1 +210PB G 1540 302 1 +210PB G 1650 302 1 210PB G 2090 304.9 20 210PB L 0 0+ 22.23 Y 12 210PB L 799.6 3 2+ 17 PS 5 210PB G 799.6 3 98.969 30E2 0.0104231 -210PB2 G KC=0.00811 24$LC=0.00176 5$MC=4.25E-4 13 +210PB2 G KC=0.00811 24$LC=0.00176 5$MC=4.25E-4 13 210PB L 1096 3 4+ 0.6 NS 1 210PB B 4386 1213 7.3 210PBS B EAV=1763 5 -210PB G 296 3 79 10E2 0.120 5 -210PB2 G KC=0.0671 19$LC=0.0399 17$MC=0.0103 5 +210PB G 296 3 79 10E2 0.120 5 +210PB2 G KC=0.0671 19$LC=0.0399 17$MC=0.0103 5 210PB L 1192 246+ 49 NS 6 210PB B 4290 1231 6.9 210PBS B EAV=1721 11 -210PB G 97 304 2 M1+E2 1 9.000000 -210PB2 G KC=4.00000 0$LC=3.00000 0$MC=0.80000 0 +210PB G 97 304 2M1+E2 1 9 +210PB2 G KC=4 $LC=3 $MC=0.8 210PB L 1869 103- -210PB G 1070 2011.9 49[E1] 0.002227 -210PB2 G KC=0.00185 6$LC=2.81E-4 8$MC=6.5E-5 2 +210PB G 1070 2011.9 49[E1] 0.00222 7 +210PB2 G KC=0.00185 6$LC=2.81E-4 8$MC=6.5E-5 2 210PB L 2208 13(2)+ 210PB G 1110 206.9 20 210PB G 1410 204.9 20 @@ -59,11 +59,11 @@ 210PB B 2413 1210 6.4 2U 210PBS B EAV=907 7 210PB G 860 306.9 20 -210PB G 2280 123 2 +210PB G 2280 123 2 210PB L 3458 22(4)+ 210PB B 2024 1210 6.1 210PBS B EAV=743 10 -210PB G 1590 302 1 +210PB G 1590 302 1 210PB G 2360 307.9 30 210PB L 3622 21 + 210PB B 1860 1224 5.6 @@ -77,5 +77,5 @@ 210PB L 4102 29 + 210PB B 1380 122 6.2 210PBS B EAV=477 13 -210PB G 480 362 1 +210PB G 480 362 1 diff --git a/HEN_HOUSE/spectra/lnhb/Tm-170.txt b/HEN_HOUSE/spectra/lnhb/Tm-170.txt index 68484eb54..23b481bc0 100644 --- a/HEN_HOUSE/spectra/lnhb/Tm-170.txt +++ b/HEN_HOUSE/spectra/lnhb/Tm-170.txt @@ -1,72 +1,72 @@ 170ER 170TM EC DECAY (127.8 D) 170ER C References: 1962Bo12, 1977La19 -170ER T Auger electrons and ^X ray energies and emission intensities: -170ER T {U Energy (keV)} {U Intensity } {U Line } +170ER T Auger electrons and X ray energies and emission intensities: +170ER T {U Energy (keV)} {U Intensity} {U Line} 170ER T -170ER T 48.2212 0.332 16 XKA2 -170ER T 49.1276 0.0590 24 XKA1 +170ER T 48.2212 0.332 16 XKA2 +170ER T 49.1276 0.0590 24 XKA1 170ER T -170ER T 55.4797 |] XKB3 -170ER T 55.6737 |] 0.0191 10 XKB1 -170ER T 56.0322 |] XKB5II -170ER T 56.0762 |] XKB5I +170ER T 55.4797 |] XKB3 +170ER T 55.6737 |] 0.0191 10 XKB1 +170ER T 56.0322 |] XKB5II +170ER T 56.0762 |] XKB5I 170ER T -170ER T 57.142 |] XKB2 -170ER T 57.313 |] 0.0050 3 XKB4 -170ER T 57.456 |] XKO23 +170ER T 57.142 |] XKB2 +170ER T 57.313 |] 0.0050 3 XKB4 +170ER T 57.456 |] XKO23 170ER T -170ER T 6.15-9.43 0.0306 19 XL (total) +170ER T 6.15-9.43 0.0306 19 XL (total) 170ER T 6.15 XLL 170ER T -9.43 XLG 170ER T -170ER T 37.79-40.56 |] KLL AUGER -170ER T 45.47-49.1 |] 0.0072 6 ^KLX AUGER -170ER T 53.02-57.43 |] KXY AUGER +170ER T 37.79-40.56 |] KLL AUGER +170ER T 45.47-49.1 |] 0.0072 6 KLX AUGER +170ER T 53.02-57.43 |] KXY AUGER 170TM P 0.0 1- 127.8 D 6 314.4 18 170ER N 6.803E2 6.803E2 0.00147 6.803E2 170ER L 0 0+ STABLE -170ER E 0.118 7 9.906 1 -170ER2 E EAV= $CK=0.7838 19$CL=0.1645 13$CM=0.0401 8$CN= $CO= +170ER E 0.118 79.906 1 +170ER2 E CK=0.7838 19$CL=0.1645 13$CM=0.0401 8 170ER L 78.59 2 2+ -170ER E 0.029 3 10.21 1 -170ER2 E EAV= $CK=0.7595 22$CL=0.1822 15$CM=0.0451 9$CN= $CO= -170ER G 78.59 2 0.0034 3 E2 7.6 5 -170ER2 G KC=1.72 11$LC=4.51 30$MC=1.10 7 +170ER E 0.029 310.21 1 +170ER2 E CK=0.7595 22$CL=0.1822 15$CM=0.0451 9 +170ER G 78.59 2 0.0034 3E2 7.6 5 +170ER2 G KC=1.72 11$LC=4.51 30$MC=1.10 7 170YB 170TM B- DECAY (127.8 D) 170YB C References: 1962Bo12, 1977La19 -170YB T Auger electrons and ^X ray energies and emission intensities: -170YB T {U Energy (keV)} {U Intensity } {U Line } +170YB T Auger electrons and X ray energies and emission intensities: +170YB T {U Energy (keV)} {U Intensity} {U Line} 170YB T -170YB T 51.3546 0.95 4 XKA2 -170YB T 52.3895 1.67 7 XKA1 +170YB T 51.3546 0.95 4 XKA2 +170YB T 52.3895 1.67 7 XKA1 170YB T -170YB T 59.15 |] XKB3 -170YB T 59.37 |] 0.55 3 XKB1 -170YB T 59.782 |] XKB5II +170YB T 59.15 |] XKB3 +170YB T 59.37 |] 0.55 3 XKB1 +170YB T 59.782 |] XKB5II 170YB T -170YB T 60.98 |] XKB2 -170YB T 61.141 |] 0.144 7 XKB4 -170YB T 61.309 |] XKO23 +170YB T 60.98 |] XKB2 +170YB T 61.141 |] 0.144 7 XKB4 +170YB T 61.309 |] XKO23 170YB T -170YB T 6.548-10.142 3.22 13 XL (total) -170YB T 6.548 0.0590 29 XLL -170YB T 7.369-7.416 1.42 7 XLA +170YB T 6.548-10.142 3.22 13 XL (total) +170YB T 6.548 0.0590 29 XLL +170YB T 7.369-7.416 1.42 7 XLA 170YB T 7.583 XLC -170YB T 8.026-8.756 1.50 7 XLB -170YB T 9.736-10.142 0.242 12 XLG +170YB T 8.026-8.756 1.50 7 XLB +170YB T 9.736-10.142 0.242 12 XLG 170YB T -170YB T 40.16-43.23 |] KLL AUGER -170YB T 48.36-52.36 |] 0.182 14 ^KLX AUGER -170YB T 56.48-61.29 |] KXY AUGER +170YB T 40.16-43.23 |] KLL AUGER +170YB T 48.36-52.36 |] 0.182 14 KLX AUGER +170YB T 56.48-61.29 |] KXY AUGER 170TM P 0.0 1- 127.8 D 6 968.0 8 170YB N 1.001E0 1.001E0 0.999 1.001E0 170YB L 0 0+ STABLE -170YB B 968.0 8 81.6 7 9.432 1 +170YB B 968.0 8 81.6 7 9.432 1 170YBS B EAV=323.1 3 170YB L 84.25477 8 2+ -170YB B 883.7 8 18.3 7 8.924 1 +170YB B 883.7 8 18.3 7 8.924 1 170YBS B EAV=290.5 3 -170YB G 84.25474 8 2.48 9 E2 6.39 10 -170YB2 G KC=1.39 2$LC=3.81 6$MC=0.94 1 +170YB G 84.25474 8 2.48 9E2 6.39 10 +170YB2 G KC=1.39 2$LC=3.81 6$MC=0.94 1 diff --git a/HEN_HOUSE/spectra/lnhb/U-232.txt b/HEN_HOUSE/spectra/lnhb/U-232.txt index 60ea073a8..43b389ef8 100644 --- a/HEN_HOUSE/spectra/lnhb/U-232.txt +++ b/HEN_HOUSE/spectra/lnhb/U-232.txt @@ -5,78 +5,78 @@ 228TH2C 1964Ch05, 1965Be15, 1966Ah02, 1966Ba49, 1971He23, 1973Ta25, 1977Ku15, 228TH3C 1979Bo30, 1979He10, 1979Ag04, 1982Ma52, 1984Ge07, 1985Ba18, 1987Da28, 228TH4C 1990Bo16, 1995Ba42, 1996Sc06, 2000Bo46, 2000He14, 2003Wa32, 2003Au03 -228TH T Auger electrons and ^X ray energies and emission intensities: -228TH T {U Energy (keV)} {U Intensity } {U Line } +228TH T Auger electrons and X ray energies and emission intensities: +228TH T {U Energy (keV)} {U Intensity} {U Line} 228TH T -228TH T 89.954 0.00524 11 XKA2 -228TH T 93.351 0.00847 16 XKA1 +228TH T 89.954 0.00524 11 XKA2 +228TH T 93.351 0.00847 16 XKA1 228TH T -228TH T 104.819 |] XKB3 -228TH T 105.604 |] 0.00301 7 XKB1 -228TH T 106.239 |] XKB5II +228TH T 104.819 |] XKB3 +228TH T 105.604 |] 0.00301 7 XKB1 +228TH T 106.239 |] XKB5II 228TH T -228TH T 108.509 |] XKB2 -228TH T 108.955 |] 0.001016 29 XKB4 -228TH T 109.442 |] XKO23 +228TH T 108.509 |] XKB2 +228TH T 108.955 |] 0.00101629 XKB4 +228TH T 109.442 |] XKO23 228TH T -228TH T 11.1177-19.5043 11.00 24 XL (total) -228TH T 11.1177 0.223 7 XLL -228TH T 12.8085-12.967 3.71 11 XLA -228TH T 14.509 0.129 5 XLC -228TH T 14.972-16.4253 5.61 16 XLB -228TH T 18.3633-19.5043 1.32 4 XLG +228TH T 11.1177-19.5043 11.00 24 XL (total) +228TH T 11.1177 0.223 7 XLL +228TH T 12.8085-12.967 3.71 11 XLA +228TH T 14.509 0.129 5 XLC +228TH T 14.972-16.4253 5.61 16 XLB +228TH T 18.3633-19.5043 1.32 4 XLG 228TH T -228TH T 68.406-76.745 |] KLL AUGER -228TH T 83.857-93.345 |] 0.00057 8 ^KLX AUGER -228TH T 99.29-109.64 |] KXY AUGER -228TH T 5.8-20.3 11.62 22 L AUGER +228TH T 68.406-76.745 |] KLL AUGER +228TH T 83.857-93.345 |] 0.00057 8 KLX AUGER +228TH T 99.29-109.64 |] KXY AUGER +228TH T 5.8-20.3 11.62 22 L AUGER 232U P 0.0 0+ 70.6 Y 11 5413.63 9 228TH N 1.0 1.0 1 1.0 228TH L 0 0+ 1.9126 Y 9 228TH A 5320.24 9 69.1 6 1 228TH L 57.759 4 2+ 0.405 NS 7 228TH A 5263.48 9 30.6 6 1.04 -228TH G 57.752 130.200 4 E2 153.2 22 -228TH2 G KC=$LC=112.2 16$MC=30.7 5 +228TH G 57.752 130.200 4E2 153.2 22 +228TH2 G KC=$LC=112.2 16$MC=30.7 5 228TH L 186.823 4 4+ 0.164 NS 4 228TH A 5136.64 9 0.325 6 16.4 -228TH G 129.065 3 0.0686 7 E2 3.74 6 -228TH2 G KC=0.264 4$LC=2.54 4$MC=0.697 10 +228TH G 129.065 3 0.0686 7E2 3.74 6 +228TH2 G KC=0.264 4$LC=2.54 4$MC=0.697 10 228TH L 328.003 4 1- 228TH A 4997.90 9 0.00622 9 112 -228TH G 270.245 7 0.00317 7 E1 0.0470 7 -228TH2 G KC=0.0376 6$LC=0.00716 10$MC=1717E-6 24 -228TH G 328.004 7 0.00283 7 E1 0.0305 5 -228TH2 G KC=0.0245 4$LC=0.00455 7$MC=1089E-6 16 +228TH G 270.245 7 0.00317 7E1 0.0470 7 +228TH2 G KC=0.0376 6$LC=0.00716 10$MC=1717E-6 24 +228TH G 328.004 7 0.00283 7E1 0.0305 5 +228TH2 G KC=0.0245 4$LC=0.00455 7$MC=1089E-6 16 228TH L 378.179 106+ 228TH A 4948.59 9 51000E-96 6490 -228TH G 191.351 113.1E-5 3 E2 0.776 11 -228TH2 G KC=0.1710 24$LC=0.443 7$MC=0.1209 17 +228TH G 191.351 110.000031 3E2 0.776 11 +228TH2 G KC=0.1710 24$LC=0.443 7$MC=0.1209 17 228TH L 396.078 103- 228TH A 4931.00 9 48000E-94 5270 -228TH G 209.252 6 1.1E-5 3 E1 0.0848 12 -228TH2 G KC=0.0672 10$LC=0.01333 19$MC=0.00321 5 -228TH G 338.320 5 3.70E-5 18E1 0.0285 4 -228TH2 G KC=0.0229 4$LC=0.00424 6$MC=1014E-6 15 +228TH G 209.252 6 0.000011 3E1 0.0848 12 +228TH2 G KC=0.0672 10$LC=0.01333 19$MC=0.00321 5 +228TH G 338.320 5 3.70E-5 18E1 0.0285 4 +228TH2 G KC=0.0229 4$LC=0.00424 6$MC=1014E-6 15 228TH L 519.192 6 5- 228TH A 4810.01 9 54000E-94 712 -228TH G 140.999 203.1E-6 13E1 0.217 3 -228TH2 G KC=0.1690 24$LC=0.0362 5$MC=0.00876 13 -228TH G 332.371 6 4.9E-5 3 E1 0.0297 5 -228TH2 G KC=0.0238 4$LC=0.00441 7$MC=1056E-6 15 +228TH G 140.999 203.1E-6 13E1 0.217 3 +228TH2 G KC=0.1690 24$LC=0.0362 5$MC=0.00876 13 +228TH G 332.371 6 0.000049 3E1 0.0297 5 +228TH2 G KC=0.0238 4$LC=0.00441 7$MC=1056E-6 15 228TH L 831.823 100+ 228TH A 4502.77 9 21400E-91610.6 -228TH G 503.819 231.45E-5 9 E1 0.0124318 -228TH2 G KC=0.01009 15$LC=1775E-6 25$MC=4.22E-4 6 -228TH G 774.05 9 4.7E-6 8 E2 0.0164923 -228TH2 G KC=0.01204 17$LC=0.00333 5$MC=8.35E-4 12 +228TH G 503.819 231.45E-5 9E1 0.0124318 +228TH2 G KC=0.01009 15$LC=1775E-6 25$MC=4.22E-4 6 +228TH G 774.05 9 4.7E-6 8E2 0.0164923 +228TH2 G KC=0.01204 17$LC=0.00333 5$MC=8.35E-4 12 228TH G 831.823 10 228TH L 874.473 182+ 228TH A 4460.86 9 33000E-19 33 -228TH G 478.41 5 1.4E-6 6 E1 0.0137920 -228TH2 G KC=1118E-5 2$LC=0.00198 3$MC=4.71E-4 7 -228TH G 546.454 211.0E-6 6 E1 0.0105815 -228TH2 G KC=0.00861 12$LC=1500E-6 21$MC=3.57E-4 5 -228TH G 816.62 708E-7 3 M1+E2 1 0.0359 5 -228TH2 G KC=0.0284 4$LC=0.00566 8$MC=1369E-6 20 +228TH G 478.41 5 1.4E-6 6E1 0.0137920 +228TH2 G KC=1118E-5 2$LC=0.00198 3$MC=4.71E-4 7 +228TH G 546.454 211.0E-6 6E1 0.0105815 +228TH2 G KC=0.00861 12$LC=1500E-6 21$MC=3.57E-4 5 +228TH G 817 7 8E-7 3M1+E2 1 0.0359 5 +228TH2 G KC=0.0284 4$LC=0.00566 8$MC=1369E-6 20 diff --git a/HEN_HOUSE/spectra/lnhb/U-234.txt b/HEN_HOUSE/spectra/lnhb/U-234.txt index 2582af11a..002a8ad14 100644 --- a/HEN_HOUSE/spectra/lnhb/U-234.txt +++ b/HEN_HOUSE/spectra/lnhb/U-234.txt @@ -7,60 +7,59 @@ 230TH4C 1972Sc01, 1973Ta25, 1974HeYW, 1980Ge13, 1980Me01, 1981Vo02, 1981HoZI, 230TH5C 1983Ak12, 1984Di08, 1984Va41, 1986LoZT, 1987Bo25, 1987Sh27, 1989Ho24, 230TH6C 1991Ry01, 1993Ak02, 1993Ak05, 1995Jo23, 1996Sc06, 2002Ba85, 2003Au03 -230TH T Auger electrons and ^X ray energies and emission intensities: -230TH T {U Energy (keV)} {U Intensity } {U Line } +230TH T Auger electrons and X ray energies and emission intensities: +230TH T {U Energy (keV)} {U Intensity} {U Line} 230TH T -230TH T 89.954 0.00269 25 XKA2 -230TH T 93.351 0.0044 4 XKA1 +230TH T 89.954 0.00269 25 XKA2 +230TH T 93.351 0.0044 4 XKA1 230TH T -230TH T 104.819 |] XKB3 -230TH T 105.604 |] 0.00155 15 XKB1 -230TH T 106.239 |] XKB5II +230TH T 104.819 |] XKB3 +230TH T 105.604 |] 0.00155 15 XKB1 +230TH T 106.239 |] XKB5II 230TH T -230TH T 108.509 |] XKB2 -230TH T 108.955 |] 0.00052 5 XKB4 -230TH T 109.442 |] XKO23 +230TH T 108.509 |] XKB2 +230TH T 108.955 |] 0.00052 5 XKB4 +230TH T 109.442 |] XKO23 230TH T -230TH T 11.118-19.504 10.2 4 XL (total) -230TH T 11.118 0.209 12 XLL -230TH T 12.8085-12.967 3.48 17 XLA -230TH T 14.509 0.118 7 XLC -230TH T 14.972-16.4253 5.16 26 XLB -230TH T 18.3633-19.504 1.21 6 XLG +230TH T 11.118-19.504 10.2 4 XL (total) +230TH T 11.118 0.209 12 XLL +230TH T 12.8085-12.967 3.48 17 XLA +230TH T 14.509 0.118 7 XLC +230TH T 14.972-16.4253 5.16 26 XLB +230TH T 18.3633-19.504 1.21 6 XLG 230TH T -230TH T 68.406-76.745 |] KLL AUGER -230TH T 83.857-93.345 |] 0.00029 5 ^KLX AUGER -230TH T 99.29-109.64 |] KXY AUGER -230TH T 5.8-20.3 10.8 4 L AUGER +230TH T 68.406-76.745 |] KLL AUGER +230TH T 83.857-93.345 |] 0.00029 5 KLX AUGER +230TH T 99.29-109.64 |] KXY AUGER +230TH T 5.8-20.3 10.8 4 L AUGER 234U P 0.0 0+ 2.455E5 Y 6 4857.7 7 230TH N 1.0 1.0 1 1.0 230TH L 0 0+ 75.38E3 Y 30 230TH A 4774.6 7 71.37 2 1 230TH L 53.20 2 2+ 0.354 NS 9 230TH A 4722.4 7 28.42 2 1.1 -230TH G 53.20 2 0.1253 40E2+M3 228 7 -230TH2 G KC=$LC=167 5$MC=45.6 14 +230TH G 53.20 2 0.1253 40E2+M3 228 7 +230TH2 G LC=167 5$MC=45.6 14 230TH L 174.10 4 4+ 0.166 NS 5 230TH A 4603.5 7 0.210 2 21 -230TH G 120.90 4 0.0386 32E2 4.92 15 -230TH2 G KC=0.244 7$LC=3.42 10$MC=0.940 28 +230TH G 120.900 400.0386 32E2 4.92 15 +230TH2 G KC=0.244 7$LC=3.42 10$MC=0.940 28 230TH L 508.16 4 1- 230TH A 4275.2 7 0.00004 1 288 -230TH G 454.96 5 2.5E-5 6 E1 0.0152646 -230TH2 G KC=0.01235 37$LC=0.00220 7$MC=5.25E-4 16 +230TH G 454.96 5 0.000025 6E1 0.0152646 +230TH2 G KC=0.01235 37$LC=0.00220 7$MC=5.25E-4 16 230TH G 508.16 5 1.50E-5 39E1 0.0122137 -230TH2 G KC=0.00991 30$LC=0.00174 5$MC=4.15E-4 12 +230TH2 G KC=0.00991 30$LC=0.00174 5$MC=4.15E-4 12 230TH L 634.90 7 0+ 230TH A 4150.6 7 26000E-9 39 -230TH G 581.7 1 1.2E-5 5 E2 0.0300 9 -230TH2 G KC=0.0202 6$LC=0.00734 22$MC=0.00188 6 +230TH G 581.7 1 0.000012 5E2 0.0300 9 +230TH2 G KC=0.0202 6$LC=0.00734 22$MC=0.00188 6 230TH G 634.9 1 230TH L 677.60 6 2+ 230TH A 4108.6 7 70000E-1 63 -230TH G 503.5 1 950E-9 0 [E2] 0.0418 13 -230TH2 G KC=0.0264 8$LC=0.01141 34$MC=0.00296 9 -230TH G 624.4 1 820E-9 0 +E2+M1 5.1 20 -230TH2 G KC=$LC=$MC= -230TH G 677.6 1 1000E-9 0 [E2] 0.0216 6 +230TH G 503.5 1 9.5E-7 [E2] 0.0418 13 +230TH2 G KC=0.0264 8$LC=0.01141 34$MC=0.00296 9 +230TH G 624.4 1 8.2E-7 +E2+M1 5.1 20 +230TH G 677.6 1 0.000001 [E2] 0.0216 6 230TH2 G KC=0.01526 46$LC=0.00475 14$MC=1204E-6 36 diff --git a/HEN_HOUSE/spectra/lnhb/U-235.txt b/HEN_HOUSE/spectra/lnhb/U-235.txt index 86eabf8f4..775c322db 100644 --- a/HEN_HOUSE/spectra/lnhb/U-235.txt +++ b/HEN_HOUSE/spectra/lnhb/U-235.txt @@ -6,184 +6,184 @@ 231TH2C Type=update;Author=M.M. Bé;Cutoff date= -- 231TH3C Type=Full;Author=X. Huang;Cutoff date=30-JUN-2008 231TH C References: 2008Ki07 -231TH T Auger electrons and ^X ray energies and emission intensities: -231TH T {U Energy (keV)} {U Intensity } {U Line } +231TH T Auger electrons and X ray energies and emission intensities: +231TH T {U Energy (keV)} {U Intensity} {U Line} 231TH T -231TH T 89.954 3.56 7 XKA2 -231TH T 93.351 5.75 11 XKA1 +231TH T 89.954 3.56 7 XKA2 +231TH T 93.351 5.75 11 XKA1 231TH T -231TH T 104.819 |] XKB3 -231TH T 105.604 |] 2.05 5 XKB1 -231TH T 106.239 |] XKB5II +231TH T 104.819 |] XKB3 +231TH T 105.604 |] 2.05 5 XKB1 +231TH T 106.239 |] XKB5II 231TH T -231TH T 108.509 |] XKB2 -231TH T 108.955 |] 0.690 19 XKB4 -231TH T 109.442 |] XKO23 +231TH T 108.509 |] XKB2 +231TH T 108.955 |] 0.690 19 XKB4 +231TH T 109.442 |] XKO23 231TH T -231TH T 11.1177-19.5043 40 22 XL (total) -231TH T 11.1177 1.2 10 XLL -231TH T 12.8085-12.967 21 15 XLA -231TH T 14.509 0.243 24 XLC -231TH T 14.972-17.1383 15 4 XLB -231TH T 18.3633-19.5043 2.70 21 XLG +231TH T 11.1177-19.5043 40 22 XL (total) +231TH T 11.1177 1.2 10 XLL +231TH T 12.8085-12.967 21 15 XLA +231TH T 14.509 0.243 24 XLC +231TH T 14.972-17.1383 15 4 XLB +231TH T 18.3633-19.5043 2.70 21 XLG 231TH T -231TH T 68.406-76.745 |] KLL AUGER -231TH T 83.857-93.345 |] 0.39 5 ^KLX AUGER -231TH T 99.29-109.64 |] KXY AUGER -231TH T 5.8-20.3 47 22 L AUGER +231TH T 68.406-76.745 |] KLL AUGER +231TH T 83.857-93.345 |] 0.39 5 KLX AUGER +231TH T 99.29-109.64 |] KXY AUGER +231TH T 5.8-20.3 47 22 L AUGER 235U P 0.0 Null+ 704E6 Y 1 4678.3 7 231TH N 1.0 1.0 1 1.0 231TH L 0 5/2+ 25.52 H 1 231TH A 4596.4 134.74 6 2571 231TH L 41.954 4 7/2+ 231TH A 4556.0 4 3.79 6 1586 -231TH G 42.01 6 0.056 9 M1+E2 1.2 1 440 30 -231TH2 G KC=$LC=325 22$MC=88 6 +231TH G 42.01 6 0.056 9M1+E2 1.2 1 440 30 +231TH2 G LC=325 22$MC=88 6 231TH L 96.170 129/2+ 231TH A 4502.4 7 1.28 5 1856 -231TH G 54.25 5 2850E-5 0 [M1+E2] 0.60 2 71 3 -231TH2 G KC=$LC=52.7 20$MC=14.0 6 +231TH G 54.25 5 0.0285 [M1+E2] 0.60 2 71 3 +231TH2 G LC=52.7 20$MC=14.0 6 231TH G 96.09 2 0.091 11[E2] 13.58 19 -231TH2 G KC=$LC=9.93 14$MC=2.73 4 +231TH2 G LC=9.93 14$MC=2.73 4 231TH L 162.06 3 11/2+ 231TH A 4437.9 400.236 253170 -231TH G 120.35 5 2600E-5 0 [M1] 10.95 16 -231TH2 G KC=8.73 13$LC=1.678 24$MC=0.404 6 +231TH G 120.35 5 0.026 [M1] 10.95 16 +231TH2 G KC=8.73 13$LC=1.678 24$MC=0.404 6 231TH L 185.721 4 5/2- 0.77 NS 12 231TH A 4414.9 5 3.01 16164 -231TH G 143.767 3 10.94 6 E1 0.207 3 -231TH2 G KC=0.1615 23$LC=0.0344 5$MC=0.00833 12 -231TH G 185.720 4 57.0 3 E1 0.1124 16 -231TH2 G KC=0.0887 13$LC=0.0179 3$MC=0.00433 6 +231TH G 143.767 3 10.94 6E1 0.207 3 +231TH2 G KC=0.1615 23$LC=0.0344 5$MC=0.00833 12 +231TH G 185.720 4 57.0 3E1 0.1124 16 +231TH2 G KC=0.0887 13$LC=0.0179 3$MC=0.00433 6 231TH L 205.313 4 7/2- 231TH A 4397.8 1357.19 206.08 -231TH G 19.592 6 0.006 6 [M1+E2] 1E4 1 -231TH2 G KC=$LC=6E3 6$MC=3E3 3 +231TH G 19.592 6 0.006 6[M1+E2] 1E4 1 +231TH2 G LC=6E3 6$MC=3E3 3 231TH G 109.19 7 1.66 13[E1] 0.0932 14 -231TH2 G KC=$LC=0.0704 10$MC=0.01708 24 -231TH G 163.356 3 5.08 3 (E1) 0.1526 22 -231TH2 G KC=0.1197 17$LC=0.0248 4$MC=0.00599 9 -231TH G 205.316 4 5.02 3 (E1) 0.0887 13 -231TH2 G KC=0.0703 10$LC=0.01397 20$MC=0.00336 5 +231TH2 G LC=0.0704 10$MC=0.01708 24 +231TH G 163.356 3 5.08 3(E1) 0.1526 22 +231TH2 G KC=0.1197 17$LC=0.0248 4$MC=0.00599 9 +231TH G 205.316 4 5.02 3(E1) 0.0887 13 +231TH2 G KC=0.0703 10$LC=0.01397 20$MC=0.00336 5 231TH L 221.386 143/2+ 231TH A 4381.1 7 0.106 162460 -231TH G 221.386 140.118 5 M1 1.96 3 -231TH2 G KC=1.566 22$LC=0.296 5$MC=0.0712 10 +231TH G 221.386 140.118 5M1 1.96 3 +231TH2 G KC=1.566 22$LC=0.296 5$MC=0.0712 10 231TH L 236.902 7 9/2- 231TH A 4366.1 2018.80 1310.47 -231TH G 31.60 5 0.017 6 M1+E2 0.5 666 11 -231TH2 G KC=$LC=490 8$MC=131.5 21 -231TH G 51.21 4 0.034 7 [E2] 274 4 -231TH2 G KC=$LC=201 3$MC=54.9 8 -231TH G 74.94 3 0.051 6 [E1] 0.252 4 -231TH2 G KC=$LC=0.190 3$MC=0.0464 7 -231TH G 140.76 2 0.20 1 [E1] 0.218 3 -231TH2 G KC=0.1696 24$LC=0.0364 5$MC=0.00879 13 -231TH G 194.940 6 0.63 1 [E1] 0.1002 14 -231TH2 G KC=0.0792 11$LC=0.01589 23$MC=0.00383 6 +231TH G 31.60 5 0.017 6M1+E2 0.5 666 11 +231TH2 G LC=490 8$MC=131.5 21 +231TH G 51.21 4 0.034 7[E2] 274 4 +231TH2 G LC=201 3$MC=54.9 8 +231TH G 74.94 3 0.051 6[E1] 0.252 4 +231TH2 G LC=0.190 3$MC=0.0464 7 +231TH G 140.76 2 0.20 1[E1] 0.218 3 +231TH2 G KC=0.1696 24$LC=0.0364 5$MC=0.00879 13 +231TH G 194.940 6 0.63 1[E1] 0.1002 14 +231TH2 G KC=0.0792 11$LC=0.01589 23$MC=0.00383 6 231TH L 240.858 145/2+ 231TH A 4361.9 7 0.206 21890 -231TH G 198.894 140.036 2 M1 2.64 4 -231TH2 G KC=2.11 3$LC=0.401 6$MC=0.0963 14 -231TH G 240.88 4 0.074 4 M1(+E2) 0.3 3 1.45 22 +231TH G 198.894 140.036 2M1 2.64 4 +231TH2 G KC=2.11 3$LC=0.401 6$MC=0.0963 14 +231TH G 240.88 4 0.074 4M1(+E2) 0.3 3 1.45 22 231TH2 G KC=1.14 21$LC=0.228 13$MC=0.0553 21 231TH L 275.459 197/2+ 231TH A 4327.9 7 0.405 13241 -231TH G 54.1 1 1150E-6 0 [E2] 210 4 -231TH2 G KC=$LC=154 3$MC=42.1 7 -231TH G 233.50 2 0.038 4 M1 1.687 24 -231TH2 G KC=1.350 19$LC=0.255 4$MC=0.0613 9 -231TH G 275.49 6 3200E-5 0 M1(+E2) 0.25 25 1.02 12 -231TH2 G KC=0.81 11$LC=0.157 9$MC=0.0379 18 +231TH G 54.1 1 0.00115 [E2] 210 4 +231TH2 G LC=154 3$MC=42.1 7 +231TH G 233.500 200.038 4M1 1.687 24 +231TH2 G KC=1.350 19$LC=0.255 4$MC=0.0613 9 +231TH G 275.49 6 0.032 M1(+E2) 0.25 25 1.02 12 +231TH2 G KC=0.81 11$LC=0.157 9$MC=0.0379 18 231TH L 277.56 6 (11/2)- 231TH A 4322 4 3.33 6 28.1 231TH G 41.4 3 0.029 11[M1] 49.9 13 -231TH2 G KC=$LC=37.7 10$MC=9.08 24 -231TH G 72.7 2 0.116 20M1+E2 0.4 1 15 3 -231TH2 G KC=$LC=11.4 19$MC=2.9 6 -231TH G 115.45 5 0.03 1 [E1] 0.348 5 -231TH2 G KC=0.267 4$LC=0.0609 9$MC=0.01475 21 +231TH2 G LC=37.7 10$MC=9.08 24 +231TH G 72.7 2 0.116 20M1+E2 0.4 1 15 3 +231TH2 G LC=11.4 19$MC=2.9 6 +231TH G 115.45 5 0.03 1[E1] 0.348 5 +231TH2 G KC=0.267 4$LC=0.0609 9$MC=0.01475 21 231TH G 182.1 231TH L 301.7 1 (5/2)+ 231TH A 4302.1 7 0.00959 136260 -231TH G 301.7 1 5300E-6 0 M1 0.829 12 -231TH2 G KC=0.664 10$LC=0.1249 18$MC=0.0300 5 +231TH G 301.7 1 0.0053 M1 0.829 12 +231TH2 G KC=0.664 10$LC=0.1249 18$MC=0.0300 5 231TH L 317.15 7 5/2+ 231TH A 4286.9 7 0.065 13690 231TH G 95.7 -231TH G 275.35 150.051 6 M1+E2 0.6 1 0.84 6 -231TH2 G KC=0.65 5$LC=0.144 5$MC=0.0355 10 -231TH G 317.10 8 1100E-6 0 M1 0.723 11 -231TH2 G KC=0.579 9$LC=0.1088 16$MC=0.0261 4 +231TH G 275.35 150.051 6M1+E2 0.6 1 0.84 6 +231TH2 G KC=0.65 5$LC=0.144 5$MC=0.0355 10 +231TH G 317.10 8 0.0011 M1 0.723 11 +231TH2 G KC=0.579 9$LC=0.1088 16$MC=0.0261 4 231TH L 324.91 4 (9/2)+ 231TH A 4279.3 7 0.0329 5 1185 -231TH G 228.76 5 7400E-6 0 M1 1.79 3 -231TH2 G KC=1.429 20$LC=0.270 4$MC=0.0649 9 -231TH G 282.94 5 6300E-6 0 [M1] 0.990 14 -231TH2 G KC=0.792 12$LC=0.1493 21$MC=0.0359 5 +231TH G 228.76 5 0.0074 M1 1.79 3 +231TH2 G KC=1.429 20$LC=0.270 4$MC=0.0649 9 +231TH G 282.94 5 0.0063 [M1] 0.990 14 +231TH2 G KC=0.792 12$LC=0.1493 21$MC=0.0359 5 231TH L 334 4 (13/2)- 231TH A 4266 5 0.22 3 150 -231TH G 97 4 0.016 4 [E2] 13 3 -231TH2 G KC=$LC=9.5 21$MC=2.6 6 +231TH G 97 4 0.016 4[E2] 13 3 +231TH2 G LC=9.5 21$MC=2.6 6 231TH L 351.565 167/2+ 231TH A 4248 5 0.069 10343 -231TH G 255.365 107400E-6 0 M1 1.315 19 -231TH2 G KC=1.052 15$LC=0.199 3$MC=0.0477 7 -231TH G 310.69 6 9400E-6 0 (E2) 0.1517 22 -231TH2 G KC=0.068 1$LC=0.0616 9$MC=0.01650 24 -231TH G 350 5 6000E-6 0 M1 0.552 24 -231TH2 G KC=0.442 19$LC=0.083 4$MC=0.0199 9 +231TH G 255.365 100.0074 M1 1.315 19 +231TH2 G KC=1.052 15$LC=0.199 3$MC=0.0477 7 +231TH G 310.69 6 0.0094 (E2) 0.1517 22 +231TH2 G KC=0.068 1$LC=0.0616 9$MC=0.01650 24 +231TH G 350 5 0.006 M1 0.552 24 +231TH2 G KC=0.442 19$LC=0.083 4$MC=0.0199 9 231TH L 377.50 4 (7/2)+ 231TH A 4227.6 7 0.122 6 119 -231TH G 136.55 5 1200E-5 0 [M1] 7.66 11 -231TH2 G KC=6.11 9$LC=1.168 17$MC=0.281 4 -231TH G 173 1 0.006 5 [E1] 0.133 3 -231TH2 G KC=0.1047 21$LC=0.0215 5$MC=0.00518 11 -231TH G 281.42 5 6300E-6 0 M1 1.005 14 -231TH2 G KC=0.804 12$LC=0.1515 22$MC=0.0364 5 +231TH G 136.55 5 0.012 [M1] 7.66 11 +231TH2 G KC=6.11 9$LC=1.168 17$MC=0.281 4 +231TH G 173 1 0.006 5[E1] 0.133 3 +231TH2 G KC=0.1047 21$LC=0.0215 5$MC=0.00518 11 +231TH G 281.42 5 0.0063 M1 1.005 14 +231TH2 G KC=0.804 12$LC=0.1515 22$MC=0.0364 5 231TH L 385.72 4 (11/2)+ 231TH A 4219.5 7 0.01732 12714 -231TH G 289.56 4 7400E-6 0 [M1] 0.929 13 -231TH2 G KC=0.743 11$LC=0.140 2$MC=0.0336 5 -231TH G 343.5 2 3200E-6 0 +231TH G 289.56 4 0.0074 [M1] 0.929 13 +231TH2 G KC=0.743 11$LC=0.140 2$MC=0.0336 5 +231TH G 343.5 2 0.0032 231TH L 387.841 8 7/2- 231TH A 4214.7 195.95 122 231TH G 147 -231TH G 150.936 150.09 3 [M1] 5.76 8 -231TH2 G KC=4.60 7$LC=0.877 13$MC=0.211 3 -231TH G 182.62 5 0.39 5 [M1] 3.36 5 -231TH2 G KC=2.69 4$LC=0.510 8$MC=0.1226 18 -231TH G 202.12 1 1.08 2 [M1] 2.53 4 -231TH2 G KC=2.02 3$LC=0.383 6$MC=0.0920 13 -231TH G 291.65 3 0.040 6 [E1] 0.0396 6 -231TH2 G KC=0.0317 5$LC=0.00598 9$MC=1433E-6 20 -231TH G 345.92 3 0.040 6 [E1] 0.0272 4 -231TH2 G KC=0.0219 3$LC=0.00403 6$MC=9.64E-4 14 -231TH G 387.84 3 0.040 6 [E1] 0.0213 3 -231TH2 G KC=0.01717 24$LC=0.00312 5$MC=7.45E-4 11 +231TH G 150.936 150.09 3[M1] 5.76 8 +231TH2 G KC=4.60 7$LC=0.877 13$MC=0.211 3 +231TH G 182.62 5 0.39 5[M1] 3.36 5 +231TH2 G KC=2.69 4$LC=0.510 8$MC=0.1226 18 +231TH G 202.12 1 1.08 2[M1] 2.53 4 +231TH2 G KC=2.02 3$LC=0.383 6$MC=0.0920 13 +231TH G 291.65 3 0.040 6[E1] 0.0396 6 +231TH2 G KC=0.0317 5$LC=0.00598 9$MC=1433E-6 20 +231TH G 345.92 3 0.040 6[E1] 0.0272 4 +231TH2 G KC=0.0219 3$LC=0.00403 6$MC=9.64E-4 14 +231TH G 387.84 3 0.040 6[E1] 0.0213 3 +231TH2 G KC=0.01717 24$LC=0.00312 5$MC=7.45E-4 11 231TH L 452.182 159/2- 231TH A 4152 5 0.294 1311.6 -231TH G 64.45 5 1800E-5 0 [M1] 13.6 2 -231TH2 G KC=$LC=10.28 15$MC=2.47 4 -231TH G 215.28 4 0.029 3 [M1] 2.12 3 -231TH2 G KC=1.693 24$LC=0.321 5$MC=0.0770 11 -231TH G 246.83 2 0.055 3 [M1] 1.445 21 -231TH2 G KC=1.157 17$LC=0.218 3$MC=0.0525 8 -231TH G 266.47 4 0.0078 6 [E2] 0.245 4 -231TH2 G KC=0.0921 13$LC=0.1121 16$MC=0.0303 5 +231TH G 64.45 5 0.018 [M1] 13.6 2 +231TH2 G LC=10.28 15$MC=2.47 4 +231TH G 215.28 4 0.029 3[M1] 2.12 3 +231TH2 G KC=1.693 24$LC=0.321 5$MC=0.0770 11 +231TH G 246.830 200.055 3[M1] 1.445 21 +231TH2 G KC=1.157 17$LC=0.218 3$MC=0.0525 8 +231TH G 266.47 4 0.0078 6[E2] 0.245 4 +231TH2 G KC=0.0921 13$LC=0.1121 16$MC=0.0303 5 231TH G 291.2 -231TH G 356.03 5 5300E-6 0 [E1] 0.0255 4 -231TH2 G KC=0.0206 3$LC=0.00377 6$MC=9.03E-4 13 -231TH G 410.29 4 3200E-6 0 [E1] 0.0189 3 -231TH2 G KC=0.01527 22$LC=0.00275 4$MC=6.57E-4 10 +231TH G 356.03 5 0.0053 [E1] 0.0255 4 +231TH2 G KC=0.0206 3$LC=0.00377 6$MC=9.03E-4 13 +231TH G 410.29 4 0.0032 [E1] 0.0189 3 +231TH2 G KC=0.01527 22$LC=0.00275 4$MC=6.57E-4 10 231TH L 530.24 5 (11/2)- 231TH A 4077.5 7 0.016 1246 -231TH G 142.40 5 5100E-6 0 [E2] 2.48 4 -231TH2 G KC=0.253 4$LC=1.627 23$MC=0.446 7 +231TH G 142.40 5 0.0051 [E2] 2.48 4 +231TH2 G KC=0.253 4$LC=1.627 23$MC=0.446 7 231TH L 595.58 205/2- 231TH A 4013.2 8 0.0396 104.86 -231TH G 390.27 200.040 1 +231TH G 390.27 200.040 1 231TH L 634.12 6 7/2- 231TH A 3976 5 0.0011 79 -231TH G 448.40 6 1100E-6 0 +231TH G 448.40 6 0.0011 diff --git a/HEN_HOUSE/spectra/lnhb/U-236.txt b/HEN_HOUSE/spectra/lnhb/U-236.txt index a5b8e0a44..b9d28d35a 100644 --- a/HEN_HOUSE/spectra/lnhb/U-236.txt +++ b/HEN_HOUSE/spectra/lnhb/U-236.txt @@ -4,31 +4,31 @@ 232TH C References: 1951JA09, 1952FL20, 1960KO04, 1971CO35, 1972FL03, 1972Sc01, 232TH2C 1981VO02, 1983BE66, 1988WoZO, 1989Ho24, 1992IT01, 1994Tr12, 2002GE02, 232TH3C 2003AU03, 2006BR19 -232TH T Auger electrons and ^X ray energies and emission intensities: -232TH T {U Energy (keV)} {U Intensity } {U Line } +232TH T Auger electrons and X ray energies and emission intensities: +232TH T {U Energy (keV)} {U Intensity} {U Line} 232TH T -232TH T 89.954 0.00128 22 XKA2 -232TH T 93.351 0.0021 4 XKA1 +232TH T 89.954 0.00128 22 XKA2 +232TH T 93.351 0.0021 4 XKA1 232TH T -232TH T 104.819 |] XKB3 -232TH T 105.604 |] 0.00074 13 XKB1 -232TH T 106.239 |] XKB5II +232TH T 104.819 |] XKB3 +232TH T 105.604 |] 0.00074 13 XKB1 +232TH T 106.239 |] XKB5II 232TH T -232TH T 108.509 |] XKB2 -232TH T 108.955 |] 0.00025 5 XKB4 -232TH T 109.442 |] XKO23 +232TH T 108.509 |] XKB2 +232TH T 108.955 |] 0.00025 5 XKB4 +232TH T 109.442 |] XKO23 232TH T -232TH T 11.118-19.599 9.4 10 XL (total) -232TH T 11.118 0.194 26 XLL -232TH T 12.809-12.968 3.2 4 XLA -232TH T 14.511 0.108 17 XLC -232TH T 14.97-16.426 4.7 6 XLB -232TH T 18.98-19.599 1.11 14 XLG +232TH T 11.118-19.599 9.4 10 XL (total) +232TH T 11.118 0.194 26 XLL +232TH T 12.809-12.968 3.2 4 XLA +232TH T 14.511 0.108 17 XLC +232TH T 14.97-16.426 4.7 6 XLB +232TH T 18.98-19.599 1.11 14 XLG 232TH T -232TH T 68.406-76.745 |] KLL AUGER -232TH T 83.857-93.345 |] 0.000139 30 ^KLX AUGER -232TH T 99.29-109.64 |] KXY AUGER -232TH T 5.8-20.3 10.1 12 L AUGER +232TH T 68.406-76.745 |] KLL AUGER +232TH T 83.857-93.345 |] 0.00013930 KLX AUGER +232TH T 99.29-109.64 |] KXY AUGER +232TH T 5.8-20.3 10.1 12 L AUGER 236U P 0.0 0+ 23.43E6 Y 6 4573.1 9 232TH N 1.0 1.0 1 1.0 232TH L 0 0+ 14.02E9 Y 6 @@ -36,13 +36,13 @@ 232TH L 49.46 102+ 345 PS 15 232TH A 4445 5 26.1 401.2 232TH G 49.46 100.081 12E2 324 10 -232TH2 G KC=$LC=237 7$MC=65.0 19 +232TH2 G LC=237 7$MC=65.0 19 232TH L 162.25 154+ 164 PS 13 232TH A 4332 8 0.149 2227.3 232TH G 112.79 100.0195 31E2 6.67 20 -232TH2 G KC=0.229 7$LC=4.71 14$MC=1.295 39 +232TH2 G KC=0.229 7$LC=4.71 14$MC=1.295 39 232TH L 333.40 256+ 62 PS 4 232TH A 4168 0.00014 5 1160 -232TH G 171.15 206.5E-5 22E2 1.186 36 -232TH2 G KC=0.204 6$LC=0.719 22$MC=0.197 6 +232TH G 171.15 200.00006522E2 1.186 36 +232TH2 G KC=0.204 6$LC=0.719 22$MC=0.197 6 diff --git a/HEN_HOUSE/spectra/lnhb/U-237.txt b/HEN_HOUSE/spectra/lnhb/U-237.txt index 126017c95..153adc869 100644 --- a/HEN_HOUSE/spectra/lnhb/U-237.txt +++ b/HEN_HOUSE/spectra/lnhb/U-237.txt @@ -20,103 +20,103 @@ 237NP3C 1971Cl03, 1970Gr36, 1976GuZN, 1982BuZF, 1984BAYS, 1985He02, 1985Wi04, 237NP4C 1986LoZT, 1996Jo28, 1996Sc06, 1996Ya05, 1998Ko61, 2000He14, 2003Au03, 237NP5C 2006Ba41, 2008Ki07 -237NP T Auger electrons and ^X ray energies and emission intensities: -237NP T {U Energy (keV)} {U Intensity } {U Line } +237NP T Auger electrons and X ray energies and emission intensities: +237NP T {U Energy (keV)} {U Intensity} {U Line} 237NP T -237NP T 97.069 14.8 4 XKA2 -237NP T 101.059 23.5 6 XKA1 +237NP T 97.069 14.8 4 XKA2 +237NP T 101.059 23.5 6 XKA1 237NP T -237NP T 113.303 |] XKB3 -237NP T 114.234 |] 8.57 27 XKB1 -237NP T 114.912 |] XKB5II +237NP T 113.303 |] XKB3 +237NP T 114.234 |] 8.57 27 XKB1 +237NP T 114.912 |] XKB5II 237NP T -237NP T 117.476 |] XKB2 -237NP T 117.876 |] 2.95 10 XKB4 -237NP T 118.429 |] XKO23 +237NP T 117.476 |] XKB2 +237NP T 117.876 |] 2.95 10 XKB4 +237NP T 118.429 |] XKO23 237NP T -237NP T 11.89-22.2 59.0 21 XL (total) -237NP T 11.89 1.56 8 XLL -237NP T 13.76-13.94 24.7 11 XLA -237NP T 15.88 0.433 29 XLC -237NP T 16.13-17.99 26.2 11 XLB -237NP T 20.12-22.2 5.99 25 XLG +237NP T 11.89-22.2 59.0 21 XL (total) +237NP T 11.89 1.56 8 XLL +237NP T 13.76-13.94 24.7 11 XLA +237NP T 15.88 0.433 29 XLC +237NP T 16.13-17.99 26.2 11 XLB +237NP T 20.12-22.2 5.99 25 XLG 237NP T -237NP T 73.5-83.13 |] KLL AUGER -237NP T 90.36-97.28 |] 1.49 21 ^KLX AUGER -237NP T 107.1-114.58 |] KXY AUGER -237NP T 5.04-13.52 58.5 21 L AUGER +237NP T 73.5-83.13 |] KLL AUGER +237NP T 90.36-97.28 |] 1.49 21 KLX AUGER +237NP T 107.1-114.58 |] KXY AUGER +237NP T 5.04-13.52 58.5 21 L AUGER 237U P 0.0 1/2+ 6.749 D 16 518.6 6 237NP N 1.0 1.0 1 1.0 237NP G 114.09 5 -237NP G 340.45 0.0016 3 +237NP G 340.45 0.0016 3 237NP L 0 5/2+ 2.144E6 Y 7 237NP L 33.19629 227/2+ 54 PS -237NP G 33.19629 220.130 5 M1+E2 0.13 3 175 24 -237NP2 G KC=$LC=131 17$MC=33 5 +237NP G 33.19629 220.130 5M1+E2 0.13 3 175 24 +237NP2 G LC=131 17$MC=33 5 237NP L 59.54092 105/2- 67 NS 5 -237NP B 459.1 6 7 4 8.1 3U +237NP B 459.1 6 7 4 8.1 1U 237NPS B EAV=137.6 2 -237NP G 26.34463 242.43 6 E1 8 2 -237NP2 G KC=$LC=6 2$MC=1.6 2 -237NP G 59.54091 1034.1 9 E1 1.16 7 -237NP2 G KC=$LC=0.84 6$MC=0.226 7 +237NP G 26.34463 242.43 6E1 8 2 +237NP2 G LC=6 2$MC=1.6 2 +237NP G 59.54091 1034.1 9E1 1.16 7 +237NP2 G LC=0.84 6$MC=0.226 7 237NP L 75.899 5 9/2+ 56 PS -237NP G 42.704 5 8500E-6 0 M1+E2 0.13 4 75 9 -237NP2 G KC=$LC=56 7$MC=13.9 19 -237NP G 75.899 5 9100E-7 0 (E2) 53.4 11 -237NP2 G KC=$LC=38.9 8$MC=10.8 2 +237NP G 42.704 5 0.0085 M1+E2 0.13 4 75 9 +237NP2 G LC=56 7$MC=13.9 19 +237NP G 75.899 5 0.00091 (E2) 53.4 11 +237NP2 G LC=38.9 8$MC=10.8 2 237NP L 102.959 3 7/2- 80 PS 237NP G 27.020 7 -237NP G 43.420 3 0.024 2 M1+E2 0.45 5 180 23 -237NP2 G KC=$LC=132 17$MC=35 5 -237NP G 69.76 3 0.00095 19(E1) 0.330 7 -237NP2 G KC=$LC=0.248 5$MC=0.0612 12 -237NP G 102.959 3 0.0064 9 E1 0.119 3 -237NP2 G KC=$LC=0.0894 18$MC=0.0219 4 +237NP G 43.420 3 0.024 2M1+E2 0.45 5 180 23 +237NP2 G LC=132 17$MC=35 5 +237NP G 69.76 3 0.00095 19(E1) 0.330 7 +237NP2 G LC=0.248 5$MC=0.0612 12 +237NP G 102.959 3 0.0064 9E1 0.119 3 +237NP2 G LC=0.0894 18$MC=0.0219 4 237NP L 267.556 123/2- 5.2 NS -237NP B 251.1 6 40.9 31 6.54 1U +237NP B 251.1 6 40.9 31 6.54 1 237NPS B EAV=68.6 2 -237NP G 164.61 2 1.86 3 E2 1.70 4 -237NP2 G KC=0.195 4$LC=1.095 20$MC=0.304 6 -237NP G 208.00 1 21.3 3 M1+E2 0.156 5 2.98 7 -237NP2 G KC=2.35 5$LC=0.473 10$MC=0.115 3 -237NP G 234.40 4 0.0205 8 M2 8.24 16 -237NP2 G KC=5.560 12$LC=1.95 4$MC=0.511 10 -237NP G 267.556 120.721 10E1+M2 0.490 15 1.06 6 -237NP2 G KC=0.74 4$LC=0.238 12$MC=0.062 3 +237NP G 164.61 2 1.86 3E2 1.70 4 +237NP2 G KC=0.195 4$LC=1.095 20$MC=0.304 6 +237NP G 208.00 1 21.3 3M1+E2 0.156 5 2.98 7 +237NP2 G KC=2.35 5$LC=0.473 10$MC=0.115 3 +237NP G 234.40 4 0.0205 8M2 8.24 16 +237NP2 G KC=5.560 12$LC=1.95 4$MC=0.511 10 +237NP G 267.556 120.721 10E1+M2 0.490 15 1.06 6 +237NP2 G KC=0.74 4$LC=0.238 12$MC=0.062 3 237NP L 281.356 181/2- 237NP B 237.2 6 48.2 25 6.39 237NPS B EAV=64.5 2 -237NP G 13.81 2 0.099 4 M1+E2 0.0321 10 492 16 -237NP2 G KC=$LC=$MC=364 13 -237NP G 221.80 4 0.0204 8 E2 0.547 11 -237NP2 G KC=0.130 3$LC=0.304 6$MC=0.0839 17 +237NP G 13.81 2 0.099 4M1+E2 0.0321 10 492 16 +237NP2 G MC=364 13 +237NP G 221.80 4 0.0204 8E2 0.547 11 +237NP2 G KC=0.130 3$LC=0.304 6$MC=0.0839 17 237NP L 332.376 161/2+ 1 NS -237NP B 186.2 6 2.9 9 7.28 +237NP B 186.2 6 2.9 9 7.28 237NPS B EAV=49.8 2 237NP G 51.01 3 0.340 14E1 0.753 15 -237NP2 G KC=$LC=0.565 12$MC=0.140 3 -237NP G 64.83 2 1.286 17E1 0.400 8 -237NP2 G KC=$LC=0.301 6$MC=0.0744 15 -237NP G 332.376 161.199 16E2 0.146 3 -237NP2 G KC=0.0631 12$LC=0.0611 12$MC=0.0164 4 +237NP2 G LC=0.565 12$MC=0.140 3 +237NP G 64.83 2 1.286 17E1 0.400 8 +237NP2 G LC=0.301 6$MC=0.0744 15 +237NP G 332.376 161.199 16E2 0.146 3 +237NP2 G KC=0.0631 12$LC=0.0611 12$MC=0.0164 4 237NP L 368.602 205/2+ -237NP G 292.77 6 0.0025 7 (E2) 0.215 4 -237NP2 G KC=0.0796 16$LC=0.0991 19$MC=0.0270 6 -237NP G 309.1 3 2700E-7 0 (E1) 0.0377 8 -237NP2 G KC=0.0300 6$LC=0.00585 12$MC=0.00143 3 -237NP G 335.38 4 0.0958 22M1+E2 0.46 17 0.69 8 -237NP2 G KC=0.54 7$LC=0.113 8$MC=0.0278 17 +237NP G 292.77 6 0.0025 7(E2) 0.215 4 +237NP2 G KC=0.0796 16$LC=0.0991 19$MC=0.0270 6 +237NP G 309.1 3 0.00027 (E1) 0.0377 8 +237NP2 G KC=0.0300 6$LC=0.00585 12$MC=0.00143 3 +237NP G 335.38 4 0.0958 22M1+E2 0.46 17 0.69 8 +237NP2 G KC=0.54 7$LC=0.113 8$MC=0.0278 17 237NP G 368.602 200.0416 17M1(+E2) 0.31 0.622 13 -237NP2 G KC=0.494 10$LC=0.0963 20$MC=0.0233 5 +237NP2 G KC=0.494 10$LC=0.0963 20$MC=0.0233 5 237NP L 370.928 233/2+ -237NP B 147.7 6 1.3 9 7.32 2 +237NP B 147.7 6 1.3 9 7.32 237NPS B EAV=39.0 2 237NP G 2.3 237NP G 38.54 3 0.0033 20M1+E2 0.42 25 2.8E2 21 -237NP2 G KC=$LC=2.1E2 16$MC=60 50 -237NP G 337.7 2 0.0089 5 (E2) 0.139 3 -237NP2 G KC=0.0612 12$LC=0.0575 12$MC=0.0157 3 -237NP G 370.928 230.109 2 M1+E2 0.43 21 0.53 7 -237NP2 G KC=0.42 6$LC=0.086 8$MC=0.0211 17 +237NP2 G LC=2.1E2 16$MC=60 50 +237NP G 337.7 2 0.0089 5(E2) 0.139 3 +237NP2 G KC=0.0612 12$LC=0.0575 12$MC=0.0157 3 +237NP G 370.928 230.109 2M1+E2 0.43 21 0.53 7 +237NP2 G KC=0.42 6$LC=0.086 8$MC=0.0211 17 diff --git a/HEN_HOUSE/spectra/lnhb/U-238.txt b/HEN_HOUSE/spectra/lnhb/U-238.txt index 1faea15b0..741c84003 100644 --- a/HEN_HOUSE/spectra/lnhb/U-238.txt +++ b/HEN_HOUSE/spectra/lnhb/U-238.txt @@ -9,31 +9,31 @@ 234TH6C 1987Al28, 1990Ko40, 1991Ry01, 1994Ak05, 1994Du15, 1996Sc06, 1996Ru11, 234TH7C 1998Ad08, 2000Ho27, 2000Ga05, 2002Ba85, 2002Ch52, 2003Au03, 2003Ha06, 234TH8C 2004Sc03 -234TH T Auger electrons and ^X ray energies and emission intensities: -234TH T {U Energy (keV)} {U Intensity } {U Line } +234TH T Auger electrons and X ray energies and emission intensities: +234TH T {U Energy (keV)} {U Intensity} {U Line} 234TH T -234TH T 89.954 0.00109 30 XKA2 -234TH T 93.351 0.0018 5 XKA1 +234TH T 89.954 0.00109 30 XKA2 +234TH T 93.351 0.0018 5 XKA1 234TH T -234TH T 104.819 |] XKB3 -234TH T 105.604 |] 0.00063 17 XKB1 -234TH T 106.239 |] XKB5II +234TH T 104.819 |] XKB3 +234TH T 105.604 |] 0.00063 17 XKB1 +234TH T 106.239 |] XKB5II 234TH T -234TH T 108.509 |] XKB2 -234TH T 108.955 |] 0.00021 6 XKB4 -234TH T 109.442 |] XKO23 +234TH T 108.509 |] XKB2 +234TH T 108.955 |] 0.00021 6 XKB4 +234TH T 109.442 |] XKO23 234TH T -234TH T 11.118-19.504 7.94 28 XL (total) -234TH T 11.118 0.164 8 XLL -234TH T 12.8085-12.967 2.74 12 XLA -234TH T 14.509 0.092 5 XLC -234TH T 14.972-17.1383 4.01 18 XLB -234TH T 18.3633-19.504 0.94 4 XLG +234TH T 11.118-19.504 7.94 28 XL (total) +234TH T 11.118 0.164 8 XLL +234TH T 12.8085-12.967 2.74 12 XLA +234TH T 14.509 0.092 5 XLC +234TH T 14.972-17.1383 4.01 18 XLB +234TH T 18.3633-19.504 0.94 4 XLG 234TH T -234TH T 68.406-76.745 |] KLL AUGER -234TH T 83.857-93.345 |] 0.00012 4 ^KLX AUGER -234TH T 99.29-109.64 |] KXY AUGER -234TH T 5.8-20.3 8.43 25 L AUGER +234TH T 68.406-76.745 |] KLL AUGER +234TH T 83.857-93.345 |] 0.00012 4 KLX AUGER +234TH T 99.29-109.64 |] KXY AUGER +234TH T 5.8-20.3 8.43 25 L AUGER 238U P 0.0 0+ 4.468E9 Y 5 4269.7 29 234TH N 1.0 1.0 1 1.0 234TH L 0 0 0+ 24.10 D 3 @@ -41,9 +41,9 @@ 234TH L 49.55 6 2+ 0.37 NS 3 234TH A 4151 5 22.3 5 1.33 234TH G 49.55 6 0.0697 26E2 321 10 -234TH2 G KC=$LC=235 7$MC=64.4 19 +234TH2 G LC=235 7$MC=64.4 19 234TH L 163.0 1 4+ 234TH A 4038 5 0.13 3 24 234TH G 113.5 1 0.0174 47[E2] 6.47 19 -234TH2 G KC=0.219 7$LC=4.57 14$MC=1.257 38 +234TH2 G KC=0.219 7$LC=4.57 14$MC=1.257 38 diff --git a/HEN_HOUSE/spectra/lnhb/U-239.txt b/HEN_HOUSE/spectra/lnhb/U-239.txt index 26c11d0f3..8e9e2eea8 100644 --- a/HEN_HOUSE/spectra/lnhb/U-239.txt +++ b/HEN_HOUSE/spectra/lnhb/U-239.txt @@ -8,306 +8,306 @@ 239NP C References: 1943Mi10, 1947Fe05, 1957Ho07, 1964Bl11, 1968Ma06, 1969Hu21, 239NP2C 1969Cl12, 1969En02, 1971Ar47, 1975Pa04, 1979Bo30, 1982Ah04, 1989Ab05, 239NP3C 1996Sa23, 2003Au03, 2003Br12, 2006WoO3, 2008Ki07 -239NP T Auger electrons and ^X ray energies and emission intensities: -239NP T {U Energy (keV)} {U Intensity } {U Line } +239NP T Auger electrons and X ray energies and emission intensities: +239NP T {U Energy (keV)} {U Intensity} {U Line} 239NP T -239NP T 97.069 0.091 3 XKA2 -239NP T 101.059 0.144 5 XKA1 +239NP T 97.069 0.091 3 XKA2 +239NP T 101.059 0.144 5 XKA1 239NP T -239NP T 113.303 |] XKB3 -239NP T 114.234 |] 0.052 2 XKB1 -239NP T 114.912 |] XKB5II +239NP T 113.303 |] XKB3 +239NP T 114.234 |] 0.052 2 XKB1 +239NP T 114.912 |] XKB5II 239NP T -239NP T 117.463 |] XKB2 -239NP T 117.876 |] 0.018 1 XKB4 -239NP T 118.429 |] XKO23 +239NP T 117.463 |] XKB2 +239NP T 117.876 |] 0.018 1 XKB4 +239NP T 118.429 |] XKO23 239NP T -239NP T 11.871-21.491 16.1 5 XL (total) -239NP T 11.871 0.38 2 XLL -239NP T 13.671-13.946 7.0 2 XLA -239NP T 15.861 0.108 4 XLC -239NP T 16.109-17.992 6.9 2 XLB -239NP T 20.784-21.491 1.68 4 XLG +239NP T 11.871-21.491 16.1 5 XL (total) +239NP T 11.871 0.38 2 XLL +239NP T 13.671-13.946 7.0 2 XLA +239NP T 15.861 0.108 4 XLC +239NP T 16.109-17.992 6.9 2 XLB +239NP T 20.784-21.491 1.68 4 XLG 239NP T -239NP T 73.501-83.134 |] KLL AUGER -239NP T 90.358-101.054 |] 0.0091 13 ^KLX AUGER -239NP T 107.19-118.66 |] KXY AUGER -239NP T 6.04-13.12 14.7 7 L AUGER +239NP T 73.501-83.134 |] KLL AUGER +239NP T 90.358-101.054 |] 0.0091 13 KLX AUGER +239NP T 107.19-118.66 |] KXY AUGER +239NP T 6.04-13.12 14.7 7 L AUGER 239U P 0.0 5/2+ 23.46 M 5 1261.5 16 239NP N 1.0 1.0 1 1.0 -239NP G 46.6 0.009 4 -239NP G 134.71 130.0019 3 -239NP G 142.5 1 0.0045 6 -239NP G 174.07 6 0.0097 3 -239NP G 220.52 4 0.0282 7 +239NP G 46.6 0.009 4 +239NP G 134.71 130.0019 3 +239NP G 142.5 1 0.0045 6 +239NP G 174.07 6 0.0097 3 +239NP G 220.52 4 0.0282 7 239NP G 236.28 140.00092 18 -239NP G 262.89 190.0008 3 -239NP G 265.44 170.0009 3 +239NP G 262.89 190.0008 3 +239NP G 265.44 170.0009 3 239NP G 330.14 140.00069 13 -239NP G 332.06 140.0012 2 -239NP G 348.23 180.0007 3 -239NP G 351.33 150.0007 2 -239NP G 361.83 8 0.0044 3 -239NP G 393.01 180.0006 2 -239NP G 400.55 150.0009 2 -239NP G 404.84 180.0009 3 -239NP G 445.81 120.0011 2 -239NP G 452.17 120.0016 2 +239NP G 332.06 140.0012 2 +239NP G 348.23 180.0007 3 +239NP G 351.33 150.0007 2 +239NP G 361.83 8 0.0044 3 +239NP G 393.01 180.0006 2 +239NP G 400.55 150.0009 2 +239NP G 404.84 180.0009 3 +239NP G 445.81 120.0011 2 +239NP G 452.17 120.0016 2 239NP G 478.13 190.00055 23 -239NP G 479.55 140.0010 2 -239NP G 490.33 130.0007 1 -239NP G 502.12 170.0006 2 -239NP G 506.80 140.0010 2 -239NP G 541.32 100.0029 3 -239NP G 558.46 170.0006 2 -239NP G 567.88 180.0004 1 -239NP G 575.27 5 0.0131 4 -239NP G 577.15 140.0014 3 -239NP G 585.49 140.0012 2 -239NP G 591.82 190.0009 4 -239NP G 599.13 150.0007 2 -239NP G 602.79 8 0.0048 3 +239NP G 479.55 140.0010 2 +239NP G 490.33 130.0007 1 +239NP G 502.12 170.0006 2 +239NP G 506.80 140.0010 2 +239NP G 541.32 100.0029 3 +239NP G 558.46 170.0006 2 +239NP G 567.88 180.0004 1 +239NP G 575.27 5 0.0131 4 +239NP G 577.15 140.0014 3 +239NP G 585.49 140.0012 2 +239NP G 591.82 190.0009 4 +239NP G 599.13 150.0007 2 +239NP G 602.79 8 0.0048 3 239NP G 604.85 6 0.00096 27 -239NP G 614.53 170.0006 2 -239NP G 618.03 160.0007 2 -239NP G 629.00 110.0027 3 -239NP G 649.79 190.0009 4 +239NP G 614.53 170.0006 2 +239NP G 618.03 160.0007 2 +239NP G 629.00 110.0027 3 +239NP G 649.79 190.0009 4 239NP G 668.76 180.00055 18 -239NP G 670.88 200.0006 3 -239NP G 691.01 6 0.0074 3 -239NP G 692.61 130.0016 3 -239NP G 701.21 100.0024 2 -239NP G 714.22 9 0.0030 3 -239NP G 730.95 6 0.0090 3 -239NP G 746.06 110.0043 5 -239NP G 764.04 110.0026 3 -239NP G 768.15 110.0020 2 -239NP G 769.52 170.0004 1 -239NP G 795.13 150.0008 2 +239NP G 670.88 200.0006 3 +239NP G 691.01 6 0.0074 3 +239NP G 692.61 130.0016 3 +239NP G 701.21 100.0024 2 +239NP G 714.22 9 0.0030 3 +239NP G 730.95 6 0.0090 3 +239NP G 746.06 110.0043 5 +239NP G 764.04 110.0026 3 +239NP G 768.15 110.0020 2 +239NP G 769.52 170.0004 1 +239NP G 795.13 150.0008 2 239NP G 829.59 170.00046 13 -239NP G 831.89 9 0.0021 2 -239NP G 862.56 180.0004 1 -239NP G 913.68 9 0.0019 1 +239NP G 831.89 9 0.0021 2 +239NP G 862.56 180.0004 1 +239NP G 913.68 9 0.0019 1 239NP G 948.88 190.00024 10 -239NP G 970.07 140.0009 2 -239NP G 988.51 140.00044 9 -239NP G 1002.40 130.00049 9 -239NP G 1005.27 130.0006 1 -239NP G 1009.38 180.0003 1 -239NP G 1101.99 160.00031 1 +239NP G 970.07 140.0009 2 +239NP G 988.51 140.00044 9 +239NP G 1002.40 130.00049 9 +239NP G 1005.27 130.0006 1 +239NP G 1009.38 180.0003 1 +239NP G 1101.99 160.00031 1 239NP L 0 5/2+ 2.356 D 3 239NP B 1261.5 1614.4 22 6.7 239NPS B EAV=418.6 5 239NP L 31.1310 127/2+ -239NP B 1230.4 169.4 15 6.83 2 +239NP B 1230.4 169.4 15 6.83 239NPS B EAV=406.8 5 -239NP G 31.1310 120.072 4 M1+E2 0.17 1 263 13 -239NP2 G KC=$LC=195 10$MC=50 3 +239NP G 31.1310 120.072 4M1+E2 0.17 1 263 13 +239NP2 G LC=195 10$MC=50 3 239NP L 71.210 2 9/2+ -239NP G 71.210 2 0.00193 4 E2 71.9 14 -239NP2 G KC=$LC=52.3 10$MC=14.6 3 +239NP G 71.210 2 0.00193 4E2 71.9 14 +239NP2 G LC=52.3 10$MC=14.6 3 239NP L 74.664 1 5/2- 1.39 NS 3 239NP B 1186.5 1672.8 19 5.91 239NPS B EAV=390.4 5 -239NP G 43.533 1 4.35 28E1 1.14 3 -239NP2 G KC=$LC=0.856 17$MC=0.215 4 -239NP G 74.664 1 51.6 13E1 0.276 6 -239NP2 G KC=$LC=0.207 4$MC=0.0512 10 +239NP G 43.533 1 4.35 28E1 1.14 3 +239NP2 G LC=0.856 17$MC=0.215 4 +239NP G 74.664 1 51.6 13E1 0.276 6 +239NP2 G LC=0.207 4$MC=0.0512 10 239NP L 117.727 207/2- 40 PS -239NP B 1143.9 162.2 4 7.4 1U +239NP B 1143.9 162.2 4 7.4 1 239NPS B EAV=374.0 5 -239NP G 43.06 2 0.013 2 M1+E2 0.38 38 154 18 -239NP2 G KC=$LC=114 13$MC=30 4 -239NP G 86.72 7 0.055 5 E1 0.186 4 -239NP2 G KC=$LC=0.140 3$MC=0.0344 7 -239NP G 117.727 200.113 9 E1 0.0841 17 -239NP2 G KC=$LC=0.0632 13$MC=0.0155 3 +239NP G 43.06 2 0.013 2M1+E2 0.38 38 154 18 +239NP2 G LC=114 13$MC=30 4 +239NP G 86.72 7 0.055 5E1 0.186 4 +239NP2 G LC=0.140 3$MC=0.0344 7 +239NP G 117.727 200.113 9E1 0.0841 17 +239NP2 G LC=0.0632 13$MC=0.0155 3 239NP L 122.5 10(11/2)+ 239NP L 173.10 4 9/2- 239NP G 55.37 5 8.36E-5 20M1+E2 0.6 2 90 30 -239NP2 G KC=$LC=63 20$MC=17 6 +239NP2 G LC=63 20$MC=17 6 239NP L 241.36 5 (11/2-)- -239NP G 170.15 5 0.031 1 +239NP G 170.15 5 0.031 1 239NP L 260.799 17(3/2)- -239NP G 186.15 4 0.0288 7 [M1+E2] 2.6 16 +239NP G 186.15 4 0.0288 7[M1+E2] 2.6 16 239NP2 G KC=1.7 16$LC=0.645 13$MC=0.167 14 -239NP G 260.80 2 0.0031 2 [E1] 0.0549 11 -239NP2 G KC=0.0434 9$LC=0.0087 2$MC=0.00211 4 +239NP G 260.80 2 0.0031 2[E1] 0.0549 11 +239NP2 G KC=0.0434 9$LC=0.0087 2$MC=0.00211 4 239NP L 438.83 5 (11/2+)+ -239NP G 197.28 120.0024 3 +239NP G 197.28 120.0024 3 239NP L 448.178 16(3/2-)- -239NP G 187.28 8 0.0056 3 [M1+E2] 2.6 16 +239NP G 187.28 8 0.0056 3[M1+E2] 2.6 16 239NP2 G KC=1.7 16$LC=0.631 13$MC=0.164 14 -239NP G 373.51 4 0.025 6 [M1+E2] 0.35 22 -239NP2 G KC=0.26 22$LC=0.07 3$MC=0.017 6 -239NP G 448.18 2 0.0090 3 [E1] 0.0173 4 -239NP2 G KC=0.0139 3$LC=0.00258 5$MC=0.00062 1 +239NP G 373.51 4 0.025 6[M1+E2] 0.35 22 +239NP2 G KC=0.26 22$LC=0.07 3$MC=0.017 6 +239NP G 448.18 2 0.0090 3[E1] 0.0173 4 +239NP2 G KC=0.0139 3$LC=0.00258 5$MC=0.00062 1 239NP L 452.736 2 (5/2+,7/2-)+ -239NP G 378.06 6 0.0101 4 -239NP G 381.27 160.0006 2 +239NP G 378.06 6 0.0101 4 +239NP G 381.27 160.0006 2 239NP L 474.36 6 + -239NP B 787.1 160.0033 4 +239NP B 787.1 160.0033 4 239NPS B EAV=244.0 5 -239NP G 399.13 130.0016 3 -239NP G 474.36 6 0.0017 2 +239NP G 399.13 130.0016 3 +239NP G 474.36 6 0.0017 2 239NP L 517.998 20(7/2-)- -239NP B 743.5 160.063 2 1U +239NP B 743.5 160.063 2 1 239NPS B EAV=228.6 5 -239NP G 486.87 3 0.0618 14[E1] 0.0147 4 -239NP2 G KC=0.0118 3$LC=0.00217 5$MC=0.00052 1 -239NP G 518.00 2 0.0045 3 [E1] 0.0130019 -239NP2 G KC=0.01050 15$LC=0.00190 4$MC=0.00046 1 +239NP G 486.87 3 0.0618 14[E1] 0.0147 4 +239NP2 G KC=0.0118 3$LC=0.00217 5$MC=0.00052 1 +239NP G 518.00 2 0.0045 3[E1] 0.0130019 +239NP2 G KC=0.01050 15$LC=0.00190 4$MC=0.00046 1 239NP L 530.29 6 + -239NP B 731.2 160.0029 4 +239NP B 731.2 160.0029 4 239NPS B EAV=224.3 5 -239NP G 455.63 6 0.0008 3 -239NP G 499.1 1 0.0021 2 +239NP G 455.63 6 0.0008 3 +239NP G 499.1 1 0.0021 2 239NP L 563.89 4 + -239NP B 697.6 160.0247 7 +239NP B 697.6 160.0247 7 239NPS B EAV=212.6 5 -239NP G 111.0 2 0.0202 5 -239NP G 492.76 7 0.0050 2 -239NP G 532.86 100.0023 2 -239NP G 563.89 4 0.0004 2 +239NP G 111.0 2 0.0202 5 +239NP G 492.76 7 0.0050 2 +239NP G 532.86 100.0023 2 +239NP G 563.89 4 0.0004 2 239NP L 579.40 4 (9/2-)- -239NP G 504.76 8 0.0052 3 [E2] 0.0488 10 -239NP2 G KC=0.0293 6$LC=0.0143 3$MC=0.0038 1 -239NP G 547.99 120.0020 3 [E1] 0.0117024 -239NP2 G KC=0.00941 19$LC=0.00170 4$MC=0.00041 1 +239NP G 504.76 8 0.0052 3[E2] 0.0488 10 +239NP2 G KC=0.0293 6$LC=0.0143 3$MC=0.0038 1 +239NP G 547.99 120.0020 3[E1] 0.0117024 +239NP2 G KC=0.00941 19$LC=0.00170 4$MC=0.00041 1 239NP L 662.282 17(5/2-)- -239NP B 599.2 160.261 6 7.35 +239NP B 599.2 160.261 6 7.35 239NPS B EAV=179.0 5 -239NP G 544.48 9 0.0036 3 [M1+E2] 0.13 9 -239NP2 G KC=0.10 8$LC=0.022 11$MC=0.005 3 -239NP G 587.62 2 0.0193 5 [M1+E2] 0.11 7 -239NP2 G KC=0.08 6$LC=0.018 9$MC=0.004 2 -239NP G 631.10 3 0.067 2 [E1] 0.0089217 -239NP2 G KC=0.0072 2$LC=0.00128 3$MC=0.00031 1 -239NP G 662.28 2 0.170 5 [E1] 0.0081516 -239NP2 G KC=0.00660 13$LC=1170E-6 17$MC=0.00028 1 +239NP G 544.48 9 0.0036 3[M1+E2] 0.13 9 +239NP2 G KC=0.10 8$LC=0.022 11$MC=0.005 3 +239NP G 587.62 2 0.0193 5[M1+E2] 0.11 7 +239NP2 G KC=0.08 6$LC=0.018 9$MC=0.004 2 +239NP G 631.10 3 0.067 2[E1] 0.0089217 +239NP2 G KC=0.0072 2$LC=0.00128 3$MC=0.00031 1 +239NP G 662.28 2 0.170 5[E1] 0.0081516 +239NP2 G KC=0.00660 13$LC=1170E-6 17$MC=0.00028 1 239NP L 695.229 23(7/2-)- -239NP B 566.3 160.0118 11 1U +239NP B 566.3 160.0118 11 1 239NPS B EAV=168.0 5 -239NP G 522.12 100.0024 2 [M1+E2] 0.14 10 -239NP2 G KC=0.11 9$LC=0.025 13$MC=0.006 3 -239NP G 624.11 7 0.0062 3 [E1] 0.0091 2 -239NP2 G KC=0.00737 15$LC=0.00131 3$MC=0.00031 1 -239NP G 664.17 9 0.0054 4 [E1] 0.0081116 -239NP2 G KC=0.00657 13$LC=1160E-6 17$MC=0.00028 1 -239NP G 695.23 2 0.0036 3 [E1] 0.0074515 -239NP2 G KC=0.00604 13$LC=1060E-6 15$MC=0.00025 1 +239NP G 522.12 100.0024 2[M1+E2] 0.14 10 +239NP2 G KC=0.11 9$LC=0.025 13$MC=0.006 3 +239NP G 624.11 7 0.0062 3[E1] 0.0091 2 +239NP2 G KC=0.00737 15$LC=0.00131 3$MC=0.00031 1 +239NP G 664.17 9 0.0054 4[E1] 0.0081116 +239NP2 G KC=0.00657 13$LC=1160E-6 17$MC=0.00028 1 +239NP G 695.23 2 0.0036 3[E1] 0.0074515 +239NP2 G KC=0.00604 13$LC=1060E-6 15$MC=0.00025 1 239NP L 781.93 4 + -239NP G 707.38 9 0.0022 2 +239NP G 707.38 9 0.0022 2 239NP L 784.94 5 + -239NP G 710.35 153000E-6 0 +239NP G 710.35 150.003 239NP L 819.26 3 (7/2)+ -239NP B 442.2 160.228 3 2 +239NP B 442.2 160.228 3 239NPS B EAV=127.4 5 239NP G 239.86 5 0.00087 23 -239NP G 255.37 5 0.0011 2 -239NP G 646.26 100.0029 3 -239NP G 748.09 3 0.0890 4 -239NP G 788.19 7 0.0049 2 -239NP G 819.26 3 0.129 3 +239NP G 255.37 5 0.0011 2 +239NP G 646.26 100.0029 3 +239NP G 748.09 3 0.0890 4 +239NP G 788.19 7 0.0049 2 +239NP G 819.26 3 0.129 3 239NP L 844.10 3 (5/2,7/2)+ -239NP B 417.4 160.215 3 +239NP B 417.4 160.215 3 239NPS B EAV=119.6 5 -239NP G 326.21 7 0.0044 2 -239NP G 772.94 9 0.0029 2 -239NP G 812.89 3 0.0685 3 -239NP G 844.10 3 0.139 3 +239NP G 326.21 7 0.0044 2 +239NP G 772.94 9 0.0029 2 +239NP G 812.89 3 0.0685 3 +239NP G 844.10 3 0.139 3 239NP L 849.44 9 + -239NP B 412.0 160.0264 4 +239NP B 412.0 160.0264 4 239NPS B EAV=117.8 5 -239NP G 588.70 8 0.0055 3 -239NP G 607.96 150.0013 3 -239NP G 727.52 100.0026 3 -239NP G 774.77 4 0.015 4 -239NP G 849.44 9 0.0020 2 +239NP G 588.70 8 0.0055 3 +239NP G 607.96 150.0013 3 +239NP G 727.52 100.0026 3 +239NP G 774.77 4 0.015 4 +239NP G 849.44 9 0.0020 2 239NP L 863.46 6 (3/2,5/2,7/2)+ -239NP B 398.1 160.0005 2 2 +239NP B 398.1 160.0005 2 239NPS B EAV=113.4 5 -239NP G 201.18 6 0.0005 2 +239NP G 201.18 6 0.0005 2 239NP L 959.18 3 + -239NP B 302.3 160.0284 7 +239NP B 302.3 160.0284 7 239NPS B EAV=83.9 5 -239NP G 296.93 13 [M1+E2] 0.7 5 -239NP2 G KC=0.5 4$LC=0.13 4$MC=0.034 9 -239NP G 395.19 110.0021 2 -239NP G 841.45 4 0.0025 4 -239NP G 884.45 5 0.0086 2 -239NP G 887.97 3 0.0023 2 -239NP G 928.05 3 0.0051 2 -239NP G 959.18 3 0.0078 3 +239NP G 296.93 13 [M1+E2] 0.7 5 +239NP2 G KC=0.5 4$LC=0.13 4$MC=0.034 9 +239NP G 395.19 110.0021 2 +239NP G 841.45 4 0.0025 4 +239NP G 884.45 5 0.0086 2 +239NP G 887.97 3 0.0023 2 +239NP G 928.05 3 0.0051 2 +239NP G 959.18 3 0.0078 3 239NP L 964.234 20(7/2-)- -239NP B 297.3 160.211 3 1U +239NP B 297.3 160.211 3 1 239NPS B EAV=82.4 5 -239NP G 301.95 3 0.0011 3 [M1+E2] 0.6 5 -239NP2 G KC=0.5 4$LC=0.13 4$MC=0.032 9 -239NP G 703.63 100.0023 2 [E2] 0.0234 5 -239NP2 G KC=0.0162 3$LC=0.00537 11$MC=0.00138 3 -239NP G 722.85 4 0.0270 7 [E2] 0.0222 4 -239NP2 G KC=0.0155 3$LC=0.00499 10$MC=1060E-6 18 -239NP G 791.13 5 0.0075 2 -239NP G 846.39 4 0.0312 8 [M1+E2] 0.04 3 -239NP2 G KC=0.032 21$LC=0.007 4$MC=0.0016 8 -239NP G 889.49 4 0.0209 5 [M1+E2] 0.036 22 -239NP2 G KC=0.029 18$LC=0.006 3$MC=0.0014 7 -239NP G 933.09 3 0.0262 6 [E1] 0.004399 -239NP2 G KC=0.00358 7$LC=0.00061 1$MC=0.00015 1 -239NP G 964.23 2 0.0905 20[E1] 0.004158 -239NP2 G KC=0.00338 7$LC=0.00058 1$MC=0.00014 1 +239NP G 301.95 3 0.0011 3[M1+E2] 0.6 5 +239NP2 G KC=0.5 4$LC=0.13 4$MC=0.032 9 +239NP G 703.63 100.0023 2[E2] 0.0234 5 +239NP2 G KC=0.0162 3$LC=0.00537 11$MC=0.00138 3 +239NP G 722.85 4 0.0270 7[E2] 0.0222 4 +239NP2 G KC=0.0155 3$LC=0.00499 10$MC=1060E-6 18 +239NP G 791.13 5 0.0075 2 +239NP G 846.39 4 0.0312 8[M1+E2] 0.04 3 +239NP2 G KC=0.032 21$LC=0.007 4$MC=0.0016 8 +239NP G 889.49 4 0.0209 5[M1+E2] 0.036 22 +239NP2 G KC=0.029 18$LC=0.006 3$MC=0.0014 7 +239NP G 933.09 3 0.0262 6[E1] 0.00439 9 +239NP2 G KC=0.00358 7$LC=0.00061 1$MC=0.00015 1 +239NP G 964.23 2 0.0905 20[E1] 0.00415 8 +239NP2 G KC=0.00338 7$LC=0.00058 1$MC=0.00014 1 239NP L 966.55 5 (7/2,9/2-)- -239NP B 295.0 160.0008 2 1U +239NP B 295.0 160.0008 2 1 239NPS B EAV=81.7 5 -239NP G 895.15 150.0008 2 +239NP G 895.15 150.0008 2 239NP L 992.158 22(7/2-)- -239NP B 269.3 160.0262 9 1U +239NP B 269.3 160.0262 9 1 239NPS B EAV=74.0 5 -239NP G 296.93 130.0014 2 [M1+E2] 0.7 5 -239NP2 G KC=0.5 4$LC=0.13 4$MC=0.034 9 -239NP G 869.57 9 0.0016 1 -239NP G 874.43 3 0.0033 2 [M1+E2] 0.038 23 -239NP2 G KC=0.030 19$LC=0.006 4$MC=0.0015 8 -239NP G 917.40 8 0.0027 1 [M1+E2] 0.034 22 -239NP2 G KC=0.026 17$LC=0.005 3$MC=0.0013 7 -239NP G 920.95 8 0.0026 1 [E1] 0.004509 -239NP2 G KC=0.00366 6$LC=0.00063 1$MC=0.00015 1 -239NP G 960.99 5 0.0105 3 [E1] 0.004179 -239NP2 G KC=0.00340 7$LC=0.00058 1$MC=0.00014 1 -239NP G 992.16 2 0.0028 1 [E1] 0.003958 -239NP2 G KC=0.00322 7$LC=0.00055 1$MC=0.00013 1 +239NP G 296.93 130.0014 2[M1+E2] 0.7 5 +239NP2 G KC=0.5 4$LC=0.13 4$MC=0.034 9 +239NP G 869.57 9 0.0016 1 +239NP G 874.43 3 0.0033 2[M1+E2] 0.038 23 +239NP2 G KC=0.030 19$LC=0.006 4$MC=0.0015 8 +239NP G 917.40 8 0.0027 1[M1+E2] 0.034 22 +239NP2 G KC=0.026 17$LC=0.005 3$MC=0.0013 7 +239NP G 920.95 8 0.0026 1[E1] 0.00450 9 +239NP2 G KC=0.00366 6$LC=0.00063 1$MC=0.00015 1 +239NP G 960.99 5 0.0105 3[E1] 0.00417 9 +239NP2 G KC=0.00340 7$LC=0.00058 1$MC=0.00014 1 +239NP G 992.16 2 0.0028 1[E1] 0.00395 8 +239NP2 G KC=0.00322 7$LC=0.00055 1$MC=0.00013 1 239NP L 1013.64 8 - -239NP B 247.9 160.0074 4 +239NP B 247.9 160.0074 4 239NPS B EAV=67.6 5 -239NP G 560.63 7 0.0058 3 -239NP G 752.84 8 0.0013 3 -239NP G 938.98 8 0.00031 8 +239NP G 560.63 7 0.0058 3 +239NP G 752.84 8 0.0013 3 +239NP G 938.98 8 0.00031 8 239NP L 1040.37 4 (5/2-,7/2)+ -239NP B 221.1 160.0077 4 +239NP B 221.1 160.0077 4 239NPS B EAV=59.9 5 239NP G 258.44 6 0.00073 18 -239NP G 345.13 8 0.0039 2 -239NP G 779.57 140.0006 1 -239NP G 867.11 110.00076 8 -239NP G 922.83 130.0006 1 -239NP G 1040.37 4 0.0011 1 +239NP G 345.13 8 0.0039 2 +239NP G 779.57 140.0006 1 +239NP G 867.11 110.00076 8 +239NP G 922.83 130.0006 1 +239NP G 1040.37 4 0.0011 1 239NP L 1049.24 4 (9/2-)- -239NP B 212.3 160.0059 4 3U +239NP B 212.3 160.0059 4 1U 239NPS B EAV=57.3 5 -239NP G 931.51 5 0.0053 3 [M1+E2] 0.032 19 -239NP2 G KC=0.026 16$LC=0.005 3$MC=0.0013 7 -239NP G 974.58 4 0.00040 8 [E2] 0.0123 5 -239NP2 G KC=0.00917 18$LC=0.00234 5$MC=0.00059 1 +239NP G 931.51 5 0.0053 3[M1+E2] 0.032 19 +239NP2 G KC=0.026 16$LC=0.005 3$MC=0.0013 7 +239NP G 974.58 4 0.00040 8[E2] 0.0123 5 +239NP2 G KC=0.00917 18$LC=0.00234 5$MC=0.00059 1 239NP L 1096.99 3 - -239NP B 164.5 160.0060 5 +239NP B 164.5 160.0060 5 239NPS B EAV=43.7 5 -239NP G 312.05 3 6000E-7 0 -239NP G 434.71 4 0.0012 2 (E1) 0.0184 4 -239NP2 G KC=0.0148 3$LC=0.00276 5$MC=0.00066 1 -239NP G 644.253 300.0019 4 -239NP G 1065.76 120.00059 8 [M1+E2] 0.023 13 -239NP2 G KC=0.018 11$LC=0.004 2$MC=0.0009 4 -239NP G 1096.99 3 0.0016 1 [M1+E2] 0.022 13 -239NP2 G KC=0.017 11$LC=0.003 2$MC=0.0008 4 +239NP G 312.05 3 0.0006 +239NP G 434.71 4 0.0012 2(E1) 0.0184 4 +239NP2 G KC=0.0148 3$LC=0.00276 5$MC=0.00066 1 +239NP G 644.253 300.0019 4 +239NP G 1065.76 120.00059 8[M1+E2] 0.023 13 +239NP2 G KC=0.018 11$LC=0.004 2$MC=0.0009 4 +239NP G 1096.99 3 0.0016 1[M1+E2] 0.022 13 +239NP2 G KC=0.017 11$LC=0.003 2$MC=0.0008 4 diff --git a/HEN_HOUSE/spectra/lnhb/Xe-127.txt b/HEN_HOUSE/spectra/lnhb/Xe-127.txt index 349d3958b..f2f2536ec 100644 --- a/HEN_HOUSE/spectra/lnhb/Xe-127.txt +++ b/HEN_HOUSE/spectra/lnhb/Xe-127.txt @@ -4,54 +4,54 @@ 127I 3C 1967GE10, 1968KO01, 1968SC14, 1969GUZV, 1969LA08, 1969BEZH, 1970AP02, 127I 4C 1974CO05, 1975AN19, 1976LE23, 1977GE10, 1979AL14, 2002UN02, 2011HA31, 127I 5C 2012WA38, 2012FI12 -127I T Auger electrons and ^X ray energies and emission intensities: -127I T {U Energy (keV)} {U Intensity } {U Line } +127I T Auger electrons and X ray energies and emission intensities: +127I T {U Energy (keV)} {U Intensity} {U Line} 127I T -127I T 28.3175 25.0 4 XKA2 -127I T 28.6123 46.5 8 XKA1 +127I T 28.3175 25.0 4 XKA2 +127I T 28.6123 46.5 8 XKA1 127I T -127I T 32.2397 |] XKB3 -127I T 32.2951 |] 13.39 25 XKB1 -127I T 32.544 |] XKB5II +127I T 32.2397 |] XKB3 +127I T 32.2951 |] 13.39 25 XKB1 +127I T 32.544 |] XKB5II 127I T -127I T 33.042 |] XKB2 -127I T 33.12 |] 3.03 9 XKB4 -127I T 33.166 |] XKO23 +127I T 33.042 |] XKB2 +127I T 33.12 |] 3.03 9 XKB4 +127I T 33.166 |] XKO23 127I T -127I T 3.4848-5.0595 9.60 19 XL (total) -127I T 3.4848 0.184 6 XLL -127I T 3.9269-3.9382 4.85 13 XLA -127I T 3.7791 0.0706 22 XLC -127I T 4.2212-4.5678 3.93 9 XLB -127I T 4.6668-5.0595 0.569 13 XLG +127I T 3.4848-5.0595 9.60 19 XL (total) +127I T 3.4848 0.184 6 XLL +127I T 3.9269-3.9382 4.85 13 XLA +127I T 3.7791 0.0706 22 XLC +127I T 4.2212-4.5678 3.93 9 XLB +127I T 4.6668-5.0595 0.569 13 XLG 127I T -127I T 22.66-23.91 |] KLL AUGER -127I T 26.85-28.56 |] 11.8 5 ^KLX AUGER -127I T 30.99-33.07 |] KXY AUGER -127I T 2.4-5.1 96.4 6 L AUGER +127I T 22.66-23.91 |] KLL AUGER +127I T 26.85-28.56 |] 11.8 5 KLX AUGER +127I T 30.99-33.07 |] KXY AUGER +127I T 2.4-5.1 96.4 6 L AUGER 127XE P 0.0 1/2+ 36.358 D 31 662.3 20 127I N 1.0 1.0 1 1.0 127I L 0 5/2+ STABLE 127I L 57.609 117/2+ 1.95 NS 1 -127I G 57.61 2 1.272 35M1+()E2 -0.083 5 3.72 6 -127I 2 G KC=3.16 5$LC=0.449 8$MC=0.0910 16 +127I G 57.610 201.272 35M1+()E2 -0.083 5 3.72 6 +127I 2 G KC=3.16 5$LC=0.449 8$MC=0.0910 16 127I L 202.860 8 3/2+ 0.387 NS 6 -127I E 52.7 146.61 2 -127I 2 E EAV= $CK=0.842 8$CL=0.125 1$CM=0.0272 5$CN=0.0062 3$CO= -127I G 145.252 104.23 7 E2 0.471 7 -127I 2 G KC=0.357 5$LC=0.0906 13$MC=0.0189 3 +127I E 52.7 146.61 +127I 2 E CK=0.842 8$CL=0.125 1$CM=0.0272 5$CN=0.0062 3 +127I G 145.252 104.23 7E2 0.471 7 +127I 2 G KC=0.357 5$LC=0.0906 13$MC=0.0189 3 127I G 202.86 1 68.45 45M1+()E2 0.517 27 0.1142 18 -127I 2 G KC=0.0964 15$LC=0.0142 3$MC=0.00289 6 +127I 2 G KC=0.0964 15$LC=0.0142 3$MC=0.00289 6 127I L 374.992 9 1/2+ 31 PS 8 -127I E 47.3 7 6.21 -127I 2 E EAV= $CK=0.830 8$CL=0.134 1$CM=0.0294 6$CN=0.0067 4$CO= +127I E 47.3 76.21 +127I 2 E CK=0.830 8$CL=0.134 1$CM=0.0294 6$CN=0.0067 4 127I G 172.132 1025.53 38M1+()E2 -0.085 6 0.1649 24 -127I 2 G KC=0.1419 20$LC=0.0185 3$MC=0.00373 6 -127I G 374.991 1217.26 27E2 0.0199 3 -127I 2 G KC=0.01671 24$LC=0.00257 4$MC=5.24E-4 8 +127I 2 G KC=0.1419 20$LC=0.0185 3$MC=0.00373 6 +127I G 374.991 1217.26 27E2 0.0199 3 +127I 2 G KC=0.01671 24$LC=0.00257 4$MC=5.24E-4 8 127I L 618.4 3 3/2+ -127I E 0.0142 9 7.42 2 -127I 2 E EAV= $CK=0.31 6$CL=0.523 44$CM=0.137 12$CN=0.0324 32$CO= -127I G 618.41 140.0141 9 M1+()E2 0.081 18 0.006099 -127I 2 G KC=0.00528 8$LC=6.56E-4 10$MC=1316E-7 19 +127I E 0.0142 97.42 +127I 2 E CK=0.31 6$CL=0.523 44$CM=0.137 12$CN=0.0324 32 +127I G 618.41 140.0141 9M1+()E2 0.081 18 0.00609 9 +127I 2 G KC=0.00528 8$LC=6.56E-4 10$MC=1316E-7 19 diff --git a/HEN_HOUSE/spectra/lnhb/Xe-131m.txt b/HEN_HOUSE/spectra/lnhb/Xe-131m.txt index ee8e5adc7..a090bc510 100644 --- a/HEN_HOUSE/spectra/lnhb/Xe-131m.txt +++ b/HEN_HOUSE/spectra/lnhb/Xe-131m.txt @@ -6,35 +6,35 @@ 131XE C References: 1952Be55, 1954Be36, 1962Ge01, 1964An08, 1966Kn09, 1969fr04, 131XE2C 1972Em09, 1973Be06, 1974Me21, 1975Ho12, 1976Au08, 1990Ta02, 1994Se07, 131XE3C 1996Sc33, 2002Ba85, 2008Ki07, 2012Wa38, 2012Fi12 -131XE T Auger electrons and ^X ray energies and emission intensities: -131XE T {U Energy (keV)} {U Intensity } {U Line } +131XE T Auger electrons and X ray energies and emission intensities: +131XE T {U Energy (keV)} {U Intensity} {U Line} 131XE T -131XE T 29.459 15.5 4 XKA2 -131XE T 29.779 28.7 7 XKA1 +131XE T 29.459 15.5 4 XKA2 +131XE T 29.779 28.7 7 XKA1 131XE T -131XE T 33.562 |] XKB3 -131XE T 33.625 |] 8.31 22 XKB1 -131XE T 33.881 |] XKB5II +131XE T 33.562 |] XKB3 +131XE T 33.625 |] 8.31 22 XKB1 +131XE T 33.881 |] XKB5II 131XE T -131XE T 34.415 |] XKB2 -131XE T 34.496 |] 1.96 7 XKB4 -131XE T 34.552 |] XKO23 +131XE T 34.415 |] XKB2 +131XE T 34.496 |] 1.96 7 XKB4 +131XE T 34.552 |] XKO23 131XE T -131XE T 3.64-5.3 8.12 16 XL (total) -131XE T 3.64 0.160 5 XLL -131XE T 4.1-4.11 4.20 11 XLA -131XE T 3.96 0.0537 17 XLC -131XE T 4.42-4.78 3.22 7 XLB -131XE T 4.89-5.3 0.479 10 XLG +131XE T 3.64-5.3 8.12 16 XL (total) +131XE T 3.64 0.160 5 XLL +131XE T 4.1-4.11 4.20 11 XLA +131XE T 3.96 0.0537 17 XLC +131XE T 4.42-4.78 3.22 7 XLB +131XE T 4.89-5.3 0.479 10 XLG 131XE T -131XE T 23.512-24.842 |] KLL AUGER -131XE T 27.897-29.77 |] 6.9 4 ^KLX AUGER -131XE T 32.27-34.54 |] KXY AUGER -131XE T 2.5-5.43 75.8 5 L AUGER +131XE T 23.512-24.842 |] KLL AUGER +131XE T 27.897-29.77 |] 6.9 4 KLX AUGER +131XE T 32.27-34.54 |] KXY AUGER +131XE T 2.5-5.43 75.8 5 L AUGER 131XE P 163.930 8 11/2- 11.962 D 20 131XE N 1.0 1.0 1 1.0 131XE L 0 3/2+ STABLE 131XE L 163.930 8 11/2- 11.962 D 20 -131XE G 163.930 8 1.942 26M4 50.5 7 -131XE2 G KC=31.6 5$LC=14.75 21$MC=3.38 5 +131XE G 163.930 8 1.942 26M4 50.5 7 +131XE2 G KC=31.6 5$LC=14.75 21$MC=3.38 5 diff --git a/HEN_HOUSE/spectra/lnhb/Xe-133.txt b/HEN_HOUSE/spectra/lnhb/Xe-133.txt index e78d7d54c..a82b12127 100644 --- a/HEN_HOUSE/spectra/lnhb/Xe-133.txt +++ b/HEN_HOUSE/spectra/lnhb/Xe-133.txt @@ -8,53 +8,53 @@ 133CS3C 1965GE04, 1966TH09, 1968AL16, 1972EM01, 1974CA27, 1974FOZY, 1975HO18, 133CS4C 1975WO10, 1977KR13, 1989RA17, 1992UN01, 1992MA05, 1995RA12, 1996SC06, 133CS5C 2000HE14, 2002BA85, 2002UN02, 2003AU03 -133CS T Auger electrons and ^X ray energies and emission intensities: -133CS T {U Energy (keV)} {U Intensity } {U Line } +133CS T Auger electrons and X ray energies and emission intensities: +133CS T {U Energy (keV)} {U Intensity} {U Line} 133CS T -133CS T 30.6254 13.54 24 XKA2 -133CS T 30.9731 25.0 5 XKA1 +133CS T 30.6254 13.54 24 XKA2 +133CS T 30.9731 25.0 5 XKA1 133CS T -133CS T 34.9197 |] XKB3 -133CS T 34.9873 |] 7.31 15 XKB1 -133CS T 35.252 |] XKB5II +133CS T 34.9197 |] XKB3 +133CS T 34.9873 |] 7.31 15 XKB1 +133CS T 35.252 |] XKB5II 133CS T -133CS T 35.822 |] XKB2 -133CS T 35.907 |] 1.78 6 XKB4 -133CS T 35.972 |] XKO23 +133CS T 35.822 |] XKB2 +133CS T 35.907 |] 1.78 6 XKB4 +133CS T 35.972 |] XKO23 133CS T -133CS T 3.795-5.553 5.79 11 XL (total) -133CS T 3.795 0.111 3 XLL -133CS T 4.273-4.287 2.91 8 XLA -133CS T 4.142 0.0429 13 XLC -133CS T 4.62-4.988 2.37 5 XLB -133CS T 5.131-5.553 0.359 8 XLG +133CS T 3.795-5.553 5.79 11 XL (total) +133CS T 3.795 0.111 3 XLL +133CS T 4.273-4.287 2.91 8 XLA +133CS T 4.142 0.0429 13 XLC +133CS T 4.62-4.988 2.37 5 XLB +133CS T 5.131-5.553 0.359 8 XLG 133CS T -133CS T 24.411-25.804 |] KLL AUGER -133CS T 28.991-30.961 |] 5.65 24 ^KLX AUGER -133CS T 33.55-35.96 |] KXY AUGER -133CS T 2.5-5.6 49.9 3 L AUGER +133CS T 24.411-25.804 |] KLL AUGER +133CS T 28.991-30.961 |] 5.65 24 KLX AUGER +133CS T 33.55-35.96 |] KXY AUGER +133CS T 2.5-5.6 49.9 3 L AUGER 133XE P 0.0 3/2+ 5.2474 D 5 427.4 24 133CS N 1.0 1.0 1 1.0 133CS L 0 0 7/2+ STABLE 133CS L 80.9979 115/2+ 6.31 NS 6 -133CS B 346.4 2499.12 8 5.62 2 +133CS B 346.4 2499.12 8 5.62 133CSS B EAV=100.6 8 -133CS G 80.9979 1137.0 3 M1+E2 -0.151 2 1.698 24 -133CS2 G KC=1.429 20$LC=0.214 3$MC=0.0442 6 +133CS G 80.9979 1137.0 3M1+E2 -0.151 2 1.698 24 +133CS2 G KC=1.429 20$LC=0.214 3$MC=0.0442 6 133CS L 160.6120 165/2+ -133CS B 266.8 240.87 8 7.31 2 +133CS B 266.8 240.87 8 7.31 133CSS B EAV=75.2 8 -133CS G 79.6142 120.28 3 M1+E2 0.124 15 1.768 26 -133CS2 G KC=1.495 21$LC=0.217 6$MC=0.0447 12 -133CS G 160.6120 160.068 8 M1+E2 0.96 5 0.294 5 -133CS2 G KC=0.234 4$LC=0.0471 13$MC=0.0099 3 +133CS G 79.6142 120.28 3M1+E2 0.124 15 1.768 26 +133CS2 G KC=1.495 21$LC=0.217 6$MC=0.0447 12 +133CS G 160.6120 160.068 8M1+E2 0.96 5 0.294 5 +133CS2 G KC=0.234 4$LC=0.0471 13$MC=0.0099 3 133CS L 383.8485 123/2+ -133CS B 43.6 240.0092 9 6.84 +133CS B 43.6 240.0092 9 6.84 133CSS B EAV=11.1 7 -133CS G 223.2368 130.00017 6 M1+E2 -0.114 14 0.0975 14 -133CS2 G KC=0.0836 12$LC=0.01103 16$MC=0.00226 3 -133CS G 302.8508 5 0.0058 8 M1+E2 0.022 20 0.0434 6 -133CS2 G KC=0.0373 5$LC=0.00484 7$MC=9.88E-4 14 -133CS G 383.8485 120.0028 4 E2 0.0202 3 -133CS2 G KC=0.01684 24$LC=0.00269 4$MC=5.59E-4 8 +133CS G 223.2368 130.00017 6M1+E2 -0.114 14 0.0975 14 +133CS2 G KC=0.0836 12$LC=0.01103 16$MC=0.00226 3 +133CS G 302.8508 5 0.0058 8M1+E2 0.022 20 0.0434 6 +133CS2 G KC=0.0373 5$LC=0.00484 7$MC=9.88E-4 14 +133CS G 383.8485 120.0028 4E2 0.0202 3 +133CS2 G KC=0.01684 24$LC=0.00269 4$MC=5.59E-4 8 diff --git a/HEN_HOUSE/spectra/lnhb/Xe-133m.txt b/HEN_HOUSE/spectra/lnhb/Xe-133m.txt index f636b6e0d..7c4a5af69 100644 --- a/HEN_HOUSE/spectra/lnhb/Xe-133m.txt +++ b/HEN_HOUSE/spectra/lnhb/Xe-133m.txt @@ -4,35 +4,35 @@ 133XE C References: 1951BE11, 1952BE55, 1954BE36, 1961ER04, 1968AL16, 1969FR09, 133XE2C 1972AC02, 1974FOZY, 1975HO18, 1976ME16, 1989RA17, 1995RA12, 1996SC06, 133XE3C 2002BA85 -133XE T Auger electrons and ^X ray energies and emission intensities: -133XE T {U Energy (keV)} {U Intensity } {U Line } +133XE T Auger electrons and X ray energies and emission intensities: +133XE T {U Energy (keV)} {U Intensity} {U Line} 133XE T -133XE T 29.459 16.0 4 XKA2 -133XE T 29.779 29.7 6 XKA1 +133XE T 29.459 16.0 4 XKA2 +133XE T 29.779 29.7 6 XKA1 133XE T -133XE T 33.562 |] XKB3 -133XE T 33.625 |] 8.61 20 XKB1 -133XE T 33.881 |] XKB5II +133XE T 33.562 |] XKB3 +133XE T 33.625 |] 8.61 20 XKB1 +133XE T 33.881 |] XKB5II 133XE T -133XE T 34.415 |] XKB2 -133XE T 34.496 |] 2.03 7 XKB4 -133XE T 34.552 |] XKO23 +133XE T 34.415 |] XKB2 +133XE T 34.496 |] 2.03 7 XKB4 +133XE T 34.552 |] XKO23 133XE T -133XE T 3.638-5.296 7.6 4 XL (total) -133XE T 3.638 0.146 5 XLL -133XE T 4.098-4.11 3.84 10 XLA -133XE T 3.958 0.0530 16 XLC -133XE T 4.418-4.776 3.07 7 XLB -133XE T 4.895-5.296 0.457 10 XLG +133XE T 3.638-5.296 7.6 4 XL (total) +133XE T 3.638 0.146 5 XLL +133XE T 4.098-4.11 3.84 10 XLA +133XE T 3.958 0.0530 16 XLC +133XE T 4.418-4.776 3.07 7 XLB +133XE T 4.895-5.296 0.457 10 XLG 133XE T -133XE T 23.512-24.842 |] KLL AUGER -133XE T 27.897-29.77 |] 7.1 4 ^KLX AUGER -133XE T 32.27-34.54 |] KXY AUGER -133XE T 2.4-5.2 70.4 10 L AUGER +133XE T 23.512-24.842 |] KLL AUGER +133XE T 27.897-29.77 |] 7.1 4 KLX AUGER +133XE T 32.27-34.54 |] KXY AUGER +133XE T 2.4-5.2 70.4 10 L AUGER 133XE P 233.219 1511/2- 2.198 D 13 133XE N 1.0 1.0 1 1.0 133XE L 0 0 3/2+ 5.2474 D 5 133XE L 233.219 1511/2- 2.198 D 13 133XE G 233.219 1510.16 13M4 8.84 13 -133XE2 G KC=6.25 9$LC=2.04 3$MC=0.453 7 +133XE2 G KC=6.25 9$LC=2.04 3$MC=0.453 7 diff --git a/HEN_HOUSE/spectra/lnhb/Xe-135m.txt b/HEN_HOUSE/spectra/lnhb/Xe-135m.txt index 4dfdbbe22..d9c46eb5b 100644 --- a/HEN_HOUSE/spectra/lnhb/Xe-135m.txt +++ b/HEN_HOUSE/spectra/lnhb/Xe-135m.txt @@ -4,37 +4,37 @@ 135XE C References: 1960AL12, 1960KO02, 1968HA52, 1968AL16, 1968TO20, 1971GO40, 135XE2C 1971HA13, 1972AC02, 1974FOZY, 1974MEZV, 1975FU12, 1976FE04, 1979BO26, 135XE3C 1982WA21, 1989RA17, 1996SC06, 2002BA85, 2003AU03, 2008SI01 -135XE T Auger electrons and ^X ray energies and emission intensities: -135XE T {U Energy (keV)} {U Intensity } {U Line } +135XE T Auger electrons and X ray energies and emission intensities: +135XE T {U Energy (keV)} {U Intensity} {U Line} 135XE T -135XE T 29.459 3.90 7 XKA2 -135XE T 29.779 7.22 12 XKA1 +135XE T 29.459 3.90 7 XKA2 +135XE T 29.779 7.22 12 XKA1 135XE T -135XE T 33.562 |] XKB3 -135XE T 33.625 |] 2.09 4 XKB1 -135XE T 33.881 |] XKB5II +135XE T 33.562 |] XKB3 +135XE T 33.625 |] 2.09 4 XKB1 +135XE T 33.881 |] XKB5II 135XE T -135XE T 34.415 |] XKB2 -135XE T 34.496 |] 0.494 14 XKB4 -135XE T 34.552 |] XKO23 +135XE T 34.415 |] XKB2 +135XE T 34.496 |] 0.494 14 XKB4 +135XE T 34.552 |] XKO23 135XE T -135XE T 3.638-5.296 1.637 30 XL (total) -135XE T 3.638 0.0313 9 XLL -135XE T 4.0977-4.1103 0.822 21 XLA -135XE T 3.9576 0.0120 4 XLC -135XE T 4.4176-4.7758 0.672 14 XLB -135XE T 4.895-5.296 0.0999 21 XLG +135XE T 3.638-5.296 1.637 30 XL (total) +135XE T 3.638 0.0313 9 XLL +135XE T 4.0977-4.1103 0.822 21 XLA +135XE T 3.9576 0.0120 4 XLC +135XE T 4.4176-4.7758 0.672 14 XLB +135XE T 4.895-5.296 0.0999 21 XLG 135XE T -135XE T 23.512-24.842 |] KLL AUGER -135XE T 27.897-29.77 |] 1.73 8 ^KLX AUGER -135XE T 32.27-34.54 |] KXY AUGER -135XE T 2.5-5.3 15.21 9 L AUGER +135XE T 23.512-24.842 |] KLL AUGER +135XE T 27.897-29.77 |] 1.73 8 KLX AUGER +135XE T 32.27-34.54 |] KXY AUGER +135XE T 2.5-5.3 15.21 9 L AUGER 135XE P 526.570 5 11/2- 15.30 M 3 135XE N 1.00E0 1.00E0 0.99996 1.00E0 135XE L 0 3/2+ 9.14 H 2 135XE L 526.570 5 11/2- 15.30 M 3 -135XE G 526.570 5 80.84 20M4 0.237 3 -135XE2 G KC=0.1908 27$LC=0.0364 5$MC=0.0077 1 +135XE G 526.570 5 80.84 20M4 0.237 3 +135XE2 G KC=0.1908 27$LC=0.0364 5$MC=0.0077 1 135CS 135XE B- DECAY (15.30 M) 135CS H TYP=Full$AUT=M. Galan$CUT=30-MAY-2008$ @@ -42,19 +42,19 @@ 135CS C References: 1960AL12, 1960KO02, 1968HA52, 1968AL16, 1968TO20, 1971GO40, 135CS2C 1971HA13, 1972AC02, 1974FOZY, 1974MEZV, 1975FU12, 1976FE04, 1979BO26, 135CS3C 1982WA21, 1989RA17, 1996SC06, 2002BA85, 2003AU03, 2008SI01 -135CS T Auger electrons and ^X ray energies and emission intensities: -135CS T {U Energy (keV)} {U Intensity } {U Line } +135CS T Auger electrons and X ray energies and emission intensities: +135CS T {U Energy (keV)} {U Intensity} {U Line} 135CS T 135CS T 30.6254 XKA2 135CS T 30.9731 XKA1 135CS T -135CS T 34.9197 |] XKB3 -135CS T 34.9873 |] XKB1 -135CS T 35.252 |] XKB5II +135CS T 34.9197 |] XKB3 +135CS T 34.9873 |] XKB1 +135CS T 35.252 |] XKB5II 135CS T -135CS T 35.822 |] XKB2 -135CS T 35.907 |] XKB4 -135CS T 35.972 |] XKO23 +135CS T 35.822 |] XKB2 +135CS T 35.907 |] XKB4 +135CS T 35.972 |] XKO23 135CS T 135CS T 3.7946 XLL 135CS T 4.2729-4.2866 XLA @@ -62,9 +62,9 @@ 135CS T 4.62-4.9881 XLB 135CS T 5.1308-5.5525 XLG 135CS T -135CS T 24.411-25.804 |] KLL AUGER -135CS T 28.991-30.961 |] ^KLX AUGER -135CS T 33.55-35.96 |] KXY AUGER +135CS T 24.411-25.804 |] KLL AUGER +135CS T 28.991-30.961 |] KLX AUGER +135CS T 33.55-35.96 |] KXY AUGER 135CS T 2.5-5.6 L AUGER 135XE P 526.570 5 11/2- 15.30 M 3 1165.4 40 135CS N 2.50E4 2.50E4 0.00004 2.50E4 @@ -74,15 +74,15 @@ 135CSS B EAV=306 17 135CS G 786.89 0.0036 18E2 135CS L 1133 (9/2)+ -135CS B 559 4 0.00024 9.2 1U +135CS B 559 4 0.00024 9.2 1 135CSS B EAV=173.9 15 -135CS G 1133 2400E-7 0 +135CS G 1133 0.00024 135CS L 1192 (11/2)- -135CS B 500 4 32000E-9 9.9 +135CS B 500 4 0.000032 9.9 135CSS B EAV=152.8 15 -135CS G 1192 3200E-8 0 +135CS G 1192 0.000032 135CS L 1358 + 135CS B 334 4 0.00016 8.7 135CSS B EAV=96.4 13 -135CS G 1358 1600E-7 0 E1 +135CS G 1358 0.00016 E1 diff --git a/HEN_HOUSE/spectra/lnhb/Y-88.txt b/HEN_HOUSE/spectra/lnhb/Y-88.txt index 9faca61d2..3846b4de9 100644 --- a/HEN_HOUSE/spectra/lnhb/Y-88.txt +++ b/HEN_HOUSE/spectra/lnhb/Y-88.txt @@ -6,57 +6,57 @@ 88SR5C 1988Mu09, 1990Sc08, 1992Un01, 1994Ko34, 1997Ma75, 2000Sc47, 2002Ba85, 88SR6C 2002Un02, 2004BeZR, 2005Am01, 2008Ki07, 2012Fi12, 2012Wa38, 2014Mc01, 88SR7C 2014Un01 - 88SR T Auger electrons and ^X ray energies and emission intensities: - 88SR T {U Energy (keV)} {U Intensity } {U Line } + 88SR T Auger electrons and X ray energies and emission intensities: + 88SR T {U Energy (keV)} {U Intensity} {U Line} 88SR T - 88SR T 14.098 17.55 16 XKA2 - 88SR T 14.1652 33.71 26 XKA1 + 88SR T 14.098 17.55 16 XKA2 + 88SR T 14.1652 33.71 26 XKA1 88SR T - 88SR T 15.8252 |] XKB3 - 88SR T 15.8359 |] 8.32 10 XKB1 - 88SR T 15.969 |] XKB5II + 88SR T 15.8252 |] XKB3 + 88SR T 15.8359 |] 8.32 10 XKB1 + 88SR T 15.969 |] XKB5II 88SR T - 88SR T 16.0847 |] XKB2 - 88SR T 16.104 |] 1.08 4 XKB4 + 88SR T 16.0847 |] XKB2 + 88SR T 16.104 |] 1.08 4 XKB4 88SR T - 88SR T 1.5833-2.1971 2.76 5 XL (total) - 88SR T 1.5833 0.0670 17 XLL - 88SR T 1.8054-1.8071 1.73 4 XLA - 88SR T 1.6501 0.0285 7 XLC - 88SR T 1.8722-1.9466 0.921 22 XLB - 88SR T 1.9707-2.1971 0.01489 29 XLG + 88SR T 1.5833-2.1971 2.76 5 XL (total) + 88SR T 1.5833 0.0670 17 XLL + 88SR T 1.8054-1.8071 1.73 4 XLA + 88SR T 1.6501 0.0285 7 XLC + 88SR T 1.8722-1.9466 0.921 22 XLB + 88SR T 1.9707-2.1971 0.01489 29 XLG 88SR T - 88SR T 11.587-12.134 |] KLL AUGER - 88SR T 13.498-14.145 |] 26.5 4 ^KLX AUGER - 88SR T 15.39-16.065 |] KXY AUGER - 88SR T 1.2246-2.1944 103.8 5 L AUGER + 88SR T 11.587-12.134 |] KLL AUGER + 88SR T 13.498-14.145 |] 26.5 4 KLX AUGER + 88SR T 15.39-16.065 |] KXY AUGER + 88SR T 1.2246-2.1944 103.8 5 L AUGER 88Y P 0.0 4- 106.63 D 5 3622.6 15 88SR N 1.0 1.0 1 1.0 88SR L 0 0+ STABLE 88SR L 1836.090 8 2+ 0.154 PS 8 - 88SR E 0.21 1 5.7 3 9.8 1U - 88SR2 E EAV=359.5 7$CK=0.8393 3$CL=0.100085 4$CM=0.02206 8$CN= $CO= - 88SR G 1836.070 8 99.346 25E2 1.63E-42 - 88SR2 G KC=1449E-7 21$LC=1550E-8 22$MC=2.60E-6 4 + 88SR E 0.21 15.7 39.8 1U + 88SR2 E EAV=359.5 7$CK=0.8393 3$CL=0.100085 4$CM=0.02206 8 + 88SR G 1836.070 8 99.346 25E2 1.63E-4 2 + 88SR2 G KC=1449E-7 21$LC=1550E-8 22$MC=2.60E-6 4 88SR L 2734.137 8 3- 0.70 PS 5 - 88SR E 94.3 3 6.9 - 88SR2 E EAV= $CK=0.8726 15$CL=0.1046 14$CM=0.0229 6$CN=0.0030 2$CO=0 0 - 88SR G 898.042 1193.7 3 E1(+M2) -0.002 9 3.07E-45 - 88SR2 G KC=2.73E-4 4$LC=2.92E-5 4$MC=4.89E-6 7 - 88SR G 2734.092 8 0.608 25(E3) 1.24E-42 - 88SR2 G KC=1098E-7 16$LC=1176E-8 17$MC=1.97E-6 3 + 88SR E 94.3 36.9 + 88SR2 E CK=0.8726 15$CL=0.1046 14$CM=0.0229 6$CN=0.0030 2$CO=0 0 + 88SR G 898.042 1193.7 3E1(+M2) -0.002 9 3.07E-4 5 + 88SR2 G KC=2.73E-4 4$LC=2.92E-5 4$MC=4.89E-6 7 + 88SR G 2734.092 8 0.608 25(E3) 1.24E-4 2 + 88SR2 G KC=1098E-7 16$LC=1176E-8 17$MC=1.97E-6 3 88SR L 3218.489 222+ 0.154 PS 10 - 88SR E 0.023 4 9.5 1U - 88SR2 E EAV= $CK=0.8521 2$CL=0.1209 1$CM=0.02701 3$CN=0.0031 2$CO=0 0 - 88SR G 484.352 230.0009 9 [E1] 1217E-617 - 88SR2 G KC=1079E-6 16$LC=1165E-7 17$MC=1.95E-5 3 - 88SR G 1382.387 230.016 3 M1+E2 0.04 2 2.88E-44 - 88SR2 G KC=2.55E-4 4$LC=2.73E-5 4$MC=4.58E-6 7 - 88SR G 3218.426 220.0071 20E2 6.13E-58 - 88SR2 G KC=5.45E-5 8$LC=5.77E-6 8$MC=9.67E-7 14 + 88SR E 0.023 49.5 1U + 88SR2 E CK=0.8521 2$CL=0.1209 1$CM=0.02701 3$CN=0.0031 2$CO=0 0 + 88SR G 484.352 230.0009 9[E1] 1217E-617 + 88SR2 G KC=1079E-6 16$LC=1165E-7 17$MC=1.95E-5 3 + 88SR G 1382.387 230.016 3M1+E2 0.04 2 2.88E-4 4 + 88SR2 G KC=2.55E-4 4$LC=2.73E-5 4$MC=4.58E-6 7 + 88SR G 3218.426 220.0071 20E2 6.13E-5 8 + 88SR2 G KC=5.45E-5 8$LC=5.77E-6 8$MC=9.67E-7 14 88SR L 3584.784 195- 0.14 NS 4 88SR E 0.048 187 - 88SR2 E EAV= $CK=0.721 12$CL=0.225 10$CM=0.0542 25$CN=0.0072 5$CO=0 0 + 88SR2 E CK=0.721 12$CL=0.225 10$CM=0.0542 25$CN=0.0072 5$CO=0 0 88SR G 850.643 210.048 18E2 8.53E-412 - 88SR2 G KC=7.54E-4 11$LC=8.28E-5 12$MC=1.39E-5 2 + 88SR2 G KC=7.54E-4 11$LC=8.28E-5 12$MC=1.39E-5 2 diff --git a/HEN_HOUSE/spectra/lnhb/Y-90.txt b/HEN_HOUSE/spectra/lnhb/Y-90.txt index d14058e4d..51b4e4176 100644 --- a/HEN_HOUSE/spectra/lnhb/Y-90.txt +++ b/HEN_HOUSE/spectra/lnhb/Y-90.txt @@ -11,19 +11,19 @@ 90ZR4C 1967Bi02, 1968La10, 1969Gr38, 1971Na09, 1972Le**, 1976Gr16, 1983Ha35, 90ZR5C 1990Zh20, 1993Gr17, 1996Sc06, 1997Br34, 2002Ba85, 2004Ko18, 2007Se01, 90ZR6C 2007St**, 2008Ki07, 2012Wa38 - 90ZR T Auger electrons and ^X ray energies and emission intensities: - 90ZR T {U Energy (keV)} {U Intensity } {U Line } + 90ZR T Auger electrons and X ray energies and emission intensities: + 90ZR T {U Energy (keV)} {U Intensity} {U Line} 90ZR T 90ZR T 15.6906 XKA2 90ZR T 15.7749 XKA1 90ZR T - 90ZR T 17.6541 |] XKB3 - 90ZR T 17.6674 |] XKB1 - 90ZR T 17.8152 |] XKB5II - 90ZR T 17.818 |] XKB5I + 90ZR T 17.6541 |] XKB3 + 90ZR T 17.6674 |] XKB1 + 90ZR T 17.8152 |] XKB5II + 90ZR T 17.818 |] XKB5I 90ZR T - 90ZR T 17.9691 |] XKB2 - 90ZR T 18.0001 |] XKB4 + 90ZR T 17.9691 |] XKB2 + 90ZR T 18.0001 |] XKB4 90ZR T 90ZR T 1.7932 XLL 90ZR T 2.0403-2.0431 XLA @@ -31,22 +31,21 @@ 90ZR T 2.1246-2.2252 XLB 90ZR T 2.2579-2.5044 XLG 90ZR T - 90ZR T 12.843-13.455 |] KLL AUGER - 90ZR T 15-15.772 |] ^KLX AUGER - 90ZR T 17.137-17.992 |] KXY AUGER + 90ZR T 12.843-13.455 |] KLL AUGER + 90ZR T 15-15.772 |] KLX AUGER + 90ZR T 17.137-17.992 |] KXY AUGER 90ZR T 0.04-2.5256 L AUGER 90Y P 0.0 2- 2.6684 D 13 2278.7 16 90ZR N 1.0 1.0 1 1.0 90ZR L 0 0+ STABLE - 90ZR B 2278.7 1699.983 7 8.05 1U + 90ZR B 2278.7 1699.983 7 8.05 1U 90ZRS B EAV=926.7 8 90ZR L 1760.72 200+ - 90ZR B 518.0 160.017 7 9.4 1U + 90ZR B 518.0 160.017 7 9.4 1U 90ZRS B EAV=163.7 6 90ZR G 1760.7 2 90ZR L 2186.282 102+ - 90ZR B 92.4 1614000E-13 11.1 + 90ZR B 92.4 161.4E-6 3 11.1 90ZRS B EAV=24.5 5 - 90ZR G 2186.254 101.4E-6 3 E2 5.36E-48 - 90ZR2 G KC=$LC=$MC= + 90ZR G 2186.254 101.4E-6 3E2 5.36E-4 8 diff --git a/HEN_HOUSE/spectra/lnhb/Y-90m.txt b/HEN_HOUSE/spectra/lnhb/Y-90m.txt index 6fec2213d..d43c80553 100644 --- a/HEN_HOUSE/spectra/lnhb/Y-90m.txt +++ b/HEN_HOUSE/spectra/lnhb/Y-90m.txt @@ -4,7 +4,7 @@ 90Y T Auger electrons and X ray energies and emission intensities: 90Y T {U Energy (keV)} {U Intensity} {U Line} 90Y T - 90Y T 14.8829 2.02 6 XKA2 + 90Y T 14.8829 2.02 6 XKA2 90Y T 14.9585 3.88 10 XKA1 90Y T 90Y T 16.7259 |] XKB3 @@ -12,30 +12,30 @@ 90Y T 16.88 |] XKB5II 90Y T 90Y T 17.0156 |] XKB2 - 90Y T 17.0362 |] 0.134 6 XKB4 + 90Y T 17.0362 |] 0.134 6 XKB4 90Y T - 90Y T 1.6865-2.3482 0.343 8 XL (total) + 90Y T 1.6865-2.3482 0.343 8 XL (total) 90Y T 1.6865 0.00823 27 XLL - 90Y T 1.9211-1.9233 0.215 7 XLA + 90Y T 1.9211-1.9233 0.215 7 XLA 90Y T 1.7617 0.00343 12 XLC - 90Y T 1.9962-2.0713 0.114 4 XLB - 90Y T 2.1118-2.3482 0.00191 4 XLG + 90Y T 1.9962-2.0713 0.114 4 XLB + 90Y T 2.1118-2.3482 0.00191 4 XLG 90Y T 90Y T 12.205-12.784 |] KLL AUGER - 90Y T 14.238-14.956 |] 2.78 8 KLX AUGER + 90Y T 14.238-14.956 |] 2.78 8 KLX AUGER 90Y T 16.251-17.034 |] KXY AUGER 90Y T 1.2-2.3 11.56 10 L AUGER 90Y P 682.04 0 7+ 3.19 H 6 90Y N 1.00E0 1.00E0 0.999981 1.00E0 90Y L 0 2- 2.6684 D 13 90Y L 202.53 3 3+ 250 PS 7 - 90Y G 202.53 3 97.1 14M1+E2 -0.04 4 0.0272 8 - 90Y 2 G KC=0.0240 7$LC=0.00272 8$MC=4.65E-4 14 + 90Y G 202.53 3 97.1 14M1+E2 -0.04 4 0.0272 8 + 90Y 2 G KC=0.0240 7$LC=0.00272 8$MC=4.65E-4 14 90Y L 682.04 6 7+ 3.18 H 5 90Y G 479.51 7 90.97 24M4(+E5) 0.0957 29 - 90Y 2 G KC=0.0818 25$LC=0.01157 35$MC=0.00202 6 - 90Y G 682.04 6 0.322 22E5 0.0225 7 - 90Y 2 G KC=0.0190 6$LC=0.00292 9$MC=5.07E-4 15 + 90Y 2 G KC=0.0818 25$LC=0.01157 35$MC=0.00202 6 + 90Y G 682.04 6 0.322 22E5 0.0225 7 + 90Y 2 G KC=0.0190 6$LC=0.00292 9$MC=5.07E-4 15 90ZR 90Y B- DECAY (3.19 H) 90ZR H TYP=FULL$AUT=V Chisté$CUT= -- $ @@ -44,10 +44,10 @@ 90ZR T {U Energy (keV)} {U Intensity} {U Line} 90ZR T 90ZR T 15.6906 1.81E-7 19 XKA2 - 90ZR T 15.7749 3.5E-7 4 XKA1 + 90ZR T 15.7749 3.5E-7 4 XKA1 90ZR T 90ZR T 17.6541 |] XKB3 - 90ZR T 17.6674 |] 8.8E-8 9 XKB1 + 90ZR T 17.6674 |] 8.8E-8 9 XKB1 90ZR T 17.8152 |] XKB5II 90ZR T 17.818 |] XKB5I 90ZR T @@ -55,10 +55,10 @@ 90ZR T 18.0001 |] 1.29E-8 14 XKB4 90ZR T 90ZR T 1.7932-2.5044 3.15E-8 19 XL (total) - 90ZR T 1.7932 75E-11 6 XLL + 90ZR T 1.7932 75E-11 6 XLL 90ZR T 2.0403-2.0431 1.99E-8 15 XLA 90ZR T 1.8774 292E-12 29 XLC - 90ZR T 2.1246-2.2252 1.03E-8 9 XLB + 90ZR T 2.1246-2.2252 1.03E-8 9 XLB 90ZR T 2.2579-2.5044 320E-12 17 XLG 90ZR T 90ZR T 12.843-13.455 |] KLL AUGER @@ -69,8 +69,8 @@ 90ZR N 5.263E4 5.263E4 0.000019 5.263E4 90ZR L 0 0+ STABLE 90ZR L 2318.99 2 5- 809.2 MS 20 - 90ZR B 642.9 170.0019 2 9.6 1U + 90ZR B 642.9 170.0019 2 9.6 1U 90ZRS B EAV=231.9 7 - 90ZR G 2318.958 200.0019 2 E5 4.63E-414 + 90ZR G 2318.958 200.0019 2E5 4.63E-414 90ZR2 G KC=4.08E-4 12$LC=4.63E-5 14$MC=8.04E-6 24 diff --git a/HEN_HOUSE/spectra/lnhb/Yb-169.txt b/HEN_HOUSE/spectra/lnhb/Yb-169.txt index 03b18eb7d..8031110f4 100644 --- a/HEN_HOUSE/spectra/lnhb/Yb-169.txt +++ b/HEN_HOUSE/spectra/lnhb/Yb-169.txt @@ -1,161 +1,156 @@ 169TM 169YB EC DECAY (32.018 D) -169TM T Auger electrons and ^X ray energies and emission intensities: -169TM T {U Energy (keV)} {U Intensity } {U Line } +169TM T Auger electrons and X ray energies and emission intensities: +169TM T {U Energy (keV)} {U Intensity} {U Line} 169TM T -169TM T 49.7731 52.9 8 XKA2 -169TM T 50.7417 93.5 13 XKA1 +169TM T 49.7731 52.9 8 XKA2 +169TM T 50.7417 93.5 13 XKA1 169TM T -169TM T 57.304 |] XKB3 -169TM T 57.516 |] 30.6 6 XKB1 -169TM T 57.925 |] XKB5II +169TM T 57.304 |] XKB3 +169TM T 57.516 |] 30.6 6 XKB1 +169TM T 57.925 |] XKB5II 169TM T -169TM T 59.1 |] XKB2 -169TM T 59.21 |] 7.95 21 XKB4 -169TM T 59.357 |] XKO23 +169TM T 59.1 |] XKB2 +169TM T 59.21 |] 7.95 21 XKB4 +169TM T 59.357 |] XKO23 169TM T -169TM T 6.34-9.78 49.4 8 XL (total) -169TM T 6.34 0.956 25 XLL -169TM T 7.13-7.18 21.7 5 XLA -169TM T 7.31 0.437 12 XLC -169TM T 8.18-8.64 22.5 6 XLB -169TM T 9.15-9.78 3.1 1 XLG +169TM T 6.34-9.78 49.4 8 XL (total) +169TM T 6.34 0.956 25 XLL +169TM T 7.13-7.18 21.7 5 XLA +169TM T 7.31 0.437 12 XLC +169TM T 8.18-8.64 22.5 6 XLB +169TM T 9.15-9.78 3.1 1 XLG 169TM T -169TM T 38.96-41.88 |] KLL AUGER -169TM T 46.88-50.71 |] 10.8 8 ^KLX AUGER -169TM T 54.78-59.32 |] KXY AUGER -169TM T 3.85-7.18 168.2 18 L AUGER +169TM T 38.96-41.88 |] KLL AUGER +169TM T 46.88-50.71 |] 10.8 8 KLX AUGER +169TM T 54.78-59.32 |] KXY AUGER +169TM T 3.85-7.18 168.2 18 L AUGER 169YB P 0.0 7/2+ 32.018 D 5 909 4 169TM N 1.0 1.0 1 1.0 169TM G 328 2 0.00672 43 -169TM G 614.1 5 9.7E-5 14 +169TM G 614.1 5 0.00009714 169TM L 0 1/2+ STABLE 169TM L 8.4102 3/2+ 4.08 NS 169TM G 8.41016 150.347 17M1+E2 273 13 -169TM2 G KC=$LC=$MC=218 11 +169TM2 G MC=218 11 169TM L 118.1894 5/2+ 62 PS -169TM G 109.77924 4 17.36 9 M1+E2 2.45 4 -169TM2 G KC=2.03 3$LC=0.327 5$MC=0.0730 11 -169TM G 118.18940 141.87 1 E2 1.66 5 -169TM2 G KC=0.697 21$LC=0.734 22$MC=0.179 6 +169TM G 109.77924 4 17.36 9M1+E2 2.45 4 +169TM2 G KC=2.03 3$LC=0.327 5$MC=0.0730 11 +169TM G 118.18940 141.87 1E2 1.66 5 +169TM2 G KC=0.697 21$LC=0.734 22$MC=0.179 6 169TM L 138.9331 7/2+ 302 PS 169TM G 20.74370 210.1925 43M1+E2 57.3 17 -169TM2 G KC=$LC=44.5 13$MC=10.0 3 -169TM G 130.52293 6 11.38 5 E2 1.15 4 -169TM2 G KC=0.538 17$LC=0.470 15$MC=0.115 4 +169TM2 G LC=44.5 13$MC=10.0 3 +169TM G 130.52293 6 11.38 5E2 1.15 4 +169TM2 G KC=0.538 17$LC=0.470 15$MC=0.115 4 169TM L 316.1463 7/2+ 660 NS 169TM E 5.1 198.33 -169TM2 E EAV= $CK=0.8093 17$CL=0.1457 12$CM=0.0349 7$CN= $CO= -169TM G 177.21307 6 22.32 10M1+E2 0.590 9 -169TM2 G KC=0.484 7$LC=0.0868 13$MC=0.0197 3 -169TM G 197.95675 7 35.93 12M1+E2 0.448 7 -169TM2 G KC=0.370 6$LC=0.0603 9$MC=0.0136 2 +169TM2 E CK=0.8093 17$CL=0.1457 12$CM=0.0349 7 +169TM G 177.21307 6 22.32 10M1+E2 0.590 9 +169TM2 G KC=0.484 7$LC=0.0868 13$MC=0.0197 3 +169TM G 197.95675 7 35.93 12M1+E2 0.448 7 +169TM2 G KC=0.370 6$LC=0.0603 9$MC=0.0136 2 169TM G 307.73757 9 10.046 45E2 0.0666 20 -169TM2 G KC=0.0482 15$LC=0.0141 4$MC=0.00333 10 -169TM G 316.2 7 0.0033 3 M3+E4 +169TM2 G KC=0.0482 15$LC=0.0141 4$MC=0.00333 10 +169TM G 316.2 7 0.0033 3M3+E4 169TM L 332.119 9/2+ 18.8 PS -169TM E 0.0142 1610.9 2 -169TM2 E EAV= $CK=0.8085 18$CL=0.1463 12$CM=0.0350 7$CN= $CO= -169TM G 193.15 5 0.0074 10M1+E2 0.50 3 -169TM2 G KC=0.42 2$LC=0.063 5$MC= -169TM G 213.936 170.00291 22E2 0.21 1 -169TM2 G KC=0.135 7$LC=0.072 6$MC= +169TM E 0.0142 1610.9 +169TM2 E CK=0.8085 18$CL=0.1463 12$CM=0.0350 7 +169TM G 193.15 5 0.0074 10M1+E2 0.50 3 +169TM2 G KC=0.42 2$LC=0.063 5 +169TM G 213.936 170.00291 22E2 0.21 1 +169TM2 G KC=0.135 7$LC=0.072 6 169TM L 345.031 (5/2)- -169TM E 0.0138 1311 1U -169TM2 E EAV= $CK=0.8078 18$CL=0.1469 12$CM=0.0352 7$CN= $CO= -169TM G 205.99 6 0.0034 8 (E1) 0.050 2 -169TM2 G KC=0.042 2$LC=0.0020 2$MC= +169TM E 0.0138 1311 1 +169TM2 E CK=0.8078 18$CL=0.1469 12$CM=0.0352 7 +169TM G 205.99 6 0.0034 8(E1) 0.050 2 +169TM2 G KC=0.042 2$LC=0.0020 2 169TM G 226.3 7 0.00025 18 -169TM G 336.621 3 0.0098 9 (E1) 0.0146 15 -169TM2 G KC=0.0123 13$LC=0.00179 18$MC=0.00040 4 +169TM G 336.621 3 0.0098 9(E1) 0.0146 15 +169TM2 G KC=0.0123 13$LC=0.00179 18$MC=0.00040 4 169TM L 367.66 11/2+ 41.6 PS -169TM G 51.51 400.0034 1 E2 48.6 22 -169TM2 G KC=$LC=37.1 15$MC=9.1 4 +169TM G 51.51 400.0034 1E2 48.6 22 +169TM2 G LC=37.1 15$MC=9.1 4 169TM L 379.268 7/2- 52.6 NS 169TM E 82.2 187 -169TM2 E EAV= $CK=0.8057 18$CL=0.1484 12$CM=0.0356 7$CN= $CO= -169TM G 63.12044 4 44.05 24E1+M2 1.11 4 -169TM2 G KC=0.899 27$LC=0.163 6$MC=0.0366 12 -169TM G 240.33344 120.115 5 E1+M2 0.045 5 -169TM2 G KC=0.037 4$LC=0.0065 7$MC=0.0009 1 -169TM G 261.07712 9 1.687 8 E1+M2 0.0283 9 -169TM2 G KC=0.0237 7$LC=0.00355 11$MC=0.00079 30 -169TM G 370.85616 290.00085 11[M2] 0.308 9 -169TM2 G KC=0.249 8$LC=0.0460 14$MC=0.0106 3 -169TM G 379.26630 250.00030 12[E3] 0.128 4 -169TM2 G KC=0.0757 23$LC=0.0401 12$MC=0.0098 3 +169TM2 E CK=0.8057 18$CL=0.1484 12$CM=0.0356 7 +169TM G 63.12044 4 44.05 24E1+M2 1.11 4 +169TM2 G KC=0.899 27$LC=0.163 6$MC=0.0366 12 +169TM G 240.33344 120.115 5E1+M2 0.045 5 +169TM2 G KC=0.037 4$LC=0.0065 7$MC=0.0009 1 +169TM G 261.07712 9 1.687 8E1+M2 0.0283 9 +169TM2 G KC=0.0237 7$LC=0.00355 11$MC=0.00079 30 +169TM G 370.85616 290.00085 11[M2] 0.308 9 +169TM2 G KC=0.249 8$LC=0.0460 14$MC=0.0106 3 +169TM G 379.26630 250.00030 12[E3] 0.128 4 +169TM2 G KC=0.0757 23$LC=0.0401 12$MC=0.0098 3 169TM L 430.124 (9/2)- -169TM E 0.0044 1 11.2 1U -169TM2 E EAV= $CK=0.8020 18$CL=0.1511 13$CM=0.0364 7$CN= $CO= -169TM G 291.190 110.00431 14[E1] 0.021 2 -169TM2 G KC=0.018 1$LC=0.0026 2$MC= +169TM E 0.0044 111.2 1 +169TM2 E CK=0.8020 18$CL=0.1511 13$CM=0.0364 7 +169TM G 291.190 110.00431 14[E1] 0.021 2 +169TM2 G KC=0.018 1$LC=0.0026 2 169TM L 433.524 (9/2)+ -169TM E 0.121 149.9 2 -169TM2 E EAV= $CK=0.8017 18$CL=0.1513 13$CM=0.0365 7$CN= $CO= +169TM E 0.121 149.9 +169TM2 E CK=0.8017 18$CL=0.1513 13$CM=0.0365 7 169TM G 117.377 180.0398 36(M1+E2) 2.03 20 -169TM2 G KC=1.70 17$LC=0.257 26$MC=0.057 6 -169TM G 294.54 110.0011 5 +169TM2 G KC=1.70 17$LC=0.257 26$MC=0.057 6 +169TM G 294.54 110.0011 5 169TM G 425.0 2 0.00162 29 169TM L 472.8841 9/2- 0.14 NS -169TM E 12.6 3 7.6 1U -169TM2 E EAV= $CK=0.7980 19$CL=0.1540 13$CM=0.0372 7$CN= $CO= +169TM E 12.6 37.6 1 +169TM2 E CK=0.7980 19$CL=0.1540 13$CM=0.0372 7 169TM G 93.61447 8 2.571 17M1+E2 3.89 12 -169TM2 G KC=3.18 10$LC=0.55 2$MC=0.124 4 -169TM G 105.19 100.0026 8 [E1] 0.293 15 -169TM2 G KC=0.24 1$LC=0.039 3$MC= -169TM G 156.73487 9 0.00990 25(E1) 0.102 3 -169TM2 G KC=0.0853 26$LC=0.0132 4$MC=0.0029 1 -169TM G 333.94777 270.00171 9 E1 0.0149 15 -169TM2 G KC=0.0126 13$LC=0.00182 19$MC=0.00040 4 +169TM2 G KC=3.18 10$LC=0.55 2$MC=0.124 4 +169TM G 105.19 100.0026 8[E1] 0.293 15 +169TM2 G KC=0.24 1$LC=0.039 3 +169TM G 156.73487 9 0.00990 25(E1) 0.102 3 +169TM2 G KC=0.0853 26$LC=0.0132 4$MC=0.0029 1 +169TM G 333.94777 270.00171 9E1 0.0149 15 +169TM2 G KC=0.0126 13$LC=0.00182 19$MC=0.00040 4 169TM L 474.973 3/2- -169TM E 34400E-87 12 3U -169TM2 E EAV= $CK= $CL= $CM= $CN= $CO= -169TM G 356.74 5 1.41E-4 6 -169TM G 474.973 9 2.03E-4 9 +169TM E 0.000344 712 1U +169TM G 356.74 5 0.000141 6 +169TM G 474.973 9 0.000203 9 169TM L 570.827 3/2+ 10 PS -169TM E 0.00030 6 12 -169TM2 E EAV= $CK= $CL= $CM= $CN= $CO= -169TM G 452.62 8 3.5E-5 19(M1+E2) -169TM G 562.413 120.00014 4 (M1+E2) -169TM G 570.89 3 1.27E-4 26(M1+E2) +169TM E 0.00030 612 2 +169TM G 452.62 8 0.00003519(M1+E2) +169TM G 562.413 120.00014 4(M1+E2) +169TM G 570.89 3 0.00012726(M1+E2) 169TM L 633.296 5/2+ -169TM E 0.0109 4 10.3 2 -169TM2 E EAV= $CK=0.7692 25$CL=0.1750 18$CM=0.0432 9$CN= $CO= +169TM E 0.0109 410.3 +169TM2 E CK=0.7692 25$CL=0.1750 18$CM=0.0432 9 169TM G 494.360 8 0.00157 12 -169TM G 515.107 6 0.00422 16(M1) 0.036 4 -169TM2 G KC=0.0306 30$LC=0.0045 5$MC=0.00099 10 +169TM G 515.107 6 0.00422 16(M1) 0.036 4 +169TM2 G KC=0.0306 30$LC=0.0045 5$MC=0.00099 10 169TM G 624.886 4 0.00484 27(M1) 0.0222 22 -169TM2 G KC=0.0187 19$LC=0.0027 3$MC=0.00060 6 -169TM G 633.32 107.0E-6 5 +169TM2 G KC=0.0187 19$LC=0.0027 3$MC=0.00060 6 +169TM G 633.32 107.0E-6 5 169TM L 646.763 (7/2)- -169TM E 0.00013 7 12 -169TM2 E EAV= $CK= $CL= $CM= $CN= $CO= -169TM G 507.8 3 1.5E-6 8 -169TM G 528.572 100.00013 6 +169TM E 0.00013 712 +169TM G 507.8 3 1.5E-6 8 +169TM G 528.572 100.00013 6 169TM L 718.791 (7/2)+ -169TM E 0.0037 2 10.3 -169TM2 E EAV= $CK=0.725 5$CL=0.2073 35$CM=0.0526 13$CN= $CO= -169TM G 386.673 130.00038 4 [M1E2] -169TM G 579.854 5 0.00204 16(M1) 0.027 2 -169TM2 G KC=0.023 1$LC=0.0033 3$MC= -169TM G 600.607 8 0.00114 7 (M1) +169TM E 0.0037 210.3 +169TM2 E CK=0.725 5$CL=0.2073 35$CM=0.0526 13 +169TM G 386.673 130.00038 4[M1E2] +169TM G 579.854 5 0.00204 16(M1) 0.027 2 +169TM2 G KC=0.023 1$LC=0.0033 3 +169TM G 600.607 8 0.00114 7(M1) 169TM G 710.358 153.13E-5 22 169TM L 781.803 5/2+ -169TM E 0.0045 3 10.5 2 -169TM2 E EAV= $CK=0.623 15$CL=0.280 11$CM=0.0743 32$CN= $CO= -169TM G 465.657 6 2.31E-4 24 -169TM G 642.877 9 8.1E-5 5 +169TM E 0.0045 310.5 +169TM2 E CK=0.623 15$CL=0.280 11$CM=0.0743 32 +169TM G 465.657 6 0.00023124 +169TM G 642.877 9 0.000081 5 169TM G 663.603 7 0.00203 15 169TM G 773.390 140.00219 11 -169TM G 781.64 8 3.0E-6 3 +169TM G 781.64 8 3.0E-6 3 169TM L 832.41 (9/2)+ -169TM E 17500E-95 11.2 2 -169TM2 E EAV= $CK= $CL= $CM= $CN= $CO= -169TM G 500.35 108.8E-6 8 -169TM G 693.46 8 8.7E-6 4 +169TM E 1.75E-5 511.2 +169TM G 500.35 108.8E-6 8 +169TM G 693.46 8 8.7E-6 4 169TM L 878.35 (7/2)+ -169TM E 40000E-11 10.8 -169TM2 E EAV= $CK= $CL= $CM= $CN= $CO= -169TM G 546.16 221.5E-6 4 +169TM E 0.000004 110.8 +169TM G 546.16 221.5E-6 4 169TM G 739.42 111.83E-6 22 169TM G 760.24 248.3E-7 22 diff --git a/HEN_HOUSE/spectra/lnhb/Zn-63.txt b/HEN_HOUSE/spectra/lnhb/Zn-63.txt index 2ce62d4b1..5cd0178db 100644 --- a/HEN_HOUSE/spectra/lnhb/Zn-63.txt +++ b/HEN_HOUSE/spectra/lnhb/Zn-63.txt @@ -8,171 +8,171 @@ 63CU5C 1982Gr10, 1995ScZY, 1996Sc06, 1998Si25, 1998ScZM, 1998Sc28, 1999ScZX, 63CU6C 2000Sc47, 2001Ba27, 2002Le02, 2002Ba85, 2002Ra45, 2008Ki07, 2011StZZ, 63CU7C 2012Wa38 - 63CU T Auger electrons and ^X ray energies and emission intensities: - 63CU T {U Energy (keV)} {U Intensity } {U Line } + 63CU T Auger electrons and X ray energies and emission intensities: + 63CU T {U Energy (keV)} {U Intensity} {U Line} 63CU T - 63CU T 8.02792 0.865 12 XKA2 - 63CU T 8.04787 1.686 22 XKA1 + 63CU T 8.02792 0.865 12 XKA2 + 63CU T 8.04787 1.686 22 XKA1 63CU T - 63CU T 8.90541 |] XKB3 - 63CU T 8.90539 |] 0.355 6 XKB1 - 63CU T 8.9771 |] XKB5II + 63CU T 8.90541 |] XKB3 + 63CU T 8.90539 |] 0.355 6 XKB1 + 63CU T 8.9771 |] XKB5II 63CU T 63CU T - 63CU T 0.811-1.022 0.0958 16 XL (total) - 63CU T 0.811 0.00311 8 XLL - 63CU T 0.929-0.93 0.0547 13 XLA - 63CU T 0.831 0.00186 5 XLC - 63CU T 0.949-1.022 0.0361 10 XLB - 63CU T 0.952- 0.000052 8 XLG + 63CU T 0.811-1.022 0.0958 16 XL (total) + 63CU T 0.811 0.00311 8 XLL + 63CU T 0.929-0.93 0.0547 13 XLA + 63CU T 0.831 0.00186 5 XLC + 63CU T 0.949-1.022 0.0361 10 XLB + 63CU T 0.952- 0.000052 8 XLG 63CU T - 63CU T 6.731-7.059 |] KLL AUGER - 63CU T 7.746-8.064 |] 3.50 5 ^KLX AUGER - 63CU T 8.739-8.982 |] KXY AUGER - 63CU T 0.68-0.8 9.30 9 L AUGER + 63CU T 6.731-7.059 |] KLL AUGER + 63CU T 7.746-8.064 |] 3.50 5 KLX AUGER + 63CU T 8.739-8.982 |] KXY AUGER + 63CU T 0.68-0.8 9.30 9 L AUGER 63ZN P 0.0 3/2- 38.33 M 10 3366.2 15 63CU N 1.0 1.0 1 1.0 - 63CU G 1696.6 100.002 1 - 63CU G 2181.8 7 0.0013 8 + 63CU G 1696.6 100.002 1 + 63CU G 2181.8 7 0.0013 8 63CU L 0 3/2- STABLE - 63CU E 80.3 6 3.75 5 5.397 + 63CU E 80.3 63.75 55.397 63CU2 E EAV=1041.9 7$CK=0.8860 16$CL=0.0971 13$CM=0.0158 5$CN=0.0010 1$CO=0 0 63CU L 669.93 4 1/2- - 63CU E 7.00 2 0.92 1 5.814 2 - 63CU2 E EAV=732.0 7$CK=0.8859 16$CL=0.0972 13$CM=0.0159 5$CN=0.0010 1$CO= - 63CU G 669.93 4 8.19 32M1+E2 0.11 2 5.19E-48 - 63CU2 G KC=4.66E-4 7$LC=4.62E-5 7$MC=6.5E-6 1 + 63CU E 7.00 20.92 15.814 + 63CU2 E EAV=732.0 7$CK=0.8859 16$CL=0.0972 13$CM=0.0159 5$CN=0.0010 1 + 63CU G 669.93 4 8.19 32M1+E2 0.11 2 5.19E-4 8 + 63CU2 G KC=4.66E-4 7$LC=4.62E-5 7$MC=6.5E-6 1 63CU L 962.02 3 5/2- - 63CU E 4.96 131.19 3 5.602 2 - 63CU2 E EAV=599.5 7$CK=0.8858 16$CL=0.0973 13$CM=0.0159 5$CN=0.0010 1$CO= - 63CU G 962.01 3 6.50 16M1+E2 -0.48 2 2.51E-44 - 63CU2 G KC=2.26E-4 4$LC=2.23E-5 4$MC=3.14E-6 5 + 63CU E 4.96 131.19 35.602 + 63CU2 E EAV=599.5 7$CK=0.8858 16$CL=0.0973 13$CM=0.0159 5$CN=0.0010 1 + 63CU G 962.01 3 6.50 16M1+E2 -0.48 2 2.51E-4 4 + 63CU2 G KC=2.26E-4 4$LC=2.23E-5 4$MC=3.14E-6 5 63CU L 1326.76 5 7/2- - 63CU G 364.74 6 0.0115 25M1+E2 -0.060 5 0.002053 - 63CU2 G KC=0.00184 3$LC=1.84E-4 3$MC=2.59E-5 4 - 63CU G 1326.75 5 0.069 4 E2 1757E-725 + 63CU G 364.74 6 0.0115 25M1+E2 -0.060 5 0.00205 3 + 63CU2 G KC=0.00184 3$LC=1.84E-4 3$MC=2.59E-5 4 + 63CU G 1326.75 5 0.069 4E2 1757E-725 63CU2 G KC=1268E-7 18$LC=1251E-8 18$MC=1758E-9 25 63CU L 1412.16 4 5/2- - 63CU E 0.49 2 0.42 2 5.87 2 - 63CU2 E EAV=399.7 7$CK=0.8857 16$CL=0.0974 13$CM=0.0159 5$CN=0.0010 1$CO= - 63CU G 450.14 5 0.229 16M1+E2 0.115 100 0.001275 - 63CU2 G KC=0.00114 4$LC=1.13E-4 5$MC=1.60E-5 6 - 63CU G 742.23 6 0.067 8 E2 5.71E-48 - 63CU2 G KC=5.12E-4 8$LC=5.11E-5 8$MC=7.18E-6 10 - 63CU G 1412.14 4 0.74 3 M1+E2 0.76 7 1.66E-43 + 63CU E 0.49 20.42 25.87 + 63CU2 E EAV=399.7 7$CK=0.8857 16$CL=0.0974 13$CM=0.0159 5$CN=0.0010 1 + 63CU G 450.14 5 0.229 16M1+E2 0.115 100 0.00127 5 + 63CU2 G KC=0.00114 4$LC=1.13E-4 5$MC=1.60E-5 6 + 63CU G 742.23 6 0.067 8E2 5.71E-4 8 + 63CU2 G KC=5.12E-4 8$LC=5.11E-5 8$MC=7.18E-6 10 + 63CU G 1412.14 4 0.74 3M1+E2 0.76 7 1.66E-4 3 63CU2 G KC=1055E-7 16$LC=1038E-8 15$MC=1460E-9 22 63CU L 1547.00 5 3/2- - 63CU E 0.042 4 0.060 7 6.65 - 63CU2 E EAV=341.0 7$CK=0.8856 16$CL=0.0975 13$CM=0.0159 5$CN=0.0010 1$CO= - 63CU G 584.98 6 0.033 4 M1+E2 - 63CU G 877.06 6 0.003 2 M1+E2 - 63CU G 1546.98 5 0.124 5 M1+E2 0.39 7 1.81E-43 + 63CU E 0.042 40.060 76.65 + 63CU2 E EAV=341.0 7$CK=0.8856 16$CL=0.0975 13$CM=0.0159 5$CN=0.0010 1 + 63CU G 584.98 6 0.033 4M1+E2 + 63CU G 877.06 6 0.003 2M1+E2 + 63CU G 1546.98 5 0.124 5M1+E2 0.39 7 1.81E-4 3 63CU2 G KC=8.70E-5 13$LC=8.54E-6 13$MC=1201E-9 18 63CU L 1860.63 6 7/2- - 63CU G 898.60 7 0.009 3 M1+E2 - 63CU G 1860.60 6 0.011 3 E2 3.16E-45 - 63CU2 G KC=6.46E-5 9$LC=6.35E-6 9$MC=8.92E-7 13 + 63CU G 898.60 7 0.009 3M1+E2 + 63CU G 1860.60 6 0.011 3E2 3.16E-4 5 + 63CU2 G KC=6.46E-5 9$LC=6.35E-6 9$MC=8.92E-7 13 63CU L 2012.92 113/2- - 63CU E 0.00039 2 0.0130 3 7.063 - 63CU2 E EAV=143.6 6$CK=0.8853 16$CL=0.0977 13$CM=0.0160 5$CN=0.0010 1$CO= + 63CU E 0.00039 20.0130 37.063 + 63CU2 E EAV=143.6 6$CK=0.8853 16$CL=0.0977 13$CM=0.0160 5$CN=0.0010 1 63CU G 1050.89 110.0044 11M1+E2 - 63CU G 1342.97 120.0025 8 M1+E2 - 63CU G 2012.89 110.011 2 M1+E2 + 63CU G 1342.97 120.0025 8M1+E2 + 63CU G 2012.89 110.011 2M1+E2 63CU L 2062.45 8 (1/2)- - 63CU E 0.0025 2 0.153 135.96 2 - 63CU2 E EAV=123.0 6$CK=0.8853 16$CL=0.0978 13$CM=0.0160 5$CN=0.0010 1$CO= - 63CU G 515.45 9 0.021 8 (M1+E2) - 63CU G 1392.50 9 0.10 1 (M1+E2) 1.0 2 1.67E-44 - 63CU2 G KC=1098E-7 19$LC=1080E-8 19$MC=1.52E-6 3 - 63CU G 2062.41 8 0.034 3 (M1+E2) + 63CU E 0.0025 20.153 135.96 + 63CU2 E EAV=123.0 6$CK=0.8853 16$CL=0.0978 13$CM=0.0160 5$CN=0.0010 1 + 63CU G 515.45 9 0.021 8(M1+E2) + 63CU G 1392.50 9 0.10 1(M1+E2) 1.0 2 1.67E-4 4 + 63CU2 G KC=1098E-7 19$LC=1080E-8 19$MC=1.52E-6 3 + 63CU G 2062.41 8 0.034 3(M1+E2) 63CU L 2081.32 225/2- - 63CU E 0.00043 9 0.035 7 6.59 2 - 63CU2 E EAV=115.1 6$CK=0.8853 16$CL=0.0978 13$CM=0.0160 5$CN=0.0010 1$CO= - 63CU G 534.32 230.005 2 (M1+E2) - 63CU G 754.56 230.016 6 M1+E2 - 63CU G 2081.28 220.015 2 (M1+E2) + 63CU E 0.00043 90.035 76.59 + 63CU2 E EAV=115.1 6$CK=0.8853 16$CL=0.0978 13$CM=0.0160 5$CN=0.0010 1 + 63CU G 534.32 230.005 2(M1+E2) + 63CU G 754.56 230.016 6M1+E2 + 63CU G 2081.28 220.015 2(M1+E2) 63CU L 2092.13 107/2- - 63CU G 765.37 110.007 3 M1+E2 - 63CU G 1130.1 1 0.013 2 M1+E2 - 63CU G 2092.09 100.005 3 E2 + 63CU G 765.37 110.007 3M1+E2 + 63CU G 1130.10 100.013 2M1+E2 + 63CU G 2092.09 100.005 3E2 63CU L 2336.54 125/2- - 63CU E 0.141 9 5.79 2 - 63CU2 E EAV= $CK=0.8849 16$CL=0.0980 13$CM=0.0160 5$CN=0.0010 1$CO= - 63CU G 475.91 130.006 3 M1+E2 + 63CU E 0.141 95.79 + 63CU2 E CK=0.8849 16$CL=0.0980 13$CM=0.0160 5$CN=0.0010 1 + 63CU G 475.91 130.006 3M1+E2 63CU G 924.37 130.0099 20M1+E2 - 63CU G 1374.50 120.034 2 M1+E2 - 63CU G 1666.59 130.0014 6 E2 - 63CU G 2336.49 120.077 5 M1+E2 + 63CU G 1374.50 120.034 2M1+E2 + 63CU G 1666.59 130.0014 6E2 + 63CU G 2336.49 120.077 5M1+E2 63CU L 2497.19 9 (3/2)- 63CU E 0.0247 206.4 - 63CU2 E EAV= $CK=0.8846 16$CL=0.0983 13$CM=0.0161 5$CN=0.0010 1$CO= + 63CU2 E CK=0.8846 16$CL=0.0983 13$CM=0.0161 5$CN=0.0010 1 63CU G 1827.23 100.0042 11(M1+E2) - 63CU G 2497.14 9 0.020 2 (M1+E2) + 63CU G 2497.14 9 0.020 2(M1+E2) 63CU L 2511.06 6 1/2,3/2,5/2- - 63CU E 0.011 2 6.73 2 - 63CU2 E EAV= $CK=0.8846 16$CL=0.0983 13$CM=0.0161 5$CN=0.0010 1$CO= - 63CU G 2511.01 6 0.011 2 [M1+E2] + 63CU E 0.011 26.73 + 63CU2 E CK=0.8846 16$CL=0.0983 13$CM=0.0161 5$CN=0.0010 1 + 63CU G 2511.01 6 0.011 2[M1+E2] 63CU L 2535.83 7 (5/2)- - 63CU E 0.261 145.33 2 - 63CU2 E EAV= $CK=0.8846 16$CL=0.0984 13$CM=0.0161 5$CN=0.0010 1$CO= - 63CU G 443.70 120.013 4 (M1+E2) 1.0 2 0.0019816 + 63CU E 0.261 145.33 + 63CU2 E CK=0.8846 16$CL=0.0984 13$CM=0.0161 5$CN=0.0010 1 + 63CU G 443.70 120.013 4(M1+E2) 1.0 2 0.0019816 63CU2 G KC=0.00177 14$LC=1.79E-4 14$MC=2.51E-5 20 - 63CU G 675.20 9 0.015 3 (M1+E2) + 63CU G 675.20 9 0.015 3(M1+E2) 63CU G 988.82 9 0.0038 11(M1+E2) - 63CU G 1123.66 8 0.112 11M1+E2 1.0 2 1.92E-44 - 63CU2 G KC=1.71E-4 4$LC=1.69E-5 4$MC=2.37E-6 5 - 63CU G 1209.06 9 0.014 3 (M1+E2) - 63CU G 1573.79 8 0.016 2 (M1+E2) - 63CU G 1865.87 8 0.0200 21(E2) 3.19E-45 - 63CU2 G KC=6.43E-5 9$LC=6.31E-6 9$MC=8.87E-7 13 - 63CU G 2535.78 7 0.067 3 (M1+E2) + 63CU G 1123.66 8 0.112 11M1+E2 1.0 2 1.92E-4 4 + 63CU2 G KC=1.71E-4 4$LC=1.69E-5 4$MC=2.37E-6 5 + 63CU G 1209.06 9 0.014 3(M1+E2) + 63CU G 1573.79 8 0.016 2(M1+E2) + 63CU G 1865.87 8 0.0200 21(E2) 3.19E-4 5 + 63CU2 G KC=6.43E-5 9$LC=6.31E-6 9$MC=8.87E-7 13 + 63CU G 2535.78 7 0.067 3(M1+E2) 63CU L 2696.66 131/2,3/2- - 63CU E 0.122 6 5.47 2 - 63CU2 E EAV= $CK=0.8841 16$CL=0.0988 13$CM=0.0161 5$CN=0.0010 1$CO= - 63CU G 683.74 170.004 2 M1+E2 - 63CU G 1149.65 140.019 2 M1+E2 - 63CU G 2026.70 140.060 4 M1+E2 - 63CU G 2696.60 130.039 3 M1+E2 + 63CU E 0.122 65.47 + 63CU2 E CK=0.8841 16$CL=0.0988 13$CM=0.0161 5$CN=0.0010 1 + 63CU G 683.74 170.004 2M1+E2 + 63CU G 1149.65 140.019 2M1+E2 + 63CU G 2026.70 140.060 4M1+E2 + 63CU G 2696.60 130.039 3M1+E2 63CU L 2716.47 9 3/2,5/2- - 63CU E 0.082 7 5.62 - 63CU2 E EAV= $CK=0.8840 16$CL=0.0988 13$CM=0.0162 5$CN=0.0010 1$CO= - 63CU G 624.13 130.011 4 (E2) + 63CU E 0.082 75.62 + 63CU2 E CK=0.8840 16$CL=0.0988 13$CM=0.0162 5$CN=0.0010 1 + 63CU G 624.13 130.011 4(E2) 63CU G 1169.46 100.0077 16M1+E2 - 63CU G 1388.68 100.043 6 (E2) + 63CU G 1388.68 100.043 6(E2) 63CU G 1754.42 9 0.0043 11M1+E2 - 63CU G 2046.5 1 0.0035 11M1+E2 - 63CU G 2716.41 9 0.012 1 M1+E2 + 63CU G 2046.50 100.0035 11M1+E2 + 63CU G 2716.41 9 0.012 1M1+E2 63CU L 2780.23 21(1/2,3/2)- - 63CU E 0.0298 215.97 2 - 63CU2 E EAV= $CK=0.8837 16$CL=0.0991 13$CM=0.0162 5$CN=0.0010 1$CO= - 63CU G 244.40 220.0053 8 (E2) 0.0213 3 - 63CU2 G KC=0.0190 3$LC=0.00198 3$MC=2.77E-4 4 - 63CU G 1233.22 220.0025 8 M1+E2 + 63CU E 0.0298 215.97 + 63CU2 E CK=0.8837 16$CL=0.0991 13$CM=0.0162 5$CN=0.0010 1 + 63CU G 244.40 220.0053 8(E2) 0.0213 3 + 63CU2 G KC=0.0190 3$LC=0.00198 3$MC=2.77E-4 4 + 63CU G 1233.22 220.0025 8M1+E2 63CU G 2110.26 210.0065 13M1+E2 63CU G 2780.16 210.0154 12M1+E2 63CU L 2808.10 8 3/2- 63CU E 0.0052 106.68 - 63CU2 E EAV= $CK=0.8836 16$CL=0.0992 13$CM=0.0162 5$CN=0.0010 1$CO= - 63CU G 1481.32 9 0.0016 8 E2 - 63CU G 2808.03 8 0.0036 6 M1+E2 + 63CU2 E CK=0.8836 16$CL=0.0992 13$CM=0.0162 5$CN=0.0010 1 + 63CU G 1481.32 9 0.0016 8E2 + 63CU G 2808.03 8 0.0036 6M1+E2 63CU L 2857.9 3 (1/2,3/2)- - 63CU E 0.0069 126.48 2 - 63CU2 E EAV= $CK=0.8833 16$CL=0.0994 13$CM=0.0163 5$CN=0.0010 1$CO= - 63CU G 1445.7 3 0.0025 8 (E2) - 63CU G 2188.0 3 0.0016 8 M1+E2 - 63CU G 2857.8 3 0.0028 5 M1+E2 + 63CU E 0.0069 126.48 + 63CU2 E CK=0.8833 16$CL=0.0994 13$CM=0.0163 5$CN=0.0010 1 + 63CU G 1445.7 3 0.0025 8(E2) + 63CU G 2188.0 3 0.0016 8M1+E2 + 63CU G 2857.8 3 0.0028 5M1+E2 63CU L 2888.9 4 1/2,3/2,5/2- - 63CU E 0.0104 146.24 2 - 63CU2 E EAV= $CK=0.8831 16$CL=0.0996 13$CM=0.0163 5$CN=0.0010 1$CO= + 63CU E 0.0104 146.24 + 63CU2 E CK=0.8831 16$CL=0.0996 13$CM=0.0163 5$CN=0.0010 1 63CU G 1926.9 4 0.0053 11(E2) - 63CU G 2219.0 4 0.0029 8 M1+E2 - 63CU G 2888.8 4 0.0021 2 M1+E2 + 63CU G 2219.0 4 0.0029 8M1+E2 + 63CU G 2888.8 4 0.0021 2M1+E2 63CU L 3042.59 8 (5/2)- - 63CU E 0.0048 8 6.24 2 - 63CU2 E EAV= $CK=0.8814 16$CL=0.1010 13$CM=0.0166 5$CN=0.0010 1$CO= - 63CU G 3042.51 8 0.0048 8 M1+E2 + 63CU E 0.0048 86.24 + 63CU2 E CK=0.8814 16$CL=0.1010 13$CM=0.0166 5$CN=0.0010 1 + 63CU G 3042.51 8 0.0048 8M1+E2 63CU L 3101.4 4 1/2,3/2- - 63CU E 0.0007 2 6.89 2 - 63CU2 E EAV= $CK=0.8802 16$CL=0.1020 13$CM=0.0168 5$CN=0.0011 1$CO=0 0 - 63CU G 3101.3 4 0.0007 2 M1+E2 + 63CU E 0.0007 26.89 + 63CU2 E CK=0.8802 16$CL=0.1020 13$CM=0.0168 5$CN=0.0011 1$CO=0 0 + 63CU G 3101.3 4 0.0007 2M1+E2 diff --git a/HEN_HOUSE/spectra/lnhb/Zn-65.txt b/HEN_HOUSE/spectra/lnhb/Zn-65.txt index c930487ba..6bda6e638 100644 --- a/HEN_HOUSE/spectra/lnhb/Zn-65.txt +++ b/HEN_HOUSE/spectra/lnhb/Zn-65.txt @@ -6,40 +6,40 @@ 65CU5C 1984ScZP, 1985HaZA, 1990Sc08, 1990Ku11, 1992Un01, 1993Bh04, 1995ScZY, 65CU6C 1996Sc06, 2000He14, 2002Un02, 2002Ba85, 2003Lu06, 2003Au03, 2004Sc04, 65CU7C 2004Va02, 2005BeZX, 2006Be34 - 65CU T Auger electrons and ^X ray energies and emission intensities: - 65CU T {U Energy (keV)} {U Intensity } {U Line } + 65CU T Auger electrons and X ray energies and emission intensities: + 65CU T {U Energy (keV)} {U Intensity} {U Line} 65CU T - 65CU T 8.02792 11.76 13 XKA2 - 65CU T 8.04787 22.91 22 XKA1 + 65CU T 8.02792 11.76 13 XKA2 + 65CU T 8.04787 22.91 22 XKA1 65CU T - 65CU T 8.90539 |] 4.82 7 XKB1 - 65CU T 8.9771 |] XKB5II + 65CU T 8.90539 |] 4.82 7 XKB1 + 65CU T 8.9771 |] XKB5II 65CU T 65CU T - 65CU T 0.811-1.022 1.305 21 XL (total) - 65CU T 0.811 0.0424 11 XLL - 65CU T 0.929-0.93 0.745 16 XLA - 65CU T 0.831 0.0253 7 XLC - 65CU T 0.932-1.022 0.491 13 XLB - 65CU T 0.952-0.952 0.00070 11 XLG + 65CU T 0.811-1.022 1.305 21 XL (total) + 65CU T 0.811 0.0424 11 XLL + 65CU T 0.929-0.93 0.745 16 XLA + 65CU T 0.831 0.0253 7 XLC + 65CU T 0.932-1.022 0.491 13 XLB + 65CU T 0.952-0.952 0.00070 11 XLG 65CU T - 65CU T 6.76-7.12 |] KLL AUGER - 65CU T 7.76-8.05 |] 47.5 4 ^KLX AUGER - 65CU T 8.73-8.9 |] KXY AUGER - 65CU T 0.7-1 126.6 7 L AUGER + 65CU T 6.76-7.12 |] KLL AUGER + 65CU T 7.76-8.05 |] 47.5 4 KLX AUGER + 65CU T 8.73-8.9 |] KXY AUGER + 65CU T 0.7-1 126.6 7 L AUGER 65ZN P 0.0 5/2- 244.01 D 9 1352.1 3 65CU N 1.0 1.0 1 1.0 65CU L 0 3/2- STABLE - 65CU E 1.421 7 48.35 117.46 2 - 65CU2 E EAV=143.1 1$CK=0.8853 16$CL=0.0977 15$CM=0.017 $CN= $CO= + 65CU E 1.421 748.35 117.46 + 65CU2 E EAV=143.1 1$CK=0.8853 16$CL=0.0977 15$CM=0.017 65CU L 770.64 9 1/2- 0.099 PS 5 65CU G 770.64 9 0.00269 22M1+E2 0.096 7 3.84E-412 - 65CU2 G KC=3.45E-4 10$LC=3.43E-5 10$MC= + 65CU2 G KC=3.45E-4 10$LC=3.43E-5 10 65CU L 1115.556 4 5/2- 0.285 PS 9 65CU E 50.23 115.89 - 65CU2 E EAV= $CK=0.8794 17$CL=0.1027 16$CM=0.0179 $CN= $CO= + 65CU2 E CK=0.8794 17$CL=0.1027 16$CM=0.0179 65CU G 344.95 200.00254 18[E2] 0.0062019 - 65CU2 G KC=0.00555 17$LC=5.69E-4 19$MC= - 65CU G 1115.539 2 50.22 11M1+E2 -0.437 15 1.84E-47 - 65CU2 G KC=1.66E-4 6$LC=1.62E-5 5$MC= + 65CU2 G KC=0.00555 17$LC=5.69E-4 19 + 65CU G 1115.539 2 50.22 11M1+E2 -0.437 15 1.84E-4 7 + 65CU2 G KC=1.66E-4 6$LC=1.62E-5 5 diff --git a/HEN_HOUSE/spectra/lnhb/Zr-89.txt b/HEN_HOUSE/spectra/lnhb/Zr-89.txt index 446ba0600..82a20a349 100644 --- a/HEN_HOUSE/spectra/lnhb/Zr-89.txt +++ b/HEN_HOUSE/spectra/lnhb/Zr-89.txt @@ -10,53 +10,53 @@ 89Y 7C 1995ItZY, 1995ScZY, 1996Sc06, 1996Sc06, 1997La20, 1998ScZM, 1998Sc28, 89Y 8C 1999ScZX, 2000Sc47, 2002Ba85, 2002Ra45, 2003Au03, 2008Ki07, 2012Wa38, 89Y 9C 2013Si03 - 89Y T Auger electrons and ^X ray energies and emission intensities: - 89Y T {U Energy (keV)} {U Intensity } {U Line } + 89Y T Auger electrons and X ray energies and emission intensities: + 89Y T {U Energy (keV)} {U Intensity} {U Line} 89Y T - 89Y T 14.8829 14.08 13 XKA2 - 89Y T 14.9585 27.01 20 XKA1 + 89Y T 14.8829 14.08 13 XKA2 + 89Y T 14.9585 27.01 20 XKA1 89Y T - 89Y T 16.7259 |] XKB3 - 89Y T 16.7381 |] 6.78 8 XKB1 - 89Y T 16.88 |] XKB5II + 89Y T 16.7259 |] XKB3 + 89Y T 16.7381 |] 6.78 8 XKB1 + 89Y T 16.88 |] XKB5II 89Y T - 89Y T 17.0156 |] XKB2 - 89Y T 17.0362 |] 0.94 4 XKB4 + 89Y T 17.0156 |] XKB2 + 89Y T 17.0362 |] 0.94 4 XKB4 89Y T - 89Y T 1.686-2.347 2.36 5 XL (total) - 89Y T 1.686 0.0568 15 XLL - 89Y T 1.92-1.923 1.48 4 XLA - 89Y T 1.762 0.0234 7 XLC - 89Y T 1.996-2.078 0.778 19 XLB - 89Y T 2.153-2.347 0.01331 24 XLG + 89Y T 1.686-2.347 2.36 5 XL (total) + 89Y T 1.686 0.0568 15 XLL + 89Y T 1.92-1.923 1.48 4 XLA + 89Y T 1.762 0.0234 7 XLC + 89Y T 1.996-2.078 0.778 19 XLB + 89Y T 2.153-2.347 0.01331 24 XLG 89Y T - 89Y T 12.205-12.784 |] KLL AUGER - 89Y T 14.238-14.956 |] 19.4 3 ^KLX AUGER - 89Y T 16.251-17.034 |] KXY AUGER - 89Y T 1.27-1.89 79.5 7 L AUGER + 89Y T 12.205-12.784 |] KLL AUGER + 89Y T 14.238-14.956 |] 19.4 3 KLX AUGER + 89Y T 16.251-17.034 |] KXY AUGER + 89Y T 1.27-1.89 79.5 7 L AUGER 89ZR P 0.0 9/2+ 78.42 H 13 2832.8 28 89Y N 1.0 1.0 1 1.0 89Y L 0 1/2- STABLE 89Y L 908.97 3 9/2+ 15.84 S 18 - 89Y E 22.8 3 76.2 3 6.152 - 89Y 2 E EAV=395.7 14$CK=0.8731 15$CL=0.1041 12$CM=0.0196 4$CN=0.0032 2$CO= - 89Y G 908.97 3 99.03 2 M4 0.0085112 + 89Y E 22.8 376.2 36.152 + 89Y 2 E EAV=395.7 14$CK=0.8731 15$CL=0.1041 12$CM=0.0196 4$CN=0.0032 2 + 89Y G 908.97 3 99.03 2M4 0.0085112 89Y 2 G KC=0.00743 11$LC=9.06E-4 13$MC=1561E-7 22 89Y L 1744.74 185/2- 0.62 PS 14 - 89Y E 0.123 4 9.09 3U - 89Y 2 E EAV= $CK=0.8677 15$CL=0.1082 12$CM=0.0208 4$CN=0.0033 2$CO= - 89Y G 1744.72 180.123 4 E2 3.82E-46 - 89Y 2 G KC=1722E-7 25$LC=1.86E-5 3$MC=3.17E-6 5 + 89Y E 0.123 49.09 1U + 89Y 2 E CK=0.8677 15$CL=0.1082 12$CM=0.0208 4$CN=0.0033 2 + 89Y G 1744.72 180.123 4E2 3.82E-4 6 + 89Y 2 G KC=1722E-7 25$LC=1.86E-5 3$MC=3.17E-6 5 89Y L 2529.8 2 7/2+ 0.08 PS 3 - 89Y E 0.074 5 7.52 2 - 89Y 2 E EAV= $CK=0.8632 16$CL=0.1120 13$CM=0.0213 4$CN=0.0035 2$CO= - 89Y G 1620.81 200.074 5 M1+E2 + 89Y E 0.074 57.52 + 89Y 2 E CK=0.8632 16$CL=0.1120 13$CM=0.0213 4$CN=0.0035 2 + 89Y G 1620.81 200.074 5M1+E2 89Y L 2566.55 1511/2+ - 89Y E 0.106 5 7.25 2 - 89Y 2 E EAV= $CK=0.8615 16$CL=0.1134 13$CM=0.0216 5$CN=0.0035 2$CO= - 89Y G 1657.56 150.106 5 M1+E2 + 89Y E 0.106 57.25 + 89Y 2 E CK=0.8615 16$CL=0.1134 13$CM=0.0216 5$CN=0.0035 2 + 89Y G 1657.56 150.106 5M1+E2 89Y L 2622.1 3 9/2+ 0.21 PS 10 89Y E 0.745 106.18 - 89Y 2 E EAV= $CK=0.8575 17$CL=0.1165 13$CM=0.0223 5$CN=0.0036 2$CO= + 89Y 2 E CK=0.8575 17$CL=0.1165 13$CM=0.0223 5$CN=0.0036 2 89Y G 1713.1 3 0.745 10M1+E2 diff --git a/HEN_HOUSE/spectra/lnhb/Zr-93.txt b/HEN_HOUSE/spectra/lnhb/Zr-93.txt index 1c4852f30..a84e3d8ca 100644 --- a/HEN_HOUSE/spectra/lnhb/Zr-93.txt +++ b/HEN_HOUSE/spectra/lnhb/Zr-93.txt @@ -3,38 +3,38 @@ 93NB C Evaluation history: Type=Full;Author=M.A. Kellett;Cutoff date=17-SEP-2013 93NB C References: 1950St90, 1952Gl**, 1953Gl31, 1972FlZM, 2004BeZQ, 2008DuZX, 93NB2C 2010Ca01, 2010Ya01, 2012Wa38 - 93NB T Auger electrons and ^X ray energies and emission intensities: - 93NB T {U Energy (keV)} {U Intensity } {U Line } + 93NB T Auger electrons and X ray energies and emission intensities: + 93NB T {U Energy (keV)} {U Intensity} {U Line} 93NB T - 93NB T 16.5213 2.41 18 XKA2 - 93NB T 16.6152 4.6 4 XKA1 + 93NB T 16.5213 2.41 18 XKA2 + 93NB T 16.6152 4.6 4 XKA1 93NB T - 93NB T 18.607 |] XKB3 - 93NB T 18.623 |] 1.19 9 XKB1 - 93NB T 18.78 |] XKB5II + 93NB T 18.607 |] XKB3 + 93NB T 18.623 |] 1.19 9 XKB1 + 93NB T 18.78 |] XKB5II 93NB T - 93NB T 18.953 |] XKB2 - 93NB T 18.981 |] 0.179 15 XKB4 + 93NB T 18.953 |] XKB2 + 93NB T 18.981 |] 0.179 15 XKB4 93NB T - 93NB T 1.9-2.67 2.1 1 XL (total) - 93NB T 1.9 0.063 4 XLL - 93NB T 2.16-2.17 1.69 9 XLA - 93NB T 2 0.0064 4 XLC - 93NB T 2.26-2.49 0.325 13 XLB - 93NB T 2.41-2.67 0.0172 6 XLG + 93NB T 1.9-2.67 2.1 1 XL (total) + 93NB T 1.9 0.063 4 XLL + 93NB T 2.16-2.17 1.69 9 XLA + 93NB T 2 0.0064 4 XLC + 93NB T 2.26-2.49 0.325 13 XLB + 93NB T 2.41-2.67 0.0172 6 XLG 93NB T - 93NB T 13.49-14.14 |] KLL AUGER - 93NB T 15.78-16.61 |] 2.78 21 ^KLX AUGER - 93NB T 18.05-18.98 |] KXY AUGER - 93NB T 1.4-2.7 59.1 4 L AUGER + 93NB T 13.49-14.14 |] KLL AUGER + 93NB T 15.78-16.61 |] 2.78 21 KLX AUGER + 93NB T 18.05-18.98 |] KXY AUGER + 93NB T 1.4-2.7 59.1 4 L AUGER 93ZR P 0.0 5/2+ 1.61E6 Y 6 90.3 15 93NB N 1.0 1.0 1 1.0 93NB L 0 9/2+ STABLE - 93NB B 90.3 1527 5 12.09 + 93NB B 90.3 1527 5 12.09 2 93NBS B EAV=23.64 42 93NB L 30.77 2 1/2- 16.12 Y 15 - 93NB B 59.5 1573 5 10.16 3U + 93NB B 59.5 1573 5 10.16 1U 93NBS B EAV=18.75 54 - 93NB G 30.77 2 0.00043 3 M4 1.693E525 - 93NB2 G KC=2.60E4 4$LC=1.151E5 17$MC=2.49E4 4 + 93NB G 30.77 2 0.00043 3M4 1.693E525 + 93NB2 G KC=2.60E4 4$LC=1.151E5 17$MC=2.49E4 4 diff --git a/HEN_HOUSE/spectra/lnhb/Zr-95.txt b/HEN_HOUSE/spectra/lnhb/Zr-95.txt index ebb11c5e4..694491808 100644 --- a/HEN_HOUSE/spectra/lnhb/Zr-95.txt +++ b/HEN_HOUSE/spectra/lnhb/Zr-95.txt @@ -3,42 +3,42 @@ 95NB2 H TYP=Full$AUT=R.G.Helmer$CUT= -- $ 95NB C Evaluation history: Type=update;Author=M.M. Bé;Cutoff date= -- 95NB2C Type=Full;Author=R.G.Helmer;Cutoff date= -- - 95NB T Auger electrons and ^X ray energies and emission intensities: - 95NB T {U Energy (keV)} {U Intensity } {U Line } + 95NB T Auger electrons and X ray energies and emission intensities: + 95NB T {U Energy (keV)} {U Intensity} {U Line} 95NB T - 95NB T 16.5213 0.167 11 XKA2 - 95NB T 16.6152 0.319 20 XKA1 + 95NB T 16.5213 0.167 11 XKA2 + 95NB T 16.6152 0.319 20 XKA1 95NB T - 95NB T 18.6065 |] XKB3 - 95NB T 18.6227 |] 0.082 6 XKB1 - 95NB T 18.78 |] XKB5II + 95NB T 18.6065 |] XKB3 + 95NB T 18.6227 |] 0.082 6 XKB1 + 95NB T 18.78 |] XKB5II 95NB T - 95NB T 18.953 |] XKB2 - 95NB T 18.981 |] 0.0124 9 XKB4 + 95NB T 18.953 |] XKB2 + 95NB T 18.981 |] 0.0124 9 XKB4 95NB T 95NB T - 95NB T 13.49-14.14 |] KLL AUGER - 95NB T 15.79-16.58 |] 0.192 13 ^KLX AUGER - 95NB T 18.02-18.91 |] KXY AUGER - 95NB T 1.4-2.6 0.92 5 L AUGER + 95NB T 13.49-14.14 |] KLL AUGER + 95NB T 15.79-16.58 |] 0.192 13 KLX AUGER + 95NB T 18.02-18.91 |] KXY AUGER + 95NB T 1.4-2.6 0.92 5 L AUGER 95ZR P 0.0 5/2+ 64.032 D 6 1124.8 19 95NB N 1.0 1.0 1 1.0 95NB L 0 9/2+ 34.991 D 6 - 95NB B 1124.8 190.10 3 11.22 + 95NB B 1124.8 190.10 3 11.22 2 95NBS B EAV=406.0 8 95NB L 235.69 2 1/2- 3.61 D 3 - 95NB B 889.1 191.08 7 10.28 3U + 95NB B 889.1 191.08 7 10.28 1U 95NBS B EAV=327.6 8 - 95NB G 235.69 2 0.27 2 M4 2.88 9 - 95NB2 G KC=2.31 8$LC=0.468 14$MC=0.10000 0 + 95NB G 235.69 2 0.27 2M4 2.88 9 + 95NB2 G KC=2.31 8$LC=0.468 14$MC=0.1 95NB L 724.195 4 7/2+ - 95NB B 400.6 1944.34 22 6.98 2 + 95NB B 400.6 1944.34 22 6.98 95NBS B EAV=120.9 7 - 95NB G 724.193 3 44.27 22M1+E2 0.001575 - 95NB2 G KC=0.00132 4$LC=1.47E-4 4$MC= + 95NB G 724.193 3 44.27 22M1+E2 0.00157 5 + 95NB2 G KC=0.00132 4$LC=1.47E-4 4 95NB L 756.732 127/2+ - 95NB B 368.1 1954.46 22 6.77 2 + 95NB B 368.1 1954.46 22 6.77 95NBS B EAV=109.7 7 - 95NB G 756.729 1254.38 22M1+E2 0.001424 - 95NB2 G KC=0.00120 4$LC=1.33E-4 4$MC= + 95NB G 756.729 1254.38 22M1+E2 0.00142 4 + 95NB2 G KC=0.00120 4$LC=1.33E-4 4 From e286a247bc0f3d39b7f4190dcf0457bd5ce04cf5 Mon Sep 17 00:00:00 2001 From: Reid Townson Date: Fri, 15 Jul 2016 11:15:34 -0400 Subject: [PATCH 06/34] Add electron capture and fix positron energies Add support for electron capture, and account for the balance between electron capture and positron emission. Also, calculate the positron emission energy in cases where it is not specified. --- HEN_HOUSE/egs++/egs_ensdf.cpp | 41 ++++++++++++++++++++++++--- HEN_HOUSE/egs++/egs_ensdf.h | 17 +++++++++-- HEN_HOUSE/egs++/egs_spectra.cpp | 50 ++++++++++++++++++++++++++------- 3 files changed, 91 insertions(+), 17 deletions(-) diff --git a/HEN_HOUSE/egs++/egs_ensdf.cpp b/HEN_HOUSE/egs++/egs_ensdf.cpp index d58bb6e61..ad19ca991 100644 --- a/HEN_HOUSE/egs++/egs_ensdf.cpp +++ b/HEN_HOUSE/egs++/egs_ensdf.cpp @@ -1082,13 +1082,24 @@ ParentRecord::ParentRecord(vector ensdf):Record(ensdf) { void ParentRecord::processEnsdf() { halfLife = parseHalfLife(40, 49); - printf("ParentRecord::processEnsdf: %f\n", halfLife); + + // Ground state Q-value in keV + // (total energy available for g.s. -> g.s. transition + // It will always be a positive number + // We convert to MeV + Q = recordToDouble(65, 74) / 1000; + + printf("ParentRecord::processEnsdf: %f %f\n", halfLife, Q); } double ParentRecord::getHalfLife() const { return halfLife; } +double ParentRecord::getQ() const { + return Q; +} + const ParentRecord *ParentRecordLeaf::getParentRecord() const { return getBranch(); } @@ -1283,14 +1294,32 @@ BetaPlusRecord::BetaPlusRecord(vector ensdf, void BetaPlusRecord::processEnsdf() { finalEnergy = recordToDouble(10, 19) / 1000; // Convert keV to MeV - betaIntensity = recordToDouble(22, 29); + positronIntensity = recordToDouble(22, 29); ecIntensity = recordToDouble(32, 39); if (getNormalizationRecord()) { - betaIntensity *= getNormalizationRecord()->getBetaMultiplier() * + positronIntensity *= getNormalizationRecord()->getBetaMultiplier() * + getNormalizationRecord()->getBranchMultiplier(); + ecIntensity *= getNormalizationRecord()->getBetaMultiplier() * getNormalizationRecord()->getBranchMultiplier(); } + + // The total intensity for this decay branch + // A decay down this branch will then be split between positron or EC + betaIntensity = positronIntensity + ecIntensity; + + // Re-normalize the intensities to make it easier to sample which occurs + positronIntensity = positronIntensity / betaIntensity; + ecIntensity = positronIntensity + ecIntensity / betaIntensity; + + // For positrons we may need to calculate the emission energy + // E = Q - level_energy - 2*mc^2 + if(finalEnergy == 0 && positronIntensity > 0) { + finalEnergy = getParentRecord()->getQ() + - getLevelRecord()->getEnergy() - 1.022; + } + printf("BetaPlusRecord::processEnsdf: %f %f %f\n", finalEnergy, - betaIntensity, ecIntensity); + positronIntensity, ecIntensity); } double BetaPlusRecord::getFinalEnergy() const { @@ -1301,6 +1330,10 @@ double BetaPlusRecord::getBetaIntensity() const { return betaIntensity; } +double BetaPlusRecord::getPositronIntensity() const { + return positronIntensity; +} + double BetaPlusRecord::getECIntensity() const { return ecIntensity; } diff --git a/HEN_HOUSE/egs++/egs_ensdf.h b/HEN_HOUSE/egs++/egs_ensdf.h index b6192077c..e47c3dbc1 100644 --- a/HEN_HOUSE/egs++/egs_ensdf.h +++ b/HEN_HOUSE/egs++/egs_ensdf.h @@ -185,9 +185,11 @@ class ParentRecord : public Record, public Branch > { public: ParentRecord(vector ensdf); double getHalfLife() const; + double getQ() const; protected: - double halfLife; + double halfLife, + Q; private: void processEnsdf(); @@ -255,6 +257,8 @@ class BetaRecordLeaf : public Record, public ParentRecordLeaf, public virtual double getFinalEnergy() const = 0; virtual double getBetaIntensity() const = 0; + virtual double getPositronIntensity() const {}; + virtual double getECIntensity() const {}; virtual void setBetaIntensity(double newIntensity) = 0; int getCharge() const; void incrNumSampled(); @@ -298,12 +302,14 @@ class BetaPlusRecord : public BetaRecordLeaf { double getFinalEnergy() const; double getBetaIntensity() const; + double getPositronIntensity() const; double getECIntensity() const; void setBetaIntensity(double newIntensity); void setECIntensity(double newIntensity); protected: - double ecIntensity; + double ecIntensity, + positronIntensity; private: void processEnsdf(); @@ -367,7 +373,12 @@ class AlphaRecord : public Record, public ParentRecordLeaf, public \ingroup egspp_main - ... add description here + Reads in a decay spectrum file in ensdf format, and builds the decays into an + object oriented tree structure. This decay structure is useful for + \ref EGS_RadionuclideSpectrum. + + Uncertainties on values are ignored! The energies and intensities for various + emissions are taken as is. */ class EGS_EXPORT EGS_Ensdf { diff --git a/HEN_HOUSE/egs++/egs_spectra.cpp b/HEN_HOUSE/egs++/egs_spectra.cpp index 61bf71ae4..90cbba098 100644 --- a/HEN_HOUSE/egs++/egs_spectra.cpp +++ b/HEN_HOUSE/egs++/egs_spectra.cpp @@ -24,6 +24,7 @@ # Author: Iwan Kawrakow, 2005 # # Contributors: Frederic Tessier +# Reid Townson # ############################################################################### */ @@ -467,7 +468,13 @@ class EGS_EXPORT EGS_RadionuclideBetaSpectrum { for (vector::iterator beta = myBetas.begin(); beta != myBetas.end(); beta++) { - + + // Skip electron capture records since they don't emit a particle + if((*beta)->getCharge() == 1 && + (*beta)->getPositronIntensity() == 0) { + continue; + } + printf("EGS_RadionuclideBetaSpectrum: Energy, Z, A, forbidden: %f " "%d %d %d\n", (*beta)->getFinalEnergy(), (*beta)->getZ(), @@ -483,7 +490,7 @@ class EGS_EXPORT EGS_RadionuclideBetaSpectrum { double de, s_y, s_sr, factor, e1, e2, se_y, se_sr; int isrc; - ncomps=1; // if we increase this, then we must fill the remainder + ncomps=1; // if we increase this, then we must fill the remainder area[0]=1.0; rel[0]=1.0; @@ -942,6 +949,9 @@ class EGS_EXPORT EGS_RadionuclideSpectrum : public EGS_BaseSpectrum { // The energy of the sampled particle EGS_Float E; + //TODO: Maybe need to adjust particle weights?? to account for + // intensities that give >1 particle per decay? + // If the daughter is in an excited state // Check for transitions if (currentLevel && currentLevel->getEnergy() > 0) { @@ -957,7 +967,10 @@ class EGS_EXPORT EGS_RadionuclideSpectrum : public EGS_BaseSpectrum { (*gamma)->incrNumSampled(); currentQ = (*gamma)->getCharge(); - + + // Update the current time by sampling how long + // it took for this transition to occur + // time += halflife / ln(2) * log(u) currentTime += currentLevel->getHalfLife() / 0.693147180559945309417232121458176568075500134360255254120680009493393 * log(rndm->getUniform()); @@ -978,23 +991,40 @@ class EGS_EXPORT EGS_RadionuclideSpectrum : public EGS_BaseSpectrum { // Uniformly distribute decays over the experiment time currentTime = rndm->getUniform() * Tmax; + // ============================ // Sample which decay occurs - // Betas + // ============================ + + // Beta-, beta+ and electron capture for (vector::iterator beta = myBetas.begin(); beta != myBetas.end(); beta++) { if (u < (*beta)->getBetaIntensity()) { (*beta)->incrNumSampled(); currentQ = (*beta)->getCharge(); - + // Set the energy level of the daughter currentLevel = (*beta)->getLevelRecord(); - - // TODO: Need to implement electron capture - - // For now just uniform up to max! - //E = u * (*beta)->getFinalEnergy(); + + // For beta+ records we decide between + // branches for beta+ or electron capture + if(currentQ == 1) { + // For positron emission, continue as usual + if(rndm->getUniform() < + (*beta)->getPositronIntensity()) { + + + // For electron capture, there is no emitted particle + // (only a neutrino) + // so we return a 0 energy particle + } else { + return 0; + } + } + + // Sample the energy from the spectrum alias table E = (*beta)->getSpectrum()->sample(rndm); + //printf("\nEGS_RadionuclideSpectrum: E: %f\n",E); return E; From c68ab3961d1f6b3ed172990c85ebe0a92a9bb17e Mon Sep 17 00:00:00 2001 From: Reid Townson Date: Tue, 26 Jul 2016 14:48:45 -0400 Subject: [PATCH 07/34] Fix beta spectrum floating point errors Fix a floating point error bug in beta spectrum generation. The results now agree with the original Fortran code. The dependency on the GNU Scientific Library (GSL) has been removed. --- HEN_HOUSE/egs++/egs_spectra.cpp | 362 ++++++++++++++++++++------------ 1 file changed, 226 insertions(+), 136 deletions(-) diff --git a/HEN_HOUSE/egs++/egs_spectra.cpp b/HEN_HOUSE/egs++/egs_spectra.cpp index 90cbba098..d681318f0 100644 --- a/HEN_HOUSE/egs++/egs_spectra.cpp +++ b/HEN_HOUSE/egs++/egs_spectra.cpp @@ -43,9 +43,6 @@ #include "egs_ensdf.h" #include "egs_application.h" -#include -#include - #include #include "egs_math.h" #include @@ -57,7 +54,9 @@ #define S_STREAM std::istrstream #endif +#include #include +//#include using namespace std; @@ -448,14 +447,11 @@ class EGS_EXPORT EGS_TabulatedSpectrum : public EGS_BaseSpectrum { * * \ingroup egspp_main * + * Based on code by L. VanderZwan March 7, 1985 + * + * Patrick Saull improved the code and ported from fortran to c++ in 2014 * - * L. VanderZwan - * March 7,1985. - * Oct. 14,1994 Converted to Microsoft Fortran v5.1 - * PRBS, August 2002. Convert to subroutine for sampling spectrum. - * PRBS, SEPT 2003. Make double precision. replace (ln)gamma calls with - * cernlib calls - * PRBS 7 Oct, 2014 - port to C++ ! + * Reid Townson integrated spectrum generation into egs++ in 2016 */ class EGS_EXPORT EGS_RadionuclideBetaSpectrum { @@ -468,18 +464,18 @@ class EGS_EXPORT EGS_RadionuclideBetaSpectrum { for (vector::iterator beta = myBetas.begin(); beta != myBetas.end(); beta++) { - + // Skip electron capture records since they don't emit a particle - if((*beta)->getCharge() == 1 && + if ((*beta)->getCharge() == 1 && (*beta)->getPositronIntensity() == 0) { continue; } - - printf("EGS_RadionuclideBetaSpectrum: Energy, Z, A, forbidden: %f " - "%d %d %d\n", - (*beta)->getFinalEnergy(), (*beta)->getZ(), - (*beta)->getAtomicWeight(), (*beta)->getForbidden() - ); + + egsInformation("EGS_RadionuclideBetaSpectrum: " + "Energy, Z, A, forbidden: %f %d %d %d\n", + (*beta)->getFinalEnergy(), (*beta)->getZ(), + (*beta)->getAtomicWeight(), (*beta)->getForbidden() + ); const int nbin=1000; EGS_Float *e = new EGS_Float [nbin]; @@ -499,6 +495,12 @@ class EGS_EXPORT EGS_RadionuclideBetaSpectrum { rmass = (*beta)->getAtomicWeight(); lamda[0] = (*beta)->getForbidden(); + // For positrons from zzz negative (just how the spectrum code + // was designed) + if ((*beta)->getCharge() == 1) { + zzz[0] *= -1; + } + etop[0]=emax; // prbs july 9, 2007 moved here from before src loop. @@ -511,11 +513,11 @@ class EGS_EXPORT EGS_RadionuclideBetaSpectrum { e1=0.001; // may be too low for some spectra (e.g. Tl-204) de=((int)(etop[0]*10.0+1)/10.)/nbin; // round up to nearest 100kev; // /= NBIN -// cout << "Binwidth " << de << endl; + //cout << "Binwidth " << de << endl; for (int ib=0; ibsetSpectrum(bspec); + + // Write the spectrum to a file + // This is just intended to be temporary to test the + // spectrum generation code + ostringstream ostr; + ostr << decays->radionuclide << "_d_" << emax << ".spec"; + + ofstream specStream; + specStream.open(ostr.str().c_str()); + for (int ib=0; ib cgamma(complex z) { static const int g=7; static const double pi = 3.1415926535897932384626433832795028841972; static const double p[g+2] = {0.99999999999980993, 676.5203681218851, - -1259.1392167224028, 771.32342877765313, -176.61502916214059, - 12.507343278686905, -0.13857109526572012, 9.9843695780195716e-6, + -1259.1392167224028, + 771.32342877765313, + -176.61502916214059, + 12.507343278686905, + -0.13857109526572012, + 9.9843695780195716e-6, 1.5056327351493116e-7 }; if (real(z)<0.5) { - return pi / (sin(pi*z)*cgamma(1.0-z)); + return pi / (sin(pi*z)*cgamma(double(1.0)-z)); } z -= 1.0; @@ -565,8 +584,91 @@ class EGS_EXPORT EGS_RadionuclideBetaSpectrum { for (int i=1; i(i,0)); } - complex t = z + (g + 0.5); - return sqrt(2*pi) * pow(t,z+0.5) * exp(-t) * x; + complex t = z + (g + double(0.5)); + + return double(sqrt(2.*pi)) * pow(t,z+double(0.5)) * exp(-t) * x; + } + + complex clgamma(complex z) { + complex u, v, h, p, r; + + static const double pi = 3.1415926535897932384626433832795028841972; + static const double c1 = 9.189385332046727e-1; + static const double c2 = 1.144729885849400; + static const double c[10] = {8.333333333333333e-2, + -2.777777777777777e-3, + 7.936507936507936e-4, + -5.952380952380952e-4, + 8.417508417508417e-4, + -1.917526917526917e-3, + 6.410256410256410e-3, + -2.955065359477124e-2, + 1.796443723688305e-1, + -1.392432216905901 + }; + + static const double hf = 0.5; + + double x = real(z); + double y = imag(z); + h = 0; + + if (y == 0 && -abs(x) == int(x)) { + return 0; + } + else { + double ya = abs(y); + if (x < 0) { + u = double(1.) - complex(x, ya); + } + else { + u = complex(x, ya); + } + + h = 0; + double ur = real(u); + double ui, a; + if (ur < 7.) { + ui = imag(u); + a = atan2(ui,ur); + h = u; + for (int i=1; i<=6-int(ur); i++) { + ur = ur + 1; + u = complex(ur, ui); + h = h * u; + a = a + atan2(ui, ur); + } + h = complex(hf * log(pow(real(h),2) + pow(imag(h),2)), + a); + + u = double(1.) + u; + } + + r = double(1.) / pow(u,2); + p = r * c[9]; + + for (int i=8; i>=1; i--) { + p = r * (c[i] + p); + } + + h = c1 + (u-hf)*log(u) - u + (c[0]+p) / u - h; + + if (x < 0.) { + ur = double(int(x)) - 1.; + ui = pi * (x-ur); + x = pi * ya; + double t = exp(-x-x); + a = sin(ui); + t = x + hf * log(t*pow(a,2)+pow(hf*(1.-t),2)); + a = atan2(cos(ui)*tanh(x),a) - ur*pi; + h = c2 - complex(t,a) - h; + } + if (y < 0) { + h = conj(h); + } + } + + return h; } void slfact(double p, double z, double radf, double xl[4]) { @@ -577,41 +679,23 @@ class EGS_EXPORT EGS_RadionuclideBetaSpectrum { complex aa; - pi=acos(-1.0); - c137=137.036; // 1/ fine structure constant - az=z/c137; - g1=sqrt(1.0-az*az); - w =sqrt(p*p+1.0); - rad=radf/386.159; - pr=p*rad; - y =az*w/p; + pi = acos(-1.0); + c137= 137.036; // 1/ fine structure constant + az = z/c137; + g1 = sqrt(1.0-az*az); + w = sqrt(p*p+1.0); + rad = radf/386.159; + pr = p*rad; + y = az*w/p; for (int k=1; k<=4; k++) { - gk=sqrt(k*k-az*az); - x1=pow((pow(p,k-1)/dfac[k-1]) ,2); - - // Fortran original was: - // aa=complex(gk,y) - // aa=clgama(aa) ! (using CERNLIB's log gamma function) - // ! for complex arguments - // Now use gnu scientific library's function: - // int gsl_sf_lngamma_complex_e (double zr, double zi, - // gsl_sf_result * lnr, gsl_sf_result * arg) - // returned pars are lnr = \log|\Gamma(z)| - // arg = \arg(\Gamma(z)) in (-\pi,\pi]. - // If we assume the Gamma function has complex form Rexp(i*phi) - // then log(Gamma) is just log(R) + i*phi. The former is purely real - // and the latter purely imaginary, hence the last two arguments - // return the real and the imaginary parts of ln(gamma(aa)), and it - // is only the former which is used below. - // Note that gsl_sf_result is a structure with elements val and err. - - gsl_sf_result gr_aa_real, gr_aa_imag; - gsl_sf_lngamma_complex_e(gk, y, &gr_aa_real, &gr_aa_imag); - double aa_real=gr_aa_real.val; - - // Now use cmath's lgamma function + gk = sqrt(k*k-az*az); + x1 = pow((pow(p,k-1)/dfac[k-1]) ,2); + + aa = clgamma(complex(gk,y)); + double aa_real = real(aa); + bb=lgamma((double)k); cc=lgamma(2.0*k +1.0); dd=lgamma(2.0*gk+1.0); @@ -658,30 +742,33 @@ class EGS_EXPORT EGS_RadionuclideBetaSpectrum { double pi,c137,zab,v,z,x,w,psq,p,y,qsq,g,cab,f,radf; double xl[4]; - complex c,a; + complex c; + complex a; bspec=0.0; if (e>emax) { return; } - pi=acos(-1.); + pi =acos(-1.); c137=137.036; // 1/ fine structure constant - zab=abs(zz); - v=1.13*pow(zab,1.333)/pow(c137,2); // Screening correction - v=copysign(v,zz); - z=zab/c137; - x=sqrt(1.0-z*z); // s parameter - w=1.0+(e/0.51097)-v; // Total energy of b particle - if (w<1.00001) { - w=1.00001; - } - psq= w*w-1.0; - p =sqrt(psq); // Momemtum of beta particle - y = z*w/p; // eta = alpha * z * e / p - y =copysign(y,zz); - qsq=3.83*pow(emax-e,2); + zab = abs(zz); + v = 1.13*pow(zab,1.333)/pow(c137,2); // Screening correction + v = copysign(v,zz); + z = zab/c137; + x = sqrt(1.0-z*z); // s parameter + w = 1.0+(e/0.51097)-v; // Total energy of b particle + if (w<1.0000001) { + bspec = 0.; + return; + } + //if(w<1.00001) w=1.00001; + psq = w*w-double(1.0); + p = sqrt(psq); // Momemtum of beta particle + y = z*w/p; // eta = alpha * z * e / p + y = copysign(y,zz); + qsq = 3.83*pow(emax-e,2); if (e <= 1.0e-5) { g=0.0; // Low energy approximation @@ -690,69 +777,71 @@ class EGS_EXPORT EGS_RadionuclideBetaSpectrum { } } else { - a=complex(x,y); - c=cgamma(a); - cab=abs(c); - f=pow(psq,x-1.0)*exp(pi*y)*pow(cab,2); - g=f*p*w*qsq; + a = complex(x,y); + c = cgamma(a); + cab = abs(c); + f = pow(psq,x-1.0)*exp(pi*y)*pow(cab,2); + g = f*p*w*qsq; } - factor=1.0; // Necessary to calculate kurie plot (not done) - bspec=g; + factor = 1.0; // Necessary to calculate kurie plot (not done) + bspec = g; if (lam == 0) { return; } - radf=1.2*pow(rmass,0.333); // Nuclear radius + radf = 1.2*pow(rmass,0.333); // Nuclear radius slfact(p,zz,radf,xl); if (lam==1) { - bspec=g*(qsq*xl[0]+9.0*xl[1]); + bspec = g*(qsq*xl[0]+9.0*xl[1]); return; } else if (lam==2) { - bspec=g*(pow(qsq,2)*xl[0]+30.0*qsq*xl[1]+225.0*xl[2]); + bspec = g*(pow(qsq,2)*xl[0]+30.0*qsq*xl[1]+225.0*xl[2]); return; } else if (lam==3) { - bspec=g*(pow(qsq,3.0)*xl[0]+63.0*pow(qsq,2)*xl[1]+ - 1575.0*qsq*xl[2] + 11025.0*xl[3]); + bspec = g*(pow(qsq,3.0)*xl[0]+63.0*pow(qsq,2)*xl[1]+ + 1575.0*qsq*xl[2] + 11025.0*xl[3]); return; } else { // lam==4 + //TODO: Currently no isotopes will get here + // Fudge factors for nuclides whose experimental spectra don't // seem to fit theory. // for cl36 (ref: nuc. phys. 99a, 625,(67)) if (zab == 18.0) { - bspec=bspec*(qsq*xl[0]+20.07*xl[1]); + bspec = bspec*(qsq*xl[0]+20.07*xl[1]); } // for i129 (ref: phys. rev. 95, 458, 54)) if (zab == 54.) { - bspec=bspec*(psq+10.0*qsq); + bspec = bspec*(psq+10.0*qsq); } // for cs-ba137 (ref: nuc. phys. 112a, 156, (68)) if (zab == 56.) { - bspec=bspec*(qsq*xl[0]+0.045*xl[1]); + bspec = bspec*(qsq*xl[0]+0.045*xl[1]); } // for tl204 (ref: can. j. phys., 45, 2621, (67)) if (zab == 82.) { - bspec=bspec*(1.0-1.677*e+ 2.77*e*e); + bspec = bspec*(1.0-1.677*e+ 2.77*e*e); } // for bi210 (ref: nuc. phys., 31, 293, (62)) if (zab == 84.) { - bspec=bspec*(1.78-2.35*e+e*e); + bspec = bspec*(1.78-2.35*e+e*e); } return; } } - + // Sums weighted, normalized spectral components to give total spectrum void sp(double e, double &spec, double &factor) { @@ -760,11 +849,11 @@ class EGS_EXPORT EGS_RadionuclideBetaSpectrum { spec=0.0; for (int icomp=0; icompradionuclide.c_str()); - printf("========================\n"); - printf("Energy | Intensity per 100 emissions\n"); + egsInformation("\nSampled %s emissions:\n", decays->radionuclide.c_str()); + egsInformation("========================\n"); + egsInformation("Energy | Intensity per 100 emissions\n"); if (myBetas.size() > 0) { - printf("Beta records:\n"); + egsInformation("Beta records:\n"); } for (vector::iterator beta = myBetas.begin(); beta != myBetas.end(); beta++) { - printf("%f %f\n", (*beta)->getFinalEnergy(), - ((EGS_Float)(*beta)->getNumSampled()/ishower)*100); + egsInformation("%f %f\n", (*beta)->getFinalEnergy(), + ((EGS_Float)(*beta)->getNumSampled()/ishower)*100); } if (myAlphas.size() > 0) { - printf("Alpha records:\n"); + egsInformation("Alpha records:\n"); } for (vector::iterator alpha = myAlphas.begin(); alpha != myAlphas.end(); alpha++) { - printf("%f %f\n", (*alpha)->getFinalEnergy(), - ((EGS_Float)(*alpha)->getNumSampled()/ishower)*100); + egsInformation("%f %f\n", (*alpha)->getFinalEnergy(), + ((EGS_Float)(*alpha)->getNumSampled()/ishower)*100); } if (myGammas.size() > 0) { - printf("Gamma records:\n"); + egsInformation("Gamma records:\n"); } for (vector::iterator gamma = myGammas.begin(); gamma != myGammas.end(); gamma++) { - printf("%f %f\n", (*gamma)->getDecayEnergy(), - ((EGS_Float)(*gamma)->getNumSampled()/ishower)*100); + egsInformation("%f %f\n", (*gamma)->getDecayEnergy(), + ((EGS_Float)(*gamma)->getNumSampled()/ishower)*100); } if (xrayEnergies.size() > 0) { - printf("X-Ray records:\n"); + egsInformation("X-Ray records:\n"); } for (unsigned int i=0; i < xrayEnergies.size(); ++i) { - printf("%f %f\n", xrayEnergies[i], - ((EGS_Float)numSampledXRay[i]/ishower)*100); + egsInformation("%f %f\n", xrayEnergies[i], + ((EGS_Float)numSampledXRay[i]/ishower)*100); } if (augerEnergies.size() > 0) { - printf("Auger records:\n"); + egsInformation("Auger records:\n"); } for (unsigned int i=0; i < augerEnergies.size(); ++i) { - printf("%f %f\n", augerEnergies[i], - ((EGS_Float)numSampledAuger[i]/ishower)*100); + egsInformation("%f %f\n", augerEnergies[i], + ((EGS_Float)numSampledAuger[i]/ishower)*100); } - printf("\n"); + egsInformation("\n"); } protected: @@ -949,13 +1038,13 @@ class EGS_EXPORT EGS_RadionuclideSpectrum : public EGS_BaseSpectrum { // The energy of the sampled particle EGS_Float E; - //TODO: Maybe need to adjust particle weights?? to account for + //TODO: Maybe need to adjust particle weights?? to account for // intensities that give >1 particle per decay? - + // If the daughter is in an excited state // Check for transitions if (currentLevel && currentLevel->getEnergy() > 0) { -// printf("EGS_RadionuclideSpectrum:sample: excited daughter " +// egsInformation("EGS_RadionuclideSpectrum:sample: excited daughter " // "%f\n",currentLevel->getEnergy()); for (vector::iterator gamma = myGammas.begin(); @@ -967,7 +1056,7 @@ class EGS_EXPORT EGS_RadionuclideSpectrum : public EGS_BaseSpectrum { (*gamma)->incrNumSampled(); currentQ = (*gamma)->getCharge(); - + // Update the current time by sampling how long // it took for this transition to occur // time += halflife / ln(2) * log(u) @@ -994,7 +1083,7 @@ class EGS_EXPORT EGS_RadionuclideSpectrum : public EGS_BaseSpectrum { // ============================ // Sample which decay occurs // ============================ - + // Beta-, beta+ and electron capture for (vector::iterator beta = myBetas.begin(); beta != myBetas.end(); beta++) { @@ -1002,30 +1091,31 @@ class EGS_EXPORT EGS_RadionuclideSpectrum : public EGS_BaseSpectrum { (*beta)->incrNumSampled(); currentQ = (*beta)->getCharge(); - + // Set the energy level of the daughter currentLevel = (*beta)->getLevelRecord(); - + // For beta+ records we decide between // branches for beta+ or electron capture - if(currentQ == 1) { + if (currentQ == 1) { // For positron emission, continue as usual - if(rndm->getUniform() < + if (rndm->getUniform() < (*beta)->getPositronIntensity()) { - - - // For electron capture, there is no emitted particle - // (only a neutrino) - // so we return a 0 energy particle - } else { + + + // For electron capture, there is no emitted particle + // (only a neutrino) + // so we return a 0 energy particle + } + else { return 0; } } - + // Sample the energy from the spectrum alias table E = (*beta)->getSpectrum()->sample(rndm); - - //printf("\nEGS_RadionuclideSpectrum: E: %f\n",E); + + //egsInformation("\nEGS_RadionuclideSpectrum: E: %f\n",E); return E; } From 2b39e5d5cb4260f5a7442b62673dbf5e1e08d493 Mon Sep 17 00:00:00 2001 From: Reid Townson Date: Mon, 8 Aug 2016 11:39:00 -0400 Subject: [PATCH 08/34] Fix minor bugs in radionuclide source Fix a bug in calculating the time delay of emissions for the case when no half-life is given. Also add some failure conditions related to positron emissions. Change printf to egsInformation or egsWarning. --- HEN_HOUSE/egs++/egs_ensdf.cpp | 111 +++++++++++++++++++------------- HEN_HOUSE/egs++/egs_ensdf.h | 2 - HEN_HOUSE/egs++/egs_spectra.cpp | 16 +++-- 3 files changed, 77 insertions(+), 52 deletions(-) diff --git a/HEN_HOUSE/egs++/egs_ensdf.cpp b/HEN_HOUSE/egs++/egs_ensdf.cpp index ad19ca991..6b2607f45 100644 --- a/HEN_HOUSE/egs++/egs_ensdf.cpp +++ b/HEN_HOUSE/egs++/egs_ensdf.cpp @@ -47,9 +47,9 @@ EGS_Ensdf::EGS_Ensdf(const string isotope, const string ensdf_filename) { // The parent element //string element = radionuclide.substr(0, radionuclide.find("-")); - printf("EGS_Ensdf::EGS_Ensdf: Isotope: " + egsInformation("EGS_Ensdf::EGS_Ensdf: Isotope: " "%s\n",isotope.c_str()); - printf("EGS_Ensdf::EGS_Ensdf: Now loading ensdf file: " + egsInformation("EGS_Ensdf::EGS_Ensdf: Now loading ensdf file: " "\"%s\"\n",ensdf_filename.c_str()); ensdf_file.open(ensdf_filename.c_str(),ios::in); @@ -177,7 +177,7 @@ void EGS_Ensdf::parseEnsdf(vector ensdf) { for (vector::iterator it = ensdf.begin(); it!=ensdf.end(); it++) { string line = *it; - printf("ENSDF::parseEnsdf: %s\n", line.c_str()); + egsInformation("ENSDF::parseEnsdf: %s\n", line.c_str()); // Identification if (line[6]==' ' && line[7]==' ' && line[8]==' ') { @@ -300,7 +300,7 @@ void EGS_Ensdf::parseEnsdf(vector ensdf) { // states of the daughter, we will treat this gamma as an xray // The halflife will be ignored if (!(*it)->getLevelRecord()) { - printf("EGS_Ensdf::parseEnsdf: Switching gamma with unknown " + egsInformation("EGS_Ensdf::parseEnsdf: Switching gamma with unknown " "level to X-Ray for non-correlated sampling\n"); xrayEnergies.push_back((*it)->getDecayEnergy()); xrayIntensities.push_back((*it)->getTransitionIntensity()); @@ -311,11 +311,11 @@ void EGS_Ensdf::parseEnsdf(vector ensdf) { } for (unsigned int i=0; i < xrayEnergies.size(); ++i) { - printf("EGS_Ensdf::parseEnsdf: XRays (E,I): %f %f\n", + egsInformation("EGS_Ensdf::parseEnsdf: XRays (E,I): %f %f\n", xrayEnergies[i], xrayIntensities[i]); } for (unsigned int i=0; i < augerEnergies.size(); ++i) { - printf("EGS_Ensdf::parseEnsdf: Auger (E,I): %f %f\n", + egsInformation("EGS_Ensdf::parseEnsdf: Auger (E,I): %f %f\n", augerEnergies[i], augerIntensities[i]); } } @@ -336,7 +336,7 @@ void EGS_Ensdf::buildRecords() { } for (int i = 0; i < recordStack.size(); i++) { -// printf("EGS_Ensdf::buildRecords:test %d\n",i); +// egsInformation("EGS_Ensdf::buildRecords:test %d\n",i); if (!recordStack[i].empty()) { if (i==0) { @@ -379,7 +379,7 @@ void EGS_Ensdf::buildRecords() { LastNormalization, LastLevel)); } else if (i==11) { - printf("EGS_Ensdf::buildRecords: Warning: Delayed particle not " + egsInformation("EGS_Ensdf::buildRecords: Warning: Delayed particle not " "supported! Further development required.\n"); } else if (i==12) { @@ -401,7 +401,7 @@ void EGS_Ensdf::normalizeIntensities() { for (vector::iterator beta = myBetaRecords.begin(); beta != myBetaRecords.end(); beta++) { - printf("EGS_Ensdf::normalizeIntensities: Beta (E,I): %f %f\n", + egsInformation("EGS_Ensdf::normalizeIntensities: Beta (E,I): %f %f\n", (*beta)->getFinalEnergy(), (*beta)->getBetaIntensity()); totalDecayIntensity += (*beta)->getBetaIntensity(); @@ -409,25 +409,25 @@ void EGS_Ensdf::normalizeIntensities() { for (vector::iterator alpha = myAlphaRecords.begin(); alpha != myAlphaRecords.end(); alpha++) { - printf("EGS_Ensdf::normalizeIntensities: Alpha (E,I): %f %f\n", + egsInformation("EGS_Ensdf::normalizeIntensities: Alpha (E,I): %f %f\n", (*alpha)->getFinalEnergy(), (*alpha)->getAlphaIntensity()); totalDecayIntensity += (*alpha)->getAlphaIntensity(); } for (unsigned int i=0; i < xrayIntensities.size(); ++i) { - printf("EGS_Ensdf::normalizeIntensities: XRay (E,I): %f %f\n", + egsInformation("EGS_Ensdf::normalizeIntensities: XRay (E,I): %f %f\n", xrayEnergies[i], xrayIntensities[i]); totalDecayIntensity += xrayIntensities[i]; } for (unsigned int i=0; i < augerIntensities.size(); ++i) { - printf("EGS_Ensdf::normalizeIntensities: Auger (E,I): %f %f\n", + egsInformation("EGS_Ensdf::normalizeIntensities: Auger (E,I): %f %f\n", augerEnergies[i], augerIntensities[i]); totalDecayIntensity += augerIntensities[i]; } - printf("EGS_Ensdf::normalizeIntensities: totalDecayIntensity: " + egsInformation("EGS_Ensdf::normalizeIntensities: totalDecayIntensity: " "%f\n",totalDecayIntensity); // Normalize beta emission intensities @@ -443,7 +443,7 @@ void EGS_Ensdf::normalizeIntensities() { } lastIntensity = (*beta)->getBetaIntensity(); - printf("EGS_Ensdf::normalizeIntensities: Beta (E,I): %f %f\n", + egsInformation("EGS_Ensdf::normalizeIntensities: Beta (E,I): %f %f\n", (*beta)->getFinalEnergy(), (*beta)->getBetaIntensity()); } @@ -506,7 +506,7 @@ void EGS_Ensdf::normalizeIntensities() { if ((*gamma)->getLevelRecord() == (*it)) { totalLevelIntensity[j] += (*gamma)->getTransitionIntensity(); - printf("EGS_Ensdf::normalizeIntensities: %d %f %f\n", j, + egsInformation("EGS_Ensdf::normalizeIntensities: %d %f %f\n", j, (*gamma)->getTransitionIntensity(), totalLevelIntensity[j]); } @@ -525,9 +525,11 @@ void EGS_Ensdf::normalizeIntensities() { if ((*gamma)->getLevelRecord() == (*it)) { - (*gamma)->setTransitionIntensity( - (*gamma)->getTransitionIntensity() / - totalLevelIntensity[j]); + if(totalLevelIntensity[j] > 0.) { + (*gamma)->setTransitionIntensity( + (*gamma)->getTransitionIntensity() / + totalLevelIntensity[j]); + } if (i > 0) { (*gamma)->setTransitionIntensity( @@ -536,7 +538,7 @@ void EGS_Ensdf::normalizeIntensities() { } ++i; - printf("EGS_Ensdf::normalizeIntensities: Gamma intensities: " + egsInformation("EGS_Ensdf::normalizeIntensities: Gamma intensities: " "%f\n",(*gamma)->getTransitionIntensity()); } } @@ -549,11 +551,13 @@ void EGS_Ensdf::normalizeIntensities() { for (vector::iterator gamma = myGammaRecords.begin(); gamma != myGammaRecords.end(); gamma++) { + egsInformation("test0\n"); double energy = (*gamma)->getDecayEnergy(); + egsInformation("test1\n"); double guessedLevelEnergy = ((*gamma)->getLevelRecord()->getEnergy() - energy); - printf("EGS_Ensdf::normalizeIntensities: Gamma (LE,E,GE): " + egsInformation("EGS_Ensdf::normalizeIntensities: Gamma (LE,E,GE): " "%f %f %f\n",(*gamma)->getLevelRecord()->getEnergy(), energy, guessedLevelEnergy); @@ -572,7 +576,7 @@ void EGS_Ensdf::normalizeIntensities() { } } if (bestMatch == 1E10) { - printf("EGS_Ensdf::normalizeIntensities: Warning: Could not find a " + egsInformation("EGS_Ensdf::normalizeIntensities: Warning: Could not find a " "level with energy matching decay of gamma with energy E=%f, " "assuming ground state\n",energy); (*gamma)->setFinalLevel(myLevelRecords.front()); @@ -581,7 +585,7 @@ void EGS_Ensdf::normalizeIntensities() { (*gamma)->setFinalLevel(level); } - printf("EGS_Ensdf::normalizeIntensities: Gamma (final level E): " + egsInformation("EGS_Ensdf::normalizeIntensities: Gamma (final level E): " "%f\n",level->getEnergy()); } } @@ -671,7 +675,7 @@ void EGS_Ensdf::getEmissionsFromComments() { continue; } -// printf("EGS_Ensdf::getEmissionsFromComments: %s\n", +// egsInformation("EGS_Ensdf::getEmissionsFromComments: %s\n", // emissionLine.c_str()); string eStr = egsTrimString(line.substr(13, 15)); @@ -734,7 +738,7 @@ void EGS_Ensdf::getEmissionsFromComments() { } } -// printf("EGS_Ensdf::getEmissionsFromComments: (E,I) %f %f\n", +// egsInformation("EGS_Ensdf::getEmissionsFromComments: (E,I) %f %f\n", // energy, intensity); } } @@ -792,25 +796,33 @@ vector Record::getRecords() const { double Record::recordToDouble(int startPos, int endPos) { if (!lines.empty()) { + if(lines.front().length() < startPos) { + egsWarning("Record::recordToDouble: Warning: Record too short to " + "contain desired quantity\n"); + return -1; + } string record = lines.front().substr(startPos-1, endPos-startPos+1); return atof(record.c_str()); } else { - printf("Record::recordToDouble: Error: Record is empty\n"); + egsWarning("Record::recordToDouble: Error: Record is empty\n"); return -1; } } +// Parse a halflife from a record +// Converts the units to seconds +// Returns the halflife, or a negative number upon failure double Record::parseHalfLife(int startPos, int endPos) { if (lines.empty()) { - printf("Record::parseHalfLife: Error: Record is empty\n"); + egsWarning("Record::parseHalfLife: Error: Record is empty\n"); return -5; } string halfLifeStr = egsTrimString(lines.front().substr(startPos-1, endPos-startPos+1)); - printf("Record::parseHalfLife: %s\n", halfLifeStr.c_str()); + egsInformation("Record::parseHalfLife: %s\n", halfLifeStr.c_str()); // Return -1 for stable if (halfLifeStr.substr(0,5).compare("STABLE") == 0) { @@ -1082,14 +1094,21 @@ ParentRecord::ParentRecord(vector ensdf):Record(ensdf) { void ParentRecord::processEnsdf() { halfLife = parseHalfLife(40, 49); - + // Ground state Q-value in keV // (total energy available for g.s. -> g.s. transition // It will always be a positive number // We convert to MeV - Q = recordToDouble(65, 74) / 1000; + Q = recordToDouble(65, 74) / 1000.; - printf("ParentRecord::processEnsdf: %f %f\n", halfLife, Q); + // If the Q was not contained in the record it returned -1 + if(Q == -0.001) { + egsWarning("ParentRecord::processEnsdf: Warning: No Q-value given, any " + "positron records will give errors\n"); + Q = 0.; + } + + egsInformation("ParentRecord::processEnsdf: %f %f\n", halfLife, Q); } double ParentRecord::getHalfLife() const { @@ -1120,7 +1139,7 @@ void NormalizationRecord::processEnsdf() { normalizeTransition = recordToDouble(22, 29); normalizeBranch = recordToDouble(32, 39); normalizeBeta = recordToDouble(42, 49); - printf("NormalizationRecord::processEnsdf: %f %f %f %f\n", + egsInformation("NormalizationRecord::processEnsdf: %f %f %f %f\n", normalizeRelative, normalizeTransition, normalizeBranch, normalizeBeta); } @@ -1167,9 +1186,9 @@ LevelRecord::LevelRecord(vector ensdf):Record(ensdf) { } void LevelRecord::processEnsdf() { - energy = recordToDouble(10, 19) / 1000; // Convert keV to MeV + energy = recordToDouble(10, 19) / 1000.; // Convert keV to MeV halfLife = recordToDouble(40, 49); - printf("LevelRecord::processEnsdf: %f %f\n", energy, halfLife); + egsInformation("LevelRecord::processEnsdf: %f %f\n", energy, halfLife); } double LevelRecord::getEnergy() const { @@ -1261,13 +1280,13 @@ BetaMinusRecord::BetaMinusRecord(vector ensdf, } void BetaMinusRecord::processEnsdf() { - finalEnergy = recordToDouble(10, 19) / 1000; // Convert keV to MeV + finalEnergy = recordToDouble(10, 19) / 1000.; // Convert keV to MeV betaIntensity = recordToDouble(22, 29); if (getNormalizationRecord()) { betaIntensity *= getNormalizationRecord()->getBetaMultiplier() * getNormalizationRecord()->getBranchMultiplier(); } - printf("BetaMinusRecord::processEnsdf: %f %f\n", finalEnergy, + egsInformation("BetaMinusRecord::processEnsdf: %f %f\n", finalEnergy, betaIntensity); } @@ -1293,7 +1312,7 @@ BetaPlusRecord::BetaPlusRecord(vector ensdf, } void BetaPlusRecord::processEnsdf() { - finalEnergy = recordToDouble(10, 19) / 1000; // Convert keV to MeV + finalEnergy = recordToDouble(10, 19) / 1000.; // Convert keV to MeV positronIntensity = recordToDouble(22, 29); ecIntensity = recordToDouble(32, 39); if (getNormalizationRecord()) { @@ -1316,9 +1335,16 @@ void BetaPlusRecord::processEnsdf() { if(finalEnergy == 0 && positronIntensity > 0) { finalEnergy = getParentRecord()->getQ() - getLevelRecord()->getEnergy() - 1.022; + + if(finalEnergy < 0.) { + egsWarning("BetaPlusRecord::processEnsdf: Error: Final energy of " + "positron could not be calculated. Setting energy to zero!\n" + ); + finalEnergy = 0.; + } } - printf("BetaPlusRecord::processEnsdf: %f %f %f\n", finalEnergy, + egsInformation("BetaPlusRecord::processEnsdf: %f %f %f\n", finalEnergy, positronIntensity, ecIntensity); } @@ -1356,9 +1382,8 @@ GammaRecord::GammaRecord(vector ensdf, NormalizationRecord } void GammaRecord::processEnsdf() { - decayEnergy = recordToDouble(10, 19) / 1000; // Convert keV to MeV + decayEnergy = recordToDouble(10, 19) / 1000.; // Convert keV to MeV transitionIntensity = recordToDouble(22, 29); - halfLife = parseHalfLife(40, 49); if (getNormalizationRecord()) { transitionIntensity *= @@ -1366,8 +1391,8 @@ void GammaRecord::processEnsdf() { getNormalizationRecord()->getBranchMultiplier(); } - printf("GammaRecord::processEnsdf: %f %f %f\n", decayEnergy, - transitionIntensity, halfLife); + egsInformation("GammaRecord::processEnsdf: %f %f %f\n", decayEnergy, + transitionIntensity); } double GammaRecord::getDecayEnergy() const { @@ -1418,9 +1443,9 @@ AlphaRecord::AlphaRecord(vector ensdf, } void AlphaRecord::processEnsdf() { - finalEnergy = recordToDouble(10, 19) / 1000; // Convert keV to MeV + finalEnergy = recordToDouble(10, 19) / 1000.; // Convert keV to MeV alphaIntensity = recordToDouble(22, 29); - printf("AlphaRecord::processEnsdf: %f %f\n", finalEnergy, + egsInformation("AlphaRecord::processEnsdf: %f %f\n", finalEnergy, alphaIntensity); } diff --git a/HEN_HOUSE/egs++/egs_ensdf.h b/HEN_HOUSE/egs++/egs_ensdf.h index e47c3dbc1..8cfe5e004 100644 --- a/HEN_HOUSE/egs++/egs_ensdf.h +++ b/HEN_HOUSE/egs++/egs_ensdf.h @@ -328,7 +328,6 @@ class GammaRecord : public Record, public NormalizationRecordLeaf, public int getCharge() const; LevelRecord *getFinalLevel() const; void setFinalLevel(LevelRecord *newLevel); - double getHalfLife() const; void incrNumSampled(); EGS_I64 getNumSampled() const; @@ -336,7 +335,6 @@ class GammaRecord : public Record, public NormalizationRecordLeaf, public EGS_I64 numSampled; double decayEnergy; double transitionIntensity; - double halfLife; int q; LevelRecord *finalLevel; diff --git a/HEN_HOUSE/egs++/egs_spectra.cpp b/HEN_HOUSE/egs++/egs_spectra.cpp index d681318f0..68d2000cd 100644 --- a/HEN_HOUSE/egs++/egs_spectra.cpp +++ b/HEN_HOUSE/egs++/egs_spectra.cpp @@ -1060,9 +1060,12 @@ class EGS_EXPORT EGS_RadionuclideSpectrum : public EGS_BaseSpectrum { // Update the current time by sampling how long // it took for this transition to occur // time += halflife / ln(2) * log(u) - currentTime += currentLevel->getHalfLife() / - 0.693147180559945309417232121458176568075500134360255254120680009493393 - * log(rndm->getUniform()); + double hl = currentLevel->getHalfLife(); + if(hl > 0.) { + currentTime += currentLevel->getHalfLife() / + 0.693147180559945309417232121458176568075500134360255254120680009493393 + * log(rndm->getUniform()); + } currentLevel = (*gamma)->getFinalLevel(); @@ -1102,12 +1105,11 @@ class EGS_EXPORT EGS_RadionuclideSpectrum : public EGS_BaseSpectrum { if (rndm->getUniform() < (*beta)->getPositronIntensity()) { - + } + else { // For electron capture, there is no emitted particle // (only a neutrino) // so we return a 0 energy particle - } - else { return 0; } } @@ -1165,7 +1167,7 @@ class EGS_EXPORT EGS_RadionuclideSpectrum : public EGS_BaseSpectrum { } } - // Shouldn't get here + // Shouldn't get here if intensities are normalized correctly return 0; }; From e1eec7404c093ea3076e56c247338dede4620021 Mon Sep 17 00:00:00 2001 From: Reid Townson Date: Mon, 8 Aug 2016 16:36:01 -0400 Subject: [PATCH 09/34] Fix bugs for ENSDF gammas with no assigned level Fix two bugs in the EGS_Ensdf class. One where gammas with no assigned level were being assigned as x-rays but missing every other record. The other where two different parents in the ENSDF file resulted in unassigned gammas using the LevelRecord for the previous parent (instead of no assigned level). --- HEN_HOUSE/egs++/egs_base_source.h | 7 -- HEN_HOUSE/egs++/egs_ensdf.cpp | 164 ++++++++++++++++-------------- HEN_HOUSE/egs++/egs_ensdf.h | 45 ++++---- HEN_HOUSE/egs++/egs_spectra.cpp | 21 ++-- 4 files changed, 127 insertions(+), 110 deletions(-) diff --git a/HEN_HOUSE/egs++/egs_base_source.h b/HEN_HOUSE/egs++/egs_base_source.h index 8f19844d3..4e526f66e 100644 --- a/HEN_HOUSE/egs++/egs_base_source.h +++ b/HEN_HOUSE/egs++/egs_base_source.h @@ -133,13 +133,6 @@ class EGS_EXPORT EGS_BaseSource : public EGS_Object { EGS_Float &E, EGS_Float &wt, // energy and weight EGS_Vector &x, EGS_Vector &u) = 0; // position and direction -// virtual EGS_I64 getNextParticle(EGS_RandomGenerator *rndm, -// int &q, int &latch, // charge and latch -// EGS_Float &E, EGS_Float &wt, // energy and weight -// EGS_Vector &x, EGS_Vector &u, // position and direction -// EGS_I64 &ishower, EGS_Float &time -// ) {}; - /*! \brief Set the next simulation chunk to start at \a nstart and to consist of \a nrun particles. diff --git a/HEN_HOUSE/egs++/egs_ensdf.cpp b/HEN_HOUSE/egs++/egs_ensdf.cpp index 6b2607f45..a83c4c5a8 100644 --- a/HEN_HOUSE/egs++/egs_ensdf.cpp +++ b/HEN_HOUSE/egs++/egs_ensdf.cpp @@ -43,14 +43,14 @@ EGS_Ensdf::EGS_Ensdf(const string isotope, const string ensdf_filename) { } radionuclide = isotope.substr(0, isotope.find_last_of(".")); - + // The parent element //string element = radionuclide.substr(0, radionuclide.find("-")); egsInformation("EGS_Ensdf::EGS_Ensdf: Isotope: " - "%s\n",isotope.c_str()); + "%s\n",isotope.c_str()); egsInformation("EGS_Ensdf::EGS_Ensdf: Now loading ensdf file: " - "\"%s\"\n",ensdf_filename.c_str()); + "\"%s\"\n",ensdf_filename.c_str()); ensdf_file.open(ensdf_filename.c_str(),ios::in); if (!ensdf_file.is_open()) { @@ -68,7 +68,7 @@ EGS_Ensdf::EGS_Ensdf(const string isotope, const string ensdf_filename) { if (ensdf_file.is_open()) { ensdf_file.close(); } - + // Parse the ensdf data parseEnsdf(ensdf); } @@ -292,51 +292,61 @@ void EGS_Ensdf::parseEnsdf(vector ensdf) { // Search through the gamma records for any with unknown levels for (vector::iterator it = myGammaRecords.begin(); - it!=myGammaRecords.end(); it++) { + it!=myGammaRecords.end();) { // Some gamma may be emitted but the energy level is not known // This is reported in the lnhb data as decays from the -1 level // Since we cannot correlate the emission with a change of energy // states of the daughter, we will treat this gamma as an xray // The halflife will be ignored - if (!(*it)->getLevelRecord()) { + if ((*it)->getLevelRecord()->getEnergy() < 1e-10) { egsInformation("EGS_Ensdf::parseEnsdf: Switching gamma with unknown " - "level to X-Ray for non-correlated sampling\n"); + "level to X-Ray for non-correlated sampling\n"); xrayEnergies.push_back((*it)->getDecayEnergy()); xrayIntensities.push_back((*it)->getTransitionIntensity()); // Erase the gamma record object myGammaRecords.erase(it); } + else { + ++it; + } } for (unsigned int i=0; i < xrayEnergies.size(); ++i) { egsInformation("EGS_Ensdf::parseEnsdf: XRays (E,I): %f %f\n", - xrayEnergies[i], xrayIntensities[i]); + xrayEnergies[i], xrayIntensities[i]); } for (unsigned int i=0; i < augerEnergies.size(); ++i) { egsInformation("EGS_Ensdf::parseEnsdf: Auger (E,I): %f %f\n", - augerEnergies[i], augerIntensities[i]); + augerEnergies[i], augerIntensities[i]); } } // Create record objects from the arrays void EGS_Ensdf::buildRecords() { - ParentRecord *LastParent = 0; + ParentRecord *lastParent = 0; if (!myParentRecords.empty()) { - LastParent = myParentRecords.back(); + lastParent = myParentRecords.back(); } - NormalizationRecord *LastNormalization = 0; + NormalizationRecord *lastNormalization = 0; if (!myNormalizationRecords.empty()) { - LastNormalization = myNormalizationRecords.back(); + lastNormalization = myNormalizationRecords.back(); } - LevelRecord *LastLevel = 0; + LevelRecord *lastLevel; if (!myLevelRecords.empty()) { - LastLevel = myLevelRecords.back(); + if (!previousParent || previousParent == lastParent) { + lastLevel = myLevelRecords.back(); + } + else { + lastLevel = new LevelRecord(); + } + } + else { + lastLevel = new LevelRecord(); } for (int i = 0; i < recordStack.size(); i++) { -// egsInformation("EGS_Ensdf::buildRecords:test %d\n",i); if (!recordStack[i].empty()) { if (i==0) { @@ -358,33 +368,34 @@ void EGS_Ensdf::buildRecords() { } else if (i==6) { myNormalizationRecords.push_back(new - NormalizationRecord(recordStack[i], LastParent)); + NormalizationRecord(recordStack[i], lastParent)); } else if (i==7) { myLevelRecords.push_back(new LevelRecord(recordStack[i])); + previousParent = lastParent; } else if (i==8) { myBetaMinusRecords.push_back(new - BetaMinusRecord(recordStack[i], LastParent, - LastNormalization, LastLevel)); + BetaMinusRecord(recordStack[i], lastParent, + lastNormalization, lastLevel)); } else if (i==9) { myBetaPlusRecords.push_back(new - BetaPlusRecord(recordStack[i], LastParent, - LastNormalization, LastLevel)); + BetaPlusRecord(recordStack[i], lastParent, + lastNormalization, lastLevel)); } else if (i==10) { myAlphaRecords.push_back(new - AlphaRecord(recordStack[i], LastParent, - LastNormalization, LastLevel)); + AlphaRecord(recordStack[i], lastParent, + lastNormalization, lastLevel)); } else if (i==11) { egsInformation("EGS_Ensdf::buildRecords: Warning: Delayed particle not " - "supported! Further development required.\n"); + "supported! Further development required.\n"); } else if (i==12) { myGammaRecords.push_back(new - GammaRecord(recordStack[i], LastNormalization, LastLevel)); + GammaRecord(recordStack[i], lastNormalization, lastLevel)); } recordStack[i].clear(); @@ -402,7 +413,7 @@ void EGS_Ensdf::normalizeIntensities() { beta != myBetaRecords.end(); beta++) { egsInformation("EGS_Ensdf::normalizeIntensities: Beta (E,I): %f %f\n", - (*beta)->getFinalEnergy(), (*beta)->getBetaIntensity()); + (*beta)->getFinalEnergy(), (*beta)->getBetaIntensity()); totalDecayIntensity += (*beta)->getBetaIntensity(); } @@ -410,25 +421,25 @@ void EGS_Ensdf::normalizeIntensities() { alpha != myAlphaRecords.end(); alpha++) { egsInformation("EGS_Ensdf::normalizeIntensities: Alpha (E,I): %f %f\n", - (*alpha)->getFinalEnergy(), (*alpha)->getAlphaIntensity()); + (*alpha)->getFinalEnergy(), (*alpha)->getAlphaIntensity()); totalDecayIntensity += (*alpha)->getAlphaIntensity(); } for (unsigned int i=0; i < xrayIntensities.size(); ++i) { egsInformation("EGS_Ensdf::normalizeIntensities: XRay (E,I): %f %f\n", - xrayEnergies[i], xrayIntensities[i]); + xrayEnergies[i], xrayIntensities[i]); totalDecayIntensity += xrayIntensities[i]; } for (unsigned int i=0; i < augerIntensities.size(); ++i) { egsInformation("EGS_Ensdf::normalizeIntensities: Auger (E,I): %f %f\n", - augerEnergies[i], augerIntensities[i]); + augerEnergies[i], augerIntensities[i]); totalDecayIntensity += augerIntensities[i]; } egsInformation("EGS_Ensdf::normalizeIntensities: totalDecayIntensity: " - "%f\n",totalDecayIntensity); + "%f\n",totalDecayIntensity); // Normalize beta emission intensities for (vector::iterator beta = myBetaRecords.begin(); @@ -444,7 +455,7 @@ void EGS_Ensdf::normalizeIntensities() { lastIntensity = (*beta)->getBetaIntensity(); egsInformation("EGS_Ensdf::normalizeIntensities: Beta (E,I): %f %f\n", - (*beta)->getFinalEnergy(), (*beta)->getBetaIntensity()); + (*beta)->getFinalEnergy(), (*beta)->getBetaIntensity()); } // Normalize alpha emission intensities @@ -507,8 +518,8 @@ void EGS_Ensdf::normalizeIntensities() { if ((*gamma)->getLevelRecord() == (*it)) { totalLevelIntensity[j] += (*gamma)->getTransitionIntensity(); egsInformation("EGS_Ensdf::normalizeIntensities: %d %f %f\n", j, - (*gamma)->getTransitionIntensity(), - totalLevelIntensity[j]); + (*gamma)->getTransitionIntensity(), + totalLevelIntensity[j]); } } ++j; @@ -525,7 +536,7 @@ void EGS_Ensdf::normalizeIntensities() { if ((*gamma)->getLevelRecord() == (*it)) { - if(totalLevelIntensity[j] > 0.) { + if (totalLevelIntensity[j] > 0.) { (*gamma)->setTransitionIntensity( (*gamma)->getTransitionIntensity() / totalLevelIntensity[j]); @@ -539,7 +550,7 @@ void EGS_Ensdf::normalizeIntensities() { ++i; egsInformation("EGS_Ensdf::normalizeIntensities: Gamma intensities: " - "%f\n",(*gamma)->getTransitionIntensity()); + "%f\n",(*gamma)->getTransitionIntensity()); } } ++j; @@ -551,15 +562,13 @@ void EGS_Ensdf::normalizeIntensities() { for (vector::iterator gamma = myGammaRecords.begin(); gamma != myGammaRecords.end(); gamma++) { - egsInformation("test0\n"); double energy = (*gamma)->getDecayEnergy(); - egsInformation("test1\n"); double guessedLevelEnergy = ((*gamma)->getLevelRecord()->getEnergy() - energy); egsInformation("EGS_Ensdf::normalizeIntensities: Gamma (LE,E,GE): " - "%f %f %f\n",(*gamma)->getLevelRecord()->getEnergy(), - energy, guessedLevelEnergy); + "%f %f %f\n",(*gamma)->getLevelRecord()->getEnergy(), + energy, guessedLevelEnergy); double bestMatch = 1E10; LevelRecord *level; @@ -577,8 +586,8 @@ void EGS_Ensdf::normalizeIntensities() { } if (bestMatch == 1E10) { egsInformation("EGS_Ensdf::normalizeIntensities: Warning: Could not find a " - "level with energy matching decay of gamma with energy E=%f, " - "assuming ground state\n",energy); + "level with energy matching decay of gamma with energy E=%f, " + "assuming ground state\n",energy); (*gamma)->setFinalLevel(myLevelRecords.front()); } else { @@ -586,7 +595,7 @@ void EGS_Ensdf::normalizeIntensities() { } egsInformation("EGS_Ensdf::normalizeIntensities: Gamma (final level E): " - "%f\n",level->getEnergy()); + "%f\n",level->getEnergy()); } } @@ -780,6 +789,7 @@ vector EGS_Ensdf::getAlphaRecords() const { return myAlphaRecords; } +Record::Record() {}; Record::Record(vector ensdf) { if (!ensdf.empty()) { lines = ensdf; @@ -796,7 +806,7 @@ vector Record::getRecords() const { double Record::recordToDouble(int startPos, int endPos) { if (!lines.empty()) { - if(lines.front().length() < startPos) { + if (lines.front().length() < startPos) { egsWarning("Record::recordToDouble: Warning: Record too short to " "contain desired quantity\n"); return -1; @@ -916,7 +926,7 @@ double Record::parseHalfLife(int startPos, int endPos) { } unsigned short int Record::setZ(string id) { - + string element; for (unsigned int i=0; i < id.length(); ++i) { if (!isdigit(id[i])) { @@ -1058,7 +1068,7 @@ map Record::getElementMap() { } unsigned short int Record::findZ(string element) { - + transform(element.begin(), element.end(), element.begin(), ::toupper); map elementMap = getElementMap(); @@ -1100,14 +1110,14 @@ void ParentRecord::processEnsdf() { // It will always be a positive number // We convert to MeV Q = recordToDouble(65, 74) / 1000.; - + // If the Q was not contained in the record it returned -1 - if(Q == -0.001) { + if (Q == -0.001) { egsWarning("ParentRecord::processEnsdf: Warning: No Q-value given, any " "positron records will give errors\n"); Q = 0.; } - + egsInformation("ParentRecord::processEnsdf: %f %f\n", halfLife, Q); } @@ -1140,7 +1150,7 @@ void NormalizationRecord::processEnsdf() { normalizeBranch = recordToDouble(32, 39); normalizeBeta = recordToDouble(42, 49); egsInformation("NormalizationRecord::processEnsdf: %f %f %f %f\n", - normalizeRelative, normalizeTransition, normalizeBranch, normalizeBeta); + normalizeRelative, normalizeTransition, normalizeBranch, normalizeBeta); } // Multiplier for converting relative photon intensity to photons per 100 @@ -1181,7 +1191,12 @@ NormalizationRecordLeaf::NormalizationRecordLeaf(NormalizationRecord } // Level Record -LevelRecord::LevelRecord(vector ensdf):Record(ensdf) { +LevelRecord::LevelRecord() { + energy = 0; + halfLife = 0; +} +LevelRecord::LevelRecord(vector ensdf): + Record(ensdf) { processEnsdf(); } @@ -1216,23 +1231,24 @@ BetaRecordLeaf::BetaRecordLeaf(vector ensdf, NormalizationRecordLeaf(myNormalization), LevelRecordLeaf(myLevel), Record(ensdf) { - + numSampled = 0; - + // Set the Z and atomic weight for the daughter of this decay string id = egsRemoveWhite(lines.front().substr(0,5)); Z = setZ(id); - + string atomicWeight; for (unsigned int i=0; i < id.length(); ++i) { if (!isdigit(id[i])) { break; - } else { + } + else { atomicWeight.push_back(id[i]); } } A = atoi(atomicWeight.c_str()); - + // Get the forbiddenness string lambda; lambda.push_back(lines.front().at(77)); @@ -1266,7 +1282,7 @@ void BetaRecordLeaf::setSpectrum(EGS_AliasTable *bspec) { spectrum = bspec; } -EGS_AliasTable* BetaRecordLeaf::getSpectrum() const { +EGS_AliasTable *BetaRecordLeaf::getSpectrum() const { return spectrum; } @@ -1287,7 +1303,7 @@ void BetaMinusRecord::processEnsdf() { getNormalizationRecord()->getBranchMultiplier(); } egsInformation("BetaMinusRecord::processEnsdf: %f %f\n", finalEnergy, - betaIntensity); + betaIntensity); } double BetaMinusRecord::getFinalEnergy() const { @@ -1317,35 +1333,35 @@ void BetaPlusRecord::processEnsdf() { ecIntensity = recordToDouble(32, 39); if (getNormalizationRecord()) { positronIntensity *= getNormalizationRecord()->getBetaMultiplier() * - getNormalizationRecord()->getBranchMultiplier(); + getNormalizationRecord()->getBranchMultiplier(); ecIntensity *= getNormalizationRecord()->getBetaMultiplier() * - getNormalizationRecord()->getBranchMultiplier(); + getNormalizationRecord()->getBranchMultiplier(); } - + // The total intensity for this decay branch // A decay down this branch will then be split between positron or EC betaIntensity = positronIntensity + ecIntensity; - + // Re-normalize the intensities to make it easier to sample which occurs positronIntensity = positronIntensity / betaIntensity; ecIntensity = positronIntensity + ecIntensity / betaIntensity; - + // For positrons we may need to calculate the emission energy // E = Q - level_energy - 2*mc^2 - if(finalEnergy == 0 && positronIntensity > 0) { + if (finalEnergy == 0 && positronIntensity > 0) { finalEnergy = getParentRecord()->getQ() - - getLevelRecord()->getEnergy() - 1.022; - - if(finalEnergy < 0.) { + - getLevelRecord()->getEnergy() - 1.022; + + if (finalEnergy < 0.) { egsWarning("BetaPlusRecord::processEnsdf: Error: Final energy of " - "positron could not be calculated. Setting energy to zero!\n" - ); + "positron could not be calculated. Setting energy to zero!\n" + ); finalEnergy = 0.; } } - + egsInformation("BetaPlusRecord::processEnsdf: %f %f %f\n", finalEnergy, - positronIntensity, ecIntensity); + positronIntensity, ecIntensity); } double BetaPlusRecord::getFinalEnergy() const { @@ -1392,7 +1408,7 @@ void GammaRecord::processEnsdf() { } egsInformation("GammaRecord::processEnsdf: %f %f %f\n", decayEnergy, - transitionIntensity); + transitionIntensity); } double GammaRecord::getDecayEnergy() const { @@ -1427,10 +1443,6 @@ void GammaRecord::setFinalLevel(LevelRecord *newLevel) { finalLevel = newLevel; } -double GammaRecord::getHalfLife() const { - return halfLife; -} - // Alpha Record AlphaRecord::AlphaRecord(vector ensdf, ParentRecord *myParent, NormalizationRecord *myNormalization, @@ -1446,7 +1458,7 @@ void AlphaRecord::processEnsdf() { finalEnergy = recordToDouble(10, 19) / 1000.; // Convert keV to MeV alphaIntensity = recordToDouble(22, 29); egsInformation("AlphaRecord::processEnsdf: %f %f\n", finalEnergy, - alphaIntensity); + alphaIntensity); } double AlphaRecord::getFinalEnergy() const { diff --git a/HEN_HOUSE/egs++/egs_ensdf.h b/HEN_HOUSE/egs++/egs_ensdf.h index 8cfe5e004..5ae29ae50 100644 --- a/HEN_HOUSE/egs++/egs_ensdf.h +++ b/HEN_HOUSE/egs++/egs_ensdf.h @@ -109,51 +109,52 @@ template class Branch { template class Leaf { public: - Leaf(T *existingTree) { - tree = existingTree; - if (tree) { - tree->addLeaf(this); + Leaf(T *existingBranch) { + branch = existingBranch; + if (branch) { + branch->addLeaf(this); } } ~Leaf() { - if (tree) { - tree->removeLeaf(this); + if (branch) { + branch->removeLeaf(this); } - tree = 0; + branch = 0; } virtual T *getBranch() const { - return tree; + return branch; } void removeBranch() { - tree = 0; + branch = 0; } // A new == operator for this class bool operator== (const T &rhs) const { - if (tree==0 && rhs.tree==0) { + if (branch==0 && rhs.branch==0) { return true; } - else if ((tree==0) && rhs.tree!=0) { + else if ((branch==0) && rhs.branch!=0) { return false; } - else if ((tree!=0) && rhs.tree==0) { + else if ((branch!=0) && rhs.branch==0) { return false; } - else if (tree!=0 && rhs.tree!=0) { - return *tree == *(rhs.tree); + else if (branch!=0 && rhs.branch!=0) { + return *branch == *(rhs.branch); } } private: - T *tree; + T *branch; }; // The Record class class Record { public: + Record(); Record(vector ensdf); virtual ~Record(); vector getRecords() const; @@ -230,6 +231,7 @@ class NormalizationRecordLeaf : public Leaf { // Level Record class LevelRecord : public Record, public Branch > { public: + LevelRecord(); LevelRecord(vector ensdf); double getEnergy() const; double getHalfLife() const; @@ -267,7 +269,7 @@ class BetaRecordLeaf : public Record, public ParentRecordLeaf, public unsigned short int getAtomicWeight() const; unsigned short int getForbidden() const; void setSpectrum(EGS_AliasTable *bspec); - EGS_AliasTable* getSpectrum() const; + EGS_AliasTable *getSpectrum() const; protected: EGS_I64 numSampled; @@ -371,11 +373,11 @@ class AlphaRecord : public Record, public ParentRecordLeaf, public \ingroup egspp_main - Reads in a decay spectrum file in ensdf format, and builds the decays into an - object oriented tree structure. This decay structure is useful for + Reads in a decay spectrum file in ensdf format, and builds the decays into an + object oriented tree structure. This decay structure is useful for \ref EGS_RadionuclideSpectrum. - - Uncertainties on values are ignored! The energies and intensities for various + + Uncertainties on values are ignored! The energies and intensities for various emissions are taken as is. */ @@ -401,7 +403,7 @@ class EGS_EXPORT EGS_Ensdf { vector getXRayEnergies() const; vector getAugerIntensities() const; vector getAugerEnergies() const; - + string radionuclide; void normalizeIntensities(); @@ -438,6 +440,7 @@ class EGS_EXPORT EGS_Ensdf { xrayIntensities, augerEnergies, augerIntensities; + ParentRecord *previousParent; }; diff --git a/HEN_HOUSE/egs++/egs_spectra.cpp b/HEN_HOUSE/egs++/egs_spectra.cpp index 68d2000cd..460a31c31 100644 --- a/HEN_HOUSE/egs++/egs_spectra.cpp +++ b/HEN_HOUSE/egs++/egs_spectra.cpp @@ -56,7 +56,6 @@ #include #include -//#include using namespace std; @@ -907,6 +906,7 @@ class EGS_EXPORT EGS_RadionuclideSpectrum : public EGS_BaseSpectrum { Emax = 0; currentTime = 0; ishower = -1; // Start with ishower -1 so first shower has index 0 + totalGammaEnergy = 0; // Get the maximum energy for emissions for (vector::iterator beta = myBetas.begin(); @@ -1006,12 +1006,18 @@ class EGS_EXPORT EGS_RadionuclideSpectrum : public EGS_BaseSpectrum { if (myGammas.size() > 0) { egsInformation("Gamma records:\n"); } + EGS_I64 totalNumSampled = 0; for (vector::iterator gamma = myGammas.begin(); gamma != myGammas.end(); gamma++) { - + + totalNumSampled += (*gamma)->getNumSampled(); egsInformation("%f %f\n", (*gamma)->getDecayEnergy(), ((EGS_Float)(*gamma)->getNumSampled()/ishower)*100); } + if (myGammas.size() > 0) { + egsInformation("Average gamma energy: %f\n", + totalGammaEnergy / totalNumSampled); + } if (xrayEnergies.size() > 0) { egsInformation("X-Ray records:\n"); } @@ -1061,15 +1067,17 @@ class EGS_EXPORT EGS_RadionuclideSpectrum : public EGS_BaseSpectrum { // it took for this transition to occur // time += halflife / ln(2) * log(u) double hl = currentLevel->getHalfLife(); - if(hl > 0.) { + if (hl > 0.) { currentTime += currentLevel->getHalfLife() / - 0.693147180559945309417232121458176568075500134360255254120680009493393 - * log(rndm->getUniform()); + 0.693147180559945309417232121458176568075500134360255254120680009493393 + * log(rndm->getUniform()); } currentLevel = (*gamma)->getFinalLevel(); E = (*gamma)->getDecayEnergy(); + + totalGammaEnergy += E; return E; } @@ -1197,7 +1205,8 @@ class EGS_EXPORT EGS_RadionuclideSpectrum : public EGS_BaseSpectrum { EGS_Float currentTime, Emax, Tmax, - spectrumWeight; + spectrumWeight, + totalGammaEnergy; EGS_I64 ishower; EGS_RadionuclideBetaSpectrum *betaSpectra; From dfd2b4eb570550d81ed4656524c6bb4d1d12dd30 Mon Sep 17 00:00:00 2001 From: Reid Townson Date: Fri, 26 Aug 2016 15:17:09 -0400 Subject: [PATCH 10/34] Add documentation for the radionuclide source --- HEN_HOUSE/egs++/egs_ensdf.cpp | 9 ++- HEN_HOUSE/egs++/egs_ensdf.h | 55 +++++++++++---- HEN_HOUSE/egs++/egs_spectra.cpp | 67 +++++++++++++++++-- .../egs_radionuclide_source.h | 31 ++++++--- 4 files changed, 129 insertions(+), 33 deletions(-) diff --git a/HEN_HOUSE/egs++/egs_ensdf.cpp b/HEN_HOUSE/egs++/egs_ensdf.cpp index a83c4c5a8..c6963c13d 100644 --- a/HEN_HOUSE/egs++/egs_ensdf.cpp +++ b/HEN_HOUSE/egs++/egs_ensdf.cpp @@ -153,7 +153,7 @@ void EGS_Ensdf::parseEnsdf(vector ensdf) { /* IDs of recordStack * 0 Identification (not used) * 1 History (not used) - * 2 Q-value + * 2 Q-value(not used) * 3 Cross-Reference (not used) * 4 Comment * 5 Parent @@ -162,7 +162,7 @@ void EGS_Ensdf::parseEnsdf(vector ensdf) { * 8 Beta- * 9 EC + Beta+ * 10 Alpha - * 11 Delayed Particle + * 11 Delayed Particle (not used) * 12 Gamma * 13 Reference (not used) * */ @@ -611,6 +611,11 @@ void EGS_Ensdf::getEmissionsFromComments() { string line = (*comment)->getComment(); + //TODO: Maybe we should sample one of the energies instead of using + // an average, using equal probability. Then the emissions have a + // sensible energy rather than a non-physical one. But the way + // we currently do it is the same as the Lara data files + // Check for the end of multi-line records // and average them together if (line.length() < 48 || diff --git a/HEN_HOUSE/egs++/egs_ensdf.h b/HEN_HOUSE/egs++/egs_ensdf.h index 5ae29ae50..a86a80c83 100644 --- a/HEN_HOUSE/egs++/egs_ensdf.h +++ b/HEN_HOUSE/egs++/egs_ensdf.h @@ -368,29 +368,58 @@ class AlphaRecord : public Record, public ParentRecordLeaf, public void processEnsdf(); }; - -/*! \brief The ensdf class - - \ingroup egspp_main - - Reads in a decay spectrum file in ensdf format, and builds the decays into an - object oriented tree structure. This decay structure is useful for - \ref EGS_RadionuclideSpectrum. - - Uncertainties on values are ignored! The energies and intensities for various - emissions are taken as is. +/*! \brief The ensdf class for reading ensdf format data files + +\ingroup egspp_main + +Reads in a decay spectrum file in ensdf format, and builds the decays into an +object oriented tree structure. This decay structure is useful for +\ref EGS_RadionuclideSpectrum used by \ref EGS_RadionuclideSource. + +Uncertainties on values are ignored! The energies and intensities for various +emissions are taken as is. Very low intensities are not discarded, all +data is used. + +When processing an ensdf file, only the following records are considered: +Comment, Parent, Normalization, Level, Beta-, EC / Beta+, Alpha, Gamma. + +X-Rays and Auger emissions are obtained from Comment records. The data is +processed in the same way as Lara files on nucleide.org. If a single +intensity is present for a combination of lines (but a single energy is not +provided), then the average energy of the lines is used. For example, in the +case below a single line of energy 97.4527 keV would be used. +\verbatim +221FR T 96.815 |] XKB3 +221FR T 97.474 |] 0.57 5 XKB1 +221FR T 98.069 |] XKB5II +\endverbatim +If an energy and intensity are given for the total of several lines, it is +used instead of those lines. For example, in the case below a single line +of energy 14.0895 keV would be used. +\verbatim +221FR T 10.38-17.799 18.7 9 XL (total) +221FR T 10.38 XLL +221FR T 11.89-12.03 XLA +221FR T 13.254 XLC +221FR T 13.877-15.639 XLB +221FR T 16.752-17.799 XLG +\endverbatim + +The ensdf class has been tested on radionuclide data from +http://www.nucleide.org/DDEP_WG/DDEPdata.htm */ + class EGS_EXPORT EGS_Ensdf { public: - /*! \brief Construct an ensdf object + /*! \brief Construct an ensdf object. * */ EGS_Ensdf(const string isotope, const string ensdf_filename=""); - /*! \brief Destructor. Deallocates all allocated memory */ + /*! \brief Destructor. */ ~EGS_Ensdf(); vector getRecords() const; diff --git a/HEN_HOUSE/egs++/egs_spectra.cpp b/HEN_HOUSE/egs++/egs_spectra.cpp index 460a31c31..0cde7f8f4 100644 --- a/HEN_HOUSE/egs++/egs_spectra.cpp +++ b/HEN_HOUSE/egs++/egs_spectra.cpp @@ -442,15 +442,16 @@ class EGS_EXPORT EGS_TabulatedSpectrum : public EGS_BaseSpectrum { }; -/*! \brief Beta spectrum generation for radionuclide spectra +/*! \brief Beta spectrum generation for \link EGS_RadionuclideSpectrum + * radionuclide spectra \endlink * * \ingroup egspp_main * - * Based on code by L. VanderZwan March 7, 1985 + * Based on code by L. VanderZwan March 7, 1985. * - * Patrick Saull improved the code and ported from fortran to c++ in 2014 + * Patrick Saull improved the code and ported from fortran to c++ in 2014. * - * Reid Townson integrated spectrum generation into egs++ in 2016 + * Reid Townson integrated spectrum generation into egs++ in 2016. */ class EGS_EXPORT EGS_RadionuclideBetaSpectrum { @@ -864,11 +865,33 @@ class EGS_EXPORT EGS_RadionuclideBetaSpectrum { /*! \brief A radionuclide spectrum. - * - * \ingroup egspp_main - * +\ingroup egspp_main +Generates spectra for radionuclide emissions. This spectrum type is used by +\ref EGS_RadionuclideSource. +Currently spectrum data is obtained from ENSDF format data files. +These files can be found in $HEN_HOUSE/spectra/lnhb/. +The decay structure is created by \ref EGS_Ensdf. + +It is defined using the following input +\verbatim +:start spectrum: + type = radionuclide + isotope = name of the isotope (e.g. Sr-90), used to look up the + ensdf file as $HEN_HOUSE/spectra/lnhb/{isotope}.ensdf + if ensdf file not provided below + ensdf file = [optional] path to a spectrum file in ensdf format, + including extension + weight = [optional] the relative activity (sampling + probability) for this isotope in a mixture +:stop spectrum: +:start spectrum: + type = radionuclide + isotope = name of next isotope in mixture (e.g. Y-90) + weight = ... +:stop spectrum: +\endverbatim */ class EGS_EXPORT EGS_RadionuclideSpectrum : public EGS_BaseSpectrum { @@ -981,6 +1004,8 @@ class EGS_EXPORT EGS_RadionuclideSpectrum : public EGS_BaseSpectrum { spectrumWeight = newWeight; } + /*! \brief Print the sampled emission intensities. + */ void printSampledEmissions() { egsInformation("\nSampled %s emissions:\n", decays->radionuclide.c_str()); egsInformation("========================\n"); @@ -1036,6 +1061,30 @@ class EGS_EXPORT EGS_RadionuclideSpectrum : public EGS_BaseSpectrum { } protected: + /*! \brief Sample an event from the spectrum. + +Returns the energy of the emitted particle. + +Determines which emission type occurs, and proceeds to sample the +emission parameters. If the daughter isotope is +in an excited state, a transition gamma is emitted and +the daughter transitions to a lower energy state. If the daughter +isotope is not in an exited state, one of the following events occurs: + +Beta events may set the energy level of the daughter to an excited state. +Beta- and beta+ events emit an electron or positron, respectively. The energies +of beta particles are sampled from spectra generated by +\ref EGS_RadionuclideBetaSpectrum. Electron capture events are sampled, +but no particles are emitted. + +Alpha events may set the energy level of the daughter to an excited state. +Alpha events do not emit any particles. + +X-Ray events emit a photon from a sampled energy line. + +Auger events emit an electron from a sampled energy line. + + */ EGS_Float sample(EGS_RandomGenerator *rndm) { // Sample a uniform random number @@ -1179,10 +1228,14 @@ class EGS_EXPORT EGS_RadionuclideSpectrum : public EGS_BaseSpectrum { return 0; }; + /*! \brief Returns the maximum energy that may be emitted. + */ EGS_Float maxEnergy() const { return Emax; }; + /*! \brief Not implemented - returns 0. + */ EGS_Float expectedAverage() const { return 0; }; diff --git a/HEN_HOUSE/egs++/sources/egs_radionuclide_source/egs_radionuclide_source.h b/HEN_HOUSE/egs++/sources/egs_radionuclide_source/egs_radionuclide_source.h index 33a1849ff..356fc4e9c 100644 --- a/HEN_HOUSE/egs++/sources/egs_radionuclide_source/egs_radionuclide_source.h +++ b/HEN_HOUSE/egs++/sources/egs_radionuclide_source/egs_radionuclide_source.h @@ -31,7 +31,7 @@ /*! \file egs_radionuclide_source.h * \brief A radionuclide source - * \IK + * \RT */ #ifndef EGS_RADIONUCLIDE_SOURCE_ @@ -70,15 +70,17 @@ #endif -/*! \brief A radionuclide source +/*! \brief A radionuclide source. - \ingroup Sources +\ingroup Sources A radionuclide source is a source that delivers particles with directions uniformly distributed in \f$4 \pi\f$ emitted from -\link EGS_BaseShape any shape. Emissions are based on decays from the -radionuclide isotope and can be a mix of beta decays, X-radiations, etc. -\endlink +\link EGS_BaseShape any shape. \endlink + +Emissions are based on decays from the radionuclide isotope and can be a mix of +beta decays, X-radiations, etc. + It is defined using the following input \verbatim :start source: @@ -86,10 +88,10 @@ It is defined using the following input library = egs_radionuclide_source activity = total activity of mixture, assumed constant charge = list including at least one of -1, 0, 1 to -include electrons, photons and positrons + include electrons, photons and positrons geometry = my_geometry # see egs_isotropic_source region selection = geometry confinement option, one of IncludeAll, -ExcludeAll, IncludeSelected, ExcludeSelected + ExcludeAll, IncludeSelected, ExcludeSelected selected regions = regions to apply geometry confinement :start shape: definition of the shape @@ -97,10 +99,12 @@ ExcludeAll, IncludeSelected, ExcludeSelected :start spectrum: type = radionuclide isotope = name of the isotope (e.g. Sr-90), used to look up the -ensdf file in $HEN_HOUSE/spectra/lnhb if ensdf file not provided - ensdf file = [optional] path to a spectrum file in ensdf format + ensdf file as $HEN_HOUSE/spectra/lnhb/{isotope}.ensdf + if ensdf file not provided below + ensdf file = [optional] path to a spectrum file in ensdf format, + including extension weight = [optional] the relative activity (sampling -probability) for this isotope in a mixture + probability) for this isotope in a mixture :stop spectrum: :start spectrum: type = radionuclide @@ -110,6 +114,11 @@ probability) for this isotope in a mixture :stop source: \endverbatim +The emission spectrum generation is described in \ref EGS_RadionuclideSpectrum. + +Proceed with caution - \ref EGS_RadionuclideSource is in the development stages +and has not been thoroughly tested. + */ class EGS_RADIONUCLIDE_SOURCE_EXPORT EGS_RadionuclideSource : From 7ba2ce5d4c3762cebaabb2b3c6604c2cb09fae35 Mon Sep 17 00:00:00 2001 From: Reid Townson Date: Wed, 21 Sep 2016 12:25:16 -0400 Subject: [PATCH 11/34] Fix radionuclide fluence normalization The getFluence function in egs_radionuclide_source now returns the number of disintegrations (ishower) instead of the number of emissions (count). Also, the x-ray and Auger emissions are no longer treated as independent disintegrations. Instead, each disintegration has a chance of resulting in an x-ray and/or an Auger. --- HEN_HOUSE/egs++/egs_spectra.cpp | 11 ++++++----- .../egs_radionuclide_source/egs_radionuclide_source.h | 2 +- 2 files changed, 7 insertions(+), 6 deletions(-) diff --git a/HEN_HOUSE/egs++/egs_spectra.cpp b/HEN_HOUSE/egs++/egs_spectra.cpp index 0cde7f8f4..d39e4b31b 100644 --- a/HEN_HOUSE/egs++/egs_spectra.cpp +++ b/HEN_HOUSE/egs++/egs_spectra.cpp @@ -1093,9 +1093,6 @@ Auger events emit an electron from a sampled energy line. // The energy of the sampled particle EGS_Float E; - //TODO: Maybe need to adjust particle weights?? to account for - // intensities that give >1 particle per decay? - // If the daughter is in an excited state // Check for transitions if (currentLevel && currentLevel->getEnergy() > 0) { @@ -1134,8 +1131,6 @@ Auger events emit an electron from a sampled energy line. } } else { - // Incremember the shower number - ishower++; // Uniformly distribute decays over the experiment time currentTime = rndm->getUniform() * Tmax; @@ -1148,6 +1143,9 @@ Auger events emit an electron from a sampled energy line. for (vector::iterator beta = myBetas.begin(); beta != myBetas.end(); beta++) { if (u < (*beta)->getBetaIntensity()) { + + // Incremember the shower number + ishower++; (*beta)->incrNumSampled(); currentQ = (*beta)->getCharge(); @@ -1184,6 +1182,9 @@ Auger events emit an electron from a sampled energy line. for (vector::iterator alpha = myAlphas.begin(); alpha != myAlphas.end(); alpha++) { if (u < (*alpha)->getAlphaIntensity()) { + + // Incremember the shower number + ishower++; (*alpha)->incrNumSampled(); currentQ = (*alpha)->getCharge(); diff --git a/HEN_HOUSE/egs++/sources/egs_radionuclide_source/egs_radionuclide_source.h b/HEN_HOUSE/egs++/sources/egs_radionuclide_source/egs_radionuclide_source.h index 356fc4e9c..4b6e72848 100644 --- a/HEN_HOUSE/egs++/sources/egs_radionuclide_source/egs_radionuclide_source.h +++ b/HEN_HOUSE/egs++/sources/egs_radionuclide_source/egs_radionuclide_source.h @@ -181,7 +181,7 @@ class EGS_RADIONUCLIDE_SOURCE_EXPORT EGS_RadionuclideSource : }; EGS_Float getFluence() const { - return count; + return ishower; }; double getTime() const { From 882127db4269d050eafb28bfa1e33d962945a2fb Mon Sep 17 00:00:00 2001 From: Reid Townson Date: Fri, 23 Sep 2016 15:41:51 -0400 Subject: [PATCH 12/34] Update radionuclide source output messages --- .../egs_radionuclide_source/egs_radionuclide_source.cpp | 4 ++-- 1 file changed, 2 insertions(+), 2 deletions(-) diff --git a/HEN_HOUSE/egs++/sources/egs_radionuclide_source/egs_radionuclide_source.cpp b/HEN_HOUSE/egs++/sources/egs_radionuclide_source/egs_radionuclide_source.cpp index 3af21587e..110b340e5 100644 --- a/HEN_HOUSE/egs++/sources/egs_radionuclide_source/egs_radionuclide_source.cpp +++ b/HEN_HOUSE/egs++/sources/egs_radionuclide_source/egs_radionuclide_source.cpp @@ -97,7 +97,7 @@ EGS_RadionuclideSource::EGS_RadionuclideSource(EGS_Input *input, if (!err) { activity = tmp_A; } - egsWarning("EGS_RadionuclideSource: Activity [disintegrations/s]: %e\n", + egsInformation("EGS_RadionuclideSource: Activity [disintegrations/s]: %e\n", activity); // Calculate the duration of the experiment @@ -130,7 +130,7 @@ EGS_RadionuclideSource::EGS_RadionuclideSource(EGS_Input *input, } double Tmax = ncase_double / activity; - egsWarning("EGS_RadionuclideSource: Duration of experiment [s]: %e\n", + egsInformation("EGS_RadionuclideSource: Duration of experiment [s]: %e\n", Tmax); for (i=0; isetMaximumTime(Tmax); From 7d6b04172d609aa621a373d2b8a45a01422d7a45 Mon Sep 17 00:00:00 2001 From: Reid Townson Date: Fri, 30 Sep 2016 13:19:56 -0400 Subject: [PATCH 13/34] Fix several bugs in radionuclide source Fix a bug that occured when all gammas for a given excited daughter state had zero probability of emission. Fix a bug with electron capture where returning a zero energy particle threw off the particle count. Now getNextParticle() loops until it gets a particle with nonzero energy. Fix some floating point errors. Fix a bug where all x-rays had an energy 10 times too large. Remove the branch multiplier for ENSDF normalization records. I'm not sure if this is correct in general, but it works for the ENSDF files provided by LNHB, for now. Check for the existence of ENSDF files in order to exit gracefully. Use the 'charge' input correctly. Improve the sampling efficiency of getNextParticle(). Fix a bug in the fluence, which was off by 1. --- HEN_HOUSE/egs++/egs_ensdf.cpp | 87 +++++++++++++------ HEN_HOUSE/egs++/egs_ensdf.h | 7 +- HEN_HOUSE/egs++/egs_spectra.cpp | 73 +++++++++------- .../egs_radionuclide_source.cpp | 66 +++++++++++--- .../egs_radionuclide_source.h | 7 +- 5 files changed, 161 insertions(+), 79 deletions(-) diff --git a/HEN_HOUSE/egs++/egs_ensdf.cpp b/HEN_HOUSE/egs++/egs_ensdf.cpp index c6963c13d..e38975e42 100644 --- a/HEN_HOUSE/egs++/egs_ensdf.cpp +++ b/HEN_HOUSE/egs++/egs_ensdf.cpp @@ -54,8 +54,8 @@ EGS_Ensdf::EGS_Ensdf(const string isotope, const string ensdf_filename) { ensdf_file.open(ensdf_filename.c_str(),ios::in); if (!ensdf_file.is_open()) { - egsWarning("EGS_Ensdf::EGS_Ensdf: failed to open ensdf file %s" - " for reading\n",ensdf_filename.c_str()); + egsWarning("\nEGS_Ensdf::EGS_Ensdf: failed to open ensdf file %s" + " for reading\n\n",ensdf_filename.c_str()); return; } @@ -291,15 +291,23 @@ void EGS_Ensdf::parseEnsdf(vector ensdf) { getEmissionsFromComments(); // Search through the gamma records for any with unknown levels + // or with zero emission probability for (vector::iterator it = myGammaRecords.begin(); it!=myGammaRecords.end();) { - // Some gamma may be emitted but the energy level is not known - // This is reported in the lnhb data as decays from the -1 level - // Since we cannot correlate the emission with a change of energy - // states of the daughter, we will treat this gamma as an xray - // The halflife will be ignored - if ((*it)->getLevelRecord()->getEnergy() < 1e-10) { + if ((*it)->getTransitionIntensity() <= 0.) { + // Throw away gammas with zero probability + // Erase the gamma record object + myGammaRecords.erase(it); + + } + else if ((*it)->getLevelRecord()->getEnergy() < 1e-10) { + // Some gamma may be emitted but the energy level is not known + // This is reported in the lnhb data as decays from the -1 level + // Since we cannot correlate the emission with a change of energy + // states of the daughter, we will treat this gamma as an xray + // The halflife will be ignored + egsInformation("EGS_Ensdf::parseEnsdf: Switching gamma with unknown " "level to X-Ray for non-correlated sampling\n"); xrayEnergies.push_back((*it)->getDecayEnergy()); @@ -465,7 +473,7 @@ void EGS_Ensdf::normalizeIntensities() { (*alpha)->setAlphaIntensity( (*alpha)->getAlphaIntensity() / totalDecayIntensity); - if ((alpha - myAlphaRecords.begin()) == 0 && lastIntensity > 0) { + if ((alpha - myAlphaRecords.begin()) == 0 && lastIntensity > 1e-10) { (*alpha)->setAlphaIntensity( (*alpha)->getAlphaIntensity() + lastIntensity); } @@ -475,13 +483,16 @@ void EGS_Ensdf::normalizeIntensities() { (*(alpha-1))->getAlphaIntensity()); } lastIntensity = (*alpha)->getAlphaIntensity(); + + egsInformation("EGS_Ensdf::normalizeIntensities: Alpha (E,I): %f %f\n", + (*alpha)->getFinalEnergy(), (*alpha)->getAlphaIntensity()); } // Normalize XRay emission intensities for (unsigned int i=0; i < xrayIntensities.size(); ++i) { xrayIntensities[i] /= totalDecayIntensity; - if (i==0 && lastIntensity > 0) { + if (i==0 && lastIntensity > 1e-10) { xrayIntensities[i] += lastIntensity; } else if (i > 0) { @@ -494,7 +505,7 @@ void EGS_Ensdf::normalizeIntensities() { for (unsigned int i=0; i < augerIntensities.size(); ++i) { augerIntensities[i] /= totalDecayIntensity; - if (i==0 && lastIntensity > 0) { + if (i==0 && lastIntensity > 1e-10) { augerIntensities[i] += lastIntensity; } else if (i > 0) { @@ -531,12 +542,14 @@ void EGS_Ensdf::normalizeIntensities() { it!=myLevelRecords.end(); it++) { unsigned int i = 0; + bool levelCanDecay = false; for (vector::iterator gamma = myGammaRecords.begin(); gamma != myGammaRecords.end(); gamma++) { if ((*gamma)->getLevelRecord() == (*it)) { + levelCanDecay = true; - if (totalLevelIntensity[j] > 0.) { + if (totalLevelIntensity[j] > 1e-10) { (*gamma)->setTransitionIntensity( (*gamma)->getTransitionIntensity() / totalLevelIntensity[j]); @@ -553,6 +566,14 @@ void EGS_Ensdf::normalizeIntensities() { "%f\n",(*gamma)->getTransitionIntensity()); } } + + // Set whether or not the level can decay + // If there are no gammas that decay from this excited energy state, + // then it will effectively stay in this state forever + // In practice this means we don't have to sample for the emission of + // transition photons + (*it)->setLevelCanDecay(levelCanDecay); + ++j; } @@ -615,7 +636,7 @@ void EGS_Ensdf::getEmissionsFromComments() { // an average, using equal probability. Then the emissions have a // sensible energy rather than a non-physical one. But the way // we currently do it is the same as the Lara data files - + // Check for the end of multi-line records // and average them together if (line.length() < 48 || @@ -639,7 +660,7 @@ void EGS_Ensdf::getEmissionsFromComments() { } } for (unsigned int i=0; i < multilineIntensities.size(); ++i) { - if (multilineIntensities[i] > 0) { + if (multilineIntensities[i] > 1e-10) { intensitySum += multilineIntensities[i]; numNonzeroI++; } @@ -713,7 +734,7 @@ void EGS_Ensdf::getEmissionsFromComments() { } // Convert the energy from keV to MeV - energy /= 100; + energy /= 1000.; // Get the intensity string iStr = egsTrimString(line.substr(32, 9)); @@ -741,7 +762,7 @@ void EGS_Ensdf::getEmissionsFromComments() { } else { if (emissionLine.at(0) == 'X') { - if (energy > 0 && intensity > 0) { + if (energy > 1e-10 && intensity > 1e-10) { xrayEnergies.push_back(energy); xrayIntensities.push_back(intensity); } @@ -1211,6 +1232,14 @@ void LevelRecord::processEnsdf() { egsInformation("LevelRecord::processEnsdf: %f %f\n", energy, halfLife); } +void LevelRecord::setLevelCanDecay(bool canDecayTmp) { + canDecay = canDecayTmp; +} + +bool LevelRecord::levelCanDecay() const { + return canDecay; +} + double LevelRecord::getEnergy() const { return energy; } @@ -1304,8 +1333,9 @@ void BetaMinusRecord::processEnsdf() { finalEnergy = recordToDouble(10, 19) / 1000.; // Convert keV to MeV betaIntensity = recordToDouble(22, 29); if (getNormalizationRecord()) { - betaIntensity *= getNormalizationRecord()->getBetaMultiplier() * - getNormalizationRecord()->getBranchMultiplier(); +// betaIntensity *= getNormalizationRecord()->getBetaMultiplier() * +// getNormalizationRecord()->getBranchMultiplier(); + betaIntensity *= getNormalizationRecord()->getBetaMultiplier(); } egsInformation("BetaMinusRecord::processEnsdf: %f %f\n", finalEnergy, betaIntensity); @@ -1337,10 +1367,12 @@ void BetaPlusRecord::processEnsdf() { positronIntensity = recordToDouble(22, 29); ecIntensity = recordToDouble(32, 39); if (getNormalizationRecord()) { - positronIntensity *= getNormalizationRecord()->getBetaMultiplier() * - getNormalizationRecord()->getBranchMultiplier(); - ecIntensity *= getNormalizationRecord()->getBetaMultiplier() * - getNormalizationRecord()->getBranchMultiplier(); +// positronIntensity *= getNormalizationRecord()->getBetaMultiplier() * +// getNormalizationRecord()->getBranchMultiplier(); +// ecIntensity *= getNormalizationRecord()->getBetaMultiplier() * +// getNormalizationRecord()->getBranchMultiplier(); + positronIntensity *= getNormalizationRecord()->getBetaMultiplier(); + ecIntensity *= getNormalizationRecord()->getBetaMultiplier(); } // The total intensity for this decay branch @@ -1353,7 +1385,7 @@ void BetaPlusRecord::processEnsdf() { // For positrons we may need to calculate the emission energy // E = Q - level_energy - 2*mc^2 - if (finalEnergy == 0 && positronIntensity > 0) { + if (finalEnergy == 0 && positronIntensity > 1e-10) { finalEnergy = getParentRecord()->getQ() - getLevelRecord()->getEnergy() - 1.022; @@ -1407,12 +1439,13 @@ void GammaRecord::processEnsdf() { transitionIntensity = recordToDouble(22, 29); if (getNormalizationRecord()) { - transitionIntensity *= - getNormalizationRecord()->getRelativeMultiplier() * - getNormalizationRecord()->getBranchMultiplier(); +// transitionIntensity *= +// getNormalizationRecord()->getRelativeMultiplier() * +// getNormalizationRecord()->getBranchMultiplier(); + transitionIntensity *= getNormalizationRecord()->getRelativeMultiplier(); } - egsInformation("GammaRecord::processEnsdf: %f %f %f\n", decayEnergy, + egsInformation("GammaRecord::processEnsdf: %f %f\n", decayEnergy, transitionIntensity); } diff --git a/HEN_HOUSE/egs++/egs_ensdf.h b/HEN_HOUSE/egs++/egs_ensdf.h index a86a80c83..6afb55558 100644 --- a/HEN_HOUSE/egs++/egs_ensdf.h +++ b/HEN_HOUSE/egs++/egs_ensdf.h @@ -233,12 +233,15 @@ class LevelRecord : public Record, public Branch > { public: LevelRecord(); LevelRecord(vector ensdf); + void setLevelCanDecay(bool canDecay); + bool levelCanDecay() const; double getEnergy() const; double getHalfLife() const; protected: double energy; double halfLife; + bool canDecay; private: void processEnsdf(); @@ -387,7 +390,7 @@ X-Rays and Auger emissions are obtained from Comment records. The data is processed in the same way as Lara files on nucleide.org. If a single intensity is present for a combination of lines (but a single energy is not provided), then the average energy of the lines is used. For example, in the -case below a single line of energy 97.4527 keV would be used. +case below a single line of energy 97.4527 keV would be used. \verbatim 221FR T 96.815 |] XKB3 221FR T 97.474 |] 0.57 5 XKB1 @@ -405,7 +408,7 @@ of energy 14.0895 keV would be used. 221FR T 16.752-17.799 XLG \endverbatim -The ensdf class has been tested on radionuclide data from +The ensdf class has been tested on radionuclide data from http://www.nucleide.org/DDEP_WG/DDEPdata.htm */ diff --git a/HEN_HOUSE/egs++/egs_spectra.cpp b/HEN_HOUSE/egs++/egs_spectra.cpp index d39e4b31b..78261e84e 100644 --- a/HEN_HOUSE/egs++/egs_spectra.cpp +++ b/HEN_HOUSE/egs++/egs_spectra.cpp @@ -442,7 +442,7 @@ class EGS_EXPORT EGS_TabulatedSpectrum : public EGS_BaseSpectrum { }; -/*! \brief Beta spectrum generation for \link EGS_RadionuclideSpectrum +/*! \brief Beta spectrum generation for \link EGS_RadionuclideSpectrum * radionuclide spectra \endlink * * \ingroup egspp_main @@ -870,9 +870,9 @@ class EGS_EXPORT EGS_RadionuclideBetaSpectrum { Generates spectra for radionuclide emissions. This spectrum type is used by \ref EGS_RadionuclideSource. -Currently spectrum data is obtained from ENSDF format data files. -These files can be found in $HEN_HOUSE/spectra/lnhb/. -The decay structure is created by \ref EGS_Ensdf. +Currently spectrum data is obtained from ENSDF format data files. +These files can be found in $HEN_HOUSE/spectra/lnhb/. +The decay structure is created by \ref EGS_Ensdf. It is defined using the following input \verbatim @@ -1034,13 +1034,13 @@ class EGS_EXPORT EGS_RadionuclideSpectrum : public EGS_BaseSpectrum { EGS_I64 totalNumSampled = 0; for (vector::iterator gamma = myGammas.begin(); gamma != myGammas.end(); gamma++) { - + totalNumSampled += (*gamma)->getNumSampled(); egsInformation("%f %f\n", (*gamma)->getDecayEnergy(), ((EGS_Float)(*gamma)->getNumSampled()/ishower)*100); } if (myGammas.size() > 0) { - egsInformation("Average gamma energy: %f\n", + egsInformation("Average gamma energy: %f\n", totalGammaEnergy / totalNumSampled); } if (xrayEnergies.size() > 0) { @@ -1063,27 +1063,27 @@ class EGS_EXPORT EGS_RadionuclideSpectrum : public EGS_BaseSpectrum { protected: /*! \brief Sample an event from the spectrum. -Returns the energy of the emitted particle. + Returns the energy of the emitted particle. + + Determines which emission type occurs, and proceeds to sample the + emission parameters. If the daughter isotope is + in an excited state, a transition gamma is emitted and + the daughter transitions to a lower energy state. If the daughter + isotope is not in an exited state, one of the following events occurs: -Determines which emission type occurs, and proceeds to sample the -emission parameters. If the daughter isotope is -in an excited state, a transition gamma is emitted and -the daughter transitions to a lower energy state. If the daughter -isotope is not in an exited state, one of the following events occurs: + Beta events may set the energy level of the daughter to an excited state. + Beta- and beta+ events emit an electron or positron, respectively. The energies + of beta particles are sampled from spectra generated by + \ref EGS_RadionuclideBetaSpectrum. Electron capture events are sampled, + but no particles are emitted. -Beta events may set the energy level of the daughter to an excited state. -Beta- and beta+ events emit an electron or positron, respectively. The energies -of beta particles are sampled from spectra generated by -\ref EGS_RadionuclideBetaSpectrum. Electron capture events are sampled, -but no particles are emitted. + Alpha events may set the energy level of the daughter to an excited state. + Alpha events do not emit any particles. -Alpha events may set the energy level of the daughter to an excited state. -Alpha events do not emit any particles. + X-Ray events emit a photon from a sampled energy line. -X-Ray events emit a photon from a sampled energy line. + Auger events emit an electron from a sampled energy line. -Auger events emit an electron from a sampled energy line. - */ EGS_Float sample(EGS_RandomGenerator *rndm) { @@ -1095,9 +1095,7 @@ Auger events emit an electron from a sampled energy line. // If the daughter is in an excited state // Check for transitions - if (currentLevel && currentLevel->getEnergy() > 0) { -// egsInformation("EGS_RadionuclideSpectrum:sample: excited daughter " -// "%f\n",currentLevel->getEnergy()); + if (currentLevel && currentLevel->levelCanDecay() && currentLevel->getEnergy() > 1e-10) { for (vector::iterator gamma = myGammas.begin(); gamma != myGammas.end(); gamma++) { @@ -1113,7 +1111,7 @@ Auger events emit an electron from a sampled energy line. // it took for this transition to occur // time += halflife / ln(2) * log(u) double hl = currentLevel->getHalfLife(); - if (hl > 0.) { + if (hl > 1e-10) { currentTime += currentLevel->getHalfLife() / 0.693147180559945309417232121458176568075500134360255254120680009493393 * log(rndm->getUniform()); @@ -1122,7 +1120,7 @@ Auger events emit an electron from a sampled energy line. currentLevel = (*gamma)->getFinalLevel(); E = (*gamma)->getDecayEnergy(); - + totalGammaEnergy += E; return E; @@ -1143,7 +1141,7 @@ Auger events emit an electron from a sampled energy line. for (vector::iterator beta = myBetas.begin(); beta != myBetas.end(); beta++) { if (u < (*beta)->getBetaIntensity()) { - + // Incremember the shower number ishower++; @@ -1157,8 +1155,7 @@ Auger events emit an electron from a sampled energy line. // branches for beta+ or electron capture if (currentQ == 1) { // For positron emission, continue as usual - if (rndm->getUniform() < - (*beta)->getPositronIntensity()) { + if ((*beta)->getPositronIntensity() > 1e-10 && rndm->getUniform() < (*beta)->getPositronIntensity()) { } else { @@ -1172,8 +1169,6 @@ Auger events emit an electron from a sampled energy line. // Sample the energy from the spectrum alias table E = (*beta)->getSpectrum()->sample(rndm); - //egsInformation("\nEGS_RadionuclideSpectrum: E: %f\n",E); - return E; } } @@ -1182,7 +1177,7 @@ Auger events emit an electron from a sampled energy line. for (vector::iterator alpha = myAlphas.begin(); alpha != myAlphas.end(); alpha++) { if (u < (*alpha)->getAlphaIntensity()) { - + // Incremember the shower number ishower++; @@ -1667,6 +1662,18 @@ EGS_BaseSpectrum *EGS_BaseSpectrum::createSpectrum(EGS_Input *input) { } ensdf_file = egsJoinPath(ensdf_file.c_str(),isotope.append(".txt")); } + + // Check that the ensdf file exists + ifstream ensdf_fh; + ensdf_fh.open(ensdf_file.c_str(),ios::in); + if (!ensdf_fh.is_open()) { + egsWarning("EGS_BaseSpectrum::createSpectrum: failed to open ensdf file %s" + " for reading\n",ensdf_file.c_str()); + return 0; + } + ensdf_fh.close(); + + // Create the spectrum spec = new EGS_RadionuclideSpectrum(isotope, ensdf_file, weight); } else { diff --git a/HEN_HOUSE/egs++/sources/egs_radionuclide_source/egs_radionuclide_source.cpp b/HEN_HOUSE/egs++/sources/egs_radionuclide_source/egs_radionuclide_source.cpp index 110b340e5..903cab385 100644 --- a/HEN_HOUSE/egs++/sources/egs_radionuclide_source/egs_radionuclide_source.cpp +++ b/HEN_HOUSE/egs++/sources/egs_radionuclide_source/egs_radionuclide_source.cpp @@ -46,13 +46,25 @@ EGS_RadionuclideSource::EGS_RadionuclideSource(EGS_Input *input, activity(0) { int err; - - // TODO: Make use of q_allowed to reject particles? vector tmp_q; err = input->getInput("charge", tmp_q); if (!err) { + if (std::find(q_allowed.begin(), q_allowed.end(), -1) != q_allowed.end() + && std::find(q_allowed.begin(), q_allowed.end(), 0) != q_allowed.end() + && std::find(q_allowed.begin(), q_allowed.end(), 1) != q_allowed.end()) { + q_allowAll = true; + } + else { + q_allowAll = false; + } q_allowed = tmp_q; } + else { + q_allowAll = true; + q_allowed.push_back(-1); + q_allowed.push_back(1); + q_allowed.push_back(0); + } // Create the decay spectra count = 0; @@ -62,8 +74,11 @@ EGS_RadionuclideSource::EGS_RadionuclideSource(EGS_Input *input, while (input->getInputItem("spectrum")) { decays.push_back(EGS_BaseSpectrum::createSpectrum(input)); + + // If spectrum creation failed skip to the next spectrum block if (!decays[i]) { - break; + decays.pop_back(); + continue; } EGS_Float spectrumMaxE = decays[i]->maxEnergy(); @@ -76,7 +91,8 @@ EGS_RadionuclideSource::EGS_RadionuclideSource(EGS_Input *input, ++i; } if (decays.size() < 1) { - egsWarning("EGS_RadionuclideSource: no spectrum was defined\n"); + egsWarning("EGS_RadionuclideSource: Error: No spectrum was defined\n"); + return; } // Normalize the spectrum weights @@ -97,8 +113,11 @@ EGS_RadionuclideSource::EGS_RadionuclideSource(EGS_Input *input, if (!err) { activity = tmp_A; } + else { + activity = 1; + } egsInformation("EGS_RadionuclideSource: Activity [disintegrations/s]: %e\n", - activity); + activity); // Calculate the duration of the experiment // Based on ncase and activity @@ -131,7 +150,7 @@ EGS_RadionuclideSource::EGS_RadionuclideSource(EGS_Input *input, double Tmax = ncase_double / activity; egsInformation("EGS_RadionuclideSource: Duration of experiment [s]: %e\n", - Tmax); + Tmax); for (i=0; isetMaximumTime(Tmax); } @@ -218,19 +237,38 @@ EGS_I64 EGS_RadionuclideSource::getNextParticle(EGS_RandomGenerator *rndm, int &q, int &latch, EGS_Float &E, EGS_Float &wt, EGS_Vector &x, EGS_Vector &u) { - // Sample a uniform random number - EGS_Float uRand = rndm->getUniform(); + unsigned int i = 0; + if (decays.size() > 1) { + // Sample a uniform random number + EGS_Float uRand = rndm->getUniform(); + + // Sample which spectrum to use + for (i=0; igetSpectrumWeight()) { + break; + } + } + } - // Sample which spectrum to use - unsigned int i; - for (i=0; igetSpectrumWeight()) { + for (EGS_I64 j=0; j<1e6; ++j) { + + E = decays[i]->sampleEnergy(rndm); + + if (E < 1e-10) { + continue; + } + + q = decays[i]->getCharge(); + + // Check if the charge is allowed + // If so, break out of the loop and keep the particle + // Otherwise the loop will continue generating particles until + // one matches the q_allowed criteria + if (q_allowAll || std::find(q_allowed.begin(), q_allowed.end(), q) != q_allowed.end()) { break; } } - E = decays[i]->sampleEnergy(rndm); - q = decays[i]->getCharge(); time = decays[i]->getTime(); ishower = decays[i]->getShowerIndex(); diff --git a/HEN_HOUSE/egs++/sources/egs_radionuclide_source/egs_radionuclide_source.h b/HEN_HOUSE/egs++/sources/egs_radionuclide_source/egs_radionuclide_source.h index 4b6e72848..bdbdc1ab4 100644 --- a/HEN_HOUSE/egs++/sources/egs_radionuclide_source/egs_radionuclide_source.h +++ b/HEN_HOUSE/egs++/sources/egs_radionuclide_source/egs_radionuclide_source.h @@ -78,7 +78,7 @@ A radionuclide source is a source that delivers particles with directions uniformly distributed in \f$4 \pi\f$ emitted from \link EGS_BaseShape any shape. \endlink -Emissions are based on decays from the radionuclide isotope and can be a mix of +Emissions are based on decays from the radionuclide isotope and can be a mix of beta decays, X-radiations, etc. It is defined using the following input @@ -117,7 +117,7 @@ It is defined using the following input The emission spectrum generation is described in \ref EGS_RadionuclideSpectrum. Proceed with caution - \ref EGS_RadionuclideSource is in the development stages -and has not been thoroughly tested. +and has not been thoroughly tested. */ @@ -181,7 +181,7 @@ class EGS_RADIONUCLIDE_SOURCE_EXPORT EGS_RadionuclideSource : }; EGS_Float getFluence() const { - return ishower; + return ishower+1; }; double getTime() const { @@ -381,6 +381,7 @@ class EGS_RADIONUCLIDE_SOURCE_EXPORT EGS_RadionuclideSource : vector decays; //!< The radionuclide decay structure vector q_allowed; + bool q_allowAll; EGS_Float activity; double time; EGS_I64 ishower; From 61ad23d76ef56ec2eb685d6fad4a768a96c378b3 Mon Sep 17 00:00:00 2001 From: Reid Townson Date: Tue, 11 Oct 2016 13:47:59 -0400 Subject: [PATCH 14/34] Fix radionuclide normalization, update ENSDF data Throw away gammas, betas and alphas with probability less than 1e-6. Fix a bug for gamma transitions where the transition intensities don't add up to unity for a level. In these cases, there is now a chance for no gamma transition to occur, instead of forcing a transition. Add alphas to the list of charges that can be included in the input for the radionuclide sources. Update the ENSDF data with the October 4, 2016 version from LNHB. Fix what appears to be a mistake in the LNHB Tc-99m ENSDF data file. The branch normalization value was changed. Reinstate branch normalization for beta, alpha and gamma emission intensities. --- HEN_HOUSE/egs++/egs_ensdf.cpp | 155 ++++--- HEN_HOUSE/egs++/egs_ensdf.h | 3 + HEN_HOUSE/egs++/egs_spectra.cpp | 186 ++++---- .../egs_radionuclide_source.cpp | 27 +- .../egs_radionuclide_source.h | 10 +- HEN_HOUSE/spectra/lnhb/Am-244m.txt | 6 +- HEN_HOUSE/spectra/lnhb/Br-76.txt | 402 ++++++++++++++++++ HEN_HOUSE/spectra/lnhb/Np-236m.txt | 6 +- HEN_HOUSE/spectra/lnhb/Tc-94m.txt | 58 +-- HEN_HOUSE/spectra/lnhb/Tc-99m.txt | 2 +- 10 files changed, 659 insertions(+), 196 deletions(-) create mode 100644 HEN_HOUSE/spectra/lnhb/Br-76.txt diff --git a/HEN_HOUSE/egs++/egs_ensdf.cpp b/HEN_HOUSE/egs++/egs_ensdf.cpp index e38975e42..b5fd98460 100644 --- a/HEN_HOUSE/egs++/egs_ensdf.cpp +++ b/HEN_HOUSE/egs++/egs_ensdf.cpp @@ -28,6 +28,7 @@ ############################################################################### */ + /*! \file egs_ensdf.cpp * \brief The ensdf implementation * \RT @@ -178,90 +179,91 @@ void EGS_Ensdf::parseEnsdf(vector ensdf) { string line = *it; egsInformation("ENSDF::parseEnsdf: %s\n", line.c_str()); - // Identification + if (line[6]==' ' && line[7]==' ' && line[8]==' ') { + // Identification - // History } else if (line[6]==' ' && line[7]=='H' && line[8]==' ') { + // History - // Q-value } else if (line[6]== ' ' && line[7]=='Q' && line[8]==' ') { + // Q-value - // Cross-Reference } else if (line[6]==' ' && line[7]=='X') { + // Cross-Reference - // Comment } else if ((line[6]=='C' || line[6]=='D' || line[6]=='T' || line[6]=='c' || line[6]=='d' || line[6]=='t')) { + // Comment if (line[5]==' ') { buildRecords(); } recordStack[4].push_back(line); - //Parent } else if (line[6]==' ' && line[7]=='P') { + //Parent if (line[5]==' ') { buildRecords(); } recordStack[5].push_back(line); - // Normalization } else if (line[6]==' ' && line[7]=='N') { + // Normalization if (line[5]==' ') { buildRecords(); } recordStack[6].push_back(line); - // Level } if (line[6]==' ' && line[7]=='L' && line[8]== ' ') { + // Level if (line[5]==' ') { buildRecords(); } recordStack[7].push_back(line); - // Beta- } else if (line[6]==' ' && line[7]=='B' && line[8]==' ') { + // Beta- if (line[5]==' ') { buildRecords(); } recordStack[8].push_back(line); - // Beta+ and Electron Capture } else if (line[6]==' ' && line[7]=='E' && line[8]==' ') { + // Beta+ and Electron Capture if (line[5]==' ') { buildRecords(); } recordStack[9].push_back(line); - // Alpha } else if (line[6]==' ' && line[7]=='A' && line[8]==' ') { + // Alpha if (line[5]==' ') { buildRecords(); } recordStack[10].push_back(line); - // Delayed Particle } else if (line[6]==' ' && (line[7]=='D' || line[7]==' ') && (line[8]=='N' || line[8]=='P' || line[8]=='A')) { + // Delayed Particle if (line[5]==' ') { buildRecords(); } recordStack[11].push_back(line); - // Gamma } else if (line[6]==' ' && line[7]=='G' && line[8]==' ') { + // Gamma if (line[5]==' ') { buildRecords(); } @@ -289,14 +291,29 @@ void EGS_Ensdf::parseEnsdf(vector ensdf) { // Get X-ray and auger emissions from comments getEmissionsFromComments(); + + // Get rid of very low emission probability particles + double minimumIntensity = 1e-6; + for (vector::iterator beta = myBetaRecords.begin(); + beta != myBetaRecords.end(); beta++) { + if((*beta)->getBetaIntensity() <= minimumIntensity) { + myBetaRecords.erase(beta); + } + } + for (vector::iterator alpha = myAlphaRecords.begin(); + alpha != myAlphaRecords.end(); alpha++) { + if((*alpha)->getAlphaIntensity() <= minimumIntensity) { + myAlphaRecords.erase(alpha); + } + } // Search through the gamma records for any with unknown levels - // or with zero emission probability + // or with low emission probability for (vector::iterator it = myGammaRecords.begin(); it!=myGammaRecords.end();) { - if ((*it)->getTransitionIntensity() <= 0.) { - // Throw away gammas with zero probability + if ((*it)->getTransitionIntensity() <= minimumIntensity) { + // Throw away gammas with low probability // Erase the gamma record object myGammaRecords.erase(it); @@ -499,6 +516,9 @@ void EGS_Ensdf::normalizeIntensities() { xrayIntensities[i] += xrayIntensities[i-1]; } lastIntensity = xrayIntensities[i]; + + egsInformation("EGS_Ensdf::normalizeIntensities: XRay (E,I): %f %f\n", + xrayEnergies[i], xrayIntensities[i]); } // Normalize auger emission intensities @@ -512,6 +532,9 @@ void EGS_Ensdf::normalizeIntensities() { augerIntensities[i] += augerIntensities[i-1]; } lastIntensity = augerIntensities[i]; + + egsInformation("EGS_Ensdf::normalizeIntensities: Auger (E,I): %f %f\n", + augerEnergies[i], augerIntensities[i]); } // Get the gamma transition intensities @@ -522,15 +545,21 @@ void EGS_Ensdf::normalizeIntensities() { for (vector::iterator it = myLevelRecords.begin(); it!=myLevelRecords.end(); it++) { - totalLevelIntensity[j] = 0; - for (vector::iterator gamma = myGammaRecords.begin(); - gamma != myGammaRecords.end(); gamma++) { - - if ((*gamma)->getLevelRecord() == (*it)) { - totalLevelIntensity[j] += (*gamma)->getTransitionIntensity(); - egsInformation("EGS_Ensdf::normalizeIntensities: %d %f %f\n", j, - (*gamma)->getTransitionIntensity(), - totalLevelIntensity[j]); + double disintIntensity = (*it)->getDisintegrationIntensity(); + if (disintIntensity > 1e-10) { + totalLevelIntensity[j] = disintIntensity; + } + else { + totalLevelIntensity[j] = 0; + for (vector::iterator gamma = myGammaRecords.begin(); + gamma != myGammaRecords.end(); gamma++) { + + if ((*gamma)->getLevelRecord() == (*it)) { + totalLevelIntensity[j] += (*gamma)->getTransitionIntensity(); + egsInformation("EGS_Ensdf::normalizeIntensities: %d %f %f\n", j, + (*gamma)->getTransitionIntensity(), + totalLevelIntensity[j]); + } } } ++j; @@ -710,9 +739,6 @@ void EGS_Ensdf::getEmissionsFromComments() { continue; } -// egsInformation("EGS_Ensdf::getEmissionsFromComments: %s\n", -// emissionLine.c_str()); - string eStr = egsTrimString(line.substr(13, 15)); // If we have a range in energy (e.g. 0.1-0.3) @@ -772,9 +798,6 @@ void EGS_Ensdf::getEmissionsFromComments() { augerIntensities.push_back(intensity); } } - -// egsInformation("EGS_Ensdf::getEmissionsFromComments: (E,I) %f %f\n", -// energy, intensity); } } } @@ -1176,7 +1199,8 @@ void NormalizationRecord::processEnsdf() { normalizeBranch = recordToDouble(32, 39); normalizeBeta = recordToDouble(42, 49); egsInformation("NormalizationRecord::processEnsdf: %f %f %f %f\n", - normalizeRelative, normalizeTransition, normalizeBranch, normalizeBeta); + normalizeRelative, normalizeTransition, normalizeBranch, + normalizeBeta); } // Multiplier for converting relative photon intensity to photons per 100 @@ -1220,10 +1244,12 @@ NormalizationRecordLeaf::NormalizationRecordLeaf(NormalizationRecord LevelRecord::LevelRecord() { energy = 0; halfLife = 0; + disintegrationIntensity = 0; } LevelRecord::LevelRecord(vector ensdf): Record(ensdf) { processEnsdf(); + disintegrationIntensity = 0; } void LevelRecord::processEnsdf() { @@ -1240,6 +1266,14 @@ bool LevelRecord::levelCanDecay() const { return canDecay; } +void LevelRecord::cumulDisintegrationIntensity(double disintIntensity) { + disintegrationIntensity += disintIntensity; +} + +double LevelRecord::getDisintegrationIntensity() const { + return disintegrationIntensity; +} + double LevelRecord::getEnergy() const { return energy; } @@ -1259,7 +1293,8 @@ LevelRecordLeaf::LevelRecordLeaf(LevelRecord // Beta Record BetaRecordLeaf::BetaRecordLeaf(vector ensdf, - ParentRecord *myParent, NormalizationRecord *myNormalization, + ParentRecord *myParent, + NormalizationRecord *myNormalization, LevelRecord *myLevel): ParentRecordLeaf(myParent), NormalizationRecordLeaf(myNormalization), @@ -1322,20 +1357,22 @@ EGS_AliasTable *BetaRecordLeaf::getSpectrum() const { // Beta- Record BetaMinusRecord::BetaMinusRecord(vector ensdf, - ParentRecord *myParent, NormalizationRecord *myNormalization, - LevelRecord *myLevel):BetaRecordLeaf(ensdf, myParent, - myNormalization, myLevel) { + ParentRecord *myParent, + NormalizationRecord *myNormalization, + LevelRecord *myLevel): + BetaRecordLeaf(ensdf, myParent, + myNormalization, myLevel) { processEnsdf(); q = -1; + myLevel->cumulDisintegrationIntensity(betaIntensity); } void BetaMinusRecord::processEnsdf() { finalEnergy = recordToDouble(10, 19) / 1000.; // Convert keV to MeV betaIntensity = recordToDouble(22, 29); if (getNormalizationRecord()) { -// betaIntensity *= getNormalizationRecord()->getBetaMultiplier() * -// getNormalizationRecord()->getBranchMultiplier(); - betaIntensity *= getNormalizationRecord()->getBetaMultiplier(); + betaIntensity *= getNormalizationRecord()->getBetaMultiplier() * + getNormalizationRecord()->getBranchMultiplier(); } egsInformation("BetaMinusRecord::processEnsdf: %f %f\n", finalEnergy, betaIntensity); @@ -1355,11 +1392,14 @@ void BetaMinusRecord::setBetaIntensity(double newIntensity) { // Beta+ Record (and Electron Capture) BetaPlusRecord::BetaPlusRecord(vector ensdf, - ParentRecord *myParent, NormalizationRecord *myNormalization, - LevelRecord *myLevel):BetaRecordLeaf(ensdf, myParent, - myNormalization, myLevel) { + ParentRecord *myParent, + NormalizationRecord *myNormalization, + LevelRecord *myLevel): + BetaRecordLeaf(ensdf, myParent, + myNormalization, myLevel) { processEnsdf(); q = 1; + myLevel->cumulDisintegrationIntensity(betaIntensity); } void BetaPlusRecord::processEnsdf() { @@ -1367,12 +1407,10 @@ void BetaPlusRecord::processEnsdf() { positronIntensity = recordToDouble(22, 29); ecIntensity = recordToDouble(32, 39); if (getNormalizationRecord()) { -// positronIntensity *= getNormalizationRecord()->getBetaMultiplier() * -// getNormalizationRecord()->getBranchMultiplier(); -// ecIntensity *= getNormalizationRecord()->getBetaMultiplier() * -// getNormalizationRecord()->getBranchMultiplier(); - positronIntensity *= getNormalizationRecord()->getBetaMultiplier(); - ecIntensity *= getNormalizationRecord()->getBetaMultiplier(); + positronIntensity *= getNormalizationRecord()->getBetaMultiplier() * + getNormalizationRecord()->getBranchMultiplier(); + ecIntensity *= getNormalizationRecord()->getBetaMultiplier() * + getNormalizationRecord()->getBranchMultiplier(); } // The total intensity for this decay branch @@ -1427,8 +1465,10 @@ void BetaPlusRecord::setECIntensity(double newIntensity) { // Gamma Record GammaRecord::GammaRecord(vector ensdf, NormalizationRecord - *myNormalization, LevelRecord *myLevel):Record(ensdf), - NormalizationRecordLeaf(myNormalization), LevelRecordLeaf(myLevel) { + *myNormalization, LevelRecord *myLevel): + Record(ensdf), + NormalizationRecordLeaf(myNormalization), + LevelRecordLeaf(myLevel) { processEnsdf(); q = 0; numSampled = 0; @@ -1439,10 +1479,9 @@ void GammaRecord::processEnsdf() { transitionIntensity = recordToDouble(22, 29); if (getNormalizationRecord()) { -// transitionIntensity *= -// getNormalizationRecord()->getRelativeMultiplier() * -// getNormalizationRecord()->getBranchMultiplier(); - transitionIntensity *= getNormalizationRecord()->getRelativeMultiplier(); + transitionIntensity *= + getNormalizationRecord()->getRelativeMultiplier() * + getNormalizationRecord()->getBranchMultiplier(); } egsInformation("GammaRecord::processEnsdf: %f %f\n", decayEnergy, @@ -1483,13 +1522,17 @@ void GammaRecord::setFinalLevel(LevelRecord *newLevel) { // Alpha Record AlphaRecord::AlphaRecord(vector ensdf, - ParentRecord *myParent, NormalizationRecord *myNormalization, - LevelRecord *myLevel):Record(ensdf), + ParentRecord *myParent, + NormalizationRecord *myNormalization, + LevelRecord *myLevel): + Record(ensdf), ParentRecordLeaf(myParent), NormalizationRecordLeaf(myNormalization), LevelRecordLeaf(myLevel) { + processEnsdf(); q = 2; numSampled = 0; + myLevel->cumulDisintegrationIntensity(alphaIntensity); } void AlphaRecord::processEnsdf() { diff --git a/HEN_HOUSE/egs++/egs_ensdf.h b/HEN_HOUSE/egs++/egs_ensdf.h index 6afb55558..83ba57cd7 100644 --- a/HEN_HOUSE/egs++/egs_ensdf.h +++ b/HEN_HOUSE/egs++/egs_ensdf.h @@ -233,12 +233,15 @@ class LevelRecord : public Record, public Branch > { public: LevelRecord(); LevelRecord(vector ensdf); + void cumulDisintegrationIntensity(double disintIntensity); + double getDisintegrationIntensity() const; void setLevelCanDecay(bool canDecay); bool levelCanDecay() const; double getEnergy() const; double getHalfLife() const; protected: + double disintegrationIntensity; double energy; double halfLife; bool canDecay; diff --git a/HEN_HOUSE/egs++/egs_spectra.cpp b/HEN_HOUSE/egs++/egs_spectra.cpp index 78261e84e..d670e0554 100644 --- a/HEN_HOUSE/egs++/egs_spectra.cpp +++ b/HEN_HOUSE/egs++/egs_spectra.cpp @@ -1071,18 +1071,41 @@ class EGS_EXPORT EGS_RadionuclideSpectrum : public EGS_BaseSpectrum { the daughter transitions to a lower energy state. If the daughter isotope is not in an exited state, one of the following events occurs: - Beta events may set the energy level of the daughter to an excited state. - Beta- and beta+ events emit an electron or positron, respectively. The energies - of beta particles are sampled from spectra generated by - \ref EGS_RadionuclideBetaSpectrum. Electron capture events are sampled, - but no particles are emitted. - - Alpha events may set the energy level of the daughter to an excited state. - Alpha events do not emit any particles. - - X-Ray events emit a photon from a sampled energy line. - - Auger events emit an electron from a sampled energy line. + Disintegration events may set the energy level of the daughter to an + excited state. Beta- and beta+ disintegrations emit an electron or positron, + respectively. The energies of beta particles are sampled from spectra + generated by \ref EGS_RadionuclideBetaSpectrum. Electron capture events + are also sampled, but neutrinos are not modeled so a zero energy + particle is returned. + + Alpha disintegrations may set the energy level of the daughter to an + excited state, leading to the emission of transition photons. + Alpha particles themselves are not modeled, so a zero energy particle + is returned. + + X-Ray and Auger events emit a photon or electron from a sampled energy line. + X-Ray and Auger emissions are not disintegrations so are not counted in + the fluence (or the ishower parameter). + + Transition gammas are sampled and emitted following a disintegration (if + the daughter is created in an excited state). The energy level of the + daughter is then set according to the transition that took place. + Note that there are cases where a transition photon is not guaranteed. + In such a case, the daughter level is set to zero and a zero energy + particle is returned. + + Note about emission times: the time of emission of a particle is modeled + by uniformly distributing disintegrations over the total experiment time + determined by the activity provided by the user. The time of emission of + a transition photon is determined by sampling the delay that occurs after + disintegration (according to the transition half life). X-Rays and + Auger electrons are assumed to occur at the same time as the disintegration + and will have both time and ishower corresponding to the most recent + disintegration. + + Currently, it is possible for an X-Ray or Auger to be emitted before a + disintegration has taken place. They are assigned currentTime=0 and + ishower=-1. */ EGS_Float sample(EGS_RandomGenerator *rndm) { @@ -1094,7 +1117,7 @@ class EGS_EXPORT EGS_RadionuclideSpectrum : public EGS_BaseSpectrum { EGS_Float E; // If the daughter is in an excited state - // Check for transitions + // check for transitions if (currentLevel && currentLevel->levelCanDecay() && currentLevel->getEnergy() > 1e-10) { for (vector::iterator gamma = myGammas.begin(); @@ -1104,9 +1127,6 @@ class EGS_EXPORT EGS_RadionuclideSpectrum : public EGS_BaseSpectrum { if (u < (*gamma)->getTransitionIntensity()) { - (*gamma)->incrNumSampled(); - currentQ = (*gamma)->getCharge(); - // Update the current time by sampling how long // it took for this transition to occur // time += halflife / ln(2) * log(u) @@ -1117,6 +1137,9 @@ class EGS_EXPORT EGS_RadionuclideSpectrum : public EGS_BaseSpectrum { * log(rndm->getUniform()); } + (*gamma)->incrNumSampled(); + currentQ = (*gamma)->getCharge(); + currentLevel = (*gamma)->getFinalLevel(); E = (*gamma)->getDecayEnergy(); @@ -1127,96 +1150,101 @@ class EGS_EXPORT EGS_RadionuclideSpectrum : public EGS_BaseSpectrum { } } } + currentLevel = 0; + return 0; } - else { - - // Uniformly distribute decays over the experiment time - currentTime = rndm->getUniform() * Tmax; - // ============================ - // Sample which decay occurs - // ============================ + // ============================ + // Sample which decay occurs + // ============================ - // Beta-, beta+ and electron capture - for (vector::iterator beta = myBetas.begin(); - beta != myBetas.end(); beta++) { - if (u < (*beta)->getBetaIntensity()) { + // Beta-, beta+ and electron capture + for (vector::iterator beta = myBetas.begin(); + beta != myBetas.end(); beta++) { + if (u < (*beta)->getBetaIntensity()) { - // Incremember the shower number - ishower++; + // Increment the shower number + ishower++; + + // Uniformly distribute decays over the experiment time + currentTime = rndm->getUniform() * Tmax; - (*beta)->incrNumSampled(); - currentQ = (*beta)->getCharge(); + // Increment the counter of betas and get the charge + (*beta)->incrNumSampled(); + currentQ = (*beta)->getCharge(); - // Set the energy level of the daughter - currentLevel = (*beta)->getLevelRecord(); + // Set the energy level of the daughter + currentLevel = (*beta)->getLevelRecord(); - // For beta+ records we decide between - // branches for beta+ or electron capture - if (currentQ == 1) { - // For positron emission, continue as usual - if ((*beta)->getPositronIntensity() > 1e-10 && rndm->getUniform() < (*beta)->getPositronIntensity()) { + // For beta+ records we decide between + // branches for beta+ or electron capture + if (currentQ == 1) { + // For positron emission, continue as usual + if ((*beta)->getPositronIntensity() > 1e-10 && rndm->getUniform() < (*beta)->getPositronIntensity()) { - } - else { - // For electron capture, there is no emitted particle - // (only a neutrino) - // so we return a 0 energy particle - return 0; - } } + else { + // For electron capture, there is no emitted particle + // (only a neutrino) + // so we return a 0 energy particle + return 0; + } + } - // Sample the energy from the spectrum alias table - E = (*beta)->getSpectrum()->sample(rndm); + // Sample the energy from the spectrum alias table + E = (*beta)->getSpectrum()->sample(rndm); - return E; - } + return E; } + } - // Alphas - for (vector::iterator alpha = myAlphas.begin(); - alpha != myAlphas.end(); alpha++) { - if (u < (*alpha)->getAlphaIntensity()) { + // Alphas + for (vector::iterator alpha = myAlphas.begin(); + alpha != myAlphas.end(); alpha++) { + if (u < (*alpha)->getAlphaIntensity()) { - // Incremember the shower number - ishower++; + // Increment the shower number + ishower++; + + // Uniformly distribute decays over the experiment time + currentTime = rndm->getUniform() * Tmax; - (*alpha)->incrNumSampled(); - currentQ = (*alpha)->getCharge(); + // Increment the counter of alphas and get the charge + (*alpha)->incrNumSampled(); + currentQ = (*alpha)->getCharge(); - // Set the energy level of the daughter - currentLevel = (*alpha)->getLevelRecord(); + // Set the energy level of the daughter + currentLevel = (*alpha)->getLevelRecord(); - // For alphas we simulate a disintegration but the - // transport will not be performed - return 0; - } + // For alphas we simulate a disintegration but the + // transport will not be performed + return 0; } + } - // XRays - for (unsigned int i=0; i < xrayIntensities.size(); ++i) { - if (u < xrayIntensities[i]) { + // XRays + for (unsigned int i=0; i < xrayIntensities.size(); ++i) { + if (u < xrayIntensities[i]) { - numSampledXRay[i]++; - currentQ = 0; + numSampledXRay[i]++; + currentQ = 0; - E = xrayEnergies[i]; + E = xrayEnergies[i]; - return E; - } + return E; } + } - // Auger electrons - for (unsigned int i=0; i < augerIntensities.size(); ++i) { - if (u < augerIntensities[i]) { + // Auger electrons + for (unsigned int i=0; i < augerIntensities.size(); ++i) { + if (u < augerIntensities[i]) { - numSampledAuger[i]++; - currentQ = -1; + numSampledAuger[i]++; + currentQ = -1; - E = augerEnergies[i]; + E = augerEnergies[i]; - return E; - } + return E; } } diff --git a/HEN_HOUSE/egs++/sources/egs_radionuclide_source/egs_radionuclide_source.cpp b/HEN_HOUSE/egs++/sources/egs_radionuclide_source/egs_radionuclide_source.cpp index 903cab385..f8c19f0ca 100644 --- a/HEN_HOUSE/egs++/sources/egs_radionuclide_source/egs_radionuclide_source.cpp +++ b/HEN_HOUSE/egs++/sources/egs_radionuclide_source/egs_radionuclide_source.cpp @@ -51,7 +51,9 @@ EGS_RadionuclideSource::EGS_RadionuclideSource(EGS_Input *input, if (!err) { if (std::find(q_allowed.begin(), q_allowed.end(), -1) != q_allowed.end() && std::find(q_allowed.begin(), q_allowed.end(), 0) != q_allowed.end() - && std::find(q_allowed.begin(), q_allowed.end(), 1) != q_allowed.end()) { + && std::find(q_allowed.begin(), q_allowed.end(), 1) != q_allowed.end() + && std::find(q_allowed.begin(), q_allowed.end(), 2) != q_allowed.end() + ) { q_allowAll = true; } else { @@ -64,6 +66,7 @@ EGS_RadionuclideSource::EGS_RadionuclideSource(EGS_Input *input, q_allowed.push_back(-1); q_allowed.push_back(1); q_allowed.push_back(0); + q_allowed.push_back(2); } // Create the decay spectra @@ -275,28 +278,9 @@ EGS_I64 EGS_RadionuclideSource::getNextParticle(EGS_RandomGenerator *rndm, int getPositionDirection(rndm,x,u,wt); latch = 0; -// egsWarning("EGS_RadionuclideSource::getNextParticle: E: %f\n", -// E); -// -// egsWarning("EGS_RadionuclideSource::getNextParticle: q: %d\n", -// q); - return ++count; } -// EGS_I64 EGS_RadionuclideSource::getNextParticle(EGS_RandomGenerator *rndm, int -// &q, int &latch, EGS_Float &E, EGS_Float &wt, EGS_Vector &x, EGS_Vector -// &u, EGS_I64 &ishower, EGS_Float &time) { -// -// ishower = count; -// -// getNextParticle(rndm, q, latch, E, wt, x, u); -// -// time = decays->getTime(); -// -// return count; -// } - void EGS_RadionuclideSource::setUp() { otype = "EGS_RadionuclideSource"; if (!isValid()) { @@ -316,6 +300,9 @@ void EGS_RadionuclideSource::setUp() { if (std::find(q_allowed.begin(), q_allowed.end(), 1) != q_allowed.end()) { description += " positrons"; } + if (std::find(q_allowed.begin(), q_allowed.end(), 1) != q_allowed.end()) { + description += " alphas"; + } if (geom) { geom->ref(); diff --git a/HEN_HOUSE/egs++/sources/egs_radionuclide_source/egs_radionuclide_source.h b/HEN_HOUSE/egs++/sources/egs_radionuclide_source/egs_radionuclide_source.h index bdbdc1ab4..f474ee7ae 100644 --- a/HEN_HOUSE/egs++/sources/egs_radionuclide_source/egs_radionuclide_source.h +++ b/HEN_HOUSE/egs++/sources/egs_radionuclide_source/egs_radionuclide_source.h @@ -380,11 +380,11 @@ class EGS_RADIONUCLIDE_SOURCE_EXPORT EGS_RadionuclideSource : GeometryConfinement gc; vector decays; //!< The radionuclide decay structure - vector q_allowed; - bool q_allowAll; - EGS_Float activity; - double time; - EGS_I64 ishower; + vector q_allowed; //!< A list of allowed charges + bool q_allowAll; //!< Whether or not to allow all charges + EGS_Float activity; //!< The activity of the source + double time; //!< The time of emission of the most recently generated particle + EGS_I64 ishower; //!< The shower index (disintegration number) of the most recently generated particle }; #endif diff --git a/HEN_HOUSE/spectra/lnhb/Am-244m.txt b/HEN_HOUSE/spectra/lnhb/Am-244m.txt index e3da61b32..45f5c0662 100644 --- a/HEN_HOUSE/spectra/lnhb/Am-244m.txt +++ b/HEN_HOUSE/spectra/lnhb/Am-244m.txt @@ -21,9 +21,9 @@ 244PU T 92.607-103.729 |] 0.00025345 KLX AUGER 244PU T 109.93-121.78 |] KXY AUGER 244PU T 6.19-22.99 0.0124 11 L AUGER -244AM P 0.0 0+ 26 M 3 164 9 +244AM P 89 2 0+ 26 M 3 75 9 244PU N 2.778E3 2.778E3 0.00036 2.778E3 -244PU L 0 0+ 80.0E6 Y 9 +244PU L 0 0+ 81.1E6 Y 6 244PU E 0.036 16.37 244PU2 E CK=0.24 5$CL=0.53 4$CM=0.168 12$CN=0.050 4 @@ -56,7 +56,7 @@ 244CM T 97.226-109.267 |] 0.00125 27 KLX AUGER 244CM T 115.57-128.23 |] KXY AUGER 244CM T 6.19-14.46 10.6 23 L AUGER -244AM P 0.0 0+ 26 M 3 1516 3 +244AM P 89 2 0+ 26 M 3 1427.0 36 244CM N 1.00E0 1.00E0 0.99964 1.00E0 244CM L 0 0+ 18.11 Y 3 244CM B 1516 3 67 9 6.45 diff --git a/HEN_HOUSE/spectra/lnhb/Br-76.txt b/HEN_HOUSE/spectra/lnhb/Br-76.txt new file mode 100644 index 000000000..7f75dfda8 --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Br-76.txt @@ -0,0 +1,402 @@ + 76SE 76BR EC DECAY (16.1 H) + 76SE C References: 1952Fu04, 1954Ca03, 1955Th01, 1956Te26, 1959Gi46, 1960Bu22, + 76SE2C 1962Ku06, 1962Ga13, 1962St02, 1963Sa26, 1963Do04, 1964By02, 1969Dz01, + 76SE3C 1970AgZV, 1970Dz09, 1971La01, 1971Go40, 1971FuZP, 1971Dz08, 1973Pa02, + 76SE4C 1974Na17, 1974HeYW, 1974MuZB, 1974Ba80, 1975VyZX, 1975NeZR, 1976Ba15, + 76SE5C 1977Le11, 1977La19, 1980Ka36, 1982MuZV, 1983Pa10, 1986Gi12, 1987Su05, + 76SE6C 1988Wh03, 1988Gr26, 1989Za03, 1992Gr20, 1993Oh09, 1995ScZY, 1995Si03, + 76SE7C 1996Sc06, 1998ScZM, 1998Sc28, 1999ScZX, 2000Sc47, 2002Ba85, 2002Ra45, + 76SE8C 2007Qa02, 2008Ki07, 2012Co17, 2012Wa38, 2013Go19, 2014StZZ + 76SE T Auger electrons and X ray energies and emission intensities: + 76SE T {U Energy (keV)} {U Intensity} {U Line} + 76SE T + 76SE T 11.1815 7.20 13 XKA2 + 76SE T 11.2225 13.96 25 XKA1 + 76SE T + 76SE T 12.4897 |] XKB3 + 76SE T 12.496 |] 3.26 7 XKB1 + 76SE T 12.596 |] XKB5II + 76SE T + 76SE T 12.6523 |] XKB2 + 76SE T |] 0.183 7 XKB4 + 76SE T + 76SE T 1.204-1.648 0.968 20 XL (total) + 76SE T 1.204 0.0242 8 XLL + 76SE T 1.379- 0.569 16 XLA + 76SE T 1.245 0.0131 4 XLC + 76SE T 1.42-1.492 0.360 11 XLB + 76SE T 1.648- 0.00245 7 XLG + 76SE T + 76SE T 9.28-9.712 |] KLL AUGER + 76SE T 10.749-11.216 |] 16.3 3 KLX AUGER + 76SE T 12.195-12.647 |] KXY AUGER + 76SE T 0.956-1.312 52.9 7 L AUGER + 76BR P 0.0 1- 16.1 H 2 4963 9 + 76SE N 1.0 1.0 1 1.0 + 76SE G 546.5 5 0.163 23 + 76SE G 2170 2 0.10 4 + 76SE G 2235 2 0.13 6 + 76SE G 2837 3 0.11 5 + 76SE G 3892 2 0.030 15 + 76SE G 3963.5 100.022 8 + 76SE L 0 0 0+ STABLE + 76SE E 5.7 8 0.10 2 8.93 1 + 76SE2 E EAV=1803 4$CK=0.8803 15$CL=0.1003 12$CM=0.0176 4$CN=0.0019 2$CO= + 76SE L 559.102 5 2+ 12.22 PS 17 + 76SE E 25.7 9 0.75 3 7.98 1 + 76SE2 E EAV=1535 4$CK=0.8802 15$CL=0.1003 12$CM=0.0176 4$CN=0.0019 2$CO= + 76SE G 559.100 5 74.0 7 E2 0.001973 + 76SE2 G KC=1747E-6 25$LC=1.87E-4 3$MC=2.91E-5 4 + 76SE L 1122.283 7 0+ 9 PS 4 + 76SE E 2.1 6 0.11 3 8.71 1 + 76SE2 E EAV=1268 4$CK=0.8801 15$CL=0.1004 12$CM=0.0176 4$CN=0.0019 2$CO= + 76SE G 563.179 9 3.5 6 E2 0.001923 + 76SE2 G KC=1710E-6 24$LC=1.83E-4 3$MC=2.85E-5 4 + 76SE G 1122.274 7 + 76SE L 1216.147 7 2+ 3.4 PS 1 + 76SE E 1.8 9 0.10 5 8.71 1 + 76SE2 E EAV=1224 4$CK=0.8801 15$CL=0.1004 12$CM=0.0176 4$CN=0.0019 2$CO= + 76SE G 657.042 9 16.0 4 M1+E2(+) 5.2 2 1226E-618 + 76SE2 G KC=1090E-6 16$LC=1159E-7 17$MC=1.80E-5 3 + 76SE G 1216.137 7 8.73 22E2 2.81E-44 + 76SE2 G KC=2.41E-4 4$LC=2.51E-5 4$MC=3.90E-6 6 + 76SE L 1330.860 8 4+ 1.52 PS 4 + 76SE G 114.7 1 0.33 11E2 0.501 8 + 76SE2 G KC=0.434 6$LC=0.0573 9$MC=0.00886 13 + 76SE G 771.754 100.414 23E2 8.00E-412 + 76SE2 G KC=7.12E-4 10$LC=7.52E-5 11$MC=1170E-8 17 + 76SE L 1688.962 7 3+ + 76SE E 0.6 3 0.11 6 10 1U + 76SE2 E EAV=1026 4$CK=0.8800 15$CL=0.1005 12$CM=0.0176 4$CN=0.0019 2$CO= + 76SE G 358.101 110.37 15M1+E2 1.0 2 0.0059 5 + 76SE2 G KC=0.0053 5$LC=0.00057 5$MC=8.9E-5 8 + 76SE G 472.813 101.92 8 M1+E2 1.0 2 0.0026315 + 76SE2 G KC=0.00233 13$LC=2.50E-4 15$MC=3.88E-5 23 + 76SE G 1129.851 9 4.59 23M1+E2 1.08 10 3.09E-45 + 76SE2 G KC=2.75E-4 4$LC=2.86E-5 5$MC=4.44E-6 7 + 76SE L 1787.648 8 2+ 8 PS 5 + 76SE E 0.9 4 0.10 4 8.6 1 + 76SE2 E EAV=957 4$CK=0.8800 15$CL=0.1005 12$CM=0.0176 4$CN=0.0019 2$CO= + 76SE G 456.787 110.067 15E2 0.003656 + 76SE2 G KC=0.00324 5$LC=3.51E-4 5$MC=5.46E-5 8 + 76SE G 571.499 110.44 23M1+E2 0.13 12 0.001293 + 76SE2 G KC=0.00115 3$LC=1.20E-4 3$MC=1.87E-5 5 + 76SE G 665.362 110.71 8 E2 1194E-617 + 76SE2 G KC=1062E-6 15$LC=1128E-7 16$MC=1755E-8 25 + 76SE G 1228.535 102.13 10M1+E2 -0.51 5 2.64E-44 + 76SE2 G KC=2.26E-4 4$LC=2.34E-5 4$MC=3.64E-6 6 + 76SE G 1787.625 8 0.55 3 E2 3.33E-45 + 76SE2 G KC=1103E-7 16$LC=1139E-8 16$MC=1772E-9 25 + 76SE L 2127.215 8 (2)+ + 76SE E 0.19 110.04 2 8.9 1 + 76SE2 E EAV=800 4$CK=0.8799 15$CL=0.1006 12$CM=0.0176 4$CN=0.0019 2$CO= + 76SE G 438.252 110.27 3 (M1+E2) 1.0 2 0.0032621 + 76SE2 G KC=0.00290 18$LC=3.11E-4 21$MC=4.8E-5 4 + 76SE G 796.351 110.074 23(E2) 7.37E-411 + 76SE2 G KC=6.56E-4 10$LC=6.93E-5 10$MC=1077E-8 15 + 76SE G 911.062 110.05 3 (M1+E2) + 76SE G 1568.096 100.95 5 (M1+E2) 1.0 2 2.59E-45 + 76SE2 G KC=1404E-7 20$LC=1451E-8 21$MC=2.26E-6 4 + 76SE G 2127.183 8 0.21 7 (E2) 4.61E-47 + 76SE2 G KC=8.00E-5 12$LC=8.24E-6 12$MC=1282E-9 18 + 76SE L 2170.554 12(0)+ + 76SE G 1611.434 130.222 23(E2) 2.82E-44 + 76SE2 G KC=1348E-7 19$LC=1394E-8 20$MC=2.17E-6 3 + 76SE G 2170.521 12 () + 76SE L 2374.2 6 + + 76SE E 0.21 2 0.07 1 8.6 + 76SE2 E EAV=688 4$CK=0.8798 15$CL=0.1006 12$CM=0.0176 4$CN=0.0019 2$CO= + 76SE G 1158.1 5 0.133 8 + 76SE G 1815.1 6 0.148 15 + 76SE L 2429.095 113- + 76SE E 0.6 4 0.2 1 8.1 2 + 76SE2 E EAV=663 4$CK=0.8798 15$CL=0.1006 12$CM=0.0176 4$CN=0.0019 2$CO= + 76SE G 641.444 140.14 4 E1 4.60E-47 + 76SE2 G KC=4.10E-4 6$LC=4.26E-5 6$MC=6.62E-6 10 + 76SE G 740.129 130.13 4 E1+M2 -0.21 12 0.000409 + 76SE2 G KC=0.00036 8$LC=3.7E-5 9$MC=5.8E-6 14 + 76SE G 1212.938 131.7 6 E1 1.82E-43 + 76SE2 G KC=1134E-7 16$LC=1167E-8 17$MC=1.81E-6 3 + 76SE G 1306.800 130.185 23E3 4.45E-47 + 76SE2 G KC=3.88E-4 6$LC=4.11E-5 6$MC=6.39E-6 9 + 76SE G 1869.968 120.141 15E1 5.97E-49 + 76SE2 G KC=5.55E-5 8$LC=5.68E-6 8$MC=8.84E-7 13 + 76SE G 2429.053 110.10 5 E3 4.37E-47 + 76SE2 G KC=9.91E-5 14$LC=1026E-8 15$MC=1596E-9 23 + 76SE L 2514.663 13(2)+ + 76SE E 0.28 170.11 7 8.3 1 + 76SE2 E EAV=624 4$CK=0.8798 15$CL=0.1007 12$CM=0.0176 4$CN=0.0019 2$CO= + 76SE G 727.011 150.67 23(M1+E2) 1.0 2 8.44E-424 + 76SE2 G KC=7.51E-4 21$LC=7.90E-5 24$MC=1.23E-5 4 + 76SE G 1298.504 150.089 8 (M1+E2) + 76SE G 1955.534 140.30 6 (M1+E2) + 76SE L 2630.8 5 (1, 2)+ + 76SE E 0.20 150.11 9 8.3 + 76SE2 E EAV=572 4$CK=0.8797 15$CL=0.1007 12$CM=0.0176 4$CN=0.0019 2$CO= + 76SE G 941.8 5 0.111 23 + 76SE G 2071.7 5 0.27 23 + 76SE G 2630.8 5 0.13 4 + 76SE L 2655.32 4 1- + 76SE E 0.26 8 0.15 4 8.1 + 76SE2 E EAV=561 4$CK=0.8797 15$CL=0.1007 12$CM=0.0176 4$CN=0.0019 2$CO= + 76SE G 867.66 4 0.318 23(E1) 2.40E-44 + 76SE2 G KC=2.15E-4 3$LC=2.22E-5 4$MC=3.45E-6 5 + 76SE G 1324.45 4 0.044 23(E3) 4.32E-46 + 76SE2 G KC=3.76E-4 6$LC=3.97E-5 6$MC=6.18E-6 9 + 76SE G 1439.16 4 0.58 3 (E1) 2.99E-45 + 76SE2 G KC=8.43E-5 12$LC=8.67E-6 13$MC=1347E-9 19 + 76SE G 1533.01 4 0.06 4 (E1) 3.62E-45 + 76SE2 G KC=7.60E-5 11$LC=7.80E-6 11$MC=1213E-9 17 + 76SE G 2096.19 4 1.35 8 (E1) 7.49E-411 + 76SE2 G KC=4.67E-5 7$LC=4.78E-6 7$MC=7.43E-7 11 + 76SE G 2655.27 4 0.170 15(E1) 1087E-616 + 76SE2 G KC=3.33E-5 5$LC=3.40E-6 5$MC=5.29E-7 8 + 76SE L 2669.88 4 2- + 76SE E 1.49 100.88 6 7.33 + 76SE2 E EAV=554 4$CK=0.8797 15$CL=0.1007 12$CM=0.0176 4$CN=0.0019 2$CO= + 76SE G 499.33 4 0.16 7 (M2) 0.005648 + 76SE2 G KC=0.00500 7$LC=5.46E-4 8$MC=8.53E-5 12 + 76SE G 882.22 4 0.40 2 E1+M2 0.26 15 0.000298 + 76SE2 G KC=0.00026 7$LC=2.7E-5 8$MC=4.2E-6 12 + 76SE G 980.91 4 0.355 23E1 1.89E-43 + 76SE2 G KC=1682E-7 24$LC=1736E-8 25$MC=2.70E-6 4 + 76SE G 1453.72 4 0.81 5 E1 3.08E-45 + 76SE2 G KC=8.29E-5 12$LC=8.52E-6 12$MC=1325E-9 19 + 76SE G 2110.75 4 2.46 12E1 7.59E-411 + 76SE2 G KC=4.62E-5 7$LC=4.73E-6 7$MC=7.36E-7 11 + 76SE L 2858.1 20 + + 76SE E 0.13 3 0.14 3 8.1 + 76SE2 E EAV=471 4$CK=0.8796 15$CL=0.1008 12$CM=0.0177 4$CN=0.0019 2$CO= + 76SE G 1642 2 0.13 5 + 76SE G 2299 2 0.14 5 + 76SE L 2950.53 5 1, 2+ + 76SE E 5.1 2 6.9 3 6.33 + 76SE2 E EAV=430 4$CK=0.8796 15$CL=0.1008 12$CM=0.0177 4$CN=0.0019 2$CO= + 76SE G 1162.87 5 0.163 15M1+E2 + 76SE G 2391.39 5 4.7 3 M1+E2 1.0 2 5.41E-411 + 76SE2 G KC=6.46E-5 10$LC=6.63E-6 10$MC=1032E-9 15 + 76SE G 2950.47 5 7.4 4 [M1+E2] 1.0 2 7.70E-414 + 76SE2 G KC=4.52E-5 7$LC=4.63E-6 7$MC=7.20E-7 11 + 76SE L 3069.75 4 (1, 2)+ + 76SE E 6.1 1 12.7 2 6.01 + 76SE2 E EAV=378 4$CK=0.8795 15$CL=0.1009 12$CM=0.0177 4$CN=0.0019 2$CO= + 76SE G 399.87 6 0.052 15E1 1466E-621 + 76SE2 G KC=1307E-6 19$LC=1363E-7 19$MC=2.12E-5 3 + 76SE G 899.19 4 0.170 23 + 76SE G 942.53 4 0.074 15(M1+E2) + 76SE G 1282.09 4 0.07 3 (M1+E2) + 76SE G 1380.78 4 2.50 11[M1+E2] 1.0 2 2.45E-44 + 76SE2 G KC=1.81E-4 3$LC=1.87E-5 3$MC=2.91E-6 5 + 76SE G 1853.58 4 14.6 8 (M1+E2) 1.0 2 3.34E-47 + 76SE2 G KC=1022E-7 15$LC=1053E-8 15$MC=1638E-9 24 + 76SE G 2510.61 4 1.92 12(M1+E2) 1.0 2 5.90E-411 + 76SE2 G KC=5.93E-5 9$LC=6.09E-6 9$MC=9.48E-7 14 + 76SE G 3069.68 4 0.044 15 + 76SE L 3160.07 6 (2)+ + 76SE E 1.32 4 3.99 146.47 1 + 76SE2 E EAV=339 4$CK=0.8794 15$CL=0.1010 12$CM=0.0177 4$CN=0.0019 2$CO= + 76SE G 490.19 7 0.333 23[E1] 8.72E-413 + 76SE2 G KC=7.78E-4 11$LC=8.09E-5 12$MC=1258E-8 18 + 76SE G 504.75 7 0.229 15[E1] 8.11E-412 + 76SE2 G KC=7.23E-4 11$LC=7.53E-5 11$MC=1170E-8 17 + 76SE G 730.98 6 0.58 8 [E1] 3.44E-45 + 76SE2 G KC=3.07E-4 5$LC=3.18E-5 5$MC=4.95E-6 7 + 76SE G 1032.85 6 0.58 5 + 76SE G 1372.41 6 0.51 3 + 76SE G 1471.09 6 2.32 11M1+E2 1.0 2 2.45E-45 + 76SE2 G KC=1592E-7 23$LC=1647E-8 24$MC=2.56E-6 4 + 76SE G 1943.89 6 0.47 9 + 76SE G 2600.92 6 0.69 3 + 76SE G 3160.00 6 0.141 15 + 76SE L 3268.8 4 (2, 3, 4)- + 76SE L 3351.54 7 (1, 2)+ + 76SE E 1.00 4 8.0 4 6.07 + 76SE2 E EAV=256 4$CK=0.8793 15$CL=0.1011 12$CM=0.0177 4$CN=0.0019 2$CO= + 76SE G 401.01 9 0.30 4 (M1+E2) 1.0 2 0.0042 3 + 76SE2 G KC=0.0038 3$LC=0.00041 3$MC=6.3E-5 5 + 76SE G 681.66 8 0.429 23E1 4.01E-46 + 76SE2 G KC=3.58E-4 5$LC=3.71E-5 6$MC=5.77E-6 8 + 76SE G 696.22 8 0.496 23(E1) 3.83E-46 + 76SE2 G KC=3.42E-4 5$LC=3.54E-5 5$MC=5.51E-6 8 + 76SE G 836.88 7 0.45 4 (M1+E2) + 76SE G 922.44 7 0.192 15 + 76SE G 1180.98 7 0.111 15 + 76SE G 1224.32 7 0.29 11(M1+E2) + 76SE G 1662.56 7 0.14 6 + 76SE G 2135.36 7 0.93 6 (M1+E2) 1.0 2 4.38E-49 + 76SE2 G KC=7.89E-5 12$LC=8.12E-6 12$MC=1262E-9 18 + 76SE G 2229.22 7 0.10 7 + 76SE G 2792.38 7 5.6 3 (M1+E2) 1.0 2 7.06E-413 + 76SE2 G KC=4.95E-5 7$LC=5.08E-6 8$MC=7.90E-7 12 + 76SE G 3351.46 7 0.252 15 + 76SE L 3441.5 2 (1, 2, 3)+ + 76SE E 0.006 2 0.09 3 8 + 76SE2 E EAV=218 4$CK=0.8792 15$CL=0.1012 12$CM=0.0177 4$CN=0.0019 2$CO= + 76SE G 281.4 2 0.044 23[M1+E2] 1.0 2 0.0127 13 + 76SE2 G KC=0.0113 12$LC=0.00125 14$MC=1.94E-4 21 + 76SE G 1270.9 200.059 23(M1+E2) + 76SE L 3459.40 8 (2)+ + 76SE E 0.108 9 1.81 156.65 1 + 76SE2 E EAV=210 4$CK=0.8792 15$CL=0.1012 12$CM=0.0177 4$CN=0.0019 2$CO= + 76SE G 789.52 9 0.46 3 (E1) 2.92E-44 + 76SE2 G KC=2.61E-4 4$LC=2.70E-5 4$MC=4.19E-6 6 + 76SE G 804.08 9 0.53 4 (E1) 2.81E-44 + 76SE2 G KC=2.51E-4 4$LC=2.60E-5 4$MC=4.04E-6 6 + 76SE G 1030.30 8 0.56 6 (E1) 1716E-724 + 76SE2 G KC=1531E-7 22$LC=1579E-8 23$MC=2.45E-6 4 + 76SE G 1288.84 8 0.052 23(E2) 2.64E-44 + 76SE2 G KC=2.13E-4 3$LC=2.21E-5 3$MC=3.44E-6 5 + 76SE G 1671.73 8 0.170 15(M1+E2) + 76SE G 1770.42 8 0.200 23(M1+E2) + 76SE G 2900.24 8 0.27 10(M1+E2) + 76SE L 3556.46 8 (1, 2)+ + 76SE E 0.040 4 1.53 8 6.67 + 76SE2 E EAV=169 4$CK=0.8791 15$CL=0.1013 12$CM=0.0178 4$CN=0.0019 2$CO= + 76SE G 886.57 9 0.340 23 + 76SE G 901.13 9 0.17 5 + 76SE G 1429.24 8 0.06 3 + 76SE G 2340.27 8 0.09 4 + 76SE G 2997.30 8 0.955 24[M1+E2] 1.0 2 7.89E-414 + 76SE2 G KC=4.40E-5 7$LC=4.51E-6 7$MC=7.01E-7 10 + 76SE L 3604.08 8 1, 2+ + 76SE E 0.026 3 1.64 136.61 + 76SE2 E EAV=149 4$CK=0.8790 15$CL=0.1013 12$CM=0.0178 4$CN=0.0019 2$CO= + 76SE G 934.19 9 0.052 15E1 2.07E-43 + 76SE2 G KC=1.85E-4 3$LC=1.91E-5 3$MC=2.97E-6 5 + 76SE G 2481.76 8 0.133 23 + 76SE G 3044.91 8 0.022 8 (M1+E2) + 76SE G 3603.99 8 1.60 11[M1+E2] 1.0 2 1018E-617 + 76SE2 G KC=3.26E-5 5$LC=3.34E-6 5$MC=5.20E-7 8 + 76SE L 3622.2 20 + + 76SE E 0.005 2 0.36 117.3 + 76SE2 E EAV=142 4$CK=0.8790 15$CL=0.1013 12$CM=0.0178 4$CN=0.0019 2$CO= + 76SE G 1193.1 200.10 5 + 76SE G 1834.6 200.19 10 + 76SE G 3063 2 0.074 23 + 76SE L 3669.5 10 + + 76SE E 0.005 1 0.73 196.9 + 76SE2 E EAV=122 4$CK=0.8789 15$CL=0.1014 12$CM=0.0178 4$CN=0.0019 2$CO= + 76SE G 210.1 100.044 15[M1+E2] 1.0 2 0.034 5 + 76SE2 G KC=0.030 4$LC=0.0034 5$MC=0.00053 7 + 76SE G 318 1 0.13 5 [M1+E2] 1.0 2 0.0086 8 + 76SE2 G KC=0.0076 7$LC=0.00084 8$MC=1.30E-4 13 + 76SE G 599.8 100.42 17[M1+E2] 1.0 2 0.001376 + 76SE2 G KC=0.00122 5$LC=1.29E-4 6$MC=2.01E-5 9 + 76SE G 1881.9 100.13 5 + 76SE G 2547.2 100.006 4 + 76SE L 3913 1 + + 76SE E 0.133 157.5 + 76SE2 E EAV= $CK=0.8785 15$CL=0.1017 13$CM=0.0179 4$CN=0.0019 2$CO= + 76SE G 1742.4 100.118 15 + 76SE G 3912.9 100.015 8 + 76SE L 3929.1 6 (1, 2)+ + 76SE E 0.17 4 7.4 + 76SE2 E EAV= $CK=0.8784 15$CL=0.1018 13$CM=0.0179 4$CN=0.0019 2$CO= + 76SE G 1801.9 6 0.030 15 + 76SE G 2712.9 6 0.074 23 + 76SE G 3369.9 6 0.096 8 + 76SE G 3929.0 6 0.089 15 + 76SE L 3970.6 4 (1, 2)+ + 76SE E 0.64 5 6.7 + 76SE2 E EAV= $CK=0.8783 15$CL=0.1019 13$CM=0.0179 4$CN=0.0019 2$CO= + 76SE G 1300.7 4 0.155 15(E1) 2.26E-44 + 76SE2 G KC=1002E-7 14$LC=1031E-8 15$MC=1603E-9 23 + 76SE G 1315.3 4 0.052 15(E1) 2.34E-44 + 76SE2 G KC=9.83E-5 14$LC=1011E-8 15$MC=1572E-9 22 + 76SE G 2183.0 4 0.13 3 (M1+E2) + 76SE G 2754.4 4 0.074 23(M1+E2) + 76SE G 3411.4 4 0.296 15(M1+E2) + 76SE G 3970.5 4 0.010 5 + 76SE L 3998.4 10 + + 76SE E 0.42 4 6.9 + 76SE2 E EAV= $CK=0.8783 15$CL=0.1019 13$CM=0.0179 4$CN=0.0019 2$CO= + 76SE G 838.3 100.318 23 + 76SE G 2309.4 100.10 3 + 76SE L 4019.3 5 + + 76SE E 0.36 7 7 + 76SE2 E EAV= $CK=0.8782 15$CL=0.1020 13$CM=0.0179 4$CN=0.0019 2$CO= + 76SE G 1504.6 5 0.09 4 + 76SE G 2688.3 5 0.36 4 + 76SE G 4019.2 5 0.059 15 + 76SE L 4064 4 + + 76SE E 0.43 9 6.8 + 76SE2 E EAV= $CK=0.8781 15$CL=0.1021 13$CM=0.0179 4$CN=0.0019 2$CO= + 76SE G 605 4 0.22 8 [M1+E2] 1.0 2 0.001346 + 76SE2 G KC=0.00120 5$LC=1.27E-4 6$MC=1.97E-5 9 + 76SE G 2848 4 0.15 5 + 76SE G 3505 4 0.037 15 + 76SE G 4064 4 0.022 8 + 76SE L 4084.3 2 (1, 2)+ + 76SE E 0.50 4 6.7 + 76SE2 E EAV= $CK=0.8780 15$CL=0.1021 13$CM=0.0179 4$CN=0.0019 2$CO= + 76SE G 1429.0 2 0.192 23 + 76SE G 1655.2 2 0.118 23 + 76SE G 3525.1 2 0.178 15 + 76SE G 4084.2 2 0.015 8 + 76SE L 4173.1 9 (1, 2)+ + 76SE E 0.200 157.1 + 76SE2 E EAV= $CK=0.8777 15$CL=0.1024 13$CM=0.0180 4$CN=0.0019 2$CO= + 76SE G 2045.9 9 0.178 15 + 76SE G 4173.0 9 0.021 8 + 76SE L 4199.6 4 (1, 2)+ + 76SE E 0.36 4 6.8 + 76SE2 E EAV= $CK=0.8776 15$CL=0.1025 13$CM=0.0180 4$CN=0.0019 2$CO= + 76SE G 1039.5 4 0.044 15 + 76SE G 1770.5 4 0.044 15 + 76SE G 2412.0 4 0.030 8 + 76SE G 2983.4 4 0.09 3 + 76SE G 3640.4 4 0.155 15 + 76SE L 4210 1 + + 76SE E 0.24 4 6.9 + 76SE2 E EAV= $CK=0.8776 15$CL=0.1025 13$CM=0.0180 4$CN=0.0019 2$CO= + 76SE G 281 1 0.118 23[M1+E2] 1.0 2 0.0128 14 + 76SE2 G KC=0.0113 12$LC=0.00125 14$MC=1.95E-4 21 + 76SE G 2082 1 0.12 4 + 76SE L 4215.5 2 (1, 2)+ + 76SE E 0.61 3 6.5 + 76SE2 E EAV= $CK=0.8775 15$CL=0.1025 13$CM=0.0180 4$CN=0.0019 2$CO= + 76SE G 1560.2 2 0.444 23(E1) 3.81E-46 + 76SE2 G KC=7.38E-5 11$LC=7.58E-6 11$MC=1178E-9 17 + 76SE G 3093.1 2 0.163 15 + 76SE L 4328.7 10 + + 76SE E 0.19 5 6.9 + 76SE2 E EAV= $CK=0.8769 16$CL=0.1030 13$CM=0.0181 4$CN=0.0020 2$CO= + 76SE G 309.4 4 0.14 5 [M1+E2] 1.0 2 0.0094 9 + 76SE2 G KC=0.0083 8$LC=0.00091 9$MC=1.42E-4 14 + 76SE G 1060 1 0.044 23 + 76SE L 4416 2 + + 76SE E 0.26 7 6.6 + 76SE2 E EAV= $CK=0.8763 16$CL=0.1035 13$CM=0.0182 4$CN=0.0020 2$CO= + 76SE G 812.1 8 0.14 5 + 76SE G 1901 2 0.12 5 + 76SE L 4436.9 10(1, 2)+ + 76SE E 0.067 157.2 + 76SE2 E EAV= $CK=0.8761 16$CL=0.1037 13$CM=0.0182 4$CN=0.0020 2$CO= + 76SE G 3877.7 100.015 8 + 76SE G 4436.8 100.052 15 + 76SE L 4455.2 30 + + 76SE E 0.007 2 8.1 + 76SE2 E EAV= $CK=0.8760 16$CL=0.1038 13$CM=0.0183 4$CN=0.0020 2$CO= + 76SE G 4454.9 300.0067 23 + 76SE L 4492 3 + + 76SE E 0.052 157.2 + 76SE2 E EAV= $CK=0.8756 16$CL=0.1041 13$CM=0.0183 4$CN=0.0020 2$CO= + 76SE G 936 3 0.044 15 + 76SE G 4492 3 0.0059 23 + 76SE L 4605.8 7 (1, 2)+ + 76SE E 0.56 125.9 + 76SE2 E EAV= $CK=0.8738 16$CL=0.1055 13$CM=0.0186 4$CN=0.0020 2$CO= + 76SE G 635.2 8 0.074 23(M1+E2) 1.0 2 0.001185 + 76SE2 G KC=0.00105 4$LC=1.11E-4 5$MC=1.73E-5 7 + 76SE G 1146.4 7 0.059 15(M1+E2) + 76SE G 1254.3 7 0.08 3 (M1+E2) + 76SE G 1536.1 7 0.17 7 (M1+E2) + 76SE G 1975.0 9 0.11 9 + 76SE G 4046.6 7 0.044 15(M1+E2) + 76SE G 4605.7 7 0.015 8 + 76SE L 4621.5 20 + + 76SE E 0.21 4 6.3 + 76SE2 E EAV= $CK=0.8735 16$CL=0.1058 13$CM=0.0187 4$CN=0.0020 2$CO= + 76SE G 1461.4 200.13 3 + 76SE G 1990.7 210.08 3 + diff --git a/HEN_HOUSE/spectra/lnhb/Np-236m.txt b/HEN_HOUSE/spectra/lnhb/Np-236m.txt index bfe2af6b2..bff6d325e 100644 --- a/HEN_HOUSE/spectra/lnhb/Np-236m.txt +++ b/HEN_HOUSE/spectra/lnhb/Np-236m.txt @@ -29,7 +29,7 @@ 236U T 88.153-98.429 |] 1.03 17 KLX AUGER 236U T 104.51-115.59 |] KXY AUGER 236U T 6.4-21.6 21.7 15 L AUGER -236NP P 0.0 1+ 22.5 H 4 993 13 +236NP P 60 501+ 22.5 H 4 930 50 236U N 1.887E0 1.887E0 0.53 1.887E0 236U L 0 0+ 23.43E6 Y 6 236U E 43.1 327.1 @@ -84,9 +84,9 @@ 236PU T 92.607-103.729 |] KLX AUGER 236PU T 109.93-121.78 |] KXY AUGER 236PU T 6.19-22.99 3.8 14 L AUGER -236NP P 0.0 1+ 22.5 H 4 537 8 +236NP P 60 501+ 22.5 H 4 480 50 236PU N 2.128E0 2.128E0 0.47 2.128E0 -236PU L 0 0+ STABLE +236PU L 0 0+ 2.87 Y 1 236PU B 537 8 36 4 6.8 236PUS B EAV=158 3 236PU L 44.63 102+ diff --git a/HEN_HOUSE/spectra/lnhb/Tc-94m.txt b/HEN_HOUSE/spectra/lnhb/Tc-94m.txt index 6d0938300..0e8ce6fab 100644 --- a/HEN_HOUSE/spectra/lnhb/Tc-94m.txt +++ b/HEN_HOUSE/spectra/lnhb/Tc-94m.txt @@ -29,7 +29,7 @@ 94MO T 16.592-17.478 |] 6.28 15 KLX AUGER 94MO T 18.99-19.996 |] KXY AUGER 94MO T 1.48-2.25 29.8 4 L AUGER - 94TC P 0.0 (2)+ 51.9 M 10 4332 5 + 94TC P 76 3 (2)+ 51.9 M 10 4256 6 94MO N 1.0 1.0 1 1.0 94MO G 1022 0.027 14 94MO G 1037.2 3 0.044 14 @@ -38,34 +38,34 @@ 94MO G 3085.8 3 0.016 4 94MO G 3640.6 3 0.007 2 94MO G 4136.2 3 0.007 1 - 94MO L 0 0+ STABLE - 94MO L 871.098 162+ + 94MO L 0 0+ STABLE + 94MO L 871.098 162+ 94MO E 67.2 412.8 15.6 94MO2 E EAV=1094.4 24$CK=0.8704 14$CL=0.1055 11$CM=0.0205 4$CN=0.0037 2 94MO G 871.094 1694.04 21E2 1068E-615 94MO2 G KC=9.39E-4 14$LC=1073E-7 15$MC=1.92E-5 3 - 94MO L 1573.76 4 4+ + 94MO L 1573.76 4 4+ 94MO G 702.66 4 0.18 2E2 0.00183 3 94MO2 G KC=1608E-6 23$LC=1.87E-4 3$MC=3.34E-5 5 - 94MO L 1741.65 150+ + 94MO L 1741.65 150+ 94MO G 870.55 220.26 3E2 1070E-615 94MO2 G KC=9.40E-4 14$LC=1075E-7 15$MC=1.92E-5 3 - 94MO L 1864.31 5 2+ + 94MO L 1864.31 5 2+ 94MO E 0.41 100.39 96.82 94MO2 E EAV=639.6 23$CK=0.8699 14$CL=0.1059 11$CM=0.0206 4$CN=0.0037 2 94MO G 993.20 5 2.21 18M1+E2 -2 1 7.91E-415 94MO2 G KC=6.96E-4 13$LC=7.86E-5 13$MC=1403E-8 22 94MO G 1864.29 5 0.23 3E2 4.55E-4 7 94MO2 G KC=1.89E-4 3$LC=2.09E-5 3$MC=3.72E-6 6 - 94MO L 2067.35 6 2+ + 94MO L 2067.35 6 2+ 94MO E 0.22 30.34 56.8 94MO2 E EAV=548.7 23$CK=0.8697 14$CL=0.1060 11$CM=0.0206 4$CN=0.0037 2 94MO G 1196.24 6 0.71 7M1+E2 0.15 4 5.53E-4 8 94MO2 G KC=4.83E-4 7$LC=5.36E-5 8$MC=9.57E-6 14 94MO G 2067.33 6 0.11 1E2 5.15E-4 8 94MO2 G KC=1562E-7 22$LC=1722E-8 25$MC=3.07E-6 5 - 94MO L 2294.79 164+ - 94MO L 2393.02 6 2+ + 94MO L 2294.79 164+ + 94MO L 2393.02 6 2+ 94MO E 0.91 64.0 25.6 94MO2 E EAV=404.8 22$CK=0.8694 14$CL=0.1062 11$CM=0.0207 4$CN=0.0037 2 94MO G 325.67 9 0.027 2M1+E2 1.0 2 0.0147 9 @@ -76,10 +76,10 @@ 94MO2 G KC=2.95E-4 5$LC=3.26E-5 5$MC=5.81E-6 9 94MO G 2392.99 6 0.50 4E2 6.33E-4 9 94MO2 G KC=1203E-7 17$LC=1322E-8 19$MC=2.35E-6 4 - 94MO L 2423.45 9 6+ - 94MO L 2533.87 123- - 94MO L 2610.57 165- - 94MO L 2739.91 7 1+ + 94MO L 2423.45 9 6+ + 94MO L 2533.87 123- + 94MO L 2610.57 165- + 94MO L 2739.91 7 1+ 94MO E 0.427 2110.1 45.03 94MO2 E EAV=254.3 22$CK=0.8690 14$CL=0.1066 11$CM=0.0207 4$CN=0.0037 2 94MO G 672.56 9 0.17 3M1+E2 1.0 2 0.00200 3 @@ -92,8 +92,8 @@ 94MO2 G KC=1.96E-4 3$LC=2.16E-5 3$MC=3.85E-6 6 94MO G 2739.87 7 3.53 20M1 7.25E-411 94MO2 G KC=9.59E-5 14$LC=1051E-8 15$MC=1.87E-6 3 - 94MO L 2805.04 193+ - 94MO L 2869.90 8 2+ + 94MO L 2805.04 193+ + 94MO L 2869.90 8 2+ 94MO E 0.0024 50.15 36.8 94MO2 E EAV=198.5 22$CK=0.8688 14$CL=0.1067 11$CM=0.0208 4$CN=0.0037 2 94MO G 802.55 100.0246 14M1+E2 1.0 2 1303E-619 @@ -104,9 +104,9 @@ 94MO2 G KC=1.68E-4 3$LC=1.86E-5 3$MC=3.31E-6 6 94MO G 2869.85 8 0.016 2E2 8.16E-412 94MO2 G KC=8.81E-5 13$LC=9.64E-6 14$MC=1717E-9 24 - 94MO L 2872.40 116+ - 94MO L 2955.55 13(8)+ - 94MO L 2965.41 6 3+ + 94MO L 2872.40 116+ + 94MO L 2955.55 13(8)+ + 94MO L 2965.41 6 3+ 94MO E 0.00058 90.093 146.9 94MO2 E EAV=157.5 22$CK=0.8686 14$CL=0.1069 11$CM=0.0208 4$CN=0.0037 2 94MO G 898.06 9 0.0098 5M1+E2 2.0 9 9.97E-415 @@ -117,7 +117,7 @@ 94MO2 G KC=3.53E-4 5$LC=3.91E-5 6$MC=6.98E-6 10 94MO G 2094.28 6 0.0156 6M1+E2 1.1 7 5.12E-414 94MO2 G KC=1.55E-4 3$LC=1.71E-5 4$MC=3.04E-6 6 - 94MO L 3128.66 7 1+ + 94MO L 3128.66 7 1+ 94MO E 1.63 95.57 94MO2 E CK=0.8682 14$CL=0.1072 11$CM=0.0209 4$CN=0.0037 2 94MO G 1061.30 9 0.016 2M1+E2 -0.57 16 6.99E-411 @@ -128,15 +128,15 @@ 94MO2 G KC=1356E-7 20$LC=1491E-8 22$MC=2.66E-6 4 94MO G 3128.60 7 1.34 9M1 8.71E-413 94MO2 G KC=7.58E-5 11$LC=8.29E-6 12$MC=1476E-9 21 - 94MO L 3163.29 19(3)+ + 94MO L 3163.29 19(3)+ 94MO E 0.058 177 94MO2 E CK=0.8681 14$CL=0.1073 11$CM=0.0209 4$CN=0.0037 2 94MO G 358.3 3 0.0084 7M1+E2 -0.35 12 0.0092 4 94MO2 G KC=0.0080 4$LC=0.00093 5$MC=1.67E-4 8 94MO G 2292.16 190.050 17M1+E2 0.17 4 5.62E-4 8 94MO2 G KC=1330E-7 19$LC=1461E-8 21$MC=2.60E-6 4 - 94MO L 3165.77 9 6+ - 94MO L 3331.74 17(3)+ + 94MO L 3165.77 9 6+ + 94MO L 3331.74 17(3)+ 94MO E 0.234 206.3 94MO2 E CK=0.8675 14$CL=0.1078 11$CM=0.0210 4$CN=0.0038 2 94MO G 1467.42 180.072 5M1+E2 0.3 16 4.19E-4 9 @@ -144,26 +144,26 @@ 94MO G 1757.96 170.15 2M1+E2 -0.10 3 4.18E-4 6 94MO2 G KC=2.21E-4 3$LC=2.44E-5 4$MC=4.35E-6 6 94MO G 2460.61 170.011 2(M1+E2) - 94MO L 3339.54 176+ - 94MO L 3400.83 17 + + 94MO L 3339.54 176+ + 94MO L 3400.83 17 + 94MO E 0.36 46 94MO2 E CK=0.8672 14$CL=0.1080 11$CM=0.0211 4$CN=0.0038 2 94MO G 1536.51 180.014 3 94MO G 2529.69 170.34 4 94MO G 3400.76 170.005 2 - 94MO L 3447.6 4 (1,2)+ + 94MO L 3447.6 4 (1,2)+ 94MO E 0.118 196.4 94MO2 E CK=0.8669 14$CL=0.1082 11$CM=0.0211 4$CN=0.0038 2 94MO G 2576.5 4 0.11 2M1+E2 -1.9 6 6.94E-412 94MO2 G KC=1061E-7 15$LC=1164E-8 17$MC=2.07E-6 3 94MO G 3447.5 4 0.006 1 - 94MO L 3511.86 141+ + 94MO L 3511.86 141+ 94MO E 0.121 106.4 94MO2 E CK=0.8666 15$CL=0.1085 11$CM=0.0212 4$CN=0.0038 2 94MO G 1770.19 210.025 6(M1+E2) 94MO G 2640.72 140.033 4(M1+E2) 94MO G 3511.79 140.063 7(M1+E2) - 94MO L 3534.32 9 2+ + 94MO L 3534.32 9 2+ 94MO E 0.106 36.4 94MO2 E CK=0.8664 15$CL=0.1086 11$CM=0.0212 4$CN=0.0038 2 94MO G 1669.99 100.037 2M1+E2 0.15 19 4.10E-4 6 @@ -172,14 +172,14 @@ 94MO2 G KC=1009E-7 15$LC=1106E-8 16$MC=1.97E-6 3 94MO G 3534.25 9 0.0034 4E2 1065E-615 94MO2 G KC=6.25E-5 9$LC=6.82E-6 10$MC=1215E-9 17 - 94MO L 3792.87 152+ + 94MO L 3792.87 152+ 94MO E 0.169 205.9 94MO2 E CK=0.8639 15$CL=0.1106 11$CM=0.0216 4$CN=0.0039 2 94MO G 1399.84 160.041 3M1+E2 94MO G 1928.54 160.075 19M1+E2 94MO G 3792.79 150.052 5E2 1149E-616 94MO2 G KC=5.59E-5 8$LC=6.09E-6 9$MC=1084E-9 16 - 94MO L 3892.16 7 (2)+ + 94MO L 3892.16 7 (2)+ 94MO E 0.212 135.6 94MO2 E CK=0.8620 15$CL=0.1121 12$CM=0.0220 4$CN=0.0039 2 94MO G 1499.13 9 0.067 11M1+E2 diff --git a/HEN_HOUSE/spectra/lnhb/Tc-99m.txt b/HEN_HOUSE/spectra/lnhb/Tc-99m.txt index 5dac3985f..beac6265d 100644 --- a/HEN_HOUSE/spectra/lnhb/Tc-99m.txt +++ b/HEN_HOUSE/spectra/lnhb/Tc-99m.txt @@ -50,7 +50,7 @@ 99RU T 22.104 |] XKB4 99RU T 99TC P 142.683 1 1/2- 6.0067 H 10 293.52 20 - 99RU N 2.50E4 2.50E4 0.00004 2.50E4 + 99RU N 2.50E4 2.50E4 0.004 2.50E4 99RU L 0 5/2+ STABLE 99RU B 436.3 2 0.0010 3 9.4 1U 99RUS B EAV=152.3 5 From 93ce7840f61a57fcfae0d311a620e17437d1f875 Mon Sep 17 00:00:00 2001 From: Reid Townson Date: Tue, 18 Oct 2016 11:16:39 -0400 Subject: [PATCH 15/34] Add support for metastable radionuclides Treat metastable radionuclide sources correctly. The transition gammas from metastable sources are now counted as disintegrations. This has only been tested on Tc-99m so far. Change the Tc-99m ENSDF data back to match the LNHB data, given that we have fixed the metastable bug. --- HEN_HOUSE/egs++/egs_ensdf.cpp | 282 +++++++++++++++++++++++------- HEN_HOUSE/egs++/egs_ensdf.h | 16 +- HEN_HOUSE/egs++/egs_spectra.cpp | 82 +++++++-- HEN_HOUSE/spectra/lnhb/Tc-99m.txt | 2 +- 4 files changed, 292 insertions(+), 90 deletions(-) diff --git a/HEN_HOUSE/egs++/egs_ensdf.cpp b/HEN_HOUSE/egs++/egs_ensdf.cpp index b5fd98460..881fce1ac 100644 --- a/HEN_HOUSE/egs++/egs_ensdf.cpp +++ b/HEN_HOUSE/egs++/egs_ensdf.cpp @@ -289,20 +289,50 @@ void EGS_Ensdf::parseEnsdf(vector ensdf) { myBetaRecords.push_back(*it); } + // For each parent record, search through all disintegration types + // (betas, alphas) to see if any exist + // If no disintegrations exist for the parent, but we do have internal + // transition (IT) gammas, then we must have a metastable radionuclide + // In this case, add the gammas to the myMetastableGammaRecords vector + for (vector::iterator parent = myParentRecords.begin(); + parent!=myParentRecords.end(); parent++) { + + bool gotDisint = false; + for (vector::iterator beta = myBetaRecords.begin(); + beta != myBetaRecords.end(); beta++) { + + if ((*beta)->getParentRecord() == *parent) { + gotDisint = true; + break; + } + } + + if (!gotDisint) { + for (vector::iterator gamma = myGammaRecords.begin(); + gamma != myGammaRecords.end(); gamma++) { + + if ((*gamma)->getParentRecord() == *parent) { + myMetastableGammaRecords.push_back(*gamma); + myGammaRecords.erase(gamma); + } + } + } + } + // Get X-ray and auger emissions from comments getEmissionsFromComments(); - + // Get rid of very low emission probability particles double minimumIntensity = 1e-6; for (vector::iterator beta = myBetaRecords.begin(); beta != myBetaRecords.end(); beta++) { - if((*beta)->getBetaIntensity() <= minimumIntensity) { + if ((*beta)->getBetaIntensity() <= minimumIntensity) { myBetaRecords.erase(beta); } } for (vector::iterator alpha = myAlphaRecords.begin(); alpha != myAlphaRecords.end(); alpha++) { - if((*alpha)->getAlphaIntensity() <= minimumIntensity) { + if ((*alpha)->getAlphaIntensity() <= minimumIntensity) { myAlphaRecords.erase(alpha); } } @@ -338,6 +368,57 @@ void EGS_Ensdf::parseEnsdf(vector ensdf) { } } + // Check for instances where the intensity of disintegrations that + // lead towards a particular excited daughter level is less than + // the intensities of gamma transitions from it. + // In these cases, there are some gamma transitions that are + // uncorrelated with the disintegrations. + // To account for this, we convert a fraction of those gamma transitions + // into X-Rays. + unsigned int j = 0; + vector totalLevelIntensity; + totalLevelIntensity.resize(myLevelRecords.size()); + for (vector::iterator it = myLevelRecords.begin(); + it!=myLevelRecords.end(); it++) { + + double disintIntensity = (*it)->getDisintegrationIntensity(); + + totalLevelIntensity[j] = 0; + for (vector::iterator gamma = myGammaRecords.begin(); + gamma != myGammaRecords.end(); gamma++) { + + if ((*gamma)->getLevelRecord() == (*it)) { + totalLevelIntensity[j] += (*gamma)->getTransitionIntensity(); + egsInformation("EGS_Ensdf::normalizeIntensities: %d %f %f\n", j, + (*gamma)->getTransitionIntensity(), + totalLevelIntensity[j]); + } + } + + if (totalLevelIntensity[j] > disintIntensity) { + for (vector::iterator gamma = myGammaRecords.begin(); + gamma != myGammaRecords.end(); gamma++) { + + if ((*gamma)->getLevelRecord() == (*it)) { + // Add a faction of these gammas to the X-Rays since + // they are uncorrelated with disintegrations + xrayEnergies.push_back((*gamma)->getDecayEnergy()); + xrayIntensities.push_back( + (*gamma)->getTransitionIntensity() * (1. - disintIntensity/totalLevelIntensity[j]) + ); + + // Reduce the transition intensities + // Now they will add to 1 + (*gamma)->setTransitionIntensity( + (*gamma)->getTransitionIntensity() * disintIntensity/totalLevelIntensity[j] + ); + } + } + } + + ++j; + } + for (unsigned int i=0; i < xrayEnergies.size(); ++i) { egsInformation("EGS_Ensdf::parseEnsdf: XRays (E,I): %f %f\n", xrayEnergies[i], xrayIntensities[i]); @@ -420,7 +501,8 @@ void EGS_Ensdf::buildRecords() { } else if (i==12) { myGammaRecords.push_back(new - GammaRecord(recordStack[i], lastNormalization, lastLevel)); + GammaRecord(recordStack[i], lastParent, + lastNormalization, lastLevel)); } recordStack[i].clear(); @@ -450,6 +532,30 @@ void EGS_Ensdf::normalizeIntensities() { totalDecayIntensity += (*alpha)->getAlphaIntensity(); } + double totalMetastableGammaIntensity = 0; + for (vector::iterator gamma = myMetastableGammaRecords.begin(); + gamma != myMetastableGammaRecords.end(); gamma++) { + + egsInformation("EGS_Ensdf::normalizeIntensities: MetastableGamma (E,I): %f %f\n", + (*gamma)->getDecayEnergy(), + (*gamma)->getTransitionIntensity()); + + totalMetastableGammaIntensity += (*gamma)->getTransitionIntensity(); + totalDecayIntensity += (*gamma)->getTransitionIntensity(); + } + if (totalMetastableGammaIntensity > 0 && totalMetastableGammaIntensity < 100. - 1e-10) { + double metastableFailIntensity = 100. - totalMetastableGammaIntensity; + totalDecayIntensity += metastableFailIntensity; + + egsInformation("EGS_Ensdf::normalizeIntensities: MetastableGamma adds to less than 100\%. Fail chance: %f\n", metastableFailIntensity); + + // Push a copy of the last metastable gamma onto the vector + myMetastableGammaRecords.push_back(new GammaRecord(myMetastableGammaRecords.back())); + + // Edit that copy so that it has zero energy and the right + // intensity corresponding to the chance of no internal transition + myMetastableGammaRecords.back()->setTransitionIntensity(metastableFailIntensity); + } for (unsigned int i=0; i < xrayIntensities.size(); ++i) { egsInformation("EGS_Ensdf::normalizeIntensities: XRay (E,I): %f %f\n", xrayEnergies[i], xrayIntensities[i]); @@ -505,6 +611,28 @@ void EGS_Ensdf::normalizeIntensities() { (*alpha)->getFinalEnergy(), (*alpha)->getAlphaIntensity()); } + // Normalize metastable gamma transition intensities + for (vector::iterator gamma = myMetastableGammaRecords.begin(); + gamma != myMetastableGammaRecords.end(); gamma++) { + + (*gamma)->setTransitionIntensity( + (*gamma)->getTransitionIntensity() / totalDecayIntensity); + + if ((gamma - myMetastableGammaRecords.begin()) == 0 && lastIntensity > 1e-10) { + (*gamma)->setTransitionIntensity( + (*gamma)->getTransitionIntensity() + lastIntensity); + } + else if ((gamma - myMetastableGammaRecords.begin()) > 0) { + (*gamma)->setTransitionIntensity( + (*gamma)->getTransitionIntensity() + + (*(gamma-1))->getTransitionIntensity()); + } + lastIntensity = (*gamma)->getTransitionIntensity(); + + egsInformation("EGS_Ensdf::normalizeIntensities: MetastableGamma (E,I): %f %f\n", + (*gamma)->getDecayEnergy(), (*gamma)->getTransitionIntensity()); + } + // Normalize XRay emission intensities for (unsigned int i=0; i < xrayIntensities.size(); ++i) { xrayIntensities[i] /= totalDecayIntensity; @@ -537,6 +665,50 @@ void EGS_Ensdf::normalizeIntensities() { augerEnergies[i], augerIntensities[i]); } + // Determine the final level that the gammas decay towards + // We have to use the gamma decay energy to guess at the resulting + // energy state of the radionuclide + for (vector::iterator gamma = myGammaRecords.begin(); + gamma != myGammaRecords.end(); gamma++) { + + double energy = (*gamma)->getDecayEnergy(); + double guessedLevelEnergy = + ((*gamma)->getLevelRecord()->getEnergy() - energy); + + egsInformation("EGS_Ensdf::normalizeIntensities: Gamma (LE,E,GE): " + "%f %f %f\n",(*gamma)->getLevelRecord()->getEnergy(), + energy, guessedLevelEnergy); + + double bestMatch = 1E10; + LevelRecord *level; + for (vector::iterator it = myLevelRecords.begin(); + it!=myLevelRecords.end(); it++) { + + double testMatch = fabs((*it)->getEnergy()-guessedLevelEnergy); + + if (testMatch < bestMatch && + (testMatch < guessedLevelEnergy*0.3 || testMatch < 20)) { + + bestMatch = testMatch; + level = (*it); + } + } + if (bestMatch == 1E10) { + egsInformation("EGS_Ensdf::normalizeIntensities: Warning: Could not find a " + "level with energy matching decay of gamma with energy E=%f, " + "assuming ground state\n",energy); + (*gamma)->setFinalLevel(myLevelRecords.front()); + } + else { + (*gamma)->setFinalLevel(level); + } + + egsInformation("EGS_Ensdf::normalizeIntensities: Gamma (final level E): " + "%f\n",level->getEnergy()); + + (*gamma)->getFinalLevel()->cumulDisintegrationIntensity((*gamma)->getTransitionIntensity()); + } + // Get the gamma transition intensities // and the total intensity for each level unsigned int j = 0; @@ -546,22 +718,23 @@ void EGS_Ensdf::normalizeIntensities() { it!=myLevelRecords.end(); it++) { double disintIntensity = (*it)->getDisintegrationIntensity(); - if (disintIntensity > 1e-10) { - totalLevelIntensity[j] = disintIntensity; - } - else { - totalLevelIntensity[j] = 0; - for (vector::iterator gamma = myGammaRecords.begin(); - gamma != myGammaRecords.end(); gamma++) { - if ((*gamma)->getLevelRecord() == (*it)) { - totalLevelIntensity[j] += (*gamma)->getTransitionIntensity(); - egsInformation("EGS_Ensdf::normalizeIntensities: %d %f %f\n", j, - (*gamma)->getTransitionIntensity(), - totalLevelIntensity[j]); - } + totalLevelIntensity[j] = 0; + for (vector::iterator gamma = myGammaRecords.begin(); + gamma != myGammaRecords.end(); gamma++) { + + if ((*gamma)->getLevelRecord() == (*it)) { + totalLevelIntensity[j] += (*gamma)->getTransitionIntensity(); + egsInformation("EGS_Ensdf::normalizeIntensities: %d %f %f\n", j, + (*gamma)->getTransitionIntensity(), + totalLevelIntensity[j]); } } + + if (disintIntensity > 1e-10 && totalLevelIntensity[j] < disintIntensity + 1e-10) { + totalLevelIntensity[j] = disintIntensity; + egsInformation("EGS_Ensdf::normalizeIntensities: disintegrationIntensity %f\n", totalLevelIntensity[j]); + } ++j; } @@ -591,8 +764,8 @@ void EGS_Ensdf::normalizeIntensities() { } ++i; - egsInformation("EGS_Ensdf::normalizeIntensities: Gamma intensities: " - "%f\n",(*gamma)->getTransitionIntensity()); + egsInformation("EGS_Ensdf::normalizeIntensities: Gamma (L,E,I): " + "%d %f %f\n",j,(*gamma)->getDecayEnergy(), (*gamma)->getTransitionIntensity()); } } @@ -605,48 +778,6 @@ void EGS_Ensdf::normalizeIntensities() { ++j; } - - // Determine the final level that the gammas decay towards - // We have to use the gamma decay energy to guess at the resulting - // energy state of the radionuclide - for (vector::iterator gamma = myGammaRecords.begin(); - gamma != myGammaRecords.end(); gamma++) { - - double energy = (*gamma)->getDecayEnergy(); - double guessedLevelEnergy = - ((*gamma)->getLevelRecord()->getEnergy() - energy); - - egsInformation("EGS_Ensdf::normalizeIntensities: Gamma (LE,E,GE): " - "%f %f %f\n",(*gamma)->getLevelRecord()->getEnergy(), - energy, guessedLevelEnergy); - - double bestMatch = 1E10; - LevelRecord *level; - for (vector::iterator it = myLevelRecords.begin(); - it!=myLevelRecords.end(); it++) { - - double testMatch = fabs((*it)->getEnergy()-guessedLevelEnergy); - - if (testMatch < bestMatch && - (testMatch < guessedLevelEnergy*0.3 || testMatch < 20)) { - - bestMatch = testMatch; - level = (*it); - } - } - if (bestMatch == 1E10) { - egsInformation("EGS_Ensdf::normalizeIntensities: Warning: Could not find a " - "level with energy matching decay of gamma with energy E=%f, " - "assuming ground state\n",energy); - (*gamma)->setFinalLevel(myLevelRecords.front()); - } - else { - (*gamma)->setFinalLevel(level); - } - - egsInformation("EGS_Ensdf::normalizeIntensities: Gamma (final level E): " - "%f\n",level->getEnergy()); - } } void EGS_Ensdf::getEmissionsFromComments() { @@ -834,6 +965,10 @@ vector EGS_Ensdf::getGammaRecords() const { return myGammaRecords; } +vector EGS_Ensdf::getMetastableGammaRecords() const { + return myMetastableGammaRecords; +} + vector EGS_Ensdf::getAlphaRecords() const { return myAlphaRecords; } @@ -1178,7 +1313,7 @@ double ParentRecord::getQ() const { return Q; } -const ParentRecord *ParentRecordLeaf::getParentRecord() const { +ParentRecord *ParentRecordLeaf::getParentRecord() const { return getBranch(); } @@ -1230,7 +1365,7 @@ double NormalizationRecord::getBetaMultiplier() const { return normalizeBeta; } -const NormalizationRecord *NormalizationRecordLeaf::getNormalizationRecord() +NormalizationRecord *NormalizationRecordLeaf::getNormalizationRecord() const { return getBranch(); } @@ -1282,7 +1417,7 @@ double LevelRecord::getHalfLife() const { return halfLife; } -const LevelRecord *LevelRecordLeaf::getLevelRecord() const { +LevelRecord *LevelRecordLeaf::getLevelRecord() const { return getBranch(); } @@ -1464,9 +1599,12 @@ void BetaPlusRecord::setECIntensity(double newIntensity) { } // Gamma Record -GammaRecord::GammaRecord(vector ensdf, NormalizationRecord - *myNormalization, LevelRecord *myLevel): +GammaRecord::GammaRecord(vector ensdf, + ParentRecord *myParent, + NormalizationRecord *myNormalization, + LevelRecord *myLevel): Record(ensdf), + ParentRecordLeaf(myParent), NormalizationRecordLeaf(myNormalization), LevelRecordLeaf(myLevel) { processEnsdf(); @@ -1474,6 +1612,18 @@ GammaRecord::GammaRecord(vector ensdf, NormalizationRecord numSampled = 0; } +GammaRecord::GammaRecord(GammaRecord *gamma): + Record(), + ParentRecordLeaf(gamma->getParentRecord()), + NormalizationRecordLeaf(gamma->getNormalizationRecord()), + LevelRecordLeaf(gamma->getLevelRecord()) { + + q = gamma->q; + decayEnergy = 0; + transitionIntensity = 0; + numSampled = 0; +} + void GammaRecord::processEnsdf() { decayEnergy = recordToDouble(10, 19) / 1000.; // Convert keV to MeV transitionIntensity = recordToDouble(22, 29); diff --git a/HEN_HOUSE/egs++/egs_ensdf.h b/HEN_HOUSE/egs++/egs_ensdf.h index 83ba57cd7..8d763a81b 100644 --- a/HEN_HOUSE/egs++/egs_ensdf.h +++ b/HEN_HOUSE/egs++/egs_ensdf.h @@ -199,7 +199,7 @@ class ParentRecord : public Record, public Branch > { class ParentRecordLeaf : public Leaf { public: ParentRecordLeaf(ParentRecord *myRecord); - virtual const ParentRecord *getParentRecord() const; + virtual ParentRecord *getParentRecord() const; }; // Normalization Record @@ -225,7 +225,7 @@ class NormalizationRecord : public Record, public class NormalizationRecordLeaf : public Leaf { public: NormalizationRecordLeaf(NormalizationRecord *myRecord); - virtual const NormalizationRecord *getNormalizationRecord() const; + virtual NormalizationRecord *getNormalizationRecord() const; }; // Level Record @@ -253,7 +253,7 @@ class LevelRecord : public Record, public Branch > { class LevelRecordLeaf : public Leaf { public: LevelRecordLeaf(LevelRecord *myRecord); - virtual const LevelRecord *getLevelRecord() const; + virtual LevelRecord *getLevelRecord() const; }; // Generic beta record @@ -324,11 +324,13 @@ class BetaPlusRecord : public BetaRecordLeaf { }; // Gamma record -class GammaRecord : public Record, public NormalizationRecordLeaf, public - LevelRecordLeaf { +class GammaRecord : public Record, public ParentRecordLeaf, + public NormalizationRecordLeaf, public LevelRecordLeaf { public: - GammaRecord(vector ensdf, NormalizationRecord *myNormalization, + GammaRecord(vector ensdf, ParentRecord *myParent, + NormalizationRecord *myNormalization, LevelRecord *myLevel); + GammaRecord(GammaRecord *gamma); double getDecayEnergy() const; double getTransitionIntensity() const; @@ -434,6 +436,7 @@ class EGS_EXPORT EGS_Ensdf { vector getLevelRecords() const; vector getAlphaRecords() const; vector getGammaRecords() const; + vector getMetastableGammaRecords() const; vector getXRayIntensities() const; vector getXRayEnergies() const; vector getAugerIntensities() const; @@ -466,6 +469,7 @@ class EGS_EXPORT EGS_Ensdf { vector myBetaPlusRecords; vector myAlphaRecords; vector myGammaRecords; + vector myMetastableGammaRecords; private: diff --git a/HEN_HOUSE/egs++/egs_spectra.cpp b/HEN_HOUSE/egs++/egs_spectra.cpp index d670e0554..f0312b0df 100644 --- a/HEN_HOUSE/egs++/egs_spectra.cpp +++ b/HEN_HOUSE/egs++/egs_spectra.cpp @@ -918,6 +918,7 @@ class EGS_EXPORT EGS_RadionuclideSpectrum : public EGS_BaseSpectrum { myBetas = decays->getBetaRecords(); myAlphas = decays->getAlphaRecords(); myGammas = decays->getGammaRecords(); + myMetastableGammas = decays->getMetastableGammaRecords(); myLevels = decays->getLevelRecords(); xrayIntensities = decays->getXRayIntensities(); xrayEnergies = decays->getXRayEnergies(); @@ -956,6 +957,14 @@ class EGS_EXPORT EGS_RadionuclideSpectrum : public EGS_BaseSpectrum { Emax = energy; } } + for (vector::iterator gamma = myMetastableGammas.begin(); + gamma != myMetastableGammas.end(); gamma++) { + + double energy = (*gamma)->getDecayEnergy(); + if (Emax < energy) { + Emax = energy; + } + } for (unsigned int i=0; i < xrayEnergies.size(); ++i) { numSampledXRay.push_back(0); if (Emax < xrayEnergies[i]) { @@ -1043,6 +1052,17 @@ class EGS_EXPORT EGS_RadionuclideSpectrum : public EGS_BaseSpectrum { egsInformation("Average gamma energy: %f\n", totalGammaEnergy / totalNumSampled); } + if (myMetastableGammas.size() > 0) { + egsInformation("Metastable Gamma records:\n"); + } + totalNumSampled = 0; + for (vector::iterator gamma = myMetastableGammas.begin(); + gamma != myMetastableGammas.end(); gamma++) { + + totalNumSampled += (*gamma)->getNumSampled(); + egsInformation("%f %f\n", (*gamma)->getDecayEnergy(), + ((EGS_Float)(*gamma)->getNumSampled()/ishower)*100); + } if (xrayEnergies.size() > 0) { egsInformation("X-Ray records:\n"); } @@ -1071,39 +1091,39 @@ class EGS_EXPORT EGS_RadionuclideSpectrum : public EGS_BaseSpectrum { the daughter transitions to a lower energy state. If the daughter isotope is not in an exited state, one of the following events occurs: - Disintegration events may set the energy level of the daughter to an - excited state. Beta- and beta+ disintegrations emit an electron or positron, - respectively. The energies of beta particles are sampled from spectra - generated by \ref EGS_RadionuclideBetaSpectrum. Electron capture events + Disintegration events may set the energy level of the daughter to an + excited state. Beta- and beta+ disintegrations emit an electron or positron, + respectively. The energies of beta particles are sampled from spectra + generated by \ref EGS_RadionuclideBetaSpectrum. Electron capture events are also sampled, but neutrinos are not modeled so a zero energy particle is returned. - Alpha disintegrations may set the energy level of the daughter to an + Alpha disintegrations may set the energy level of the daughter to an excited state, leading to the emission of transition photons. Alpha particles themselves are not modeled, so a zero energy particle is returned. - X-Ray and Auger events emit a photon or electron from a sampled energy line. - X-Ray and Auger emissions are not disintegrations so are not counted in + X-Ray and Auger events emit a photon or electron from a sampled energy line. + X-Ray and Auger emissions are not disintegrations so are not counted in the fluence (or the ishower parameter). - - Transition gammas are sampled and emitted following a disintegration (if - the daughter is created in an excited state). The energy level of the - daughter is then set according to the transition that took place. + + Transition gammas are sampled and emitted following a disintegration (if + the daughter is created in an excited state). The energy level of the + daughter is then set according to the transition that took place. Note that there are cases where a transition photon is not guaranteed. In such a case, the daughter level is set to zero and a zero energy particle is returned. - + Note about emission times: the time of emission of a particle is modeled by uniformly distributing disintegrations over the total experiment time determined by the activity provided by the user. The time of emission of a transition photon is determined by sampling the delay that occurs after disintegration (according to the transition half life). X-Rays and Auger electrons are assumed to occur at the same time as the disintegration - and will have both time and ishower corresponding to the most recent + and will have both time and ishower corresponding to the most recent disintegration. - - Currently, it is possible for an X-Ray or Auger to be emitted before a + + Currently, it is possible for an X-Ray or Auger to be emitted before a disintegration has taken place. They are assigned currentTime=0 and ishower=-1. @@ -1165,7 +1185,7 @@ class EGS_EXPORT EGS_RadionuclideSpectrum : public EGS_BaseSpectrum { // Increment the shower number ishower++; - + // Uniformly distribute decays over the experiment time currentTime = rndm->getUniform() * Tmax; @@ -1205,7 +1225,7 @@ class EGS_EXPORT EGS_RadionuclideSpectrum : public EGS_BaseSpectrum { // Increment the shower number ishower++; - + // Uniformly distribute decays over the experiment time currentTime = rndm->getUniform() * Tmax; @@ -1222,6 +1242,33 @@ class EGS_EXPORT EGS_RadionuclideSpectrum : public EGS_BaseSpectrum { } } + // Metastable internal transition gammas + for (vector::iterator gamma = myMetastableGammas.begin(); + gamma != myMetastableGammas.end(); gamma++) { + if (u < (*gamma)->getTransitionIntensity()) { + + // Increment the shower number + // Yes, these internal transition gammas are counted as + // disintegrations! This is due to the metastable state. + ishower++; + + // Uniformly distribute decays over the experiment time + currentTime = rndm->getUniform() * Tmax; + + // Increment the counter of gammas and get the charge + (*gamma)->incrNumSampled(); + currentQ = (*gamma)->getCharge(); + + // Notice that we do NOT set the energy level of the daughter + // Instead, all of these are treated as uncorrelated + + // Get the gamma internal transition energy + E = (*gamma)->getDecayEnergy(); + + return E; + } + } + // XRays for (unsigned int i=0; i < xrayIntensities.size(); ++i) { if (u < xrayIntensities[i]) { @@ -1270,6 +1317,7 @@ class EGS_EXPORT EGS_RadionuclideSpectrum : public EGS_BaseSpectrum { vector myBetas; vector myAlphas; vector myGammas; + vector myMetastableGammas; vector myLevels; vector xrayIntensities, xrayEnergies, diff --git a/HEN_HOUSE/spectra/lnhb/Tc-99m.txt b/HEN_HOUSE/spectra/lnhb/Tc-99m.txt index beac6265d..5dac3985f 100644 --- a/HEN_HOUSE/spectra/lnhb/Tc-99m.txt +++ b/HEN_HOUSE/spectra/lnhb/Tc-99m.txt @@ -50,7 +50,7 @@ 99RU T 22.104 |] XKB4 99RU T 99TC P 142.683 1 1/2- 6.0067 H 10 293.52 20 - 99RU N 2.50E4 2.50E4 0.004 2.50E4 + 99RU N 2.50E4 2.50E4 0.00004 2.50E4 99RU L 0 5/2+ STABLE 99RU B 436.3 2 0.0010 3 9.4 1U 99RUS B EAV=152.3 5 From f141060374420ac35774e30678710d3f5ae80bb1 Mon Sep 17 00:00:00 2001 From: Reid Townson Date: Wed, 26 Oct 2016 14:24:53 -0400 Subject: [PATCH 16/34] Fix bugs in radionuclide source alpha emission Count alpha emissions as a disintegration again; a bug was introduced in the previous commit. Fix a crash that occurred when the ENSDF data contained a non-empty line with only whitespace. --- HEN_HOUSE/egs++/egs_ensdf.cpp | 12 +++++++++++- 1 file changed, 11 insertions(+), 1 deletion(-) diff --git a/HEN_HOUSE/egs++/egs_ensdf.cpp b/HEN_HOUSE/egs++/egs_ensdf.cpp index 881fce1ac..391646b59 100644 --- a/HEN_HOUSE/egs++/egs_ensdf.cpp +++ b/HEN_HOUSE/egs++/egs_ensdf.cpp @@ -306,6 +306,16 @@ void EGS_Ensdf::parseEnsdf(vector ensdf) { break; } } + if(!gotDisint) { + for (vector::iterator alpha = myAlphaRecords.begin(); + alpha != myAlphaRecords.end(); alpha++) { + + if ((*alpha)->getParentRecord() == *parent) { + gotDisint = true; + break; + } + } + } if (!gotDisint) { for (vector::iterator gamma = myGammaRecords.begin(); @@ -453,7 +463,7 @@ void EGS_Ensdf::buildRecords() { } for (int i = 0; i < recordStack.size(); i++) { - if (!recordStack[i].empty()) { + if (!recordStack[i].empty() && recordStack[i].front().length() > 5) { if (i==0) { } From e59b65bb178d3b5f30cbfb92fad2d0bced0c50d0 Mon Sep 17 00:00:00 2001 From: Reid Townson Date: Mon, 31 Oct 2016 11:50:29 -0400 Subject: [PATCH 17/34] Fix bug in radionuclide fluence for parallel runs Use ishower instead of count in storeState and addState for radionuclide parallel runs. --- .../egs_radionuclide_source.h | 12 ++++++------ 1 file changed, 6 insertions(+), 6 deletions(-) diff --git a/HEN_HOUSE/egs++/sources/egs_radionuclide_source/egs_radionuclide_source.h b/HEN_HOUSE/egs++/sources/egs_radionuclide_source/egs_radionuclide_source.h index f474ee7ae..31aba915d 100644 --- a/HEN_HOUSE/egs++/sources/egs_radionuclide_source/egs_radionuclide_source.h +++ b/HEN_HOUSE/egs++/sources/egs_radionuclide_source/egs_radionuclide_source.h @@ -271,7 +271,7 @@ class EGS_RADIONUCLIDE_SOURCE_EXPORT EGS_RadionuclideSource : * of the spectrum object and the storeFluenceState() virtual function. */ bool storeState(ostream &data_out) const { - if (!egsStoreI64(data_out,count)) { + if (!egsStoreI64(data_out,ishower)) { return false; } for (unsigned int i=0; iresetCounter(); } @@ -347,7 +347,7 @@ class EGS_RADIONUCLIDE_SOURCE_EXPORT EGS_RadionuclideSource : * function. */ bool setState(istream &data) { - if (!egsGetI64(data,count)) { + if (!egsGetI64(data,ishower)) { return false; } for (unsigned int i=0; i Date: Thu, 10 Nov 2016 14:31:00 -0500 Subject: [PATCH 18/34] Move radionuclide functions from header to source --- HEN_HOUSE/egs++/egs_ensdf.h | 3 +- .../egs_radionuclide_source.cpp | 111 +++++++++++++++++ .../egs_radionuclide_source.h | 114 +----------------- 3 files changed, 117 insertions(+), 111 deletions(-) diff --git a/HEN_HOUSE/egs++/egs_ensdf.h b/HEN_HOUSE/egs++/egs_ensdf.h index 8d763a81b..a21283c68 100644 --- a/HEN_HOUSE/egs++/egs_ensdf.h +++ b/HEN_HOUSE/egs++/egs_ensdf.h @@ -385,8 +385,7 @@ object oriented tree structure. This decay structure is useful for \ref EGS_RadionuclideSpectrum used by \ref EGS_RadionuclideSource. Uncertainties on values are ignored! The energies and intensities for various -emissions are taken as is. Very low intensities are not discarded, all -data is used. +emissions are taken as is. Very low intensities are discarded. When processing an ensdf file, only the following records are considered: Comment, Parent, Normalization, Level, Beta-, EC / Beta+, Alpha, Gamma. diff --git a/HEN_HOUSE/egs++/sources/egs_radionuclide_source/egs_radionuclide_source.cpp b/HEN_HOUSE/egs++/sources/egs_radionuclide_source/egs_radionuclide_source.cpp index f8c19f0ca..fadd62093 100644 --- a/HEN_HOUSE/egs++/sources/egs_radionuclide_source/egs_radionuclide_source.cpp +++ b/HEN_HOUSE/egs++/sources/egs_radionuclide_source/egs_radionuclide_source.cpp @@ -281,6 +281,62 @@ EGS_I64 EGS_RadionuclideSource::getNextParticle(EGS_RandomGenerator *rndm, int return ++count; } +void EGS_RadionuclideSource::getPositionDirection(EGS_RandomGenerator *rndm, + EGS_Vector &x, EGS_Vector &u, EGS_Float &wt) { + + bool ok = true; + do { + x = shape->getRandomPoint(rndm); + if (geom) { + if (gc == IncludeAll) { + ok = geom->isInside(x); + } + else if (gc == ExcludeAll) { + ok = !geom->isInside(x); + } + else if (gc == IncludeSelected) { + ok = false; + int ireg = geom->isWhere(x); + for (int j=0; jisWhere(x); + for (int j=0; jgetUniform()*(buf_1 - buf_2) - buf_1; + + EGS_Float sinz = 1-u.z*u.z; + if (sinz > 1e-15) { + sinz = sqrt(sinz); + EGS_Float cphi, sphi; + EGS_Float phi = min_phi +(max_phi - min_phi)*rndm->getUniform(); + cphi = cos(phi); + sphi = sin(phi); + u.x = sinz*cphi; + u.y = sinz*sphi; + } + else { + u.x = 0; + u.y = 0; + } + wt = 1; +} + void EGS_RadionuclideSource::setUp() { otype = "EGS_RadionuclideSource"; if (!isValid()) { @@ -310,6 +366,61 @@ void EGS_RadionuclideSource::setUp() { } } +bool EGS_RadionuclideSource::storeState(ostream &data_out) const { + if (!egsStoreI64(data_out,ishower)) { + return false; + } + for (unsigned int i=0; istoreState(data_out)) { + return false; + } + } + if (!storeFluenceState(data_out)) { + return false; + } + return true; +} + +bool EGS_RadionuclideSource::addState(istream &data) { + EGS_I64 count_save = ishower; + if (!egsGetI64(data,ishower)) { + return false; + } + for (unsigned int i=0; iaddState(data)) { + return false; + } + } + if (!addFluenceData(data)) { + return false; + } + ishower += count_save; + return true; +} + +void EGS_RadionuclideSource::resetCounter() { + ishower = 0; + for (unsigned int i=0; iresetCounter(); + } + resetFluenceCounter(); +} + +bool EGS_RadionuclideSource::setState(istream &data) { + if (!egsGetI64(data,ishower)) { + return false; + } + for (unsigned int i=0; isetState(data)) { + return false; + } + } + if (!setFluenceState(data)) { + return false; + } + return true; +} + extern "C" { EGS_RADIONUCLIDE_SOURCE_EXPORT EGS_BaseSource *createSource(EGS_Input diff --git a/HEN_HOUSE/egs++/sources/egs_radionuclide_source/egs_radionuclide_source.h b/HEN_HOUSE/egs++/sources/egs_radionuclide_source/egs_radionuclide_source.h index 31aba915d..7944a94a9 100644 --- a/HEN_HOUSE/egs++/sources/egs_radionuclide_source/egs_radionuclide_source.h +++ b/HEN_HOUSE/egs++/sources/egs_radionuclide_source/egs_radionuclide_source.h @@ -171,11 +171,6 @@ class EGS_RADIONUCLIDE_SOURCE_EXPORT EGS_RadionuclideSource : int &q, int &latch, EGS_Float &E, EGS_Float &wt, EGS_Vector &x, EGS_Vector &u); -// EGS_I64 getNextParticle(EGS_RandomGenerator *rndm, -// int &q, int &latch, EGS_Float &E, EGS_Float &wt, -// EGS_Vector &x, EGS_Vector &u, EGS_I64 &ishower, -// EGS_Float &time); - EGS_Float getEmax() const { return Emax; }; @@ -199,59 +194,7 @@ class EGS_RADIONUCLIDE_SOURCE_EXPORT EGS_RadionuclideSource : } void getPositionDirection(EGS_RandomGenerator *rndm, - EGS_Vector &x, EGS_Vector &u, EGS_Float &wt) { - bool ok = true; - do { - x = shape->getRandomPoint(rndm); - if (geom) { - if (gc == IncludeAll) { - ok = geom->isInside(x); - } - else if (gc == ExcludeAll) { - ok = !geom->isInside(x); - } - else if (gc == IncludeSelected) { - ok = false; - int ireg = geom->isWhere(x); - for (int j=0; jisWhere(x); - for (int j=0; jgetUniform()*(buf_1 - buf_2) - buf_1; - - EGS_Float sinz = 1-u.z*u.z; - if (sinz > 1e-15) { - sinz = sqrt(sinz); - EGS_Float cphi, sphi; - EGS_Float phi = min_phi +(max_phi - min_phi)*rndm->getUniform(); - cphi = cos(phi); - sphi = sin(phi); - u.x = sinz*cphi; - u.y = sinz*sphi; - } - else { - u.x = 0; - u.y = 0; - } - wt = 1; - }; + EGS_Vector &x, EGS_Vector &u, EGS_Float &wt); bool storeFluenceState(ostream &data) const { return true; @@ -270,20 +213,7 @@ class EGS_RADIONUCLIDE_SOURCE_EXPORT EGS_RadionuclideSource : * Uses the \link EGS_BaseSpectrum::storeState() storeState() \endlink * of the spectrum object and the storeFluenceState() virtual function. */ - bool storeState(ostream &data_out) const { - if (!egsStoreI64(data_out,ishower)) { - return false; - } - for (unsigned int i=0; istoreState(data_out)) { - return false; - } - } - if (!storeFluenceState(data_out)) { - return false; - } - return true; - }; + bool storeState(ostream &data_out) const; /*! \brief Add the source state from the stream \a data to the * current state. @@ -291,22 +221,7 @@ class EGS_RADIONUCLIDE_SOURCE_EXPORT EGS_RadionuclideSource : * Uses the \link EGS_BaseSpectrum::addState() addState() \endlink * of the spectrum object and the addFluenceData() virtual function. */ - bool addState(istream &data) { - EGS_I64 count_save = ishower; - if (!egsGetI64(data,ishower)) { - return false; - } - for (unsigned int i=0; iaddState(data)) { - return false; - } - } - if (!addFluenceData(data)) { - return false; - } - ishower += count_save; - return true; - }; + bool addState(istream &data); /*! \brief Reset the source to a state with zero sampled particles. * @@ -314,13 +229,7 @@ class EGS_RADIONUCLIDE_SOURCE_EXPORT EGS_RadionuclideSource : * function of the spectrum object and the virtual function * resetFluenceCounter(). */ - void resetCounter() { - ishower = 0; - for (unsigned int i=0; iresetCounter(); - } - resetFluenceCounter(); - }; + void resetCounter(); /*! \brief Add fluence data from the stream \a data to the current state. * @@ -346,20 +255,7 @@ class EGS_RADIONUCLIDE_SOURCE_EXPORT EGS_RadionuclideSource : * method of the spectrum object and the setFluenceState() virtual * function. */ - bool setState(istream &data) { - if (!egsGetI64(data,ishower)) { - return false; - } - for (unsigned int i=0; isetState(data)) { - return false; - } - } - if (!setFluenceState(data)) { - return false; - } - return true; - }; + bool setState(istream &data); protected: From b6662fb9f0714286c92df9d6cb9c09a122e9f88a Mon Sep 17 00:00:00 2001 From: Reid Townson Date: Wed, 30 Nov 2016 16:18:34 -0500 Subject: [PATCH 19/34] Fix radionuclide ENSDF x-ray intensities Fix a problem with the energies of x-rays from radionuclide sources using ENSDF files. In the cases where x-ray data is provided in ENSDF comments with a line denoting the 'total' contribution from a series of lines, don't rely on the total. Instead, assign each line its own probability. If the intensities are provided, use them. Otherwise, assign each line an equal fraction of the intensity from the 'total'. This change avoids a problem where a single x-ray line (total) could have an artificially large intensity, instead of several lower intensity lines. It also avoids having an x-ray line with a non-physical energy, since the 'total' lines may be an average of several lines. --- HEN_HOUSE/egs++/egs_ensdf.cpp | 96 +++++++++++++++++++++++++++++------ 1 file changed, 81 insertions(+), 15 deletions(-) diff --git a/HEN_HOUSE/egs++/egs_ensdf.cpp b/HEN_HOUSE/egs++/egs_ensdf.cpp index 391646b59..5cc678f0c 100644 --- a/HEN_HOUSE/egs++/egs_ensdf.cpp +++ b/HEN_HOUSE/egs++/egs_ensdf.cpp @@ -796,24 +796,76 @@ void EGS_Ensdf::getEmissionsFromComments() { bool gotTotal = false; vector multilineEnergies, multilineIntensities; + double lineTotalIntensity; + unsigned int countNumAfterTotal = 0; + int lineTotalType; for (vector::iterator comment = myCommentRecords.begin(); comment != myCommentRecords.end(); comment++) { string line = (*comment)->getComment(); - //TODO: Maybe we should sample one of the energies instead of using - // an average, using equal probability. Then the emissions have a - // sensible energy rather than a non-physical one. But the way - // we currently do it is the same as the Lara data files + //TODO: Maybe we should sample energies instead of using averages. + // Then we would avoid emissions with a non-physical energy. + // For multiple energy lines given a single intensity, we could + // split the intensity evenly between the lines. + // For energy ranges given for a single line, we could sample a Gaussian + // distributed energy within the range. // Check for the end of multi-line records // and average them together if (line.length() < 48 || ((xrayContinues || augerContinues) && line.at(30) != '|')) { + // If we just finished going through a series of + // lines that started with a "total" line at the top + // then we'll check to make sure they have intensities assigned if (gotTotal) { + + // In the event that a zero intensity is in one of the lines + // following the "total" line, ALL of those following + // lines are assigned an equal fraction of the total + // intensity. This is an imperfect work-around for insufficient + // data. Using this method, the correct energies are used, + // rather than assigning a single averaged "total" energy line. + if(countNumAfterTotal > 0) { + // X-rays + if(lineTotalType == 0) { + bool containsZeroIntensity = false; + for (std::vector::iterator it = xrayIntensities.end()-countNumAfterTotal; it != xrayIntensities.end(); ++it) { + if(*it < 1e-10) { + containsZeroIntensity = true; + break; + } + } + + if(containsZeroIntensity) { + for (std::vector::iterator it = xrayIntensities.end()-countNumAfterTotal; it != xrayIntensities.end(); ++it) { + *it = lineTotalIntensity / countNumAfterTotal; + } + } + + // Auger + } else if(lineTotalType == -1) { + bool containsZeroIntensity = false; + for (std::vector::iterator it = augerIntensities.end()-countNumAfterTotal; it != augerIntensities.end(); ++it) { + if(*it < 1e-10) { + containsZeroIntensity = true; + break; + } + } + + if(containsZeroIntensity) { + for (std::vector::iterator it = augerIntensities.end()-countNumAfterTotal; it != augerIntensities.end(); ++it) { + *it = lineTotalIntensity / countNumAfterTotal; + } + } + } + } + gotTotal = false; + countNumAfterTotal = 0; + lineTotalIntensity = 0.; } if ((xrayContinues || augerContinues) @@ -866,12 +918,6 @@ void EGS_Ensdf::getEmissionsFromComments() { // Check for records containing XRays or Auger electrons if (line.length() > 48) { - // Skip this line if we already recorded the total - // emission for the line - if (gotTotal) { - continue; - } - string emissionLine = egsTrimString(line.substr(47)); // See if the line is an XRay or Auger @@ -906,11 +952,27 @@ void EGS_Ensdf::getEmissionsFromComments() { // Get the intensity string iStr = egsTrimString(line.substr(32, 9)); double intensity = atof(iStr.c_str()); - + + // If this is a line coming after a "total" line, + // increment a counter. This will be used in the + // event that the lines following the "total" + // have zero intensity assigned + if(gotTotal && energy > 1e-10) { + countNumAfterTotal++; + } + // If this line is the total of the next lines, we will - // skip the next lines and just use this one + // skip this line and use the individual ones + // However, record the total intensity in case we need it if (emissionLine.find("(total)") != std::string::npos) { gotTotal = true; + lineTotalIntensity = intensity; + if (emissionLine.find("AUGER") != std::string::npos) { + lineTotalType = -1; + } else { + lineTotalType = 0; + } + continue; } // Multi-line records have a bar '|' at 30 @@ -929,14 +991,18 @@ void EGS_Ensdf::getEmissionsFromComments() { } else { if (emissionLine.at(0) == 'X') { - if (energy > 1e-10 && intensity > 1e-10) { + if ((energy > 1e-10 && intensity > 1e-10) || + (gotTotal && energy > 1e-10)) { xrayEnergies.push_back(energy); xrayIntensities.push_back(intensity); } } else if (emissionLine.find("AUGER") != std::string::npos) { - augerEnergies.push_back(energy); - augerIntensities.push_back(intensity); + if ((energy > 1e-10 && intensity > 1e-10) || + (gotTotal && energy > 1e-10)) { + augerEnergies.push_back(energy); + augerIntensities.push_back(intensity); + } } } } From 8fffdb746bcc26747f9833f2fa7303286dc11ea1 Mon Sep 17 00:00:00 2001 From: Reid Townson Date: Tue, 6 Dec 2016 11:37:36 -0500 Subject: [PATCH 20/34] Fix metastable bug, add fluorescence input Fix a segmentation fault for metastable radionuclides. Add input to control x-ray fluorescence and Auger electrons modelling. Add verbosity control. --- HEN_HOUSE/egs++/egs_ensdf.cpp | 207 ++++++++++++------ HEN_HOUSE/egs++/egs_ensdf.h | 15 +- HEN_HOUSE/egs++/egs_spectra.cpp | 37 +++- .../egs_radionuclide_source.cpp | 4 +- 4 files changed, 181 insertions(+), 82 deletions(-) diff --git a/HEN_HOUSE/egs++/egs_ensdf.cpp b/HEN_HOUSE/egs++/egs_ensdf.cpp index 5cc678f0c..205d1f8e8 100644 --- a/HEN_HOUSE/egs++/egs_ensdf.cpp +++ b/HEN_HOUSE/egs++/egs_ensdf.cpp @@ -37,7 +37,11 @@ #include "egs_ensdf.h" -EGS_Ensdf::EGS_Ensdf(const string isotope, const string ensdf_filename) { +EGS_Ensdf::EGS_Ensdf(const string isotope, const string ensdf_filename, + const string useFluor, int verbosity) { + + verbose = verbosity; + useFluorescence = useFluor; if (ensdf_file.is_open()) { ensdf_file.close(); @@ -49,9 +53,9 @@ EGS_Ensdf::EGS_Ensdf(const string isotope, const string ensdf_filename) { //string element = radionuclide.substr(0, radionuclide.find("-")); egsInformation("EGS_Ensdf::EGS_Ensdf: Isotope: " - "%s\n",isotope.c_str()); + "%s\n",isotope.c_str()); egsInformation("EGS_Ensdf::EGS_Ensdf: Now loading ensdf file: " - "\"%s\"\n",ensdf_filename.c_str()); + "\"%s\"\n",ensdf_filename.c_str()); ensdf_file.open(ensdf_filename.c_str(),ios::in); if (!ensdf_file.is_open()) { @@ -178,7 +182,14 @@ void EGS_Ensdf::parseEnsdf(vector ensdf) { for (vector::iterator it = ensdf.begin(); it!=ensdf.end(); it++) { string line = *it; - egsInformation("ENSDF::parseEnsdf: %s\n", line.c_str()); + + if(line.length() < 3) { + continue; + } + + if(verbose) { + egsInformation("EGS_Ensdf::parseEnsdf: %s\n", line.c_str()); + } if (line[6]==' ' && line[7]==' ' && line[8]==' ') { // Identification @@ -294,6 +305,9 @@ void EGS_Ensdf::parseEnsdf(vector ensdf) { // If no disintegrations exist for the parent, but we do have internal // transition (IT) gammas, then we must have a metastable radionuclide // In this case, add the gammas to the myMetastableGammaRecords vector + if(verbose) { + egsInformation("EGS_Ensdf::parseEnsdf: Checking for metastable radionuclides...\n"); + } for (vector::iterator parent = myParentRecords.begin(); parent!=myParentRecords.end(); parent++) { @@ -319,18 +333,33 @@ void EGS_Ensdf::parseEnsdf(vector ensdf) { if (!gotDisint) { for (vector::iterator gamma = myGammaRecords.begin(); - gamma != myGammaRecords.end(); gamma++) { + gamma < myGammaRecords.end(); gamma++) { if ((*gamma)->getParentRecord() == *parent) { myMetastableGammaRecords.push_back(*gamma); myGammaRecords.erase(gamma); } } + + if(verbose && myMetastableGammaRecords.size() > 0) { + egsInformation("EGS_Ensdf::parseEnsdf: Metastable isotope " + "detected.\n"); + } } } + if(verbose && myMetastableGammaRecords.size() < 1) { + egsInformation("EGS_Ensdf::parseEnsdf: No metastable isotopes " + "detected.\n"); + } // Get X-ray and auger emissions from comments - getEmissionsFromComments(); + if(useFluorescence == "yes") { + if(verbose) { + egsInformation("EGS_Ensdf::parseEnsdf: Checking for x-rays and Auger...\n"); + } + + getEmissionsFromComments(); + } // Get rid of very low emission probability particles double minimumIntensity = 1e-6; @@ -365,10 +394,15 @@ void EGS_Ensdf::parseEnsdf(vector ensdf) { // states of the daughter, we will treat this gamma as an xray // The halflife will be ignored - egsInformation("EGS_Ensdf::parseEnsdf: Switching gamma with unknown " - "level to X-Ray for non-correlated sampling\n"); + egsInformation("EGS_Ensdf::parseEnsdf: Warning: Switching gamma " + "with unknown decay level to X-Ray (for " + "non-correlated sampling)\n"); + xrayEnergies.push_back((*it)->getDecayEnergy()); xrayIntensities.push_back((*it)->getTransitionIntensity()); + + egsInformation("EGS_Ensdf::parseEnsdf: X-Ray added (E,I): %f %f\n", + xrayEnergies.back(), xrayIntensities.back()); // Erase the gamma record object myGammaRecords.erase(it); @@ -399,9 +433,6 @@ void EGS_Ensdf::parseEnsdf(vector ensdf) { if ((*gamma)->getLevelRecord() == (*it)) { totalLevelIntensity[j] += (*gamma)->getTransitionIntensity(); - egsInformation("EGS_Ensdf::normalizeIntensities: %d %f %f\n", j, - (*gamma)->getTransitionIntensity(), - totalLevelIntensity[j]); } } @@ -430,12 +461,16 @@ void EGS_Ensdf::parseEnsdf(vector ensdf) { } for (unsigned int i=0; i < xrayEnergies.size(); ++i) { - egsInformation("EGS_Ensdf::parseEnsdf: XRays (E,I): %f %f\n", - xrayEnergies[i], xrayIntensities[i]); + if(verbose) { + egsInformation("EGS_Ensdf::parseEnsdf: XRays (E,I): %f %f\n", + xrayEnergies[i], xrayIntensities[i]); + } } for (unsigned int i=0; i < augerEnergies.size(); ++i) { - egsInformation("EGS_Ensdf::parseEnsdf: Auger (E,I): %f %f\n", - augerEnergies[i], augerIntensities[i]); + if(verbose) { + egsInformation("EGS_Ensdf::parseEnsdf: Auger (E,I): %f %f\n", + augerEnergies[i], augerIntensities[i]); + } } } @@ -522,6 +557,11 @@ void EGS_Ensdf::buildRecords() { // Normalize intensities for alpha, beta, gamma objects void EGS_Ensdf::normalizeIntensities() { + if(verbose) { + egsInformation("EGS_Ensdf::normalizeIntensities: Normalizing the " + "emission intensities to allow for spectrum sampling " + "routines.\n"); + } // Add up the beta, alpha, xray and auger decay intensities double totalDecayIntensity = 0; @@ -529,16 +569,20 @@ void EGS_Ensdf::normalizeIntensities() { for (vector::iterator beta = myBetaRecords.begin(); beta != myBetaRecords.end(); beta++) { - egsInformation("EGS_Ensdf::normalizeIntensities: Beta (E,I): %f %f\n", - (*beta)->getFinalEnergy(), (*beta)->getBetaIntensity()); + if(verbose > 1) { + egsInformation("EGS_Ensdf::normalizeIntensities: Beta (E,I): %f %f\n", + (*beta)->getFinalEnergy(), (*beta)->getBetaIntensity()); + } totalDecayIntensity += (*beta)->getBetaIntensity(); } for (vector::iterator alpha = myAlphaRecords.begin(); alpha != myAlphaRecords.end(); alpha++) { - egsInformation("EGS_Ensdf::normalizeIntensities: Alpha (E,I): %f %f\n", - (*alpha)->getFinalEnergy(), (*alpha)->getAlphaIntensity()); + if(verbose > 1) { + egsInformation("EGS_Ensdf::normalizeIntensities: Alpha (E,I): %f %f\n", + (*alpha)->getFinalEnergy(), (*alpha)->getAlphaIntensity()); + } totalDecayIntensity += (*alpha)->getAlphaIntensity(); } @@ -546,9 +590,11 @@ void EGS_Ensdf::normalizeIntensities() { for (vector::iterator gamma = myMetastableGammaRecords.begin(); gamma != myMetastableGammaRecords.end(); gamma++) { - egsInformation("EGS_Ensdf::normalizeIntensities: MetastableGamma (E,I): %f %f\n", - (*gamma)->getDecayEnergy(), - (*gamma)->getTransitionIntensity()); + if(verbose > 1) { + egsInformation("EGS_Ensdf::normalizeIntensities: MetastableGamma (E,I): %f %f\n", + (*gamma)->getDecayEnergy(), + (*gamma)->getTransitionIntensity()); + } totalMetastableGammaIntensity += (*gamma)->getTransitionIntensity(); totalDecayIntensity += (*gamma)->getTransitionIntensity(); @@ -557,7 +603,9 @@ void EGS_Ensdf::normalizeIntensities() { double metastableFailIntensity = 100. - totalMetastableGammaIntensity; totalDecayIntensity += metastableFailIntensity; - egsInformation("EGS_Ensdf::normalizeIntensities: MetastableGamma adds to less than 100\%. Fail chance: %f\n", metastableFailIntensity); + if(verbose) { + egsInformation("EGS_Ensdf::normalizeIntensities: MetastableGamma adds to less than 100%%. Fail chance (per 100 disintegrations): %f\n", metastableFailIntensity); + } // Push a copy of the last metastable gamma onto the vector myMetastableGammaRecords.push_back(new GammaRecord(myMetastableGammaRecords.back())); @@ -567,20 +615,28 @@ void EGS_Ensdf::normalizeIntensities() { myMetastableGammaRecords.back()->setTransitionIntensity(metastableFailIntensity); } for (unsigned int i=0; i < xrayIntensities.size(); ++i) { - egsInformation("EGS_Ensdf::normalizeIntensities: XRay (E,I): %f %f\n", - xrayEnergies[i], xrayIntensities[i]); + if(verbose > 1) { + egsInformation("EGS_Ensdf::normalizeIntensities: XRay (E,I): %f %f\n", + xrayEnergies[i], xrayIntensities[i]); + } totalDecayIntensity += xrayIntensities[i]; } for (unsigned int i=0; i < augerIntensities.size(); ++i) { - egsInformation("EGS_Ensdf::normalizeIntensities: Auger (E,I): %f %f\n", - augerEnergies[i], augerIntensities[i]); + if(verbose > 1) { + egsInformation("EGS_Ensdf::normalizeIntensities: Auger (E,I): %f %f\n", + augerEnergies[i], augerIntensities[i]); + } totalDecayIntensity += augerIntensities[i]; } - egsInformation("EGS_Ensdf::normalizeIntensities: totalDecayIntensity: " - "%f\n",totalDecayIntensity); + if(verbose) { + egsInformation("EGS_Ensdf::normalizeIntensities: totalDecayIntensity: " + "%f\n",totalDecayIntensity); + egsInformation("EGS_Ensdf::normalizeIntensities: " + "Calculating renormalized intensities...\n"); + } // Normalize beta emission intensities for (vector::iterator beta = myBetaRecords.begin(); @@ -595,8 +651,10 @@ void EGS_Ensdf::normalizeIntensities() { } lastIntensity = (*beta)->getBetaIntensity(); - egsInformation("EGS_Ensdf::normalizeIntensities: Beta (E,I): %f %f\n", - (*beta)->getFinalEnergy(), (*beta)->getBetaIntensity()); + if(verbose) { + egsInformation("EGS_Ensdf::normalizeIntensities: Beta (E,I): %f %f\n", + (*beta)->getFinalEnergy(), (*beta)->getBetaIntensity()); + } } // Normalize alpha emission intensities @@ -617,8 +675,10 @@ void EGS_Ensdf::normalizeIntensities() { } lastIntensity = (*alpha)->getAlphaIntensity(); - egsInformation("EGS_Ensdf::normalizeIntensities: Alpha (E,I): %f %f\n", - (*alpha)->getFinalEnergy(), (*alpha)->getAlphaIntensity()); + if(verbose) { + egsInformation("EGS_Ensdf::normalizeIntensities: Alpha (E,I): %f %f\n", + (*alpha)->getFinalEnergy(), (*alpha)->getAlphaIntensity()); + } } // Normalize metastable gamma transition intensities @@ -639,8 +699,10 @@ void EGS_Ensdf::normalizeIntensities() { } lastIntensity = (*gamma)->getTransitionIntensity(); - egsInformation("EGS_Ensdf::normalizeIntensities: MetastableGamma (E,I): %f %f\n", - (*gamma)->getDecayEnergy(), (*gamma)->getTransitionIntensity()); + if(verbose) { + egsInformation("EGS_Ensdf::normalizeIntensities: MetastableGamma (E,I): %f %f\n", + (*gamma)->getDecayEnergy(), (*gamma)->getTransitionIntensity()); + } } // Normalize XRay emission intensities @@ -655,8 +717,10 @@ void EGS_Ensdf::normalizeIntensities() { } lastIntensity = xrayIntensities[i]; - egsInformation("EGS_Ensdf::normalizeIntensities: XRay (E,I): %f %f\n", - xrayEnergies[i], xrayIntensities[i]); + if(verbose) { + egsInformation("EGS_Ensdf::normalizeIntensities: XRay (E,I): %f %f\n", + xrayEnergies[i], xrayIntensities[i]); + } } // Normalize auger emission intensities @@ -671,8 +735,10 @@ void EGS_Ensdf::normalizeIntensities() { } lastIntensity = augerIntensities[i]; - egsInformation("EGS_Ensdf::normalizeIntensities: Auger (E,I): %f %f\n", - augerEnergies[i], augerIntensities[i]); + if(verbose) { + egsInformation("EGS_Ensdf::normalizeIntensities: Auger (E,I): %f %f\n", + augerEnergies[i], augerIntensities[i]); + } } // Determine the final level that the gammas decay towards @@ -685,9 +751,12 @@ void EGS_Ensdf::normalizeIntensities() { double guessedLevelEnergy = ((*gamma)->getLevelRecord()->getEnergy() - energy); - egsInformation("EGS_Ensdf::normalizeIntensities: Gamma (LE,E,GE): " - "%f %f %f\n",(*gamma)->getLevelRecord()->getEnergy(), - energy, guessedLevelEnergy); + if(verbose) { + egsInformation("EGS_Ensdf::normalizeIntensities: Gamma " + "(LevelE,E,GuessedE): " + "%f %f %f\n",(*gamma)->getLevelRecord()->getEnergy(), + energy, guessedLevelEnergy); + } double bestMatch = 1E10; LevelRecord *level; @@ -704,17 +773,20 @@ void EGS_Ensdf::normalizeIntensities() { } } if (bestMatch == 1E10) { - egsInformation("EGS_Ensdf::normalizeIntensities: Warning: Could not find a " - "level with energy matching decay of gamma with energy E=%f, " - "assuming ground state\n",energy); + egsWarning("EGS_Ensdf::normalizeIntensities: Warning: Could " + "not find a level with energy matching decay " + "of gamma with energy E=%f; " + "assuming final level is ground state\n",energy); (*gamma)->setFinalLevel(myLevelRecords.front()); } else { (*gamma)->setFinalLevel(level); } - egsInformation("EGS_Ensdf::normalizeIntensities: Gamma (final level E): " - "%f\n",level->getEnergy()); + if(verbose) { + egsInformation("EGS_Ensdf::normalizeIntensities: Gamma (final level E): " + "%f\n",level->getEnergy()); + } (*gamma)->getFinalLevel()->cumulDisintegrationIntensity((*gamma)->getTransitionIntensity()); } @@ -735,15 +807,15 @@ void EGS_Ensdf::normalizeIntensities() { if ((*gamma)->getLevelRecord() == (*it)) { totalLevelIntensity[j] += (*gamma)->getTransitionIntensity(); - egsInformation("EGS_Ensdf::normalizeIntensities: %d %f %f\n", j, - (*gamma)->getTransitionIntensity(), - totalLevelIntensity[j]); } } if (disintIntensity > 1e-10 && totalLevelIntensity[j] < disintIntensity + 1e-10) { totalLevelIntensity[j] = disintIntensity; - egsInformation("EGS_Ensdf::normalizeIntensities: disintegrationIntensity %f\n", totalLevelIntensity[j]); + if(verbose > 1) { + egsInformation("EGS_Ensdf::normalizeIntensities: " + "disintegrationIntensity: %f\n", totalLevelIntensity[j]); + } } ++j; } @@ -774,8 +846,12 @@ void EGS_Ensdf::normalizeIntensities() { } ++i; - egsInformation("EGS_Ensdf::normalizeIntensities: Gamma (L,E,I): " - "%d %f %f\n",j,(*gamma)->getDecayEnergy(), (*gamma)->getTransitionIntensity()); + if(verbose > 1) { + egsInformation("EGS_Ensdf::normalizeIntensities: " + "Gamma (level,E,I): " + "%d %f %f\n", + j,(*gamma)->getDecayEnergy(), (*gamma)->getTransitionIntensity()); + } } } @@ -791,6 +867,10 @@ void EGS_Ensdf::normalizeIntensities() { } void EGS_Ensdf::getEmissionsFromComments() { + if(verbose) { + egsInformation("EGS_Ensdf::getEmissionsFromComments: Attempting to obtain x-ray and Auger emissions from the ENSDF comments. This assumes a particular comment format...\n"); + } + bool xrayContinues = false; bool augerContinues = false; bool gotTotal = false; @@ -1092,7 +1172,6 @@ double Record::parseHalfLife(int startPos, int endPos) { string halfLifeStr = egsTrimString(lines.front().substr(startPos-1, endPos-startPos+1)); - egsInformation("Record::parseHalfLife: %s\n", halfLifeStr.c_str()); // Return -1 for stable if (halfLifeStr.substr(0,5).compare("STABLE") == 0) { @@ -1196,8 +1275,8 @@ unsigned short int Record::setZ(string id) { unsigned short int Z = findZ(element); if (Z == 0) { - egsWarning("EGS_Ensdf::createIsotope: element does not exist in our " - "data (%s)\n", element.c_str()); + egsWarning("EGS_Ensdf::createIsotope: Warning: Element does not exist " + "in our data (%s)\n", element.c_str()); } return Z; @@ -1377,8 +1456,6 @@ void ParentRecord::processEnsdf() { "positron records will give errors\n"); Q = 0.; } - - egsInformation("ParentRecord::processEnsdf: %f %f\n", halfLife, Q); } double ParentRecord::getHalfLife() const { @@ -1409,9 +1486,6 @@ void NormalizationRecord::processEnsdf() { normalizeTransition = recordToDouble(22, 29); normalizeBranch = recordToDouble(32, 39); normalizeBeta = recordToDouble(42, 49); - egsInformation("NormalizationRecord::processEnsdf: %f %f %f %f\n", - normalizeRelative, normalizeTransition, normalizeBranch, - normalizeBeta); } // Multiplier for converting relative photon intensity to photons per 100 @@ -1466,7 +1540,6 @@ LevelRecord::LevelRecord(vector ensdf): void LevelRecord::processEnsdf() { energy = recordToDouble(10, 19) / 1000.; // Convert keV to MeV halfLife = recordToDouble(40, 49); - egsInformation("LevelRecord::processEnsdf: %f %f\n", energy, halfLife); } void LevelRecord::setLevelCanDecay(bool canDecayTmp) { @@ -1585,8 +1658,6 @@ void BetaMinusRecord::processEnsdf() { betaIntensity *= getNormalizationRecord()->getBetaMultiplier() * getNormalizationRecord()->getBranchMultiplier(); } - egsInformation("BetaMinusRecord::processEnsdf: %f %f\n", finalEnergy, - betaIntensity); } double BetaMinusRecord::getFinalEnergy() const { @@ -1645,9 +1716,6 @@ void BetaPlusRecord::processEnsdf() { finalEnergy = 0.; } } - - egsInformation("BetaPlusRecord::processEnsdf: %f %f %f\n", finalEnergy, - positronIntensity, ecIntensity); } double BetaPlusRecord::getFinalEnergy() const { @@ -1709,9 +1777,6 @@ void GammaRecord::processEnsdf() { getNormalizationRecord()->getRelativeMultiplier() * getNormalizationRecord()->getBranchMultiplier(); } - - egsInformation("GammaRecord::processEnsdf: %f %f\n", decayEnergy, - transitionIntensity); } double GammaRecord::getDecayEnergy() const { @@ -1764,8 +1829,6 @@ AlphaRecord::AlphaRecord(vector ensdf, void AlphaRecord::processEnsdf() { finalEnergy = recordToDouble(10, 19) / 1000.; // Convert keV to MeV alphaIntensity = recordToDouble(22, 29); - egsInformation("AlphaRecord::processEnsdf: %f %f\n", finalEnergy, - alphaIntensity); } double AlphaRecord::getFinalEnergy() const { diff --git a/HEN_HOUSE/egs++/egs_ensdf.h b/HEN_HOUSE/egs++/egs_ensdf.h index a21283c68..5690f254b 100644 --- a/HEN_HOUSE/egs++/egs_ensdf.h +++ b/HEN_HOUSE/egs++/egs_ensdf.h @@ -400,9 +400,10 @@ case below a single line of energy 97.4527 keV would be used. 221FR T 97.474 |] 0.57 5 XKB1 221FR T 98.069 |] XKB5II \endverbatim -If an energy and intensity are given for the total of several lines, it is -used instead of those lines. For example, in the case below a single line -of energy 14.0895 keV would be used. +If an energy and intensity are given for the "total" of several lines, it is +only used if the intensities of the individual lines are not provided. +For example, in the case below a single line of energy 14.0895 keV +would be used. \verbatim 221FR T 10.38-17.799 18.7 9 XL (total) 221FR T 10.38 XLL @@ -415,6 +416,9 @@ of energy 14.0895 keV would be used. The ensdf class has been tested on radionuclide data from http://www.nucleide.org/DDEP_WG/DDEPdata.htm +ENSDF files from other sources may contain x-ray and Auger emissions formatted +differently. In this case, the x-ray and Auger lines will not be modeled. + */ class EGS_EXPORT EGS_Ensdf { @@ -424,7 +428,8 @@ class EGS_EXPORT EGS_Ensdf { /*! \brief Construct an ensdf object. * */ - EGS_Ensdf(const string isotope, const string ensdf_filename=""); + EGS_Ensdf(const string isotope, const string ensdf_filename="", + const string useFluor="yes", int verbosity=1); /*! \brief Destructor. */ ~EGS_Ensdf(); @@ -442,6 +447,8 @@ class EGS_EXPORT EGS_Ensdf { vector getAugerEnergies() const; string radionuclide; + int verbose; + string useFluorescence; void normalizeIntensities(); diff --git a/HEN_HOUSE/egs++/egs_spectra.cpp b/HEN_HOUSE/egs++/egs_spectra.cpp index f0312b0df..8671e410a 100644 --- a/HEN_HOUSE/egs++/egs_spectra.cpp +++ b/HEN_HOUSE/egs++/egs_spectra.cpp @@ -885,6 +885,9 @@ It is defined using the following input including extension weight = [optional] the relative activity (sampling probability) for this isotope in a mixture + use fluorescence and auger = [optional, default=yes] yes or no + whether or not to model the x-ray and Auger + emissions provided in the ensdf file :stop spectrum: :start spectrum: type = radionuclide @@ -901,12 +904,18 @@ class EGS_EXPORT EGS_RadionuclideSpectrum : public EGS_BaseSpectrum { /*! \brief Construct a radionuclide spectrum. */ EGS_RadionuclideSpectrum(const string isotope, const string ensdf_file, - const EGS_Float weight) : + const EGS_Float weight, const string useFluorescence) : EGS_BaseSpectrum() { + // For now, hard-code verbose mode + // 0 - minimal output + // 1 - some output of ensdf data and normalized intensities + // 2 - verbose output + int verbose = 1; + // Read in the data file for the isotope // and build the decay structure - decays = new EGS_Ensdf(isotope, ensdf_file); + decays = new EGS_Ensdf(isotope, ensdf_file, useFluorescence, verbose); // Normalize the emission and transition intensities decays->normalizeIntensities(); @@ -981,8 +990,10 @@ class EGS_EXPORT EGS_RadionuclideSpectrum : public EGS_BaseSpectrum { // Set the weight of the spectrum spectrumWeight = weight; - egsInformation("EGS_RadionuclideSpectrum: Emax: %f\n",Emax); - egsInformation("EGS_RadionuclideSpectrum: Weight: %f\n",weight); + if(verbose) { + egsInformation("EGS_RadionuclideSpectrum: Emax: %f\n",Emax); + egsInformation("EGS_RadionuclideSpectrum: Weight: %f\n",weight); + } }; ~EGS_RadionuclideSpectrum() { @@ -1708,6 +1719,22 @@ EGS_BaseSpectrum *EGS_BaseSpectrum::createSpectrum(EGS_Input *input) { if (err) { weight = 1; } + + // Determine whether to sample X-Rays and Auger electrons + // using the ensdf data (options: yes or no) + string tmp_useFl, useFluorescence; + err = inp->getInput("use fluorescence and auger", tmp_useFl); + if (!err) { + useFluorescence = tmp_useFl; + } + else { + useFluorescence = "yes"; + } + if(useFluorescence == "yes") { + egsInformation("EGS_BaseSpectrum::createSpectrum: Fluorescence and auger from the ensdf file will be used.\n"); + } else { + egsInformation("EGS_BaseSpectrum::createSpectrum: Fluorescence and auger from the ensdf file will be ignored.\n"); + } // For ensdf input, first check for the input argument string ensdf_file; @@ -1750,7 +1777,7 @@ EGS_BaseSpectrum *EGS_BaseSpectrum::createSpectrum(EGS_Input *input) { ensdf_fh.close(); // Create the spectrum - spec = new EGS_RadionuclideSpectrum(isotope, ensdf_file, weight); + spec = new EGS_RadionuclideSpectrum(isotope, ensdf_file, weight, useFluorescence); } else { egsWarning("%s unknown spectrum type %s\n",spec_msg1,stype.c_str()); diff --git a/HEN_HOUSE/egs++/sources/egs_radionuclide_source/egs_radionuclide_source.cpp b/HEN_HOUSE/egs++/sources/egs_radionuclide_source/egs_radionuclide_source.cpp index fadd62093..1210d81ea 100644 --- a/HEN_HOUSE/egs++/sources/egs_radionuclide_source/egs_radionuclide_source.cpp +++ b/HEN_HOUSE/egs++/sources/egs_radionuclide_source/egs_radionuclide_source.cpp @@ -151,8 +151,10 @@ EGS_RadionuclideSource::EGS_RadionuclideSource(EGS_Input *input, "input to determine 'ncase'\n"); } + //TODO: Currently the Tmax is incorrect, because it is based on + // ncase, which is NOT the number of disintegrations double Tmax = ncase_double / activity; - egsInformation("EGS_RadionuclideSource: Duration of experiment [s]: %e\n", + egsInformation("EGS_RadionuclideSource: Duration of experiment (CURRENTLY INCORRECT) [s]: %e\n", Tmax); for (i=0; isetMaximumTime(Tmax); From 1f292122eacb7cdd496373e53eba30a8124425d4 Mon Sep 17 00:00:00 2001 From: Reid Townson Date: Wed, 7 Dec 2016 15:51:39 -0500 Subject: [PATCH 21/34] Fix radionuclide bug for low intensity records Fix a segmentation fault that occurred when low intensity beta or alpha records were erased. Tidy up formatting. --- HEN_HOUSE/egs++/egs_ensdf.cpp | 225 +++++++++++++++++--------------- HEN_HOUSE/egs++/egs_ensdf.h | 8 +- HEN_HOUSE/egs++/egs_spectra.cpp | 11 +- 3 files changed, 131 insertions(+), 113 deletions(-) diff --git a/HEN_HOUSE/egs++/egs_ensdf.cpp b/HEN_HOUSE/egs++/egs_ensdf.cpp index 205d1f8e8..84d2e148e 100644 --- a/HEN_HOUSE/egs++/egs_ensdf.cpp +++ b/HEN_HOUSE/egs++/egs_ensdf.cpp @@ -37,9 +37,9 @@ #include "egs_ensdf.h" -EGS_Ensdf::EGS_Ensdf(const string isotope, const string ensdf_filename, +EGS_Ensdf::EGS_Ensdf(const string isotope, const string ensdf_filename, const string useFluor, int verbosity) { - + verbose = verbosity; useFluorescence = useFluor; @@ -53,9 +53,9 @@ EGS_Ensdf::EGS_Ensdf(const string isotope, const string ensdf_filename, //string element = radionuclide.substr(0, radionuclide.find("-")); egsInformation("EGS_Ensdf::EGS_Ensdf: Isotope: " - "%s\n",isotope.c_str()); + "%s\n",isotope.c_str()); egsInformation("EGS_Ensdf::EGS_Ensdf: Now loading ensdf file: " - "\"%s\"\n",ensdf_filename.c_str()); + "\"%s\"\n",ensdf_filename.c_str()); ensdf_file.open(ensdf_filename.c_str(),ios::in); if (!ensdf_file.is_open()) { @@ -182,12 +182,12 @@ void EGS_Ensdf::parseEnsdf(vector ensdf) { for (vector::iterator it = ensdf.begin(); it!=ensdf.end(); it++) { string line = *it; - - if(line.length() < 3) { + + if (line.length() < 3) { continue; } - - if(verbose) { + + if (verbose) { egsInformation("EGS_Ensdf::parseEnsdf: %s\n", line.c_str()); } @@ -305,7 +305,7 @@ void EGS_Ensdf::parseEnsdf(vector ensdf) { // If no disintegrations exist for the parent, but we do have internal // transition (IT) gammas, then we must have a metastable radionuclide // In this case, add the gammas to the myMetastableGammaRecords vector - if(verbose) { + if (verbose) { egsInformation("EGS_Ensdf::parseEnsdf: Checking for metastable radionuclides...\n"); } for (vector::iterator parent = myParentRecords.begin(); @@ -320,7 +320,7 @@ void EGS_Ensdf::parseEnsdf(vector ensdf) { break; } } - if(!gotDisint) { + if (!gotDisint) { for (vector::iterator alpha = myAlphaRecords.begin(); alpha != myAlphaRecords.end(); alpha++) { @@ -333,47 +333,66 @@ void EGS_Ensdf::parseEnsdf(vector ensdf) { if (!gotDisint) { for (vector::iterator gamma = myGammaRecords.begin(); - gamma < myGammaRecords.end(); gamma++) { + gamma < myGammaRecords.end();) { if ((*gamma)->getParentRecord() == *parent) { myMetastableGammaRecords.push_back(*gamma); myGammaRecords.erase(gamma); } + else { + gamma++; + } } - - if(verbose && myMetastableGammaRecords.size() > 0) { + + if (verbose && myMetastableGammaRecords.size() > 0) { egsInformation("EGS_Ensdf::parseEnsdf: Metastable isotope " "detected.\n"); } } } - if(verbose && myMetastableGammaRecords.size() < 1) { + if (verbose && myMetastableGammaRecords.size() < 1) { egsInformation("EGS_Ensdf::parseEnsdf: No metastable isotopes " - "detected.\n"); + "detected.\n"); } // Get X-ray and auger emissions from comments - if(useFluorescence == "yes") { - if(verbose) { + if (useFluorescence == "yes") { + if (verbose) { egsInformation("EGS_Ensdf::parseEnsdf: Checking for x-rays and Auger...\n"); } - + getEmissionsFromComments(); + + if (verbose > 1) { + egsInformation("EGS_Ensdf::parseEnsdf: Done checking for x-rays and Auger.\n"); + } } // Get rid of very low emission probability particles double minimumIntensity = 1e-6; for (vector::iterator beta = myBetaRecords.begin(); - beta != myBetaRecords.end(); beta++) { + beta != myBetaRecords.end();) { if ((*beta)->getBetaIntensity() <= minimumIntensity) { + if (verbose) { + egsInformation("EGS_Ensdf::parseEnsdf: Removing beta due to small intensity (%.1e < %.1e)\n",(*beta)->getBetaIntensity(),minimumIntensity); + } myBetaRecords.erase(beta); } + else { + beta++; + } } for (vector::iterator alpha = myAlphaRecords.begin(); - alpha != myAlphaRecords.end(); alpha++) { + alpha != myAlphaRecords.end();) { if ((*alpha)->getAlphaIntensity() <= minimumIntensity) { + if (verbose) { + egsInformation("EGS_Ensdf::parseEnsdf: Removing alpha due to small intensity (%.1e < %.1e)\n",(*alpha)->getAlphaIntensity(),minimumIntensity); + } myAlphaRecords.erase(alpha); } + else { + alpha++; + } } // Search through the gamma records for any with unknown levels @@ -382,6 +401,9 @@ void EGS_Ensdf::parseEnsdf(vector ensdf) { it!=myGammaRecords.end();) { if ((*it)->getTransitionIntensity() <= minimumIntensity) { + if (verbose) { + egsInformation("EGS_Ensdf::parseEnsdf: Removing gamma due to small intensity (%.1e < %.1e)\n",(*it)->getTransitionIntensity(),minimumIntensity); + } // Throw away gammas with low probability // Erase the gamma record object myGammaRecords.erase(it); @@ -394,15 +416,12 @@ void EGS_Ensdf::parseEnsdf(vector ensdf) { // states of the daughter, we will treat this gamma as an xray // The halflife will be ignored - egsInformation("EGS_Ensdf::parseEnsdf: Warning: Switching gamma " - "with unknown decay level to X-Ray (for " - "non-correlated sampling)\n"); - + egsWarning("EGS_Ensdf::parseEnsdf: Warning: Switching gamma with unknown decay level to X-Ray (these emissions will still occur, but uncorrelated with disintegrations).\n"); + xrayEnergies.push_back((*it)->getDecayEnergy()); xrayIntensities.push_back((*it)->getTransitionIntensity()); - - egsInformation("EGS_Ensdf::parseEnsdf: X-Ray added (E,I): %f %f\n", - xrayEnergies.back(), xrayIntensities.back()); + + egsInformation("EGS_Ensdf::parseEnsdf: Gamma converted to X-Ray (E,I): %f %f\n", xrayEnergies.back(), xrayIntensities.back()); // Erase the gamma record object myGammaRecords.erase(it); @@ -419,6 +438,9 @@ void EGS_Ensdf::parseEnsdf(vector ensdf) { // uncorrelated with the disintegrations. // To account for this, we convert a fraction of those gamma transitions // into X-Rays. + if (verbose) { + egsInformation("EGS_Ensdf::parseEnsdf: Comparing the cumulative disintegration intensity of each level with the gamma transition intensities... \n"); + } unsigned int j = 0; vector totalLevelIntensity; totalLevelIntensity.resize(myLevelRecords.size()); @@ -461,15 +483,15 @@ void EGS_Ensdf::parseEnsdf(vector ensdf) { } for (unsigned int i=0; i < xrayEnergies.size(); ++i) { - if(verbose) { + if (verbose) { egsInformation("EGS_Ensdf::parseEnsdf: XRays (E,I): %f %f\n", - xrayEnergies[i], xrayIntensities[i]); + xrayEnergies[i], xrayIntensities[i]); } } for (unsigned int i=0; i < augerEnergies.size(); ++i) { - if(verbose) { + if (verbose) { egsInformation("EGS_Ensdf::parseEnsdf: Auger (E,I): %f %f\n", - augerEnergies[i], augerIntensities[i]); + augerEnergies[i], augerIntensities[i]); } } } @@ -541,8 +563,8 @@ void EGS_Ensdf::buildRecords() { lastNormalization, lastLevel)); } else if (i==11) { - egsInformation("EGS_Ensdf::buildRecords: Warning: Delayed particle not " - "supported! Further development required.\n"); + egsWarning("EGS_Ensdf::buildRecords: Warning: Delayed particle not " + "supported! Further development required.\n"); } else if (i==12) { myGammaRecords.push_back(new @@ -557,7 +579,7 @@ void EGS_Ensdf::buildRecords() { // Normalize intensities for alpha, beta, gamma objects void EGS_Ensdf::normalizeIntensities() { - if(verbose) { + if (verbose) { egsInformation("EGS_Ensdf::normalizeIntensities: Normalizing the " "emission intensities to allow for spectrum sampling " "routines.\n"); @@ -569,9 +591,9 @@ void EGS_Ensdf::normalizeIntensities() { for (vector::iterator beta = myBetaRecords.begin(); beta != myBetaRecords.end(); beta++) { - if(verbose > 1) { + if (verbose > 1) { egsInformation("EGS_Ensdf::normalizeIntensities: Beta (E,I): %f %f\n", - (*beta)->getFinalEnergy(), (*beta)->getBetaIntensity()); + (*beta)->getFinalEnergy(), (*beta)->getBetaIntensity()); } totalDecayIntensity += (*beta)->getBetaIntensity(); @@ -579,9 +601,9 @@ void EGS_Ensdf::normalizeIntensities() { for (vector::iterator alpha = myAlphaRecords.begin(); alpha != myAlphaRecords.end(); alpha++) { - if(verbose > 1) { + if (verbose > 1) { egsInformation("EGS_Ensdf::normalizeIntensities: Alpha (E,I): %f %f\n", - (*alpha)->getFinalEnergy(), (*alpha)->getAlphaIntensity()); + (*alpha)->getFinalEnergy(), (*alpha)->getAlphaIntensity()); } totalDecayIntensity += (*alpha)->getAlphaIntensity(); @@ -590,10 +612,10 @@ void EGS_Ensdf::normalizeIntensities() { for (vector::iterator gamma = myMetastableGammaRecords.begin(); gamma != myMetastableGammaRecords.end(); gamma++) { - if(verbose > 1) { + if (verbose > 1) { egsInformation("EGS_Ensdf::normalizeIntensities: MetastableGamma (E,I): %f %f\n", - (*gamma)->getDecayEnergy(), - (*gamma)->getTransitionIntensity()); + (*gamma)->getDecayEnergy(), + (*gamma)->getTransitionIntensity()); } totalMetastableGammaIntensity += (*gamma)->getTransitionIntensity(); @@ -603,7 +625,7 @@ void EGS_Ensdf::normalizeIntensities() { double metastableFailIntensity = 100. - totalMetastableGammaIntensity; totalDecayIntensity += metastableFailIntensity; - if(verbose) { + if (verbose) { egsInformation("EGS_Ensdf::normalizeIntensities: MetastableGamma adds to less than 100%%. Fail chance (per 100 disintegrations): %f\n", metastableFailIntensity); } @@ -615,27 +637,27 @@ void EGS_Ensdf::normalizeIntensities() { myMetastableGammaRecords.back()->setTransitionIntensity(metastableFailIntensity); } for (unsigned int i=0; i < xrayIntensities.size(); ++i) { - if(verbose > 1) { + if (verbose > 1) { egsInformation("EGS_Ensdf::normalizeIntensities: XRay (E,I): %f %f\n", - xrayEnergies[i], xrayIntensities[i]); + xrayEnergies[i], xrayIntensities[i]); } totalDecayIntensity += xrayIntensities[i]; } for (unsigned int i=0; i < augerIntensities.size(); ++i) { - if(verbose > 1) { + if (verbose > 1) { egsInformation("EGS_Ensdf::normalizeIntensities: Auger (E,I): %f %f\n", - augerEnergies[i], augerIntensities[i]); + augerEnergies[i], augerIntensities[i]); } totalDecayIntensity += augerIntensities[i]; } - if(verbose) { + if (verbose) { egsInformation("EGS_Ensdf::normalizeIntensities: totalDecayIntensity: " - "%f\n",totalDecayIntensity); + "%f\n",totalDecayIntensity); egsInformation("EGS_Ensdf::normalizeIntensities: " - "Calculating renormalized intensities...\n"); + "Calculating renormalized intensities...\n"); } // Normalize beta emission intensities @@ -651,9 +673,9 @@ void EGS_Ensdf::normalizeIntensities() { } lastIntensity = (*beta)->getBetaIntensity(); - if(verbose) { + if (verbose) { egsInformation("EGS_Ensdf::normalizeIntensities: Beta (E,I): %f %f\n", - (*beta)->getFinalEnergy(), (*beta)->getBetaIntensity()); + (*beta)->getFinalEnergy(), (*beta)->getBetaIntensity()); } } @@ -675,9 +697,9 @@ void EGS_Ensdf::normalizeIntensities() { } lastIntensity = (*alpha)->getAlphaIntensity(); - if(verbose) { + if (verbose) { egsInformation("EGS_Ensdf::normalizeIntensities: Alpha (E,I): %f %f\n", - (*alpha)->getFinalEnergy(), (*alpha)->getAlphaIntensity()); + (*alpha)->getFinalEnergy(), (*alpha)->getAlphaIntensity()); } } @@ -699,9 +721,9 @@ void EGS_Ensdf::normalizeIntensities() { } lastIntensity = (*gamma)->getTransitionIntensity(); - if(verbose) { + if (verbose) { egsInformation("EGS_Ensdf::normalizeIntensities: MetastableGamma (E,I): %f %f\n", - (*gamma)->getDecayEnergy(), (*gamma)->getTransitionIntensity()); + (*gamma)->getDecayEnergy(), (*gamma)->getTransitionIntensity()); } } @@ -717,9 +739,9 @@ void EGS_Ensdf::normalizeIntensities() { } lastIntensity = xrayIntensities[i]; - if(verbose) { + if (verbose) { egsInformation("EGS_Ensdf::normalizeIntensities: XRay (E,I): %f %f\n", - xrayEnergies[i], xrayIntensities[i]); + xrayEnergies[i], xrayIntensities[i]); } } @@ -735,9 +757,9 @@ void EGS_Ensdf::normalizeIntensities() { } lastIntensity = augerIntensities[i]; - if(verbose) { + if (verbose) { egsInformation("EGS_Ensdf::normalizeIntensities: Auger (E,I): %f %f\n", - augerEnergies[i], augerIntensities[i]); + augerEnergies[i], augerIntensities[i]); } } @@ -751,11 +773,11 @@ void EGS_Ensdf::normalizeIntensities() { double guessedLevelEnergy = ((*gamma)->getLevelRecord()->getEnergy() - energy); - if(verbose) { + if (verbose) { egsInformation("EGS_Ensdf::normalizeIntensities: Gamma " - "(LevelE,E,GuessedE): " - "%f %f %f\n",(*gamma)->getLevelRecord()->getEnergy(), - energy, guessedLevelEnergy); + "(LevelE,E,GuessedE): " + "%f %f %f\n",(*gamma)->getLevelRecord()->getEnergy(), + energy, guessedLevelEnergy); } double bestMatch = 1E10; @@ -774,18 +796,18 @@ void EGS_Ensdf::normalizeIntensities() { } if (bestMatch == 1E10) { egsWarning("EGS_Ensdf::normalizeIntensities: Warning: Could " - "not find a level with energy matching decay " - "of gamma with energy E=%f; " - "assuming final level is ground state\n",energy); + "not find a level with energy matching decay " + "of gamma with energy E=%f; " + "assuming final level is ground state\n",energy); (*gamma)->setFinalLevel(myLevelRecords.front()); } else { (*gamma)->setFinalLevel(level); } - if(verbose) { + if (verbose) { egsInformation("EGS_Ensdf::normalizeIntensities: Gamma (final level E): " - "%f\n",level->getEnergy()); + "%f\n",level->getEnergy()); } (*gamma)->getFinalLevel()->cumulDisintegrationIntensity((*gamma)->getTransitionIntensity()); @@ -812,9 +834,9 @@ void EGS_Ensdf::normalizeIntensities() { if (disintIntensity > 1e-10 && totalLevelIntensity[j] < disintIntensity + 1e-10) { totalLevelIntensity[j] = disintIntensity; - if(verbose > 1) { + if (verbose > 1) { egsInformation("EGS_Ensdf::normalizeIntensities: " - "disintegrationIntensity: %f\n", totalLevelIntensity[j]); + "disintegrationIntensity: %f\n", totalLevelIntensity[j]); } } ++j; @@ -846,11 +868,11 @@ void EGS_Ensdf::normalizeIntensities() { } ++i; - if(verbose > 1) { + if (verbose > 1) { egsInformation("EGS_Ensdf::normalizeIntensities: " - "Gamma (level,E,I): " - "%d %f %f\n", - j,(*gamma)->getDecayEnergy(), (*gamma)->getTransitionIntensity()); + "Gamma (level,E,I): " + "%d %f %f\n", + j,(*gamma)->getDecayEnergy(), (*gamma)->getTransitionIntensity()); } } } @@ -867,10 +889,10 @@ void EGS_Ensdf::normalizeIntensities() { } void EGS_Ensdf::getEmissionsFromComments() { - if(verbose) { + if (verbose) { egsInformation("EGS_Ensdf::getEmissionsFromComments: Attempting to obtain x-ray and Auger emissions from the ENSDF comments. This assumes a particular comment format...\n"); } - + bool xrayContinues = false; bool augerContinues = false; bool gotTotal = false; @@ -885,13 +907,6 @@ void EGS_Ensdf::getEmissionsFromComments() { string line = (*comment)->getComment(); - //TODO: Maybe we should sample energies instead of using averages. - // Then we would avoid emissions with a non-physical energy. - // For multiple energy lines given a single intensity, we could - // split the intensity evenly between the lines. - // For energy ranges given for a single line, we could sample a Gaussian - // distributed energy within the range. - // Check for the end of multi-line records // and average them together if (line.length() < 48 || @@ -901,48 +916,49 @@ void EGS_Ensdf::getEmissionsFromComments() { // lines that started with a "total" line at the top // then we'll check to make sure they have intensities assigned if (gotTotal) { - + // In the event that a zero intensity is in one of the lines // following the "total" line, ALL of those following // lines are assigned an equal fraction of the total // intensity. This is an imperfect work-around for insufficient // data. Using this method, the correct energies are used, // rather than assigning a single averaged "total" energy line. - if(countNumAfterTotal > 0) { + if (countNumAfterTotal > 0) { // X-rays - if(lineTotalType == 0) { + if (lineTotalType == 0) { bool containsZeroIntensity = false; for (std::vector::iterator it = xrayIntensities.end()-countNumAfterTotal; it != xrayIntensities.end(); ++it) { - if(*it < 1e-10) { + if (*it < 1e-10) { containsZeroIntensity = true; break; } } - - if(containsZeroIntensity) { + + if (containsZeroIntensity) { for (std::vector::iterator it = xrayIntensities.end()-countNumAfterTotal; it != xrayIntensities.end(); ++it) { *it = lineTotalIntensity / countNumAfterTotal; } } - - // Auger - } else if(lineTotalType == -1) { + + // Auger + } + else if (lineTotalType == -1) { bool containsZeroIntensity = false; for (std::vector::iterator it = augerIntensities.end()-countNumAfterTotal; it != augerIntensities.end(); ++it) { - if(*it < 1e-10) { + if (*it < 1e-10) { containsZeroIntensity = true; break; } } - - if(containsZeroIntensity) { + + if (containsZeroIntensity) { for (std::vector::iterator it = augerIntensities.end()-countNumAfterTotal; it != augerIntensities.end(); ++it) { *it = lineTotalIntensity / countNumAfterTotal; } } } } - + gotTotal = false; countNumAfterTotal = 0; lineTotalIntensity = 0.; @@ -1032,15 +1048,15 @@ void EGS_Ensdf::getEmissionsFromComments() { // Get the intensity string iStr = egsTrimString(line.substr(32, 9)); double intensity = atof(iStr.c_str()); - + // If this is a line coming after a "total" line, // increment a counter. This will be used in the // event that the lines following the "total" // have zero intensity assigned - if(gotTotal && energy > 1e-10) { + if (gotTotal && energy > 1e-10) { countNumAfterTotal++; } - + // If this line is the total of the next lines, we will // skip this line and use the individual ones // However, record the total intensity in case we need it @@ -1049,7 +1065,8 @@ void EGS_Ensdf::getEmissionsFromComments() { lineTotalIntensity = intensity; if (emissionLine.find("AUGER") != std::string::npos) { lineTotalType = -1; - } else { + } + else { lineTotalType = 0; } continue; @@ -1071,15 +1088,15 @@ void EGS_Ensdf::getEmissionsFromComments() { } else { if (emissionLine.at(0) == 'X') { - if ((energy > 1e-10 && intensity > 1e-10) || - (gotTotal && energy > 1e-10)) { + if ((energy > 1e-10 && intensity > 1e-10) || + (gotTotal && energy > 1e-10)) { xrayEnergies.push_back(energy); xrayIntensities.push_back(intensity); } } else if (emissionLine.find("AUGER") != std::string::npos) { - if ((energy > 1e-10 && intensity > 1e-10) || - (gotTotal && energy > 1e-10)) { + if ((energy > 1e-10 && intensity > 1e-10) || + (gotTotal && energy > 1e-10)) { augerEnergies.push_back(energy); augerIntensities.push_back(intensity); } diff --git a/HEN_HOUSE/egs++/egs_ensdf.h b/HEN_HOUSE/egs++/egs_ensdf.h index 5690f254b..6456b4096 100644 --- a/HEN_HOUSE/egs++/egs_ensdf.h +++ b/HEN_HOUSE/egs++/egs_ensdf.h @@ -401,8 +401,8 @@ case below a single line of energy 97.4527 keV would be used. 221FR T 98.069 |] XKB5II \endverbatim If an energy and intensity are given for the "total" of several lines, it is -only used if the intensities of the individual lines are not provided. -For example, in the case below a single line of energy 14.0895 keV +only used if the intensities of the individual lines are not provided. +For example, in the case below a single line of energy 14.0895 keV would be used. \verbatim 221FR T 10.38-17.799 18.7 9 XL (total) @@ -417,7 +417,7 @@ The ensdf class has been tested on radionuclide data from http://www.nucleide.org/DDEP_WG/DDEPdata.htm ENSDF files from other sources may contain x-ray and Auger emissions formatted -differently. In this case, the x-ray and Auger lines will not be modeled. +differently. In this case, the x-ray and Auger lines will not be modeled. */ @@ -428,7 +428,7 @@ class EGS_EXPORT EGS_Ensdf { /*! \brief Construct an ensdf object. * */ - EGS_Ensdf(const string isotope, const string ensdf_filename="", + EGS_Ensdf(const string isotope, const string ensdf_filename="", const string useFluor="yes", int verbosity=1); /*! \brief Destructor. */ diff --git a/HEN_HOUSE/egs++/egs_spectra.cpp b/HEN_HOUSE/egs++/egs_spectra.cpp index 8671e410a..276eec448 100644 --- a/HEN_HOUSE/egs++/egs_spectra.cpp +++ b/HEN_HOUSE/egs++/egs_spectra.cpp @@ -912,7 +912,7 @@ class EGS_EXPORT EGS_RadionuclideSpectrum : public EGS_BaseSpectrum { // 1 - some output of ensdf data and normalized intensities // 2 - verbose output int verbose = 1; - + // Read in the data file for the isotope // and build the decay structure decays = new EGS_Ensdf(isotope, ensdf_file, useFluorescence, verbose); @@ -990,7 +990,7 @@ class EGS_EXPORT EGS_RadionuclideSpectrum : public EGS_BaseSpectrum { // Set the weight of the spectrum spectrumWeight = weight; - if(verbose) { + if (verbose) { egsInformation("EGS_RadionuclideSpectrum: Emax: %f\n",Emax); egsInformation("EGS_RadionuclideSpectrum: Weight: %f\n",weight); } @@ -1719,7 +1719,7 @@ EGS_BaseSpectrum *EGS_BaseSpectrum::createSpectrum(EGS_Input *input) { if (err) { weight = 1; } - + // Determine whether to sample X-Rays and Auger electrons // using the ensdf data (options: yes or no) string tmp_useFl, useFluorescence; @@ -1730,9 +1730,10 @@ EGS_BaseSpectrum *EGS_BaseSpectrum::createSpectrum(EGS_Input *input) { else { useFluorescence = "yes"; } - if(useFluorescence == "yes") { + if (useFluorescence == "yes") { egsInformation("EGS_BaseSpectrum::createSpectrum: Fluorescence and auger from the ensdf file will be used.\n"); - } else { + } + else { egsInformation("EGS_BaseSpectrum::createSpectrum: Fluorescence and auger from the ensdf file will be ignored.\n"); } From 5bed3611fd070fcc5faca1cbf69fd02e5a56ea74 Mon Sep 17 00:00:00 2001 From: Reid Townson Date: Fri, 9 Dec 2016 15:44:19 -0500 Subject: [PATCH 22/34] Fix the radionuclide sampling of mixtures Mixtures of radionuclides using the relative activity input are now balanced by their relative number of disintegrations, rather than the relative number of emissions (which includes x-rays and Auger). The fluence returned by getFluence() is now a sum of the number of disintegrations for each spectrum in the mixture. --- HEN_HOUSE/egs++/egs_ensdf.cpp | 3 ++ HEN_HOUSE/egs++/egs_spectra.cpp | 38 ++++++++++++------- .../egs_radionuclide_source.cpp | 23 +++++++++-- .../egs_radionuclide_source.h | 7 +++- 4 files changed, 54 insertions(+), 17 deletions(-) diff --git a/HEN_HOUSE/egs++/egs_ensdf.cpp b/HEN_HOUSE/egs++/egs_ensdf.cpp index 84d2e148e..dbd54a11f 100644 --- a/HEN_HOUSE/egs++/egs_ensdf.cpp +++ b/HEN_HOUSE/egs++/egs_ensdf.cpp @@ -588,6 +588,7 @@ void EGS_Ensdf::normalizeIntensities() { // Add up the beta, alpha, xray and auger decay intensities double totalDecayIntensity = 0; double lastIntensity = 0; + for (vector::iterator beta = myBetaRecords.begin(); beta != myBetaRecords.end(); beta++) { @@ -729,6 +730,7 @@ void EGS_Ensdf::normalizeIntensities() { // Normalize XRay emission intensities for (unsigned int i=0; i < xrayIntensities.size(); ++i) { + xrayIntensities[i] /= totalDecayIntensity; if (i==0 && lastIntensity > 1e-10) { @@ -747,6 +749,7 @@ void EGS_Ensdf::normalizeIntensities() { // Normalize auger emission intensities for (unsigned int i=0; i < augerIntensities.size(); ++i) { + augerIntensities[i] /= totalDecayIntensity; if (i==0 && lastIntensity > 1e-10) { diff --git a/HEN_HOUSE/egs++/egs_spectra.cpp b/HEN_HOUSE/egs++/egs_spectra.cpp index 276eec448..ee6e5f724 100644 --- a/HEN_HOUSE/egs++/egs_spectra.cpp +++ b/HEN_HOUSE/egs++/egs_spectra.cpp @@ -883,16 +883,16 @@ It is defined using the following input if ensdf file not provided below ensdf file = [optional] path to a spectrum file in ensdf format, including extension - weight = [optional] the relative activity (sampling + relative activity = [optional] the relative activity (sampling probability) for this isotope in a mixture use fluorescence and auger = [optional, default=yes] yes or no whether or not to model the x-ray and Auger emissions provided in the ensdf file :stop spectrum: :start spectrum: - type = radionuclide - isotope = name of next isotope in mixture (e.g. Y-90) - weight = ... + type = radionuclide + isotope = name of next isotope in mixture (e.g. Y-90) + relative activity = ... :stop spectrum: \endverbatim @@ -904,7 +904,7 @@ class EGS_EXPORT EGS_RadionuclideSpectrum : public EGS_BaseSpectrum { /*! \brief Construct a radionuclide spectrum. */ EGS_RadionuclideSpectrum(const string isotope, const string ensdf_file, - const EGS_Float weight, const string useFluorescence) : + const EGS_Float relativeActivity, const string useFluorescence) : EGS_BaseSpectrum() { // For now, hard-code verbose mode @@ -988,11 +988,11 @@ class EGS_EXPORT EGS_RadionuclideSpectrum : public EGS_BaseSpectrum { } // Set the weight of the spectrum - spectrumWeight = weight; + spectrumWeight = relativeActivity; if (verbose) { egsInformation("EGS_RadionuclideSpectrum: Emax: %f\n",Emax); - egsInformation("EGS_RadionuclideSpectrum: Weight: %f\n",weight); + egsInformation("EGS_RadionuclideSpectrum: Relative activity: %f\n",relativeActivity); } }; @@ -1027,8 +1027,15 @@ class EGS_EXPORT EGS_RadionuclideSpectrum : public EGS_BaseSpectrum { /*! \brief Print the sampled emission intensities. */ void printSampledEmissions() { + egsInformation("\nSampled %s emissions:\n", decays->radionuclide.c_str()); egsInformation("========================\n"); + + if (ishower < 1) { + egsWarning("EGS_RadionuclideSpectrum::printSampledEmissions: Warning: The number of disintegrations (tracked by `ishower`) is less than 1.\n"); + return; + } + egsInformation("Energy | Intensity per 100 emissions\n"); if (myBetas.size() > 0) { egsInformation("Beta records:\n"); @@ -1060,8 +1067,13 @@ class EGS_EXPORT EGS_RadionuclideSpectrum : public EGS_BaseSpectrum { ((EGS_Float)(*gamma)->getNumSampled()/ishower)*100); } if (myGammas.size() > 0) { - egsInformation("Average gamma energy: %f\n", - totalGammaEnergy / totalNumSampled); + if (totalNumSampled > 0) { + egsInformation("Average gamma energy: %f\n", + totalGammaEnergy / totalNumSampled); + } + else { + egsInformation("Zero gamma transitions occurred.\n"); + } } if (myMetastableGammas.size() > 0) { egsInformation("Metastable Gamma records:\n"); @@ -1714,10 +1726,10 @@ EGS_BaseSpectrum *EGS_BaseSpectrum::createSpectrum(EGS_Input *input) { return 0; } - EGS_Float weight; - err = inp->getInput("weight",weight); + EGS_Float relativeActivity; + err = inp->getInput("relative activity",relativeActivity); if (err) { - weight = 1; + relativeActivity = 1; } // Determine whether to sample X-Rays and Auger electrons @@ -1778,7 +1790,7 @@ EGS_BaseSpectrum *EGS_BaseSpectrum::createSpectrum(EGS_Input *input) { ensdf_fh.close(); // Create the spectrum - spec = new EGS_RadionuclideSpectrum(isotope, ensdf_file, weight, useFluorescence); + spec = new EGS_RadionuclideSpectrum(isotope, ensdf_file, relativeActivity, useFluorescence); } else { egsWarning("%s unknown spectrum type %s\n",spec_msg1,stype.c_str()); diff --git a/HEN_HOUSE/egs++/sources/egs_radionuclide_source/egs_radionuclide_source.cpp b/HEN_HOUSE/egs++/sources/egs_radionuclide_source/egs_radionuclide_source.cpp index 1210d81ea..27d2e91b6 100644 --- a/HEN_HOUSE/egs++/sources/egs_radionuclide_source/egs_radionuclide_source.cpp +++ b/HEN_HOUSE/egs++/sources/egs_radionuclide_source/egs_radionuclide_source.cpp @@ -74,8 +74,12 @@ EGS_RadionuclideSource::EGS_RadionuclideSource(EGS_Input *input, Emax = 0; unsigned int i = 0; EGS_Float spectrumWeightTotal = 0; + disintegrationOccurred = true; + ishower = 0; while (input->getInputItem("spectrum")) { + egsInformation("**********************************************\n"); + decays.push_back(EGS_BaseSpectrum::createSpectrum(input)); // If spectrum creation failed skip to the next spectrum block @@ -243,7 +247,7 @@ EGS_I64 EGS_RadionuclideSource::getNextParticle(EGS_RandomGenerator *rndm, int &u) { unsigned int i = 0; - if (decays.size() > 1) { + if (decays.size() > 1 && disintegrationOccurred) { // Sample a uniform random number EGS_Float uRand = rndm->getUniform(); @@ -255,10 +259,11 @@ EGS_I64 EGS_RadionuclideSource::getNextParticle(EGS_RandomGenerator *rndm, int } } - for (EGS_I64 j=0; j<1e6; ++j) { + for (EGS_I64 j=0; j<=1e6; ++j) { E = decays[i]->sampleEnergy(rndm); + // Skip zero energy particles if (E < 1e-10) { continue; } @@ -272,10 +277,22 @@ EGS_I64 EGS_RadionuclideSource::getNextParticle(EGS_RandomGenerator *rndm, int if (q_allowAll || std::find(q_allowed.begin(), q_allowed.end(), q) != q_allowed.end()) { break; } + + if (j == 1e6) { + egsWarning("EGS_RadionuclideSource::getNextParticle: Error: Could not generate a particle after 1e6 tries. Spectrum will be wrong.\n"); + E = 0; + } } time = decays[i]->getTime(); - ishower = decays[i]->getShowerIndex(); + EGS_I64 ishowerNew = decays[i]->getShowerIndex(); + if (ishowerNew > ishower) { + disintegrationOccurred = true; + ishower = ishowerNew; + } + else { + disintegrationOccurred = false; + } getPositionDirection(rndm,x,u,wt); latch = 0; diff --git a/HEN_HOUSE/egs++/sources/egs_radionuclide_source/egs_radionuclide_source.h b/HEN_HOUSE/egs++/sources/egs_radionuclide_source/egs_radionuclide_source.h index 7944a94a9..7f7d308dc 100644 --- a/HEN_HOUSE/egs++/sources/egs_radionuclide_source/egs_radionuclide_source.h +++ b/HEN_HOUSE/egs++/sources/egs_radionuclide_source/egs_radionuclide_source.h @@ -176,7 +176,11 @@ class EGS_RADIONUCLIDE_SOURCE_EXPORT EGS_RadionuclideSource : }; EGS_Float getFluence() const { - return ishower+1; + EGS_Float fluence = 0; + for (unsigned int i=0; igetShowerIndex() + 1; + } + return fluence; }; double getTime() const { @@ -278,6 +282,7 @@ class EGS_RADIONUCLIDE_SOURCE_EXPORT EGS_RadionuclideSource : vector decays; //!< The radionuclide decay structure vector q_allowed; //!< A list of allowed charges bool q_allowAll; //!< Whether or not to allow all charges + bool disintegrationOccurred; EGS_Float activity; //!< The activity of the source double time; //!< The time of emission of the most recently generated particle EGS_I64 ishower; //!< The shower index (disintegration number) of the most recently generated particle From a0c412b511f19e9201e07ea8eb06796e51630866 Mon Sep 17 00:00:00 2001 From: Reid Townson Date: Tue, 13 Dec 2016 15:44:45 -0500 Subject: [PATCH 23/34] Fix radionuclide parallel run functions Fix the storeState, addState, etc. functions for radionuclide sources. This enables the 'combine' and 'analyze' options in parallel runs. --- HEN_HOUSE/egs++/egs_spectra.cpp | 15 +++++++++ .../egs_radionuclide_source.cpp | 33 +++++-------------- .../egs_radionuclide_source.h | 32 +----------------- 3 files changed, 24 insertions(+), 56 deletions(-) diff --git a/HEN_HOUSE/egs++/egs_spectra.cpp b/HEN_HOUSE/egs++/egs_spectra.cpp index ee6e5f724..ada7ea241 100644 --- a/HEN_HOUSE/egs++/egs_spectra.cpp +++ b/HEN_HOUSE/egs++/egs_spectra.cpp @@ -1103,6 +1103,21 @@ class EGS_EXPORT EGS_RadionuclideSpectrum : public EGS_BaseSpectrum { egsInformation("\n"); } + bool storeState(ostream &data) const { + return egsStoreI64(data,ishower); + } + + bool setState(istream &data) { + return egsGetI64(data,ishower); + } + + void resetCounter() { + currentLevel = 0; + currentTime = 0; + ishower = -1; + totalGammaEnergy = 0; + } + protected: /*! \brief Sample an event from the spectrum. diff --git a/HEN_HOUSE/egs++/sources/egs_radionuclide_source/egs_radionuclide_source.cpp b/HEN_HOUSE/egs++/sources/egs_radionuclide_source/egs_radionuclide_source.cpp index 27d2e91b6..596170f45 100644 --- a/HEN_HOUSE/egs++/sources/egs_radionuclide_source/egs_radionuclide_source.cpp +++ b/HEN_HOUSE/egs++/sources/egs_radionuclide_source/egs_radionuclide_source.cpp @@ -259,6 +259,8 @@ EGS_I64 EGS_RadionuclideSource::getNextParticle(EGS_RandomGenerator *rndm, int } } + EGS_I64 ishowerOld = decays[i]->getShowerIndex(); + for (EGS_I64 j=0; j<=1e6; ++j) { E = decays[i]->sampleEnergy(rndm); @@ -286,9 +288,9 @@ EGS_I64 EGS_RadionuclideSource::getNextParticle(EGS_RandomGenerator *rndm, int time = decays[i]->getTime(); EGS_I64 ishowerNew = decays[i]->getShowerIndex(); - if (ishowerNew > ishower) { + if (ishowerNew > ishowerOld) { disintegrationOccurred = true; - ishower = ishowerNew; + ishower++; } else { disintegrationOccurred = false; @@ -386,57 +388,38 @@ void EGS_RadionuclideSource::setUp() { } bool EGS_RadionuclideSource::storeState(ostream &data_out) const { - if (!egsStoreI64(data_out,ishower)) { - return false; - } for (unsigned int i=0; istoreState(data_out)) { return false; } } - if (!storeFluenceState(data_out)) { - return false; - } return true; } bool EGS_RadionuclideSource::addState(istream &data) { - EGS_I64 count_save = ishower; - if (!egsGetI64(data,ishower)) { - return false; - } for (unsigned int i=0; iaddState(data)) { + if (!decays[i]->setState(data)) { return false; } + ishower += decays[i]->getShowerIndex(); } - if (!addFluenceData(data)) { - return false; - } - ishower += count_save; return true; } void EGS_RadionuclideSource::resetCounter() { - ishower = 0; for (unsigned int i=0; iresetCounter(); } - resetFluenceCounter(); + ishower = 0; + count = 0; } bool EGS_RadionuclideSource::setState(istream &data) { - if (!egsGetI64(data,ishower)) { - return false; - } for (unsigned int i=0; isetState(data)) { return false; } } - if (!setFluenceState(data)) { - return false; - } return true; } diff --git a/HEN_HOUSE/egs++/sources/egs_radionuclide_source/egs_radionuclide_source.h b/HEN_HOUSE/egs++/sources/egs_radionuclide_source/egs_radionuclide_source.h index 7f7d308dc..9b03baf16 100644 --- a/HEN_HOUSE/egs++/sources/egs_radionuclide_source/egs_radionuclide_source.h +++ b/HEN_HOUSE/egs++/sources/egs_radionuclide_source/egs_radionuclide_source.h @@ -176,11 +176,7 @@ class EGS_RADIONUCLIDE_SOURCE_EXPORT EGS_RadionuclideSource : }; EGS_Float getFluence() const { - EGS_Float fluence = 0; - for (unsigned int i=0; igetShowerIndex() + 1; - } - return fluence; + return ishower+1; }; double getTime() const { @@ -200,14 +196,6 @@ class EGS_RADIONUCLIDE_SOURCE_EXPORT EGS_RadionuclideSource : void getPositionDirection(EGS_RandomGenerator *rndm, EGS_Vector &x, EGS_Vector &u, EGS_Float &wt); - bool storeFluenceState(ostream &data) const { - return true; - }; - - bool setFluenceState(istream &data) { - return true; - }; - bool isValid() const { return (decays.size() != 0 && shape != 0); }; @@ -235,24 +223,6 @@ class EGS_RADIONUCLIDE_SOURCE_EXPORT EGS_RadionuclideSource : */ void resetCounter(); - /*! \brief Add fluence data from the stream \a data to the current state. - * - * - * \sa storeFluenceState(), setFluenceState(), resetFluenceCounter(), - * setState(), storeState(), resetCounter() and addState(). - */ - bool addFluenceData(istream &data) { - return true; - } - - /*! \brief Reset the data related to the sampling of positions and - * directions to a state with zero sampled particles. - * - * \sa storeFluenceState(), setFluenceState(), addFluenceData(), - * setState(), storeState(), resetCounter() and addState(). - */ - void resetFluenceCounter() { }; - /*! \brief Set the source state according to the data in the stream \a data. * * Uses the \link EGS_BaseSpectrum::setState() setState() \endlink From 301a1265dc3c7b92732819cb28cfc306d4799794 Mon Sep 17 00:00:00 2001 From: Reid Townson Date: Mon, 19 Dec 2016 13:10:10 -0500 Subject: [PATCH 24/34] Fix the radionuclide time parameter Base disintegration times on the total activity. The internal transition gammas now correctly parse the half-life and use it to determine the time of the internal transition. --- HEN_HOUSE/egs++/egs_ensdf.cpp | 2 +- HEN_HOUSE/egs++/egs_spectra.cpp | 36 ++++++------------- .../egs_radionuclide_source.cpp | 19 ++++------ .../egs_radionuclide_source.h | 12 +++---- 4 files changed, 25 insertions(+), 44 deletions(-) diff --git a/HEN_HOUSE/egs++/egs_ensdf.cpp b/HEN_HOUSE/egs++/egs_ensdf.cpp index dbd54a11f..0f16e58c9 100644 --- a/HEN_HOUSE/egs++/egs_ensdf.cpp +++ b/HEN_HOUSE/egs++/egs_ensdf.cpp @@ -1559,7 +1559,7 @@ LevelRecord::LevelRecord(vector ensdf): void LevelRecord::processEnsdf() { energy = recordToDouble(10, 19) / 1000.; // Convert keV to MeV - halfLife = recordToDouble(40, 49); + halfLife = parseHalfLife(40, 49); } void LevelRecord::setLevelCanDecay(bool canDecayTmp) { diff --git a/HEN_HOUSE/egs++/egs_spectra.cpp b/HEN_HOUSE/egs++/egs_spectra.cpp index ada7ea241..335e0607d 100644 --- a/HEN_HOUSE/egs++/egs_spectra.cpp +++ b/HEN_HOUSE/egs++/egs_spectra.cpp @@ -1008,10 +1008,6 @@ class EGS_EXPORT EGS_RadionuclideSpectrum : public EGS_BaseSpectrum { return currentTime; } - void setMaximumTime(double maxTime) { - Tmax = maxTime; - } - EGS_I64 getShowerIndex() const { return ishower; } @@ -1152,14 +1148,14 @@ class EGS_EXPORT EGS_RadionuclideSpectrum : public EGS_BaseSpectrum { In such a case, the daughter level is set to zero and a zero energy particle is returned. - Note about emission times: the time of emission of a particle is modeled - by uniformly distributing disintegrations over the total experiment time - determined by the activity provided by the user. The time of emission of + Note about emission times: The time of emission of a transition photon is determined by sampling the delay that occurs after - disintegration (according to the transition half life). X-Rays and - Auger electrons are assumed to occur at the same time as the disintegration - and will have both time and ishower corresponding to the most recent - disintegration. + disintegration (according to the transition half life). + The time of disintegration is calculated similarly based on the + total activity of the mixture in \ref EGS_RadionuclideSource. + X-Rays and Auger electrons are assumed to occur at the same time + as the disintegration and will have both time and ishower corresponding + to the most recent disintegration. Currently, it is possible for an X-Ray or Auger to be emitted before a disintegration has taken place. They are assigned currentTime=0 and @@ -1189,10 +1185,9 @@ class EGS_EXPORT EGS_RadionuclideSpectrum : public EGS_BaseSpectrum { // it took for this transition to occur // time += halflife / ln(2) * log(u) double hl = currentLevel->getHalfLife(); - if (hl > 1e-10) { - currentTime += currentLevel->getHalfLife() / - 0.693147180559945309417232121458176568075500134360255254120680009493393 - * log(rndm->getUniform()); + if (hl > 0) { + currentTime = -hl * log(1.-rndm->getUniform()) / + 0.693147180559945309417232121458176568075500134360255254120680009493393; } (*gamma)->incrNumSampled(); @@ -1215,6 +1210,7 @@ class EGS_EXPORT EGS_RadionuclideSpectrum : public EGS_BaseSpectrum { // ============================ // Sample which decay occurs // ============================ + currentTime = 0; // Beta-, beta+ and electron capture for (vector::iterator beta = myBetas.begin(); @@ -1224,9 +1220,6 @@ class EGS_EXPORT EGS_RadionuclideSpectrum : public EGS_BaseSpectrum { // Increment the shower number ishower++; - // Uniformly distribute decays over the experiment time - currentTime = rndm->getUniform() * Tmax; - // Increment the counter of betas and get the charge (*beta)->incrNumSampled(); currentQ = (*beta)->getCharge(); @@ -1264,9 +1257,6 @@ class EGS_EXPORT EGS_RadionuclideSpectrum : public EGS_BaseSpectrum { // Increment the shower number ishower++; - // Uniformly distribute decays over the experiment time - currentTime = rndm->getUniform() * Tmax; - // Increment the counter of alphas and get the charge (*alpha)->incrNumSampled(); currentQ = (*alpha)->getCharge(); @@ -1290,9 +1280,6 @@ class EGS_EXPORT EGS_RadionuclideSpectrum : public EGS_BaseSpectrum { // disintegrations! This is due to the metastable state. ishower++; - // Uniformly distribute decays over the experiment time - currentTime = rndm->getUniform() * Tmax; - // Increment the counter of gammas and get the charge (*gamma)->incrNumSampled(); currentQ = (*gamma)->getCharge(); @@ -1367,7 +1354,6 @@ class EGS_EXPORT EGS_RadionuclideSpectrum : public EGS_BaseSpectrum { int currentQ; EGS_Float currentTime, Emax, - Tmax, spectrumWeight, totalGammaEnergy; EGS_I64 ishower; diff --git a/HEN_HOUSE/egs++/sources/egs_radionuclide_source/egs_radionuclide_source.cpp b/HEN_HOUSE/egs++/sources/egs_radionuclide_source/egs_radionuclide_source.cpp index 596170f45..71fffef57 100644 --- a/HEN_HOUSE/egs++/sources/egs_radionuclide_source/egs_radionuclide_source.cpp +++ b/HEN_HOUSE/egs++/sources/egs_radionuclide_source/egs_radionuclide_source.cpp @@ -75,7 +75,8 @@ EGS_RadionuclideSource::EGS_RadionuclideSource(EGS_Input *input, unsigned int i = 0; EGS_Float spectrumWeightTotal = 0; disintegrationOccurred = true; - ishower = 0; + ishower = -1; + time = 0; while (input->getInputItem("spectrum")) { egsInformation("**********************************************\n"); @@ -123,6 +124,7 @@ EGS_RadionuclideSource::EGS_RadionuclideSource(EGS_Input *input, else { activity = 1; } + egsInformation("EGS_RadionuclideSource: Activity [disintegrations/s]: %e\n", activity); @@ -155,15 +157,6 @@ EGS_RadionuclideSource::EGS_RadionuclideSource(EGS_Input *input, "input to determine 'ncase'\n"); } - //TODO: Currently the Tmax is incorrect, because it is based on - // ncase, which is NOT the number of disintegrations - double Tmax = ncase_double / activity; - egsInformation("EGS_RadionuclideSource: Duration of experiment (CURRENTLY INCORRECT) [s]: %e\n", - Tmax); - for (i=0; isetMaximumTime(Tmax); - } - // Create the shape for source emissions vector pos; EGS_Input *ishape = input->takeInputItem("shape"); @@ -286,14 +279,16 @@ EGS_I64 EGS_RadionuclideSource::getNextParticle(EGS_RandomGenerator *rndm, int } } - time = decays[i]->getTime(); EGS_I64 ishowerNew = decays[i]->getShowerIndex(); if (ishowerNew > ishowerOld) { disintegrationOccurred = true; - ishower++; + + time += -log(1.-rndm->getUniform()) / activity; + ++ishower; } else { disintegrationOccurred = false; + time += decays[i]->getTime(); } getPositionDirection(rndm,x,u,wt); diff --git a/HEN_HOUSE/egs++/sources/egs_radionuclide_source/egs_radionuclide_source.h b/HEN_HOUSE/egs++/sources/egs_radionuclide_source/egs_radionuclide_source.h index 9b03baf16..a7837a22e 100644 --- a/HEN_HOUSE/egs++/sources/egs_radionuclide_source/egs_radionuclide_source.h +++ b/HEN_HOUSE/egs++/sources/egs_radionuclide_source/egs_radionuclide_source.h @@ -103,13 +103,13 @@ It is defined using the following input if ensdf file not provided below ensdf file = [optional] path to a spectrum file in ensdf format, including extension - weight = [optional] the relative activity (sampling - probability) for this isotope in a mixture + relative activity = [optional] the relative activity for this + isotope in a mixture :stop spectrum: :start spectrum: type = radionuclide isotope = name of next isotope in mixture (e.g. Y-90) - weight = ... + relative activity = ... :stop spectrum: :stop source: \endverbatim @@ -252,9 +252,9 @@ class EGS_RADIONUCLIDE_SOURCE_EXPORT EGS_RadionuclideSource : vector decays; //!< The radionuclide decay structure vector q_allowed; //!< A list of allowed charges bool q_allowAll; //!< Whether or not to allow all charges - bool disintegrationOccurred; - EGS_Float activity; //!< The activity of the source - double time; //!< The time of emission of the most recently generated particle + bool disintegrationOccurred; //!< Whether or not a disintegration occurred while generating the most recent source particle + EGS_Float activity, //!< The activity of the source + time; //!< The time of emission of the most recently generated particle EGS_I64 ishower; //!< The shower index (disintegration number) of the most recently generated particle }; From ad23c1d384c591cdb971750de3de300d7e27b893 Mon Sep 17 00:00:00 2001 From: Reid Townson Date: Thu, 12 Jan 2017 14:59:33 -0500 Subject: [PATCH 25/34] Fix minor bug in radionuclide fluence calculation Account for disintegrations that don't result in a particle, in the ishower parameter. Not doing so had a small effect on the fluence. --- HEN_HOUSE/egs++/egs_ensdf.cpp | 4 ++-- .../egs_radionuclide_source/egs_radionuclide_source.cpp | 2 +- 2 files changed, 3 insertions(+), 3 deletions(-) diff --git a/HEN_HOUSE/egs++/egs_ensdf.cpp b/HEN_HOUSE/egs++/egs_ensdf.cpp index 0f16e58c9..fe2553573 100644 --- a/HEN_HOUSE/egs++/egs_ensdf.cpp +++ b/HEN_HOUSE/egs++/egs_ensdf.cpp @@ -809,8 +809,8 @@ void EGS_Ensdf::normalizeIntensities() { } if (verbose) { - egsInformation("EGS_Ensdf::normalizeIntensities: Gamma (final level E): " - "%f\n",level->getEnergy()); + egsInformation("EGS_Ensdf::normalizeIntensities: Gamma (final level E, I): " + "%f %f\n",level->getEnergy(), (*gamma)->getTransitionIntensity()); } (*gamma)->getFinalLevel()->cumulDisintegrationIntensity((*gamma)->getTransitionIntensity()); diff --git a/HEN_HOUSE/egs++/sources/egs_radionuclide_source/egs_radionuclide_source.cpp b/HEN_HOUSE/egs++/sources/egs_radionuclide_source/egs_radionuclide_source.cpp index 71fffef57..a13e01b89 100644 --- a/HEN_HOUSE/egs++/sources/egs_radionuclide_source/egs_radionuclide_source.cpp +++ b/HEN_HOUSE/egs++/sources/egs_radionuclide_source/egs_radionuclide_source.cpp @@ -284,7 +284,7 @@ EGS_I64 EGS_RadionuclideSource::getNextParticle(EGS_RandomGenerator *rndm, int disintegrationOccurred = true; time += -log(1.-rndm->getUniform()) / activity; - ++ishower; + ishower += (ishowerNew - ishowerOld); } else { disintegrationOccurred = false; From 8d42ce7808c3de87eb7eac13fcd051459d3ce184 Mon Sep 17 00:00:00 2001 From: Reid Townson Date: Fri, 20 Jan 2017 10:56:11 -0500 Subject: [PATCH 26/34] Add option to output beta spectra, update docs Add a radionuclide spectrum option to output the beta spectra of the isotope, instead of outputting the files by default. Update the documentation of the radionuclide source, spectrum and ensdf class. --- HEN_HOUSE/doc/src/pirs898-egs++/Doxyfile | 1 + .../figures/egs_radionuclide_source.png | Bin 0 -> 114991 bytes HEN_HOUSE/egs++/egs_ensdf.h | 10 +- HEN_HOUSE/egs++/egs_spectra.cpp | 138 +++++++++--------- .../egs_radionuclide_source.h | 136 +++++++++++++---- 5 files changed, 189 insertions(+), 96 deletions(-) create mode 100644 HEN_HOUSE/doc/src/pirs898-egs++/figures/egs_radionuclide_source.png diff --git a/HEN_HOUSE/doc/src/pirs898-egs++/Doxyfile b/HEN_HOUSE/doc/src/pirs898-egs++/Doxyfile index b654e1176..77b07153b 100644 --- a/HEN_HOUSE/doc/src/pirs898-egs++/Doxyfile +++ b/HEN_HOUSE/doc/src/pirs898-egs++/Doxyfile @@ -223,6 +223,7 @@ ALIASES = "internwarning=\par Warning:\n This class is not part o "FT=\author Frederic Tessier, NRC" \ "EM=\author Ernesto Mainegra-Hing, NRC" \ "BW=\author Blake Walters, NRC" \ + "RT=\author Reid Townson, NRC" \ "GG=\author Georgi Gerganov" # This tag can be used to 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This decay structure is useful for \ref EGS_RadionuclideSpectrum used by \ref EGS_RadionuclideSource. Uncertainties on values are ignored! The energies and intensities for various -emissions are taken as is. Very low intensities are discarded. +emissions are taken as is. Very low probability emissions are discarded. When processing an ensdf file, only the following records are considered: Comment, Parent, Normalization, Level, Beta-, EC / Beta+, Alpha, Gamma. -X-Rays and Auger emissions are obtained from Comment records. The data is -processed in the same way as Lara files on nucleide.org. If a single -intensity is present for a combination of lines (but a single energy is not -provided), then the average energy of the lines is used. For example, in the +X-Ray fluorescence and Auger emissions are obtained from Comment records. +If a single intensity is present for a combination of lines (but a single +energy is not provided), then the average energy of the lines is used. +For example, in the case below a single line of energy 97.4527 keV would be used. \verbatim 221FR T 96.815 |] XKB3 diff --git a/HEN_HOUSE/egs++/egs_spectra.cpp b/HEN_HOUSE/egs++/egs_spectra.cpp index 335e0607d..7b08407e7 100644 --- a/HEN_HOUSE/egs++/egs_spectra.cpp +++ b/HEN_HOUSE/egs++/egs_spectra.cpp @@ -458,7 +458,7 @@ class EGS_EXPORT EGS_RadionuclideBetaSpectrum { public: /*! \brief Construct beta spectra for a radionuclide */ - EGS_RadionuclideBetaSpectrum(EGS_Ensdf *decays) { + EGS_RadionuclideBetaSpectrum(EGS_Ensdf *decays, const string outputBetaSpectra) { vector myBetas = decays->getBetaRecords(); @@ -544,18 +544,21 @@ class EGS_EXPORT EGS_RadionuclideBetaSpectrum { (*beta)->setSpectrum(bspec); // Write the spectrum to a file - // This is just intended to be temporary to test the - // spectrum generation code - ostringstream ostr; - ostr << decays->radionuclide << "_d_" << emax << ".spec"; - - ofstream specStream; - specStream.open(ostr.str().c_str()); - for (int ib=0; ibradionuclide << "_" << emax << ".spec"; + + egsInformation("EGS_RadionuclideBetaSpectrum: Outputting beta spectrum to file: %s\n", ostr.str().c_str()); + + ofstream specStream; + specStream.open(ostr.str().c_str()); + for (int ib=0; ib\c ishower parameter). These particles will +be assigned the same shower index and time of emission as the most recent +disintegration or internal transition. + +- Internal transition gammas are sampled and emitted following a disintegration if +the daughter isotope is created in an excited state. The energy level of the +daughter is then set according to the transition that took place. +Note that there are cases where a transition photon is not guaranteed. +In such a case, the daughter level is set to zero and a zero energy +particle is returned. + */ class EGS_EXPORT EGS_RadionuclideSpectrum : public EGS_BaseSpectrum { @@ -904,7 +944,7 @@ class EGS_EXPORT EGS_RadionuclideSpectrum : public EGS_BaseSpectrum { /*! \brief Construct a radionuclide spectrum. */ EGS_RadionuclideSpectrum(const string isotope, const string ensdf_file, - const EGS_Float relativeActivity, const string useFluorescence) : + const EGS_Float relativeActivity, const string useFluorescence, const string outputBetaSpectra) : EGS_BaseSpectrum() { // For now, hard-code verbose mode @@ -921,7 +961,7 @@ class EGS_EXPORT EGS_RadionuclideSpectrum : public EGS_BaseSpectrum { decays->normalizeIntensities(); // Get the beta energy spectra - betaSpectra = new EGS_RadionuclideBetaSpectrum(decays); + betaSpectra = new EGS_RadionuclideBetaSpectrum(decays, outputBetaSpectra); // Get the particle records from the decay scheme myBetas = decays->getBetaRecords(); @@ -1115,53 +1155,7 @@ class EGS_EXPORT EGS_RadionuclideSpectrum : public EGS_BaseSpectrum { } protected: - /*! \brief Sample an event from the spectrum. - - Returns the energy of the emitted particle. - - Determines which emission type occurs, and proceeds to sample the - emission parameters. If the daughter isotope is - in an excited state, a transition gamma is emitted and - the daughter transitions to a lower energy state. If the daughter - isotope is not in an exited state, one of the following events occurs: - - Disintegration events may set the energy level of the daughter to an - excited state. Beta- and beta+ disintegrations emit an electron or positron, - respectively. The energies of beta particles are sampled from spectra - generated by \ref EGS_RadionuclideBetaSpectrum. Electron capture events - are also sampled, but neutrinos are not modeled so a zero energy - particle is returned. - - Alpha disintegrations may set the energy level of the daughter to an - excited state, leading to the emission of transition photons. - Alpha particles themselves are not modeled, so a zero energy particle - is returned. - - X-Ray and Auger events emit a photon or electron from a sampled energy line. - X-Ray and Auger emissions are not disintegrations so are not counted in - the fluence (or the ishower parameter). - - Transition gammas are sampled and emitted following a disintegration (if - the daughter is created in an excited state). The energy level of the - daughter is then set according to the transition that took place. - Note that there are cases where a transition photon is not guaranteed. - In such a case, the daughter level is set to zero and a zero energy - particle is returned. - - Note about emission times: The time of emission of - a transition photon is determined by sampling the delay that occurs after - disintegration (according to the transition half life). - The time of disintegration is calculated similarly based on the - total activity of the mixture in \ref EGS_RadionuclideSource. - X-Rays and Auger electrons are assumed to occur at the same time - as the disintegration and will have both time and ishower corresponding - to the most recent disintegration. - - Currently, it is possible for an X-Ray or Auger to be emitted before a - disintegration has taken place. They are assigned currentTime=0 and - ishower=-1. - - */ + /*! \brief Sample an event from the spectrum, returns the energy of the emitted particle. */ EGS_Float sample(EGS_RandomGenerator *rndm) { // Sample a uniform random number @@ -1749,6 +1743,20 @@ EGS_BaseSpectrum *EGS_BaseSpectrum::createSpectrum(EGS_Input *input) { else { egsInformation("EGS_BaseSpectrum::createSpectrum: Fluorescence and auger from the ensdf file will be ignored.\n"); } + + // Determine whether to output beta energy spectra to files + // (options: yes or no) + string tmp_outputBetaSpectra, outputBetaSpectra; + err = inp->getInput("output beta spectra", tmp_outputBetaSpectra); + if (!err) { + outputBetaSpectra = tmp_outputBetaSpectra; + } + else { + outputBetaSpectra = "no"; + } + if (outputBetaSpectra == "yes") { + egsInformation("EGS_BaseSpectrum::createSpectrum: Beta energy spectra will be output to files.\n"); + } // For ensdf input, first check for the input argument string ensdf_file; @@ -1791,7 +1799,7 @@ EGS_BaseSpectrum *EGS_BaseSpectrum::createSpectrum(EGS_Input *input) { ensdf_fh.close(); // Create the spectrum - spec = new EGS_RadionuclideSpectrum(isotope, ensdf_file, relativeActivity, useFluorescence); + spec = new EGS_RadionuclideSpectrum(isotope, ensdf_file, relativeActivity, useFluorescence, outputBetaSpectra); } else { egsWarning("%s unknown spectrum type %s\n",spec_msg1,stype.c_str()); diff --git a/HEN_HOUSE/egs++/sources/egs_radionuclide_source/egs_radionuclide_source.h b/HEN_HOUSE/egs++/sources/egs_radionuclide_source/egs_radionuclide_source.h index a7837a22e..feadad8a8 100644 --- a/HEN_HOUSE/egs++/sources/egs_radionuclide_source/egs_radionuclide_source.h +++ b/HEN_HOUSE/egs++/sources/egs_radionuclide_source/egs_radionuclide_source.h @@ -78,47 +78,124 @@ A radionuclide source is a source that delivers particles with directions uniformly distributed in \f$4 \pi\f$ emitted from \link EGS_BaseShape any shape. \endlink -Emissions are based on decays from the radionuclide isotope and can be a mix of -beta decays, X-radiations, etc. +Note that \ref EGS_RadionuclideSource is an experimental source and only a +subset of the available radionuclides have been tested against measurement. -It is defined using the following input +Emissions are based on decays from the radionuclide isotope and can be a mix of +beta, positron and alpha decays. Internal transition gamma emissions are +modeled and assigned a shower index \c ishower and \c time +to allow for coincidence counting. +Auger and fluorescence radiations are also modeled as a part of the +source, if the corresponding data is provided in the ENSDF format spectrum +files for the radionuclide. Metastable isotopes are supported. For more +information, see \ref EGS_RadionuclideSpectrum. + +A radionuclide source is defined using the following input. Notice that the +format is similar to \ref EGS_IsotropicSource. \verbatim :start source: name = my_mixture library = egs_radionuclide_source activity = total activity of mixture, assumed constant - charge = list including at least one of -1, 0, 1 to - include electrons, photons and positrons - geometry = my_geometry # see egs_isotropic_source - region selection = geometry confinement option, one of IncludeAll, - ExcludeAll, IncludeSelected, ExcludeSelected - selected regions = regions to apply geometry confinement + charge = [optional] list including at least one of -1, 0, 1, 2 + to include electrons, photons, positrons and alphas + geometry = [optional] my_geometry # see egs_isotropic_source + region selection = [optional] geometry confinement option + one of IncludeAll, ExcludeAll, + IncludeSelected, ExcludeSelected + selected regions = [required for IncludeSelected, ExcludeSelected] + regions to apply geometry confinement :start shape: definition of the shape :stop shape: :start spectrum: - type = radionuclide - isotope = name of the isotope (e.g. Sr-90), used to look up the - ensdf file as $HEN_HOUSE/spectra/lnhb/{isotope}.ensdf - if ensdf file not provided below - ensdf file = [optional] path to a spectrum file in ensdf format, - including extension - relative activity = [optional] the relative activity for this - isotope in a mixture - :stop spectrum: - :start spectrum: - type = radionuclide - isotope = name of next isotope in mixture (e.g. Y-90) - relative activity = ... + definition of an EGS_RadionuclideSpectrum (see link below) :stop spectrum: :stop source: \endverbatim The emission spectrum generation is described in \ref EGS_RadionuclideSpectrum. -Proceed with caution - \ref EGS_RadionuclideSource is in the development stages -and has not been thoroughly tested. +Note about emission times: + +The \c time of disintegration is sampled based on the +total activity of the \c mixture in \ref EGS_RadionuclideSource. +For uniform random number u, + +time += -log(1-u) / activity; +The time of emission of a transition photon is determined by sampling +the delay that occurs after disintegration, according to the transition + \c halflife . + +time += -halflife * log(1-u) / ln(2); + +It is possible for an X-Ray or Auger to be emitted before a +disintegration has taken place. They are assigned +currentTime = 0 and +ishower = -1. + +A simple example: +\verbatim +:start geometry definition: + :start geometry: + name = my_box + library = egs_box + box size = 1 2 3 + :start media input: + media = H2O521ICRU + :stop media input: + :stop geometry: + :start geometry: + name = sphere1 + library = egs_spheres + midpoint = 0 0 1 + radii = 0.3 + :start media input: + media = AIR521ICRU + :stop media input: + :stop geometry: + :start geometry: + name = sphere2 + library = egs_spheres + midpoint = 0 0 -1 + radii = 0.3 + :start media input: + media = AIR521ICRU + :stop media input: + :stop geometry: + :start geometry: + name = my_envelope + library = egs_genvelope + base geometry = my_box + inscribed geometries = sphere1 sphere2 + :stop geometry: + simulation geometry = my_envelope +:stop geometry definition: +:start source definition: + :start source: + name = my_source + library = egs_radionuclide_source + activity = 28e6 + geometry = my_envelope + region selection = IncludeSelected + selected regions = 1 2 + :start shape: + type = box + box size = 1 2 3 + :start media input: + media = H2O521ICRU + :stop media input: + :stop shape: + :start spectrum: + type = radionuclide + isotope = Ir-192 + :stop spectrum: + :stop source: + simulation source = my_source +:stop source definition: +\endverbatim +\image html egs_radionuclide_source.png "An (unrealistic) example of two spheres emitting Ir-192 radiations" */ class EGS_RADIONUCLIDE_SOURCE_EXPORT EGS_RadionuclideSource : @@ -167,35 +244,43 @@ class EGS_RADIONUCLIDE_SOURCE_EXPORT EGS_RadionuclideSource : } }; + /*! \brief Gets the next particle from the radionuclide spectra */ EGS_I64 getNextParticle(EGS_RandomGenerator *rndm, int &q, int &latch, EGS_Float &E, EGS_Float &wt, EGS_Vector &x, EGS_Vector &u); + /*! \brief Returns the maximum energy out of all the spectra */ EGS_Float getEmax() const { return Emax; }; + /*! \brief Returns the current fluence (number of disintegrations) */ EGS_Float getFluence() const { return ishower+1; }; + /*! \brief Returns the emission time of the most recent particle */ double getTime() const { return time; }; + /*! \brief Returns the shower index of the most recent particle */ EGS_I64 getShowerIndex() const { return ishower; }; + /*! \brief Outputs the emission stats of the spectra */ void printSampledEmissions() { for (unsigned int i=0; iprintSampledEmissions(); } } + /*! \brief Calculates the position and direction of a new source particle */ void getPositionDirection(EGS_RandomGenerator *rndm, EGS_Vector &x, EGS_Vector &u, EGS_Float &wt); + /*! \brief Checks the validity of the source */ bool isValid() const { return (decays.size() != 0 && shape != 0); }; @@ -243,8 +328,7 @@ class EGS_RADIONUCLIDE_SOURCE_EXPORT EGS_RadionuclideSource : void setUp(); EGS_Float min_theta, max_theta; - EGS_Float buf_1, buf_2; //! avoid multi-calculating cos(min_theta) and - // cos(max_theta) + EGS_Float buf_1, buf_2; EGS_Float min_phi, max_phi; int nrs; GeometryConfinement gc; From 0672219f7eca0080afd6bd100c44fac6256dc484 Mon Sep 17 00:00:00 2001 From: Reid Townson Date: Wed, 8 Feb 2017 14:11:59 -0500 Subject: [PATCH 27/34] Use epsilon comparisons in radionuclide source --- HEN_HOUSE/egs++/egs_ensdf.cpp | 34 +++++++++---------- HEN_HOUSE/egs++/egs_spectra.cpp | 4 +-- .../egs_radionuclide_source.cpp | 4 +-- 3 files changed, 21 insertions(+), 21 deletions(-) diff --git a/HEN_HOUSE/egs++/egs_ensdf.cpp b/HEN_HOUSE/egs++/egs_ensdf.cpp index fe2553573..f0f719323 100644 --- a/HEN_HOUSE/egs++/egs_ensdf.cpp +++ b/HEN_HOUSE/egs++/egs_ensdf.cpp @@ -409,7 +409,7 @@ void EGS_Ensdf::parseEnsdf(vector ensdf) { myGammaRecords.erase(it); } - else if ((*it)->getLevelRecord()->getEnergy() < 1e-10) { + else if ((*it)->getLevelRecord()->getEnergy() < epsilon) { // Some gamma may be emitted but the energy level is not known // This is reported in the lnhb data as decays from the -1 level // Since we cannot correlate the emission with a change of energy @@ -622,7 +622,7 @@ void EGS_Ensdf::normalizeIntensities() { totalMetastableGammaIntensity += (*gamma)->getTransitionIntensity(); totalDecayIntensity += (*gamma)->getTransitionIntensity(); } - if (totalMetastableGammaIntensity > 0 && totalMetastableGammaIntensity < 100. - 1e-10) { + if (totalMetastableGammaIntensity > 0 && totalMetastableGammaIntensity < 100. - epsilon) { double metastableFailIntensity = 100. - totalMetastableGammaIntensity; totalDecayIntensity += metastableFailIntensity; @@ -687,7 +687,7 @@ void EGS_Ensdf::normalizeIntensities() { (*alpha)->setAlphaIntensity( (*alpha)->getAlphaIntensity() / totalDecayIntensity); - if ((alpha - myAlphaRecords.begin()) == 0 && lastIntensity > 1e-10) { + if ((alpha - myAlphaRecords.begin()) == 0 && lastIntensity > epsilon) { (*alpha)->setAlphaIntensity( (*alpha)->getAlphaIntensity() + lastIntensity); } @@ -711,7 +711,7 @@ void EGS_Ensdf::normalizeIntensities() { (*gamma)->setTransitionIntensity( (*gamma)->getTransitionIntensity() / totalDecayIntensity); - if ((gamma - myMetastableGammaRecords.begin()) == 0 && lastIntensity > 1e-10) { + if ((gamma - myMetastableGammaRecords.begin()) == 0 && lastIntensity > epsilon) { (*gamma)->setTransitionIntensity( (*gamma)->getTransitionIntensity() + lastIntensity); } @@ -733,7 +733,7 @@ void EGS_Ensdf::normalizeIntensities() { xrayIntensities[i] /= totalDecayIntensity; - if (i==0 && lastIntensity > 1e-10) { + if (i==0 && lastIntensity > epsilon) { xrayIntensities[i] += lastIntensity; } else if (i > 0) { @@ -752,7 +752,7 @@ void EGS_Ensdf::normalizeIntensities() { augerIntensities[i] /= totalDecayIntensity; - if (i==0 && lastIntensity > 1e-10) { + if (i==0 && lastIntensity > epsilon) { augerIntensities[i] += lastIntensity; } else if (i > 0) { @@ -835,7 +835,7 @@ void EGS_Ensdf::normalizeIntensities() { } } - if (disintIntensity > 1e-10 && totalLevelIntensity[j] < disintIntensity + 1e-10) { + if (disintIntensity > epsilon && totalLevelIntensity[j] < disintIntensity + epsilon) { totalLevelIntensity[j] = disintIntensity; if (verbose > 1) { egsInformation("EGS_Ensdf::normalizeIntensities: " @@ -858,7 +858,7 @@ void EGS_Ensdf::normalizeIntensities() { if ((*gamma)->getLevelRecord() == (*it)) { levelCanDecay = true; - if (totalLevelIntensity[j] > 1e-10) { + if (totalLevelIntensity[j] > epsilon) { (*gamma)->setTransitionIntensity( (*gamma)->getTransitionIntensity() / totalLevelIntensity[j]); @@ -931,7 +931,7 @@ void EGS_Ensdf::getEmissionsFromComments() { if (lineTotalType == 0) { bool containsZeroIntensity = false; for (std::vector::iterator it = xrayIntensities.end()-countNumAfterTotal; it != xrayIntensities.end(); ++it) { - if (*it < 1e-10) { + if (*it < epsilon) { containsZeroIntensity = true; break; } @@ -948,7 +948,7 @@ void EGS_Ensdf::getEmissionsFromComments() { else if (lineTotalType == -1) { bool containsZeroIntensity = false; for (std::vector::iterator it = augerIntensities.end()-countNumAfterTotal; it != augerIntensities.end(); ++it) { - if (*it < 1e-10) { + if (*it < epsilon) { containsZeroIntensity = true; break; } @@ -981,7 +981,7 @@ void EGS_Ensdf::getEmissionsFromComments() { } } for (unsigned int i=0; i < multilineIntensities.size(); ++i) { - if (multilineIntensities[i] > 1e-10) { + if (multilineIntensities[i] > epsilon) { intensitySum += multilineIntensities[i]; numNonzeroI++; } @@ -1056,7 +1056,7 @@ void EGS_Ensdf::getEmissionsFromComments() { // increment a counter. This will be used in the // event that the lines following the "total" // have zero intensity assigned - if (gotTotal && energy > 1e-10) { + if (gotTotal && energy > epsilon) { countNumAfterTotal++; } @@ -1091,15 +1091,15 @@ void EGS_Ensdf::getEmissionsFromComments() { } else { if (emissionLine.at(0) == 'X') { - if ((energy > 1e-10 && intensity > 1e-10) || - (gotTotal && energy > 1e-10)) { + if ((energy > epsilon && intensity > epsilon) || + (gotTotal && energy > epsilon)) { xrayEnergies.push_back(energy); xrayIntensities.push_back(intensity); } } else if (emissionLine.find("AUGER") != std::string::npos) { - if ((energy > 1e-10 && intensity > 1e-10) || - (gotTotal && energy > 1e-10)) { + if ((energy > epsilon && intensity > epsilon) || + (gotTotal && energy > epsilon)) { augerEnergies.push_back(energy); augerIntensities.push_back(intensity); } @@ -1725,7 +1725,7 @@ void BetaPlusRecord::processEnsdf() { // For positrons we may need to calculate the emission energy // E = Q - level_energy - 2*mc^2 - if (finalEnergy == 0 && positronIntensity > 1e-10) { + if (finalEnergy == 0 && positronIntensity > epsilon) { finalEnergy = getParentRecord()->getQ() - getLevelRecord()->getEnergy() - 1.022; diff --git a/HEN_HOUSE/egs++/egs_spectra.cpp b/HEN_HOUSE/egs++/egs_spectra.cpp index 7b08407e7..3719854f3 100644 --- a/HEN_HOUSE/egs++/egs_spectra.cpp +++ b/HEN_HOUSE/egs++/egs_spectra.cpp @@ -1166,7 +1166,7 @@ class EGS_EXPORT EGS_RadionuclideSpectrum : public EGS_BaseSpectrum { // If the daughter is in an excited state // check for transitions - if (currentLevel && currentLevel->levelCanDecay() && currentLevel->getEnergy() > 1e-10) { + if (currentLevel && currentLevel->levelCanDecay() && currentLevel->getEnergy() > epsilon) { for (vector::iterator gamma = myGammas.begin(); gamma != myGammas.end(); gamma++) { @@ -1225,7 +1225,7 @@ class EGS_EXPORT EGS_RadionuclideSpectrum : public EGS_BaseSpectrum { // branches for beta+ or electron capture if (currentQ == 1) { // For positron emission, continue as usual - if ((*beta)->getPositronIntensity() > 1e-10 && rndm->getUniform() < (*beta)->getPositronIntensity()) { + if ((*beta)->getPositronIntensity() > epsilon && rndm->getUniform() < (*beta)->getPositronIntensity()) { } else { diff --git a/HEN_HOUSE/egs++/sources/egs_radionuclide_source/egs_radionuclide_source.cpp b/HEN_HOUSE/egs++/sources/egs_radionuclide_source/egs_radionuclide_source.cpp index a13e01b89..72bc5ffc5 100644 --- a/HEN_HOUSE/egs++/sources/egs_radionuclide_source/egs_radionuclide_source.cpp +++ b/HEN_HOUSE/egs++/sources/egs_radionuclide_source/egs_radionuclide_source.cpp @@ -259,7 +259,7 @@ EGS_I64 EGS_RadionuclideSource::getNextParticle(EGS_RandomGenerator *rndm, int E = decays[i]->sampleEnergy(rndm); // Skip zero energy particles - if (E < 1e-10) { + if (E < epsilon) { continue; } @@ -337,7 +337,7 @@ void EGS_RadionuclideSource::getPositionDirection(EGS_RandomGenerator *rndm, u.z = rndm->getUniform()*(buf_1 - buf_2) - buf_1; EGS_Float sinz = 1-u.z*u.z; - if (sinz > 1e-15) { + if (sinz > epsilon) { sinz = sqrt(sinz); EGS_Float cphi, sphi; EGS_Float phi = min_phi +(max_phi - min_phi)*rndm->getUniform(); From 68496b306c32eaa9974d9b6da227ef9cb8615f4a Mon Sep 17 00:00:00 2001 From: Reid Townson Date: Tue, 28 Feb 2017 13:38:18 -0500 Subject: [PATCH 28/34] Remove trailing whitespace --- HEN_HOUSE/egs++/egs_ensdf.h | 6 ++--- HEN_HOUSE/egs++/egs_spectra.cpp | 22 +++++++++---------- .../egs_radionuclide_source.h | 20 ++++++++--------- 3 files changed, 24 insertions(+), 24 deletions(-) diff --git a/HEN_HOUSE/egs++/egs_ensdf.h b/HEN_HOUSE/egs++/egs_ensdf.h index dc92c41fd..6db172704 100644 --- a/HEN_HOUSE/egs++/egs_ensdf.h +++ b/HEN_HOUSE/egs++/egs_ensdf.h @@ -390,9 +390,9 @@ emissions are taken as is. Very low probability emissions are discarded. When processing an ensdf file, only the following records are considered: Comment, Parent, Normalization, Level, Beta-, EC / Beta+, Alpha, Gamma. -X-Ray fluorescence and Auger emissions are obtained from Comment records. -If a single intensity is present for a combination of lines (but a single -energy is not provided), then the average energy of the lines is used. +X-Ray fluorescence and Auger emissions are obtained from Comment records. +If a single intensity is present for a combination of lines (but a single +energy is not provided), then the average energy of the lines is used. For example, in the case below a single line of energy 97.4527 keV would be used. \verbatim diff --git a/HEN_HOUSE/egs++/egs_spectra.cpp b/HEN_HOUSE/egs++/egs_spectra.cpp index 3719854f3..aaa6309af 100644 --- a/HEN_HOUSE/egs++/egs_spectra.cpp +++ b/HEN_HOUSE/egs++/egs_spectra.cpp @@ -545,12 +545,12 @@ class EGS_EXPORT EGS_RadionuclideBetaSpectrum { // Write the spectrum to a file if(outputBetaSpectra == "yes") { - + ostringstream ostr; ostr << decays->radionuclide << "_" << emax << ".spec"; egsInformation("EGS_RadionuclideBetaSpectrum: Outputting beta spectrum to file: %s\n", ostr.str().c_str()); - + ofstream specStream; specStream.open(ostr.str().c_str()); for (int ib=0; ib\c ishower parameter). These particles will be assigned the same shower index and time of emission as the most recent disintegration or internal transition. @@ -1743,7 +1743,7 @@ EGS_BaseSpectrum *EGS_BaseSpectrum::createSpectrum(EGS_Input *input) { else { egsInformation("EGS_BaseSpectrum::createSpectrum: Fluorescence and auger from the ensdf file will be ignored.\n"); } - + // Determine whether to output beta energy spectra to files // (options: yes or no) string tmp_outputBetaSpectra, outputBetaSpectra; diff --git a/HEN_HOUSE/egs++/sources/egs_radionuclide_source/egs_radionuclide_source.h b/HEN_HOUSE/egs++/sources/egs_radionuclide_source/egs_radionuclide_source.h index feadad8a8..9247bf675 100644 --- a/HEN_HOUSE/egs++/sources/egs_radionuclide_source/egs_radionuclide_source.h +++ b/HEN_HOUSE/egs++/sources/egs_radionuclide_source/egs_radionuclide_source.h @@ -78,13 +78,13 @@ A radionuclide source is a source that delivers particles with directions uniformly distributed in \f$4 \pi\f$ emitted from \link EGS_BaseShape any shape. \endlink -Note that \ref EGS_RadionuclideSource is an experimental source and only a +Note that \ref EGS_RadionuclideSource is an experimental source and only a subset of the available radionuclides have been tested against measurement. Emissions are based on decays from the radionuclide isotope and can be a mix of -beta, positron and alpha decays. Internal transition gamma emissions are +beta, positron and alpha decays. Internal transition gamma emissions are modeled and assigned a shower index \c ishower and \c time -to allow for coincidence counting. +to allow for coincidence counting. Auger and fluorescence radiations are also modeled as a part of the source, if the corresponding data is provided in the ENSDF format spectrum files for the radionuclide. Metastable isotopes are supported. For more @@ -97,11 +97,11 @@ format is similar to \ref EGS_IsotropicSource. name = my_mixture library = egs_radionuclide_source activity = total activity of mixture, assumed constant - charge = [optional] list including at least one of -1, 0, 1, 2 + charge = [optional] list including at least one of -1, 0, 1, 2 to include electrons, photons, positrons and alphas geometry = [optional] my_geometry # see egs_isotropic_source - region selection = [optional] geometry confinement option - one of IncludeAll, ExcludeAll, + region selection = [optional] geometry confinement option + one of IncludeAll, ExcludeAll, IncludeSelected, ExcludeSelected selected regions = [required for IncludeSelected, ExcludeSelected] regions to apply geometry confinement @@ -119,19 +119,19 @@ The emission spectrum generation is described in \ref EGS_RadionuclideSpectrum. Note about emission times: The \c time of disintegration is sampled based on the -total activity of the \c mixture in \ref EGS_RadionuclideSource. +total activity of the \c mixture in \ref EGS_RadionuclideSource. For uniform random number u, time += -log(1-u) / activity; -The time of emission of a transition photon is determined by sampling -the delay that occurs after disintegration, according to the transition +The time of emission of a transition photon is determined by sampling +the delay that occurs after disintegration, according to the transition \c halflife . time += -halflife * log(1-u) / ln(2); It is possible for an X-Ray or Auger to be emitted before a -disintegration has taken place. They are assigned +disintegration has taken place. They are assigned currentTime = 0 and ishower = -1. From c6b7f07561dc25a120f1a848e6a83f61034235b0 Mon Sep 17 00:00:00 2001 From: Reid Townson Date: Thu, 16 Mar 2017 09:44:40 -0400 Subject: [PATCH 29/34] Update ENSDF data files from LNHB --- HEN_HOUSE/egs++/egs_ensdf.cpp | 5 + HEN_HOUSE/spectra/lnhb/Ac-225.txt | 799 ++++++------ HEN_HOUSE/spectra/lnhb/Ac-227.txt | 517 ++++---- HEN_HOUSE/spectra/lnhb/Ac-228.txt | 1465 ++++++++++++---------- HEN_HOUSE/spectra/lnhb/Ag-108.txt | 183 ++- HEN_HOUSE/spectra/lnhb/Ag-108m.txt | 132 +- HEN_HOUSE/spectra/lnhb/Ag-110.txt | 184 +-- HEN_HOUSE/spectra/lnhb/Ag-110m.txt | 364 +++--- HEN_HOUSE/spectra/lnhb/Al-26.txt | 60 +- HEN_HOUSE/spectra/lnhb/Am-241.txt | 916 +++++++------- HEN_HOUSE/spectra/lnhb/Am-242.txt | 166 +-- HEN_HOUSE/spectra/lnhb/Am-242m.txt | 569 +++++---- HEN_HOUSE/spectra/lnhb/Am-243.txt | 187 +-- HEN_HOUSE/spectra/lnhb/Am-244.txt | 116 +- HEN_HOUSE/spectra/lnhb/Am-244m.txt | 198 +-- HEN_HOUSE/spectra/lnhb/Ar-37.txt | 57 +- HEN_HOUSE/spectra/lnhb/Ar-41.txt | 67 +- HEN_HOUSE/spectra/lnhb/At-211.txt | 200 +-- HEN_HOUSE/spectra/lnhb/At-215.txt | 78 +- HEN_HOUSE/spectra/lnhb/At-217.txt | 114 +- HEN_HOUSE/spectra/lnhb/At-218.txt | 48 +- HEN_HOUSE/spectra/lnhb/At-219.txt | 112 +- HEN_HOUSE/spectra/lnhb/Au-195.txt | 124 +- HEN_HOUSE/spectra/lnhb/Au-198.txt | 123 +- HEN_HOUSE/spectra/lnhb/Ba-133.txt | 168 +-- HEN_HOUSE/spectra/lnhb/Ba-137m.txt | 60 +- HEN_HOUSE/spectra/lnhb/Ba-140.txt | 176 +-- HEN_HOUSE/spectra/lnhb/Be-7.txt | 40 +- HEN_HOUSE/spectra/lnhb/Bi-207.txt | 115 +- HEN_HOUSE/spectra/lnhb/Bi-210.txt | 176 +-- HEN_HOUSE/spectra/lnhb/Bi-211.txt | 143 ++- HEN_HOUSE/spectra/lnhb/Bi-212.txt | 333 ++--- HEN_HOUSE/spectra/lnhb/Bi-213.txt | 239 ++-- HEN_HOUSE/spectra/lnhb/Bi-214.txt | 1208 +++++++++--------- HEN_HOUSE/spectra/lnhb/Bi-215.txt | 199 +-- HEN_HOUSE/spectra/lnhb/Br-76.txt | 862 +++++++------ HEN_HOUSE/spectra/lnhb/C-11.txt | 20 +- HEN_HOUSE/spectra/lnhb/C-14.txt | 26 +- HEN_HOUSE/spectra/lnhb/Ca-41.txt | 65 +- HEN_HOUSE/spectra/lnhb/Ca-45.txt | 36 +- HEN_HOUSE/spectra/lnhb/Cd-109.txt | 97 +- HEN_HOUSE/spectra/lnhb/Ce-139.txt | 77 +- HEN_HOUSE/spectra/lnhb/Ce-141.txt | 91 +- HEN_HOUSE/spectra/lnhb/Ce-144.txt | 140 ++- HEN_HOUSE/spectra/lnhb/Cf-252.txt | 104 +- HEN_HOUSE/spectra/lnhb/Cl-36.txt | 106 +- HEN_HOUSE/spectra/lnhb/Cm-242.txt | 261 ++-- HEN_HOUSE/spectra/lnhb/Cm-243.txt | 408 +++--- HEN_HOUSE/spectra/lnhb/Cm-244.txt | 209 ++-- HEN_HOUSE/spectra/lnhb/Cm-245.txt | 189 +-- HEN_HOUSE/spectra/lnhb/Cm-246.txt | 85 +- HEN_HOUSE/spectra/lnhb/Co-56.txt | 228 ++-- HEN_HOUSE/spectra/lnhb/Co-57.txt | 123 +- HEN_HOUSE/spectra/lnhb/Co-58.txt | 106 +- HEN_HOUSE/spectra/lnhb/Co-60.txt | 100 +- HEN_HOUSE/spectra/lnhb/Cr-51.txt | 91 +- HEN_HOUSE/spectra/lnhb/Cs-134.txt | 215 ++-- HEN_HOUSE/spectra/lnhb/Cs-137.txt | 88 +- HEN_HOUSE/spectra/lnhb/Cu-61.txt | 219 ++-- HEN_HOUSE/spectra/lnhb/Cu-64.txt | 109 +- HEN_HOUSE/spectra/lnhb/Er-169.txt | 76 +- HEN_HOUSE/spectra/lnhb/Eu-152.txt | 814 ++++++------ HEN_HOUSE/spectra/lnhb/Eu-154.txt | 699 +++++------ HEN_HOUSE/spectra/lnhb/Eu-155.txt | 149 ++- HEN_HOUSE/spectra/lnhb/F-18.txt | 57 +- HEN_HOUSE/spectra/lnhb/Fe-52.txt | 88 +- HEN_HOUSE/spectra/lnhb/Fe-55.txt | 69 +- HEN_HOUSE/spectra/lnhb/Fe-59.txt | 131 +- HEN_HOUSE/spectra/lnhb/Fr-221.txt | 240 ++-- HEN_HOUSE/spectra/lnhb/Fr-223.txt | 729 +++++------ HEN_HOUSE/spectra/lnhb/Ga-66.txt | 486 ++++---- HEN_HOUSE/spectra/lnhb/Ga-67.txt | 149 ++- HEN_HOUSE/spectra/lnhb/Ga-68.txt | 153 ++- HEN_HOUSE/spectra/lnhb/Gd-153.txt | 140 ++- HEN_HOUSE/spectra/lnhb/Gd-159.txt | 188 ++- HEN_HOUSE/spectra/lnhb/Ge-68.txt | 72 +- HEN_HOUSE/spectra/lnhb/H-3.txt | 24 +- HEN_HOUSE/spectra/lnhb/Hg-203.txt | 74 +- HEN_HOUSE/spectra/lnhb/Hg-206.txt | 114 +- HEN_HOUSE/spectra/lnhb/Ho-166.txt | 173 +-- HEN_HOUSE/spectra/lnhb/Ho-166m.txt | 400 +++--- HEN_HOUSE/spectra/lnhb/I-123.txt | 252 ++-- HEN_HOUSE/spectra/lnhb/I-125.txt | 90 +- HEN_HOUSE/spectra/lnhb/I-129.txt | 67 +- HEN_HOUSE/spectra/lnhb/I-131.txt | 214 ++-- HEN_HOUSE/spectra/lnhb/I-133.txt | 286 +++-- HEN_HOUSE/spectra/lnhb/In-111.txt | 102 +- HEN_HOUSE/spectra/lnhb/Ir-192.txt | 298 +++-- HEN_HOUSE/spectra/lnhb/Ir-194.txt | 424 +++---- HEN_HOUSE/spectra/lnhb/K-40.txt | 137 +- HEN_HOUSE/spectra/lnhb/Kr-85.txt | 76 +- HEN_HOUSE/spectra/lnhb/La-138.txt | 174 ++- HEN_HOUSE/spectra/lnhb/La-140.txt | 372 +++--- HEN_HOUSE/spectra/lnhb/Lu-177.txt | 106 +- HEN_HOUSE/spectra/lnhb/Mn-54.txt | 90 +- HEN_HOUSE/spectra/lnhb/Mn-56.txt | 110 +- HEN_HOUSE/spectra/lnhb/Mo-99.txt | 248 ++-- HEN_HOUSE/spectra/lnhb/N-13.txt | 14 +- HEN_HOUSE/spectra/lnhb/Na-22.txt | 65 +- HEN_HOUSE/spectra/lnhb/Na-24.txt | 112 +- HEN_HOUSE/spectra/lnhb/Nb-93m.txt | 81 +- HEN_HOUSE/spectra/lnhb/Nb-95.txt | 83 +- HEN_HOUSE/spectra/lnhb/Nb-95m.txt | 144 ++- HEN_HOUSE/spectra/lnhb/Nd-147.txt | 277 +++-- HEN_HOUSE/spectra/lnhb/Ni-57.txt | 168 +-- HEN_HOUSE/spectra/lnhb/Ni-59.txt | 66 +- HEN_HOUSE/spectra/lnhb/Ni-63.txt | 52 +- HEN_HOUSE/spectra/lnhb/Np-236.txt | 345 +++--- HEN_HOUSE/spectra/lnhb/Np-236m.txt | 194 +-- HEN_HOUSE/spectra/lnhb/Np-237.txt | 437 ++++--- HEN_HOUSE/spectra/lnhb/Np-238.txt | 291 +++-- HEN_HOUSE/spectra/lnhb/Np-239.txt | 288 ++--- HEN_HOUSE/spectra/lnhb/O-15.txt | 14 +- HEN_HOUSE/spectra/lnhb/P-32.txt | 14 +- HEN_HOUSE/spectra/lnhb/P-33.txt | 14 +- HEN_HOUSE/spectra/lnhb/Pa-231.txt | 482 +++---- HEN_HOUSE/spectra/lnhb/Pa-233.txt | 297 ++--- HEN_HOUSE/spectra/lnhb/Pa-234.txt | 1863 ++++++++++++++++------------ HEN_HOUSE/spectra/lnhb/Pa-234m.txt | 766 ++++++------ HEN_HOUSE/spectra/lnhb/Pb-203.txt | 107 +- HEN_HOUSE/spectra/lnhb/Pb-209.txt | 62 +- HEN_HOUSE/spectra/lnhb/Pb-210.txt | 139 ++- HEN_HOUSE/spectra/lnhb/Pb-211.txt | 205 +-- HEN_HOUSE/spectra/lnhb/Pb-212.txt | 124 +- HEN_HOUSE/spectra/lnhb/Pb-214.txt | 213 ++-- HEN_HOUSE/spectra/lnhb/Pd-109.txt | 329 ++--- HEN_HOUSE/spectra/lnhb/Pm-147.txt | 113 +- HEN_HOUSE/spectra/lnhb/Pm-148.txt | 241 ++-- HEN_HOUSE/spectra/lnhb/Pm-148m.txt | 307 ++--- HEN_HOUSE/spectra/lnhb/Po-209.txt | 167 +-- HEN_HOUSE/spectra/lnhb/Po-210.txt | 92 +- HEN_HOUSE/spectra/lnhb/Po-211.txt | 99 +- HEN_HOUSE/spectra/lnhb/Po-212.txt | 34 +- HEN_HOUSE/spectra/lnhb/Po-213.txt | 38 +- HEN_HOUSE/spectra/lnhb/Po-214.txt | 79 +- HEN_HOUSE/spectra/lnhb/Po-215.txt | 178 +-- HEN_HOUSE/spectra/lnhb/Po-216.txt | 83 +- HEN_HOUSE/spectra/lnhb/Po-218.txt | 122 +- HEN_HOUSE/spectra/lnhb/Pr-142.txt | 96 ++ HEN_HOUSE/spectra/lnhb/Pr-144.txt | 227 ++-- HEN_HOUSE/spectra/lnhb/Pr-144m.txt | 197 +-- HEN_HOUSE/spectra/lnhb/Pu-238.txt | 303 +++-- HEN_HOUSE/spectra/lnhb/Pu-239.txt | 1020 +++++++-------- HEN_HOUSE/spectra/lnhb/Pu-240.txt | 205 +-- HEN_HOUSE/spectra/lnhb/Pu-241.txt | 240 ++-- HEN_HOUSE/spectra/lnhb/Pu-242.txt | 103 +- HEN_HOUSE/spectra/lnhb/Ra-223.txt | 433 ++++--- HEN_HOUSE/spectra/lnhb/Ra-224.txt | 119 +- HEN_HOUSE/spectra/lnhb/Ra-225.txt | 70 +- HEN_HOUSE/spectra/lnhb/Ra-226.txt | 109 +- HEN_HOUSE/spectra/lnhb/Ra-228.txt | 94 +- HEN_HOUSE/spectra/lnhb/Rb-82.txt | 313 ++--- HEN_HOUSE/spectra/lnhb/Re-186.txt | 198 +-- HEN_HOUSE/spectra/lnhb/Re-188.txt | 338 ++--- HEN_HOUSE/spectra/lnhb/Rh-106.txt | 549 ++++---- HEN_HOUSE/spectra/lnhb/Rn-217.txt | 29 +- HEN_HOUSE/spectra/lnhb/Rn-218.txt | 69 +- HEN_HOUSE/spectra/lnhb/Rn-219.txt | 211 ++-- HEN_HOUSE/spectra/lnhb/Rn-220.txt | 85 +- HEN_HOUSE/spectra/lnhb/Rn-222.txt | 75 +- HEN_HOUSE/spectra/lnhb/Ru-106.txt | 57 +- HEN_HOUSE/spectra/lnhb/S-35.txt | 38 +- HEN_HOUSE/spectra/lnhb/Sb-124.txt | 483 ++++---- HEN_HOUSE/spectra/lnhb/Sb-125.txt | 222 ++-- HEN_HOUSE/spectra/lnhb/Sb-127.txt | 350 +++--- HEN_HOUSE/spectra/lnhb/Sc-44.txt | 78 +- HEN_HOUSE/spectra/lnhb/Sc-46.txt | 93 +- HEN_HOUSE/spectra/lnhb/Sc-47.txt | 75 +- HEN_HOUSE/spectra/lnhb/Se-73.txt | 358 +++--- HEN_HOUSE/spectra/lnhb/Se-75.txt | 214 ++-- HEN_HOUSE/spectra/lnhb/Se-79.txt | 41 +- HEN_HOUSE/spectra/lnhb/Sm-151.txt | 86 +- HEN_HOUSE/spectra/lnhb/Sm-153.txt | 349 +++--- HEN_HOUSE/spectra/lnhb/Sn-113.txt | 101 +- HEN_HOUSE/spectra/lnhb/Sr-82.txt | 69 +- HEN_HOUSE/spectra/lnhb/Sr-85.txt | 121 +- HEN_HOUSE/spectra/lnhb/Sr-89.txt | 52 +- HEN_HOUSE/spectra/lnhb/Sr-90.txt | 65 +- HEN_HOUSE/spectra/lnhb/Ta-182.txt | 368 +++--- HEN_HOUSE/spectra/lnhb/Tc-94m.txt | 423 ++++--- HEN_HOUSE/spectra/lnhb/Tc-99.txt | 90 +- HEN_HOUSE/spectra/lnhb/Tc-99m.txt | 140 +-- HEN_HOUSE/spectra/lnhb/Te-123m.txt | 87 +- HEN_HOUSE/spectra/lnhb/Te-127.txt | 154 +-- HEN_HOUSE/spectra/lnhb/Te-127m.txt | 212 ++-- HEN_HOUSE/spectra/lnhb/Te-132.txt | 101 +- HEN_HOUSE/spectra/lnhb/Th-228.txt | 179 +-- HEN_HOUSE/spectra/lnhb/Th-231.txt | 380 +++--- HEN_HOUSE/spectra/lnhb/Th-232.txt | 91 +- HEN_HOUSE/spectra/lnhb/Th-233.txt | 687 +++++----- HEN_HOUSE/spectra/lnhb/Th-234.txt | 167 +-- HEN_HOUSE/spectra/lnhb/Ti-44.txt | 70 +- HEN_HOUSE/spectra/lnhb/Tl-201.txt | 131 +- HEN_HOUSE/spectra/lnhb/Tl-204.txt | 106 +- HEN_HOUSE/spectra/lnhb/Tl-206.txt | 93 +- HEN_HOUSE/spectra/lnhb/Tl-207.txt | 104 +- HEN_HOUSE/spectra/lnhb/Tl-208.txt | 309 ++--- HEN_HOUSE/spectra/lnhb/Tl-209.txt | 215 ++-- HEN_HOUSE/spectra/lnhb/Tl-210.txt | 164 +-- HEN_HOUSE/spectra/lnhb/Tm-170.txt | 144 +-- HEN_HOUSE/spectra/lnhb/U-232.txt | 177 +-- HEN_HOUSE/spectra/lnhb/U-234.txt | 137 +- HEN_HOUSE/spectra/lnhb/U-235.txt | 425 ++++--- HEN_HOUSE/spectra/lnhb/U-236.txt | 98 +- HEN_HOUSE/spectra/lnhb/U-237.txt | 252 ++-- HEN_HOUSE/spectra/lnhb/U-238.txt | 99 +- HEN_HOUSE/spectra/lnhb/U-239.txt | 666 +++++----- HEN_HOUSE/spectra/lnhb/Xe-127.txt | 120 +- HEN_HOUSE/spectra/lnhb/Xe-131m.txt | 79 +- HEN_HOUSE/spectra/lnhb/Xe-133.txt | 124 +- HEN_HOUSE/spectra/lnhb/Xe-133m.txt | 79 +- HEN_HOUSE/spectra/lnhb/Xe-135m.txt | 175 ++- HEN_HOUSE/spectra/lnhb/Y-88.txt | 131 +- HEN_HOUSE/spectra/lnhb/Y-90.txt | 100 +- HEN_HOUSE/spectra/lnhb/Y-90m.txt | 154 +-- HEN_HOUSE/spectra/lnhb/Yb-169.txt | 322 ++--- HEN_HOUSE/spectra/lnhb/Zn-63.txt | 370 +++--- HEN_HOUSE/spectra/lnhb/Zn-65.txt | 90 +- HEN_HOUSE/spectra/lnhb/Zr-89.txt | 126 +- HEN_HOUSE/spectra/lnhb/Zr-93.txt | 80 +- HEN_HOUSE/spectra/lnhb/Zr-95.txt | 86 +- 221 files changed, 24394 insertions(+), 22412 deletions(-) create mode 100644 HEN_HOUSE/spectra/lnhb/Pr-142.txt diff --git a/HEN_HOUSE/egs++/egs_ensdf.cpp b/HEN_HOUSE/egs++/egs_ensdf.cpp index f0f719323..0fb4fd7d3 100644 --- a/HEN_HOUSE/egs++/egs_ensdf.cpp +++ b/HEN_HOUSE/egs++/egs_ensdf.cpp @@ -1189,6 +1189,11 @@ double Record::parseHalfLife(int startPos, int endPos) { egsWarning("Record::parseHalfLife: Error: Record is empty\n"); return -5; } + if (lines.front().length() < startPos) { + egsWarning("Record::parseHalfLife: Warning: Record too short to " + "contain desired quantity\n"); + return -5; + } string halfLifeStr = egsTrimString(lines.front().substr(startPos-1, endPos-startPos+1)); diff --git a/HEN_HOUSE/spectra/lnhb/Ac-225.txt b/HEN_HOUSE/spectra/lnhb/Ac-225.txt index c067cd0e0..a99a0eddc 100644 --- a/HEN_HOUSE/spectra/lnhb/Ac-225.txt +++ b/HEN_HOUSE/spectra/lnhb/Ac-225.txt @@ -1,358 +1,441 @@ -221FR 225AC A DECAY (10.0 D) -221FR H TYP=Full$AUT=Huang Xiaolong$CUT=31-DEC-2008$ -221FR C Evaluation history: Type=Full;Author=Huang Xiaolong;Cutoff date=31-DEC-2008 -221FR T Auger electrons and X ray energies and emission intensities: -221FR T {U Energy (keV)} {U Intensity} {U Line} -221FR T -221FR T 83.23 1.00 8 XKA2 -221FR T 86.1 1.64 12 XKA1 -221FR T -221FR T 96.815 |] XKB3 -221FR T 97.474 |] 0.57 5 XKB1 -221FR T 98.069 |] XKB5II -221FR T -221FR T 100.16 |] XKB2 -221FR T 100.548 |] 0.19 2 XKB4 -221FR T 100.972 |] XKO23 -221FR T -221FR T 10.38-17.799 18.7 9 XL (total) -221FR T 10.38 XLL -221FR T 11.89-12.03 XLA -221FR T 13.254 XLC -221FR T 13.877-15.639 XLB -221FR T 16.752-17.799 XLG -221FR T -221FR T 63.576-70.787 |] KLL AUGER -221FR T 77.72-86.101 |] 0.115 9 KLX AUGER -221FR T 91.84-101.12 |] KXY AUGER -221FR T 5.73-18.52 23.8 12 L AUGER -225AC P 0.0 (3/2)- 10.0 D 1 5935.1 14 -221FR N 1.0 1.0 1 1.0 -221FR L 0 5/2- 4.79 M 2 -221FR A 5829.6 1452.4 248.7 -221FR L 25.856 17(1/2,3/2)- -221FR A 5804.2 140.3 1135 -221FR G 26.00 100.00159 21E2 5.94E3 15 -221FR2 G LC=4.39E3 11$MC=1180 30 -221FR L 36.646 11(3/2)- 1.5 NS 2 -221FR A 5793.1 2118.9 2016 -221FR G 10.6 0.015 2M1 510 7 -221FR2 G MC=383 5 -221FR G 36.69 3 0.0181 15E2 1092 16 -221FR2 G LC=806 12$MC=217 4 -221FR L 38.546 12(9/2)- -221FR A 5791.7 146.2 9 48 -221FR G 38.58 4 0.0107 10E2 854 13 -221FR2 G LC=630 10$MC=169 3 -221FR L 99.596 13(3/2)- 80 PS 30 -221FR A 5731.9 179.0 5 16.4 -221FR G 62.94 3 0.49 3M1 10.85 15 -221FR2 G LC=8.24 12$MC=1.964 28 -221FR G 73.55 9 0.019 5E2 37.5 6 -221FR2 G LC=27.6 4$MC=7.48 11 -221FR G 99.67 5 0.76 5M1+E2 0.19 4 3.06 11 -221FR2 G LC=2.32 8$MC=0.56 2 -221FR L 99.752 16(3/2)+ 160 PS 30 -221FR A 5731.6 141.24 10119 -221FR G 63.5 3 0.021 3[E1] 0.360 7 -221FR2 G LC=0.273 5$MC=0.0660 12 -221FR G 73.85 3 0.309 23E1 0.240 3 -221FR2 G LC=0.182 3$MC=0.0440 6 -221FR G 99.89 6 1.08 8E1 0.1073 15 -221FR2 G LC=0.0814 11$MC=0.0196 3 -221FR L 100.897 11(5/2)- -221FR A 5730.5 141.6 3 91 -221FR G 62.6 3 0.0053 12[E2] 81.2 23 -221FR2 G LC=59.8 16$MC=16.2 5 -221FR G 64.27 3 0.047 4M1+E2 0.51 10 23 4 -221FR2 G LC=17 3$MC=4.4 8 -221FR G 74.82 5 0.015 3(M1+E2) 0.5 12.15 18 -221FR2 G LC=9.06 13$MC=2.32 4 -221FR G 100.86 4 0.096 8M1+E2 0.7 7 4.6 19 -221FR2 G LC=3.4 14$MC=0.9 4 -221FR L 108.404 11(7/2)- 280 PS -221FR A 5723.1 142.03 2366 -221FR G 69.86 5 0.0047 12E2 47.9 7 -221FR2 G LC=35.3 5$MC=9.55 14 -221FR G 71.71 4 0.0132 13E2 42.3 6 -221FR2 G LC=31.1 5$MC=8.43 12 -221FR G 108.38 3 0.255 16M1+E2 0.53 6 10.27 25 -221FR2 G KC=7.2 4$LC=2.30 12$MC=0.58 4 -221FR L 145.755 20(1/2)+ -221FR A 5686.4 140.021 144100 -221FR G 46.24 5 0.0049 7[E1] 0.841 12 -221FR2 G LC=0.636 9$MC=0.155 2 -221FR G 119.85 3 0.080 5[E1] 0.305 4 -221FR2 G KC=0.239 4$LC=0.0503 7$MC=0.01207 17 -221FR L 150.063 13(7/2)+ 80 PS 20 -221FR A 5682.2 141.31 4 62.9 -221FR G 49.12 4 0.0080 8[E1] 0.715 11 -221FR2 G LC=0.541 8$MC=0.1320 19 -221FR G 50.2 0.00062 [E2] 236.0 34 -221FR2 G LC=174.2 25$MC=47.0 7 -221FR G 111.52 3 0.313 21(E1) 0.363 5 -221FR2 G KC=0.282 4$LC=0.0609 9$MC=0.01461 21 -221FR G 150.05 3 0.693 12E1 0.1766 25 -221FR2 G KC=0.1397 20$LC=0.0280 4$MC=0.0067 1 -221FR L 195.789 11(5/2,7/2)- 20 PS 5 -221FR A 5637.3 144.16 2311.6 -221FR G 87.41 3 0.271 19M1 4.16 6 -221FR2 G LC=3.16 5$MC=0.754 10 -221FR G 94.90 2 0.105 10M1 3.28 5 -221FR2 G LC=2.49 3$MC=0.594 8 -221FR G 96.16 5 0.033 7M1+E2 0.8 3 6.0 14 -221FR2 G LC=4.5 10$MC=1.2 3 -221FR G 157.250 300.36 3M1+E2 0.21 21 3.8 3 -221FR2 G KC=3.1 4$LC=0.59 3$MC=0.143 9 -221FR G 169.9 0.0139 14 -221FR G 195.74 3 0.148 9M1+E2 0.8 8 1.5 6 -221FR2 G KC=1.1 6$LC=0.314 5$MC=0.079 4 -221FR L 224.567 13(3/2,5/2)+ 35 PS 10 -221FR A 5609.0 141.09 5 31.5 -221FR G 78.8 0.0123 19M1 5.63 8 -221FR2 G LC=4.27 6$MC=1.019 14 -221FR G 123.75 4 0.087 6[E1] 0.282 4 -221FR2 G KC=0.221 4$LC=0.0463 7$MC=0.0111 2 -221FR G 124.81 3 0.0292 18M1+E2 0.8 6.01 -221FR2 G KC=3.87 $LC=1.593 $MC=0.409 -221FR G 186.1 0.0127 14 -221FR G 187.96 3 0.53 3E1 0.1023 14 -221FR2 G KC=0.0816 12$LC=0.01571 22$MC=0.00375 6 -221FR G 198.47 230.0188 13[E1] 0.0898 13 -221FR2 G KC=0.0718 11$LC=0.01369 20$MC=0.00327 5 -221FR G 224.59 3 0.112 8[E1] 0.0669 9 -221FR2 G KC=0.0537 8$LC=0.01005 14$MC=0.00239 4 -221FR L 234.470 18(5/2)+ -221FR A 5599.3 140.114 7 268 -221FR G 126.10 5 0.0079 7(E1) 0.270 4 -221FR2 G KC=0.212 3$LC=0.0440 7$MC=0.0106 2 -221FR G 133.60 3 0.0196 16(E1) 0.234 3 -221FR2 G KC=0.184 3$LC=0.0379 6$MC=0.00907 13 -221FR G 134.850 300.032 3(E1) 0.229 3 -221FR2 G KC=0.180 3$LC=0.0370 6$MC=0.00885 13 -221FR G 197.70 100.038 5[E1] 0.0906 13 -221FR2 G KC=0.0724 11$LC=0.01382 20$MC=0.00330 5 -221FR L 253.551 12(5/2)+ 35 PS 15 -221FR A 5580.5 140.95 4 25.6 -221FR G 57.71 4 0.0051 8(E1) 0.465 7 -221FR2 G LC=0.352 5$MC=0.0854 12 -221FR G 103.48 100.0030 7[M1E2] 10 3 -221FR2 G KC=5 2$LC=3.7 18$MC=1.0 5 -221FR G 145.15 3 0.146 9(E1) 0.191 3 -221FR2 G KC=0.1513 22$LC=0.0305 5$MC=0.00730 11 -221FR G 152.64 3 0.0197 13[E1] 0.1694 24 -221FR2 G KC=0.1341 19$LC=0.0268 4$MC=0.00640 9 -221FR G 153.920 300.205 13E1 0.1660 23 -221FR2 G KC=0.1315 19$LC=0.0262 4$MC=0.00627 9 -221FR G 216.89 3 0.32 2(E1) 0.0726 10 -221FR2 G KC=0.0582 9$LC=0.01096 16$MC=0.00261 4 -221FR G 228.2 4 0.0046 12 -221FR G 253.46 3 0.132 8[E1] 0.0504 7 -221FR2 G KC=0.0405 6$LC=0.00747 11$MC=1776E-6 25 -221FR L 271.14 7 (5/2,7/2,9/2)- -221FR A 5563.3 140.017 7 1160 -221FR G 121.06 7 0.017 5(E1) 0.298 4 -221FR2 G KC=0.233 4$LC=0.0490 7$MC=0.01176 17 -221FR G 236.0 6 0.0017 3 -221FR L 279.209 17(7/2)+ -221FR A 5555.3 140.084 10213 -221FR G 129.22 7 0.0027 5[M1E2] 5 2 -221FR2 G KC=3 3$LC=1.5 5$MC=0.39 15 -221FR G 170.77 5 0.013 7(E1) 0.1290 18 -221FR2 G KC=0.1026 15$LC=0.0201 3$MC=0.00479 7 -221FR G 178.29 3 0.0161 12E1 0.1162 16 -221FR2 G KC=0.0925 13$LC=0.0180 3$MC=0.00429 6 -221FR G 240.68 3 0.0117 10[E1] 0.0568 8 -221FR2 G KC=0.0457 7$LC=0.00847 12$MC=0.00202 3 -221FR G 279.18 3 0.0305 22E1 0.0403 6 -221FR2 G KC=0.0325 5$LC=0.00591 9$MC=1405E-6 20 -221FR L 288.16 3 (9/2)- -221FR A 5546.5 140.055 12292 -221FR G 179.78 4 0.0108 8(M1E2) 1.8 10 -221FR2 G KC=1.2 10$LC=0.43 3$MC=0.109 14 -221FR G 187.2 0.0103 7 -221FR G 249.60 3 0.0135 10(E2) 0.258 4 -221FR2 G KC=0.1033 15$LC=0.1145 16$MC=0.0305 5 -221FR L 294.69 4 (9/2)+ -221FR A 5540.1 140.0072 8 2060 -221FR G 144.70 200.00046 12(M1+E2) 0.8 3.79 -221FR2 G KC=2.57 $LC=0.914 $MC=0.232 -221FR G 186.29 3 0.0042 5E1 0.1045 15 -221FR2 G KC=0.0834 12$LC=0.01607 23$MC=0.00383 6 -221FR G 256.0 2 0.00037 7[E1] 0.0492 7 -221FR2 G KC=0.0396 6$LC=0.00729 11$MC=1733E-6 25 -221FR L 311.41 8 (5/2,7/2,9/2)+ -221FR A 5523.7 140.013 6 930 -221FR G 161.35 7 0.0036 9[M1E2] 2.5 13 -221FR2 G KC=1.6 14$LC=0.64 10$MC=0.16 4 -221FR L 320.03 8 (1/2,3/2,5/2)+ -221FR A 5515.2 140.0052 192100 -221FR G 220.43 8 0.0060 18 -221FR L 338.24 8 (1/2,3/2,5/2)- -221FR A 5497.4 140.0022 7 4000 -221FR G 238.64 8 0.0010 3(M1) 1.225 17 -221FR2 G KC=0.988 14$LC=0.180 3$MC=0.0428 6 -221FR L 348.35 4 (3/2,5/2,7/2)+ -221FR A 5487.4 140.0020 3 3860 -221FR G 348.33 5 0.0030 3 -221FR L 367.74 12 + -221FR A 5468.4 140.00052 1811700 -221FR G 367.74 120.00052 18 -221FR L 393.300 18(5/2,7/2,9/2)+ -221FR A 5443.3 140.098 1945 -221FR G 114 0.00087 13M1 9.86 14 -221FR2 G KC=7.93 12$LC=1.466 21$MC=0.350 5 -221FR G 139.6 0.00139 21M1+E2 3.9 17 -221FR2 G KC=2.4 21$LC=1.1 3$MC=0.29 9 -221FR G 169.18 4 0.012 5[M1E2] 2.1 11 -221FR2 G KC=1.4 12$LC=0.53 6$MC=0.136 24 -221FR G 197.50 3 0.026 3E1 0.0908 13 -221FR2 G KC=0.0726 11$LC=0.01386 20$MC=0.00331 5 -221FR G 243.12 5 0.0031 4[M1] 1.163 16 -221FR2 G KC=0.938 14$LC=0.1707 24$MC=0.0407 6 -221FR G 284.75 3 0.0074 6[E1] 0.0385 5 -221FR2 G KC=0.0311 5$LC=0.00564 8$MC=1340E-6 19 -221FR G 354.56 6 0.0020 7[E1] 0.0236 3 -221FR2 G KC=0.0191 3$LC=0.00338 5$MC=8.00E-4 12 -221FR L 400.94 4 (11/2)+ -221FR A 5435.8 140.0083 6 485 -221FR G 112.80 2 0.0021 3[E1] 0.353 5 -221FR2 G KC=0.275 4$LC=0.0591 9$MC=0.01417 21 -221FR G 362.380 300.0054 5(E1) 0.0225 3 -221FR2 G KC=0.0182 3$LC=0.00321 6$MC=7610E-7 11 -221FR L 406.73 6 (3/2,5/2,7/2)- -221FR A 5430.1 140.0028 8 1340 -221FR G 298.33 5 0.0020 3(M1E2) 0.4 3 -221FR2 G KC=0.30 24$LC=0.077 20$MC=0.019 4 -221FR L 408.54 13 + -221FR A 5428.3 140.0023 3 1590 -221FR G 137.4 1 0.0023 3 -221FR L 422.65 4 (3/2,5/2,7/2)+ -221FR A 5414.5 140.0030 4 1020 -221FR G 321.77 4 0.0033 4[E1] 0.0292 4 -221FR2 G KC=0.0237 4$LC=0.00423 6$MC=1003E-6 14 -221FR L 446.31 10(3/2,5/2,7/2)+ -221FR A 5391.2 140.0006 4 3800 -221FR G 446.31 100.0006 4 -221FR L 458.74 6 (3/2,5/2,7/2)+ -221FR A 5379.0 140.0020 5 980 -221FR G 205.07 110.0015 5 -221FR G 458.79 8 0.00053 13 -221FR L 481.98 10 + -221FR A 5356.2 1497000E-92 14960 -221FR G 443.43 100.0001 -221FR L 496.50 7 (5/2,7/2)+ -221FR A 5341.9 140.0027 8 450 -221FR G 388.07 7 0.00125 21 -221FR G 496.9 3 0.0015 7 -221FR L 517.634 25(5/2)+ -221FR A 5321.2 140.007 7 130 -221FR G 321.77 4 -221FR G 417.90 2 0.0056 5 -221FR G 480.85 110.0340 22 -221FR G 491.45 100.00035 14 -221FR G 517.51 3 0.0159 10 -221FR L 551.812 17(3/2,5/2)- -221FR A 5287.6 140.214 102.76 -221FR G 298.33 5 -221FR G 317.23 18 E1 0.0302 4 -221FR2 G KC=0.0244 4$LC=0.00437 7$MC=1037E-6 15 -221FR G 356.6 0.00026 11 -221FR G 405.95 3 0.0078 5[E1] 0.0175925 -221FR2 G KC=0.01432 20$LC=0.00249 4$MC=5.89E-4 9 -221FR G 443.43 100.0014 5[E2] 0.0494 7 -221FR2 G KC=0.0310 5$LC=0.0137 2$MC=0.00353 5 -221FR G 451.04 5 0.0030 5[M1] 0.215 3 -221FR2 G KC=0.1739 25$LC=0.0312 5$MC=0.00742 11 -221FR G 452.23 3 0.107 8[M1] 0.213 3 -221FR2 G KC=0.1727 25$LC=0.0310 5$MC=0.00737 11 -221FR G 512.5 7 0.00055 21 -221FR G 515.13 3 0.0214 13[M1] 0.1506 21 -221FR2 G KC=0.1219 17$LC=0.0218 3$MC=0.00518 8 -221FR G 525.94 170.0353 22[M1] 0.1425 20 -221FR2 G KC=0.1154 17$LC=0.0206 3$MC=0.00490 7 -221FR G 551.79 3 0.0052 14[M1] 0.1254 17 -221FR2 G KC=0.1016 15$LC=0.0181 3$MC=0.00431 6 -221FR L 570.67 3 (5/2,7/2)+ -221FR A 5269.1 140.048 1910 -221FR G 53.4 4 0.004 [M1] 17.6 5 -221FR2 G LC=13.3 4$MC=3.18 8 -221FR G 317.23 180.00042 21M1 0.558 8 -221FR2 G KC=0.451 7$LC=0.0816 12$MC=0.0194 3 -221FR G 374.98 5 0.0019 5[E1] 0.0209 3 -221FR2 G KC=0.01694 24$LC=0.00297 5$MC=7.04E-4 10 -221FR G 462.43 130.00044 11[E1] 0.0133819 -221FR2 G KC=0.01092 16$LC=0.00187 3$MC=4.42E-4 7 -221FR G 469.48 5 0.0028 4 -221FR G 532.11 9 0.00076 21[E1] 0.0100514 -221FR2 G KC=0.00823 12$LC=1389E-6 20$MC=3.27E-4 5 -221FR G 570.69 3 0.0040 5[E1] 0.0087412 -221FR2 G KC=0.00716 10$LC=1201E-6 17$MC=2.83E-4 4 -221FR L 600.94 3 (5/2)- -221FR A 5239.3 140.0026 5 119 -221FR G 564.34 110.00022 9 -221FR G 600.92 3 0.0024 5 -221FR L 630.551 23(5/2)- -221FR A 5210.2 140.022 1 9.5 -221FR G 282.10 200.00055 5[M1] 0.771 11 -221FR2 G KC=0.622 9$LC=0.1129 16$MC=0.0269 4 -221FR G 434.82 5 0.0029 3 -221FR G 522.14 4 0.00208 15 -221FR G 529.59 3 0.0076 7 -221FR G 530.87 4 0.0047 5 -221FR G 590.42 5 0.00083 14 -221FR G 593.87 4 0.0029 3 -221FR L 637.60 3 + -221FR A 5203.3 140.0101 1018.9 -221FR G 403.13 100.00019 16 -221FR G 538.1 1 0.0038 10 -221FR G 600.92 3 0.006 -221FR G 637.1 7 0.00012 -221FR L 645.94 12 + -221FR A 5195.1 140.00015 5 1140 -221FR G 645.94 120.00015 5 -221FR L 679.53 7 (7/2)- -221FR A 5162.1 140.00066 12165 -221FR G 679.36 6 0.00066 12 -221FR L 713.24 6 (1/2,3/2)+ -221FR A 5129.0 140.0058 8 11.9 -221FR G 442.16 8 0.0045 7 -221FR G 567.48 5 0.0012 4 -221FR L 748.83 3 (3/2)+ -221FR A 5094.1 140.015 7 2.8 -221FR G 231.16 7 0.005 3(M1) 1.338 19 -221FR2 G KC=1.079 16$LC=0.197 3$MC=0.0468 7 -221FR G 603.09 4 0.00173 21 -221FR G 649.03 4 0.0017 5 -221FR L 766.44 5 + -221FR A 5076.8 140.0038 199 -221FR G 657.88 5 0.0014 3 -221FR G 667.14 8 0.0021 18 -221FR G 767.9 3 0.00030 6 -221FR L 779.32 6 + -221FR A 5064.1 140.00114 1824 -221FR G 545.8 6 0.00053 14 -221FR G 628.95 100.00032 7 -221FR G 679.36 6 -221FR G 754.04 130.00023 7 -221FR G 780.6 6 0.00005514 -221FR L 808.48 10 + -221FR A 5035.5 140.0021 3 8.8 -221FR G 808.48 100.0021 3 -221FR L 818.6 6 + -221FR A 5025.5 140.00083 2119 -221FR G 498.6 6 0.00083 21 -221FR L 825.0 3 + -221FR A 5019.3 140.00015 5 98 -221FR G 674.9 3 0.00010 5 -221FR G 824.2 7 0.000049 -221FR L 852.08 7 + -221FR A 4992.7 140.0013 3 7.7 -221FR G 429.80 180.00038 19 -221FR G 656.18 110.00049 21 -221FR G 702.00 140.00016 7 -221FR G 752.46 120.00026 7 -221FR L 942.79 10(3/2)- -221FR A 4903.6 140.0011 4 2.5 -221FR G 747.0 1 0.0011 4 - +221FR 225AC A DECAY (10.0 D) +221FR H TYP=FUL$AUT=X.HUANG$CUT=31-DEC-2008$ +221FR T Auger electrons and X ray energies and emission intensities: +221FR T {U Energy (keV)} {U Intensity} {U Line} +221FR T +221FR T 83.23 1.00 8 XKA2 +221FR T 86.1 1.64 12 XKA1 +221FR T +221FR T 96.815 |] XKB3 +221FR T 97.474 |] 0.57 5 XKB1 +221FR T 98.069 |] XKB5II +221FR T +221FR T 100.16 |] XKB2 +221FR T 100.548 |] 0.19 2 XKB4 +221FR T 100.972 |] XKO23 +221FR T +221FR T 10.38-17.799 18.7 9 XL (total) +221FR T 10.38 XLL +221FR T 11.89-12.03 XLA +221FR T 13.254 XLC +221FR T 13.877-15.639 XLB +221FR T 16.752-17.799 XLG +221FR T +221FR T 63.576-70.787 |] KLL AUGER +221FR T 77.72-86.101 |] 0.115 9 KLX AUGER +221FR T 91.84-101.12 |] KXY AUGER +221FR T 5.73-18.52 23.8 12 L AUGER +225AC P 0.0 (3/2)- 10.0 D 1 5935.1 14 +221FR N 1.0 1.0 1 +221FR L 0 5/2- 4.79 M 2 +221FR A 5829.6 1452.4 248.7 +221FR L 25.856 17(1/2,3/2)- +221FR A 5804.2 140.3 1135 +221FR G 26.00 100.00159 21E2 5.94E3 15 +221FR2 G LC=4.39E3 11$MC=1180 30$NC=307 8 +221FR3 G OC=63.3 15 +221FR L 36.646 11(3/2)- 1.5 NS 2 +221FR A 5793.1 2118.9 2016 +221FR G 10.6 0.015 2M1 510 7 +221FR2 G MC=383 5$NC=0.1006 14 +221FR3 G OC=0.00225 3 +221FR G 36.69 3 0.0181 15E2 1092 16 +221FR2 G LC=806 12$MC=217 4$NC=56.6 9 +221FR3 G OC=11.68 17 +221FR L 38.546 12(9/2)- +221FR A 5791.7 146.2 948 +221FR G 38.58 4 0.0107 10E2 854 13 +221FR2 G LC=630 10$MC=169 3$NC=44.3 7 +221FR3 G OC=9.14 14 +221FR L 99.596 13(3/2)- 80 PS 30 +221FR A 5731.9 179.0 516.4 +221FR G 62.94 3 0.49 3M1 10.85 15 +221FR2 G LC=8.24 12$MC=1.964 28$NC=0.000515 7 +221FR3 G OC=1.15E-5 2 +221FR G 73.55 9 0.019 5E2 37.5 6 +221FR2 G LC=27.6 4$MC=7.48 11$NC=0.00196 3 +221FR3 G OC=4.05E-5 6 +221FR G 99.67 5 0.76 5M1+E2 0.19 4 3.06 11 +221FR2 G LC=2.32 8$MC=0.56 2$NC=0.000147 6 +221FR3 G OC=3.25E-6 11 +221FR L 99.752 16(3/2)+ 160 PS 30 +221FR A 5731.6 141.24 10119 +221FR G 63.5 3 0.021 3[E1] 0.360 7 +221FR2 G LC=0.273 5$MC=0.0660 12$NC=1.70E-5 3 +221FR3 G OC=3.60E-7 7 +221FR G 73.85 3 0.309 23E1 0.240 3 +221FR2 G LC=0.182 3$MC=0.0440 6$NC=1.13E-5 2 +221FR3 G OC=2.40E-7 3 +221FR G 99.89 6 1.08 8E1 0.1073 15 +221FR2 G LC=0.0814 11$MC=0.0196 3$NC=5.05E-6 7 +221FR3 G OC=1.080E-7 15 +221FR L 100.897 11(5/2)- +221FR A 5730.5 141.6 391 +221FR G 62.6 3 0.0053 12[E2] 81.2 23 +221FR2 G LC=59.8 16$MC=16.2 5$NC=0.00423 11 +221FR3 G OC=8.75E-5 24 +221FR G 64.27 3 0.047 4M1+E2 0.51 10 23 4 +221FR2 G LC=17 3$MC=4.4 8$NC=0.00115 21 +221FR3 G OC=0.000025 4 +221FR G 74.82 5 0.015 3(M1+E2) 0.5 12.15 18 +221FR2 G LC=9.06 13$MC=2.32 4$NC=0.609 9 +221FR3 G OC=0.1302 19 +221FR G 100.86 4 0.096 8M1+E2 0.7 7 4.6 19 +221FR2 G LC=3.4 14$MC=0.9 4$NC=0.00023 10 +221FR3 G OC=0.000005 2 +221FR L 108.404 11(7/2)- 280 PS +221FR A 5723.1 142.03 2366 +221FR G 69.86 5 0.0047 12E2 47.9 7 +221FR2 G LC=35.3 5$MC=9.55 14$NC=2.50 4 +221FR3 G OC=0.517 8 +221FR G 71.71 4 0.0132 13E2 42.3 6 +221FR2 G LC=31.1 5$MC=8.43 12$NC=2.21 4 +221FR3 G OC=0.457 7 +221FR G 108.38 3 0.255 16M1+E2 0.53 6 10.27 25 +221FR2 G KC=7.2 4$LC=2.30 12$MC=0.58 4$NC=0.152 9 +221FR3 G OC=0.0328 17 +221FR L 145.755 20(1/2)+ +221FR A 5686.4 140.021 144100 +221FR G 46.24 5 0.0049 7[E1] 0.841 12 +221FR2 G LC=0.636 9$MC=0.155 2$NC=3.98E-5 6 +221FR3 G OC=8.19E-7 11 +221FR G 119.85 3 0.080 5[E1] 0.305 4 +221FR2 G KC=0.239 4$LC=0.0503 7$MC=0.01207 17$NC=0.00312 4 +221FR3 G OC=0.000669 9 +221FR L 150.063 13(7/2)+ 80 PS 20 +221FR A 5682.2 141.31 462.9 +221FR G 49.12 4 0.0080 8[E1] 0.715 11 +221FR2 G LC=0.541 8$MC=0.1320 19$NC=0.0338 5 +221FR3 G OC=0.00698 10 +221FR G 50.2 0.00062 [E2] 236.0 34 +221FR2 G LC=174.2 25$MC=47.0 7$NC=0.0151 2 +221FR G 111.52 3 0.313 21(E1) 0.363 5 +221FR2 G KC=0.282 4$LC=0.0609 9$MC=0.01461 21$NC=0.00378 6 +221FR3 G OC=0.000807 12 +221FR G 150.05 3 0.693 12E1 0.1766 25 +221FR2 G KC=0.1397 20$LC=0.0280 4$MC=0.0067 1$NC=0.00174 2 +221FR3 G OC=0.000374 5 +221FR L 195.789 11(5/2,7/2)- 20 PS 5 +221FR A 5637.3 144.16 2311.6 +221FR G 87.41 3 0.271 19M1 4.16 6 +221FR2 G LC=3.16 5$MC=0.754 10$NC=0.000198 3 +221FR3 G OC=4.4E-6 1 +221FR G 94.90 2 0.105 10M1 3.28 5 +221FR2 G LC=2.49 3$MC=0.594 8$NC=0.000156 2 +221FR3 G OC=3.48E-6 5 +221FR G 96.16 5 0.033 7M1+E2 0.8 3 6.0 14 +221FR2 G LC=4.5 10$MC=1.2 3$NC=0.00031 8 +221FR3 G OC=6.5E-6 15 +221FR G 157.250 300.36 3M1+E2 0.21 21 3.8 3 +221FR2 G KC=3.1 4$LC=0.59 3$MC=0.143 9$NC=3.74E-5 23 +221FR3 G OC=0.000832 4 +221FR G 169.9 0.0139 14 +221FR G 195.74 3 0.148 9M1+E2 0.8 8 1.5 6 +221FR2 G KC=1.1 6$LC=0.314 5$MC=0.079 4$NC=0.000021 11 +221FR3 G OC=0.000448 12 +221FR L 224.567 13(3/2,5/2)+ 35 PS 10 +221FR A 5609.0 141.09 531.5 +221FR G 78.8 0.0123 19M1 5.63 8 +221FR2 G LC=4.27 6$MC=1.019 14$NC=0.000267 4 +221FR3 G OC=6.00E-6 8 +221FR G 123.75 4 0.087 6[E1] 0.282 4 +221FR2 G KC=0.221 4$LC=0.0463 7$MC=0.0111 2$NC=0.00287 4 +221FR3 G OC=0.000616 9 +221FR G 124.81 3 0.0292 18M1+E2 0.8 6.01 +221FR2 G KC=3.87 $LC=1.593 $MC=0.409 $NC=0.000107 +221FR3 G OC=2.3E-6 +221FR G 186.1 0.0127 14 +221FR G 187.96 3 0.53 3E1 0.1023 14 +221FR2 G KC=0.0816 12$LC=0.01571 22$MC=0.00375 6$NC=0.00972 1 +221FR3 G OC=0.000211 3 +221FR G 198.47 230.0188 13[E1] 0.0898 13 +221FR2 G KC=0.0718 11$LC=0.01369 20$MC=0.00327 5$NC=0.000847 13 +221FR3 G OC=0.000184 3 +221FR G 224.59 3 0.112 8[E1] 0.0669 9 +221FR2 G KC=0.0537 8$LC=0.01005 14$MC=0.00239 4$NC=0.00622 9 +221FR3 G OC=0.000135 2 +221FR L 234.470 18(5/2)+ +221FR A 5599.3 140.114 7268 +221FR G 126.10 5 0.0079 7(E1) 0.270 4 +221FR2 G KC=0.212 3$LC=0.0440 7$MC=0.0106 2$NC=0.00273 4 +221FR3 G OC=0.000586 8 +221FR G 133.60 3 0.0196 16(E1) 0.234 3 +221FR2 G KC=0.184 3$LC=0.0379 6$MC=0.00907 13$NC=0.00235 3 +221FR3 G OC=0.000505 7 +221FR G 134.850 300.032 3(E1) 0.229 3 +221FR2 G KC=0.180 3$LC=0.0370 6$MC=0.00885 13$NC=0.00229 3 +221FR3 G OC=0.000493 7 +221FR G 197.70 100.038 5[E1] 0.0906 13 +221FR2 G KC=0.0724 11$LC=0.01382 20$MC=0.00330 5$NC=0.00856 12 +221FR3 G OC=0.000186 3 +221FR L 253.551 12(5/2)+ 35 PS 15 +221FR A 5580.5 140.95 425.6 +221FR G 57.71 4 0.0051 8(E1) 0.465 7 +221FR2 G LC=0.352 5$MC=0.0854 12$NC=0.0219 3 +221FR3 G OC=0.00457 7 +221FR G 103.48 100.0030 7[M1,E2] 10 3 +221FR2 G KC=5 2$LC=3.7 18$MC=1.0 5$NC=0.00026 14 +221FR3 G OC=0.000005 3 +221FR G 145.15 3 0.146 9(E1) 0.191 3 +221FR2 G KC=0.1513 22$LC=0.0305 5$MC=0.00730 11$NC=0.00189 3 +221FR3 G OC=0.000407 6 +221FR G 152.64 3 0.0197 13[E1] 0.1694 24 +221FR2 G KC=0.1341 19$LC=0.0268 4$MC=0.00640 9$NC=0.001659 23 +221FR3 G OC=0.000358 5 +221FR G 153.920 300.205 13E1 0.1660 23 +221FR2 G KC=0.1315 19$LC=0.0262 4$MC=0.00627 9$NC=0.00162 2 +221FR3 G OC=0.000350 1 +221FR G 216.89 3 0.32 2(E1) 0.0726 10 +221FR2 G KC=0.0582 9$LC=0.01096 16$MC=0.00261 4$NC=0.00678 10 +221FR3 G OC=0.000148 2 +221FR G 228.2 4 0.0046 12 +221FR G 253.46 3 0.132 8[E1] 0.0504 7 +221FR2 G KC=0.0405 6$LC=0.00747 11$MC=0.001776 25$NC=0.00462 6 +221FR3 G OC=0.000101 2 +221FR L 271.14 7 (5/2,7/2,9/2)- +221FR A 5563.3 140.017 71160 +221FR G 121.06 7 0.017 5(E1) 0.298 4 +221FR2 G KC=0.233 4$LC=0.0490 7$MC=0.01176 17$NC=0.00304 4 +221FR3 G OC=0.000652 9 +221FR G 236.0 6 0.0017 3 +221FR L 279.209 17(7/2)+ +221FR A 5555.3 140.084 10213 +221FR G 129.22 7 0.0027 5[M1,E2] 5 2 +221FR2 G KC=3 3$LC=1.5 5$MC=0.39 15$NC=0.10 4 +221FR3 G OC=0.022 8 +221FR G 170.77 5 0.013 7(E1) 0.1290 18 +221FR2 G KC=0.1026 15$LC=0.0201 3$MC=0.00479 7$NC=0.00124 2 +221FR3 G OC=0.000269 4 +221FR G 178.29 3 0.0161 12E1 0.1162 16 +221FR2 G KC=0.0925 13$LC=0.0180 3$MC=0.00429 6$NC=0.00111 2 +221FR3 G OC=0.000241 3 +221FR G 240.68 3 0.0117 10[E1] 0.0568 8 +221FR2 G KC=0.0457 7$LC=0.00847 12$MC=0.00202 3$NC=0.00524 7 +221FR3 G OC=0.000114 2 +221FR G 279.18 3 0.0305 22E1 0.0403 6 +221FR2 G KC=0.0325 5$LC=0.00591 9$MC=0.001405 20$NC=0.00365 5 +221FR3 G OC=0.000799 11 +221FR L 288.16 3 (9/2)- +221FR A 5546.5 140.055 12292 +221FR G 179.78 4 0.0108 8(M1,E2) 1.8 10 +221FR2 G KC=1.2 10$LC=0.43 3$MC=0.109 14$NC=0.000029 4 +221FR3 G OC=0.000613 6 +221FR G 187.2 0.0103 7 +221FR G 249.60 3 0.0135 10(E2) 0.258 4 +221FR2 G KC=0.1033 15$LC=0.1145 16$MC=0.0305 5$NC=8.0E-6 1 +221FR3 G OC=0.000168 2 +221FR L 294.69 4 (9/2)+ +221FR A 5540.1 140.0072 82060 +221FR G 144.70 200.00046 12(M1+E2) 0.8 3.79 +221FR2 G KC=2.57 $LC=0.914 $MC=0.232 $NC=0.000061 +221FR3 G OC=1.31E-6 +221FR G 186.29 3 0.0042 5E1 0.1045 15 +221FR2 G KC=0.0834 12$LC=0.01607 23$MC=0.00383 6$NC=0.00995 2 +221FR3 G OC=0.000216 3 +221FR G 256.0 2 0.00037 7[E1] 0.0492 7 +221FR2 G KC=0.0396 6$LC=0.00729 11$MC=0.001733 25$NC=0.00451 6 +221FR3 G OC=0.000984 14 +221FR L 311.41 8 (5/2,7/2,9/2)+ +221FR A 5523.7 140.013 6930 +221FR G 161.35 7 0.0036 9[M1,E2] 2.5 13 +221FR2 G KC=1.6 14$LC=0.64 10$MC=0.16 4$NC=4.28E-5 10 +221FR3 G OC=0.00092 16 +221FR L 320.03 8 (1/2,3/2,5/2)+ +221FR A 5515.2 140.0052 192100 +221FR G 220.43 8 0.0060 18 +221FR L 338.24 8 (1/2,3/2,5/2)- +221FR A 5497.4 140.0022 74000 +221FR G 238.64 8 0.0010 3(M1) 1.225 17 +221FR2 G KC=0.988 14$LC=0.180 3$MC=0.0428 6$NC=1.12E-5 2 +221FR3 G OC=0.000251 4 +221FR L 348.35 4 (3/2,5/2,7/2)+ +221FR A 5487.4 140.0020 33860 +221FR G 348.33 5 0.0030 3 +221FR L 367.74 12 +221FR A 5468.4 140.00052 1811700 +221FR G 367.74 120.00052 18 +221FR L 393.300 18(5/2,7/2,9/2)+ +221FR A 5443.3 140.098 1945 +221FR G 114 0.00087 13M1 9.86 14 +221FR2 G KC=7.93 12$LC=1.466 21$MC=0.350 5$NC=9.17E-5 13 +221FR3 G OC=2.05E-6 3 +221FR G 139.6 0.00139 21M1+E2 3.9 17 +221FR2 G KC=2.4 21$LC=1.1 3$MC=0.29 9$NC=0.000075 24 +221FR3 G OC=1.6E-6 5 +221FR G 169.18 4 0.012 5[M1,E2] 2.1 11 +221FR2 G KC=1.4 12$LC=0.53 6$MC=0.136 24$NC=0.000036 6 +221FR3 G OC=7.7E-7 10 +221FR G 197.50 3 0.026 3E1 0.0908 13 +221FR2 G KC=0.0726 11$LC=0.01386 20$MC=0.00331 5$NC=0.00858 12 +221FR3 G OC=0.000186 3 +221FR G 243.12 5 0.0031 4[M1] 1.163 16 +221FR2 G KC=0.938 14$LC=0.1707 24$MC=0.0407 6$NC=1.07E-5 2 +221FR3 G OC=0.000238 3 +221FR G 284.75 3 0.0074 6[E1] 0.0385 5 +221FR2 G KC=0.0311 5$LC=0.00564 8$MC=0.001340 19$NC=0.00348 5 +221FR3 G OC=0.000762 11 +221FR G 354.56 6 0.0020 7[E1] 0.0236 3 +221FR2 G KC=0.0191 3$LC=0.00338 5$MC=0.000800 12$NC=0.00208 3 +221FR3 G OC=0.000457 6 +221FR L 400.94 4 (11/2)+ +221FR A 5435.8 140.0083 6485 +221FR G 112.80 2 0.0021 3[E1] 0.353 5 +221FR2 G KC=0.275 4$LC=0.0591 9$MC=0.01417 21$NC=0.00366 5 +221FR3 G OC=0.000784 11 +221FR G 362.380 300.0054 5(E1) 0.0225 3 +221FR2 G KC=0.0182 3$LC=0.00321 6$MC=7.610E-4 11$NC=0.00198 3 +221FR3 G OC=0.000435 6 +221FR L 406.73 6 (3/2,5/2,7/2)- +221FR A 5430.1 140.0028 81340 +221FR G 298.33 5 0.0020 3(M1,E2) 0.4 3 +221FR2 G KC=0.30 24$LC=0.077 20$MC=0.019 4$NC=0.000005 1 +221FR3 G OC=1.1E-7 3 +221FR L 408.54 13 +221FR A 5428.3 140.0023 31590 +221FR G 137.4 1 0.0023 3 +221FR L 422.65 4 (3/2,5/2,7/2)+ +221FR A 5414.5 140.0030 41020 +221FR G 321.77 4 0.0033 4[E1] 0.0292 4 +221FR2 G KC=0.0237 4$LC=0.00423 6$MC=0.001003 14$NC=0.00261 4 +221FR3 G OC=0.000572 8 +221FR L 446.31 10(3/2,5/2,7/2)+ +221FR A 5391.2 140.0006 43800 +221FR G 446.31 100.0006 4 +221FR L 458.74 6 (3/2,5/2,7/2)+ +221FR A 5379.0 140.0020 5980 +221FR G 205.07 110.0015 5 +221FR G 458.79 8 0.00053 13 +221FR L 481.98 10 +221FR A 5356.2 140.000097 214960 +221FR G 443.43 100.0001 +221FR L 496.50 7 (5/2,7/2)+ +221FR A 5341.9 140.0027 8450 +221FR G 388.07 7 0.00125 21 +221FR G 496.9 3 0.0015 7 +221FR L 517.634 25(5/2)+ +221FR A 5321.2 140.007 7130 +221FR G 321.77 4 +221FR G 417.90 2 0.0056 5 +221FR G 480.85 110.0340 22 +221FR G 491.45 100.00035 14 +221FR G 517.51 3 0.0159 10 +221FR L 551.812 17(3/2,5/2)- +221FR A 5287.6 140.214 102.76 +221FR G 298.33 5 +221FR G 317.23 18 E1 0.0302 4 +221FR2 G KC=0.0244 4$LC=0.00437 7$MC=0.001037 15$NC=0.00270 4 +221FR3 G OC=0.000591 8 +221FR G 356.6 0.00026 11 +221FR G 405.95 3 0.0078 5[E1] 0.0175925 +221FR2 G KC=0.01432 20$LC=0.00249 4$MC=0.000589 9$NC=1.533E-4 22 +221FR3 G OC=3.37E-5 5 +221FR G 443.43 100.0014 5[E2] 0.0494 7 +221FR2 G KC=0.0310 5$LC=0.0137 2$MC=0.00353 5$NC=0.00926 13 +221FR3 G OC=0.000198 3 +221FR G 451.04 5 0.0030 5[M1] 0.215 3 +221FR2 G KC=0.1739 25$LC=0.0312 5$MC=0.00742 11$NC=0.00195 3 +221FR3 G OC=0.000435 6 +221FR G 452.23 3 0.107 8[M1] 0.213 3 +221FR2 G KC=0.1727 25$LC=0.0310 5$MC=0.00737 11$NC=0.00193 3 +221FR3 G OC=0.000432 6 +221FR G 512.5 7 0.00055 21 +221FR G 515.13 3 0.0214 13[M1] 0.1506 21 +221FR2 G KC=0.1219 17$LC=0.0218 3$MC=0.00518 8$NC=0.001358 19 +221FR3 G OC=0.000304 5 +221FR G 525.94 170.0353 22[M1] 0.1425 20 +221FR2 G KC=0.1154 17$LC=0.0206 3$MC=0.00490 7$NC=0.00128 2 +221FR3 G OC=0.000287 4 +221FR G 551.79 3 0.0052 14[M1] 0.1254 17 +221FR2 G KC=0.1016 15$LC=0.0181 3$MC=0.00431 6$NC=0.00113 2 +221FR3 G OC=0.000252 4 +221FR L 570.67 3 (5/2,7/2)+ +221FR A 5269.1 140.048 1910 +221FR G 53.4 4 0.004 [M1] 17.6 5 +221FR2 G LC=13.3 4$MC=3.18 8$NC=0.000083 2 +221FR3 G OC=1.86E-5 5 +221FR G 317.23 180.00042 21M1 0.558 8 +221FR2 G KC=0.451 7$LC=0.0816 12$MC=0.0194 3$NC=0.00509 7 +221FR3 G OC=0.000114 2 +221FR G 374.98 5 0.0019 5[E1] 0.0209 3 +221FR2 G KC=0.01694 24$LC=0.00297 5$MC=0.000704 10$NC=0.00183 3 +221FR3 G OC=0.000403 6 +221FR G 462.43 130.00044 11[E1] 0.0133819 +221FR2 G KC=0.01092 16$LC=0.00187 3$MC=0.000442 7$NC=0.00115 2 +221FR3 G OC=0.000254 4 +221FR G 469.48 5 0.0028 4 +221FR G 532.11 9 0.00076 21[E1] 0.0100514 +221FR2 G KC=0.00823 12$LC=0.001389 20$MC=0.000327 5$NC=0.00853 12 +221FR3 G OC=0.000189 3 +221FR G 570.69 3 0.0040 5[E1] 0.0087412 +221FR2 G KC=0.00716 10$LC=0.001201 17$MC=0.000283 4$NC=0.00737 10 +221FR3 G OC=0.000163 2 +221FR L 600.94 3 (5/2)- +221FR A 5239.3 140.0026 5119 +221FR G 564.34 110.00022 9 +221FR G 600.92 3 0.0024 5 +221FR L 630.551 23(5/2)- +221FR A 5210.2 140.022 19.5 +221FR G 282.10 200.00055 5[M1] 0.771 11 +221FR2 G KC=0.622 9$LC=0.1129 16$MC=0.0269 4$NC=0.00705 10 +221FR3 G OC=0.000158 2 +221FR G 434.82 5 0.0029 3 +221FR G 522.14 4 0.00208 15 +221FR G 529.59 3 0.0076 7 +221FR G 530.87 4 0.0047 5 +221FR G 590.42 5 0.00083 14 +221FR G 593.87 4 0.0029 3 +221FR L 637.60 3 +221FR A 5203.3 140.0101 1018.9 +221FR G 403.13 100.00019 16 +221FR G 538.1 1 0.0038 10 +221FR G 600.92 3 0.006 +221FR G 637.1 7 0.00012 +221FR L 645.94 12 +221FR A 5195.1 140.00015 51140 +221FR G 645.94 120.00015 5 +221FR L 679.53 7 (7/2)- +221FR A 5162.1 140.00066 12165 +221FR G 679.36 6 0.00066 12 +221FR L 713.24 6 (1/2,3/2)+ +221FR A 5129.0 140.0058 811.9 +221FR G 442.16 8 0.0045 7 +221FR G 567.48 5 0.0012 4 +221FR L 748.83 3 (3/2)+ +221FR A 5094.1 140.015 72.8 +221FR G 231.16 7 0.005 3(M1) 1.338 19 +221FR2 G KC=1.079 16$LC=0.197 3$MC=0.0468 7$NC=0.00123 17 +221FR3 G OC=0.000274 4 +221FR G 603.09 4 0.00173 21 +221FR G 649.03 4 0.0017 5 +221FR L 766.44 5 +221FR A 5076.8 140.0038 199 +221FR G 657.88 5 0.0014 3 +221FR G 667.14 8 0.0021 18 +221FR G 767.9 3 0.00030 6 +221FR L 779.32 6 +221FR A 5064.1 140.00114 1824 +221FR G 545.8 6 0.00053 14 +221FR G 628.95 100.00032 7 +221FR G 679.36 6 +221FR G 754.04 130.00023 7 +221FR G 780.6 6 0.00005514 +221FR L 808.48 10 +221FR A 5035.5 140.0021 38.8 +221FR G 808.48 100.0021 3 +221FR L 818.6 6 +221FR A 5025.5 140.00083 2119 +221FR G 498.6 6 0.00083 21 +221FR L 825.0 3 +221FR A 5019.3 140.00015 598 +221FR G 674.9 3 0.00010 5 +221FR G 824.2 7 0.000049 +221FR L 852.08 7 +221FR A 4992.7 140.0013 37.7 +221FR G 429.80 180.00038 19 +221FR G 656.18 110.00049 21 +221FR G 702.00 140.00016 7 +221FR G 752.46 120.00026 7 +221FR L 942.79 10(3/2)- +221FR A 4903.6 140.0011 42.5 +221FR G 747.0 1 0.0011 4 + diff --git a/HEN_HOUSE/spectra/lnhb/Ac-227.txt b/HEN_HOUSE/spectra/lnhb/Ac-227.txt index 8613c2ce5..3349cef63 100644 --- a/HEN_HOUSE/spectra/lnhb/Ac-227.txt +++ b/HEN_HOUSE/spectra/lnhb/Ac-227.txt @@ -1,259 +1,258 @@ -223FR 227AC A DECAY (21.772 Y) -223FR H TYP=Full$AUT=Chechev. Kuzmenkho$CUT=30-JUN-2008$ -223FR C Evaluation history: Type=Full;Author=Chechev. Kuzmenkho;Cutoff date=30-JUN-2008 -223FR C References: 1950Ho79, 1955To07, 1956Sh43, 1959No41, 1959Ro51, 1963Ei10, -223FR2C 1966Ba19, 1967JoZX, 1970Ki12, 1974Mo05, 1986Ry04, 1991Ry01, 1995Sh03, -223FR3C 1995Li04, 1997Mu08, 2001Br31, 2002Ba85, 2003Au03 -223FR T Auger electrons and X ray energies and emission intensities: -223FR T {U Energy (keV)} {U Intensity} {U Line} -223FR T -223FR T 83.23 0.0043 12 XKA2 -223FR T 86.1 0.0070 19 XKA1 -223FR T -223FR T 96.815 |] XKB3 -223FR T 97.474 |] 0.0024 7 XKB1 -223FR T 98.069 |] XKB5II -223FR T -223FR T 100.16 |] XKB2 -223FR T 100.548 |] 0.00079 22 XKB4 -223FR T 100.972 |] XKO23 -223FR T -223FR T 10.381-17.839 0.074 8 XL (total) -223FR T 10.381 0.00097 18 XLL -223FR T 11.896-12.032 0.017 3 XLA -223FR T 13.255 0.0006 1 XLC -223FR T 13.877-14.978 0.044 5 XLB -223FR T 17.302-17.839 0.012 1 XLG -223FR T -223FR T 63.576-70.787 |] KLL AUGER -223FR T 77.72-86.101 |] 0.00050 15 KLX AUGER -223FR T 91.84-101.12 |] KXY AUGER -223FR T 5.73-18.52 0.097 10 L AUGER -227AC P 0.0 3/2- 21.772 Y 3 5042.19 14 -223FR N 7.246E1 7.246E1 0.01380 4 7.246E1 -223FR G 219.2 4 1.40E-5 4 -223FR L 0 3/2- 22.00 M 7 -223FR A 4953.23 1447.7 107 -223FR L 12.89 5 (5/2)- -223FR A 4940.57 1539.6 127 -223FR G 12.9 1 0.000014 (E2) 4.99E4 10 -223FR2 G MC=3.77E4 8 -223FR L 54.97 7 1/2- -223FR A 4899.23 1510870E-5 1360 -223FR G 55.0 1 0.00044 8M1+E2 0.05 4 16.4 8 -223FR2 G LC=12.5 6$MC=2.98 16 -223FR L 82.13 6 (7/2)- -223FR A 4872.55 156.3 5 16 -223FR G 69.28 8 0.0039 6M1+E2 0.57 18.4 19 -223FR2 G LC=13.7 14$MC=3.6 4 -223FR G 82.2 1 0.00083 10E2 22.1 5 -223FR2 G LC=16.25 30$MC=4.40 9 -223FR L 99.63 6 (3/2)- -223FR A 4855.36 155.8 7 13 -223FR G 44.7 1 0.00011 3[M1+E2] 1 2.2E2 20 -223FR2 G LC=1.6E2 15$MC=44 40 -223FR G 86.7 2 0.0028 4[M1+E2] 1 11 7 -223FR2 G LC=8 5$MC=2.1 14 -223FR G 99.6 1 0.0051 7M1+E2 1 6 3 -223FR2 G LC=4.4 22$MC=1.2 7 -223FR L 101.00 6 (5/2)- -223FR A 4854.01 150 -223FR G 88.1 1 0.00069 10[M1+E2] 1 10 6 -223FR2 G LC=8 5$MC=2.0 13 -223FR G 101.0 1 0.00069 30[M1+E2] 1 6 3 -223FR2 G LC=4.1 21$MC=1.1 6 -223FR L 134.51 6 (3/2)+ -223FR A 4821.09 1572464E-6 663 -223FR G 33.5 1 0.00011 3[E1] 1.99 4 -223FR2 G LC=1.50 3$MC=0.371 8 -223FR G 35.0 2 0.00002810[E1] 1.77 4 -223FR2 G LC=1.34 3$MC=0.330 7 -223FR G 79.54 8 0.0011 1E1 0.197 4 -223FR2 G LC=0.149 3$MC=0.0360 7 -223FR G 121.6 1 0.0012 3[E1] 0.295 6 -223FR2 G KC=0.231 5$LC=0.0485 10$MC=0.0116 3 -223FR G 134.5 1 0.00055 10E1 0.230 5 -223FR2 G KC=0.182 4$LC=0.0372 8$MC=0.00891 18 -223FR L 149.3 3 (1/2)+ -223FR G 149.3 3 0.000014 -223FR L 160.48 7 (3/2)+ -223FR A 4795.58 151.0 5 31 -223FR G 25.95 5.5E-7 -223FR G 59.4 2 0.00004110[E1] 0.430 9 -223FR2 G LC=0.326 7$MC=0.0790 16 -223FR G 60.6 3 0.00004110[E1] 0.408 9 -223FR2 G LC=0.309 6$MC=0.0749 15 -223FR G 147.61 8 0.0025 3E1 0.184 4 -223FR2 G KC=0.145 3$LC=0.0292 6$MC=0.00699 14 -223FR G 160.49 100.0044 4E1 0.150 3 -223FR2 G KC=0.119 3$LC=0.0235 5$MC=0.00562 11 -223FR L 172.08 6 (5/2)+ -223FR A 4784.19 1579710E-6 329 -223FR G 72.5 2 0.00006930[E1] 0.252 5 -223FR2 G LC=0.191 4$MC=0.0462 10 -223FR G 90.0 1 0.00018 7[E1] 0.142 3 -223FR2 G LC=0.107 2$MC=0.0259 5 -223FR G 159.2 1 0.00055 10[E1] 0.153 3 -223FR2 G KC=0.121 3$LC=0.0240 5$MC=0.00574 11 -223FR G 172.0 1 0.00097 10E1 0.127 3 -223FR2 G KC=0.101 2$LC=0.0197 4$MC=0.0047 1 -223FR L 187.18 10(5/2)- -223FR A 4769.35 171.8 5 11 -223FR G 52.32 1.4E-6 -223FR G 86.1 1 0.00047 -223FR G 105.0 2 0.00034 10M1 12.4 25 -223FR2 G KC=9.96 20$LC=1.86 4$MC=0.443 9 -223FR G 174.3 1 0.00028 6[M1+E2] 1 1.9 11 -223FR2 G KC=1.3 11$LC=0.48 4$MC=0.122 17 -223FR L 189.10 7 (7/2)- -223FR A 4767.47 150 -223FR G 88.1 1 0.00069 10[M1+E2] 1 10 6 -223FR2 G LC=8 5$MC=2.0 13 -223FR G 106.85 100.0011 1(+E2) 1 9 3 -223FR2 G KC=5 2$LC=3.2 15$MC=0.8 4 -223FR G 176.1 1 0.00033 6M1E2 1 1.9 11 -223FR2 G KC=1.3 11$LC=0.46 4$MC=0.117 17 -223FR L 219.61 9 (7/2)+ -223FR A 4737.50 1686957E-6 142 -223FR G 85.0 5 0.000011 -223FR G 118.7 4 0.00004110[E1] 0.312 6 -223FR2 G KC=0.244 5$LC=0.0516 11$MC=0.0124 3 -223FR G 137.4 1 0.00041 10[E1] 0.220 5 -223FR2 G KC=0.172 4$LC=0.0352 7$MC=0.00843 17 -223FR G 206.8 1 0.00097 10E1 0.0814 17 -223FR2 G KC=0.0651 13$LC=0.0124 3$MC=0.00294 6 -223FR L 222.75 10(7/2)+ -223FR A 4734.41 170 -223FR G 51.06 2.8E-7 -223FR G 88.5 6 9.7E-7 -223FR G 140.9 1 0.00021 6[E1] 0.206 4 -223FR2 G KC=0.162 4$LC=0.0330 7$MC=0.00789 16 -223FR L 242.63 7 (5/2)+ -223FR A 4714.88 150.43 2223 -223FR G 53.7 2 0.00004110[E1] 0.563 11 -223FR2 G LC=0.427 9$MC=0.104 2 -223FR G 70.6 2 0.00008330[M1+E2] 1 27 19 -223FR2 G LC=20 14$MC=5 4 -223FR G 108.0 3 0.00004110[M1+E2] 1 9 3 -223FR2 G KC=5 2$LC=3.1 15$MC=0.8 4 -223FR G 143.0 1 0.00028 6[E1] 0.198 4 -223FR2 G KC=0.157 3$LC=0.0317 7$MC=0.00759 15 -223FR G 229.7 1 0.00041 7[E1] 0.0634 13 -223FR2 G KC=0.0509 11$LC=0.00951 19$MC=0.00226 5 -223FR G 242.6 2 0.00028 7[E1] 0.0558 12 -223FR2 G KC=0.0448 9$LC=0.00831 17$MC=0.00198 4 -223FR L 243.85 13(5/2)+ -223FR A 4713.68 190 -223FR G 83.0 1 1.4E-6 -223FR G 161.4 4 0.00014 4[M1+E2] 1 2.5 13 -223FR2 G KC=1.6 15$LC=0.64 9$MC=0.16 4 -223FR G 230.9 5 0.000014 [M1+E2] 1 0.8 5 -223FR2 G KC=0.6 5$LC=0.177 24$MC=0.045 4 -223FR G 243.9 4 2.80E-5 8[E2] 0.279 6 -223FR2 G KC=0.108 2$LC=0.126 3$MC=0.0335 7 -223FR L 244.66 15(7/2)- -223FR A 4712.89 200 -223FR G 55.80 5 3.9E-6 -223FR G 57.56 5 3.2E-6 -223FR G 72.5 2 0.00006930[E1] 0.252 5 -223FR2 G LC=0.191 4$MC=0.0462 10 -223FR G 143.65 5 0.000026 M1 5.11 11 -223FR2 G KC=4.12 8$LC=0.755 15$MC=0.180 4 -223FR G 162.6 2 0.00005530M1E2 1 2.4 13 -223FR2 G KC=1.6 15$LC=0.62 9$MC=0.16 4 -223FR G 231.79 5 7.2E-6 -223FR L 298.7 3 (9/2)- -223FR G 216.6 3 0.00005530[M1+E2] 1 1.0 7 -223FR2 G KC=0.7 6$LC=0.221 20$MC=0.0556 18 -223FR L 365.47 10 + -223FR A 4594.21 1721739E-6 65 -223FR G 121.6 1 0.0012 3[E1] 0.295 6 -223FR2 G KC=0.231 5$LC=0.0485 10$MC=0.0116 3 -223FR G 143.0 1 0.00028 6[M1+E2] 1 3.6 18 -223FR2 G KC=2.2 11$LC=1.0 5$MC=0.26 13 -223FR G 146.0 2 8.8E-6 -223FR G 176.1 1 0.00033 4[E1] 0.120 3 -223FR2 G KC=0.095 2$LC=0.0185 4$MC=0.00443 9 -223FR G 283.4 3 0.00005530[E1] 0.0389 8 -223FR2 G KC=0.0314 7$LC=0.00570 12$MC=0.00136 3 -223FR L 379 7 + -223FR A 4581 7 28986E-7 340 -223FR L 449 5 + -223FR A 4512 5 28986E-7 108 -223FR L 503 7 + -223FR A 4459 7 50725E-7 26 -223FR L 515.20 223/2- -223FR A 4447.12 2650725E-6 2.1 -223FR G 415.6 3 0.00021 6 1 0.16 11 -223FR2 G KC=0.13 10$LC=0.028 12$MC=0.007 3 -223FR G 460.2 3 0.00021 6M1+E2 1 0.12 9 -223FR2 G KC=0.10 8$LC=0.021 10$MC=0.0051 22 -223FR L 540.74 25(5/2)+ -223FR A 4422.03 2857971E-7 12 -223FR G 351.7 3 0.00005530[E1] 0.0240 5 -223FR2 G KC=0.0195 4$LC=0.00344 7$MC=8.15E-4 17 -223FR G 439.60 5 0.000034 1 -223FR G 441.0 4 0.00005530[E1] 0.0148 3 -223FR2 G KC=0.0120 3$LC=0.00207 4$MC=0.00049 1 -223FR G 527.6 1 0.000029 -223FR G 540.40 5 0.00007 -223FR L 601 7 (5/2)- -223FR A 4362.83 1528986E-7 8 - -227TH 227AC B- DECAY (21.772 Y) -227TH H TYP=Full$AUT=Chechev. Kuzmenkho$CUT=30-JUN-2008$ -227TH C Evaluation history: Type=Full;Author=Chechev. Kuzmenkho;Cutoff date=30-JUN-2008 -227TH C References: 1950Ho79, 1955To07, 1956Sh43, 1959No41, 1959Ro51, 1963Ei10, -227TH2C 1966Ba19, 1967JoZX, 1970Ki12, 1974Mo05, 1986Ry04, 1991Ry01, 1995Sh03, -227TH3C 1995Li04, 1997Mu08, 2001Br31, 2002Ba85, 2003Au03 -227TH T Auger electrons and X ray energies and emission intensities: -227TH T {U Energy (keV)} {U Intensity} {U Line} -227TH T -227TH T 89.954 XKA2 -227TH T 93.351 XKA1 -227TH T -227TH T 104.819 |] XKB3 -227TH T 105.604 |] XKB1 -227TH T 106.239 |] XKB5II -227TH T -227TH T 108.509 |] XKB2 -227TH T 108.955 |] XKB4 -227TH T 109.442 |] XKO23 -227TH T -227TH T 11.118-19.599 2.64 XL (total) -227TH T 11.118 0.044 XLL -227TH T 12.809-12.968 0.147 XLA -227TH T 14.511 0.027 XLC -227TH T 14.97-16.426 1.9 XLB -227TH T 18.98-19.599 0.52 XLG -227TH T -227TH T 68.406-76.745 |] KLL AUGER -227TH T 83.857-93.345 |] KLX AUGER -227TH T 99.29-109.64 |] KXY AUGER -227TH T 5.8-20.3 3.9 L AUGER -227AC P 0.0 3/2- 21.772 Y 3 44.8 8 -227TH N 1.014E0 1.014E0 0.98620 4 1.014E0 -227TH G 219.2 4 1.40E-5 4 -227TH L 0 1/2+ 18.718 D 5 -227TH B 44.8 8 53 7.1 1 -227THS B EAV=11.4 3 -227TH L 9.3 1 (5/2)+ -227TH B 35.5 8 35 7 1 -227THS B EAV=9.0 3 -227TH G 9.3 0.00011 E2 326000 -227TH2 G MC=2.44E5 5 -227TH L 24.5 3/2+ -227TH B 20.5 8 10 6.8 -227THS B EAV=5.1 3 -227TH G 15.2 1 0.00063 M1 238 5 -227TH2 G MC=177 4 -227TH G 24.33 5 0.028 M1+E2 0.100 5 340 11 -227TH2 G LC=254 8$MC=64.0 23 -227TH L 37.9 3/2- -227TH B 6.9 8 0.3 6.9 -227THS B EAV=1.7 3 -227TH G 28.57 5 0.042 E1 3.24 7 -227TH2 G LC=2.42 5$MC=0.616 13 -227TH G 37.90 3 0.049 E1 1.54 3 -227TH2 G LC=1.16 3$MC=0.288 6 - +223FR 227AC A DECAY (21.772 Y) +223FR H TYP=FUL$AUT=V.P.CHECHEV, N.K.KUZMENKO$CUT=30-JUN-2008$ +223FR C References:1950Ho79, 1955To07, 1956Sh43, 1959No41, 1959Ro51, 1963Ei10, +223FR2C 1966Ba19, 1967JoZX, 1970Ki12, 1974Mo05, 1986Ry04, 1991Ry01, 1995Sh03, +223FR3C 1995Li04, 1997Mu08, 2000Sc**, 2001Br31, 2001Br31, 2002Ba85, 2002Be**, +223FR4C 2003Au03 +223FR T Auger electrons and X ray energies and emission intensities: +223FR T {U Energy (keV)} {U Intensity} {U Line} +223FR T +223FR T 83.23 0.0043 12 XKA2 +223FR T 86.1 0.0070 19 XKA1 +223FR T +223FR T 96.815 |] XKB3 +223FR T 97.474 |] 0.0024 7 XKB1 +223FR T 98.069 |] XKB5II +223FR T +223FR T 100.16 |] XKB2 +223FR T 100.548 |] 0.00079 22 XKB4 +223FR T 100.972 |] XKO23 +223FR T +223FR T 10.381-17.839 0.074 8 XL (total) +223FR T 10.381 0.00097 18 XLL +223FR T 11.896-12.032 0.017 3 XLA +223FR T 13.255 0.0006 1 XLC +223FR T 13.877-14.978 0.044 5 XLB +223FR T 17.302-17.839 0.012 1 XLG +223FR T +223FR T 63.576-70.787 |] KLL AUGER +223FR T 77.72-86.101 |] 0.00050 15 KLX AUGER +223FR T 91.84-101.12 |] KXY AUGER +223FR T 5.73-18.52 0.097 10 L AUGER +227AC P 0.0 3/2- 21.772 Y 3 5042.19 14 +223FR N 7.246E1 7.246E1 0.01380 4 +223FR G 219.2 4 1.40E-5 4 +223FR L 0 3/2- 22.00 M 7 +223FR A 4953.23 1447.7 107 +223FR L 12.89 5 (5/2)- +223FR A 4940.57 1539.6 127 +223FR G 12.9 1 0.000014 (E2) 4.99E4 10 +223FR2 G MC=3.77E4 8 +223FR L 54.97 7 1/2- +223FR A 4899.23 150.108696 1360 +223FR G 55.0 1 0.00044 8M1+E2 0.05 4 16.4 8 +223FR2 G LC=12.5 6$MC=2.98 16 +223FR L 82.13 6 (7/2)- +223FR A 4872.55 156.3 516 +223FR G 69.28 8 0.0039 6M1+E2 0.57 18.4 19 +223FR2 G LC=13.7 14$MC=3.6 4 +223FR G 82.2 1 0.00083 10E2 22.1 5 +223FR2 G LC=16.25 30$MC=4.40 9 +223FR L 99.63 6 (3/2)- +223FR A 4855.36 155.8 713 +223FR G 44.7 1 0.00011 3[M1+E2] 1 2.2E2 20 +223FR2 G LC=1.6E2 15$MC=44 40 +223FR G 86.7 2 0.0028 4[M1+E2] 1 11 7 +223FR2 G LC=8 5$MC=2.1 14 +223FR G 99.6 1 0.0051 7[M1+E2] 1 6 3 +223FR2 G LC=4.4 22$MC=1.2 7 +223FR L 101.00 6 (5/2)- +223FR A 4854.01 151E-9 +223FR G 88.1 1 0.00069 10[M1+E2] 1 10 6 +223FR2 G LC=8 5$MC=2.0 13 +223FR G 101.0 1 0.00069 30[M1+E2] 1 6 3 +223FR2 G LC=4.1 21$MC=1.1 6 +223FR L 134.51 6 (3/2)+ +223FR A 4821.09 1572464E-6 663 +223FR G 33.5 1 0.00011 3[E1] 1.99 4 +223FR2 G LC=1.50 3$MC=0.371 8 +223FR G 35.0 2 0.00002810[E1] 1.77 4 +223FR2 G LC=1.34 3$MC=0.330 7 +223FR G 79.54 8 0.0011 1E1 0.197 4 +223FR2 G LC=0.149 3$MC=0.0360 7 +223FR G 121.6 1 0.0012 3[E1] 0.295 6 +223FR2 G KC=0.231 5$LC=0.0485 10$MC=0.0116 3 +223FR G 134.5 1 0.00055 10E1 0.230 5 +223FR2 G KC=0.182 4$LC=0.0372 8$MC=0.00891 18 +223FR L 149.3 3 (1/2)+ +223FR G 149.3 3 0.000014 +223FR L 160.48 7 (3/2)+ +223FR A 4795.58 151.0 531 +223FR G 25.95 5.5E-7 +223FR G 59.4 2 0.00004110[E1] 0.430 9 +223FR2 G LC=0.326 7$MC=0.0790 16 +223FR G 60.6 3 0.00004110[E1] 0.408 9 +223FR2 G LC=0.309 6$MC=0.0749 15 +223FR G 147.61 8 0.0025 3E1 0.184 4 +223FR2 G KC=0.145 3$LC=0.0292 6$MC=0.00699 14 +223FR G 160.49 100.0044 4E1 0.150 3 +223FR2 G KC=0.119 3$LC=0.0235 5$MC=0.00562 11 +223FR L 172.08 6 (5/2)+ +223FR A 4784.19 1579710E-6 329 +223FR G 72.5 2 0.00006930[E1] 0.252 5 +223FR2 G LC=0.191 4$MC=0.0462 10 +223FR G 90.0 1 0.00018 7[E1] 0.142 3 +223FR2 G LC=0.107 2$MC=0.0259 5 +223FR G 159.2 1 0.00055 10[E1] 0.153 3 +223FR2 G KC=0.121 3$LC=0.0240 5$MC=0.00574 11 +223FR G 172.0 1 0.00097 10E1 0.127 3 +223FR2 G KC=0.101 2$LC=0.0197 4$MC=0.0047 1 +223FR L 187.18 10(5/2)- +223FR A 4769.35 171.8 511 +223FR G 52.32 1.4E-6 +223FR G 86.1 1 0.00047 +223FR G 105.0 2 0.00034 10M1 12.4 25 +223FR2 G KC=9.96 20$LC=1.86 4$MC=0.443 9 +223FR G 174.3 1 0.00028 6[M1+E2] 1 1.9 11 +223FR2 G KC=1.3 11$LC=0.48 4$MC=0.122 17 +223FR L 189.10 7 (7/2)- +223FR A 4767.47 151E-9 +223FR G 88.1 1 0.00069 10[M1+E2] 1 10 6 +223FR2 G LC=8 5$MC=2.0 13 +223FR G 106.85 100.0011 1[M1+E2] 1 9 3 +223FR2 G KC=5 2$LC=3.2 15$MC=0.8 4 +223FR G 176.1 1 0.00033 6[M1+E2] 1 1.9 11 +223FR2 G KC=1.3 11$LC=0.46 4$MC=0.117 17 +223FR L 219.61 9 (7/2)+ +223FR A 4737.50 1686957E-6 142 +223FR G 85.0 5 0.000011 +223FR G 118.7 4 0.00004110[E1] 0.312 6 +223FR2 G KC=0.244 5$LC=0.0516 11$MC=0.0124 3 +223FR G 137.4 1 0.00041 10[E1] 0.220 5 +223FR2 G KC=0.172 4$LC=0.0352 7$MC=0.00843 17 +223FR G 206.8 1 0.00097 10E1 0.0814 17 +223FR2 G KC=0.0651 13$LC=0.0124 3$MC=0.00294 6 +223FR L 222.75 10(7/2)+ +223FR A 4734.41 171E-9 +223FR G 51.06 2.8E-7 +223FR G 88.5 6 9.7E-7 +223FR G 140.9 1 0.00021 6[E1] 0.206 4 +223FR2 G KC=0.162 4$LC=0.0330 7$MC=0.00789 16 +223FR L 242.63 7 (5/2)+ +223FR A 4714.88 150.43 2223 +223FR G 53.7 2 0.00004110[E1] 0.563 11 +223FR2 G LC=0.427 9$MC=0.104 2 +223FR G 70.6 2 0.00008330[M1+E2] 1 27 19 +223FR2 G LC=20 14$MC=5 4 +223FR G 108.0 3 0.00004110[M1+E2] 1 9 3 +223FR2 G KC=5 2$LC=3.1 15$MC=0.8 4 +223FR G 143.0 1 0.00028 6[E1] 0.198 4 +223FR2 G KC=0.157 3$LC=0.0317 7$MC=0.00759 15 +223FR G 229.7 1 0.00041 7[E1] 0.0634 13 +223FR2 G KC=0.0509 11$LC=0.00951 19$MC=0.00226 5 +223FR G 242.6 2 0.00028 7[E1] 0.0558 12 +223FR2 G KC=0.0448 9$LC=0.00831 17$MC=0.00198 4 +223FR L 243.85 13(5/2)+ +223FR A 4713.68 191E-9 +223FR G 83.0 1 1.4E-6 +223FR G 161.4 4 0.00014 4[M1+E2] 1 2.5 13 +223FR2 G KC=1.6 15$LC=0.64 9$MC=0.16 4 +223FR G 230.9 5 0.000014 [M1+E2] 1 0.8 5 +223FR2 G KC=0.6 5$LC=0.177 24$MC=0.045 4 +223FR G 243.9 4 2.80E-5 8[E2] 0.279 6 +223FR2 G KC=0.108 2$LC=0.126 3$MC=0.0335 7 +223FR L 244.66 15(7/2)- +223FR A 4712.89 201E-9 +223FR G 55.80 5 3.9E-6 +223FR G 57.56 5 3.2E-6 +223FR G 72.5 2 0.00006930[E1] 0.252 5 +223FR2 G LC=0.191 4$MC=0.0462 10 +223FR G 143.65 5 0.000026 M1 5.11 11 +223FR2 G KC=4.12 8$LC=0.755 15$MC=0.180 4 +223FR G 162.6 2 0.00005530[M1+E2] 1 2.4 13 +223FR2 G KC=1.6 15$LC=0.62 9$MC=0.16 4 +223FR G 231.79 5 7.2E-6 +223FR L 298.7 3 (9/2)- +223FR G 216.6 3 0.00005530[M1+E2] 1 1.0 7 +223FR2 G KC=0.7 6$LC=0.221 20$MC=0.0556 18 +223FR L 365.47 10 +223FR A 4594.21 1721739E-6 65 +223FR G 121.6 1 0.0012 3[E1] 0.295 6 +223FR2 G KC=0.231 5$LC=0.0485 10$MC=0.0116 3 +223FR G 143.0 1 0.00028 6[M1+E2] 1 3.6 18 +223FR2 G KC=2.2 11$LC=1.0 5$MC=0.26 13 +223FR G 146.0 2 8.8E-6 +223FR G 176.1 1 0.00033 4[E1] 0.120 3 +223FR2 G KC=0.095 2$LC=0.0185 4$MC=0.00443 9 +223FR G 283.4 3 0.00005530[E1] 0.0389 8 +223FR2 G KC=0.0314 7$LC=0.00570 12$MC=0.00136 3 +223FR L 379 7 +223FR A 4581 7 28986E-7 340 +223FR L 449 5 +223FR A 4512 5 28986E-7 108 +223FR L 503 7 +223FR A 4459 7 50725E-7 26 +223FR L 515.20 223/2- +223FR A 4447.12 2650725E-6 2.1 +223FR G 415.6 3 0.00021 6[M1+E2] 1 0.16 11 +223FR2 G KC=0.13 10$LC=0.028 12$MC=0.007 3 +223FR G 460.2 3 0.00021 6[M1+E2] 1 0.12 9 +223FR2 G KC=0.10 8$LC=0.021 10$MC=0.0051 22 +223FR L 540.74 25(5/2)+ +223FR A 4422.03 2857971E-7 12 +223FR G 351.7 3 0.00005530[E1] 0.0240 5 +223FR2 G KC=0.0195 4$LC=0.00344 7$MC=0.000815 17 +223FR G 439.60 5 0.000034 1 +223FR G 441.0 4 0.00005530[E1] 0.0148 3 +223FR2 G KC=0.0120 3$LC=0.00207 4$MC=0.00049 1 +223FR G 527.6 1 0.000029 +223FR G 540.40 5 0.00007 +223FR L 601 7 (5/2)- +223FR A 4362.83 1528986E-7 8 + +227TH 227AC B- DECAY (21.772 Y) +227TH H TYP=FUL$AUT=V.P.CHECHEV, N.K.KUZMENKO$CUT=30-JUN-2008$ +227TH C References:1950Ho79, 1955To07, 1956Sh43, 1959No41, 1959Ro51, 1963Ei10, +227TH2C 1966Ba19, 1967JoZX, 1970Ki12, 1974Mo05, 1986Ry04, 1991Ry01, 1995Sh03, +227TH3C 1995Li04, 1997Mu08, 2000Sc**, 2001Br31, 2001Br31, 2002Ba85, 2002Be**, +227TH4C 2003Au03 +227TH T Auger electrons and X ray energies and emission intensities: +227TH T {U Energy (keV)} {U Intensity} {U Line} +227TH T +227TH T 89.954 XKA2 +227TH T 93.351 XKA1 +227TH T +227TH T 104.819 |] XKB3 +227TH T 105.604 |] XKB1 +227TH T 106.239 |] XKB5II +227TH T +227TH T 108.509 |] XKB2 +227TH T 108.955 |] XKB4 +227TH T 109.442 |] XKO23 +227TH T +227TH T 11.118-19.599 2.64 XL (total) +227TH T 11.118 0.044 XLL +227TH T 12.809-12.968 0.147 XLA +227TH T 14.511 0.027 XLC +227TH T 14.97-16.426 1.9 XLB +227TH T 18.98-19.599 0.52 XLG +227TH T +227TH T 68.406-76.745 |] KLL AUGER +227TH T 83.857-93.345 |] KLX AUGER +227TH T 99.29-109.64 |] KXY AUGER +227TH T 5.8-20.3 3.9 L AUGER +227AC P 0.0 3/2- 21.772 Y 3 44.8 8 +227TH N 1.014E0 1.014E0 0.98620 41.014E0 +227TH L 0 1/2+ 18.718 D 5 +227TH B 44.8 8 53 7.1 1 +227THS B EAV=11.4 3 +227TH L 9.3 1 (5/2)+ +227TH B 35.5 8 35 7 1 +227THS B EAV=9.0 3 +227TH G 9.3 0.00011 E2 326000 +227TH2 G MC=2.44E5 5 +227TH L 24.5 3/2+ +227TH B 20.5 8 10 6.8 +227THS B EAV=5.1 3 +227TH G 15.2 1 0.00063 M1 238 5 +227TH2 G MC=177 4 +227TH G 24.33 5 0.028 M1+E2 0.100 5 340 11 +227TH2 G LC=254 8$MC=64.0 23 +227TH L 37.9 3/2- +227TH B 6.9 8 0.3 6.9 +227THS B EAV=1.7 3 +227TH G 28.57 5 0.042 E1 3.24 7 +227TH2 G LC=2.42 5$MC=0.616 13 +227TH G 37.90 3 0.049 E1 1.54 3 +227TH2 G LC=1.16 3$MC=0.288 6 + diff --git a/HEN_HOUSE/spectra/lnhb/Ac-228.txt b/HEN_HOUSE/spectra/lnhb/Ac-228.txt index 099620c5b..bc3d16b24 100644 --- a/HEN_HOUSE/spectra/lnhb/Ac-228.txt +++ b/HEN_HOUSE/spectra/lnhb/Ac-228.txt @@ -1,643 +1,822 @@ -224FR 228AC A DECAY (6.15 H) -224FR H TYP=Full$AUT=Andy Pearce$CUT=31-JAN-2009$ -224FR C Evaluation history: Type=Full;Author=Andy Pearce;Cutoff date=31-JAN-2009 -224FR C References: 1931Cu01, 1969Lu12, 1971He23, 1979He23, 1985Sk02, 1987Da28, -224FR2C 1992Li05, 1995Ba42, 1996Sc06, 1997Ar08, 2003Wa32, 2003Au03, 2005KiZT, -224FR3C 2004KiZW -224FR T Auger electrons and X ray energies and emission intensities: -224FR T {U Energy (keV)} {U Intensity} {U Line} -224FR T -224FR T 83.23 XKA2 -224FR T 86.1 XKA1 -224FR T -224FR T 96.815 |] XKB3 -224FR T 97.474 |] XKB1 -224FR T 98.069 |] XKB5II -224FR T -224FR T 100.16 |] XKB2 -224FR T 100.548 |] XKB4 -224FR T 100.972 |] XKO23 -224FR T -224FR T -224FR T 63.576-70.787 |] KLL AUGER -224FR T 77.72-86.101 |] KLX AUGER -224FR T 91.84-101.12 |] KXY AUGER -224FR T 0.1-18.519 L AUGER -228AC P 0.0 3+ 6.15 H 3 4810 50 -224FR N 1.818E7 1.818E7 5.5E-08 221.818E7 -224FR L 0 1- - -228TH 228AC B- DECAY (6.15 H) -228TH H TYP=Full$AUT=Andy Pearce$CUT=31-JAN-2009$ -228TH C Evaluation history: Type=Full;Author=Andy Pearce;Cutoff date=31-JAN-2009 -228TH C References: 1931Cu01, 1969Lu12, 1971He23, 1979He23, 1985Sk02, 1987Da28, -228TH2C 1992Li05, 1995Ba42, 1996Sc06, 1997Ar08, 2003Wa32, 2003Au03, 2005KiZT, -228TH3C 2004KiZW -228TH T Auger electrons and X ray energies and emission intensities: -228TH T {U Energy (keV)} {U Intensity} {U Line} -228TH T -228TH T 89.954 2.5 7 XKA2 -228TH T 93.351 4.1 11 XKA1 -228TH T -228TH T 104.819 |] XKB3 -228TH T 105.604 |] 1.5 4 XKB1 -228TH T 106.239 |] XKB5II -228TH T -228TH T 108.509 |] XKB2 -228TH T 108.955 |] 0.49 13 XKB4 -228TH T 109.442 |] XKO23 -228TH T -228TH T 11.1177-19.5043 37 4 XL (total) -228TH T 11.1177 0.80 5 XLL -228TH T 12.8085-12.967 13.3 8 XLA -228TH T 14.509 0.385 17 XLC -228TH T 14.972-16.4253 18.2 7 XLB -228TH T 18.3633-19.5043 4.23 15 XLG -228TH T -228TH T 68.406-76.745 |] KLL AUGER -228TH T 83.857-93.345 |] 0.27 8 KLX AUGER -228TH T 99.29-109.64 |] KXY AUGER -228TH T 5.8-20.3 39.9 21 L AUGER -228AC P 0.0 3+ 6.15 H 3 2123.8 27 -228TH N 1.0 1.0 1 1.0 -228TH L 0 - 1.9126 Y 9 -228TH L 57.759 4 2+ -228TH B 2066.0 276 4 9 -228THS B EAV=742.8 11 -228TH G 57.752 130.470 17E2 153.2 22 -228TH2 G LC=112.2 16$MC=30.7 5 -228TH L 186.823 4 4+ -228TH B 1937.0 270.6 5 10 -228THS B EAV=690.2 11 -228TH G 129.065 3 2.50 7E2 3.74 6 -228TH2 G KC=0.264 4$LC=2.54 4$MC=0.697 10 -228TH L 328.003 4 1- -228TH B 1795.8 270.72 23 10.65 1U -228THS B EAV=605.4 11 -228TH G 270.245 7 3.55 10E1 0.0470 7 -228TH2 G KC=0.0376 6$LC=0.00716 10$MC=1717E-6 24 -228TH G 328.004 7 3.04 11E1 0.0305 5 -228TH2 G KC=0.0245 4$LC=0.00455 7$MC=1089E-6 16 -228TH L 378.179 106+ -228TH B 1745.6 270.147 21 12.29 2U -228THS B EAV=587.3 11 -228TH G 191.351 170.133 8E2 0.776 11 -228TH2 G KC=0.1710 24$LC=0.443 7$MC=0.1209 17 -228TH L 396.078 5 3- -228TH B 1727.7 2712.4 5 8.4 -228THS B EAV=605.7 11 -228TH G 209.248 7 3.97 13E1 0.0848 12 -228TH2 G KC=0.0672 10$LC=0.01333 19$MC=0.00321 5 -228TH G 338.320 5 11.4 4E1 0.0285 4 -228TH2 G KC=0.0229 4$LC=0.00424 6$MC=1014E-6 15 -228TH L 519.192 6 5- -228TH G 140.999 200.045 9E1 0.217 3 -228TH2 G KC=0.1690 24$LC=0.0362 5$MC=0.00876 13 -228TH G 332.371 6 0.37 6E1 0.0297 5 -228TH2 G KC=0.0238 4$LC=0.00441 7$MC=1056E-6 15 -228TH L 831.823 100+ -228TH G 503.819 230.171 19E1 0.0124318 -228TH2 G KC=0.01009 15$LC=1775E-6 25$MC=4.22E-4 6 -228TH G 774.07 100.062 4E2 0.0164923 -228TH2 G KC=0.01204 17$LC=0.00333 5$MC=8.35E-4 12 -228TH L 874.473 182+ -228TH B 1249.3 270.17 10 9.7 -228THS B EAV=417.2 11 -228TH G 478.40 5 0.224 19E1 0.0137920 -228TH2 G KC=0.01118 16$LC=0.00198 3$MC=4.71E-4 7 -228TH G 546.445 210.199 16E1 0.0105815 -228TH2 G KC=0.00861 12$LC=1500E-6 21$MC=3.57E-4 5 -228TH G 816.82 100.031 4M1+E2 0.036 21 -228TH2 G KC=0.028 18$LC=0.006 3$MC=0.0014 7 -228TH G 874.45 8 0.050 11E2 0.0129419 -228TH2 G KC=0.00968 14$LC=0.00245 4$MC=6.08E-4 9 -228TH L 938.58 7 0+ -228TH G 610.65 100.024 5E1 0.0085312 -228TH2 G KC=0.00695 10$LC=1198E-6 17$MC=2.84E-4 4 -228TH G 880.76 100.0065 19E2 0.0127618 -228TH2 G KC=0.00956 14$LC=0.00240 4$MC=5.97E-4 9 -228TH L 944.196 131,2+ -228TH B 1179.6 270.087 16 9.95 2 -228THS B EAV=390.6 11 -228TH G 616.210 300.084 7E1 0.0083812 -228TH2 G KC=0.00683 10$LC=1176E-6 17$MC=2.79E-4 4 -228TH G 944.190 300.10 1E1+M2 0.025 14 -228TH2 G KC=0.020 12$LC=0.0039 19$MC=0.0009 5 -228TH L 968.369 203- -228TH B 1155.4 270.18 3 9.6 -228THS B EAV=381.4 11 -228TH G 449.11 6 0.050 6E2 0.0554 8 -228TH2 G KC=0.0331 5$LC=0.01653 24$MC=0.00432 6 -228TH G 572.10 5 0.156 18M1+E2 0.09 6 -228TH2 G KC=0.07 5$LC=0.015 7$MC=0.0036 17 -228TH G 640.320 400.057 6E2 0.0245 4 -228TH2 G KC=0.01700 24$LC=0.00556 8$MC=1416E-6 20 -228TH L 968.968 5 2+ -228TH B 1154.8 2731 4 7.37 -228THS B EAV=381.1 11 -228TH G 782.140 6 0.50 4E2 0.0161523 -228TH2 G KC=0.01182 17$LC=0.00324 5$MC=8.12E-4 12 -228TH G 911.196 6 26.2 8E2 0.0119417 -228TH2 G KC=0.00900 13$LC=0.00221 3$MC=5.49E-4 8 -228TH G 968.960 9 15.9 5E2 0.0106115 -228TH2 G KC=0.00806 12$LC=0.00191 3$MC=4.72E-4 7 -228TH L 979.499 142+ -228TH B 1144.3 270.238 20 9.47 -228THS B EAV=377.1 11 -228TH G 583.391 100.120 11E1 0.0093213 -228TH2 G KC=0.00759 11$LC=1313E-6 19$MC=3.12E-4 5 -228TH G 651.530 300.094 10E1 0.0075411 -228TH2 G KC=0.00615 9$LC=1053E-6 15$MC=2.50E-4 4 -228TH G 792.69 100.081 5E2 0.0157222 -228TH2 G KC=0.01154 17$LC=0.00313 5$MC=7.84E-4 11 -228TH G 921.87 120.0154 23M1+E2 0.027 15 -228TH2 G KC=0.021 13$LC=0.0041 20$MC=0.0010 5 -228TH G 979.49 100.028 3E2 0.0103915 -228TH2 G KC=0.00791 11$LC=0.00186 3$MC=4.59E-4 7 -228TH L 1016.406 212,3,4- -228TH B 1107.4 270.39 6 9.2 1 -228THS B EAV=363.1 11 -228TH G 620.32 7 0.084 7 -228TH G 688.120 400.070 7 -228TH G 958.590 400.29 5 -228TH G 1016.44 100.019 3M1+E2 0.021 12 -228TH2 G KC=0.017 10$LC=0.0032 15$MC=0.0008 4 -228TH L 1022.527 6 (3)+ -228TH B 1101.3 273.0 4 8.31 -228THS B EAV=360.8 11 -228TH G 835.704 8 1.70 7E2 0.0141520 -228TH2 G KC=0.01050 15$LC=0.00274 4$MC=6.83E-4 10 -228TH G 964.786 8 4.99 17E2+M1 -7.2 10 0.0111923 -228TH2 G KC=0.00853 19$LC=0.00199 4$MC=4.92E-4 9 -228TH L 1059.93 3 4- -228TH B 1063.9 270.099 11 9.74 1 -228THS B EAV=346.7 11 -228TH G 540.67 5 0.027 3M1+E2 0.10 7 -228TH2 G KC=0.08 6$LC=0.017 9$MC=0.0042 19 -228TH G 663.88 8 0.029 6M1+E2 0.06 4 -228TH2 G KC=0.05 4$LC=0.010 5$MC=0.0024 12 -228TH G 873.10 150.032 7E1 0.00440 7 -228TH2 G KC=0.00361 5$LC=6.01E-4 9$MC=1422E-7 20 -228TH L 1091.017 8 4+ -228TH G 904.20 5 0.78 4E2 0.0121217 -228TH2 G KC=0.00912 13$LC=0.00225 4$MC=5.59E-4 8 -228TH G 1033.244 230.204 12E2 0.0093814 -228TH2 G KC=0.0072 1$LC=1643E-6 23$MC=4.04E-4 6 -228TH L 1122.951 6 2- -228TH B 1000.8 276.67 18 7.81 1 -228THS B EAV=323.2 10 -228TH G 100.41 3 0.114 6E1+M2 0.23 3.10 5 -228TH2 G LC=2.27 4$MC=0.615 9 -228TH G 153.967 110.754 23E1 0.1757 25 -228TH2 G KC=0.1375 20$LC=0.0289 4$MC=0.00698 10 -228TH G 726.88 100.68 8E2 0.0187 3 -228TH2 G KC=0.01349 19$LC=0.00393 6$MC=9.90E-4 14 -228TH G 794.942 144.31 14E2+M1 -4.4 10 0.0179 14 -228TH2 G KC=0.0133 12$LC=0.00340 19$MC=0.00085 5 -228TH G 1065.168 150.135 8 -228TH L 1153.467 102+ 0.29 NS 2 -228TH B 970.3 276 3 7.8 -228THS B EAV=311.9 10 -228TH G 173.960 300.036 5M1+E2 2.5 14 -228TH2 G KC=1.6 15$LC=0.63 5$MC=0.162 22 -228TH G 184.547 190.054 19+M1 100 40 -228TH2 G KC=80 30 -228TH G 214.89 100.031 5E2 0.514 8 -228TH2 G KC=0.1399 20$LC=0.274 4$MC=0.0746 11 -228TH G 278.80 150.204 28M1+E2 0.6 4 -228TH2 G KC=0.5 4$LC=0.12 3$MC=0.031 6 -228TH G 321.646 8 0.232 14E2 0.1369 20 -228TH2 G KC=0.0635 9$LC=0.0540 8$MC=0.01444 21 -228TH G 1095.671 230.126 10M1+E2 0.017 9 -228TH2 G KC=0.014 8$LC=0.0026 13$MC=0.0006 3 -228TH G 1153.270 400.148 13E1+M2 0.03 3 -228TH2 G KC=0.022 20$LC=0.004 5$MC=0.0011 10 -228TH L 1168.375 5 3- -228TH B 955.4 273.39 13 8.04 -228THS B EAV=306.4 10 -228TH G 77.34 3 0.027 6E1 0.232 4 -228TH2 G LC=0.1747 25$MC=0.0426 6 -228TH G 145.842 200.169 6E1 0.200 3 -228TH2 G KC=0.1562 22$LC=0.0332 5$MC=0.00803 12 -228TH G 199.402 150.299 23E1 0.0950 14 -228TH2 G KC=0.0752 11$LC=0.01502 21$MC=0.00362 5 -228TH G 649.02 120.0332 36E2 0.0238 4 -228TH2 G KC=0.01658 24$LC=0.00536 8$MC=1362E-6 19 -228TH G 772.291 7 1.52 6M1+E2 2.3 2 0.0244 14 -228TH2 G KC=0.0186 11$LC=0.00437 18$MC=0.00108 5 -228TH G 840.372 9 0.97 4E2 0.0140 2 -228TH2 G KC=0.01039 15$LC=0.00270 4$MC=6.73E-4 10 -228TH G 1110.604 9 0.284 22E1 0.00288 4 -228TH2 G KC=0.00237 4$LC=3.88E-4 6$MC=9.15E-5 13 -228TH L 1174.508 18(5)+ -228TH G 987.87 100.14 6M1+E2 0.022 13 -228TH2 G KC=0.018 10$LC=0.0034 17$MC=0.0008 4 -228TH L 1175.39 5 2+ -228TH B 948.4 270.166 19 9.34 -228THS B EAV=303.9 10 -228TH G 231.42 100.026 4E2 0.392 6 -228TH2 G KC=0.1211 17$LC=0.199 3$MC=0.0539 8 -228TH G 988.65 200.081 14E2 0.0102115 -228TH2 G KC=0.00778 11$LC=0.00182 3$MC=4.49E-4 7 -228TH G 1117.65 100.061 7 -228TH G 1175.33 100.025 4E1+M2 0.027 24 -228TH2 G KC=0.021 19$LC=0.004 4$MC=0.001 1 -228TH L 1226.565 7 (4)- -228TH B 897.2 270.67 8 8.65 1 -228THS B EAV=285.1 10 -228TH G 135.507 220.024 6E1 0.238 4 -228TH2 G KC=0.185 3$LC=0.0401 6$MC=0.00971 14 -228TH G 707.42 5 0.162 18E2 0.0198 3 -228TH2 G KC=0.01417 20$LC=0.00422 6$MC=1067E-6 15 -228TH G 830.481 8 0.61 6E2+M1 -7.7 9 0.0150 3 -228TH2 G KC=0.01117 22$LC=0.00287 5$MC=7.15E-4 12 -228TH G 1039.83 7 0.056 18 -228TH L 1297.423 10(5)- -228TH B 826.4 271.46 11 8.18 1U -228THS B EAV=259.4 10 -228TH G 204.029 110.114 8M2 10.65 15 -228TH2 G KC=7.26 11$LC=2.51 4$MC=0.653 10 -228TH G 901.380 300.017 4E2 0.0122017 -228TH2 G KC=0.00917 13$LC=0.00227 4$MC=5.64E-4 8 -228TH G 1110.604 9 0.0272 21E1 0.00288 4 -228TH2 G KC=0.00237 4$LC=3.88E-4 6$MC=9.15E-5 13 -228TH L 1344.078 113- -228TH B 779.7 270.208 18 8.94 -228THS B EAV=242.7 10 -228TH G 168.53 120.0111 27M1+E2 2.7 15 -228TH2 G KC=1.8 16$LC=0.70 7$MC=0.18 3 -228TH G 824.931 250.053 6E2 0.0145221 -228TH2 G KC=0.01074 15$LC=0.00283 4$MC=7.06E-4 10 -228TH G 947.976 240.111 10M1+E2 0.025 14 -228TH2 G KC=0.020 12$LC=0.0038 19$MC=0.0009 5 -228TH G 1157.16 150.0073 14E1+M2 0.03 3 -228TH2 G KC=0.022 20$LC=0.004 4$MC=0.0011 10 -228TH G 1286.29 200.052 11E1+M2 -228TH L 1416.11 6 2,3- -228TH B 707.7 270.060 8 9.34 1 -228THS B EAV=217.3 10 -228TH G 471.77 150.034 4E2 0.0491 7 -228TH2 G KC=0.0301 5$LC=0.01407 20$MC=0.00367 6 -228TH G 1019.88 100.022 5 -228TH G 1088.20 150.0062 14 -228TH G 1229.42 150.0078 25 -228TH L 1431.979 6 4+ -228TH B 691.8 271.6 5 7.88 -228THS B EAV=211.8 10 -228TH G 257.482 210.0286 19M1 1.285 18 -228TH2 G KC=1.029 15$LC=0.194 3$MC=0.0466 7 -228TH G 263.58 100.043 3E1 0.0498 7 -228TH2 G KC=0.0397 6$LC=0.00760 11$MC=0.00182 3 -228TH G 278.80 150.031 5E2 0.212 3 -228TH2 G KC=0.0843 12$LC=0.0937 14$MC=0.0252 4 -228TH G 340.969 210.405 20E2+M1 -5.2 18 0.133 21 -228TH2 G KC=0.071 19$LC=0.0451 21$MC=0.0119 5 -228TH G 409.460 132.02 6E2+M1 0.21 15 -228TH2 G KC=0.16 13$LC=0.038 16$MC=0.009 4 -228TH G 452.50 6 0.0199 19E2 0.0544 8 -228TH2 G KC=0.0326 5$LC=0.01613 23$MC=0.00422 6 -228TH G 463.002 6 4.45 24E2 0.0514 8 -228TH2 G KC=0.0312 5$LC=0.01495 21$MC=0.00390 6 -228TH G 1103.43 100.0102 11E3 0.0195 3 -228TH2 G KC=0.01377 20$LC=0.00429 6$MC=1090E-6 16 -228TH G 1245.15 6 0.110 8M1+E2 0.013 6 -228TH2 G KC=0.010 5$LC=0.0019 9$MC=0.00046 20 -228TH G 1374.24 7 0.0196 14E2+M3 0.03 3 -228TH2 G KC=0.024 20$LC=0.005 5$MC=0.0014 12 -228TH L 1450.394 104- -228TH G 18.415 120.019 4E1 6.46 10 -228TH2 G LC=3.82 6$MC=2.00 3 -228TH G 223.793 210.058 6M1+E2 -0.18 5 1.85 4 -228TH2 G KC=1.48 4$LC=0.286 5$MC=0.0688 10 -228TH G 282.020 400.09 3M1+E2 0.6 4 -228TH2 G KC=0.4 4$LC=0.12 3$MC=0.030 6 -228TH G 930.99 7 0.0025 23M1+E2 0.026 15 -228TH2 G KC=0.021 12$LC=0.004 2$MC=0.0010 5 -228TH G 1054.13 200.019 6M1+E2 0.019 10 -228TH2 G KC=0.015 9$LC=0.0029 14$MC=0.0007 4 -228TH G 1451.43 150.0111 22M1+E2 0.009 4 -228TH2 G KC=0.007 3$LC=0.0013 6$MC=0.00031 13 -228TH L 1531.474 6 3+ -228TH G 99.505 121.26 4M1 3.84 6 -228TH2 G LC=2.90 4$MC=0.699 10 -228TH G 377.99 100.026 3M1+E2 0.27 18 -228TH2 G KC=0.20 16$LC=0.049 19$MC=0.012 5 -228TH G 440.450 240.128 10M1 0.295 5 -228TH2 G KC=0.237 4$LC=0.0442 7$MC=0.01061 15 -228TH G 508.955 130.51 4E2+M1 1.1 0.1130 16 -228TH2 G KC=0.0870 13$LC=0.0196 3$MC=0.00481 7 -228TH G 562.496 7 0.89 4E2+M1 0.09 6 -228TH2 G KC=0.07 5$LC=0.015 8$MC=0.0038 17 -228TH G 1135.26 150.0102 17 -228TH G 1344.62 150.0094 20M1+E2 0.011 5 -228TH2 G KC=0.008 4$LC=0.0016 7$MC=0.00038 16 -228TH L 1539.21 9 2,3,4+ -228TH B 584.6 270.030 6 9.36 -228THS B EAV=175.0 9 -228TH G 415.96 140.0138 23E1 0.0184 3 -228TH2 G KC=0.01485 21$LC=0.00267 4$MC=6.38E-4 9 -228TH G 1142.87 150.0108 22 -228TH L 1588.335 144- -228TH B 535.5 278.8 23 6.77 1 -228THS B EAV=158.5 9 -228TH G 56.88 5 0.020 5E1+[M2] 1.0 5 3.6E2 22 -228TH2 G LC=2.6E2 16$MC=70 50 -228TH G 137.936 220.028 4M1 7.52 11 -228TH2 G KC=6.00 9$LC=1.146 16$MC=0.276 4 -228TH L 1617.78 7 2,3,4+ -228TH B 506.0 270.071 10 8.78 -228THS B EAV=148.7 9 -228TH G 649.02 120.0086 9 -228TH G 1430.99 100.037 8 -228TH G 1560.02 7 0.021 5 -228TH L 1638.284 9 2+ -228TH B 485.5 271.23 6 7.48 -228THS B EAV=142.0 9 -228TH G 470.21 200.014 3E1 0.0142820 -228TH2 G KC=0.01157 17$LC=0.00205 3$MC=4.89E-4 7 -228TH G 515.12 7 0.051 6E1 0.0118917 -228TH2 G KC=0.00966 14$LC=1694E-6 24$MC=4.03E-4 6 -228TH G 1309.76 200.020 7E1+M2 0.020 18 -228TH2 G KC=0.016 15$LC=0.003 3$MC=0.0008 7 -228TH G 1580.531 250.62 4M1+E2 0.007 3 -228TH2 G KC=0.0057 24$LC=0.0011 4$MC=0.00025 10 -228TH G 1638.272 230.46 3E2 0.00410 6 -228TH2 G KC=0.00319 5$LC=6.08E-4 9$MC=1463E-7 21 -228TH L 1643.125 15(2,3)- -228TH B 480.7 270.82 3 7.64 1 -228THS B EAV=140.4 9 -228TH G 474.79 100.023 4M1+E2 0.14 10 -228TH2 G KC=0.11 9$LC=0.025 12$MC=0.006 3 -228TH G 520.160 300.070 7M1+E2 0.11 8 -228TH2 G KC=0.09 7$LC=0.019 9$MC=0.0047 21 -228TH G 626.80 220.015 3 -228TH G 674.630 400.105 10M1+E2 0.06 4 -228TH2 G KC=0.05 3$LC=0.009 5$MC=0.0023 11 -228TH G 698.99 100.038 6E2 0.0203 3 -228TH2 G KC=0.01448 21$LC=0.00436 7$MC=1103E-6 16 -228TH G 1247.10 5 0.524 24M1 0.0187 3 -228TH2 G KC=0.01505 21$LC=0.00274 4$MC=6.54E-4 10 -228TH G 1315.33 100.015 3M1+E2 0.011 6 -228TH2 G KC=0.009 5$LC=0.0017 7$MC=0.00040 17 -228TH L 1645.954 123+ -228TH B 477.8 274.12 20 6.94 -228THS B EAV=139.5 9 -228TH G 114.56 7 0.0102 22M1+E2 9 4 -228TH2 G KC=5 5$LC=3.2 13$MC=0.8 4 -228TH G 419.38 7 0.022 3E1 0.0181 3 -228TH2 G KC=0.01460 21$LC=0.00263 4$MC=6.26E-4 9 -228TH G 492.29 8 0.025 3M1+E2 0.13 9 -228TH2 G KC=0.10 8$LC=0.022 11$MC=0.0055 24 -228TH G 523.129 220.129 10E1 0.0115317 -228TH2 G KC=0.00937 14$LC=1641E-6 23$MC=3.90E-4 6 -228TH G 555.07 160.048 6M1+E2 -228TH G 623.48 220.012 3M1+E2 0.07 5 -228TH2 G KC=0.06 4$LC=0.012 6$MC=0.0028 13 -228TH G 629.41 5 0.047 5E2 0.0254 4 -228TH2 G KC=0.01754 25$LC=0.00584 9$MC=1489E-6 21 -228TH G 666.45 5 0.058 6M1+E2 0.06 4 -228TH2 G KC=0.05 4$LC=0.010 5$MC=0.0024 11 -228TH G 677.08 100.065 6M1+E2 0.06 4 -228TH2 G KC=0.05 3$LC=0.009 5$MC=0.0023 11 -228TH G 1250.06 5 0.065 6 -228TH G 1459.131 220.87 5E2 0.00498 7 -228TH2 G KC=0.00391 6$LC=7.71E-4 11$MC=1.87E-4 3 -228TH G 1588.200 253.06 12E2 0.007 3 -228TH2 G KC=0.0057 23$LC=0.0010 4$MC=0.00025 10 -228TH L 1682.81 3 2,3(),4+ -228TH B 441.0 271.21 4 7.35 -228THS B EAV=127.5 9 -228TH G 660.10 300.0054 3M1+E2 0.06 4 -228TH2 G KC=0.05 4$LC=0.010 5$MC=0.0024 12 -228TH G 1495.904 160.92 3E2 0.00477 7 -228TH2 G KC=0.00374 6$LC=7.32E-4 11$MC=1769E-7 25 -228TH G 1625.090 400.270 23E2+M3 0.020 17 -228TH2 G KC=0.016 13$LC=0.003 3$MC=0.0008 7 -228TH L 1683.82 5 (4)- -228TH B 440.0 270.20 3 8.13 1 -228THS B EAV=127.2 9 -228TH G 457.18 150.016 3M1+E2 0.16 11 -228TH2 G KC=0.12 10$LC=0.028 13$MC=0.007 3 -228TH G 1164.55 7 0.067 7M1+E2 0.015 8 -228TH2 G KC=0.012 6$LC=0.0023 11$MC=0.00055 24 -228TH G 1287.77 8 0.109 25M1+E2 0.012 6 -228TH2 G KC=0.009 5$LC=0.0018 8$MC=0.00042 18 -228TH L 1688.394 112,3+ -228TH B 435.4 272.50 16 7.02 -228THS B EAV=125.7 9 -228TH G 42.46 5 0.009 3M1 46.3 7 -228TH2 G LC=35.0 5$MC=8.43 13 -228TH G 671.95 8 0.027 8 -228TH G 813.88 100.0073 17M1+E2 0.036 22 -228TH2 G KC=0.029 18$LC=0.006 3$MC=0.0014 7 -228TH G 1501.59 5 0.513 17 -228TH G 1630.618 201.52 6M1+E2 0.007 3 -228TH2 G KC=0.0053 22$LC=0.0010 4$MC=0.00023 9 -228TH L 1724.283 6 2+ -228TH B 399.5 271.93 8 7.01 -228THS B EAV=114.3 9 -228TH G 497.64 100.0062 19M2 0.581 9 -228TH2 G KC=0.437 7$LC=0.1074 15$MC=0.0268 4 -228TH G 548.73 110.024 4M1+E2 0.10 7 -228TH2 G KC=0.08 6$LC=0.017 8$MC=0.0041 18 -228TH G 570.880 400.19 5M1 0.1472 21 -228TH2 G KC=0.1182 17$LC=0.0219 3$MC=0.00525 8 -228TH G 701.742 150.181 15M1 0.0850 12 -228TH2 G KC=0.0684 10$LC=0.01261 18$MC=0.00302 5 -228TH G 755.313 9 1.03 4M1 0.070 1 -228TH2 G KC=0.0563 8$LC=0.01036 15$MC=0.00248 4 -228TH G 1537.89 100.049 6E2+M3 0.023 19 -228TH2 G KC=0.018 15$LC=0.004 4$MC=0.0010 8 -228TH G 1666.514 130.173 9M1 0.0089513 -228TH2 G KC=0.00702 10$LC=1269E-6 18$MC=3.03E-4 5 -228TH G 1724.19 5 0.030 4E1+M2 -228TH L 1735.450 25(4)+ -228TH B 388.4 270.149 11 8.08 -228THS B EAV=110.7 9 -228TH G 1217.03 100.022 4 -228TH G 1357.81 150.021 5 -228TH G 1548.65 6 0.040 5 -228TH G 1677.66 6 0.057 6 -228TH L 1743.89 3 4+ -228TH B 379.9 270.378 16 7.65 -228THS B EAV=108.1 9 -228TH G 399.83 140.031 4E1 0.0200 3 -228TH2 G KC=0.01611 23$LC=0.00291 4$MC=6.96E-4 10 -228TH G 1347.50 150.016 4E1+M2 0.019 17 -228TH2 G KC=0.015 14$LC=0.003 3$MC=0.0007 7 -228TH G 1365.71 120.014 3E2+M3 0.03 3 -228TH2 G KC=0.025 21$LC=0.006 5$MC=0.0014 12 -228TH G 1415.55 140.022 5E3 0.0114116 -228TH2 G KC=0.00849 12$LC=0.00218 3$MC=5.43E-4 8 -228TH G 1557.13 7 0.173 9E2+M1 1.2 2 0.0070 6 -228TH2 G KC=0.0055 5$LC=0.00102 8$MC=2.45E-4 19 -228TH G 1686.22 110.094 7E2 0.00391 6 -228TH2 G KC=0.00303 5$LC=5.73E-4 8$MC=1378E-7 20 -228TH L 1758.24 122,3,4+ -228TH B 365.6 270.060 8 8.39 -228THS B EAV=103.6 9 -228TH G 326.04 200.035 6E2 0.1315 19 -228TH2 G KC=0.0618 9$LC=0.0513 8$MC=0.01372 20 -228TH G 1571.55 200.0059 17 -228TH G 1700.62 200.0105 25 -228TH L 1760.218 242,3()+ -228TH B 363.6 270.139 12 8.02 -228THS B EAV=103.0 9 -228TH G 737.74 5 0.039 5M1+E2 0.05 3 -228TH2 G KC=0.037 24$LC=0.007 4$MC=0.0018 9 -228TH G 791.43 9 0.010 3M1+E2 0.039 23 -228TH2 G KC=0.031 19$LC=0.006 3$MC=0.0015 7 -228TH G 1573.389 240.034 4E2 0.00438 7 -228TH2 G KC=0.00342 5$LC=0.00066 1$MC=1592E-7 23 -228TH G 1702.40 8 0.055 7E2+M3 0.018 15 -228TH2 G KC=0.014 11$LC=0.0030 25$MC=0.0007 6 -228TH L 1795.9 1 3,4+ -228TH B 327.9 270.035 6 8.48 -228THS B EAV=91.9 8 -228TH G 1276.72 100.015 3 -228TH G 1738.46 5 0.018 4 -228TH L 1797.65 8 2+ -228TH B 326.2 270.051 8 8.3 -228THS B EAV=91.4 8 -228TH G 1401.52 100.013 3E1+M2 0.017 15 -228TH2 G KC=0.013 12$LC=0.0026 24$MC=0.0006 6 -228TH G 1469.74 150.021 5E1+M2 0.015 14 -228TH2 G KC=0.012 11$LC=0.0023 21$MC=0.0006 5 -228TH G 1740.5 3 0.011 4 -228TH G 1797.5 5 0.0022 8E1+M2 0.009 8 -228TH2 G KC=0.007 7$LC=0.0014 13$MC=0.0003 3 -228TH L 1892.996 173+ -228TH B 230.8 270.109 8 7.5 -228THS B EAV=62.8 8 -228TH G 666.45 5 0.0068 7E1 0.0072211 -228TH2 G KC=0.00590 9$LC=1007E-6 14$MC=2.39E-4 4 -228TH G 870.47 7 0.046 5M1 0.0481 7 -228TH2 G KC=0.0387 6$LC=0.0071 1$MC=1699E-6 24 -228TH G 1706.17 7 0.0089 12M1+E2 0.42 40 0.0078 12 -228TH2 G KC=0.0061 10$LC=0.00110 16$MC=0.00026 4 -228TH G 1835.29 100.038 4E2+M1 2.9 3 0.0038210 -228TH2 G KC=0.00291 8$LC=5.36E-4 14$MC=1.28E-4 4 -228TH L 1899.95 4 2+ -228TH B 223.9 270.069 8 7.65 -228THS B EAV=60.8 8 -228TH G 877.38 7 0.014 3M1+E2 0.030 18 -228TH2 G KC=0.024 15$LC=0.0047 23$MC=0.0011 6 -228TH G 930.99 7 0.004 1 -228TH G 1713.49 200.0057 11E2+M3 0.018 14 -228TH2 G KC=0.014 11$LC=0.0029 24$MC=0.0007 6 -228TH G 1842.15 8 0.037 6M1+E2 -0.86 14 0.0055 4 -228TH2 G KC=0.00420 25$LC=0.00076 5$MC=1.82E-4 11 -228TH G 1900.16 200.0030 6E1+M2 0.008 7 -228TH2 G KC=0.006 6$LC=0.0012 11$MC=0.0003 3 -228TH L 1906.64 10(2)+ -228TH B 217.2 270.025 5 8.05 -228THS B EAV=58.8 8 -228TH G 490.33 150.0116 25E2 0.0447 7 -228TH2 G KC=0.0280 4$LC=0.01242 18$MC=0.00323 5 -228TH G 1074.73 150.011 4 -228TH L 1928.57 6 3+ -228TH B 195.2 270.061 8 7.52 -228THS B EAV=52.5 8 -228TH G 168.53 120.0025 7M1+E2 2.7 15 -228TH2 G KC=1.8 16$LC=0.70 7$MC=0.18 3 -228TH G 389.32 130.0108 17M1+E2 0.25 17 -228TH2 G KC=0.19 15$LC=0.044 18$MC=0.011 4 -228TH G 1742.1 3 0.0084 25M1+E2 -228TH G 1870.82 9 0.0257 24M1+E2 0.0051 18 -228TH2 G KC=0.0038 14$LC=0.00070 24$MC=0.00017 6 -228TH L 1937.16 9 2,3,4+ -228TH B 186.6 270.053 6 7.52 -228THS B EAV=50.0 8 -228TH G 397.95 100.029 3 -228TH G 1062.57 150.011 4 -228TH G 1750.58 200.0084 9 -228TH G 1879.6 3 0.0013 5 -228TH L 1944.895 113+ -228TH B 178.9 270.307 22 6.7 -228THS B EAV=47.8 8 -228TH G 356.70 300.0178 21E1+M2 0.5 0.8 8 -228TH2 G KC=0.6 6$LC=0.17 17$MC=0.04 5 -228TH G 718.300 300.019 4E1 0.00628 9 -228TH2 G KC=0.00513 8$LC=8.70E-4 13$MC=2.06E-4 3 -228TH G 776.510 300.020 6 -228TH G 791.43 9 0.014 4M1 0.0618 9 -228TH2 G KC=0.0498 7$LC=0.00915 13$MC=0.00219 3 -228TH G 853.96 8 0.0124 20M1+E2 0.032 19 -228TH2 G KC=0.025 16$LC=0.0050 25$MC=0.0012 6 -228TH G 975.98 5 0.052 6M1 0.0356 5 -228TH2 G KC=0.0287 4$LC=0.00524 8$MC=1254E-6 18 -228TH G 1000.68 100.0054 3 -228TH G 1758.11 5 0.036 4E2+M1 -9.1 0.00371 6 -228TH2 G KC=0.00285 4$LC=5.33E-4 8$MC=1281E-7 18 -228TH G 1887.13 5 0.094 7E2+M1 0.0050 17 -228TH2 G KC=0.0038 13$LC=0.00068 23$MC=0.00016 6 -228TH L 1958.72 222+ -228TH B 165.1 270.0038 8 8.5 -228THS B EAV=43.9 8 -228TH G 1772.20 300.0019 5E2+M3 0.016 13 -228TH2 G KC=0.013 10$LC=0.0027 22$MC=0.0007 6 -228TH G 1958.40 300.0016 5E1+M2 -228TH L 1964.98 7 2,3,4+ -228TH B 158.8 270.0132 14 7.91 -228THS B EAV=42.2 8 -228TH G 1907.14 110.0124 13 -228TH L 1987.46 104+ -228TH B 136.3 270.07 4 7 -228THS B EAV=35.9 8 -228TH G 1017.94 200.03 3E2+M3 0.07 7 -228TH2 G KC=0.05 5$LC=0.014 12$MC=0.003 3 -228TH G 1609.44 150.0081 17E2 0.00422 6 -228TH2 G KC=0.00329 5$LC=6.30E-4 9$MC=1518E-7 22 -228TH G 1800.90 200.0046 8 -228TH G 1929.78 200.0208 14E2+M3 0.013 10 -228TH2 G KC=0.010 8$LC=0.0021 17$MC=0.0005 5 -228TH L 2010.11 5 2,3,(4)+ -228TH B 113.7 270.238 15 6.2 -228THS B EAV=29.7 8 -228TH G 372.59 3 0.0070 17E2 0.0902 13 -228TH2 G KC=0.0475 7$LC=0.0315 5$MC=0.00834 12 -228TH G 887.26 100.029 3M1+E2 0.029 17 -228TH2 G KC=0.023 14$LC=0.0046 22$MC=0.0011 6 -228TH G 919.03 120.028 3 -228TH G 1040.94 150.047 10E2+M3 0.07 6 -228TH2 G KC=0.05 5$LC=0.013 12$MC=0.003 3 -228TH G 1823.22 100.046 5 -228TH G 1952.37 100.062 5E2+M3 0.013 10 -228TH2 G KC=0.010 8$LC=0.0020 17$MC=0.0005 4 -228TH L 2013.6 3 2,3,4+ -228TH B 110.2 270.0032 10 8.03 -228THS B EAV=28.7 7 -228TH G 1826.80 300.0022 8 -228TH G 1955.9 5 0.0008 3 -228TH L 2022.84 10 + -228TH B 101.0 270.061 6 6.64 -228THS B EAV=26.2 7 -228TH G 384.47 9 0.0070 17E2 0.0828 12 -228TH2 G KC=0.0447 7$LC=0.0282 4$MC=0.00745 11 -228TH G 1053.11 200.014 4M1+E2 0.019 10 -228TH2 G KC=0.015 9$LC=0.0029 14$MC=0.0007 4 -228TH G 1148.17 140.0062 14M1+E2 0.015 8 -228TH2 G KC=0.012 7$LC=0.0023 11$MC=0.00057 25 -228TH G 1190.83 200.0065 17M1+E2 0.014 7 -228TH2 G KC=0.011 6$LC=0.0021 10$MC=0.00052 23 -228TH G 1965.22 120.0223 22M1+E2 0.0046 15 -228TH2 G KC=0.0034 12$LC=0.00062 20$MC=0.00015 5 -228TH L 2029.84 161,2+ -228TH B 94.0 270.026 4 6.91 2 -228THS B EAV=24.3 7 -228TH G 939.89 150.009 3 -228TH G 1013.55 130.0097 16 -228TH G 1972.00 300.0038 8 -228TH G 2029.4 5 0.0019 5E1+M2 0.007 6 -228TH2 G KC=0.005 5$LC=0.0010 9$MC=0.00024 22 -228TH L 2036.99 172,3,4+ -228TH B 86.8 270.0069 11 7.38 -228THS B EAV=22.4 8 -228TH G 1850.17 200.0046 8 -228TH G 1979.30 300.0019 5 -228TH L 2123.1 3 (2)+ -228TH B 0.7 270.0047 11 3.3 -228THS B EAV=0.18 68 -228TH G 1795.13 6 0.0022 8 -228TH G 1936.30 300.0022 6 - +224FR 228AC A DECAY (6.15 H) +224FR H TYP=FUL$AUT=A.PEARCE$CUT=31-JAN-2009$ +224FR C References:1931Cu01, 1969Lu12, 1969Ar**, 1971He23, 1973Ta25, 1977Ku15, +224FR2C 1979He23, 1979Bo30, 1982Ma**, 1982Sa36, 1983Sc13, 1985Sk02, 1987Da28, +224FR3C 1992Li05, 1995Ba42, 1996Sc06, 1997Ar08, 2003He**, 2003Wa32, 2003Au03, +224FR4C 2005KiZT, 2004KiZW +224FR T Auger electrons and X ray energies and emission intensities: +224FR T {U Energy (keV)} {U Intensity} {U Line} +224FR T +224FR T 83.23 XKA2 +224FR T 86.1 XKA1 +224FR T +224FR T 96.815 |] XKB3 +224FR T 97.474 |] XKB1 +224FR T 98.069 |] XKB5II +224FR T +224FR T 100.16 |] XKB2 +224FR T 100.548 |] XKB4 +224FR T 100.972 |] XKO23 +224FR T +224FR T +224FR T 63.576-70.787 |] KLL AUGER +224FR T 77.72-86.101 |] KLX AUGER +224FR T 91.84-101.12 |] KXY AUGER +224FR T 0.1-18.519 L AUGER +228AC P 0.0 3+ 6.15 H 3 4810 50 +224FR N 1.818E7 1.818E7 5.5E-8 22 +224FR L 0 1- + +228TH 228AC B- DECAY (6.15 H) +228TH H TYP=FUL$AUT=A.PEARCE$CUT=31-JAN-2009$ +228TH C References:1931Cu01, 1969Lu12, 1969Ar**, 1971He23, 1973Ta25, 1977Ku15, +228TH2C 1979He23, 1979Bo30, 1982Ma**, 1982Sa36, 1983Sc13, 1985Sk02, 1987Da28, +228TH3C 1992Li05, 1995Ba42, 1996Sc06, 1997Ar08, 2003He**, 2003Wa32, 2003Au03, +228TH4C 2005KiZT, 2004KiZW +228TH T Auger electrons and X ray energies and emission intensities: +228TH T {U Energy (keV)} {U Intensity} {U Line} +228TH T +228TH T 89.954 2.5 7 XKA2 +228TH T 93.351 4.1 11 XKA1 +228TH T +228TH T 104.819 |] XKB3 +228TH T 105.604 |] 1.5 4 XKB1 +228TH T 106.239 |] XKB5II +228TH T +228TH T 108.509 |] XKB2 +228TH T 108.955 |] 0.49 13 XKB4 +228TH T 109.442 |] XKO23 +228TH T +228TH T 11.1177-19.5043 37 4 XL (total) +228TH T 11.1177 0.80 5 XLL +228TH T 12.8085-12.967 13.3 8 XLA +228TH T 14.509 0.385 17 XLC +228TH T 14.972-16.4253 18.2 7 XLB +228TH T 18.3633-19.5043 4.23 15 XLG +228TH T +228TH T 68.406-76.745 |] KLL AUGER +228TH T 83.857-93.345 |] 0.27 8 KLX AUGER +228TH T 99.29-109.64 |] KXY AUGER +228TH T 5.8-20.3 39.9 21 L AUGER +228AC P 0.0 3+ 6.15 H 3 2123.8 27 +228TH N 1.0 1.0 1 1.0 +228TH L 0 1.9126 Y 9 +228TH L 57.759 4 2+ +228TH B 2066.0 276 4 9 +228THS B EAV=742.8 11 +228TH G 57.752 130.470 17E2 153.2 22 +228TH2 G LC=112.2 16$MC=30.7 5$NC=8.23 12 +228TH3 G OC=1.83 3 +228TH L 186.823 4 4+ +228TH B 1937.0 270.6 5 10 +228THS B EAV=690.2 11 +228TH G 129.065 3 2.50 7E2 3.74 6 +228TH2 G KC=0.264 4$LC=2.54 4$MC=0.697 10$NC=0.187 3 +228TH3 G OC=0.0417 6 +228TH L 328.003 4 1- +228TH B 1795.8 270.72 23 10.65 1U +228THS B EAV=605.4 11 +228TH G 270.245 7 3.55 10E1 0.0470 7 +228TH2 G KC=0.0376 6$LC=0.00716 10$MC=0.001717 24$NC=0.000454 7 +228TH3 G OC=1.054E-4 15 +228TH G 328.004 7 3.04 11E1 0.0305 5 +228TH2 G KC=0.0245 4$LC=0.00455 7$MC=0.001089 16$NC=0.000288 4 +228TH3 G OC=6.71E-5 10 +228TH L 378.179 106+ +228TH B 1745.6 270.147 21 12.29 2U +228THS B EAV=587.3 11 +228TH G 191.351 170.133 8E2 0.776 11 +228TH2 G KC=0.1710 24$LC=0.443 7$MC=0.1209 17$NC=0.0324 5 +228TH3 G OC=0.00726 11 +228TH L 396.078 5 3- +228TH B 1727.7 2712.4 5 8.4 +228THS B EAV=605.7 11 +228TH G 209.248 7 3.97 13E1 0.0848 12 +228TH2 G KC=0.0672 10$LC=0.01333 19$MC=0.00321 5$NC=0.000848 12 +228TH3 G OC=0.000196 3 +228TH G 338.320 5 11.4 4E1 0.0285 4 +228TH2 G KC=0.0229 4$LC=0.00424 6$MC=0.001014 15$NC=0.000269 4 +228TH3 G OC=6.25E-5 9 +228TH L 519.192 6 5- +228TH G 140.999 200.045 9E1 0.217 3 +228TH2 G KC=0.1690 24$LC=0.0362 5$MC=0.00876 13$NC=0.00231 4 +228TH3 G OC=0.000529 8 +228TH G 332.371 6 0.37 6E1 0.0297 5 +228TH2 G KC=0.0238 4$LC=0.00441 7$MC=0.001056 15$NC=0.000280 4 +228TH3 G OC=6.51E-5 10 +228TH L 831.823 100+ +228TH G 503.819 230.171 19E1 0.0124318 +228TH2 G KC=0.01009 15$LC=0.001775 25$MC=0.000422 6$NC=1.119E-4 16 +228TH3 G OC=2.62E-5 4 +228TH G 774.07 100.062 4E2 0.0164923 +228TH2 G KC=0.01204 17$LC=0.00333 5$MC=0.000835 12$NC=0.000223 4 +228TH3 G OC=5.17E-5 8 +228TH L 874.473 182+ +228TH B 1249.3 270.17 10 9.7 +228THS B EAV=417.2 11 +228TH G 478.40 5 0.224 19E1 0.0137920 +228TH2 G KC=0.01118 16$LC=0.00198 3$MC=0.000471 7$NC=1.249E-4 18 +228TH3 G OC=2.92E-5 4 +228TH G 546.445 210.199 16E1 0.0105815 +228TH2 G KC=0.00861 12$LC=0.001500 21$MC=0.000357 5$NC=9.45E-5 14 +228TH3 G OC=2.22E-5 4 +228TH G 816.82 100.031 4M1+E2 0.036 21 +228TH2 G KC=0.028 18$LC=0.006 3$MC=0.0014 7$NC=0.00036 18 +228TH3 G OC=0.00009 5 +228TH G 874.45 8 0.050 11E2 0.0129419 +228TH2 G KC=0.00968 14$LC=0.00245 4$MC=0.000608 9$NC=1.623E-4 23 +228TH3 G OC=3.78E-5 6 +228TH L 938.58 7 0+ +228TH G 610.65 100.024 5E1 0.0085312 +228TH2 G KC=0.00695 10$LC=0.001198 17$MC=0.000284 4$NC=7.54E-5 11 +228TH3 G OC=1.769E-5 25 +228TH G 880.76 100.0065 19E2 0.0127618 +228TH2 G KC=0.00956 14$LC=0.00240 4$MC=0.000597 9$NC=1.594E-4 23 +228TH3 G OC=3.71E-5 6 +228TH L 944.196 131,2+ +228TH B 1179.6 270.087 16 9.95 2 +228THS B EAV=390.6 11 +228TH G 616.210 300.084 7E1 0.0083812 +228TH2 G KC=0.00683 10$LC=0.001176 17$MC=0.000279 4$NC=7.40E-5 11 +228TH3 G OC=1.737E-5 25 +228TH G 944.190 300.10 1E1+M2 0.025 14 +228TH2 G KC=0.020 12$LC=0.0039 19$MC=0.0009 5$NC=0.00025 12 +228TH3 G OC=0.00006 3 +228TH L 968.369 203- +228TH B 1155.4 270.18 3 9.6 +228THS B EAV=381.4 11 +228TH G 449.11 6 0.050 6E2 0.0554 8 +228TH2 G KC=0.0331 5$LC=0.01653 24$MC=0.00432 6$NC=0.001157 17 +228TH3 G OC=0.000264 4 +228TH G 572.10 5 0.156 18M1+E2 0.09 6 +228TH2 G KC=0.07 5$LC=0.015 7$MC=0.0036 17$NC=0.0010 5 +228TH3 G OC=0.00023 11 +228TH G 640.320 400.057 6E2 0.0245 4 +228TH2 G KC=0.01700 24$LC=0.00556 8$MC=0.001416 20$NC=0.000378 6 +228TH3 G OC=8.73E-5 13 +228TH L 968.968 5 2+ +228TH B 1154.8 2731 4 7.37 +228THS B EAV=381.1 11 +228TH G 782.140 6 0.50 4E2 0.0161523 +228TH2 G KC=0.01182 17$LC=0.00324 5$MC=0.000812 12$NC=0.000217 3 +228TH3 G OC=5.03E-5 7 +228TH G 911.196 6 26.2 8E2 0.0119417 +228TH2 G KC=0.00900 13$LC=0.00221 3$MC=0.000549 8$NC=1.463E-4 21 +228TH3 G OC=3.41E-5 5 +228TH G 968.960 9 15.9 5E2 0.0106115 +228TH2 G KC=0.00806 12$LC=0.00191 3$MC=0.000472 7$NC=1.258E-4 18 +228TH3 G OC=2.93E-5 5 +228TH L 979.499 142+ +228TH B 1144.3 270.238 20 9.47 +228THS B EAV=377.1 11 +228TH G 583.391 100.120 11E1 0.0093213 +228TH2 G KC=0.00759 11$LC=0.001313 19$MC=0.000312 5$NC=8.27E-5 12 +228TH3 G OC=1.94E-5 3 +228TH G 651.530 300.094 10E1 0.0075411 +228TH2 G KC=0.00615 9$LC=0.001053 15$MC=0.000250 4$NC=6.62E-5 10 +228TH3 G OC=1.555E-5 22 +228TH G 792.69 100.081 5E2 0.0157222 +228TH2 G KC=0.01154 17$LC=0.00313 5$MC=0.000784 11$NC=0.000209 3 +228TH3 G OC=4.86E-5 7 +228TH G 921.87 120.0154 23M1+E2 0.027 15 +228TH2 G KC=0.021 13$LC=0.0041 20$MC=0.0010 5$NC=0.00027 13 +228TH3 G OC=0.00006 3 +228TH G 979.49 100.028 3E2 0.0103915 +228TH2 G KC=0.00791 11$LC=0.00186 3$MC=0.000459 7$NC=1.225E-4 18 +228TH3 G OC=2.86E-5 4 +228TH L 1016.406 212,3,4- +228TH B 1107.4 270.39 6 9.2 1 +228THS B EAV=363.1 11 +228TH G 620.32 7 0.084 7 +228TH G 688.120 400.070 7 +228TH G 958.590 400.29 5 +228TH G 1016.44 100.019 3M1+E2 0.021 12 +228TH2 G KC=0.017 10$LC=0.0032 15$MC=0.0008 4$NC=0.00021 10 +228TH3 G OC=0.000049 23 +228TH L 1022.527 6 (3)+ +228TH B 1101.3 273.0 4 8.31 +228THS B EAV=360.8 11 +228TH G 835.704 8 1.70 7E2 0.0141520 +228TH2 G KC=0.01050 15$LC=0.00274 4$MC=0.000683 10$NC=0.000182 3 +228TH3 G OC=4.24E-5 6 +228TH G 964.786 8 4.99 17E2+M1 -7.2 10 0.0111923 +228TH2 G KC=0.00853 19$LC=0.00199 4$MC=0.000492 9$NC=1.312E-4 23 +228TH3 G OC=3.06E-5 6 +228TH L 1059.93 3 4- +228TH B 1063.9 270.099 11 9.74 1 +228THS B EAV=346.7 11 +228TH G 540.67 5 0.027 3M1+E2 0.10 7 +228TH2 G KC=0.08 6$LC=0.017 9$MC=0.0042 19$NC=0.0011 5 +228TH3 G OC=0.00026 12 +228TH G 663.88 8 0.029 6M1+E2 0.06 4 +228TH2 G KC=0.05 4$LC=0.010 5$MC=0.0024 12$NC=0.0006 3 +228TH3 G OC=0.00015 8 +228TH G 873.10 150.032 7E1 0.00440 7 +228TH2 G KC=0.00361 5$LC=0.000601 9$MC=1.422E-4 20$NC=3.77E-5 6 +228TH3 G OC=8.88E-6 13 +228TH L 1091.017 8 4+ +228TH G 904.20 5 0.78 4E2 0.0121217 +228TH2 G KC=0.00912 13$LC=0.00225 4$MC=0.000559 8$NC=1.492E-4 21 +228TH3 G OC=3.47E-5 5 +228TH G 1033.244 230.204 12E2 0.0093814 +228TH2 G KC=0.0072 1$LC=0.001643 23$MC=0.000404 6$NC=1.078E-4 15 +228TH3 G OC=2.52E-5 4 +228TH L 1122.951 6 2- +228TH B 1000.8 276.67 18 7.81 1 +228THS B EAV=323.2 10 +228TH G 100.41 3 0.114 6E1+M2 0.23 3.10 5 +228TH2 G LC=2.27 4$MC=0.615 9$NC=0.1676 24 +228TH3 G OC=0.0393 6 +228TH G 153.967 110.754 23E1 0.1757 25 +228TH2 G KC=0.1375 20$LC=0.0289 4$MC=0.00698 10$NC=0.00184 3 +228TH3 G OC=0.000423 6 +228TH G 726.88 100.68 8E2 0.0187 3 +228TH2 G KC=0.01349 19$LC=0.00393 6$MC=0.000990 14$NC=0.000264 4 +228TH3 G OC=6.12E-5 9 +228TH G 794.942 144.31 14E2+M1 -4.4 10 0.0179 14 +228TH2 G KC=0.0133 12$LC=0.00340 19$MC=0.00085 5$NC=0.000226 12 +228TH3 G OC=0.000053 3 +228TH G 1065.168 150.135 8 +228TH L 1153.467 102+ 0.29 NS 2 +228TH B 970.3 276 3 7.8 +228THS B EAV=311.9 10 +228TH G 173.960 300.036 5M1+E2 2.5 14 +228TH2 G KC=1.6 15$LC=0.63 5$MC=0.162 22$NC=0.043 6 +228TH3 G OC=0.0099 11 +228TH G 184.547 190.054 19E0+M1 100 40 +228TH2 G KC=80 30 +228TH G 214.89 100.031 5E2 0.514 8 +228TH2 G KC=0.1399 20$LC=0.274 4$MC=0.0746 11$NC=0.0200 3 +228TH3 G OC=0.00449 7 +228TH G 278.80 150.204 28M1+E2 0.6 4 +228TH2 G KC=0.5 4$LC=0.12 3$MC=0.031 6$NC=0.0084 16 +228TH3 G OC=0.0019 5 +228TH G 321.646 8 0.232 14E2 0.1369 20 +228TH2 G KC=0.0635 9$LC=0.0540 8$MC=0.01444 21$NC=0.00387 6 +228TH3 G OC=0.000875 13 +228TH G 1095.671 230.126 10M1+E2 0.017 9 +228TH2 G KC=0.014 8$LC=0.0026 13$MC=0.0006 3$NC=0.00017 8 +228TH3 G OC=0.000040 19 +228TH G 1153.270 400.148 13E1+M2 0.03 3 +228TH2 G KC=0.022 20$LC=0.004 5$MC=0.0011 10$NC=0.0003 3 +228TH3 G OC=0.00007 7 +228TH L 1168.375 5 3- +228TH B 955.4 273.39 13 8.04 +228THS B EAV=306.4 10 +228TH G 77.34 3 0.027 6E1 0.232 4 +228TH2 G LC=0.1747 25$MC=0.0426 6$NC=0.01118 16 +228TH3 G OC=0.00252 4 +228TH G 145.842 200.169 6E1 0.200 3 +228TH2 G KC=0.1562 22$LC=0.0332 5$MC=0.00803 12$NC=0.00212 3 +228TH3 G OC=0.000485 7 +228TH G 199.402 150.299 23E1 0.0950 14 +228TH2 G KC=0.0752 11$LC=0.01502 21$MC=0.00362 5$NC=0.000956 14 +228TH3 G OC=0.000221 3 +228TH G 649.02 120.0332 36E2 0.0238 4 +228TH2 G KC=0.01658 24$LC=0.00536 8$MC=0.001362 19$NC=0.000364 5 +228TH3 G OC=8.39E-5 12 +228TH G 772.291 7 1.52 6M1+E2 2.3 2 0.0244 14 +228TH2 G KC=0.0186 11$LC=0.00437 18$MC=0.00108 5$NC=0.000288 11 +228TH3 G OC=0.000067 3 +228TH G 840.372 9 0.97 4E2 0.0140 2 +228TH2 G KC=0.01039 15$LC=0.00270 4$MC=0.000673 10$NC=0.000180 3 +228TH3 G OC=4.18E-5 6 +228TH G 1110.604 9 0.284 22E1 0.00288 4 +228TH2 G KC=0.00237 4$LC=0.000388 6$MC=9.15E-5 13$NC=2.43E-5 4 +228TH3 G OC=5.73E-6 8 +228TH L 1174.508 18(5)+ +228TH G 987.87 100.14 6M1+E2 0.022 13 +228TH2 G KC=0.018 10$LC=0.0034 17$MC=0.0008 4$NC=0.00022 11 +228TH3 G OC=0.000052 25 +228TH L 1175.39 5 2+ +228TH B 948.4 270.166 19 9.34 +228THS B EAV=303.9 10 +228TH G 231.42 100.026 4E2 0.392 6 +228TH2 G KC=0.1211 17$LC=0.199 3$MC=0.0539 8$NC=0.01445 21 +228TH3 G OC=0.00325 5 +228TH G 988.65 200.081 14E2 0.0102115 +228TH2 G KC=0.00778 11$LC=0.00182 3$MC=0.000449 7$NC=1.198E-4 17 +228TH3 G OC=2.79E-5 4 +228TH G 1117.65 100.061 7 +228TH G 1175.33 100.025 4E1+M2 0.027 24 +228TH2 G KC=0.021 19$LC=0.004 4$MC=0.001 1$NC=0.0003 3 +228TH3 G OC=0.00007 6 +228TH L 1226.565 7 (4)- +228TH B 897.2 270.67 8 8.65 1 +228THS B EAV=285.1 10 +228TH G 135.507 220.024 6E1 0.238 4 +228TH2 G KC=0.185 3$LC=0.0401 6$MC=0.00971 14$NC=0.00256 4 +228TH3 G OC=0.000586 9 +228TH G 707.42 5 0.162 18E2 0.0198 3 +228TH2 G KC=0.01417 20$LC=0.00422 6$MC=0.001067 15$NC=0.000285 4 +228TH3 G OC=6.59E-5 10 +228TH G 830.481 8 0.61 6E2+M1 -7.7 9 0.0150 3 +228TH2 G KC=0.01117 22$LC=0.00287 5$MC=0.000715 12$NC=0.000191 3 +228TH3 G OC=4.43E-5 8 +228TH G 1039.83 7 0.056 18 +228TH L 1297.423 10(5)- +228TH B 826.4 271.46 11 8.18 1U +228THS B EAV=259.4 10 +228TH G 204.029 110.114 8M2 10.65 15 +228TH2 G KC=7.26 11$LC=2.51 4$MC=0.653 10$NC=0.1769 25 +228TH3 G OC=0.0417 6 +228TH G 901.380 300.017 4E2 0.0122017 +228TH2 G KC=0.00917 13$LC=0.00227 4$MC=0.000564 8$NC=1.503E-4 21 +228TH3 G OC=3.50E-5 5 +228TH G 1110.604 9 0.0272 21E1 0.00288 4 +228TH2 G KC=0.00237 4$LC=0.000388 6$MC=9.15E-5 13$NC=2.43E-5 4 +228TH3 G OC=5.73E-6 8 +228TH L 1344.078 113- +228TH B 779.7 270.208 18 8.94 +228THS B EAV=242.7 10 +228TH G 168.53 120.0111 27M1+E2 2.7 15 +228TH2 G KC=1.8 16$LC=0.70 7$MC=0.18 3$NC=0.049 8 +228TH3 G OC=0.0112 15 +228TH G 824.931 250.053 6E2 0.0145221 +228TH2 G KC=0.01074 15$LC=0.00283 4$MC=0.000706 10$NC=0.000188 3 +228TH3 G OC=4.38E-5 7 +228TH G 947.976 240.111 10M1+E2 0.025 14 +228TH2 G KC=0.020 12$LC=0.0038 19$MC=0.0009 5$NC=0.00025 12 +228TH3 G OC=0.00006 3 +228TH G 1157.16 150.0073 14E1+M2 0.03 3 +228TH2 G KC=0.022 20$LC=0.004 4$MC=0.0011 10$NC=0.0003 3 +228TH3 G OC=0.00007 7 +228TH G 1286.29 200.052 11E1+M2 +228TH L 1416.11 6 2,3- +228TH B 707.7 270.060 8 9.34 1 +228THS B EAV=217.3 10 +228TH G 471.77 150.034 4E2 0.0491 7 +228TH2 G KC=0.0301 5$LC=0.01407 20$MC=0.00367 6$NC=0.000980 14 +228TH3 G OC=0.000224 4 +228TH G 1019.88 100.022 5 +228TH G 1088.20 150.0062 14 +228TH G 1229.42 150.0078 25 +228TH L 1431.979 6 4+ +228TH B 691.8 271.6 5 7.88 +228THS B EAV=211.8 10 +228TH G 257.482 210.0286 19M1 1.285 18 +228TH2 G KC=1.029 15$LC=0.194 3$MC=0.0466 7$NC=0.01244 18 +228TH3 G OC=0.00294 5 +228TH G 263.58 100.043 3E1 0.0498 7 +228TH2 G KC=0.0397 6$LC=0.00760 11$MC=0.00182 3$NC=0.000482 7 +228TH3 G OC=1.119E-4 16 +228TH G 278.80 150.031 5E2 0.212 3 +228TH2 G KC=0.0843 12$LC=0.0937 14$MC=0.0252 4$NC=0.00676 10 +228TH3 G OC=0.001525 22 +228TH G 340.969 210.405 20E2+M1 -5.2 18 0.133 21 +228TH2 G KC=0.071 19$LC=0.0451 21$MC=0.0119 5$NC=0.00319 13 +228TH3 G OC=0.00073 3 +228TH G 409.460 132.02 6E2+M1 0.21 15 +228TH2 G KC=0.16 13$LC=0.038 16$MC=0.009 4$NC=0.0025 10 +228TH3 G OC=0.00059 23 +228TH G 452.50 6 0.0199 19E2 0.0544 8 +228TH2 G KC=0.0326 5$LC=0.01613 23$MC=0.00422 6$NC=0.001128 16 +228TH3 G OC=0.000257 4 +228TH G 463.002 6 4.45 24E2 0.0514 8 +228TH2 G KC=0.0312 5$LC=0.01495 21$MC=0.00390 6$NC=0.001044 15 +228TH3 G OC=0.000238 4 +228TH G 1103.43 100.0102 11E3 0.0195 3 +228TH2 G KC=0.01377 20$LC=0.00429 6$MC=0.001090 16$NC=0.000292 4 +228TH3 G OC=6.78E-5 10 +228TH G 1245.15 6 0.110 8M1+E2 0.013 6 +228TH2 G KC=0.010 5$LC=0.0019 9$MC=0.00046 20$NC=0.00012 6 +228TH3 G OC=0.000029 13 +228TH G 1374.24 7 0.0196 14E2+M3 0.03 3 +228TH2 G KC=0.024 20$LC=0.005 5$MC=0.0014 12$NC=0.0004 3 +228TH3 G OC=0.00009 8 +228TH L 1450.394 104- +228TH G 18.415 120.019 4E1 6.46 10 +228TH2 G LC=3.82 6$MC=2.00 3$NC=0.514 8 +228TH3 G OC=0.1053 15 +228TH G 223.793 210.058 6M1+E2 -0.18 5 1.85 4 +228TH2 G KC=1.48 4$LC=0.286 5$MC=0.0688 10$NC=0.0184 3 +228TH3 G OC=0.00434 7 +228TH G 282.020 400.09 3M1+E2 0.6 4 +228TH2 G KC=0.4 4$LC=0.12 3$MC=0.030 6$NC=0.0081 16 +228TH3 G OC=0.0019 5 +228TH G 930.99 7 0.0025 23M1+E2 0.026 15 +228TH2 G KC=0.021 12$LC=0.004 2$MC=0.0010 5$NC=0.00026 12 +228TH3 G OC=0.00006 3 +228TH G 1054.13 200.019 6M1+E2 0.019 10 +228TH2 G KC=0.015 9$LC=0.0029 14$MC=0.0007 4$NC=0.00019 9 +228TH3 G OC=0.000044 21 +228TH G 1451.43 150.0111 22M1+E2 0.009 4 +228TH2 G KC=0.007 3$LC=0.0013 6$MC=0.00031 13$NC=0.00008 4 +228TH3 G OC=0.000020 8 +228TH L 1531.474 6 3+ +228TH G 99.505 121.26 4M1 3.84 6 +228TH2 G LC=2.90 4$MC=0.699 10$NC=0.186 3 +228TH3 G OC=0.0442 7 +228TH G 377.99 100.026 3M1+E2 0.27 18 +228TH2 G KC=0.20 16$LC=0.049 19$MC=0.012 5$NC=0.0032 11 +228TH3 G OC=0.0007 3 +228TH G 440.450 240.128 10M1 0.295 5 +228TH2 G KC=0.237 4$LC=0.0442 7$MC=0.01061 15$NC=0.00283 4 +228TH3 G OC=0.00067 1 +228TH G 508.955 130.51 4E2+M1 1.1 0.1130 16 +228TH2 G KC=0.0870 13$LC=0.0196 3$MC=0.00481 7$NC=0.001283 18 +228TH3 G OC=0.000301 5 +228TH G 562.496 7 0.89 4E2+M1 0.09 6 +228TH2 G KC=0.07 5$LC=0.015 8$MC=0.0038 17$NC=0.0010 5 +228TH3 G OC=0.00024 11 +228TH G 1135.26 150.0102 17 +228TH G 1344.62 150.0094 20M1+E2 0.011 5 +228TH2 G KC=0.008 4$LC=0.0016 7$MC=0.00038 16$NC=0.00010 5 +228TH3 G OC=0.000024 10 +228TH L 1539.21 9 2,3,4+ +228TH B 584.6 270.030 6 9.36 +228THS B EAV=175.0 9 +228TH G 415.96 140.0138 23E1 0.0184 3 +228TH2 G KC=0.01485 21$LC=0.00267 4$MC=0.000638 9$NC=1.689E-4 24 +228TH3 G OC=3.95E-5 6 +228TH G 1142.87 150.0108 22 +228TH L 1588.335 144- +228TH B 535.5 278.8 23 6.77 1 +228THS B EAV=158.5 9 +228TH G 56.88 5 0.020 5E1+[M2] 1.0 5 3.6E2 22 +228TH2 G LC=2.6E2 16$MC=70 50$NC=20 12 +228TH3 G OC=5 3 +228TH G 137.936 220.028 4M1 7.52 11 +228TH2 G KC=6.00 9$LC=1.146 16$MC=0.276 4$NC=0.0735 11 +228TH3 G OC=0.01742 25 +228TH L 1617.78 7 2,3,4+ +228TH B 506.0 270.071 10 8.78 +228THS B EAV=148.7 9 +228TH G 649.02 120.0086 9 +228TH G 1430.99 100.037 8 +228TH G 1560.02 7 0.021 5 +228TH L 1638.284 9 2+ +228TH B 485.5 271.23 6 7.48 +228THS B EAV=142.0 9 +228TH G 470.21 200.014 3E1 0.0142820 +228TH2 G KC=0.01157 17$LC=0.00205 3$MC=0.000489 7$NC=1.296E-4 19 +228TH3 G OC=3.03E-5 5 +228TH G 515.12 7 0.051 6E1 0.0118917 +228TH2 G KC=0.00966 14$LC=0.001694 24$MC=0.000403 6$NC=1.069E-4 15 +228TH3 G OC=2.50E-5 4 +228TH G 1309.76 200.020 7E1+M2 0.020 18 +228TH2 G KC=0.016 15$LC=0.003 3$MC=0.0008 7$NC=0.00021 19 +228TH3 G OC=0.00005 5 +228TH G 1580.531 250.62 4M1+E2 0.007 3 +228TH2 G KC=0.0057 24$LC=0.0011 4$MC=0.00025 10$NC=0.00007 3 +228TH3 G OC=0.000016 6 +228TH G 1638.272 230.46 3E2 0.00410 6 +228TH2 G KC=0.00319 5$LC=0.000608 9$MC=1.463E-4 21$NC=3.89E-5 6 +228TH3 G OC=9.16E-6 13 +228TH L 1643.125 15(2,3)- +228TH B 480.7 270.82 3 7.64 1 +228THS B EAV=140.4 9 +228TH G 474.79 100.023 4M1+E2 0.14 10 +228TH2 G KC=0.11 9$LC=0.025 12$MC=0.006 3$NC=0.0016 7 +228TH3 G OC=0.00038 17 +228TH G 520.160 300.070 7M1+E2 0.11 8 +228TH2 G KC=0.09 7$LC=0.019 9$MC=0.0047 21$NC=0.0013 6 +228TH3 G OC=0.00029 14 +228TH G 626.80 220.015 3 +228TH G 674.630 400.105 10M1+E2 0.06 4 +228TH2 G KC=0.05 3$LC=0.009 5$MC=0.0023 11$NC=0.0006 3 +228TH3 G OC=0.00014 7 +228TH G 698.99 100.038 6E2 0.0203 3 +228TH2 G KC=0.01448 21$LC=0.00436 7$MC=0.001103 16$NC=0.000295 5 +228TH3 G OC=6.81E-5 10 +228TH G 1247.10 5 0.524 24M1 0.0187 3 +228TH2 G KC=0.01505 21$LC=0.00274 4$MC=0.000654 10$NC=1.743E-4 25 +228TH3 G OC=4.13E-5 6 +228TH G 1315.33 100.015 3M1+E2 0.011 6 +228TH2 G KC=0.009 5$LC=0.0017 7$MC=0.00040 17$NC=0.00011 5 +228TH3 G OC=0.000025 11 +228TH L 1645.954 123+ +228TH B 477.8 274.12 20 6.94 +228THS B EAV=139.5 9 +228TH G 114.56 7 0.0102 22M1+E2 9 4 +228TH2 G KC=5 5$LC=3.2 13$MC=0.8 4$NC=0.22 10 +228TH3 G OC=0.051 22 +228TH G 419.38 7 0.022 3E1 0.0181 3 +228TH2 G KC=0.01460 21$LC=0.00263 4$MC=0.000626 9$NC=1.659E-4 24 +228TH3 G OC=3.88E-5 6 +228TH G 492.29 8 0.025 3M1+E2 0.13 9 +228TH2 G KC=0.10 8$LC=0.022 11$MC=0.0055 24$NC=0.0015 7 +228TH3 G OC=0.00034 15 +228TH G 523.129 220.129 10E1 0.0115317 +228TH2 G KC=0.00937 14$LC=0.001641 23$MC=0.000390 6$NC=1.035E-4 15 +228TH3 G OC=2.42E-5 4 +228TH G 555.07 160.048 6M1+E2 +228TH G 623.48 220.012 3M1+E2 0.07 5 +228TH2 G KC=0.06 4$LC=0.012 6$MC=0.0028 13$NC=0.0008 4 +228TH3 G OC=0.00018 9 +228TH G 629.41 5 0.047 5E2 0.0254 4 +228TH2 G KC=0.01754 25$LC=0.00584 9$MC=0.001489 21$NC=0.000398 6 +228TH3 G OC=9.17E-5 13 +228TH G 666.45 5 0.058 6M1+E2 0.06 4 +228TH2 G KC=0.05 4$LC=0.010 5$MC=0.0024 11$NC=0.0006 3 +228TH3 G OC=0.00015 7 +228TH G 677.08 100.065 6M1+E2 0.06 4 +228TH2 G KC=0.05 3$LC=0.009 5$MC=0.0023 11$NC=0.0006 3 +228TH3 G OC=0.00014 7 +228TH G 1250.06 5 0.065 6 +228TH G 1459.131 220.87 5E2 0.00498 7 +228TH2 G KC=0.00391 6$LC=0.000771 11$MC=0.000187 3$NC=4.97E-5 7 +228TH3 G OC=1.167E-5 17 +228TH G 1588.200 253.06 12E2 0.007 3 +228TH2 G KC=0.0057 23$LC=0.0010 4$MC=0.00025 10$NC=0.00007 3 +228TH3 G OC=0.000016 6 +228TH L 1682.81 3 2,3(),4+ +228TH B 441.0 271.21 4 7.35 +228THS B EAV=127.5 9 +228TH G 660.10 300.0054 3M1+E2 0.06 4 +228TH2 G KC=0.05 4$LC=0.010 5$MC=0.0024 12$NC=0.0006 3 +228TH3 G OC=0.00015 8 +228TH G 1495.904 160.92 3E2 0.00477 7 +228TH2 G KC=0.00374 6$LC=0.000732 11$MC=1.769E-4 25$NC=4.71E-5 7 +228TH3 G OC=1.107E-5 16 +228TH G 1625.090 400.270 23E2+M3 0.020 17 +228TH2 G KC=0.016 13$LC=0.003 3$MC=0.0008 7$NC=0.00022 19 +228TH3 G OC=0.00005 5 +228TH L 1683.82 5 (4)- +228TH B 440.0 270.20 3 8.13 1 +228THS B EAV=127.2 9 +228TH G 457.18 150.016 3M1+E2 0.16 11 +228TH2 G KC=0.12 10$LC=0.028 13$MC=0.007 3$NC=0.0018 8 +228TH3 G OC=0.00043 18 +228TH G 1164.55 7 0.067 7M1+E2 0.015 8 +228TH2 G KC=0.012 6$LC=0.0023 11$MC=0.00055 24$NC=0.00015 7 +228TH3 G OC=0.000034 16 +228TH G 1287.77 8 0.109 25M1+E2 0.012 6 +228TH2 G KC=0.009 5$LC=0.0018 8$MC=0.00042 18$NC=0.00011 5 +228TH3 G OC=0.000027 12 +228TH L 1688.394 112,3+ +228TH B 435.4 272.50 16 7.02 +228THS B EAV=125.7 9 +228TH G 42.46 5 0.009 3M1 46.3 7 +228TH2 G LC=35.0 5$MC=8.43 13$NC=2.25 4 +228TH3 G OC=0.533 8 +228TH G 671.95 8 0.027 8 +228TH G 813.88 100.0073 17M1+E2 0.036 22 +228TH2 G KC=0.029 18$LC=0.006 3$MC=0.0014 7$NC=0.00037 18 +228TH3 G OC=0.00009 5 +228TH G 1501.59 5 0.513 17 +228TH G 1630.618 201.52 6M1+E2 0.007 3 +228TH2 G KC=0.0053 22$LC=0.0010 4$MC=0.00023 9$NC=0.000062 24 +228TH3 G OC=0.000015 6 +228TH L 1724.283 6 2+ +228TH B 399.5 271.93 8 7.01 +228THS B EAV=114.3 9 +228TH G 497.64 100.0062 19M2 0.581 9 +228TH2 G KC=0.437 7$LC=0.1074 15$MC=0.0268 4$NC=0.00721 11 +228TH3 G OC=0.001704 24 +228TH G 548.73 110.024 4M1+E2 0.10 7 +228TH2 G KC=0.08 6$LC=0.017 8$MC=0.0041 18$NC=0.0011 5 +228TH3 G OC=0.00025 12 +228TH G 570.880 400.19 5M1 0.1472 21 +228TH2 G KC=0.1182 17$LC=0.0219 3$MC=0.00525 8$NC=0.001401 20 +228TH3 G OC=0.000332 5 +228TH G 701.742 150.181 15M1 0.0850 12 +228TH2 G KC=0.0684 10$LC=0.01261 18$MC=0.00302 5$NC=0.000805 12 +228TH3 G OC=0.000191 3 +228TH G 755.313 9 1.03 4M1 0.070 1 +228TH2 G KC=0.0563 8$LC=0.01036 15$MC=0.00248 4$NC=0.000661 10 +228TH3 G OC=1.566E-4 22 +228TH G 1537.89 100.049 6E2+M3 0.023 19 +228TH2 G KC=0.018 15$LC=0.004 4$MC=0.0010 8$NC=0.00026 22 +228TH3 G OC=0.00006 6 +228TH G 1666.514 130.173 9M1 0.0089513 +228TH2 G KC=0.00702 10$LC=0.001269 18$MC=0.000303 5$NC=8.08E-5 12 +228TH3 G OC=1.91E-5 3 +228TH G 1724.19 5 0.030 4E1+M2 +228TH L 1735.450 25(4)+ +228TH B 388.4 270.149 11 8.08 +228THS B EAV=110.7 9 +228TH G 1217.03 100.022 4 +228TH G 1357.81 150.021 5 +228TH G 1548.65 6 0.040 5 +228TH G 1677.66 6 0.057 6 +228TH L 1743.89 3 4+ +228TH B 379.9 270.378 16 7.65 +228THS B EAV=108.1 9 +228TH G 399.83 140.031 4E1 0.0200 3 +228TH2 G KC=0.01611 23$LC=0.00291 4$MC=0.000696 10$NC=0.000184 3 +228TH3 G OC=4.30E-5 6 +228TH G 1347.50 150.016 4E1+M2 0.019 17 +228TH2 G KC=0.015 14$LC=0.003 3$MC=0.0007 7$NC=0.00019 18 +228TH3 G OC=0.00004 4 +228TH G 1365.71 120.014 3E2+M3 0.03 3 +228TH2 G KC=0.025 21$LC=0.006 5$MC=0.0014 12$NC=0.0004 4 +228TH3 G OC=0.00009 8 +228TH G 1415.55 140.022 5E3 0.0114116 +228TH2 G KC=0.00849 12$LC=0.00218 3$MC=0.000543 8$NC=1.451E-4 21 +228TH3 G OC=3.39E-5 5 +228TH G 1557.13 7 0.173 9E2+M1 1.2 2 0.0070 6 +228TH2 G KC=0.0055 5$LC=0.00102 8$MC=0.000245 19$NC=0.000065 5 +228TH3 G OC=1.54E-5 12 +228TH G 1686.22 110.094 7E2 0.00391 6 +228TH2 G KC=0.00303 5$LC=0.000573 8$MC=1.378E-4 20$NC=3.67E-5 6 +228TH3 G OC=8.63E-6 12 +228TH L 1758.24 122,3,4+ +228TH B 365.6 270.060 8 8.39 +228THS B EAV=103.6 9 +228TH G 326.04 200.035 6E2 0.1315 19 +228TH2 G KC=0.0618 9$LC=0.0513 8$MC=0.01372 20$NC=0.00367 6 +228TH3 G OC=0.000831 12 +228TH G 1571.55 200.0059 17 +228TH G 1700.62 200.0105 25 +228TH L 1760.218 242,3()+ +228TH B 363.6 270.139 12 8.02 +228THS B EAV=103.0 9 +228TH G 737.74 5 0.039 5M1+E2 0.05 3 +228TH2 G KC=0.037 24$LC=0.007 4$MC=0.0018 9$NC=0.00048 23 +228TH3 G OC=0.00011 6 +228TH G 791.43 9 0.010 3M1+E2 0.039 23 +228TH2 G KC=0.031 19$LC=0.006 3$MC=0.0015 7$NC=0.00040 19 +228TH3 G OC=0.00009 5 +228TH G 1573.389 240.034 4E2 0.00438 7 +228TH2 G KC=0.00342 5$LC=0.00066 1$MC=1.592E-4 23$NC=4.24E-5 6 +228TH3 G OC=9.97E-6 14 +228TH G 1702.40 8 0.055 7E2+M3 0.018 15 +228TH2 G KC=0.014 11$LC=0.0030 25$MC=0.0007 6$NC=0.00020 16 +228TH3 G OC=0.00005 4 +228TH L 1795.9 1 3,4+ +228TH B 327.9 270.035 6 8.48 +228THS B EAV=91.9 8 +228TH G 1276.72 100.015 3 +228TH G 1738.46 5 0.018 4 +228TH L 1797.65 8 2+ +228TH B 326.2 270.051 8 8.3 +228THS B EAV=91.4 8 +228TH G 1401.52 100.013 3E1+M2 0.017 15 +228TH2 G KC=0.013 12$LC=0.0026 24$MC=0.0006 6$NC=0.00017 16 +228TH3 G OC=0.00004 4 +228TH G 1469.74 150.021 5E1+M2 0.015 14 +228TH2 G KC=0.012 11$LC=0.0023 21$MC=0.0006 5$NC=0.00015 14 +228TH3 G OC=0.00004 4 +228TH G 1740.5 3 0.011 4 +228TH G 1797.5 5 0.0022 8E1+M2 0.009 8 +228TH2 G KC=0.007 7$LC=0.0014 13$MC=0.0003 3$NC=0.00009 8 +228TH3 G OC=0.000021 19 +228TH L 1892.996 173+ +228TH B 230.8 270.109 8 7.5 +228THS B EAV=62.8 8 +228TH G 666.45 5 0.0068 7E1 0.0072211 +228TH2 G KC=0.00590 9$LC=0.001007 14$MC=0.000239 4$NC=6.33E-5 9 +228TH3 G OC=1.487E-5 21 +228TH G 870.47 7 0.046 5M1 0.0481 7 +228TH2 G KC=0.0387 6$LC=0.0071 1$MC=0.001699 24$NC=0.000453 7 +228TH3 G OC=1.073E-4 15 +228TH G 1706.17 7 0.0089 12M1+E2 0.42 40 0.0078 12 +228TH2 G KC=0.0061 10$LC=0.00110 16$MC=0.00026 4$NC=0.000070 11 +228TH3 G OC=1.65E-5 25 +228TH G 1835.29 100.038 4E2+M1 2.9 3 0.0038210 +228TH2 G KC=0.00291 8$LC=0.000536 14$MC=0.000128 4$NC=3.42E-5 9 +228TH3 G OC=8.06E-6 21 +228TH L 1899.95 4 2+ +228TH B 223.9 270.069 8 7.65 +228THS B EAV=60.8 8 +228TH G 877.38 7 0.014 3M1+E2 0.030 18 +228TH2 G KC=0.024 15$LC=0.0047 23$MC=0.0011 6$NC=0.00030 15 +228TH3 G OC=0.00007 4 +228TH G 930.99 7 0.004 1 +228TH G 1713.49 200.0057 11E2+M3 0.018 14 +228TH2 G KC=0.014 11$LC=0.0029 24$MC=0.0007 6$NC=0.00019 16 +228TH3 G OC=0.00005 4 +228TH G 1842.15 8 0.037 6M1+E2 -0.86 14 0.0055 4 +228TH2 G KC=0.00420 25$LC=0.00076 5$MC=0.000182 11$NC=0.000049 3 +228TH3 G OC=1.15E-5 7 +228TH G 1900.16 200.0030 6E1+M2 0.008 7 +228TH2 G KC=0.006 6$LC=0.0012 11$MC=0.0003 3$NC=0.00008 7 +228TH3 G OC=0.000018 16 +228TH L 1906.64 10(2)+ +228TH B 217.2 270.025 5 8.05 +228THS B EAV=58.8 8 +228TH G 490.33 150.0116 25E2 0.0447 7 +228TH2 G KC=0.0280 4$LC=0.01242 18$MC=0.00323 5$NC=0.000863 13 +228TH3 G OC=0.000198 3 +228TH G 1074.73 150.011 4 +228TH L 1928.57 6 3+ +228TH B 195.2 270.061 8 7.52 +228THS B EAV=52.5 8 +228TH G 168.53 120.0025 7M1+E2 2.7 15 +228TH2 G KC=1.8 16$LC=0.70 7$MC=0.18 3$NC=0.049 8 +228TH3 G OC=0.0112 15 +228TH G 389.32 130.0108 17M1+E2 0.25 17 +228TH2 G KC=0.19 15$LC=0.044 18$MC=0.011 4$NC=0.0029 11 +228TH3 G OC=0.0007 3 +228TH G 1742.1 3 0.0084 25M1+E2 +228TH G 1870.82 9 0.0257 24M1+E2 0.0051 18 +228TH2 G KC=0.0038 14$LC=0.00070 24$MC=0.00017 6$NC=0.000044 15 +228TH3 G OC=0.000011 4 +228TH L 1937.16 9 2,3,4+ +228TH B 186.6 270.053 6 7.52 +228THS B EAV=50.0 8 +228TH G 397.95 100.029 3 +228TH G 1062.57 150.011 4 +228TH G 1750.58 200.0084 9 +228TH G 1879.6 3 0.0013 5 +228TH L 1944.895 113+ +228TH B 178.9 270.307 22 6.7 +228THS B EAV=47.8 8 +228TH G 356.70 300.0178 21E1+M2 0.5 0.8 8 +228TH2 G KC=0.6 6$LC=0.17 17$MC=0.04 5$NC=0.011 11 +228TH3 G OC=0.003 3 +228TH G 718.300 300.019 4E1 0.00628 9 +228TH2 G KC=0.00513 8$LC=0.000870 13$MC=0.000206 3$NC=5.47E-5 8 +228TH3 G OC=1.285E-5 18 +228TH G 776.510 300.020 6 +228TH G 791.43 9 0.014 4M1 0.0618 9 +228TH2 G KC=0.0498 7$LC=0.00915 13$MC=0.00219 3$NC=0.000584 9 +228TH3 G OC=1.382E-4 20 +228TH G 853.96 8 0.0124 20M1+E2 0.032 19 +228TH2 G KC=0.025 16$LC=0.0050 25$MC=0.0012 6$NC=0.00032 16 +228TH3 G OC=0.00008 4 +228TH G 975.98 5 0.052 6M1 0.0356 5 +228TH2 G KC=0.0287 4$LC=0.00524 8$MC=0.001254 18$NC=0.000334 5 +228TH3 G OC=7.91E-5 11 +228TH G 1000.68 100.0054 3 +228TH G 1758.11 5 0.036 4E2+M1 -9.1 0.00371 6 +228TH2 G KC=0.00285 4$LC=0.000533 8$MC=1.281E-4 18$NC=3.41E-5 5 +228TH3 G OC=8.03E-6 12 +228TH G 1887.13 5 0.094 7E2+M1 0.0050 17 +228TH2 G KC=0.0038 13$LC=0.00068 23$MC=0.00016 6$NC=0.000044 15 +228TH3 G OC=0.000010 4 +228TH L 1958.72 222+ +228TH B 165.1 270.0038 8 8.5 +228THS B EAV=43.9 8 +228TH G 1772.20 300.0019 5E2+M3 0.016 13 +228TH2 G KC=0.013 10$LC=0.0027 22$MC=0.0007 6$NC=0.00017 15 +228TH3 G OC=0.00004 4 +228TH G 1958.40 300.0016 5E1+M2 +228TH L 1964.98 7 2,3,4+ +228TH B 158.8 270.0132 14 7.91 +228THS B EAV=42.2 8 +228TH G 1907.14 110.0124 13 +228TH L 1987.46 104+ +228TH B 136.3 270.07 4 7 +228THS B EAV=35.9 8 +228TH G 1017.94 200.03 3E2+M3 0.07 7 +228TH2 G KC=0.05 5$LC=0.014 12$MC=0.003 3$NC=0.0009 9 +228TH3 G OC=0.00022 20 +228TH G 1609.44 150.0081 17E2 0.00422 6 +228TH2 G KC=0.00329 5$LC=0.000630 9$MC=1.518E-4 22$NC=4.04E-5 6 +228TH3 G OC=9.51E-6 14 +228TH G 1800.90 200.0046 8 +228TH G 1929.78 200.0208 14E2+M3 0.013 10 +228TH2 G KC=0.010 8$LC=0.0021 17$MC=0.0005 5$NC=0.00014 11 +228TH3 G OC=0.00003 3 +228TH L 2010.11 5 2,3,(4)+ +228TH B 113.7 270.238 15 6.2 +228THS B EAV=29.7 8 +228TH G 372.59 3 0.0070 17E2 0.0902 13 +228TH2 G KC=0.0475 7$LC=0.0315 5$MC=0.00834 12$NC=0.00223 4 +228TH3 G OC=0.000507 8 +228TH G 887.26 100.029 3M1+E2 0.029 17 +228TH2 G KC=0.023 14$LC=0.0046 22$MC=0.0011 6$NC=0.00029 14 +228TH3 G OC=0.00007 4 +228TH G 919.03 120.028 3 +228TH G 1040.94 150.047 10E2+M3 0.07 6 +228TH2 G KC=0.05 5$LC=0.013 12$MC=0.003 3$NC=0.0009 8 +228TH3 G OC=0.00020 18 +228TH G 1823.22 100.046 5 +228TH G 1952.37 100.062 5E2+M3 0.013 10 +228TH2 G KC=0.010 8$LC=0.0020 17$MC=0.0005 4$NC=0.00013 11 +228TH3 G OC=0.00003 3 +228TH L 2013.6 3 2,3,4+ +228TH B 110.2 270.0032 10 8.03 +228THS B EAV=28.7 7 +228TH G 1826.80 300.0022 8 +228TH G 1955.9 5 0.0008 3 +228TH L 2022.84 10 +228TH B 101.0 270.061 6 6.64 +228THS B EAV=26.2 7 +228TH G 384.47 9 0.0070 17E2 0.0828 12 +228TH2 G KC=0.0447 7$LC=0.0282 4$MC=0.00745 11$NC=0.00199 3 +228TH3 G OC=0.000453 7 +228TH G 1053.11 200.014 4M1+E2 0.019 10 +228TH2 G KC=0.015 9$LC=0.0029 14$MC=0.0007 4$NC=0.00019 9 +228TH3 G OC=0.000044 21 +228TH G 1148.17 140.0062 14M1+E2 0.015 8 +228TH2 G KC=0.012 7$LC=0.0023 11$MC=0.00057 25$NC=0.00015 7 +228TH3 G OC=0.000036 16 +228TH G 1190.83 200.0065 17M1+E2 0.014 7 +228TH2 G KC=0.011 6$LC=0.0021 10$MC=0.00052 23$NC=0.00014 6 +228TH3 G OC=0.000032 15 +228TH G 1965.22 120.0223 22M1+E2 0.0046 15 +228TH2 G KC=0.0034 12$LC=0.00062 20$MC=0.00015 5$NC=0.000039 13 +228TH3 G OC=0.000009 3 +228TH L 2029.84 161,2+ +228TH B 94.0 270.026 4 6.91 2 +228THS B EAV=24.3 7 +228TH G 939.89 150.009 3 +228TH G 1013.55 130.0097 16 +228TH G 1972.00 300.0038 8 +228TH G 2029.4 5 0.0019 5E1+M2 0.007 6 +228TH2 G KC=0.005 5$LC=0.0010 9$MC=0.00024 22$NC=0.00007 6 +228TH3 G OC=0.000015 14 +228TH L 2036.99 172,3,4+ +228TH B 86.8 270.0069 11 7.38 +228THS B EAV=22.4 8 +228TH G 1850.17 200.0046 8 +228TH G 1979.30 300.0019 5 +228TH L 2123.1 3 (2)+ +228TH B 0.7 270.0047 11 3.3 +228THS B EAV=0.18 68 +228TH G 1795.13 6 0.0022 8 +228TH G 1936.30 300.0022 6 + diff --git a/HEN_HOUSE/spectra/lnhb/Ag-108.txt b/HEN_HOUSE/spectra/lnhb/Ag-108.txt index c46dd7a2d..ad6eb1756 100644 --- a/HEN_HOUSE/spectra/lnhb/Ag-108.txt +++ b/HEN_HOUSE/spectra/lnhb/Ag-108.txt @@ -1,92 +1,91 @@ -108PD 108AG EC DECAY (2.382 M) -108PD H TYP=Update$AUT=V.Chisté$CUT=25-AUG-2006$ -108PD2 H TYP=Full$AUT=V.Chisté$CUT=31-JAN-2005$ -108PD C Evaluation history: Type=Update;Author=V.Chisté;Cutoff date=25-AUG-2006 -108PD2C Type=Full;Author=V.Chisté;Cutoff date=31-JAN-2005 -108PD T Auger electrons and X ray energies and emission intensities: -108PD T {U Energy (keV)} {U Intensity} {U Line} -108PD T -108PD T 21.0203 0.44 3 XKA2 -108PD T 21.1774 0.84 6 XKA1 -108PD T -108PD T 23.7914 |] XKB3 -108PD T 23.819 |] 0.230 16 XKB1 -108PD T 24.013 |] XKB5II -108PD T -108PD T 24.2994 |] XKB2 -108PD T 24.344 |] 0.0391 30 XKB4 -108PD T -108PD T -108PD T 17.032-17.884 |] KLL AUGER -108PD T 20.032-21.176 |] 0.341 25 KLX AUGER -108PD T 23.011-24.347 |] KXY AUGER -108PD T 1.7-3.6 1.97 4 L AUGER -108AG P 0.0 1+ 2.382 M 11 1922 6 -108PD N 4.049E1 4.049E1 0.0247 4.049E1 -108PD L 0 0+ -108PD E 0.28 21.73 124.7 -108PD2 E EAV=401 3$CK=0.8644 14$CL=0.1092 10$CM=0.0221 4$CN=0.0043 2$CO=0 0 -108PD L 433.938 5 2+ 23.9 PS 7 -108PD E 0.0026 30.19 85.46 -108PD2 E EAV=212 3$CK=0.8636 14$CL=0.1098 10$CM=0.0223 4$CN=0.0043 2$CO=0 0 -108PD G 433.938 5 0.46 7[E2] 0.0090927 -108PD2 G KC=0.00784 24$LC=1021E-6 31$MC=1.92E-4 6 -108PD L 931.07 122+ 6.2 PS 4 -108PD G 497.13 120.00152 40 -108PD G 931.07 120.00048 8 -108PD L 1052.80 5 0+ 4.0 PS 4 -108PD E 0.243 394.89 -108PD2 E CK=0.8611 14$CL=0.1118 11$CM=0.0227 5$CN=0.0044 2$CO=0 0 -108PD G 618.86 5 0.245 39 -108PD L 1314.2 1 0+ -108PD E 0.0038 66.37 -108PD2 E CK=0.8585 14$CL=0.1138 11$CM=0.0232 5$CN=0.0045 2$CO=0 0 -108PD G 383.13 160.00083 30 -108PD G 880.26 100.00298 48 -108PD L 1441.16 5 2+ 4.8 PS -108PD E 0.0170 215.46 -108PD2 E CK=0.8560 14$CL=0.1157 11$CM=0.0237 5$CN=0.0046 2$CO=0 0 -108PD G 388.36 7 0.0017 6 -108PD G 1007.22 5 0.0126 20 -108PD G 1441.15 5 0.00269 44[E2] 4.64E-414 -108PD2 G KC=4.07E-4 12$LC=4.69E-5 14$MC=8.78E-6 26 -108PD L 1539.95 7 (1,2)+ -108PD E 0.00224 276.12 -108PD2 E CK=0.8529 15$CL=0.1181 11$CM=0.0242 5$CN=0.0047 3$CO=0 0 -108PD G 1106.01 7 0.00130 22 -108PD G 1539.94 7 0.00094 16 - -108CD 108AG B- DECAY (2.382 M) -108CD H TYP=Update$AUT=V.Chisté$CUT=25-AUG-2006$ -108CD2 H TYP=Full$AUT=V.Chisté$CUT=31-JAN-2005$ -108CD C Evaluation history: Type=Update;Author=V.Chisté;Cutoff date=25-AUG-2006 -108CD2C Type=Full;Author=V.Chisté;Cutoff date=31-JAN-2005 -108CD T Auger electrons and X ray energies and emission intensities: -108CD T {U Energy (keV)} {U Intensity} {U Line} -108CD T -108CD T 22.9843 0.00127 6 XKA2 -108CD T 23.1738 0.00239 11 XKA1 -108CD T -108CD T 26.0615 |] XKB3 -108CD T 26.0958 |] 0.00067 4 XKB1 -108CD T 26.304 |] XKB5II -108CD T -108CD T 26.644 |] XKB2 -108CD T 26.702 |] 0.000121 7 XKB4 -108CD T -108CD T -108CD T 18.556-19.507 |] KLL AUGER -108CD T 21.873-23.172 |] 0.00084 5 KLX AUGER -108CD T 25.171-26.707 |] KXY AUGER -108CD T 1.8-4 0.00535 7 L AUGER -108AG P 0.0 1+ 2.382 M 11 1649 8 -108CD N 1.025E0 1.025E0 0.9753 1.025E0 -108CD L 0 0+ -108CD B 1649 8 95.9 3 4.43 -108CDS B EAV=628 4 -108CD L 632.98 5 2+ 6.86 PS 7 -108CD B 1016 8 1.63 26 5.35 -108CDS B EAV=355 3 -108CD G 632.98 5 1.62 26E2 0.0034710 -108CD2 G KC=0.00300 9$LC=3.80E-4 11$MC=7.30E-5 22 - +108PD 108AG EC DECAY (2.382 M) +108PD H TYP=UPD$AUT=V.CHISTE$CUT=25-AUG-2006$ +108PD2 H TYP=FUL$AUT=V.CHISTE$CUT=31-JAN-2005$ +108PD T Auger electrons and X ray energies and emission intensities: +108PD T {U Energy (keV)} {U Intensity} {U Line} +108PD T +108PD T 21.0203 0.44 3 XKA2 +108PD T 21.1774 0.84 6 XKA1 +108PD T +108PD T 23.7914 |] XKB3 +108PD T 23.819 |] 0.230 16 XKB1 +108PD T 24.013 |] XKB5II +108PD T +108PD T 24.2994 |] XKB2 +108PD T 24.344 |] 0.0391 30 XKB4 +108PD T +108PD T +108PD T 17.032-17.884 |] KLL AUGER +108PD T 20.032-21.176 |] 0.341 25 KLX AUGER +108PD T 23.011-24.347 |] KXY AUGER +108PD T 1.7-3.6 1.97 4 L AUGER +108AG P 0.0 1+ 2.382 M 11 1922 6 +108PD N 4.049E1 4.049E1 0.0247 4.049E1 +108PD L 0 0+ +108PD E 0.28 21.73 124.7 +108PD2 E EAV=401 3$CK=0.7440 12$CL=0.0940 9$CM=0.01902 34 +108PD3 E CN=0.00370 17 +108PD L 433.938 5 2+ 23.9 PS 7 +108PD E 0.0026 30.19 85.46 +108PD2 E EAV=212 3$CK=0.8519 14$CL=0.1083 10$CM=0.02200 39 +108PD3 E CN=0.00424 20 +108PD G 433.938 5 0.46 7[E2] 0.0090927 +108PD2 G KC=0.00784 24$LC=0.001021 31$MC=0.000192 6$NC=3.19E-5 10 +108PD L 931.07 122+ 6.2 PS 4 +108PD G 497.13 120.00152 40 +108PD G 931.07 120.00048 8 +108PD L 1052.80 5 0+ 4.0 PS 4 +108PD E 0.243 394.89 +108PD2 E CK=0.8611 14$CL=0.1118 11$CM=0.0227 5$CN=0.0044 2 +108PD G 618.86 5 0.245 39 +108PD L 1314.2 1 0+ +108PD E 0.0038 66.37 +108PD2 E CK=0.8585 14$CL=0.1138 11$CM=0.0232 5$CN=0.0045 2 +108PD G 383.13 160.00083 30 +108PD G 880.26 100.00298 48 +108PD L 1441.16 5 2+ 4.8 PS +108PD E 0.0170 215.46 +108PD2 E CK=0.8560 14$CL=0.1157 11$CM=0.0237 5$CN=0.0046 2 +108PD G 388.36 7 0.0017 6 +108PD G 1007.22 5 0.0126 20 +108PD G 1441.15 5 0.00269 44[E2] 4.64E-414 +108PD2 G KC=0.000407 12$LC=4.69E-5 14$MC=8.78E-6 26$NC=1.479E-6 44 +108PD L 1539.95 7 (1,2)+ +108PD E 0.00224 276.12 +108PD2 E CK=0.8529 15$CL=0.1181 11$CM=0.0242 5$CN=0.0047 3 +108PD G 1106.01 7 0.00130 22 +108PD G 1539.94 7 0.00094 16 + +108CD 108AG B- DECAY (2.382 M) +108CD H TYP=UPD$AUT=V.CHISTE$CUT=25-AUG-2006$ +108CD2 H TYP=FUL$AUT=V.CHISTE$CUT=31-JAN-2005$ +108CD T Auger electrons and X ray energies and emission intensities: +108CD T {U Energy (keV)} {U Intensity} {U Line} +108CD T +108CD T 22.9843 0.00127 6 XKA2 +108CD T 23.1738 0.00239 11 XKA1 +108CD T +108CD T 26.0615 |] XKB3 +108CD T 26.0958 |] 0.00067 4 XKB1 +108CD T 26.304 |] XKB5II +108CD T +108CD T 26.644 |] XKB2 +108CD T 26.702 |] 0.000121 7 XKB4 +108CD T +108CD T +108CD T 18.556-19.507 |] KLL AUGER +108CD T 21.873-23.172 |] 0.00084 5 KLX AUGER +108CD T 25.171-26.707 |] KXY AUGER +108CD T 1.8-4 0.00535 7 L AUGER +108AG P 0.0 1+ 2.382 M 11 1649 8 +108CD N 1.025E0 1.025E0 0.9753 1.025E0 +108CD L 0 0+ +108CD B 1649 8 95.9 3 4.43 +108CDS B EAV=628 4 +108CD L 632.98 5 2+ 6.86 PS 7 +108CD B 1016 8 1.63 26 5.35 +108CDS B EAV=355 3 +108CD G 632.98 5 1.62 26E2 0.0034710 +108CD2 G KC=0.00300 9$LC=0.000380 11$MC=7.30E-5 22$NC=1.290E-5 39 +108CD3 G OC=6.91E-7 21 + diff --git a/HEN_HOUSE/spectra/lnhb/Ag-108m.txt b/HEN_HOUSE/spectra/lnhb/Ag-108m.txt index f07966df7..1ccdc2cfe 100644 --- a/HEN_HOUSE/spectra/lnhb/Ag-108m.txt +++ b/HEN_HOUSE/spectra/lnhb/Ag-108m.txt @@ -1,65 +1,67 @@ -108AG 108AG IT DECAY (438 Y) -108AG C References: 2004Sc04 -108AG T Auger electrons and X ray energies and emission intensities: -108AG T {U Energy (keV)} {U Intensity} {U Line} -108AG T -108AG T 21.9906 0.49 4 XKA2 -108AG T 22.16317 0.93 7 XKA1 -108AG T -108AG T 24.9118 |] XKB3 -108AG T 24.9427 |] 0.256 19 XKB1 -108AG T 25.146 |] XKB5II -108AG T -108AG T 25.4567 |] XKB2 -108AG T 25.512 |] 0.045 4 XKB4 -108AG T -108AG T -108AG T 17.79-18.69 |] KLL AUGER -108AG T 20.945-22.16 |] 0.349 27 KLX AUGER -108AG T 24.079-25.507 |] KXY AUGER -108AG T 1.9-3.8 8.60 7 L AUGER -108AG P 109.440 7 6+ 438 Y 9 -108AG N 1.099E1 1.099E1 9.100001 1.099E1 -108AG L 0 1+ 2.382 M 11 -108AG L 79.131 3 2- 1 NS -108AG G 79.131 3 6.9 5E1 0.310 9 -108AG2 G KC=0.269 8$LC=0.0336 10$MC=0.00633 19 -108AG L 109.440 7 6+ 438 Y 8 -108AG G 30.309 8 2.15E-5 18M4 4.25E5 13 -108AG2 G KC=9.77E3 29$LC=3.2E5 1$MC=8.20E4 25 - -108PD 108AG EC DECAY (438 Y) -108PD C References: 2004Sc04 -108PD T Auger electrons and X ray energies and emission intensities: -108PD T {U Energy (keV)} {U Intensity} {U Line} -108PD T -108PD T 21.0203 18.38 18 XKA2 -108PD T 21.1774 34.72 30 XKA1 -108PD T -108PD T 23.7914 |] XKB3 -108PD T 23.819 |] 9.53 12 XKB1 -108PD T 24.013 |] XKB5II -108PD T -108PD T 24.2994 |] XKB2 -108PD T 24.344 |] 1.62 6 XKB4 -108PD T -108PD T -108PD T 17.032-17.884 |] KLL AUGER -108PD T 20.032-21.176 |] 14.1 4 KLX AUGER -108PD T 23.011-24.347 |] KXY AUGER -108PD T 1.7-3.6 83.1 4 L AUGER -108AG P 109.440 7 6+ 438 Y 9 1922 6 -108PD N 1.10E0 1.10E0 0.909 1.10E0 -108PD L 0 0+ -108PD L 433.938 5 2+ -108PD G 433.938 5 90.1 6[E2] 0.0090927 -108PD2 G KC=0.00784 24$LC=1021E-6 31$MC=1.92E-4 6 -108PD L 1048.25 5 4+ -108PD G 614.276 4 90.5 16E2 0.0033510 -108PD2 G KC=0.00291 9$LC=3.60E-4 11$MC=6.77E-5 20 -108PD L 1771.162 116+ -108PD E 90.9 69.24 -108PD2 E CK=0.8457 15$CL=0.1238 12$CM=0.0256 5$CN=0.0050 3$CO=0 0 -108PD G 722.907 1090.8 16E2 0.00219 7 -108PD2 G KC=0.00191 6$LC=2.31E-4 7$MC=4.34E-5 13 - +108AG 108AG IT DECAY (438 Y) +108AG C References:2004Sc04 +108AG T Auger electrons and X ray energies and emission intensities: +108AG T {U Energy (keV)} {U Intensity} {U Line} +108AG T +108AG T 21.9906 0.49 4 XKA2 +108AG T 22.16317 0.93 7 XKA1 +108AG T +108AG T 24.9118 |] XKB3 +108AG T 24.9427 |] 0.256 19 XKB1 +108AG T 25.146 |] XKB5II +108AG T +108AG T 25.4567 |] XKB2 +108AG T 25.512 |] 0.045 4 XKB4 +108AG T +108AG T +108AG T 17.79-18.69 |] KLL AUGER +108AG T 20.945-22.16 |] 0.349 27 KLX AUGER +108AG T 24.079-25.507 |] KXY AUGER +108AG T 1.9-3.8 8.60 7 L AUGER +108AG P 109.440 7 6+ 438 Y 9 +108AG N 1.099E1 1.099E1 91000E-6 +108AG L 0 1+ 2.382 M 11 +108AG L 79.131 3 2- 1 NS +108AG G 79.131 3 6.9 5E1 0.310 9 +108AG2 G KC=0.269 8$LC=0.0336 10$MC=0.00633 19$NC=0.001069 32 +108AG3 G OC=4.14E-5 12 +108AG L 109.440 7 6+ 438 Y 8 +108AG G 30.309 8 2.15E-5 18M4 4.25E5 13 +108AG2 G KC=9.77E3 29$LC=3.2E5 1$MC=8.20E4 25$NC=1.316E4 39 +108AG3 G OC=121.7 37 + +108PD 108AG EC DECAY (438 Y) +108PD C References:2004Sc04 +108PD T Auger electrons and X ray energies and emission intensities: +108PD T {U Energy (keV)} {U Intensity} {U Line} +108PD T +108PD T 21.0203 18.38 18 XKA2 +108PD T 21.1774 34.72 30 XKA1 +108PD T +108PD T 23.7914 |] XKB3 +108PD T 23.819 |] 9.53 12 XKB1 +108PD T 24.013 |] XKB5II +108PD T +108PD T 24.2994 |] XKB2 +108PD T 24.344 |] 1.62 6 XKB4 +108PD T +108PD T +108PD T 17.032-17.884 |] KLL AUGER +108PD T 20.032-21.176 |] 14.1 4 KLX AUGER +108PD T 23.011-24.347 |] KXY AUGER +108PD T 1.7-3.6 83.1 4 L AUGER +108AG P 109.440 7 6+ 438 Y 9 1922 6 +108PD N 1.10E0 1.10E0 0.909 1.10E0 +108PD L 0 0+ +108PD L 433.938 5 2+ +108PD G 433.938 5 90.1 6[E2] 0.0090927 +108PD2 G KC=0.00784 24$LC=0.001021 31$MC=0.000192 6$NC=3.19E-5 10 +108PD L 1048.25 5 4+ +108PD G 614.276 4 90.5 16E2 0.0033510 +108PD2 G KC=0.00291 9$LC=0.000360 11$MC=6.77E-5 20$NC=1.130E-5 34 +108PD L 1771.162 116+ +108PD E 90.9 69.24 +108PD2 E CK=0.8457 15$CL=0.1238 12$CM=0.0256 5$CN=0.0050 3 +108PD G 722.907 1090.8 16E2 0.00219 7 +108PD2 G KC=0.00191 6$LC=0.000231 7$MC=4.34E-5 13$NC=7.27E-6 22 + diff --git a/HEN_HOUSE/spectra/lnhb/Ag-110.txt b/HEN_HOUSE/spectra/lnhb/Ag-110.txt index c0e8e94d0..2be4359f1 100644 --- a/HEN_HOUSE/spectra/lnhb/Ag-110.txt +++ b/HEN_HOUSE/spectra/lnhb/Ag-110.txt @@ -1,92 +1,92 @@ -110PD 110AG EC DECAY (24.56 S) -110PD T Auger electrons and X ray energies and emission intensities: -110PD T {U Energy (keV)} {U Intensity} {U Line} -110PD T -110PD T 21.0203 0.060 12 XKA2 -110PD T 21.1774 0.114 23 XKA1 -110PD T -110PD T 23.7914 |] XKB3 -110PD T 23.819 |] 0.032 7 XKB1 -110PD T 24.013 |] XKB5II -110PD T -110PD T 24.2994 |] XKB2 -110PD T 24.344 |] 0.0054 10 XKB4 -110PD T -110AG P 0.0 1+ 24.56 S 11 892 11 -110PD N 3.333E2 3.333E2 0.003 3.333E2 -110PD L 0 - STABLE -110PD E 0.30 64.1 -110PD2 E CK=0.862 $CL=0.111 $CM=0.027 - -110CD 110AG B- DECAY (24.56 S) -110CD T Auger electrons and X ray energies and emission intensities: -110CD T {U Energy (keV)} {U Intensity} {U Line} -110CD T -110CD T 22.9843 0.0032 3 XKA2 -110CD T 23.1738 0.0061 6 XKA1 -110CD T -110CD T 26.0615 |] XKB3 -110CD T 26.0958 |] 0.00169 15 XKB1 -110CD T 26.304 |] XKB5I -110CD T -110CD T 26.644 |] XKB2 -110CD T 26.702 |] 0.00031 3 XKB4 -110CD T -110AG P 0.0 1+ 24.56 S 11 2892.2 16 -110CD N 1.003E0 1.003E0 0.997 1.003E0 -110CD L 0 0+ STABLE -110CD B 2892.2 1695.2 4 4.66 -110CDS B EAV=1199.0 8 -110CD L 657.7622 112+ 5.39 PS 7 -110CD B 2234.4 164.4 4 5.53 -110CDS B EAV=893.8 8 -110CD G 657.7600 114.6 4E2 0.00318 9 -110CD2 G KC=0.00272 8$LC=0.00034 1 -110CD L 1473.27 200+ -110CD B 1419.2 170.038 3 6.81 -110CDS B EAV=527.1 7 -110CD G 815.50 2 0.039 4E2 0.00185 6 -110CD2 G KC=0.00159 5$LC=0.00019 1 -110CD L 1475.7894 162+ 0.68 PS 10 -110CD B 1416.5 160.0099 10 7.39 -110CDS B EAV=526.0 7 -110CD G 818.0244 180.0092 9M1+E2 -1.36 7 0.00194 6 -110CD2 G KC=0.00167 5$LC=0.00020 1 -110CD G 1475.7792 230.0037 6E2 0.0051 2 -110CD2 G KC=0.0044 1$LC=0.00007 -110CD L 1731.77 200+ -110CD B 1160.7 170.0009 5 8.1 -110CDS B EAV=415.9 7 -110CD G 1074.0 2 0.0009 5E2 0.0098 3 -110CD2 G KC=0.0085 3$LC=0.00010 1 -110CD L 1783.469 172+ -110CD B 1108.8 170.0121 17 6.89 -110CDS B EAV=394.1 7 -110CD G 1125.699 200.0156 14M1+E2 0.33 8 0.00105 3 -110CD2 G KC=0.00089 30$LC=0.00010 1 -110CD G 1783.46 3 0.0046 8E2 -110CD L 2078.77 200+ -110CD B 813.6 170.0076 14 6.6 -110CDS B EAV=273.3 7 -110CD G 295.3 2 0.0078 16(E1) 0.0080524 -110CD2 G KC=0.00703 21$LC=0.00083 3$MC=0.00016 1 -110CD L 2079.27 203-+ 0.72 PS 30 -110CD B 813.3 170.0022 5 7.54 2 -110CDS B EAV=290.7 7 -110CD G 1421.5 2 0.0023 5 0.0026 1 -110CD2 G KC=0.0023 1$LC=0.00003 1 -110CD L 2287.68 202+ -110CD B 604.8 170.0022 5 6.68 -110CDS B EAV=192.8 6 -110CD G 1629.9 2 0.0023 5E2(+M1) 0.06 3 -110CD L 2332.08 200+ -110CD B 560.4 170.0072 5 6.05 -110CDS B EAV=176.4 6 -110CD G 1674.3 2 0.007 1 -110CD L 2662.14 150+ -110CD B 230.1 160.0063 8 4.83 -110CDS B EAV=64.2 5 -110CD G 1186.3 2 0.0028 5[E2] 0.0079 2 -110CD2 G KC=0.0069 2$LC=0.00009 1 -110CD G 2004.40 2 0.0037 6E2 - +110PD 110AG EC DECAY (24.56 S) +110PD T Auger electrons and X ray energies and emission intensities: +110PD T {U Energy (keV)} {U Intensity} {U Line} +110PD T +110PD T 21.0203 0.060 12 XKA2 +110PD T 21.1774 0.114 23 XKA1 +110PD T +110PD T 23.7914 |] XKB3 +110PD T 23.819 |] 0.032 7 XKB1 +110PD T 24.013 |] XKB5II +110PD T +110PD T 24.2994 |] XKB2 +110PD T 24.344 |] 0.0054 10 XKB4 +110PD T +110AG P 0.0 1+ 24.56 S 11 892 11 +110PD N 3.333E2 3.333E2 0.003 3.333E2 +110PD L 0 STABLE +110PD E 0.30 64.1 +110PD2 E CK=0.862 $CL=0.111 $CM=0.027 + +110CD 110AG B- DECAY (24.56 S) +110CD T Auger electrons and X ray energies and emission intensities: +110CD T {U Energy (keV)} {U Intensity} {U Line} +110CD T +110CD T 22.9843 0.0032 3 XKA2 +110CD T 23.1738 0.0061 6 XKA1 +110CD T +110CD T 26.0615 |] XKB3 +110CD T 26.0958 |] 0.00169 15 XKB1 +110CD T 26.304 |] XKB5I +110CD T +110CD T 26.644 |] XKB2 +110CD T 26.702 |] 0.00031 3 XKB4 +110CD T +110AG P 0.0 1+ 24.56 S 11 2892.2 16 +110CD N 1.003E0 1.003E0 0.997 1.003E0 +110CD L 0 0+ STABLE +110CD B 2892.2 1695.2 4 4.66 +110CDS B EAV=1199.0 8 +110CD L 657.7622 112+ 5.39 PS 7 +110CD B 2234.4 164.4 4 5.53 +110CDS B EAV=893.8 8 +110CD G 657.7600 114.6 4E2 0.00318 9 +110CD2 G KC=0.00272 8$LC=0.00034 1 +110CD L 1473.27 200+ +110CD B 1419.2 170.038 3 6.81 +110CDS B EAV=527.1 7 +110CD G 815.50 2 0.039 4E2 0.00185 6 +110CD2 G KC=0.00159 5$LC=0.00019 1 +110CD L 1475.7894 162+ 0.68 PS 10 +110CD B 1416.5 160.0099 10 7.39 +110CDS B EAV=526.0 7 +110CD G 818.0244 180.0092 9M1+E2 -1.36 7 0.00194 6 +110CD2 G KC=0.00167 5$LC=0.00020 1 +110CD G 1475.7792 230.0037 6E2 0.0051 2 +110CD2 G KC=0.0044 1$LC=0.00007 +110CD L 1731.77 200+ +110CD B 1160.7 170.0009 5 8.1 +110CDS B EAV=415.9 7 +110CD G 1074.0 2 0.0009 5E2 0.0098 3 +110CD2 G KC=0.0085 3$LC=0.00010 1 +110CD L 1783.469 172+ +110CD B 1108.8 170.0121 17 6.89 +110CDS B EAV=394.1 7 +110CD G 1125.699 200.0156 14M1+E2 0.33 8 0.00105 3 +110CD2 G KC=0.00089 30$LC=0.00010 1 +110CD G 1783.46 3 0.0046 8E2 +110CD L 2078.77 200+ +110CD B 813.6 170.0076 14 6.6 +110CDS B EAV=273.3 7 +110CD G 295.3 2 0.0078 16(E1) 0.0080524 +110CD2 G KC=0.00703 21$LC=0.00083 3$MC=0.00016 1 +110CD L 2079.27 203- 0.72 PS 30 +110CD B 813.3 170.0022 5 7.54 2 +110CDS B EAV=290.7 7 +110CD G 1421.5 2 0.0023 5 0.0026 1 +110CD2 G KC=0.0023 1$LC=0.00003 1 +110CD L 2287.68 202+ +110CD B 604.8 170.0022 5 6.68 +110CDS B EAV=192.8 6 +110CD G 1629.9 2 0.0023 5E2(+M1) 0.06 3 +110CD L 2332.08 200+ +110CD B 560.4 170.0072 5 6.05 +110CDS B EAV=176.4 6 +110CD G 1674.3 2 0.007 1 +110CD L 2662.14 150+ +110CD B 230.1 160.0063 8 4.83 +110CDS B EAV=64.2 5 +110CD G 1186.3 2 0.0028 5[E2] 0.0079 2 +110CD2 G KC=0.0069 2$LC=0.00009 1 +110CD G 2004.40 2 0.0037 6E2 + diff --git a/HEN_HOUSE/spectra/lnhb/Ag-110m.txt b/HEN_HOUSE/spectra/lnhb/Ag-110m.txt index afb21ca46..65c2c7555 100644 --- a/HEN_HOUSE/spectra/lnhb/Ag-110m.txt +++ b/HEN_HOUSE/spectra/lnhb/Ag-110m.txt @@ -1,183 +1,181 @@ -110AG 110AG IT DECAY (249.78 D) -110AG T Auger electrons and X ray energies and emission intensities: -110AG T {U Energy (keV)} {U Intensity} {U Line} -110AG T -110AG T 21.9906 0.198 12 XKA2 -110AG T 22.16317 0.372 22 XKA1 -110AG T -110AG T 24.9118 |] XKB3 -110AG T 24.9427 |] 0.103 7 XKB1 -110AG T 25.146 |] XKB5II -110AG T -110AG T 25.4567 |] XKB2 -110AG T 25.512 |] 0.0179 12 XKB4 -110AG T -110AG P 117.59 5 6+ 249.78 D 2 -110AG N 7.353E1 7.353E1 0.0136 7.353E1 -110AG G 264.25 6 0.0060 6 -110AG G 356.43 100.00425 30 -110AG G 647.8 4 0.018 5 -110AG G 666.6 5 0.028 14 -110AG G 676.58 100.14 1 -110AG G 1050.5 5 0.0076 10 -110AG G 1465.6 1 0.0018 2 -110AG G 1572.4 2 0.0011 3 -110AG L 0 0+ 24.56 S 11 -110AG L 1.113 2- 660 NS 40 -110AG G 1.113 E1 -110AG L 117.59 5 6+ 249.78 D 2 -110AG G 116.48 5 0.0080 3M4 168 5 -110AG2 G KC=105 3$LC=50.1 15$MC=11 - -110CD 110AG B- DECAY (249.78 D) -110CD T Auger electrons and X ray energies and emission intensities: -110CD T {U Energy (keV)} {U Intensity} {U Line} -110CD T -110CD T 22.9843 0.153 9 XKA2 -110CD T 23.1738 0.288 16 XKA1 -110CD T -110CD T 26.0615 |] XKB3 -110CD T 26.0958 |] 0.080 5 XKB1 -110CD T 26.304 |] XKB5II -110CD T -110CD T 26.644 |] XKB2 -110CD T 26.702 |] 0.0146 9 XKB4 -110CD T -110AG P 117.59 5 6+ 249.78 D 2 2892.2 16 -110CD N 1.014E0 1.014E0 0.9864 1.014E0 -110CD G 264.25 6 0.0060 6 -110CD G 356.43 100.00425 30 -110CD G 647.8 4 0.018 5 -110CD G 666.6 5 0.028 14 -110CD G 676.58 100.14 1 -110CD G 1050.5 5 0.0076 10 -110CD G 1465.6 1 0.0018 2 -110CD G 1572.4 2 0.0011 3 -110CD L 0 0+ STABLE -110CD L 657.7621 112+ 5.39 PS 7 -110CD G 657.7600 1194.38 8E2 0.00318 9 -110CD2 G KC=0.00272 8$LC=0.00034 1 -110CD L 1475.7898 232+ 0.68 PS 10 -110CD G 818.0244 187.33 4M1+E2 -1.36 7 0.00194 6 -110CD2 G KC=0.00167 5$LC=0.00020 1 -110CD G 1475.7792 234.03 5E2 0.00051 2 -110CD2 G KC=0.00044 1 -110CD L 1542.4440 174+ 0.73 PS 9 -110CD G 884.6781 1374.0 12E2 0.00152 5 -110CD2 G KC=0.00131 4$LC=0.00016 1 -110CD L 1783.46 3 2+ -110CD G 1125.699 200.0304 14M1+E2 0.33 8 0.00103 3 -110CD2 G KC=0.00089 30$LC=0.00010 1 -110CD G 1783.46 3 0.0101 5E2 -110CD L 2078.69 7 3- 0.72 PS 30 -110CD G 603.08 100.011 8E1 0.0013940 -110CD2 G KC=0.00121 4$LC=0.00014 10 -110CD G 1420.07 5 0.026 4E1 0.00026 1 -110CD2 G KC=0.00023 1 -110CD L 2162.8012 253+ -110CD G 620.3553 172.72 8M1+E2 -0.50 4 0.0039712 -110CD2 G KC=0.00342 10$LC=0.00041 1 -110CD G 687.0091 186.45 3M1+E2 -1.76 6 0.00292 9 -110CD2 G KC=0.00251 8$LC=0.00031 1 -110CD G 1505.028 2 13.16 16M1+E2 -1.21 4 0.00045 1 -110CD2 G KC=0.00045 1 -110CD L 2220.0680 264+ -110CD G 677.6217 1210.56 6M1+E2 0.36 2 0.0032410 -110CD2 G KC=0.00280 8$LC=0.00033 1 -110CD G 744.2755 184.71 3E2(+M3) 0 0.00232 7 -110CD2 G KC=0.00199 6$LC=0.00025 1 -110CD G 1562.2940 181.21 3E2(+M3) -0.10 15 -110CD L 2250.547 134+ -110CD B 759.3 160.06 5 11.5 2 -110CDS B EAV=251.9 7 -110CD G 467.03 4 0.0249 19(E2) 0.0081324 -110CD2 G KC=0.00699 21$LC=0.00092 3$MC=0.00018 1 -110CD G 708.128 200.23 5M1+E2 -0.15 9 0.00295 9 -110CD2 G KC=0.00255 8$LC=0.00030 1 -110CD G 774.7 1 0.006 3(E2) 0.00210 6 -110CD2 G KC=0.00180 5$LC=0.00022 1 -110CD G 1592.80 150.0207 8(E2) -110CD L 2287.53 15 + -110CD G 1629.75 150.0040 5M1+E2 0.06 3 -110CD L 2356.6 2 1+,2++ -110CD G 1698.8 2 0.0017 3 -110CD L 2433.20 4 3+ -110CD G 957.35 100.0093 19M1+E2 -0.9 7 0.0013910 -110CD2 G KC=0.00120 9$LC=0.00014 1 -110CD G 1775.41 4 0.0065 3M1+E2 -110CD L 2479.933 4 6+ -110CD B 529.9 1630.8 3 8.28 -110CDS B EAV=165.3 6 -110CD G 229.423 230.0119 14 -110CD G 937.485 3 34.51 27E2(+M3) -0.07 0.00133 4 -110CD2 G KC=0.00115 3$LC=0.00014 1 -110CD L 2539.675 8 5- 0.62 PS 28 -110CD B 470.1 160.060 4 10.8 1 -110CDS B EAV=143.9 6 -110CD G 997.243 150.128 4E1(+M2) -0.30 46 0.0007 9 -110CD L 2561.281 8 4+ -110CD G 341.3 2 0.0022 5 -110CD G 1018.95 8 0.0141 7M1+E2 -0.56 35 -110CD G 1085.447 140.072 4E2 0.00096 3 -110CD2 G KC=0.00083 3$LC=0.00010 1 -110CD G 1903.52 4 0.0159 7 -110CD L 2659.852 115- -110CD B 349.9 160.031 4 10.7 1 -110CDS B EAV=102.6 6 -110CD G 120.23 3 0.0169 9M1(+E2) -0.13 33 0.29 8 -110CD2 G KC=0.25 6$LC=0.032 18$MC=0.006 4 -110CD G 409.4 5 0.0063 E1(+M2) -0.029 23 0.0034610 -110CD2 G KC=0.00303 9$LC=0.00036 1 -110CD G 1117.46 3 0.0488 9E1(+M2) 0.021 44 0.00040 1 -110CD2 G KC=0.00034 1 -110CD L 2662.41 103+ -110CD G 1186.7 1 0.00160 5 -110CD G 2004.65 100.0012 4 -110CD L 2705.668 104+ -110CD G 1163.14 8 0.074 24M1+E2 0.03 0.00097 3 -110CD2 G KC=0.00084 3$LC=9.8E-5 3 -110CD L 2707.397 8 4+ -110CD G 544.55 5 0.018 3M1+E2 0.0054 2 -110CD2 G KC=0.00464 19$LC=0.00057 2 -110CD G 1164.94 9 0.043 3M1+E2 0.0 3 0.00090 3 -110CD2 G KC=0.00077 7 -110CD L 2793.417 7 4+ -110CD G 360.23 8 0.008 5 -110CD G 572.8 2 0.0173 13 -110CD G 630.62 6 0.033 5 -110CD G 714.9 1 0.0092 24 -110CD G 1251.04 4 0.026 3 -110CD L 2842.51 105- -110CD B 167.3 160.0252 10 9.7 1 -110CDS B EAV=45.4 5 -110CD G 409.4 5 0.0063 E1(+M2) -0.029 23 0.0034610 -110CD2 G KC=0.00303 9$LC=0.00036 1 -110CD G 1300.05 100.0189 7E1(+M2) 0.0 1 0.00030 1 -110CD2 G KC=0.00026 1 -110CD L 2876.803 126+ -110CD B 133.0 160.392 18 8.2 -110CDS B EAV=35.5 5 -110CD G 396.895 230.037 4 -110CD G 626.258 100.214 17E2 0.0036111 -110CD2 G KC=0.00309 9$LC=0.00039 1 -110CD G 1334.326 170.141 5E2 0.00062 2 -110CD2 G KC=0.00054 2 -110CD L 2926.746 3 5+ -110CD B 83.1 1667.5 6 5.36 -110CDS B EAV=21.6 5 -110CD G 133.333 7 0.0736 16 -110CD G 219.348 8 0.072 5 -110CD G 221.079 100.068 10 -110CD G 266.913 120.041 4 -110CD G 365.448 100.092 5 -110CD G 387.073 9 0.0518 9 -110CD G 446.812 3 3.65 5M1+E2 -0.38 2 0.0089 3 -110CD2 G KC=0.00772 23$LC=0.00094 3$MC=0.00018 1 -110CD G 493.43 100.0095 11 -110CD G 706.6760 1516.48 8M1+E2 -1.42 7 0.00275 8 -110CD2 G KC=0.00237 7$LC=0.00029 1 -110CD G 763.9424 1722.31 9E2+M3 -0.10 15 0.00230 9 -110CD2 G KC=0.00198 10$LC=0.00024 2 -110CD G 1384.2931 2024.7 5M1+E2 -0.44 2 0.00065 2 -110CD2 G KC=0.00056 2 - +110AG 110AG IT DECAY (249.78 D) +110AG T Auger electrons and X ray energies and emission intensities: +110AG T {U Energy (keV)} {U Intensity} {U Line} +110AG T +110AG T 21.9906 0.198 12 XKA2 +110AG T 22.16317 0.372 22 XKA1 +110AG T +110AG T 24.9118 |] XKB3 +110AG T 24.9427 |] 0.103 7 XKB1 +110AG T 25.146 |] XKB5II +110AG T +110AG T 25.4567 |] XKB2 +110AG T 25.512 |] 0.0179 12 XKB4 +110AG T +110AG P 117.59 5 6+ 249.78 D 2 +110AG N 7.353E1 7.353E1 0.0136 +110AG L 0 0+ 24.56 S 11 +110AG L 1.113 2- 660 NS 40 +110AG G 1.113 E1 +110AG L 117.59 5 6+ 249.78 D 2 +110AG G 116.48 5 0.0080 3M4 168 5 +110AG2 G KC=105 3$LC=50.1 15$MC=11 + +110CD 110AG B- DECAY (249.78 D) +110CD T Auger electrons and X ray energies and emission intensities: +110CD T {U Energy (keV)} {U Intensity} {U Line} +110CD T +110CD T 22.9843 0.153 9 XKA2 +110CD T 23.1738 0.288 16 XKA1 +110CD T +110CD T 26.0615 |] XKB3 +110CD T 26.0958 |] 0.080 5 XKB1 +110CD T 26.304 |] XKB5II +110CD T +110CD T 26.644 |] XKB2 +110CD T 26.702 |] 0.0146 9 XKB4 +110CD T +110AG P 117.59 5 6+ 249.78 D 2 2892.2 16 +110CD N 1.014E0 1.014E0 0.9864 1.014E0 +110CD G 264.25 6 0.0060 6 +110CD G 356.43 100.00425 30 +110CD G 647.8 4 0.018 5 +110CD G 666.6 5 0.028 14 +110CD G 676.58 100.14 1 +110CD G 1050.5 5 0.0076 10 +110CD G 1465.6 1 0.0018 2 +110CD G 1572.4 2 0.0011 3 +110CD L 0 0+ STABLE +110CD L 657.7621 112+ 5.39 PS 7 +110CD G 657.7600 1194.38 8E2 0.00318 9 +110CD2 G KC=0.00272 8$LC=0.00034 1 +110CD L 1475.7898 232+ 0.68 PS 10 +110CD G 818.0244 187.33 4M1+E2 -1.36 7 0.00194 6 +110CD2 G KC=0.00167 5$LC=0.00020 1 +110CD G 1475.7792 234.03 5E2 0.00051 2 +110CD2 G KC=0.00044 1 +110CD3 G IPC=0.000067 +110CD L 1542.4440 174+ 0.73 PS 9 +110CD G 884.6781 1374.0 12E2 0.00152 5 +110CD2 G KC=0.00131 4$LC=0.00016 1 +110CD L 1783.46 3 2+ +110CD G 1125.699 200.0304 14M1+E2 0.33 8 0.00103 3 +110CD2 G KC=0.00089 30$LC=0.00010 1 +110CD G 1783.46 3 0.0101 5E2 +110CD L 2078.69 7 3- 0.72 PS 30 +110CD G 603.08 100.011 8E1 0.0013940 +110CD2 G KC=0.00121 4$LC=0.00014 10 +110CD G 1420.07 5 0.026 4E1 0.00026 1 +110CD2 G KC=0.00023 1 +110CD3 G IPC=0.00017 +110CD L 2162.8012 253+ +110CD G 620.3553 172.72 8M1+E2 -0.50 4 0.0039712 +110CD2 G KC=0.00342 10$LC=0.00041 1 +110CD G 687.0091 186.45 3M1+E2 -1.76 6 0.00292 9 +110CD2 G KC=0.00251 8$LC=0.00031 1 +110CD G 1505.028 2 13.16 16M1+E2 -1.21 4 0.00045 1 +110CD2 G KC=0.00045 1 +110CD3 G IPC=0.000076 +110CD L 2220.0680 264+ +110CD G 677.6217 1210.56 6M1+E2 0.36 2 0.0032410 +110CD2 G KC=0.00280 8$LC=0.00033 1 +110CD G 744.2755 184.71 3E2(+M3) 0 0.00232 7 +110CD2 G KC=0.00199 6$LC=0.00025 1 +110CD G 1562.2940 181.21 3E2(+M3) -0.10 15 +110CD L 2250.547 134+ +110CD B 759.3 160.06 5 11.5 2 +110CDS B EAV=251.9 7 +110CD G 467.03 4 0.0249 19(E2) 0.0081324 +110CD2 G KC=0.00699 21$LC=0.00092 3$MC=0.00018 1 +110CD G 708.128 200.23 5M1+E2 -0.15 9 0.00295 9 +110CD2 G KC=0.00255 8$LC=0.00030 1 +110CD G 774.7 1 0.006 3(E2) 0.00210 6 +110CD2 G KC=0.00180 5$LC=0.00022 1 +110CD G 1592.80 150.0207 8(E2) +110CD L 2287.53 15 +110CD G 1629.75 150.0040 5M1+E2 0.06 3 +110CD L 2356.6 2 1+,2+ +110CD G 1698.8 2 0.0017 3 +110CD L 2433.20 4 3+ +110CD G 957.35 100.0093 19M1+E2 -0.9 7 0.0013910 +110CD2 G KC=0.00120 9$LC=0.00014 1 +110CD G 1775.41 4 0.0065 3M1+E2 +110CD L 2479.933 4 6+ +110CD B 529.9 1630.8 3 8.28 +110CDS B EAV=165.3 6 +110CD G 229.423 230.0119 14 +110CD G 937.485 3 34.51 27E2(+M3) -0.07 0.00133 4 +110CD2 G KC=0.00115 3$LC=0.00014 1 +110CD L 2539.675 8 5- 0.62 PS 28 +110CD B 470.1 160.060 4 10.8 1 +110CDS B EAV=143.9 6 +110CD G 997.243 150.128 4E1(+M2) -0.30 46 0.0007 9 +110CD L 2561.281 8 4+ +110CD G 341.3 2 0.0022 5 +110CD G 1018.95 8 0.0141 7M1+E2 -0.56 35 +110CD G 1085.447 140.072 4E2 0.00096 3 +110CD2 G KC=0.00083 3$LC=0.00010 1 +110CD G 1903.52 4 0.0159 7 +110CD L 2659.852 115- +110CD B 349.9 160.031 4 10.7 1 +110CDS B EAV=102.6 6 +110CD G 120.23 3 0.0169 9M1(+E2) -0.13 33 0.29 8 +110CD2 G KC=0.25 6$LC=0.032 18$MC=0.006 4 +110CD G 409.4 5 0.0063 E1(+M2) -0.029 23 0.0034610 +110CD2 G KC=0.00303 9$LC=0.00036 1 +110CD G 1117.46 3 0.0488 9E1(+M2) 0.021 44 0.00040 1 +110CD2 G KC=0.00034 1 +110CD L 2662.41 103+ +110CD G 1186.7 1 0.00160 5 +110CD G 2004.65 100.0012 4 +110CD L 2705.668 104+ +110CD G 1163.14 8 0.074 24M1+E2 0.03 0.00097 3 +110CD2 G KC=0.00084 3$LC=0.000098 3 +110CD L 2707.397 8 4+ +110CD G 544.55 5 0.018 3M1+E2 0.0054 2 +110CD2 G KC=0.00464 19$LC=0.00057 2 +110CD G 1164.94 9 0.043 3M1+E2 0.0 3 0.00090 3 +110CD2 G KC=0.00077 7 +110CD L 2793.417 7 4+ +110CD G 360.23 8 0.008 5 +110CD G 572.8 2 0.0173 13 +110CD G 630.62 6 0.033 5 +110CD G 714.9 1 0.0092 24 +110CD G 1251.04 4 0.026 3 +110CD L 2842.51 105- +110CD B 167.3 160.0252 10 9.7 1 +110CDS B EAV=45.4 5 +110CD G 409.4 5 0.0063 E1(+M2) -0.029 23 0.0034610 +110CD2 G KC=0.00303 9$LC=0.00036 1 +110CD G 1300.05 100.0189 7E1(+M2) 0.0 1 0.00030 1 +110CD2 G KC=0.00026 1 +110CD3 G IPC=0.000019 +110CD L 2876.803 126+ +110CD B 133.0 160.392 18 8.2 +110CDS B EAV=35.5 5 +110CD G 396.895 230.037 4 +110CD G 626.258 100.214 17E2 0.0036111 +110CD2 G KC=0.00309 9$LC=0.00039 1 +110CD G 1334.326 170.141 5E2 0.00062 2 +110CD2 G KC=0.00054 2 +110CD3 G IPC=0.000029 +110CD L 2926.746 3 5+ +110CD B 83.1 1667.5 6 5.36 +110CDS B EAV=21.6 5 +110CD G 133.333 7 0.0736 16 +110CD G 219.348 8 0.072 5 +110CD G 221.079 100.068 10 +110CD G 266.913 120.041 4 +110CD G 365.448 100.092 5 +110CD G 387.073 9 0.0518 9 +110CD G 446.812 3 3.65 5M1+E2 -0.38 2 0.0089 3 +110CD2 G KC=0.00772 23$LC=0.00094 3$MC=0.00018 1 +110CD G 493.43 100.0095 11 +110CD G 706.6760 1516.48 8M1+E2 -1.42 7 0.00275 8 +110CD2 G KC=0.00237 7$LC=0.00029 1 +110CD G 763.9424 1722.31 9E2+M3 -0.10 15 0.00230 9 +110CD2 G KC=0.00198 10$LC=0.00024 2 +110CD G 1384.2931 2024.7 5M1+E2 -0.44 2 0.00065 2 +110CD2 G KC=0.00056 2 +110CD3 G IPC=0.000039 + diff --git a/HEN_HOUSE/spectra/lnhb/Al-26.txt b/HEN_HOUSE/spectra/lnhb/Al-26.txt index bd84e3381..841efcd02 100644 --- a/HEN_HOUSE/spectra/lnhb/Al-26.txt +++ b/HEN_HOUSE/spectra/lnhb/Al-26.txt @@ -1,30 +1,30 @@ - 26MG 26AL EC DECAY (717E3 Y) - 26MG T Auger electrons and X ray energies and emission intensities: - 26MG T {U Energy (keV)} {U Intensity} {U Line} - 26MG T - 26MG T 1.2536 0.160 6 XKA2 - 26MG T 1.2536 0.318 11 XKA1 - 26MG T - 26MG T - 26MG T - 26MG T - 26MG T 1.102-1.182 |] KLL AUGER - 26MG T 1.214-1.252 |] 16.22 22 KLX AUGER - 26MG T 1.301-1.301 |] KXY AUGER - 26MG T 0.0359-0.0359 2.2E-6 18 L AUGER - 26AL P 0.0 5+ 717E3 Y 24 4004.19 6 - 26MG N 1.0 1.0 1 1.0 - 26MG L 0 0+ STABLE - 26MG L 1808.72 7 2+ 476 FS 12 - 26MG E 81.73 2115.51 1315.7 2U - 26MG2 E EAV=543.29 4$CK=0.915 4$CL=0.079 4$CM=0.0059 12 - 26MG G 1808.65 7 99.76 4E2 6.33E-6 - 26MG2 G KC=5.89E-6 $LC=3.52E-7 - 26MG L 2938.41 132+ 141 FS 8 - 26MG E 5.4E-7 42.74 2014.6 2U - 26MG2 E EAV=24.78 8$CK=0.915 4$CL=0.079 4$CM=0.0059 12 - 26MG G 1129.67 102.5 2M1+E2 -0.12 2 1.25E-5 - 26MG2 G KC=1.15E-5 $LC=7.54E-7 - 26MG G 2938 1 0.24 4E2 2.35E-6 - 26MG2 G KC=2.16E-6 $LC=1.49E-7 - + 26MG 26AL EC DECAY (717E3 Y) + 26MG T Auger electrons and X ray energies and emission intensities: + 26MG T {U Energy (keV)} {U Intensity} {U Line} + 26MG T + 26MG T 1.2536 0.160 6 XKA2 + 26MG T 1.2536 0.318 11 XKA1 + 26MG T + 26MG T + 26MG T + 26MG T + 26MG T 1.102-1.182 |] KLL AUGER + 26MG T 1.214-1.252 |] 16.22 22 KLX AUGER + 26MG T 1.301-1.301 |] KXY AUGER + 26MG T 0.0359-0.0359 2.2E-6 18 L AUGER + 26AL P 0.0 5+ 717E3 Y 24 4004.19 6 + 26MG N 1.0 1.0 1 1.0 + 26MG L 0 0+ STABLE + 26MG L 1808.72 7 2+ 476 FS 12 + 26MG E 81.73 2115.51 1315.7 2U + 26MG2 E EAV=543.29 4$CK=0.1459 6$CL=0.0126 6$CM=0.00094 19 + 26MG G 1808.65 7 99.76 4E2 6.33E-6 + 26MG2 G KC=5.89E-6 $LC=3.52E-7 + 26MG L 2938.41 132+ 141 FS 8 + 26MG E 5.4E-7 42.74 2014.6 2U + 26MG2 E EAV=24.78 8$CK=0.915 4$CL=0.079 4$CM=0.0059 12 + 26MG G 1129.67 102.5 2M1+E2 -0.12 2 1.25E-5 + 26MG2 G KC=1.15E-5 $LC=7.54E-7 + 26MG G 2938 1 0.24 4E2 2.35E-6 + 26MG2 G KC=2.16E-6 $LC=1.49E-7 + diff --git a/HEN_HOUSE/spectra/lnhb/Am-241.txt b/HEN_HOUSE/spectra/lnhb/Am-241.txt index 962899042..4ec0bf1d8 100644 --- a/HEN_HOUSE/spectra/lnhb/Am-241.txt +++ b/HEN_HOUSE/spectra/lnhb/Am-241.txt @@ -1,416 +1,500 @@ -237NP 241AM A DECAY (432.6 Y) -237NP H TYP=Update$AUT=V.P. Chechev. N.K. Kuzmenco$CUT=01-SEP-2010$ -237NP2 H TYP=update$AUT=Chechev$CUT= -- $ -237NP3 H TYP=Full$AUT=V.P. Chechev. N.K. Kuzmenco$CUT= -- $ -237NP C Evaluation history: Type=Update;Author=V.P. Chechev. N.K. Kuzmenco;Cutoff date=01-SEP-2010 -237NP2C Type=update;Author=Chechev;Cutoff date= -- -237NP3C Type=Full;Author=V.P. Chechev. N.K. Kuzmenco;Cutoff date= -- -237NP C References: 1952Be24, 1955Tu13, 1955Ja01, 1955Da02, 1956Ho38, 1955Go57, -237NP2C 1957Ro20, 1957Ma17, 1959Sa10, 1960As02, 1962LE11, 1964Wo03, 1964Ba26, -237NP3C 1965Mi06, 1965Be38, 1965Mc12, 1966Ya05, 1966Le13, 1967Pa23, 1967Gu08, -237NP4C 1967Br26, 1967Oe01, 1966Ko06, 1968St02, 1968Je01, 1968Br22, 1968Ba25, -237NP5C 1968Ka09, 1969Pe17, 1970Ne11, 1970Gr36, 1971Cl03, 1971Wa28, 1971Gr17, -237NP6C 1971Ka48, 1971Ge11, 1972Jo07, 1974HeYW, 1974Ga40, 1974Ca16, 1974StYG, -237NP7C 1974Po16, 1975Ra35, 1975Le09, 1976Pl05, 1976GuZN, 1978Ge06, 1978Ov01, -237NP8C 1978Ge17, 1979Ar11, 1982Ba56, 1983De11, 1983Hu04, 1983Ah02, 1984Ah06, -237NP9C 1984Ov02, 1987Bo25, 1987De22, 1988ChZL, 1988Co07, 1992Ma16, 1992Bl07, -237NP10C 1994Le37, 1994Bl12, 1995Ak01, 1996Jo28, 1998Ab43, 1998Ko61, 1998Ya17, -237NP11C 2000Ho27, 2000He14, 2001Sc08, 2003Au03, 2005Iw01, 2006Ba41, 2008Le07, -237NP12C 2008Go10, 2008Ki07 -237NP T Auger electrons and X ray energies and emission intensities: -237NP T {U Energy (keV)} {U Intensity} {U Line} -237NP T -237NP T 97.069 0.00113430 XKA2 -237NP T 101.059 0.00181 5 XKA1 -237NP T -237NP T 113.303 |] XKB3 -237NP T 114.234 |] 0.00065821 XKB1 -237NP T 114.912 |] XKB5II -237NP T -237NP T 117.463 |] XKB2 -237NP T 117.876 |] 0.000226 8 XKB4 -237NP T 118.429 |] XKO23 -237NP T -237NP T 11.89-22.2 37.66 17 XL (total) -237NP T 11.89 0.844 9 XLL -237NP T 13.76-13.944 13.02 10 XLA -237NP T 15.876 0.384 20 XLC -237NP T 16.13-17.79 18.58 13 XLB -237NP T 20.12-22.2 4.83 30 XLG -237NP T -237NP T 73.5-83.13 |] KLL AUGER -237NP T 90.36-97.28 |] 0.00011416 KLX AUGER -237NP T 107.1-114.58 |] KXY AUGER -237NP T 6.04-13.52 33.4 17 L AUGER -241AM P 0.0 5/2- 432.6 Y 6 5637.82 12 -237NP N 1.0 1.0 1 1.0 -237NP G 32.183 0.0174 4 -237NP G 57.85 5 0.0052 15 -237NP G 106.42 5 0.000015 -237NP G 128.05 -237NP G 136.7 -237NP G 156.4 3 -237NP G 190.4 2.2E-6 5 -237NP G 201.70 148E-7 -237NP G 270.63 155E-7 2 -237NP G 271.54 1.44E-6 5 -237NP G 324.69 1.8E-6 3 -237NP G 329.69 1.1E-6 2 -237NP G 350.71 1.39E-6 5 -237NP G 374.83 3.13E-6 6 -237NP G 389.0 3 4.9E-7 -237NP G 390.61 5 5.73E-6 10 -237NP G 411.27 1.8E-7 4 -237NP G 429.9 1 1.09E-6 5 -237NP G 440.63 5.6E-7 3 -237NP G 442.81 7 3.31E-6 8 -237NP G 486.05 1.05E-6 6 -237NP G 494.39 1.0E-7 2 -237NP G 501.39 1.4E-7 2 -237NP G 525.14 1.6E-7 3 -237NP G 532.44 8E-8 2 -237NP G 548.15 5E-8 2 -237NP G 555.25 9E-8 2 -237NP G 582.89 1.01E-6 6 -237NP G 600.26 2.2E-7 3 -237NP G 636.9 2.1E-7 3 -237NP G 693.46 3.54E-6 8 -237NP G 709.42 5 6.41E-6 19 -237NP G 712.5 2.0E-7 3 -237NP G 731.44 4.6E-7 4 -237NP G 736.68 1.28E-6 5 -237NP G 740.51 1.9E-7 3 -237NP G 742.9 3 3.5E-7 -237NP G 745.02 9E-8 2 -237NP G 750.39 6E-8 2 -237NP G 759.5 1 1.81E-6 5 -237NP G 763.31 2.3E-7 2 -237NP G 774.67 1.1E-7 2 -237NP G 777.39 1.5E-7 2 -237NP G 780.53 3.1E-7 2 -237NP G 782.2 5 1.5E-7 -237NP G 789.0 3 4.2E-7 6 -237NP G 792.6 3E-8 1 -237NP G 794.92 209.4E-7 -237NP G 803.19 1.6E-7 3 -237NP G 811.9 3 6.3E-7 6 -237NP G 819.33 4.3E-7 6 -237NP G 822.21 2.4E-7 6 -237NP G 835.21 3E-8 1 -237NP G 838.88 4E-8 1 -237NP G 841.14 1.0E-7 3 -237NP G 843.7 9.7E-7 8 -237NP G 846.86 1.6E-7 3 -237NP G 847.4 5 2.7E-7 3 -237NP G 851.6 104.1E-7 6 -237NP G 854.95 2.3E-7 4 -237NP G 856.26 1.0E-7 3 -237NP G 870.63 1.50E-6 4 -237NP G 882 4E-8 1 -237NP G 886.53 1.5E-7 3 -237NP G 890.38 3.2E-7 5 -237NP G 894.47 3E-8 1 -237NP G 898.17 6E-8 2 -237NP G 902.61 3.3E-7 3 -237NP G 909.95 5E-8 1 -237NP G 912.4 2.8E-7 3 -237NP G 928.95 9E-8 2 -237NP G 939.2 5E-8 1 -237NP G 952.72 3E-8 1 -237NP G 955.91 6.0E-7 5 -237NP G 969.09 3E-8 1 -237NP G 980.84 3E-8 1 -237NP L 0 5/2+ 2.144E6 Y 7 -237NP A 5544.11 120.38 1 610 -237NP L 33.19629 227/2+ 54 PS 24 -237NP A 5511.46 120.23 1 600 -237NP G 33.1963 3 0.1215 28M1+E2 0.13 3 175 24 -237NP2 G LC=131 17$MC=33 5 -237NP L 59.54092 105/2- 67 NS 2 -237NP A 5485.56 1284.45 101.3 -237NP G 26.34460 202.31 8E1 8 2 -237NP2 G LC=6 2$MC=1.6 2 -237NP G 59.5409 1 35.92 17E1 1.16 7 -237NP2 G LC=0.84 6$MC=0.226 7 -237NP L 75.899 5 9/2+ 56 PS -237NP A 5469.47 120.04 2000 -237NP G 42.704 5 0.0055 11(M1+E2) 0.13 3 75 7 -237NP2 G LC=56 5$MC=13.9 14 -237NP G 75.90 1 0.0006 (E2) 53.1 11 -237NP2 G LC=38.6 8$MC=10.76 22 -237NP L 102.959 3 7/2- 80 PS 40 -237NP A 5442.86 1213.23 104.3 -237NP G 27.06 1 -237NP G 43.420 3 0.0669 29M1+E2 0.45 5 180 23 -237NP2 G LC=132 17$MC=35 5 -237NP G 69.76 3 0.0029 4(E1) 0.330 7 -237NP2 G LC=0.248 5$MC=0.0612 12 -237NP G 102.98 2 0.0195 4E1 0.1189 24 -237NP2 G LC=0.0895 18$MC=0.0219 4 -237NP L 129.99 3 11/2+ -237NP A 5416.28 130.01 4000 -237NP G 54.09 3 -237NP G 96.79 3 0.00004716 -237NP L 158.497 119/2- -237NP A 5388.25 131.66 3 16.4 -237NP G 55.56 2 0.0181 18M1+E2 0.46 4 65 6 -237NP2 G LC=48 4$MC=12.6 11 -237NP G 98.97 2 0.0203 4E2 15.2 3 -237NP2 G LC=11.07 22$MC=3.08 6 -237NP G 125.30 2 0.0041 2(E1) 0.299 6 -237NP2 G KC=0.228 5$LC=0.0538 11$MC=0.0132 3 -237NP L 191.53 6 13/2+ -237NP G 61.56 7 -237NP G 115.65 6 -237NP L 225.957 1611/2- -237NP A 5321.87 130.014 3 770 -237NP G 67.50 2 0.00042 10(M1+E2) 0.46 12 29 6 -237NP2 G LC=22 5$MC=5.7 13 -237NP G 123.05 1 0.00100 4E2 5.75 12 -237NP2 G KC=0.184 4$LC=4.05 8$MC=1.127 23 -237NP G 150.04 3 0.000073 5[E1] 0.197 4 -237NP2 G KC=0.152 3$LC=0.0339 7$MC=0.00827 17 -237NP L 267.556 123/2- 5.2 NS 2 -237NP A 5280.99 130.0005 12000 -237NP G 164.61 2 0.000066 3E2 1.70 4 -237NP2 G KC=0.195 4$LC=1.095 22$MC=0.304 6 -237NP G 208.005 230.000786 9M1+E2 0.156 5 2.98 6 -237NP2 G KC=2.35 5$LC=0.473 9$MC=0.1149 23 -237NP G 234.40 4 8.7E-7 8M2 8.24 17 -237NP2 G KC=5.60 11$LC=1.95 4$MC=0.511 10 -237NP G 267.54 4 2.68E-5 6E1+M2 0.490 15 1.06 6 -237NP2 G KC=0.74 4$LC=0.238 12$MC=0.062 2 -237NP L 281.356 181/2- -237NP G 13.81 2 M1+E2 0.0321 10 494 10 -237NP2 G MC=365 7 -237NP L 305.05 3 13/2- -237NP A 5244.13 130.0022 3 1600 -237NP G 79.05 3 -237NP G 146.55 3 0.00046 1E2 2.73 6 -237NP2 G KC=0.210 4$LC=1.83 4$MC=0.51 1 -237NP G 175.07 4 0.000018 3[E1] 0.137 3 -237NP2 G KC=0.1066 21$LC=0.0230 5$MC=0.00560 11 -237NP L 316.8 2 + -237NP A 5232.6 3 0 -237NP G 316.8 2 -237NP L 324.420 23(7/2)- -237NP A 5225.08 130.0013 2100 -237NP G 56.86 3 -237NP G 165.81 6 0.000023 1[M1+E2] 3.7 22 -237NP2 G KC=2.4 22$LC=0.98 8$MC=0.26 4 -237NP G 221.46 3 4.34E-5 8[M1+E2] 1.5 10 -237NP2 G KC=1.1 10$LC=0.35 5$MC=0.090 7 -237NP G 248.52 3 1.46E-6 3[E1] 0.0612 12 -237NP2 G KC=0.0482 10$LC=0.00975 20$MC=0.00236 5 -237NP G 264.88 3 9.43E-6 12[M1+E2] 0.9 7 -237NP2 G KC=0.7 6$LC=0.19 5$MC=0.049 9 -237NP G 291.3 2 3.05E-6 8[E1] 0.0430 9 -237NP2 G KC=0.0341 7$LC=0.00671 14$MC=0.00162 3 -237NP L 332.376 161/2+ 1 NS -237NP A 5217.26 130 -237NP G 51.01 3 0.00002612E1 0.753 11 -237NP2 G LC=0.564 11$MC=0.141 3 -237NP G 64.83 2 0.00014 2E1 0.400 8 -237NP2 G LC=0.301 6$MC=0.0744 15 -237NP G 332.35 3 0.000150 4E2 0.147 3 -237NP2 G KC=0.0631 13$LC=0.0611 12$MC=0.0165 4 -237NP L 359.7 1 (5/2)- -237NP A 5190.17 230.0006 2700 -237NP G 92.35 20 -237NP G 300.13 6 -237NP L 368.602 205/2+ -237NP A 5181.63 130.0009 1600 -237NP G 292.77 6 1.42E-5 3[E2] 0.215 4 -237NP2 G KC=0.0796 16$LC=0.0991 20$MC=0.0270 6 -237NP G 309.1 3 2.0E-6 3[E1] 0.0377 8 -237NP2 G KC=0.0300 6$LC=0.00585 12$MC=0.00142 3 -237NP G 335.37 3 0.000496 7M1+E2 0.46 17 0.69 8 -237NP2 G KC=0.54 7$LC=0.113 8$MC=0.0278 10 -237NP G 368.62 3 0.000214 5(M1) 0.622 12 -237NP2 G KC=0.494 10$LC=0.0963 19$MC=0.0233 5 -237NP L 370.928 233/2+ -237NP A 5179.35 130.0003 4600 -237NP G 38.54 3 M1+E2 472 -237NP2 G LC=94 $MC=345 -237NP G 337.7 2 4.88E-6 9(E2) 0.140 3 -237NP2 G KC=0.0612 12$LC=0.0575 11$MC=0.0156 3 -237NP G 370.94 3 5.20E-5 8M1+E2 0.43 21 0.53 7 -237NP2 G KC=0.42 6$LC=0.086 8$MC=0.0211 10 -237NP L 395.53 4 15/2- -237NP A 5155.12 130.0007 1400 -237NP G 169.56 3 0.00017 1E2 1.51 3 -237NP2 G KC=0.189 4$LC=0.961 19$MC=0.267 6 -237NP G 204.06 6 2.06E-6 6[E1] 0.0960 19 -237NP2 G KC=0.0752 15$LC=0.0157 3$MC=0.00382 8 -237NP L 418.2 1 + -237NP A 5132.8 2 0 -237NP L 434.12 5 (11/2)- -237NP A 5117.21 130.0004 1400 -237NP G 109.70 7 4.9E-6 [E2] 9.44 19 -237NP2 G LC=6.86 14$MC=1.91 4 -237NP G 129.07 6 -237NP G 275.77 8 6.32E-6 10[M1+E2] 0.8 6 -237NP2 G KC=0.6 5$LC=0.17 5$MC=0.043 9 -237NP G 304.21 209.3E-7 2[E1] 0.0391 8 -237NP2 G KC=0.0310 6$LC=0.00607 12$MC=0.00147 3 -237NP G 358.25 201.29E-6 5[E1] 0.0275 6 -237NP2 G KC=0.0220 4$LC=0.00419 8$MC=0.00101 2 -237NP L 444.78 10 + -237NP A 5106.72 160 -237NP G 120.36 8 4.5E-6 -237NP L 452.545 229/2+ -237NP A 5099.08 130.0004 1000 -237NP G 261.00 7 1.29E-6 6[E2] 0.312 6 -237NP2 G KC=0.0979 20$LC=0.156 3$MC=0.0428 9 -237NP G 322.56 3 0.000151 4(M1+E2) 0.6 0.702 12 -237NP2 G KC=0.541 8$LC=0.1204 17$MC=0.0297 5 -237NP G 376.65 3 0.000137 3(M1) 0.586 12 -237NP2 G KC=0.466 9$LC=0.0908 18$MC=0.0220 5 -237NP G 419.33 4 2.84E-5 4[M1+E2] 0.26 18 -237NP2 G KC=0.19 16$LC=0.047 21$MC=0.012 5 -237NP G 452.6 2 2.36E-6 7[E2] 0.0635 13 -237NP2 G KC=0.0357 7$LC=0.0205 4$MC=0.00543 11 -237NP L 459.693 247/2+ -237NP A 5092.06 130.0004 1000 -237NP G 135.27 4 -237NP G 383.81 3 2.81E-5 6[M1+E2] 0.33 23 -237NP2 G KC=0.25 20$LC=0.06 3$MC=0.015 6 -237NP G 426.47 4 0.000031 6[M1+E2] 0.25 18 -237NP2 G KC=0.19 15$LC=0.045 20$MC=0.011 5 -237NP G 459.68 103.55E-6 7[M1+E2] 0.20 14 -237NP2 G KC=0.15 12$LC=0.036 17$MC=0.009 4 -237NP L 486.21 9 (9/2)- -237NP A 5065.97 150.00011 2300 -237NP G 161.54 101.5E-6 [M1] 6.20 12 -237NP2 G KC=4.91 10$LC=0.971 19$MC=0.236 5 -237NP G 260.22 9 -237NP L 497.01 5 17/2- -237NP A 5055.36 130 -237NP G 191.96 4 2.15E-5 10[E2] 0.932 19 -237NP2 G KC=0.162 3$LC=0.561 11$MC=0.155 3 -237NP L 514.19 4 (3/2)- -237NP G 154.27 205E-7 [M1] 7.06 14 -237NP2 G KC=5.59 11$LC=1.108 22$MC=0.269 6 -237NP G 232.81 5 4.82E-6 9[M1] 2.22 5 -237NP2 G KC=1.76 4$LC=0.345 7$MC=0.0837 17 -237NP G 246.73 102.44E-6 7[M1] 1.88 4 -237NP2 G KC=1.49 3$LC=0.294 6$MC=0.0711 14 -237NP G 454.66 8 9.53E-6 12[M1] 0.351 7 -237NP2 G KC=0.279 6$LC=0.0542 11$MC=0.0131 3 -237NP G 514.0 5 3.8E-6 2[E1] 0.0132 -237NP2 G KC=0.0106 2$LC=0.00194 4$MC=0.00047 1 -237NP L 546.12 6 (5/2)- -237NP A 5007.07 140.0001 1000 -237NP G 31.92 8 -237NP G 264.76 7 -237NP G 278.04 151.15E-6 3[M1] 1.35 3 -237NP2 G KC=1.072 21$LC=0.210 4$MC=0.0509 10 -237NP G 512.5 3 2.1E-6 4[E1] 0.0133 3 -237NP2 G KC=0.0107 2$LC=0.00195 4$MC=0.00047 1 -237NP G 546.12 6 2.5E-7 3[E1] 0.0117 2 -237NP2 G KC=0.00947 19$LC=0.00171 3$MC=0.00041 1 -237NP L 590.09 4 (7/2)- -237NP A 4963.83 130 -237NP G 322.52 4 -237NP G 487.13 4 6.2E-7 5[M1] 0.291 6 -237NP2 G KC=0.232 6$LC=0.0449 9$MC=0.0109 2 -237NP G 590.09 4 2.80E-6 6[E1] 0.0101 2 -237NP2 G KC=0.00818 16$LC=0.00147 3$MC=3.51E-4 7 -237NP L 592.33 7 13/2+ -237NP A 4961.63 140 -237NP G 139.44 8 5.3E-6 11[E2] 3.37 7 -237NP2 G KC=0.211 4$LC=2.29 5$MC=0.638 13 -237NP G 159.26 201.4E-6 5[E1] 0.171 4 -237NP2 G KC=0.132 3$LC=0.0292 6$MC=0.00711 14 -237NP G 196.76 8 4.9E-7 [E1] 0.1045 21 -237NP2 G KC=0.0816 16$LC=0.0172 4$MC=0.00418 9 -237NP G 400.78 101.4E-7 3[M1+E2] 0.29 21 -237NP2 G KC=0.22 18$LC=0.054 23$MC=0.013 6 -237NP G 462.34 8 0.000001 [M1+E2] 0.20 14 -237NP2 G KC=0.15 12$LC=0.035 17$MC=0.009 4 -237NP L 597.99 9 11/2+ -237NP A 4956.06 150 -237NP G 138.30 9 -237NP G 406.35 151.37E-6 5[M1+E2] 0.28 20 -237NP2 G KC=0.21 17$LC=0.052 22$MC=0.013 5 -237NP G 468.12 152.69E-6 6[M1+E2] 0.19 14 -237NP2 G KC=0.15 12$LC=0.034 16$MC=0.008 4 -237NP G 522.06 159.9E-7 5[M1+E2] 0.14 10 -237NP2 G KC=0.11 9$LC=0.025 13$MC=0.006 3 -237NP L 646.03 17(9/2)- -237NP G 586.59 201.24E-6 5[E2] 0.0346 7 -237NP2 G KC=0.0224 4$LC=0.00903 18$MC=0.00235 5 -237NP L 666.19 10(5/2,7/2)+ -237NP A 4888.98 150 -237NP G 398.64 15 -237NP G 632.93 151.24E-6 5 -237NP G 666.2 2 9.5E-7 7 -237NP L 721.961 135/2- -237NP A 4834.15 130.0007 9.5 -237NP G 563.46 2 4.4E-7 2[E2] 0.0378 8 -237NP2 G KC=0.0241 5$LC=0.0102 2$MC=0.00266 5 -237NP G 619.01 2 0.000060 2[M1+E2] 0.09 7 -237NP2 G KC=0.07 5$LC=0.016 8$MC=0.0037 10 -237NP G 662.40 2 0.000367 6(+M1+E2) 0.23 5 -237NP2 G KC=0.18 4$LC=0.045 15 -237NP G 688.72 4 3.23E-5 6[E1] 0.0075816 -237NP2 G KC=0.00615 12$LC=0.00108 2$MC=2.59E-4 5 -237NP G 721.96 2 0.000196 5[E1] 0.0070 2 -237NP2 G KC=0.0056 1$LC=0.00099 2$MC=0.00024 1 -237NP L 755.685 197/2- -237NP A 4800.99 1386000E-9 44 -237NP G 597.19 2 7.29E-6 11[M1+E2] 0.10 7 -237NP2 G KC=0.08 6$LC=0.017 9$MC=0.0042 20 -237NP G 652.73 2 3.76E-5 9[M1+E2] 0.08 6 -237NP2 G KC=0.06 5$LC=0.013 7$MC=0.0033 10 -237NP G 679.79 2 3.31E-6 8[E1] 0.0077616 -237NP2 G KC=0.00630 13$LC=0.00111 2$MC=2.65E-4 5 -237NP G 696.14 2 5.17E-6 8[M1+E2] 0.07 5 -237NP2 G KC=0.05 4$LC=0.011 6$MC=0.0028 10 -237NP G 755.68 2 7.84E-6 11[E1] 0.0064 1 -237NP2 G KC=0.0052 1$LC=0.00091 1$MC=2.17E-4 4 -237NP L 770.57 5 + -237NP G 446.15 6 1.1E-7 2 -237NP G 737.34 5 7.94E-6 11 -237NP G 770.57 104.81E-6 7 -237NP L 799.82 4 9/2- -237NP A 4757.58 130.00004 3 47 -237NP G 77.86 4 -237NP G 573.94 201.28E-6 5[M1+E2] 0.11 8 -237NP2 G KC=0.09 7$LC=0.019 10$MC=0.0027 16 -237NP G 641.32 4 7.04E-6 10[M1+E2] 0.08 6 -237NP2 G KC=0.06 5$LC=0.014 8$MC=0.0035 10 -237NP G 669.83 2 5.1E-7 7[E1] 0.0080 2 -237NP2 G KC=0.00647 13$LC=0.00114 2$MC=0.00073 1 -237NP G 766.62 4 5.01E-6 6[E1] 0.0062312 -237NP2 G KC=0.00507 10$LC=0.00088 2$MC=2.11E-4 4 -237NP L 805.77 12(7/2,9/2)+ -237NP G 675.78 138.5E-7 5[E2M1] 0.07 5 -237NP2 G KC=0.06 4$LC=0.012 7$MC=0.0030 15 -237NP G 729.72 151.37E-6 5[M1] 0.099 2 -237NP2 G KC=0.079 2$LC=0.0151 4$MC=0.0036 1 -237NP G 772.57 122.79E-6 4[M1] 0.0847 17 -237NP2 G KC=0.0675 14$LC=0.0129 3$MC=0.00312 6 -237NP G 805.77 123.1E-7 [M1E2] 0.05 3 -237NP2 G KC=0.037 24$LC=0.008 4$MC=0.0019 10 -237NP L 853.36 1511/2- -237NP G 529.17 206.9E-7 5[E2] 0.0437 9 -237NP2 G KC=0.0269 5$LC=0.0124 2$MC=0.00324 6 -237NP G 627.18 205.1E-7 2[M1+E2] 0.09 6 -237NP2 G KC=0.07 5$LC=0.015 8$MC=0.0037 10 -237NP L 861.65 19(5/2,7/2)+ -237NP G 786.00 156.2E-7 -237NP G 801.94 201.23E-6 7 -237NP G 828.60 122.1E-7 4 -237NP G 861.80 126.1E-7 6 -237NP L 920.88 20 + -237NP G 861.34 208E-8 3 -237NP G 887.68 203.3E-7 6 -237NP G 920.88 201.9E-7 3 -237NP L 946 2 + -237NP G 946.06 1.0E-8 2 -237NP L 962 3 + -237NP G 962.19 4E-8 1 -237NP L 1014 3 + -237NP G 1014.33 1.0E-6 2 - +237NP 241AM A DECAY (432.6 Y) +237NP H TYP=UPD$AUT=V.P.CHECHEV, N.K.KUZMENCO$CUT=01-SEP-2010$ +237NP2 H TYP=UPD$AUT=V.P.CHECHEV$CUT=30-SEP-2004$ +237NP3 H TYP=FUL$AUT=V.P.CHECHEV, N.K.KUZMENCO$CUT=01-OCT-2002$ +237NP C References:1952Be24, 1955Tu13, 1955Ja01, 1955Da02, 1956Ho38, 1955Go57, +237NP2C 1957Ro20, 1957Ma17, 1959Sa10, 1960As02, 1962LE11, 1964Wo03, 1964Ba26, +237NP3C 1965Mi06, 1965Be38, 1965Mc12, 1966Ya05, 1966Le13, 1967Pa23, 1967Gu08, +237NP4C 1967Br26, 1967Oe01, 1966Ko06, 1968St02, 1968Je01, 1968Br22, 1968Ba25, +237NP5C 1968Ka09, 1969Pe17, 1970Ne11, 1970Gr36, 1971Cl03, 1971Wa28, 1971Gr17, +237NP6C 1971Ka48, 1971Ge11, 1972Jo07, 1974HeYW, 1974Ga40, 1974Ca16, 1974StYG, +237NP7C 1974Po16, 1975Ra35, 1975Le09, 1976Pl05, 1976GuZN, 1978Ge06, 1978Ov01, +237NP8C 1978Ge17, 1979Ar11, 1982Ba56, 1983De11, 1983Hu04, 1983Ah02, 1984Ah06, +237NP9C 1984Ov02, 1987Bo25, 1987De22, 1988ChZL, 1988Co07, 1992Ma16, 1992Bl07, +237NPAC 1994Le37, 1994Bl12, 1995Ak01, 1996Jo28, 1998Ab43, 1998Ko61, 1998Ya17, +237NPBC 2000Ho27, 2000He14, 2001Sc08, 2002Be**, 2003Au03, 2005Iw01, 2006Ba41, +237NPCC 2008Le07, 2008Go10, 2008Ki07 +237NP T Auger electrons and X ray energies and emission intensities: +237NP T {U Energy (keV)} {U Intensity} {U Line} +237NP T +237NP T 97.069 0.00113430 XKA2 +237NP T 101.059 0.00181 5 XKA1 +237NP T +237NP T 113.303 |] XKB3 +237NP T 114.234 |] 0.00065821 XKB1 +237NP T 114.912 |] XKB5II +237NP T +237NP T 117.463 |] XKB2 +237NP T 117.876 |] 0.000226 8 XKB4 +237NP T 118.429 |] XKO23 +237NP T +237NP T 11.89-22.2 37.66 17 XL (total) +237NP T 11.89 0.844 9 XLL +237NP T 13.76-13.944 13.02 10 XLA +237NP T 15.876 0.384 20 XLC +237NP T 16.13-17.79 18.58 13 XLB +237NP T 20.12-22.2 4.83 30 XLG +237NP T +237NP T 73.5-83.13 |] KLL AUGER +237NP T 90.36-97.28 |] 0.00011416 KLX AUGER +237NP T 107.1-114.58 |] KXY AUGER +237NP T 6.04-13.52 33.4 17 L AUGER +241AM P 0.0 5/2- 432.6 Y 6 5637.82 12 +237NP N 1.0 1.0 1 +237NP G 32.183 0.0174 4 +237NP G 57.85 5 0.0052 15 +237NP G 106.42 5 0.000015 +237NP G 128.05 +237NP G 136.7 +237NP G 156.4 3 +237NP G 190.4 2.2E-6 5 +237NP G 201.70 148E-7 +237NP G 270.63 155E-7 2 +237NP G 271.54 1.44E-6 5 +237NP G 324.69 1.8E-6 3 +237NP G 329.69 1.1E-6 2 +237NP G 350.71 1.39E-6 5 +237NP G 374.83 3.13E-6 6 +237NP G 389.0 3 4.9E-7 +237NP G 390.61 5 5.73E-6 10 +237NP G 411.27 1.8E-7 4 +237NP G 429.9 1 1.09E-6 5 +237NP G 440.63 5.6E-7 3 +237NP G 442.81 7 3.31E-6 8 +237NP G 486.05 1.05E-6 6 +237NP G 494.39 1.0E-7 2 +237NP G 501.39 1.4E-7 2 +237NP G 525.14 1.6E-7 3 +237NP G 532.44 8E-8 2 +237NP G 548.15 5E-8 2 +237NP G 555.25 9E-8 2 +237NP G 582.89 1.01E-6 6 +237NP G 600.26 2.2E-7 3 +237NP G 636.9 2.1E-7 3 +237NP G 693.46 3.54E-6 8 +237NP G 709.42 5 6.41E-6 19 +237NP G 712.5 2.0E-7 3 +237NP G 731.44 4.6E-7 4 +237NP G 736.68 1.28E-6 5 +237NP G 740.51 1.9E-7 3 +237NP G 742.9 3 3.5E-7 +237NP G 745.02 9E-8 2 +237NP G 750.39 6E-8 2 +237NP G 759.5 1 1.81E-6 5 +237NP G 763.31 2.3E-7 2 +237NP G 774.67 1.1E-7 2 +237NP G 777.39 1.5E-7 2 +237NP G 780.53 3.1E-7 2 +237NP G 782.2 5 1.5E-7 +237NP G 789.0 3 4.2E-7 6 +237NP G 792.6 3E-8 1 +237NP G 794.92 209.4E-7 +237NP G 803.19 1.6E-7 3 +237NP G 811.9 3 6.3E-7 6 +237NP G 819.33 4.3E-7 6 +237NP G 822.21 2.4E-7 6 +237NP G 835.21 3E-8 1 +237NP G 838.88 4E-8 1 +237NP G 841.14 1.0E-7 3 +237NP G 843.7 9.7E-7 8 +237NP G 846.86 1.6E-7 3 +237NP G 847.4 5 2.7E-7 3 +237NP G 851.6 104.1E-7 6 +237NP G 854.95 2.3E-7 4 +237NP G 856.26 1.0E-7 3 +237NP G 870.63 1.50E-6 4 +237NP G 882 4E-8 1 +237NP G 886.53 1.5E-7 3 +237NP G 890.38 3.2E-7 5 +237NP G 894.47 3E-8 1 +237NP G 898.17 6E-8 2 +237NP G 902.61 3.3E-7 3 +237NP G 909.95 5E-8 1 +237NP G 912.4 2.8E-7 3 +237NP G 928.95 9E-8 2 +237NP G 939.2 5E-8 1 +237NP G 952.72 3E-8 1 +237NP G 955.91 6.0E-7 5 +237NP G 969.09 3E-8 1 +237NP G 980.84 3E-8 1 +237NP L 0 5/2+ 2.144E6 Y 7 +237NP A 5544.11 120.38 1610 +237NP L 33.19629 227/2+ 54 PS 24 +237NP A 5511.46 120.23 1600 +237NP G 33.1963 3 0.1215 28M1+E2 0.13 3 175 24 +237NP2 G LC=131 17$MC=33 5$NC=8.9 13 +237NP3 G OC=2.2 3 +237NP L 59.54092 105/2- 67 NS 2 +237NP A 5485.56 1284.45 101.3 +237NP G 26.34460 202.31 8E1 8 2 +237NP2 G LC=6 2$MC=1.6 2 +237NP G 59.5409 1 35.92 17E1 1.16 7 +237NP2 G LC=0.84 6$MC=0.226 7 +237NP L 75.899 5 9/2+ 56 PS +237NP A 5469.47 120.04 2000 +237NP G 42.704 5 0.0055 11(M1+E2) 0.13 3 75 7 +237NP2 G LC=56 5$MC=13.9 14$NC=3.8 4 +237NP3 G OC=0.92 9 +237NP G 75.90 1 0.0006 (E2) 53.1 11 +237NP2 G LC=38.6 8$MC=10.76 22$NC=2.94 5 +237NP3 G OC=0.684 10 +237NP L 102.959 3 7/2- 80 PS 40 +237NP A 5442.86 1213.23 104.3 +237NP G 27.06 1 +237NP G 43.420 3 0.0669 29M1+E2 0.45 5 180 23 +237NP2 G LC=132 17$MC=35 5$NC=9.7 13 +237NP3 G OC=2.3 3 +237NP G 69.76 3 0.0029 4(E1) 0.330 7 +237NP2 G LC=0.248 5$MC=0.0612 12$NC=0.01633 23 +237NP3 G OC=0.00381 6 +237NP G 102.98 2 0.0195 4E1 0.1189 24 +237NP2 G LC=0.0895 18$MC=0.0219 4$NC=0.00587 9 +237NP3 G OC=0.001388 20 +237NP L 129.99 3 11/2+ +237NP A 5416.28 130.01 4000 +237NP G 54.09 3 +237NP G 96.79 3 0.00004716 +237NP L 158.497 119/2- +237NP A 5388.25 131.66 316.4 +237NP G 55.56 2 0.0181 18M1+E2 0.46 4 65 6 +237NP2 G LC=48 4$MC=12.6 11$NC=3.4 3 +237NP3 G OC=0.82 7 +237NP G 98.97 2 0.0203 4E2 15.2 3 +237NP2 G LC=11.07 22$MC=3.08 6$NC=0.843 12 +237NP3 G OC=0.196 3 +237NP G 125.30 2 0.0041 2(E1) 0.299 6 +237NP2 G KC=0.228 5$LC=0.0538 11$MC=0.0132 3$NC=0.00352 5 +237NP3 G OC=0.000837 12 +237NP L 191.53 6 13/2+ +237NP G 61.56 7 +237NP G 115.65 6 +237NP L 225.957 1611/2- +237NP A 5321.87 130.014 3770 +237NP G 67.50 2 0.00042 10(M1+E2) 0.46 12 29 6 +237NP2 G LC=22 5$MC=5.7 13$NC=1.6 4 +237NP3 G OC=0.37 8 +237NP G 123.05 1 0.00100 4E2 5.75 12 +237NP2 G KC=0.184 4$LC=4.05 8$MC=1.127 23$NC=0.308 5 +237NP3 G OC=0.0719 10 +237NP G 150.04 3 0.000073 5[E1] 0.197 4 +237NP2 G KC=0.152 3$LC=0.0339 7$MC=0.00827 17$NC=0.00222 4 +237NP3 G OC=0.000529 8 +237NP L 267.556 123/2- 5.2 NS 2 +237NP A 5280.99 130.0005 12000 +237NP G 164.61 2 0.000066 3E2 1.70 4 +237NP2 G KC=0.195 4$LC=1.095 22$MC=0.304 6$NC=0.0831 12 +237NP3 G OC=0.0194 3 +237NP G 208.005 230.000786 9M1+E2 0.156 5 2.98 6 +237NP2 G KC=2.35 5$LC=0.473 9$MC=0.1149 23$NC=0.0311 5 +237NP3 G OC=0.00766 11 +237NP G 234.40 4 8.7E-7 8M2 8.24 17 +237NP2 G KC=5.60 11$LC=1.95 4$MC=0.511 10$NC=0.1407 20 +237NP3 G OC=0.0345 5 +237NP G 267.54 4 2.68E-5 6E1+M2 0.490 15 1.06 6 +237NP2 G KC=0.74 4$LC=0.238 12$MC=0.062 2$NC=0.0170 9 +237NP3 G OC=0.00417 21 +237NP L 281.356 181/2- +237NP G 13.81 2 M1+E2 0.0321 10 494 10 +237NP2 G MC=365 7$NC=98.9 17 +237NP3 G OC=24.2 4 +237NP L 305.05 3 13/2- +237NP A 5244.13 130.0022 31600 +237NP G 79.05 3 +237NP G 146.55 3 0.00046 1E2 2.73 6 +237NP2 G KC=0.210 4$LC=1.83 4$MC=0.51 1$NC=0.1394 20 +237NP3 G OC=0.0326 5 +237NP G 175.07 4 0.000018 3[E1] 0.137 3 +237NP2 G KC=0.1066 21$LC=0.0230 5$MC=0.00560 11$NC=0.001501 21 +237NP3 G OC=0.000360 5 +237NP L 316.8 2 +237NP A 5232.6 3 1E-9 +237NP G 316.8 2 +237NP L 324.420 23(7/2)- +237NP A 5225.08 130.0013 2100 +237NP G 56.86 3 +237NP G 165.81 6 0.000023 1[M1+E2] 3.7 22 +237NP2 G KC=2.4 22$LC=0.98 8$MC=0.26 4$NC=0.070 11 +237NP3 G OC=0.0167 22 +237NP G 221.46 3 4.34E-5 8[M1+E2] 1.5 10 +237NP2 G KC=1.1 10$LC=0.35 5$MC=0.090 7$NC=0.0246 16 +237NP3 G OC=0.0059 6 +237NP G 248.52 3 1.46E-6 3[E1] 0.0612 12 +237NP2 G KC=0.0482 10$LC=0.00975 20$MC=0.00236 5$NC=0.000635 9 +237NP3 G OC=1.530E-4 22 +237NP G 264.88 3 9.43E-6 12[M1+E2] 0.9 7 +237NP2 G KC=0.7 6$LC=0.19 5$MC=0.049 9$NC=0.0134 24 +237NP3 G OC=0.0032 7 +237NP G 291.3 2 3.05E-6 8[E1] 0.0430 9 +237NP2 G KC=0.0341 7$LC=0.00671 14$MC=0.00162 3$NC=0.000437 7 +237NP3 G OC=1.055E-4 15 +237NP L 332.376 161/2+ 1 NS +237NP A 5217.26 131E-9 +237NP G 51.01 3 0.00002612E1 0.753 11 +237NP2 G LC=0.564 11$MC=0.141 3$NC=0.0374 6 +237NP3 G OC=0.00862 13 +237NP G 64.83 2 0.00014 2E1 0.400 8 +237NP2 G LC=0.301 6$MC=0.0744 15$NC=0.0198 3 +237NP3 G OC=0.00462 7 +237NP G 332.35 3 0.000150 4E2 0.147 3 +237NP2 G KC=0.0631 13$LC=0.0611 12$MC=0.0165 4$NC=0.00451 7 +237NP3 G OC=0.001066 15 +237NP L 359.7 1 (5/2)- +237NP A 5190.17 230.0006 2700 +237NP G 92.35 20 +237NP G 300.13 6 +237NP L 368.602 205/2+ +237NP A 5181.63 130.0009 1600 +237NP G 292.77 6 1.42E-5 3[E2] 0.215 4 +237NP2 G KC=0.0796 16$LC=0.0991 20$MC=0.0270 6$NC=0.00738 11 +237NP3 G OC=0.001738 25 +237NP G 309.1 3 2.0E-6 3[E1] 0.0377 8 +237NP2 G KC=0.0300 6$LC=0.00585 12$MC=0.00142 3$NC=0.000380 6 +237NP3 G OC=9.20E-5 13 +237NP G 335.37 3 0.000496 7M1+E2 0.46 17 0.69 8 +237NP2 G KC=0.54 7$LC=0.113 8$MC=0.0278 10$NC=0.0075 5 +237NP3 G OC=0.00184 12 +237NP G 368.62 3 0.000214 5(M1) 0.622 12 +237NP2 G KC=0.494 10$LC=0.0963 19$MC=0.0233 5$NC=0.00631 9 +237NP3 G OC=0.001554 22 +237NP L 370.928 233/2+ +237NP A 5179.35 130.0003 4600 +237NP G 38.54 3 M1+E2 472 +237NP2 G LC=94 $MC=345 +237NP G 337.7 2 4.88E-6 9(E2) 0.140 3 +237NP2 G KC=0.0612 12$LC=0.0575 11$MC=0.0156 3$NC=0.00425 6 +237NP3 G OC=0.001003 15 +237NP G 370.94 3 5.20E-5 8M1+E2 0.43 21 0.53 7 +237NP2 G KC=0.42 6$LC=0.086 8$MC=0.0211 10$NC=0.0057 5 +237NP3 G OC=0.00140 12 +237NP L 395.53 4 15/2- +237NP A 5155.12 130.0007 1400 +237NP G 169.56 3 0.00017 1E2 1.51 3 +237NP2 G KC=0.189 4$LC=0.961 19$MC=0.267 6$NC=0.0729 11 +237NP3 G OC=0.01705 24 +237NP G 204.06 6 2.06E-6 6[E1] 0.0960 19 +237NP2 G KC=0.0752 15$LC=0.0157 3$MC=0.00382 8$NC=0.001026 15 +237NP3 G OC=0.000246 4 +237NP L 418.2 1 +237NP A 5132.8 2 1E-9 +237NP L 434.12 5 (11/2)- +237NP A 5117.21 130.0004 1400 +237NP G 109.70 7 4.9E-6 [E2] 9.44 19 +237NP2 G LC=6.86 14$MC=1.91 4$NC=0.523 8 +237NP3 G OC=0.1219 18 +237NP G 129.07 6 +237NP G 275.77 8 6.32E-6 10[M1+E2] 0.8 6 +237NP2 G KC=0.6 5$LC=0.17 5$MC=0.043 9$NC=0.0117 24 +237NP3 G OC=0.0028 7 +237NP G 304.21 209.3E-7 2[E1] 0.0391 8 +237NP2 G KC=0.0310 6$LC=0.00607 12$MC=0.00147 3$NC=0.000395 6 +237NP3 G OC=9.54E-5 14 +237NP G 358.25 201.29E-6 5[E1] 0.0275 6 +237NP2 G KC=0.0220 4$LC=0.00419 8$MC=0.00101 2$NC=0.000272 4 +237NP3 G OC=0.000066 1 +237NP L 444.78 10 +237NP A 5106.72 161E-9 +237NP G 120.36 8 4.5E-6 +237NP L 452.545 229/2+ +237NP A 5099.08 130.0004 1000 +237NP G 261.00 7 1.29E-6 6[E2] 0.312 6 +237NP2 G KC=0.0979 20$LC=0.156 3$MC=0.0428 9$NC=0.01168 17 +237NP3 G OC=0.00275 4 +237NP G 322.56 3 0.000151 4(M1+E2) 0.6 0.702 12 +237NP2 G KC=0.541 8$LC=0.1204 17$MC=0.0297 5$NC=0.00805 12 +237NP3 G OC=0.00197 3 +237NP G 376.65 3 0.000137 3(M1) 0.586 12 +237NP2 G KC=0.466 9$LC=0.0908 18$MC=0.0220 5$NC=0.00595 9 +237NP3 G OC=0.001465 21 +237NP G 419.33 4 2.84E-5 4[M1+E2] 0.26 18 +237NP2 G KC=0.19 16$LC=0.047 21$MC=0.012 5$NC=0.0032 13 +237NP3 G OC=0.0008 4 +237NP G 452.6 2 2.36E-6 7[E2] 0.0635 13 +237NP2 G KC=0.0357 7$LC=0.0205 4$MC=0.00543 11$NC=0.001479 21 +237NP3 G OC=0.000352 5 +237NP L 459.693 247/2+ +237NP A 5092.06 130.0004 1000 +237NP G 135.27 4 +237NP G 383.81 3 2.81E-5 6[M1+E2] 0.33 23 +237NP2 G KC=0.25 20$LC=0.06 3$MC=0.015 6$NC=0.0041 15 +237NP3 G OC=0.0010 4 +237NP G 426.47 4 0.000031 6[M1+E2] 0.25 18 +237NP2 G KC=0.19 15$LC=0.045 20$MC=0.011 5$NC=0.0030 12 +237NP3 G OC=0.0007 3 +237NP G 459.68 103.55E-6 7[M1+E2] 0.20 14 +237NP2 G KC=0.15 12$LC=0.036 17$MC=0.009 4$NC=0.0024 11 +237NP3 G OC=0.0006 3 +237NP L 486.21 9 (9/2)- +237NP A 5065.97 150.00011 2300 +237NP G 161.54 101.5E-6 [M1] 6.20 12 +237NP2 G KC=4.91 10$LC=0.971 19$MC=0.236 5$NC=0.0638 9 +237NP3 G OC=0.01572 23 +237NP G 260.22 9 +237NP L 497.01 5 17/2- +237NP A 5055.36 131E-9 +237NP G 191.96 4 2.15E-5 10[E2] 0.932 19 +237NP2 G KC=0.162 3$LC=0.561 11$MC=0.155 3$NC=0.0424 6 +237NP3 G OC=0.00994 14 +237NP L 514.19 4 (3/2)- +237NP G 154.27 205E-7 [M1] 7.06 14 +237NP2 G KC=5.59 11$LC=1.108 22$MC=0.269 6$NC=0.0728 11 +237NP3 G OC=0.0179 3 +237NP G 232.81 5 4.82E-6 9[M1] 2.22 5 +237NP2 G KC=1.76 4$LC=0.345 7$MC=0.0837 17$NC=0.0227 4 +237NP3 G OC=0.00558 8 +237NP G 246.73 102.44E-6 7[M1] 1.88 4 +237NP2 G KC=1.49 3$LC=0.294 6$MC=0.0711 14$NC=0.0193 3 +237NP3 G OC=0.00474 7 +237NP G 454.66 8 9.53E-6 12[M1] 0.351 7 +237NP2 G KC=0.279 6$LC=0.0542 11$MC=0.0131 3$NC=0.00355 5 +237NP3 G OC=0.000874 13 +237NP G 514.0 5 3.8E-6 2[E1] 0.0132 +237NP2 G KC=0.0106 2$LC=0.00194 4$MC=0.00047 1$NC=1.251E-4 18 +237NP3 G OC=3.05E-5 5 +237NP L 546.12 6 (5/2)- +237NP A 5007.07 140.0001 1000 +237NP G 31.92 8 +237NP G 264.76 7 +237NP G 278.04 151.15E-6 3[M1] 1.35 3 +237NP2 G KC=1.072 21$LC=0.210 4$MC=0.0509 10$NC=0.01379 20 +237NP3 G OC=0.00340 5 +237NP G 512.5 3 2.1E-6 4[E1] 0.0133 3 +237NP2 G KC=0.0107 2$LC=0.00195 4$MC=0.00047 1$NC=1.258E-4 18 +237NP3 G OC=3.07E-5 5 +237NP G 546.12 6 2.5E-7 3[E1] 0.0117 2 +237NP2 G KC=0.00947 19$LC=0.00171 3$MC=0.00041 1$NC=1.104E-4 16 +237NP3 G OC=2.69E-5 4 +237NP L 590.09 4 (7/2)- +237NP A 4963.83 131E-9 +237NP G 322.52 4 +237NP G 487.13 4 6.2E-7 5[M1] 0.291 6 +237NP2 G KC=0.232 6$LC=0.0449 9$MC=0.0109 2$NC=0.00294 5 +237NP3 G OC=0.000724 11 +237NP G 590.09 4 2.80E-6 6[E1] 0.0101 2 +237NP2 G KC=0.00818 16$LC=0.00147 3$MC=0.000351 7$NC=9.44E-5 14 +237NP3 G OC=2.30E-5 4 +237NP L 592.33 7 13/2+ +237NP A 4961.63 141E-9 +237NP G 139.44 8 5.3E-6 11[E2] 3.37 7 +237NP2 G KC=0.211 4$LC=2.29 5$MC=0.638 13$NC=0.1745 25 +237NP3 G OC=0.0407 6 +237NP G 159.26 201.4E-6 5[E1] 0.171 4 +237NP2 G KC=0.132 3$LC=0.0292 6$MC=0.00711 14$NC=0.00191 3 +237NP3 G OC=0.000456 7 +237NP G 196.76 8 4.9E-7 [E1] 0.1045 21 +237NP2 G KC=0.0816 16$LC=0.0172 4$MC=0.00418 9$NC=0.001122 16 +237NP3 G OC=0.000269 4 +237NP G 400.78 101.4E-7 3[M1+E2] 0.29 21 +237NP2 G KC=0.22 18$LC=0.054 23$MC=0.013 6$NC=0.0036 14 +237NP3 G OC=0.0009 4 +237NP G 462.34 8 0.000001 [M1+E2] 0.20 14 +237NP2 G KC=0.15 12$LC=0.035 17$MC=0.009 4$NC=0.0024 10 +237NP3 G OC=0.0006 3 +237NP L 597.99 9 11/2+ +237NP A 4956.06 151E-9 +237NP G 138.30 9 +237NP G 406.35 151.37E-6 5[M1+E2] 0.28 20 +237NP2 G KC=0.21 17$LC=0.052 22$MC=0.013 5$NC=0.0035 14 +237NP3 G OC=0.0008 4 +237NP G 468.12 152.69E-6 6[M1+E2] 0.19 14 +237NP2 G KC=0.15 12$LC=0.034 16$MC=0.008 4$NC=0.0023 10 +237NP3 G OC=0.00056 25 +237NP G 522.06 159.9E-7 5[M1+E2] 0.14 10 +237NP2 G KC=0.11 9$LC=0.025 13$MC=0.006 3$NC=0.0017 8 +237NP3 G OC=0.00041 19 +237NP L 646.03 17(9/2)- +237NP G 586.59 201.24E-6 5[E2] 0.0346 7 +237NP2 G KC=0.0224 4$LC=0.00903 18$MC=0.00235 5$NC=0.000639 9 +237NP3 G OC=1.530E-4 22 +237NP L 666.19 10(5/2,7/2)+ +237NP A 4888.98 151E-9 +237NP G 398.64 15 +237NP G 632.93 151.24E-6 5 +237NP G 666.2 2 9.5E-7 7 +237NP L 721.961 135/2- +237NP A 4834.15 130.0007 9.5 +237NP G 563.46 2 4.4E-7 2[E2] 0.0378 8 +237NP2 G KC=0.0241 5$LC=0.0102 2$MC=0.00266 5$NC=0.000723 11 +237NP3 G OC=1.730E-4 25 +237NP G 619.01 2 0.000060 2[M1+E2] 0.09 7 +237NP2 G KC=0.07 5$LC=0.016 8$MC=0.0037 10$NC=0.0010 5 +237NP3 G OC=0.00025 13 +237NP G 662.40 2 0.000367 6(E0+M1+E2) 0.23 5 +237NP2 G KC=0.18 4$LC=0.045 15 +237NP G 688.72 4 3.23E-5 6[E1] 0.0075816 +237NP2 G KC=0.00615 12$LC=0.00108 2$MC=0.000259 5$NC=6.96E-5 10 +237NP3 G OC=1.702E-5 24 +237NP G 721.96 2 0.000196 5[E1] 0.0070 2 +237NP2 G KC=0.0056 1$LC=0.00099 2$MC=0.00024 1$NC=6.36E-5 9 +237NP3 G OC=1.555E-5 22 +237NP L 755.685 197/2- +237NP A 4800.99 130.000086 44 +237NP G 597.19 2 7.29E-6 11[M1+E2] 0.10 7 +237NP2 G KC=0.08 6$LC=0.017 9$MC=0.0042 20$NC=0.0011 6 +237NP3 G OC=0.00028 14 +237NP G 652.73 2 3.76E-5 9[M1+E2] 0.08 6 +237NP2 G KC=0.06 5$LC=0.013 7$MC=0.0033 10$NC=0.0009 5 +237NP3 G OC=0.00022 11 +237NP G 679.79 2 3.31E-6 8[E1] 0.0077616 +237NP2 G KC=0.00630 13$LC=0.00111 2$MC=0.000265 5$NC=7.14E-5 10 +237NP3 G OC=1.745E-5 25 +237NP G 696.14 2 5.17E-6 8[M1+E2] 0.07 5 +237NP2 G KC=0.05 4$LC=0.011 6$MC=0.0028 10$NC=0.0008 4 +237NP3 G OC=0.00018 10 +237NP G 755.68 2 7.84E-6 11[E1] 0.0064 1 +237NP2 G KC=0.0052 1$LC=0.00091 1$MC=0.000217 4$NC=5.83E-5 9 +237NP3 G OC=1.425E-5 20 +237NP L 770.57 5 +237NP G 446.15 6 1.1E-7 2 +237NP G 737.34 5 7.94E-6 11 +237NP G 770.57 104.81E-6 7 +237NP L 799.82 4 9/2- +237NP A 4757.58 130.00004 347 +237NP G 77.86 4 +237NP G 573.94 201.28E-6 5[M1+E2] 0.11 8 +237NP2 G KC=0.09 7$LC=0.019 10$MC=0.0027 16$NC=0.0013 6 +237NP3 G OC=0.00031 15 +237NP G 641.32 4 7.04E-6 10[M1+E2] 0.08 6 +237NP2 G KC=0.06 5$LC=0.014 8$MC=0.0035 10$NC=0.0009 5 +237NP3 G OC=0.00023 12 +237NP G 669.83 2 5.1E-7 7[E1] 0.0080 2 +237NP2 G KC=0.00647 13$LC=0.00114 2$MC=0.00073 1$NC=7.35E-5 11 +237NP3 G OC=1.80E-5 3 +237NP G 766.62 4 5.01E-6 6[E1] 0.0062312 +237NP2 G KC=0.00507 10$LC=0.00088 2$MC=0.000211 4$NC=5.67E-5 8 +237NP3 G OC=1.387E-5 20 +237NP L 805.77 12(7/2,9/2)+ +237NP G 675.78 138.5E-7 5[E2,M1] 0.07 5 +237NP2 G KC=0.06 4$LC=0.012 7$MC=0.0030 15$NC=0.0008 4 +237NP3 G OC=0.0002 1 +237NP G 729.72 151.37E-6 5[M1] 0.099 2 +237NP2 G KC=0.079 2$LC=0.0151 4$MC=0.0036 1$NC=0.000986 14 +237NP3 G OC=0.000243 4 +237NP G 772.57 122.79E-6 4[M1] 0.0847 17 +237NP2 G KC=0.0675 14$LC=0.0129 3$MC=0.00312 6$NC=0.000846 12 +237NP3 G OC=0.000208 3 +237NP G 805.77 123.1E-7 [M1,E2] 0.05 3 +237NP2 G KC=0.037 24$LC=0.008 4$MC=0.0019 10$NC=0.00051 25 +237NP3 G OC=0.00012 7 +237NP L 853.36 1511/2- +237NP G 529.17 206.9E-7 5[E2] 0.0437 9 +237NP2 G KC=0.0269 5$LC=0.0124 2$MC=0.00324 6$NC=0.000883 13 +237NP3 G OC=0.000211 3 +237NP G 627.18 205.1E-7 2[M1+E2] 0.09 6 +237NP2 G KC=0.07 5$LC=0.015 8$MC=0.0037 10$NC=0.0010 5 +237NP3 G OC=0.00025 12 +237NP L 861.65 19(5/2,7/2)+ +237NP G 786.00 156.2E-7 +237NP G 801.94 201.23E-6 7 +237NP G 828.60 122.1E-7 4 +237NP G 861.80 126.1E-7 6 +237NP L 920.88 20 +237NP G 861.34 208E-8 3 +237NP G 887.68 203.3E-7 6 +237NP G 920.88 201.9E-7 3 +237NP L 946 2 +237NP G 946.06 1.0E-8 2 +237NP L 962 3 +237NP G 962.19 4E-8 1 +237NP L 1014 3 +237NP G 1014.33 1.0E-6 2 + diff --git a/HEN_HOUSE/spectra/lnhb/Am-242.txt b/HEN_HOUSE/spectra/lnhb/Am-242.txt index e057f312b..5900d913e 100644 --- a/HEN_HOUSE/spectra/lnhb/Am-242.txt +++ b/HEN_HOUSE/spectra/lnhb/Am-242.txt @@ -1,83 +1,83 @@ -242PU 242AM EC DECAY (16.01 H) -242PU H TYP=Full$AUT=A.L. Nichols$CUT=30-SEP-2008$ -242PU C Evaluation history: Type=Full;Author=A.L. Nichols;Cutoff date=30-SEP-2008 -242PU C References: 1953Ke38, 1955Ba31, 1955Ho67, 1959Ba22, 1959Ho02, 1960As05, -242PU2C 1961Ma27, 1969Al20, 1969Ga17, 1972Ga35, 1977La19, 1980VyZZ, 1982Wi05, -242PU3C 1996Sc06, 1998ScZM, 1999ScZX, 2002Ak06, 2002Ba85, 2002Ra45, 2003Au03, -242PU4C 2008Ki07 -242PU T Auger electrons and X ray energies and emission intensities: -242PU T {U Energy (keV)} {U Intensity} {U Line} -242PU T -242PU T 99.525 3.55 17 XKA2 -242PU T 103.734 5.6 3 XKA1 -242PU T -242PU T 116.244 |] XKB3 -242PU T 117.228 |] 2.06 11 XKB1 -242PU T 117.918 |] XKB5II -242PU T -242PU T 120.54 |] XKB2 -242PU T 120.969 |] 0.72 4 XKB4 -242PU T 121.543 |] XKO23 -242PU T -242PU T 12.124-22.153 10.8 5 XL (total) -242PU T 12.124 0.293 11 XLL -242PU T 14.087-14.282 4.56 16 XLA -242PU T 16.333 0.084 4 XLC -242PU T 16.498-18.541 4.64 15 XLB -242PU T 21.42-22.153 1.03 4 XLG -242PU T -242PU T 75.263-85.357 |] KLL AUGER -242PU T 92.607-103.729 |] 0.36 4 KLX AUGER -242PU T 109.93-121.78 |] KXY AUGER -242PU T 6.19-22.99 9.9 5 L AUGER -242AM P 0.0 1- 16.01 H 2 751.3 7 -242PU N 5.917E0 5.917E0 0.169 5.917E0 -242PU L 0 0 0+ 3.73E5 Y 3 -242PU E 6.3 67.55 1 -242PU2 E CK=0.7303 22$CL=0.1987 15$CM=0.0522 10 -242PU L 44.54 2 2+ -242PU E 10.6 57.26 1 -242PU2 E CK=0.7261 23$CL=0.2016 15$CM=0.0532 10$CN=0.0152 7 -242PU G 44.54 2 0.014 1E2 748 11 -242PU2 G LC=543 8$MC=151.6 22 - -242CM 242AM B- DECAY (16.01 H) -242CM H TYP=Full$AUT=A.L. Nichols$CUT=30-SEP-2008$ -242CM C Evaluation history: Type=Full;Author=A.L. Nichols;Cutoff date=30-SEP-2008 -242CM C References: 1953Ke38, 1955Ba31, 1955Ho67, 1959Ba22, 1959Ho02, 1960As05, -242CM2C 1961Ma27, 1969Al20, 1969Ga17, 1972Ga35, 1977La19, 1980VyZZ, 1982Wi05, -242CM3C 1996Sc06, 1998ScZM, 1999ScZX, 2002Ak06, 2002Ba85, 2002Ra45, 2003Au03, -242CM4C 2008Ki07 -242CM T Auger electrons and X ray energies and emission intensities: -242CM T {U Energy (keV)} {U Intensity} {U Line} -242CM T -242CM T 104.59 XKA2 -242CM T 109.271 XKA1 -242CM T -242CM T 122.304 |] XKB3 -242CM T 123.403 |] XKB1 -242CM T 124.124 |] XKB5II -242CM T -242CM T 126.889 |] XKB2 -242CM T 127.352 |] XKB4 -242CM T 127.97 |] XKO23 -242CM T -242CM T 12.633-23.527 18.0 11 XL (total) -242CM T 12.633 0.451 22 XLL -242CM T 14.746-14.961 6.8 3 XLA -242CM T 17.314 0.194 11 XLC -242CM T 17.286-19.688 8.7 4 XLB -242CM T 22.735-23.527 2.09 10 XLG -242CM T -242CM T 6.19-14.46 15.4 10 L AUGER -242AM P 0.0 1- 16.01 H 2 664.5 4 -242CM N 1.203E0 1.203E0 0.831 1.203E0 -242CM L 0 0+ 162.86 D 8 -242CM B 664.5 4 37.3 23 7.03 1 -242CMS B EAV=200.17 14 -242CM L 42.13 5 2+ -242CM B 622.4 4 45.8 23 6.84 1 -242CMS B EAV=185.92 14 -242CM G 42.13 5 0.040 2E2 1155 17 -242CM2 G LC=836 13$MC=235 4 - +242PU 242AM EC DECAY (16.01 H) +242PU H TYP=FUL$AUT=A.L.NICHOLS$CUT=30-SEP-2008$ +242PU C References:1953Ke38, 1955Ba31, 1955Ho67, 1959Ba22, 1959Ho02, 1960As05, +242PU2C 1961Ma27, 1969Al20, 1969Ga17, 1972Ga35, 1977La19, 1980VyZZ, 1982Wi05, +242PU3C 1996Sc06, 1998ScZM, 1999ScZX, 2002Ak06, 2002Ba85, 2002Ra45, 2003Au03, +242PU4C 2008Ki07 +242PU T Auger electrons and X ray energies and emission intensities: +242PU T {U Energy (keV)} {U Intensity} {U Line} +242PU T +242PU T 99.525 3.55 17 XKA2 +242PU T 103.734 5.6 3 XKA1 +242PU T +242PU T 116.244 |] XKB3 +242PU T 117.228 |] 2.06 11 XKB1 +242PU T 117.918 |] XKB5II +242PU T +242PU T 120.54 |] XKB2 +242PU T 120.969 |] 0.72 4 XKB4 +242PU T 121.543 |] XKO23 +242PU T +242PU T 12.124-22.153 10.8 5 XL (total) +242PU T 12.124 0.293 11 XLL +242PU T 14.087-14.282 4.56 16 XLA +242PU T 16.333 0.084 4 XLC +242PU T 16.498-18.541 4.64 15 XLB +242PU T 21.42-22.153 1.03 4 XLG +242PU T +242PU T 75.263-85.357 |] KLL AUGER +242PU T 92.607-103.729 |] 0.36 4 KLX AUGER +242PU T 109.93-121.78 |] KXY AUGER +242PU T 6.19-22.99 9.9 5 L AUGER +242AM P 0.0 1- 16.01 H 2 751.3 7 +242PU N 5.917E0 5.917E0 0.169 5.917E0 +242PU L 0 0+ 3.73E5 Y 3 +242PU E 6.3 67.55 1 +242PU2 E CK=0.7303 22$CL=0.1987 15$CM=0.0522 10 +242PU L 44.54 2 2+ +242PU E 10.6 57.26 1 +242PU2 E CK=0.7261 23$CL=0.2016 15$CM=0.0532 10$CN=0.0152 7 +242PU G 44.54 2 0.014 1E2 748 11 +242PU2 G LC=543 8$MC=151.6 22$NC=41.6 6 +242PU3 G OC=9.78 14 + +242CM 242AM B- DECAY (16.01 H) +242CM H TYP=FUL$AUT=A.L.NICHOLS$CUT=30-SEP-2008$ +242CM C References:1953Ke38, 1955Ba31, 1955Ho67, 1959Ba22, 1959Ho02, 1960As05, +242CM2C 1961Ma27, 1969Al20, 1969Ga17, 1972Ga35, 1977La19, 1980VyZZ, 1982Wi05, +242CM3C 1996Sc06, 1998ScZM, 1999ScZX, 2002Ak06, 2002Ba85, 2002Ra45, 2003Au03, +242CM4C 2008Ki07 +242CM T Auger electrons and X ray energies and emission intensities: +242CM T {U Energy (keV)} {U Intensity} {U Line} +242CM T +242CM T 104.59 XKA2 +242CM T 109.271 XKA1 +242CM T +242CM T 122.304 |] XKB3 +242CM T 123.403 |] XKB1 +242CM T 124.124 |] XKB5II +242CM T +242CM T 126.889 |] XKB2 +242CM T 127.352 |] XKB4 +242CM T 127.97 |] XKO23 +242CM T +242CM T 12.633-23.527 18.0 11 XL (total) +242CM T 12.633 0.451 22 XLL +242CM T 14.746-14.961 6.8 3 XLA +242CM T 17.314 0.194 11 XLC +242CM T 17.286-19.688 8.7 4 XLB +242CM T 22.735-23.527 2.09 10 XLG +242CM T +242CM T 6.19-14.46 15.4 10 L AUGER +242AM P 0.0 1- 16.01 H 2 664.5 4 +242CM N 1.203E0 1.203E0 0.831 1.203E0 +242CM L 0 0+ 162.86 D 8 +242CM B 664.5 4 37.3 23 7.03 1 +242CMS B EAV=200.17 14 +242CM L 42.13 5 2+ +242CM B 622.4 4 45.8 23 6.84 1 +242CMS B EAV=185.92 14 +242CM G 42.13 5 0.040 2E2 1155 17 +242CM2 G LC=836 13$MC=235 4$NC=65.5 10 +242CM3 G OC=15.82 24 + diff --git a/HEN_HOUSE/spectra/lnhb/Am-242m.txt b/HEN_HOUSE/spectra/lnhb/Am-242m.txt index e8251b40a..26d09e2a6 100644 --- a/HEN_HOUSE/spectra/lnhb/Am-242m.txt +++ b/HEN_HOUSE/spectra/lnhb/Am-242m.txt @@ -1,257 +1,312 @@ -242AM 242AM IT DECAY (143 Y) -242AM H TYP=Full$AUT=A. Nichols$CUT=30-APR-2010$ -242AM C Evaluation history: Type=Full;Author=A. Nichols;Cutoff date=30-APR-2010 -242AM C References: 1950St61, 1959Ba22, 1960As05, 1967Ca04, 1977La19, 1979Ba67, -242AM2C 1979Ze05, 1980VyZZ, 1986Ze06, 1990Ho02, 1996Sc06, 1998Ak04, 1998ScZM, -242AM3C 1999ScZX, 2002Ak06, 2002Ba25, 2002Ch52, 2002Ra45, 2003Au03, 2008Ki07 -242AM T Auger electrons and X ray energies and emission intensities: -242AM T {U Energy (keV)} {U Intensity} {U Line} -242AM T -242AM T 102.03 XKA2 -242AM T 106.472 XKA1 -242AM T -242AM T 119.243 |] XKB3 -242AM T 120.284 |] XKB1 -242AM T 120.989 |] XKB5II -242AM T -242AM T 123.58 |] XKB2 -242AM T 124.127 |] XKB4 -242AM T 124.723 |] XKO23 -242AM T -242AM T 12.377-22.836 25.0 11 XL (total) -242AM T 12.377 0.608 18 XLL -242AM T 14.414-14.62 9.33 24 XLA -242AM T 16.819 0.274 9 XLC -242AM T 16.89-19.11 12.2 3 XLB -242AM T 22.072-22.836 2.90 8 XLG -242AM T -242AM T 77.04-85.638 |] KLL AUGER -242AM T 94.891-106.467 |] KLX AUGER -242AM T 112.72-124.97 |] KXY AUGER -242AM T 6.26-23.7 22.1 11 L AUGER -242AM P 48.60 5 5- 143 Y 2 -242AM N 1.005E0 1.005E0 0.9954 1.005E0 -242AM G 89.60 5 0.0013 3 -242AM G 160.61 2 0.00041 18 -242AM G 165.97 150.00004623 -242AM G 233.69 100.00013 3 -242AM L 0 1- 16.01 H 2 -242AM L 48.60 5 5- 143 Y 2 -242AM G 48.60 5 1.414E-422E4 7.04E5 8 -242AM2 G LC=3.33E5 5$MC=2.66E5 5 - -238NP 242AM A DECAY (143 Y) -238NP H TYP=Full$AUT=A. Nichols$CUT=30-APR-2010$ -238NP C Evaluation history: Type=Full;Author=A. Nichols;Cutoff date=30-APR-2010 -238NP C References: 1950St61, 1959Ba22, 1960As05, 1967Ca04, 1977La19, 1979Ba67, -238NP2C 1979Ze05, 1980VyZZ, 1986Ze06, 1990Ho02, 1996Sc06, 1998Ak04, 1998ScZM, -238NP3C 1999ScZX, 2002Ak06, 2002Ba25, 2002Ch52, 2002Ra45, 2003Au03, 2008Ki07 -238NP T Auger electrons and X ray energies and emission intensities: -238NP T {U Energy (keV)} {U Intensity} {U Line} -238NP T -238NP T 97.069 0.019 9 XKA2 -238NP T 101.059 0.030 14 XKA1 -238NP T -238NP T 113.303 |] XKB3 -238NP T 114.234 |] 0.011 5 XKB1 -238NP T 114.912 |] XKB5II -238NP T -238NP T 117.463 |] XKB2 -238NP T 117.876 |] 0.0037 17 XKB4 -238NP T 118.429 |] XKO23 -238NP T -238NP T 11.871-21.491 0.37 4 XL (total) -238NP T 11.871 0.0090 9 XLL -238NP T 13.761-13.946 0.143 13 XLA -238NP T 15.861 0.0022 4 XLC -238NP T 16.109-17.992 0.164 13 XLB -238NP T 20.784-21.491 0.040 3 XLG -238NP T -238NP T 73.501-83.134 |] KLL AUGER -238NP T 90.358-101.054 |] 0.0019 7 KLX AUGER -238NP T 107.19-118.66 |] KXY AUGER -238NP T 6.036-13.516 0.35 4 L AUGER -242AM P 48.60 5 5- 143 Y 2 5588.50 25 -238NP N 2.174E2 2.174E2 0.0046 2.174E2 -238NP G 89.60 5 0.0013 3 -238NP G 160.61 2 0.00041 18 -238NP G 165.97 150.00004623 -238NP G 233.69 100.00013 3 -238NP L 0 2+ 2.102 D 5 -238NP L 26.427 2 3+ -238NP A 5517.93 250.003 3 4000000 -238NP G 26.427 2 0.000708 M1+E2 0.1 338 5 -238NP2 G LC=252 4$MC=63.7 9 -238NP L 62.330 4 4+ -238NP L 86.674 2 3+ -238NP A 5458.68 250.139 3939000 -238NP G 24.34 1 0.000064 9M1+E2 0.01 322 5 -238NP2 G LC=242 4$MC=59.6 9 -238NP G 60.247 3 0.0055 5M1+E2 0.07 23.1 4 -238NP2 G LC=17.34 25$MC=4.23 6 -238NP G 86.674 2 0.0229 7M1+E2 0.1 7.95 12 -238NP2 G LC=5.98 9$MC=1.459 21 -238NP L 106.155 155+ -238NP L 121.645 9 4+ -238NP L 136.045 2 3- 6 NS -238NP A 5410.13 251.0 2 2820 -238NP G 49.371 3 0.134 4E1 0.821 12 -238NP2 G LC=0.615 9$MC=0.1536 22 -238NP G 73.72 1 0.0079 6E1 0.285 4 -238NP2 G LC=0.214 3$MC=0.0529 8 -238NP G 109.618 3 0.0184 E1 0.1010 15 -238NP2 G LC=0.0760 11$MC=0.0186 3 -238NP G 136.045 2 0.0094 3E1 0.247 4 -238NP2 G KC=0.190 3$LC=0.0436 6$MC=0.01064 15 -238NP L 161.69 2 6+ -238NP L 165.532 155+ -238NP G 139.11 2 0.00011 E2 3.40 5 -238NP2 G KC=0.211 3$LC=2.32 4$MC=0.646 9 -238NP L 179.154 7 4- -238NP A 5367.73 251.11 201430 -238NP G 43.11 1 0.00006414M1+E2 0.045 61.3 9 -238NP2 G LC=46.1 7$MC=11.25 16 -238NP G 57.51 1 0.00097 23E1 0.549 8 -238NP2 G LC=0.412 6$MC=0.1023 15 -238NP G 92.48 1 0.0028 3E1 0.1574 22 -238NP2 G LC=0.1184 17$MC=0.0291 4 -238NP G 152.73 1 0.00069 E1 0.189 3 -238NP2 G KC=0.1457 21$LC=0.0324 5$MC=0.00791 11 -238NP L 182.878 2 2- -238NP G 46.833 3 7.4E-6 14M1+E2 0.063 48.8 7 -238NP2 G LC=36.7 6$MC=8.97 13 -238NP G 156.451 3 0.00027 5E1 0.1784 25 -238NP2 G KC=0.1379 20$LC=0.0305 5$MC=0.00744 11 -238NP G 182.878 2 0.00092 3E1 0.1238 18 -238NP2 G KC=0.0965 14$LC=0.0206 3$MC=0.00502 7 -238NP L 215.522 4 3- -238NP A 5331.97 250.15 116400 -238NP G 32.64 1 0.000019 3M1+E2 0.014 136.4 20 -238NP2 G LC=102.6 15$MC=25.0 4 -238NP G 79.48 1 0.00012423M1+E2 1.0 2 26 4 -238NP2 G LC=19 3$MC=5.2 8 -238NP G 93.88 1 0.0036 4E1 0.1513 22 -238NP2 G LC=0.1138 16$MC=0.0280 4 -238NP G 153.19 1 0.00031 4E1 0.187 3 -238NP2 G KC=0.1447 21$LC=0.0322 5$MC=0.00785 11 -238NP G 189.10 1 0.00027 5E1 0.1146 16 -238NP2 G KC=0.0894 13$LC=0.0190 3$MC=0.00462 7 -238NP G 215.522 4 0.00059 10E1 0.0847 12 -238NP2 G KC=0.0664 10$LC=0.01376 20$MC=0.00334 5 -238NP L 218.7 6 (6)+ -238NP L 232.828 8 5- -238NP A 5314.95 250.61 111250 -238NP G 53.67 1 0.0021 3M1+E2 0.25 46.0 7 -238NP2 G LC=34.2 5$MC=8.73 13 -238NP G 96.78 1 0.00033 6E2 16.90 24 -238NP2 G LC=12.28 18$MC=3.42 5 -238NP G 111.18 1 0.0025 4E1 0.0974 14 -238NP2 G LC=0.0733 11$MC=0.0180 3 -238NP L 250.33 3 (1)+ -238NP G 250.33 3 0.00056 (M1+E2) 1.0 2 1.08 16 -238NP2 G KC=0.77 15$LC=0.233 12$MC=0.0595 21 -238NP L 258.853 8 4- -238NP G 43.33 1 8.7E-6 14M1+E2 0.32 126.7 18 -238NP2 G LC=93.5 14$MC=24.6 4 -238NP G 75.98 1 9.7E-6 14E2 52.8 8 -238NP2 G LC=38.4 6$MC=10.70 15 -238NP G 122.81 1 0.00004 2M1+E2 1.0 2 9.6 9 -238NP2 G KC=5.4 12$LC=3.11 22$MC=0.83 7 -238NP G 152.70 2 0.00069 E1 0.189 3 -238NP2 G KC=0.1458 21$LC=0.0325 5$MC=0.00791 11 -238NP G 196.52 1 0.00010 5E1 0.1048 15 -238NP2 G KC=0.0819 12$LC=0.01725 25$MC=0.00419 6 -238NP G 232.43 1 0.00056 3E1 0.0712 10 -238NP2 G KC=0.0560 8$LC=0.01145 16$MC=0.00278 4 -238NP L 275.519 9 5+ -238NP A 5272.96 251.00 11414 -238NP G 153.87 1 0.00332 10M1+E2 0.14 7.02 10 -238NP2 G KC=5.53 8$LC=1.123 16$MC=0.273 4 -238NP G 213.19 1 0.00005518M1+E2 1.0 2 1.73 25 -238NP2 G KC=1.19 24$LC=0.401 11$MC=0.1032 17 -238NP L 297.03 5 (6)- -238NP A 5251.80 250.020 1115300 -238NP G 131.50 5 0.00027 6E1 0.268 4 -238NP2 G KC=0.205 3$LC=0.0475 7$MC=0.01161 17 -238NP G 190.88 5 0.00010624E1 0.1121 16 -238NP2 G KC=0.0875 13$LC=0.0185 3$MC=0.00451 7 -238NP L 299.23 6 (3)+ -238NP A 5249.64 260.020 1114800 -238NP G 236.90 6 0.00004623M1+E2 1.0 2 1.27 19 -238NP2 G KC=0.89 18$LC=0.280 12$MC=0.0717 21 -238NP G 272.80 6 0.000037 8M1+E2 1.0 2 0.85 13 -238NP2 G KC=0.61 12$LC=0.176 11$MC=0.0448 21 -238NP G 299.23 6 0.00002814M1+E2 1.0 2 0.65 10 -238NP2 G KC=0.48 9$LC=0.131 9$MC=0.0332 19 -238NP L 300.68 7 (1 to 4)- -238NP A 5248.21 260.39 11730 -238NP G 85.16 7 0.0010 3M1+E2 1.0 2 19 3 -238NP2 G LC=14.3 18$MC=3.9 6 -238NP G 238.35 7 0.000016 8E1 0.0673 10 -238NP2 G KC=0.0530 8$LC=0.01078 16$MC=0.00261 4 -238NP L 300.743 16(6)- -238NP A 5248.15 250.39 11730 -238NP G 67.92 2 0.0040 3M1+E2 0.35 6 24 3 -238NP2 G LC=17.7 19$MC=4.6 6 -238NP G 135.21 2 0.0068 4E1 0.251 4 -238NP2 G KC=0.192 3$LC=0.0443 7$MC=0.01081 16 -238NP G 139.05 3 0.00011 E1 0.235 4 -238NP2 G KC=0.180 3$LC=0.0412 6$MC=0.01006 15 -238NP G 194.59 2 0.00142 5E1 0.1072 15 -238NP2 G KC=0.0837 12$LC=0.01768 25$MC=0.00430 6 -238NP L 312.70 2 5- -238NP G 53.85 2 2.8E-6 14M1+E2 0.16 37.2 6 -238NP2 G LC=27.8 4$MC=6.93 10 -238NP G 97.18 2 0.000007 4E2 16.58 24 -238NP2 G LC=12.05 17$MC=3.36 5 -238NP G 151.01 3 0.00008318E1 0.194 3 -238NP2 G KC=0.1495 21$LC=0.0334 5$MC=0.00814 12 -238NP G 176.66 2 0.00002814E2 1.285 18 -238NP2 G KC=0.181 3$LC=0.804 12$MC=0.223 4 -238NP G 250.37 2 0.00056 E1 0.0602 9 -238NP2 G KC=0.0475 7$LC=0.00958 14$MC=0.00232 4 -238NP L 328.6 5 6+ -238NP G 163.1 5 0.0161 M1+E2 1.0 2 3.9 5 -238NP2 G KC=2.5 5$LC=1.04 3$MC=0.273 11 -238NP L 334.0 6 (1 to 3)- -238NP A 5215.4 7 0.030 116000 -238NP L 342.439 8 5- -238NP A 5207.15 2588.9 201.8 -238NP G 66.92 1 0.0150 5E1 0.368 6 -238NP2 G LC=0.277 4$MC=0.0684 10 -238NP G 109.61 1 0.0184 M1+E2 1.0 2 6.7 7 -238NP2 G LC=4.9 5$MC=1.32 14 -238NP G 126.92 1 0.00013 7E2 5.03 7 -238NP2 G KC=0.196 3$LC=3.51 5$MC=0.979 14 -238NP G 163.29 1 0.0161 M1+E2 1.0 2 3.9 5 -238NP2 G KC=2.5 5$LC=1.04 3$MC=0.272 11 -238NP G 206.39 1 0.00156 18E2 0.711 10 -238NP2 G KC=0.1454 21$LC=0.412 6$MC=0.1138 16 -238NP G 280.11 1 0.000060 6E1 0.0468 7 -238NP2 G KC=0.0371 6$LC=0.00735 11$MC=0.00178 3 -238NP L 374.7 10(5)+ -238NP A 5175.4 100.020 115000 -238NP L 376.70 7 (6)- -238NP A 5173.45 260.020 114900 -238NP G 270.55 7 0.000029 8E1 0.0506 7 -238NP2 G KC=0.0400 6$LC=0.00798 12$MC=0.00193 3 -238NP L 389.4 5 7+ -238NP G 170.7 8 0.00063 5M1+E2 1.0 2 3.4 5 -238NP2 G KC=2.2 5$LC=0.882 23$MC=0.230 9 -238NP L 397.3 15 + -238NP A 5153.2 150.020 113600 -238NP L 407.59 6 6- -238NP A 5143.07 265.61 2411.2 -238NP G 174.76 6 0.00017 4M1+E2 1.0 2 3.1 4 -238NP2 G KC=2.1 5$LC=0.809 17$MC=0.211 7 -238NP L 459.6 6 (6)+ -238NP A 5091.9 7 0.20 7 146 -238NP L 469.1 12(1 to 4)- -238NP A 5082.6 120.030 11840 -238NP L 484 3 7- -238NP A 5068 3 0.26 7 81 -238NP L 525.3 15(7)+ -238NP A 5027.3 150.020 11540 -238NP L 578 3 + -238NP A 4975 3 0.0020 112400 - +242AM 242AM IT DECAY (143 Y) +242AM H TYP=FUL$AUT=A.L.NICHOLS$CUT=30-APR-2010$ +242AM C References:1950St61, 1959Ba22, 1960As05, 1967Ca04, 1977La19, 1979Ba67, +242AM2C 1979Ze05, 1980VyZZ, 1986Ze06, 1990Ho02, 1996Sc06, 1998Ak04, 1998ScZM, +242AM3C 1999ScZX, 2002Ak06, 2002Ba25, 2002Ch52, 2002Ra45, 2003Au03, 2008Ki07 +242AM T Auger electrons and X ray energies and emission intensities: +242AM T {U Energy (keV)} {U Intensity} {U Line} +242AM T +242AM T 102.03 XKA2 +242AM T 106.472 XKA1 +242AM T +242AM T 119.243 |] XKB3 +242AM T 120.284 |] XKB1 +242AM T 120.989 |] XKB5II +242AM T +242AM T 123.58 |] XKB2 +242AM T 124.127 |] XKB4 +242AM T 124.723 |] XKO23 +242AM T +242AM T 12.377-22.836 25.0 11 XL (total) +242AM T 12.377 0.608 18 XLL +242AM T 14.414-14.62 9.33 24 XLA +242AM T 16.819 0.274 9 XLC +242AM T 16.89-19.11 12.2 3 XLB +242AM T 22.072-22.836 2.90 8 XLG +242AM T +242AM T 77.04-85.638 |] KLL AUGER +242AM T 94.891-106.467 |] KLX AUGER +242AM T 112.72-124.97 |] KXY AUGER +242AM T 6.26-23.7 22.1 11 L AUGER +242AM P 48.60 5 5- 143 Y 2 +242AM N 1.005E0 1.005E0 0.9954 +242AM L 0 1- 16.01 H 2 +242AM L 48.60 5 5- 143 Y 2 +242AM G 48.60 5 1.414E-422E4 7.04E5 8 +242AM2 G LC=3.33E5 5$MC=2.66E5 5$NC=8.43E4 14 +242AM3 G OC=1.92E4 3 + +238NP 242AM A DECAY (143 Y) +238NP H TYP=FUL$AUT=A.L.NICHOLS$CUT=30-APR-2010$ +238NP C References:1950St61, 1959Ba22, 1960As05, 1967Ca04, 1977La19, 1979Ba67, +238NP2C 1979Ze05, 1980VyZZ, 1986Ze06, 1990Ho02, 1996Sc06, 1998Ak04, 1998ScZM, +238NP3C 1999ScZX, 2002Ak06, 2002Ba25, 2002Ch52, 2002Ra45, 2003Au03, 2008Ki07 +238NP T Auger electrons and X ray energies and emission intensities: +238NP T {U Energy (keV)} {U Intensity} {U Line} +238NP T +238NP T 97.069 0.019 9 XKA2 +238NP T 101.059 0.030 14 XKA1 +238NP T +238NP T 113.303 |] XKB3 +238NP T 114.234 |] 0.011 5 XKB1 +238NP T 114.912 |] XKB5II +238NP T +238NP T 117.463 |] XKB2 +238NP T 117.876 |] 0.0037 17 XKB4 +238NP T 118.429 |] XKO23 +238NP T +238NP T 11.871-21.491 0.37 4 XL (total) +238NP T 11.871 0.0090 9 XLL +238NP T 13.761-13.946 0.143 13 XLA +238NP T 15.861 0.0022 4 XLC +238NP T 16.109-17.992 0.164 13 XLB +238NP T 20.784-21.491 0.040 3 XLG +238NP T +238NP T 73.501-83.134 |] KLL AUGER +238NP T 90.358-101.054 |] 0.0019 7 KLX AUGER +238NP T 107.19-118.66 |] KXY AUGER +238NP T 6.036-13.516 0.35 4 L AUGER +242AM P 48.60 5 5- 143 Y 2 5588.50 25 +238NP N 2.174E2 2.174E2 0.0046 +238NP G 89.60 5 0.0013 3 +238NP G 160.61 2 0.00041 18 +238NP G 165.97 150.00004623 +238NP G 233.69 100.00013 3 +238NP L 0 2+ 2.102 D 5 +238NP L 26.427 2 3+ +238NP A 5517.93 250.003 34000000 +238NP G 26.427 2 0.000708 M1+E2 0.1 338 5 +238NP2 G LC=252 4$MC=63.7 9$NC=17.29 25 +238NP3 G OC=4.19 6 +238NP L 62.330 4 4+ +238NP L 86.674 2 3+ +238NP A 5458.68 250.139 3939000 +238NP G 24.34 1 0.000064 9M1+E2 0.01 322 5 +238NP2 G LC=242 4$MC=59.6 9$NC=16.15 23 +238NP3 G OC=3.98 6 +238NP G 60.247 3 0.0055 5M1+E2 0.07 23.1 4 +238NP2 G LC=17.34 25$MC=4.23 6$NC=1.147 16 +238NP3 G OC=0.282 4 +238NP G 86.674 2 0.0229 7M1+E2 0.1 7.95 12 +238NP2 G LC=5.98 9$MC=1.459 21$NC=0.395 6 +238NP3 G OC=0.0972 14 +238NP L 106.155 155+ +238NP L 121.645 9 4+ +238NP L 136.045 2 3- 6 NS +238NP A 5410.13 251.0 22820 +238NP G 49.371 3 0.134 4E1 0.821 12 +238NP2 G LC=0.615 9$MC=0.1536 22$NC=0.0408 6 +238NP3 G OC=0.00939 14 +238NP G 73.72 1 0.0079 6E1 0.285 4 +238NP2 G LC=0.214 3$MC=0.0529 8$NC=0.01411 20 +238NP3 G OC=0.00330 5 +238NP G 109.618 3 0.0184 E1 0.1010 15 +238NP2 G LC=0.0760 11$MC=0.0186 3$NC=0.00498 7 +238NP3 G OC=0.001180 17 +238NP G 136.045 2 0.0094 3E1 0.247 4 +238NP2 G KC=0.190 3$LC=0.0436 6$MC=0.01064 15$NC=0.00285 4 +238NP3 G OC=0.000679 10 +238NP L 161.69 2 6+ +238NP L 165.532 155+ +238NP G 139.11 2 0.00011 E2 3.40 5 +238NP2 G KC=0.211 3$LC=2.32 4$MC=0.646 9$NC=0.1764 25 +238NP3 G OC=0.0412 6 +238NP L 179.154 7 4- +238NP A 5367.73 251.11 201430 +238NP G 43.11 1 0.00006414M1+E2 0.045 61.3 9 +238NP2 G LC=46.1 7$MC=11.25 16$NC=3.05 5 +238NP3 G OC=0.750 11 +238NP G 57.51 1 0.00097 23E1 0.549 8 +238NP2 G LC=0.412 6$MC=0.1023 15$NC=0.0272 4 +238NP3 G OC=0.00631 9 +238NP G 92.48 1 0.0028 3E1 0.1574 22 +238NP2 G LC=0.1184 17$MC=0.0291 4$NC=0.00777 11 +238NP3 G OC=0.00183 3 +238NP G 152.73 1 0.00069 E1 0.189 3 +238NP2 G KC=0.1457 21$LC=0.0324 5$MC=0.00791 11$NC=0.00212 3 +238NP3 G OC=0.000506 7 +238NP L 182.878 2 2- +238NP G 46.833 3 7.4E-6 14M1+E2 0.063 48.8 7 +238NP2 G LC=36.7 6$MC=8.97 13$NC=2.43 4 +238NP3 G OC=0.598 9 +238NP G 156.451 3 0.00027 5E1 0.1784 25 +238NP2 G KC=0.1379 20$LC=0.0305 5$MC=0.00744 11$NC=0.00199 3 +238NP3 G OC=0.000477 7 +238NP G 182.878 2 0.00092 3E1 0.1238 18 +238NP2 G KC=0.0965 14$LC=0.0206 3$MC=0.00502 7$NC=0.001346 19 +238NP3 G OC=0.000323 5 +238NP L 215.522 4 3- +238NP A 5331.97 250.15 116400 +238NP G 32.64 1 0.000019 3M1+E2 0.014 136.4 20 +238NP2 G LC=102.6 15$MC=25.0 4$NC=6.77 10 +238NP3 G OC=1.669 24 +238NP G 79.48 1 0.00012423M1+E2 1.0 2 26 4 +238NP2 G LC=19 3$MC=5.2 8$NC=1.43 21 +238NP3 G OC=0.34 5 +238NP G 93.88 1 0.0036 4E1 0.1513 22 +238NP2 G LC=0.1138 16$MC=0.0280 4$NC=0.00747 11 +238NP3 G OC=0.001762 25 +238NP G 153.19 1 0.00031 4E1 0.187 3 +238NP2 G KC=0.1447 21$LC=0.0322 5$MC=0.00785 11$NC=0.00210 3 +238NP3 G OC=0.000503 7 +238NP G 189.10 1 0.00027 5E1 0.1146 16 +238NP2 G KC=0.0894 13$LC=0.0190 3$MC=0.00462 7$NC=0.001238 18 +238NP3 G OC=0.000297 5 +238NP G 215.522 4 0.00059 10E1 0.0847 12 +238NP2 G KC=0.0664 10$LC=0.01376 20$MC=0.00334 5$NC=0.000897 13 +238NP3 G OC=0.000216 3 +238NP L 218.7 6 (6)+ +238NP L 232.828 8 5- +238NP A 5314.95 250.61 111250 +238NP G 53.67 1 0.0021 3M1+E2 0.25 46.0 7 +238NP2 G LC=34.2 5$MC=8.73 13$NC=2.37 4 +238NP3 G OC=0.572 8 +238NP G 96.78 1 0.00033 6E2 16.90 24 +238NP2 G LC=12.28 18$MC=3.42 5$NC=0.936 14 +238NP3 G OC=0.218 3 +238NP G 111.18 1 0.0025 4E1 0.0974 14 +238NP2 G LC=0.0733 11$MC=0.0180 3$NC=0.00480 7 +238NP3 G OC=0.001138 16 +238NP L 250.33 3 (1)+ +238NP G 250.33 3 0.00056 (M1+E2) 1.0 2 1.08 16 +238NP2 G KC=0.77 15$LC=0.233 12$MC=0.0595 21$NC=0.0162 6 +238NP3 G OC=0.00391 16 +238NP L 258.853 8 4- +238NP G 43.33 1 8.7E-6 14M1+E2 0.32 126.7 18 +238NP2 G LC=93.5 14$MC=24.6 4$NC=6.68 10 +238NP3 G OC=1.591 23 +238NP G 75.98 1 9.7E-6 14E2 52.8 8 +238NP2 G LC=38.4 6$MC=10.70 15$NC=2.92 4 +238NP3 G OC=0.681 10 +238NP G 122.81 1 0.00004 2M1+E2 1.0 2 9.6 9 +238NP2 G KC=5.4 12$LC=3.11 22$MC=0.83 7$NC=0.225 19 +238NP3 G OC=0.054 5 +238NP G 152.70 2 0.00069 E1 0.189 3 +238NP2 G KC=0.1458 21$LC=0.0325 5$MC=0.00791 11$NC=0.00212 3 +238NP3 G OC=0.000507 7 +238NP G 196.52 1 0.00010 5E1 0.1048 15 +238NP2 G KC=0.0819 12$LC=0.01725 25$MC=0.00419 6$NC=0.001126 16 +238NP3 G OC=0.000270 4 +238NP G 232.43 1 0.00056 3E1 0.0712 10 +238NP2 G KC=0.0560 8$LC=0.01145 16$MC=0.00278 4$NC=0.000746 11 +238NP3 G OC=0.000180 3 +238NP L 275.519 9 5+ +238NP A 5272.96 251.00 11414 +238NP G 153.87 1 0.00332 10M1+E2 0.14 7.02 10 +238NP2 G KC=5.53 8$LC=1.123 16$MC=0.273 4$NC=0.0741 11 +238NP3 G OC=0.0182 3 +238NP G 213.19 1 0.00005518M1+E2 1.0 2 1.73 25 +238NP2 G KC=1.19 24$LC=0.401 11$MC=0.1032 17$NC=0.0281 5 +238NP3 G OC=0.00675 13 +238NP L 297.03 5 (6)- +238NP A 5251.80 250.020 1115300 +238NP G 131.50 5 0.00027 6E1 0.268 4 +238NP2 G KC=0.205 3$LC=0.0475 7$MC=0.01161 17$NC=0.00311 5 +238NP3 G OC=0.000740 11 +238NP G 190.88 5 0.00010624E1 0.1121 16 +238NP2 G KC=0.0875 13$LC=0.0185 3$MC=0.00451 7$NC=0.001210 17 +238NP3 G OC=0.000290 4 +238NP L 299.23 6 (3)+ +238NP A 5249.64 260.020 1114800 +238NP G 236.90 6 0.00004623M1+E2 1.0 2 1.27 19 +238NP2 G KC=0.89 18$LC=0.280 12$MC=0.0717 21$NC=0.0195 6 +238NP3 G OC=0.00470 15 +238NP G 272.80 6 0.000037 8M1+E2 1.0 2 0.85 13 +238NP2 G KC=0.61 12$LC=0.176 11$MC=0.0448 21$NC=0.0122 6 +238NP3 G OC=0.00294 15 +238NP G 299.23 6 0.00002814M1+E2 1.0 2 0.65 10 +238NP2 G KC=0.48 9$LC=0.131 9$MC=0.0332 19$NC=0.0090 5 +238NP3 G OC=0.00218 14 +238NP L 300.68 7 (1:4)- +238NP A 5248.21 260.39 11730 +238NP G 85.16 7 0.0010 3M1+E2 1.0 2 19 3 +238NP2 G LC=14.3 18$MC=3.9 6$NC=1.05 15 +238NP3 G OC=0.25 4 +238NP G 238.35 7 0.000016 8E1 0.0673 10 +238NP2 G KC=0.0530 8$LC=0.01078 16$MC=0.00261 4$NC=0.000702 10 +238NP3 G OC=1.692E-4 24 +238NP L 300.743 16(6)- +238NP A 5248.15 250.39 11730 +238NP G 67.92 2 0.0040 3M1+E2 0.35 6 24 3 +238NP2 G LC=17.7 19$MC=4.6 6$NC=1.24 15 +238NP3 G OC=0.30 4 +238NP G 135.21 2 0.0068 4E1 0.251 4 +238NP2 G KC=0.192 3$LC=0.0443 7$MC=0.01081 16$NC=0.00290 4 +238NP3 G OC=0.00069 1 +238NP G 139.05 3 0.00011 E1 0.235 4 +238NP2 G KC=0.180 3$LC=0.0412 6$MC=0.01006 15$NC=0.00269 4 +238NP3 G OC=0.000642 9 +238NP G 194.59 2 0.00142 5E1 0.1072 15 +238NP2 G KC=0.0837 12$LC=0.01768 25$MC=0.00430 6$NC=0.001153 17 +238NP3 G OC=0.000277 4 +238NP L 312.70 2 5- +238NP G 53.85 2 2.8E-6 14M1+E2 0.16 37.2 6 +238NP2 G LC=27.8 4$MC=6.93 10$NC=1.88 3 +238NP3 G OC=0.458 7 +238NP G 97.18 2 0.000007 4E2 16.58 24 +238NP2 G LC=12.05 17$MC=3.36 5$NC=0.918 13 +238NP3 G OC=0.214 3 +238NP G 151.01 3 0.00008318E1 0.194 3 +238NP2 G KC=0.1495 21$LC=0.0334 5$MC=0.00814 12$NC=0.00218 3 +238NP3 G OC=0.000521 8 +238NP G 176.66 2 0.00002814E2 1.285 18 +238NP2 G KC=0.181 3$LC=0.804 12$MC=0.223 4$NC=0.0609 9 +238NP3 G OC=0.01425 20 +238NP G 250.37 2 0.00056 E1 0.0602 9 +238NP2 G KC=0.0475 7$LC=0.00958 14$MC=0.00232 4$NC=0.000624 9 +238NP3 G OC=1.505E-4 21 +238NP L 328.6 5 6+ +238NP G 163.1 5 0.0161 M1+E2 1.0 2 3.9 5 +238NP2 G KC=2.5 5$LC=1.04 3$MC=0.273 11$NC=0.074 3 +238NP3 G OC=0.0178 7 +238NP L 334.0 6 (1:3)- +238NP A 5215.4 7 0.030 116000 +238NP L 342.439 8 5- +238NP A 5207.15 2588.9 201.8 +238NP G 66.92 1 0.0150 5E1 0.368 6 +238NP2 G LC=0.277 4$MC=0.0684 10$NC=0.0182 3 +238NP3 G OC=0.00425 6 +238NP G 109.61 1 0.0184 M1+E2 1.0 2 6.7 7 +238NP2 G LC=4.9 5$MC=1.32 14$NC=0.36 4 +238NP3 G OC=0.085 9 +238NP G 126.92 1 0.00013 7E2 5.03 7 +238NP2 G KC=0.196 3$LC=3.51 5$MC=0.979 14$NC=0.267 4 +238NP3 G OC=0.0624 9 +238NP G 163.29 1 0.0161 M1+E2 1.0 2 3.9 5 +238NP2 G KC=2.5 5$LC=1.04 3$MC=0.272 11$NC=0.074 3 +238NP3 G OC=0.0177 6 +238NP G 206.39 1 0.00156 18E2 0.711 10 +238NP2 G KC=0.1454 21$LC=0.412 6$MC=0.1138 16$NC=0.0311 5 +238NP3 G OC=0.00728 11 +238NP G 280.11 1 0.000060 6E1 0.0468 7 +238NP2 G KC=0.0371 6$LC=0.00735 11$MC=0.00178 3$NC=0.000478 7 +238NP3 G OC=1.154E-4 17 +238NP L 374.7 10(5)+ +238NP A 5175.4 100.020 115000 +238NP L 376.70 7 (6)- +238NP A 5173.45 260.020 114900 +238NP G 270.55 7 0.000029 8E1 0.0506 7 +238NP2 G KC=0.0400 6$LC=0.00798 12$MC=0.00193 3$NC=0.000519 8 +238NP3 G OC=1.253E-4 18 +238NP L 389.4 5 7+ +238NP G 170.7 8 0.00063 5M1+E2 1.0 2 3.4 5 +238NP2 G KC=2.2 5$LC=0.882 23$MC=0.230 9$NC=0.0627 23 +238NP3 G OC=0.0150 5 +238NP L 397.3 15 +238NP A 5153.2 150.020 113600 +238NP L 407.59 6 6- +238NP A 5143.07 265.61 2411.2 +238NP G 174.76 6 0.00017 4M1+E2 1.0 2 3.1 4 +238NP2 G KC=2.1 5$LC=0.809 17$MC=0.211 7$NC=0.0574 18 +238NP3 G OC=0.0137 4 +238NP L 459.6 6 (6)+ +238NP A 5091.9 7 0.20 7146 +238NP L 469.1 12(1:4)- +238NP A 5082.6 120.030 11840 +238NP L 484 3 7- +238NP A 5068 3 0.26 781 +238NP L 525.3 15(7)+ +238NP A 5027.3 150.020 11540 +238NP L 578 3 +238NP A 4975 3 0.0020 112400 + diff --git a/HEN_HOUSE/spectra/lnhb/Am-243.txt b/HEN_HOUSE/spectra/lnhb/Am-243.txt index dec53f06d..265ee266c 100644 --- a/HEN_HOUSE/spectra/lnhb/Am-243.txt +++ b/HEN_HOUSE/spectra/lnhb/Am-243.txt @@ -1,88 +1,99 @@ -239NP 243AM A DECAY (7367 Y) -239NP H TYP=Update$AUT=M.M. Bé$CUT=30-APR-2009$ -239NP C Evaluation history: Type=Update;Author=M.M. Bé;Cutoff date=30-APR-2009 -239NP C References: 2004BeZQ, 1977La19, 1998Ya17, 2007Ag02, 2008Ki07 -239NP T Auger electrons and X ray energies and emission intensities: -239NP T {U Energy (keV)} {U Intensity} {U Line} -239NP T -239NP T 97.069 0.0058 4 XKA2 -239NP T 101.059 0.0092 7 XKA1 -239NP T -239NP T 113.303 |] XKB3 -239NP T 114.234 |] 0.00335 25 XKB1 -239NP T 114.912 |] XKB5II -239NP T -239NP T 117.463 |] XKB2 -239NP T 117.876 |] 0.00115 9 XKB4 -239NP T 118.429 |] XKO23 -239NP T -239NP T 11.871-21.491 18.9 7 XL (total) -239NP T 11.871 0.465 25 XLL -239NP T 13.671-13.946 7.4 4 XLA -239NP T 15.861 0.143 10 XLC -239NP T 16.109-17.992 8.7 4 XLB -239NP T 20.784-21.491 2.10 9 XLG -239NP T -239NP T 73.501-83.134 |] KLL AUGER -239NP T 90.358-101.054 |] 0.00058 9 KLX AUGER -239NP T 107.19-118.66 |] KXY AUGER -239NP T 6.04-13.52 18.4 11 L AUGER -243AM P 0.0 5/2- 7367 Y 23 5438.8 10 -239NP N 1.0 1.0 1 1.0 -239NP L 0 5/2+ 2.356 D 3 -239NP A 5349.4 230.240 3 1120 -239NP L 31.130 217/2+ -239NP A 5321 1 0.192 3 95 -239NP G 31.140 300.048 11M1+E2 0.17 1 263 13 -239NP2 G LC=195 10$MC=50 3 -239NP L 71 9/2+ -239NP L 74.660 185/2- 1.39 NS 3 -239NP A 5275.3 1086.74 5 1.14 -239NP G 43.53 2 5.89 10E1 1.143 16 -239NP2 G LC=0.856 12$MC=0.215 3 -239NP G 74.66 2 67.2 12E1 0.276 4 -239NP2 G LC=0.207 3$MC=0.0512 8 -239NP L 117.84 3 7/2- 0.04 NS -239NP A 5233.3 1011.46 5 4.71 -239NP G 43.1 0.065 M1+E2 0.38 4 154 18 -239NP2 G LC=114 13$MC=30 4 -239NP G 86.71 2 0.346 9E1 0.186 3 -239NP2 G LC=0.1401 20$MC=0.0345 5 -239NP G 117.60 150.57 5E1 0.0842 13 -239NP2 G LC=0.0634 10$MC=0.01551 23 -239NP L 122.4 10(11/2)+ -239NP L 173.02 4 9/2- -239NP A 5181 1 1.383 7 17.7 -239NP G 50.6 100.0062 10(E1) 0.77 5 -239NP2 G LC=0.58 4$MC=0.144 9 -239NP G 55.18 5 0.0168 11M1+E2 0.75 10 107 14 -239NP2 G LC=78 10$MC=21 3 -239NP G 98.50 200.0151 21(E2) 15.6 3 -239NP2 G LC=11.31 20$MC=3.15 6 -239NP G 141.90 6 0.115 8E1 0.224 4 -239NP2 G KC=0.1723 25$LC=0.0391 6$MC=0.00955 14 -239NP L 240 (11/2)- -239NP A 5113 1 0.010 1 900 -239NP G 169 0.0012 (E1) 0.149 3 -239NP2 G KC=0.1156 23$LC=0.0251 6$MC=0.00612 13 -239NP L 267 3 (5/2)+ -239NP A 5088 5 0.0055 6 1100 -239NP L 317.4 15(13/2)- -239NP A 5035 3 0.0020 6 -239NP G 195.0 180.00085 (E1) 0.107 3 -239NP2 G KC=0.0833 22$LC=0.0176 5$MC=0.00428 12 -239NP L 325 3 (5/2)- -239NP A 5029 3 0.0020 6 700 -239NP L 347 3 (7/2,9/2)+ -239NP A 5008 3 0.0009 4 -239NP L 359 3 (9/2)+ -239NP A 4997 3 0.0009 4 900 -239NP L 411 3 + -239NP A 4946 3 0.00034 2000 -239NP L 427 3 + -239NP A 4930 3 0.00018 3000 -239NP L 438 3 (11/2)+ -239NP A 4919 3 85000E-9 5400 -239NP L 662 3 (5/2)- -239NP A 4695 3 0.0017 5 7.2 - +239NP 243AM A DECAY (7367 Y) +239NP H TYP=UPD$AUT=M.-M.BE$CUT=30-APR-2009$ +239NP C References:2004BeZQ, 1977La19, 1998Ya17, 2007Ag02, 2008Ki07 +239NP T Auger electrons and X ray energies and emission intensities: +239NP T {U Energy (keV)} {U Intensity} {U Line} +239NP T +239NP T 97.069 0.0058 4 XKA2 +239NP T 101.059 0.0092 7 XKA1 +239NP T +239NP T 113.303 |] XKB3 +239NP T 114.234 |] 0.00335 25 XKB1 +239NP T 114.912 |] XKB5II +239NP T +239NP T 117.463 |] XKB2 +239NP T 117.876 |] 0.00115 9 XKB4 +239NP T 118.429 |] XKO23 +239NP T +239NP T 11.871-21.491 18.9 7 XL (total) +239NP T 11.871 0.465 25 XLL +239NP T 13.671-13.946 7.4 4 XLA +239NP T 15.861 0.143 10 XLC +239NP T 16.109-17.992 8.7 4 XLB +239NP T 20.784-21.491 2.10 9 XLG +239NP T +239NP T 73.501-83.134 |] KLL AUGER +239NP T 90.358-101.054 |] 0.00058 9 KLX AUGER +239NP T 107.19-118.66 |] KXY AUGER +239NP T 6.04-13.52 18.4 11 L AUGER +243AM P 0.0 5/2- 7367 Y 23 5438.8 10 +239NP N 1.0 1.0 1 +239NP L 0 5/2+ 2.356 D 3 +239NP A 5349.4 230.240 31120 +239NP L 31.130 217/2+ +239NP A 5321 1 0.192 395 +239NP G 31.140 300.048 11M1+E2 0.17 1 263 13 +239NP2 G LC=195 10$MC=50 3$NC=13.6 8 +239NP3 G OC=3.27 17 +239NP L 71 9/2+ +239NP L 74.660 185/2- 1.39 NS 3 +239NP A 5275.3 1086.74 51.14 +239NP G 43.53 2 5.89 10E1 1.143 16 +239NP2 G LC=0.856 12$MC=0.215 3$NC=0.0570 8 +239NP3 G OC=0.01304 19 +239NP G 74.66 2 67.2 12E1 0.276 4 +239NP2 G LC=0.207 3$MC=0.0512 8$NC=0.01365 20 +239NP3 G OC=0.00320 5 +239NP L 117.84 3 7/2- 0.04 NS +239NP A 5233.3 1011.46 54.71 +239NP G 43.1 0.065 M1+E2 0.38 4 154 18 +239NP2 G LC=114 13$MC=30 4$NC=8.2 10 +239NP3 G OC=1.95 24 +239NP G 86.71 2 0.346 9E1 0.186 3 +239NP2 G LC=0.1401 20$MC=0.0345 5$NC=0.00920 13 +239NP3 G OC=0.00217 3 +239NP G 117.60 150.57 5E1 0.0842 13 +239NP2 G LC=0.0634 10$MC=0.01551 23$NC=0.00415 6 +239NP3 G OC=0.000985 15 +239NP L 122.4 10(11/2)+ +239NP L 173.02 4 9/2- +239NP A 5181 1 1.383 717.7 +239NP G 50.6 100.0062 10(E1) 0.77 5 +239NP2 G LC=0.58 4$MC=0.144 9$NC=0.0382 22 +239NP3 G OC=0.0088 5 +239NP G 55.18 5 0.0168 11M1+E2 0.75 10 107 14 +239NP2 G LC=78 10$MC=21 3$NC=5.8 8 +239NP3 G OC=1.36 18 +239NP G 98.50 200.0151 21(E2) 15.6 3 +239NP2 G LC=11.31 20$MC=3.15 6$NC=0.862 15 +239NP3 G OC=0.201 4 +239NP G 141.90 6 0.115 8E1 0.224 4 +239NP2 G KC=0.1723 25$LC=0.0391 6$MC=0.00955 14$NC=0.00256 4 +239NP3 G OC=0.000610 9 +239NP L 240 (11/2)- +239NP A 5113 1 0.010 1900 +239NP G 169 0.0012 (E1) 0.149 3 +239NP2 G KC=0.1156 23$LC=0.0251 6$MC=0.00612 13$NC=0.00164 4 +239NP3 G OC=0.000393 8 +239NP L 267 3 (5/2)+ +239NP A 5088 5 0.0055 61100 +239NP L 317.4 15(13/2)- +239NP A 5035 3 0.0020 6 +239NP G 195.0 180.00085 (E1) 0.107 3 +239NP2 G KC=0.0833 22$LC=0.0176 5$MC=0.00428 12$NC=0.00115 4 +239NP3 G OC=0.000275 8 +239NP L 325 3 (5/2)- +239NP A 5029 3 0.0020 6700 +239NP L 347 3 (7/2,9/2)+ +239NP A 5008 3 0.0009 4 +239NP L 359 3 (9/2)+ +239NP A 4997 3 0.0009 4900 +239NP L 411 3 +239NP A 4946 3 0.00034 2000 +239NP L 427 3 +239NP A 4930 3 0.00018 3000 +239NP L 438 3 (11/2)+ +239NP A 4919 3 0.000085 5400 +239NP L 662 3 (5/2)- +239NP A 4695 3 0.0017 57.2 + diff --git a/HEN_HOUSE/spectra/lnhb/Am-244.txt b/HEN_HOUSE/spectra/lnhb/Am-244.txt index ef073d21b..d4fae2e7b 100644 --- a/HEN_HOUSE/spectra/lnhb/Am-244.txt +++ b/HEN_HOUSE/spectra/lnhb/Am-244.txt @@ -1,55 +1,61 @@ -244CM 244AM B- DECAY (10.1 H) -244CM H TYP=Full$AUT=A.L. Nichols$CUT=28-FEB-2009$ -244CM C Evaluation history: Type=Full;Author=A.L. Nichols;Cutoff date=28-FEB-2009 -244CM C References: 1962Va08, 1963Ha29, 1967Sc34, 1977La19, 1984Ho02, 1996Sc06, -244CM2C 1998ScZM, 1999ScZX, 2002Ra45, 2002Ba25, 2003Au03, 2003Ak04, 2008Ki07 -244CM T Auger electrons and X ray energies and emission intensities: -244CM T {U Energy (keV)} {U Intensity} {U Line} -244CM T -244CM T 104.59 2.2 3 XKA2 -244CM T 109.271 3.4 4 XKA1 -244CM T -244CM T 122.304 |] XKB3 -244CM T 123.403 |] 1.29 16 XKB1 -244CM T 124.124 |] XKB5II -244CM T -244CM T 126.889 |] XKB2 -244CM T 127.352 |] 0.45 6 XKB4 -244CM T 127.97 |] XKO23 -244CM T -244CM T 12.633-23.527 100 10 XL (total) -244CM T 12.633 2.36 24 XLL -244CM T 14.746-14.961 36 4 XLA -244CM T 17.314 1.15 15 XLC -244CM T 17.286-19.688 51 5 XLB -244CM T 22.735-23.527 12 13 XLG -244CM T -244CM T 78.858-89.973 |] KLL AUGER -244CM T 97.226-109.267 |] 0.213 27 KLX AUGER -244CM T 115.57-128.23 |] KXY AUGER -244CM T 6.19-14.46 86 9 L AUGER -244AM P 0.0 6- 10.1 H 1 1427.3 10 -244CM N 1.0 1.0 1 1.0 -244CM L 0 0+ 18.11 Y 3 -244CM L 42.965 102+ -244CM G 42.965 100.096 20E2 1050 15 -244CM2 G LC=760 11$MC=214 3 -244CM L 142.348 114+ -244CM G 99.383 4 5.0 11E2 19.3 3 -244CM2 G LC=13.93 20$MC=3.94 6 -244CM L 296.211 116+ -244CM G 153.863 2 19 4E2 2.81 4 -244CM2 G KC=0.1741 25$LC=1.90 3$MC=0.536 8 -244CM L 501.786 128+ -244CM G 205.575 4 0.35 8E2 0.887 13 -244CM2 G KC=0.1409 20$LC=0.541 8$MC=0.1514 22 -244CM L 1040.188 126+ 34 MS 2 -244CM B 387.1 10100 5.63 -244CMS B EAV=109.6 3 -244CM G 538.402 160.66 19E2 0.0495 7 -244CM2 G KC=0.0292 4$LC=0.01492 21$MC=0.00396 6 -244CM G 743.977 5 66 8M1+E2 -0.92 8 0.077 5 -244CM2 G KC=0.059 4$LC=0.0130 7$MC=0.00321 15 -244CM G 897.840 7 28 8E2 0.0169724 -244CM2 G KC=0.01215 17$LC=0.00358 5$MC=9.12E-4 13 - +244CM 244AM B- DECAY (10.1 H) +244CM H TYP=FUL$AUT=A.L.NICHOLS$CUT=28-FEB-2009$ +244CM C References:1962Va08, 1963Ha29, 1967Sc34, 1977La19, 1984Ho02, 1996Sc06, +244CM2C 1998ScZM, 1999ScZX, 2002Ra45, 2002Ba25, 2003Au03, 2003Ak04, 2008Ki07 +244CM T Auger electrons and X ray energies and emission intensities: +244CM T {U Energy (keV)} {U Intensity} {U Line} +244CM T +244CM T 104.59 2.2 3 XKA2 +244CM T 109.271 3.4 4 XKA1 +244CM T +244CM T 122.304 |] XKB3 +244CM T 123.403 |] 1.29 16 XKB1 +244CM T 124.124 |] XKB5II +244CM T +244CM T 126.889 |] XKB2 +244CM T 127.352 |] 0.45 6 XKB4 +244CM T 127.97 |] XKO23 +244CM T +244CM T 12.633-23.527 100 10 XL (total) +244CM T 12.633 2.36 24 XLL +244CM T 14.746-14.961 36 4 XLA +244CM T 17.314 1.15 15 XLC +244CM T 17.286-19.688 51 5 XLB +244CM T 22.735-23.527 12 13 XLG +244CM T +244CM T 78.858-89.973 |] KLL AUGER +244CM T 97.226-109.267 |] 0.213 27 KLX AUGER +244CM T 115.57-128.23 |] KXY AUGER +244CM T 6.19-14.46 86 9 L AUGER +244AM P 0.0 6- 10.1 H 1 1427.3 10 +244CM N 1.0 1.0 1 1.0 +244CM L 0 0+ 18.11 Y 3 +244CM L 42.965 102+ +244CM G 42.965 100.096 20E2 1050 15 +244CM2 G LC=760 11$MC=214 3$NC=59.5 9 +244CM3 G OC=14.38 21 +244CM L 142.348 114+ +244CM G 99.383 4 5.0 11E2 19.3 3 +244CM2 G LC=13.93 20$MC=3.94 6$NC=1.095 16 +244CM3 G OC=0.265 4 +244CM L 296.211 116+ +244CM G 153.863 2 19 4E2 2.81 4 +244CM2 G KC=0.1741 25$LC=1.90 3$MC=0.536 8$NC=0.1492 21 +244CM3 G OC=0.0362 5 +244CM L 501.786 128+ +244CM G 205.575 4 0.35 8E2 0.887 13 +244CM2 G KC=0.1409 20$LC=0.541 8$MC=0.1514 22$NC=0.0421 6 +244CM3 G OC=0.01025 15 +244CM L 1040.188 126+ 34 MS 2 +244CM B 387.1 10100 5.63 +244CMS B EAV=109.6 3 +244CM G 538.402 160.66 19E2 0.0495 7 +244CM2 G KC=0.0292 4$LC=0.01492 21$MC=0.00396 6$NC=0.001096 16 +244CM3 G OC=0.000271 4 +244CM G 743.977 5 66 8M1+E2 -0.92 8 0.077 5 +244CM2 G KC=0.059 4$LC=0.0130 7$MC=0.00321 15$NC=0.00088 4 +244CM3 G OC=0.000223 11 +244CM G 897.840 7 28 8E2 0.0169724 +244CM2 G KC=0.01215 17$LC=0.00358 5$MC=0.000912 13$NC=0.000251 4 +244CM3 G OC=6.29E-5 9 + diff --git a/HEN_HOUSE/spectra/lnhb/Am-244m.txt b/HEN_HOUSE/spectra/lnhb/Am-244m.txt index 45f5c0662..3258a49b8 100644 --- a/HEN_HOUSE/spectra/lnhb/Am-244m.txt +++ b/HEN_HOUSE/spectra/lnhb/Am-244m.txt @@ -1,98 +1,100 @@ -244PU 244AM EC DECAY (26 M) -244PU C References: 1950St61, 1954Gh24, 1955Fi36, 1962Va08, 1964Va04, 1976Ga31, -244PU2C 1977La19, 1984Vo07, 1984Ho02, 1996Sc06, 1998ScZM, 1999SzZX, 2002Ba85, -244PU3C 2002Ra45, 2003Ak04, 2003Au03, 2008Ki07 -244PU T Auger electrons and X ray energies and emission intensities: -244PU T {U Energy (keV)} {U Intensity} {U Line} -244PU T -244PU T 99.525 XKA2 -244PU T 103.734 XKA1 -244PU T -244PU T 116.244 |] XKB3 -244PU T 117.228 |] XKB1 -244PU T 117.918 |] XKB5II -244PU T -244PU T 120.54 |] XKB2 -244PU T 120.969 |] XKB4 -244PU T 121.543 |] XKO23 -244PU T -244PU T -244PU T 75.263-85.357 |] KLL AUGER -244PU T 92.607-103.729 |] 0.00025345 KLX AUGER -244PU T 109.93-121.78 |] KXY AUGER -244PU T 6.19-22.99 0.0124 11 L AUGER -244AM P 89 2 0+ 26 M 3 75 9 -244PU N 2.778E3 2.778E3 0.00036 2.778E3 -244PU L 0 0+ 81.1E6 Y 6 -244PU E 0.036 16.37 -244PU2 E CK=0.24 5$CL=0.53 4$CM=0.168 12$CN=0.050 4 - -244CM 244AM B- DECAY (26 M) -244CM C References: 1950St61, 1954Gh24, 1955Fi36, 1962Va08, 1964Va04, 1976Ga31, -244CM2C 1977La19, 1984Vo07, 1984Ho02, 1996Sc06, 1998ScZM, 1999SzZX, 2002Ba85, -244CM3C 2002Ra45, 2003Ak04, 2003Au03, 2008Ki07 -244CM T Auger electrons and X ray energies and emission intensities: -244CM T {U Energy (keV)} {U Intensity} {U Line} -244CM T -244CM T 104.59 0.013 4 XKA2 -244CM T 109.271 0.020 6 XKA1 -244CM T -244CM T 122.304 |] XKB3 -244CM T 123.403 |] 0.0076 21 XKB1 -244CM T 124.124 |] XKB5II -244CM T -244CM T 126.889 |] XKB2 -244CM T 127.352 |] 0.0027 8 XKB4 -244CM T 127.97 |] XKO23 -244CM T -244CM T 12.633-23.527 12.3 27 XL (total) -244CM T 12.633 0.31 8 XLL -244CM T 14.746-14.961 4.6 11 XLA -244CM T 17.314 0.13 4 XLC -244CM T 17.286-19.688 6.0 14 XLB -244CM T 22.735-23.527 1.4 4 XLG -244CM T -244CM T 78.858-89.973 |] KLL AUGER -244CM T 97.226-109.267 |] 0.00125 27 KLX AUGER -244CM T 115.57-128.23 |] KXY AUGER -244CM T 6.19-14.46 10.6 23 L AUGER -244AM P 89 2 0+ 26 M 3 1427.0 36 -244CM N 1.00E0 1.00E0 0.99964 1.00E0 -244CM L 0 0+ 18.11 Y 3 -244CM B 1516 3 67 9 6.45 -244CMS B EAV=512.3 9 -244CM L 42.965 102+ -244CM B 1473 3 31 9 6.74 2 -244CMS B EAV=495.8 9 -244CM G 42.965 100.030 9E2 1050 15 -244CM2 G LC=760 11$MC=214 3 -244CM L 142.348 114+ -244CM L 296.211 116+ -244CM L 501.786 128+ -244CM L 970 4 (2+, 3-)+ -244CM L 984.914 210+ -244CM B 531.1 301.36 16 6.58 -244CMS B EAV=155.7 7 -244CM G 941.95 3 0.35 12E2 0.0154722 -244CM2 G KC=0.01120 16$LC=0.00318 5$MC=8.07E-4 12 -244CM G 984.91 2 -244CM L 1020.76 3 (2)+ -244CM B 496 3 0.08 2 7.7 2 -244CMS B EAV=144.0 7 -244CM G 977.80 4 (+M1+E2) -244CM L 1038 6 (2+, 3-)+ -244CM L 1040.188 126+ -244CM L 1084.181 141, 2+ -244CM B 432 3 0.56 13 6.67 -244CMS B EAV=123.7 7 -244CM G 1041.22 3 0.19 6(M1+E2) -244CM G 1084.181 140.36 12(E2) 0.041 11 -244CM2 G KC=0.030 8$LC=0.008 2$MC=0.0020 1 -244CM L 1105.91 2 (1, 2)- -244CM B 410 3 0.35 9 6.8 1 -244CMS B EAV=116.9 7 -244CM G 1062.95 3 0.27 8E1 0.11 3 -244CM2 G KC=0.09 3$LC=0.015 4$MC=0.0032 1 -244CM G 1105.91 2 0.04 2(E1) 0.17 4 -244CM2 G KC=0.14 3$LC=0.024 6$MC=0.0058 1 - +244PU 244AM EC DECAY (26 M) +244PU C References:1950St61, 1954Gh24, 1955Fi36, 1962Va08, 1964Va04, 1976Ga31, +244PU2C 1977La19, 1984Vo07, 1984Ho02, 1996Sc06, 1998ScZM, 1999SzZX, 2002Ba85, +244PU3C 2002Ra45, 2003Ak04, 2003Au03, 2008Ki07 +244PU T Auger electrons and X ray energies and emission intensities: +244PU T {U Energy (keV)} {U Intensity} {U Line} +244PU T +244PU T 99.525 XKA2 +244PU T 103.734 XKA1 +244PU T +244PU T 116.244 |] XKB3 +244PU T 117.228 |] XKB1 +244PU T 117.918 |] XKB5II +244PU T +244PU T 120.54 |] XKB2 +244PU T 120.969 |] XKB4 +244PU T 121.543 |] XKO23 +244PU T +244PU T +244PU T 75.263-85.357 |] KLL AUGER +244PU T 92.607-103.729 |] 0.00025345 KLX AUGER +244PU T 109.93-121.78 |] KXY AUGER +244PU T 6.19-22.99 0.0124 11 L AUGER +244AM P 89 2 0+ 26 M 3 75 9 +244PU N 2.778E3 2.778E3 0.00036 2.778E3 +244PU L 0 0+ 81.1E6 Y 6 +244PU E 0.036 16.37 +244PU2 E CK=0.24 5$CL=0.53 4$CM=0.168 12$CN=0.050 4 + +244CM 244AM B- DECAY (26 M) +244CM C References:1950St61, 1954Gh24, 1955Fi36, 1962Va08, 1964Va04, 1976Ga31, +244CM2C 1977La19, 1984Vo07, 1984Ho02, 1996Sc06, 1998ScZM, 1999SzZX, 2002Ba85, +244CM3C 2002Ra45, 2003Ak04, 2003Au03, 2008Ki07 +244CM T Auger electrons and X ray energies and emission intensities: +244CM T {U Energy (keV)} {U Intensity} {U Line} +244CM T +244CM T 104.59 0.013 4 XKA2 +244CM T 109.271 0.020 6 XKA1 +244CM T +244CM T 122.304 |] XKB3 +244CM T 123.403 |] 0.0076 21 XKB1 +244CM T 124.124 |] XKB5II +244CM T +244CM T 126.889 |] XKB2 +244CM T 127.352 |] 0.0027 8 XKB4 +244CM T 127.97 |] XKO23 +244CM T +244CM T 12.633-23.527 12.3 27 XL (total) +244CM T 12.633 0.31 8 XLL +244CM T 14.746-14.961 4.6 11 XLA +244CM T 17.314 0.13 4 XLC +244CM T 17.286-19.688 6.0 14 XLB +244CM T 22.735-23.527 1.4 4 XLG +244CM T +244CM T 78.858-89.973 |] KLL AUGER +244CM T 97.226-109.267 |] 0.00125 27 KLX AUGER +244CM T 115.57-128.23 |] KXY AUGER +244CM T 6.19-14.46 10.6 23 L AUGER +244AM P 89 2 0+ 26 M 3 1427.0 36 +244CM N 1.00E0 1.00E0 0.99964 1.00E0 +244CM L 0 0+ 18.11 Y 3 +244CM B 1516 3 67 9 6.45 +244CMS B EAV=512.3 9 +244CM L 42.965 102+ +244CM B 1473 3 31 9 6.74 2 +244CMS B EAV=495.8 9 +244CM G 42.965 100.030 9E2 1050 15 +244CM2 G LC=760 11$MC=214 3$NC=59.5 9 +244CM3 G OC=14.38 21 +244CM L 142.348 114+ +244CM L 296.211 116+ +244CM L 501.786 128+ +244CM L 970 4 (2+,3-) +244CM L 984.914 210+ +244CM B 531.1 301.36 16 6.58 +244CMS B EAV=155.7 7 +244CM G 941.95 3 0.35 12E2 0.0154722 +244CM2 G KC=0.01120 16$LC=0.00318 5$MC=0.000807 12$NC=0.000222 4 +244CM3 G OC=5.57E-5 8 +244CM G 984.91 2 E0 +244CM L 1020.76 3 (2)+ +244CM B 496 3 0.08 2 7.7 2 +244CMS B EAV=144.0 7 +244CM G 977.80 4 E0(+M1+E2) +244CM L 1038 6 (2+,3-) +244CM L 1040.188 126+ +244CM L 1084.181 141,2+ +244CM B 432 3 0.56 13 6.67 +244CMS B EAV=123.7 7 +244CM G 1041.22 3 0.19 6(M1+E2) +244CM G 1084.181 140.36 12(E2) 0.041 11 +244CM2 G KC=0.030 8$LC=0.008 2$MC=0.0020 1 +244CM L 1105.91 2 (1,2)- +244CM B 410 3 0.35 9 6.8 1 +244CMS B EAV=116.9 7 +244CM G 1062.95 3 0.27 8E1 0.11 3 +244CM2 G KC=0.09 3$LC=0.015 4$MC=0.0032 1 +244CM G 1105.91 2 0.04 2(E1) 0.17 4 +244CM2 G KC=0.14 3$LC=0.024 6$MC=0.0058 1 + diff --git a/HEN_HOUSE/spectra/lnhb/Ar-37.txt b/HEN_HOUSE/spectra/lnhb/Ar-37.txt index b28ccea7a..f3b7b957c 100644 --- a/HEN_HOUSE/spectra/lnhb/Ar-37.txt +++ b/HEN_HOUSE/spectra/lnhb/Ar-37.txt @@ -1,29 +1,28 @@ - 37CL 37AR EC DECAY (35.01 D) - 37CL H TYP=Full$AUT=V.P. Chechev$CUT=30-MAR-2012$ - 37CL C Evaluation history: Type=Full;Author=V.P. Chechev;Cutoff date=30-MAR-2012 - 37CL C References: 1944We**, 1952Mi**, 1959Ki41, 1965St09, 1972Dz09, 1973Co26, - 37CL2C 1975Ki10, 1986BrZQ, 1996Sc06, 1998Bo30, 1998Sc28, 1998En04, 2000Sc47, - 37CL3C 2001Re01, 2003Au03, 2011Ch65, 2012Au06 - 37CL T Auger electrons and X ray energies and emission intensities: - 37CL T {U Energy (keV)} {U Intensity} {U Line} - 37CL T - 37CL T 2.6208 2.76 7 XKA2 - 37CL T 2.62241 5.46 14 XKA1 - 37CL T - 37CL T 2.8156 |] 0.71 4 XKB1 - 37CL T - 37CL T - 37CL T 0.1833-0.2681 0.20 4 XL (total) - 37CL T 0.1833 XLL - 37CL T -0.2681 XLB - 37CL T - 37CL T 2.241-2.384 |] KLL AUGER - 37CL T 2.535-2.616 |] 81.3 3 KLX AUGER - 37CL T 2.787-2.809 |] KXY AUGER - 37CL T 0.165-0.257 166.49 21 L AUGER - 37AR P 0.0 3/2+ 35.01 D 2 813.87 20 - 37CL N 1.0 1.0 1 1.0 - 37CL L 0 0 3/2+ STABLE - 37CL E 100 5.1 - 37CL2 E CK=0.9021 24$CL=0.0872 20$CM=0.0106 7$CN=0 $CO=0 - + 37CL 37AR EC DECAY (35.01 D) + 37CL H TYP=FUL$AUT=V.P.CHECHEV$CUT=30-MAR-2012$ + 37CL C References:1944We**, 1952Mi**, 1959Ki41, 1965St09, 1972Dz09, 1973Co26, + 37CL2C 1975Ki10, 1986BrZQ, 1996Sc06, 1998Bo30, 1998Sc28, 1998En04, 2000Sc47, + 37CL3C 2001Re01, 2003Au03, 2011Ch65, 2012Au06 + 37CL T Auger electrons and X ray energies and emission intensities: + 37CL T {U Energy (keV)} {U Intensity} {U Line} + 37CL T + 37CL T 2.6208 2.76 7 XKA2 + 37CL T 2.62241 5.46 14 XKA1 + 37CL T + 37CL T 2.8156 |] 0.71 4 XKB1 + 37CL T + 37CL T + 37CL T 0.1833-0.2681 0.20 4 XL (total) + 37CL T 0.1833 XLL + 37CL T -0.2681 XLB + 37CL T + 37CL T 2.241-2.384 |] KLL AUGER + 37CL T 2.535-2.616 |] 81.3 3 KLX AUGER + 37CL T 2.787-2.809 |] KXY AUGER + 37CL T 0.165-0.257 166.49 21 L AUGER + 37AR P 0.0 3/2+ 35.01 D 2 813.87 20 + 37CL N 1.0 1.0 1 1.0 + 37CL L 0 3/2+ STABLE + 37CL E 100 5.1 + 37CL2 E CK=0.9021 24$CL=0.0872 20$CM=0.0106 7 + diff --git a/HEN_HOUSE/spectra/lnhb/Ar-41.txt b/HEN_HOUSE/spectra/lnhb/Ar-41.txt index eeb31be61..71f397c1a 100644 --- a/HEN_HOUSE/spectra/lnhb/Ar-41.txt +++ b/HEN_HOUSE/spectra/lnhb/Ar-41.txt @@ -1,34 +1,33 @@ - 41K 41AR B- DECAY (1.8268 H) - 41K H TYP=Full$AUT=v. chisté$CUT=28-FEB-2010$ - 41K 2 H TYP=update$AUT=v. chisté$CUT= -- $ - 41K C Evaluation history: Type=Full;Author=v. chisté;Cutoff date=28-FEB-2010 - 41K 2C Type=update;Author=v. chisté;Cutoff date= -- - 41K C References: 1936Sn01, 1946Bl28, 1950Br29, 1951Ha78, 1956Sc91, 1961Ka19, - 41K 2C 1962En05, 1964Pa03, 1965Pr05, 1969Bo11, 1971Ju04, 1978Eg01, 1978En23, - 41K 3C 1986Ru09, 1990En08, 1990Ab06, 1996Sc06, 2001Ca59, 2002Ba85, 2003Au03, - 41K 4C 2008Ki07 - 41K T Auger electrons and X ray energies and emission intensities: - 41K T {U Energy (keV)} {U Intensity} {U Line} - 41K T - 41K T 3.3111 0.000270 9 XKA2 - 41K T 3.3138 0.00053317 XKA1 - 41K T - 41K T 3.5896 |] 0.000098 4 XKB1 - 41K T 3.6028 |] XKB5II - 41K T - 41K T - 41AR P 0.0 7/2- 1.8268 H 6 2491.6 4 - 41K N 1.0 1.0 1 1.0 - 41K L 0 3/2+ STABLE - 41K B 2491.6 4 0.78 19 9.72 1U - 41K S B EAV=1076.6 2 - 41K L 1293.64 4 7/2- 6.7 NS 5 - 41K B 1197.96 4099.165 20 5.05 - 41K S B EAV=459.18 18 - 41K G 1293.64 4 99.157 20M2+E3 0.118 12 7.44E-511 - 41K 2 G KC=6.36E-5 9$LC=5.34E-6 8$MC=5.80E-7 9 - 41K L 1677.0 3 7/2+ - 41K B 814.6 4 0.0515 49 7.68 - 41K S B EAV=293.9 2 - 41K G 1677.0 3 0.0515 49 - + 41K 41AR B- DECAY (1.8268 H) + 41K H TYP=FUL$AUT=V.CHISTE$CUT=28-FEB-2010$ + 41K 2 H TYP=UPD$AUT=V.CHISTE$CUT=22-MAY-2008$ + 41K C References:1936Sn01, 1946Bl28, 1950Br29, 1951Ha78, 1956Sc91, 1961Ka19, + 41K 2C 1962En05, 1964Pa03, 1965Pr05, 1969Bo11, 1971Ju04, 1978Eg01, 1978En23, + 41K 3C 1986Ru09, 1990En08, 1990Ab06, 1996Sc06, 2001Ca59, 2002Ba85, 2003Au03, + 41K 4C 2008Ki07 + 41K T Auger electrons and X ray energies and emission intensities: + 41K T {U Energy (keV)} {U Intensity} {U Line} + 41K T + 41K T 3.3111 0.000270 9 XKA2 + 41K T 3.3138 0.00053317 XKA1 + 41K T + 41K T 3.5896 |] 0.000098 4 XKB1 + 41K T 3.6028 |] XKB5II + 41K T + 41K T + 41AR P 0.0 7/2- 1.8268 H 6 2491.6 4 + 41K N 1.0 1.0 1 1.0 + 41K L 0 3/2+ STABLE + 41K B 2491.6 4 0.78 19 9.72 1U + 41K S B EAV=1076.6 2 + 41K L 1293.64 4 7/2- 6.7 NS 5 + 41K B 1197.96 4099.165 20 5.05 + 41K S B EAV=459.18 18 + 41K G 1293.64 4 99.157 20M2+E3 0.118 12 7.44E-511 + 41K 2 G KC=6.36E-5 9$LC=5.34E-6 8$MC=5.80E-7 9$NC=2.14E-8 3 + 41K 3 G IPC=4.92E-6 7 + 41K L 1677.0 3 7/2+ + 41K B 814.6 4 0.0515 49 7.68 + 41K S B EAV=293.9 2 + 41K G 1677.0 3 0.0515 49 + diff --git a/HEN_HOUSE/spectra/lnhb/At-211.txt b/HEN_HOUSE/spectra/lnhb/At-211.txt index bad7c3b76..3c019a3ee 100644 --- a/HEN_HOUSE/spectra/lnhb/At-211.txt +++ b/HEN_HOUSE/spectra/lnhb/At-211.txt @@ -1,98 +1,102 @@ -211PO 211AT EC DECAY (7.216 H) -211PO H TYP=Full$AUT=A.L. Nichols$CUT=30-AUG-2010$ -211PO C Evaluation history: Type=Full;Author=A.L. Nichols;Cutoff date=30-AUG-2010 -211PO C References: 1951Ne02, 1953Ho49, 1956Gr11, 1959Ra08, 1961Ap01, 1962Th08, -211PO2C 1969Go23, 1970As07, 1970AfZZ, 1975Ja04, 1977La19, 1978Sc12, 1978Ya04, -211PO3C 1983He09, 1985La17, 1991Ry01, 1996Sc06, 1998Ak04, 1998ScZM, 1999ScZX, -211PO4C 2001Ch66, 2002Ba85, 2002Ra45, 2003Au03, 2004Br45, 2008Ki07 -211PO T Auger electrons and X ray energies and emission intensities: -211PO T {U Energy (keV)} {U Intensity} {U Line} -211PO T -211PO T 76.864 12.66 9 XKA2 -211PO T 79.293 21.08 12 XKA1 -211PO T -211PO T 89.256 |] XKB3 -211PO T 89.807 |] 7.26 12 XKB1 -211PO T 90.363 |] XKB5II -211PO T -211PO T 92.263 |] XKB2 -211PO T 92.618 |] 2.26 5 XKB4 -211PO T 92.983 |] XKO23 -211PO T -211PO T 9.658-16.213 18.6 8 XL (total) -211PO T 9.658 0.465 12 XLL -211PO T 11.016-11.13 8.53 20 XLA -211PO T 12.085 0.134 4 XLC -211PO T 12.823-13.778 7.76 14 XLB -211PO T 15.742-16.213 1.53 3 XLG -211PO T -211PO T 58.978-65.205 |] KLL AUGER -211PO T 71.902-79.289 |] 1.57 18 KLX AUGER -211PO T 84.8-93.1 |] KXY AUGER -211PO T 5.434-10.934 27.6 8 L AUGER -211AT P 0.0 9/2- 7.216 H 7 785.4 25 -211PO N 1.718E0 1.718E0 0.5822 1.718E0 -211PO L 0 9/2+ 0.516 S 3 -211PO E 57.96 85.97 -211PO2 E CK=0.7731 2$CL=0.1693 1$CM=0.05758 4 -211PO L 687.2 7 11/2+ -211PO E 0.258 135.77 1 -211PO2 E CK=0.015 17$CL=0.684 10$CM=0.301 7 -211PO G 687.2 7 0.245 12(M1+E2] -0.20 2 0.0536 9 -211PO2 G KC=0.0437 7$LC=0.00752 12$MC=0.00177 3 - -207BI 211AT A DECAY (7.216 H) -207BI H TYP=Full$AUT=A.L. Nichols$CUT=30-AUG-2010$ -207BI C Evaluation history: Type=Full;Author=A.L. Nichols;Cutoff date=30-AUG-2010 -207BI C References: 1951Ne02, 1953Ho49, 1956Gr11, 1959Ra08, 1961Ap01, 1962Th08, -207BI2C 1969Go23, 1970As07, 1970AfZZ, 1975Ja04, 1977La19, 1978Sc12, 1978Ya04, -207BI3C 1983He09, 1985La17, 1991Ry01, 1996Sc06, 1998Ak04, 1998ScZM, 1999ScZX, -207BI4C 2001Ch66, 2002Ba85, 2002Ra45, 2003Au03, 2004Br45, 2008Ki07 -207BI T Auger electrons and X ray energies and emission intensities: -207BI T {U Energy (keV)} {U Intensity} {U Line} -207BI T -207BI T 74.8157 0.00009815 XKA2 -207BI T 77.1088 0.00016425 XKA1 -207BI T -207BI T 86.835 |] XKB3 -207BI T 87.344 |] 0.000056 9 XKB1 -207BI T 87.862 |] XKB5II -207BI T -207BI T 89.732 |] XKB2 -207BI T 90.074 |] 0.000017 3 XKB4 -207BI T 90.421 |] XKO23 -207BI T -207BI T 9.42-15.709 0.00013614 XL (total) -207BI T 9.42 3.3E-6 4 XLL -207BI T 10.731-10.839 0.000063 7 XLA -207BI T 11.712 1.03E-6 15 XLC -207BI T 12.48-13.393 0.000057 6 XLB -207BI T 15.248-15.709 1.10E-5 12 XLG -207BI T -207BI T 57.491-63.419 |] KLL AUGER -207BI T 70.025-77.105 |] 1.26E-5 24 KLX AUGER -207BI T 82.53-90.52 |] KXY AUGER -207BI T 5.35-10.66 0.00021120 L AUGER -211AT P 0.0 9/2- 7.216 H 7 5982.4 13 -207BI N 2.393E0 2.393E0 0.4178 2.393E0 -207BI L 0 9/2- 32.9 Y 14 -207BI A 5869.0 13100.00 191.59 -207BI L 669.77 7 11/2- -207BI A 5211.9 130.0093 7 7.3 -207BI G 669.77 7 0.0038 3[M1+E2] 0.25 3 0.0520 9 -207BI2 G KC=0.0426 8$LC=0.00725 12$MC=0.00170 3 -207BI L 742.74 7 7/2- -207BI A 5140.3 130.00263 4810.1 -207BI G 742.74 7 0.00125 19[M1+E2] 0.30 3 0.0391 7 -207BI2 G KC=0.0320 6$LC=0.00544 10$MC=1276E-6 22 -207BI L 892.46 7 9/2- -207BI A 4993.4 1395740E-8 3.8 -207BI G 149.72 100.00005 M1+E2 0.4 2 3.0 3 -207BI2 G KC=2.3 3$LC=0.50 4$MC=0.120 12 -207BI G 222.69 100.00004 M1+E2 0.4 1 0.95 5 -207BI2 G KC=0.76 5$LC=0.1473 23$MC=0.0351 5 -207BI G 892.46 7 0.00014 [M1+E2] 1.4 2 0.0145 13 -207BI2 G KC=0.0117 11$LC=0.00215 16$MC=0.00051 4 -207BI L 992.43 7 7/2- -207BI A 4895.4 1395740E-9 9.6 - +211PO 211AT EC DECAY (7.216 H) +211PO H TYP=FUL$AUT=A.L.NICHOLS$CUT=30-AUG-2010$ +211PO C References:1951Ne02, 1953Ho49, 1956Gr11, 1959Ra08, 1961Ap01, 1962Th08, +211PO2C 1969Go23, 1970As07, 1970AfZZ, 1975Ja04, 1977La19, 1978Sc12, 1978Ya04, +211PO3C 1983He09, 1985La17, 1991Ry01, 1996Sc06, 1998Ak04, 1998ScZM, 1999ScZX, +211PO4C 2001Ch66, 2002Ba85, 2002Ra45, 2003Au03, 2004Br45, 2008Ki07, 2010Ko** +211PO T Auger electrons and X ray energies and emission intensities: +211PO T {U Energy (keV)} {U Intensity} {U Line} +211PO T +211PO T 76.864 12.66 9 XKA2 +211PO T 79.293 21.08 12 XKA1 +211PO T +211PO T 89.256 |] XKB3 +211PO T 89.807 |] 7.26 12 XKB1 +211PO T 90.363 |] XKB5II +211PO T +211PO T 92.263 |] XKB2 +211PO T 92.618 |] 2.26 5 XKB4 +211PO T 92.983 |] XKO23 +211PO T +211PO T 9.658-16.213 18.6 8 XL (total) +211PO T 9.658 0.465 12 XLL +211PO T 11.016-11.13 8.53 20 XLA +211PO T 12.085 0.134 4 XLC +211PO T 12.823-13.778 7.76 14 XLB +211PO T 15.742-16.213 1.53 3 XLG +211PO T +211PO T 58.978-65.205 |] KLL AUGER +211PO T 71.902-79.289 |] 1.57 18 KLX AUGER +211PO T 84.8-93.1 |] KXY AUGER +211PO T 5.434-10.934 27.6 8 L AUGER +211AT P 0.0 9/2- 7.216 H 7 785.4 25 +211PO N 1.718E0 1.718E0 0.5822 1.718E0 +211PO L 0 9/2+ 0.516 S 3 +211PO E 57.96 85.97 +211PO2 E CK=0.7731 2$CL=0.1693 1$CM=0.05758 4 +211PO L 687.2 7 11/2+ +211PO E 0.258 135.77 1 +211PO2 E CK=0.015 17$CL=0.684 10$CM=0.301 7 +211PO G 687.2 7 0.245 12[M1+E2] -0.20 2 0.0536 9 +211PO2 G KC=0.0437 7$LC=0.00752 12$MC=0.00177 3$NC=0.000455 7 +211PO3 G OC=9.52E-5 15 + +207BI 211AT A DECAY (7.216 H) +207BI H TYP=FUL$AUT=A.L.NICHOLS$CUT=30-AUG-2010$ +207BI C References:1951Ne02, 1953Ho49, 1956Gr11, 1959Ra08, 1961Ap01, 1962Th08, +207BI2C 1969Go23, 1970As07, 1970AfZZ, 1975Ja04, 1977La19, 1978Sc12, 1978Ya04, +207BI3C 1983He09, 1985La17, 1991Ry01, 1996Sc06, 1998Ak04, 1998ScZM, 1999ScZX, +207BI4C 2001Ch66, 2002Ba85, 2002Ra45, 2003Au03, 2004Br45, 2008Ki07, 2010Ko** +207BI T Auger electrons and X ray energies and emission intensities: +207BI T {U Energy (keV)} {U Intensity} {U Line} +207BI T +207BI T 74.8157 0.00009815 XKA2 +207BI T 77.1088 0.00016425 XKA1 +207BI T +207BI T 86.835 |] XKB3 +207BI T 87.344 |] 0.000056 9 XKB1 +207BI T 87.862 |] XKB5II +207BI T +207BI T 89.732 |] XKB2 +207BI T 90.074 |] 0.000017 3 XKB4 +207BI T 90.421 |] XKO23 +207BI T +207BI T 9.42-15.709 0.00013614 XL (total) +207BI T 9.42 3.3E-6 4 XLL +207BI T 10.731-10.839 0.000063 7 XLA +207BI T 11.712 1.03E-6 15 XLC +207BI T 12.48-13.393 0.000057 6 XLB +207BI T 15.248-15.709 1.10E-5 12 XLG +207BI T +207BI T 57.491-63.419 |] KLL AUGER +207BI T 70.025-77.105 |] 1.26E-5 24 KLX AUGER +207BI T 82.53-90.52 |] KXY AUGER +207BI T 5.35-10.66 0.00021120 L AUGER +211AT P 0.0 9/2- 7.216 H 7 5982.4 13 +207BI N 2.393E0 2.393E0 0.4178 +207BI L 0 9/2- 32.9 Y 14 +207BI A 5869.0 13100.00 191.59 +207BI L 669.77 7 11/2- +207BI A 5211.9 130.0093 77.3 +207BI G 669.77 7 0.0038 3[M1+E2] 0.25 3 0.0520 9 +207BI2 G KC=0.0426 8$LC=0.00725 12$MC=0.00170 3$NC=0.000435 8 +207BI3 G OC=8.88E-5 15 +207BI L 742.74 7 7/2- +207BI A 5140.3 130.00263 4810.1 +207BI G 742.74 7 0.00125 19[M1+E2] 0.30 3 0.0391 7 +207BI2 G KC=0.0320 6$LC=0.00544 10$MC=0.001276 22$NC=0.000326 6 +207BI3 G OC=6.66E-5 12 +207BI L 892.46 7 9/2- +207BI A 4993.4 1395740E-8 3.8 +207BI G 149.72 100.00005 M1+E2 0.4 2 3.0 3 +207BI2 G KC=2.3 3$LC=0.50 4$MC=0.120 12$NC=0.031 3 +207BI3 G OC=0.0061 5 +207BI G 222.69 100.00004 M1+E2 0.4 1 0.95 5 +207BI2 G KC=0.76 5$LC=0.1473 23$MC=0.0351 5$NC=0.00898 13 +207BI3 G OC=0.00181 3 +207BI G 892.46 7 0.00014 [M1+E2] 1.4 2 0.0145 13 +207BI2 G KC=0.0117 11$LC=0.00215 16$MC=0.00051 4$NC=0.000130 9 +207BI3 G OC=2.63E-5 19 +207BI L 992.43 7 7/2- +207BI A 4895.4 1395740E-9 9.6 + diff --git a/HEN_HOUSE/spectra/lnhb/At-215.txt b/HEN_HOUSE/spectra/lnhb/At-215.txt index 701e6ec00..b8c6fc43b 100644 --- a/HEN_HOUSE/spectra/lnhb/At-215.txt +++ b/HEN_HOUSE/spectra/lnhb/At-215.txt @@ -1,39 +1,39 @@ -211BI 215AT A DECAY (0.10 MS) -211BI H TYP=Full$AUT=V.P. Chechev$CUT=15-DEC-2010$ -211BI C Evaluation history: Type=Full;Author=V.P. Chechev;Cutoff date=15-DEC-2010 -211BI C References: 1951Me10, 1966Gr07, 1982Bo04, 1991Ry01, 2003Au03, 2004Br45, -211BI2C 2008Ki07 -211BI T Auger electrons and X ray energies and emission intensities: -211BI T {U Energy (keV)} {U Intensity} {U Line} -211BI T -211BI T 74.8157 0.0012 5 XKA2 -211BI T 77.1088 0.0020 9 XKA1 -211BI T -211BI T 86.835 |] XKB3 -211BI T 87.344 |] 0.00069 28 XKB1 -211BI T 87.862 |] XKB5II -211BI T -211BI T 89.732 |] XKB2 -211BI T 90.074 |] 0.00021 9 XKB4 -211BI T 90.421 |] XKO23 -211BI T -211BI T 9.4207-15.7084 0.0017 4 XL (total) -211BI T 9.4207 0.00004213 XLL -211BI T 10.7308-10.8387 0.00078 22 XLA -211BI T 11.7127 0.000013 5 XLC -211BI T 12.4814-13.8066 0.00073 18 XLB -211BI T 14.7735-15.7084 0.00014 4 XLG -211BI T -211BI T 57.491-63.419 |] KLL AUGER -211BI T 70.025-77.105 |] 0.00015 7 KLX AUGER -211BI T 82.53-90.52 |] KXY AUGER -211BI T 5.42-16.34 0.0027 5 L AUGER -215AT P 0.0 9/2- 0.10 MS 2 8178 4 -211BI N 1.0 1.0 1 1.0 -211BI L 0 9/2- 2.15 M 2 -211BI A 8026 4 99.95 2 2.8 -211BI L 404.854 9 7/2- 0.317 NS 11 -211BI A 7628 4 0.05 2 390 -211BI G 404.853 9 0.045 18M1+E2 -1.1 1 0.122 8 -211BI2 G KC=0.095 7$LC=0.0206 8$MC=0.00498 17 - +211BI 215AT A DECAY (0.10 MS) +211BI H TYP=FUL$AUT=V.P.CHECHEV$CUT=15-DEC-2010$ +211BI C References:1951Me10, 1966Gr07, 1982Bo04, 1991Ry01, 2003Au03, 2004Br45, +211BI2C 2008Ki07 +211BI T Auger electrons and X ray energies and emission intensities: +211BI T {U Energy (keV)} {U Intensity} {U Line} +211BI T +211BI T 74.8157 0.0012 5 XKA2 +211BI T 77.1088 0.0020 9 XKA1 +211BI T +211BI T 86.835 |] XKB3 +211BI T 87.344 |] 0.00069 28 XKB1 +211BI T 87.862 |] XKB5II +211BI T +211BI T 89.732 |] XKB2 +211BI T 90.074 |] 0.00021 9 XKB4 +211BI T 90.421 |] XKO23 +211BI T +211BI T 9.4207-15.7084 0.0017 4 XL (total) +211BI T 9.4207 0.00004213 XLL +211BI T 10.7308-10.8387 0.00078 22 XLA +211BI T 11.7127 0.000013 5 XLC +211BI T 12.4814-13.8066 0.00073 18 XLB +211BI T 14.7735-15.7084 0.00014 4 XLG +211BI T +211BI T 57.491-63.419 |] KLL AUGER +211BI T 70.025-77.105 |] 0.00015 7 KLX AUGER +211BI T 82.53-90.52 |] KXY AUGER +211BI T 5.42-16.34 0.0027 5 L AUGER +215AT P 0.0 9/2- 0.10 MS 2 8178 4 +211BI N 1.0 1.0 1 +211BI L 0 9/2- 2.15 M 2 +211BI A 8026 4 99.95 22.8 +211BI L 404.854 9 7/2- 0.317 NS 11 +211BI A 7628 4 0.05 2390 +211BI G 404.853 9 0.045 18M1+E2 -1.1 1 0.122 8 +211BI2 G KC=0.095 7$LC=0.0206 8$MC=0.00498 17$NC=0.00127 5 +211BI3 G OC=0.000254 10 + diff --git a/HEN_HOUSE/spectra/lnhb/At-217.txt b/HEN_HOUSE/spectra/lnhb/At-217.txt index 1cc4541bd..a8983ab90 100644 --- a/HEN_HOUSE/spectra/lnhb/At-217.txt +++ b/HEN_HOUSE/spectra/lnhb/At-217.txt @@ -1,58 +1,56 @@ -213BI 217AT A DECAY (32.3 MS) -213BI H TYP=Full$AUT=X.Huang$CUT=31-DEC-2007$ -213BI C Evaluation history: Type=Full;Author=X.Huang;Cutoff date=31-DEC-2007 -213BI T Auger electrons and X ray energies and emission intensities: -213BI T {U Energy (keV)} {U Intensity} {U Line} -213BI T -213BI T 74.8157 0.00351 20 XKA2 -213BI T 77.1088 0.0059 4 XKA1 -213BI T -213BI T 86.835 |] XKB3 -213BI T 87.344 |] 0.00201 11 XKB1 -213BI T 87.862 |] XKB5II -213BI T -213BI T 89.732 |] XKB2 -213BI T 90.074 |] 0.00062 4 XKB4 -213BI T 90.421 |] XKO23 -213BI T -213BI T 9.421-15.708 0.00497 23 XL (total) -213BI T 9.421 XLL -213BI T -15.708 XLG -213BI T -213BI T 57.491-63.419 |] KLL AUGER -213BI T 70.025-77.105 |] 0.00044 3 KLX AUGER -213BI T 82.53-90.52 |] KXY AUGER -213BI T 5.3-16.4 0.0077 4 L AUGER -217AT P 0.0 9/2- 32.3 MS 4 7201.3 12 -213BI N 1.00E0 1.00E0 0.999933241.00E0 -213BI L 0 9/2- 45.59 M 6 -213BI A 7066.9 1699.9387 301.16 -213BI L 257.87 117/2- -213BI A 6813.8 160.0384 15379 -213BI G 257.88 4 0.0287 7M1+E2 0.64 8 0.555 26 -213BI2 G KC=0.434 17$LC=0.0918 16$MC=0.02212 37 -213BI L 593.18 13(5/2,7/2,9/2)- -213BI A 6484.7 160.0167 8 49 -213BI G 335.33 100.0062 3 -213BI G 593.1 1 0.0115 5 -213BI L 758.9 1 (5/2,13/2)- -213BI A 6322.0 160.0049 4 36 -213BI G 758.9 1 0.0049 4 -213BI L 1050 - -213BI A 6037 3 20001E-7 5.2 -213BI G 455 0.002 - -217RN 217AT B- DECAY (32.3 MS) -217RN H TYP=Full$AUT=X.Huang$CUT=31-DEC-2007$ -217RN C Evaluation history: Type=Full;Author=X.Huang;Cutoff date=31-DEC-2007 -217RN T Auger electrons and X ray energies and emission intensities: -217RN T {U Energy (keV)} {U Intensity} {U Line} -217RN T -217RN T -217RN T -217RN T -217RN T -217AT P 0.0 9/2- 32.3 MS 4 737 6 -217RN N 1.493E4 1.493E4 0.000067 1.493E4 -217RN L 0 - 0.54 MS 5 - +213BI 217AT A DECAY (32.3 MS) +213BI H TYP=FUL$AUT=X.HUANG$CUT=31-DEC-2007$ +213BI T Auger electrons and X ray energies and emission intensities: +213BI T {U Energy (keV)} {U Intensity} {U Line} +213BI T +213BI T 74.8157 0.00351 20 XKA2 +213BI T 77.1088 0.0059 4 XKA1 +213BI T +213BI T 86.835 |] XKB3 +213BI T 87.344 |] 0.00201 11 XKB1 +213BI T 87.862 |] XKB5II +213BI T +213BI T 89.732 |] XKB2 +213BI T 90.074 |] 0.00062 4 XKB4 +213BI T 90.421 |] XKO23 +213BI T +213BI T 9.421-15.708 0.00497 23 XL (total) +213BI T 9.421 XLL +213BI T -15.708 XLG +213BI T +213BI T 57.491-63.419 |] KLL AUGER +213BI T 70.025-77.105 |] 0.00044 3 KLX AUGER +213BI T 82.53-90.52 |] KXY AUGER +213BI T 5.3-16.4 0.0077 4 L AUGER +217AT P 0.0 9/2- 32.3 MS 4 7201.3 12 +213BI N 1.00E0 1.00E0 0.99993324 +213BI L 0 9/2- 45.59 M 6 +213BI A 7066.9 1699.9387 301.16 +213BI L 257.87 117/2- +213BI A 6813.8 160.0384 15379 +213BI G 257.88 4 0.0287 7M1+E2 0.64 8 0.555 26 +213BI2 G KC=0.434 17$LC=0.0918 16$MC=0.02212 37$NC=0.00565 6 +213BI L 593.18 13(5/2,7/2,9/2)- +213BI A 6484.7 160.0167 849 +213BI G 335.33 100.0062 3 +213BI G 593.1 1 0.0115 5 +213BI L 758.9 1 (5/2,13/2)- +213BI A 6322.0 160.0049 436 +213BI G 758.9 1 0.0049 4 +213BI L 1050 +213BI A 6037 3 20001E-7 5.2 +213BI G 455 0.002 + +217RN 217AT B- DECAY (32.3 MS) +217RN H TYP=FUL$AUT=X.HUANG$CUT=31-DEC-2007$ +217RN T Auger electrons and X ray energies and emission intensities: +217RN T {U Energy (keV)} {U Intensity} {U Line} +217RN T +217RN T +217RN T +217RN T +217RN T +217AT P 0.0 9/2- 32.3 MS 4 737 6 +217RN N 1.493E4 1.493E4 0.000067 1.493E4 +217RN L 0 0.54 MS 5 + diff --git a/HEN_HOUSE/spectra/lnhb/At-218.txt b/HEN_HOUSE/spectra/lnhb/At-218.txt index 2059c9f57..3c51b7c73 100644 --- a/HEN_HOUSE/spectra/lnhb/At-218.txt +++ b/HEN_HOUSE/spectra/lnhb/At-218.txt @@ -1,25 +1,23 @@ -214BI 218AT A DECAY (1.4 S) -214BI H TYP=Full$AUT=V.Chisté$CUT= -- $ -214BI C Evaluation history: Type=Full;Author=V.Chisté;Cutoff date= -- -214BI C References: 1948Wa20, 1949Wa05, 1958Wa16, 1963Wa29, 1964Hy02, 1979Ry03, -214BI2C 1987El12, 1989Bu09, 1991Ry01, 1995El08, 1995El07, 2003Au03, 2006Ja03 -218AT P 0.0 - 1.4 S 2 6874 3 -214BI N 1.001E0 1.001E0 0.999 1.001E0 -214BI L 0 1- 19.8 M 1 -214BI A 6756 5 3.6 1 150 -214BI L 62.7 10 + -214BI A 6694 3 90.09 103.9 -214BI L 103 6 + -214BI A 6653 5 6.41 1038 - -218RN 218AT B- DECAY (1.4 S) -218RN H TYP=Full$AUT=V.Chisté$CUT= -- $ -218RN C Evaluation history: Type=Full;Author=V.Chisté;Cutoff date= -- -218RN C References: 1948Wa20, 1949Wa05, 1958Wa16, 1963Wa29, 1964Hy02, 1979Ry03, -218RN2C 1987El12, 1989Bu09, 1991Ry01, 1995El08, 1995El07, 2003Au03, 2006Ja03 -218AT P 0.0 - 1.4 S 2 2881 12 -218RN N 1.000E3 1.000E3 0.001 1.000E3 -218RN L 0 0+ 36.0 MS 19 -218RN B 2881 120.1 1 -218RNS B EAV=1095 12 - +214BI 218AT A DECAY (1.4 S) +214BI H TYP=FUL$AUT=V.CHISTE$CUT=31-JAN-2007$ +214BI C References:1948Wa20, 1949Wa05, 1958Wa16, 1963Wa29, 1964Hy02, 1979Ry03, +214BI2C 1987El12, 1989Bu09, 1991Ry01, 1995El08, 1995El07, 2003Au03, 2006Ja03 +218AT P 0.0 - 1.4 S 2 6874 3 +214BI N 1.001E0 1.001E0 0.999 +214BI L 0 1- 19.8 M 1 +214BI A 6756 5 3.6 1150 +214BI L 62.7 10 +214BI A 6694 3 90.09 103.9 +214BI L 103 6 +214BI A 6653 5 6.41 1038 + +218RN 218AT B- DECAY (1.4 S) +218RN H TYP=FUL$AUT=V.CHISTE$CUT=31-JAN-2007$ +218RN C References:1948Wa20, 1949Wa05, 1958Wa16, 1963Wa29, 1964Hy02, 1979Ry03, +218RN2C 1987El12, 1989Bu09, 1991Ry01, 1995El08, 1995El07, 2003Au03, 2006Ja03 +218AT P 0.0 - 1.4 S 2 2881 12 +218RN N 1.000E3 1.000E3 0.001 1.000E3 +218RN L 0 0+ 36.0 MS 19 +218RN B 2881 120.1 1 +218RNS B EAV=1095 12 + diff --git a/HEN_HOUSE/spectra/lnhb/At-219.txt b/HEN_HOUSE/spectra/lnhb/At-219.txt index e6662f9ef..90bc51122 100644 --- a/HEN_HOUSE/spectra/lnhb/At-219.txt +++ b/HEN_HOUSE/spectra/lnhb/At-219.txt @@ -1,57 +1,55 @@ -215BI 219AT A DECAY (56 S) -215BI H TYP=Full$AUT=A.L. Nichols$CUT=15-SEP-2010$ -215BI C Evaluation history: Type=Full;Author=A.L. Nichols;Cutoff date=15-SEP-2010 -215BI C References: 1953Hy83, 1989Bu09, 1998Ak04, 2001Br31, 2003Au03, 2009AuZZ -215BI T Auger electrons and X ray energies and emission intensities: -215BI T {U Energy (keV)} {U Intensity} {U Line} -215BI T -215BI T 74.8157 XKA2 -215BI T 77.1088 XKA1 -215BI T -215BI T 86.835 |] XKB3 -215BI T 87.344 |] XKB1 -215BI T 87.862 |] XKB5II -215BI T -215BI T 89.732 |] XKB2 -215BI T 90.074 |] XKB4 -215BI T 90.421 |] XKO23 -215BI T -215BI T -215BI T 57.491-63.419 |] KLL AUGER -215BI T 70.025-77.105 |] KLX AUGER -215BI T 82.53-90.52 |] KXY AUGER -215BI T 0.21-16.3366 L AUGER -219AT P 0.0 (7/2)- 56 S 4 6324 15 -215BI N 1.031E0 1.031E0 0.97 1.031E0 -215BI L 0 (9/2)- 7.6 M 2 -215BI A 6208 15100 1.07 - -219RN 219AT B- DECAY (56 S) -219RN H TYP=Full$AUT=A.L. Nichols$CUT=15-SEP-2010$ -219RN C Evaluation history: Type=Full;Author=A.L. Nichols;Cutoff date=15-SEP-2010 -219RN C References: 1953Hy83, 1989Bu09, 1998Ak04, 2001Br31, 2003Au03, 2009AuZZ -219RN T Auger electrons and X ray energies and emission intensities: -219RN T {U Energy (keV)} {U Intensity} {U Line} -219RN T -219RN T 81.07 XKA2 -219RN T 83.78 XKA1 -219RN T -219RN T 94.247 |] XKB3 -219RN T 94.868 |] XKB1 -219RN T 95.449 |] XKB5II -219RN T -219RN T 97.48 |] XKB2 -219RN T 97.853 |] XKB4 -219RN T 98.357 |] XKO23 -219RN T -219RN T -219RN T 62.017-68.885 |] KLL AUGER -219RN T 75.744-83.785 |] KLX AUGER -219RN T 89.45-98.39 |] KXY AUGER -219RN T 0.2-17.957 L AUGER -219AT P 0.0 (7/2)- 56 S 4 1566 3 -219RN N 3.333E1 3.333E1 0.03 3.333E1 -219RN L 0 5/2+ 3.98 S 3 -219RN B 1566 3 3 6.2 1 -219RNS B EAV=547 2 - +215BI 219AT A DECAY (56 S) +215BI H TYP=FUL$AUT=A.L.NICHOLS$CUT=15-SEP-2010$ +215BI C References:1953Hy83, 1989Bu09, 1998Ak04, 2001Br31, 2003Au03, 2009AuZZ +215BI T Auger electrons and X ray energies and emission intensities: +215BI T {U Energy (keV)} {U Intensity} {U Line} +215BI T +215BI T 74.8157 XKA2 +215BI T 77.1088 XKA1 +215BI T +215BI T 86.835 |] XKB3 +215BI T 87.344 |] XKB1 +215BI T 87.862 |] XKB5II +215BI T +215BI T 89.732 |] XKB2 +215BI T 90.074 |] XKB4 +215BI T 90.421 |] XKO23 +215BI T +215BI T +215BI T 57.491-63.419 |] KLL AUGER +215BI T 70.025-77.105 |] KLX AUGER +215BI T 82.53-90.52 |] KXY AUGER +215BI T 0.21-16.3366 L AUGER +219AT P 0.0 (7/2)- 56 S 4 6324 15 +215BI N 1.031E0 1.031E0 0.97 +215BI L 0 (9/2)- 7.6 M 2 +215BI A 6208 15100 1.07 + +219RN 219AT B- DECAY (56 S) +219RN H TYP=FUL$AUT=A.L.NICHOLS$CUT=15-SEP-2010$ +219RN C References:1953Hy83, 1989Bu09, 1998Ak04, 2001Br31, 2003Au03, 2009AuZZ +219RN T Auger electrons and X ray energies and emission intensities: +219RN T {U Energy (keV)} {U Intensity} {U Line} +219RN T +219RN T 81.07 XKA2 +219RN T 83.78 XKA1 +219RN T +219RN T 94.247 |] XKB3 +219RN T 94.868 |] XKB1 +219RN T 95.449 |] XKB5II +219RN T +219RN T 97.48 |] XKB2 +219RN T 97.853 |] XKB4 +219RN T 98.357 |] XKO23 +219RN T +219RN T +219RN T 62.017-68.885 |] KLL AUGER +219RN T 75.744-83.785 |] KLX AUGER +219RN T 89.45-98.39 |] KXY AUGER +219RN T 0.2-17.957 L AUGER +219AT P 0.0 (7/2)- 56 S 4 1566 3 +219RN N 3.333E1 3.333E1 0.03 3.333E1 +219RN L 0 5/2+ 3.98 S 3 +219RN B 1566 3 3 6.2 1 +219RNS B EAV=547 2 + diff --git a/HEN_HOUSE/spectra/lnhb/Au-195.txt b/HEN_HOUSE/spectra/lnhb/Au-195.txt index c828ebc88..2576e593d 100644 --- a/HEN_HOUSE/spectra/lnhb/Au-195.txt +++ b/HEN_HOUSE/spectra/lnhb/Au-195.txt @@ -1,60 +1,64 @@ -195PT 195AU EC DECAY (184.7 D) -195PT H TYP=Full$AUT=V. Chisté$CUT=30-MAY-2012$ -195PT C Evaluation history: Type=Full;Author=V. Chisté;Cutoff date=30-MAY-2012 -195PT C References: 1949Wi08, 1949St17, 1959Mc69, 1959Bi07, 1960Br11, 1962Bo12, -195PT2C 1963Ha17, 1964Go19, 1965Ha13, 1967Sc18, 1969Fi08, 1970To19, 1970Ah05, -195PT3C 1972Ha21, 1973Go05, 1974HeYW, 1982HoZJ, 1996Sc06, 1999Zh11, 2002Un02, -195PT4C 2008Ki07, 2012Au06 -195PT T Auger electrons and X ray energies and emission intensities: -195PT T {U Energy (keV)} {U Intensity} {U Line} -195PT T -195PT T 65.123 27.4 17 XKA2 -195PT T 66.833 46.9 29 XKA1 -195PT T -195PT T 75.369 |] XKB3 -195PT T 75.749 |] 15.8 10 XKB1 -195PT T 76.234 |] XKB5II -195PT T -195PT T 77.786 |] XKB2 -195PT T 78.07 |] 4.51 30 XKB4 -195PT T 78.337 |] XKO23 -195PT T -195PT T 8.2683-13.3617 53.1 24 XL (total) -195PT T 8.2683 1.29 9 XLL -195PT T 9.362-9.4423 26.1 16 XLA -195PT T 9.9768 0.309 17 XLC -195PT T 10.8411-11.2344 21.5 8 XLB -195PT T 12.5496-13.3617 3.99 16 XLG -195PT T -195PT T 50.399-55.021 |] KLL AUGER -195PT T 61.116-66.829 |] 4.0 5 KLX AUGER -195PT T 71.8-78.39 |] KXY AUGER -195PT T 5.07-14.25 129 8 L AUGER -195AU P 0.0 3/2+ 184.7 D 14 226.8 10 -195PT N 1.0 1.0 1 1.0 -195PT L 0 1/2- STABLE -195PT E 9.5 48.1 1 -195PT2 E CK=0.6851 10$CL=0.2336 7$CM=0.0813 3 -195PT L 98.882 4 3/2- -195PT E 57.6 356.5 -195PT2 E CK=0.452 6$CL=0.398 4$CM=0.1499 18 -195PT G 98.882 4 11.21 15M1+E2 -0.122 15 6.86 10 -195PT2 G KC=5.59 8$LC=0.977 16$MC=0.227 4 -195PT L 129.777 5 5,/2- -195PT E 32.8 306.3 1 -195PT2 E CK=0.178 12$CL=0.587 9$CM=0.235 4 -195PT G 30.895 7 0.80 8M1+E2 -0.013 7 37.3 6 -195PT2 G LC=28.7 5$MC=6.65 11 -195PT G 129.777 5 0.854 29E2 1.729 25 -195PT2 G KC=0.467 7$LC=0.948 14$MC=0.245 4 -195PT L 199.526 123/2- -195PT E 0.0149 148.1 -195PT2 E CL=0.50 2$CM=0.50 2 -195PT G 199.526 120.0093 8M1+E2 1.2 2 0.60 6 -195PT2 G KC=0.42 6$LC=0.1374 25$MC=0.0338 9 -195PT L 211.398 6 3/2- -195PT E 0.0210 187.1 -195PT2 E CL=0.05 5$CM=0.95 5 -195PT G 211.398 6 0.0121 10M1+E2 0.38 3 0.737 14 -195PT2 G KC=0.595 13$LC=0.1090 16$MC=0.0255 4 - +195PT 195AU EC DECAY (184.7 D) +195PT H TYP=FUL$AUT=V.CHISTE$CUT=30-MAY-2012$ +195PT C References:1949Wi08, 1949St17, 1959Mc69, 1959Bi07, 1960Br11, 1962Bo12, +195PT2C 1963Ha17, 1964Go19, 1965Ha13, 1967Sc18, 1969Fi08, 1970To19, 1970Ah05, +195PT3C 1972Ha21, 1973Go05, 1974HeYW, 1982HoZJ, 1996Sc06, 1999Zh11, 2002Un02, +195PT4C 2008Ki07, 2012Au06 +195PT T Auger electrons and X ray energies and emission intensities: +195PT T {U Energy (keV)} {U Intensity} {U Line} +195PT T +195PT T 65.123 27.4 17 XKA2 +195PT T 66.833 46.9 29 XKA1 +195PT T +195PT T 75.369 |] XKB3 +195PT T 75.749 |] 15.8 10 XKB1 +195PT T 76.234 |] XKB5II +195PT T +195PT T 77.786 |] XKB2 +195PT T 78.07 |] 4.51 30 XKB4 +195PT T 78.337 |] XKO23 +195PT T +195PT T 8.2683-13.3617 53.1 24 XL (total) +195PT T 8.2683 1.29 9 XLL +195PT T 9.362-9.4423 26.1 16 XLA +195PT T 9.9768 0.309 17 XLC +195PT T 10.8411-11.2344 21.5 8 XLB +195PT T 12.5496-13.3617 3.99 16 XLG +195PT T +195PT T 50.399-55.021 |] KLL AUGER +195PT T 61.116-66.829 |] 4.0 5 KLX AUGER +195PT T 71.8-78.39 |] KXY AUGER +195PT T 5.07-14.25 129 8 L AUGER +195AU P 0.0 3/2+ 184.7 D 14 226.8 10 +195PT N 1.0 1.0 1 1.0 +195PT L 0 1/2- STABLE +195PT E 9.5 48.1 1 +195PT2 E CK=0.6851 10$CL=0.2336 7$CM=0.0813 3 +195PT L 98.882 4 3/2- +195PT E 57.6 356.5 +195PT2 E CK=0.452 6$CL=0.398 4$CM=0.1499 18 +195PT G 98.882 4 11.21 15M1+E2 -0.122 15 6.86 10 +195PT2 G KC=5.59 8$LC=0.977 16$MC=0.227 4$NC=0.0562 10 +195PT3 G OC=0.01004 16 +195PT L 129.777 5 5/2- +195PT E 32.8 306.3 1 +195PT2 E CK=0.178 12$CL=0.587 9$CM=0.235 4 +195PT G 30.895 7 0.80 8M1+E2 -0.013 7 37.3 6 +195PT2 G LC=28.7 5$MC=6.65 11$NC=1.65 3 +195PT3 G OC=0.296 5 +195PT G 129.777 5 0.854 29E2 1.729 25 +195PT2 G KC=0.467 7$LC=0.948 14$MC=0.245 4$NC=0.0597 9 +195PT3 G OC=0.00935 14 +195PT L 199.526 123/2- +195PT E 0.0149 148.1 +195PT2 E CL=0.50 2$CM=0.50 2 +195PT G 199.526 120.0093 8M1+E2 1.2 2 0.60 6 +195PT2 G KC=0.42 6$LC=0.1374 25$MC=0.0338 9$NC=0.0083 2 +195PT3 G OC=0.001383 23 +195PT L 211.398 6 3/2- +195PT E 0.0210 187.1 +195PT2 E CL=0.05 5$CM=0.95 5 +195PT G 211.398 6 0.0121 10M1+E2 0.38 3 0.737 14 +195PT2 G KC=0.595 13$LC=0.1090 16$MC=0.0255 4$NC=0.00631 9 +195PT3 G OC=0.001117 16 + diff --git a/HEN_HOUSE/spectra/lnhb/Au-198.txt b/HEN_HOUSE/spectra/lnhb/Au-198.txt index 79c00f882..66f69d315 100644 --- a/HEN_HOUSE/spectra/lnhb/Au-198.txt +++ b/HEN_HOUSE/spectra/lnhb/Au-198.txt @@ -1,61 +1,62 @@ -198HG 198AU B- DECAY (2.6943 D) -198HG H TYP=UPDate$AUT=V.P. Chechev. N.Kuzmenko$CUT=14-JAN-2014$ -198HG2 H TYP=FULL$AUT=E. Schönfeld. R. Dersch$CUT=01-SEP-1998$ -198HG C Evaluation history: Type=UPDate;Author=V.P. Chechev. N.Kuzmenko;Cutoff date=14-JAN-2014 -198HG2C Type=FULL;Author=E. Schönfeld. R. Dersch;Cutoff date=01-SEP-1998 -198HG C References: 1935Am01, 1937Po04, 1937Mc04, 1941Sh08, 1946Di**, 1947Se33, -198HG2C 1948Sa36, 1949Sa18, 1949St17, 1951Si91, 1951Ca06, 1951Si25, 1951Br52, -198HG3C 1951Hu18, 1953Sc19, 1953Sc23, 1953Lo09, 1954Be61, 1954El04, 1954Ma19, -198HG4C 1955DZ41, 1955To07, 1955El11, 1956Jo24, 1956Sa75, 1956Vo20, 1958Ke26, -198HG5C 1960Ro22, 1963Le11, 1963St20, 1964Be33, 1964Sa11, 1965An07, 1965Pa08, -198HG6C 1965Pe05, 1965Ke04, 1965Be07, 1966Uh01, 1967Ko13, 1967BoZZ, 1968Go22, -198HG7C 1968La10, 1968Re04, 1969Ca23, 1969Vu04, 1969BeZR, 1970Co14, 1971Pa06, -198HG8C 1971GoYM, 1971De**, 1971Be09, 1972Ve03, 1972Na22, 1973El10, 1974Ka18, -198HG9C 1976Re**, 1980Iw03, 1982RuZV, 1982HoZJ, 1989Ch45, 1990Ab02, 1992Un01, -198HG10C 1992Ha02, 1994Mi03, 2002Un02, 2002Ba85, 2004Un01, 2004BeZQ, 2005Li66, -198HG11C 2006No10, 2007Go39, 2007Sp01, 2008Ki07, 2008Ru05, 2008Ku09, 2009Hu11, -198HG12C 2010Mo06, 2010Li48, 2010Go25, 2010Fo13, 2011Li52, 2011Ch22, 2012Fi12, -198HG13C 2012Ha23, 2012Wa38, 2014Un** -198HG T Auger electrons and X ray energies and emission intensities: -198HG T {U Energy (keV)} {U Intensity} {U Line} -198HG T -198HG T 68.895 0.807 15 XKA2 -198HG T 70.82 1.369 24 XKA1 -198HG T -198HG T 79.823 |] XKB3 -198HG T 80.254 |] 0.465 11 XKB1 -198HG T 80.762 |] XKB5II -198HG T -198HG T 82.435 |] XKB2 -198HG T 82.776 |] 0.136 4 XKB4 -198HG T 83.028 |] XKO23 -198HG T -198HG T 8.7226-14.2672 1.203 22 XL (total) -198HG T 8.7226 0.0270 8 XLL -198HG T 9.8981-9.9886 0.527 14 XLA -198HG T 10.6473 0.01054 29 XLC -198HG T 11.4835-12.5471 0.536 12 XLB -198HG T 13.4081-14.2672 0.1024 23 XLG -198HG T -198HG T 53.178-58.277 |] KLL AUGER -198HG T 64.594-70.811 |] 0.110 12 KLX AUGER -198HG T 75.98-83.09 |] KXY AUGER -198HG T 5.161-14.822 2.156 24 L AUGER -198AU P 0.0 2- 2.6943 D 3 1372.8 5 -198HG N 1.0 1.0 1 1.0 -198HG L 0 0+ STABLE -198HG B 1372.8 5 0.025 5 12.4 1U -198HGS B EAV=467.3 2 -198HG L 411.80250 172+ 23.16 PS 12 -198HG B 961.0 5 98.99 6 7.37 -198HGS B EAV=314.7 2 -198HG G 411.80205 1795.62 6E2 0.0439 7 -198HG2 G KC=0.0300 5$LC=0.01055 15$MC=0.00263 4 -198HG L 1087.6874 5 2+ 2.5 PS 20 -198HG B 285.1 5 0.985 5 7.6 -198HGS B EAV=79.5 2 -198HG G 675.8836 7 0.804 5M1+E2 1.07 14 0.0267 20 -198HG2 G KC=0.0216 17$LC=0.00389 24$MC=0.00091 6 -198HG G 1087.6842 7 0.1591 21E2 0.00512 8 -198HG2 G KC=0.00414 6$LC=7.51E-4 11$MC=1766E-7 25 - +198HG 198AU B- DECAY (2.6943 D) +198HG H TYP=UPD$AUT=V.P.CHECHEV, N.K.KUZMENKO$CUT=14-JAN-2014$ +198HG2 H TYP=FUL$AUT=E.SCHONFELD, R.DERSCH$CUT=01-SEP-1998$ +198HG C References:1935Am01, 1937Po04, 1937Mc04, 1941Sh08, 1946Di**, 1947Se33, +198HG2C 1948Sa36, 1949Sa18, 1949St17, 1951Si91, 1951Ca06, 1951Si25, 1951Br52, +198HG3C 1951Hu18, 1953Sc19, 1953Sc23, 1953Lo09, 1954Be61, 1954El04, 1954Ma19, +198HG4C 1955DZ41, 1955To07, 1955El11, 1956Jo24, 1956Sa75, 1956Vo20, 1958Ke26, +198HG5C 1960Ro22, 1963Le11, 1963St20, 1964Be33, 1964Sa11, 1965An07, 1965Pa08, +198HG6C 1965Pe05, 1965Ke04, 1965Be07, 1966Uh01, 1967Ko13, 1967BoZZ, 1968Go22, +198HG7C 1968La10, 1968Re04, 1969Ca23, 1969Vu04, 1969BeZR, 1970Co14, 1971Pa06, +198HG8C 1971GoYM, 1971De**, 1971Be09, 1972Ve03, 1972Na22, 1973El10, 1974Ka18, +198HG9C 1976Re**, 1980Iw03, 1982RuZV, 1982HoZJ, 1989Ch45, 1990Ab02, 1992Un01, +198HGAC 1992Ha02, 1994Mi03, 2002Un02, 2002Ba85, 2004Un01, 2004BeZQ, 2005Li66, +198HGBC 2006No10, 2007Go39, 2007Sp01, 2008Ki07, 2008Ru05, 2008Ku09, 2009Hu11, +198HGCC 2010Mo06, 2010Li48, 2010Go25, 2010Fo13, 2011Li52, 2011Ch22, 2012Fi12, +198HGDC 2012Ha23, 2012Wa38, 2014Un** +198HG T Auger electrons and X ray energies and emission intensities: +198HG T {U Energy (keV)} {U Intensity} {U Line} +198HG T +198HG T 68.895 0.807 15 XKA2 +198HG T 70.82 1.369 24 XKA1 +198HG T +198HG T 79.823 |] XKB3 +198HG T 80.254 |] 0.465 11 XKB1 +198HG T 80.762 |] XKB5II +198HG T +198HG T 82.435 |] XKB2 +198HG T 82.776 |] 0.136 4 XKB4 +198HG T 83.028 |] XKO23 +198HG T +198HG T 8.7226-14.2672 1.203 22 XL (total) +198HG T 8.7226 0.0270 8 XLL +198HG T 9.8981-9.9886 0.527 14 XLA +198HG T 10.6473 0.01054 29 XLC +198HG T 11.4835-12.5471 0.536 12 XLB +198HG T 13.4081-14.2672 0.1024 23 XLG +198HG T +198HG T 53.178-58.277 |] KLL AUGER +198HG T 64.594-70.811 |] 0.110 12 KLX AUGER +198HG T 75.98-83.09 |] KXY AUGER +198HG T 5.161-14.822 2.156 24 L AUGER +198AU P 0.0 2- 2.6943 D 3 1372.8 5 +198HG N 1.0 1.0 1 1.0 +198HG L 0 0+ STABLE +198HG B 1372.8 5 0.025 5 12.4 1U +198HGS B EAV=467.3 2 +198HG L 411.80250 172+ 23.16 PS 12 +198HG B 961.0 5 98.99 6 7.37 +198HGS B EAV=314.7 2 +198HG G 411.80205 1795.62 6E2 0.0439 7 +198HG2 G KC=0.0300 5$LC=0.01055 15$MC=0.00263 4$NC=0.000655 10 +198HG3 G OC=1.152E-4 17 +198HG L 1087.6874 5 2+ 2.5 PS 20 +198HG B 285.1 5 0.985 5 7.6 +198HGS B EAV=79.5 2 +198HG G 675.8836 7 0.804 5M1+E2 1.07 14 0.0267 20 +198HG2 G KC=0.0216 17$LC=0.00389 24$MC=0.00091 6$NC=0.000228 14 +198HG3 G OC=0.000043 3 +198HG G 1087.6842 7 0.1591 21E2 0.00512 8 +198HG2 G KC=0.00414 6$LC=0.000751 11$MC=1.766E-4 25$NC=4.42E-5 7 +198HG3 G OC=8.20E-6 12 + diff --git a/HEN_HOUSE/spectra/lnhb/Ba-133.txt b/HEN_HOUSE/spectra/lnhb/Ba-133.txt index 09aba21c5..ec2e04cb2 100644 --- a/HEN_HOUSE/spectra/lnhb/Ba-133.txt +++ b/HEN_HOUSE/spectra/lnhb/Ba-133.txt @@ -1,82 +1,86 @@ -133CS 133BA EC DECAY (10.539 Y) -133CS H TYP=UPD$AUT=V.P. Chechev. N.K. Kuzmenko$CUT=01-MAY-2015$ -133CS2 H TYP=UPD$AUT=V.P. Chechev. N.K. Kuzmenko$CUT=01-JUL-2014$ -133CS3 H TYP=UPD$AUT=V.P. Chechev. N.K. Kuzmenko$CUT=01-JAN-2004$ -133CS4 H TYP=UPD$AUT=V.P. Chechev. N.K. Kuzmenko$CUT=01-APR-2000$ -133CS5 H TYP=FUL$AUT=V.P. Chechev. N.K. Kuzmenko$CUT=01-MAY-1999$ -133CS C Evaluation history: Type=UPD;Author=V.P. Chechev. N.K. Kuzmenko;Cutoff date=01-MAY-2015 -133CS2C Type=UPD;Author=V.P. Chechev. N.K. Kuzmenko;Cutoff date=01-JUL-2014 -133CS3C Type=UPD;Author=V.P. Chechev. N.K. Kuzmenko;Cutoff date=01-JAN-2004 -133CS4C Type=UPD;Author=V.P. Chechev. N.K. Kuzmenko;Cutoff date=01-APR-2000 -133CS5C Type=FUL;Author=V.P. Chechev. N.K. Kuzmenko;Cutoff date=01-MAY-1999 -133CS C References: 1961Wy01, 1967Bl15, 1967Be65, 1968BO04, 1968Re04, 1968No01, -133CS2C 1968Na16, 1968La10, 1968Al16, 1968Do10, 1969Gu15, 1970Wa19, 1972Sc08, -133CS3C 1972Em01, 1973Le**, 1973Ll01, 1973Mc18, 1973In06, 1974Da09, 1975Ni07, -133CS4C 1977La19, 1977Ge12, 1977Sc31, 1978He21, 1978Vy**, 1979HaYC, 1980Ro22, -133CS5C 1980Ho17, 1980Ch**, 1980RuZY, 1982HoZJ, 1983Si17, 1983Ki08, 1983Si22, -133CS6C 1983Wa26, 1983Yo03, 1983Ch11, 1987La**, 1988BeYQ, 1989Ma60, 1989Eg**, -133CS7C 1989DA11, 1990Da11, 1990Me15, 1990Fi03, 1990Bh01, 1991We08, 1992Sa28, -133CS8C 1992Ch**, 1992Un01, 1993Ni**, 1995Ra12, 1996Mi26, 1996Sc06, 1997Ma75, -133CS9C 1998Hw07, 2000He14, 2002Un02, 2004BeZQ, 2004Sc04, 2008Ki07, 2010Sc08, -133CS10C 2011Kh02, 2012Fi12, 2012Wa38, 2014Ma**, 2014Un01 -133CS T Auger electrons and X ray energies and emission intensities: -133CS T {U Energy (keV)} {U Intensity} {U Line} -133CS T -133CS T 30.6254 33.8 4 XKA2 -133CS T 30.9731 62.4 7 XKA1 -133CS T -133CS T 34.9197 |] XKB3 -133CS T 34.9873 |] 18.24 29 XKB1 -133CS T 35.252 |] XKB5II -133CS T -133CS T 35.822 |] XKB2 -133CS T 35.907 |] 4.45 12 XKB4 -133CS T 35.972 |] XKO23 -133CS T -133CS T 3.7946-5.5525 15.87 26 XL (total) -133CS T 3.7946 0.293 8 XLL -133CS T 4.2729-4.2866 7.63 18 XLA -133CS T 4.1418 0.1117 30 XLC -133CS T 4.62-4.9333 6.76 12 XLB -133CS T 5.1308-5.5525 1.086 20 XLG -133CS T -133CS T 24.411-25.804 |] KLL AUGER -133CS T 28.991-30.961 |] 14.1 6 KLX AUGER -133CS T 33.55-35.96 |] KXY AUGER -133CS T 2.5777-5.559 136.8 8 L AUGER -133BA P 0.0 1/2+ 10.539 Y 6 517.3 10 -133CS N 1.0 1.0 1 1.0 -133CS L 0 7/2+ STABLE -133CS E 0.0005 13.9 2U -133CS2 E CK=0.77 $CL=0.18 $CM=0.05 -133CS L 80.9979 115/2+ 6.283 NS 14 -133CS E 0.7 10.9 2 -133CS2 E CK=0.84 $CL=0.13 $CM=0.037 -133CS G 80.9979 1133.31 30M1+E2 0.158 5 1.703 24 -133CS2 G KC=1.431 20$LC=0.216 4$MC=0.0447 8 -133CS L 160.6121 165/2+ 172 PS 4 -133CS E 0.3 10.6 2 -133CS2 E CK=0.83 $CL=0.13 $CM=0.037 -133CS G 79.6142 192.63 19M1+E2 0.124 15 1.77 3 -133CS2 G KC=1.495 22$LC=0.217 6$MC=0.0447 13 -133CS G 160.6121 160.638 6M1+E2 0.96 5 0.294 6 -133CS2 G KC=0.234 4$LC=0.0471 13$MC=0.0099 3 -133CS L 383.8491 123/2+ 44 PS 11 -133CS E 14.5 58.03 -133CS2 E CK=0.7727 9$CL=0.1755 7$CM=0.05174 23 -133CS G 223.2368 130.450 5M1+E2 0.114 14 0.0975 14 -133CS2 G KC=0.0836 12$LC=0.01103 16$MC=0.00226 4 -133CS G 302.8508 5 18.31 11M1+E2 0.022 20 0.0434 6 -133CS2 G KC=0.0373 6$LC=0.00484 7$MC=9.88E-4 14 -133CS G 383.8485 128.94 6E2 0.0202 3 -133CS2 G KC=0.01684 24$LC=0.00270 4$MC=5.60E-4 8 -133CS L 437.0113 131/2+ 150 PS -133CS E 85.4 56.63 -133CS2 E CK=0.671 5$CL=0.251 4$CM=0.0777 11 -133CS G 53.1622 182.14 6M1+E2 0.08 3 5.66 11 -133CS2 G KC=4.78 7$LC=0.70 5$MC=0.144 12 -133CS G 276.3989 127.13 6E2 0.0566 8 -133CS2 G KC=0.0460 7$LC=0.00842 12$MC=1763E-6 25 -133CS G 356.0129 7 62.05 19E2 0.0254 4 -133CS2 G KC=0.0211 3$LC=0.00346 5$MC=7.21E-4 10 - +133CS 133BA EC DECAY (10.539 Y) +133CS H TYP=UPD$AUT=V.P.CHECHEV, N.K.KUZMENKO$CUT=01-MAY-2015$ +133CS2 H TYP=UPD$AUT=V.P.CHECHEV, N.K.KUZMENKO$CUT=01-JUL-2014$ +133CS3 H TYP=UPD$AUT=V.P.CHECHEV, N.K.KUZMENKO$CUT=01-JAN-2004$ +133CS4 H TYP=UPD$AUT=V.P.CHECHEV, N.K.KUZMENKO$CUT=01-APR-2000$ +133CS5 H TYP=FUL$AUT=V.P.CHECHEV, N.K.KUZMENKO$CUT=01-MAY-1999$ +133CS C References:1961Wy01, 1967Bl15, 1967Be65, 1968BO04, 1968Re04, 1968No01, +133CS2C 1968Na16, 1968La10, 1968Al16, 1968Do10, 1969Gu15, 1970Wa19, 1972Sc08, +133CS3C 1972Em01, 1973Le**, 1973Ll01, 1973Mc18, 1973In06, 1974Da09, 1975Ni07, +133CS4C 1977La19, 1977Ge12, 1977Sc31, 1978He21, 1978Vy**, 1979HaYC, 1980Ro22, +133CS5C 1980Ho17, 1980Ch**, 1980RuZY, 1982HoZJ, 1983Si17, 1983Ki08, 1983Si22, +133CS6C 1983Wa26, 1983Yo03, 1983Ch11, 1987La**, 1988BeYQ, 1989Ma60, 1989Eg**, +133CS7C 1989DA11, 1990Da11, 1990Me15, 1990Fi03, 1990Bh01, 1991We08, 1992Sa28, +133CS8C 1992Ch**, 1992Un01, 1993Ni**, 1995Ra12, 1996Mi26, 1996Sc06, 1997Ma75, +133CS9C 1998Hw07, 2000He14, 2002Un02, 2004BeZQ, 2004Sc04, 2008Ki07, 2010Sc08, +133CSAC 2011Kh02, 2012Fi12, 2012Wa38, 2014Ma**, 2014Un01 +133CS T Auger electrons and X ray energies and emission intensities: +133CS T {U Energy (keV)} {U Intensity} {U Line} +133CS T +133CS T 30.6254 33.8 4 XKA2 +133CS T 30.9731 62.4 7 XKA1 +133CS T +133CS T 34.9197 |] XKB3 +133CS T 34.9873 |] 18.24 29 XKB1 +133CS T 35.252 |] XKB5II +133CS T +133CS T 35.822 |] XKB2 +133CS T 35.907 |] 4.45 12 XKB4 +133CS T 35.972 |] XKO23 +133CS T +133CS T 3.7946-5.5525 15.87 26 XL (total) +133CS T 3.7946 0.293 8 XLL +133CS T 4.2729-4.2866 7.63 18 XLA +133CS T 4.1418 0.1117 30 XLC +133CS T 4.62-4.9333 6.76 12 XLB +133CS T 5.1308-5.5525 1.086 20 XLG +133CS T +133CS T 24.411-25.804 |] KLL AUGER +133CS T 28.991-30.961 |] 14.1 6 KLX AUGER +133CS T 33.55-35.96 |] KXY AUGER +133CS T 2.5777-5.559 136.8 8 L AUGER +133BA P 0.0 1/2+ 10.539 Y 6 517.3 10 +133CS N 1.0 1.0 1 1.0 +133CS L 0 7/2+ STABLE +133CS E 0.0005 13.9 2U +133CS2 E CK=0.77 $CL=0.18 $CM=0.05 +133CS L 80.9979 115/2+ 6.283 NS 14 +133CS E 0.7 10.9 2 +133CS2 E CK=0.84 $CL=0.13 $CM=0.037 +133CS G 80.9979 1133.31 30M1+E2 0.158 5 1.703 24 +133CS2 G KC=1.431 20$LC=0.216 4$MC=0.0447 8$NC=0.00939 16 +133CS3 G OC=0.001271 20 +133CS L 160.6121 165/2+ 172 PS 4 +133CS E 0.3 10.6 2 +133CS2 E CK=0.83 $CL=0.13 $CM=0.037 +133CS G 79.6142 192.63 19M1+E2 0.124 15 1.77 3 +133CS2 G KC=1.495 22$LC=0.217 6$MC=0.0447 13$NC=0.00940 25 +133CS3 G OC=0.00128 3 +133CS G 160.6121 160.638 6M1+E2 0.96 5 0.294 6 +133CS2 G KC=0.234 4$LC=0.0471 13$MC=0.0099 3$NC=0.00205 6 +133CS3 G OC=0.000261 7 +133CS L 383.8491 123/2+ 44 PS 11 +133CS E 14.5 58.03 +133CS2 E CK=0.7727 9$CL=0.1755 7$CM=0.05174 23 +133CS G 223.2368 130.450 5M1+E2 0.114 14 0.0975 14 +133CS2 G KC=0.0836 12$LC=0.01103 16$MC=0.00226 4$NC=0.000477 7 +133CS3 G OC=6.64E-5 10 +133CS G 302.8508 5 18.31 11M1+E2 0.022 20 0.0434 6 +133CS2 G KC=0.0373 6$LC=0.00484 7$MC=0.000988 14$NC=0.000209 3 +133CS3 G OC=2.92E-5 4 +133CS G 383.8485 128.94 6E2 0.0202 3 +133CS2 G KC=0.01684 24$LC=0.00270 4$MC=0.000560 8$NC=1.166E-4 17 +133CS3 G OC=1.541E-5 22 +133CS L 437.0113 131/2+ 150 PS +133CS E 85.4 56.63 +133CS2 E CK=0.671 5$CL=0.251 4$CM=0.0777 11 +133CS G 53.1622 182.14 6M1+E2 0.08 3 5.66 11 +133CS2 G KC=4.78 7$LC=0.70 5$MC=0.144 12$NC=0.0303 23 +133CS3 G OC=0.0041 3 +133CS G 276.3989 127.13 6E2 0.0566 8 +133CS2 G KC=0.0460 7$LC=0.00842 12$MC=0.001763 25$NC=0.000365 6 +133CS3 G OC=4.70E-5 7 +133CS G 356.0129 7 62.05 19E2 0.0254 4 +133CS2 G KC=0.0211 3$LC=0.00346 5$MC=0.000721 10$NC=1.499E-4 21 +133CS3 G OC=1.97E-5 3 + diff --git a/HEN_HOUSE/spectra/lnhb/Ba-137m.txt b/HEN_HOUSE/spectra/lnhb/Ba-137m.txt index 4cf927d63..8bed7bd5e 100644 --- a/HEN_HOUSE/spectra/lnhb/Ba-137m.txt +++ b/HEN_HOUSE/spectra/lnhb/Ba-137m.txt @@ -1,30 +1,30 @@ -137BA 137BA IT DECAY (2.552 M) -137BA T Auger electrons and X ray energies and emission intensities: -137BA T {U Energy (keV)} {U Intensity} {U Line} -137BA T -137BA T 31.8174 2.06 4 XKA2 -137BA T 32.1939 3.80 7 XKA1 -137BA T -137BA T 36.3045 |] XKB3 -137BA T 36.3786 |] 1.12 2 XKB1 -137BA T 36.654 |] XKB5II -137BA T -137BA T 37.258 |] XKB2 -137BA T 37.312 |] 0.28 1 XKB4 -137BA T 37.425 |] XKO23 -137BA T -137BA T 3.954-5.809 0.95 5 XL (total) -137BA T 3.954 XLL -137BA T -5.809 XLG -137BA T -137BA T 25.31-26.79 |] KLL AUGER -137BA T 30.09-31.36 |] 0.8 1 KLX AUGER -137BA T 34.84-37.41 |] KXY AUGER -137BA T 2.6-5.9 7.7 1 L AUGER -137BA P 661.659 3 11/2- 2.552 M 1 -137BA N 1.0 1.0 1 1.0 -137BA L 0 3/2+ STABLE -137BA L 661.659 3 11/2- 2.552 M 1 -137BA G 661.657 3 90.07 20M4 0.1102 19 -137BA2 G KC=0.0896 15$LC=0.0167 5 - +137BA 137BA IT DECAY (2.552 M) +137BA T Auger electrons and X ray energies and emission intensities: +137BA T {U Energy (keV)} {U Intensity} {U Line} +137BA T +137BA T 31.8174 2.06 4 XKA2 +137BA T 32.1939 3.80 7 XKA1 +137BA T +137BA T 36.3045 |] XKB3 +137BA T 36.3786 |] 1.12 2 XKB1 +137BA T 36.654 |] XKB5II +137BA T +137BA T 37.258 |] XKB2 +137BA T 37.312 |] 0.28 1 XKB4 +137BA T 37.425 |] XKO23 +137BA T +137BA T 3.954-5.809 0.95 5 XL (total) +137BA T 3.954 XLL +137BA T -5.809 XLG +137BA T +137BA T 25.31-26.79 |] KLL AUGER +137BA T 30.09-31.36 |] 0.8 1 KLX AUGER +137BA T 34.84-37.41 |] KXY AUGER +137BA T 2.6-5.9 7.7 1 L AUGER +137BA P 661.659 3 11/2- 2.552 M 1 +137BA N 1.0 1.0 1 +137BA L 0 3/2+ STABLE +137BA L 661.659 3 11/2- 2.552 M 1 +137BA G 661.657 3 90.07 20M4 0.1102 19 +137BA2 G KC=0.0896 15$LC=0.0167 5 + diff --git a/HEN_HOUSE/spectra/lnhb/Ba-140.txt b/HEN_HOUSE/spectra/lnhb/Ba-140.txt index fe1538d69..66a4e6c04 100644 --- a/HEN_HOUSE/spectra/lnhb/Ba-140.txt +++ b/HEN_HOUSE/spectra/lnhb/Ba-140.txt @@ -1,83 +1,93 @@ -140LA 140BA B- DECAY (12.753 D) -140LA H TYP=UPD$AUT=V.P. Chechev. N.K. Kuzmenko$CUT=01-MAR-2015$ -140LA2 H TYP=UPD$AUT=M.M.Bé$CUT=19-JUN-2008$ -140LA3 H TYP=FUL$AUT=R.G. Helmer$CUT=01-JAN-2003$ -140LA C Evaluation history: Type=UPD;Author=V.P. Chechev. N.K. Kuzmenko;Cutoff date=01-MAR-2015 -140LA2C Type=UPD;Author=M.M.Bé;Cutoff date=19-JUN-2008 -140LA3C Type=FUL;Author=R.G. Helmer;Cutoff date=01-JAN-2003 -140LA C References: 1965Si17, 1966Mo16, 1969Ka33, 1970Ke09, 1971Ba28, 1973Ra10, -140LA2C 1975Ha50, 1976Li06, 1977De34, 1977Ge12, 1982HoZJ, 1982Ad02, 1983Wa26, -140LA3C 1990Me03, 1991Ch05, 1992Un01, 1998Si17, 2002Un02, 2002Ba85, 2004BeZR, -140LA4C 2007Ni07, 2008Ki07, 2012Fi12, 2014Wa38, 2014Un01 -140LA T Auger electrons and X ray energies and emission intensities: -140LA T {U Energy (keV)} {U Intensity} {U Line} -140LA T -140LA T 33.0344 0.562 19 XKA2 -140LA T 33.4421 1.03 4 XKA1 -140LA T -140LA T 37.7206 |] XKB3 -140LA T 37.8015 |] 0.307 11 XKB1 -140LA T 38.075 |] XKB5II -140LA T 39.095 |] XKB5I -140LA T -140LA T 38.7303 |] XKB2 -140LA T 38.828 |] 0.078 3 XKB4 -140LA T 39.91 |] XKO23 -140LA T -140LA T 4.1174-6.0724 13.7 4 XL (total) -140LA T 4.1174 0.148 7 XLL -140LA T 4.6338-4.6504 3.81 15 XLA -140LA T 4.5248 0.0762 30 XLC -140LA T 5.0412-5.3814 7.86 19 XLB -140LA T 5.6198-6.0724 1.76 4 XLG -140LA T -140LA T 26.24-27.795 |] KLL AUGER -140LA T 31.231-33.428 |] 0.208 11 KLX AUGER -140LA T 36.2-38.9 |] KXY AUGER -140LA T 2.7-6.2 99.5 19 L AUGER -140BA P 0.0 0+ 12.753 D 5 1048 8 -140LA N 1.0 1.0 1 1.0 -140LA L 0 3- 1.67858 D 21 -140LA L 29.9641 6 2- 0.25 NS 4 -140LA B 1018 8 25.6 42 8.7 1U -140LAS B EAV=362 3 -140LA G 29.9641 6 14.4 4M1(+E2) 5.37 8 -140LA2 G LC=4.26 6$MC=0.885 13 -140LA L 43.844 181- 0.52 NS 14 -140LA B 1004 8 35.6 31 8 1 -140LAS B EAV=345 3 -140LA G 13.880 181.16 4M1+E2 0.0100 55 54.0 19 -140LA2 G LC=42.8 15$MC=8.9 4 -140LA L 63.1790 7 4- -140LA G 63.1790 7 0.00003015M1 4.05 6 -140LA2 G KC=3.45 5$LC=0.472 7$MC=0.0983 14 -140LA L 162.6591 192- 0.01 NS -140LA B 885 8 4.14 31 9.3 1U -140LAS B EAV=311 3 -140LA G 99.4801 200.00002012[E2] 2.03 3 -140LA2 G KC=1.235 18$LC=0.620 9$MC=0.1371 20 -140LA G 118.815 180.0610 21M1 0.663 10 -140LA2 G KC=0.566 8$LC=0.0765 11$MC=0.01591 23 -140LA G 132.695 2 0.202 6M1 0.485 7 -140LA2 G KC=0.415 6$LC=0.0560 8$MC=0.01163 17 -140LA G 162.6591 196.49 27M1(+E2) 0.275 4 -140LA2 G KC=0.235 4$LC=0.0317 5$MC=0.00659 11 -140LA L 467.63 3 1`- 7.7 NS -140LA B 580 8 9.71 12 7.8 1 -140LAS B EAV=181 3 -140LA G 304.971 304.33 9M1(+E2) 0.1 0.0506 7 -140LA2 G KC=0.0434 6$LC=0.00573 8$MC=1189E-6 17 -140LA G 423.786 353.13 6M1 0.0217 3 -140LA2 G KC=0.0186 3$LC=0.00243 4$MC=5.03E-4 7 -140LA G 437.666 301.94 4M1 0.0200 3 -140LA2 G KC=0.01716 24$LC=0.00224 4$MC=4.64E-4 7 -140LA L 581.106 180- -140LA B 467 8 24.9 5 7.1 -140LAS B EAV=141 3 -140LA G 113.48 4 0.0172 13M1 0.755 11 -140LA2 G KC=0.645 9$LC=0.0872 13$MC=0.0181 3 -140LA G 537.261 2524.6 5M1 0.0119717 -140LA2 G KC=0.01029 15$LC=1332E-6 19$MC=2.76E-4 4 -140LA G 551.141 180.0049 20[E2] 0.0079211 -140LA2 G KC=0.00666 10$LC=9.97E-4 14$MC=2.09E-4 3 - +140LA 140BA B- DECAY (12.753 D) +140LA H TYP=UPD$AUT=V.P.CHECHEV, N.K.KUZMENKO$CUT=01-MAR-2015$ +140LA2 H TYP=UPD$AUT=M.-M.BE$CUT=19-JUN-2008$ +140LA3 H TYP=FUL$AUT=R.G.HELMER$CUT=01-JAN-2003$ +140LA C References:1965Si17, 1966Mo16, 1969Ka33, 1970Ke09, 1971Ba28, 1973Ra10, +140LA2C 1975Ha50, 1976Li06, 1977De34, 1977Ge12, 1982HoZJ, 1982Ad02, 1983Wa26, +140LA3C 1990Me03, 1991Ch05, 1992Un01, 1998Si17, 2002Un02, 2002Ba85, 2004BeZR, +140LA4C 2007Ni07, 2008Ki07, 2012Fi12, 2014Wa38, 2014Un01 +140LA T Auger electrons and X ray energies and emission intensities: +140LA T {U Energy (keV)} {U Intensity} {U Line} +140LA T +140LA T 33.0344 0.562 19 XKA2 +140LA T 33.4421 1.03 4 XKA1 +140LA T +140LA T 37.7206 |] XKB3 +140LA T 37.8015 |] 0.307 11 XKB1 +140LA T 38.075 |] XKB5II +140LA T 39.095 |] XKB5I +140LA T +140LA T 38.7303 |] XKB2 +140LA T 38.828 |] 0.078 3 XKB4 +140LA T 39.91 |] XKO23 +140LA T +140LA T 4.1174-6.0724 13.7 4 XL (total) +140LA T 4.1174 0.148 7 XLL +140LA T 4.6338-4.6504 3.81 15 XLA +140LA T 4.5248 0.0762 30 XLC +140LA T 5.0412-5.3814 7.86 19 XLB +140LA T 5.6198-6.0724 1.76 4 XLG +140LA T +140LA T 26.24-27.795 |] KLL AUGER +140LA T 31.231-33.428 |] 0.208 11 KLX AUGER +140LA T 36.2-38.9 |] KXY AUGER +140LA T 2.7-6.2 99.5 19 L AUGER +140BA P 0.0 0+ 12.753 D 5 1048 8 +140LA N 1.0 1.0 1 1.0 +140LA L 0 3- 1.67858 D 21 +140LA L 29.9641 6 2- 0.25 NS 4 +140LA B 1018 8 25.6 42 8.7 1U +140LAS B EAV=362 3 +140LA G 29.9641 6 14.4 4M1(+E2) 5.37 8 +140LA2 G LC=4.26 6$MC=0.885 13$NC=0.194 3 +140LA3 G OC=0.0315 5 +140LA L 43.844 181- 0.52 NS 14 +140LA B 1004 8 35.6 31 8 1 +140LAS B EAV=345 3 +140LA G 13.880 181.16 4M1+E2 0.0100 55 54.0 19 +140LA2 G LC=42.8 15$MC=8.9 4$NC=1.95 7 +140LA3 G OC=0.315 10 +140LA L 63.1790 7 4- +140LA G 63.1790 7 0.00003015M1 4.05 6 +140LA2 G KC=3.45 5$LC=0.472 7$MC=0.0983 14$NC=0.0216 3 +140LA3 G OC=0.00351 5 +140LA L 162.6591 192- 0.01 NS +140LA B 885 8 4.14 31 9.3 1U +140LAS B EAV=311 3 +140LA G 99.4801 200.00002012[E2] 2.03 3 +140LA2 G KC=1.235 18$LC=0.620 9$MC=0.1371 20$NC=0.0291 4 +140LA3 G OC=0.00414 6 +140LA G 118.815 180.0610 21M1 0.663 10 +140LA2 G KC=0.566 8$LC=0.0765 11$MC=0.01591 23$NC=0.00350 5 +140LA3 G OC=0.000568 8 +140LA G 132.695 2 0.202 6M1 0.485 7 +140LA2 G KC=0.415 6$LC=0.0560 8$MC=0.01163 17$NC=0.00256 4 +140LA3 G OC=0.000416 6 +140LA G 162.6591 196.49 27M1(+E2) 0.275 4 +140LA2 G KC=0.235 4$LC=0.0317 5$MC=0.00659 11$NC=0.001448 23 +140LA3 G OC=0.000235 4 +140LA L 467.63 3 1- 7.7 NS +140LA B 580 8 9.71 12 7.8 1 +140LAS B EAV=181 3 +140LA G 304.971 304.33 9M1(+E2) 0.1 0.0506 7 +140LA2 G KC=0.0434 6$LC=0.00573 8$MC=0.001189 17$NC=0.000261 4 +140LA3 G OC=4.26E-5 6 +140LA G 423.786 353.13 6M1 0.0217 3 +140LA2 G KC=0.0186 3$LC=0.00243 4$MC=0.000503 7$NC=1.107E-4 16 +140LA3 G OC=1.81E-5 3 +140LA G 437.666 301.94 4M1 0.0200 3 +140LA2 G KC=0.01716 24$LC=0.00224 4$MC=0.000464 7$NC=1.019E-4 15 +140LA3 G OC=1.663E-5 24 +140LA L 581.106 180- +140LA B 467 8 24.9 5 7.1 +140LAS B EAV=141 3 +140LA G 113.48 4 0.0172 13M1 0.755 11 +140LA2 G KC=0.645 9$LC=0.0872 13$MC=0.0181 3$NC=0.00398 6 +140LA3 G OC=0.000648 9 +140LA G 537.261 2524.6 5M1 0.0119717 +140LA2 G KC=0.01029 15$LC=0.001332 19$MC=0.000276 4$NC=6.06E-5 9 +140LA3 G OC=9.90E-6 14 +140LA G 551.141 180.0049 20[E2] 0.0079211 +140LA2 G KC=0.00666 10$LC=0.000997 14$MC=0.000209 3$NC=4.55E-5 7 +140LA3 G OC=7.22E-6 11 + diff --git a/HEN_HOUSE/spectra/lnhb/Be-7.txt b/HEN_HOUSE/spectra/lnhb/Be-7.txt index 7c018a427..1b35daa8f 100644 --- a/HEN_HOUSE/spectra/lnhb/Be-7.txt +++ b/HEN_HOUSE/spectra/lnhb/Be-7.txt @@ -1,20 +1,20 @@ - 7LI 7BE EC DECAY (53.22 D) - 7LI C References: 2000Hu20, 2000Li21 - 7LI T Auger electrons and X ray energies and emission intensities: - 7LI T {U Energy (keV)} {U Intensity} {U Line} - 7LI T - 7LI T 0.0543 XKA2 - 7LI T 0.0543 XKA1 - 7LI T - 7LI T - 7LI T - 7BE P 0.0 3/2- 53.22 D 6 861.815 18 - 7LI N 1.0 1.0 1 1.0 - 7LI L 0 3/2- STABLE - 7LI E 89.56 43.32 - 7LI2 E CK=0.908 12$CL=0.092 12 - 7LI L 477.621 2 1/2- 105 FS - 7LI E 10.44 43.56 - 7LI2 E CK=0.908 12$CL=0.092 12 - 7LI G 477.6035 2010.44 4M1+E2 7.3E-7 11 - + 7LI 7BE EC DECAY (53.22 D) + 7LI C References:2000Hu20, 2000Li21 + 7LI T Auger electrons and X ray energies and emission intensities: + 7LI T {U Energy (keV)} {U Intensity} {U Line} + 7LI T + 7LI T 0.0543 XKA2 + 7LI T 0.0543 XKA1 + 7LI T + 7LI T + 7LI T + 7BE P 0.0 3/2- 53.22 D 6 861.815 18 + 7LI N 1.0 1.0 1 1.0 + 7LI L 0 3/2- STABLE + 7LI E 89.56 43.32 + 7LI2 E CK=0.908 12$CL=0.092 12 + 7LI L 477.621 2 1/2- 105 FS + 7LI E 10.44 43.56 + 7LI2 E CK=0.908 12$CL=0.092 12 + 7LI G 477.6035 2010.44 4M1+E2 7.3E-7 11 + diff --git a/HEN_HOUSE/spectra/lnhb/Bi-207.txt b/HEN_HOUSE/spectra/lnhb/Bi-207.txt index de0ab643f..2074a5bf3 100644 --- a/HEN_HOUSE/spectra/lnhb/Bi-207.txt +++ b/HEN_HOUSE/spectra/lnhb/Bi-207.txt @@ -1,56 +1,59 @@ -207PB 207BI EC DECAY (32.9 Y) -207PB H TYP=Update$AUT=M.M. Bé$CUT=01-DEC-2009$ -207PB2 H TYP=Full$AUT=M.M.Bé$CUT=01-FEB-1998$ -207PB C Evaluation history: Type=Update;Author=M.M. Bé;Cutoff date=01-DEC-2009 -207PB2C Type=Full;Author=M.M.Bé;Cutoff date=01-FEB-1998 -207PB C References: 1971Al03, 2002Ba85, 2008Ki07 -207PB T Auger electrons and X ray energies and emission intensities: -207PB T {U Energy (keV)} {U Intensity} {U Line} -207PB T -207PB T 72.8049 21.75 30 XKA2 -207PB T 74.97 36.6 5 XKA1 -207PB T -207PB T 84.451 |] XKB3 -207PB T 84.937 |] 12.49 25 XKB1 -207PB T 85.47 |] XKB5II -207PB T -207PB T 87.238 |] XKB2 -207PB T 87.58 |] 3.77 10 XKB4 -207PB T 87.911 |] XKO23 -207PB T -207PB T 9.18-15.84 32.9 6 XL (total) -207PB T 9.18 0.822 21 XLL -207PB T 10.4496-10.5516 15.6 4 XLA -207PB T 11.3494 0.226 7 XLC -207PB T 12.143-13.015 13.62 26 XLB -207PB T 15.101-15.84 2.61 5 XLG -207PB T -207PB T 56.028-61.669 |] KLL AUGER -207PB T 68.181-74.969 |] 2.9 4 KLX AUGER -207PB T 80.3-88 |] KXY AUGER -207PB T 5.2-15.7 54.8 7 L AUGER -207BI P 0.0 9/2- 32.9 Y 14 2397.5 21 -207PB N 1.0 1.0 1 1.0 -207PB L 0 1/2- STABLE -207PB L 569.703 2 5/2- 130.5 PS 8 -207PB E 0.012 28.8 612.1 2 -207PB2 E EAV=383.4 9$CK=0.797 8$CL=0.150 3$CM=0.049 1 -207PB G 569.698 2 97.76 3E2 0.0216 3 -207PB2 G KC=0.01583 23$LC=0.00439 7$MC=1081E-6 16 -207PB L 897.80 5 3/2- -207PB G 328.11 100.0044 35[M1] -207PB G 897.8 1 0.1284 47M1+E2 0.3 1 0.0222 9 -207PB2 G KC=0.0182 8$LC=0.00304 12$MC=0.071 3 -207PB L 1633.368 5 13/2+ 0.806 S 6 -207PB E 84.1 610.58 1U -207PB2 E CK=0.733 7$CL=0.199 4$CM=0.069 1 -207PB G 1063.656 3 74.58 22M4+E5 0.01 1 0.1278 24 -207PB2 G KC=0.0953 23$LC=0.0247 7$MC=0.00591 33 -207PB L 2339.948 117/2- -207PB E 7.03 238.3 -207PB2 E CL=0.651 6$CM=0.349 6 -207PB G 1442.2 2 0.1315 22E2 0.00337 5 -207PB2 G KC=0.00271 4$LC=4.68E-4 7$MC=1098E-7 16 -207PB G 1770.228 9 6.871 26M1+E2 0.05 2 0.00442 7 -207PB2 G KC=0.00342 5$LC=5.56E-4 8$MC=1292E-7 19 - +207PB 207BI EC DECAY (32.9 Y) +207PB H TYP=UPD$AUT=M.-M.BE$CUT=01-DEC-2009$ +207PB2 H TYP=FUL$AUT=M.-M.BE$CUT=01-FEB-1998$ +207PB C References:1971Al03, 2002Ba85, 2008Ki07 +207PB T Auger electrons and X ray energies and emission intensities: +207PB T {U Energy (keV)} {U Intensity} {U Line} +207PB T +207PB T 72.8049 21.75 30 XKA2 +207PB T 74.97 36.6 5 XKA1 +207PB T +207PB T 84.451 |] XKB3 +207PB T 84.937 |] 12.49 25 XKB1 +207PB T 85.47 |] XKB5II +207PB T +207PB T 87.238 |] XKB2 +207PB T 87.58 |] 3.77 10 XKB4 +207PB T 87.911 |] XKO23 +207PB T +207PB T 9.18-15.84 32.9 6 XL (total) +207PB T 9.18 0.822 21 XLL +207PB T 10.4496-10.5516 15.6 4 XLA +207PB T 11.3494 0.226 7 XLC +207PB T 12.143-13.015 13.62 26 XLB +207PB T 15.101-15.84 2.61 5 XLG +207PB T +207PB T 56.028-61.669 |] KLL AUGER +207PB T 68.181-74.969 |] 2.9 4 KLX AUGER +207PB T 80.3-88 |] KXY AUGER +207PB T 5.2-15.7 54.8 7 L AUGER +207BI P 0.0 9/2- 32.9 Y 14 2397.5 21 +207PB N 1.0 1.0 1 1.0 +207PB L 0 1/2- STABLE +207PB L 569.703 2 5/2- 130.5 PS 8 +207PB E 0.012 28.8 612.1 2 +207PB2 E EAV=383.4 9$CK=0.796 8$CL=0.1498 30$CM=0.0489 10 +207PB G 569.698 2 97.76 3E2 0.0216 3 +207PB2 G KC=0.01583 23$LC=0.00439 7$MC=0.001081 16$NC=0.000274 4 +207PB3 G OC=5.21E-5 8 +207PB L 897.80 5 3/2- +207PB G 328.11 100.0044 35[M1] +207PB G 897.8 1 0.1284 47M1+E2 0.3 1 0.0222 9 +207PB2 G KC=0.0182 8$LC=0.00304 12$MC=0.071 3$NC=0.000180 7 +207PB3 G OC=3.59E-5 14 +207PB L 1633.368 5 13/2+ 0.806 S 6 +207PB E 84.1 610.58 1U +207PB2 E CK=0.733 7$CL=0.199 4$CM=0.069 1 +207PB G 1063.656 3 74.58 22M4+E5 0.01 1 0.1278 24 +207PB2 G KC=0.0953 23$LC=0.0247 7$MC=0.00591 33$NC=0.00160 4 +207PB3 G OC=0.00031 1 +207PB L 2339.948 117/2- +207PB E 7.03 238.3 +207PB2 E CL=0.651 6$CM=0.349 6 +207PB G 1442.2 2 0.1315 22E2 0.00337 5 +207PB2 G KC=0.00271 4$LC=0.000468 7$MC=1.098E-4 16$NC=2.78E-5 4 +207PB3 G OC=5.50E-6 8 +207PB G 1770.228 9 6.871 26M1+E2 0.05 2 0.00442 7 +207PB2 G KC=0.00342 5$LC=0.000556 8$MC=1.292E-4 19$NC=3.28E-5 5 +207PB3 G OC=6.56E-6 10 + diff --git a/HEN_HOUSE/spectra/lnhb/Bi-210.txt b/HEN_HOUSE/spectra/lnhb/Bi-210.txt index 896809746..ba24e71f4 100644 --- a/HEN_HOUSE/spectra/lnhb/Bi-210.txt +++ b/HEN_HOUSE/spectra/lnhb/Bi-210.txt @@ -1,88 +1,88 @@ -206TL 210BI A DECAY (5.011 D) -206TL H TYP=UPD$AUT=M.A.Kellett$CUT=01-OCT-2014$ -206TL2 H TYP=FUL$AUT=V. Chiste. M.-M.Be$CUT=31-JAN-2008$ -206TL C Evaluation history: Type=UPD;Author=M.A.Kellett;Cutoff date=01-OCT-2014 -206TL2C Type=FUL;Author=V. Chiste. M.-M.Be;Cutoff date=31-JAN-2008 -206TL C References: 1935Po01, 1935Po01, 1939Fl02, 1939Fl02, 1940Ne04, 1940Ne04, -206TL2C 1944Hole, 1947Br36, 1947Br36, 1952Be22, 1952Be22, 1953Lo09, 1953Lo09, -206TL3C 1954Pl30, 1954Pl30, 1956Fi09, 1956Ro18, 1956Ro18, 1956Fi09, 1959Ro51, -206TL4C 1959Wa05, 1959Wa05, 1959Ro51, 1960Wa14, 1960Wa14, 1961Ru02, 1961Ru02, -206TL5C 1961Nu01, 1961Nu01, 1962Da03, 1962Ka27, 1962Ka27, 1962Da03, 1967Hs01, -206TL6C 1967Hs01, 1969Fl02, 1969Fl02, 1969La18, 1969La18, 1991Ry01, 1991Ry01, -206TL7C 1996Sc06, 1996Sc06, 1999Br39, 2002Ba85, 2002Ba85, 2003Br13, 2003Au03, -206TL8C 2003Br13, 2005Gr41, 2008BeZV, 2008Ki07, 2008Ko21, 2010MoZU, 2012Wa38 -206TL T Auger electrons and X ray energies and emission intensities: -206TL T {U Energy (keV)} {U Intensity} {U Line} -206TL T -206TL T 70.8325 6.4E-6 7 XKA2 -206TL T 72.8725 1.08E-5 11 XKA1 -206TL T -206TL T 82.118 |] XKB3 -206TL T 82.577 |] 3.7E-6 4 XKB1 -206TL T 83.115 |] XKB5II -206TL T -206TL T 84.838 |] XKB2 -206TL T 85.134 |] 1.10E-6 11 XKB4 -206TL T 85.444 |] XKO23 -206TL T -206TL T 8.9531-14.7362 9.0E-6 5 XL (total) -206TL T 8.9531 2.13E-7 16 XLL -206TL T 10.1718-10.2679 4.09E-6 28 XLA -206TL T 10.9942 7.2E-8 6 XLC -206TL T 11.8117-12.9566 3.86E-6 23 XLB -206TL T 13.8528-14.7362 7.3E-7 5 XLG -206TL T -206TL T 54.587-59.954 |] KLL AUGER -206TL T 66.37-72.86 |] 8.5E-7 13 KLX AUGER -206TL T 78.12-85.5 |] KXY AUGER -206TL T 5.2493-15.3183 1.55E-5 6 L AUGER -210BI P 0.0 1- 5.011 D 5 5036.5 8 -206TL N 7.143E5 7.143E5 0.0000012 7.143E5 -206TL L 0 0- 4.202 M 11 -206TL L 265.832 5 2- 2.29 NS 14 -206TL A 4687 4 40.0 4358 -206TL G 265.832 5 0.000048 5E2 0.1603 23 -206TL2 G KC=0.0855 12$LC=0.0561 8$MC=0.01440 21 -206TL L 304.896 6 1- 4.2 PS 14 -206TL A 4650 4 60 6 49 -206TL G 304.896 6 0.000061 7M1 0.375 6 -206TL2 G KC=0.308 5$LC=0.0519 8$MC=0.01211 17 - -210PO 210BI B- DECAY (5.011 D) -210PO H TYP=UPD$AUT=M.A.Kellett$CUT=01-OCT-2014$ -210PO2 H TYP=FUL$AUT=V. Chiste. M.-M.Be$CUT=31-JAN-2008$ -210PO C Evaluation history: Type=UPD;Author=M.A.Kellett;Cutoff date=01-OCT-2014 -210PO2C Type=FUL;Author=V. Chiste. M.-M.Be;Cutoff date=31-JAN-2008 -210PO C References: 1935Po01, 1935Po01, 1939Fl02, 1939Fl02, 1940Ne04, 1940Ne04, -210PO2C 1944Hole, 1947Br36, 1947Br36, 1952Be22, 1952Be22, 1953Lo09, 1953Lo09, -210PO3C 1954Pl30, 1954Pl30, 1956Fi09, 1956Ro18, 1956Ro18, 1956Fi09, 1959Ro51, -210PO4C 1959Wa05, 1959Wa05, 1959Ro51, 1960Wa14, 1960Wa14, 1961Ru02, 1961Ru02, -210PO5C 1961Nu01, 1961Nu01, 1962Da03, 1962Ka27, 1962Ka27, 1962Da03, 1967Hs01, -210PO6C 1967Hs01, 1969Fl02, 1969Fl02, 1969La18, 1969La18, 1991Ry01, 1991Ry01, -210PO7C 1996Sc06, 1996Sc06, 1999Br39, 2002Ba85, 2002Ba85, 2003Br13, 2003Au03, -210PO8C 2003Br13, 2005Gr41, 2008BeZV, 2008Ki07, 2008Ko21, 2010MoZU, 2012Wa38 -210PO T Auger electrons and X ray energies and emission intensities: -210PO T {U Energy (keV)} {U Intensity} {U Line} -210PO T -210PO T 76.864 XKA2 -210PO T 79.293 XKA1 -210PO T -210PO T 89.256 |] XKB3 -210PO T 89.807 |] XKB1 -210PO T 90.363 |] XKB5II -210PO T -210PO T 92.263 |] XKB2 -210PO T 92.618 |] XKB4 -210PO T 92.983 |] XKO23 -210PO T -210PO T -210PO T 58.978-65.205 |] KLL AUGER -210PO T 71.902-79.289 |] KLX AUGER -210PO T 84.8-93.1 |] KXY AUGER -210PO T 5.506-16.864 L AUGER -210BI P 0.0 1- 5.011 D 5 1161.2 8 -210PO N 1.00E0 1.00E0 0.9999982 1.00E0 -210PO L 0 0+ 138.3763 D17 -210PO B 1161.2 8 99.99986 2 8 1 -210POS B EAV=317 3 - +206TL 210BI A DECAY (5.011 D) +206TL H TYP=UPD$AUT=M.A.KELLETT$CUT=01-OCT-2014$ +206TL2 H TYP=FUL$AUT=V.CHISTE, M.-M.BE$CUT=31-JAN-2008$ +206TL C References:1926Mc**, 1927Cu**, 1935Po01, 1935Po01, 1939Fl02, 1939Fl02, +206TL2C 1940Ne04, 1940Ne04, 1944Ho**, 1944Ho**, 1947Br36, 1947Br36, 1952Be22, +206TL3C 1952Be22, 1953Lo09, 1953Lo09, 1954Pl30, 1954Pl30, 1956Fi09, 1956Ro18, +206TL4C 1956Ro18, 1956Fi09, 1959Ro51, 1959Wa05, 1959Wa05, 1959Ro51, 1960Wa14, +206TL5C 1960Wa14, 1961Ru02, 1961Ru02, 1961Nu01, 1961Nu01, 1962Da03, 1962Ka27, +206TL6C 1962Ka27, 1962Da03, 1967Hs01, 1967Hs01, 1969Fl02, 1969Fl02, 1969La18, +206TL7C 1969La18, 1991Ry01, 1991Ry01, 1996Sc06, 1996Sc06, 1999Br39, 2002Ba85, +206TL8C 2002Ba85, 2003Br13, 2003Au03, 2003Br13, 2005Gr41, 2008BeZV, 2008Ki07, +206TL9C 2008Ko21, 2010MoZU, 2012Wa38 +206TL T Auger electrons and X ray energies and emission intensities: +206TL T {U Energy (keV)} {U Intensity} {U Line} +206TL T +206TL T 70.8325 6.4E-6 7 XKA2 +206TL T 72.8725 1.08E-5 11 XKA1 +206TL T +206TL T 82.118 |] XKB3 +206TL T 82.577 |] 3.7E-6 4 XKB1 +206TL T 83.115 |] XKB5II +206TL T +206TL T 84.838 |] XKB2 +206TL T 85.134 |] 1.10E-6 11 XKB4 +206TL T 85.444 |] XKO23 +206TL T +206TL T 8.9531-14.7362 9.0E-6 5 XL (total) +206TL T 8.9531 2.13E-7 16 XLL +206TL T 10.1718-10.2679 4.09E-6 28 XLA +206TL T 10.9942 7.2E-8 6 XLC +206TL T 11.8117-12.9566 3.86E-6 23 XLB +206TL T 13.8528-14.7362 7.3E-7 5 XLG +206TL T +206TL T 54.587-59.954 |] KLL AUGER +206TL T 66.37-72.86 |] 8.5E-7 13 KLX AUGER +206TL T 78.12-85.5 |] KXY AUGER +206TL T 5.2493-15.3183 1.55E-5 6 L AUGER +210BI P 0.0 1- 5.011 D 5 5036.5 8 +206TL N 7.143E5 7.143E5 1.4E-6 2 +206TL L 0 0- 4.202 M 11 +206TL L 265.832 5 2- 2.29 NS 14 +206TL A 4687 4 40.0 4358 +206TL G 265.832 5 0.000048 5E2 0.1603 23 +206TL2 G KC=0.0855 12$LC=0.0561 8$MC=0.01440 21$NC=0.00361 5 +206TL3 G OC=0.000639 9 +206TL L 304.896 6 1- 4.2 PS 14 +206TL A 4650 4 60 649 +206TL G 304.896 6 0.000061 7M1 0.375 6 +206TL2 G KC=0.308 5$LC=0.0519 8$MC=0.01211 17$NC=0.00306 5 +206TL3 G OC=0.000594 9 + +210PO 210BI B- DECAY (5.011 D) +210PO H TYP=UPD$AUT=M.A.KELLETT$CUT=01-OCT-2014$ +210PO2 H TYP=FUL$AUT=V.CHISTE, M.-M.BE$CUT=31-JAN-2008$ +210PO C References:1926Mc**, 1927Cu**, 1935Po01, 1935Po01, 1939Fl02, 1939Fl02, +210PO2C 1940Ne04, 1940Ne04, 1944Ho**, 1944Ho**, 1947Br36, 1947Br36, 1952Be22, +210PO3C 1952Be22, 1953Lo09, 1953Lo09, 1954Pl30, 1954Pl30, 1956Fi09, 1956Ro18, +210PO4C 1956Ro18, 1956Fi09, 1959Ro51, 1959Wa05, 1959Wa05, 1959Ro51, 1960Wa14, +210PO5C 1960Wa14, 1961Ru02, 1961Ru02, 1961Nu01, 1961Nu01, 1962Da03, 1962Ka27, +210PO6C 1962Ka27, 1962Da03, 1967Hs01, 1967Hs01, 1969Fl02, 1969Fl02, 1969La18, +210PO7C 1969La18, 1991Ry01, 1991Ry01, 1996Sc06, 1996Sc06, 1999Br39, 2002Ba85, +210PO8C 2002Ba85, 2003Br13, 2003Au03, 2003Br13, 2005Gr41, 2008BeZV, 2008Ki07, +210PO9C 2008Ko21, 2010MoZU, 2012Wa38 +210PO T Auger electrons and X ray energies and emission intensities: +210PO T {U Energy (keV)} {U Intensity} {U Line} +210PO T +210PO T 76.864 XKA2 +210PO T 79.293 XKA1 +210PO T +210PO T 89.256 |] XKB3 +210PO T 89.807 |] XKB1 +210PO T 90.363 |] XKB5II +210PO T +210PO T 92.263 |] XKB2 +210PO T 92.618 |] XKB4 +210PO T 92.983 |] XKO23 +210PO T +210PO T +210PO T 58.978-65.205 |] KLL AUGER +210PO T 71.902-79.289 |] KLX AUGER +210PO T 84.8-93.1 |] KXY AUGER +210PO T 5.506-16.864 L AUGER +210BI P 0.0 1- 5.011 D 5 1161.2 8 +210PO N 1.00E0 1.00E0 0.999999011.00E0 +210PO L 0 0+ 138.3763 D17 +210PO B 1161.2 8 99.99986 2 8 1 +210POS B EAV=317 3 + diff --git a/HEN_HOUSE/spectra/lnhb/Bi-211.txt b/HEN_HOUSE/spectra/lnhb/Bi-211.txt index b31aaaf83..5d61d25f8 100644 --- a/HEN_HOUSE/spectra/lnhb/Bi-211.txt +++ b/HEN_HOUSE/spectra/lnhb/Bi-211.txt @@ -1,72 +1,71 @@ -207TL 211BI A DECAY (2.15 M) -207TL H TYP=Full$AUT=A.Luca$CUT=31-DEC-2008$ -207TL C Evaluation history: Type=Full;Author=A.Luca;Cutoff date=31-DEC-2008 -207TL C References: 1931CU01, 1954SP32, 1962Wa18, 1962Gi04, 1965NU03, 1966Go13, -207TL2C 1967Da10, 1968Br17, 1970MU21, 1971Ko37, 1971Gr17, 1973UrZX, 1975VaYT, -207TL3C 1976Bl13, 1982Mo30, 1988Hi14, 1989It01, 1991Ry01, 1992Sc26, 1993Ma73, -207TL4C 2003Au03, 2004Br45, 2008Ki07 -207TL T Auger electrons and X ray energies and emission intensities: -207TL T {U Energy (keV)} {U Intensity} {U Line} -207TL T -207TL T 70.8325 0.726 16 XKA2 -207TL T 72.8725 1.225 27 XKA1 -207TL T -207TL T 82.118 |] XKB3 -207TL T 82.577 |] 0.417 11 XKB1 -207TL T 83.115 |] XKB5II -207TL T -207TL T 84.838 |] XKB2 -207TL T 85.134 |] 0.124 4 XKB4 -207TL T 85.444 |] XKO23 -207TL T -207TL T 8.9531-14.7362 0.929 19 XL (total) -207TL T 8.9531 0.0228 7 XLL -207TL T 10.1718-10.2679 0.438 12 XLA -207TL T 10.9942 0.00696 22 XLC -207TL T 11.8117-12.9566 0.388 9 XLB -207TL T 13.8528-14.7362 0.0724 18 XLG -207TL T -207TL T 54.587-59.954 |] KLL AUGER -207TL T 66.37-72.86 |] 0.096 11 KLX AUGER -207TL T 78.12-85.5 |] KXY AUGER -207TL T 5.18-15.31 1.617 21 L AUGER -211BI P 0.0 9/2- 2.15 M 2 6750.33 46 -207TL N 1.003E0 1.003E0 0.99724 4 1.003E0 -207TL L 0 1/2+ 4.774 M 12 -207TL A 6622.4 6 83.79 23187 -207TL L 351.03 4 3/2+ 30 PS 7 -207TL A 6278.5 9 16.20 2343 -207TL G 351.03 4 13.00 19M1+E2 0.271 4 0.243 4 -207TL2 G KC=0.199 3$LC=0.0342 5$MC=0.00801 12 - -211PO 211BI B- DECAY (2.15 M) -211PO H TYP=Full$AUT=A.Luca$CUT=31-DEC-2008$ -211PO C Evaluation history: Type=Full;Author=A.Luca;Cutoff date=31-DEC-2008 -211PO C References: 1931CU01, 1954SP32, 1962Wa18, 1962Gi04, 1965NU03, 1966Go13, -211PO2C 1967Da10, 1968Br17, 1970MU21, 1971Ko37, 1971Gr17, 1973UrZX, 1975VaYT, -211PO3C 1976Bl13, 1982Mo30, 1988Hi14, 1989It01, 1991Ry01, 1992Sc26, 1993Ma73, -211PO4C 2003Au03, 2004Br45, 2008Ki07 -211PO T Auger electrons and X ray energies and emission intensities: -211PO T {U Energy (keV)} {U Intensity} {U Line} -211PO T -211PO T 76.864 XKA2 -211PO T 79.293 XKA1 -211PO T -211PO T 89.256 |] XKB3 -211PO T 89.807 |] XKB1 -211PO T 90.363 |] XKB5II -211PO T -211PO T 92.263 |] XKB2 -211PO T 92.618 |] XKB4 -211PO T 92.983 |] XKO23 -211PO T -211PO T -211PO T 58.978-65.205 |] KLL AUGER -211PO T 71.902-79.289 |] KLX AUGER -211PO T 84.8-93.1 |] KXY AUGER -211BI P 0.0 9/2- 2.15 M 2 574 5 -211PO N 3.623E2 3.623E2 0.00276 3.623E2 -211PO L 0 9/2+ 0.516 S 3 -211PO B 574 5 0.276 4 5.99 -211POS B EAV=172.9 18 - +207TL 211BI A DECAY (2.15 M) +207TL H TYP=FUL$AUT=A.LUCA$CUT=31-DEC-2008$ +207TL C References:1931CU01, 1954SP32, 1962Wa18, 1962Gi04, 1965NU03, 1966Go13, +207TL2C 1967Da10, 1968Br17, 1970MU21, 1971Ko37, 1971Gr17, 1973UrZX, 1975VaYT, +207TL3C 1976Bl13, 1982Mo30, 1988Hi14, 1989It01, 1991Ry01, 1992Sc26, 1993Ma73, +207TL4C 2003Au03, 2004Br45, 2008Ki07 +207TL T Auger electrons and X ray energies and emission intensities: +207TL T {U Energy (keV)} {U Intensity} {U Line} +207TL T +207TL T 70.8325 0.726 16 XKA2 +207TL T 72.8725 1.225 27 XKA1 +207TL T +207TL T 82.118 |] XKB3 +207TL T 82.577 |] 0.417 11 XKB1 +207TL T 83.115 |] XKB5II +207TL T +207TL T 84.838 |] XKB2 +207TL T 85.134 |] 0.124 4 XKB4 +207TL T 85.444 |] XKO23 +207TL T +207TL T 8.9531-14.7362 0.929 19 XL (total) +207TL T 8.9531 0.0228 7 XLL +207TL T 10.1718-10.2679 0.438 12 XLA +207TL T 10.9942 0.00696 22 XLC +207TL T 11.8117-12.9566 0.388 9 XLB +207TL T 13.8528-14.7362 0.0724 18 XLG +207TL T +207TL T 54.587-59.954 |] KLL AUGER +207TL T 66.37-72.86 |] 0.096 11 KLX AUGER +207TL T 78.12-85.5 |] KXY AUGER +207TL T 5.18-15.31 1.617 21 L AUGER +211BI P 0.0 9/2- 2.15 M 2 6750.33 46 +207TL N 1.003E0 1.003E0 0.99724 4 +207TL L 0 1/2+ 4.774 M 12 +207TL A 6622.4 6 83.79 23187 +207TL L 351.03 4 3/2+ 30 PS 7 +207TL A 6278.5 9 16.20 2343 +207TL G 351.03 4 13.00 19M1+E2 0.271 4 0.243 4 +207TL2 G KC=0.199 3$LC=0.0342 5$MC=0.00801 12$NC=0.00202 3 +207TL3 G OC=0.000391 6 + +211PO 211BI B- DECAY (2.15 M) +211PO H TYP=FUL$AUT=A.LUCA$CUT=31-DEC-2008$ +211PO C References:1931CU01, 1954SP32, 1962Wa18, 1962Gi04, 1965NU03, 1966Go13, +211PO2C 1967Da10, 1968Br17, 1970MU21, 1971Ko37, 1971Gr17, 1973UrZX, 1975VaYT, +211PO3C 1976Bl13, 1982Mo30, 1988Hi14, 1989It01, 1991Ry01, 1992Sc26, 1993Ma73, +211PO4C 2003Au03, 2004Br45, 2008Ki07 +211PO T Auger electrons and X ray energies and emission intensities: +211PO T {U Energy (keV)} {U Intensity} {U Line} +211PO T +211PO T 76.864 XKA2 +211PO T 79.293 XKA1 +211PO T +211PO T 89.256 |] XKB3 +211PO T 89.807 |] XKB1 +211PO T 90.363 |] XKB5II +211PO T +211PO T 92.263 |] XKB2 +211PO T 92.618 |] XKB4 +211PO T 92.983 |] XKO23 +211PO T +211PO T +211PO T 58.978-65.205 |] KLL AUGER +211PO T 71.902-79.289 |] KLX AUGER +211PO T 84.8-93.1 |] KXY AUGER +211BI P 0.0 9/2- 2.15 M 2 574 5 +211PO N 3.623E2 3.623E2 0.00276 3.623E2 +211PO L 0 9/2+ 0.516 S 3 +211PO B 574 5 0.276 4 5.99 +211POS B EAV=172.9 18 + diff --git a/HEN_HOUSE/spectra/lnhb/Bi-212.txt b/HEN_HOUSE/spectra/lnhb/Bi-212.txt index 5681883bb..da9a54674 100644 --- a/HEN_HOUSE/spectra/lnhb/Bi-212.txt +++ b/HEN_HOUSE/spectra/lnhb/Bi-212.txt @@ -1,158 +1,175 @@ -208TL 212BI A DECAY (60.54 M) -208TL H TYP=Update$AUT=A.L. Nichols$CUT=30-MAY-2010$ -208TL2 H TYP=Full$AUT=A.L. Nichols$CUT=30-NOV-2003$ -208TL C Evaluation history: Type=Update;Author=A.L. Nichols;Cutoff date=30-MAY-2010 -208TL2C Type=Full;Author=A.L. Nichols;Cutoff date=30-NOV-2003 -208TL C References: 1914Le01, 1951Ry17, 1957Bu34, 1960Wa14, 1960Em01, 1960Sc07, -208TL2C 1961Ap03, 1962Fl03, 1962Be09, 1965Wa09, 1965Le08, 1966KlZZ, 1967Be19, -208TL3C 1968Yt02, 1972DaZA, 1973Da38, 1977La19, 1978Av01, 1982Be09, 1982Sa36, -208TL4C 1983Sc13, 1983Va22, 1984Ge07, 1992Li05, 1996Sc06, 1998ScZM, 1999ScZX, -208TL5C 2002Ra45, 2002Ba85, 2003Au03, 2005Br03, 2007St23, 2007Ma45, 2008Ki07 -208TL T Auger electrons and X ray energies and emission intensities: -208TL T {U Energy (keV)} {U Intensity} {U Line} -208TL T -208TL T 70.8325 0.0525 23 XKA2 -208TL T 72.8725 0.089 4 XKA1 -208TL T -208TL T 82.118 |] XKB3 -208TL T 82.577 |] 0.0301 14 XKB1 -208TL T 83.115 |] XKB5II -208TL T -208TL T 84.838 |] XKB2 -208TL T 85.134 |] 0.0089 5 XKB4 -208TL T 85.444 |] XKO23 -208TL T -208TL T 8.953-14.738 7.1 3 XL (total) -208TL T 8.953 0.171 6 XLL -208TL T 10.172-10.268 3.3 1 XLA -208TL T 10.994 0.0230 7 XLC -208TL T 11.812-12.643 2.76 5 XLB -208TL T 14.291-14.738 0.579 9 XLG -208TL T -208TL T 54.587-59.954 |] KLL AUGER -208TL T 66.37-72.86 |] 0.0069 8 KLX AUGER -208TL T 78.12-85.5 |] KXY AUGER -208TL T 5.182-10.132 12.2 4 L AUGER -212BI P 0.0 1- 60.54 M 6 6207.26 3 -208TL N 2.783E0 2.783E0 0.3593 2.783E0 -208TL L 0 5+ 3.058 M 6 -208TL A 0 -208TL A 6090.14 3 27.00 28481 -208TL L 39.858 4 4+ -208TL A 6051.04 3 69.86 28126 -208TL G 39.858 4 1.07 1[M1] 23.3 4 -208TL2 G LC=17.81 25$MC=4.17 6 -208TL L 328.04 5 5+ -208TL A 5768.29 6 1.70 8 279 -208TL G 288.18 5 0.32 2M1+E2 0.08 0.436 7 -208TL2 G KC=0.357 5$LC=0.0605 9$MC=0.01411 20 -208TL G 328.04 5 0.121 3[M1] 0.308 5 -208TL2 G KC=0.252 4$LC=0.0425 6$MC=0.00991 14 -208TL L 473.4 4 (4)+ -208TL A 5625.7 4 0.167 8 595 -208TL G 433.5 4 0.011 1[M1] 0.1453 21 -208TL2 G KC=0.1193 17$LC=0.0199 3$MC=0.00465 7 -208TL G 473.4 4 0.044 3[M1+E2] 1.0 2 0.074 10 -208TL2 G KC=0.059 8$LC=0.0115 10$MC=0.00273 21 -208TL L 492.84 4 (3)+ -208TL A 5606.60 5 1.20 8 67 -208TL G 164.80 6 0.0055 6(E2) 0.816 12 -208TL2 G KC=0.263 4$LC=0.413 6$MC=0.1078 16 -208TL G 452.98 4 0.34 3(M1) 0.1293 18 -208TL2 G KC=0.1061 15$LC=0.01772 25$MC=0.00413 6 -208TL G 492.84 4 0.039 10E2 0.0291 4 -208TL2 G KC=0.0207 3$LC=0.00633 9$MC=1567E-6 22 -208TL L 617 2 + -208TL L 620.4 3 (6)+ -208TL A 5481.4 3 0.0139 111380 -208TL G 580.5 3 0.0011 2E2 0.0198 3 -208TL2 G KC=0.01470 21$LC=0.00388 6$MC=9.50E-4 14 -208TL G 620.4 3 0.0038 4[M1+E2] 1.0 2 0.037 5 -208TL2 G KC=0.030 4$LC=0.0054 5$MC=0.00129 12 -208TL L 760 2 + -208TL A 5344 2 0.00100 8 3770 -208TL L 803 2 + -208TL A 5302 2 11100E-81120300 - -212PO 212BI B- DECAY (60.54 M) -212PO H TYP=Update$AUT=A.L. Nichols$CUT=30-MAY-2010$ -212PO2 H TYP=Full$AUT=A.L. Nichols$CUT=30-NOV-2003$ -212PO C Evaluation history: Type=Update;Author=A.L. Nichols;Cutoff date=30-MAY-2010 -212PO2C Type=Full;Author=A.L. Nichols;Cutoff date=30-NOV-2003 -212PO C References: 1914Le01, 1951Ry17, 1957Bu34, 1960Wa14, 1960Em01, 1960Sc07, -212PO2C 1961Ap03, 1962Fl03, 1962Be09, 1965Wa09, 1965Le08, 1966KlZZ, 1967Be19, -212PO3C 1968Yt02, 1972DaZA, 1973Da38, 1977La19, 1978Av01, 1982Be09, 1982Sa36, -212PO4C 1983Sc13, 1983Va22, 1984Ge07, 1992Li05, 1996Sc06, 1998ScZM, 1999ScZX, -212PO5C 2002Ra45, 2002Ba85, 2003Au03, 2005Br03, 2007St23, 2007Ma45, 2008Ki07 -212PO T Auger electrons and X ray energies and emission intensities: -212PO T {U Energy (keV)} {U Intensity} {U Line} -212PO T -212PO T 76.864 0.0388 8 XKA2 -212PO T 79.293 0.0647 13 XKA1 -212PO T -212PO T 89.256 |] XKB3 -212PO T 89.807 |] 0.0223 6 XKB1 -212PO T 90.363 |] XKB5II -212PO T -212PO T 92.263 |] XKB2 -212PO T 92.618 |] 0.00693 20 XKB4 -212PO T 92.983 |] XKO23 -212PO T -212PO T 9.658-16.213 0.0563 24 XL (total) -212PO T 9.658 0.00138 4 XLL -212PO T 11.016-11.13 0.0253 7 XLA -212PO T 12.085 0.00044013 XLC -212PO T 12.823-13.778 0.0241 6 XLB -212PO T 15.742-16.213 0.00477 11 XLG -212PO T -212PO T 58.978-65.205 |] KLL AUGER -212PO T 71.902-79.289 |] 0.0048 6 KLX AUGER -212PO T 84.8-93.1 |] KXY AUGER -212PO T 5.434-10.934 0.0833 25 L AUGER -212BI P 0.0 1- 60.54 M 6 2252.1 17 -212PO N 1.561E0 1.561E0 0.6407 1.561E0 -212PO L 0 0+ 300 NS 2 -212PO B 2252.1 1755.31 9 7.267 1 -212POS B EAV=834.2 7 -212PO L 727.330 9 2+ -212PO B 1524.8 174.50 6 7.718 1 -212POS B EAV=533.1 7 -212PO G 727.330 9 6.65 4E2 0.0139320 -212PO2 G KC=0.01054 15$LC=0.00257 4$MC=6.28E-4 9 -212PO L 1512.70 8 2+ -212PO B 739.4 171.44 1 7.094 1 -212POS B EAV=230.8 6 -212PO G 785.37 9 1.11 1M1+E2 0.09 0.0387 6 -212PO2 G KC=0.0316 5$LC=0.00539 8$MC=1266E-6 18 -212PO G 1512.70 8 0.29 1E2 0.00344 5 -212PO2 G KC=0.00274 4$LC=4.83E-4 7$MC=1139E-7 16 -212PO L 1620.738 101+ -212PO B 631.4 171.90 3 6.74 -212POS B EAV=192.7 6 -212PO G 893.408 140.38 1M1+E2 0.045 0.0278 4 -212PO2 G KC=0.0227 4$LC=0.00386 6$MC=9.06E-4 13 -212PO G 1620.738 101.51 3[M1] 0.00620 9 -212PO2 G KC=0.00494 7$LC=8.24E-4 12$MC=1.93E-4 3 -212PO L 1679.450 142+ -212PO B 572.7 170.21 4 7.55 1 -212POS B EAV=172.4 6 -212PO G 952.12 2 0.14 4M1+E2 0.65 0.0190 3 -212PO2 G KC=0.01548 22$LC=0.00269 4$MC=6.34E-4 9 -212PO G 1679.450 140.07 1E2 0.00291 4 -212PO2 G KC=0.00227 4$LC=3.91E-4 6$MC=9.20E-5 13 -212PO L 1800.9 2 0+ -212PO B 451.2 170.032 4 8.03 1 -212POS B EAV=131.7 6 -212PO G 180.2 2 0.0031 12M1 2.08 3 -212PO2 G KC=1.692 25$LC=0.298 5$MC=0.0704 10 -212PO G 1073.6 2 0.0154 6E2 0.00642 9 -212PO2 G KC=0.00510 8$LC=1002E-6 14$MC=2.40E-4 4 -212PO G 1800.9 2 -212PO L 1805.96 102+ -212PO B 446.1 170.68 4 6.67 1 -212POS B EAV=130.1 6 -212PO G 1078.63 100.55 2M1+E2 0.135 0.0169224 -212PO2 G KC=0.01386 20$LC=0.00234 4$MC=5.49E-4 8 -212PO G 1805.96 100.12 3E2 0.00261 4 -212PO2 G KC=0.00200 3$LC=3.38E-4 5$MC=7.94E-5 12 - +208TL 212BI A DECAY (60.54 M) +208TL H TYP=UPD$AUT=A.L.NICHOLS$CUT=30-MAY-2010$ +208TL2 H TYP=FUL$AUT=A.L.NICHOLS$CUT=30-NOV-2003$ +208TL C References:1914Le01, 1951Ry17, 1957Bu34, 1960Wa14, 1960Em01, 1960Sc07, +208TL2C 1961Ap03, 1962Fl03, 1962Be09, 1965Wa09, 1965Le08, 1966KlZZ, 1967Be19, +208TL3C 1968Yt02, 1972DaZA, 1973Da38, 1977La19, 1978Av01, 1982Be09, 1982Sa36, +208TL4C 1983Sc13, 1983Va22, 1984Ge07, 1992Li05, 1996Sc06, 1998ScZM, 1999ScZX, +208TL5C 2002Ra45, 2002Ba85, 2003Au03, 2005Br03, 2007St23, 2007Ma45, 2008Ki07 +208TL T Auger electrons and X ray energies and emission intensities: +208TL T {U Energy (keV)} {U Intensity} {U Line} +208TL T +208TL T 70.8325 0.0525 23 XKA2 +208TL T 72.8725 0.089 4 XKA1 +208TL T +208TL T 82.118 |] XKB3 +208TL T 82.577 |] 0.0301 14 XKB1 +208TL T 83.115 |] XKB5II +208TL T +208TL T 84.838 |] XKB2 +208TL T 85.134 |] 0.0089 5 XKB4 +208TL T 85.444 |] XKO23 +208TL T +208TL T 8.953-14.738 7.1 3 XL (total) +208TL T 8.953 0.171 6 XLL +208TL T 10.172-10.268 3.3 1 XLA +208TL T 10.994 0.0230 7 XLC +208TL T 11.812-12.643 2.76 5 XLB +208TL T 14.291-14.738 0.579 9 XLG +208TL T +208TL T 54.587-59.954 |] KLL AUGER +208TL T 66.37-72.86 |] 0.0069 8 KLX AUGER +208TL T 78.12-85.5 |] KXY AUGER +208TL T 5.182-10.132 12.2 4 L AUGER +212BI P 0.0 1- 60.54 M 6 6207.26 3 +208TL N 2.783E0 2.783E0 0.3593 +208TL L 0 5+ 3.058 M 6 +208TL A 1E-9 +208TL A 6090.14 3 27.00 28481 +208TL L 39.858 4 4+ +208TL A 6051.04 3 69.86 28126 +208TL G 39.858 4 1.07 1[M1] 23.3 4 +208TL2 G LC=17.81 25$MC=4.17 6$NC=1.052 15 +208TL3 G OC=0.204 3 +208TL L 328.04 5 5+ +208TL A 5768.29 6 1.70 8279 +208TL G 288.18 5 0.32 2M1+E2 0.08 0.436 7 +208TL2 G KC=0.357 5$LC=0.0605 9$MC=0.01411 20$NC=0.00356 5 +208TL3 G OC=0.000692 10 +208TL G 328.04 5 0.121 3[M1] 0.308 5 +208TL2 G KC=0.252 4$LC=0.0425 6$MC=0.00991 14$NC=0.00250 4 +208TL3 G OC=0.000486 7 +208TL L 473.4 4 (4)+ +208TL A 5625.7 4 0.167 8595 +208TL G 433.5 4 0.011 1[M1] 0.1453 21 +208TL2 G KC=0.1193 17$LC=0.0199 3$MC=0.00465 7$NC=0.001173 17 +208TL3 G OC=0.000228 4 +208TL G 473.4 4 0.044 3[M1+E2] 1.0 2 0.074 10 +208TL2 G KC=0.059 8$LC=0.0115 10$MC=0.00273 21$NC=0.00069 6 +208TL3 G OC=0.000131 11 +208TL L 492.84 4 (3)+ +208TL A 5606.60 5 1.20 867 +208TL G 164.80 6 0.0055 6(E2) 0.816 12 +208TL2 G KC=0.263 4$LC=0.413 6$MC=0.1078 16$NC=0.0270 4 +208TL3 G OC=0.00469 7 +208TL G 452.98 4 0.34 3(M1) 0.1293 18 +208TL2 G KC=0.1061 15$LC=0.01772 25$MC=0.00413 6$NC=0.001043 15 +208TL3 G OC=0.000203 3 +208TL G 492.84 4 0.039 10E2 0.0291 4 +208TL2 G KC=0.0207 3$LC=0.00633 9$MC=0.001567 22$NC=0.000394 6 +208TL3 G OC=7.22E-5 11 +208TL L 617 2 +208TL L 620.4 3 (6)+ +208TL A 5481.4 3 0.0139 111380 +208TL G 580.5 3 0.0011 2E2 0.0198 3 +208TL2 G KC=0.01470 21$LC=0.00388 6$MC=0.000950 14$NC=0.000239 4 +208TL3 G OC=4.42E-5 7 +208TL G 620.4 3 0.0038 4[M1+E2] 1.0 2 0.037 5 +208TL2 G KC=0.030 4$LC=0.0054 5$MC=0.00129 12$NC=0.00032 3 +208TL3 G OC=0.000062 6 +208TL L 760 2 +208TL A 5344 2 0.00100 83770 +208TL L 803 2 +208TL A 5302 2 0.0001111120300 + +212PO 212BI B- DECAY (60.54 M) +212PO H TYP=UPD$AUT=A.L.NICHOLS$CUT=30-MAY-2010$ +212PO2 H TYP=FUL$AUT=A.L.NICHOLS$CUT=30-NOV-2003$ +212PO C References:1914Le01, 1951Ry17, 1957Bu34, 1960Wa14, 1960Em01, 1960Sc07, +212PO2C 1961Ap03, 1962Fl03, 1962Be09, 1965Wa09, 1965Le08, 1966KlZZ, 1967Be19, +212PO3C 1968Yt02, 1972DaZA, 1973Da38, 1977La19, 1978Av01, 1982Be09, 1982Sa36, +212PO4C 1983Sc13, 1983Va22, 1984Ge07, 1992Li05, 1996Sc06, 1998ScZM, 1999ScZX, +212PO5C 2002Ra45, 2002Ba85, 2003Au03, 2005Br03, 2007St23, 2007Ma45, 2008Ki07 +212PO T Auger electrons and X ray energies and emission intensities: +212PO T {U Energy (keV)} {U Intensity} {U Line} +212PO T +212PO T 76.864 0.0388 8 XKA2 +212PO T 79.293 0.0647 13 XKA1 +212PO T +212PO T 89.256 |] XKB3 +212PO T 89.807 |] 0.0223 6 XKB1 +212PO T 90.363 |] XKB5II +212PO T +212PO T 92.263 |] XKB2 +212PO T 92.618 |] 0.00693 20 XKB4 +212PO T 92.983 |] XKO23 +212PO T +212PO T 9.658-16.213 0.0563 24 XL (total) +212PO T 9.658 0.00138 4 XLL +212PO T 11.016-11.13 0.0253 7 XLA +212PO T 12.085 0.00044013 XLC +212PO T 12.823-13.778 0.0241 6 XLB +212PO T 15.742-16.213 0.00477 11 XLG +212PO T +212PO T 58.978-65.205 |] KLL AUGER +212PO T 71.902-79.289 |] 0.0048 6 KLX AUGER +212PO T 84.8-93.1 |] KXY AUGER +212PO T 5.434-10.934 0.0833 25 L AUGER +212BI P 0.0 1- 60.54 M 6 2252.1 17 +212PO N 1.561E0 1.561E0 0.6407 1.561E0 +212PO L 0 0+ 300 NS 2 +212PO B 2252.1 1755.31 9 7.267 1 +212POS B EAV=834.2 7 +212PO L 727.330 9 2+ +212PO B 1524.8 174.50 6 7.718 1 +212POS B EAV=533.1 7 +212PO G 727.330 9 6.65 4E2 0.0139320 +212PO2 G KC=0.01054 15$LC=0.00257 4$MC=0.000628 9$NC=1.613E-4 23 +212PO3 G OC=3.28E-5 5 +212PO L 1512.70 8 2+ +212PO B 739.4 171.44 1 7.094 1 +212POS B EAV=230.8 6 +212PO G 785.37 9 1.11 1M1+E2 0.09 0.0387 6 +212PO2 G KC=0.0316 5$LC=0.00539 8$MC=0.001266 18$NC=0.000326 5 +212PO3 G OC=6.82E-5 10 +212PO G 1512.70 8 0.29 1E2 0.00344 5 +212PO2 G KC=0.00274 4$LC=0.000483 7$MC=1.139E-4 16$NC=2.93E-5 4 +212PO3 G OC=6.07E-6 9$IPC=6.63E-5 10 +212PO L 1620.738 101+ +212PO B 631.4 171.90 3 6.74 +212POS B EAV=192.7 6 +212PO G 893.408 140.38 1M1+E2 0.045 0.0278 4 +212PO2 G KC=0.0227 4$LC=0.00386 6$MC=0.000906 13$NC=0.000233 4 +212PO3 G OC=4.88E-5 7 +212PO G 1620.738 101.51 3[M1] 0.00620 9 +212PO2 G KC=0.00494 7$LC=0.000824 12$MC=0.000193 3$NC=4.97E-5 7 +212PO3 G OC=1.041E-5 15$IPC=0.000185 3 +212PO L 1679.450 142+ +212PO B 572.7 170.21 4 7.55 1 +212POS B EAV=172.4 6 +212PO G 952.12 2 0.14 4M1+E2 0.65 0.0190 3 +212PO2 G KC=0.01548 22$LC=0.00269 4$MC=0.000634 9$NC=1.632E-4 23 +212PO3 G OC=3.41E-5 5 +212PO G 1679.450 140.07 1E2 0.00291 4 +212PO2 G KC=0.00227 4$LC=0.000391 6$MC=9.20E-5 13$NC=2.36E-5 4 +212PO3 G OC=4.91E-6 7$IPC=1.252E-4 18 +212PO L 1800.9 2 0+ +212PO B 451.2 170.032 4 8.03 1 +212POS B EAV=131.7 6 +212PO G 180.2 2 0.0031 12M1 2.08 3 +212PO2 G KC=1.692 25$LC=0.298 5$MC=0.0704 10$NC=0.0181 3 +212PO3 G OC=0.00379 6 +212PO G 1073.6 2 0.0154 6E2 0.00642 9 +212PO2 G KC=0.00510 8$LC=0.001002 14$MC=0.000240 4$NC=6.16E-5 9 +212PO3 G OC=1.269E-5 18 +212PO G 1800.9 2 E0 +212PO L 1805.96 102+ +212PO B 446.1 170.68 4 6.67 1 +212POS B EAV=130.1 6 +212PO G 1078.63 100.55 2M1+E2 0.135 0.0169224 +212PO2 G KC=0.01386 20$LC=0.00234 4$MC=0.000549 8$NC=1.413E-4 20 +212PO3 G OC=2.96E-5 5 +212PO G 1805.96 100.12 3E2 0.00261 4 +212PO2 G KC=0.00200 3$LC=0.000338 5$MC=7.94E-5 12$NC=2.04E-5 3 +212PO3 G OC=4.24E-6 6$IPC=1.758E-4 25 + diff --git a/HEN_HOUSE/spectra/lnhb/Bi-213.txt b/HEN_HOUSE/spectra/lnhb/Bi-213.txt index 2f565bb22..ab3089ddc 100644 --- a/HEN_HOUSE/spectra/lnhb/Bi-213.txt +++ b/HEN_HOUSE/spectra/lnhb/Bi-213.txt @@ -1,119 +1,120 @@ -209TL 213BI A DECAY (45.59 M) -209TL H TYP=Full$AUT=X. Huang$CUT=30-JAN-2006$ -209TL C Evaluation history: Type=Full;Author=X. Huang;Cutoff date=30-JAN-2006 -209TL T Auger electrons and X ray energies and emission intensities: -209TL T {U Energy (keV)} {U Intensity} {U Line} -209TL T -209TL T 70.8325 0.0058 7 XKA2 -209TL T 72.8725 0.0098 12 XKA1 -209TL T -209TL T 82.118 |] XKB3 -209TL T 82.577 |] 0.0033 5 XKB1 -209TL T 83.115 |] XKB5II -209TL T -209TL T 84.838 |] XKB2 -209TL T 85.134 |] 0.00098 14 XKB4 -209TL T 85.444 |] XKO23 -209TL T -209TL T 8.9531-14.7362 0.0062 8 XL (total) -209TL T 8.9531 XLL -209TL T 10.1718-10.2679 XLA -209TL T 10.9942 XLC -209TL T 11.8117-12.9566 XLB -209TL T 13.8528-14.7362 XLG -209TL T -209TL T 54.587-59.954 |] KLL AUGER -209TL T 66.37-72.86 |] 0.00076 9 KLX AUGER -209TL T 78.12-85.5 |] KXY AUGER -209TL T 5.18-10.13 0.0107 13 L AUGER -213BI P 0.0 9/2- 45.59 M 6 5983 6 -209TL N 4.785E1 4.785E1 0.0209 3 4.785E1 -209TL L 0 1/2+ 2.161 M 7 -209TL A 5869 1090.9 19319 -209TL L 323.70 2 3/2+ -209TL A 5549 108.90 24103 -209TL G 323.70 2 0.1584 24M1+E2 1.26 16 0.178 15 -209TL2 G KC=0.134 14$LC=0.0333 13$MC=0.0081 3 - -213PO 213BI B- DECAY (45.59 M) -213PO H TYP=Full$AUT=X. Huang$CUT=30-JAN-2006$ -213PO C Evaluation history: Type=Full;Author=X. Huang;Cutoff date=30-JAN-2006 -213PO T Auger electrons and X ray energies and emission intensities: -213PO T {U Energy (keV)} {U Intensity} {U Line} -213PO T -213PO T 76.864 1.103 29 XKA2 -213PO T 79.293 1.84 5 XKA1 -213PO T -213PO T 89.256 |] XKB3 -213PO T 89.807 |] 0.633 19 XKB1 -213PO T 90.363 |] XKB5II -213PO T -213PO T 92.263 |] XKB2 -213PO T 92.618 |] 0.197 7 XKB4 -213PO T 92.983 |] XKO23 -213PO T -213PO T 9.6576-16.2129 1.54 4 XL (total) -213PO T 9.6576 0.0387 13 XLL -213PO T 11.0161-11.1303 0.710 21 XLA -213PO T 12.0847 0.0116 4 XLC -213PO T 12.8239-14.2476 0.653 16 XLB -213PO T 15.251-16.2129 0.128 4 XLG -213PO T -213PO T 58.978-65.205 |] KLL AUGER -213PO T 71.902-79.289 |] 0.137 16 KLX AUGER -213PO T 84.8-93.1 |] KXY AUGER -213PO T 5.43-16.86 2.31 4 L AUGER -213BI P 0.0 9/2- 45.59 M 6 1423 5 -213PO N 1.021E0 1.021E0 0.9791 3 1.021E0 -213PO L 0 9/2+ 3.70 US 5 -213PO B 1423 5 66.2 4 6.316 -213POS B EAV=492.2 20 -213PO L 292.796 8 11/2+ 78 PS 14 -213PO B 1130 5 0.21 9 8.45 1 -213POS B EAV=376.8 20 -213PO G 292.80 1 0.421 7M1+E2 1.2 8 0.30 18 -213PO2 G KC=0.22 17$LC=0.06 2$MC=1.5E-5 3 -213PO L 440.439 9 7/2+ 93 PS 3 -213PO B 983 5 30.8 4 6.07 1 -213POS B EAV=320.4 19 -213PO G 147.70 4 0.0128 8E2 1.453 21 -213PO2 G KC=0.307 4$LC=0.85 1$MC=2.26E-4 3 -213PO G 440.44 1 26.1 3M1 0.179 3 -213PO2 G KC=0.146 2$LC=0.0250 4$MC=0.00594 8 -213PO L 600.8 3 (5/2)+ -213PO B 822 5 0.0025 19 9.9 1U -213POS B EAV=260.8 19 -213PO G 600.9 2 0.0026 19 -213PO L 867.961 2013/2+ -213PO B 555 5 0.0129 6 8.597 1U -213POS B EAV=166.4 17 -213PO G 574.9 3 0.00068 16 -213PO G 867.960 200.0122 6 -213PO L 1003.593 17(9/2)+ -213PO B 419 5 0.0648 23 7.494 -213POS B EAV=121.4 17 -213PO G 402.8 3 0.00010 4 -213PO G 710.82 3 0.0112 6 -213PO G 1003.580 200.0535 22 -213PO L 1045.62 8 (2/9,11/2)+ -213PO B 377 5 0.020 4 7.85 -213POS B EAV=107.9 16 -213PO G 604.93 170.0014 5 -213PO G 1045.67 8 0.019 4 -213PO L 1100.168 8 7/2,9/2,11/2- -213PO B 323 5 0.595 17 6.16 -213POS B EAV=90.8 16 -213PO G 659.750 200.043 6 -213PO G 807.370 100.287 14 -213PO G 1100.16 1 0.265 6 -213PO L 1119.36 4 7/2,9/2,11/2+ -213PO B 304 5 0.0608 20 7.07 1 -213POS B EAV=84.9 16 -213PO G 826.550 400.0065 4 -213PO G 1119.42 8 0.0543 20 -213PO L 1328.2 3 (7/2,9/2,11/2)- -213PO B 95 5 0.0014 2 7.68 -213POS B EAV=24.6 14 -213PO G 886.66 140.00102 19 -213PO G 1328.2 3 0.00039 13 - +209TL 213BI A DECAY (45.59 M) +209TL H TYP=FUL$AUT=X.HUANG$CUT=30-JAN-2006$ +209TL T Auger electrons and X ray energies and emission intensities: +209TL T {U Energy (keV)} {U Intensity} {U Line} +209TL T +209TL T 70.8325 0.0058 7 XKA2 +209TL T 72.8725 0.0098 12 XKA1 +209TL T +209TL T 82.118 |] XKB3 +209TL T 82.577 |] 0.0033 5 XKB1 +209TL T 83.115 |] XKB5II +209TL T +209TL T 84.838 |] XKB2 +209TL T 85.134 |] 0.00098 14 XKB4 +209TL T 85.444 |] XKO23 +209TL T +209TL T 8.9531-14.7362 0.0062 8 XL (total) +209TL T 8.9531 XLL +209TL T 10.1718-10.2679 XLA +209TL T 10.9942 XLC +209TL T 11.8117-12.9566 XLB +209TL T 13.8528-14.7362 XLG +209TL T +209TL T 54.587-59.954 |] KLL AUGER +209TL T 66.37-72.86 |] 0.00076 9 KLX AUGER +209TL T 78.12-85.5 |] KXY AUGER +209TL T 5.18-10.13 0.0107 13 L AUGER +213BI P 0.0 9/2- 45.59 M 6 5983 6 +209TL N 4.785E1 4.785E1 0.0209 3 +209TL L 0 1/2+ 2.161 M 7 +209TL A 5869 1090.9 19319 +209TL L 323.70 2 3/2+ +209TL A 5549 108.90 24103 +209TL G 323.70 2 0.1584 24M1+E2 1.26 16 0.178 15 +209TL2 G KC=0.134 14$LC=0.0333 13$MC=0.0081 3$NC=0.00200 7 + +213PO 213BI B- DECAY (45.59 M) +213PO H TYP=FUL$AUT=X.HUANG$CUT=30-JAN-2006$ +213PO T Auger electrons and X ray energies and emission intensities: +213PO T {U Energy (keV)} {U Intensity} {U Line} +213PO T +213PO T 76.864 1.103 29 XKA2 +213PO T 79.293 1.84 5 XKA1 +213PO T +213PO T 89.256 |] XKB3 +213PO T 89.807 |] 0.633 19 XKB1 +213PO T 90.363 |] XKB5II +213PO T +213PO T 92.263 |] XKB2 +213PO T 92.618 |] 0.197 7 XKB4 +213PO T 92.983 |] XKO23 +213PO T +213PO T 9.6576-16.2129 1.54 4 XL (total) +213PO T 9.6576 0.0387 13 XLL +213PO T 11.0161-11.1303 0.710 21 XLA +213PO T 12.0847 0.0116 4 XLC +213PO T 12.8239-14.2476 0.653 16 XLB +213PO T 15.251-16.2129 0.128 4 XLG +213PO T +213PO T 58.978-65.205 |] KLL AUGER +213PO T 71.902-79.289 |] 0.137 16 KLX AUGER +213PO T 84.8-93.1 |] KXY AUGER +213PO T 5.43-16.86 2.31 4 L AUGER +213BI P 0.0 9/2- 45.59 M 6 1423 5 +213PO N 1.021E0 1.021E0 0.9791 31.021E0 +213PO L 0 9/2+ 3.70 US 5 +213PO B 1423 5 66.2 4 6.316 +213POS B EAV=492.2 20 +213PO L 292.796 8 11/2+ 78 PS 14 +213PO B 1130 5 0.21 9 8.45 1 +213POS B EAV=376.8 20 +213PO G 292.80 1 0.421 7M1+E2 1.2 8 0.30 18 +213PO2 G KC=0.22 17$LC=0.06 2$MC=0.000015 3$NC=0.0038 7 +213PO3 G OC=7.7E-8 16 +213PO L 440.439 9 7/2+ 93 PS 3 +213PO B 983 5 30.8 4 6.07 1 +213POS B EAV=320.4 19 +213PO G 147.70 4 0.0128 8E2 1.453 21 +213PO2 G KC=0.307 4$LC=0.85 1$MC=0.000226 3$NC=0.0580 8 +213PO3 G OC=1.10E-6 2 +213PO G 440.44 1 26.1 3M1 0.179 3 +213PO2 G KC=0.146 2$LC=0.0250 4$MC=0.00594 8$NC=0.00150 2 +213PO3 G OC=0.000320 5 +213PO L 600.8 3 (5/2)+ +213PO B 822 5 0.0025 19 9.9 1U +213POS B EAV=260.8 19 +213PO G 600.9 2 0.0026 19 +213PO L 867.961 2013/2+ +213PO B 555 5 0.0129 6 8.597 1U +213POS B EAV=166.4 17 +213PO G 574.9 3 0.00068 16 +213PO G 867.960 200.0122 6 +213PO L 1003.593 17(9/2)+ +213PO B 419 5 0.0648 23 7.494 +213POS B EAV=121.4 17 +213PO G 402.8 3 0.00010 4 +213PO G 710.82 3 0.0112 6 +213PO G 1003.580 200.0535 22 +213PO L 1045.62 8 (9/2,11/2)+ +213PO B 377 5 0.020 4 7.85 +213POS B EAV=107.9 16 +213PO G 604.93 170.0014 5 +213PO G 1045.67 8 0.019 4 +213PO L 1100.168 8 7/2,9/2,11/2- +213PO B 323 5 0.595 17 6.16 +213POS B EAV=90.8 16 +213PO G 659.750 200.043 6 +213PO G 807.370 100.287 14 +213PO G 1100.16 1 0.265 6 +213PO L 1119.36 4 7/2,9/2,11/2+ +213PO B 304 5 0.0608 20 7.07 1 +213POS B EAV=84.9 16 +213PO G 826.550 400.0065 4 +213PO G 1119.42 8 0.0543 20 +213PO L 1328.2 3 (7/2,9/2,11/2)- +213PO B 95 5 0.0014 2 7.68 +213POS B EAV=24.6 14 +213PO G 886.66 140.00102 19 +213PO G 1328.2 3 0.00039 13 + diff --git a/HEN_HOUSE/spectra/lnhb/Bi-214.txt b/HEN_HOUSE/spectra/lnhb/Bi-214.txt index 6a3fd762d..434a5044e 100644 --- a/HEN_HOUSE/spectra/lnhb/Bi-214.txt +++ b/HEN_HOUSE/spectra/lnhb/Bi-214.txt @@ -1,570 +1,638 @@ -210TL 214BI A DECAY (19.8 M) -210TL H TYP=Full$AUT=V.Chisté$CUT=31-JAN-2007$ -210TL C Evaluation history: Type=Full;Author=V.Chisté;Cutoff date=31-JAN-2007 -210TL C References: 1934Le01, 1951Co15, 1954Br07, 1956Da06, 1960Wa14, 1965Le08, -210TL2C 1969Gu15, 1969Li10, 1969Wa27, 1969Gr33, 1974Ha68, 1975Ha31, 1977Zo01, -210TL3C 1978Ro21, 1979He13, 1979Be12, 1981Mo28, 1982Ak03, 1982Fa10, 1983Sc13, -210TL4C 1983Ol01, 1990Mo08, 1990Co08, 1990Mo**, 1991Li11, 1993Di09, 1995El07, -210TL5C 1996Sc06, 1998Mo14, 2000Sa32, 2002Ba85, 2002De03, 2003Br13, 2002MoZP, -210TL6C 2003Au03, 2004Mo07, 2007BeZP -214BI P 0.0 1- 19.8 M 1 5621 3 -210TL N 4.762E3 4.762E3 0.00021 4.762E3 -210TL G 230 1 0.0029 10 0.0585 11 -210TL G 304.2 2 0.0255 23 0.30 19 -210TL G 334.78 8 0.033 5 -210TL G 630.79 7 0.0166 14 -210TL G 1226.7 3 0.018 8 -210TL L 0 + 1.30 M 3 -210TL A 0 -210TL A 5516 3 39.0 24370 -210TL L 62.5 10 + -210TL A 5452 3 55.2 33130 -210TL G 62.5 100.0116 7(M1) -210TL L 253.6 15 + -210TL A 5273 9 5.95 33130 -210TL G 191.1 180.00125 7 -210TL L 335 3 + -210TL A 5184 3 0.619 48450 -210TL L 499 4 + -210TL A 5023 3 0.214 14160 -210TL L 583 4 + -210TL A 4941 3 0.248 1445 - -214PO 214BI B- DECAY (19.8 M) -214PO H TYP=Full$AUT=V.Chisté$CUT=31-JAN-2007$ -214PO C Evaluation history: Type=Full;Author=V.Chisté;Cutoff date=31-JAN-2007 -214PO C References: 1934Le01, 1951Co15, 1954Br07, 1956Da06, 1960Wa14, 1965Le08, -214PO2C 1969Gu15, 1969Li10, 1969Wa27, 1969Gr33, 1974Ha68, 1975Ha31, 1977Zo01, -214PO3C 1978Ro21, 1979He13, 1979Be12, 1981Mo28, 1982Ak03, 1982Fa10, 1983Sc13, -214PO4C 1983Ol01, 1990Mo08, 1990Co08, 1990Mo**, 1991Li11, 1993Di09, 1995El07, -214PO5C 1996Sc06, 1998Mo14, 2000Sa32, 2002Ba85, 2002De03, 2003Br13, 2002MoZP, -214PO6C 2003Au03, 2004Mo07, 2007BeZP -214PO T Auger electrons and X ray energies and emission intensities: -214PO T {U Energy (keV)} {U Intensity} {U Line} -214PO T -214PO T 76.864 0.426 13 XKA2 -214PO T 79.293 0.710 22 XKA1 -214PO T -214PO T 89.256 |] XKB3 -214PO T 89.807 |] 0.244 9 XKB1 -214PO T 90.363 |] XKB5II -214PO T -214PO T 92.263 |] XKB2 -214PO T 92.618 |] 0.0760 29 XKB4 -214PO T 92.983 |] XKO23 -214PO T -214PO T 9.66-16.21 0.627 15 XL (total) -214PO T 9.66 0.0153 6 XLL -214PO T 11.016-11.13 0.281 9 XLA -214PO T 12.085 0.00502 18 XLC -214PO T 12.824-14.248 0.272 7 XLB -214PO T 15.251-16.21 0.0541 14 XLG -214PO T -214PO T 58.97-65.2 |] KLL AUGER -214PO T 71.93-76.6 |] 0.053 7 KLX AUGER -214PO T 84.72-93.04 |] KXY AUGER -214PO T 5.43-16.86 0.934 16 L AUGER -214BI P 0.0 1- 19.8 M 1 3270 11 -214PO N 1.00E0 1.00E0 0.99979 1.00E0 -214PO G 230 1 0.0029 10 0.0585 11 -214PO G 304.2 2 0.0255 23 0.30 19 -214PO G 334.78 8 0.033 5 -214PO G 630.79 7 0.0166 14 -214PO G 1226.7 3 0.018 8 -214PO L 0 0+ 162.3 US 12 -214PO B 3270 1119.67 20 7.9 1 -214POS B EAV=1270 5 -214PO L 609.316 7 2+ -214PO B 2661 110.62 20 9 1 -214POS B EAV=1008 5 -214PO G 609.312 7 45.49 19E2 0.0204 3 -214PO2 G KC=0.01487 21$LC=0.00416 6$MC=1030E-6 15 -214PO L 1015.05 4 (4)+ -214PO G 405.74 3 0.171 7[E2] 0.0541 8 -214PO2 G KC=0.0344 5$LC=0.01478 21$MC=0.00377 6 -214PO L 1274.761 22(3)- -214PO G 665.453 221.530 7E1 0.00579 9 -214PO2 G KC=0.00479 7$LC=7.67E-4 11$MC=1.79E-4 3 -214PO L 1377.675 122+ -214PO B 1892 117.45 5 7.4 1 -214POS B EAV=685 5 -214PO G 768.356 104.892 16M1+E2 2.8 7 0.0157 21 -214PO2 G KC=0.0122 18$LC=0.0026 3$MC=0.00063 6 -214PO G 1377.669 123.968 11E2 0.00404 6 -214PO2 G KC=0.00324 5$LC=5.85E-4 9$MC=1385E-7 20 -214PO L 1415.489 190+ 99 PS 3 -214PO B 1855 110.396 46 8.6 1 -214POS B EAV=669 5 -214PO G 806.174 181.262 6E2 0.0112716 -214PO2 G KC=0.00867 13$LC=0.00197 3$MC=4.80E-4 7 -214PO L 1543.375 142+ -214PO B 1727 113.12 4 7.6 1 -214POS B EAV=616 5 -214PO G 268.80 200.0161 18[E1] 0.0405 6 -214PO2 G KC=0.0329 5$LC=0.00577 9$MC=1359E-6 20 -214PO G 528 1 0.0109 13[E2] 0.0282 5 -214PO2 G KC=0.0198 3$LC=0.00633 10$MC=1584E-6 24 -214PO G 934.061 123.10 1M1+E2 -0.3 1 0.0234 10 -214PO2 G KC=0.0192 8$LC=0.00327 13$MC=0.00077 3 -214PO G 1543.32 6 0.302 13[E2] 0.00333 5 -214PO2 G KC=0.00265 4$LC=4.63E-4 7$MC=1093E-7 16 -214PO L 1661.28 3 2+ -214PO B 1609 110.65 6 8.2 1 -214POS B EAV=568 4 -214PO G 1051.960 300.324 8[M1E2] 0.012 6 -214PO2 G KC=0.010 5$LC=0.0018 8$MC=0.00042 17 -214PO G 1661.28 6 1.048 9E2 0.00296 5 -214PO2 G KC=0.00232 4$LC=3.99E-4 6$MC=9.40E-5 14 -214PO L 1712.93 20(3)+ -214PO B 1557 110.170 16 8.7 1U -214POS B EAV=547 4 -214PO G 697.90 250.067 4[M1E2] 0.034 19 -214PO2 G KC=0.027 16$LC=0.0051 23$MC=0.0012 6 -214PO G 1103.64 190.106 15[M1E2] 0.011 5 -214PO2 G KC=0.009 5$LC=0.0016 7$MC=0.00037 15 -214PO L 1729.611 132+ -214PO B 1540 1117.494 36 6.7 1 -214POS B EAV=540 4 -214PO G 454.770 120.288 5[E1] 0.0125118 -214PO2 G KC=0.01028 15$LC=1706E-6 24$MC=3.99E-4 6 -214PO G 1120.287 1014.91 3M1+E2 0.18 2 0.0152223 -214PO2 G KC=0.01246 19$LC=0.00210 3$MC=4.94E-4 8 -214PO G 1729.595 152.844 10E2 0.00278 4 -214PO2 G KC=0.00216 3$LC=3.68E-4 6$MC=8.66E-5 13 -214PO L 1742.98 3 0+ -214PO B 1527 110.116 16 8.8 1 -214POS B EAV=535 4 -214PO G 1133.660 300.254 8[E2] 0.00578 8 -214PO2 G KC=0.00462 7$LC=8.88E-4 13$MC=2.12E-4 3 -214PO L 1764.498 141+ -214PO B 1506 1117.10 8 6.6 -214POS B EAV=526 4 -214PO G 221 1 0.059 6[M1E2] 0.8 5 -214PO2 G KC=0.5 5$LC=0.158 10$MC=0.0394 9 -214PO G 348.92 6 0.123 32[M1] 0.335 5 -214PO2 G KC=0.272 4$LC=0.0475 7$MC=0.01118 16 -214PO G 386.77 5 0.296 5[M1E2] 0.16 10 -214PO2 G KC=0.12 9$LC=0.027 10$MC=0.0065 20 -214PO G 1155.190 201.635 7M1+E2 0.33 6 0.0135 4 -214PO2 G KC=0.0110 3$LC=0.00187 5$MC=4.38E-4 11 -214PO G 1764.494 1415.31 5M1 0.00511 8 -214PO2 G KC=0.00397 6$LC=6.61E-4 10$MC=1548E-7 22 -214PO L 1847.431 142+ -214PO B 1423 118.147 28 6.9 1 -214POS B EAV=493 4 -214PO G 469.76 7 0.133 15[M1E2] 0.09 6 -214PO2 G KC=0.07 5$LC=0.015 6$MC=0.0036 14 -214PO G 572.76 7 0.071 8[E1] 0.0077911 -214PO2 G KC=0.00643 9$LC=1042E-6 15$MC=2.43E-4 4 -214PO G 832.39 110.035 2[E2] 0.0105715 -214PO2 G KC=0.00816 12$LC=0.00182 4$MC=4.42E-4 7 -214PO G 1238.111 125.831 14M1+E2 -0.03 3 0.0120017 -214PO2 G KC=0.00983 14$LC=1651E-6 24$MC=3.87E-4 6 -214PO G 1847.420 252.025 12 -214PO L 1890.287 212+ -214PO B 1380 111.584 10 7.5 1 -214POS B EAV=476 4 -214PO G 615.73 100.055 7[E1] 0.0067410 -214PO2 G KC=0.00557 8$LC=8.98E-4 13$MC=2.09E-4 3 -214PO G 1280.96 2 1.435 6M1 0.0110116 -214PO2 G KC=0.00901 13$LC=1513E-6 22$MC=3.55E-4 5 -214PO G 1890.30 150.078 4 -214PO L 1994.63 3 (2)- -214PO B 1275 111.171 18 7.5 -214POS B EAV=434 4 -214PO G 333.350 420.063 4[E1] 0.0247 4 -214PO2 G KC=0.0202 3$LC=0.00345 5$MC=8.11E-4 12 -214PO G 617.0 2 0.027 5[E1] 0.0067210 -214PO2 G KC=0.00555 8$LC=8.94E-4 13$MC=2.09E-4 3 -214PO G 719.860 300.393 10E2 0.0142420 -214PO2 G KC=0.01075 15$LC=0.00264 4$MC=6.46E-4 9 -214PO G 1385.310 300.795 5[E1] 1631E-623 -214PO2 G KC=1281E-6 18$LC=1.96E-4 3$MC=4.53E-5 7 -214PO L 2010.81 4 2+ -214PO B 1259 111.430 9 7.4 1 -214POS B EAV=428 4 -214PO G 595.23 7 0.0174 15[M1E2] 0.05 3 -214PO2 G KC=0.04 3$LC=0.008 4$MC=0.0019 8 -214PO G 633.14 100.055 3[M1E2] 0.044 25 -214PO2 G KC=0.035 21$LC=0.007 3$MC=0.0016 7 -214PO G 1401.500 401.330 7(M1+E2) 1.6 5 0.0053 9 -214PO2 G KC=0.0043 7$LC=0.00074 11$MC=0.00017 3 -214PO G 2010.78 120.0434 17 -214PO L 2017.30 5 0+ -214PO B 1253 112.449 10 7.2 1 -214POS B EAV=425 4 -214PO G 252.80 6 0.0117 18[M1] 0.809 12 -214PO2 G KC=0.658 10$LC=0.1154 17$MC=0.0272 4 -214PO G 639.67 100.034 5[E2] 0.0183 3 -214PO2 G KC=0.01351 19$LC=0.00363 5$MC=8.95E-4 13 -214PO G 1407.98 4 2.389 8(E2) 0.00389 6 -214PO2 G KC=0.00312 5$LC=5.59E-4 8$MC=1323E-7 19 -214PO L 2088.41 12(1-),(1,2)+ -214PO B 1182 110.114 6 8.4 -214POS B EAV=398 4 -214PO G 710.67 100.076 4 -214PO G 1479.15 140.051 4 -214PO L 2118.552 171+ -214PO B 1151 114.339 18 6.8 -214POS B EAV=386 4 -214PO G 388.88 5 0.394 5(M1) 0.250 4 -214PO2 G KC=0.203 3$LC=0.0353 5$MC=0.00832 12 -214PO G 703.11 4 0.479 11[M1] 0.0519 8 -214PO2 G KC=0.0424 6$LC=0.00724 11$MC=1702E-6 24 -214PO G 740.73 180.0428 21[M1E2] 0.029 16 -214PO2 G KC=0.024 14$LC=0.0044 20$MC=0.0010 5 -214PO G 1509.228 152.128 10M1+E2 -0.053 35 0.0073211 -214PO2 G KC=0.00591 9$LC=9.88E-4 14$MC=2.32E-4 4 -214PO G 2118.550 301.158 5M1 0.00356 5 -214PO2 G KC=0.00248 4$LC=4.12E-4 6$MC=9.64E-5 14 -214PO L 2147.78 6 1(-),2+ -214PO B 1122 110.433 22 7.8 -214POS B EAV=375 4 -214PO G 873.07 190.019 3 -214PO G 1538.50 6 0.401 22 -214PO G 2147.9 2 0.0134 13 -214PO L 2192.56 4 2+ -214PO B 1077 110.851 10 7.4 1 -214POS B EAV=357 4 -214PO G 649.18 7 0.054 7[M1E2] 0.041 24 -214PO2 G KC=0.033 20$LC=0.006 3$MC=0.0015 7 -214PO G 815.00 100.039 3[M1E2] 0.023 13 -214PO2 G KC=0.019 11$LC=0.0034 15$MC=0.0008 4 -214PO G 917.8 3 0.005 3[E1] 0.00317 5 -214PO2 G KC=0.00263 4$LC=4.11E-4 6$MC=9.56E-5 14 -214PO G 1583.220 400.707 5M1+E2 -0.2 1 0.0064218 -214PO2 G KC=0.00513 14$LC=8.58E-4 23$MC=2.01E-4 6 -214PO G 2192.58 160.038 3 -214PO L 2204.13 9 1+ -214PO B 1066 115.642 43 6.6 -214POS B EAV=353 4 -214PO G 461.00 200.058 8[M1] 0.1581 23 -214PO2 G KC=0.1289 19$LC=0.0223 4$MC=0.00525 8 -214PO G 474.41 5 0.092 6[M1E2] 0.09 6 -214PO2 G KC=0.07 5$LC=0.015 6$MC=0.0035 14 -214PO G 543.0 2 0.088 21[M1E2] 0.06 4 -214PO2 G KC=0.05 4$LC=0.010 5$MC=0.0024 10 -214PO G 661.1 2 0.054 4[M1E2] 0.039 22 -214PO2 G KC=0.031 19$LC=0.006 3$MC=0.0014 6 -214PO G 788.6 5 0.015 5[M1] 0.0385 6 -214PO2 G KC=0.0315 5$LC=0.00536 8$MC=1258E-6 18 -214PO G 826.30 200.129 11M1 0.0341 5 -214PO2 G KC=0.0279 4$LC=0.00474 7$MC=1113E-6 16 -214PO G 1594.73 8 0.274 15[M1] 0.00644 9 -214PO2 G KC=0.00514 8$LC=8.59E-4 12$MC=2.01E-4 3 -214PO G 2204.21 4 4.913 23M1 0.00333 5 -214PO2 G KC=0.00224 4$LC=3.72E-4 6$MC=8.70E-5 13 -214PO L 2208.67 7 (2,3)+ -214PO G 547.6 3 0.034 3 -214PO G 1599.31 6 0.322 15 -214PO L 2266.39 181(-),2+ -214PO B 1004 110.187 12 8 -214POS B EAV=329 4 -214PO G 501.96 150.0181 22 -214PO G 536.77 4 0.061 8 -214PO G 722.98 120.037 7 -214PO G 991.49 190.011 3[M1E2] 0.014 7 -214PO2 G KC=0.012 6$LC=0.0021 9$MC=0.00049 21 -214PO G 1657.00 190.047 5 -214PO G 2266.51 130.0165 8 -214PO L 2293.34 5 1(+),2+ -214PO B 977 110.558 8 7.4 -214POS B EAV=319 4 -214PO G 878.03 120.0118 27[M1E2] 0.019 10 -214PO2 G KC=0.016 9$LC=0.0028 13$MC=0.0007 3 -214PO G 915.74 150.023 5[M1E2] 0.017 9 -214PO2 G KC=0.014 8$LC=0.0025 11$MC=0.0006 3 -214PO G 1683.99 4 0.217 3 -214PO G 2293.40 120.306 4 -214PO L 2348.3 9 (1-),(1,2)+ -214PO B 922 110.0014 9 9.9 -214POS B EAV=298 4 -214PO G 2348.0 130.0014 9 -214PO L 2360.8 4 (1-),(1,2)+ -214PO B 909 110.0030 8 9.6 -214POS B EAV=294 4 -214PO G 1751.4 8 0.0009 5 -214PO G 2361.00 190.0021 6 -214PO L 2423.19 15(1-),(1,2)+ -214PO B 847 110.0620 49 8.1 -214POS B EAV=271 4 -214PO G 658.7 2 0.017 4 -214PO G 693.3 5 0.0059 15 -214PO G 1045.6 2 0.023 3 -214PO G 1813.73 140.0108 9 -214PO G 2423.27 130.0048 6 -214PO L 2447.70 6 1- -214PO B 822 112.76 6 6.5 -214POS B EAV=262 4 -214PO G 452.92 100.031 4[M1E2] 0.10 7 -214PO2 G KC=0.08 6$LC=0.017 7$MC=0.0040 15 -214PO G 683.22 6 0.084 6[E1] 0.00551 8 -214PO2 G KC=0.00456 7$LC=7.28E-4 11$MC=1696E-7 2 -214PO G 704.9 3 0.051 10[E1] 0.00519 8 -214PO2 G KC=0.00429 6$LC=6.84E-4 10$MC=1593E-7 23 -214PO G 786.1 4 0.31 5[E1] 0.00422 6 -214PO2 G KC=0.00350 5$LC=5.53E-4 8$MC=1285E-7 18 -214PO G 904.29 100.066 8[E1] 0.00326 5 -214PO2 G KC=0.00271 4$LC=4.23E-4 6$MC=9.83E-5 14 -214PO G 1032.37 8 0.061 4[E1] 0.00257 4 -214PO2 G KC=0.00213 3$LC=3.31E-4 5$MC=7.68E-5 11 -214PO G 1069.96 8 0.271 10[E1] 0.00241 4 -214PO2 G KC=0.00200 3$LC=3.10E-4 5$MC=7.19E-5 10 -214PO G 1172.98 100.055 7[E2] 0.00542 8 -214PO2 G KC=0.00434 6$LC=8.24E-4 12$MC=1.96E-4 3 -214PO G 1838.36 5 0.343 10 -214PO G 2447.86 101.548 7E1 1424E-620 -214PO2 G KC=5.03E-4 7$LC=7.51E-5 11$MC=1735E-8 25 -214PO L 2482.46 4 (2)+ -214PO B 788 111.227 27 6.8 1 -214POS B EAV=249 3 -214PO G 273.80 5 0.120 8 -214PO G 394.05 8 0.0127 18 -214PO G 487.95 130.028 9[E1] 0.0108016 -214PO2 G KC=0.00889 13$LC=1463E-6 21$MC=3.42E-4 5 -214PO G 634.72 210.0064 23[M1E2] 0.043 25 -214PO2 G KC=0.035 21$LC=0.007 3$MC=0.0016 7 -214PO G 752.84 3 0.126 8[M1E2] 0.028 16 -214PO2 G KC=0.023 13$LC=0.0042 19$MC=0.0010 5 -214PO G 821.18 3 0.166 10M1 0.0346 5 -214PO2 G KC=0.0283 4$LC=0.00482 7$MC=1131E-6 16 -214PO G 939.6 5 0.016 4[M1E2] 0.016 8 -214PO2 G KC=0.013 7$LC=0.0024 11$MC=0.00056 24 -214PO G 1104.79 190.073 14[M1E2] 0.011 5 -214PO2 G KC=0.009 5$LC=0.0016 7$MC=0.00037 15 -214PO G 1207.68 3 0.454 12[E1] 0.00196 3 -214PO2 G KC=1622E-6 23$LC=2.49E-4 4$MC=5.77E-5 8 -214PO G 1873.16 6 0.212 8 -214PO G 2482.8 4 0.00096 18 -214PO L 2505.21 151(-),2+ -214PO B 765 110.169 10 7.6 -214POS B EAV=241 4 -214PO G 961.61 170.0101 14 -214PO G 1230.6 4 0.007 5 -214PO G 1895.92 140.146 8 -214PO G 2505.4 2 0.0056 6 -214PO L 2508.2 2 + -214PO B 762 110.092 9 7.9 -214POS B EAV=240 4 -214PO G 496.90 180.0068 18 -214PO G 1130.29 190.036 3 -214PO G 1898.7 4 0.049 8 -214PO L 2544.9 3 + -214PO B 725 110.044 7 8.1 -214POS B EAV=226 4 -214PO G 1167.3 2 0.0123 17 -214PO G 1935.5 2 0.032 7 -214PO L 2553.0 6 + -214PO L 2562.4 3 + -214PO B 708 110.00018 9 10.5 -214POS B EAV=220 4 -214PO G 2562.0 6 0.00018 9 -214PO L 2604.66 14(2)+ -214PO B 665 110.058 4 7.7 1 -214POS B EAV=205 4 -214PO G 396.01 8 0.0259 18 -214PO G 943.34 120.017 3 -214PO G 1330.0 2 0.0120 14 -214PO G 1994.6 6 0.0024 5 -214PO G 2604.5 5 0.00036 9 -214PO L 2630.85 17(1-),(1,2)+ -214PO B 639 110.0223 21 8.2 -214POS B EAV=196 4 -214PO G 2021.6 2 0.0214 21 -214PO G 2630.9 3 0.00086 23 -214PO L 2662.29 12(2)+ -214PO B 608 110.098 9 7.5 1 -214POS B EAV=185 4 -214PO G 949.8 5 0.0055 23 -214PO G 1118.9 5 0.010 4 -214PO G 1284 1 0.013 6 -214PO G 2052.94 120.069 4 -214PO G 2662.4 100.00020041 -214PO L 2694.6 2 1(-),2+ -214PO B 575 110.231 15 7 -214POS B EAV=174 4 -214PO G 485.92 110.021 4 -214PO G 677.41 150.0055 23 -214PO G 699.82 180.016 5 -214PO G 847.16 110.016 6 -214PO G 930.2 2 0.043 8 -214PO G 952.2 8 0.0059 23 -214PO G 1316.96 150.077 7 -214PO G 1419.7 3 0.0055 10 -214PO G 2085.1 2 0.0082 5 -214PO G 2694.7 2 0.033 3 -214PO L 2698.8 3 (1-,2+)+ -214PO B 571 110.026 4 8 -214POS B EAV=173 4 -214PO G 494.2 4 0.011 3 -214PO G 687.6 3 0.0066 14 -214PO G 1038.0 3 0.0086 15 -214PO L 2699.2 2 1(-),2+ -214PO B 571 110.0471 23 7.7 -214POS B EAV=172 4 -214PO G 2089.7 2 0.0443 22 -214PO G 2699.4 3 0.00282 23 -214PO L 2719.22 9 (1-),(1,2)+ -214PO B 551 110.247 8 6.9 -214POS B EAV=166 4 -214PO G 600.0 5 0.008 4 -214PO G 708.8 3 0.0119 20 -214PO G 976.18 120.0151 21 -214PO G 1303.76 8 0.105 5 -214PO G 1341.49 160.0214 27 -214PO G 2109.92 120.084 3 -214PO G 2719.3 2 0.00170 17 -214PO L 2728.59 4 (1,2)+ -214PO B 541 110.525 16 6.6 -214POS B EAV=162 4 -214PO G 280.95 5 0.062 6 -214PO G 519.90 5 0.0166 17 -214PO G 524.6 2 0.0169 17 -214PO G 733.80 150.038 3 -214PO G 964.08 3 0.363 12 -214PO G 1067.2 3 0.024 7 -214PO G 1351 1 0.0042 11 -214PO L 2769.9 2 (1-),(1,2)+ -214PO B 500 110.038 5 7.6 -214POS B EAV=149 4 -214PO G 1392.5 4 0.0087 19 -214PO G 2160.4 3 0.007 5 -214PO G 2769.9 2 0.0225 8 -214PO L 2785.9 2 (1-),(1,2)+ -214PO B 484 110.0248 31 7.8 -214POS B EAV=143 4 -214PO G 1021.0 5 0.016 3 -214PO G 2176.5 2 0.0033 6 -214PO G 2785.9 2 0.0055 5 -214PO L 2794.1 6 + -214PO L 2802.6 6 + -214PO L 2827.0 2 (1-),(1,2)+ -214PO B 443 110.00218 17 8.7 -214POS B EAV=130 4 -214PO G 2826.98 200.00218 17 -214PO L 2861.1 3 (1-),(1,2)+ -214PO B 409 110.0146 20 7.6 -214POS B EAV=119 4 -214PO G 1013.8 2 0.0087 19 -214PO G 2251.6 2 0.0055 5 -214PO G 2861.08 400.00041 13 -214PO L 2869.6 2 + -214PO B 400 110.0087 4 7.9 -214POS B EAV=116 3 -214PO G 2260.3 2 0.0087 4 -214PO L 2880.3 2 (1-),(1,2)+ -214PO B 390 110.0115 16 7.8 -214POS B EAV=113 3 -214PO G 2270.9 4 0.0014 3 -214PO G 2880.3 2 0.0101 16 -214PO L 2893.6 2 (1-),(1,2)+ -214PO B 376 110.022 3 7.5 -214POS B EAV=108 3 -214PO G 626.4 6 0.0041 14 -214PO G 1515.5 3 0.0072 21 -214PO G 2284.3 2 0.0050 4 -214PO G 2893.5 2 0.0057 5 -214PO L 2897.0 3 + -214PO B 373 110.0046 5 8.1 -214POS B EAV=107 3 -214PO G 2287.65 230.0046 5 -214PO L 2919.5 3 + -214PO B 350 110.0014 9 8.6 -214POS B EAV=100 3 -214PO G 2310.2 3 0.0014 9 -214PO L 2921.8 4 (1-),(1,2)+ -214PO B 348 110.0220 9 7.3 -214POS B EAV=99 3 -214PO G 2312.4 2 0.0086 8 -214PO G 2921.9 2 0.0134 5 -214PO L 2928.6 3 (1-),(1,2)+ -214PO B 341 110.0025 9 8.3 -214POS B EAV=97 3 -214PO G 2319.3 3 0.0014 9 -214PO G 2928.6 3 0.00109 9 -214PO L 2934.5 3 (1-),(1,2)+ -214PO B 336 110.00216 32 8.3 -214POS B EAV=95 3 -214PO G 2325.0 3 0.0017 3 -214PO G 2934.6 3 0.00046 12 -214PO L 2940.6 2 (1,2-),2+ -214PO B 329 110.041 7 7 -214POS B EAV=93 3 -214PO G 1665.8 2 0.015 6 -214PO G 2331.3 2 0.026 4 -214PO L 2962.8 7 + -214PO B 307 110.00036 14 9 -214POS B EAV=87 3 -214PO G 2353.5 7 0.00036 14 -214PO L 2967.6 6 + -214PO L 2978.8 2 (1-),(1,2)+ -214PO B 291 110.0165 6 7.2 -214POS B EAV=82 3 -214PO G 2369.0 4 0.0028 4 -214PO G 2978.9 2 0.0137 4 -214PO L 2986.2 2 (1,2 -),(2)+ -214PO B 284 110.032 5 6.9 -214POS B EAV=80 3 -214PO G 1711.0 8 0.023 5 -214PO G 2376.9 2 0.0086 8 -214PO L 3000.0 2 (1-),(2)+ -214PO B 270 110.0160 16 7.1 -214POS B EAV=75 3 -214PO G 551.9 8 0.0055 14 -214PO G 2390.8 2 0.00156 14 -214PO G 2999.98 200.0089 7 -214PO L 3003 1 + -214PO L 3005.8 6 + -214PO L 3014.1 3 (1-),(1,2)+ -214PO B 256 110.0252 24 6.9 -214POS B EAV=71 3 -214PO G 1353.4 8 0.0036 9 -214PO G 1470.9 3 0.0094 13 -214PO G 1636.3 2 0.0111 16 -214PO G 2405.1 5 0.0011 7 -214PO L 3022.3 3 + -214PO L 3030.3 6 + -214PO L 3039.3 6 + -214PO L 3053.9 2 (1-),(1,2)+ -214PO B 216 110.030 5 6.6 -214POS B EAV=59 3 -214PO G 2444.7 8 0.008 4 -214PO G 3053.88 200.022 3 -214PO L 3068.3 8 + -214PO B 202 110.00141 23 7.8 -214POS B EAV=55 3 -214PO G 2459.0 8 0.00141 23 -214PO L 3078.7 6 + -214PO L 3081.7 3 (1-),(1,2)+ -214PO B 188 110.0052 7 7.1 -214POS B EAV=51 3 -214PO G 3081.7 3 0.0052 7 -214PO L 3094.0 4 (1-),(2)+ -214PO B 176 110.00037 4 8.2 -214POS B EAV=48 3 -214PO G 3093.98 400.00037 4 -214PO L 3139.0 8 + -214PO L 3142.6 4 (1-),(1,2)+ -214PO B 127 110.00118 9 7.3 -214POS B EAV=34 3 -214PO G 3142.58 400.00118 9 -214PO L 3149.2 5 (1-),(1,2)+ -214PO B 121 110.00019 8 -214POS B EAV=32 3 -214PO G 3149.0 5 0.00019 -214PO L 3160.4 6 (1-),(1,2)+ -214PO B 110 110.00079 12 7.2 -214POS B EAV=29 3 -214PO G 2550.7 7 0.00032 9 -214PO G 3160.6 6 0.00047 8 -214PO L 3164.8 8 + -214PO L 3173.3 6 + -214PO B 97 110.00014 9 7.8 -214POS B EAV=26 3 -214PO G 2564.0 6 0.00014 9 -214PO L 3183.6 4 (1-),(1,2)+ -214PO B 86 110.0011 5 6.8 -214POS B EAV=23 3 -214PO G 3183.57 400.0011 5 -214PO L 3262.4 8 + - +210TL 214BI A DECAY (19.8 M) +210TL H TYP=FUL$AUT=V.CHISTE$CUT=31-JAN-2007$ +210TL C References:1934Le01, 1951Co15, 1954Br07, 1956Da06, 1960Wa14, 1965Le08, +210TL2C 1969Gu15, 1969Li10, 1969Wa27, 1969Gr33, 1974Ha68, 1975Ha31, 1977Zo01, +210TL3C 1978Ro21, 1979He13, 1979Be12, 1981Mo28, 1982Ak03, 1982Fa10, 1983Sc13, +210TL4C 1983Ol01, 1990Mo08, 1990Co08, 1990Mo**, 1991Li11, 1993Di09, 1995El07, +210TL5C 1996Sc06, 1998Mo14, 2000Sa32, 2002Ba85, 2002De03, 2003Br13, 2002MoZP, +210TL6C 2003Au03, 2004Mo07, 2007BeZP +214BI P 0.0 1- 19.8 M 1 5621 3 +210TL N 4.762E3 4.762E3 0.00021 +210TL L 0 1.30 M 3 +210TL A 1E-9 +210TL A 5516 3 39.0 24370 +210TL L 62.5 10 +210TL A 5452 3 55.2 33130 +210TL G 62.5 100.0116 7(M1) +210TL L 253.6 15 +210TL A 5273 9 5.95 33130 +210TL G 191.1 180.00125 7 +210TL L 335 3 +210TL A 5184 3 0.619 48450 +210TL L 499 4 +210TL A 5023 3 0.214 14160 +210TL L 583 4 +210TL A 4941 3 0.248 1445 + +214PO 214BI B- DECAY (19.8 M) +214PO H TYP=FUL$AUT=V.CHISTE$CUT=31-JAN-2007$ +214PO C References:1934Le01, 1951Co15, 1954Br07, 1956Da06, 1960Wa14, 1965Le08, +214PO2C 1969Gu15, 1969Li10, 1969Wa27, 1969Gr33, 1974Ha68, 1975Ha31, 1977Zo01, +214PO3C 1978Ro21, 1979He13, 1979Be12, 1981Mo28, 1982Ak03, 1982Fa10, 1983Sc13, +214PO4C 1983Ol01, 1990Mo08, 1990Co08, 1990Mo**, 1991Li11, 1993Di09, 1995El07, +214PO5C 1996Sc06, 1998Mo14, 2000Sa32, 2002Ba85, 2002De03, 2003Br13, 2002MoZP, +214PO6C 2003Au03, 2004Mo07, 2007BeZP +214PO T Auger electrons and X ray energies and emission intensities: +214PO T {U Energy (keV)} {U Intensity} {U Line} +214PO T +214PO T 76.864 0.426 13 XKA2 +214PO T 79.293 0.710 22 XKA1 +214PO T +214PO T 89.256 |] XKB3 +214PO T 89.807 |] 0.244 9 XKB1 +214PO T 90.363 |] XKB5II +214PO T +214PO T 92.263 |] XKB2 +214PO T 92.618 |] 0.0760 29 XKB4 +214PO T 92.983 |] XKO23 +214PO T +214PO T 9.66-16.21 0.627 15 XL (total) +214PO T 9.66 0.0153 6 XLL +214PO T 11.016-11.13 0.281 9 XLA +214PO T 12.085 0.00502 18 XLC +214PO T 12.824-14.248 0.272 7 XLB +214PO T 15.251-16.21 0.0541 14 XLG +214PO T +214PO T 58.97-65.2 |] KLL AUGER +214PO T 71.93-76.6 |] 0.053 7 KLX AUGER +214PO T 84.72-93.04 |] KXY AUGER +214PO T 5.43-16.86 0.934 16 L AUGER +214BI P 0.0 1- 19.8 M 1 3270 11 +214PO N 1.00E0 1.00E0 0.99979 1.00E0 +214PO G 230 1 0.0029 10 0.0585 11 +214PO G 304.2 2 0.0255 23 0.30 19 +214PO G 334.78 8 0.033 5 +214PO G 630.79 7 0.0166 14 +214PO G 1226.7 3 0.018 8 +214PO L 0 0+ 162.3 US 12 +214PO B 3270 1119.67 20 7.9 1 +214POS B EAV=1270 5 +214PO L 609.316 7 2+ +214PO B 2661 110.62 20 9 1 +214POS B EAV=1008 5 +214PO G 609.312 7 45.49 19E2 0.0204 3 +214PO2 G KC=0.01487 21$LC=0.00416 6$MC=0.001030 15$NC=0.000264 4 +214PO3 G OC=5.33E-5 8 +214PO L 1015.05 4 (4)+ +214PO G 405.74 3 0.171 7[E2] 0.0541 8 +214PO2 G KC=0.0344 5$LC=0.01478 21$MC=0.00377 6$NC=0.000968 14 +214PO3 G OC=0.000191 3 +214PO L 1274.761 22(3)- +214PO G 665.453 221.530 7E1 0.00579 9 +214PO2 G KC=0.00479 7$LC=0.000767 11$MC=0.000179 3$NC=4.58E-5 7 +214PO3 G OC=9.48E-6 14 +214PO L 1377.675 122+ +214PO B 1892 117.45 5 7.4 1 +214POS B EAV=685 5 +214PO G 768.356 104.892 16M1+E2 2.8 7 0.0157 21 +214PO2 G KC=0.0122 18$LC=0.0026 3$MC=0.00063 6$NC=0.000163 15 +214PO3 G OC=0.000033 4 +214PO G 1377.669 123.968 11E2 0.00404 6 +214PO2 G KC=0.00324 5$LC=0.000585 9$MC=1.385E-4 20$NC=3.56E-5 5 +214PO3 G OC=7.37E-6 11 +214PO L 1415.489 190+ 99 PS 3 +214PO B 1855 110.396 46 8.6 1 +214POS B EAV=669 5 +214PO G 806.174 181.262 6E2 0.0112716 +214PO2 G KC=0.00867 13$LC=0.00197 3$MC=0.000480 7$NC=1.232E-4 18 +214PO3 G OC=2.51E-5 4 +214PO L 1543.375 142+ +214PO B 1727 113.12 4 7.6 1 +214POS B EAV=616 5 +214PO G 268.80 200.0161 18[E1] 0.0405 6 +214PO2 G KC=0.0329 5$LC=0.00577 9$MC=0.001359 20$NC=0.000347 5 +214PO3 G OC=7.07E-5 10 +214PO G 528 1 0.0109 13[E2] 0.0282 5 +214PO2 G KC=0.0198 3$LC=0.00633 10$MC=0.001584 24$NC=0.000407 7 +214PO3 G OC=8.14E-5 13 +214PO G 934.061 123.10 1M1+E2 -0.3 1 0.0234 10 +214PO2 G KC=0.0192 8$LC=0.00327 13$MC=0.00077 3$NC=0.000198 8 +214PO3 G OC=4.14E-5 16 +214PO G 1543.32 6 0.302 13[E2] 0.00333 5 +214PO2 G KC=0.00265 4$LC=0.000463 7$MC=1.093E-4 16$NC=2.81E-5 4 +214PO3 G OC=5.83E-6 9 +214PO L 1661.28 3 2+ +214PO B 1609 110.65 6 8.2 1 +214POS B EAV=568 4 +214PO G 1051.960 300.324 8[M1,E2] 0.012 6 +214PO2 G KC=0.010 5$LC=0.0018 8$MC=0.00042 17$NC=0.00011 5 +214PO3 G OC=0.000023 10 +214PO G 1661.28 6 1.048 9E2 0.00296 5 +214PO2 G KC=0.00232 4$LC=0.000399 6$MC=9.40E-5 14$NC=2.41E-5 4 +214PO3 G OC=5.02E-6 7 +214PO L 1712.93 20(3)+ +214PO B 1557 110.170 16 8.7 1U +214POS B EAV=547 4 +214PO G 697.90 250.067 4[M1,E2] 0.034 19 +214PO2 G KC=0.027 16$LC=0.0051 23$MC=0.0012 6$NC=0.00031 14 +214PO3 G OC=0.00007 3 +214PO G 1103.64 190.106 15[M1,E2] 0.011 5 +214PO2 G KC=0.009 5$LC=0.0016 7$MC=0.00037 15$NC=0.00010 4 +214PO3 G OC=0.000020 9 +214PO L 1729.611 132+ +214PO B 1540 1117.494 36 6.7 1 +214POS B EAV=540 4 +214PO G 454.770 120.288 5[E1] 0.0125118 +214PO2 G KC=0.01028 15$LC=0.001706 24$MC=0.000399 6$NC=1.021E-4 15 +214PO3 G OC=2.10E-5 3 +214PO G 1120.287 1014.91 3M1+E2 0.18 2 0.0152223 +214PO2 G KC=0.01246 19$LC=0.00210 3$MC=0.000494 8$NC=1.270E-4 19 +214PO3 G OC=2.66E-5 4 +214PO G 1729.595 152.844 10E2 0.00278 4 +214PO2 G KC=0.00216 3$LC=0.000368 6$MC=8.66E-5 13$NC=2.22E-5 4 +214PO3 G OC=4.63E-6 7 +214PO L 1742.98 3 0+ +214PO B 1527 110.116 16 8.8 1 +214POS B EAV=535 4 +214PO G 1133.660 300.254 8[E2] 0.00578 8 +214PO2 G KC=0.00462 7$LC=0.000888 13$MC=0.000212 3$NC=5.44E-5 8 +214PO3 G OC=1.123E-5 16 +214PO L 1764.498 141+ +214PO B 1506 1117.10 8 6.6 +214POS B EAV=526 4 +214PO G 221 1 0.059 6[M1,E2] 0.8 5 +214PO2 G KC=0.5 5$LC=0.158 10$MC=0.0394 9$NC=0.01013 23 +214PO3 G OC=0.00204 11 +214PO G 348.92 6 0.123 32[M1] 0.335 5 +214PO2 G KC=0.272 4$LC=0.0475 7$MC=0.01118 16$NC=0.00288 4 +214PO3 G OC=0.000602 9 +214PO G 386.77 5 0.296 5[M1,E2] 0.16 10 +214PO2 G KC=0.12 9$LC=0.027 10$MC=0.0065 20$NC=0.0017 6 +214PO3 G OC=0.00034 12 +214PO G 1155.190 201.635 7M1+E2 0.33 6 0.0135 4 +214PO2 G KC=0.0110 3$LC=0.00187 5$MC=0.000438 11$NC=0.000113 3 +214PO3 G OC=2.36E-5 6 +214PO G 1764.494 1415.31 5M1 0.00511 8 +214PO2 G KC=0.00397 6$LC=0.000661 10$MC=1.548E-4 22$NC=3.98E-5 6 +214PO3 G OC=8.35E-6 12 +214PO L 1847.431 142+ +214PO B 1423 118.147 28 6.9 1 +214POS B EAV=493 4 +214PO G 469.76 7 0.133 15[M1,E2] 0.09 6 +214PO2 G KC=0.07 5$LC=0.015 6$MC=0.0036 14$NC=0.0009 4 +214PO3 G OC=0.00019 8 +214PO G 572.76 7 0.071 8[E1] 0.0077911 +214PO2 G KC=0.00643 9$LC=0.001042 15$MC=0.000243 4$NC=6.22E-5 9 +214PO3 G OC=1.287E-5 18 +214PO G 832.39 110.035 2[E2] 0.0105715 +214PO2 G KC=0.00816 12$LC=0.00182 4$MC=0.000442 7$NC=1.135E-4 16 +214PO3 G OC=2.32E-5 4 +214PO G 1238.111 125.831 14M1+E2 -0.03 3 0.0120017 +214PO2 G KC=0.00983 14$LC=0.001651 24$MC=0.000387 6$NC=9.96E-5 14 +214PO3 G OC=2.09E-5 3 +214PO G 1847.420 252.025 12 +214PO L 1890.287 212+ +214PO B 1380 111.584 10 7.5 1 +214POS B EAV=476 4 +214PO G 615.73 100.055 7[E1] 0.0067410 +214PO2 G KC=0.00557 8$LC=0.000898 13$MC=0.000209 3$NC=5.36E-5 8 +214PO3 G OC=1.109E-5 16 +214PO G 1280.96 2 1.435 6M1 0.0110116 +214PO2 G KC=0.00901 13$LC=0.001513 22$MC=0.000355 5$NC=9.12E-5 13 +214PO3 G OC=1.91E-5 3 +214PO G 1890.30 150.078 4 +214PO L 1994.63 3 (2)- +214PO B 1275 111.171 18 7.5 +214POS B EAV=434 4 +214PO G 333.350 420.063 4[E1] 0.0247 4 +214PO2 G KC=0.0202 3$LC=0.00345 5$MC=0.000811 12$NC=0.000207 3 +214PO3 G OC=4.24E-5 6 +214PO G 617.0 2 0.027 5[E1] 0.0067210 +214PO2 G KC=0.00555 8$LC=0.000894 13$MC=0.000209 3$NC=5.34E-5 8 +214PO3 G OC=1.105E-5 16 +214PO G 719.860 300.393 10E2 0.0142420 +214PO2 G KC=0.01075 15$LC=0.00264 4$MC=0.000646 9$NC=1.659E-4 24 +214PO3 G OC=3.37E-5 5 +214PO G 1385.310 300.795 5[E1] 1631E-623 +214PO2 G KC=0.001281 18$LC=0.000196 3$MC=4.53E-5 7$NC=1.160E-5 17 +214PO3 G OC=2.42E-6 4 +214PO L 2010.81 4 2+ +214PO B 1259 111.430 9 7.4 1 +214POS B EAV=428 4 +214PO G 595.23 7 0.0174 15[M1,E2] 0.05 3 +214PO2 G KC=0.04 3$LC=0.008 4$MC=0.0019 8$NC=0.00048 20 +214PO3 G OC=0.00010 5 +214PO G 633.14 100.055 3[M1,E2] 0.044 25 +214PO2 G KC=0.035 21$LC=0.007 3$MC=0.0016 7$NC=0.00041 17 +214PO3 G OC=0.00008 4 +214PO G 1401.500 401.330 7(M1+E2) 1.6 5 0.0053 9 +214PO2 G KC=0.0043 7$LC=0.00074 11$MC=0.00017 3$NC=0.000045 7 +214PO3 G OC=9.4E-6 14 +214PO G 2010.78 120.0434 17 +214PO L 2017.30 5 0+ +214PO B 1253 112.449 10 7.2 1 +214POS B EAV=425 4 +214PO G 252.80 6 0.0117 18[M1] 0.809 12 +214PO2 G KC=0.658 10$LC=0.1154 17$MC=0.0272 4$NC=0.0070 1 +214PO3 G OC=0.001466 21 +214PO G 639.67 100.034 5[E2] 0.0183 3 +214PO2 G KC=0.01351 19$LC=0.00363 5$MC=0.000895 13$NC=0.000230 4 +214PO3 G OC=4.64E-5 7 +214PO G 1407.98 4 2.389 8(E2) 0.00389 6 +214PO2 G KC=0.00312 5$LC=0.000559 8$MC=1.323E-4 19$NC=3.40E-5 5 +214PO3 G OC=7.04E-6 10 +214PO L 2088.41 12(1-),(1,2)+ +214PO B 1182 110.114 6 8.4 +214POS B EAV=398 4 +214PO G 710.67 100.076 4 +214PO G 1479.15 140.051 4 +214PO L 2118.552 171+ +214PO B 1151 114.339 18 6.8 +214POS B EAV=386 4 +214PO G 388.88 5 0.394 5(M1) 0.250 4 +214PO2 G KC=0.203 3$LC=0.0353 5$MC=0.00832 12$NC=0.00214 3 +214PO3 G OC=0.000448 7 +214PO G 703.11 4 0.479 11[M1] 0.0519 8 +214PO2 G KC=0.0424 6$LC=0.00724 11$MC=0.001702 24$NC=0.000438 7 +214PO3 G OC=9.17E-5 13 +214PO G 740.73 180.0428 21[M1,E2] 0.029 16 +214PO2 G KC=0.024 14$LC=0.0044 20$MC=0.0010 5$NC=0.00027 12 +214PO3 G OC=0.000056 25 +214PO G 1509.228 152.128 10M1+E2 -0.053 35 0.0073211 +214PO2 G KC=0.00591 9$LC=0.000988 14$MC=0.000232 4$NC=5.96E-5 9 +214PO3 G OC=1.249E-5 18 +214PO G 2118.550 301.158 5M1 0.00356 5 +214PO2 G KC=0.00248 4$LC=0.000412 6$MC=9.64E-5 14$NC=2.48E-5 4 +214PO3 G OC=5.20E-6 8 +214PO L 2147.78 6 1(-),2+ +214PO B 1122 110.433 22 7.8 +214POS B EAV=375 4 +214PO G 873.07 190.019 3 +214PO G 1538.50 6 0.401 22 +214PO G 2147.9 2 0.0134 13 +214PO L 2192.56 4 2+ +214PO B 1077 110.851 10 7.4 1 +214POS B EAV=357 4 +214PO G 649.18 7 0.054 7[M1,E2] 0.041 24 +214PO2 G KC=0.033 20$LC=0.006 3$MC=0.0015 7$NC=0.00038 16 +214PO3 G OC=0.00008 4 +214PO G 815.00 100.039 3[M1,E2] 0.023 13 +214PO2 G KC=0.019 11$LC=0.0034 15$MC=0.0008 4$NC=0.00021 9 +214PO3 G OC=0.000043 19 +214PO G 917.8 3 0.005 3[E1] 0.00317 5 +214PO2 G KC=0.00263 4$LC=0.000411 6$MC=9.56E-5 14$NC=2.45E-5 4 +214PO3 G OC=5.09E-6 8 +214PO G 1583.220 400.707 5M1+E2 -0.2 1 0.0064218 +214PO2 G KC=0.00513 14$LC=0.000858 23$MC=0.000201 6$NC=5.17E-5 14 +214PO3 G OC=1.08E-5 3 +214PO G 2192.58 160.038 3 +214PO L 2204.13 9 1+ +214PO B 1066 115.642 43 6.6 +214POS B EAV=353 4 +214PO G 461.00 200.058 8[M1] 0.1581 23 +214PO2 G KC=0.1289 19$LC=0.0223 4$MC=0.00525 8$NC=0.001351 19 +214PO3 G OC=0.000283 4 +214PO G 474.41 5 0.092 6[M1,E2] 0.09 6 +214PO2 G KC=0.07 5$LC=0.015 6$MC=0.0035 14$NC=0.0009 4 +214PO3 G OC=0.00019 8 +214PO G 543.0 2 0.088 21[M1,E2] 0.06 4 +214PO2 G KC=0.05 4$LC=0.010 5$MC=0.0024 10$NC=0.00062 25 +214PO3 G OC=0.00013 6 +214PO G 661.1 2 0.054 4[M1,E2] 0.039 22 +214PO2 G KC=0.031 19$LC=0.006 3$MC=0.0014 6$NC=0.00036 16 +214PO3 G OC=0.00008 4 +214PO G 788.6 5 0.015 5[M1] 0.0385 6 +214PO2 G KC=0.0315 5$LC=0.00536 8$MC=0.001258 18$NC=0.000324 5 +214PO3 G OC=6.78E-5 10 +214PO G 826.30 200.129 11M1 0.0341 5 +214PO2 G KC=0.0279 4$LC=0.00474 7$MC=0.001113 16$NC=0.000286 4 +214PO3 G OC=6.00E-5 9 +214PO G 1594.73 8 0.274 15[M1] 0.00644 9 +214PO2 G KC=0.00514 8$LC=0.000859 12$MC=0.000201 3$NC=5.18E-5 8 +214PO3 G OC=1.085E-5 16 +214PO G 2204.21 4 4.913 23M1 0.00333 5 +214PO2 G KC=0.00224 4$LC=0.000372 6$MC=8.70E-5 13$NC=2.24E-5 4 +214PO3 G OC=4.69E-6 7 +214PO L 2208.67 7 (2,3)+ +214PO G 547.6 3 0.034 3 +214PO G 1599.31 6 0.322 15 +214PO L 2266.39 181(-),2+ +214PO B 1004 110.187 12 8 +214POS B EAV=329 4 +214PO G 501.96 150.0181 22 +214PO G 536.77 4 0.061 8 +214PO G 722.98 120.037 7 +214PO G 991.49 190.011 3[M1,E2] 0.014 7 +214PO2 G KC=0.012 6$LC=0.0021 9$MC=0.00049 21$NC=0.00013 6 +214PO3 G OC=0.000026 11 +214PO G 1657.00 190.047 5 +214PO G 2266.51 130.0165 8 +214PO L 2293.34 5 1(+),2+ +214PO B 977 110.558 8 7.4 +214POS B EAV=319 4 +214PO G 878.03 120.0118 27[M1,E2] 0.019 10 +214PO2 G KC=0.016 9$LC=0.0028 13$MC=0.0007 3$NC=0.00017 8 +214PO3 G OC=0.000036 16 +214PO G 915.74 150.023 5[M1,E2] 0.017 9 +214PO2 G KC=0.014 8$LC=0.0025 11$MC=0.0006 3$NC=0.00015 7 +214PO3 G OC=0.000032 14 +214PO G 1683.99 4 0.217 3 +214PO G 2293.40 120.306 4 +214PO L 2348.3 9 (1-),(1,2)+ +214PO B 922 110.0014 9 9.9 +214POS B EAV=298 4 +214PO G 2348.0 130.0014 9 +214PO L 2360.8 4 (1-),(1,2)+ +214PO B 909 110.0030 8 9.6 +214POS B EAV=294 4 +214PO G 1751.4 8 0.0009 5 +214PO G 2361.00 190.0021 6 +214PO L 2423.19 15(1-),(1,2)+ +214PO B 847 110.0620 49 8.1 +214POS B EAV=271 4 +214PO G 658.7 2 0.017 4 +214PO G 693.3 5 0.0059 15 +214PO G 1045.6 2 0.023 3 +214PO G 1813.73 140.0108 9 +214PO G 2423.27 130.0048 6 +214PO L 2447.70 6 1- +214PO B 822 112.76 6 6.5 +214POS B EAV=262 4 +214PO G 452.92 100.031 4[M1,E2] 0.10 7 +214PO2 G KC=0.08 6$LC=0.017 7$MC=0.0040 15$NC=0.0010 4 +214PO3 G OC=0.00021 9 +214PO G 683.22 6 0.084 6[E1] 0.00551 8 +214PO2 G KC=0.00456 7$LC=0.000728 11$MC=16960E-8 24$NC=4.34E-5 6 +214PO3 G OC=9.00E-6 13 +214PO G 704.9 3 0.051 10[E1] 0.00519 8 +214PO2 G KC=0.00429 6$LC=0.000684 10$MC=1.593E-4 23$NC=4.08E-5 6 +214PO3 G OC=8.45E-6 12 +214PO G 786.1 4 0.31 5[E1] 0.00422 6 +214PO2 G KC=0.00350 5$LC=0.000553 8$MC=1.285E-4 18$NC=3.29E-5 5 +214PO3 G OC=6.83E-6 10 +214PO G 904.29 100.066 8[E1] 0.00326 5 +214PO2 G KC=0.00271 4$LC=0.000423 6$MC=9.83E-5 14$NC=2.52E-5 4 +214PO3 G OC=5.23E-6 8 +214PO G 1032.37 8 0.061 4[E1] 0.00257 4 +214PO2 G KC=0.00213 3$LC=0.000331 5$MC=7.68E-5 11$NC=1.97E-5 3 +214PO3 G OC=4.09E-6 6 +214PO G 1069.96 8 0.271 10[E1] 0.00241 4 +214PO2 G KC=0.00200 3$LC=0.000310 5$MC=7.19E-5 10$NC=1.84E-5 3 +214PO3 G OC=3.84E-6 6 +214PO G 1172.98 100.055 7[E2] 0.00542 8 +214PO2 G KC=0.00434 6$LC=0.000824 12$MC=0.000196 3$NC=5.05E-5 7 +214PO3 G OC=1.041E-5 15 +214PO G 1838.36 5 0.343 10 +214PO G 2447.86 101.548 7E1 1424E-620 +214PO2 G KC=0.000503 7$LC=7.51E-5 11$MC=1.735E-5 25$NC=4.45E-6 7 +214PO3 G OC=9.31E-7 13 +214PO L 2482.46 4 (2)+ +214PO B 788 111.227 27 6.8 1 +214POS B EAV=249 3 +214PO G 273.80 5 0.120 8 +214PO G 394.05 8 0.0127 18 +214PO G 487.95 130.028 9[E1] 0.0108016 +214PO2 G KC=0.00889 13$LC=0.001463 21$MC=0.000342 5$NC=8.75E-5 13 +214PO3 G OC=1.81E-5 3 +214PO G 634.72 210.0064 23[M1,E2] 0.043 25 +214PO2 G KC=0.035 21$LC=0.007 3$MC=0.0016 7$NC=0.00040 17 +214PO3 G OC=0.00008 4 +214PO G 752.84 3 0.126 8[M1,E2] 0.028 16 +214PO2 G KC=0.023 13$LC=0.0042 19$MC=0.0010 5$NC=0.00026 11 +214PO3 G OC=0.000053 24 +214PO G 821.18 3 0.166 10M1 0.0346 5 +214PO2 G KC=0.0283 4$LC=0.00482 7$MC=0.001131 16$NC=0.000291 4 +214PO3 G OC=6.09E-5 9 +214PO G 939.6 5 0.016 4[M1,E2] 0.016 8 +214PO2 G KC=0.013 7$LC=0.0024 11$MC=0.00056 24$NC=0.00014 6 +214PO3 G OC=0.000030 13 +214PO G 1104.79 190.073 14[M1,E2] 0.011 5 +214PO2 G KC=0.009 5$LC=0.0016 7$MC=0.00037 15$NC=0.00010 4 +214PO3 G OC=0.000020 8 +214PO G 1207.68 3 0.454 12[E1] 0.00196 3 +214PO2 G KC=0.001622 23$LC=0.000249 4$MC=5.77E-5 8$NC=1.479E-5 21 +214PO3 G OC=3.09E-6 5 +214PO G 1873.16 6 0.212 8 +214PO G 2482.8 4 0.00096 18 +214PO L 2505.21 151(-),2+ +214PO B 765 110.169 10 7.6 +214POS B EAV=241 4 +214PO G 961.61 170.0101 14 +214PO G 1230.6 4 0.007 5 +214PO G 1895.92 140.146 8 +214PO G 2505.4 2 0.0056 6 +214PO L 2508.2 2 +214PO B 762 110.092 9 7.9 +214POS B EAV=240 4 +214PO G 496.90 180.0068 18 +214PO G 1130.29 190.036 3 +214PO G 1898.7 4 0.049 8 +214PO L 2544.9 3 +214PO B 725 110.044 7 8.1 +214POS B EAV=226 4 +214PO G 1167.3 2 0.0123 17 +214PO G 1935.5 2 0.032 7 +214PO L 2553.0 6 +214PO L 2562.4 3 +214PO B 708 110.00018 9 10.5 +214POS B EAV=220 4 +214PO G 2562.0 6 0.00018 9 +214PO L 2604.66 14(2)+ +214PO B 665 110.058 4 7.7 1 +214POS B EAV=205 4 +214PO G 396.01 8 0.0259 18 +214PO G 943.34 120.017 3 +214PO G 1330.0 2 0.0120 14 +214PO G 1994.6 6 0.0024 5 +214PO G 2604.5 5 0.00036 9 +214PO L 2630.85 17(1-),(1,2)+ +214PO B 639 110.0223 21 8.2 +214POS B EAV=196 4 +214PO G 2021.6 2 0.0214 21 +214PO G 2630.9 3 0.00086 23 +214PO L 2662.29 12(2)+ +214PO B 608 110.098 9 7.5 1 +214POS B EAV=185 4 +214PO G 949.8 5 0.0055 23 +214PO G 1118.9 5 0.010 4 +214PO G 1284 1 0.013 6 +214PO G 2052.94 120.069 4 +214PO G 2662.4 100.00020041 +214PO L 2694.6 2 1(-),2+ +214PO B 575 110.231 15 7 +214POS B EAV=174 4 +214PO G 485.92 110.021 4 +214PO G 677.41 150.0055 23 +214PO G 699.82 180.016 5 +214PO G 847.16 110.016 6 +214PO G 930.2 2 0.043 8 +214PO G 952.2 8 0.0059 23 +214PO G 1316.96 150.077 7 +214PO G 1419.7 3 0.0055 10 +214PO G 2085.1 2 0.0082 5 +214PO G 2694.7 2 0.033 3 +214PO L 2698.8 3 (1-,2+) +214PO B 571 110.026 4 8 +214POS B EAV=173 4 +214PO G 494.2 4 0.011 3 +214PO G 687.6 3 0.0066 14 +214PO G 1038.0 3 0.0086 15 +214PO L 2699.2 2 1(-),2+ +214PO B 571 110.0471 23 7.7 +214POS B EAV=172 4 +214PO G 2089.7 2 0.0443 22 +214PO G 2699.4 3 0.00282 23 +214PO L 2719.22 9 (1-),(1,2)+ +214PO B 551 110.247 8 6.9 +214POS B EAV=166 4 +214PO G 600.0 5 0.008 4 +214PO G 708.8 3 0.0119 20 +214PO G 976.18 120.0151 21 +214PO G 1303.76 8 0.105 5 +214PO G 1341.49 160.0214 27 +214PO G 2109.92 120.084 3 +214PO G 2719.3 2 0.00170 17 +214PO L 2728.59 4 (1,2)+ +214PO B 541 110.525 16 6.6 +214POS B EAV=162 4 +214PO G 280.95 5 0.062 6 +214PO G 519.90 5 0.0166 17 +214PO G 524.6 2 0.0169 17 +214PO G 733.80 150.038 3 +214PO G 964.08 3 0.363 12 +214PO G 1067.2 3 0.024 7 +214PO G 1351 1 0.0042 11 +214PO L 2769.9 2 (1-),(1,2)+ +214PO B 500 110.038 5 7.6 +214POS B EAV=149 4 +214PO G 1392.5 4 0.0087 19 +214PO G 2160.4 3 0.007 5 +214PO G 2769.9 2 0.0225 8 +214PO L 2785.9 2 (1-),(1,2)+ +214PO B 484 110.0248 31 7.8 +214POS B EAV=143 4 +214PO G 1021.0 5 0.016 3 +214PO G 2176.5 2 0.0033 6 +214PO G 2785.9 2 0.0055 5 +214PO L 2794.1 6 +214PO L 2802.6 6 +214PO L 2827.0 2 (1-),(1,2)+ +214PO B 443 110.00218 17 8.7 +214POS B EAV=130 4 +214PO G 2826.98 200.00218 17 +214PO L 2861.1 3 (1-),(1,2)+ +214PO B 409 110.0146 20 7.6 +214POS B EAV=119 4 +214PO G 1013.8 2 0.0087 19 +214PO G 2251.6 2 0.0055 5 +214PO G 2861.08 400.00041 13 +214PO L 2869.6 2 +214PO B 400 110.0087 4 7.9 +214POS B EAV=116 3 +214PO G 2260.3 2 0.0087 4 +214PO L 2880.3 2 (1-),(1,2)+ +214PO B 390 110.0115 16 7.8 +214POS B EAV=113 3 +214PO G 2270.9 4 0.0014 3 +214PO G 2880.3 2 0.0101 16 +214PO L 2893.6 2 (1-),(1,2)+ +214PO B 376 110.022 3 7.5 +214POS B EAV=108 3 +214PO G 626.4 6 0.0041 14 +214PO G 1515.5 3 0.0072 21 +214PO G 2284.3 2 0.0050 4 +214PO G 2893.5 2 0.0057 5 +214PO L 2897.0 3 +214PO B 373 110.0046 5 8.1 +214POS B EAV=107 3 +214PO G 2287.65 230.0046 5 +214PO L 2919.5 3 +214PO B 350 110.0014 9 8.6 +214POS B EAV=100 3 +214PO G 2310.2 3 0.0014 9 +214PO L 2921.8 4 (1-),(1,2)+ +214PO B 348 110.0220 9 7.3 +214POS B EAV=99 3 +214PO G 2312.4 2 0.0086 8 +214PO G 2921.9 2 0.0134 5 +214PO L 2928.6 3 (1-),(1,2)+ +214PO B 341 110.0025 9 8.3 +214POS B EAV=97 3 +214PO G 2319.3 3 0.0014 9 +214PO G 2928.6 3 0.00109 9 +214PO L 2934.5 3 (1-),(1,2)+ +214PO B 336 110.00216 32 8.3 +214POS B EAV=95 3 +214PO G 2325.0 3 0.0017 3 +214PO G 2934.6 3 0.00046 12 +214PO L 2940.6 2 (1,2-),2+ +214PO B 329 110.041 7 7 +214POS B EAV=93 3 +214PO G 1665.8 2 0.015 6 +214PO G 2331.3 2 0.026 4 +214PO L 2962.8 7 +214PO B 307 110.00036 14 9 +214POS B EAV=87 3 +214PO G 2353.5 7 0.00036 14 +214PO L 2967.6 6 +214PO L 2978.8 2 (1-),(1,2)+ +214PO B 291 110.0165 6 7.2 +214POS B EAV=82 3 +214PO G 2369.0 4 0.0028 4 +214PO G 2978.9 2 0.0137 4 +214PO L 2986.2 2 (1,2-),(2)+ +214PO B 284 110.032 5 6.9 +214POS B EAV=80 3 +214PO G 1711.0 8 0.023 5 +214PO G 2376.9 2 0.0086 8 +214PO L 3000.0 2 (1-),(2)+ +214PO B 270 110.0160 16 7.1 +214POS B EAV=75 3 +214PO G 551.9 8 0.0055 14 +214PO G 2390.8 2 0.00156 14 +214PO G 2999.98 200.0089 7 +214PO L 3003 1 +214PO L 3005.8 6 +214PO L 3014.1 3 (1-),(1,2)+ +214PO B 256 110.0252 24 6.9 +214POS B EAV=71 3 +214PO G 1353.4 8 0.0036 9 +214PO G 1470.9 3 0.0094 13 +214PO G 1636.3 2 0.0111 16 +214PO G 2405.1 5 0.0011 7 +214PO L 3022.3 3 +214PO L 3030.3 6 +214PO L 3039.3 6 +214PO L 3053.9 2 (1-),(1,2)+ +214PO B 216 110.030 5 6.6 +214POS B EAV=59 3 +214PO G 2444.7 8 0.008 4 +214PO G 3053.88 200.022 3 +214PO L 3068.3 8 +214PO B 202 110.00141 23 7.8 +214POS B EAV=55 3 +214PO G 2459.0 8 0.00141 23 +214PO L 3078.7 6 +214PO L 3081.7 3 (1-),(1,2)+ +214PO B 188 110.0052 7 7.1 +214POS B EAV=51 3 +214PO G 3081.7 3 0.0052 7 +214PO L 3094.0 4 (1-),(2)+ +214PO B 176 110.00037 4 8.2 +214POS B EAV=48 3 +214PO G 3093.98 400.00037 4 +214PO L 3139.0 8 +214PO L 3142.6 4 (1-),(1,2)+ +214PO B 127 110.00118 9 7.3 +214POS B EAV=34 3 +214PO G 3142.58 400.00118 9 +214PO L 3149.2 5 (1-),(1,2)+ +214PO B 121 110.00019 8 +214POS B EAV=32 3 +214PO G 3149.0 5 0.00019 +214PO L 3160.4 6 (1-),(1,2)+ +214PO B 110 110.00079 12 7.2 +214POS B EAV=29 3 +214PO G 2550.7 7 0.00032 9 +214PO G 3160.6 6 0.00047 8 +214PO L 3164.8 8 +214PO L 3173.3 6 +214PO B 97 110.00014 9 7.8 +214POS B EAV=26 3 +214PO G 2564.0 6 0.00014 9 +214PO L 3183.6 4 (1-),(1,2)+ +214PO B 86 110.0011 5 6.8 +214POS B EAV=23 3 +214PO G 3183.57 400.0011 5 +214PO L 3262.4 8 + diff --git a/HEN_HOUSE/spectra/lnhb/Bi-215.txt b/HEN_HOUSE/spectra/lnhb/Bi-215.txt index f63a7d1b6..ec1b6cb9e 100644 --- a/HEN_HOUSE/spectra/lnhb/Bi-215.txt +++ b/HEN_HOUSE/spectra/lnhb/Bi-215.txt @@ -1,97 +1,102 @@ -215PO 215BI B- DECAY (7.6 M) -215PO H TYP=Full$AUT=A.L. Nichols$CUT=30-JUL-2011$ -215PO C Evaluation history: Type=Full;Author=A.L. Nichols;Cutoff date=30-JUL-2011 -215PO C References: 1933Sa01, 1953Hy83, 1955Ev23, 1963KaZZ, 1965Nu03, 1970Da09, -215PO2C 1977La19, 1989Bu09, 1990Ru02, 1991Ma16, 1996Sc06, 1998ScZM, 1999ScZX, -215PO3C 2001Br31, 2002Ra45, 2002Ba85, 2003Ku26, 2003Ak06, 2003Auo3, 2004Br45, -215PO4C 2007Ba19, 2008Ki07 -215PO T Auger electrons and X ray energies and emission intensities: -215PO T {U Energy (keV)} {U Intensity} {U Line} -215PO T -215PO T 76.864 1.8 3 XKA2 -215PO T 79.293 3.0 5 XKA1 -215PO T -215PO T 89.256 |] XKB3 -215PO T 89.807 |] 1.02 16 XKB1 -215PO T 90.363 |] XKB5II -215PO T -215PO T 92.263 |] XKB2 -215PO T 92.618 |] 0.32 5 XKB4 -215PO T 92.983 |] XKO23 -215PO T -215PO T 9.658-16.213 2.7 3 XL (total) -215PO T 9.658 0.065 8 XLL -215PO T 11.016-11.13 1.20 13 XLA -215PO T 12.085 0.022 3 XLC -215PO T 12.823-13.778 1.18 11 XLB -215PO T 15.742-16.213 0.24 2 XLG -215PO T -215PO T 58.978-65.205 |] KLL AUGER -215PO T 71.902-79.289 |] 0.22 5 KLX AUGER -215PO T 84.8-93.1 |] KXY AUGER -215PO T 5.434-10.934 4.0 4 L AUGER -215BI P 0.0 (9/2)- 7.6 M 2 2189 15 -215PO N 1.0 1.0 1 1.0 -215PO L 0 9/2+ 1.781 MS 4 -215PO B 2189 1561 6 6.28 -215POS B EAV=808 6 -215PO L 271.228 107/2+ -215PO G 271.228 101.95 7M1+E2 4.0 4 0.201 7 -215PO2 G KC=0.111 6$LC=0.0668 11$MC=0.0173 3 -215PO L 293.56 4 (11/2)+ -215PO B 1895 1530 6 6.35 1 -215POS B EAV=685 6 -215PO G 293.56 4 23.8 9M1+E2 1.0 2 0.34 5 -215PO2 G KC=0.25 4$LC=0.062 4$MC=0.0152 7 -215PO L 401.812 105/2+ -215PO B 1787 150.5 1 9 1U -215POS B EAV=619 6 -215PO G 130.58 1 0.0093 10M1+E2 0.60 6 4.44 13 -215PO2 G KC=3.19 16$LC=0.94 4$MC=0.234 10 -215PO G 401.81 1 0.48 7E2 0.0555 8 -215PO2 G KC=0.0351 5$LC=0.01528 22$MC=0.00390 6 -215PO L 517.60 6 7/2, 9/2+ -215PO B 1671 150.3 2 8.1 1 -215POS B EAV=593 6 -215PO G 224.04 7 0.033 5E2 0.319 5 -215PO2 G KC=0.1296 19$LC=0.1407 20$MC=0.0370 6 -215PO G 517.60 6 1.02 8M1+E2 1.0 2 0.073 10 -215PO2 G KC=0.058 9$LC=0.0115 11$MC=0.00277 24 -215PO L 608.30 7 (11/2, 13/2)+ -215PO B 1581 150.7 1 7.7 1 -215POS B EAV=556 6 -215PO G 608.30 7 0.67 7(M1+E2) -215PO L 676.66 7 + -215PO B 1512 150.5 1 7.8 -215POS B EAV=528 6 -215PO G 383.10 8 0.14 7 -215PO G 405.43 7 0.006 1 -215PO G 676.66 7 0.40 7 -215PO L 835.32 22 + -215PO B 1354 151.5 1 7.1 -215POS B EAV=465 6 -215PO G 541.76 220.21 7 -215PO G 564.09 220.67 7 -215PO G 835.32 220.62 7 -215PO L 1077.6 20 + -215PO B 1111 150.7 1 7.1 -215POS B EAV=370 6 -215PO G 784 2 0.33 7 -215PO G 806.4 200.40 7 -215PO L 1176.2 20 + -215PO B 1013 150.2 1 7.5 -215POS B EAV=332 6 -215PO G 905 2 0.21 7 -215PO L 1294.5 1 + -215PO B 895 152.0 2 6.34 -215POS B EAV=287 6 -215PO G 776.9 1 0.81 14 -215PO G 1023.3 1 0.62 7 -215PO G 1294.5 1 0.62 7 -215PO L 1398.8 4 + -215PO B 790 152.8 1 6 -215POS B EAV=249 6 -215PO G 1105.2 4 1.50 7 -215PO G 1127.6 4 0.48 7 -215PO G 1398.8 4 0.81 7 - +215PO 215BI B- DECAY (7.6 M) +215PO H TYP=FUL$AUT=A.L.NICHOLS$CUT=30-JUL-2011$ +215PO C References:1933Sa01, 1953Hy83, 1955Ev23, 1963KaZZ, 1965Nu03, 1970Da09, +215PO2C 1977La19, 1989Bu09, 1990Ru02, 1991Ma16, 1996Sc06, 1998ScZM, 1999ScZX, +215PO3C 2001Br31, 2002Ra45, 2002Ba85, 2003Ku26, 2003Ak06, 2003Au03, 2004Br45, +215PO4C 2007Ba19, 2008Ki07 +215PO T Auger electrons and X ray energies and emission intensities: +215PO T {U Energy (keV)} {U Intensity} {U Line} +215PO T +215PO T 76.864 1.8 3 XKA2 +215PO T 79.293 3.0 5 XKA1 +215PO T +215PO T 89.256 |] XKB3 +215PO T 89.807 |] 1.02 16 XKB1 +215PO T 90.363 |] XKB5II +215PO T +215PO T 92.263 |] XKB2 +215PO T 92.618 |] 0.32 5 XKB4 +215PO T 92.983 |] XKO23 +215PO T +215PO T 9.658-16.213 2.7 3 XL (total) +215PO T 9.658 0.065 8 XLL +215PO T 11.016-11.13 1.20 13 XLA +215PO T 12.085 0.022 3 XLC +215PO T 12.823-13.778 1.18 11 XLB +215PO T 15.742-16.213 0.24 2 XLG +215PO T +215PO T 58.978-65.205 |] KLL AUGER +215PO T 71.902-79.289 |] 0.22 5 KLX AUGER +215PO T 84.8-93.1 |] KXY AUGER +215PO T 5.434-10.934 4.0 4 L AUGER +215BI P 0.0 (9/2)- 7.6 M 2 2189 15 +215PO N 1.0 1.0 1 1.0 +215PO L 0 9/2+ 1.781 MS 4 +215PO B 2189 1561 6 6.28 +215POS B EAV=808 6 +215PO L 271.228 107/2+ +215PO G 271.228 101.95 7M1+E2 4.0 4 0.201 7 +215PO2 G KC=0.111 6$LC=0.0668 11$MC=0.0173 3$NC=0.00444 7 +215PO3 G OC=0.000868 13 +215PO L 293.56 4 (11/2)+ +215PO B 1895 1530 6 6.35 1 +215POS B EAV=685 6 +215PO G 293.56 4 23.8 9M1+E2 1.0 2 0.34 5 +215PO2 G KC=0.25 4$LC=0.062 4$MC=0.0152 7$NC=0.00391 17 +215PO3 G OC=0.00080 4 +215PO L 401.812 105/2+ +215PO B 1787 150.5 1 9 1U +215POS B EAV=619 6 +215PO G 130.58 1 0.0093 10M1+E2 0.60 6 4.44 13 +215PO2 G KC=3.19 16$LC=0.94 4$MC=0.234 10$NC=0.0601 24 +215PO3 G OC=0.0121 5 +215PO G 401.81 1 0.48 7E2 0.0555 8 +215PO2 G KC=0.0351 5$LC=0.01528 22$MC=0.00390 6$NC=0.001001 14 +215PO3 G OC=0.000198 3 +215PO L 517.60 6 7/2,9/2+ +215PO B 1671 150.3 2 8.1 1 +215POS B EAV=593 6 +215PO G 224.04 7 0.033 5E2 0.319 5 +215PO2 G KC=0.1296 19$LC=0.1407 20$MC=0.0370 6$NC=0.00950 14 +215PO3 G OC=0.00183 3 +215PO G 517.60 6 1.02 8M1+E2 1.0 2 0.073 10 +215PO2 G KC=0.058 9$LC=0.0115 11$MC=0.00277 24$NC=0.00071 7 +215PO3 G OC=0.000147 14 +215PO L 608.30 7 (11/2,13/2)+ +215PO B 1581 150.7 1 7.7 1 +215POS B EAV=556 6 +215PO G 608.30 7 0.67 7(M1+E2) +215PO L 676.66 7 +215PO B 1512 150.5 1 7.8 +215POS B EAV=528 6 +215PO G 383.10 8 0.14 7 +215PO G 405.43 7 0.006 1 +215PO G 676.66 7 0.40 7 +215PO L 835.32 22 +215PO B 1354 151.5 1 7.1 +215POS B EAV=465 6 +215PO G 541.76 220.21 7 +215PO G 564.09 220.67 7 +215PO G 835.32 220.62 7 +215PO L 1077.6 20 +215PO B 1111 150.7 1 7.1 +215POS B EAV=370 6 +215PO G 784 2 0.33 7 +215PO G 806.4 200.40 7 +215PO L 1176.2 20 +215PO B 1013 150.2 1 7.5 +215POS B EAV=332 6 +215PO G 905 2 0.21 7 +215PO L 1294.5 1 +215PO B 895 152.0 2 6.34 +215POS B EAV=287 6 +215PO G 776.9 1 0.81 14 +215PO G 1023.3 1 0.62 7 +215PO G 1294.5 1 0.62 7 +215PO L 1398.8 4 +215PO B 790 152.8 1 6 +215POS B EAV=249 6 +215PO G 1105.2 4 1.50 7 +215PO G 1127.6 4 0.48 7 +215PO G 1398.8 4 0.81 7 + diff --git a/HEN_HOUSE/spectra/lnhb/Br-76.txt b/HEN_HOUSE/spectra/lnhb/Br-76.txt index 7f75dfda8..61c75f6eb 100644 --- a/HEN_HOUSE/spectra/lnhb/Br-76.txt +++ b/HEN_HOUSE/spectra/lnhb/Br-76.txt @@ -1,402 +1,460 @@ - 76SE 76BR EC DECAY (16.1 H) - 76SE C References: 1952Fu04, 1954Ca03, 1955Th01, 1956Te26, 1959Gi46, 1960Bu22, - 76SE2C 1962Ku06, 1962Ga13, 1962St02, 1963Sa26, 1963Do04, 1964By02, 1969Dz01, - 76SE3C 1970AgZV, 1970Dz09, 1971La01, 1971Go40, 1971FuZP, 1971Dz08, 1973Pa02, - 76SE4C 1974Na17, 1974HeYW, 1974MuZB, 1974Ba80, 1975VyZX, 1975NeZR, 1976Ba15, - 76SE5C 1977Le11, 1977La19, 1980Ka36, 1982MuZV, 1983Pa10, 1986Gi12, 1987Su05, - 76SE6C 1988Wh03, 1988Gr26, 1989Za03, 1992Gr20, 1993Oh09, 1995ScZY, 1995Si03, - 76SE7C 1996Sc06, 1998ScZM, 1998Sc28, 1999ScZX, 2000Sc47, 2002Ba85, 2002Ra45, - 76SE8C 2007Qa02, 2008Ki07, 2012Co17, 2012Wa38, 2013Go19, 2014StZZ - 76SE T Auger electrons and X ray energies and emission intensities: - 76SE T {U Energy (keV)} {U Intensity} {U Line} - 76SE T - 76SE T 11.1815 7.20 13 XKA2 - 76SE T 11.2225 13.96 25 XKA1 - 76SE T - 76SE T 12.4897 |] XKB3 - 76SE T 12.496 |] 3.26 7 XKB1 - 76SE T 12.596 |] XKB5II - 76SE T - 76SE T 12.6523 |] XKB2 - 76SE T |] 0.183 7 XKB4 - 76SE T - 76SE T 1.204-1.648 0.968 20 XL (total) - 76SE T 1.204 0.0242 8 XLL - 76SE T 1.379- 0.569 16 XLA - 76SE T 1.245 0.0131 4 XLC - 76SE T 1.42-1.492 0.360 11 XLB - 76SE T 1.648- 0.00245 7 XLG - 76SE T - 76SE T 9.28-9.712 |] KLL AUGER - 76SE T 10.749-11.216 |] 16.3 3 KLX AUGER - 76SE T 12.195-12.647 |] KXY AUGER - 76SE T 0.956-1.312 52.9 7 L AUGER - 76BR P 0.0 1- 16.1 H 2 4963 9 - 76SE N 1.0 1.0 1 1.0 - 76SE G 546.5 5 0.163 23 - 76SE G 2170 2 0.10 4 - 76SE G 2235 2 0.13 6 - 76SE G 2837 3 0.11 5 - 76SE G 3892 2 0.030 15 - 76SE G 3963.5 100.022 8 - 76SE L 0 0 0+ STABLE - 76SE E 5.7 8 0.10 2 8.93 1 - 76SE2 E EAV=1803 4$CK=0.8803 15$CL=0.1003 12$CM=0.0176 4$CN=0.0019 2$CO= - 76SE L 559.102 5 2+ 12.22 PS 17 - 76SE E 25.7 9 0.75 3 7.98 1 - 76SE2 E EAV=1535 4$CK=0.8802 15$CL=0.1003 12$CM=0.0176 4$CN=0.0019 2$CO= - 76SE G 559.100 5 74.0 7 E2 0.001973 - 76SE2 G KC=1747E-6 25$LC=1.87E-4 3$MC=2.91E-5 4 - 76SE L 1122.283 7 0+ 9 PS 4 - 76SE E 2.1 6 0.11 3 8.71 1 - 76SE2 E EAV=1268 4$CK=0.8801 15$CL=0.1004 12$CM=0.0176 4$CN=0.0019 2$CO= - 76SE G 563.179 9 3.5 6 E2 0.001923 - 76SE2 G KC=1710E-6 24$LC=1.83E-4 3$MC=2.85E-5 4 - 76SE G 1122.274 7 - 76SE L 1216.147 7 2+ 3.4 PS 1 - 76SE E 1.8 9 0.10 5 8.71 1 - 76SE2 E EAV=1224 4$CK=0.8801 15$CL=0.1004 12$CM=0.0176 4$CN=0.0019 2$CO= - 76SE G 657.042 9 16.0 4 M1+E2(+) 5.2 2 1226E-618 - 76SE2 G KC=1090E-6 16$LC=1159E-7 17$MC=1.80E-5 3 - 76SE G 1216.137 7 8.73 22E2 2.81E-44 - 76SE2 G KC=2.41E-4 4$LC=2.51E-5 4$MC=3.90E-6 6 - 76SE L 1330.860 8 4+ 1.52 PS 4 - 76SE G 114.7 1 0.33 11E2 0.501 8 - 76SE2 G KC=0.434 6$LC=0.0573 9$MC=0.00886 13 - 76SE G 771.754 100.414 23E2 8.00E-412 - 76SE2 G KC=7.12E-4 10$LC=7.52E-5 11$MC=1170E-8 17 - 76SE L 1688.962 7 3+ - 76SE E 0.6 3 0.11 6 10 1U - 76SE2 E EAV=1026 4$CK=0.8800 15$CL=0.1005 12$CM=0.0176 4$CN=0.0019 2$CO= - 76SE G 358.101 110.37 15M1+E2 1.0 2 0.0059 5 - 76SE2 G KC=0.0053 5$LC=0.00057 5$MC=8.9E-5 8 - 76SE G 472.813 101.92 8 M1+E2 1.0 2 0.0026315 - 76SE2 G KC=0.00233 13$LC=2.50E-4 15$MC=3.88E-5 23 - 76SE G 1129.851 9 4.59 23M1+E2 1.08 10 3.09E-45 - 76SE2 G KC=2.75E-4 4$LC=2.86E-5 5$MC=4.44E-6 7 - 76SE L 1787.648 8 2+ 8 PS 5 - 76SE E 0.9 4 0.10 4 8.6 1 - 76SE2 E EAV=957 4$CK=0.8800 15$CL=0.1005 12$CM=0.0176 4$CN=0.0019 2$CO= - 76SE G 456.787 110.067 15E2 0.003656 - 76SE2 G KC=0.00324 5$LC=3.51E-4 5$MC=5.46E-5 8 - 76SE G 571.499 110.44 23M1+E2 0.13 12 0.001293 - 76SE2 G KC=0.00115 3$LC=1.20E-4 3$MC=1.87E-5 5 - 76SE G 665.362 110.71 8 E2 1194E-617 - 76SE2 G KC=1062E-6 15$LC=1128E-7 16$MC=1755E-8 25 - 76SE G 1228.535 102.13 10M1+E2 -0.51 5 2.64E-44 - 76SE2 G KC=2.26E-4 4$LC=2.34E-5 4$MC=3.64E-6 6 - 76SE G 1787.625 8 0.55 3 E2 3.33E-45 - 76SE2 G KC=1103E-7 16$LC=1139E-8 16$MC=1772E-9 25 - 76SE L 2127.215 8 (2)+ - 76SE E 0.19 110.04 2 8.9 1 - 76SE2 E EAV=800 4$CK=0.8799 15$CL=0.1006 12$CM=0.0176 4$CN=0.0019 2$CO= - 76SE G 438.252 110.27 3 (M1+E2) 1.0 2 0.0032621 - 76SE2 G KC=0.00290 18$LC=3.11E-4 21$MC=4.8E-5 4 - 76SE G 796.351 110.074 23(E2) 7.37E-411 - 76SE2 G KC=6.56E-4 10$LC=6.93E-5 10$MC=1077E-8 15 - 76SE G 911.062 110.05 3 (M1+E2) - 76SE G 1568.096 100.95 5 (M1+E2) 1.0 2 2.59E-45 - 76SE2 G KC=1404E-7 20$LC=1451E-8 21$MC=2.26E-6 4 - 76SE G 2127.183 8 0.21 7 (E2) 4.61E-47 - 76SE2 G KC=8.00E-5 12$LC=8.24E-6 12$MC=1282E-9 18 - 76SE L 2170.554 12(0)+ - 76SE G 1611.434 130.222 23(E2) 2.82E-44 - 76SE2 G KC=1348E-7 19$LC=1394E-8 20$MC=2.17E-6 3 - 76SE G 2170.521 12 () - 76SE L 2374.2 6 + - 76SE E 0.21 2 0.07 1 8.6 - 76SE2 E EAV=688 4$CK=0.8798 15$CL=0.1006 12$CM=0.0176 4$CN=0.0019 2$CO= - 76SE G 1158.1 5 0.133 8 - 76SE G 1815.1 6 0.148 15 - 76SE L 2429.095 113- - 76SE E 0.6 4 0.2 1 8.1 2 - 76SE2 E EAV=663 4$CK=0.8798 15$CL=0.1006 12$CM=0.0176 4$CN=0.0019 2$CO= - 76SE G 641.444 140.14 4 E1 4.60E-47 - 76SE2 G KC=4.10E-4 6$LC=4.26E-5 6$MC=6.62E-6 10 - 76SE G 740.129 130.13 4 E1+M2 -0.21 12 0.000409 - 76SE2 G KC=0.00036 8$LC=3.7E-5 9$MC=5.8E-6 14 - 76SE G 1212.938 131.7 6 E1 1.82E-43 - 76SE2 G KC=1134E-7 16$LC=1167E-8 17$MC=1.81E-6 3 - 76SE G 1306.800 130.185 23E3 4.45E-47 - 76SE2 G KC=3.88E-4 6$LC=4.11E-5 6$MC=6.39E-6 9 - 76SE G 1869.968 120.141 15E1 5.97E-49 - 76SE2 G KC=5.55E-5 8$LC=5.68E-6 8$MC=8.84E-7 13 - 76SE G 2429.053 110.10 5 E3 4.37E-47 - 76SE2 G KC=9.91E-5 14$LC=1026E-8 15$MC=1596E-9 23 - 76SE L 2514.663 13(2)+ - 76SE E 0.28 170.11 7 8.3 1 - 76SE2 E EAV=624 4$CK=0.8798 15$CL=0.1007 12$CM=0.0176 4$CN=0.0019 2$CO= - 76SE G 727.011 150.67 23(M1+E2) 1.0 2 8.44E-424 - 76SE2 G KC=7.51E-4 21$LC=7.90E-5 24$MC=1.23E-5 4 - 76SE G 1298.504 150.089 8 (M1+E2) - 76SE G 1955.534 140.30 6 (M1+E2) - 76SE L 2630.8 5 (1, 2)+ - 76SE E 0.20 150.11 9 8.3 - 76SE2 E EAV=572 4$CK=0.8797 15$CL=0.1007 12$CM=0.0176 4$CN=0.0019 2$CO= - 76SE G 941.8 5 0.111 23 - 76SE G 2071.7 5 0.27 23 - 76SE G 2630.8 5 0.13 4 - 76SE L 2655.32 4 1- - 76SE E 0.26 8 0.15 4 8.1 - 76SE2 E EAV=561 4$CK=0.8797 15$CL=0.1007 12$CM=0.0176 4$CN=0.0019 2$CO= - 76SE G 867.66 4 0.318 23(E1) 2.40E-44 - 76SE2 G KC=2.15E-4 3$LC=2.22E-5 4$MC=3.45E-6 5 - 76SE G 1324.45 4 0.044 23(E3) 4.32E-46 - 76SE2 G KC=3.76E-4 6$LC=3.97E-5 6$MC=6.18E-6 9 - 76SE G 1439.16 4 0.58 3 (E1) 2.99E-45 - 76SE2 G KC=8.43E-5 12$LC=8.67E-6 13$MC=1347E-9 19 - 76SE G 1533.01 4 0.06 4 (E1) 3.62E-45 - 76SE2 G KC=7.60E-5 11$LC=7.80E-6 11$MC=1213E-9 17 - 76SE G 2096.19 4 1.35 8 (E1) 7.49E-411 - 76SE2 G KC=4.67E-5 7$LC=4.78E-6 7$MC=7.43E-7 11 - 76SE G 2655.27 4 0.170 15(E1) 1087E-616 - 76SE2 G KC=3.33E-5 5$LC=3.40E-6 5$MC=5.29E-7 8 - 76SE L 2669.88 4 2- - 76SE E 1.49 100.88 6 7.33 - 76SE2 E EAV=554 4$CK=0.8797 15$CL=0.1007 12$CM=0.0176 4$CN=0.0019 2$CO= - 76SE G 499.33 4 0.16 7 (M2) 0.005648 - 76SE2 G KC=0.00500 7$LC=5.46E-4 8$MC=8.53E-5 12 - 76SE G 882.22 4 0.40 2 E1+M2 0.26 15 0.000298 - 76SE2 G KC=0.00026 7$LC=2.7E-5 8$MC=4.2E-6 12 - 76SE G 980.91 4 0.355 23E1 1.89E-43 - 76SE2 G KC=1682E-7 24$LC=1736E-8 25$MC=2.70E-6 4 - 76SE G 1453.72 4 0.81 5 E1 3.08E-45 - 76SE2 G KC=8.29E-5 12$LC=8.52E-6 12$MC=1325E-9 19 - 76SE G 2110.75 4 2.46 12E1 7.59E-411 - 76SE2 G KC=4.62E-5 7$LC=4.73E-6 7$MC=7.36E-7 11 - 76SE L 2858.1 20 + - 76SE E 0.13 3 0.14 3 8.1 - 76SE2 E EAV=471 4$CK=0.8796 15$CL=0.1008 12$CM=0.0177 4$CN=0.0019 2$CO= - 76SE G 1642 2 0.13 5 - 76SE G 2299 2 0.14 5 - 76SE L 2950.53 5 1, 2+ - 76SE E 5.1 2 6.9 3 6.33 - 76SE2 E EAV=430 4$CK=0.8796 15$CL=0.1008 12$CM=0.0177 4$CN=0.0019 2$CO= - 76SE G 1162.87 5 0.163 15M1+E2 - 76SE G 2391.39 5 4.7 3 M1+E2 1.0 2 5.41E-411 - 76SE2 G KC=6.46E-5 10$LC=6.63E-6 10$MC=1032E-9 15 - 76SE G 2950.47 5 7.4 4 [M1+E2] 1.0 2 7.70E-414 - 76SE2 G KC=4.52E-5 7$LC=4.63E-6 7$MC=7.20E-7 11 - 76SE L 3069.75 4 (1, 2)+ - 76SE E 6.1 1 12.7 2 6.01 - 76SE2 E EAV=378 4$CK=0.8795 15$CL=0.1009 12$CM=0.0177 4$CN=0.0019 2$CO= - 76SE G 399.87 6 0.052 15E1 1466E-621 - 76SE2 G KC=1307E-6 19$LC=1363E-7 19$MC=2.12E-5 3 - 76SE G 899.19 4 0.170 23 - 76SE G 942.53 4 0.074 15(M1+E2) - 76SE G 1282.09 4 0.07 3 (M1+E2) - 76SE G 1380.78 4 2.50 11[M1+E2] 1.0 2 2.45E-44 - 76SE2 G KC=1.81E-4 3$LC=1.87E-5 3$MC=2.91E-6 5 - 76SE G 1853.58 4 14.6 8 (M1+E2) 1.0 2 3.34E-47 - 76SE2 G KC=1022E-7 15$LC=1053E-8 15$MC=1638E-9 24 - 76SE G 2510.61 4 1.92 12(M1+E2) 1.0 2 5.90E-411 - 76SE2 G KC=5.93E-5 9$LC=6.09E-6 9$MC=9.48E-7 14 - 76SE G 3069.68 4 0.044 15 - 76SE L 3160.07 6 (2)+ - 76SE E 1.32 4 3.99 146.47 1 - 76SE2 E EAV=339 4$CK=0.8794 15$CL=0.1010 12$CM=0.0177 4$CN=0.0019 2$CO= - 76SE G 490.19 7 0.333 23[E1] 8.72E-413 - 76SE2 G KC=7.78E-4 11$LC=8.09E-5 12$MC=1258E-8 18 - 76SE G 504.75 7 0.229 15[E1] 8.11E-412 - 76SE2 G KC=7.23E-4 11$LC=7.53E-5 11$MC=1170E-8 17 - 76SE G 730.98 6 0.58 8 [E1] 3.44E-45 - 76SE2 G KC=3.07E-4 5$LC=3.18E-5 5$MC=4.95E-6 7 - 76SE G 1032.85 6 0.58 5 - 76SE G 1372.41 6 0.51 3 - 76SE G 1471.09 6 2.32 11M1+E2 1.0 2 2.45E-45 - 76SE2 G KC=1592E-7 23$LC=1647E-8 24$MC=2.56E-6 4 - 76SE G 1943.89 6 0.47 9 - 76SE G 2600.92 6 0.69 3 - 76SE G 3160.00 6 0.141 15 - 76SE L 3268.8 4 (2, 3, 4)- - 76SE L 3351.54 7 (1, 2)+ - 76SE E 1.00 4 8.0 4 6.07 - 76SE2 E EAV=256 4$CK=0.8793 15$CL=0.1011 12$CM=0.0177 4$CN=0.0019 2$CO= - 76SE G 401.01 9 0.30 4 (M1+E2) 1.0 2 0.0042 3 - 76SE2 G KC=0.0038 3$LC=0.00041 3$MC=6.3E-5 5 - 76SE G 681.66 8 0.429 23E1 4.01E-46 - 76SE2 G KC=3.58E-4 5$LC=3.71E-5 6$MC=5.77E-6 8 - 76SE G 696.22 8 0.496 23(E1) 3.83E-46 - 76SE2 G KC=3.42E-4 5$LC=3.54E-5 5$MC=5.51E-6 8 - 76SE G 836.88 7 0.45 4 (M1+E2) - 76SE G 922.44 7 0.192 15 - 76SE G 1180.98 7 0.111 15 - 76SE G 1224.32 7 0.29 11(M1+E2) - 76SE G 1662.56 7 0.14 6 - 76SE G 2135.36 7 0.93 6 (M1+E2) 1.0 2 4.38E-49 - 76SE2 G KC=7.89E-5 12$LC=8.12E-6 12$MC=1262E-9 18 - 76SE G 2229.22 7 0.10 7 - 76SE G 2792.38 7 5.6 3 (M1+E2) 1.0 2 7.06E-413 - 76SE2 G KC=4.95E-5 7$LC=5.08E-6 8$MC=7.90E-7 12 - 76SE G 3351.46 7 0.252 15 - 76SE L 3441.5 2 (1, 2, 3)+ - 76SE E 0.006 2 0.09 3 8 - 76SE2 E EAV=218 4$CK=0.8792 15$CL=0.1012 12$CM=0.0177 4$CN=0.0019 2$CO= - 76SE G 281.4 2 0.044 23[M1+E2] 1.0 2 0.0127 13 - 76SE2 G KC=0.0113 12$LC=0.00125 14$MC=1.94E-4 21 - 76SE G 1270.9 200.059 23(M1+E2) - 76SE L 3459.40 8 (2)+ - 76SE E 0.108 9 1.81 156.65 1 - 76SE2 E EAV=210 4$CK=0.8792 15$CL=0.1012 12$CM=0.0177 4$CN=0.0019 2$CO= - 76SE G 789.52 9 0.46 3 (E1) 2.92E-44 - 76SE2 G KC=2.61E-4 4$LC=2.70E-5 4$MC=4.19E-6 6 - 76SE G 804.08 9 0.53 4 (E1) 2.81E-44 - 76SE2 G KC=2.51E-4 4$LC=2.60E-5 4$MC=4.04E-6 6 - 76SE G 1030.30 8 0.56 6 (E1) 1716E-724 - 76SE2 G KC=1531E-7 22$LC=1579E-8 23$MC=2.45E-6 4 - 76SE G 1288.84 8 0.052 23(E2) 2.64E-44 - 76SE2 G KC=2.13E-4 3$LC=2.21E-5 3$MC=3.44E-6 5 - 76SE G 1671.73 8 0.170 15(M1+E2) - 76SE G 1770.42 8 0.200 23(M1+E2) - 76SE G 2900.24 8 0.27 10(M1+E2) - 76SE L 3556.46 8 (1, 2)+ - 76SE E 0.040 4 1.53 8 6.67 - 76SE2 E EAV=169 4$CK=0.8791 15$CL=0.1013 12$CM=0.0178 4$CN=0.0019 2$CO= - 76SE G 886.57 9 0.340 23 - 76SE G 901.13 9 0.17 5 - 76SE G 1429.24 8 0.06 3 - 76SE G 2340.27 8 0.09 4 - 76SE G 2997.30 8 0.955 24[M1+E2] 1.0 2 7.89E-414 - 76SE2 G KC=4.40E-5 7$LC=4.51E-6 7$MC=7.01E-7 10 - 76SE L 3604.08 8 1, 2+ - 76SE E 0.026 3 1.64 136.61 - 76SE2 E EAV=149 4$CK=0.8790 15$CL=0.1013 12$CM=0.0178 4$CN=0.0019 2$CO= - 76SE G 934.19 9 0.052 15E1 2.07E-43 - 76SE2 G KC=1.85E-4 3$LC=1.91E-5 3$MC=2.97E-6 5 - 76SE G 2481.76 8 0.133 23 - 76SE G 3044.91 8 0.022 8 (M1+E2) - 76SE G 3603.99 8 1.60 11[M1+E2] 1.0 2 1018E-617 - 76SE2 G KC=3.26E-5 5$LC=3.34E-6 5$MC=5.20E-7 8 - 76SE L 3622.2 20 + - 76SE E 0.005 2 0.36 117.3 - 76SE2 E EAV=142 4$CK=0.8790 15$CL=0.1013 12$CM=0.0178 4$CN=0.0019 2$CO= - 76SE G 1193.1 200.10 5 - 76SE G 1834.6 200.19 10 - 76SE G 3063 2 0.074 23 - 76SE L 3669.5 10 + - 76SE E 0.005 1 0.73 196.9 - 76SE2 E EAV=122 4$CK=0.8789 15$CL=0.1014 12$CM=0.0178 4$CN=0.0019 2$CO= - 76SE G 210.1 100.044 15[M1+E2] 1.0 2 0.034 5 - 76SE2 G KC=0.030 4$LC=0.0034 5$MC=0.00053 7 - 76SE G 318 1 0.13 5 [M1+E2] 1.0 2 0.0086 8 - 76SE2 G KC=0.0076 7$LC=0.00084 8$MC=1.30E-4 13 - 76SE G 599.8 100.42 17[M1+E2] 1.0 2 0.001376 - 76SE2 G KC=0.00122 5$LC=1.29E-4 6$MC=2.01E-5 9 - 76SE G 1881.9 100.13 5 - 76SE G 2547.2 100.006 4 - 76SE L 3913 1 + - 76SE E 0.133 157.5 - 76SE2 E EAV= $CK=0.8785 15$CL=0.1017 13$CM=0.0179 4$CN=0.0019 2$CO= - 76SE G 1742.4 100.118 15 - 76SE G 3912.9 100.015 8 - 76SE L 3929.1 6 (1, 2)+ - 76SE E 0.17 4 7.4 - 76SE2 E EAV= $CK=0.8784 15$CL=0.1018 13$CM=0.0179 4$CN=0.0019 2$CO= - 76SE G 1801.9 6 0.030 15 - 76SE G 2712.9 6 0.074 23 - 76SE G 3369.9 6 0.096 8 - 76SE G 3929.0 6 0.089 15 - 76SE L 3970.6 4 (1, 2)+ - 76SE E 0.64 5 6.7 - 76SE2 E EAV= $CK=0.8783 15$CL=0.1019 13$CM=0.0179 4$CN=0.0019 2$CO= - 76SE G 1300.7 4 0.155 15(E1) 2.26E-44 - 76SE2 G KC=1002E-7 14$LC=1031E-8 15$MC=1603E-9 23 - 76SE G 1315.3 4 0.052 15(E1) 2.34E-44 - 76SE2 G KC=9.83E-5 14$LC=1011E-8 15$MC=1572E-9 22 - 76SE G 2183.0 4 0.13 3 (M1+E2) - 76SE G 2754.4 4 0.074 23(M1+E2) - 76SE G 3411.4 4 0.296 15(M1+E2) - 76SE G 3970.5 4 0.010 5 - 76SE L 3998.4 10 + - 76SE E 0.42 4 6.9 - 76SE2 E EAV= $CK=0.8783 15$CL=0.1019 13$CM=0.0179 4$CN=0.0019 2$CO= - 76SE G 838.3 100.318 23 - 76SE G 2309.4 100.10 3 - 76SE L 4019.3 5 + - 76SE E 0.36 7 7 - 76SE2 E EAV= $CK=0.8782 15$CL=0.1020 13$CM=0.0179 4$CN=0.0019 2$CO= - 76SE G 1504.6 5 0.09 4 - 76SE G 2688.3 5 0.36 4 - 76SE G 4019.2 5 0.059 15 - 76SE L 4064 4 + - 76SE E 0.43 9 6.8 - 76SE2 E EAV= $CK=0.8781 15$CL=0.1021 13$CM=0.0179 4$CN=0.0019 2$CO= - 76SE G 605 4 0.22 8 [M1+E2] 1.0 2 0.001346 - 76SE2 G KC=0.00120 5$LC=1.27E-4 6$MC=1.97E-5 9 - 76SE G 2848 4 0.15 5 - 76SE G 3505 4 0.037 15 - 76SE G 4064 4 0.022 8 - 76SE L 4084.3 2 (1, 2)+ - 76SE E 0.50 4 6.7 - 76SE2 E EAV= $CK=0.8780 15$CL=0.1021 13$CM=0.0179 4$CN=0.0019 2$CO= - 76SE G 1429.0 2 0.192 23 - 76SE G 1655.2 2 0.118 23 - 76SE G 3525.1 2 0.178 15 - 76SE G 4084.2 2 0.015 8 - 76SE L 4173.1 9 (1, 2)+ - 76SE E 0.200 157.1 - 76SE2 E EAV= $CK=0.8777 15$CL=0.1024 13$CM=0.0180 4$CN=0.0019 2$CO= - 76SE G 2045.9 9 0.178 15 - 76SE G 4173.0 9 0.021 8 - 76SE L 4199.6 4 (1, 2)+ - 76SE E 0.36 4 6.8 - 76SE2 E EAV= $CK=0.8776 15$CL=0.1025 13$CM=0.0180 4$CN=0.0019 2$CO= - 76SE G 1039.5 4 0.044 15 - 76SE G 1770.5 4 0.044 15 - 76SE G 2412.0 4 0.030 8 - 76SE G 2983.4 4 0.09 3 - 76SE G 3640.4 4 0.155 15 - 76SE L 4210 1 + - 76SE E 0.24 4 6.9 - 76SE2 E EAV= $CK=0.8776 15$CL=0.1025 13$CM=0.0180 4$CN=0.0019 2$CO= - 76SE G 281 1 0.118 23[M1+E2] 1.0 2 0.0128 14 - 76SE2 G KC=0.0113 12$LC=0.00125 14$MC=1.95E-4 21 - 76SE G 2082 1 0.12 4 - 76SE L 4215.5 2 (1, 2)+ - 76SE E 0.61 3 6.5 - 76SE2 E EAV= $CK=0.8775 15$CL=0.1025 13$CM=0.0180 4$CN=0.0019 2$CO= - 76SE G 1560.2 2 0.444 23(E1) 3.81E-46 - 76SE2 G KC=7.38E-5 11$LC=7.58E-6 11$MC=1178E-9 17 - 76SE G 3093.1 2 0.163 15 - 76SE L 4328.7 10 + - 76SE E 0.19 5 6.9 - 76SE2 E EAV= $CK=0.8769 16$CL=0.1030 13$CM=0.0181 4$CN=0.0020 2$CO= - 76SE G 309.4 4 0.14 5 [M1+E2] 1.0 2 0.0094 9 - 76SE2 G KC=0.0083 8$LC=0.00091 9$MC=1.42E-4 14 - 76SE G 1060 1 0.044 23 - 76SE L 4416 2 + - 76SE E 0.26 7 6.6 - 76SE2 E EAV= $CK=0.8763 16$CL=0.1035 13$CM=0.0182 4$CN=0.0020 2$CO= - 76SE G 812.1 8 0.14 5 - 76SE G 1901 2 0.12 5 - 76SE L 4436.9 10(1, 2)+ - 76SE E 0.067 157.2 - 76SE2 E EAV= $CK=0.8761 16$CL=0.1037 13$CM=0.0182 4$CN=0.0020 2$CO= - 76SE G 3877.7 100.015 8 - 76SE G 4436.8 100.052 15 - 76SE L 4455.2 30 + - 76SE E 0.007 2 8.1 - 76SE2 E EAV= $CK=0.8760 16$CL=0.1038 13$CM=0.0183 4$CN=0.0020 2$CO= - 76SE G 4454.9 300.0067 23 - 76SE L 4492 3 + - 76SE E 0.052 157.2 - 76SE2 E EAV= $CK=0.8756 16$CL=0.1041 13$CM=0.0183 4$CN=0.0020 2$CO= - 76SE G 936 3 0.044 15 - 76SE G 4492 3 0.0059 23 - 76SE L 4605.8 7 (1, 2)+ - 76SE E 0.56 125.9 - 76SE2 E EAV= $CK=0.8738 16$CL=0.1055 13$CM=0.0186 4$CN=0.0020 2$CO= - 76SE G 635.2 8 0.074 23(M1+E2) 1.0 2 0.001185 - 76SE2 G KC=0.00105 4$LC=1.11E-4 5$MC=1.73E-5 7 - 76SE G 1146.4 7 0.059 15(M1+E2) - 76SE G 1254.3 7 0.08 3 (M1+E2) - 76SE G 1536.1 7 0.17 7 (M1+E2) - 76SE G 1975.0 9 0.11 9 - 76SE G 4046.6 7 0.044 15(M1+E2) - 76SE G 4605.7 7 0.015 8 - 76SE L 4621.5 20 + - 76SE E 0.21 4 6.3 - 76SE2 E EAV= $CK=0.8735 16$CL=0.1058 13$CM=0.0187 4$CN=0.0020 2$CO= - 76SE G 1461.4 200.13 3 - 76SE G 1990.7 210.08 3 - + 76SE 76BR EC DECAY (16.1 H) + 76SE H TYP=FUL$AUT=A.L.NICHOLS$CUT=30-NOV-2015$ + 76SE C References:1952Fu04, 1954Ca03, 1955Th01, 1956Te26, 1959Gi46, 1960Bu22, + 76SE2C 1962Ku06, 1962Ga13, 1962St02, 1963Sa26, 1963Do04, 1964By02, 1970AgZV, + 76SE3C 1969Dz01, 1971FuZP, 1971La01, 1971Go40, 1970Dz09, 1971Dz08, 1973Pa02, + 76SE4C 1974Na17, 1974HeYW, 1974Ba80, 1974MuZB, 1975NeZR, 1975VyZX, 1976Ba15, + 76SE5C 1977Le11, 1977La19, 1980Ka36, 1982MuZV, 1983Pa10, 1986Gi12, 1987Su05, + 76SE6C 1988Gr26, 1988Wh03, 1989Za03, 1992Gr20, 1993Oh09, 1995ScZY, 1995Si03, + 76SE7C 1996Sc06, 1996Sc06, 1998Sc28, 1998ScZM, 1999ScZX, 2000Sc47, 2002Ba85, + 76SE8C 2002Ra45, 2003Au03, 2007Qa02, 2008Ki07, 2012Co17, 2012Wa38, 2013Go19, + 76SE9C 2014StZZ + 76SE T Auger electrons and X ray energies and emission intensities: + 76SE T {U Energy (keV)} {U Intensity} {U Line} + 76SE T + 76SE T 11.1815 7.20 13 XKA2 + 76SE T 11.2225 13.96 25 XKA1 + 76SE T + 76SE T 12.4897 |] XKB3 + 76SE T 12.496 |] 3.26 7 XKB1 + 76SE T 12.596 |] XKB5II + 76SE T + 76SE T 12.6523 |] XKB2 + 76SE T |] 0.183 7 XKB4 + 76SE T + 76SE T 1.204-1.648 0.968 20 XL (total) + 76SE T 1.204 0.0242 8 XLL + 76SE T 1.379- 0.569 16 XLA + 76SE T 1.245 0.0131 4 XLC + 76SE T 1.42-1.492 0.360 11 XLB + 76SE T 1.648- 0.00245 7 XLG + 76SE T + 76SE T 9.28-9.712 |] KLL AUGER + 76SE T 10.749-11.216 |] 16.3 3 KLX AUGER + 76SE T 12.195-12.647 |] KXY AUGER + 76SE T 0.956-1.312 52.9 7 L AUGER + 76BR P 0.0 1- 16.1 H 2 4963 9 + 76SE N 1.0 1.0 1 1.0 + 76SE G 546.5 5 0.163 23 + 76SE G 2170 2 0.10 4 + 76SE G 2235 2 0.13 6 + 76SE G 2837 3 0.11 5 + 76SE G 3892 2 0.030 15 + 76SE G 3963.5 100.022 8 + 76SE L 0 0+ STABLE + 76SE E 5.7 80.10 28.93 1 + 76SE2 E EAV=1803 4$CK=0.015178 26$CL=0.001729 21$CM=0.000303 7 + 76SE3 E CN=3.28E-5 34 + 76SE L 559.102 5 2+ 12.22 PS 17 + 76SE E 25.7 90.75 37.98 1 + 76SE2 E EAV=1535 4$CK=0.024958 43$CL=0.002844 34$CM=0.000499 11 + 76SE3 E CN=0.000054 6 + 76SE G 559.100 5 74.0 7E2 0.00197 3 + 76SE2 G KC=0.001747 25$LC=0.000187 3$MC=2.91E-5 4$NC=2.45E-6 4 + 76SE L 1122.283 7 0+ 9 PS 4 + 76SE E 2.1 60.11 38.71 1 + 76SE2 E EAV=1268 4$CK=0.04381 7$CL=0.00500 6$CM=0.000876 20 + 76SE3 E CN=0.000095 10 + 76SE G 563.179 9 3.5 6E2 0.00192 3 + 76SE2 G KC=0.001710 24$LC=0.000183 3$MC=2.85E-5 4$NC=2.40E-6 4 + 76SE G 1122.274 7 E0 + 76SE L 1216.147 7 2+ 3.4 PS 1 + 76SE E 1.8 90.10 58.71 1 + 76SE2 E EAV=1224 4$CK=0.04632 8$CL=0.00528 6$CM=0.000926 21 + 76SE3 E CN=0.000100 11 + 76SE G 657.042 9 16.0 4M1+E2(+E0)5.2 2 1226E-618 + 76SE2 G KC=0.001090 16$LC=1.159E-4 17$MC=1.80E-5 3$NC=1.524E-6 22 + 76SE G 1216.137 7 8.73 22E2 2.81E-4 4 + 76SE2 G KC=0.000241 4$LC=2.51E-5 4$MC=3.90E-6 6$NC=3.33E-7 5 + 76SE3 G IPC=1.090E-5 16 + 76SE L 1330.860 8 4+ 1.52 PS 4 + 76SE G 114.7 1 0.33 11E2 0.501 8 + 76SE2 G KC=0.434 6$LC=0.0573 9$MC=0.00886 13$NC=0.000683 10 + 76SE G 771.754 100.414 23E2 8.00E-412 + 76SE2 G KC=0.000712 10$LC=7.52E-5 11$MC=1.170E-5 17$NC=9.93E-7 14 + 76SE L 1688.962 7 3+ + 76SE E 0.6 30.11 610 1U + 76SE2 E EAV=1026 4$CK=0.13634 23$CL=0.01557 19$CM=0.00273 6 + 76SE3 E CN=0.000294 31 + 76SE G 358.101 110.37 15M1+E2 1.0 2 0.0059 5 + 76SE2 G KC=0.0053 5$LC=0.00057 5$MC=0.000089 8$NC=7.5E-6 6 + 76SE G 472.813 101.92 8M1+E2 1.0 2 0.0026315 + 76SE2 G KC=0.00233 13$LC=0.000250 15$MC=3.88E-5 23$NC=3.28E-6 19 + 76SE G 1129.851 9 4.59 23M1+E2 1.08 10 3.09E-4 5 + 76SE2 G KC=0.000275 4$LC=2.86E-5 5$MC=4.44E-6 7$NC=3.80E-7 6 + 76SE3 G IPC=1.57E-6 4 + 76SE L 1787.648 8 2+ 8 PS 5 + 76SE E 0.9 40.10 48.6 1 + 76SE2 E EAV=957 4$CK=0.08800 15$CL=0.01005 12$CM=0.00176 4 + 76SE3 E CN=0.00019 2 + 76SE G 456.787 110.067 15E2 0.00365 6 + 76SE2 G KC=0.00324 5$LC=0.000351 5$MC=5.46E-5 8$NC=4.57E-6 7 + 76SE G 571.499 110.44 23M1+E2 0.13 12 0.00129 3 + 76SE2 G KC=0.00115 3$LC=0.000120 3$MC=1.87E-5 5$NC=1.60E-6 4 + 76SE G 665.362 110.71 8E2 1194E-617 + 76SE2 G KC=0.001062 15$LC=1.128E-4 16$MC=1.755E-5 25$NC=1.484E-6 21 + 76SE G 1228.535 102.13 10M1+E2 -0.51 5 2.64E-4 4 + 76SE2 G KC=0.000226 4$LC=2.34E-5 4$MC=3.64E-6 6$NC=3.12E-7 5 + 76SE3 G IPC=1.041E-5 18 + 76SE G 1787.625 8 0.55 3E2 3.33E-4 5 + 76SE2 G KC=1.103E-4 16$LC=1.139E-5 16$MC=1.772E-6 25$NC=1.517E-7 22 + 76SE3 G IPC=0.000209 3 + 76SE L 2127.215 8 (2)+ + 76SE E 0.19 110.04 28.9 1 + 76SE2 E EAV=800 4$CK=0.15303 26$CL=0.01750 21$CM=0.00306 7 + 76SE3 E CN=0.000330 35 + 76SE G 438.252 110.27 3(M1+E2) 1.0 2 0.0032621 + 76SE2 G KC=0.00290 18$LC=0.000311 21$MC=0.000048 4$NC=4.1E-6 3 + 76SE G 796.351 110.074 23(E2) 7.37E-411 + 76SE2 G KC=0.000656 10$LC=6.93E-5 10$MC=1.077E-5 15$NC=9.15E-7 13 + 76SE G 911.062 110.05 3(M1+E2) + 76SE G 1568.096 100.95 5(M1+E2) 1.0 2 2.59E-4 5 + 76SE2 G KC=1.404E-4 20$LC=1.451E-5 21$MC=2.26E-6 4$NC=1.93E-7 3 + 76SE3 G IPC=0.000101 3 + 76SE G 2127.183 8 0.21 7(E2) 4.61E-4 7 + 76SE2 G KC=8.00E-5 12$LC=8.24E-6 12$MC=1.282E-6 18$NC=1.098E-7 16 + 76SE3 G IPC=0.000372 6 + 76SE L 2170.554 12(0)+ + 76SE G 1611.434 130.222 23(E2) 2.82E-4 4 + 76SE2 G KC=1.348E-4 19$LC=1.394E-5 20$MC=2.17E-6 3$NC=1.86E-7 3 + 76SE3 G IPC=1.309E-4 19 + 76SE G 2170.521 12 (E0) + 76SE L 2374.2 6 + 76SE E 0.21 20.07 18.6 + 76SE2 E EAV=688 4$CK=0.21995 38$CL=0.02515 30$CM=0.0044 1 + 76SE3 E CN=0.00048 5 + 76SE G 1158.1 5 0.133 8 + 76SE G 1815.1 6 0.148 15 + 76SE L 2429.095 113- + 76SE E 0.6 40.2 18.1 2 + 76SE2 E EAV=663 4$CK=0.21995 38$CL=0.02515 30$CM=0.0044 1 + 76SE3 E CN=0.00048 5 + 76SE G 641.444 140.14 4E1 4.60E-4 7 + 76SE2 G KC=0.000410 6$LC=4.26E-5 6$MC=6.62E-6 10$NC=5.65E-7 8 + 76SE G 740.129 130.13 4E1+M2 -0.21 12 0.00040 9 + 76SE2 G KC=0.00036 8$LC=0.000037 9$MC=5.8E-6 14$NC=5.0E-7 12 + 76SE G 1212.938 131.7 6E1 1.82E-4 3 + 76SE2 G KC=1.134E-4 16$LC=1.167E-5 17$MC=1.81E-6 3$NC=1.552E-7 22 + 76SE3 G IPC=5.48E-5 8 + 76SE G 1306.800 130.185 23E3 4.45E-4 7 + 76SE2 G KC=0.000388 6$LC=4.11E-5 6$MC=6.39E-6 9$NC=5.44E-7 8 + 76SE3 G IPC=8.38E-6 12 + 76SE G 1869.968 120.141 15E1 5.97E-4 9 + 76SE2 G KC=5.55E-5 8$LC=5.68E-6 8$MC=8.84E-7 13$NC=7.57E-8 11 + 76SE3 G IPC=0.000535 8 + 76SE G 2429.053 110.10 5E3 4.37E-4 7 + 76SE2 G KC=9.91E-5 14$LC=1.026E-5 15$MC=1.596E-6 23$NC=1.367E-7 20 + 76SE3 G IPC=0.000326 5 + 76SE L 2514.663 13(2)+ + 76SE E 0.28 170.11 78.3 1 + 76SE2 E EAV=624 4$CK=0.24815 42$CL=0.02840 34$CM=0.00496 11 + 76SE3 E CN=0.00054 6 + 76SE G 727.011 150.67 23(M1+E2) 1.0 2 8.44E-424 + 76SE2 G KC=0.000751 21$LC=7.90E-5 24$MC=1.23E-5 4$NC=1.05E-6 3 + 76SE G 1298.504 150.089 8(M1+E2) + 76SE G 1955.534 140.30 6(M1+E2) + 76SE L 2630.8 5 (1,2)+ + 76SE E 0.20 150.11 98.3 + 76SE2 E EAV=572 4$CK=0.3122 5$CL=0.03573 43$CM=0.00625 14 + 76SE3 E CN=0.00067 7 + 76SE G 941.8 5 0.111 23 + 76SE G 2071.7 5 0.27 23 + 76SE G 2630.8 5 0.13 4 + 76SE L 2655.32 4 1- + 76SE E 0.26 80.15 48.1 + 76SE2 E EAV=561 4$CK=0.3218 5$CL=0.03684 44$CM=0.00644 15 + 76SE3 E CN=0.00070 7 + 76SE G 867.66 4 0.318 23(E1) 2.40E-4 4 + 76SE2 G KC=0.000215 3$LC=2.22E-5 4$MC=3.45E-6 5$NC=2.94E-7 5 + 76SE G 1324.45 4 0.044 23(E3) 4.32E-4 6 + 76SE2 G KC=0.000376 6$LC=3.97E-5 6$MC=6.18E-6 9$NC=5.26E-7 8 + 76SE3 G IPC=9.93E-6 14 + 76SE G 1439.16 4 0.58 3(E1) 2.99E-4 5 + 76SE2 G KC=8.43E-5 12$LC=8.67E-6 13$MC=1.347E-6 19$NC=1.154E-7 17 + 76SE3 G IPC=0.000205 3 + 76SE G 1533.01 4 0.06 4(E1) 3.62E-4 5 + 76SE2 G KC=7.60E-5 11$LC=7.80E-6 11$MC=1.213E-6 17$NC=1.039E-7 15 + 76SE3 G IPC=0.000277 4 + 76SE G 2096.19 4 1.35 8(E1) 7.49E-411 + 76SE2 G KC=4.67E-5 7$LC=4.78E-6 7$MC=7.43E-7 11$NC=6.37E-8 9 + 76SE3 G IPC=0.000697 10 + 76SE G 2655.27 4 0.170 15(E1) 1087E-616 + 76SE2 G KC=3.33E-5 5$LC=3.40E-6 5$MC=5.29E-7 8$NC=4.54E-8 7 + 76SE3 G IPC=0.001049 15 + 76SE L 2669.88 4 2- + 76SE E 1.49 100.88 67.33 + 76SE2 E EAV=554 4$CK=0.3266 6$CL=0.03739 45$CM=0.00654 15 + 76SE3 E CN=0.00071 7 + 76SE G 499.33 4 0.16 7(M2) 0.00564 8 + 76SE2 G KC=0.00500 7$LC=0.000546 8$MC=8.53E-5 12$NC=7.25E-6 11 + 76SE G 882.22 4 0.40 2E1+M2 0.26 15 0.00029 8 + 76SE2 G KC=0.00026 7$LC=0.000027 8$MC=4.2E-6 12$NC=3.6E-7 10 + 76SE G 980.91 4 0.355 23E1 1.89E-4 3 + 76SE2 G KC=1.682E-4 24$LC=1.736E-5 25$MC=2.70E-6 4$NC=2.31E-7 4 + 76SE G 1453.72 4 0.81 5E1 3.08E-4 5 + 76SE2 G KC=8.29E-5 12$LC=8.52E-6 12$MC=1.325E-6 19$NC=1.134E-7 16 + 76SE3 G IPC=0.000215 3 + 76SE G 2110.75 4 2.46 12E1 7.59E-411 + 76SE2 G KC=4.62E-5 7$LC=4.73E-6 7$MC=7.36E-7 11$NC=6.31E-8 9 + 76SE3 G IPC=0.000707 10 + 76SE L 2858.1 20 + 76SE E 0.13 30.14 38.1 + 76SE2 E EAV=471 4$CK=0.4561 8$CL=0.0523 6$CM=0.00918 21 + 76SE3 E CN=0.00099 10 + 76SE G 1642 2 0.13 5 + 76SE G 2299 2 0.14 5 + 76SE L 2950.53 5 1,2+ + 76SE E 5.1 26.9 36.33 + 76SE2 E EAV=430 4$CK=0.5058 9$CL=0.0580 7$CM=0.01018 23 + 76SE3 E CN=0.00109 12 + 76SE G 1162.87 5 0.163 15M1+E2 + 76SE G 2391.39 5 4.7 3M1+E2 1.0 2 5.41E-411 + 76SE2 G KC=6.46E-5 10$LC=6.63E-6 10$MC=1.032E-6 15$NC=8.85E-8 13 + 76SE3 G IPC=0.000469 10 + 76SE G 2950.47 5 7.4 4[M1+E2] 1.0 2 7.70E-414 + 76SE2 G KC=4.52E-5 7$LC=4.63E-6 7$MC=7.20E-7 11$NC=6.18E-8 9 + 76SE3 G IPC=0.000719 13 + 76SE L 3069.75 4 (1,2)+ + 76SE E 6.1 112.7 26.01 + 76SE2 E EAV=378 4$CK=0.5941 10$CL=0.0682 8$CM=0.01196 27 + 76SE3 E CN=0.00128 14 + 76SE G 399.87 6 0.052 15E1 1466E-621 + 76SE2 G KC=0.001307 19$LC=1.363E-4 19$MC=2.12E-5 3$NC=1.80E-6 3 + 76SE G 899.19 4 0.170 23 + 76SE G 942.53 4 0.074 15(M1+E2) + 76SE G 1282.09 4 0.07 3(M1+E2) + 76SE G 1380.78 4 2.50 11[M1+E2] 1.0 2 2.45E-4 4 + 76SE2 G KC=0.000181 3$LC=1.87E-5 3$MC=2.91E-6 5$NC=2.49E-7 4 + 76SE3 G IPC=4.22E-5 14 + 76SE G 1853.58 4 14.6 8(M1+E2) 1.0 2 3.34E-4 7 + 76SE2 G KC=1.022E-4 15$LC=1.053E-5 15$MC=1.638E-6 24$NC=1.404E-7 20 + 76SE3 G IPC=0.000219 6 + 76SE G 2510.61 4 1.92 12(M1+E2) 1.0 2 5.90E-411 + 76SE2 G KC=5.93E-5 9$LC=6.09E-6 9$MC=9.48E-7 14$NC=8.13E-8 12 + 76SE3 G IPC=0.000524 11 + 76SE G 3069.68 4 0.044 15 + 76SE L 3160.07 6 (2)+ + 76SE E 1.32 43.99 146.47 1 + 76SE2 E EAV=339 4$CK=0.6608 11$CL=0.0759 9$CM=0.0133 3 + 76SE3 E CN=0.00143 15 + 76SE G 490.19 7 0.333 23[E1] 8.72E-413 + 76SE2 G KC=0.000778 11$LC=8.09E-5 12$MC=1.258E-5 18$NC=1.070E-6 15 + 76SE G 504.75 7 0.229 15[E1] 8.11E-412 + 76SE2 G KC=0.000723 11$LC=7.53E-5 11$MC=1.170E-5 17$NC=9.95E-7 14 + 76SE G 730.98 6 0.58 8[E1] 3.44E-4 5 + 76SE2 G KC=0.000307 5$LC=3.18E-5 5$MC=4.95E-6 7$NC=4.22E-7 6 + 76SE G 1032.85 6 0.58 5 + 76SE G 1372.41 6 0.51 3 + 76SE G 1471.09 6 2.32 11M1+E2 1.0 2 2.45E-4 5 + 76SE2 G KC=1.592E-4 23$LC=1.647E-5 24$MC=2.56E-6 4$NC=2.19E-7 4 + 76SE3 G IPC=6.71E-5 20 + 76SE G 1943.89 6 0.47 9 + 76SE G 2600.92 6 0.69 3 + 76SE G 3160.00 6 0.141 15 + 76SE L 3268.8 4 (2,3,4)- + 76SE L 3351.54 7 (1,2)+ + 76SE E 1.00 48.0 46.07 + 76SE2 E EAV=256 4$CK=0.7816 13$CL=0.0899 11$CM=0.01573 36 + 76SE3 E CN=0.00169 18 + 76SE G 401.01 9 0.30 4(M1+E2) 1.0 2 0.0042 3 + 76SE2 G KC=0.0038 3$LC=0.00041 3$MC=0.000063 5$NC=5.3E-6 4 + 76SE G 681.66 8 0.429 23E1 4.01E-4 6 + 76SE2 G KC=0.000358 5$LC=3.71E-5 6$MC=5.77E-6 8$NC=4.92E-7 7 + 76SE G 696.22 8 0.496 23(E1) 3.83E-4 6 + 76SE2 G KC=0.000342 5$LC=3.54E-5 5$MC=5.51E-6 8$NC=4.70E-7 7 + 76SE G 836.88 7 0.45 4(M1+E2) + 76SE G 922.44 7 0.192 15 + 76SE G 1180.98 7 0.111 15 + 76SE G 1224.32 7 0.29 11(M1+E2) + 76SE G 1662.56 7 0.14 6 + 76SE G 2135.36 7 0.93 6(M1+E2) 1.0 2 4.38E-4 9 + 76SE2 G KC=7.89E-5 12$LC=8.12E-6 12$MC=1.262E-6 18$NC=1.083E-7 16 + 76SE3 G IPC=0.000349 8 + 76SE G 2229.22 7 0.10 7 + 76SE G 2792.38 7 5.6 3(M1+E2) 1.0 2 7.06E-413 + 76SE2 G KC=4.95E-5 7$LC=5.08E-6 8$MC=7.90E-7 12$NC=6.78E-8 10 + 76SE3 G IPC=0.000651 13 + 76SE G 3351.46 7 0.252 15 + 76SE L 3441.5 2 (1,2,3)+ + 76SE E 0.006 20.09 38 + 76SE2 E EAV=218 4$CK=0.8242 14$CL=0.0949 11$CM=0.01659 38 + 76SE3 E CN=0.00178 19 + 76SE G 281.4 2 0.044 23[M1+E2] 1.0 2 0.0127 13 + 76SE2 G KC=0.0113 12$LC=0.00125 14$MC=0.000194 21$NC=1.61E-5 17 + 76SE G 1270.9 200.059 23(M1+E2) + 76SE L 3459.40 8 (2)+ + 76SE E 0.108 91.81 156.65 1 + 76SE2 E EAV=210 4$CK=0.8297 14$CL=0.0955 11$CM=0.01670 38 + 76SE3 E CN=0.00179 19 + 76SE G 789.52 9 0.46 3(E1) 2.92E-4 4 + 76SE2 G KC=0.000261 4$LC=2.70E-5 4$MC=4.19E-6 6$NC=3.58E-7 5 + 76SE G 804.08 9 0.53 4(E1) 2.81E-4 4 + 76SE2 G KC=0.000251 4$LC=2.60E-5 4$MC=4.04E-6 6$NC=3.45E-7 5 + 76SE G 1030.30 8 0.56 6(E1) 1716E-724 + 76SE2 G KC=1.531E-4 22$LC=1.579E-5 23$MC=2.45E-6 4$NC=2.10E-7 3 + 76SE G 1288.84 8 0.052 23(E2) 2.64E-4 4 + 76SE2 G KC=0.000213 3$LC=2.21E-5 3$MC=3.44E-6 5$NC=2.94E-7 5 + 76SE3 G IPC=2.54E-5 4 + 76SE G 1671.73 8 0.170 15(M1+E2) + 76SE G 1770.42 8 0.200 23(M1+E2) + 76SE G 2900.24 8 0.27 10(M1+E2) + 76SE L 3556.46 8 (1,2)+ + 76SE E 0.040 41.53 86.67 + 76SE2 E EAV=169 4$CK=0.8567 15$CL=0.0987 12$CM=0.01735 39 + 76SE3 E CN=0.00185 19 + 76SE G 886.57 9 0.340 23 + 76SE G 901.13 9 0.17 5 + 76SE G 1429.24 8 0.06 3 + 76SE G 2340.27 8 0.09 4 + 76SE G 2997.30 8 0.955 24[M1+E2] 1.0 2 7.89E-414 + 76SE2 G KC=4.40E-5 7$LC=4.51E-6 7$MC=7.01E-7 10$NC=6.02E-8 9 + 76SE3 G IPC=0.000739 14 + 76SE L 3604.08 8 1,2+ + 76SE E 0.026 31.64 136.61 + 76SE2 E EAV=149 4$CK=0.8653 15$CL=0.0997 12$CM=0.01752 39 + 76SE3 E CN=0.00187 20 + 76SE G 934.19 9 0.052 15E1 2.07E-4 3 + 76SE2 G KC=0.000185 3$LC=1.91E-5 3$MC=2.97E-6 5$NC=2.54E-7 4 + 76SE G 2481.76 8 0.133 23 + 76SE G 3044.91 8 0.022 8(M1+E2) + 76SE G 3603.99 8 1.60 11[M1+E2] 1.0 2 1018E-617 + 76SE2 G KC=3.26E-5 5$LC=3.34E-6 5$MC=5.20E-7 8$NC=4.46E-8 7 + 76SE3 G IPC=0.000981 17 + 76SE L 3622.2 20 + 76SE E 0.005 20.36 117.3 + 76SE2 E EAV=142 4$CK=0.8670 15$CL=0.0999 12$CM=0.01756 39 + 76SE3 E CN=0.00187 20 + 76SE G 1193.1 200.10 5 + 76SE G 1834.6 200.19 10 + 76SE G 3063.0 200.074 23 + 76SE L 3669.5 10 + 76SE E 0.005 10.73 196.9 + 76SE2 E EAV=122 4$CK=0.8729 15$CL=0.1007 12$CM=0.01768 40 + 76SE3 E CN=0.00189 20 + 76SE G 210.1 100.044 15[M1+E2] 1.0 2 0.034 5 + 76SE2 G KC=0.030 4$LC=0.0034 5$MC=0.00053 7$NC=0.000043 6 + 76SE G 318 1 0.13 5[M1+E2] 1.0 2 0.0086 8 + 76SE2 G KC=0.0076 7$LC=0.00084 8$MC=0.000130 13$NC=1.08E-5 10 + 76SE G 599.8 100.42 17[M1+E2] 1.0 2 0.00137 6 + 76SE2 G KC=0.00122 5$LC=0.000129 6$MC=2.01E-5 9$NC=1.71E-6 7 + 76SE G 1881.9 100.13 5 + 76SE G 2547.2 100.006 4 + 76SE L 3913 1 + 76SE E 0.133 157.5 + 76SE2 E CK=0.8785 15$CL=0.1017 13$CM=0.0179 4$CN=0.0019 2 + 76SE G 1742.4 100.118 15 + 76SE G 3912.9 100.015 8 + 76SE L 3929.1 6 (1,2)+ + 76SE E 0.17 47.4 + 76SE2 E CK=0.8784 15$CL=0.1018 13$CM=0.0179 4$CN=0.0019 2 + 76SE G 1801.9 6 0.030 15 + 76SE G 2712.9 6 0.074 23 + 76SE G 3369.9 6 0.096 8 + 76SE G 3929.0 6 0.089 15 + 76SE L 3970.6 4 (1,2)+ + 76SE E 0.64 56.7 + 76SE2 E CK=0.8783 15$CL=0.1019 13$CM=0.0179 4$CN=0.0019 2 + 76SE G 1300.7 4 0.155 15(E1) 2.26E-4 4 + 76SE2 G KC=1.002E-4 14$LC=1.031E-5 15$MC=1.603E-6 23$NC=1.372E-7 20 + 76SE3 G IPC=1.141E-4 17 + 76SE G 1315.3 4 0.052 15(E1) 2.34E-4 4 + 76SE2 G KC=9.83E-5 14$LC=1.011E-5 15$MC=1.572E-6 22$NC=1.346E-7 19 + 76SE3 G IPC=1.237E-4 18 + 76SE G 2183.0 4 0.13 3(M1+E2) + 76SE G 2754.4 4 0.074 23(M1+E2) + 76SE G 3411.4 4 0.296 15(M1+E2) + 76SE G 3970.5 4 0.010 5 + 76SE L 3998.4 10 + 76SE E 0.42 46.9 + 76SE2 E CK=0.8783 15$CL=0.1019 13$CM=0.0179 4$CN=0.0019 2 + 76SE G 838.3 100.318 23 + 76SE G 2309.4 100.10 3 + 76SE L 4019.3 5 + 76SE E 0.36 77 + 76SE2 E CK=0.8782 15$CL=0.1020 13$CM=0.0179 4$CN=0.0019 2 + 76SE G 1504.6 5 0.09 4 + 76SE G 2688.3 5 0.36 4 + 76SE G 4019.2 5 0.059 15 + 76SE L 4064 4 + 76SE E 0.43 96.8 + 76SE2 E CK=0.8781 15$CL=0.1021 13$CM=0.0179 4$CN=0.0019 2 + 76SE G 605 4 0.22 8[M1+E2] 1.0 2 0.00134 6 + 76SE2 G KC=0.00120 5$LC=0.000127 6$MC=1.97E-5 9$NC=1.67E-6 7 + 76SE G 2848 4 0.15 5 + 76SE G 3505 4 0.037 15 + 76SE G 4064 4 0.022 8 + 76SE L 4084.3 2 (1,2)+ + 76SE E 0.50 46.7 + 76SE2 E CK=0.8780 15$CL=0.1021 13$CM=0.0179 4$CN=0.0019 2 + 76SE G 1429.0 2 0.192 23 + 76SE G 1655.2 2 0.118 23 + 76SE G 3525.1 2 0.178 15 + 76SE G 4084.2 2 0.015 8 + 76SE L 4173.1 9 (1,2)+ + 76SE E 0.200 157.1 + 76SE2 E CK=0.8777 15$CL=0.1024 13$CM=0.0180 4$CN=0.0019 2 + 76SE G 2045.9 9 0.178 15 + 76SE G 4173.0 9 0.021 8 + 76SE L 4199.6 4 (1,2)+ + 76SE E 0.36 46.8 + 76SE2 E CK=0.8776 15$CL=0.1025 13$CM=0.0180 4$CN=0.0019 2 + 76SE G 1039.5 4 0.044 15 + 76SE G 1770.5 4 0.044 15 + 76SE G 2412.0 4 0.030 8 + 76SE G 2983.4 4 0.09 3 + 76SE G 3640.4 4 0.155 15 + 76SE L 4210 1 + 76SE E 0.24 46.9 + 76SE2 E CK=0.8776 15$CL=0.1025 13$CM=0.0180 4$CN=0.0019 2 + 76SE G 281 1 0.118 23[M1+E2] 1.0 2 0.0128 14 + 76SE2 G KC=0.0113 12$LC=0.00125 14$MC=0.000195 21$NC=1.62E-5 17 + 76SE G 2082 1 0.12 4 + 76SE L 4215.5 2 (1,2)+ + 76SE E 0.61 36.5 + 76SE2 E CK=0.8775 15$CL=0.1025 13$CM=0.0180 4$CN=0.0019 2 + 76SE G 1560.2 2 0.444 23(E1) 3.81E-4 6 + 76SE2 G KC=7.38E-5 11$LC=7.58E-6 11$MC=1.178E-6 17$NC=1.009E-7 15 + 76SE3 G IPC=0.000299 5 + 76SE G 3093.1 2 0.163 15 + 76SE L 4328.7 10 + 76SE E 0.19 56.9 + 76SE2 E CK=0.8769 16$CL=0.1030 13$CM=0.0181 4$CN=0.0020 2 + 76SE G 309.4 4 0.14 5[M1+E2] 1.0 2 0.0094 9 + 76SE2 G KC=0.0083 8$LC=0.00091 9$MC=0.000142 14$NC=1.18E-5 12 + 76SE G 1060 1 0.044 23 + 76SE L 4416 2 + 76SE E 0.26 76.6 + 76SE2 E CK=0.8763 16$CL=0.1035 13$CM=0.0182 4$CN=0.0020 2 + 76SE G 812.1 8 0.14 5 + 76SE G 1901 2 0.12 5 + 76SE L 4436.9 10(1,2)+ + 76SE E 0.067 157.2 + 76SE2 E CK=0.8761 16$CL=0.1037 13$CM=0.0182 4$CN=0.0020 2 + 76SE G 3877.7 100.015 8 + 76SE G 4436.8 100.052 15 + 76SE L 4455.2 30 + 76SE E 0.007 28.1 + 76SE2 E CK=0.8760 16$CL=0.1038 13$CM=0.0183 4$CN=0.0020 2 + 76SE G 4454.9 300.0067 23 + 76SE L 4492 3 + 76SE E 0.052 157.2 + 76SE2 E CK=0.8756 16$CL=0.1041 13$CM=0.0183 4$CN=0.0020 2 + 76SE G 936 3 0.044 15 + 76SE G 4492 3 0.0059 23 + 76SE L 4605.8 7 (1,2)+ + 76SE E 0.56 125.9 + 76SE2 E CK=0.8738 16$CL=0.1055 13$CM=0.0186 4$CN=0.0020 2 + 76SE G 635.2 8 0.074 23(M1+E2) 1.0 2 0.00118 5 + 76SE2 G KC=0.00105 4$LC=0.000111 5$MC=1.73E-5 7$NC=1.47E-6 6 + 76SE G 1146.4 7 0.059 15(M1+E2) + 76SE G 1254.3 7 0.08 3(M1+E2) + 76SE G 1536.1 7 0.17 7(M1+E2) + 76SE G 1975.0 9 0.11 9 + 76SE G 4046.6 7 0.044 15(M1+E2) + 76SE G 4605.7 7 0.015 8 + 76SE L 4621.5 20 + 76SE E 0.21 46.3 + 76SE2 E CK=0.8735 16$CL=0.1058 13$CM=0.0187 4$CN=0.0020 2 + 76SE G 1461.4 200.13 3 + 76SE G 1990.7 210.08 3 + diff --git a/HEN_HOUSE/spectra/lnhb/C-11.txt b/HEN_HOUSE/spectra/lnhb/C-11.txt index cfdc51a84..cf87c5921 100644 --- a/HEN_HOUSE/spectra/lnhb/C-11.txt +++ b/HEN_HOUSE/spectra/lnhb/C-11.txt @@ -1,11 +1,9 @@ - 11B 11C EC DECAY (20.361 M) - 11B H TYP=Update$AUT=V. Chisté$CUT=01-NOV-2011$ - 11B 2 H TYP=Full$AUT=V. Chisté$CUT=30-MAR-2002$ - 11B C Evaluation history: Type=Update;Author=V. Chisté;Cutoff date=01-NOV-2011 - 11B 2C Type=Full;Author=V. Chisté;Cutoff date=30-MAR-2002 - 11C P 0.0 3/2- 20.361 M 23 1982.5 9 - 11B N 1.0 1.0 1 1.0 - 11B L 0 3/2- STABLE - 11B E 99.750 130.250 13 - 11B 2 E EAV=385.7 4$CK=0.9174 91$CL=0.0826 91$CO=0 0 - + 11B 11C EC DECAY (20.361 M) + 11B H TYP=UPD$AUT=V.CHISTE$CUT=01-NOV-2011$ + 11B 2 H TYP=FUL$AUT=V.CHISTE$CUT=30-MAR-2002$ + 11C P 0.0 3/2- 20.361 M 23 1982.5 9 + 11B N 1.0 1.0 1 1.0 + 11B L 0 3/2- STABLE + 11B E 99.750 130.250 13 + 11B 2 E EAV=385.7 4$CK=0.002294 23$CL=0.000207 23 + diff --git a/HEN_HOUSE/spectra/lnhb/C-14.txt b/HEN_HOUSE/spectra/lnhb/C-14.txt index 805f5e38f..660189c57 100644 --- a/HEN_HOUSE/spectra/lnhb/C-14.txt +++ b/HEN_HOUSE/spectra/lnhb/C-14.txt @@ -1,14 +1,12 @@ - 14N 14C B- DECAY (5700 Y) - 14N H TYP=Update$AUT=M.M. Bé$CUT=01-JAN-2012$ - 14N 2 H TYP=Full$AUT=V.P. Chechev$CUT=01-JAN-1998$ - 14N C Evaluation history: Type=Update;Author=M.M. Bé;Cutoff date=01-JAN-2012 - 14N 2C Type=Full;Author=V.P. Chechev;Cutoff date=01-JAN-1998 - 14N C References: 1952Je11, 1961Wa16, 1961Ma32, 1962Ol04, 1964Hu09, 1968Be47, - 14N 2C 1968Re22, 1972Em01, 1975Sm02, 1990Ho18, 1991Su09, 1995Wi20, 2000Ku25, - 14N 3C 2003Au03, 2012Au06, 2012Mo** - 14C P 0.0 0+ 5700 Y 30 156.476 4 - 14N N 1.0 1.0 1 1.0 - 14N L 0 1+ STABLE - 14N B 156.476 4 100 9.04 - 14N S B EAV=49.16 1 - + 14N 14C B- DECAY (5700 Y) + 14N H TYP=UPD$AUT=M.-M.BE$CUT=01-JAN-2012$ + 14N 2 H TYP=FUL$AUT=V.P.CHECHEV$CUT=01-JAN-1998$ + 14N C References:1952Je11, 1961Wa16, 1961Ma32, 1962Ol04, 1964Hu09, 1968Be47, + 14N 2C 1968Re22, 1972Em01, 1975Sm02, 1990Ho18, 1991Su09, 1995Wi20, 2000Ku25, + 14N 3C 2003Au03, 2012Au06, 2012Mo** + 14C P 0.0 0+ 5700 Y 30 156.476 4 + 14N N 1.0 1.0 1 1.0 + 14N L 0 1+ STABLE + 14N B 156.476 4 100 9.04 + 14N S B EAV=49.16 1 + diff --git a/HEN_HOUSE/spectra/lnhb/Ca-41.txt b/HEN_HOUSE/spectra/lnhb/Ca-41.txt index 214d42ac7..2e93190c7 100644 --- a/HEN_HOUSE/spectra/lnhb/Ca-41.txt +++ b/HEN_HOUSE/spectra/lnhb/Ca-41.txt @@ -1,33 +1,32 @@ - 41K 41CA EC DECAY (1.002E5 Y) - 41K H TYP=Full$AUT=X. Mougeot$CUT=31-JAN-2013$ - 41K C Evaluation history: Type=Full;Author=X. Mougeot;Cutoff date=31-JAN-2013 - 41K C References: 1950RI59, 1951BR94, 1951SA31, 1953BR71, 1962DR03, 1970SI24, - 41K 2C 1973MY03, 1973ZO03, 1974MA30, 1987HO16, 1988JA11, 1990FI13, 1991PA10, - 41K 3C 1991KL06, 1992KA05, 1996SC06, 2001CA59, 2006MUZX, 2008MO18, 2011AUZZ, - 41K 4C 2011BE53, 2012JO04 - 41K T Auger electrons and X ray energies and emission intensities: - 41K T {U Energy (keV)} {U Intensity} {U Line} - 41K T - 41K T 3.3111 3.82 12 XKA2 - 41K T 3.3138 7.56 23 XKA1 - 41K T - 41K T 3.5896 |] 1.40 5 XKB1 - 41K T 3.6028 |] XKB5II - 41K T - 41K T - 41K T 0.2604-0.3618 0.27 6 XL (total) - 41K T 0.2604 0.27 6 XLL - 41K T 0.263 XLC - 41K T 0.29654-0.3618 XLB - 41K T 0.29917-0.29917 XLG - 41K T - 41K T 2.615-2.985 |] KLL AUGER - 41K T 3.183-3.296 |] 76.6 9 KLX AUGER - 41K T 3.54-3.572 |] KXY AUGER - 41K T 0.226-0.342 156.76 11 L AUGER - 41CA P 0.0 7/2- 1.002E5 Y 17 421.63 14 - 41K N 1.0 1.0 1 1.0 - 41K L 0 3/2+ STABLE - 41K E 100 10.53 1U - 41K 2 E CK=0.894 9$CL=0.0916 9$CM=0.01482 15 - + 41K 41CA EC DECAY (1.002E5 Y) + 41K H TYP=FUL$AUT=X.MOUGEOT$CUT=31-JAN-2013$ + 41K C References:1950RI59, 1951BR94, 1951SA31, 1953BR71, 1962DR03, 1970SI24, + 41K 2C 1973MY03, 1973ZO03, 1974MA30, 1987HO16, 1988JA11, 1990FI13, 1991PA10, + 41K 3C 1991KL06, 1992KA05, 1996SC06, 2001Ca59, 2006MUZX, 2008MO18, 2011AUZZ, + 41K 4C 2011BE53, 2012JO04 + 41K T Auger electrons and X ray energies and emission intensities: + 41K T {U Energy (keV)} {U Intensity} {U Line} + 41K T + 41K T 3.3111 3.82 12 XKA2 + 41K T 3.3138 7.56 23 XKA1 + 41K T + 41K T 3.5896 |] 1.40 5 XKB1 + 41K T 3.6028 |] XKB5II + 41K T + 41K T + 41K T 0.2604-0.3618 0.27 6 XL (total) + 41K T 0.2604 0.27 6 XLL + 41K T 0.263 XLC + 41K T 0.29654-0.3618 XLB + 41K T 0.29917-0.29917 XLG + 41K T + 41K T 2.615-2.985 |] KLL AUGER + 41K T 3.183-3.296 |] 76.6 9 KLX AUGER + 41K T 3.54-3.572 |] KXY AUGER + 41K T 0.226-0.342 156.76 11 L AUGER + 41CA P 0.0 7/2- 1.002E5 Y 17 421.63 14 + 41K N 1.0 1.0 1 1.0 + 41K L 0 3/2+ STABLE + 41K E 100 10.53 1U + 41K 2 E CK=0.894 9$CL=0.0916 9$CM=0.01482 15 + diff --git a/HEN_HOUSE/spectra/lnhb/Ca-45.txt b/HEN_HOUSE/spectra/lnhb/Ca-45.txt index 07c4097b2..13dd16a70 100644 --- a/HEN_HOUSE/spectra/lnhb/Ca-45.txt +++ b/HEN_HOUSE/spectra/lnhb/Ca-45.txt @@ -1,19 +1,17 @@ - 45SC 45CA B- DECAY (162.64 D) - 45SC H TYP=Full$AUT=M.M.Bé$CUT=15-FEB-2012$ - 45SC2 H TYP=Full$AUT=F.Lagoutine$CUT= -- $ - 45SC C Evaluation history: Type=Full;Author=M.M.Bé;Cutoff date=15-FEB-2012 - 45SC2C Type=Full;Author=F.Lagoutine;Cutoff date= -- - 45SC C References: 1950Ma03, 1950Ke60, 1952Ca10, 1952De01, 1957Th11, 1959Ca12, - 45SC2C 1961Wy01, 1965An07, 1965Fr12, 1967Ha39, 1970Si24, 1994Lo04, 2003Au03, - 45SC3C 2008Ki07, 2012Mo**, 2012Au06 - 45CA P 0.0 7/2- 162.64 D 11 258.0 7 - 45SC N 1.0 1.0 1 1.0 - 45SC L 0 7/2- STABLE - 45SC B 258.0 7 99.9980 7 6 - 45SCS B EAV=76.8 7 - 45SC L 12.40 5 3/2+ 318 MS 7 - 45SC B 245.6 7 0.0020 7 10.3 1U - 45SCS B EAV=91.7 7 - 45SC G 12.40 5 M2 423 9 - 45SC2 G KC=362 8$LC=53.4 12$MC=6.63 15 - + 45SC 45CA B- DECAY (162.64 D) + 45SC H TYP=FUL$AUT=M.-M.BE$CUT=15-FEB-2012$ + 45SC2 H TYP=FUL$AUT=F.LAGOUTINE$CUT=30-JAN-1984$ + 45SC C References:1950Ma03, 1950Ke60, 1952Ca10, 1952De01, 1957Th11, 1959Ca12, + 45SC2C 1961Wy01, 1965An07, 1965Fr12, 1967Ha39, 1970Si24, 1994Lo04, 2003Au03, + 45SC3C 2008Ki07, 2012Mo**, 2012Au06 + 45CA P 0.0 7/2- 162.64 D 11 258.0 7 + 45SC N 1.0 1.0 1 1.0 + 45SC L 0 7/2- STABLE + 45SC B 258.0 7 99.9980 7 6 + 45SCS B EAV=76.8 7 + 45SC L 12.40 5 3/2+ 318 MS 7 + 45SC B 245.6 7 0.0020 7 10.3 1U + 45SCS B EAV=91.7 7 + 45SC G 12.40 5 M2 423 9 + 45SC2 G KC=362 8$LC=53.4 12$MC=6.63 15$NC=0.3 1 + diff --git a/HEN_HOUSE/spectra/lnhb/Cd-109.txt b/HEN_HOUSE/spectra/lnhb/Cd-109.txt index 0776a2bff..572a73421 100644 --- a/HEN_HOUSE/spectra/lnhb/Cd-109.txt +++ b/HEN_HOUSE/spectra/lnhb/Cd-109.txt @@ -1,49 +1,48 @@ -109AG 109CD EC DECAY (461.9 D) -109AG H TYP=Full$AUT=M.M. Bé$CUT=31-OCT-2014$ -109AG2 H TYP=update$AUT=M.M.Bé$CUT= -- $ -109AG C Evaluation history: Type=Full;Author=M.M. Bé;Cutoff date=31-OCT-2014 -109AG2C Type=update;Author=M.M.Bé;Cutoff date= -- -109AG C References: 1940Al01, 1941He01, 1945Wi11, 1947Br05, 1950Gu54, 1951Wo15, -109AG2C 1953br73, 1953De26, 1954Be41, 1957Wa05, 1964Bo12, 1965Le06, 1965Se08, -109AG3C 1965Mo06, 1967Mi11, 1966ja01, 1966Fr12, 1966Du01, 1967Pi05, 1967Sc22, -109AG4C 1967Li10, 1967Ab07, 1968Go25, 1968GoZY, 1968Ea01, 1968Re04, 1968Fo03, -109AG5C 1968Fu05, 1969Pl08, 1969HeZY, 1970Gr13, 1970Ra37, 1970ba37, 1970Go39, -109AG6C 1972Ca16, 1972Br02, 1973Co10, 1973Le29, 1975Ma32, 1976Dr07, 1977Va05, -109AG7C 1978Pr**, 1978Mo22, 1978Sh08, 1979Pl04, 1979Va04, 1980Da03, 1981Va11, -109AG8C 1982HoZJ, 1982La25, 1984Ma**, 1985Ho06, 1988Ba60, 1988Il01, 1989Hi01, -109AG9C 1989Eg**, 1989Ne**, 1992ScZZ, 1994Ra37, 1996Sc06, 1997Ma75, 2000He14, -109AG10C 2000Yo07, 2000Sc47, 2002Ba85, 2004Sc04, 2006Bl02, 2006Ko27, 2008Ki07, -109AG11C 2011va02, 2012Fi12, 2012Wa38, 2014Un01 -109AG T Auger electrons and X ray energies and emission intensities: -109AG T {U Energy (keV)} {U Intensity} {U Line} -109AG T -109AG T 21.9906 29.21 30 XKA2 -109AG T 22.16317 55.1 5 XKA1 -109AG T -109AG T 24.9118 |] XKB3 -109AG T 24.9427 |] 15.25 20 XKB1 -109AG T 25.146 |] XKB5II -109AG T -109AG T 25.4567 |] XKB2 -109AG T 25.512 |] 2.65 10 XKB4 -109AG T -109AG T 2.634-3.748 10.37 27 XL (total) -109AG T 2.634 0.221 9 XLL -109AG T 2.977-2.985 5.93 21 XLA -109AG T 2.807 0.0849 20 XLC -109AG T 3.151-3.438 3.76 10 XLB -109AG T 3.431-3.748 0.366 8 XLG -109AG T -109AG T 17.79-18.69 |] KLL AUGER -109AG T 20.945-22.16 |] 20.8 6 KLX AUGER -109AG T 24.079-25.507 |] KXY AUGER -109AG T 1.8-3.8 167.3 8 L AUGER -109CD P 0.0 5/2+ 461.9 D 4 215.5 18 -109AG N 1.0 1.0 1 1.0 -109AG L 0 1/2- STABLE -109AG L 88.0341 7/2+ 39.7 S 2 -109AG E 100 6 -109AG2 E CK=0.812 3$CL=0.150 3$CM=0.0321 9$CN=0.0064 4 -109AG G 88.0336 103.66 5E3 26.3 4 -109AG2 G KC=11.41 16$LC=12.06 17$MC=2.47 4 - +109AG 109CD EC DECAY (461.9 D) +109AG H TYP=FUL$AUT=M.-M.BE$CUT=31-OCT-2014$ +109AG2 H TYP=UPD$AUT=M.-M.BE$CUT=12-FEB-2013$ +109AG C References:1940Al01, 1941He01, 1945Wi11, 1947Br05, 1950Gu54, 1951Wo15, +109AG2C 1953br73, 1953De26, 1954Be41, 1957Wa05, 1964Bo12, 1965Le06, 1965Se08, +109AG3C 1965Mo06, 1967Mi11, 1966ja01, 1966Fr12, 1966Du01, 1967Pi05, 1967Sc22, +109AG4C 1967Li10, 1967Ab07, 1968Go25, 1968GoZY, 1968Ea01, 1968Re04, 1968Fo03, +109AG5C 1968Fu05, 1969Pl08, 1969HeZY, 1970Gr13, 1970Ra37, 1970ba37, 1970Go39, +109AG6C 1972Ca16, 1972Br02, 1973Co10, 1973Le29, 1975Ma32, 1976Dr07, 1977Va05, +109AG7C 1978Pr**, 1978Mo22, 1978Sh08, 1979Pl04, 1979Va04, 1980Da03, 1981Va11, +109AG8C 1982HoZJ, 1982La25, 1984Ma**, 1985Ho06, 1988Ba60, 1988Il01, 1989Hi01, +109AG9C 1989Eg**, 1989Ne**, 1992ScZZ, 1994Ra37, 1996Sc06, 1997Ma75, 2000He14, +109AGAC 2000Yo07, 2000Sc47, 2002Ba85, 2004Sc04, 2006Bl02, 2006Ko27, 2008Ki07, +109AGBC 2011va02, 2012Fi12, 2012Wa38, 2014Un01 +109AG T Auger electrons and X ray energies and emission intensities: +109AG T {U Energy (keV)} {U Intensity} {U Line} +109AG T +109AG T 21.9906 29.21 30 XKA2 +109AG T 22.16317 55.1 5 XKA1 +109AG T +109AG T 24.9118 |] XKB3 +109AG T 24.9427 |] 15.25 20 XKB1 +109AG T 25.146 |] XKB5II +109AG T +109AG T 25.4567 |] XKB2 +109AG T 25.512 |] 2.65 10 XKB4 +109AG T +109AG T 2.634-3.748 10.37 27 XL (total) +109AG T 2.634 0.221 9 XLL +109AG T 2.977-2.985 5.93 21 XLA +109AG T 2.807 0.0849 20 XLC +109AG T 3.151-3.438 3.76 10 XLB +109AG T 3.431-3.748 0.366 8 XLG +109AG T +109AG T 17.79-18.69 |] KLL AUGER +109AG T 20.945-22.16 |] 20.8 6 KLX AUGER +109AG T 24.079-25.507 |] KXY AUGER +109AG T 1.8-3.8 167.3 8 L AUGER +109CD P 0.0 5/2+ 461.9 D 4 215.5 18 +109AG N 1.0 1.0 1 1.0 +109AG L 0 1/2- STABLE +109AG L 88.0341 7/2+ 39.7 S 2 +109AG E 100 6 +109AG2 E CK=0.812 3$CL=0.150 3$CM=0.0321 9$CN=0.0064 4 +109AG G 88.0336 103.66 5E3 26.3 4 +109AG2 G KC=11.41 16$LC=12.06 17$MC=2.47 4$NC=0.386 6 +109AG3 G OC=0.001398 20 + diff --git a/HEN_HOUSE/spectra/lnhb/Ce-139.txt b/HEN_HOUSE/spectra/lnhb/Ce-139.txt index 380b91e4c..b62a5f911 100644 --- a/HEN_HOUSE/spectra/lnhb/Ce-139.txt +++ b/HEN_HOUSE/spectra/lnhb/Ce-139.txt @@ -1,38 +1,39 @@ -139LA 139CE EC DECAY (137.641 D) -139LA C References: 1968Va08, 1968Ad08, 1975Mo12, 1975Da08, 1977Sc38, 1978SeZS, -139LA2C 1987BeYL, 1988KoZM, 1998Si17, 2001Sc08, 2003Au03, 2005KiZW -139LA T Auger electrons and X ray energies and emission intensities: -139LA T {U Energy (keV)} {U Intensity} {U Line} -139LA T -139LA T 33.0344 22.80 24 XKA2 -139LA T 33.4421 41.9 4 XKA1 -139LA T -139LA T 37.7206 |] XKB3 -139LA T 37.8015 |] 12.47 18 XKB1 -139LA T 38.084 |] XKB5II -139LA T -139LA T 38.7303 |] XKB2 -139LA T 38.828 |] 3.16 8 XKB4 -139LA T 38.91 |] XKO23 -139LA T -139LA T 4.117-6.072 12.19 18 XL (total) -139LA T 4.117 0.222 6 XLL -139LA T 4.634-4.65 5.70 13 XLA -139LA T 4.525 0.0842 21 XLC -139LA T 5.041-5.381 5.27 9 XLB -139LA T 5.62-6.072 0.903 16 XLG -139LA T -139LA T 26.24-27.795 |] KLL AUGER -139LA T 31.231-33.428 |] 8.4 4 KLX AUGER -139LA T 36.2-38.9 |] KXY AUGER -139LA T 2.7-6.2 90.1 6 L AUGER -139CE P 0.0 3/2+ 137.641 D 20 270 3 -139LA N 1.0 1.0 1 1.0 -139LA L 0 7/2+ STABLE -139LA E 0.008 10.6 2 -139LA L 165.8576 115/2+ 1.499 NS 19 -139LA E 99.9973 275.42 -139LA2 E CK=0.716 7$CL=0.217 5$CM=0.0669 18 -139LA G 165.8575 1179.90 4M1 0.2516 7 -139LA2 G KC=0.2146 10$LC=0.0288 6$MC=0.0060 2 - +139LA 139CE EC DECAY (137.641 D) +139LA C References:1968Va08, 1968Ad08, 1975Mo12, 1975Da08, 1977Sc38, 1978SeZS, +139LA2C 1987BeYL, 1988KoZM, 1998Si17, 2001Sc08, 2003Au03, 2005KiZW +139LA T Auger electrons and X ray energies and emission intensities: +139LA T {U Energy (keV)} {U Intensity} {U Line} +139LA T +139LA T 33.0344 22.80 24 XKA2 +139LA T 33.4421 41.9 4 XKA1 +139LA T +139LA T 37.7206 |] XKB3 +139LA T 37.8015 |] 12.47 18 XKB1 +139LA T 38.084 |] XKB5II +139LA T +139LA T 38.7303 |] XKB2 +139LA T 38.828 |] 3.16 8 XKB4 +139LA T 38.91 |] XKO23 +139LA T +139LA T 4.117-6.072 12.19 18 XL (total) +139LA T 4.117 0.222 6 XLL +139LA T 4.634-4.65 5.70 13 XLA +139LA T 4.525 0.0842 21 XLC +139LA T 5.041-5.381 5.27 9 XLB +139LA T 5.62-6.072 0.903 16 XLG +139LA T +139LA T 26.24-27.795 |] KLL AUGER +139LA T 31.231-33.428 |] 8.4 4 KLX AUGER +139LA T 36.2-38.9 |] KXY AUGER +139LA T 2.7-6.2 90.1 6 L AUGER +139CE P 0.0 3/2+ 137.641 D 20 270 3 +139LA N 1.0 1.0 1 1.0 +139LA L 0 7/2+ STABLE +139LA E 0.008 10.6 2 +139LA2 E CK=0.8162 17$CL=0.1433 12$CM=0.0326 6$CN=0.0079 4 +139LA L 165.8576 115/2+ 1.499 NS 19 +139LA E 99.9973 275.42 +139LA2 E CK=0.716 7$CL=0.217 5$CM=0.0669 18 +139LA G 165.8575 1179.90 4M1 0.2516 7 +139LA2 G KC=0.2146 10$LC=0.0288 6$MC=0.0060 2 + diff --git a/HEN_HOUSE/spectra/lnhb/Ce-141.txt b/HEN_HOUSE/spectra/lnhb/Ce-141.txt index a3ccbaacf..f47944308 100644 --- a/HEN_HOUSE/spectra/lnhb/Ce-141.txt +++ b/HEN_HOUSE/spectra/lnhb/Ce-141.txt @@ -1,46 +1,45 @@ -141PR 141CE B- DECAY (32.503 D) -141PR H TYP=Update$AUT=V.P. Chechev$CUT=01-FEB-2012$ -141PR2 H TYP=Full$AUT=E. Schönfeld$CUT=01-JUN-1998$ -141PR C Evaluation history: Type=Update;Author=V.P. Chechev;Cutoff date=01-FEB-2012 -141PR2C Type=Full;Author=E. Schönfeld;Cutoff date=01-JUN-1998 -141PR C References: 1949Wa23, 1950Fr58, 1957Ke26, 1961Ne12, 1962Sc11, 1963Ha07, -141PR2C 1965An07, 1966El02, 1967Ob01, 1971De11, 1971Ba28, 1972Em01, 1973MeYE, -141PR3C 1975Le09, 1976Va30, 1977La19, 1979Ha09, 1979Ha21, 1980Sc07, 1980RuZY, -141PR4C 1983Wa26, 1992Sc24, 1992Un01, 1996Sc06, 2000He14, 2000Sc47, 2001Tu01, -141PR5C 2002Ba85, 2002Un02, 2008Ki07, 2012Au06 -141PR T Auger electrons and X ray energies and emission intensities: -141PR T {U Energy (keV)} {U Intensity} {U Line} -141PR T -141PR T 35.5506 4.80 9 XKA2 -141PR T 36.0267 8.76 15 XKA1 -141PR T -141PR T 40.6533 |] XKB3 -141PR T 40.7487 |] 2.67 6 XKB1 -141PR T 41.05 |] XKB5II -141PR T -141PR T 41.774 |] XKB2 -141PR T 41.877 |] 0.682 20 XKB4 -141PR T 41.968 |] XKO23 -141PR T -141PR T 4.458-6.617 2.52 5 XL (total) -141PR T 4.458 0.0485 15 XLL -141PR T 5.0129-5.0343 1.23 4 XLA -141PR T 4.9337 0.0187 6 XLC -141PR T 5.4887-5.9032 1.054 23 XLB -141PR T 6.1375-6.617 0.169 4 XLG -141PR T -141PR T 28.162-29.89 |] KLL AUGER -141PR T 33.576-36.004 |] 1.59 8 KLX AUGER -141PR T 38.97-41.95 |] KXY AUGER -141PR T 2.94-6.79 16.15 11 L AUGER -141CE P 0.0 7/2- 32.503 D 11 580.4 11 -141PR N 1.0 1.0 1 1.0 -141PR L 0 0 5/2+ STABLE -141PR B 580.4 1130.03 44 7.76 1 -141PRS B EAV=180.8 6 -141PR L 145.4434 147/2+ -141PR B 435.0 1169.97 44 6.97 -141PRS B EAV=129.7 5 -141PR G 145.4433 1448.29 19M1+E2 0.068 5 0.449 7 -141PR2 G KC=0.383 6$LC=0.0529 8$MC=0.01116 16 - +141PR 141CE B- DECAY (32.503 D) +141PR H TYP=UPD$AUT=V.P.CHECHEV$CUT=01-FEB-2012$ +141PR2 H TYP=FUL$AUT=E.SCHONFELD$CUT=01-JUN-1998$ +141PR C References:1949Wa23, 1950Fr58, 1957Ke26, 1961Ne12, 1962Sc11, 1963Ha07, +141PR2C 1965An07, 1966El02, 1967Ob01, 1971De11, 1971Ba28, 1972Em01, 1973MeYE, +141PR3C 1975Le09, 1976Va30, 1977La19, 1979Ha09, 1979Ha21, 1980Sc07, 1980RuZY, +141PR4C 1983Wa26, 1992Sc24, 1992Un01, 1996Sc06, 2000He14, 2000Sc47, 2001Tu01, +141PR5C 2002Ba85, 2002Un02, 2008Ki07, 2012Au06 +141PR T Auger electrons and X ray energies and emission intensities: +141PR T {U Energy (keV)} {U Intensity} {U Line} +141PR T +141PR T 35.5506 4.80 9 XKA2 +141PR T 36.0267 8.76 15 XKA1 +141PR T +141PR T 40.6533 |] XKB3 +141PR T 40.7487 |] 2.67 6 XKB1 +141PR T 41.05 |] XKB5II +141PR T +141PR T 41.774 |] XKB2 +141PR T 41.877 |] 0.682 20 XKB4 +141PR T 41.968 |] XKO23 +141PR T +141PR T 4.458-6.617 2.52 5 XL (total) +141PR T 4.458 0.0485 15 XLL +141PR T 5.0129-5.0343 1.23 4 XLA +141PR T 4.9337 0.0187 6 XLC +141PR T 5.4887-5.9032 1.054 23 XLB +141PR T 6.1375-6.617 0.169 4 XLG +141PR T +141PR T 28.162-29.89 |] KLL AUGER +141PR T 33.576-36.004 |] 1.59 8 KLX AUGER +141PR T 38.97-41.95 |] KXY AUGER +141PR T 2.94-6.79 16.15 11 L AUGER +141CE P 0.0 7/2- 32.503 D 11 580.4 11 +141PR N 1.0 1.0 1 1.0 +141PR L 0 5/2+ STABLE +141PR B 580.4 1130.03 44 7.76 1 +141PRS B EAV=180.8 6 +141PR L 145.4434 147/2+ +141PR B 435.0 1169.97 44 6.97 +141PRS B EAV=129.7 5 +141PR G 145.4433 1448.29 19M1+E2 0.068 5 0.449 7 +141PR2 G KC=0.383 6$LC=0.0529 8$MC=0.01116 16$NC=0.00249 4 +141PR3 G OC=0.000401 6 + diff --git a/HEN_HOUSE/spectra/lnhb/Ce-144.txt b/HEN_HOUSE/spectra/lnhb/Ce-144.txt index 884c193d9..21d74b8f1 100644 --- a/HEN_HOUSE/spectra/lnhb/Ce-144.txt +++ b/HEN_HOUSE/spectra/lnhb/Ce-144.txt @@ -1,67 +1,73 @@ -144PR 144CE B- DECAY (284.89 D) -144PR H TYP=FUL$AUT=A.L.Nichols$CUT=01-MAR-2014$ -144PR C Evaluation history: Type=FUL;Author=A.L.Nichols;Cutoff date=01-MAR-2014 -144PR C References: 1954Kr40, 1954Em09, 1954Co60, 1956Pu24, 1956Sc87, 1957Pa51, -144PR2C 1957Me47, 1958Hi76, 1959Se57, 1959Fr54, 1960Ea02, 1960Ge05, 1960Sa22, -144PR3C 1961Ge09, 1962Bu22, 1962Fo04, 1962Bu09, 1962Bl05, 1963Cr11, 1963Kn05, -144PR4C 1963Si10, 1963Fu16, 1963Co18, 1963Bh11, 1963Iw02, 1964Az02, 1964Mc22, -144PR5C 1964Be36, 1965Fl02, 1965Re13, 1965Co19, 1966Da04, 1966Be11, 1967Gu17, -144PR6C 1968La10, 1968Re04, 1968Da12, 1969Ge01, 1969Gu15, 1969Ma24, 1970Fa03, -144PR7C 1970Po09, 1970An15, 1971Sa20, 1975Ba32, 1975De17, 1976Ra22, 1976Ch33, -144PR8C 1977Ge12, 1977La19, 1978Mo22, 1979Bo26, 1980Ho17, 1981Ol04, 1982Yu02, -144PR9C 1983El04, 1983Wa26, 1984Da13, 1986Ol01, 1992Un01, 1996Sc06, 1997Ma75, -144PR10C 1998ScZM, 1999ScZX, 2000Sc47, 2001So16, 2002Un02, 2002Ra45, 2002Ba85, -144PR11C 2008Ki07, 2012Wa38, 2012Fi12, 2014Un01 -144PR T Auger electrons and X ray energies and emission intensities: -144PR T {U Energy (keV)} {U Intensity} {U Line} -144PR T -144PR T 35.5506 2.41 5 XKA2 -144PR T 36.0267 4.40 9 XKA1 -144PR T -144PR T 40.6533 |] XKB3 -144PR T 40.7487 |] 1.34 3 XKB1 -144PR T 41.05 |] XKB5II -144PR T -144PR T 41.774 |] XKB2 -144PR T 41.877 |] 0.343 10 XKB4 -144PR T 41.968 |] XKO23 -144PR T -144PR T 4.453-6.617 1.54 4 XL (total) -144PR T 4.453 0.0282 9 XLL -144PR T 5.013-5.033 0.711 21 XLA -144PR T 4.929 0.0107 4 XLC -144PR T 5.489-5.851 0.673 15 XLB -144PR T 6.327-6.617 0.116 3 XLG -144PR T -144PR T 28.162-29.89 |] KLL AUGER -144PR T 33.576-36.004 |] 0.80 4 KLX AUGER -144PR T 38.97-41.95 |] KXY AUGER -144PR T 2.9-4.91 9.88 10 L AUGER -144CE P 0.0 0+ 284.89 D 6 318.6 8 -144PR N 1.0 1.0 1.00 1 1.0 -144PR L 0 0- 17.29 M 4 -144PR B 318.6 8 76.9 3 7.424 -144PRS B EAV=91.3 3 -144PR L 59.03 3 3- 7.2 M 2 -144PR G 59.03 3 0.00094 19M3 1221 18 -144PR2 G KC=408 6$LC=618 9$MC=155.0 23 -144PR L 80.120 4 1- 136 PS 11 -144PR B 238.5 8 3.9 2 8.33 1 -144PRS B EAV=66.24 25 -144PR G 80.120 4 1.40 5M1 2.45 4 -144PR2 G KC=2.08 3$LC=0.288 4$MC=0.0608 9 -144PR L 99.952 9 2- 0.67 NS 6 -144PR G 40.92 3 0.32 5M1 2.61 4 -144PR2 G LC=2.06 3$MC=0.434 7 -144PR G 99.952 9 0.041 2E2 2.12 3 -144PR2 G KC=1.214 17$LC=0.71 1$MC=0.1599 23 -144PR L 133.5152 201- 7 PS 4 -144PR B 185.1 8 19.2 1 7.27 1 -144PRS B EAV=50.29 24 -144PR G 33.563 9 0.225 11M1 4.69 7 -144PR2 G LC=3.70 6$MC=0.780 11 -144PR G 53.395 5 0.101 5M1 7.94 12 -144PR2 G KC=6.75 10$LC=0.942 14$MC=0.199 3 -144PR G 133.5152 2010.83 12M1 0.571 8 -144PR2 G KC=0.486 7$LC=0.0668 10$MC=0.01408 20 - +144PR 144CE B- DECAY (284.89 D) +144PR H TYP=FUL$AUT=A.L.NICHOLS$CUT=01-MAR-2014$ +144PR C References:1954Kr40, 1954Em09, 1954Co60, 1956Pu24, 1956Sc87, 1957Pa51, +144PR2C 1957Me47, 1958Hi76, 1959Se57, 1959Fr54, 1960Ea02, 1960Ge05, 1960Sa22, +144PR3C 1961Ge09, 1962Bu22, 1962Fo04, 1962Bu09, 1962Bl05, 1963Cr11, 1963Kn05, +144PR4C 1963Si10, 1963Fu16, 1963Co18, 1963Bh11, 1963Iw02, 1964Az02, 1964Mc22, +144PR5C 1964Be36, 1965Fl02, 1965Re13, 1965Co19, 1966Da04, 1966Be11, 1967Gu17, +144PR6C 1968La10, 1968Re04, 1968Da12, 1969Ge01, 1969Gu15, 1969Ma24, 1970Fa03, +144PR7C 1970Po09, 1970An15, 1971Sa20, 1975Ba32, 1975De17, 1976Ra22, 1976Ch33, +144PR8C 1977Ge12, 1977La19, 1978Mo22, 1979Bo26, 1980Ho17, 1981Ol04, 1982Yu02, +144PR9C 1983El04, 1983Wa26, 1984Da13, 1986Ol01, 1992Un01, 1996Sc06, 1997Ma75, +144PRAC 1998ScZM, 1999ScZX, 2000Sc47, 2001So16, 2002Un02, 2002Ra45, 2002Ba85, +144PRBC 2008Ki07, 2012Wa38, 2012Fi12, 2014Un01 +144PR T Auger electrons and X ray energies and emission intensities: +144PR T {U Energy (keV)} {U Intensity} {U Line} +144PR T +144PR T 35.5506 2.41 5 XKA2 +144PR T 36.0267 4.40 9 XKA1 +144PR T +144PR T 40.6533 |] XKB3 +144PR T 40.7487 |] 1.34 3 XKB1 +144PR T 41.05 |] XKB5II +144PR T +144PR T 41.774 |] XKB2 +144PR T 41.877 |] 0.343 10 XKB4 +144PR T 41.968 |] XKO23 +144PR T +144PR T 4.453-6.617 1.54 4 XL (total) +144PR T 4.453 0.0282 9 XLL +144PR T 5.013-5.033 0.711 21 XLA +144PR T 4.929 0.0107 4 XLC +144PR T 5.489-5.851 0.673 15 XLB +144PR T 6.327-6.617 0.116 3 XLG +144PR T +144PR T 28.162-29.89 |] KLL AUGER +144PR T 33.576-36.004 |] 0.80 4 KLX AUGER +144PR T 38.97-41.95 |] KXY AUGER +144PR T 2.9-4.91 9.88 10 L AUGER +144CE P 0.0 0+ 284.89 D 6 318.6 8 +144PR N 1.0 1.0 1.00 11.0 +144PR L 0 0- 17.29 M 4 +144PR B 318.6 8 76.9 3 7.424 +144PRS B EAV=91.3 3 +144PR L 59.03 3 3- 7.2 M 2 +144PR G 59.03 3 0.00094 19M3 1221 18 +144PR2 G KC=408 6$LC=618 9$MC=155.0 23$NC=34.7 5 +144PR3 G OC=5.03 8 +144PR L 80.120 4 1- 136 PS 11 +144PR B 238.5 8 3.9 2 8.33 1 +144PRS B EAV=66.24 25 +144PR G 80.120 4 1.40 5M1 2.45 4 +144PR2 G KC=2.08 3$LC=0.288 4$MC=0.0608 9$NC=0.01359 19 +144PR3 G OC=0.00219 3 +144PR L 99.952 9 2- 0.67 NS 6 +144PR G 40.92 3 0.32 5M1 2.61 4 +144PR2 G LC=2.06 3$MC=0.434 7$NC=0.0971 14 +144PR3 G OC=0.01559 22 +144PR G 99.952 9 0.041 2E2 2.12 3 +144PR2 G KC=1.214 17$LC=0.71 1$MC=0.1599 23$NC=0.0346 5 +144PR3 G OC=0.00483 7 +144PR L 133.5152 201- 7 PS 4 +144PR B 185.1 8 19.2 1 7.27 1 +144PRS B EAV=50.29 24 +144PR G 33.563 9 0.225 11M1 4.69 7 +144PR2 G LC=3.70 6$MC=0.780 11$NC=0.1744 25 +144PR3 G OC=0.0280 4 +144PR G 53.395 5 0.101 5M1 7.94 12 +144PR2 G KC=6.75 10$LC=0.942 14$MC=0.199 3$NC=0.0444 7 +144PR3 G OC=0.00713 10 +144PR G 133.5152 2010.83 12M1 0.571 8 +144PR2 G KC=0.486 7$LC=0.0668 10$MC=0.01408 20$NC=0.00315 5 +144PR3 G OC=0.000507 7 + diff --git a/HEN_HOUSE/spectra/lnhb/Cf-252.txt b/HEN_HOUSE/spectra/lnhb/Cf-252.txt index 2b46a30bb..5cb7aa4a8 100644 --- a/HEN_HOUSE/spectra/lnhb/Cf-252.txt +++ b/HEN_HOUSE/spectra/lnhb/Cf-252.txt @@ -1,51 +1,53 @@ -248CM 252CF A DECAY (2.6470 Y) -248CM H TYP=Full$AUT=M.M. Bé$CUT=23-OCT-2007$ -248CM C Evaluation history: Type=Full;Author=M.M. Bé;Cutoff date=23-OCT-2007 -248CM C References: 1955As42, 1963Bj03, 1965Me02, 1969De23, 1970Ba18, 1970Al23, -248CM2C 1971Ba10, 1971Wa28, 1971Ha**, 1973Mi05, 1974Sp02, 1974Sh15, 1976BaZZ, -248CM3C 1976Mo30, 1982La25, 1983Al**, 1984Di08, 1984SmZV, 1985Wi14, 1985Ax**, -248CM4C 1986Ry04, 1987Sh**, 1988Ke**, 1990Po24, 1991Ry01, 1992Sh33, 1993Pa29, -248CM5C 1994KhZW, 1996Sc33, 1999Ak02, 1999Ba03, 2003Au03, 2005KiZW -248CM T Auger electrons and X ray energies and emission intensities: -248CM T {U Energy (keV)} {U Intensity} {U Line} -248CM T -248CM T 104.59 2.57E-5 7 XKA2 -248CM T 109.271 4.02E-5 11 XKA1 -248CM T -248CM T 122.304 |] XKB3 -248CM T 123.403 |] 1.51E-5 5 XKB1 -248CM T 124.124 |] XKB5II -248CM T -248CM T 126.889 |] XKB2 -248CM T 127.352 |] 5.30E-6 19 XKB4 -248CM T 127.97 |] XKO23 -248CM T -248CM T 12.634-23.319 6.07 14 XL (total) -248CM T 12.634 0.146 5 XLL -248CM T 14.744-14.96 2.25 7 XLA -248CM T 17.315 0.0644 24 XLC -248CM T 17.288-20.515 2.90 9 XLB -248CM T 21.969-23.319 0.702 21 XLG -248CM T -248CM T 78.858-89.973 |] KLL AUGER -248CM T 97.226-109.267 |] 2.5E-6 4 KLX AUGER -248CM T 115.57-128.23 |] KXY AUGER -248CM T 6.3-24.5 5.02 13 L AUGER -252CF P 0.0 0+ 2.6470 Y 26 6216.87 4 -248CM N 1.032E0 1.032E0 0.96914 1.032E0 -248CM L 0 0+ 348E3 Y 6 -248CM A 6118.1 1 84.30 311 -248CM L 43.40 3 2+ 124 PS 5 -248CM A 6075.64 1115.58 313.2 -248CM G 43.399 250.0152 4E2 1000 15 -248CM2 G LC=724 11$MC=204 3 -248CM L 143.6 4 4+ 78 PS 22 -248CM A 5976.6 0.237 4165 -248CM G 100.2 4 0.0119 20E2 18.5 5 -248CM2 G LC=13.4 4$MC=3.79 9 -248CM L 298.1 5 6+ 33 PS 8 -248CM A 5826.3 19605E-7 1200 -248CM G 154.5 6 0.00051 E2 2.76 6 -248CM2 G KC=0.1741 25$LC=1.87 5$MC=0.526 12 -248CM L 505.0 5 8+ - +248CM 252CF A DECAY (2.6470 Y) +248CM H TYP=FUL$AUT=M.-M.BE$CUT=23-OCT-2007$ +248CM C References:1955As42, 1963Bj03, 1965Me02, 1969De23, 1970Ba18, 1970Al23, +248CM2C 1971Ba10, 1971Wa28, 1971Ha**, 1973Mi05, 1974Sp02, 1974Sh15, 1976BaZZ, +248CM3C 1976Mo30, 1982La25, 1983Al**, 1984Di08, 1984SmZV, 1985Wi14, 1985Ax**, +248CM4C 1986Ry04, 1987Sh**, 1988Ke**, 1990Po24, 1991Ry01, 1992Sh33, 1993Pa29, +248CM5C 1994KhZW, 1996Sc33, 1999Po**, 1999Ak02, 1999Ba03, 2003Au03, 2005KiZW +248CM T Auger electrons and X ray energies and emission intensities: +248CM T {U Energy (keV)} {U Intensity} {U Line} +248CM T +248CM T 104.59 2.57E-5 7 XKA2 +248CM T 109.271 4.02E-5 11 XKA1 +248CM T +248CM T 122.304 |] XKB3 +248CM T 123.403 |] 1.51E-5 5 XKB1 +248CM T 124.124 |] XKB5II +248CM T +248CM T 126.889 |] XKB2 +248CM T 127.352 |] 5.30E-6 19 XKB4 +248CM T 127.97 |] XKO23 +248CM T +248CM T 12.634-23.319 6.07 14 XL (total) +248CM T 12.634 0.146 5 XLL +248CM T 14.744-14.96 2.25 7 XLA +248CM T 17.315 0.0644 24 XLC +248CM T 17.288-20.515 2.90 9 XLB +248CM T 21.969-23.319 0.702 21 XLG +248CM T +248CM T 78.858-89.973 |] KLL AUGER +248CM T 97.226-109.267 |] 2.5E-6 4 KLX AUGER +248CM T 115.57-128.23 |] KXY AUGER +248CM T 6.3-24.5 5.02 13 L AUGER +252CF P 0.0 0+ 2.6470 Y 26 6216.87 4 +248CM N 1.032E0 1.032E0 0.96914 +248CM L 0 0+ 348E3 Y 6 +248CM A 6118.1 1 84.30 311 +248CM L 43.40 3 2+ 124 PS 5 +248CM A 6075.64 1115.58 313.2 +248CM G 43.399 250.0152 4E2 1000 15 +248CM2 G LC=724 11$MC=204 3$NC=56.7 8 +248CM3 G OC=13.7 2 +248CM L 143.6 4 4+ 78 PS 22 +248CM A 5976.6 0.237 4165 +248CM G 100.2 4 0.0119 20E2 18.5 5 +248CM2 G LC=13.4 4$MC=3.79 9$NC=1.054 25 +248CM3 G OC=0.255 6 +248CM L 298.1 5 6+ 33 PS 8 +248CM A 5826.3 19605E-7 1200 +248CM G 154.5 6 0.00051 E2 2.76 6 +248CM2 G KC=0.1741 25$LC=1.87 5$MC=0.526 12$NC=0.146 4 +248CM3 G OC=0.0356 8 +248CM L 505.0 5 8+ + diff --git a/HEN_HOUSE/spectra/lnhb/Cl-36.txt b/HEN_HOUSE/spectra/lnhb/Cl-36.txt index 908403cac..f2d0b255c 100644 --- a/HEN_HOUSE/spectra/lnhb/Cl-36.txt +++ b/HEN_HOUSE/spectra/lnhb/Cl-36.txt @@ -1,55 +1,51 @@ - 36S 36CL EC DECAY (302E3 Y) - 36S H TYP=Update$AUT=M.M. Bé$CUT=15-JAN-2012$ - 36S 2 H TYP=Full$AUT=V.P. Chechev$CUT=30-APR-1998$ - 36S C Evaluation history: Type=Update;Author=M.M. Bé;Cutoff date=15-JAN-2012 - 36S 2C Type=Full;Author=V.P. Chechev;Cutoff date=30-APR-1998 - 36S C References: 1949Wu15, 1955Dr35, 1955Ba93, 1957Wr37, 1962Do07, 1962Be29, - 36S 2C 1963Ba38, 1965To05, 1966Go07, 1967Pi04, 1976Lj03, 1977La19, 2012Mo** - 36S T Auger electrons and X ray energies and emission intensities: - 36S T {U Energy (keV)} {U Intensity} {U Line} - 36S T - 36S T 2.3066 0.044 3 XKA2 - 36S T 2.3078 0.086 5 XKA1 - 36S T - 36S T 2.457 |] XKB3 - 36S T |] 0.008 1 XKB1 - 36S T - 36S T - 36S T - 36S T 1.98-2.12 |] KLL AUGER - 36S T 2.22-2.3 |] 1.58 9 KLX AUGER - 36S T 2.44-2.46 |] KXY AUGER - 36S T - 0.163 12 L AUGER - 36CL P 0.0 2+ 302E3 Y 4 1142.14 19 - 36S N 5.263E1 5.263E1 0.019 1 5.263E1 - 36S L 0 0+ STABLE - 36S E 0.00157 301.9 113.5 2 - 36S 2 E EAV=54 4$CK=0.904 5$CL=0.086 4$CM=0.010 1 - - 36AR 36CL B- DECAY (302E3 Y) - 36AR H TYP=Update$AUT=M.M. Bé$CUT=15-JAN-2012$ - 36AR2 H TYP=Full$AUT=V.P. Chechev$CUT=30-APR-1998$ - 36AR C Evaluation history: Type=Update;Author=M.M. Bé;Cutoff date=15-JAN-2012 - 36AR2C Type=Full;Author=V.P. Chechev;Cutoff date=30-APR-1998 - 36AR C References: 1949Wu15, 1955Dr35, 1955Ba93, 1957Wr37, 1962Do07, 1962Be29, - 36AR2C 1963Ba38, 1965To05, 1966Go07, 1967Pi04, 1976Lj03, 1977La19, 2012Mo** - 36AR T Auger electrons and X ray energies and emission intensities: - 36AR T {U Energy (keV)} {U Intensity} {U Line} - 36AR T - 36AR T 2.9553 0.0062 10 XKA2 - 36AR T 2.9577 0.0123 19 XKA1 - 36AR T - 36AR T 3.1905 |] XKB3 - 36AR T |] 0.0020 3 XKB1 - 36AR T - 36AR T - 36AR T - 36AR T 2.511-2.669 |] KLL AUGER - 36AR T 2.831-2.942 |] 0.13 2 KLX AUGER - 36AR T 3.149-3.174 |] KXY AUGER - 36CL P 0.0 2+ 302E3 Y 4 709.55 5 - 36AR N 1.019E0 1.019E0 0.981 1 1.019E0 - 36AR L 0 0+ STABLE - 36AR B 709.53 5 98.1 1 13.3 2 - 36ARS B EAV=316 16 - + 36S 36CL EC DECAY (302E3 Y) + 36S H TYP=UPD$AUT=M.-M.BE$CUT=15-JAN-2012$ + 36S 2 H TYP=FUL$AUT=V.P.CHECHEV$CUT=30-APR-1998$ + 36S C References:1949Wu15, 1955Dr35, 1955Ba93, 1957Wr37, 1962Do07, 1962Be29, + 36S 2C 1963Ba38, 1965To05, 1966Go07, 1967Pi04, 1976Lj03, 1977La19, 2012Mo** + 36S T Auger electrons and X ray energies and emission intensities: + 36S T {U Energy (keV)} {U Intensity} {U Line} + 36S T + 36S T 2.3066 0.044 3 XKA2 + 36S T 2.3078 0.086 5 XKA1 + 36S T + 36S T 2.457 |] XKB3 + 36S T |] 0.008 1 XKB1 + 36S T + 36S T + 36S T + 36S T 1.98-2.12 |] KLL AUGER + 36S T 2.22-2.3 |] 1.58 9 KLX AUGER + 36S T 2.44-2.46 |] KXY AUGER + 36S T - 0.163 12 L AUGER + 36CL P 0.0 2+ 302E3 Y 4 1142.14 19 + 36S N 5.263E1 5.263E1 0.019 15.263E1 + 36S L 0 0+ STABLE + 36S E 0.00157 301.9 113.5 2 + 36S 2 E EAV=54 4$CK=0.9033 50$CL=0.0859 40$CM=0.010 1 + + 36AR 36CL B- DECAY (302E3 Y) + 36AR H TYP=UPD$AUT=M.-M.BE$CUT=15-JAN-2012$ + 36AR2 H TYP=FUL$AUT=V.P.CHECHEV$CUT=30-APR-1998$ + 36AR C References:1949Wu15, 1955Dr35, 1955Ba93, 1957Wr37, 1962Do07, 1962Be29, + 36AR2C 1963Ba38, 1965To05, 1966Go07, 1967Pi04, 1976Lj03, 1977La19, 2012Mo** + 36AR T Auger electrons and X ray energies and emission intensities: + 36AR T {U Energy (keV)} {U Intensity} {U Line} + 36AR T + 36AR T 2.9553 0.0062 10 XKA2 + 36AR T 2.9577 0.0123 19 XKA1 + 36AR T + 36AR T 3.1905 |] XKB3 + 36AR T |] 0.0020 3 XKB1 + 36AR T + 36AR T + 36AR T + 36AR T 2.511-2.669 |] KLL AUGER + 36AR T 2.831-2.942 |] 0.13 2 KLX AUGER + 36AR T 3.149-3.174 |] KXY AUGER + 36CL P 0.0 2+ 302E3 Y 4 709.55 5 + 36AR N 1.019E0 1.019E0 0.981 11.019E0 + 36AR L 0 0+ STABLE + 36AR B 709.53 5 98.1 1 13.3 2 + 36ARS B EAV=316 16 + diff --git a/HEN_HOUSE/spectra/lnhb/Cm-242.txt b/HEN_HOUSE/spectra/lnhb/Cm-242.txt index ecbce4068..2986c58f4 100644 --- a/HEN_HOUSE/spectra/lnhb/Cm-242.txt +++ b/HEN_HOUSE/spectra/lnhb/Cm-242.txt @@ -1,121 +1,140 @@ -238PU 242CM A DECAY (162.86 D) -238PU H TYP=Update$AUT=Chechev$CUT= -- $ -238PU2 H TYP=Full$AUT=Chechev$CUT=01-SEP-2005$ -238PU C Evaluation history: Type=Update;Author=Chechev;Cutoff date= -- -238PU2C Type=Full;Author=Chechev;Cutoff date=01-SEP-2005 -238PU C References: 1950Ha14, 1951Ha87, 1952Du12, 1953As14, 1954Gl37, 1954Hu32, -238PU2C 1956Ba95, 1956Sm18, 1958Ko87, 1960As10, 1963Le17, 1963Dz07, 1965Ak02, -238PU3C 1965Fl02, 1966Ba07, 1967Ar09, 1967Be65, 1970By01, 1971Gr17, 1971Po09, -238PU4C 1972Wi22, 1972Ah04, 1971Bb10, 1975Ke02, 1977Di04, 1979Ch41, 1980Di13, -238PU5C 1981Le15, 1981Us03, 1982Ag02, 1982Ba56, 1982Ra33, 1982UmZZ, 1984Wi14, -238PU6C 1986LoZT, 1986Ze06, 1989Us04, 1990Po14, 1991Ry01, 1995Jo23, 1996Sc06, -238PU7C 1998Ya17, 2000Ho27, 2002Ch52, 2003Au03, 2006Ch34, 2008Ki07 -238PU T Auger electrons and X ray energies and emission intensities: -238PU T {U Energy (keV)} {U Intensity} {U Line} -238PU T -238PU T 99.525 0.000082 9 XKA2 -238PU T 103.734 0.00013015 XKA1 -238PU T -238PU T 116.244 |] XKB3 -238PU T 117.228 |] 0.000048 6 XKB1 -238PU T 117.918 |] XKB5II -238PU T -238PU T 120.54 |] XKB2 -238PU T 120.969 |] 1.65E-5 19 XKB4 -238PU T 121.543 |] XKO23 -238PU T -238PU T 12.12-23.07 9.92 23 XL (total) -238PU T 12.12 0.243 8 XLL -238PU T 14.087-14.282 3.79 11 XLA -238PU T 16.333 0.103 4 XLC -238PU T 16.5-19.33 4.69 14 XLB -238PU T 20.71-23.07 1.09 4 XLG -238PU T -238PU T 75.2-85.3 |] KLL AUGER -238PU T 92.6-103.6 |] 8.2E-6 15 KLX AUGER -238PU T 109.8-121.5 |] KXY AUGER -238PU T 6.19-22.99 8.99 21 L AUGER -242CM P 0.0 0+ 162.86 D 8 6215.56 8 -238PU N 1.0 1.0 1 1.0 -238PU L 0 0+ 87.74 Y 3 -238PU A 6112.72 8 74.06 7 1 -238PU L 44.08 3 2+ 177 PS 5 -238PU A 6069.37 9 25.94 7 1.733 -238PU G 44.08 3 0.0330 7E2 787 16 -238PU2 G LC=572 12$MC=159.4 32 -238PU L 146.00 5 4+ -238PU A 5969.24 9 0.034 2 390 -238PU G 101.92 4 0.00251 14E2 14.45 21 -238PU2 G LC=10.48 21$MC=2.94 6 -238PU L 303.42 7 6+ -238PU A 5816.39 110.0046 5 458 -238PU G 157.42 9 0.00145 16[E2] 2.19 4 -238PU2 G KC=0.193 4$LC=1.450 29$MC=0.405 8 -238PU L 513.62 168+ -238PU A 5607.76 160.00002 7500 -238PU G 210.20 140.000012 E2 0.710 14 -238PU2 G KC=0.140 3$LC=0.415 8$MC=0.115 2 -238PU L 605.08 7 1- -238PU A 5517.75 110.00025 5 183 -238PU G 561.02 100.00015 4E1 0.0115323 -238PU2 G KC=0.00929 18$LC=0.00169 3$MC=4.07E-4 8 -238PU G 605.04 100.00010530E1 0.0099920 -238PU2 G KC=0.00806 16$LC=0.00146 3$MC=3.50E-4 7 -238PU L 661.28 113- -238PU A 5462.47 1413000E-93 1700 -238PU G 515.25 194.5E-6 12E1+M2 0.114 17 0.022 3 -238PU2 G KC=0.0175 21$LC=0.0037 6$MC=0.00092 14 -238PU G 617.20 127.9E-6 21E1+M2 0.077 17 0.0120 12 -238PU2 G KC=0.0095 9$LC=0.00185 22$MC=0.00045 6 -238PU L 763.22 5- -238PU A 5366.22 1522000E-1 24000 -238PU G 459.8 2 6E-8 3 -238PU G 617.22 131.6E-7 -238PU L 941.44 9 0+ -238PU A 5186.95 1235000E-97 12 -238PU G 336.36 157E-7 3[E1] 0.0323 6 -238PU2 G KC=0.0257 5$LC=0.00502 10$MC=0.00122 2 -238PU G 897.33 100.000022 6(E2) 0.0152 3 -238PU2 G KC=0.01108 22$LC=0.00308 6$MC=7.78E-4 15 -238PU G 941.5 2 -238PU L 962.72 8 1- -238PU A 5165.95 1611300E-121278 -238PU G 357.64 7 4.5E-8 9M1+E2 2.43 20 0.214 15 -238PU2 G KC=0.133 12$LC=0.0599 17$MC=0.0158 4 -238PU G 918.7 2 5.4E-7 15E1 0.00469 9 -238PU2 G KC=0.00382 8$LC=6.63E-4 13$MC=1.58E-4 3 -238PU G 962.8 2 5.3E-7 15E1 0.00432 8 -238PU2 G KC=0.00352 7$LC=6.09E-4 12$MC=1452E-7 29 -238PU L 983.00 9 2+ -238PU A 5146.07 1217000E-15 137 -238PU G 837.01 151.9E-7 6[E2] 0.0174 3 -238PU2 G KC=0.01250 25$LC=0.00366 7$MC=9.30E-4 19 -238PU G 938.91 101.8E-7 6+E2 4.4 4 -238PU G 983.0 3 5.0E-7 18[E2] 0.0127625 -238PU2 G KC=0.00946 18$LC=0.00246 5$MC=6.19E-4 12 -238PU L 1018.6 3 1- -238PU A 5111.1 3 20000E-1 700 -238PU G 974.5 3 2E-7 -238PU L 1028.62 5 2+ -238PU A 5101.21 1037000E-11032 -238PU G 882.63 3 6.7E-8 15(E2) 0.0157 3 -238PU2 G KC=0.01141 23$LC=0.00321 6$MC=8.11E-4 16 -238PU G 984.5 1 2.0E-6 6M1+E2 23 0.0127926 -238PU2 G KC=0.00949 19$LC=0.00247 5$MC=6.19E-4 12 -238PU G 1028.5 2 1.6E-6 5E2 0.0117123 -238PU2 G KC=0.00875 17$LC=0.00221 4$MC=5.54E-4 11 -238PU L 1125.79 17(4)+ -238PU A 5005.64 1931000E-11088 -238PU G 979.8 2 2.6E-7 8 -238PU G 1081.7 3 5E-8 2 -238PU L 1228.69 220+ -238PU A 4904.44 2355000E-11510 -238PU G 1184.6 3 5.0E-7 15E2 0.0089918 -238PU2 G KC=0.00685 14$LC=0.00160 3$MC=3.97E-4 8 -238PU G 1228.7 3 -238PU L 1264.29 222+ -238PU A 4869.43 2352000E-1146 -238PU G 1118.3 3 1.7E-7 9[E2] 0.0100120 -238PU2 G KC=0.00757 15$LC=0.00182 3$MC=4.54E-4 9 -238PU G 1220.2 3 2.8E-7 9+E2+(M1) 0.26 3 - +238PU 242CM A DECAY (162.86 D) +238PU H TYP=UPD$AUT=V.P.CHECHEV$CUT=15-OCT-2009$ +238PU2 H TYP=FUL$AUT=V.P.CHECHEV$CUT=01-SEP-2005$ +238PU C References:1950Ha14, 1951Ha87, 1952Du12, 1953As14, 1954Gl37, 1954Hu32, +238PU2C 1956Ba95, 1956Sm18, 1957Tr**, 1958Ko87, 1960As10, 1963Le17, 1963Dz07, +238PU3C 1965Ak02, 1965Fl02, 1966Ba07, 1967Ar09, 1967Be65, 1970By01, 1971Gr17, +238PU4C 1971Po09, 1971Sw**, 1972Wi22, 1972Ah04, 1971Bb10, 1975Ke02, 1977Di04, +238PU5C 1979Ch41, 1980Di13, 1980Ja**, 1981Le15, 1981Us03, 1982Ag02, 1982Ba56, +238PU6C 1982Ra33, 1982UmZZ, 1984Wi14, 1986LoZT, 1986Ze06, 1989Us04, 1990Po14, +238PU7C 1991Ry01, 1995Jo23, 1996Sc06, 1998Ya17, 1999Sc**, 2000Ho27, 2000Sc**, +238PU8C 2002Ch52, 2003Au03, 2006Ch34, 2008Ki07 +238PU T Auger electrons and X ray energies and emission intensities: +238PU T {U Energy (keV)} {U Intensity} {U Line} +238PU T +238PU T 99.525 0.000082 9 XKA2 +238PU T 103.734 0.00013015 XKA1 +238PU T +238PU T 116.244 |] XKB3 +238PU T 117.228 |] 0.000048 6 XKB1 +238PU T 117.918 |] XKB5II +238PU T +238PU T 120.54 |] XKB2 +238PU T 120.969 |] 1.65E-5 19 XKB4 +238PU T 121.543 |] XKO23 +238PU T +238PU T 12.12-23.07 9.92 23 XL (total) +238PU T 12.12 0.243 8 XLL +238PU T 14.087-14.282 3.79 11 XLA +238PU T 16.333 0.103 4 XLC +238PU T 16.5-19.33 4.69 14 XLB +238PU T 20.71-23.07 1.09 4 XLG +238PU T +238PU T 75.2-85.3 |] KLL AUGER +238PU T 92.6-103.6 |] 8.2E-6 15 KLX AUGER +238PU T 109.8-121.5 |] KXY AUGER +238PU T 6.19-22.99 8.99 21 L AUGER +242CM P 0.0 0+ 162.86 D 8 6215.56 8 +238PU N 1.0 1.0 1 +238PU L 0 0+ 87.74 Y 3 +238PU A 6112.72 8 74.06 71 +238PU L 44.08 3 2+ 177 PS 5 +238PU A 6069.37 9 25.94 71.733 +238PU G 44.08 3 0.0330 7E2 787 16 +238PU2 G LC=572 12$MC=159.4 32$NC=43.8 8 +238PU3 G OC=10.29 20 +238PU L 146.00 5 4+ +238PU A 5969.24 9 0.034 2390 +238PU G 101.92 4 0.00251 14E2 14.45 21 +238PU2 G LC=10.48 21$MC=2.94 6$NC=0.807 16 +238PU3 G OC=0.190 4 +238PU L 303.42 7 6+ +238PU A 5816.39 110.0046 5458 +238PU G 157.42 9 0.00145 16[E2] 2.19 4 +238PU2 G KC=0.193 4$LC=1.450 29$MC=0.405 8$NC=0.111 2 +238PU3 G OC=0.0263 5 +238PU L 513.62 168+ +238PU A 5607.76 160.00002 7500 +238PU G 210.20 140.000012 E2 0.710 14 +238PU2 G KC=0.140 3$LC=0.415 8$MC=0.115 2$NC=0.0316 6 +238PU3 G OC=0.00749 15 +238PU L 605.08 7 1- +238PU A 5517.75 110.00025 5183 +238PU G 561.02 100.00015 4E1 0.0115323 +238PU2 G KC=0.00929 18$LC=0.00169 3$MC=0.000407 8$NC=0.000110 22 +238PU3 G OC=2.71E-5 5 +238PU G 605.04 100.00010530E1 0.0099920 +238PU2 G KC=0.00806 16$LC=0.00146 3$MC=0.000350 7$NC=9.46E-5 19 +238PU3 G OC=2.33E-5 5 +238PU L 661.28 113- +238PU A 5462.47 140.000013 31700 +238PU G 515.25 194.5E-6 12E1+M2 0.114 17 0.022 3 +238PU2 G KC=0.0175 21$LC=0.0037 6$MC=0.00092 14$NC=0.00025 4 +238PU3 G OC=0.000062 10 +238PU G 617.20 127.9E-6 21E1+M2 0.077 17 0.0120 12 +238PU2 G KC=0.0095 9$LC=0.00185 22$MC=0.00045 6$NC=0.000122 15 +238PU3 G OC=0.000030 4 +238PU L 763.22 5- +238PU A 5366.22 152.2E-7 24000 +238PU G 459.8 2 6E-8 3 +238PU G 617.22 131.6E-7 +238PU L 941.44 9 0+ +238PU A 5186.95 120.000035 712 +238PU G 336.36 157E-7 3[E1] 0.0323 6 +238PU2 G KC=0.0257 5$LC=0.00502 10$MC=0.00122 2$NC=0.000328 7 +238PU3 G OC=8.04E-5 16 +238PU G 897.33 100.000022 6(E2) 0.0152 3 +238PU2 G KC=0.01108 22$LC=0.00308 6$MC=0.000778 15$NC=0.000212 4 +238PU3 G OC=5.18E-5 10 +238PU G 941.5 2 E0 +238PU L 962.72 8 1- +238PU A 5165.95 161.13E-6 21278 +238PU G 357.64 7 4.5E-8 9M1+E2 2.43 20 0.214 15 +238PU2 G KC=0.133 12$LC=0.0599 17$MC=0.0158 4$NC=0.00432 11 +238PU3 G OC=0.00104 3 +238PU G 918.7 2 5.4E-7 15E1 0.00469 9 +238PU2 G KC=0.00382 8$LC=0.000663 13$MC=0.000158 3$NC=4.28E-5 8 +238PU3 G OC=1.058E-5 21 +238PU G 962.8 2 5.3E-7 15E1 0.00432 8 +238PU2 G KC=0.00352 7$LC=0.000609 12$MC=1.452E-4 29$NC=3.93E-5 8 +238PU3 G OC=9.72E-6 19 +238PU L 983.00 9 2+ +238PU A 5146.07 121.7E-6 5137 +238PU G 837.01 151.9E-7 6[E2] 0.0174 3 +238PU2 G KC=0.01250 25$LC=0.00366 7$MC=0.000930 19$NC=0.000254 5 +238PU3 G OC=6.20E-5 12 +238PU G 938.91 101.8E-7 6E0+E2 4.4 4 +238PU G 983.0 3 5.0E-7 18[E2] 0.0127625 +238PU2 G KC=0.00946 18$LC=0.00246 5$MC=0.000619 12$NC=0.000169 3 +238PU3 G OC=4.13E-5 8 +238PU L 1018.6 3 1- +238PU A 5111.1 3 2E-7 700 +238PU G 974.5 3 2E-7 +238PU L 1028.62 5 2+ +238PU A 5101.21 103.7E-6 1032 +238PU G 882.63 3 6.7E-8 15(E2) 0.0157 3 +238PU2 G KC=0.01141 23$LC=0.00321 6$MC=0.000811 16$NC=0.000221 4 +238PU3 G OC=5.41E-5 11 +238PU G 984.5 1 2.0E-6 6M1+E2 23 0.0127926 +238PU2 G KC=0.00949 19$LC=0.00247 5$MC=0.000619 12$NC=0.000169 3 +238PU3 G OC=4.13E-5 8 +238PU G 1028.5 2 1.6E-6 5E2 0.0117123 +238PU2 G KC=0.00875 17$LC=0.00221 4$MC=0.000554 11$NC=0.000151 3 +238PU3 G OC=3.70E-5 7 +238PU L 1125.79 17(4)+ +238PU A 5005.64 193.1E-7 1088 +238PU G 979.8 2 2.6E-7 8 +238PU G 1081.7 3 5E-8 2 +238PU L 1228.69 220+ +238PU A 4904.44 235.5E-7 1510 +238PU G 1184.6 3 5.0E-7 15E2 0.0089918 +238PU2 G KC=0.00685 14$LC=0.00160 3$MC=0.000397 8$NC=1.081E-4 21 +238PU3 G OC=2.66E-5 6 +238PU G 1228.7 3 E0 +238PU L 1264.29 222+ +238PU A 4869.43 235.2E-7 146 +238PU G 1118.3 3 1.7E-7 9[E2] 0.0100120 +238PU2 G KC=0.00757 15$LC=0.00182 3$MC=0.000454 9$NC=1.236E-4 25 +238PU3 G OC=3.04E-5 6 +238PU G 1220.2 3 2.8E-7 9E0+E2+(M1) 0.26 3 + diff --git a/HEN_HOUSE/spectra/lnhb/Cm-243.txt b/HEN_HOUSE/spectra/lnhb/Cm-243.txt index 41329ec3c..c98496780 100644 --- a/HEN_HOUSE/spectra/lnhb/Cm-243.txt +++ b/HEN_HOUSE/spectra/lnhb/Cm-243.txt @@ -1,196 +1,212 @@ -243AM 243CM EC DECAY (28.9 Y) -243AM H TYP=Full$AUT=V.P. Chechev$CUT=30-OCT-2010$ -243AM C Evaluation history: Type=Full;Author=V.P. Chechev;Cutoff date=30-OCT-2010 -243AM C References: 1950Th52, 1953As14, 1953As40, 1955Sc08, 1956Ne17, 1957As70, -243AM2C 1957As83, 1958Ch38, 1959Ew90, 1962Iv01, 1963Le17, 1963Dz07, 1964Ba31, -243AM3C 1964Hy02, 1965Ma17, 1966Ba07, 1970By01, 1971Bb10, 1972Po04, 1972Ah02, -243AM4C 1972Kr07, 1973Ah04, 1976BaZZ, 1977VaZW, 1979Bo30, 1982Ah04, 1986Ti03, -243AM5C 1987Po19, 1990Si12, 1991Ry01, 2003Au03, 2003Br12, 2004Ak21, 2005Tr08, -243AM6C 2008BeZV, 2008Ki07, 2009KoZV -243AM T Auger electrons and X ray energies and emission intensities: -243AM T {U Energy (keV)} {U Intensity} {U Line} -243AM T -243AM T 102.03 XKA2 -243AM T 106.472 XKA1 -243AM T -243AM T 119.243 |] XKB3 -243AM T 120.284 |] XKB1 -243AM T 120.989 |] XKB5II -243AM T -243AM T 123.58 |] XKB2 -243AM T 124.127 |] XKB4 -243AM T 124.723 |] XKO23 -243AM T -243AM T -243AM T 77.04-85.638 |] KLL AUGER -243AM T 94.891-106.467 |] KLX AUGER -243AM T 112.72-124.97 |] KXY AUGER -243AM T 6.26-23.7 L AUGER -243CM P 0.0 5/2+ 28.9 Y 4 7.5 17 -243AM N 3.448E2 3.448E2 0.0029 3 3.448E2 -243AM G 640 -243AM G 680 -243AM G 720 -243AM G 740 -243AM G 760 -243AM L 0 5/2- 7367 Y 23 -243AM E 0.29 37.2 -243AM2 E CM=0.12 12$CN=0.64 15 - -239PU 243CM A DECAY (28.9 Y) -239PU H TYP=Full$AUT=V.P. Chechev$CUT=30-OCT-2010$ -239PU C Evaluation history: Type=Full;Author=V.P. Chechev;Cutoff date=30-OCT-2010 -239PU C References: 1950Th52, 1953As14, 1953As40, 1955Sc08, 1956Ne17, 1957As70, -239PU2C 1957As83, 1958Ch38, 1959Ew90, 1962Iv01, 1963Le17, 1963Dz07, 1964Ba31, -239PU3C 1964Hy02, 1965Ma17, 1966Ba07, 1970By01, 1971Bb10, 1972Po04, 1972Ah02, -239PU4C 1972Kr07, 1973Ah04, 1976BaZZ, 1977VaZW, 1979Bo30, 1982Ah04, 1986Ti03, -239PU5C 1987Po19, 1990Si12, 1991Ry01, 2003Au03, 2003Br12, 2004Ak21, 2005Tr08, -239PU6C 2008BeZV, 2008Ki07, 2009KoZV -239PU T Auger electrons and X ray energies and emission intensities: -239PU T {U Energy (keV)} {U Intensity} {U Line} -239PU T -239PU T 99.525 13.34 28 XKA2 -239PU T 103.734 21.1 5 XKA1 -239PU T -239PU T 116.244 |] XKB3 -239PU T 117.228 |] 7.75 21 XKB1 -239PU T 117.918 |] XKB5II -239PU T -239PU T 120.54 |] XKB2 -239PU T 120.969 |] 2.69 8 XKB4 -239PU T 121.543 |] XKO23 -239PU T -239PU T 12.1246-21.9844 52.1 16 XL (total) -239PU T 12.1246 1.40 6 XLL -239PU T 14.0834-14.2791 21.8 8 XLA -239PU T 16.334 0.418 26 XLC -239PU T 16.4987-18.5427 23.2 9 XLB -239PU T 20.7081-21.9844 5.30 22 XLG -239PU T -239PU T 75.263-85.357 |] KLL AUGER -239PU T 92.607-103.729 |] 1.34 19 KLX AUGER -239PU T 109.93-121.78 |] KXY AUGER -239PU T 6.19-22.99 49.3 15 L AUGER -243CM P 0.0 5/2+ 28.9 Y 4 6168.8 10 -239PU N 1.003E0 1.003E0 0.9971 3 1.003E0 -239PU G 640 -239PU G 680 -239PU G 720 -239PU G 740 -239PU G 760 -239PU L 0 1/2+ 24100 Y 11 -239PU A 6067.2 101.3 2 2210 -239PU L 7.861 2 3/2+ 36 PS 3 -239PU A 6059.4 104.41 20593 -239PU G 7.861 2 0.015 M1+E2 0.055 3 5.7E3 4 -239PU2 G MC=4.2E3 3 -239PU L 57.275 2 5/2+ 101 PS 5 -239PU A 6010.8 101.05 121410 -239PU G 49.414 2 0.2 M1+E2 0.50 3 126 8 -239PU2 G LC=92 6$MC=24.8 17 -239PU G 57.273 4 0.06 E2 222 4 -239PU2 G LC=161.1 23$MC=45.0 7 -239PU L 75.705 3 7/2+ 83 PS 8 -239PU A 5992.7 105.72 20209 -239PU G 18.430 4 0.0001 (M1+E2) 8E3 6 -239PU2 G MC=6E3 6 -239PU G 67.841 7 0.20 5E2 98.5 14 -239PU2 G LC=71.5 10$MC=20.0 3 -239PU L 163.76 3 9/2+ 73 PS 4 -239PU A 5906.1 1010029E-5 4230 -239PU G 88.06 3 0.0018 M1+E2 0.5 12.26 18 -239PU2 G LC=9.07 13$MC=2.36 4 -239PU G 106.47 4 0.015 E2 11.80 17 -239PU2 G LC=8.56 12$MC=2.40 4 -239PU L 192.8 1011/2+ -239PU A 5877.6 1470204E-5 427 -239PU G 117.1 100.08 [E2] 7.6 4 -239PU2 G LC=5.52 24$MC=1.54 7 -239PU L 285.460 2 5/2+ 1.12 NS 5 -239PU A 5786.4 1073.61 401.32 -239PU G 209.753 2 3.29 10M1+E2 -0.019 15 3.24 5 -239PU2 G KC=2.56 4$LC=0.511 8$MC=0.1241 18 -239PU G 228.183 2 10.6 3M1+E2 0.009 6 2.56 4 -239PU2 G KC=2.02 3$LC=0.403 6$MC=0.0979 14 -239PU G 277.599 2 14.0 4M1+E2 0.165 2 1.448 21 -239PU2 G KC=1.142 16$LC=0.230 4$MC=0.0560 8 -239PU G 285.460 2 0.73 2E2 0.247 4 -239PU2 G KC=0.0843 12$LC=0.1190 17$MC=0.0326 5 -239PU L 330.124 4 7/2+ -239PU A 5742.5 1011.33 204.94 -239PU G 44.663 5 0.131 16M1+E2 0.24 4 96 13 -239PU2 G LC=72 9$MC=18 3 -239PU G 166.39 6 0.016 7M1 6.22 9 -239PU2 G KC=4.91 7$LC=0.984 14$MC=0.239 4 -239PU G 254.40 3 0.11 1M1+E2 -0.159 6 1.85 3 -239PU2 G KC=1.457 21$LC=0.294 5$MC=0.0716 10 -239PU G 272.87 9 0.08 1M1+E2 0.165 9 1.518 22 -239PU2 G KC=1.198 18$LC=0.241 4$MC=0.0588 9 -239PU G 322.3 2 0.007 1[E2] 0.1699 24 -239PU2 G KC=0.0679 10$LC=0.0745 11$MC=0.0203 3 -239PU L 387.42 2 9/2+ -239PU A 5686.1 101.6 1 17 -239PU G 57.30 2 0.08 [M1] 28.6 4 -239PU2 G LC=21.5 3$MC=5.24 8 -239PU G 101.96 2 0.008 E2 14.42 21 -239PU2 G LC=10.46 15$MC=2.93 5 -239PU G 311.7 2 0.017 2M1+E2 0.1 1 1.06 3 -239PU2 G KC=0.84 3$LC=0.168 4$MC=0.0408 8 -239PU L 391.584 3 7/2- 193 NS 4 -239PU A 5682 1 20058E-5 129 -239PU G 4.16 2 E1 -239PU G 61.460 2 0.0151 13E1 0.473 7 -239PU2 G LC=0.354 5$MC=0.0881 13 -239PU G 106.125 2 0.296 25E1(+M2) -0.007 7 0.26 4 -239PU2 G LC=0.19 3$MC=0.050 8 -239PU G 315.880 3 0.018 2E1(+M2) 0.008 8 0.0372 9 -239PU2 G KC=0.0294 6$LC=0.00583 16$MC=0.00141 4 -239PU G 334.310 3 0.024 2E1(+M2) 0.006 6 0.0329 6 -239PU2 G KC=0.0261 5$LC=0.00511 10$MC=1238E-6 24 -239PU L 427 3 + -239PU A 5647 3 30087E-6 549 -239PU L 434 3 9/2- -239PU A 5640 3 14041E-5 108 -239PU L 451 5 + -239PU A 5624 5 60175E-6 202 -239PU L 462 3 11/2+ -239PU A 5613 3 30087E-6 351 -239PU L 469.8 4 1/2- -239PU A 5605.1 1110029E-6 951 -239PU G 461.9 5 E1+M2 -239PU G 469.8 5 E1 -239PU L 481 3 + -239PU A 5594 3 10029E-6 823 -239PU L 487 3 11/2- -239PU A 5588 3 20058E-6 381 -239PU L 492.1 3 3/2- -239PU A 5583.2 1090262E-7 792 -239PU G 434.7 5 E1+M2 -239PU G 484.3 5 -239PU G 492.3 5 E1+M2 -239PU L 499 3 + -239PU A 5576 3 70204E-7 930 -239PU L 505.6 2 5/2- -239PU A 5569.9 1070204E-7 854 -239PU G 430.0 3 E1+M2 -239PU G 447.6 5 -239PU G 497.8 3 E1+M2 -239PU L 538 3 + -239PU A 5538 3 20058E-7 1955 -239PU L 543 3 + -239PU A 5533 3 60175E-7 610 -239PU L 556.2 5 7/2- -239PU A 5520.1 1120058E-7 1538 -239PU G 392.4 5 E1+M2 -239PU G 499 E1+M2 -239PU L 746 3 + -239PU A 5333 3 30087E-7 77.9 -239PU L 756 3 + -239PU A 5324 3 30087E-7 67.7 -239PU L 763 3 + -239PU A 5317 3 10029E-7 184 -239PU L 813 3 + -239PU A 5268 3 15044E-7 60.6 -239PU L 850 15 + -239PU A 5231 1539113E-8 137 - +243AM 243CM EC DECAY (28.9 Y) +243AM H TYP=FUL$AUT=V.P.CHECHEV$CUT=30-OCT-2010$ +243AM C References:1950Th52, 1953As14, 1953As40, 1955Sc08, 1956Ne17, 1957As70, +243AM2C 1957As83, 1958Ch38, 1959Ew90, 1962Iv01, 1963Le17, 1963Dz07, 1964Ba31, +243AM3C 1964Hy02, 1965Ma17, 1966Ba07, 1970By01, 1971Bb10, 1972Po04, 1972Ah02, +243AM4C 1972Kr07, 1973Ah04, 1976BaZZ, 1977VaZW, 1979Bo30, 1982Ah04, 1986Ti03, +243AM5C 1987Po19, 1990Si12, 1991Ry01, 2003Au03, 2003Br12, 2004Ak21, 2005Tr08, +243AM6C 2008BeZV, 2008Ki07, 2009KoZV +243AM T Auger electrons and X ray energies and emission intensities: +243AM T {U Energy (keV)} {U Intensity} {U Line} +243AM T +243AM T 102.03 XKA2 +243AM T 106.472 XKA1 +243AM T +243AM T 119.243 |] XKB3 +243AM T 120.284 |] XKB1 +243AM T 120.989 |] XKB5II +243AM T +243AM T 123.58 |] XKB2 +243AM T 124.127 |] XKB4 +243AM T 124.723 |] XKO23 +243AM T +243AM T +243AM T 77.04-85.638 |] KLL AUGER +243AM T 94.891-106.467 |] KLX AUGER +243AM T 112.72-124.97 |] KXY AUGER +243AM T 6.26-23.7 L AUGER +243CM P 0.0 5/2+ 28.9 Y 4 7.5 17 +243AM N 3.448E2 3.448E2 0.0029 33.448E2 +243AM L 0 5/2- 7367 Y 23 +243AM E 0.29 37.2 +243AM2 E CM=0.12 12$CN=0.64 15 + +239PU 243CM A DECAY (28.9 Y) +239PU H TYP=FUL$AUT=V.P.CHECHEV$CUT=30-OCT-2010$ +239PU C References:1950Th52, 1953As14, 1953As40, 1955Sc08, 1956Ne17, 1957As70, +239PU2C 1957As83, 1958Ch38, 1959Ew90, 1962Iv01, 1963Le17, 1963Dz07, 1964Ba31, +239PU3C 1964Hy02, 1965Ma17, 1966Ba07, 1970By01, 1971Bb10, 1972Po04, 1972Ah02, +239PU4C 1972Kr07, 1973Ah04, 1976BaZZ, 1977VaZW, 1979Bo30, 1982Ah04, 1986Ti03, +239PU5C 1987Po19, 1990Si12, 1991Ry01, 2003Au03, 2003Br12, 2004Ak21, 2005Tr08, +239PU6C 2008BeZV, 2008Ki07, 2009KoZV +239PU T Auger electrons and X ray energies and emission intensities: +239PU T {U Energy (keV)} {U Intensity} {U Line} +239PU T +239PU T 99.525 13.34 28 XKA2 +239PU T 103.734 21.1 5 XKA1 +239PU T +239PU T 116.244 |] XKB3 +239PU T 117.228 |] 7.75 21 XKB1 +239PU T 117.918 |] XKB5II +239PU T +239PU T 120.54 |] XKB2 +239PU T 120.969 |] 2.69 8 XKB4 +239PU T 121.543 |] XKO23 +239PU T +239PU T 12.1246-21.9844 52.1 16 XL (total) +239PU T 12.1246 1.40 6 XLL +239PU T 14.0834-14.2791 21.8 8 XLA +239PU T 16.334 0.418 26 XLC +239PU T 16.4987-18.5427 23.2 9 XLB +239PU T 20.7081-21.9844 5.30 22 XLG +239PU T +239PU T 75.263-85.357 |] KLL AUGER +239PU T 92.607-103.729 |] 1.34 19 KLX AUGER +239PU T 109.93-121.78 |] KXY AUGER +239PU T 6.19-22.99 49.3 15 L AUGER +243CM P 0.0 5/2+ 28.9 Y 4 6168.8 10 +239PU N 1.003E0 1.003E0 0.9971 3 +239PU G 640 +239PU G 680 +239PU G 720 +239PU G 740 +239PU G 760 +239PU L 0 1/2+ 24100 Y 11 +239PU A 6067.2 101.3 22210 +239PU L 7.861 2 3/2+ 36 PS 3 +239PU A 6059.4 104.41 20593 +239PU G 7.861 2 0.015 M1+E2 0.055 3 5.7E3 4 +239PU2 G MC=4.2E3 3$NC=1160 80 +239PU3 G OC=280 18 +239PU L 57.275 2 5/2+ 101 PS 5 +239PU A 6010.8 101.05 121410 +239PU G 49.414 2 0.2 M1+E2 0.50 3 126 8 +239PU2 G LC=92 6$MC=24.8 17$NC=6.8 5 +239PU3 G OC=1.62 11 +239PU G 57.273 4 0.06 E2 222 4 +239PU2 G LC=161.1 23$MC=45.0 7$NC=12.36 18 +239PU3 G OC=2.91 4 +239PU L 75.705 3 7/2+ 83 PS 8 +239PU A 5992.7 105.72 20209 +239PU G 18.430 4 0.0001 (M1+E2) 8E3 6 +239PU2 G MC=6E3 6$NC=1.6E3 16 +239PU3 G OC=4E2 4 +239PU G 67.841 7 0.20 5E2 98.5 14 +239PU2 G LC=71.5 10$MC=20.0 3$NC=5.50 8 +239PU3 G OC=1.293 19 +239PU L 163.76 3 9/2+ 73 PS 4 +239PU A 5906.1 100.100291 4230 +239PU G 88.06 3 0.0018 M1+E2 0.5 12.26 18 +239PU2 G LC=9.07 13$MC=2.36 4$NC=0.645 9 +239PU3 G OC=0.1563 22 +239PU G 106.47 4 0.015 E2 11.80 17 +239PU2 G LC=8.56 12$MC=2.40 4$NC=0.659 10 +239PU3 G OC=0.1553 22 +239PU L 192.8 1011/2+ +239PU A 5877.6 140.702036 427 +239PU G 117.1 100.08 [E2] 7.6 4 +239PU2 G LC=5.52 24$MC=1.54 7$NC=0.425 18 +239PU3 G OC=0.100 5 +239PU L 285.460 2 5/2+ 1.12 NS 5 +239PU A 5786.4 1073.61 401.32 +239PU G 209.753 2 3.29 10M1+E2 -0.019 15 3.24 5 +239PU2 G KC=2.56 4$LC=0.511 8$MC=0.1241 18$NC=0.0338 5 +239PU3 G OC=0.00840 12 +239PU G 228.183 2 10.6 3M1+E2 0.009 6 2.56 4 +239PU2 G KC=2.02 3$LC=0.403 6$MC=0.0979 14$NC=0.0266 4 +239PU3 G OC=0.00663 10 +239PU G 277.599 2 14.0 4M1+E2 0.165 2 1.448 21 +239PU2 G KC=1.142 16$LC=0.230 4$MC=0.0560 8$NC=0.01523 22 +239PU3 G OC=0.00379 6 +239PU G 285.460 2 0.73 2E2 0.247 4 +239PU2 G KC=0.0843 12$LC=0.1190 17$MC=0.0326 5$NC=0.00896 13 +239PU3 G OC=0.00213 3 +239PU L 330.124 4 7/2+ +239PU A 5742.5 1011.33 204.94 +239PU G 44.663 5 0.131 16M1+E2 0.24 4 96 13 +239PU2 G LC=72 9$MC=18 3$NC=5.0 7 +239PU3 G OC=1.22 17 +239PU G 166.39 6 0.016 7M1 6.22 9 +239PU2 G KC=4.91 7$LC=0.984 14$MC=0.239 4$NC=0.0651 10 +239PU3 G OC=0.01621 23 +239PU G 254.40 3 0.11 1M1+E2 -0.159 6 1.85 3 +239PU2 G KC=1.457 21$LC=0.294 5$MC=0.0716 10$NC=0.0195 3 +239PU3 G OC=0.00485 7 +239PU G 272.87 9 0.08 1M1+E2 0.165 9 1.518 22 +239PU2 G KC=1.198 18$LC=0.241 4$MC=0.0588 9$NC=0.01599 23 +239PU3 G OC=0.00397 6 +239PU G 322.3 2 0.007 1[E2] 0.1699 24 +239PU2 G KC=0.0679 10$LC=0.0745 11$MC=0.0203 3$NC=0.00557 8 +239PU3 G OC=0.001329 19 +239PU L 387.42 2 9/2+ +239PU A 5686.1 101.6 117 +239PU G 57.30 2 0.08 [M1] 28.6 4 +239PU2 G LC=21.5 3$MC=5.24 8$NC=1.428 20 +239PU3 G OC=0.355 5 +239PU G 101.96 2 0.008 E2 14.42 21 +239PU2 G LC=10.46 15$MC=2.93 5$NC=0.805 12 +239PU3 G OC=0.190 3 +239PU G 311.7 2 0.017 2M1+E2 0.1 1 1.06 3 +239PU2 G KC=0.84 3$LC=0.168 4$MC=0.0408 8$NC=0.01109 21 +239PU3 G OC=0.00276 6 +239PU L 391.584 3 7/2- 193 NS 4 +239PU A 5682 1 0.200582 129 +239PU G 4.16 2 E1 +239PU G 61.460 2 0.0151 13E1 0.473 7 +239PU2 G LC=0.354 5$MC=0.0881 13$NC=0.0236 4 +239PU3 G OC=0.00553 8 +239PU G 106.125 2 0.296 25E1(+M2) -0.007 7 0.26 4 +239PU2 G LC=0.19 3$MC=0.050 8$NC=0.017 3 +239PU G 315.880 3 0.018 2E1(+M2) 0.008 8 0.0372 9 +239PU2 G KC=0.0294 6$LC=0.00583 16$MC=0.00141 4$NC=0.000382 12 +239PU3 G OC=0.000093 3 +239PU G 334.310 3 0.024 2E1(+M2) 0.006 6 0.0329 6 +239PU2 G KC=0.0261 5$LC=0.00511 10$MC=0.001238 24$NC=0.000334 7 +239PU3 G OC=8.18E-5 16 +239PU L 427 3 +239PU A 5647 3 30087E-6 549 +239PU L 434 3 9/2- +239PU A 5640 3 0.140407 108 +239PU L 451 5 +239PU A 5624 5 60175E-6 202 +239PU L 462 3 11/2+ +239PU A 5613 3 30087E-6 351 +239PU L 469.8 4 1/2- +239PU A 5605.1 1110029E-6 951 +239PU G 461.9 5 E1+M2 +239PU G 469.8 5 E1 +239PU L 481 3 +239PU A 5594 3 10029E-6 823 +239PU L 487 3 11/2- +239PU A 5588 3 20058E-6 381 +239PU L 492.1 3 3/2- +239PU A 5583.2 1090262E-7 792 +239PU G 434.7 5 E1+M2 +239PU G 484.3 5 +239PU G 492.3 5 E1+M2 +239PU L 499 3 +239PU A 5576 3 70204E-7 930 +239PU L 505.6 2 5/2- +239PU A 5569.9 1070204E-7 854 +239PU G 430.0 3 E1+M2 +239PU G 447.6 5 +239PU G 497.8 3 E1+M2 +239PU L 538 3 +239PU A 5538 3 20058E-7 1955 +239PU L 543 3 +239PU A 5533 3 60175E-7 610 +239PU L 556.2 5 7/2- +239PU A 5520.1 1120058E-7 1538 +239PU G 392.4 5 E1+M2 +239PU G 499 E1+M2 +239PU L 746 3 +239PU A 5333 3 30087E-7 77.9 +239PU L 756 3 +239PU A 5324 3 30087E-7 67.7 +239PU L 763 3 +239PU A 5317 3 10029E-7 184 +239PU L 813 3 +239PU A 5268 3 15044E-7 60.6 +239PU L 850 15 +239PU A 5231 1539113E-8 137 + diff --git a/HEN_HOUSE/spectra/lnhb/Cm-244.txt b/HEN_HOUSE/spectra/lnhb/Cm-244.txt index c307f0472..3ed7d24c2 100644 --- a/HEN_HOUSE/spectra/lnhb/Cm-244.txt +++ b/HEN_HOUSE/spectra/lnhb/Cm-244.txt @@ -1,102 +1,107 @@ -240PU 244CM A DECAY (18.11 Y) -240PU H TYP=Update$AUT=V.P. Chechev$CUT=31-OCT-2009$ -240PU2 H TYP=Full$AUT=V.P.Chechev$CUT=31-OCT-2009$ -240PU3 H TYP=Full$AUT=V.P.Chechev$CUT=31-JAN-2005$ -240PU4 H TYP=Full$AUT=V.P.Chechev$CUT=31-JAN-2005$ -240PU5 H TYP=Full$AUT=V.P.Chechev$CUT=31-JAN-2005$ -240PU6 H TYP=Full$AUT=V.P.Chechev$CUT=31-JAN-2005$ -240PU C Evaluation history: Type=Update;Author=V.P. Chechev;Cutoff date=31-OCT-2009 -240PU2C Type=Full;Author=V.P.Chechev;Cutoff date=31-OCT-2009 -240PU3C Type=Full;Author=V.P.Chechev;Cutoff date=31-JAN-2005 -240PU4C Type=Full;Author=V.P.Chechev;Cutoff date=31-JAN-2005 -240PU5C Type=Full;Author=V.P.Chechev;Cutoff date=31-JAN-2005 -240PU6C Type=Full;Author=V.P.Chechev;Cutoff date=31-JAN-2005 -240PU C References: 1952Gh27, 1954Fr19, 1954St33, 1956Hu96, 1956Sm18, 1960As11, -240PU2C 1961Ca01, 1963Bj03, 1963Ma56, 1963Dz07, 1965Me02, 1967Ar09, 1967Be65, -240PU3C 1966Ba07, 1968Be26, 1968Du06, 1969Sc18, 1970Sc39, 1970Ba11, 1971Gr17, -240PU4C 1972Sp06, 1972Ah07, 1972Ha80, 1972Ke29, 1972Sc01, 1978LeZA, 1980Di13, -240PU5C 1981Hs02, 1982Ba56, 1982Po14, 1984BuZJ, 1990Pe03, 1990Po14, 1991ry01, -240PU6C 1992Fr04, 1993Pa29, 1995Jo23, 1996Bu50, 1996Sc09, 1996Sa24, 1997Ka59, -240PU7C 1998Ga19, 1998Ya17, 2002Da21, 2003Au03, 2004Ch64, 2006Ch34, 2008Ki07 -240PU T Auger electrons and X ray energies and emission intensities: -240PU T {U Energy (keV)} {U Intensity} {U Line} -240PU T -240PU T 99.525 0.000061 4 XKA2 -240PU T 103.734 0.000097 5 XKA1 -240PU T -240PU T 116.244 |] XKB3 -240PU T 117.228 |] 3.54E-5 20 XKB1 -240PU T 117.918 |] XKB5II -240PU T -240PU T 120.54 |] XKB2 -240PU T 120.969 |] 1.23E-5 7 XKB4 -240PU T 121.543 |] XKO23 -240PU T -240PU T 12.125-21.984 8.92 23 XL (total) -240PU T 12.125 0.219 8 XLL -240PU T 14.083-14.279 3.42 11 XLA -240PU T 16.334 0.092 4 XLC -240PU T 16.499-19.331 4.21 14 XLB -240PU T 20.708-21.984 0.970 4 XLG -240PU T -240PU T 75.263-85.357 |] KLL AUGER -240PU T 92.607-103.729 |] 6.1E-6 9 KLX AUGER -240PU T 109.93-121.78 |] KXY AUGER -240PU T 6.19-22.99 8.09 20 L AUGER -244CM P 0.0 0+ 18.11 Y 3 5901.74 5 -240PU N 1.0 1.0 1 1.0 -240PU L 0 0+ 6561 Y 7 -240PU A 5804.77 5 76.7 4 1 -240PU L 42.824 8 2+ 164 PS 5 -240PU A 5762.65 5 23.3 4 1.94 -240PU G 42.824 8 0.0258 7E2 905 18 -240PU2 G LC=658 13$MC=183 4 -240PU L 141.690 154+ -240PU A 5665.41 5 0.0204 15636 -240PU G 98.860 130.00136 9E2 16.6 3 -240PU2 G LC=12.08 24$MC=3.38 7 -240PU L 294.319 246+ -240PU A 5515.29 6 0.00352 18512 -240PU G 152.63 2 0.00102 5(E2) 2.48 5 -240PU2 G KC=0.196 4$LC=1.66 3$MC=0.465 9 -240PU L 497.6 8+ -240PU A 5315.3 0.00004 -240PU G 202.4 0.000022 (E2) 0.817 16 -240PU2 G KC=0.148 3$LC=0.487 10$MC=0.135 3 -240PU L 597.34 4 1- -240PU A 5217.24 7 55000E-99 500 -240PU G 554.52 4 0.00008711(E1) 0.0117924 -240PU2 G KC=0.00949 19$LC=0.00174 4$MC=4.17E-4 9 -240PU G 597.34 4 0.000053 7(E1) 0.0102421 -240PU2 G KC=0.00826 17$LC=0.00150 3$MC=3.59E-4 7 -240PU L 648.85 4 3- -240PU A 5166.58 7 42000E-1303100 -240PU G 507.16 5 8.7E-6 28(E1) 0.0140129 -240PU2 G KC=0.01126 23$LC=0.00208 4$MC=0.00050 1 -240PU G 606.03 4 8.1E-6 14 -240PU L 860.71 7 0+ -240PU A 4958.20 9 14900E-8163.5 -240PU G 263.37 8 0.000062 9(E1) 0.0547 11 -240PU2 G KC=0.0433 9$LC=0.00881 18$MC=0.00214 4 -240PU G 817.89 7 0.000068 9(E2) 0.0182 4 -240PU2 G KC=0.0130 3$LC=0.00389 8$MC=9.89E-4 20 -240PU G 860.71 7 8.2E-6 20() -240PU L 900.32 4 2+ -240PU A 4919.24 7 50000E-95 5.6 -240PU G 251.47 6 1.14E-5 23(E1) 0.0606 12 -240PU2 G KC=0.048 1$LC=0.00983 20$MC=0.00239 5 -240PU G 302.98 6 0.000019 3(E1) 0.0405 8 -240PU2 G KC=0.0320 7$LC=0.00637 13$MC=0.00154 3 -240PU G 758.63 5 1.38E-5 19(E2) 0.0212 4 -240PU2 G KC=0.0148 3$LC=0.00473 9$MC=1211E-6 24 -240PU G 857.50 4 5.7E-6 8 -240PU G 900.32 4 1.3E-6 6 -240PU L 938.06 6 1- -240PU A 4882.12 8 47000E-11133 -240PU G 289.21 7 6E-7 3E2+M3 7 7 -240PU2 G KC=3 4$LC=2.4 23$MC=0.7 7 -240PU G 340.72 7 1.8E-6 9 -240PU G 895.24 6 1.8E-6 6E1+M2 0.07 7 -240PU2 G KC=0.06 6$LC=0.013 13$MC=0.003 3 -240PU G 938.06 6 4E-7 4 - +240PU 244CM A DECAY (18.11 Y) +240PU H TYP=FUL$AUT=V.P.CHECHEV$CUT=31-OCT-2009$ +240PU2 H TYP=FUL$AUT=V.P.CHECHEV$CUT=31-JAN-2005$ +240PU C References:1952Gh27, 1954Fr19, 1954St33, 1956Hu96, 1956Sm18, 1960As11, +240PU2C 1961Ca01, 1963Bj03, 1963Ma56, 1963Dz07, 1965Me02, 1967Ar09, 1967Be65, +240PU3C 1966Ba07, 1968Be26, 1968Du06, 1969Sc18, 1970Sc39, 1970Ba11, 1971Gr17, +240PU4C 1972Sp06, 1972Ah07, 1972Ha80, 1972Ke29, 1972Sc01, 1978LeZA, 1980Di13, +240PU5C 1981Hs02, 1982Ba56, 1982Po14, 1984BuZJ, 1990Pe03, 1990Po14, 1991ry01, +240PU6C 1992Fr04, 1993Pa29, 1995Jo23, 1996Bu50, 1996Sc09, 1996Sa24, 1997Ka59, +240PU7C 1998Ga19, 1998Ya17, 1999Sc**, 2000H027, 2000Sc**, 2002Da21, 2003Au03, +240PU8C 2004Ch64, 2006Ch34, 2008Ki07 +240PU T Auger electrons and X ray energies and emission intensities: +240PU T {U Energy (keV)} {U Intensity} {U Line} +240PU T +240PU T 99.525 0.000061 4 XKA2 +240PU T 103.734 0.000097 5 XKA1 +240PU T +240PU T 116.244 |] XKB3 +240PU T 117.228 |] 3.54E-5 20 XKB1 +240PU T 117.918 |] XKB5II +240PU T +240PU T 120.54 |] XKB2 +240PU T 120.969 |] 1.23E-5 7 XKB4 +240PU T 121.543 |] XKO23 +240PU T +240PU T 12.125-21.984 8.92 23 XL (total) +240PU T 12.125 0.219 8 XLL +240PU T 14.083-14.279 3.42 11 XLA +240PU T 16.334 0.092 4 XLC +240PU T 16.499-19.331 4.21 14 XLB +240PU T 20.708-21.984 0.970 4 XLG +240PU T +240PU T 75.263-85.357 |] KLL AUGER +240PU T 92.607-103.729 |] 6.1E-6 9 KLX AUGER +240PU T 109.93-121.78 |] KXY AUGER +240PU T 6.19-22.99 8.09 20 L AUGER +244CM P 0.0 0+ 18.11 Y 3 5901.74 5 +240PU N 1.0 1.0 1 +240PU L 0 0+ 6561 Y 7 +240PU A 5804.77 5 76.7 41 +240PU L 42.824 8 2+ 164 PS 5 +240PU A 5762.65 5 23.3 41.94 +240PU G 42.824 8 0.0258 7E2 905 18 +240PU2 G LC=658 13$MC=183 4$NC=50.4 10 +240PU3 G OC=11.83 23 +240PU L 141.690 154+ +240PU A 5665.41 5 0.0204 15636 +240PU G 98.860 130.00136 9E2 16.6 3 +240PU2 G LC=12.08 24$MC=3.38 7$NC=0.930 19 +240PU3 G OC=0.219 4 +240PU L 294.319 246+ +240PU A 5515.29 6 0.00352 18512 +240PU G 152.63 2 0.00102 5(E2) 2.48 5 +240PU2 G KC=0.196 4$LC=1.66 3$MC=0.465 9$NC=0.1278 25 +240PU3 G OC=0.0302 6 +240PU L 497.6 8+ +240PU A 5315.3 0.00004 +240PU G 202.4 0.000022 (E2) 0.817 16 +240PU2 G KC=0.148 3$LC=0.487 10$MC=0.135 3$NC=0.037 8 +240PU3 G OC=0.00880 18 +240PU L 597.34 4 1- +240PU A 5217.24 7 0.000055 9500 +240PU G 554.52 4 0.00008711(E1) 0.0117924 +240PU2 G KC=0.00949 19$LC=0.00174 4$MC=0.000417 9$NC=1.127E-4 22 +240PU3 G OC=2.77E-5 5 +240PU G 597.34 4 0.000053 7(E1) 0.0102421 +240PU2 G KC=0.00826 17$LC=0.00150 3$MC=0.000359 7$NC=9.70E-5 19 +240PU3 G OC=2.39E-5 5 +240PU L 648.85 4 3- +240PU A 5166.58 7 4.2E-6 303100 +240PU G 507.16 5 8.7E-6 28(E1) 0.0140129 +240PU2 G KC=0.01126 23$LC=0.00208 4$MC=0.00050 1$NC=1.352E-4 27 +240PU3 G OC=3.33E-5 7 +240PU G 606.03 4 8.1E-6 14 +240PU L 860.71 7 0+ +240PU A 4958.20 9 0.000149163.5 +240PU G 263.37 8 0.000062 9(E1) 0.0547 11 +240PU2 G KC=0.0433 9$LC=0.00881 18$MC=0.00214 4$NC=0.000578 12 +240PU3 G OC=1.409E-4 30 +240PU G 817.89 7 0.000068 9(E2) 0.0182 4 +240PU2 G KC=0.0130 3$LC=0.00389 8$MC=0.000989 20$NC=0.000270 6 +240PU3 G OC=6.58E-5 13 +240PU G 860.71 7 8.2E-6 20(E0) +240PU L 900.32 4 2+ +240PU A 4919.24 7 0.000050 55.6 +240PU G 251.47 6 1.14E-5 23(E1) 0.0606 12 +240PU2 G KC=0.048 1$LC=0.00983 20$MC=0.00239 5$NC=0.000645 13 +240PU3 G OC=1.571E-4 30 +240PU G 302.98 6 0.000019 3(E1) 0.0405 8 +240PU2 G KC=0.0320 7$LC=0.00637 13$MC=0.00154 3$NC=0.000417 8 +240PU3 G OC=1.018E-4 20 +240PU G 758.63 5 1.38E-5 19(E2) 0.0212 4 +240PU2 G KC=0.0148 3$LC=0.00473 9$MC=0.001211 24$NC=0.000331 7 +240PU3 G OC=8.05E-5 16 +240PU G 857.50 4 5.7E-6 8 +240PU G 900.32 4 1.3E-6 6 +240PU L 938.06 6 1- +240PU A 4882.12 8 4.7E-6 1133 +240PU G 289.21 7 6E-7 3E2+M3 7 7 +240PU2 G KC=3 4$LC=2.4 23$MC=0.7 7$NC=0.19 19 +240PU3 G OC=0.05 5 +240PU G 340.72 7 1.8E-6 9 +240PU G 895.24 6 1.8E-6 6E1+M2 0.07 7 +240PU2 G KC=0.06 6$LC=0.013 13$MC=0.003 3$NC=0.0009 9 +240PU3 G OC=0.00022 21 +240PU G 938.06 6 4E-7 4 + diff --git a/HEN_HOUSE/spectra/lnhb/Cm-245.txt b/HEN_HOUSE/spectra/lnhb/Cm-245.txt index 5c26d06b0..2d249270c 100644 --- a/HEN_HOUSE/spectra/lnhb/Cm-245.txt +++ b/HEN_HOUSE/spectra/lnhb/Cm-245.txt @@ -1,87 +1,102 @@ -241PU 245CM A DECAY (8250 Y) -241PU H TYP=Full$AUT=V.P. Chechev$CUT=30-OCT-2010$ -241PU C Evaluation history: Type=Full;Author=V.P. Chechev;Cutoff date=30-OCT-2010 -241PU C References: 1954HU50, 1954Fr19, 1955Br02, 1955Pe32, 1957HU76, 1960As11, -241PU2C 1961Ca01, 1963DZ07, 1964Hy02, 1966BA07, 1966FR03, 1969Me01, 1971Ma32, -241PU3C 1975BA65, 1976BAZZ, 1977La19, 1980DI13, 1982Po14, 1985DR10, 1989Ho24, -241PU4C 1991PO17, 1991RY01, 1994SH31, 1996Sc06, 1998WH01, 2000Sc47, 2003Au03, -241PU5C 2005MA88, 2008Ki07, 2008KOZP, 2009KOZV -241PU T Auger electrons and X ray energies and emission intensities: -241PU T {U Energy (keV)} {U Intensity} {U Line} -241PU T -241PU T 99.525 19.0 5 XKA2 -241PU T 103.734 30.1 7 XKA1 -241PU T -241PU T 116.244 |] XKB3 -241PU T 117.228 |] 11.06 30 XKB1 -241PU T 117.918 |] XKB5II -241PU T -241PU T 120.54 |] XKB2 -241PU T 120.969 |] 3.84 12 XKB4 -241PU T 121.543 |] XKO23 -241PU T -241PU T 12.1246-21.9844 51.7 10 XL (total) -241PU T 12.1246 1.46 4 XLL -241PU T 14.0834-14.2791 22.8 6 XLA -241PU T 16.334 0.334 11 XLC -241PU T 16.4987-19.331 22.1 5 XLB -241PU T 20.7081-21.9844 4.97 10 XLG -241PU T -241PU T 75.263-85.357 |] KLL AUGER -241PU T 92.607-103.729 |] 1.91 27 KLX AUGER -241PU T 109.93-121.78 |] KXY AUGER -241PU T 6.19-22.99 50.1 13 L AUGER -245CM P 0.0 7/2+ 8250 Y 70 5622.3 5 -241PU N 1.0 1.0 1 1.0 -241PU G 388.16 5 0.019 1 -241PU L 0 5/2+ 14.33 Y 4 -241PU A 5530.4 4 0.58 1770 -241PU L 41.9722 9 7/2+ -241PU A 5488.5 5 0.83 768 -241PU G 41.972 1 0.369 20M1+E2 0.186 4 102.4 20 -241PU2 G LC=76.2 15$MC=19.4 4 -241PU L 95.7795 129/2+ -241PU A 5436.1 5 0.04 7130 -241PU G 53.807 1 0.073 4M1+E2 0.201 8 44.7 11 -241PU2 G LC=33.3 8$MC=8.42 21 -241PU G 95.7795 120.0109 23E2 19.3 3 -241PU2 G LC=14.0 2$MC=3.92 6 -241PU L 161.314 4 11/2+ -241PU A 5371.7 5 0.39 22300 -241PU G 65.535 3 0.018 2M1+E2 0.22 22 24 12 -241PU2 G LC=18 9$MC=4.5 24 -241PU L 161.6852 9 1/2+ 0.88 US 5 -241PU A 5371.4 5 0.0210 9 5520 -241PU G 161.685 1 0.071 3E2 1.96 3 -241PU2 G KC=0.190 3$LC=1.289 18$MC=0.360 5 -241PU L 175.0523 147/2+ -241PU A 5361.8 1293.2 5 1.03 -241PU G 79.2728 180.120 7M1+E2 0.65 25 22 6 -241PU2 G LC=16 5$MC=4.3 12 -241PU G 133.081 2 2.81 7M1+E2 0.222 9 11.36 17 -241PU2 G KC=8.80 13$LC=1.92 3$MC=0.473 7 -241PU G 175.0523 149.83 22M1+E2 0.217 19 5.21 8 -241PU2 G KC=4.07 7$LC=0.855 12$MC=0.209 3 -241PU L 231.935 9 9/2+ -241PU A 5303.6 125.0 1 8.7 -241PU G 56.89 3 0.0359 21M1+E2 0.638 50 87 7 -241PU2 G LC=64 5$MC=17.3 14 -241PU G 136.156 9 0.113 4M1+E2 0.63 21 9 1 -241PU2 G KC=6.2 12$LC=2.04 15$MC=0.52 5 -241PU G 189.965 100.204 6M1+E2 0.63 7 3.36 16 -241PU2 G KC=2.46 15$LC=0.665 10$MC=0.1680 25 -241PU G 231.935 9 0.0117 18[E2] 0.498 7 -241PU2 G KC=0.1200 17$LC=0.275 4$MC=0.0760 11 -241PU L 301.172 1611/2+ -241PU A 5234.4 120.32 51 -241PU G 69.237 180.007 3M1(+E2) 0.433 300 28 14 -241PU2 G LC=21 10$MC=5 3 -241PU G 126.09 4 0.007 2[E2] 5.59 8 -241PU2 G KC=0.1705 24$LC=3.94 6$MC=1.101 16 -241PU G 139.858 160.008 1[M1E2] 7 4 -241PU2 G KC=4 4$LC=2.0 5$MC=0.54 15 -241PU G 205.393 160.009 1[M1E2] 2.1 14 -241PU2 G KC=1.4 13$LC=0.50 5$MC=0.129 3 -241PU L 385 3 (13/2)+ -241PU A 5152 3 0.005 1000 - +241PU 245CM A DECAY (8250 Y) +241PU H TYP=FUL$AUT=V.P.CHECHEV$CUT=30-OCT-2010$ +241PU C References:1954HU50, 1954Fr19, 1955Br02, 1955Pe32, 1957HU76, 1960As11, +241PU2C 1961Ca01, 1963DZ07, 1964Hy02, 1966BA07, 1966FR03, 1969Me01, 1971Ma32, +241PU3C 1975BA65, 1976BAZZ, 1977La19, 1980DI13, 1982Po14, 1985DR10, 1989Ho24, +241PU4C 1991PO17, 1991RY01, 1994SH31, 1996Sc06, 1998WH01, 2000Sc47, 2003Au03, +241PU5C 2005Ma88, 2008Ki07, 2008KOZP, 2009KOZV +241PU T Auger electrons and X ray energies and emission intensities: +241PU T {U Energy (keV)} {U Intensity} {U Line} +241PU T +241PU T 99.525 19.0 5 XKA2 +241PU T 103.734 30.1 7 XKA1 +241PU T +241PU T 116.244 |] XKB3 +241PU T 117.228 |] 11.06 30 XKB1 +241PU T 117.918 |] XKB5II +241PU T +241PU T 120.54 |] XKB2 +241PU T 120.969 |] 3.84 12 XKB4 +241PU T 121.543 |] XKO23 +241PU T +241PU T 12.1246-21.9844 51.7 10 XL (total) +241PU T 12.1246 1.46 4 XLL +241PU T 14.0834-14.2791 22.8 6 XLA +241PU T 16.334 0.334 11 XLC +241PU T 16.4987-19.331 22.1 5 XLB +241PU T 20.7081-21.9844 4.97 10 XLG +241PU T +241PU T 75.263-85.357 |] KLL AUGER +241PU T 92.607-103.729 |] 1.91 27 KLX AUGER +241PU T 109.93-121.78 |] KXY AUGER +241PU T 6.19-22.99 50.1 13 L AUGER +245CM P 0.0 7/2+ 8250 Y 70 5622.3 5 +241PU N 1.0 1.0 1 +241PU G 388.16 5 0.019 1 +241PU L 0 5/2+ 14.33 Y 4 +241PU A 5530.4 4 0.58 1770 +241PU L 41.9722 9 7/2+ +241PU A 5488.5 5 0.83 768 +241PU G 41.972 1 0.369 20M1+E2 0.186 4 102.4 20 +241PU2 G LC=76.2 15$MC=19.4 4$NC=5.30 11 +241PU3 G OC=1.294 25 +241PU L 95.7795 129/2+ +241PU A 5436.1 5 0.04 7130 +241PU G 53.807 1 0.073 4M1+E2 0.201 8 44.7 11 +241PU2 G LC=33.3 8$MC=8.42 21$NC=2.30 6 +241PU3 G OC=0.563 14 +241PU G 95.7795 120.0109 23E2 19.3 3 +241PU2 G LC=14.0 2$MC=3.92 6$NC=1.078 15 +241PU3 G OC=0.254 4 +241PU L 161.314 4 11/2+ +241PU A 5371.7 5 0.39 22300 +241PU G 65.535 3 0.018 2M1+E2 0.22 22 24 12 +241PU2 G LC=18 9$MC=4.5 24$NC=1.2 7 +241PU3 G OC=0.30 15 +241PU L 161.6852 9 1/2+ 0.88 US 5 +241PU A 5371.4 5 0.0210 95520 +241PU G 161.685 1 0.071 3E2 1.96 3 +241PU2 G KC=0.190 3$LC=1.289 18$MC=0.360 5$NC=0.0989 14 +241PU3 G OC=0.0234 4 +241PU L 175.0523 147/2+ +241PU A 5361.8 1293.2 51.03 +241PU G 79.2728 180.120 7M1+E2 0.65 25 22 6 +241PU2 G LC=16 5$MC=4.3 12$NC=1.2 4 +241PU3 G OC=0.28 8 +241PU G 133.081 2 2.81 7M1+E2 0.222 9 11.36 17 +241PU2 G KC=8.80 13$LC=1.92 3$MC=0.473 7$NC=0.1287 19 +241PU3 G OC=0.0319 5 +241PU G 175.0523 149.83 22M1+E2 0.217 19 5.21 8 +241PU2 G KC=4.07 7$LC=0.855 12$MC=0.209 3$NC=0.0570 8 +241PU3 G OC=0.01414 20 +241PU L 231.935 9 9/2+ +241PU A 5303.6 125.0 18.7 +241PU G 56.89 3 0.0359 21M1+E2 0.638 50 87 7 +241PU2 G LC=64 5$MC=17.3 14$NC=4.7 4 +241PU3 G OC=1.13 9 +241PU G 136.156 9 0.113 4M1+E2 0.63 21 9 1 +241PU2 G KC=6.2 12$LC=2.04 15$MC=0.52 5$NC=0.143 14 +241PU3 G OC=0.035 3 +241PU G 189.965 100.204 6M1+E2 0.63 7 3.36 16 +241PU2 G KC=2.46 15$LC=0.665 10$MC=0.1680 25$NC=0.0459 7 +241PU3 G OC=0.01125 16 +241PU G 231.935 9 0.0117 18[E2] 0.498 7 +241PU2 G KC=0.1200 17$LC=0.275 4$MC=0.0760 11$NC=0.0209 3 +241PU3 G OC=0.00495 7 +241PU L 301.172 1611/2+ +241PU A 5234.4 120.32 51 +241PU G 69.237 180.007 3M1(+E2) 0.433 300 28 14 +241PU2 G LC=21 10$MC=5 3$NC=1.5 8 +241PU3 G OC=0.36 19 +241PU G 126.09 4 0.007 2[E2] 5.59 8 +241PU2 G KC=0.1705 24$LC=3.94 6$MC=1.101 16$NC=0.303 5 +241PU3 G OC=0.0714 10 +241PU G 139.858 160.008 1[M1,E2] 7 4 +241PU2 G KC=4 4$LC=2.0 5$MC=0.54 15$NC=0.15 5 +241PU3 G OC=0.036 9 +241PU G 205.393 160.009 1[M1,E2] 2.1 14 +241PU2 G KC=1.4 13$LC=0.50 5$MC=0.129 3$NC=0.0354 7 +241PU3 G OC=0.0086 4 +241PU L 385 3 (13/2)+ +241PU A 5152 3 0.005 1000 + diff --git a/HEN_HOUSE/spectra/lnhb/Cm-246.txt b/HEN_HOUSE/spectra/lnhb/Cm-246.txt index c3770faae..b269dc252 100644 --- a/HEN_HOUSE/spectra/lnhb/Cm-246.txt +++ b/HEN_HOUSE/spectra/lnhb/Cm-246.txt @@ -1,42 +1,43 @@ -242PU 246CM A DECAY (4723 Y) -242PU H TYP=Full$AUT=F.Kondev$CUT=31-OCT-2006$ -242PU C Evaluation history: Type=Full;Author=F.Kondev;Cutoff date=31-OCT-2006 -242PU C References: 1977La19 -242PU T Auger electrons and X ray energies and emission intensities: -242PU T {U Energy (keV)} {U Intensity} {U Line} -242PU T -242PU T 99.525 XKA2 -242PU T 103.734 XKA1 -242PU T -242PU T 116.244 |] XKB3 -242PU T 117.228 |] XKB1 -242PU T 117.918 |] XKB5II -242PU T -242PU T 120.54 |] XKB2 -242PU T 120.969 |] XKB4 -242PU T 121.543 |] XKO23 -242PU T -242PU T 12.125-21.984 7.95 24 XL (total) -242PU T 12.125 0.195 8 XLL -242PU T 14.083-14.279 3.03 11 XLA -242PU T 16.334 0.082 4 XLC -242PU T 16.499-19.331 3.76 14 XLB -242PU T 20.708-21.984 0.87 4 XLG -242PU T -242PU T 75.263-85.357 |] KLL AUGER -242PU T 92.607-103.729 |] KLX AUGER -242PU T 109.93-121.78 |] KXY AUGER -242PU T 6.19-22.99 7.20 21 L AUGER -246CM P 0.0 0+ 4723 Y 27 5476.7 9 -242PU N 1.00E0 1.00E0 0.999738 1.00E0 -242PU L 0 0+ 3.73E5 Y 3 -242PU A 5387.5 9 79.19 221 -242PU L 44.545 9 2+ -242PU A 5343.7 9 20.82 222.05 -242PU G 44.545 9 0.0279 8E2 746 22 -242PU2 G LC=542 16$MC=151.4 45 -242PU L 147.35 104+ -242PU A 5242.5 100.020 2 500 -242PU G 102.8 1 0.00134 14E2 13.86 42 -242PU2 G LC=10.06 30$MC=2.82 8 - +242PU 246CM A DECAY (4723 Y) +242PU H TYP=FUL$AUT=F.G.KONDEV$CUT=31-OCT-2006$ +242PU C References:1977La19 +242PU T Auger electrons and X ray energies and emission intensities: +242PU T {U Energy (keV)} {U Intensity} {U Line} +242PU T +242PU T 99.525 XKA2 +242PU T 103.734 XKA1 +242PU T +242PU T 116.244 |] XKB3 +242PU T 117.228 |] XKB1 +242PU T 117.918 |] XKB5II +242PU T +242PU T 120.54 |] XKB2 +242PU T 120.969 |] XKB4 +242PU T 121.543 |] XKO23 +242PU T +242PU T 12.125-21.984 7.95 24 XL (total) +242PU T 12.125 0.195 8 XLL +242PU T 14.083-14.279 3.03 11 XLA +242PU T 16.334 0.082 4 XLC +242PU T 16.499-19.331 3.76 14 XLB +242PU T 20.708-21.984 0.87 4 XLG +242PU T +242PU T 75.263-85.357 |] KLL AUGER +242PU T 92.607-103.729 |] KLX AUGER +242PU T 109.93-121.78 |] KXY AUGER +242PU T 6.19-22.99 7.20 21 L AUGER +246CM P 0.0 0+ 4723 Y 27 5476.7 9 +242PU N 1.00E0 1.00E0 0.999738 +242PU L 0 0+ 3.73E5 Y 3 +242PU A 5387.5 9 79.19 221 +242PU L 44.545 9 2+ +242PU A 5343.7 9 20.82 222.05 +242PU G 44.545 9 0.0279 8E2 746 22 +242PU2 G LC=542 16$MC=151.4 45$NC=41.6 12 +242PU3 G OC=9.77 29 +242PU L 147.35 104+ +242PU A 5242.5 100.020 2500 +242PU G 102.8 1 0.00134 14E2 13.86 42 +242PU2 G LC=10.06 30$MC=2.82 8$NC=0.775 23 +242PU3 G OC=0.183 5 + diff --git a/HEN_HOUSE/spectra/lnhb/Co-56.txt b/HEN_HOUSE/spectra/lnhb/Co-56.txt index 5a9f85e9b..1c0c36a07 100644 --- a/HEN_HOUSE/spectra/lnhb/Co-56.txt +++ b/HEN_HOUSE/spectra/lnhb/Co-56.txt @@ -1,114 +1,114 @@ - 56FE 56CO EC DECAY (77.236 D) - 56FE C References: 1977La19, 1979Sc31, 1999Hu04, 2000He14, 2000Ra36, 2002Ba38, - 56FE2C 2003Au03 - 56FE T Auger electrons and X ray energies and emission intensities: - 56FE T {U Energy (keV)} {U Intensity} {U Line} - 56FE T - 56FE T 6.39091 7.53 10 XKA2 - 56FE T 6.40391 14.75 17 XKA1 - 56FE T - 56FE T 7.05804 |] 3.05 5 XKB1 - 56FE T 7.1083 |] XKB5II - 56FE T - 56FE T - 56FE T 0.615-0.792 0.581 17 XL (total) - 56FE T 0.615 XLL - 56FE T -0.792 XLB - 56FE T - 56FE T 5.37-5.645 |] KLL AUGER - 56FE T 6.158-6.4 |] 46.04 30 KLX AUGER - 56FE T 6.926-7.105 |] KXY AUGER - 56FE T 0.51-0.594 111.8 8 L AUGER - 56CO P 0.0 4+ 77.236 D 26 4566 2 - 56FE N 1.0 1.0 1 1.0 - 56FE L 0 0+ STABLE - 56FE L 846.7700 192+ - 56FE E 0.25 170.005 311.6 2 - 56FE2 E EAV=1205.8 10$CK=0.8890 16$CL=0.0951 13$CM=0.0152 5 - 56FE G 846.7638 1999.9399 23E2 3.03E-4 9 - 56FE L 2085.0583 254+ - 56FE E 18.29 162.43 38.62 - 56FE2 E EAV=631.2 9$CK=0.8888 16$CL=0.0952 13$CM=0.0152 5 - 56FE G 1238.2736 2266.41 16E2 - 56FE L 2657.527 4 2+ - 56FE G 1810.726 4 0.639 3M1+E2 -0.17 3 - 56FE G 2657.4 8 0.0195 20[E2] - 56FE L 2959.905 5 2+ - 56FE E 0.0086 220.023 610.26 2 - 56FE2 E EAV=247.1 9$CK=0.8885 16$CL=0.0955 13$CM=0.0153 5 - 56FE G 2113.092 6 0.376 3M1+E2 0.27 3 - 56FE L 3122.901 3 4+ - 56FE E 1.04 28.99 67.58 - 56FE2 E EAV=178.7 8$CK=0.8884 16$CL=0.0955 13$CM=0.0153 5 - 56FE G 1037.8333 2414.03 5M1(+E2) 0.00 5 - 56FE G 2276.36 160.118 4E2 - 56FE L 3369.86 112+ - 56FE E 0.000006200.015 510.2 2 - 56FE2 E EAV=76.7 8$CK=0.8883 16$CL=0.0957 13$CM=0.0153 5 - 56FE G 2523.0 8 0.063 4M1+E2 0.25 15 - 56FE G 3369.69 300.0103 8E2 - 56FE L 3445.270 3 3+ - 56FE E 0.0080 721.40 56.98 - 56FE2 E EAV=45.3 9$CK=0.8882 16$CL=0.0957 13$CM=0.0153 5 - 56FE G 787.7391 230.310 4M1+E2 0.85 35 - 56FE G 1360.1960 404.280 13M1+E2 -0.11 1 - 56FE G 2598.438 4 16.96 4M1+E2 -0.28 2 - 56FE L 3856.415 3 3+ - 56FE E 16.86 56.69 - 56FE2 E CK=0.8875 16$CL=0.0963 13$CM=0.0154 5 - 56FE G 411.38 8 0.0269 23 - 56FE G 486.54 110.058 3 - 56FE G 733.5085 230.191 4M1+E2 -0.02 2 - 56FE G 896.503 7 0.0704 22 - 56FE G 1198.78 200.044 3 - 56FE G 1771.3270 3015.45 4M1+E2 -0.004 2 - 56FE G 3009.559 4 1.038 19M1+E2 0.065 5 - 56FE L 4048.799 8 3+ - 56FE E 3.965 157.04 - 56FE2 E CK=0.8868 16$CL=0.0969 13$CM=0.0155 5 - 56FE G 1089.03 240.054 4M1+E2 0.43 12 - 56FE G 1963.703 110.706 4M1+E2 0.22 3 - 56FE G 3201.930 113.203 13M1+E2 0.50 1 - 56FE L 4100.273 4 4+ 55 FS 25 - 56FE E 12.66 46.44 - 56FE2 E CK=0.8866 16$CL=0.0971 13$CM=0.0156 5 - 56FE G 655.0 8 0.038 8 - 56FE G 977.363 4 1.422 7M1(+E2) 0.07 3 - 56FE G 1140.356 7 0.132 4 - 56FE G 1442.75 8 0.180 4 - 56FE G 2015.176 5 3.017 14M1+E2 0.68 5 - 56FE G 3253.402 5 7.87 3E2 - 56FE L 4119.849 4 3+ - 56FE E 9.940 186.51 - 56FE2 E CK=0.8864 16$CL=0.0972 13$CM=0.0156 5 - 56FE G 263.41 100.0234 20 - 56FE G 674.7 8 0.035 5 - 56FE G 996.939 5 0.116 6M1+E2 - 56FE G 1159.933 8 0.088 3M1+E2 0.064 16 - 56FE G 1462.34 120.0778 9 - 56FE G 2034.752 5 7.741 13M1+E2 -0.073 5 - 56FE G 3272.978 6 1.855 9M1+E2 0.420 4 - 56FE L 4298.002 3 4+ 110 FS 50 - 56FE E 3.688 136.49 - 56FE2 E CK=0.8845 16$CL=0.0989 13$CM=0.0159 5 - 56FE G 852.78 5 0.049 3 - 56FE G 1175.0878 222.249 9M1+E2 0.14 4 - 56FE G 1640.450 5 0.0621 21 - 56FE G 2212.8980 300.385 5M1+E2 -3 1 - 56FE G 3451.119 4 0.942 6E2 - 56FE L 4394.82 6 3+ - 56FE E 0.2159 187.32 - 56FE2 E CK=0.8816 17$CL=0.1013 13$CM=0.0164 6 - 56FE G 1272.2 6 0.0202 8 - 56FE G 3547.93 6 0.1956 16M1+E2 -0.30 2 - 56FE L 4447.6 4 (2-,3,4)+ - 56FE E 0.0167 58.1 2 - 56FE2 E CK=0.8779 17$CL=0.1044 14$CM=0.0169 6 - 56FE G 3600.71 400.0167 5 - 56FE L 4458.30 3 4+ - 56FE E 0.209 76.91 - 56FE2 E CK=0.8766 17$CL=0.1055 14$CM=0.0171 6 - 56FE G 1335.380 290.1228 16 - 56FE G 2373.70 400.078 6 - 56FE G 3611.8 8 0.0084 4[E2] - + 56FE 56CO EC DECAY (77.236 D) + 56FE C References:1977La19, 1979Sc31, 1999Hu04, 2000He14, 2000Ra36, 2002Ba38, + 56FE2C 2003Mo**, 2003Au03 + 56FE T Auger electrons and X ray energies and emission intensities: + 56FE T {U Energy (keV)} {U Intensity} {U Line} + 56FE T + 56FE T 6.39091 7.53 10 XKA2 + 56FE T 6.40391 14.75 17 XKA1 + 56FE T + 56FE T 7.05804 |] 3.05 5 XKB1 + 56FE T 7.1083 |] XKB5II + 56FE T + 56FE T + 56FE T 0.615-0.792 0.581 17 XL (total) + 56FE T 0.615 XLL + 56FE T -0.792 XLB + 56FE T + 56FE T 5.37-5.645 |] KLL AUGER + 56FE T 6.158-6.4 |] 46.04 30 KLX AUGER + 56FE T 6.926-7.105 |] KXY AUGER + 56FE T 0.51-0.594 111.8 8 L AUGER + 56CO P 0.0 4+ 77.236 D 26 4566 2 + 56FE N 1.0 1.0 1 1.0 + 56FE L 0 0+ STABLE + 56FE L 846.7700 192+ + 56FE E 0.25 170.005 311.6 2 + 56FE2 E EAV=1205.8 10$CK=0.017431 31$CL=0.001865 25$CM=0.000298 10 + 56FE G 846.7638 1999.9399 23E2 3.03E-4 9 + 56FE L 2085.0583 254+ + 56FE E 18.29 162.43 38.62 + 56FE2 E EAV=631.2 9$CK=0.10424 19$CL=0.01116 15$CM=0.00178 6 + 56FE G 1238.2736 2266.41 16E2 + 56FE L 2657.527 4 2+ + 56FE G 1810.726 4 0.639 3M1+E2 -0.17 3 + 56FE G 2657.4 8 0.0195 20[E2] + 56FE L 2959.905 5 2+ + 56FE E 0.0086 220.023 610.26 2 + 56FE2 E EAV=247.1 9$CK=0.6467 12$CL=0.0695 9$CM=0.01114 36 + 56FE G 2113.092 6 0.376 3M1+E2 0.27 3 + 56FE L 3122.901 3 4+ + 56FE E 1.04 28.99 67.58 + 56FE2 E EAV=178.7 8$CK=0.7963 14$CL=0.0856 12$CM=0.01371 45 + 56FE G 1037.8333 2414.03 5M1(+E2) 0.00 5 + 56FE G 2276.36 160.118 4E2 + 56FE L 3369.86 112+ + 56FE E 0.000006200.015 510.2 2 + 56FE2 E EAV=76.7 8$CK=0.8879 16$CL=0.0957 13$CM=0.01529 50 + 56FE G 2523.0 8 0.063 4M1+E2 0.25 15 + 56FE G 3369.69 300.0103 8E2 + 56FE L 3445.270 3 3+ + 56FE E 0.0080 721.40 56.98 + 56FE2 E EAV=45.3 9$CK=0.8879 16$CL=0.0957 13$CM=0.01529 50 + 56FE G 787.7391 230.310 4M1+E2 0.85 35 + 56FE G 1360.1960 404.280 13M1+E2 -0.11 1 + 56FE G 2598.438 4 16.96 4M1+E2 -0.28 2 + 56FE L 3856.415 3 3+ + 56FE E 16.86 56.69 + 56FE2 E CK=0.8875 16$CL=0.0963 13$CM=0.0154 5 + 56FE G 411.38 8 0.0269 23 + 56FE G 486.54 110.058 3 + 56FE G 733.5085 230.191 4M1+E2 -0.02 2 + 56FE G 896.503 7 0.0704 22 + 56FE G 1198.78 200.044 3 + 56FE G 1771.3270 3015.45 4M1+E2 -0.004 2 + 56FE G 3009.559 4 1.038 19M1+E2 0.065 5 + 56FE L 4048.799 8 3+ + 56FE E 3.965 157.04 + 56FE2 E CK=0.8868 16$CL=0.0969 13$CM=0.0155 5 + 56FE G 1089.03 240.054 4M1+E2 0.43 12 + 56FE G 1963.703 110.706 4M1+E2 0.22 3 + 56FE G 3201.930 113.203 13M1+E2 0.50 1 + 56FE L 4100.273 4 4+ 55 FS 25 + 56FE E 12.66 46.44 + 56FE2 E CK=0.8866 16$CL=0.0971 13$CM=0.0156 5 + 56FE G 655.0 8 0.038 8 + 56FE G 977.363 4 1.422 7M1(+E2) 0.07 3 + 56FE G 1140.356 7 0.132 4 + 56FE G 1442.75 8 0.180 4 + 56FE G 2015.176 5 3.017 14M1+E2 0.68 5 + 56FE G 3253.402 5 7.87 3E2 + 56FE L 4119.849 4 3+ + 56FE E 9.940 186.51 + 56FE2 E CK=0.8864 16$CL=0.0972 13$CM=0.0156 5 + 56FE G 263.41 100.0234 20 + 56FE G 674.7 8 0.035 5 + 56FE G 996.939 5 0.116 6M1+E2 + 56FE G 1159.933 8 0.088 3M1+E2 0.064 16 + 56FE G 1462.34 120.0778 9 + 56FE G 2034.752 5 7.741 13M1+E2 -0.073 5 + 56FE G 3272.978 6 1.855 9M1+E2 0.420 4 + 56FE L 4298.002 3 4+ 110 FS 50 + 56FE E 3.688 136.49 + 56FE2 E CK=0.8845 16$CL=0.0989 13$CM=0.0159 5 + 56FE G 852.78 5 0.049 3 + 56FE G 1175.0878 222.249 9M1+E2 0.14 4 + 56FE G 1640.450 5 0.0621 21 + 56FE G 2212.8980 300.385 5M1+E2 -3 1 + 56FE G 3451.119 4 0.942 6E2 + 56FE L 4394.82 6 3+ + 56FE E 0.2159 187.32 + 56FE2 E CK=0.8816 17$CL=0.1013 13$CM=0.0164 6 + 56FE G 1272.2 6 0.0202 8 + 56FE G 3547.93 6 0.1956 16M1+E2 -0.30 2 + 56FE L 4447.6 4 (2-,3,4+) + 56FE E 0.0167 58.1 2 + 56FE2 E CK=0.8779 17$CL=0.1044 14$CM=0.0169 6 + 56FE G 3600.71 400.0167 5 + 56FE L 4458.30 3 4+ + 56FE E 0.209 76.91 + 56FE2 E CK=0.8766 17$CL=0.1055 14$CM=0.0171 6 + 56FE G 1335.380 290.1228 16 + 56FE G 2373.70 400.078 6 + 56FE G 3611.8 8 0.0084 4[E2] + diff --git a/HEN_HOUSE/spectra/lnhb/Co-57.txt b/HEN_HOUSE/spectra/lnhb/Co-57.txt index aff841dfa..bdf7cbd40 100644 --- a/HEN_HOUSE/spectra/lnhb/Co-57.txt +++ b/HEN_HOUSE/spectra/lnhb/Co-57.txt @@ -1,54 +1,69 @@ - 57FE 57CO EC DECAY (271.80 D) - 57FE C References: 1977La19 - 57FE T Auger electrons and X ray energies and emission intensities: - 57FE T {U Energy (keV)} {U Intensity} {U Line} - 57FE T - 57FE T 6.39091 16.8 3 XKA2 - 57FE T 6.40391 33.2 5 XKA1 - 57FE T - 57FE T 7.05804 |] 7.1 2 XKB1 - 57FE T 7.1083 |] XKB5II - 57FE T - 57FE T - 57FE T 0.61-0.79 1.55 13 XL (total) - 57FE T 0.61 XLL - 57FE T -0.79 XLB - 57FE T - 57FE T 5.37-5.64 |] KLL AUGER - 57FE T 6.16-6.4 |] 105.2 13 KLX AUGER - 57FE T 6.91-7.1 |] KXY AUGER - 57FE T 0.6-0.7 252 3 L AUGER - 57CO P 0.0 7/2- 271.80 D 5 836.0 4 - 57FE N 1.0 1.0 1 1.0 - 57FE L 0 1/2- STABLE - 57FE E 0.00035 12.9 2U - 57FE L 14.41295 313/2- 98.0 NS 3 - 57FE E 0.003 11.1 2 - 57FE G 14.41295 319.15 17M1+E2 8.58 18 - 57FE2 G KC=7.69 16$LC=0.782 16$MC=0.113 3 - 57FE L 136.47374 295/2- 8.8 NS 5 - 57FE E 99.82 206.45 - 57FE2 E CK=0.8875 16$CL=0.0963 13$CM=0.0154 5 - 57FE G 122.06065 1285.51 6M1+E2 0.0236 5 - 57FE2 G KC=0.0212 5$LC=0.00208 5$MC=3.03E-4 7 - 57FE G 136.47356 2910.71 15E2 0.148 3 - 57FE2 G KC=0.133 3$LC=0.0136 3$MC=0.00196 4 - 57FE L 366.74 3 3/2- - 57FE E 0.002 10.8 2 - 57FE G 230.27 3 0.0004 4M1+E2 0.00415 9 - 57FE2 G KC=0.00374 8$LC=3.56E-4 8$MC=5.24E-5 11 - 57FE G 352.34 2 0.0032 4M1+E2 0.00150 3 - 57FE2 G KC=0.00135 3$LC=1.29E-4 3$MC=1.88E-5 4 - 57FE G 366.74 3 0.0013 4M1+E2 0.00178 6 - 57FE2 G KC=0.00160 5$LC=1.53E-4 5$MC=2.23E-5 7 - 57FE L 706.42 2 5/2- - 57FE E 0.183 77.69 - 57FE2 E CK=0.8789 17$CL=0.1035 14$CM=0.0168 6 - 57FE G 339.67 3 0.0038 4M1+E2 0.00165 4 - 57FE2 G KC=0.00149 3$LC=1.42E-4 3$MC=2.08E-5 5 - 57FE G 569.94 4 0.015 2M1+E2 5.08E-412 - 57FE2 G KC=4.58E-4 10$LC=4.34E-5 9$MC=6.31E-6 14 - 57FE G 692.01 2 0.159 6M1+E2 3.64E-412 - 57FE2 G KC=3.28E-4 10$LC=3.1E-5 1$MC=4.52E-6 14 - 57FE G 706.42 2 0.0050 5(E2) - + 57FE 57CO EC DECAY (271.81 D) + 57FE H TYP=UPD$AUT=V.P. CHECHEV, N.K. KUZMENKO$CUT=01-AUG-2014$ + 57FE2 H TYP=FUL$AUT=V.P. CHECHEV, N.K. KUZMENKO$CUT=01-OCT-2001$ + 57FE C References:1955Co31, 1960Fe06, 1961Cl11, 1961Ho05, 1965Mo22, 1965An07, + 57FE2C 1965Ma38, 1965Ki03, 1966Sp06, 1966Ec05, 1967Be65, 1967Ha06, 1968Ru04, + 57FE3C 1969JA18, 1969Ho28, 1969Bo49, 1970Jo30, 1970Gr13, 1971Ko19, 1971Po05, + 57FE4C 1972Kr15, 1972He42, 1972Fo05, 1972La14, 1972Em01, 1973Mu**, 1973Sc15, + 57FE5C 1974HeYW, 1974Ti01, 1975Co22, 1976Bo16, 1976Ba63, 1977La19, 1978Vy**, + 57FE6C 1978AlZX, 1978Kr19, 1980Sc07, 1980Ho17, 1980Ve05, 1981Va11, 1982Gr10, + 57FE7C 1983Wa26, 1985HaZA, 1989De**, 1990Si03, 1992ScZZ, 1992Un01, 1994Ar22, + 57FE8C 1995Ah04, 1996Me11, 1996Sc06, 1997Ma75, 1997KoZJ, 1997Lépy, 1998Be**, + 57FE9C 1998Sc28, 1998Bh11, 2000He14, 2002Ba85, 2004BeZR, 2006Mo26, 2008Ki07, + 57FEAC 2012Fi12, 2012Wa38, 2012Da06, 2014Un01 + 57FE T Auger electrons and X ray energies and emission intensities: + 57FE T {U Energy (keV)} {U Intensity} {U Line} + 57FE T + 57FE T 6.39091 17.12 26 XKA2 + 57FE T 6.40391 33.5 5 XKA1 + 57FE T + 57FE T 7.05804 |] 6.93 13 XKB1 + 57FE T 7.1083 |] XKB5II + 57FE T + 57FE T + 57FE T 0.617-0.7938 1.30 4 XL (total) + 57FE T 0.617 0.0662 27 XLL + 57FE T 0.7075-0.7084 0.699 26 XLA + 57FE T 0.6306 0.0422 19 XLC + 57FE T 0.7148-0.7938 0.492 21 XLB + 57FE T 0.72841-0.72841 0.0037 4 XLG + 57FE T + 57FE T 5.37-5.645 |] KLL AUGER + 57FE T 6.158-6.4 |] 104.6 11 KLX AUGER + 57FE T 6.926-7.105 |] KXY AUGER + 57FE T 0.5223-0.8421 250.6 16 L AUGER + 57CO P 0.0 7/2- 271.81 D 4 836.2 5 + 57FE N 1.0 1.0 1 1.0 + 57FE L 0 1/2- STABLE + 57FE E 0.00035 12.9 2U + 57FE L 14.41295 313/2- 98.0 NS 4 + 57FE E 0.0003 311.1 2 + 57FE G 14.41295 319.18 12M1+E2 0.00223 18 8.55 12 + 57FE2 G KC=7.65 11$LC=0.787 11$MC=0.1082 16$NC=0.00470 7 + 57FE L 136.47374 295/2- 8.6 NS 4 + 57FE E 99.80 236.45 + 57FE2 E CK=0.8875 16$CL=0.0963 14$CM=0.0154 5 + 57FE G 122.06065 1285.49 14M1+E2 0.1180 12 0.0236 4 + 57FE2 G KC=0.0212 3$LC=0.00211 3$MC=0.000290 5$NC=1.293E-5 19 + 57FE G 136.47356 2910.71 15E2 0.1487 21 + 57FE2 G KC=0.1331 19$LC=0.01371 20$MC=0.00187 3$NC=7.65E-5 11 + 57FE L 366.74 3 3/2- 10.5 PS 14 + 57FE E 0.002 210.8 2 + 57FE G 230.27 3 0.0004 4M1+E2 0.02 0.00416 6 + 57FE2 G KC=0.00375 6$LC=0.000364 5$MC=5.01E-5 7$NC=2.30E-6 4 + 57FE G 352.34 2 0.0032 4M1+E2 0.025 9 1503E-622 + 57FE2 G KC=0.001354 19$LC=1.303E-4 19$MC=1.80E-5 3$NC=8.28E-7 12 + 57FE G 366.74 3 0.0013 4M1+E2 0.45 5 0.00178 9 + 57FE2 G KC=0.00160 8$LC=0.000155 8$MC=2.13E-5 10$NC=9.7E-7 5 + 57FE L 706.42 2 5/2- 4.1 PS 11 + 57FE E 0.183 77.69 + 57FE2 E CK=0.8789 17$CL=0.1035 14$CM=0.0168 6 + 57FE G 339.67 3 0.0038 4M1+E2 0.083 5 1659E-624 + 57FE2 G KC=0.001494 21$LC=1.439E-4 21$MC=1.98E-5 3$NC=9.13E-7 13 + 57FE G 569.94 4 0.015 2M1+E2 0.097 8 5.10E-4 8 + 57FE2 G KC=0.000460 7$LC=4.40E-5 7$MC=6.06E-6 9$NC=2.81E-7 4 + 57FE G 692.01 2 0.159 6M1+E2 0.465 8 3.65E-4 6 + 57FE2 G KC=0.000329 5$LC=3.15E-5 5$MC=4.33E-6 7$NC=2.01E-7 3 + 57FE G 706.415 200.0050 5E2 4.83E-4 7 + 57FE2 G KC=0.000435 6$LC=4.18E-5 6$MC=5.75E-6 8$NC=2.64E-7 4 + diff --git a/HEN_HOUSE/spectra/lnhb/Co-58.txt b/HEN_HOUSE/spectra/lnhb/Co-58.txt index fd26cd890..3bec47823 100644 --- a/HEN_HOUSE/spectra/lnhb/Co-58.txt +++ b/HEN_HOUSE/spectra/lnhb/Co-58.txt @@ -1,56 +1,50 @@ - 58FE 58CO EC DECAY (70.85 D) - 58FE H TYP=Full$AUT=M.M. Bé$CUT=31-AUG-2013$ - 58FE2 H TYP=Full$AUT=M.M. Bé$CUT=30-NOV-1998$ - 58FE C Evaluation history: Type=Full;Author=M.M. Bé;Cutoff date=31-AUG-2013 - 58FE2C Type=Full;Author=M.M. Bé;Cutoff date=30-NOV-1998 - 58FE C References: 1946Go01, 1946Go01, 1952Ch31, 1956Fr17, 1956Sc87, 1956Gr**, - 58FE2C 1956Co70, 1956Gr**, 1956Sc87, 1956Co70, 1956Fr17, 1958Ko64, 1958Da03, - 58FE3C 1958Da03, 1958Ko64, 1961Ra13, 1961Ra13, 1962Ma33, 1962Ma33, 1962Fr13, - 58FE4C 1963Mo12, 1964Ma09, 1964Ma09, 1965Hi12, 1965Hi12, 1966Ra22, 1966Ra22, - 58FE5C 1966Bi13, 1966Bi13, 1968Ri03, 1968Ba49, 1968De08, 1968Ri03, 1968Ba49, - 58FE6C 1968De08, 1969GuZV, 1969Fa05, 1969Si13, 1969Sc11, 1969Si13, 1969Fa05, - 58FE7C 1969Sc11, 1969GuZV, 1970Wi14, 1970Wi14, 1971GoYM, 1971Si15, 1971GoYM, - 58FE8C 1971Si15, 1972We17, 1972DyZV, 1972Fo05, 1972DyZV, 1972Cr02, 1972Cr02, - 58FE9C 1972We17, 1972Fo05, 1973ArZI, 1973Ba67, 1973Ba67, 1973ArZI, 1975La16, - 58FE10C 1975La16, 1976Va30, 1976Va30, 1974HeYW, 1974HeYW, 1979Gr01, 1980Ho17, - 58FE11C 1980Ho17, 1982Gr10, 1982HoZJ, 1982HoZJ, 1982Gr10, 1992Sy**, 1992So04, - 58FE12C 1992Sy**, 1992So04, 1996Sc06, 1996Sc06, 2000He14, 2000He14, 2002Ba85, - 58FE13C 2002Ba85, 2003Au03, 2003Au03, 2008Ki07, 2008Ki07, 2010Ne01, 2010Ne01, - 58FE14C 2012Wa38, 2012Fi12, 2012Wa38, 2012Fi12 - 58FE T Auger electrons and X ray energies and emission intensities: - 58FE T {U Energy (keV)} {U Intensity} {U Line} - 58FE T - 58FE T 6.39091 7.98 11 XKA2 - 58FE T 6.40391 15.63 19 XKA1 - 58FE T - 58FE T 7.0581 |] 3.23 5 XKB1 - 58FE T 7.1083 |] XKB5II - 58FE T - 58FE T - 58FE T 0.617-0.8454 0.609 18 XL (total) - 58FE T 0.617 0.0309 13 XLL - 58FE T 0.7075-0.7084 0.327 12 XLA - 58FE T 0.6306 0.0197 9 XLC - 58FE T 0.7148-0.8454 0.229 10 XLB - 58FE T 0.7284-0.7284 0.00172 19 XLG - 58FE T - 58FE T 5.37-5.65 |] KLL AUGER - 58FE T 6.16-6.4 |] 48.8 4 KLX AUGER - 58FE T 6.93-7.11 |] KXY AUGER - 58FE T 0.52-0.84 116.9 7 L AUGER - 58CO P 0.0 2+ 70.85 D 3 2307.9 11 - 58FE N 1.0 1.0 1 1.0 - 58FE L 0 0+ STABLE - 58FE L 810.7662 202+ 6.54 PS 19 - 58FE E 14.94 1683.83 166.6 - 58FE2 E EAV=201.3 5$CK=0.8885 16$CL=0.0955 13$CM=0.0153 5$CN=0.0007 2 - 58FE G 810.7602 2099.44 2E2 3.32E-4 5 - 58FE2 G KC=2.99E-4 5$LC=2.87E-5 4 - 58FE L 1674.731 6 2+ 1.6 PS 4 - 58FE E 1.228 357.7 - 58FE2 E CK=0.8873 16$CL=0.0965 13$CM=0.0155 5$CN=0.0007 2 - 58FE G 863.958 6 0.700 22M1+E2 0.643 41 2.31E-4 4 - 58FE2 G KC=2.08E-4 4$LC=1.99E-5 4 - 58FE G 1674.705 6 0.528 13E2 2.25E-4 4 - 58FE2 G KC=5.77E-5 8$LC=5.47E-6 8 - + 58FE 58CO EC DECAY (70.85 D) + 58FE H TYP=FUL$AUT=M.-M.BE$CUT=31-AUG-2013$ + 58FE2 H TYP=FUL$AUT=M.-M.BE$CUT=30-NOV-1998$ + 58FE C References:1946Go01, 1952Ch31, 1956Fr17, 1956Sc87, 1956Co70, 1956Gr**, + 58FE2C 1958Da03, 1958Ko64, 1961Ra13, 1962Fr13, 1962Ma33, 1963Mo12, 1964Ma09, + 58FE3C 1965Hi12, 1966Ra22, 1966Bi13, 1968Ri03, 1968De08, 1968Ba49, 1969Sc11, + 58FE4C 1969GuZV, 1969Si13, 1969Fa05, 1970Wi14, 1971Si15, 1971GoYM, 1972DyZV, + 58FE5C 1972We17, 1972Cr02, 1972Fo05, 1973Ba67, 1973ArZI, 1975La16, 1976Va30, + 58FE6C 1974HeYW, 1979Gr01, 1980Ho17, 1982HoZJ, 1982Gr10, 1992So04, 1992Sy**, + 58FE7C 1996Sc06, 2000He14, 2002Ba85, 2003Au03, 2008Ki07, 2010Ne01, 2012Fi12, + 58FE8C 2012Wa38 + 58FE T Auger electrons and X ray energies and emission intensities: + 58FE T {U Energy (keV)} {U Intensity} {U Line} + 58FE T + 58FE T 6.39091 7.98 11 XKA2 + 58FE T 6.40391 15.63 19 XKA1 + 58FE T + 58FE T 7.0581 |] 3.23 5 XKB1 + 58FE T 7.1083 |] XKB5II + 58FE T + 58FE T + 58FE T 0.617-0.8454 0.609 18 XL (total) + 58FE T 0.617 0.0309 13 XLL + 58FE T 0.7075-0.7084 0.327 12 XLA + 58FE T 0.6306 0.0197 9 XLC + 58FE T 0.7148-0.8454 0.229 10 XLB + 58FE T 0.7284-0.7284 0.00172 19 XLG + 58FE T + 58FE T 5.37-5.65 |] KLL AUGER + 58FE T 6.16-6.4 |] 48.8 4 KLX AUGER + 58FE T 6.93-7.11 |] KXY AUGER + 58FE T 0.52-0.84 116.9 7 L AUGER + 58CO P 0.0 2+ 70.85 D 3 2307.9 11 + 58FE N 1.0 1.0 1 1.0 + 58FE L 0 0+ STABLE + 58FE L 810.7662 202+ 6.54 PS 19 + 58FE E 14.94 1683.83 166.6 + 58FE2 E EAV=201.3 5$CK=0.7541 14$CL=0.0811 11$CM=0.01299 42 + 58FE3 E CN=0.00059 17 + 58FE G 810.7602 2099.44 2E2 3.32E-4 5 + 58FE2 G KC=0.000299 5$LC=2.87E-5 4 + 58FE L 1674.731 6 2+ 1.6 PS 4 + 58FE E 1.228 357.7 + 58FE2 E CK=0.8873 16$CL=0.0965 13$CM=0.0155 5$CN=0.0007 2 + 58FE G 863.958 6 0.700 22M1+E2 0.643 41 2.31E-4 4 + 58FE2 G KC=0.000208 4$LC=1.99E-5 4 + 58FE G 1674.705 6 0.528 13E2 2.25E-4 4 + 58FE2 G KC=5.77E-5 8$LC=5.47E-6 8 + 58FE3 G IPC=1.606E-4 23 + diff --git a/HEN_HOUSE/spectra/lnhb/Co-60.txt b/HEN_HOUSE/spectra/lnhb/Co-60.txt index d7e48e9f7..02617190b 100644 --- a/HEN_HOUSE/spectra/lnhb/Co-60.txt +++ b/HEN_HOUSE/spectra/lnhb/Co-60.txt @@ -1,50 +1,50 @@ - 60NI 60CO B- DECAY (5.2711 Y) - 60NI H TYP=Update$AUT=M.-M.Bé$CUT=16-JAN-2006$ - 60NI2 H TYP=Full$AUT=R.G.Helmer$CUT=01-JAN-1998$ - 60NI C Evaluation history: Type=Update;Author=M.-M.Bé;Cutoff date=16-JAN-2006 - 60NI2C Type=Full;Author=R.G.Helmer;Cutoff date=01-JAN-1998 - 60NI C References: 2002Ba85 - 60NI T Auger electrons and X ray energies and emission intensities: - 60NI T {U Energy (keV)} {U Intensity} {U Line} - 60NI T - 60NI T 7.46097 0.00334 12 XKA2 - 60NI T 7.47824 0.0065 3 XKA1 - 60NI T - 60NI T 8.2647 |] XKB3 - 60NI T |] 0.00136 5 XKB1 - 60NI T 8.3287 |] XKB5II - 60NI T - 60NI T - 60NI T 0.74-0.94 0.0002 XL (total) - 60NI T 0.74 XLL - 60NI T -0.94 XLG - 60NI T - 60NI T 6.26-6.54 |] KLL AUGER - 60NI T 7.2-7.47 |] 0.0154 5 KLX AUGER - 60NI T 8.1-8.32 |] KXY AUGER - 60NI T 0.7-0.9 0.0392 12 L AUGER - 60CO P 0.0 5+ 5.2711 Y 8 2823.07 21 - 60NI N 1.0 1.0 1 1.0 - 60NI L 0 0+ STABLE - 60NI L 1332.508 4 2+ 0.713 PS 11 - 60NI B 1490.56 210.12 3 14.7 2U - 60NIS B EAV=625.6 1 - 60NI G 1332.492 4 99.9826 6E2 1.28E-4 5 - 60NI2 G KC=1.15E-4 5$LC=1.13E-5 3 - 60NI L 2158.61 3 2+ 0.59 PS 17 - 60NI B 664.46 210.002 2U - 60NIS B EAV=274.8 1 - 60NI G 826.10 3 0.0076 8M1+E2 0.9 3 0.00034 4 - 60NI2 G KC=0.00030 4$LC=2.91E-5 17 - 60NI G 2158.57 3 0.0012 2E2 4.95E-515 - 60NI2 G KC=4.45E-5 14$LC=4.3E-6 2 - 60NI L 2505.748 5 4+ 0.30 PS 9 - 60NI B 317.32 2199.88 3 7.51 - 60NIS B EAV=95.6 1 - 60NI G 347.14 7 0.0075 4[E2] 0.0055717 - 60NI2 G KC=0.00499 15$LC=5.03E-4 15 - 60NI G 1173.228 3 99.85 3E2(+M3) 1.68E-4 4 - 60NI2 G KC=1.51E-4 7$LC=1.48E-5 4 - 60NI G 2505.692 5 2.0E-6 4E4 8.6E-5 3 - 60NI2 G KC=7.80E-5 3$LC=7.6E-6 3 - + 60NI 60CO B- DECAY (5.2711 Y) + 60NI H TYP=UPD$AUT=M.-M.BE$CUT=16-JAN-2006$ + 60NI2 H TYP=FUL$AUT=R.G.HELMER$CUT=01-JAN-1998$ + 60NI C References:2002Ba85 + 60NI T Auger electrons and X ray energies and emission intensities: + 60NI T {U Energy (keV)} {U Intensity} {U Line} + 60NI T + 60NI T 7.46097 0.00334 12 XKA2 + 60NI T 7.47824 0.0065 3 XKA1 + 60NI T + 60NI T 8.2647 |] XKB3 + 60NI T |] 0.00136 5 XKB1 + 60NI T 8.3287 |] XKB5II + 60NI T + 60NI T + 60NI T 0.74-0.94 0.0002 XL (total) + 60NI T 0.74 XLL + 60NI T -0.94 XLG + 60NI T + 60NI T 6.26-6.54 |] KLL AUGER + 60NI T 7.2-7.47 |] 0.0154 5 KLX AUGER + 60NI T 8.1-8.32 |] KXY AUGER + 60NI T 0.7-0.9 0.0392 12 L AUGER + 60CO P 0.0 5+ 5.2711 Y 8 2823.07 21 + 60NI N 1.0 1.0 1 1.0 + 60NI L 0 0+ STABLE + 60NI L 1332.508 4 2+ 0.713 PS 11 + 60NI B 1490.56 210.12 3 14.7 2U + 60NIS B EAV=625.6 1 + 60NI G 1332.492 4 99.9826 6E2 1.28E-4 5 + 60NI2 G KC=0.000115 5$LC=1.13E-5 3 + 60NI3 G IPC=0.000034 4 + 60NI L 2158.61 3 2+ 0.59 PS 17 + 60NI B 664.46 210.002 2U + 60NIS B EAV=274.8 1 + 60NI G 826.10 3 0.0076 8M1+E2 0.9 3 0.00034 4 + 60NI2 G KC=0.00030 4$LC=2.91E-5 17 + 60NI G 2158.57 3 0.0012 2E2 4.95E-515 + 60NI2 G KC=4.45E-5 14$LC=4.3E-6 2 + 60NI L 2505.748 5 4+ 0.30 PS 9 + 60NI B 317.32 2199.88 3 7.51 + 60NIS B EAV=95.6 1 + 60NI G 347.14 7 0.0075 4[E2] 0.0055717 + 60NI2 G KC=0.00499 15$LC=0.000503 15 + 60NI G 1173.228 3 99.85 3E2(+M3) 1.68E-4 4 + 60NI2 G KC=0.000151 7$LC=1.48E-5 4 + 60NI3 G IPC=6.2E-6 7 + 60NI G 2505.692 5 2.0E-6 4E4 8.6E-5 3 + 60NI2 G KC=7.80E-5 3$LC=7.6E-6 3 + diff --git a/HEN_HOUSE/spectra/lnhb/Cr-51.txt b/HEN_HOUSE/spectra/lnhb/Cr-51.txt index ce4c6170a..4fc3a690e 100644 --- a/HEN_HOUSE/spectra/lnhb/Cr-51.txt +++ b/HEN_HOUSE/spectra/lnhb/Cr-51.txt @@ -1,47 +1,44 @@ - 51V 51CR EC DECAY (27.704 D) - 51V H TYP=UPD$AUT=V.P.Chechev and N.K.Kuzmenko$CUT=31-MAR-2014$ - 51V 2 H TYP=ERR$AUT=M.-M.Be$CUT=28-FEB-2001$ - 51V 3 H TYP=FULL$AUT=R.G.Helmer and E.Schonfeld$CUT=28-FEB-2001$ - 51V C Evaluation history: Type=UPD;Author=V.P.Chechev and N.K.Kuzmenko;Cutoff date=31-MAR-2014 - 51V 2C Type=ERR;Author=M.-M.Be;Cutoff date=28-FEB-2001 - 51V 3C Type=FULL;Author=R.G.Helmer and E.Schonfeld;Cutoff date=28-FEB-2001 - 51V C References: 1940Wa02, 1948Mi12, 1948Ho04, 1952Ly17, 1955Co56, 1956Ka33, - 51V 2C 1956Sc87, 1957Ka65, 1957Wr37, 1960AD01, 1962RI09, 1963Ho17, 1963MeZZ, - 51V 3C 1964Ma56, 1965Dh01, 1965Le24, 1965Sa09, 1967LaZZ, 1968Bo25, 1969MeZV, - 51V 4C 1970MeZQ, 1970Wa**, 1971DaZM, 1972Em01, 1973De60, 1973ArZI, 1973La**, - 51V 5C 1973Vi13, 1974Ts01, 1975La16, 1980Sc07, 1980Ho17, 1982HoZJ, 1982DeYX, - 51V 6C 1982ChZF, 1983Wa26, 1984Fi10, 1991Ba11, 1992Un01, 1994Ko34, 1999Ka65, - 51V 7C 2002Un02, 2002Ba85, 2004BeZR, 2005Ya01, 2006Hu10, 2008Ki07, 2010Mo01, - 51V 8C 2012Wa38, 2012Fi12, 2014Un01 - 51V T Auger electrons and X ray energies and emission intensities: - 51V T {U Energy (keV)} {U Intensity} {U Line} - 51V T - 51V T 4.9447 6.79 14 XKA2 - 51V T 4.95224 13.36 27 XKA1 - 51V T - 51V T 5.42735 |] 2.69 7 XKB1 - 51V T 5.463 |] XKB5II - 51V T - 51V T - 51V T 0.4475-0.6268 0.56 12 XL (total) - 51V T 0.4475 XLL - 51V T 0.5135- XLA - 51V T 0.4557 XLC - 51V T 0.51938-0.6268 XLB - 51V T 0.52758-0.52758 XLG - 51V T - 51V T 4.164-4.395 |] KLL AUGER - 51V T 4.755-4.95 |] 66.4 5 KLX AUGER - 51V T 5.332-5.461 |] KXY AUGER - 51V T 0.3799-0.6257 146.0 6 L AUGER - 51CR P 0.0 7/2- 27.704 D 4 752.62 24 - 51V N 1.0 1.0 1 1.0 - 51V L 0 7/2- STABLE - 51V E 90.09 25.39 - 51V 2 E CK=0.8919 17$CL=0.0927 14$CM=0.0154 6 - 51V L 320.0835 4 5/2- 184 PS 6 - 51V E 9.91 25.86 - 51V 2 E CK=0.8910 17$CL=0.0935 14$CM=0.0156 6 - 51V G 320.0835 4 9.89 2M1+E2 0.465 20 0.00181 5 - 51V 2 G KC=0.00164 5$LC=1.51E-4 4$MC=1.98E-5 6 - + 51V 51CR EC DECAY (27.704 D) + 51V H TYP=UPD$AUT=V.P.CHECHEV, N.K.KUZMENKO$CUT=31-MAR-2014$ + 51V 2 H TYP=ERR$AUT=M.-M.BE$DAT=13-FEB-2004$COM=See DDEP website$ + 51V 3 H TYP=FUL$AUT=R.G.HELMER, E.SCHONFELD$CUT=28-FEB-2001$ + 51V C References:1940Wa02, 1948Mi12, 1948Ho04, 1952Ly17, 1955Co56, 1956Ka33, + 51V 2C 1956Sc87, 1957Ka65, 1957Wr37, 1960AD01, 1962RI09, 1963Ho17, 1963MeZZ, + 51V 3C 1964Ma56, 1965Dh01, 1965Le24, 1965Sa09, 1967LaZZ, 1968Bo25, 1969MeZV, + 51V 4C 1970MeZQ, 1970Wa**, 1971DaZM, 1972Em01, 1973De60, 1973ArZI, 1973La**, + 51V 5C 1973Vi13, 1974Ts01, 1975La16, 1980Sc07, 1980Ho17, 1982HoZJ, 1982DeYX, + 51V 6C 1982ChZF, 1983Wa26, 1984Fi10, 1991Ba11, 1992Un01, 1994Ko34, 1999Ka65, + 51V 7C 2002Un02, 2002Ba85, 2004BeZR, 2005Ya01, 2006Hu10, 2008Ki07, 2010Mo01, + 51V 8C 2012Wa38, 2012Fi12, 2014Un01 + 51V T Auger electrons and X ray energies and emission intensities: + 51V T {U Energy (keV)} {U Intensity} {U Line} + 51V T + 51V T 4.9447 6.79 14 XKA2 + 51V T 4.95224 13.36 27 XKA1 + 51V T + 51V T 5.42735 |] 2.69 7 XKB1 + 51V T 5.463 |] XKB5II + 51V T + 51V T + 51V T 0.4475-0.6268 0.56 12 XL (total) + 51V T 0.4475 XLL + 51V T 0.5135- XLA + 51V T 0.4557 XLC + 51V T 0.51938-0.6268 XLB + 51V T 0.52758-0.52758 XLG + 51V T + 51V T 4.164-4.395 |] KLL AUGER + 51V T 4.755-4.95 |] 66.4 5 KLX AUGER + 51V T 5.332-5.461 |] KXY AUGER + 51V T 0.3799-0.6257 146.0 6 L AUGER + 51CR P 0.0 7/2- 27.704 D 4 752.62 24 + 51V N 1.0 1.0 1 1.0 + 51V L 0 7/2- STABLE + 51V E 90.09 25.39 + 51V 2 E CK=0.8919 17$CL=0.0927 14$CM=0.0154 6 + 51V L 320.0835 4 5/2- 184 PS 6 + 51V E 9.91 25.86 + 51V 2 E CK=0.8910 17$CL=0.0935 14$CM=0.0156 6 + 51V G 320.0835 4 9.89 2M1+E2 0.465 20 0.00181 5 + 51V 2 G KC=0.00164 5$LC=0.000151 4$MC=1.98E-5 6$NC=1.01E-6 3 + diff --git a/HEN_HOUSE/spectra/lnhb/Cs-134.txt b/HEN_HOUSE/spectra/lnhb/Cs-134.txt index 0695ee9ba..c36f7e87f 100644 --- a/HEN_HOUSE/spectra/lnhb/Cs-134.txt +++ b/HEN_HOUSE/spectra/lnhb/Cs-134.txt @@ -1,103 +1,112 @@ -134XE 134CS EC DECAY (2.0644 Y) -134XE H TYP=Full$AUT=M.M. Bé$CUT=01-MAY-2012$ -134XE C Evaluation history: Type=Full;Author=M.M. Bé;Cutoff date=01-MAY-2012 -134XE C References: 1967Le18, 1968Ab01, 1972La14, 1973Di11, 1975Va12, 1987Wa28, -134XE2C 1988Ch44, 1997Ma75, 2002Un02, 2002Mi06, 2004So32, 2008Ki07, 2012Au06 -134XE T Auger electrons and X ray energies and emission intensities: -134XE T {U Energy (keV)} {U Intensity} {U Line} -134XE T -134XE T 29.459 XKA2 -134XE T 29.779 XKA1 -134XE T -134XE T 33.562 |] XKB3 -134XE T 33.625 |] XKB1 -134XE T 33.881 |] XKB5II -134XE T -134XE T 34.415 |] XKB2 -134XE T 34.496 |] XKB4 -134XE T 34.552 |] XKO23 -134XE T -134XE T -134XE T 23.512-24.842 |] KLL AUGER -134XE T 27.897-29.77 |] KLX AUGER -134XE T 32.27-34.54 |] KXY AUGER -134XE T 2.4848-5.3158 L AUGER -134CS P 0.0 4+ 2.0644 Y 14 1233.3 8 -134XE N 3.333E5 3.333E5 0.0000031 3.333E5 -134XE L 0 0+ STABLE -134XE L 847.041 232+ -134XE E 0.0003 113 2 -134XE2 E CK=0.8361 16$CL=0.1289 11$CM=0.0283 6$CN=0.0066 4 -134XE G 847.000 200.0003 1E2 - -134BA 134CS B- DECAY (2.0644 Y) -134BA H TYP=Full$AUT=M.M. Bé$CUT=01-MAY-2012$ -134BA C Evaluation history: Type=Full;Author=M.M. Bé;Cutoff date=01-MAY-2012 -134BA C References: 1967Le18, 1968Ab01, 1972La14, 1973Di11, 1975Va12, 1987Wa28, -134BA2C 1988Ch44, 1997Ma75, 2002Un02, 2002Mi06, 2004So32, 2008Ki07, 2012Au06 -134BA T Auger electrons and X ray energies and emission intensities: -134BA T {U Energy (keV)} {U Intensity} {U Line} -134BA T -134BA T 31.8174 0.2378 26 XKA2 -134BA T 32.1939 0.438 5 XKA1 -134BA T -134BA T 36.3045 |] XKB3 -134BA T 36.3786 |] 0.1289 19 XKB1 -134BA T 36.654 |] XKB5II -134BA T -134BA T 37.258 |] XKB2 -134BA T 37.312 |] 0.0325 8 XKB4 -134BA T 37.425 |] XKO23 -134BA T -134BA T 3.9544-5.8104 0.1058 17 XL (total) -134BA T 3.9544 0.00204 5 XLL -134BA T 4.4515-4.4666 0.0528 12 XLA -134BA T 4.3307 0.00077620 XLC -134BA T 4.8278-5.207 0.0435 8 XLB -134BA T 5.3715-5.8104 0.00675 14 XLG -134BA T -134BA T 25.314-26.786 |] KLL AUGER -134BA T 30.095-32.179 |] 0.093 4 KLX AUGER -134BA T 34.86-37.41 |] KXY AUGER -134BA T 2.66-5.81 0.850 5 L AUGER -134CS P 0.0 4+ 2.0644 Y 14 2058.98 33 -134BA N 1.00E0 1.00E0 0.9999971 1.00E0 -134BA L 0 0+ STABLE -134BA L 604.7223 192+ -134BA B 1454.26 330.06 6 13.1 2 -134BAS B EAV=535 1 -134BA G 604.7200 3097.63 8E2 0.00593 9 -134BA2 G KC=0.00503 7$LC=7.21E-4 10$MC=1495E-7 21 -134BA L 1167.968 3 2+ -134BA B 891.01 33 13 2 -134BAS B EAV=300 1 -134BA G 563.2460 308.342 15E2 0.0071410 -134BA2 G KC=0.00603 9$LC=8.81E-4 13$MC=1.83E-4 3 -134BA G 1167.967 4 1.791 5E2 1307E-619 -134BA2 G KC=1122E-6 16$LC=1444E-7 21$MC=2.97E-5 5 -134BA L 1400.590 4 4+ -134BA B 658.39 3370.19 8 8.89 -134BAS B EAV=210.3 4 -134BA G 795.860 1085.47 9E2 0.00302 5 -134BA2 G KC=0.00258 4$LC=3.51E-4 5$MC=7.24E-5 11 -134BA L 1643.336 4 3+ -134BA B 415.64 332.498 8 9.65 -134BAS B EAV=123.6 4 -134BA G 242.76 5 0.0241 31(M1+E2) 0.087 3 -134BA2 G KC=0.0722 12$LC=0.0120 25$MC=0.0025 6 -134BA G 475.365 2 1.479 7M1+()E2 6.0 35 0.0114 5 -134BA2 G KC=0.0096 4$LC=0.00146 3$MC=3.04E-4 6 -134BA G 1038.605 8 0.9909 33M1+()E2 0.71 14 0.00208 7 -134BA2 G KC=0.00179 6$LC=2.28E-4 7$MC=4.67E-5 13 -134BA L 1969.921 4 4+ -134BA B 89.06 3327.27 3 6.49 -134BAS B EAV=23.2 4 -134BA G 326.585 140.0171 11(M1+E2) 0.0367 22 -134BA2 G KC=0.031 3$LC=0.0047 3$MC=0.00097 8 -134BA G 569.330 2 15.368 21M1+()E2 0.28 2 0.0093614 -134BA2 G KC=0.00805 12$LC=1039E-6 15$MC=2.14E-4 3 -134BA G 801.950 6 8.694 16E2 0.00297 5 -134BA2 G KC=0.00254 4$LC=3.44E-4 5$MC=7.1E-5 1 -134BA G 1365.1940 403.019 8E2 9.87E-414 -134BA2 G KC=8.20E-4 12$LC=1039E-7 15$MC=2.13E-5 3 - +134XE 134CS EC DECAY (2.0644 Y) +134XE H TYP=FUL$AUT=M.-M.BE$CUT=01-MAY-2012$ +134XE C References:1967Le18, 1968Ab01, 1972La14, 1973Di11, 1975Va12, 1987Wa28, +134XE2C 1988Ch44, 1997Ma75, 2002Un02, 2002Mi06, 2004So32, 2008Ki07, 2012Au06 +134XE T Auger electrons and X ray energies and emission intensities: +134XE T {U Energy (keV)} {U Intensity} {U Line} +134XE T +134XE T 29.459 XKA2 +134XE T 29.779 XKA1 +134XE T +134XE T 33.562 |] XKB3 +134XE T 33.625 |] XKB1 +134XE T 33.881 |] XKB5II +134XE T +134XE T 34.415 |] XKB2 +134XE T 34.496 |] XKB4 +134XE T 34.552 |] XKO23 +134XE T +134XE T +134XE T 23.512-24.842 |] KLL AUGER +134XE T 27.897-29.77 |] KLX AUGER +134XE T 32.27-34.54 |] KXY AUGER +134XE T 2.4848-5.3158 L AUGER +134CS P 0.0 4+ 2.0644 Y 14 1233.3 8 +134XE N 3.333E5 3.333E5 0.000003 13.333E5 +134XE L 0 0+ STABLE +134XE L 847.041 232+ +134XE E 0.0003 113 2 +134XE2 E CK=0.8361 16$CL=0.1289 11$CM=0.0283 6$CN=0.0066 4 +134XE G 847.000 200.0003 1E2 + +134BA 134CS B- DECAY (2.0644 Y) +134BA H TYP=FUL$AUT=M.-M.BE$CUT=01-MAY-2012$ +134BA C References:1967Le18, 1968Ab01, 1972La14, 1973Di11, 1975Va12, 1987Wa28, +134BA2C 1988Ch44, 1997Ma75, 2002Un02, 2002Mi06, 2004So32, 2008Ki07, 2012Au06 +134BA T Auger electrons and X ray energies and emission intensities: +134BA T {U Energy (keV)} {U Intensity} {U Line} +134BA T +134BA T 31.8174 0.2378 26 XKA2 +134BA T 32.1939 0.438 5 XKA1 +134BA T +134BA T 36.3045 |] XKB3 +134BA T 36.3786 |] 0.1289 19 XKB1 +134BA T 36.654 |] XKB5II +134BA T +134BA T 37.258 |] XKB2 +134BA T 37.312 |] 0.0325 8 XKB4 +134BA T 37.425 |] XKO23 +134BA T +134BA T 3.9544-5.8104 0.1058 17 XL (total) +134BA T 3.9544 0.00204 5 XLL +134BA T 4.4515-4.4666 0.0528 12 XLA +134BA T 4.3307 0.00077620 XLC +134BA T 4.8278-5.207 0.0435 8 XLB +134BA T 5.3715-5.8104 0.00675 14 XLG +134BA T +134BA T 25.314-26.786 |] KLL AUGER +134BA T 30.095-32.179 |] 0.093 4 KLX AUGER +134BA T 34.86-37.41 |] KXY AUGER +134BA T 2.66-5.81 0.850 5 L AUGER +134CS P 0.0 4+ 2.0644 Y 14 2058.98 33 +134BA N 1.00E0 1.00E0 0.999997 11.00E0 +134BA L 0 0+ STABLE +134BA L 604.7223 192+ +134BA B 1454.26 330.06 6 13.1 2 +134BAS B EAV=535 1 +134BA G 604.7200 3097.63 8E2 0.00593 9 +134BA2 G KC=0.00503 7$LC=0.000721 10$MC=1.495E-4 21$NC=3.20E-5 5 +134BA3 G OC=4.79E-6 7 +134BA L 1167.968 3 2+ +134BA B 891.01 33 13 2 +134BAS B EAV=300 1 +134BA G 563.2460 308.342 15E2 0.0071410 +134BA2 G KC=0.00603 9$LC=0.000881 13$MC=0.000183 3$NC=3.91E-5 6 +134BA3 G OC=5.83E-6 9 +134BA G 1167.967 4 1.791 5E2 1307E-619 +134BA2 G KC=0.001122 16$LC=1.444E-4 21$MC=2.97E-5 5$NC=6.39E-6 9 +134BA3 G OC=9.74E-7 14 +134BA L 1400.590 4 4+ +134BA B 658.39 3370.19 8 8.89 +134BAS B EAV=210.3 4 +134BA G 795.860 1085.47 9E2 0.00302 5 +134BA2 G KC=0.00258 4$LC=0.000351 5$MC=7.24E-5 11$NC=1.554E-5 22 +134BA3 G OC=2.35E-6 4 +134BA L 1643.336 4 3+ +134BA B 415.64 332.498 8 9.65 +134BAS B EAV=123.6 4 +134BA G 242.76 5 0.0241 31(M1+E2) 0.087 3 +134BA2 G KC=0.0722 12$LC=0.0120 25$MC=0.0025 6$NC=0.00054 12 +134BA3 G OC=0.000079 14 +134BA G 475.365 2 1.479 7M1+E2 6.0 35 0.0114 5 +134BA2 G KC=0.0096 4$LC=0.00146 3$MC=0.000304 6$NC=6.49E-5 14 +134BA3 G OC=9.61E-6 24 +134BA G 1038.605 8 0.9909 33M1+E2 0.71 14 0.00208 7 +134BA2 G KC=0.00179 6$LC=0.000228 7$MC=4.67E-5 13$NC=1.01E-5 3 +134BA3 G OC=1.55E-6 5 +134BA L 1969.921 4 4+ +134BA B 89.06 3327.27 3 6.49 +134BAS B EAV=23.2 4 +134BA G 326.585 140.0171 11(M1+E2) 0.0367 22 +134BA2 G KC=0.031 3$LC=0.0047 3$MC=0.00097 8$NC=0.000207 14 +134BA3 G OC=3.08E-5 13 +134BA G 569.330 2 15.368 21M1+E2 0.28 2 0.0093614 +134BA2 G KC=0.00805 12$LC=0.001039 15$MC=0.000214 3$NC=4.61E-5 7 +134BA3 G OC=7.07E-6 10 +134BA G 801.950 6 8.694 16E2 0.00297 5 +134BA2 G KC=0.00254 4$LC=0.000344 5$MC=0.000071 1$NC=1.525E-5 22 +134BA3 G OC=2.30E-6 4 +134BA G 1365.1940 403.019 8E2 9.87E-414 +134BA2 G KC=0.000820 12$LC=1.039E-4 15$MC=2.13E-5 3$NC=4.59E-6 7 +134BA3 G OC=7.02E-7 10 + diff --git a/HEN_HOUSE/spectra/lnhb/Cs-137.txt b/HEN_HOUSE/spectra/lnhb/Cs-137.txt index 12726780d..c922f3bce 100644 --- a/HEN_HOUSE/spectra/lnhb/Cs-137.txt +++ b/HEN_HOUSE/spectra/lnhb/Cs-137.txt @@ -1,45 +1,43 @@ -137BA 137CS B- DECAY (30.05 Y) -137BA H TYP=Update$AUT=M.M. Bé$CUT=11-DEC-2007$ -137BA2 H TYP=Update$AUT=V.Chechev$CUT=01-MAR-2006$ -137BA3 H TYP=Full$AUT=R.G.Helmer$CUT=01-JUN-1998$ -137BA C Evaluation history: Type=Update;Author=M.M. Bé;Cutoff date=11-DEC-2007 -137BA2C Type=Update;Author=V.Chechev;Cutoff date=01-MAR-2006 -137BA3C Type=Full;Author=R.G.Helmer;Cutoff date=01-JUN-1998 -137BA T Auger electrons and X ray energies and emission intensities: -137BA T {U Energy (keV)} {U Intensity} {U Line} -137BA T -137BA T 31.8174 1.95 4 XKA2 -137BA T 32.1939 3.59 7 XKA1 -137BA T -137BA T 36.3045 |] XKB3 -137BA T 36.3786 |] 1.055 22 XKB1 -137BA T 36.654 |] XKB5II -137BA T -137BA T 37.258 |] XKB2 -137BA T 37.312 |] 0.266 8 XKB4 -137BA T 37.425 |] XKO23 -137BA T -137BA T 3.954-5.809 0.90 5 XL (total) -137BA T 3.954 XLL -137BA T -5.809 XLG -137BA T -137BA T 25.314-26.786 |] KLL AUGER -137BA T 30.095-32.179 |] 0.76 4 KLX AUGER -137BA T 34.86-37.41 |] KXY AUGER -137BA T 2.6-5.8 7.28 12 L AUGER -137CS P 0.0 7/2+ 30.05 Y 8 1175.63 17 -137BA N 1.0 1.0 1 1.0 -137BA L 0 3/2+ STABLE -137BA B 1175.63 175.64 28 12.06 2 -137BAS B EAV=416.26 8 -137BA L 283.5 1 1/2+ -137BA B 892.13 200.00061 8 15.64 2U -137BAS B EAV=300.57 8 -137BA G 283.5 1 0.00058 8[M1E2] 0.0557 13 -137BA2 G KC=0.046 3$LC=0.0073 10$MC=0.0015 2 -137BA L 661.659 3 11/2- 2.552 M 1 -137BA B 513.97 1794.36 28 9.63 1U -137BAS B EAV=174.32 6 -137BA G 661.657 3 84.99 20M4 0.1102 19 -137BA2 G KC=0.0896 15$LC=0.0165 5$MC=0.00352 7 - +137BA 137CS B- DECAY (30.05 Y) +137BA H TYP=UPD$AUT=M.-M.BE$CUT=11-DEC-2007$ +137BA2 H TYP=UPD$AUT=V.P.CHECHEV$CUT=01-MAR-2006$ +137BA3 H TYP=FUL$AUT=R.G.HELMER$CUT=01-JUN-1998$ +137BA C References:1999BeZQ +137BA T Auger electrons and X ray energies and emission intensities: +137BA T {U Energy (keV)} {U Intensity} {U Line} +137BA T +137BA T 31.8174 1.95 4 XKA2 +137BA T 32.1939 3.59 7 XKA1 +137BA T +137BA T 36.3045 |] XKB3 +137BA T 36.3786 |] 1.055 22 XKB1 +137BA T 36.654 |] XKB5II +137BA T +137BA T 37.258 |] XKB2 +137BA T 37.312 |] 0.266 8 XKB4 +137BA T 37.425 |] XKO23 +137BA T +137BA T 3.954-5.809 0.90 5 XL (total) +137BA T 3.954 XLL +137BA T -5.809 XLG +137BA T +137BA T 25.314-26.786 |] KLL AUGER +137BA T 30.095-32.179 |] 0.76 4 KLX AUGER +137BA T 34.86-37.41 |] KXY AUGER +137BA T 2.6-5.8 7.28 12 L AUGER +137CS P 0.0 7/2+ 30.05 Y 8 1175.63 17 +137BA N 1.0 1.0 1 1.0 +137BA L 0 3/2+ STABLE +137BA B 1175.63 175.64 28 12.06 2 +137BAS B EAV=416.26 8 +137BA L 283.5 1 1/2+ +137BA B 892.13 200.00061 8 15.64 2U +137BAS B EAV=300.57 8 +137BA G 283.5 1 0.00058 8[M1,E2] 0.0557 13 +137BA2 G KC=0.046 3$LC=0.0073 10$MC=0.0015 2 +137BA L 661.659 3 11/2- 2.552 M 1 +137BA B 513.97 1794.36 28 9.63 1U +137BAS B EAV=174.32 6 +137BA G 661.657 3 84.99 20M4 0.1102 19 +137BA2 G KC=0.0896 15$LC=0.0165 5$MC=0.00352 7 + diff --git a/HEN_HOUSE/spectra/lnhb/Cu-61.txt b/HEN_HOUSE/spectra/lnhb/Cu-61.txt index 972dfb17b..569a19198 100644 --- a/HEN_HOUSE/spectra/lnhb/Cu-61.txt +++ b/HEN_HOUSE/spectra/lnhb/Cu-61.txt @@ -1,107 +1,112 @@ - 61NI 61CU EC DECAY (3.366 H) - 61NI H TYP=Full$AUT=M.M. Bé$CUT=31-JUL-2013$ - 61NI C Evaluation history: Type=Full;Author=M.M. Bé;Cutoff date=31-JUL-2013 - 61NI C References: 1954Be84, 1956Nu02, 1967Sc02, 1967Bo01, 1967Be12, 1969Ri04, - 61NI2C 1971Go40, 1972Du09, 1972Cr02, 1973Ne02, 1977Wa03, 1978ME10, 1982Gr10, - 61NI3C 1982Ma41, 1988Sa26, 1996Sc06, 1998Sc28, 1999Bh04, 2000Sc47, 2008Ki07, - 61NI4C 2012Wa38 - 61NI T Auger electrons and X ray energies and emission intensities: - 61NI T {U Energy (keV)} {U Intensity} {U Line} - 61NI T - 61NI T 7.46097 4.33 20 XKA2 - 61NI T 7.47824 8.4 4 XKA1 - 61NI T - 61NI T 8.26475 |] 1.76 9 XKB1 - 61NI T 8.3287 |] XKB5II - 61NI T - 61NI T - 61NI T 0.7445-1.0083 0.437 14 XL (total) - 61NI T 0.7445 0.0165 8 XLL - 61NI T 0.8532-0.8539 0.244 10 XLA - 61NI T 0.7622 0.0101 5 XLC - 61NI T 0.86123-1.0083 0.165 8 XLB - 61NI T 0.87898-0.87898 0.0008 1 XLG - 61NI T - 61NI T 6.262-6.567 |] KLL AUGER - 61NI T 7.196-7.475 |] 20.0 9 KLX AUGER - 61NI T 8.109-8.326 |] KXY AUGER - 61NI T 0.632-1.01 51.2 9 L AUGER - 61CU P 0.0 3/2- 3.366 H 33 2237.5 10 - 61NI N 1.0 1.0 1 1.0 - 61NI L 0 3/2- STABLE - 61NI E 51.6 2516.3 85 - 61NI2 E EAV=523.8 5$CK=0.8867 16$CL=0.0967 13$CM=0.0157 5$CN=0.0009 1 - 61NI L 67.412 3 5/2- 5.34 NS 16 - 61NI E 2.1 50.79 206.3 - 61NI2 E EAV=493.8 5$CK=0.8866 16$CL=0.0968 13$CM=0.0157 5$CN=0.0009 1 - 61NI G 67.412 3 4.0 6(M1) 0.1368 20 - 61NI2 G KC=0.1224 18$LC=0.01261 18$MC=1776E-6 25 - 61NI L 282.9568 191/2- 22 PS 4 - 61NI E 5.4 94.0 75.5 - 61NI2 E EAV=398.9 5$CK=0.8866 16$CL=0.0968 13$CM=0.0157 5$CN=0.0009 1 - 61NI G 215.55 180.013 7 - 61NI G 282.9560 2012.0 17(M1) 0.00329 5 - 61NI2 G KC=0.00295 5$LC=2.93E-4 5$MC=4.13E-5 6 - 61NI L 656.012 3 1/2- 22 PS 4 - 61NI E 2.52 2710.7 124.9 - 61NI2 E EAV=238.5 4$CK=0.8864 16$CL=0.0970 13$CM=0.0157 5$CN=0.0009 1 - 61NI G 373.050 5 2.09 30[M1] 0.00170 2 - 61NI2 G KC=0.00153 2$LC=1.51E-4 2$MC=2.13E-5 3 - 61NI G 588.605 9 1.15 16[E2] - 61NI G 656.008 4 10.4 15(M1+E2) - 61NI L 908.620 115/2- - 61NI E 0.0347 401.32 155.7 - 61NI2 E EAV=132.8 4$CK=0.8862 16$CL=0.0971 13$CM=0.0158 5$CN=0.0009 1 - 61NI G 625.605 240.044 7[E2] - 61NI G 841.211 170.224 34M1+()E2 -1.83 20 - 61NI G 908.631 171.12 16M1+()E2 -0.18 5 - 61NI L 1014.8 4 7/2- - 61NI E 0.000032320.006 67.8 2 - 61NI2 E EAV=88.7 4$CK=0.8861 16$CL=0.0972 13$CM=0.0158 5$CN=0.0009 1 - 61NI G 947.40 400.0060 19M1+()E2 -2.46 15 - 61NI G 1014.8 4 0.0103 39E2+()M3 0.03 300 0.0002 6 - 61NI2 G KC=0.0002 6$LC=0.00002 6$MC=3E-6 8 - 61NI L 1099.622 103/2- - 61NI E 0.64 65.9 - 61NI2 E CK=0.8860 16$CL=0.0973 13$CM=0.0158 5$CN=0.0009 1 - 61NI G 816.692 130.32 5M1+()E2 -0.23 700 - 61NI G 1032.162 100.053 10 - 61NI G 1099.560 190.257 39 - 61NI L 1132.332 175/2- - 61NI E 0.154 176.5 - 61NI2 E CK=0.8860 16$CL=0.0973 13$CM=0.0158 5$CN=0.0009 1 - 61NI G 117.5 0.010 6 - 61NI G 1064.896 200.052 9M1+()E2 -0.14 12 - 61NI G 1132.350 300.092 13M1+()E2 0.47 9 - 61NI L 1185.236 113/2- - 61NI E 4.1 55 - 61NI2 E CK=0.8859 16$CL=0.0974 13$CM=0.0158 5$CN=0.0009 1 - 61NI G 529.169 220.38 5 - 61NI G 902.294 200.084 12 - 61NI G 1117.822 430.039 9 - 61NI G 1185.234 153.6 5(M1+E2) - 61NI L 1609.639 215/2- - 61NI E 0.063 76.5 - 61NI2 E CK=0.8849 16$CL=0.0982 13$CM=0.0160 5$CN=0.0009 1 - 61NI G 701.10 300.0108 28 - 61NI G 1542.204 230.029 5M1+()E2 0.07 500 - 61NI G 1609.625 480.0236 43M1+()E2 0.33 14 - 61NI L 1729.471 103/2- - 61NI E 0.228 185.7 - 61NI2 E CK=0.8843 16$CL=0.0987 13$CM=0.0160 5$CN=0.0009 1 - 61NI G 544.8 0.006 4 - 61NI G 820.89 170.0216 39 - 61NI G 1073.465 250.042 11 - 61NI G 1446.492 190.046 7 - 61NI G 1662.000 190.051 8 - 61NI G 1729.473 180.065 14 - 61NI L 1997.7 9 5/2- - 61NI E 0.0043 146.7 - 61NI2 E CK=0.8808 17$CL=0.1016 14$CM=0.0166 5$CN=0.0010 1 - 61NI G 1089.11 0.00060 8 - 61NI G 1997.7 9 0.0037 13M1+()E2 0.27 6 - 61NI L 2124 1 1/2- - 61NI E 0.040 55 - 61NI2 E CK=0.8729 22$CL=0.1083 18$CM=0.0178 6$CN=0.0010 2 - 61NI G 2124 1 0.040 6 - + 61NI 61CU EC DECAY (3.366 H) + 61NI H TYP=FUL$AUT=M.-M.BE$CUT=31-JUL-2013$ + 61NI C References:1954Be84, 1956Nu02, 1967Sc02, 1967Bo01, 1967Be12, 1969Ri04, + 61NI2C 1971Go40, 1972Du09, 1972Cr02, 1973Ne02, 1977Wa03, 1978ME10, 1982Gr10, + 61NI3C 1982Ma41, 1988Sa26, 1996Sc06, 1998Sc28, 1999Bh04, 2000Sc47, 2008Ki07, + 61NI4C 2012Wa38 + 61NI T Auger electrons and X ray energies and emission intensities: + 61NI T {U Energy (keV)} {U Intensity} {U Line} + 61NI T + 61NI T 7.46097 4.33 20 XKA2 + 61NI T 7.47824 8.4 4 XKA1 + 61NI T + 61NI T 8.26475 |] 1.76 9 XKB1 + 61NI T 8.3287 |] XKB5II + 61NI T + 61NI T + 61NI T 0.7445-1.0083 0.437 14 XL (total) + 61NI T 0.7445 0.0165 8 XLL + 61NI T 0.8532-0.8539 0.244 10 XLA + 61NI T 0.7622 0.0101 5 XLC + 61NI T 0.86123-1.0083 0.165 8 XLB + 61NI T 0.87898-0.87898 0.0008 1 XLG + 61NI T + 61NI T 6.262-6.567 |] KLL AUGER + 61NI T 7.196-7.475 |] 20.0 9 KLX AUGER + 61NI T 8.109-8.326 |] KXY AUGER + 61NI T 0.632-1.01 51.2 9 L AUGER + 61CU P 0.0 3/2- 3.366 H 33 2237.5 10 + 61NI N 1.0 1.0 1 1.0 + 61NI L 0 3/2- STABLE + 61NI E 51.6 2516.3 85 + 61NI2 E EAV=523.8 5$CK=0.21286 38$CL=0.02321 31$CM=0.00377 12 + 61NI3 E CN=0.000216 24 + 61NI L 67.412 3 5/2- 5.34 NS 16 + 61NI E 2.1 50.79 206.3 + 61NI2 E EAV=493.8 5$CK=0.24236 44$CL=0.02646 36$CM=0.00429 14 + 61NI3 E CN=0.000246 27 + 61NI G 67.412 3 4.0 6(M1) 0.1368 20 + 61NI2 G KC=0.1224 18$LC=0.01261 18$MC=0.001776 25$NC=7.38E-5 11 + 61NI L 282.9568 191/2- 22 PS 4 + 61NI E 5.4 94.0 75.5 + 61NI2 E EAV=398.9 5$CK=0.3773 7$CL=0.0412 6$CM=0.00668 21 + 61NI3 E CN=0.000383 43 + 61NI G 215.55 180.013 7 + 61NI G 282.9560 2012.0 17(M1) 0.00329 5 + 61NI2 G KC=0.00295 5$LC=0.000293 5$MC=4.13E-5 6$NC=1.765E-6 25 + 61NI L 656.012 3 1/2- 22 PS 4 + 61NI E 2.52 2710.7 124.9 + 61NI2 E EAV=238.5 4$CK=0.7174 13$CL=0.0785 11$CM=0.01271 40 + 61NI3 E CN=0.00073 8 + 61NI G 373.050 5 2.09 30[M1] 0.00170 2 + 61NI2 G KC=0.00153 2$LC=0.000151 2$MC=2.13E-5 3$NC=9.14E-7 13 + 61NI G 588.605 9 1.15 16[E2] + 61NI G 656.008 4 10.4 15(M1+E2) + 61NI L 908.620 115/2- + 61NI E 0.0347 401.32 155.7 + 61NI2 E EAV=132.8 4$CK=0.8635 16$CL=0.0946 13$CM=0.01540 49 + 61NI3 E CN=0.00088 10 + 61NI G 625.605 240.044 7[E2] + 61NI G 841.211 170.224 34M1+E2 -1.83 20 + 61NI G 908.631 171.12 16M1+E2 -0.18 5 + 61NI L 1014.8 4 7/2- + 61NI E 0.000032320.006 67.8 2 + 61NI2 E EAV=88.7 4$CK=0.8814 16$CL=0.0967 13$CM=0.01572 50 + 61NI3 E CN=0.0009 1 + 61NI G 947.40 400.0060 19M1+E2 -2.46 15 + 61NI G 1014.8 4 0.0103 39E2+M3 0.03 300 0.0002 6 + 61NI2 G KC=0.0002 6$LC=0.00002 6$MC=0.000003 8$NC=1E-7 4 + 61NI L 1099.622 103/2- + 61NI E 0.64 65.9 + 61NI2 E CK=0.8860 16$CL=0.0973 13$CM=0.0158 5$CN=0.0009 1 + 61NI G 816.692 130.32 5M1+E2 -0.23 700 + 61NI G 1032.162 100.053 10 + 61NI G 1099.560 190.257 39 + 61NI L 1132.332 175/2- + 61NI E 0.154 176.5 + 61NI2 E CK=0.8860 16$CL=0.0973 13$CM=0.0158 5$CN=0.0009 1 + 61NI G 117.5 0.010 6 + 61NI G 1064.896 200.052 9M1+E2 -0.14 12 + 61NI G 1132.350 300.092 13M1+E2 0.47 9 + 61NI L 1185.236 113/2- + 61NI E 4.1 55 + 61NI2 E CK=0.8859 16$CL=0.0974 13$CM=0.0158 5$CN=0.0009 1 + 61NI G 529.169 220.38 5 + 61NI G 902.294 200.084 12 + 61NI G 1117.822 430.039 9 + 61NI G 1185.234 153.6 5(M1+E2) + 61NI L 1609.639 215/2- + 61NI E 0.063 76.5 + 61NI2 E CK=0.8849 16$CL=0.0982 13$CM=0.0160 5$CN=0.0009 1 + 61NI G 701.10 300.0108 28 + 61NI G 1542.204 230.029 5M1+E2 0.07 500 + 61NI G 1609.625 480.0236 43M1+E2 0.33 14 + 61NI L 1729.471 103/2- + 61NI E 0.228 185.7 + 61NI2 E CK=0.8843 16$CL=0.0987 13$CM=0.0160 5$CN=0.0009 1 + 61NI G 544.8 0.006 4 + 61NI G 820.89 170.0216 39 + 61NI G 1073.465 250.042 11 + 61NI G 1446.492 190.046 7 + 61NI G 1662.000 190.051 8 + 61NI G 1729.473 180.065 14 + 61NI L 1997.7 9 5/2- + 61NI E 0.0043 146.7 + 61NI2 E CK=0.8808 17$CL=0.1016 14$CM=0.0166 5$CN=0.0010 1 + 61NI G 1089.11 0.00060 8 + 61NI G 1997.7 9 0.0037 13M1+E2 0.27 6 + 61NI L 2124 1 1/2- + 61NI E 0.040 55 + 61NI2 E CK=0.8729 22$CL=0.1083 18$CM=0.0178 6$CN=0.0010 2 + 61NI G 2124 1 0.040 6 + diff --git a/HEN_HOUSE/spectra/lnhb/Cu-64.txt b/HEN_HOUSE/spectra/lnhb/Cu-64.txt index 3cab20f48..3c9767450 100644 --- a/HEN_HOUSE/spectra/lnhb/Cu-64.txt +++ b/HEN_HOUSE/spectra/lnhb/Cu-64.txt @@ -1,57 +1,52 @@ - 64NI 64CU EC DECAY (12.7004 H) - 64NI H TYP=update$AUT=M.-M.Bé$CUT=30-JUN-2011$ - 64NI2 H TYP=Full$AUT=M.-M.Bé$CUT= -- $ - 64NI3 H TYP=Full$AUT=R.G.Helmer$CUT=31-JAN-2002$ - 64NI C Evaluation history: Type=update;Author=M.-M.Bé;Cutoff date=30-JUN-2011 - 64NI2C Type=Full;Author=M.-M.Bé;Cutoff date= -- - 64NI3C Type=Full;Author=R.G.Helmer;Cutoff date=31-JAN-2002 - 64NI C References: 1976Ba63, 1989Ab22, 1996Sc06, 2002WE02, 2003Au03, 2007Qa02, - 64NI2C 2007Si04 - 64NI T Auger electrons and X ray energies and emission intensities: - 64NI T {U Energy (keV)} {U Intensity} {U Line} - 64NI T - 64NI T 7.46093 4.90 6 XKA2 - 64NI T 7.47819 9.56 11 XKA1 - 64NI T - 64NI T 8.2647 |] XKB3 - 64NI T |] 1.99 3 XKB1 - 64NI T 8.3287 |] XKB5II - 64NI T - 64NI T - 64NI T 0.7445-1.0083 0.493 10 XL (total) - 64NI T 0.7445 0.0186 6 XLL - 64NI T 0.8532-0.8539 0.276 7 XLA - 64NI T 0.7622 0.0114 4 XLC - 64NI T 0.86123-1.0083 0.187 6 XLB - 64NI T 0.87898-0.87898 0.0009 1 XLG - 64NI T - 64NI T 6.262-6.567 |] KLL AUGER - 64NI T 7.196-7.475 |] 22.62 21 KLX AUGER - 64NI T 8.109-8.326 |] KXY AUGER - 64NI T 0.6-0.9 57.9 4 L AUGER - 64CU P 0.0 1+ 12.7004 H 20 1675.03 20 - 64NI N 1.625E0 1.625E0 0.6152 261.625E0 - 64NI L 0 0+ STABLE - 64NI E 17.52 1543.53 204.97 - 64NI2 E EAV=278.21 9$CK=0.888 3$CL=0.095 2$CM=0.0155 5 - 64NI L 1345.75 5 2+ 1.088 PS 35 - 64NI E 0.4744 335.51 - 64NI2 E CK=0.884 3$CL=0.099 2$CM=0.0162 5 - 64NI G 1345.77 6 0.4748 34E2 1.24E-4 2 - 64NI2 G KC=1112E-7 2$LC=1.09E-5 2 - - 64ZN 64CU B- DECAY (12.7004 H) - 64ZN H TYP=update$AUT=M.-M.Bé$CUT=30-JUN-2011$ - 64ZN2 H TYP=Full$AUT=M.-M.Bé$CUT= -- $ - 64ZN3 H TYP=Full$AUT=R.G.Helmer$CUT=31-JAN-2002$ - 64ZN C Evaluation history: Type=update;Author=M.-M.Bé;Cutoff date=30-JUN-2011 - 64ZN2C Type=Full;Author=M.-M.Bé;Cutoff date= -- - 64ZN3C Type=Full;Author=R.G.Helmer;Cutoff date=31-JAN-2002 - 64ZN C References: 1976Ba63, 1989Ab22, 1996Sc06, 2002WE02, 2003Au03, 2007Qa02, - 64ZN2C 2007Si04 - 64CU P 0.0 1+ 12.7004 H 20 579.4 7 - 64ZN N 2.599E0 2.599E0 0.3848 262.599E0 - 64ZN L 0 0+ STABLE - 64ZN B 579.4 7 38.48 26 5.29 - 64ZNS B EAV=190.7 3 - + 64NI 64CU EC DECAY (12.7004 H) + 64NI H TYP=UPD$AUT=M.-M.BE$CUT=30-JUN-2011$ + 64NI2 H TYP=FUL$AUT=M.-M.BE$CUT=30-SEP-2010$ + 64NI3 H TYP=FUL$AUT=R.G.HELMER$CUT=31-JAN-2002$ + 64NI C References:1976Ba63, 1989Ab22, 1996Sc06, 2002We02, 2003Au03, 2007Qa02, + 64NI2C 2007Si04, 2010Wa**, 2012Be** + 64NI T Auger electrons and X ray energies and emission intensities: + 64NI T {U Energy (keV)} {U Intensity} {U Line} + 64NI T + 64NI T 7.46093 4.90 6 XKA2 + 64NI T 7.47819 9.56 11 XKA1 + 64NI T + 64NI T 8.2647 |] XKB3 + 64NI T |] 1.99 3 XKB1 + 64NI T 8.3287 |] XKB5II + 64NI T + 64NI T + 64NI T 0.7445-1.0083 0.493 10 XL (total) + 64NI T 0.7445 0.0186 6 XLL + 64NI T 0.8532-0.8539 0.276 7 XLA + 64NI T 0.7622 0.0114 4 XLC + 64NI T 0.86123-1.0083 0.187 6 XLB + 64NI T 0.87898-0.87898 0.0009 1 XLG + 64NI T + 64NI T 6.262-6.567 |] KLL AUGER + 64NI T 7.196-7.475 |] 22.62 21 KLX AUGER + 64NI T 8.109-8.326 |] KXY AUGER + 64NI T 0.6-0.9 57.9 4 L AUGER + 64CU P 0.0 1+ 12.7004 H 20 1675.03 20 + 64NI N 1.625E0 1.625E0 0.6152 261.625E0 + 64NI L 0 0+ STABLE + 64NI E 17.52 1543.53 204.97 + 64NI2 E EAV=278.21 9$CK=0.6332 21$CL=0.0677 14$CM=0.01105 36 + 64NI L 1345.75 5 2+ 1.088 PS 35 + 64NI E 0.4744 335.51 + 64NI2 E CK=0.884 3$CL=0.099 2$CM=0.0162 5 + 64NI G 1345.77 6 0.4748 34E2 1.24E-4 2 + 64NI2 G KC=1.112E-4 2$LC=1.09E-5 2 + 64NI3 G IPC=3.94E-5 6 + + 64ZN 64CU B- DECAY (12.7004 H) + 64ZN H TYP=UPD$AUT=M.-M.BE$CUT=30-JUN-2011$ + 64ZN2 H TYP=FUL$AUT=M.-M.BE$CUT=30-SEP-2010$ + 64ZN3 H TYP=FUL$AUT=R.G.HELMER$CUT=31-JAN-2002$ + 64ZN C References:1976Ba63, 1989Ab22, 1996Sc06, 2002We02, 2003Au03, 2007Qa02, + 64ZN2C 2007Si04, 2010Wa**, 2012Be** + 64CU P 0.0 1+ 12.7004 H 20 579.4 7 + 64ZN N 2.599E0 2.599E0 0.3848 262.599E0 + 64ZN L 0 0+ STABLE + 64ZN B 579.4 7 38.48 26 5.29 + 64ZNS B EAV=190.7 3 + diff --git a/HEN_HOUSE/spectra/lnhb/Er-169.txt b/HEN_HOUSE/spectra/lnhb/Er-169.txt index faaef923f..c76164d90 100644 --- a/HEN_HOUSE/spectra/lnhb/Er-169.txt +++ b/HEN_HOUSE/spectra/lnhb/Er-169.txt @@ -1,37 +1,39 @@ -169TM 169ER B- DECAY (9.38 D) -169TM H TYP=FUL$AUT=M.M. Bé$CUT=31-DEC-2014$ -169TM C Evaluation history: Type=FUL;Author=M.M. Bé;Cutoff date=31-DEC-2014 -169TM C References: 1948Ke11, 1956Bi30, 1958Pa16, 1958Sh64, 1959Ch31, 1960Wi10, -169TM2C 1961Bj02, 1962Gr16, 1963Mc13, 1963Ra15, 1964Ka02, 1965Du02, 1967Ma42, -169TM3C 1968Ca06, 1968Wa05, 1970Sh09, 1971MaXG, 1977My02, 2001KoZQ, 2002Be05, -169TM4C 2002Ba85, 2004BeZQ, 2004Sc04, 2008Ki07, 2008Ba31, 2012Mo38, 2012Wa38, -169TM5C 2012Le09, 2014Mo20, 2015In02 -169TM T Auger electrons and X ray energies and emission intensities: -169TM T {U Energy (keV)} {U Intensity} {U Line} -169TM T -169TM T -169TM T -169TM T -169TM T -169TM T 0.04-0.53 |] KLL AUGER -169TM T 0.31-1.47 |] 74.6 KLX AUGER -169TM T 0.85-1.79 |] KXY AUGER -169TM T 0.05-0.186 116.1 L AUGER -169ER P 0.0 1/2- 9.38 D 2 353.0 12 -169TM N 1.0 1.0 1 0 1.0 -169TM L 0 1/2+ STABLE -169TM B 353.0 1256 5 6.3 -169TMS B EAV=99.1 5 -169TM L 8.4102 1 3/2+ 4.09 NS 5 -169TM B 344.6 1244 5 6.5 1 -169TMS B EAV=96.5 5 -169TM G 8.4102 1 0.174 21M1+(E2) 0.0306 16 251 10 -169TM2 G MC=199 8 -169TM L 118.1895 1 5/2+ -169TM B 234.8 120.016 9.5 1U -169TMS B EAV=73.0 5 -169TM G 109.77930 140.0045 9M1+E2 0.15 1 2.37 4 -169TM2 G KC=1.96 3$LC=0.316 5$MC=0.0710 12 -169TM G 118.1895 1 0.0005 E2 1.642 23 -169TM2 G KC=0.70 1$LC=0.721 10$MC=0.1759 25 - +169TM 169ER B- DECAY (9.38 D) +169TM H TYP=FUL$AUT=M.-M.BE$CUT=31-DEC-2014$ +169TM C References:1948Ke11, 1956Bi30, 1958Pa16, 1958Sh64, 1959Ch31, 1960Wi10, +169TM2C 1961Bj02, 1962Gr16, 1963Mc13, 1963Ra15, 1964Ka02, 1965Du02, 1967Ma42, +169TM3C 1968Ca06, 1968Wa05, 1970Sh09, 1971MaXG, 1977My02, 2001KoZQ, 2002Be05, +169TM4C 2002Ba85, 2004BeZQ, 2004Sc04, 2008Ki07, 2008Ba31, 2012Mo38, 2012Wa38, +169TM5C 2012Le09, 2014Mo20, 2015In02 +169TM T Auger electrons and X ray energies and emission intensities: +169TM T {U Energy (keV)} {U Intensity} {U Line} +169TM T +169TM T +169TM T +169TM T +169TM T +169TM T 0.04-0.53 |] KLL AUGER +169TM T 0.31-1.47 |] 74.6 KLX AUGER +169TM T 0.85-1.79 |] KXY AUGER +169TM T 0.05-0.186 116.1 L AUGER +169ER P 0.0 1/2- 9.38 D 2 353.0 12 +169TM N 1.0 1.0 1 1.0 +169TM L 0 1/2+ STABLE +169TM B 353.0 1256 5 6.3 +169TMS B EAV=99.1 5 +169TM L 8.4102 1 3/2+ 4.09 NS 5 +169TM B 344.6 1244 5 6.5 1 +169TMS B EAV=96.5 5 +169TM G 8.4102 1 0.174 21M1+(E2) 0.0306 16 251 10 +169TM2 G MC=199 8$NC=45.8 18 +169TM3 G OC=6.1 2 +169TM L 118.1895 1 5/2+ +169TM B 234.8 120.016 9.5 1U +169TMS B EAV=73.0 5 +169TM G 109.77930 140.0045 9M1+E2 0.15 1 2.37 4 +169TM2 G KC=1.96 3$LC=0.316 5$MC=0.0710 12$NC=0.017 1 +169TM3 G OC=0.0024 1 +169TM G 118.1895 1 0.0005 E2 1.642 23 +169TM2 G KC=0.70 1$LC=0.721 10$MC=0.1759 25$NC=0.040 1 +169TM3 G OC=0.0047 1 + diff --git a/HEN_HOUSE/spectra/lnhb/Eu-152.txt b/HEN_HOUSE/spectra/lnhb/Eu-152.txt index e590ed60b..170363639 100644 --- a/HEN_HOUSE/spectra/lnhb/Eu-152.txt +++ b/HEN_HOUSE/spectra/lnhb/Eu-152.txt @@ -1,411 +1,403 @@ -152SM 152EU EC DECAY (13.522 Y) -152SM C References: 1977La19 -152SM T Auger electrons and X ray energies and emission intensities: -152SM T {U Energy (keV)} {U Intensity} {U Line} -152SM T -152SM T 39.5229 20.8 3 XKA2 -152SM T 40.1186 37.7 5 XKA1 -152SM T -152SM T 45.289 |] XKB3 -152SM T 45.413 |] 11.78 19 XKB1 -152SM T 45.731 |] XKB5II -152SM T -152SM T 46.575 |] XKB2 -152SM T 46.705 |] 3.04 8 XKB4 -152SM T 46.813 |] XKO23 -152SM T -152SM T 5.61-7.18 13.0 4 XL (total) -152SM T 5.61-5.64 XLA -152SM T -7.18 XLG -152SM T -152SM T 31.19-33.218 |] KLL AUGER -152SM T 37.302-40.097 |] 5.9 4 KLX AUGER -152SM T 43.39-46.79 |] KXY AUGER -152SM T 3.2-7.7 67.7 7 L AUGER -152EU P 0.0 3- 13.522 Y 16 1874.3 7 -152SM N 1.387E0 1.387E0 0.721 1.387E0 -152SM G 237.31 5 0.0025 8(E1) 0.0272 8 -152SM G 320.03 150.0017 6 -152SM G 379.37 6 0.00083 21 -152SM G 391.32 140.00125 21 -152SM G 406.74 150.00083 21 -152SM G 535.4 4 0.0060 16(M1+E2) 1 0.0147044 -152SM G 595.61 1 0.0031 17 -152SM G 683.32 110.0031 8 -152SM G 696.87 190.0029 10 -152SM G 735.4 1 0.0058 10 -152SM G 756.12 9 0.0054 8 -152SM G 896.58 9 0.0669 21 -152SM G 1001.1 3 0.0046 10 -152SM G 1084 1 0.244 8 -152SM G 1139 1 0.0013 3 -152SM G 1674.30 6 0.0060 8 -152SM L 0 0+ STABLE -152SM L 121.7818 3 2+ 1.400 NS 11 -152SM E 0.025 151.7 1011.8 1 -152SM2 E EAV=338.1 3$CK=0.8408 15$CL=0.1241 10$CM=0.0281 5$CN=0.0069 4 -152SM G 121.7817 3 28.41 13E2 1.165 35 -152SM2 G KC=0.676 20$LC=0.378 11$MC=0.0875 26 -152SM L 366.4786 8 4+ 57.7 PS 8 -152SM E 0.0024 20.77 512 1 -152SM2 E EAV=230.7 3$CK=0.8398 15$CL=0.1249 11$CM=0.0283 5$CN=0.0070 4 -152SM G 244.6974 8 7.55 4E2 0.1080 32 -152SM2 G KC=0.0809 24$LC=0.0211 6$MC=0.00475 14 -152SM L 684.714 200+ -152SM G 562.93 2 0.038 13E2 0.0095028 -152SM2 G KC=0.00780 23$LC=1290E-6 39$MC=2.82E-4 8 -152SM L 706.91 5 6+ -152SM G 340.40 140.031 3E2 0.0385 12 -152SM2 G KC=0.0304 9$LC=0.00632 19$MC=1410E-6 42 -152SM L 810.4474 202+ 7.4 PS 6 -152SM E 1.28 311.4 1 -152SM2 E CK=0.8366 15$CL=0.1273 11$CM=0.0290 6$CN=0.0071 4 -152SM G 125.69 130.019 6(E2) 1.042 31 -152SM2 G KC=0.616 18$LC=0.329 10$MC=0.0760 23 -152SM G 443.965 3 0.32 2(E2) 0.0178 5 -152SM2 G KC=0.01450 44$LC=0.00263 8$MC=5.79E-4 17 -152SM G 688.670 5 0.841 6E2+M1+ 0.0434 13 -152SM2 G KC=0.0359 13 -152SM G 810.451 5 0.317 3(E2) 0.0040012 -152SM2 G KC=0.0033 1$LC=4.93E-4 15$MC=1070E-7 32 -152SM L 963.360 4 1- -152SM G 841.574 5 0.163 2E1 1500E-645 -152SM2 G KC=1200E-6 36$LC=1610E-7 48$MC=3.43E-5 10 -152SM G 963.390 120.1341 20E1 1100E-633 -152SM2 G KC=0.00100 3$LC=1230E-7 37$MC=2.63E-5 8 -152SM L 1022.967 5 4- 4.9 PS -152SM E 0.238 511.9 -152SM2 E CK=0.8338 15$CL=0.1294 11$CM=0.0295 6$CN=0.0073 4 -152SM G 212.568 150.0196 6E2 0.171 5 -152SM2 G KC=0.1244 37$LC=0.0364 11$MC=0.00825 25 -152SM G 316.2 2 0.0031 10(E2) 0.0481 14 -152SM2 G KC=0.0376 11$LC=0.00819 25$MC=0.00183 5 -152SM G 656.489 5 0.1437 18E2+M1+ 0.0568 20 -152SM2 G KC=0.0497 16 -152SM G 901.181 110.084 3E2 0.00310 9 -152SM2 G KC=0.00260 8$LC=3.82E-4 11$MC=8.24E-5 25 -152SM L 1041.1342 183- 27 FS 5 -152SM E 0.086 712.4 -152SM2 E CK=0.8335 15$CL=0.1296 11$CM=0.0296 6$CN=0.0073 4 -152SM G 674.675 3 0.170 4E1 0.00230 7 -152SM2 G KC=0.00190 6$LC=2.54E-4 8$MC=5.42E-5 16 -152SM G 919.337 4 0.429 5E1 1200E-636 -152SM2 G KC=0.00100 3$LC=1.35E-4 4$MC=2.88E-5 9 -152SM L 1085.8499 232+ 0.87 PS 4 -152SM E 21.35 119.9 1 -152SM2 E CK=0.8327 15$CL=0.1302 11$CM=0.0297 6$CN=0.0073 4 -152SM G 275.449 150.0323 17(M1) 0.1044 31 -152SM2 G KC=0.0887 27$LC=0.01230 37$MC=0.00265 8 -152SM G 719.349 4 0.268 13(E2) 0.0052016 -152SM2 G KC=0.00440 13$LC=6.66E-4 20$MC=1440E-7 43 -152SM G 964.079 1814.50 6E2(+M1) 0.00270 8 -152SM2 G KC=0.00230 7$LC=3.27E-4 10$MC=7.03E-5 21 -152SM G 1085.837 1010.13 6E2 0.00210 6 -152SM2 G KC=0.00180 5$LC=2.50E-4 8$MC=5.36E-5 16 -152SM L 1233.8656 173+ 3 PS 3 -152SM E 17.16 89.8 -152SM2 E CK=0.8291 16$CL=0.1329 11$CM=0.0305 6$CN=0.0075 4 -152SM G 148.010 170.035 5(M1+E2) 1 0.578 17 -152SM2 G KC=0.430 13$LC=0.1150 34$MC=0.0260 8 -152SM G 423.45 4 0.0032 5(M1+E2) 1 0.0271 8 -152SM2 G KC=0.0226 7$LC=0.0035 1$MC=7.61E-4 23 -152SM G 867.380 3 4.243 23E2+M1 -6.5 0.0035 1 -152SM2 G KC=0.00290 9$LC=4.23E-4 13$MC=9.13E-5 27 -152SM G 1112.076 3 13.41 6E2(+M1) -8.7 0.00200 6 -152SM2 G KC=0.00170 5$LC=2.38E-4 7$MC=5.11E-5 15 -152SM L 1292.771 6 (2)+ 8 PS 8 -152SM E 0.644 1011.2 1 -152SM2 E CK=0.8271 16$CL=0.1344 11$CM=0.0309 6$CN=0.0076 4 -152SM G 251.633 100.0671 15(E1) 0.0233 7 -152SM2 G KC=0.0198 6$LC=0.00272 8$MC=5.83E-4 17 -152SM G 269.86 6 0.0060 24(E2) 0.0789 24 -152SM2 G KC=0.0602 18$LC=0.01460 44$MC=0.00327 10 -152SM G 329.425 210.129 6(E1) 0.0117035 -152SM2 G KC=0.0100 3$LC=1360E-6 41$MC=2.90E-4 9 -152SM G 482.31 3 0.0279 16(M1+E2) 1 0.0192 6 -152SM2 G KC=0.01610 48$LC=0.00243 7$MC=5.26E-4 16 -152SM G 926.317 150.273 4(E2) 0.00290 9 -152SM2 G KC=0.00250 8$LC=3.58E-4 11$MC=7.72E-5 23 -152SM G 1170.93 110.0365 13(M1+E2) 1 0.00230 7 -152SM2 G KC=0.00200 6$LC=2.65E-4 8$MC=5.67E-5 17 -152SM G 1292.778 190.104 3(E2) 1500E-645 -152SM2 G KC=1300E-6 39$LC=1.72E-4 5$MC=3.68E-5 11 -152SM L 1371.691 9 4+ 1.4 PS 4 -152SM E 0.869 2410.9 1 -152SM2 E CK=0.8236 16$CL=0.1370 11$CM=0.0316 6$CN=0.0078 4 -152SM G 285.98 3 0.0100 6(E2) 0.0657 20 -152SM2 G KC=0.0506 15$LC=0.01180 35$MC=0.00263 8 -152SM G 330.54 100.0060 17(E1) 0.0116035 -152SM2 G KC=0.0099 3$LC=0.00134 4$MC=2.88E-4 9 -152SM G 561.2 5 0.00108 21(E2) 0.0096029 -152SM2 G KC=0.00790 24$LC=1300E-6 39$MC=2.85E-4 9 -152SM G 664.78 5 0.010 3(E2) 0.0063019 -152SM2 G KC=0.00520 16$LC=8.18E-4 25$MC=1.78E-4 5 -152SM G 1005.272 170.665 23 0.00260 8 -152SM2 G KC=0.00220 7$LC=3.11E-4 9$MC=6.69E-5 20 -152SM G 1249.938 130.186 3E2 1600E-648 -152SM2 G KC=1400E-6 42$LC=1.84E-4 6$MC=3.95E-5 12 -152SM L 1529.8073 162- 27 FS -152SM E 24.72 119.1 -152SM2 E CK=0.8109 17$CL=0.1465 12$CM=0.0341 7$CN=0.0085 4 -152SM G 295.9387 170.442 3E1 0.0153046 -152SM2 G KC=0.01310 39$LC=0.00178 5$MC=3.81E-4 11 -152SM G 443.965 3 2.80 2E1(+M2) 0.0060018 -152SM2 G KC=0.00520 16$LC=6.35E-4 19$MC=1390E-7 42 -152SM G 488.6792 200.4139 24M1+E2 0.0140042 -152SM2 G KC=0.01150 34$LC=0.00196 6$MC=4.29E-4 13 -152SM G 566.442 5 0.131 4M1+E2 -0.74 0.0138041 -152SM2 G KC=0.01170 35$LC=0.00166 5$MC=3.57E-4 11 -152SM G 719.349 4 0.059 7(E1) 0.00200 6 -152SM2 G KC=0.00170 5$LC=2.22E-4 7$MC=4.73E-5 14 -152SM G 1408.013 3 20.85 8E1(+M2) 6.00E-418 -152SM2 G KC=5.00E-4 15$LC=6.15E-5 18$MC=1310E-8 39 -152SM L 1579.365 3 3- -152SM E 2.068 1210 -152SM2 E CK=0.8036 17$CL=0.1519 12$CM=0.0356 7$CN=0.0088 5 -152SM G 207.6 3 0.0059 4(E1) 0.0385 12 -152SM2 G KC=0.0327 10$LC=0.00455 14$MC=9.75E-4 29 -152SM G 493.508 200.0278 30(E1) 0.0045014 -152SM2 G KC=0.00380 11$LC=5.09E-4 15$MC=1090E-7 33 -152SM G 538.29 6 0.0042 6(M1+E2) 1 0.0145044 -152SM2 G KC=0.01220 37$LC=0.00180 5$MC=3.89E-4 12 -152SM G 556.56 3 0.0177 11(E1) 0.0034 1 -152SM2 G KC=0.00290 9$LC=3.87E-4 12$MC=8.26E-5 25 -152SM G 616.05 3 0.0092 6(E2) 0.0076023 -152SM2 G KC=0.00630 19$LC=0.00100 3$MC=2.19E-4 7 -152SM G 768.944 9 0.088 3(E1) 0.00170 5 -152SM2 G KC=1500E-6 45$LC=1.93E-4 6$MC=4.12E-5 12 -152SM G 1212.948 111.416 9E1 7.00E-421 -152SM2 G KC=6.00E-4 18$LC=8.02E-5 24$MC=1.70E-5 5 -152SM G 1457.643 110.498 4E1 5.00E-415 -152SM2 G KC=5.00E-4 15$LC=5.80E-5 17$MC=1230E-8 37 -152SM L 1612.94 6 + -152SM E 0.0208 1411.9 -152SM2 E CK=0.7966 18$CL=0.1571 13$CM=0.0370 7$CN=0.0092 5 -152SM G 571.83 8 0.0048 8 -152SM G 906.01 6 0.016 1 -152SM L 1649.910 8 2- -152SM E 0.889 1410.1 -152SM2 E CK=0.7859 19$CL=0.1651 13$CM=0.0392 7$CN=0.0098 5 -152SM G 357.26 5 0.0040 5(E1) 0.0096029 -152SM2 G KC=0.00820 25$LC=1110E-6 33$MC=2.37E-4 7 -152SM G 416.048 8 0.1090 17(E1) 0.0067 2 -152SM2 G KC=0.00570 17$LC=7.62E-4 23$MC=1630E-7 49 -152SM G 563.990 7 0.457 13E1 0.0033 1 -152SM2 G KC=0.00280 8$LC=3.76E-4 11$MC=8.02E-5 24 -152SM G 686.61 5 0.0200 17(M1+E2) 1 0.0079024 -152SM2 G KC=0.0067 2$LC=9.54E-4 29$MC=2.05E-4 6 -152SM G 839.36 4 0.0160 8(E1) 1500E-645 -152SM2 G KC=1200E-6 36$LC=1620E-7 49$MC=3.45E-5 10 -152SM G 1528.103 180.281 5E1 5.00E-415 -152SM2 G KC=4.00E-4 12 -152SM L 1730.241 22(3)- -152SM E 0.0422 1210.9 -152SM2 E CK=0.7339 23$CL=0.2036 16$CM=0.0499 9$CN=0.0125 7 -152SM G 496.39 3 0.0049 5(E1) 0.0044013 -152SM2 G KC=0.00380 11$LC=5.02E-4 15$MC=1070E-7 32 -152SM G 644.37 5 0.0063 6(E1) 0.00250 8 -152SM2 G KC=0.00210 6$LC=2.80E-4 8$MC=5.98E-5 18 -152SM G 1363.77 5 0.0256 8M1(+E2) 0.00200 6 -152SM2 G KC=0.00170 5$LC=2.22E-4 7$MC=4.74E-5 14 -152SM G 1608.36 8 0.0053 3(E1) 4.00E-412 -152SM2 G KC=4.00E-4 12 -152SM L 1757.151 132,3+ -152SM E 0.041 310.7 1 -152SM2 E CK=0.6903 28$CL=0.2358 20$CM=0.0591 11$CN=0.0149 8 -152SM G 385.69 200.0050 6(M1+E2) 1 0.0348 10 -152SM2 G KC=0.0290 9$LC=0.00459 14$MC=9.99E-4 30 -152SM G 523.13 5 0.0113 21(M1+E2) 0.0156047 -152SM2 G KC=0.01310 39$LC=0.00194 6$MC=4.21E-4 13 -152SM G 671.155 170.0194 13M1+E2 0.14 0.0105032 -152SM2 G KC=0.00900 27$LC=1220E-6 37$MC=2.60E-4 8 -152SM G 1390.36 160.0048 6(M1+E2) 1 1600E-648 -152SM2 G KC=1400E-6 42$LC=1.80E-4 5$MC=3.85E-5 12 -152SM G 1635.2 5 0.00015 5(M1+E2) 1 0.00100 3 -152SM2 G KC=0.00100 3 -152SM L 1769.10 3 2+ -152SM E 0.068 510.3 1 -152SM2 E CK=0.6586 33$CL=0.2591 24$CM=0.0657 12$CN=0.0166 9 -152SM G 239.42 170.008 3(E1) 0.0265 8 -152SM2 G KC=0.0225 7$LC=0.00311 9$MC=6.65E-4 20 -152SM G 727.99 140.0106 13(E1) 0.00193 6 -152SM2 G KC=0.00166 5$LC=2.16E-4 6$MC=4.61E-5 14 -152SM G 805.70 7 0.0125 8(E1) 1600E-648 -152SM2 G KC=1400E-6 42$LC=1.76E-4 5$MC=3.74E-5 11 -152SM G 958.63 5 0.0210 19(M1+E2) 0.0036011 -152SM2 G KC=0.00310 9 -152SM G 1647.41 140.0064 4(E2) 8.00E-424 -152SM2 G KC=8.00E-4 24 -152SM G 1769.09 5 0.0092 3(E2) 7.00E-421 -152SM2 G KC=7.00E-4 21 - -152GD 152EU B- DECAY (13.522 Y) -152GD C References: 1977La19 -152GD T Auger electrons and X ray energies and emission intensities: -152GD T {U Energy (keV)} {U Intensity} {U Line} -152GD T -152GD T 42.3093 0.243 7 XKA2 -152GD T 42.9967 0.437 12 XKA1 -152GD T -152GD T 48.556 |] XKB3 -152GD T 48.697 |] 0.138 4 XKB1 -152GD T 49.053 |] XKB5II -152GD T -152GD T 49.961 |] XKB2 -152GD T 50.099 |] 0.0363 13 XKB4 -152GD T 50.219 |] XKO23 -152GD T -152GD T 5.3611-8.104 0.177 5 XL (total) -152GD T 5.3611 XLL -152GD T 6.024-6.0578 XLA -152GD T 6.0483 XLC -152GD T 6.6848-7.1888 XLB -152GD T 7.5509-8.104 XLG -152GD T -152GD T 33.31-35.562 |] KLL AUGER -152GD T 39.907-42.976 |] 0.062 4 KLX AUGER -152GD T 46.48-50.2 |] KXY AUGER -152GD T 3.4-8.3 0.800 14 L AUGER -152EU P 0.0 3- 13.522 Y 16 1818.8 11 -152GD N 3.584E0 3.584E0 0.279 3.584E0 -152GD G 237.31 5 0.0025 8(E1) 0.0272 8 -152GD G 320.03 150.0017 6 -152GD G 379.37 6 0.00083 21 -152GD G 391.32 140.00125 21 -152GD G 406.74 150.00083 21 -152GD G 535.4 4 0.0060 16(M1+E2) 1 0.0147044 -152GD G 595.61 1 0.0031 17 -152GD G 683.32 110.0031 8 -152GD G 696.87 190.0029 10 -152GD G 735.4 1 0.0058 10 -152GD G 756.12 9 0.0054 8 -152GD G 896.58 9 0.0669 21 -152GD G 1001.1 3 0.0046 10 -152GD G 1084 1 0.244 8 -152GD G 1139 1 0.0013 3 -152GD G 1674.30 6 0.0060 8 -152GD L 0 0+ STABLE -152GD L 344.2798 122+ 32.4 PS 17 -152GD B 1474.5 118.17 11 12.1 1 -152GDS B EAV=535.4 5 -152GD G 344.2785 1226.59 12E2 0.0399 12 -152GD2 G KC=0.0311 9$LC=0.00687 21$MC=1550E-6 46 -152GD L 615.553 5 0+ -152GD G 271.131 8 0.078 3E2 0.0831 25 -152GD2 G KC=0.0621 19$LC=0.01620 49$MC=0.00370 11 -152GD L 755.3964 174+ 7.3 PS 4 -152GD B 1063.4 110.904 14 12.5 1 -152GDS B EAV=364.6 5 -152GD G 411.1165 122.238 10E2 0.0239 7 -152GD2 G KC=0.0190 6$LC=0.00379 11$MC=8.49E-4 25 -152GD L 930.562 3 2+ 7.3 PS 6 -152GD B 888.2 110.303 7 12.7 1 -152GDS B EAV=295.1 5 -152GD G 315.174 170.0496 17(E2) 0.0521 16 -152GD2 G KC=0.0400 12$LC=0.00938 28$MC=0.00212 6 -152GD G 586.265 3 0.462 4E2+M1+ -4.9 0.0243 9 -152GD2 G KC=0.0202 16 -152GD G 930.58 150.0729 19(E2) 0.0032 1 -152GD2 G KC=0.00270 8$LC=4.00E-4 12$MC=8.72E-5 26 -152GD L 1047.51 6 0+ -152GD G 703.25 6 0.0018 9(E2) 0.0060018 -152GD2 G KC=0.00500 15$LC=7.96E-4 24$MC=1.75E-4 5 -152GD L 1109.076 5 2+ -152GD B 709.7 110.245 8 12.4 1 -152GDS B EAV=226.9 5 -152GD G 493.508 200.009 2(E2) 0.0145044 -152GD2 G KC=0.01180 35$LC=0.00214 6$MC=4.76E-4 14 -152GD G 764.900 9 0.190 4E2+M1 3.8 0.0052016 -152GD2 G KC=0.00440 13$LC=6.69E-4 20$MC=1460E-7 44 -152GD G 1109.174 120.186 4E2 0.00220 7 -152GD2 G KC=0.00190 6$LC=2.69E-4 8$MC=5.84E-5 18 -152GD L 1123.184 2 3- -152GD B 695.6 1113.80 15 10.6 -152GDS B EAV=221.7 4 -152GD G 192.6 4 0.0068 2(E1) 0.0504 15 -152GD2 G KC=0.0426 13$LC=0.00609 18$MC=0.00132 4 -152GD G 367.7891 200.862 5E1 0.0097029 -152GD2 G KC=0.00830 25$LC=1130E-6 34$MC=2.45E-4 7 -152GD G 778.9045 2412.97 6E1 0.00190 6 -152GD2 G KC=1600E-6 48$LC=2.09E-4 6$MC=4.50E-5 14 -152GD L 1282.267 184+ -152GD B 536.5 110.037 8 12.8 1 -152GDS B EAV=164.1 4 -152GD G 351.66 4 0.0140 22E2 0.0375 11 -152GD2 G KC=0.0293 9$LC=0.00639 19$MC=1440E-6 43 -152GD G 526.881 200.0129 6M1+E2+ 0.094 8 -152GD2 G KC=0.084 9 -152GD L 1314.71 201- -152GD B 504.1 110.0048 7 13.6 2 -152GDS B EAV=152.7 4 -152GD G 1314.7 2 0.0048 6E1 7.00E-421 -152GD2 G KC=6.00E-4 18$LC=7.73E-5 23$MC=1.66E-5 5 -152GD L 1318.50 3 2+ -152GD B 500.3 110.0267 17 12.9 1 -152GDS B EAV=151.4 4 -152GD G 387.90 8 0.00296 21(M1+E2+) 0.45 11 -152GD2 G KC=0.38 9 -152GD G 703.25 6 0.0035 9(E2) 0.0060018 -152GD2 G KC=0.00500 15$LC=7.96E-4 24$MC=1.75E-4 5 -152GD G 974.09 4 0.0138 8M1+E2+ 1 0.0056 6 -152GD2 G KC=0.0048 5 -152GD L 1434.025 4 3+ -152GD B 384.8 112.44 3 10.5 -152GDS B EAV=112.3 4 -152GD G 324.83 3 0.0738 15M1+E2 1 0.0636 19 -152GD2 G KC=0.0521 16$LC=0.00897 27$MC=0.00199 6 -152GD G 503.474 5 0.1533 18(E2) 0.0138041 -152GD2 G KC=0.01120 34$LC=0.00202 6$MC=4.48E-4 13 -152GD G 678.623 5 0.470 4E2+M1 4.1 0.0069021 -152GD2 G KC=0.00570 17$LC=9.00E-4 27$MC=1.98E-4 6 -152GD G 1089.737 5 1.73 1(M1)+E2 0.00230 7 -152GD2 G KC=0.00200 6 -152GD L 1550.19 3 4+ -152GD B 268.6 110.0536 18 11.7 1 -152GDS B EAV=75.2 4 -152GD G 440.86 100.0133 10(E2) 0.0197 6 -152GD2 G KC=0.01580 47$LC=0.00303 9$MC=6.77E-4 20 -152GD G 794.81 3 0.0263 10M1(+E2) -0.4 0.0077023 -152GD2 G KC=0.0065 2$LC=9.05E-4 27$MC=1.96E-4 6 -152GD G 1206.11 150.0135 8(E2) 0.00190 6 -152GD2 G KC=1600E-6 48$LC=2.25E-4 7$MC=4.87E-5 15 -152GD L 1605.255 4 2+ -152GD B 213.5 110.101 3 11.1 1 -152GDS B EAV=58.6 4 -152GD G 482.31 3 0.00139 6(E1) 0.0051015 -152GD2 G KC=0.00440 13$LC=5.94E-4 18$MC=1280E-7 38 -152GD G 496.39 3 0.0042 4M1+E2+ 0.097 11 -152GD2 G KC=0.082 9 -152GD G 557.91 170.0044 7(E2) 0.0106032 -152GD2 G KC=0.00870 26$LC=1490E-6 45$MC=3.31E-4 10 -152GD G 674.677 3 0.0171 18E2+M1 0.0076023 -152GD2 G KC=0.00630 19$LC=9.80E-4 29$MC=2.15E-4 6 -152GD G 990.19 3 0.0315 13(E2) 0.00300 9 -152GD2 G KC=0.00240 7$LC=3.47E-4 10$MC=7.55E-5 23 -152GD G 1261.343 230.0336 11M1 0.00270 8 -152GD2 G KC=0.00230 7$LC=3.13E-4 9$MC=6.76E-5 20 -152GD G 1605.61 7 0.0081 4(E2) 9.00E-427 -152GD2 G KC=9.00E-4 27 -152GD L 1643.395 4 2- -152GD B 175.4 111.826 21 9.6 -152GDS B EAV=47.4 4 -152GD G 209.41 130.0055 5(E1) 0.0404 12 -152GD2 G KC=0.0342 10$LC=0.00486 15$MC=1050E-6 32 -152GD G 520.227 5 0.0536 13(M1+E2) 1 0.0181 5 -152GD2 G KC=0.01520 46$LC=0.00230 7$MC=5.04E-4 15 -152GD G 534.245 7 0.0368 19(E1) 0.0041012 -152GD2 G KC=0.0035 1$LC=4.70E-4 14$MC=1.01E-4 3 -152GD G 712.843 6 0.0961 19(E1) 0.00220 7 -152GD2 G KC=0.00190 6$LC=2.51E-4 8$MC=5.41E-5 16 -152GD G 1299.142 8 1.633 9E1(+M2) 0.043 7.00E-421 -152GD2 G KC=6.00E-4 18$LC=8.03E-5 24$MC=1.72E-5 5 -152GD G 1643.6 1 0.0015 4(M2) 0.0032 1 -152GD2 G KC=0.00280 8 -152GD L 1692.447 153+ -152GD B 126.4 110.0203 11 11.1 -152GDS B EAV=33.4 3 -152GD G 937.050 150.0027 6(M1+E2) 1 0.0043013 -152GD2 G KC=0.00370 11$LC=5.16E-4 15$MC=1120E-7 34 -152GD G 1348.10 7 0.0175 8E2+(M1) -13 1600E-648 -152GD2 G KC=1300E-6 39$LC=1.79E-4 5$MC=3.87E-5 12 - +152SM 152EU EC DECAY (13.522 Y) +152SM C References:1977La19 +152SM T Auger electrons and X ray energies and emission intensities: +152SM T {U Energy (keV)} {U Intensity} {U Line} +152SM T +152SM T 39.5229 20.8 3 XKA2 +152SM T 40.1186 37.7 5 XKA1 +152SM T +152SM T 45.289 |] XKB3 +152SM T 45.413 |] 11.78 19 XKB1 +152SM T 45.731 |] XKB5II +152SM T +152SM T 46.575 |] XKB2 +152SM T 46.705 |] 3.04 8 XKB4 +152SM T 46.813 |] XKO23 +152SM T +152SM T 5.61-7.18 13.0 4 XL (total) +152SM T 5.61-5.64 XLA +152SM T -7.18 XLG +152SM T +152SM T 31.19-33.218 |] KLL AUGER +152SM T 37.302-40.097 |] 5.9 4 KLX AUGER +152SM T 43.39-46.79 |] KXY AUGER +152SM T 3.2-7.7 67.7 7 L AUGER +152EU P 0.0 3- 13.522 Y 16 1874.3 7 +152SM N 1.387E0 1.387E0 0.721 1.387E0 +152SM G 237.31 5 0.0025 8(E1) 0.0272 8 +152SM G 320.03 150.0017 6 +152SM G 379.37 6 0.00083 21 +152SM G 391.32 140.00125 21 +152SM G 406.74 150.00083 21 +152SM G 535.4 4 0.0060 16(M1+E2) 1 0.0147044 +152SM G 595.61 1 0.0031 17 +152SM G 683.32 110.0031 8 +152SM G 696.87 190.0029 10 +152SM G 735.4 1 0.0058 10 +152SM G 756.12 9 0.0054 8 +152SM G 896.58 9 0.0669 21 +152SM G 1001.1 3 0.0046 10 +152SM G 1084 1 0.244 8 +152SM G 1139 1 0.0013 3 +152SM G 1674.30 6 0.0060 8 +152SM L 0 0+ STABLE +152SM L 121.7818 3 2+ 1.400 NS 11 +152SM E 0.025 151.7 1011.8 1 +152SM2 E EAV=338.1 3$CK=0.8286 15$CL=0.1223 10$CM=0.02769 49 +152SM3 E CN=0.00680 39 +152SM G 121.7817 3 28.41 13E2 1.165 35 +152SM2 G KC=0.676 20$LC=0.378 11$MC=0.0875 26$NC=0.0200 6 +152SM L 366.4786 8 4+ 57.7 PS 8 +152SM E 0.0024 20.77 512 1 +152SM2 E EAV=230.7 3$CK=0.8372 15$CL=0.1245 11$CM=0.02821 50 +152SM3 E CN=0.00698 40 +152SM G 244.6974 8 7.55 4E2 0.1080 32 +152SM2 G KC=0.0809 24$LC=0.0211 6$MC=0.00475 14$NC=0.001430 43 +152SM L 684.714 200+ +152SM G 562.93 2 0.038 13E2 0.0095028 +152SM2 G KC=0.00780 23$LC=0.001290 39$MC=0.000282 8$NC=6.61E-5 20 +152SM L 706.91 5 6+ +152SM G 340.40 140.031 3E2 0.0385 12 +152SM2 G KC=0.0304 9$LC=0.00632 19$MC=0.001410 42$NC=0.000327 10 +152SM L 810.4474 202+ 7.4 PS 6 +152SM E 1.28 311.4 1 +152SM2 E CK=0.8366 15$CL=0.1273 11$CM=0.0290 6$CN=0.0071 4 +152SM G 125.69 130.019 6(E2) 1.042 31 +152SM2 G KC=0.616 18$LC=0.329 10$MC=0.0760 23$NC=0.0174 5 +152SM G 443.965 3 0.32 2(E2) 0.0178 5 +152SM2 G KC=0.01450 44$LC=0.00263 8$MC=0.000579 17$NC=0.000135 4 +152SM G 688.670 5 0.841 6E2+M1+E0 0.0434 13 +152SM2 G KC=0.0359 13 +152SM G 810.451 5 0.317 3(E2) 0.0040012 +152SM2 G KC=0.0033 1$LC=0.000493 15$MC=1.070E-4 32$NC=2.50E-5 8 +152SM L 963.360 4 1- +152SM G 841.574 5 0.163 2E1 1500E-645 +152SM2 G KC=0.001200 36$LC=1.610E-4 48$MC=3.43E-5 10$NC=8.07E-6 24 +152SM G 963.390 120.1341 20E1 1100E-633 +152SM2 G KC=0.00100 3$LC=1.230E-4 37$MC=2.63E-5 8$NC=6.19E-6 19 +152SM3 G OC=1.038E-6 31 +152SM L 1022.967 5 4- 4.9 PS +152SM E 0.238 511.9 +152SM2 E CK=0.8338 15$CL=0.1294 11$CM=0.0295 6$CN=0.0073 4 +152SM G 212.568 150.0196 6E2 0.171 5 +152SM2 G KC=0.1244 37$LC=0.0364 11$MC=0.00825 25$NC=0.00247 7 +152SM G 316.2 2 0.0031 10(E2) 0.0481 14 +152SM2 G KC=0.0376 11$LC=0.00819 25$MC=0.00183 5$NC=0.000548 16 +152SM G 656.489 5 0.1437 18E2+M1+E0 0.0568 20 +152SM2 G KC=0.0497 16 +152SM G 901.181 110.084 3E2 0.00310 9 +152SM2 G KC=0.00260 8$LC=0.000382 11$MC=8.24E-5 25$NC=1.94E-5 6 +152SM L 1041.1342 183- 27 FS 5 +152SM E 0.086 712.4 +152SM2 E CK=0.8335 15$CL=0.1296 11$CM=0.0296 6$CN=0.0073 4 +152SM G 674.675 3 0.170 4E1 0.00230 7 +152SM2 G KC=0.00190 6$LC=0.000254 8$MC=5.42E-5 16$NC=1.270E-5 38 +152SM G 919.337 4 0.429 5E1 1200E-636 +152SM2 G KC=0.00100 3$LC=0.000135 4$MC=2.88E-5 9$NC=6.78E-6 20 +152SM L 1085.8499 232+ 0.87 PS 4 +152SM E 21.35 119.9 1 +152SM2 E CK=0.8327 15$CL=0.1302 11$CM=0.0297 6$CN=0.0073 4 +152SM G 275.449 150.0323 17(M1) 0.1044 31 +152SM2 G KC=0.0887 27$LC=0.01230 37$MC=0.00265 8$NC=0.000796 24 +152SM G 719.349 4 0.268 13(E2) 0.0052016 +152SM2 G KC=0.00440 13$LC=0.000666 20$MC=1.440E-4 43$NC=3.38E-5 10 +152SM G 964.079 1814.50 6E2(+M1) 0.00270 8 +152SM2 G KC=0.00230 7$LC=0.000327 10$MC=7.03E-5 21$NC=1.65E-5 5 +152SM G 1085.837 1010.13 6E2 0.00210 6 +152SM2 G KC=0.00180 5$LC=0.000250 8$MC=5.36E-5 16$NC=1.260E-5 38 +152SM L 1233.8656 173+ 3 PS 3 +152SM E 17.16 89.8 +152SM2 E CK=0.8291 16$CL=0.1329 11$CM=0.0305 6$CN=0.0075 4 +152SM G 148.010 170.035 5(M1+E2) 1 0.578 17 +152SM2 G KC=0.430 13$LC=0.1150 34$MC=0.0260 8$NC=0.00601 18 +152SM G 423.45 4 0.0032 5(M1+E2) 1 0.0271 8 +152SM2 G KC=0.0226 7$LC=0.0035 1$MC=0.000761 23$NC=0.000179 5 +152SM G 867.380 3 4.243 23E2+M1 -6.5 0.0035 1 +152SM2 G KC=0.00290 9$LC=0.000423 13$MC=9.13E-5 27$NC=2.15E-5 6 +152SM G 1112.076 3 13.41 6E2(+M1) -8.7 0.00200 6 +152SM2 G KC=0.00170 5$LC=0.000238 7$MC=5.11E-5 15$NC=1.200E-5 36 +152SM L 1292.771 6 (2)+ 8 PS 8 +152SM E 0.644 1011.2 1 +152SM2 E CK=0.8271 16$CL=0.1344 11$CM=0.0309 6$CN=0.0076 4 +152SM G 251.633 100.0671 15(E1) 0.0233 7 +152SM2 G KC=0.0198 6$LC=0.00272 8$MC=0.000583 17$NC=0.000175 5 +152SM G 269.86 6 0.0060 24(E2) 0.0789 24 +152SM2 G KC=0.0602 18$LC=0.01460 44$MC=0.00327 10$NC=0.000981 29 +152SM G 329.425 210.129 6(E1) 0.0117035 +152SM2 G KC=0.0100 3$LC=0.001360 41$MC=0.000290 9$NC=8.70E-5 26 +152SM G 482.31 3 0.0279 16(M1+E2) 1 0.0192 6 +152SM2 G KC=0.01610 48$LC=0.00243 7$MC=0.000526 16$NC=1.240E-4 37 +152SM G 926.317 150.273 4(E2) 0.00290 9 +152SM2 G KC=0.00250 8$LC=0.000358 11$MC=7.72E-5 23$NC=1.82E-5 5 +152SM G 1170.93 110.0365 13(M1+E2) 1 0.00230 7 +152SM2 G KC=0.00200 6$LC=0.000265 8$MC=5.67E-5 17$NC=1.34E-5 4 +152SM G 1292.778 190.104 3(E2) 1500E-645 +152SM2 G KC=0.001300 39$LC=0.000172 5$MC=3.68E-5 11$NC=8.69E-6 26 +152SM L 1371.691 9 4+ 1.4 PS 4 +152SM E 0.869 2410.9 1 +152SM2 E CK=0.8236 16$CL=0.1370 11$CM=0.0316 6$CN=0.0078 4 +152SM G 285.98 3 0.0100 6(E2) 0.0657 20 +152SM2 G KC=0.0506 15$LC=0.01180 35$MC=0.00263 8$NC=0.000790 24 +152SM G 330.54 100.0060 17(E1) 0.0116035 +152SM2 G KC=0.0099 3$LC=0.00134 4$MC=0.000288 9$NC=8.63E-5 26 +152SM G 561.2 5 0.00108 21(E2) 0.0096029 +152SM2 G KC=0.00790 24$LC=0.001300 39$MC=0.000285 9$NC=6.66E-5 20 +152SM G 664.78 5 0.010 3(E2) 0.0063019 +152SM2 G KC=0.00520 16$LC=0.000818 25$MC=0.000178 5$NC=4.17E-5 13 +152SM G 1005.272 170.665 23 0.00260 8 +152SM2 G KC=0.00220 7$LC=0.000311 9$MC=6.69E-5 20$NC=1.580E-5 47 +152SM G 1249.938 130.186 3E2 1600E-648 +152SM2 G KC=0.001400 42$LC=0.000184 6$MC=3.95E-5 12$NC=9.32E-6 28 +152SM L 1529.8073 162- 27 FS +152SM E 24.72 119.1 +152SM2 E CK=0.8109 17$CL=0.1465 12$CM=0.0341 7$CN=0.0085 4 +152SM G 295.9387 170.442 3E1 0.0153046 +152SM2 G KC=0.01310 39$LC=0.00178 5$MC=0.000381 11$NC=1.140E-4 34 +152SM G 443.965 3 2.80 2E1(+M2) 0.0060018 +152SM2 G KC=0.00520 16$LC=0.000635 19$MC=1.390E-4 42$NC=3.27E-5 10 +152SM G 488.6792 200.4139 24M1+E2 0.0140042 +152SM2 G KC=0.01150 34$LC=0.00196 6$MC=0.000429 13$NC=0.000100 3 +152SM G 566.442 5 0.131 4M1+E2 -0.74 0.0138041 +152SM2 G KC=0.01170 35$LC=0.00166 5$MC=0.000357 11$NC=8.42E-5 25 +152SM G 719.349 4 0.059 7(E1) 0.00200 6 +152SM2 G KC=0.00170 5$LC=0.000222 7$MC=4.73E-5 14$NC=1.110E-5 33 +152SM G 1408.013 3 20.85 8E1(+M2) 6.00E-418 +152SM2 G KC=0.000500 15$LC=6.15E-5 18$MC=1.310E-5 39$NC=3.08E-6 9 +152SM L 1579.365 3 3- +152SM E 2.068 1210 +152SM2 E CK=0.8036 17$CL=0.1519 12$CM=0.0356 7$CN=0.0088 5 +152SM G 207.6 3 0.0059 4(E1) 0.0385 12 +152SM2 G KC=0.0327 10$LC=0.00455 14$MC=0.000975 29$NC=0.000292 9 +152SM G 493.508 200.0278 30(E1) 0.0045014 +152SM2 G KC=0.00380 11$LC=0.000509 15$MC=1.090E-4 33$NC=2.56E-5 8 +152SM G 538.29 6 0.0042 6(M1+E2) 1 0.0145044 +152SM2 G KC=0.01220 37$LC=0.00180 5$MC=0.000389 12$NC=9.16E-5 27 +152SM G 556.56 3 0.0177 11(E1) 0.0034 1 +152SM2 G KC=0.00290 9$LC=0.000387 12$MC=8.26E-5 25$NC=1.94E-5 6 +152SM G 616.05 3 0.0092 6(E2) 0.0076023 +152SM2 G KC=0.00630 19$LC=0.00100 3$MC=0.000219 7$NC=5.13E-5 15 +152SM G 768.944 9 0.088 3(E1) 0.00170 5 +152SM2 G KC=0.001500 45$LC=0.000193 6$MC=4.12E-5 12$NC=9.69E-6 29 +152SM3 G OC=1.622E-6 49 +152SM G 1212.948 111.416 9E1 7.00E-421 +152SM2 G KC=0.000600 18$LC=8.02E-5 24$MC=1.70E-5 5$NC=4.02E-6 12 +152SM G 1457.643 110.498 4E1 5.00E-415 +152SM2 G KC=0.000500 15$LC=5.80E-5 17$MC=1.230E-5 37$NC=2.90E-6 9 +152SM L 1612.94 6 +152SM E 0.0208 1411.9 +152SM2 E CK=0.7966 18$CL=0.1571 13$CM=0.0370 7$CN=0.0092 5 +152SM G 571.83 8 0.0048 8 +152SM G 906.01 6 0.016 1 +152SM L 1649.910 8 2- +152SM E 0.889 1410.1 +152SM2 E CK=0.7859 19$CL=0.1651 13$CM=0.0392 7$CN=0.0098 5 +152SM G 357.26 5 0.0040 5(E1) 0.0096029 +152SM2 G KC=0.00820 25$LC=0.001110 33$MC=0.000237 7$NC=5.55E-5 17 +152SM G 416.048 8 0.1090 17(E1) 0.0067 2 +152SM2 G KC=0.00570 17$LC=0.000762 23$MC=1.630E-4 49$NC=3.82E-5 11 +152SM G 563.990 7 0.457 13E1 0.0033 1 +152SM2 G KC=0.00280 8$LC=0.000376 11$MC=8.02E-5 24$NC=1.89E-5 6 +152SM G 686.61 5 0.0200 17(M1+E2) 1 0.0079024 +152SM2 G KC=0.0067 2$LC=0.000954 29$MC=0.000205 6$NC=4.84E-5 15 +152SM G 839.36 4 0.0160 8(E1) 1500E-645 +152SM2 G KC=0.001200 36$LC=1.620E-4 49$MC=3.45E-5 10$NC=8.11E-6 24 +152SM G 1528.103 180.281 5E1 5.00E-415 +152SM2 G KC=0.000400 12 +152SM L 1730.241 22(3)- +152SM E 0.0422 1210.9 +152SM2 E CK=0.7339 23$CL=0.2036 16$CM=0.0499 9$CN=0.0125 7 +152SM G 496.39 3 0.0049 5(E1) 0.0044013 +152SM2 G KC=0.00380 11$LC=0.000502 15$MC=1.070E-4 32$NC=2.52E-5 8 +152SM G 644.37 5 0.0063 6(E1) 0.00250 8 +152SM2 G KC=0.00210 6$LC=0.000280 8$MC=5.98E-5 18$NC=1.406E-5 42 +152SM3 G OC=2.35E-6 7 +152SM G 1363.77 5 0.0256 8M1(+E2) 0.00200 6 +152SM2 G KC=0.00170 5$LC=0.000222 7$MC=4.74E-5 14$NC=1.120E-5 34 +152SM G 1608.36 8 0.0053 3(E1) 4.00E-412 +152SM2 G KC=0.000400 12 +152SM L 1757.151 132,3+ +152SM E 0.041 310.7 1 +152SM2 E CK=0.6903 28$CL=0.2358 20$CM=0.0591 11$CN=0.0149 8 +152SM G 385.69 200.0050 6(M1+E2) 1 0.0348 10 +152SM2 G KC=0.0290 9$LC=0.00459 14$MC=0.000999 30$NC=0.000234 7 +152SM G 523.13 5 0.0113 21(M1+E2) 0.0156047 +152SM2 G KC=0.01310 39$LC=0.00194 6$MC=0.000421 13$NC=9.89E-5 30 +152SM G 671.155 170.0194 13M1+E2 0.14 0.0105032 +152SM2 G KC=0.00900 27$LC=0.001220 37$MC=0.000260 8$NC=6.15E-5 18 +152SM G 1390.36 160.0048 6(M1+E2) 1 1600E-648 +152SM2 G KC=0.001400 42$LC=0.000180 5$MC=3.85E-5 12$NC=9.10E-6 27 +152SM G 1635.2 5 0.00015 5(M1+E2) 1 0.00100 3 +152SM2 G KC=0.00100 3 +152SM L 1769.10 3 2+ +152SM E 0.068 510.3 1 +152SM2 E CK=0.6586 33$CL=0.2591 24$CM=0.0657 12$CN=0.0166 9 +152SM G 239.42 170.008 3(E1) 0.0265 8 +152SM2 G KC=0.0225 7$LC=0.00311 9$MC=0.000665 20$NC=0.000199 6 +152SM G 727.99 140.0106 13(E1) 0.00193 6 +152SM2 G KC=0.00166 5$LC=0.000216 6$MC=4.61E-5 14$NC=1.085E-5 33 +152SM3 G OC=1.82E-6 5 +152SM G 805.70 7 0.0125 8(E1) 1600E-648 +152SM2 G KC=0.001400 42$LC=0.000176 5$MC=3.74E-5 11$NC=8.81E-6 26 +152SM G 958.63 5 0.0210 19(M1+E2) 0.0036011 +152SM2 G KC=0.00310 9 +152SM G 1647.41 140.0064 4(E2) 8.00E-424 +152SM2 G KC=0.000800 24 +152SM G 1769.09 5 0.0092 3(E2) 7.00E-421 +152SM2 G KC=0.000700 21 + +152GD 152EU B- DECAY (13.522 Y) +152GD C References:1977La19 +152GD T Auger electrons and X ray energies and emission intensities: +152GD T {U Energy (keV)} {U Intensity} {U Line} +152GD T +152GD T 42.3093 0.243 7 XKA2 +152GD T 42.9967 0.437 12 XKA1 +152GD T +152GD T 48.556 |] XKB3 +152GD T 48.697 |] 0.138 4 XKB1 +152GD T 49.053 |] XKB5II +152GD T +152GD T 49.961 |] XKB2 +152GD T 50.099 |] 0.0363 13 XKB4 +152GD T 50.219 |] XKO23 +152GD T +152GD T 5.3611-8.104 0.177 5 XL (total) +152GD T 5.3611 XLL +152GD T 6.024-6.0578 XLA +152GD T 6.0483 XLC +152GD T 6.6848-7.1888 XLB +152GD T 7.5509-8.104 XLG +152GD T +152GD T 33.31-35.562 |] KLL AUGER +152GD T 39.907-42.976 |] 0.062 4 KLX AUGER +152GD T 46.48-50.2 |] KXY AUGER +152GD T 3.4-8.3 0.800 14 L AUGER +152EU P 0.0 3- 13.522 Y 16 1818.8 11 +152GD N 3.584E0 3.584E0 0.279 3.584E0 +152GD L 0 0+ STABLE +152GD L 344.2798 122+ 32.4 PS 17 +152GD B 1474.5 118.17 11 12.1 1 +152GDS B EAV=535.4 5 +152GD G 344.2785 1226.59 12E2 0.0399 12 +152GD2 G KC=0.0311 9$LC=0.00687 21$MC=0.001550 46$NC=0.000365 11 +152GD L 615.553 5 0+ +152GD G 271.131 8 0.078 3E2 0.0831 25 +152GD2 G KC=0.0621 19$LC=0.01620 49$MC=0.00370 11$NC=0.000867 26 +152GD L 755.3964 174+ 7.3 PS 4 +152GD B 1063.4 110.904 14 12.5 1 +152GDS B EAV=364.6 5 +152GD G 411.1165 122.238 10E2 0.0239 7 +152GD2 G KC=0.0190 6$LC=0.00379 11$MC=0.000849 25$NC=0.000200 6 +152GD L 930.562 3 2+ 7.3 PS 6 +152GD B 888.2 110.303 7 12.7 1 +152GDS B EAV=295.1 5 +152GD G 315.174 170.0496 17(E2) 0.0521 16 +152GD2 G KC=0.0400 12$LC=0.00938 28$MC=0.00212 6$NC=0.000498 15 +152GD G 586.265 3 0.462 4E2+M1+E0 -4.9 0.0243 9 +152GD2 G KC=0.0202 16 +152GD G 930.58 150.0729 19(E2) 0.0032 1 +152GD2 G KC=0.00270 8$LC=0.000400 12$MC=8.72E-5 26$NC=2.07E-5 6 +152GD L 1047.51 6 0+ +152GD G 703.25 6 0.0018 9(E2) 0.0060018 +152GD2 G KC=0.00500 15$LC=0.000796 24$MC=0.000175 5$NC=5.24E-5 16 +152GD L 1109.076 5 2+ +152GD B 709.7 110.245 8 12.4 1 +152GDS B EAV=226.9 5 +152GD G 493.508 200.009 2(E2) 0.0145044 +152GD2 G KC=0.01180 35$LC=0.00214 6$MC=0.000476 14$NC=1.430E-4 43 +152GD G 764.900 9 0.190 4E2+M1 3.8 0.0052016 +152GD2 G KC=0.00440 13$LC=0.000669 20$MC=1.460E-4 44$NC=3.48E-5 10 +152GD3 G OC=5.85E-6 18 +152GD G 1109.174 120.186 4E2 0.00220 7 +152GD2 G KC=0.00190 6$LC=0.000269 8$MC=5.84E-5 18$NC=1.390E-5 42 +152GD L 1123.184 2 3- +152GD B 695.6 1113.80 15 10.6 +152GDS B EAV=221.7 4 +152GD G 192.6 4 0.0068 2(E1) 0.0504 15 +152GD2 G KC=0.0426 13$LC=0.00609 18$MC=0.00132 4$NC=0.000312 9 +152GD G 367.7891 200.862 5E1 0.0097029 +152GD2 G KC=0.00830 25$LC=0.001130 34$MC=0.000245 7$NC=5.82E-5 17 +152GD G 778.9045 2412.97 6E1 0.00190 6 +152GD2 G KC=0.001600 48$LC=0.000209 6$MC=4.50E-5 14$NC=1.070E-5 32 +152GD L 1282.267 184+ +152GD B 536.5 110.037 8 12.8 1 +152GDS B EAV=164.1 4 +152GD G 351.66 4 0.0140 22E2 0.0375 11 +152GD2 G KC=0.0293 9$LC=0.00639 19$MC=0.001440 43$NC=0.000339 10 +152GD G 526.881 200.0129 6M1+E2+E0 0.094 8 +152GD2 G KC=0.084 9 +152GD L 1314.71 201- +152GD B 504.1 110.0048 7 13.6 2 +152GDS B EAV=152.7 4 +152GD G 1314.7 2 0.0048 6E1 7.00E-421 +152GD2 G KC=0.000600 18$LC=7.73E-5 23$MC=1.66E-5 5$NC=3.96E-6 12 +152GD L 1318.50 3 2+ +152GD B 500.3 110.0267 17 12.9 1 +152GDS B EAV=151.4 4 +152GD G 387.90 8 0.00296 21(M1+E2+E0) 0.45 11 +152GD2 G KC=0.38 9 +152GD G 703.25 6 0.0035 9(E2) 0.0060018 +152GD2 G KC=0.00500 15$LC=0.000796 24$MC=0.000175 5$NC=5.24E-5 16 +152GD G 974.09 4 0.0138 8M1+E2+E0 1 0.0056 6 +152GD2 G KC=0.0048 5 +152GD L 1434.025 4 3+ +152GD B 384.8 112.44 3 10.5 +152GDS B EAV=112.3 4 +152GD G 324.83 3 0.0738 15M1+E2 1 0.0636 19 +152GD2 G KC=0.0521 16$LC=0.00897 27$MC=0.00199 6$NC=0.000471 14 +152GD G 503.474 5 0.1533 18(E2) 0.0138041 +152GD2 G KC=0.01120 34$LC=0.00202 6$MC=0.000448 13$NC=0.000134 4 +152GD G 678.623 5 0.470 4E2+M1 4.1 0.0069021 +152GD2 G KC=0.00570 17$LC=0.000900 27$MC=0.000198 6$NC=5.95E-5 18 +152GD G 1089.737 5 1.73 1(M1)+E2 0.00230 7 +152GD2 G KC=0.00200 6 +152GD L 1550.19 3 4+ +152GD B 268.6 110.0536 18 11.7 1 +152GDS B EAV=75.2 4 +152GD G 440.86 100.0133 10(E2) 0.0197 6 +152GD2 G KC=0.01580 47$LC=0.00303 9$MC=0.000677 20$NC=1.600E-4 48 +152GD G 794.81 3 0.0263 10M1(+E2) -0.4 0.0077023 +152GD2 G KC=0.0065 2$LC=0.000905 27$MC=0.000196 6$NC=4.68E-5 14 +152GD G 1206.11 150.0135 8(E2) 0.00190 6 +152GD2 G KC=0.001600 48$LC=0.000225 7$MC=4.87E-5 15$NC=1.160E-5 35 +152GD L 1605.255 4 2+ +152GD B 213.5 110.101 3 11.1 1 +152GDS B EAV=58.6 4 +152GD G 482.31 3 0.00139 6(E1) 0.0051015 +152GD2 G KC=0.00440 13$LC=0.000594 18$MC=1.280E-4 38$NC=3.85E-5 12 +152GD G 496.39 3 0.0042 4M1+E2+E0 0.097 11 +152GD2 G KC=0.082 9 +152GD G 557.91 170.0044 7(E2) 0.0106032 +152GD2 G KC=0.00870 26$LC=0.001490 45$MC=0.000331 10$NC=9.92E-5 30 +152GD G 674.677 3 0.0171 18E2+M1 0.0076023 +152GD2 G KC=0.00630 19$LC=0.000980 29$MC=0.000215 6$NC=6.44E-5 19 +152GD G 990.19 3 0.0315 13(E2) 0.00300 9 +152GD2 G KC=0.00240 7$LC=0.000347 10$MC=7.55E-5 23$NC=1.80E-5 5 +152GD3 G OC=3.05E-6 9 +152GD G 1261.343 230.0336 11M1 0.00270 8 +152GD2 G KC=0.00230 7$LC=0.000313 9$MC=6.76E-5 20$NC=1.620E-5 49 +152GD G 1605.61 7 0.0081 4(E2) 9.00E-427 +152GD2 G KC=0.000900 27 +152GD L 1643.395 4 2- +152GD B 175.4 111.826 21 9.6 +152GDS B EAV=47.4 4 +152GD G 209.41 130.0055 5(E1) 0.0404 12 +152GD2 G KC=0.0342 10$LC=0.00486 15$MC=0.001050 32$NC=0.000249 7 +152GD G 520.227 5 0.0536 13(M1+E2) 1 0.0181 5 +152GD2 G KC=0.01520 46$LC=0.00230 7$MC=0.000504 15$NC=1.510E-4 45 +152GD G 534.245 7 0.0368 19(E1) 0.0041012 +152GD2 G KC=0.0035 1$LC=0.000470 14$MC=0.000101 3$NC=3.04E-5 9 +152GD G 712.843 6 0.0961 19(E1) 0.00220 7 +152GD2 G KC=0.00190 6$LC=0.000251 8$MC=5.41E-5 16$NC=1.290E-5 39 +152GD G 1299.142 8 1.633 9E1(+M2) 0.043 7.00E-421 +152GD2 G KC=0.000600 18$LC=8.03E-5 24$MC=1.72E-5 5$NC=4.11E-6 12 +152GD G 1643.6 1 0.0015 4(M2) 0.0032 1 +152GD2 G KC=0.00280 8 +152GD L 1692.447 153+ +152GD B 126.4 110.0203 11 11.1 +152GDS B EAV=33.4 3 +152GD G 937.050 150.0027 6(M1+E2) 1 0.0043013 +152GD2 G KC=0.00370 11$LC=0.000516 15$MC=1.120E-4 34$NC=2.67E-5 8 +152GD G 1348.10 7 0.0175 8E2+(M1) -13 1600E-648 +152GD2 G KC=0.001300 39$LC=0.000179 5$MC=3.87E-5 12$NC=9.23E-6 28 + diff --git a/HEN_HOUSE/spectra/lnhb/Eu-154.txt b/HEN_HOUSE/spectra/lnhb/Eu-154.txt index c16aca015..31d387ed3 100644 --- a/HEN_HOUSE/spectra/lnhb/Eu-154.txt +++ b/HEN_HOUSE/spectra/lnhb/Eu-154.txt @@ -1,363 +1,336 @@ -154SM 154EU EC DECAY (8.601 Y) -154SM C References: 1952Ka26, 1977La19 -154SM T Auger electrons and X ray energies and emission intensities: -154SM T {U Energy (keV)} {U Intensity} {U Line} -154SM T -154SM T 39.5229 0.006 4 XKA2 -154SM T 40.1186 0.010 8 XKA1 -154SM T -154SM T 45.289 |] XKB3 -154SM T 45.413 |] 0.003 2 XKB1 -154SM T 45.731 |] XKB5II -154SM T -154SM T 46.575 |] XKB2 -154SM T 46.705 |] 0.001 XKB4 -154SM T 46.813 |] XKO23 -154SM T -154SM T 4.99-7.49 0.0044 20 XL (total) -154SM T 4.99 XLL -154SM T -7.49 XLG -154SM T -154SM T 31.19-33.22 |] KLL AUGER -154SM T 37.3-40.18 |] 0.0016 13 KLX AUGER -154SM T 45.3-46.23 |] KXY AUGER -154SM T 3.2-7.6 0.023 13 L AUGER -154EU P 0.0 3- 8.601 Y 4 717.3 11 -154SM N 5.556E3 5.556E3 0.00018 5.556E3 -154SM G 159.9 0.0010 5 -154SM G 195.5 5 0.002 1 -154SM G 197 0.0016 2 -154SM G 274.0 5 0.0039 2 -154SM G 296 1 0.0014 9 0.0166 3 -154SM G 308.2 0.0024 6 -154SM G 320 1 0.0010 7 -154SM G 414.3 0.0049 6 -154SM G 422.1 0.0022 9 -154SM G 435.9 0.0038 10 -154SM G 484.64 0.0039 2 -154SM G 510 0.059 7 -154SM G 512 0.032 7 -154SM G 737.6 0.0063 24 -154SM G 830.3 0.008 3 -154SM G 919.24 0.012 1 -154SM G 928.4 0.0045 21 -154SM G 984.5 0.0094 21 -154SM G 1033.4 0.0119 7 -154SM G 1049.4 1 0.0172 8 -154SM G 1072.2 0.0035 14 -154SM G 1124.2 0.0069 10 -154SM G 1153.1 5 0.011 4 -154SM G 1216.8 0.0033 10 -154SM G 1232.1 5 0.008 5 -154SM G 1316.4 3 0.017 4 -154SM G 1554 0.0011 5 -154SM L 0 0+ STABLE -154SM L 81.98 2+ 3 NS -154SM E 0.013 1312.7 1 -154SM2 E CK=0.8289 16$CL=0.1330 11$CM=0.0305 6 -154SM G 81.99 2 0.0031 21E2 4.93 10 -154SM2 G KC=1.98 4$LC=2.28 5$MC=0.532 11 -154SM L 266.79 4+ 172 PS -154SM E 0.0047 812.9 1 -154SM2 E CK=0.8205 16$CL=0.1393 11$CM=0.0322 6 -154SM G 184.72 0.0037 7E2 0.275 6 -154SM2 G KC=0.193 4$LC=0.0642 13$MC=0.0146 3 -154SM L 543.73 6+ 23 PS - -154GD 154EU B- DECAY (8.601 Y) -154GD C References: 1952Ka26, 1977La19 -154GD T Auger electrons and X ray energies and emission intensities: -154GD T {U Energy (keV)} {U Intensity} {U Line} -154GD T -154GD T 42.3093 7.2 2 XKA2 -154GD T 42.9967 13.0 3 XKA1 -154GD T -154GD T 48.556 |] XKB3 -154GD T 48.697 |] 4.1 1 XKB1 -154GD T 49.053 |] XKB5II -154GD T -154GD T 49.961 |] XKB2 -154GD T 50.099 |] 1.08 3 XKB4 -154GD T 50.219 |] XKO23 -154GD T -154GD T 5.3611-8.104 7.1 3 XL (total) -154GD T 5.3611 XLL -154GD T 6.024-6.0578 XLA -154GD T 6.0483 XLC -154GD T 6.6848-7.1888 XLB -154GD T 7.5509-8.104 XLG -154GD T -154GD T 33.32-35.58 |] KLL AUGER -154GD T 39.98-42.86 |] 1.86 12 KLX AUGER -154GD T 47.98-48.91 |] KXY AUGER -154GD T 3.4-8.3 33.2 6 L AUGER -154EU P 0.0 3- 8.601 Y 4 1968.4 11 -154GD N 1.00E0 1.00E0 0.99982 1.00E0 -154GD G 159.9 0.0010 5 -154GD G 195.5 5 0.002 1 -154GD G 197 0.0016 2 -154GD G 274.0 5 0.0039 2 -154GD G 296 1 0.0014 9 0.0166 3 -154GD G 308.2 0.0024 6 -154GD G 320 1 0.0010 7 -154GD G 414.3 0.0049 6 -154GD G 422.1 0.0022 9 -154GD G 435.9 0.0038 10 -154GD G 484.64 0.0039 2 -154GD G 510 0.059 7 -154GD G 512 0.032 7 -154GD G 737.6 0.0063 24 -154GD G 830.3 0.008 3 -154GD G 919.24 0.012 1 -154GD G 928.4 0.0045 21 -154GD G 984.5 0.0094 21 -154GD G 1033.4 0.0119 7 -154GD G 1049.4 1 0.0172 8 -154GD G 1072.2 0.0035 14 -154GD G 1124.2 0.0069 10 -154GD G 1153.1 5 0.011 4 -154GD G 1216.8 0.0033 10 -154GD G 1232.1 5 0.008 5 -154GD G 1316.4 3 0.017 4 -154GD G 1554 0.0011 5 -154GD L 0 0+ STABLE -154GD L 123.071 2+ 1.18 NS -154GD B 1845.3 1110.3 5 12.4 1 -154GDS B EAV=695.6 5 -154GD G 123.0706 9 40.4 5E2 1.197 19 -154GD2 G KC=0.653 13$LC=0.418 9$MC=0.096 2 -154GD L 371 4+ 40 PS -154GD B 1597.4 110.31 7 13.43 1 -154GDS B EAV=588.0 5 -154GD G 247.9288 7 6.89 7E2 0.110 2 -154GD2 G KC=0.0810 16$LC=0.0228 5 -154GD L 680.66 0+ -154GD G 557.58 5 0.267 5E2 0.0106 2 -154GD2 G KC=0.0087 2$LC=0.0015 3 -154GD G 680.72 10 -154GD L 717.7 6+ -154GD G 346.72 5 0.029 1E2 0.0391 8 -154GD L 815.5 2+ -154GD B 1152.9 110.33 3 12.8 1 -154GDS B EAV=401.0 5 -154GD G 134.84 0.0072 4E2 0.868 18 -154GD G 444.4924 190.560 8E2 0.0192 4 -154GD2 G KC=0.0154 3$LC=$MC=6.50E-4 13 -154GD G 692.4205 181.79 3+M1+E2 0.049 6 -154GD2 G KC=0.040 4$LC=0.0070 7 -154GD G 815.53 5 0.512 7E2 0.00430 9 -154GD2 G KC=0.00360 7$LC=5.48E-4 11 -154GD L 996.26 2+ -154GD B 972.1 112.82 18 11.66 1 -154GDS B EAV=328.1 4 -154GD G 180.7 0.0040 5(M1E2) 0.35 4 -154GD G 315.4 0.007 2(E2) 0.052 1 -154GD G 625.2556 240.317 5E2 0.0079716 -154GD2 G KC=0.00658 13$LC=0.00109 2 -154GD G 873.1834 2312.17 12E2+M1+ 0.00373 8 -154GD2 G KC=0.00313 6$LC=0.00047 1 -154GD G 996.25 5 10.5 1E2 0.00279 6 -154GD2 G KC=0.00236 5$LC=3.42E-4 7 -154GD L 1047.6 4+ -154GD B 920.8 110.108 18 13 1 -154GDS B EAV=307.8 4 -154GD G 232.01 5 0.024 1E2 0.137 3 -154GD G 329.9 7 0.0091 5E2 0.0454 9 -154GD G 676.596 120.157 11+M1+E2 0.059 6 -154GD2 G KC=0.049 5$LC=0.0080 8 -154GD G 924.63 5 0.062 2E2 0.00327 7 -154GD L 1127.8 3+ -154GD B 840.6 1117.33 18 10.64 -154GDS B EAV=276.6 4 -154GD G 80.4 0.0028 14(M1E2) 4.8 10 -154GD G 131.58 5 0.0111 5M1+E2 0.95 4 -154GD G 312.3 0.018 2(M1E2) 0.07 2 -154GD G 756.8020 234.53 5E1+M2 0.0051 12 -154GD2 G KC=0.00431 9$LC=0.00067 2 -154GD G 1004.718 7 17.86 18E1+M2 0.00276 6 -154GD2 G KC=0.00232 5$LC=3.36E-4 7 -154GD L 1136 1,2+ -154GD G 1012.8 2 0.003 1 -154GD G 1136.1 0.007 1 -154GD L 1233.2 + -154GD G 1110 0.003 2 -154GD L 1241.3 1- -154GD G 1118.52 6 0.108 14E1 0.00093 2 -154GD2 G KC=7.98E-4 16$LC=1.03E-4 20 -154GD G 1241.43 100.133 6E1+(M2) 7.71E-415 -154GD2 G KC=6.62E-4 13$LC=8.49E-5 17 -154GD L 1251.6 3- -154GD B 716.8 110.289 6 12.18 -154GDS B EAV=229.5 4 -154GD G 880.60 3 0.081 4E1+M2 0.00153 8 -154GD G 1128.552 7 0.317 5E1 9.15E-418 -154GD2 G KC=7.85E-4 16$LC=1.01E-4 2 -154GD L 1263.78 4+ -154GD B 704.6 110.707 7 11.76 1 -154GDS B EAV=225.0 4 -154GD G 545.6 0.014 2(E2) 0.0112 2 -154GD G 892.775 6 0.514 7+E2+M1 0.00369 8 -154GD G 1140.702 6 0.235 4E2 0.00211 4 -154GD L 1277 + -154GD G 229.01 130.0024 8 -154GD G 906.1 0.0118 6 -154GD L 1294.2 (2)+ -154GD G 165.90 210.0025 5 -154GD G 1170.7 5 0.0036 10 -154GD L 1397.5 2- -154GD B 570.9 1136.06 35 9.74 -154GDS B EAV=176.2 4 -154GD G 146.05 5 0.026 1(M1E2) 0.68 2 -154GD G 156.2 0.0098 4(M1E2) 0.55 3 -154GD G 260.9 0.0022 7 -154GD G 269.8 0.0070 11E1+M2 0.0209 4 -154GD G 401.259 140.189 3(E1M2E3) 0.07 2 -154GD G 582.01 5 0.886 11E1 0.00339 7 -154GD2 G KC=0.00288 6$LC=3.85E-4 8 -154GD G 1274.429 4 34.9 3E1+M2 7.37E-415 -154GD2 G KC=6.32E-4 13$LC=8.10E-5 16 -154GD L 1414.4 1- -154GD G 600 0.006 4(E1) 0.00318 7 -154GD G 1292.0 2 0.0127 5E1 0.00072 2 -154GD G 1415.0 5 0.040 2E1 0.00061 1 -154GD L 1418 2+ -154GD B 550.0 110.075 2 12.23 1 -154GDS B EAV=168.8 4 -154GD G 125.39 5 0.007 2 -154GD G 370.71 0.0056 14E2 0.0321 7 -154GD G 602.81 5 0.0033 2+M1+E2 0.048 6 -154GD G 1047.4 1 0.049 3E2 0.00251 5 -154GD G 1295.5 2 0.0091 10 -154GD G 1418.6 2 0.011 2E2 0.00138 3 -154GD L 1510.1 (1)- -154GD B 458.3 110.021 2 12.66 2 -154GDS B EAV=136.9 4 -154GD G 1387.0 5 0.019 2(E1) 0.00063 2 -154GD G 1510.0 5 0.0048 10(E1) 0.00047 1 -154GD L 1531.3 2+ -154GD B 437.1 110.330 13 11.39 1 -154GDS B EAV=129.8 4 -154GD G 237 0.006 3 0.018 7 -154GD G 267.44 0.0136 7(E2) 0.087 2 -154GD G 279.9 0.0030 2(E1) 0.0190 4 -154GD G 290 0.0033 2(E1) 0.0174 3 -154GD G 403.55 5 0.026 1(M1E2) 0.035 10 -154GD G 483.74 0.0050 3(E2) 0.0153 3 -154GD G 715.77 3 0.19 1(M1E2) 0.013 4 -154GD G 850.64 3 0.241 4E2 0.00392 8 -154GD G 1160.36 8 0.0436 21(E2) 0.00204 4 -154GD G 1408.5 2 0.023 3(M1E2) 0.0037 14 -154GD G 1531.4 2 0.0060 4(E2) 0.00101 2 -154GD L 1560 (4)- -154GD B 408.8 120.100 4 11.81 -154GDS B EAV=120.3 4 -154GD G 162.09 5 0.0011 4(E2) 0.457 9 -154GD G 295.7 0.0024 2(E1) 0.0166 3 -154GD G 563.4 0.0028 7(M2) 0.058 1 -154GD G 1188.34 170.093 7(E1) 0.00083 2 -154GD L 1617.13 3- -154GD B 351.3 111.78 3 10.34 -154GDS B EAV=101.4 4 -154GD G 202.50 160.03 1 -154GD G 219.4 0.0023 5(M1E2) 0.20 4 -154GD G 375.2 5 0.0020 8(E2) 0.0310 6 -154GD G 480.61 0.0048 3 -154GD G 488.26 0.007 3(E1) 0.0049810 -154GD G 569.23 0.0100 8(E1) 0.0036 1 -154GD G 620.52 0.091 5(E1) 0.00296 6 -154GD G 801.21 4 0.012 3(E1) 0.00175 4 -154GD G 1246.121 4 0.862 11E1 7.66E-415 -154GD2 G KC=6.58E-4 13$LC=8.43E-5 17 -154GD G 1494.048 4 0.698 9E1 0.00056 1 -154GD2 G KC=4.81E-4 10$LC=6.11E-5 12 -154GD L 1645.8 4+ -154GD B 322.6 110.148 4 11.31 1 -154GDS B EAV=92.2 4 -154GD G 368.21 0.0030 2 -154GD G 382.00 5 0.0099 4(E2M1) 0.034 11 -154GD G 518.00 5 0.047 2(E2M1) 0.013 1 -154GD G 598.3 0.0062 7M1+E2 0.014 1 -154GD G 649.44 5 0.078 3E2 0.0073 2 -154GD L 1660.9 3+ -154GD B 307.5 110.849 9 10.48 -154GDS B EAV=87.4 3 -154GD G 129.5 0.014 2(M1E2) 0.99 3 -154GD G 397.1 0.029 1(M1E2) 0.036 10 -154GD G 419.4 0.0034 20M2 0.140 3 -154GD G 533.1 0.007 2 -154GD G 613.26 5 0.093 4(E2M1) 0.012 4 -154GD G 664.68 5 0.029 1(M1E2) 0.010 3 -154GD G 845.416 7 0.586 9E2 0.00397 8 -154GD2 G KC=0.00333 7$LC=5.02E-4 10 -154GD G 1290.50 100.025 3(M1E2) 0.0021 5 -154GD G 1537.81 4 0.053 2(M1E2) 0.0012 3 -154GD L 1698.5 (4)+ -154GD B 270.2 110.0100 4 12.33 1 -154GDS B EAV=75.7 3 -154GD G 650.6 0.0098 4(M1E2) 0.026 8 -154GD L 1719.56 2- -154GD B 248.8 1128.32 22 8.66 -154GDS B EAV=69.2 3 -154GD G 58.4 0.0039 4(E1) 1.23 3 -154GD G 188.24 2 0.239 6E1 0.0536 11 -154GD2 G KC=0.0453 9$LC=0.0065 2 -154GD G 209.4 4 0.0025 6 -154GD G 301.25 0.0102 4(E2) 0.0158 3 -154GD G 305.1 0.0174 7(M1E2) 0.075 18 -154GD G 322.02 5 0.066 3(M1E2) 0.065 17 -154GD G 467.84 5 0.0604 24(M1E2) 0.024 7 -154GD G 478.27 5 0.224 3M1 0.0287 6 -154GD2 G KC=0.0245 5$LC=0.00341 7$MC=0.00074 2 -154GD G 591.755 3 4.95 5E1+(M2) 0.0032910 -154GD2 G KC=0.0028 6$LC=3.74E-4 8$MC=3.72E-5 8 -154GD G 723.3014 2220.05 21E1+M2 0.00215 5 -154GD2 G KC=0.00184 4$LC=2.44E-4 5 -154GD G 904.064 3 0.890 11E1(+M2) 0.00138 3 -154GD2 G KC=0.00118 4$LC=1.56E-4 3 -154GD G 1596.4804 281.783 17E1(+M2) 0.00049 1 -154GD2 G KC=4.30E-4 9$LC=5.46E-5 11 -154GD L 1770.2 5+ -154GD B 197.9 110.0022 4 12.46 1U -154GDS B EAV=53.9 3 -154GD G 506.4 0.0063 14E2 0.0136 3 -154GD G 642.4 0.0044 17(M1E2) 0.011 4 -154GD G 774.4 0.008 4(M3) 0.053 2 -154GD G 1397.34 5 0.0031 8(M1E2) 0.0018 4 -154GD L 1790.2 (4)+ -154GD B 178.1 110.022 1 11.31 1 -154GDS B EAV=48.1 3 -154GD G 1419.0 2 0.0020 1(M1E2) 0.0017 4 -154GD G 1667.3 2 0.0019 3(E2) -154GD L 1797 3- -154GD B 171.7 120.060 6 10.8 -154GDS B EAV=46.3 3 -154GD G 533.1 0.004 3E1 0.00412 8 -154GD G 668.9 0.013 2E1 0.00253 5 -154GD G 800.2 0.032 5E1 0.00175 4 -154GD G 981.3 5 0.0084 17(E1) 0.00118 3 -154GD G 1425.9 5 0.0012 7(E1) 0.00060 1 -154GD G 1674.0 5 0.0017 4(E1) -154GD L 1838.6 2+ -154GD B 130.1 120.017 5 10.99 1 -154GDS B EAV=34.5 3 -154GD G 790.2 0.010 3(E2) 0.00462 9 -154GD G 1023 1 0.0066 25(M1E2) -154GD G 1716.9 5 0.0006 3(M1E2) -154GD G 1838.0 5 0.0008 2(E2) -154GD L 1861.5 4- -154GD B 107.2 110.034 3 10.44 -154GDS B EAV=28.1 3 -154GD G 597.5 0.0055 3(E1) 0.00321 7 -154GD G 1489.6 2 0.0029 4(E1) 0.00056 1 -154GD L 1878.5 + -154GD B 89.4 110.0042 3 -154GDS B EAV=23.3 3 -154GD G 463.9 0.0042 3 -154GD L 1894.7 5 2+ -154GD B 73.7 110.0035 6 10.92 1 -154GDS B EAV=19.0 3 -154GD G 898.36 0.0020 5(M1E2) 0.0048 13 -154GD G 1522 1 0.0006 3(E2) 0.00102 2 -154GD G 1773 1 0.00035 21(M1E2) -154GD G 1895 1 0.0006 2(E2) - +154SM 154EU EC DECAY (8.601 Y) +154SM C References:1952Ka26, 1977La19 +154SM T Auger electrons and X ray energies and emission intensities: +154SM T {U Energy (keV)} {U Intensity} {U Line} +154SM T +154SM T 39.5229 0.006 4 XKA2 +154SM T 40.1186 0.010 8 XKA1 +154SM T +154SM T 45.289 |] XKB3 +154SM T 45.413 |] 0.003 2 XKB1 +154SM T 45.731 |] XKB5II +154SM T +154SM T 46.575 |] XKB2 +154SM T 46.705 |] 0.001 XKB4 +154SM T 46.813 |] XKO23 +154SM T +154SM T 4.99-7.49 0.0044 20 XL (total) +154SM T 4.99 XLL +154SM T -7.49 XLG +154SM T +154SM T 31.19-33.22 |] KLL AUGER +154SM T 37.3-40.18 |] 0.0016 13 KLX AUGER +154SM T 45.3-46.23 |] KXY AUGER +154SM T 3.2-7.6 0.023 13 L AUGER +154EU P 0.0 3- 8.601 Y 4 717.3 11 +154SM N 5.556E3 5.556E3 0.00018 5.556E3 +154SM L 0 0+ STABLE +154SM L 81.98 2+ 3 NS +154SM E 0.013 1312.7 1 +154SM2 E CK=0.8289 16$CL=0.1330 11$CM=0.0305 6 +154SM G 81.99 2 0.0031 21E2 4.93 10 +154SM2 G KC=1.98 4$LC=2.28 5$MC=0.532 11 +154SM L 266.79 4+ 172 PS +154SM E 0.0047 812.9 1 +154SM2 E CK=0.8205 16$CL=0.1393 11$CM=0.0322 6 +154SM G 184.72 0.0037 7E2 0.275 6 +154SM2 G KC=0.193 4$LC=0.0642 13$MC=0.0146 3 +154SM L 543.73 6+ 23 PS + +154GD 154EU B- DECAY (8.601 Y) +154GD C References:1952Ka26, 1977La19 +154GD T Auger electrons and X ray energies and emission intensities: +154GD T {U Energy (keV)} {U Intensity} {U Line} +154GD T +154GD T 42.3093 7.2 2 XKA2 +154GD T 42.9967 13.0 3 XKA1 +154GD T +154GD T 48.556 |] XKB3 +154GD T 48.697 |] 4.1 1 XKB1 +154GD T 49.053 |] XKB5II +154GD T +154GD T 49.961 |] XKB2 +154GD T 50.099 |] 1.08 3 XKB4 +154GD T 50.219 |] XKO23 +154GD T +154GD T 5.3611-8.104 7.1 3 XL (total) +154GD T 5.3611 XLL +154GD T 6.024-6.0578 XLA +154GD T 6.0483 XLC +154GD T 6.6848-7.1888 XLB +154GD T 7.5509-8.104 XLG +154GD T +154GD T 33.32-35.58 |] KLL AUGER +154GD T 39.98-42.86 |] 1.86 12 KLX AUGER +154GD T 47.98-48.91 |] KXY AUGER +154GD T 3.4-8.3 33.2 6 L AUGER +154EU P 0.0 3- 8.601 Y 4 1968.4 11 +154GD N 1.00E0 1.00E0 0.99982 1.00E0 +154GD G 159.9 0.0010 5 +154GD G 195.5 5 0.002 1 +154GD G 197 0.0016 2 +154GD G 274.0 5 0.0039 2 +154GD G 296 1 0.0014 9 0.0166 3 +154GD G 308.2 0.0024 6 +154GD G 320 1 0.0010 7 +154GD G 414.3 0.0049 6 +154GD G 422.1 0.0022 9 +154GD G 435.9 0.0038 10 +154GD G 484.64 0.0039 2 +154GD G 510 0.059 7 +154GD G 512 0.032 7 +154GD G 737.6 0.0063 24 +154GD G 830.3 0.008 3 +154GD G 919.24 0.012 1 +154GD G 928.4 0.0045 21 +154GD G 984.5 0.0094 21 +154GD G 1033.4 0.0119 7 +154GD G 1049.4 1 0.0172 8 +154GD G 1072.2 0.0035 14 +154GD G 1124.2 0.0069 10 +154GD G 1153.1 5 0.011 4 +154GD G 1216.8 0.0033 10 +154GD G 1232.1 5 0.008 5 +154GD G 1316.4 3 0.017 4 +154GD G 1554 0.0011 5 +154GD L 0 0+ STABLE +154GD L 123.071 2+ 1.18 NS +154GD B 1845.3 1110.3 5 12.4 1 +154GDS B EAV=695.6 5 +154GD G 123.0706 9 40.4 5E2 1.197 19 +154GD2 G KC=0.653 13$LC=0.418 9$MC=0.096 2 +154GD L 371 4+ 40 PS +154GD B 1597.4 110.31 7 13.43 1 +154GDS B EAV=588.0 5 +154GD G 247.9288 7 6.89 7E2 0.110 2 +154GD2 G KC=0.0810 16$LC=0.0228 5 +154GD L 680.66 0+ +154GD G 557.58 5 0.267 5E2 0.0106 2 +154GD2 G KC=0.0087 2$LC=0.0015 3 +154GD G 680.72 10 E0 +154GD L 717.7 6+ +154GD G 346.72 5 0.029 1E2 0.0391 8 +154GD L 815.5 2+ +154GD B 1152.9 110.33 3 12.8 1 +154GDS B EAV=401.0 5 +154GD G 134.84 0.0072 4E2 0.868 18 +154GD G 444.4924 190.560 8E2 0.0192 4 +154GD2 G KC=0.0154 3$LC=0.00295 6$MC=0.000650 13 +154GD G 692.4205 181.79 3E0+M1+E2 0.049 6 +154GD2 G KC=0.040 4$LC=0.0070 7 +154GD G 815.53 5 0.512 7E2 0.00430 9 +154GD2 G KC=0.00360 7$LC=0.000548 11 +154GD L 996.26 2+ +154GD B 972.1 112.82 18 11.66 1 +154GDS B EAV=328.1 4 +154GD G 180.7 0.0040 5(M1,E2) 0.35 4 +154GD G 315.4 0.007 2(E2) 0.052 1 +154GD G 625.2556 240.317 5E2 0.0079716 +154GD2 G KC=0.00658 13$LC=0.00109 2 +154GD G 873.1834 2312.17 12E2+M1+E0 0.00373 8 +154GD2 G KC=0.00313 6$LC=0.00047 1 +154GD G 996.25 5 10.5 1E2 0.00279 6 +154GD2 G KC=0.00236 5$LC=0.000342 7 +154GD L 1047.6 4+ +154GD B 920.8 110.108 18 13 1 +154GDS B EAV=307.8 4 +154GD G 232.01 5 0.024 1E2 0.137 3 +154GD G 329.9 7 0.0091 5E2 0.0454 9 +154GD G 676.596 120.157 11E0+M1+E2 0.059 6 +154GD2 G KC=0.049 5$LC=0.0080 8 +154GD G 924.63 5 0.062 2E2 0.00327 7 +154GD L 1127.8 3+ +154GD B 840.6 1117.33 18 10.64 +154GDS B EAV=276.6 4 +154GD G 80.4 0.0028 14(M1,E2) 4.8 10 +154GD G 131.58 5 0.0111 5M1+E2 0.95 4 +154GD G 312.3 0.018 2(M1,E2) 0.07 2 +154GD G 756.8020 234.53 5E1+M2 0.0051 12 +154GD2 G KC=0.00431 9$LC=0.00067 2 +154GD G 1004.718 7 17.86 18E1+M2 0.00276 6 +154GD2 G KC=0.00232 5$LC=0.000336 7 +154GD L 1136 1,2+ +154GD G 1012.8 2 0.003 1 +154GD G 1136.1 0.007 1 +154GD L 1233.2 +154GD G 1110 0.003 2 +154GD L 1241.3 1- +154GD G 1118.52 6 0.108 14E1 0.00093 2 +154GD2 G KC=0.000798 16$LC=0.000103 20 +154GD G 1241.43 100.133 6E1+(M2) 7.71E-415 +154GD2 G KC=0.000662 13$LC=8.49E-5 17 +154GD L 1251.6 3- +154GD B 716.8 110.289 6 12.18 +154GDS B EAV=229.5 4 +154GD G 880.60 3 0.081 4E1+M2 0.00153 8 +154GD G 1128.552 7 0.317 5E1 9.15E-418 +154GD2 G KC=0.000785 16$LC=0.000101 2 +154GD L 1263.78 4+ +154GD B 704.6 110.707 7 11.76 1 +154GDS B EAV=225.0 4 +154GD G 545.6 0.014 2(E2) 0.0112 2 +154GD G 892.775 6 0.514 7E0+E2+M1 0.00369 8 +154GD G 1140.702 6 0.235 4E2 0.00211 4 +154GD L 1277 +154GD G 229.01 130.0024 8 +154GD G 906.1 0.0118 6 +154GD L 1294.2 (2)+ +154GD G 165.90 210.0025 5 +154GD G 1170.7 5 0.0036 10 +154GD L 1397.5 2- +154GD B 570.9 1136.06 35 9.74 +154GDS B EAV=176.2 4 +154GD G 146.05 5 0.026 1(M1,E2) 0.68 2 +154GD G 156.2 0.0098 4(M1,E2) 0.55 3 +154GD G 260.9 0.0022 7 +154GD G 269.8 0.0070 11E1+M2 0.0209 4 +154GD G 401.259 140.189 3(E1,M2,E3) 0.07 2 +154GD G 582.01 5 0.886 11E1 0.00339 7 +154GD2 G KC=0.00288 6$LC=0.000385 8 +154GD G 1274.429 4 34.9 3E1+M2 7.37E-415 +154GD2 G KC=0.000632 13$LC=8.10E-5 16 +154GD L 1414.4 1- +154GD G 600 0.006 4(E1) 0.00318 7 +154GD G 1292.0 2 0.0127 5E1 0.00072 2 +154GD G 1415.0 5 0.040 2E1 0.00061 1 +154GD L 1418 2+ +154GD B 550.0 110.075 2 12.23 1 +154GDS B EAV=168.8 4 +154GD G 125.39 5 0.007 2 +154GD G 370.71 0.0056 14E2 0.0321 7 +154GD G 602.81 5 0.0033 2E0+M1+E2 0.048 6 +154GD G 1047.4 1 0.049 3E2 0.00251 5 +154GD G 1295.5 2 0.0091 10 +154GD G 1418.6 2 0.011 2E2 0.00138 3 +154GD L 1510.1 (1)- +154GD B 458.3 110.021 2 12.66 2 +154GDS B EAV=136.9 4 +154GD G 1387.0 5 0.019 2(E1) 0.00063 2 +154GD G 1510.0 5 0.0048 10(E1) 0.00047 1 +154GD L 1531.3 2+ +154GD B 437.1 110.330 13 11.39 1 +154GDS B EAV=129.8 4 +154GD G 237 0.006 3 0.018 7 +154GD G 267.44 0.0136 7(E2) 0.087 2 +154GD G 279.9 0.0030 2(E1) 0.0190 4 +154GD G 290 0.0033 2(E1) 0.0174 3 +154GD G 403.55 5 0.026 1(M1,E2) 0.035 10 +154GD G 483.74 0.0050 3(E2) 0.0153 3 +154GD G 715.77 3 0.19 1(E0,M1,E2) 0.013 4 +154GD G 850.64 3 0.241 4E2 0.00392 8 +154GD G 1160.36 8 0.0436 21(E2) 0.00204 4 +154GD G 1408.5 2 0.023 3(E0,M1,E2) 0.0037 14 +154GD G 1531.4 2 0.0060 4(E2) 0.00101 2 +154GD L 1560 (4)- +154GD B 408.8 120.100 4 11.81 +154GDS B EAV=120.3 4 +154GD G 162.09 5 0.0011 4(E2) 0.457 9 +154GD G 295.7 0.0024 2(E1) 0.0166 3 +154GD G 563.4 0.0028 7(M2) 0.058 1 +154GD G 1188.34 170.093 7(E1) 0.00083 2 +154GD L 1617.13 3- +154GD B 351.3 111.78 3 10.34 +154GDS B EAV=101.4 4 +154GD G 202.50 160.03 1 +154GD G 219.4 0.0023 5(M1,E2) 0.20 4 +154GD G 375.2 5 0.0020 8(E2) 0.0310 6 +154GD G 480.61 0.0048 3 +154GD G 488.26 0.007 3(E1) 0.0049810 +154GD G 569.23 0.0100 8(E1) 0.0036 1 +154GD G 620.52 0.091 5(E1) 0.00296 6 +154GD G 801.21 4 0.012 3(E1) 0.00175 4 +154GD G 1246.121 4 0.862 11E1 7.66E-415 +154GD2 G KC=0.000658 13$LC=8.43E-5 17 +154GD G 1494.048 4 0.698 9E1 0.00056 1 +154GD2 G KC=0.000481 10$LC=6.11E-5 12 +154GD L 1645.8 4+ +154GD B 322.6 110.148 4 11.31 1 +154GDS B EAV=92.2 4 +154GD G 368.21 0.0030 2 +154GD G 382.00 5 0.0099 4(E2,M1) 0.034 11 +154GD G 518.00 5 0.047 2(E2,M1) 0.013 1 +154GD G 598.3 0.0062 7M1+E2 0.014 1 +154GD G 649.44 5 0.078 3E2 0.0073 2 +154GD L 1660.9 3+ +154GD B 307.5 110.849 9 10.48 +154GDS B EAV=87.4 3 +154GD G 129.5 0.014 2(M1,E2) 0.99 3 +154GD G 397.1 0.029 1(M1,E2) 0.036 10 +154GD G 419.4 0.0034 20M2 0.140 3 +154GD G 533.1 0.007 2 +154GD G 613.26 5 0.093 4(E2,M1) 0.012 4 +154GD G 664.68 5 0.029 1(M1,E2) 0.010 3 +154GD G 845.416 7 0.586 9E2 0.00397 8 +154GD2 G KC=0.00333 7$LC=0.000502 10 +154GD G 1290.50 100.025 3(M1,E2) 0.0021 5 +154GD G 1537.81 4 0.053 2(M1,E2) 0.0012 3 +154GD L 1698.5 (4)+ +154GD B 270.2 110.0100 4 12.33 1 +154GDS B EAV=75.7 3 +154GD G 650.6 0.0098 4(E0,M1,E2) 0.026 8 +154GD L 1719.56 2- +154GD B 248.8 1128.32 22 8.66 +154GDS B EAV=69.2 3 +154GD G 58.4 0.0039 4(E1) 1.23 3 +154GD G 188.24 2 0.239 6E1 0.0536 11 +154GD2 G KC=0.0453 9$LC=0.0065 2 +154GD G 209.4 4 0.0025 6 +154GD G 301.25 0.0102 4(E2) 0.0158 3 +154GD G 305.1 0.0174 7(M1,E2) 0.075 18 +154GD G 322.02 5 0.066 3(M1,E2) 0.065 17 +154GD G 467.84 5 0.0604 24(M1,E2) 0.024 7 +154GD G 478.27 5 0.224 3M1 0.0287 6 +154GD2 G KC=0.0245 5$LC=0.00341 7$MC=0.00074 2 +154GD G 591.755 3 4.95 5E1+(M2) 0.0032910 +154GD2 G KC=0.0028 6$LC=0.000374 8$MC=3.72E-5 8 +154GD G 723.3014 2220.05 21E1+M2 0.00215 5 +154GD2 G KC=0.00184 4$LC=0.000244 5 +154GD G 904.064 3 0.890 11E1(+M2) 0.00138 3 +154GD2 G KC=0.00118 4$LC=0.000156 3 +154GD G 1596.4804 281.783 17E1(+M2) 0.00049 1 +154GD2 G KC=0.000430 9$LC=5.46E-5 11 +154GD L 1770.2 5+ +154GD B 197.9 110.0022 4 12.46 1U +154GDS B EAV=53.9 3 +154GD G 506.4 0.0063 14E2 0.0136 3 +154GD G 642.4 0.0044 17(M1,E2) 0.011 4 +154GD G 774.4 0.008 4(M3) 0.053 2 +154GD G 1397.34 5 0.0031 8(M1,E2) 0.0018 4 +154GD L 1790.2 (4)+ +154GD B 178.1 110.022 1 11.31 1 +154GDS B EAV=48.1 3 +154GD G 1419.0 2 0.0020 1(M1,E2) 0.0017 4 +154GD G 1667.3 2 0.0019 3(E2) +154GD L 1797 3- +154GD B 171.7 120.060 6 10.8 +154GDS B EAV=46.3 3 +154GD G 533.1 0.004 3E1 0.00412 8 +154GD G 668.9 0.013 2E1 0.00253 5 +154GD G 800.2 0.032 5E1 0.00175 4 +154GD G 981.3 5 0.0084 17(E1) 0.00118 3 +154GD G 1425.9 5 0.0012 7(E1) 0.00060 1 +154GD G 1674.0 5 0.0017 4(E1) +154GD L 1838.6 2+ +154GD B 130.1 120.017 5 10.99 1 +154GDS B EAV=34.5 3 +154GD G 790.2 0.010 3(E2) 0.00462 9 +154GD G 1023 1 0.0066 25(M1,E2) +154GD G 1716.9 5 0.0006 3(M1,E2) +154GD G 1838.0 5 0.0008 2(E2) +154GD L 1861.5 4- +154GD B 107.2 110.034 3 10.44 +154GDS B EAV=28.1 3 +154GD G 597.5 0.0055 3(E1) 0.00321 7 +154GD G 1489.6 2 0.0029 4(E1) 0.00056 1 +154GD L 1878.5 +154GD B 89.4 110.0042 3 +154GDS B EAV=23.3 3 +154GD G 463.9 0.0042 3 +154GD L 1894.7 5 2+ +154GD B 73.7 110.0035 6 10.92 1 +154GDS B EAV=19.0 3 +154GD G 898.36 0.0020 5(M1,E2) 0.0048 13 +154GD G 1522 1 0.0006 3(E2) 0.00102 2 +154GD G 1773 1 0.00035 21(M1,E2) +154GD G 1895 1 0.0006 2(E2) + diff --git a/HEN_HOUSE/spectra/lnhb/Eu-155.txt b/HEN_HOUSE/spectra/lnhb/Eu-155.txt index 22e2df417..230029af5 100644 --- a/HEN_HOUSE/spectra/lnhb/Eu-155.txt +++ b/HEN_HOUSE/spectra/lnhb/Eu-155.txt @@ -1,75 +1,74 @@ -155GD 155EU B- DECAY (4.753 Y) -155GD C References: 1977La19 -155GD T Auger electrons and X ray energies and emission intensities: -155GD T {U Energy (keV)} {U Intensity} {U Line} -155GD T -155GD T 42.3093 6.70 13 XKA2 -155GD T 42.9967 12.05 23 XKA1 -155GD T -155GD T 48.556 |] XKB3 -155GD T 48.697 |] 3.84 11 XKB1 -155GD T 49.053 |] XKB5II -155GD T -155GD T 49.961 |] XKB2 -155GD T 50.099 |] 0.977 26 XKB4 -155GD T 50.219 |] XKO23 -155GD T -155GD T 5.3611-8.104 7.5 5 XL (total) -155GD T 5.3611 XLL -155GD T 6.024-6.0578 XLA -155GD T 6.0483 XLC -155GD T 6.6848-7.1888 XLB -155GD T 7.5509-8.104 XLG -155GD T -155GD T 33.49-35.75 |] KLL AUGER -155GD T 39.98-42.86 |] 1.71 11 KLX AUGER -155GD T 47.98-48.95 |] KXY AUGER -155GD T 3.4-8.3 35.1 20 L AUGER -155EU P 0.0 5/2+ 4.753 Y 14 252.1 11 -155GD N 1.0 1.0 1 1.0 -155GD L 0 3/2- STABLE -155GD B 252.2 1116.6 11 8.65 1 -155GDS B EAV=70.2 3 -155GD L 60.0086 105/2- 0.193 NS 10 -155GD B 192.2 119.2 4 8.54 -155GDS B EAV=52.3 3 -155GD G 60.0086 101.22 5M1+E2 9.48 11 -155GD2 G KC=7.48 9$LC=1.55 6$MC=0.347 14 -155GD L 86.5479 105/2+ 6.50 NS 4 -155GD B 165.7 1125.5 29 7.89 -155GDS B EAV=44.6 3 -155GD G 26.531 210.316 22E1 1.98 6 -155GD2 G LC=1.55 5$MC=0.342 11 -155GD G 86.5479 1030.7 3E1 0.432 7 -155GD2 G KC=0.360 4$LC=0.0561 17$MC=0.0122 4 -155GD L 105.3083 103/2+ 1.16 NS 1 -155GD B 146.9 1146.1 29 7.47 -155GDS B EAV=39.2 3 -155GD G 18.763 2 0.048 7M1+E2 367 22 -155GD2 G LC=284 22$MC=65.9 30 -155GD G 45.299 1 1.31 5E1 0.443 11 -155GD2 G LC=0.347 10$MC=0.0758 23 -155GD G 105.3083 1021.1 6E1 0.255 3 -155GD2 G KC=0.214 2$LC=0.0323 10$MC=0.00701 21 -155GD L 107.583 5 9/2+ -155GD B 144.6 110.01 11.1 2 -155GDS B EAV= -155GD G 21.035 4 0.00046 3E2 2600 70 -155GD2 G LC=2010 60$MC=471 14 -155GD L 117.998 2 7/2+ -155GD B 134.2 111.85 23 8.75 -155GDS B EAV=35.6 3 -155GD G 10.4183 130.0035 4M1+E2 340 23 -155GD2 G LC=265 22$MC=59 5 -155GD G 31.444 7 0.0071 15M1+E2 69 14 -155GD2 G LC=53 13$MC=12.5 30 -155GD G 57.989 1 0.067 6E1 1.243 11 -155GD2 G KC=1.021 10$LC=0.173 5$MC=0.0377 11 -155GD L 146.0711 107/2- 0.101 NS 120 -155GD B 106.1 110.73 7 8.83 1 -155GDS B EAV=27.8 3 -155GD G 86.0591 100.154 17M1+E2 3.23 4 -155GD2 G KC=2.66 3$LC=0.443 17$MC=0.098 4 -155GD G 146.071 1 0.051 4E2 0.653 8 -155GD2 G KC=0.397 4$LC=0.198 6$MC=0.0462 14 - +155GD 155EU B- DECAY (4.753 Y) +155GD C References:1977La19 +155GD T Auger electrons and X ray energies and emission intensities: +155GD T {U Energy (keV)} {U Intensity} {U Line} +155GD T +155GD T 42.3093 6.70 13 XKA2 +155GD T 42.9967 12.05 23 XKA1 +155GD T +155GD T 48.556 |] XKB3 +155GD T 48.697 |] 3.84 11 XKB1 +155GD T 49.053 |] XKB5II +155GD T +155GD T 49.961 |] XKB2 +155GD T 50.099 |] 0.977 26 XKB4 +155GD T 50.219 |] XKO23 +155GD T +155GD T 5.3611-8.104 7.5 5 XL (total) +155GD T 5.3611 XLL +155GD T 6.024-6.0578 XLA +155GD T 6.0483 XLC +155GD T 6.6848-7.1888 XLB +155GD T 7.5509-8.104 XLG +155GD T +155GD T 33.49-35.75 |] KLL AUGER +155GD T 39.98-42.86 |] 1.71 11 KLX AUGER +155GD T 47.98-48.95 |] KXY AUGER +155GD T 3.4-8.3 35.1 20 L AUGER +155EU P 0.0 5/2+ 4.753 Y 14 252.1 11 +155GD N 1.0 1.0 1 1.0 +155GD L 0 3/2- STABLE +155GD B 252.2 1116.6 11 8.65 1 +155GDS B EAV=70.2 3 +155GD L 60.0086 105/2- 0.193 NS 10 +155GD B 192.2 119.2 4 8.54 +155GDS B EAV=52.3 3 +155GD G 60.0086 101.22 5M1+E2 9.48 11 +155GD2 G KC=7.48 9$LC=1.55 6$MC=0.347 14 +155GD L 86.5479 105/2+ 6.50 NS 4 +155GD B 165.7 1125.5 29 7.89 +155GDS B EAV=44.6 3 +155GD G 26.531 210.316 22E1 1.98 6 +155GD2 G LC=1.55 5$MC=0.342 11 +155GD G 86.5479 1030.7 3E1 0.432 7 +155GD2 G KC=0.360 4$LC=0.0561 17$MC=0.0122 4 +155GD L 105.3083 103/2+ 1.16 NS 1 +155GD B 146.9 1146.1 29 7.47 +155GDS B EAV=39.2 3 +155GD G 18.763 2 0.048 7M1+E2 367 22 +155GD2 G LC=284 22$MC=65.9 30 +155GD G 45.299 1 1.31 5E1 0.443 11 +155GD2 G LC=0.347 10$MC=0.0758 23 +155GD G 105.3083 1021.1 6E1 0.255 3 +155GD2 G KC=0.214 2$LC=0.0323 10$MC=0.00701 21 +155GD L 107.583 5 9/2+ +155GD B 144.6 110.01 11.1 2 +155GD G 21.035 4 0.00046 3E2 2600 70 +155GD2 G LC=2010 60$MC=471 14 +155GD L 117.998 2 7/2+ +155GD B 134.2 111.85 23 8.75 +155GDS B EAV=35.6 3 +155GD G 10.4183 130.0035 4M1+E2 340 23 +155GD2 G LC=265 22$MC=59 5 +155GD G 31.444 7 0.0071 15M1+E2 69 14 +155GD2 G LC=53 13$MC=12.5 30 +155GD G 57.989 1 0.067 6E1 1.243 11 +155GD2 G KC=1.021 10$LC=0.173 5$MC=0.0377 11 +155GD L 146.0711 107/2- 0.101 NS 120 +155GD B 106.1 110.73 7 8.83 1 +155GDS B EAV=27.8 3 +155GD G 86.0591 100.154 17M1+E2 3.23 4 +155GD2 G KC=2.66 3$LC=0.443 17$MC=0.098 4 +155GD G 146.071 1 0.051 4E2 0.653 8 +155GD2 G KC=0.397 4$LC=0.198 6$MC=0.0462 14 + diff --git a/HEN_HOUSE/spectra/lnhb/F-18.txt b/HEN_HOUSE/spectra/lnhb/F-18.txt index a3e8adb3f..6af53e6f4 100644 --- a/HEN_HOUSE/spectra/lnhb/F-18.txt +++ b/HEN_HOUSE/spectra/lnhb/F-18.txt @@ -1,30 +1,27 @@ - 18O 18F EC DECAY (1.82890 H) - 18O H TYP=UPD$AUT=N.K. Kuzmenko$CUT=01-JUN-2014$ - 18O 2 H TYP=UPD$AUT=V. Chisté. M.-M. Bé$CUT=01-JUN-2006$ - 18O 3 H TYP=FUL$AUT=V. Chisté. M.-M. Bé$CUT=01-OCT-2002$ - 18O C Evaluation history: Type=UPD;Author=N.K. Kuzmenko;Cutoff date=01-JUN-2014 - 18O 2C Type=UPD;Author=V. Chisté. M.-M. Bé;Cutoff date=01-JUN-2006 - 18O 3C Type=FUL;Author=V. Chisté. M.-M. Bé;Cutoff date=01-OCT-2002 - 18O C References: 1938Br01, 1943Hu02, 1949Bl26, 1951Ru24, 1956Dr38, 1958Be74, - 18O 2C 1958Ma68, 1959Aj76, 1959Ca01, 1960Yu02, 1961Ra06, 1962Ma48, 1963Be47, - 18O 3C 1964Ho28, 1964Ho09, 1964Ma12, 1965Eb01, 1965Bo42, 1970Al11, 1972Aj02, - 18O 4C 1973Ho43, 1977Ba48, 1978Aj03, 1980RuZY, 1987Aj02, 1989Sc17, 2002Un02, - 18O 5C 2004BeZQ, 2004Sc04, 2010Ga04, 2012Ha35, 2012Wa38, 2014Un01 - 18O T Auger electrons and X ray energies and emission intensities: - 18O T {U Energy (keV)} {U Intensity} {U Line} - 18O T - 18O T 0.525 0.007 2 XKA2 - 18O T 0.525 0.013 4 XKA1 - 18O T - 18O T - 18O T - 18O T - 18O T 0.456-0.502 |] KLL AUGER - 18O T - |] 2.89 18 KLX AUGER - 18O T -0.0143 0.229 21 L AUGER - 18F P 0.0 1+ 1.82890 H 23 1655.9 5 - 18O N 1.0 1.0 1 1.0 - 18O L 0 0+ STABLE - 18O E 96.86 193.14 193.57 - 18O 2 E EAV=249.5 3$CK=0.927 5$CL=0.073 5 - + 18O 18F EC DECAY (1.82890 H) + 18O H TYP=UPD$AUT=N.K.KUZMENKO$CUT=01-JUN-2014$ + 18O 2 H TYP=UPD$AUT=V.CHISTE, M.-M.BE$CUT=01-JUN-2006$ + 18O 3 H TYP=FUL$AUT=V.CHISTE, M.-M.BE$CUT=01-OCT-2002$ + 18O C References:1938Br01, 1943Hu02, 1949Bl26, 1951Ru24, 1956Dr38, 1958Be74, + 18O 2C 1958Ma68, 1959Aj76, 1959Ca01, 1960Yu02, 1961Ra06, 1962Ma48, 1963Be47, + 18O 3C 1964Ho28, 1964Ho09, 1964Ma12, 1965Eb01, 1965Bo42, 1970Al11, 1972Aj02, + 18O 4C 1973Ho43, 1977Ba48, 1978Aj03, 1980RuZY, 1987Aj02, 1989Sc17, 2002Un02, + 18O 5C 2004BeZQ, 2004Sc04, 2010Ga04, 2012Ha35, 2012Wa38, 2014Un01 + 18O T Auger electrons and X ray energies and emission intensities: + 18O T {U Energy (keV)} {U Intensity} {U Line} + 18O T + 18O T 0.525 0.007 2 XKA2 + 18O T 0.525 0.013 4 XKA1 + 18O T + 18O T + 18O T + 18O T + 18O T 0.456-0.502 |] KLL AUGER + 18O T - |] 2.89 18 KLX AUGER + 18O T -0.0143 0.229 21 L AUGER + 18F P 0.0 1+ 1.82890 H 23 1655.9 5 + 18O N 1.0 1.0 1 1.0 + 18O L 0 0+ STABLE + 18O E 96.86 193.14 193.57 + 18O 2 E EAV=249.5 3$CK=0.02911 16$CL=0.00229 16 + diff --git a/HEN_HOUSE/spectra/lnhb/Fe-52.txt b/HEN_HOUSE/spectra/lnhb/Fe-52.txt index 647d1330a..d1836b9a0 100644 --- a/HEN_HOUSE/spectra/lnhb/Fe-52.txt +++ b/HEN_HOUSE/spectra/lnhb/Fe-52.txt @@ -1,44 +1,44 @@ - 52MN 52FE EC DECAY (8.273 H) - 52MN H TYP=FULL$AUT=A.Luca$CUT=30-SEP-2013$ - 52MN C Evaluation history: Type=FULL;Author=A.Luca;Cutoff date=30-SEP-2013 - 52MN C References: 1948Mi12, 1956Ar33, 1959Ju40, 1960Ka20, 1967Pa22, 1971Go40, - 52MN2C 1971Sa21, 1972McYW, 1974Ro18, 1977Ya08, 1996Sc06, 1998Sc28, 2000Sc47, - 52MN3C 2007Hu08, 2008Ki07, 2012Wa38 - 52MN T Auger electrons and X ray energies and emission intensities: - 52MN T {U Energy (keV)} {U Intensity} {U Line} - 52MN T - 52MN T 5.88772 3.70 17 XKA2 - 52MN T 5.89881 7.3 4 XKA1 - 52MN T - 52MN T 6.49051 |] 1.49 7 XKB1 - 52MN T 6.5354 |] XKB5II - 52MN T - 52MN T - 52MN T 0.5576-0.7694 0.213 10 XL (total) - 52MN T 0.5576 0.124 8 XLL - 52MN T 0.6394-0.6404 XLA - 52MN T 0.5695 0.085 6 XLC - 52MN T 0.64636-0.7694 0.00315 18 XLB - 52MN T 0.65826-0.65826 XLG - 52MN T - 52MN T 4.953-5.21 |] KLL AUGER - 52MN T 5.671-5.895 |] 26.3 11 KLX AUGER - 52MN T 6.37-6.532 |] KXY AUGER - 52MN T 0.4725-0.7653 57.1 15 L AUGER - 52FE P 0.0 0+ 8.273 H 8 2375 6 - 52MN N 1.0 1.0 1 1.0 - 52MN L 0 6+ 5.591 D 3 - 52MN L 377.749 5 2+ 21.1 M 2 - 52MN G 377.749 5 1.64 4E4 0.0399 6 - 52MN2 G KC=0.0356 5$LC=0.00382 6$MC=5.15E-4 8 - 52MN L 546.438 6 1+ - 52MN E 56.1 743.8 134.7 - 52MN2 E EAV=339 6$CK=0.8898 16$CL=0.0946 13$CM=0.0150 5$CN=0.0006 2 - 52MN G 168.689 8 99.1 15M1 0.0078311 - 52MN2 G KC=0.00705 10$LC=6.79E-4 10$MC=9.22E-5 13 - 52MN L 1417.688 18 + - 52MN E 0.095 45.8 - 52MN2 E CK=0.8892 16$CL=0.0950 13$CM=0.0151 5$CN=0.0006 2 - 52MN G 1039.939 190.095 4M1+E2 1.43E-416 - 52MN2 G KC=1.30E-4 15$LC=1.22E-5 14$MC=1.65E-6 19 - + 52MN 52FE EC DECAY (8.273 H) + 52MN H TYP=FUL$AUT=A.LUCA$CUT=30-SEP-2013$ + 52MN C References:1948Mi12, 1956Ar33, 1959Ju40, 1960Ka20, 1967Pa22, 1971Go40, + 52MN2C 1971Sa21, 1972McYW, 1974Ro18, 1977Ya08, 1996Sc06, 1998Sc28, 2000Sc47, + 52MN3C 2007Hu08, 2008Ki07, 2012Wa38 + 52MN T Auger electrons and X ray energies and emission intensities: + 52MN T {U Energy (keV)} {U Intensity} {U Line} + 52MN T + 52MN T 5.88772 3.70 17 XKA2 + 52MN T 5.89881 7.3 4 XKA1 + 52MN T + 52MN T 6.49051 |] 1.49 7 XKB1 + 52MN T 6.5354 |] XKB5II + 52MN T + 52MN T + 52MN T 0.5576-0.7694 0.213 10 XL (total) + 52MN T 0.5576 0.124 8 XLL + 52MN T 0.6394-0.6404 1E-9 XLA + 52MN T 0.5695 0.085 6 XLC + 52MN T 0.64636-0.7694 0.00315 18 XLB + 52MN T 0.65826-0.65826 1E-9 XLG + 52MN T + 52MN T 4.953-5.21 |] KLL AUGER + 52MN T 5.671-5.895 |] 26.3 11 KLX AUGER + 52MN T 6.37-6.532 |] KXY AUGER + 52MN T 0.4725-0.7653 57.1 15 L AUGER + 52FE P 0.0 0+ 8.273 H 8 2375 6 + 52MN N 1.0 1.0 1 1.0 + 52MN L 0 6+ 5.591 D 3 + 52MN L 377.749 5 2+ 21.1 M 2 + 52MN G 377.749 5 1.64 4E4 0.0399 6 + 52MN2 G KC=0.0356 5$LC=0.00382 6$MC=0.000515 8$NC=2.13E-5 3 + 52MN L 546.438 6 1+ + 52MN E 56.1 743.8 134.7 + 52MN2 E EAV=339 6$CK=0.3901 7$CL=0.0415 6$CM=0.00658 22 + 52MN3 E CN=0.00026 9 + 52MN G 168.689 8 99.1 15M1 0.0078311 + 52MN2 G KC=0.00705 10$LC=0.000679 10$MC=9.22E-5 13$NC=4.37E-6 7 + 52MN L 1417.688 18 + 52MN E 0.095 45.8 + 52MN2 E CK=0.8892 16$CL=0.0950 13$CM=0.0151 5$CN=0.0006 2 + 52MN G 1039.939 190.095 4M1+E2 1.43E-416 + 52MN2 G KC=0.000130 15$LC=1.22E-5 14$MC=1.65E-6 19$NC=8.0E-8 9 + diff --git a/HEN_HOUSE/spectra/lnhb/Fe-55.txt b/HEN_HOUSE/spectra/lnhb/Fe-55.txt index bca375b27..365250fd4 100644 --- a/HEN_HOUSE/spectra/lnhb/Fe-55.txt +++ b/HEN_HOUSE/spectra/lnhb/Fe-55.txt @@ -1,35 +1,34 @@ - 55MN 55FE EC DECAY (2.747 Y) - 55MN H TYP=Updated$AUT=MMBé$CUT=20-DEC-2005$ - 55MN2 H TYP=Full$AUT=MMBé$CUT=01-APR-1998$ - 55MN C Evaluation history: Type=Updated;Author=MMBé;Cutoff date=20-DEC-2005 - 55MN2C Type=Full;Author=MMBé;Cutoff date=01-APR-1998 - 55MN C References: 1977La19 - 55MN T Auger electrons and X ray energies and emission intensities: - 55MN T {U Energy (keV)} {U Intensity} {U Line} - 55MN T - 55MN T 5.88765 8.45 14 XKA2 - 55MN T 5.89875 16.57 27 XKA1 - 55MN T - 55MN T 6.49045 |] XKB3 - 55MN T |] 3.40 7 XKB1 - 55MN T 6.5352 |] XKB5II - 55MN T - 55MN T - 55MN T 0.556-0.721 0.524 21 XL (total) - 55MN T 0.556 0.309 17 XLL - 55MN T 0.567 0.204 13 XLC - 55MN T 0.649-0.721 0.0104 5 XLB - 55MN T - 55MN T 4.953-5.21 |] KLL AUGER - 55MN T 5.671-5.895 |] 60.1 5 KLX AUGER - 55MN T 6.37-6.532 |] KXY AUGER - 55MN T 0.47-0.67 140.2 8 L AUGER - 55FE P 0.0 3/2- 2.747 Y 8 231.21 18 - 55MN N 1.0 1.0 1 1.0 - 55MN L 0 5/2- STABLE - 55MN E 100 6 - 55MN2 E CK=0.8853 16$CL=0.0983 13$CM=0.0163 8 - 55MN L 125.949 107/2- - 55MN E 1.3E-7 114.2 2 - 55MN G 125.949 101.3E-7 1M1+(E2) - + 55MN 55FE EC DECAY (2.747 Y) + 55MN H TYP=UPD$AUT=M.-M.BE$CUT=20-DEC-2005$ + 55MN2 H TYP=FUL$AUT=M.-M.BE$CUT=01-APR-1998$ + 55MN C References:1977La19 + 55MN T Auger electrons and X ray energies and emission intensities: + 55MN T {U Energy (keV)} {U Intensity} {U Line} + 55MN T + 55MN T 5.88765 8.45 14 XKA2 + 55MN T 5.89875 16.57 27 XKA1 + 55MN T + 55MN T 6.49045 |] XKB3 + 55MN T |] 3.40 7 XKB1 + 55MN T 6.5352 |] XKB5II + 55MN T + 55MN T + 55MN T 0.556-0.721 0.524 21 XL (total) + 55MN T 0.556 0.309 17 XLL + 55MN T 0.567 0.204 13 XLC + 55MN T 0.649-0.721 0.0104 5 XLB + 55MN T + 55MN T 4.953-5.21 |] KLL AUGER + 55MN T 5.671-5.895 |] 60.1 5 KLX AUGER + 55MN T 6.37-6.532 |] KXY AUGER + 55MN T 0.47-0.67 140.2 8 L AUGER + 55FE P 0.0 3/2- 2.747 Y 8 231.21 18 + 55MN N 1.0 1.0 1 1.0 + 55MN L 0 5/2- STABLE + 55MN E 100 6 + 55MN2 E CK=0.8853 16$CL=0.0983 13$CM=0.0163 8 + 55MN L 125.949 107/2- + 55MN E 1.3E-7 114.2 2 + 55MN2 E CK=0.8786 17$CL=0.1039 14$CM=0.0167 6$CN=0.0007 2 + 55MN G 125.949 101.3E-7 1M1+(E2) + diff --git a/HEN_HOUSE/spectra/lnhb/Fe-59.txt b/HEN_HOUSE/spectra/lnhb/Fe-59.txt index 867d4bf38..30761107b 100644 --- a/HEN_HOUSE/spectra/lnhb/Fe-59.txt +++ b/HEN_HOUSE/spectra/lnhb/Fe-59.txt @@ -1,66 +1,65 @@ - 59CO 59FE B- DECAY (44.494 D) - 59CO H TYP=UPD$AUT=V.Chechev$CUT=12-JUL-2014$ - 59CO2 H TYP=UPD$AUT=MM.Be. V.Chiste$CUT=31-MAR-2004$ - 59CO3 H TYP=FUL$AUT=MM.Be. V.Chiste$CUT=01-DEC-2001$ - 59CO C Evaluation history: Type=UPD;Author=V.Chechev;Cutoff date=12-JUL-2014 - 59CO2C Type=UPD;Author=MM.Be. V.Chiste;Cutoff date=31-MAR-2004 - 59CO3C Type=FUL;Author=MM.Be. V.Chiste;Cutoff date=01-DEC-2001 - 59CO C References: 1952Me53, 1953Hi02, 1958Ke26, 1959Pi43, 1959Fe18, 1960Be06, - 59CO2C 1960Fu03, 1960He06, 1960Su10, 1963Wo01, 1964Co34, 1967Be60, 1970Le03, - 59CO3C 1971Ar07, 1972Ga39, 1972Em01, 1973Pa16, 1973Er11, 1973Vi13, 1974Ra13, - 59CO4C 1974Ba**, 1974Mu12, 1975Al02, 1977Kr13, 1980Ho17, 1983Wa26, 1989Mi07, - 59CO5C 1992Un01, 1997Ma75, 2000He14, 2002Ba42, 2002Ba85, 2004BeZR, 2008Ki07, - 59CO6C 2012Fi12, 2012Wa38, 2014Un01 - 59CO T Auger electrons and X ray energies and emission intensities: - 59CO T {U Energy (keV)} {U Intensity} {U Line} - 59CO T - 59CO T 6.91538 0.00596 11 XKA2 - 59CO T 6.9304 0.01166 21 XKA1 - 59CO T - 59CO T 7.6495 |] 0.00242 5 XKB1 - 59CO T 7.706 |] XKB5II - 59CO T - 59CO T - 59CO T 0.6793-0.8674 0.00053213 XL (total) - 59CO T 0.6793 2.31E-5 8 XLL - 59CO T 0.7787-0.7795 0.000293 9 XLA - 59CO T 0.6949 1.44E-5 6 XLC - 59CO T 0.78642-0.8674 0.000201 8 XLB - 59CO T 0.80198-0.80198 1.22E-6 14 XLG - 59CO T - 59CO T 5.81-6.1 |] KLL AUGER - 59CO T 6.67-6.93 |] 0.0316 5 KLX AUGER - 59CO T 7.51-7.7 |] KXY AUGER - 59CO T 0.58-0.92 0.0778 6 L AUGER - 59FE P 0.0 3/2- 44.494 D 12 1565.0 4 - 59CO N 1.0 1.0 1 1.0 - 59CO L 0 0 7/2- STABLE - 59CO B 1565.0 4 0.18 4 11.15 2 - 59COS B EAV=584 - 59CO L 1099.256 3 3/2- 3.1 PS 4 - 59CO B 465.7 4 53.30 31 6.69 - 59COS B EAV=149.2 2 - 59CO G 1099.245 3 56.51 31E2 1744E-725 - 59CO2 G KC=1571E-7 22$LC=1515E-8 22$MC=2.11E-6 3 - 59CO L 1291.605 5 3/2- 551 PS 7 - 59CO B 273.4 4 45.19 34 5.98 - 59COS B EAV=80.9 2 - 59CO G 192.349 5 2.91 5 0.211 9 0.0090018 - 59CO2 G KC=0.00808 17$LC=8.05E-4 17$MC=1120E-7 23 - 59CO G 1291.590 6 43.23 33E2 1483E-721 - 59CO2 G KC=1096E-7 16$LC=1055E-8 15$MC=1470E-9 21 - 59CO L 1434.256 5 1/2- 210 PS 20 - 59CO B 130.7 4 1.25 3 6.49 - 59COS B EAV=35.7 1 - 59CO G 142.651 2 0.978 28M1+E2 -0.008 7 0.0159623 - 59CO2 G KC=0.01432 21$LC=1428E-6 20$MC=1.99E-4 3 - 59CO G 335.000 6 0.260 11M1+E2 -0.12 6 0.00198 8 - 59CO2 G KC=0.00178 7$LC=1.74E-4 7$MC=2.43E-5 9 - 59CO L 1481.72 125/2- - 59CO B 83.3 4 0.080 6 7.08 - 59COS B EAV=22.0 1 - 59CO G 382.46 120.0215 23M1+E2 0.1 1 0.00144 7 - 59CO2 G KC=0.00129 6$LC=1.26E-4 6$MC=1.76E-5 9 - 59CO G 1481.70 120.059 6M1+E2 -0.19 4 1448E-721 - 59CO2 G KC=7.51E-5 11$LC=7.20E-6 11$MC=1003E-9 15 - + 59CO 59FE B- DECAY (44.494 D) + 59CO H TYP=UPD$AUT=V.P.CHECHEV$CUT=12-JUL-2014$ + 59CO2 H TYP=UPD$AUT=M.-M.BE, V.CHISTE$CUT=31-MAR-2004$ + 59CO3 H TYP=FUL$AUT=M.-M.BE, V.CHISTE$CUT=01-DEC-2001$ + 59CO C References:1952Me53, 1953Hi02, 1958Ke26, 1959Pi43, 1959Fe18, 1960Be06, + 59CO2C 1960Fu03, 1960He06, 1960Su10, 1963Wo01, 1964Co34, 1967Be60, 1970Le03, + 59CO3C 1971Ar07, 1972Ga39, 1972Em01, 1973Pa16, 1973Er11, 1973Vi13, 1974Ra13, + 59CO4C 1974Ba**, 1974Mu12, 1975Al02, 1977Kr13, 1980Ho17, 1983Wa26, 1989Mi07, + 59CO5C 1992Un01, 1997Ma75, 2000He14, 2002Ba42, 2002Ba85, 2004BeZR, 2008Ki07, + 59CO6C 2012Fi12, 2012Wa38, 2014Un01 + 59CO T Auger electrons and X ray energies and emission intensities: + 59CO T {U Energy (keV)} {U Intensity} {U Line} + 59CO T + 59CO T 6.91538 0.00596 11 XKA2 + 59CO T 6.9304 0.01166 21 XKA1 + 59CO T + 59CO T 7.6495 |] 0.00242 5 XKB1 + 59CO T 7.706 |] XKB5II + 59CO T + 59CO T + 59CO T 0.6793-0.8674 0.00053213 XL (total) + 59CO T 0.6793 2.31E-5 8 XLL + 59CO T 0.7787-0.7795 0.000293 9 XLA + 59CO T 0.6949 1.44E-5 6 XLC + 59CO T 0.78642-0.8674 0.000201 8 XLB + 59CO T 0.80198-0.80198 1.22E-6 14 XLG + 59CO T + 59CO T 5.81-6.1 |] KLL AUGER + 59CO T 6.67-6.93 |] 0.0316 5 KLX AUGER + 59CO T 7.51-7.7 |] KXY AUGER + 59CO T 0.58-0.92 0.0778 6 L AUGER + 59FE P 0.0 3/2- 44.494 D 12 1565.0 4 + 59CO N 1.0 1.0 1 1.0 + 59CO L 0 7/2- STABLE + 59CO B 1565.0 4 0.18 4 11.15 2 + 59COS B EAV=584 + 59CO L 1099.256 3 3/2- 3.1 PS 4 + 59CO B 465.7 4 53.30 31 6.69 + 59COS B EAV=149.2 2 + 59CO G 1099.245 3 56.51 31E2 1744E-725 + 59CO2 G KC=1.571E-4 22$LC=1.515E-5 22$MC=2.11E-6 3$NC=9.41E-8 14 + 59CO L 1291.605 5 3/2- 551 PS 7 + 59CO B 273.4 4 45.19 34 5.98 + 59COS B EAV=80.9 2 + 59CO G 192.349 5 2.91 5M1+E2 0.211 9 0.0090018 + 59CO2 G KC=0.00808 17$LC=0.000805 17$MC=1.120E-4 23$NC=4.85E-6 10 + 59CO G 1291.590 6 43.23 33E2 1483E-721 + 59CO2 G KC=1.096E-4 16$LC=1.055E-5 15$MC=1.470E-6 21$NC=6.57E-8 10 + 59CO3 G IPC=2.66E-5 4 + 59CO L 1434.256 5 1/2- 210 PS 20 + 59CO B 130.7 4 1.25 3 6.49 + 59COS B EAV=35.7 1 + 59CO G 142.651 2 0.978 28M1+E2 -0.008 7 0.0159623 + 59CO2 G KC=0.01432 21$LC=0.001428 20$MC=0.000199 3$NC=8.71E-6 13 + 59CO G 335.000 6 0.260 11M1+E2 -0.12 6 0.00198 8 + 59CO2 G KC=0.00178 7$LC=0.000174 7$MC=2.43E-5 9$NC=1.08E-6 4 + 59CO L 1481.72 125/2- + 59CO B 83.3 4 0.080 6 7.08 + 59COS B EAV=22.0 1 + 59CO G 382.46 120.0215 23M1+E2 0.1 1 0.00144 7 + 59CO2 G KC=0.00129 6$LC=0.000126 6$MC=1.76E-5 9$NC=7.8E-7 4 + 59CO G 1481.70 120.059 6M1+E2 -0.19 4 1448E-721 + 59CO2 G KC=7.51E-5 11$LC=7.20E-6 11$MC=1.003E-6 15$NC=4.51E-8 7 + 59CO3 G IPC=6.14E-5 10 + diff --git a/HEN_HOUSE/spectra/lnhb/Fr-221.txt b/HEN_HOUSE/spectra/lnhb/Fr-221.txt index 499a8c2f5..46c592eba 100644 --- a/HEN_HOUSE/spectra/lnhb/Fr-221.txt +++ b/HEN_HOUSE/spectra/lnhb/Fr-221.txt @@ -1,114 +1,126 @@ -217AT 221FR A DECAY (4.79 M) -217AT H TYP=Full$AUT=Huang Xiaolong$CUT= -- $ -217AT C Evaluation history: Type=Full;Author=Huang Xiaolong;Cutoff date= -- -217AT T Auger electrons and X ray energies and emission intensities: -217AT T {U Energy (keV)} {U Intensity} {U Line} -217AT T -217AT T 78.94 0.96 5 XKA2 -217AT T 81.51 1.59 9 XKA1 -217AT T -217AT T 91.73 |] XKB3 -217AT T 92.315 |] 0.55 6 XKB1 -217AT T 92.883 |] XKB5II -217AT T -217AT T 94.846 |] XKB2 -217AT T 95.211 |] 0.18 2 XKB4 -217AT T 95.595 |] XKO23 -217AT T -217AT T 9.8964-16.7291 2.18 7 XL (total) -217AT T 9.8964 XLL -217AT T 11.3052-11.426 XLA -217AT T 12.4653 XLC -217AT T 13.1704-14.6997 XLB -217AT T 15.7394-16.7291 XLG -217AT T -217AT T 60.489-67.031 |] KLL AUGER -217AT T 73.811-81.516 |] 0.114 6 KLX AUGER -217AT T 87.1-95.72 |] KXY AUGER -217AT T 5.6-17.4 3.05 10 L AUGER -221FR P 0.0 5/2- 4.79 M 2 6457.8 14 -217AT N 1.00E0 1.00E0 0.999952 1.00E0 -217AT L 0 9/2- 32.3 MS 4 -217AT A 6341.0 1382.8 2 3.44 -217AT L 100.25 2 7/2- 0.5 NS -217AT A 6243 2 1.34 7 120 -217AT G 100.25 2 0.156 13M1 11.97 17 -217AT2 G KC=9.66 14$LC=1.758 25$MC=0.416 6 -217AT L 218.12 2 5/2- -217AT A 6126.3 1515.1 2 2.2 -217AT G 117.82 3 0.022 16M1 7.58 11 -217AT2 G KC=6.13 9$LC=1.104 16$MC=0.261 4 -217AT G 218.12 2 11.42 15E2 0.367 5 -217AT2 G KC=0.1375 20$LC=0.1701 24$MC=0.0451 7 -217AT L 272.07 4 3/2- 0.27 NS 2 -217AT A 6075.9 200.15 3 65 -217AT G 53.81 3 0.0145 25M1 14.17 20 -217AT2 G LC=10.79 15$MC=2.56 4 -217AT G 171.83 3 0.069 9E2 0.863 12 -217AT2 G KC=0.226 4$LC=0.471 7$MC=0.1257 18 -217AT L 368.23 4 (3/2)- -217AT A 5979.9 200.39 7 27 -217AT G 96.3 3 0.007 3M1+E2 0.7 7 5.6 24 -217AT2 G LC=4.1 18$MC=1.1 5 -217AT G 150.21 3 0.0449 25M1 3.80 5 -217AT2 G KC=3.08 5$LC=0.550 8$MC=0.1303 19 -217AT L 382.34 4 (7/2)- -217AT A 5965.9 250.064 16117 -217AT G 282.12 9 0.0069 7[M1E2] 0.41 25 -217AT2 G KC=0.30 23$LC=0.077 17$MC=0.019 4 -217AT G 382.34 4 0.0340 14M1 0.284 4 -217AT2 G KC=0.231 4$LC=0.0406 6$MC=0.00960 14 -217AT L 410.64 5 13/2- -217AT A 5938.9 200.128 3 36.4 -217AT G 410.64 5 0.1204 25E2 0.0548 8 -217AT2 G KC=0.0344 5$LC=0.01528 22$MC=0.00392 6 -217AT L 424.35 7 (5/2,7/2,9/2)- -217AT A 5925 3 0.0285 24143 -217AT G 324.10 6 0.0174 12M1 0.446 6 -217AT2 G KC=0.362 5$LC=0.0639 9$MC=0.01510 22 -217AT L 537.5 5 (9/2)+ -217AT A 5813 3 0.006 1 197 -217AT G 437.00 5 0.0010 1 -217AT G 537.8 8 0.0045 8 -217AT L 568.5 3 (7/2,9/2)+ -217AT A 5783 4 0.0031 6 290 -217AT G 468.3 7 0.0018 3 -217AT G 568.5 3 0.0012 4 -217AT L 577.5 5 (7/2)- -217AT A 5776 3 0.064 4 11.7 -217AT G 208.3 6 0.0051 10[E2] 0.430 8 -217AT2 G KC=0.1519 24$LC=0.206 4$MC=0.0547 11 -217AT G 359.86 4 0.0385 15M1 0.335 5 -217AT2 G KC=0.272 4$LC=0.0479 7$MC=0.01133 16 -217AT G 576.9 4 0.0030 6[M1] 0.0948 13 -217AT2 G KC=0.0772 11$LC=0.01342 19$MC=0.00317 5 -217AT L 652 2 + -217AT A 5697 4 30001E-8 828 -217AT G 652 2 0.0004 4 -217AT L 664.4 2 + -217AT A 5689 3 0.0025 5 111 -217AT G 282.12 9 -217AT G 446.30 8 0.0017 4E1+M2 -217AT G 562.3 120.005 5 -217AT G 665 2 0.0009 9 -217AT L 809.3 2 + -217AT A 5530 250.00010 2 60 -217AT G 809.3 2 0.00010 2 -217AT L 891.9 3 - -217AT A 5500 4038000E-91061 -217AT G 891.9 3 0.00003810 - -221RA 221FR B- DECAY (4.79 M) -221RA H TYP=Full$AUT=Huang Xiaolong$CUT= -- $ -221RA C Evaluation history: Type=Full;Author=Huang Xiaolong;Cutoff date= -- -221RA T Auger electrons and X ray energies and emission intensities: -221RA T {U Energy (keV)} {U Intensity} {U Line} -221RA T -221RA T -221RA T -221RA T -221RA T -221FR P 0.0 5/2- 4.79 M 2 314 6 -221RA N 2.083E4 2.083E4 0.000048 2.083E4 -221RA L 0 5/2+ 28 S 2 - +217AT 221FR A DECAY (4.79 M) +217AT H TYP=FUL$AUT=X.HUANG$CUT=31-DEC-2007$ +217AT T Auger electrons and X ray energies and emission intensities: +217AT T {U Energy (keV)} {U Intensity} {U Line} +217AT T +217AT T 78.94 0.96 5 XKA2 +217AT T 81.51 1.59 9 XKA1 +217AT T +217AT T 91.73 |] XKB3 +217AT T 92.315 |] 0.55 6 XKB1 +217AT T 92.883 |] XKB5II +217AT T +217AT T 94.846 |] XKB2 +217AT T 95.211 |] 0.18 2 XKB4 +217AT T 95.595 |] XKO23 +217AT T +217AT T 9.8964-16.7291 2.18 7 XL (total) +217AT T 9.8964 XLL +217AT T 11.3052-11.426 XLA +217AT T 12.4653 XLC +217AT T 13.1704-14.6997 XLB +217AT T 15.7394-16.7291 XLG +217AT T +217AT T 60.489-67.031 |] KLL AUGER +217AT T 73.811-81.516 |] 0.114 6 KLX AUGER +217AT T 87.1-95.72 |] KXY AUGER +217AT T 5.6-17.4 3.05 10 L AUGER +221FR P 0.0 5/2- 4.79 M 2 6457.8 14 +217AT N 1.00E0 1.00E0 0.999952 +217AT L 0 9/2- 32.3 MS 4 +217AT A 6341.0 1382.8 23.44 +217AT L 100.25 2 7/2- 0.5 NS +217AT A 6243 2 1.34 7120 +217AT G 100.25 2 0.156 13M1 11.97 17 +217AT2 G KC=9.66 14$LC=1.758 25$MC=0.416 6$NC=1.08E-5 2 +217AT3 G OC=2.31E-6 3 +217AT L 218.12 2 5/2- +217AT A 6126.3 1515.1 22.2 +217AT G 117.82 3 0.022 16M1 7.58 11 +217AT2 G KC=6.13 9$LC=1.104 16$MC=0.261 4$NC=6.77E-6 9 +217AT3 G OC=1.45E-6 2 +217AT G 218.12 2 11.42 15E2 0.367 5 +217AT2 G KC=0.1375 20$LC=0.1701 24$MC=0.0451 7$NC=1.17E-6 2 +217AT3 G OC=2.31E-7 3 +217AT L 272.07 4 3/2- 0.27 NS 2 +217AT A 6075.9 200.15 365 +217AT G 53.81 3 0.0145 25M1 14.17 20 +217AT2 G LC=10.79 15$MC=2.56 4$NC=6.62E-5 9 +217AT3 G OC=1.42E-5 2 +217AT G 171.83 3 0.069 9E2 0.863 12 +217AT2 G KC=0.226 4$LC=0.471 7$MC=0.1257 18$NC=3.25E-6 5 +217AT3 G OC=6.4E-7 1 +217AT L 368.23 4 (3/2)- +217AT A 5979.9 200.39 727 +217AT G 96.3 3 0.007 3M1+E2 0.7 7 5.6 24 +217AT2 G LC=4.1 18$MC=1.1 5$NC=0.000026 11 +217AT3 G OC=0.000005 2 +217AT G 150.21 3 0.0449 25M1 3.80 5 +217AT2 G KC=3.08 5$LC=0.550 8$MC=0.1303 19$NC=3.38E-6 5 +217AT3 G OC=7.2E-7 1 +217AT L 382.34 4 (7/2)- +217AT A 5965.9 250.064 16117 +217AT G 282.12 9 0.0069 7[M1,E2] 0.41 25 +217AT2 G KC=0.30 23$LC=0.077 17$MC=0.019 4$NC=4.9E-7 8 +217AT3 G OC=1.0E-7 2 +217AT G 382.34 4 0.0340 14M1 0.284 4 +217AT2 G KC=0.231 4$LC=0.0406 6$MC=0.00960 14$NC=2.49E-7 3 +217AT3 G OC=0.000533 4 +217AT L 410.64 5 13/2- +217AT A 5938.9 200.128 336.4 +217AT G 410.64 5 0.1204 25E2 0.0548 8 +217AT2 G KC=0.0344 5$LC=0.01528 22$MC=0.00392 6$NC=0.000101 14 +217AT3 G OC=0.000206 3 +217AT L 424.35 7 (5/2,7/2,9/2)- +217AT A 5925 3 0.0285 24143 +217AT G 324.10 6 0.0174 12M1 0.446 6 +217AT2 G KC=0.362 5$LC=0.0639 9$MC=0.01510 22$NC=3.91E-7 5 +217AT3 G OC=8.4E-8 1 +217AT L 537.5 5 (9/2)+ +217AT A 5813 3 0.006 1197 +217AT G 437.00 5 0.0010 1 +217AT G 537.8 8 0.0045 8 +217AT L 568.5 3 (7/2,9/2)+ +217AT A 5783 4 0.0031 6290 +217AT G 468.3 7 0.0018 3 +217AT G 568.5 3 0.0012 4 +217AT L 577.5 5 (7/2)- +217AT A 5776 3 0.064 411.7 +217AT G 208.3 6 0.0051 10[E2] 0.430 8 +217AT2 G KC=0.1519 24$LC=0.206 4$MC=0.0547 11$NC=1.42E-6 3 +217AT3 G OC=2.81E-7 5 +217AT G 359.86 4 0.0385 15M1 0.335 5 +217AT2 G KC=0.272 4$LC=0.0479 7$MC=0.01133 16$NC=2.94E-7 5 +217AT3 G OC=0.000629 9 +217AT G 576.9 4 0.0030 6[M1] 0.0948 13 +217AT2 G KC=0.0772 11$LC=0.01342 19$MC=0.00317 5$NC=0.000820 11 +217AT3 G OC=0.000176 25 +217AT L 652 2 +217AT A 5697 4 30001E-8 828 +217AT G 652 2 0.0004 4 +217AT L 664.4 2 +217AT A 5689 3 0.0025 5111 +217AT G 282.12 9 +217AT G 446.30 8 0.0017 4E1+M2 +217AT G 562.3 120.005 5 +217AT G 665 2 0.0009 9 +217AT L 809.3 2 +217AT A 5530 250.00010 260 +217AT G 809.3 2 0.00010 2 +217AT L 891.9 3 +217AT A 5500 400.0000381061 +217AT G 891.9 3 0.00003810 + +221RA 221FR B- DECAY (4.79 M) +221RA H TYP=FUL$AUT=X.HUANG$CUT=31-DEC-2007$ +221RA T Auger electrons and X ray energies and emission intensities: +221RA T {U Energy (keV)} {U Intensity} {U Line} +221RA T +221RA T +221RA T +221RA T +221RA T +221FR P 0.0 5/2- 4.79 M 2 314 6 +221RA N 2.083E4 2.083E4 0.000048 2.083E4 +221RA L 0 5/2+ 28 S 2 + diff --git a/HEN_HOUSE/spectra/lnhb/Fr-223.txt b/HEN_HOUSE/spectra/lnhb/Fr-223.txt index 7a8a8d8a6..8ef4748b6 100644 --- a/HEN_HOUSE/spectra/lnhb/Fr-223.txt +++ b/HEN_HOUSE/spectra/lnhb/Fr-223.txt @@ -1,345 +1,384 @@ -219AT 223FR A DECAY (22.00 M) -219AT H TYP=Full$AUT=Huang Xiaolong$CUT=31-DEC-2008$ -219AT C Evaluation history: Type=Full;Author=Huang Xiaolong;Cutoff date=31-DEC-2008 -219AT T Auger electrons and X ray energies and emission intensities: -219AT T {U Energy (keV)} {U Intensity} {U Line} -219AT T -219AT T 78.94 0.00056 15 XKA2 -219AT T 81.51 0.00092 25 XKA1 -219AT T -219AT T 91.73 |] XKB3 -219AT T 92.315 |] 0.00031 11 XKB1 -219AT T 92.883 |] XKB5II -219AT T -219AT T 94.846 |] XKB2 -219AT T 95.211 |] 0.00011 6 XKB4 -219AT T 95.595 |] XKO23 -219AT T -219AT T 9.8964-16.7291 0.0054 13 XL (total) -219AT T 9.8964 XLL -219AT T 11.3052-11.426 XLA -219AT T 12.4653 XLC -219AT T 13.1704-14.6997 XLB -219AT T 15.7394-16.7291 XLG -219AT T -219AT T 60.489-67.031 |] KLL AUGER -219AT T 73.811-81.516 |] 0.00006520 KLX AUGER -219AT T 87.1-95.72 |] KXY AUGER -219AT T 5.6-17.4 0.0076 18 L AUGER -223FR P 0.0 3/2- 22.00 M 7 5562 3 -219AT N 5.000E3 5.000E3 0.0002 5.000E3 -219AT L 0 9/2- 56 S 4 -219AT A 5462 3 17 8 -219AT L 58.9 2 (7/2)- -219AT A 5403 3 22 10 -219AT G 58.9 2 0.0008 3M1 10.87 19 -219AT2 G LC=8.27 15$MC=1.96 4 -219AT L 150.9 2 5/2- -219AT A 5314 4 27 12 -219AT G 150.9 2 0.0056 5E2 1.417 21 -219AT2 G KC=0.287 4$LC=0.836 13$MC=0.224 4 -219AT L 175.04 213/2- -219AT A 5291 4 30 13 -219AT G 24.14 3 -219AT L 296.2 4 3/2- -219AT A 5172 5 4.5 25 -219AT G 145.3 3 0.0002 1M1+(E2) 2.9 13 -219AT2 G KC=1.8 16$LC=0.8 2$MC=0.20 6 - -223RA 223FR B- DECAY (22.00 M) -223RA H TYP=Full$AUT=Huang Xiaolong$CUT=31-DEC-2008$ -223RA C Evaluation history: Type=Full;Author=Huang Xiaolong;Cutoff date=31-DEC-2008 -223RA T Auger electrons and X ray energies and emission intensities: -223RA T {U Energy (keV)} {U Intensity} {U Line} -223RA T -223RA T 85.43 1.44 19 XKA2 -223RA T 88.47 2.3 3 XKA1 -223RA T -223RA T 99.432 |] XKB3 -223RA T 100.13 |] 0.83 11 XKB1 -223RA T 100.738 |] XKB5II -223RA T -223RA T 102.89 |] XKB2 -223RA T 103.295 |] 0.27 4 XKB4 -223RA T 103.74 |] XKO23 -223RA T -223RA T 10.6241-18.3539 24 3 XL (total) -223RA T 10.6241 XLL -223RA T 12.1957-12.3381 XLA -223RA T 13.6624 XLC -223RA T 14.2373-16.1261 XLB -223RA T 17.2756-18.3539 XLG -223RA T -223RA T 65.149-72.729 |] KLL AUGER -223RA T 79.721-88.466 |] 0.159 21 KLX AUGER -223RA T 94.27-103.91 |] KXY AUGER -223RA T 5.71-12.04 29 4 L AUGER -223FR P 0.0 3/2- 22.00 M 7 1149.2 9 -223RA N 1.00E0 1.00E0 0.9998 1.00E0 -223RA L 0 3/2+ 11.43 D 3 -223RA B 1149.2 9 1 7.6 -223RAS B EAV=380.8 4 -223RA L 29.854 18(5/2)+ -223RA B 1119.3 9 6 6 6.8 1 -223RAS B EAV=369.4 4 -223RA G 29.78 4 0.070 17M1+E2 0.30 3 370 50 -223RA2 G LC=280 40$MC=72 10 -223RA L 50.101 163/2- -223RA B 1099.1 9 67 13 5.68 -223RAS B EAV=361.7 4 -223RA G 20.27 5 1.4 3[E1] 7.76 22 -223RA2 G LC=5.77 16$MC=1.50 3 -223RA G 50.10 2 33 7E1 0.696 10 -223RA2 G LC=0.526 8$MC=0.1288 18 -223RA L 61.435 23(7/2)+ -223RA B 1087.8 9 0.27 19 8.1 1U -223RAS B EAV=357.4 4 -223RA G 31.69 5 0.00135 M1+E2 0.28 6 260 80 -223RA2 G LC=190 60$MC=50 15 -223RA G 61.43 5 0.0035 7E2 96.5 14 -223RA2 G LC=71.0 11$MC=19.3 3 -223RA L 79.649 16(5/2)- -223RA B 1069.6 9 15 3 6.29 -223RAS B EAV=350.5 4 -223RA G 49.80 5 2.5 6E1 0.708 10 -223RA2 G LC=0.535 8$MC=0.1309 19 -223RA G 79.65 2 9.0 18E1 0.202 3 -223RA2 G LC=0.1530 22$MC=0.0370 6 -223RA L 123.724 23(7/2)- -223RA B 1025.5 9 0.24 6 8.02 2 -223RAS B EAV=333.9 4 -223RA G 44.0 1 0.00135 M1+E2 0.52 4 131 12 -223RA2 G LC=97 9$MC=25.5 24 -223RA G 62.31 6 0.016 7E1 0.389 6 -223RA2 G LC=0.294 5$MC=0.0716 11 -223RA G 73.5 1 0.0013 9E2 40.8 6 -223RA2 G LC=30.0 5$MC=8.16 13 -223RA G 93.88 5 0.059 14E1 0.1305 18 -223RA2 G LC=0.0989 14$MC=0.0239 4 -223RA L 234.747 20(5/2)+ -223RA B 914.5 9 9.1 17 6.27 1 -223RAS B EAV=292.6 4 -223RA G 111.05 3 0.0049 14 -223RA G 155.5 5 0.0027 -223RA G 173.35 5 0.115 22M1E2 2.1 12 -223RA2 G KC=1.4 12$LC=0.53 5$MC=0.136 20 -223RA G 184.65 5 0.22 5E1 0.1092 15 -223RA2 G KC=0.0868 13$LC=0.01701 24$MC=0.00407 6 -223RA G 204.85 5 0.92 18M1+E2 -0.12 7 2.02 5 -223RA2 G KC=1.62 4$LC=0.304 5$MC=0.0726 11 -223RA G 234.70 5 2.7 5M1(+E2) -0.07 2 1.393 16 -223RA2 G KC=1.120 16$LC=0.207 3$MC=0.0495 7 -223RA L 280.19 4 (7/2)+ -223RA B 869.0 9 0.004 4 9.5 1U -223RAS B EAV=275.9 4 -223RA G 200.7 2 0.0027 10 -223RA G 218.80 5 0.0086 17M1 1.701 24 -223RA2 G KC=1.368 20$LC=0.252 4$MC=0.0603 9 -223RA G 250.25 5 0.016 M1 1.170 16 -223RA2 G KC=0.941 14$LC=0.1733 25$MC=0.0414 6 -223RA G 280.7 5 0.0003 -223RA L 286.07 4 1/2+ -223RA B 863.1 9 0.032 9 8.64 1 -223RAS B EAV=273.8 4 -223RA G 236.05 5 0.027 8E1 0.0610 9 -223RA2 G KC=0.0489 7$LC=0.00922 13$MC=0.00220 3 -223RA G 256.18 5 0.020 4E2 0.250 4 -223RA2 G KC=0.0983 14$LC=0.1117 16$MC=0.0299 5 -223RA G 286.0 2 0.0046 10M1+E2 0.5 4 -223RA2 G KC=0.4 3$LC=0.096 24$MC=0.024 5 -223RA L 329.82 3 3/2- -223RA B 819.4 9 0.049 10 8.37 -223RAS B EAV=257.9 4 -223RA G 43.5 2 0.0022 E1 1.015 19 -223RA2 G LC=0.767 15$MC=0.189 4 -223RA G 205.6 2 0.0059 11E2 0.530 8 -223RA2 G KC=0.1533 22$LC=0.277 4$MC=0.0747 11 -223RA G 250.25 5 0.003 M1+E2 -2.1 4 0.44 7 -223RA2 G KC=0.26 6$LC=0.132 4$MC=0.0344 8 -223RA G 299.95 5 0.020 4E1 0.0352 5 -223RA2 G KC=0.0284 4$LC=0.00518 8$MC=1234E-6 18 -223RA G 329.80 5 0.024 5(E1) 0.0285 4 -223RA2 G KC=0.0230 4$LC=0.00415 6$MC=9.88E-4 14 -223RA L 334.29 4 5/2+ -223RA B 814.9 9 0.042 9 8.43 1 -223RAS B EAV=256.3 4 -223RA G 210.60 5 0.0097 19E1 0.0798 11 -223RA2 G KC=0.0637 9$LC=0.01222 18$MC=0.00292 4 -223RA G 254.6 2 0.0057 12E1 0.0512 7 -223RA2 G KC=0.0411 6$LC=0.00767 11$MC=0.00183 3 -223RA G 272.8 2 0.004 1M1+E2 0.6 4 -223RA2 G KC=0.4 4$LC=0.112 25$MC=0.028 5 -223RA G 304.40 5 0.0086 17M1+E2(+) 0.26 4 0.647 14 -223RA2 G KC=0.518 12$LC=0.0978 16$MC=0.0234 4 -223RA G 334.30 6 0.0084 17M1+E2 -0.61 4 0.414 13 -223RA2 G KC=0.325 11$LC=0.0674 14$MC=0.0164 3 -223RA L 342.51 4 3/2+ -223RA B 806.7 9 0.037 8 8.47 -223RAS B EAV=253.3 4 -223RA G 262.9 2 0.0035 11E1 0.0475 7 -223RA2 G KC=0.0382 6$LC=0.00709 10$MC=1692E-6 24 -223RA G 280.7 5 0.0003 -223RA G 312.65 5 0.016 4M1+E2 0.16 3 0.621 10 -223RA2 G KC=0.499 9$LC=0.0924 14$MC=0.0221 4 -223RA G 342.50 7 0.0116 24M1+E2 1.29 2 0.250 5 -223RA2 G KC=0.183 4$LC=0.0501 8$MC=1252E-5 2 -223RA L 350.53 101/2- -223RA G 350.5 2 0.0027 15E1 0.0249 4 -223RA2 G KC=0.0202 3$LC=0.00361 5$MC=8.58E-4 12 -223RA L 369.342 20(5/2)- -223RA B 779.9 9 1.8 4 6.73 -223RAS B EAV=243.7 4 -223RA G 89.08 100.054 11 -223RA G 134.60 2 0.5 1[E1] 0.234 3 -223RA2 G KC=0.184 3$LC=0.0383 6$MC=0.00921 13 -223RA G 245.60 5 0.019 4 -223RA G 289.67 5 0.21 -223RA G 307.93 5 0.0013 13 -223RA G 319.25 5 0.46 9M1+E2 0.18 3 0.583 10 -223RA2 G KC=0.468 8$LC=0.0869 13$MC=0.0208 3 -223RA G 339.50 5 0.062 13 -223RA G 369.32 5 0.089 18 -223RA L 376.09 15(7/2)- -223RA B 773.1 100.0046 12 9.31 2 -223RAS B EAV=241.3 4 -223RA G 296.5 2 0.0013 4M1+E2 -0.13 2 0.723 9 -223RA2 G KC=0.581 9$LC=0.1074 16$MC=0.0257 4 -223RA G 314.6 2 0.0022 7E1 0.0316 5 -223RA2 G KC=0.0255 4$LC=0.00463 7$MC=1103E-6 16 -223RA L 593.94 6 + -223RA B 555.3 9 0.013 3 8.38 -223RAS B EAV=165.6 4 -223RA G 307.93 5 0.012 3 -223RA G 469.3 2 0.001 -223RA L 782.54 171/2,3/2+ -223RA B 366.7 100.00111 22 8.85 1 -223RAS B EAV=104.1 3 -223RA G 439.6 3 0.00030 8 -223RA G 452.9 2 0.0008 -223RA L 787.13 5 5/2+ -223RA B 362.1 9 0.019 4 7.6 1 -223RAS B EAV=102.7 3 -223RA G 444.5 3 0.0011 4 -223RA G 452.9 2 0.0008 -223RA G 457.5 2 0.0008 -223RA G 506.9 2 0.0022 7 -223RA G 552.3 2 0.0027 8 -223RA G 663.7 3 0.0011 4 -223RA G 708.3 3 0.0013 4 -223RA G 737.4 3 0.0009 3 -223RA G 757.20 5 0.0076 20 -223RA G 787.6 2 0.0003 3 -223RA L 803.77 3 3/2,5/2+ -223RA B 345.4 9 0.14 3 6.67 -223RAS B EAV=97.5 3 -223RA G 434.4 1 0.0022 7 -223RA G 469.3 2 0.001 -223RA G 569.03 8 0.049 11 -223RA G 724.15 5 0.014 4 -223RA G 742.4 3 0.0011 4 -223RA G 753.65 5 0.0094 22 -223RA G 803.77 5 0.059 14 -223RA L 805.38 101/2,3/2,5/2+ -223RA B 343.8 9 0.0040 8 8.21 1 -223RAS B EAV=97.0 3 -223RA G 475.4 1 0.0027 -223RA G 806.0 2 0.0013 4 -223RA L 823.22 7 1/2,3/2,5/2+ -223RA B 326.0 9 0.014 3 7.59 1 -223RAS B EAV=91.5 3 -223RA G 480.9 3 0.0013 4 -223RA G 493.4 2 0.0024 7 -223RA G 537.2 2 0.0032 -223RA G 823.20 7 0.0070 16 -223RA L 825.94 4 (3/2)+ -223RA B 323.3 9 0.54 10 5.99 -223RAS B EAV=90.7 3 -223RA G 475.4 1 0.003 -223RA G 539.8 2 0.0059 18 -223RA G 545.4 4 0.00030 8 -223RA G 746.30 5 0.020 5 -223RA G 775.83 5 0.45 9 -223RA G 825.95 7 0.054 13 -223RA L 842.25 5 3/2,5/2+ -223RA B 306.9 9 0.035 7 7.11 -223RAS B EAV=85.7 3 -223RA G 556.3 3 0.0011 4 -223RA G 607.6 3 0.0022 7 -223RA G 762.6 2 0.0024 7 -223RA G 780.8 1 0.003 1 -223RA G 792.2 3 0.00054 14 -223RA G 812.40 6 0.021 5 -223RA G 842.2 1 0.0049 11 -223RA L 846.37 3 5/2+ -223RA B 302.8 9 0.088 18 6.69 1 -223RAS B EAV=84.4 3 -223RA G 516.7 2 0.0032 8 -223RA G 722.65 5 0.038 9 -223RA G 766.64 5 0.022 5 -223RA G 784.93 5 0.0086 21 -223RA G 796.22 5 0.0108 25 -223RA G 846.85 100.005 3 -223RA L 867.34 6 3/2,5/2+ -223RA B 281.9 9 0.025 5 7.14 -223RAS B EAV=78.1 3 -223RA G 524.8 2 0.0043 12 -223RA G 533.1 3 0.0019 7 -223RA G 537.2 2 0.0019 -223RA G 581.3 4 0.0013 4 -223RA G 632.7 3 0.0022 7 -223RA G 787.6 2 0.0024 7 -223RA G 837.5 1 0.0097 21 -223RA G 867.4 1 0.0016 4 -223RA L 905.9 4 + -223RA B 243.3 100.0011 4 8.29 -223RAS B EAV=66.6 3 -223RA G 576.1 4 0.0011 4 -223RA L 926.56 7 3/2,5/2+ -223RA B 222.6 9 0.106 22 6.18 -223RAS B EAV=60.5 3 -223RA G 592.3 2 0.0032 10 -223RA G 596.9 4 0.0008 3 -223RA G 846.85 100.049 13 -223RA G 876.5 1 0.038 9 -223RA G 896.7 2 0.013 3 -223RA G 926.5 3 0.0016 4 -223RA L 940.78 133/2,5/2- -223RA B 208.4 9 0.0051 12 7.41 -223RAS B EAV=56.3 3 -223RA G 816.5 2 0.0013 4 -223RA G 911.3 3 0.0008 3 -223RA G 941.2 3 0.0030 8 -223RA L 943.26 9 3/2,5/2+ -223RA B 205.9 9 0.0082 18 7.19 -223RAS B EAV=55.6 3 -223RA G 600.7 4 0.00054 14 -223RA G 613.6 4 0.0011 4 -223RA G 863.6 1 0.0038 9 -223RA G 893.1 2 0.0024 7 -223RA G 913.6 3 0.00041 14 -223RA L 957.72 113/2,5/2+ -223RA B 191.5 9 0.020 4 6.7 -223RAS B EAV=51.5 3 -223RA G 671.9 4 0.00054 14 -223RA G 833.9 2 0.0013 4 -223RA G 878.1 2 0.0032 8 -223RA G 907.6 2 0.014 3 -223RA G 958.0 7 0.00035 8 -223RA L 1019.3 4 + -223RA B 129.9 100.00046 12 7.82 -223RAS B EAV=34.1 3 -223RA G 969.2 4 0.00032 8 -223RA G 989.4 5 0.00014 3 -223RA L 1024.59 23 + -223RA B 124.6 100.0004 1 7.82 -223RAS B EAV=32.7 3 -223RA G 975.2 5 0.00016 5 -223RA G 994.3 3 0.00011 3 -223RA G 1025.1 5 0.00014 3 -223RA L 1028.94 25 - -223RA B 120.3 100.0012 3 7.3 -223RAS B EAV=31.5 3 -223RA G 949.3 4 0.00032 8 -223RA G 978.7 4 0.00067 12 -223RA G 999.3 5 0.00019 4 - +219AT 223FR A DECAY (22.00 M) +219AT H TYP=FUL$AUT=X.HUANG$CUT=31-DEC-2008$ +219AT T Auger electrons and X ray energies and emission intensities: +219AT T {U Energy (keV)} {U Intensity} {U Line} +219AT T +219AT T 78.94 0.00056 15 XKA2 +219AT T 81.51 0.00092 25 XKA1 +219AT T +219AT T 91.73 |] XKB3 +219AT T 92.315 |] 0.00031 11 XKB1 +219AT T 92.883 |] XKB5II +219AT T +219AT T 94.846 |] XKB2 +219AT T 95.211 |] 0.00011 6 XKB4 +219AT T 95.595 |] XKO23 +219AT T +219AT T 9.8964-16.7291 0.0054 13 XL (total) +219AT T 9.8964 XLL +219AT T 11.3052-11.426 XLA +219AT T 12.4653 XLC +219AT T 13.1704-14.6997 XLB +219AT T 15.7394-16.7291 XLG +219AT T +219AT T 60.489-67.031 |] KLL AUGER +219AT T 73.811-81.516 |] 0.00006520 KLX AUGER +219AT T 87.1-95.72 |] KXY AUGER +219AT T 5.6-17.4 0.0076 18 L AUGER +223FR P 0.0 3/2- 22.00 M 7 5562 3 +219AT N 5.000E3 5.000E3 0.0002 +219AT L 0 9/2- 56 S 4 +219AT A 5462 3 17 8 +219AT L 58.9 2 (7/2)- +219AT A 5403 3 22 10 +219AT G 58.9 2 0.0008 3M1 10.87 19 +219AT2 G LC=8.27 15$MC=1.96 4$NC=0.508 9 +219AT3 G OC=0.109 2 +219AT L 150.9 2 5/2- +219AT A 5314 4 27 12 +219AT G 150.9 2 0.0056 5E2 1.417 21 +219AT2 G KC=0.287 4$LC=0.836 13$MC=0.224 4$NC=0.0578 9 +219AT3 G OC=0.0110 2 +219AT L 175.04 213/2- +219AT A 5291 4 30 13 +219AT G 24.14 3 +219AT L 296.2 4 3/2- +219AT A 5172 5 4.5 25 +219AT G 145.3 3 0.0002 1M1+(E2) 2.9 13 +219AT2 G KC=1.8 16$LC=0.8 2$MC=0.20 6$NC=0.053 16 +219AT3 G OC=0.011 3 + +223RA 223FR B- DECAY (22.00 M) +223RA H TYP=FUL$AUT=X.HUANG$CUT=31-DEC-2008$ +223RA T Auger electrons and X ray energies and emission intensities: +223RA T {U Energy (keV)} {U Intensity} {U Line} +223RA T +223RA T 85.43 1.44 19 XKA2 +223RA T 88.47 2.3 3 XKA1 +223RA T +223RA T 99.432 |] XKB3 +223RA T 100.13 |] 0.83 11 XKB1 +223RA T 100.738 |] XKB5II +223RA T +223RA T 102.89 |] XKB2 +223RA T 103.295 |] 0.27 4 XKB4 +223RA T 103.74 |] XKO23 +223RA T +223RA T 10.6241-18.3539 24 3 XL (total) +223RA T 10.6241 XLL +223RA T 12.1957-12.3381 XLA +223RA T 13.6624 XLC +223RA T 14.2373-16.1261 XLB +223RA T 17.2756-18.3539 XLG +223RA T +223RA T 65.149-72.729 |] KLL AUGER +223RA T 79.721-88.466 |] 0.159 21 KLX AUGER +223RA T 94.27-103.91 |] KXY AUGER +223RA T 5.71-12.04 29 4 L AUGER +223FR P 0.0 3/2- 22.00 M 7 1149.2 9 +223RA N 1.00E0 1.00E0 0.9998 1.00E0 +223RA L 0 3/2+ 11.43 D 3 +223RA B 1149.2 9 1 7.6 +223RAS B EAV=380.8 4 +223RA L 29.854 18(5/2)+ +223RA B 1119.3 9 6 6 6.8 1 +223RAS B EAV=369.4 4 +223RA G 29.78 4 0.070 17M1+E2 0.30 3 370 50 +223RA2 G LC=280 40$MC=72 10$NC=0.019 3 +223RA3 G OC=0.0041 6 +223RA L 50.101 163/2- +223RA B 1099.1 9 67 13 5.68 +223RAS B EAV=361.7 4 +223RA G 20.27 5 1.4 3[E1] 7.76 22 +223RA2 G LC=5.77 16$MC=1.50 3$NC=0.000375 6 +223RA3 G OC=0.000074 1 +223RA G 50.10 2 33 7E1 0.696 10 +223RA2 G LC=0.526 8$MC=0.1288 18$NC=3.30E-5 5 +223RA3 G OC=7.00E-6 1 +223RA L 61.435 23(7/2)+ +223RA B 1087.8 9 0.27 19 8.1 1U +223RAS B EAV=357.4 4 +223RA G 31.69 5 0.00135 M1+E2 0.28 6 260 80 +223RA2 G LC=190 60$MC=50 15$NC=0.013 4 +223RA3 G OC=0.0029 8 +223RA G 61.43 5 0.0035 7E2 96.5 14 +223RA2 G LC=71.0 11$MC=19.3 3$NC=0.00508 7 +223RA3 G OC=0.00108 2 +223RA L 79.649 16(5/2)- +223RA B 1069.6 9 15 3 6.29 +223RAS B EAV=350.5 4 +223RA G 49.80 5 2.5 6E1 0.708 10 +223RA2 G LC=0.535 8$MC=0.1309 19$NC=3.37E-5 4 +223RA3 G OC=7.1E-6 1 +223RA G 79.65 2 9.0 18E1 0.202 3 +223RA2 G LC=0.1530 22$MC=0.0370 6$NC=9.6E-6 2 +223RA3 G OC=2.10E-6 3 +223RA L 123.724 23(7/2)- +223RA B 1025.5 9 0.24 6 8.02 2 +223RAS B EAV=333.9 4 +223RA G 44.0 1 0.00135 M1+E2 0.52 4 131 12 +223RA2 G LC=97 9$MC=25.5 24$NC=0.0067 6 +223RA3 G OC=0.00145 13 +223RA G 62.31 6 0.016 7E1 0.389 6 +223RA2 G LC=0.294 5$MC=0.0716 11$NC=1.85E-5 3 +223RA3 G OC=0.00396 6 +223RA G 73.5 1 0.0013 9E2 40.8 6 +223RA2 G LC=30.0 5$MC=8.16 13$NC=0.00215 3 +223RA3 G OC=0.000457 7 +223RA G 93.88 5 0.059 14E1 0.1305 18 +223RA2 G LC=0.0989 14$MC=0.0239 4$NC=0.00620 9 +223RA3 G OC=0.00135 2 +223RA L 234.747 20(5/2)+ +223RA B 914.5 9 9.1 17 6.27 1 +223RAS B EAV=292.6 4 +223RA G 111.05 3 0.0049 14 +223RA G 155.5 5 0.0027 +223RA G 173.35 5 0.115 22M1,E2 2.1 12 +223RA2 G KC=1.4 12$LC=0.53 5$MC=0.136 20$NC=0.000036 5 +223RA3 G OC=0.000008 1 +223RA G 184.65 5 0.22 5E1 0.1092 15 +223RA2 G KC=0.0868 13$LC=0.01701 24$MC=0.00407 6$NC=0.00106 15 +223RA3 G OC=0.00236 3 +223RA G 204.85 5 0.92 18M1+E2 -0.12 7 2.02 5 +223RA2 G KC=1.62 4$LC=0.304 5$MC=0.0726 11$NC=1.92E-5 4 +223RA3 G OC=0.00437 6 +223RA G 234.70 5 2.7 5M1(+E2) -0.07 2 1.393 16 +223RA2 G KC=1.120 16$LC=0.207 3$MC=0.0495 7$NC=1.31E-5 2 +223RA3 G OC=0.00298 4 +223RA L 280.19 4 (7/2)+ +223RA B 869.0 9 0.004 4 9.5 1U +223RAS B EAV=275.9 4 +223RA G 200.7 2 0.0027 10 +223RA G 218.80 5 0.0086 17M1 1.701 24 +223RA2 G KC=1.368 20$LC=0.252 4$MC=0.0603 9$NC=1.59E-5 2 +223RA3 G OC=0.00363 5 +223RA G 250.25 5 0.016 M1 1.170 16 +223RA2 G KC=0.941 14$LC=0.1733 25$MC=0.0414 6$NC=1.09E-5 2 +223RA3 G OC=0.00249 4 +223RA G 280.7 5 0.0003 +223RA L 286.07 4 1/2+ +223RA B 863.1 9 0.032 9 8.64 1 +223RAS B EAV=273.8 4 +223RA G 236.05 5 0.027 8E1 0.0610 9 +223RA2 G KC=0.0489 7$LC=0.00922 13$MC=0.00220 3$NC=0.00575 8 +223RA3 G OC=0.00128 2 +223RA G 256.18 5 0.020 4E2 0.250 4 +223RA2 G KC=0.0983 14$LC=0.1117 16$MC=0.0299 5$NC=0.00789 10 +223RA3 G OC=1.70E-6 2 +223RA G 286.0 2 0.0046 10M1+E2 0.5 4 +223RA2 G KC=0.4 3$LC=0.096 24$MC=0.024 5$NC=6.3E-6 12 +223RA3 G OC=1.4E-6 4 +223RA L 329.82 3 3/2- +223RA B 819.4 9 0.049 10 8.37 +223RAS B EAV=257.9 4 +223RA G 43.5 2 0.0022 E1 1.015 19 +223RA2 G LC=0.767 15$MC=0.189 4$NC=4.85E-5 9 +223RA3 G OC=1.02E-5 2 +223RA G 205.6 2 0.0059 11E2 0.530 8 +223RA2 G KC=0.1533 22$LC=0.277 4$MC=0.0747 11$NC=1.97E-5 3 +223RA3 G OC=0.00423 6 +223RA G 250.25 5 0.003 M1+E2 -2.1 4 0.44 7 +223RA2 G KC=0.26 6$LC=0.132 4$MC=0.0344 8$NC=0.00909 20 +223RA3 G OC=0.00198 5 +223RA G 299.95 5 0.020 4E1 0.0352 5 +223RA2 G KC=0.0284 4$LC=0.00518 8$MC=0.001234 18$NC=0.00323 5 +223RA3 G OC=0.00722 10 +223RA G 329.80 5 0.024 5(E1) 0.0285 4 +223RA2 G KC=0.0230 4$LC=0.00415 6$MC=0.000988 14$NC=0.00259 4 +223RA3 G OC=0.00579 8 +223RA L 334.29 4 5/2+ +223RA B 814.9 9 0.042 9 8.43 1 +223RAS B EAV=256.3 4 +223RA G 210.60 5 0.0097 19E1 0.0798 11 +223RA2 G KC=0.0637 9$LC=0.01222 18$MC=0.00292 4$NC=0.00763 1 +223RA3 G OC=0.00170 3 +223RA G 254.6 2 0.0057 12E1 0.0512 7 +223RA2 G KC=0.0411 6$LC=0.00767 11$MC=0.00183 3$NC=0.00478 7 +223RA3 G OC=0.00107 2 +223RA G 272.8 2 0.004 1M1+E2 0.6 4 +223RA2 G KC=0.4 4$LC=0.112 25$MC=0.028 5$NC=7.3E-6 12 +223RA3 G OC=1.6E-6 3 +223RA G 304.40 5 0.0086 17M1+E2(+E0)0.26 4 0.647 14 +223RA2 G KC=0.518 12$LC=0.0978 16$MC=0.0234 4$NC=0.00618 10 +223RA3 G OC=0.00141 2 +223RA G 334.30 6 0.0084 17M1+E2 -0.61 4 0.414 13 +223RA2 G KC=0.325 11$LC=0.0674 14$MC=0.0164 3$NC=0.00432 8 +223RA3 G OC=0.00977 2 +223RA L 342.51 4 3/2+ +223RA B 806.7 9 0.037 8 8.47 +223RAS B EAV=253.3 4 +223RA G 262.9 2 0.0035 11E1 0.0475 7 +223RA2 G KC=0.0382 6$LC=0.00709 10$MC=0.001692 24$NC=0.00443 6 +223RA3 G OC=0.00987 14 +223RA G 280.7 5 0.0003 +223RA G 312.65 5 0.016 4M1+E2 0.16 3 0.621 10 +223RA2 G KC=0.499 9$LC=0.0924 14$MC=0.0221 4$NC=0.00582 9 +223RA3 G OC=0.00133 2 +223RA G 342.50 7 0.0116 24M1+E2 1.29 2 0.250 5 +223RA2 G KC=0.183 4$LC=0.0501 8$MC=0.012520 19$NC=0.00330 5 +223RA3 G OC=0.00736 11 +223RA L 350.53 101/2- +223RA G 350.5 2 0.0027 15E1 0.0249 4 +223RA2 G KC=0.0202 3$LC=0.00361 5$MC=0.000858 12$NC=0.00225 3 +223RA3 G OC=0.00504 7 +223RA L 369.342 20(5/2)- +223RA B 779.9 9 1.8 4 6.73 +223RAS B EAV=243.7 4 +223RA G 89.08 100.054 11 +223RA G 134.60 2 0.5 1[E1] 0.234 3 +223RA2 G KC=0.184 3$LC=0.0383 6$MC=0.00921 13$NC=2.4E-6 1 +223RA3 G OC=0.00527 7 +223RA G 245.60 5 0.019 4 +223RA G 289.67 5 0.21 +223RA G 307.93 5 0.0013 13 +223RA G 319.25 5 0.46 9M1+E2 0.18 3 0.583 10 +223RA2 G KC=0.468 8$LC=0.0869 13$MC=0.0208 3$NC=0.00548 8 +223RA3 G OC=0.00125 2 +223RA G 339.50 5 0.062 13 +223RA G 369.32 5 0.089 18 +223RA L 376.09 15(7/2)- +223RA B 773.1 100.0046 12 9.31 2 +223RAS B EAV=241.3 4 +223RA G 296.5 2 0.0013 4M1+E2 -0.13 2 0.723 9 +223RA2 G KC=0.581 9$LC=0.1074 16$MC=0.0257 4$NC=0.00677 10 +223RA3 G OC=0.00154 2 +223RA G 314.6 2 0.0022 7E1 0.0316 5 +223RA2 G KC=0.0255 4$LC=0.00463 7$MC=0.001103 16$NC=0.00289 4 +223RA3 G OC=0.00646 9 +223RA L 593.94 6 +223RA B 555.3 9 0.013 3 8.38 +223RAS B EAV=165.6 4 +223RA G 307.93 5 0.012 3 +223RA G 469.3 2 0.001 +223RA L 782.54 171/2,3/2+ +223RA B 366.7 100.00111 22 8.85 1 +223RAS B EAV=104.1 3 +223RA G 439.6 3 0.00030 8 +223RA G 452.9 2 0.0008 +223RA L 787.13 5 5/2+ +223RA B 362.1 9 0.019 4 7.6 1 +223RAS B EAV=102.7 3 +223RA G 444.5 3 0.0011 4 +223RA G 452.9 2 0.0008 +223RA G 457.5 2 0.0008 +223RA G 506.9 2 0.0022 7 +223RA G 552.3 2 0.0027 8 +223RA G 663.7 3 0.0011 4 +223RA G 708.3 3 0.0013 4 +223RA G 737.4 3 0.0009 3 +223RA G 757.20 5 0.0076 20 +223RA G 787.6 2 0.0003 3 +223RA L 803.77 3 3/2,5/2+ +223RA B 345.4 9 0.14 3 6.67 +223RAS B EAV=97.5 3 +223RA G 434.4 1 0.0022 7 +223RA G 469.3 2 0.001 +223RA G 569.03 8 0.049 11 +223RA G 724.15 5 0.014 4 +223RA G 742.4 3 0.0011 4 +223RA G 753.65 5 0.0094 22 +223RA G 803.77 5 0.059 14 +223RA L 805.38 101/2,3/2,5/2+ +223RA B 343.8 9 0.0040 8 8.21 1 +223RAS B EAV=97.0 3 +223RA G 475.4 1 0.0027 +223RA G 806.0 2 0.0013 4 +223RA L 823.22 7 1/2,3/2,5/2+ +223RA B 326.0 9 0.014 3 7.59 1 +223RAS B EAV=91.5 3 +223RA G 480.9 3 0.0013 4 +223RA G 493.4 2 0.0024 7 +223RA G 537.2 2 0.0032 +223RA G 823.20 7 0.0070 16 +223RA L 825.94 4 (3/2)+ +223RA B 323.3 9 0.54 10 5.99 +223RAS B EAV=90.7 3 +223RA G 475.4 1 0.003 +223RA G 539.8 2 0.0059 18 +223RA G 545.4 4 0.00030 8 +223RA G 746.30 5 0.020 5 +223RA G 775.83 5 0.45 9 +223RA G 825.95 7 0.054 13 +223RA L 842.25 5 3/2,5/2+ +223RA B 306.9 9 0.035 7 7.11 +223RAS B EAV=85.7 3 +223RA G 556.3 3 0.0011 4 +223RA G 607.6 3 0.0022 7 +223RA G 762.6 2 0.0024 7 +223RA G 780.8 1 0.003 1 +223RA G 792.2 3 0.00054 14 +223RA G 812.40 6 0.021 5 +223RA G 842.2 1 0.0049 11 +223RA L 846.37 3 5/2+ +223RA B 302.8 9 0.088 18 6.69 1 +223RAS B EAV=84.4 3 +223RA G 516.7 2 0.0032 8 +223RA G 722.65 5 0.038 9 +223RA G 766.64 5 0.022 5 +223RA G 784.93 5 0.0086 21 +223RA G 796.22 5 0.0108 25 +223RA G 846.85 100.005 3 +223RA L 867.34 6 3/2,5/2+ +223RA B 281.9 9 0.025 5 7.14 +223RAS B EAV=78.1 3 +223RA G 524.8 2 0.0043 12 +223RA G 533.1 3 0.0019 7 +223RA G 537.2 2 0.0019 +223RA G 581.3 4 0.0013 4 +223RA G 632.7 3 0.0022 7 +223RA G 787.6 2 0.0024 7 +223RA G 837.5 1 0.0097 21 +223RA G 867.4 1 0.0016 4 +223RA L 905.9 4 +223RA B 243.3 100.0011 4 8.29 +223RAS B EAV=66.6 3 +223RA G 576.1 4 0.0011 4 +223RA L 926.56 7 3/2,5/2+ +223RA B 222.6 9 0.106 22 6.18 +223RAS B EAV=60.5 3 +223RA G 592.3 2 0.0032 10 +223RA G 596.9 4 0.0008 3 +223RA G 846.85 100.049 13 +223RA G 876.5 1 0.038 9 +223RA G 896.7 2 0.013 3 +223RA G 926.5 3 0.0016 4 +223RA L 940.78 133/2,5/2- +223RA B 208.4 9 0.0051 12 7.41 +223RAS B EAV=56.3 3 +223RA G 816.5 2 0.0013 4 +223RA G 911.3 3 0.0008 3 +223RA G 941.2 3 0.0030 8 +223RA L 943.26 9 3/2,5/2+ +223RA B 205.9 9 0.0082 18 7.19 +223RAS B EAV=55.6 3 +223RA G 600.7 4 0.00054 14 +223RA G 613.6 4 0.0011 4 +223RA G 863.6 1 0.0038 9 +223RA G 893.1 2 0.0024 7 +223RA G 913.6 3 0.00041 14 +223RA L 957.72 113/2,5/2+ +223RA B 191.5 9 0.020 4 6.7 +223RAS B EAV=51.5 3 +223RA G 671.9 4 0.00054 14 +223RA G 833.9 2 0.0013 4 +223RA G 878.1 2 0.0032 8 +223RA G 907.6 2 0.014 3 +223RA G 958.0 7 0.00035 8 +223RA L 1019.3 4 +223RA B 129.9 100.00046 12 7.82 +223RAS B EAV=34.1 3 +223RA G 969.2 4 0.00032 8 +223RA G 989.4 5 0.00014 3 +223RA L 1024.59 23 +223RA B 124.6 100.0004 1 7.82 +223RAS B EAV=32.7 3 +223RA G 975.2 5 0.00016 5 +223RA G 994.3 3 0.00011 3 +223RA G 1025.1 5 0.00014 3 +223RA L 1028.94 25 +223RA B 120.3 100.0012 3 7.3 +223RAS B EAV=31.5 3 +223RA G 949.3 4 0.00032 8 +223RA G 978.7 4 0.00067 12 +223RA G 999.3 5 0.00019 4 + diff --git a/HEN_HOUSE/spectra/lnhb/Ga-66.txt b/HEN_HOUSE/spectra/lnhb/Ga-66.txt index d38ab0bad..9d273c70e 100644 --- a/HEN_HOUSE/spectra/lnhb/Ga-66.txt +++ b/HEN_HOUSE/spectra/lnhb/Ga-66.txt @@ -1,243 +1,243 @@ - 66ZN 66GA EC DECAY (9.49 H) - 66ZN T Auger electrons and X ray energies and emission intensities: - 66ZN T {U Energy (keV)} {U Intensity} {U Line} - 66ZN T - 66ZN T 8.61587 5.8 3 XKA2 - 66ZN T 8.63896 11.3 6 XKA1 - 66ZN T - 66ZN T 9.5721 |] 2.42 12 XKB1 - 66ZN T 9.6499 |] XKB5II - 66ZN T - 66ZN T 9.6581 |] XKB2 - 66ZN T - 66ZN T 0.884-1.035 0.597 19 XL (total) - 66ZN T 0.884 XLL - 66ZN T -1.035 XLB - 66ZN T - 66ZN T 7.21-7.55 |] KLL AUGER - 66ZN T 8.31-8.63 |] 20.6 10 KLX AUGER - 66ZN T 9.39-9.65 |] KXY AUGER - 66ZN T 0.732-0.997 57.2 16 L AUGER - 66GA P 0.0 0+ 9.49 H 7 5175 3 - 66ZN N 1.0 1.0 1 1.0 - 66ZN G 171.9 2 0.0104 9 - 66ZN G 3724.8 100.0024 4 - 66ZN G 3806.3 100.0024 4 - 66ZN G 3827.5 8 0.0069 10 - 66ZN L 0 0+ STABLE - 66ZN E 50 40.47 47.88 - 66ZN2 E EAV=1904.1 15$CK=0.8850 15$CL=0.0978 12$CM=0.0161 4 - 66ZN L 1039.2268 212+ 1.65 PS 6 - 66ZN G 1039.2200 3037 3E2 - 66ZN L 1872.7633 242+ 0.19 PS 7 - 66ZN G 833.5324 215.9 5M1+E2 -1.6 2 - 66ZN G 1872.740 6 0.0229 24[E2] - 66ZN L 2372.352 4 0+ - 66ZN E 0.30 30.038 38.46 - 66ZN2 E EAV=781.6 14$CK=0.8847 15$CL=0.0980 12$CM=0.0162 4 - 66ZN G 499.590 6 0.0048 12E2+M3 - 66ZN G 1333.112 5 1.17 9E2 - 66ZN L 2780.156 7 2+ 0.26 PS 7 - 66ZN G 907.390 190.0218 23M1+E2 0.13 24 - 66ZN G 1740.904 160.029 4M1+E2 0.33 28 - 66ZN G 2780.095 160.123 10E2 - 66ZN L 2826.69 5 3- - 66ZN E 0.0053 80.0017 39.66 3 - 66ZN2 E EAV=575.3 14$CK=0.8846 15$CL=0.0981 12$CM=0.0162 4 - 66ZN G 953.93 9 0.00100 13 - 66ZN G 1787.44 9 0.0089 10(E1) - 66ZN L 2938.072 3 2+ 0.044 PS 16 - 66ZN G 1065.305 9 0.0023 5 - 66ZN G 1898.823 8 0.39 3(M1+E2) 0.03 1 - 66ZN L 3105.038 4 0+ - 66ZN G 1232.264 8 0.50 4 - 66ZN G 2065.778 7 0.031 3 - 66ZN L 3212.580 8 2+ - 66ZN G 2173.319 150.084 8 - 66ZN G 3212.499 190.0019 4 - 66ZN L 3228.884 3 1+ 0.12 PS 3 - 66ZN E 3.7 33.7 36.14 - 66ZN2 E EAV=397.1 14$CK=0.8844 15$CL=0.0982 12$CM=0.0162 4 - 66ZN G 290.8105 110.049 4 - 66ZN G 448.730 200.107 9M1+E2 -0.02 3 - 66ZN G 856.527 100.111 11 - 66ZN G 1356.104 9 0.36 5 - 66ZN G 2189.616 6 5.3 4M1+E2 0.12 2 - 66ZN G 3228.800 6 1.51 12M1+E2 - 66ZN L 3331.440 6 2+ 0.083 PS 17 - 66ZN G 551.284 220.0070 8 - 66ZN G 1458.662 120.096 23M1+E2 -0.010 9 - 66ZN G 2292.171 130.0170 18 - 66ZN G 3331.351 140.0023 30 - 66ZN L 3380.942 4 1- - 66ZN E 0.70 61.31 116.53 1 - 66ZN2 E EAV=331.1 13$CK=0.8843 15$CL=0.0983 12$CM=0.0162 4 - 66ZN G 442.873 140.01554 16 - 66ZN G 600.788 210.0135 14 - 66ZN G 1008.588 120.059 9 - 66ZN G 1508.158 7 0.55 4 - 66ZN G 2341.673 110.0032 7 - 66ZN G 3380.850 6 1.46 12 - 66ZN L 3427.404 181,2- - 66ZN E 0.0020 50.0047 118.95 1 - 66ZN2 E EAV=311.1 13$CK=0.8843 15$CL=0.0983 12$CM=0.0162 4 - 66ZN G 1554.62 3 0.0183 18 - 66ZN L 3432.406 4 1- 30 FS 13 - 66ZN E 0.16 20.39 47.03 1 - 66ZN2 E EAV=308.9 13$CK=0.8843 15$CL=0.0983 12$CM=0.0162 4 - 66ZN G 494.336 130.0056 9 - 66ZN G 1060.051 110.0155 17 - 66ZN G 1559.627 100.0219 23 - 66ZN G 2393.129 7 0.23 2E1 - 66ZN G 3432.309 7 0.288 24 - 66ZN L 3507.247 232+ - 66ZN G 680.56 100.0015 4 - 66ZN G 1634.46 7 0.0035 6 - 66ZN G 2467.97 7 0.0084 10 - 66ZN L 3531.691 140+ - 66ZN G 2492.42 3 0.0222 23 - 66ZN L 3576.368 224+ - 66ZN G 749.68 100.0014 4 - 66ZN G 796.21 5 0.0029 7 - 66ZN G 1703.59 5 0.0054 19 - 66ZN G 2537.09 5 0.0051 12 - 66ZN L 3670.72 5 2+ - 66ZN G 1797.94 9 0.0019 5 - 66ZN G 2631.44 9 0.0029 11 - 66ZN L 3738.207 21 + 9.7 FS 25 - 66ZN E 0.0009 30.015 68.27 - 66ZN2 E EAV=179.2 13$CK=0.8841 15$CL=0.0985 12$CM=0.0163 4 - 66ZN G 800.13 5 0.0010 5 - 66ZN G 2698.92 5 0.0037 7 - 66ZN G 3738.10 5 0.0138 13 - 66ZN L 3753.01 4 4+ - 66ZN G 2713.73 5 0.0062 19 - 66ZN L 3791.121 3 1+ - 66ZN E 0.94 826.0 215 - 66ZN2 E EAV=157.0 13$CK=0.8841 15$CL=0.0985 12$CM=0.0163 4 - 66ZN G 283.87 3 0.0036 8 - 66ZN G 410.178 120.065 6 - 66ZN G 459.683 140.088 8 - 66ZN G 562.241 100.0066 8 - 66ZN G 578.540 190.059 6 - 66ZN G 686.080 6 0.252 22 - 66ZN G 853.038 8 0.076 6M1+E2 0.37 18 - 66ZN G 1010.957 190.027 3 - 66ZN G 1418.754 5 0.61 5 - 66ZN G 1918.329 5 1.99 16M1+E2 -0.07 3 - 66ZN G 2751.835 5 22.7 18(M1+E2) - 66ZN G 3791.004 8 1.09 9M1+E2 - 66ZN L 3825.0 3 0+ - 66ZN E 0.0030 68.92 - 66ZN2 E CK=0.8840 15$CL=0.0986 12$CM=0.0163 4 - 66ZN G 2785.7 3 0.0030 6 - 66ZN L 3882.422 10(2)+ - 66ZN E 0.0014 99.2 2 - 66ZN2 E CK=0.8840 15$CL=0.0986 12$CM=0.0163 4 - 66ZN G 2009.628 160.0031 7 - 66ZN G 2843.130 160.0017 4 - 66ZN L 4085.982 4 1+ - 66ZN E 1.67 145.99 - 66ZN2 E CK=0.8837 15$CL=0.0988 12$CM=0.0163 4 - 66ZN G 347.77 5 0.0018 6 - 66ZN G 554.280 300.0045 6 - 66ZN G 653.568 140.0013 5 - 66ZN G 658.570 300.0075 10 - 66ZN G 705.031 150.0038 5 - 66ZN G 857.093 9 0.015 5 - 66ZN G 873.392 210.0170 18 - 66ZN G 980.934 130.048 19 - 66ZN G 1147.896 100.078 9M1+E2 -0.18 5 - 66ZN G 1305.807 210.0040 5 - 66ZN G 1713.602 120.0243 23 - 66ZN G 2213.181 9 0.131 12M1+E2 -0.23 5 - 66ZN G 3046.684 9 0.057 5M1+E2 -0.8 2 - 66ZN G 4085.853 9 1.27 10M1+E2 - 66ZN L 4295.337 4 1+ 4.2 FS 13 - 66ZN E 6.2 55.23 - 66ZN2 E CK=0.8833 15$CL=0.0992 12$CM=0.0164 4 - 66ZN G 412.916 160.0034 6 - 66ZN G 557.13 5 0.0061 8M1+E2 - 66ZN G 718.97 5 0.0099 10 - 66ZN G 763.640 300.0089 10 - 66ZN G 862.926 130.0152 14 - 66ZN G 867.930 300.0043 6 - 66ZN G 914.388 140.027 3 - 66ZN G 963.892 150.0144 16 - 66ZN G 1066.450 120.0024 5 - 66ZN G 1082.750 200.0133 13 - 66ZN G 1190.287 7 0.128 13 - 66ZN G 1357.250 120.16 5M1+E2 -0.18 5 - 66ZN G 1515.162 200.0062 7 - 66ZN G 2422.525 7 1.88 15M1+E2 0.01 3 - 66ZN G 3256.021 9 0.094 8M1+E2 1.5 2 - 66ZN G 4295.187 103.8 3 - 66ZN L 4461.370 5 1+ 7.0 FS 7 - 66ZN E 1.96 175.54 - 66ZN2 E CK=0.8828 15$CL=0.0996 12$CM=0.0165 4 - 66ZN G 375.398 170.0021 6 - 66ZN G 670.251 140.0041 7 - 66ZN G 708.36 5 0.0087 10 - 66ZN G 723.17 5 0.0034 6 - 66ZN G 885.00 5 0.0019 5 - 66ZN G 929.680 300.0046 7 - 66ZN G 954.12 7 0.0045 7 - 66ZN G 1129.923 180.0136 13 - 66ZN G 1232.480 150.056 19 - 66ZN G 1248.779 220.0010 3 - 66ZN G 1356.320 150.122 21 - 66ZN G 1523.279 150.0055 7 - 66ZN G 2088.985 130.011 3 - 66ZN G 2588.553 130.0263 26M1+E2 0.35 27 - 66ZN G 3422.040 8 0.86 7M1+E2 -0.06 2 - 66ZN G 4461.202 9 0.84 7 - 66ZN L 4638.24 141+ - 66ZN E 0.0042 107.96 - 66ZN2 E CK=0.8820 15$CL=0.1003 12$CM=0.0166 4 - 66ZN G 1106.53 240.0012 4 - 66ZN G 1409.35 240.0016 7 - 66ZN G 2265.84 240.0014 5 - 66ZN L 4675.6 5 1+ - 66ZN E 0.0015 58.35 - 66ZN2 E CK=0.8817 15$CL=0.1005 12$CM=0.0166 4 - 66ZN G 2802.8 5 0.0015 4 - 66ZN L 4806.197 5 1+ 3.8 FS 10 - 66ZN E 2.27 194.9 - 66ZN2 E CK=0.8804 15$CL=0.1016 13$CM=0.0169 4 - 66ZN G 1015.081 180.012 3 - 66ZN G 1135.47 9 0.0047 6 - 66ZN G 1274.500 300.0070 8 - 66ZN G 1298.95 7 0.0038 5 - 66ZN G 1425.25 2 0.0060 7 - 66ZN G 1577.308 200.0040 7 - 66ZN G 1868.105 200.0027 6 - 66ZN G 2026.016 250.0026 6 - 66ZN G 2433.807 180.0074 9 - 66ZN G 2933.358 9 0.213 17M1+E2 1.6 2 - 66ZN G 3766.850 9 0.149 13M1+E2 0.11 4 - 66ZN G 4806.007 9 1.86 15 - 66ZN L 4849.93 3 1+ - 66ZN E 0.033 46.62 - 66ZN2 E CK=0.8797 15$CL=0.1021 13$CM=0.0170 5 - 66ZN G 1468.97 5 0.0014 4 - 66ZN G 2977.08 4 0.023 3 - 66ZN G 3810.59 5 0.0092 11 - 66ZN L 4866.054 161+ - 66ZN E 0.047 66.42 - 66ZN2 E CK=0.8794 15$CL=0.1024 13$CM=0.0170 5 - 66ZN G 1195.32 9 0.0009 3 - 66ZN G 1433.630 400.0018 4 - 66ZN G 1534.600 400.0057 16 - 66ZN G 1927.96 4 0.0022 8 - 66ZN G 2085.860 400.0021 15 - 66ZN G 2993.21 3 0.031 4 - 66ZN G 4865.87 4 0.0028 3 - 66ZN L 4958.2 4 1+ - 66ZN E 0.0020 57.48 - 66ZN2 E CK=0.8768 16$CL=0.1046 13$CM=0.0174 5 - 66ZN G 3085.4 4 0.0020 5 - 66ZN L 5005.8 3 1+ - 66ZN E 0.00122 157.47 - 66ZN2 E CK=0.8742 16$CL=0.1067 13$CM=0.0178 5 - 66ZN G 5005.6 3 0.00124 18 - + 66ZN 66GA EC DECAY (9.49 H) + 66ZN T Auger electrons and X ray energies and emission intensities: + 66ZN T {U Energy (keV)} {U Intensity} {U Line} + 66ZN T + 66ZN T 8.61587 5.8 3 XKA2 + 66ZN T 8.63896 11.3 6 XKA1 + 66ZN T + 66ZN T 9.5721 |] 2.42 12 XKB1 + 66ZN T 9.6499 |] XKB5II + 66ZN T + 66ZN T 9.6581 |] XKB2 + 66ZN T + 66ZN T 0.884-1.035 0.597 19 XL (total) + 66ZN T 0.884 XLL + 66ZN T -1.035 XLB + 66ZN T + 66ZN T 7.21-7.55 |] KLL AUGER + 66ZN T 8.31-8.63 |] 20.6 10 KLX AUGER + 66ZN T 9.39-9.65 |] KXY AUGER + 66ZN T 0.732-0.997 57.2 16 L AUGER + 66GA P 0.0 0+ 9.49 H 7 5175 3 + 66ZN N 1.0 1.0 1 1.0 + 66ZN G 171.9 2 0.0104 9 + 66ZN G 3724.8 100.0024 4 + 66ZN G 3806.3 100.0024 4 + 66ZN G 3827.5 8 0.0069 10 + 66ZN L 0 0+ STABLE + 66ZN E 50 40.47 47.88 + 66ZN2 E EAV=1904.1 15$CK=0.008242 14$CL=0.000911 11$CM=1.499E-4 37 + 66ZN L 1039.2268 212+ 1.65 PS 6 + 66ZN G 1039.2200 3037 3E2 + 66ZN L 1872.7633 242+ 0.19 PS 7 + 66ZN G 833.5324 215.9 5M1+E2 -1.6 2 + 66ZN G 1872.740 6 0.0229 24[E2] + 66ZN L 2372.352 4 0+ + 66ZN E 0.30 30.038 38.46 + 66ZN2 E EAV=781.6 14$CK=0.09946 17$CL=0.01102 13$CM=0.001821 45 + 66ZN G 499.590 6 0.0048 12E2+M3 + 66ZN G 1333.112 5 1.17 9E2 + 66ZN L 2780.156 7 2+ 0.26 PS 7 + 66ZN G 907.390 190.0218 23M1+E2 0.13 24 + 66ZN G 1740.904 160.029 4M1+E2 0.33 28 + 66ZN G 2780.095 160.123 10E2 + 66ZN L 2826.69 5 3- + 66ZN E 0.0053 80.0017 39.66 3 + 66ZN2 E EAV=575.3 14$CK=0.21483 36$CL=0.02382 29$CM=0.00393 10 + 66ZN G 953.93 9 0.00100 13 + 66ZN G 1787.44 9 0.0089 10(E1) + 66ZN L 2938.072 3 2+ 0.044 PS 16 + 66ZN G 1065.305 9 0.0023 5 + 66ZN G 1898.823 8 0.39 3(M1+E2) 0.03 1 + 66ZN L 3105.038 4 0+ + 66ZN G 1232.264 8 0.50 4 + 66ZN G 2065.778 7 0.031 3 + 66ZN L 3212.580 8 2+ + 66ZN G 2173.319 150.084 8 + 66ZN G 3212.499 190.0019 4 + 66ZN L 3228.884 3 1+ 0.12 PS 3 + 66ZN E 3.7 33.7 36.14 + 66ZN2 E EAV=397.1 14$CK=0.4422 8$CL=0.0491 6$CM=0.0081 2 + 66ZN G 290.8105 110.049 4 + 66ZN G 448.730 200.107 9M1+E2 -0.02 3 + 66ZN G 856.527 100.111 11 + 66ZN G 1356.104 9 0.36 5 + 66ZN G 2189.616 6 5.3 4M1+E2 0.12 2 + 66ZN G 3228.800 6 1.51 12M1+E2 + 66ZN L 3331.440 6 2+ 0.083 PS 17 + 66ZN G 551.284 220.0070 8 + 66ZN G 1458.662 120.096 23M1+E2 -0.010 9 + 66ZN G 2292.171 130.0170 18 + 66ZN G 3331.351 140.0023 30 + 66ZN L 3380.942 4 1- + 66ZN E 0.70 61.31 116.53 1 + 66ZN2 E EAV=331.1 13$CK=0.5763 10$CL=0.0641 8$CM=0.01056 26 + 66ZN G 442.873 140.01554 16 + 66ZN G 600.788 210.0135 14 + 66ZN G 1008.588 120.059 9 + 66ZN G 1508.158 7 0.55 4 + 66ZN G 2341.673 110.0032 7 + 66ZN G 3380.850 6 1.46 12 + 66ZN L 3427.404 181,2- + 66ZN E 0.0020 50.0047 118.95 1 + 66ZN2 E EAV=311.1 13$CK=0.6203 11$CL=0.0690 8$CM=0.01136 28 + 66ZN G 1554.62 3 0.0183 18 + 66ZN L 3432.406 4 1- 30 FS 13 + 66ZN E 0.16 20.39 47.03 1 + 66ZN2 E EAV=308.9 13$CK=0.6270 11$CL=0.0697 9$CM=0.01149 28 + 66ZN G 494.336 130.0056 9 + 66ZN G 1060.051 110.0155 17 + 66ZN G 1559.627 100.0219 23 + 66ZN G 2393.129 7 0.23 2E1 + 66ZN G 3432.309 7 0.288 24 + 66ZN L 3507.247 232+ + 66ZN G 680.56 100.0015 4 + 66ZN G 1634.46 7 0.0035 6 + 66ZN G 2467.97 7 0.0084 10 + 66ZN L 3531.691 140+ + 66ZN G 2492.42 3 0.0222 23 + 66ZN L 3576.368 224+ + 66ZN G 749.68 100.0014 4 + 66ZN G 796.21 5 0.0029 7 + 66ZN G 1703.59 5 0.0054 19 + 66ZN G 2537.09 5 0.0051 12 + 66ZN L 3670.72 5 2+ + 66ZN G 1797.94 9 0.0019 5 + 66ZN G 2631.44 9 0.0029 11 + 66ZN L 3738.207 21 9.7 FS 25 + 66ZN E 0.0009 30.015 68.27 + 66ZN2 E EAV=179.2 13$CK=0.8341 14$CL=0.0929 11$CM=0.01538 38 + 66ZN G 800.13 5 0.0010 5 + 66ZN G 2698.92 5 0.0037 7 + 66ZN G 3738.10 5 0.0138 13E0 + 66ZN L 3753.01 4 4+ + 66ZN G 2713.73 5 0.0062 19 + 66ZN L 3791.121 3 1+ + 66ZN E 0.94 826.0 215 + 66ZN2 E EAV=157.0 13$CK=0.8533 14$CL=0.0951 12$CM=0.01573 39 + 66ZN G 283.87 3 0.0036 8 + 66ZN G 410.178 120.065 6 + 66ZN G 459.683 140.088 8 + 66ZN G 562.241 100.0066 8 + 66ZN G 578.540 190.059 6 + 66ZN G 686.080 6 0.252 22 + 66ZN G 853.038 8 0.076 6M1+E2 0.37 18 + 66ZN G 1010.957 190.027 3 + 66ZN G 1418.754 5 0.61 5 + 66ZN G 1918.329 5 1.99 16M1+E2 -0.07 3 + 66ZN G 2751.835 5 22.7 18(M1+E2) + 66ZN G 3791.004 8 1.09 9M1+E2 + 66ZN L 3825.0 3 0+ + 66ZN E 0.0030 68.92 + 66ZN2 E CK=0.8840 15$CL=0.0986 12$CM=0.0163 4 + 66ZN G 2785.7 3 0.0030 6 + 66ZN L 3882.422 10(2)+ + 66ZN E 0.0014 99.2 2 + 66ZN2 E CK=0.8840 15$CL=0.0986 12$CM=0.0163 4 + 66ZN G 2009.628 160.0031 7 + 66ZN G 2843.130 160.0017 4 + 66ZN L 4085.982 4 1+ + 66ZN E 1.67 145.99 + 66ZN2 E CK=0.8837 15$CL=0.0988 12$CM=0.0163 4 + 66ZN G 347.77 5 0.0018 6 + 66ZN G 554.280 300.0045 6 + 66ZN G 653.568 140.0013 5 + 66ZN G 658.570 300.0075 10 + 66ZN G 705.031 150.0038 5 + 66ZN G 857.093 9 0.015 5 + 66ZN G 873.392 210.0170 18 + 66ZN G 980.934 130.048 19 + 66ZN G 1147.896 100.078 9M1+E2 -0.18 5 + 66ZN G 1305.807 210.0040 5 + 66ZN G 1713.602 120.0243 23 + 66ZN G 2213.181 9 0.131 12M1+E2 -0.23 5 + 66ZN G 3046.684 9 0.057 5M1+E2 -0.8 2 + 66ZN G 4085.853 9 1.27 10M1+E2 + 66ZN L 4295.337 4 1+ 4.2 FS 13 + 66ZN E 6.2 55.23 + 66ZN2 E CK=0.8833 15$CL=0.0992 12$CM=0.0164 4 + 66ZN G 412.916 160.0034 6 + 66ZN G 557.13 5 0.0061 8M1+E2 + 66ZN G 718.97 5 0.0099 10 + 66ZN G 763.640 300.0089 10 + 66ZN G 862.926 130.0152 14 + 66ZN G 867.930 300.0043 6 + 66ZN G 914.388 140.027 3 + 66ZN G 963.892 150.0144 16 + 66ZN G 1066.450 120.0024 5 + 66ZN G 1082.750 200.0133 13 + 66ZN G 1190.287 7 0.128 13 + 66ZN G 1357.250 120.16 5M1+E2 -0.18 5 + 66ZN G 1515.162 200.0062 7 + 66ZN G 2422.525 7 1.88 15M1+E2 0.01 3 + 66ZN G 3256.021 9 0.094 8M1+E2 1.5 2 + 66ZN G 4295.187 103.8 3 + 66ZN L 4461.370 5 1+ 7.0 FS 7 + 66ZN E 1.96 175.54 + 66ZN2 E CK=0.8828 15$CL=0.0996 12$CM=0.0165 4 + 66ZN G 375.398 170.0021 6 + 66ZN G 670.251 140.0041 7 + 66ZN G 708.36 5 0.0087 10 + 66ZN G 723.17 5 0.0034 6 + 66ZN G 885.00 5 0.0019 5 + 66ZN G 929.680 300.0046 7 + 66ZN G 954.12 7 0.0045 7 + 66ZN G 1129.923 180.0136 13 + 66ZN G 1232.480 150.056 19 + 66ZN G 1248.779 220.0010 3 + 66ZN G 1356.320 150.122 21 + 66ZN G 1523.279 150.0055 7 + 66ZN G 2088.985 130.011 3 + 66ZN G 2588.553 130.0263 26M1+E2 0.35 27 + 66ZN G 3422.040 8 0.86 7M1+E2 -0.06 2 + 66ZN G 4461.202 9 0.84 7 + 66ZN L 4638.24 141+ + 66ZN E 0.0042 107.96 + 66ZN2 E CK=0.8820 15$CL=0.1003 12$CM=0.0166 4 + 66ZN G 1106.53 240.0012 4 + 66ZN G 1409.35 240.0016 7 + 66ZN G 2265.84 240.0014 5 + 66ZN L 4675.6 5 1+ + 66ZN E 0.0015 58.35 + 66ZN2 E CK=0.8817 15$CL=0.1005 12$CM=0.0166 4 + 66ZN G 2802.8 5 0.0015 4 + 66ZN L 4806.197 5 1+ 3.8 FS 10 + 66ZN E 2.27 194.9 + 66ZN2 E CK=0.8804 15$CL=0.1016 13$CM=0.0169 4 + 66ZN G 1015.081 180.012 3 + 66ZN G 1135.47 9 0.0047 6 + 66ZN G 1274.500 300.0070 8 + 66ZN G 1298.95 7 0.0038 5 + 66ZN G 1425.25 2 0.0060 7 + 66ZN G 1577.308 200.0040 7 + 66ZN G 1868.105 200.0027 6 + 66ZN G 2026.016 250.0026 6 + 66ZN G 2433.807 180.0074 9 + 66ZN G 2933.358 9 0.213 17M1+E2 1.6 2 + 66ZN G 3766.850 9 0.149 13M1+E2 0.11 4 + 66ZN G 4806.007 9 1.86 15 + 66ZN L 4849.93 3 1+ + 66ZN E 0.033 46.62 + 66ZN2 E CK=0.8797 15$CL=0.1021 13$CM=0.0170 5 + 66ZN G 1468.97 5 0.0014 4 + 66ZN G 2977.08 4 0.023 3 + 66ZN G 3810.59 5 0.0092 11 + 66ZN L 4866.054 161+ + 66ZN E 0.047 66.42 + 66ZN2 E CK=0.8794 15$CL=0.1024 13$CM=0.0170 5 + 66ZN G 1195.32 9 0.0009 3 + 66ZN G 1433.630 400.0018 4 + 66ZN G 1534.600 400.0057 16 + 66ZN G 1927.96 4 0.0022 8 + 66ZN G 2085.860 400.0021 15 + 66ZN G 2993.21 3 0.031 4 + 66ZN G 4865.87 4 0.0028 3 + 66ZN L 4958.2 4 1+ + 66ZN E 0.0020 57.48 + 66ZN2 E CK=0.8768 16$CL=0.1046 13$CM=0.0174 5 + 66ZN G 3085.4 4 0.0020 5 + 66ZN L 5005.8 3 1+ + 66ZN E 0.00122 157.47 + 66ZN2 E CK=0.8742 16$CL=0.1067 13$CM=0.0178 5 + 66ZN G 5005.6 3 0.00124 18 + diff --git a/HEN_HOUSE/spectra/lnhb/Ga-67.txt b/HEN_HOUSE/spectra/lnhb/Ga-67.txt index 4032a317f..0f357acab 100644 --- a/HEN_HOUSE/spectra/lnhb/Ga-67.txt +++ b/HEN_HOUSE/spectra/lnhb/Ga-67.txt @@ -1,76 +1,73 @@ - 67ZN 67GA EC DECAY (3.2613 D) - 67ZN H TYP=Ajout$AUT=mmbe$CUT= -- $ - 67ZN2 H TYP=Correction$AUT=mmbe$CUT= -- $ - 67ZN3 H TYP=Hist.$AUT=mmbe$CUT= -- $ - 67ZN C Evaluation history: Type=Ajout;Author=mmbe;Cutoff date= -- - 67ZN2C Type=Correction;Author=mmbe;Cutoff date= -- - 67ZN3C Type=Hist.;Author=mmbe;Cutoff date= -- - 67ZN C References: 1938AL02, 1938MA01, 1948MC32, 1948HO04, 1950HO26, 1953ME52, - 67ZN2C 1955TO27, 1957BU39, 1958CH08, 1961HO05, 1962RI09, 1964RU06, 1964AL28, - 67ZN3C 1966FR12, 1967BE65, 1968LI02, 1967VR03, 1969RA15, 1969LI04, 1969IV02, - 67ZN4C 1969BO41, 1971SU18, 1972CR02, 1972EN08, 1972LE37, 1973BA54, 1973LE18, - 67ZN5C 1974HEYW, 1974AR22, 1974NI01, 1975TH01, 1975WE08, 1975RO25, 1977La19, - 67ZN6C 1977AB02, 1978LA21, 1978DU04, 1978ME10, 1978LO06, 1979DE42, 1980HO17, - 67ZN7C 1982HOZJ, 1988BE55, 1990ME15, 1991BH06, 1992UN01, 1996HW03, 1996SC06, - 67ZN8C 1998AT04, 2000SI03, 2002UN02, 2003AU03, 2003AU02, 2004SC04, 2004DA05, - 67ZN9C 2005YA01, 2005HU18, 2008MO18, 2008KI07 - 67ZN T Auger electrons and X ray energies and emission intensities: - 67ZN T {U Energy (keV)} {U Intensity} {U Line} - 67ZN T - 67ZN T 8.61587 17.0 6 XKA2 - 67ZN T 8.63896 33.0 12 XKA1 - 67ZN T - 67ZN T 9.5721 |] 7.08 26 XKB1 - 67ZN T 9.6499 |] XKB5II - 67ZN T - 67ZN T 9.6581 |] XKB2 - 67ZN T - 67ZN T 0.8836-1.1861 1.75 5 XL (total) - 67ZN T 0.8836 0.0504 18 XLL - 67ZN T 1.0119-1.0122 0.97 3 XLA - 67ZN T 0.9065 0.0328 13 XLC - 67ZN T 1.02044-1.1861 0.700 26 XLB - 67ZN T 1.04333-1.04333 0.00228 17 XLG - 67ZN T - 67ZN T 7.21-7.55 |] KLL AUGER - 67ZN T 8.31-8.63 |] 60.4 21 KLX AUGER - 67ZN T 9.39-9.65 |] KXY AUGER - 67ZN T 0.732-0.997 167.5 21 L AUGER - 67GA P 0.0 3/2- 3.2613 D 5 1000.8 12 - 67ZN N 1.0 1.0 1 1.0 - 67ZN L 0 5/2- STABLE - 67ZN E 3.3 326.532 - 67ZN2 E CK=0.8836 15$CL=0.0989 12$CM=0.0164 4$CN=0.0011 1$CO=0 0 - 67ZN L 93.31 1/2- 9.00 US 4 - 67ZN E 50.5 175.261 - 67ZN2 E CK=0.8834 15$CL=0.0991 12$CM=0.0164 4$CN=0.0011 1 - 67ZN G 93.307 1238.1 7E2 0.854 12 - 67ZN2 G KC=0.748 11$LC=0.0922 13$MC=0.01300 19 - 67ZN L 184.58 3/2- 1.028 NS 14 - 67ZN E 22.3 275.523 - 67ZN2 E CK=0.8832 15$CL=0.0993 12$CM=0.0164 4$CN=0.0011 1 - 67ZN G 91.263 153.09 7M1+()E2 0.123 25 0.091 6 - 67ZN2 G KC=0.081 5$LC=0.0087 7$MC=0.00125 9 - 67ZN G 184.577 1720.96 44M1+()E2 0.31 7 0.0169 21 - 67ZN2 G KC=0.0151 19$LC=0.00158 20$MC=0.00023 3 - 67ZN L 393.53 3/2- - 67ZN E 23.60 475.239 - 67ZN2 E CK=0.8824 15$CL=0.0999 12$CM=0.0165 4$CN=0.0011 1 - 67ZN G 208.939 152.37 5M1+()E2 0.042 17 0.0090114 - 67ZN2 G KC=0.00806 13$LC=8.27E-4 13$MC=1186E-7 19 - 67ZN G 300.232 2116.60 37M1+()E2 0.178 10 0.00388 6 - 67ZN2 G KC=0.00348 6$LC=3.54E-4 6$MC=5.08E-5 8 - 67ZN G 393.528 204.59 10M1+()E2 0.051 16 0.00193 3 - 67ZN2 G KC=1728E-6 25$LC=1748E-7 25$MC=2.51E-5 4 - 67ZN L 887.69 5/2- - 67ZN E 0.280 85.648 - 67ZN2 E CK=0.8680 17$CL=0.1119 14$CM=0.0188 5$CN=0.0013 1 - 67ZN G 494.143 280.0666 29M1+()E2 0.110 34 1149E-618 - 67ZN2 G KC=1030E-6 16$LC=1038E-7 17$MC=1488E-8 24 - 67ZN G 703.11 8 0.0113 9M1+()E2 0.090 28 5.24E-4 8 - 67ZN2 G KC=4.70E-4 7$LC=4.70E-5 7$MC=6.74E-6 10 - 67ZN G 794.400 410.0528 17E2+()M3 0.09 11 0.00054 6 - 67ZN2 G KC=0.00048 5$LC=4.9E-5 6$MC=7.0E-6 8 - 67ZN G 887.676 330.1492 38M1+()E2 0.95 9 3.54E-4 7 - 67ZN2 G KC=3.18E-4 6$LC=3.18E-5 6$MC=4.56E-6 8 - + 67ZN 67GA EC DECAY (3.2613 D) + 67ZN H TYP=MOD$AUT=M.-M.BE$DAT=23-FEB-2006$COM=See DDEP website$ + 67ZN2 H TYP=MOD$AUT=M.-M.BE$DAT=02-DEC-2005$COM=See DDEP website$ + 67ZN3 H TYP=MOD$AUT=M.-M.BE$DAT=01-DEC-2005$COM=See DDEP website$ + 67ZN C References:1938AL02, 1938MA01, 1948MC32, 1948HO04, 1950HO26, 1953Ke**, + 67ZN2C 1953ME52, 1955TO27, 1957BU39, 1958CH08, 1961HO05, 1962RI09, 1964RU06, + 67ZN3C 1964AL28, 1966FR12, 1967BE65, 1968LI02, 1967VR03, 1969RA15, 1969LI04, + 67ZN4C 1969IV02, 1969BO41, 1971SU18, 1972CR02, 1972EN08, 1972LE37, 1973BA54, + 67ZN5C 1973LE18, 1974HEYW, 1974AR22, 1974NI01, 1975TH01, 1975WE08, 1975RO25, + 67ZN6C 1977La19, 1977AB02, 1978LA21, 1978DU04, 1978ME10, 1978LO06, 1979DE42, + 67ZN7C 1980HO17, 1982HOZJ, 1987Ta**, 1988BE55, 1990ME15, 1991BH06, 1992UN01, + 67ZN8C 1996HW03, 1996SC06, 1998AT04, 2000SI03, 2002Un02, 2003Au03, 2003Au02, + 67ZN9C 2004SC04, 2004Da05, 2005YA01, 2005HU18, 2007Bo**, 2008MO18, 2008Ki07 + 67ZN T Auger electrons and X ray energies and emission intensities: + 67ZN T {U Energy (keV)} {U Intensity} {U Line} + 67ZN T + 67ZN T 8.61587 17.0 6 XKA2 + 67ZN T 8.63896 33.0 12 XKA1 + 67ZN T + 67ZN T 9.5721 |] 7.08 26 XKB1 + 67ZN T 9.6499 |] XKB5II + 67ZN T + 67ZN T 9.6581 |] XKB2 + 67ZN T + 67ZN T 0.8836-1.1861 1.75 5 XL (total) + 67ZN T 0.8836 0.0504 18 XLL + 67ZN T 1.0119-1.0122 0.97 3 XLA + 67ZN T 0.9065 0.0328 13 XLC + 67ZN T 1.02044-1.1861 0.700 26 XLB + 67ZN T 1.04333-1.04333 0.00228 17 XLG + 67ZN T + 67ZN T 7.21-7.55 |] KLL AUGER + 67ZN T 8.31-8.63 |] 60.4 21 KLX AUGER + 67ZN T 9.39-9.65 |] KXY AUGER + 67ZN T 0.732-0.997 167.5 21 L AUGER + 67GA P 0.0 3/2- 3.2613 D 5 1000.8 12 + 67ZN N 1.0 1.0 1 1.0 + 67ZN L 0 5/2- STABLE + 67ZN E 3.3 326.532 + 67ZN2 E CK=0.8836 15$CL=0.0989 12$CM=0.0164 4$CN=0.0011 1 + 67ZN L 93.31 1/2- 9.00 US 4 + 67ZN E 50.5 175.261 + 67ZN2 E CK=0.8834 15$CL=0.0991 12$CM=0.0164 4$CN=0.0011 1 + 67ZN G 93.307 1238.1 7E2 0.854 12 + 67ZN2 G KC=0.748 11$LC=0.0922 13$MC=0.01300 19$NC=0.000388 6 + 67ZN L 184.58 3/2- 1.028 NS 14 + 67ZN E 22.3 275.523 + 67ZN2 E CK=0.8832 15$CL=0.0993 12$CM=0.0164 4$CN=0.0011 1 + 67ZN G 91.263 153.09 7M1+E2 0.123 25 0.091 6 + 67ZN2 G KC=0.081 5$LC=0.0087 7$MC=0.00125 9$NC=0.000047 3 + 67ZN G 184.577 1720.96 44M1+E2 0.31 7 0.0169 21 + 67ZN2 G KC=0.0151 19$LC=0.00158 20$MC=0.00023 3$NC=8.6E-6 10 + 67ZN L 393.53 3/2- + 67ZN E 23.60 475.239 + 67ZN2 E CK=0.8824 15$CL=0.0999 12$CM=0.0165 4$CN=0.0011 1 + 67ZN G 208.939 152.37 5M1+E2 0.042 17 0.0090114 + 67ZN2 G KC=0.00806 13$LC=0.000827 13$MC=1.186E-4 19$NC=4.70E-6 7 + 67ZN G 300.232 2116.60 37M1+E2 0.178 10 0.00388 6 + 67ZN2 G KC=0.00348 6$LC=0.000354 6$MC=5.08E-5 8$NC=2.02E-6 3 + 67ZN G 393.528 204.59 10M1+E2 0.051 16 0.00193 3 + 67ZN2 G KC=0.001728 25$LC=1.748E-4 25$MC=2.51E-5 4$NC=1.004E-6 15 + 67ZN L 887.69 5/2- + 67ZN E 0.280 85.648 + 67ZN2 E CK=0.8680 17$CL=0.1119 14$CM=0.0188 5$CN=0.0013 1 + 67ZN G 494.143 280.0666 29M1+E2 0.110 34 1149E-618 + 67ZN2 G KC=0.001030 16$LC=1.038E-4 17$MC=1.488E-5 24$NC=5.98E-7 10 + 67ZN G 703.11 8 0.0113 9M1+E2 0.090 28 5.24E-4 8 + 67ZN2 G KC=0.000470 7$LC=4.70E-5 7$MC=6.74E-6 10$NC=2.72E-7 4 + 67ZN G 794.400 410.0528 17E2+M3 0.09 11 0.00054 6 + 67ZN2 G KC=0.00048 5$LC=0.000049 6$MC=7.0E-6 8$NC=2.8E-7 3 + 67ZN G 887.676 330.1492 38M1+E2 0.95 9 3.54E-4 7 + 67ZN2 G KC=0.000318 6$LC=3.18E-5 6$MC=4.56E-6 8$NC=1.83E-7 4 + diff --git a/HEN_HOUSE/spectra/lnhb/Ga-68.txt b/HEN_HOUSE/spectra/lnhb/Ga-68.txt index 4f2556b29..d3f943b3a 100644 --- a/HEN_HOUSE/spectra/lnhb/Ga-68.txt +++ b/HEN_HOUSE/spectra/lnhb/Ga-68.txt @@ -1,77 +1,76 @@ - 68ZN 68GA EC DECAY (67.83 M) - 68ZN H TYP=Full$AUT=M.-M. Bé$CUT=30-NOV-2011$ - 68ZN2 H TYP=Full$AUT=E.Schonfeld$CUT= -- $ - 68ZN C Evaluation history: Type=Full;Author=M.-M. Bé;Cutoff date=30-NOV-2011 - 68ZN2C Type=Full;Author=E.Schonfeld;Cutoff date= -- - 68ZN C References: 1956Cr29, 1959Ho85, 1959Ra04, 1959Ho85, 1960Ra22, 1965Bo42, - 68ZN2C 1965Eb01, 1968Ca15, 1969Va16, 1971Oo01, 1971Sm02, 1972Sl03, 1973La01, - 68ZN3C 1977Kr17, 1983Iw02, 1992Sy**, 1994Vo15, 1994Sc44, 2003Au03, 2012Lu14 - 68ZN T Auger electrons and X ray energies and emission intensities: - 68ZN T {U Energy (keV)} {U Intensity} {U Line} - 68ZN T - 68ZN T 8.61587 1.42 6 XKA2 - 68ZN T 8.63896 2.76 11 XKA1 - 68ZN T - 68ZN T 9.5721 |] 0.593 24 XKB1 - 68ZN T 9.6499 |] XKB5II - 68ZN T - 68ZN T - 68ZN T 0.884-1.186 0.146 4 XL (total) - 68ZN T 0.884 0.00421 16 XLL - 68ZN T 1.012-1.012 0.0807 28 XLA - 68ZN T 0.906 0.00273 11 XLC - 68ZN T 1.02-1.186 0.0584 23 XLB - 68ZN T 1.043-1.043 0.00019014 XLG - 68ZN T - 68ZN T 7.21-7.55 |] KLL AUGER - 68ZN T 8.31-8.63 |] 5.05 20 KLX AUGER - 68ZN T 9.39-9.65 |] KXY AUGER - 68ZN T 0.732-0.997 13.98 19 L AUGER - 68GA P 0.0 1+ 67.83 M 20 2921.1 12 - 68ZN N 1.0 1.0 1 1.0 - 68ZN L 0 0+ STABLE - 68ZN E 87.68 418.94 415.2 - 68ZN2 E EAV=836.0 6$CK=0.8847 15$CL=0.0980 12$CM=0.0162 4$CN=0.0011 1$CO=0 0 - 68ZN L 1077.35 5 2+ 1.57 PS 4 - 68ZN E 1.20 41.80 55.5 - 68ZN2 E EAV=352.6 6$CK=0.8844 15$CL=0.0983 14$CM=0.0162 5 - 68ZN G 1077.34 5 3.235 30E2 2.47E-4 4 - 68ZN2 G KC=2.21E-4 4$LC=2.22E-5 4$MC=3.18E-6 5 - 68ZN L 1655.87 140+ 70 PS 35 - 68ZN E 0.00026 20.0335 236.9 - 68ZN2 E EAV=107.6 6$CK=0.8839 15$CL=0.0986 14$CM=0.0163 5 - 68ZN G 1655.87 14 - 68ZN G 578.52 130.0343 23E2 1272E-618 - 68ZN2 G KC=1139E-6 16$LC=1160E-7 17$MC=1.66E-5 3 - 68ZN L 1883.19 6 2+ 1.6 PS 3 - 68ZN E 0.234 55.9 - 68ZN2 E CK=0.8836 15$CL=0.0989 14$CM=0.0164 5 - 68ZN G 227.31 150.00012049E2 0.0300 5 - 68ZN2 G KC=0.0268 4$LC=0.00286 4$MC=4.06E-4 6 - 68ZN G 805.83 8 0.0928 27M1+()E2 -1.53 5 4.70E-4 7 - 68ZN2 G KC=4.21E-4 6$LC=4.24E-5 7$MC=6.07E-6 9 - 68ZN G 1883.16 6 0.1420 35E2 3.33E-4 5 - 68ZN2 G KC=6.97E-5 10$LC=6.91E-6 10$MC=9.9E-7 2 - 68ZN L 2338.44 8 2+ 0.24 PS - 68ZN E 0.096 35.7 - 68ZN2 E CK=0.8823 16$CL=0.1000 15$CM=0.0166 5 - 68ZN G 682.57 160.00031420E2 7.89E-411 - 68ZN2 G KC=7.07E-4 10$LC=7.16E-5 10$MC=1.03E-5 2 - 68ZN G 1261.08 9 0.0954 21M1+()E2 -0.15 2 1725E-725 - 68ZN2 G KC=1418E-7 20$LC=1409E-8 20$MC=2.02E-6 3 - 68ZN G 2338.44 8 0.00113 16E2 5.29E-4 8 - 68ZN2 G KC=4.71E-5 7$LC=4.67E-6 7$MC=6.7E-7 1 - 68ZN L 2821.79 142+ - 68ZN E 0.0104 55.1 - 68ZN2 E CK=0.8653 18$CL=0.1141 17$CM=0.0192 5 - 68ZN G 483.35 160.00026529M1+()E2 1.0 5 0.0017 3 - 68ZN2 G KC=0.0015 3$LC=0.00016 3$MC=2.2E-5 4 - 68ZN G 938.61 200.00017816M1+()E2 -0.7 3 3.04E-412 - 68ZN2 G KC=2.72E-4 11$LC=2.72E-5 11$MC=3.9E-6 2 - 68ZN G 1165.92 150.00001610E2 2.11E-4 3 - 68ZN2 G KC=1.85E-4 3$LC=1.85E-5 3$MC=2.65E-6 4 - 68ZN G 1744.42 130.0096 5M1+()E2 0.272 18 2.41E-4 4 - 68ZN2 G KC=7.70E-5 11$LC=7.63E-6 11$MC=1.09E-6 2 - 68ZN G 2821.73 140.00046636E2 7.40E-411 - 68ZN2 G KC=3.43E-5 5$LC=3.39E-6 5$MC=4.86E-7 7 - + 68ZN 68GA EC DECAY (67.83 M) + 68ZN H TYP=FUL$AUT=M.-M.BE$CUT=30-NOV-2011$ + 68ZN2 H TYP=FUL$AUT=E.SCHONFELD$CUT=15-JAN-1998$ + 68ZN C References:1956Cr29, 1959Ho85, 1959Ra04, 1959Ho85, 1960Ra22, 1965Bo42, + 68ZN2C 1965Eb01, 1968Ca15, 1969Va16, 1971Oo01, 1971Sm02, 1972Sl03, 1973La01, + 68ZN3C 1977Kr17, 1983Iw02, 1992Sy**, 1994Vo15, 1994Sc44, 2003Au03, 2012Lu14 + 68ZN T Auger electrons and X ray energies and emission intensities: + 68ZN T {U Energy (keV)} {U Intensity} {U Line} + 68ZN T + 68ZN T 8.61587 1.42 6 XKA2 + 68ZN T 8.63896 2.76 11 XKA1 + 68ZN T + 68ZN T 9.5721 |] 0.593 24 XKB1 + 68ZN T 9.6499 |] XKB5II + 68ZN T + 68ZN T + 68ZN T 0.884-1.186 0.146 4 XL (total) + 68ZN T 0.884 0.00421 16 XLL + 68ZN T 1.012-1.012 0.0807 28 XLA + 68ZN T 0.906 0.00273 11 XLC + 68ZN T 1.02-1.186 0.0584 23 XLB + 68ZN T 1.043-1.043 0.00019014 XLG + 68ZN T + 68ZN T 7.21-7.55 |] KLL AUGER + 68ZN T 8.31-8.63 |] 5.05 20 KLX AUGER + 68ZN T 9.39-9.65 |] KXY AUGER + 68ZN T 0.732-0.997 13.98 19 L AUGER + 68GA P 0.0 1+ 67.83 M 20 2921.1 12 + 68ZN N 1.0 1.0 1 1.0 + 68ZN L 0 0+ STABLE + 68ZN E 87.68 418.94 415.2 + 68ZN2 E EAV=836.0 6$CK=0.08186 14$CL=0.00907 11$CM=0.001499 37 + 68ZN3 E CN=0.000102 9 + 68ZN L 1077.35 5 2+ 1.57 PS 4 + 68ZN E 1.20 41.80 55.5 + 68ZN2 E EAV=352.6 6$CK=0.5306 9$CL=0.0590 8$CM=0.00972 30 + 68ZN G 1077.34 5 3.235 30E2 2.47E-4 4 + 68ZN2 G KC=0.000221 4$LC=2.22E-5 4$MC=3.18E-6 5$NC=1.273E-7 18 + 68ZN L 1655.87 140+ 70 PS 35 + 68ZN E 0.00026 20.0335 236.9 + 68ZN2 E EAV=107.6 6$CK=0.8771 15$CL=0.0978 14$CM=0.01617 50 + 68ZN G 578.52 130.0343 23E2 1272E-618 + 68ZN2 G KC=0.001139 16$LC=1.160E-4 17$MC=1.66E-5 3$NC=6.5E-7 1 + 68ZN G 1655.87 14 E0 + 68ZN L 1883.19 6 2+ 1.6 PS 3 + 68ZN E 0.234 55.9 + 68ZN2 E CK=0.8836 15$CL=0.0989 14$CM=0.0164 5 + 68ZN G 227.31 150.00012049E2 0.0300 5 + 68ZN2 G KC=0.0268 4$LC=0.00286 4$MC=0.000406 6$NC=1.476E-5 21 + 68ZN G 805.83 8 0.0928 27M1+E2 -1.53 5 4.70E-4 7 + 68ZN2 G KC=0.000421 6$LC=4.24E-5 7$MC=6.07E-6 9$NC=2.42E-7 4 + 68ZN G 1883.16 6 0.1420 35E2 3.33E-4 5 + 68ZN2 G KC=6.97E-5 10$LC=6.91E-6 10$MC=9.9E-7 2$NC=4.01E-8 6 + 68ZN L 2338.44 8 2+ 0.24 PS + 68ZN E 0.096 35.7 + 68ZN2 E CK=0.8823 16$CL=0.1000 15$CM=0.0166 5 + 68ZN G 682.57 160.00031420E2 7.89E-411 + 68ZN2 G KC=0.000707 10$LC=7.16E-5 10$MC=1.03E-5 2$NC=4.05E-7 6 + 68ZN G 1261.08 9 0.0954 21M1+E2 -0.15 2 1725E-725 + 68ZN2 G KC=1.418E-4 20$LC=1.409E-5 20$MC=2.02E-6 3$NC=8.19E-8 12 + 68ZN G 2338.44 8 0.00113 16E2 5.29E-4 8 + 68ZN2 G KC=4.71E-5 7$LC=4.67E-6 7$MC=6.7E-7 1$NC=2.71E-8 4 + 68ZN L 2821.79 142+ + 68ZN E 0.0104 55.1 + 68ZN2 E CK=0.8653 18$CL=0.1141 17$CM=0.0192 5 + 68ZN G 483.35 160.00026529M1+E2 1.0 5 0.0017 3 + 68ZN2 G KC=0.0015 3$LC=0.00016 3$MC=0.000022 4$NC=8.7E-7 15 + 68ZN G 938.61 200.00017816M1+E2 -0.7 3 3.04E-412 + 68ZN2 G KC=0.000272 11$LC=2.72E-5 11$MC=3.9E-6 2$NC=1.57E-7 6 + 68ZN G 1165.92 150.00001610E2 2.11E-4 3 + 68ZN2 G KC=0.000185 3$LC=1.85E-5 3$MC=2.65E-6 4$NC=1.065E-7 15 + 68ZN G 1744.42 130.0096 5M1+E2 0.272 18 2.41E-4 4 + 68ZN2 G KC=7.70E-5 11$LC=7.63E-6 11$MC=1.09E-6 2$NC=4.44E-8 7 + 68ZN G 2821.73 140.00046636E2 7.40E-411 + 68ZN2 G KC=3.43E-5 5$LC=3.39E-6 5$MC=4.86E-7 7$NC=1.97E-8 3 + diff --git a/HEN_HOUSE/spectra/lnhb/Gd-153.txt b/HEN_HOUSE/spectra/lnhb/Gd-153.txt index d2cbf10f7..a393f89ae 100644 --- a/HEN_HOUSE/spectra/lnhb/Gd-153.txt +++ b/HEN_HOUSE/spectra/lnhb/Gd-153.txt @@ -1,66 +1,74 @@ -153EU 153GD EC DECAY (240.4 D) -153EU H TYP=Update$AUT=M.M. Bé$CUT=15-NOV-2011$ -153EU2 H TYP=Full$AUT=R.G. Helmer$CUT=30-JUN-2001$ -153EU C Evaluation history: Type=Update;Author=M.M. Bé;Cutoff date=15-NOV-2011 -153EU2C Type=Full;Author=R.G. Helmer;Cutoff date=30-JUN-2001 -153EU C References: 2002Ba85, 2008Ki07 -153EU T Auger electrons and X ray energies and emission intensities: -153EU T {U Energy (keV)} {U Intensity} {U Line} -153EU T -153EU T 40.9024 34.2 9 XKA2 -153EU T 41.5427 61.7 16 XKA1 -153EU T -153EU T 46.904 |] XKB3 -153EU T 47.0384 |] 19.4 6 XKB1 -153EU T 47.373 |] XKB5II -153EU T -153EU T 48.257 |] XKB2 -153EU T 48.386 |] 5.01 17 XKB4 -153EU T 48.497 |] XKO23 -153EU T -153EU T 5.1751-7.791 20.1 5 XL (total) -153EU T 5.1751 0.413 14 XLL -153EU T 5.815-5.8461 10.07 30 XLA -153EU T 5.8149 0.156 5 XLC -153EU T 6.4365-6.9193 8.24 20 XLB -153EU T 7.2538-7.791 1.27 4 XLG -153EU T -153EU T 32.25-34.38 |] KLL AUGER -153EU T 38.59-41.27 |] 9.2 6 KLX AUGER -153EU T 44.9-48.2 |] KXY AUGER -153EU T 3.4-7.8 98.4 9 L AUGER -153GD P 0.0 3/2- 240.4 D 10 484.0 7 -153EU N 1.0 1.0 1 1.0 -153EU L 0 5/2+ STABLE -153EU E 4 38.9 1 -153EU2 E CK=0.8192 17$CL=0.1392 15$CM=0.0324 8 -153EU L 83.36720 177/2+ 0.77 NS -153EU E 0.05 7 1U -153EU G 83.36717 210.197 7M1+E2 0.81 4 3.76 7 -153EU2 G KC=2.33 4$LC=1.11 5$MC=0.257 12 -153EU L 97.43103 175/2- 0.18 NS -153EU E 38.0 117.7 -153EU2 E CK=0.8116 18$CL=0.1448 16$CM=0.034 8 -153EU G 14.06383 200.020 5E1 10.89 16 -153EU2 G LC=8.54 12$MC=1.90 3 -153EU G 97.43100 2129.0 8E1 0.305 5 -153EU2 G KC=0.256 4$LC=0.0382 6$MC=0.00823 12 -153EU L 103.18016 133/2+ 3.88 NS -153EU E 42.0 187.7 -153EU2 E CK=0.8111 18$CL=0.1452 16$CM=0.0341 8 -153EU G 19.81296 190.00014 E2 3220 50 -153EU2 G LC=2490 40$MC=578 8 -153EU G 103.18012 1721.1 6M1+E2 0.119 3 1.694 24 -153EU2 G KC=1.422 20$LC=0.213 3$MC=0.0462 7 -153EU L 172.85320 135/2+ -153EU E 15.7 67.9 1 -153EU2 E CK=0.8019 19$CL=0.1519 4$CM=0.0359 9 -153EU G 69.67300 132.42 7M1+E2 0.136 4 5.31 8 -153EU2 G KC=4.39 7$LC=0.719 12$MC=0.1572 25 -153EU G 75.42213 230.078 3E1+M2 0.055 10 0.76 7 -153EU2 G KC=0.62 5$LC=0.112 13$MC=0.025 3 -153EU G 89.48595 220.069 5M1+E2 0.25 10 2.60 7 -153EU2 G KC=2.11 5$LC=0.38 7$MC=0.085 16 -153EU G 172.85307 210.036 2M1+E2 0.81 8 0.377 6 -153EU2 G KC=0.296 7$LC=0.0637 22$MC=0.0142 6 - +153EU 153GD EC DECAY (240.4 D) +153EU H TYP=UPD$AUT=M.-M.BE$CUT=15-NOV-2011$ +153EU2 H TYP=FUL$AUT=R.G.HELMER$CUT=30-JUN-2001$ +153EU C References:2002Ba85, 2008Ki07, 2011Au** +153EU T Auger electrons and X ray energies and emission intensities: +153EU T {U Energy (keV)} {U Intensity} {U Line} +153EU T +153EU T 40.9024 34.2 9 XKA2 +153EU T 41.5427 61.7 16 XKA1 +153EU T +153EU T 46.904 |] XKB3 +153EU T 47.0384 |] 19.4 6 XKB1 +153EU T 47.373 |] XKB5II +153EU T +153EU T 48.257 |] XKB2 +153EU T 48.386 |] 5.01 17 XKB4 +153EU T 48.497 |] XKO23 +153EU T +153EU T 5.1751-7.791 20.1 5 XL (total) +153EU T 5.1751 0.413 14 XLL +153EU T 5.815-5.8461 10.07 30 XLA +153EU T 5.8149 0.156 5 XLC +153EU T 6.4365-6.9193 8.24 20 XLB +153EU T 7.2538-7.791 1.27 4 XLG +153EU T +153EU T 32.25-34.38 |] KLL AUGER +153EU T 38.59-41.27 |] 9.2 6 KLX AUGER +153EU T 44.9-48.2 |] KXY AUGER +153EU T 3.4-7.8 98.4 9 L AUGER +153GD P 0.0 3/2- 240.4 D 10 484.0 7 +153EU N 1.0 1.0 1 1.0 +153EU L 0 5/2+ STABLE +153EU E 4 38.9 1 +153EU2 E CK=0.8192 17$CL=0.1392 15$CM=0.0324 8 +153EU L 83.36720 177/2+ 0.77 NS +153EU E 0.05 7 1U +153EU2 E CK=0.8139 17$CL=0.1440 12$CM=0.0337 6$CN=0.0084 4 +153EU G 83.36717 210.197 7M1+E2 0.81 4 3.76 7 +153EU2 G KC=2.33 4$LC=1.11 5$MC=0.257 12$NC=0.0573 25 +153EU3 G OC=0.0080 4 +153EU L 97.43103 175/2- 0.18 NS +153EU E 38.0 117.7 +153EU2 E CK=0.8116 18$CL=0.1448 16$CM=0.034 8 +153EU G 14.06383 200.020 5E1 10.89 16 +153EU2 G LC=8.54 12$MC=1.90 3$NC=0.405 6 +153EU3 G OC=0.0479 7 +153EU G 97.43100 2129.0 8E1 0.305 5 +153EU2 G KC=0.256 4$LC=0.0382 6$MC=0.00823 12$NC=0.00185 3 +153EU3 G OC=0.000278 4 +153EU L 103.18016 133/2+ 3.88 NS +153EU E 42.0 187.7 +153EU2 E CK=0.8111 18$CL=0.1452 16$CM=0.0341 8 +153EU G 19.81296 190.00014 E2 3220 50 +153EU2 G LC=2490 40$MC=578 8$NC=127.1 18 +153EU3 G OC=16.73 24 +153EU G 103.18012 1721.1 6M1+E2 0.119 3 1.694 24 +153EU2 G KC=1.422 20$LC=0.213 3$MC=0.0462 7$NC=0.01057 15 +153EU3 G OC=0.001662 24 +153EU L 172.85320 135/2+ +153EU E 15.7 67.9 1 +153EU2 E CK=0.8019 19$CL=0.1519 4$CM=0.0359 9 +153EU G 69.67300 132.42 7M1+E2 0.136 4 5.31 8 +153EU2 G KC=4.39 7$LC=0.719 12$MC=0.1572 25$NC=0.0358 6 +153EU3 G OC=0.00555 9 +153EU G 75.42213 230.078 3E1+M2 0.055 10 0.76 7 +153EU2 G KC=0.62 5$LC=0.112 13$MC=0.025 3$NC=0.0056 7 +153EU3 G OC=0.00083 11 +153EU G 89.48595 220.069 5M1+E2 0.25 10 2.60 7 +153EU2 G KC=2.11 5$LC=0.38 7$MC=0.085 16$NC=0.019 4 +153EU3 G OC=0.0029 5 +153EU G 172.85307 210.036 2M1+E2 0.81 8 0.377 6 +153EU2 G KC=0.296 7$LC=0.0637 22$MC=0.0142 6$NC=0.00321 12 +153EU3 G OC=0.000477 15 + diff --git a/HEN_HOUSE/spectra/lnhb/Gd-159.txt b/HEN_HOUSE/spectra/lnhb/Gd-159.txt index 555096410..36912032e 100644 --- a/HEN_HOUSE/spectra/lnhb/Gd-159.txt +++ b/HEN_HOUSE/spectra/lnhb/Gd-159.txt @@ -1,95 +1,93 @@ -159TB 159GD B- DECAY (18.479 H) -159TB H TYP=Update$AUT=M.M.Bé$CUT= -- $ -159TB2 H TYP=Full$AUT=R.G.Helmer$CUT=30-APR-2004$ -159TB C Evaluation history: Type=Update;Author=M.M.Bé;Cutoff date= -- -159TB2C Type=Full;Author=R.G.Helmer;Cutoff date=30-APR-2004 -159TB T Auger electrons and X ray energies and emission intensities: -159TB T {U Energy (keV)} {U Intensity} {U Line} -159TB T -159TB T 43.7447 6.09 25 XKA2 -159TB T 44.4821 10.9 5 XKA1 -159TB T -159TB T 50.23 |] XKB3 -159TB T 50.383 |] 3.49 15 XKB1 -159TB T -159TB T 51.724 |] XKB2 -159TB T 51.849 |] 0.90 5 XKB4 -159TB T -159TB T -159TB T 34.398-36.773 |] KLL AUGER -159TB T 41.243-44.456 |] 1.49 11 KLX AUGER -159TB T 48.06-51.95 |] KXY AUGER -159TB T 3.58-8.7 0.195 5 L AUGER -159GD P 0.0 3/2- 18.479 H 7 970.5 7 -159TB N 1.0 1.0 1 1.0 -159TB L 0 3/2+ STABLE -159TB B 970.5 7 57.8 12 6.73 -159TBS B EAV=326.9 3 -159TB L 57.9963 145/2+ 53.6 PS 14 -159TB B 912.5 7 29.6 12 6.99 1 -159TBS B EAV=304.1 3 -159TB G 58.0000 222.49 7M1+E2 0.119 2 11.1 3 -159TB2 G KC=9.14 27$LC=1.55 5$MC=0.343 10 -159TB L 137.5054 177/2+ 41.4 PS 23 -159TB B 833.0 7 0.012 9 10.6 1U -159TBS B EAV=283.9 3 -159TB G 79.5132 270.0468 11M1+E2 0.126 8 4.41 13 -159TB2 G KC=3.66 11$LC=0.584 18$MC=0.129 4 -159TB G 137.515 5 0.00648 15[E2] 0.833 25 -159TB2 G KC=0.474 14$LC=0.277 8$MC=0.0653 19 -159TB L 348.2830 155/2+ -159TB B 622.2 7 0.315 4 8.39 1 -159TBS B EAV=194.5 3 -159TB G 210.783 3 0.0200 14[M1E2] 0.23 7 -159TB2 G KC=0.18 3$LC=0.039 7$MC=0.0089 16 -159TB G 290.2865 250.0323 5[M1E2] 0.093 29 -159TB2 G KC=0.075 23$LC=0.014 1$MC=0.0031 1 -159TB G 348.2807 180.2393 25M1+E2 0.43 0.067 2 -159TB2 G KC=0.056 2$LC=0.0084 3$MC=0.00180 5 -159TB L 363.5451 145/2- 15.2 PS 5 -159TB B 607.0 7 12.19 6 6.76 -159TBS B EAV=189.0 3 -159TB G 226.0406 180.2170 21E1 0.0343 10 -159TB2 G KC=0.0290 9$LC=0.00414 12$MC=0.00089 3 -159TB G 305.5492 200.0620 7E1 0.0159 5 -159TB2 G KC=0.0135 4$LC=0.00189 6$MC=4.11E-4 12 -159TB G 363.5430 1811.78 5E1 0.0104 3 -159TB2 G KC=0.00882 26$LC=0.00123 4$MC=2.66E-4 8 -159TB L 580.808 6 1/2+ 0.76 PS 10 -159TB B 389.7 7 0.0626 8 8.41 1 -159TBS B EAV=113.8 2 -159TB G 580.808 6 0.0693 7[M1E2] 0.015 5 -159TB2 G KC=0.012 4$LC=0.0018 6 -159TB L 617.619 5 3/2+ -159TB B 352.9 7 0.0300 9 8.58 -159TBS B EAV=101.84 23 -159TB G 559.623 6 0.0221 6M1+E2 0.67 0.019 3 -159TB2 G KC=0.0152 5$LC=0.0022 2$MC=0.00040 9 -159TB G 617.615 8 0.0159 5(M1) 0.0166 5 -159TB2 G KC=0.0141 4$LC=0.00196 6$MC=0.00043 2 -159TB L 674.235 175/2+ -159TB B 296.3 7 0.00388 10 9.22 1 -159TBS B EAV=83.82 22 -159TB G 536.730 120.00160 5M1+E2 0.0236 7 -159TB2 G KC=0.0200 6$LC=0.00280 8$MC=0.00061 2 -159TB G 616.233 180.00188 8(M1) 0.0167 5 -159TB2 G KC=0.0142 4$LC=0.00197 6$MC=0.00042 2 -159TB G 674.26 5 0.00031622(M1) 0.0133 4 -159TB2 G KC=0.0113 3$LC=0.00157 5$MC=0.00034 1 -159TB L 854.960 7 (1/2)- -159TB B 115.5 7 0.0162 5 7.31 -159TBS B EAV=30.43 20 -159TB G 237.341 5 0.00769 16[E1] 0.0302 9 -159TB2 G KC=0.0256 8$LC=0.00364 11$MC=0.00079 2 -159TB G 274.163 190.0057 4[E1] 0.0209 6 -159TB2 G KC=0.0177 5$LC=0.00250 8$MC=0.00054 2 -159TB G 854.947 200.00246 14[E1] 0.00162 5 -159TB2 G KC=0.00138 4$LC=1.83E-4 5$MC=4.0E-5 1 -159TB L 891.25 6 (5/2)- -159TB B 79.3 7 0.0009 4 8.08 -159TBS B EAV=20.54 19 -159TB G 273.62 120.0007 4[E1] 0.0210 6 -159TB2 G KC=0.0178 5$LC=0.00251 8$MC=0.00055 2 -159TB G 753.74 6 0.00018 2[E1] 0.00207 6 -159TB2 G KC=0.00177 5$LC=2.36E-4 7$MC=5.1E-5 2 - +159TB 159GD B- DECAY (18.479 H) +159TB H TYP=UPD$AUT=M.-M.BE$CUT=31-AUG-2006$ +159TB2 H TYP=FUL$AUT=R.G.HELMER$CUT=30-APR-2004$ +159TB T Auger electrons and X ray energies and emission intensities: +159TB T {U Energy (keV)} {U Intensity} {U Line} +159TB T +159TB T 43.7447 6.09 25 XKA2 +159TB T 44.4821 10.9 5 XKA1 +159TB T +159TB T 50.23 |] XKB3 +159TB T 50.383 |] 3.49 15 XKB1 +159TB T +159TB T 51.724 |] XKB2 +159TB T 51.849 |] 0.90 5 XKB4 +159TB T +159TB T +159TB T 34.398-36.773 |] KLL AUGER +159TB T 41.243-44.456 |] 1.49 11 KLX AUGER +159TB T 48.06-51.95 |] KXY AUGER +159TB T 3.58-8.7 0.195 5 L AUGER +159GD P 0.0 3/2- 18.479 H 7 970.5 7 +159TB N 1.0 1.0 1 1.0 +159TB L 0 3/2+ STABLE +159TB B 970.5 7 57.8 12 6.73 +159TBS B EAV=326.9 3 +159TB L 57.9963 145/2+ 53.6 PS 14 +159TB B 912.5 7 29.6 12 6.99 1 +159TBS B EAV=304.1 3 +159TB G 58.0000 222.49 7M1+E2 0.119 2 11.1 3 +159TB2 G KC=9.14 27$LC=1.55 5$MC=0.343 10$NC=0.094 3 +159TB L 137.5054 177/2+ 41.4 PS 23 +159TB B 833.0 7 0.012 9 10.6 1U +159TBS B EAV=283.9 3 +159TB G 79.5132 270.0468 11M1+E2 0.126 8 4.41 13 +159TB2 G KC=3.66 11$LC=0.584 18$MC=0.129 4$NC=0.0356 11 +159TB G 137.515 5 0.00648 15[E2] 0.833 25 +159TB2 G KC=0.474 14$LC=0.277 8$MC=0.0653 19$NC=0.0172 5 +159TB L 348.2830 155/2+ +159TB B 622.2 7 0.315 4 8.39 1 +159TBS B EAV=194.5 3 +159TB G 210.783 3 0.0200 14[M1,E2] 0.23 7 +159TB2 G KC=0.18 3$LC=0.039 7$MC=0.0089 16 +159TB G 290.2865 250.0323 5[M1,E2] 0.093 29 +159TB2 G KC=0.075 23$LC=0.014 1$MC=0.0031 1 +159TB G 348.2807 180.2393 25M1+E2 0.43 0.067 2 +159TB2 G KC=0.056 2$LC=0.0084 3$MC=0.00180 5 +159TB L 363.5451 145/2- 15.2 PS 5 +159TB B 607.0 7 12.19 6 6.76 +159TBS B EAV=189.0 3 +159TB G 226.0406 180.2170 21E1 0.0343 10 +159TB2 G KC=0.0290 9$LC=0.00414 12$MC=0.00089 3$NC=0.00025 1 +159TB G 305.5492 200.0620 7E1 0.0159 5 +159TB2 G KC=0.0135 4$LC=0.00189 6$MC=0.000411 12$NC=0.000113 3 +159TB G 363.5430 1811.78 5E1 0.0104 3 +159TB2 G KC=0.00882 26$LC=0.00123 4$MC=0.000266 8 +159TB L 580.808 6 1/2+ 0.76 PS 10 +159TB B 389.7 7 0.0626 8 8.41 1 +159TBS B EAV=113.8 2 +159TB G 580.808 6 0.0693 7[M1,E2] 0.015 5 +159TB2 G KC=0.012 4$LC=0.0018 6 +159TB L 617.619 5 3/2+ +159TB B 352.9 7 0.0300 9 8.58 +159TBS B EAV=101.84 23 +159TB G 559.623 6 0.0221 6M1+E2 0.67 0.019 3 +159TB2 G KC=0.0152 5$LC=0.0022 2$MC=0.00040 9 +159TB G 617.615 8 0.0159 5(M1) 0.0166 5 +159TB2 G KC=0.0141 4$LC=0.00196 6$MC=0.00043 2 +159TB L 674.235 175/2+ +159TB B 296.3 7 0.00388 10 9.22 1 +159TBS B EAV=83.82 22 +159TB G 536.730 120.00160 5M1+E2 0.0236 7 +159TB2 G KC=0.0200 6$LC=0.00280 8$MC=0.00061 2 +159TB G 616.233 180.00188 8(M1) 0.0167 5 +159TB2 G KC=0.0142 4$LC=0.00197 6$MC=0.00042 2 +159TB G 674.26 5 0.00031622(M1) 0.0133 4 +159TB2 G KC=0.0113 3$LC=0.00157 5$MC=0.00034 1 +159TB L 854.960 7 (1/2)- +159TB B 115.5 7 0.0162 5 7.31 +159TBS B EAV=30.43 20 +159TB G 237.341 5 0.00769 16[E1] 0.0302 9 +159TB2 G KC=0.0256 8$LC=0.00364 11$MC=0.00079 2 +159TB G 274.163 190.0057 4[E1] 0.0209 6 +159TB2 G KC=0.0177 5$LC=0.00250 8$MC=0.00054 2 +159TB G 854.947 200.00246 14[E1] 0.00162 5 +159TB2 G KC=0.00138 4$LC=0.000183 5$MC=0.000040 1 +159TB L 891.25 6 (5/2)- +159TB B 79.3 7 0.0009 4 8.08 +159TBS B EAV=20.54 19 +159TB G 273.62 120.0007 4[E1] 0.0210 6 +159TB2 G KC=0.0178 5$LC=0.00251 8$MC=0.00055 2 +159TB G 753.74 6 0.00018 2[E1] 0.00207 6 +159TB2 G KC=0.00177 5$LC=0.000236 7$MC=0.000051 2 + diff --git a/HEN_HOUSE/spectra/lnhb/Ge-68.txt b/HEN_HOUSE/spectra/lnhb/Ge-68.txt index 73083e2d1..f83f0a167 100644 --- a/HEN_HOUSE/spectra/lnhb/Ge-68.txt +++ b/HEN_HOUSE/spectra/lnhb/Ge-68.txt @@ -1,37 +1,35 @@ - 68GA 68GE EC DECAY (270.95 D) - 68GA H TYP=Update$AUT=M.M Bé$CUT=30-NOV-2011$ - 68GA2 H TYP=Full$AUT=E.Schönfeld$CUT= -- $ - 68GA C Evaluation history: Type=Update;Author=M.M Bé;Cutoff date=30-NOV-2011 - 68GA2C Type=Full;Author=E.Schönfeld;Cutoff date= -- - 68GA C References: 1950Ho26, 1956Ru45, 1956Cr25, 1981Wa26, 1994Sc44, 2002Bu29, - 68GA2C 2003Au03 - 68GA T Auger electrons and X ray energies and emission intensities: - 68GA T {U Energy (keV)} {U Intensity} {U Line} - 68GA T - 68GA T 9.22495 13.25 13 XKA2 - 68GA T 9.25184 25.74 22 XKA1 - 68GA T - 68GA T 10.2605 |] XKB3 - 68GA T 10.2644 |] 5.65 7 XKB1 - 68GA T 10.348 |] XKB5II - 68GA T - 68GA T 10.3664 |] XKB2 - 68GA T |] 0.034 9 XKB4 - 68GA T - 68GA T 0.959-1.303 1.490 24 XL (total) - 68GA T 0.959 0.0414 10 XLL - 68GA T 1.098-1.099 0.851 18 XLA - 68GA T 0.985 0.0244 7 XLC - 68GA T 1.114-1.283 0.571 16 XLB - 68GA T 1.141-1.303 0.00211 13 XLG - 68GA T - 68GA T 7.708-8.069 |] KLL AUGER - 68GA T 8.889-9.251 |] 41.7 4 KLX AUGER - 68GA T 10.051-10.366 |] KXY AUGER - 68GA T 0.8-1.3 121.8 7 L AUGER - 68GE P 0.0 0+ 270.95 D 26 106.9 24 - 68GA N 1.0 1.0 1 1.0 - 68GA L 0 1+ 67.83 M 20 - 68GA E 100 5.006 - 68GA2 E CK=0.8639 24$CL=0.1150 23$CM=0.0196 5$CN=0.0015 2$CO=0 0 - + 68GA 68GE EC DECAY (270.95 D) + 68GA H TYP=UPD$AUT=M.-M.BE$CUT=30-NOV-2011$ + 68GA2 H TYP=FUL$AUT=E.SCHONFELD$CUT=15-JAN-1998$ + 68GA C References:1950Ho26, 1956Ru45, 1956Cr25, 1981Wa26, 1994Sc44, 2002Bu29, + 68GA2C 2003Au03 + 68GA T Auger electrons and X ray energies and emission intensities: + 68GA T {U Energy (keV)} {U Intensity} {U Line} + 68GA T + 68GA T 9.22495 13.25 13 XKA2 + 68GA T 9.25184 25.74 22 XKA1 + 68GA T + 68GA T 10.2605 |] XKB3 + 68GA T 10.2644 |] 5.65 7 XKB1 + 68GA T 10.348 |] XKB5II + 68GA T + 68GA T 10.3664 |] XKB2 + 68GA T |] 0.034 9 XKB4 + 68GA T + 68GA T 0.959-1.303 1.490 24 XL (total) + 68GA T 0.959 0.0414 10 XLL + 68GA T 1.098-1.099 0.851 18 XLA + 68GA T 0.985 0.0244 7 XLC + 68GA T 1.114-1.283 0.571 16 XLB + 68GA T 1.141-1.303 0.00211 13 XLG + 68GA T + 68GA T 7.708-8.069 |] KLL AUGER + 68GA T 8.889-9.251 |] 41.7 4 KLX AUGER + 68GA T 10.051-10.366 |] KXY AUGER + 68GA T 0.8-1.3 121.8 7 L AUGER + 68GE P 0.0 0+ 270.95 D 26 106.9 24 + 68GA N 1.0 1.0 1 1.0 + 68GA L 0 1+ 67.83 M 20 + 68GA E 100 5.006 + 68GA2 E CK=0.8639 24$CL=0.1150 23$CM=0.0196 5$CN=0.0015 2 + diff --git a/HEN_HOUSE/spectra/lnhb/H-3.txt b/HEN_HOUSE/spectra/lnhb/H-3.txt index 17e9caf0b..a608d8b73 100644 --- a/HEN_HOUSE/spectra/lnhb/H-3.txt +++ b/HEN_HOUSE/spectra/lnhb/H-3.txt @@ -1,13 +1,11 @@ - 3HE 3H B- DECAY (12.312 Y) - 3HE H TYP=Full$AUT=V. Chechev$CUT=01-JUN-1998$ - 3HE2 H TYP=Update$AUT=V. Chechev$CUT=01-MAY-1998$ - 3HE C Evaluation history: Type=Full;Author=V. Chechev;Cutoff date=01-JUN-1998 - 3HE2C Type=Update;Author=V. Chechev;Cutoff date=01-MAY-1998 - 3HE C References: 2000Lu17, 2002Bo31, 2003Lo10, 2003Au03, 2004Ak16, 2005Ak04, - 3HE2C 2005Kr03 - 3H P 0.0 1/2+ 12.312 Y 25 18.591 1 - 3HE N 1.0 1.0 1 1.0 - 3HE L 0 1/2+ STABLE - 3HE B 18.564 2 100 3.05 - 3HES B EAV=5.68 1 - + 3HE 3H B- DECAY (12.312 Y) + 3HE H TYP=FUL$AUT=V.P.CHECHEV$CUT=01-JUN-1998$ + 3HE2 H TYP=UPD$AUT=V.P.CHECHEV$CUT=01-MAY-1998$ + 3HE C References:1999BeZQ, 2000Lu17, 2002Bo31, 2003Lo10, 2003Au03, 2004Ak16, + 3HE2C 2005Ak04, 2005Kr03 + 3H P 0.0 1/2+ 12.312 Y 25 18.591 1 + 3HE N 1.0 1.0 1 1.0 + 3HE L 0 1/2+ STABLE + 3HE B 18.564 2 100 3.05 + 3HES B EAV=5.68 1 + diff --git a/HEN_HOUSE/spectra/lnhb/Hg-203.txt b/HEN_HOUSE/spectra/lnhb/Hg-203.txt index 600c1c5e5..7fccbe4d9 100644 --- a/HEN_HOUSE/spectra/lnhb/Hg-203.txt +++ b/HEN_HOUSE/spectra/lnhb/Hg-203.txt @@ -1,37 +1,37 @@ -203TL 203HG B- DECAY (46.594 D) -203TL T Auger electrons and X ray energies and emission intensities: -203TL T {U Energy (keV)} {U Intensity} {U Line} -203TL T -203TL T 70.8325 3.75 4 XKA2 -203TL T 72.8725 6.33 6 XKA1 -203TL T -203TL T 82.118 |] XKB3 -203TL T 82.577 |] 2.15 4 XKB1 -203TL T 83.115 |] XKB5II -203TL T -203TL T 84.838 |] XKB2 -203TL T 85.134 |] 0.639 16 XKB4 -203TL T 85.444 |] XKO23 -203TL T -203TL T 8.953-14.738 5.43 9 XL (total) -203TL T 8.953 0.126 4 XLL -203TL T 10.172-10.268 2.43 7 XLA -203TL T 10.994 0.0457 12 XLC -203TL T 11.812-12.643 2.37 7 XLB -203TL T 14.291-14.738 0.435 11 XLG -203TL T -203TL T 54.587-59.954 |] KLL AUGER -203TL T 66.37-72.86 |] 0.49 6 KLX AUGER -203TL T 78.12-85.5 |] KXY AUGER -203TL T 5.18-15.31 10.1 1 L AUGER -203HG P 0.0 5/2- 46.594 D 12 491.8 12 -203TL N 1.0 1.0 1 1.0 -203TL L 0 1/2+ STABLE -203TL B 491.8 120.01 1 11.6 1U -203TLS B EAV=154.4 4 -203TL L 279.1969 123/2+ -203TL B 212.6 1299.99 1 6.455 1 -203TLS B EAV=57.8 4 -203TL G 279.1952 1081.48 8M1+E2 1.73 50 0.2271 12 -203TL2 G KC=0.1640 1$LC=0.0476 2$MC=0.0155 2 - +203TL 203HG B- DECAY (46.594 D) +203TL T Auger electrons and X ray energies and emission intensities: +203TL T {U Energy (keV)} {U Intensity} {U Line} +203TL T +203TL T 70.8325 3.75 4 XKA2 +203TL T 72.8725 6.33 6 XKA1 +203TL T +203TL T 82.118 |] XKB3 +203TL T 82.577 |] 2.15 4 XKB1 +203TL T 83.115 |] XKB5II +203TL T +203TL T 84.838 |] XKB2 +203TL T 85.134 |] 0.639 16 XKB4 +203TL T 85.444 |] XKO23 +203TL T +203TL T 8.953-14.738 5.43 9 XL (total) +203TL T 8.953 0.126 4 XLL +203TL T 10.172-10.268 2.43 7 XLA +203TL T 10.994 0.0457 12 XLC +203TL T 11.812-12.643 2.37 7 XLB +203TL T 14.291-14.738 0.435 11 XLG +203TL T +203TL T 54.587-59.954 |] KLL AUGER +203TL T 66.37-72.86 |] 0.49 6 KLX AUGER +203TL T 78.12-85.5 |] KXY AUGER +203TL T 5.18-15.31 10.1 1 L AUGER +203HG P 0.0 5/2- 46.594 D 12 491.8 12 +203TL N 1.0 1.0 1 1.0 +203TL L 0 1/2+ STABLE +203TL B 491.8 120.01 1 11.6 1U +203TLS B EAV=154.4 4 +203TL L 279.1969 123/2+ +203TL B 212.6 1299.99 1 6.455 1 +203TLS B EAV=57.8 4 +203TL G 279.1952 1081.48 8M1+E2 1.73 50 0.2271 12 +203TL2 G KC=0.1640 1$LC=0.0476 2$MC=0.0155 2 + diff --git a/HEN_HOUSE/spectra/lnhb/Hg-206.txt b/HEN_HOUSE/spectra/lnhb/Hg-206.txt index 133dbb61d..95e862a3d 100644 --- a/HEN_HOUSE/spectra/lnhb/Hg-206.txt +++ b/HEN_HOUSE/spectra/lnhb/Hg-206.txt @@ -1,55 +1,59 @@ -206TL 206HG B- DECAY (8.32 M) -206TL H TYP=Full$AUT=F. Kondev$CUT=31-DEC-2010$ -206TL C Evaluation history: Type=Full;Author=F. Kondev;Cutoff date=31-DEC-2010 -206TL C References: 1961Nu01, 1968Wo08, 1969La18, 1970As05, 1969La18, 1976TuZY, -206TL2C 1977La19, 1992Ra08, 1994Ka08, 1996Sc06, 1998Si17, 1998ScZM, 1999ScZX, -206TL3C 1999Br39, 2000Sc47, 2002Ba85, 2003Au03, 2003De44, 2004Ma11, 2008Ki07, -206TL4C 2008Ko21, 2008DuZX -206TL T Auger electrons and X ray energies and emission intensities: -206TL T {U Energy (keV)} {U Intensity} {U Line} -206TL T -206TL T 70.8325 2.3 5 XKA2 -206TL T 72.8725 3.9 8 XKA1 -206TL T -206TL T 82.118 |] XKB3 -206TL T 82.577 |] 1.32 25 XKB1 -206TL T 83.115 |] XKB5II -206TL T -206TL T 84.838 |] XKB2 -206TL T 85.134 |] 0.39 8 XKB4 -206TL T 85.444 |] XKO23 -206TL T -206TL T 8.9531-14.7362 2.9 4 XL (total) -206TL T 8.9531 0.072 11 XLL -206TL T 10.1718-10.2679 1.39 19 XLA -206TL T 10.9942 0.022 4 XLC -206TL T 11.8117-12.9566 1.23 15 XLB -206TL T 13.8528-14.7362 0.23 3 XLG -206TL T -206TL T 54.587-59.954 |] KLL AUGER -206TL T 66.37-72.86 |] 0.30 7 KLX AUGER -206TL T 78.12-85.5 |] KXY AUGER -206TL T 5.25-15.32 5.1 4 L AUGER -206HG P 0.0 0+ 8.32 M 7 1308 20 -206TL N 1.0 1.0 1 1.0 -206TL L 0 0 0- STABLE -206TL B 1308 2062 7 5.67 -206TLS B EAV=450 8 -206TL L 265.832 5 2- 2.29 NS 14 -206TL G 265.832 5 0.012 6E2 0.1603 23 -206TL2 G KC=0.0855 12$LC=0.0561 8$MC=0.01440 21 -206TL L 304.896 6 1- 4.2 PS 14 -206TL B 1003 2035 7 5.24 1 -206TLS B EAV=330 8 -206TL G 304.896 6 26 5M1 0.375 6 -206TL2 G KC=0.308 5$LC=0.0519 8$MC=0.01211 17 -206TL L 649.42 4 1- -206TL B 659 203.0 4 5.41 1 -206TLS B EAV=203 7 -206TL G 344.52 170.55 11M1 0.269 4 -206TL2 G KC=0.221 4$LC=0.0371 6$MC=0.00866 13 -206TL G 383.59 6 0.012 6M1(+E2) 0.13 8 -206TL2 G KC=0.10 7$LC=0.021 7$MC=0.0050 15 -206TL G 649.42 5 2.2 3M1 0.0501 7 -206TL2 G KC=0.0412 6$LC=0.00681 10$MC=1585E-6 23 - +206TL 206HG B- DECAY (8.32 M) +206TL H TYP=FUL$AUT=F.G.KONDEV$CUT=31-DEC-2010$ +206TL C References:1961Nu01, 1968Wo08, 1969La18, 1970As05, 1969La18, 1976TuZY, +206TL2C 1977La19, 1992Ra08, 1994Ka08, 1996Sc06, 1998Si17, 1998ScZM, 1999ScZX, +206TL3C 1999Br39, 2000Sc47, 2002Ba85, 2003Au03, 2003De44, 2004Ma11, 2008Ki07, +206TL4C 2008Ko21, 2008DuZX +206TL T Auger electrons and X ray energies and emission intensities: +206TL T {U Energy (keV)} {U Intensity} {U Line} +206TL T +206TL T 70.8325 2.3 5 XKA2 +206TL T 72.8725 3.9 8 XKA1 +206TL T +206TL T 82.118 |] XKB3 +206TL T 82.577 |] 1.32 25 XKB1 +206TL T 83.115 |] XKB5II +206TL T +206TL T 84.838 |] XKB2 +206TL T 85.134 |] 0.39 8 XKB4 +206TL T 85.444 |] XKO23 +206TL T +206TL T 8.9531-14.7362 2.9 4 XL (total) +206TL T 8.9531 0.072 11 XLL +206TL T 10.1718-10.2679 1.39 19 XLA +206TL T 10.9942 0.022 4 XLC +206TL T 11.8117-12.9566 1.23 15 XLB +206TL T 13.8528-14.7362 0.23 3 XLG +206TL T +206TL T 54.587-59.954 |] KLL AUGER +206TL T 66.37-72.86 |] 0.30 7 KLX AUGER +206TL T 78.12-85.5 |] KXY AUGER +206TL T 5.25-15.32 5.1 4 L AUGER +206HG P 0.0 0+ 8.32 M 7 1308 20 +206TL N 1.0 1.0 1 1.0 +206TL L 0 0- STABLE +206TL B 1308 2062 7 5.67 +206TLS B EAV=450 8 +206TL L 265.832 5 2- 2.29 NS 14 +206TL G 265.832 5 0.012 6E2 0.1603 23 +206TL2 G KC=0.0855 12$LC=0.0561 8$MC=0.01440 21$NC=0.00361 5 +206TL3 G OC=0.000639 9 +206TL L 304.896 6 1- 4.2 PS 14 +206TL B 1003 2035 7 5.24 1 +206TLS B EAV=330 8 +206TL G 304.896 6 26 5M1 0.375 6 +206TL2 G KC=0.308 5$LC=0.0519 8$MC=0.01211 17$NC=0.00306 5 +206TL3 G OC=0.000594 9 +206TL L 649.42 4 1- +206TL B 659 203.0 4 5.41 1 +206TLS B EAV=203 7 +206TL G 344.52 170.55 11M1 0.269 4 +206TL2 G KC=0.221 4$LC=0.0371 6$MC=0.00866 13$NC=0.00219 3 +206TL3 G OC=0.000425 6 +206TL G 383.59 6 0.012 6M1(+E2) 0.13 8 +206TL2 G KC=0.10 7$LC=0.021 7$MC=0.0050 15$NC=0.0013 4 +206TL3 G OC=0.00024 8 +206TL G 649.42 5 2.2 3M1 0.0501 7 +206TL2 G KC=0.0412 6$LC=0.00681 10$MC=0.001585 23$NC=0.000400 6 +206TL3 G OC=7.78E-5 11 + diff --git a/HEN_HOUSE/spectra/lnhb/Ho-166.txt b/HEN_HOUSE/spectra/lnhb/Ho-166.txt index 4c9fddbc6..490811cb7 100644 --- a/HEN_HOUSE/spectra/lnhb/Ho-166.txt +++ b/HEN_HOUSE/spectra/lnhb/Ho-166.txt @@ -1,82 +1,91 @@ -166ER 166HO B- DECAY (26.795 H) -166ER C References: 1977La19 -166ER T Auger electrons and X ray energies and emission intensities: -166ER T {U Energy (keV)} {U Intensity} {U Line} -166ER T -166ER T 48.2215 2.91 10 XKA2 -166ER T 49.1282 5.16 17 XKA1 -166ER T -166ER T 55.495 |] XKB3 -166ER T 55.682 |] 1.68 6 XKB1 -166ER T 56.04 |] XKB5II -166ER T -166ER T 57.21 |] XKB2 -166ER T 57.313 |] 0.436 18 XKB4 -166ER T 57.456 |] XKO23 -166ER T -166ER T 6.14-9.43 7.91 18 XL (total) -166ER T 6.14 0.151 5 XLL -166ER T 6.9-6.95 3.47 10 XLA -166ER T 7.05 0.0775 27 XLC -166ER T 7.75-8.34 3.62 11 XLB -166ER T 8.81-9.43 0.586 19 XLG -166ER T -166ER T 37.78-40.55 |] KLL AUGER -166ER T 45.52-49.1 |] 0.63 5 KLX AUGER -166ER T 53.07-57.84 |] KXY AUGER -166ER T 3.9-7.6 28.0 6 L AUGER -166HO P 0.0 0- 26.795 H 29 1854.5 9 -166ER N 1.0 1.0 1 1.0 -166ER L 0 0+ STABLE -166ER B 1854.5 9 48.2 15 8.1 -166ERS B EAV=693.8 6 -166ER L 80.5725 132+ 1.82 NS 3 -166ER B 1773.9 9 50.5 15 9 1U -166ERS B EAV=651.1 6 -166ER G 80.5725 136.55 8E2 6.90 14 -166ER2 G KC=1.65 5$LC=4.01 8$MC=0.978 20 -166ER L 264.9832 174+ 118 PS 5 -166ER G 184.4107 110.0015 7E2 0.333 10 -166ER2 G KC=0.205 6$LC=0.0984 30$MC=0.0236 7 -166ER L 785.78 7 2+ 3.26 PS 11 -166ER B 1068.6 9 0.0072 21 11.6 1U -166ERS B EAV=356 9 -166ER G 520.80 7 0.00035 2E2 0.0149 5 -166ER2 G KC=0.01192 36$LC=0.00234 7$MC=5.35E-4 16 -166ER G 705.21 7 0.0146 12E2+M1 0.0072122 -166ER2 G KC=0.00591 18$LC=1012E-6 30$MC=2.28E-4 7 -166ER G 785.78 7 0.0120 3E2 0.0056617 -166ER2 G KC=0.00467 14$LC=7.69E-4 23$MC=1.73E-4 5 -166ER L 1460.025 100+ -166ER B 394.5 9 0.955 16 7.4 -166ERS B EAV=115 3 -166ER G 674.24 7 0.0198 17E2 0.0079924 -166ER2 G KC=0.00653 20$LC=1138E-6 34$MC=2.57E-4 8 -166ER G 1379.446 100.933 35E2 0.00179 5 -166ER2 G KC=0.00151 5$LC=0.00022 1$MC=4.8E-5 2 -166ER G 1460.018 100.0002 -166ER L 1528.23 152+ -166ER B 326.2 9 0.00276 22 9.5 1U -166ERS B EAV=93 3 -166ER G 1263.24 150.0155 9E2(+M3) 0.0021 2 -166ER2 G KC=0.0018 2$LC=0.0003 1$MC=5.8E-5 2 -166ER G 1447.66 150.00105 10E2(+) 0.00163 5 -166ER2 G KC=0.00138 4$LC=1.98E-4 6$MC=4.4E-5 2 -166ER G 1528.23 150.00014 5E2 0.00147 4 -166ER2 G KC=0.00125 4$LC=1.78E-4 5 -166ER L 1662.433 151- -166ER B 192.0 9 0.304 7 6.9 -166ERS B EAV=52 1 -166ER G 1581.852 150.186 4E1+(M2) -166ER G 1662.424 150.118 5E1 -166ER L 1812.8 5 1- -166ER B 41.7 9 0.00010 3 12.1 -166ERS B EAV=13 2 -166ER G 1732.2 5 0.00004620M1(+E2) -166ER G 1812.8 5 0.00005619E1(+M2) -166ER L 1830.419 241- -166ER B 24.1 9 0.0353 11 5 -166ERS B EAV=7.1 10 -166ER G 1749.837 140.0272 10E1(+M2) -166ER G 1830.408 240.0081 2E1 - +166ER 166HO B- DECAY (26.795 H) +166ER C References:1977La19 +166ER T Auger electrons and X ray energies and emission intensities: +166ER T {U Energy (keV)} {U Intensity} {U Line} +166ER T +166ER T 48.2215 2.91 10 XKA2 +166ER T 49.1282 5.16 17 XKA1 +166ER T +166ER T 55.495 |] XKB3 +166ER T 55.682 |] 1.68 6 XKB1 +166ER T 56.04 |] XKB5II +166ER T +166ER T 57.21 |] XKB2 +166ER T 57.313 |] 0.436 18 XKB4 +166ER T 57.456 |] XKO23 +166ER T +166ER T 6.14-9.43 7.91 18 XL (total) +166ER T 6.14 0.151 5 XLL +166ER T 6.9-6.95 3.47 10 XLA +166ER T 7.05 0.0775 27 XLC +166ER T 7.75-8.34 3.62 11 XLB +166ER T 8.81-9.43 0.586 19 XLG +166ER T +166ER T 37.78-40.55 |] KLL AUGER +166ER T 45.52-49.1 |] 0.63 5 KLX AUGER +166ER T 53.07-57.84 |] KXY AUGER +166ER T 3.9-7.6 28.0 6 L AUGER +166HO P 0.0 0- 26.795 H 29 1854.5 9 +166ER N 1.0 1.0 1 1.0 +166ER L 0 0+ STABLE +166ER B 1854.5 9 48.2 15 8.1 +166ERS B EAV=693.8 6 +166ER L 80.5725 132+ 1.82 NS 3 +166ER B 1773.9 9 50.5 15 9 1U +166ERS B EAV=651.1 6 +166ER G 80.5725 136.55 8E2 6.90 14 +166ER2 G KC=1.65 5$LC=4.01 8$MC=0.978 20$NC=0.228 7 +166ER3 G OC=0.0296 9 +166ER L 264.9832 174+ 118 PS 5 +166ER G 184.4107 110.0015 7E2 0.333 10 +166ER2 G KC=0.205 6$LC=0.0984 30$MC=0.0236 7$NC=0.00554 17 +166ER3 G OC=0.000754 23 +166ER L 785.78 7 2+ 3.26 PS 11 +166ER B 1068.6 9 0.0072 21 11.6 1U +166ERS B EAV=356 9 +166ER G 520.80 7 0.00035 2E2 0.0149 5 +166ER2 G KC=0.01192 36$LC=0.00234 7$MC=0.000535 16$NC=1.275E-4 38 +166ER3 G OC=1.92E-5 6 +166ER G 705.21 7 0.0146 12E2+M1 0.0072122 +166ER2 G KC=0.00591 18$LC=0.001012 30$MC=0.000228 7$NC=5.46E-5 16 +166ER3 G OC=8.43E-6 25 +166ER G 785.78 7 0.0120 3E2 0.0056617 +166ER2 G KC=0.00467 14$LC=0.000769 23$MC=0.000173 5$NC=4.14E-5 12 +166ER3 G OC=6.44E-6 19 +166ER L 1460.025 100+ +166ER B 394.5 9 0.955 16 7.4 +166ERS B EAV=115 3 +166ER G 674.24 7 0.0198 17E2 0.0079924 +166ER2 G KC=0.00653 20$LC=0.001138 34$MC=0.000257 8$NC=6.15E-5 18 +166ER3 G OC=9.46E-6 28 +166ER G 1379.446 100.933 35E2 0.00179 5 +166ER2 G KC=0.00151 5$LC=0.00022 1$MC=0.000048 2$NC=1.162E-5 35 +166ER3 G OC=1.85E-6 6 +166ER G 1460.018 100.0002 E0 +166ER L 1528.23 152+ +166ER B 326.2 9 0.00276 22 9.5 1U +166ERS B EAV=93 3 +166ER G 1263.24 150.0155 9E2(+M3) 0.0021 2 +166ER2 G KC=0.0018 2$LC=0.0003 1$MC=0.000058 2$NC=1.395E-5 42 +166ER3 G OC=2.22E-6 7 +166ER G 1447.66 150.00105 10E2(+E0) 0.00163 5 +166ER2 G KC=0.00138 4$LC=0.000198 6$MC=0.000044 2$NC=1.054E-5 32 +166ER3 G OC=1.68E-6 5 +166ER G 1528.23 150.00014 5E2 0.00147 4 +166ER2 G KC=0.00125 4$LC=0.000178 5 +166ER L 1662.433 151- +166ER B 192.0 9 0.304 7 6.9 +166ERS B EAV=52 1 +166ER G 1581.852 150.186 4E1+(M2) +166ER G 1662.424 150.118 5E1 +166ER L 1812.8 5 1- +166ER B 41.7 9 0.00010 3 12.1 +166ERS B EAV=13 2 +166ER G 1732.2 5 0.00004620M1(+E2) +166ER G 1812.8 5 0.00005619E1(+M2) +166ER L 1830.419 241- +166ER B 24.1 9 0.0353 11 5 +166ERS B EAV=7.1 10 +166ER G 1749.837 140.0272 10E1(+M2) +166ER G 1830.408 240.0081 2E1 + diff --git a/HEN_HOUSE/spectra/lnhb/Ho-166m.txt b/HEN_HOUSE/spectra/lnhb/Ho-166m.txt index 2f8971ec9..5d7835fb2 100644 --- a/HEN_HOUSE/spectra/lnhb/Ho-166m.txt +++ b/HEN_HOUSE/spectra/lnhb/Ho-166m.txt @@ -1,175 +1,225 @@ -166ER 166HO B- DECAY (1133 Y) -166ER H TYP=Update$AUT=M.-M.Bé$CUT=01-JUN-2006$ -166ER2 H TYP=Full$AUT=E.Schonfeld$CUT=01-JUN-1999$ -166ER C Evaluation history: Type=Update;Author=M.-M.Bé;Cutoff date=01-JUN-2006 -166ER2C Type=Full;Author=E.Schonfeld;Cutoff date=01-JUN-1999 -166ER T Auger electrons and X ray energies and emission intensities: -166ER T {U Energy (keV)} {U Intensity} {U Line} -166ER T -166ER T 48.2215 10.81 21 XKA2 -166ER T 49.1282 19.2 4 XKA1 -166ER T -166ER T 55.495 |] XKB3 -166ER T 55.682 |] 6.24 14 XKB1 -166ER T 56.04 |] XKB5II -166ER T -166ER T 57.21 |] XKB2 -166ER T 57.313 |] 1.62 5 XKB4 -166ER T 57.456 |] XKO23 -166ER T -166ER T 6.14-9.43 20.8 4 XL (total) -166ER T 6.14 0.398 12 XLL -166ER T 6.9-6.95 9.19 24 XLA -166ER T 7.05 0.198 6 XLC -166ER T 7.75-8.34 9.46 24 XLB -166ER T 8.81-9.43 1.54 5 XLG -166ER T -166ER T 37.78-40.55 |] KLL AUGER -166ER T 45.52-49.1 |] 2.33 17 KLX AUGER -166ER T 53.07-56.84 |] KXY AUGER -166ER T 3.9-7.6 72.0 7 L AUGER -166HO P 5.98 2 7- 1133 Y 8 1854.5 9 -166ER N 1.0 1.0 1 1.0 -166ER L 0 0+ STABLE -166ER L 80.5725 132+ 1.82 NS -166ER G 80.5725 1312.66 23E2 6.90 14 -166ER2 G KC=1.65 3$LC=4.01 8$MC=0.978 29 -166ER L 264.9832 174+ 118 PS -166ER G 184.4107 1172.5 3E2 0.334 7 -166ER2 G KC=0.205 6$LC=0.0984 30$MC=0.0236 7 -166ER L 545.4462 296+ -166ER B 1315.1 9 3.4 6 14.3 1 -166ERS B EAV=674.6 9 -166ER G 280.4630 2329.54 25E2 0.0855 17 -166ER2 G KC=0.0613 12$LC=0.0187 4$MC=0.00439 13 -166ER L 785.78 7 2+ 3.26 PS -166ER G 520.80 7 0.153 6E2 0.0149 3 -166ER2 G KC=0.01192 36$LC=0.00234 7$MC=5.35E-4 16 -166ER G 705.21 7 0.014 7E2(+M1) 0.0072122 -166ER2 G KC=0.00591 18$LC=1012E-6 30$MC=2.28E-4 7 -166ER G 785.78 7 0.019 4E2 0.0056617 -166ER2 G KC=0.00467 14$LC=7.69E-4 23$MC=1.73E-4 5 -166ER L 859.400 6 3+ -166ER G 73.62 7 0.0260 16M1+E2 7.14 21 -166ER2 G KC=5.98 18$LC=0.902 27$MC=0.201 6 -166ER G 594.417 6 0.58 6E2+M1 0.0108933 -166ER2 G KC=0.00881 26$LC=1613E-6 48$MC=3.66E-4 11 -166ER G 778.827 6 3.01 8E2+M1 0.0057917 -166ER2 G KC=0.00477 14$LC=7.88E-4 24$MC=1.77E-4 5 -166ER L 911.214 7 8+ 4.2 PS -166ER B 949.3 9 1.12 6 14.2 1 -166ERS B EAV=294.3 9 -166ER G 365.768 6 2.46 4E2 0.0388 8 -166ER2 G KC=0.0294 6$LC=0.00721 15$MC=0.00167 5 -166ER L 956.236 8 4+ -166ER G 691.253 7 1.32 7E2+M1 0.0075823 -166ER2 G KC=0.00620 19$LC=1069E-6 32$MC=2.41E-4 7 -166ER G 875.663 7 0.721 9E2 0.0044713 -166ER2 G KC=0.00371 11$LC=5.92E-4 18$MC=1324E-7 40 -166ER L 1075.269 5 5+ 60 PS -166ER G 119.033 100.173 3E2+M1 1.614 48 -166ER2 G KC=0.888 27$LC=0.556 17$MC=0.1339 40 -166ER G 215.871 7 2.66 17E2 0.197 4 -166ER2 G KC=0.1299 26$LC=0.0516 10$MC=0.01229 37 -166ER G 529.825 4 9.4 4M1+E2 0.0144 3 -166ER2 G KC=0.01145 26$LC=0.00223 5$MC=5.08E-4 15 -166ER G 810.286 4 57.3 11E2+M1 0.0053 1 -166ER2 G KC=0.00438 9$LC=0.00071 2$MC=1603E-7 48 -166ER L 1215.972 5 6+ -166ER B 644.5 9 2.31 29 13.4 1 -166ERS B EAV=201.2 9 -166ER G 140.703 7 0.0428 22M1+E2 0.938 28 -166ER2 G KC=0.604 18$LC=0.256 8$MC=0.0611 18 -166ER G 259.736 101.078 10E2 0.1087 22 -166ER2 G KC=0.0762 15$LC=0.0249 5$MC=0.00589 18 -166ER G 304.758 9 0.0183 12E2 0.0662 13 -166ER2 G KC=0.0485 10$LC=0.0137 3$MC=0.00322 10 -166ER G 670.526 4 5.34 21E2+M1 0.0081624 -166ER2 G KC=0.00666 20$LC=1161E-6 35$MC=2.62E-4 8 -166ER G 950.988 4 2.744 19E2 0.0037611 -166ER2 G KC=0.00313 9$LC=4.88E-4 15$MC=1089E-7 33 -166ER L 1376.011 5 7+ -166ER B 484.5 9 0.81 26 13 -166ERS B EAV= -166ER G 160.039 7 0.097 5M1+E2 1.45 11 0.616 18 -166ER2 G KC=0.417 13$LC=0.1530 46$MC=0.0363 11 -166ER G 300.741 3 3.73 3E2 0.0691 14 -166ER2 G KC=0.0503 10$LC=0.0144 3$MC=0.00338 10 -166ER G 464.798 6 1.25 4M1+E2 0.0201 6 -166ER2 G KC=0.01579 47$LC=0.0033 1$MC=7.58E-4 23 -166ER G 830.565 4 9.72 18E2+M1 0.0050315 -166ER2 G KC=0.00416 12$LC=6.73E-4 20$MC=1509E-7 45 -166ER L 1555.72 5 8+ -166ER B 304.6 9 0.394 5 12.9 1 -166ERS B EAV= -166ER G 339.75 5 0.1616 23E2 0.048 1 -166ER2 G KC=0.0359 7$LC=0.00930 19$MC=0.00217 7 -166ER G 644.51 7 0.144 4E2+M1 0.0098930 -166ER2 G KC=0.00810 24$LC=1384E-6 42$MC=3.12E-4 9 -166ER G 1010.27 6 0.0794 16E2 0.0033210 -166ER2 G KC=0.00277 8$LC=4.25E-4 13$MC=9.47E-5 28 -166ER L 1572.22 6 4- -166ER G 496.90 6 0.125 3E1(+M2) 0.0057117 -166ER2 G KC=0.00483 15$LC=6.79E-4 20$MC=1497E-7 45 -166ER G 615.93 6 0.094 29E4 0.0687 21 -166ER2 G KC=0.0444 13$LC=0.0185 6$MC=0.00449 13 -166ER G 712.89 130.30 9E1 -166ER G 1307.19 6 0.0055 11E1 8.52E-426 -166ER2 G KC=7.27E-4 22$LC=9.70E-5 29$MC=2.13E-5 6 -166ER L 1596.10 7 4- -166ER G 639.86 6 0.0943 7E1 0.0033110 -166ER2 G KC=0.00282 8$LC=3.89E-4 12$MC=8.57E-5 26 -166ER G 736.70 7 0.373 6E1 0.00249 7 -166ER2 G KC=0.00211 6$LC=2.90E-4 9$MC=6.37E-5 19 -166ER G 1331.12 7 0.0043 12E1 8.25E-425 -166ER2 G KC=7.05E-4 21$LC=9.39E-5 28$MC=2.06E-5 6 -166ER L 1665.79 3 5- -166ER G 1120.320 300.199 4E1 1121E-634 -166ER2 G KC=9.56E-4 29$LC=1283E-7 38$MC=2.81E-5 8 -166ER G 1400.79 2 0.508 6E1 7.55E-423 -166ER2 G KC=6.45E-4 19$LC=8.59E-5 26$MC=1.88E-5 6 -166ER L 1692.291 125- -166ER G 476.250 400.0363 13E1 0.0062719 -166ER2 G KC=0.00531 16$LC=7.48E-4 22$MC=1.65E-4 5 -166ER G 736.02 8 0.14 2 -166ER G 1146.770 300.2059 26E1 1075E-632 -166ER2 G KC=9.18E-4 28$LC=1230E-7 37$MC=2.70E-5 8 -166ER G 1427.24 2 0.498 6E1 7.32E-422 -166ER2 G KC=6.25E-4 19$LC=8.31E-5 25$MC=1.82E-5 5 -166ER L 1786.966 7 6- -166ER B 73.5 9 74.8 12 8.8 -166ERS B EAV=18.6 4 -166ER G 94.675 140.146 4M1+E2 3.45 10 -166ER2 G KC=2.89 9$LC=0.435 13$MC=0.0967 29 -166ER G 121.175 100.241 7E2 1.460 44 -166ER2 G KC=0.663 20$LC=0.610 18$MC=0.1480 44 -166ER G 190.86 7 0.215 5E2 0.297 9 -166ER2 G KC=0.186 6$LC=0.0853 26$MC=0.0204 6 -166ER G 214.79 3 0.445 11E2 0.200 4 -166ER2 G KC=0.1318 40$LC=0.0526 16$MC=0.01254 38 -166ER G 410.956 3 11.35 17E1(+M2) 0.0087826 -166ER2 G KC=0.00743 22$LC=1055E-6 32$MC=2.33E-4 7 -166ER G 570.995 5 5.43 20E1(+M2) 0.0042113 -166ER2 G KC=0.00358 11$LC=4.98E-4 15$MC=1097E-7 33 -166ER G 711.697 3 54.9 9E1(+M2) 0.00266 8 -166ER2 G KC=0.00227 7$LC=3.11E-4 9$MC=6.85E-5 21 -166ER G 1241.519 4 0.85 3E1(+M2) 9.32E-428 -166ER2 G KC=7.96E-4 24$LC=1063E-7 32$MC=2.33E-5 7 -166ER L 1827.551 7 6- -166ER B 32.9 9 17.2 4 8.4 -166ERS B EAV=8.2 2 -166ER G 135.260 140.0979 19E2 0.981 29 -166ER2 G KC=0.493 15$LC=0.373 11$MC=0.0904 27 -166ER G 161.76 3 0.109 4E2(+M1) 0.522 16 -166ER2 G KC=0.299 9$LC=0.171 5$MC=0.0412 12 -166ER G 231.45 7 0.219 6E2 0.157 3 -166ER2 G KC=0.1062 21$LC=0.0391 8$MC=0.00928 28 -166ER G 451.540 4 2.915 14E1(+M2) 0.0070721 -166ER2 G KC=0.00599 18$LC=8.46E-4 25$MC=1.87E-4 6 -166ER G 611.579 6 1.31 21E1(+M2) 0.0036411 -166ER2 G KC=0.00309 9$LC=4.29E-4 13$MC=9.44E-5 28 -166ER G 752.280 4 12.2 3E1(+M2) 0.00238 7 -166ER2 G KC=0.00203 6$LC=2.78E-4 8$MC=6.11E-5 18 -166ER G 1282.102 5 0.183 7E1(+M2) 8.81E-426 -166ER2 G KC=7.52E-4 23$LC=1004E-7 30$MC=2.20E-5 7 - +166ER 166HO B- DECAY (1133 Y) +166ER H TYP=UPD$AUT=M.-M.BE$CUT=01-JUN-2006$ +166ER2 H TYP=FUL$AUT=E.SCHONFELD$CUT=01-JUN-1999$ +166ER T Auger electrons and X ray energies and emission intensities: +166ER T {U Energy (keV)} {U Intensity} {U Line} +166ER T +166ER T 48.2215 10.81 21 XKA2 +166ER T 49.1282 19.2 4 XKA1 +166ER T +166ER T 55.495 |] XKB3 +166ER T 55.682 |] 6.24 14 XKB1 +166ER T 56.04 |] XKB5II +166ER T +166ER T 57.21 |] XKB2 +166ER T 57.313 |] 1.62 5 XKB4 +166ER T 57.456 |] XKO23 +166ER T +166ER T 6.14-9.43 20.8 4 XL (total) +166ER T 6.14 0.398 12 XLL +166ER T 6.9-6.95 9.19 24 XLA +166ER T 7.05 0.198 6 XLC +166ER T 7.75-8.34 9.46 24 XLB +166ER T 8.81-9.43 1.54 5 XLG +166ER T +166ER T 37.78-40.55 |] KLL AUGER +166ER T 45.52-49.1 |] 2.33 17 KLX AUGER +166ER T 53.07-56.84 |] KXY AUGER +166ER T 3.9-7.6 72.0 7 L AUGER +166HO P 5.98 2 7- 1133 Y 8 1854.5 9 +166ER N 1.0 1.0 1 1.0 +166ER L 0 0+ STABLE +166ER L 80.5725 132+ 1.82 NS +166ER G 80.5725 1312.66 23E2 6.90 14 +166ER2 G KC=1.65 3$LC=4.01 8$MC=0.978 29$NC=0.228 7 +166ER3 G OC=0.0296 9 +166ER L 264.9832 174+ 118 PS +166ER G 184.4107 1172.5 3E2 0.334 7 +166ER2 G KC=0.205 6$LC=0.0984 30$MC=0.0236 7$NC=0.00554 17 +166ER3 G OC=0.000754 23 +166ER L 545.4462 296+ +166ER B 1315.1 9 3.4 6 14.3 1 +166ERS B EAV=674.6 9 +166ER G 280.4630 2329.54 25E2 0.0855 17 +166ER2 G KC=0.0613 12$LC=0.0187 4$MC=0.00439 13$NC=0.001037 31 +166ER3 G OC=1.470E-4 44 +166ER L 785.78 7 2+ 3.26 PS +166ER G 520.80 7 0.153 6E2 0.0149 3 +166ER2 G KC=0.01192 36$LC=0.00234 7$MC=0.000535 16$NC=1.275E-4 38 +166ER3 G OC=1.92E-5 6 +166ER G 705.21 7 0.014 7E2(+M1) 0.0072122 +166ER2 G KC=0.00591 18$LC=0.001012 30$MC=0.000228 7$NC=5.46E-5 16 +166ER3 G OC=8.43E-6 25 +166ER G 785.78 7 0.019 4E2 0.0056617 +166ER2 G KC=0.00467 14$LC=0.000769 23$MC=0.000173 5$NC=4.14E-5 12 +166ER3 G OC=6.44E-6 19 +166ER L 859.400 6 3+ +166ER G 73.62 7 0.0260 16M1+E2 7.14 21 +166ER2 G KC=5.98 18$LC=0.902 27$MC=0.201 6$NC=0.0484 15 +166ER3 G OC=0.00777 23 +166ER G 594.417 6 0.58 6E2+M1 0.0108933 +166ER2 G KC=0.00881 26$LC=0.001613 48$MC=0.000366 11$NC=8.75E-5 26 +166ER3 G OC=1.335E-5 40 +166ER G 778.827 6 3.01 8E2+M1 0.0057917 +166ER2 G KC=0.00477 14$LC=0.000788 24$MC=0.000177 5$NC=4.24E-5 13 +166ER3 G OC=6.6E-6 2 +166ER L 911.214 7 8+ 4.2 PS +166ER B 949.3 9 1.12 6 14.2 1 +166ERS B EAV=294.3 9 +166ER G 365.768 6 2.46 4E2 0.0388 8 +166ER2 G KC=0.0294 6$LC=0.00721 15$MC=0.00167 5$NC=0.000397 12 +166ER3 G OC=5.78E-5 17 +166ER L 956.236 8 4+ +166ER G 691.253 7 1.32 7E2+M1 0.0075823 +166ER2 G KC=0.00620 19$LC=0.001069 32$MC=0.000241 7$NC=5.77E-5 17 +166ER3 G OC=8.90E-6 27 +166ER G 875.663 7 0.721 9E2 0.0044713 +166ER2 G KC=0.00371 11$LC=0.000592 18$MC=1.324E-4 40$NC=3.18E-5 10 +166ER3 G OC=4.97E-6 15 +166ER L 1075.269 5 5+ 60 PS +166ER G 119.033 100.173 3E2+M1 1.614 48 +166ER2 G KC=0.888 27$LC=0.556 17$MC=0.1339 40$NC=0.0314 9 +166ER3 G OC=0.00423 13 +166ER G 215.871 7 2.66 17E2 0.197 4 +166ER2 G KC=0.1299 26$LC=0.0516 10$MC=0.01229 37$NC=0.00289 9 +166ER3 G OC=0.000399 12 +166ER G 529.825 4 9.4 4M1+E2 0.0144 3 +166ER2 G KC=0.01145 26$LC=0.00223 5$MC=0.000508 15$NC=1.212E-4 36 +166ER3 G OC=1.83E-5 5 +166ER G 810.286 4 57.3 11E2+M1 0.0053 1 +166ER2 G KC=0.00438 9$LC=0.00071 2$MC=1.603E-4 48$NC=3.84E-5 12 +166ER3 G OC=5.98E-6 18 +166ER L 1215.972 5 6+ +166ER B 644.5 9 2.31 29 13.4 1 +166ERS B EAV=201.2 9 +166ER G 140.703 7 0.0428 22M1+E2 0.938 28 +166ER2 G KC=0.604 18$LC=0.256 8$MC=0.0611 18$NC=0.01437 43 +166ER3 G OC=0.00198 6 +166ER G 259.736 101.078 10E2 0.1087 22 +166ER2 G KC=0.0762 15$LC=0.0249 5$MC=0.00589 18$NC=0.001390 42 +166ER3 G OC=0.000196 6 +166ER G 304.758 9 0.0183 12E2 0.0662 13 +166ER2 G KC=0.0485 10$LC=0.0137 3$MC=0.00322 10$NC=0.000761 23 +166ER3 G OC=1.088E-4 33 +166ER G 670.526 4 5.34 21E2+M1 0.0081624 +166ER2 G KC=0.00666 20$LC=0.001161 35$MC=0.000262 8$NC=6.28E-5 19 +166ER3 G OC=9.66E-6 29 +166ER G 950.988 4 2.744 19E2 0.0037611 +166ER2 G KC=0.00313 9$LC=0.000488 15$MC=1.089E-4 33$NC=2.61E-5 8 +166ER3 G OC=4.10E-6 12 +166ER L 1376.011 5 7+ +166ER B 484.5 9 0.81 26 13 +166ER G 160.039 7 0.097 5M1+E2 1.45 11 0.616 18 +166ER2 G KC=0.417 13$LC=0.1530 46$MC=0.0363 11$NC=0.00855 26 +166ER3 G OC=0.001194 36 +166ER G 300.741 3 3.73 3E2 0.0691 14 +166ER2 G KC=0.0503 10$LC=0.0144 3$MC=0.00338 10$NC=0.000799 24 +166ER3 G OC=1.141E-4 34 +166ER G 464.798 6 1.25 4M1+E2 0.0201 6 +166ER2 G KC=0.01579 47$LC=0.0033 1$MC=0.000758 23$NC=0.000181 5 +166ER3 G OC=2.69E-5 8 +166ER G 830.565 4 9.72 18E2+M1 0.0050315 +166ER2 G KC=0.00416 12$LC=0.000673 20$MC=1.509E-4 45$NC=3.62E-5 11 +166ER3 G OC=5.64E-6 17 +166ER L 1555.72 5 8+ +166ER B 304.6 9 0.394 5 12.9 1 +166ER G 339.75 5 0.1616 23E2 0.048 1 +166ER2 G KC=0.0359 7$LC=0.00930 19$MC=0.00217 7$NC=0.000514 15 +166ER3 G OC=7.43E-5 22 +166ER G 644.51 7 0.144 4E2+M1 0.0098930 +166ER2 G KC=0.00810 24$LC=0.001384 42$MC=0.000312 9$NC=7.48E-5 22 +166ER3 G OC=1.156E-5 35 +166ER G 1010.27 6 0.0794 16E2 0.0033210 +166ER2 G KC=0.00277 8$LC=0.000425 13$MC=9.47E-5 28$NC=2.27E-5 7 +166ER3 G OC=3.58E-6 11 +166ER L 1572.22 6 4- +166ER G 496.90 6 0.125 3E1(+M2) 0.0057117 +166ER2 G KC=0.00483 15$LC=0.000679 20$MC=1.497E-4 45$NC=3.59E-5 11 +166ER3 G OC=5.68E-6 17 +166ER G 615.93 6 0.094 29E4 0.0687 21 +166ER2 G KC=0.0444 13$LC=0.0185 6$MC=0.00449 13$NC=0.001070 32 +166ER3 G OC=1.524E-4 46 +166ER G 712.89 130.30 9E1 +166ER G 1307.19 6 0.0055 11E1 8.52E-426 +166ER2 G KC=0.000727 22$LC=9.70E-5 29$MC=2.13E-5 6$NC=5.11E-6 15 +166ER3 G OC=8.22E-7 25 +166ER L 1596.10 7 4- +166ER G 639.86 6 0.0943 7E1 0.0033110 +166ER2 G KC=0.00282 8$LC=0.000389 12$MC=8.57E-5 26$NC=2.06E-5 6 +166ER3 G OC=3.27E-6 10 +166ER G 736.70 7 0.373 6E1 0.00249 7 +166ER2 G KC=0.00211 6$LC=0.000290 9$MC=6.37E-5 19$NC=1.531E-5 46 +166ER3 G OC=2.44E-6 7 +166ER G 1331.12 7 0.0043 12E1 8.25E-425 +166ER2 G KC=0.000705 21$LC=9.39E-5 28$MC=2.06E-5 6$NC=4.95E-6 15 +166ER3 G OC=7.96E-7 24 +166ER L 1665.79 3 5- +166ER G 1120.320 300.199 4E1 1121E-634 +166ER2 G KC=0.000956 29$LC=1.283E-4 38$MC=2.81E-5 8$NC=6.77E-6 20 +166ER3 G OC=1.086E-6 33 +166ER G 1400.79 2 0.508 6E1 7.55E-423 +166ER2 G KC=0.000645 19$LC=8.59E-5 26$MC=1.88E-5 6$NC=4.53E-6 14 +166ER3 G OC=7.28E-7 22 +166ER L 1692.291 125- +166ER G 476.250 400.0363 13E1 0.0062719 +166ER2 G KC=0.00531 16$LC=0.000748 22$MC=0.000165 5$NC=3.95E-5 12 +166ER3 G OC=6.25E-6 19 +166ER G 736.02 8 0.14 2 +166ER G 1146.770 300.2059 26E1 1075E-632 +166ER2 G KC=0.000918 28$LC=1.230E-4 37$MC=2.70E-5 8$NC=6.49E-6 19 +166ER3 G OC=1.041E-6 31 +166ER G 1427.24 2 0.498 6E1 7.32E-422 +166ER2 G KC=0.000625 19$LC=8.31E-5 25$MC=1.82E-5 5$NC=4.38E-6 13 +166ER3 G OC=7.05E-7 21 +166ER L 1786.966 7 6- +166ER B 73.5 9 74.8 12 8.8 +166ERS B EAV=18.6 4 +166ER G 94.675 140.146 4M1+E2 3.45 10 +166ER2 G KC=2.89 9$LC=0.435 13$MC=0.0967 29$NC=0.0233 7 +166ER3 G OC=0.00374 11 +166ER G 121.175 100.241 7E2 1.460 44 +166ER2 G KC=0.663 20$LC=0.610 18$MC=0.1480 44$NC=0.0346 10 +166ER3 G OC=0.00457 14 +166ER G 190.86 7 0.215 5E2 0.297 9 +166ER2 G KC=0.186 6$LC=0.0853 26$MC=0.0204 6$NC=0.00480 14 +166ER3 G OC=0.000655 20 +166ER G 214.79 3 0.445 11E2 0.200 4 +166ER2 G KC=0.1318 40$LC=0.0526 16$MC=0.01254 38$NC=0.00295 9 +166ER3 G OC=0.000407 12 +166ER G 410.956 3 11.35 17E1(+M2) 0.0087826 +166ER2 G KC=0.00743 22$LC=0.001055 32$MC=0.000233 7$NC=5.58E-5 17 +166ER3 G OC=8.78E-6 26 +166ER G 570.995 5 5.43 20E1(+M2) 0.0042113 +166ER2 G KC=0.00358 11$LC=0.000498 15$MC=1.097E-4 33$NC=2.63E-5 8 +166ER3 G OC=4.17E-6 13 +166ER G 711.697 3 54.9 9E1(+M2) 0.00266 8 +166ER2 G KC=0.00227 7$LC=0.000311 9$MC=6.85E-5 21$NC=1.644E-5 49 +166ER3 G OC=2.62E-6 8 +166ER G 1241.519 4 0.85 3E1(+M2) 9.32E-428 +166ER2 G KC=0.000796 24$LC=1.063E-4 32$MC=2.33E-5 7$NC=5.61E-6 17 +166ER3 G OC=9.01E-7 27 +166ER L 1827.551 7 6- +166ER B 32.9 9 17.2 4 8.4 +166ERS B EAV=8.2 2 +166ER G 135.260 140.0979 19E2 0.981 29 +166ER2 G KC=0.493 15$LC=0.373 11$MC=0.0904 27$NC=0.0211 6 +166ER3 G OC=0.00281 8 +166ER G 161.76 3 0.109 4E2(+M1) 0.522 16 +166ER2 G KC=0.299 9$LC=0.171 5$MC=0.0412 12$NC=0.00967 29 +166ER3 G OC=0.001303 39 +166ER G 231.45 7 0.219 6E2 0.157 3 +166ER2 G KC=0.1062 21$LC=0.0391 8$MC=0.00928 28$NC=0.00219 7 +166ER3 G OC=0.000304 9 +166ER G 451.540 4 2.915 14E1(+M2) 0.0070721 +166ER2 G KC=0.00599 18$LC=0.000846 25$MC=0.000187 6$NC=4.47E-5 13 +166ER3 G OC=7.06E-6 21 +166ER G 611.579 6 1.31 21E1(+M2) 0.0036411 +166ER2 G KC=0.00309 9$LC=0.000429 13$MC=9.44E-5 28$NC=2.27E-5 7 +166ER3 G OC=3.60E-6 11 +166ER G 752.280 4 12.2 3E1(+M2) 0.00238 7 +166ER2 G KC=0.00203 6$LC=0.000278 8$MC=6.11E-5 18$NC=1.466E-5 44 +166ER3 G OC=2.34E-6 7 +166ER G 1282.102 5 0.183 7E1(+M2) 8.81E-426 +166ER2 G KC=0.000752 23$LC=1.004E-4 30$MC=2.20E-5 7$NC=5.29E-6 16 +166ER3 G OC=8.51E-7 26 + diff --git a/HEN_HOUSE/spectra/lnhb/I-123.txt b/HEN_HOUSE/spectra/lnhb/I-123.txt index aad2feafb..c66aa41a1 100644 --- a/HEN_HOUSE/spectra/lnhb/I-123.txt +++ b/HEN_HOUSE/spectra/lnhb/I-123.txt @@ -1,126 +1,126 @@ -123TE 123I EC DECAY (13.2234 H) -123TE T Auger electrons and X ray energies and emission intensities: -123TE T {U Energy (keV)} {U Intensity} {U Line} -123TE T -123TE T 27.202 24.69 20 XKA2 -123TE T 27.4726 45.98 29 XKA1 -123TE T -123TE T 30.9446 |] XKB3 -123TE T 30.996 |] 13.16 17 XKB1 -123TE T 31.236 |] XKB5II -123TE T 31.241 |] XKB5I -123TE T -123TE T 31.7008 |] XKB2 -123TE T 31.774 |] 2.86 8 XKB4 -123TE T 31.812 |] XKO23 -123TE T -123TE T 3.336-4.82 9.0 4 XL (total) -123TE T 3.336 0.159 5 XLL -123TE T 3.76-3.77 4.22 11 XLA -123TE T 3.606 0.0598 18 XLC -123TE T 4.02-4.37 2.91 7 XLB -123TE T 4.44-4.82 0.366 10 XLG -123TE T -123TE T 21.804-22.989 |] KLL AUGER -123TE T 25.814-27.47 |] 12.4 4 KLX AUGER -123TE T 29.8-31.81 |] KXY AUGER -123TE T 2.3-4.8 95.3 6 L AUGER -123I P 0.0 5/2+ 13.2234 H 37 1234 3 -123TE N 1.0 1.0 1 1.0 -123TE L 0 1/2+ 12E12 Y -123TE L 158.99 3 3/2+ 196 PS 9 -123TE E 97.18 325.26 -123TE2 E CK=0.8533 14$CL=0.1163 10$CM=0.0248 5$CN=0.0056 3$CO=0 0 -123TE G 158.97 5 83.25 21M1+E2 0.111 3 0.1918 19 -123TE2 G KC=0.1648 16$LC=0.02160 22 -123TE L 440.00 4 3/2+ 22 PS 3 -123TE E 0.419 57.35 -123TE2 E CK=0.8510 14$CL=0.1181 10$CM=0.0253 5$CN=0.0056 3$CO=0 0 -123TE G 281.03 5 0.0789 9M1+E2 -0.39 15 0.0422 33 -123TE2 G KC=0.0362 20$LC=0.0048 11 -123TE G 440.02 5 0.4229 43M1+E2 -2.1 1 0.0121 7 -123TE2 G KC=0.0103 7$LC=1452E-6 18 -123TE L 489.70 8 (7/2)+ 30.7 NS -123TE E 0.0025 109.52 -123TE2 E CK=0.8503 14$CL=0.1186 10$CM=0.0254 5$CN=0.0057 3$CO=0 0 -123TE G 330.70 8 0.01164 33E2 0.0284 9 -123TE2 G KC=0.0237 7$LC=0.00376 11 -123TE L 505.34 4 (5/2)+ 13.5 PS 25 -123TE E 0.349 427.35 -123TE2 E CK=0.8501 14$CL=0.1187 10$CM=0.0254 5$CN=0.0058 3$CO=0 0 -123TE G 346.35 5 0.1257 9M1+E2 0.07 7 0.0240723 -123TE2 G KC=0.02080 14$LC=0.00262 29 -123TE G 505.33 5 0.266 42M1+E2 0.10 2 0.0093 7 -123TE2 G KC=0.0081 7$LC=1063E-6 27 -123TE L 599.57 151/2+ -123TE G 599.69 160.00266 17 -123TE L 687.95 4 3/2+ -123TE E 1.40 126.49 -123TE2 E CK=0.8466 14$CL=0.1214 10$CM=0.0261 5$CN=0.0059 3$CO=0 0 -123TE G 182.61 6 0.018 5M1+E2 1 0.168 38 -123TE2 G KC=0.138 24$LC=0.024 10 -123TE G 198.23 0.0035 7M1+E2 1 0.130 26 -123TE2 G KC=0.107 17$LC=0.018 7 -123TE G 247.96 5 0.0698 23M1+E2 1 0.065 8 -123TE2 G KC=0.054 5$LC=0.0084 21 -123TE G 528.96 5 1.28 12 -123TE G 687.95 100.0269 6 -123TE L 697.52 5 7/2+ -123TE E 0.419 136.98 -123TE2 E CK=0.8464 14$CL=0.1216 10$CM=0.0262 5$CN=0.0058 3$CO=0 0 -123TE G 192.17 7 0.0199 7M1+E2 1 0.143 30 -123TE2 G KC=0.118 20$LC=0.020 8 -123TE G 207.8 0.00112 32M1+E2 1 0.119 20 -123TE2 G KC=0.093 14$LC=0.015 5 -123TE G 257.51 150.0016 2E2 0.0640 19 -123TE2 G KC=0.0526 16$LC=0.00917 27 -123TE G 538.54 5 0.3788 43E2+M3 1 0.038 31 -123TE2 G KC=0.032 26$LC=0.0049 41 -123TE L 769.26 14 + -123TE E 0.0037 68.92 -123TE2 E CK=0.8441 14$CL=0.1233 10$CM=0.0266 5$CN=0.0060 3$CO=0 0 -123TE G 329.38 170.0026 6 -123TE G 610.05 230.0011 3 -123TE L 783.60 4 3/2,5/2+ 52 FS 33 -123TE E 0.1461 207.29 -123TE2 E CK=0.8436 14$CL=0.1237 10$CM=0.0267 5$CN=0.0060 3$CO=0 0 -123TE G 278.36 120.0023 4M1+E2 1 0.0459 36 -123TE2 G KC=0.0387 22$LC=0.0058 11 -123TE G 343.73 140.0044 3 -123TE G 624.57 5 0.0798 20M1+E2 1.30 35 0.0049 6 -123TE2 G KC=0.0042 5$LC=5.49E-4 40 -123TE G 783.59 6 0.0591 11 -123TE L 894.74 6 3/2,5/2+ 45 FS 24 -123TE E 0.0744 137.32 -123TE2 E CK=0.8377 15$CL=0.1283 11$CM=0.0278 5$CN=0.0062 3$CO=0 0 -123TE G 197.22 0.00033 17M1+E2 1 0.132 26 -123TE2 G KC=0.109 18$LC=0.018 7 -123TE G 206.79 0.0033 8M1+E2 1 0.114 21 -123TE2 G KC=0.094 14$LC=0.016 5 -123TE G 295.17 0.001582 4 -123TE G 405.02 130.00298 23 -123TE G 454.76 150.00412 22 -123TE G 735.78 7 0.0616 8 -123TE G 894.8 2 0.00101 7 -123TE L 996.06 12(5/2)- -123TE E 0.0035 38.31 -123TE2 E CK=0.8266 16$CL=0.1363 12$CM=0.0300 6$CN=0.0067 4$CO=0 0 -123TE G 556.05 130.0029 3 -123TE G 837.1 2 0.000582 8 -123TE L 1036.64 123/2,5/2+ 43 FS 16 -123TE E 0.0025 98.27 -123TE2 E CK=0.8182 18$CL=0.1427 13$CM=0.0316 6$CN=0.0071 4$CO=0 0 -123TE G 437.5 3 0.0007 7 -123TE G 877.52 170.00083 7 -123TE G 1036.63 170.00097 7 -123TE L 1068.18 8 3/2,5/2+ -123TE E 0.0079 47.59 -123TE2 E CK=0.8082 21$CL=0.1503 15$CM=0.0336 7$CN=0.0075 4$CO=0 0 -123TE G 174.2 3 0.00083 25M1+E2 1 0.195 47 -123TE2 G KC=0.159 32$LC=0.029 12 -123TE G 562.79 120.00115 7 -123TE G 578.26 200.00126 8 -123TE G 628.26 220.00164 14 -123TE G 909.12 120.00141 8 -123TE G 1068.12 150.00142 7 - +123TE 123I EC DECAY (13.2234 H) +123TE T Auger electrons and X ray energies and emission intensities: +123TE T {U Energy (keV)} {U Intensity} {U Line} +123TE T +123TE T 27.202 24.69 20 XKA2 +123TE T 27.4726 45.98 29 XKA1 +123TE T +123TE T 30.9446 |] XKB3 +123TE T 30.996 |] 13.16 17 XKB1 +123TE T 31.236 |] XKB5II +123TE T 31.241 |] XKB5I +123TE T +123TE T 31.7008 |] XKB2 +123TE T 31.774 |] 2.86 8 XKB4 +123TE T 31.812 |] XKO23 +123TE T +123TE T 3.336-4.82 9.0 4 XL (total) +123TE T 3.336 0.159 5 XLL +123TE T 3.76-3.77 4.22 11 XLA +123TE T 3.606 0.0598 18 XLC +123TE T 4.02-4.37 2.91 7 XLB +123TE T 4.44-4.82 0.366 10 XLG +123TE T +123TE T 21.804-22.989 |] KLL AUGER +123TE T 25.814-27.47 |] 12.4 4 KLX AUGER +123TE T 29.8-31.81 |] KXY AUGER +123TE T 2.3-4.8 95.3 6 L AUGER +123I P 0.0 5/2+ 13.2234 H 37 1234 3 +123TE N 1.0 1.0 1 1.0 +123TE L 0 1/2+ 12E12 Y +123TE L 158.99 3 3/2+ 196 PS 9 +123TE E 97.18 325.26 +123TE2 E CK=0.8533 14$CL=0.1163 10$CM=0.0248 5$CN=0.0056 3 +123TE G 158.97 5 83.25 21M1+E2 0.111 3 0.1918 19 +123TE2 G KC=0.1648 16$LC=0.02160 22 +123TE L 440.00 4 3/2+ 22 PS 3 +123TE E 0.419 57.35 +123TE2 E CK=0.8510 14$CL=0.1181 10$CM=0.0253 5$CN=0.0056 3 +123TE G 281.03 5 0.0789 9M1+E2 -0.39 15 0.0422 33 +123TE2 G KC=0.0362 20$LC=0.0048 11 +123TE G 440.02 5 0.4229 43M1+E2 -2.1 1 0.0121 7 +123TE2 G KC=0.0103 7$LC=0.001452 18 +123TE L 489.70 8 (7/2)+ 30.7 NS +123TE E 0.0025 109.52 +123TE2 E CK=0.8503 14$CL=0.1186 10$CM=0.0254 5$CN=0.0057 3 +123TE G 330.70 8 0.01164 33E2 0.0284 9 +123TE2 G KC=0.0237 7$LC=0.00376 11 +123TE L 505.34 4 (5/2)+ 13.5 PS 25 +123TE E 0.349 427.35 +123TE2 E CK=0.8501 14$CL=0.1187 10$CM=0.0254 5$CN=0.0058 3 +123TE G 346.35 5 0.1257 9M1+E2 0.07 7 0.0240723 +123TE2 G KC=0.02080 14$LC=0.00262 29 +123TE G 505.33 5 0.266 42M1+E2 0.10 2 0.0093 7 +123TE2 G KC=0.0081 7$LC=0.001063 27 +123TE L 599.57 151/2+ +123TE G 599.69 160.00266 17 +123TE L 687.95 4 3/2+ +123TE E 1.40 126.49 +123TE2 E CK=0.8466 14$CL=0.1214 10$CM=0.0261 5$CN=0.0059 3 +123TE G 182.61 6 0.018 5M1+E2 1 0.168 38 +123TE2 G KC=0.138 24$LC=0.024 10 +123TE G 198.23 0.0035 7M1+E2 1 0.130 26 +123TE2 G KC=0.107 17$LC=0.018 7 +123TE G 247.96 5 0.0698 23M1+E2 1 0.065 8 +123TE2 G KC=0.054 5$LC=0.0084 21 +123TE G 528.96 5 1.28 12 +123TE G 687.95 100.0269 6 +123TE L 697.52 5 7/2+ +123TE E 0.419 136.98 +123TE2 E CK=0.8464 14$CL=0.1216 10$CM=0.0262 5$CN=0.0058 3 +123TE G 192.17 7 0.0199 7M1+E2 1 0.143 30 +123TE2 G KC=0.118 20$LC=0.020 8 +123TE G 207.8 0.00112 32M1+E2 1 0.119 20 +123TE2 G KC=0.093 14$LC=0.015 5 +123TE G 257.51 150.0016 2E2 0.0640 19 +123TE2 G KC=0.0526 16$LC=0.00917 27 +123TE G 538.54 5 0.3788 43E2+M3 1 0.038 31 +123TE2 G KC=0.032 26$LC=0.0049 41 +123TE L 769.26 14 +123TE E 0.0037 68.92 +123TE2 E CK=0.8441 14$CL=0.1233 10$CM=0.0266 5$CN=0.0060 3 +123TE G 329.38 170.0026 6 +123TE G 610.05 230.0011 3 +123TE L 783.60 4 3/2,5/2+ 52 FS 33 +123TE E 0.1461 207.29 +123TE2 E CK=0.8436 14$CL=0.1237 10$CM=0.0267 5$CN=0.0060 3 +123TE G 278.36 120.0023 4M1+E2 1 0.0459 36 +123TE2 G KC=0.0387 22$LC=0.0058 11 +123TE G 343.73 140.0044 3 +123TE G 624.57 5 0.0798 20M1+E2 1.30 35 0.0049 6 +123TE2 G KC=0.0042 5$LC=0.000549 40 +123TE G 783.59 6 0.0591 11 +123TE L 894.74 6 3/2,5/2+ 45 FS 24 +123TE E 0.0744 137.32 +123TE2 E CK=0.8377 15$CL=0.1283 11$CM=0.0278 5$CN=0.0062 3 +123TE G 197.22 0.00033 17M1+E2 1 0.132 26 +123TE2 G KC=0.109 18$LC=0.018 7 +123TE G 206.79 0.0033 8M1+E2 1 0.114 21 +123TE2 G KC=0.094 14$LC=0.016 5 +123TE G 295.17 0.001582 4 +123TE G 405.02 130.00298 23 +123TE G 454.76 150.00412 22 +123TE G 735.78 7 0.0616 8 +123TE G 894.8 2 0.00101 7 +123TE L 996.06 12(5/2)- +123TE E 0.0035 38.31 +123TE2 E CK=0.8266 16$CL=0.1363 12$CM=0.0300 6$CN=0.0067 4 +123TE G 556.05 130.0029 3 +123TE G 837.1 2 0.000582 8 +123TE L 1036.64 123/2,5/2+ 43 FS 16 +123TE E 0.0025 98.27 +123TE2 E CK=0.8182 18$CL=0.1427 13$CM=0.0316 6$CN=0.0071 4 +123TE G 437.5 3 0.0007 7 +123TE G 877.52 170.00083 7 +123TE G 1036.63 170.00097 7 +123TE L 1068.18 8 3/2,5/2+ +123TE E 0.0079 47.59 +123TE2 E CK=0.8082 21$CL=0.1503 15$CM=0.0336 7$CN=0.0075 4 +123TE G 174.2 3 0.00083 25M1+E2 1 0.195 47 +123TE2 G KC=0.159 32$LC=0.029 12 +123TE G 562.79 120.00115 7 +123TE G 578.26 200.00126 8 +123TE G 628.26 220.00164 14 +123TE G 909.12 120.00141 8 +123TE G 1068.12 150.00142 7 + diff --git a/HEN_HOUSE/spectra/lnhb/I-125.txt b/HEN_HOUSE/spectra/lnhb/I-125.txt index 776eae791..057ce7c10 100644 --- a/HEN_HOUSE/spectra/lnhb/I-125.txt +++ b/HEN_HOUSE/spectra/lnhb/I-125.txt @@ -1,46 +1,44 @@ -125TE 125I EC DECAY (59.388 D) -125TE H TYP=Full$AUT=V. Chisté$CUT=30-AUG-2010$ -125TE2 H TYP=Update$AUT=M.M. Bé$CUT= -- $ -125TE3 H TYP=Full$AUT=E.Schönfeld$CUT= -- $ -125TE C Evaluation history: Type=Full;Author=V. Chisté;Cutoff date=30-AUG-2010 -125TE2C Type=Update;Author=M.M. Bé;Cutoff date= -- -125TE3C Type=Full;Author=E.Schönfeld;Cutoff date= -- -125TE C References: 1946Re**, 1951Fr21, 1958Ku82, 1960Ma36, 1963Ge**, 1964Le05, -125TE2C 1965An07, 1966Ri14, 1968La10, 1969Ka08, 1972Em01, 1977Kr13, 1979Ku**, -125TE3C 1980Ho17, 1979CoZG, 1982HoZJ, 1983De11, 1983Ku**, 1987Sc20, 1989Si19, -125TE4C 1990Wo03, 1990Iw04, 1990De09, 1991Al05, 1992ScZZ, 1995Ra32, 1996Sc06, -125TE5C 1999Ka26, 2002Un02, 2003Au03, 2006Da20, 2008Ki07 -125TE T Auger electrons and X ray energies and emission intensities: -125TE T {U Energy (keV)} {U Intensity} {U Line} -125TE T -125TE T 27.202 39.3 5 XKA2 -125TE T 27.4726 73.2 8 XKA1 -125TE T -125TE T 30.9446 |] XKB3 -125TE T 30.996 |] 20.9 3 XKB1 -125TE T 31.236 |] XKB5II -125TE T -125TE T 31.7008 |] XKB2 -125TE T 31.774 |] 4.54 13 XKB4 -125TE T 31.812 |] XKO23 -125TE T -125TE T 3.3348-4.8228 14.70 28 XL (total) -125TE T 3.3348 0.281 9 XLL -125TE T 3.7595-3.7697 7.45 20 XLA -125TE T 3.6052 0.108 4 XLC -125TE T 4.0299-4.3661 6.02 13 XLB -125TE T 4.4448-4.8228 0.844 19 XLG -125TE T -125TE T 21.804-22.989 |] KLL AUGER -125TE T 25.814-27.47 |] 19.7 7 KLX AUGER -125TE T 29.8-31.81 |] KXY AUGER -125TE T 2.3-4.8 158.2 8 L AUGER -125I P 0.0 5/2+ 59.388 D 28 185.77 6 -125TE N 1.0 1.0 1 1.0 -125TE L 0 1/2+ STABLE -125TE L 35.4922 5 3/2+ 1.48 NS -125TE E 100 5.4 -125TE2 E CK=0.8011 17$CL=0.1561 13$CM=0.0349 7$CN=0.0079 4$CO=0 0 -125TE G 35.4922 5 6.63 6M1+E2 0.085 6 14.08 22 -125TE2 G KC=11.70 17$LC=1.91 8$MC=0.386 16 - +125TE 125I EC DECAY (59.388 D) +125TE H TYP=FUL$AUT=V.CHISTE$CUT=30-AUG-2010$ +125TE2 H TYP=UPD$AUT=M.-M.BE$CUT=24-JUL-2002$ +125TE3 H TYP=FUL$AUT=E.SCHONFELD$CUT=02-JAN-1998$ +125TE C References:1946Re**, 1951Fr21, 1958Ku82, 1960Ma36, 1963Ge**, 1964Le05, +125TE2C 1965An07, 1966Ri14, 1968La10, 1969Ka08, 1972Em01, 1977Kr13, 1979Ku**, +125TE3C 1980Ho17, 1979CoZG, 1982HoZJ, 1983De11, 1983Ku**, 1987Sc20, 1989Si19, +125TE4C 1990Wo03, 1990Iw04, 1990De09, 1991Al05, 1992ScZZ, 1995Ra32, 1996Sc06, +125TE5C 1999Ka26, 2002Un02, 2003Au03, 2006Da20, 2008Ki07 +125TE T Auger electrons and X ray energies and emission intensities: +125TE T {U Energy (keV)} {U Intensity} {U Line} +125TE T +125TE T 27.202 39.3 5 XKA2 +125TE T 27.4726 73.2 8 XKA1 +125TE T +125TE T 30.9446 |] XKB3 +125TE T 30.996 |] 20.9 3 XKB1 +125TE T 31.236 |] XKB5II +125TE T +125TE T 31.7008 |] XKB2 +125TE T 31.774 |] 4.54 13 XKB4 +125TE T 31.812 |] XKO23 +125TE T +125TE T 3.3348-4.8228 14.70 28 XL (total) +125TE T 3.3348 0.281 9 XLL +125TE T 3.7595-3.7697 7.45 20 XLA +125TE T 3.6052 0.108 4 XLC +125TE T 4.0299-4.3661 6.02 13 XLB +125TE T 4.4448-4.8228 0.844 19 XLG +125TE T +125TE T 21.804-22.989 |] KLL AUGER +125TE T 25.814-27.47 |] 19.7 7 KLX AUGER +125TE T 29.8-31.81 |] KXY AUGER +125TE T 2.3-4.8 158.2 8 L AUGER +125I P 0.0 5/2+ 59.388 D 28 185.77 6 +125TE N 1.0 1.0 1 1.0 +125TE L 0 1/2+ STABLE +125TE L 35.4922 5 3/2+ 1.48 NS +125TE E 100 5.4 +125TE2 E CK=0.8011 17$CL=0.1561 13$CM=0.0349 7$CN=0.0079 4 +125TE G 35.4922 5 6.63 6M1+E2 0.085 6 14.08 22 +125TE2 G KC=11.70 17$LC=1.91 8$MC=0.386 16$NC=0.075 3 +125TE3 G OC=0.00766 23 + diff --git a/HEN_HOUSE/spectra/lnhb/I-129.txt b/HEN_HOUSE/spectra/lnhb/I-129.txt index c8a5792cd..bcc3c4da7 100644 --- a/HEN_HOUSE/spectra/lnhb/I-129.txt +++ b/HEN_HOUSE/spectra/lnhb/I-129.txt @@ -1,34 +1,33 @@ -129XE 129I B- DECAY (16.1E6 Y) -129XE T Auger electrons and X ray energies and emission intensities: -129XE T {U Energy (keV)} {U Intensity} {U Line} -129XE T -129XE T 29.459 20.1 3 XKA2 -129XE T 29.779 37.2 6 XKA1 -129XE T -129XE T 33.562 |] XKB3 -129XE T 33.625 |] 10.3 4 XKB1 -129XE T 33.881 |] XKB5II -129XE T -129XE T 34.415 |] XKB2 -129XE T 34.496 |] 2.30 13 XKB4 -129XE T 34.552 |] XKO23 -129XE T -129XE T 3.6-5.4 7.9 4 XL (total) -129XE T 3.6 XLL -129XE T -5.4 XLG -129XE T -129XE T 23.512-24.842 |] KLL AUGER -129XE T 27.897-29.77 |] 8.8 4 KLX AUGER -129XE T 32.27-34.54 |] KXY AUGER -129XE T 2.4-5.4 73.9 12 L AUGER -129I P 0.0 7/2+ 16.1E6 Y 7 190.8 11 -129XE N 1.0 1.0 1 1.0 -129XE L 0 1/2+ STABLE -129XE B 190.8 110.5 5 14.9 2U -129XES B EAV= -129XE L 39.578 4 3/2+ 1 NS -129XE B 151.2 1199.5 5 13.49 2 -129XES B EAV=37 1 -129XE G 39.578 4 7.42 8M1+E2 12.41 13 -129XE2 G KC=10.59 11$LC=1.45 5$MC=0.296 10 - +129XE 129I B- DECAY (16.1E6 Y) +129XE T Auger electrons and X ray energies and emission intensities: +129XE T {U Energy (keV)} {U Intensity} {U Line} +129XE T +129XE T 29.459 20.1 3 XKA2 +129XE T 29.779 37.2 6 XKA1 +129XE T +129XE T 33.562 |] XKB3 +129XE T 33.625 |] 10.3 4 XKB1 +129XE T 33.881 |] XKB5II +129XE T +129XE T 34.415 |] XKB2 +129XE T 34.496 |] 2.30 13 XKB4 +129XE T 34.552 |] XKO23 +129XE T +129XE T 3.6-5.4 7.9 4 XL (total) +129XE T 3.6 XLL +129XE T -5.4 XLG +129XE T +129XE T 23.512-24.842 |] KLL AUGER +129XE T 27.897-29.77 |] 8.8 4 KLX AUGER +129XE T 32.27-34.54 |] KXY AUGER +129XE T 2.4-5.4 73.9 12 L AUGER +129I P 0.0 7/2+ 16.1E6 Y 7 190.8 11 +129XE N 1.0 1.0 1 1.0 +129XE L 0 1/2+ STABLE +129XE B 190.8 110.5 5 14.9 2U +129XE L 39.578 4 3/2+ 1 NS +129XE B 151.2 1199.5 5 13.49 2 +129XES B EAV=37 1 +129XE G 39.578 4 7.42 8M1+E2 12.41 13 +129XE2 G KC=10.59 11$LC=1.45 5$MC=0.296 10$NC=0.074 3 + diff --git a/HEN_HOUSE/spectra/lnhb/I-131.txt b/HEN_HOUSE/spectra/lnhb/I-131.txt index 450622e34..d00d4a1bc 100644 --- a/HEN_HOUSE/spectra/lnhb/I-131.txt +++ b/HEN_HOUSE/spectra/lnhb/I-131.txt @@ -1,99 +1,115 @@ -131XE 131I B- DECAY (8.0233 D) -131XE H TYP=Full$AUT=M.M. Bé$CUT=30-NOV-2013$ -131XE2 H TYP=Full$AUT=V. Chisté$CUT=01-DEC-2001$ -131XE C Evaluation history: Type=Full;Author=M.M. Bé;Cutoff date=30-NOV-2013 -131XE2C Type=Full;Author=V. Chisté;Cutoff date=01-DEC-2001 -131XE C References: 1938Li05, 1951Si25, 1952Be95, 1952Be55, 1953Lo09, 1953Ba10, -131XE2C 1953Se28, 1958Bu14, 1958Ke26, 1962Wo09, 1963Ju02, 1963Ha08, 1964Da19, -131XE3C 1966Mo10, 1967Yt02, 1967Ya02, 1967Gr05, 1968Ke05, 1970Be46, 1971Zo02, -131XE4C 1972Kr07, 1972Em01, 1974Me21, 1974Ko02, 1974Ka37, 1975Ko15, 1976ba42, -131XE5C 1977Kr13, 1978La21, 1979Ir01, 1980Ho17, 1982HoZF, 1983Wa26, 1989Ch45, -131XE6C 1990Me15, 1994Se10, 1996Sc06, 2002Ba85, 2004Da05, 2004Sc04, 2008Ki07, -131XE7C 2012Wa38, 2012Fi12 -131XE T Auger electrons and X ray energies and emission intensities: -131XE T {U Energy (keV)} {U Intensity} {U Line} -131XE T -131XE T 29.459 1.52 4 XKA2 -131XE T 29.779 2.81 6 XKA1 -131XE T -131XE T 33.562 |] XKB3 -131XE T 33.625 |] 0.816 19 XKB1 -131XE T 33.881 |] XKB5II -131XE T -131XE T 34.415 |] XKB2 -131XE T 34.496 |] 0.193 6 XKB4 -131XE T 34.552 |] XKO23 -131XE T -131XE T 3.64-5.3 0.631 13 XL (total) -131XE T 3.64 0.0122 4 XLL -131XE T 4.1-4.11 0.321 9 XLA -131XE T 3.96 0.00461 15 XLC -131XE T 4.42-4.78 0.256 6 XLB -131XE T 4.89-5.3 0.0377 9 XLG -131XE T -131XE T 23.512-24.842 |] KLL AUGER -131XE T 27.897-29.77 |] 0.67 4 KLX AUGER -131XE T 32.27-34.54 |] KXY AUGER -131XE T 2.5-5.43 5.87 4 L AUGER -131I P 0.0 7/2+ 8.0233 D 19 970.8 6 -131XE N 1.0 1.0 1 1.0 -131XE L 0 3/2+ STABLE -131XE L 80.1854 191/2+ 0.48 NS 3 -131XE G 80.1850 202.607 35M1 1.544 46 -131XE2 G KC=1.32 4$LC=0.175 5$MC=0.036 1 -131XE L 163.930 8 11/2- 11.962 D 20 -131XE B 806.9 6 0.386 23 10.03 1U -131XES B EAV=267.91 23 -131XE G 163.930 8 0.0211 3M4 50.5 7 -131XE2 G KC=31.6 5$LC=14.75 21$MC=3.38 5 -131XE L 341.144 9 9/2- 1.6 NS 4 -131XE B 629.7 6 0.060 12 9.8 1 -131XES B EAV=200.23 22 -131XE G 177.214 200.277 7M1+()E2 -4.3 4 0.241 7 -131XE2 G KC=0.187 6$LC=0.0427 13$MC=0.00901 27 -131XE L 364.490 4 5/2+ 69 PS 2 -131XE B 606.3 6 89.4 8 6.64 -131XES B EAV=191.59 22 -131XE G 284.305 5 6.14 6E2 0.0497 7 -131XE2 G KC=0.0408 6$LC=0.00714 10$MC=1479E-6 21 -131XE G 364.489 5 81.2 5M1+()E2 -4.53 11 0.0228 4 -131XE2 G KC=0.0190 3$LC=0.00300 5$MC=6.16E-4 9 -131XE L 404.815 4 3/2+ 18 PS 3 -131XE G 324.651 250.0244 25M1+E2 0.0329 6 -131XE2 G KC=0.0278 10$LC=0.0041 4$MC=0.00083 9 -131XE G 404.814 4 0.0552 17M1+E2 1.0 9 0.0177 12 -131XE2 G KC=0.0151 13$LC=0.00210 4$MC=4.29E-4 11 -131XE L 636.990 4 7/2+ 6.1 PS 5 -131XE B 333.8 6 7.20 7 6.86 -131XES B EAV=96.61 19 -131XE G 232.18 150.0023 9[E2] 0.097 2 -131XE2 G KC=0.0782 22$LC=0.0151 5$MC=0.0031 1 -131XE G 272.498 170.0581 15M1+()E2 -0.38 17 0.0530 9 -131XE2 G KC=0.0453 7$LC=0.0061 3$MC=0.00125 6 -131XE G 295.80 200.0012 6[E1] 0.0108 3 -131XE2 G KC=0.0093 2$LC=0.00117 3$MC=0.00024 4 -131XE G 636.989 4 7.12 7E2 0.00470 7 -131XE2 G KC=0.00401 6$LC=5.51E-4 8$MC=1123E-7 16 -131XE L 666.934 9 7/2- 0.5 NS -131XE B 303.9 6 0.643 27 7.79 -131XES B EAV=86.94 19 -131XE G 302.40 200.0046 7[E1] 0.0102 2 -131XE2 G KC=0.0088 2$LC=0.00111 1$MC=0.00022 1 -131XE G 325.7890 400.274 8M1+()E2 -0.8 7 0.0335 10 -131XE2 G KC=0.0288 9$LC=0.00376 11$MC=7.65E-4 23 -131XE G 503.0040 400.3540 46E2 0.0088313 -131XE2 G KC=0.00748 11$LC=1083E-6 16$MC=2.21E-4 3 -131XE L 722.909 4 5/2+ 0.53 PS 5 -131XE B 247.9 6 2.130 21 6.98 -131XES B EAV=69.35 19 -131XE G 85.9 2 0.0051 7[M1E2] 2.2 1 -131XE2 G KC=1.50 6$LC=0.56 2 -131XE G 318.088 160.0807 20M1+()E2 -0.11 8 0.0350 5 -131XE2 G KC=0.0301 5$LC=0.00388 6$MC=7.86E-4 12 -131XE G 358.4 2 0.017 8[M1E2] 0.0248 10 -131XE2 G KC=0.0210 12$LC=0.00301 18$MC=0.00061 5 -131XE G 642.719 5 0.2183 26[E2] 0.0046 1 -131XE2 G KC=0.0039 1$LC=0.00054 1$MC=0.00011 2 -131XE G 722.911 5 1.786 19M1+()E2 0.207 5 0.00451 7 -131XE2 G KC=0.00390 6$LC=4.88E-4 7$MC=9.87E-5 14 - +131XE 131I B- DECAY (8.0233 D) +131XE H TYP=FUL$AUT=M.-M.BE$CUT=30-NOV-2013$ +131XE2 H TYP=FUL$AUT=V.CHISTE$CUT=01-DEC-2001$ +131XE C References:1938Li05, 1951Si25, 1952Be95, 1952Be55, 1953Lo09, 1953Ba10, +131XE2C 1953Se28, 1958Bu14, 1958Ke26, 1962Wo09, 1963Ju02, 1963Ha08, 1964Da19, +131XE3C 1966Mo10, 1967Yt02, 1967Ya02, 1967Gr05, 1968Ke05, 1970Be46, 1971Zo02, +131XE4C 1972Kr07, 1972Em01, 1974Me21, 1974Ko02, 1974Ka37, 1975Ko15, 1976ba42, +131XE5C 1977Kr13, 1978La21, 1979Ir01, 1980Ho17, 1982HoZF, 1983Wa26, 1989Ch45, +131XE6C 1990Me15, 1994Se10, 1996Sc06, 2002Ba85, 2004Da05, 2004Sc04, 2008Ki07, +131XE7C 2012Wa38, 2012Fi12 +131XE T Auger electrons and X ray energies and emission intensities: +131XE T {U Energy (keV)} {U Intensity} {U Line} +131XE T +131XE T 29.459 1.52 4 XKA2 +131XE T 29.779 2.81 6 XKA1 +131XE T +131XE T 33.562 |] XKB3 +131XE T 33.625 |] 0.816 19 XKB1 +131XE T 33.881 |] XKB5II +131XE T +131XE T 34.415 |] XKB2 +131XE T 34.496 |] 0.193 6 XKB4 +131XE T 34.552 |] XKO23 +131XE T +131XE T 3.64-5.3 0.631 13 XL (total) +131XE T 3.64 0.0122 4 XLL +131XE T 4.1-4.11 0.321 9 XLA +131XE T 3.96 0.00461 15 XLC +131XE T 4.42-4.78 0.256 6 XLB +131XE T 4.89-5.3 0.0377 9 XLG +131XE T +131XE T 23.512-24.842 |] KLL AUGER +131XE T 27.897-29.77 |] 0.67 4 KLX AUGER +131XE T 32.27-34.54 |] KXY AUGER +131XE T 2.5-5.43 5.87 4 L AUGER +131I P 0.0 7/2+ 8.0233 D 19 970.8 6 +131XE N 1.0 1.0 1 1.0 +131XE L 0 3/2+ STABLE +131XE L 80.1854 191/2+ 0.48 NS 3 +131XE G 80.1850 202.607 35M1 1.544 46 +131XE2 G KC=1.32 4$LC=0.175 5$MC=0.036 1$NC=0.00737 11 +131XE3 G OC=0.000919 13 +131XE L 163.930 8 11/2- 11.962 D 20 +131XE B 806.9 6 0.386 23 10.03 1U +131XES B EAV=267.91 23 +131XE G 163.930 8 0.0211 3M4 50.5 7 +131XE2 G KC=31.6 5$LC=14.75 21$MC=3.38 5$NC=0.691 10 +131XE3 G OC=0.0755 11 +131XE L 341.144 9 9/2- 1.6 NS 4 +131XE B 629.7 6 0.060 12 9.8 1 +131XES B EAV=200.23 22 +131XE G 177.214 200.277 7M1+E2 -4.3 4 0.241 7 +131XE2 G KC=0.187 6$LC=0.0427 13$MC=0.00901 27$NC=0.00192 6 +131XE3 G OC=0.000245 7 +131XE L 364.490 4 5/2+ 69 PS 2 +131XE B 606.3 6 89.4 8 6.64 +131XES B EAV=191.59 22 +131XE G 284.305 5 6.14 6E2 0.0497 7 +131XE2 G KC=0.0408 6$LC=0.00714 10$MC=0.001479 21$NC=0.000300 5 +131XE3 G OC=3.42E-5 5 +131XE G 364.489 5 81.2 5M1+E2 -4.53 11 0.0228 4 +131XE2 G KC=0.0190 3$LC=0.00300 5$MC=0.000616 9$NC=1.256E-4 18 +131XE3 G OC=1.473E-5 21 +131XE L 404.815 4 3/2+ 18 PS 3 +131XE G 324.651 250.0244 25M1+E2 0.0329 6 +131XE2 G KC=0.0278 10$LC=0.0041 4$MC=0.00083 9$NC=0.000171 17 +131XE3 G OC=2.05E-5 13 +131XE G 404.814 4 0.0552 17M1+E2 1.0 9 0.0177 12 +131XE2 G KC=0.0151 13$LC=0.00210 4$MC=0.000429 11$NC=8.81E-5 17 +131XE3 G OC=1.072E-5 24 +131XE L 636.990 4 7/2+ 6.1 PS 5 +131XE B 333.8 6 7.20 7 6.86 +131XES B EAV=96.61 19 +131XE G 232.18 150.0023 9[E2] 0.097 2 +131XE2 G KC=0.0782 22$LC=0.0151 5$MC=0.0031 1$NC=0.000634 9 +131XE3 G OC=7.09E-5 10 +131XE G 272.498 170.0581 15M1+E2 -0.38 17 0.0530 9 +131XE2 G KC=0.0453 7$LC=0.0061 3$MC=0.00125 6$NC=0.000257 12 +131XE3 G OC=3.17E-5 11 +131XE G 295.80 200.0012 6[E1] 0.0108 3 +131XE2 G KC=0.0093 2$LC=0.00117 3$MC=0.00024 4$NC=4.87E-5 7 +131XE3 G OC=5.98E-6 9 +131XE G 636.989 4 7.12 7E2 0.00470 7 +131XE2 G KC=0.00401 6$LC=0.000551 8$MC=1.123E-4 16$NC=2.31E-5 4 +131XE3 G OC=2.81E-6 4 +131XE L 666.934 9 7/2- 0.5 NS +131XE B 303.9 6 0.643 27 7.79 +131XES B EAV=86.94 19 +131XE G 302.40 200.0046 7[E1] 0.0102 2 +131XE2 G KC=0.0088 2$LC=0.00111 1$MC=0.00022 1$NC=4.59E-5 7 +131XE3 G OC=5.65E-6 8 +131XE G 325.7890 400.274 8M1+E2 -0.8 7 0.0335 10 +131XE2 G KC=0.0288 9$LC=0.00376 11$MC=0.000765 23$NC=0.000168 5 +131XE3 G OC=2.47E-5 7 +131XE G 503.0040 400.3540 46E2 0.0088313 +131XE2 G KC=0.00748 11$LC=0.001083 16$MC=0.000221 3$NC=4.53E-5 7 +131XE3 G OC=5.44E-6 8 +131XE L 722.909 4 5/2+ 0.53 PS 5 +131XE B 247.9 6 2.130 21 6.98 +131XES B EAV=69.35 19 +131XE G 85.9 2 0.0051 7[M1,E2] 2.2 1 +131XE2 G KC=1.50 6$LC=0.56 2 +131XE G 318.088 160.0807 20M1+E2 -0.11 8 0.0350 5 +131XE2 G KC=0.0301 5$LC=0.00388 6$MC=0.000786 12$NC=1.628E-4 25 +131XE3 G OC=2.04E-5 3 +131XE G 358.4 2 0.017 8[M1,E2] 0.0248 10 +131XE2 G KC=0.0210 12$LC=0.00301 18$MC=0.00061 5$NC=0.000126 8 +131XE3 G OC=1.53E-5 4 +131XE G 642.719 5 0.2183 26[E2] 0.0046 1 +131XE2 G KC=0.0039 1$LC=0.00054 1$MC=0.00011 2$NC=2.25E-5 4 +131XE3 G OC=2.74E-6 4 +131XE G 722.911 5 1.786 19M1+E2 0.207 5 0.00451 7 +131XE2 G KC=0.00390 6$LC=0.000488 7$MC=9.87E-5 14$NC=2.04E-5 3 +131XE3 G OC=2.57E-6 4 + diff --git a/HEN_HOUSE/spectra/lnhb/I-133.txt b/HEN_HOUSE/spectra/lnhb/I-133.txt index f6237b12b..50ef6a274 100644 --- a/HEN_HOUSE/spectra/lnhb/I-133.txt +++ b/HEN_HOUSE/spectra/lnhb/I-133.txt @@ -1,135 +1,151 @@ -133XE 133I B- DECAY (20.87 H) -133XE H TYP=Full$AUT=M.Galan$CUT= -- $ -133XE C Evaluation history: Type=Full;Author=M.Galan;Cutoff date= -- -133XE C References: 1953KA28, 1955WA35, 1959HO97, 1960EI01, 1965AN05, 1966EI01, -133XE2C 1968RE04, 1971SA09, 1972KR07, 1972AC02, 1972BE90, 1974KO26, 1976FU06, -133XE3C 1976ME16, 1977KR13, 1983LO08, 1989RA17, 1995RA12, 1996SC06, 2002BA85, -133XE4C 2003AU03 -133XE T Auger electrons and X ray energies and emission intensities: -133XE T {U Energy (keV)} {U Intensity} {U Line} -133XE T -133XE T 29.459 0.163 4 XKA2 -133XE T 29.779 0.303 6 XKA1 -133XE T -133XE T 33.562 |] XKB3 -133XE T 33.625 |] 0.0877 19 XKB1 -133XE T 33.881 |] XKB5II -133XE T -133XE T 34.415 |] XKB2 -133XE T 34.496 |] 0.0207 7 XKB4 -133XE T 34.552 |] XKO23 -133XE T -133XE T 3.6378-5.296 0.0724 14 XL (total) -133XE T 3.6378 0.00149 5 XLL -133XE T 4.0977-4.1103 0.039 1 XLA -133XE T 3.9576 0.00048315 XLC -133XE T 4.4176-4.7758 0.0275 6 XLB -133XE T 4.895-5.296 0.003890 9 XLG -133XE T -133XE T 23.512-24.842 |] KLL AUGER -133XE T 27.897-29.77 |] 0.072 4 KLX AUGER -133XE T 32.27-34.54 |] KXY AUGER -133XE T 2.4-5.2 0.677 4 L AUGER -133I P 0.0 7/2+ 20.87 H 8 1757 4 -133XE N 1.0 1.0 1 1.0 -133XE G 167.97 6 0.078 17 -133XE G 567.1 4 0.003 3 -133XE G 1018.1 5 0.0060 26 -133XE L 0 0 3/2+ 5.2474 D 5 -133XE L 233.219 1511/2- 2.198 D 13 -133XE B 1524 4 1.07 6 9.92 1U -133XES B EAV=572.0 17 -133XE G 233.219 150.293 4M4 8.84 12 -133XE2 G KC=6.24 9$LC=2.035 29$MC=0.453 6 -133XE L 262.702 601/2+ -133XE G 262.70 6 0.356 12M1+E2 0.0577 8 -133XE2 G KC=0.0497 7$LC=0.00641 9$MC=1300E-6 18 -133XE L 529.872 3 5/2+ -133XE B 1227 4 83.42 21 6.81 -133XES B EAV=439.4 17 -133XE G 267.17 6 0.117 7 -133XE G 529.8709 3086.3 2M1+E2 1.85 20 0.0081014 -133XE2 G KC=0.00691 13$LC=9.56E-4 14$MC=1948E-7 29 -133XE L 680.254 9 3/2+ -133XE G 150.382 9 0.029 6 -133XE G 417.55 6 0.153 10M1+E2 1.0 13 0.0163 11 -133XE2 G KC=0.0139 10$LC=1921E-6 27$MC=3.92E-4 6 -133XE G 680.252 9 0.645 19M1 0.00527 7 -133XE2 G KC=$LC=5.70E-4 8$MC=1152E-7 16 -133XE L 743.750 16(7/2,9/2,11/2)- -133XE B 1013 4 1.81 6 8.17 -133XES B EAV=350.5 17 -133XE G 510.530 221.81 6 -133XE L 875.331 5 (7/2)+ -133XE B 882 4 4.16 13 7.59 -133XES B EAV=297.4 16 -133XE G 345.459 6 0.104 18 -133XE G 875.328 5 4.47 12E2+M3 0.00218 3 -133XE2 G KC=1876E-6 26$LC=2.45E-4 3$MC=4.96E-5 7 -133XE L 911.45 3 (1/2,3/2)+ -133XE B 846 4 0.026 18 9.7 2U -133XES B EAV=283.1 16 -133XE G 381.578 300.045 5 -133XE G 648.75 7 0.056 13M1 0.00590 8 -133XE2 G KC=0.00510 7$LC=6.39E-4 9$MC=1292E-7 18 -133XE G 911.447 300.046 6 -133XE L 1052.397 175/2+ -133XE B 706 4 0.58 5 8.09 -133XES B EAV=228.4 16 -133XE G 372.143 190.009 6 -133XE G 522.524 170.04 5 -133XE G 789.69 6 0.050 4 -133XE G 1052.393 170.551 16 -133XE L 1236.449 5 (7/2)+ -133XE B 521 4 3.12 6 6.91 -133XES B EAV=160.4 15 -133XE G 361.118 7 0.11 4 -133XE G 556.194 100.020 3 -133XE G 706.575 6 1.49 4M1+E2 0.0042 6 -133XE2 G KC=0.0036 6$LC=0.00047 5$MC=9.5E-5 10 -133XE G 1236.443 5 1.49 4 -133XE L 1298.234 5 5/2+ -133XE B 459 4 3.75 7 6.64 -133XES B EAV=138.7 14 -133XE G 245.837 180.035 9 -133XE G 386.784 300.059 5 -133XE G 422.903 7 0.309 10M1+E2 1.8 12 0.0151 13 -133XE2 G KC=0.0128 13$LC=0.00185 3$MC=3.79E-4 6 -133XE G 554.483 170.0004 5 -133XE G 617.978 100.539 15M1+E2 0.0059 8 -133XE2 G KC=0.0050 7$LC=0.00066 6$MC=1.34E-4 12 -133XE G 768.360 6 0.457 15M1+E2 0.6 4 0.0036824 -133XE2 G KC=0.00318 22$LC=4.02E-4 22$MC=8.1E-5 4 -133XE G 1035.53 6 0.0086 18 -133XE G 1298.227 5 2.33 7M1+E2 4.2 3 9.72E-414 -133XE2 G KC=8.22E-4 12$LC=1026E-7 15$MC=2070E-8 29 -133XE L 1350.380 175/2+ -133XE B 407 4 0.397 12 7.44 -133XES B EAV=120.8 14 -133XE G 438.930 340.040 5 -133XE G 670.124 190.042 6 -133XE G 820.505 170.154 6M1+E2 0.8 8 0.0031 4 -133XE2 G KC=0.0026 3$LC=0.00033 3$MC=6.8E-5 6 -133XE G 1087.67 6 0.0121 18 -133XE G 1350.373 170.148 5M1+E2 0.0010112 -133XE2 G KC=0.00085 10$LC=1.04E-4 12$MC=2.11E-5 23 -133XE L 1386.153 8 7/2+ -133XE B 371 4 1.25 4 6.81 -133XES B EAV=108.8 14 -133XE G 510.821 9 0.004 5 -133XE G 856.278 9 1.23 4M1+E2 3.7 3 0.00235 3 -133XE2 G KC=0.00202 3$LC=2.63E-4 4$MC=5.33E-5 8 -133XE G 1386.145 8 0.0086 26[E2] -133XE L 1589.94 3 5/2+ -133XE B 167 4 0.414 15 6.18 -133XES B EAV=45.1 12 -133XE G 203.787 310.00432 8 -133XE G 537.542 340.035 7 -133XE G 678.488 420.022 7 -133XE G 909.683 310.212 9M1+E2 0.40 6 0.00257 4 -133XE2 G KC=0.00222 4$LC=2.77E-4 5$MC=5.59E-5 9 -133XE G 1060.063 0.137 7M1+E2 0.0016523 -133XE2 G KC=0.00143 20$LC=1.79E-4 22$MC=3.6E-5 4 -133XE G 1327.23 7 0.00022 22 -133XE G 1589.93 3 0.0029 4 - +133XE 133I B- DECAY (20.87 H) +133XE H TYP=FUL$AUT=M.GALAN$CUT=01-JAN-2008$ +133XE C References:1953KA28, 1955WA35, 1959HO97, 1960EI01, 1965AN05, 1966EI01, +133XE2C 1968RE04, 1971SA09, 1972KR07, 1972AC02, 1972BE90, 1974KO26, 1976FU06, +133XE3C 1976ME16, 1977KR13, 1983LO08, 1989RA17, 1995RA12, 1996SC06, 2002Ba85, +133XE4C 2003Au03 +133XE T Auger electrons and X ray energies and emission intensities: +133XE T {U Energy (keV)} {U Intensity} {U Line} +133XE T +133XE T 29.459 0.163 4 XKA2 +133XE T 29.779 0.303 6 XKA1 +133XE T +133XE T 33.562 |] XKB3 +133XE T 33.625 |] 0.0877 19 XKB1 +133XE T 33.881 |] XKB5II +133XE T +133XE T 34.415 |] XKB2 +133XE T 34.496 |] 0.0207 7 XKB4 +133XE T 34.552 |] XKO23 +133XE T +133XE T 3.6378-5.296 0.0724 14 XL (total) +133XE T 3.6378 0.00149 5 XLL +133XE T 4.0977-4.1103 0.039 1 XLA +133XE T 3.9576 0.00048315 XLC +133XE T 4.4176-4.7758 0.0275 6 XLB +133XE T 4.895-5.296 0.003890 9 XLG +133XE T +133XE T 23.512-24.842 |] KLL AUGER +133XE T 27.897-29.77 |] 0.072 4 KLX AUGER +133XE T 32.27-34.54 |] KXY AUGER +133XE T 2.4-5.2 0.677 4 L AUGER +133I P 0.0 7/2+ 20.87 H 8 1757 4 +133XE N 1.0 1.0 1 1.0 +133XE G 167.97 6 0.078 17 +133XE G 567.1 4 0.003 3 +133XE G 1018.1 5 0.0060 26 +133XE L 0 3/2+ 5.2474 D 5 +133XE L 233.219 1511/2- 2.198 D 13 +133XE B 1524 4 1.07 6 9.92 1U +133XES B EAV=572.0 17 +133XE G 233.219 150.293 4M4 8.84 12 +133XE2 G KC=6.24 9$LC=2.035 29$MC=0.453 6$NC=0.0928 13 +133XE3 G OC=0.01045 15 +133XE L 262.702 601/2+ +133XE G 262.70 6 0.356 12M1+E2 0.0577 8 +133XE2 G KC=0.0497 7$LC=0.00641 9$MC=0.001300 18$NC=0.000269 4 +133XE3 G OC=3.37E-5 5 +133XE L 529.872 3 5/2+ +133XE B 1227 4 83.42 21 6.81 +133XES B EAV=439.4 17 +133XE G 267.17 6 0.117 7 +133XE G 529.8709 3086.3 2M1+E2 1.85 20 0.0081014 +133XE2 G KC=0.00691 13$LC=0.000956 14$MC=1.948E-4 29$NC=4.00E-5 6 +133XE3 G OC=4.87E-6 8 +133XE L 680.254 9 3/2+ +133XE G 150.382 9 0.029 6 +133XE G 417.55 6 0.153 10M1+E2 1.0 13 0.0163 11 +133XE2 G KC=0.0139 10$LC=0.001921 27$MC=0.000392 6$NC=8.05E-5 11 +133XE3 G OC=9.82E-6 26 +133XE G 680.252 9 0.645 19M1 0.00527 7 +133XE2 G KC=0.00460 6$LC=0.000570 8$MC=1.152E-4 16$NC=2.39E-5 3 +133XE3 G OC=3.00E-6 4 +133XE L 743.750 16(7/2,9/2,11/2)- +133XE B 1013 4 1.81 6 8.17 +133XES B EAV=350.5 17 +133XE G 510.530 221.81 6 +133XE L 875.331 5 (7/2)+ +133XE B 882 4 4.16 13 7.59 +133XES B EAV=297.4 16 +133XE G 345.459 6 0.104 18 +133XE G 875.328 5 4.47 12E2+M3 0.00218 3 +133XE2 G KC=0.001876 26$LC=0.000245 3$MC=4.96E-5 7$NC=1.022E-5 14 +133XE3 G OC=1.262E-6 18 +133XE L 911.45 3 (1/2,3/2)+ +133XE B 846 4 0.026 18 9.7 2U +133XES B EAV=283.1 16 +133XE G 381.578 300.045 5 +133XE G 648.75 7 0.056 13M1 0.00590 8 +133XE2 G KC=0.00510 7$LC=0.000639 9$MC=1.292E-4 18$NC=2.68E-5 4 +133XE3 G OC=3.37E-6 5 +133XE G 911.447 300.046 6 +133XE L 1052.397 175/2+ +133XE B 706 4 0.58 5 8.09 +133XES B EAV=228.4 16 +133XE G 372.143 190.009 6 +133XE G 522.524 170.04 5 +133XE G 789.69 6 0.050 4 +133XE G 1052.393 170.551 16 +133XE L 1236.449 5 (7/2)+ +133XE B 521 4 3.12 6 6.91 +133XES B EAV=160.4 15 +133XE G 361.118 7 0.11 4 +133XE G 556.194 100.020 3 +133XE G 706.575 6 1.49 4M1+E2 0.0042 6 +133XE2 G KC=0.0036 6$LC=0.00047 5$MC=0.000095 10$NC=1.96E-5 22 +133XE3 G OC=2.4E-6 3 +133XE G 1236.443 5 1.49 4 +133XE L 1298.234 5 5/2+ +133XE B 459 4 3.75 7 6.64 +133XES B EAV=138.7 14 +133XE G 245.837 180.035 9 +133XE G 386.784 300.059 5 +133XE G 422.903 7 0.309 10M1+E2 1.8 12 0.0151 13 +133XE2 G KC=0.0128 13$LC=0.00185 3$MC=0.000379 6$NC=7.76E-5 11 +133XE3 G OC=9.3E-6 3 +133XE G 554.483 170.0004 5 +133XE G 617.978 100.539 15M1+E2 0.0059 8 +133XE2 G KC=0.0050 7$LC=0.00066 6$MC=0.000134 12$NC=2.76E-5 26 +133XE3 G OC=3.4E-6 4 +133XE G 768.360 6 0.457 15M1+E2 0.6 4 0.0036824 +133XE2 G KC=0.00318 22$LC=0.000402 22$MC=0.000081 4$NC=1.68E-5 9 +133XE3 G OC=2.106E-5 12 +133XE G 1035.53 6 0.0086 18 +133XE G 1298.227 5 2.33 7M1+E2 4.2 3 9.72E-414 +133XE2 G KC=0.000822 12$LC=1.026E-4 15$MC=2.070E-5 29$NC=4.28E-6 6 +133XE3 G OC=5.35E-7 8 +133XE L 1350.380 175/2+ +133XE B 407 4 0.397 12 7.44 +133XES B EAV=120.8 14 +133XE G 438.930 340.040 5 +133XE G 670.124 190.042 6 +133XE G 820.505 170.154 6M1+E2 0.8 8 0.0031 4 +133XE2 G KC=0.0026 3$LC=0.00033 3$MC=0.000068 6$NC=1.40E-5 13 +133XE3 G OC=1.74E-6 18 +133XE G 1087.67 6 0.0121 18 +133XE G 1350.373 170.148 5M1+E2 0.0010112 +133XE2 G KC=0.00085 10$LC=0.000104 12$MC=2.11E-5 23$NC=4.4E-6 5 +133XE3 G OC=5.5E-7 6 +133XE L 1386.153 8 7/2+ +133XE B 371 4 1.25 4 6.81 +133XES B EAV=108.8 14 +133XE G 510.821 9 0.004 5 +133XE G 856.278 9 1.23 4M1+E2 3.7 3 0.00235 3 +133XE2 G KC=0.00202 3$LC=0.000263 4$MC=5.33E-5 8$NC=1.099E-5 16 +133XE3 G OC=1.357E-6 20 +133XE G 1386.145 8 0.0086 26[E2] +133XE L 1589.94 3 5/2+ +133XE B 167 4 0.414 15 6.18 +133XES B EAV=45.1 12 +133XE G 203.787 310.00432 8 +133XE G 537.542 340.035 7 +133XE G 678.488 420.022 7 +133XE G 909.683 310.212 9M1+E2 0.40 6 0.00257 4 +133XE2 G KC=0.00222 4$LC=0.000277 5$MC=5.59E-5 9$NC=1.158E-5 19 +133XE3 G OC=1.456E-6 24 +133XE G 1060.063 0.137 7M1+E2 0.0016523 +133XE2 G KC=0.00143 20$LC=0.000179 22$MC=0.000036 4$NC=7.5E-6 9 +133XE3 G OC=9.3E-7 12 +133XE G 1327.23 7 0.00022 22 +133XE G 1589.93 3 0.0029 4 + diff --git a/HEN_HOUSE/spectra/lnhb/In-111.txt b/HEN_HOUSE/spectra/lnhb/In-111.txt index e45e59b20..45ffb954f 100644 --- a/HEN_HOUSE/spectra/lnhb/In-111.txt +++ b/HEN_HOUSE/spectra/lnhb/In-111.txt @@ -1,52 +1,50 @@ -111CD 111IN EC DECAY (2.8049 D) -111CD H TYP=Update$AUT=V. Chechev$CUT=01-MAR-2006$ -111CD2 H TYP=Full$AUT=V. Chechev$CUT=01-JUN-1998$ -111CD C Evaluation history: Type=Update;Author=V. Chechev;Cutoff date=01-MAR-2006 -111CD2C Type=Full;Author=V. Chechev;Cutoff date=01-JUN-1998 -111CD C References: 1945Wi11, 1948Ho37, 1949He06, 1951Mc11, 1956St64, 1957Ma26, -111CD2C 1966Sp04, 1967Be65, 1968Bo28, 1968Li08, 1968Sm08, 1972Gu19, 1972MeZD, -111CD3C 1972Em01, 1973Budz, 1973Path, 1974Kr03, 1974HeYW, 1975Sh29, 1977La19, -111CD4C 1978La21, 1980Ho17, 1982HoZY, 1983Wa26, 1985Ka29, 1986Ru09, 1987Ne01, -111CD5C 1992Un01, 1994Ka08, 1996Sc06, 1997We17, 1998Si17, 2003Bl10, 2003Au03, -111CD6C 2004Sc04, 2005Ya03, 2006Ra03 -111CD T Auger electrons and X ray energies and emission intensities: -111CD T {U Energy (keV)} {U Intensity} {U Line} -111CD T -111CD T 22.9843 23.65 18 XKA2 -111CD T 23.1738 44.47 26 XKA1 -111CD T -111CD T 26.0615 |] XKB3 -111CD T 26.0958 |] 12.40 14 XKB1 -111CD T 26.304 |] XKB5II -111CD T -111CD T 26.644 |] XKB2 -111CD T 26.7106 |] 2.26 7 XKB4 -111CD T -111CD T 2.77-3.95 6.78 14 XL (total) -111CD T 2.77 0.147 6 XLL -111CD T 3.127-3.134 3.95 13 XLA -111CD T 2.957 0.0504 12 XLC -111CD T 3.316-3.528 2.39 5 XLB -111CD T 3.718-3.95 0.247 5 XLG -111CD T -111CD T 18.675-19.636 |] KLL AUGER -111CD T 21.923-23.172 |] 15.5 4 KLX AUGER -111CD T 25.171-26.028 |] KXY AUGER -111CD T 3.404-3.804 100.5 8 L AUGER -111IN P 0.0 9/2+ 2.8049 D 4 861.8 46 -111CD N 1.0 1.0 1 1.0 -111CD L 0 1/2+ STABLE -111CD L 245.4 5/2+ -111CD G 245.35 4 94.12 6E2 0.0625 7 -111CD2 G KC=0.0524 10$LC=0.00818 16$MC=0.00159 3 -111CD L 396.15 11/2- 48.50 M 9 -111CD E 0.005 59 1 -111CD2 E CK=0.8524 2$CL=0.1179 2$CM=0.02975 4 -111CD G 150.81 3 0.0015 15E3 2.28 5 -111CD2 G KC=1.45 3$LC=0.673 14$MC=0.137 3 -111CD L 416.6 7/2+ -111CD E 99.995 55 -111CD2 E CK=0.8518 2$CL=0.11835 13$CM=0.02989 4 -111CD G 171.28 3 90.61 20M1+E2 0.1036 24 -111CD2 G KC=0.0897 22$LC=0.0113 3$MC=0.00217 5 - +111CD 111IN EC DECAY (2.8049 D) +111CD H TYP=UPD$AUT=V.P.CHECHEV$CUT=01-MAR-2006$ +111CD2 H TYP=FUL$AUT=V.P.CHECHEV$CUT=01-JUN-1998$ +111CD C References:1945Wi11, 1948Ho37, 1949He06, 1951Mc11, 1956St64, 1957Ma26, +111CD2C 1966Sp04, 1967Be65, 1968Bo28, 1968Li08, 1968Sm08, 1972Gu19, 1972MeZD, +111CD3C 1972Em01, 1973Budz, 1973Path, 1974Kr03, 1974HeYW, 1975Sh29, 1977La19, +111CD4C 1978La21, 1980Ho17, 1982HoZY, 1983Wa26, 1985Ka29, 1986Ru09, 1987Ne01, +111CD5C 1992Un01, 1994Ka08, 1996Sc06, 1997We17, 1998Si17, 1999Be**, 2003Bl10, +111CD6C 2003Au03, 2004Sc04, 2005Ya03, 2006Ra03 +111CD T Auger electrons and X ray energies and emission intensities: +111CD T {U Energy (keV)} {U Intensity} {U Line} +111CD T +111CD T 22.9843 23.65 18 XKA2 +111CD T 23.1738 44.47 26 XKA1 +111CD T +111CD T 26.0615 |] XKB3 +111CD T 26.0958 |] 12.40 14 XKB1 +111CD T 26.304 |] XKB5II +111CD T +111CD T 26.644 |] XKB2 +111CD T 26.7106 |] 2.26 7 XKB4 +111CD T +111CD T 2.77-3.95 6.78 14 XL (total) +111CD T 2.77 0.147 6 XLL +111CD T 3.127-3.134 3.95 13 XLA +111CD T 2.957 0.0504 12 XLC +111CD T 3.316-3.528 2.39 5 XLB +111CD T 3.718-3.95 0.247 5 XLG +111CD T +111CD T 18.675-19.636 |] KLL AUGER +111CD T 21.923-23.172 |] 15.5 4 KLX AUGER +111CD T 25.171-26.028 |] KXY AUGER +111CD T 3.404-3.804 100.5 8 L AUGER +111IN P 0.0 9/2+ 2.8049 D 4 861.8 46 +111CD N 1.0 1.0 1 1.0 +111CD L 0 1/2+ STABLE +111CD L 245.4 5/2+ +111CD G 245.35 4 94.12 6E2 0.0625 7 +111CD2 G KC=0.0524 10$LC=0.00818 16$MC=0.00159 3 +111CD L 396.15 11/2- 48.50 M 9 +111CD E 0.005 59 1 +111CD2 E CK=0.8524 2$CL=0.1179 2$CM=0.02975 4 +111CD G 150.81 3 0.0015 15E3 2.28 5 +111CD2 G KC=1.45 3$LC=0.673 14$MC=0.137 3 +111CD L 416.6 7/2+ +111CD E 99.995 55 +111CD2 E CK=0.8518 2$CL=0.11835 13$CM=0.02989 4 +111CD G 171.28 3 90.61 20M1+E2 0.1036 24 +111CD2 G KC=0.0897 22$LC=0.0113 3$MC=0.00217 5 + diff --git a/HEN_HOUSE/spectra/lnhb/Ir-192.txt b/HEN_HOUSE/spectra/lnhb/Ir-192.txt index adedd014c..154dfdf68 100644 --- a/HEN_HOUSE/spectra/lnhb/Ir-192.txt +++ b/HEN_HOUSE/spectra/lnhb/Ir-192.txt @@ -1,152 +1,146 @@ -192OS 192IR EC DECAY (73.827 D) -192OS H TYP=Full$AUT=E. Browne$CUT= -- $ -192OS C Evaluation history: Type=Full;Author=E. Browne;Cutoff date= -- -192OS T Auger electrons and X ray energies and emission intensities: -192OS T {U Energy (keV)} {U Intensity} {U Line} -192OS T -192OS T 61.4873 1.211 25 XKA2 -192OS T 63.0011 2.09 5 XKA1 -192OS T -192OS T 71.078 |] XKB3 -192OS T 71.414 |] 0.710 21 XKB1 -192OS T 71.855 |] XKB5II -192OS T -192OS T 73.319 |] XKB2 -192OS T 73.615 |] 0.180 6 XKB4 -192OS T 73.819 |] XKO23 -192OS T -192OS T 7.822-12.92 1.525 25 XL (total) -192OS T 7.822 XLL -192OS T 8.9- XLA -192OS T -12.92 XLG -192OS T -192OS T 47.71-51.892 |] KLL AUGER -192OS T 57.759-62.955 |] 0.196 19 KLX AUGER -192OS T 67.77-73.78 |] KXY AUGER -192OS T 4.8-12.86 L AUGER -192IR P 0.0 4+ 73.827 D 13 1046.2 23 -192OS N 2.053E1 2.053E1 0.0487 2.053E1 -192OS G 214.7 5 -192OS G 314.8 3 -192OS G 415.4 5 -192OS G 739 -192OS L 0 0+ STABLE -192OS L 205.79430 9 2+ 0.277 NS 4 -192OS G 205.79430 9 3.34 4E2 0.305 9 -192OS2 G KC=0.157 5$LC=0.111 3$MC=0.0281 8 -192OS L 489.0602 6 2+ 0.0321 NS 10 -192OS G 283.2668 8 0.266 3E2+M1 0.123 4 -192OS2 G KC=0.081 4$LC=0.0318 8$MC=0.00785 20 -192OS G 489.06 3 0.438 14E2 0.0243 7 -192OS2 G KC=0.0182 5$LC=0.00471 14$MC=0.00114 3 -192OS L 580.2798 8 4+ 0.0147 NS 4 -192OS E 0.686 99.5 -192OS2 E CK=0.777 2$CL=0.168 2$CM=0.055 1 -192OS G 374.4852 8 0.726 6E2 0.0490 15 -192OS2 G KC=0.0341 10$LC=0.0113 3$MC=0.00276 8 -192OS L 690.3705 4 3+ -192OS E 3.97 38.5 -192OS2 E CK=0.758 2$CL=0.182 2$CM=0.060 1 -192OS G 110.4 3 0.0122 11E2+M1 3.65 11 -192OS2 G KC=2.03 6$LC=1.22 4$MC=0.306 9 -192OS G 201.3112 7 0.473 8E2+M1 0.387 10 -192OS2 G KC=0.228 11$LC=0.120 3$MC=0.0301 8 -192OS G 484.5751 4 3.189 24E2+M1 0.0263 8 -192OS2 G KC=0.0198 6$LC=0.00499 14$MC=0.00120 4 -192OS L 909.58 6 4+ 0.010 NS 5 -192OS E 0.095 49.5 -192OS2 E CK=0.537 9$CL=0.339 14$CM=0.124 5 -192OS G 329.17 150.0174 17E2+M1 0.094 7 -192OS2 G KC=0.069 7$LC=0.0195 10$MC=0.00472 24 -192OS G 420.52 6 0.069 7[E2] 0.0358 11 -192OS2 G KC=0.0258 8$LC=0.00762 23$MC=0.00186 6 - -192PT 192IR B- DECAY (73.827 D) -192PT H TYP=Full$AUT=E. Browne$CUT= -- $ -192PT C Evaluation history: Type=Full;Author=E. Browne;Cutoff date= -- -192PT T Auger electrons and X ray energies and emission intensities: -192PT T {U Energy (keV)} {U Intensity} {U Line} -192PT T -192PT T 65.123 2.66 5 XKA2 -192PT T 66.833 4.55 8 XKA1 -192PT T -192PT T 75.369 |] XKB3 -192PT T 75.749 |] 1.58 3 XKB1 -192PT T 76.234 |] XKB5II -192PT T -192PT T 77.786 |] XKB2 -192PT T 78.07 |] 0.411 10 XKB4 -192PT T 78.337 |] XKO23 -192PT T -192PT T 9.4-13.8 3.96 6 XL (total) -192PT T 9.4- XLA -192PT T -13.8 XLG -192PT T -192PT T 50.399-55.021 |] KLL AUGER -192PT T 61.116-66.829 |] 0.39 4 KLX AUGER -192PT T 71.8-78.39 |] KXY AUGER -192PT T 4.9-13.9 L AUGER -192IR P 0.0 4+ 73.827 D 13 1459.7 19 -192PT N 1.051E0 1.051E0 0.9513 1.051E0 -192PT G 214.7 5 -192PT G 314.8 3 -192PT G 415.4 5 -192PT G 739 -192PT L 0 0+ STABLE -192PT L 316.0641 212+ 0.0437 NS 12 -192PT G 316.50618 1782.75 21E2 0.0849 25 -192PT2 G KC=0.0537 16$LC=0.0236 7$MC=0.00591 17 -192PT L 612.46283 212+ 0.0265 NS 15 -192PT G 295.95650 1528.72 14E2+M1 0.106 3 -192PT2 G KC=0.0654 20$LC=0.0305 9$MC=0.00767 23 -192PT G 612.4621 3 5.34 8E2 0.0155 5 -192PT2 G KC=0.0119 4$LC=0.00278 8$MC=6.69E-4 20 -192PT L 784.5757 3 4+ 0.0042 NS 2 -192PT B 675.1 1947.9 3 8.5 -192PTS B EAV=209.9 7 -192PT G 468.0688 3 47.81 24E2 0.0295 9 -192PT2 G KC=0.0213 6$LC=0.00617 19$MC=0.00151 5 -192PT L 920.91815 243+ 0.0213 NS 21 -192PT B 538.8 1941.4 3 8.3 -192PTS B EAV=162.1 7 -192PT G 136.3426 3 0.199 25E2+M1 1.56 6 -192PT2 G KC=0.57 8$LC=0.747 22$MC=0.192 6 -192PT G 308.45507 1729.68 15E2+M1 0.096 3 -192PT2 G KC=0.0608 18$LC=0.0262 8$MC=0.00657 20 -192PT G 604.41105 258.20 4E2+M1 0.0266 8 -192PT2 G KC=0.0213 6$LC=0.00403 12$MC=0.00095 3 -192PT L 1201.0450 5 4+ -192PT B 258.7 195.59 3 8.1 -192PTS B EAV=71.6 6 -192PT G 280.27 240.009 5E2+M1 0.16 7 -192PT2 G KC=0.11 7$LC=0.039 11$MC=0.0098 25 -192PT G 416.4688 7 0.669 21E2+M1 0.050 4 -192PT2 G KC=0.037 4$LC=0.0099 6$MC=0.00242 13 -192PT G 588.5810 7 4.517 22E2 0.0170 5 -192PT2 G KC=0.0129 4$LC=0.00311 9$MC=7.51E-4 23 -192PT G 884.5365 7 0.291 7E2 0.0070721 -192PT2 G KC=0.00566 17$LC=0.00108 3$MC=2.54E-4 8 -192PT L 1378.02 3 3- 0.064 NS 18 -192PT B 81.7 190.1026 23 8.3 1 -192PTS B EAV=21.1 5 -192PT G 176.98 4 0.0043 12[E1] 0.097 3 -192PT2 G KC=0.0786 24$LC=0.0137 4$MC=0.00215 6 -192PT G 593.49 130.0421 17E1+M2 0.0067 4 -192PT2 G KC=0.0055 4$LC=0.00087 6$MC=3.27E-4 14 -192PT G 765.8 3 0.0013 6E1+M2 0.0052 14 -192PT2 G KC=0.0043 11$LC=0.00070 19$MC=0.00014 4 -192PT G 1061.48 4 0.053 1E1+M2 0.00197 9 -192PT2 G KC=0.00166 7$LC=2.43E-4 11$MC=5.8E-5 3 -192PT G 1378.20 150.0012 3[E3] 0.0062019 -192PT2 G KC=0.00492 15$LC=0.00098 3$MC=2.32E-4 7 -192PT L 1383.99 15(5)- -192PT B 75.7 190.0039 17 9.6 1 -192PTS B EAV=19.5 5 -192PT G 599.41 150.0039 17E1 0.0059018 -192PT2 G KC=0.00481 14$LC=7.52E-4 23$MC=2.84E-4 9 -192PT L 1406.24 11(3)+ -192PT B 53.5 190.0033 5 9.2 -192PTS B EAV=13.6 5 -192PT G 1089.9 3 0.0012 2E2+M1 0.0063 6 -192PT2 G KC=0.0052 5$LC=0.00087 8$MC=2.01E-4 18 - +192OS 192IR EC DECAY (73.827 D) +192OS H TYP=FUL$AUT=E.BROWNE$CUT=30-JUN-1998$ +192OS T Auger electrons and X ray energies and emission intensities: +192OS T {U Energy (keV)} {U Intensity} {U Line} +192OS T +192OS T 61.4873 1.211 25 XKA2 +192OS T 63.0011 2.09 5 XKA1 +192OS T +192OS T 71.078 |] XKB3 +192OS T 71.414 |] 0.710 21 XKB1 +192OS T 71.855 |] XKB5II +192OS T +192OS T 73.319 |] XKB2 +192OS T 73.615 |] 0.180 6 XKB4 +192OS T 73.819 |] XKO23 +192OS T +192OS T 7.822-12.92 1.525 25 XL (total) +192OS T 7.822 XLL +192OS T 8.9- XLA +192OS T -12.92 XLG +192OS T +192OS T 47.71-51.892 |] KLL AUGER +192OS T 57.759-62.955 |] 0.196 19 KLX AUGER +192OS T 67.77-73.78 |] KXY AUGER +192OS T 4.8-12.86 L AUGER +192IR P 0.0 4+ 73.827 D 13 1046.2 23 +192OS N 2.053E1 2.053E1 0.0487 2.053E1 +192OS L 0 0+ STABLE +192OS L 205.79430 9 2+ 0.277 NS 4 +192OS G 205.79430 9 3.34 4E2 0.305 9 +192OS2 G KC=0.157 5$LC=0.111 3$MC=0.0281 8$NC=0.00810 24 +192OS L 489.0602 6 2+ 0.0321 NS 10 +192OS G 283.2668 8 0.266 3E2+M1 0.123 4 +192OS2 G KC=0.081 4$LC=0.0318 8$MC=0.00785 20$NC=0.00228 6 +192OS G 489.06 3 0.438 14E2 0.0243 7 +192OS2 G KC=0.0182 5$LC=0.00471 14$MC=0.00114 3$NC=0.000335 10 +192OS L 580.2798 8 4+ 0.0147 NS 4 +192OS E 0.686 99.5 +192OS2 E CK=0.777 2$CL=0.168 2$CM=0.055 1 +192OS G 374.4852 8 0.726 6E2 0.0490 15 +192OS2 G KC=0.0341 10$LC=0.0113 3$MC=0.00276 8$NC=0.000807 24 +192OS L 690.3705 4 3+ +192OS E 3.97 38.5 +192OS2 E CK=0.758 2$CL=0.182 2$CM=0.060 1 +192OS G 110.4 3 0.0122 11E2+M1 3.65 11 +192OS2 G KC=2.03 6$LC=1.22 4$MC=0.306 9$NC=0.088 3 +192OS G 201.3112 7 0.473 8E2+M1 0.387 10 +192OS2 G KC=0.228 11$LC=0.120 3$MC=0.0301 8$NC=0.00870 22 +192OS G 484.5751 4 3.189 24E2+M1 0.0263 8 +192OS2 G KC=0.0198 6$LC=0.00499 14$MC=0.00120 4$NC=0.000354 11 +192OS L 909.58 6 4+ 0.010 NS 5 +192OS E 0.095 49.5 +192OS2 E CK=0.537 9$CL=0.339 14$CM=0.124 5 +192OS G 329.17 150.0174 17E2+M1 0.094 7 +192OS2 G KC=0.069 7$LC=0.0195 10$MC=0.00472 24$NC=0.00139 6 +192OS G 420.52 6 0.069 7[E2] 0.0358 11 +192OS2 G KC=0.0258 8$LC=0.00762 23$MC=0.00186 6$NC=0.000544 16 + +192PT 192IR B- DECAY (73.827 D) +192PT H TYP=FUL$AUT=E.BROWNE$CUT=30-JUN-1998$ +192PT T Auger electrons and X ray energies and emission intensities: +192PT T {U Energy (keV)} {U Intensity} {U Line} +192PT T +192PT T 65.123 2.66 5 XKA2 +192PT T 66.833 4.55 8 XKA1 +192PT T +192PT T 75.369 |] XKB3 +192PT T 75.749 |] 1.58 3 XKB1 +192PT T 76.234 |] XKB5II +192PT T +192PT T 77.786 |] XKB2 +192PT T 78.07 |] 0.411 10 XKB4 +192PT T 78.337 |] XKO23 +192PT T +192PT T 9.4-13.8 3.96 6 XL (total) +192PT T 9.4- XLA +192PT T -13.8 XLG +192PT T +192PT T 50.399-55.021 |] KLL AUGER +192PT T 61.116-66.829 |] 0.39 4 KLX AUGER +192PT T 71.8-78.39 |] KXY AUGER +192PT T 4.9-13.9 L AUGER +192IR P 0.0 4+ 73.827 D 13 1459.7 19 +192PT N 1.051E0 1.051E0 0.9513 1.051E0 +192PT G 214.7 5 +192PT G 314.8 3 +192PT G 415.4 5 +192PT G 739 +192PT L 0 0+ STABLE +192PT L 316.0641 212+ 0.0437 NS 12 +192PT G 316.50618 1782.75 21E2 0.0849 25 +192PT2 G KC=0.0537 16$LC=0.0236 7$MC=0.00591 17$NC=0.00175 5 +192PT L 612.46283 212+ 0.0265 NS 15 +192PT G 295.95650 1528.72 14E2+M1 0.106 3 +192PT2 G KC=0.0654 20$LC=0.0305 9$MC=0.00767 23$NC=0.00227 7 +192PT G 612.4621 3 5.34 8E2 0.0155 5 +192PT2 G KC=0.0119 4$LC=0.00278 8$MC=0.000669 20$NC=0.000202 6 +192PT L 784.5757 3 4+ 0.0042 NS 2 +192PT B 675.1 1947.9 3 8.5 +192PTS B EAV=209.9 7 +192PT G 468.0688 3 47.81 24E2 0.0295 9 +192PT2 G KC=0.0213 6$LC=0.00617 19$MC=0.00151 5$NC=0.000452 14 +192PT L 920.91815 243+ 0.0213 NS 21 +192PT B 538.8 1941.4 3 8.3 +192PTS B EAV=162.1 7 +192PT G 136.3426 3 0.199 25E2+M1 1.56 6 +192PT2 G KC=0.57 8$LC=0.747 22$MC=0.192 6$NC=0.0564 14 +192PT G 308.45507 1729.68 15E2+M1 0.096 3 +192PT2 G KC=0.0608 18$LC=0.0262 8$MC=0.00657 20$NC=0.00195 6 +192PT G 604.41105 258.20 4E2+M1 0.0266 8 +192PT2 G KC=0.0213 6$LC=0.00403 12$MC=0.00095 3$NC=0.000289 9 +192PT L 1201.0450 5 4+ +192PT B 258.7 195.59 3 8.1 +192PTS B EAV=71.6 6 +192PT G 280.27 240.009 5E2+M1 0.16 7 +192PT2 G KC=0.11 7$LC=0.039 11$MC=0.0098 25$NC=0.0029 6 +192PT G 416.4688 7 0.669 21E2+M1 0.050 4 +192PT2 G KC=0.037 4$LC=0.0099 6$MC=0.00242 13$NC=0.00073 3 +192PT G 588.5810 7 4.517 22E2 0.0170 5 +192PT2 G KC=0.0129 4$LC=0.00311 9$MC=0.000751 23$NC=0.000226 7 +192PT G 884.5365 7 0.291 7E2 0.0070721 +192PT2 G KC=0.00566 17$LC=0.00108 3$MC=0.000254 8$NC=7.72E-5 23 +192PT L 1378.02 3 3- 0.064 NS 18 +192PT B 81.7 190.1026 23 8.3 1 +192PTS B EAV=21.1 5 +192PT G 176.98 4 0.0043 12[E1] 0.097 3 +192PT2 G KC=0.0786 24$LC=0.0137 4$MC=0.00215 6$NC=0.00290 9 +192PT G 593.49 130.0421 17E1+M2 0.0067 4 +192PT2 G KC=0.0055 4$LC=0.00087 6$MC=0.000327 14$NC=0.000059 4 +192PT G 765.8 3 0.0013 6E1+M2 0.0052 14 +192PT2 G KC=0.0043 11$LC=0.00070 19$MC=0.00014 4$NC=0.000046 11 +192PT G 1061.48 4 0.053 1E1+M2 0.00197 9 +192PT2 G KC=0.00166 7$LC=0.000243 11$MC=0.000058 3$NC=1.68E-5 7 +192PT G 1378.20 150.0012 3[E3] 0.0062019 +192PT2 G KC=0.00492 15$LC=0.00098 3$MC=0.000232 7$NC=7.07E-5 21 +192PT L 1383.99 15(5)- +192PT B 75.7 190.0039 17 9.6 1 +192PTS B EAV=19.5 5 +192PT G 599.41 150.0039 17E1 0.0059018 +192PT2 G KC=0.00481 14$LC=0.000752 23$MC=0.000284 9$NC=5.01E-5 15 +192PT L 1406.24 11(3)+ +192PT B 53.5 190.0033 5 9.2 +192PTS B EAV=13.6 5 +192PT G 1089.9 3 0.0012 2E2+M1 0.0063 6 +192PT2 G KC=0.0052 5$LC=0.00087 8$MC=0.000201 18$NC=0.000062 5 + diff --git a/HEN_HOUSE/spectra/lnhb/Ir-194.txt b/HEN_HOUSE/spectra/lnhb/Ir-194.txt index 5bd4179a7..37c5e9b5d 100644 --- a/HEN_HOUSE/spectra/lnhb/Ir-194.txt +++ b/HEN_HOUSE/spectra/lnhb/Ir-194.txt @@ -1,212 +1,212 @@ -194PT 194IR B- DECAY (19.3 H) -194PT T Auger electrons and X ray energies and emission intensities: -194PT T {U Energy (keV)} {U Intensity} {U Line} -194PT T -194PT T 65.123 0.24 3 XKA2 -194PT T 66.833 0.41 5 XKA1 -194PT T -194PT T 75.369 |] XKB3 -194PT T 75.749 |] 0.00138 19 XKB1 -194PT T 76.234 |] XKB5II -194PT T -194PT T 77.786 |] XKB2 -194PT T 78.07 |] 0.00040 5 XKB4 -194PT T 78.337 |] XKO23 -194PT T -194PT T 8.268-13.361 0.36 6 XL (total) -194PT T 8.268 XLL -194PT T -13.361 XLG -194PT T -194PT T 50.4-55.02 |] KLL AUGER -194PT T 61.12-64.62 |] 0.035 4 KLX AUGER -194PT T 71.7-74.1 |] KXY AUGER -194IR P 0.0 1- 19.3 H 1 2246.8 16 -194PT N 1.0 1.0 1 1.0 -194PT G 1675.24 170.00086 18 -194PT G 2207 1 0.0013 4 -194PT L 0 0+ STABLE -194PT B 2246.9 1685.4 19 8.2 1 -194PTS B EAV=845.7 7 -194PT L 328.449 2+ 41.8 PS -194PT B 1918.5 169.3 13 8.9 1 -194PTS B EAV=705.4 7 -194PT G 328.448 1413.1 17E2 0.076 2 -194PT2 G KC=0.049 2$LC=0.020 1$MC=0.0070 2 -194PT L 621.99 2+ 35 PS -194PT B 1624.9 161.28 20 9.5 1 -194PTS B EAV=582.2 7 -194PT G 293.541 142.5 3E2+M1+ 0.107 3 -194PT2 G KC=0.066 2$LC=0.031 1$MC=0.010 1 -194PT G 621.971 190.33 5E2 0.0150 5 -194PT2 G KC=0.0115 4$LC=0.0025 1 -194PT L 811.33 4+ -194PT G 482.857 260.046 6E2 0.0272 8 -194PT2 G KC=0.0200 6$LC=0.0056 2$MC=0.0016 1 -194PT L 922.739 3+ -194PT B 1324.2 160.30 4 10.5 1U -194PTS B EAV=452.4 6 -194PT G 111.4 4 0.0017 6[M1E2] 4.1 10 -194PT2 G KC=2.4 18$LC=1.3 7$MC=0.40 18 -194PT G 300.741 140.35 5E2(+M1) 0.103 4 -194PT2 G KC=0.061 2$LC=0.028 1$MC=0.014 1 -194PT G 594.291 190.062 8E2(+M1) 0.0166 5 -194PT2 G KC=0.0126 4$LC=0.0030 1$MC=0.0010 1 -194PT L 1229.6 4+ -194PT G 607.61 8 0.0039 6E2 0.0158 5 -194PT2 G KC=0.0121 4$LC=0.0028 1$MC=0.0010 1 -194PT L 1267.145 0+ -194PT B 979.8 161.77 23 8.6 1 -194PTS B EAV=323.1 6 -194PT G 645.146 201.18 16E2 0.0138 4 -194PT2 G KC=0.0106 3$LC=0.0024 1 -194PT G 938.690 250.60 8E2 0.0062719 -194PT2 G KC=0.0050 2$LC=0.00090 3 -194PT L 1432.49 3- -194PT G 202.91 150.0030 8E1 0.068 2 -194PT2 G KC=0.056 2$LC=0.0093 3$MC=0.0027 1 -194PT G 621.29 150.0096 18E1+M2 0.0091 18 -194PT2 G KC=0.0074 15$LC=0.0013 3 -194PT G 810.66 190.0025 6[E1] 0.0032 1 -194PT2 G KC=0.0027 1 -194PT G 1104.05 5 0.026 4E1 0.00178 5 -194PT2 G KC=0.00149 5 -194PT G 1432.52 120.0011 3[E3] 0.0057117 -194PT2 G KC=0.00455 14 -194PT L 1479.2 0+ -194PT B 767.7 160.61 8 8.7 1 -194PTS B EAV=243.4 6 -194PT G 1479.2 -194PT G 857.12 190.0071 12[E2] 0.0075 2 -194PT2 G KC=0.0060 2 -194PT G 1150.75 5 0.60 8E2 0.0042013 -194PT2 G KC=0.00342 10 -194PT L 1511.927 2+ -194PT B 735.0 160.56 7 8.6 1 -194PTS B EAV=231.5 6 -194PT G 244.83 5 0.0077 11E2 0.186 6 -194PT2 G KC=0.102 3$LC=0.063 2$MC=0.020 1 -194PT G 589.179 170.140 18E2+M1 0.0231 24 -194PT2 G KC=0.0181 5$LC=0.0037 3$MC=0.0013 1 -194PT G 700.55 4 0.026 5E2 0.0115 4 -194PT2 G KC=0.0089 3$LC=0.0019 1 -194PT G 889.98 4 0.051 7E2+M1 0.0105 17 -194PT2 G KC=0.0085 14$LC=0.0015 2 -194PT G 1183.49 5 0.31 4E2+M1 0.0057917 -194PT2 G KC=0.00476 14 -194PT G 1511.98 100.024 4(E2) 0.00249 7 -194PT2 G KC=0.00208 6 -194PT L 1547.24 0+ -194PT B 699.7 160.070 9 9.5 1 -194PTS B EAV=218.7 6 -194PT G 925.26 6 0.0126 18E2 0.0065 2 -194PT2 G KC=0.0052 2 -194PT G 1218.78 5 0.056 8E2 0.0037611 -194PT2 G KC=0.00307 9 -194PT L 1622.13 2+ -194PT B 624.8 160.160 21 8.9 1 -194PTS B EAV=192.0 6 -194PT G 699.5 4 0.0025 13[M1E2] 0.023 11 -194PT2 G KC=0.019 10$LC=0.0032 14 -194PT G 1000.12 4 0.047 6E2+M1 0.0083 18 -194PT2 G KC=0.0068 15$LC=0.00113 21 -194PT G 1293.67 6 0.046 7M1+E2 0.02 1 -194PT2 G KC=0.016 8 -194PT G 1622.20 180.064 9 -194PT L 1670.64 2+ -194PT B 576.3 160.072 10 9.2 1 -194PTS B EAV=175.0 6 -194PT G 859.45 180.0017 8[E2] 0.0075 2 -194PT2 G KC=0.0060 2 -194PT G 1048.64 5 0.026 4M1(+E2) 0.011 1 -194PT2 G KC=0.0077 24$LC=0.0012 40 -194PT G 1342.16 6 0.038 5M1+E2 0.005 2 -194PT2 G KC=0.0040 15 -194PT G 1670.72 100.0058 8 -194PT L 1778.67 1,2+ -194PT B 468.2 160.0035 6 10.2 -194PTS B EAV=138.2 5 -194PT G 1156.6 3 0.0018 5M1(+E2) 0.0088 19 -194PT2 G KC=0.0073 16 -194PT G 1450.23 110.0016 3M1+E2 0.0040 3 -194PT2 G KC=0.0033 3 -194PT L 1797.355 1- -194PT B 449.5 160.33 4 8.2 -194PTS B EAV=132.0 5 -194PT G 364.867 150.041 6E2 0.0568 17 -194PT2 G KC=0.038 11$LC=0.014 1$MC=0.0050 2 -194PT G 530.173 300.016 2E1 0.0073522 -194PT2 G KC=0.0061 2$LC=0.00094 3$MC=0.00031 1 -194PT G 1175.38 5 0.061 8E1 0.00159 5 -194PT2 G KC=0.00133 4 -194PT G 1468.91 7 0.19 3E1 0.00109 3 -194PT2 G KC=0.00092 3 -194PT G 1797.48 9 0.0176 2 -194PT L 1893.59 (0)+ -194PT B 353.3 160.021 3 9 1 -194PTS B EAV=10.9 5 -194PT G 1565.15 8 0.021 3 -194PT L 1924.29 1+ -194PT B 322.6 160.0035 5 9.6 -194PTS B EAV=91.2 5 -194PT G 1595.77 100.0016 3 -194PT G 1924.42 140.0018 3 -194PT L 1930.25 (2)+ -194PT B 316.6 160.0032 5 9.7 1 -194PTS B EAV=89.3 5 -194PT G 1308.15 120.00130 22E2(+M1) 0.0039 6 -194PT2 G KC=0.0032 5 -194PT G 1601.90 120.0020 3 -194PT L 2043.72 1+ -194PT B 203.2 160.0090 13 8.6 -194PTS B EAV=55.1 5 -194PT G 1421.48 280.00063 21M1(+E2) 0.0052 13 -194PT2 G KC=0.0043 10 -194PT G 1715.28 110.00131 21 -194PT G 2043.72 110.0071 10 -194PT L 2053.08 (<=3)+ -194PT B 193.8 160.0030 8 9 1U -194PTS B EAV=52.4 5 -194PT G 1431.35 340.0022 7 -194PT G 1724.54 150.00076 14 -194PT L 2063.81 1,2+ -194PT B 183.1 160.0040 6 8.8 -194PTS B EAV=49.3 5 -194PT G 1441.78 140.0015 3M1+E2 0.0041 5 -194PT2 G KC=0.0034 4 -194PT G 1735.37 120.0025 4 -194PT L 2085.6 0+ -194PT B 161.3 160.0066 15 8.4 1 -194PTS B EAV=43.1 4 -194PT G 1463.50 150.0059 14E2 0.00267 8 -194PT2 G KC=0.00220 7 -194PT G 1757.27 190.00042 11 -194PT L 2109.08 1,2+ -194PT B 137.8 160.031 4 7.5 -194PTS B EAV=36.5 5 -194PT G 1186.4 4 0.0084 19E2(+M1) 0.0056 17 -194PT2 G KC=0.0046 14 -194PT G 1487.05 8 0.0170 23M1(+E2) 0.0045 12 -194PT2 G KC=0.0037 10 -194PT G 1780.69 110.0052 8 -194PT L 2114.17 1+ -194PT B 132.7 160.0081 11 8.1 -194PTS B EAV=35.0 5 -194PT G 1492.18 130.0015 3M1(+E2) 0.0045 12 -194PT2 G KC=0.0037 10 -194PT G 1785.69 110.0040 6 -194PT G 2114.20 140.0026 4 -194PT L 2134.2 (0,1,2)+ -194PT B 112.7 160.046 6 7.1 1 -194PTS B EAV=29.5 4 -194PT G 1512.15 210.0132 18 -194PT G 1805.75 9 0.032 5 -194PT L 2140.83 (0,1,2)+ -194PT B 106.1 160.0021 4 8.4 1 -194PTS B EAV=27.7 4 -194PT G 1518.76 140.0017 3 -194PT G 1812.59 250.00045 14 -194PT L 2158.05 1,2+ -194PT B 88.9 160.0019 3 8.2 -194PTS B EAV=23.0 4 -194PT G 1829.59 150.0019 3 - +194PT 194IR B- DECAY (19.3 H) +194PT T Auger electrons and X ray energies and emission intensities: +194PT T {U Energy (keV)} {U Intensity} {U Line} +194PT T +194PT T 65.123 0.24 3 XKA2 +194PT T 66.833 0.41 5 XKA1 +194PT T +194PT T 75.369 |] XKB3 +194PT T 75.749 |] 0.00138 19 XKB1 +194PT T 76.234 |] XKB5II +194PT T +194PT T 77.786 |] XKB2 +194PT T 78.07 |] 0.00040 5 XKB4 +194PT T 78.337 |] XKO23 +194PT T +194PT T 8.268-13.361 0.36 6 XL (total) +194PT T 8.268 XLL +194PT T -13.361 XLG +194PT T +194PT T 50.4-55.02 |] KLL AUGER +194PT T 61.12-64.62 |] 0.035 4 KLX AUGER +194PT T 71.7-74.1 |] KXY AUGER +194IR P 0.0 1- 19.3 H 1 2246.8 16 +194PT N 1.0 1.0 1 1.0 +194PT G 1675.24 170.00086 18 +194PT G 2207 1 0.0013 4 +194PT L 0 0+ STABLE +194PT B 2246.9 1685.4 19 8.2 1 +194PTS B EAV=845.7 7 +194PT L 328.449 2+ 41.8 PS +194PT B 1918.5 169.3 13 8.9 1 +194PTS B EAV=705.4 7 +194PT G 328.448 1413.1 17E2 0.076 2 +194PT2 G KC=0.049 2$LC=0.020 1$MC=0.0070 2 +194PT L 621.99 2+ 35 PS +194PT B 1624.9 161.28 20 9.5 1 +194PTS B EAV=582.2 7 +194PT G 293.541 142.5 3E2+M1+E0 0.107 3 +194PT2 G KC=0.066 2$LC=0.031 1$MC=0.010 1 +194PT G 621.971 190.33 5E2 0.0150 5 +194PT2 G KC=0.0115 4$LC=0.0025 1 +194PT L 811.33 4+ +194PT G 482.857 260.046 6E2 0.0272 8 +194PT2 G KC=0.0200 6$LC=0.0056 2$MC=0.0016 1 +194PT L 922.739 3+ +194PT B 1324.2 160.30 4 10.5 1U +194PTS B EAV=452.4 6 +194PT G 111.4 4 0.0017 6[M1,E2] 4.1 10 +194PT2 G KC=2.4 18$LC=1.3 7$MC=0.40 18 +194PT G 300.741 140.35 5E2(+M1) 0.103 4 +194PT2 G KC=0.061 2$LC=0.028 1$MC=0.014 1 +194PT G 594.291 190.062 8E2(+M1) 0.0166 5 +194PT2 G KC=0.0126 4$LC=0.0030 1$MC=0.0010 1 +194PT L 1229.6 4+ +194PT G 607.61 8 0.0039 6E2 0.0158 5 +194PT2 G KC=0.0121 4$LC=0.0028 1$MC=0.0010 1 +194PT L 1267.145 0+ +194PT B 979.8 161.77 23 8.6 1 +194PTS B EAV=323.1 6 +194PT G 645.146 201.18 16E2 0.0138 4 +194PT2 G KC=0.0106 3$LC=0.0024 1 +194PT G 938.690 250.60 8E2 0.0062719 +194PT2 G KC=0.0050 2$LC=0.00090 3 +194PT L 1432.49 3- +194PT G 202.91 150.0030 8E1 0.068 2 +194PT2 G KC=0.056 2$LC=0.0093 3$MC=0.0027 1 +194PT G 621.29 150.0096 18E1+M2 0.0091 18 +194PT2 G KC=0.0074 15$LC=0.0013 3 +194PT G 810.66 190.0025 6[E1] 0.0032 1 +194PT2 G KC=0.0027 1 +194PT G 1104.05 5 0.026 4E1 0.00178 5 +194PT2 G KC=0.00149 5 +194PT G 1432.52 120.0011 3[E3] 0.0057117 +194PT2 G KC=0.00455 14 +194PT L 1479.2 0+ +194PT B 767.7 160.61 8 8.7 1 +194PTS B EAV=243.4 6 +194PT G 857.12 190.0071 12[E2] 0.0075 2 +194PT2 G KC=0.0060 2 +194PT G 1150.75 5 0.60 8E2 0.0042013 +194PT2 G KC=0.00342 10 +194PT G 1479.2 E0 +194PT L 1511.927 2+ +194PT B 735.0 160.56 7 8.6 1 +194PTS B EAV=231.5 6 +194PT G 244.83 5 0.0077 11E2 0.186 6 +194PT2 G KC=0.102 3$LC=0.063 2$MC=0.020 1 +194PT G 589.179 170.140 18E2+M1 0.0231 24 +194PT2 G KC=0.0181 5$LC=0.0037 3$MC=0.0013 1 +194PT G 700.55 4 0.026 5E2 0.0115 4 +194PT2 G KC=0.0089 3$LC=0.0019 1 +194PT G 889.98 4 0.051 7E2+M1 0.0105 17 +194PT2 G KC=0.0085 14$LC=0.0015 2 +194PT G 1183.49 5 0.31 4E2+M1 0.0057917 +194PT2 G KC=0.00476 14 +194PT G 1511.98 100.024 4(E2) 0.00249 7 +194PT2 G KC=0.00208 6 +194PT L 1547.24 0+ +194PT B 699.7 160.070 9 9.5 1 +194PTS B EAV=218.7 6 +194PT G 925.26 6 0.0126 18E2 0.0065 2 +194PT2 G KC=0.0052 2 +194PT G 1218.78 5 0.056 8E2 0.0037611 +194PT2 G KC=0.00307 9 +194PT L 1622.13 2+ +194PT B 624.8 160.160 21 8.9 1 +194PTS B EAV=192.0 6 +194PT G 699.5 4 0.0025 13[M1,E2] 0.023 11 +194PT2 G KC=0.019 10$LC=0.0032 14 +194PT G 1000.12 4 0.047 6E2+M1 0.0083 18 +194PT2 G KC=0.0068 15$LC=0.00113 21 +194PT G 1293.67 6 0.046 7M1+E2 0.02 1 +194PT2 G KC=0.016 8 +194PT G 1622.20 180.064 9 +194PT L 1670.64 2+ +194PT B 576.3 160.072 10 9.2 1 +194PTS B EAV=175.0 6 +194PT G 859.45 180.0017 8[E2] 0.0075 2 +194PT2 G KC=0.0060 2 +194PT G 1048.64 5 0.026 4M1(+E2) 0.011 1 +194PT2 G KC=0.0077 24$LC=0.0012 40 +194PT G 1342.16 6 0.038 5M1+E2 0.005 2 +194PT2 G KC=0.0040 15 +194PT G 1670.72 100.0058 8 +194PT L 1778.67 1,2+ +194PT B 468.2 160.0035 6 10.2 +194PTS B EAV=138.2 5 +194PT G 1156.6 3 0.0018 5M1(+E2) 0.0088 19 +194PT2 G KC=0.0073 16 +194PT G 1450.23 110.0016 3M1+E2 0.0040 3 +194PT2 G KC=0.0033 3 +194PT L 1797.355 1- +194PT B 449.5 160.33 4 8.2 +194PTS B EAV=132.0 5 +194PT G 364.867 150.041 6E2 0.0568 17 +194PT2 G KC=0.038 11$LC=0.014 1$MC=0.0050 2 +194PT G 530.173 300.016 2E1 0.0073522 +194PT2 G KC=0.0061 2$LC=0.00094 3$MC=0.00031 1 +194PT G 1175.38 5 0.061 8E1 0.00159 5 +194PT2 G KC=0.00133 4 +194PT G 1468.91 7 0.19 3E1 0.00109 3 +194PT2 G KC=0.00092 3 +194PT G 1797.48 9 0.0176 2 +194PT L 1893.59 (0)+ +194PT B 353.3 160.021 3 9 1 +194PTS B EAV=10.9 5 +194PT G 1565.15 8 0.021 3 +194PT L 1924.29 1+ +194PT B 322.6 160.0035 5 9.6 +194PTS B EAV=91.2 5 +194PT G 1595.77 100.0016 3 +194PT G 1924.42 140.0018 3 +194PT L 1930.25 (2)+ +194PT B 316.6 160.0032 5 9.7 1 +194PTS B EAV=89.3 5 +194PT G 1308.15 120.00130 22E2(+M1) 0.0039 6 +194PT2 G KC=0.0032 5 +194PT G 1601.90 120.0020 3 +194PT L 2043.72 1+ +194PT B 203.2 160.0090 13 8.6 +194PTS B EAV=55.1 5 +194PT G 1421.48 280.00063 21M1(+E2) 0.0052 13 +194PT2 G KC=0.0043 10 +194PT G 1715.28 110.00131 21 +194PT G 2043.72 110.0071 10 +194PT L 2053.08 (LE3)+ +194PT B 193.8 160.0030 8 9 1U +194PTS B EAV=52.4 5 +194PT G 1431.35 340.0022 7 +194PT G 1724.54 150.00076 14 +194PT L 2063.81 1,2+ +194PT B 183.1 160.0040 6 8.8 +194PTS B EAV=49.3 5 +194PT G 1441.78 140.0015 3M1+E2 0.0041 5 +194PT2 G KC=0.0034 4 +194PT G 1735.37 120.0025 4 +194PT L 2085.6 0+ +194PT B 161.3 160.0066 15 8.4 1 +194PTS B EAV=43.1 4 +194PT G 1463.50 150.0059 14E2 0.00267 8 +194PT2 G KC=0.00220 7 +194PT G 1757.27 190.00042 11 +194PT L 2109.08 1,2+ +194PT B 137.8 160.031 4 7.5 +194PTS B EAV=36.5 5 +194PT G 1186.4 4 0.0084 19E2(+M1) 0.0056 17 +194PT2 G KC=0.0046 14 +194PT G 1487.05 8 0.0170 23M1(+E2) 0.0045 12 +194PT2 G KC=0.0037 10 +194PT G 1780.69 110.0052 8 +194PT L 2114.17 1+ +194PT B 132.7 160.0081 11 8.1 +194PTS B EAV=35.0 5 +194PT G 1492.18 130.0015 3M1(+E2) 0.0045 12 +194PT2 G KC=0.0037 10 +194PT G 1785.69 110.0040 6 +194PT G 2114.20 140.0026 4 +194PT L 2134.2 (0,1,2)+ +194PT B 112.7 160.046 6 7.1 1 +194PTS B EAV=29.5 4 +194PT G 1512.15 210.0132 18 +194PT G 1805.75 9 0.032 5 +194PT L 2140.83 (0,1,2)+ +194PT B 106.1 160.0021 4 8.4 1 +194PTS B EAV=27.7 4 +194PT G 1518.76 140.0017 3 +194PT G 1812.59 250.00045 14 +194PT L 2158.05 1,2+ +194PT B 88.9 160.0019 3 8.2 +194PTS B EAV=23.0 4 +194PT G 1829.59 150.0019 3 + diff --git a/HEN_HOUSE/spectra/lnhb/K-40.txt b/HEN_HOUSE/spectra/lnhb/K-40.txt index d275c0bbd..b6a8af8f0 100644 --- a/HEN_HOUSE/spectra/lnhb/K-40.txt +++ b/HEN_HOUSE/spectra/lnhb/K-40.txt @@ -1,67 +1,70 @@ - 40AR 40K EC DECAY (1.2504E9 Y) - 40AR H TYP=Upadte$AUT=M.M. Bé$CUT= -- $ - 40AR2 H TYP=Update$AUT=X. Mougeot$CUT=30-APR-2009$ - 40AR C Evaluation history: Type=Upadte;Author=M.M. Bé;Cutoff date= -- - 40AR2C Type=Update;Author=X. Mougeot;Cutoff date=30-APR-2009 - 40AR C References: 1947GL07, 1950SA52, 1953BU58, 1955BA25, 1955KO21, 1955SU38, - 40AR2C 1956MC20, 1957WE43, 1959KE26, 1959Ti20, 1960SA31, 1961GL07, 1962FL05, - 40AR3C 1962EN01, 1965BR25, 1965LE15, 1966FE09, 1967KI10, 1970JA15, 1977CE04, - 40AR4C 1979HE13, 1990EN08, 2001BE81, 2003AU03, 2004KO09, 2008KI07 - 40AR T Auger electrons and X ray energies and emission intensities: - 40AR T {U Energy (keV)} {U Intensity} {U Line} - 40AR T - 40AR T 2.95566 0.299 9 XKA2 - 40AR T 2.95774 0.592 17 XKA1 - 40AR T - 40AR T 3.1905 |] 0.096 4 XKB1 - 40AR T - 40AR T - 40AR T 0.2195-0.3114 0.003 1 XL (total) - 40AR T 0.2195 XLL - 40AR T 0.2215 XLC - 40AR T 0.3112-0.3114 XLB - 40AR T - 40AR T 2.511-2.669 |] KLL AUGER - 40AR T 2.831-2.942 |] 7.24 11 KLX AUGER - 40AR T 3.149-3.174 |] KXY AUGER - 40AR T 0.17-0.31 2.22 2 L AUGER - 40K P 0.0 4- 1.2504E9 Y30 1504.69 19 - 40AR N 9.302E0 9.302E0 0.1075 9.302E0 - 40AR L 0 0+ STABLE - 40AR E 0.00100 120.2 121.35 3U - 40AR2 E CK=0.88 $CL=0.086 $CM=0.013 - 40AR L 1460.851 6 2+ 0.00161 NS6 - 40AR E 10.55 1111.55 1U - 40AR2 E CK=0.763 $CL=0.209 $CM=0.027 - 40AR G 1460.822 6 10.55 11E2 1028E-715 - 40AR2 G KC=2.63E-5 4$LC=2.15E-6 3$MC=2.10E-7 3 - - 40CA 40K B- DECAY (1.2504E9 Y) - 40CA H TYP=Upadte$AUT=M.M. Bé$CUT= -- $ - 40CA2 H TYP=Update$AUT=X. Mougeot$CUT=30-APR-2009$ - 40CA C Evaluation history: Type=Upadte;Author=M.M. Bé;Cutoff date= -- - 40CA2C Type=Update;Author=X. Mougeot;Cutoff date=30-APR-2009 - 40CA C References: 1947GL07, 1950SA52, 1953BU58, 1955BA25, 1955KO21, 1955SU38, - 40CA2C 1956MC20, 1957WE43, 1959KE26, 1959Ti20, 1960SA31, 1961GL07, 1962FL05, - 40CA3C 1962EN01, 1965BR25, 1965LE15, 1966FE09, 1967KI10, 1970JA15, 1977CE04, - 40CA4C 1979HE13, 1990EN08, 2001BE81, 2003AU03, 2004KO09, 2008KI07 - 40CA T Auger electrons and X ray energies and emission intensities: - 40CA T {U Energy (keV)} {U Intensity} {U Line} - 40CA T - 40CA T 3.68813 XKA2 - 40CA T 3.69172 XKA1 - 40CA T - 40CA T 4.0128 |] XKB1 - 40CA T 4.0325 |] XKB5II - 40CA T - 40CA T - 40CA T - 40CA T 3.123-3.307 |] KLL AUGER - 40CA T 3.543-3.666 |] KLX AUGER - 40CA T 3.951-3.987 |] KXY AUGER - 40K P 0.0 4- 1.2504E9 Y30 1311.07 11 - 40CA N 1.12E0 1.12E0 0.8925 1.12E0 - 40CA L 0 0+ STABLE - 40CA B 1311.07 1189.25 17 20.58 3U - 40CAS B EAV=508.32 6 - + 40AR 40K EC DECAY (1.2504E9 Y) + 40AR H TYP=UPD$AUT=M.-M.BE$CUT=19-JUL-2012$ + 40AR2 H TYP=UPD$AUT=X.MOUGEOT$CUT=30-APR-2009$ + 40AR C References:1931Or**, 1947GL07, 1948Ah**, 1948Gr**, 1948Hi**, 1949Fl**, + 40AR2C 1949St**, 1950SA52, 1950Sa**, 1950Gr**, 1950Fa**, 1950Ho**, 1950Sp**, + 40AR3C 1950Sm**, 1951Go**, 1951De**, 1953BU58, 1955BA25, 1955KO21, 1955SU38, + 40AR4C 1956MC20, 1956We**, 1957WE43, 1959KE26, 1959Ti20, 1960SA31, 1961GL07, + 40AR5C 1962FL05, 1962EN01, 1965BR25, 1965LE15, 1966De**, 1966Eg**, 1966FE09, + 40AR6C 1967KI10, 1970JA15, 1971Ve**, 1972Go**, 1977CE04, 1979HE13, 1990EN08, + 40AR7C 2001Be81, 2001Ch**, 2003Au03, 2004Ko09, 2008Ki07 + 40AR T Auger electrons and X ray energies and emission intensities: + 40AR T {U Energy (keV)} {U Intensity} {U Line} + 40AR T + 40AR T 2.95566 0.299 9 XKA2 + 40AR T 2.95774 0.592 17 XKA1 + 40AR T + 40AR T 3.1905 |] 0.096 4 XKB1 + 40AR T + 40AR T + 40AR T 0.2195-0.3114 0.003 1 XL (total) + 40AR T 0.2195 XLL + 40AR T 0.2215 XLC + 40AR T 0.3112-0.3114 XLB + 40AR T + 40AR T 2.511-2.669 |] KLL AUGER + 40AR T 2.831-2.942 |] 7.24 11 KLX AUGER + 40AR T 3.149-3.174 |] KXY AUGER + 40AR T 0.17-0.31 2.22 2 L AUGER + 40K P 0.0 4- 1.2504E9 Y30 1504.69 19 + 40AR N 9.302E0 9.302E0 0.1075 9.302E0 + 40AR L 0 0+ STABLE + 40AR E 0.00100 120.2 121.35 3U + 40AR2 E EAV=251.95 9$CK=0.875622 $CL=85572E-6 $CM=12935E-6 + 40AR L 1460.851 6 2+ 0.00161 NS6 + 40AR E 10.55 1111.55 1U + 40AR2 E CK=0.763 $CL=0.209 $CM=0.027 + 40AR G 1460.822 6 10.55 11E2 1028E-715 + 40AR2 G KC=2.63E-5 4$LC=2.15E-6 3$MC=2.10E-7 3 + 40AR3 G IPC=0.000073 5 + + 40CA 40K B- DECAY (1.2504E9 Y) + 40CA H TYP=UPD$AUT=M.-M.BE$CUT=19-JUL-2012$ + 40CA2 H TYP=UPD$AUT=X.MOUGEOT$CUT=30-APR-2009$ + 40CA C References:1931Or**, 1947GL07, 1948Ah**, 1948Gr**, 1948Hi**, 1949Fl**, + 40CA2C 1949St**, 1950SA52, 1950Sa**, 1950Gr**, 1950Fa**, 1950Ho**, 1950Sp**, + 40CA3C 1950Sm**, 1951Go**, 1951De**, 1953BU58, 1955BA25, 1955KO21, 1955SU38, + 40CA4C 1956MC20, 1956We**, 1957WE43, 1959KE26, 1959Ti20, 1960SA31, 1961GL07, + 40CA5C 1962FL05, 1962EN01, 1965BR25, 1965LE15, 1966De**, 1966Eg**, 1966FE09, + 40CA6C 1967KI10, 1970JA15, 1971Ve**, 1972Go**, 1977CE04, 1979HE13, 1990EN08, + 40CA7C 2001Be81, 2001Ch**, 2003Au03, 2004Ko09, 2008Ki07 + 40CA T Auger electrons and X ray energies and emission intensities: + 40CA T {U Energy (keV)} {U Intensity} {U Line} + 40CA T + 40CA T 3.68813 XKA2 + 40CA T 3.69172 XKA1 + 40CA T + 40CA T 4.0128 |] XKB1 + 40CA T 4.0325 |] XKB5II + 40CA T + 40CA T + 40CA T + 40CA T 3.123-3.307 |] KLL AUGER + 40CA T 3.543-3.666 |] KLX AUGER + 40CA T 3.951-3.987 |] KXY AUGER + 40K P 0.0 4- 1.2504E9 Y30 1311.07 11 + 40CA N 1.12E0 1.12E0 0.8925 1.12E0 + 40CA L 0 0+ STABLE + 40CA B 1311.07 1189.25 17 20.58 3U + 40CAS B EAV=583.982 48 + diff --git a/HEN_HOUSE/spectra/lnhb/Kr-85.txt b/HEN_HOUSE/spectra/lnhb/Kr-85.txt index cf87e69d1..ff1803e7a 100644 --- a/HEN_HOUSE/spectra/lnhb/Kr-85.txt +++ b/HEN_HOUSE/spectra/lnhb/Kr-85.txt @@ -1,37 +1,39 @@ - 85RB 85KR B- DECAY (10.752 Y) - 85RB H TYP=update$AUT=V. Chisté$CUT= -- $ - 85RB C Evaluation history: Type=update;Author=V. Chisté;Cutoff date= -- - 85RB T Auger electrons and X ray energies and emission intensities: - 85RB T {U Energy (keV)} {U Intensity} {U Line} - 85RB T - 85RB T 13.3359 0.00054014 XKA2 - 85RB T 13.3955 0.00104025 XKA1 - 85RB T - 85RB T 14.9519 |] XKB3 - 85RB T 14.9614 |] 0.000253 7 XKB1 - 85RB T 15.085 |] XKB5II - 85RB T - 85RB T 15.1856 |] XKB2 - 85RB T 15.205 |] 2.94E-5 13 XKB4 - 85RB T - 85RB T - 85RB T 10.987-11.503 |] KLL AUGER - 85RB T 12.782-13.381 |] 0.00090124 KLX AUGER - 85RB T 14.556-15.172 |] KXY AUGER - 85RB T 1.1-2 0.00336 6 L AUGER - 85KR P 0.0 9/2+ 10.752 Y 23 687.1 19 - 85RB N 1.0 1.0 1 1.0 - 85RB L 0 5/2- STABLE - 85RB B 687.1 1999.562 10 8.4 1U - 85RBS B EAV=251.4 8 - 85RB L 151.18 3 3/2- 0.71 NS 5 - 85RB G 151.18 3 2.2E-6 13M1+()E2 0.072 8 0.0488 14 - 85RB2 G KC=0.0430 13$LC=0.00485 14$MC=8.17E-4 25 - 85RB L 513.998 5 9/2+ 1.015 US 1 - 85RB B 173.1 190.438 10 9.5 - 85RBS B EAV=47.5 6 - 85RB G 362.81 4 2.18E-6 44(E3) 0.034 1 - 85RB2 G KC=0.0292 9$LC=0.00400 12$MC=0.00067 2 - 85RB G 513.997 5 0.435 10M2 0.0072122 - 85RB2 G KC=0.00635 19$LC=0.00072 2$MC=1.22E-4 4 - + 85RB 85KR B- DECAY (10.752 Y) + 85RB H TYP=UPD$AUT=V.CHISTE$CUT=27-MAR-2006$ + 85RB T Auger electrons and X ray energies and emission intensities: + 85RB T {U Energy (keV)} {U Intensity} {U Line} + 85RB T + 85RB T 13.3359 0.00054014 XKA2 + 85RB T 13.3955 0.00104025 XKA1 + 85RB T + 85RB T 14.9519 |] XKB3 + 85RB T 14.9614 |] 0.000253 7 XKB1 + 85RB T 15.085 |] XKB5II + 85RB T + 85RB T 15.1856 |] XKB2 + 85RB T 15.205 |] 2.94E-5 13 XKB4 + 85RB T + 85RB T + 85RB T 10.987-11.503 |] KLL AUGER + 85RB T 12.782-13.381 |] 0.00090124 KLX AUGER + 85RB T 14.556-15.172 |] KXY AUGER + 85RB T 1.1-2 0.00336 6 L AUGER + 85KR P 0.0 9/2+ 10.752 Y 23 687.1 19 + 85RB N 1.0 1.0 1 1.0 + 85RB L 0 5/2- STABLE + 85RB B 687.1 1999.562 10 8.4 1U + 85RBS B EAV=251.4 8 + 85RB L 151.18 3 3/2- 0.71 NS 5 + 85RB G 151.18 3 2.2E-6 13M1+E2 0.072 8 0.0488 14 + 85RB2 G KC=0.0430 13$LC=0.00485 14$MC=0.000817 25$NC=1.092E-4 33 + 85RB3 G OC=5.80E-6 17 + 85RB L 513.998 5 9/2+ 1.015 US 1 + 85RB B 173.1 190.438 10 9.5 + 85RBS B EAV=47.5 6 + 85RB G 362.81 4 2.18E-6 44(E3) 0.034 1 + 85RB2 G KC=0.0292 9$LC=0.00400 12$MC=0.00067 2$NC=8.56E-5 26 + 85RB3 G OC=3.71E-6 11 + 85RB G 513.997 5 0.435 10M2 0.0072122 + 85RB2 G KC=0.00635 19$LC=0.00072 2$MC=0.000122 4$NC=1.634E-5 49 + 85RB3 G OC=8.77E-7 26 + diff --git a/HEN_HOUSE/spectra/lnhb/La-138.txt b/HEN_HOUSE/spectra/lnhb/La-138.txt index 549076cfb..69d4fb02a 100644 --- a/HEN_HOUSE/spectra/lnhb/La-138.txt +++ b/HEN_HOUSE/spectra/lnhb/La-138.txt @@ -1,88 +1,86 @@ -138BA 138LA EC DECAY (103.6E9 Y) -138BA H TYP=UPD$AUT=X. Mougeot$CUT=01-MAY-2016$ -138BA2 H TYP=FUL$AUT=M.M. Bé$CUT=01-NOV-2013$ -138BA C Evaluation history: Type=UPD;Author=X. Mougeot;Cutoff date=01-MAY-2016 -138BA2C Type=FUL;Author=M.M. Bé;Cutoff date=01-NOV-2013 -138BA C References: 1956Tu17, 1956Tu17, 1957Gl20, 1957Gl20, 1966De04, 1966De04, -138BA2C 1972El02, 1972Ma31, 1972El02, 1972Ma31, 1979Ta21, 1979Ta21, 1981Sa42, -138BA3C 1981Sa42, 1983No02, 1983No02, 1984Ma46, 1984Ma46, 1997Ni12, 1997Ni12, -138BA4C 2002Ba85, 2002Ba85, 2005Be73, 2005Be73, 2008Ki07, 2008Ki07, 2012Qu02, -138BA5C 2012Wa38, 2012Qu02, 2012Wa38, 2016Qu01 -138BA T Auger electrons and X ray energies and emission intensities: -138BA T {U Energy (keV)} {U Intensity} {U Line} -138BA T -138BA T 31.8174 10.63 15 XKA2 -138BA T 32.1939 19.58 26 XKA1 -138BA T -138BA T 36.3045 |] XKB3 -138BA T 36.3786 |] 5.76 10 XKB1 -138BA T 36.654 |] XKB5II -138BA T -138BA T 37.258 |] XKB2 -138BA T 37.312 |] 1.45 4 XKB4 -138BA T 37.425 |] XKO23 -138BA T -138BA T 3.9544-5.8104 6.03 10 XL (total) -138BA T 3.9544 0.1201 30 XLL -138BA T 4.4515-4.4666 3.11 8 XLA -138BA T 4.3307 0.0367 10 XLC -138BA T 4.8278-5.207 2.39 5 XLB -138BA T 5.3715-5.8104 0.380 8 XLG -138BA T -138BA T 25.314-26.786 |] KLL AUGER -138BA T 30.095-32.179 |] 4.16 18 KLX AUGER -138BA T 34.86-37.41 |] KXY AUGER -138BA T 2.66-5.81 48.8 4 L AUGER -138LA P 0.0 5+ 103.6E9 Y 20 1740.0 34 -138BA N 1.534E0 1.534E0 0.652 6 1.534E0 -138BA L 0 0+ STABLE -138BA L 1435.816 102+ -138BA E 65.2 617.2 2U -138BA2 E CK=0.637 5$CL=0.275 3$CM=0.0880 11 -138BA G 1435.795 1065.1 6E2 9.17E-413 -138BA2 G KC=7.42E-4 11$LC=9.37E-5 14$MC=1.92E-5 3 - -138CE 138LA B- DECAY (103.6E9 Y) -138CE H TYP=UPD$AUT=X. Mougeot$CUT=01-MAY-2016$ -138CE2 H TYP=FUL$AUT=M.M. Bé$CUT=01-NOV-2013$ -138CE C Evaluation history: Type=UPD;Author=X. Mougeot;Cutoff date=01-MAY-2016 -138CE2C Type=FUL;Author=M.M. Bé;Cutoff date=01-NOV-2013 -138CE C References: 1956Tu17, 1956Tu17, 1957Gl20, 1957Gl20, 1966De04, 1966De04, -138CE2C 1972El02, 1972Ma31, 1972El02, 1972Ma31, 1979Ta21, 1979Ta21, 1981Sa42, -138CE3C 1981Sa42, 1983No02, 1983No02, 1984Ma46, 1984Ma46, 1997Ni12, 1997Ni12, -138CE4C 2002Ba85, 2002Ba85, 2005Be73, 2005Be73, 2008Ki07, 2008Ki07, 2012Qu02, -138CE5C 2012Wa38, 2012Qu02, 2012Wa38, 2016Qu01 -138CE T Auger electrons and X ray energies and emission intensities: -138CE T {U Energy (keV)} {U Intensity} {U Line} -138CE T -138CE T 34.2793 0.0261 6 XKA2 -138CE T 34.72 0.0478 11 XKA1 -138CE T -138CE T 39.1705 |] XKB3 -138CE T 39.2578 |] 0.0144 4 XKB1 -138CE T 39.549 |] XKB5II -138CE T -138CE T 40.233 |] XKB2 -138CE T 40.337 |] 0.00365 12 XKB4 -138CE T 40.423 |] XKO23 -138CE T -138CE T 4.2868-6.3412 0.01301 29 XL (total) -138CE T 4.2868 0.000252 9 XLL -138CE T 4.822-4.8411 0.00642 20 XLA -138CE T 4.7274 9.54E-5 29 XLC -138CE T 5.2625-5.665 0.00538 12 XLB -138CE T 5.8755-6.3412 0.00085 2 XLG -138CE T -138CE T 27.19-28.828 |] KLL AUGER -138CE T 32.392-34.7 |] 0.0091 5 KLX AUGER -138CE T 37.57-40.4 |] KXY AUGER -138CE T 2.85-6.51 0.0895 7 L AUGER -138LA P 0.0 5+ 103.6E9 Y 20 1051.7 40 -138CE N 2.874E0 2.874E0 0.348 6 2.874E0 -138CE L 0 0+ STABLE -138CE L 788.744 8 2+ -138CE B 263 4 34.8 6 18.7 2U -138CES B EAV=91.1 21 -138CE G 788.742 8 34.7 6E2 0.00342 5 -138CE2 G KC=0.00291 4$LC=4.06E-4 6$MC=8.52E-5 12 - +138BA 138LA EC DECAY (103.6E9 Y) +138BA H TYP=UPD$AUT=X.MOUGEOT$CUT=01-MAY-2016$ +138BA2 H TYP=FUL$AUT=M.-M.BE$CUT=01-NOV-2013$ +138BA C References:1956Tu17, 1956Tu17, 1957Gl20, 1957Gl20, 1966De04, 1966De04, +138BA2C 1972El02, 1972Ma31, 1972El02, 1972Ma31, 1979Ta21, 1979Ta21, 1981Sa42, +138BA3C 1981Sa42, 1983No02, 1983No02, 1984Ma46, 1984Ma46, 1997Ni12, 1997Ni12, +138BA4C 2002Ba85, 2002Ba85, 2005Be73, 2005Be73, 2008Ki07, 2008Ki07, 2012Qu02, +138BA5C 2012Wa38, 2012Qu02, 2012Wa38, 2016Qu01 +138BA T Auger electrons and X ray energies and emission intensities: +138BA T {U Energy (keV)} {U Intensity} {U Line} +138BA T +138BA T 31.8174 10.63 15 XKA2 +138BA T 32.1939 19.58 26 XKA1 +138BA T +138BA T 36.3045 |] XKB3 +138BA T 36.3786 |] 5.76 10 XKB1 +138BA T 36.654 |] XKB5II +138BA T +138BA T 37.258 |] XKB2 +138BA T 37.312 |] 1.45 4 XKB4 +138BA T 37.425 |] XKO23 +138BA T +138BA T 3.9544-5.8104 6.03 10 XL (total) +138BA T 3.9544 0.1201 30 XLL +138BA T 4.4515-4.4666 3.11 8 XLA +138BA T 4.3307 0.0367 10 XLC +138BA T 4.8278-5.207 2.39 5 XLB +138BA T 5.3715-5.8104 0.380 8 XLG +138BA T +138BA T 25.314-26.786 |] KLL AUGER +138BA T 30.095-32.179 |] 4.16 18 KLX AUGER +138BA T 34.86-37.41 |] KXY AUGER +138BA T 2.66-5.81 48.8 4 L AUGER +138LA P 0.0 5+ 103.6E9 Y 20 1740.0 34 +138BA N 1.534E0 1.534E0 0.652 61.534E0 +138BA L 0 0+ STABLE +138BA L 1435.816 102+ +138BA E 65.2 617.2 2U +138BA2 E CK=0.637 5$CL=0.275 3$CM=0.0880 11 +138BA G 1435.795 1065.1 6E2 9.17E-413 +138BA2 G KC=0.000742 11$LC=9.37E-5 14$MC=1.92E-5 3 +138BA3 G IPC=5.72E-5 8 + +138CE 138LA B- DECAY (103.6E9 Y) +138CE H TYP=UPD$AUT=X.MOUGEOT$CUT=01-MAY-2016$ +138CE2 H TYP=FUL$AUT=M.-M.BE$CUT=01-NOV-2013$ +138CE C References:1956Tu17, 1956Tu17, 1957Gl20, 1957Gl20, 1966De04, 1966De04, +138CE2C 1972El02, 1972Ma31, 1972El02, 1972Ma31, 1979Ta21, 1979Ta21, 1981Sa42, +138CE3C 1981Sa42, 1983No02, 1983No02, 1984Ma46, 1984Ma46, 1997Ni12, 1997Ni12, +138CE4C 2002Ba85, 2002Ba85, 2005Be73, 2005Be73, 2008Ki07, 2008Ki07, 2012Qu02, +138CE5C 2012Wa38, 2012Qu02, 2012Wa38, 2016Qu01 +138CE T Auger electrons and X ray energies and emission intensities: +138CE T {U Energy (keV)} {U Intensity} {U Line} +138CE T +138CE T 34.2793 0.0261 6 XKA2 +138CE T 34.72 0.0478 11 XKA1 +138CE T +138CE T 39.1705 |] XKB3 +138CE T 39.2578 |] 0.0144 4 XKB1 +138CE T 39.549 |] XKB5II +138CE T +138CE T 40.233 |] XKB2 +138CE T 40.337 |] 0.00365 12 XKB4 +138CE T 40.423 |] XKO23 +138CE T +138CE T 4.2868-6.3412 0.01301 29 XL (total) +138CE T 4.2868 0.000252 9 XLL +138CE T 4.822-4.8411 0.00642 20 XLA +138CE T 4.7274 9.54E-5 29 XLC +138CE T 5.2625-5.665 0.00538 12 XLB +138CE T 5.8755-6.3412 0.00085 2 XLG +138CE T +138CE T 27.19-28.828 |] KLL AUGER +138CE T 32.392-34.7 |] 0.0091 5 KLX AUGER +138CE T 37.57-40.4 |] KXY AUGER +138CE T 2.85-6.51 0.0895 7 L AUGER +138LA P 0.0 5+ 103.6E9 Y 20 1051.7 40 +138CE N 2.874E0 2.874E0 0.348 62.874E0 +138CE L 0 0+ STABLE +138CE L 788.744 8 2+ +138CE B 263 4 34.8 6 18.7 2U +138CES B EAV=91.1 21 +138CE G 788.742 8 34.7 6E2 0.00342 5 +138CE2 G KC=0.00291 4$LC=0.000406 6$MC=8.52E-5 12$NC=1.88E-5 3 +138CE3 G OC=3.01E-6 5 + diff --git a/HEN_HOUSE/spectra/lnhb/La-140.txt b/HEN_HOUSE/spectra/lnhb/La-140.txt index de2e27cd3..8ecf003e3 100644 --- a/HEN_HOUSE/spectra/lnhb/La-140.txt +++ b/HEN_HOUSE/spectra/lnhb/La-140.txt @@ -1,168 +1,204 @@ -140CE 140LA B- DECAY (1.67858 D) -140CE H TYP=Update$AUT=M.M.Bé$CUT=19-JUN-2008$ -140CE C Evaluation history: Type=Update;Author=M.M.Bé;Cutoff date=19-JUN-2008 -140CE C References: 1954Ya02, 1954Ki08, 1957Pe09, 1960Wi10, 1962Ha14, 1964Re09, -140CE2C 1965Si17, 1967Ka12, 1966Dz05, 1968Gu05, 1968Re04, 1968Ba18, 1969GuZV, -140CE3C 1970Ke06, 1970Ka18, 1972GeZG, 1974HeYW, 1975Ha50, 1976Li06, 1977Ge12, -140CE4C 1977DeYO, 1977De34, 1978Ar28, 1978Da21, 1979Bo26, 1980Ho17, 1980Ka32, -140CE5C 1980Ol03, 1982HoZJ, 1982Ad02, 1983Wa26, 1989Ab18, 1991Ch05, 1992Un01, -140CE6C 1998Si17, 2002Ad04, 2002Ba85, 2002Un02, 2004BeZR, 2007Ni07, 2008Ki07, -140CE7C 2012Fi12, 2012Wa38, 2014Un01 -140CE T Auger electrons and X ray energies and emission intensities: -140CE T {U Energy (keV)} {U Intensity} {U Line} -140CE T -140CE T 34.2793 0.591 8 XKA2 -140CE T 34.72 1.082 13 XKA1 -140CE T -140CE T 39.1705 |] XKB3 -140CE T 39.2578 |] 0.326 6 XKB1 -140CE T 39.549 |] XKB5II -140CE T -140CE T 40.233 |] XKB2 -140CE T 40.337 |] 0.0828 21 XKB4 -140CE T -140CE T 4.2868-6.3412 0.343 7 XL (total) -140CE T 4.2868 0.00666 20 XLL -140CE T 4.822-4.8411 0.170 5 XLA -140CE T 4.7274 0.00258 6 XLC -140CE T 5.2625-5.6103 0.1422 25 XLB -140CE T 5.8755-6.3412 0.0222 5 XLG -140CE T -140CE T 27.19-28.828 |] KLL AUGER -140CE T 32.392-34.7 |] 0.206 10 KLX AUGER -140CE T 37.57-40.4 |] KXY AUGER -140CE T 2.8-6.5 2.360 13 L AUGER -140LA P 0.0 3- 1.67858 D 21 3760.9 18 -140CE N 1.0 1.0 1 1.0 -140CE L 0 0+ STABLE -140CE L 1596.213 132+ 0.0916 PS 19 -140CE B 2164.7 184.5 6 9.4 1 -140CES B EAV=846.4 8 -140CE G 1596.203 1395.40 5E2 7.87E-413 -140CE2 G KC=6.76E-4 10$LC=8.63E-5 12$MC=1.79E-5 3 -140CE L 1903.29 4 0+ 0.40 NS 3 -140CE G 307.08 4 0.022 5E2 0.0450 7 -140CE2 G KC=0.0362 6$LC=0.00695 10$MC=1495E-6 21 -140CE G 1903.29 4 -140CE L 2083.236 144+ 3.45 NS 3 -140CE B 1677.7 1820.8 6 8.3 1 -140CES B EAV=629.7 8 -140CE G 487.022 6 46.1 5E2 0.0115617 -140CE2 G KC=0.00963 14$LC=1526E-6 22$MC=3.24E-4 5 -140CE G 2083.219 140.036 7E4 1364E-619 -140CE2 G KC=1162E-6 17$LC=1598E-7 23$MC=3.35E-5 5 -140CE L 2107.830 146+ 7.3 US 15 -140CE G 24.595 4 0.00068919E2 696 10 -140CE2 G LC=545 8$MC=122.0 18 -140CE L 2347.868 142+ -140CE B 1413.0 185.03 12 8.6 1 -140CES B EAV=515.0 8 -140CE G 444.57 4 0.003 1[E2] 0.0149021 -140CE2 G KC=0.01234 18$LC=0.00202 3$MC=4.29E-4 6 -140CE G 751.653 7 4.39 5M1+E2 0.38 4 0.00548 9 -140CE2 G KC=0.00471 8$LC=6.13E-4 10$MC=1277E-7 20 -140CE G 2347.847 140.845 16E2 3.86E-4 5 -140CE2 G KC=3.33E-4 5$LC=4.15E-5 6$MC=8.60E-6 12 -140CE L 2349.789 145+ -140CE B 1411.1 180.262 22 10.7 1U -140CES B EAV=518.8 8 -140CE G 241.959 6 0.436 10M1+E2 0.60 35 0.1005 18 -140CE2 G KC=0.084 3$LC=0.0130 11$MC=0.00275 25 -140CE G 266.554 5 0.492 9M1+E2 0.14 12 0.0785 12 -140CE2 G KC=0.0671 11$LC=0.00906 17$MC=0.00190 4 -140CE L 2411.997 143+ 55 PS 15 -140CE B 1348.9 1844.8 4 7.6 -140CES B EAV=487.6 8 -140CE G 64.129 4 0.014 2M1 4.24 6 -140CE2 G KC=3.61 5$LC=0.499 7$MC=0.1046 15 -140CE G 328.761 4 20.8 3M1+E2 0.049 6 0.0453 7 -140CE2 G KC=0.0388 6$LC=0.00516 8$MC=1078E-6 15 -140CE G 815.784 6 23.72 20M1+E2 0.03 1 0.00471 7 -140CE2 G KC=0.00405 6$LC=5.21E-4 8$MC=1085E-7 16 -140CE L 2464.055 213- 0.10 PS 2 -140CE B 1296.8 185.60 7 8.44 -140CES B EAV=465.6 8 -140CE G 867.839 165.58 7E1+M2 0.044 20 0.00113 3 -140CE2 G KC=9.77E-4 22$LC=1.22E-4 3$MC=2.53E-5 7 -140CE G 2464.031 200.0097 13[E3] 5.98E-4 8 -140CE2 G KC=5.15E-4 8$LC=6.61E-5 10$MC=1375E-8 20 -140CE L 2480.910 144+ 3.2 NS 3 -140CE B 1280.0 181.14 2 9.1 1 -140CES B EAV=458.4 8 -140CE G 68.923 5 0.077 2M1 3.44 5 -140CE2 G KC=2.93 5$LC=0.405 6$MC=0.0848 12 -140CE G 131.121 4 0.47 1M1+E2 0.13 5 0.552 9 -140CE2 G KC=0.468 7$LC=0.0660 22$MC=0.0139 5 -140CE G 397.674 6 0.075 3(E2) 0.0205 3 -140CE2 G KC=0.01689 24$LC=0.00288 4$MC=6.15E-4 9 -140CE L 2515.749 163+ -140CE B 1245.2 185.80 4 8.4 -140CES B EAV=443.8 8 -140CE G 432.513 8 3.00 3M1+E2 0.54 5 0.0210 4 -140CE2 G KC=0.0179 4$LC=0.00245 4$MC=5.14E-4 8 -140CE G 919.533 102.73 3M1+E2 2.6 4 0.00257 6 -140CE2 G KC=0.00219 6$LC=2.95E-4 7$MC=6.16E-5 13 -140CE L 2521.414 142+ -140CE B 1239.5 1811.11 9 8.1 1 -140CES B EAV=441.4 8 -140CE G 109.417 4 0.217 6M1+E2 0.26 2 0.949 15 -140CE2 G KC=0.787 12$LC=0.128 4$MC=0.0271 8 -140CE G 173.546 5 0.126 5M1 0.251 4 -140CE2 G KC=0.214 3$LC=0.0291 4$MC=0.00609 9 -140CE G 438.178 6 0.017 10M1 0.0217 3 -140CE2 G KC=0.0186 3$LC=0.00244 4$MC=5.10E-4 8 -140CE G 618.12 4 0.041 3[E2] 0.00617 9 -140CE2 G KC=0.00520 8$LC=7.68E-4 11$MC=1619E-7 23 -140CE G 925.198 7 7.04 7M1+E2 0.22 4 0.00344 6 -140CE2 G KC=0.00296 5$LC=3.81E-4 6$MC=7.92E-5 12 -140CE G 2521.390 143.41 5E2 3.40E-4 5 -140CE2 G KC=2.94E-4 5$LC=3.65E-5 6$MC=7.56E-6 11 -140CE L 2547.205 231+ -140CE B 1213.7 180.636 7 10 1U -140CES B EAV=438.4 7 -140CE G 950.988 200.531 7M1+E2 0.01 7 0.00328 5 -140CE2 G KC=0.00282 4$LC=3.61E-4 5$MC=7.52E-5 11 -140CE G 2547.180 230.102 2M1 3.70E-4 5 -140CE2 G KC=3.20E-4 5$LC=3.98E-5 6$MC=8.24E-6 12 -140CE L 2899.56 7 2+ -140CE B 861.2 180.112 6 9.5 1 -140CES B EAV=287.3 7 -140CE G 1303.34 7 0.045 6[M1+E2+] 0.0014 2 -140CE2 G KC=0.0012 2$LC=0.00015 2$MC=3.2E-5 5 -140CE G 2899.53 7 0.066 1E2 2.66E-4 4 -140CE2 G KC=2.31E-4 4$LC=2.84E-5 4$MC=5.88E-6 9 -140CE L 3000.88 9 2+ -140CE B 760.0 180.085 9 9.4 1 -140CES B EAV=248.0 7 -140CE G 1097.58 9 0.023 5[E2] 1658E-624 -140CE2 G KC=0.00142 2$LC=1.88E-4 3$MC=3.92E-5 6 -140CE G 1404.66 9 0.062 8[M1+E2] 0.0011715 -140CE2 G KC=0.00101 15$LC=1.29E-4 18$MC=2.7E-5 4 -140CE L 3118.53 102+ -140CE B 642.5 180.027 1 9.6 1 -140CES B EAV=203.7 7 -140CE G 3118.49 100.026 1(E2) 2.34E-4 3 -140CE2 G KC=2.04E-4 3$LC=2.50E-5 4$MC=5.18E-6 8 -140CE L 3319.56 242+ -140CE B 441.3 180.0039 3 9.9 1 -140CES B EAV=132.0 6 -140CE G 3319.52 240.0039 3E2 2.11E-4 3 -140CE2 G KC=1.83E-4 3$LC=2.25E-5 4$MC=4.64E-6 7 -140CE L 3394.82 9 4- -140CE B 366.1 180.020 4 9 -140CES B EAV=106.7 6 -140CE G 1045.02 9 0.020 4[E1] 7.81E-411 -140CE2 G KC=6.75E-4 10$LC=8.37E-5 12$MC=1733E-8 25 -140CE L 3473.55 183- -140CE B 287.4 180.052 7 8.2 -140CES B EAV=81.4 6 -140CE G 992.64 180.010 3[E1] 8.60E-412 -140CE2 G KC=7.43E-4 11$LC=9.24E-5 13$MC=1.91E-5 3 -140CE G 1877.33 180.041 6[E1] 2.84E-4 4 -140CE2 G KC=2.45E-4 4$LC=3.00E-5 5$MC=6.21E-6 9 -140CE L 3520.8 2 4+ -140CE B 240.1 180.011 3 8.6 1 -140CES B EAV=66.7 6 -140CE G 1924.5 2 0.011 3[E2] 5.54E-4 8 -140CE2 G KC=4.78E-4 7$LC=6.01E-5 9$MC=1247E-8 18 - +140CE 140LA B- DECAY (1.67858 D) +140CE H TYP=UPD$AUT=M.-M.BE$CUT=19-JUN-2008$ +140CE C References:1954Ya02, 1954Ki08, 1957Pe09, 1960Wi10, 1962Ha14, 1964Re09, +140CE2C 1965Si17, 1967Ka12, 1966Dz05, 1968Gu05, 1968Re04, 1968Ba18, 1969GuZV, +140CE3C 1970Ke06, 1970Ka18, 1972GeZG, 1974HeYW, 1975Ha50, 1976Li06, 1977Ge12, +140CE4C 1977DeYO, 1977De34, 1978Ar28, 1978Da21, 1979Bo26, 1980Ho17, 1980Ka32, +140CE5C 1980Ol03, 1982HoZJ, 1982Ad02, 1983Wa26, 1989Ab18, 1991Ch05, 1992Un01, +140CE6C 1998Si17, 2002Ad04, 2002Ba85, 2002Un02, 2004BeZR, 2007Ni07, 2008Ki07, +140CE7C 2012Fi12, 2012Wa38, 2014Un01 +140CE T Auger electrons and X ray energies and emission intensities: +140CE T {U Energy (keV)} {U Intensity} {U Line} +140CE T +140CE T 34.2793 0.591 8 XKA2 +140CE T 34.72 1.082 13 XKA1 +140CE T +140CE T 39.1705 |] XKB3 +140CE T 39.2578 |] 0.326 6 XKB1 +140CE T 39.549 |] XKB5II +140CE T +140CE T 40.233 |] XKB2 +140CE T 40.337 |] 0.0828 21 XKB4 +140CE T +140CE T 4.2868-6.3412 0.343 7 XL (total) +140CE T 4.2868 0.00666 20 XLL +140CE T 4.822-4.8411 0.170 5 XLA +140CE T 4.7274 0.00258 6 XLC +140CE T 5.2625-5.6103 0.1422 25 XLB +140CE T 5.8755-6.3412 0.0222 5 XLG +140CE T +140CE T 27.19-28.828 |] KLL AUGER +140CE T 32.392-34.7 |] 0.206 10 KLX AUGER +140CE T 37.57-40.4 |] KXY AUGER +140CE T 2.8-6.5 2.360 13 L AUGER +140LA P 0.0 3- 1.67858 D 21 3760.9 18 +140CE N 1.0 1.0 1 1.0 +140CE L 0 0+ STABLE +140CE L 1596.213 132+ 0.0916 PS 19 +140CE B 2164.7 184.5 6 9.4 1 +140CES B EAV=846.4 8 +140CE G 1596.203 1395.40 5E2 7.87E-413 +140CE2 G KC=0.000676 10$LC=8.63E-5 12$MC=1.79E-5 3$NC=3.97E-6 6 +140CE3 G OC=6.45E-7 9$IPC=1.128E-4 16 +140CE L 1903.29 4 0+ 0.40 NS 3 +140CE G 307.08 4 0.022 5E2 0.0450 7 +140CE2 G KC=0.0362 6$LC=0.00695 10$MC=0.001495 21$NC=0.000326 5 +140CE3 G OC=4.97E-5 7 +140CE G 1903.29 4 E0 +140CE L 2083.236 144+ 3.45 NS 3 +140CE B 1677.7 1820.8 6 8.3 1 +140CES B EAV=629.7 8 +140CE G 487.022 6 46.1 5E2 0.0115617 +140CE2 G KC=0.00963 14$LC=0.001526 22$MC=0.000324 5$NC=7.11E-5 10 +140CE3 G OC=1.113E-5 16 +140CE G 2083.219 140.036 7E4 1364E-619 +140CE2 G KC=0.001162 17$LC=1.598E-4 23$MC=3.35E-5 5$NC=7.43E-6 11 +140CE3 G OC=1.198E-6 17 +140CE L 2107.830 146+ 7.3 US 15 +140CE G 24.595 4 0.00068919E2 696 10 +140CE2 G LC=545 8$MC=122.0 18$NC=25.9 4 +140CE3 G OC=3.52 5 +140CE L 2347.868 142+ +140CE B 1413.0 185.03 12 8.6 1 +140CES B EAV=515.0 8 +140CE G 444.57 4 0.003 1[E2] 0.0149021 +140CE2 G KC=0.01234 18$LC=0.00202 3$MC=0.000429 6$NC=9.42E-5 14 +140CE3 G OC=1.467E-5 21 +140CE G 751.653 7 4.39 5M1+E2 0.38 4 0.00548 9 +140CE2 G KC=0.00471 8$LC=0.000613 10$MC=1.277E-4 20$NC=2.83E-5 5 +140CE3 G OC=4.60E-6 8 +140CE G 2347.847 140.845 16E2 3.86E-4 5 +140CE2 G KC=0.000333 5$LC=4.15E-5 6$MC=8.60E-6 12$NC=1.91E-6 3 +140CE3 G OC=3.11E-7 5$IPC=0.000460 7 +140CE L 2349.789 145+ +140CE B 1411.1 180.262 22 10.7 1U +140CES B EAV=518.8 8 +140CE G 241.959 6 0.436 10M1+E2 0.60 35 0.1005 18 +140CE2 G KC=0.084 3$LC=0.0130 11$MC=0.00275 25$NC=0.00061 6 +140CE3 G OC=0.000096 7 +140CE G 266.554 5 0.492 9M1+E2 0.14 12 0.0785 12 +140CE2 G KC=0.0671 11$LC=0.00906 17$MC=0.00190 4$NC=0.000420 9 +140CE3 G OC=6.81E-5 12 +140CE L 2411.997 143+ 55 PS 15 +140CE B 1348.9 1844.8 4 7.6 +140CES B EAV=487.6 8 +140CE G 64.129 4 0.014 2M1 4.24 6 +140CE2 G KC=3.61 5$LC=0.499 7$MC=0.1046 15$NC=0.0232 4 +140CE3 G OC=0.00375 6 +140CE G 328.761 4 20.8 3M1+E2 0.049 6 0.0453 7 +140CE2 G KC=0.0388 6$LC=0.00516 8$MC=0.001078 15$NC=0.000239 4 +140CE3 G OC=3.88E-5 6 +140CE G 815.784 6 23.72 20M1+E2 0.03 1 0.00471 7 +140CE2 G KC=0.00405 6$LC=0.000521 8$MC=1.085E-4 16$NC=2.41E-5 4 +140CE3 G OC=3.92E-6 6 +140CE L 2464.055 213- 0.10 PS 2 +140CE B 1296.8 185.60 7 8.44 +140CES B EAV=465.6 8 +140CE G 867.839 165.58 7E1+M2 0.044 20 0.00113 3 +140CE2 G KC=0.000977 22$LC=0.000122 3$MC=2.53E-5 7$NC=5.61E-6 14 +140CE3 G OC=9.09E-7 23 +140CE G 2464.031 200.0097 13[E3] 5.98E-4 8 +140CE2 G KC=0.000515 8$LC=6.61E-5 10$MC=1.375E-5 20$NC=3.05E-6 5 +140CE3 G OC=4.95E-7 7$IPC=0.000331 5 +140CE L 2480.910 144+ 3.2 NS 3 +140CE B 1280.0 181.14 2 9.1 1 +140CES B EAV=458.4 8 +140CE G 68.923 5 0.077 2M1 3.44 5 +140CE2 G KC=2.93 5$LC=0.405 6$MC=0.0848 12$NC=0.0188 3 +140CE3 G OC=0.00304 5 +140CE G 131.121 4 0.47 1M1+E2 0.13 5 0.552 9 +140CE2 G KC=0.468 7$LC=0.0660 22$MC=0.0139 5$NC=0.00307 11 +140CE3 G OC=0.000494 15 +140CE G 397.674 6 0.075 3(E2) 0.0205 3 +140CE2 G KC=0.01689 24$LC=0.00288 4$MC=0.000615 9$NC=1.347E-4 19 +140CE3 G OC=2.08E-5 3 +140CE L 2515.749 163+ +140CE B 1245.2 185.80 4 8.4 +140CES B EAV=443.8 8 +140CE G 432.513 8 3.00 3M1+E2 0.54 5 0.0210 4 +140CE2 G KC=0.0179 4$LC=0.00245 4$MC=0.000514 8$NC=1.138E-4 17 +140CE3 G OC=1.83E-5 3 +140CE G 919.533 102.73 3M1+E2 2.6 4 0.00257 6 +140CE2 G KC=0.00219 6$LC=0.000295 7$MC=6.16E-5 13$NC=1.36E-5 3 +140CE3 G OC=2.19E-6 5 +140CE L 2521.414 142+ +140CE B 1239.5 1811.11 9 8.1 1 +140CES B EAV=441.4 8 +140CE G 109.417 4 0.217 6M1+E2 0.26 2 0.949 15 +140CE2 G KC=0.787 12$LC=0.128 4$MC=0.0271 8$NC=0.00597 18 +140CE3 G OC=0.000940 25 +140CE G 173.546 5 0.126 5M1 0.251 4 +140CE2 G KC=0.214 3$LC=0.0291 4$MC=0.00609 9$NC=0.001350 19 +140CE3 G OC=0.000219 3 +140CE G 438.178 6 0.017 10M1 0.0217 3 +140CE2 G KC=0.0186 3$LC=0.00244 4$MC=0.000510 8$NC=1.132E-4 16 +140CE3 G OC=1.84E-5 3 +140CE G 618.12 4 0.041 3[E2] 0.00617 9 +140CE2 G KC=0.00520 8$LC=0.000768 11$MC=1.619E-4 23$NC=3.57E-5 5 +140CE3 G OC=5.64E-6 8 +140CE G 925.198 7 7.04 7M1+E2 0.22 4 0.00344 6 +140CE2 G KC=0.00296 5$LC=0.000381 6$MC=7.92E-5 12$NC=1.76E-5 3 +140CE3 G OC=2.86E-6 5 +140CE G 2521.390 143.41 5E2 3.40E-4 5 +140CE2 G KC=0.000294 5$LC=3.65E-5 6$MC=7.56E-6 11$NC=1.676E-6 24 +140CE3 G OC=2.73E-7 4$IPC=0.000542 8 +140CE L 2547.205 231+ +140CE B 1213.7 180.636 7 10 1U +140CES B EAV=438.4 7 +140CE G 950.988 200.531 7M1+E2 0.01 7 0.00328 5 +140CE2 G KC=0.00282 4$LC=0.000361 5$MC=7.52E-5 11$NC=1.669E-5 24 +140CE3 G OC=2.72E-6 4 +140CE G 2547.180 230.102 2M1 3.70E-4 5 +140CE2 G KC=0.000320 5$LC=3.98E-5 6$MC=8.24E-6 12$NC=1.83E-6 3 +140CE3 G OC=2.99E-7 5$IPC=0.000593 9 +140CE L 2899.56 7 2+ +140CE B 861.2 180.112 6 9.5 1 +140CES B EAV=287.3 7 +140CE G 1303.34 7 0.045 6[M1+E2+E0] 0.0014 2 +140CE2 G KC=0.0012 2$LC=0.00015 2$MC=0.000032 5 +140CE G 2899.53 7 0.066 1E2 2.66E-4 4 +140CE2 G KC=0.000231 4$LC=2.84E-5 4$MC=5.88E-6 9$NC=1.306E-6 19 +140CE3 G OC=2.13E-7 3$IPC=0.000714 10 +140CE L 3000.88 9 2+ +140CE B 760.0 180.085 9 9.4 1 +140CES B EAV=248.0 7 +140CE G 1097.58 9 0.023 5[E2] 1658E-624 +140CE2 G KC=0.00142 2$LC=0.000188 3$MC=3.92E-5 6$NC=8.68E-6 13 +140CE3 G OC=1.399E-6 20 +140CE G 1404.66 9 0.062 8[M1+E2] 0.0011715 +140CE2 G KC=0.00101 15$LC=0.000129 18$MC=0.000027 4$NC=5.9E-6 8 +140CE3 G OC=9.7E-7 14$IPC=4.73E-5 8 +140CE L 3118.53 102+ +140CE B 642.5 180.027 1 9.6 1 +140CES B EAV=203.7 7 +140CE G 3118.49 100.026 1(E2) 2.34E-4 3 +140CE2 G KC=0.000204 3$LC=2.50E-5 4$MC=5.18E-6 8$NC=1.149E-6 16 +140CE3 G OC=1.87E-7 3$IPC=0.000808 12 +140CE L 3319.56 242+ +140CE B 441.3 180.0039 3 9.9 1 +140CES B EAV=132.0 6 +140CE G 3319.52 240.0039 3E2 2.11E-4 3 +140CE2 G KC=0.000183 3$LC=2.25E-5 4$MC=4.64E-6 7$NC=1.031E-6 15 +140CE3 G OC=1.680E-7 24$IPC=0.000892 13 +140CE L 3394.82 9 4- +140CE B 366.1 180.020 4 9 +140CES B EAV=106.7 6 +140CE G 1045.02 9 0.020 4[E1] 7.81E-411 +140CE2 G KC=0.000675 10$LC=8.37E-5 12$MC=1.733E-5 25$NC=3.84E-6 6 +140CE3 G OC=6.23E-7 9 +140CE L 3473.55 183- +140CE B 287.4 180.052 7 8.2 +140CES B EAV=81.4 6 +140CE G 992.64 180.010 3[E1] 8.60E-412 +140CE2 G KC=0.000743 11$LC=9.24E-5 13$MC=1.91E-5 3$NC=4.23E-6 6 +140CE3 G OC=6.87E-7 10 +140CE G 1877.33 180.041 6[E1] 2.84E-4 4 +140CE2 G KC=0.000245 4$LC=3.00E-5 5$MC=6.21E-6 9$NC=1.377E-6 20 +140CE3 G OC=2.24E-7 4$IPC=0.000499 7 +140CE L 3520.8 2 4+ +140CE B 240.1 180.011 3 8.6 1 +140CES B EAV=66.7 6 +140CE G 1924.5 2 0.011 3[E2] 5.54E-4 8 +140CE2 G KC=0.000478 7$LC=6.01E-5 9$MC=1.247E-5 18$NC=2.76E-6 4 +140CE3 G OC=4.49E-7 7$IPC=0.000257 4 + diff --git a/HEN_HOUSE/spectra/lnhb/Lu-177.txt b/HEN_HOUSE/spectra/lnhb/Lu-177.txt index 23db7959a..bbc73325a 100644 --- a/HEN_HOUSE/spectra/lnhb/Lu-177.txt +++ b/HEN_HOUSE/spectra/lnhb/Lu-177.txt @@ -1,53 +1,53 @@ -177HF 177LU B- DECAY (6.647 D) -177HF T Auger electrons and X ray energies and emission intensities: -177HF T {U Energy (keV)} {U Intensity} {U Line} -177HF T -177HF T 54.612 1.59 3 XKA2 -177HF T 55.7909 2.78 6 XKA1 -177HF T -177HF T 62.985 |] XKB3 -177HF T 63.234 |] 0.917 23 XKB1 -177HF T 63.662 |] XKB5II -177HF T -177HF T 64.942 |] XKB2 -177HF T 65.132 |] 0.245 8 XKB4 -177HF T 65.316 |] XKO23 -177HF T -177HF T 6.96-10.89 3.18 6 XL (total) -177HF T 6.96 0.0613 16 XLL -177HF T 7.844-7.899 1.35 3 XLA -177HF T 8.139 0.031 9 XLC -177HF T 8.905-9.342 1.49 5 XLB -177HF T 10.516-10.89 0.254 7 XLG -177HF T -177HF T 42.601-46.007 |] KLL AUGER -177HF T 51.391-55.784 |] 0.28 9 KLX AUGER -177HF T 60.15-65.34 |] KXY AUGER -177HF T 4.3-11.2 8.75 20 L AUGER -177LU P 0.0 7/2+ 6.647 D 4 498.3 8 -177HF N 1.0 1.0 1 1.0 -177HF L 0 7/2- STABLE -177HF B 498.3 8 79.3 5 6.7 -177HFS B EAV=149.4 3 -177HF L 112.9499 9/2- 0.506 NS -177HF B 385.4 8 9.1 5 7.3 1 -177HFS B EAV=111.7 3 -177HF G 112.9498 4 6.20 7M1+E2 2.272 5 -177HF2 G KC=0.817 12$LC=1.104 6$MC=0.2755 14 -177HF L 249.6744 11/2- 105 PS -177HF B 248.6 8 0.012 8 9.2 1U -177HFS B EAV=78.6 3 -177HF G 136.7245 5 0.0470 7M1+E2 1.158 18 -177HF2 G KC=0.559 21$LC=0.456 7$MC=0.1129 21 -177HF G 249.6742 6 0.2012 21E2 0.141 -177HF2 G KC=0.091 $LC=0.038 $MC=0.009 -177HF L 321.3162 9/2+ 0.663 NS -177HF B 177.0 8 11.64 10 6.1 -177HFS B EAV=47.66 23 -177HF G 71.6418 6 0.1726 23E1+M2 0.894 22 -177HF2 G KC=0.715 14$LC=0.138 6$MC=0.0317 14 -177HF G 208.3662 4 10.38 7E1+M2 0.068 5 -177HF2 G KC=0.055 4$LC=0.0094 10$MC=0.00216 24 -177HF G 321.3159 6 0.216 8E1+M2 0.08 6 -177HF2 G KC=0.06 5$LC=0.012 10$MC=0.0028 22 - +177HF 177LU B- DECAY (6.647 D) +177HF T Auger electrons and X ray energies and emission intensities: +177HF T {U Energy (keV)} {U Intensity} {U Line} +177HF T +177HF T 54.612 1.59 3 XKA2 +177HF T 55.7909 2.78 6 XKA1 +177HF T +177HF T 62.985 |] XKB3 +177HF T 63.234 |] 0.917 23 XKB1 +177HF T 63.662 |] XKB5II +177HF T +177HF T 64.942 |] XKB2 +177HF T 65.132 |] 0.245 8 XKB4 +177HF T 65.316 |] XKO23 +177HF T +177HF T 6.96-10.89 3.18 6 XL (total) +177HF T 6.96 0.0613 16 XLL +177HF T 7.844-7.899 1.35 3 XLA +177HF T 8.139 0.031 9 XLC +177HF T 8.905-9.342 1.49 5 XLB +177HF T 10.516-10.89 0.254 7 XLG +177HF T +177HF T 42.601-46.007 |] KLL AUGER +177HF T 51.391-55.784 |] 0.28 9 KLX AUGER +177HF T 60.15-65.34 |] KXY AUGER +177HF T 4.3-11.2 8.75 20 L AUGER +177LU P 0.0 7/2+ 6.647 D 4 498.3 8 +177HF N 1.0 1.0 1 1.0 +177HF L 0 7/2- STABLE +177HF B 498.3 8 79.3 5 6.7 +177HFS B EAV=149.4 3 +177HF L 112.9499 9/2- 0.506 NS +177HF B 385.4 8 9.1 5 7.3 1 +177HFS B EAV=111.7 3 +177HF G 112.9498 4 6.20 7M1+E2 2.272 5 +177HF2 G KC=0.817 12$LC=1.104 6$MC=0.2755 14 +177HF L 249.6744 11/2- 105 PS +177HF B 248.6 8 0.012 8 9.2 1U +177HFS B EAV=78.6 3 +177HF G 136.7245 5 0.0470 7M1+E2 1.158 18 +177HF2 G KC=0.559 21$LC=0.456 7$MC=0.1129 21 +177HF G 249.6742 6 0.2012 21E2 0.141 +177HF2 G KC=0.091 $LC=0.038 $MC=0.009 +177HF L 321.3162 9/2+ 0.663 NS +177HF B 177.0 8 11.64 10 6.1 +177HFS B EAV=47.66 23 +177HF G 71.6418 6 0.1726 23E1+M2 0.894 22 +177HF2 G KC=0.715 14$LC=0.138 6$MC=0.0317 14 +177HF G 208.3662 4 10.38 7E1+M2 0.068 5 +177HF2 G KC=0.055 4$LC=0.0094 10$MC=0.00216 24 +177HF G 321.3159 6 0.216 8E1+M2 0.08 6 +177HF2 G KC=0.06 5$LC=0.012 10$MC=0.0028 22 + diff --git a/HEN_HOUSE/spectra/lnhb/Mn-54.txt b/HEN_HOUSE/spectra/lnhb/Mn-54.txt index ae1a6a38e..c94416326 100644 --- a/HEN_HOUSE/spectra/lnhb/Mn-54.txt +++ b/HEN_HOUSE/spectra/lnhb/Mn-54.txt @@ -1,46 +1,44 @@ - 54CR 54MN EC DECAY (312.19 D) - 54CR H TYP=Update$AUT=V.Chechev$CUT=31-MAR-2014$ - 54CR2 H TYP=ERR$AUT=M.-M.Bé$CUT= -- $ - 54CR3 H TYP=FUL$AUT=R.G.Helmer and E.Schönfeld$CUT=28-FEB-2001$ - 54CR C Evaluation history: Type=Update;Author=V.Chechev;Cutoff date=31-MAR-2014 - 54CR2C Type=ERR;Author=M.-M.Bé;Cutoff date= -- - 54CR3C Type=FUL;Author=R.G.Helmer and E.Schönfeld;Cutoff date=28-FEB-2001 - 54CR C References: 1955Ba10, 1956Ka33, 1956Sc87, 1961Wy01, 1963Ta19, 1964Be26, - 54CR2C 1964Ma14, 1965Sa09, 1965An07, 1965Le21, 1967PeZZ, 1967Ba50, 1968Zi01, - 54CR3C 1968Ha47, 1968La10, 1968Be01, 1969BoZX, 1973MeYE, 1973Vi13, 1973Mu**, - 54CR4C 1973Ko**, 1974Cr05, 1978Ma06, 1979MeZY, 1980Co22, 1980RuZV, 1982RyZX, - 54CR5C 1982HoZJ, 1982RuZV, 1989Su08, 1992Un01, 1993Da20, 1996Du15, 1997Ma75, - 54CR6C 1998Si17, 2000Hu20, 2002Ba85, 2002Un02, 2004BeZR, 2006Hu08, 2006Da20, - 54CR7C 2008Ki07, 2010Va13, 2012Wa38, 2012Fi12, 2014Un01 - 54CR T Auger electrons and X ray energies and emission intensities: - 54CR T {U Energy (keV)} {U Intensity} {U Line} - 54CR T - 54CR T 5.40557 7.65 14 XKA2 - 54CR T 5.41479 15.02 27 XKA1 - 54CR T - 54CR T 5.94677 |] 3.05 7 XKB1 - 54CR T 5.987 |] XKB5II - 54CR T - 54CR T - 54CR T 0.5003-0.69748 0.65 13 XL (total) - 54CR T 0.5003 XLL - 54CR T 0.5729-0.57695 XLA - 54CR T 0.5102 XLC - 54CR T 0.57515-0.69748 XLB - 54CR T 0.58496-0.58496 XLG - 54CR T - 54CR T 4.554-4.794 |] KLL AUGER - 54CR T 5.206-5.412 |] 63.3 5 KLX AUGER - 54CR T 5.841-5.985 |] KXY AUGER - 54CR T 0.4-0.7 143.0 6 L AUGER - 54MN P 0.0 3+ 312.19 D 3 1377.2 10 - 54CR N 1.0 1.0 1 1.0 - 54CR L 0 0+ STABLE - 54CR E 5.7E-7 0.0003 313.9 2U - 54CR2 E EAV=182 $CK=0.8908 16$CL=0.0938 13$CM=0.0148 6$CN=0.0005 2$CO=0 0 - 54CR L 834.855 3 2+ 0.0079 NS 3 - 54CR E 99.9997 36.17 - 54CR2 E CK=0.8896 17$CL=0.0948 14$CM=0.0150 6$CN=0.0005 2$CO=0 0 - 54CR G 834.848 3 99.9752 5E2 2.45E-4 4 - 54CR2 G KC=2.22E-4 4$LC=2.06E-5 3$MC=2.71E-6 4 - + 54CR 54MN EC DECAY (312.19 D) + 54CR H TYP=UPD$AUT=V.P.CHECHEV$CUT=31-MAR-2014$ + 54CR2 H TYP=ERR$AUT=M.-M.BE$DAT=29-JAN-2004$COM=See DDEP website$ + 54CR3 H TYP=FUL$AUT=R.G.HELMER, E.SCHONFELD$CUT=28-FEB-2001$ + 54CR C References:1955Ba10, 1956Ka33, 1956Sc87, 1961Wy01, 1963Ta19, 1964Be26, + 54CR2C 1964Ma14, 1965Sa09, 1965An07, 1965Le21, 1967PeZZ, 1967Ba50, 1968Zi01, + 54CR3C 1968Ha47, 1968La10, 1968Be01, 1969BoZX, 1973MeYE, 1973Vi13, 1973Mu**, + 54CR4C 1973Ko**, 1974Cr05, 1978Ma06, 1979MeZY, 1980Co22, 1980RuZV, 1982RyZX, + 54CR5C 1982HoZJ, 1982RuZV, 1989Su08, 1992Un01, 1993Da20, 1996Du15, 1997Ma75, + 54CR6C 1998Si17, 2000Hu20, 2002Ba85, 2002Un02, 2004BeZR, 2006Hu08, 2006Da20, + 54CR7C 2008Ki07, 2010Va13, 2012Wa38, 2012Fi12, 2014Un01 + 54CR T Auger electrons and X ray energies and emission intensities: + 54CR T {U Energy (keV)} {U Intensity} {U Line} + 54CR T + 54CR T 5.40557 7.65 14 XKA2 + 54CR T 5.41479 15.02 27 XKA1 + 54CR T + 54CR T 5.94677 |] 3.05 7 XKB1 + 54CR T 5.987 |] XKB5II + 54CR T + 54CR T + 54CR T 0.5003-0.69748 0.65 13 XL (total) + 54CR T 0.5003 XLL + 54CR T 0.5729-0.57695 XLA + 54CR T 0.5102 XLC + 54CR T 0.57515-0.69748 XLB + 54CR T 0.58496-0.58496 XLG + 54CR T + 54CR T 4.554-4.794 |] KLL AUGER + 54CR T 5.206-5.412 |] 63.3 5 KLX AUGER + 54CR T 5.841-5.985 |] KXY AUGER + 54CR T 0.4-0.7 143.0 6 L AUGER + 54MN P 0.0 3+ 312.19 D 3 1377.2 10 + 54CR N 1.0 1.0 1 1.0 + 54CR L 0 0+ STABLE + 54CR E 5.7E-7 0.0003 313.9 2U + 54CR2 E EAV=182 $CK=0.8891 16$CL=0.0936 13$CM=0.0148 6 + 54CR3 E CN=0.0005 2 + 54CR L 834.855 3 2+ 0.0079 NS 3 + 54CR E 99.9997 36.17 + 54CR2 E CK=0.8896 17$CL=0.0948 14$CM=0.0150 6$CN=0.0005 2 + 54CR G 834.848 3 99.9752 5E2 2.45E-4 4 + 54CR2 G KC=0.000222 4$LC=2.06E-5 3$MC=2.71E-6 4$NC=1.011E-7 15 + diff --git a/HEN_HOUSE/spectra/lnhb/Mn-56.txt b/HEN_HOUSE/spectra/lnhb/Mn-56.txt index bf2c6ba82..21bae7a05 100644 --- a/HEN_HOUSE/spectra/lnhb/Mn-56.txt +++ b/HEN_HOUSE/spectra/lnhb/Mn-56.txt @@ -1,55 +1,55 @@ - 56FE 56MN B- DECAY (2.57878 H) - 56FE T Auger electrons and X ray energies and emission intensities: - 56FE T {U Energy (keV)} {U Intensity} {U Line} - 56FE T - 56FE T 6.39091 0.00295 4 XKA2 - 56FE T 6.40391 0.00578 7 XKA1 - 56FE T - 56FE T 7.05804 |] 0.00119 2 XKB1 - 56FE T 7.1083 |] XKB5II - 56FE T - 56FE T - 56FE T - 56FE T 5.37-5.645 |] KLL AUGER - 56FE T 6.158-6.4 |] 0.0180 1 KLX AUGER - 56FE T 6.926-7.105 |] KXY AUGER - 56FE T 0.51-0.594 0.0428 3 L AUGER - 56MN P 0.0 3+ 2.57878 H 46 3695.5 3 - 56FE N 1.0 1.0 1 1.0 - 56FE L 0 0+ STABLE - 56FE L 846.776 5 2+ 6.07 PS - 56FE B 2848.7 3 56.6 7 7.101 - 56FES B EAV=1216.8 2 - 56FE G 846.7638 1998.85 3E2 3.00E-4 9 - 56FE2 G KC=2.70E-4 8$LC=2.50E-5 8$MC=3.7E-6 1 - 56FE L 2085.076 7 4+ - 56FE B 1610.4 3 0.057 6 9.06 - 56FES B EAV=636.3 2 - 56FE G 1238.2736 220.097 2E2 1.20E-4 4 - 56FE2 G KC=1.10E-4 3$LC=1.00E-5 3$MC=2.00E-6 6 - 56FE L 2657.562 102+ - 56FE B 1037.9 3 27.5 4 5.621 - 56FES B EAV=381.9 2 - 56FE G 1810.7260 4026.9 4M1+E2 -0.18 1 5.10E-515 - 56FE2 G KC=4.60E-5 14$LC=4.30E-6 13$MC=6.3E-7 2 - 56FE G 2657.56 1 0.645 7E2 - 56FE L 2959.923 102+ - 56FE B 735.6 3 14.5 3 5.34 - 56FES B EAV=255.2 2 - 56FE G 2113.092 6 14.2 3M1+E2 - 56FE G 2959.92 1 0.307 5E2 - 56FE L 3122.927 7 4+ - 56FE B 572.6 3 0.040 4 7.5 - 56FES B EAV=190.4 2 - 56FE G 1037.8333 240.040 4M1+E2 0.02 1 1500E-745 - 56FE2 G KC=1.30E-4 4$LC=1.20E-5 4$MC=6.0E-6 2 - 56FE L 3369.84 4 2+ - 56FE B 325.7 3 1.20 3 5.17 - 56FES B EAV=99.1 1 - 56FE G 2523.06 5 1.02 2M1+E2 - 56FE G 3369.84 4 0.17 1E2 - 56FE L 3445.306 203+ - 56FE B 250.2 3 0.020 2 6.57 - 56FES B EAV=73.5 1 - 56FE G 2598.438 4 0.020 2M1+E2 - + 56FE 56MN B- DECAY (2.57878 H) + 56FE T Auger electrons and X ray energies and emission intensities: + 56FE T {U Energy (keV)} {U Intensity} {U Line} + 56FE T + 56FE T 6.39091 0.00295 4 XKA2 + 56FE T 6.40391 0.00578 7 XKA1 + 56FE T + 56FE T 7.05804 |] 0.00119 2 XKB1 + 56FE T 7.1083 |] XKB5II + 56FE T + 56FE T + 56FE T + 56FE T 5.37-5.645 |] KLL AUGER + 56FE T 6.158-6.4 |] 0.0180 1 KLX AUGER + 56FE T 6.926-7.105 |] KXY AUGER + 56FE T 0.51-0.594 0.0428 3 L AUGER + 56MN P 0.0 3+ 2.57878 H 46 3695.5 3 + 56FE N 1.0 1.0 1 1.0 + 56FE L 0 0+ STABLE + 56FE L 846.776 5 2+ 6.07 PS + 56FE B 2848.7 3 56.6 7 7.101 + 56FES B EAV=1216.8 2 + 56FE G 846.7638 1998.85 3E2 3.00E-4 9 + 56FE2 G KC=0.000270 8$LC=2.50E-5 8$MC=3.7E-6 1 + 56FE L 2085.076 7 4+ + 56FE B 1610.4 3 0.057 6 9.06 + 56FES B EAV=636.3 2 + 56FE G 1238.2736 220.097 2E2 1.20E-4 4 + 56FE2 G KC=0.000110 3$LC=1.00E-5 3$MC=2.00E-6 6 + 56FE L 2657.562 102+ + 56FE B 1037.9 3 27.5 4 5.621 + 56FES B EAV=381.9 2 + 56FE G 1810.7260 4026.9 4M1+E2 -0.18 1 5.10E-515 + 56FE2 G KC=4.60E-5 14$LC=4.30E-6 13$MC=6.3E-7 2 + 56FE G 2657.56 1 0.645 7E2 + 56FE L 2959.923 102+ + 56FE B 735.6 3 14.5 3 5.34 + 56FES B EAV=255.2 2 + 56FE G 2113.092 6 14.2 3M1+E2 + 56FE G 2959.92 1 0.307 5E2 + 56FE L 3122.927 7 4+ + 56FE B 572.6 3 0.040 4 7.5 + 56FES B EAV=190.4 2 + 56FE G 1037.8333 240.040 4M1+E2 0.02 1 1500E-745 + 56FE2 G KC=0.000130 4$LC=1.20E-5 4$MC=6.0E-6 2 + 56FE L 3369.84 4 2+ + 56FE B 325.7 3 1.20 3 5.17 + 56FES B EAV=99.1 1 + 56FE G 2523.06 5 1.02 2M1+E2 + 56FE G 3369.84 4 0.17 1E2 + 56FE L 3445.306 203+ + 56FE B 250.2 3 0.020 2 6.57 + 56FES B EAV=73.5 1 + 56FE G 2598.438 4 0.020 2M1+E2 + diff --git a/HEN_HOUSE/spectra/lnhb/Mo-99.txt b/HEN_HOUSE/spectra/lnhb/Mo-99.txt index 101248770..3c370b620 100644 --- a/HEN_HOUSE/spectra/lnhb/Mo-99.txt +++ b/HEN_HOUSE/spectra/lnhb/Mo-99.txt @@ -1,118 +1,130 @@ - 99TC 99MO B- DECAY (2.7479 D) - 99TC H TYP=update$AUT=mmbe$CUT= -- $ - 99TC2 H TYP=update$AUT=mmbe$CUT= -- $ - 99TC C Evaluation history: Type=update;Author=mmbe;Cutoff date= -- - 99TC2C Type=update;Author=mmbe;Cutoff date= -- - 99TC C References: 1977La19 - 99TC T Auger electrons and X ray energies and emission intensities: - 99TC T {U Energy (keV)} {U Intensity} {U Line} - 99TC T - 99TC T 18.251 3.19 9 XKA2 - 99TC T 18.3672 6.06 16 XKA1 - 99TC T - 99TC T 20.599 |] XKB3 - 99TC T 20.619 |] 1.61 5 XKB1 - 99TC T 20.789 |] XKB5II - 99TC T - 99TC T 21.005 |] XKB2 - 99TC T 21.042 |] 0.254 11 XKB4 - 99TC T - 99TC T 2.424-2.537 0.697 17 XL (total) - 99TC T 2.424- 0.430 13 XLA - 99TC T 2.537- 0.231 7 XLB - 99TC T - 99TC T 14.858-15.582 |] KLL AUGER - 99TC T 17.418-18.365 |] 3.1 1 KLX AUGER - 99TC T 19.956-21.04 |] KXY AUGER - 99TC T 1.6-3.04 15.87 26 L AUGER - 99MO P 0.0 1/2+ 2.7479 D 6 1357.2 10 - 99TC N 1.0 1.0 1 1.0 - 99TC L 0 9/2+ 211.5E3 Y 11 - 99TC L 140.5106 7/2+ 0.221 NS 20 - 99TC G 140.511 1 89.6 17M1+()E2 0.186 8 0.119 3 - 99TC2 G KC=0.104 3$LC=0.0129 4$MC=0.00236 7 - 99TC L 142.6832 1/2- 6.0067 H 10 - 99TC B 1214.5 1082.1 15 7.1 - 99TCS B EAV=442.7 3 - 99TC G 2.1726 4 7E-9 E3 135E8 4 - 99TC2 G MC=119E8 3 - 99TC G 142.675 250.0211 17M4 40.9 8 - 99TC2 G KC=29.3 6$LC=9.35 20$MC=1.86 6 - 99TC L 181.0939 5/2+ 3.61 NS 7 - 99TC G 40.58323 171.022 27M1+()E2 -0.119 8 4.18 13 - 99TC2 G KC=3.50 8$LC=0.560 13$MC=0.104 3 - 99TC G 181.068 8 6.01 11E2 0.149 3 - 99TC2 G KC=0.125 3$LC=0.0191 4$MC=0.00353 7 - 99TC L 509.106 (3/2)- - 99TC B 848.1 101.18 3 8.38 1 - 99TCS B EAV=289.7 3 - 99TC G 366.421 151.194 23M1 0.0091518 - 99TC2 G KC=0.00802 16$LC=0.00093 2$MC=1.70E-4 4 - 99TC L 534.41 (3/2)+ - 99TC B 822.8 100.0010 2 - 99TCS B EAV=279 2 - 99TC G 391.7 4 0.0025 6 - 99TC L 671.489 (3/2)- - 99TC B 685.7 100.052 5 9.46 1 - 99TCS B EAV=225.4 4 - 99TC G 162.370 150.0114 6 - 99TC G 528.788 150.0541 19M1 0.00378 8 - 99TC2 G KC=0.00331 7$LC=3.79E-4 8$MC=6930E-8 14 - 99TC L 761.71 5/2+ - 99TC G 580.51 5 0.0036 4 - 99TC G 761.77 8 0.0023 13 - 99TC L 762.243 (3/2)+ - 99TC G 581.30 120.00010 5 - 99TC G 621.773 240.0262 10M1(+E2) 0.00258 8 - 99TC2 G KC=0.00227 5$LC=2.59E-4 8$MC=4.73E-5 14 - 99TC L 920.591 1/2+ - 99TC B 436.6 1016.45 30 6.21 - 99TCS B EAV=133.0 3 - 99TC G 158.782 150.0145 9 - 99TC G 249.03 3 0.0035 4 - 99TC G 411.491 150.0161 12E1 3.5 0.00257 5 - 99TC2 G KC=0.00226 5$LC=2.56E-4 5$MC=4.67E-5 9 - 99TC G 739.500 1712.12 15E2+M1 0.00173 4 - 99TC2 G KC=0.00151 3$LC=1.78E-4 5$MC=3.2E-5 1 - 99TC G 777.921 204.28 8E1 5.89E-412 - 99TC2 G KC=5.18E-4 10$LC=5.80E-5 12$MC=1057E-8 2 - 99TC L 1004.066 3/2- - 99TC B 353.1 100.134 5 7.97 1 - 99TCS B EAV=104.3 3 - 99TC G 242.29 8 0.0014 3(E1) 0.0106 2 - 99TC2 G KC=0.0093 2$LC=0.00106 2$MC=1.93E-4 6 - 99TC G 822.972 150.1321 29E1 5.24E-411 - 99TC2 G KC=4.61E-4 9$LC=5.2E-5 1$MC=9.4E-6 2 - 99TC G 861.2 9 0.0007 2 - 99TC L 1072.2 (7/2)+ - 99TC B 285 1 0.0027 7 2U - 99TCS B EAV=82 1 - 99TC G 537.79 150.0015 5 - 99TC G 1072.2 4 0.0012 5 - 99TC L 1129.116 (1/2,3/2)- - 99TC B 228.1 100.011 1 8.5 - 99TCS B EAV=69.3 3 - 99TC G 457.60 3 0.0074 6M1+()E2 1.6 0.0063 7 - 99TC2 G KC=0.0054 4$LC=0.00066 5$MC=0.00012 1 - 99TC G 620.03 5 0.0024 6 - 99TC G 986.44 4 0.0014 1 - 99TC L 1141.871 3/2+ - 99TC B 215.3 100.111 3 7.39 - 99TCS B EAV=59.8 3 - 99TC G 380.13 8 0.0091 5M1+()E2 1.3 6 0.0105 8 - 99TC2 G KC=0.0091 7$LC=0.00113 8$MC=0.00021 2 - 99TC G 469.63 7 0.0027 5 - 99TC G 960.754 200.095 3(M1) 0.0010 1 - 99TC G 1001.343 180.0043 4(E2) 0.0008 1 - 99TC L 1171.98 3/2+ - 99TC B 185.2 100.0016 4 8.91 - 99TCS B EAV=51.0 4 - 99TC G 410.27 100.0016 4M1+()E2 0.5 0.0074 3 - 99TC2 G KC=0.0065 2$LC=$MC=0.00014 1 - 99TC L 1198.88 (3/2)+ - 99TC B 158.3 100.0021 3 8.65 - 99TCS B EAV=43.3 4 - 99TC G 689.6 9 0.00042 18 - 99TC G 1017.0 5 0.0007 2 - 99TC G 1056.20 5 0.00103 9 - + 99TC 99MO B- DECAY (2.7479 D) + 99TC H TYP=UPD$AUT=M.-M.BE$CUT=27-SEP-2006$ + 99TC2 H TYP=UPD$AUT=M.-M.BE$CUT=20-SEP-2006$ + 99TC C References:1977La19 + 99TC T Auger electrons and X ray energies and emission intensities: + 99TC T {U Energy (keV)} {U Intensity} {U Line} + 99TC T + 99TC T 18.251 3.19 9 XKA2 + 99TC T 18.3672 6.06 16 XKA1 + 99TC T + 99TC T 20.599 |] XKB3 + 99TC T 20.619 |] 1.61 5 XKB1 + 99TC T 20.789 |] XKB5II + 99TC T + 99TC T 21.005 |] XKB2 + 99TC T 21.042 |] 0.254 11 XKB4 + 99TC T + 99TC T 2.424-2.537 0.697 17 XL (total) + 99TC T 2.424- 0.430 13 XLA + 99TC T 2.537- 0.231 7 XLB + 99TC T + 99TC T 14.858-15.582 |] KLL AUGER + 99TC T 17.418-18.365 |] 3.1 1 KLX AUGER + 99TC T 19.956-21.04 |] KXY AUGER + 99TC T 1.6-3.04 15.87 26 L AUGER + 99MO P 0.0 1/2+ 2.7479 D 6 1357.2 10 + 99TC N 1.0 1.0 1 1.0 + 99TC L 0 9/2+ 211.5E3 Y 11 + 99TC L 140.5106 7/2+ 0.221 NS 20 + 99TC G 140.511 1 89.6 17M1+E2 0.186 8 0.119 3 + 99TC2 G KC=0.104 3$LC=0.0129 4$MC=0.00236 7$NC=0.000414 12 + 99TC3 G OC=3.36E-5 10 + 99TC L 142.6832 1/2- 6.0067 H 10 + 99TC B 1214.5 1082.1 15 7.1 + 99TCS B EAV=442.7 3 + 99TC G 2.1726 4 7E-9 E3 135E8 4 + 99TC2 G MC=119E8 3 + 99TC G 142.675 250.0211 17M4 40.9 8 + 99TC2 G KC=29.3 6$LC=9.35 20$MC=1.86 6$NC=0.314 9 + 99TC3 G OC=0.01600 48 + 99TC L 181.0939 5/2+ 3.61 NS 7 + 99TC G 40.58323 171.022 27M1+E2 -0.119 8 4.18 13 + 99TC2 G KC=3.50 8$LC=0.560 13$MC=0.104 3$NC=0.0177 5 + 99TC3 G OC=0.001134 34 + 99TC G 181.068 8 6.01 11E2 0.149 3 + 99TC2 G KC=0.125 3$LC=0.0191 4$MC=0.00353 7$NC=0.000599 18 + 99TC3 G OC=3.59E-5 11 + 99TC L 509.106 (3/2)- + 99TC B 848.1 101.18 3 8.38 1 + 99TCS B EAV=289.7 3 + 99TC G 366.421 151.194 23M1 0.0091518 + 99TC2 G KC=0.00802 16$LC=0.00093 2$MC=0.000170 4$NC=3.01E-5 9 + 99TC3 G OC=2.62E-6 8 + 99TC L 534.41 (3/2)+ + 99TC B 822.8 100.0010 2 + 99TCS B EAV=279 2 + 99TC G 391.7 4 0.0025 6 + 99TC L 671.489 (3/2)- + 99TC B 685.7 100.052 5 9.46 1 + 99TCS B EAV=225.4 4 + 99TC G 162.370 150.0114 6 + 99TC G 528.788 150.0541 19M1 0.00378 8 + 99TC2 G KC=0.00331 7$LC=0.000379 8$MC=6.930E-5 14$NC=1.229E-5 37 + 99TC3 G OC=1.075E-6 32 + 99TC L 761.71 5/2+ + 99TC G 580.51 5 0.0036 4 + 99TC G 761.77 8 0.0023 13 + 99TC L 762.243 (3/2)+ + 99TC G 581.30 120.00010 5 + 99TC G 621.773 240.0262 10M1(+E2) 0.00258 8 + 99TC2 G KC=0.00227 5$LC=0.000259 8$MC=4.73E-5 14$NC=8.38E-6 25 + 99TC3 G OC=7.36E-7 22 + 99TC L 920.591 1/2+ + 99TC B 436.6 1016.45 30 6.21 + 99TCS B EAV=133.0 3 + 99TC G 158.782 150.0145 9 + 99TC G 249.03 3 0.0035 4 + 99TC G 411.491 150.0161 12E1 0.00257 5 + 99TC2 G KC=0.00226 5$LC=0.000256 5$MC=4.67E-5 9$NC=8.23E-6 25 + 99TC3 G OC=6.98E-7 21 + 99TC G 739.500 1712.12 15E2+M1 0.00173 4 + 99TC2 G KC=0.00151 3$LC=0.000178 5$MC=0.000032 1$NC=5.71E-6 17 + 99TC3 G OC=4.79E-7 14 + 99TC G 777.921 204.28 8E1 5.89E-412 + 99TC2 G KC=0.000518 10$LC=5.80E-5 12$MC=1.057E-5 2$NC=1.87E-6 6 + 99TC3 G OC=1.624E-7 49 + 99TC L 1004.066 3/2- + 99TC B 353.1 100.134 5 7.97 1 + 99TCS B EAV=104.3 3 + 99TC G 242.29 8 0.0014 3(E1) 0.0106 2 + 99TC2 G KC=0.0093 2$LC=0.00106 2$MC=0.000193 6 + 99TC G 822.972 150.1321 29E1 5.24E-411 + 99TC2 G KC=0.000461 9$LC=0.000052 1$MC=9.4E-6 2$NC=1.66E-6 5 + 99TC3 G OC=1.447E-7 43 + 99TC G 861.2 9 0.0007 2 + 99TC L 1072.2 (7/2)+ + 99TC B 285 1 0.0027 7 2U + 99TCS B EAV=82 1 + 99TC G 537.79 150.0015 5 + 99TC G 1072.2 4 0.0012 5 + 99TC L 1129.116 (1/2,3/2)- + 99TC B 228.1 100.011 1 8.5 + 99TCS B EAV=69.3 3 + 99TC G 457.60 3 0.0074 6M1+E2 1.6 0.0063 7 + 99TC2 G KC=0.0054 4$LC=0.00066 5$MC=0.00012 1$NC=2.12E-5 6 + 99TC3 G OC=1.70E-6 5 + 99TC G 620.03 5 0.0024 6 + 99TC G 986.44 4 0.0014 1 + 99TC L 1141.871 3/2+ + 99TC B 215.3 100.111 3 7.39 + 99TCS B EAV=59.8 3 + 99TC G 380.13 8 0.0091 5M1+E2 1.3 6 0.0105 8 + 99TC2 G KC=0.0091 7$LC=0.00113 8$MC=0.00021 2$NC=3.62E-5 11 + 99TC3 G OC=2.85E-6 9 + 99TC G 469.63 7 0.0027 5 + 99TC G 960.754 200.095 3(M1) 0.0010 1 + 99TC G 1001.343 180.0043 4(E2) 0.0008 1 + 99TC L 1171.98 3/2+ + 99TC B 185.2 100.0016 4 8.91 + 99TCS B EAV=51.0 4 + 99TC G 410.27 100.0016 4M1+E2 0.5 0.0074 3 + 99TC2 G KC=0.0065 2$LC=0.00076 3$MC=0.00014 1$NC=2.46E-5 7 + 99TC3 G OC=2.08E-6 6 + 99TC L 1198.88 (3/2)+ + 99TC B 158.3 100.0021 3 8.65 + 99TCS B EAV=43.3 4 + 99TC G 689.6 9 0.00042 18 + 99TC G 1017.0 5 0.0007 2 + 99TC G 1056.20 5 0.00103 9 + diff --git a/HEN_HOUSE/spectra/lnhb/N-13.txt b/HEN_HOUSE/spectra/lnhb/N-13.txt index 4852f932b..742e7a03c 100644 --- a/HEN_HOUSE/spectra/lnhb/N-13.txt +++ b/HEN_HOUSE/spectra/lnhb/N-13.txt @@ -1,7 +1,7 @@ - 13C 13N EC DECAY (9.9670 M) - 13N P 0.0 1/2- 9.9670 M 37 2220.45 27 - 13C N 1.0 1.0 1 1.0 - 13C L 0 1/2- STABLE - 13C E 99.818 130.182 12 - 13C 2 E EAV=493.0 2$CK=0.923 7$CL=0.078 7$CO=0 0 - + 13C 13N EC DECAY (9.9670 M) + 13N P 0.0 1/2- 9.9670 M 37 2220.45 27 + 13C N 1.0 1.0 1 1.0 + 13C L 0 1/2- STABLE + 13C E 99.818 130.182 12 + 13C 2 E EAV=493.0 2$CK=0.001680 13$CL=0.000142 13 + diff --git a/HEN_HOUSE/spectra/lnhb/Na-22.txt b/HEN_HOUSE/spectra/lnhb/Na-22.txt index d200a6dcd..571edffce 100644 --- a/HEN_HOUSE/spectra/lnhb/Na-22.txt +++ b/HEN_HOUSE/spectra/lnhb/Na-22.txt @@ -1,33 +1,32 @@ - 22NE 22NA EC DECAY (2.6029 Y) - 22NE H TYP=Update$AUT=M. Galan$CUT=30-MAY-2009$ - 22NE2 H TYP=Full$AUT=Helmer. Schönfeld$CUT=18-JAN-1999$ - 22NE C Evaluation history: Type=Update;Author=M. Galan;Cutoff date=30-MAY-2009 - 22NE2C Type=Full;Author=Helmer. Schönfeld;Cutoff date=18-JAN-1999 - 22NE C References: 1953WR13, 1954KR01, 1954SH01, 1954ZW01, 1955Al01, 1957ME47, - 22NE2C 1958KO75, 1959RA09, 1961WY01, 1964WI04, 1965AN07, 1967lE07, 1968VA13, - 22NE3C 1969MC06, 1970WA11, 1973KA50, 1976MA38, 1977BO10, 1977BA48, 1978FI11, - 22NE4C 1979SC31, 1980HO17, 1982RUZV, 1983BA41, 1985HAZA, 1990KU11, 1991BAZS, - 22NE5C 1995SCZY, 1996SC06, 1999BeZS, 1999BeZQ, 2000HE14, 2002UN02, 2002BA85, - 22NE6C 2004MU26, 2009NA08, 2008MU05 - 22NE T Auger electrons and X ray energies and emission intensities: - 22NE T {U Energy (keV)} {U Intensity} {U Line} - 22NE T - 22NE T 0.8486 0.0453 25 XKA2 - 22NE T 0.8486 0.090 5 XKA1 - 22NE T - 22NE T - 22NE T - 22NE T - 22NE T 0.75-0.81 |] KLL AUGER - 22NE T - |] 8.8 1 KLX AUGER - 22NA P 0.0 3+ 2.6029 Y 8 2843.02 21 - 22NE N 1.0 1.0 1 1.0 - 22NE L 0 0+ STABLE - 22NE E 0.055 140.00098 2514.91 2U - 22NE2 E EAV=835.04 19 - 22NE L 1274.577 7 2+ 0.00524 NS7 - 22NE E 90.30 99.64 97.41 - 22NE2 E EAV=215.62 17$CK=0.923 4$CL=0.077 4 - 22NE G 1274.537 7 99.94 13E2 6.71E-6 9 - 22NE2 G KC=6.36E-6 9 - + 22NE 22NA EC DECAY (2.6029 Y) + 22NE H TYP=UPD$AUT=M.GALAN$CUT=30-MAY-2009$ + 22NE2 H TYP=FUL$AUT=R.G.HELMER, E.SCHONFELD$CUT=18-JAN-1999$ + 22NE C References:1953WR13, 1954KR01, 1954SH01, 1954ZW01, 1955Al01, 1957ME47, + 22NE2C 1958KO75, 1959RA09, 1961WY01, 1964WI04, 1965AN07, 1967lE07, 1968VA13, + 22NE3C 1969MC06, 1970WA11, 1971ME**, 1973KA50, 1976MA38, 1977BO10, 1977BA48, + 22NE4C 1978FI11, 1979SC31, 1980HO17, 1982RUZV, 1983BA41, 1985HAZA, 1990KU11, + 22NE5C 1991BAZS, 1995SCZY, 1996SC06, 1999BeZS, 1999BeZQ, 2000HE14, 2002Un02, + 22NE6C 2002Ba85, 2004Mu26, 2009Na08, 2008MU05 + 22NE T Auger electrons and X ray energies and emission intensities: + 22NE T {U Energy (keV)} {U Intensity} {U Line} + 22NE T + 22NE T 0.8486 0.0453 25 XKA2 + 22NE T 0.8486 0.090 5 XKA1 + 22NE T + 22NE T + 22NE T + 22NE T + 22NE T 0.75-0.81 |] KLL AUGER + 22NE T - |] 8.8 1 KLX AUGER + 22NA P 0.0 3+ 2.6029 Y 8 2843.02 21 + 22NE N 1.0 1.0 1 1.0 + 22NE L 0 0+ STABLE + 22NE E 0.055 140.00098 2514.91 2U + 22NE2 E EAV=835.04 19 + 22NE L 1274.577 7 2+ 0.00524 NS7 + 22NE E 90.30 99.64 97.41 + 22NE2 E EAV=215.62 17$CK=0.08903 39$CL=0.00743 39 + 22NE G 1274.537 7 99.94 13E2 6.71E-6 9 + 22NE2 G KC=6.36E-6 9 + 22NE3 G IPC=2.34E-5 3 + diff --git a/HEN_HOUSE/spectra/lnhb/Na-24.txt b/HEN_HOUSE/spectra/lnhb/Na-24.txt index fc5648236..076a475e7 100644 --- a/HEN_HOUSE/spectra/lnhb/Na-24.txt +++ b/HEN_HOUSE/spectra/lnhb/Na-24.txt @@ -1,55 +1,57 @@ - 24MG 24NA B- DECAY (14.958 H) - 24MG H TYP=UPDATE$AUT=V.Chechev and N.K.Kuzmenko$CUT=31-MAR-2014$ - 24MG2 H TYP=ERR$AUT=M.-M.Be$CUT=12-FEB-2004$ - 24MG3 H TYP=FULL$AUT=R.G.Helmer and E.Schonfeld$CUT=31-MAR-2000$ - 24MG C Evaluation history: Type=UPDATE;Author=V.Chechev and N.K.Kuzmenko;Cutoff date=31-MAR-2014 - 24MG2C Type=ERR;Author=M.-M.Be;Cutoff date=12-FEB-2004 - 24MG3C Type=FULL;Author=R.G.Helmer and E.Schonfeld;Cutoff date=31-MAR-2000 - 24MG C References: 1950Gr01, 1951Tu12, 1952Sl52, 1955To07, 1958Ca20, 1958Da10, - 24MG2C 1960Ar10, 1961De23, 1961Wy01, 1961De25, 1963Pa20, 1964Le09, 1965Be24, - 24MG3C 1968Va06, 1969Bo48, 1972Gi17, 1973Br16, 1976Ge06, 1977La19, 1980RuZY, - 24MG4C 1982HoZJ, 1982RuZV, 1983Wa26, 1990En08, 1990En02, 1992Un01, 1998Si17, - 24MG5C 2000He14, 2002Ba85, 2002Un02, 2003Ep02, 2004Un01, 2004BeZR, 2005Li66, - 24MG6C 2007Fi14, 2008Ki07, 2012Wa38, 2012Fi12, 2014Un01 - 24MG T Auger electrons and X ray energies and emission intensities: - 24MG T {U Energy (keV)} {U Intensity} {U Line} - 24MG T - 24MG T 1.25361 1.13E-5 4 XKA2 - 24MG T 1.25361 2.25E-5 8 XKA1 - 24MG T - 24MG T 1.3022 |] 5.8E-7 14 XKB1 - 24MG T - 24MG T - 24MG T - 24MG T 1.102-1.182 |] KLL AUGER - 24MG T 1.214-1.252 |] 0.00114814 KLX AUGER - 24MG T 1.301-1.301 |] KXY AUGER - 24NA P 0.0 4+ 14.958 H 2 5515.61 4 - 24MG N 1.0 1.0 1 1.0 - 24MG G 511 0.144 2 - 24MG L 0 0 0+ STABLE - 24MG L 1368.672 5 2+ 1.33 PS 6 - 24MG B 4146.94 4 0.003 2 12.7 2 - 24MGS B EAV=1866.70 2 - 24MG G 1368.630 5 99.9934 5E2 9.91E-613 - 24MG2 G KC=9.29E-6 13$LC=5.97E-7 9$MC=2.21E-8 3 - 24MG L 4122.889 124+ 22 FS 2 - 24MG B 1392.72 4 99.930 3 6.12 - 24MGS B EAV=555.05 2 - 24MG G 2754.049 1399.862 3E2 2.71E-6 4 - 24MG2 G KC=2.54E-6 4$LC=163E-9 2$MC=6.05E-9 9 - 24MG L 4238.24 3 2+ 41 FS 4 - 24MG B 1277.37 5 0.001 1 12.3 2 - 24MGS B EAV=503 - 24MG G 2869.38 3 0.00025 3M1+E2 23 9 2.54E-6 6 - 24MG2 G KC=2.38E-6 4$LC=153E-9 2$MC=5.67E-9 8 - 24MG G 4237.84 3 0.00084 10E2 1.42E-6 2 - 24MG2 G KC=1330E-9 19$LC=8.53E-8 12$MC=3.16E-9 5 - 24MG L 5235.12 4 3+ 61 FS 7 - 24MG B 280.49 6 0.066 3 6.69 - 24MGS B EAV=90.00 2 - 24MG G 996.86 5 0.00145 25M1+E2 5.1 12 2.05E-5 4 - 24MG2 G KC=1.92E-5 4$LC=1233E-9 20$MC=4.56E-8 8 - 24MG G 3866.12 4 0.066 2M1+E2 17 4 1.62E-6 2 - 24MG2 G KC=1516E-9 22$LC=9.73E-8 14$MC=3.61E-9 5 - + 24MG 24NA B- DECAY (14.958 H) + 24MG H TYP=UPD$AUT=V.P.CHECHEV, N.K.KUZMENKO$CUT=31-MAR-2014$ + 24MG2 H TYP=ERR$AUT=M.-M.BE$DAT=12-FEB-2004$COM=See DDEP website$ + 24MG3 H TYP=FUL$AUT=R.G.HELMER, E.SCHONFELD$CUT=31-MAR-2000$ + 24MG C References:1950Gr01, 1951Tu12, 1952Sl52, 1955To07, 1958Da10, 1958Ca20, + 24MG2C 1960Ar10, 1961De23, 1961De25, 1961Wy01, 1963Pa20, 1964Le09, 1965Be24, + 24MG3C 1968Va06, 1969Bo48, 1972Gi17, 1973Br16, 1976Ge06, 1977La19, 1980RuZY, + 24MG4C 1982RuZV, 1982HoZJ, 1983Wa26, 1990En08, 1990En02, 1992Un01, 1998Si17, + 24MG5C 2000He14, 2002Un02, 2002Ba85, 2003Ep02, 2004BeZR, 2004Un01, 2005Li66, + 24MG6C 2007Fi14, 2008Ki07, 2012Wa38, 2012Fi12, 2014Un01 + 24MG T Auger electrons and X ray energies and emission intensities: + 24MG T {U Energy (keV)} {U Intensity} {U Line} + 24MG T + 24MG T 1.25361 1.13E-5 4 XKA2 + 24MG T 1.25361 2.25E-5 8 XKA1 + 24MG T + 24MG T 1.3022 |] 5.8E-7 14 XKB1 + 24MG T + 24MG T + 24MG T + 24MG T 1.102-1.182 |] KLL AUGER + 24MG T 1.214-1.252 |] 0.00114814 KLX AUGER + 24MG T 1.301-1.301 |] KXY AUGER + 24NA P 0.0 4+ 14.958 H 2 5515.61 4 + 24MG N 1.0 1.0 1 1.0 + 24MG G 511 0.144 2 + 24MG L 0 0+ STABLE + 24MG L 1368.672 5 2+ 1.33 PS 6 + 24MG B 4146.94 4 0.003 2 12.7 2 + 24MGS B EAV=1866.70 2 + 24MG G 1368.630 5 99.9934 5E2 9.91E-613 + 24MG2 G KC=9.29E-6 13$LC=5.97E-7 9$MC=2.21E-8 3 + 24MG3 G IPC=4.63E-5 7 + 24MG L 4122.889 124+ 22 FS 2 + 24MG B 1392.72 4 99.930 3 6.12 + 24MGS B EAV=555.05 2 + 24MG G 2754.049 1399.862 3E2 2.71E-6 4 + 24MG2 G KC=2.54E-6 4$LC=1.632E-7 23$MC=6.05E-9 9 + 24MG3 G IPC=0.000675 10 + 24MG L 4238.24 3 2+ 41 FS 4 + 24MG B 1277.37 5 0.001 1 12.3 2 + 24MGS B EAV=503 + 24MG G 2869.38 3 0.00025 3M1+E2 23 9 2.54E-6 6 + 24MG2 G KC=2.38E-6 4$LC=1.528E-7 22$MC=5.67E-9 8 + 24MG3 G IPC=0.000727 11 + 24MG G 4237.84 3 0.00084 10E2 1.42E-6 2 + 24MG2 G KC=1.330E-6 19$LC=8.53E-8 12$MC=3.16E-9 5 + 24MG3 G IPC=0.001253 18 + 24MG L 5235.12 4 3+ 61 FS 7 + 24MG B 280.49 6 0.066 3 6.69 + 24MGS B EAV=90.00 2 + 24MG G 996.86 5 0.00145 25M1+E2 5.1 12 2.05E-5 4 + 24MG2 G KC=1.92E-5 4$LC=1.233E-6 20$MC=4.56E-8 8 + 24MG G 3866.12 4 0.066 2M1+E2 17 4 1.62E-6 2 + 24MG2 G KC=1.516E-6 22$LC=9.73E-8 14$MC=3.61E-9 5 + 24MG3 G IPC=0.001122 16 + diff --git a/HEN_HOUSE/spectra/lnhb/Nb-93m.txt b/HEN_HOUSE/spectra/lnhb/Nb-93m.txt index 1cdde237b..cb562c181 100644 --- a/HEN_HOUSE/spectra/lnhb/Nb-93m.txt +++ b/HEN_HOUSE/spectra/lnhb/Nb-93m.txt @@ -1,41 +1,40 @@ - 93NB 93NB IT DECAY (16.12 Y) - 93NB H TYP=UPDate$AUT=M.A.Kellett$CUT=02-OCT-2013$ - 93NB2 H TYP=FULL$AUT=V.Chechev. N.Kuzmenko$CUT=15-JUN-2001$ - 93NB C Evaluation history: Type=UPDate;Author=M.A.Kellett;Cutoff date=02-OCT-2013 - 93NB2C Type=FULL;Author=V.Chechev. N.Kuzmenko;Cutoff date=15-JUN-2001 - 93NB C References: 1954Sc74, 1964Ho08, 1965Fl02, 1967Be65, 1972FlZM, 1972Ko59, - 93NB2C 1976He**, 1976Ju04, 1977La19, 1977La19, 1977Mo07, 1977Ll01, 1978Ba**, - 93NB3C 1980Va**, 1981Ll01, 1982Re09, 1982Al**, 1983Va25, 1985Ge**, 1987La**, - 93NB4C 1990Co17, 1991BaZS, 1996Sc06, 1997Ba13, 1999ScZX, 1999ZhZY, 2000Sc47, - 93NB5C 2008Ki07 - 93NB T Auger electrons and X ray energies and emission intensities: - 93NB T {U Energy (keV)} {U Intensity} {U Line} - 93NB T - 93NB T 16.5213 3.32 8 XKA2 - 93NB T 16.6152 6.34 15 XKA1 - 93NB T - 93NB T 18.607 |] XKB3 - 93NB T 18.623 |] 1.64 4 XKB1 - 93NB T 18.78 |] XKB5II - 93NB T - 93NB T 18.952 |] XKB2 - 93NB T 18.982 |] 0.246 11 XKB4 - 93NB T - 93NB T 1.9-2.67 2.88 6 XL (total) - 93NB T 1.9 0.0870 23 XLL - 93NB T 2.16-2.17 2.32 6 XLA - 93NB T 2 0.00877 24 XLC - 93NB T 2.26-2.37 0.446 11 XLB - 93NB T 2.41-2.67 0.0236 4 XLG - 93NB T - 93NB T 13.49-14.14 |] KLL AUGER - 93NB T 15.79-16.58 |] 3.83 11 KLX AUGER - 93NB T 18.02-18.91 |] KXY AUGER - 93NB T 1.4-2.7 81.25 28 L AUGER - 93NB P 30.77 2 1/2- 16.12 Y 15 - 93NB N 1.0 1.0 1 1.0 - 93NB L 0 9/2+ STABLE - 93NB L 30.77 2 1/2- 16.12 Y 15 - 93NB G 30.77 2 0.000591 9M4 1.693E525 - 93NB2 G KC=2.60E4 4$LC=1.151E5 17$MC=2.49E4 4 - + 93NB 93NB IT DECAY (16.12 Y) + 93NB H TYP=UPD$AUT=M.A.KELLETT$CUT=02-OCT-2013$ + 93NB2 H TYP=FUL$AUT=V.P.CHECHEV, N.K.KUZMENKO$CUT=15-JUN-2001$ + 93NB C References:1954Sc74, 1964Ho08, 1965Fl02, 1967Be65, 1972FlZM, 1972Ko59, + 93NB2C 1976He**, 1976Ju04, 1977La19, 1977La19, 1977Mo07, 1977Ll01, 1978Ba**, + 93NB3C 1980Va**, 1981Ll01, 1982Re09, 1982Al**, 1983Va25, 1985Ge**, 1987La**, + 93NB4C 1990Co17, 1991BaZS, 1996Sc06, 1997Ba13, 1999ScZX, 1999ZhZY, 2000Sc47, + 93NB5C 2008Ki07 + 93NB T Auger electrons and X ray energies and emission intensities: + 93NB T {U Energy (keV)} {U Intensity} {U Line} + 93NB T + 93NB T 16.5213 3.32 8 XKA2 + 93NB T 16.6152 6.34 15 XKA1 + 93NB T + 93NB T 18.607 |] XKB3 + 93NB T 18.623 |] 1.64 4 XKB1 + 93NB T 18.78 |] XKB5II + 93NB T + 93NB T 18.952 |] XKB2 + 93NB T 18.982 |] 0.246 11 XKB4 + 93NB T + 93NB T 1.9-2.67 2.88 6 XL (total) + 93NB T 1.9 0.0870 23 XLL + 93NB T 2.16-2.17 2.32 6 XLA + 93NB T 2 0.00877 24 XLC + 93NB T 2.26-2.37 0.446 11 XLB + 93NB T 2.41-2.67 0.0236 4 XLG + 93NB T + 93NB T 13.49-14.14 |] KLL AUGER + 93NB T 15.79-16.58 |] 3.83 11 KLX AUGER + 93NB T 18.02-18.91 |] KXY AUGER + 93NB T 1.4-2.7 81.25 28 L AUGER + 93NB P 30.77 2 1/2- 16.12 Y 15 + 93NB N 1.0 1.0 1 + 93NB L 0 9/2+ STABLE + 93NB L 30.77 2 1/2- 16.12 Y 15 + 93NB G 30.77 2 0.000591 9M4 1.693E525 + 93NB2 G KC=2.60E4 4$LC=1.151E5 17$MC=2.49E4 4$NC=3230 50 + 93NB3 G OC=48.2 7 + diff --git a/HEN_HOUSE/spectra/lnhb/Nb-95.txt b/HEN_HOUSE/spectra/lnhb/Nb-95.txt index 13245ac70..3dcd81d79 100644 --- a/HEN_HOUSE/spectra/lnhb/Nb-95.txt +++ b/HEN_HOUSE/spectra/lnhb/Nb-95.txt @@ -1,42 +1,41 @@ - 95MO 95NB B- DECAY (34.991 D) - 95MO H TYP=Full$AUT=R.G.Helmer$CUT= -- $ - 95MO C Evaluation history: Type=Full;Author=R.G.Helmer;Cutoff date= -- - 95MO T Auger electrons and X ray energies and emission intensities: - 95MO T {U Energy (keV)} {U Intensity} {U Line} - 95MO T - 95MO T 17.3745 0.0286 9 XKA2 - 95MO T 17.4795 0.0546 18 XKA1 - 95MO T - 95MO T 19.5904 |] XKB3 - 95MO T 19.6085 |] 0.0143 5 XKB1 - 95MO T 19.774 |] XKB5II - 95MO T - 95MO T 19.9653 |] XKB2 - 95MO T 19.998 |] 0.00221 11 XKB4 - 95MO T - 95MO T 2.01-2.83 0.0055 9 XL (total) - 95MO T 2.01 XLL - 95MO T -2.83 XLG - 95MO T - 95MO T 14.268-14.96 |] KLL AUGER - 95MO T 16.628-17.476 |] 0.0303 11 KLX AUGER - 95MO T 18.99-19.99 |] KXY AUGER - 95MO T 1.856-2.86 0.143 4 L AUGER - 95NB P 0.0 9/2+ 34.991 D 6 925.6 5 - 95MO N 1.0 1.0 1 1.0 - 95MO L 0 5/2+ STABLE - 95MO B 925.6 5 0.030 5 11.2 2 - 95MOS B EAV=321.94 21 - 95MO L 204.118 9 3/2+ 0.751 NS 9 - 95MO B 721.5 5 2U - 95MOS B EAV=283.58 20 - 95MO G 204.117 2 0.028 8M1+E2 0.0515 22 - 95MO2 G KC=0.045 3$LC=0.0058 4 - 95MO L 765.806 6 7/2+ 0.0044 NS 7 - 95MO B 159.8 5 99.970 6 5.09 - 95MOS B EAV=43.36 15 - 95MO G 561.88 2 0.015 3[E2] 0.0034110 - 95MO2 G KC=0.00298 9$LC=3.54E-4 11 - 95MO G 765.803 6 99.808 7M1+E2 0.00147 4 - 95MO2 G KC=0.00129 4$LC=1.45E-4 4 - + 95MO 95NB B- DECAY (34.991 D) + 95MO H TYP=FUL$AUT=R.G.HELMER$CUT=30-JUN-1998$ + 95MO T Auger electrons and X ray energies and emission intensities: + 95MO T {U Energy (keV)} {U Intensity} {U Line} + 95MO T + 95MO T 17.3745 0.0286 9 XKA2 + 95MO T 17.4795 0.0546 18 XKA1 + 95MO T + 95MO T 19.5904 |] XKB3 + 95MO T 19.6085 |] 0.0143 5 XKB1 + 95MO T 19.774 |] XKB5II + 95MO T + 95MO T 19.9653 |] XKB2 + 95MO T 19.998 |] 0.00221 11 XKB4 + 95MO T + 95MO T 2.01-2.83 0.0055 9 XL (total) + 95MO T 2.01 XLL + 95MO T -2.83 XLG + 95MO T + 95MO T 14.268-14.96 |] KLL AUGER + 95MO T 16.628-17.476 |] 0.0303 11 KLX AUGER + 95MO T 18.99-19.99 |] KXY AUGER + 95MO T 1.856-2.86 0.143 4 L AUGER + 95NB P 0.0 9/2+ 34.991 D 6 925.6 5 + 95MO N 1.0 1.0 1 1.0 + 95MO L 0 5/2+ STABLE + 95MO B 925.6 5 0.030 5 11.2 2 + 95MOS B EAV=321.94 21 + 95MO L 204.118 9 3/2+ 0.751 NS 9 + 95MO B 721.5 5 2U + 95MOS B EAV=283.58 20 + 95MO G 204.117 2 0.028 8M1+E2 0.0515 22 + 95MO2 G KC=0.045 3$LC=0.0058 4 + 95MO L 765.806 6 7/2+ 0.0044 NS 7 + 95MO B 159.8 5 99.970 6 5.09 + 95MOS B EAV=43.36 15 + 95MO G 561.88 2 0.015 3[E2] 0.0034110 + 95MO2 G KC=0.00298 9$LC=0.000354 11 + 95MO G 765.803 6 99.808 7M1+E2 0.00147 4 + 95MO2 G KC=0.00129 4$LC=0.000145 4 + diff --git a/HEN_HOUSE/spectra/lnhb/Nb-95m.txt b/HEN_HOUSE/spectra/lnhb/Nb-95m.txt index 93b1e9df0..3fafd132a 100644 --- a/HEN_HOUSE/spectra/lnhb/Nb-95m.txt +++ b/HEN_HOUSE/spectra/lnhb/Nb-95m.txt @@ -1,73 +1,71 @@ - 95NB 95NB IT DECAY (3.61 D) - 95NB H TYP=Full$AUT=M.M.Bé. R.G.Helmer$CUT= -- $ - 95NB C Evaluation history: Type=Full;Author=M.M.Bé. R.G.Helmer;Cutoff date= -- - 95NB T Auger electrons and X ray energies and emission intensities: - 95NB T {U Energy (keV)} {U Intensity} {U Line} - 95NB T - 95NB T 16.521 12.5 6 XKA2 - 95NB T 16.615 23.9 10 XKA1 - 95NB T - 95NB T 18.607 |] XKB3 - 95NB T 18.623 |] 6.19 27 XKB1 - 95NB T 18.78 |] XKB5II - 95NB T - 95NB T 18.952 |] XKB2 - 95NB T 18.982 |] 0.93 5 XKB4 - 95NB T - 95NB T 1.9-2.66 0.0251 11 XL (total) - 95NB T 1.9 XLL - 95NB T -2.66 XLG - 95NB T - 95NB T 13.49-14.14 |] KLL AUGER - 95NB T 15.79-16.58 |] 14.5 7 KLX AUGER - 95NB T 18.02-18.91 |] KXY AUGER - 95NB T 1.4-2.6 69.9 25 L AUGER - 95NB P 235.69 2 1/2- 3.61 D 3 - 95NB N 1.026E0 1.026E0 0.975 1.026E0 - 95NB L 0 9/2+ 34.991 D 6 - 95NB L 235.69 5 1/2- 3.61 D 3 - 95NB G 235.69 2 25.1 3M4 2.88 9 - 95NB2 G KC=2.31 8$LC=0.468 14$MC=0.1 - - 95MO 95NB B- DECAY (3.61 D) - 95MO H TYP=Full$AUT=M.M.Bé. R.G.Helmer$CUT= -- $ - 95MO C Evaluation history: Type=Full;Author=M.M.Bé. R.G.Helmer;Cutoff date= -- - 95MO T Auger electrons and X ray energies and emission intensities: - 95MO T {U Energy (keV)} {U Intensity} {U Line} - 95MO T - 95MO T 17.374 XKA2 - 95MO T 17.479 XKA1 - 95MO T - 95MO T 17.59 |] XKB3 - 95MO T 19.608 |] XKB1 - 95MO T 19.771 |] XKB5II - 95MO T - 95MO T 19.965 |] XKB2 - 95MO T 19.997 |] XKB4 - 95MO T - 95MO T - 95MO T 14.268-14.96 |] KLL AUGER - 95MO T 16.628-17.476 |] KLX AUGER - 95MO T 18.99-19.99 |] KXY AUGER - 95MO T 1.86-2.86 L AUGER - 95NB P 235.69 2 1/2- 3.61 D 3 925.6 5 - 95MO N 4.00E1 4.00E1 0.025 4.00E1 - 95MO L 0 5/2+ STABLE - 95MO L 204.118 3/2+ 0.751 NS - 95MO B 957.2 5 2.4 1 8.3 1 - 95MOS B EAV=345 1 - 95MO G 204.117 2 2.28 10M1+E2 0.0515 22 - 95MO2 G KC=0.045 3$LC=0.0058 4 - 95MO L 786.19 1/2+ - 95MO B 375.1 5 0.016 9.1 - 95MOS B EAV=123 1 - 95MO G 786.19 1 0.016 1E2 0.00131 5 - 95MO L 820.61 3/2+ - 95MO B 340.7 5 0.00038 10.6 1 - 95MOS B EAV=123 1 - 95MO G 820.61 1 0.00038 M1+E2 - 95MO L 1039.25 1/2+ - 95MO B 122.0 5 0.00002525 10.2 - 95MOS B EAV=44.0 5 - 95MO G 835.13 1 0.000025 - + 95NB 95NB IT DECAY (3.61 D) + 95NB H TYP=FUL$AUT=M.-M.BE, R.G.HELMER$CUT=30-OCT-1998$ + 95NB T Auger electrons and X ray energies and emission intensities: + 95NB T {U Energy (keV)} {U Intensity} {U Line} + 95NB T + 95NB T 16.521 12.5 6 XKA2 + 95NB T 16.615 23.9 10 XKA1 + 95NB T + 95NB T 18.607 |] XKB3 + 95NB T 18.623 |] 6.19 27 XKB1 + 95NB T 18.78 |] XKB5II + 95NB T + 95NB T 18.952 |] XKB2 + 95NB T 18.982 |] 0.93 5 XKB4 + 95NB T + 95NB T 1.9-2.66 0.0251 11 XL (total) + 95NB T 1.9 XLL + 95NB T -2.66 XLG + 95NB T + 95NB T 13.49-14.14 |] KLL AUGER + 95NB T 15.79-16.58 |] 14.5 7 KLX AUGER + 95NB T 18.02-18.91 |] KXY AUGER + 95NB T 1.4-2.6 69.9 25 L AUGER + 95NB P 235.69 2 1/2- 3.61 D 3 + 95NB N 1.026E0 1.026E0 0.975 + 95NB L 0 9/2+ 34.991 D 6 + 95NB L 235.69 5 1/2- 3.61 D 3 + 95NB G 235.69 2 25.1 3M4 2.88 9 + 95NB2 G KC=2.31 8$LC=0.468 14$MC=0.1 + + 95MO 95NB B- DECAY (3.61 D) + 95MO H TYP=FUL$AUT=M.-M.BE, R.G.HELMER$CUT=30-OCT-1998$ + 95MO T Auger electrons and X ray energies and emission intensities: + 95MO T {U Energy (keV)} {U Intensity} {U Line} + 95MO T + 95MO T 17.374 XKA2 + 95MO T 17.479 XKA1 + 95MO T + 95MO T 17.59 |] XKB3 + 95MO T 19.608 |] XKB1 + 95MO T 19.771 |] XKB5II + 95MO T + 95MO T 19.965 |] XKB2 + 95MO T 19.997 |] XKB4 + 95MO T + 95MO T + 95MO T 14.268-14.96 |] KLL AUGER + 95MO T 16.628-17.476 |] KLX AUGER + 95MO T 18.99-19.99 |] KXY AUGER + 95MO T 1.86-2.86 L AUGER + 95NB P 235.69 2 1/2- 3.61 D 3 925.6 5 + 95MO N 4.00E1 4.00E1 0.025 4.00E1 + 95MO L 0 5/2+ STABLE + 95MO L 204.118 3/2+ 0.751 NS + 95MO B 957.2 5 2.4 1 8.3 1 + 95MOS B EAV=345 1 + 95MO G 204.117 2 2.28 10M1+E2 0.0515 22 + 95MO2 G KC=0.045 3$LC=0.0058 4 + 95MO L 786.19 1/2+ + 95MO B 375.1 5 0.016 9.1 + 95MOS B EAV=123 1 + 95MO G 786.19 1 0.016 1E2 0.00131 5 + 95MO L 820.61 3/2+ + 95MO B 340.7 5 0.00038 10.6 1 + 95MOS B EAV=123 1 + 95MO G 820.61 1 0.00038 M1+E2 + 95MO L 1039.25 1/2+ + 95MO B 122.0 5 0.00002525 10.2 + 95MOS B EAV=44.0 5 + 95MO G 835.13 1 0.000025 + diff --git a/HEN_HOUSE/spectra/lnhb/Nd-147.txt b/HEN_HOUSE/spectra/lnhb/Nd-147.txt index 8092e9c75..532730c94 100644 --- a/HEN_HOUSE/spectra/lnhb/Nd-147.txt +++ b/HEN_HOUSE/spectra/lnhb/Nd-147.txt @@ -1,125 +1,152 @@ -147PM 147ND B- DECAY (10.987 D) -147PM H TYP=Full$AUT=V. Chisté$CUT=30-MAR-2011$ -147PM C Evaluation history: Type=Full;Author=V. Chisté;Cutoff date=30-MAR-2011 -147PM C References: 1946Bo25, 1951EM23, 1951Ko01, 1951Ma**, 1952Ru10, 1957Li40, -147PM2C 1957Bi86, 1957Wr37, 1960Wi10, 1960Ma03, 1960Bo17, 1961Sa13, 1961Ar09, -147PM3C 1961Ew02, 1961We07, 1962Sh08, 1963Ho15, 1963Sp07, 1963Ph02, 1966Go25, -147PM4C 1966Be09, 1967Ja05, 1966Ar16, 1967Ca18, 1967Ba21, 1967Do07, 1967Hi04, -147PM5C 1967Ba06, 1967Ba22, 1968Ra28, 1969Ba32, 1970Bl12, 1971Ba28, 1971Si20, -147PM6C 1971Na11, 1974HeYW, 1974Ra30, 1974Bh02, 1976Si08, 1977Kr13, 1977Al34, -147PM7C 1979Vo09, 1979Se05, 1995Go**, 1996Sc06, 1997Sa53, 1998Po**, 2002Ba85, -147PM8C 2008Ki07, 2009AuZZ, 2009Ni02, 2010Gh** -147PM T Auger electrons and X ray energies and emission intensities: -147PM T {U Energy (keV)} {U Intensity} {U Line} -147PM T -147PM T 38.1716 12.9 9 XKA2 -147PM T 38.7251 23.5 15 XKA1 -147PM T -147PM T 43.713 |] XKB3 -147PM T 43.826 |] 7.3 5 XKB1 -147PM T 44.145 |] XKB5II -147PM T -147PM T 44.937 |] XKB2 -147PM T 45.064 |] 1.87 13 XKB4 -147PM T 45.162 |] XKO23 -147PM T -147PM T 4.81-7.1893 7.6 3 XL (total) -147PM T 4.81 0.148 9 XLL -147PM T 5.4061-5.4325 3.68 20 XLA -147PM T 5.363 0.057 4 XLC -147PM T 5.9552-6.3985 3.20 14 XLB -147PM T 6.6814-7.1893 0.517 24 XLG -147PM T -147PM T 30.16-32.08 |] KLL AUGER -147PM T 36.03-37.63 |] 3.9 4 KLX AUGER -147PM T 41.84-44.16 |] KXY AUGER -147PM T 3.1-6.27 43.4 18 L AUGER -147ND P 0.0 5/2- 10.987 D 11 895.7 9 -147PM N 1.0 1.0 1 1.0 -147PM L 0 7/2+ 2.6234 Y 4 -147PM B 895.7 9 7.5 1 -147PMS B EAV=299.45 35 -147PM L 91.1049 205/2+ 2.50 NS 5 -147PM B 804.6 9 81 5 7.4 -147PMS B EAV=263.99 35 -147PM G 91.105 2 28.4 18M1+E2 0.090 5 2.03 3 -147PM2 G KC=1.714 24$LC=0.250 4$MC=0.0535 8 -147PM L 408.54 5 9/2+ -147PM G 408.52 6 0.0178 13M1+E2 0.57 3 0.0304 5 -147PM2 G KC=0.0257 5$LC=0.00368 6$MC=7.89E-4 12 -147PM L 410.512 133/2+ 0.139 NS 14 -147PM B 485.2 9 0.715 34 8.7 1 -147PMS B EAV=146.67 30 -147PM G 319.411 181.991 19M1+E2 -0.378 9 0.0607 9 -147PM2 G KC=0.0514 8$LC=0.00734 11$MC=1572E-6 22 -147PM G 410.48 3 0.137 6E2 0.0212 3 -147PM2 G KC=0.01724 25$LC=0.00313 5$MC=6.83E-4 10 -147PM L 489.255 167/2+ -147PM B 406.4 9 0.781 15 8.4 1 -147PMS B EAV=119.83 30 -147PM G 80.82 270.00086 11[M1E2] 3.9 11 -147PM2 G KC=2.26 17$LC=1.3 10$MC=0.29 22 -147PM G 398.155 200.855 8M1+E2 0.297 37 0.0345 5 -147PM2 G KC=0.0293 5$LC=0.00406 6$MC=8.66E-4 13 -147PM G 489.24 3 0.136 11M1+E2 -0.79 35 0.0179 18 -147PM2 G KC=0.0152 16$LC=0.00218 14$MC=0.00047 3 -147PM L 531.012 155/2+ 0.083 NS 15 -147PM B 364.7 9 14.6 9 7 -147PMS B EAV=106.02 30 -147PM G 120.48 5 0.361 14M1+E2 0.116 42 0.914 14 -147PM2 G KC=0.772 11$LC=0.112 4$MC=0.0239 8 -147PM G 439.895 221.203 11M1+E2 0.609 21 0.0248 4 -147PM2 G KC=0.0210 4$LC=0.00300 5$MC=6.41E-4 10 -147PM G 531.016 2212.7 9M1+E2 -0.407 35 0.0161 3 -147PM2 G KC=0.01374 23$LC=0.00188 3$MC=4.02E-4 6 -147PM L 632.93 7 1/2+ -147PM B 262.8 9 0.0190 27 9.1 1U -147PMS B EAV=85.89 33 -147PM G 541.83 7 0.0188 27[E2] 0.0099414 -147PM2 G KC=0.00824 12$LC=1338E-6 19$MC=2.90E-4 4 -147PM L 641.27 8 + -147PM G 230.77 8 -147PM L 649.03 4 11/2- 27 NS 3 -147PM B 246.7 9 0.296 19 7.5 2U -147PMS B EAV=91.35 33 -147PM G 117.98 8 0.0152 13E3 14.07 20 -147PM2 G KC=3.15 5$LC=8.41 12$MC=2.02 3 -147PM G 159.7 2 0.00508 38M2 2.74 4 -147PM2 G KC=2.18 4$LC=0.439 7$MC=0.0977 15 -147PM G 240.5 2 0.0406 25E1 0.0250 4 -147PM2 G KC=0.0213 3$LC=0.00290 5$MC=6.15E-4 9 -147PM G 649.04 8 0.00495 38M2 0.0299 5 -147PM2 G KC=0.0251 4$LC=0.00371 6$MC=7.99E-4 12 -147PM L 680.44 4 7/2+ -147PM B 215.3 9 0.0897 28 8.4 1 -147PMS B EAV=59.16 27 -147PM G 31.3 2 [M2] 548 18 -147PM2 G LC=422 14$MC=100 4 -147PM G 149.3 2 0.00368 38[M1E2] 0.52 3 -147PM2 G KC=0.39 3$LC=0.10 5$MC=0.022 10 -147PM G 191.0 3 0.00356 38[M1E2] 0.244 9 -147PM2 G KC=0.192 22$LC=0.040 11$MC=0.009 3 -147PM G 271.87 6 0.0126 9M1+E2 0.10 3 0.0964 14 -147PM2 G KC=0.0820 12$LC=0.01133 16$MC=0.00242 4 -147PM G 589.35 4 0.037 2[M1E2] 0.011 3 -147PM2 G KC=0.0090 23$LC=0.00128 23$MC=0.00027 4 -147PM G 680.52 150.0283 14[M1E2] 0.0074 18 -147PM2 G KC=0.0063 18$LC=0.00088 17$MC=0.00019 4 -147PM L 685.890 155/2+ 0.25 NS 10 -147PM B 209.8 9 2.184 16 7 -147PMS B EAV=57.54 27 -147PM G 36.75 10 [E3] 1.004E422 -147PM2 G LC=7.60E3 17$MC=1960 50 -147PM G 53.1 2 [E2] 25.1 6 -147PM2 G KC=4.40 7$LC=16.1 4$MC=3.73 9 -147PM G 154.7 2 0.00394 38[M1E2] 0.468 19 -147PM2 G KC=0.36 3$LC=0.09 4$MC=0.020 9 -147PM G 196.64 4 0.1798 18M1+E2 -0.20 8 0.231 4 -147PM2 G KC=0.196 3$LC=0.0281 8$MC=0.00601 18 -147PM G 275.374 150.775 11M1+E2 0.112 5 0.0931 13 -147PM2 G KC=0.0792 11$LC=0.01095 16$MC=0.00234 4 -147PM G 594.80 3 0.2653 36M1+E2 0.55 6 0.0117 3 -147PM2 G KC=0.00995 23$LC=0.00137 3$MC=2.92E-4 6 -147PM G 685.90 4 0.834 9M1+E2 -0.92 20 0.0074 5 -147PM2 G KC=0.0063 4$LC=0.00088 4$MC=1.88E-4 9 - +147PM 147ND B- DECAY (10.987 D) +147PM H TYP=FUL$AUT=V.CHISTE$CUT=30-MAR-2011$ +147PM C References:1946Bo25, 1951EM23, 1951Ko01, 1951Ma**, 1952Ru10, 1957Li40, +147PM2C 1957Bi86, 1957Wr37, 1960Wi10, 1960Ma03, 1960Bo17, 1961Sa13, 1961Ar09, +147PM3C 1961Ew02, 1961We07, 1962Sh08, 1963Ho15, 1963Sp07, 1963Ph02, 1966Go25, +147PM4C 1966Be09, 1967Ja05, 1966Ar16, 1967Ca18, 1967Ba21, 1967Do07, 1967Hi04, +147PM5C 1967Ba06, 1967Ba22, 1968Ra28, 1969Ba32, 1970Bl12, 1971Ba28, 1971Si20, +147PM6C 1971Na11, 1974HeYW, 1974Ra30, 1974Bh02, 1976Si08, 1977Kr13, 1977Al34, +147PM7C 1979Vo09, 1979Se05, 1995Go**, 1996Sc06, 1997Sa53, 1998Po**, 2002Ba85, +147PM8C 2008Ki07, 2009AuZZ, 2009Ni02, 2010Gh** +147PM T Auger electrons and X ray energies and emission intensities: +147PM T {U Energy (keV)} {U Intensity} {U Line} +147PM T +147PM T 38.1716 12.9 9 XKA2 +147PM T 38.7251 23.5 15 XKA1 +147PM T +147PM T 43.713 |] XKB3 +147PM T 43.826 |] 7.3 5 XKB1 +147PM T 44.145 |] XKB5II +147PM T +147PM T 44.937 |] XKB2 +147PM T 45.064 |] 1.87 13 XKB4 +147PM T 45.162 |] XKO23 +147PM T +147PM T 4.81-7.1893 7.6 3 XL (total) +147PM T 4.81 0.148 9 XLL +147PM T 5.4061-5.4325 3.68 20 XLA +147PM T 5.363 0.057 4 XLC +147PM T 5.9552-6.3985 3.20 14 XLB +147PM T 6.6814-7.1893 0.517 24 XLG +147PM T +147PM T 30.16-32.08 |] KLL AUGER +147PM T 36.03-37.63 |] 3.9 4 KLX AUGER +147PM T 41.84-44.16 |] KXY AUGER +147PM T 3.1-6.27 43.4 18 L AUGER +147ND P 0.0 5/2- 10.987 D 11 895.7 9 +147PM N 1.0 1.0 1 1.0 +147PM L 0 7/2+ 2.6234 Y 4 +147PM B 895.7 9 0 5 7.5 1 +147PMS B EAV=299.45 35 +147PM L 91.1049 205/2+ 2.50 NS 5 +147PM B 804.6 9 81 5 7.4 +147PMS B EAV=263.99 35 +147PM G 91.105 2 28.4 18M1+E2 0.090 5 2.03 3 +147PM2 G KC=1.714 24$LC=0.250 4$MC=0.0535 8$NC=0.01203 18 +147PM3 G OC=0.00180 3 +147PM L 408.54 5 9/2+ +147PM G 408.52 6 0.0178 13M1+E2 0.57 3 0.0304 5 +147PM2 G KC=0.0257 5$LC=0.00368 6$MC=0.000789 12$NC=0.000177 3 +147PM3 G OC=2.65E-5 4 +147PM L 410.512 133/2+ 0.139 NS 14 +147PM B 485.2 9 0.715 34 8.7 1 +147PMS B EAV=146.67 30 +147PM G 319.411 181.991 19M1+E2 -0.378 9 0.0607 9 +147PM2 G KC=0.0514 8$LC=0.00734 11$MC=0.001572 22$NC=0.000354 5 +147PM3 G OC=5.30E-5 8 +147PM G 410.48 3 0.137 6E2 0.0212 3 +147PM2 G KC=0.01724 25$LC=0.00313 5$MC=0.000683 10$NC=1.520E-4 22 +147PM3 G OC=2.17E-5 3 +147PM L 489.255 167/2+ +147PM B 406.4 9 0.781 15 8.4 1 +147PMS B EAV=119.83 30 +147PM G 80.82 270.00086 11[M1,E2] 3.9 11 +147PM2 G KC=2.26 17$LC=1.3 10$MC=0.29 22$NC=0.06 5 +147PM3 G OC=0.008 6 +147PM G 398.155 200.855 8M1+E2 0.297 37 0.0345 5 +147PM2 G KC=0.0293 5$LC=0.00406 6$MC=0.000866 13$NC=0.000195 3 +147PM3 G OC=2.94E-5 5 +147PM G 489.24 3 0.136 11M1+E2 -0.79 35 0.0179 18 +147PM2 G KC=0.0152 16$LC=0.00218 14$MC=0.00047 3$NC=0.000105 7 +147PM3 G OC=1.57E-5 12 +147PM L 531.012 155/2+ 0.083 NS 15 +147PM B 364.7 9 14.6 9 7 +147PMS B EAV=106.02 30 +147PM G 120.48 5 0.361 14M1+E2 0.116 42 0.914 14 +147PM2 G KC=0.772 11$LC=0.112 4$MC=0.0239 8$NC=0.00538 16 +147PM3 G OC=0.000807 21 +147PM G 439.895 221.203 11M1+E2 0.609 21 0.0248 4 +147PM2 G KC=0.0210 4$LC=0.00300 5$MC=0.000641 10$NC=1.442E-4 21 +147PM3 G OC=2.16E-5 4 +147PM G 531.016 2212.7 9M1+E2 -0.407 35 0.0161 3 +147PM2 G KC=0.01374 23$LC=0.00188 3$MC=0.000402 6$NC=9.05E-5 14 +147PM3 G OC=1.364E-5 22 +147PM L 632.93 7 1/2+ +147PM B 262.8 9 0.0190 27 9.1 1U +147PMS B EAV=85.89 33 +147PM G 541.83 7 0.0188 27[E2] 0.0099414 +147PM2 G KC=0.00824 12$LC=0.001338 19$MC=0.000290 4$NC=6.47E-5 9 +147PM3 G OC=9.40E-6 14 +147PM L 641.27 8 +147PM G 230.77 8 +147PM L 649.03 4 11/2- 27 NS 3 +147PM B 246.7 9 0.296 19 7.5 2U +147PMS B EAV=91.35 33 +147PM G 117.98 8 0.0152 13E3 14.07 20 +147PM2 G KC=3.15 5$LC=8.41 12$MC=2.02 3$NC=0.441 7 +147PM3 G OC=0.0549 8 +147PM G 159.7 2 0.00508 38M2 2.74 4 +147PM2 G KC=2.18 4$LC=0.439 7$MC=0.0977 15$NC=0.0221 4 +147PM3 G OC=0.00326 5 +147PM G 240.5 2 0.0406 25E1 0.0250 4 +147PM2 G KC=0.0213 3$LC=0.00290 5$MC=0.000615 9$NC=1.374E-4 20 +147PM3 G OC=2.02E-5 3 +147PM G 649.04 8 0.00495 38M2 0.0299 5 +147PM2 G KC=0.0251 4$LC=0.00371 6$MC=0.000799 12$NC=0.000180 3 +147PM3 G OC=2.72E-5 4 +147PM L 680.44 4 7/2+ +147PM B 215.3 9 0.0897 28 8.4 1 +147PMS B EAV=59.16 27 +147PM G 31.3 2 [M2] 548 18 +147PM2 G LC=422 14$MC=100 4$NC=22.6 8 +147PM3 G OC=3.22 11 +147PM G 149.3 2 0.00368 38[M1,E2] 0.52 3 +147PM2 G KC=0.39 3$LC=0.10 5$MC=0.022 10$NC=0.0050 22 +147PM3 G OC=0.00068 25 +147PM G 191.0 3 0.00356 38[M1,E2] 0.244 9 +147PM2 G KC=0.192 22$LC=0.040 11$MC=0.009 3$NC=0.0020 6 +147PM3 G OC=0.00028 7 +147PM G 271.87 6 0.0126 9M1+E2 0.10 3 0.0964 14 +147PM2 G KC=0.0820 12$LC=0.01133 16$MC=0.00242 4$NC=0.000545 8 +147PM3 G OC=8.23E-5 12 +147PM G 589.35 4 0.037 2[M1,E2] 0.011 3 +147PM2 G KC=0.0090 23$LC=0.00128 23$MC=0.00027 4$NC=0.000065 11 +147PM3 G OC=9.2E-6 18 +147PM G 680.52 150.0283 14[M1,E2] 0.0074 18 +147PM2 G KC=0.0063 18$LC=0.00088 17$MC=0.00019 4$NC=0.000042 8 +147PM3 G OC=6.4E-6 13 +147PM L 685.890 155/2+ 0.25 NS 10 +147PM B 209.8 9 2.184 16 7 +147PMS B EAV=57.54 27 +147PM G 36.75 10 [E3] 1.004E422 +147PM2 G LC=7.60E3 17$MC=1960 50$NC=430 10 +147PM3 G OC=51.0 11 +147PM G 53.1 2 [E2] 25.1 6 +147PM2 G KC=4.40 7$LC=16.1 4$MC=3.73 9$NC=0.808 19 +147PM3 G OC=0.1003 23 +147PM G 154.7 2 0.00394 38[M1,E2] 0.468 19 +147PM2 G KC=0.36 3$LC=0.09 4$MC=0.020 9$NC=0.0043 18 +147PM3 G OC=0.00059 21 +147PM G 196.64 4 0.1798 18M1+E2 -0.20 8 0.231 4 +147PM2 G KC=0.196 3$LC=0.0281 8$MC=0.00601 18$NC=0.00135 4 +147PM3 G OC=0.000203 5 +147PM G 275.374 150.775 11M1+E2 0.112 5 0.0931 13 +147PM2 G KC=0.0792 11$LC=0.01095 16$MC=0.00234 4$NC=0.000526 8 +147PM3 G OC=7.95E-5 12 +147PM G 594.80 3 0.2653 36M1+E2 0.55 6 0.0117 3 +147PM2 G KC=0.00995 23$LC=0.00137 3$MC=0.000292 6$NC=6.57E-5 13 +147PM3 G OC=9.9E-6 2 +147PM G 685.90 4 0.834 9M1+E2 -0.92 20 0.0074 5 +147PM2 G KC=0.0063 4$LC=0.00088 4$MC=0.000188 9$NC=4.22E-5 20 +147PM3 G OC=6.3E-6 4 + diff --git a/HEN_HOUSE/spectra/lnhb/Ni-57.txt b/HEN_HOUSE/spectra/lnhb/Ni-57.txt index 28407bef2..21d4dfeb2 100644 --- a/HEN_HOUSE/spectra/lnhb/Ni-57.txt +++ b/HEN_HOUSE/spectra/lnhb/Ni-57.txt @@ -1,84 +1,84 @@ - 57CO 57NI EC DECAY (1.496 D) - 57CO T Auger electrons and X ray energies and emission intensities: - 57CO T {U Energy (keV)} {U Intensity} {U Line} - 57CO T - 57CO T 6.91538 5.84 12 XKA2 - 57CO T 6.9304 11.42 23 XKA1 - 57CO T - 57CO T 7.6495 |] 2.37 6 XKB1 - 57CO T 7.706 |] XKB5II - 57CO T - 57CO T - 57CO T 0.678-0.87 0.56 4 XL (total) - 57CO T 0.678 XLL - 57CO T -0.87 XLG - 57CO T - 57CO T 5.81-6.1 |] KLL AUGER - 57CO T 6.67-6.86 |] 31.0 6 KLX AUGER - 57CO T 7.5-7.58 |] KXY AUGER - 57CO T 0.564-0.653 76.7 12 L AUGER - 57NI P 0.0 3/2- 1.496 D 23 3264.2 26 - 57CO N 1.0 1.0 1 1.0 - 57CO L 0 7/2- 271.80 D 5 - 57CO L 1223.79 7 9/2- 54 FS 5 - 57CO G 1223.8 3 0.076 13M1+E2 1.20E-4 4 - 57CO2 G KC=1.08E-4 3$LC=1.03E-5 3 - 57CO L 1377.65 3 3/2- 19 PS 4 - 57CO E 35.3 529.3 55.6 - 57CO2 E EAV=368.3 $CK=0.8876 16$CL=0.0961 13$CM=0.0155 5 - 57CO G 1377.62 4 81.2 6E2 1.05E-4 3 - 57CO2 G KC=9.5E-5 3$LC=9.1E-6 3 - 57CO L 1504.82 3 1/2- 0.21 NS 2 - 57CO E 6.8 39.6 46.1 - 57CO2 E EAV=313.4 $CK=0.8875 16$CL=0.0962 13$CM=0.0155 5 - 57CO G 127.164 3 16.0 5M1+E2 0.0215 6 - 57CO2 G KC=0.0193 6$LC=0.00191 6 - 57CO L 1757.596 243/2- 0.27 PS 2 - 57CO E 0.85 65.2 36.2 - 57CO2 E EAV=206.1 $CK=0.8874 16$CL=0.0963 13$CM=0.0155 5 - 57CO G 379.940 200.072 6[M1] 0.00143 4 - 57CO2 G KC=0.00129 4$LC=1.24E-4 4 - 57CO G 1757.55 3 6.1 4E2 - 57CO L 1897.24 6 7/2- 110 FS 10 - 57CO G 673.44 4 0.0483 15M1+E2 0.00040 1 - 57CO2 G KC=0.00036 1$LC=3.4E-5 1 - 57CO G 1897.0 5 0.0252 25M1+E2 - 57CO L 1919.47 4 5/2- 22 FS 3 - 57CO E 0.45 312.1 65.7 - 57CO2 E EAV=138.6 $CK=0.8873 16$CL=0.0964 13$CM=0.0155 5 - 57CO G 161.86 3 0.0202 24M1 0.0115 3 - 57CO2 G KC=0.0104 3$LC=0.00102 3 - 57CO G 541.9 1 0.0036 5[E2] 0.00116 3 - 57CO2 G KC=0.00105 3$LC=1.02E-4 3 - 57CO G 696.0 4 0.0009 6[E2] 0.00056 2 - 57CO2 G KC=0.00050 2$LC=4.8E-5 1 - 57CO G 1919.62 1412.5 5M1+E2 - 57CO L 2133.06 5 5/2- 0.34 PS 6 - 57CO E 0.039 58.1 - 57CO2 E CK=0.8871 16$CL=0.0965 13$CM=0.0156 5 - 57CO G 755.30 100.0054 6M1+E2 0.00033 1 - 57CO2 G KC=2.95E-4 9$LC=2.82E-5 8 - 57CO G 2133.04 5 0.033 5M1 - 57CO L 2730.83 143/2,5/2- 91 FS 12 - 57CO E 0.020 37.7 - 57CO2 E CK=0.8857 16$CL=0.0977 13$CM=0.0158 5 - 57CO G 2730.76 140.020 3 - 57CO L 2804.18 6 (3/2,5/2)- 37 FS 7 - 57CO E 0.308 236.4 - 57CO2 E CK=0.8853 16$CL=0.0980 13$CM=0.0158 5 - 57CO G 906.98 5 0.075 14 - 57CO G 1046.68 140.132 3 - 57CO G 2804.08 150.102 17E2 - 57CO L 3108.14 4 (3/2)- 54 FS 7 - 57CO E 0.063 46.1 - 57CO2 E CK=0.8790 17$CL=0.1033 14$CM=0.0168 5 - 57CO G 304.1 1 0.0020 6 - 57CO G 1350.52 6 0.002 1 - 57CO G 1603.28 6 0.0039 6 - 57CO G 1730.45 6 0.055 3 - 57CO L 3177.31 5 5/2,7/2- 152 FS 35 - 57CO E 0.025 56 - 57CO2 E CK=0.8706 19$CL=0.1103 15$CM=0.0181 6 - 57CO G 1279.99 6 0.0096 7 - 57CO G 3177.27 5 0.015 4 - + 57CO 57NI EC DECAY (1.496 D) + 57CO T Auger electrons and X ray energies and emission intensities: + 57CO T {U Energy (keV)} {U Intensity} {U Line} + 57CO T + 57CO T 6.91538 5.84 12 XKA2 + 57CO T 6.9304 11.42 23 XKA1 + 57CO T + 57CO T 7.6495 |] 2.37 6 XKB1 + 57CO T 7.706 |] XKB5II + 57CO T + 57CO T + 57CO T 0.678-0.87 0.56 4 XL (total) + 57CO T 0.678 XLL + 57CO T -0.87 XLG + 57CO T + 57CO T 5.81-6.1 |] KLL AUGER + 57CO T 6.67-6.86 |] 31.0 6 KLX AUGER + 57CO T 7.5-7.58 |] KXY AUGER + 57CO T 0.564-0.653 76.7 12 L AUGER + 57NI P 0.0 3/2- 1.496 D 23 3264.2 26 + 57CO N 1.0 1.0 1 1.0 + 57CO L 0 7/2- 271.80 D 5 + 57CO L 1223.79 7 9/2- 54 FS 5 + 57CO G 1223.8 3 0.076 13M1+E2 1.20E-4 4 + 57CO2 G KC=0.000108 3$LC=1.03E-5 3 + 57CO L 1377.65 3 3/2- 19 PS 4 + 57CO E 35.3 529.3 55.6 + 57CO2 E EAV=368.3 $CK=0.4026 7$CL=0.0436 6$CM=0.00703 23 + 57CO G 1377.62 4 81.2 6E2 1.05E-4 3 + 57CO2 G KC=0.000095 3$LC=9.1E-6 3 + 57CO L 1504.82 3 1/2- 0.21 NS 2 + 57CO E 6.8 39.6 46.1 + 57CO2 E EAV=313.4 $CK=0.5195 9$CL=0.0563 8$CM=0.00907 29 + 57CO G 127.164 3 16.0 5M1+E2 0.0215 6 + 57CO2 G KC=0.0193 6$LC=0.00191 6 + 57CO L 1757.596 243/2- 0.27 PS 2 + 57CO E 0.85 65.2 36.2 + 57CO2 E EAV=206.1 $CK=0.7627 14$CL=0.0828 11$CM=0.01332 43 + 57CO G 379.940 200.072 6[M1] 0.00143 4 + 57CO2 G KC=0.00129 4$LC=0.000124 4 + 57CO G 1757.55 3 6.1 4E2 + 57CO L 1897.24 6 7/2- 110 FS 10 + 57CO G 673.44 4 0.0483 15M1+E2 0.00040 1 + 57CO2 G KC=0.00036 1$LC=0.000034 1 + 57CO G 1897.0 5 0.0252 25M1+E2 + 57CO L 1919.47 4 5/2- 22 FS 3 + 57CO E 0.45 312.1 65.7 + 57CO2 E EAV=138.6 $CK=0.8555 15$CL=0.0929 13$CM=0.01494 48 + 57CO G 161.86 3 0.0202 24M1 0.0115 3 + 57CO2 G KC=0.0104 3$LC=0.00102 3 + 57CO G 541.9 1 0.0036 5[E2] 0.00116 3 + 57CO2 G KC=0.00105 3$LC=0.000102 3 + 57CO G 696.0 4 0.0009 6[E2] 0.00056 2 + 57CO2 G KC=0.00050 2$LC=0.000048 1 + 57CO G 1919.62 1412.5 5M1+E2 + 57CO L 2133.06 5 5/2- 0.34 PS 6 + 57CO E 0.039 58.1 + 57CO2 E CK=0.8871 16$CL=0.0965 13$CM=0.0156 5 + 57CO G 755.30 100.0054 6M1+E2 0.00033 1 + 57CO2 G KC=0.000295 9$LC=2.82E-5 8 + 57CO G 2133.04 5 0.033 5M1 + 57CO L 2730.83 143/2,5/2- 91 FS 12 + 57CO E 0.020 37.7 + 57CO2 E CK=0.8857 16$CL=0.0977 13$CM=0.0158 5 + 57CO G 2730.76 140.020 3 + 57CO L 2804.18 6 (3/2,5/2)- 37 FS 7 + 57CO E 0.308 236.4 + 57CO2 E CK=0.8853 16$CL=0.0980 13$CM=0.0158 5 + 57CO G 906.98 5 0.075 14 + 57CO G 1046.68 140.132 3 + 57CO G 2804.08 150.102 17E2 + 57CO L 3108.14 4 (3/2)- 54 FS 7 + 57CO E 0.063 46.1 + 57CO2 E CK=0.8790 17$CL=0.1033 14$CM=0.0168 5 + 57CO G 304.1 1 0.0020 6 + 57CO G 1350.52 6 0.002 1 + 57CO G 1603.28 6 0.0039 6 + 57CO G 1730.45 6 0.055 3 + 57CO L 3177.31 5 5/2,7/2- 152 FS 35 + 57CO E 0.025 56 + 57CO2 E CK=0.8706 19$CL=0.1103 15$CM=0.0181 6 + 57CO G 1279.99 6 0.0096 7 + 57CO G 3177.27 5 0.015 4 + diff --git a/HEN_HOUSE/spectra/lnhb/Ni-59.txt b/HEN_HOUSE/spectra/lnhb/Ni-59.txt index e9e49a196..1cfada548 100644 --- a/HEN_HOUSE/spectra/lnhb/Ni-59.txt +++ b/HEN_HOUSE/spectra/lnhb/Ni-59.txt @@ -1,33 +1,33 @@ - 59CO 59NI EC DECAY (76E3 Y) - 59CO H TYP=Full$AUT=M. Galan$CUT=30-NOV-2009$ - 59CO C Evaluation history: Type=Full;Author=M. Galan;Cutoff date=30-NOV-2009 - 59CO C References: 1981MUZQ, 1949PO04, 1951BR05, 1951WI14, 1956SA32, 1976BE02, - 59CO2C 1981NI08, 1988BO30, 1991NO08, 1991JA02, 1994RU19, 1996SC06, 2002BA19, - 59CO3C 2004RA23, 2007WA00, 2009AUZZ - 59CO T Auger electrons and X ray energies and emission intensities: - 59CO T {U Energy (keV)} {U Intensity} {U Line} - 59CO T - 59CO T 6.91538 10.24 12 XKA2 - 59CO T 6.9304 20.02 22 XKA1 - 59CO T - 59CO T 7.6495 |] 4.15 6 XKB1 - 59CO T 7.706 |] XKB5II - 59CO T - 59CO T - 59CO T 0.6793-0.9251 0.98 7 XL (total) - 59CO T 0.6793 0.0400 13 XLL - 59CO T 0.7787-0.7795 0.508 15 XLA - 59CO T 0.6949 0.0247 9 XLC - 59CO T 0.78642-0.9251 0.346 12 XLB - 59CO T 0.80198-0.80198 0.00210 23 XLG - 59CO T - 59CO T 5.806-6.099 |] KLL AUGER - 59CO T 6.667-6.927 |] 54.3 4 KLX AUGER - 59CO T 7.508-7.703 |] KXY AUGER - 59CO T 0.68-0.83 134.5 8 L AUGER - 59NI P 0.0 3/2- 76E3 Y 5 1072.76 19 - 59CO N 1.0 1.0 1 1.0 - 59CO L 0 0 7/2- STABLE - 59CO E 0.0000371299.99996 111.89 2 - 59CO2 E EAV=24.81 9$CK=0.8870 16$CL=0.0966 13$CM=0.0156 5$CN=0.0008 2 - + 59CO 59NI EC DECAY (76E3 Y) + 59CO H TYP=FUL$AUT=M.GALAN$CUT=30-NOV-2009$ + 59CO C References:1981MUZQ, 1949PO04, 1951BR05, 1951WI14, 1956SA32, 1976BE02, + 59CO2C 1981NI08, 1988BO30, 1991NO08, 1991JA02, 1994RU19, 1996SC06, 2002BA19, + 59CO3C 2004Ra23, 2007WA00, 2009AUZZ + 59CO T Auger electrons and X ray energies and emission intensities: + 59CO T {U Energy (keV)} {U Intensity} {U Line} + 59CO T + 59CO T 6.91538 10.24 12 XKA2 + 59CO T 6.9304 20.02 22 XKA1 + 59CO T + 59CO T 7.6495 |] 4.15 6 XKB1 + 59CO T 7.706 |] XKB5II + 59CO T + 59CO T + 59CO T 0.6793-0.9251 0.98 7 XL (total) + 59CO T 0.6793 0.0400 13 XLL + 59CO T 0.7787-0.7795 0.508 15 XLA + 59CO T 0.6949 0.0247 9 XLC + 59CO T 0.78642-0.9251 0.346 12 XLB + 59CO T 0.80198-0.80198 0.00210 23 XLG + 59CO T + 59CO T 5.806-6.099 |] KLL AUGER + 59CO T 6.667-6.927 |] 54.3 4 KLX AUGER + 59CO T 7.508-7.703 |] KXY AUGER + 59CO T 0.68-0.83 134.5 8 L AUGER + 59NI P 0.0 3/2- 76E3 Y 5 1072.76 19 + 59CO N 1.0 1.0 1 1.0 + 59CO L 0 7/2- STABLE + 59CO E 0.0000371299.99996 111.89 2 + 59CO2 E EAV=24.81 9$CK=0.8870 16$CL=0.0966 13$CM=0.0156 5 + 59CO3 E CN=0.0008 2 + diff --git a/HEN_HOUSE/spectra/lnhb/Ni-63.txt b/HEN_HOUSE/spectra/lnhb/Ni-63.txt index 5838f38fb..0cccabc9e 100644 --- a/HEN_HOUSE/spectra/lnhb/Ni-63.txt +++ b/HEN_HOUSE/spectra/lnhb/Ni-63.txt @@ -1,26 +1,26 @@ - 63CU 63NI B- DECAY (98.7 Y) - 63CU H TYP=Full$AUT=K.B. Lee$CUT=28-SEP-2009$ - 63CU C Evaluation history: Type=Full;Author=K.B. Lee;Cutoff date=28-SEP-2009 - 63CU C References: 1966Hs01, 1971Ba89, 1987He14, 1992Ka29, 1993Oh02, 1996Co25, - 63CU2C 1996Sc33, 1999Ho09, 2003Au03 - 63CU T Auger electrons and X ray energies and emission intensities: - 63CU T {U Energy (keV)} {U Intensity} {U Line} - 63CU T - 63CU T 8.02792 XKA2 - 63CU T 8.04787 XKA1 - 63CU T - 63CU T 8.90539 |] XKB1 - 63CU T 8.9771 |] XKB5II - 63CU T - 63CU T - 63CU T - 63CU T 6.731-7.059 |] KLL AUGER - 63CU T 7.746-8.064 |] KLX AUGER - 63CU T 8.739-8.982 |] KXY AUGER - 63CU T 0.03-1.09 L AUGER - 63NI P 0.0 1/2- 98.7 Y 24 66.980 15 - 63CU N 1.0 1.0 1 1.0 - 63CU L 0 3/2- STABLE - 63CU B 66.980 15100 6.7 - 63CUS B EAV=17.434 4 - + 63CU 63NI B- DECAY (98.7 Y) + 63CU H TYP=FUL$AUT=K.B.LEE$CUT=28-SEP-2009$ + 63CU C References:1950Wi**, 1951Br**, 1956Mc**, 1957Pr**, 1962Ho**, 1966Hs01, + 63CU2C 1971Ba89, 1987He14, 1992Ka29, 1993Oh02, 1996Co25, 1996Sc33, 1999Ho09, + 63CU3C 2003Au03 + 63CU T Auger electrons and X ray energies and emission intensities: + 63CU T {U Energy (keV)} {U Intensity} {U Line} + 63CU T + 63CU T 8.02792 XKA2 + 63CU T 8.04787 XKA1 + 63CU T + 63CU T 8.90539 |] XKB1 + 63CU T 8.9771 |] XKB5II + 63CU T + 63CU T + 63CU T + 63CU T 6.731-7.059 |] KLL AUGER + 63CU T 7.746-8.064 |] KLX AUGER + 63CU T 8.739-8.982 |] KXY AUGER + 63CU T 0.03-1.09 L AUGER + 63NI P 0.0 1/2- 98.7 Y 24 66.980 15 + 63CU N 1.0 1.0 1 1.0 + 63CU L 0 3/2- STABLE + 63CU B 66.980 15100 6.7 + 63CUS B EAV=17.434 4 + diff --git a/HEN_HOUSE/spectra/lnhb/Np-236.txt b/HEN_HOUSE/spectra/lnhb/Np-236.txt index 8a16f1cf7..6a0732ebd 100644 --- a/HEN_HOUSE/spectra/lnhb/Np-236.txt +++ b/HEN_HOUSE/spectra/lnhb/Np-236.txt @@ -1,195 +1,150 @@ -236U 236NP EC DECAY (1.55E5 Y) -236U H TYP=update$AUT=mmbe$CUT= -- $ -236U 2 H TYP=update$AUT=mmbe$CUT= -- $ -236U 3 H TYP=update$AUT=mmbe$CUT= -- $ -236U 4 H TYP=update$AUT=mmbe$CUT= -- $ -236U 5 H TYP=update$AUT=mmbe$CUT= -- $ -236U 6 H TYP=Full$AUT=V.P. Chechev$CUT=27-JUN-2006$ -236U 7 H TYP=Full$AUT=V.P. Chechev$CUT=27-JUN-2006$ -236U 8 H TYP=Full$AUT=V.P. Chechev$CUT=27-JUN-2006$ -236U 9 H TYP=Full$AUT=V.P. Chechev$CUT=27-JUN-2006$ -236U A H TYP=Full$AUT=V.P. Chechev$CUT=27-JUN-2006$ -236U C Evaluation history: Type=update;Author=mmbe;Cutoff date= -- -236U 2C Type=update;Author=mmbe;Cutoff date= -- -236U 3C Type=update;Author=mmbe;Cutoff date= -- -236U 4C Type=update;Author=mmbe;Cutoff date= -- -236U 5C Type=update;Author=mmbe;Cutoff date= -- -236U 6C Type=Full;Author=V.P. Chechev;Cutoff date=27-JUN-2006 -236U 7C Type=Full;Author=V.P. Chechev;Cutoff date=27-JUN-2006 -236U 8C Type=Full;Author=V.P. Chechev;Cutoff date=27-JUN-2006 -236U 9C Type=Full;Author=V.P. Chechev;Cutoff date=27-JUN-2006 -236U AC Type=Full;Author=V.P. Chechev;Cutoff date=27-JUN-2006 -236U C References: 1969Le05, 1971Dr11, 1971GuZY, 1972Dzh., 1972El21, 1972En06, -236U 2C 1975Dr05, 1975OtZX, 1976GuZN, 1977Po05, 1980Sc26, 1981Li30, 1983Ah02, -236U 3C 1991Sc08, 1996FiZX, 2003Au03, 2006Br20, 2008Ki07 -236U T Auger electrons and X ray energies and emission intensities: -236U T {U Energy (keV)} {U Intensity} {U Line} -236U T -236U T 94.666 20.2 3 XKA2 -236U T 98.44 32.4 5 XKA1 -236U T -236U T 110.421 |] XKB3 -236U T 111.298 |] 11.69 25 XKB1 -236U T 111.964 |] XKB5II -236U T -236U T 114.407 |] XKB2 -236U T 115.012 |] 4.00 11 XKB4 -236U T 115.377 |] XKO23 -236U T -236U T 11.619-20.714 117.5 30 XL (total) -236U T 11.619 2.63 7 XLL -236U T 13.438-13.615 42.3 11 XLA -236U T 15.399 1.24 4 XLC -236U T 15.727-18.206 57.7 13 XLB -236U T 19.507-20.714 13.6 3 XLG -236U T -236U T 71.78-80.95 |] KLL AUGER -236U T 88.15-98.43 |] 2.1 3 KLX AUGER -236U T 104.51-115.59 |] KXY AUGER -236U T 6.07-21.68 128.8 19 L AUGER -236NP P 0.0 6- 1.55E5 Y 8 930 50 -236U N 1.139E0 1.139E0 0.878 1.139E0 -236U L 0 0+ 23.43E6 Y 6 -236U L 45.244 2 2+ 234 PS 6 -236U G 45.244 2 0.149 3E2 589 12 -236U 2 G LC=429 9$MC=118.6 24 -236U L 149.477 6 4+ 124 PS 7 -236U E 4.4 15.9 1U -236U 2 E CK=0.74 $CL=0.19 $CM=0.07 $CN=0.0001 -236U G 104.234 6 7.32 13E2 10.99 22 -236U 2 G LC=8.00 16$MC=2.22 5 -236U L 309.785 7 6+ 58 PS 3 -236U E 87.8 4314.1 -236U 2 E CK=0.726 8$CL=0.201 5$CM=0.073 2$CN=0.0001 -236U G 160.307 3 31.8 15E2 1.76 4 -236U 2 G KC=0.208 4$LC=1.13 2$MC=0.313 7 -236U L 687.59 4 1- 3.78 NS 9 -236U G 538.1 1 0.0007 E3 0.143 3 -236U 2 G KC=0.0622 13$LC=0.0587 12$MC=0.0160 3 -236U G 642.34 5 0.059 E1+(M2+E3) 0.15 2 -236U 2 G KC=0.112 10$LC=$MC= -236U G 687.60 5 0.016 E1+(M2+E3) 0.31 2 -236U 2 G KC=0.219 12$LC=0.068 6$MC= -236U L 744.18 7 3- 0.1 NS -236U G 56.6 5 0.0004 (E2) 199 10 -236U 2 G LC=145 7$MC=40.1 19 -236U G 594.5 3 0.008 -236U L 848.1 8 5- -236U E 0.096 14.6 -236U 2 E CL=0.6 $CM=0.4 -236U G 104.1 100.008 E2 11.1 6 -236U 2 G LC=8.1 4$MC=2.23 11 - -232PA 236NP A DECAY (1.55E5 Y) -232PA H TYP=update$AUT=mmbe$CUT= -- $ -232PA2 H TYP=update$AUT=mmbe$CUT= -- $ -232PA3 H TYP=update$AUT=mmbe$CUT= -- $ -232PA4 H TYP=update$AUT=mmbe$CUT= -- $ -232PA5 H TYP=update$AUT=mmbe$CUT= -- $ -232PA6 H TYP=Full$AUT=V.P. Chechev$CUT=27-JUN-2006$ -232PA7 H TYP=Full$AUT=V.P. Chechev$CUT=27-JUN-2006$ -232PA8 H TYP=Full$AUT=V.P. Chechev$CUT=27-JUN-2006$ -232PA9 H TYP=Full$AUT=V.P. Chechev$CUT=27-JUN-2006$ -232PAA H TYP=Full$AUT=V.P. Chechev$CUT=27-JUN-2006$ -232PA C Evaluation history: Type=update;Author=mmbe;Cutoff date= -- -232PA2C Type=update;Author=mmbe;Cutoff date= -- -232PA3C Type=update;Author=mmbe;Cutoff date= -- -232PA4C Type=update;Author=mmbe;Cutoff date= -- -232PA5C Type=update;Author=mmbe;Cutoff date= -- -232PA6C Type=Full;Author=V.P. Chechev;Cutoff date=27-JUN-2006 -232PA7C Type=Full;Author=V.P. Chechev;Cutoff date=27-JUN-2006 -232PA8C Type=Full;Author=V.P. Chechev;Cutoff date=27-JUN-2006 -232PA9C Type=Full;Author=V.P. Chechev;Cutoff date=27-JUN-2006 -232PAAC Type=Full;Author=V.P. Chechev;Cutoff date=27-JUN-2006 -232PA C References: 1969Le05, 1971Dr11, 1971GuZY, 1972Dzh., 1972El21, 1972En06, -232PA2C 1975Dr05, 1975OtZX, 1976GuZN, 1977Po05, 1980Sc26, 1981Li30, 1983Ah02, -232PA3C 1991Sc08, 1996FiZX, 2003Au03, 2006Br20, 2008Ki07 -232PA T Auger electrons and X ray energies and emission intensities: -232PA T {U Energy (keV)} {U Intensity} {U Line} -232PA T -232PA T 92.288 XKA2 -232PA T 95.869 XKA1 -232PA T -232PA T 107.595 |] XKB3 -232PA T 108.422 |] XKB1 -232PA T 109.072 |] XKB5II -232PA T -232PA T 111.405 |] XKB2 -232PA T 111.87 |] XKB4 -232PA T 112.38 |] XKO23 -232PA T -232PA T -232PA T 70.081-78.822 |] KLL AUGER -232PA T 85.989-95.858 |] KLX AUGER -232PA T 101.87-112.59 |] KXY AUGER -232PA T 6.011-21.0077 L AUGER -236NP P 0.0 6- 1.55E5 Y 8 5010 50 -232PA N 6.25E2 6.25E2 0.0016 6.25E2 -232PA L 0 - 1.31 D 2 - -236PU 236NP B- DECAY (1.55E5 Y) -236PU H TYP=update$AUT=mmbe$CUT= -- $ -236PU2 H TYP=update$AUT=mmbe$CUT= -- $ -236PU3 H TYP=update$AUT=mmbe$CUT= -- $ -236PU4 H TYP=update$AUT=mmbe$CUT= -- $ -236PU5 H TYP=update$AUT=mmbe$CUT= -- $ -236PU6 H TYP=Full$AUT=V.P. Chechev$CUT=27-JUN-2006$ -236PU7 H TYP=Full$AUT=V.P. Chechev$CUT=27-JUN-2006$ -236PU8 H TYP=Full$AUT=V.P. Chechev$CUT=27-JUN-2006$ -236PU9 H TYP=Full$AUT=V.P. Chechev$CUT=27-JUN-2006$ -236PUA H TYP=Full$AUT=V.P. Chechev$CUT=27-JUN-2006$ -236PU C Evaluation history: Type=update;Author=mmbe;Cutoff date= -- -236PU2C Type=update;Author=mmbe;Cutoff date= -- -236PU3C Type=update;Author=mmbe;Cutoff date= -- -236PU4C Type=update;Author=mmbe;Cutoff date= -- -236PU5C Type=update;Author=mmbe;Cutoff date= -- -236PU6C Type=Full;Author=V.P. Chechev;Cutoff date=27-JUN-2006 -236PU7C Type=Full;Author=V.P. Chechev;Cutoff date=27-JUN-2006 -236PU8C Type=Full;Author=V.P. Chechev;Cutoff date=27-JUN-2006 -236PU9C Type=Full;Author=V.P. Chechev;Cutoff date=27-JUN-2006 -236PUAC Type=Full;Author=V.P. Chechev;Cutoff date=27-JUN-2006 -236PU C References: 1969Le05, 1971Dr11, 1971GuZY, 1972Dzh., 1972El21, 1972En06, -236PU2C 1975Dr05, 1975OtZX, 1976GuZN, 1977Po05, 1980Sc26, 1981Li30, 1983Ah02, -236PU3C 1991Sc08, 1996FiZX, 2003Au03, 2006Br20, 2008Ki07 -236PU T Auger electrons and X ray energies and emission intensities: -236PU T {U Energy (keV)} {U Intensity} {U Line} -236PU T -236PU T 99.525 0.212 23 XKA2 -236PU T 103.734 0.33 4 XKA1 -236PU T -236PU T 116.244 |] XKB3 -236PU T 117.228 |] 0.123 14 XKB1 -236PU T 117.918 |] XKB5II -236PU T -236PU T 120.54 |] XKB2 -236PU T 120.969 |] 0.043 5 XKB4 -236PU T 121.543 |] XKO23 -236PU T -236PU T 12.1246-21.984 12.1 4 XL (total) -236PU T 12.1246 0.276 11 XLL -236PU T 14.083-14.279 4.30 16 XLA -236PU T 16.334 0.133 7 XLC -236PU T 16.499-18.543 5.92 24 XLB -236PU T 20.708-21.984 1.42 6 XLG -236PU T -236PU T 75.26-85.36 |] KLL AUGER -236PU T 92.61-103.73 |] 0.021 4 KLX AUGER -236PU T 109.93-121.78 |] KXY AUGER -236PU T 6.19-23.1 10.7 3 L AUGER -236NP P 0.0 6- 1.55E5 Y 8 480 50 -236PU N 8.333E0 8.333E0 0.12 8.333E0 -236PU L 0 0+ 2.87 Y 1 -236PU L 44.63 102+ -236PU G 44.63 100.0161 9E2 741 15 -236PU2 G LC=538 11$MC=150 3 -236PU L 147.45 104+ -236PU B 333 501.6 16 1U -236PUS B EAV=92 16 -236PU G 102.82 2 0.81 6E2 13.87 28 -236PU2 G LC=10.06 20$MC=2.82 6 -236PU L 305.80 116+ -236PU B 174 5011.8 12 14.5 -236PUS B EAV=46 15 -236PU G 158.35 3 3.8 4E2 2.14 4 -236PU2 G KC=0.193 4$LC=1.41 3$MC=0.394 8 - +236U 236NP EC DECAY (1.55E5 Y) +236U H TYP=UPD$AUT=M.-M.BE$CUT=08-MAR-2007$ +236U 2 H TYP=FUL$AUT=V.P.CHECHEV$CUT=27-JUN-2006$ +236U C References:1969Le05, 1971Dr11, 1971GuZY, 1972Dz09, 1972El21, 1972En06, +236U 2C 1975Dr05, 1975OtZX, 1976GuZN, 1977Po05, 1980Sc26, 1981Li30, 1983Ah02, +236U 3C 1991Sc08, 1996FiZX, 2003Au03, 2006Br20, 2008Ki07 +236U T Auger electrons and X ray energies and emission intensities: +236U T {U Energy (keV)} {U Intensity} {U Line} +236U T +236U T 94.666 20.2 3 XKA2 +236U T 98.44 32.4 5 XKA1 +236U T +236U T 110.421 |] XKB3 +236U T 111.298 |] 11.69 25 XKB1 +236U T 111.964 |] XKB5II +236U T +236U T 114.407 |] XKB2 +236U T 115.012 |] 4.00 11 XKB4 +236U T 115.377 |] XKO23 +236U T +236U T 11.619-20.714 117.5 30 XL (total) +236U T 11.619 2.63 7 XLL +236U T 13.438-13.615 42.3 11 XLA +236U T 15.399 1.24 4 XLC +236U T 15.727-18.206 57.7 13 XLB +236U T 19.507-20.714 13.6 3 XLG +236U T +236U T 71.78-80.95 |] KLL AUGER +236U T 88.15-98.43 |] 2.1 3 KLX AUGER +236U T 104.51-115.59 |] KXY AUGER +236U T 6.07-21.68 128.8 19 L AUGER +236NP P 0.0 6- 1.55E5 Y 8 930 50 +236U N 1.139E0 1.139E0 0.878 1.139E0 +236U L 0 0+ 23.43E6 Y 6 +236U L 45.244 2 2+ 234 PS 6 +236U G 45.244 2 0.149 3E2 589 12 +236U 2 G LC=429 9$MC=118.6 24$NC=32.1 6 +236U 3 G OC=7.36 15 +236U L 149.477 6 4+ 124 PS 7 +236U E 4.4 15.9 1U +236U 2 E CK=0.74 $CL=0.19 $CM=0.07 $CN=0.0001 +236U G 104.234 6 7.32 13E2 10.99 22 +236U 2 G LC=8.00 16$MC=2.22 5$NC=0.603 12 +236U 3 G OC=0.1385 30 +236U L 309.785 7 6+ 58 PS 3 +236U E 87.8 4314.1 +236U 2 E CK=0.726 8$CL=0.201 5$CM=0.073 2$CN=0.0001 +236U G 160.307 3 31.8 15E2 1.76 4 +236U 2 G KC=0.208 4$LC=1.13 2$MC=0.313 7$NC=0.0850 17 +236U 3 G OC=0.0196 4 +236U L 687.59 4 1- 3.78 NS 9 +236U G 538.1 1 0.0007 E3 0.143 3 +236U 2 G KC=0.0622 13$LC=0.0587 12$MC=0.0160 3$NC=0.00437 9 +236U 3 G OC=0.001024 15 +236U G 642.34 5 0.059 E1+(M2+E3) 0.15 2 +236U 2 G KC=0.112 10$LC=0.031 3$MC=0.0080 8 +236U G 687.60 5 0.016 E1+(M2+E3) 0.31 2 +236U 2 G KC=0.219 12$LC=0.068 6$MC=0.018 2 +236U L 744.18 7 3- 0.1 NS +236U G 56.6 5 0.0004 (E2) 199 10 +236U 2 G LC=145 7$MC=40.1 19$NC=10.9 5 +236U 3 G OC=2.50 12 +236U G 594.5 3 0.008 +236U L 848.1 8 5- +236U E 0.096 14.6 +236U 2 E CL=0.6 $CM=0.4 +236U G 104.1 100.008 E2 11.1 6 +236U 2 G LC=8.1 4$MC=2.23 11$NC=0.61 3 +236U 3 G OC=0.139 7 + +232PA 236NP A DECAY (1.55E5 Y) +232PA H TYP=UPD$AUT=M.-M.BE$CUT=08-MAR-2007$ +232PA2 H TYP=FUL$AUT=V.P.CHECHEV$CUT=27-JUN-2006$ +232PA C References:1969Le05, 1971Dr11, 1971GuZY, 1972Dz09, 1972El21, 1972En06, +232PA2C 1975Dr05, 1975OtZX, 1976GuZN, 1977Po05, 1980Sc26, 1981Li30, 1983Ah02, +232PA3C 1991Sc08, 1996FiZX, 2003Au03, 2006Br20, 2008Ki07 +232PA T Auger electrons and X ray energies and emission intensities: +232PA T {U Energy (keV)} {U Intensity} {U Line} +232PA T +232PA T 92.288 XKA2 +232PA T 95.869 XKA1 +232PA T +232PA T 107.595 |] XKB3 +232PA T 108.422 |] XKB1 +232PA T 109.072 |] XKB5II +232PA T +232PA T 111.405 |] XKB2 +232PA T 111.87 |] XKB4 +232PA T 112.38 |] XKO23 +232PA T +232PA T +232PA T 70.081-78.822 |] KLL AUGER +232PA T 85.989-95.858 |] KLX AUGER +232PA T 101.87-112.59 |] KXY AUGER +232PA T 6.011-21.0077 L AUGER +236NP P 0.0 6- 1.55E5 Y 8 5010 50 +232PA N 6.25E2 6.25E2 0.0016 +232PA L 0 1.31 D 2 + +236PU 236NP B- DECAY (1.55E5 Y) +236PU H TYP=UPD$AUT=M.-M.BE$CUT=08-MAR-2007$ +236PU2 H TYP=FUL$AUT=V.P.CHECHEV$CUT=27-JUN-2006$ +236PU C References:1969Le05, 1971Dr11, 1971GuZY, 1972Dz09, 1972El21, 1972En06, +236PU2C 1975Dr05, 1975OtZX, 1976GuZN, 1977Po05, 1980Sc26, 1981Li30, 1983Ah02, +236PU3C 1991Sc08, 1996FiZX, 2003Au03, 2006Br20, 2008Ki07 +236PU T Auger electrons and X ray energies and emission intensities: +236PU T {U Energy (keV)} {U Intensity} {U Line} +236PU T +236PU T 99.525 0.212 23 XKA2 +236PU T 103.734 0.33 4 XKA1 +236PU T +236PU T 116.244 |] XKB3 +236PU T 117.228 |] 0.123 14 XKB1 +236PU T 117.918 |] XKB5II +236PU T +236PU T 120.54 |] XKB2 +236PU T 120.969 |] 0.043 5 XKB4 +236PU T 121.543 |] XKO23 +236PU T +236PU T 12.1246-21.984 12.1 4 XL (total) +236PU T 12.1246 0.276 11 XLL +236PU T 14.083-14.279 4.30 16 XLA +236PU T 16.334 0.133 7 XLC +236PU T 16.499-18.543 5.92 24 XLB +236PU T 20.708-21.984 1.42 6 XLG +236PU T +236PU T 75.26-85.36 |] KLL AUGER +236PU T 92.61-103.73 |] 0.021 4 KLX AUGER +236PU T 109.93-121.78 |] KXY AUGER +236PU T 6.19-23.1 10.7 3 L AUGER +236NP P 0.0 6- 1.55E5 Y 8 480 50 +236PU N 8.333E0 8.333E0 0.12 8.333E0 +236PU L 0 0+ 2.87 Y 1 +236PU L 44.63 102+ +236PU G 44.63 100.0161 9E2 741 15 +236PU2 G LC=538 11$MC=150 3$NC=41.2 8 +236PU3 G OC=9.69 20 +236PU L 147.45 104+ +236PU B 333 501.6 16 1U +236PUS B EAV=92 16 +236PU G 102.82 2 0.81 6E2 13.87 28 +236PU2 G LC=10.06 20$MC=2.82 6$NC=0.775 16 +236PU3 G OC=0.183 4 +236PU L 305.80 116+ +236PU B 174 5011.8 12 14.5 +236PUS B EAV=46 15 +236PU G 158.35 3 3.8 4E2 2.14 4 +236PU2 G KC=0.193 4$LC=1.41 3$MC=0.394 8$NC=0.1084 22 +236PU3 G OC=0.0256 5 + diff --git a/HEN_HOUSE/spectra/lnhb/Np-236m.txt b/HEN_HOUSE/spectra/lnhb/Np-236m.txt index bff6d325e..cd25f5b72 100644 --- a/HEN_HOUSE/spectra/lnhb/Np-236m.txt +++ b/HEN_HOUSE/spectra/lnhb/Np-236m.txt @@ -1,97 +1,97 @@ -236U 236NP EC DECAY (22.5 H) -236U H TYP=Full$AUT=V.P.Chechev$CUT=18-JUN-2006$ -236U C Evaluation history: Type=Full;Author=V.P.Chechev;Cutoff date=18-JUN-2006 -236U C References: 1949Ja01, 1956Gr11, 1959Gi58, 1967Be65, 1969Le05, 1971GuZY, -236U 2C 1971Dr11, 1975Dr05, 1975OtZX, 1976GuZN, 1977Po05, 1977La19, 1984Gr33, -236U 3C 1987Lag., 1991Sc08, 1996Sc06, 1996FiZX, 2003Au03 -236U T Auger electrons and X ray energies and emission intensities: -236U T {U Energy (keV)} {U Intensity} {U Line} -236U T -236U T 94.666 9.9 10 XKA2 -236U T 98.44 15.8 15 XKA1 -236U T -236U T 110.421 |] XKB3 -236U T 111.298 |] 5.7 6 XKB1 -236U T 111.964 |] XKB5II -236U T -236U T 114.407 |] XKB2 -236U T 115.012 |] 1.95 15 XKB4 -236U T 115.377 |] XKO23 -236U T -236U T 11.618-20.714 21.3 18 XL (total) -236U T 11.618 0.57 5 XLL -236U T 13.438-13.614 9.1 8 XLA -236U T 15.399 0.166 17 XLC -236U T 15.726-18.206 9.4 6 XLB -236U T 19.507-20.714 2.07 15 XLG -236U T -236U T 71.776-80.954 |] KLL AUGER -236U T 88.153-98.429 |] 1.03 17 KLX AUGER -236U T 104.51-115.59 |] KXY AUGER -236U T 6.4-21.6 21.7 15 L AUGER -236NP P 60 501+ 22.5 H 4 930 50 -236U N 1.887E0 1.887E0 0.53 1.887E0 -236U L 0 0+ 23.43E6 Y 6 -236U E 43.1 327.1 -236U 2 E CK=0.753 1$CL=0.182 1$CM=0.0646 1 -236U L 45.242 3 2+ 234 PS -236U E 8.3 307.8 -236U 2 E CK=0.751 1$CL=0.184 1$CM=0.0652 1 -236U G 45.242 3 0.016 5E2 589 12 -236U 2 G LC=429 9$MC=118.6 24 -236U L 149.476 154+ 124 PS -236U G 104.234 6 0.00119 14E2 11.0 2 -236U 2 G LC=8.00 16$MC=2.22 5 -236U L 309.783 6+ 58 PS -236U L 687.60 5 1- 3.8 NS -236U E 1.64 97.3 -236U 2 E CK=0.621 10$CL=0.274 7$CM=0.105 3 -236U G 538.11 100.0125 15E3 0.143 3 -236U 2 G KC=0.0622 13$LC=0.0587 12$MC=0.0160 4 -236U G 642.35 9 1.08 6E1+(M2+E3) 0.15 2 -236U 2 G KC=0.112 10$LC=0.031 3$MC=0.0080 8 -236U G 687.60 5 0.292 21E1 0.31 2 -236U 2 G KC=0.219 12$LC=0.068 6$MC=0.018 2 - -236PU 236NP B- DECAY (22.5 H) -236PU H TYP=Full$AUT=V.P.Chechev$CUT=18-JUN-2006$ -236PU C Evaluation history: Type=Full;Author=V.P.Chechev;Cutoff date=18-JUN-2006 -236PU C References: 1949Ja01, 1956Gr11, 1959Gi58, 1967Be65, 1969Le05, 1971GuZY, -236PU2C 1971Dr11, 1975Dr05, 1975OtZX, 1976GuZN, 1977Po05, 1977La19, 1984Gr33, -236PU3C 1987Lag., 1991Sc08, 1996Sc06, 1996FiZX, 2003Au03 -236PU T Auger electrons and X ray energies and emission intensities: -236PU T {U Energy (keV)} {U Intensity} {U Line} -236PU T -236PU T 99.525 XKA2 -236PU T 103.734 XKA1 -236PU T -236PU T 116.244 |] XKB3 -236PU T 117.228 |] XKB1 -236PU T 117.918 |] XKB5II -236PU T -236PU T 120.54 |] XKB2 -236PU T 120.969 |] XKB4 -236PU T 121.543 |] XKO23 -236PU T -236PU T 12.124-21.984 4.2 16 XL (total) -236PU T 12.124 0.10 4 XLL -236PU T 14.083-14.279 1.5 6 XLA -236PU T 16.334 0.046 17 XLC -236PU T 16.498-19.331 2.1 8 XLB -236PU T 20.708-21.984 0.49 18 XLG -236PU T -236PU T 75.263-85.357 |] KLL AUGER -236PU T 92.607-103.729 |] KLX AUGER -236PU T 109.93-121.78 |] KXY AUGER -236PU T 6.19-22.99 3.8 14 L AUGER -236NP P 60 501+ 22.5 H 4 480 50 -236PU N 2.128E0 2.128E0 0.47 2.128E0 -236PU L 0 0+ 2.87 Y 1 -236PU B 537 8 36 4 6.8 -236PUS B EAV=158 3 -236PU L 44.63 102+ -236PU B 492 8 11 4 7.2 -236PUS B EAV=143 3 -236PU G 44.63 100.015 5E2 743 15 -236PU2 G LC=540 11$MC=151 3 - +236U 236NP EC DECAY (22.5 H) +236U H TYP=FUL$AUT=V.P.CHECHEV$CUT=18-JUN-2006$ +236U C References:1949Ja01, 1956Gr11, 1959Gi58, 1967Be65, 1969Le05, 1971GuZY, +236U 2C 1971Dr11, 1972Dz09, 1975Dr05, 1975OtZX, 1976GuZN, 1977Po05, 1977La19, +236U 3C 1984Gr33, 1987La**, 1991Sc08, 1996Sc06, 1996FiZX, 1999Sc**, 2003Au03, +236U 4C 2004BeZQ +236U T Auger electrons and X ray energies and emission intensities: +236U T {U Energy (keV)} {U Intensity} {U Line} +236U T +236U T 94.666 9.9 10 XKA2 +236U T 98.44 15.8 15 XKA1 +236U T +236U T 110.421 |] XKB3 +236U T 111.298 |] 5.7 6 XKB1 +236U T 111.964 |] XKB5II +236U T +236U T 114.407 |] XKB2 +236U T 115.012 |] 1.95 15 XKB4 +236U T 115.377 |] XKO23 +236U T +236U T 11.618-20.714 21.3 18 XL (total) +236U T 11.618 0.57 5 XLL +236U T 13.438-13.614 9.1 8 XLA +236U T 15.399 0.166 17 XLC +236U T 15.726-18.206 9.4 6 XLB +236U T 19.507-20.714 2.07 15 XLG +236U T +236U T 71.776-80.954 |] KLL AUGER +236U T 88.153-98.429 |] 1.03 17 KLX AUGER +236U T 104.51-115.59 |] KXY AUGER +236U T 6.4-21.6 21.7 15 L AUGER +236NP P 60 501+ 22.5 H 4 930 50 +236U N 1.887E0 1.887E0 0.53 1.887E0 +236U L 0 0+ 23.43E6 Y 6 +236U E 43.1 327.1 +236U 2 E CK=0.753 1$CL=0.182 1$CM=0.0646 1 +236U L 45.242 3 2+ 234 PS +236U E 8.3 307.8 +236U 2 E CK=0.751 1$CL=0.184 1$CM=0.0652 1 +236U G 45.242 3 0.016 5E2 589 12 +236U 2 G LC=429 9$MC=118.6 24 +236U L 149.476 154+ 124 PS +236U G 104.234 6 0.00119 14E2 11.0 2 +236U 2 G LC=8.00 16$MC=2.22 5 +236U L 309.783 6+ 58 PS +236U L 687.60 5 1- 3.8 NS +236U E 1.64 97.3 +236U 2 E CK=0.621 10$CL=0.274 7$CM=0.105 3 +236U G 538.11 100.0125 15E3 0.143 3 +236U 2 G KC=0.0622 13$LC=0.0587 12$MC=0.0160 4 +236U G 642.35 9 1.08 6E1+(M2+E3) 0.15 2 +236U 2 G KC=0.112 10$LC=0.031 3$MC=0.0080 8 +236U G 687.60 5 0.292 21E1 0.31 2 +236U 2 G KC=0.219 12$LC=0.068 6$MC=0.018 2 + +236PU 236NP B- DECAY (22.5 H) +236PU H TYP=FUL$AUT=V.P.CHECHEV$CUT=18-JUN-2006$ +236PU C References:1949Ja01, 1956Gr11, 1959Gi58, 1967Be65, 1969Le05, 1971GuZY, +236PU2C 1971Dr11, 1972Dz09, 1975Dr05, 1975OtZX, 1976GuZN, 1977Po05, 1977La19, +236PU3C 1984Gr33, 1987La**, 1991Sc08, 1996Sc06, 1996FiZX, 1999Sc**, 2003Au03, +236PU4C 2004BeZQ +236PU T Auger electrons and X ray energies and emission intensities: +236PU T {U Energy (keV)} {U Intensity} {U Line} +236PU T +236PU T 99.525 XKA2 +236PU T 103.734 XKA1 +236PU T +236PU T 116.244 |] XKB3 +236PU T 117.228 |] XKB1 +236PU T 117.918 |] XKB5II +236PU T +236PU T 120.54 |] XKB2 +236PU T 120.969 |] XKB4 +236PU T 121.543 |] XKO23 +236PU T +236PU T 12.124-21.984 4.2 16 XL (total) +236PU T 12.124 0.10 4 XLL +236PU T 14.083-14.279 1.5 6 XLA +236PU T 16.334 0.046 17 XLC +236PU T 16.498-19.331 2.1 8 XLB +236PU T 20.708-21.984 0.49 18 XLG +236PU T +236PU T 75.263-85.357 |] KLL AUGER +236PU T 92.607-103.729 |] KLX AUGER +236PU T 109.93-121.78 |] KXY AUGER +236PU T 6.19-22.99 3.8 14 L AUGER +236NP P 60 501+ 22.5 H 4 480 50 +236PU N 2.128E0 2.128E0 0.47 2.128E0 +236PU L 0 0+ 2.87 Y 1 +236PU B 537 8 36 4 6.8 +236PUS B EAV=158 3 +236PU L 44.63 102+ +236PU B 492 8 11 4 7.2 +236PUS B EAV=143 3 +236PU G 44.63 100.015 5E2 743 15 +236PU2 G LC=540 11$MC=151 3 + diff --git a/HEN_HOUSE/spectra/lnhb/Np-237.txt b/HEN_HOUSE/spectra/lnhb/Np-237.txt index 9ad2fb4ee..50eb2b8c9 100644 --- a/HEN_HOUSE/spectra/lnhb/Np-237.txt +++ b/HEN_HOUSE/spectra/lnhb/Np-237.txt @@ -1,199 +1,238 @@ -233PA 237NP A DECAY (2.144E6 Y) -233PA H TYP=Full$AUT=V.Chechev$CUT=31-OCT-2007$ -233PA2 H TYP=Full$AUT=V.Chechev$CUT=31-OCT-2007$ -233PA3 H TYP=Full$AUT=V.Chechev$CUT=31-OCT-2007$ -233PA C Evaluation history: Type=Full;Author=V.Chechev;Cutoff date=31-OCT-2007 -233PA2C Type=Full;Author=V.Chechev;Cutoff date=31-OCT-2007 -233PA3C Type=Full;Author=V.Chechev;Cutoff date=31-OCT-2007 -233PA C References: 1949Ma01, 1960Br12, 1960As02, 1961Dr04, 1961Ba44, 1968Br12, -233PA2C 1968Br25, 1969HoXY, 1969Br12, 1971Cl03, 1974HeYW, 1976Sk01, 1979Go12, -233PA3C 1981Ba68, 1984BaYS, 1984Va27, 1986LoZT, 1988Io05, 1988Wo01, 1990Lo04, -233PA4C 1990Bo44, 1992Lo03, 1992Gr16, 2000Sc04, 2000Si02, 2000Wo01, 2002Lu01, -233PA5C 2002Wo03, 2002Ba85, 2003Au03, 2004Sh07, 2005Si15, 2006Ch39, 2008De10, -233PA6C 2008Ki07 -233PA T Auger electrons and X ray energies and emission intensities: -233PA T {U Energy (keV)} {U Intensity} {U Line} -233PA T -233PA T 92.288 1.813 20 XKA2 -233PA T 95.869 2.906 20 XKA1 -233PA T -233PA T 107.595 |] XKB3 -233PA T 108.422 |] 1.06 10 XKB1 -233PA T 109.072 |] XKB5II -233PA T -233PA T 111.405 |] XKB2 -233PA T 111.87 |] 0.380 9 XKB4 -233PA T 112.38 |] XKO23 -233PA T -233PA T 11.368-20.113 59.7 32 XL (total) -233PA T 11.368 1.32 8 XLL -233PA T 13.122-13.289 24.0 24 XLA -233PA T 14.949 0.54 4 XLC -233PA T 15.358-17.666 28 2 XLB -233PA T 18.94-20.113 5.8 4 XLG -233PA T -233PA T 70.08-78.82 |] KLL AUGER -233PA T 85.99-95.86 |] 0.167 24 KLX AUGER -233PA T 101.87-112.59 |] KXY AUGER -233PA T 5.9-21.01 47.1 20 L AUGER -237NP P 0.0 5/2+ 2.144E6 Y 7 4958.3 12 -233PA N 1.0 1.0 1 1.0 -233PA G 21.5 0.352 13 -233PA G 27.7 0.84 7 -233PA G 29.6 -233PA G 288.3 0.0162 5 -233PA L 0 3/2- 26.98 D 2 -233PA A 4872.7 142.41 3 387 -233PA L 6.654 251/2- -233PA A 4866.4 140.51 3 1570 -233PA A 4550.5 220.011 3 84000 -233PA G 6.65 5 (M1) 3080 90 -233PA2 G MC=2280 60 -233PA L 57.101 147/2- -233PA A 4816.8 102.430 17156 -233PA G 57.104 200.381 21E2 176 4 -233PA2 G LC=128 3$MC=35.3 7 -233PA L 70.510 255/2- -233PA A 4803.5 102.02 2 152 -233PA G 63.9 1 0.0107 4(E2) 102.3 20 -233PA2 G LC=74.7 15$MC=20.6 4 -233PA G 70.49 100.0107 4[M1+E2] 1 1 38 26 -233PA2 G LC=28 19$MC=8 5 -233PA L 86.469 9 5/2+ 35.8 NS 4 -233PA A 4788.0 9 47.64 6 5 -233PA G 29.374 2014.3 6E1 3.07 6 -233PA2 G LC=2.29 5$MC=0.585 12 -233PA G 86.477 1012.26 12E1 1.43 8 -233PA2 G LC=1.13 5$MC=0.22 6 -233PA L 94.645 163/2+ -233PA G 8.22 5 0.12 5 -233PA G 87.99 3 0.143 3[E1] 0.169 4 -233PA2 G LC=0.128 3$MC=0.0312 6 -233PA G 94.64 5 0.66 7E1 0.140 3 -233PA2 G LC=0.1054 21$MC=0.0257 5 -233PA L 103.636 207/2+ -233PA A 4771.4 8 23.0 3 7.8 -233PA G 9 -233PA G 17.40 5 M1+E2 -233PA G 46.53 6 0.109 4[E1] 0.914 18 -233PA2 G LC=0.687 14$MC=0.171 4 -233PA L 109.04 5 9/2+ -233PA A 4766.5 8 9.5 3 17.9 -233PA G 5.18 0.220 5 -233PA G 22.6 -233PA L 133.2 10(11/2+)+ -233PA A 4741.3 200.019 5932 -233PA G 24.14 10 -233PA L 163.34 10(11/2-)- -233PA A 4712.3 201.174 1351 -233PA G 54.4 1 -233PA G 106.15 250.0509 29[E2] 9.28 19 -233PA2 G LC=6.78 14$MC=1.87 4 -233PA L 169.152 201/2+ -233PA A 4708.3 200 56 -233PA G 74.54 100.012 3[M1] 9.84 20 -233PA2 G LC=7.42 15$MC=1.79 4 -233PA G 162.41 8 0.033 1[E1] 0.158 3 -233PA2 G KC=0.1232 25$LC=0.0260 5$MC=0.00630 13 -233PA G 169.156 200.0672 3[E1] 0.143 3 -233PA2 G KC=0.1120 22$LC=0.0235 5$MC=0.00568 11 -233PA L 179.1 4 (9/2-)- -233PA A 4698.2 8 0.535 1099 -233PA G 109.1 1 -233PA L 201.594 193/2+ -233PA A 4676.4 0.38 2 -233PA G 32.46 -233PA G 115.40 350.0026 8[M1+E2] 10 4 -233PA2 G KC=5 6$LC=3.3 13$MC=0.9 4 -233PA G 131.101 250.084 5E1 0.262 5 -233PA2 G KC=0.202 4$LC=0.0451 9$MC=0.01094 22 -233PA G 194.95 3 0.174 20E1 0.1024 21 -233PA2 G KC=0.0806 16$LC=0.0164 4$MC=0.00397 8 -233PA G 201.62 5 0.0392 9E1 0.0946 19 -233PA2 G KC=0.0746 15$LC=0.0151 3$MC=0.00365 7 -233PA L 212.342 185/2+ -233PA A 4665.0 9 3.46 3 8.9 -233PA G 10.7 -233PA G 43.2 -233PA G 108.7 0.071 3M1+E2 0.22 3.5 6 -233PA2 G LC=2.7 5$MC=0.65 13 -233PA G 117.702 200.171 4M1+E2 0.30 9 12.2 6 -233PA2 G KC=9.3 5$LC=2.16 12$MC=0.53 4 -233PA G 141.74 10 -233PA G 155.239 200.088 8E1 0.176 4 -233PA2 G KC=0.1368 27$LC=0.0292 6$MC=0.00708 14 -233PA G 212.29 5 0.17 1E1 0.0839 17 -233PA2 G KC=0.0663 13$LC=0.0133 3$MC=0.00321 7 -233PA L 237.895 135/2+ -233PA A 4640 1 6.43 3 3.14 -233PA G 36.32 2 0.005 1M1+E2 0.11 5 99 20 -233PA2 G LC=74 15$MC=18 4 -233PA G 134.285 200.069 5[M1+E2] 0.4 2 8.0 11 -233PA2 G KC=6.1 10$LC=1.5 3$MC=0.37 8 -233PA G 143.249 200.42 4M1+E2 0.29 3 6.94 14 -233PA2 G KC=5.38 12$LC=1.171 24$MC=0.287 6 -233PA G 151.414 200.234 2M1+E2 0.70 15 4.9 6 -233PA2 G KC=3.4 5$LC=1.09 4$MC=0.277 14 -233PA G 180.81 100.016 1[E1] 0.1223 25 -233PA2 G KC=0.0960 19$LC=0.0199 4$MC=0.0048 1 -233PA G 237.86 2 0.0573 6[E1] 0.0645 13 -233PA2 G KC=0.0511 10$LC=0.01010 15$MC=0.00243 5 -233PA L 257.1 4 5/2- -233PA A 4619.7 210.032 8 46000 -233PA G 153.37 -233PA G 162.41 -233PA G 170.59 -233PA G 186.86 -233PA G 199.95 -233PA G 250.58 -233PA G 257.09 -233PA L 279.71 3 (7/2+)+ -233PA A 4599.1 180.373 9 27 -233PA G 170.59 6 0.020 4[M1+E2] 0.4 2 4.0 5 -233PA2 G KC=3.1 5$LC=0.70 7$MC=0.17 1 -233PA G 176.12 6 0.015 3[M1+E2] 0.4 2 3.7 5 -233PA2 G KC=2.8 4$LC=0.63 7$MC=0.16 1 -233PA G 193.26 5 0.044 1[M1+E2] 0.4 2 2.8 4 -233PA2 G KC=2.2 3$LC=0.48 5$MC=0.12 1 -233PA G 209.19 5 0.0150 15[E1] 0.0868 17 -233PA2 G KC=0.0686 14$LC=0.0138 3$MC=0.00333 7 -233PA G 222.6 2 0.002 2 -233PA L 300.48 3 7/2++ -233PA A 4578.6 140.393 2319.1 -233PA G 62.59 100.006 2[M1+E2] 1 1 60 50 -233PA2 G LC=50 40$MC=13 10 -233PA G 191.46 5 0.019 1[M1+E2] 0.4 2 2.9 4 -233PA2 G KC=2.2 3$LC=0.49 5$MC=0.12 1 -233PA G 196.86 5 0.0210 1[M1+E2] 0.4 2 2.7 3 -233PA2 G KC=2.1 3$LC=0.45 5$MC=0.11 1 -233PA G 214.01 5 0.037 2[M1+E2] 0.4 2 2.1 3 -233PA2 G KC=1.64 23$LC=0.35 1$MC=0.09 1 -233PA G 229.94 5 0.014 3[E1] 0.0697 14 -233PA2 G KC=0.0552 11$LC=0.0110 2$MC=0.00264 5 -233PA L 303.59 7 (9/2+)+ -233PA A 4573 3 0.048 23139 -233PA G 139.9 1 0.0046 4[E1] 0.225 5 -233PA2 G KC=0.174 3$LC=0.0381 8$MC=0.00925 19 -233PA G 194.67 200.033 1 -233PA G 199.95 6 0.0053 8[M1] 2.85 6 -233PA2 G KC=2.27 5$LC=0.436 9$MC=0.105 2 -233PA L 306.05 10(7/2+)+ -233PA G 48.96 10 -233PA G 219.8 -233PA G 248.95 100.005 1[M1+E2] 0.4 2 1.37 16 -233PA2 G KC=1.08 15$LC=0.22 1$MC=0.055 6 -233PA L 365.93 8 9/2+ -233PA A 4515.1 190.038 4 65 -233PA G 153.37 100.007 2[E2] 1.96 4 -233PA2 G KC=0.226 5$LC=1.267 3$MC=0.349 7 -233PA G 186.86 350.003 3[E1] 0.1131 23 -233PA2 G KC=0.0889 19$LC=0.0183 4$MC=0.00442 9 -233PA G 202.9 2 0.0048 19[E1] 0.0932 19 -233PA2 G KC=0.074 5$LC=0.0149 3$MC=0.00360 7 -233PA G 257.09 200.02 1[M1] 1.41 3 -233PA2 G KC=1.125 23$LC=0.215 4$MC=0.0518 11 -233PA G 262.44 200.0048 2[M1] 1.33 3 -233PA2 G KC=1.063 21$LC=0.203 4$MC=0.0489 10 -233PA G 279.65 200.0108 4[E2] 0.222 5 -233PA2 G KC=0.0847 17$LC=0.100 2$MC=0.0272 6 - +233PA 237NP A DECAY (2.144E6 Y) +233PA H TYP=FUL$AUT=V.P.CHECHEV$CUT=31-OCT-2007$ +233PA C References:1949Ma01, 1960Br12, 1960As02, 1961Dr04, 1961Ba44, 1968Br12, +233PA2C 1968Br25, 1969HoXY, 1969Br12, 1971Cl03, 1974HeYW, 1976Sk01, 1979Go12, +233PA3C 1981Ba68, 1984BaYS, 1984Va27, 1986LoZT, 1988Io05, 1988Wo01, 1990Lo04, +233PA4C 1990Bo44, 1992Lo03, 1992Gr16, 2000Sc04, 2000Sc**, 2000Si02, 2000Wo01, +233PA5C 2002Lu01, 2002Wo03, 2002Ba85, 2003Au03, 2004Sh07, 2005Si15, 2006Ch39, +233PA6C 2008De10, 2008Ki07 +233PA T Auger electrons and X ray energies and emission intensities: +233PA T {U Energy (keV)} {U Intensity} {U Line} +233PA T +233PA T 92.288 1.813 20 XKA2 +233PA T 95.869 2.906 20 XKA1 +233PA T +233PA T 107.595 |] XKB3 +233PA T 108.422 |] 1.06 10 XKB1 +233PA T 109.072 |] XKB5II +233PA T +233PA T 111.405 |] XKB2 +233PA T 111.87 |] 0.380 9 XKB4 +233PA T 112.38 |] XKO23 +233PA T +233PA T 11.368-20.113 59.7 32 XL (total) +233PA T 11.368 1.32 8 XLL +233PA T 13.122-13.289 24.0 24 XLA +233PA T 14.949 0.54 4 XLC +233PA T 15.358-17.666 28 2 XLB +233PA T 18.94-20.113 5.8 4 XLG +233PA T +233PA T 70.08-78.82 |] KLL AUGER +233PA T 85.99-95.86 |] 0.167 24 KLX AUGER +233PA T 101.87-112.59 |] KXY AUGER +233PA T 5.9-21.01 47.1 20 L AUGER +237NP P 0.0 5/2+ 2.144E6 Y 7 4958.3 12 +233PA N 1.0 1.0 1 +233PA G 21.5 0.352 13 +233PA G 27.7 0.84 7 +233PA G 29.6 +233PA G 288.3 0.0162 5 +233PA L 0 3/2- 26.98 D 2 +233PA A 4872.7 142.41 3387 +233PA L 6.654 251/2- +233PA A 4866.4 140.51 31570 +233PA A 4550.5 220.011 384000 +233PA G 6.65 5 (M1) 3080 90 +233PA2 G MC=2280 60$NC=618 17 +233PA3 G OC=148 4 +233PA L 57.101 147/2- +233PA A 4816.8 102.430 17156 +233PA G 57.104 200.381 21E2 176 4 +233PA2 G LC=128 3$MC=35.3 7$NC=9.52 19 +233PA3 G OC=2.15 3 +233PA L 70.510 255/2- +233PA A 4803.5 102.02 2152 +233PA G 63.9 1 0.0107 4(E2) 102.3 20 +233PA2 G LC=74.7 15$MC=20.6 4$NC=5.55 11 +233PA3 G OC=1.252 25 +233PA G 70.49 100.0107 4[M1+E2] 1 1 38 26 +233PA2 G LC=28 19$MC=8 5$NC=2.0 15 +233PA3 G OC=0.5 4 +233PA L 86.469 9 5/2+ 35.8 NS 4 +233PA A 4788.0 9 47.64 65 +233PA G 29.374 2014.3 6E1 3.07 6 +233PA2 G LC=2.29 5$MC=0.585 12$NC=0.1527 31 +233PA3 G OC=0.0331 7 +233PA G 86.477 1012.26 12E1 1.43 8 +233PA2 G LC=1.13 5$MC=0.22 6$NC=0.08 1 +233PA L 94.645 163/2+ +233PA G 8.22 5 0.12 5 +233PA G 87.99 3 0.143 3[E1] 0.169 4 +233PA2 G LC=0.128 3$MC=0.0312 6$NC=0.00824 17 +233PA3 G OC=0.00189 4 +233PA G 94.64 5 0.66 7E1 0.140 3 +233PA2 G LC=0.1054 21$MC=0.0257 5$NC=0.00680 14 +233PA3 G OC=0.001561 31 +233PA L 103.636 207/2+ +233PA A 4771.4 8 23.0 37.8 +233PA G 9 +233PA G 17.40 5 M1+E2 +233PA G 46.53 6 0.109 4[E1] 0.914 18 +233PA2 G LC=0.687 14$MC=0.171 4$NC=0.0448 9 +233PA3 G OC=0.0100 2 +233PA L 109.04 5 9/2+ +233PA A 4766.5 8 9.5 317.9 +233PA G 5.18 0.220 5 +233PA G 22.6 +233PA L 133.2 10(11/2+) +233PA A 4741.3 200.019 5932 +233PA G 24.14 10 +233PA L 163.34 10(11/2-) +233PA A 4712.3 201.174 1351 +233PA G 54.4 1 +233PA G 106.15 250.0509 29[E2] 9.28 19 +233PA2 G LC=6.78 14$MC=1.87 4$NC=0.505 10 +233PA3 G OC=0.1141 23 +233PA L 169.152 201/2+ +233PA A 4708.3 201E-9 56 +233PA G 74.54 100.012 3[M1] 9.84 20 +233PA2 G LC=7.42 15$MC=1.79 4$NC=0.481 10 +233PA3 G OC=0.1153 23 +233PA G 162.41 8 0.033 1[E1] 0.158 3 +233PA2 G KC=0.1232 25$LC=0.0260 5$MC=0.00630 13$NC=0.001673 30 +233PA3 G OC=0.000389 8 +233PA G 169.156 200.0672 3[E1] 0.143 3 +233PA2 G KC=0.1120 22$LC=0.0235 5$MC=0.00568 11$NC=0.001508 30 +233PA3 G OC=0.000352 7 +233PA L 179.1 4 (9/2-) +233PA A 4698.2 8 0.535 1099 +233PA G 109.1 1 +233PA L 201.594 193/2+ +233PA A 4676.4 0.38 2 +233PA G 32.46 +233PA G 115.40 350.0026 8[M1+E2] 10 4 +233PA2 G KC=5 6$LC=3.3 13$MC=0.9 4$NC=0.24 11 +233PA3 G OC=0.055 23 +233PA G 131.101 250.084 5E1 0.262 5 +233PA2 G KC=0.202 4$LC=0.0451 9$MC=0.01094 22$NC=0.00290 6 +233PA3 G OC=0.000672 14 +233PA G 194.95 3 0.174 20E1 0.1024 21 +233PA2 G KC=0.0806 16$LC=0.0164 4$MC=0.00397 8$NC=0.001055 21 +233PA3 G OC=0.000247 5 +233PA G 201.62 5 0.0392 9E1 0.0946 19 +233PA2 G KC=0.0746 15$LC=0.0151 3$MC=0.00365 7$NC=0.00097 2 +233PA3 G OC=0.000227 5 +233PA L 212.342 185/2+ +233PA A 4665.0 9 3.46 38.9 +233PA G 10.7 +233PA G 43.2 +233PA G 108.7 0.071 3M1+E2 0.22 3.5 6 +233PA2 G LC=2.7 5$MC=0.65 13$NC=0.17 4 +233PA3 G OC=0.042 8 +233PA G 117.702 200.171 4M1+E2 0.30 9 12.2 6 +233PA2 G KC=9.3 5$LC=2.16 12$MC=0.53 4$NC=0.143 10 +233PA3 G OC=0.0340 21 +233PA G 141.74 10 +233PA G 155.239 200.088 8E1 0.176 4 +233PA2 G KC=0.1368 27$LC=0.0292 6$MC=0.00708 14$NC=0.00188 4 +233PA3 G OC=0.000437 9 +233PA G 212.29 5 0.17 1E1 0.0839 17 +233PA2 G KC=0.0663 13$LC=0.0133 3$MC=0.00321 7$NC=0.000854 17 +233PA3 G OC=0.000200 4 +233PA L 237.895 135/2+ +233PA A 4640 1 6.43 33.14 +233PA G 36.32 2 0.005 1M1+E2 0.11 5 99 20 +233PA2 G LC=74 15$MC=18 4$NC=4.9 11 +233PA3 G OC=1.17 24 +233PA G 134.285 200.069 5[M1+E2] 0.4 2 8.0 11 +233PA2 G KC=6.1 10$LC=1.5 3$MC=0.37 8$NC=0.099 11 +233PA3 G OC=0.0235 23 +233PA G 143.249 200.42 4M1+E2 0.29 3 6.94 14 +233PA2 G KC=5.38 12$LC=1.171 24$MC=0.287 6$NC=0.0770 14 +233PA3 G OC=0.0183 4 +233PA G 151.414 200.234 2M1+E2 0.70 15 4.9 6 +233PA2 G KC=3.4 5$LC=1.09 4$MC=0.277 14$NC=0.074 4 +233PA3 G OC=0.0174 8 +233PA G 180.81 100.016 1[E1] 0.1223 25 +233PA2 G KC=0.0960 19$LC=0.0199 4$MC=0.0048 1$NC=0.00128 26 +233PA3 G OC=0.000297 6 +233PA G 237.86 2 0.0573 6[E1] 0.0645 13 +233PA2 G KC=0.0511 10$LC=0.01010 15$MC=0.00243 5$NC=0.000646 13 +233PA3 G OC=1.516E-4 30 +233PA L 257.1 4 5/2- +233PA A 4619.7 210.032 846000 +233PA G 153.37 +233PA G 162.41 +233PA G 170.59 +233PA G 186.86 +233PA G 199.95 +233PA G 250.58 +233PA G 257.09 +233PA L 279.71 3 (7/2+) +233PA A 4599.1 180.373 927 +233PA G 170.59 6 0.020 4[M1+E2] 0.4 2 4.0 5 +233PA2 G KC=3.1 5$LC=0.70 7$MC=0.17 1$NC=0.0462 20 +233PA3 G OC=0.0110 4 +233PA G 176.12 6 0.015 3[M1+E2] 0.4 2 3.7 5 +233PA2 G KC=2.8 4$LC=0.63 7$MC=0.16 1$NC=0.0418 15 +233PA3 G OC=0.0099 3 +233PA G 193.26 5 0.044 1[M1+E2] 0.4 2 2.8 4 +233PA2 G KC=2.2 3$LC=0.48 5$MC=0.12 1$NC=0.0314 6 +233PA3 G OC=0.00748 12 +233PA G 209.19 5 0.0150 15[E1] 0.0868 17 +233PA2 G KC=0.0686 14$LC=0.0138 3$MC=0.00333 7$NC=0.000886 20 +233PA3 G OC=0.000207 4 +233PA G 222.6 2 0.002 2 +233PA L 300.48 3 7/2+ +233PA A 4578.6 140.393 2319.1 +233PA G 62.59 100.006 2[M1+E2] 1 1 60 50 +233PA2 G LC=50 40$MC=13 10$NC=3 3 +233PA3 G OC=0.8 6 +233PA G 191.46 5 0.019 1[M1+E2] 0.4 2 2.9 4 +233PA2 G KC=2.2 3$LC=0.49 5$MC=0.12 1$NC=0.0323 7 +233PA3 G OC=0.00770 13 +233PA G 196.86 5 0.0210 1[M1+E2] 0.4 2 2.7 3 +233PA2 G KC=2.1 3$LC=0.45 5$MC=0.11 1$NC=0.0297 5 +233PA3 G OC=0.00707 10 +233PA G 214.01 5 0.037 2[M1+E2] 0.4 2 2.1 3 +233PA2 G KC=1.64 23$LC=0.35 1$MC=0.09 1$NC=0.0231 4 +233PA3 G OC=0.00550 11 +233PA G 229.94 5 0.014 3[E1] 0.0697 14 +233PA2 G KC=0.0552 11$LC=0.0110 2$MC=0.00264 5$NC=0.000702 14 +233PA3 G OC=1.646E-4 30 +233PA L 303.59 7 (9/2+) +233PA A 4573 3 0.048 23139 +233PA G 139.9 1 0.0046 4[E1] 0.225 5 +233PA2 G KC=0.174 3$LC=0.0381 8$MC=0.00925 19$NC=0.00245 5 +233PA3 G OC=0.000569 12 +233PA G 194.67 200.033 1 +233PA G 199.95 6 0.0053 8[M1] 2.85 6 +233PA2 G KC=2.27 5$LC=0.436 9$MC=0.105 2$NC=0.0282 6 +233PA3 G OC=0.00676 14 +233PA L 306.05 10(7/2+) +233PA G 48.96 10 +233PA G 219.8 +233PA G 248.95 100.005 1[M1+E2] 0.4 2 1.37 16 +233PA2 G KC=1.08 15$LC=0.22 1$MC=0.055 6$NC=0.0147 5 +233PA3 G OC=0.00351 14 +233PA L 365.93 8 9/2+ +233PA A 4515.1 190.038 465 +233PA G 153.37 100.007 2[E2] 1.96 4 +233PA2 G KC=0.226 5$LC=1.267 3$MC=0.349 7$NC=0.0942 19 +233PA3 G OC=0.0214 4 +233PA G 186.86 350.003 3[E1] 0.1131 23 +233PA2 G KC=0.0889 19$LC=0.0183 4$MC=0.00442 9$NC=0.00117 24 +233PA3 G OC=0.000274 6 +233PA G 202.9 2 0.0048 19[E1] 0.0932 19 +233PA2 G KC=0.074 5$LC=0.0149 3$MC=0.00360 7$NC=0.000955 20 +233PA3 G OC=0.000223 5 +233PA G 257.09 200.02 1[M1] 1.41 3 +233PA2 G KC=1.125 23$LC=0.215 4$MC=0.0518 11$NC=0.01389 28 +233PA3 G OC=0.00333 7 +233PA G 262.44 200.0048 2[M1] 1.33 3 +233PA2 G KC=1.063 21$LC=0.203 4$MC=0.0489 10$NC=0.01312 26 +233PA3 G OC=0.00315 6 +233PA G 279.65 200.0108 4[E2] 0.222 5 +233PA2 G KC=0.0847 17$LC=0.100 2$MC=0.0272 6$NC=0.00733 15 +233PA3 G OC=0.001676 30 + diff --git a/HEN_HOUSE/spectra/lnhb/Np-238.txt b/HEN_HOUSE/spectra/lnhb/Np-238.txt index 0686fac57..24cffae74 100644 --- a/HEN_HOUSE/spectra/lnhb/Np-238.txt +++ b/HEN_HOUSE/spectra/lnhb/Np-238.txt @@ -1,146 +1,145 @@ -238PU 238NP B- DECAY (2.102 D) -238PU H TYP=Full$AUT=V.P Chechev. N.K. Kuzmenko$CUT=30-NOV-2006$ -238PU C Evaluation history: Type=Full;Author=V.P Chechev. N.K. Kuzmenko;Cutoff date=30-NOV-2006 -238PU C References: 1950Fr53, 1952Du12, 1956Ba95, 1956Sm18, 1958Al92, 1960As10, -238PU2C 1960Al29, 1965Ak02, 1966Qa01, 1970Be57, 1972Wi22, 1981Le15, 1990Ch35, -238PU3C 1996Sc06, 2002Ch52, 2003Au03, 2006Re09 -238PU T Auger electrons and X ray energies and emission intensities: -238PU T {U Energy (keV)} {U Intensity} {U Line} -238PU T -238PU T 99.525 0.210 8 XKA2 -238PU T 103.734 0.332 12 XKA1 -238PU T -238PU T 116.244 |] XKB3 -238PU T 117.228 |] 0.122 5 XKB1 -238PU T 117.918 |] XKB5II -238PU T -238PU T 120.54 |] XKB2 -238PU T 120.969 |] 0.042 2 XKB4 -238PU T 121.543 |] XKO23 -238PU T -238PU T 12.125-21.984 32.4 14 XL (total) -238PU T 12.125 0.797 25 XLL -238PU T 14.083-14.279 12.5 4 XLA -238PU T 16.334 0.338 12 XLC -238PU T 16.499-19.331 15.4 5 XLB -238PU T 20.708-21.984 3.58 10 XLG -238PU T -238PU T 75.26-85.36 |] KLL AUGER -238PU T 92.607-103.729 |] 0.021 8 KLX AUGER -238PU T 109.93-121.78 |] KXY AUGER -238PU T 6.19-22.99 29.7 14 L AUGER -238NP P 0.0 2+ 2.102 D 5 1291.5 4 -238PU N 1.0 1.0 1 1.0 -238PU G 103.74 2 0.312 3 -238PU G 116.27 8 0.04 -238PU G 117.27 8 0.074 -238PU G 120.5 0.02 -238PU G 121.70 8 0.010 1 -238PU G 220.87 110.0030 5(M2) 11.4 20 -238PU G 885 0.040 5 -238PU L 0 0+ 87.74 Y 3 -238PU L 44.08 2 2+ 177 PS 5 -238PU B 1247.4 4 41.0 25 8.38 -238PUS B EAV=412.2 2 -238PU G 44.07 2 0.1024 21E2 788 16 -238PU2 G LC=572 12$MC=160 3 -238PU L 145.95 2 4+ -238PU G 101.88 2 0.252 8E2 14.5 3 -238PU2 G LC=10.5 2$MC=2.94 6 -238PU L 303.38 6 6+ -238PU G 157.42 5 0.001 [E2] 2.19 4 -238PU2 G KC=0.193 4$LC=1.45 3$MC=0.405 8 -238PU L 605.14 4 1- -238PU B 686.4 4 0.103 3 10.08 1 -238PUS B EAV=208.4 2 -238PU G 561.14 5 0.106 2E1 0.0115 2 -238PU2 G KC=0.00929 19$LC=0.00169 4$MC=4.07E-4 8 -238PU G 605.16 5 0.077 2E1 0.0100 2 -238PU2 G KC=0.00806 16$LC=0.00146 3$MC=3.50E-4 7 -238PU L 661.40 6 3- -238PU B 630.1 4 0.036 3 10.44 1 -238PUS B EAV=189.2 2 -238PU G 515.51 7 0.0378 11E1+M2 0.114 17 0.022 4 -238PU2 G KC=0.017 3$LC=0.0037 7$MC=0.00092 17 -238PU G 617.39 5 0.0593 E1+M2 0.077 17 0.0120 14 -238PU2 G KC=0.0095 11$LC=0.00185 22$MC=0.00045 5 -238PU L 763.24 115- -238PU G 459.8 2 0.0023 15 -238PU G 617.4 0.008 -238PU L 941.46 8 0+ -238PU G 336.36 150.0002 1[E1] 0.0324 7 -238PU2 G KC=0.0257 5$LC=0.00503 10$MC=0.00122 3 -238PU G 897.34 100.0073 10(E2) 0.0152 3 -238PU2 G KC=0.0111 2$LC=0.00308 6$MC=0.00078 2 -238PU G 941.5 3 -238PU L 962.78 2 1- -238PU B 328.7 4 1.25 1 7.95 1 -238PUS B EAV=91.8 2 -238PU G 301.37 7 0.0106 10E2 0.208 4 -238PU2 G KC=0.0766 16$LC=0.096 2$MC=0.0264 5 -238PU G 357.64 7 0.0504 13M1+E2 2.43 20 0.214 16 -238PU2 G KC=0.133 12$LC=0.060 5$MC=0.0158 12 -238PU G 918.70 4 0.529 6E1 0.0047 1 -238PU2 G KC=0.00383 8$LC=0.00066 1$MC=1.58E-4 3 -238PU G 962.76 2 0.645 8E1 0.00433 9 -238PU2 G KC=0.00352 7$LC=0.00061 1$MC=1.45E-4 3 -238PU L 968.2 4 (2)- -238PU B 323.3 6 0.082 6 9.11 -238PUS B EAV=90.1 2 -238PU G 924 0.065 -238PU G 968.9 4 0.015 8[M2] 0.116 3 -238PU2 G KC=0.089 2$LC=0.0200 4$MC=0.0050 1 -238PU L 983.09 7 2+ -238PU B 308.4 4 0.27 3 8.51 -238PUS B EAV=85.6 2 -238PU G 321.75 200.0013 8 -238PU G 378.05 130.0030 5 -238PU G 836.96 7 0.0206 8[E2] 0.0174 4 -238PU2 G KC=0.0125 3$LC=0.00366 8$MC=0.00093 2 -238PU G 938.94 100.0327 25+E2 4.4 4 -238PU2 G KC=3.5 4$LC=0.67 7 -238PU G 983.0 3 0.068 20[E2] 0.0128 3 -238PU2 G KC=0.00947 19$LC=0.00247 5$MC=0.00062 1 -238PU L 985.45 5 2- -238PU B 306.0 4 0.49 1 8.25 -238PUS B EAV=84.9 2 -238PU G 324.02 9 0.0146 8M1+E2 2.8 8 0.26 7 -238PU2 G KC=0.15 6$LC=0.082 7$MC=0.022 2 -238PU G 380.31 100.0111 5[M1] 0.623 9 -238PU2 G KC=0.493 10$LC=0.098 2$MC=0.0237 5 -238PU G 941.40 4 0.504 6[E1+M2] -238PU L 1028.54 2 2+ -238PU B 263.0 4 44.75 19 6.09 -238PUS B EAV=72.0 2 -238PU G 882.63 3 0.803 9(E2) 0.0157 3 -238PU2 G KC=0.0114 2$LC=0.00320 7$MC=0.00081 2 -238PU G 984.45 2 25.18 13M1+E2 0.0125 5 -238PU2 G KC=0.0096 3$LC=0.0022 1$MC=0.0006 1 -238PU G 1028.54 2 18.25 13E2 0.0117 2 -238PU2 G KC=0.00875 18$LC=0.00222 5$MC=0.00055 1 -238PU L 1069.94 2 3+ -238PU B 221.6 4 11.50 7 6.44 -238PUS B EAV=59.9 2 -238PU G 923.99 2 2.604 20(M1+E2) 0.014 1 -238PU2 G KC=0.0099 4 -238PU G 1025.87 2 8.76 6M1+E2 0.0120 5 -238PU2 G KC=0.0091 4$LC=0.0021 1$MC=0.0006 1 -238PU L 1082.56 6 (4)- -238PU G 114.4 4 0.0058 10[E2] 8.47 17 -238PU2 G LC=6.15 12$MC=1.72 14 -238PU G 319.29 110.0083 10M1+E2 1.0 5 0.59 25 -238PU2 G KC=0.43 22$LC=0.118 25$MC=0.030 5 -238PU G 421.1 1 0.021 1[M1] 0.472 7 -238PU2 G KC=0.374 8$LC=0.0737 15$MC=0.0179 4 -238PU G 936.60 5 0.365 5[E1+M2] -0.24 4 0.0112 22 -238PU2 G KC=0.0089 17$LC=0.0018 4$MC=0.00044 10 -238PU L 1202.46 8 (3)- -238PU B 89.0 4 0.51 6 6.57 1 -238PUS B EAV=23.0 2 -238PU G 120.11 5 0.101 5M1(+E2) 3.8 6 -238PU2 G LC=2.8 6$MC=0.69 6 -238PU G 132.5 1 0.0014 8[E1] 0.267 5 -238PU2 G KC=0.203 4$LC=0.048 1$MC=0.0118 2 -238PU G 174.08 5 0.0229 8[E1] 0.142 3 -238PU2 G KC=0.110 2$LC=0.0241 5$MC=0.0059 1 - +238PU 238NP B- DECAY (2.102 D) +238PU H TYP=FUL$AUT=V.P.CHECHEV, N.K.KUZMENKO$CUT=30-NOV-2006$ +238PU C References:1950Fr53, 1952Du12, 1956Ba95, 1956Sm18, 1958Al92, 1960As10, +238PU2C 1960Al29, 1965Ak02, 1966Qa01, 1970Be57, 1972Wi22, 1981Le15, 1990Ch35, +238PU3C 1996Sc06, 1999Sc**, 2002Ch52, 2003Au03, 2006Re09 +238PU T Auger electrons and X ray energies and emission intensities: +238PU T {U Energy (keV)} {U Intensity} {U Line} +238PU T +238PU T 99.525 0.210 8 XKA2 +238PU T 103.734 0.332 12 XKA1 +238PU T +238PU T 116.244 |] XKB3 +238PU T 117.228 |] 0.122 5 XKB1 +238PU T 117.918 |] XKB5II +238PU T +238PU T 120.54 |] XKB2 +238PU T 120.969 |] 0.042 2 XKB4 +238PU T 121.543 |] XKO23 +238PU T +238PU T 12.125-21.984 32.4 14 XL (total) +238PU T 12.125 0.797 25 XLL +238PU T 14.083-14.279 12.5 4 XLA +238PU T 16.334 0.338 12 XLC +238PU T 16.499-19.331 15.4 5 XLB +238PU T 20.708-21.984 3.58 10 XLG +238PU T +238PU T 75.26-85.36 |] KLL AUGER +238PU T 92.607-103.729 |] 0.021 8 KLX AUGER +238PU T 109.93-121.78 |] KXY AUGER +238PU T 6.19-22.99 29.7 14 L AUGER +238NP P 0.0 2+ 2.102 D 5 1291.5 4 +238PU N 1.0 1.0 1 1.0 +238PU G 103.74 2 0.312 3 +238PU G 116.27 8 0.04 +238PU G 117.27 8 0.074 +238PU G 120.5 0.02 +238PU G 121.70 8 0.010 1 +238PU G 220.87 110.0030 5(M2) 11.4 20 +238PU G 885 0.040 5 +238PU L 0 0+ 87.74 Y 3 +238PU L 44.08 2 2+ 177 PS 5 +238PU B 1247.4 4 41.0 25 8.38 +238PUS B EAV=412.2 2 +238PU G 44.07 2 0.1024 21E2 788 16 +238PU2 G LC=572 12$MC=160 3 +238PU L 145.95 2 4+ +238PU G 101.88 2 0.252 8E2 14.5 3 +238PU2 G LC=10.5 2$MC=2.94 6 +238PU L 303.38 6 6+ +238PU G 157.42 5 0.001 [E2] 2.19 4 +238PU2 G KC=0.193 4$LC=1.45 3$MC=0.405 8 +238PU L 605.14 4 1- +238PU B 686.4 4 0.103 3 10.08 1 +238PUS B EAV=208.4 2 +238PU G 561.14 5 0.106 2E1 0.0115 2 +238PU2 G KC=0.00929 19$LC=0.00169 4$MC=0.000407 8 +238PU G 605.16 5 0.077 2E1 0.0100 2 +238PU2 G KC=0.00806 16$LC=0.00146 3$MC=0.000350 7 +238PU L 661.40 6 3- +238PU B 630.1 4 0.036 3 10.44 1 +238PUS B EAV=189.2 2 +238PU G 515.51 7 0.0378 11E1+M2 0.114 17 0.022 4 +238PU2 G KC=0.017 3$LC=0.0037 7$MC=0.00092 17 +238PU G 617.39 5 0.0593 E1+M2 0.077 17 0.0120 14 +238PU2 G KC=0.0095 11$LC=0.00185 22$MC=0.00045 5 +238PU L 763.24 115- +238PU G 459.8 2 0.0023 15 +238PU G 617.4 0.008 +238PU L 941.46 8 0+ +238PU G 336.36 150.0002 1[E1] 0.0324 7 +238PU2 G KC=0.0257 5$LC=0.00503 10$MC=0.00122 3 +238PU G 897.34 100.0073 10(E2) 0.0152 3 +238PU2 G KC=0.0111 2$LC=0.00308 6$MC=0.00078 2 +238PU G 941.5 3 E0 +238PU L 962.78 2 1- +238PU B 328.7 4 1.25 1 7.95 1 +238PUS B EAV=91.8 2 +238PU G 301.37 7 0.0106 10E2 0.208 4 +238PU2 G KC=0.0766 16$LC=0.096 2$MC=0.0264 5 +238PU G 357.64 7 0.0504 13M1+E2 2.43 20 0.214 16 +238PU2 G KC=0.133 12$LC=0.060 5$MC=0.0158 12 +238PU G 918.70 4 0.529 6E1 0.0047 1 +238PU2 G KC=0.00383 8$LC=0.00066 1$MC=0.000158 3 +238PU G 962.76 2 0.645 8E1 0.00433 9 +238PU2 G KC=0.00352 7$LC=0.00061 1$MC=0.000145 3 +238PU L 968.2 4 (2)- +238PU B 323.3 6 0.082 6 9.11 +238PUS B EAV=90.1 2 +238PU G 924 0.065 +238PU G 968.9 4 0.015 8[M2] 0.116 3 +238PU2 G KC=0.089 2$LC=0.0200 4$MC=0.0050 1 +238PU L 983.09 7 2+ +238PU B 308.4 4 0.27 3 8.51 +238PUS B EAV=85.6 2 +238PU G 321.75 200.0013 8 +238PU G 378.05 130.0030 5 +238PU G 836.96 7 0.0206 8[E2] 0.0174 4 +238PU2 G KC=0.0125 3$LC=0.00366 8$MC=0.00093 2 +238PU G 938.94 100.0327 25E0+E2 4.4 4 +238PU2 G KC=3.5 4$LC=0.67 7 +238PU G 983.0 3 0.068 20[E2] 0.0128 3 +238PU2 G KC=0.00947 19$LC=0.00247 5$MC=0.00062 1 +238PU L 985.45 5 2- +238PU B 306.0 4 0.49 1 8.25 +238PUS B EAV=84.9 2 +238PU G 324.02 9 0.0146 8M1+E2 2.8 8 0.26 7 +238PU2 G KC=0.15 6$LC=0.082 7$MC=0.022 2 +238PU G 380.31 100.0111 5[M1] 0.623 9 +238PU2 G KC=0.493 10$LC=0.098 2$MC=0.0237 5 +238PU G 941.40 4 0.504 6[E1+M2] +238PU L 1028.54 2 2+ +238PU B 263.0 4 44.75 19 6.09 +238PUS B EAV=72.0 2 +238PU G 882.63 3 0.803 9(E2) 0.0157 3 +238PU2 G KC=0.0114 2$LC=0.00320 7$MC=0.00081 2 +238PU G 984.45 2 25.18 13M1+E2 0.0125 5 +238PU2 G KC=0.0096 3$LC=0.0022 1$MC=0.0006 1 +238PU G 1028.54 2 18.25 13E2 0.0117 2 +238PU2 G KC=0.00875 18$LC=0.00222 5$MC=0.00055 1 +238PU L 1069.94 2 3+ +238PU B 221.6 4 11.50 7 6.44 +238PUS B EAV=59.9 2 +238PU G 923.99 2 2.604 20(M1+E2) 0.014 1 +238PU2 G KC=0.0099 4 +238PU G 1025.87 2 8.76 6M1+E2 0.0120 5 +238PU2 G KC=0.0091 4$LC=0.0021 1$MC=0.0006 1 +238PU L 1082.56 6 (4)- +238PU G 114.4 4 0.0058 10[E2] 8.47 17 +238PU2 G LC=6.15 12$MC=1.72 14 +238PU G 319.29 110.0083 10M1+E2 1.0 5 0.59 25 +238PU2 G KC=0.43 22$LC=0.118 25$MC=0.030 5 +238PU G 421.1 1 0.021 1[M1] 0.472 7 +238PU2 G KC=0.374 8$LC=0.0737 15$MC=0.0179 4 +238PU G 936.60 5 0.365 5[E1+M2] -0.24 4 0.0112 22 +238PU2 G KC=0.0089 17$LC=0.0018 4$MC=0.00044 10 +238PU L 1202.46 8 (3)- +238PU B 89.0 4 0.51 6 6.57 1 +238PUS B EAV=23.0 2 +238PU G 120.11 5 0.101 5M1(+E2) 3.8 6 +238PU2 G LC=2.8 6$MC=0.69 6 +238PU G 132.5 1 0.0014 8[E1] 0.267 5 +238PU2 G KC=0.203 4$LC=0.048 1$MC=0.0118 2 +238PU G 174.08 5 0.0229 8[E1] 0.142 3 +238PU2 G KC=0.110 2$LC=0.0241 5$MC=0.0059 1 + diff --git a/HEN_HOUSE/spectra/lnhb/Np-239.txt b/HEN_HOUSE/spectra/lnhb/Np-239.txt index 021dc2e33..b21fe465d 100644 --- a/HEN_HOUSE/spectra/lnhb/Np-239.txt +++ b/HEN_HOUSE/spectra/lnhb/Np-239.txt @@ -1,141 +1,147 @@ -239PU 239NP B- DECAY (2.356 D) -239PU H TYP=Full$AUT=V.P. Chechev. N.K. Kuzmenco$CUT= -- $ -239PU C Evaluation history: Type=Full;Author=V.P. Chechev. N.K. Kuzmenco;Cutoff date= -- -239PU C References: 1952Fr25, 1956Wi25, 1956Ba95, 1959Co93, 1959Co63, 1959Ew90, -239PU2C 1965Ma17, 1966Qa01, 1969Bi12, 1972Po04, 1972Kr07, 1972Ah02, 1974HeYW, -239PU3C 1974Yu04, 1977St35, 1979Mo25, 1979Bo30, 1982Ah04, 1984Va41, 1986Ch17, -239PU4C 1990Ab06, 1990Si12, 1991Sh06, 1991Po17, 1992Ha02, 1996FiZX, 1996Wo05, -239PU5C 1996Sc06, 2003Au03, 2003Br12 -239PU T Auger electrons and X ray energies and emission intensities: -239PU T {U Energy (keV)} {U Intensity} {U Line} -239PU T -239PU T 99.525 13.5 4 XKA2 -239PU T 103.734 21.4 6 XKA1 -239PU T -239PU T 116.244 |] XKB3 -239PU T 117.228 |] 7.84 25 XKB1 -239PU T 117.918 |] XKB5II -239PU T -239PU T 120.54 |] XKB2 -239PU T 120.969 |] 2.72 10 XKB4 -239PU T 121.543 |] XKO23 -239PU T -239PU T 12.125-21.984 51.3 24 XL (total) -239PU T 12.125 1.38 6 XLL -239PU T 14.083-14.279 21.5 10 XLA -239PU T 16.334 0.414 28 XLC -239PU T 16.499-19.331 22.8 10 XLB -239PU T 20.708-21.984 5.19 24 XLG -239PU T -239PU T 75.26-85.36 |] KLL AUGER -239PU T 92.61-103.73 |] 1.36 19 KLX AUGER -239PU T 109.93-121.78 |] KXY AUGER -239PU T 6.19-22.99 47.9 26 L AUGER -239NP P 0.0 5/2+ 2.356 D 3 722.5 10 -239PU N 1.0 1.0 1 1.0 -239PU L 0 1/2+ 24100 Y 11 -239PU B 722.5 5 2 -239PUS B EAV= -239PU L 7.861 2 3/2+ 36 PS 3 -239PU B 714.6 5 6.5 10 8.4 -239PUS B EAV=218.3 2 -239PU G 7.861 2 0.0122 12M1+E2 0.055 3 5.72E3 40 -239PU2 G MC=4.2E3 3 -239PU L 57.276 2 5/2+ 101 PS 5 -239PU B 665.2 5 0 7 -239PUS B EAV= -239PU G 49.415 3 0.145 35M1+E2 0.50 3 126 8 -239PU2 G LC=92 6$MC=24.8 17 -239PU G 57.273 4 0.12 3E2 222 4 -239PU2 G LC=161.1 23$MC=45.0 7 -239PU L 75.706 3 7/2+ 83 PS 8 -239PU B 646.8 5 -239PUS B EAV= -239PU G 18.430 4 0.02 [M1+E2] -239PU G 67.841 7 0.10 3E2 98.5 14 -239PU2 G LC=71.5 10$MC=20.0 3 -239PU L 163.76 2 9/2+ 73 PS 4 -239PU B 558.7 5 2 -239PUS B EAV= -239PU G 88.06 3 0.006 2M1+E2 0.5 2 12 6 -239PU2 G LC=9 4$MC=2.4 13 -239PU G 106.50 3 0.049 8E2 11.8 3 -239PU2 G LC=8.55 17$MC=2.39 5 -239PU L 285.460 2 5/2+ 1.12 NS 5 -239PU B 437.0 5 43.0 22 6.9 -239PUS B EAV=125.6 2 -239PU G 209.753 2 3.42 3M1+E2 0.37 8 2.93 13 -239PU2 G KC=2.27 12$LC=0.499 9$MC=0.1231 18 -239PU G 228.183 1 11.32 22M1+E2 0.28 7 2.41 9 -239PU2 G KC=1.88 8$LC=0.395 7$MC=0.0967 15 -239PU G 277.599 1 14.4 1M1+E2 0.23 10 1.42 7 -239PU2 G KC=1.12 6$LC=0.228 6$MC=0.0555 13 -239PU G 285.460 2 0.78 1E2 0.248 5 -239PU2 G KC=0.0843 17$LC=0.119 3$MC=0.0327 7 -239PU L 330.125 4 7/2+ -239PU B 392.4 5 9.4 14 7.4 -239PUS B EAV=111.5 2 -239PU G 44.663 5 0.13 1M1+E2 0.20 3 86 8 -239PU2 G LC=64 6$MC=16.2 17 -239PU G 166.39 6 0.016 7M1(+E2) 0.5 4 6.23 13 -239PU2 G KC=4.92 10$LC=0.987 20$MC=0.240 5 -239PU G 254.40 3 0.110 3M1+E2 1.85 4 -239PU2 G KC=1.46 3$LC=0.295 6$MC=0.0718 15 -239PU G 272.84 3 0.077 3M1+E2 0.16 5 1.52 3 -239PU2 G KC=1.20 3$LC=0.242 4$MC=0.0588 9 -239PU G 322.3 2 0.0052 (E2) 0.170 4 -239PU2 G KC=0.0680 14$LC=0.076 4$MC=0.0203 4 -239PU L 387.41 2 9/2+ -239PU B 335.1 5 2 -239PUS B EAV= -239PU G 57.3 0.012 M1(+E2) -239PU G 101.96 2 0.008 2E2 14.42 21 -239PU2 G LC=10.46 15$MC=2.93 5 -239PU G 311.70 2 0.002 2(M1+E2) -239PU L 391.586 3 7/2- 193 NS 4 -239PU B 330.9 5 38.8 9 6.3 1 -239PUS B EAV=98.3 2 -239PU G 61.460 2 1.29 2E1 0.473 7 -239PU2 G LC=0.354 5$MC=0.0881 13 -239PU G 106.125 2 25.9 3E1(+M2) -0.007 7 0.26 3 -239PU2 G LC=0.19 3$MC=0.050 8 -239PU G 227.83 0.5 1M1+E2 0.0762 15 -239PU2 G KC=0.0597 12$LC=0.0125 3$MC=0.00303 6 -239PU G 315.880 3 1.59 1E1(+M2) 0.0372 8 -239PU2 G KC=0.0295 6$LC=0.0059 2$MC=0.00141 4 -239PU G 334.310 3 2.04 2E1(+M2) 0.0329 7 -239PU2 G KC=0.0261 5$LC=0.00515 7$MC=0.0012 3 -239PU L 469.8 4 (1/2)- -239PU B 252.7 5 0.0027 9.9 1U -239PUS B EAV=74.7 2 -239PU G 461.9 5 0.0016 (E1) -239PU G 469.8 5 0.0011 (E1) -239PU L 492.2 3 3/2- -239PU B 230.3 5 0.02 9.3 1 -239PUS B EAV=62.5 2 -239PU G 434.7 5 0.013 E1(+M2) -239PU G 484.3 5 0.001 (E1) -239PU G 492.3 5 0.006 (E1) -239PU L 505.2 (5/2)- -239PU B 217.3 5 0.0074 9.7 -239PUS B EAV=58.7 2 -239PU G 429.5 5 0.0039 -239PU G 447.6 5 0.00026 -239PU G 497.8 5 0.0032 -239PU L 511.81 6 7/2+ -239PU B 210.7 5 1.56 16 7.3 -239PUS B EAV=56.8 2 -239PU G 124.4 0.01 E2 13.6 3 -239PU2 G KC=10.4 2$LC=2.39 5$MC=0.591 12 -239PU G 181.70 3 0.086 2M1 4.78 10 -239PU2 G KC=3.76 8$LC=0.768 15$MC=0.187 4 -239PU G 226.38 2 0.255 14M1+E2 2.58 8 -239PU2 G KC=2.04 7$LC=0.411 12$MC=0.100 3 -239PU G 454.2 5 0.00082 (M1) -239PU G 504.2 5 0.00078 (E2) -239PU L 556.2 (7/2)- -239PU B 166.3 5 0.0026 9.7 1 -239PUS B EAV=44.2 2 -239PU G 392.4 5 0.0016 (E1) -239PU G 498.7 0.001 (E1) - +239PU 239NP B- DECAY (2.356 D) +239PU H TYP=FUL$AUT=V.P.CHECHEV, N.K.KUZMENKO$CUT=31-MAY-2006$ +239PU C References:1952Fr25, 1956Wi25, 1956Ba95, 1959Co93, 1959Co63, 1959Ew90, +239PU2C 1965Ma17, 1966Qa01, 1969Bi12, 1972Po04, 1972Kr07, 1972Ah02, 1974HeYW, +239PU3C 1974Yu04, 1977St35, 1979Mo25, 1979Bo30, 1982Ah04, 1984Va41, 1986Ch17, +239PU4C 1990Ab06, 1990Si12, 1991Sh06, 1991Po17, 1992Ha02, 1996FiZX, 1996Wo05, +239PU5C 1996Sc06, 1999Sc**, 2003Au03, 2003Br12 +239PU T Auger electrons and X ray energies and emission intensities: +239PU T {U Energy (keV)} {U Intensity} {U Line} +239PU T +239PU T 99.525 13.5 4 XKA2 +239PU T 103.734 21.4 6 XKA1 +239PU T +239PU T 116.244 |] XKB3 +239PU T 117.228 |] 7.84 25 XKB1 +239PU T 117.918 |] XKB5II +239PU T +239PU T 120.54 |] XKB2 +239PU T 120.969 |] 2.72 10 XKB4 +239PU T 121.543 |] XKO23 +239PU T +239PU T 12.125-21.984 51.3 24 XL (total) +239PU T 12.125 1.38 6 XLL +239PU T 14.083-14.279 21.5 10 XLA +239PU T 16.334 0.414 28 XLC +239PU T 16.499-19.331 22.8 10 XLB +239PU T 20.708-21.984 5.19 24 XLG +239PU T +239PU T 75.26-85.36 |] KLL AUGER +239PU T 92.61-103.73 |] 1.36 19 KLX AUGER +239PU T 109.93-121.78 |] KXY AUGER +239PU T 6.19-22.99 47.9 26 L AUGER +239NP P 0.0 5/2+ 2.356 D 3 722.5 10 +239PU N 1.0 1.0 1 1.0 +239PU L 0 1/2+ 24100 Y 11 +239PU B 722.5 5 2 +239PU L 7.861 2 3/2+ 36 PS 3 +239PU B 714.6 5 6.5 10 8.4 +239PUS B EAV=218.3 2 +239PU G 7.861 2 0.0122 12M1+E2 0.055 3 5.72E3 40 +239PU2 G MC=4.2E3 3$NC=1160 80 +239PU3 G OC=279 18 +239PU L 57.276 2 5/2+ 101 PS 5 +239PU B 665.2 5 0 7 +239PU G 49.415 3 0.145 35M1+E2 0.50 3 126 8 +239PU2 G LC=92 6$MC=24.8 17$NC=6.8 5 +239PU3 G OC=1.62 11 +239PU G 57.273 4 0.12 3E2 222 4 +239PU2 G LC=161.1 23$MC=45.0 7$NC=12.36 18 +239PU3 G OC=2.91 4 +239PU L 75.706 3 7/2+ 83 PS 8 +239PU B 646.8 5 +239PU G 18.430 4 0.02 [M1+E2] +239PU G 67.841 7 0.10 3E2 98.5 14 +239PU2 G LC=71.5 10$MC=20.0 3$NC=5.50 8 +239PU3 G OC=1.293 19 +239PU L 163.76 2 9/2+ 73 PS 4 +239PU B 558.7 5 2 +239PU G 88.06 3 0.006 2M1+E2 0.5 2 12 6 +239PU2 G LC=9 4$MC=2.4 13 +239PU G 106.50 3 0.049 8E2 11.8 3 +239PU2 G LC=8.55 17$MC=2.39 5$NC=0.658 10 +239PU3 G OC=0.155 2 +239PU L 285.460 2 5/2+ 1.12 NS 5 +239PU B 437.0 5 43.0 22 6.9 +239PUS B EAV=125.6 2 +239PU G 209.753 2 3.42 3M1+E2 0.37 8 2.93 13 +239PU2 G KC=2.27 12$LC=0.499 9$MC=0.1231 18$NC=0.0335 5 +239PU3 G OC=0.00830 13 +239PU G 228.183 1 11.32 22M1+E2 0.28 7 2.41 9 +239PU2 G KC=1.88 8$LC=0.395 7$MC=0.0967 15$NC=0.0263 4 +239PU3 G OC=0.00653 11 +239PU G 277.599 1 14.4 1M1+E2 0.23 10 1.42 7 +239PU2 G KC=1.12 6$LC=0.228 6$MC=0.0555 13$NC=0.0151 4 +239PU3 G OC=0.00375 9 +239PU G 285.460 2 0.78 1E2 0.248 5 +239PU2 G KC=0.0843 17$LC=0.119 3$MC=0.0327 7 +239PU L 330.125 4 7/2+ +239PU B 392.4 5 9.4 14 7.4 +239PUS B EAV=111.5 2 +239PU G 44.663 5 0.13 1M1+E2 0.20 3 86 8 +239PU2 G LC=64 6$MC=16.2 17$NC=4.4 5 +239PU3 G OC=1.08 11 +239PU G 166.39 6 0.016 7M1(+E2) 0.5 4 6.23 13 +239PU2 G KC=4.92 10$LC=0.987 20$MC=0.240 5 +239PU G 254.40 3 0.110 3M1+E2 1.85 4 +239PU2 G KC=1.46 3$LC=0.295 6$MC=0.0718 15 +239PU G 272.84 3 0.077 3M1+E2 0.16 5 1.52 3 +239PU2 G KC=1.20 3$LC=0.242 4$MC=0.0588 9$NC=0.01600 25 +239PU3 G OC=0.00398 7 +239PU G 322.3 2 0.0052 (E2) 0.170 4 +239PU2 G KC=0.0680 14$LC=0.076 4$MC=0.0203 4 +239PU L 387.41 2 9/2+ +239PU B 335.1 5 2 +239PU G 57.3 0.012 M1(+E2) +239PU G 101.96 2 0.008 2E2 14.42 21 +239PU2 G LC=10.46 15$MC=2.93 5$NC=0.805 12 +239PU3 G OC=0.190 3 +239PU G 311.70 2 0.002 2(M1+E2) +239PU L 391.586 3 7/2- 193 NS 4 +239PU B 330.9 5 38.8 9 6.3 1 +239PUS B EAV=98.3 2 +239PU G 61.460 2 1.29 2E1 0.473 7 +239PU2 G LC=0.354 5$MC=0.0881 13$NC=0.0236 4 +239PU3 G OC=0.00553 8 +239PU G 106.125 2 25.9 3E1(+M2) -0.007 7 0.26 3 +239PU2 G LC=0.19 3$MC=0.050 8 +239PU G 227.83 0.5 1M1+E2 0.0762 15 +239PU2 G KC=0.0597 12$LC=0.0125 3$MC=0.00303 6 +239PU G 315.880 3 1.59 1E1(+M2) 0.0372 8 +239PU2 G KC=0.0295 6$LC=0.0059 2$MC=0.00141 4 +239PU G 334.310 3 2.04 2E1(+M2) 0.0329 7 +239PU2 G KC=0.0261 5$LC=0.00515 7$MC=0.0012 3 +239PU L 469.8 4 (1/2)- +239PU B 252.7 5 0.0027 9.9 1U +239PUS B EAV=74.7 2 +239PU G 461.9 5 0.0016 (E1) +239PU G 469.8 5 0.0011 (E1) +239PU L 492.2 3 3/2- +239PU B 230.3 5 0.02 9.3 1 +239PUS B EAV=62.5 2 +239PU G 434.7 5 0.013 E1(+M2) +239PU G 484.3 5 0.001 (E1) +239PU G 492.3 5 0.006 (E1) +239PU L 505.2 (5/2)- +239PU B 217.3 5 0.0074 9.7 +239PUS B EAV=58.7 2 +239PU G 429.5 5 0.0039 +239PU G 447.6 5 0.00026 +239PU G 497.8 5 0.0032 +239PU L 511.81 6 7/2+ +239PU B 210.7 5 1.56 16 7.3 +239PUS B EAV=56.8 2 +239PU G 124.4 0.01 E2 13.6 3 +239PU2 G KC=10.4 2$LC=2.39 5$MC=0.591 12 +239PU G 181.70 3 0.086 2M1 4.78 10 +239PU2 G KC=3.76 8$LC=0.768 15$MC=0.187 4 +239PU G 226.38 2 0.255 14M1+E2 2.58 8 +239PU2 G KC=2.04 7$LC=0.411 12$MC=0.100 3 +239PU G 454.2 5 0.00082 (M1) +239PU G 504.2 5 0.00078 (E2) +239PU L 556.2 (7/2)- +239PU B 166.3 5 0.0026 9.7 1 +239PUS B EAV=44.2 2 +239PU G 392.4 5 0.0016 (E1) +239PU G 498.7 0.001 (E1) + diff --git a/HEN_HOUSE/spectra/lnhb/O-15.txt b/HEN_HOUSE/spectra/lnhb/O-15.txt index ac5565517..bfb13966b 100644 --- a/HEN_HOUSE/spectra/lnhb/O-15.txt +++ b/HEN_HOUSE/spectra/lnhb/O-15.txt @@ -1,7 +1,7 @@ - 15N 15O EC DECAY (2.041 M) - 15O P 0.0 1/2- 2.041 M 6 2757.0 13 - 15N N 1.0 1.0 1 1.0 - 15N L 0 1/2- STABLE - 15N E 99.885 60.115 6 - 15N 2 E EAV=736.7 6$CK=0.926 6$CL=0.074 6$CO=0 0 - + 15N 15O EC DECAY (2.041 M) + 15O P 0.0 1/2- 2.041 M 6 2757.0 13 + 15N N 1.0 1.0 1 1.0 + 15N L 0 1/2- STABLE + 15N E 99.885 60.115 6 + 15N 2 E EAV=736.7 6$CK=0.001065 7$CL=0.000085 7 + diff --git a/HEN_HOUSE/spectra/lnhb/P-32.txt b/HEN_HOUSE/spectra/lnhb/P-32.txt index 3beb96bd9..cb3a00af0 100644 --- a/HEN_HOUSE/spectra/lnhb/P-32.txt +++ b/HEN_HOUSE/spectra/lnhb/P-32.txt @@ -1,7 +1,7 @@ - 32S 32P B- DECAY (14.284 D) - 32P P 0.0 1+ 14.284 D 36 1710.66 21 - 32S N 1.0 1.0 1 1.0 - 32S L 0 0+ STABLE - 32S B 1710.66 21100 7.9 - 32S S B EAV=695.5 3 - + 32S 32P B- DECAY (14.284 D) + 32P P 0.0 1+ 14.284 D 36 1710.66 21 + 32S N 1.0 1.0 1 1.0 + 32S L 0 0+ STABLE + 32S B 1710.66 21100 7.9 + 32S S B EAV=695.5 3 + diff --git a/HEN_HOUSE/spectra/lnhb/P-33.txt b/HEN_HOUSE/spectra/lnhb/P-33.txt index fd5f9a3d4..bd9d9cfa0 100644 --- a/HEN_HOUSE/spectra/lnhb/P-33.txt +++ b/HEN_HOUSE/spectra/lnhb/P-33.txt @@ -1,7 +1,7 @@ - 33S 33P B- DECAY (25.383 D) - 33P P 0.0 1/2+ 25.383 D 40 248.5 11 - 33S N 1.0 1.0 1 1.0 - 33S L 0 3/2+ STABLE - 33S B 248.5 11100 5 - 33S S B EAV=76.4 5 - + 33S 33P B- DECAY (25.383 D) + 33P P 0.0 1/2+ 25.383 D 40 248.5 11 + 33S N 1.0 1.0 1 1.0 + 33S L 0 3/2+ STABLE + 33S B 248.5 11100 5 + 33S S B EAV=76.4 5 + diff --git a/HEN_HOUSE/spectra/lnhb/Pa-231.txt b/HEN_HOUSE/spectra/lnhb/Pa-231.txt index caa4e703c..cb7061228 100644 --- a/HEN_HOUSE/spectra/lnhb/Pa-231.txt +++ b/HEN_HOUSE/spectra/lnhb/Pa-231.txt @@ -1,215 +1,267 @@ -227AC 231PA A DECAY (32670 Y) -227AC H TYP=Full$AUT=A. Arinc$CUT=30-JUN-2009$ -227AC C Evaluation history: Type=Full;Author=A. Arinc;Cutoff date=30-JUN-2009 -227AC C References: 1949Va02, 1953Fa08, 1956Hu96, 1960As02, 1960Fo05, 1961Br32, -227AC2C 1961kI05, 1961Ba42, 1963Su10, 1963aB04, 1966Ba14, 1968Br04, 1968Ba25, -227AC3C 1968Ha22, 1969Ba20, 1969La04, 1969Ro33, 1970De19, 1970Le11, 1971Le10, -227AC4C 1972Ga39, 1974De11, 1976BaZZ, 1979Te02, 1979Bo30, 1982An02, 1985Is03, -227AC5C 1986LOZT, 1990Ho28, 1991Ry01, 1998Ak04, 2001Br31, 2003Au03, 2008kI07 -227AC T Auger electrons and X ray energies and emission intensities: -227AC T {U Energy (keV)} {U Intensity} {U Line} -227AC T -227AC T 87.768 0.715 23 XKA2 -227AC T 90.885 1.16 4 XKA1 -227AC T -227AC T 102.101 |] XKB3 -227AC T 102.841 |] 0.410 15 XKB1 -227AC T 103.462 |] XKB5II -227AC T -227AC T 105.679 |] XKB2 -227AC T 106.098 |] 0.136 6 XKB4 -227AC T 106.563 |] XKO23 -227AC T -227AC T 10.8701-18.9228 44.3 13 XL (total) -227AC T 10.8701 1.10 4 XLL -227AC T 12.5002-12.6505 18.7 7 XLA -227AC T 14.0807 0.303 19 XLC -227AC T 14.6024-15.9311 19.7 7 XLB -227AC T 17.813-18.9228 4.45 16 XLG -227AC T -227AC T 66.769-74.715 |] KLL AUGER -227AC T 81.775-90.882 |] 0.078 11 KLX AUGER -227AC T 96.76-106.75 |] KXY AUGER -227AC T 5.87-19.69 52.6 15 L AUGER -231PA P 0.0 3/2- 32670 Y 260 5149.9 8 -227AC N 1.0 1.0 1 1.0 -227AC G 70.49 5 0.0051 8 -227AC G 242.18 8 0.0099 10 -227AC G 286.58 100.0104 5 -227AC G 310.0 1 0.00092 20 -227AC G 374.95 100.0045 3 -227AC G 438.72 100.0013 4 -227AC L 0 3/2- 21.772 Y 3 -227AC A 5060.7 8 11.7 5 250 -227AC L 27.37 1 3/2+ 38.3 NS 30 -227AC A 5033.8 8 2.8 3 707 -227AC G 27.37 1 10.8 4E1 4.5 6 -227AC2 G LC=3.3 4$MC=0.87 13 -227AC L 29.98 1 5/2- -227AC A 5031.2 8 20 2 95 -227AC G 29.98 1 0.097 4M1+E2 0.22 2 270 30 -227AC2 G LC=202 21$MC=52 6 -227AC L 46.35 1 5/2+ -227AC A 5015.1 8 25.3 5 59.5 -227AC G 16.370 140.221 9E1 8.58 12 -227AC2 G LC=5.06 7$MC=2.68 4 -227AC G 18.980 140.37 3M1 113.2 16 -227AC2 G LC=2.35 4$MC=82.7 12 -227AC G 46.35 1 0.19 1E1 0.879 13 -227AC2 G LC=0.663 10$MC=0.1634 23 -227AC L 74.14 1 (7/2)- -227AC A 4987.8 8 1.6 2 629 -227AC G 44.160 140.055 4M1 37.4 6 -227AC2 G LC=28.3 4$MC=6.79 10 -227AC G 74.14 1 0.0223 9E2 42.6 6 -227AC2 G LC=31.2 5$MC=8.53 12 -227AC L 84.55 1 (7/2)+ -227AC A 4977.6 8 0.4 1 2160 -227AC G 38.200 140.144 6M1+E2 0.18 5 89 19 -227AC2 G LC=66 14$MC=17 4 -227AC G 54.570 140.070 4E1 0.569 8 -227AC2 G LC=0.430 6$MC=0.1053 15 -227AC G 57.180 140.031 3E2 148.1 21 -227AC2 G LC=108.6 16$MC=29.6 5 -227AC L 109.94 2 (9/2)+ -227AC A 4952.6 8 22.5 5 26.5 -227AC G 25.390 220.095 7M1 191 3 -227AC2 G LC=144.6 21$MC=34.9 5 -227AC G 35.800 220.0163 10E1 1.746 25 -227AC2 G LC=1.313 19$MC=0.327 5 -227AC G 63.590 220.0446 17E2 88.8 13 -227AC2 G LC=65.1 10$MC=17.8 3 -227AC L 126.86 2 (9/2)- -227AC A 4936.0 8 2.9 3 160 -227AC G 52.720 220.076 4M1 22.2 4 -227AC2 G LC=16.81 24$MC=4.03 6 -227AC G 96.880 220.084 3E2 12.02 17 -227AC2 G LC=8.81 13$MC=2.41 4 -227AC L 160 2 + -227AC A 4903.4 220.002 1 141000 -227AC L 187.32 3 (11/2)+ -227AC G 60.46 4 0.0053 7E1 0.433 7 -227AC2 G LC=0.327 5$MC=0.0800 12 -227AC G 77.38 4 0.061 4M1 7.23 11 -227AC2 G LC=5.47 8$MC=1.313 19 -227AC G 102.77 3 0.019 4E2 9.12 13 -227AC2 G LC=6.69 10$MC=1.83 3 -227AC L 198.71 4 (11/2)- -227AC G 71.85 5 0.0019 7M1 8.98 13 -227AC2 G LC=6.79 10$MC=1.630 23 -227AC G 124.57 4 0.0043 4E2 4.04 6 -227AC2 G KC=0.285 4$LC=2.75 4$MC=0.752 11 -227AC L 210.78 5 (13/2)+ -227AC A 4853.5 8 1.40 1594 -227AC G 23.46 6 0.0048 6M1 241 4 -227AC2 G LC=182 3$MC=44.1 7 -227AC G 100.84 5 0.0226 9E2 9.97 15 -227AC2 G LC=7.30 11$MC=2.00 3 -227AC L 271.29 6 (13/2)- -227AC A 4794.1 8 0.040 151300 -227AC G 72.58 7 0.0030 7M1 8.71 13 -227AC2 G LC=6.59 10$MC=1.582 23 -227AC G 144.43 6 0.0115 9E2 2.18 3 -227AC2 G KC=0.263 4$LC=1.407 20$MC=0.384 6 -227AC L 273.14 3 (5/2)- -227AC G 199.00 3 0.0030 12 -227AC G 243.16 3 0.036 5M1+E2 1.1 3 0.80 17 -227AC2 G KC=0.56 16$LC=0.176 10$MC=0.0445 16 -227AC G 245.77 3 0.012 4E1 0.0570 8 -227AC2 G KC=0.0455 7$LC=0.00867 13$MC=0.00208 3 -227AC G 273.14 3 0.0579 12M1+E2 0.7 2 0.74 11 -227AC2 G KC=0.57 10$LC=0.131 8$MC=0.0323 15 -227AC L 304.73 5 (5/2)+ -227AC A 4761.2 8 0.0032 9 9600 -227AC G 230.59 5 0.0017 8 -227AC G 258.38 5 0.0015 4 -227AC L 330.04 1 3/2- -227AC A 4736.3 8 8.4 4 2.46 -227AC G 56.90 3 0.0047 7M1+E2 0.41 7 37 6 -227AC2 G LC=28 5$MC=7.1 12 -227AC G 245.490 140.0067 5M2 5.24 8 -227AC2 G KC=3.70 6$LC=1.143 16$MC=0.293 5 -227AC G 255.900 140.1059 22E2 0.264 4 -227AC2 G KC=0.0992 14$LC=0.1216 17$MC=0.0327 5 -227AC G 283.690 141.65 3E1 0.0410 6 -227AC2 G KC=0.0329 5$LC=0.00614 9$MC=1468E-6 21 -227AC G 300.060 142.41 5M1+E2 -0.12 7 0.764 17 -227AC2 G KC=0.613 15$LC=0.1146 20$MC=0.0275 5 -227AC G 302.670 142.3 3E1 0.0355 5 -227AC2 G KC=0.0285 4$LC=0.00527 8$MC=1260E-6 18 -227AC G 330.04 1 1.36 3M1+E2 0.36 6 0.541 19 -227AC2 G KC=0.430 16$LC=0.0836 20$MC=0.0202 5 -227AC L 354.50 4 1/2- -227AC A 4712.3 8 1.20 2211.7 -227AC G 24.46 4 0.0049 10M1 214 4 -227AC2 G LC=161.3 24$MC=39.0 6 -227AC G 327.13 4 0.0361 11E1 0.0298 5 -227AC2 G KC=0.0240 4$LC=0.00440 7$MC=1050E-6 15 -227AC G 354.50 4 0.0962 20M1+E2 3 0.1375 20 -227AC2 G KC=0.0855 12$LC=0.0386 6$MC=0.01003 14 -227AC L 387.23 2 7/2- -227AC A 4680.1 8 1.8 3 4.6 -227AC G 57.190 220.0046 21E2 148.0 21 -227AC2 G LC=108.5 16$MC=29.6 5 -227AC G 260.37 3 0.182 4M1+E2 1.4 3 0.55 11 -227AC2 G KC=0.37 10$LC=0.133 7$MC=0.0340 13 -227AC G 277.29 3 0.0680 15E1+M2 0.4 4 0.5 9 -227AC2 G KC=0.4 7$LC=0.11 19$MC=0.03 5 -227AC G 302.680 220.21 10E1 0.0355 5 -227AC2 G KC=0.0285 4$LC=0.00527 8$MC=1260E-6 18 -227AC G 313.090 220.0987 20M1+E2 1.5 0.31 9 -227AC2 G KC=0.22 8$LC=0.070 8$MC=0.0177 16 -227AC G 340.880 220.177 4E1+M2 0.22 4 0.11 3 -227AC2 G KC=0.081 22$LC=0.020 6$MC=0.0050 15 -227AC G 357.250 220.168 4M1+E2 0.4 4 0.43 10 -227AC2 G KC=0.34 9$LC=0.066 10$MC=0.0159 21 -227AC G 359.860 220.0085 3 -227AC G 387.23 2 0.0003 1E2 0.0773 11 -227AC2 G KC=0.0430 6$LC=0.0254 4$MC=0.00667 10 -227AC L 425.59 3 5/2+ -227AC A 4642.5 8 0.080 6 56 -227AC G 351.45 3 0.0028 12E1 0.0255 4 -227AC2 G KC=0.0206 3$LC=0.00373 6$MC=8.91E-4 13 -227AC G 379.24 3 0.0498 11M1+E2 0.6 6 0.32 11 -227AC2 G KC=0.25 10$LC=0.052 11$MC=0.0125 24 -227AC G 395.61 3 0.00226 22E1 0.0198 3 -227AC2 G KC=0.01601 23$LC=0.00286 4$MC=6.82E-4 10 -227AC G 398.22 3 0.0095 3 -227AC L 435.19 2 (1/2)+ -227AC A 4633.0 8 0.0504 1175.8 -227AC G 407.820 220.0356 8M1 0.334 5 -227AC2 G KC=0.269 4$LC=0.0496 7$MC=0.01187 17 -227AC G 435.19 2 0.00294 17 -227AC L 437.96 4 (5/2)- -227AC A 4630.3 8 0.078 2147 -227AC G 50.73 5 0.0022 8M1 24.9 4 -227AC2 G LC=18.8 3$MC=4.52 7 -227AC G 363.82 4 0.0080 3 -227AC G 391.61 4 0.00673 22E1 0.0202 3 -227AC2 G KC=0.01636 23$LC=0.00293 5$MC=6.97E-4 10 -227AC G 410.59 4 0.00180 22E1 0.0183 3 -227AC2 G KC=0.01482 21$LC=0.00264 4$MC=6.28E-4 9 -227AC G 437.96 4 0.0045 3 -227AC L 469.24 6 (9/2)+ -227AC A 4599.6 8 0.015 7 146 -227AC G 384.69 6 0.00365 22 -227AC L 501.28 7 (3/2,5/2)- -227AC A 4568.1 9 0.008 4 160 -227AC G 427.14 7 0.0007 4 -227AC G 501.28 7 0.00076 18 -227AC L 537.0 1 (3/2)+ -227AC A 4533.0 8 0.00076 20930 -227AC G 490.65 100.0004 1 -227AC G 509.63 100.00036 17 -227AC L 562.8 1 (3/2,5/2)+ -227AC A 4507.6 8 0.0036 3 126 -227AC G 488.66 100.00165 17 -227AC G 516.45 100.00137 15 -227AC G 535.43 100.00061 12 -227AC L 656.4 3 (7/2)+ -227AC A 4415.6 9 0.0021 5 43 -227AC G 546.5 3 0.00083 13 -227AC G 571.9 3 0.00048 20 -227AC G 582.3 3 0.00031 17 -227AC G 610.1 3 0.0005 4 - +227AC 231PA A DECAY (32670 Y) +227AC H TYP=FUL$AUT=A.ARINC$CUT=30-JUN-2009$ +227AC C References:1932Gr**, 1949Va02, 1953Fa08, 1956Hu96, 1960As02, 1960Fo05, +227AC2C 1961Br32, 1961kI05, 1961Ba42, 1963Su10, 1963aB04, 1966Ba14, 1968Br04, +227AC3C 1968Ba25, 1968Ha22, 1969Ba20, 1969La04, 1969Ro33, 1970De19, 1970Le11, +227AC4C 1971Le10, 1972Ga39, 1974De11, 1976Ba**, 1976BaZZ, 1979Te02, 1979Bo30, +227AC5C 1982An02, 1983Ba**, 1985Is03, 1986LOZT, 1990Ho28, 1991Ry01, 1998Ak04, +227AC6C 2001Br31, 2003Au03, 2008Ki07 +227AC T Auger electrons and X ray energies and emission intensities: +227AC T {U Energy (keV)} {U Intensity} {U Line} +227AC T +227AC T 87.768 0.715 23 XKA2 +227AC T 90.885 1.16 4 XKA1 +227AC T +227AC T 102.101 |] XKB3 +227AC T 102.841 |] 0.410 15 XKB1 +227AC T 103.462 |] XKB5II +227AC T +227AC T 105.679 |] XKB2 +227AC T 106.098 |] 0.136 6 XKB4 +227AC T 106.563 |] XKO23 +227AC T +227AC T 10.8701-18.9228 44.3 13 XL (total) +227AC T 10.8701 1.10 4 XLL +227AC T 12.5002-12.6505 18.7 7 XLA +227AC T 14.0807 0.303 19 XLC +227AC T 14.6024-15.9311 19.7 7 XLB +227AC T 17.813-18.9228 4.45 16 XLG +227AC T +227AC T 66.769-74.715 |] KLL AUGER +227AC T 81.775-90.882 |] 0.078 11 KLX AUGER +227AC T 96.76-106.75 |] KXY AUGER +227AC T 5.87-19.69 52.6 15 L AUGER +231PA P 0.0 3/2- 32670 Y 260 5149.9 8 +227AC N 1.0 1.0 1 +227AC G 70.49 5 0.0051 8 +227AC G 242.18 8 0.0099 10 +227AC G 286.58 100.0104 5 +227AC G 310.0 1 0.00092 20 +227AC G 374.95 100.0045 3 +227AC G 438.72 100.0013 4 +227AC L 0 3/2- 21.772 Y 3 +227AC A 5060.7 8 11.7 5250 +227AC L 27.37 1 3/2+ 38.3 NS 30 +227AC A 5033.8 8 2.8 3707 +227AC G 27.37 1 10.8 4E1 4.5 6 +227AC2 G LC=3.3 4$MC=0.87 13$NC=0.23 4 +227AC3 G OC=0.048 8 +227AC L 29.98 1 5/2- +227AC A 5031.2 8 20 295 +227AC G 29.98 1 0.097 4M1+E2 0.22 2 270 30 +227AC2 G LC=202 21$MC=52 6$NC=13.8 15 +227AC3 G OC=3.1 4 +227AC L 46.35 1 5/2+ +227AC A 5015.1 8 25.3 559.5 +227AC G 16.370 140.221 9E1 8.58 12 +227AC2 G LC=5.06 7$MC=2.68 4$NC=0.683 10 +227AC3 G OC=0.1347 19 +227AC G 18.980 140.37 3M1 113.2 16 +227AC2 G LC=2.35 4$MC=82.7 12$NC=22.0 4 +227AC3 G OC=5.11 8 +227AC G 46.35 1 0.19 1E1 0.879 13 +227AC2 G LC=0.663 10$MC=0.1634 23$NC=0.0423 6 +227AC3 G OC=0.00913 13 +227AC L 74.14 1 (7/2)- +227AC A 4987.8 8 1.6 2629 +227AC G 44.160 140.055 4M1 37.4 6 +227AC2 G LC=28.3 4$MC=6.79 10$NC=1.80 3 +227AC3 G OC=0.419 6 +227AC G 74.14 1 0.0223 9E2 42.6 6 +227AC2 G LC=31.2 5$MC=8.53 12$NC=2.27 4 +227AC3 G OC=0.493 7 +227AC L 84.55 1 (7/2)+ +227AC A 4977.6 8 0.4 12160 +227AC G 38.200 140.144 6M1+E2 0.18 5 89 19 +227AC2 G LC=66 14$MC=17 4$NC=4.4 10 +227AC3 G OC=1.00 22 +227AC G 54.570 140.070 4E1 0.569 8 +227AC2 G LC=0.430 6$MC=0.1053 15$NC=0.0274 4 +227AC3 G OC=0.00595 9 +227AC G 57.180 140.031 3E2 148.1 21 +227AC2 G LC=108.6 16$MC=29.6 5$NC=7.87 11 +227AC3 G OC=1.710 24 +227AC L 109.94 2 (9/2)+ +227AC A 4952.6 8 22.5 526.5 +227AC G 25.390 220.095 7M1 191 3 +227AC2 G LC=144.6 21$MC=34.9 5$NC=9.26 14 +227AC3 G OC=2.15 3 +227AC G 35.800 220.0163 10E1 1.746 25 +227AC2 G LC=1.313 19$MC=0.327 5$NC=0.0845 12 +227AC3 G OC=0.0180 3 +227AC G 63.590 220.0446 17E2 88.8 13 +227AC2 G LC=65.1 10$MC=17.8 3$NC=4.72 7 +227AC3 G OC=1.027 15 +227AC L 126.86 2 (9/2)- +227AC A 4936.0 8 2.9 3160 +227AC G 52.720 220.076 4M1 22.2 4 +227AC2 G LC=16.81 24$MC=4.03 6$NC=1.071 15 +227AC3 G OC=0.249 4 +227AC G 96.880 220.084 3E2 12.02 17 +227AC2 G LC=8.81 13$MC=2.41 4$NC=0.641 9 +227AC3 G OC=0.1396 20 +227AC L 160 2 +227AC A 4903.4 220.002 1141000 +227AC L 187.32 3 (11/2)+ +227AC G 60.46 4 0.0053 7E1 0.433 7 +227AC2 G LC=0.327 5$MC=0.0800 12$NC=0.0208 3 +227AC3 G OC=0.00454 7 +227AC G 77.38 4 0.061 4M1 7.23 11 +227AC2 G LC=5.47 8$MC=1.313 19$NC=0.348 5 +227AC3 G OC=0.0810 12 +227AC G 102.77 3 0.019 4E2 9.12 13 +227AC2 G LC=6.69 10$MC=1.83 3$NC=0.487 7 +227AC3 G OC=0.1060 15 +227AC L 198.71 4 (11/2)- +227AC G 71.85 5 0.0019 7M1 8.98 13 +227AC2 G LC=6.79 10$MC=1.630 23$NC=0.432 7 +227AC3 G OC=0.1006 15 +227AC G 124.57 4 0.0043 4E2 4.04 6 +227AC2 G KC=0.285 4$LC=2.75 4$MC=0.752 11$NC=0.200 3 +227AC3 G OC=0.0436 7 +227AC L 210.78 5 (13/2)+ +227AC A 4853.5 8 1.40 1594 +227AC G 23.46 6 0.0048 6M1 241 4 +227AC2 G LC=182 3$MC=44.1 7$NC=11.70 19 +227AC3 G OC=2.72 5 +227AC G 100.84 5 0.0226 9E2 9.97 15 +227AC2 G LC=7.30 11$MC=2.00 3$NC=0.532 8 +227AC3 G OC=0.1158 17 +227AC L 271.29 6 (13/2)- +227AC A 4794.1 8 0.040 151300 +227AC G 72.58 7 0.0030 7M1 8.71 13 +227AC2 G LC=6.59 10$MC=1.582 23$NC=0.420 6 +227AC3 G OC=0.0976 14 +227AC G 144.43 6 0.0115 9E2 2.18 3 +227AC2 G KC=0.263 4$LC=1.407 20$MC=0.384 6$NC=0.1022 15 +227AC3 G OC=0.0223 4 +227AC L 273.14 3 (5/2)- +227AC G 199.00 3 0.0030 12 +227AC G 243.16 3 0.036 5M1+E2 1.1 3 0.80 17 +227AC2 G KC=0.56 16$LC=0.176 10$MC=0.0445 16$NC=0.0118 5 +227AC3 G OC=0.00268 12 +227AC G 245.77 3 0.012 4E1 0.0570 8 +227AC2 G KC=0.0455 7$LC=0.00867 13$MC=0.00208 3$NC=0.000546 8 +227AC3 G OC=1.241E-4 18 +227AC G 273.14 3 0.0579 12M1+E2 0.7 2 0.74 11 +227AC2 G KC=0.57 10$LC=0.131 8$MC=0.0323 15$NC=0.0086 4 +227AC3 G OC=0.00197 10 +227AC L 304.73 5 (5/2)+ +227AC A 4761.2 8 0.0032 99600 +227AC G 230.59 5 0.0017 8 +227AC G 258.38 5 0.0015 4 +227AC L 330.04 1 3/2- +227AC A 4736.3 8 8.4 42.46 +227AC G 56.90 3 0.0047 7M1+E2 0.41 7 37 6 +227AC2 G LC=28 5$MC=7.1 12$NC=1.9 4 +227AC3 G OC=0.42 7 +227AC G 245.490 140.0067 5M2 5.24 8 +227AC2 G KC=3.70 6$LC=1.143 16$MC=0.293 5$NC=0.0789 11 +227AC3 G OC=0.0183 3 +227AC G 255.900 140.1059 22E2 0.264 4 +227AC2 G KC=0.0992 14$LC=0.1216 17$MC=0.0327 5$NC=0.00870 13 +227AC3 G OC=0.00192 3 +227AC G 283.690 141.65 3E1 0.0410 6 +227AC2 G KC=0.0329 5$LC=0.00614 9$MC=0.001468 21$NC=0.000386 6 +227AC3 G OC=8.81E-5 13 +227AC G 300.060 142.41 5M1+E2 -0.12 7 0.764 17 +227AC2 G KC=0.613 15$LC=0.1146 20$MC=0.0275 5$NC=0.00728 12 +227AC3 G OC=0.00169 3 +227AC G 302.670 142.3 3E1 0.0355 5 +227AC2 G KC=0.0285 4$LC=0.00527 8$MC=0.001260 18$NC=0.000331 5 +227AC3 G OC=7.56E-5 11 +227AC G 330.04 1 1.36 3M1+E2 0.36 6 0.541 19 +227AC2 G KC=0.430 16$LC=0.0836 20$MC=0.0202 5$NC=0.00535 12 +227AC3 G OC=0.00124 3 +227AC L 354.50 4 1/2- +227AC A 4712.3 8 1.20 2211.7 +227AC G 24.46 4 0.0049 10M1 214 4 +227AC2 G LC=161.3 24$MC=39.0 6$NC=10.34 16 +227AC3 G OC=2.40 4 +227AC G 327.13 4 0.0361 11E1 0.0298 5 +227AC2 G KC=0.0240 4$LC=0.00440 7$MC=0.001050 15$NC=0.000277 4 +227AC3 G OC=6.32E-5 9 +227AC G 354.50 4 0.0962 20M1+E2 3 0.1375 20 +227AC2 G KC=0.0855 12$LC=0.0386 6$MC=0.01003 14$NC=0.00267 4 +227AC3 G OC=0.000597 9 +227AC L 387.23 2 7/2- +227AC A 4680.1 8 1.8 34.6 +227AC G 57.190 220.0046 21E2 148.0 21 +227AC2 G LC=108.5 16$MC=29.6 5$NC=7.87 12 +227AC3 G OC=1.709 25 +227AC G 260.37 3 0.182 4M1+E2 1.4 3 0.55 11 +227AC2 G KC=0.37 10$LC=0.133 7$MC=0.0340 13$NC=0.0090 4 +227AC3 G OC=0.00204 9 +227AC G 277.29 3 0.0680 15E1+M2 0.4 4 0.5 9 +227AC2 G KC=0.4 7$LC=0.11 19$MC=0.03 5$NC=0.007 13 +227AC3 G OC=0.002 3 +227AC G 302.680 220.21 10E1 0.0355 5 +227AC2 G KC=0.0285 4$LC=0.00527 8$MC=0.001260 18$NC=0.000331 5 +227AC3 G OC=7.56E-5 11 +227AC G 313.090 220.0987 20M1+E2 1.5 0.31 9 +227AC2 G KC=0.22 8$LC=0.070 8$MC=0.0177 16$NC=0.0047 5 +227AC3 G OC=0.00107 11 +227AC G 340.880 220.177 4E1+M2 0.22 4 0.11 3 +227AC2 G KC=0.081 22$LC=0.020 6$MC=0.0050 15$NC=0.0013 4 +227AC3 G OC=0.00031 10 +227AC G 357.250 220.168 4M1+E2 0.4 4 0.43 10 +227AC2 G KC=0.34 9$LC=0.066 10$MC=0.0159 21$NC=0.0042 6 +227AC3 G OC=0.00098 14 +227AC G 359.860 220.0085 3 +227AC G 387.23 2 0.0003 1E2 0.0773 11 +227AC2 G KC=0.0430 6$LC=0.0254 4$MC=0.00667 10$NC=0.001774 25 +227AC3 G OC=0.000395 6 +227AC L 425.59 3 5/2+ +227AC A 4642.5 8 0.080 656 +227AC G 351.45 3 0.0028 12E1 0.0255 4 +227AC2 G KC=0.0206 3$LC=0.00373 6$MC=0.000891 13$NC=0.000234 4 +227AC3 G OC=5.36E-5 8 +227AC G 379.24 3 0.0498 11M1+E2 0.6 6 0.32 11 +227AC2 G KC=0.25 10$LC=0.052 11$MC=0.0125 24$NC=0.0033 7 +227AC3 G OC=0.00077 16 +227AC G 395.61 3 0.00226 22E1 0.0198 3 +227AC2 G KC=0.01601 23$LC=0.00286 4$MC=0.000682 10$NC=0.000180 3 +227AC3 G OC=4.11E-5 6 +227AC G 398.22 3 0.0095 3 +227AC L 435.19 2 (1/2)+ +227AC A 4633.0 8 0.0504 1175.8 +227AC G 407.820 220.0356 8M1 0.334 5 +227AC2 G KC=0.269 4$LC=0.0496 7$MC=0.01187 17$NC=0.00315 5 +227AC3 G OC=0.000732 11 +227AC G 435.19 2 0.00294 17 +227AC L 437.96 4 (5/2)- +227AC A 4630.3 8 0.078 2147 +227AC G 50.73 5 0.0022 8M1 24.9 4 +227AC2 G LC=18.8 3$MC=4.52 7$NC=1.199 18 +227AC3 G OC=0.279 4 +227AC G 363.82 4 0.0080 3 +227AC G 391.61 4 0.00673 22E1 0.0202 3 +227AC2 G KC=0.01636 23$LC=0.00293 5$MC=0.000697 10$NC=0.000184 3 +227AC3 G OC=4.21E-5 6 +227AC G 410.59 4 0.00180 22E1 0.0183 3 +227AC2 G KC=0.01482 21$LC=0.00264 4$MC=0.000628 9$NC=1.654E-4 24 +227AC3 G OC=3.79E-5 6 +227AC G 437.96 4 0.0045 3 +227AC L 469.24 6 (9/2)+ +227AC A 4599.6 8 0.015 7146 +227AC G 384.69 6 0.00365 22 +227AC L 501.28 7 (3/2,5/2)- +227AC A 4568.1 9 0.008 4160 +227AC G 427.14 7 0.0007 4 +227AC G 501.28 7 0.00076 18 +227AC L 537.0 1 (3/2)+ +227AC A 4533.0 8 0.00076 20930 +227AC G 490.65 100.0004 1 +227AC G 509.63 100.00036 17 +227AC L 562.8 1 (3/2,5/2)+ +227AC A 4507.6 8 0.0036 3126 +227AC G 488.66 100.00165 17 +227AC G 516.45 100.00137 15 +227AC G 535.43 100.00061 12 +227AC L 656.4 3 (7/2)+ +227AC A 4415.6 9 0.0021 543 +227AC G 546.5 3 0.00083 13 +227AC G 571.9 3 0.00048 20 +227AC G 582.3 3 0.00031 17 +227AC G 610.1 3 0.0005 4 + diff --git a/HEN_HOUSE/spectra/lnhb/Pa-233.txt b/HEN_HOUSE/spectra/lnhb/Pa-233.txt index 4cc20eea2..13135a06a 100644 --- a/HEN_HOUSE/spectra/lnhb/Pa-233.txt +++ b/HEN_HOUSE/spectra/lnhb/Pa-233.txt @@ -1,161 +1,136 @@ -233U 233PA B- DECAY (26.98 D) -233U H TYP=Corrected$AUT=Chechev$CUT= -- $ -233U 2 H TYP=Corrected$AUT=Chechev$CUT= -- $ -233U 3 H TYP=Corrected$AUT=Chechev$CUT= -- $ -233U 4 H TYP=Corrected$AUT=Chechev$CUT= -- $ -233U 5 H TYP=Corrected$AUT=Chechev$CUT= -- $ -233U 6 H TYP=Corrected$AUT=Chechev$CUT= -- $ -233U 7 H TYP=Corrected$AUT=Chechev$CUT= -- $ -233U 8 H TYP=Corrected$AUT=Chechev$CUT= -- $ -233U 9 H TYP=Corrected$AUT=mmbe$CUT= -- $ -233U A H TYP=Corrected$AUT=mmbe$CUT= -- $ -233U B H TYP=Corrected$AUT=mmbe$CUT= -- $ -233U C H TYP=Corrected$AUT=mmbe$CUT= -- $ -233U D H TYP=Corrected$AUT=mmbe$CUT= -- $ -233U E H TYP=Corrected$AUT=mmbe$CUT= -- $ -233U F H TYP=Corrected$AUT=mmbe$CUT= -- $ -233U G H TYP=Corrected$AUT=mmbe$CUT= -- $ -233U H H TYP=Full$AUT=Chechev$CUT=01-JAN-2005$ -233U I H TYP=Full$AUT=Chechev$CUT=01-JAN-2005$ -233U J H TYP=Full$AUT=Chechev$CUT=01-JAN-2005$ -233U K H TYP=Full$AUT=Chechev$CUT=01-JAN-2005$ -233U L H TYP=Full$AUT=Chechev$CUT=01-JAN-2005$ -233U M H TYP=Full$AUT=Chechev$CUT=01-JAN-2005$ -233U N H TYP=Full$AUT=Chechev$CUT=01-JAN-2005$ -233U C Evaluation history: Type=Corrected;Author=Chechev;Cutoff date= -- -233U 2C Type=Corrected;Author=Chechev;Cutoff date= -- -233U 3C Type=Corrected;Author=Chechev;Cutoff date= -- -233U 4C Type=Corrected;Author=Chechev;Cutoff date= -- -233U 5C Type=Corrected;Author=Chechev;Cutoff date= -- -233U 6C Type=Corrected;Author=Chechev;Cutoff date= -- -233U 7C Type=Corrected;Author=Chechev;Cutoff date= -- -233U 8C Type=Corrected;Author=Chechev;Cutoff date= -- -233U 9C Type=Corrected;Author=mmbe;Cutoff date= -- -233U AC Type=Corrected;Author=mmbe;Cutoff date= -- -233U BC Type=Corrected;Author=mmbe;Cutoff date= -- -233U CC Type=Corrected;Author=mmbe;Cutoff date= -- -233U DC Type=Corrected;Author=mmbe;Cutoff date= -- -233U EC Type=Corrected;Author=mmbe;Cutoff date= -- -233U FC Type=Corrected;Author=mmbe;Cutoff date= -- -233U GC Type=Corrected;Author=mmbe;Cutoff date= -- -233U HC Type=Full;Author=Chechev;Cutoff date=01-JAN-2005 -233U IC Type=Full;Author=Chechev;Cutoff date=01-JAN-2005 -233U JC Type=Full;Author=Chechev;Cutoff date=01-JAN-2005 -233U KC Type=Full;Author=Chechev;Cutoff date=01-JAN-2005 -233U LC Type=Full;Author=Chechev;Cutoff date=01-JAN-2005 -233U MC Type=Full;Author=Chechev;Cutoff date=01-JAN-2005 -233U NC Type=Full;Author=Chechev;Cutoff date=01-JAN-2005 -233U C References: 1941Gr03, 1952Br84, 1954Br37, 1955On05, 1956Mc60, 1957Wr37, -233U 2C 1960Un01, 1961Al19, 1962Sc03, 1963Bj03, 1963Bi03, 1966Ze02, 1967Br20, -233U 3C 1968Ma13, 1971Vo02, 1972De67, 1973Va33, 1979Ge08, 1984Va27, 1985DeZR, -233U 4C 1986Kr10, 1986Jo07, 1988Wo01, 1989Br24, 1990Ak02, 1990Ko41, 1990Pe16, -233U 5C 1992Ra08, 2000Us01, 2000Wo01, 2000Ch01, 2000Sc04, 2000Lu01, 2002Lu01, -233U 6C 2003Au03, 2004Sh07, 2005Hu06, 2005Si15, 2006Ch39, 2006Ha53, 2008Ki07, -233U 7C 2008De10 -233U T Auger electrons and X ray energies and emission intensities: -233U T {U Energy (keV)} {U Intensity} {U Line} -233U T -233U T 94.666 9.10 26 XKA2 -233U T 98.44 14.6 4 XKA1 -233U T -233U T 110.421 |] XKB3 -233U T 111.298 |] 5.25 18 XKB1 -233U T 111.964 |] XKB5II -233U T -233U T 114.407 |] XKB2 -233U T 115.012 |] 1.80 7 XKB4 -233U T 115.377 |] XKO23 -233U T -233U T 11.619-20.714 40.6 11 XL (total) -233U T 11.619 1.05 4 XLL -233U T 13.438-13.615 16.9 6 XLA -233U T 15.399 0.272 16 XLC -233U T 15.727-18.206 18.1 6 XLB -233U T 19.507-20.714 4.23 14 XLG -233U T -233U T 71.78-80.95 |] KLL AUGER -233U T 88.15-98.34 |] 0.95 13 KLX AUGER -233U T 104.42-115.4 |] KXY AUGER -233U T 5.9-21.6 42.2 13 L AUGER -233PA P 0.0 3/2- 26.98 D 2 570.1 20 -233U N 1.0 1.0 1 1.0 -233U L 0 5/2+ 159.1E3 Y 2 -233U B 570.1 206.3 23 9.1 1 -233U S B EAV=169.6 6 -233U L 40.350 4 7/2+ 0.11 NS 8 -233U B 529.8 200.3 19 10.2 1U -233U S B EAV=156.1 6 -233U G 40.349 5 0.024 2M1+E2 1.08 12 580 60 -233U 2 G LC=430 50$MC=117 12 -233U L 92.16 4 9/2+ -233U G 51.81 4 0.0005 [M1+E2] 0.62 108 -233U 2 G LC=79 $MC=21 -233U G 92.16 4 0.0024 [E2] 19.5 -233U 2 G LC=14.2 $MC=3.95 -233U L 298.810 4 5/2- -233U B 271.3 200.12 5 9.8 -233U S B EAV=74.6 6 -233U G 258.45 2 0.0274 6[E1] 0.0547 11 -233U 2 G KC=0.0433 9$LC=0.00857 17$MC=0.00207 4 -233U G 298.81 2 0.12 5[E1] 0.0396 8 -233U 2 G KC=0.0315 6$LC=0.00609 12$MC=0.00147 3 -233U L 301.94 9 5/2- -233U B 268.1 200.010 2 11.8 -233U S B EAV=73.7 6 -233U G 301.99 100.010 2 -233U L 311.904 4 3/2+ 0.120 NS 15 -233U B 258.2 2026.6 32 7.3 -233U S B EAV=70.8 6 -233U G 271.555 100.323 3E2 0.258 5 -233U 2 G KC=0.0904 18$LC=0.1226 25$MC=0.0334 7 -233U G 311.904 5 38.3 5M1+E2 0.10 1 0.80 2 -233U 2 G KC=0.64 2$LC=0.126 4$MC=0.031 1 -233U L 320.83 4 7/2- -233U B 249.4 200.020 5 10.4 2 -233U S B EAV=68.2 6 -233U G 228.57 5 0.0042 7 -233U G 280.61 5 0.011 2 -233U G 320.73 100.0051 4 -233U L 340.477 4 5/2+ 52 PS 10 -233U B 229.6 2025.9 32 7.2 1 -233U S B EAV=62.4 6 -233U G 28.559 100.071 8M1+E2 0.158 10 313 18 -233U 2 G LC=233 13$MC=60 4 -233U G 41.663 100.014 3[E1] 1.253 25 -233U 2 G LC=0.939 19$MC=0.235 5 -233U G 248.38 4 0.0609 11[E2] 0.346 7 -233U 2 G KC=0.1065 21$LC=0.175 4$MC=0.0479 10 -233U G 300.129 5 6.60 21M1+E2 0.08 3 0.87 2 -233U 2 G KC=0.70 2$LC=0.133 4$MC=0.031 1 -233U G 340.476 5 4.47 3M1+E2 0.23 5 0.62 2 -233U 2 G KC=0.50 2$LC=0.103 3$MC=0.022 1 -233U L 380.43 8 7/2+ -233U B 189.8 200.020 3 9.4 1U -233U S B EAV=50.9 6 -233U G 288.42 100.016 3 -233U G 380.28 100.0037 9 -233U L 398.496 4 1/2+ 55 PS 20 -233U B 171.5 2015.4 8 7 1 -233U S B EAV=45.7 5 -233U G 86.595 5 1.99 10M1+E2 0.056 5 7.08 14 -233U 2 G LC=5.33 11$MC=1.29 3 -233U G 398.492 5 1.408 14E2 0.0835 17 -233U 2 G KC=0.0439 9$LC=0.0291 6$MC=0.00777 16 -233U L 415.758 4 3/2+ 30 PS -233U B 154.3 2025.4 16 6.7 -233U S B EAV=40.9 5 -233U G 17.262 6 0.0041 M1+E2 503 -233U 2 G MC=374 -233U G 75.269 101.30 3M1+E2 0.15 8 11.4 12 -233U 2 G LC=8.6 9$MC=2.11 24 -233U G 103.86 1 0.853 6M1+(E2) 0.1 1 4.21 21 -233U 2 G LC=3.17 15$MC=0.77 5 -233U G 375.404 5 0.684 7E2 0.0981 20 -233U 2 G KC=0.0491 10$LC=0.0360 7$MC=0.00962 19 -233U G 415.764 5 1.747 7M1+E2 2.2 9 0.13 8 -233U 2 G KC=0.09 6$LC=0.032 9$MC=0.0081 21 -233U L 456.114 6 5/2+ -233U B 114.1 200.0011 2 10.6 1 -233U S B EAV=29.8 5 -233U G 455.96 100.0011 2 - +233U 233PA B- DECAY (26.98 D) +233U H TYP=MOD$AUT=V.P.CHECHEV$DAT=31-MAR-2006$COM=See DDEP website$ +233U 2 H TYP=MOD$AUT=M.-M.BE$DAT=05-DEC-2005$COM=See DDEP website$ +233U 3 H TYP=FUL$AUT=V.P.CHECHEV$CUT=01-JAN-2005$ +233U C References:1941Gr03, 1952Br84, 1954Br37, 1955On05, 1956Mc60, 1957Wr37, +233U 2C 1960Un01, 1961Al19, 1962Sc03, 1963Bj03, 1963Bi03, 1966Ze02, 1967Br20, +233U 3C 1968Ma13, 1971Vo02, 1972De67, 1973Va33, 1978Po**, 1979Ge08, 1984Va27, +233U 4C 1985DeZR, 1986Kr10, 1986Jo07, 1988Wo01, 1989Br24, 1990Ak02, 1990Ko41, +233U 5C 1990Pe16, 1992Ra08, 1999Po**, 2000Us01, 2000Wo01, 2000Ch01, 2000Sm**, +233U 6C 2000Sc04, 2000Lu01, 2002Lu01, 2003Au03, 2004Sh07, 2005Hu06, 2005Si15, +233U 7C 2006Ch39, 2006Ha53, 2008Ki07, 2008De10 +233U T Auger electrons and X ray energies and emission intensities: +233U T {U Energy (keV)} {U Intensity} {U Line} +233U T +233U T 94.666 9.10 26 XKA2 +233U T 98.44 14.6 4 XKA1 +233U T +233U T 110.421 |] XKB3 +233U T 111.298 |] 5.25 18 XKB1 +233U T 111.964 |] XKB5II +233U T +233U T 114.407 |] XKB2 +233U T 115.012 |] 1.80 7 XKB4 +233U T 115.377 |] XKO23 +233U T +233U T 11.619-20.714 40.6 11 XL (total) +233U T 11.619 1.05 4 XLL +233U T 13.438-13.615 16.9 6 XLA +233U T 15.399 0.272 16 XLC +233U T 15.727-18.206 18.1 6 XLB +233U T 19.507-20.714 4.23 14 XLG +233U T +233U T 71.78-80.95 |] KLL AUGER +233U T 88.15-98.34 |] 0.95 13 KLX AUGER +233U T 104.42-115.4 |] KXY AUGER +233U T 5.9-21.6 42.2 13 L AUGER +233PA P 0.0 3/2- 26.98 D 2 570.1 20 +233U N 1.0 1.0 1 1.0 +233U L 0 5/2+ 159.1E3 Y 2 +233U B 570.1 206.3 23 9.1 1 +233U S B EAV=169.6 6 +233U L 40.350 4 7/2+ 0.11 NS 8 +233U B 529.8 200.3 19 10.2 1U +233U S B EAV=156.1 6 +233U G 40.349 5 0.024 2M1+E2 1.08 12 580 60 +233U 2 G LC=430 50$MC=117 12$NC=32 4 +233U 3 G OC=7.3 8 +233U L 92.16 4 9/2+ +233U G 51.81 4 0.0005 [M1+E2] 0.62 108 +233U 2 G LC=79 $MC=21 $NC=5.8 +233U 3 G OC=1.3 +233U G 92.16 4 0.0024 [E2] 19.5 +233U 2 G LC=14.2 $MC=3.95 $NC=1.071 +233U 3 G OC=0.246 +233U L 298.810 4 5/2- +233U B 271.3 200.12 5 9.8 +233U S B EAV=74.6 6 +233U G 258.45 2 0.0274 6[E1] 0.0547 11 +233U 2 G KC=0.0433 9$LC=0.00857 17$MC=0.00207 4$NC=0.000553 8 +233U 3 G OC=1.318E-4 19 +233U G 298.81 2 0.12 5[E1] 0.0396 8 +233U 2 G KC=0.0315 6$LC=0.00609 12$MC=0.00147 3$NC=0.000393 8 +233U 3 G OC=9.38E-5 20 +233U L 301.94 9 5/2- +233U B 268.1 200.010 2 11.8 +233U S B EAV=73.7 6 +233U G 301.99 100.010 2 +233U L 311.904 4 3/2+ 0.120 NS 15 +233U B 258.2 2026.6 32 7.3 +233U S B EAV=70.8 6 +233U G 271.555 100.323 3E2 0.258 5 +233U 2 G KC=0.0904 18$LC=0.1226 25$MC=0.0334 7$NC=0.00905 18 +233U 3 G OC=0.00210 4 +233U G 311.904 5 38.3 5M1+E2 0.10 1 0.80 2 +233U 2 G KC=0.64 2$LC=0.126 4$MC=0.031 1$NC=0.00896 10 +233U 3 G OC=0.00218 3 +233U L 320.83 4 7/2- +233U B 249.4 200.020 5 10.4 2 +233U S B EAV=68.2 6 +233U G 228.57 5 0.0042 7 +233U G 280.61 5 0.011 2 +233U G 320.73 100.0051 4 +233U L 340.477 4 5/2+ 52 PS 10 +233U B 229.6 2025.9 32 7.2 1 +233U S B EAV=62.4 6 +233U G 28.559 100.071 8M1+E2 0.158 10 313 18 +233U 2 G LC=233 13$MC=60 4$NC=16.1 10 +233U 3 G OC=3.82 22 +233U G 41.663 100.014 3[E1] 1.253 25 +233U 2 G LC=0.939 19$MC=0.235 5$NC=0.0621 9 +233U 3 G OC=0.01398 20 +233U G 248.38 4 0.0609 11[E2] 0.346 7 +233U 2 G KC=0.1065 21$LC=0.175 4$MC=0.0479 10$NC=0.01301 26 +233U 3 G OC=0.00301 6 +233U G 300.129 5 6.60 21M1+E2 0.08 3 0.87 2 +233U 2 G KC=0.70 2$LC=0.133 4$MC=0.031 1$NC=0.00999 20 +233U 3 G OC=0.00243 4 +233U G 340.476 5 4.47 3M1+E2 0.23 5 0.62 2 +233U 2 G KC=0.50 2$LC=0.103 3$MC=0.022 1$NC=0.0054 17 +233U 3 G OC=0.0013 5 +233U L 380.43 8 7/2+ +233U B 189.8 200.020 3 9.4 1U +233U S B EAV=50.9 6 +233U G 288.42 100.016 3 +233U G 380.28 100.0037 9 +233U L 398.496 4 1/2+ 55 PS 20 +233U B 171.5 2015.4 8 7 1 +233U S B EAV=45.7 5 +233U G 86.595 5 1.99 10M1+E2 0.056 5 7.08 14 +233U 2 G LC=5.33 11$MC=1.29 3$NC=0.349 7 +233U 3 G OC=0.0847 17 +233U G 398.492 5 1.408 14E2 0.0835 17 +233U 2 G KC=0.0439 9$LC=0.0291 6$MC=0.00777 16$NC=0.00210 4 +233U 3 G OC=0.0005 7 +233U L 415.758 4 3/2+ 30 PS +233U B 154.3 2025.4 16 6.7 +233U S B EAV=40.9 5 +233U G 17.262 6 0.0041 M1+E2 503 +233U 2 G MC=374 +233U G 75.269 101.30 3M1+E2 0.15 8 11.4 12 +233U 2 G LC=8.6 9$MC=2.11 24$NC=0.57 7 +233U 3 G OC=0.137 15 +233U G 103.86 1 0.853 6M1+(E2) 0.1 1 4.21 21 +233U 2 G LC=3.17 15$MC=0.77 5$NC=0.208 12 +233U 3 G OC=0.050 3 +233U G 375.404 5 0.684 7E2 0.0981 20 +233U 2 G KC=0.0491 10$LC=0.0360 7$MC=0.00962 19$NC=0.00261 5 +233U 3 G OC=0.000610 12 +233U G 415.764 5 1.747 7M1+E2 2.2 9 0.13 8 +233U 2 G KC=0.09 6$LC=0.032 9$MC=0.0081 21$NC=0.0022 5 +233U 3 G OC=0.00052 12 +233U L 456.114 6 5/2+ +233U B 114.1 200.0011 2 10.6 1 +233U S B EAV=29.8 5 +233U G 455.96 100.0011 2 + diff --git a/HEN_HOUSE/spectra/lnhb/Pa-234.txt b/HEN_HOUSE/spectra/lnhb/Pa-234.txt index 3d5427164..22eb34cd3 100644 --- a/HEN_HOUSE/spectra/lnhb/Pa-234.txt +++ b/HEN_HOUSE/spectra/lnhb/Pa-234.txt @@ -1,819 +1,1044 @@ -234U 234PA B- DECAY (6.70 H) -234U H TYP=Full$AUT=Huang$CUT=31-DEC-2009$ -234U C Evaluation history: Type=Full;Author=Huang;Cutoff date=31-DEC-2009 -234U T Auger electrons and X ray energies and emission intensities: -234U T {U Energy (keV)} {U Intensity} {U Line} -234U T -234U T 94.666 10.5 6 XKA2 -234U T 98.44 16.8 9 XKA1 -234U T -234U T 110.421 |] XKB3 -234U T 111.298 |] 6.1 4 XKB1 -234U T 111.964 |] XKB5II -234U T -234U T 114.407 |] XKB2 -234U T 115.012 |] 2.0 1 XKB4 -234U T 115.377 |] XKO23 -234U T -234U T 11.6185-20.7141 77 10 XL (total) -234U T 11.6185 XLL -234U T 13.4382-13.6146 XLA -234U T 15.399 XLC -234U T 15.7268-18.2061 XLB -234U T 19.5072-20.7141 XLG -234U T -234U T 71.776-80.954 |] KLL AUGER -234U T 88.153-98.429 |] 1.08 6 KLX AUGER -234U T 104.51-115.59 |] KXY AUGER -234U T 5.9-21.6 77 10 L AUGER -234PA P 0.0 4+ 6.70 H 5 2195 4 -234U N 1.0 1.0 1 1.0 -234U G 401.8 2 0.036 11 -234U G 425.3 2 0.036 11 -234U G 643.2 2 0.027 9 -234U G 659.8 1 0.27 4 -234U G 711.5 1 0.156 25 -234U G 778.6 2 0.046 10 -234U G 824.2 2 1.25 15 -234U G 846.1 2 0.052 12 -234U G 920.5 2 0.029 8 -234U G 992.0 2 0.083 22 -234U G 1023.6 2 0.062 22 -234U G 1025.3 2 0.052 22 -234U G 1035.9 2 0.026 10 -234U G 1220.4 2 0.062 12 -234U G 1296.4 2 0.029 7 -234U G 1301.2 2 0.018 5 -234U G 1327.0 2 0.018 5 -234U G 1507.3 2 0.020 5 -234U G 1520.7 2 0.0094 9 -234U G 1538.8 2 0.014 4 -234U G 1655.7 1 0.026 4 -234U G 1664.8 3 0.018 7 -234U G 1743.2 2 0.033 8 -234U G 1757.5 1 0.024 6 -234U G 1830.8 3 0.0042 11 -234U G 1849.8 2 0.028 7 -234U G 1927.9 4 0.054 12 -234U G 1935.2 4 0.0094 -234U L 0 0+ 2.455E5 Y 6 -234U L 43.481 152+ 0.252 NS 7 -234U G 43.49 2 0.12 3E2 713 11 -234U 2 G LC=520 8$MC=143.7 21 -234U L 143.375 214+ -234U B 2052 4 5 9.2 -234U S B EAV=732.2 17 -234U G 99.86 2 3.2 6E2 13.42 19 -234U 2 G LC=9.77 14$MC=2.71 4 -234U L 296.075 246+ -234U G 152.71 2 6.0 7E2 2.14 3 -234U 2 G KC=0.217 3$LC=1.404 20$MC=0.388 6 -234U L 497.05 4 8+ -234U G 200.97 3 0.90 13E2 0.734 11 -234U 2 G KC=0.1534 22$LC=0.424 6$MC=0.1166 17 -234U L 786.295 151- -234U G 742.813 5 2.08 21E1 0.00636 9 -234U 2 G KC=0.00518 8$LC=8.95E-4 13$MC=2.13E-4 3 -234U G 786.272 221.21 13(E1) 0.00573 8 -234U 2 G KC=0.00467 7$LC=8.04E-4 12$MC=1.91E-4 3 -234U L 809.92 8 0+ 0.1 NS -234U G 766.4 2 0.26 5(E2) 0.0187 3 -234U 2 G KC=0.01336 19$LC=0.00396 6$MC=1003E-6 14 -234U G 810.0 7 -234U L 849.265 233- -234U B 1346 4 0.8 9.3 1 -234U S B EAV=452.1 16 -234U G 705.9 1 2.29 23[E1] 0.0069810 -234U 2 G KC=0.00568 8$LC=9.87E-4 14$MC=2.35E-4 4 -234U G 805.80 5 2.5 3[E1] 0.00549 8 -234U 2 G KC=0.00447 7$LC=7.68E-4 11$MC=1.83E-4 3 -234U L 851.73 5 2+ 1.71 PS -234U G 41.82 11 -234U G 708.3 2 0.023 9[E2] 0.0219 3 -234U 2 G KC=0.01537 22$LC=0.00489 7$MC=1246E-6 18 -234U G 808.4 3 0.036 11+E2 4.2 -234U 2 G KC=3.30000 7$LC=0.9 10 -234U G 851.8 1 0.073 22[E2] 0.0151322 -234U 2 G KC=0.01109 16$LC=0.00302 5$MC=7.59E-4 11 -234U L 926.744 212+ 1.38 PS 17 -234U G 783.4 1 0.30 4[E2] 0.0179 3 -234U 2 G KC=0.01285 18$LC=0.00374 6$MC=9.46E-4 14 -234U G 883.24 4 9.7 11E2 0.0140920 -234U 2 G KC=0.01040 15$LC=0.00276 4$MC=6.92E-4 10 -234U G 926.7 1 7.3 12(E2) 0.0128418 -234U 2 G KC=0.00956 14$LC=0.00245 4$MC=6.13E-4 9 -234U L 947.59 5 4+ -234U B 1247 4 0.8 9.2 -234U S B EAV=414.4 16 -234U G 804.1 1 0.62 22+E2 0.37 -234U 2 G KC=0.1559 8$LC=0.11056 15$MC=0.10254 4 -234U G 904.2 1 0.34 4[E2] 0.0134619 -234U 2 G KC=0.00998 14$LC=0.00260 4$MC=6.52E-4 10 -234U L 962.55 3 5- -234U B 1232 4 0.4 9.4 1 -234U S B EAV=408.7 16 -234U G 666.5 1 1.18 13[E1] 0.0077711 -234U 2 G KC=0.00631 9$LC=1103E-6 16$MC=2.63E-4 4 -234U G 819.2 1 1.9 2[E1] 0.00533 8 -234U 2 G KC=0.00434 6$LC=7.44E-4 11$MC=1770E-7 25 -234U L 968.45 3 3+ -234U B 1227 4 2.5 8.6 -234U S B EAV=406.4 16 -234U G 825.1 2 1.9 2[E2] 0.0161123 -234U 2 G KC=0.01173 17$LC=0.00327 5$MC=8.25E-4 12 -234U G 925.0 1 7.9 9(E2) 0.0128818 -234U 2 G KC=0.00959 14$LC=0.00246 4$MC=6.16E-4 9 -234U L 989.444 202- 0.76 NS 4 -234U B 1206 4 3.1 8.5 1U -234U S B EAV=398.5 16 -234U G 62.70 1 1.6 5E1 0.426 6 -234U 2 G LC=0.320 5$MC=0.0791 11 -234U G 140.15 2 0.51 7M1+E2 1.2 6 5.3 18 -234U 2 G KC=2.9 22$LC=1.76 25$MC=0.47 9 -234U G 203.12 3 1.24 15M1+E2 1.5 4 1.4 4 -234U 2 G KC=0.8 4$LC=0.422 10$MC=0.1113 16 -234U G 946.00 3 13.5 15(E1) 0.00412 6 -234U 2 G KC=0.00337 5$LC=5.71E-4 8$MC=1355E-7 19 -234U L 1023.795 243- -234U B 1171.2 405 8.3 1 -234U S B EAV=385.4 16 -234U G 34.30 4 0.0037 4(E2) 2270 40 -234U 2 G LC=1660 30$MC=457 7 -234U G 54.96 100.0094 [E1] 0.603 9 -234U 2 G LC=0.453 7$MC=0.1123 17 -234U G 97.17 100.24 9[E1] 0.1343 20 -234U 2 G LC=0.1012 15$MC=0.0248 4 -234U G 174.55 3 0.17 3[M1+E2] 2.9 17 -234U 2 G KC=1.9 18$LC=0.74 4$MC=0.193 23 -234U G 880.52 4 4.3 6[E1] 0.00468 7 -234U 2 G KC=0.00382 6$LC=6.51E-4 10$MC=1547E-7 22 -234U G 980.3 1 2.7 [E1] 0.00387 6 -234U 2 G KC=0.00317 5$LC=5.35E-4 8$MC=1270E-7 18 -234U L 1023.92 3 4+ -234U B 1171 4 1.5 13 8.8 -234U S B EAV=385.4 16 -234U G 54.96 100.0094 [M1+E2] 1.3E2 11 -234U 2 G LC=90 80$MC=26 21 -234U G 727.8 2 0.114 15[E2] 0.0207 3 -234U 2 G KC=0.01464 21$LC=0.00454 7$MC=1156E-6 17 -234U G 880.52 4 6.2 8[E2] 0.0141820 -234U 2 G KC=0.01046 15$LC=0.00278 4$MC=6.97E-4 10 -234U G 980.3 1 1.77 [E2] 0.0115217 -234U 2 G KC=0.00866 13$LC=0.00214 3$MC=5.34E-4 8 -234U L 1069.297 224- -234U B 1126 4 8 8 -234U S B EAV=368.3 15 -234U G 45.45 5 0.027 9M1+E2 0.8 4 2.5E2 14 -234U 2 G LC=1.9E2 10$MC=50 30 -234U G 79.84 2 0.062 22E2 38.4 6 -234U 2 G LC=28.0 4$MC=7.76 11 -234U G 100.89 2 0.125 24[E1] 0.1218 17 -234U 2 G LC=0.0917 13$MC=0.0224 4 -234U G 106.68 5 0.036 11[M1] 3.83 6 -234U 2 G LC=2.89 4$MC=0.699 10 -234U G 220.00 8 0.146 25(M1) 2.37 4 -234U 2 G KC=1.89 3$LC=0.366 6$MC=0.0886 13 -234U G 926.0 2 1.8 13[E1] 0.00428 6 -234U 2 G KC=0.00350 5$LC=5.94E-4 9$MC=1409E-7 20 -234U L 1085.07 102+ -234U G 233.6 2 -234U G 235.9 300.005 3 -234U G 298.7 2 0.014 6[E1] 0.0396 6 -234U 2 G KC=0.0315 5$LC=0.00610 9$MC=1470E-6 21 -234U G 942.0 3 0.046 9[E2] 0.0124418 -234U 2 G KC=0.00929 13$LC=0.00236 4$MC=5.89E-4 9 -234U G 1041.1 2 0.032 11[E2M1] 0.023 13 -234U 2 G KC=0.018 11$LC=0.0036 18$MC=0.0009 4 -234U G 1085.3 3 0.027 8[E2] 0.0095014 -234U 2 G KC=0.00725 11$LC=1690E-6 24$MC=4.18E-4 6 -234U L 1090.89 4 5+ -234U B 1104 4 0.69 20 9.04 -234U S B EAV=360.2 15 -234U G 794.9 2 0.68 11[E2] 0.0173525 -234U 2 G KC=0.01253 18$LC=0.00360 5$MC=9.10E-4 13 -234U G 947.7 2 1.63 21[E2] 0.0123018 -234U 2 G KC=0.00919 13$LC=0.00232 4$MC=5.80E-4 9 -234U L 1096.12 9 6+ -234U G 799.7 2 +E2 -234U G 952.7 1 0.083 13 -234U L 1125.29 5 7- -234U G 628.1 1 0.24 5[E1] 0.0086813 -234U 2 G KC=0.00705 10$LC=1239E-6 18$MC=2.96E-4 5 -234U G 829.3 2 0.36 11[E1] 0.00521 8 -234U 2 G KC=0.00425 6$LC=7.27E-4 11$MC=1729E-7 25 -234U L 1126.65 3 2+ -234U G 137.23 5 0.027 9[E1] 0.239 4 -234U 2 G KC=0.184 3$LC=0.0413 6$MC=0.01006 15 -234U G 199.95 5 0.073 22(+E2+M1) 2.0 13 -234U 2 G KC=1.4 13$LC=0.483 21$MC=0.124 4 -234U G 275.04 100.094 23[M1E2] 0.8 6 -234U 2 G KC=0.6 5$LC=0.16 4$MC=0.040 8 -234U G 316.7 1 0.104 14[E2] 0.1597 23 -234U 2 G KC=0.0677 10$LC=0.0674 10$MC=0.0182 3 -234U G 340.2 1 0.041 9[E1] 0.0298 5 -234U 2 G KC=0.0239 4$LC=0.00453 7$MC=1090E-6 16 -234U G 1083.2 1 0.51 6(M1) 0.0317 5 -234U 2 G KC=0.0254 4$LC=0.00477 7$MC=1147E-6 16 -234U G 1126.8 1 0.30 4[E2] 0.0088513 -234U 2 G KC=0.00679 10$LC=1552E-6 22$MC=3.83E-4 6 -234U L 1127.535 255- -234U B 1067 4 1.9 10 8.54 1 -234U S B EAV=346.5 15 -234U G 58.20 6 0.0027 9(E2) 174 3 -234U 2 G LC=126.9 19$MC=35.1 6 -234U G 103.77 2 0.24 4(E2) 11.22 16 -234U 2 G LC=8.17 12$MC=2.27 4 -234U G 164.94 5 0.052 22[E2M1] 3.5 19 -234U 2 G KC=2.2 21$LC=0.91 9$MC=0.24 4 -234U G 278.3 1 0.042 11[E2] 0.238 4 -234U 2 G KC=0.0863 13$LC=0.1112 16$MC=0.0303 5 -234U G 831.5 1 4.2 5[E1] 0.00518 8 -234U 2 G KC=0.00423 6$LC=7.24E-4 11$MC=1721E-7 24 -234U G 984.2 1 1.63 21[E1] 0.00385 6 -234U 2 G KC=0.00315 5$LC=5.31E-4 8$MC=1261E-7 18 -234U L 1165.41 4 3+ -234U G 196.80 5 0.073 22+E2+M1 2.0 13 -234U 2 G KC=1.4 13$LC=0.483 21$MC=0.124 4 -234U G 313.5 1 0.104 14[E2M1] 0.5 4 -234U 2 G KC=0.4 4$LC=0.10 4$MC=0.026 7 -234U G 1021.8 2 0.15 4[M1] 0.0370 6 -234U 2 G KC=0.0297 5$LC=0.00557 8$MC=1340E-6 19 -234U G 1121.7 1 0.25 4M1 0.0289 4 -234U 2 G KC=0.0232 4$LC=0.00434 6$MC=1045E-6 15 -234U L 1172.03 3 6+ -234U G 675.1 1 0.101 14[E2] 0.0242 4 -234U 2 G KC=0.01674 24$LC=0.00558 8$MC=1427E-6 20 -234U G 876.0 1 2.55 23(E2) 0.0143220 -234U 2 G KC=0.01055 15$LC=0.00282 4$MC=7.06E-4 10 -234U G 1028.7 1 0.57 6[E2] 0.0105115 -234U 2 G KC=0.00796 12$LC=0.00191 3$MC=4.75E-4 7 -234U L 1194.761 236- -234U B 1000 4 1.5 8.5 1U -234U S B EAV=312.6 14 -234U G 67.25 100.036 11M1+E2 1.2 3 57 11 -234U 2 G LC=42 8$MC=11.5 22 -234U G 69.46 5 0.018 8[E2M1] 40 30 -234U 2 G LC=32 23$MC=9 7 -234U G 125.46 1 0.79 12E2 4.89 7 -234U 2 G KC=0.216 3$LC=3.41 5$MC=0.945 14 -234U G 232.21 3 0.18 3[E2M1] 1.2 8 -234U 2 G KC=0.9 8$LC=0.27 5$MC=0.070 7 -234U G 898.67 5 3.3 4[E1] 0.00451 7 -234U 2 G KC=0.00369 6$LC=6.27E-4 9$MC=1489E-7 21 -234U L 1214.70 5 4+ -234U B 980 4 0.30 12 9.22 -234U S B EAV=314.2 15 -234U G 267.12 5 0.18 3[E2M1] 0.8 6 -234U 2 G KC=0.6 5$LC=0.17 5$MC=0.044 8 -234U G 365.0 3 0.018 7[E1] 0.0257 4 -234U 2 G KC=0.0206 3$LC=0.00387 6$MC=9.30E-4 14 -234U G 918.4 1 0.100 14[E2] 0.0130619 -234U 2 G KC=0.00971 14$LC=0.00251 4$MC=6.27E-4 9 -234U G 1171.3 1 0.090 13[E2] 0.0082412 -234U 2 G KC=0.00634 9$LC=1423E-6 20$MC=3.50E-4 5 -234U L 1237.24 3 1- -234U G 247.79 7 0.00037 4 -234U G 310.52 100.00013515 -234U G 387.94 6 0.00072 6 -234U G 427.4 4 0.00003110 -234U G 450.93 4 0.0040 19M1+E2 0.7 0.241 4 -234U 2 G KC=0.187 3$LC=0.0400 6$MC=0.00980 14 -234U G 1193.77 2 0.021 6E1 0.00277 4 -234U 2 G KC=0.00226 4$LC=3.77E-4 6$MC=8.92E-5 13 -234U G 1237.3 3 0.0094 E1 0.00262 4 -234U 2 G KC=0.00213 3$LC=3.54E-4 5$MC=8.38E-5 12 -234U L 1261.77 3 7+ -234U G 764.8 2 0.20 5[M1E2] 0.05 3 -234U 2 G KC=0.04 3$LC=0.008 4$MC=0.002 1 -234U G 965.8 1 0.48 6[M1E2] 0.027 16 -234U 2 G KC=0.022 13$LC=0.0043 22$MC=0.0011 5 -234U L 1274.32 9 (5+)+ -234U G 978.2 3 0.090 23 -234U L 1277.45 3 7- -234U G 149.88 3 0.073 22[E2] 2.31 4 -234U 2 G KC=0.220 3$LC=1.526 22$MC=0.422 6 -234U G 780.4 2 0.90 9[E1] 0.00581 9 -234U 2 G KC=0.00474 7$LC=8.15E-4 12$MC=1.94E-4 3 -234U G 981.6 3 0.73 22[E1] 0.00387 6 -234U 2 G KC=0.00316 5$LC=5.34E-4 8$MC=1267E-7 18 -234U L 1312.20 9 3- -234U B 883 4 0.109 18 9.5 1 -234U S B EAV=278.7 15 -234U G 75.0 3 -234U G 343.8 2 0.034 8[E1] 0.0292 5 -234U 2 G KC=0.0233 4$LC=0.00442 7$MC=1064E-6 15 -234U G 365.0 3 -234U G 385.4 1 0.042 11[E1] 0.0229 4 -234U 2 G KC=0.0184 3$LC=0.00343 5$MC=8.24E-4 12 -234U L 1341.33 8 (6+)+ -234U G 379.1 1 0.042 11[E1] 0.0237 4 -234U 2 G KC=0.0190 3$LC=0.00356 5$MC=8.54E-4 12 -234U G 1044.4 2 0.031 3 -234U L 1421.252 246- 33.5 US 20 -234U G 143.78 2 0.32 5(M1+E2) 1 5.31 -234U 2 G KC=3.24 $LC=1.532 $MC=0.403 -234U G 159.48 2 0.66 10[E1] 0.1676 24 -234U 2 G KC=0.1303 19$LC=0.0282 4$MC=0.00684 10 -234U G 226.50 3 4.9 6M1+E2 1.0 3 1.3 3 -234U 2 G KC=0.9 3$LC=0.297 15$MC=0.0759 23 -234U G 249.22 1 2.5 4E1 0.0594 9 -234U 2 G KC=0.0470 7$LC=0.00935 13$MC=0.00226 4 -234U G 293.79 5 3.0 4M1+E2 1.7 4 0.42 10 -234U 2 G KC=0.28 9$LC=0.109 9$MC=0.0283 18 -234U G 295.91 8 0.146 25[M1+E2] 0.6 5 -234U 2 G KC=0.5 4$LC=0.12 4$MC=0.031 8 -234U G 330.40 5 0.78 9[E1] 0.0318 5 -234U 2 G KC=0.0254 4$LC=0.00484 7$MC=1165E-6 17 -234U G 351.9 1 0.42 5E2 0.1175 17 -234U 2 G KC=0.0555 8$LC=0.0455 7$MC=0.01222 18 -234U G 397.7 3 0.027 7[M2] 1.349 20 -234U 2 G KC=0.986 14$LC=0.270 4$MC=0.0687 10 -234U G 458.68 5 1.14 12M1+E2 1.4 4 0.14 5 -234U 2 G KC=0.11 4$LC=0.028 5$MC=0.0071 11 -234U G 1125.2 1 0.36 8[E1] 0.00305 5 -234U 2 G KC=0.00250 4$LC=4.18E-4 6$MC=9.91E-5 14 -234U G 1277.7 2 0.045 9[M2] 0.0473 7 -234U 2 G KC=0.0370 6$LC=0.00771 11$MC=0.00188 3 -234U L 1447.89 105- -234U B 747 4 0.11 3 9.25 1 -234U S B EAV=230.3 14 -234U G 320.4 1 0.052 8[E2M1] 0.5 4 -234U 2 G KC=0.4 3$LC=0.10 4$MC=0.024 7 -234U G 1151.4 3 0.032 10[E1] 0.00294 5 -234U 2 G KC=0.00240 4$LC=4.02E-4 6$MC=9.51E-5 14 -234U L 1456.54 7 (2-)+ -234U G 669.7 1 0.0006 -234U G 1414.4 2 0.0028 -234U L 1486.17 12(3-)+ -234U B 709 4 0.12 3 9.14 -234U S B EAV=216.9 14 -234U G 559.2 2 0.073 22[E1] 0.0108416 -234U 2 G KC=0.00877 13$LC=1562E-6 22$MC=3.73E-4 6 -234U G 1342.9 2 0.012 5[E1] 0.00232 4 -234U 2 G KC=0.00185 3$LC=3.07E-4 5$MC=7.26E-5 11 -234U G 1442.8 2 0.031 7[E1] 0.00212 3 -234U 2 G KC=1643E-6 23$LC=2.71E-4 4$MC=6.41E-5 9 -234U L 1496.14 3 3+ -234U B 699 4 2.7 7.8 -234U S B EAV=213.5 14 -234U G 221.83 100.073 22[E2] 0.513 8 -234U 2 G KC=0.1301 19$LC=0.280 4$MC=0.0767 11 -234U G 330.40 5 M1+E2 0.7 0.562 8 -234U 2 G KC=0.431 6$LC=0.0980 14$MC=0.0242 4 -234U G 369.50 5 2.5 3M1 0.565 8 -234U 2 G KC=0.450 7$LC=0.0866 13$MC=0.0209 3 -234U G 426.95 5 0.46 5[E1] 0.0185 3 -234U 2 G KC=0.01491 21$LC=0.00274 4$MC=6.58E-4 10 -234U G 472.3 1 0.36 4[M1] 0.290 4 -234U 2 G KC=0.231 4$LC=0.0443 7$MC=0.01069 15 -234U G 506.75 5 1.30 14[E1] 0.0131419 -234U 2 G KC=0.01061 15$LC=0.00191 3$MC=4.57E-4 7 -234U G 527.90 100.40 5(M1) 0.215 3 -234U 2 G KC=0.1716 24$LC=0.0328 5$MC=0.00790 11 -234U G 569.5 1 9.3 12M1 0.1754 25 -234U 2 G KC=0.1401 20$LC=0.0267 4$MC=0.00643 9 -234U G 646.5 1 0.114 15[E1] 0.0082212 -234U 2 G KC=0.00668 10$LC=1170E-6 17$MC=2.79E-4 4 -234U G 1352.9 1 1.16 12M1 0.0176625 -234U 2 G KC=0.01412 20$LC=0.00263 4$MC=6.33E-4 9 -234U G 1452.7 1 0.81 9[M1] 0.0146821 -234U 2 G KC=0.01169 17$LC=0.00218 3$MC=5.24E-4 8 -234U L 1502.38 8 3,4++ -234U B 693 4 0.25 4 8.78 -234U S B EAV=211.3 14 -234U G 1359.0 1 0.156 25 -234U G 1458.9 1 0.094 23 -234U L 1533.37 5 (4-)+ -234U B 662 4 0.21 4 8.79 -234U S B EAV=200.6 14 -234U G 464.2 1 0.031 11[M1] 0.304 5 -234U 2 G KC=0.243 4$LC=0.0464 7$MC=0.01120 16 -234U G 543.8 1 0.135 24[E2] 0.0389 6 -234U 2 G KC=0.0247 4$LC=0.01049 15$MC=0.00273 4 -234U G 1389.6 2 0.073 22[E1] 0.00222 4 -234U 2 G KC=1749E-6 25$LC=2.89E-4 4$MC=6.84E-5 10 -234U L 1537.25 3 4+ -234U B 658 4 0.9 8.1 -234U S B EAV=199.3 14 -234U G 372.0 1 1.23 14M1(+E2) 0.3 0.517 8 -234U 2 G KC=0.410 6$LC=0.0811 12$MC=0.0197 3 -234U G 409.8 1 0.34 5[E1] 0.0202 3 -234U 2 G KC=0.01620 23$LC=0.00300 5$MC=0.00072 1 -234U G 446.6 1 0.114 15[M1] 0.338 5 -234U 2 G KC=0.269 4$LC=0.0516 8$MC=0.01245 18 -234U G 468.0 1 0.22 3[E1] 0.0153922 -234U 2 G KC=0.01241 18$LC=0.00226 4$MC=5.41E-4 8 -234U G 513.4 1 0.38 [M1] 0.232 4 -234U 2 G KC=0.185 3$LC=0.0353 5$MC=0.00852 12 -234U G 513.5 1 0.76 [E1] 0.0128018 -234U 2 G KC=0.01035 15$LC=0.00186 3$MC=4.45E-4 7 -234U G 568.9 2 3.6 6M1 0.1759 25 -234U 2 G KC=0.1404 20$LC=0.0268 4$MC=0.00645 9 -234U G 590.3 100.036 11[E2M1] 0.10 7 -234U 2 G KC=0.07 6$LC=0.016 8$MC=0.0040 19 -234U G 685.1 2 0.15 4 -234U G 1241.2 1 0.23 3(E2) 0.0074011 -234U 2 G KC=0.00573 8$LC=1251E-6 18$MC=3.07E-4 5 -234U G 1393.9 1 2.08 21M1 0.0163423 -234U 2 G KC=0.01304 19$LC=0.00243 4$MC=5.85E-4 9 -234U G 1493.6 1 0.104 14[E2] 0.00531 8 -234U 2 G KC=0.00414 6$LC=8.42E-4 12$MC=2.05E-4 3 -234U L 1543.71 5 4+ -234U B 651 4 0.10 9 9.1 -234U S B EAV=197.1 14 -234U G 474.2 2 0.036 11[E1] 0.0149921 -234U 2 G KC=0.01209 17$LC=0.00219 3$MC=5.26E-4 8 -234U G 575.5 1 0.027 9[E2M1] 0.10 7 -234U 2 G KC=0.08 6$LC=0.017 9$MC=0.0043 20 -234U G 617.0 2 0.052 22[E2] 0.0294 5 -234U 2 G KC=0.0197 3$LC=0.00720 11$MC=0.00186 3 -234U G 1247.8 2 0.022 6[E2] 0.0073311 -234U 2 G KC=0.00567 8$LC=1237E-6 18$MC=3.04E-4 5 -234U G 1400.3 1 0.18 3[E2M1] 0.011 6 -234U 2 G KC=0.009 5$LC=0.0017 8$MC=0.00041 18 -234U G 1500.0 2 0.011 4[E2] 0.00528 8 -234U 2 G KC=0.00411 6$LC=8.35E-4 12$MC=2.03E-4 3 -234U L 1548.10 8 (5)+ -234U B 647 4 0.078 20 9.18 -234U S B EAV=195.6 14 -234U G 452.4 3 0.027 9 -234U G 478.6 1 0.125 15[E1] 0.0147221 -234U 2 G KC=0.01187 17$LC=0.00215 3$MC=5.16E-4 8 -234U G 1252.6 2 0.018 8 -234U L 1552.554 245+ 2.200 NS 25 -234U B 642 4 19.6 18 6.77 -234U S B EAV=194.0 14 -234U G 131.30 1 18.2 16E1 0.265 4 -234U 2 G KC=0.204 3$LC=0.0463 7$MC=0.01128 16 -234U G 461.5 1 -234U G 529.1 3 0.09 4[E2M1] 0.13 9 -234U 2 G KC=0.10 8$LC=0.022 11$MC=0.0054 25 -234U G 584.1 1 0.18 30[E2] 0.0331 5 -234U 2 G KC=0.0217 3$LC=0.00845 12$MC=0.00219 3 -234U G 604.6 3 0.052 22[E2M1] 0.09 6 -234U 2 G KC=0.07 5$LC=0.015 8$MC=0.0037 18 -234U G 1256.5 1 0.059 8[M1E2] 0.014 8 -234U 2 G KC=0.011 6$LC=0.0022 10$MC=0.00054 24 -234U G 1409.1 2 0.045 10 -234U L 1581.67 10(5-)+ -234U B 613 4 0.05 3 9.3 -234U S B EAV=184.1 14 -234U G 558.0 2 0.094 23[E2] 0.0367 6 -234U 2 G KC=0.0236 4$LC=0.00970 14$MC=0.00252 4 -234U G 619.0 2 0.036 11[M1+E2] 0.08 6 -234U 2 G KC=0.07 5$LC=0.014 7$MC=0.0035 17 -234U G 634.3 2 -234U L 1588.84 5 5+ -234U B 606 4 0.7 8.1 -234U S B EAV=181.7 14 -234U G 55.45 5 0.027 9(E1) 0.589 9 -234U 2 G LC=0.443 7$MC=0.1097 16 -234U G 394.1 1 0.094 14[E1] 0.0219 3 -234U 2 G KC=0.01755 25$LC=0.00326 5$MC=7.84E-4 11 -234U G 461.5 1 0.034 11[M1] 0.309 5 -234U 2 G KC=0.246 4$LC=0.0472 7$MC=0.01138 16 -234U G 498.0 1 0.062 12[M1] 0.252 4 -234U 2 G KC=0.201 3$LC=0.0384 6$MC=0.00925 13 -234U G 519.60 100.40 5[E1] 0.0125118 -234U 2 G KC=0.01011 15$LC=0.00181 3$MC=4.34E-4 6 -234U G 565.2 1 1.04 11(M1) 0.179 3 -234U 2 G KC=0.1429 20$LC=0.0272 4$MC=0.00656 10 -234U G 1292.8 1 0.47 6M1 0.0199 3 -234U 2 G KC=0.01592 23$LC=0.00297 5$MC=7.15E-4 10 -234U G 1445.4 1 0.32 5[M1] 0.0148821 -234U 2 G KC=0.01185 17$LC=0.00221 3$MC=5.31E-4 8 -234U L 1619.46 9 (6+)+ -234U B 576 4 0.035 20 9.36 2 -234U S B EAV=171.4 14 -234U G 357.9 1 0.036 11[M1E2] 0.4 3 -234U 2 G KC=0.27 22$LC=0.07 3$MC=0.017 6 -234U G 446.6 1 -234U G 529.1 3 -234U G 657.4 1 0.40 5 -234U G 1475.8 2 0.008 4 -234U L 1649.99 12(6-)+ -234U B 545 4 0.18 4 8.64 2 -234U S B EAV=164.6 13 -234U G 553.70 100.045 16[E1] 0.0110516 -234U 2 G KC=0.00894 13$LC=1594E-6 23$MC=3.81E-4 6 -234U G 1354.6 2 0.14 4[E1] 0.00229 4 -234U 2 G KC=0.00183 3$LC=3.02E-4 5$MC=7.15E-5 10 -234U L 1653.35 7 (3+)+ -234U B 542 4 0.95 13 7.84 -234U S B EAV=160.1 14 -234U G 629.4 1 0.35 6(M1) 0.1342 19 -234U 2 G KC=0.1072 15$LC=0.0204 3$MC=0.00491 7 -234U G 663.9 1 0.54 9[E1] 0.0078211 -234U 2 G KC=0.00636 9$LC=1111E-6 16$MC=2.65E-4 4 -234U G 1510.1 2 0.0094 -234U L 1693.42 3 5- -234U B 502 4 6.9 8 6.87 1 -234U S B EAV=146.8 14 -234U G 140.91 3 0.31 5[E1] 0.224 4 -234U 2 G KC=0.1732 25$LC=0.0386 6$MC=0.00940 14 -234U G 272.28 5 1.09 14M1+E2 0.64 1.004 14 -234U 2 G KC=0.766 11$LC=0.1783 25$MC=0.0442 7 -234U G 416.1 1 0.036 11[E2] 0.0746 11 -234U 2 G KC=0.0405 6$LC=0.0251 4$MC=0.00666 10 -234U G 478.6 1 -234U G 498.0 1 -234U G 521.40 100.75 9[E1] 0.0124218 -234U 2 G KC=0.01004 14$LC=0.00180 3$MC=4.31E-4 6 -234U G 565.2 1 -234U G 602.6 1 0.54 6[E1] 0.0093914 -234U 2 G KC=0.00762 11$LC=1345E-6 19$MC=3.21E-4 5 -234U G 624.2 1 0.35 5(M1+E2) 0.7 0.1015 15 -234U 2 G KC=0.0799 12$LC=0.01627 23$MC=0.00396 6 -234U G 669.7 1 1.0 1[E1] 0.0077011 -234U 2 G KC=0.00626 9$LC=1092E-6 16$MC=2.60E-4 4 -234U G 730.9 2 0.63 10[M1E2] 0.06 4 -234U 2 G KC=0.04 3$LC=0.009 5$MC=0.0022 11 -234U G 745.9 1 0.32 5[E1] 0.00631 9 -234U 2 G KC=0.00514 8$LC=8.88E-4 13$MC=2.11E-4 3 -234U G 844.1 1 0.43 5[E2] 0.0154022 -234U 2 G KC=0.01127 16$LC=0.00309 5$MC=7.77E-4 11 -234U G 1397.5 2 0.083 22[E1] 0.00220 3 -234U 2 G KC=1733E-6 25$LC=2.86E-4 4$MC=6.78E-5 10 -234U G 1550.1 1 0.073 13[E1] 0.00196 3 -234U 2 G KC=1460E-6 21$LC=2.40E-4 4$MC=5.68E-5 8 -234U L 1722.89 4 3- -234U B 472 4 8.4 9 6.7 1 -234U S B EAV=137.2 13 -234U G 595.4 2 0.094 23[E2] 0.0317 5 -234U 2 G KC=0.0210 3$LC=0.00799 12$MC=0.00207 3 -234U G 653.7 1 0.47 8M1 0.1213 17 -234U 2 G KC=0.0969 14$LC=0.0184 3$MC=0.00443 7 -234U G 699.03 5 M1 0.1015 15 -234U 2 G KC=0.0811 12$LC=0.01537 22$MC=0.00370 6 -234U G 733.39 5 7.0 8M1 0.0893 13 -234U 2 G KC=0.0714 10$LC=0.01351 19$MC=0.00325 5 -234U G 761.0 2 0.073 22[E2] 0.0189 3 -234U 2 G KC=0.01353 19$LC=0.00403 6$MC=1023E-6 15 -234U G 874.0 3 0.036 8[E2M1] 0.035 21 -234U 2 G KC=0.028 18$LC=0.006 3$MC=0.0014 7 -234U G 1679.5 1 0.077 18 -234U L 1723.424 244+ -234U B 472 4 36 5 6.06 -234U S B EAV=137.1 13 -234U G 134.61 2 0.114 23M1 9.50 14 -234U 2 G KC=7.54 11$LC=1.480 21$MC=0.358 5 -234U G 170.85 2 0.51 7M1 4.83 7 -234U 2 G KC=3.84 6$LC=0.749 11$MC=0.181 3 -234U G 179.80 8 0.045 16[M1] 4.19 6 -234U 2 G KC=3.33 5$LC=0.648 10$MC=0.1567 22 -234U G 186.15 2 1.78 19M1 3.79 6 -234U 2 G KC=3.02 5$LC=0.587 9$MC=0.142 2 -234U G 227.25 3 5.8 6M1 2.17 3 -234U 2 G KC=1.724 25$LC=0.335 5$MC=0.0809 12 -234U G 558.0 2 -234U G 596.9 1 -234U G 632.6 2 0.036 11[E2M1] 0.08 6 -234U 2 G KC=0.06 5$LC=0.013 7$MC=0.0033 16 -234U G 699.03 5 3.6 4 -234U G 755.0 1 1.23 13(E2M1) 0.05 4 -234U 2 G KC=0.04 3$LC=0.008 5$MC=0.002 1 -234U G 796.1 1 2.6 3[E2] 0.0173025 -234U 2 G KC=0.01249 18$LC=0.00359 5$MC=9.06E-4 13 -234U G 1426.9 1 0.17 3 -234U G 1579.9 1 0.073 22 -234U L 1737.42 7 3+ -234U B 458 4 1.16 14 7.51 -234U S B EAV=132.5 14 -234U G 713.7 1 0.146 25[E1] 0.0068410 -234U 2 G KC=0.00557 8$LC=9.66E-4 14$MC=2.30E-4 4 -234U G 748.1 3 0.104 23[E1] 0.00628 9 -234U 2 G KC=0.00511 8$LC=8.83E-4 13$MC=2.10E-4 3 -234U G 1594.0 1 0.31 4M1E2 0.008 4 -234U 2 G KC=0.006 3$LC=0.0012 5$MC=0.00029 12 -234U G 1693.8 2 0.7 1 -234U L 1738.18 6 (3+)+ -234U B 457 4 0.78 19 7.68 -234U S B EAV=132.3 14 -234U G 612.0 1 0.38 5(M1) 0.1447 21 -234U 2 G KC=0.1156 17$LC=0.0220 3$MC=0.00530 8 -234U G 811.5 1 0.125 15[M1E2] 0.04 3 -234U 2 G KC=0.033 22$LC=0.007 4$MC=0.0017 9 -234U G 1695.0 3 0.27 7 -234U L 1761.86 6 (4-)+ -234U B 433 4 2.8 4 7.05 -234U S B EAV=124.7 13 -234U G 634.3 2 0.135 24[M1] 0.1315 19 -234U 2 G KC=0.1050 15$LC=0.0200 3$MC=0.00481 7 -234U G 692.6 1 1.25 13(M1) 0.1040 15 -234U 2 G KC=0.0831 12$LC=0.01575 22$MC=0.00379 6 -234U G 738.0 1 1.16 13(M1) 0.0878 13 -234U 2 G KC=0.0702 10$LC=0.01329 19$MC=0.00320 5 -234U G 772.4 2 0.073 22[E2] 0.0184 3 -234U 2 G KC=0.01318 19$LC=0.00388 6$MC=9.83E-4 14 -234U G 792.8 3 0.045 11[E1] 0.00565 8 -234U 2 G KC=0.00460 7$LC=7.91E-4 11$MC=1.88E-4 3 -234U G 1618.3 2 0.009 4 -234U L 1770.79 9 (3+)+ -234U B 424 4 0.129 17 8.36 -234U S B EAV=121.8 13 -234U G 802.3 2 0.031 9[M1] 0.0703 10 -234U 2 G KC=0.0563 8$LC=0.01062 15$MC=0.00256 4 -234U G 1627.3 1 0.076 11 -234U G 1727.8 2 0.020 5 -234U L 1782.58 3 5+ -234U B 412 4 8 3 6.53 -234U S B EAV=118.1 13 -234U G 59.19 5 0.032 11[M1+E2] 90 70 -234U 2 G LC=70 50$MC=18 15 -234U G 193.73 3 0.50 8[M1+E2] 2.1 13 -234U 2 G KC=1.4 13$LC=0.510 16$MC=0.132 6 -234U G 245.37 2 0.76 11M1 1.749 25 -234U 2 G KC=1.392 20$LC=0.270 4$MC=0.0652 10 -234U G 360.6 3 0.018 7[E1] 0.0264 4 -234U 2 G KC=0.0211 3$LC=0.00397 6$MC=9.55E-4 14 -234U G 617.0 2 -234U G 655.2 2 0.135 24[E1] 0.0080212 -234U 2 G KC=0.00651 10$LC=1140E-6 16$MC=2.72E-4 4 -234U G 758.9 1 0.25 3[M1E2] 0.05 4 -234U 2 G KC=0.04 3$LC=0.008 5$MC=0.002 1 -234U G 814.2 1 0.31 4[E2] 0.0165424 -234U 2 G KC=0.01201 17$LC=0.00338 5$MC=8.54E-4 12 -234U G 1485.4 2 0.030 7[M1] 0.0138720 -234U 2 G KC=0.01102 16$LC=0.00205 3$MC=4.94E-4 7 -234U G 1638.1 1 0.208 21(M1) 0.0108316 -234U 2 G KC=0.00850 12$LC=1581E-6 23$MC=3.80E-4 6 -234U L 1784.19 134+ -234U B 411 4 0.061 11 8.64 -234U S B EAV=117.6 13 -234U G 857.7 2 0.036 8[E2] 0.0149321 -234U 2 G KC=0.01095 16$LC=0.00297 5$MC=7.46E-4 11 -234U G 1488.0 2 0.014 6 -234U G 1640.5 3 0.010 4 -234U L 1793.05 6 4+ -234U B 402 4 0.41 8 7.78 -234U S B EAV=114.8 13 -234U G 240.2 1 0.052 22[M1E2] 1.1 8 -234U 2 G KC=0.8 7$LC=0.24 5$MC=0.062 8 -234U G 769.1 1 0.187 20[M1E2] 0.05 3 -234U 2 G KC=0.038 25$LC=0.008 4$MC=0.0019 10 -234U G 1496.0 2 0.036 9 -234U G 1650.2 2 0.006 -234U G 1750.0 1 0.064 10 -234U L 1811.62 6 4+ -234U B 383 4 1.43 15 7.17 -234U S B EAV=108.9 13 -234U G 596.9 1 0.20 3[M1] 0.1547 22 -234U 2 G KC=0.1235 18$LC=0.0235 4$MC=0.00566 8 -234U G 683.9 2 0.16 4[E1] 0.0074011 -234U 2 G KC=0.00602 9$LC=1049E-6 15$MC=2.50E-4 4 -234U G 685.1 2 [E2] 0.0235 4 -234U 2 G KC=0.01631 23$LC=0.00535 8$MC=1369E-6 20 -234U G 848.9 2 0.027 8[E1] 0.00500 7 -234U 2 G KC=0.00408 6$LC=6.96E-4 10$MC=1655E-7 24 -234U G 863.2 2 0.073 22[E2M1] 0.036 22 -234U 2 G KC=0.029 18$LC=0.006 3$MC=0.0014 7 -234U G 960.0 1 0.073 13[E2] 0.0119917 -234U 2 G KC=0.00899 13$LC=0.00225 4$MC=5.62E-4 8 -234U G 1515.6 2 0.073 13 -234U G 1668.4 1 0.77 9(M1) 0.0103515 -234U 2 G KC=0.00809 12$LC=1505E-6 21$MC=3.62E-4 5 -234U G 1768.0 3 0.020 5 -234U L 1843.88 173,4,5-+ -234U B 351 4 0.17 3 7.97 -234U S B EAV=98.9 13 -234U G 994.6 3 0.062 22 -234U G 1700.5 2 0.104 14 -234U L 1863.08 15(5+)+ -234U B 332 4 0.029 7 8.66 -234U S B EAV=93.0 13 -234U G 1567.0 2 0.0114 23 -234U G 1719.7 2 0.018 6 -234U L 1881.75 7 4+ -234U B 313 4 0.25 3 7.65 -234U S B EAV=87.3 13 -234U G 716.5 2 0.031 9[M1E2] 0.06 4 -234U 2 G KC=0.05 3$LC=0.010 5$MC=0.0023 12 -234U G 755.0 1 -234U G 1585.9 1 0.146 17 -234U G 1737.7 2 0.075 11 -234U G 1838.0 2 -234U L 1916.28 9 3,4++ -234U B 279 4 0.21 3 7.56 -234U S B EAV=76.9 12 -234U G 989.5 1 0.104 14 -234U G 1773.0 2 0.068 17 -234U G 1872.8 2 0.035 9 -234U L 1927.51 7 4+ -234U B 267 4 0.22 4 7.49 -234U S B EAV=73.5 12 -234U G 165.61 5 0.073 22[E1] 0.1533 22 -234U 2 G KC=0.1194 17$LC=0.0256 4$MC=0.00622 9 -234U G 308.6 2 0.021 6[E2] 0.1726 25 -234U 2 G KC=0.0711 10$LC=0.0744 11$MC=0.0201 3 -234U G 586.3 1 0.073 13[E2] 0.0328 5 -234U 2 G KC=0.0216 3$LC=0.00836 12$MC=0.00216 3 -234U G 653.7 1 -234U G 713.7 1 -234U G 1783.7 2 0.025 7 -234U G 1884.1 3 0.016 5 -234U L 1940.52 9 4+ -234U B 254 4 0.35 5 7.22 -234U S B EAV=69.7 12 -234U G 916.5 2 0.024 7 -234U G 1644.9 2 0.010 4 -234U G 1797.1 1 0.24 3 -234U G 1896.7 2 0.104 23 -234U L 1958.75 4 3- -234U B 236 4 0.44 19 7.01 1 -234U S B EAV=64.3 12 -234U G 221.15 100.052 22[E1] 0.0780 11 -234U 2 G KC=0.0615 9$LC=0.01248 18$MC=0.00302 5 -234U G 235.11 3 0.114 23[E1] 0.0678 10 -234U 2 G KC=0.0536 8$LC=0.01075 15$MC=0.00260 4 -234U G 502.0 1 0.03 9[E2M1] 0.15 10 -234U 2 G KC=0.11 9$LC=0.026 12$MC=0.006 3 -234U G 890.1 4 0.027 8 -234U G 935.8 2 0.067 10 -234U G 1110.6 1 0.062 12 -234U G 1173.1 1 0.046 9 -234U G 1815.3 3 0.009 4 -234U G 1915.5 3 0.020 5 -234U L 1968.84 104+,5+ -234U B 226 4 0.044 12 7.95 -234U S B EAV=61.3 12 -234U G 1672.8 1 0.034 11 -234U G 1825.1 3 0.009 4 -234U L 1981.22 7 4+ -234U B 214 4 0.59 8 6.75 -234U S B EAV=57.8 12 -234U G 257.2 1 0.052 22[M1E2] 0.9 7 -234U 2 G KC=0.7 6$LC=0.19 5$MC=0.049 8 -234U G 433.1 1 0.094 14 -234U G 1685.7 1 0.31 4 -234U G 1838.0 2 0.0042 11 -234U G 1937.7 3 0.042 11 -234U L 2000.45 13(4+)+ -234U B 195 4 0.122 16 7.31 -234U S B EAV=52.2 12 -234U G 1037.9 2 0.018 7 -234U G 1073.6 2 0.104 14 -234U G 1151.4 3 -234U L 2019.82 134+ -234U B 175 4 0.112 16 7.2 -234U S B EAV=46.7 12 -234U G 1051.4 2 0.062 12 -234U G 1057.8 3 0.0177 16 -234U G 1723.2 2 0.016 4 -234U G 1977.4 4 0.017 5 -234U L 2033.54 5 3+,4++ -234U B 161 4 0.90 15 6.19 -234U S B EAV=42.9 12 -234U G 310.2 1 0.073 13[M1E2] 0.5 4 -234U 2 G KC=0.4 4$LC=0.11 4$MC=0.027 7 -234U G 481.0 1 0.31 4[M1E2] 0.16 12 -234U 2 G KC=0.13 10$LC=0.029 14$MC=0.007 3 -234U G 537.2 1 0.083 13[M1E2] 0.12 9 -234U 2 G KC=0.09 7$LC=0.021 11$MC=0.0052 24 -234U G 1009.9 3 0.067 12 -234U G 1065.1 1 0.027 8 -234U G 1106.9 2 0.083 13 -234U G 1182.1 2 0.0094 -234U G 1890.1 2 0.146 17 -234U G 1989.6 4 0.007 4 -234U L 2037.06 174+,5+ -234U B 158 4 0.055 8 7.37 -234U S B EAV=41.9 12 -234U G 1741.1 2 0.049 8 -234U G 1893.4 3 0.0062 -234U L 2066.24 10 + -234U B 129 4 0.140 24 6.69 -234U S B EAV=33.8 11 -234U G 975.1 1 0.027 8 -234U G 997.7 3 0.046 12 -234U G 1770.8 2 0.068 17 -234U L 2068.82 113,4,5++ -234U B 126 4 0.40 7 6.21 -234U S B EAV=33.1 11 -234U G 331.4 1 0.073 13 -234U G 1925.4 2 0.30 5 -234U L 2101.42 9 5+ -234U B 94 4 0.064 11 6.6 -234U S B EAV=24.2 11 -234U G 839.5 1 0.031 8 -234U G 1009.9 3 -234U G 1032.8 2 0.018 5 -234U G 1805.8 3 0.0052 22 -234U G 1958.0 4 0.010 3 -234U L 2115.71 114+ -234U B 79 4 0.21 3 5.87 -234U S B EAV=20.4 11 -234U G 534.1 1 0.083 13[E1] 0.0118517 -234U 2 G KC=0.00958 14$LC=1715E-6 24$MC=4.10E-4 6 -234U G 562.8 3 0.036 11[M1E2] 0.11 8 -234U 2 G KC=0.08 6$LC=0.018 9$MC=0.0045 21 -234U G 1019.5 4 0.027 8 -234U G 1153.5 3 0.046 9 -234U G 1819.8 3 0.0042 11 -234U G 1971.2 4 0.0027 -234U G 2072.2 4 0.0042 22 -234U L 2144.04 9 3+,4+- -234U B 51 4 0.42 5 4.98 1 -234U S B EAV=13.0 11 -234U G 869.7 1 0.20 3 -234U G 1217.3 1 0.22 3 - +234U 234PA B- DECAY (6.70 H) +234U H TYP=FUL$AUT=X.HUANG$CUT=31-DEC-2009$ +234U T Auger electrons and X ray energies and emission intensities: +234U T {U Energy (keV)} {U Intensity} {U Line} +234U T +234U T 94.666 10.5 6 XKA2 +234U T 98.44 16.8 9 XKA1 +234U T +234U T 110.421 |] XKB3 +234U T 111.298 |] 6.1 4 XKB1 +234U T 111.964 |] XKB5II +234U T +234U T 114.407 |] XKB2 +234U T 115.012 |] 2.0 1 XKB4 +234U T 115.377 |] XKO23 +234U T +234U T 11.6185-20.7141 77 10 XL (total) +234U T 11.6185 XLL +234U T 13.4382-13.6146 XLA +234U T 15.399 XLC +234U T 15.7268-18.2061 XLB +234U T 19.5072-20.7141 XLG +234U T +234U T 71.776-80.954 |] KLL AUGER +234U T 88.153-98.429 |] 1.08 6 KLX AUGER +234U T 104.51-115.59 |] KXY AUGER +234U T 5.9-21.6 77 10 L AUGER +234PA P 0.0 4+ 6.70 H 5 2195 4 +234U N 1.0 1.0 1 1.0 +234U G 401.8 2 0.036 11 +234U G 425.3 2 0.036 11 +234U G 643.2 2 0.027 9 +234U G 659.8 1 0.27 4 +234U G 711.5 1 0.156 25 +234U G 778.6 2 0.046 10 +234U G 824.2 2 1.25 15 +234U G 846.1 2 0.052 12 +234U G 920.5 2 0.029 8 +234U G 992.0 2 0.083 22 +234U G 1023.6 2 0.062 22 +234U G 1025.3 2 0.052 22 +234U G 1035.9 2 0.026 10 +234U G 1220.4 2 0.062 12 +234U G 1296.4 2 0.029 7 +234U G 1301.2 2 0.018 5 +234U G 1327.0 2 0.018 5 +234U G 1507.3 2 0.020 5 +234U G 1520.7 2 0.0094 9 +234U G 1538.8 2 0.014 4 +234U G 1655.7 1 0.026 4 +234U G 1664.8 3 0.018 7 +234U G 1743.2 2 0.033 8 +234U G 1757.5 1 0.024 6 +234U G 1830.8 3 0.0042 11 +234U G 1849.8 2 0.028 7 +234U G 1927.9 4 0.054 12 +234U G 1935.2 4 0.0094 +234U L 0 0+ 2.455E5 Y 6 +234U L 43.481 152+ 0.252 NS 7 +234U G 43.49 2 0.12 3E2 713 11 +234U 2 G LC=520 8$MC=143.7 21$NC=38.9 6 +234U 3 G OC=8.92 13 +234U L 143.375 214+ +234U B 2052 4 5 9.2 +234U S B EAV=732.2 17 +234U G 99.86 2 3.2 6E2 13.42 19 +234U 2 G LC=9.77 14$MC=2.71 4$NC=0.736 11 +234U 3 G OC=0.1691 24 +234U L 296.075 246+ +234U G 152.71 2 6.0 7E2 2.14 3 +234U 2 G KC=0.217 3$LC=1.404 20$MC=0.388 6$NC=0.1055 15 +234U 3 G OC=0.0243 4 +234U L 497.05 4 8+ +234U G 200.97 3 0.90 13E2 0.734 11 +234U 2 G KC=0.1534 22$LC=0.424 6$MC=0.1166 17$NC=0.0317 5 +234U 3 G OC=0.00731 11 +234U L 786.295 151- +234U G 742.813 5 2.08 21E1 0.00636 9 +234U 2 G KC=0.00518 8$LC=0.000895 13$MC=0.000213 3$NC=5.71E-5 8 +234U 3 G OC=1.378E-5 20 +234U G 786.272 221.21 13(E1) 0.00573 8 +234U 2 G KC=0.00467 7$LC=0.000804 12$MC=0.000191 3$NC=5.12E-5 8 +234U 3 G OC=1.237E-5 18 +234U L 809.92 8 0+ 0.1 NS +234U G 766.4 2 0.26 5(E2) 0.0187 3 +234U 2 G KC=0.01336 19$LC=0.00396 6$MC=0.001003 14$NC=0.000271 4 +234U 3 G OC=6.45E-5 9 +234U G 810.0 7 E0 +234U L 849.265 233- +234U B 1346 4 0.8 9.3 1 +234U S B EAV=452.1 16 +234U G 705.9 1 2.29 23[E1] 0.0069810 +234U 2 G KC=0.00568 8$LC=0.000987 14$MC=0.000235 4$NC=6.30E-5 9 +234U 3 G OC=1.519E-5 22 +234U G 805.80 5 2.5 3[E1] 0.00549 8 +234U 2 G KC=0.00447 7$LC=0.000768 11$MC=0.000183 3$NC=4.89E-5 7 +234U 3 G OC=1.181E-5 17 +234U L 851.73 5 2+ 1.71 PS +234U G 41.82 11 +234U G 708.3 2 0.023 9[E2] 0.0219 3 +234U 2 G KC=0.01537 22$LC=0.00489 7$MC=0.001246 18$NC=0.000337 5 +234U 3 G OC=8.00E-5 12 +234U G 808.4 3 0.036 11E0+E2 4.2 +234U 2 G KC=3.30000 7$LC=0.9 10 +234U G 851.8 1 0.073 22[E2] 0.0151322 +234U 2 G KC=0.01109 16$LC=0.00302 5$MC=0.000759 11$NC=0.000205 3 +234U 3 G OC=4.89E-5 7 +234U L 926.744 212+ 1.38 PS 17 +234U G 783.4 1 0.30 4[E2] 0.0179 3 +234U 2 G KC=0.01285 18$LC=0.00374 6$MC=0.000946 14$NC=0.000255 4 +234U 3 G OC=6.08E-5 9 +234U G 883.24 4 9.7 11E2 0.0140920 +234U 2 G KC=0.01040 15$LC=0.00276 4$MC=0.000692 10$NC=0.000187 3 +234U 3 G OC=4.46E-5 7 +234U G 926.7 1 7.3 12(E2) 0.0128418 +234U 2 G KC=0.00956 14$LC=0.00245 4$MC=0.000613 9$NC=1.653E-4 24 +234U 3 G OC=3.95E-5 6 +234U L 947.59 5 4+ +234U B 1247 4 0.8 9.2 +234U S B EAV=414.4 16 +234U G 804.1 1 0.62 22E0+E2 0.37 +234U 2 G KC=0.1559 8$LC=0.11056 15$MC=0.10254 4$NC=0.000685 10 +234U 3 G OC=1.665E-4 24 +234U G 904.2 1 0.34 4[E2] 0.0134619 +234U 2 G KC=0.00998 14$LC=0.00260 4$MC=0.000652 10$NC=1.758E-4 25 +234U 3 G OC=4.20E-5 6 +234U L 962.55 3 5- +234U B 1232 4 0.4 9.4 1 +234U S B EAV=408.7 16 +234U G 666.5 1 1.18 13[E1] 0.0077711 +234U 2 G KC=0.00631 9$LC=0.001103 16$MC=0.000263 4$NC=7.04E-5 10 +234U 3 G OC=1.698E-5 24 +234U G 819.2 1 1.9 2[E1] 0.00533 8 +234U 2 G KC=0.00434 6$LC=0.000744 11$MC=1.770E-4 25$NC=4.74E-5 7 +234U 3 G OC=1.146E-5 16 +234U L 968.45 3 3+ +234U B 1227 4 2.5 8.6 +234U S B EAV=406.4 16 +234U G 825.1 2 1.9 2[E2] 0.0161123 +234U 2 G KC=0.01173 17$LC=0.00327 5$MC=0.000825 12$NC=0.000223 4 +234U 3 G OC=5.31E-5 8 +234U G 925.0 1 7.9 9(E2) 0.0128818 +234U 2 G KC=0.00959 14$LC=0.00246 4$MC=0.000616 9$NC=1.661E-4 24 +234U 3 G OC=3.97E-5 6 +234U L 989.444 202- 0.76 NS 4 +234U B 1206 4 3.1 8.5 1U +234U S B EAV=398.5 16 +234U G 62.70 1 1.6 5E1 0.426 6 +234U 2 G LC=0.320 5$MC=0.0791 11$NC=0.0209 3 +234U 3 G OC=0.00481 7 +234U G 140.15 2 0.51 7M1+E2 1.2 6 5.3 18 +234U 2 G KC=2.9 22$LC=1.76 25$MC=0.47 9$NC=0.127 23 +234U 3 G OC=0.030 5 +234U G 203.12 3 1.24 15M1+E2 1.5 4 1.4 4 +234U 2 G KC=0.8 4$LC=0.422 10$MC=0.1113 16$NC=0.0301 5 +234U 3 G OC=0.00708 11 +234U G 946.00 3 13.5 15(E1) 0.00412 6 +234U 2 G KC=0.00337 5$LC=0.000571 8$MC=1.355E-4 19$NC=3.63E-5 5 +234U 3 G OC=8.78E-6 13 +234U L 1023.795 243- +234U B 1171.2 405 8.3 1 +234U S B EAV=385.4 16 +234U G 34.30 4 0.0037 4(E2) 2270 40 +234U 2 G LC=1660 30$MC=457 7$NC=123.8 19 +234U 3 G OC=28.3 5 +234U G 54.96 100.0094 [E1] 0.603 9 +234U 2 G LC=0.453 7$MC=0.1123 17$NC=0.0297 5 +234U 3 G OC=0.00678 10 +234U G 97.17 100.24 9[E1] 0.1343 20 +234U 2 G LC=0.1012 15$MC=0.0248 4$NC=0.00658 10 +234U 3 G OC=0.001534 22 +234U G 174.55 3 0.17 3[M1+E2] 2.9 17 +234U 2 G KC=1.9 18$LC=0.74 4$MC=0.193 23$NC=0.052 7 +234U 3 G OC=0.0123 12 +234U G 880.52 4 4.3 6[E1] 0.00468 7 +234U 2 G KC=0.00382 6$LC=0.000651 10$MC=1.547E-4 22$NC=4.14E-5 6 +234U 3 G OC=1.002E-5 14 +234U G 980.3 1 2.7 [E1] 0.00387 6 +234U 2 G KC=0.00317 5$LC=0.000535 8$MC=1.270E-4 18$NC=3.40E-5 5 +234U 3 G OC=8.23E-6 12 +234U L 1023.92 3 4+ +234U B 1171 4 1.5 13 8.8 +234U S B EAV=385.4 16 +234U G 54.96 100.0094 [M1+E2] 1.3E2 11 +234U 2 G LC=90 80$MC=26 21$NC=7 6 +234U 3 G OC=1.6 13 +234U G 727.8 2 0.114 15[E2] 0.0207 3 +234U 2 G KC=0.01464 21$LC=0.00454 7$MC=0.001156 17$NC=0.000312 5 +234U 3 G OC=7.42E-5 11 +234U G 880.52 4 6.2 8[E2] 0.0141820 +234U 2 G KC=0.01046 15$LC=0.00278 4$MC=0.000697 10$NC=0.000188 3 +234U 3 G OC=4.49E-5 7 +234U G 980.3 1 1.77 [E2] 0.0115217 +234U 2 G KC=0.00866 13$LC=0.00214 3$MC=0.000534 8$NC=1.439E-4 21 +234U 3 G OC=3.45E-5 5 +234U L 1069.297 224- +234U B 1126 4 8 8 +234U S B EAV=368.3 15 +234U G 45.45 5 0.027 9M1+E2 0.8 4 2.5E2 14 +234U 2 G LC=1.9E2 10$MC=50 30$NC=14 8 +234U 3 G OC=3.1 17 +234U G 79.84 2 0.062 22E2 38.4 6 +234U 2 G LC=28.0 4$MC=7.76 11$NC=2.11 3 +234U 3 G OC=0.483 7 +234U G 100.89 2 0.125 24[E1] 0.1218 17 +234U 2 G LC=0.0917 13$MC=0.0224 4$NC=0.00596 9 +234U 3 G OC=0.001391 20 +234U G 106.68 5 0.036 11[M1] 3.83 6 +234U 2 G LC=2.89 4$MC=0.699 10$NC=0.189 3 +234U 3 G OC=0.0459 7 +234U G 220.00 8 0.146 25(M1) 2.37 4 +234U 2 G KC=1.89 3$LC=0.366 6$MC=0.0886 13$NC=0.0239 4 +234U 3 G OC=0.00581 9 +234U G 926.0 2 1.8 13[E1] 0.00428 6 +234U 2 G KC=0.00350 5$LC=0.000594 9$MC=1.409E-4 20$NC=3.78E-5 6 +234U 3 G OC=9.13E-6 13 +234U L 1085.07 102+ +234U G 233.6 2 +234U G 235.9 300.005 3 +234U G 298.7 2 0.014 6[E1] 0.0396 6 +234U 2 G KC=0.0315 5$LC=0.00610 9$MC=0.001470 21$NC=0.000393 6 +234U 3 G OC=9.39E-5 14 +234U G 942.0 3 0.046 9[E2] 0.0124418 +234U 2 G KC=0.00929 13$LC=0.00236 4$MC=0.000589 9$NC=1.587E-4 23 +234U 3 G OC=3.80E-5 6 +234U G 1041.1 2 0.032 11[E2,M1] 0.023 13 +234U 2 G KC=0.018 11$LC=0.0036 18$MC=0.0009 4$NC=0.00023 11 +234U 3 G OC=0.00006 3 +234U G 1085.3 3 0.027 8[E2] 0.0095014 +234U 2 G KC=0.00725 11$LC=0.001690 24$MC=0.000418 6$NC=1.127E-4 16 +234U 3 G OC=2.71E-5 4 +234U L 1090.89 4 5+ +234U B 1104 4 0.69 20 9.04 +234U S B EAV=360.2 15 +234U G 794.9 2 0.68 11[E2] 0.0173525 +234U 2 G KC=0.01253 18$LC=0.00360 5$MC=0.000910 13$NC=0.000246 4 +234U 3 G OC=5.85E-5 9 +234U G 947.7 2 1.63 21[E2] 0.0123018 +234U 2 G KC=0.00919 13$LC=0.00232 4$MC=0.000580 9$NC=1.563E-4 22 +234U 3 G OC=3.74E-5 6 +234U L 1096.12 9 6+ +234U G 799.7 2 E0+E2 +234U G 952.7 1 0.083 13 +234U L 1125.29 5 7- +234U G 628.1 1 0.24 5[E1] 0.0086813 +234U 2 G KC=0.00705 10$LC=0.001239 18$MC=0.000296 5$NC=7.91E-5 11 +234U 3 G OC=1.91E-5 3 +234U G 829.3 2 0.36 11[E1] 0.00521 8 +234U 2 G KC=0.00425 6$LC=0.000727 11$MC=1.729E-4 25$NC=4.63E-5 7 +234U 3 G OC=1.120E-5 16 +234U L 1126.65 3 2+ +234U G 137.23 5 0.027 9[E1] 0.239 4 +234U 2 G KC=0.184 3$LC=0.0413 6$MC=0.01006 15$NC=0.00268 4 +234U 3 G OC=0.000630 9 +234U G 199.95 5 0.073 22(E0+E2+M1) 2.0 13 +234U 2 G KC=1.4 13$LC=0.483 21$MC=0.124 4$NC=0.0337 11 +234U 3 G OC=0.00798 12 +234U G 275.04 100.094 23[M1,E2] 0.8 6 +234U 2 G KC=0.6 5$LC=0.16 4$MC=0.040 8$NC=0.0107 21 +234U 3 G OC=0.0026 6 +234U G 316.7 1 0.104 14[E2] 0.1597 23 +234U 2 G KC=0.0677 10$LC=0.0674 10$MC=0.0182 3$NC=0.00494 7 +234U 3 G OC=0.001150 17 +234U G 340.2 1 0.041 9[E1] 0.0298 5 +234U 2 G KC=0.0239 4$LC=0.00453 7$MC=0.001090 16$NC=0.000292 4 +234U 3 G OC=6.97E-5 10 +234U G 1083.2 1 0.51 6(M1) 0.0317 5 +234U 2 G KC=0.0254 4$LC=0.00477 7$MC=0.001147 16$NC=0.000309 5 +234U 3 G OC=7.51E-5 11 +234U G 1126.8 1 0.30 4[E2] 0.0088513 +234U 2 G KC=0.00679 10$LC=0.001552 22$MC=0.000383 6$NC=1.032E-4 15 +234U 3 G OC=2.48E-5 4 +234U L 1127.535 255- +234U B 1067 4 1.9 10 8.54 1 +234U S B EAV=346.5 15 +234U G 58.20 6 0.0027 9(E2) 174 3 +234U 2 G LC=126.9 19$MC=35.1 6$NC=9.52 15 +234U 3 G OC=2.18 4 +234U G 103.77 2 0.24 4(E2) 11.22 16 +234U 2 G LC=8.17 12$MC=2.27 4$NC=0.615 9 +234U 3 G OC=0.1414 20 +234U G 164.94 5 0.052 22[E2,M1] 3.5 19 +234U 2 G KC=2.2 21$LC=0.91 9$MC=0.24 4$NC=0.064 11 +234U 3 G OC=0.0152 21 +234U G 278.3 1 0.042 11[E2] 0.238 4 +234U 2 G KC=0.0863 13$LC=0.1112 16$MC=0.0303 5$NC=0.00821 12 +234U 3 G OC=0.00190 3 +234U G 831.5 1 4.2 5[E1] 0.00518 8 +234U 2 G KC=0.00423 6$LC=0.000724 11$MC=1.721E-4 24$NC=4.61E-5 7 +234U 3 G OC=1.114E-5 16 +234U G 984.2 1 1.63 21[E1] 0.00385 6 +234U 2 G KC=0.00315 5$LC=0.000531 8$MC=1.261E-4 18$NC=3.38E-5 5 +234U 3 G OC=8.18E-6 12 +234U L 1165.41 4 3+ +234U G 196.80 5 0.073 22E0+E2+M1 2.0 13 +234U 2 G KC=1.4 13$LC=0.483 21$MC=0.124 4$NC=0.0337 11 +234U 3 G OC=0.00798 12 +234U G 313.5 1 0.104 14[E2,M1] 0.5 4 +234U 2 G KC=0.4 4$LC=0.10 4$MC=0.026 7$NC=0.0070 19 +234U 3 G OC=0.0017 5 +234U G 1021.8 2 0.15 4[M1] 0.0370 6 +234U 2 G KC=0.0297 5$LC=0.00557 8$MC=0.001340 19$NC=0.000361 5 +234U 3 G OC=8.78E-5 13 +234U G 1121.7 1 0.25 4M1 0.0289 4 +234U 2 G KC=0.0232 4$LC=0.00434 6$MC=0.001045 15$NC=0.000281 4 +234U 3 G OC=6.84E-5 10 +234U L 1172.03 3 6+ +234U G 675.1 1 0.101 14[E2] 0.0242 4 +234U 2 G KC=0.01674 24$LC=0.00558 8$MC=0.001427 20$NC=0.000386 6 +234U 3 G OC=9.15E-5 13 +234U G 876.0 1 2.55 23(E2) 0.0143220 +234U 2 G KC=0.01055 15$LC=0.00282 4$MC=0.000706 10$NC=0.000191 3 +234U 3 G OC=4.55E-5 7 +234U G 1028.7 1 0.57 6[E2] 0.0105115 +234U 2 G KC=0.00796 12$LC=0.00191 3$MC=0.000475 7$NC=1.280E-4 18 +234U 3 G OC=3.07E-5 5 +234U L 1194.761 236- +234U B 1000 4 1.5 8.5 1U +234U S B EAV=312.6 14 +234U G 67.25 100.036 11M1+E2 1.2 3 57 11 +234U 2 G LC=42 8$MC=11.5 22$NC=3.1 6 +234U 3 G OC=0.72 14 +234U G 69.46 5 0.018 8[E2,M1] 40 30 +234U 2 G LC=32 23$MC=9 7$NC=2.4 18 +234U 3 G OC=0.5 4 +234U G 125.46 1 0.79 12E2 4.89 7 +234U 2 G KC=0.216 3$LC=3.41 5$MC=0.945 14$NC=0.257 4 +234U 3 G OC=0.0590 9 +234U G 232.21 3 0.18 3[E2,M1] 1.2 8 +234U 2 G KC=0.9 8$LC=0.27 5$MC=0.070 7$NC=0.0188 17 +234U 3 G OC=0.0045 5 +234U G 898.67 5 3.3 4[E1] 0.00451 7 +234U 2 G KC=0.00369 6$LC=0.000627 9$MC=1.489E-4 21$NC=3.99E-5 6 +234U 3 G OC=9.65E-6 14 +234U L 1214.70 5 4+ +234U B 980 4 0.30 12 9.22 +234U S B EAV=314.2 15 +234U G 267.12 5 0.18 3[E2,M1] 0.8 6 +234U 2 G KC=0.6 5$LC=0.17 5$MC=0.044 8$NC=0.0118 21 +234U 3 G OC=0.0028 6 +234U G 365.0 3 0.018 7[E1] 0.0257 4 +234U 2 G KC=0.0206 3$LC=0.00387 6$MC=0.000930 14$NC=0.000249 4 +234U 3 G OC=5.96E-5 9 +234U G 918.4 1 0.100 14[E2] 0.0130619 +234U 2 G KC=0.00971 14$LC=0.00251 4$MC=0.000627 9$NC=1.691E-4 24 +234U 3 G OC=4.04E-5 6 +234U G 1171.3 1 0.090 13[E2] 0.0082412 +234U 2 G KC=0.00634 9$LC=0.001423 20$MC=0.000350 5$NC=9.44E-5 14 +234U 3 G OC=2.27E-5 4 +234U L 1237.24 3 1- +234U G 247.79 7 0.00037 4 +234U G 310.52 100.00013515 +234U G 387.94 6 0.00072 6 +234U G 427.4 4 0.00003110 +234U G 450.93 4 0.0040 19M1+E2 0.7 0.241 4 +234U 2 G KC=0.187 3$LC=0.0400 6$MC=0.00980 14$NC=0.00264 4 +234U 3 G OC=0.000638 9 +234U G 1193.77 2 0.021 6E1 0.00277 4 +234U 2 G KC=0.00226 4$LC=0.000377 6$MC=8.92E-5 13$NC=2.39E-5 4 +234U 3 G OC=5.80E-6 9 +234U G 1237.3 3 0.0094 E1 0.00262 4 +234U 2 G KC=0.00213 3$LC=0.000354 5$MC=8.38E-5 12$NC=2.25E-5 4 +234U 3 G OC=5.44E-6 8 +234U L 1261.77 3 7+ +234U G 764.8 2 0.20 5[M1,E2] 0.05 3 +234U 2 G KC=0.04 3$LC=0.008 4$MC=0.002 1$NC=0.0005 3 +234U 3 G OC=0.00013 7 +234U G 965.8 1 0.48 6[M1,E2] 0.027 16 +234U 2 G KC=0.022 13$LC=0.0043 22$MC=0.0011 5$NC=0.00028 14 +234U 3 G OC=0.00007 4 +234U L 1274.32 9 (5+) +234U G 978.2 3 0.090 23 +234U L 1277.45 3 7- +234U G 149.88 3 0.073 22[E2] 2.31 4 +234U 2 G KC=0.220 3$LC=1.526 22$MC=0.422 6$NC=0.1147 16 +234U 3 G OC=0.0264 4 +234U G 780.4 2 0.90 9[E1] 0.00581 9 +234U 2 G KC=0.00474 7$LC=0.000815 12$MC=0.000194 3$NC=5.19E-5 8 +234U 3 G OC=1.255E-5 18 +234U G 981.6 3 0.73 22[E1] 0.00387 6 +234U 2 G KC=0.00316 5$LC=0.000534 8$MC=1.267E-4 18$NC=3.39E-5 5 +234U 3 G OC=8.21E-6 12 +234U L 1312.20 9 3- +234U B 883 4 0.109 18 9.5 1 +234U S B EAV=278.7 15 +234U G 75.0 3 +234U G 343.8 2 0.034 8[E1] 0.0292 5 +234U 2 G KC=0.0233 4$LC=0.00442 7$MC=0.001064 15$NC=0.000285 4 +234U 3 G OC=6.81E-5 10 +234U G 365.0 3 +234U G 385.4 1 0.042 11[E1] 0.0229 4 +234U 2 G KC=0.0184 3$LC=0.00343 5$MC=0.000824 12$NC=0.000220 3 +234U 3 G OC=5.28E-5 8 +234U L 1341.33 8 (6+) +234U G 379.1 1 0.042 11[E1] 0.0237 4 +234U 2 G KC=0.0190 3$LC=0.00356 5$MC=0.000854 12$NC=0.000229 4 +234U 3 G OC=5.48E-5 8 +234U G 1044.4 2 0.031 3 +234U L 1421.252 246- 33.5 US 20 +234U G 143.78 2 0.32 5(M1+E2) 1 5.31 +234U 2 G KC=3.24 $LC=1.532 $MC=0.403 $NC=0.1091 +234U 3 G OC=0.0256 +234U G 159.48 2 0.66 10[E1] 0.1676 24 +234U 2 G KC=0.1303 19$LC=0.0282 4$MC=0.00684 10$NC=0.00182 3 +234U 3 G OC=0.000431 6 +234U G 226.50 3 4.9 6M1+E2 1.0 3 1.3 3 +234U 2 G KC=0.9 3$LC=0.297 15$MC=0.0759 23$NC=0.0205 6 +234U 3 G OC=0.00488 18 +234U G 249.22 1 2.5 4E1 0.0594 9 +234U 2 G KC=0.0470 7$LC=0.00935 13$MC=0.00226 4$NC=0.000604 9 +234U 3 G OC=1.437E-4 21 +234U G 293.79 5 3.0 4M1+E2 1.7 4 0.42 10 +234U 2 G KC=0.28 9$LC=0.109 9$MC=0.0283 18$NC=0.0076 5 +234U 3 G OC=0.00181 13 +234U G 295.91 8 0.146 25[M1+E2] 0.6 5 +234U 2 G KC=0.5 4$LC=0.12 4$MC=0.031 8$NC=0.0084 20 +234U 3 G OC=0.0020 6 +234U G 330.40 5 0.78 9[E1] 0.0318 5 +234U 2 G KC=0.0254 4$LC=0.00484 7$MC=0.001165 17$NC=0.000312 5 +234U 3 G OC=7.45E-5 11 +234U G 351.9 1 0.42 5E2 0.1175 17 +234U 2 G KC=0.0555 8$LC=0.0455 7$MC=0.01222 18$NC=0.00331 5 +234U 3 G OC=0.000773 11 +234U G 397.7 3 0.027 7[M2] 1.349 20 +234U 2 G KC=0.986 14$LC=0.270 4$MC=0.0687 10$NC=0.0187 3 +234U 3 G OC=0.00454 7 +234U G 458.68 5 1.14 12M1+E2 1.4 4 0.14 5 +234U 2 G KC=0.11 4$LC=0.028 5$MC=0.0071 11$NC=0.0019 3 +234U 3 G OC=0.00046 8 +234U G 1125.2 1 0.36 8[E1] 0.00305 5 +234U 2 G KC=0.00250 4$LC=0.000418 6$MC=9.91E-5 14$NC=2.66E-5 4 +234U 3 G OC=6.43E-6 9 +234U G 1277.7 2 0.045 9[M2] 0.0473 7 +234U 2 G KC=0.0370 6$LC=0.00771 11$MC=0.00188 3$NC=0.000509 8 +234U 3 G OC=1.237E-4 18 +234U L 1447.89 105- +234U B 747 4 0.11 3 9.25 1 +234U S B EAV=230.3 14 +234U G 320.4 1 0.052 8[E2,M1] 0.5 4 +234U 2 G KC=0.4 3$LC=0.10 4$MC=0.024 7$NC=0.0065 19 +234U 3 G OC=0.0016 5 +234U G 1151.4 3 0.032 10[E1] 0.00294 5 +234U 2 G KC=0.00240 4$LC=0.000402 6$MC=9.51E-5 14$NC=2.55E-5 4 +234U 3 G OC=6.18E-6 9 +234U L 1456.54 7 (2-) +234U G 669.7 1 0.0006 +234U G 1414.4 2 0.0028 +234U L 1486.17 12(3-) +234U B 709 4 0.12 3 9.14 +234U S B EAV=216.9 14 +234U G 559.2 2 0.073 22[E1] 0.0108416 +234U 2 G KC=0.00877 13$LC=0.001562 22$MC=0.000373 6$NC=1.000E-4 14 +234U 3 G OC=2.41E-5 4 +234U G 1342.9 2 0.012 5[E1] 0.00232 4 +234U 2 G KC=0.00185 3$LC=0.000307 5$MC=7.26E-5 11$NC=1.95E-5 3 +234U 3 G OC=4.72E-6 7 +234U G 1442.8 2 0.031 7[E1] 0.00212 3 +234U 2 G KC=0.001643 23$LC=0.000271 4$MC=6.41E-5 9$NC=1.719E-5 24 +234U 3 G OC=4.17E-6 6 +234U L 1496.14 3 3+ +234U B 699 4 2.7 7.8 +234U S B EAV=213.5 14 +234U G 221.83 100.073 22[E2] 0.513 8 +234U 2 G KC=0.1301 19$LC=0.280 4$MC=0.0767 11$NC=0.0208 3 +234U 3 G OC=0.00481 7 +234U G 330.40 5 M1+E2 0.7 0.562 8 +234U 2 G KC=0.431 6$LC=0.0980 14$MC=0.0242 4$NC=0.00653 10 +234U 3 G OC=0.001574 22 +234U G 369.50 5 2.5 3M1 0.565 8 +234U 2 G KC=0.450 7$LC=0.0866 13$MC=0.0209 3$NC=0.00563 8 +234U 3 G OC=0.00137 2 +234U G 426.95 5 0.46 5[E1] 0.0185 3 +234U 2 G KC=0.01491 21$LC=0.00274 4$MC=0.000658 10$NC=1.762E-4 25 +234U 3 G OC=4.23E-5 6 +234U G 472.3 1 0.36 4[M1] 0.290 4 +234U 2 G KC=0.231 4$LC=0.0443 7$MC=0.01069 15$NC=0.00288 4 +234U 3 G OC=0.00070 1 +234U G 506.75 5 1.30 14[E1] 0.0131419 +234U 2 G KC=0.01061 15$LC=0.00191 3$MC=0.000457 7$NC=1.225E-4 18 +234U 3 G OC=2.94E-5 5 +234U G 527.90 100.40 5(M1) 0.215 3 +234U 2 G KC=0.1716 24$LC=0.0328 5$MC=0.00790 11$NC=0.00213 3 +234U 3 G OC=0.000517 8 +234U G 569.5 1 9.3 12M1 0.1754 25 +234U 2 G KC=0.1401 20$LC=0.0267 4$MC=0.00643 9$NC=0.001732 25 +234U 3 G OC=0.000421 6 +234U G 646.5 1 0.114 15[E1] 0.0082212 +234U 2 G KC=0.00668 10$LC=0.001170 17$MC=0.000279 4$NC=7.48E-5 11 +234U 3 G OC=1.80E-5 3 +234U G 1352.9 1 1.16 12M1 0.0176625 +234U 2 G KC=0.01412 20$LC=0.00263 4$MC=0.000633 9$NC=1.705E-4 24 +234U 3 G OC=4.15E-5 6 +234U G 1452.7 1 0.81 9[M1] 0.0146821 +234U 2 G KC=0.01169 17$LC=0.00218 3$MC=0.000524 8$NC=0.000141 2 +234U 3 G OC=3.43E-5 5 +234U L 1502.38 8 3,4+ +234U B 693 4 0.25 4 8.78 +234U S B EAV=211.3 14 +234U G 1359.0 1 0.156 25 +234U G 1458.9 1 0.094 23 +234U L 1533.37 5 (4-) +234U B 662 4 0.21 4 8.79 +234U S B EAV=200.6 14 +234U G 464.2 1 0.031 11[M1] 0.304 5 +234U 2 G KC=0.243 4$LC=0.0464 7$MC=0.01120 16$NC=0.00302 5 +234U 3 G OC=0.000734 11 +234U G 543.8 1 0.135 24[E2] 0.0389 6 +234U 2 G KC=0.0247 4$LC=0.01049 15$MC=0.00273 4$NC=0.000739 11 +234U 3 G OC=1.743E-4 25 +234U G 1389.6 2 0.073 22[E1] 0.00222 4 +234U 2 G KC=0.001749 25$LC=0.000289 4$MC=6.84E-5 10$NC=1.83E-5 3 +234U 3 G OC=4.45E-6 7 +234U L 1537.25 3 4+ +234U B 658 4 0.9 8.1 +234U S B EAV=199.3 14 +234U G 372.0 1 1.23 14M1(+E2) 0.3 0.517 8 +234U 2 G KC=0.410 6$LC=0.0811 12$MC=0.0197 3$NC=0.00530 8 +234U 3 G OC=0.001286 18 +234U G 409.8 1 0.34 5[E1] 0.0202 3 +234U 2 G KC=0.01620 23$LC=0.00300 5$MC=0.00072 1$NC=0.000193 3 +234U 3 G OC=4.62E-5 7 +234U G 446.6 1 0.114 15[M1] 0.338 5 +234U 2 G KC=0.269 4$LC=0.0516 8$MC=0.01245 18$NC=0.00335 5 +234U 3 G OC=0.000815 12 +234U G 468.0 1 0.22 3[E1] 0.0153922 +234U 2 G KC=0.01241 18$LC=0.00226 4$MC=0.000541 8$NC=1.447E-4 21 +234U 3 G OC=3.48E-5 5 +234U G 513.4 1 0.38 [M1] 0.232 4 +234U 2 G KC=0.185 3$LC=0.0353 5$MC=0.00852 12$NC=0.00229 4 +234U 3 G OC=0.000558 8 +234U G 513.5 1 0.76 [E1] 0.0128018 +234U 2 G KC=0.01035 15$LC=0.00186 3$MC=0.000445 7$NC=1.192E-4 17 +234U 3 G OC=2.87E-5 4 +234U G 568.9 2 3.6 6M1 0.1759 25 +234U 2 G KC=0.1404 20$LC=0.0268 4$MC=0.00645 9$NC=0.001737 25 +234U 3 G OC=0.000422 6 +234U G 590.3 100.036 11[E2,M1] 0.10 7 +234U 2 G KC=0.07 6$LC=0.016 8$MC=0.0040 19$NC=0.0011 5 +234U 3 G OC=0.00026 13 +234U G 685.1 2 0.15 4 +234U G 1241.2 1 0.23 3(E2) 0.0074011 +234U 2 G KC=0.00573 8$LC=0.001251 18$MC=0.000307 5$NC=8.28E-5 12 +234U 3 G OC=1.99E-5 3 +234U G 1393.9 1 2.08 21M1 0.0163423 +234U 2 G KC=0.01304 19$LC=0.00243 4$MC=0.000585 9$NC=1.574E-4 22 +234U 3 G OC=3.83E-5 6 +234U G 1493.6 1 0.104 14[E2] 0.00531 8 +234U 2 G KC=0.00414 6$LC=0.000842 12$MC=0.000205 3$NC=5.52E-5 8 +234U 3 G OC=1.331E-5 19 +234U L 1543.71 5 4+ +234U B 651 4 0.10 9 9.1 +234U S B EAV=197.1 14 +234U G 474.2 2 0.036 11[E1] 0.0149921 +234U 2 G KC=0.01209 17$LC=0.00219 3$MC=0.000526 8$NC=1.407E-4 20 +234U 3 G OC=3.38E-5 5 +234U G 575.5 1 0.027 9[E2,M1] 0.10 7 +234U 2 G KC=0.08 6$LC=0.017 9$MC=0.0043 20$NC=0.0012 6 +234U 3 G OC=0.00028 14 +234U G 617.0 2 0.052 22[E2] 0.0294 5 +234U 2 G KC=0.0197 3$LC=0.00720 11$MC=0.00186 3$NC=0.000502 7 +234U 3 G OC=1.188E-4 17 +234U G 1247.8 2 0.022 6[E2] 0.0073311 +234U 2 G KC=0.00567 8$LC=0.001237 18$MC=0.000304 5$NC=8.18E-5 12 +234U 3 G OC=1.97E-5 3 +234U G 1400.3 1 0.18 3[E2,M1] 0.011 6 +234U 2 G KC=0.009 5$LC=0.0017 8$MC=0.00041 18$NC=0.00011 5 +234U 3 G OC=0.000027 12 +234U G 1500.0 2 0.011 4[E2] 0.00528 8 +234U 2 G KC=0.00411 6$LC=0.000835 12$MC=0.000203 3$NC=5.47E-5 8 +234U 3 G OC=1.320E-5 19 +234U L 1548.10 8 (5)+ +234U B 647 4 0.078 20 9.18 +234U S B EAV=195.6 14 +234U G 452.4 3 0.027 9 +234U G 478.6 1 0.125 15[E1] 0.0147221 +234U 2 G KC=0.01187 17$LC=0.00215 3$MC=0.000516 8$NC=0.000138 2 +234U 3 G OC=3.32E-5 5 +234U G 1252.6 2 0.018 8 +234U L 1552.554 245+ 2.200 NS 25 +234U B 642 4 19.6 18 6.77 +234U S B EAV=194.0 14 +234U G 131.30 1 18.2 16E1 0.265 4 +234U 2 G KC=0.204 3$LC=0.0463 7$MC=0.01128 16$NC=0.00300 5 +234U 3 G OC=0.000706 10 +234U G 461.5 1 +234U G 529.1 3 0.09 4[E2,M1] 0.13 9 +234U 2 G KC=0.10 8$LC=0.022 11$MC=0.0054 25$NC=0.0015 7 +234U 3 G OC=0.00035 17 +234U G 584.1 1 0.18 30[E2] 0.0331 5 +234U 2 G KC=0.0217 3$LC=0.00845 12$MC=0.00219 3$NC=0.000592 9 +234U 3 G OC=1.399E-4 20 +234U G 604.6 3 0.052 22[E2,M1] 0.09 6 +234U 2 G KC=0.07 5$LC=0.015 8$MC=0.0037 18$NC=0.0010 5 +234U 3 G OC=0.00024 12 +234U G 1256.5 1 0.059 8[M1,E2] 0.014 8 +234U 2 G KC=0.011 6$LC=0.0022 10$MC=0.00054 24$NC=0.00014 7 +234U 3 G OC=0.000035 16 +234U G 1409.1 2 0.045 10 +234U L 1581.67 10(5-) +234U B 613 4 0.05 3 9.3 +234U S B EAV=184.1 14 +234U G 558.0 2 0.094 23[E2] 0.0367 6 +234U 2 G KC=0.0236 4$LC=0.00970 14$MC=0.00252 4$NC=0.000682 10 +234U 3 G OC=1.609E-4 23 +234U G 619.0 2 0.036 11[M1+E2] 0.08 6 +234U 2 G KC=0.07 5$LC=0.014 7$MC=0.0035 17$NC=0.0009 5 +234U 3 G OC=0.00023 11 +234U G 634.3 2 +234U L 1588.84 5 5+ +234U B 606 4 0.7 8.1 +234U S B EAV=181.7 14 +234U G 55.45 5 0.027 9(E1) 0.589 9 +234U 2 G LC=0.443 7$MC=0.1097 16$NC=0.0290 5 +234U 3 G OC=0.00663 10 +234U G 394.1 1 0.094 14[E1] 0.0219 3 +234U 2 G KC=0.01755 25$LC=0.00326 5$MC=0.000784 11$NC=0.000210 3 +234U 3 G OC=5.03E-5 7 +234U G 461.5 1 0.034 11[M1] 0.309 5 +234U 2 G KC=0.246 4$LC=0.0472 7$MC=0.01138 16$NC=0.00307 5 +234U 3 G OC=0.000745 11 +234U G 498.0 1 0.062 12[M1] 0.252 4 +234U 2 G KC=0.201 3$LC=0.0384 6$MC=0.00925 13$NC=0.00249 4 +234U 3 G OC=0.000606 9 +234U G 519.60 100.40 5[E1] 0.0125118 +234U 2 G KC=0.01011 15$LC=0.00181 3$MC=0.000434 6$NC=1.162E-4 17 +234U 3 G OC=2.80E-5 4 +234U G 565.2 1 1.04 11(M1) 0.179 3 +234U 2 G KC=0.1429 20$LC=0.0272 4$MC=0.00656 10$NC=0.001768 25 +234U 3 G OC=0.000430 6 +234U G 1292.8 1 0.47 6M1 0.0199 3 +234U 2 G KC=0.01592 23$LC=0.00297 5$MC=0.000715 10$NC=0.000193 3 +234U 3 G OC=4.68E-5 7 +234U G 1445.4 1 0.32 5[M1] 0.0148821 +234U 2 G KC=0.01185 17$LC=0.00221 3$MC=0.000531 8$NC=1.429E-4 20 +234U 3 G OC=3.48E-5 5 +234U L 1619.46 9 (6+) +234U B 576 4 0.035 20 9.36 2 +234U S B EAV=171.4 14 +234U G 357.9 1 0.036 11[M1,E2] 0.4 3 +234U 2 G KC=0.27 22$LC=0.07 3$MC=0.017 6$NC=0.0046 16 +234U 3 G OC=0.0011 4 +234U G 446.6 1 +234U G 529.1 3 +234U G 657.4 1 0.40 5 +234U G 1475.8 2 0.008 4 +234U L 1649.99 12(6-) +234U B 545 4 0.18 4 8.64 2 +234U S B EAV=164.6 13 +234U G 553.70 100.045 16[E1] 0.0110516 +234U 2 G KC=0.00894 13$LC=0.001594 23$MC=0.000381 6$NC=1.020E-4 15 +234U 3 G OC=2.46E-5 4 +234U G 1354.6 2 0.14 4[E1] 0.00229 4 +234U 2 G KC=0.00183 3$LC=0.000302 5$MC=7.15E-5 10$NC=1.92E-5 3 +234U 3 G OC=4.65E-6 7 +234U L 1653.35 7 (3+) +234U B 542 4 0.95 13 7.84 +234U S B EAV=160.1 14 +234U G 629.4 1 0.35 6(M1) 0.1342 19 +234U 2 G KC=0.1072 15$LC=0.0204 3$MC=0.00491 7$NC=0.001322 19 +234U 3 G OC=0.000322 5 +234U G 663.9 1 0.54 9[E1] 0.0078211 +234U 2 G KC=0.00636 9$LC=0.001111 16$MC=0.000265 4$NC=7.09E-5 10 +234U 3 G OC=1.711E-5 24 +234U G 1510.1 2 0.0094 +234U L 1693.42 3 5- +234U B 502 4 6.9 8 6.87 1 +234U S B EAV=146.8 14 +234U G 140.91 3 0.31 5[E1] 0.224 4 +234U 2 G KC=0.1732 25$LC=0.0386 6$MC=0.00940 14$NC=0.00250 4 +234U 3 G OC=0.000589 9 +234U G 272.28 5 1.09 14M1+E2 0.64 1.004 14 +234U 2 G KC=0.766 11$LC=0.1783 25$MC=0.0442 7$NC=0.01192 17 +234U 3 G OC=0.00287 4 +234U G 416.1 1 0.036 11[E2] 0.0746 11 +234U 2 G KC=0.0405 6$LC=0.0251 4$MC=0.00666 10$NC=0.00180 3 +234U 3 G OC=0.000423 6 +234U G 478.6 1 +234U G 498.0 1 +234U G 521.40 100.75 9[E1] 0.0124218 +234U 2 G KC=0.01004 14$LC=0.00180 3$MC=0.000431 6$NC=1.154E-4 17 +234U 3 G OC=2.78E-5 4 +234U G 565.2 1 +234U G 602.6 1 0.54 6[E1] 0.0093914 +234U 2 G KC=0.00762 11$LC=0.001345 19$MC=0.000321 5$NC=8.60E-5 12 +234U 3 G OC=2.07E-5 3 +234U G 624.2 1 0.35 5(M1+E2) 0.7 0.1015 15 +234U 2 G KC=0.0799 12$LC=0.01627 23$MC=0.00396 6$NC=0.001067 15 +234U 3 G OC=0.000258 4 +234U G 669.7 1 1.0 1[E1] 0.0077011 +234U 2 G KC=0.00626 9$LC=0.001092 16$MC=0.000260 4$NC=6.98E-5 10 +234U 3 G OC=1.683E-5 24 +234U G 730.9 2 0.63 10[M1,E2] 0.06 4 +234U 2 G KC=0.04 3$LC=0.009 5$MC=0.0022 11$NC=0.0006 3 +234U 3 G OC=0.00014 7 +234U G 745.9 1 0.32 5[E1] 0.00631 9 +234U 2 G KC=0.00514 8$LC=0.000888 13$MC=0.000211 3$NC=5.66E-5 8 +234U 3 G OC=1.367E-5 20 +234U G 844.1 1 0.43 5[E2] 0.0154022 +234U 2 G KC=0.01127 16$LC=0.00309 5$MC=0.000777 11$NC=0.000210 3 +234U 3 G OC=5.01E-5 7 +234U G 1397.5 2 0.083 22[E1] 0.00220 3 +234U 2 G KC=0.001733 25$LC=0.000286 4$MC=6.78E-5 10$NC=1.82E-5 3 +234U 3 G OC=4.41E-6 7 +234U G 1550.1 1 0.073 13[E1] 0.00196 3 +234U 2 G KC=0.001460 21$LC=0.000240 4$MC=5.68E-5 8$NC=1.521E-5 22 +234U 3 G OC=3.69E-6 6 +234U L 1722.89 4 3- +234U B 472 4 8.4 9 6.7 1 +234U S B EAV=137.2 13 +234U G 595.4 2 0.094 23[E2] 0.0317 5 +234U 2 G KC=0.0210 3$LC=0.00799 12$MC=0.00207 3$NC=0.000558 8 +234U 3 G OC=1.321E-4 19 +234U G 653.7 1 0.47 8M1 0.1213 17 +234U 2 G KC=0.0969 14$LC=0.0184 3$MC=0.00443 7$NC=0.001194 17 +234U 3 G OC=0.000290 4 +234U G 699.03 5 M1 0.1015 15 +234U 2 G KC=0.0811 12$LC=0.01537 22$MC=0.00370 6$NC=0.000997 14 +234U 3 G OC=0.000242 4 +234U G 733.39 5 7.0 8M1 0.0893 13 +234U 2 G KC=0.0714 10$LC=0.01351 19$MC=0.00325 5$NC=0.000876 13 +234U 3 G OC=0.000213 3 +234U G 761.0 2 0.073 22[E2] 0.0189 3 +234U 2 G KC=0.01353 19$LC=0.00403 6$MC=0.001023 15$NC=0.000276 4 +234U 3 G OC=6.57E-5 10 +234U G 874.0 3 0.036 8[E2,M1] 0.035 21 +234U 2 G KC=0.028 18$LC=0.006 3$MC=0.0014 7$NC=0.00037 18 +234U 3 G OC=0.00009 5 +234U G 1679.5 1 0.077 18 +234U L 1723.424 244+ +234U B 472 4 36 5 6.06 +234U S B EAV=137.1 13 +234U G 134.61 2 0.114 23M1 9.50 14 +234U 2 G KC=7.54 11$LC=1.480 21$MC=0.358 5$NC=0.0965 14 +234U 3 G OC=0.0235 4 +234U G 170.85 2 0.51 7M1 4.83 7 +234U 2 G KC=3.84 6$LC=0.749 11$MC=0.181 3$NC=0.0488 7 +234U 3 G OC=0.01188 17 +234U G 179.80 8 0.045 16[M1] 4.19 6 +234U 2 G KC=3.33 5$LC=0.648 10$MC=0.1567 22$NC=0.0422 6 +234U 3 G OC=0.01027 15 +234U G 186.15 2 1.78 19M1 3.79 6 +234U 2 G KC=3.02 5$LC=0.587 9$MC=0.142 2$NC=0.0383 6 +234U 3 G OC=0.00931 13 +234U G 227.25 3 5.8 6M1 2.17 3 +234U 2 G KC=1.724 25$LC=0.335 5$MC=0.0809 12$NC=0.0218 3 +234U 3 G OC=0.00530 8 +234U G 558.0 2 +234U G 596.9 1 +234U G 632.6 2 0.036 11[E2,M1] 0.08 6 +234U 2 G KC=0.06 5$LC=0.013 7$MC=0.0033 16$NC=0.0009 5 +234U 3 G OC=0.00021 11 +234U G 699.03 5 3.6 4 +234U G 755.0 1 1.23 13(E2,M1) 0.05 4 +234U 2 G KC=0.04 3$LC=0.008 5$MC=0.002 1$NC=0.0005 3 +234U 3 G OC=0.00013 7 +234U G 796.1 1 2.6 3[E2] 0.0173025 +234U 2 G KC=0.01249 18$LC=0.00359 5$MC=0.000906 13$NC=0.000245 4 +234U 3 G OC=5.83E-5 9 +234U G 1426.9 1 0.17 3 +234U G 1579.9 1 0.073 22 +234U L 1737.42 7 3+ +234U B 458 4 1.16 14 7.51 +234U S B EAV=132.5 14 +234U G 713.7 1 0.146 25[E1] 0.0068410 +234U 2 G KC=0.00557 8$LC=0.000966 14$MC=0.000230 4$NC=6.16E-5 9 +234U 3 G OC=1.488E-5 21 +234U G 748.1 3 0.104 23[E1] 0.00628 9 +234U 2 G KC=0.00511 8$LC=0.000883 13$MC=0.000210 3$NC=5.63E-5 8 +234U 3 G OC=1.360E-5 19 +234U G 1594.0 1 0.31 4M1,E2 0.008 4 +234U 2 G KC=0.006 3$LC=0.0012 5$MC=0.00029 12$NC=0.00008 4 +234U 3 G OC=0.000019 8 +234U G 1693.8 2 0.7 1 +234U L 1738.18 6 (3+) +234U B 457 4 0.78 19 7.68 +234U S B EAV=132.3 14 +234U G 612.0 1 0.38 5(M1) 0.1447 21 +234U 2 G KC=0.1156 17$LC=0.0220 3$MC=0.00530 8$NC=0.001426 20 +234U 3 G OC=0.000347 5 +234U G 811.5 1 0.125 15[M1,E2] 0.04 3 +234U 2 G KC=0.033 22$LC=0.007 4$MC=0.0017 9$NC=0.00045 22 +234U 3 G OC=0.00011 6 +234U G 1695.0 3 0.27 7 +234U L 1761.86 6 (4-) +234U B 433 4 2.8 4 7.05 +234U S B EAV=124.7 13 +234U G 634.3 2 0.135 24[M1] 0.1315 19 +234U 2 G KC=0.1050 15$LC=0.0200 3$MC=0.00481 7$NC=0.001295 19 +234U 3 G OC=0.000315 5 +234U G 692.6 1 1.25 13(M1) 0.1040 15 +234U 2 G KC=0.0831 12$LC=0.01575 22$MC=0.00379 6$NC=0.001022 15 +234U 3 G OC=0.000249 4 +234U G 738.0 1 1.16 13(M1) 0.0878 13 +234U 2 G KC=0.0702 10$LC=0.01329 19$MC=0.00320 5$NC=0.000862 12 +234U 3 G OC=0.000210 3 +234U G 772.4 2 0.073 22[E2] 0.0184 3 +234U 2 G KC=0.01318 19$LC=0.00388 6$MC=0.000983 14$NC=0.000265 4 +234U 3 G OC=6.32E-5 9 +234U G 792.8 3 0.045 11[E1] 0.00565 8 +234U 2 G KC=0.00460 7$LC=0.000791 11$MC=0.000188 3$NC=5.04E-5 7 +234U 3 G OC=1.218E-5 17 +234U G 1618.3 2 0.009 4 +234U L 1770.79 9 (3+) +234U B 424 4 0.129 17 8.36 +234U S B EAV=121.8 13 +234U G 802.3 2 0.031 9[M1] 0.0703 10 +234U 2 G KC=0.0563 8$LC=0.01062 15$MC=0.00256 4$NC=0.000689 10 +234U 3 G OC=1.675E-4 24 +234U G 1627.3 1 0.076 11 +234U G 1727.8 2 0.020 5 +234U L 1782.58 3 5+ +234U B 412 4 8 3 6.53 +234U S B EAV=118.1 13 +234U G 59.19 5 0.032 11[M1+E2] 90 70 +234U 2 G LC=70 50$MC=18 15$NC=5 4 +234U 3 G OC=1.1 9 +234U G 193.73 3 0.50 8[M1+E2] 2.1 13 +234U 2 G KC=1.4 13$LC=0.510 16$MC=0.132 6$NC=0.0356 16 +234U 3 G OC=0.00844 18 +234U G 245.37 2 0.76 11M1 1.749 25 +234U 2 G KC=1.392 20$LC=0.270 4$MC=0.0652 10$NC=0.01757 25 +234U 3 G OC=0.00427 6 +234U G 360.6 3 0.018 7[E1] 0.0264 4 +234U 2 G KC=0.0211 3$LC=0.00397 6$MC=0.000955 14$NC=0.000256 4 +234U 3 G OC=6.12E-5 9 +234U G 617.0 2 +234U G 655.2 2 0.135 24[E1] 0.0080212 +234U 2 G KC=0.00651 10$LC=0.001140 16$MC=0.000272 4$NC=7.28E-5 11 +234U 3 G OC=1.756E-5 25 +234U G 758.9 1 0.25 3[M1,E2] 0.05 4 +234U 2 G KC=0.04 3$LC=0.008 5$MC=0.002 1$NC=0.0005 3 +234U 3 G OC=0.00013 7 +234U G 814.2 1 0.31 4[E2] 0.0165424 +234U 2 G KC=0.01201 17$LC=0.00338 5$MC=0.000854 12$NC=0.000230 4 +234U 3 G OC=5.50E-5 8 +234U G 1485.4 2 0.030 7[M1] 0.0138720 +234U 2 G KC=0.01102 16$LC=0.00205 3$MC=0.000494 7$NC=1.329E-4 19 +234U 3 G OC=3.23E-5 5 +234U G 1638.1 1 0.208 21(M1) 0.0108316 +234U 2 G KC=0.00850 12$LC=0.001581 23$MC=0.000380 6$NC=1.023E-4 15 +234U 3 G OC=2.49E-5 4 +234U L 1784.19 134+ +234U B 411 4 0.061 11 8.64 +234U S B EAV=117.6 13 +234U G 857.7 2 0.036 8[E2] 0.0149321 +234U 2 G KC=0.01095 16$LC=0.00297 5$MC=0.000746 11$NC=0.000201 3 +234U 3 G OC=4.80E-5 7 +234U G 1488.0 2 0.014 6 +234U G 1640.5 3 0.010 4 +234U L 1793.05 6 4+ +234U B 402 4 0.41 8 7.78 +234U S B EAV=114.8 13 +234U G 240.2 1 0.052 22[M1,E2] 1.1 8 +234U 2 G KC=0.8 7$LC=0.24 5$MC=0.062 8$NC=0.0168 19 +234U 3 G OC=0.0040 6 +234U G 769.1 1 0.187 20[M1,E2] 0.05 3 +234U 2 G KC=0.038 25$LC=0.008 4$MC=0.0019 10$NC=0.0005 3 +234U 3 G OC=0.00013 7 +234U G 1496.0 2 0.036 9 +234U G 1650.2 2 0.006 +234U G 1750.0 1 0.064 10 +234U L 1811.62 6 4+ +234U B 383 4 1.43 15 7.17 +234U S B EAV=108.9 13 +234U G 596.9 1 0.20 3[M1] 0.1547 22 +234U 2 G KC=0.1235 18$LC=0.0235 4$MC=0.00566 8$NC=0.001525 22 +234U 3 G OC=0.000371 6 +234U G 683.9 2 0.16 4[E1] 0.0074011 +234U 2 G KC=0.00602 9$LC=0.001049 15$MC=0.000250 4$NC=0.000067 1 +234U 3 G OC=1.615E-5 23 +234U G 685.1 2 [E2] 0.0235 4 +234U 2 G KC=0.01631 23$LC=0.00535 8$MC=0.001369 20$NC=0.000370 6 +234U 3 G OC=8.78E-5 13 +234U G 848.9 2 0.027 8[E1] 0.00500 7 +234U 2 G KC=0.00408 6$LC=0.000696 10$MC=1.655E-4 24$NC=4.43E-5 7 +234U 3 G OC=1.072E-5 15 +234U G 863.2 2 0.073 22[E2,M1] 0.036 22 +234U 2 G KC=0.029 18$LC=0.006 3$MC=0.0014 7$NC=0.00038 19 +234U 3 G OC=0.00009 5 +234U G 960.0 1 0.073 13[E2] 0.0119917 +234U 2 G KC=0.00899 13$LC=0.00225 4$MC=0.000562 8$NC=1.514E-4 22 +234U 3 G OC=3.63E-5 5 +234U G 1515.6 2 0.073 13 +234U G 1668.4 1 0.77 9(M1) 0.0103515 +234U 2 G KC=0.00809 12$LC=0.001505 21$MC=0.000362 5$NC=9.74E-5 14 +234U 3 G OC=2.37E-5 4 +234U G 1768.0 3 0.020 5 +234U L 1843.88 173,4,5- +234U B 351 4 0.17 3 7.97 +234U S B EAV=98.9 13 +234U G 994.6 3 0.062 22 +234U G 1700.5 2 0.104 14 +234U L 1863.08 15(5+) +234U B 332 4 0.029 7 8.66 +234U S B EAV=93.0 13 +234U G 1567.0 2 0.0114 23 +234U G 1719.7 2 0.018 6 +234U L 1881.75 7 4+ +234U B 313 4 0.25 3 7.65 +234U S B EAV=87.3 13 +234U G 716.5 2 0.031 9[M1,E2] 0.06 4 +234U 2 G KC=0.05 3$LC=0.010 5$MC=0.0023 12$NC=0.0006 3 +234U 3 G OC=0.00015 8 +234U G 755.0 1 +234U G 1585.9 1 0.146 17 +234U G 1737.7 2 0.075 11 +234U G 1838.0 2 +234U L 1916.28 9 3,4+ +234U B 279 4 0.21 3 7.56 +234U S B EAV=76.9 12 +234U G 989.5 1 0.104 14 +234U G 1773.0 2 0.068 17 +234U G 1872.8 2 0.035 9 +234U L 1927.51 7 4+ +234U B 267 4 0.22 4 7.49 +234U S B EAV=73.5 12 +234U G 165.61 5 0.073 22[E1] 0.1533 22 +234U 2 G KC=0.1194 17$LC=0.0256 4$MC=0.00622 9$NC=0.001658 24 +234U 3 G OC=0.000392 6 +234U G 308.6 2 0.021 6[E2] 0.1726 25 +234U 2 G KC=0.0711 10$LC=0.0744 11$MC=0.0201 3$NC=0.00546 8 +234U 3 G OC=0.001270 18 +234U G 586.3 1 0.073 13[E2] 0.0328 5 +234U 2 G KC=0.0216 3$LC=0.00836 12$MC=0.00216 3$NC=0.000585 9 +234U 3 G OC=1.383E-4 20 +234U G 653.7 1 +234U G 713.7 1 +234U G 1783.7 2 0.025 7 +234U G 1884.1 3 0.016 5 +234U L 1940.52 9 4+ +234U B 254 4 0.35 5 7.22 +234U S B EAV=69.7 12 +234U G 916.5 2 0.024 7 +234U G 1644.9 2 0.010 4 +234U G 1797.1 1 0.24 3 +234U G 1896.7 2 0.104 23 +234U L 1958.75 4 3- +234U B 236 4 0.44 19 7.01 1 +234U S B EAV=64.3 12 +234U G 221.15 100.052 22[E1] 0.0780 11 +234U 2 G KC=0.0615 9$LC=0.01248 18$MC=0.00302 5$NC=0.000807 12 +234U 3 G OC=0.000192 3 +234U G 235.11 3 0.114 23[E1] 0.0678 10 +234U 2 G KC=0.0536 8$LC=0.01075 15$MC=0.00260 4$NC=0.000695 10 +234U 3 G OC=1.652E-4 24 +234U G 502.0 1 0.03 9[E2,M1] 0.15 10 +234U 2 G KC=0.11 9$LC=0.026 12$MC=0.006 3$NC=0.0017 8 +234U 3 G OC=0.00041 19 +234U G 890.1 4 0.027 8 +234U G 935.8 2 0.067 10 +234U G 1110.6 1 0.062 12 +234U G 1173.1 1 0.046 9 +234U G 1815.3 3 0.009 4 +234U G 1915.5 3 0.020 5 +234U L 1968.84 104+,5+ +234U B 226 4 0.044 12 7.95 +234U S B EAV=61.3 12 +234U G 1672.8 1 0.034 11 +234U G 1825.1 3 0.009 4 +234U L 1981.22 7 4+ +234U B 214 4 0.59 8 6.75 +234U S B EAV=57.8 12 +234U G 257.2 1 0.052 22[M1,E2] 0.9 7 +234U 2 G KC=0.7 6$LC=0.19 5$MC=0.049 8$NC=0.0133 21 +234U 3 G OC=0.0032 6 +234U G 433.1 1 0.094 14 +234U G 1685.7 1 0.31 4 +234U G 1838.0 2 0.0042 11 +234U G 1937.7 3 0.042 11 +234U L 2000.45 13(4+) +234U B 195 4 0.122 16 7.31 +234U S B EAV=52.2 12 +234U G 1037.9 2 0.018 7 +234U G 1073.6 2 0.104 14 +234U G 1151.4 3 +234U L 2019.82 134+ +234U B 175 4 0.112 16 7.2 +234U S B EAV=46.7 12 +234U G 1051.4 2 0.062 12 +234U G 1057.8 3 0.0177 16 +234U G 1723.2 2 0.016 4 +234U G 1977.4 4 0.017 5 +234U L 2033.54 5 3+,4+ +234U B 161 4 0.90 15 6.19 +234U S B EAV=42.9 12 +234U G 310.2 1 0.073 13[M1,E2] 0.5 4 +234U 2 G KC=0.4 4$LC=0.11 4$MC=0.027 7$NC=0.0072 19 +234U 3 G OC=0.0017 5 +234U G 481.0 1 0.31 4[M1,E2] 0.16 12 +234U 2 G KC=0.13 10$LC=0.029 14$MC=0.007 3$NC=0.0019 9 +234U 3 G OC=0.00046 21 +234U G 537.2 1 0.083 13[M1,E2] 0.12 9 +234U 2 G KC=0.09 7$LC=0.021 11$MC=0.0052 24$NC=0.0014 7 +234U 3 G OC=0.00034 16 +234U G 1009.9 3 0.067 12 +234U G 1065.1 1 0.027 8 +234U G 1106.9 2 0.083 13 +234U G 1182.1 2 0.0094 +234U G 1890.1 2 0.146 17 +234U G 1989.6 4 0.007 4 +234U L 2037.06 174+,5+ +234U B 158 4 0.055 8 7.37 +234U S B EAV=41.9 12 +234U G 1741.1 2 0.049 8 +234U G 1893.4 3 0.0062 +234U L 2066.24 10 +234U B 129 4 0.140 24 6.69 +234U S B EAV=33.8 11 +234U G 975.1 1 0.027 8 +234U G 997.7 3 0.046 12 +234U G 1770.8 2 0.068 17 +234U L 2068.82 113,4,5+ +234U B 126 4 0.40 7 6.21 +234U S B EAV=33.1 11 +234U G 331.4 1 0.073 13 +234U G 1925.4 2 0.30 5 +234U L 2101.42 9 5+ +234U B 94 4 0.064 11 6.6 +234U S B EAV=24.2 11 +234U G 839.5 1 0.031 8 +234U G 1009.9 3 +234U G 1032.8 2 0.018 5 +234U G 1805.8 3 0.0052 22 +234U G 1958.0 4 0.010 3 +234U L 2115.71 114+ +234U B 79 4 0.21 3 5.87 +234U S B EAV=20.4 11 +234U G 534.1 1 0.083 13[E1] 0.0118517 +234U 2 G KC=0.00958 14$LC=0.001715 24$MC=0.000410 6$NC=1.098E-4 16 +234U 3 G OC=2.64E-5 4 +234U G 562.8 3 0.036 11[M1,E2] 0.11 8 +234U 2 G KC=0.08 6$LC=0.018 9$MC=0.0045 21$NC=0.0012 6 +234U 3 G OC=0.00030 14 +234U G 1019.5 4 0.027 8 +234U G 1153.5 3 0.046 9 +234U G 1819.8 3 0.0042 11 +234U G 1971.2 4 0.0027 +234U G 2072.2 4 0.0042 22 +234U L 2144.04 9 3+,4+ +234U B 51 4 0.42 5 4.98 1 +234U S B EAV=13.0 11 +234U G 869.7 1 0.20 3 +234U G 1217.3 1 0.22 3 + diff --git a/HEN_HOUSE/spectra/lnhb/Pa-234m.txt b/HEN_HOUSE/spectra/lnhb/Pa-234m.txt index a9b6bc0dd..8687a9418 100644 --- a/HEN_HOUSE/spectra/lnhb/Pa-234m.txt +++ b/HEN_HOUSE/spectra/lnhb/Pa-234m.txt @@ -1,358 +1,408 @@ -234PA 234PA IT DECAY (1.159 M) -234PA H TYP=Full$AUT=Huang$CUT=30-JAN-2009$ -234PA C Evaluation history: Type=Full;Author=Huang;Cutoff date=30-JAN-2009 -234PA T Auger electrons and X ray energies and emission intensities: -234PA T {U Energy (keV)} {U Intensity} {U Line} -234PA T -234PA T -234PA T -234PA T -234PA T 11.3676-20.1126 0.046 4 XL (total) -234PA T 11.3676 XLL -234PA T 13.1215-13.2887 XLA -234PA T 14.9488 XLC -234PA T 15.3584-17.6655 XLB -234PA T 18.9396-20.1126 XLG -234PA T -234PA T 5.9-20.9 0.048 4 L AUGER -234PA P 73.92 2 (0-)- 1.159 M 11 -234PA N 6.667E2 6.667E2 0.0015 6.667E2 -234PA G 243.5 8 0.00050 9 -234PA G 557.3 100.00072 17 -234PA G 647.7 8 0.00158 15 -234PA G 760.3 100.00158 15 -234PA G 887.29 100.00708 14 -234PA G 1220.37 100.00091 9 -234PA G 1353.0 150.0015 5 -234PA G 1720.5 150.00033 15 -234PA G 1732.2 150.0019 3 -234PA G 1759.81 100.00146 5 -234PA G 2022.24 120.000186 3 -234PA G 2041.23 130.00011 1 -234PA G 2065.80 130.00007 -234PA G 2093.19 380.00002 -234PA G 2102.14 150.00006 -234PA G 2136.69 140.00007 -234PA L 0 4+ 6.70 H 5 -234PA L 73.92 2 (3+)+ -234PA G 73.92 2 0.0129 9(M1+E2) 0.11 3 10.6 4 -234PA2 G LC=7.96 25$MC=1.94 7 -234PA L 83.92 (0-)- 1.159 M 11 -234PA G 10 - -234U 234PA B- DECAY (1.159 M) -234U H TYP=Full$AUT=Huang$CUT=30-JAN-2009$ -234U C Evaluation history: Type=Full;Author=Huang;Cutoff date=30-JAN-2009 -234U T Auger electrons and X ray energies and emission intensities: -234U T {U Energy (keV)} {U Intensity} {U Line} -234U T -234U T 94.666 0.1973 25 XKA2 -234U T 98.44 0.316 4 XKA1 -234U T -234U T 110.421 |] XKB3 -234U T 111.298 |] 0.115 2 XKB1 -234U T 111.964 |] XKB5II -234U T -234U T 114.407 |] XKB2 -234U T 115.012 |] 0.0382 5 XKB4 -234U T 115.377 |] XKO23 -234U T -234U T 11.6185-20.7141 0.856 19 XL (total) -234U T 11.6185 XLL -234U T 13.4382-13.6146 XLA -234U T 15.399 XLC -234U T 15.7268-18.2061 XLB -234U T 19.5072-20.7141 XLG -234U T -234U T 71.776-80.954 |] KLL AUGER -234U T 88.153-98.429 |] 0.0203 3 KLX AUGER -234U T 104.51-115.59 |] KXY AUGER -234U T 5.9-21.6 0.856 19 L AUGER -234PA P 73.92 2 (0-)+ 1.159 M 11 2195.1 40 -234U N 1.002E0 1.002E0 0.9985 1.002E0 -234U G 243.5 8 0.00050 9 -234U G 557.3 100.00072 17 -234U G 647.7 8 0.00158 15 -234U G 760.3 100.00158 15 -234U G 887.29 100.00708 14 -234U G 1220.37 100.00091 9 -234U G 1353.0 150.0015 5 -234U G 1720.5 150.00033 15 -234U G 1732.2 150.0019 3 -234U G 1759.81 100.00146 5 -234U G 2022.24 120.000186 3 -234U G 2041.23 130.00011 1 -234U G 2065.80 130.00007 -234U G 2093.19 380.00002 -234U G 2102.14 150.00006 -234U G 2136.69 140.00007 -234U L 0 0+ STABLE -234U B 2269 4 97.599 24 5.5 -234U S B EAV=820.5 17 -234U L 43.428 142+ 0.252 NS 7 -234U G 43.49 2 0.00198 2E2 713 11 -234U 2 G LC=520 8$MC=143.7 21 -234U L 143.279 244+ -234U G 99.86 2 0.00057 5E2 13.42 19 -234U 2 G LC=9.77 14$MC=2.71 4 -234U L 786.243 141- -234U B 1483 4 0.049 3 8 1 -234U S B EAV=505.3 16 -234U G 742.813 5 0.094 3E1 0.00636 9 -234U 2 G KC=0.00518 8$LC=8.95E-4 13$MC=2.13E-4 3 -234U G 786.272 220.0536 7E1+M2 0.00573 8 -234U 2 G KC=0.00467 7$LC=8.04E-4 12$MC=1.91E-4 3 -234U L 809.786 230+ 0.1 NS -234U B 1459 4 0.945 12 6.8 -234U S B EAV=496.0 16 -234U G 766.361 200.323 4(E2) 0.0187 3 -234U 2 G KC=0.01336 19$LC=0.00396 6$MC=1004E-6 14 -234U G 810.0 7 -234U L 849.18 7 3- -234U G 705.94 120.0052 6[E1] 0.0069810 -234U 2 G KC=0.00568 8$LC=9.87E-4 14$MC=2.35E-4 4 -234U G 805.75 100.0062 8[E1] 0.00549 8 -234U 2 G KC=0.00447 7$LC=7.68E-4 11$MC=1.83E-4 3 -234U L 851.56 4 2+ 1.74 PS -234U G 41.82 -234U G 708.2 100.0007 [E2] 0.0219 4 -234U 2 G KC=0.01537 22$LC=0.00489 7$MC=1247E-6 19 -234U G 808.20 100.00281 17 -234U G 851.6 1 0.00696 15[E2] 0.0151422 -234U 2 G KC=0.01109 16$LC=0.00302 5$MC=7.60E-4 11 -234U L 926.659 202+ 1.38 PS 17 -234U G 783.4 1 0.000039 7[E2] 0.0179 3 -234U 2 G KC=0.01285 18$LC=0.00374 6$MC=9.46E-4 14 -234U G 883.24 3 0.00381 5E2 0.0140920 -234U 2 G KC=0.01040 15$LC=0.00276 4$MC=6.92E-4 10 -234U G 926.61 100.00125 13(E2) 0.0128418 -234U 2 G KC=0.00956 14$LC=0.00245 4$MC=6.13E-4 9 -234U L 989.359 192- 0.76 NS 4 -234U G 62.70 1 0.0013 4E1 0.426 6 -234U 2 G LC=0.320 5$MC=0.0791 11 -234U G 140.1 100.00127 M1+E2 1.2 6 5.3 18 -234U 2 G KC=2.9 22$LC=1.76 25$MC=0.47 9 -234U G 203.3 8 0.00119 9M1+E2 1.5 4 1.4 4 -234U 2 G KC=0.8 4$LC=0.420 12$MC=0.1109 23 -234U G 945.961 160.01060 14(E1) 0.00412 6 -234U 2 G KC=0.00337 5$LC=5.71E-4 8$MC=1355E-7 19 -234U L 1044.469 150+ -234U B 1224 4 1.006 13 6.5 -234U S B EAV=405.6 16 -234U G 193.4 8 0.00072 15[E2] 0.847 18 -234U 2 G KC=0.163 3$LC=0.500 12$MC=0.138 4 -234U G 236 1 -234U G 258.227 3 0.0738 8(E1) 0.0548 8 -234U 2 G KC=0.0434 6$LC=0.00859 12$MC=0.00207 3 -234U G 1001.026 180.847 8E2 0.0110716 -234U 2 G KC=0.00835 12$LC=0.00204 3$MC=5.07E-4 8 -234U L 1085.04 4 2+ -234U G 233.6 2 -234U G 235.9 3 0.00009 4[E1] 0.0673 10 -234U 2 G KC=0.0532 8$LC=0.01067 16$MC=0.00258 4 -234U G 299 1 0.00064 13[E1] 0.0395 7 -234U 2 G KC=0.0315 5$LC=0.00608 10$MC=1467E-6 24 -234U G 941.96 100.00250 9[E2] 0.0124418 -234U 2 G KC=0.00929 13$LC=0.00236 4$MC=5.89E-4 9 -234U G 1041.7 1 0.00119 8[E2M1] 0.023 13 -234U 2 G KC=0.018 11$LC=0.0036 18$MC=0.0009 4 -234U G 1084.25 100.0008 4[E2] 0.0095214 -234U 2 G KC=0.00726 11$LC=1694E-6 24$MC=4.19E-4 6 -234U L 1126.32 4 2+ -234U G 137.23 5 0.00004817[E1] 0.239 4 -234U 2 G KC=0.184 3$LC=0.0413 6$MC=0.01006 15 -234U G 199.9 100.00058 12(+E2+M1) 1.9 12 -234U 2 G KC=1.3 12$LC=0.473 22$MC=0.122 4 -234U G 275.5 8 0.00031 6[M1E2] 0.8 6 -234U 2 G KC=0.5 5$LC=0.16 4$MC=0.039 8 -234U G 316.7 1 0.00019 5[E2] 0.1597 23 -234U 2 G KC=0.0677 10$LC=0.0674 10$MC=0.0182 3 -234U G 340.2 1 0.00007221[E1] 0.0298 5 -234U 2 G KC=0.0239 4$LC=0.00453 7$MC=1090E-6 16 -234U G 1081.9 100.00091 19(M1) 0.0318 5 -234U 2 G KC=0.0255 4$LC=0.00478 7$MC=1151E-6 17 -234U G 1124.93 100.00039 9[E2] 0.0088813 -234U 2 G KC=0.00681 10$LC=1558E-6 22$MC=3.85E-4 6 -234U L 1174.2 4 (1,2+)+ -234U B 1095 4 0.0046 3 8.7 -234U S B EAV=356.7 15 -234U G 185.0 4 0.00172 15 -234U G 387.6 8 0.00097 15 -234U G 1174.2 100.00192 19 -234U L 1237.23 3 1- -234U B 1032 4 0.0121 11 8.2 1 -234U S B EAV=333.1 15 -234U G 247.7 8 0.00097 22[M1E2] 1.0 7 -234U 2 G KC=0.7 7$LC=0.22 5$MC=0.056 8 -234U G 311 1 0.00052 11[E1] 0.0363 6 -234U 2 G KC=0.0289 5$LC=0.00556 9$MC=1339E-6 22 -234U G 387.6 8 0.00047 4[E2] 0.0899 14 -234U 2 G KC=0.0463 7$LC=0.0321 5$MC=0.00858 14 -234U G 427.4 2 0.000020 5[E1] 0.0185 3 -234U 2 G KC=0.01488 21$LC=0.00274 4$MC=6.57E-4 10 -234U G 450.98 100.00310 13M1+E2 0.7 0.241 4 -234U 2 G KC=0.187 3$LC=0.0400 6$MC=0.00979 14 -234U G 1193.77 3 0.01359 18E1 0.00277 4 -234U 2 G KC=0.00226 4$LC=3.77E-4 6$MC=8.92E-5 13 -234U G 1237.28 100.00528 11E1 0.00262 4 -234U 2 G KC=0.00213 3$LC=3.54E-4 5$MC=8.38E-5 12 -234U L 1435.05 5 1- -234U B 834 4 0.0092 11 7.9 1 -234U S B EAV=261.1 15 -234U G 197.91 150.000027 7[M1E2] 2.0 12 -234U 2 G KC=1.3 12$LC=0.473 22$MC=0.122 4 -234U G 445.91 100.000031 7[M1E2] 0.20 14 -234U 2 G KC=0.15 12$LC=0.036 16$MC=0.009 4 -234U G 624.6 100.00011612[E1] 0.0087713 -234U 2 G KC=0.00712 11$LC=1252E-6 18$MC=2.99E-4 5 -234U G 649.0 100.000059 8[M1E2] 0.08 5 -234U 2 G KC=0.06 4$LC=0.012 7$MC=0.0031 15 -234U G 1392.6 9 0.0029 11E1 0.00221 4 -234U 2 G KC=1743E-6 25$LC=2.88E-4 4$MC=6.82E-5 10 -234U G 1434.16 100.00973 16E1 0.00213 3 -234U 2 G KC=1660E-6 24$LC=2.74E-4 4$MC=6.48E-5 9 -234U L 1457.40 8 (2-)+ -234U G 670.8 100.00037 9[M1E2] 0.07 5 -234U 2 G KC=0.05 4$LC=0.011 6$MC=0.0028 14 -234U G 1413.89 100.00229 8[E1] 0.00217 3 -234U 2 G KC=1700E-6 24$LC=2.81E-4 4$MC=6.64E-5 10 -234U L 1500.8 3 (1)+ -234U B 768 4 0.0131 6 7.7 -234U S B EAV=237.6 15 -234U G 649.0 100.0010 3 -234U G 691.0 3 0.00898 19 -234U G 1458.5 150.0019 5 -234U G 1501.0 200.0013 -234U L 1553.62 6 (1)+ -234U B 715 4 0.0320 6 7.2 -234U S B EAV=219.2 14 -234U G 468.43 100.00206 12 -234U G 509.2 8 0.0022 3 -234U G 702.00 100.00721 16 -234U G 1510.22 100.01308 19 -234U G 1553.77 100.00826 14 -234U L 1570.53 4 1+ -234U B 698 4 0.00231 19 8.4 -234U S B EAV=213.3 14 -234U G 135.32 8 4.2E-6 5[E1] 0.247 4 -234U 2 G KC=0.190 3$LC=0.0428 6$MC=0.01043 15 -234U G 485.44 7 1.87E-5 17[M1E2] 0.16 11 -234U 2 G KC=0.12 10$LC=0.028 13$MC=0.007 3 -234U G 526.02 100.000009 1[M1] 0.217 3 -234U 2 G KC=0.1732 25$LC=0.0331 5$MC=0.00797 12 -234U G 581.19 100.000080 9[E1] 0.0100614 -234U 2 G KC=0.00815 12$LC=1445E-6 21$MC=3.45E-4 5 -234U G 719.01 7 2.56E-5 20[M1+E2] 0.06 4 -234U 2 G KC=0.05 3$LC=0.009 5$MC=0.0023 12 -234U G 760.53 154.3E-6 9[M1] 0.0811 12 -234U 2 G KC=0.0648 9$LC=0.01226 18$MC=0.00295 5 -234U G 1527.28 100.00235 8M1+E2 0.009 4 -234U 2 G KC=0.007 4$LC=0.0014 6$MC=0.00033 14 -234U G 1570.67 100.00110 8M1 0.0120417 -234U 2 G KC=0.00951 14$LC=1769E-6 25$MC=4.25E-4 6 -234U L 1591.64 7 (1)+ -234U B 677 4 0.0249 5 7.2 -234U S B EAV=205.8 14 -234U G 507.5 100.00158 15 -234U G 740.10 8 0.0118 3 -234U G 781.75 100.00782 18 -234U G 1550.1 100.00137 15 -234U G 1593.5 6 0.00235 12 -234U L 1601.68 4 1+ -234U B 667 4 0.00127 23 8.5 -234U S B EAV=202.5 14 -234U G 166.5 1 2.37E-7 5[E1] 0.1514 22 -234U 2 G KC=0.1179 17$LC=0.0253 4$MC=0.00613 9 -234U G 516.60 6 1.22E-5 16(M1) 0.228 4 -234U 2 G KC=0.182 3$LC=0.0347 5$MC=0.00837 12 -234U G 557.24 6 8.3E-6 11(M1) 0.186 3 -234U 2 G KC=0.1485 21$LC=0.0283 4$MC=0.00682 10 -234U G 750.12 6 0.000017 2(M1) 0.0841 12 -234U 2 G KC=0.0672 10$LC=0.01272 18$MC=0.00306 5 -234U G 791.94 5 9.9E-6 13[M1] 0.0728 11 -234U 2 G KC=0.0582 9$LC=0.01100 16$MC=0.00265 4 -234U G 1558.4 100.00073 9M1 0.0122818 -234U 2 G KC=0.00971 14$LC=0.00181 3$MC=4.34E-4 7 -234U G 1601.8 150.00047 22(M1) 0.0114617 -234U 2 G KC=0.00902 13$LC=1679E-6 24$MC=4.03E-4 6 -234U L 1666.77 5 (1-)+ -234U B 602 4 0.0061 3 7.6 -234U S B EAV=180.1 14 -234U G 818.2 5 0.0010 3 -234U G 880.52 4 0.00392 5 -234U G 1667.6 100.00118 6 -234U L 1693.7 6 (1-)+ -234U B 575 4 0.0024 3 8 -234U S B EAV=171.2 14 -234U G 456.7 100.00072 15[M1] 0.318 5 -234U 2 G KC=0.253 4$LC=0.0485 8$MC=0.01171 18 -234U G 844.1 8 0.00109 23 -234U G 1694.1 100.00038 2 -234U L 1781.19 8 (0+,1)+ -234U B 488 4 0.0357 18 6.6 -234U S B EAV=142.3 14 -234U G 209.9 4 0.00132 15 -234U G 543.98 100.00349 15 -234U G 655.3 100.00139 15 -234U G 695.5 100.00164 14 -234U G 996.1 200.0059 17 -234U G 1737.77 100.0214 3 -234U L 1796.4 6 (1)+ -234U B 473 4 0.0021 3 7.7 -234U S B EAV=137.4 14 -234U G 338.1 8 0.00113 23 -234U G 362.8 100.00069 15 -234U G 1796.3 9 0.00031 5 -234U L 1808.97 7 (1-)+ -234U B 460 4 0.0146 7 6.9 -234U S B EAV=133.3 13 -234U G 572.0 100.00087 17[M1] 0.173 3 -234U 2 G KC=0.1384 21$LC=0.0264 4$MC=0.00636 10 -234U G 683.4 100.00058 12[E1] 0.0074111 -234U 2 G KC=0.00603 9$LC=1050E-6 15$MC=2.50E-4 4 -234U G 960.0 100.0009 3 -234U G 1765.44 100.0084 6 -234U G 1809.05 100.00376 7 -234U L 1863.11 7 (1)+ -234U B 406 4 0.00311 19 7.4 -234U S B EAV=116.0 13 -234U G 936.3 100.00102 17 -234U G 1819.69 100.00089 5 -234U G 1863.09 100.00120 5 -234U L 1874.86 8 (1)+ -234U B 394 4 0.0258 3 6.4 -234U S B EAV=112.3 13 -234U G 1831.37 100.01759 23 -234U G 1874.9 1 0.00819 14 -234U L 1911.04 5 (1-)+ -234U B 358 4 0.0452 8 6 -234U S B EAV=101.0 13 -234U G 357.5 100.00080 17 -234U G 453.58 100.00213 12[M1] 0.324 5 -234U 2 G KC=0.258 4$LC=0.0495 7$MC=0.01193 17 -234U G 475.74 100.00237 13[M1] 0.285 4 -234U 2 G KC=0.227 4$LC=0.0434 6$MC=0.01048 15 -234U G 673.9 100.00064 13[M1] 0.1118 17 -234U 2 G KC=0.0894 13$LC=0.01695 25$MC=0.00408 6 -234U G 825.5 2 0.0014 4 -234U G 866.8 100.00116 16 -234U G 921.72 100.01275 20 -234U G 1059.4 8 0.00111 22 -234U G 1061.86 100.00224 9 -234U G 1124.93 100.00347 9 -234U G 1867.7 1 0.00932 12 -234U G 1911.20 110.00628 9 -234U L 1936.68 7 (1)+ -234U B 332 4 0.0108 3 6.6 -234U S B EAV=93.0 13 -234U G 699.02 100.0058 3 -234U G 1893.51 110.00218 6 -234U G 1937.01 130.00285 5 -234U L 1970.0 5 (1-)- -234U B 299 4 0.00389 22 6.8 1 -234U S B EAV=83.0 13 -234U G 732.5 100.00130 15 -234U G 1120.6 8 0.00173 15 -234U G 1926.5 100.00045 4 -234U G 1970.3 8 0.00041 4 - +234PA 234PA IT DECAY (1.159 M) +234PA H TYP=FUL$AUT=X.HUANG$CUT=30-JAN-2009$ +234PA T Auger electrons and X ray energies and emission intensities: +234PA T {U Energy (keV)} {U Intensity} {U Line} +234PA T +234PA T +234PA T +234PA T +234PA T 11.3676-20.1126 0.046 4 XL (total) +234PA T 11.3676 XLL +234PA T 13.1215-13.2887 XLA +234PA T 14.9488 XLC +234PA T 15.3584-17.6655 XLB +234PA T 18.9396-20.1126 XLG +234PA T +234PA T 5.9-20.9 0.048 4 L AUGER +234PA P 73.92 2 (0-) 1.159 M 11 +234PA N 6.667E2 6.667E2 0.0015 +234PA L 0 4+ 6.70 H 5 +234PA L 73.92 2 (3+) +234PA G 73.92 2 0.0129 9(M1+E2) 0.11 3 10.6 4 +234PA2 G LC=7.96 25$MC=1.94 7$NC=0.520 18 +234PA3 G OC=0.124 4 +234PA L 83.92 (0-) 1.159 M 11 +234PA G 10 + +234U 234PA B- DECAY (1.159 M) +234U H TYP=FUL$AUT=X.HUANG$CUT=30-JAN-2009$ +234U T Auger electrons and X ray energies and emission intensities: +234U T {U Energy (keV)} {U Intensity} {U Line} +234U T +234U T 94.666 0.1973 25 XKA2 +234U T 98.44 0.316 4 XKA1 +234U T +234U T 110.421 |] XKB3 +234U T 111.298 |] 0.115 2 XKB1 +234U T 111.964 |] XKB5II +234U T +234U T 114.407 |] XKB2 +234U T 115.012 |] 0.0382 5 XKB4 +234U T 115.377 |] XKO23 +234U T +234U T 11.6185-20.7141 0.856 19 XL (total) +234U T 11.6185 XLL +234U T 13.4382-13.6146 XLA +234U T 15.399 XLC +234U T 15.7268-18.2061 XLB +234U T 19.5072-20.7141 XLG +234U T +234U T 71.776-80.954 |] KLL AUGER +234U T 88.153-98.429 |] 0.0203 3 KLX AUGER +234U T 104.51-115.59 |] KXY AUGER +234U T 5.9-21.6 0.856 19 L AUGER +234PA P 73.92 2 (0-) 1.159 M 11 2195.1 40 +234U N 1.002E0 1.002E0 0.9985 1.002E0 +234U G 243.5 8 0.00050 9 +234U G 557.3 100.00072 17 +234U G 647.7 8 0.00158 15 +234U G 760.3 100.00158 15 +234U G 887.29 100.00708 14 +234U G 1220.37 100.00091 9 +234U G 1353.0 150.0015 5 +234U G 1720.5 150.00033 15 +234U G 1732.2 150.0019 3 +234U G 1759.81 100.00146 5 +234U G 2022.24 120.000186 3 +234U G 2041.23 130.00011 1 +234U G 2065.80 130.00007 +234U G 2093.19 380.00002 +234U G 2102.14 150.00006 +234U G 2136.69 140.00007 +234U L 0 0+ 2.455E5 Y 6 +234U B 2269 4 97.599 24 5.5 +234U S B EAV=820.5 17 +234U L 43.428 142+ 0.252 NS 7 +234U G 43.49 2 0.00198 2E2 713 11 +234U 2 G LC=520 8$MC=143.7 21$NC=38.9 6 +234U 3 G OC=8.92 13 +234U L 143.279 244+ +234U G 99.86 2 0.00057 5E2 13.42 19 +234U 2 G LC=9.77 14$MC=2.71 4$NC=0.736 11 +234U 3 G OC=0.1691 24 +234U L 786.243 141- +234U B 1483 4 0.049 3 8 1 +234U S B EAV=505.3 16 +234U G 742.813 5 0.094 3E1 0.00636 9 +234U 2 G KC=0.00518 8$LC=0.000895 13$MC=0.000213 3$NC=5.71E-5 8 +234U 3 G OC=1.378E-5 20 +234U G 786.272 220.0536 7E1+M2 0.00573 8 +234U 2 G KC=0.00467 7$LC=0.000804 12$MC=0.000191 3$NC=5.12E-5 8 +234U 3 G OC=1.237E-5 18 +234U L 809.786 230+ 0.1 NS +234U B 1459 4 0.945 12 6.8 +234U S B EAV=496.0 16 +234U G 766.361 200.323 4(E2) 0.0187 3 +234U 2 G KC=0.01336 19$LC=0.00396 6$MC=0.001004 14$NC=0.000271 4 +234U 3 G OC=6.45E-5 9 +234U G 810.0 7 E0 +234U L 849.18 7 3- +234U G 705.94 120.0052 6[E1] 0.0069810 +234U 2 G KC=0.00568 8$LC=0.000987 14$MC=0.000235 4$NC=6.30E-5 9 +234U 3 G OC=1.519E-5 22 +234U G 805.75 100.0062 8[E1] 0.00549 8 +234U 2 G KC=0.00447 7$LC=0.000768 11$MC=0.000183 3$NC=4.89E-5 7 +234U 3 G OC=1.182E-5 17 +234U L 851.56 4 2+ 1.74 PS +234U G 41.82 +234U G 708.2 100.0007 [E2] 0.0219 4 +234U 2 G KC=0.01537 22$LC=0.00489 7$MC=0.001247 19$NC=0.000337 5 +234U 3 G OC=8.00E-5 12 +234U G 808.20 100.00281 17 +234U G 851.6 1 0.00696 15[E2] 0.0151422 +234U 2 G KC=0.01109 16$LC=0.00302 5$MC=0.000760 11$NC=0.000205 3 +234U 3 G OC=4.89E-5 7 +234U L 926.659 202+ 1.38 PS 17 +234U G 783.4 1 0.000039 7[E2] 0.0179 3 +234U 2 G KC=0.01285 18$LC=0.00374 6$MC=0.000946 14$NC=0.000255 4 +234U 3 G OC=6.08E-5 9 +234U G 883.24 3 0.00381 5E2 0.0140920 +234U 2 G KC=0.01040 15$LC=0.00276 4$MC=0.000692 10$NC=0.000187 3 +234U 3 G OC=4.46E-5 7 +234U G 926.61 100.00125 13(E2) 0.0128418 +234U 2 G KC=0.00956 14$LC=0.00245 4$MC=0.000613 9$NC=1.653E-4 24 +234U 3 G OC=3.96E-5 6 +234U L 989.359 192- 0.76 NS 4 +234U G 62.70 1 0.0013 4E1 0.426 6 +234U 2 G LC=0.320 5$MC=0.0791 11$NC=0.0209 3 +234U 3 G OC=0.00481 7 +234U G 140.1 100.00127 M1+E2 1.2 6 5.3 18 +234U 2 G KC=2.9 22$LC=1.76 25$MC=0.47 9$NC=0.127 23 +234U 3 G OC=0.030 5 +234U G 203.3 8 0.00119 9M1+E2 1.5 4 1.4 4 +234U 2 G KC=0.8 4$LC=0.420 12$MC=0.1109 23$NC=0.0300 7 +234U 3 G OC=0.00705 16 +234U G 945.961 160.01060 14(E1) 0.00412 6 +234U 2 G KC=0.00337 5$LC=0.000571 8$MC=1.355E-4 19$NC=3.63E-5 5 +234U 3 G OC=8.79E-6 13 +234U L 1044.469 150+ +234U B 1224 4 1.006 13 6.5 +234U S B EAV=405.6 16 +234U G 193.4 8 0.00072 15[E2] 0.847 18 +234U 2 G KC=0.163 3$LC=0.500 12$MC=0.138 4$NC=0.0374 9 +234U 3 G OC=0.00862 20 +234U G 236 1 E0 +234U G 258.227 3 0.0738 8(E1) 0.0548 8 +234U 2 G KC=0.0434 6$LC=0.00859 12$MC=0.00207 3$NC=0.000554 8 +234U 3 G OC=1.321E-4 19 +234U G 1001.026 180.847 8E2 0.0110716 +234U 2 G KC=0.00835 12$LC=0.00204 3$MC=0.000507 8$NC=1.367E-4 20 +234U 3 G OC=3.28E-5 5 +234U L 1085.04 4 2+ +234U G 233.6 2 +234U G 235.9 3 0.00009 4[E1] 0.0673 10 +234U 2 G KC=0.0532 8$LC=0.01067 16$MC=0.00258 4$NC=0.000689 10 +234U 3 G OC=1.639E-4 24 +234U G 299 1 0.00064 13[E1] 0.0395 7 +234U 2 G KC=0.0315 5$LC=0.00608 10$MC=0.001467 24$NC=0.000392 7 +234U 3 G OC=9.37E-5 15 +234U G 941.96 100.00250 9[E2] 0.0124418 +234U 2 G KC=0.00929 13$LC=0.00236 4$MC=0.000589 9$NC=1.587E-4 23 +234U 3 G OC=3.80E-5 6 +234U G 1041.7 1 0.00119 8[E2,M1] 0.023 13 +234U 2 G KC=0.018 11$LC=0.0036 18$MC=0.0009 4$NC=0.00023 11 +234U 3 G OC=0.00006 3 +234U G 1084.25 100.0008 4[E2] 0.0095214 +234U 2 G KC=0.00726 11$LC=0.001694 24$MC=0.000419 6$NC=1.130E-4 16 +234U 3 G OC=2.71E-5 4 +234U L 1126.32 4 2+ +234U G 137.23 5 0.00004817[E1] 0.239 4 +234U 2 G KC=0.184 3$LC=0.0413 6$MC=0.01006 15$NC=0.00268 4 +234U 3 G OC=0.000630 9 +234U G 199.9 100.00058 12(E0+E2+M1) 1.9 12 +234U 2 G KC=1.3 12$LC=0.473 22$MC=0.122 4$NC=0.033 1 +234U 3 G OC=0.00782 12 +234U G 275.5 8 0.00031 6[M1,E2] 0.8 6 +234U 2 G KC=0.5 5$LC=0.16 4$MC=0.039 8$NC=0.0106 21 +234U 3 G OC=0.0025 6 +234U G 316.7 1 0.00019 5[E2] 0.1597 23 +234U 2 G KC=0.0677 10$LC=0.0674 10$MC=0.0182 3$NC=0.00494 7 +234U 3 G OC=0.001150 17 +234U G 340.2 1 0.00007221[E1] 0.0298 5 +234U 2 G KC=0.0239 4$LC=0.00453 7$MC=0.001090 16$NC=0.000292 4 +234U 3 G OC=6.97E-5 10 +234U G 1081.9 100.00091 19(M1) 0.0318 5 +234U 2 G KC=0.0255 4$LC=0.00478 7$MC=0.001151 17$NC=0.000310 5 +234U 3 G OC=7.53E-5 11 +234U G 1124.93 100.00039 9[E2] 0.0088813 +234U 2 G KC=0.00681 10$LC=0.001558 22$MC=0.000385 6$NC=1.036E-4 15 +234U 3 G OC=2.49E-5 4 +234U L 1174.2 4 (1,2+) +234U B 1095 4 0.0046 3 8.7 +234U S B EAV=356.7 15 +234U G 185.0 4 0.00172 15 +234U G 387.6 8 0.00097 15 +234U G 1174.2 100.00192 19 +234U L 1237.23 3 1- +234U B 1032 4 0.0121 11 8.2 1 +234U S B EAV=333.1 15 +234U G 247.7 8 0.00097 22[M1,E2] 1.0 7 +234U 2 G KC=0.7 7$LC=0.22 5$MC=0.056 8$NC=0.0151 20 +234U 3 G OC=0.0036 6 +234U G 311 1 0.00052 11[E1] 0.0363 6 +234U 2 G KC=0.0289 5$LC=0.00556 9$MC=0.001339 22$NC=0.000358 6 +234U 3 G OC=8.55E-5 14 +234U G 387.6 8 0.00047 4[E2] 0.0899 14 +234U 2 G KC=0.0463 7$LC=0.0321 5$MC=0.00858 14$NC=0.00232 4 +234U 3 G OC=0.000543 9 +234U G 427.4 2 0.000020 5[E1] 0.0185 3 +234U 2 G KC=0.01488 21$LC=0.00274 4$MC=0.000657 10$NC=1.758E-4 25 +234U 3 G OC=4.22E-5 6 +234U G 450.98 100.00310 13M1+E2 0.7 0.241 4 +234U 2 G KC=0.187 3$LC=0.0400 6$MC=0.00979 14$NC=0.00264 4 +234U 3 G OC=0.000638 9 +234U G 1193.77 3 0.01359 18E1 0.00277 4 +234U 2 G KC=0.00226 4$LC=0.000377 6$MC=8.92E-5 13$NC=2.39E-5 4 +234U 3 G OC=5.80E-6 9 +234U G 1237.28 100.00528 11E1 0.00262 4 +234U 2 G KC=0.00213 3$LC=0.000354 5$MC=8.38E-5 12$NC=2.25E-5 4 +234U 3 G OC=5.44E-6 8 +234U L 1435.05 5 1- +234U B 834 4 0.0092 11 7.9 1 +234U S B EAV=261.1 15 +234U G 197.91 150.000027 7[M1,E2] 2.0 12 +234U 2 G KC=1.3 12$LC=0.473 22$MC=0.122 4$NC=0.033 1 +234U 3 G OC=0.00782 12 +234U G 445.91 100.000031 7[M1,E2] 0.20 14 +234U 2 G KC=0.15 12$LC=0.036 16$MC=0.009 4$NC=0.0024 10 +234U 3 G OC=0.00058 25 +234U G 624.6 100.00011612[E1] 0.0087713 +234U 2 G KC=0.00712 11$LC=0.001252 18$MC=0.000299 5$NC=8.00E-5 12 +234U 3 G OC=1.93E-5 3 +234U G 649.0 100.000059 8[M1,E2] 0.08 5 +234U 2 G KC=0.06 4$LC=0.012 7$MC=0.0031 15$NC=0.0008 4 +234U 3 G OC=0.0002 1 +234U G 1392.6 9 0.0029 11E1 0.00221 4 +234U 2 G KC=0.001743 25$LC=0.000288 4$MC=6.82E-5 10$NC=1.83E-5 3 +234U 3 G OC=4.43E-6 7 +234U G 1434.16 100.00973 16E1 0.00213 3 +234U 2 G KC=0.001660 24$LC=0.000274 4$MC=6.48E-5 9$NC=1.737E-5 25 +234U 3 G OC=4.21E-6 6 +234U L 1457.40 8 (2-) +234U G 670.8 100.00037 9[M1,E2] 0.07 5 +234U 2 G KC=0.05 4$LC=0.011 6$MC=0.0028 14$NC=0.0008 4 +234U 3 G OC=0.00018 9 +234U G 1413.89 100.00229 8[E1] 0.00217 3 +234U 2 G KC=0.001700 24$LC=0.000281 4$MC=6.64E-5 10$NC=1.780E-5 25 +234U 3 G OC=4.32E-6 6 +234U L 1500.8 3 (1)+ +234U B 768 4 0.0131 6 7.7 +234U S B EAV=237.6 15 +234U G 649.0 100.0010 3 +234U G 691.0 3 0.00898 19 +234U G 1458.5 150.0019 5 +234U G 1501.0 200.0013 +234U L 1553.62 6 (1)+ +234U B 715 4 0.0320 6 7.2 +234U S B EAV=219.2 14 +234U G 468.43 100.00206 12 +234U G 509.2 8 0.0022 3 +234U G 702.00 100.00721 16 +234U G 1510.22 100.01308 19 +234U G 1553.77 100.00826 14 +234U L 1570.53 4 1+ +234U B 698 4 0.00231 19 8.4 +234U S B EAV=213.3 14 +234U G 135.32 8 4.2E-6 5[E1] 0.247 4 +234U 2 G KC=0.190 3$LC=0.0428 6$MC=0.01043 15$NC=0.00278 4 +234U 3 G OC=0.000653 10 +234U G 485.44 7 1.87E-5 17[M1,E2] 0.16 11 +234U 2 G KC=0.12 10$LC=0.028 13$MC=0.007 3$NC=0.0019 8 +234U 3 G OC=0.00045 20 +234U G 526.02 100.000009 1[M1] 0.217 3 +234U 2 G KC=0.1732 25$LC=0.0331 5$MC=0.00797 12$NC=0.00215 3 +234U 3 G OC=0.000522 8 +234U G 581.19 100.000080 9[E1] 0.0100614 +234U 2 G KC=0.00815 12$LC=0.001445 21$MC=0.000345 5$NC=9.24E-5 13 +234U 3 G OC=2.23E-5 4 +234U G 719.01 7 2.56E-5 20[M1+E2] 0.06 4 +234U 2 G KC=0.05 3$LC=0.009 5$MC=0.0023 12$NC=0.0006 3 +234U 3 G OC=0.00015 8 +234U G 760.53 154.3E-6 9[M1] 0.0811 12 +234U 2 G KC=0.0648 9$LC=0.01226 18$MC=0.00295 5$NC=0.000795 12 +234U 3 G OC=0.000193 3 +234U G 1527.28 100.00235 8M1+E2 0.009 4 +234U 2 G KC=0.007 4$LC=0.0014 6$MC=0.00033 14$NC=0.00009 4 +234U 3 G OC=0.000021 9 +234U G 1570.67 100.00110 8M1 0.0120417 +234U 2 G KC=0.00951 14$LC=0.001769 25$MC=0.000425 6$NC=1.145E-4 16 +234U 3 G OC=2.79E-5 4 +234U L 1591.64 7 (1)+ +234U B 677 4 0.0249 5 7.2 +234U S B EAV=205.8 14 +234U G 507.5 100.00158 15 +234U G 740.10 8 0.0118 3 +234U G 781.75 100.00782 18 +234U G 1550.1 100.00137 15 +234U G 1593.5 6 0.00235 12 +234U L 1601.68 4 1+ +234U B 667 4 0.00127 23 8.5 +234U S B EAV=202.5 14 +234U G 166.5 1 2.37E-7 5[E1] 0.1514 22 +234U 2 G KC=0.1179 17$LC=0.0253 4$MC=0.00613 9$NC=0.001636 23 +234U 3 G OC=0.000386 6 +234U G 516.60 6 1.22E-5 16(M1) 0.228 4 +234U 2 G KC=0.182 3$LC=0.0347 5$MC=0.00837 12$NC=0.00226 4 +234U 3 G OC=0.000548 8 +234U G 557.24 6 8.3E-6 11(M1) 0.186 3 +234U 2 G KC=0.1485 21$LC=0.0283 4$MC=0.00682 10$NC=0.00184 3 +234U 3 G OC=0.000447 7 +234U G 750.12 6 0.000017 2(M1) 0.0841 12 +234U 2 G KC=0.0672 10$LC=0.01272 18$MC=0.00306 5$NC=0.000825 12 +234U 3 G OC=0.000201 3 +234U G 791.94 5 9.9E-6 13[M1] 0.0728 11 +234U 2 G KC=0.0582 9$LC=0.01100 16$MC=0.00265 4$NC=0.000713 10 +234U 3 G OC=1.735E-4 25 +234U G 1558.4 100.00073 9M1 0.0122818 +234U 2 G KC=0.00971 14$LC=0.00181 3$MC=0.000434 7$NC=1.169E-4 17 +234U 3 G OC=2.84E-5 4 +234U G 1601.8 150.00047 22(M1) 0.0114617 +234U 2 G KC=0.00902 13$LC=0.001679 24$MC=0.000403 6$NC=1.086E-4 16 +234U 3 G OC=2.64E-5 4 +234U L 1666.77 5 (1-) +234U B 602 4 0.0061 3 7.6 +234U S B EAV=180.1 14 +234U G 818.2 5 0.0010 3 +234U G 880.52 4 0.00392 5 +234U G 1667.6 100.00118 6 +234U L 1693.7 6 (1-) +234U B 575 4 0.0024 3 8 +234U S B EAV=171.2 14 +234U G 456.7 100.00072 15[M1] 0.318 5 +234U 2 G KC=0.253 4$LC=0.0485 8$MC=0.01171 18$NC=0.00315 5 +234U 3 G OC=0.000767 12 +234U G 844.1 8 0.00109 23 +234U G 1694.1 100.00038 2 +234U L 1781.19 8 (0+,1+) +234U B 488 4 0.0357 18 6.6 +234U S B EAV=142.3 14 +234U G 209.9 4 0.00132 15 +234U G 543.98 100.00349 15 +234U G 655.3 100.00139 15 +234U G 695.5 100.00164 14 +234U G 996.1 200.0059 17 +234U G 1737.77 100.0214 3 +234U L 1796.4 6 (1)+ +234U B 473 4 0.0021 3 7.7 +234U S B EAV=137.4 14 +234U G 338.1 8 0.00113 23 +234U G 362.8 100.00069 15 +234U G 1796.3 9 0.00031 5 +234U L 1808.97 7 (1-) +234U B 460 4 0.0146 7 6.9 +234U S B EAV=133.3 13 +234U G 572.0 100.00087 17[M1] 0.173 3 +234U 2 G KC=0.1384 21$LC=0.0264 4$MC=0.00636 10$NC=0.00171 3 +234U 3 G OC=0.000416 7 +234U G 683.4 100.00058 12[E1] 0.0074111 +234U 2 G KC=0.00603 9$LC=0.001050 15$MC=0.000250 4$NC=0.000067 1 +234U 3 G OC=1.618E-5 24 +234U G 960.0 100.0009 3 +234U G 1765.44 100.0084 6 +234U G 1809.05 100.00376 7 +234U L 1863.11 7 (1)+ +234U B 406 4 0.00311 19 7.4 +234U S B EAV=116.0 13 +234U G 936.3 100.00102 17 +234U G 1819.69 100.00089 5 +234U G 1863.09 100.00120 5 +234U L 1874.86 8 (1)+ +234U B 394 4 0.0258 3 6.4 +234U S B EAV=112.3 13 +234U G 1831.37 100.01759 23 +234U G 1874.9 1 0.00819 14 +234U L 1911.04 5 (1-) +234U B 358 4 0.0452 8 6 +234U S B EAV=101.0 13 +234U G 357.5 100.00080 17 +234U G 453.58 100.00213 12[M1] 0.324 5 +234U 2 G KC=0.258 4$LC=0.0495 7$MC=0.01193 17$NC=0.00321 5 +234U 3 G OC=0.000781 11 +234U G 475.74 100.00237 13[M1] 0.285 4 +234U 2 G KC=0.227 4$LC=0.0434 6$MC=0.01048 15$NC=0.00282 4 +234U 3 G OC=0.000686 10 +234U G 673.9 100.00064 13[M1] 0.1118 17 +234U 2 G KC=0.0894 13$LC=0.01695 25$MC=0.00408 6$NC=0.001100 16 +234U 3 G OC=0.000268 4 +234U G 825.5 2 0.0014 4 +234U G 866.8 100.00116 16 +234U G 921.72 100.01275 20 +234U G 1059.4 8 0.00111 22 +234U G 1061.86 100.00224 9 +234U G 1124.93 100.00347 9 +234U G 1867.7 1 0.00932 12 +234U G 1911.20 110.00628 9 +234U L 1936.68 7 (1)+ +234U B 332 4 0.0108 3 6.6 +234U S B EAV=93.0 13 +234U G 699.02 100.0058 3 +234U G 1893.51 110.00218 6 +234U G 1937.01 130.00285 5 +234U L 1970.0 5 (1-) +234U B 299 4 0.00389 22 6.8 1 +234U S B EAV=83.0 13 +234U G 732.5 100.00130 15 +234U G 1120.6 8 0.00173 15 +234U G 1926.5 100.00045 4 +234U G 1970.3 8 0.00041 4 + diff --git a/HEN_HOUSE/spectra/lnhb/Pb-203.txt b/HEN_HOUSE/spectra/lnhb/Pb-203.txt index 8128d7fcb..0d89e2d55 100644 --- a/HEN_HOUSE/spectra/lnhb/Pb-203.txt +++ b/HEN_HOUSE/spectra/lnhb/Pb-203.txt @@ -1,53 +1,54 @@ -203TL 203PB EC DECAY (51.929 H) -203TL H TYP=Full$AUT=V.Chisté$CUT=01-JUL-2006$ -203TL C Evaluation history: Type=Full;Author=V.Chisté;Cutoff date=01-JUL-2006 -203TL C References: 1941Fa04, 1952He18, 1954Pr04, 1954Th17, 1954Wa12, 1955Az33, -203TL2C 1955Do12, 1955Ma40, 1956No26, 1956Wo09, 1956OF03, 1956Wa30, 1957Be57, -203TL3C 1958Bart, 1958Ni28, 1960Pe16, 1960St21, 1960Ra04, 1960Pe22, 1960Jo15, -203TL4C 1960Go15, 1960Ba16, 1960De04, 1961Ge01, 1961Hu15, 1961Pe12, 1961Sc04, -203TL5C 1961Su10, 1962Ta06, 1962De14, 1963Bu09, 1963Cr14, 1964He19, 1964Ro19, -203TL6C 1965Ka02, 1965Ra12, 1965Wa13, 1967Pa09, 1968Ra26, 1968Sa22, 1969Cl11, -203TL7C 1971Ch54, 1971WaKF, 1974Ha29, 1978He21, 1980Ho17, 1982HoZJ, 1985HaZA, -203TL8C 1989Ne05, 1996Sc06, 2000He14, 2000Sc05, 2001Li17, 2002Un02, 2003Au03, -203TL9C 2005Ko20, 2006Ra03 -203TL T Auger electrons and X ray energies and emission intensities: -203TL T {U Energy (keV)} {U Intensity} {U Line} -203TL T -203TL T 70.8325 25.61 19 XKA2 -203TL T 72.8725 43.24 25 XKA1 -203TL T -203TL T 82.118 |] XKB3 -203TL T 82.577 |] 14.70 24 XKB1 -203TL T 83.115 |] XKB5II -203TL T -203TL T 84.838 |] XKB2 -203TL T 85.134 |] 4.37 11 XKB4 -203TL T 85.444 |] XKO23 -203TL T -203TL T 8.9531-14.7362 33.2 6 XL (total) -203TL T 8.9531 0.819 21 XLL -203TL T 10.1718-10.2679 15.8 4 XLA -203TL T 10.9942 0.243 6 XLC -203TL T 11.8117-12.9566 13.79 25 XLB -203TL T 13.8528-14.7362 2.58 5 XLG -203TL T -203TL T 54.587-59.954 |] KLL AUGER -203TL T 66.37-72.86 |] 3.4 4 KLX AUGER -203TL T 78.12-85.5 |] KXY AUGER -203TL T 5.18-15.31 57.9 6 L AUGER -203PB P 0.0 5/2- 51.929 H 10 975 6 -203TL N 1.0 1.0 1 1.0 -203TL L 0 1/2+ STABLE -203TL L 279.1958 123/2+ 282.3 PS 37 -203TL E 95.20 126.404 1 -203TL2 E CK=0.7786 4$CL=0.1661 3$CM=0.0552 1$CO=0 0 -203TL G 279.1952 1080.94 5M1+E2 1.17 6 0.2261 8 -203TL2 G KC=0.164 1$LC=0.04837 48 -203TL L 680.5164 225/2+ 0.88 PS 8 -203TL E 4.80 86.812 -203TL2 E CK=0.7076 32$CL=0.2168 22$CM=0.0756 9$CO=0 0 -203TL G 401.320 3 3.43 6M1+E2 0.030 3 0.1784 25 -203TL2 G KC=0.1464 21$LC=0.0245 4$MC=0.00572 8 -203TL G 680.515 3 0.754 18E2 0.0139320 -203TL2 G KC=0.01065 15$LC=0.00250 4$MC=6.05E-4 9 - +203TL 203PB EC DECAY (51.929 H) +203TL H TYP=FUL$AUT=V.CHISTE$CUT=01-JUL-2006$ +203TL C References:1941Fa04, 1952He18, 1954Pr04, 1954Th17, 1954Wa12, 1955Az33, +203TL2C 1955Do12, 1955Ma40, 1956No26, 1956Wo09, 1956OF03, 1956Wa30, 1957Be57, +203TL3C 1958Bart, 1958Ni28, 1960Pe16, 1960St21, 1960Ra04, 1960Pe22, 1960Jo15, +203TL4C 1960Go15, 1960Ba16, 1960De04, 1961Ge01, 1961Hu15, 1961Pe12, 1961Sc04, +203TL5C 1961Su10, 1962Ta06, 1962De14, 1963Bu09, 1963Cr14, 1964He19, 1964Ro19, +203TL6C 1965Ka02, 1965Ra12, 1965Wa13, 1967Bo47, 1967Pa09, 1968Ra26, 1968Sa22, +203TL7C 1969Cl11, 1971Ch54, 1971WaKF, 1974Ha29, 1978He21, 1980Ho17, 1982HoZJ, +203TL8C 1985HaZA, 1989Ne05, 1996Sc06, 2000He14, 2000Sc05, 2001Li17, 2002Un02, +203TL9C 2003Au03, 2005Ko20, 2006Ra03 +203TL T Auger electrons and X ray energies and emission intensities: +203TL T {U Energy (keV)} {U Intensity} {U Line} +203TL T +203TL T 70.8325 25.61 19 XKA2 +203TL T 72.8725 43.24 25 XKA1 +203TL T +203TL T 82.118 |] XKB3 +203TL T 82.577 |] 14.70 24 XKB1 +203TL T 83.115 |] XKB5II +203TL T +203TL T 84.838 |] XKB2 +203TL T 85.134 |] 4.37 11 XKB4 +203TL T 85.444 |] XKO23 +203TL T +203TL T 8.9531-14.7362 33.2 6 XL (total) +203TL T 8.9531 0.819 21 XLL +203TL T 10.1718-10.2679 15.8 4 XLA +203TL T 10.9942 0.243 6 XLC +203TL T 11.8117-12.9566 13.79 25 XLB +203TL T 13.8528-14.7362 2.58 5 XLG +203TL T +203TL T 54.587-59.954 |] KLL AUGER +203TL T 66.37-72.86 |] 3.4 4 KLX AUGER +203TL T 78.12-85.5 |] KXY AUGER +203TL T 5.18-15.31 57.9 6 L AUGER +203PB P 0.0 5/2- 51.929 H 10 975 6 +203TL N 1.0 1.0 1 1.0 +203TL L 0 1/2+ STABLE +203TL L 279.1958 123/2+ 282.3 PS 37 +203TL E 95.20 126.404 1 +203TL2 E CK=0.7786 4$CL=0.1661 3$CM=0.0552 1 +203TL G 279.1952 1080.94 5M1+E2 1.17 6 0.2261 8 +203TL2 G KC=0.164 1$LC=0.04837 48 +203TL L 680.5164 225/2+ 0.88 PS 8 +203TL E 4.80 86.812 +203TL2 E CK=0.7076 32$CL=0.2168 22$CM=0.0756 9 +203TL G 401.320 3 3.43 6M1+E2 0.030 3 0.1784 25 +203TL2 G KC=0.1464 21$LC=0.0245 4$MC=0.00572 8$NC=0.001444 21 +203TL3 G OC=0.000281 4 +203TL G 680.515 3 0.754 18E2 0.0139320 +203TL2 G KC=0.01065 15$LC=0.00250 4$MC=0.000605 9$NC=1.521E-4 22 +203TL3 G OC=2.84E-5 4 + diff --git a/HEN_HOUSE/spectra/lnhb/Pb-209.txt b/HEN_HOUSE/spectra/lnhb/Pb-209.txt index d12ff0b68..e63df4e28 100644 --- a/HEN_HOUSE/spectra/lnhb/Pb-209.txt +++ b/HEN_HOUSE/spectra/lnhb/Pb-209.txt @@ -1,32 +1,30 @@ -209BI 209PB B- DECAY (3.277 H) -209BI H TYP=Full$AUT=F. Kondev$CUT=31-DEC-2010$ -209BI2 H TYP=full$AUT=mmbe$CUT= -- $ -209BI C Evaluation history: Type=Full;Author=F. Kondev;Cutoff date=31-DEC-2010 -209BI2C Type=full;Author=mmbe;Cutoff date= -- -209BI C References: 1940Kr08, 1941Fa04, 1942Ma03, 1959Po64, 1971Go40, 1971Pe03, -209BI2C 1972Be44, 1991Ma16, 2003Au03 -209BI T Auger electrons and X ray energies and emission intensities: -209BI T {U Energy (keV)} {U Intensity} {U Line} -209BI T -209BI T 74.8157 XKA2 -209BI T 77.1088 XKA1 -209BI T -209BI T 86.835 |] XKB3 -209BI T 87.344 |] XKB1 -209BI T 87.862 |] XKB5II -209BI T -209BI T 89.732 |] XKB2 -209BI T 90.074 |] XKB4 -209BI T 90.421 |] XKO23 -209BI T -209BI T -209BI T 57.491-63.419 |] KLL AUGER -209BI T 70.025-77.105 |] KLX AUGER -209BI T 82.53-90.52 |] KXY AUGER -209BI T 5.4204-16.3366 L AUGER -209PB P 0.0 9/2+ 3.277 H 15 644.0 12 -209BI N 1.0 1.0 1 1.0 -209BI L 0 9/2- STABLE -209BI B 644.0 12100 5.54 -209BIS B EAV=197.35 42 - +209BI 209PB B- DECAY (3.277 H) +209BI H TYP=FUL$AUT=F.G.KONDEV$CUT=31-DEC-2010$ +209BI2 H TYP=FUL$AUT=M.-M.BE$CUT=28-FEB-2007$ +209BI C References:1940Kr08, 1941Fa04, 1942Ma03, 1959Po64, 1971Go40, 1971Pe03, +209BI2C 1972Be44, 1991Ma16, 2003Au03 +209BI T Auger electrons and X ray energies and emission intensities: +209BI T {U Energy (keV)} {U Intensity} {U Line} +209BI T +209BI T 74.8157 XKA2 +209BI T 77.1088 XKA1 +209BI T +209BI T 86.835 |] XKB3 +209BI T 87.344 |] XKB1 +209BI T 87.862 |] XKB5II +209BI T +209BI T 89.732 |] XKB2 +209BI T 90.074 |] XKB4 +209BI T 90.421 |] XKO23 +209BI T +209BI T +209BI T 57.491-63.419 |] KLL AUGER +209BI T 70.025-77.105 |] KLX AUGER +209BI T 82.53-90.52 |] KXY AUGER +209BI T 5.4204-16.3366 L AUGER +209PB P 0.0 9/2+ 3.277 H 15 644.0 12 +209BI N 1.0 1.0 1 1.0 +209BI L 0 9/2- STABLE +209BI B 644.0 12100 5.54 +209BIS B EAV=197.35 42 + diff --git a/HEN_HOUSE/spectra/lnhb/Pb-210.txt b/HEN_HOUSE/spectra/lnhb/Pb-210.txt index 83634f900..e620eb76c 100644 --- a/HEN_HOUSE/spectra/lnhb/Pb-210.txt +++ b/HEN_HOUSE/spectra/lnhb/Pb-210.txt @@ -1,70 +1,69 @@ -206HG 210PB A DECAY (22.23 Y) -206HG H TYP=Full$AUT=V. Chisté$CUT= -- $ -206HG C Evaluation history: Type=Full;Author=V. Chisté;Cutoff date= -- -206HG C References: 1951Bu37, 1953Wu28, 1954Da23, 1955To14, 1956St99, 1957To16, -206HG2C 1957Me47, 1957Fi06, 1958Kr71, 1958To10, 1959Pa03, 1959Ha02, 1960Ec01, -206HG3C 1961Nu01, 1962Ka27, 1963Im02, 1964Wo05, 1964Ra12, 1967Vo04, 1969Ho06, -206HG4C 1969Gr33, 1971Ge11, 1981He15, 1983De11, 1987Me17, 1990He18, 1990Sc08, -206HG5C 1990Hi03, 1996Sc06, 1999Br38, 2000He14, 2002Re18, 2002Ba85, 2003Br13, -206HG6C 2003Au03 -206HG T Auger electrons and X ray energies and emission intensities: -206HG T {U Energy (keV)} {U Intensity} {U Line} -206HG T -206HG T 68.895 XKA2 -206HG T 70.82 XKA1 -206HG T -206HG T 79.823 |] XKB3 -206HG T 80.254 |] XKB1 -206HG T 80.762 |] XKB5II -206HG T -206HG T 82.435 |] XKB2 -206HG T 82.776 |] XKB4 -206HG T 83.028 |] XKO23 -206HG T -210PB P 0.0 0+ 22.23 Y 12 3792 20 -206HG N 5.263E7 5.263E7 1.9E-08 5.263E7 -206HG L 0 0+ 8.32 M 7 -206HG A 3720 20100 211 - -210BI 210PB B- DECAY (22.23 Y) -210BI H TYP=Full$AUT=V. Chisté$CUT= -- $ -210BI C Evaluation history: Type=Full;Author=V. Chisté;Cutoff date= -- -210BI C References: 1951Bu37, 1953Wu28, 1954Da23, 1955To14, 1956St99, 1957To16, -210BI2C 1957Me47, 1957Fi06, 1958Kr71, 1958To10, 1959Pa03, 1959Ha02, 1960Ec01, -210BI3C 1961Nu01, 1962Ka27, 1963Im02, 1964Wo05, 1964Ra12, 1967Vo04, 1969Ho06, -210BI4C 1969Gr33, 1971Ge11, 1981He15, 1983De11, 1987Me17, 1990He18, 1990Sc08, -210BI5C 1990Hi03, 1996Sc06, 1999Br38, 2000He14, 2002Re18, 2002Ba85, 2003Br13, -210BI6C 2003Au03 -210BI T Auger electrons and X ray energies and emission intensities: -210BI T {U Energy (keV)} {U Intensity} {U Line} -210BI T -210BI T 74.8157 XKA2 -210BI T 77.1088 XKA1 -210BI T -210BI T 86.835 |] XKB3 -210BI T 87.344 |] XKB1 -210BI T 87.862 |] XKB5II -210BI T -210BI T 89.732 |] XKB2 -210BI T 90.074 |] XKB4 -210BI T 90.421 |] XKO23 -210BI T -210BI T 9.4207-15.7084 22.0 5 XL (total) -210BI T 9.4207 0.552 17 XLL -210BI T 10.7308-10.8387 10.30 29 XLA -210BI T 11.7127 0.0745 21 XLC -210BI T 12.4814-13.8066 9.05 13 XLB -210BI T 14.7735-15.7084 1.968 28 XLG -210BI T -210BI T 5.3-10.7 36.0 9 L AUGER -210PB P 0.0 0+ 22.23 Y 12 63.5 5 -210BI N 1.0 1.0 1 1.0 -210BI L 0 1- 5.012 D 5 -210BI B 63.5 5 19.8 13 7.8 1 -210BIS B EAV=16.3 1 -210BI L 46.539 1 0- 3 NS -210BI B 17.0 5 80.2 13 5.5 -210BIS B EAV=4.3 1 -210BI G 46.539 1 4.252 40M1 17.86 25 -210BI2 G LC=13.64 19$MC=3.21 5 - +206HG 210PB A DECAY (22.23 Y) +206HG H TYP=FUL$AUT=V.CHISTE$CUT=31-OCT-2007$ +206HG C References:1951Bu37, 1953Wu28, 1954Da23, 1955To14, 1956St99, 1957To16, +206HG2C 1957Me47, 1957Fi06, 1958Kr71, 1958To10, 1959Pa03, 1959Ha02, 1960Ec01, +206HG3C 1961Nu01, 1962Ka27, 1963Im02, 1964Wo05, 1964Ra12, 1967Vo04, 1969Ho06, +206HG4C 1969Gr33, 1971Ge11, 1981He15, 1983De11, 1987Me17, 1990He18, 1990Sc08, +206HG5C 1990Hi03, 1996Sc06, 1999Br38, 2000He14, 2002Re18, 2002Ba85, 2003Br13, +206HG6C 2003Au03 +206HG T Auger electrons and X ray energies and emission intensities: +206HG T {U Energy (keV)} {U Intensity} {U Line} +206HG T +206HG T 68.895 XKA2 +206HG T 70.82 XKA1 +206HG T +206HG T 79.823 |] XKB3 +206HG T 80.254 |] XKB1 +206HG T 80.762 |] XKB5II +206HG T +206HG T 82.435 |] XKB2 +206HG T 82.776 |] XKB4 +206HG T 83.028 |] XKO23 +206HG T +210PB P 0.0 0+ 22.23 Y 12 3792 20 +206HG N 5.263E7 5.263E7 1.9E-8 +206HG L 0 0+ 8.32 M 7 +206HG A 3720 20100 211 + +210BI 210PB B- DECAY (22.23 Y) +210BI H TYP=FUL$AUT=V.CHISTE$CUT=31-OCT-2007$ +210BI C References:1951Bu37, 1953Wu28, 1954Da23, 1955To14, 1956St99, 1957To16, +210BI2C 1957Me47, 1957Fi06, 1958Kr71, 1958To10, 1959Pa03, 1959Ha02, 1960Ec01, +210BI3C 1961Nu01, 1962Ka27, 1963Im02, 1964Wo05, 1964Ra12, 1967Vo04, 1969Ho06, +210BI4C 1969Gr33, 1971Ge11, 1981He15, 1983De11, 1987Me17, 1990He18, 1990Sc08, +210BI5C 1990Hi03, 1996Sc06, 1999Br38, 2000He14, 2002Re18, 2002Ba85, 2003Br13, +210BI6C 2003Au03 +210BI T Auger electrons and X ray energies and emission intensities: +210BI T {U Energy (keV)} {U Intensity} {U Line} +210BI T +210BI T 74.8157 XKA2 +210BI T 77.1088 XKA1 +210BI T +210BI T 86.835 |] XKB3 +210BI T 87.344 |] XKB1 +210BI T 87.862 |] XKB5II +210BI T +210BI T 89.732 |] XKB2 +210BI T 90.074 |] XKB4 +210BI T 90.421 |] XKO23 +210BI T +210BI T 9.4207-15.7084 22.0 5 XL (total) +210BI T 9.4207 0.552 17 XLL +210BI T 10.7308-10.8387 10.30 29 XLA +210BI T 11.7127 0.0745 21 XLC +210BI T 12.4814-13.8066 9.05 13 XLB +210BI T 14.7735-15.7084 1.968 28 XLG +210BI T +210BI T 5.3-10.7 36.0 9 L AUGER +210PB P 0.0 0+ 22.23 Y 12 63.5 5 +210BI N 1.0 1.0 1 1.0 +210BI L 0 1- 5.012 D 5 +210BI B 63.5 5 19.8 13 7.8 1 +210BIS B EAV=16.3 1 +210BI L 46.539 1 0- 3 NS +210BI B 17.0 5 80.2 13 5.5 +210BIS B EAV=4.3 1 +210BI G 46.539 1 4.252 40M1 17.86 25 +210BI2 G LC=13.64 19$MC=3.21 5$NC=0.822 12 +210BI3 G OC=0.1678 24 + diff --git a/HEN_HOUSE/spectra/lnhb/Pb-211.txt b/HEN_HOUSE/spectra/lnhb/Pb-211.txt index 46377e156..6eeca8a6f 100644 --- a/HEN_HOUSE/spectra/lnhb/Pb-211.txt +++ b/HEN_HOUSE/spectra/lnhb/Pb-211.txt @@ -1,98 +1,107 @@ -211BI 211PB B- DECAY (36.1 M) -211BI H TYP=Full$AUT=F.G. Kondev$CUT=30-MAY-2011$ -211BI C Evaluation history: Type=Full;Author=F.G. Kondev;Cutoff date=30-MAY-2011 -211BI C References: 1939Sa11, 1962Gi03, 1963Va05, 1965Co06, 1965Me07, 1965Nu03, -211BI2C 1967Da10, 1967Da20, 1968Br17, 1968Go15, 1968Ha21, 1971Da34, 1971Go40, -211BI3C 1976Bl13, 1988Hi14, 1996Sc06, 1998ScZM, 1999ScZX, 2000Sc47, 2003Au03, -211BI4C 2003De44, 2004Br45, 2008DuZX, 2008Ki07, 2011Ko04 -211BI T Auger electrons and X ray energies and emission intensities: -211BI T {U Energy (keV)} {U Intensity} {U Line} -211BI T -211BI T 74.8157 0.228 10 XKA2 -211BI T 77.1088 0.381 17 XKA1 -211BI T -211BI T 86.835 |] XKB3 -211BI T 87.344 |] 0.130 6 XKB1 -211BI T 87.862 |] XKB5II -211BI T -211BI T 89.732 |] XKB2 -211BI T 90.074 |] 0.0399 20 XKB4 -211BI T 90.421 |] XKO23 -211BI T -211BI T 9.4207-15.7084 0.494 13 XL (total) -211BI T 9.4207 0.0120 5 XLL -211BI T 10.7308-10.8387 0.225 8 XLA -211BI T 11.7127 0.00330 15 XLC -211BI T 12.4814-13.8066 0.211 6 XLB -211BI T 14.7735-15.7084 0.0427 12 XLG -211BI T -211BI T 57.491-63.419 |] KLL AUGER -211BI T 70.025-77.105 |] 0.029 4 KLX AUGER -211BI T 82.53-90.52 |] KXY AUGER -211BI T 5.42-16.34 0.782 18 L AUGER -211PB P 0.0 9/2+ 36.1 M 2 1367 6 -211BI N 1.0 1.0 1 1.0 -211BI L 0 9/2- 2.15 M 2 -211BI B 1367 6 91.28 12 5.99 -211BIS B EAV=470.9 24 -211BI L 404.834 9 7/2- 0.317 NS 11 -211BI B 962 6 1.57 9 7.21 1 -211BIS B EAV=313.3 23 -211BI G 404.834 9 3.83 6M1+E2 -1.1 1 0.122 8 -211BI2 G KC=0.095 7$LC=0.0206 8$MC=0.00499 17 -211BI L 766.680 13(9/2,11/2)- -211BI B 600 6 0.09 7.7 -211BIS B EAV=182.2 21 -211BI G 361.846 160.042 3[M1E2] 0.17 11 -211BI2 G KC=0.14 10$LC=0.03 1$MC=0.0072 20 -211BI G 766.680 130.62 4M1 0.0382 6 -211BI2 G KC=0.0313 5$LC=0.00527 8$MC=1234E-6 18 -211BI L 831.984 129/2- -211BI B 535 6 6.32 9 5.73 -211BIS B EAV=159.8 21 -211BI G 65.304 180.077 4M1 6.61 10 -211BI2 G LC=5.05 7$MC=1.188 17 -211BI G 427.150 151.81 4M1+E2 -0.022 9 0.1783 25 -211BI2 G KC=0.1457 21$LC=0.0249 4$MC=0.00585 9 -211BI G 831.984 123.50 5M1+E2 0.4 2 0.028 3 -211BI2 G KC=0.0229 23$LC=0.0039 4$MC=0.00092 8 -211BI L 1014.38 4 (7/2,9/2,11/2)- -211BI G 609.55 4 0.033 9 -211BI G 1014.38 4 0.0173 5 -211BI L 1080.64 4 + -211BI B 286 6 0.0570 24 -211BIS B EAV=79.7 19 -211BI G 313.96 4 0.0268 21 -211BI G 675.81 4 0.0181 9 -211BI G 1080.64 4 0.0121 5 -211BI L 1103.52 20 + -211BI B 263 6 0.0047 7 -211BIS B EAV=72.8 18 -211BI G 1103.52 200.0047 7 -211BI L 1109.509 239/2- -211BI B 257 6 1.06 4 5.58 -211BIS B EAV=71.0 18 -211BI G 95.13 5 0.018 3M1+E2 1.7 6 9.3 4 -211BI2 G KC=2.8 9$LC=4.8 5$MC=1.27 12 -211BI G 342.83 3 0.029 4[M1E2] 0.20 12 -211BI2 G KC=0.16 11$LC=0.035 11$MC=0.0085 22 -211BI G 704.675 250.47 1M1+E2 -0.022 7 0.0476 7 -211BI2 G KC=0.0390 6$LC=0.00657 10$MC=1540E-6 22 -211BI G 1109.509 230.116 3[M1] 0.0147221 -211BI2 G KC=0.01209 17$LC=0.00201 3$MC=4.70E-4 7 -211BI L 1196.33 5 + -211BI B 171 6 0.019 4 -211BIS B EAV=45.6 18 -211BI G 429.65 6 0.008 3 -211BI G 1196.33 5 0.0103 4 -211BI L 1234.3 4 + -211BI B 133 6 0.0009 3 -211BIS B EAV=35.0 17 -211BI G 1234.3 4 0.0009 3 -211BI L 1270.75 6 (7/2,9/2,11/2)+ -211BI B 96 6 0.0172 15 5.93 -211BIS B EAV=25.0 17 -211BI G 504.07 6 0.0059 8 -211BI G 865.92 6 0.0046 2 -211BI G 1270.75 6 0.0068 12 - +211BI 211PB B- DECAY (36.1 M) +211BI H TYP=FUL$AUT=F.G.KONDEV$CUT=30-MAY-2011$ +211BI C References:1939Sa11, 1962Gi03, 1963Va05, 1965Co06, 1965Me07, 1965Nu03, +211BI2C 1967Da10, 1967Da20, 1968Br17, 1968Go15, 1968Ha21, 1971Da34, 1971Go40, +211BI3C 1976Bl13, 1988Hi14, 1996Sc06, 1998ScZM, 1999ScZX, 2000Sc47, 2003Au03, +211BI4C 2003De44, 2004Br45, 2008DuZX, 2008Ki07, 2011Ko04 +211BI T Auger electrons and X ray energies and emission intensities: +211BI T {U Energy (keV)} {U Intensity} {U Line} +211BI T +211BI T 74.8157 0.228 10 XKA2 +211BI T 77.1088 0.381 17 XKA1 +211BI T +211BI T 86.835 |] XKB3 +211BI T 87.344 |] 0.130 6 XKB1 +211BI T 87.862 |] XKB5II +211BI T +211BI T 89.732 |] XKB2 +211BI T 90.074 |] 0.0399 20 XKB4 +211BI T 90.421 |] XKO23 +211BI T +211BI T 9.4207-15.7084 0.494 13 XL (total) +211BI T 9.4207 0.0120 5 XLL +211BI T 10.7308-10.8387 0.225 8 XLA +211BI T 11.7127 0.00330 15 XLC +211BI T 12.4814-13.8066 0.211 6 XLB +211BI T 14.7735-15.7084 0.0427 12 XLG +211BI T +211BI T 57.491-63.419 |] KLL AUGER +211BI T 70.025-77.105 |] 0.029 4 KLX AUGER +211BI T 82.53-90.52 |] KXY AUGER +211BI T 5.42-16.34 0.782 18 L AUGER +211PB P 0.0 9/2+ 36.1 M 2 1367 6 +211BI N 1.0 1.0 1 1.0 +211BI L 0 9/2- 2.15 M 2 +211BI B 1367 6 91.28 12 5.99 +211BIS B EAV=470.9 24 +211BI L 404.834 9 7/2- 0.317 NS 11 +211BI B 962 6 1.57 9 7.21 1 +211BIS B EAV=313.3 23 +211BI G 404.834 9 3.83 6M1+E2 -1.1 1 0.122 8 +211BI2 G KC=0.095 7$LC=0.0206 8$MC=0.00499 17$NC=0.00127 5 +211BI3 G OC=0.000254 10 +211BI L 766.680 13(9/2,11/2)- +211BI B 600 6 0.09 7.7 +211BIS B EAV=182.2 21 +211BI G 361.846 160.042 3[M1,E2] 0.17 11 +211BI2 G KC=0.14 10$LC=0.03 1$MC=0.0072 20$NC=0.0018 5 +211BI3 G OC=0.00037 12 +211BI G 766.680 130.62 4M1 0.0382 6 +211BI2 G KC=0.0313 5$LC=0.00527 8$MC=0.001234 18$NC=0.000315 5 +211BI3 G OC=6.45E-5 9 +211BI L 831.984 129/2- +211BI B 535 6 6.32 9 5.73 +211BIS B EAV=159.8 21 +211BI G 65.304 180.077 4M1 6.61 10 +211BI2 G LC=5.05 7$MC=1.188 17$NC=0.304 5 +211BI3 G OC=0.0621 9 +211BI G 427.150 151.81 4M1+E2 -0.022 9 0.1783 25 +211BI2 G KC=0.1457 21$LC=0.0249 4$MC=0.00585 9$NC=0.001497 21 +211BI3 G OC=0.000306 5 +211BI G 831.984 123.50 5M1+E2 0.4 2 0.028 3 +211BI2 G KC=0.0229 23$LC=0.0039 4$MC=0.00092 8$NC=0.000234 20 +211BI3 G OC=0.000048 4 +211BI L 1014.38 4 (7/2,9/2,11/2)- +211BI G 609.55 4 0.033 9 +211BI G 1014.38 4 0.0173 5 +211BI L 1080.64 4 +211BI B 286 6 0.0570 24 +211BIS B EAV=79.7 19 +211BI G 313.96 4 0.0268 21 +211BI G 675.81 4 0.0181 9 +211BI G 1080.64 4 0.0121 5 +211BI L 1103.52 20 +211BI B 263 6 0.0047 7 +211BIS B EAV=72.8 18 +211BI G 1103.52 200.0047 7 +211BI L 1109.509 239/2- +211BI B 257 6 1.06 4 5.58 +211BIS B EAV=71.0 18 +211BI G 95.13 5 0.018 3M1+E2 1.7 6 9.3 4 +211BI2 G KC=2.8 9$LC=4.8 5$MC=1.27 12$NC=0.32 3 +211BI3 G OC=0.060 6 +211BI G 342.83 3 0.029 4[M1,E2] 0.20 12 +211BI2 G KC=0.16 11$LC=0.035 11$MC=0.0085 22$NC=0.0022 6 +211BI3 G OC=0.00043 13 +211BI G 704.675 250.47 1M1+E2 -0.022 7 0.0476 7 +211BI2 G KC=0.0390 6$LC=0.00657 10$MC=0.001540 22$NC=0.000394 6 +211BI3 G OC=8.05E-5 12 +211BI G 1109.509 230.116 3[M1] 0.0147221 +211BI2 G KC=0.01209 17$LC=0.00201 3$MC=0.000470 7$NC=1.203E-4 17 +211BI3 G OC=2.46E-5 4 +211BI L 1196.33 5 +211BI B 171 6 0.019 4 +211BIS B EAV=45.6 18 +211BI G 429.65 6 0.008 3 +211BI G 1196.33 5 0.0103 4 +211BI L 1234.3 4 +211BI B 133 6 0.0009 3 +211BIS B EAV=35.0 17 +211BI G 1234.3 4 0.0009 3 +211BI L 1270.75 6 (7/2,9/2,11/2)+ +211BI B 96 6 0.0172 15 5.93 +211BIS B EAV=25.0 17 +211BI G 504.07 6 0.0059 8 +211BI G 865.92 6 0.0046 2 +211BI G 1270.75 6 0.0068 12 + diff --git a/HEN_HOUSE/spectra/lnhb/Pb-212.txt b/HEN_HOUSE/spectra/lnhb/Pb-212.txt index bd7d962f4..7ed0b8ec4 100644 --- a/HEN_HOUSE/spectra/lnhb/Pb-212.txt +++ b/HEN_HOUSE/spectra/lnhb/Pb-212.txt @@ -1,60 +1,64 @@ -212BI 212PB B- DECAY (10.64 H) -212BI H TYP=Update$AUT=A.L. Nichols$CUT=30-MAY-2010$ -212BI2 H TYP=Full$AUT=A.L. Nichols$CUT=01-JAN-2004$ -212BI C Evaluation history: Type=Update;Author=A.L. Nichols;Cutoff date=30-MAY-2010 -212BI2C Type=Full;Author=A.L. Nichols;Cutoff date=01-JAN-2004 -212BI C References: 1948Ma30, 1952Bu72, 1953Ma26, 1955To11, 1957Kr49, 1957Ni11, -212BI2C 1959Se59, 1960Ro16, 1961Gi02, 1963Da11, 1969Kr06, 1972DaZA, 1973Da38, -212BI3C 1977La19, 1978Av01, 1982Sa36, 1983Va22, 1983Sc13, 1984Ge07, 1992Li05, -212BI4C 1996Sc06, 1999ScZM, 1999ScZX, 2002Ra45, 2002Ba85, 2003Au03, 2005Br03, -212BI5C 2008Ki07 -212BI T Auger electrons and X ray energies and emission intensities: -212BI T {U Energy (keV)} {U Intensity} {U Line} -212BI T -212BI T 74.8157 10.07 18 XKA2 -212BI T 77.1088 16.9 3 XKA1 -212BI T -212BI T 86.835 |] XKB3 -212BI T 87.344 |] 5.77 13 XKB1 -212BI T 87.862 |] XKB5II -212BI T -212BI T 89.732 |] XKB2 -212BI T 90.074 |] 1.77 5 XKB4 -212BI T 90.421 |] XKO23 -212BI T -212BI T 9.42-15.709 13.8 6 XL (total) -212BI T 9.42 0.340 9 XLL -212BI T 10.731-10.839 6.36 16 XLA -212BI T 11.712 0.103 3 XLC -212BI T 12.48-13.393 5.76 12 XLB -212BI T 15.248-15.709 1.111 23 XLG -212BI T -212BI T 57.49-63.42 |] KLL AUGER -212BI T 70.03-77.11 |] 1.29 15 KLX AUGER -212BI T 82.53-90.52 |] KXY AUGER -212BI T 5.35-10.66 21.4 7 L AUGER -212PB P 0.0 0+ 10.64 H 1 569.9 19 -212BI N 1.0 1.0 1 1.0 -212BI L 0 1- 60.54 M 6 -212BI B 569.9 1913.3 11 6.74 1 -212BIS B EAV=171.7 7 -212BI L 115.183 5 2- -212BI G 115.183 5 0.624 23[M1] 6.8 1 -212BI2 G KC=5.53 8$LC=0.972 14$MC=0.229 4 -212BI L 238.632 2 0- -212BI B 331.3 1981.7 11 5.18 -212BIS B EAV=93.5 6 -212BI G 123.449 5 0.052 5[E2] 2.80 4 -212BI2 G KC=0.421 6$LC=1.766 25$MC=0.468 7 -212BI G 238.632 2 43.6 5[M1] 0.872 13 -212BI2 G KC=0.71 1$LC=0.1232 18$MC=0.0290 4 -212BI L 415.272 111- -212BI B 154.6 194.99 21 5.35 1 -212BIS B EAV=41.1 5 -212BI G 176.640 110.052 5[M1] 2.02 3 -212BI2 G KC=1.646 23$LC=0.287 4$MC=0.0675 10 -212BI G 300.089 123.18 14[M1] 0.464 7 -212BI2 G KC=0.378 6$LC=0.0653 10$MC=0.01534 22 -212BI G 415.272 110.144 22[M1] 0.192 3 -212BI2 G KC=0.1571 22$LC=0.0269 4$MC=0.00632 9 - +212BI 212PB B- DECAY (10.64 H) +212BI H TYP=UPD$AUT=A.L.NICHOLS$CUT=30-MAY-2010$ +212BI2 H TYP=FUL$AUT=A.L.NICHOLS$CUT=01-JAN-2004$ +212BI C References:1948Ma30, 1952Bu72, 1953Ma26, 1955To11, 1957Kr49, 1957Ni11, +212BI2C 1959Se59, 1960Ro16, 1961Gi02, 1963Da11, 1969Kr06, 1972DaZA, 1973Da38, +212BI3C 1977La19, 1978Av01, 1982Sa36, 1983Va22, 1983Sc13, 1984Ge07, 1992Li05, +212BI4C 1996Sc06, 1999ScZM, 1999ScZX, 2002Ra45, 2002Ba85, 2003Au03, 2005Br03, +212BI5C 2008Ki07 +212BI T Auger electrons and X ray energies and emission intensities: +212BI T {U Energy (keV)} {U Intensity} {U Line} +212BI T +212BI T 74.8157 10.07 18 XKA2 +212BI T 77.1088 16.9 3 XKA1 +212BI T +212BI T 86.835 |] XKB3 +212BI T 87.344 |] 5.77 13 XKB1 +212BI T 87.862 |] XKB5II +212BI T +212BI T 89.732 |] XKB2 +212BI T 90.074 |] 1.77 5 XKB4 +212BI T 90.421 |] XKO23 +212BI T +212BI T 9.42-15.709 13.8 6 XL (total) +212BI T 9.42 0.340 9 XLL +212BI T 10.731-10.839 6.36 16 XLA +212BI T 11.712 0.103 3 XLC +212BI T 12.48-13.393 5.76 12 XLB +212BI T 15.248-15.709 1.111 23 XLG +212BI T +212BI T 57.49-63.42 |] KLL AUGER +212BI T 70.03-77.11 |] 1.29 15 KLX AUGER +212BI T 82.53-90.52 |] KXY AUGER +212BI T 5.35-10.66 21.4 7 L AUGER +212PB P 0.0 0+ 10.64 H 1 569.9 19 +212BI N 1.0 1.0 1 1.0 +212BI L 0 1- 60.54 M 6 +212BI B 569.9 1913.3 11 6.74 1 +212BIS B EAV=171.7 7 +212BI L 115.183 5 2- +212BI G 115.183 5 0.624 23[M1] 6.8 1 +212BI2 G KC=5.53 8$LC=0.972 14$MC=0.229 4$NC=0.0585 9 +212BI3 G OC=0.01196 17 +212BI L 238.632 2 0- +212BI B 331.3 1981.7 11 5.18 +212BIS B EAV=93.5 6 +212BI G 123.449 5 0.052 5[E2] 2.80 4 +212BI2 G KC=0.421 6$LC=1.766 25$MC=0.468 7$NC=0.1191 17 +212BI3 G OC=0.0220 3 +212BI G 238.632 2 43.6 5[M1] 0.872 13 +212BI2 G KC=0.71 1$LC=0.1232 18$MC=0.0290 4$NC=0.00741 11 +212BI3 G OC=0.001514 22 +212BI L 415.272 111- +212BI B 154.6 194.99 21 5.35 1 +212BIS B EAV=41.1 5 +212BI G 176.640 110.052 5[M1] 2.02 3 +212BI2 G KC=1.646 23$LC=0.287 4$MC=0.0675 10$NC=0.01726 25 +212BI3 G OC=0.00353 5 +212BI G 300.089 123.18 14[M1] 0.464 7 +212BI2 G KC=0.378 6$LC=0.0653 10$MC=0.01534 22$NC=0.00392 6 +212BI3 G OC=0.000802 12 +212BI G 415.272 110.144 22[M1] 0.192 3 +212BI2 G KC=0.1571 22$LC=0.0269 4$MC=0.00632 9$NC=0.001616 23 +212BI3 G OC=0.000330 5 + diff --git a/HEN_HOUSE/spectra/lnhb/Pb-214.txt b/HEN_HOUSE/spectra/lnhb/Pb-214.txt index 902b62611..a0a634aec 100644 --- a/HEN_HOUSE/spectra/lnhb/Pb-214.txt +++ b/HEN_HOUSE/spectra/lnhb/Pb-214.txt @@ -1,100 +1,113 @@ -214BI 214PB B- DECAY (26.916 M) -214BI H TYP=update$AUT=V.Chisté$CUT= -- $ -214BI2 H TYP=Full$AUT=V.Chisté$CUT= -- $ -214BI C Evaluation history: Type=update;Author=V.Chisté;Cutoff date= -- -214BI2C Type=Full;Author=V.Chisté;Cutoff date= -- -214BI C References: 1931Cu03, 1952Be78, 1953Sa40, 1957Ni11, 1956Da28, 1964Ew04, -214BI2C 1969Li10, 1969Wa27, 1969Gr33, 1970Mo28, 1975Ha31, 1977Zo01, 1978Ro22, -214BI3C 1981Mo28, 1982Ak03, 1982Fa10, 1983Ol01, 1983Sc13, 1984Pe13, 1988Ak01, -214BI4C 1990Mo08, 1991Li11, 1993Di09, 1995El07, 1996Sc06, 1998Mo14, 2000Sa32, -214BI5C 2002De03, 2002MoZP, 2002Ba85, 2003Au03, 2004Mo07, 2007BeZP -214BI T Auger electrons and X ray energies and emission intensities: -214BI T {U Energy (keV)} {U Intensity} {U Line} -214BI T -214BI T 74.8157 6.26 12 XKA2 -214BI T 77.1088 10.47 20 XKA1 -214BI T -214BI T 86.835 |] XKB3 -214BI T 87.344 |] 3.59 9 XKB1 -214BI T 87.862 |] XKB5II -214BI T -214BI T 89.732 |] XKB2 -214BI T 90.074 |] 1.10 4 XKB4 -214BI T 90.421 |] XKO23 -214BI T -214BI T 9.42-16.36 12.42 22 XL (total) -214BI T 9.42 0.311 9 XLL -214BI T 10.45-10.55 5.80 15 XLA -214BI T 11.35 0.0770 21 XLC -214BI T 12.13-13.38 5.18 9 XLB -214BI T 14.31-16.36 1.039 18 XLG -214BI T -214BI T 57.49-63.42 |] KLL AUGER -214BI T 70.02-77.1 |] 0.80 9 KLX AUGER -214BI T 82.45-90.52 |] KXY AUGER -214BI T 5.3-16.4 19.8 3 L AUGER -214PB P 0.0 0+ 26.916 M 44 1019 11 -214BI N 1.0 1.0 1 1.0 -214BI G 107.22 9 0.0068 14 -214BI G 137.45 300.045 18 -214BI G 141.3 6 0.027 14 -214BI G 170.07 6 0.0146 27 -214BI G 216.47 7 0.0100 23 -214BI G 765.96 9 0.053 8 -214BI L 0 1- 19.8 M 1 -214BI B 1019 119.2 7 6.3 1 -214BIS B EAV=337 4 -214BI L 53.2275 21(2)- 0.52 NS 15 -214BI G 53.2275 211.060 7M1+E2 0.03 1 12.88 39 -214BI2 G LC=9.80 29$MC=2.32 7 -214BI L 62.7 1 + -214BI L 258.87 3 (2)- -214BI G 196.20 5 0.069 9 -214BI G 205.68 9 0.0114 23 -214BI G 258.87 3 0.5318 36M1 0.737 22 -214BI2 G KC=0.601 18$LC=0.1037 31$MC=0.0244 7 -214BI L 295.224 2 1- -214BI B 724 1141.09 39 5.2 1 -214BIS B EAV=227 4 -214BI G 241.997 3 7.268 22M1(+E2) 0.00 15 0.888 27 -214BI2 G KC=0.724 22$LC=0.1250 38$MC=0.0295 9 -214BI G 295.224 2 18.414 36M1+E2 0.30 13 0.482 14 -214BI2 G KC=0.390 12$LC=0.0698 21$MC=0.0165 5 -214BI L 351.932 2 (0,1)- -214BI B 667 1146.52 37 5.1 -214BIS B EAV=207 4 -214BI G 351.932 2 35.60 7M1(+E2) 0.00 35 0.319 10 -214BI2 G KC=0.260 8$LC=0.0445 13$MC=0.01049 31 -214BI L 377.03 4 - -214BI G 314.32 7 0.077 6 -214BI G 323.83 4 0.0287 32 -214BI L 533.67 2 (1)- -214BI B 485 111.047 17 6.2 1 -214BIS B EAV=145 4 -214BI G 274.80 5 0.362 10M1+E2 1 0.392 12 -214BI2 G KC=0.295 9$LC=0.0731 22$MC=0.0179 5 -214BI G 480.43 2 0.3371 41M1(+E2) 0 1 0.1384 42 -214BI2 G KC=0.1132 34$LC=0.0192 6$MC=0.00452 14 -214BI G 533.66 2 0.182 6[M1E2] 0.06 4 -214BI2 G KC=0.05 3$LC=0.010 4$MC=0.0023 9 -214BI L 797.24 9 + -214BI B 222 110.0196 27 6.9 -214BIS B EAV=62 3 -214BI G 538.41 8 0.0196 27 -214BI L 839.00 4 1+ -214BI B 180 112.762 22 4.5 -214BIS B EAV=50 3 -214BI G 305.26 3 0.0315 21[E1] 0.0295 9 -214BI2 G KC=0.0241 7$LC=0.00413 12$MC=9.71E-4 29 -214BI G 462.00 7 0.213 6 -214BI G 487.09 7 0.433 6(E1) 0.0105832 -214BI2 G KC=0.00871 26$LC=1423E-6 43$MC=3.33E-4 10 -214BI G 543.81 7 0.050 9E1+M2 0.0084325 -214BI2 G KC=0.00696 21$LC=1124E-6 34$MC=2.62E-4 8 -214BI G 580.13 3 0.369 6(E1) 0.0074022 -214BI2 G KC=0.00611 18$LC=9.81E-4 29$MC=2.29E-4 7 -214BI G 785.96 9 1.064 13E1 0.0041012 -214BI2 G KC=0.00341 10$LC=5.33E-4 16$MC=1239E-7 37 -214BI G 839.04 9 0.587 8(E1) 0.0036311 -214BI2 G KC=0.00302 9$LC=4.70E-4 14$MC=1092E-7 33 - +214BI 214PB B- DECAY (26.916 M) +214BI H TYP=UPD$AUT=V.CHISTE$CUT=01-DEC-2010$ +214BI2 H TYP=FUL$AUT=V.CHISTE$CUT=28-FEB-2007$ +214BI C References:1931Cu03, 1952Be78, 1953Sa40, 1956Da06, 1957Ni11, 1956Da28, +214BI2C 1964Ew04, 1969Li10, 1969Wa27, 1969Gr33, 1970Mo28, 1975Ha31, 1977Zo01, +214BI3C 1978Ro22, 1981Mo28, 1982Ak03, 1982Fa10, 1983Ol01, 1983Sc13, 1984Pe13, +214BI4C 1988Ak01, 1990Mo**, 1990Mo08, 1991Li11, 1993Di09, 1995El07, 1996Sc06, +214BI5C 1998Mo14, 2000Sa32, 2002De03, 2002MoZP, 2002Ba85, 2003Au03, 2004Mo07, +214BI6C 2007BeZP +214BI T Auger electrons and X ray energies and emission intensities: +214BI T {U Energy (keV)} {U Intensity} {U Line} +214BI T +214BI T 74.8157 6.26 12 XKA2 +214BI T 77.1088 10.47 20 XKA1 +214BI T +214BI T 86.835 |] XKB3 +214BI T 87.344 |] 3.59 9 XKB1 +214BI T 87.862 |] XKB5II +214BI T +214BI T 89.732 |] XKB2 +214BI T 90.074 |] 1.10 4 XKB4 +214BI T 90.421 |] XKO23 +214BI T +214BI T 9.42-16.36 12.42 22 XL (total) +214BI T 9.42 0.311 9 XLL +214BI T 10.45-10.55 5.80 15 XLA +214BI T 11.35 0.0770 21 XLC +214BI T 12.13-13.38 5.18 9 XLB +214BI T 14.31-16.36 1.039 18 XLG +214BI T +214BI T 57.49-63.42 |] KLL AUGER +214BI T 70.02-77.1 |] 0.80 9 KLX AUGER +214BI T 82.45-90.52 |] KXY AUGER +214BI T 5.3-16.4 19.8 3 L AUGER +214PB P 0.0 0+ 26.916 M 44 1019 11 +214BI N 1.0 1.0 1 1.0 +214BI G 107.22 9 0.0068 14 +214BI G 137.45 300.045 18 +214BI G 141.3 6 0.027 14 +214BI G 170.07 6 0.0146 27 +214BI G 216.47 7 0.0100 23 +214BI G 765.96 9 0.053 8 +214BI L 0 1- 19.8 M 1 +214BI B 1019 119.2 7 6.3 1 +214BIS B EAV=337 4 +214BI L 53.2275 21(2)- 0.52 NS 15 +214BI G 53.2275 211.060 7M1+E2 0.03 1 12.88 39 +214BI2 G LC=9.80 29$MC=2.32 7$NC=0.605 18 +214BI3 G OC=0.1331 40 +214BI L 62.7 1 +214BI L 258.87 3 (2)- +214BI G 196.20 5 0.069 9 +214BI G 205.68 9 0.0114 23 +214BI G 258.87 3 0.5318 36M1 0.737 22 +214BI2 G KC=0.601 18$LC=0.1037 31$MC=0.0244 7$NC=0.00638 19 +214BI3 G OC=0.001405 42 +214BI L 295.224 2 1- +214BI B 724 1141.09 39 5.2 1 +214BIS B EAV=227 4 +214BI G 241.997 3 7.268 22M1(+E2) 0.00 15 0.888 27 +214BI2 G KC=0.724 22$LC=0.1250 38$MC=0.0295 9$NC=0.00770 23 +214BI3 G OC=0.00170 5 +214BI G 295.224 2 18.414 36M1+E2 0.30 13 0.482 14 +214BI2 G KC=0.390 12$LC=0.0698 21$MC=0.0165 5$NC=0.00431 13 +214BI3 G OC=0.000946 28 +214BI L 351.932 2 (0,1)- +214BI B 667 1146.52 37 5.1 +214BIS B EAV=207 4 +214BI G 351.932 2 35.60 7M1(+E2) 0.00 35 0.319 10 +214BI2 G KC=0.260 8$LC=0.0445 13$MC=0.01049 31$NC=0.00274 8 +214BI3 G OC=0.000603 18 +214BI L 377.03 4 +214BI G 314.32 7 0.077 6 +214BI G 323.83 4 0.0287 32 +214BI L 533.67 2 (1)- +214BI B 485 111.047 17 6.2 1 +214BIS B EAV=145 4 +214BI G 274.80 5 0.362 10M1+E2 1 0.392 12 +214BI2 G KC=0.295 9$LC=0.0731 22$MC=0.0179 5$NC=0.00467 14 +214BI3 G OC=0.000997 30 +214BI G 480.43 2 0.3371 41M1(+E2) 0 1 0.1384 42 +214BI2 G KC=0.1132 34$LC=0.0192 6$MC=0.00452 14$NC=0.001180 35 +214BI3 G OC=0.000260 8 +214BI G 533.66 2 0.182 6[M1,E2] 0.06 4 +214BI2 G KC=0.05 3$LC=0.010 4$MC=0.0023 9$NC=0.00059 23 +214BI3 G OC=0.00012 5 +214BI L 797.24 9 +214BI B 222 110.0196 27 6.9 +214BIS B EAV=62 3 +214BI G 538.41 8 0.0196 27 +214BI L 839.00 4 1+ +214BI B 180 112.762 22 4.5 +214BIS B EAV=50 3 +214BI G 305.26 3 0.0315 21[E1] 0.0295 9 +214BI2 G KC=0.0241 7$LC=0.00413 12$MC=0.000971 29$NC=0.000251 8 +214BI3 G OC=5.40E-5 16 +214BI G 462.00 7 0.213 6 +214BI G 487.09 7 0.433 6(E1) 0.0105832 +214BI2 G KC=0.00871 26$LC=0.001423 43$MC=0.000333 10$NC=8.62E-5 26 +214BI3 G OC=1.87E-5 6 +214BI G 543.81 7 0.050 9E1+M2 0.0084325 +214BI2 G KC=0.00696 21$LC=0.001124 34$MC=0.000262 8$NC=0.000068 2 +214BI3 G OC=1.479E-5 44 +214BI G 580.13 3 0.369 6(E1) 0.0074022 +214BI2 G KC=0.00611 18$LC=0.000981 29$MC=0.000229 7$NC=5.94E-5 18 +214BI3 G OC=1.291E-5 39 +214BI G 785.96 9 1.064 13E1 0.0041012 +214BI2 G KC=0.00341 10$LC=0.000533 16$MC=1.239E-4 37$NC=3.22E-5 10 +214BI3 G OC=7.02E-6 21 +214BI G 839.04 9 0.587 8(E1) 0.0036311 +214BI2 G KC=0.00302 9$LC=0.000470 14$MC=1.092E-4 33$NC=2.84E-5 9 +214BI3 G OC=6.19E-6 19 + diff --git a/HEN_HOUSE/spectra/lnhb/Pd-109.txt b/HEN_HOUSE/spectra/lnhb/Pd-109.txt index b0a0e69db..22b94e4fb 100644 --- a/HEN_HOUSE/spectra/lnhb/Pd-109.txt +++ b/HEN_HOUSE/spectra/lnhb/Pd-109.txt @@ -1,150 +1,179 @@ -109AG 109PD B- DECAY (13.58 H) -109AG H TYP=Full$AUT=A.L. Nichols$CUT=30-JAN-2009$ -109AG C Evaluation history: Type=Full;Author=A.L. Nichols;Cutoff date=30-JAN-2009 -109AG C References: 1940Al01, 1941He03, 1945Br06, 1945Wi11, 1946Br07, 1947Br05, -109AG2C 1951Wo15, 1953Av25, 1953Nu04, 1954Mo38, 1957Wa05, 1957Ma16, 1957Wa05, -109AG3C 1958Gu09, 1959St28, 1962Br15, 1962Ec02, 1966Mi11, 1967Ab07, 1967Bl08, -109AG4C 1968Be22, 1968Gr02, 1968BaZY, 1969Sc12, 1970Bo22, 1970Ba37, 1970Fo01, -109AG5C 1970Ro14, 1973Co10, 1975El10, 1977Bo04, 1977Gi11, 1978Pr08, 1983Ch42, -109AG6C 1990Ab06, 1996Sc06, 1998ScZM, 1999ScZX, 2000He14, 2002Ba25, 2002Ra45, -109AG7C 2003Au03, 2006Bl02, 2008Ki07 -109AG T Auger electrons and X ray energies and emission intensities: -109AG T {U Energy (keV)} {U Intensity} {U Line} -109AG T -109AG T 21.9906 9.92 23 XKA2 -109AG T 22.16317 18.7 5 XKA1 -109AG T -109AG T 24.9118 |] XKB3 -109AG T 24.9427 |] 5.18 13 XKB1 -109AG T 25.146 |] XKB5II -109AG T -109AG T 25.4567 |] XKB2 -109AG T 25.512 |] 0.90 4 XKB4 -109AG T -109AG T 2.634-3.75 4.92 13 XL (total) -109AG T 2.634 0.101 4 XLL -109AG T 2.978-2.984 2.71 10 XLA -109AG T 2.806 0.0460 12 XLC -109AG T 3.151-3.348 1.91 6 XLB -109AG T 3.52-3.75 0.184 5 XLG -109AG T -109AG T 17.79-18.69 |] KLL AUGER -109AG T 20.945-22.16 |] 7.06 23 KLX AUGER -109AG T 24.079-25.507 |] KXY AUGER -109AG T 1.9-3.8 79.5 5 L AUGER -109PD P 0.0 5/2+ 13.58 H 12 1116.1 20 -109AG N 1.0 1.0 1 1.0 -109AG L 0 1/2- STABLE -109AG L 88.0341 117/2+ 39.7 S 2 -109AG B 1028.1 2099.891 3 6.134 -109AGS B EAV=361.0 8 -109AG G 88.0336 103.66 6E3 26.33 40 -109AG2 G KC=11.41 16$LC=12.06 17$MC=2.47 4 -109AG L 132.74 119/2+ -109AG G 44.7 1 0.00121 15M1+E2 0.533 1 9.00 15 -109AG2 G KC=5.69 9$LC=2.69 5$MC=0.533 10 -109AG L 311.38 8 3/2- -109AG B 804.7 200.0191 22 9.46 1 -109AGS B EAV=270.3 8 -109AG G 311.4 1 0.0314 21M1+E2 0.220 3 0.0201 3 -109AG2 G KC=0.01749 25$LC=0.00213 3$MC=4.05E-4 6 -109AG L 415.21 165/2- -109AG B 700.9 200.0063 2 9.73 -109AGS B EAV=229.7 8 -109AG G 103.8 2 0.00070 11M1+E2 -0.045 0.379 7 -109AG2 G KC=0.329 6$LC=0.0411 7$MC=0.00783 13 -109AG G 327.2 2 0.00013115E1 0.00582 9 -109AG2 G KC=0.00509 8$LC=5.99E-4 9$MC=1133E-7 17 -109AG G 415.2 2 0.0109 6E2 0.0109816 -109AG2 G KC=0.00944 14$LC=1257E-6 18$MC=2.40E-4 4 -109AG L 697.8 4 (5/2)+ -109AG B 418.3 200.00016 7 10.55 -109AGS B EAV=125.9 7 -109AG G 565.1 5 0.00010814(E2) 0.00446 7 -109AG2 G KC=0.00386 6$LC=4.89E-4 7$MC=9.31E-5 14 -109AG G 609.8 4 0.00018 6(M1+E2) -109AG L 701.91 153/2- -109AG B 414.2 200.00460 21 9.08 1 -109AGS B EAV=124.5 7 -109AG G 286.7 3 0.00017616M1+E2 0.199 3 0.0248 4 -109AG2 G KC=0.0216 3$LC=0.00264 4$MC=5.01E-4 8 -109AG G 390.5 2 0.00093 7M1+E2 0.190 3 0.0112416 -109AG2 G KC=0.00980 14$LC=1178E-6 17$MC=2.24E-4 4 -109AG G 701.9 2 0.00347 20M1+E2 0.029 2 0.00273 4 -109AG2 G KC=0.00239 4$LC=2.80E-4 4$MC=5.31E-5 8 -109AG L 707.00 17(3/2)+ -109AG B 409.1 200.00178 12 9.47 -109AGS B EAV=122.8 7 -109AG G 395.6 3 0.00006813(E1) 0.00357 5 -109AG2 G KC=0.00312 5$LC=3.66E-4 6$MC=6.92E-5 10 -109AG G 707.0 2 0.00171 12(E1) 9.21E-413 -109AG2 G KC=8.07E-4 12$LC=9.33E-5 13$MC=1762E-8 25 -109AG L 724.35 10(3/2)+ 3.2 NS 8 -109AG B 391.8 200.0204 9 8.351 -109AGS B EAV=116.8 7 -109AG G 309.1 3 0.00413 23(E1) 0.0067710 -109AG2 G KC=0.00591 9$LC=6.97E-4 10$MC=1317E-7 19 -109AG G 413.0 2 0.0068 7(E1+(M2)) 0.179 4 0.00420 8 -109AG2 G KC=0.00366 7$LC=4.42E-4 8$MC=8.39E-5 16 -109AG G 636.3 1 0.0101 6(E2) 0.00323 5 -109AG2 G KC=0.00281 4$LC=3.50E-4 5$MC=6.65E-5 10 -109AG G 724.4 1 0.00025 3(E1) 8.74E-413 -109AG2 G KC=7.66E-4 11$LC=8.85E-5 13$MC=1672E-8 24 -109AG L 735.29 9 5/2+ -109AG B 380.8 200.0334 15 8.096 -109AGS B EAV=113.1 7 -109AG G 423.9 2 0.00093 7E1(+M2) 0.270 2 0.00502 8 -109AG2 G KC=0.00436 7$LC=5.36E-4 9$MC=1020E-7 16 -109AG G 602.6 2 0.0086 6E2 0.00374 6 -109AG2 G KC=0.00324 5$LC=4.07E-4 6$MC=7.74E-5 11 -109AG G 647.3 1 0.0252 14M1+E2 -109AG L 812.0 5 (3/2)+ -109AG B 304.1 210.00010824 10.3 -109AGS B EAV=87.7 7 -109AG G 114.2 9 0.00006321(M1+E2) -109AG G 500.6 6 0.00004511(E1) 0.00201 3 -109AG2 G KC=1756E-6 25$LC=2.05E-4 3$MC=3.87E-5 6 -109AG L 862.76 205/2- -109AG B 253.3 200.00167 10 8.82 -109AGS B EAV=71.5 6 -109AG G 447.6 4 0.00086 7M1+E2 0.160 4 0.0080012 -109AG2 G KC=0.00698 10$LC=8.33E-4 12$MC=1580E-7 23 -109AG G 551.4 3 0.00065 7M1+E2 0.280 3 0.00482 7 -109AG2 G KC=0.00420 6$LC=5.00E-4 7$MC=9.48E-5 14 -109AG G 862.8 2 0.00014820E2 0.00151 2 -109AG2 G KC=1313E-6 19$LC=1583E-7 23$MC=3.00E-5 5 -109AG L 869.47 115/2+ -109AG B 246.6 200.0194 9 7.72 -109AGS B EAV=69.4 6 -109AG G 134.2 2 0.00111 10M1+E2 0.150 4 0.192 3 -109AG2 G KC=0.1658 25$LC=0.0212 4$MC=0.00404 6 -109AG G 145.1 2 0.00083 7(M1+E2) 0.132 5 0.153 2 -109AG2 G KC=0.1326 20$LC=0.01670 25$MC=0.00318 5 -109AG G 454.3 3 0.00050 4E1 0.00253 4 -109AG2 G KC=0.00222 4$LC=2.59E-4 4$MC=4.90E-5 7 -109AG G 558.1 2 0.00249 17E1(+M2) 0.260 3 0.00238 4 -109AG2 G KC=0.00207 4$LC=2.49E-4 4$MC=4.73E-5 8 -109AG G 736.7 2 0.00181 13E2 0.00221 4 -109AG2 G KC=0.00193 3$LC=2.36E-4 4$MC=4.48E-5 7 -109AG G 781.4 1 0.0123 9M1+E2 -109AG G 869.5 1 0.00005316M2(+E3) 0.00427 6 -109AG2 G KC=0.00372 6$LC=4.53E-4 7$MC=8.62E-5 13 -109AG L 911.0 4 7/2+ -109AG B 205.1 200.00166 17 8.53 -109AGS B EAV=56.7 6 -109AG G 778.3 5 0.00148 17M1+E2 -109AG G 823.0 4 0.00018118M1+E2 -109AG L 912.1 8 7/2- -109AG B 204.0 220.00007414 9.87 1 -109AGS B EAV=56.3 7 -109AG G 496.9 100.00007314M1+E2 0.199 3 0.0062 1 -109AG2 G KC=0.00541 8$LC=6.44E-4 10$MC=1222E-7 18 -109AG L 1098.5 2 5/2, 7/2+ -109AG B 17.6 200.00018 3 6.22 -109AGS B EAV=4.5 5 -109AG G 400.7 6 0.00006323(M1+E2) -109AG G 787.1 3 2.16E-5 18(E1) 7.35E-411 -109AG2 G KC=6.44E-4 9$LC=7.43E-5 11$MC=1403E-8 20 -109AG G 965.8 3 0.00006811 -109AG G 1010.5 2 0.000030 6 - +109AG 109PD B- DECAY (13.58 H) +109AG H TYP=FUL$AUT=A.L.NICHOLS$CUT=30-JAN-2009$ +109AG C References:1940Al01, 1941He03, 1945Br06, 1945Wi11, 1946Br07, 1947Br05, +109AG2C 1951Wo15, 1953Av25, 1953Nu04, 1954Mo38, 1957Wa05, 1957Ma16, 1957Wa05, +109AG3C 1958Gu09, 1959St28, 1962Br15, 1962Ec02, 1966Mi11, 1967Ab07, 1967Bl08, +109AG4C 1968Be22, 1968Gr02, 1968BaZY, 1969Sc12, 1970Bo22, 1970Ba37, 1970Fo01, +109AG5C 1970Ro14, 1973Co10, 1975El10, 1977Bo04, 1977Gi11, 1978Pr08, 1983Ch42, +109AG6C 1990Ab06, 1996Sc06, 1998ScZM, 1999ScZX, 2000He14, 2002Ba25, 2002Ra45, +109AG7C 2003Au03, 2006Bl02, 2008Ki07 +109AG T Auger electrons and X ray energies and emission intensities: +109AG T {U Energy (keV)} {U Intensity} {U Line} +109AG T +109AG T 21.9906 9.92 23 XKA2 +109AG T 22.16317 18.7 5 XKA1 +109AG T +109AG T 24.9118 |] XKB3 +109AG T 24.9427 |] 5.18 13 XKB1 +109AG T 25.146 |] XKB5II +109AG T +109AG T 25.4567 |] XKB2 +109AG T 25.512 |] 0.90 4 XKB4 +109AG T +109AG T 2.634-3.75 4.92 13 XL (total) +109AG T 2.634 0.101 4 XLL +109AG T 2.978-2.984 2.71 10 XLA +109AG T 2.806 0.0460 12 XLC +109AG T 3.151-3.348 1.91 6 XLB +109AG T 3.52-3.75 0.184 5 XLG +109AG T +109AG T 17.79-18.69 |] KLL AUGER +109AG T 20.945-22.16 |] 7.06 23 KLX AUGER +109AG T 24.079-25.507 |] KXY AUGER +109AG T 1.9-3.8 79.5 5 L AUGER +109PD P 0.0 5/2+ 13.58 H 12 1116.1 20 +109AG N 1.0 1.0 1 1.0 +109AG L 0 1/2- STABLE +109AG L 88.0341 117/2+ 39.7 S 2 +109AG B 1028.1 2099.891 3 6.134 +109AGS B EAV=361.0 8 +109AG G 88.0336 103.66 6E3 26.33 40 +109AG2 G KC=11.41 16$LC=12.06 17$MC=2.47 4$NC=0.386 6 +109AG3 G OC=0.001398 20 +109AG L 132.74 119/2+ +109AG G 44.7 1 0.00121 15M1+E2 0.533 1 9.00 15 +109AG2 G KC=5.69 9$LC=2.69 5$MC=0.533 10$NC=0.0844 15 +109AG3 G OC=0.000909 14 +109AG L 311.38 8 3/2- +109AG B 804.7 200.0191 22 9.46 1 +109AGS B EAV=270.3 8 +109AG G 311.4 1 0.0314 21M1+E2 0.220 3 0.0201 3 +109AG2 G KC=0.01749 25$LC=0.00213 3$MC=0.000405 6$NC=0.000070 1 +109AG3 G OC=3.24E-6 5 +109AG L 415.21 165/2- +109AG B 700.9 200.0063 2 9.73 +109AGS B EAV=229.7 8 +109AG G 103.8 2 0.00070 11M1+E2 -0.045 0.379 7 +109AG2 G KC=0.329 6$LC=0.0411 7$MC=0.00783 13$NC=0.001352 22 +109AG3 G OC=6.19E-5 10 +109AG G 327.2 2 0.00013115E1 0.00582 9 +109AG2 G KC=0.00509 8$LC=0.000599 9$MC=1.133E-4 17$NC=1.95E-5 3 +109AG3 G OC=8.81E-7 13 +109AG G 415.2 2 0.0109 6E2 0.0109816 +109AG2 G KC=0.00944 14$LC=0.001257 18$MC=0.000240 4$NC=4.08E-5 6 +109AG3 G OC=1.637E-6 23 +109AG L 697.8 4 (5/2)+ +109AG B 418.3 200.00016 7 10.55 +109AGS B EAV=125.9 7 +109AG G 565.1 5 0.00010814(E2) 0.00446 7 +109AG2 G KC=0.00386 6$LC=0.000489 7$MC=9.31E-5 14$NC=1.596E-5 23 +109AG3 G OC=6.83E-7 10 +109AG G 609.8 4 0.00018 6(M1+E2) +109AG L 701.91 153/2- +109AG B 414.2 200.00460 21 9.08 1 +109AGS B EAV=124.5 7 +109AG G 286.7 3 0.00017616M1+E2 0.199 3 0.0248 4 +109AG2 G KC=0.0216 3$LC=0.00264 4$MC=0.000501 8$NC=8.67E-5 13 +109AG3 G OC=4.01E-6 6 +109AG G 390.5 2 0.00093 7M1+E2 0.190 3 0.0112416 +109AG2 G KC=0.00980 14$LC=0.001178 17$MC=0.000224 4$NC=3.87E-5 6 +109AG3 G OC=1.82E-6 3 +109AG G 701.9 2 0.00347 20M1+E2 0.029 2 0.00273 4 +109AG2 G KC=0.00239 4$LC=0.000280 4$MC=5.31E-5 8$NC=9.23E-6 13 +109AG3 G OC=4.41E-7 7 +109AG L 707.00 17(3/2)+ +109AG B 409.1 200.00178 12 9.47 +109AGS B EAV=122.8 7 +109AG G 395.6 3 0.00006813(E1) 0.00357 5 +109AG2 G KC=0.00312 5$LC=0.000366 6$MC=6.92E-5 10$NC=1.194E-5 17 +109AG3 G OC=5.45E-7 8 +109AG G 707.0 2 0.00171 12(E1) 9.21E-413 +109AG2 G KC=0.000807 12$LC=9.33E-5 13$MC=1.762E-5 25$NC=3.05E-6 5 +109AG3 G OC=1.431E-7 20 +109AG L 724.35 10(3/2)+ 3.2 NS 8 +109AG B 391.8 200.0204 9 8.351 +109AGS B EAV=116.8 7 +109AG G 309.1 3 0.00413 23(E1) 0.0067710 +109AG2 G KC=0.00591 9$LC=0.000697 10$MC=1.317E-4 19$NC=2.27E-5 4 +109AG3 G OC=1.020E-6 15 +109AG G 413.0 2 0.0068 7(E1+(M2)) 0.179 4 0.00420 8 +109AG2 G KC=0.00366 7$LC=0.000442 8$MC=8.39E-5 16$NC=1.45E-5 3 +109AG3 G OC=6.62E-7 12 +109AG G 636.3 1 0.0101 6(E2) 0.00323 5 +109AG2 G KC=0.00281 4$LC=0.000350 5$MC=6.65E-5 10$NC=1.142E-5 16 +109AG3 G OC=4.99E-7 7 +109AG G 724.4 1 0.00025 3(E1) 8.74E-413 +109AG2 G KC=0.000766 11$LC=8.85E-5 13$MC=1.672E-5 24$NC=2.89E-6 4 +109AG3 G OC=1.359E-7 19 +109AG L 735.29 9 5/2+ +109AG B 380.8 200.0334 15 8.096 +109AGS B EAV=113.1 7 +109AG G 423.9 2 0.00093 7E1(+M2) 0.270 2 0.00502 8 +109AG2 G KC=0.00436 7$LC=0.000536 9$MC=1.020E-4 16$NC=1.76E-5 3 +109AG3 G OC=8.06E-7 13 +109AG G 602.6 2 0.0086 6E2 0.00374 6 +109AG2 G KC=0.00324 5$LC=0.000407 6$MC=7.74E-5 11$NC=1.329E-5 19 +109AG3 G OC=5.75E-7 8 +109AG G 647.3 1 0.0252 14M1+E2 +109AG L 812.0 5 (3/2)+ +109AG B 304.1 210.00010824 10.3 +109AGS B EAV=87.7 7 +109AG G 114.2 9 0.00006321(M1+E2) +109AG G 500.6 6 0.00004511(E1) 0.00201 3 +109AG2 G KC=0.001756 25$LC=0.000205 3$MC=3.87E-5 6$NC=6.69E-6 10 +109AG3 G OC=3.09E-7 5 +109AG L 862.76 205/2- +109AG B 253.3 200.00167 10 8.82 +109AGS B EAV=71.5 6 +109AG G 447.6 4 0.00086 7M1+E2 0.160 4 0.0080012 +109AG2 G KC=0.00698 10$LC=0.000833 12$MC=1.580E-4 23$NC=2.74E-5 4 +109AG3 G OC=1.293E-6 19 +109AG G 551.4 3 0.00065 7M1+E2 0.280 3 0.00482 7 +109AG2 G KC=0.00420 6$LC=0.000500 7$MC=9.48E-5 14$NC=1.644E-5 24 +109AG3 G OC=7.76E-7 11 +109AG G 862.8 2 0.00014820E2 0.00151 2 +109AG2 G KC=0.001313 19$LC=1.583E-4 23$MC=3.00E-5 5$NC=5.18E-6 8 +109AG3 G OC=2.35E-7 4 +109AG L 869.47 115/2+ +109AG B 246.6 200.0194 9 7.72 +109AGS B EAV=69.4 6 +109AG G 134.2 2 0.00111 10M1+E2 0.150 4 0.192 3 +109AG2 G KC=0.1658 25$LC=0.0212 4$MC=0.00404 6$NC=0.000695 11 +109AG3 G OC=3.09E-5 5 +109AG G 145.1 2 0.00083 7(M1+E2) 0.132 5 0.153 2 +109AG2 G KC=0.1326 20$LC=0.01670 25$MC=0.00318 5$NC=0.000549 9 +109AG3 G OC=2.47E-5 4 +109AG G 454.3 3 0.00050 4E1 0.00253 4 +109AG2 G KC=0.00222 4$LC=0.000259 4$MC=4.90E-5 7$NC=8.46E-6 12 +109AG3 G OC=3.89E-7 6 +109AG G 558.1 2 0.00249 17E1(+M2) 0.260 3 0.00238 4 +109AG2 G KC=0.00207 4$LC=0.000249 4$MC=4.73E-5 8$NC=8.18E-6 14 +109AG3 G OC=3.79E-7 7 +109AG G 736.7 2 0.00181 13E2 0.00221 4 +109AG2 G KC=0.00193 3$LC=0.000236 4$MC=4.48E-5 7$NC=7.71E-6 11 +109AG3 G OC=3.44E-7 5 +109AG G 781.4 1 0.0123 9M1+E2 +109AG G 869.5 1 0.00005316M2(+E3) 0.00427 6 +109AG2 G KC=0.00372 6$LC=0.000453 7$MC=8.62E-5 13$NC=1.495E-5 21 +109AG3 G OC=7.05E-7 10 +109AG L 911.0 4 7/2+ +109AG B 205.1 200.00166 17 8.53 +109AGS B EAV=56.7 6 +109AG G 778.3 5 0.00148 17M1+E2 +109AG G 823.0 4 0.00018118M1+E2 +109AG L 912.1 8 7/2- +109AG B 204.0 220.00007414 9.87 1 +109AGS B EAV=56.3 7 +109AG G 496.9 100.00007314M1+E2 0.199 3 0.0062 1 +109AG2 G KC=0.00541 8$LC=0.000644 10$MC=1.222E-4 18$NC=2.12E-5 3 +109AG3 G OC=1.001E-6 15 +109AG L 1098.5 2 5/2,7/2+ +109AG B 17.6 200.00018 3 6.22 +109AGS B EAV=4.5 5 +109AG G 400.7 6 0.00006323(M1+E2) +109AG G 787.1 3 2.16E-5 18(E1) 7.35E-411 +109AG2 G KC=0.000644 9$LC=7.43E-5 11$MC=1.403E-5 20$NC=2.43E-6 4 +109AG3 G OC=1.144E-7 16 +109AG G 965.8 3 0.00006811 +109AG G 1010.5 2 0.000030 6 + diff --git a/HEN_HOUSE/spectra/lnhb/Pm-147.txt b/HEN_HOUSE/spectra/lnhb/Pm-147.txt index e38b1f914..7953b0294 100644 --- a/HEN_HOUSE/spectra/lnhb/Pm-147.txt +++ b/HEN_HOUSE/spectra/lnhb/Pm-147.txt @@ -1,61 +1,52 @@ -147SM 147PM B- DECAY (2.6234 Y) -147SM H TYP=Full$AUT=V. Chisté$CUT=30-MAY-2011$ -147SM2 H TYP=update$AUT=V. Chisté$CUT= -- $ -147SM3 H TYP=update$AUT=V. Chisté$CUT= -- $ -147SM4 H TYP=update$AUT=V. Chisté$CUT= -- $ -147SM5 H TYP=update$AUT=V. Chisté$CUT= -- $ -147SM6 H TYP=update$AUT=V. Chisté$CUT= -- $ -147SM7 H TYP=update$AUT=V. Chisté$CUT= -- $ -147SM C Evaluation history: Type=Full;Author=V. Chisté;Cutoff date=30-MAY-2011 -147SM2C Type=update;Author=V. Chisté;Cutoff date= -- -147SM3C Type=update;Author=V. Chisté;Cutoff date= -- -147SM4C Type=update;Author=V. Chisté;Cutoff date= -- -147SM5C Type=update;Author=V. Chisté;Cutoff date= -- -147SM6C Type=update;Author=V. Chisté;Cutoff date= -- -147SM7C Type=update;Author=V. Chisté;Cutoff date= -- -147SM C References: 1934Li03, 1936Ho**, 1946Cu**, 1949Pi**, 1954Be69, 1955Me52, -147SM2C 1956La17, 1956Le55, 1956Sc87, 1957Me47, 1957St05, 1958Be78, 1958An36, -147SM3C 1959Ca12, 1960Ka23, 1960Ka**, 1961Wy01, 1961Wr02, 1961Ma05, 1962Sc09, -147SM4C 1963Ro20, 1962Al19, 1964Do01, 1965Va16, 1965Fl02, 1965Ei04, 1965An07, -147SM5C 1965Wh04, 1966Go26, 1966Av02, 1967Jo07, 1968Re04, 1969Ba33, 1970Mo02, -147SM6C 1970Gu14, 1970Va38, 1971Be53, 1971Mc09, 1973HaXY, 1987Al28, 1989Ad10, -147SM7C 1990Sc08, 1992Ma56, 1996Sc06, 2001Be81, 2003Au03, 2003Ki26, 2008Ki07, -147SM8C 2009Ko15, 2009Ni02 -147SM T Auger electrons and X ray energies and emission intensities: -147SM T {U Energy (keV)} {U Intensity} {U Line} -147SM T -147SM T 39.5229 0.00058316 XKA2 -147SM T 40.1186 0.00105529 XKA1 -147SM T -147SM T 45.289 |] XKB3 -147SM T 45.413 |] 0.00033 1 XKB1 -147SM T 45.731 |] XKB5II -147SM T -147SM T 46.575 |] XKB2 -147SM T 46.705 |] 8.51E-5 30 XKB4 -147SM T 46.813 |] XKO23 -147SM T -147SM T 4.991-7.487 0.000369 8 XL (total) -147SM T 4.991 7.20E-6 24 XLL -147SM T 5.609-5.638 0.000177 6 XLA -147SM T 5.586 2.81E-6 9 XLC -147SM T 6.193-6.656 0.000156 4 XLB -147SM T 6.964-7.487 2.54E-5 7 XLG -147PM P 0.0 7/2+ 2.6234 Y 4 224.1 3 -147SM N 1.0 1.0 1 1.0 -147SM L 0 7/2- 107.9E9 Y 12 -147SM B 224.1 3 99.9945613 7.4 -147SMS B EAV=61.8 1 -147SM L 121.223 125/2- 0.798 NS 17 -147SM B 102.9 3 0.00542 13 10.6 1 -147SMS B EAV=26.9 1 -147SM G 121.223 120.00272 6M1+E2 -0.317 19000 0.994 14 -147SM2 G KC=0.815 12$LC=0.141 4$MC=0.0308 8 -147SM L 197.298 113/2- 1.25 NS 3 -147SM B 26.8 3 4.0E-7 7 12.1 1U -147SMS B EAV=6.9 1 -147SM G 76.073 101.1E-8 2M1+E2 0.655 34 4.53 9 -147SM2 G KC=2.91 5$LC=1.26 7$MC=0.288 15 -147SM G 197.298 113.3E-7 5E2 0.218 3 -147SM2 G KC=0.1565 22$LC=0.0482 7$MC=0.01092 16 - +147SM 147PM B- DECAY (2.6234 Y) +147SM H TYP=FUL$AUT=V.CHISTE$CUT=30-MAY-2011$ +147SM2 H TYP=UPD$AUT=V.CHISTE$CUT=20-MAY-2008$ +147SM C References:1934Li03, 1936Ho**, 1946Cu**, 1949Pi**, 1954Be69, 1955Me52, +147SM2C 1956La17, 1956Le55, 1956Sc87, 1957Me47, 1957St05, 1958Be78, 1958An36, +147SM3C 1959Ca12, 1960Ka23, 1960Ka**, 1961Wy01, 1961Wr02, 1961Ma05, 1962Sc09, +147SM4C 1963Ro20, 1962Al19, 1964Do01, 1965Va16, 1965Fl02, 1965Ei04, 1965An07, +147SM5C 1965Wh04, 1966Go26, 1966Av02, 1967Jo07, 1968Re04, 1969Ba33, 1970Mo02, +147SM6C 1970Gu14, 1970Va38, 1971Be53, 1971Mc09, 1973HaXY, 1987Al28, 1989Ad10, +147SM7C 1990Sc08, 1992Ma56, 1996Sc06, 2001Be81, 2003Au03, 2003Ki26, 2008Ki07, +147SM8C 2009Ko15, 2009Ni02 +147SM T Auger electrons and X ray energies and emission intensities: +147SM T {U Energy (keV)} {U Intensity} {U Line} +147SM T +147SM T 39.5229 0.00058316 XKA2 +147SM T 40.1186 0.00105529 XKA1 +147SM T +147SM T 45.289 |] XKB3 +147SM T 45.413 |] 0.00033 1 XKB1 +147SM T 45.731 |] XKB5II +147SM T +147SM T 46.575 |] XKB2 +147SM T 46.705 |] 8.51E-5 30 XKB4 +147SM T 46.813 |] XKO23 +147SM T +147SM T 4.991-7.487 0.000369 8 XL (total) +147SM T 4.991 7.20E-6 24 XLL +147SM T 5.609-5.638 0.000177 6 XLA +147SM T 5.586 2.81E-6 9 XLC +147SM T 6.193-6.656 0.000156 4 XLB +147SM T 6.964-7.487 2.54E-5 7 XLG +147PM P 0.0 7/2+ 2.6234 Y 4 224.1 3 +147SM N 1.0 1.0 1 1.0 +147SM L 0 7/2- 107.9E9 Y 12 +147SM B 224.1 3 99.9945613 7.4 +147SMS B EAV=61.8 1 +147SM L 121.223 125/2- 0.798 NS 17 +147SM B 102.9 3 0.00542 13 10.6 1 +147SMS B EAV=26.9 1 +147SM G 121.223 120.00272 6M1+E2 -0.317 19000 0.994 14 +147SM2 G KC=0.815 12$LC=0.141 4$MC=0.0308 8$NC=0.00693 17 +147SM3 G OC=0.000999 22 +147SM L 197.298 113/2- 1.25 NS 3 +147SM B 26.8 3 4.0E-7 7 12.1 1U +147SMS B EAV=6.9 1 +147SM G 76.073 101.1E-8 2M1+E2 0.655 34 4.53 9 +147SM2 G KC=2.91 5$LC=1.26 7$MC=0.288 15$NC=0.064 4 +147SM3 G OC=0.0083 4 +147SM G 197.298 113.3E-7 5E2 0.218 3 +147SM2 G KC=0.1565 22$LC=0.0482 7$MC=0.01092 16$NC=0.00241 4 +147SM3 G OC=0.000320 5 + diff --git a/HEN_HOUSE/spectra/lnhb/Pm-148.txt b/HEN_HOUSE/spectra/lnhb/Pm-148.txt index 81e464252..ecb7f23c4 100644 --- a/HEN_HOUSE/spectra/lnhb/Pm-148.txt +++ b/HEN_HOUSE/spectra/lnhb/Pm-148.txt @@ -1,111 +1,130 @@ -148SM 148PM B- DECAY (5.370 D) -148SM H TYP=FULL$AUT=M.A.Kellett$CUT=05-JUN-2013$ -148SM C Evaluation history: Type=FULL;Author=M.A.Kellett;Cutoff date=05-JUN-2013 -148SM C References: 1943Ku**, 1947Pa**, 1948Se40, 1951Fo**, 1952Ki25, 1952Lo01, -148SM2C 1955Fo18, 1955He64, 1955Ma77, 1959Ei31, 1959Bh95, 1960Sc09, 1959Ei31, -148SM3C 1960Sc12, 1961Br41, 1961El02, 1962Gr34, 1962Re03, 1962Sc04, 1963Ew01, -148SM4C 1963Al22, 1963Ba06, 1963Ba31, 1963Ba32, 1963Gr10, 1964Ha17, 1964Ke03, -148SM5C 1965Al16, 1967Cl05, 1968Wy02, 1970Ca09, 1970FoZZ, 1970FoZZ, 1970GrYP, -148SM6C 1971Ca23, 1970Pe22, 1971Sh08, 1971Mo04, 1972AmZX, 1974LoZL, 1974DuZO, -148SM7C 1977Ka14, 1977La19, 1979Dz07, 1984LaZZ, 1988No02, 1989Le01, 1996Sc06, -148SM8C 1996FiZX, 1998ScZM, 1999ScZX, 2000Bh03, 2000Sc47, 2008DuZX, 2008Ki07, -148SM9C 2012Wa38 -148SM T Auger electrons and X ray energies and emission intensities: -148SM T {U Energy (keV)} {U Intensity} {U Line} -148SM T -148SM T 39.5229 0.0581 16 XKA2 -148SM T 40.1186 0.1051 28 XKA1 -148SM T -148SM T 45.289 |] XKB3 -148SM T 45.413 |] 0.0328 10 XKB1 -148SM T 45.731 |] XKB5II -148SM T -148SM T 46.575 |] XKB2 -148SM T 46.705 |] 0.00847 30 XKB4 -148SM T 46.813 |] XKO23 -148SM T -148SM T 4.9909-7.4871 0.0363 8 XL (total) -148SM T 4.9909 0.00070924 XLL -148SM T 5.6088-5.6376 0.0174 6 XLA -148SM T 5.586 0.000277 9 XLC -148SM T 6.1928-6.6557 0.0154 4 XLB -148SM T 6.9644-7.4871 0.00249 6 XLG -148SM T -148SM T 31.19-33.218 |] KLL AUGER -148SM T 37.302-40.097 |] 0.0163 10 KLX AUGER -148SM T 43.39-46.79 |] KXY AUGER -148SM T 3.27-7.69 0.1883 16 L AUGER -148PM P 0.0 1- 5.370 D 15 2471 6 -148SM N 1.0 1.0 1 1.0 -148SM L 0 0+ STABLE -148SM B 2471 6 55.5 7 9.1 1 -148SMS B EAV=977.7 28 -148SM L 550.274 172+ -148SM B 1921 6 9.3 6 9.5 1 -148SMS B EAV=731.6 27 -148SM G 550.270 3022.5 6E2 0.0099814 -148SM2 G KC=0.00825 12$LC=1360E-6 19$MC=2.96E-4 5 -148SM L 1161.537 243- -148SM G 611.260 301.04 4E1+M2 0.026 13 0.00279 5 -148SM2 G KC=0.00239 5$LC=3.15E-4 6$MC=6.70E-5 13 -148SM L 1424.46 4 0+ -148SM B 1047 6 0.236 9 10.1 1 -148SMS B EAV=359.1 25 -148SM G 874.180 300.24 1E2 0.00332 5 -148SM2 G KC=0.00280 4$LC=4.06E-4 6$MC=8.74E-5 13 -148SM L 1454.217 232+ -148SM B 1017 6 0.093 3 10.4 1 -148SMS B EAV=347.1 25 -148SM G 903.940 300.042 2M1+E2 2.32 10 0.00339 6 -148SM2 G KC=0.00287 5$LC=4.06E-4 7$MC=8.72E-5 14 -148SM G 1454.210 300.0511 25E2 1230E-618 -148SM2 G KC=1000E-6 14$LC=1338E-7 19$MC=2.86E-5 4 -148SM L 1465.129 191- -148SM B 1006 6 33.3 6 7.8 -148SMS B EAV=342.7 24 -148SM G 303.590 300.0377 45E2 0.0542 8 -148SM2 G KC=0.0423 6$LC=0.00931 13$MC=0.00207 3 -148SM G 914.850 3012.0 5E1 1221E-617 -148SM2 G KC=1050E-6 15$LC=1354E-7 19$MC=2.88E-5 4 -148SM G 1465.120 3022.2 5E1 7.04E-410 -148SM2 G KC=4.49E-4 7$LC=5.70E-5 8$MC=1208E-8 17 -148SM L 1664.160 212+ -148SM B 807 6 0.018 3 10.8 1 -148SMS B EAV=264.4 23 -148SM G 1113.880 300.0222 23M1+E2 -0.565 21 0.00279 5 -148SM2 G KC=0.00239 4$LC=3.19E-4 5$MC=6.81E-5 10 -148SM G 1664.150 300.0113 11E2 1042E-615 -148SM2 G KC=7.75E-4 11$LC=1024E-7 15$MC=2.18E-5 3 -148SM L 1921.58 200+ -148SM B 549 6 0.0138 14 10.3 1 -148SMS B EAV=169.0 22 -148SM G 1371.30 200.0138 14E2 1347E-619 -148SM2 G KC=1119E-6 16$LC=1507E-7 22$MC=3.22E-5 5 -148SM L 2057.961 222- -148SM B 413 6 1.360 22 7.9 -148SMS B EAV=121.9 21 -148SM G 393.800 300.0155 22E1 0.0075211 -148SM2 G KC=0.00643 9$LC=8.62E-4 12$MC=1.84E-4 3 -148SM G 592.830 300.35 1M1 0.0140420 -148SM2 G KC=0.01198 17$LC=1621E-6 23$MC=3.47E-4 5 -148SM G 896.420 300.98 2M1+E2 1.32 9 0.00386 9 -148SM2 G KC=0.00328 8$LC=4.56E-4 10$MC=9.77E-5 20 -148SM G 1507.680 300.0056 9E1 7.11E-410 -148SM2 G KC=4.28E-4 6$LC=5.42E-5 8$MC=1150E-8 17 -148SM L 2284.405 211- -148SM B 187 6 0.0965 34 7.9 -148SMS B EAV=50.7 18 -148SM G 819.270 300.0133 22M1 0.00635 9 -148SM2 G KC=0.00542 8$LC=7.26E-4 11$MC=1551E-7 22 -148SM G 1734.120 300.0386 11E1 7.77E-411 -148SM2 G KC=3.39E-4 5$LC=4.28E-5 6$MC=9.07E-6 13 -148SM G 2284.390 300.0444 24E1 1027E-615 -148SM2 G KC=2.19E-4 3$LC=2.74E-5 4$MC=5.81E-6 9 -148SM L 2314.01 152+ -148SM B 157 6 0.0091 15 8.7 1 -148SMS B EAV=42.1 18 -148SM G 1152.50 200.0029 13E1+M2 -0.10 9 0.0008615 -148SM2 G KC=0.00073 13$LC=9.5E-5 18$MC=2.0E-5 4 -148SM G 1763.70 200.0062 7M1+E2 2.2 5 0.00104 3 -148SM2 G KC=7.32E-4 22$LC=9.6E-5 3$MC=2.05E-5 6 - +148SM 148PM B- DECAY (5.370 D) +148SM H TYP=FUL$AUT=M.A.KELLETT$CUT=05-JUN-2013$ +148SM C References:1943Ku**, 1947Pa**, 1948Se40, 1951Fo**, 1952Ki25, 1952Lo01, +148SM2C 1955Fo18, 1955He64, 1955Ma77, 1959Ei31, 1959Bh95, 1960Sc09, 1959Ei31, +148SM3C 1960Sc12, 1961Br41, 1961El02, 1962Gr34, 1962Re03, 1962Sc04, 1963Ew01, +148SM4C 1963Al22, 1963Ba06, 1963Ba31, 1963Ba32, 1963Gr10, 1964Ha17, 1964Ke03, +148SM5C 1965Al16, 1967Cl05, 1968Wy02, 1970Ca09, 1970FoZZ, 1970FoZZ, 1970GrYP, +148SM6C 1971Ca23, 1970Pe22, 1971Sh08, 1971Mo04, 1972AmZX, 1974LoZL, 1974DuZO, +148SM7C 1977Ka14, 1977La19, 1979Dz07, 1984LaZZ, 1988No02, 1989Le01, 1996Sc06, +148SM8C 1996FiZX, 1998ScZM, 1999ScZX, 2000Bh03, 2000Sc47, 2008DuZX, 2008Ki07, +148SM9C 2012Wa38 +148SM T Auger electrons and X ray energies and emission intensities: +148SM T {U Energy (keV)} {U Intensity} {U Line} +148SM T +148SM T 39.5229 0.0581 16 XKA2 +148SM T 40.1186 0.1051 28 XKA1 +148SM T +148SM T 45.289 |] XKB3 +148SM T 45.413 |] 0.0328 10 XKB1 +148SM T 45.731 |] XKB5II +148SM T +148SM T 46.575 |] XKB2 +148SM T 46.705 |] 0.00847 30 XKB4 +148SM T 46.813 |] XKO23 +148SM T +148SM T 4.9909-7.4871 0.0363 8 XL (total) +148SM T 4.9909 0.00070924 XLL +148SM T 5.6088-5.6376 0.0174 6 XLA +148SM T 5.586 0.000277 9 XLC +148SM T 6.1928-6.6557 0.0154 4 XLB +148SM T 6.9644-7.4871 0.00249 6 XLG +148SM T +148SM T 31.19-33.218 |] KLL AUGER +148SM T 37.302-40.097 |] 0.0163 10 KLX AUGER +148SM T 43.39-46.79 |] KXY AUGER +148SM T 3.27-7.69 0.1883 16 L AUGER +148PM P 0.0 1- 5.370 D 15 2471 6 +148SM N 1.0 1.0 1 1.0 +148SM L 0 0+ STABLE +148SM B 2471 6 55.5 7 9.1 1 +148SMS B EAV=977.7 28 +148SM L 550.274 172+ +148SM B 1921 6 9.3 6 9.5 1 +148SMS B EAV=731.6 27 +148SM G 550.270 3022.5 6E2 0.0099814 +148SM2 G KC=0.00825 12$LC=0.001360 19$MC=0.000296 5$NC=6.66E-5 10 +148SM3 G OC=9.59E-6 14 +148SM L 1161.537 243- +148SM G 611.260 301.04 4E1+M2 0.026 13 0.00279 5 +148SM2 G KC=0.00239 5$LC=0.000315 6$MC=6.70E-5 13$NC=1.51E-5 3 +148SM3 G OC=2.25E-6 5 +148SM L 1424.46 4 0+ +148SM B 1047 6 0.236 9 10.1 1 +148SMS B EAV=359.1 25 +148SM G 874.180 300.24 1E2 0.00332 5 +148SM2 G KC=0.00280 4$LC=0.000406 6$MC=8.74E-5 13$NC=1.97E-5 3 +148SM3 G OC=2.91E-6 4 +148SM L 1454.217 232+ +148SM B 1017 6 0.093 3 10.4 1 +148SMS B EAV=347.1 25 +148SM G 903.940 300.042 2M1+E2 2.32 10 0.00339 6 +148SM2 G KC=0.00287 5$LC=0.000406 7$MC=8.72E-5 14$NC=1.97E-5 3 +148SM3 G OC=2.92E-6 5 +148SM G 1454.210 300.0511 25E2 1230E-618 +148SM2 G KC=0.001000 14$LC=1.338E-4 19$MC=2.86E-5 4$NC=6.46E-6 9 +148SM3 G OC=9.66E-7 14$IPC=6.03E-5 9 +148SM L 1465.129 191- +148SM B 1006 6 33.3 6 7.8 +148SMS B EAV=342.7 24 +148SM G 303.590 300.0377 45E2 0.0542 8 +148SM2 G KC=0.0423 6$LC=0.00931 13$MC=0.00207 3$NC=0.000462 7 +148SM3 G OC=6.36E-5 9 +148SM G 914.850 3012.0 5E1 1221E-617 +148SM2 G KC=0.001050 15$LC=1.354E-4 19$MC=2.88E-5 4$NC=6.51E-6 10 +148SM3 G OC=9.73E-7 14 +148SM G 1465.120 3022.2 5E1 7.04E-410 +148SM2 G KC=0.000449 7$LC=5.70E-5 8$MC=1.208E-5 17$NC=2.74E-6 4 +148SM3 G OC=4.11E-7 6$IPC=0.000183 3 +148SM L 1664.160 212+ +148SM B 807 6 0.018 3 10.8 1 +148SMS B EAV=264.4 23 +148SM G 1113.880 300.0222 23M1+E2 -0.565 21 0.00279 5 +148SM2 G KC=0.00239 4$LC=0.000319 5$MC=6.81E-5 10$NC=1.544E-5 23 +148SM3 G OC=2.32E-6 4$IPC=5.65E-7 8 +148SM G 1664.150 300.0113 11E2 1042E-615 +148SM2 G KC=0.000775 11$LC=1.024E-4 15$MC=2.18E-5 3$NC=4.94E-6 7 +148SM3 G OC=7.40E-7 11$IPC=1.375E-4 20 +148SM L 1921.58 200+ +148SM B 549 6 0.0138 14 10.3 1 +148SMS B EAV=169.0 22 +148SM G 1371.30 200.0138 14E2 1347E-619 +148SM2 G KC=0.001119 16$LC=1.507E-4 22$MC=3.22E-5 5$NC=7.29E-6 11 +148SM3 G OC=1.088E-6 16$IPC=3.64E-5 6 +148SM L 2057.961 222- +148SM B 413 6 1.360 22 7.9 +148SMS B EAV=121.9 21 +148SM G 393.800 300.0155 22E1 0.0075211 +148SM2 G KC=0.00643 9$LC=0.000862 12$MC=0.000184 3$NC=4.14E-5 6 +148SM3 G OC=6.12E-6 9 +148SM G 592.830 300.35 1M1 0.0140420 +148SM2 G KC=0.01198 17$LC=0.001621 23$MC=0.000347 5$NC=7.86E-5 11 +148SM3 G OC=1.183E-5 17 +148SM G 896.420 300.98 2M1+E2 1.32 9 0.00386 9 +148SM2 G KC=0.00328 8$LC=0.000456 10$MC=9.77E-5 20$NC=2.21E-5 5 +148SM3 G OC=3.29E-6 7 +148SM G 1507.680 300.0056 9E1 7.11E-410 +148SM2 G KC=0.000428 6$LC=5.42E-5 8$MC=1.150E-5 17$NC=2.60E-6 4 +148SM3 G OC=3.91E-7 6$IPC=0.000214 3 +148SM L 2284.405 211- +148SM B 187 6 0.0965 34 7.9 +148SMS B EAV=50.7 18 +148SM G 819.270 300.0133 22M1 0.00635 9 +148SM2 G KC=0.00542 8$LC=0.000726 11$MC=1.551E-4 22$NC=3.52E-5 5 +148SM3 G OC=5.30E-6 8 +148SM G 1734.120 300.0386 11E1 7.77E-411 +148SM2 G KC=0.000339 5$LC=4.28E-5 6$MC=9.07E-6 13$NC=2.05E-6 3 +148SM3 G OC=3.09E-7 5$IPC=0.000383 6 +148SM G 2284.390 300.0444 24E1 1027E-615 +148SM2 G KC=0.000219 3$LC=2.74E-5 4$MC=5.81E-6 9$NC=1.316E-6 19 +148SM3 G OC=1.98E-7 3$IPC=0.000774 11 +148SM L 2314.01 152+ +148SM B 157 6 0.0091 15 8.7 1 +148SMS B EAV=42.1 18 +148SM G 1152.50 200.0029 13E1+M2 -0.10 9 0.0008615 +148SM2 G KC=0.00073 13$LC=0.000095 18$MC=0.000020 4$NC=4.5E-6 9 +148SM3 G OC=6.8E-7 14$IPC=9.8E-6 3 +148SM G 1763.70 200.0062 7M1+E2 2.2 5 0.00104 3 +148SM2 G KC=0.000732 22$LC=0.000096 3$MC=2.05E-5 6$NC=4.64E-6 14 +148SM3 G OC=6.97E-7 21$IPC=0.000183 3 + diff --git a/HEN_HOUSE/spectra/lnhb/Pm-148m.txt b/HEN_HOUSE/spectra/lnhb/Pm-148m.txt index f1f147b74..cd378f3fa 100644 --- a/HEN_HOUSE/spectra/lnhb/Pm-148m.txt +++ b/HEN_HOUSE/spectra/lnhb/Pm-148m.txt @@ -1,143 +1,164 @@ -148PM 148PM IT DECAY (41.29 D) -148PM H TYP=FULL$AUT=M.A.Kellett$CUT=05-JUN-2013$ -148PM C Evaluation history: Type=FULL;Author=M.A.Kellett;Cutoff date=05-JUN-2013 -148PM C References: 1951Fo**, 1952Ki25, 1952Lo01, 1955Ma77, 1955He64, 1955Fo18, -148PM2C 1959Ei31, 1959Bh95, 1960Sc09, 1959Ei31, 1960Sc12, 1961El02, 1961Ha23, -148PM3C 1961Br41, 1962Re03, 1962Sc04, 1962Gr34, 1963Ku09, 1963Ba31, 1963Ba32, -148PM4C 1963Ba06, 1963Ew01, 1963Gr10, 1967Cl05, 1968Wy02, 1970GrYP, 1970FoZZ, -148PM5C 1970Gr09, 1969Gr32, 1970FoZZ, 1971Mo04, 1971Wa05, 1971BaZW, 1974DuZO, -148PM6C 1977La19, 1977Ka14, 1984LaZZ, 1988No02, 1989Le01, 1996FiZX, 1996Sc06, -148PM7C 1998ScZM, 1999ScZX, 2000Bh03, 2000Sc47, 2008DuZX, 2008Ki07, 2012Wa38 -148PM T Auger electrons and X ray energies and emission intensities: -148PM T {U Energy (keV)} {U Intensity} {U Line} -148PM T -148PM T 38.1716 0.96 6 XKA2 -148PM T 38.7251 1.75 11 XKA1 -148PM T -148PM T 43.713 |] XKB3 -148PM T 43.826 |] 0.54 4 XKB1 -148PM T 44.145 |] XKB5II -148PM T -148PM T 44.937 |] XKB2 -148PM T 45.064 |] 0.139 9 XKB4 -148PM T 45.162 |] XKO23 -148PM T -148PM T 4.81-7.1893 1.20 4 XL (total) -148PM T 4.81 0.0223 10 XLL -148PM T 5.4061-5.4325 0.554 22 XLA -148PM T 5.363 0.0107 5 XLC -148PM T 5.9552-6.3985 0.526 20 XLB -148PM T 6.6814-7.1893 0.083 4 XLG -148PM T -148PM T 30.162-32.086 |] KLL AUGER -148PM T 36.035-38.703 |] 0.287 23 KLX AUGER -148PM T 41.88-45.14 |] KXY AUGER -148PM T 3.16-7.38 6.59 10 L AUGER -148PM P 137 3 6- 41.29 D 13 -148PM N 1.786E1 1.786E1 0.056 5 1.786E1 -148PM L 0 1- 5.370 D 15 -148PM L 75.8 2- -148PM G 75.8 1 1.27 20M1 3.4 5 -148PM2 G KC=2.9 4$LC=0.41 6$MC=0.088 11 -148PM L 137.1 306- 41.29 D 13 -148PM G 61.30 5 0.00040 17E4 1.4E4 6 -148PM2 G KC=30 5$LC=1.0E4 4$MC=2.9E3 12 - -148SM 148PM B- DECAY (41.29 D) -148SM H TYP=FULL$AUT=M.A.Kellett$CUT=05-JUN-2013$ -148SM C Evaluation history: Type=FULL;Author=M.A.Kellett;Cutoff date=05-JUN-2013 -148SM C References: 1951Fo**, 1952Ki25, 1952Lo01, 1955Ma77, 1955He64, 1955Fo18, -148SM2C 1959Ei31, 1959Bh95, 1960Sc09, 1959Ei31, 1960Sc12, 1961El02, 1961Ha23, -148SM3C 1961Br41, 1962Re03, 1962Sc04, 1962Gr34, 1963Ku09, 1963Ba31, 1963Ba32, -148SM4C 1963Ba06, 1963Ew01, 1963Gr10, 1967Cl05, 1968Wy02, 1970GrYP, 1970FoZZ, -148SM5C 1970Gr09, 1969Gr32, 1970FoZZ, 1971Mo04, 1971Wa05, 1971BaZW, 1974DuZO, -148SM6C 1977La19, 1977Ka14, 1984LaZZ, 1988No02, 1989Le01, 1996FiZX, 1996Sc06, -148SM7C 1998ScZM, 1999ScZX, 2000Bh03, 2000Sc47, 2008DuZX, 2008Ki07, 2012Wa38 -148SM T Auger electrons and X ray energies and emission intensities: -148SM T {U Energy (keV)} {U Intensity} {U Line} -148SM T -148SM T 39.5229 1.92 11 XKA2 -148SM T 40.1186 3.47 19 XKA1 -148SM T -148SM T 45.289 |] XKB3 -148SM T 45.413 |] 1.09 6 XKB1 -148SM T 45.731 |] XKB5II -148SM T -148SM T 46.575 |] XKB2 -148SM T 46.705 |] 0.280 17 XKB4 -148SM T 46.813 |] XKO23 -148SM T -148SM T 4.9909-7.4871 1.20 4 XL (total) -148SM T 4.9909 0.0234 12 XLL -148SM T 5.6088-5.6376 0.576 27 XLA -148SM T 5.586 0.0091 5 XLC -148SM T 6.1928-6.6557 0.508 19 XLB -148SM T 6.9644-7.4871 0.082 4 XLG -148SM T -148SM T 31.19-33.218 |] KLL AUGER -148SM T 37.302-40.097 |] 0.54 5 KLX AUGER -148SM T 43.39-46.79 |] KXY AUGER -148SM T 3.27-7.69 6.23 10 L AUGER -148PM P 137 3 6- 41.29 D 13 2471 7 -148SM N 1.059E0 1.059E0 0.944 5 1.059E0 -148SM L 0 0+ STABLE -148SM L 550.27 3 2+ -148SM G 550.27 3 93.5 14E2 0.0099814 -148SM2 G KC=0.00825 12$LC=1360E-6 19$MC=2.96E-4 5 -148SM L 1161.53 4 3- -148SM G 611.26 3 5.6 2E1 0.00277 4 -148SM2 G KC=0.00237 4$LC=3.12E-4 5$MC=6.63E-5 10 -148SM L 1180.24 4 4+ -148SM G 629.97 3 87.8 14E2 0.0071 1 -148SM2 G KC=0.00591 9$LC=9.32E-4 13$MC=2.02E-4 3 -148SM L 1594.31 4 5- -148SM B 1014 6 0.93 45 10.29 -148SMS B EAV=345.9 31 -148SM G 414.07 3 18.35 33E1+M2 -0.013 10 0.0067011 -148SM2 G KC=0.00572 9$LC=7.66E-4 13$MC=1.63E-4 3 -148SM G 432.78 3 5.19 13E2 0.0190 3 -148SM2 G KC=0.01544 22$LC=0.00281 4$MC=6.17E-4 9 -148SM L 1733.48 4 4+ -148SM G 553.24 3 0.35 4M1+E2 1.66 20 0.0117 4 -148SM2 G KC=0.0098 4$LC=0.00150 4$MC=3.24E-4 8 -148SM G 571.95 3 0.211 7E1 0.00320 5 -148SM2 G KC=0.00274 4$LC=3.61E-4 5$MC=7.68E-5 11 -148SM L 1894.93 124+ -148SM G 714.70 200.045 5M1+E2 0.0070 18 -148SM2 G KC=0.0060 16$LC=0.00084 18$MC=0.00018 4 -148SM G 1344.60 200.057 5E2 1392E-620 -148SM2 G KC=1162E-6 17$LC=1570E-7 22$MC=3.35E-5 5 -148SM L 1905.94 5 6+ -148SM B 702 6 21.8 7 8.35 -148SMS B EAV=224.7 29 -148SM G 311.63 3 3.77 11E1 0.0133719 -148SM2 G KC=0.01141 16$LC=1546E-6 22$MC=3.30E-4 5 -148SM G 725.70 3 32.3 6E2 0.00506 7 -148SM2 G KC=0.00424 6$LC=6.42E-4 9$MC=1389E-7 20 -148SM L 2095.57 4 6+ -148SM B 513 6 18.1 9 7.96 -148SMS B EAV=156.0 27 -148SM G 189.63 3 1.15 6E2 0.249 4 -148SM2 G KC=0.1769 25$LC=0.0565 8$MC=0.01284 18 -148SM G 362.09 3 0.171 13E2 0.0318 5 -148SM2 G KC=0.0253 4$LC=0.00504 7$MC=1114E-6 16 -148SM G 501.26 3 6.59 11E1+M2 -0.017 14 0.00431 8 -148SM2 G KC=0.00369 7$LC=4.89E-4 9$MC=1042E-7 20 -148SM G 915.33 3 17.9 5E2 0.00300 5 -148SM2 G KC=0.00254 4$LC=3.64E-4 6$MC=7.83E-5 11 -148SM L 2194.05 4 6+ -148SM B 414 6 54.0 9 7.18 -148SMS B EAV=122.3 26 -148SM G 98.48 3 2.92 26M1+E2 0.18 1.79 3 -148SM2 G KC=1.488 21$LC=0.236 4$MC=0.0511 8 -148SM G 288.11 3 12.0 4M1+E2 0.088 21 0.0898 13 -148SM2 G KC=0.0763 11$LC=0.01062 15$MC=0.00228 4 -148SM G 299.10 200.13 4E2 0.0567 8 -148SM2 G KC=0.0442 7$LC=0.00982 14$MC=0.00219 3 -148SM G 460.57 3 0.40 1E2 0.0160123 -148SM2 G KC=0.01306 19$LC=0.00231 4$MC=5.07E-4 7 -148SM G 599.74 3 12.35 22E1+M2 -0.021 11 0.00290 5 -148SM2 G KC=0.00249 4$LC=3.27E-4 6$MC=6.96E-5 12 -148SM G 1013.81 3 19.8 4E2+M3 -0.025 14 0.00243 4 -148SM2 G KC=0.00206 4$LC=2.90E-4 5$MC=6.22E-5 10 - +148PM 148PM IT DECAY (41.29 D) +148PM H TYP=FUL$AUT=M.A.KELLETT$CUT=05-JUN-2013$ +148PM C References:1951Fo**, 1952Ki25, 1952Lo01, 1955Ma77, 1955He64, 1955Fo18, +148PM2C 1959Ei31, 1959Bh95, 1960Sc09, 1959Ei31, 1960Sc12, 1961El02, 1961Ha23, +148PM3C 1961Br41, 1962Re03, 1962Sc04, 1962Gr34, 1963Ku09, 1963Ba31, 1963Ba32, +148PM4C 1963Ba06, 1963Ew01, 1963Gr10, 1967Cl05, 1968Wy02, 1970GrYP, 1970FoZZ, +148PM5C 1970Gr09, 1969Gr32, 1970FoZZ, 1971Mo04, 1971Wa05, 1971BaZW, 1974DuZO, +148PM6C 1977La19, 1977Ka14, 1984LaZZ, 1988No02, 1989Le01, 1996FiZX, 1996Sc06, +148PM7C 1998ScZM, 1999ScZX, 2000Bh03, 2000Sc47, 2008DuZX, 2008Ki07, 2012Wa38 +148PM T Auger electrons and X ray energies and emission intensities: +148PM T {U Energy (keV)} {U Intensity} {U Line} +148PM T +148PM T 38.1716 0.96 6 XKA2 +148PM T 38.7251 1.75 11 XKA1 +148PM T +148PM T 43.713 |] XKB3 +148PM T 43.826 |] 0.54 4 XKB1 +148PM T 44.145 |] XKB5II +148PM T +148PM T 44.937 |] XKB2 +148PM T 45.064 |] 0.139 9 XKB4 +148PM T 45.162 |] XKO23 +148PM T +148PM T 4.81-7.1893 1.20 4 XL (total) +148PM T 4.81 0.0223 10 XLL +148PM T 5.4061-5.4325 0.554 22 XLA +148PM T 5.363 0.0107 5 XLC +148PM T 5.9552-6.3985 0.526 20 XLB +148PM T 6.6814-7.1893 0.083 4 XLG +148PM T +148PM T 30.162-32.086 |] KLL AUGER +148PM T 36.035-38.703 |] 0.287 23 KLX AUGER +148PM T 41.88-45.14 |] KXY AUGER +148PM T 3.16-7.38 6.59 10 L AUGER +148PM P 137 3 6- 41.29 D 13 +148PM N 1.786E1 1.786E1 0.056 5 +148PM L 0 1- 5.370 D 15 +148PM L 75.8 2- +148PM G 75.8 1 1.27 20M1 3.4 5 +148PM2 G KC=2.9 4$LC=0.41 6$MC=0.088 11$NC=0.0198 25 +148PM3 G OC=0.0030 4 +148PM L 137.1 306- 41.29 D 13 +148PM G 61.30 5 0.00040 17E4 1.4E4 6 +148PM2 G KC=30 5$LC=1.0E4 4$MC=2.9E3 12$NC=6E2 3 +148PM3 G OC=70 30 + +148SM 148PM B- DECAY (41.29 D) +148SM H TYP=FUL$AUT=M.A.KELLETT$CUT=05-JUN-2013$ +148SM C References:1951Fo**, 1952Ki25, 1952Lo01, 1955Ma77, 1955He64, 1955Fo18, +148SM2C 1959Ei31, 1959Bh95, 1960Sc09, 1959Ei31, 1960Sc12, 1961El02, 1961Ha23, +148SM3C 1961Br41, 1962Re03, 1962Sc04, 1962Gr34, 1963Ku09, 1963Ba31, 1963Ba32, +148SM4C 1963Ba06, 1963Ew01, 1963Gr10, 1967Cl05, 1968Wy02, 1970GrYP, 1970FoZZ, +148SM5C 1970Gr09, 1969Gr32, 1970FoZZ, 1971Mo04, 1971Wa05, 1971BaZW, 1974DuZO, +148SM6C 1977La19, 1977Ka14, 1984LaZZ, 1988No02, 1989Le01, 1996FiZX, 1996Sc06, +148SM7C 1998ScZM, 1999ScZX, 2000Bh03, 2000Sc47, 2008DuZX, 2008Ki07, 2012Wa38 +148SM T Auger electrons and X ray energies and emission intensities: +148SM T {U Energy (keV)} {U Intensity} {U Line} +148SM T +148SM T 39.5229 1.92 11 XKA2 +148SM T 40.1186 3.47 19 XKA1 +148SM T +148SM T 45.289 |] XKB3 +148SM T 45.413 |] 1.09 6 XKB1 +148SM T 45.731 |] XKB5II +148SM T +148SM T 46.575 |] XKB2 +148SM T 46.705 |] 0.280 17 XKB4 +148SM T 46.813 |] XKO23 +148SM T +148SM T 4.9909-7.4871 1.20 4 XL (total) +148SM T 4.9909 0.0234 12 XLL +148SM T 5.6088-5.6376 0.576 27 XLA +148SM T 5.586 0.0091 5 XLC +148SM T 6.1928-6.6557 0.508 19 XLB +148SM T 6.9644-7.4871 0.082 4 XLG +148SM T +148SM T 31.19-33.218 |] KLL AUGER +148SM T 37.302-40.097 |] 0.54 5 KLX AUGER +148SM T 43.39-46.79 |] KXY AUGER +148SM T 3.27-7.69 6.23 10 L AUGER +148PM P 137 3 6- 41.29 D 13 2471 7 +148SM N 1.059E0 1.059E0 0.944 51.059E0 +148SM L 0 0+ STABLE +148SM L 550.27 3 2+ +148SM G 550.27 3 93.5 14E2 0.0099814 +148SM2 G KC=0.00825 12$LC=0.001360 19$MC=0.000296 5$NC=6.66E-5 10 +148SM3 G OC=9.59E-6 14 +148SM L 1161.53 4 3- +148SM G 611.26 3 5.6 2E1 0.00277 4 +148SM2 G KC=0.00237 4$LC=0.000312 5$MC=6.63E-5 10$NC=1.499E-5 21 +148SM3 G OC=2.23E-6 4 +148SM L 1180.24 4 4+ +148SM G 629.97 3 87.8 14E2 0.0071 1 +148SM2 G KC=0.00591 9$LC=0.000932 13$MC=0.000202 3$NC=4.55E-5 7 +148SM3 G OC=6.61E-6 10 +148SM L 1594.31 4 5- +148SM B 1014 6 0.93 45 10.29 +148SMS B EAV=345.9 31 +148SM G 414.07 3 18.35 33E1+M2 -0.013 10 0.0067011 +148SM2 G KC=0.00572 9$LC=0.000766 13$MC=0.000163 3$NC=3.68E-5 6 +148SM3 G OC=5.44E-6 9 +148SM G 432.78 3 5.19 13E2 0.0190 3 +148SM2 G KC=0.01544 22$LC=0.00281 4$MC=0.000617 9$NC=1.382E-4 20 +148SM3 G OC=1.96E-5 3 +148SM L 1733.48 4 4+ +148SM G 553.24 3 0.35 4M1+E2 1.66 20 0.0117 4 +148SM2 G KC=0.0098 4$LC=0.00150 4$MC=0.000324 8$NC=7.30E-5 18 +148SM3 G OC=1.07E-5 3 +148SM G 571.95 3 0.211 7E1 0.00320 5 +148SM2 G KC=0.00274 4$LC=0.000361 5$MC=7.68E-5 11$NC=1.735E-5 25 +148SM3 G OC=2.58E-6 4 +148SM L 1894.93 124+ +148SM G 714.70 200.045 5M1+E2 0.0070 18 +148SM2 G KC=0.0060 16$LC=0.00084 18$MC=0.00018 4$NC=0.000041 9 +148SM3 G OC=6.1E-6 14 +148SM G 1344.60 200.057 5E2 1392E-620 +148SM2 G KC=0.001162 17$LC=1.570E-4 22$MC=3.35E-5 5$NC=7.59E-6 11 +148SM3 G OC=1.133E-6 16 +148SM L 1905.94 5 6+ +148SM B 702 6 21.8 7 8.35 +148SMS B EAV=224.7 29 +148SM G 311.63 3 3.77 11E1 0.0133719 +148SM2 G KC=0.01141 16$LC=0.001546 22$MC=0.000330 5$NC=7.43E-5 11 +148SM3 G OC=1.091E-5 16 +148SM G 725.70 3 32.3 6E2 0.00506 7 +148SM2 G KC=0.00424 6$LC=0.000642 9$MC=1.389E-4 20$NC=3.13E-5 5 +148SM3 G OC=4.58E-6 7 +148SM L 2095.57 4 6+ +148SM B 513 6 18.1 9 7.96 +148SMS B EAV=156.0 27 +148SM G 189.63 3 1.15 6E2 0.249 4 +148SM2 G KC=0.1769 25$LC=0.0565 8$MC=0.01284 18$NC=0.00284 4 +148SM3 G OC=0.000375 6 +148SM G 362.09 3 0.171 13E2 0.0318 5 +148SM2 G KC=0.0253 4$LC=0.00504 7$MC=0.001114 16$NC=0.000249 4 +148SM3 G OC=3.48E-5 5 +148SM G 501.26 3 6.59 11E1+M2 -0.017 14 0.00431 8 +148SM2 G KC=0.00369 7$LC=0.000489 9$MC=1.042E-4 20$NC=2.35E-5 5 +148SM3 G OC=3.49E-6 7 +148SM G 915.33 3 17.9 5E2 0.00300 5 +148SM2 G KC=0.00254 4$LC=0.000364 6$MC=7.83E-5 11$NC=1.769E-5 25 +148SM3 G OC=2.61E-6 4 +148SM L 2194.05 4 6+ +148SM B 414 6 54.0 9 7.18 +148SMS B EAV=122.3 26 +148SM G 98.48 3 2.92 26M1+E2 0.18 1.79 3 +148SM2 G KC=1.488 21$LC=0.236 4$MC=0.0511 8$NC=0.01154 17 +148SM3 G OC=0.001692 24 +148SM G 288.11 3 12.0 4M1+E2 0.088 21 0.0898 13 +148SM2 G KC=0.0763 11$LC=0.01062 15$MC=0.00228 4$NC=0.000516 8 +148SM3 G OC=7.75E-5 11 +148SM G 299.10 200.13 4E2 0.0567 8 +148SM2 G KC=0.0442 7$LC=0.00982 14$MC=0.00219 3$NC=0.000487 7 +148SM3 G OC=0.000067 1 +148SM G 460.57 3 0.40 1E2 0.0160123 +148SM2 G KC=0.01306 19$LC=0.00231 4$MC=0.000507 7$NC=1.136E-4 16 +148SM3 G OC=1.617E-5 23 +148SM G 599.74 3 12.35 22E1+M2 -0.021 11 0.00290 5 +148SM2 G KC=0.00249 4$LC=0.000327 6$MC=6.96E-5 12$NC=1.57E-5 3 +148SM3 G OC=2.34E-6 4 +148SM G 1013.81 3 19.8 4E2+M3 -0.025 14 0.00243 4 +148SM2 G KC=0.00206 4$LC=0.000290 5$MC=6.22E-5 10$NC=1.404E-5 22 +148SM3 G OC=2.08E-6 4 + diff --git a/HEN_HOUSE/spectra/lnhb/Po-209.txt b/HEN_HOUSE/spectra/lnhb/Po-209.txt index 0303dc125..222030bae 100644 --- a/HEN_HOUSE/spectra/lnhb/Po-209.txt +++ b/HEN_HOUSE/spectra/lnhb/Po-209.txt @@ -1,83 +1,84 @@ -209BI 209PO EC DECAY (115 Y) -209BI H TYP=Full$AUT=V. Chisté$CUT=30-SEP-2009$ -209BI C Evaluation history: Type=Full;Author=V. Chisté;Cutoff date=30-SEP-2009 -209BI C References: 1956An05, 1966Ha29, 1971Jo06, 1980Sc26, 1989Ma05, 1991Ma16, -209BI2C 1996Sc24, 1996Sc06, 2003Au03, 2004Ko28, 2007Co07, 2008Ki07 -209BI T Auger electrons and X ray energies and emission intensities: -209BI T {U Energy (keV)} {U Intensity} {U Line} -209BI T -209BI T 74.8157 0.0927 16 XKA2 -209BI T 77.1088 0.1551 25 XKA1 -209BI T -209BI T 86.835 |] XKB3 -209BI T 87.344 |] 0.0531 12 XKB1 -209BI T 87.862 |] XKB5II -209BI T -209BI T 89.732 |] XKB2 -209BI T 90.074 |] 0.0163 5 XKB4 -209BI T 90.421 |] XKO23 -209BI T -209BI T 9.4207-15.7084 0.1411 24 XL (total) -209BI T 9.4207 0.00357 10 XLL -209BI T 10.7308-10.8387 0.0667 16 XLA -209BI T 11.7127 0.00097527 XLC -209BI T 12.4814-13.8066 0.0585 11 XLB -209BI T 14.7735-15.7084 0.01130 22 XLG -209BI T -209BI T 57.491-63.419 |] KLL AUGER -209BI T 70.025-77.105 |] 0.0118 14 KLX AUGER -209BI T 82.53-90.52 |] KXY AUGER -209BI T 5.42-16.34 0.2240 27 L AUGER -209PO P 0.0 1/2- 115 Y 13 1892.5 16 -209BI N 2.203E2 2.203E2 0.00454 2.203E2 -209BI L 0 9/2- 19E18 Y 2 -209BI L 896.29 5 7/2- 9.7 PS 11 -209BI E 0.454 714.36 2U -209BI2 E CK=0.70796 22$CL=0.21518 16$CM=0.07686 7$CO=0 0 -209BI G 896.28 6 0.445 7M1+E2 -0.62 4 0.0208 6 -209BI2 G KC=0.0170 5$LC=0.00292 7$MC=6.87E-4 16 - -205PB 209PO A DECAY (115 Y) -205PB H TYP=Full$AUT=V. Chisté$CUT=30-SEP-2009$ -205PB C Evaluation history: Type=Full;Author=V. Chisté;Cutoff date=30-SEP-2009 -205PB C References: 1956An05, 1966Ha29, 1971Jo06, 1980Sc26, 1989Ma05, 1991Ma16, -205PB2C 1996Sc24, 1996Sc06, 2003Au03, 2004Ko28, 2007Co07, 2008Ki07 -205PB T Auger electrons and X ray energies and emission intensities: -205PB T {U Energy (keV)} {U Intensity} {U Line} -205PB T -205PB T 72.8049 0.0478 11 XKA2 -205PB T 74.97 0.0804 18 XKA1 -205PB T -205PB T 84.451 |] XKB3 -205PB T 84.937 |] 0.0275 8 XKB1 -205PB T 85.47 |] XKB5II -205PB T -205PB T 87.238 |] XKB2 -205PB T 87.58 |] 0.00830 26 XKB4 -205PB T 87.911 |] XKO23 -205PB T -205PB T 9.186-15.2169 0.0631 13 XL (total) -205PB T 9.186 0.00156 5 XLL -205PB T 10.4495-10.5512 0.0296 8 XLA -205PB T 11.3495 0.00047315 XLC -205PB T 12.1443-12.7953 0.0264 6 XLB -205PB T 14.3078-15.2169 0.00501 12 XLG -205PB T -205PB T 56.028-61.669 |] KLL AUGER -205PB T 68.181-74.969 |] 0.0063 7 KLX AUGER -205PB T 80.3-88 |] KXY AUGER -205PB T 5.33-15.82 0.1044 14 L AUGER -209PO P 0.0 1/2- 115 Y 13 4979.2 14 -205PB N 1.005E0 1.005E0 0.99546 1.005E0 -205PB L 0 5/2- 17.3E6 Y 7 -205PB A 4885 2 19.9 326 -205PB L 2.329 7 1/2- 24.2 US 4 -205PB A 4883 2 79.6 321.3 -205PB G 2.328 7 -205PB L 262.833 253/2- -205PB A 4622 5 0.550 7 4.5 -205PB G 260.50 5 0.254 3M1+E2 0.16 6 0.617 13 -205PB2 G KC=0.503 12$LC=0.0874 14$MC=0.0205 3 -205PB G 262.80 5 0.085 2M1+E2 0.05 7 0.612 10 -205PB2 G KC=0.500 9$LC=0.0857 13$MC=0.0201 3 - +209BI 209PO EC DECAY (115 Y) +209BI H TYP=FUL$AUT=V.CHISTE$CUT=30-SEP-2009$ +209BI C References:1956An05, 1966Ha29, 1971Jo06, 1980Sc26, 1989Ma05, 1991Ma16, +209BI2C 1996Sc24, 1996Sc06, 2003Au03, 2004Ko28, 2007Co07, 2008Ki07 +209BI T Auger electrons and X ray energies and emission intensities: +209BI T {U Energy (keV)} {U Intensity} {U Line} +209BI T +209BI T 74.8157 0.0927 16 XKA2 +209BI T 77.1088 0.1551 25 XKA1 +209BI T +209BI T 86.835 |] XKB3 +209BI T 87.344 |] 0.0531 12 XKB1 +209BI T 87.862 |] XKB5II +209BI T +209BI T 89.732 |] XKB2 +209BI T 90.074 |] 0.0163 5 XKB4 +209BI T 90.421 |] XKO23 +209BI T +209BI T 9.4207-15.7084 0.1411 24 XL (total) +209BI T 9.4207 0.00357 10 XLL +209BI T 10.7308-10.8387 0.0667 16 XLA +209BI T 11.7127 0.00097527 XLC +209BI T 12.4814-13.8066 0.0585 11 XLB +209BI T 14.7735-15.7084 0.01130 22 XLG +209BI T +209BI T 57.491-63.419 |] KLL AUGER +209BI T 70.025-77.105 |] 0.0118 14 KLX AUGER +209BI T 82.53-90.52 |] KXY AUGER +209BI T 5.42-16.34 0.2240 27 L AUGER +209PO P 0.0 1/2- 115 Y 13 1892.5 16 +209BI N 2.203E2 2.203E2 0.00454 2.203E2 +209BI L 0 9/2- 19E18 Y 2 +209BI L 896.29 5 7/2- 9.7 PS 11 +209BI E 0.454 714.36 2U +209BI2 E CK=0.70796 22$CL=0.21518 16$CM=0.07686 7 +209BI G 896.28 6 0.445 7M1+E2 -0.62 4 0.0208 6 +209BI2 G KC=0.0170 5$LC=0.00292 7$MC=0.000687 16$NC=0.000175 4 +209BI3 G OC=3.58E-5 9 + +205PB 209PO A DECAY (115 Y) +205PB H TYP=FUL$AUT=V.CHISTE$CUT=30-SEP-2009$ +205PB C References:1956An05, 1966Ha29, 1971Jo06, 1980Sc26, 1989Ma05, 1991Ma16, +205PB2C 1996Sc24, 1996Sc06, 2003Au03, 2004Ko28, 2007Co07, 2008Ki07 +205PB T Auger electrons and X ray energies and emission intensities: +205PB T {U Energy (keV)} {U Intensity} {U Line} +205PB T +205PB T 72.8049 0.0478 11 XKA2 +205PB T 74.97 0.0804 18 XKA1 +205PB T +205PB T 84.451 |] XKB3 +205PB T 84.937 |] 0.0275 8 XKB1 +205PB T 85.47 |] XKB5II +205PB T +205PB T 87.238 |] XKB2 +205PB T 87.58 |] 0.00830 26 XKB4 +205PB T 87.911 |] XKO23 +205PB T +205PB T 9.186-15.2169 0.0631 13 XL (total) +205PB T 9.186 0.00156 5 XLL +205PB T 10.4495-10.5512 0.0296 8 XLA +205PB T 11.3495 0.00047315 XLC +205PB T 12.1443-12.7953 0.0264 6 XLB +205PB T 14.3078-15.2169 0.00501 12 XLG +205PB T +205PB T 56.028-61.669 |] KLL AUGER +205PB T 68.181-74.969 |] 0.0063 7 KLX AUGER +205PB T 80.3-88 |] KXY AUGER +205PB T 5.33-15.82 0.1044 14 L AUGER +209PO P 0.0 1/2- 115 Y 13 4979.2 14 +205PB N 1.005E0 1.005E0 0.99546 +205PB L 0 5/2- 17.3E6 Y 7 +205PB A 4885 2 19.9 326 +205PB L 2.329 7 1/2- 24.2 US 4 +205PB A 4883 2 79.6 321.3 +205PB G 2.328 7 +205PB L 262.833 253/2- +205PB A 4622 5 0.550 74.5 +205PB G 260.50 5 0.254 3M1+E2 0.16 6 0.617 13 +205PB2 G KC=0.503 12$LC=0.0874 14$MC=0.0205 3$NC=0.00521 8 +205PB3 G OC=0.001037 16 +205PB G 262.80 5 0.085 2M1+E2 0.05 7 0.612 10 +205PB2 G KC=0.500 9$LC=0.0857 13$MC=0.0201 3$NC=0.00510 8 +205PB3 G OC=0.001017 15 + diff --git a/HEN_HOUSE/spectra/lnhb/Po-210.txt b/HEN_HOUSE/spectra/lnhb/Po-210.txt index 54746d775..ac6a694a5 100644 --- a/HEN_HOUSE/spectra/lnhb/Po-210.txt +++ b/HEN_HOUSE/spectra/lnhb/Po-210.txt @@ -1,46 +1,46 @@ -206PB 210PO A DECAY (138.3763 D) -206PB H TYP=Update$AUT=M.A.Kellett$CUT=31-MAR-2014$ -206PB2 H TYP=Full$AUT=V.Chisté$CUT=28-FEB-2008$ -206PB C Evaluation history: Type=Update;Author=M.A.Kellett;Cutoff date=31-MAR-2014 -206PB2C Type=Full;Author=V.Chisté;Cutoff date=28-FEB-2008 -206PB C References: 1927Da**, 1931CU01, 1933Ro03, 1934Le01, 1949Be54, 1951Gr15, -206PB2C 1952De08, 1952Ri14, 1952Ba20, 1952Ba20, 1953Cu46, 1953Gi10, 1953Co64, -206PB3C 1954Ei20, 1954Br07, 1954AL31, 1955Ro30, 1955Ha09, 1956As46, 1956Sh24, -206PB4C 1957Ag15, 1958Wh09, 1957Ag15, 1958Wh09, 1958Ba45, 1960Br20, 1961Ry05, -206PB5C 1961Be13, 1962Br22, 1964EiZZ, 1972KA30, 1972MA63, 1973Go39, 1977DR08, -206PB6C 1989MA05, 1990He18, 1991Ry01, 1996RA16, 1996Sc06, 1999Br39, 2002Ba85, -206PB7C 2003Au03, 2008KI07, 2008Ko21, 2012Wa38 -206PB T Auger electrons and X ray energies and emission intensities: -206PB T {U Energy (keV)} {U Intensity} {U Line} -206PB T -206PB T 72.805 2.77E-6 11 XKA2 -206PB T 74.97 4.66E-6 17 XKA1 -206PB T -206PB T 84.451 |] XKB3 -206PB T 84.937 |] 1.59E-6 7 XKB1 -206PB T 85.47 |] XKB5II -206PB T -206PB T 87.238 |] XKB2 -206PB T 87.58 |] 4.81E-7 21 XKB4 -206PB T 87.911 |] XKO23 -206PB T -206PB T 9.186-15.217 3.84E-6 10 XL (total) -206PB T 9.186 9.3E-8 4 XLL -206PB T 10.449-10.551 1.75E-6 6 XLA -206PB T 11.349 3.06E-8 12 XLC -206PB T 12.144-13.377 1.65E-6 5 XLB -206PB T 14.308-15.217 3.18E-7 10 XLG -206PB T -206PB T 56.028-61.669 |] KLL AUGER -206PB T 68.181-74.969 |] 3.7E-7 5 KLX AUGER -206PB T 80.3-88 |] KXY AUGER -206PB T 5.3338-15.8198 6.31E-6 11 L AUGER -210PO P 0.0 0+ 138.3763 D17 5407.45 7 -206PB N 1.0 1.0 1 1.0 -206PB L 0 0+ STABLE -206PB A 5304.33 7 99999E-34 1 -206PB L 803.052 242+ 8.30 PS 25 -206PB A 4516.70 9 0.00124 4 1.46 -206PB G 803.052 240.00123 4E2 0.0103215 -206PB2 G KC=0.00803 12$LC=1742E-6 25$MC=4.19E-4 6 - +206PB 210PO A DECAY (138.3763 D) +206PB H TYP=UPD$AUT=M.A.KELLETT$CUT=31-MAR-2014$ +206PB2 H TYP=FUL$AUT=V.CHISTE$CUT=28-FEB-2008$ +206PB C References:1912Sc**, 1920Cu**, 1927Da**, 1931Do**, 1931CU01, 1933Ro03, +206PB2C 1934Le01, 1936Sa**, 1949Be54, 1951Gr15, 1952De08, 1952Ri14, 1952Ba20, +206PB3C 1952Ba20, 1953Cu46, 1953Gi10, 1953Co64, 1954Ei20, 1954Br07, 1954AL31, +206PB4C 1955Ro30, 1955Ha09, 1956As46, 1956Sh24, 1957Ag15, 1958Wh09, 1957Ag15, +206PB5C 1958Wh09, 1958Ba45, 1960Br20, 1961Ry05, 1961Be13, 1962Br22, 1964EiZZ, +206PB6C 1972KA30, 1972MA63, 1973Go39, 1977DR08, 1989MA05, 1990He18, 1991Ry01, +206PB7C 1996RA16, 1996Sc06, 1999Br39, 2002Ba85, 2003Au03, 2008Ki07, 2008Ko21, +206PB8C 2012Wa38 +206PB T Auger electrons and X ray energies and emission intensities: +206PB T {U Energy (keV)} {U Intensity} {U Line} +206PB T +206PB T 72.805 2.77E-6 11 XKA2 +206PB T 74.97 4.66E-6 17 XKA1 +206PB T +206PB T 84.451 |] XKB3 +206PB T 84.937 |] 1.59E-6 7 XKB1 +206PB T 85.47 |] XKB5II +206PB T +206PB T 87.238 |] XKB2 +206PB T 87.58 |] 4.81E-7 21 XKB4 +206PB T 87.911 |] XKO23 +206PB T +206PB T 9.186-15.217 3.84E-6 10 XL (total) +206PB T 9.186 9.3E-8 4 XLL +206PB T 10.449-10.551 1.75E-6 6 XLA +206PB T 11.349 3.06E-8 12 XLC +206PB T 12.144-13.377 1.65E-6 5 XLB +206PB T 14.308-15.217 3.18E-7 10 XLG +206PB T +206PB T 56.028-61.669 |] KLL AUGER +206PB T 68.181-74.969 |] 3.7E-7 5 KLX AUGER +206PB T 80.3-88 |] KXY AUGER +206PB T 5.3338-15.8198 6.31E-6 11 L AUGER +210PO P 0.0 0+ 138.3763 D17 5407.45 7 +206PB N 1.0 1.0 1 +206PB L 0 0+ STABLE +206PB A 5304.33 7 99.99876 41 +206PB L 803.052 242+ 8.30 PS 25 +206PB A 4516.70 9 0.00124 41.46 +206PB G 803.052 240.00123 4E2 0.0103215 +206PB2 G KC=0.00803 12$LC=0.001742 25$MC=0.000419 6$NC=1.063E-4 15 +206PB3 G OC=2.06E-5 3 + diff --git a/HEN_HOUSE/spectra/lnhb/Po-211.txt b/HEN_HOUSE/spectra/lnhb/Po-211.txt index fed40a242..7b65715c1 100644 --- a/HEN_HOUSE/spectra/lnhb/Po-211.txt +++ b/HEN_HOUSE/spectra/lnhb/Po-211.txt @@ -1,49 +1,50 @@ -207PB 211PO A DECAY (0.516 S) -207PB H TYP=Full$AUT=A. Luca$CUT=31-DEC-2008$ -207PB2 H TYP=Full$AUT=mmbe$CUT= -- $ -207PB C Evaluation history: Type=Full;Author=A. Luca;Cutoff date=31-DEC-2008 -207PB2C Type=Full;Author=mmbe;Cutoff date= -- -207PB C References: 1931Cu01, 1951Ne02, 1953AsZZ, 1953Ho49, 1954Br07, 1954Mi70, -207PB2C 1954Sp32, 1954Wi26, 1958To25, 1962Wa18, 1963Jo09, 1968GuZX, 1968Br17, -207PB3C 1969Go23, 1969Ha32, 1970Va13, 1974Ba29, 1975Ja04, 1978Ya04, 1982Bo04, -207PB4C 1985La17, 1991Ry01, 1996Sc06, 2003Au03, 2008Ki07 -207PB T Auger electrons and X ray energies and emission intensities: -207PB T {U Energy (keV)} {U Intensity} {U Line} -207PB T -207PB T 72.8049 0.00535 14 XKA2 -207PB T 74.97 0.00900 24 XKA1 -207PB T -207PB T 84.451 |] XKB3 -207PB T 84.937 |] 0.00308 10 XKB1 -207PB T 85.47 |] XKB5II -207PB T -207PB T 87.238 |] XKB2 -207PB T 87.58 |] 0.00093 4 XKB4 -207PB T 87.911 |] XKO23 -207PB T -207PB T 9.186-15.2169 0.00740 16 XL (total) -207PB T 9.186 0.000179 6 XLL -207PB T 10.4495-10.5512 0.00339 10 XLA -207PB T 11.3495 5.83E-5 19 XLC -207PB T 12.1443-13.3763 0.00317 8 XLB -207PB T 14.3078-15.2169 0.00060815 XLG -207PB T -207PB T 56.028-61.669 |] KLL AUGER -207PB T 68.181-74.969 |] 0.00071 8 KLX AUGER -207PB T 80.3-88 |] KXY AUGER -207PB T 5.33-15.82 0.01216 17 L AUGER -211PO P 0.0 9/2+ 0.516 S 3 7594.5 5 -207PB N 1.0 1.0 1 1.0 -207PB L 0 1/2- STABLE -207PB A 7450.2 3 98.936 19112 -207PB L 569.65 105/2- -207PB A 6891.2 100.541 17272 -207PB G 569.65 150.534 17E2 0.0216 3 -207PB2 G KC=0.01583 23$LC=0.00439 7$MC=1081E-6 16 -207PB L 897.8 1 3/2- -207PB A 6568.4 100.523 9 17.9 -207PB G 328.2 2 0.0032 11M1 0.334 5 -207PB2 G KC=0.273 4$LC=0.0465 7$MC=0.01089 16 -207PB G 897.8 2 0.507 9M1+E2 0.092 10 0.0233 4 -207PB2 G KC=0.0192 3$LC=0.00318 5$MC=7.41E-4 11 - +207PB 211PO A DECAY (0.516 S) +207PB H TYP=FUL$AUT=A.LUCA$CUT=31-DEC-2008$ +207PB2 H TYP=FUL$AUT=M.-M.BE$CUT=27-FEB-2007$ +207PB C References:1931Cu01, 1951Ne02, 1953AsZZ, 1953Ho49, 1954Br07, 1954Mi70, +207PB2C 1954Sp32, 1954Wi26, 1958To25, 1962Wa18, 1963Jo09, 1968GuZX, 1968Br17, +207PB3C 1969Go23, 1969Ha32, 1970Va13, 1974Ba29, 1975Ja04, 1978Ya04, 1982Bo04, +207PB4C 1985La17, 1991Ry01, 1996Sc06, 2003Au03, 2008Ki07 +207PB T Auger electrons and X ray energies and emission intensities: +207PB T {U Energy (keV)} {U Intensity} {U Line} +207PB T +207PB T 72.8049 0.00535 14 XKA2 +207PB T 74.97 0.00900 24 XKA1 +207PB T +207PB T 84.451 |] XKB3 +207PB T 84.937 |] 0.00308 10 XKB1 +207PB T 85.47 |] XKB5II +207PB T +207PB T 87.238 |] XKB2 +207PB T 87.58 |] 0.00093 4 XKB4 +207PB T 87.911 |] XKO23 +207PB T +207PB T 9.186-15.2169 0.00740 16 XL (total) +207PB T 9.186 0.000179 6 XLL +207PB T 10.4495-10.5512 0.00339 10 XLA +207PB T 11.3495 5.83E-5 19 XLC +207PB T 12.1443-13.3763 0.00317 8 XLB +207PB T 14.3078-15.2169 0.00060815 XLG +207PB T +207PB T 56.028-61.669 |] KLL AUGER +207PB T 68.181-74.969 |] 0.00071 8 KLX AUGER +207PB T 80.3-88 |] KXY AUGER +207PB T 5.33-15.82 0.01216 17 L AUGER +211PO P 0.0 9/2+ 0.516 S 3 7594.5 5 +207PB N 1.0 1.0 1 +207PB L 0 1/2- STABLE +207PB A 7450.2 3 98.936 19112 +207PB L 569.65 105/2- +207PB A 6891.2 100.541 17272 +207PB G 569.65 150.534 17E2 0.0216 3 +207PB2 G KC=0.01583 23$LC=0.00439 7$MC=0.001081 16$NC=0.000274 4 +207PB3 G OC=5.21E-5 8 +207PB L 897.8 1 3/2- +207PB A 6568.4 100.523 917.9 +207PB G 328.2 2 0.0032 11M1 0.334 5 +207PB2 G KC=0.273 4$LC=0.0465 7$MC=0.01089 16$NC=0.00277 4 +207PB3 G OC=0.000552 8 +207PB G 897.8 2 0.507 9M1+E2 0.092 10 0.0233 4 +207PB2 G KC=0.0192 3$LC=0.00318 5$MC=0.000741 11$NC=0.000188 3 +207PB3 G OC=3.76E-5 6 + diff --git a/HEN_HOUSE/spectra/lnhb/Po-212.txt b/HEN_HOUSE/spectra/lnhb/Po-212.txt index 330be907c..ac0276170 100644 --- a/HEN_HOUSE/spectra/lnhb/Po-212.txt +++ b/HEN_HOUSE/spectra/lnhb/Po-212.txt @@ -1,18 +1,16 @@ -208PB 212PO A DECAY (300 NS) -208PB H TYP=Update$AUT=A.L. Nichols$CUT=30-MAY-2010$ -208PB2 H TYP=Full$AUT=A.L. Nichols$CUT=30-DEC-2003$ -208PB C Evaluation history: Type=Update;Author=A.L. Nichols;Cutoff date=30-MAY-2010 -208PB2C Type=Full;Author=A.L. Nichols;Cutoff date=30-DEC-2003 -208PB C References: 1949Bu09, 1962Fl03, 1963As02, 1972Mc29, 1975Sa06, 1981Bo29, -208PB2C 2003Au03, 2005Br03 -208PB T Auger electrons and X ray energies and emission intensities: -208PB T {U Energy (keV)} {U Intensity} {U Line} -208PB T -208PB T -208PB T -208PB T -212PO P 0.0 0+ 300 NS 2 8954.12 11 -208PB N 1.0 1.0 1 1.0 -208PB L 0 0+ STABLE -208PB A 8785.17 11100 1 - +208PB 212PO A DECAY (300 NS) +208PB H TYP=UPD$AUT=A.L.NICHOLS$CUT=30-MAY-2010$ +208PB2 H TYP=FUL$AUT=A.L.NICHOLS$CUT=30-DEC-2003$ +208PB C References:1949Bu09, 1962Fl03, 1963As02, 1972Mc29, 1975Sa06, 1981Bo29, +208PB2C 2003Au03, 2005Br03 +208PB T Auger electrons and X ray energies and emission intensities: +208PB T {U Energy (keV)} {U Intensity} {U Line} +208PB T +208PB T +208PB T +208PB T +212PO P 0.0 0+ 300 NS 2 8954.12 11 +208PB N 1.0 1.0 1 +208PB L 0 0+ STABLE +208PB A 8785.17 11100 1 + diff --git a/HEN_HOUSE/spectra/lnhb/Po-213.txt b/HEN_HOUSE/spectra/lnhb/Po-213.txt index ca76d14bd..2d34bddcc 100644 --- a/HEN_HOUSE/spectra/lnhb/Po-213.txt +++ b/HEN_HOUSE/spectra/lnhb/Po-213.txt @@ -1,19 +1,19 @@ -209PB 213PO A DECAY (3.70 US) -209PB H TYP=Full$AUT=Huang Xiaolong$CUT=31-DEC-2007$ -209PB C Evaluation history: Type=Full;Author=Huang Xiaolong;Cutoff date=31-DEC-2007 -209PB T Auger electrons and X ray energies and emission intensities: -209PB T {U Energy (keV)} {U Intensity} {U Line} -209PB T -209PB T -209PB T -209PB T -209PB T -213PO P 0.0 9/2+ 3.70 US 5 8536.1 26 -209PB N 1.0 1.0 1 1.0 -209PB L 0 9/2+ 3.277 H 15 -209PB A 8375.9 2599.9950 5 1.238 -209PB L 778.8 3 11/2+ -209PB A 7614 100.0050 5 185 -209PB G 778.8 3 0.0048 5M1 0.0339 5 -209PB2 G KC=0.0278 4$LC=0.00462 7$MC=1079E-6 16 - +209PB 213PO A DECAY (3.70 US) +209PB H TYP=FUL$AUT=X.HUANG$CUT=31-DEC-2007$ +209PB T Auger electrons and X ray energies and emission intensities: +209PB T {U Energy (keV)} {U Intensity} {U Line} +209PB T +209PB T +209PB T +209PB T +209PB T +213PO P 0.0 9/2+ 3.70 US 5 8536.1 26 +209PB N 1.0 1.0 1 +209PB L 0 9/2+ 3.277 H 15 +209PB A 8375.9 2599.9950 51.238 +209PB L 778.8 3 11/2+ +209PB A 7614 100.0050 5185 +209PB G 778.8 3 0.0048 5M1 0.0339 5 +209PB2 G KC=0.0278 4$LC=0.00462 7$MC=0.001079 16$NC=0.000274 4 +209PB3 G OC=5.47E-5 8 + diff --git a/HEN_HOUSE/spectra/lnhb/Po-214.txt b/HEN_HOUSE/spectra/lnhb/Po-214.txt index 39fdc16f0..03e86ef34 100644 --- a/HEN_HOUSE/spectra/lnhb/Po-214.txt +++ b/HEN_HOUSE/spectra/lnhb/Po-214.txt @@ -1,39 +1,40 @@ -210PB 214PO A DECAY (162.3 US) -210PB H TYP=full$AUT=V.Chisté$CUT= -- $ -210PB C Evaluation history: Type=full;Author=V.Chisté;Cutoff date= -- -210PB C References: 1942Wa04, 1950Vo02, 1953Ba60, 1960Og01, 1961Ry02, 1961Do02, -210PB2C 1969Pe17, 1971Gr17, 1971Er02, 1976Ku08, 1990Ho28, 1992Br01, 1993Zh30, -210PB3C 1991Ry01, 1995El07, 1996Sc06, 1998Ak04, 2002Ba85, 2003Au03, 2003Br13 -210PB T Auger electrons and X ray energies and emission intensities: -210PB T {U Energy (keV)} {U Intensity} {U Line} -210PB T -210PB T 72.8049 2.46E-5 15 XKA2 -210PB T 74.97 4.14E-5 25 XKA1 -210PB T -210PB T 84.451 |] XKB3 -210PB T 84.937 |] 1.41E-5 9 XKB1 -210PB T 85.47 |] XKB5II -210PB T -210PB T 87.238 |] XKB2 -210PB T 87.58 |] 4.27E-6 27 XKB4 -210PB T 87.911 |] XKO23 -210PB T -210PB T 9.19-15.22 3.47E-5 13 XL (total) -210PB T 9.19 8.3E-7 5 XLL -210PB T 10.4495-10.5512 1.57E-5 8 XLA -210PB T 11.3495 2.79E-7 16 XLC -210PB T 12.1443-12.7953 1.50E-5 6 XLB -210PB T 14.3078-15.22 2.89E-6 12 XLG -214PO P 0.0 0+ 162.3 US 12 7833.46 6 -210PB N 1.0 1.0 1 1.0 -210PB L 0 0+ 22.23 Y 12 -210PB A 7686.82 6 99.9895 7 1 -210PB L 799.7 2 2+ 17 PS 5 -210PB A 6902.6 3 0.0105 7 27 -210PB G 799.7 1 0.0104 6E2 0.0104215 -210PB2 G KC=0.00810 12$LC=1763E-6 25$MC=4.25E-4 6 -210PB L 1097.7 104+ 0.6 NS 1 -210PB A 6610.1 1058000E-92 400 -210PB G 298 1 0.00005218E2 0.1180 21 -210PB2 G KC=0.0661 11$LC=0.0389 8$MC=0.00999 20 - +210PB 214PO A DECAY (162.3 US) +210PB H TYP=FUL$AUT=V.CHISTE$CUT=31-JAN-2007$ +210PB C References:1942Wa04, 1950Vo02, 1953Ba60, 1960Og01, 1961Ry02, 1961Do02, +210PB2C 1969Pe17, 1971Gr17, 1971Er02, 1976Ku08, 1990Ho28, 1992Br01, 1993Zh30, +210PB3C 1991Ry01, 1995El07, 1996Sc06, 1998Ak04, 2002Ba85, 2003Au03, 2003Br13 +210PB T Auger electrons and X ray energies and emission intensities: +210PB T {U Energy (keV)} {U Intensity} {U Line} +210PB T +210PB T 72.8049 2.46E-5 15 XKA2 +210PB T 74.97 4.14E-5 25 XKA1 +210PB T +210PB T 84.451 |] XKB3 +210PB T 84.937 |] 1.41E-5 9 XKB1 +210PB T 85.47 |] XKB5II +210PB T +210PB T 87.238 |] XKB2 +210PB T 87.58 |] 4.27E-6 27 XKB4 +210PB T 87.911 |] XKO23 +210PB T +210PB T 9.19-15.22 3.47E-5 13 XL (total) +210PB T 9.19 8.3E-7 5 XLL +210PB T 10.4495-10.5512 1.57E-5 8 XLA +210PB T 11.3495 2.79E-7 16 XLC +210PB T 12.1443-12.7953 1.50E-5 6 XLB +210PB T 14.3078-15.22 2.89E-6 12 XLG +214PO P 0.0 0+ 162.3 US 12 7833.46 6 +210PB N 1.0 1.0 1 +210PB L 0 0+ 22.23 Y 12 +210PB A 7686.82 6 99.9895 71 +210PB L 799.7 2 2+ 17 PS 5 +210PB A 6902.6 3 0.0105 727 +210PB G 799.7 1 0.0104 6E2 0.0104215 +210PB2 G KC=0.00810 12$LC=0.001763 25$MC=0.000425 6$NC=1.076E-4 15 +210PB3 G OC=2.08E-5 3 +210PB L 1097.7 104+ 0.6 NS 1 +210PB A 6610.1 100.000058 2400 +210PB G 298 1 0.00005218E2 0.1180 21 +210PB2 G KC=0.0661 11$LC=0.0389 8$MC=0.00999 20$NC=0.00253 5 +210PB3 G OC=0.000464 9 + diff --git a/HEN_HOUSE/spectra/lnhb/Po-215.txt b/HEN_HOUSE/spectra/lnhb/Po-215.txt index 0955c0de6..815251661 100644 --- a/HEN_HOUSE/spectra/lnhb/Po-215.txt +++ b/HEN_HOUSE/spectra/lnhb/Po-215.txt @@ -1,89 +1,89 @@ -211PB 215PO A DECAY (1.781 MS) -211PB H TYP=Full$AUT=V.P. Chechev$CUT=30-NOV-2010$ -211PB C Evaluation history: Type=Full;Author=V.P. Chechev;Cutoff date=30-NOV-2010 -211PB C References: 1942Wa04, 1950Av61, 1961Vo06, 1962Wa18, 1965Va10, 1968Br17, -211PB2C 1970Da09, 1971Gr17, 1971Er02, 1977Ma29, 1991Ry01, 1998Li53, 2003Au03, -211PB3C 2004Br45, 2008Ki07 -211PB T Auger electrons and X ray energies and emission intensities: -211PB T {U Energy (keV)} {U Intensity} {U Line} -211PB T -211PB T 72.8049 0.00045 15 XKA2 -211PB T 74.97 0.00075 25 XKA1 -211PB T -211PB T 84.451 |] XKB3 -211PB T 84.937 |] 0.00026 9 XKB1 -211PB T 85.47 |] XKB5II -211PB T -211PB T 87.238 |] XKB2 -211PB T 87.58 |] 0.00007826 XKB4 -211PB T 87.911 |] XKO23 -211PB T -211PB T 9.186-15.2169 0.00071 12 XL (total) -211PB T 9.186 0.000016 4 XLL -211PB T 10.4495-10.5512 0.00031 7 XLA -211PB T 11.3495 6.3E-6 15 XLC -211PB T 12.1443-13.3763 0.00032 6 XLB -211PB T 14.3078-15.2169 0.00006312 XLG -211PB T -211PB T 56.028-61.669 |] KLL AUGER -211PB T 68.181-74.969 |] 0.00005921 KLX AUGER -211PB T 80.3-88 |] KXY AUGER -211PB T 5.33-15.82 0.00115 14 L AUGER -215PO P 0.0 9/2+ 1.781 MS 4 7526.3 8 -211PB N 1.00E0 1.00E0 0.999997 1.00E0 -211PB L 0 9/2+ 36.1 M 2 -211PB A 7386.1 8 99.934 201.34 -211PB L 438.9 2 (7/2)+ -211PB A 6955.4 8 0.06 2 82 -211PB G 438.9 2 0.058 19E2 0.0405 6 -211PB2 G KC=0.0275 4$LC=0.00984 14$MC=0.00247 4 -211PB L 584 3 + -211PB A 6813 3 0.0004 2 3800 -211PB G 584 3 -211PB L 598 3 (5/2)+ -211PB A 6799 3 0.0016 5 8500 -211PB G 598 3 -211PB L 643 3 11/2+ -211PB A 6755 3 0.0008 3 1170 -211PB G 643 3 (M1+E2) 0.036 20 -211PB2 G KC=0.029 17$LC=0.0054 23$MC=0.0013 6 -211PB L 733 3 (13/2)+ -211PB A 6667 3 0.0008 3 550 -211PB G 733 3 -211PB L 815 3 (9/2)+ -211PB A 6586 3 0.0020 6 109 -211PB G 815 3 -211PB L 894 3 (11/2)+ -211PB A 6509 3 30000E-8 365 -211PB G 310 4 -211PB G 894 3 - -215AT 215PO B- DECAY (1.781 MS) -215AT H TYP=Full$AUT=V.P. Chechev$CUT=30-NOV-2010$ -215AT C Evaluation history: Type=Full;Author=V.P. Chechev;Cutoff date=30-NOV-2010 -215AT C References: 1942Wa04, 1950Av61, 1961Vo06, 1962Wa18, 1965Va10, 1968Br17, -215AT2C 1970Da09, 1971Gr17, 1971Er02, 1977Ma29, 1991Ry01, 1998Li53, 2003Au03, -215AT3C 2004Br45, 2008Ki07 -215AT T Auger electrons and X ray energies and emission intensities: -215AT T {U Energy (keV)} {U Intensity} {U Line} -215AT T -215AT T 78.94 XKA2 -215AT T 81.51 XKA1 -215AT T -215AT T 91.73 |] XKB3 -215AT T 92.315 |] XKB1 -215AT T 92.883 |] XKB5II -215AT T -215AT T 94.846 |] XKB2 -215AT T 95.211 |] XKB4 -215AT T 95.595 |] XKO23 -215AT T -215AT T -215AT T 60.489-67.031 |] KLL AUGER -215AT T 73.811-81.516 |] KLX AUGER -215AT T 87.1-95.72 |] KXY AUGER -215AT T 5.58-17.41 L AUGER -215PO P 0.0 9/2+ 1.781 MS 4 715 7 -215AT N 4.348E5 4.348E5 0.000002 4.348E5 -215AT L 0 + 0.10 MS 2 - +211PB 215PO A DECAY (1.781 MS) +211PB H TYP=FUL$AUT=V.P.CHECHEV$CUT=30-NOV-2010$ +211PB C References:1942Wa04, 1950Av61, 1961Vo06, 1962Wa18, 1965Va10, 1968Br17, +211PB2C 1970Da09, 1971Gr17, 1971Er02, 1977Ma29, 1991Ry01, 1998Li53, 2003Au03, +211PB3C 2004Br45, 2008Ki07 +211PB T Auger electrons and X ray energies and emission intensities: +211PB T {U Energy (keV)} {U Intensity} {U Line} +211PB T +211PB T 72.8049 0.00045 15 XKA2 +211PB T 74.97 0.00075 25 XKA1 +211PB T +211PB T 84.451 |] XKB3 +211PB T 84.937 |] 0.00026 9 XKB1 +211PB T 85.47 |] XKB5II +211PB T +211PB T 87.238 |] XKB2 +211PB T 87.58 |] 0.00007826 XKB4 +211PB T 87.911 |] XKO23 +211PB T +211PB T 9.186-15.2169 0.00071 12 XL (total) +211PB T 9.186 0.000016 4 XLL +211PB T 10.4495-10.5512 0.00031 7 XLA +211PB T 11.3495 6.3E-6 15 XLC +211PB T 12.1443-13.3763 0.00032 6 XLB +211PB T 14.3078-15.2169 0.00006312 XLG +211PB T +211PB T 56.028-61.669 |] KLL AUGER +211PB T 68.181-74.969 |] 0.00005921 KLX AUGER +211PB T 80.3-88 |] KXY AUGER +211PB T 5.33-15.82 0.00115 14 L AUGER +215PO P 0.0 9/2+ 1.781 MS 4 7526.3 8 +211PB N 1.00E0 1.00E0 0.999998 +211PB L 0 9/2+ 36.1 M 2 +211PB A 7386.1 8 99.934 201.34 +211PB L 438.9 2 (7/2)+ +211PB A 6955.4 8 0.06 282 +211PB G 438.9 2 0.058 19E2 0.0405 6 +211PB2 G KC=0.0275 4$LC=0.00984 14$MC=0.00247 4$NC=0.000624 9 +211PB3 G OC=1.171E-4 17 +211PB L 584 3 +211PB A 6813 3 0.0004 23800 +211PB G 584 3 +211PB L 598 3 (5/2)+ +211PB A 6799 3 0.0016 58500 +211PB G 598 3 +211PB L 643 3 11/2+ +211PB A 6755 3 0.0008 31170 +211PB G 643 3 (M1+E2) 0.036 20 +211PB2 G KC=0.029 17$LC=0.0054 23$MC=0.0013 6$NC=0.00032 13 +211PB3 G OC=0.00006 3 +211PB L 733 3 (13/2)+ +211PB A 6667 3 0.0008 3550 +211PB G 733 3 +211PB L 815 3 (9/2)+ +211PB A 6586 3 0.0020 6109 +211PB G 815 3 +211PB L 894 3 (11/2)+ +211PB A 6509 3 30000E-8 365 +211PB G 310 4 +211PB G 894 3 + +215AT 215PO B- DECAY (1.781 MS) +215AT H TYP=FUL$AUT=V.P.CHECHEV$CUT=30-NOV-2010$ +215AT C References:1942Wa04, 1950Av61, 1961Vo06, 1962Wa18, 1965Va10, 1968Br17, +215AT2C 1970Da09, 1971Gr17, 1971Er02, 1977Ma29, 1991Ry01, 1998Li53, 2003Au03, +215AT3C 2004Br45, 2008Ki07 +215AT T Auger electrons and X ray energies and emission intensities: +215AT T {U Energy (keV)} {U Intensity} {U Line} +215AT T +215AT T 78.94 XKA2 +215AT T 81.51 XKA1 +215AT T +215AT T 91.73 |] XKB3 +215AT T 92.315 |] XKB1 +215AT T 92.883 |] XKB5II +215AT T +215AT T 94.846 |] XKB2 +215AT T 95.211 |] XKB4 +215AT T 95.595 |] XKO23 +215AT T +215AT T +215AT T 60.489-67.031 |] KLL AUGER +215AT T 73.811-81.516 |] KLX AUGER +215AT T 87.1-95.72 |] KXY AUGER +215AT T 5.58-17.41 L AUGER +215PO P 0.0 9/2+ 1.781 MS 4 715 7 +215AT N 4.348E5 4.348E5 2.3E-6 4.348E5 +215AT L 0 0.10 MS 2 + diff --git a/HEN_HOUSE/spectra/lnhb/Po-216.txt b/HEN_HOUSE/spectra/lnhb/Po-216.txt index b1be173e3..1573621d9 100644 --- a/HEN_HOUSE/spectra/lnhb/Po-216.txt +++ b/HEN_HOUSE/spectra/lnhb/Po-216.txt @@ -1,42 +1,41 @@ -212PB 216PO A DECAY (0.148 S) -212PB H TYP=Update$AUT=A.L. Nichols$CUT=30-JAN-2011$ -212PB2 H TYP=Full$AUT=A.L. Nichols$CUT=30-JAN-2004$ -212PB C Evaluation history: Type=Update;Author=A.L. Nichols;Cutoff date=30-JAN-2011 -212PB2C Type=Full;Author=A.L. Nichols;Cutoff date=30-JAN-2004 -212PB C References: 1911Mo11, 1942Wa04, 1962Wa28, 1963Di05, 1977Ku15, 1977La19, -212PB2C 1996Sc06, 1998ScZM, 1998Ak04, 1999ScZX, 2002Ba85, 2002Ra45, 2003Au03, -212PB3C 2003Da24, 2005Br03, 2007Wu02, 2007St23, 2008Ki07 -212PB T Auger electrons and X ray energies and emission intensities: -212PB T {U Energy (keV)} {U Intensity} {U Line} -212PB T -212PB T 72.8049 4.3E-6 7 XKA2 -212PB T 74.97 7.2E-6 12 XKA1 -212PB T -212PB T 84.451 |] XKB3 -212PB T 84.937 |] 2.4E-6 4 XKB1 -212PB T 85.47 |] XKB5II -212PB T -212PB T 87.238 |] XKB2 -212PB T 87.58 |] 7.4E-7 12 XKB4 -212PB T 87.911 |] XKO23 -212PB T -212PB T 9.184-15.216 5.9E-6 6 XL (total) -212PB T 9.184 1.42E-7 18 XLL -212PB T 10.45-10.551 2.7E-6 3 XLA -212PB T 11.349 4.7E-8 7 XLC -212PB T 12.142-13.015 2.53E-6 24 XLB -212PB T 14.765-15.216 4.9E-7 5 XLG -212PB T -212PB T 56.03-61.67 |] KLL AUGER -212PB T 68.18-74.97 |] 5.6E-7 11 KLX AUGER -212PB T 80.3-88 |] KXY AUGER -212PB T 5.26-10.4 9.7E-6 10 L AUGER -216PO P 0.0 0+ 0.148 S 4 6906.3 5 -212PB N 1.0 1.0 1 1.0 -212PB L 0 0+ 10.64 H 1 -212PB A 6778.4 5 99.9981 3 1 -212PB L 804.9 5 (2)+ -212PB A 5988.4 7 0.0019 3 35 -212PB G 804.9 5 0.0019 3[E2] 0.0102715 -212PB2 G KC=0.00799 12$LC=1732E-6 25$MC=4.17E-4 6 - +212PB 216PO A DECAY (0.148 S) +212PB H TYP=UPD$AUT=A.L.NICHOLS$CUT=30-JAN-2011$ +212PB2 H TYP=FUL$AUT=A.L.NICHOLS$CUT=30-JAN-2004$ +212PB C References:1911Mo11, 1942Wa04, 1962Wa28, 1963Di05, 1977Ku15, 1977La19, +212PB2C 1996Sc06, 1998ScZM, 1998Ak04, 1999ScZX, 2002Ba85, 2002Ra45, 2003Au03, +212PB3C 2003Da24, 2005Br03, 2007Wu02, 2007St23, 2008Ki07 +212PB T Auger electrons and X ray energies and emission intensities: +212PB T {U Energy (keV)} {U Intensity} {U Line} +212PB T +212PB T 72.8049 4.3E-6 7 XKA2 +212PB T 74.97 7.2E-6 12 XKA1 +212PB T +212PB T 84.451 |] XKB3 +212PB T 84.937 |] 2.4E-6 4 XKB1 +212PB T 85.47 |] XKB5II +212PB T +212PB T 87.238 |] XKB2 +212PB T 87.58 |] 7.4E-7 12 XKB4 +212PB T 87.911 |] XKO23 +212PB T +212PB T 9.184-15.216 5.9E-6 6 XL (total) +212PB T 9.184 1.42E-7 18 XLL +212PB T 10.45-10.551 2.7E-6 3 XLA +212PB T 11.349 4.7E-8 7 XLC +212PB T 12.142-13.015 2.53E-6 24 XLB +212PB T 14.765-15.216 4.9E-7 5 XLG +212PB T +212PB T 56.03-61.67 |] KLL AUGER +212PB T 68.18-74.97 |] 5.6E-7 11 KLX AUGER +212PB T 80.3-88 |] KXY AUGER +212PB T 5.26-10.4 9.7E-6 10 L AUGER +216PO P 0.0 0+ 0.148 S 4 6906.3 5 +212PB N 1.0 1.0 1 +212PB L 0 0+ 10.64 H 1 +212PB A 6778.4 5 99.9981 31 +212PB L 804.9 5 (2)+ +212PB A 5988.4 7 0.0019 335 +212PB G 804.9 5 0.0019 3[E2] 0.0102715 +212PB2 G KC=0.00799 12$LC=0.001732 25$MC=0.000417 6$NC=1.057E-4 15 +212PB3 G OC=2.05E-5 3 + diff --git a/HEN_HOUSE/spectra/lnhb/Po-218.txt b/HEN_HOUSE/spectra/lnhb/Po-218.txt index 29a74848b..2f32fe8f5 100644 --- a/HEN_HOUSE/spectra/lnhb/Po-218.txt +++ b/HEN_HOUSE/spectra/lnhb/Po-218.txt @@ -1,63 +1,59 @@ -214PB 218PO A DECAY (3.071 M) -214PB H TYP=Update$AUT=V.Chisté$CUT= -- $ -214PB2 H TYP=Full$AUT=V.Chisté$CUT= -- $ -214PB C Evaluation history: Type=Update;Author=V.Chisté;Cutoff date= -- -214PB2C Type=Full;Author=V.Chisté;Cutoff date= -- -214PB C References: 1924Bl02, 1931Cu01, 1949Wa05, 1952Hi60, 1958Wa16, 1963Ba62, -214PB2C 1971Gr17, 1979Ry03, 1982Va09, 1986Po17, 1987El07, 1991Ry01, 1992Ba61, -214PB3C 1995El07, 1995El08, 1998Ak04, 2002Ba85, 2003Au03, 2006Ja03 -214PB T Auger electrons and X ray energies and emission intensities: -214PB T {U Energy (keV)} {U Intensity} {U Line} -214PB T -214PB T 72.8049 XKA2 -214PB T 74.97 XKA1 -214PB T -214PB T 84.451 |] XKB3 -214PB T 84.937 |] XKB1 -214PB T 85.47 |] XKB5II -214PB T -214PB T 87.238 |] XKB2 -214PB T 87.58 |] XKB4 -214PB T 87.911 |] XKO23 -214PB T -218PO P 0.0 0+ 3.071 M 22 6114.68 9 -214PB N 1.00E0 1.00E0 0.999779 1.00E0 -214PB L 0 0+ 26.916 M 44 -214PB A 6002.35 9 99.9989 321 -214PB L 837 (2)+ -214PB A 5181 2 0.0011 117.5 -214PB G 836 2 0.0011 11(E2) - -218AT 218PO B- DECAY (3.071 M) -218AT H TYP=Update$AUT=V.Chisté$CUT= -- $ -218AT2 H TYP=Full$AUT=V.Chisté$CUT= -- $ -218AT C Evaluation history: Type=Update;Author=V.Chisté;Cutoff date= -- -218AT2C Type=Full;Author=V.Chisté;Cutoff date= -- -218AT C References: 1924Bl02, 1931Cu01, 1949Wa05, 1952Hi60, 1958Wa16, 1963Ba62, -218AT2C 1971Gr17, 1979Ry03, 1982Va09, 1986Po17, 1987El07, 1991Ry01, 1992Ba61, -218AT3C 1995El07, 1995El08, 1998Ak04, 2002Ba85, 2003Au03, 2006Ja03 -218AT T Auger electrons and X ray energies and emission intensities: -218AT T {U Energy (keV)} {U Intensity} {U Line} -218AT T -218AT T 78.94 XKA2 -218AT T 81.51 XKA1 -218AT T -218AT T 91.73 |] XKB3 -218AT T 92.315 |] XKB1 -218AT T 92.883 |] XKB5II -218AT T -218AT T 94.846 |] XKB2 -218AT T 95.211 |] XKB4 -218AT T 95.595 |] XKO23 -218AT T -218AT T 9.8964 XLL -218AT T 11.3052-11.426 XLA -218AT T 12.4653 XLC -218AT T 13.1704-14.6997 XLB -218AT T 15.7394-16.7291 XLG -218PO P 0.0 0+ 3.071 M 22 260 12 -218AT N 4.545E3 4.545E3 0.00022 4.545E3 -218AT L 0 (2)- 1.4 S 2 -218AT B 260 120.022 3 1U -218ATS B EAV=73 4 - +214PB 218PO A DECAY (3.071 M) +214PB H TYP=UPD$AUT=V.CHISTE$CUT=01-DEC-2010$ +214PB2 H TYP=FUL$AUT=V.CHISTE$CUT=31-JAN-2007$ +214PB C References:1924Bl02, 1931Cu01, 1949Wa05, 1952Hi60, 1958Wa16, 1963Ba62, +214PB2C 1971Gr17, 1979Ry03, 1982Va09, 1986Po17, 1987El07, 1991Ry01, 1992Ba61, +214PB3C 1995El07, 1995El08, 1998Ak04, 2002Ba85, 2003Au03, 2006Ja03 +214PB T Auger electrons and X ray energies and emission intensities: +214PB T {U Energy (keV)} {U Intensity} {U Line} +214PB T +214PB T 72.8049 XKA2 +214PB T 74.97 XKA1 +214PB T +214PB T 84.451 |] XKB3 +214PB T 84.937 |] XKB1 +214PB T 85.47 |] XKB5II +214PB T +214PB T 87.238 |] XKB2 +214PB T 87.58 |] XKB4 +214PB T 87.911 |] XKO23 +214PB T +218PO P 0.0 0+ 3.071 M 22 6114.68 9 +214PB N 1.00E0 1.00E0 0.999780 +214PB L 0 0+ 26.916 M 44 +214PB A 6002.35 9 99.9989 321 +214PB L 837 (2)+ +214PB A 5181 2 0.0011 117.5 +214PB G 836 2 0.0011 11(E2) + +218AT 218PO B- DECAY (3.071 M) +218AT H TYP=UPD$AUT=V.CHISTE$CUT=01-DEC-2010$ +218AT2 H TYP=FUL$AUT=V.CHISTE$CUT=31-JAN-2007$ +218AT C References:1924Bl02, 1931Cu01, 1949Wa05, 1952Hi60, 1958Wa16, 1963Ba62, +218AT2C 1971Gr17, 1979Ry03, 1982Va09, 1986Po17, 1987El07, 1991Ry01, 1992Ba61, +218AT3C 1995El07, 1995El08, 1998Ak04, 2002Ba85, 2003Au03, 2006Ja03 +218AT T Auger electrons and X ray energies and emission intensities: +218AT T {U Energy (keV)} {U Intensity} {U Line} +218AT T +218AT T 78.94 XKA2 +218AT T 81.51 XKA1 +218AT T +218AT T 91.73 |] XKB3 +218AT T 92.315 |] XKB1 +218AT T 92.883 |] XKB5II +218AT T +218AT T 94.846 |] XKB2 +218AT T 95.211 |] XKB4 +218AT T 95.595 |] XKO23 +218AT T +218AT T 9.8964 XLL +218AT T 11.3052-11.426 XLA +218AT T 12.4653 XLC +218AT T 13.1704-14.6997 XLB +218AT T 15.7394-16.7291 XLG +218PO P 0.0 0+ 3.071 M 22 260 12 +218AT N 4.545E3 4.545E3 0.00022 4.545E3 +218AT L 0 (2)- 1.4 S 2 +218AT B 260 120.022 3 1U +218ATS B EAV=73 4 + diff --git a/HEN_HOUSE/spectra/lnhb/Pr-142.txt b/HEN_HOUSE/spectra/lnhb/Pr-142.txt new file mode 100644 index 000000000..a0248930d --- /dev/null +++ b/HEN_HOUSE/spectra/lnhb/Pr-142.txt @@ -0,0 +1,96 @@ +142CE 142PR EC DECAY (19.14 H) +142CE C References:1942De07, 1948Co23, 1949Ma16, 1950Je56, 1952Je13, 1952Mo29, +142CE2C 1954Po26, 1955St51, 1957Ri43, 1959Fr52, 1959Se49, 1961Ma05, 1961La15, +142CE3C 1963Me15, 1966Ot03, 1966Cr02, 1966Be12, 1967Ke05, 1968Ke08, 1968Hi07, +142CE4C 1968La17, 1968Ra04, 1975Ra09, 1975Sc17, 1977La19, 1989Sp07, 1989Ab05, +142CE5C 1993Ni17, 1993Be03, 1995Be41, 1995ScZY, 1996Sc06, 1998Sc28, 1998ScZM, +142CE6C 1999ScZX, 2000Sc47, 2001Ra27, 2002Ra45, 2002Ba85, 2008Ki07, 2011Jo05, +142CE7C 2012Wa38 +142CE T Auger electrons and X ray energies and emission intensities: +142CE T {U Energy (keV)} {U Intensity} {U Line} +142CE T +142CE T 34.2793 0.0035 3 XKA2 +142CE T 34.72 0.0064 6 XKA1 +142CE T +142CE T 39.1705 |] XKB3 +142CE T 39.2578 |] 0.00192 16 XKB1 +142CE T 39.549 |] XKB5II +142CE T +142CE T 40.233 |] XKB2 +142CE T 40.337 |] 0.00049 4 XKB4 +142CE T 40.423 |] XKO23 +142CE T +142CE T 4.289-6.342 0.00179 9 XL (total) +142CE T 4.289 3.41E-5 25 XLL +142CE T 4.822-4.84 0.00087 6 XLA +142CE T 4.73 1.28E-5 10 XLC +142CE T 5.263-5.613 0.00075 4 XLB +142CE T 6.054-6.342 0.000122 7 XLG +142CE T +142CE T 27.19-28.828 |] KLL AUGER +142CE T 32.392-34.7 |] 0.00121 12 KLX AUGER +142CE T 37.57-40.4 |] KXY AUGER +142CE T 2.81-4.72 0.0123 7 L AUGER +142PR P 0.0 2- 19.14 H 4 744.5 24 +142CE N 6.098E3 6.098E3 0.000164 86.098E3 +142CE L 0 0+ STABLE +142CE E 0.0142 119.4 1U +142CE2 E CK=0.8398 15$CL=0.1255 11$CM=0.0280 5$CN=0.0068 4 +142CE L 641.282 9 2+ 5.40 PS 7 +142CE E 0.0022 87.9 +142CE2 E CK=0.704 6$CL=0.2270 46$CM=0.0554 15$CN=0.0137 8 +142CE G 641.280 9 0.0022 8E2 0.00563 8 +142CE2 G KC=0.00475 7$LC=0.000695 10$MC=1.463E-4 21$NC=3.22E-5 5 +142CE3 G OC=5.11E-6 8 + +142ND 142PR B- DECAY (19.14 H) +142ND C References:1942De07, 1948Co23, 1949Ma16, 1950Je56, 1952Je13, 1952Mo29, +142ND2C 1954Po26, 1955St51, 1957Ri43, 1959Fr52, 1959Se49, 1961Ma05, 1961La15, +142ND3C 1963Me15, 1966Ot03, 1966Cr02, 1966Be12, 1967Ke05, 1968Ke08, 1968Hi07, +142ND4C 1968La17, 1968Ra04, 1975Ra09, 1975Sc17, 1977La19, 1989Sp07, 1989Ab05, +142ND5C 1993Ni17, 1993Be03, 1995Be41, 1995ScZY, 1996Sc06, 1998Sc28, 1998ScZM, +142ND6C 1999ScZX, 2000Sc47, 2001Ra27, 2002Ra45, 2002Ba85, 2008Ki07, 2011Jo05, +142ND7C 2012Wa38 +142ND T Auger electrons and X ray energies and emission intensities: +142ND T {U Energy (keV)} {U Intensity} {U Line} +142ND T +142ND T 36.8478 0.00076 9 XKA2 +142ND T 37.3614 0.00139 15 XKA1 +142ND T +142ND T 42.167 |] XKB3 +142ND T 42.2717 |] 0.00043 5 XKB1 +142ND T 42.58 |] XKB5II +142ND T +142ND T 43.335 |] XKB2 +142ND T 43.451 |] 0.00011012 XKB4 +142ND T 43.548 |] XKO23 +142ND T +142ND T 4.633-6.901 0.00042 3 XL (total) +142ND T 4.633 8.2E-6 8 XLL +142ND T 5.208-5.23 0.00020617 XLA +142ND T 5.146 3.1E-6 3 XLC +142ND T 5.722-6.09 0.00017412 XLB +142ND T 6.604-6.901 2.79E-5 20 XLG +142ND T +142ND T 29.154-30.978 |] KLL AUGER +142ND T 34.798-37.34 |] 0.00024 3 KLX AUGER +142ND T 40.42-43.53 |] KXY AUGER +142ND T 3.01-5.1 0.00251 17 L AUGER +142PR P 0.0 2- 19.14 H 4 2161.6 15 +142ND N 1.00E0 1.00E0 0.999836 81.00E0 +142ND L 0 0+ STABLE +142ND B 2161.6 1596.3 4 8.90 1U +142NDS B EAV=833.9 7 +142ND L 1575.78 1 2+ 0.110 PS 2 +142ND B 585.8 153.7 4 7.1 +142NDS B EAV=182.5 6 +142ND G 1575.771 103.7 4E2 1003E-614 +142ND2 G KC=0.000772 11$LC=1.005E-4 14$MC=2.12E-5 3$NC=4.74E-6 7 +142ND3 G OC=7.19E-7 10$IPC=1.037E-4 15 +142ND L 2083.94 2 3- 0.44 PS +142ND B 77.7 150.024 3 6.5 +142NDS B EAV=20.1 4 +142ND G 508.159 220.024 3E1 0.00380 6 +142ND2 G KC=0.00326 5$LC=0.000424 6$MC=8.92E-5 13$NC=1.99E-5 3 +142ND3 G OC=3.00E-6 5 + diff --git a/HEN_HOUSE/spectra/lnhb/Pr-144.txt b/HEN_HOUSE/spectra/lnhb/Pr-144.txt index 842221fc2..d7f4417eb 100644 --- a/HEN_HOUSE/spectra/lnhb/Pr-144.txt +++ b/HEN_HOUSE/spectra/lnhb/Pr-144.txt @@ -1,106 +1,121 @@ -144ND 144PR B- DECAY (17.29 M) -144ND H TYP=FUL$AUT=A.L. Nichols$CUT=01-APR-2014$ -144ND C Evaluation history: Type=FUL;Author=A.L. Nichols;Cutoff date=01-APR-2014 -144ND C References: 1954Kr40, 1954Wa05, 1956Po16, 1957Pe09, 1958Gr99, 1959Po77, -144ND2C 1961Ma05, 1963Iw02, 1963Kn05, 1963Si10, 1963Ho15, 1963Co18, 1963Cr11, -144ND3C 1965Is01, 1965Co19, 1965Re13, 1966Be11, 1967Gu17, 1968Ra01, 1968Sa05, -144ND4C 1968Da12, 1969Ge01, 1969Gu15, 1969Ma24, 1970Fa03, 1971Na12, 1973Bo43, -144ND5C 1974Be09, 1975De17, 1976CoZX, 1976Ra22, 1977La19, 1977Ge12, 1979Pr11, -144ND6C 1979Gr01, 1981Ol04, 1983Sn04, 1983Kr09, 1985Da16, 1987Al28, 1994Ro13, -144ND7C 1996Sc06, 1998Hi09, 1998ScZM, 1999ScZX, 2000Sc47, 2000He14, 2001So16, -144ND8C 2002Ra45, 2002Ba85, 2008Ki07, 2012Wa38 -144ND T Auger electrons and X ray energies and emission intensities: -144ND T {U Energy (keV)} {U Intensity} {U Line} -144ND T -144ND T 36.8478 0.00165 9 XKA2 -144ND T 37.3614 0.00300 15 XKA1 -144ND T -144ND T 42.167 |] XKB3 -144ND T 42.2717 |] 0.00092 5 XKB1 -144ND T 42.58 |] XKB5II -144ND T -144ND T 43.335 |] XKB2 -144ND T 43.451 |] 0.00023713 XKB4 -144ND T 43.548 |] XKO23 -144ND T -144ND T 4.633-6.901 0.00092 3 XL (total) -144ND T 4.633 1.79E-5 9 XLL -144ND T 5.208-5.23 0.00044920 XLA -144ND T 5.146 6.9E-6 4 XLC -144ND T 5.722-6.09 0.00038414 XLB -144ND T 6.604-6.901 6.15E-5 23 XLG -144ND T -144ND T 29.154-30.978 |] KLL AUGER -144ND T 34.798-37.34 |] 0.00052 4 KLX AUGER -144ND T 40.42-43.53 |] KXY AUGER -144ND T 3.01-5.1 0.00551 18 L AUGER -144PR P 0.0 0- 17.29 M 4 2997.4 24 -144ND N 1.0 1.0 1 1.0 -144ND L 0 0 0+ 2.3E15 Y 3 -144ND B 2997.4 2497.852 10 6.53 -144NDS B EAV=12220E-1 1 -144ND L 696.561 102+ -144ND B 2300.8 241.116 3 9.17 1U -144NDS B EAV=894.90 11 -144ND G 696.505 4 1.41 7E2 0.00507 7 -144ND2 G KC=0.00427 6$LC=6.31E-4 9$MC=1348E-7 19 -144ND L 1314.669 134+ 7.40 PS 9 -144ND L 1510.871 213- 0.56 PS 7 -144ND G 814.308 230.00331 14E1 1391E-620 -144ND2 G KC=1198E-6 17$LC=1528E-7 22$MC=3.21E-5 5 -144ND L 1560.920 132+ -144ND B 1436.5 240.0017 3 10.8 1U -144NDS B EAV=526.25 10 -144ND G 864.356 160.00269 14M1+E2 -0.97 15 0.0039616 -144ND2 G KC=0.00338 14$LC=4.56E-4 16$MC=9.6E-5 4 -144ND G 1560.911 130.00021 3E2 1014E-615 -144ND2 G KC=7.86E-4 11$LC=1024E-7 15$MC=2.16E-5 3 -144ND L 2072.91 3 2+ 59 FS 10 -144ND B 924.5 240.00065 6 10.2 1U -144NDS B EAV=322.77 9 -144ND G 1376.34 3 0.00041 4M1+E2 0.34 10 0.00161 4 -144ND2 G KC=0.00135 3$LC=1.75E-4 4$MC=3.68E-5 8 -144ND G 2072.89 3 0.00024 3E2 8.65E-413 -144ND2 G KC=4.65E-4 7$LC=5.93E-5 9$MC=1246E-8 18 -144ND L 2084.68 3 0+ 0.12 PS 5 -144ND B 912.7 240.00708 6 8.7 -144NDS B EAV=306.67 10 -144ND G 1388.11 4 0.00706 6E2 1190E-617 -144ND2 G KC=9.84E-4 14$LC=1297E-7 19$MC=2.74E-5 4 -144ND L 2185.75 3 1- 15 FS 2 -144ND B 811.7 241.021 10 6.32 -144NDS B EAV=267.12 9 -144ND G 624.83 3 0.00118 3E1 0.00241 4 -144ND2 G KC=0.00207 3$LC=2.67E-4 4$MC=5.61E-5 8 -144ND G 674.88 4 0.00299 14E2 0.00547 8 -144ND2 G KC=0.00460 7$LC=6.86E-4 10$MC=1465E-7 21 -144ND G 1489.148 3 0.286 3E1 6.63E-410 -144ND2 G KC=3.97E-4 6$LC=4.95E-5 7$MC=1038E-8 15 -144ND G 2185.645 5 0.73 1E1 9.59E-414 -144ND2 G KC=2.13E-4 3$LC=2.64E-5 4$MC=5.52E-6 8 -144ND L 2368.82 4 2+ 39 FS 14 -144ND B 628.6 240.00027 6 9.7 1U -144NDS B EAV=213.04 9 -144ND G 1672.25 4 0.00021 6M1+E2 0.16 7 1189E-618 -144ND2 G KC=8.92E-4 14$LC=1146E-7 18$MC=2.41E-5 4 -144ND G 2368.80 4 0.00005114E2 8.91E-413 -144ND2 G KC=3.65E-4 6$LC=4.63E-5 7$MC=9.73E-6 14 -144ND L 2582.32 6 (3)+ -144ND L 2655.54 3 1+ 9.9 FS 2 -144ND B 341.9 240.00018 3 8.8 1 -144NDS B EAV=98.68 8 -144ND G 2655.51 3 0.00018 3M1+E2 -144ND L 2675.61 8 0+ 0.2 PS 1 -144ND B 321.8 240.00096 8 8 -144NDS B EAV=92.21 8 -144ND G 1979.04 8 0.00096 8E2 8.68E-413 -144ND2 G KC=5.05E-4 7$LC=6.47E-5 9$MC=1360E-8 19 -144ND L 2742.99 7 0+ 64 FS 40 -144ND B 254.4 240.00035 6 8.1 -144NDS B EAV=71.05 8 -144ND G 1182.06 7 0.00006 3E2 1587E-623 -144ND2 G KC=1353E-6 19$LC=1.82E-4 3$MC=3.84E-5 6 -144ND G 2046.41 7 0.00030 6E2 8.65E-413 -144ND2 G KC=4.75E-4 7$LC=6.07E-5 9$MC=1277E-8 18 -144ND L 2946.04 10(2,3,4)- - +144ND 144PR B- DECAY (17.29 M) +144ND H TYP=FUL$AUT=A.L.NICHOLS$CUT=01-APR-2014$ +144ND C References:1954Kr40, 1954Wa05, 1956Po16, 1957Pe09, 1958Gr99, 1959Po77, +144ND2C 1961Ma05, 1963Iw02, 1963Kn05, 1963Si10, 1963Ho15, 1963Co18, 1963Cr11, +144ND3C 1965Is01, 1965Co19, 1965Re13, 1966Be11, 1967Gu17, 1968Ra01, 1968Sa05, +144ND4C 1968Da12, 1969Ge01, 1969Gu15, 1969Ma24, 1970Fa03, 1971Na12, 1973Bo43, +144ND5C 1974Be09, 1975De17, 1976CoZX, 1976Ra22, 1977La19, 1977Ge12, 1979Pr11, +144ND6C 1979Gr01, 1981Ol04, 1983Sn04, 1983Kr09, 1985Da16, 1987Al28, 1994Ro13, +144ND7C 1996Sc06, 1998Hi09, 1998ScZM, 1999ScZX, 2000Sc47, 2000He14, 2001So16, +144ND8C 2002Ra45, 2002Ba85, 2008Ki07, 2012Wa38 +144ND T Auger electrons and X ray energies and emission intensities: +144ND T {U Energy (keV)} {U Intensity} {U Line} +144ND T +144ND T 36.8478 0.00165 9 XKA2 +144ND T 37.3614 0.00300 15 XKA1 +144ND T +144ND T 42.167 |] XKB3 +144ND T 42.2717 |] 0.00092 5 XKB1 +144ND T 42.58 |] XKB5II +144ND T +144ND T 43.335 |] XKB2 +144ND T 43.451 |] 0.00023713 XKB4 +144ND T 43.548 |] XKO23 +144ND T +144ND T 4.633-6.901 0.00092 3 XL (total) +144ND T 4.633 1.79E-5 9 XLL +144ND T 5.208-5.23 0.00044920 XLA +144ND T 5.146 6.9E-6 4 XLC +144ND T 5.722-6.09 0.00038414 XLB +144ND T 6.604-6.901 6.15E-5 23 XLG +144ND T +144ND T 29.154-30.978 |] KLL AUGER +144ND T 34.798-37.34 |] 0.00052 4 KLX AUGER +144ND T 40.42-43.53 |] KXY AUGER +144ND T 3.01-5.1 0.00551 18 L AUGER +144PR P 0.0 0- 17.29 M 4 2997.4 24 +144ND N 1.0 1.0 1 1.0 +144ND L 0 0+ 2.3E15 Y 3 +144ND B 2997.4 2497.852 10 6.53 +144NDS B EAV=12220E-1 1 +144ND L 696.561 102+ +144ND B 2300.8 241.116 3 9.17 1U +144NDS B EAV=894.90 11 +144ND G 696.505 4 1.41 7E2 0.00507 7 +144ND2 G KC=0.00427 6$LC=0.000631 9$MC=1.348E-4 19$NC=3.00E-5 5 +144ND3 G OC=4.45E-6 7 +144ND L 1314.669 134+ 7.40 PS 9 +144ND L 1510.871 213- 0.56 PS 7 +144ND G 814.308 230.00331 14E1 1391E-620 +144ND2 G KC=0.001198 17$LC=1.528E-4 22$MC=3.21E-5 5$NC=7.17E-6 10 +144ND3 G OC=1.087E-6 16 +144ND L 1560.920 132+ +144ND B 1436.5 240.0017 3 10.8 1U +144NDS B EAV=526.25 10 +144ND G 864.356 160.00269 14M1+E2 -0.97 15 0.0039616 +144ND2 G KC=0.00338 14$LC=0.000456 16$MC=0.000096 4$NC=2.16E-5 8 +144ND3 G OC=3.27E-6 12 +144ND G 1560.911 130.00021 3E2 1014E-615 +144ND2 G KC=0.000786 11$LC=1.024E-4 15$MC=2.16E-5 3$NC=4.83E-6 7 +144ND3 G OC=7.33E-7 11$IPC=9.81E-5 14 +144ND L 2072.91 3 2+ 59 FS 10 +144ND B 924.5 240.00065 6 10.2 1U +144NDS B EAV=322.77 9 +144ND G 1376.34 3 0.00041 4M1+E2 0.34 10 0.00161 4 +144ND2 G KC=0.00135 3$LC=0.000175 4$MC=3.68E-5 8$NC=8.24E-6 18 +144ND3 G OC=1.26E-6 3$IPC=3.98E-5 6 +144ND G 2072.89 3 0.00024 3E2 8.65E-413 +144ND2 G KC=0.000465 7$LC=5.93E-5 9$MC=1.246E-5 18$NC=2.79E-6 4 +144ND3 G OC=4.25E-7 6$IPC=0.000326 5 +144ND L 2084.68 3 0+ 0.12 PS 5 +144ND B 912.7 240.00708 6 8.7 +144NDS B EAV=306.67 10 +144ND G 1388.11 4 0.00706 6E2 1190E-617 +144ND2 G KC=0.000984 14$LC=1.297E-4 19$MC=2.74E-5 4$NC=6.11E-6 9 +144ND3 G OC=9.27E-7 13$IPC=4.16E-5 6 +144ND L 2185.75 3 1- 15 FS 2 +144ND B 811.7 241.021 10 6.32 +144NDS B EAV=267.12 9 +144ND G 624.83 3 0.00118 3E1 0.00241 4 +144ND2 G KC=0.00207 3$LC=0.000267 4$MC=5.61E-5 8$NC=1.252E-5 18 +144ND3 G OC=1.89E-6 3 +144ND G 674.88 4 0.00299 14E2 0.00547 8 +144ND2 G KC=0.00460 7$LC=0.000686 10$MC=1.465E-4 21$NC=3.26E-5 5 +144ND3 G OC=4.83E-6 7 +144ND G 1489.148 3 0.286 3E1 6.63E-410 +144ND2 G KC=0.000397 6$LC=4.95E-5 7$MC=1.038E-5 15$NC=2.32E-6 4 +144ND3 G OC=3.54E-7 5$IPC=0.000204 3 +144ND G 2185.645 5 0.73 1E1 9.59E-414 +144ND2 G KC=0.000213 3$LC=2.64E-5 4$MC=5.52E-6 8$NC=1.235E-6 18 +144ND3 G OC=1.89E-7 3$IPC=0.000712 10 +144ND L 2368.82 4 2+ 39 FS 14 +144ND B 628.6 240.00027 6 9.7 1U +144NDS B EAV=213.04 9 +144ND G 1672.25 4 0.00021 6M1+E2 0.16 7 1189E-618 +144ND2 G KC=0.000892 14$LC=1.146E-4 18$MC=2.41E-5 4$NC=5.41E-6 9 +144ND3 G OC=8.27E-7 13$IPC=1.519E-4 22 +144ND G 2368.80 4 0.00005114E2 8.91E-413 +144ND2 G KC=0.000365 6$LC=4.63E-5 7$MC=9.73E-6 14$NC=2.18E-6 3 +144ND3 G OC=3.32E-7 5$IPC=0.000467 7 +144ND L 2582.32 6 (3)+ +144ND L 2655.54 3 1+ 9.9 FS 2 +144ND B 341.9 240.00018 3 8.8 1 +144NDS B EAV=98.68 8 +144ND G 2655.51 3 0.00018 3M1+E2 +144ND L 2675.61 8 0+ 0.2 PS 1 +144ND B 321.8 240.00096 8 8 +144NDS B EAV=92.21 8 +144ND G 1979.04 8 0.00096 8E2 8.68E-413 +144ND2 G KC=0.000505 7$LC=6.47E-5 9$MC=1.360E-5 19$NC=3.04E-6 5 +144ND3 G OC=4.64E-7 7$IPC=0.000281 4 +144ND L 2742.99 7 0+ 64 FS 40 +144ND B 254.4 240.00035 6 8.1 +144NDS B EAV=71.05 8 +144ND G 1182.06 7 0.00006 3E2 1587E-623 +144ND2 G KC=0.001353 19$LC=0.000182 3$MC=3.84E-5 6$NC=8.57E-6 12 +144ND3 G OC=1.295E-6 19$IPC=4.10E-6 6 +144ND G 2046.41 7 0.00030 6E2 8.65E-413 +144ND2 G KC=0.000475 7$LC=6.07E-5 9$MC=1.277E-5 18$NC=2.86E-6 4 +144ND3 G OC=4.35E-7 6$IPC=0.000313 5 +144ND L 2946.04 10(2,3,4)- + diff --git a/HEN_HOUSE/spectra/lnhb/Pr-144m.txt b/HEN_HOUSE/spectra/lnhb/Pr-144m.txt index 6736a7399..f37b58fd8 100644 --- a/HEN_HOUSE/spectra/lnhb/Pr-144m.txt +++ b/HEN_HOUSE/spectra/lnhb/Pr-144m.txt @@ -1,97 +1,100 @@ -144PR 144PR IT DECAY (7.2 M) -144PR H TYP=FUL$AUT=A.L. Nichols$CUT=01-APR-2014$ -144PR C Evaluation history: Type=FUL;Author=A.L. Nichols;Cutoff date=01-APR-2014 -144PR C References: 1960Ge05, 1968Ra01, 1968Sa05, 1969Ge01, 1970An15, 1970Fa03, -144PR2C 1974Be09, 1976CoZX, 1976Ra22, 1977La19, 1979Pr11, 1979Gr01, 1985Da16, -144PR3C 1994Ro13, 1996Sc06, 1998Hi09, 1998ScZM, 1999ScZX, 2000Sc47, 2000He14, -144PR4C 2001So16, 2002Ra45, 2002Ba85, 2008Ki07, 2012Wa38 -144PR T Auger electrons and X ray energies and emission intensities: -144PR T {U Energy (keV)} {U Intensity} {U Line} -144PR T -144PR T 33.5506 8.66 19 XKA2 -144PR T 36.0267 15.8 4 XKA1 -144PR T -144PR T 40.6533 |] XKB3 -144PR T 40.7487 |] 4.81 12 XKB1 -144PR T 41.05 |] XKB5II -144PR T -144PR T 41.774 |] XKB2 -144PR T 41.877 |] 1.23 4 XKB4 -144PR T 41.968 |] XKO23 -144PR T -144PR T 4.453-6.617 10.5 5 XL (total) -144PR T 4.453 0.227 7 XLL -144PR T 5.013-5.033 5.74 16 XLA -144PR T 4.929 0.0498 15 XLC -144PR T 5.489-5.851 3.89 7 XLB -144PR T 6.327-6.617 0.625 13 XLG -144PR T -144PR T 28.162-29.89 |] KLL AUGER -144PR T 33.576-36.004 |] 2.87 15 KLX AUGER -144PR T 38.97-41.95 |] KXY AUGER -144PR T 2.9-4.91 69 10 L AUGER -144PR P 59.03 3 3- 7.2 M 2 -144PR N 1.001E0 1.001E0 0.9994 2 1.001E0 -144PR L 0 0 0- 17.29 M 4 -144PR L 59.03 3 3- 7.2 M 2 -144PR G 59.03 3 0.0818 12M3 1221 18 -144PR2 G KC=408 6$LC=618 9$MC=155.0 23 - -144ND 144PR B- DECAY (7.2 M) -144ND H TYP=FUL$AUT=A.L. Nichols$CUT=01-APR-2014$ -144ND C Evaluation history: Type=FUL;Author=A.L. Nichols;Cutoff date=01-APR-2014 -144ND C References: 1960Ge05, 1968Ra01, 1968Sa05, 1969Ge01, 1970An15, 1970Fa03, -144ND2C 1974Be09, 1976CoZX, 1976Ra22, 1977La19, 1979Pr11, 1979Gr01, 1985Da16, -144ND3C 1994Ro13, 1996Sc06, 1998Hi09, 1998ScZM, 1999ScZX, 2000Sc47, 2000He14, -144ND4C 2001So16, 2002Ra45, 2002Ba85, 2008Ki07, 2012Wa38 -144ND T Auger electrons and X ray energies and emission intensities: -144ND T {U Energy (keV)} {U Intensity} {U Line} -144ND T -144ND T 36.8478 0.00011923 XKA2 -144ND T 37.3614 0.00022 5 XKA1 -144ND T -144ND T 42.167 |] XKB3 -144ND T 42.2717 |] 0.00006713 XKB1 -144ND T 42.58 |] XKB5II -144ND T -144ND T 43.335 |] XKB2 -144ND T 43.451 |] 0.000017 4 XKB4 -144ND T 43.548 |] XKO23 -144ND T -144ND T -144ND T 29.154-30.978 |] KLL AUGER -144ND T 34.798-37.34 |] 0.000038 8 KLX AUGER -144ND T 40.42-43.53 |] KXY AUGER -144ND T 3.01-5.1 0.00040 5 L AUGER -144PR P 59.03 3 3- 7.2 M 2 2997.4 24 -144ND N 1.667E3 1.667E3 0.0006 2 1.667E3 -144ND L 0 0 0+ 2.3E15 Y 3 -144ND L 696.561 102+ -144ND G 696.505 4 0.06 2E2 0.00507 7 -144ND2 G KC=0.00427 6$LC=6.31E-4 9$MC=1348E-7 19 -144ND L 1314.669 134+ 7.4 PS 9 -144ND G 618.107 160.030 3E2 0.0067910 -144ND2 G KC=0.00568 8$LC=8.69E-4 13$MC=1.86E-4 3 -144ND L 1510.871 213- 0.56 PS 7 -144ND B 1545.5 240.02 1 8.7 -144NDS B EAV=570.0 11 -144ND G 814.308 230.02 1E1 1391E-620 -144ND2 G KC=1198E-6 17$LC=1528E-7 22$MC=3.21E-5 5 -144ND L 1560.920 132+ -144ND L 2072.91 3 2+ 59 FS 10 -144ND L 2084.68 3 0+ 0.12 PS 5 -144ND L 2185.75 3 1- 15 FS 2 -144ND L 2368.82 4 2+ 39 FS 14 -144ND L 2582.32 6 (3)+ -144ND B 474.1 240.010 3 7.15 -144NDS B EAV=143.0 8 -144ND G 1885.75 6 0.010 3M1+E2 0.13 5 1052E-615 -144ND2 G KC=6.86E-4 10$LC=8.78E-5 13$MC=1.85E-5 3 -144ND L 2655.54 3 1+ 9.9 FS 2 -144ND L 2675.61 8 0+ 0.2 PS 1 -144ND L 2742.99 7 0+ 64 FS 40 -144ND L 2946.04 10(2,3,4)- -144ND B 110.4 240.030 3 4.65 -144NDS B EAV=29.0 7 -144ND G 1631.36 100.030 3 - +144PR 144PR IT DECAY (7.2 M) +144PR H TYP=FUL$AUT=A.L.NICHOLS$CUT=01-APR-2014$ +144PR C References:1960Ge05, 1968Ra01, 1968Sa05, 1969Ge01, 1970An15, 1970Fa03, +144PR2C 1974Be09, 1976Ch33, 1976CoZX, 1976Ra22, 1977La19, 1979Pr11, 1979Gr01, +144PR3C 1985Da16, 1994Ro13, 1996Sc06, 1998Hi09, 1998ScZM, 1999ScZX, 2000Sc47, +144PR4C 2000He14, 2001So16, 2002Ra45, 2002Ba85, 2008Ki07, 2012Wa38 +144PR T Auger electrons and X ray energies and emission intensities: +144PR T {U Energy (keV)} {U Intensity} {U Line} +144PR T +144PR T 33.5506 8.66 19 XKA2 +144PR T 36.0267 15.8 4 XKA1 +144PR T +144PR T 40.6533 |] XKB3 +144PR T 40.7487 |] 4.81 12 XKB1 +144PR T 41.05 |] XKB5II +144PR T +144PR T 41.774 |] XKB2 +144PR T 41.877 |] 1.23 4 XKB4 +144PR T 41.968 |] XKO23 +144PR T +144PR T 4.453-6.617 10.5 5 XL (total) +144PR T 4.453 0.227 7 XLL +144PR T 5.013-5.033 5.74 16 XLA +144PR T 4.929 0.0498 15 XLC +144PR T 5.489-5.851 3.89 7 XLB +144PR T 6.327-6.617 0.625 13 XLG +144PR T +144PR T 28.162-29.89 |] KLL AUGER +144PR T 33.576-36.004 |] 2.87 15 KLX AUGER +144PR T 38.97-41.95 |] KXY AUGER +144PR T 2.9-4.91 69 10 L AUGER +144PR P 59.03 3 3- 7.2 M 2 +144PR N 1.001E0 1.001E0 0.9994 2 +144PR L 0 0- 17.29 M 4 +144PR L 59.03 3 3- 7.2 M 2 +144PR G 59.03 3 0.0818 12M3 1221 18 +144PR2 G KC=408 6$LC=618 9$MC=155.0 23$NC=34.7 5 +144PR3 G OC=5.03 8 + +144ND 144PR B- DECAY (7.2 M) +144ND H TYP=FUL$AUT=A.L.NICHOLS$CUT=01-APR-2014$ +144ND C References:1960Ge05, 1968Ra01, 1968Sa05, 1969Ge01, 1970An15, 1970Fa03, +144ND2C 1974Be09, 1976Ch33, 1976CoZX, 1976Ra22, 1977La19, 1979Pr11, 1979Gr01, +144ND3C 1985Da16, 1994Ro13, 1996Sc06, 1998Hi09, 1998ScZM, 1999ScZX, 2000Sc47, +144ND4C 2000He14, 2001So16, 2002Ra45, 2002Ba85, 2008Ki07, 2012Wa38 +144ND T Auger electrons and X ray energies and emission intensities: +144ND T {U Energy (keV)} {U Intensity} {U Line} +144ND T +144ND T 36.8478 0.00011923 XKA2 +144ND T 37.3614 0.00022 5 XKA1 +144ND T +144ND T 42.167 |] XKB3 +144ND T 42.2717 |] 0.00006713 XKB1 +144ND T 42.58 |] XKB5II +144ND T +144ND T 43.335 |] XKB2 +144ND T 43.451 |] 0.000017 4 XKB4 +144ND T 43.548 |] XKO23 +144ND T +144ND T +144ND T 29.154-30.978 |] KLL AUGER +144ND T 34.798-37.34 |] 0.000038 8 KLX AUGER +144ND T 40.42-43.53 |] KXY AUGER +144ND T 3.01-5.1 0.00040 5 L AUGER +144PR P 59.03 3 3- 7.2 M 2 2997.4 24 +144ND N 1.667E3 1.667E3 0.0006 21.667E3 +144ND L 0 0+ 2.29E15 Y 16 +144ND L 696.561 102+ +144ND G 696.505 4 0.06 2E2 0.00507 7 +144ND2 G KC=0.00427 6$LC=0.000631 9$MC=1.348E-4 19$NC=3.00E-5 5 +144ND3 G OC=4.45E-6 7 +144ND L 1314.669 134+ 7.4 PS 9 +144ND G 618.107 160.030 3E2 0.0067910 +144ND2 G KC=0.00568 8$LC=0.000869 13$MC=0.000186 3$NC=4.13E-5 6 +144ND3 G OC=6.10E-6 9 +144ND L 1510.871 213- 0.56 PS 7 +144ND B 1545.5 240.02 1 8.7 +144NDS B EAV=570.0 11 +144ND G 814.308 230.02 1E1 1391E-620 +144ND2 G KC=0.001198 17$LC=1.528E-4 22$MC=3.21E-5 5$NC=7.17E-6 10 +144ND3 G OC=1.087E-6 16 +144ND L 1560.920 132+ +144ND L 2072.91 3 2+ 59 FS 10 +144ND L 2084.68 3 0+ 0.12 PS 5 +144ND L 2185.75 3 1- 15 FS 2 +144ND L 2368.82 4 2+ 39 FS 14 +144ND L 2582.32 6 (3)+ +144ND B 474.1 240.010 3 7.15 +144NDS B EAV=143.0 8 +144ND G 1885.75 6 0.010 3M1+E2 0.13 5 1052E-615 +144ND2 G KC=0.000686 10$LC=8.78E-5 13$MC=1.85E-5 3$NC=4.14E-6 6 +144ND3 G OC=6.33E-7 9$IPC=0.000255 4 +144ND L 2655.54 3 1+ 9.9 FS 2 +144ND L 2675.61 8 0+ 0.2 PS 1 +144ND L 2742.99 7 0+ 64 FS 40 +144ND L 2946.04 10(2,3,4)- +144ND B 110.4 240.030 3 4.65 +144NDS B EAV=29.0 7 +144ND G 1631.36 100.030 3 + diff --git a/HEN_HOUSE/spectra/lnhb/Pu-238.txt b/HEN_HOUSE/spectra/lnhb/Pu-238.txt index ff84840bd..a8ec155a6 100644 --- a/HEN_HOUSE/spectra/lnhb/Pu-238.txt +++ b/HEN_HOUSE/spectra/lnhb/Pu-238.txt @@ -1,136 +1,167 @@ -234U 238PU A DECAY (87.74 Y) -234U H TYP=Update$AUT=V. Chechev$CUT= -- $ -234U C Evaluation history: Type=Update;Author=V. Chechev;Cutoff date= -- -234U C References: 1949Jaf., 1950Jaf., 1952Se67, 1954Jo10, 1954As07, 1955Ch02, -234U 2C 1956Ne17, 1957Ho71, 1957Ko33, 1961Dr04, 1962Le11, 1963Bj03, 1964Le22, -234U 3C 1964Ha14, 1964Le17, 1968By01, 1968Ba25, 1969Am02, 1969LeZX, 1970Ba72, -234U 4C 1971Cl03, 1971So15, 1971Ma68, 1971Gr17, 1971GuZY, 1972Ha11, 1972Sc01, -234U 5C 1974StYG, 1975GaZX, 1976Um01, 1976GuZN, 1976Va23, 1976Po08, 1977Di04, -234U 6C 1977La19, 1978Ro22, 1979Ce04, 1981Ag06, 1982Ba56, 1983Ah02, 1984DrZX, -234U 7C 1984Ov01, 1984He19, 1984Bo41, 1984BaYT, 1984Ah06, 1987Bo25, 1988SeZY, -234U 8C 1990Po14, 1991Jo02, 1991Ry01, 1994Le37, 1994Ba91, 1995Jo23, 1996Sc06, -234U 9C 1998Ya17, 2000He14, 2000Ho27, 2000Ni13, 2003Au03, 2007Br04, 2008Ki07 -234U T Auger electrons and X ray energies and emission intensities: -234U T {U Energy (keV)} {U Intensity} {U Line} -234U T -234U T 94.666 0.000106 3 XKA2 -234U T 98.44 0.000169 5 XKA1 -234U T -234U T 110.421 |] XKB3 -234U T 111.298 |] 6.09E-5 22 XKB1 -234U T 111.964 |] XKB5II -234U T -234U T 114.407 |] XKB2 -234U T 115.012 |] 2.08E-5 6 XKB4 -234U T 115.377 |] XKO23 -234U T -234U T 11.619-20.714 10.63 8 XL (total) -234U T 11.619 0.235 4 XLL -234U T 13.438-13.615 3.80 3 XLA -234U T 15.399 0.119 5 XLC -234U T 15.727-18.206 5.19 4 XLB -234U T 19.507-20.714 1.28 1 XLG -234U T -234U T 71.78-80.95 |] KLL AUGER -234U T 88.15-98.43 |] 1.10E-5 15 KLX AUGER -234U T 104.51-115.59 |] KXY AUGER -234U T 5.9-21.6 10.6 4 L AUGER -238PU P 0.0 0+ 87.74 Y 3 5593.20 19 -234U N 1.0 1.0 1 1.0 -234U L 0 0+ 2.455E5 Y 60 -234U A 5499.03 2071.04 6 1 -234U L 43.4981 102+ 0.252 NS 7 -234U A 5456.3 2 28.85 6 1.39 -234U G 43.498 1 0.0397 8E2 713 15 -234U 2 G LC=520 11$MC=143.5 29 -234U L 143.352 4 4+ -234U A 5358.1 2 0.104 3 102 -234U G 99.852 3 0.00735 8E2 13.42 27 -234U 2 G LC=9.77 20$MC=2.71 6 -234U L 296.072 4 6+ -234U A 5208.0 2 0.00292 4 440 -234U G 152.719 2 0.000930 7E2 2.14 4 -234U 2 G KC=0.217 4$LC=1.404 28$MC=0.388 8 -234U L 497.04 3 8+ -234U A 5010.4 2 68000E-12310000 -234U G 200.97 3 3.92E-6 13E2 0.734 15 -234U 2 G KC=0.1534 31$LC=0.424 9$MC=0.1166 23 -234U L 786.288 161- -234U A 4726.0 2 82100E-11689 -234U G 742.813 5 5.10E-6 13E1 0.0063613 -234U 2 G KC=0.00518 10$LC=8.95E-4 18$MC=2.13E-4 4 -234U G 786.27 3 3.20E-6 9E1 0.0057312 -234U 2 G KC=0.00467 9$LC=8.04E-4 16$MC=1.91E-4 4 -234U L 809.907 180+ -234U A 4702.8 2 0.0001 5 -234U G 766.38 2 2.19E-5 5E2 0.0187 4 -234U 2 G KC=0.01336 27$LC=0.00396 8$MC=1003E-6 20 -234U G 810.0 5 -234U L 849.266 183- -234U A 4664.1 2 75000E-1223400 -234U G 705.9 1 5.0E-8 13[E1] 0.0069814 -234U 2 G KC=0.00568 12$LC=9.87E-4 20$MC=2.35E-4 5 -234U G 805.80 5 5.6E-8 15[E1] 0.0054911 -234U 2 G KC=0.00447 9$LC=7.68E-4 16$MC=1.83E-4 4 -234U L 851.74 3 2+ 1.74 PS -234U A 4661.7 2 81000E-1 30.5 -234U G 41.82 113.0E-9 16[E2] 863 18 -234U 2 G LC=630 13$MC=174 4 -234U G 708.3 2 4.9E-7 3[E2] 0.0219 5 -234U 2 G KC=0.01537 31$LC=0.00489 10$MC=1246E-6 25 -234U G 808.2 1 7.67E-7 25+E2 4.3 -234U 2 G KC=3.31 $LC=0.94 -234U G 851.7 1 1.27E-6 4[E2] 0.0151330 -234U 2 G KC=0.01109 22$LC=0.00302 6$MC=7.59E-4 16 -234U L 926.720 152+ 1.38 PS 17 -234U A 4587.9 2 13000E-15 53 -234U G 783.4 1 2.2E-8 3[E2] 0.0179 4 -234U 2 G KC=0.01285 26$LC=0.00374 8$MC=9.46E-4 19 -234U G 883.24 4 7.2E-7 4E2 0.0140928 -234U 2 G KC=0.01040 21$LC=0.00276 6$MC=6.92E-4 14 -234U G 926.72 1 5.58E-7 25(E2) 0.0128426 -234U 2 G KC=0.00956 20$LC=0.00245 5$MC=6.13E-4 12 -234U L 947.64 6 4+ -234U A 4567.4 2 23000E-1 21 -234U G 804.4 3 1.1E-7 5+E2 0.57 -234U G 904.37 156.1E-8 11[E2] 0.0134627 -234U 2 G KC=0.00998 20$LC=0.00260 5$MC=6.52E-4 13 -234U L 989.430 132- 0.76 NS 4 -234U A 4526.3 2 15000E-116155 -234U G 62.70 1 1.1E-8 3E1 0.426 9 -234U 2 G LC=0.320 7$MC=0.0791 16 -234U G 140.15 2 3.5E-9 7M1+E2 1.3 5 5.1 15 -234U 2 G KC=2.6 8$LC=1.79 5$MC=0.48 14 -234U G 203.12 3 8.5E-9 15M1+E2 1.4 4 1.5 3 -234U 2 G KC=0.90 17$LC=0.423 9$MC=0.1113 23 -234U G 946.00 3 9.2E-8 13(E1) 0.00412 8 -234U 2 G KC=0.00337 7$LC=5.71E-4 12$MC=1355E-7 27 -234U L 1023.77 3 4+ -234U A 4492.5 2 20000E-1 64 -234U G 727.8 2 2.7E-9 3(E2) 0.0207 4 -234U 2 G KC=0.01464 29$LC=0.00454 9$MC=1156E-6 23 -234U G 880.5 1 1.5E-7 4(+E2) -234U G 980.3 1 4.2E-8 (E2) 0.0115223 -234U 2 G KC=0.00866 18$LC=0.00214 4$MC=5.34E-4 11 -234U L 1044.536 230+ -234U A 4472.1 2 11700E-17 7.5 -234U G 192.91 7 66E-11 20[E2] 0.856 17 -234U 2 G KC=0.1635 33$LC=0.505 10$MC=0.1391 28 -234U G 234.6 2 -234U G 258.227 3 7.0E-8 11(E1) 0.0548 11 -234U 2 G KC=0.0434 9$LC=0.00859 17$MC=0.00207 4 -234U G 1001.03 3 9.8E-7 4E2 0.0110722 -234U 2 G KC=0.00835 17$LC=0.00204 4$MC=5.07E-4 11 -234U L 1085.26 4 2+ -234U A 4432.1 2 12000E-1 3.5 -234U G 233.6 2 (+E2) -234U G 235.9 3 9E-9 5[E1] 0.0673 14 -234U 2 G KC=0.0532 11$LC=0.01067 21$MC=0.00258 5 -234U G 299.1 2 4.4E-8 3[E1] 0.0395 8 -234U 2 G KC=0.0314 6$LC=0.00608 12$MC=1466E-6 29 -234U G 941.94 104.66E-7 23[E2] 0.0124425 -234U 2 G KC=0.00929 20$LC=0.00236 5$MC=5.89E-4 12 -234U G 1041.7 2 1.97E-7 16(+E2) -234U G 1085.4 2 7.7E-8 9(E2) 0.0095019 -234U 2 G KC=0.00725 15$LC=0.00169 3$MC=4.18E-4 8 - +234U 238PU A DECAY (87.74 Y) +234U H TYP=UPD$AUT=V.P.CHECHEV$CUT=30-JUN-2009$ +234U C References:1949Ja**, 1950Ja**, 1951Ja**, 1951Ja**, 1951Se**, 1952Se67, +234U 2C 1954Jo10, 1954As07, 1955Ch02, 1956Ne17, 1957Ho71, 1957Ko33, 1961Dr04, +234U 3C 1962Le11, 1963Bj03, 1964Le22, 1964Ha14, 1964Le17, 1965Ei**, 1967Jo**, +234U 4C 1968By01, 1968Sa**, 1968Sw**, 1968Ba25, 1969Am02, 1969Be**, 1969LeZX, +234U 5C 1970Ba72, 1971Cl03, 1971Sw**, 1971So15, 1971Ma68, 1971Gr17, 1971GuZY, +234U 6C 1972Ha11, 1972Sc01, 1974StYG, 1975GaZX, 1976Um01, 1976GuZN, 1976Va23, +234U 7C 1976Po08, 1977Be**, 1977Di04, 1977La19, 1978Ro22, 1979Va**, 1979Ce04, +234U 8C 1981Se**, 1981Ag06, 1982Ba56, 1983Ah02, 1984DrZX, 1984Ov01, 1984He19, +234U 9C 1984Bo41, 1984BaYT, 1984Ah06, 1984Bu**, 1987Bo25, 1988SeZY, 1990Po14, +234U AC 1991Jo02, 1991Ry01, 1994Le37, 1994Ba91, 1995Jo23, 1996Sc06, 1998Ya17, +234U BC 1999Sc**, 2000He14, 2000Ho27, 2000Ni13, 2000Sc**, 2003Au03, 2007Br04, +234U CC 2008Ki07 +234U T Auger electrons and X ray energies and emission intensities: +234U T {U Energy (keV)} {U Intensity} {U Line} +234U T +234U T 94.666 0.000106 3 XKA2 +234U T 98.44 0.000169 5 XKA1 +234U T +234U T 110.421 |] XKB3 +234U T 111.298 |] 6.09E-5 22 XKB1 +234U T 111.964 |] XKB5II +234U T +234U T 114.407 |] XKB2 +234U T 115.012 |] 2.08E-5 6 XKB4 +234U T 115.377 |] XKO23 +234U T +234U T 11.619-20.714 10.63 8 XL (total) +234U T 11.619 0.235 4 XLL +234U T 13.438-13.615 3.80 3 XLA +234U T 15.399 0.119 5 XLC +234U T 15.727-18.206 5.19 4 XLB +234U T 19.507-20.714 1.28 1 XLG +234U T +234U T 71.78-80.95 |] KLL AUGER +234U T 88.15-98.43 |] 1.10E-5 15 KLX AUGER +234U T 104.51-115.59 |] KXY AUGER +234U T 5.9-21.6 10.6 4 L AUGER +238PU P 0.0 0+ 87.74 Y 3 5593.20 19 +234U N 1.0 1.0 1 +234U L 0 0+ 2.455E5 Y 60 +234U A 5499.03 2071.04 61 +234U L 43.4981 102+ 0.252 NS 7 +234U A 5456.3 2 28.85 61.39 +234U G 43.498 1 0.0397 8E2 713 15 +234U 2 G LC=520 11$MC=143.5 29$NC=38.9 8 +234U 3 G OC=8.91 18 +234U L 143.352 4 4+ +234U A 5358.1 2 0.104 3102 +234U G 99.852 3 0.00735 8E2 13.42 27 +234U 2 G LC=9.77 20$MC=2.71 6$NC=0.736 15 +234U 3 G OC=0.1691 34 +234U L 296.072 4 6+ +234U A 5208.0 2 0.00292 4440 +234U G 152.719 2 0.000930 7E2 2.14 4 +234U 2 G KC=0.217 4$LC=1.404 28$MC=0.388 8$NC=0.1055 22 +234U 3 G OC=0.0243 5 +234U L 497.04 3 8+ +234U A 5010.4 2 6.80E-6 2310000 +234U G 200.97 3 3.92E-6 13E2 0.734 15 +234U 2 G KC=0.1534 31$LC=0.424 9$MC=0.1166 23$NC=0.0317 6 +234U 3 G OC=0.00731 15 +234U L 786.288 161- +234U A 4726.0 2 8.21E-6 1689 +234U G 742.813 5 5.10E-6 13E1 0.0063613 +234U 2 G KC=0.00518 10$LC=0.000895 18$MC=0.000213 4$NC=5.71E-5 12 +234U 3 G OC=1.378E-5 30 +234U G 786.27 3 3.20E-6 9E1 0.0057312 +234U 2 G KC=0.00467 9$LC=0.000804 16$MC=0.000191 4$NC=5.12E-5 10 +234U 3 G OC=1.237E-5 25 +234U L 809.907 180+ +234U A 4702.8 2 0.0001 5 +234U G 766.38 2 2.19E-5 5E2 0.0187 4 +234U 2 G KC=0.01336 27$LC=0.00396 8$MC=0.001003 20$NC=0.000271 6 +234U 3 G OC=6.45E-5 13 +234U G 810.0 5 E0 +234U L 849.266 183- +234U A 4664.1 2 7.5E-8 223400 +234U G 705.9 1 5.0E-8 13[E1] 0.0069814 +234U 2 G KC=0.00568 12$LC=0.000987 20$MC=0.000235 5$NC=6.30E-5 13 +234U 3 G OC=1.519E-5 30 +234U G 805.80 5 5.6E-8 15[E1] 0.0054911 +234U 2 G KC=0.00447 9$LC=0.000768 16$MC=0.000183 4$NC=4.89E-5 10 +234U 3 G OC=1.181E-5 24 +234U L 851.74 3 2+ 1.74 PS +234U A 4661.7 2 8.1E-6 30.5 +234U G 41.82 113.0E-9 16[E2] 863 18 +234U 2 G LC=630 13$MC=174 4$NC=47.1 9 +234U 3 G OC=10.79 21 +234U G 708.3 2 4.9E-7 3[E2] 0.0219 5 +234U 2 G KC=0.01537 31$LC=0.00489 10$MC=0.001246 25$NC=0.000337 7 +234U 3 G OC=8.00E-5 16 +234U G 808.2 1 7.67E-7 25E0+E2 4.3 +234U 2 G KC=3.31 $LC=0.94 +234U G 851.7 1 1.27E-6 4[E2] 0.0151330 +234U 2 G KC=0.01109 22$LC=0.00302 6$MC=0.000759 16$NC=0.000205 4 +234U 3 G OC=4.89E-5 10 +234U L 926.720 152+ 1.38 PS 17 +234U A 4587.9 2 1.30E-6 553 +234U G 783.4 1 2.2E-8 3[E2] 0.0179 4 +234U 2 G KC=0.01285 26$LC=0.00374 8$MC=0.000946 19$NC=0.000255 5 +234U 3 G OC=6.08E-5 12 +234U G 883.24 4 7.2E-7 4E2 0.0140928 +234U 2 G KC=0.01040 21$LC=0.00276 6$MC=0.000692 14$NC=0.000187 4 +234U 3 G OC=4.46E-5 9 +234U G 926.72 1 5.58E-7 25(E2) 0.0128426 +234U 2 G KC=0.00956 20$LC=0.00245 5$MC=0.000613 12$NC=1.653E-4 33 +234U 3 G OC=3.95E-5 8 +234U L 947.64 6 4+ +234U A 4567.4 2 2.3E-7 21 +234U G 804.4 3 1.1E-7 5E0+E2 0.57 +234U G 904.37 156.1E-8 11[E2] 0.0134627 +234U 2 G KC=0.00998 20$LC=0.00260 5$MC=0.000652 13$NC=1.757E-4 35 +234U 3 G OC=4.20E-5 9 +234U L 989.430 132- 0.76 NS 4 +234U A 4526.3 2 1.50E-7 16155 +234U G 62.70 1 1.1E-8 3E1 0.426 9 +234U 2 G LC=0.320 7$MC=0.0791 16$NC=0.0209 3 +234U 3 G OC=0.00481 7 +234U G 140.15 2 3.5E-9 7M1+E2 1.3 5 5.1 15 +234U 2 G KC=2.6 8$LC=1.79 5$MC=0.48 14$NC=0.129 17 +234U 3 G OC=0.030 4 +234U G 203.12 3 8.5E-9 15M1+E2 1.4 4 1.5 3 +234U 2 G KC=0.90 17$LC=0.423 9$MC=0.1113 23$NC=0.0301 5 +234U 3 G OC=0.00709 11 +234U G 946.00 3 9.2E-8 13(E1) 0.00412 8 +234U 2 G KC=0.00337 7$LC=0.000571 12$MC=1.355E-4 27$NC=3.63E-5 7 +234U 3 G OC=8.78E-6 18 +234U L 1023.77 3 4+ +234U A 4492.5 2 2E-7 64 +234U G 727.8 2 2.7E-9 3(E2) 0.0207 4 +234U 2 G KC=0.01464 29$LC=0.00454 9$MC=0.001156 23$NC=0.000312 6 +234U 3 G OC=7.42E-5 15 +234U G 880.5 1 1.5E-7 4(E0+E2) +234U G 980.3 1 4.2E-8 (E2) 0.0115223 +234U 2 G KC=0.00866 18$LC=0.00214 4$MC=0.000534 11$NC=1.439E-4 29 +234U 3 G OC=3.45E-5 7 +234U L 1044.536 230+ +234U A 4472.1 2 1.17E-6 77.5 +234U G 192.91 7 66E-11 20[E2] 0.856 17 +234U 2 G KC=0.1635 33$LC=0.505 10$MC=0.1391 28$NC=0.0378 8 +234U 3 G OC=0.00872 18 +234U G 234.6 2 E0 +234U G 258.227 3 7.0E-8 11(E1) 0.0548 11 +234U 2 G KC=0.0434 9$LC=0.00859 17$MC=0.00207 4$NC=0.000554 11 +234U 3 G OC=1.321E-4 27 +234U G 1001.03 3 9.8E-7 4E2 0.0110722 +234U 2 G KC=0.00835 17$LC=0.00204 4$MC=0.000507 11$NC=1.367E-4 30 +234U 3 G OC=3.28E-5 7 +234U L 1085.26 4 2+ +234U A 4432.1 2 1.2E-6 3.5 +234U G 233.6 2 (E0+E2) +234U G 235.9 3 9E-9 5[E1] 0.0673 14 +234U 2 G KC=0.0532 11$LC=0.01067 21$MC=0.00258 5$NC=0.000689 14 +234U 3 G OC=1.639E-4 33 +234U G 299.1 2 4.4E-8 3[E1] 0.0395 8 +234U 2 G KC=0.0314 6$LC=0.00608 12$MC=0.001466 29$NC=0.000392 8 +234U 3 G OC=9.36E-5 19 +234U G 941.94 104.66E-7 23[E2] 0.0124425 +234U 2 G KC=0.00929 20$LC=0.00236 5$MC=0.000589 12$NC=1.587E-4 32 +234U 3 G OC=3.80E-5 8 +234U G 1041.7 2 1.97E-7 16(E0+E2) +234U G 1085.4 2 7.7E-8 9(E2) 0.0095019 +234U 2 G KC=0.00725 15$LC=0.00169 3$MC=0.000418 8$NC=1.127E-4 23 +234U 3 G OC=2.71E-5 6 + diff --git a/HEN_HOUSE/spectra/lnhb/Pu-239.txt b/HEN_HOUSE/spectra/lnhb/Pu-239.txt index 9440b4dac..72503e506 100644 --- a/HEN_HOUSE/spectra/lnhb/Pu-239.txt +++ b/HEN_HOUSE/spectra/lnhb/Pu-239.txt @@ -1,510 +1,510 @@ -235U 239PU A DECAY (24100 Y) -235U H TYP=Full$AUT=V.P. Chechev$CUT=31-JAN-2007$ -235U C Evaluation history: Type=Full;Author=V.P. Chechev;Cutoff date=31-JAN-2007 -235U C References: 1952As28, 1952Se67, 1957As83, 1957No15, 1961Dz05, 1962Le11, -235U 2C 1963Bj03, 1963Ba09, 1965Ho04, 1965Tr03, 1966Ah02, 1966Ho09, 1967Be65, -235U 3C 1968Cl02, 1968Ba25, 1970OeZZ, 1971GuZY, 1975Ba65, 1975Al15, 1975GlZQ, -235U 4C 1976GuZN, 1976BaZZ, 1977Ja08, 1978Lu10, 1978Ma45, 1978Pr07, 1978Se12, -235U 5C 1979Al03, 1980RyZX, 1981AhZV, 1981UmZZ, 1982Ba56, 1982He02, 1983Ah02, -235U 6C 1984Di08, 1984Iw02, 1984Bo41, 1984Ah06, 1985Dr09, 1986Mi10, 1987Bo25, -235U 7C 1988ChZL, 1989Ho24, 1990GlZZ, 1990An33, 1991Ry01, 1992Bl07, 1992Bl13, -235U 8C 1992Co10, 1992Fr04, 1992Ba08, 1993Ga28, 1993Sc22, 1994Mo36, 1994Ra27, -235U 9C 1994Le37, 1994Le28, 1995Jo23, 1996Sa24, 1996Sc06, 1996Vi07, 1997Bu23, -235U 10C 1997Ko52, 1999ScZX, 1999Sa19, 2002Da21, 2002Ba85, 2003Au03, 2003Br12 -235U T Auger electrons and X ray energies and emission intensities: -235U T {U Energy (keV)} {U Intensity} {U Line} -235U T -235U T 94.666 0.00418 4 XKA2 -235U T 98.44 0.00661 9 XKA1 -235U T -235U T 110.421 |] XKB3 -235U T 111.298 |] 0.00239 3 XKB1 -235U T 111.964 |] XKB5II -235U T -235U T 114.407 |] XKB2 -235U T 115.012 |] 0.00131 6 XKB4 -235U T 115.377 |] XKO23 -235U T -235U T 11.619-20.714 4.66 5 XL (total) -235U T 11.619 0.1008 11 XLL -235U T 13.438-13.615 1.65 3 XLA -235U T 15.399 0.0537 19 XLC -235U T 15.727-18.206 2.288 23 XLB -235U T 19.507-20.714 0.569 6 XLG -235U T -235U T 71.78-80.95 |] KLL AUGER -235U T 88.15-98.34 |] 0.00045 6 KLX AUGER -235U T 104.42-115.4 |] KXY AUGER -235U T 5.9-21.6 4.66 19 L AUGER -239PU P 0.0 1/2+ 24100 Y 11 5244.51 21 -235U N 1.0 1.0 1 1.0 -235U G 14.22 3 0.0055 4 -235U G 40.41 5 0.00016316 -235U G 74.96 100.000038 6 -235U G 184.55 5 2.1E-6 6[M1] 3.87 8 -235U G 193.13 129.0E-6 9 -235U G 196.87 5 3.7E-6 4 -235U G 350.8 3 1.8E-6 4 -235U G 446.82 208.5E-7 13 -235U G 497.0 5 4.4E-8 25 -235U G 538.8 2 3.09E-7 19 -235U G 557.3 5 3.8E-8 19 -235U G 608.9 2 1.17E-7 12 -235U G 650.53 6 2.7E-7 4 -235U G 685.97 111.26E-6 6E1 0.0073615 -235U G 688.1 3 1.12E-7 11 -235U G 693.2 5 3.2E-8 13 -235U G 699.6 5 8.0E-8 16 -235U G 712.96 5 5.2E-8 6 -235U G 742.7 5 3.8E-8 11 -235U G 777.1 3 2.8E-8 7 -235U G 786.9 2 8.7E-8 9E2 0.0177 4 -235U G 788.5 3 3.5E-8 7 -235U G 796.9 3 1.5E-8 3 -235U G 803.2 2 6.4E-8 5 -235U G 826.8 3 1.8E-8 6 -235U G 828.9 2 1.34E-7 8 -235U G 837.3 2 2.0E-8 4 -235U G 895.4 3 7.6E-9 25 -235U G 898.1 3 1.8E-8 4 -235U G 905.5 3 7.6E-9 25 -235U G 911.7 3 1.4E-8 3 -235U G 931.9 3 1.3E-8 4 -235U G 982.7 3 1.07E-8 25 -235U G 1009.4 3 1.39E-8 25 -235U L 0 7/2- 704E6 Y 1 -235U A 5156.65 210.03 6500 -235U L 0.0765 4 1/2+ 26 M -235U A 5156.59 1470.79 102.762 -235U G 0.0765 4 1E-8 E3 10E9 -235U L 13.0400 213/2+ 0.50 NS 3 -235U A 5143.82 2117.14 4 9.47 -235U G 12.975 100.0341 9M1+()E2 607 17 -235U 2 G MC=451 13 -235U L 46.207 109/2- -235U A 5111.21 210.02 5019 -235U G 46.21 5 0.00072613M1+()E2 52.6 27 -235U 2 G LC=39.4 19$MC=9.8 5 -235U L 51.7007 115/2+ 191 PS 5 -235U A 5105.81 2111.87 3 7.81 -235U G 38.661 2 0.01047 21M1+()E2 339 19 -235U 2 G LC=249 14$MC=67 4 -235U G 51.624 1 0.02694 26E2 310 6 -235U 2 G LC=226 5$MC=62.6 13 -235U L 81.741 4 7/2+ -235U A 5076.28 210.052 8 1150 -235U G 30.04 2 0.000219 8(M1) 157 3 -235U 2 G LC=118.0 24$MC=28.7 6 -235U G 68.696 6 0.00036 10E2 78.6 16 -235U 2 G LC=57.3 11$MC=15.9 3 -235U L 103.035 1011/2- -235U A 5055.34 210.0375 121160 -235U G 56.828 3 0.00113615M1+()E2 32.6 15 -235U 2 G LC=24.3 11$MC=6.14 30 -235U G 103.06 3 0.000217 6E2 11.58 23 -235U 2 G LC=8.44 17$MC=2.34 5 -235U L 129.2961 105/2+ -235U A 5029.51 210.013 4 2270 -235U G 47.60 3 6.25E-5 25(M1) 40.4 8 -235U 2 G LC=30.4 6$MC=7.37 15 -235U G 77.592 140.000380 6M1(+()E2) 17 10 -235U 2 G LC=12 7$MC=3.2 21 -235U G 116.26 2 0.00058119M1+()E2 12.2 26 -235U 2 G KC=8.4 18$LC=2.9 6$MC=0.74 16 -235U G 129.296 1 0.00631 4E1 0.275 6 -235U 2 G KC=0.211 4$LC=0.0482 10$MC=0.01173 24 -235U L 150.467 159/2+ -235U A 5008.70 210.0182 271180 -235U G 68.73 2 0.00013 6(M1+E2) 27 -235U 2 G LC=20 $MC=5.2 -235U G 98.78 2 0.00135 11E2 14.1 3 -235U 2 G LC=10.28 21$MC=2.85 6 -235U L 170.708 1413/2- -235U G 67.674 120.000158 5M1+()E2 16.9 5 -235U 2 G LC=12.7 4$MC=3.15 9 -235U G 124.51 3 6.81E-5 19E2 5.06 10 -235U 2 G KC=0.214 4$LC=3.53 7$MC=0.978 20 -235U L 171.388 5 7/2+ -235U A 4988.13 210.0034 104600 -235U G 41.93 5 0.000163 8(M1) 58.6 12 -235U 2 G LC=44.2 9$MC=10.71 21 -235U G 89.64 3 0.000027 2(M1+E2) 14 8 -235U 2 G LC=11 6$MC=2.8 17 -235U G 119.70 3 0.000021 3(M1+E2) 9 4 -235U 2 G KC=5 5$LC=3.1 11$MC=0.8 3 -235U G 125.21 105.63E-5 16[E1] 0.296 6 -235U 2 G KC=0.227 5$LC=0.0523 10$MC=0.0128 3 -235U G 158.1 3 1.01E-6 10[E2] 1.86 4 -235U 2 G KC=0.211 4$LC=1.200 24$MC=0.333 7 -235U G 171.393 6 0.000110 3[E1] 0.141 3 -235U 2 G KC=0.1103 22$LC=0.0235 5$MC=0.00570 11 -235U L 197.119 1411/2+ -235U A 4962.83 210.007 1 1520 -235U G 46.68 3 0.000050 6M1+()E2 86 24 -235U 2 G LC=63 17$MC=17 5 -235U G 115.38 5 0.00046 5E2 6.87 14 -235U 2 G LC=5.0 1$MC=1.39 3 -235U L 225.423 8 9/2+ -235U A 4935.00 210.0050 7 1380 -235U G 54.039 8 1.943E-428M1 27.8 6 -235U 2 G LC=21.0 4$MC=5.08 10 -235U G 96.14 3 3.79E-5 19[E2] 16.0 3 -235U 2 G LC=11.67 23$MC=3.24 7 -235U G 122.35 129.5E-7 13(E1) 0.312 6 -235U 2 G KC=0.238 5$LC=0.0556 11$MC=0.0135 3 -235U G 143.35 201.74E-5 8[M1+E2] 5.3 26 -235U 2 G KC=3.3 30$LC=1.5 3$MC=0.41 11 -235U G 173.70 5 3.1E-6 8[E2] 1.28 3 -235U 2 G KC=0.190 4$LC=0.795 16$MC=0.220 4 -235U G 179.220 126.56E-5 19[E1] 0.127 3 -235U 2 G KC=0.0995 20$LC=0.0210 4$MC=0.00509 10 -235U G 225.42 4 1.50E-5 4[E1] 0.0747 15 -235U 2 G KC=0.0589 12$LC=0.01190 24$MC=0.00288 6 -235U L 249.130 1215/2- -235U A 4911.69 210.0030 161590 -235U G 78.43 2 1.533E-428M1(+()E2) 16 10 -235U 2 G LC=12 7$MC=3.1 20 -235U G 146.094 6 0.000121 3E2 2.57 5 -235U 2 G KC=0.223 4$LC=1.71 3$MC=0.474 10 -235U L 291.144 1911/2+ -235U A 4870.38 210.0007 3 3500 -235U G 65.708 304.73E-5 25M1+()E2 19 6 -235U 2 G LC=14 5$MC=3.6 13 -235U G 119.76 2 0.000009 2[E2] 5.99 12 -235U 2 G KC=0.200 4$LC=4.22 8$MC=1.169 23 -235U G 188.23 101.10E-5 11[E1] 0.1140 23 -235U 2 G KC=0.0889 18$LC=0.0186 4$MC=0.00450 9 -235U G 244.92 5 5.1E-6 5 0.0618 12 -235U 2 G KC=0.0485 10$LC=0.00973 19$MC=0.00235 5 -235U L 294.669 1513/2+ -235U A 4866.91 210.0018 5 1300 -235U G 97.6 3 0.00009 6M1+()E2 7.0 19 -235U 2 G LC=5.2 14$MC=1.3 4 -235U G 144.201 3 0.000285 7E2 2.72 5 -235U 2 G KC=0.225 5$LC=1.82 4$MC=0.502 10 -235U L 332.845 4 5/2+ -235U A 4829.38 210.00354 7 363 -235U G 161.450 150.000122 6(M1) 5.67 11 -235U 2 G KC=4.51 9$LC=0.880 18$MC=0.213 4 -235U G 203.550 5 0.000563 9M1 2.95 6 -235U 2 G KC=2.35 5$LC=0.456 9$MC=0.1103 22 -235U G 281.2 2 2.1E-6 3[M1+E2] 0.7 5 -235U 2 G KC=0.5 4$LC=0.14 4$MC=0.036 8 -235U G 319.68 104.9E-6 5[M1+E2] 0.50 35 -235U 2 G KC=0.37 30$LC=0.10 3$MC=0.024 7 -235U G 332.845 5 0.000488 8E1 0.0313 6 -235U 2 G KC=0.0250 5$LC=0.00476 10$MC=1150E-6 23 -235U L 338.52 6 17/2- -235U A 4823.80 2222000E-9 53000 -235U G 89.39 6 0.000002 [M1] 6.40 13 -235U 2 G LC=4.82 10$MC=1.167 23 -235U G 167.81 5 3.0E-6 8[E2] 1.47 3 -235U 2 G KC=0.198 4$LC=0.925 19$MC=0.256 5 -235U L 357.30 6 15/2+ -235U A 4805.33 2217000E-94 51000 -235U G 160.19 5 6.2E-6 13[E2] 1.77 4 -235U 2 G KC=0.208 4$LC=1.140 23$MC=0.314 6 -235U L 367.069 8 7/2+ -235U A 4795.73 2194400E-817788 -235U G 141.657 203.21E-5 10[M1] 8.22 16 -235U 2 G KC=6.52 13$LC=1.28 3$MC=0.309 6 -235U G 195.679 8 0.000106 2M1 3.30 7 -235U 2 G KC=2.62 5$LC=0.51 1$MC=0.123 3 -235U G 237.77 101.45E-5 6[M1] 1.91 4 -235U 2 G KC=1.52 3$LC=0.295 6$MC=0.0712 14 -235U G 285.3 2 1.9E-6 4[M1+E2] 0.7 5 -235U 2 G KC=0.5 4$LC=0.14 4$MC=0.035 8 -235U G 320.862 205.40E-5 12[E1] 0.0337 7 -235U 2 G KC=0.0269 5$LC=0.00517 10$MC=0.00125 3 -235U G 354.0 5 7.6E-7 30[E2] 0.1150 23 -235U 2 G KC=0.0549 11$LC=0.0445 9$MC=0.01200 24 -235U G 367.073 258.71E-5 20[E1] 0.0254 5 -235U 2 G KC=0.0203 4$LC=0.00382 8$MC=9.20E-4 18 -235U L 393.225 6 3/2+ -235U A 4770.01 210.00125 3 390 -235U G 263.95 3 2.59E-5 10M1 1.43 3 -235U 2 G KC=1.140 23$LC=0.220 4$MC=0.0532 11 -235U G 341.506 106.50E-5 13M1 0.701 14 -235U 2 G KC=0.559 11$LC=0.1080 22$MC=0.0260 5 -235U G 380.191 6 0.000302 4M1 0.523 10 -235U 2 G KC=0.417 8$LC=0.0801 16$MC=0.0193 4 -235U G 393.14 3 0.00041917M1 0.477 10 -235U 2 G KC=0.380 8$LC=0.0731 15$MC=0.0176 4 -235U L 414.779 119/2+ -235U A 4748.81 210.00075 11460 -235U G 123.62 5 2.37E-5 9[M1] 12.08 24 -235U 2 G KC=9.57 19$LC=1.89 4$MC=0.457 9 -235U G 189.36 1 8.20E-5 14[M1+E2] 2.3 14 -235U 2 G KC=1.5 13$LC=0.553 11$MC=0.143 8 -235U G 218.0 5 1.2E-6 10 -235U G 243.38 3 2.54E-5 7[M1+E2] 1.1 7 -235U 2 G KC=0.8 6$LC=0.23 4$MC=0.059 7 -235U G 311.78 4 2.57E-5 8[E1] 0.0361 7 -235U 2 G KC=0.0287 6$LC=0.00552 11$MC=0.00133 3 -235U G 368.554 208.77E-5 14[E1] 0.0252 5 -235U 2 G KC=0.0202 4$LC=0.00378 8$MC=9.10E-4 18 -235U L 426.755 3 5/2+ -235U A 4737.05 210.00570 5 49.6 -235U G 255.384 157.95E-5 20[M1] 1.57 3 -235U 2 G KC=1.25 3$LC=0.241 5$MC=0.0583 12 -235U G 297.46 3 4.92E-5 13[M1] 1.025 21 -235U 2 G KC=0.816 16$LC=0.158 3$MC=0.0381 8 -235U G 345.013 4 0.000548 8M1 0.682 14 -235U 2 G KC=0.543 11$LC=0.1050 21$MC=0.0253 5 -235U G 375.054 3 0.00154021M1 0.543 11 -235U 2 G KC=0.432 9$LC=0.0832 17$MC=0.0201 4 -235U G 413.713 5 0.00146421M1 0.415 8 -235U 2 G KC=0.331 7$LC=0.0636 13$MC=0.0153 3 -235U G 426.68 3 2.39E-5 6[E2] 0.0699 14 -235U 2 G KC=0.0387 8$LC=0.0230 5$MC=0.00610 12 -235U L 445.716 207/2+ -235U A 4718.39 2140000E-9115200 -235U G 316.41 3 1.33E-5 5M1 0.865 17 -235U 2 G KC=0.689 14$LC=0.133 3$MC=0.0321 6 -235U G 399.53 6 6.12E-6 26[E1] 0.0213 4 -235U 2 G KC=0.0171 3$LC=0.00317 6$MC=7.61E-4 15 -235U G 445.72 3 8.77E-6 26E1 0.0170 3 -235U 2 G KC=0.0137 3$LC=0.00250 5$MC=5.60E-4 11 -235U L 474.297 137/2+ -235U A 4690.29 210.00056 5 230 -235U G 248.95 5 7.0E-6 6[M1] 1.68 3 -235U 2 G KC=1.34 3$LC=0.259 5$MC=0.0626 14 -235U G 302.87 5 4.9E-6 4[M1] 0.976 20 -235U 2 G KC=0.777 16$LC=0.150 3$MC=0.0362 7 -235U G 323.84 3 5.30E-5 13M1 0.811 16 -235U 2 G KC=0.646 13$LC=0.1246 25$MC=0.0301 6 -235U G 345.00 2 0.00005 (M1) 0.682 14 -235U 2 G KC=0.543 11$LC=0.1050 21$MC=0.0253 5 -235U G 392.53 3 0.00012116M1 0.479 10 -235U 2 G KC=0.382 8$LC=0.0731 15$MC=0.0177 4 -235U G 422.598 191.199E-420M1 0.392 8 -235U 2 G KC=0.313 6$LC=0.0560 11$MC=0.0145 3 -235U G 428.4 3 1.01E-6 10[E1] 0.0184 4 -235U 2 G KC=0.0147 3$LC=0.00270 5$MC=6.53E-4 13 -235U G 461.25 5 2.29E-6 5[E2] 0.0575 12 -235U 2 G KC=0.0334 7$LC=0.0177 4$MC=0.00467 9 -235U G 473.9 5 6E-8 3[E1] 0.0150 3 -235U 2 G KC=0.01210 24$LC=0.00220 4$MC=5.26E-4 11 -235U L 509.92 17(9/2+)+ -235U A 4655.27 2733000E-17 22000 -235U G 406.8 2 2.9E-6 7[E1] 0.0204 4 -235U 2 G KC=0.0164 3$LC=0.00304 6$MC=7.31E-4 15 -235U G 463.9 3 2.8E-7 3[E1] 0.0157 3 -235U 2 G KC=0.0126 3$LC=0.00230 5$MC=5.51E-4 11 -235U L 533.228 109/2+ -235U A 4632.35 210.00086 3 55.8 -235U G 242.08 3 7.4E-6 5[M1] 1.82 4 -235U 2 G KC=1.45 3$LC=0.280 6$MC=0.0678 14 -235U G 307.85 5 5.2E-6 4[M1] 0.933 19 -235U 2 G KC=0.743 15$LC=0.143 3$MC=0.0346 7 -235U G 336.113 121.111E-426M1 0.733 15 -235U 2 G KC=0.583 12$LC=0.1130 23$MC=0.0272 5 -235U G 361.89 5 1.17E-5 7[M1] 0.598 12 -235U 2 G KC=0.477 10$LC=0.0918 18$MC=0.0222 4 -235U G 382.75 5 0.000256 4M1 0.513 10 -235U 2 G KC=0.409 8$LC=0.0787 16$MC=0.0190 4 -235U G 430.08 104.29E-6 19[E1] 0.0183 4 -235U 2 G KC=0.0147 3$LC=0.00270 5$MC=6.48E-4 13 -235U G 451.481 100.000187 3M1(+E2) 0.19 13 -235U 2 G KC=0.15 11$LC=0.035 16$MC=0.009 4 -235U G 481.66 124.61E-6 10[E2] 0.0517 10 -235U 2 G KC=0.0309 6$LC=0.0154 3$MC=0.00404 8 -235U G 487.06 102.65E-7 19[E1] 0.0142 3 -235U 2 G KC=0.01150 23$LC=0.00208 4$MC=4.97E-4 10 -235U L 608.08 5 11/2+ -235U A 4558.75 2212000E-94 1110 -235U G 411.2 3 6.9E-6 30[M1] 0.422 8 -235U 2 G KC=0.337 7$LC=0.0646 13$MC=0.0156 3 -235U G 457.61 5 1.51E-6 3[M1] 0.316 6 -235U 2 G KC=0.252 5$LC=0.0483 10$MC=0.01170 23 -235U G 526.4 4 5.7E-8 19[E2] 0.0419 8 -235U 2 G KC=0.0262 5$LC=1160E-5 2$MC=0.00303 6 -235U L 633.17 6 (5/2)- -235U A 4534.08 2228400E-17 3025 -235U G 633.15 6 2.55E-6 6M1(+E2) 0.122 11 -235U 2 G KC=0.097 8$LC=0.0187 13$MC=0.0045 3 -235U L 637.81 5 3/2- -235U A 4529.52 2232200E-1212460 -235U G 586.3 3 1.53E-7 16[E1] 0.0099 2 -235U 2 G KC=0.00802 16$LC=0.00142 3$MC=3.39E-4 7 -235U G 624.78 5 4.60E-7 19[E1] 0.0087718 -235U 2 G KC=0.00712 14$LC=1250E-6 25$MC=2.99E-4 6 -235U G 637.73 5 6.4E-7 6[E1] 0.0084417 -235U 2 G KC=0.00684 14$LC=1200E-6 24$MC=2.87E-4 6 -235U G 637.80 5 1.92E-6 19E2 0.0273 5 -235U 2 G KC=0.0185 4$LC=0.00655 13$MC=0.00167 3 -235U L 658.97 4 1/2- -235U A 4508.72 2126400E-96 207 -235U G 265.7 3 1.6E-6 4[E1] 0.0514 10 -235U 2 G KC=0.0408 8$LC=0.00802 16$MC=0.00194 4 -235U G 645.94 4 1.49E-5 3E1 0.0082416 -235U 2 G KC=0.00669 13$LC=1170E-6 24$MC=2.80E-4 6 -235U G 658.86 6 9.59E-6 26E1 0.0079416 -235U 2 G KC=0.00645 13$LC=1130E-6 23$MC=2.69E-4 5 -235U L 664.541 23(5/2)- -235U A 4503.24 2163100E-111784 -235U G 493.08 5 8.8E-7 3[E1] 0.0139 3 -235U 2 G KC=0.01119 22$LC=0.00202 4$MC=4.84E-4 10 -235U G 582.89 106.18E-7 26[E1] 0.0100 2 -235U 2 G KC=0.00811 16$LC=0.00144 3$MC=3.43E-4 7 -235U G 612.83 3 9.5E-7 5E1 0.0091018 -235U 2 G KC=0.00738 15$LC=0.00130 3$MC=3.10E-4 6 -235U G 618.28 6 2.06E-6 8(E2) 0.0292 6 -235U 2 G KC=0.0196 4$LC=0.00716 14$MC=0.00184 4 -235U G 664.58 5 1.67E-6 4E2 0.0251 5 -235U 2 G KC=0.0172 4$LC=0.00583 12$MC=0.00149 3 -235U L 670.99 4 (7/2)- -235U A 4496.90 2134000E-1 130000 -235U G 624.78 3 2.2E-8 (M1) 0.137 3 -235U 2 G KC=0.1090 22$LC=0.0208 4$MC=0.00501 10 -235U G 670.99 4 9E-9 3[M1+E2] 0.06 4 -235U 2 G KC=0.05 3$LC=0.0033 17$MC=0.0025 12 -235U L 701.02 3 (7/2)- -235U A 4467.37 2170700E-113366 -235U G 550.5 2 4.35E-7 25(E1) 0.0112022 -235U 2 G KC=0.00904 18$LC=0.00161 3$MC=3.85E-4 8 -235U G 597.99 5 1.74E-6 6[E2] 0.0314 6 -235U 2 G KC=0.0208 4$LC=0.00789 16$MC=0.00204 4 -235U G 619.21 6 1.21E-6 8[E1] 0.0089218 -235U 2 G KC=0.00724 14$LC=0.00127 3$MC=3.04E-4 6 -235U G 649.32 6 7.2E-7 5[E1] 0.0081616 -235U 2 G KC=0.00662 13$LC=1160E-6 23$MC=2.77E-4 6 -235U G 654.88 8 2.27E-6 5(E2) 0.0258 5 -235U 2 G KC=0.0177 4$LC=0.00607 12$MC=0.00156 3 -235U G 701.1 2 5.24E-7 19[M1+E2] 0.06 4 -235U 2 G KC=0.05 3$LC=0.010 5$MC=0.0025 12 -235U L 703.757 193/2- -235U A 4464.68 2111400E-93 216 -235U G 652.05 2 6.63E-6 20E1 0.0080916 -235U 2 G KC=0.00657 13$LC=1150E-6 23$MC=2.74E-4 5 -235U G 690.81 8 5.9E-7 5E1 0.0072715 -235U 2 G KC=0.00591 12$LC=1030E-6 21$MC=2.45E-4 5 -235U G 703.68 5 4.10E-6 13E1 0.0070214 -235U 2 G KC=0.00571 12$LC=9.93E-4 20$MC=2.37E-4 5 -235U L 720.25 3 (9/2)- -235U A 4448.46 2121300E-19 859 -235U G 617.1 1 1.35E-6 8[M1] 0.142 3 -235U 2 G KC=0.1130 23$LC=0.0215 4$MC=0.00518 10 -235U G 674.050 305.0E-7 2 0.1120 22 -235U 2 G KC=0.0893 18$LC=0.0169 3$MC=0.00408 8 -235U G 720.3 5 2.9E-8 5 -235U L 750.07 16(9/2)- -235U A 4419.14 2634000E-14 3140 -235U G 579.4 3 8.8E-8 19[E2] 0.0337 7 -235U 2 G KC=0.0220 4$LC=0.00867 17$MC=0.00224 4 -235U G 599.6 2 2.02E-7 25[E1] 0.0094819 -235U 2 G KC=0.00769 15$LC=0.00136 3$MC=3.24E-4 6 -235U G 668.2 5 4.0E-8 12[E1] 0.0077315 -235U 2 G KC=0.00628 13$LC=1100E-6 22$MC=2.62E-4 5 -235U L 761.04 5 (1/2)- -235U A 4408.36 2210300E-1178500 -235U G 123.228 5 1.6E-9 4(M1) 12.19 24 -235U 2 G KC=9.66 19$LC=1.91 4$MC=0.461 9 -235U G 747.4 5 8.1E-8 16E1 0.0062913 -235U 2 G KC=0.00512 10$LC=8.80E-4 18$MC=2.11E-4 4 -235U L 769.27 6 1/2+ -235U A 4400.26 2127000E-93 28 -235U G 639.99 108.46E-6 20[E2] 0.0271 5 -235U 2 G KC=0.0184 4$LC=0.00648 13$MC=0.00167 3 -235U G 756.23 6 2.8E-6 5[M1+E2] 0.05 3 -235U 2 G KC=0.04 3$LC=0.008 4$MC=0.002 1 -235U G 769.15 8 5.1E-6 10M1+ 2.0 2 -235U L 769.5 3 3/2- -235U A 4400.0 4 10300E-91273 -235U G 718.0 5 2.76E-6 6E1 0.0067714 -235U 2 G KC=0.00551 11$LC=9.60E-4 19$MC=2.27E-4 5 -235U G 756.4 4 6.9E-7 19[E1] 0.0061512 -235U 2 G KC=0.00501 10$LC=8.65E-4 17$MC=2.06E-4 4 -235U G 769.4 5 6.8E-6 12E1 0.0059612 -235U 2 G KC=0.00486 10$LC=8.37E-4 17$MC=1.99E-4 4 -235U L 777.59 19(11/2)- -235U A 4392.08 2824700E-1192610 -235U G 606.9 2 1.21E-7 13M1(+E2) 0.12 3 -235U 2 G KC=0.09 3$LC=0.019 4$MC=0.0045 9 -235U G 674.4 5 1.0E-7 1(M1) 0.1120 22 -235U 2 G KC=0.0892 18$LC=0.0169 3$MC=0.00408 8 -235U L 779.51 3 (3/2)+ -235U A 4390.20 2110100E-111616 -235U G 697.8 5 7.4E-8 15 -235U G 727.9 2 1.25E-7 7M1 0.0911 18 -235U 2 G KC=0.0728 15$LC=0.0138 3$MC=0.00332 7 -235U G 766.47 3 1.3E-7 2+M1 4.0 4 -235U G 779.43 3 1.37E-7 9M1 0.0759 15 -235U 2 G KC=0.0607 12$LC=0.01148 23$MC=0.00276 6 -235U L 805.72 6 3/2- -235U A 4364.42 2284000E-1144560 -235U G 172.560 8 3E-9 M1 4.70 9 -235U 2 G KC=3.73 8$LC=0.728 15$MC=0.176 4 -235U G 412.49 6 1.8E-8 [E1] 0.0199 4 -235U 2 G KC=0.0160 3$LC=0.00296 6$MC=7.09E-4 14 -235U G 792.68 6 2.0E-8 4(E1) 0.0056511 -235U 2 G KC=0.00461 9$LC=7.90E-4 16$MC=1.88E-4 4 -235U G 805.65 6 2.8E-8 4E2 0.0169 3 -235U 2 G KC=0.01220 24$LC=0.00348 7$MC=8.80E-4 18 -235U L 821.25 4 5/2+ -235U A 4349.15 2130000E-13 960 -235U G 596.0 5 3.9E-8 12[E2] 0.0317 6 -235U 2 G KC=0.0209 4$LC=0.00797 16$MC=0.00206 4 -235U G 670.8 5 9E-9 3 -235U G 769.54 4 -235U G 808.21 4 1.22E-7 6M1 0.0690 14 -235U 2 G KC=0.0552 11$LC=0.01040 21$MC=0.00251 5 -235U G 821.25 4 5.0E-8 11E1+M2 -235U L 843.858 10(1/2)+ -235U A 4326.92 2122800E-112825 -235U G 714.71 147.9E-8 8E2 0.0215 4 -235U 2 G KC=0.0151 3$LC=0.00477 10$MC=1225E-6 25 -235U G 843.78 1 1.35E-7 8M1(+) 0.09 1 -235U L 845.3 10(7/2)+ -235U A 4325.5 1042000E-1 4360 -235U G 763.60 152.2E-8 (+M1) 0.9 -235U L 865.35 183/2+ -235U A 4305.79 2898000E-1131280 -235U G 693.81 1 1.9E-8 7(E2) 0.0229 5 -235U 2 G KC=0.0159 3$LC=0.00517 10$MC=0.00132 3 -235U G 736.5 5 3.0E-8 9M1+()E2 0.0481 10 -235U 2 G KC=0.0374 7$LC=0.00807 16$MC=0.00198 4 -235U G 813.7 2 4.5E-8 5M1 0.0677 14 -235U 2 G KC=0.0542 11$LC=0.01020 21$MC=0.00246 5 -235U L 891.89 155/2+ -235U A 4279.70 2619900E-112380 -235U G 720.55 3 2.0E-8 2 -235U G 762.6 2 1E-8 -235U G 840.4 2 4.9E-8 5M1(+) 0.14 2 -235U G 879.2 3 3.6E-8 4[M1+E2] 0.035 20 -235U 2 G KC=0.027 17$LC=0.006 3$MC=0.0014 7 -235U G 891.0 3 7.5E-8 8[E2] 0.0139 3 -235U 2 G KC=0.0102 2$LC=0.00270 5$MC=6.77E-4 14 -235U L 968.451 203/2+ -235U A 4204.42 2161000E-115281 -235U G 955.41 2 3.1E-8 3M1+()E2 0.036 4 -235U 2 G KC=0.029 3$LC=0.0055 6$MC=0.00133 13 -235U G 968.37 2 2.8E-8 M1+()E2 0.035 19 -235U 2 G KC=0.0028 15$LC=0.0053 29$MC=0.0013 7 -235U L 970.52 22(5/2,7/2)+ -235U A 4202.4 3 41000E-14 402 -235U G 918.7 3 8.8E-9 30 -235U G 957.6 3 3.2E-8 3 -235U L 986.65 17(13/2-)- -235U A 4186.53 2777000E-17 156 -235U G 816.0 2 2.5E-8 4[M1+E2] 0.042 25 -235U 2 G KC=0.033 21$LC=0.007 3$MC=0.0016 8 -235U G 940.3 3 5.0E-8 5[E2] 0.0125025 -235U 2 G KC=0.00932 19$LC=0.00237 5$MC=5.91E-4 12 -235U L 992.72 22(5/2+)+ -235U A 4180.6 3 20000E-13 53 -235U G 767.29 4 1.4E-7 3 -235U G 821.3 2 6E-9 -235U G 979.7 3 2.8E-8 5[M1+E2] 0.026 15 -235U 2 G KC=0.021 12$LC=0.0042 20$MC=0.0010 5 -235U G 992.64 3 2.7E-8 4 -235U L 1057.58 13(7/2)+ -235U A 4116.78 2593000E-19 31 -235U G 832.2 2 3.0E-8 4 -235U G 1005.7 3 1.77E-8 25 -235U G 1057.3 2 4.5E-8 7 -235U L 1116.2 2 (5/2-)- -235U A 4059.1 3 21000E-15 41 -235U G 986.90 4 2.1E-8 5E1 0.00383 8 -235U 2 G KC=0.00313 6$LC=5.29E-4 11$MC=1260E-7 25 - +235U 239PU A DECAY (24100 Y) +235U H TYP=FUL$AUT=V.P.CHECHEV$CUT=31-JAN-2007$ +235U C References:1952As28, 1952Se67, 1957As83, 1957No15, 1961Dz05, 1962Le11, +235U 2C 1963Bj03, 1963Ba09, 1965Ho04, 1965Tr03, 1966Ah02, 1966Ho09, 1967Be65, +235U 3C 1968Cl02, 1968Ba25, 1970OeZZ, 1971GuZY, 1975Ba65, 1975Al15, 1975GlZQ, +235U 4C 1976GuZN, 1976BaZZ, 1977Ja08, 1978Lu10, 1978Ma45, 1978Pr07, 1978Se12, +235U 5C 1979Al03, 1980RyZX, 1981AhZV, 1981UmZZ, 1982Ba56, 1982He02, 1983Ah02, +235U 6C 1984Di08, 1984Iw02, 1984Bo41, 1984Ah06, 1985Dr09, 1986Mi10, 1987Bo25, +235U 7C 1988ChZL, 1989Ho24, 1990GlZZ, 1990An33, 1991Ry01, 1992Bl07, 1992Bl13, +235U 8C 1992Co10, 1992Fr04, 1992Ba08, 1993Ga28, 1993Sc22, 1994Mo36, 1994Ra27, +235U 9C 1994Ba91, 1994Le37, 1994Le28, 1995Jo23, 1996Sa24, 1996Sc06, 1996Vi07, +235U AC 1997Bu23, 1997Ko52, 1999ScZX, 1999Sa19, 2002Da21, 2002Ba85, 2003Au03, +235U BC 2003Br12 +235U T Auger electrons and X ray energies and emission intensities: +235U T {U Energy (keV)} {U Intensity} {U Line} +235U T +235U T 94.666 0.00418 4 XKA2 +235U T 98.44 0.00661 9 XKA1 +235U T +235U T 110.421 |] XKB3 +235U T 111.298 |] 0.00239 3 XKB1 +235U T 111.964 |] XKB5II +235U T +235U T 114.407 |] XKB2 +235U T 115.012 |] 0.00131 6 XKB4 +235U T 115.377 |] XKO23 +235U T +235U T 11.619-20.714 4.66 5 XL (total) +235U T 11.619 0.1008 11 XLL +235U T 13.438-13.615 1.65 3 XLA +235U T 15.399 0.0537 19 XLC +235U T 15.727-18.206 2.288 23 XLB +235U T 19.507-20.714 0.569 6 XLG +235U T +235U T 71.78-80.95 |] KLL AUGER +235U T 88.15-98.34 |] 0.00045 6 KLX AUGER +235U T 104.42-115.4 |] KXY AUGER +235U T 5.9-21.6 4.66 19 L AUGER +239PU P 0.0 1/2+ 24100 Y 11 5244.51 21 +235U N 1.0 1.0 1 +235U G 14.22 3 0.0055 4 +235U G 40.41 5 0.00016316 +235U G 74.96 100.000038 6 +235U G 184.55 5 2.1E-6 6[M1] 3.87 8 +235U G 193.13 129.0E-6 9 +235U G 196.87 5 3.7E-6 4 +235U G 350.8 3 1.8E-6 4 +235U G 446.82 208.5E-7 13 +235U G 497.0 5 4.4E-8 25 +235U G 538.8 2 3.09E-7 19 +235U G 557.3 5 3.8E-8 19 +235U G 608.9 2 1.17E-7 12 +235U G 650.53 6 2.7E-7 4 +235U G 685.97 111.26E-6 6E1 0.0073615 +235U G 688.1 3 1.12E-7 11 +235U G 693.2 5 3.2E-8 13 +235U G 699.6 5 8.0E-8 16 +235U G 712.96 5 5.2E-8 6 +235U G 742.7 5 3.8E-8 11 +235U G 777.1 3 2.8E-8 7 +235U G 786.9 2 8.7E-8 9E2 0.0177 4 +235U G 788.5 3 3.5E-8 7 +235U G 796.9 3 1.5E-8 3 +235U G 803.2 2 6.4E-8 5 +235U G 826.8 3 1.8E-8 6 +235U G 828.9 2 1.34E-7 8 +235U G 837.3 2 2.0E-8 4 +235U G 895.4 3 7.6E-9 25 +235U G 898.1 3 1.8E-8 4 +235U G 905.5 3 7.6E-9 25 +235U G 911.7 3 1.4E-8 3 +235U G 931.9 3 1.3E-8 4 +235U G 982.7 3 1.07E-8 25 +235U G 1009.4 3 1.39E-8 25 +235U L 0 7/2- 704E6 Y 1 +235U A 5156.65 210.03 6500 +235U L 0.0765 4 1/2+ 26 M +235U A 5156.59 1470.79 102.762 +235U G 0.0765 4 1E-8 E3 10E9 +235U L 13.0400 213/2+ 0.50 NS 3 +235U A 5143.82 2117.14 49.47 +235U G 12.975 100.0341 9M1+E2 607 17 +235U 2 G MC=451 13 +235U L 46.207 109/2- +235U A 5111.21 210.02 5019 +235U G 46.21 5 0.00072613M1+E2 52.6 27 +235U 2 G LC=39.4 19$MC=9.8 5 +235U L 51.7007 115/2+ 191 PS 5 +235U A 5105.81 2111.87 37.81 +235U G 38.661 2 0.01047 21M1+E2 339 19 +235U 2 G LC=249 14$MC=67 4 +235U G 51.624 1 0.02694 26E2 310 6 +235U 2 G LC=226 5$MC=62.6 13 +235U L 81.741 4 7/2+ +235U A 5076.28 210.052 81150 +235U G 30.04 2 0.000219 8(M1) 157 3 +235U 2 G LC=118.0 24$MC=28.7 6 +235U G 68.696 6 0.00036 10E2 78.6 16 +235U 2 G LC=57.3 11$MC=15.9 3 +235U L 103.035 1011/2- +235U A 5055.34 210.0375 121160 +235U G 56.828 3 0.00113615M1+E2 32.6 15 +235U 2 G LC=24.3 11$MC=6.14 30 +235U G 103.06 3 0.000217 6E2 11.58 23 +235U 2 G LC=8.44 17$MC=2.34 5 +235U L 129.2961 105/2+ +235U A 5029.51 210.013 42270 +235U G 47.60 3 6.25E-5 25(M1) 40.4 8 +235U 2 G LC=30.4 6$MC=7.37 15 +235U G 77.592 140.000380 6M1(+E2) 17 10 +235U 2 G LC=12 7$MC=3.2 21 +235U G 116.26 2 0.00058119M1+E2 12.2 26 +235U 2 G KC=8.4 18$LC=2.9 6$MC=0.74 16 +235U G 129.296 1 0.00631 4E1 0.275 6 +235U 2 G KC=0.211 4$LC=0.0482 10$MC=0.01173 24 +235U L 150.467 159/2+ +235U A 5008.70 210.0182 271180 +235U G 68.73 2 0.00013 6(M1+E2) 27 +235U 2 G LC=20 $MC=5.2 +235U G 98.78 2 0.00135 11E2 14.1 3 +235U 2 G LC=10.28 21$MC=2.85 6 +235U L 170.708 1413/2- +235U G 67.674 120.000158 5M1+E2 16.9 5 +235U 2 G LC=12.7 4$MC=3.15 9 +235U G 124.51 3 6.81E-5 19E2 5.06 10 +235U 2 G KC=0.214 4$LC=3.53 7$MC=0.978 20 +235U L 171.388 5 7/2+ +235U A 4988.13 210.0034 104600 +235U G 41.93 5 0.000163 8(M1) 58.6 12 +235U 2 G LC=44.2 9$MC=10.71 21 +235U G 89.64 3 0.000027 2(M1+E2) 14 8 +235U 2 G LC=11 6$MC=2.8 17 +235U G 119.70 3 0.000021 3(M1+E2) 9 4 +235U 2 G KC=5 5$LC=3.1 11$MC=0.8 3 +235U G 125.21 105.63E-5 16[E1] 0.296 6 +235U 2 G KC=0.227 5$LC=0.0523 10$MC=0.0128 3 +235U G 158.1 3 1.01E-6 10[E2] 1.86 4 +235U 2 G KC=0.211 4$LC=1.200 24$MC=0.333 7 +235U G 171.393 6 0.000110 3[E1] 0.141 3 +235U 2 G KC=0.1103 22$LC=0.0235 5$MC=0.00570 11 +235U L 197.119 1411/2+ +235U A 4962.83 210.007 11520 +235U G 46.68 3 0.000050 6M1+E2 86 24 +235U 2 G LC=63 17$MC=17 5 +235U G 115.38 5 0.00046 5E2 6.87 14 +235U 2 G LC=5.0 1$MC=1.39 3 +235U L 225.423 8 9/2+ +235U A 4935.00 210.0050 71380 +235U G 54.039 8 1.943E-428M1 27.8 6 +235U 2 G LC=21.0 4$MC=5.08 10 +235U G 96.14 3 3.79E-5 19[E2] 16.0 3 +235U 2 G LC=11.67 23$MC=3.24 7 +235U G 122.35 129.5E-7 13(E1) 0.312 6 +235U 2 G KC=0.238 5$LC=0.0556 11$MC=0.0135 3 +235U G 143.35 201.74E-5 8[M1+E2] 5.3 26 +235U 2 G KC=3.3 30$LC=1.5 3$MC=0.41 11 +235U G 173.70 5 3.1E-6 8[E2] 1.28 3 +235U 2 G KC=0.190 4$LC=0.795 16$MC=0.220 4 +235U G 179.220 126.56E-5 19[E1] 0.127 3 +235U 2 G KC=0.0995 20$LC=0.0210 4$MC=0.00509 10 +235U G 225.42 4 1.50E-5 4[E1] 0.0747 15 +235U 2 G KC=0.0589 12$LC=0.01190 24$MC=0.00288 6 +235U L 249.130 1215/2- +235U A 4911.69 210.0030 161590 +235U G 78.43 2 1.533E-428M1(+E2) 16 10 +235U 2 G LC=12 7$MC=3.1 20 +235U G 146.094 6 0.000121 3E2 2.57 5 +235U 2 G KC=0.223 4$LC=1.71 3$MC=0.474 10 +235U L 291.144 1911/2+ +235U A 4870.38 210.0007 33500 +235U G 65.708 304.73E-5 25M1+E2 19 6 +235U 2 G LC=14 5$MC=3.6 13 +235U G 119.76 2 0.000009 2[E2] 5.99 12 +235U 2 G KC=0.200 4$LC=4.22 8$MC=1.169 23 +235U G 188.23 101.10E-5 11[E1] 0.1140 23 +235U 2 G KC=0.0889 18$LC=0.0186 4$MC=0.00450 9 +235U G 244.92 5 5.1E-6 5 0.0618 12 +235U 2 G KC=0.0485 10$LC=0.00973 19$MC=0.00235 5 +235U L 294.669 1513/2+ +235U A 4866.91 210.0018 51300 +235U G 97.6 3 0.00009 6M1+E2 7.0 19 +235U 2 G LC=5.2 14$MC=1.3 4 +235U G 144.201 3 0.000285 7E2 2.72 5 +235U 2 G KC=0.225 5$LC=1.82 4$MC=0.502 10 +235U L 332.845 4 5/2+ +235U A 4829.38 210.00354 7363 +235U G 161.450 150.000122 6(M1) 5.67 11 +235U 2 G KC=4.51 9$LC=0.880 18$MC=0.213 4 +235U G 203.550 5 0.000563 9M1 2.95 6 +235U 2 G KC=2.35 5$LC=0.456 9$MC=0.1103 22 +235U G 281.2 2 2.1E-6 3[M1+E2] 0.7 5 +235U 2 G KC=0.5 4$LC=0.14 4$MC=0.036 8 +235U G 319.68 104.9E-6 5[M1+E2] 0.50 35 +235U 2 G KC=0.37 30$LC=0.10 3$MC=0.024 7 +235U G 332.845 5 0.000488 8E1 0.0313 6 +235U 2 G KC=0.0250 5$LC=0.00476 10$MC=0.001150 23 +235U L 338.52 6 17/2- +235U A 4823.80 220.000022 53000 +235U G 89.39 6 0.000002 [M1] 6.40 13 +235U 2 G LC=4.82 10$MC=1.167 23 +235U G 167.81 5 3.0E-6 8[E2] 1.47 3 +235U 2 G KC=0.198 4$LC=0.925 19$MC=0.256 5 +235U L 357.30 6 15/2+ +235U A 4805.33 220.000017 451000 +235U G 160.19 5 6.2E-6 13[E2] 1.77 4 +235U 2 G KC=0.208 4$LC=1.140 23$MC=0.314 6 +235U L 367.069 8 7/2+ +235U A 4795.73 210.00094417788 +235U G 141.657 203.21E-5 10[M1] 8.22 16 +235U 2 G KC=6.52 13$LC=1.28 3$MC=0.309 6 +235U G 195.679 8 0.000106 2M1 3.30 7 +235U 2 G KC=2.62 5$LC=0.51 1$MC=0.123 3 +235U G 237.77 101.45E-5 6[M1] 1.91 4 +235U 2 G KC=1.52 3$LC=0.295 6$MC=0.0712 14 +235U G 285.3 2 1.9E-6 4[M1+E2] 0.7 5 +235U 2 G KC=0.5 4$LC=0.14 4$MC=0.035 8 +235U G 320.862 205.40E-5 12[E1] 0.0337 7 +235U 2 G KC=0.0269 5$LC=0.00517 10$MC=0.00125 3 +235U G 354.0 5 7.6E-7 30[E2] 0.1150 23 +235U 2 G KC=0.0549 11$LC=0.0445 9$MC=0.01200 24 +235U G 367.073 258.71E-5 20[E1] 0.0254 5 +235U 2 G KC=0.0203 4$LC=0.00382 8$MC=0.000920 18 +235U L 393.225 6 3/2+ +235U A 4770.01 210.00125 3390 +235U G 263.95 3 2.59E-5 10M1 1.43 3 +235U 2 G KC=1.140 23$LC=0.220 4$MC=0.0532 11 +235U G 341.506 106.50E-5 13M1 0.701 14 +235U 2 G KC=0.559 11$LC=0.1080 22$MC=0.0260 5 +235U G 380.191 6 0.000302 4M1 0.523 10 +235U 2 G KC=0.417 8$LC=0.0801 16$MC=0.0193 4 +235U G 393.14 3 0.00041917M1 0.477 10 +235U 2 G KC=0.380 8$LC=0.0731 15$MC=0.0176 4 +235U L 414.779 119/2+ +235U A 4748.81 210.00075 11460 +235U G 123.62 5 2.37E-5 9[M1] 12.08 24 +235U 2 G KC=9.57 19$LC=1.89 4$MC=0.457 9 +235U G 189.36 1 8.20E-5 14[M1+E2] 2.3 14 +235U 2 G KC=1.5 13$LC=0.553 11$MC=0.143 8 +235U G 218.0 5 1.2E-6 10 +235U G 243.38 3 2.54E-5 7[M1+E2] 1.1 7 +235U 2 G KC=0.8 6$LC=0.23 4$MC=0.059 7 +235U G 311.78 4 2.57E-5 8[E1] 0.0361 7 +235U 2 G KC=0.0287 6$LC=0.00552 11$MC=0.00133 3 +235U G 368.554 208.77E-5 14[E1] 0.0252 5 +235U 2 G KC=0.0202 4$LC=0.00378 8$MC=0.000910 18 +235U L 426.755 3 5/2+ +235U A 4737.05 210.00570 549.6 +235U G 255.384 157.95E-5 20[M1] 1.57 3 +235U 2 G KC=1.25 3$LC=0.241 5$MC=0.0583 12 +235U G 297.46 3 4.92E-5 13[M1] 1.025 21 +235U 2 G KC=0.816 16$LC=0.158 3$MC=0.0381 8 +235U G 345.013 4 0.000548 8M1 0.682 14 +235U 2 G KC=0.543 11$LC=0.1050 21$MC=0.0253 5 +235U G 375.054 3 0.00154021M1 0.543 11 +235U 2 G KC=0.432 9$LC=0.0832 17$MC=0.0201 4 +235U G 413.713 5 0.00146421M1 0.415 8 +235U 2 G KC=0.331 7$LC=0.0636 13$MC=0.0153 3 +235U G 426.68 3 2.39E-5 6[E2] 0.0699 14 +235U 2 G KC=0.0387 8$LC=0.0230 5$MC=0.00610 12 +235U L 445.716 207/2+ +235U A 4718.39 214.00E-5 115200 +235U G 316.41 3 1.33E-5 5M1 0.865 17 +235U 2 G KC=0.689 14$LC=0.133 3$MC=0.0321 6 +235U G 399.53 6 6.12E-6 26[E1] 0.0213 4 +235U 2 G KC=0.0171 3$LC=0.00317 6$MC=0.000761 15 +235U G 445.72 3 8.77E-6 26E1 0.0170 3 +235U 2 G KC=0.0137 3$LC=0.00250 5$MC=0.000560 11 +235U L 474.297 137/2+ +235U A 4690.29 210.00056 5230 +235U G 248.95 5 7.0E-6 6[M1] 1.68 3 +235U 2 G KC=1.34 3$LC=0.259 5$MC=0.0626 14 +235U G 302.87 5 4.9E-6 4[M1] 0.976 20 +235U 2 G KC=0.777 16$LC=0.150 3$MC=0.0362 7 +235U G 323.84 3 5.30E-5 13M1 0.811 16 +235U 2 G KC=0.646 13$LC=0.1246 25$MC=0.0301 6 +235U G 345.00 2 0.00005 (M1) 0.682 14 +235U 2 G KC=0.543 11$LC=0.1050 21$MC=0.0253 5 +235U G 392.53 3 0.00012116M1 0.479 10 +235U 2 G KC=0.382 8$LC=0.0731 15$MC=0.0177 4 +235U G 422.598 191.199E-420M1 0.392 8 +235U 2 G KC=0.313 6$LC=0.0560 11$MC=0.0145 3 +235U G 428.4 3 1.01E-6 10[E1] 0.0184 4 +235U 2 G KC=0.0147 3$LC=0.00270 5$MC=0.000653 13 +235U G 461.25 5 2.29E-6 5[E2] 0.0575 12 +235U 2 G KC=0.0334 7$LC=0.0177 4$MC=0.00467 9 +235U G 473.9 5 6E-8 3[E1] 0.0150 3 +235U 2 G KC=0.01210 24$LC=0.00220 4$MC=0.000526 11 +235U L 509.92 17(9/2+) +235U A 4655.27 273.3E-6 722000 +235U G 406.8 2 2.9E-6 7[E1] 0.0204 4 +235U 2 G KC=0.0164 3$LC=0.00304 6$MC=0.000731 15 +235U G 463.9 3 2.8E-7 3[E1] 0.0157 3 +235U 2 G KC=0.0126 3$LC=0.00230 5$MC=0.000551 11 +235U L 533.228 109/2+ +235U A 4632.35 210.00086 355.8 +235U G 242.08 3 7.4E-6 5[M1] 1.82 4 +235U 2 G KC=1.45 3$LC=0.280 6$MC=0.0678 14 +235U G 307.85 5 5.2E-6 4[M1] 0.933 19 +235U 2 G KC=0.743 15$LC=0.143 3$MC=0.0346 7 +235U G 336.113 121.111E-426M1 0.733 15 +235U 2 G KC=0.583 12$LC=0.1130 23$MC=0.0272 5 +235U G 361.89 5 1.17E-5 7[M1] 0.598 12 +235U 2 G KC=0.477 10$LC=0.0918 18$MC=0.0222 4 +235U G 382.75 5 0.000256 4M1 0.513 10 +235U 2 G KC=0.409 8$LC=0.0787 16$MC=0.0190 4 +235U G 430.08 104.29E-6 19[E1] 0.0183 4 +235U 2 G KC=0.0147 3$LC=0.00270 5$MC=0.000648 13 +235U G 451.481 100.000187 3M1(+E2) 0.19 13 +235U 2 G KC=0.15 11$LC=0.035 16$MC=0.009 4 +235U G 481.66 124.61E-6 10[E2] 0.0517 10 +235U 2 G KC=0.0309 6$LC=0.0154 3$MC=0.00404 8 +235U G 487.06 102.65E-7 19[E1] 0.0142 3 +235U 2 G KC=0.01150 23$LC=0.00208 4$MC=0.000497 10 +235U L 608.08 5 11/2+ +235U A 4558.75 220.000012 41110 +235U G 411.2 3 6.9E-6 30[M1] 0.422 8 +235U 2 G KC=0.337 7$LC=0.0646 13$MC=0.0156 3 +235U G 457.61 5 1.51E-6 3[M1] 0.316 6 +235U 2 G KC=0.252 5$LC=0.0483 10$MC=0.01170 23 +235U G 526.4 4 5.7E-8 19[E2] 0.0419 8 +235U 2 G KC=0.0262 5$LC=0.011600 23$MC=0.00303 6 +235U L 633.17 6 (5/2)- +235U A 4534.08 222.84E-6 73025 +235U G 633.15 6 2.55E-6 6M1(+E2) 0.122 11 +235U 2 G KC=0.097 8$LC=0.0187 13$MC=0.0045 3 +235U L 637.81 5 3/2- +235U A 4529.52 223.22E-6 212460 +235U G 586.3 3 1.53E-7 16[E1] 0.0099 2 +235U 2 G KC=0.00802 16$LC=0.00142 3$MC=0.000339 7 +235U G 624.78 5 4.60E-7 19[E1] 0.0087718 +235U 2 G KC=0.00712 14$LC=0.001250 25$MC=0.000299 6 +235U G 637.73 5 6.4E-7 6[E1] 0.0084417 +235U 2 G KC=0.00684 14$LC=0.001200 24$MC=0.000287 6 +235U G 637.80 5 1.92E-6 19E2 0.0273 5 +235U 2 G KC=0.0185 4$LC=0.00655 13$MC=0.00167 3 +235U L 658.97 4 1/2- +235U A 4508.72 212.64E-5 6207 +235U G 265.7 3 1.6E-6 4[E1] 0.0514 10 +235U 2 G KC=0.0408 8$LC=0.00802 16$MC=0.00194 4 +235U G 645.94 4 1.49E-5 3E1 0.0082416 +235U 2 G KC=0.00669 13$LC=0.001170 24$MC=0.000280 6 +235U G 658.86 6 9.59E-6 26E1 0.0079416 +235U 2 G KC=0.00645 13$LC=0.001130 23$MC=0.000269 5 +235U L 664.541 23(5/2)- +235U A 4503.24 216.31E-6 11784 +235U G 493.08 5 8.8E-7 3[E1] 0.0139 3 +235U 2 G KC=0.01119 22$LC=0.00202 4$MC=0.000484 10 +235U G 582.89 106.18E-7 26[E1] 0.0100 2 +235U 2 G KC=0.00811 16$LC=0.00144 3$MC=0.000343 7 +235U G 612.83 3 9.5E-7 5E1 0.0091018 +235U 2 G KC=0.00738 15$LC=0.00130 3$MC=0.000310 6 +235U G 618.28 6 2.06E-6 8(E2) 0.0292 6 +235U 2 G KC=0.0196 4$LC=0.00716 14$MC=0.00184 4 +235U G 664.58 5 1.67E-6 4E2 0.0251 5 +235U 2 G KC=0.0172 4$LC=0.00583 12$MC=0.00149 3 +235U L 670.99 4 (7/2)- +235U A 4496.90 213.4E-8 130000 +235U G 624.78 3 2.2E-8 (M1) 0.137 3 +235U 2 G KC=0.1090 22$LC=0.0208 4$MC=0.00501 10 +235U G 670.99 4 9E-9 3[M1+E2] 0.06 4 +235U 2 G KC=0.05 3$LC=0.0033 17$MC=0.0025 12 +235U L 701.02 3 (7/2)- +235U A 4467.37 217.07E-6 13366 +235U G 550.5 2 4.35E-7 25(E1) 0.0112022 +235U 2 G KC=0.00904 18$LC=0.00161 3$MC=0.000385 8 +235U G 597.99 5 1.74E-6 6[E2] 0.0314 6 +235U 2 G KC=0.0208 4$LC=0.00789 16$MC=0.00204 4 +235U G 619.21 6 1.21E-6 8[E1] 0.0089218 +235U 2 G KC=0.00724 14$LC=0.00127 3$MC=0.000304 6 +235U G 649.32 6 7.2E-7 5[E1] 0.0081616 +235U 2 G KC=0.00662 13$LC=0.001160 23$MC=0.000277 6 +235U G 654.88 8 2.27E-6 5(E2) 0.0258 5 +235U 2 G KC=0.0177 4$LC=0.00607 12$MC=0.00156 3 +235U G 701.1 2 5.24E-7 19[M1+E2] 0.06 4 +235U 2 G KC=0.05 3$LC=0.010 5$MC=0.0025 12 +235U L 703.757 193/2- +235U A 4464.68 211.14E-5 3216 +235U G 652.05 2 6.63E-6 20E1 0.0080916 +235U 2 G KC=0.00657 13$LC=0.001150 23$MC=0.000274 5 +235U G 690.81 8 5.9E-7 5E1 0.0072715 +235U 2 G KC=0.00591 12$LC=0.001030 21$MC=0.000245 5 +235U G 703.68 5 4.10E-6 13E1 0.0070214 +235U 2 G KC=0.00571 12$LC=0.000993 20$MC=0.000237 5 +235U L 720.25 3 (9/2)- +235U A 4448.46 212.13E-6 9859 +235U G 617.1 1 1.35E-6 8[M1] 0.142 3 +235U 2 G KC=0.1130 23$LC=0.0215 4$MC=0.00518 10 +235U G 674.050 305.0E-7 2 0.1120 22 +235U 2 G KC=0.0893 18$LC=0.0169 3$MC=0.00408 8 +235U G 720.3 5 2.9E-8 5 +235U L 750.07 16(9/2)- +235U A 4419.14 263.4E-7 43140 +235U G 579.4 3 8.8E-8 19[E2] 0.0337 7 +235U 2 G KC=0.0220 4$LC=0.00867 17$MC=0.00224 4 +235U G 599.6 2 2.02E-7 25[E1] 0.0094819 +235U 2 G KC=0.00769 15$LC=0.00136 3$MC=0.000324 6 +235U G 668.2 5 4.0E-8 12[E1] 0.0077315 +235U 2 G KC=0.00628 13$LC=0.001100 22$MC=0.000262 5 +235U L 761.04 5 (1/2)- +235U A 4408.36 221.03E-7 178500 +235U G 123.228 5 1.6E-9 4(M1) 12.19 24 +235U 2 G KC=9.66 19$LC=1.91 4$MC=0.461 9 +235U G 747.4 5 8.1E-8 16E1 0.0062913 +235U 2 G KC=0.00512 10$LC=0.000880 18$MC=0.000211 4 +235U L 769.27 6 1/2+ +235U A 4400.26 210.000027 328 +235U G 639.99 108.46E-6 20[E2] 0.0271 5 +235U 2 G KC=0.0184 4$LC=0.00648 13$MC=0.00167 3 +235U G 756.23 6 2.8E-6 5[M1+E2] 0.05 3 +235U 2 G KC=0.04 3$LC=0.008 4$MC=0.002 1 +235U G 769.15 8 5.1E-6 10M1+E0 2.0 2 +235U L 769.5 3 3/2- +235U A 4400.0 4 1.03E-5 1273 +235U G 718.0 5 2.76E-6 6E1 0.0067714 +235U 2 G KC=0.00551 11$LC=0.000960 19$MC=0.000227 5 +235U G 756.4 4 6.9E-7 19[E1] 0.0061512 +235U 2 G KC=0.00501 10$LC=0.000865 17$MC=0.000206 4 +235U G 769.4 5 6.8E-6 12E1 0.0059612 +235U 2 G KC=0.00486 10$LC=0.000837 17$MC=0.000199 4 +235U L 777.59 19(11/2)- +235U A 4392.08 282.47E-7 192610 +235U G 606.9 2 1.21E-7 13M1(+E2) 0.12 3 +235U 2 G KC=0.09 3$LC=0.019 4$MC=0.0045 9 +235U G 674.4 5 1.0E-7 1(M1) 0.1120 22 +235U 2 G KC=0.0892 18$LC=0.0169 3$MC=0.00408 8 +235U L 779.51 3 (3/2)+ +235U A 4390.20 211.01E-6 11616 +235U G 697.8 5 7.4E-8 15 +235U G 727.9 2 1.25E-7 7M1 0.0911 18 +235U 2 G KC=0.0728 15$LC=0.0138 3$MC=0.00332 7 +235U G 766.47 3 1.3E-7 2E0+M1 4.0 4 +235U G 779.43 3 1.37E-7 9M1 0.0759 15 +235U 2 G KC=0.0607 12$LC=0.01148 23$MC=0.00276 6 +235U L 805.72 6 3/2- +235U A 4364.42 228.4E-8 144560 +235U G 172.560 8 3E-9 M1 4.70 9 +235U 2 G KC=3.73 8$LC=0.728 15$MC=0.176 4 +235U G 412.49 6 1.8E-8 [E1] 0.0199 4 +235U 2 G KC=0.0160 3$LC=0.00296 6$MC=0.000709 14 +235U G 792.68 6 2.0E-8 4(E1) 0.0056511 +235U 2 G KC=0.00461 9$LC=0.000790 16$MC=0.000188 4 +235U G 805.65 6 2.8E-8 4E2 0.0169 3 +235U 2 G KC=0.01220 24$LC=0.00348 7$MC=0.000880 18 +235U L 821.25 4 5/2+ +235U A 4349.15 213.0E-7 3960 +235U G 596.0 5 3.9E-8 12[E2] 0.0317 6 +235U 2 G KC=0.0209 4$LC=0.00797 16$MC=0.00206 4 +235U G 670.8 5 9E-9 3 +235U G 769.54 4 E0 +235U G 808.21 4 1.22E-7 6M1 0.0690 14 +235U 2 G KC=0.0552 11$LC=0.01040 21$MC=0.00251 5 +235U G 821.25 4 5.0E-8 11E1+M2 +235U L 843.858 10(1/2)+ +235U A 4326.92 212.28E-7 12825 +235U G 714.71 147.9E-8 8E2 0.0215 4 +235U 2 G KC=0.0151 3$LC=0.00477 10$MC=0.001225 25 +235U G 843.78 1 1.35E-7 8M1(+E0) 0.09 1 +235U L 845.3 10(7/2)+ +235U A 4325.5 104.2E-8 4360 +235U G 763.60 152.2E-8 E0(+M1) 0.9 +235U L 865.35 183/2+ +235U A 4305.79 289.8E-8 131280 +235U G 693.81 1 1.9E-8 7(E2) 0.0229 5 +235U 2 G KC=0.0159 3$LC=0.00517 10$MC=0.00132 3 +235U G 736.5 5 3.0E-8 9M1+E2 0.0481 10 +235U 2 G KC=0.0374 7$LC=0.00807 16$MC=0.00198 4 +235U G 813.7 2 4.5E-8 5M1 0.0677 14 +235U 2 G KC=0.0542 11$LC=0.01020 21$MC=0.00246 5 +235U L 891.89 155/2+ +235U A 4279.70 261.99E-7 12380 +235U G 720.55 3 2.0E-8 2 +235U G 762.6 2 1E-8 +235U G 840.4 2 4.9E-8 5M1(+E0) 0.14 2 +235U G 879.2 3 3.6E-8 4[M1+E2] 0.035 20 +235U 2 G KC=0.027 17$LC=0.006 3$MC=0.0014 7 +235U G 891.0 3 7.5E-8 8[E2] 0.0139 3 +235U 2 G KC=0.0102 2$LC=0.00270 5$MC=0.000677 14 +235U L 968.451 203/2+ +235U A 4204.42 216.1E-8 15281 +235U G 955.41 2 3.1E-8 3M1+E2 0.036 4 +235U 2 G KC=0.029 3$LC=0.0055 6$MC=0.00133 13 +235U G 968.37 2 2.8E-8 M1+E2 0.035 19 +235U 2 G KC=0.0028 15$LC=0.0053 29$MC=0.0013 7 +235U L 970.52 22(5/2,7/2)+ +235U A 4202.4 3 4.1E-8 4402 +235U G 918.7 3 8.8E-9 30 +235U G 957.6 3 3.2E-8 3 +235U L 986.65 17(13/2-) +235U A 4186.53 277.7E-8 7156 +235U G 816.0 2 2.5E-8 4[M1+E2] 0.042 25 +235U 2 G KC=0.033 21$LC=0.007 3$MC=0.0016 8 +235U G 940.3 3 5.0E-8 5[E2] 0.0125025 +235U 2 G KC=0.00932 19$LC=0.00237 5$MC=0.000591 12 +235U L 992.72 22(5/2+) +235U A 4180.6 3 2.0E-7 353 +235U G 767.29 4 1.4E-7 3 +235U G 821.3 2 6E-9 +235U G 979.7 3 2.8E-8 5[M1+E2] 0.026 15 +235U 2 G KC=0.021 12$LC=0.0042 20$MC=0.0010 5 +235U G 992.64 3 2.7E-8 4 +235U L 1057.58 13(7/2)+ +235U A 4116.78 259.3E-8 931 +235U G 832.2 2 3.0E-8 4 +235U G 1005.7 3 1.77E-8 25 +235U G 1057.3 2 4.5E-8 7 +235U L 1116.2 2 (5/2-) +235U A 4059.1 3 2.1E-8 541 +235U G 986.90 4 2.1E-8 5E1 0.00383 8 +235U 2 G KC=0.00313 6$LC=0.000529 11$MC=1.260E-4 25 + diff --git a/HEN_HOUSE/spectra/lnhb/Pu-240.txt b/HEN_HOUSE/spectra/lnhb/Pu-240.txt index bb1f7d3f2..ab08116eb 100644 --- a/HEN_HOUSE/spectra/lnhb/Pu-240.txt +++ b/HEN_HOUSE/spectra/lnhb/Pu-240.txt @@ -1,97 +1,108 @@ -236U 240PU A DECAY (6561 Y) -236U H TYP=Update$AUT=V.P. Chechev$CUT= -- $ -236U C Evaluation history: Type=Update;Author=V.P. Chechev;Cutoff date= -- -236U C References: 1951In03, 1951We21, 1952As28, 1953Ki72, 1954Ba14, 1954Ch74, -236U 2C 1956Bu92, 1956Go43, 1956Ko67, 1957As83, 1958Sa21, 1959Tr37, 1959Mi90, -236U 3C 1962Wa13, 1962Le11, 1963Ma50, 1964Hy02, 1967Be65, 1967Fi13, 1968Oe02, -236U 4C 1969Le05, 1971GuZY, 1972Sc01, 1972ClZS, 1972Go33, 1974HeYW, 1975Dr05, -236U 5C 1975OtZX, 1976GuZN, 1976Um01, 1977Ba69, 1978Ja11, 1979BuZC, 1981He16, -236U 6C 1982Ba56, 1983Ah02, 1984An25, 1984St06, 1984Ru04, 1984Lu04, 1984Be19, -236U 7C 1984Ah06, 1984Bo41, 1986LoZT, 1988SeZY, 1989Dy01, 1991Ry01, 1991Iv01, -236U 8C 1990An33, 1992Ba08, 1992Bl13, 1994Le28, 1994Ba91, 1994Ra27, 1994Sa63, -236U 9C 1994Le37, 1995Jo23, 1996Vi07, 2000Ho27, 2003Au03, 2004BeZQ, 2004Si03, -236U 10C 2005ChZU, 2006Br20, 2007Ah05, 2008Ki07 -236U T Auger electrons and X ray energies and emission intensities: -236U T {U Energy (keV)} {U Intensity} {U Line} -236U T -236U T 94.666 2.60E-5 6 XKA2 -236U T 98.44 4.16E-5 9 XKA1 -236U T -236U T 110.421 |] XKB3 -236U T 111.298 |] 1.50E-5 4 XKB1 -236U T 111.964 |] XKB5II -236U T -236U T 114.407 |] XKB2 -236U T 115.012 |] 5.13E-6 16 XKB4 -236U T 115.377 |] XKO23 -236U T -236U T 11.619-20.714 10.34 15 XL (total) -236U T 11.619 0.238 4 XLL -236U T 13.438-13.615 3.70 4 XLA -236U T 15.399 0.116 3 XLC -236U T 15.727-18.206 5.01 13 XLB -236U T 19.507-20.714 1.267 22 XLG -236U T -236U T 71.78-80.95 |] KLL AUGER -236U T 88.15-98.43 |] 2.7E-6 4 KLX AUGER -236U T 104.51-115.59 |] KXY AUGER -236U T 5.01-21.6 10.3 8 L AUGER -240PU P 0.0 0+ 6561 Y 7 5255.75 15 -236U N 1.0 1.0 1 1.0 -236U L 0 0+ 23.43E6 Y 6 -236U A 5168.13 1572.74 181 -236U L 45.244 2 2+ 234 PS 6 -236U A 5123.6 2 27.16 191.4 -236U G 45.244 2 0.0462 9E2 589 12 -236U 2 G LC=429 9$MC=118.6 24 -236U L 149.477 6 4+ 124 PS 7 -236U A 5021.1 2 0.0863 1894.6 -236U G 104.233 5 0.00714 7E2 10.99 22 -236U 2 G LC=8.00 16$MC=2.22 4 -236U L 309.785 7 6+ 58 PS 3 -236U A 4863.5 2 10820E-718646 -236U G 160.308 3 4.045E-422E2 1.76 4 -236U 2 G KC=0.208 4$LC=1.132 23$MC=0.313 6 -236U L 522.25 5 8+ 24 PS 2 -236U A 4654.5 2 47000E-95 471 -236U G 212.46 5 0.000029 3E2 0.599 12 -236U 2 G KC=0.140 3$LC=0.335 7$MC=0.0920 18 -236U L 687.59 4 1- 3.78 NS 9 -236U A 4492.0 2 19300E-94 65.9 -236U G 538.1 1 1.47E-7 12E3 0.143 3 -236U 2 G KC=0.0623 12$LC=0.0587 12$MC=0.0160 3 -236U G 642.34 5 1.26E-5 3E1+(M2+E3) 0.15 2 -236U 2 G KC=0.112 10$LC=0.031 3 -236U G 687.56 103.56E-6 9E1 0.31 2 -236U 2 G KC=0.219 14$LC=0.069 9 -236U L 744.18 7 3- -236U A 4436.4 2 13000E-17 35000 -236U G 56.6 5 (E2) 199 10 -236U 2 G LC=145 7$MC=40.1 19 -236U G 594.5 3 -236U G 698.94 2.5E-8 -236U L 919.14 170+ -236U A 4264.3 3 65000E-18 27 -236U G 874.0 2 5.8E-7 6(E2) 0.0144 3 -236U 2 G KC=0.01060 15$LC=0.00283 6$MC=7.11E-4 14 -236U G 918.9 3 () -236U L 957.90 17(2)+ -236U A 4226.1 3 17000E-1 -236U G 912.4 3 7E-8 (M1) 0.050 1 -236U 2 G KC=0.0400 8$LC=0.00753 11$MC=0.00181 4 -236U G 958.0 2 1E-7 -236U L 960.3 3 (2)+ -236U A 4223.8 4 13000E-1 -236U G 810.8 4.3E-8 -236U G 915.1 3 6.3E-8 (M1+) -236U G 960.3 5E-8 -236U L 966.62 9 1- -236U A 4217.6 2 10000E-1 -236U G 222.44 -236U G 279.0 1 (M1+E2) 0.7 5 -236U 2 G KC=0.5 5$LC=0.15 4$MC=0.038 8 -236U G 921.2 2 2.2E-8 E1 0.00432 9 -236U 2 G KC=0.00353 7$LC=5.99E-4 12$MC=1.42E-4 3 -236U G 966.9 2 5E-8 E1 0.00397 8 -236U 2 G KC=0.00324 6$LC=5.49E-4 11$MC=1.30E-4 3 - +236U 240PU A DECAY (6561 Y) +236U H TYP=UPD$AUT=V.P.CHECHEV$CUT=30-JUN-2009$ +236U C References:1951In03, 1951We21, 1952As28, 1953Ki72, 1954Ba14, 1954Ch74, +236U 2C 1954Fa**, 1956Bu92, 1956Go43, 1956Ko67, 1957As83, 1958Sa21, 1959Do**, +236U 3C 1959Tr37, 1959Mi90, 1962Wa13, 1962Le11, 1963Ma50, 1964Hy02, 1967Be65, +236U 4C 1967Fi13, 1967Wh**, 1968Oe02, 1969Le05, 1970Sw**, 1971GuZY, 1972Sc01, +236U 5C 1972ClZS, 1972Go33, 1974HeYW, 1975Dr05, 1975OtZX, 1976GuZN, 1976Um01, +236U 6C 1977Ba69, 1978Ja11, 1979BuZC, 1981He16, 1981Mo**, 1982Ba56, 1983Ah02, +236U 7C 1984An25, 1984St06, 1984Ru04, 1984Lu04, 1984Be19, 1984Ah06, 1984Bo41, +236U 8C 1986LoZT, 1988SeZY, 1989Dy01, 1991Ry01, 1991Iv01, 1990An33, 1992Ba08, +236U 9C 1992Bl13, 1994Le28, 1994Ba91, 1994Ra27, 1994Sa63, 1994Le37, 1995Jo23, +236U AC 1996Vi07, 1999Sc**, 2000Sc**, 2000Ho27, 2003Au03, 2004BeZQ, 2004Si03, +236U BC 2005ChZU, 2006Br20, 2007Ah05, 2008Ki07 +236U T Auger electrons and X ray energies and emission intensities: +236U T {U Energy (keV)} {U Intensity} {U Line} +236U T +236U T 94.666 2.60E-5 6 XKA2 +236U T 98.44 4.16E-5 9 XKA1 +236U T +236U T 110.421 |] XKB3 +236U T 111.298 |] 1.50E-5 4 XKB1 +236U T 111.964 |] XKB5II +236U T +236U T 114.407 |] XKB2 +236U T 115.012 |] 5.13E-6 16 XKB4 +236U T 115.377 |] XKO23 +236U T +236U T 11.619-20.714 10.34 15 XL (total) +236U T 11.619 0.238 4 XLL +236U T 13.438-13.615 3.70 4 XLA +236U T 15.399 0.116 3 XLC +236U T 15.727-18.206 5.01 13 XLB +236U T 19.507-20.714 1.267 22 XLG +236U T +236U T 71.78-80.95 |] KLL AUGER +236U T 88.15-98.43 |] 2.7E-6 4 KLX AUGER +236U T 104.51-115.59 |] KXY AUGER +236U T 5.01-21.6 10.3 8 L AUGER +240PU P 0.0 0+ 6561 Y 7 5255.75 15 +236U N 1.0 1.0 1 +236U L 0 0+ 23.43E6 Y 6 +236U A 5168.13 1572.74 181 +236U L 45.244 2 2+ 234 PS 6 +236U A 5123.6 2 27.16 191.4 +236U G 45.244 2 0.0462 9E2 589 12 +236U 2 G LC=429 9$MC=118.6 24$NC=32.1 6 +236U 3 G OC=7.36 15 +236U L 149.477 6 4+ 124 PS 7 +236U A 5021.1 2 0.0863 1894.6 +236U G 104.233 5 0.00714 7E2 10.99 22 +236U 2 G LC=8.00 16$MC=2.22 4$NC=0.603 12 +236U 3 G OC=0.1385 30 +236U L 309.785 7 6+ 58 PS 3 +236U A 4863.5 2 0.00108218646 +236U G 160.308 3 4.045E-422E2 1.76 4 +236U 2 G KC=0.208 4$LC=1.132 23$MC=0.313 6$NC=0.0850 17 +236U 3 G OC=0.0196 4 +236U L 522.25 5 8+ 24 PS 2 +236U A 4654.5 2 0.000047 5471 +236U G 212.46 5 0.000029 3E2 0.599 12 +236U 2 G KC=0.140 3$LC=0.335 7$MC=0.0920 18$NC=0.0250 5 +236U 3 G OC=0.00577 12 +236U L 687.59 4 1- 3.78 NS 9 +236U A 4492.0 2 1.93E-5 465.9 +236U G 538.1 1 1.47E-7 12E3 0.143 3 +236U 2 G KC=0.0623 12$LC=0.0587 12$MC=0.0160 3$NC=0.00437 9 +236U 3 G OC=0.001024 12 +236U G 642.34 5 1.26E-5 3E1+(M2+E3) 0.15 2 +236U 2 G KC=0.112 10$LC=0.031 3 +236U G 687.56 103.56E-6 9E1 0.31 2 +236U 2 G KC=0.219 14$LC=0.069 9 +236U L 744.18 7 3- +236U A 4436.4 2 1.3E-8 735000 +236U G 56.6 5 (E2) 199 10 +236U 2 G LC=145 7$MC=40.1 19$NC=10.9 5 +236U 3 G OC=2.50 12 +236U G 594.5 3 +236U G 698.94 2.5E-8 +236U L 919.14 170+ +236U A 4264.3 3 6.5E-7 827 +236U G 874.0 2 5.8E-7 6(E2) 0.0144 3 +236U 2 G KC=0.01060 15$LC=0.00283 6$MC=0.000711 14$NC=1.920E-4 38 +236U 3 G OC=4.58E-5 9 +236U G 918.9 3 (E0) +236U L 957.90 17(2)+ +236U A 4226.1 3 1.7E-7 +236U G 912.4 3 7E-8 (M1) 0.050 1 +236U 2 G KC=0.0400 8$LC=0.00753 11$MC=0.00181 4$NC=0.000488 10 +236U 3 G OC=1.186E-4 20 +236U G 958.0 2 1E-7 +236U L 960.3 3 (2)+ +236U A 4223.8 4 1.3E-7 +236U G 810.8 4.3E-8 +236U G 915.1 3 6.3E-8 (M1+E0) +236U G 960.3 5E-8 +236U L 966.62 9 1- +236U A 4217.6 2 1E-7 +236U G 222.44 +236U G 279.0 1 (M1+E2) 0.7 5 +236U 2 G KC=0.5 5$LC=0.15 4$MC=0.038 8$NC=0.0102 2 +236U 3 G OC=0.00240 5 +236U G 921.2 2 2.2E-8 E1 0.00432 9 +236U 2 G KC=0.00353 7$LC=0.000599 12$MC=0.000142 3$NC=3.81E-5 7 +236U 3 G OC=9.22E-6 18 +236U G 966.9 2 5E-8 E1 0.00397 8 +236U 2 G KC=0.00324 6$LC=0.000549 11$MC=0.000130 3$NC=3.49E-5 6 +236U 3 G OC=8.44E-6 17 + diff --git a/HEN_HOUSE/spectra/lnhb/Pu-241.txt b/HEN_HOUSE/spectra/lnhb/Pu-241.txt index 5a136c3b9..7499901e6 100644 --- a/HEN_HOUSE/spectra/lnhb/Pu-241.txt +++ b/HEN_HOUSE/spectra/lnhb/Pu-241.txt @@ -1,121 +1,119 @@ -237U 241PU A DECAY (14.33 Y) -237U H TYP=Full$AUT=V.P.Chechev$CUT=30-SEP-2006$ -237U C Evaluation history: Type=Full;Author=V.P.Chechev;Cutoff date=30-SEP-2006 -237U C References: 1952Fr25, 1953As40, 1956Sh31, 1961Sm03, 1964Dz03, 1965Ba26, -237U 2C 1965Ba35, 1968Oe01, 1968Ah01, 1968Ba25, 1971GuZN, 1976BaZZ, 1976GuZN, -237U 3C 1976Um01, 1977VaYR, 1978DiZU, 1978El02, 1979Ce04, 1980Ma45, 1983DeZX, -237U 4C 1984Gl03, 1985Dr09, 1985He02, 1985Wi04, 1985Ag02, 1986Ti04, 1988ChZL, -237U 5C 1989Pa21, 1991Ry01, 1993Dr05, 1994Ba91, 1995Ak01, 1996FiZX, 1996Sc06, -237U 6C 1997DeZY, 1998Ak04, 1999Dr13, 1999ScZX, 1999YaZX, 2000Dr02, 2003Au03, -237U 7C 2004Fo01, 2005Ma88, 2006Ba41 -237U T Auger electrons and X ray energies and emission intensities: -237U T {U Energy (keV)} {U Intensity} {U Line} -237U T -237U T 94.666 0.000300 7 XKA2 -237U T 98.44 0.00047910 XKA1 -237U T -237U T 110.421 |] XKB3 -237U T 111.298 |] 0.000179 5 XKB1 -237U T 111.964 |] XKB5II -237U T -237U T 114.407 |] XKB2 -237U T 115.012 |] 0.000059 2 XKB4 -237U T 115.377 |] XKO23 -237U T -237U T 11.619-20.714 0.00116640 XL (total) -237U T 11.619 3.36E-5 12 XLL -237U T 13.438-13.615 0.00054319 XLA -237U T 15.399 4.44E-6 13 XLC -237U T 15.727-18.206 0.000477 8 XLB -237U T 19.507-20.714 0.000109 2 XLG -237U T -237U T 71.776-80.954 |] KLL AUGER -237U T 88.153-98.429 |] 0.000031 5 KLX AUGER -237U T 104.51-115.59 |] KXY AUGER -237U T 5.9-21.6 0.00117 6 L AUGER -241PU P 0.0 5/2+ 14.33 Y 4 5140.0 5 -237U N 4.098E4 4.098E4 0.000024 4.098E4 -237U L 0 1/2+ 6.749 D 16 -237U A 5054.6 5 0.352 413600 -237U L 11.39 2 3/2+ -237U A 5043.4 5 1.02 8 1000 -237U G 11.39 2 -237U L 56.30 125/2+ -237U A 4999.2 5 0.410 491300 -237U G 44.86 108.4E-7 10[M1+()E2] 131 25 -237U 2 G LC=96 18$MC=25 4 -237U G 56.30 122.5E-6 2(E2) 204 4 -237U 2 G LC=149 3$MC=41.1 8 -237U L 82.97 137/2+ -237U A 4973.1 5 1.31 12276 -237U G 26.660 40 (M1+E2) -237U G 71.64 9 2.9E-6 2(E2) 64.3 13 -237U 2 G LC=46.8 10$MC=13.0 3 -237U L 159.96 2 5/2+ 3.1 NS 1 -237U A 4897.3 5 83.2 161.3 -237U G 77.010 402.07E-5 4(M1) 9.86 20 -237U 2 G LC=7.44 15$MC=1.8 4 -237U G 103.680 5 0.000103 2[M1+()E2] 4.20 9 -237U 2 G LC=3.16 7$MC=0.767 15 -237U G 148.567 101.863E-4 8[M1+()E2] 7.05 14 -237U 2 G KC=5.55 11$LC=1.13 3$MC=0.275 6 -237U G 159.96 2 6.45E-6 9(E2) 1.78 3 -237U 2 G KC=0.208 4$LC=1.14 3$MC=0.316 7 -237U L 204.19 147/2+ -237U A 4853.8 5 12.09 334.5 -237U G 44.180 304.2E-6 2M1+()E2 60.4 29 -237U 2 G LC=45.3 25$MC=11.2 7 -237U G 121.22 5 7.0E-7 7(M1) 12.8 3 -237U 2 G KC=10.1 2$LC=2.00 4$MC=0.484 10 -237U L 260.95 179/2+ -237U A 4798.0 5 1.19 1218.6 -237U G 56.76 101.0E-6 1M1+()E2 27 3 -237U 2 G LC=21 3$MC=5.0 9 -237U G 100.94 117.2E-8 (E2) 12.8 3 -237U 2 G LC=9.3 2$MC=2.58 5 -237U L 274 1 (7/2)- 155 NS 6 -237U A 4785.1 110.020 8 90 -237U G 114 1 6.2E-6 12E1 0.0883 17 -237U 2 G LC=0.0665 13$MC=0.0163 3 -237U L 316 5 (9/2)- -237U A 4744 5 69672E-6 131 -237U L 327 3 11/2+ -237U A 4733 3 28689E-6 254 -237U L 367 3 (11/2)- -237U A 4694 3 28689E-6 132 - -241AM 241PU B- DECAY (14.33 Y) -241AM H TYP=Full$AUT=V.P.Chechev$CUT=30-SEP-2006$ -241AM C Evaluation history: Type=Full;Author=V.P.Chechev;Cutoff date=30-SEP-2006 -241AM C References: 1952Fr25, 1953As40, 1956Sh31, 1961Sm03, 1964Dz03, 1965Ba26, -241AM2C 1965Ba35, 1968Oe01, 1968Ah01, 1968Ba25, 1971GuZN, 1976BaZZ, 1976GuZN, -241AM3C 1976Um01, 1977VaYR, 1978DiZU, 1978El02, 1979Ce04, 1980Ma45, 1983DeZX, -241AM4C 1984Gl03, 1985Dr09, 1985He02, 1985Wi04, 1985Ag02, 1986Ti04, 1988ChZL, -241AM5C 1989Pa21, 1991Ry01, 1993Dr05, 1994Ba91, 1995Ak01, 1996FiZX, 1996Sc06, -241AM6C 1997DeZY, 1998Ak04, 1999Dr13, 1999ScZX, 1999YaZX, 2000Dr02, 2003Au03, -241AM7C 2004Fo01, 2005Ma88, 2006Ba41 -241AM T Auger electrons and X ray energies and emission intensities: -241AM T {U Energy (keV)} {U Intensity} {U Line} -241AM T -241AM T 102.03 XKA2 -241AM T 106.472 XKA1 -241AM T -241AM T 119.243 |] XKB3 -241AM T 120.284 |] XKB1 -241AM T 120.989 |] XKB5II -241AM T -241AM T 123.58 |] XKB2 -241AM T 124.127 |] XKB4 -241AM T 124.723 |] XKO23 -241AM T -241AM T -241AM T 77.04-85.638 |] KLL AUGER -241AM T 94.891-106.467 |] KLX AUGER -241AM T 112.72-124.97 |] KXY AUGER -241AM T 6.26-23.7 L AUGER -241PU P 0.0 5/2+ 14.33 Y 4 20.8 2 -241AM N 1.00E0 1.00E0 0.999975 1.00E0 -241AM L 0 5/2- 432.6 Y 6 -241AM B 20.8 2 99.99756 2 5.8 -241AMS B EAV=5.8 1 - +237U 241PU A DECAY (14.33 Y) +237U H TYP=FUL$AUT=V.P.CHECHEV$CUT=30-SEP-2006$ +237U C References:1952Fr25, 1953As40, 1956Sh31, 1961Sm03, 1964Dz03, 1965Ba26, +237U 2C 1965Ba35, 1968Oe01, 1968Ah01, 1968Ba25, 1971GuZN, 1972Cl**, 1976BaZZ, +237U 3C 1976GuZN, 1976Um01, 1977VaYR, 1978DiZU, 1978El02, 1979Ce04, 1980Ma45, +237U 4C 1983DeZX, 1984Gl03, 1985Dr09, 1985He02, 1985Wi04, 1985Ag02, 1986Ti04, +237U 5C 1988ChZL, 1989Pa21, 1991Ry01, 1993Dr05, 1994Ba91, 1995Ak01, 1996FiZX, +237U 6C 1996Sc06, 1997DeZY, 1998Ak04, 1999Dr13, 1999ScZX, 1999YaZX, 2000Dr02, +237U 7C 2003Au03, 2004Fo01, 2005Ma88, 2006Ba41 +237U T Auger electrons and X ray energies and emission intensities: +237U T {U Energy (keV)} {U Intensity} {U Line} +237U T +237U T 94.666 0.000300 7 XKA2 +237U T 98.44 0.00047910 XKA1 +237U T +237U T 110.421 |] XKB3 +237U T 111.298 |] 0.000179 5 XKB1 +237U T 111.964 |] XKB5II +237U T +237U T 114.407 |] XKB2 +237U T 115.012 |] 0.000059 2 XKB4 +237U T 115.377 |] XKO23 +237U T +237U T 11.619-20.714 0.00116640 XL (total) +237U T 11.619 3.36E-5 12 XLL +237U T 13.438-13.615 0.00054319 XLA +237U T 15.399 4.44E-6 13 XLC +237U T 15.727-18.206 0.000477 8 XLB +237U T 19.507-20.714 0.000109 2 XLG +237U T +237U T 71.776-80.954 |] KLL AUGER +237U T 88.153-98.429 |] 0.000031 5 KLX AUGER +237U T 104.51-115.59 |] KXY AUGER +237U T 5.9-21.6 0.00117 6 L AUGER +241PU P 0.0 5/2+ 14.33 Y 4 5140.0 5 +237U N 4.098E4 4.098E4 2.44E-5 +237U L 0 1/2+ 6.749 D 16 +237U A 5054.6 5 0.352 413600 +237U L 11.39 2 3/2+ +237U A 5043.4 5 1.02 81000 +237U G 11.39 2 +237U L 56.30 125/2+ +237U A 4999.2 5 0.410 491300 +237U G 44.86 108.4E-7 10[M1+E2] 131 25 +237U 2 G LC=96 18$MC=25 4 +237U G 56.30 122.5E-6 2(E2) 204 4 +237U 2 G LC=149 3$MC=41.1 8 +237U L 82.97 137/2+ +237U A 4973.1 5 1.31 12276 +237U G 26.660 40 (M1+E2) +237U G 71.64 9 2.9E-6 2(E2) 64.3 13 +237U 2 G LC=46.8 10$MC=13.0 3 +237U L 159.96 2 5/2+ 3.1 NS 1 +237U A 4897.3 5 83.2 161.3 +237U G 77.010 402.07E-5 4(M1) 9.86 20 +237U 2 G LC=7.44 15$MC=1.8 4 +237U G 103.680 5 0.000103 2[M1+E2] 4.20 9 +237U 2 G LC=3.16 7$MC=0.767 15 +237U G 148.567 101.863E-4 8[M1+E2] 7.05 14 +237U 2 G KC=5.55 11$LC=1.13 3$MC=0.275 6 +237U G 159.96 2 6.45E-6 9(E2) 1.78 3 +237U 2 G KC=0.208 4$LC=1.14 3$MC=0.316 7 +237U L 204.19 147/2+ +237U A 4853.8 5 12.09 334.5 +237U G 44.180 304.2E-6 2M1+E2 60.4 29 +237U 2 G LC=45.3 25$MC=11.2 7 +237U G 121.22 5 7.0E-7 7(M1) 12.8 3 +237U 2 G KC=10.1 2$LC=2.00 4$MC=0.484 10 +237U L 260.95 179/2+ +237U A 4798.0 5 1.19 1218.6 +237U G 56.76 101.0E-6 1M1+E2 27 3 +237U 2 G LC=21 3$MC=5.0 9 +237U G 100.94 117.2E-8 (E2) 12.8 3 +237U 2 G LC=9.3 2$MC=2.58 5 +237U L 274 1 (7/2)- 155 NS 6 +237U A 4785.1 110.020 890 +237U G 114 1 6.2E-6 12E1 0.0883 17 +237U 2 G LC=0.0665 13$MC=0.0163 3 +237U L 316 5 (9/2)- +237U A 4744 5 69672E-6 131 +237U L 327 3 11/2+ +237U A 4733 3 28689E-6 254 +237U L 367 3 (11/2)- +237U A 4694 3 28689E-6 132 + +241AM 241PU B- DECAY (14.33 Y) +241AM H TYP=FUL$AUT=V.P.CHECHEV$CUT=30-SEP-2006$ +241AM C References:1952Fr25, 1953As40, 1956Sh31, 1961Sm03, 1964Dz03, 1965Ba26, +241AM2C 1965Ba35, 1968Oe01, 1968Ah01, 1968Ba25, 1971GuZN, 1972Cl**, 1976BaZZ, +241AM3C 1976GuZN, 1976Um01, 1977VaYR, 1978DiZU, 1978El02, 1979Ce04, 1980Ma45, +241AM4C 1983DeZX, 1984Gl03, 1985Dr09, 1985He02, 1985Wi04, 1985Ag02, 1986Ti04, +241AM5C 1988ChZL, 1989Pa21, 1991Ry01, 1993Dr05, 1994Ba91, 1995Ak01, 1996FiZX, +241AM6C 1996Sc06, 1997DeZY, 1998Ak04, 1999Dr13, 1999ScZX, 1999YaZX, 2000Dr02, +241AM7C 2003Au03, 2004Fo01, 2005Ma88, 2006Ba41 +241AM T Auger electrons and X ray energies and emission intensities: +241AM T {U Energy (keV)} {U Intensity} {U Line} +241AM T +241AM T 102.03 XKA2 +241AM T 106.472 XKA1 +241AM T +241AM T 119.243 |] XKB3 +241AM T 120.284 |] XKB1 +241AM T 120.989 |] XKB5II +241AM T +241AM T 123.58 |] XKB2 +241AM T 124.127 |] XKB4 +241AM T 124.723 |] XKO23 +241AM T +241AM T +241AM T 77.04-85.638 |] KLL AUGER +241AM T 94.891-106.467 |] KLX AUGER +241AM T 112.72-124.97 |] KXY AUGER +241AM T 6.26-23.7 L AUGER +241PU P 0.0 5/2+ 14.33 Y 4 20.8 2 +241AM N 1.00E0 1.00E0 0.999976 1.00E0 +241AM L 0 5/2- 432.6 Y 6 +241AM B 20.8 2 99.99756 2 5.8 +241AMS B EAV=5.8 1 + diff --git a/HEN_HOUSE/spectra/lnhb/Pu-242.txt b/HEN_HOUSE/spectra/lnhb/Pu-242.txt index 5eceeb289..8c940cf35 100644 --- a/HEN_HOUSE/spectra/lnhb/Pu-242.txt +++ b/HEN_HOUSE/spectra/lnhb/Pu-242.txt @@ -1,50 +1,53 @@ -238U 242PU A DECAY (3.73E5 Y) -238U H TYP=Update$AUT=V.P. Chechev$CUT= -- $ -238U C Evaluation history: Type=Update;Author=V.P. Chechev;Cutoff date= -- -238U C References: 1956Bu64, 1956Bu92, 1956Hu96, 1956Ko67, 1956Me37, 1961Dr04, -238U 2C 1963Ma50, 1967Be65, 1968Ba25, 1969Be06, 1970Du02, 1972Sc01, 1976Bu23, -238U 3C 1976Os05, 1978MeZL, 1979Ag03, 1980Kh05, 1986LoZT, 1986Va33, 1988SeZY, -238U 4C 1990Po14, 1991Ry01, 1994Le37, 1996Sc06, 2000Ho27, 2002Ch52, 2003Au03, -238U 5C 2004BeZQ, 2005ChZU, 2008Ki07 -238U T Auger electrons and X ray energies and emission intensities: -238U T {U Energy (keV)} {U Intensity} {U Line} -238U T -238U T 94.666 1.80E-5 13 XKA2 -238U T 98.44 2.88E-5 21 XKA1 -238U T -238U T 110.421 |] XKB3 -238U T 111.298 |] 1.04E-5 8 XKB1 -238U T 111.964 |] XKB5II -238U T -238U T 114.407 |] XKB2 -238U T 115.012 |] 3.55E-6 27 XKB4 -238U T 115.377 |] XKO23 -238U T -238U T 11.62-21.73 8.71 21 XL (total) -238U T 11.62 0.191 7 XLL -238U T 13.44-13.62 3.07 10 XLA -238U T 15.4 0.098 4 XLC -238U T 15.73-18.21 4.33 13 XLB -238U T 19.51-21.73 1.021 30 XLG -238U T -238U T 71.78-80.95 |] KLL AUGER -238U T 88.15-98.43 |] 1.88E-6 29 KLX AUGER -238U T 104.51-115.59 |] KXY AUGER -238U T 5.9-21.6 8.40 19 L AUGER -242PU P 0.0 0+ 3.73E5 Y 3 4984.5 10 -238U N 1.0 1.0 1 1.0 -238U L 0 0+ 4.468E9 Y 5 -238U A 4902.3 1076.53 171 -238U L 44.915 132+ 206 PS 3 -238U A 4858.2 1023.44 171.62 -238U G 44.915 130.0384 8E2 610 12 -238U 2 G LC=445 9$MC=122.8 25 -238U L 148.39 3 4+ -238U A 4756.2 100.0304 13238 -238U G 103.50 4 0.00253 12E2 11.36 23 -238U 2 G LC=8.27 17$MC=2.29 5 -238U L 307.19 8 6+ -238U A 4600.1 100.00084 6 609 -238U G 158.80 8 0.00029820E2 1.83 4 -238U 2 G KC=0.210 4$LC=1.180 24$MC=0.326 7 - +238U 242PU A DECAY (3.73E5 Y) +238U H TYP=UPD$AUT=V.P.CHECHEV$CUT=30-SEP-2009$ +238U C References:1953As**, 1956Bu64, 1956Bu92, 1956Hu96, 1956Ko67, 1956Me37, +238U 2C 1956St**, 1961Dr04, 1963Ma50, 1967Be65, 1968Ba25, 1969Be06, 1970Du02, +238U 3C 1972Sc01, 1976Bu23, 1976Ba**, 1976Os05, 1978MeZL, 1979Ag03, 1980Kh05, +238U 4C 1986LoZT, 1986Va33, 1988SeZY, 1990Po14, 1991Ry01, 1994Le37, 1996Sc06, +238U 5C 1999Sc**, 2000Sc**, 2000Ho27, 2002Ch52, 2003Au03, 2004BeZQ, 2005ChZU, +238U 6C 2008Ki07 +238U T Auger electrons and X ray energies and emission intensities: +238U T {U Energy (keV)} {U Intensity} {U Line} +238U T +238U T 94.666 1.80E-5 13 XKA2 +238U T 98.44 2.88E-5 21 XKA1 +238U T +238U T 110.421 |] XKB3 +238U T 111.298 |] 1.04E-5 8 XKB1 +238U T 111.964 |] XKB5II +238U T +238U T 114.407 |] XKB2 +238U T 115.012 |] 3.55E-6 27 XKB4 +238U T 115.377 |] XKO23 +238U T +238U T 11.62-21.73 8.71 21 XL (total) +238U T 11.62 0.191 7 XLL +238U T 13.44-13.62 3.07 10 XLA +238U T 15.4 0.098 4 XLC +238U T 15.73-18.21 4.33 13 XLB +238U T 19.51-21.73 1.021 30 XLG +238U T +238U T 71.78-80.95 |] KLL AUGER +238U T 88.15-98.43 |] 1.88E-6 29 KLX AUGER +238U T 104.51-115.59 |] KXY AUGER +238U T 5.9-21.6 8.40 19 L AUGER +242PU P 0.0 0+ 3.73E5 Y 3 4984.5 10 +238U N 1.0 1.0 1 +238U L 0 0+ 4.468E9 Y 5 +238U A 4902.3 1076.53 171 +238U L 44.915 132+ 206 PS 3 +238U A 4858.2 1023.44 171.62 +238U G 44.915 130.0384 8E2 610 12 +238U 2 G LC=445 9$MC=122.8 25$NC=33.3 7 +238U 3 G OC=7.63 15 +238U L 148.39 3 4+ +238U A 4756.2 100.0304 13238 +238U G 103.50 4 0.00253 12E2 11.36 23 +238U 2 G LC=8.27 17$MC=2.29 5$NC=0.623 13 +238U 3 G OC=0.1431 29 +238U L 307.19 8 6+ +238U A 4600.1 100.00084 6609 +238U G 158.80 8 0.00029820E2 1.83 4 +238U 2 G KC=0.210 4$LC=1.180 24$MC=0.326 7$NC=0.0886 16 +238U 3 G OC=0.0204 4 + diff --git a/HEN_HOUSE/spectra/lnhb/Ra-223.txt b/HEN_HOUSE/spectra/lnhb/Ra-223.txt index 3b0c0f58f..9c0f9a581 100644 --- a/HEN_HOUSE/spectra/lnhb/Ra-223.txt +++ b/HEN_HOUSE/spectra/lnhb/Ra-223.txt @@ -1,204 +1,229 @@ -219RN 223RA A DECAY (11.43 D) -219RN H TYP=Full$AUT=V.P. Chechev$CUT=30-DEC-2010$ -219RN C Evaluation history: Type=Full;Author=V.P. Chechev;Cutoff date=30-DEC-2010 -219RN C References: 1954Ha60, 1957Pi31, 1957Pa07, 1959Ro51, 1961Ry02, 1962Gi04, -219RN2C 1962Wa18, 1964Wa19, 1965Ki05, 1966Po02, 1967JoZX, 1968Br17, 1969Be67, -219RN3C 1970Da08, 1970Kr01, 1971Gr17, 1972HeYM, 1974Ri05, 1976Bl13, 1977La19, -219RN4C 1977Ma31, 1987Mi10, 1991Ma16, 1991Ry01, 1996Sc06, 1998Sh02, 2000Sc47, -219RN5C 2001Br31, 2003Au03, 2008Ki07 -219RN T Auger electrons and X ray energies and emission intensities: -219RN T {U Energy (keV)} {U Intensity} {U Line} -219RN T -219RN T 81.07 14.86 23 XKA2 -219RN T 83.78 24.5 4 XKA1 -219RN T -219RN T 94.247 |] XKB3 -219RN T 94.868 |] 8.50 18 XKB1 -219RN T 95.449 |] XKB5II -219RN T -219RN T 97.48 |] XKB2 -219RN T 97.853 |] 2.72 7 XKB4 -219RN T 98.357 |] XKO23 -219RN T -219RN T 10.1372-17.2578 22.1 4 XL (total) -219RN T 10.1372 0.562 15 XLL -219RN T 11.5981-11.7259 10.00 25 XLA -219RN T 12.8551 0.168 5 XLC -219RN T 13.5219-14.5189 9.44 18 XLB -219RN T 16.2398-17.2578 1.91 4 XLG -219RN T -219RN T 62.017-68.885 |] KLL AUGER -219RN T 75.744-83.785 |] 1.73 21 KLX AUGER -219RN T 89.45-98.39 |] KXY AUGER -219RN T 5.66-17.95 30.1 4 L AUGER -223RA P 0.0 3/2+ 11.43 D 3 5978.99 21 -219RN N 1.0 1.0 1 1.0 -219RN G 490.8 3 0.0017 7 -219RN G 523.2 4 0.0014 6 -219RN G 532.9 4 0.0014 6 -219RN G 737.2 8 0.00028 14 -219RN L 0 5/2+ 3.98 S 3 -219RN A 5871.63 211.0 2 2420 -219RN L 4.47 1 (9/2)+ 15.4 NS 13 -219RN G 4.47 1 6.4E-6 E2 8600000 -219RN2 G MC=5100000 -219RN L 14.37 1 (7/2)+ 875 PS 30 -219RN A 5857.52 210.32 4 6480 -219RN G 9.90 2 0.0158 20M1+E2 0.050 2 990 40 -219RN2 G MC=750 30 -219RN G 14.37 1 0.0185 13M1+E2 0.116 2 539 15 -219RN2 G MC=409 11 -219RN L 126.77 2 (11/2)+ 402 PS 20 -219RN A 5747.14 2110.0 3 60 -219RN G 122.319 101.238 19M1+E2 0.132 14 7.34 11 -219RN2 G KC=5.88 9$LC=1.109 17$MC=0.265 4 -219RN L 158.64 1 7/2+ 42.3 PS 50 -219RN A 5715.84 2149.6 128.4 -219RN G 31.87 2 0.00010521(E2) 2010 30 -219RN2 G LC=1490 22$MC=398 6 -219RN G 144.27 2 3.36 8M1+E2 -0.12 1 4.59 7 -219RN2 G KC=3.69 6$LC=0.684 10$MC=0.1629 23 -219RN G 154.208 105.84 13M1 3.83 6 -219RN2 G KC=3.09 5$LC=0.560 8$MC=0.1331 19 -219RN G 158.635 100.713 16M1+E2 -0.18 11 3.46 12 -219RN2 G KC=2.77 13$LC=0.523 13$MC=0.125 4 -219RN L 269.48 1 3/2+ 14.2 PS 230 -219RN A 5606.99 2125.8 114.5 -219RN G 110.856 100.058 4E2 5.36 8 -219RN2 G KC=0.363 5$LC=3.69 6$MC=0.994 14 -219RN G 255.2 2 0.048 7 -219RN G 269.463 1014.23 32M1+E2 0.15 4 0.789 14 -219RN2 G KC=0.637 12$LC=0.1157 17$MC=0.0275 4 -219RN L 338.27 1 (5/2)+ 6.1 PS 28 -219RN A 5539.43 2110.6 104.8 -219RN G 179.54 6 0.154 14M1+E2 0.53 5 2.12 7 -219RN2 G KC=1.62 7$LC=0.376 6$MC=0.0922 16 -219RN G 323.871 104.06 8M1+E2 0.18 10 0.473 17 -219RN2 G KC=0.382 15$LC=0.0691 17$MC=0.0164 4 -219RN G 334.01 6 0.100 6(E2) 0.1007 15 -219RN2 G KC=0.0546 8$LC=0.0343 5$MC=0.00895 13 -219RN G 338.282 102.85 6M1 0.430 6 -219RN2 G KC=0.348 5$LC=0.0622 9$MC=0.01475 21 -219RN L 342.78 2 (5/2,7/2)- -219RN G 328.38 3 0.203 10(E1) 0.0271 4 -219RN2 G KC=0.0220 3$LC=0.00387 6$MC=9.16E-4 13 -219RN G 342.78 2 0.226 13E1 0.0246 4 -219RN2 G KC=0.0200 3$LC=0.00351 5$MC=8.28E-4 12 -219RN L 376.26 2 (9/2)+ 6.9 PS 38 -219RN A 5502.12 210.74 2544 -219RN G 249.49 3 0.038 10M1+E2 0.6 4 -219RN2 G KC=0.5 4$LC=0.125 20$MC=0.031 4 -219RN G 361.89 2 0.028 7 -219RN G 371.676 150.499 11M1 0.333 5 -219RN2 G KC=0.270 4$LC=0.0481 7$MC=0.01139 16 -219RN G 376.26 2 0.013 4 -219RN L 377.33 6 (7/2,9/2)- -219RN G 34.5 2 -219RN G 362.9 2 0.016 7 -219RN G 372.86 6 0.051 E1 0.0205 3 -219RN2 G KC=0.01667 24$LC=0.00289 4$MC=6.82E-4 10 -219RN L 397.1 4 + -219RN A 5481.7 5 0.008 3150 -219RN G 270.3 4 0.0007 4 -219RN L 445.03 1 (5/2)+ 6.2 PS 31 -219RN A 5434.60 211.60 249 -219RN G 102.2 2 0.0008 4 -219RN G 106.78 3 0.0233 14(M1) 10.89 16 -219RN2 G KC=8.77 13$LC=1.608 23$MC=0.382 6 -219RN G 175.65 150.017 4 -219RN G 430.6 3 0.020 6 -219RN G 445.033 121.28 4M1 0.205 3 -219RN2 G KC=0.1661 24$LC=0.0295 5$MC=0.00698 10 -219RN L 446.82 3 (5/2)- -219RN A 5432.83 210.50 8 27 -219RN G 69.5 1 0.007 3M1 7.36 11 -219RN2 G LC=5.60 9$MC=1.33 2 -219RN G 104.04 4 0.0194 21M1+E2 9.4 24 -219RN2 G KC=5 5$LC=3.3 16$MC=0.9 5 -219RN G 108.5 2 0.006 3 -219RN G 177.3 1 0.047 4 -219RN G 288.18 3 0.161 5E1 0.0364 6 -219RN2 G KC=0.0295 5$LC=0.00527 8$MC=1249E-6 18 -219RN G 432.45 3 0.0356 29 -219RN L 490.92 2 (5/2,7/2,9/2)- -219RN G 114.7 2 0.010 4 -219RN L 514.5 1 (9/2)+ -219RN A 5366.37 230.13 45 -219RN G 138.3 3 0.0017 7 -219RN G 355.7 2 0.0028 14 -219RN G 387.7 2 0.016 6 -219RN G 500.0 4 0.0014 6 -219RN G 510.0 4 0.0004 3 -219RN L 517.7 + -219RN G 70.9 2 0.0036 11 -219RN L 541.99 2 (7/2)+ -219RN A 5339.37 210.13 32 -219RN G 165.8 2 0.0054 28 -219RN G 383.35 2 0.007 4 -219RN G 527.611 130.073 4 -219RN G 537.6 1 0.0021 7 -219RN G 541.99 2 0.0014 6 -219RN L 594.1 1 (7/2)- -219RN A 5288.19 230.16 4 13 -219RN G 103.2 2 0.006 3M1+E2 9.6 24 -219RN2 G KC=5 5$LC=3.5 17$MC=0.9 5 -219RN G 147.2 3 0.006 3 -219RN G 251.6 3 0.055 10M1+E2 0.6 4 -219RN2 G KC=0.4 4$LC=0.122 20$MC=0.030 4 -219RN G 255.7 3 0.0055 28 -219RN G 579.6 3 0.0014 6 -219RN G 594.0 3 0.0014 6 -219RN L 598.72 2 (5/3,7/2,9/2)+ -219RN A 5283.65 210.093 21.8 -219RN G 221.32 240.036 6E1 0.0675 10 -219RN2 G KC=0.0543 8$LC=0.01005 15$MC=0.00239 4 -219RN G 260.4 3 0.0067 28 -219RN G 584.3 3 0.0014 6 -219RN G 598.721 240.092 4 -219RN L 623.68 4 + -219RN A 5259.14 210.042 35 -219RN G 247.2 5 0.0097 28 -219RN G 609.31 4 0.057 3 -219RN G 619.1 4 0.0036 11 -219RN G 623.68 4 0.009 4 -219RN L 646.1 1 + -219RN A 5237.12 230.041 27 -219RN G 131.6 2 0.006 3 -219RN G 199.3 3 0.0030 14 -219RN G 487.5 2 0.011 2 -219RN G 631.7 7 0.0004 3 -219RN G 641.7 4 0.0017 7 -219RN G 646.1 5 0.0004 4 -219RN L 672.6 5 + -219RN A 5211.1 5 0.0053 147 -219RN G 545.8 5 0.0011 6 -219RN L 711.3 1 + -219RN A 5173.10 230.026 17.9 -219RN G 112.6 -219RN G 368.56 120.009 4 -219RN G 696.9 7 0.0007 3 -219RN G 711.3 2 0.0037 10 -219RN L 732.8 1 + -219RN A 5151.98 230.021 16.6 -219RN G 286.0 4 0.0011 6 -219RN G 355.5 2 0.0043 14 -219RN G 390.1 2 0.0046 21 -219RN G 574.1 7 0.0011 6 -219RN G 718.4 4 0.0014 6 -219RN G 728.4 8 0.00028 14 -219RN G 732.8 6 0.0006 3 -219RN L 748 + -219RN A 5137.1 0.0017 168 -219RN L 773 + -219RN A 5112.5 0.0006 339 -219RN L 800 + -219RN A 5086 0.0003 470 -219RN L 830 + -219RN A 5056.5 0.0002 468 -219RN L 851 + -219RN A 5035.9 0.0004 175 -219RN L 861 + -219RN A 5026.1 0.00063 97 -219RN L 873 + -219RN A 5014.3 0.00044 117 - +219RN 223RA A DECAY (11.43 D) +219RN H TYP=FUL$AUT=V.P.CHECHEV$CUT=30-DEC-2010$ +219RN C References:1954Ha60, 1957Pi31, 1957Pa07, 1959Ro51, 1961Ry02, 1962Gi04, +219RN2C 1962Wa18, 1964Wa19, 1965Ki05, 1966Po02, 1967JoZX, 1968Br17, 1969Be67, +219RN3C 1970Da08, 1970Kr01, 1971Gr17, 1972HeYM, 1974Ri05, 1976Bl13, 1977La19, +219RN4C 1977Ma31, 1987Mi10, 1991Ma16, 1991Ry01, 1996Sc06, 1998Sh02, 2000Sc47, +219RN5C 2001Br31, 2003Au03, 2008Ki07 +219RN T Auger electrons and X ray energies and emission intensities: +219RN T {U Energy (keV)} {U Intensity} {U Line} +219RN T +219RN T 81.07 14.86 23 XKA2 +219RN T 83.78 24.5 4 XKA1 +219RN T +219RN T 94.247 |] XKB3 +219RN T 94.868 |] 8.50 18 XKB1 +219RN T 95.449 |] XKB5II +219RN T +219RN T 97.48 |] XKB2 +219RN T 97.853 |] 2.72 7 XKB4 +219RN T 98.357 |] XKO23 +219RN T +219RN T 10.1372-17.2578 22.1 4 XL (total) +219RN T 10.1372 0.562 15 XLL +219RN T 11.5981-11.7259 10.00 25 XLA +219RN T 12.8551 0.168 5 XLC +219RN T 13.5219-14.5189 9.44 18 XLB +219RN T 16.2398-17.2578 1.91 4 XLG +219RN T +219RN T 62.017-68.885 |] KLL AUGER +219RN T 75.744-83.785 |] 1.73 21 KLX AUGER +219RN T 89.45-98.39 |] KXY AUGER +219RN T 5.66-17.95 30.1 4 L AUGER +223RA P 0.0 3/2+ 11.43 D 3 5978.99 21 +219RN N 1.0 1.0 1 +219RN G 490.8 3 0.0017 7 +219RN G 523.2 4 0.0014 6 +219RN G 532.9 4 0.0014 6 +219RN G 737.2 8 0.00028 14 +219RN L 0 5/2+ 3.98 S 3 +219RN A 5871.63 211.0 22420 +219RN L 4.47 1 (9/2)+ 15.4 NS 13 +219RN G 4.47 1 6.4E-6 E2 8600000 +219RN2 G MC=5100000 +219RN L 14.37 1 (7/2)+ 875 PS 30 +219RN A 5857.52 210.32 46480 +219RN G 9.90 2 0.0158 20M1+E2 0.050 2 990 40 +219RN2 G MC=750 30$NC=194 8 +219RN3 G OC=41.0 15 +219RN G 14.37 1 0.0185 13M1+E2 0.116 2 539 15 +219RN2 G MC=409 11$NC=106 3 +219RN3 G OC=21.9 6 +219RN L 126.77 2 (11/2)+ 402 PS 20 +219RN A 5747.14 2110.0 360 +219RN G 122.319 101.238 19M1+E2 0.132 14 7.34 11 +219RN2 G KC=5.88 9$LC=1.109 17$MC=0.265 4$NC=0.0690 11 +219RN3 G OC=0.01505 23 +219RN L 158.64 1 7/2+ 42.3 PS 50 +219RN A 5715.84 2149.6 128.4 +219RN G 31.87 2 0.00010521(E2) 2010 30 +219RN2 G LC=1490 22$MC=398 6$NC=103.1 15 +219RN3 G OC=20.7 3 +219RN G 144.27 2 3.36 8M1+E2 -0.12 1 4.59 7 +219RN2 G KC=3.69 6$LC=0.684 10$MC=0.1629 23$NC=0.0425 6 +219RN3 G OC=0.00927 13 +219RN G 154.208 105.84 13M1 3.83 6 +219RN2 G KC=3.09 5$LC=0.560 8$MC=0.1331 19$NC=0.0347 5 +219RN3 G OC=0.00759 11 +219RN G 158.635 100.713 16M1+E2 -0.18 11 3.46 12 +219RN2 G KC=2.77 13$LC=0.523 13$MC=0.125 4$NC=0.0326 10 +219RN3 G OC=0.00710 19 +219RN L 269.48 1 3/2+ 14.2 PS 230 +219RN A 5606.99 2125.8 114.5 +219RN G 110.856 100.058 4E2 5.36 8 +219RN2 G KC=0.363 5$LC=3.69 6$MC=0.994 14$NC=0.259 4 +219RN3 G OC=0.0522 8 +219RN G 255.2 2 0.048 7 +219RN G 269.463 1014.23 32M1+E2 0.15 4 0.789 14 +219RN2 G KC=0.637 12$LC=0.1157 17$MC=0.0275 4$NC=0.00716 11 +219RN3 G OC=0.001566 23 +219RN L 338.27 1 (5/2)+ 6.1 PS 28 +219RN A 5539.43 2110.6 104.8 +219RN G 179.54 6 0.154 14M1+E2 0.53 5 2.12 7 +219RN2 G KC=1.62 7$LC=0.376 6$MC=0.0922 16$NC=0.0240 4 +219RN3 G OC=0.00516 8 +219RN G 323.871 104.06 8M1+E2 0.18 10 0.473 17 +219RN2 G KC=0.382 15$LC=0.0691 17$MC=0.0164 4$NC=0.00428 10 +219RN3 G OC=0.000935 22 +219RN G 334.01 6 0.100 6(E2) 0.1007 15 +219RN2 G KC=0.0546 8$LC=0.0343 5$MC=0.00895 13$NC=0.00233 4 +219RN3 G OC=0.000481 7 +219RN G 338.282 102.85 6M1 0.430 6 +219RN2 G KC=0.348 5$LC=0.0622 9$MC=0.01475 21$NC=0.00384 6 +219RN3 G OC=0.000841 12 +219RN L 342.78 2 (5/2,7/2)- +219RN G 328.38 3 0.203 10(E1) 0.0271 4 +219RN2 G KC=0.0220 3$LC=0.00387 6$MC=0.000916 13$NC=0.000237 4 +219RN3 G OC=5.08E-5 8 +219RN G 342.78 2 0.226 13E1 0.0246 4 +219RN2 G KC=0.0200 3$LC=0.00351 5$MC=0.000828 12$NC=0.000214 3 +219RN3 G OC=4.60E-5 7 +219RN L 376.26 2 (9/2)+ 6.9 PS 38 +219RN A 5502.12 210.74 2544 +219RN G 249.49 3 0.038 10M1+E2 0.6 4 +219RN2 G KC=0.5 4$LC=0.125 20$MC=0.031 4$NC=0.0081 9 +219RN3 G OC=0.00173 23 +219RN G 361.89 2 0.028 7 +219RN G 371.676 150.499 11M1 0.333 5 +219RN2 G KC=0.270 4$LC=0.0481 7$MC=0.01139 16$NC=0.00297 5 +219RN3 G OC=0.000650 9 +219RN G 376.26 2 0.013 4 +219RN L 377.33 6 (7/2,9/2)- +219RN G 34.5 2 +219RN G 362.9 2 0.016 7 +219RN G 372.86 6 0.051 E1 0.0205 3 +219RN2 G KC=0.01667 24$LC=0.00289 4$MC=0.000682 10$NC=1.766E-4 25 +219RN3 G OC=3.80E-5 6 +219RN L 397.1 4 +219RN A 5481.7 5 0.008 3150 +219RN G 270.3 4 0.0007 4 +219RN L 445.03 1 (5/2)+ 6.2 PS 31 +219RN A 5434.60 211.60 249 +219RN G 102.2 2 0.0008 4 +219RN G 106.78 3 0.0233 14(M1) 10.89 16 +219RN2 G KC=8.77 13$LC=1.608 23$MC=0.382 6$NC=0.0996 14 +219RN3 G OC=0.0218 3 +219RN G 175.65 150.017 4 +219RN G 430.6 3 0.020 6 +219RN G 445.033 121.28 4M1 0.205 3 +219RN2 G KC=0.1661 24$LC=0.0295 5$MC=0.00698 10$NC=0.00182 3 +219RN3 G OC=0.000398 6 +219RN L 446.82 3 (5/2)- +219RN A 5432.83 210.50 827 +219RN G 69.5 1 0.007 3M1 7.36 11 +219RN2 G LC=5.60 9$MC=1.33 2$NC=0.347 5 +219RN3 G OC=0.0759 11 +219RN G 104.04 4 0.0194 21M1+E2 9.4 24 +219RN2 G KC=5 5$LC=3.3 16$MC=0.9 5$NC=0.23 12 +219RN3 G OC=0.047 24 +219RN G 108.5 2 0.006 3 +219RN G 177.3 1 0.047 4 +219RN G 288.18 3 0.161 5E1 0.0364 6 +219RN2 G KC=0.0295 5$LC=0.00527 8$MC=0.001249 18$NC=0.000323 5 +219RN3 G OC=6.91E-5 10 +219RN G 432.45 3 0.0356 29 +219RN L 490.92 2 (5/2,7/2,9/2)- +219RN G 114.7 2 0.010 4 +219RN L 514.5 1 (9/2)+ +219RN A 5366.37 230.13 45 +219RN G 138.3 3 0.0017 7 +219RN G 355.7 2 0.0028 14 +219RN G 387.7 2 0.016 6 +219RN G 500.0 4 0.0014 6 +219RN G 510.0 4 0.0004 3 +219RN L 517.7 +219RN G 70.9 2 0.0036 11 +219RN L 541.99 2 (7/2)+ +219RN A 5339.37 210.13 32 +219RN G 165.8 2 0.0054 28 +219RN G 383.35 2 0.007 4 +219RN G 527.611 130.073 4 +219RN G 537.6 1 0.0021 7 +219RN G 541.99 2 0.0014 6 +219RN L 594.1 1 (7/2)- +219RN A 5288.19 230.16 413 +219RN G 103.2 2 0.006 3M1+E2 9.6 24 +219RN2 G KC=5 5$LC=3.5 17$MC=0.9 5$NC=0.24 13 +219RN3 G OC=0.048 25 +219RN G 147.2 3 0.006 3 +219RN G 251.6 3 0.055 10M1+E2 0.6 4 +219RN2 G KC=0.4 4$LC=0.122 20$MC=0.030 4$NC=0.0079 9 +219RN3 G OC=0.00168 24 +219RN G 255.7 3 0.0055 28 +219RN G 579.6 3 0.0014 6 +219RN G 594.0 3 0.0014 6 +219RN L 598.72 2 (5/2,7/2,9/2)+ +219RN A 5283.65 210.093 21.8 +219RN G 221.32 240.036 6E1 0.0675 10 +219RN2 G KC=0.0543 8$LC=0.01005 15$MC=0.00239 4$NC=0.000616 9 +219RN3 G OC=1.311E-4 19 +219RN G 260.4 3 0.0067 28 +219RN G 584.3 3 0.0014 6 +219RN G 598.721 240.092 4 +219RN L 623.68 4 +219RN A 5259.14 210.042 35 +219RN G 247.2 5 0.0097 28 +219RN G 609.31 4 0.057 3 +219RN G 619.1 4 0.0036 11 +219RN G 623.68 4 0.009 4 +219RN L 646.1 1 +219RN A 5237.12 230.041 27 +219RN G 131.6 2 0.006 3 +219RN G 199.3 3 0.0030 14 +219RN G 487.5 2 0.011 2 +219RN G 631.7 7 0.0004 3 +219RN G 641.7 4 0.0017 7 +219RN G 646.1 5 0.0004 4 +219RN L 672.6 5 +219RN A 5211.1 5 0.0053 147 +219RN G 545.8 5 0.0011 6 +219RN L 711.3 1 +219RN A 5173.10 230.026 17.9 +219RN G 112.6 +219RN G 368.56 120.009 4 +219RN G 696.9 7 0.0007 3 +219RN G 711.3 2 0.0037 10 +219RN L 732.8 1 +219RN A 5151.98 230.021 16.6 +219RN G 286.0 4 0.0011 6 +219RN G 355.5 2 0.0043 14 +219RN G 390.1 2 0.0046 21 +219RN G 574.1 7 0.0011 6 +219RN G 718.4 4 0.0014 6 +219RN G 728.4 8 0.00028 14 +219RN G 732.8 6 0.0006 3 +219RN L 748 +219RN A 5137.1 0.0017 168 +219RN L 773 +219RN A 5112.5 0.0006 339 +219RN L 800 +219RN A 5086 0.0003 470 +219RN L 830 +219RN A 5056.5 0.0002 468 +219RN L 851 +219RN A 5035.9 0.0004 175 +219RN L 861 +219RN A 5026.1 0.00063 97 +219RN L 873 +219RN A 5014.3 0.00044 117 + diff --git a/HEN_HOUSE/spectra/lnhb/Ra-224.txt b/HEN_HOUSE/spectra/lnhb/Ra-224.txt index b9bf1ca76..986bc0d63 100644 --- a/HEN_HOUSE/spectra/lnhb/Ra-224.txt +++ b/HEN_HOUSE/spectra/lnhb/Ra-224.txt @@ -1,58 +1,61 @@ -220RN 224RA A DECAY (3.631 D) -220RN H TYP=Update$AUT=A.L. Nichols$CUT=30-APR-2010$ -220RN2 H TYP=Full$AUT=A.L. Nichols$CUT=30-DEC-2003$ -220RN C Evaluation history: Type=Update;Author=A.L. Nichols;Cutoff date=30-APR-2010 -220RN2C Type=Full;Author=A.L. Nichols;Cutoff date=30-DEC-2003 -220RN C References: 1953As31, 1962Wa28, 1962Ll02, 1969Pe17, 1971Gr07, 1971So15, -220RN2C 1971Jo14, 1972DaZA, 1972Da38, 1977La19, 1977Ku15, 1982Sa36, 1983Va22, -220RN3C 1983Sc13, 1984Ge07, 1984Bo15, 1985Pr01, 1991Ry01, 1991Ho15, 1992Li05, -220RN4C 1993Ba72, 1995Ar33, 1996Sc06, 1997Ar04, 1997Tr17, 1998ScZM, 1999ScZX, -220RN5C 2002Ba85, 2002Ra45, 2003Au03, 2004Sc04, 2007St23, 2008Ki07 -220RN T Auger electrons and X ray energies and emission intensities: -220RN T {U Energy (keV)} {U Intensity} {U Line} -220RN T -220RN T 81.07 0.130 3 XKA2 -220RN T 83.78 0.214 4 XKA1 -220RN T -220RN T 94.247 |] XKB3 -220RN T 94.868 |] 0.0743 18 XKB1 -220RN T 95.449 |] XKB5II -220RN T -220RN T 97.48 |] XKB2 -220RN T 97.853 |] 0.0238 7 XKB4 -220RN T 98.357 |] XKO23 -220RN T -220RN T 10.137-17.28 0.373 16 XL (total) -220RN T 10.137 0.00774 20 XLL -220RN T 11.598-11.726 0.138 4 XLA -220RN T 12.855 0.00413 11 XLC -220RN T 13.52-14.565 0.191 5 XLB -220RN T 16.77-17.28 0.0424 9 XLG -220RN T -220RN T 62.017-68.885 |] KLL AUGER -220RN T 75.744-83.785 |] 0.0151 19 KLX AUGER -220RN T 89.45-98.39 |] KXY AUGER -220RN T 5.58-11.48 0.498 16 L AUGER -224RA P 0.0 0+ 3.631 D 2 5788.85 15 -220RN N 1.0 1.0 1 1.0 -220RN L 0 0+ 55.8 S 3 -220RN A 5685.48 1594.73 5 1 -220RN L 240.986 6 2+ 0.15 NS -220RN A 5448.80 155.25 5 1.04 -220RN G 240.986 6 4.12 4E2 0.276 4 -220RN2 G KC=0.1109 16$LC=0.1220 17$MC=0.0324 5 -220RN L 533.69 104+ -220RN A 5161.32 180.0072 8 17.9 -220RN G 292.7 1 0.0063 7E2 0.1487 21 -220RN2 G KC=0.0727 11$LC=0.0564 8$MC=0.01484 21 -220RN L 645.44 9 1- -220RN A 5051.56 170.0076 103.7 -220RN G 404.45 9 0.0022 5E1 0.0171724 -220RN2 G KC=0.01401 20$LC=0.00241 4$MC=5.68E-4 8 -220RN G 645.44 9 0.0054 9E1 0.0066310 -220RN2 G KC=0.00546 8$LC=8.94E-4 13$MC=2.10E-4 3 -220RN L 663.03 10(3)- -220RN A 5034.29 180.0030 5 6.4 -220RN G 422.04 100.0030 5[E1] 0.0156722 -220RN2 G KC=0.01280 18$LC=0.00219 3$MC=5.16E-4 8 - +220RN 224RA A DECAY (3.631 D) +220RN H TYP=UPD$AUT=A.L.NICHOLS$CUT=30-APR-2010$ +220RN2 H TYP=FUL$AUT=A.L.NICHOLS$CUT=30-DEC-2003$ +220RN C References:1953As31, 1962Wa28, 1962Ll02, 1962Ba**, 1969Pe17, 1971Gr07, +220RN2C 1971So15, 1971Jo14, 1972DaZA, 1972Da38, 1977La19, 1977Ku15, 1982Sa36, +220RN3C 1983Va22, 1983Sc13, 1984Ge07, 1984Bo15, 1985Pr01, 1991Ry01, 1991Ho15, +220RN4C 1992Li05, 1993Ba72, 1995Ar33, 1996Sc06, 1997Ar04, 1997Tr17, 1998ScZM, +220RN5C 1999ScZX, 2002Ba85, 2002Ra45, 2003Au03, 2004Sc04, 2007St23, 2008Ki07 +220RN T Auger electrons and X ray energies and emission intensities: +220RN T {U Energy (keV)} {U Intensity} {U Line} +220RN T +220RN T 81.07 0.130 3 XKA2 +220RN T 83.78 0.214 4 XKA1 +220RN T +220RN T 94.247 |] XKB3 +220RN T 94.868 |] 0.0743 18 XKB1 +220RN T 95.449 |] XKB5II +220RN T +220RN T 97.48 |] XKB2 +220RN T 97.853 |] 0.0238 7 XKB4 +220RN T 98.357 |] XKO23 +220RN T +220RN T 10.137-17.28 0.373 16 XL (total) +220RN T 10.137 0.00774 20 XLL +220RN T 11.598-11.726 0.138 4 XLA +220RN T 12.855 0.00413 11 XLC +220RN T 13.52-14.565 0.191 5 XLB +220RN T 16.77-17.28 0.0424 9 XLG +220RN T +220RN T 62.017-68.885 |] KLL AUGER +220RN T 75.744-83.785 |] 0.0151 19 KLX AUGER +220RN T 89.45-98.39 |] KXY AUGER +220RN T 5.58-11.48 0.498 16 L AUGER +224RA P 0.0 0+ 3.631 D 2 5788.85 15 +220RN N 1.0 1.0 1 +220RN L 0 0+ 55.8 S 3 +220RN A 5685.48 1594.73 51 +220RN L 240.986 6 2+ 0.15 NS +220RN A 5448.80 155.25 51.04 +220RN G 240.986 6 4.12 4E2 0.276 4 +220RN2 G KC=0.1109 16$LC=0.1220 17$MC=0.0324 5$NC=0.00843 12 +220RN3 G OC=0.001724 25 +220RN L 533.69 104+ +220RN A 5161.32 180.0072 817.9 +220RN G 292.7 1 0.0063 7E2 0.1487 21 +220RN2 G KC=0.0727 11$LC=0.0564 8$MC=0.01484 21$NC=0.00386 6 +220RN3 G OC=0.000795 12 +220RN L 645.44 9 1- +220RN A 5051.56 170.0076 103.7 +220RN G 404.45 9 0.0022 5E1 0.0171724 +220RN2 G KC=0.01401 20$LC=0.00241 4$MC=0.000568 8$NC=1.469E-4 21 +220RN3 G OC=3.16E-5 5 +220RN G 645.44 9 0.0054 9E1 0.0066310 +220RN2 G KC=0.00546 8$LC=0.000894 13$MC=0.000210 3$NC=5.43E-5 8 +220RN3 G OC=1.178E-5 17 +220RN L 663.03 10(3)- +220RN A 5034.29 180.0030 56.4 +220RN G 422.04 100.0030 5[E1] 0.0156722 +220RN2 G KC=0.01280 18$LC=0.00219 3$MC=0.000516 8$NC=1.336E-4 19 +220RN3 G OC=2.88E-5 4 + diff --git a/HEN_HOUSE/spectra/lnhb/Ra-225.txt b/HEN_HOUSE/spectra/lnhb/Ra-225.txt index ffaa1daa4..9a591e8b4 100644 --- a/HEN_HOUSE/spectra/lnhb/Ra-225.txt +++ b/HEN_HOUSE/spectra/lnhb/Ra-225.txt @@ -1,35 +1,35 @@ -225AC 225RA B- DECAY (14.82 D) -225AC H TYP=full$AUT=X. Huang$CUT=30-MAY-2007$ -225AC C Evaluation history: Type=full;Author=X. Huang;Cutoff date=30-MAY-2007 -225AC C References: 2008Ki07 -225AC T Auger electrons and X ray energies and emission intensities: -225AC T {U Energy (keV)} {U Intensity} {U Line} -225AC T -225AC T -225AC T -225AC T -225AC T 10.8701-18.9228 13.6 6 XL (total) -225AC T 10.8701 XLL -225AC T 12.5002-12.6505 XLA -225AC T 14.0807 XLC -225AC T 14.6024-16.6263 XLB -225AC T 17.813-18.9228 XLG -225AC T -225AC T 5.87-19.69 15.7 7 L AUGER -225RA P 0.0 1/2+ 14.82 D 19 356 5 -225AC N 1.0 1.0 1 1.0 -225AC L 0 3/2- 10.0 D 1 -225AC B 356 5 31.2 20 7.38 1 -225ACS B EAV=100.7 16 -225AC L 40.09 5 3/2+ 0.72 NS 3 -225AC B 316 5 68.8 20 6.87 -225ACS B EAV=88.3 16 -225AC G 40.09 5 30.0 7E1 1.293 19 -225AC2 G LC=0.974 14$MC=0.24 4 -225AC L 120.8 5/2- -225AC B 235 5 0.01 9.9 1U -225ACS B EAV=70.5 16 -225AC L 155.6 5/2+ -225AC B 200 5 0.01 10.1 2 -225ACS B EAV=54.0 15 - +225AC 225RA B- DECAY (14.82 D) +225AC H TYP=FUL$AUT=X.HUANG$CUT=30-MAY-2007$ +225AC C References:2008Ki07 +225AC T Auger electrons and X ray energies and emission intensities: +225AC T {U Energy (keV)} {U Intensity} {U Line} +225AC T +225AC T +225AC T +225AC T +225AC T 10.8701-18.9228 13.6 6 XL (total) +225AC T 10.8701 XLL +225AC T 12.5002-12.6505 XLA +225AC T 14.0807 XLC +225AC T 14.6024-16.6263 XLB +225AC T 17.813-18.9228 XLG +225AC T +225AC T 5.87-19.69 15.7 7 L AUGER +225RA P 0.0 1/2+ 14.82 D 19 356 5 +225AC N 1.0 1.0 1 1.0 +225AC L 0 3/2- 10.0 D 1 +225AC B 356 5 31.2 20 7.38 1 +225ACS B EAV=100.7 16 +225AC L 40.09 5 3/2+ 0.72 NS 3 +225AC B 316 5 68.8 20 6.87 +225ACS B EAV=88.3 16 +225AC G 40.09 5 30.0 7E1 1.293 19 +225AC2 G LC=0.974 14$MC=0.24 4$NC=0.062 9 +225AC3 G OC=0.013 2 +225AC L 120.8 5/2- +225AC B 235 5 0.01 9.9 1U +225ACS B EAV=70.5 16 +225AC L 155.6 5/2+ +225AC B 200 5 0.01 10.1 2 +225ACS B EAV=54.0 15 + diff --git a/HEN_HOUSE/spectra/lnhb/Ra-226.txt b/HEN_HOUSE/spectra/lnhb/Ra-226.txt index 979e01350..127ce1a8d 100644 --- a/HEN_HOUSE/spectra/lnhb/Ra-226.txt +++ b/HEN_HOUSE/spectra/lnhb/Ra-226.txt @@ -1,54 +1,55 @@ -222RN 226RA A DECAY (1600 Y) -222RN H TYP=Update$AUT=V.Chisté$CUT=01-JAN-2007$ -222RN2 H TYP=Full$AUT=M.M.Bé$CUT=31-DEC-2003$ -222RN C Evaluation history: Type=Update;Author=V.Chisté;Cutoff date=01-JAN-2007 -222RN2C Type=Full;Author=M.M.Bé;Cutoff date=31-DEC-2003 -222RN C References: 1929Ward, 1935Gl02, 1949Ko01, 1956Se10, 1959Ma12, 1959Go80, -222RN2C 1960St20, 1963Ba62, 1966Ra13, 1969Wa27, 1969Li10, 1970Mo28, 1969Gr33, -222RN3C 1971Lo19, 1973De50, 1973Alek, 1975Ha31, 1977Zo01, 1981Mo28, 1982Ak03, -222RN4C 1982Fa10, 1983Ol01, 1983Sc13, 1990Ho28, 1991Li11, 1991Ry01, 1996Ak02, -222RN5C 1996El01, 1996Sc06, 1998Mo14, 2000Sa32, 2001La14, 2002De03, 2002Ba85, -222RN6C 2003Au03, 2002MoZP, 2004Mo07, 2007BeZP -222RN T Auger electrons and X ray energies and emission intensities: -222RN T {U Energy (keV)} {U Intensity} {U Line} -222RN T -222RN T 81.07 0.192 4 XKA2 -222RN T 83.78 0.317 6 XKA1 -222RN T -222RN T 94.247 |] XKB3 -222RN T 94.868 |] 0.1098 25 XKB1 -222RN T 95.449 |] XKB5II -222RN T -222RN T 97.48 |] XKB2 -222RN T 97.853 |] 0.0351 10 XKB4 -222RN T 98.357 |] XKO23 -222RN T -222RN T 10.14-17.26 0.807 14 XL (total) -222RN T 10.14 0.0156 4 XLL -222RN T 11.5981-11.7259 0.277 7 XLA -222RN T 12.8551 0.00919 24 XLC -222RN T 13.5219-15.1631 0.412 9 XLB -222RN T 16.2398-17.26 0.0927 20 XLG -226RA P 0.0 0+ 1600 Y 7 4870.62 25 -222RN N 1.0 1.0 1 1.0 -222RN L 0 0+ 3.8232 D 8 -222RN A 4784.34 2594.038 401 -222RN L 186.211 132+ 0.32 NS -222RN A 4601 1 5.95 4 0.96 -222RN G 186.211 133.555 19E2 0.677 10 -222RN2 G KC=0.190 3$LC=0.360 5$MC=0.0963 14 -222RN L 448.37 124+ -222RN A 4340 1 0.0066 2210.4 -222RN G 262.27 5 0.0055 18[E2] 0.209 4 -222RN2 G KC=0.0923 14$LC=0.0868 14$MC=0.0230 4 -222RN L 600.66 5 1- -222RN A 4191 2 0.0008 4.5 -222RN G 414.60 5 0.0003 [E1] 0.0162823 -222RN2 G KC=0.01329 19$LC=0.00228 4$MC=5.37E-4 8 -222RN G 600.66 5 0.0005 [E1] 0.0076211 -222RN2 G KC=0.00627 9$LC=1034E-6 15$MC=2.43E-4 4 -222RN L 635.47 153- -222RN A 4160 2 0.0002 8.65 -222RN G 449.37 100.0002 [E1] 0.0137320 -222RN2 G KC=0.01123 16$LC=0.00191 3$MC=4.49E-4 7 - +222RN 226RA A DECAY (1600 Y) +222RN H TYP=UPD$AUT=V.CHISTE$CUT=01-JAN-2007$ +222RN2 H TYP=FUL$AUT=M.-M.BE$CUT=31-DEC-2003$ +222RN C References:1928Cu**, 1928Br**, 1928Wa**, 1929Wa**, 1930Me**, 1935Gl02, +222RN2C 1939Gu**, 1949Ko01, 1956Se10, 1959Ma12, 1959Go80, 1960St20, 1963Ba62, +222RN3C 1966Ra13, 1969Wa27, 1969Li10, 1970Mo28, 1969Gr33, 1971Lo19, 1973De50, +222RN4C 1973Alek, 1975Ha31, 1977Zo01, 1981Mo28, 1982Ak03, 1982Fa10, 1983Ol01, +222RN5C 1983Sc13, 1990Mo**, 1990Ho28, 1991Li11, 1991Ry01, 1993Di09, 1996Ak02, +222RN6C 1996El01, 1996Sc06, 1998Mo14, 2000Sa32, 2001La14, 2002De03, 2002Ba85, +222RN7C 2003Au03, 2002MoZP, 2004Mo07, 2007BeZP +222RN T Auger electrons and X ray energies and emission intensities: +222RN T {U Energy (keV)} {U Intensity} {U Line} +222RN T +222RN T 81.07 0.192 4 XKA2 +222RN T 83.78 0.317 6 XKA1 +222RN T +222RN T 94.247 |] XKB3 +222RN T 94.868 |] 0.1098 25 XKB1 +222RN T 95.449 |] XKB5II +222RN T +222RN T 97.48 |] XKB2 +222RN T 97.853 |] 0.0351 10 XKB4 +222RN T 98.357 |] XKO23 +222RN T +222RN T 10.14-17.26 0.807 14 XL (total) +222RN T 10.14 0.0156 4 XLL +222RN T 11.5981-11.7259 0.277 7 XLA +222RN T 12.8551 0.00919 24 XLC +222RN T 13.5219-15.1631 0.412 9 XLB +222RN T 16.2398-17.26 0.0927 20 XLG +226RA P 0.0 0+ 1600 Y 7 4870.62 25 +222RN N 1.0 1.0 1 +222RN L 0 0+ 3.8232 D 8 +222RN A 4784.34 2594.038 401 +222RN L 186.211 132+ 0.32 NS +222RN A 4601 1 5.95 40.96 +222RN G 186.211 133.555 19E2 0.677 10 +222RN2 G KC=0.190 3$LC=0.360 5$MC=0.0963 14$NC=0.0251 4 +222RN3 G OC=0.00510 8 +222RN L 448.37 124+ +222RN A 4340 1 0.0066 2210.4 +222RN G 262.27 5 0.0055 18[E2] 0.209 4 +222RN2 G KC=0.0923 14$LC=0.0868 14$MC=0.0230 4$NC=0.00598 10 +222RN3 G OC=0.001226 20 +222RN L 600.66 5 1- +222RN A 4191 2 0.0008 4.5 +222RN G 414.60 5 0.0003 [E1] 0.0162823 +222RN2 G KC=0.01329 19$LC=0.00228 4$MC=0.000537 8$NC=0.000139 2 +222RN G 600.66 5 0.0005 [E1] 0.0076211 +222RN2 G KC=0.00627 9$LC=0.001034 15$MC=0.000243 4$NC=6.29E-5 9 +222RN L 635.47 153- +222RN A 4160 2 0.0002 8.65 +222RN G 449.37 100.0002 [E1] 0.0137320 +222RN2 G KC=0.01123 16$LC=0.00191 3$MC=0.000449 7$NC=1.163E-4 17 + diff --git a/HEN_HOUSE/spectra/lnhb/Ra-228.txt b/HEN_HOUSE/spectra/lnhb/Ra-228.txt index f91b2915c..364da0b5d 100644 --- a/HEN_HOUSE/spectra/lnhb/Ra-228.txt +++ b/HEN_HOUSE/spectra/lnhb/Ra-228.txt @@ -1,45 +1,49 @@ -228AC 228RA B- DECAY (5.75 Y) -228AC H TYP=Full$AUT=A.Luca$CUT=31-DEC-2008$ -228AC C Evaluation history: Type=Full;Author=A.Luca;Cutoff date=31-DEC-2008 -228AC C References: 1931Cu01, 1960Du11, 1961To10, 1962Ma58, 1972HeYY, 1995So11, -228AC2C 1997Ar08, 2003Au03 -228AC T Auger electrons and X ray energies and emission intensities: -228AC T {U Energy (keV)} {U Intensity} {U Line} -228AC T -228AC T -228AC T -228AC T -228AC T 10.8701-18.9228 9.6 19 XL (total) -228AC T 10.8701 0.24 8 XLL -228AC T 12.5002-12.6505 4.0 11 XLA -228AC T 14.0807 0.046 14 XLC -228AC T 14.6024-16.6263 4.3 7 XLB -228AC T 17.813-18.9228 1.01 17 XLG -228AC T -228AC T 5.87-19.67 12 5 L AUGER -228RA P 0.0 0+ 5.75 Y 4 45.8 7 -228AC N 1.0 1.0 1 1.0 -228AC L 0 3+ 6.15 H 3 -228AC L 6.28 3 1- -228AC B 39.5 7 12 10 7.07 1 -228ACS B EAV=10.0 2 -228AC G 6.28 3 1.8E-6 15M2 6.68E6 19 -228AC2 G MC=4.93E6 14 -228AC L 6.67 2 1+ -228AC B 39.1 7 49 10 6.45 -228ACS B EAV=9.9 2 -228AC G 6.67 2 0.000057 9E2 1.56E6 4 -228AC2 G MC=1.172E6 24 -228AC L 20.19 3 1- -228AC B 25.6 7 8.7 9 6.2 1 -228ACS B EAV=6.5 2 -228AC G 13.520 361.6 1E1 5.86 10 -228AC2 G MC=4.48 7 -228AC L 33.07 111+ -228AC B 12.7 7 30 10 5.11 -228ACS B EAV=3.2 2 -228AC G 12.88 110.30 6E1 6.67 18 -228AC2 G MC=5.11 14 -228AC G 26.40 110.14 5M1+E2 0.07 201 4 -228AC2 G LC=151 3$MC=37.2 7 - +228AC 228RA B- DECAY (5.75 Y) +228AC H TYP=FUL$AUT=A.LUCA$CUT=31-DEC-2008$ +228AC C References:1931Cu01, 1960Du11, 1961To10, 1962Ma58, 1972HeYY, 1995So11, +228AC2C 1997Ar08, 2003Au03 +228AC T Auger electrons and X ray energies and emission intensities: +228AC T {U Energy (keV)} {U Intensity} {U Line} +228AC T +228AC T +228AC T +228AC T +228AC T 10.8701-18.9228 9.6 19 XL (total) +228AC T 10.8701 0.24 8 XLL +228AC T 12.5002-12.6505 4.0 11 XLA +228AC T 14.0807 0.046 14 XLC +228AC T 14.6024-16.6263 4.3 7 XLB +228AC T 17.813-18.9228 1.01 17 XLG +228AC T +228AC T 5.87-19.67 12 5 L AUGER +228RA P 0.0 0+ 5.75 Y 4 45.8 7 +228AC N 1.0 1.0 1 1.0 +228AC L 0 3+ 6.15 H 3 +228AC L 6.28 3 1- +228AC B 39.5 7 12 10 7.07 1 +228ACS B EAV=10.0 2 +228AC G 6.28 3 1.8E-6 15M2 6.68E6 19 +228AC2 G MC=4.93E6 14$NC=1.38E6 4 +228AC3 G OC=3.14E5 9 +228AC L 6.67 2 1+ +228AC B 39.1 7 49 10 6.45 +228ACS B EAV=9.9 2 +228AC G 6.67 2 0.000057 9E2 1.56E6 4 +228AC2 G MC=1.172E6 24$NC=3.12E5 7 +228AC3 G OC=6.75E4 14 +228AC L 20.19 3 1- +228AC B 25.6 7 8.7 9 6.2 1 +228ACS B EAV=6.5 2 +228AC G 13.520 361.6 1E1 5.86 10 +228AC2 G MC=4.48 7$NC=1.135 18 +228AC3 G OC=0.218 4 +228AC L 33.07 111+ +228AC B 12.7 7 30 10 5.11 +228ACS B EAV=3.2 2 +228AC G 12.88 110.30 6E1 6.67 18 +228AC2 G MC=5.11 14$NC=1.29 4 +228AC3 G OC=0.246 7 +228AC G 26.40 110.14 5M1+E2 0.07 201 4 +228AC2 G LC=151 3$MC=37.2 7$NC=9.87 19 +228AC3 G OC=2.27 5 + diff --git a/HEN_HOUSE/spectra/lnhb/Rb-82.txt b/HEN_HOUSE/spectra/lnhb/Rb-82.txt index ec9f69e79..efb5260dd 100644 --- a/HEN_HOUSE/spectra/lnhb/Rb-82.txt +++ b/HEN_HOUSE/spectra/lnhb/Rb-82.txt @@ -1,146 +1,167 @@ - 82KR 82RB EC DECAY (1.2652 M) - 82KR H TYP=Full$AUT=M.M. Bé$CUT=30-DEC-2014$ - 82KR C Evaluation history: Type=Full;Author=M.M. Bé;Cutoff date=30-DEC-2014 - 82KR C References: 1953Li27, 1953Kr10, 1962Sa10, 1967Vr07, 1969Ra06, 1970Gr01, - 82KR2C 1970Hr02, 1978Gr17, 1983Me08, 1985Ze03, 1987Ju01, 1987Wo01, 1987Ho06, - 82KR3C 1996Sc06, 1998Sc28, 2000Sc47, 2002Ba85, 2008Ki07, 2012Gr03, 2012Wa38 - 82KR T Auger electrons and X ray energies and emission intensities: - 82KR T {U Energy (keV)} {U Intensity} {U Line} - 82KR T - 82KR T 12.599 0.760 9 XKA2 - 82KR T 12.65 1.466 16 XKA1 - 82KR T - 82KR T 14.105 |] XKB3 - 82KR T 14.113 |] 0.351 5 XKB1 - 82KR T 14.238 |] XKB5II - 82KR T - 82KR T 14.315 |] XKB2 - 82KR T 14.328 |] 0.0354 12 XKB4 - 82KR T - 82KR T 1.387-1.911 0.1066 18 XL (total) - 82KR T 1.387 0.00262 7 XLL - 82KR T 1.585-1.586 0.0647 15 XLA - 82KR T 1.439 0.00127 4 XLC - 82KR T 1.637-1.831 0.0377 9 XLB - 82KR T 1.706-1.911 0.000373 7 XLG - 82KR T - 82KR T 10.398-10.885 |] KLL AUGER - 82KR T 12.077-12.637 |] 1.394 20 KLX AUGER - 82KR T 13.741-14.298 |] KXY AUGER - 82KR T 1.09-1.91 4.961 25 L AUGER - 82RB P 0.0 1+ 1.2652 M 45 4403 3 - 82KR N 1.0 1.0 1 1.0 - 82KR L 0 0+ STABLE - 82KR E 81.81 243.01 34.6 - 82KR2 E EAV=1535.6 15$CK=0.8779 14$CL=0.1014 12$CM=0.0183 4$CN=0.0024 2 - 82KR L 776.522 102+ - 82KR E 13.10 191.06 24.8 - 82KR2 E EAV=1168.5 15$CK=0.8778 14$CL=0.1016 12$CM=0.0183 4$CN=0.0024 2 - 82KR G 776.520 1015.02 19E2 9.23E-413 - 82KR2 G KC=8.19E-4 12$LC=8.84E-5 13$MC=1.43E-5 2 - 82KR L 1474.894 102+ 15 PS - 82KR E 0.135 70.0284 146.3 - 82KR2 E EAV=844.1 14$CK=0.8776 14$CL=0.1017 12$CM=0.0183 4$CN=0.0024 2 - 82KR G 698.37 5 0.159 11 - 82KR G 1474.880 100.0904 24E2 2.89E-4 4 - 82KR2 G KC=1.90E-4 3$LC=2.00E-5 3 - 82KR L 1487.62 7 0+ 10 PS - 82KR E 0.0444 410.0096 96.7 - 82KR2 E EAV=838.3 14 - 82KR G 711.2 1 0.060 4 - 82KR L 1820.6 4 4+ - 82KR E 0.00007 70.00003 311.5 2U - 82KR2 E EAV=735.6 15 - 82KR G 1044.1 5 0.0009 6 - 82KR L 1956.797 20(2)+ - 82KR E 0.00890 140.0047 86.7 - 82KR2 E EAV=624.8 14 - 82KR G 1180.270 200.0165 15 - 82KR G 1956.750 400.0068 6 - 82KR L 2171.68 3 0+ - 82KR E 0.317 60.283 55 - 82KR2 E EAV=528.6 14$CK=0.8773 14$CL=0.1019 12$CM=0.0184 4$CN=0.0024 2 - 82KR G 696.86 150.071 6 - 82KR G 1395.140 300.529 8E2 - 82KR L 2450.09 9 0(+),1,2+ - 82KR E 0.0050 40.0105 86.3 - 82KR2 E EAV=405.7 14$CK=0.8771 14$CL=0.1021 12$CM=0.0184 4$CN=0.0024 2 - 82KR G 975.2 1 0.0084 11 - 82KR G 1673.55 9 0.0071 5 - 82KR L 2479.72 3 1,2+ - 82KR E 0.0288 70.0682 145.5 - 82KR2 E EAV=392.7 14$CK=0.8771 14$CL=0.1021 12$CM=0.0184 4$CN=0.0024 2 - 82KR G 522.8 5 0.0045 15 - 82KR G 992.2 1 0.0018 8 - 82KR G 1703.190 400.0505 11 - 82KR G 2479.65 4 0.0401 16 - 82KR L 2509.0 5 + - 82KR E 0.00041 250.0011 67.4 - 82KR2 E EAV=380.0 14 - 82KR G 1021.4 5 0.0015 9 - 82KR L 2556.3 7 (4)+ - 82KR E 0.00007 40.00023 1110 2U - 82KR2 E EAV=359.4 14 - 82KR G 1081.4 7 0.00030 15 - 82KR L 2561.7 5 + - 82KR E 0.00033 190.0011 67.3 - 82KR2 E EAV=357.0 14 - 82KR G 1086.8 5 0.0014 8 - 82KR L 2655.82 101,2(+)+ - 82KR E 0.00284 340.0142 176.1 - 82KR2 E EAV=316.2 13$CK=0.8770 14$CL=0.1022 12$CM=0.0184 4$CN=0.0024 2 - 82KR G 1168.20 200.0014 6 - 82KR G 1181.3 0.0030 15 - 82KR G 1879.18 150.0101 6 - 82KR G 2655.85 150.0026 6 - 82KR L 2944.14 4 (2)+ - 82KR E 0.0500 195.4 - 82KR2 E CK=0.8766 15$CL=0.1025 12$CM=0.0185 4$CN=0.0024 2 - 82KR G 1123.6 7 0.0008 6 - 82KR G 2167.590 400.0431 6 - 82KR G 2944.0 2 0.0075 15 - 82KR L 3186.82 5 0,1,2+ - 82KR E 0.0265 155.5 - 82KR2 E CK=0.8763 15$CL=0.1028 12$CM=0.0185 4$CN=0.0024 2 - 82KR G 1698.7 3 0.0015 8 - 82KR G 1711.9 4 0.00165 30 - 82KR G 2410.26 5 0.0233 12 - 82KR L 3355.32 191,2(+)+ - 82KR E 0.00134 136.7 - 82KR G 2578.70 200.00105 11 - 82KR G 3355.6 5 0.00028530 - 82KR L 3457.5 7 1,2(+)+ - 82KR E 0.000111237.7 - 82KR G 3457.4 7 0.00011123 - 82KR L 3564.6 3 0(+),1,2+ - 82KR E 0.0034 316 - 82KR G 1607.7 3 0.00225 30 - 82KR G 2788.4 5 0.00114 8 - 82KR L 3716.83 150(),1,2+ - 82KR E 0.008 35.8 - 82KR G 2241.98 170.0009 8 - 82KR G 2940.00 300.0071 29 - 82KR L 3741.96 8 + - 82KR E 0.0036 65.9 - 82KR G 1785.13 7 0.0030 6 - 82KR G 2966.3 7 0.00060 5 - 82KR L 3815.1 101,2(+)+ - 82KR E 0.0019 85.6 - 82KR G 869.3 4 0.0014 8 - 82KR G 3815.0 100.00045131 - 82KR L 3835.8 5 1,2+ - 82KR E 0.00089 56.3 - 82KR G 3059.2 5 0.00068 5 - 82KR G 3836 1 0.00021923 - 82KR L 3881.1 5 1,2(+)+ - 82KR E 0.00024 56.8 - 82KR G 3104.5 5 0.00015 5 - 82KR G 3881 1 0.00008721 - 82KR L 3911.1 101,2(+)+ - 82KR E 0.00010 27.1 - 82KR G 3911.0 100.00010515 - 82KR L 3956.1 101,2(+)+ - 82KR E 0.00009 27.1 - 82KR2 E CK=0.8722 15$CL=0.1061 12$CM=0.0192 4$CN=0.0025 2 - 82KR G 3956.0 100.00009015 - + 82KR 82RB EC DECAY (1.2652 M) + 82KR H TYP=FUL$AUT=M.-M.BE$CUT=30-DEC-2014$ + 82KR C References:1953Li27, 1953Kr10, 1962Sa10, 1967Vr07, 1969Ra06, 1970Gr01, + 82KR2C 1970Hr02, 1978Gr17, 1983Me08, 1985Ze03, 1987Ju01, 1987Wo01, 1987Ho06, + 82KR3C 1996Sc06, 1998Sc28, 2000Sc47, 2002Ba85, 2008Ki07, 2012Gr03, 2012Wa38 + 82KR T Auger electrons and X ray energies and emission intensities: + 82KR T {U Energy (keV)} {U Intensity} {U Line} + 82KR T + 82KR T 12.599 0.760 9 XKA2 + 82KR T 12.65 1.466 16 XKA1 + 82KR T + 82KR T 14.105 |] XKB3 + 82KR T 14.113 |] 0.351 5 XKB1 + 82KR T 14.238 |] XKB5II + 82KR T + 82KR T 14.315 |] XKB2 + 82KR T 14.328 |] 0.0354 12 XKB4 + 82KR T + 82KR T 1.387-1.911 0.1066 18 XL (total) + 82KR T 1.387 0.00262 7 XLL + 82KR T 1.585-1.586 0.0647 15 XLA + 82KR T 1.439 0.00127 4 XLC + 82KR T 1.637-1.831 0.0377 9 XLB + 82KR T 1.706-1.911 0.000373 7 XLG + 82KR T + 82KR T 10.398-10.885 |] KLL AUGER + 82KR T 12.077-12.637 |] 1.394 20 KLX AUGER + 82KR T 13.741-14.298 |] KXY AUGER + 82KR T 1.09-1.91 4.961 25 L AUGER + 82RB P 0.0 1+ 1.2652 M 45 4403 3 + 82KR N 1.0 1.0 1 1.0 + 82KR L 0 0+ STABLE + 82KR E 81.81 243.01 34.6 + 82KR2 E EAV=1535.6 15$CK=0.031154 50$CL=0.003598 43$CM=0.000649 14 + 82KR3 E CN=0.000085 7 + 82KR L 776.522 102+ + 82KR E 13.10 191.06 24.8 + 82KR2 E EAV=1168.5 15$CK=0.06571 10$CL=0.00761 9$CM=0.00137 3 + 82KR3 E CN=0.000180 15 + 82KR G 776.520 1015.02 19E2 9.23E-413 + 82KR2 G KC=0.000819 12$LC=8.84E-5 13$MC=1.43E-5 2$NC=1.436E-6 20 + 82KR L 1474.894 102+ 15 PS + 82KR E 0.135 70.0284 146.3 + 82KR2 E EAV=844.1 14$CK=0.15253 24$CL=0.01768 21$CM=0.00318 7 + 82KR3 E CN=0.000417 35 + 82KR G 698.37 5 0.159 11 + 82KR G 1474.880 100.0904 24E2 2.89E-4 4 + 82KR2 G KC=0.000190 3$LC=2.00E-5 3 + 82KR L 1487.62 7 0+ 10 PS + 82KR E 0.0444 410.0096 96.7 + 82KR2 E EAV=838.3 14$CK=0.15602 25$CL=0.01808 21$CM=0.00325 7 + 82KR3 E CN=0.000427 36 + 82KR G 711.2 1 0.060 4 + 82KR L 1820.6 4 4+ + 82KR E 0.00007 70.00003 311.5 2U + 82KR2 E EAV=735.6 15$CK=0.26325 42$CL=0.03054 36$CM=0.00549 12 + 82KR3 E CN=0.00072 6 + 82KR G 1044.1 5 0.0009 6 + 82KR L 1956.797 20(2)+ + 82KR E 0.00890 140.0047 86.7 + 82KR2 E EAV=624.8 14$CK=0.30322 48$CL=0.03518 41$CM=0.00636 14 + 82KR3 E CN=0.00083 7 + 82KR G 1180.270 200.0165 15 + 82KR G 1956.750 400.0068 6 + 82KR L 2171.68 3 0+ + 82KR E 0.317 60.283 55 + 82KR2 E EAV=528.6 14$CK=0.4138 7$CL=0.0481 6$CM=0.00868 19 + 82KR3 E CN=0.00113 9 + 82KR G 696.86 150.071 6 + 82KR G 1395.140 300.529 8E2 + 82KR L 2450.09 9 0(+),1,2+ + 82KR E 0.0050 40.0105 86.3 + 82KR2 E EAV=405.7 14$CK=0.5942 9$CL=0.0692 8$CM=0.01246 27 + 82KR3 E CN=0.00163 14 + 82KR G 975.2 1 0.0084 11 + 82KR G 1673.55 9 0.0071 5 + 82KR L 2479.72 3 1,2+ + 82KR E 0.0288 70.0682 145.5 + 82KR2 E EAV=392.7 14$CK=0.6167 10$CL=0.0718 8$CM=0.01294 28 + 82KR3 E CN=0.00169 14 + 82KR G 522.8 5 0.0045 15 + 82KR G 992.2 1 0.0018 8 + 82KR G 1703.190 400.0505 11 + 82KR G 2479.65 4 0.0401 16 + 82KR L 2509.0 5 + 82KR E 0.00041 250.0011 67.4 + 82KR2 E EAV=380.0 14$CK=0.6389 10$CL=0.0744 9$CM=0.01340 29 + 82KR3 E CN=0.00175 15 + 82KR G 1021.4 5 0.0015 9 + 82KR L 2556.3 7 (4)+ + 82KR E 0.00007 40.00023 1110 2U + 82KR2 E EAV=359.4 14$CK=0.6724 11$CL=0.0783 9$CM=0.01411 31 + 82KR3 E CN=0.00184 15 + 82KR G 1081.4 7 0.00030 15 + 82KR L 2561.7 5 + 82KR E 0.00033 190.0011 67.3 + 82KR2 E EAV=357.0 14$CK=0.6746 11$CL=0.0785 9$CM=0.01415 31 + 82KR3 E CN=0.00185 15 + 82KR G 1086.8 5 0.0014 8 + 82KR L 2655.82 101,2(+) + 82KR E 0.00284 340.0142 176.1 + 82KR2 E EAV=316.2 13$CK=0.7308 12$CL=0.0852 10$CM=0.01533 33 + 82KR3 E CN=0.00200 17 + 82KR G 1168.20 200.0014 6 + 82KR G 1181.3 0.0030 15 + 82KR G 1879.18 150.0101 6 + 82KR G 2655.85 150.0026 6 + 82KR L 2944.14 4 (2)+ + 82KR E 0.0500 195.4 + 82KR2 E CK=0.8766 15$CL=0.1025 12$CM=0.0185 4$CN=0.0024 2 + 82KR G 1123.6 7 0.0008 6 + 82KR G 2167.590 400.0431 6 + 82KR G 2944.0 2 0.0075 15 + 82KR L 3186.82 5 0,1,2+ + 82KR E 0.0265 155.5 + 82KR2 E CK=0.8763 15$CL=0.1028 12$CM=0.0185 4$CN=0.0024 2 + 82KR G 1698.7 3 0.0015 8 + 82KR G 1711.9 4 0.00165 30 + 82KR G 2410.26 5 0.0233 12 + 82KR L 3355.32 191,2(+) + 82KR E 0.00134 136.7 + 82KR2 E CK=0.8759 15$CL=0.1031 12$CM=0.0186 4$CN=0.0024 2 + 82KR G 2578.70 200.00105 11 + 82KR G 3355.6 5 0.00028530 + 82KR L 3457.5 7 1,2(+) + 82KR E 0.000111237.7 + 82KR2 E CK=0.8756 15$CL=0.1033 12$CM=0.0187 4$CN=0.0024 2 + 82KR G 3457.4 7 0.00011123 + 82KR L 3564.6 3 0(+),1,2+ + 82KR E 0.0034 316 + 82KR2 E CK=0.8752 15$CL=0.1036 12$CM=0.0187 4$CN=0.0024 2 + 82KR G 1607.7 3 0.00225 30 + 82KR G 2788.4 5 0.00114 8 + 82KR L 3716.83 150(),1,2+ + 82KR E 0.008 35.8 + 82KR2 E CK=0.8745 15$CL=0.1042 12$CM=0.0188 4$CN=0.0025 2 + 82KR G 2241.98 170.0009 8 + 82KR G 2940.00 300.0071 29 + 82KR L 3741.96 8 + 82KR E 0.0036 65.9 + 82KR2 E CK=0.8743 15$CL=0.1043 12$CM=0.0189 4$CN=0.0025 2 + 82KR G 1785.13 7 0.0030 6 + 82KR G 2966.3 7 0.00060 5 + 82KR L 3815.1 101,2(+) + 82KR E 0.0019 85.6 + 82KR2 E CK=0.8738 15$CL=0.1048 12$CM=0.0190 4$CN=0.0025 2 + 82KR G 869.3 4 0.0014 8 + 82KR G 3815.0 100.00045131 + 82KR L 3835.8 5 1,2+ + 82KR E 0.00089 56.3 + 82KR2 E CK=0.8736 15$CL=0.1049 12$CM=0.0190 4$CN=0.0025 2 + 82KR G 3059.2 5 0.00068 5 + 82KR G 3836 1 0.00021923 + 82KR L 3881.1 5 1,2(+) + 82KR E 0.00024 56.8 + 82KR2 E CK=0.8732 15$CL=0.1053 12$CM=0.0191 4$CN=0.0025 2 + 82KR G 3104.5 5 0.00015 5 + 82KR G 3881 1 0.00008721 + 82KR L 3911.1 101,2(+) + 82KR E 0.00010 27.1 + 82KR2 E CK=0.8728 15$CL=0.1056 12$CM=0.0191 4$CN=0.0025 2 + 82KR G 3911.0 100.00010515 + 82KR L 3956.1 101,2(+) + 82KR E 0.00009 27.1 + 82KR2 E CK=0.8722 15$CL=0.1061 12$CM=0.0192 4$CN=0.0025 2 + 82KR G 3956.0 100.00009015 + diff --git a/HEN_HOUSE/spectra/lnhb/Re-186.txt b/HEN_HOUSE/spectra/lnhb/Re-186.txt index 11c6cbe7d..06935a9ef 100644 --- a/HEN_HOUSE/spectra/lnhb/Re-186.txt +++ b/HEN_HOUSE/spectra/lnhb/Re-186.txt @@ -1,95 +1,103 @@ -186W 186RE EC DECAY (3.7186 D) -186W T Auger electrons and X ray energies and emission intensities: -186W T {U Energy (keV)} {U Intensity} {U Line} -186W T -186W T 57.9823 1.736 30 XKA2 -186W T 59.3189 3.02 5 XKA1 -186W T -186W T 66.952 |] XKB3 -186W T 67.2451 |] 1.000 23 XKB1 -186W T 67.664 |] XKB5II -186W T -186W T 69.033 |] XKB2 -186W T 69.295 |] 0.274 8 XKB4 -186W T 69.484 |] XKO23 -186W T -186W T 7.3881-11.6761 2.00 4 XL (total) -186W T 7.3881 0.0411 13 XLL -186W T 8.3352-8.3976 0.876 24 XLA -186W T 8.725 0.0159 5 XLC -186W T 9.526-10.2903 0.902 18 XLB -186W T 10.9501-11.6761 0.166 4 XLG -186W T -186W T 45.109-48.882 |] KLL AUGER -186W T 54.514-59.312 |] 0.291 26 KLX AUGER -186W T 63.89-69.51 |] KXY AUGER -186W T 4.5-12.1 4.96 5 L AUGER -186RE P 0.0 1- 3.7186 D 17 581.6 17 -186W N 1.328E1 1.328E1 0.0753 1.328E1 -186W L 0 0+ STABLE -186W E 5.84 127.5 1 -186W 2 E CK=0.7943 18$CL=0.1560 12$CM=0.0382 7 -186W L 122.33 102+ 1.036 NS -186W E 1.69 37.8 1 -186W 2 E CK=0.7836 19$CL=0.1638 13$CM=0.0404 8 -186W G 122.33 100.603 6E2 1.81 4 -186W 2 G KC=0.585 12$LC=0.927 19$MC=0.234 7 - -186OS 186RE B- DECAY (3.7186 D) -186OS T Auger electrons and X ray energies and emission intensities: -186OS T {U Energy (keV)} {U Intensity} {U Line} -186OS T -186OS T 61.4873 1.13 4 XKA2 -186OS T 63.0011 1.94 6 XKA1 -186OS T -186OS T 71.078 |] XKB3 -186OS T 71.414 |] 0.650 23 XKB1 -186OS T 71.855 |] XKB5II -186OS T -186OS T 73.319 |] XKB2 -186OS T 73.615 |] 0.182 8 XKB4 -186OS T 73.819 |] XKO23 -186OS T -186OS T 7.8233-12.4984 2.99 7 XL (total) -186OS T 7.8233 0.0586 18 XLL -186OS T 8.841-8.9119 1.21 4 XLA -186OS T 9.3366 0.0308 10 XLC -186OS T 10.1749-11.0062 1.43 4 XLB -186OS T 11.7306-12.4984 0.262 8 XLG -186OS T -186OS T 47.71-51.892 |] KLL AUGER -186OS T 57.759-62.955 |] 0.175 18 KLX AUGER -186OS T 67.77-73.78 |] KXY AUGER -186OS T 4.7-12.9 6.43 8 L AUGER -186RE P 0.0 1- 3.7186 D 17 1069.5 9 -186OS N 1.081E0 1.081E0 0.9247 1.081E0 -186OS L 0 0+ 2E15 Y -186OS B 1069.5 9 70.9 3 7.7 1 -186OSS B EAV=359.6 7 -186OS L 137.157 8 2+ 0.818 NS -186OS B 932.3 9 21.5 3 8 1 -186OSS B EAV=306.7 7 -186OS G 137.157 8 9.42 6E2 1.290 39 -186OS2 G KC=0.433 13$LC=0.645 19$MC=0.1648 49 -186OS L 434.09 3 4+ 23.9 PS -186OS G 296.930 300.00005315E2 0.095 2 -186OS2 G KC=0.0609 12$LC=0.0260 6$MC=0.00645 19 -186OS L 767.48 3 2+ 2.38 PS -186OS B 302.0 9 0.0627 9 8.9 1 -186OSS B EAV=84.7 7 -186OS G 333.390 400.00006215[E2] 0.0678 20 -186OS2 G KC=0.0454 14$LC=0.0170 5$MC=0.00418 13 -186OS G 630.320 300.0293 6M1+E2 -14 3 0.0134 1 -186OS2 G KC=0.0105 6$LC=0.0023 2$MC=5.38E-4 16 -186OS G 767.478 300.0327 6E2 0.0086526 -186OS2 G KC=0.00690 21$LC=1342E-6 40$MC=3.15E-4 9 -186OS L 910.48 3 3+ -186OS B 159.0 9 0.000027 9 10.9 1U -186OSS B EAV=42.6 7 -186OS G 143.000 407.4E-7 25M1+E2 0.6 1.85 11 -186OS2 G KC=1.39 8$LC=0.35 2$MC=0.0842 25 -186OS G 476.390 401.5E-6 5E2+M1 -22 10 0.0259 8 -186OS2 G KC=0.0193 6$LC=0.00512 15$MC=1235E-6 37 -186OS G 773.320 300.000022 7E2+M1 60 20 0.0266 7 -186OS2 G KC=0.0189 6$LC=0.00291 9 - +186W 186RE EC DECAY (3.7186 D) +186W T Auger electrons and X ray energies and emission intensities: +186W T {U Energy (keV)} {U Intensity} {U Line} +186W T +186W T 57.9823 1.736 30 XKA2 +186W T 59.3189 3.02 5 XKA1 +186W T +186W T 66.952 |] XKB3 +186W T 67.2451 |] 1.000 23 XKB1 +186W T 67.664 |] XKB5II +186W T +186W T 69.033 |] XKB2 +186W T 69.295 |] 0.274 8 XKB4 +186W T 69.484 |] XKO23 +186W T +186W T 7.3881-11.6761 2.00 4 XL (total) +186W T 7.3881 0.0411 13 XLL +186W T 8.3352-8.3976 0.876 24 XLA +186W T 8.725 0.0159 5 XLC +186W T 9.526-10.2903 0.902 18 XLB +186W T 10.9501-11.6761 0.166 4 XLG +186W T +186W T 45.109-48.882 |] KLL AUGER +186W T 54.514-59.312 |] 0.291 26 KLX AUGER +186W T 63.89-69.51 |] KXY AUGER +186W T 4.5-12.1 4.96 5 L AUGER +186RE P 0.0 1- 3.7186 D 17 581.6 17 +186W N 1.328E1 1.328E1 0.0753 1.328E1 +186W L 0 0+ STABLE +186W E 5.84 127.5 1 +186W 2 E CK=0.7943 18$CL=0.1560 12$CM=0.0382 7 +186W L 122.33 102+ 1.036 NS +186W E 1.69 37.8 1 +186W 2 E CK=0.7836 19$CL=0.1638 13$CM=0.0404 8 +186W G 122.33 100.603 6E2 1.81 4 +186W 2 G KC=0.585 12$LC=0.927 19$MC=0.234 7$NC=0.0566 17 +186W 3 G OC=0.00862 26 + +186OS 186RE B- DECAY (3.7186 D) +186OS T Auger electrons and X ray energies and emission intensities: +186OS T {U Energy (keV)} {U Intensity} {U Line} +186OS T +186OS T 61.4873 1.13 4 XKA2 +186OS T 63.0011 1.94 6 XKA1 +186OS T +186OS T 71.078 |] XKB3 +186OS T 71.414 |] 0.650 23 XKB1 +186OS T 71.855 |] XKB5II +186OS T +186OS T 73.319 |] XKB2 +186OS T 73.615 |] 0.182 8 XKB4 +186OS T 73.819 |] XKO23 +186OS T +186OS T 7.8233-12.4984 2.99 7 XL (total) +186OS T 7.8233 0.0586 18 XLL +186OS T 8.841-8.9119 1.21 4 XLA +186OS T 9.3366 0.0308 10 XLC +186OS T 10.1749-11.0062 1.43 4 XLB +186OS T 11.7306-12.4984 0.262 8 XLG +186OS T +186OS T 47.71-51.892 |] KLL AUGER +186OS T 57.759-62.955 |] 0.175 18 KLX AUGER +186OS T 67.77-73.78 |] KXY AUGER +186OS T 4.7-12.9 6.43 8 L AUGER +186RE P 0.0 1- 3.7186 D 17 1069.5 9 +186OS N 1.081E0 1.081E0 0.9247 1.081E0 +186OS L 0 0+ 2E15 Y +186OS B 1069.5 9 70.9 3 7.7 1 +186OSS B EAV=359.6 7 +186OS L 137.157 8 2+ 0.818 NS +186OS B 932.3 9 21.5 3 8 1 +186OSS B EAV=306.7 7 +186OS G 137.157 8 9.42 6E2 1.290 39 +186OS2 G KC=0.433 13$LC=0.645 19$MC=0.1648 49$NC=0.0404 12 +186OS3 G OC=0.00663 20 +186OS L 434.09 3 4+ 23.9 PS +186OS G 296.930 300.00005315E2 0.095 2 +186OS2 G KC=0.0609 12$LC=0.0260 6$MC=0.00645 19$NC=0.001593 48 +186OS3 G OC=0.000272 8 +186OS L 767.48 3 2+ 2.38 PS +186OS B 302.0 9 0.0627 9 8.9 1 +186OSS B EAV=84.7 7 +186OS G 333.390 400.00006215[E2] 0.0678 20 +186OS2 G KC=0.0454 14$LC=0.0170 5$MC=0.00418 13$NC=0.001034 31 +186OS3 G OC=0.000178 5 +186OS G 630.320 300.0293 6M1+E2 -14 3 0.0134 1 +186OS2 G KC=0.0105 6$LC=0.0023 2$MC=0.000538 16$NC=1.337E-4 40 +186OS3 G OC=2.41E-5 7 +186OS G 767.478 300.0327 6E2 0.0086526 +186OS2 G KC=0.00690 21$LC=0.001342 40$MC=0.000315 9$NC=7.86E-5 24 +186OS3 G OC=1.432E-5 43 +186OS L 910.48 3 3+ +186OS B 159.0 9 0.000027 9 10.9 1U +186OSS B EAV=42.6 7 +186OS G 143.000 407.4E-7 25M1+E2 0.6 1.85 11 +186OS2 G KC=1.39 8$LC=0.35 2$MC=0.0842 25$NC=0.0209 6 +186OS3 G OC=0.00373 11 +186OS G 476.390 401.5E-6 5E2+M1 -22 10 0.0259 8 +186OS2 G KC=0.0193 6$LC=0.00512 15$MC=0.001235 37$NC=0.000306 9 +186OS3 G OC=5.42E-5 16 +186OS G 773.320 300.000022 7E2+M1 60 20 0.0266 7 +186OS2 G KC=0.0189 6$LC=0.00291 9 + diff --git a/HEN_HOUSE/spectra/lnhb/Re-188.txt b/HEN_HOUSE/spectra/lnhb/Re-188.txt index 8fb758abd..67eaf5121 100644 --- a/HEN_HOUSE/spectra/lnhb/Re-188.txt +++ b/HEN_HOUSE/spectra/lnhb/Re-188.txt @@ -1,169 +1,169 @@ -188OS 188RE B- DECAY (17.005 H) -188OS T Auger electrons and X ray energies and emission intensities: -188OS T {U Energy (keV)} {U Intensity} {U Line} -188OS T -188OS T 61.4873 1.36 9 XKA2 -188OS T 63.0011 2.35 16 XKA1 -188OS T -188OS T 71.078 |] XKB3 -188OS T 71.414 |] 0.79 5 XKB1 -188OS T 71.855 |] XKB5II -188OS T -188OS T 73.319 |] XKB2 -188OS T 73.615 |] 0.22 2 XKB4 -188OS T 73.819 |] XKO23 -188OS T -188OS T 7.82-12.92 3.00 15 XL (total) -188OS T 7.82 XLL -188OS T -12.92 XLG -188OS T -188OS T 47.71-51.89 |] KLL AUGER -188OS T 57.79-60.47 |] 0.210 14 KLX AUGER -188OS T 67.68-69.95 |] KXY AUGER -188RE P 0.0 1- 17.005 H 4 2120.4 4 -188OS N 1.0 1.0 1 1.0 -188OS G 979.25 170.00104 20 -188OS L 0 0+ STABLE -188OS B 2120.4 4 71.1 22 8.1 1 -188OSS B EAV=795.40 17 -188OS L 155.040 4 2+ 0.70 NS 2 -188OS B 1965.3 4 25.6 20 8.4 1 -188OSS B EAV=728.89 17 -188OS G 155.041 4 15.2 6E2 0.820 25 -188OS2 G KC=0.323 10$LC=0.375 11$MC=0.122 4 -188OS L 477.97 3 4+ 19.40 PS 9 -188OS G 322.93 4 0.0162 15E2 0.0743 22 -188OS2 G KC=0.0492 15$LC=0.0190 6$MC=0.0061 2 -188OS L 633.024 132+ 6.6 PS 3 -188OS B 1487.4 4 1.65 12 9.2 1 -188OSS B EAV=527.77 17 -188OS G 155 0.0059 6[E2] 0.820 25 -188OS2 G KC=0.323 10$LC=0.375 11$MC=0.122 4 -188OS G 477.992 251.02 9E2+M1+ 0.0260 8 -188OS2 G KC=0.0193 6$LC=0.00508 15$MC=0.00126 5 -188OS G 632.981 211.28 10E2 0.0132 4 -188OS2 G KC=0.0103 3$LC=0.00223 7$MC=0.00067 2 -188OS L 789.97 3 3+ -188OS G 312.001 240.043 12E2 0.0822 25 -188OS2 G KC=0.0536 16$LC=0.0216 6$MC=0.00070 21 -188OS G 634.98 7 0.148 12E2+M1 0.0136 4 -188OS2 G KC=0.0106 3$LC=0.00226 7$MC=0.00074 2 -188OS L 1086.382 100+ 12 PS 9 -188OS B 1034.0 4 0.63 4 9 1 -188OSS B EAV=345.33 16 -188OS G 453.34 2 0.073 8(E2) 0.0294 4 -188OS2 G KC=0.0216 6$LC=0.00597 18$MC=0.00183 5 -188OS G 931.345 100.55 4E2 0.0057918 -188OS2 G KC=0.00470 14$LC=0.00084 3$MC=0.00025 1 -188OS L 1304.85 7 (2)+ -188OS B 815.5 4 0.0241 17 10 1 -188OSS B EAV=261.94 15 -188OS G 514.88 6 0.0054 5E2(+M1) 0.0232 18 -188OS2 G KC=0.0177 16$LC=0.00421 23$MC=0.00129 6 -188OS G 1149.7 4 0.015 1 -188OS G 1304.86 200.0028 4 -188OS L 1413.8 3 (3)- -188OS B 706.6 5 0.0024 5 10.8 2 -188OSS B EAV=221.84 18 -188OS G 623.8 3 0.0024 5 -188OS L 1443.52 5 + -188OS B 676.88 5 0.00092 21 11.2 -188OSS B EAV=211.11 14 -188OS G 810.49 4 0.00092 22 -188OS L 1457.55 122+ -188OS B 662.8 5 0.042 3 9.5 1 -188OSS B EAV=206.07 15 -188OS G 825.2 7 0.0176 15M1(+E2) 0.016 5 -188OS2 G KC=0.013 5$LC=0.0021 7$MC=0.0009 2 -188OS G 1302.4 3 0.0057 8 -188OS G 1457.54 130.0186 15 -188OS L 1462.50 3 2- -188OS B 657.9 4 0.44 3 8.5 -188OSS B EAV=204.30 14 -188OS G 672.535 160.112 9E1 0.0042 1 -188OS2 G KC=0.0035 11$LC=0.00053 2$MC=1.55E-4 5 -188OS G 829.47 4 0.41 3E1(+M2) 0.0030 9 -188OS2 G KC=0.0025 7$LC=0.00038 11$MC=0.00011 3 -188OS G 984.1 5 0.00034 21 -188OS G 1463.0 6 0.0008 3 -188OS L 1478.09 5 0+ -188OS B 642.3 4 0.018 3 9.8 1 -188OSS B EAV=198.73 14 -188OS G 845.07 4 0.0065 5 -188OS G 1322.91 200.011 3 -188OS L 1685.5 3 + -188OS B 434.9 5 0.00055 17 10.8 -188OSS B EAV=127.46 17 -188OS G 1530.5 3 0.00055 17 -188OS L 1704.32 100+ -188OS B 416.1 5 0.0023 9 10.1 1 -188OSS B EAV=121.28 13 -188OS G 1704 -188OS G 1071.4 3 0.00067 13 -188OS G 1549.26 100.0016 9 -188OS L 1729.68 22(2,3)+ -188OS B 390.7 5 0.00128 21 10.3 1 -188OSS B EAV=113.02 15 -188OS G 1096.8 4 0.00064 17 -188OS G 1574.57 250.00063 11 -188OS L 1765.353 220+ -188OS B 355.0 4 0.181 13 8 1 -188OSS B EAV=101.57 13 -188OS G 1765.1 -188OS G 1132.31 2 0.083 7(E2) 0.0038712 -188OS2 G KC=0.00322 10$LC=0.00050 3$MC=0.00015 5 -188OS G 1610.40 5 0.098 8[E2] 1.07E-4 -188OS L 1807.60 3 (2)+ -188OS B 312.8 4 0.038 3 8.5 1 -188OSS B EAV=88.27 12 -188OS G 1017.7 1 0.0147 11 -188OS G 1174.57 3 0.0180 15 -188OS G 1652.49 140.0035 4 -188OS G 1807.6 3 0.00086 9 -188OS L 1824.94 6 0+ -188OS B 295.5 4 0.0236 17 8.6 1 -188OSS B EAV=82.90 12 -188OS G 1825 -188OS G 1191.84 120.0134 11 -188OS G 1669.97 7 0.0104 8[E2] 1.32E-4 -188OS L 1842.86 6 (1,2)+ -188OS B 277.5 4 0.00299 22 9.4 -188OSS B EAV=77.41 12 -188OS G 1209.790 240.00300 24M1+E2 0.0072921 -188OS2 G KC=0.00620 19$LC=8.20E-4 25 -188OS L 1936.9 3 + -188OS B 183.5 4 0.00021425 10 -188OSS B EAV=49.46 14 -188OS G 1936.9 3 0.00021 3 -188OS L 1941.03 6 (1,2)+ -188OS B 179.4 4 0.102 7 7.3 -188OSS B EAV=48.27 12 -188OS G 1150.5 4 0.015 1 -188OS G 1308.03 6 0.065 5 -188OS G 1785.95 120.0195 15[E2] 0.00018 -188OS G 1940.91 230.00185 15(M1E2) 2.48E-4 -188OS L 1948.59 3 + -188OS B 171.8 4 0.079 6 7.3 -188OSS B EAV=46.10 11 -188OS G 486.087 110.079 6 -188OS L 1957.08 4 (1,2)+ -188OS B 163.3 4 0.051 4 7.4 -188OSS B EAV=43.68 11 -188OS G 1802.04 4 0.036 3[E2] 1.85E-4 -188OS G 1956.96 170.0150 12(M1E2) 2.55E-4 -188OS L 1964.96 7 2+ -188OS B 155.4 4 0.0021 3 8.8 1 -188OSS B EAV=41.44 11 -188OS G 1331.95 7 0.00174 24 -188OS G 1809.54 300.00040 11 -188OS L 2020.18 10 + -188OS B 100.2 5 0.0059 4 7.7 -188OSS B EAV=26.12 11 -188OS G 557.71 100.00095 9 -188OS G 1864.91 250.0050 4(E2M1) 2.13E-4 -188OS L 2022.44 13(1,2)+ -188OS B 98.0 5 0.00198 16 8.2 -188OSS B EAV=25.51 11 -188OS G 1867.20 220.00046 9 -188OS G 2022.53 160.00152 12(M1E2) 2.85E-4 - +188OS 188RE B- DECAY (17.005 H) +188OS T Auger electrons and X ray energies and emission intensities: +188OS T {U Energy (keV)} {U Intensity} {U Line} +188OS T +188OS T 61.4873 1.36 9 XKA2 +188OS T 63.0011 2.35 16 XKA1 +188OS T +188OS T 71.078 |] XKB3 +188OS T 71.414 |] 0.79 5 XKB1 +188OS T 71.855 |] XKB5II +188OS T +188OS T 73.319 |] XKB2 +188OS T 73.615 |] 0.22 2 XKB4 +188OS T 73.819 |] XKO23 +188OS T +188OS T 7.82-12.92 3.00 15 XL (total) +188OS T 7.82 XLL +188OS T -12.92 XLG +188OS T +188OS T 47.71-51.89 |] KLL AUGER +188OS T 57.79-60.47 |] 0.210 14 KLX AUGER +188OS T 67.68-69.95 |] KXY AUGER +188RE P 0.0 1- 17.005 H 4 2120.4 4 +188OS N 1.0 1.0 1 1.0 +188OS G 979.25 170.00104 20 +188OS L 0 0+ STABLE +188OS B 2120.4 4 71.1 22 8.1 1 +188OSS B EAV=795.40 17 +188OS L 155.040 4 2+ 0.70 NS 2 +188OS B 1965.3 4 25.6 20 8.4 1 +188OSS B EAV=728.89 17 +188OS G 155.041 4 15.2 6E2 0.820 25 +188OS2 G KC=0.323 10$LC=0.375 11$MC=0.122 4 +188OS L 477.97 3 4+ 19.40 PS 9 +188OS G 322.93 4 0.0162 15E2 0.0743 22 +188OS2 G KC=0.0492 15$LC=0.0190 6$MC=0.0061 2 +188OS L 633.024 132+ 6.6 PS 3 +188OS B 1487.4 4 1.65 12 9.2 1 +188OSS B EAV=527.77 17 +188OS G 155 0.0059 6[E2] 0.820 25 +188OS2 G KC=0.323 10$LC=0.375 11$MC=0.122 4 +188OS G 477.992 251.02 9E2+M1+E0 0.0260 8 +188OS2 G KC=0.0193 6$LC=0.00508 15$MC=0.00126 5 +188OS G 632.981 211.28 10E2 0.0132 4 +188OS2 G KC=0.0103 3$LC=0.00223 7$MC=0.00067 2 +188OS L 789.97 3 3+ +188OS G 312.001 240.043 12E2 0.0822 25 +188OS2 G KC=0.0536 16$LC=0.0216 6$MC=0.00070 21 +188OS G 634.98 7 0.148 12E2+M1 0.0136 4 +188OS2 G KC=0.0106 3$LC=0.00226 7$MC=0.00074 2 +188OS L 1086.382 100+ 12 PS 9 +188OS B 1034.0 4 0.63 4 9 1 +188OSS B EAV=345.33 16 +188OS G 453.34 2 0.073 8(E2) 0.0294 4 +188OS2 G KC=0.0216 6$LC=0.00597 18$MC=0.00183 5 +188OS G 931.345 100.55 4E2 0.0057918 +188OS2 G KC=0.00470 14$LC=0.00084 3$MC=0.00025 1 +188OS L 1304.85 7 (2)+ +188OS B 815.5 4 0.0241 17 10 1 +188OSS B EAV=261.94 15 +188OS G 514.88 6 0.0054 5E2(+M1) 0.0232 18 +188OS2 G KC=0.0177 16$LC=0.00421 23$MC=0.00129 6 +188OS G 1149.7 4 0.015 1 +188OS G 1304.86 200.0028 4 +188OS L 1413.8 3 (3)- +188OS B 706.6 5 0.0024 5 10.8 2 +188OSS B EAV=221.84 18 +188OS G 623.8 3 0.0024 5 +188OS L 1443.52 5 +188OS B 676.88 5 0.00092 21 11.2 +188OSS B EAV=211.11 14 +188OS G 810.49 4 0.00092 22 +188OS L 1457.55 122+ +188OS B 662.8 5 0.042 3 9.5 1 +188OSS B EAV=206.07 15 +188OS G 825.2 7 0.0176 15M1(+E2) 0.016 5 +188OS2 G KC=0.013 5$LC=0.0021 7$MC=0.0009 2 +188OS G 1302.4 3 0.0057 8 +188OS G 1457.54 130.0186 15 +188OS L 1462.50 3 2- +188OS B 657.9 4 0.44 3 8.5 +188OSS B EAV=204.30 14 +188OS G 672.535 160.112 9E1 0.0042 1 +188OS2 G KC=0.0035 11$LC=0.00053 2$MC=0.000155 5 +188OS G 829.47 4 0.41 3E1(+M2) 0.0030 9 +188OS2 G KC=0.0025 7$LC=0.00038 11$MC=0.00011 3 +188OS G 984.1 5 0.00034 21 +188OS G 1463.0 6 0.0008 3 +188OS L 1478.09 5 0+ +188OS B 642.3 4 0.018 3 9.8 1 +188OSS B EAV=198.73 14 +188OS G 845.07 4 0.0065 5 +188OS G 1322.91 200.011 3 +188OS L 1685.5 3 +188OS B 434.9 5 0.00055 17 10.8 +188OSS B EAV=127.46 17 +188OS G 1530.5 3 0.00055 17 +188OS L 1704.32 100+ +188OS B 416.1 5 0.0023 9 10.1 1 +188OSS B EAV=121.28 13 +188OS G 1071.4 3 0.00067 13 +188OS G 1549.26 100.0016 9 +188OS G 1704 E0 +188OS L 1729.68 22(2,3)+ +188OS B 390.7 5 0.00128 21 10.3 1 +188OSS B EAV=113.02 15 +188OS G 1096.8 4 0.00064 17 +188OS G 1574.57 250.00063 11 +188OS L 1765.353 220+ +188OS B 355.0 4 0.181 13 8 1 +188OSS B EAV=101.57 13 +188OS G 1132.31 2 0.083 7(E2) 0.0038712 +188OS2 G KC=0.00322 10$LC=0.00050 3$MC=0.00015 5 +188OS G 1610.40 5 0.098 8[E2] 1.07E-4 +188OS G 1765.1 E0 +188OS L 1807.60 3 (2)+ +188OS B 312.8 4 0.038 3 8.5 1 +188OSS B EAV=88.27 12 +188OS G 1017.7 1 0.0147 11 +188OS G 1174.57 3 0.0180 15 +188OS G 1652.49 140.0035 4 +188OS G 1807.6 3 0.00086 9 +188OS L 1824.94 6 0+ +188OS B 295.5 4 0.0236 17 8.6 1 +188OSS B EAV=82.90 12 +188OS G 1191.84 120.0134 11 +188OS G 1669.97 7 0.0104 8[E2] 1.32E-4 +188OS G 1825 E0 +188OS L 1842.86 6 (1,2)+ +188OS B 277.5 4 0.00299 22 9.4 +188OSS B EAV=77.41 12 +188OS G 1209.790 240.00300 24M1+E2 0.0072921 +188OS2 G KC=0.00620 19$LC=0.000820 25 +188OS L 1936.9 3 +188OS B 183.5 4 0.00021425 10 +188OSS B EAV=49.46 14 +188OS G 1936.9 3 0.00021 3 +188OS L 1941.03 6 (1,2)+ +188OS B 179.4 4 0.102 7 7.3 +188OSS B EAV=48.27 12 +188OS G 1150.5 4 0.015 1 +188OS G 1308.03 6 0.065 5 +188OS G 1785.95 120.0195 15[E2] 0.00018 +188OS G 1940.91 230.00185 15(M1,E2) 2.48E-4 +188OS L 1948.59 3 +188OS B 171.8 4 0.079 6 7.3 +188OSS B EAV=46.10 11 +188OS G 486.087 110.079 6 +188OS L 1957.08 4 (1,2)+ +188OS B 163.3 4 0.051 4 7.4 +188OSS B EAV=43.68 11 +188OS G 1802.04 4 0.036 3[E2] 1.85E-4 +188OS G 1956.96 170.0150 12(M1,E2) 2.55E-4 +188OS L 1964.96 7 2+ +188OS B 155.4 4 0.0021 3 8.8 1 +188OSS B EAV=41.44 11 +188OS G 1331.95 7 0.00174 24 +188OS G 1809.54 300.00040 11 +188OS L 2020.18 10 +188OS B 100.2 5 0.0059 4 7.7 +188OSS B EAV=26.12 11 +188OS G 557.71 100.00095 9 +188OS G 1864.91 250.0050 4(E2,M1) 2.13E-4 +188OS L 2022.44 13(1,2)+ +188OS B 98.0 5 0.00198 16 8.2 +188OSS B EAV=25.51 11 +188OS G 1867.20 220.00046 9 +188OS G 2022.53 160.00152 12(M1,E2) 2.85E-4 + diff --git a/HEN_HOUSE/spectra/lnhb/Rh-106.txt b/HEN_HOUSE/spectra/lnhb/Rh-106.txt index 9cfee7c31..5e97f528c 100644 --- a/HEN_HOUSE/spectra/lnhb/Rh-106.txt +++ b/HEN_HOUSE/spectra/lnhb/Rh-106.txt @@ -1,268 +1,281 @@ -106PD 106RH B- DECAY (30.1 S) -106PD H TYP=Full$AUT=A.Arinc$CUT=31-DEC-2012$ -106PD C Evaluation history: Type=Full;Author=A.Arinc;Cutoff date=31-DEC-2012 -106PD C References: 1946Se30, 1947Pe07, 1950Gl05, 1953Ka47, 1957Fi50, 1958Gr07, -106PD2C 1960Ro12, 1960Se07, 1962Am03, 1963Ke13, 1965Ro09, 1966Ov01, 1966JoZZ, -106PD3C 1966Mi10, 1967Ra11, 1697Fo09, 1968Ha35, 1967Vr05, 1969St03, 1969Od01, -106PD4C 1969KoZW, 1969Be74, 1971Az02, 1972Ma71, 1973Ma35, 1975De17, 1975Ge06, -106PD5C 1975Hs02, 1976Sh25, 1977Ok02, 1982Ka10, 1983Ku03, 1992Gr21, 1993Ch32, -106PD6C 1996Sc06, 2000He14, 2002Ba85, 2005Ki02, 2008Ki07, 2008De09, 2012Wa38 -106PD T Auger electrons and X ray energies and emission intensities: -106PD T {U Energy (keV)} {U Intensity} {U Line} -106PD T -106PD T 21.0203 0.0310 5 XKA2 -106PD T 21.1774 0.0586 9 XKA1 -106PD T -106PD T 23.7914 |] XKB3 -106PD T 23.819 |] 0.01608 29 XKB1 -106PD T 24.013 |] XKB5II -106PD T -106PD T 24.2994 |] XKB2 -106PD T 24.344 |] 0.00273 10 XKB4 -106PD T -106PD T 2.5045-3.5545 0.00785 14 XL (total) -106PD T 2.5045 0.000174 5 XLL -106PD T 2.8337-2.839 0.00468 11 XLA -106PD T 2.6611 6.08E-5 17 XLC -106PD T 2.9904-3.1715 0.00270 8 XLB -106PD T 3.2464-3.5545 0.000242 6 XLG -106PD T -106PD T 17.032-17.884 |] KLL AUGER -106PD T 20.032-21.176 |] 0.0238 7 KLX AUGER -106PD T 23.011-24.347 |] KXY AUGER -106PD T 1.83-3.6 0.1377 8 L AUGER -106RH P 0.0 1+ 30.1 S 3 3546 5 -106PD N 1.0 1.0 1 1.0 -106PD L 0 0+ STABLE -106PD B 3546 5 78.80 24 5.18 -106PDS B EAV=1511.1 24 -106PD L 511.8547 232+ -106PD B 3034 5 8.2 3 5.87 -106PDS B EAV=1269.5 24 -106PD G 511.8534 2320.52 23E2 0.00559 8 -106PD2 G KC=0.00484 7$LC=6.12E-4 9$MC=1153E-7 17 -106PD L 1128.02 3 2+ -106PD B 2418 5 0.608 21 6.58 -106PDS B EAV=981.6 24 -106PD G 616.16 3 0.731 17M1+E2 -9.4 20 0.00333 5 -106PD2 G KC=0.00289 4$LC=3.57E-4 5$MC=6.71E-5 10 -106PD G 1128.01 3 0.398 8E2 7.73E-411 -106PD2 G KC=6.75E-4 10$LC=7.90E-5 11$MC=1479E-8 21 -106PD L 1133.76 4 0+ -106PD B 2412 5 9.82 15 5.37 -106PDS B EAV=978.9 24 -106PD G 621.90 4 9.87 15E2 0.00324 5 -106PD2 G KC=0.00282 4$LC=3.48E-4 5$MC=6.54E-5 10 -106PD G 1133.75 4 -106PD L 1229.30 4 4+ -106PD B 2317 5 0.0051 5 11 2U -106PDS B EAV=951.8 23 -106PD G 717.44 4 0.0067 4E2 0.00223 4 -106PD2 G KC=0.00194 3$LC=2.36E-4 4$MC=4.43E-5 7 -106PD L 1557.68 4 3+ -106PD G 1045.82 4 0.0131 16M1+E2 -3.8 4 9.18E-413 -106PD2 G KC=8.03E-4 12$LC=9.42E-5 14$MC=1766E-8 25 -106PD L 1562.25 3 2+ -106PD B 1984 5 1.67 3 5.79 -106PDS B EAV=781.9 23 -106PD G 428.49 5 0.0704 24E2 0.0094714 -106PD2 G KC=0.00817 12$LC=1063E-6 15$MC=2.00E-4 3 -106PD G 434.23 4 0.020 4E2 0.0090913 -106PD2 G KC=0.00785 11$LC=1019E-6 15$MC=1.92E-4 3 -106PD G 1050.39 3 1.490 25M1+E2 0.24 1 1007E-615 -106PD2 G KC=8.83E-4 13$LC=1018E-7 15$MC=1.91E-5 3 -106PD G 1562.24 3 0.156 8 -106PD L 1706.44 5 0+ -106PD B 1840 5 0.0664 10 7.06 -106PDS B EAV=716.4 23 -106PD G 578.42 6 0.0090 6E2 0.00395 6 -106PD2 G KC=0.00343 5$LC=4.27E-4 6$MC=8.04E-5 12 -106PD G 1194.58 5 0.0573 8E2 6.89E-410 -106PD2 G KC=5.97E-4 9$LC=6.96E-5 10$MC=1304E-8 19 -106PD L 1909.37 16(1,2)+ -106PD B 1637 5 0.00277 21 8.24 -106PDS B EAV=625.2 23 -106PD G 1397.51 160.00277 21 -106PD L 2001.48 5 0+ -106PD B 1545 5 0.448 9 5.93 -106PDS B EAV=584.3 23 -106PD G 439.23 6 0.0111 16 -106PD G 873.46 6 0.435 8E2 1375E-620 -106PD2 G KC=1201E-6 17$LC=1432E-7 20$MC=2.69E-5 4 -106PD G 1489.61 5 0.0018 3 -106PD L 2242.48 5 2+ -106PD B 1304 5 0.0372 8 6.72 -106PDS B EAV=478.7 22 -106PD G 680.23 6 0.0103 6E1+M2 0.4 0.00268 4 -106PD2 G KC=0.00234 4$LC=2.74E-4 4$MC=5.15E-5 8 -106PD G 684.80 6 0.00552 21 -106PD G 1108.71 6 0.0056 3 -106PD G 1114.45 6 0.0117 3M1+E2 1.5 8.23E-414 -106PD2 G KC=7.20E-4 12$LC=8.38E-5 14$MC=1570E-8 25 -106PD G 1730.44 200.00209 13 -106PD G 2242.45 5 0.00195 8 -106PD L 2278.11 9 0+ -106PD B 1268 5 0.043 5 6.62 -106PDS B EAV=463.3 22 -106PD G 715.86 9 0.0099 4 -106PD G 1150.08 9 0.00287 17E2 7.42E-411 -106PD2 G KC=6.48E-4 9$LC=7.57E-5 11$MC=1417E-8 20 -106PD G 1766.24 9 0.030 5E2 5.06E-4 7 -106PD2 G KC=2.74E-4 4$LC=3.14E-5 5$MC=5.86E-6 9 -106PD L 2308.82 5 2+ -106PD B 1237 5 0.0430 7 6.57 -106PDS B EAV=450.1 22 -106PD G 751.26 200.00121 23 -106PD G 1180.79 6 0.0144 3M1+E2 -0.06 12 7.90E-412 -106PD2 G KC=6.89E-4 10$LC=7.92E-5 12$MC=1482E-8 22 -106PD G 1796.95 5 0.0274 5M1+E2 0.25 2 5.16E-4 8 -106PD2 G KC=2.87E-4 4$LC=3.27E-5 5$MC=6.11E-6 9 -106PD L 2439.10 7 2+ -106PD B 1107 5 0.0208 5 6.71 -106PDS B EAV=394.7 21 -106PD G 1209.79 8 0.00039 8 -106PD G 1305.33 8 0.00109 12 -106PD G 1927.23 7 0.0147 4M1+E2 -0.07 5.32E-4 8 -106PD2 G KC=2.50E-4 4$LC=2.85E-5 4$MC=5.33E-6 8 -106PD G 2439.07 7 0.00464 13E2 6.89E-410 -106PD2 G KC=1525E-7 22$LC=1727E-8 25$MC=3.23E-6 5 -106PD L 2484.66 20(1)- -106PD B 1061 5 0.00093 15 7.99 -106PDS B EAV=375.6 21 -106PD G 1973.4 8 0.00017 4 -106PD G 2484.63 200.00076 14 -106PD L 2500.31 8 2- -106PD B 1046 5 0.0284 6 6.48 1 -106PDS B EAV=369.0 21 -106PD G 942.63 9 0.00060 18 -106PD G 1372.28 9 0.00199 15 -106PD G 1988.44 8 0.0258 5E1+M2 0.05 7.35E-411 -106PD2 G KC=1173E-7 22$LC=1318E-8 25$MC=2.46E-6 5 -106PD L 2624.40 5 0+ -106PD B 922 5 0.090 3 5.78 -106PDS B EAV=317.8 21 -106PD G 1062.14 6 0.0304 19 -106PD G 1496.37 6 0.0240 17 -106PD G 2112.52 5 0.0351 7E2 5.81E-4 9 -106PD2 G KC=1.97E-4 3$LC=2.24E-5 4$MC=4.19E-6 6 -106PD L 2705.30 8 (1)+ -106PD B 841 5 0.0106 4 6.56 -106PDS B EAV=285.1 20 -106PD G 702.8 100.00029 18 -106PD G 1572.47 200.00185 19 -106PD G 1577.27 9 0.00105 16 -106PD G 2193.17 100.00495 21M1+E2 -0.17 6 5.94E-4 9 -106PD2 G KC=1.94E-4 3$LC=2.20E-5 3$MC=4.12E-6 6 -106PD G 2705.26 8 0.00248 13 -106PD L 2717.59 21 + -106PD B 828 5 0.00023 12 -106PDS B EAV= -106PD G 1159.90 210.00023 12 -106PD L 2783.74 212+ -106PD B 762 5 0.00117 8 7.36 -106PDS B EAV=254 2 -106PD G 2271.86 210.00117 8 -106PD L 2820.97 9 2+ -106PD B 725 5 0.0090 3 6.4 -106PDS B EAV=239.4 20 -106PD G 1258.71 9 0.00066 8 -106PD G 1687.20 100.00055 16 -106PD G 1693.2 3 0.00082 14 -106PD G 2309.09 9 0.00575 16 -106PD G 2821.2 3 0.00120 4 -106PD L 2828.29 9 0+ -106PD B 718 5 0.00731 19 6.47 -106PDS B EAV=236.6 20 -106PD G 1266.03 9 0.00109 10 -106PD G 2316.41 9 0.00622 16E2 6.46E-4 9 -106PD2 G KC=1670E-7 24$LC=1.89E-5 3$MC=3.54E-6 5 -106PD L 2877.92 7 0+ -106PD B 668 5 0.0262 9 5.81 -106PDS B EAV=217.5 20 -106PD G 1315.66 8 0.0030 5E2 5.86E-4 9 -106PD2 G KC=4.89E-4 7$LC=5.67E-5 8$MC=1061E-8 15 -106PD G 2366.04 7 0.0232 7E2 6.63E-410 -106PD2 G KC=1608E-7 23$LC=1.82E-5 3$MC=3.41E-6 5 -106PD L 2902.48 102+ -106PD B 644 5 0.00760 18 6.29 -106PDS B EAV=208.1 19 -106PD G 1774.44 100.00094 8 -106PD G 2390.60 100.00659 16M1+E2 -0.1 6.54E-410 -106PD2 G KC=1645E-7 24$LC=1.86E-5 3$MC=3.49E-6 5 -106PD G 2902.6 5 0.00006621 -106PD L 2917.86 8 2+ -106PD B 628 5 0.0183 7 5.87 -106PDS B EAV=202.3 19 -106PD G 1355.60 9 0.00060 25 -106PD G 1360.17 9 0.0018 4 -106PD G 1784.08 9 0.00043 12 -106PD G 2405.98 8 0.0145 4M1+E2 -0.05 6.59E-410 -106PD2 G KC=1626E-7 23$LC=1.84E-5 3$MC=3.44E-6 5 -106PD G 2917.6 3 0.00094 4 -106PD L 2968.68 213- -106PD B 577 5 0.00022 4 7.82 1U -106PDS B EAV=202.8 19 -106PD G 2456.79 210.00022 4 -106PD L 3037.32 171,2+ -106PD B 509 5 0.0022 3 -106PDS B EAV= -106PD G 1909.28 170.00107 25 -106PD G 2525.43 170.00011 3 -106PD G 3037.3 3 0.00105 4 -106PD L 3054.97 9 1+ -106PD B 491 5 0.0101 5 5.76 -106PDS B EAV=151.8 18 -106PD G 1498.73 160.0068 4 -106PD G 2542.79 100.00289 9M1+E2 0.07 7 7.05E-410 -106PD2 G KC=1464E-7 21$LC=1657E-8 24$MC=3.10E-6 5 -106PD G 3055.0 3 0.00036 4 -106PD L 3083.91 180+ -106PD B 462 5 0.00278 13 -106PDS B EAV= -106PD G 1854.89 200.00125 10 -106PD G 1954.9 4 0.00020 4 -106PD G 2571.16 200.00133 6 -106PD L 3163.7 3 (1,2)+ -106PD B 382 5 0.00070 5 6.55 -106PDS B EAV=113.8 17 -106PD G 2651.39 200.00068 4 -106PD G 3164.6 100.00002312 -106PD L 3221.37 250+ -106PD B 325 5 0.00402 13 5.56 -106PDS B EAV=94.5 17 -106PD G 2093.33 250.00029 6E2 5.76E-4 8 -106PD2 G KC=2.00E-4 3$LC=2.28E-5 4$MC=4.26E-6 6 -106PD G 2709.48 250.00373 11E2 7.85E-411 -106PD2 G KC=1271E-7 18$LC=1436E-8 21$MC=2.68E-6 4 -106PD L 3249.9 5 2+ -106PD B 296 5 0.00008616 7.09 -106PDS B EAV=85.2 17 -106PD G 3249.8 5 0.00008616 -106PD L 3252.0 4 2+ -106PD B 294 5 0.00021 4 6.7 -106PDS B EAV=84.5 17 -106PD G 2740.1 4 0.00021 4 -106PD L 3273.5 7 1,2+ -106PD B 272 5 0.00004914 -106PDS B EAV= -106PD G 3273.4 7 0.00004914 -106PD L 3299.2 7 + -106PD B 247 5 0.00008221 -106PDS B EAV= -106PD G 2788.2 5 0.00008221 -106PD L 3320.5 3 0+ -106PD B 226 5 0.00087 8 5.71 -106PDS B EAV=62.9 16 -106PD G 2185.7 5 0.00025 6 -106PD G 2809.1 3 0.00062 4E2 8.22E-412 -106PD2 G KC=1195E-7 17$LC=1349E-8 19$MC=2.52E-6 4 -106PD L 3376.6 9 + -106PD B 169 5 0.000025 9 -106PDS B EAV= -106PD G 2865 1 0.000014 8 -106PD G 3375.9 141.13E-5 21 -106PD L 3401.9 6 + -106PD B 144 5 1.25E-5 19 -106PDS B EAV= -106PD G 3401.8 9 1.25E-5 19 - +106PD 106RH B- DECAY (30.1 S) +106PD H TYP=FUL$AUT=A.ARINC$CUT=31-DEC-2012$ +106PD C References:1946Se30, 1947Pe07, 1950Gl05, 1953Ka47, 1957Fi50, 1958Gr07, +106PD2C 1960Ro12, 1960Se07, 1962Am03, 1963Ke13, 1965Ro09, 1966Ov01, 1966JoZZ, +106PD3C 1966Mi10, 1967Ra11, 1697Fo09, 1968Ha35, 1967Vr05, 1969St03, 1969Od01, +106PD4C 1969KoZW, 1969Be74, 1971Az02, 1972Ma71, 1973Ma35, 1975De17, 1975Ge06, +106PD5C 1975Hs02, 1976Sh25, 1977Ok02, 1982Ka10, 1983Ku03, 1992Gr21, 1993Ch32, +106PD6C 1996Sc06, 2000He14, 2002Ba85, 2005Ki02, 2008Ki07, 2008De09, 2012Wa38 +106PD T Auger electrons and X ray energies and emission intensities: +106PD T {U Energy (keV)} {U Intensity} {U Line} +106PD T +106PD T 21.0203 0.0310 5 XKA2 +106PD T 21.1774 0.0586 9 XKA1 +106PD T +106PD T 23.7914 |] XKB3 +106PD T 23.819 |] 0.01608 29 XKB1 +106PD T 24.013 |] XKB5II +106PD T +106PD T 24.2994 |] XKB2 +106PD T 24.344 |] 0.00273 10 XKB4 +106PD T +106PD T 2.5045-3.5545 0.00785 14 XL (total) +106PD T 2.5045 0.000174 5 XLL +106PD T 2.8337-2.839 0.00468 11 XLA +106PD T 2.6611 6.08E-5 17 XLC +106PD T 2.9904-3.1715 0.00270 8 XLB +106PD T 3.2464-3.5545 0.000242 6 XLG +106PD T +106PD T 17.032-17.884 |] KLL AUGER +106PD T 20.032-21.176 |] 0.0238 7 KLX AUGER +106PD T 23.011-24.347 |] KXY AUGER +106PD T 1.83-3.6 0.1377 8 L AUGER +106RH P 0.0 1+ 30.1 S 3 3546 5 +106PD N 1.0 1.0 1 1.0 +106PD L 0 0+ STABLE +106PD B 3546 5 78.80 24 5.18 +106PDS B EAV=1511.1 24 +106PD L 511.8547 232+ +106PD B 3034 5 8.2 3 5.87 +106PDS B EAV=1269.5 24 +106PD G 511.8534 2320.52 23E2 0.00559 8 +106PD2 G KC=0.00484 7$LC=0.000612 9$MC=1.153E-4 17$NC=1.92E-5 3 +106PD L 1128.02 3 2+ +106PD B 2418 5 0.608 21 6.58 +106PDS B EAV=981.6 24 +106PD G 616.16 3 0.731 17M1+E2 -9.4 20 0.00333 5 +106PD2 G KC=0.00289 4$LC=0.000357 5$MC=6.71E-5 10$NC=1.120E-5 16 +106PD G 1128.01 3 0.398 8E2 7.73E-411 +106PD2 G KC=0.000675 10$LC=7.90E-5 11$MC=1.479E-5 21$NC=2.49E-6 4 +106PD3 G IPC=1.341E-6 19 +106PD L 1133.76 4 0+ +106PD B 2412 5 9.82 15 5.37 +106PDS B EAV=978.9 24 +106PD G 621.90 4 9.87 15E2 0.00324 5 +106PD2 G KC=0.00282 4$LC=0.000348 5$MC=6.54E-5 10$NC=1.092E-5 16 +106PD G 1133.75 4 E0 +106PD L 1229.30 4 4+ +106PD B 2317 5 0.0051 5 11 2U +106PDS B EAV=951.8 23 +106PD G 717.44 4 0.0067 4E2 0.00223 4 +106PD2 G KC=0.00194 3$LC=0.000236 4$MC=4.43E-5 7$NC=7.42E-6 11 +106PD L 1557.68 4 3+ +106PD G 1045.82 4 0.0131 16M1+E2 -3.8 4 9.18E-413 +106PD2 G KC=0.000803 12$LC=9.42E-5 14$MC=1.766E-5 25$NC=2.97E-6 5 +106PD L 1562.25 3 2+ +106PD B 1984 5 1.67 3 5.79 +106PDS B EAV=781.9 23 +106PD G 428.49 5 0.0704 24E2 0.0094714 +106PD2 G KC=0.00817 12$LC=0.001063 15$MC=0.000200 3$NC=3.32E-5 5 +106PD G 434.23 4 0.020 4E2 0.0090913 +106PD2 G KC=0.00785 11$LC=0.001019 15$MC=0.000192 3$NC=3.18E-5 5 +106PD G 1050.39 3 1.490 25M1+E2 0.24 1 1007E-615 +106PD2 G KC=0.000883 13$LC=1.018E-4 15$MC=1.91E-5 3$NC=3.22E-6 5 +106PD G 1562.24 3 0.156 8 +106PD L 1706.44 5 0+ +106PD B 1840 5 0.0664 10 7.06 +106PDS B EAV=716.4 23 +106PD G 578.42 6 0.0090 6E2 0.00395 6 +106PD2 G KC=0.00343 5$LC=0.000427 6$MC=8.04E-5 12$NC=1.340E-5 19 +106PD G 1194.58 5 0.0573 8E2 6.89E-410 +106PD2 G KC=0.000597 9$LC=6.96E-5 10$MC=1.304E-5 19$NC=2.19E-6 3 +106PD3 G IPC=6.64E-6 10 +106PD L 1909.37 16(1,2)+ +106PD B 1637 5 0.00277 21 8.24 +106PDS B EAV=625.2 23 +106PD G 1397.51 160.00277 21 +106PD L 2001.48 5 0+ +106PD B 1545 5 0.448 9 5.93 +106PDS B EAV=584.3 23 +106PD G 439.23 6 0.0111 16 +106PD G 873.46 6 0.435 8E2 1375E-620 +106PD2 G KC=0.001201 17$LC=1.432E-4 20$MC=2.69E-5 4$NC=4.51E-6 7 +106PD G 1489.61 5 0.0018 3 +106PD L 2242.48 5 2+ +106PD B 1304 5 0.0372 8 6.72 +106PDS B EAV=478.7 22 +106PD G 680.23 6 0.0103 6E1+M2 0.4 0.00268 4 +106PD2 G KC=0.00234 4$LC=0.000274 4$MC=5.15E-5 8$NC=8.68E-6 13 +106PD G 684.80 6 0.00552 21 +106PD G 1108.71 6 0.0056 3 +106PD G 1114.45 6 0.0117 3M1+E2 1.5 8.23E-414 +106PD2 G KC=0.000720 12$LC=8.38E-5 14$MC=1.570E-5 25$NC=2.64E-6 5 +106PD3 G IPC=8.30E-7 17 +106PD G 1730.44 200.00209 13 +106PD G 2242.45 5 0.00195 8 +106PD L 2278.11 9 0+ +106PD B 1268 5 0.043 5 6.62 +106PDS B EAV=463.3 22 +106PD G 715.86 9 0.0099 4 +106PD G 1150.08 9 0.00287 17E2 7.42E-411 +106PD2 G KC=0.000648 9$LC=7.57E-5 11$MC=1.417E-5 20$NC=2.38E-6 4 +106PD3 G IPC=2.48E-6 4 +106PD G 1766.24 9 0.030 5E2 5.06E-4 7 +106PD2 G KC=0.000274 4$LC=3.14E-5 5$MC=5.86E-6 9$NC=9.89E-7 14 +106PD3 G IPC=0.000193 3 +106PD L 2308.82 5 2+ +106PD B 1237 5 0.0430 7 6.57 +106PDS B EAV=450.1 22 +106PD G 751.26 200.00121 23 +106PD G 1180.79 6 0.0144 3M1+E2 -0.06 12 7.90E-412 +106PD2 G KC=0.000689 10$LC=7.92E-5 12$MC=1.482E-5 22$NC=2.50E-6 4 +106PD3 G IPC=4.21E-6 7 +106PD G 1796.95 5 0.0274 5M1+E2 0.25 2 5.16E-4 8 +106PD2 G KC=0.000287 4$LC=3.27E-5 5$MC=6.11E-6 9$NC=1.032E-6 15 +106PD3 G IPC=0.000189 3 +106PD L 2439.10 7 2+ +106PD B 1107 5 0.0208 5 6.71 +106PDS B EAV=394.7 21 +106PD G 1209.79 8 0.00039 8 +106PD G 1305.33 8 0.00109 12 +106PD G 1927.23 7 0.0147 4M1+E2 -0.07 5.32E-4 8 +106PD2 G KC=0.000250 4$LC=2.85E-5 4$MC=5.33E-6 8$NC=9.00E-7 13 +106PD3 G IPC=0.000247 4 +106PD G 2439.07 7 0.00464 13E2 6.89E-410 +106PD2 G KC=1.525E-4 22$LC=1.727E-5 25$MC=3.23E-6 5$NC=5.45E-7 8 +106PD3 G IPC=0.000515 8 +106PD L 2484.66 20(1)- +106PD B 1061 5 0.00093 15 7.99 +106PDS B EAV=375.6 21 +106PD G 1973.4 8 0.00017 4 +106PD G 2484.63 200.00076 14 +106PD L 2500.31 8 2- +106PD B 1046 5 0.0284 6 6.48 1 +106PDS B EAV=369.0 21 +106PD G 942.63 9 0.00060 18 +106PD G 1372.28 9 0.00199 15 +106PD G 1988.44 8 0.0258 5E1+M2 0.05 7.35E-411 +106PD2 G KC=1.173E-4 22$LC=1.318E-5 25$MC=2.46E-6 5$NC=4.15E-7 8 +106PD3 G IPC=0.000602 9 +106PD L 2624.40 5 0+ +106PD B 922 5 0.090 3 5.78 +106PDS B EAV=317.8 21 +106PD G 1062.14 6 0.0304 19 +106PD G 1496.37 6 0.0240 17 +106PD G 2112.52 5 0.0351 7E2 5.81E-4 9 +106PD2 G KC=0.000197 3$LC=2.24E-5 4$MC=4.19E-6 6$NC=7.07E-7 10 +106PD3 G IPC=0.000357 5 +106PD L 2705.30 8 (1)+ +106PD B 841 5 0.0106 4 6.56 +106PDS B EAV=285.1 20 +106PD G 702.8 100.00029 18 +106PD G 1572.47 200.00185 19 +106PD G 1577.27 9 0.00105 16 +106PD G 2193.17 100.00495 21M1+E2 -0.17 6 5.94E-4 9 +106PD2 G KC=0.000194 3$LC=2.20E-5 3$MC=4.12E-6 6$NC=6.96E-7 10 +106PD3 G IPC=0.000373 6 +106PD G 2705.26 8 0.00248 13 +106PD L 2717.59 21 +106PD B 828 5 0.00023 12 +106PD G 1159.90 210.00023 12 +106PD L 2783.74 212+ +106PD B 762 5 0.00117 8 7.36 +106PDS B EAV=254 2 +106PD G 2271.86 210.00117 8 +106PD L 2820.97 9 2+ +106PD B 725 5 0.0090 3 6.4 +106PDS B EAV=239.4 20 +106PD G 1258.71 9 0.00066 8 +106PD G 1687.20 100.00055 16 +106PD G 1693.2 3 0.00082 14 +106PD G 2309.09 9 0.00575 16 +106PD G 2821.2 3 0.00120 4 +106PD L 2828.29 9 0+ +106PD B 718 5 0.00731 19 6.47 +106PDS B EAV=236.6 20 +106PD G 1266.03 9 0.00109 10 +106PD G 2316.41 9 0.00622 16E2 6.46E-4 9 +106PD2 G KC=1.670E-4 24$LC=1.89E-5 3$MC=3.54E-6 5$NC=5.98E-7 9 +106PD3 G IPC=0.000456 7 +106PD L 2877.92 7 0+ +106PD B 668 5 0.0262 9 5.81 +106PDS B EAV=217.5 20 +106PD G 1315.66 8 0.0030 5E2 5.86E-4 9 +106PD2 G KC=0.000489 7$LC=5.67E-5 8$MC=1.061E-5 15$NC=1.79E-6 3 +106PD3 G IPC=2.80E-5 4 +106PD G 2366.04 7 0.0232 7E2 6.63E-410 +106PD2 G KC=1.608E-4 23$LC=1.82E-5 3$MC=3.41E-6 5$NC=5.75E-7 8 +106PD3 G IPC=0.000480 7 +106PD L 2902.48 102+ +106PD B 644 5 0.00760 18 6.29 +106PDS B EAV=208.1 19 +106PD G 1774.44 100.00094 8 +106PD G 2390.60 100.00659 16M1+E2 -0.1 6.54E-410 +106PD2 G KC=1.645E-4 24$LC=1.86E-5 3$MC=3.49E-6 5$NC=5.89E-7 9 +106PD3 G IPC=0.000467 7 +106PD G 2902.6 5 0.00006621 +106PD L 2917.86 8 2+ +106PD B 628 5 0.0183 7 5.87 +106PDS B EAV=202.3 19 +106PD G 1355.60 9 0.00060 25 +106PD G 1360.17 9 0.0018 4 +106PD G 1784.08 9 0.00043 12 +106PD G 2405.98 8 0.0145 4M1+E2 -0.05 6.59E-410 +106PD2 G KC=1.626E-4 23$LC=1.84E-5 3$MC=3.44E-6 5$NC=5.82E-7 9 +106PD3 G IPC=0.000474 7 +106PD G 2917.6 3 0.00094 4 +106PD L 2968.68 213- +106PD B 577 5 0.00022 4 7.82 1U +106PDS B EAV=202.8 19 +106PD G 2456.79 210.00022 4 +106PD L 3037.32 171,2+ +106PD B 509 5 0.0022 3 +106PD G 1909.28 170.00107 25 +106PD G 2525.43 170.00011 3 +106PD G 3037.3 3 0.00105 4 +106PD L 3054.97 9 1+ +106PD B 491 5 0.0101 5 5.76 +106PDS B EAV=151.8 18 +106PD G 1498.73 160.0068 4 +106PD G 2542.79 100.00289 9M1+E2 0.07 7 7.05E-410 +106PD2 G KC=1.464E-4 21$LC=1.657E-5 24$MC=3.10E-6 5$NC=5.24E-7 8 +106PD3 G IPC=0.000539 8 +106PD G 3055.0 3 0.00036 4 +106PD L 3083.91 180+ +106PD B 462 5 0.00278 13 +106PD G 1854.89 200.00125 10 +106PD G 1954.9 4 0.00020 4 +106PD G 2571.16 200.00133 6 +106PD L 3163.7 3 (1,2)+ +106PD B 382 5 0.00070 5 6.55 +106PDS B EAV=113.8 17 +106PD G 2651.39 200.00068 4 +106PD G 3164.6 100.00002312 +106PD L 3221.37 250+ +106PD B 325 5 0.00402 13 5.56 +106PDS B EAV=94.5 17 +106PD G 2093.33 250.00029 6E2 5.76E-4 8 +106PD2 G KC=0.000200 3$LC=2.28E-5 4$MC=4.26E-6 6$NC=7.19E-7 10 +106PD3 G IPC=0.000348 5 +106PD G 2709.48 250.00373 11E2 7.85E-411 +106PD2 G KC=1.271E-4 18$LC=1.436E-5 21$MC=2.68E-6 4$NC=4.53E-7 7 +106PD3 G IPC=0.000641 9 +106PD L 3249.9 5 2+ +106PD B 296 5 0.00008616 7.09 +106PDS B EAV=85.2 17 +106PD G 3249.8 5 0.00008616 +106PD L 3252.0 4 2+ +106PD B 294 5 0.00021 4 6.7 +106PDS B EAV=84.5 17 +106PD G 2740.1 4 0.00021 4 +106PD L 3273.5 7 1,2+ +106PD B 272 5 0.00004914 +106PD G 3273.4 7 0.00004914 +106PD L 3299.2 7 +106PD B 247 5 0.00008221 +106PD G 2788.2 5 0.00008221 +106PD L 3320.5 3 0+ +106PD B 226 5 0.00087 8 5.71 +106PDS B EAV=62.9 16 +106PD G 2185.7 5 0.00025 6 +106PD G 2809.1 3 0.00062 4E2 8.22E-412 +106PD2 G KC=1.195E-4 17$LC=1.349E-5 19$MC=2.52E-6 4$NC=4.26E-7 6 +106PD3 G IPC=0.000686 10 +106PD L 3376.6 9 +106PD B 169 5 0.000025 9 +106PD G 2865 1 0.000014 8 +106PD G 3375.9 141.13E-5 21 +106PD L 3401.9 6 +106PD B 144 5 1.25E-5 19 +106PD G 3401.8 9 1.25E-5 19 + diff --git a/HEN_HOUSE/spectra/lnhb/Rn-217.txt b/HEN_HOUSE/spectra/lnhb/Rn-217.txt index 1c4cc9c85..10e4828c4 100644 --- a/HEN_HOUSE/spectra/lnhb/Rn-217.txt +++ b/HEN_HOUSE/spectra/lnhb/Rn-217.txt @@ -1,15 +1,14 @@ -213PO 217RN A DECAY (0.54 MS) -213PO H TYP=Full$AUT=Huang Xiaolong$CUT=31-DEC-2007$ -213PO C Evaluation history: Type=Full;Author=Huang Xiaolong;Cutoff date=31-DEC-2007 -213PO T Auger electrons and X ray energies and emission intensities: -213PO T {U Energy (keV)} {U Intensity} {U Line} -213PO T -213PO T -213PO T -213PO T -213PO T -217RN P 0.0 9/2+ 0.54 MS 5 7887 3 -213PO N 1.0 1.0 1 1.0 -213PO L 0 9/2+ 3.70 US 5 -213PO A 7742 3 100 1.49 - +213PO 217RN A DECAY (0.54 MS) +213PO H TYP=FUL$AUT=X.HUANG$CUT=31-DEC-2007$ +213PO T Auger electrons and X ray energies and emission intensities: +213PO T {U Energy (keV)} {U Intensity} {U Line} +213PO T +213PO T +213PO T +213PO T +213PO T +217RN P 0.0 9/2+ 0.54 MS 5 7887 3 +213PO N 1.0 1.0 1 +213PO L 0 9/2+ 3.70 US 5 +213PO A 7742 3 100 1.49 + diff --git a/HEN_HOUSE/spectra/lnhb/Rn-218.txt b/HEN_HOUSE/spectra/lnhb/Rn-218.txt index 1b50b18c6..77dc2528e 100644 --- a/HEN_HOUSE/spectra/lnhb/Rn-218.txt +++ b/HEN_HOUSE/spectra/lnhb/Rn-218.txt @@ -1,35 +1,34 @@ -214PO 218RN A DECAY (36.0 MS) -214PO H TYP=Full$AUT=V.Chisté$CUT= -- $ -214PO C Evaluation history: Type=Full;Author=V.Chisté;Cutoff date= -- -214PO C References: 1956As38, 1958To25, 1961Ru06, 1963Di05, 1969Pe17, 1971Er02, -214PO2C 1976Ku08, 1979Ry03, 1982Bo04, 1987El12, 1991Ry01, 1995El07, 1996Sc06, -214PO3C 1998Ak04, 2002Ba85, 2003Au03 -214PO T Auger electrons and X ray energies and emission intensities: -214PO T {U Energy (keV)} {U Intensity} {U Line} -214PO T -214PO T 76.864 0.00052 4 XKA2 -214PO T 79.293 0.00086 6 XKA1 -214PO T -214PO T 89.256 |] XKB3 -214PO T 89.807 |] 0.00029621 XKB1 -214PO T 90.363 |] XKB5II -214PO T -214PO T 92.263 |] XKB2 -214PO T 92.618 |] 0.000092 7 XKB4 -214PO T 92.983 |] XKO23 -214PO T -214PO T 9.66-16.21 0.00080 3 XL (total) -214PO T 9.66 1.90E-5 11 XLL -214PO T 11.0161-11.1303 0.00034918 XLA -214PO T 12.0847 6.7E-6 4 XLC -214PO T 12.8239-13.6358 0.00035615 XLB -214PO T 15.251-16.21 0.000072 3 XLG -218RN P 0.0 0+ 36.0 MS 19 7262.5 19 -214PO N 1.0 1.0 1 1.0 -214PO L 0 0+ 162.3 US 12 -214PO A 7129.2 1999.873 7 1 -214PO L 609.31 6 2+ -214PO A 6531.1 190.127 7 4.8 -214PO G 609.31 6 0.124 7E2 0.0204 3 -214PO2 G KC=0.01487 21$LC=0.00416 6$MC=1030E-6 15 - +214PO 218RN A DECAY (36.0 MS) +214PO H TYP=FUL$AUT=V.CHISTE$CUT=31-JAN-2007$ +214PO C References:1956As38, 1958To25, 1961Ru06, 1963Di05, 1969Pe17, 1971Er02, +214PO2C 1976Ku08, 1979Ry03, 1982Bo04, 1987El12, 1991Ry01, 1995El07, 1996Sc06, +214PO3C 1998Ak04, 2002Ba85, 2003Au03 +214PO T Auger electrons and X ray energies and emission intensities: +214PO T {U Energy (keV)} {U Intensity} {U Line} +214PO T +214PO T 76.864 0.00052 4 XKA2 +214PO T 79.293 0.00086 6 XKA1 +214PO T +214PO T 89.256 |] XKB3 +214PO T 89.807 |] 0.00029621 XKB1 +214PO T 90.363 |] XKB5II +214PO T +214PO T 92.263 |] XKB2 +214PO T 92.618 |] 0.000092 7 XKB4 +214PO T 92.983 |] XKO23 +214PO T +214PO T 9.66-16.21 0.00080 3 XL (total) +214PO T 9.66 1.90E-5 11 XLL +214PO T 11.0161-11.1303 0.00034918 XLA +214PO T 12.0847 6.7E-6 4 XLC +214PO T 12.8239-13.6358 0.00035615 XLB +214PO T 15.251-16.21 0.000072 3 XLG +218RN P 0.0 0+ 36.0 MS 19 7262.5 19 +214PO N 1.0 1.0 1 +214PO L 0 0+ 162.3 US 12 +214PO A 7129.2 1999.873 71 +214PO L 609.31 6 2+ +214PO A 6531.1 190.127 74.8 +214PO G 609.31 6 0.124 7E2 0.0204 3 +214PO2 G KC=0.01487 21$LC=0.00416 6$MC=0.001030 15$NC=0.000264 4 + diff --git a/HEN_HOUSE/spectra/lnhb/Rn-219.txt b/HEN_HOUSE/spectra/lnhb/Rn-219.txt index dab5ec463..e31edfc9f 100644 --- a/HEN_HOUSE/spectra/lnhb/Rn-219.txt +++ b/HEN_HOUSE/spectra/lnhb/Rn-219.txt @@ -1,102 +1,109 @@ -215PO 219RN A DECAY (3.98 S) -215PO H TYP=Full$AUT=A.L. Nichols$CUT=30-OCT-2010$ -215PO C Evaluation history: Type=Full;Author=A.L. Nichols;Cutoff date=30-OCT-2010 -215PO C References: 1961Ro14, 1962Wa18, 1965Va10, 1966Hu20, 1967Da20, 1968Br17, -215PO2C 1970Da09, 1970Kr08, 1971Gr07, 1976Bl13, 1977La19, 1991Ry01, 1996Sc06, -215PO3C 1998Ak04, 1998ScZM, 1999Li05, 1999ScZX, 2001Br31, 2002Ba85, 2002Ra45, -215PO4C 2003Au03, 2008Ki07 -215PO T Auger electrons and X ray energies and emission intensities: -215PO T {U Energy (keV)} {U Intensity} {U Line} -215PO T -215PO T 76.864 0.540 24 XKA2 -215PO T 79.293 0.90 4 XKA1 -215PO T -215PO T 89.256 |] XKB3 -215PO T 89.807 |] 0.309 15 XKB1 -215PO T 90.363 |] XKB5II -215PO T -215PO T 92.263 |] XKB2 -215PO T 92.618 |] 0.096 5 XKB4 -215PO T 92.983 |] XKO23 -215PO T -215PO T 9.658-16.213 1.01 5 XL (total) -215PO T 9.658 0.0229 9 XLL -215PO T 11.016-11.13 0.420 15 XLA -215PO T 12.085 0.0095 4 XLC -215PO T 12.823-13.778 0.475 13 XLB -215PO T 15.742-16.213 0.098 3 XLG -215PO T -215PO T 58.978-65.205 |] KLL AUGER -215PO T 71.902-79.289 |] 0.067 9 KLX AUGER -215PO T 84.8-93.1 |] KXY AUGER -215PO T 5.434-10.934 1.50 5 L AUGER -219RN P 0.0 5/2+ 3.98 S 3 6946.1 3 -215PO N 1.0 1.0 1 1.0 -215PO G 665.5 100.00009 5 -215PO L 0 9/2+ 1.781 MS 4 -215PO A 6819.2 3 79.4 1011.2 -215PO L 271.228 107/2+ -215PO A 6553.0 3 12.6 3 6.75 -215PO G 271.228 1011.07 22M1+E2 4.0 4 0.201 7 -215PO2 G KC=0.111 6$LC=0.0668 11$MC=0.0173 3 -215PO L 293.56 4 (11/2)+ -215PO A 6531.0 3 0.098 5 710 -215PO G 293.56 4 0.075 3M1+E2 1.0 2 0.34 5 -215PO2 G KC=0.25 4$LC=0.062 4$MC=0.0152 7 -215PO L 401.812 105/2+ -215PO A 6424.8 3 7.85 243.31 -215PO G 130.58 1 0.133 11M1+E2 0.60 6 4.44 13 -215PO2 G KC=3.19 16$LC=0.94 4$MC=0.234 10 -215PO G 401.81 1 6.75 22E2 0.0555 8 -215PO2 G KC=0.0351 5$LC=0.01528 22$MC=0.00390 6 -215PO L 517.60 6 7/2,9/2+ -215PO A 6311.1 3 0.048 3 184 -215PO G 224.04 7 0.0014 2(E2) 0.319 5 -215PO2 G KC=0.1296 19$LC=0.1407 20$MC=0.0370 6 -215PO G 517.60 6 0.043 3M1+E2 1.0 2 0.073 10 -215PO2 G KC=0.058 9$LC=0.0115 11$MC=0.00277 24 -215PO L 608.30 7 (11/2,13/2)+ -215PO A 6222.0 3 0.0043 10860 -215PO G 608.30 7 0.0044 10(M1+E2) -215PO L 676.66 7 + -215PO A 6154.9 3 0.0184 22103 -215PO G 383.1 1 0.00044 7 -215PO G 405.4 1 0.00025 4 -215PO G 676.66 7 0.018 2 -215PO L 708.1 5 + -215PO A 6124.1 6 0.00064 122170 -215PO G 436.9 5 0.00031 6 -215PO G 708.1 5 0.00033 11 -215PO L 732.7 4 + -215PO A 6099.9 5 0.00123 12880 -215PO G 330.9 4 0.00100 11 -215PO G 461.5 4 0.00017 3 -215PO G 732.7 4 0.00007 4 -215PO L 835.32 22 + -215PO A 5999.2 4 0.0032 5 120 -215PO G 564.1 2 0.0015 3 -215PO G 835.32 220.0017 3 -215PO L 877.2 6 + -215PO A 5958.1 7 0.0003 1 830 -215PO G 877.2 6 0.00033 11 -215PO L 891.1 3 + -215PO A 5944.4 4 0.0021 3 103 -215PO G 373.5 3 0.00025 3 -215PO G 489.3 3 0.00064 9 -215PO G 619.9 3 0.00033 11 -215PO G 891.1 3 0.0009 2 -215PO L 930 1 + -215PO A 5906.2 100.00009 5 1590 -215PO G 322 1 0.00009 5 -215PO L 1073.7 4 (5/2)+ -215PO A 5765.1 5 0.00094 1933 -215PO G 556.1 4 0.00006 4M1+E2 1.0 2 0.061 8 -215PO2 G KC=0.048 7$LC=0.0095 9$MC=0.00226 21 -215PO G 671.9 4 0.00022 11M1+E2 -215PO G 802.5 4 0.00033 11M1+E2 -215PO G 1073.7 4 0.00033 11E2 0.00641 9 -215PO2 G KC=0.00510 8$LC=1002E-6 14$MC=2.40E-4 4 -215PO L 1094.2 10 + -215PO A 5745 1 0.00009 5 245 -215PO G 576.6 100.00009 5 - +215PO 219RN A DECAY (3.98 S) +215PO H TYP=FUL$AUT=A.L.NICHOLS$CUT=30-OCT-2010$ +215PO C References:1961Ro14, 1962Wa18, 1965Va10, 1966Hu20, 1967Da20, 1968Br17, +215PO2C 1970Da09, 1970Kr08, 1971Gr07, 1976Bl13, 1977La19, 1991Ry01, 1996Sc06, +215PO3C 1998Ak04, 1998ScZM, 1999Li05, 1999ScZX, 2001Br31, 2002Ba85, 2002Ra45, +215PO4C 2003Au03, 2008Ki07 +215PO T Auger electrons and X ray energies and emission intensities: +215PO T {U Energy (keV)} {U Intensity} {U Line} +215PO T +215PO T 76.864 0.540 24 XKA2 +215PO T 79.293 0.90 4 XKA1 +215PO T +215PO T 89.256 |] XKB3 +215PO T 89.807 |] 0.309 15 XKB1 +215PO T 90.363 |] XKB5II +215PO T +215PO T 92.263 |] XKB2 +215PO T 92.618 |] 0.096 5 XKB4 +215PO T 92.983 |] XKO23 +215PO T +215PO T 9.658-16.213 1.01 5 XL (total) +215PO T 9.658 0.0229 9 XLL +215PO T 11.016-11.13 0.420 15 XLA +215PO T 12.085 0.0095 4 XLC +215PO T 12.823-13.778 0.475 13 XLB +215PO T 15.742-16.213 0.098 3 XLG +215PO T +215PO T 58.978-65.205 |] KLL AUGER +215PO T 71.902-79.289 |] 0.067 9 KLX AUGER +215PO T 84.8-93.1 |] KXY AUGER +215PO T 5.434-10.934 1.50 5 L AUGER +219RN P 0.0 5/2+ 3.98 S 3 6946.1 3 +215PO N 1.0 1.0 1 +215PO G 665.5 100.00009 5 +215PO L 0 9/2+ 1.781 MS 4 +215PO A 6819.2 3 79.4 1011.2 +215PO L 271.228 107/2+ +215PO A 6553.0 3 12.6 36.75 +215PO G 271.228 1011.07 22M1+E2 4.0 4 0.201 7 +215PO2 G KC=0.111 6$LC=0.0668 11$MC=0.0173 3$NC=0.00444 7 +215PO3 G OC=0.000868 13 +215PO L 293.56 4 (11/2)+ +215PO A 6531.0 3 0.098 5710 +215PO G 293.56 4 0.075 3M1+E2 1.0 2 0.34 5 +215PO2 G KC=0.25 4$LC=0.062 4$MC=0.0152 7$NC=0.00391 17 +215PO3 G OC=0.00080 4 +215PO L 401.812 105/2+ +215PO A 6424.8 3 7.85 243.31 +215PO G 130.58 1 0.133 11M1+E2 0.60 6 4.44 13 +215PO2 G KC=3.19 16$LC=0.94 4$MC=0.234 10$NC=0.0601 24 +215PO3 G OC=0.0121 5 +215PO G 401.81 1 6.75 22E2 0.0555 8 +215PO2 G KC=0.0351 5$LC=0.01528 22$MC=0.00390 6$NC=0.001001 14 +215PO3 G OC=0.000198 3 +215PO L 517.60 6 7/2,9/2+ +215PO A 6311.1 3 0.048 3184 +215PO G 224.04 7 0.0014 2(E2) 0.319 5 +215PO2 G KC=0.1296 19$LC=0.1407 20$MC=0.0370 6$NC=0.00950 14 +215PO3 G OC=0.00183 3 +215PO G 517.60 6 0.043 3M1+E2 1.0 2 0.073 10 +215PO2 G KC=0.058 9$LC=0.0115 11$MC=0.00277 24$NC=0.00071 7 +215PO3 G OC=0.000147 14 +215PO L 608.30 7 (11/2,13/2)+ +215PO A 6222.0 3 0.0043 10860 +215PO G 608.30 7 0.0044 10(M1+E2) +215PO L 676.66 7 +215PO A 6154.9 3 0.0184 22103 +215PO G 383.1 1 0.00044 7 +215PO G 405.4 1 0.00025 4 +215PO G 676.66 7 0.018 2 +215PO L 708.1 5 +215PO A 6124.1 6 0.00064 122170 +215PO G 436.9 5 0.00031 6 +215PO G 708.1 5 0.00033 11 +215PO L 732.7 4 +215PO A 6099.9 5 0.00123 12880 +215PO G 330.9 4 0.00100 11 +215PO G 461.5 4 0.00017 3 +215PO G 732.7 4 0.00007 4 +215PO L 835.32 22 +215PO A 5999.2 4 0.0032 5120 +215PO G 564.1 2 0.0015 3 +215PO G 835.32 220.0017 3 +215PO L 877.2 6 +215PO A 5958.1 7 0.0003 1830 +215PO G 877.2 6 0.00033 11 +215PO L 891.1 3 +215PO A 5944.4 4 0.0021 3103 +215PO G 373.5 3 0.00025 3 +215PO G 489.3 3 0.00064 9 +215PO G 619.9 3 0.00033 11 +215PO G 891.1 3 0.0009 2 +215PO L 930 1 +215PO A 5906.2 100.00009 51590 +215PO G 322 1 0.00009 5 +215PO L 1073.7 4 (5/2)+ +215PO A 5765.1 5 0.00094 1933 +215PO G 556.1 4 0.00006 4M1+E2 1.0 2 0.061 8 +215PO2 G KC=0.048 7$LC=0.0095 9$MC=0.00226 21$NC=0.00058 6 +215PO3 G OC=0.000120 12 +215PO G 671.9 4 0.00022 11M1+E2 +215PO G 802.5 4 0.00033 11M1+E2 +215PO G 1073.7 4 0.00033 11E2 0.00641 9 +215PO2 G KC=0.00510 8$LC=0.001002 14$MC=0.000240 4$NC=6.16E-5 9 +215PO3 G OC=1.268E-5 18 +215PO L 1094.2 10 +215PO A 5745 1 0.00009 5245 +215PO G 576.6 100.00009 5 + diff --git a/HEN_HOUSE/spectra/lnhb/Rn-220.txt b/HEN_HOUSE/spectra/lnhb/Rn-220.txt index 0dc9b12cf..18daf0059 100644 --- a/HEN_HOUSE/spectra/lnhb/Rn-220.txt +++ b/HEN_HOUSE/spectra/lnhb/Rn-220.txt @@ -1,43 +1,42 @@ -216PO 220RN A DECAY (55.8 S) -216PO H TYP=Update$AUT=A.L. Nichols$CUT=30-APR-2010$ -216PO2 H TYP=Full$AUT=A.L. Nichols$CUT=30-APR-2003$ -216PO C Evaluation history: Type=Update;Author=A.L. Nichols;Cutoff date=30-APR-2010 -216PO2C Type=Full;Author=A.L. Nichols;Cutoff date=30-APR-2003 -216PO C References: 1955Sc81, 1956Ma28, 1961Ro14, 1962Wa28, 1963Gi17, 1966Hu20, -216PO2C 1972DaZA, 1973Da38, 1977La19, 1977Ku15, 1984Ge07, 1996Sc06, 1997Ar04, -216PO3C 1998ScZM, 1999ScZX, 2002Ba85, 2002Ra45, 2003Au03, 2007St23, 2007Wu02, -216PO4C 2008Ki07 -216PO T Auger electrons and X ray energies and emission intensities: -216PO T {U Energy (keV)} {U Intensity} {U Line} -216PO T -216PO T 76.864 0.00059 8 XKA2 -216PO T 79.293 0.00099 13 XKA1 -216PO T -216PO T 89.256 |] XKB3 -216PO T 89.807 |] 0.00034 5 XKB1 -216PO T 90.363 |] XKB5II -216PO T -216PO T 92.263 |] XKB2 -216PO T 92.618 |] 0.00010615 XKB4 -216PO T 92.983 |] XKO23 -216PO T -216PO T 9.658-16.213 0.00094 8 XL (total) -216PO T 9.658 2.22E-5 22 XLL -216PO T 11.016-11.13 0.00041 4 XLA -216PO T 12.085 8.1E-6 9 XLC -216PO T 12.823-13.778 0.00042 4 XLB -216PO T 15.742-16.213 0.000086 7 XLG -216PO T -216PO T 58.978-65.205 |] KLL AUGER -216PO T 71.902-79.289 |] 0.00007413 KLX AUGER -216PO T 84.8-93.1 |] KXY AUGER -216PO T 5.434-10.934 0.00140 11 L AUGER -220RN P 0.0 0+ 55.8 S 3 6404.67 10 -216PO N 1.0 1.0 1 1.0 -216PO L 0 0+ 0.148 S 4 -216PO A 6288.22 1099.882 151 -216PO L 549.76 4 2+ -216PO A 5748.46 110.118 153.1 -216PO G 549.76 4 0.115 15E2 0.0257 4 -216PO2 G KC=0.0183 3$LC=0.00561 8$MC=1399E-6 20 - +216PO 220RN A DECAY (55.8 S) +216PO H TYP=UPD$AUT=A.L.NICHOLS$CUT=30-APR-2010$ +216PO2 H TYP=FUL$AUT=A.L.NICHOLS$CUT=30-APR-2003$ +216PO C References:1955Sc81, 1956Ma28, 1961Ro14, 1962Wa28, 1963Gi17, 1966Hu20, +216PO2C 1972DaZA, 1973Da38, 1977La19, 1977Ku15, 1984Ge07, 1996Sc06, 1997Ar04, +216PO3C 1998ScZM, 1999ScZX, 2002Ba85, 2002Ra45, 2003Au03, 2007St23, 2007Wu02, +216PO4C 2008Ki07 +216PO T Auger electrons and X ray energies and emission intensities: +216PO T {U Energy (keV)} {U Intensity} {U Line} +216PO T +216PO T 76.864 0.00059 8 XKA2 +216PO T 79.293 0.00099 13 XKA1 +216PO T +216PO T 89.256 |] XKB3 +216PO T 89.807 |] 0.00034 5 XKB1 +216PO T 90.363 |] XKB5II +216PO T +216PO T 92.263 |] XKB2 +216PO T 92.618 |] 0.00010615 XKB4 +216PO T 92.983 |] XKO23 +216PO T +216PO T 9.658-16.213 0.00094 8 XL (total) +216PO T 9.658 2.22E-5 22 XLL +216PO T 11.016-11.13 0.00041 4 XLA +216PO T 12.085 8.1E-6 9 XLC +216PO T 12.823-13.778 0.00042 4 XLB +216PO T 15.742-16.213 0.000086 7 XLG +216PO T +216PO T 58.978-65.205 |] KLL AUGER +216PO T 71.902-79.289 |] 0.00007413 KLX AUGER +216PO T 84.8-93.1 |] KXY AUGER +216PO T 5.434-10.934 0.00140 11 L AUGER +220RN P 0.0 0+ 55.8 S 3 6404.67 10 +216PO N 1.0 1.0 1 +216PO L 0 0+ 0.148 S 4 +216PO A 6288.22 1099.882 151 +216PO L 549.76 4 2+ +216PO A 5748.46 110.118 153.1 +216PO G 549.76 4 0.115 15E2 0.0257 4 +216PO2 G KC=0.0183 3$LC=0.00561 8$MC=0.001399 20$NC=0.000359 5 +216PO3 G OC=0.000072 1 + diff --git a/HEN_HOUSE/spectra/lnhb/Rn-222.txt b/HEN_HOUSE/spectra/lnhb/Rn-222.txt index 9d7a1e6ff..845593199 100644 --- a/HEN_HOUSE/spectra/lnhb/Rn-222.txt +++ b/HEN_HOUSE/spectra/lnhb/Rn-222.txt @@ -1,37 +1,38 @@ -218PO 222RN A DECAY (3.8232 D) -218PO H TYP=Full$AUT=V.Chisté$CUT= -- $ -218PO C Evaluation history: Type=Full;Author=V.Chisté;Cutoff date= -- -218PO C References: 1951To25, 1956Ma28, 1956Ma64, 1956Ro31, 1958Sh69, 1958Wa16, -218PO2C 1971Gr17, 1972Bu33, 1979Ry03, 1987El12, 1990Ho28, 1991Ry01, 1995El08, -218PO3C 1996El01, 1996Sc06, 2002Ba85, 2003Au03, 2004Sc04, 2006Ja03, 2007BeZP -218PO T Auger electrons and X ray energies and emission intensities: -218PO T {U Energy (keV)} {U Intensity} {U Line} -218PO T -218PO T 76.864 0.00046910 XKA2 -218PO T 79.293 0.00078116 XKA1 -218PO T -218PO T 89.256 |] XKB3 -218PO T 89.807 |] 0.000269 7 XKB1 -218PO T 90.363 |] XKB5II -218PO T -218PO T 92.263 |] XKB2 -218PO T 92.618 |] 8.37E-5 25 XKB4 -218PO T 92.983 |] XKO23 -218PO T -218PO T 9.66-16.21 0.00076615 XL (total) -218PO T 9.66 1.78E-5 5 XLL -218PO T 11.0161-11.1303 0.000326 9 XLA -218PO T 12.0847 6.65E-6 19 XLC -218PO T 12.8239-14.2476 0.000345 8 XLB -218PO T 15.251-16.21 7.02E-5 16 XLG -222RN P 0.0 0+ 3.8232 D 8 5590.3 3 -218PO N 1.0 1.0 1 1.0 -218PO L 0 0+ 3.071 M 22 -218PO A 5489.48 3099.92 1 1 -218PO L 511 2 2+ -218PO A 4987 1 0.078 1.9 -218PO G 510 2 0.076 [E2] 0.0306 6 -218PO2 G KC=0.0213 4$LC=0.00704 13$MC=0.00177 4 -218PO L 675 5 + -218PO A 4827 4 0.0005 30 - +218PO 222RN A DECAY (3.8232 D) +218PO H TYP=FUL$AUT=V.CHISTE$CUT=31-JAN-2007$ +218PO C References:1923Bo**, 1924Cu**, 1951To25, 1956Ma28, 1956Ma64, 1956Ro31, +218PO2C 1958Sh69, 1958Wa16, 1971Gr17, 1972Bu33, 1979Ry03, 1987El12, 1990Ho28, +218PO3C 1991Ry01, 1995Co**, 1995El08, 1996El01, 1996Sc06, 2002Ba85, 2003Au03, +218PO4C 2004Sc04, 2006Ja03, 2007BeZP +218PO T Auger electrons and X ray energies and emission intensities: +218PO T {U Energy (keV)} {U Intensity} {U Line} +218PO T +218PO T 76.864 0.00046910 XKA2 +218PO T 79.293 0.00078116 XKA1 +218PO T +218PO T 89.256 |] XKB3 +218PO T 89.807 |] 0.000269 7 XKB1 +218PO T 90.363 |] XKB5II +218PO T +218PO T 92.263 |] XKB2 +218PO T 92.618 |] 8.37E-5 25 XKB4 +218PO T 92.983 |] XKO23 +218PO T +218PO T 9.66-16.21 0.00076615 XL (total) +218PO T 9.66 1.78E-5 5 XLL +218PO T 11.0161-11.1303 0.000326 9 XLA +218PO T 12.0847 6.65E-6 19 XLC +218PO T 12.8239-14.2476 0.000345 8 XLB +218PO T 15.251-16.21 7.02E-5 16 XLG +222RN P 0.0 0+ 3.8232 D 8 5590.3 3 +218PO N 1.0 1.0 1 +218PO L 0 0+ 3.071 M 22 +218PO A 5489.48 3099.92 11 +218PO L 511 2 2+ +218PO A 4987 1 0.078 1.9 +218PO G 510 2 0.076 [E2] 0.0306 6 +218PO2 G KC=0.0213 4$LC=0.00704 13$MC=0.00177 4$NC=0.000453 9 +218PO3 G OC=9.06E-5 17 +218PO L 675 5 +218PO A 4827 4 0.0005 30 + diff --git a/HEN_HOUSE/spectra/lnhb/Ru-106.txt b/HEN_HOUSE/spectra/lnhb/Ru-106.txt index 591b01db9..69a791ae3 100644 --- a/HEN_HOUSE/spectra/lnhb/Ru-106.txt +++ b/HEN_HOUSE/spectra/lnhb/Ru-106.txt @@ -1,29 +1,28 @@ -106RH 106RU B- DECAY (371.5 D) -106RH H TYP=Full$AUT=A.Arinc$CUT=31-DEC-2012$ -106RH C Evaluation history: Type=Full;Author=A.Arinc;Cutoff date=31-DEC-2012 -106RH C References: 1950Ag01, 1956Sc87, 1957Me47, 1960Ea02, 1961Wy01, 1965Fl02, -106RH2C 1980Ho17, 1983Wa26, 2004Sc04, 2012Wa38 -106RH T Auger electrons and X ray energies and emission intensities: -106RH T {U Energy (keV)} {U Intensity} {U Line} -106RH T -106RH T 20.0739 XKA2 -106RH T 20.2163 XKA1 -106RH T -106RH T 22.6991 |] XKB3 -106RH T 22.7238 |] XKB1 -106RH T 22.914 |] XKB5II -106RH T -106RH T 23.173 |] XKB2 -106RH T 23.217 |] XKB4 -106RH T -106RH T -106RH T 16.289-17.097 |] KLL AUGER -106RH T 19.138-20.214 |] KLX AUGER -106RH T 21.966-23.215 |] KXY AUGER -106RH T 1.7496-3.4069 L AUGER -106RU P 0.0 0+ 371.5 D 21 39.40 21 -106RH N 1.0 1.0 1 1.0 -106RH L 0 1+ 30.1 S 3 -106RH B 39.40 21100 4.31 -106RHS B EAV=10.03 6 - +106RH 106RU B- DECAY (371.5 D) +106RH H TYP=FUL$AUT=A.ARINC$CUT=31-DEC-2012$ +106RH C References:1950Ag01, 1956Sc87, 1957Me47, 1960Ea02, 1961Wy01, 1965Fl02, +106RH2C 1980Ho17, 1983Wa26, 2004Sc04, 2012Wa38 +106RH T Auger electrons and X ray energies and emission intensities: +106RH T {U Energy (keV)} {U Intensity} {U Line} +106RH T +106RH T 20.0739 XKA2 +106RH T 20.2163 XKA1 +106RH T +106RH T 22.6991 |] XKB3 +106RH T 22.7238 |] XKB1 +106RH T 22.914 |] XKB5II +106RH T +106RH T 23.173 |] XKB2 +106RH T 23.217 |] XKB4 +106RH T +106RH T +106RH T 16.289-17.097 |] KLL AUGER +106RH T 19.138-20.214 |] KLX AUGER +106RH T 21.966-23.215 |] KXY AUGER +106RH T 1.7496-3.4069 L AUGER +106RU P 0.0 0+ 371.5 D 21 39.40 21 +106RH N 1.0 1.0 1 1.0 +106RH L 0 1+ 30.1 S 3 +106RH B 39.40 21100 4.31 +106RHS B EAV=10.03 6 + diff --git a/HEN_HOUSE/spectra/lnhb/S-35.txt b/HEN_HOUSE/spectra/lnhb/S-35.txt index 7ed27fc87..388d655cf 100644 --- a/HEN_HOUSE/spectra/lnhb/S-35.txt +++ b/HEN_HOUSE/spectra/lnhb/S-35.txt @@ -1,20 +1,18 @@ - 35CL 35S B- DECAY (87.25 D) - 35CL H TYP=Full$AUT=M.M. Bé$CUT=15-JAN-2011$ - 35CL2 H TYP=Full$AUT=V.P.Chechev$CUT=30-SEP-1998$ - 35CL C Evaluation history: Type=Full;Author=M.M. Bé;Cutoff date=15-JAN-2011 - 35CL2C Type=Full;Author=V.P.Chechev;Cutoff date=30-SEP-1998 - 35CL C References: 1940Le**, 1941Ka01, 1943He**, 1949Ma76, 1952Ru23, 1958Se49, - 35CL2C 1959Co56, 1959Ca12, 1961Oz01, 1961Wy01, 1965Fl02, 1968Wo06, 1969La34, - 35CL3C 1999Pa18, 2012Au06 - 35CL T Auger electrons and X ray energies and emission intensities: - 35CL T {U Energy (keV)} {U Intensity} {U Line} - 35CL T - 35CL T - 35CL T - 35CL T - 35S P 0.0 3/2+ 87.25 D 15 167.33 3 - 35CL N 1.0 1.0 1 1.0 - 35CL L 0 3/2+ STABLE - 35CL B 167.33 3 100 5.01 - 35CLS B EAV=48.79 1 - + 35CL 35S B- DECAY (87.25 D) + 35CL H TYP=FUL$AUT=M.-M.BE$CUT=15-JAN-2011$ + 35CL2 H TYP=FUL$AUT=V.P.CHECHEV$CUT=30-SEP-1998$ + 35CL C References:1940Le**, 1941Ka01, 1943He**, 1949Ma76, 1952Ru23, 1958Se49, + 35CL2C 1959Co56, 1959Ca12, 1961Oz01, 1961Wy01, 1965Fl02, 1968Wo06, 1969La34, + 35CL3C 1999Pa18, 2012Au06 + 35CL T Auger electrons and X ray energies and emission intensities: + 35CL T {U Energy (keV)} {U Intensity} {U Line} + 35CL T + 35CL T + 35CL T + 35CL T + 35S P 0.0 3/2+ 87.25 D 15 167.33 3 + 35CL N 1.0 1.0 1 1.0 + 35CL L 0 3/2+ STABLE + 35CL B 167.33 3 100 5.01 + 35CLS B EAV=48.79 1 + diff --git a/HEN_HOUSE/spectra/lnhb/Sb-124.txt b/HEN_HOUSE/spectra/lnhb/Sb-124.txt index 565882f65..5bf4f45f1 100644 --- a/HEN_HOUSE/spectra/lnhb/Sb-124.txt +++ b/HEN_HOUSE/spectra/lnhb/Sb-124.txt @@ -1,224 +1,259 @@ -124TE 124SB B- DECAY (60.208 D) -124TE H TYP=Full$AUT=M.M. Bé$CUT=31-DEC-2008$ -124TE C Evaluation history: Type=Full;Author=M.M. Bé;Cutoff date=31-DEC-2008 -124TE C References: 1953La35, 1954Mo83, 1955Az29, 1956Zo06, 1957Ma50, 1956Zo06, -124TE2C 1958Jo01, 1959Ca12, 1965Hs02, 1966Fl01, 1967ST05, 1968Gr24, 1968Re04, -124TE3C 1968Gr24, 1969Me04, 1969Ra31, 1970Si17, 1971GR14, 1972BA38, 1974Jo03, -124TE4C 1979Sh08, 1983RO13, 1984Ma13, 1984Iw03, 1988YO05, 1990Su10, 1990ME15, -124TE5C 1993Go10, 1996Sc06, 2000Kh04, 2000He14, 2000Do11, 2002Ba85, 2003AU03, -124TE6C 2006Pa16, 2008Ki07 -124TE T Auger electrons and X ray energies and emission intensities: -124TE T {U Energy (keV)} {U Intensity} {U Line} -124TE T -124TE T 27.202 0.1252 18 XKA2 -124TE T 27.4726 0.233 3 XKA1 -124TE T -124TE T 30.9446 |] XKB3 -124TE T 30.996 |] 0.0667 12 XKB1 -124TE T 31.236 |] XKB5II -124TE T -124TE T 31.7008 |] XKB2 -124TE T 31.774 |] 0.0145 5 XKB4 -124TE T 31.812 |] XKO23 -124TE T -124TE T 3.3348-4.8228 0.0449 9 XL (total) -124TE T 3.3348 0.00087326 XLL -124TE T 3.7595-3.7697 0.0231 7 XLA -124TE T 3.6052 0.00033611 XLC -124TE T 4.0299-4.3661 0.0180 4 XLB -124TE T 4.4448-4.8228 0.00247 6 XLG -124TE T -124TE T 21.804-22.989 |] KLL AUGER -124TE T 25.814-27.47 |] 0.0628 22 KLX AUGER -124TE T 29.8-31.81 |] KXY AUGER -124TE T 2.3-4.9 0.4829 26 L AUGER -124SB P 0.0 3- 60.208 D 11 2904.3 15 -124TE N 1.0 1.0 1 1.0 -124TE G 159.867 350.0049 6 -124TE G 997.8 3 0.0033 23 -124TE G 1235 1 0.0073 26 -124TE L 0 0+ STABLE -124TE L 602.7278 212+ 6.2 PS 1 -124TE B 2301.6 1523.44 28 10.3 1 -124TES B EAV=918 1 -124TE G 602.7260 2397.775 20E2 0.00490 7 -124TE2 G KC=0.00420 6$LC=5.66E-4 8$MC=1132E-7 16 -124TE L 1248.582 3 4+ -124TE B 1655.7 152.472 33 10.7 1 -124TES B EAV=627 1 -124TE G 645.8520 197.422 15E2+M3 0.006 6 0.00409 6 -124TE2 G KC=0.00351 5$LC=4.68E-4 7$MC=9.35E-5 14 -124TE L 1325.512 3 2+ -124TE B 1578.8 154.815 29 10.3 1 -124TES B EAV=593 1 -124TE G 722.7820 3010.708 22M1+E2 -3.4 3 0.00314 5 -124TE2 G KC=0.00271 4$LC=3.52E-4 5$MC=7.02E-5 10 -124TE G 1325.504 4 1.587 7E2 8.27E-412 -124TE2 G KC=6.93E-4 10$LC=8.48E-5 12$MC=1685E-8 24 -124TE L 1656.6 3 0+ -124TE B 1247.7 150.0053 10 12.8 3 -124TES B EAV=450 1 -124TE G 1053.90 300.0053 10E2 1290E-618 -124TE2 G KC=1117E-6 16$LC=1394E-7 20$MC=2.77E-5 4 -124TE G 1656.6 3 -124TE L 1957.915 164+ -124TE B 946.4 152.295 7 9.8 1 -124TES B EAV=324 1 -124TE G 632.400 200.1029 21 -124TE G 709.330 201.363 5M1+E2 -0.18 5 0.00402 6 -124TE2 G KC=0.00349 5$LC=4.29E-4 7$MC=8.53E-5 13 -124TE G 1355.200 201.0412 38E2+M3 -0.32 25 0.0011 5 -124TE2 G KC=0.0009 5$LC=0.00011 6$MC=2.3E-5 11 -124TE L 2039.288 4 2, 3+ -124TE B 865.0 154.143 18 9.4 1 -124TES B EAV=292 1 -124TE G 713.776 4 2.273 7M1+E2 1.0 5 0.0036 4 -124TE2 G KC=0.0031 4$LC=0.00039 4$MC=7.8E-5 7 -124TE G 790.706 7 0.7415 24E2 0.00248 8 -124TE2 G KC=0.00214 6$LC=2.76E-4 8$MC=5.5E-5 2 -124TE G 1436.554 7 1.234 8M1+E2 1.5 8 0.00078 5 -124TE2 G KC=0.00063 5$LC=7.6E-5 6$MC=1.51E-5 11 -124TE G 2039.27 1 0.0631 5E2 6.67E-410 -124TE2 G KC=3.05E-4 5$LC=3.64E-5 5$MC=7.21E-6 10 -124TE L 2091.680 212+ -124TE B 812.6 150.688 38 10 1 -124TES B EAV=271.0 6 -124TE G 766.170 200.0103 9M1 0.021 7 -124TE2 G KC=0.019 6 -124TE G 1488.940 200.6770 37M1+E2 0.10 23 8.29E-416 -124TE2 G KC=6.59E-4 14$LC=7.92E-5 16$MC=1.57E-5 3 -124TE L 2182.39 3 2+ -124TE B 721.9 150.47 30 10 1 -124TES B EAV=236.0 6 -124TE G 856.870 300.0227 5 -124TE G 1579.650 300.412 5M1+E2 0.00072 5 -124TE2 G KC=0.00054 5$LC=6.5E-5 6$MC=1.28E-5 11 -124TE G 2182.37 3 0.04147 31 -124TE L 2224.839 254+ -124TE B 679.5 150.0967 34 10.6 1 -124TES B EAV=219.5 6 -124TE G 899.320 300.0179 7 -124TE G 976.250 300.0832 7 -124TE G 1622.100 300.0416 19E2 6.64E-410 -124TE2 G KC=4.67E-4 7$LC=5.64E-5 8$MC=1118E-8 16 -124TE L 2293.712 4 3- -124TE B 610.6 1551.21 19 7.7 -124TES B EAV=193.8 6 -124TE G 254.42 1 0.0142 9(E1) 0.0146521 -124TE2 G KC=0.01269 18$LC=1575E-6 22$MC=3.12E-4 5 -124TE G 335.800 200.0725 9E1 0.0070610 -124TE2 G KC=0.00612 9$LC=7.54E-4 11$MC=1495E-7 21 -124TE G 968.195 4 1.887 10E1+M2 -0.02 2 6.53E-411 -124TE2 G KC=5.69E-4 9$LC=6.78E-5 11$MC=1343E-8 22 -124TE G 1045.125 4 1.852 14E1+M2 -0.03 2 5.67E-410 -124TE2 G KC=4.94E-4 9$LC=5.87E-5 11$MC=1163E-8 21 -124TE G 1690.9710 4047.46 19E1+M2 0.01 3 6.15E-4 9 -124TE2 G KC=2.13E-4 4$LC=2.50E-5 4$MC=4.94E-6 8 -124TE G 2293.69 1 0.0327 41 -124TE L 2323.41 3 2+ -124TE B 580.9 150.0686 14 10.5 1 -124TES B EAV=182.8 6 -124TE G 1720.670 300.0946 6M1+E2 0.00068 4 -124TE2 G KC=0.00045 4$LC=5.4E-5 4$MC=1.07E-5 8 -124TE G 2323.39 3 0.0025 6 -124TE L 2335.26 5 5- -124TE G 1086.67 5 0.0367 9E1 5.24E-4 8 -124TE2 G KC=4.57E-4 7$LC=5.43E-5 8$MC=1074E-8 15 -124TE L 2454.96 7 2+ -124TE B 449.3 150.0050 26 11.3 1 -124TES B EAV=135.8 6 -124TE G 1852.22 7 0.0030 9M1+E2 0.00067 3 -124TE2 G KC=0.00039 3$LC=4.7E-5 4$MC=9.3E-6 7 -124TE G 2454.93 7 0.00160 12E2 7.68E-411 -124TE2 G KC=2.19E-4 3$LC=2.59E-5 4$MC=5.13E-6 8 -124TE L 2483.277 184+ -124TE B 421.0 150.332 10 9.4 1 -124TES B EAV=126.0 5 -124TE G 148.02 5 0.0037 6E1+M2 -124TE G 189.570 200.0043 5 -124TE G 444.000 200.195 16M1+E2 0.06 8 0.0126118 -124TE2 G KC=0.01092 16$LC=1360E-6 19$MC=2.71E-4 4 -124TE G 525.360 300.1451 35M1+E2 1.0 4 0.0077 3 -124TE2 G KC=0.0066 3$LC=8.67E-4 18$MC=1.73E-4 4 -124TE L 2512.04 7 4+ -124TE B 392.3 150.0422 19 10.2 1 -124TES B EAV=116.0 5 -124TE G 1263.45 7 0.0422 19 -124TE L 2521.48 6 2+ -124TE B 382.8 150.0529 5 10 1 -124TES B EAV=113.0 5 -124TE G 1918.74 6 0.0529 5M1(+E2) 0.00067 3 -124TE2 G KC=3.64E-4 24$LC=4.3E-5 3$MC=8.6E-6 6 -124TE L 2549.73 9 (4)+ -124TE B 354.6 150.0364 22 10 1 -124TES B EAV=103.6 5 -124TE G 1301.14 9 0.0364 22 -124TE L 2619.09 6 (3)+ -124TE B 285.2 150.0098 8 10.4 -124TES B EAV=81.0 5 -124TE G 2016.34 6 0.0098 8 -124TE L 2682.50 132+ -124TE B 221.8 150.0242 22 9.6 1 -124TES B EAV=61.5 5 -124TE G 2079.75 130.0224 22M1+E2 6.91E-420 -124TE2 G KC=3.11E-4 18$LC=3.71E-5 21$MC=7.3E-6 4 -124TE G 2682.47 130.00176 6 -124TE L 2693.679 5 3- -124TE B 210.6 158.663 27 7 -124TES B EAV=58.0 5 -124TE G 210.400 200.0053 7 -124TE G 370.270 300.0286 11 -124TE G 399.97 1 0.1264 31E2 0.0156622 -124TE2 G KC=0.01323 19$LC=0.00196 3$MC=3.94E-4 6 -124TE G 468.840 300.0459 26E1 0.00309 5 -124TE2 G KC=0.00268 4$LC=3.27E-4 5$MC=6.48E-5 9 -124TE G 1368.157 5 2.620 8E1+M2 -0.02 1 4.78E-4 7 -124TE2 G KC=3.03E-4 5$LC=3.58E-5 6$MC=7.09E-6 10 -124TE G 1445.09 1 0.334 7E1+M2 0.10 9 0.00052 4 -124TE2 G KC=0.00029 4$LC=3.4E-5 4$MC=6.7E-6 8 -124TE G 2090.930 7 5.493 24E1+M2 0.03 2 8.38E-412 -124TE2 G KC=1522E-7 23$LC=1.78E-5 3$MC=3.52E-6 6 -124TE G 2693.650 100.0032 14 -124TE L 2701.622 9 2- -124TE B 202.7 150.571 25 8 -124TES B EAV=55.7 5 -124TE G 662.330 100.024 11 -124TE G 1376.10 1 0.4999 43E1+M2 -0.01 3 4.79E-4 7 -124TE2 G KC=3.00E-4 5$LC=3.54E-5 6$MC=7.01E-6 12 -124TE G 2098.88 1 0.0471 33 -124TE L 2711.012 214+ -124TE B 193.3 150.106 6 8.8 1 -124TES B EAV=52.9 5 -124TE G 1385.490 200.062 6 -124TE G 2108.270 200.0444 23 -124TE L 2775.070 173,4- -124TE B 129.2 150.653 6 7.5 -124TES B EAV=34.4 4 -124TE G 291.790 300.0069 7 -124TE G 481.36 2 0.0232 31 -124TE G 735.780 200.1312 16 -124TE G 817.150 300.0744 12 -124TE G 1526.480 200.414 5E1 5.35E-4 8 -124TE2 G KC=2.52E-4 4$LC=2.96E-5 5$MC=5.86E-6 9 -124TE G 2172.320 200.0029 16 -124TE L 2807.55 242+ -124TE B 96.8 150.0012 5 9.8 1 -124TES B EAV=25.3 4 -124TE G 2807.52 240.0012 5E2 8.78E-413 -124TE2 G KC=1730E-7 25$LC=2.04E-5 3$MC=4.04E-6 6 -124TE L 2814.56 7 2 TO 5+ -124TE B 89.7 150.0207 12 8.4 -124TES B EAV=23.4 4 -124TE G 775.27 7 0.0098 4 -124TE G 1565.97 7 0.0109 12 -124TE L 2865.72 5 3- -124TE B 38.6 150.054 9 6.9 -124TES B EAV=9.8 4 -124TE G 530.46 7 0.036 9 -124TE G 572.01 5 0.0176 8 -124TE L 2886.37 6 3- -124TE B 17.9 150.0059 5 6.9 -124TES B EAV=4.5 4 -124TE G 2283.62 6 0.0059 5E1+M2 0.00091 5 -124TE2 G KC=0.00033 21$LC=4.0E-5 25$MC=8E-6 5 - +124TE 124SB B- DECAY (60.208 D) +124TE H TYP=FUL$AUT=M.-M.BE$CUT=31-DEC-2008$ +124TE C References:1953La35, 1954Mo83, 1955Az29, 1956Zo06, 1957Ma50, 1956Zo06, +124TE2C 1958Jo01, 1959Ca12, 1965Hs02, 1966Fl01, 1967ST05, 1968Gr24, 1968Re04, +124TE3C 1968Gr24, 1969Me04, 1969Ra31, 1970Si17, 1971GR14, 1972BA38, 1974Jo03, +124TE4C 1979Sh08, 1983RO13, 1984Ma13, 1984Iw03, 1988YO05, 1990Su10, 1990ME15, +124TE5C 1993Go10, 1996Sc06, 2000Kh04, 2000He14, 2000Do11, 2002Ba85, 2003Au03, +124TE6C 2006Pa16, 2008Ki07 +124TE T Auger electrons and X ray energies and emission intensities: +124TE T {U Energy (keV)} {U Intensity} {U Line} +124TE T +124TE T 27.202 0.1252 18 XKA2 +124TE T 27.4726 0.233 3 XKA1 +124TE T +124TE T 30.9446 |] XKB3 +124TE T 30.996 |] 0.0667 12 XKB1 +124TE T 31.236 |] XKB5II +124TE T +124TE T 31.7008 |] XKB2 +124TE T 31.774 |] 0.0145 5 XKB4 +124TE T 31.812 |] XKO23 +124TE T +124TE T 3.3348-4.8228 0.0449 9 XL (total) +124TE T 3.3348 0.00087326 XLL +124TE T 3.7595-3.7697 0.0231 7 XLA +124TE T 3.6052 0.00033611 XLC +124TE T 4.0299-4.3661 0.0180 4 XLB +124TE T 4.4448-4.8228 0.00247 6 XLG +124TE T +124TE T 21.804-22.989 |] KLL AUGER +124TE T 25.814-27.47 |] 0.0628 22 KLX AUGER +124TE T 29.8-31.81 |] KXY AUGER +124TE T 2.3-4.9 0.4829 26 L AUGER +124SB P 0.0 3- 60.208 D 11 2904.3 15 +124TE N 1.0 1.0 1 1.0 +124TE G 159.867 350.0049 6 +124TE G 997.8 3 0.0033 23 +124TE G 1235 1 0.0073 26 +124TE L 0 0+ STABLE +124TE L 602.7278 212+ 6.2 PS 1 +124TE B 2301.6 1523.44 28 10.3 1 +124TES B EAV=918 1 +124TE G 602.7260 2397.775 20E2 0.00490 7 +124TE2 G KC=0.00420 6$LC=0.000566 8$MC=1.132E-4 16$NC=2.22E-5 4 +124TE3 G OC=2.33E-6 4 +124TE L 1248.582 3 4+ +124TE B 1655.7 152.472 33 10.7 1 +124TES B EAV=627 1 +124TE G 645.8520 197.422 15E2+M3 0.006 6 0.00409 6 +124TE2 G KC=0.00351 5$LC=0.000468 7$MC=9.35E-5 14$NC=1.84E-5 3 +124TE3 G OC=1.94E-6 3 +124TE L 1325.512 3 2+ +124TE B 1578.8 154.815 29 10.3 1 +124TES B EAV=593 1 +124TE G 722.7820 3010.708 22M1+E2 -3.4 3 0.00314 5 +124TE2 G KC=0.00271 4$LC=0.000352 5$MC=7.02E-5 10$NC=1.382E-5 20 +124TE3 G OC=1.471E-6 22 +124TE G 1325.504 4 1.587 7E2 8.27E-412 +124TE2 G KC=0.000693 10$LC=8.48E-5 12$MC=1.685E-5 24$NC=3.33E-6 5 +124TE3 G OC=3.62E-7 5 +124TE L 1656.6 3 0+ +124TE B 1247.7 150.0053 10 12.8 3 +124TES B EAV=450 1 +124TE G 1053.90 300.0053 10E2 1290E-618 +124TE2 G KC=0.001117 16$LC=1.394E-4 20$MC=2.77E-5 4$NC=5.47E-6 8 +124TE3 G OC=5.90E-7 9 +124TE G 1656.6 3 E0 +124TE L 1957.915 164+ +124TE B 946.4 152.295 7 9.8 1 +124TES B EAV=324 1 +124TE G 632.400 200.1029 21 +124TE G 709.330 201.363 5M1+E2 -0.18 5 0.00402 6 +124TE2 G KC=0.00349 5$LC=0.000429 7$MC=8.53E-5 13$NC=1.689E-5 25 +124TE3 G OC=1.85E-6 3 +124TE G 1355.200 201.0412 38E2+M3 -0.32 25 0.0011 5 +124TE2 G KC=0.0009 5$LC=0.00011 6$MC=0.000023 11$NC=4.5E-6 22 +124TE3 G OC=4.9E-7 24 +124TE L 2039.288 4 2,3+ +124TE B 865.0 154.143 18 9.4 1 +124TES B EAV=292 1 +124TE G 713.776 4 2.273 7M1+E2 1.0 5 0.0036 4 +124TE2 G KC=0.0031 4$LC=0.00039 4$MC=0.000078 7$NC=1.54E-5 14 +124TE3 G OC=1.66E-6 17 +124TE G 790.706 7 0.7415 24E2 0.00248 8 +124TE2 G KC=0.00214 6$LC=0.000276 8$MC=0.000055 2$NC=1.082E-5 40 +124TE3 G OC=1.154E-6 40 +124TE G 1436.554 7 1.234 8M1+E2 1.5 8 0.00078 5 +124TE2 G KC=0.00063 5$LC=0.000076 6$MC=1.51E-5 11$NC=2.99E-6 21 +124TE3 G OC=3.26E-7 24 +124TE G 2039.27 1 0.0631 5E2 6.67E-410 +124TE2 G KC=0.000305 5$LC=3.64E-5 5$MC=7.21E-6 10$NC=1.427E-6 20 +124TE3 G OC=1.562E-7 22 +124TE L 2091.680 212+ +124TE B 812.6 150.688 38 10 1 +124TES B EAV=271.0 6 +124TE G 766.170 200.0103 9E0,M1 0.021 7 +124TE2 G KC=0.019 6 +124TE G 1488.940 200.6770 37M1+E2 0.10 23 8.29E-416 +124TE2 G KC=0.000659 14$LC=7.92E-5 16$MC=1.57E-5 3$NC=3.11E-6 7 +124TE3 G OC=3.42E-7 7 +124TE L 2182.39 3 2+ +124TE B 721.9 150.47 30 10 1 +124TES B EAV=236.0 6 +124TE G 856.870 300.0227 5 +124TE G 1579.650 300.412 5M1+E2 0.00072 5 +124TE2 G KC=0.00054 5$LC=0.000065 6$MC=1.28E-5 11$NC=2.54E-6 21 +124TE3 G OC=2.78E-7 24 +124TE G 2182.37 3 0.04147 31 +124TE L 2224.839 254+ +124TE B 679.5 150.0967 34 10.6 1 +124TES B EAV=219.5 6 +124TE G 899.320 300.0179 7 +124TE G 976.250 300.0832 7 +124TE G 1622.100 300.0416 19E2 6.64E-410 +124TE2 G KC=0.000467 7$LC=5.64E-5 8$MC=1.118E-5 16$NC=2.21E-6 3 +124TE3 G OC=2.41E-7 4 +124TE L 2293.712 4 3- +124TE B 610.6 1551.21 19 7.7 +124TES B EAV=193.8 6 +124TE G 254.42 1 0.0142 9(E1) 0.0146521 +124TE2 G KC=0.01269 18$LC=0.001575 22$MC=0.000312 5$NC=6.13E-5 9 +124TE3 G OC=6.51E-6 10 +124TE G 335.800 200.0725 9E1 0.0070610 +124TE2 G KC=0.00612 9$LC=0.000754 11$MC=1.495E-4 21$NC=2.94E-5 5 +124TE3 G OC=3.15E-6 5 +124TE G 968.195 4 1.887 10E1+M2 -0.02 2 6.53E-411 +124TE2 G KC=0.000569 9$LC=6.78E-5 11$MC=1.343E-5 22$NC=2.65E-6 5 +124TE3 G OC=2.89E-7 5 +124TE G 1045.125 4 1.852 14E1+M2 -0.03 2 5.67E-410 +124TE2 G KC=0.000494 9$LC=5.87E-5 11$MC=1.163E-5 21$NC=2.30E-6 4 +124TE3 G OC=2.51E-7 5 +124TE G 1690.9710 4047.46 19E1+M2 0.01 3 6.15E-4 9 +124TE2 G KC=0.000213 4$LC=2.50E-5 4$MC=4.94E-6 8$NC=9.78E-7 15 +124TE3 G OC=1.071E-7 17 +124TE G 2293.69 1 0.0327 41 +124TE L 2323.41 3 2+ +124TE B 580.9 150.0686 14 10.5 1 +124TES B EAV=182.8 6 +124TE G 1720.670 300.0946 6M1+E2 0.00068 4 +124TE2 G KC=0.00045 4$LC=0.000054 4$MC=1.07E-5 8$NC=2.13E-6 16 +124TE3 G OC=2.33E-7 19 +124TE G 2323.39 3 0.0025 6 +124TE L 2335.26 5 5- +124TE G 1086.67 5 0.0367 9E1 5.24E-4 8 +124TE2 G KC=0.000457 7$LC=5.43E-5 8$MC=1.074E-5 15$NC=2.12E-6 3 +124TE3 G OC=2.32E-7 4 +124TE L 2454.96 7 2+ +124TE B 449.3 150.0050 26 11.3 1 +124TES B EAV=135.8 6 +124TE G 1852.22 7 0.0030 9M1+E2 0.00067 3 +124TE2 G KC=0.00039 3$LC=0.000047 4$MC=9.3E-6 7$NC=1.83E-6 13 +124TE3 G OC=2.01E-7 15 +124TE G 2454.93 7 0.00160 12E2 7.68E-411 +124TE2 G KC=0.000219 3$LC=2.59E-5 4$MC=5.13E-6 8$NC=1.016E-6 15 +124TE3 G OC=1.115E-7 16 +124TE L 2483.277 184+ +124TE B 421.0 150.332 10 9.4 1 +124TES B EAV=126.0 5 +124TE G 148.02 5 0.0037 6E1+M2 +124TE G 189.570 200.0043 5 +124TE G 444.000 200.195 16M1+E2 0.06 8 0.0126118 +124TE2 G KC=0.01092 16$LC=0.001360 19$MC=0.000271 4$NC=5.36E-5 8 +124TE3 G OC=5.85E-6 9 +124TE G 525.360 300.1451 35M1+E2 1.0 4 0.0077 3 +124TE2 G KC=0.0066 3$LC=0.000867 18$MC=0.000173 4$NC=3.41E-5 8 +124TE3 G OC=3.64E-6 12 +124TE L 2512.04 7 4+ +124TE B 392.3 150.0422 19 10.2 1 +124TES B EAV=116.0 5 +124TE G 1263.45 7 0.0422 19 +124TE L 2521.48 6 2+ +124TE B 382.8 150.0529 5 10 1 +124TES B EAV=113.0 5 +124TE G 1918.74 6 0.0529 5M1(+E2) 0.00067 3 +124TE2 G KC=0.000364 24$LC=0.000043 3$MC=8.6E-6 6$NC=1.71E-6 11 +124TE3 G OC=1.87E-7 13 +124TE L 2549.73 9 (4)+ +124TE B 354.6 150.0364 22 10 1 +124TES B EAV=103.6 5 +124TE G 1301.14 9 0.0364 22 +124TE L 2619.09 6 (3)+ +124TE B 285.2 150.0098 8 10.4 +124TES B EAV=81.0 5 +124TE G 2016.34 6 0.0098 8 +124TE L 2682.50 132+ +124TE B 221.8 150.0242 22 9.6 1 +124TES B EAV=61.5 5 +124TE G 2079.75 130.0224 22M1+E2 6.91E-420 +124TE2 G KC=0.000311 18$LC=3.71E-5 21$MC=7.3E-6 4$NC=1.46E-6 9 +124TE3 G OC=1.6E-7 1 +124TE G 2682.47 130.00176 6 +124TE L 2693.679 5 3- +124TE B 210.6 158.663 27 7 +124TES B EAV=58.0 5 +124TE G 210.400 200.0053 7 +124TE G 370.270 300.0286 11 +124TE G 399.97 1 0.1264 31E2 0.0156622 +124TE2 G KC=0.01323 19$LC=0.00196 3$MC=0.000394 6$NC=7.67E-5 11 +124TE3 G OC=7.80E-6 11 +124TE G 468.840 300.0459 26E1 0.00309 5 +124TE2 G KC=0.00268 4$LC=0.000327 5$MC=6.48E-5 9$NC=1.278E-5 18 +124TE3 G OC=1.377E-6 20 +124TE G 1368.157 5 2.620 8E1+M2 -0.02 1 4.78E-4 7 +124TE2 G KC=0.000303 5$LC=3.58E-5 6$MC=7.09E-6 10$NC=1.403E-6 20 +124TE3 G OC=1.534E-7 22 +124TE G 1445.09 1 0.334 7E1+M2 0.10 9 0.00052 4 +124TE2 G KC=0.00029 4$LC=0.000034 4$MC=6.7E-6 8$NC=1.34E-6 16 +124TE3 G OC=1.46E-7 18 +124TE G 2090.930 7 5.493 24E1+M2 0.03 2 8.38E-412 +124TE2 G KC=1.522E-4 23$LC=1.78E-5 3$MC=3.52E-6 6$NC=6.97E-7 11 +124TE3 G OC=7.65E-8 12 +124TE G 2693.650 100.0032 14 +124TE L 2701.622 9 2- +124TE B 202.7 150.571 25 8 +124TES B EAV=55.7 5 +124TE G 662.330 100.024 11 +124TE G 1376.10 1 0.4999 43E1+M2 -0.01 3 4.79E-4 7 +124TE2 G KC=0.000300 5$LC=3.54E-5 6$MC=7.01E-6 12$NC=1.387E-6 23 +124TE3 G OC=1.517E-7 25 +124TE G 2098.88 1 0.0471 33 +124TE L 2711.012 214+ +124TE B 193.3 150.106 6 8.8 1 +124TES B EAV=52.9 5 +124TE G 1385.490 200.062 6 +124TE G 2108.270 200.0444 23 +124TE L 2775.070 173,4- +124TE B 129.2 150.653 6 7.5 +124TES B EAV=34.4 4 +124TE G 291.790 300.0069 7 +124TE G 481.36 2 0.0232 31 +124TE G 735.780 200.1312 16 +124TE G 817.150 300.0744 12 +124TE G 1526.480 200.414 5E1 5.35E-4 8 +124TE2 G KC=0.000252 4$LC=2.96E-5 5$MC=5.86E-6 9$NC=1.160E-6 17 +124TE3 G OC=1.270E-7 18 +124TE G 2172.320 200.0029 16 +124TE L 2807.55 242+ +124TE B 96.8 150.0012 5 9.8 1 +124TES B EAV=25.3 4 +124TE G 2807.52 240.0012 5E2 8.78E-413 +124TE2 G KC=1.730E-4 25$LC=2.04E-5 3$MC=4.04E-6 6$NC=8.01E-7 12 +124TE3 G OC=8.80E-8 13 +124TE L 2814.56 7 2:5+ +124TE B 89.7 150.0207 12 8.4 +124TES B EAV=23.4 4 +124TE G 775.27 7 0.0098 4 +124TE G 1565.97 7 0.0109 12 +124TE L 2865.72 5 3- +124TE B 38.6 150.054 9 6.9 +124TES B EAV=9.8 4 +124TE G 530.46 7 0.036 9 +124TE G 572.01 5 0.0176 8 +124TE L 2886.37 6 3- +124TE B 17.9 150.0059 5 6.9 +124TES B EAV=4.5 4 +124TE G 2283.62 6 0.0059 5E1+M2 0.00091 5 +124TE2 G KC=0.00033 21$LC=0.000040 25$MC=0.000008 5$NC=1.6E-6 10 +124TE3 G OC=1.7E-7 11 + diff --git a/HEN_HOUSE/spectra/lnhb/Sb-125.txt b/HEN_HOUSE/spectra/lnhb/Sb-125.txt index e038de209..268c8466a 100644 --- a/HEN_HOUSE/spectra/lnhb/Sb-125.txt +++ b/HEN_HOUSE/spectra/lnhb/Sb-125.txt @@ -1,112 +1,110 @@ -125TE 125SB B- DECAY (2.75855 Y) -125TE H TYP=Full$AUT=R.G.Helmer and E.Browne$CUT=10-NOV-2004$ -125TE2 H TYP=Full$AUT=R.G.Helmer$CUT=01-MAY-2004$ -125TE C Evaluation history: Type=Full;Author=R.G.Helmer and E.Browne;Cutoff date=10-NOV-2004 -125TE2C Type=Full;Author=R.G.Helmer;Cutoff date=01-MAY-2004 -125TE C References: 1990Ne01 -125TE T Auger electrons and X ray energies and emission intensities: -125TE T {U Energy (keV)} {U Intensity} {U Line} -125TE T -125TE T 27.202 21.0 9 XKA2 -125TE T 27.4726 39.1 15 XKA1 -125TE T -125TE T 30.9446 |] XKB3 -125TE T 30.996 |] 11.2 5 XKB1 -125TE T 31.236 |] XKB5II -125TE T -125TE T 31.7008 |] XKB2 -125TE T 31.774 |] 2.43 12 XKB4 -125TE T 31.812 |] XKO23 -125TE T -125TE T 3.3348-4.8228 6.56 21 XL (total) -125TE T 3.3348 0.135 6 XLL -125TE T 3.7595-3.7697 3.58 15 XLA -125TE T 3.6052 0.0508 24 XLC -125TE T 4.0299-4.3003 2.48 9 XLB -125TE T 4.4448-4.8228 0.311 13 XLG -125TE T -125TE T 21.804-22.989 |] KLL AUGER -125TE T 25.814-27.47 |] 10.5 6 KLX AUGER -125TE T 29.8-31.81 |] KXY AUGER -125TE T 2.3-4.8 70.6 9 L AUGER -125SB P 0.0 7/2+ 2.75855 Y 25 766.7 21 -125TE N 1.0 1.0 1 1.0 -125TE L 0 1/2+ STABLE -125TE L 35.490 3 3/2+ 1.48 NS 1 -125TE G 35.489 5 5.79 18M1+E2 14.3 4 -125TE2 G KC=12.1 4$LC=1.64 5$MC=0.329 10 -125TE L 144.776 1111/2- 57.40 D 15 -125TE B 621.0 2113.4 9 9.77 1U -125TES B EAV=215.5 8 -125TE G 109.276 150.0683 12M4 3.5E2 11 -125TE2 G KC=182 5$LC=135 4$MC=31 1 -125TE L 321.090 119/2- 0.673 NS 13 -125TE B 444.0 217.54 9 9.32 1 -125TES B EAV=134.5 8 -125TE G 176.314 2 6.82 7M1+E2 0.167 5 -125TE2 G KC=0.139 4$LC=0.0221 7$MC=0.00449 13 -125TE L 402.09 4 7/2+ -125TE L 443.554 6 3/2+ 19.1 PS 6 -125TE B 323.1 210.089 10 10.79 2 -125TES B EAV=93.3 7 -125TE G 408.065 100.182 2M1+E2 0.0152 5 -125TE2 G KC=0.0129 4$LC=0.00181 5$MC=0.00036 1 -125TE G 443.555 9 0.305 4M1+E2 0.0118 4 -125TE2 G KC=0.0100 3$LC=0.00142 4$MC=0.00029 1 -125TE L 463.365 3 5/2+ 13.2 PS 5 -125TE B 303.3 2140.3 4 8.04 -125TES B EAV=86.9 7 -125TE G 19.80 6 0.0202 5[M1] 11.3 3 -125TE2 G LC=9.1 3$MC=1.82 5 -125TE G 427.874 4 29.55 24M1+E2 0.0138 4 -125TE2 G KC=0.0119 4$LC=0.00154 5$MC=0.00031 1 -125TE G 463.365 4 10.48 9E2 0.0102 3 -125TE2 G KC=0.0086 3$LC=0.00124 4$MC=0.00025 1 -125TE L 525.227 9 7/2- -125TE B 241.5 211.251 12 9.23 -125TES B EAV=67.5 7 -125TE G 204.138 100.313 15M1+E2 0.128 4 -125TE2 G KC=0.104 3$LC=0.0189 6$MC=0.00386 11 -125TE G 380.452 8 1.520 15E2 0.0183 5 -125TE2 G KC=0.0154 5$LC=0.00233 7$MC=4.73E-4 15 -125TE L 538.60 5 (1/2)+ -125TE L 636.090 4 7/2+ 40 PS 20 -125TE B 130.6 2118.07 19 7.23 -125TES B EAV=34.7 6 -125TE G 110.895 120.00109 9[E1] 0.147 4 -125TE2 G KC=0.127 4$LC=0.0165 5$MC=0.00328 11 -125TE G 172.719 8 0.192 9M1(+E2) 0.151 5 -125TE2 G KC=0.129 4$LC=0.0168 5$MC=0.00337 11 -125TE G 314.95 110.0043 3(E1) 0.0083930 -125TE2 G KC=0.00726 22$LC=0.00089 3$MC=1.79E-4 5 -125TE G 600.597 2 17.76 18E2 0.0049815 -125TE2 G KC=0.00421 13$LC=0.00058 2$MC=1.16E-4 4 -125TE L 642.205 4 7/2+ -125TE B 124.5 215.82 5 7.66 -125TES B EAV=33.0 6 -125TE G 116.955 110.263 4E1 0.127 4 -125TE2 G KC=0.109 3$LC=0.0141 4$MC=0.00281 8 -125TE G 178.842 5 0.0343 15M1+E2 0.18 4 -125TE2 G KC=0.147 26$LC=0.026 11$MC=0.0054 21 -125TE G 198.654 110.0132 7[E2] 0.154 5 -125TE2 G KC=0.123 4$LC=0.0245 8$MC=0.00504 15 -125TE G 321.040 4 0.416 4E1 0.0079824 -125TE2 G KC=0.00691 21$LC=8.56E-4 30$MC=1.70E-4 5 -125TE G 497.37 120.0032 3[M2] 0.0318 10 -125TE2 G KC=0.0271 8$LC=0.00373 11$MC=0.00075 2 -125TE G 606.713 3 5.02 5E2 0.0048515 -125TE2 G KC=0.00415 13$LC=0.00056 2$MC=1.13E-4 4 -125TE L 652.9 5 (5/2)+ -125TE L 671.443 4 5/2+ 1.26 PS 6 -125TE B 95.3 2113.58 12 6.93 -125TES B EAV=24.9 6 -125TE G 208.077 5 0.246 8M1+E2 0.092 3 -125TE2 G KC=0.0791 24$LC=0.0102 3$MC=0.00205 6 -125TE G 227.891 100.131 3(M1+E2) 0.084 13 -125TE2 G KC=0.070 11$LC=0.011 4$MC=0.0023 6 -125TE G 635.950 3 11.32 10M1+E2 0.0052616 -125TE2 G KC=0.00455 14$LC=0.00057 2$MC=1.13E-4 5 -125TE G 671.441 6 1.783 16E2 0.0037311 -125TE2 G KC=0.00319 10$LC=0.00043 1$MC=8.6E-5 2 -125TE L 728.8 5 3/2+ - +125TE 125SB B- DECAY (2.75855 Y) +125TE H TYP=FUL$AUT=R.G.HELMER, E.BROWNE$CUT=10-NOV-2004$ +125TE2 H TYP=FUL$AUT=R.G.HELMER$CUT=01-MAY-2004$ +125TE C References:1990Ne01 +125TE T Auger electrons and X ray energies and emission intensities: +125TE T {U Energy (keV)} {U Intensity} {U Line} +125TE T +125TE T 27.202 21.0 9 XKA2 +125TE T 27.4726 39.1 15 XKA1 +125TE T +125TE T 30.9446 |] XKB3 +125TE T 30.996 |] 11.2 5 XKB1 +125TE T 31.236 |] XKB5II +125TE T +125TE T 31.7008 |] XKB2 +125TE T 31.774 |] 2.43 12 XKB4 +125TE T 31.812 |] XKO23 +125TE T +125TE T 3.3348-4.8228 6.56 21 XL (total) +125TE T 3.3348 0.135 6 XLL +125TE T 3.7595-3.7697 3.58 15 XLA +125TE T 3.6052 0.0508 24 XLC +125TE T 4.0299-4.3003 2.48 9 XLB +125TE T 4.4448-4.8228 0.311 13 XLG +125TE T +125TE T 21.804-22.989 |] KLL AUGER +125TE T 25.814-27.47 |] 10.5 6 KLX AUGER +125TE T 29.8-31.81 |] KXY AUGER +125TE T 2.3-4.8 70.6 9 L AUGER +125SB P 0.0 7/2+ 2.75855 Y 25 766.7 21 +125TE N 1.0 1.0 1 1.0 +125TE L 0 1/2+ STABLE +125TE L 35.490 3 3/2+ 1.48 NS 1 +125TE G 35.489 5 5.79 18M1+E2 14.3 4 +125TE2 G KC=12.1 4$LC=1.64 5$MC=0.329 10 +125TE L 144.776 1111/2- 57.40 D 15 +125TE B 621.0 2113.4 9 9.77 1U +125TES B EAV=215.5 8 +125TE G 109.276 150.0683 12M4 3.5E2 11 +125TE2 G KC=182 5$LC=135 4$MC=31 1$NC=6.6 2 +125TE L 321.090 119/2- 0.673 NS 13 +125TE B 444.0 217.54 9 9.32 1 +125TES B EAV=134.5 8 +125TE G 176.314 2 6.82 7M1+E2 0.167 5 +125TE2 G KC=0.139 4$LC=0.0221 7$MC=0.00449 13$NC=0.00093 3 +125TE L 402.09 4 7/2+ +125TE L 443.554 6 3/2+ 19.1 PS 6 +125TE B 323.1 210.089 10 10.79 2 +125TES B EAV=93.3 7 +125TE G 408.065 100.182 2M1+E2 0.0152 5 +125TE2 G KC=0.0129 4$LC=0.00181 5$MC=0.00036 1 +125TE G 443.555 9 0.305 4M1+E2 0.0118 4 +125TE2 G KC=0.0100 3$LC=0.00142 4$MC=0.00029 1 +125TE L 463.365 3 5/2+ 13.2 PS 5 +125TE B 303.3 2140.3 4 8.04 +125TES B EAV=86.9 7 +125TE G 19.80 6 0.0202 5[M1] 11.3 3 +125TE2 G LC=9.1 3$MC=1.82 5 +125TE G 427.874 4 29.55 24M1+E2 0.0138 4 +125TE2 G KC=0.0119 4$LC=0.00154 5$MC=0.00031 1 +125TE G 463.365 4 10.48 9E2 0.0102 3 +125TE2 G KC=0.0086 3$LC=0.00124 4$MC=0.00025 1 +125TE L 525.227 9 7/2- +125TE B 241.5 211.251 12 9.23 +125TES B EAV=67.5 7 +125TE G 204.138 100.313 15M1+E2 0.128 4 +125TE2 G KC=0.104 3$LC=0.0189 6$MC=0.00386 11$NC=0.00079 2 +125TE G 380.452 8 1.520 15E2 0.0183 5 +125TE2 G KC=0.0154 5$LC=0.00233 7$MC=0.000473 15 +125TE L 538.60 5 (1/2)+ +125TE L 636.090 4 7/2+ 40 PS 20 +125TE B 130.6 2118.07 19 7.23 +125TES B EAV=34.7 6 +125TE G 110.895 120.00109 9[E1] 0.147 4 +125TE2 G KC=0.127 4$LC=0.0165 5$MC=0.00328 11 +125TE G 172.719 8 0.192 9M1(+E2) 0.151 5 +125TE2 G KC=0.129 4$LC=0.0168 5$MC=0.00337 11$NC=0.00071 2 +125TE G 314.95 110.0043 3(E1) 0.0083930 +125TE2 G KC=0.00726 22$LC=0.00089 3$MC=0.000179 5 +125TE G 600.597 2 17.76 18E2 0.0049815 +125TE2 G KC=0.00421 13$LC=0.00058 2$MC=0.000116 4 +125TE L 642.205 4 7/2+ +125TE B 124.5 215.82 5 7.66 +125TES B EAV=33.0 6 +125TE G 116.955 110.263 4E1 0.127 4 +125TE2 G KC=0.109 3$LC=0.0141 4$MC=0.00281 8$NC=0.00059 2 +125TE G 178.842 5 0.0343 15M1+E2 0.18 4 +125TE2 G KC=0.147 26$LC=0.026 11$MC=0.0054 21$NC=0.0011 4 +125TE G 198.654 110.0132 7[E2] 0.154 5 +125TE2 G KC=0.123 4$LC=0.0245 8$MC=0.00504 15$NC=0.00110 4 +125TE G 321.040 4 0.416 4E1 0.0079824 +125TE2 G KC=0.00691 21$LC=0.000856 30$MC=0.000170 5 +125TE G 497.37 120.0032 3[M2] 0.0318 10 +125TE2 G KC=0.0271 8$LC=0.00373 11$MC=0.00075 2 +125TE G 606.713 3 5.02 5E2 0.0048515 +125TE2 G KC=0.00415 13$LC=0.00056 2$MC=0.000113 4 +125TE L 652.9 5 (5/2)+ +125TE L 671.443 4 5/2+ 1.26 PS 6 +125TE B 95.3 2113.58 12 6.93 +125TES B EAV=24.9 6 +125TE G 208.077 5 0.246 8M1+E2 0.092 3 +125TE2 G KC=0.0791 24$LC=0.0102 3$MC=0.00205 6$NC=0.00043 2 +125TE G 227.891 100.131 3(M1+E2) 0.084 13 +125TE2 G KC=0.070 11$LC=0.011 4$MC=0.0023 6$NC=0.00047 15 +125TE G 635.950 3 11.32 10M1+E2 0.0052616 +125TE2 G KC=0.00455 14$LC=0.00057 2$MC=0.000113 5 +125TE G 671.441 6 1.783 16E2 0.0037311 +125TE2 G KC=0.00319 10$LC=0.00043 1$MC=0.000086 2 +125TE L 728.8 5 3/2+ + diff --git a/HEN_HOUSE/spectra/lnhb/Sb-127.txt b/HEN_HOUSE/spectra/lnhb/Sb-127.txt index e90e67878..052fe9fe2 100644 --- a/HEN_HOUSE/spectra/lnhb/Sb-127.txt +++ b/HEN_HOUSE/spectra/lnhb/Sb-127.txt @@ -1,159 +1,191 @@ -127TE 127SB B- DECAY (3.85 D) -127TE H TYP=Full$AUT=A.L. Nichols$CUT=15-MAR-2012$ -127TE C Evaluation history: Type=Full;Author=A.L. Nichols;Cutoff date=15-MAR-2012 -127TE C References: 1939Ab02, 1946Gr06, 1950Sl17, 1957Bo96, 1962Dr01, 1962Uh01, -127TE2C 1967Ha27, 1967Ra13, 1967Ta05, 1972Kr15, 1972Pa13, 1974Sa03, 1977La19, -127TE3C 1977Kr13, 1985De04, 1996Sc06, 1998ScZm, 1999ScZX, 2002Ba25, 2002Ra45, -127TE4C 2003Au03, 2003De44, 2005Ho15, 2008Ki07, 2011Ha31, 2012Au06 -127TE T Auger electrons and X ray energies and emission intensities: -127TE T {U Energy (keV)} {U Intensity} {U Line} -127TE T -127TE T 27.202 1.11 4 XKA2 -127TE T 27.4726 2.06 7 XKA1 -127TE T -127TE T 30.9446 |] XKB3 -127TE T 30.996 |] 0.591 21 XKB1 -127TE T 31.232 |] XKB5II -127TE T 31.242 |] XKB5I -127TE T -127TE T 31.7008 |] XKB2 -127TE T 31.774 |] 0.128 6 XKB4 -127TE T 31.182 |] XKO23 -127TE T -127TE T 3.335-4.829 0.462 23 XL (total) -127TE T 3.335 0.0089 4 XLL -127TE T 3.759-3.77 0.235 10 XLA -127TE T 3.605 0.00355 19 XLC -127TE T 4.03-4.302 0.184 7 XLB -127TE T 4.572-4.829 0.0248 10 XLG -127TE T -127TE T 21.804-22.989 |] KLL AUGER -127TE T 25.814-27.47 |] 0.556 26 KLX AUGER -127TE T 29.8-31.81 |] KXY AUGER -127TE T 2.29-3.72 4.90 14 L AUGER -127SB P 0.0 7/2+ 3.85 D 7 1582 5 -127TE N 1.0 1.0 1 1.0 -127TE L 0 3/2+ 9.35 H 10 -127TE L 61.161 191/2+ -127TE G 61.16 2 1.140 14M1+E2 0.49 6 4.2 3 -127TE2 G KC=2.93 12$LC=0.99 14$MC=0.21 3 -127TE L 88.23 7 11/2- 106.1 D 7 -127TE B 1494 5 2.0 5 10.21 1U -127TES B EAV=562.4 21 -127TE L 340.87 6 (9/2)- 0.41 NS 2 -127TE B 1241 5 2.4 3 8.98 1 -127TES B EAV=446.9 22 -127TE G 252.64 9 8.28 14M1+E2 -2.1 5 0.0652 17 -127TE2 G KC=0.0541 12$LC=0.0090 4$MC=0.00182 8 -127TE L 473.26 4 5/2+ -127TE B 1109 5 22.6 8 7.826 -127TES B EAV=391.2 21 -127TE G 412.10 5 3.43 18E2 0.0143120 -127TE2 G KC=0.01210 17$LC=1775E-6 25$MC=3.57E-4 5 -127TE G 473.26 4 24.8 7M1+E2 -0.2 1 0.0107216 -127TE2 G KC=0.00928 14$LC=1159E-6 17$MC=2.31E-4 4 -127TE L 501.928 103/2+ -127TE G 440.77 2 0.7 3M1+E2 0.5 3 0.0126 3 -127TE2 G KC=0.0109 3$LC=1395E-6 22$MC=2.78E-4 5 -127TE G 501.93 1 0.64 11M1+E2 0.34 8 0.0091914 -127TE2 G KC=0.00795 13$LC=9.97E-4 14$MC=1.99E-4 3 -127TE L 631.40 6 7/2- -127TE B 951 5 4.00 21 8.33 -127TES B EAV=326.2 21 -127TE G 290.5 1 1.84 7M1+E2 0.40 3 0.0379 6 -127TE2 G KC=0.0326 5$LC=0.00430 7$MC=8.59E-4 14 -127TE G 543.2 1 2.62 11E2 0.00648 9 -127TE2 G KC=0.00553 8$LC=7.61E-4 11$MC=1525E-7 22 -127TE L 685.09 7 7/2+ -127TE B 897 5 34.4 4 7.304 -127TES B EAV=304.5 20 -127TE G 685.09 7 35.4 4E2 0.00352 5 -127TE2 G KC=0.00303 5$LC=3.99E-4 6$MC=7.97E-5 12 -127TE L 762.64 5 3/2+ -127TE G 762.7 1 0.07 4M1+E2 1.0 5 0.0030622 -127TE2 G KC=0.00265 20$LC=3.32E-4 19$MC=6.6E-5 4 -127TE L 782.62 3 5/2+ -127TE B 799 5 17.2 3 7.425 -127TES B EAV=265.8 20 -127TE G 280.7 1 0.53 4M1+E2 -0.09 2 0.0407 6 -127TE2 G KC=0.0351 5$LC=0.00445 7$MC=8.88E-4 13 -127TE G 309.4 1 0.076 13M1+E2 0.10 3 0.0316 5 -127TE2 G KC=0.0273 4$LC=0.00345 5$MC=6.87E-4 10 -127TE G 721.5 1 1.77 7E2 0.00309 5 -127TE2 G KC=0.00266 4$LC=3.48E-4 5$MC=6.95E-5 10 -127TE G 782.6 1 14.7 3M1+E2 0.21 1 0.00319 5 -127TE2 G KC=0.00277 4$LC=3.39E-4 5$MC=6.73E-5 10 -127TE L 786.13 6 7/2- -127TE B 796 5 7.72 21 7.766 -127TES B EAV=264.4 20 -127TE G 154.7 1 0.12 3M1+E2 0.3 2 0.214 20 -127TE2 G KC=0.182 14$LC=0.026 5$MC=0.0052 11 -127TE G 445.3 1 4.18 11M1+E2 -1.0 5 0.0120 4 -127TE2 G KC=0.0102 4$LC=1369E-6 23$MC=2.74E-4 5 -127TE G 697.9 1 3.36 18E2 0.00336 5 -127TE2 G KC=0.00289 4$LC=3.80E-4 6$MC=7.59E-5 11 -127TE L 924.02 187/2+ -127TE B 658 5 1.27 25 8.26 -127TES B EAV=211.5 19 -127TE G 292.6 2 0.28 14E1+M2 0.12 13 0.012 7 -127TE2 G KC=0.010 6$LC=0.00136 16$MC=0.00027 18 -127TE G 450.8 2 0.21 7M1+E2 0.7 5 0.0118 4 -127TE2 G KC=0.0101 4$LC=1318E-6 20$MC=2.63E-4 5 -127TE G 583.2 2 0.32 18E1 0.00187 3 -127TE2 G KC=1622E-6 23$LC=1.96E-4 3$MC=3.89E-5 6 -127TE G 924.0 2 0.460 25E2 1725E-625 -127TE2 G KC=1491E-6 21$LC=1.89E-4 3$MC=3.76E-5 6 -127TE L 1077.13 17(5/2,7/2,9/2)+ -127TE B 505 5 5.17 14 7.251 -127TES B EAV=155.3 18 -127TE G 392.0 2 0.92 7M1+E2 0.15 2 0.0172225 -127TE2 G KC=0.01490 21$LC=0.00187 3$MC=3.72E-4 6 -127TE G 603.9 2 4.21 11M1+E2 0.14 8 0.00592 9 -127TE2 G KC=0.00513 8$LC=6.34E-4 10$MC=1261E-7 18 -127TE L 1140.20 7 5/2+ -127TE B 442 5 1.35 21 7.64 -127TES B EAV=133.2 18 -127TE G 455.1 1 0.11 7M1+E2 1.0 5 0.0113 4 -127TE2 G KC=0.0097 4$LC=1287E-6 19$MC=2.58E-4 4 -127TE G 638.3 1 0.35 4M1+E2 -0.42 3 0.00506 8 -127TE2 G KC=0.00438 7$LC=5.44E-4 8$MC=1083E-7 16 -127TE G 666.9 1 0.53 18M1+E2 1.0 5 0.0042 3 -127TE2 G KC=0.0037 3$LC=4.64E-4 23$MC=9.3E-5 5 -127TE G 1140.2 1 0.35 7M1+E2 -0.14 12 1358E-623 -127TE2 G KC=1179E-6 20$LC=1427E-7 23$MC=2.83E-5 5 -127TE L 1154.70 9 5/2+ -127TE B 427 5 0.85 25 7.79 -127TES B EAV=128.2 18 -127TE G 652.8 1 0.28 4M1+E2 0.24 7 0.00488 8 -127TE2 G KC=0.00423 7$LC=5.22E-4 8$MC=1038E-7 16 -127TE G 681.4 1 0.53 25M1+E2 1.0 5 0.0040 3 -127TE2 G KC=0.00347 25$LC=4.40E-4 22$MC=8.8E-5 5 -127TE G 1153.99 9 0.039 21M1+E2 -127TE L 1206.3 7 3/2,5/2+ -127TE B 376 5 0.10 4 8.53 2 -127TES B EAV=110.7 17 -127TE G 423.7 7 0.10 4M1+E2 1.0 5 0.0137 4 -127TE2 G KC=0.0117 4$LC=0.00158 4$MC=3.16E-4 9 -127TE L 1289.79 8 5/2+ -127TE B 292 5 0.61 4 7.39 -127TES B EAV=83.4 16 -127TE G 816.5 1 0.27 3M1+E2 1.0 5 0.0026019 -127TE2 G KC=0.00225 17$LC=2.82E-4 17$MC=5.6E-5 4 -127TE G 1288.90 8 0.34 3M1+E2 0.02 8 1055E-615 -127TE2 G KC=9.01E-4 13$LC=1087E-7 16$MC=2.16E-5 3 -127TE L 1309.25 7 3/2,5/2+ -127TE B 273 5 0.06 2 8.3 2 -127TES B EAV=77.2 16 -127TE G 624.2 1 0.064 21M1+E2 1.0 5 0.0050 4 -127TE2 G KC=0.0043 3$LC=5.50E-4 24$MC=1.10E-4 5 -127TE L 1323.4 8 + -127TE B 259 5 0.12 2 7.93 -127TES B EAV=72.8 16 -127TE G 821.5 8 0.117 22 -127TE L 1378.58 7 5/2+ -127TE B 203 5 0.18 4 7.42 -127TES B EAV=55.9 15 -127TE G 747.2 1 0.11 4E1 1093E-616 -127TE2 G KC=9.51E-4 14$LC=1142E-7 16$MC=2.26E-5 4 -127TE G 1378.6 1 0.07 4M1+E2 - +127TE 127SB B- DECAY (3.85 D) +127TE H TYP=FUL$AUT=A.L.NICHOLS$CUT=15-MAR-2012$ +127TE C References:1939Ab02, 1946Gr06, 1950Sl17, 1957Bo96, 1962Dr01, 1962Uh01, +127TE2C 1967Ha27, 1967Ra13, 1967Ta05, 1972Kr15, 1972Pa13, 1974Sa03, 1977La19, +127TE3C 1977Kr13, 1985De04, 1996Sc06, 1998ScZm, 1999ScZX, 2002Ba25, 2002Ra45, +127TE4C 2003Au03, 2003De44, 2005Ho15, 2008Ki07, 2011Ha31, 2012Au06 +127TE T Auger electrons and X ray energies and emission intensities: +127TE T {U Energy (keV)} {U Intensity} {U Line} +127TE T +127TE T 27.202 1.11 4 XKA2 +127TE T 27.4726 2.06 7 XKA1 +127TE T +127TE T 30.9446 |] XKB3 +127TE T 30.996 |] 0.591 21 XKB1 +127TE T 31.232 |] XKB5II +127TE T 31.242 |] XKB5I +127TE T +127TE T 31.7008 |] XKB2 +127TE T 31.774 |] 0.128 6 XKB4 +127TE T 31.182 |] XKO23 +127TE T +127TE T 3.335-4.829 0.462 23 XL (total) +127TE T 3.335 0.0089 4 XLL +127TE T 3.759-3.77 0.235 10 XLA +127TE T 3.605 0.00355 19 XLC +127TE T 4.03-4.302 0.184 7 XLB +127TE T 4.572-4.829 0.0248 10 XLG +127TE T +127TE T 21.804-22.989 |] KLL AUGER +127TE T 25.814-27.47 |] 0.556 26 KLX AUGER +127TE T 29.8-31.81 |] KXY AUGER +127TE T 2.29-3.72 4.90 14 L AUGER +127SB P 0.0 7/2+ 3.85 D 7 1582 5 +127TE N 1.0 1.0 1 1.0 +127TE L 0 3/2+ 9.35 H 10 +127TE L 61.161 191/2+ +127TE G 61.16 2 1.140 14M1+E2 0.49 6 4.2 3 +127TE2 G KC=2.93 12$LC=0.99 14$MC=0.21 3$NC=0.039 6 +127TE3 G OC=0.0034 4 +127TE L 88.23 7 11/2- 106.1 D 7 +127TE B 1494 5 2.0 5 10.21 1U +127TES B EAV=562.4 21 +127TE L 340.87 6 (9/2)- 0.41 NS 2 +127TE B 1241 5 2.4 3 8.98 1 +127TES B EAV=446.9 22 +127TE G 252.64 9 8.28 14M1+E2 -2.1 5 0.0652 17 +127TE2 G KC=0.0541 12$LC=0.0090 4$MC=0.00182 8$NC=0.000352 15 +127TE3 G OC=3.46E-5 12 +127TE L 473.26 4 5/2+ +127TE B 1109 5 22.6 8 7.826 +127TES B EAV=391.2 21 +127TE G 412.10 5 3.43 18E2 0.0143120 +127TE2 G KC=0.01210 17$LC=0.001775 25$MC=0.000357 5$NC=6.96E-5 10 +127TE3 G OC=7.1E-6 1 +127TE G 473.26 4 24.8 7M1+E2 -0.2 1 0.0107216 +127TE2 G KC=0.00928 14$LC=0.001159 17$MC=0.000231 4$NC=4.57E-5 7 +127TE3 G OC=4.97E-6 8 +127TE L 501.928 103/2+ +127TE G 440.77 2 0.7 3M1+E2 0.5 3 0.0126 3 +127TE2 G KC=0.0109 3$LC=0.001395 22$MC=0.000278 5$NC=5.49E-5 9 +127TE3 G OC=5.92E-6 9 +127TE G 501.93 1 0.64 11M1+E2 0.34 8 0.0091914 +127TE2 G KC=0.00795 13$LC=0.000997 14$MC=0.000199 3$NC=3.93E-5 6 +127TE3 G OC=4.27E-6 7 +127TE L 631.40 6 7/2- +127TE B 951 5 4.00 21 8.33 +127TES B EAV=326.2 21 +127TE G 290.5 1 1.84 7M1+E2 0.40 3 0.0379 6 +127TE2 G KC=0.0326 5$LC=0.00430 7$MC=0.000859 14$NC=0.000169 3 +127TE3 G OC=1.81E-5 3 +127TE G 543.2 1 2.62 11E2 0.00648 9 +127TE2 G KC=0.00553 8$LC=0.000761 11$MC=1.525E-4 22$NC=2.99E-5 5 +127TE3 G OC=3.12E-6 5 +127TE L 685.09 7 7/2+ +127TE B 897 5 34.4 4 7.304 +127TES B EAV=304.5 20 +127TE G 685.09 7 35.4 4E2 0.00352 5 +127TE2 G KC=0.00303 5$LC=0.000399 6$MC=7.97E-5 12$NC=1.566E-5 22 +127TE3 G OC=1.658E-6 24 +127TE L 762.64 5 3/2+ +127TE G 762.7 1 0.07 4M1+E2 1.0 5 0.0030622 +127TE2 G KC=0.00265 20$LC=0.000332 19$MC=0.000066 4$NC=1.31E-5 8 +127TE3 G OC=1.41E-6 10 +127TE L 782.62 3 5/2+ +127TE B 799 5 17.2 3 7.425 +127TES B EAV=265.8 20 +127TE G 280.7 1 0.53 4M1+E2 -0.09 2 0.0407 6 +127TE2 G KC=0.0351 5$LC=0.00445 7$MC=0.000888 13$NC=1.757E-4 25 +127TE3 G OC=1.91E-5 3 +127TE G 309.4 1 0.076 13M1+E2 0.10 3 0.0316 5 +127TE2 G KC=0.0273 4$LC=0.00345 5$MC=0.000687 10$NC=0.000136 2 +127TE3 G OC=1.479E-5 21 +127TE G 721.5 1 1.77 7E2 0.00309 5 +127TE2 G KC=0.00266 4$LC=0.000348 5$MC=6.95E-5 10$NC=1.367E-5 20 +127TE3 G OC=1.452E-6 21 +127TE G 782.6 1 14.7 3M1+E2 0.21 1 0.00319 5 +127TE2 G KC=0.00277 4$LC=0.000339 5$MC=6.73E-5 10$NC=1.334E-5 19 +127TE3 G OC=1.459E-6 21 +127TE L 786.13 6 7/2- +127TE B 796 5 7.72 21 7.766 +127TES B EAV=264.4 20 +127TE G 154.7 1 0.12 3M1+E2 0.3 2 0.214 20 +127TE2 G KC=0.182 14$LC=0.026 5$MC=0.0052 11$NC=0.00102 20 +127TE3 G OC=0.000107 16 +127TE G 445.3 1 4.18 11M1+E2 -1.0 5 0.0120 4 +127TE2 G KC=0.0102 4$LC=0.001369 23$MC=0.000274 5$NC=5.38E-5 9 +127TE3 G OC=5.70E-6 11 +127TE G 697.9 1 3.36 18E2 0.00336 5 +127TE2 G KC=0.00289 4$LC=0.000380 6$MC=7.59E-5 11$NC=1.491E-5 21 +127TE3 G OC=1.581E-6 23 +127TE L 924.02 187/2+ +127TE B 658 5 1.27 25 8.26 +127TES B EAV=211.5 19 +127TE G 292.6 2 0.28 14E1+M2 0.12 13 0.012 7 +127TE2 G KC=0.010 6$LC=0.00136 16$MC=0.00027 18$NC=0.00005 4 +127TE3 G OC=0.000006 4 +127TE G 450.8 2 0.21 7M1+E2 0.7 5 0.0118 4 +127TE2 G KC=0.0101 4$LC=0.001318 20$MC=0.000263 5$NC=5.19E-5 8 +127TE3 G OC=5.55E-6 11 +127TE G 583.2 2 0.32 18E1 0.00187 3 +127TE2 G KC=0.001622 23$LC=0.000196 3$MC=3.89E-5 6$NC=7.68E-6 11 +127TE3 G OC=8.31E-7 12 +127TE G 924.0 2 0.460 25E2 1725E-625 +127TE2 G KC=0.001491 21$LC=0.000189 3$MC=3.76E-5 6$NC=7.41E-6 11 +127TE3 G OC=7.96E-7 12 +127TE L 1077.13 17(5/2,7/2,9/2)+ +127TE B 505 5 5.17 14 7.251 +127TES B EAV=155.3 18 +127TE G 392.0 2 0.92 7M1+E2 0.15 2 0.0172225 +127TE2 G KC=0.01490 21$LC=0.00187 3$MC=0.000372 6$NC=7.37E-5 11 +127TE3 G OC=8.03E-6 12 +127TE G 603.9 2 4.21 11M1+E2 0.14 8 0.00592 9 +127TE2 G KC=0.00513 8$LC=0.000634 10$MC=1.261E-4 18$NC=2.50E-5 4 +127TE L 1140.20 7 5/2+ +127TE B 442 5 1.35 21 7.64 +127TES B EAV=133.2 18 +127TE G 455.1 1 0.11 7M1+E2 1.0 5 0.0113 4 +127TE2 G KC=0.0097 4$LC=0.001287 19$MC=0.000258 4$NC=5.06E-5 8 +127TE3 G OC=5.37E-6 11 +127TE G 638.3 1 0.35 4M1+E2 -0.42 3 0.00506 8 +127TE2 G KC=0.00438 7$LC=0.000544 8$MC=1.083E-4 16$NC=2.14E-5 3 +127TE3 G OC=2.33E-6 4 +127TE G 666.9 1 0.53 18M1+E2 1.0 5 0.0042 3 +127TE2 G KC=0.0037 3$LC=0.000464 23$MC=0.000093 5$NC=1.83E-5 9 +127TE3 G OC=1.97E-6 12 +127TE G 1140.2 1 0.35 7M1+E2 -0.14 12 1358E-623 +127TE2 G KC=0.001179 20$LC=1.427E-4 23$MC=2.83E-5 5$NC=5.61E-6 10 +127TE3 G OC=6.16E-7 11$IPC=1.501E-6 23 +127TE L 1154.70 9 5/2+ +127TE B 427 5 0.85 25 7.79 +127TES B EAV=128.2 18 +127TE G 652.8 1 0.28 4M1+E2 0.24 7 0.00488 8 +127TE2 G KC=0.00423 7$LC=0.000522 8$MC=1.038E-4 16$NC=2.06E-5 3 +127TE3 G OC=2.25E-6 4 +127TE G 681.4 1 0.53 25M1+E2 1.0 5 0.0040 3 +127TE2 G KC=0.00347 25$LC=0.000440 22$MC=0.000088 5$NC=1.73E-5 9 +127TE3 G OC=1.86E-6 12 +127TE G 1153.99 9 0.039 21M1+E2 +127TE L 1206.3 7 3/2,5/2+ +127TE B 376 5 0.10 4 8.53 2 +127TES B EAV=110.7 17 +127TE G 423.7 7 0.10 4M1+E2 1.0 5 0.0137 4 +127TE2 G KC=0.0117 4$LC=0.00158 4$MC=0.000316 9$NC=6.20E-5 14 +127TE3 G OC=6.55E-6 10 +127TE L 1289.79 8 5/2+ +127TE B 292 5 0.61 4 7.39 +127TES B EAV=83.4 16 +127TE G 816.5 1 0.27 3M1+E2 1.0 5 0.0026019 +127TE2 G KC=0.00225 17$LC=0.000282 17$MC=0.000056 4$NC=1.11E-5 7 +127TE3 G OC=1.20E-6 9 +127TE G 1288.90 8 0.34 3M1+E2 0.02 8 1055E-615 +127TE2 G KC=0.000901 13$LC=1.087E-4 16$MC=2.16E-5 3$NC=4.28E-6 6 +127TE3 G OC=4.69E-7 7$IPC=1.88E-5 3 +127TE L 1309.25 7 3/2,5/2+ +127TE B 273 5 0.06 2 8.3 2 +127TES B EAV=77.2 16 +127TE G 624.2 1 0.064 21M1+E2 1.0 5 0.0050 4 +127TE2 G KC=0.0043 3$LC=0.000550 24$MC=0.000110 5$NC=2.16E-5 10 +127TE3 G OC=2.32E-6 13 +127TE L 1323.4 8 +127TE B 259 5 0.12 2 7.93 +127TES B EAV=72.8 16 +127TE G 821.5 8 0.117 22 +127TE L 1378.58 7 5/2+ +127TE B 203 5 0.18 4 7.42 +127TES B EAV=55.9 15 +127TE G 747.2 1 0.11 4E1 1093E-616 +127TE2 G KC=0.000951 14$LC=1.142E-4 16$MC=2.26E-5 4$NC=4.47E-6 7 +127TE3 G OC=4.85E-7 7 +127TE G 1378.6 1 0.07 4M1+E2 + diff --git a/HEN_HOUSE/spectra/lnhb/Sc-44.txt b/HEN_HOUSE/spectra/lnhb/Sc-44.txt index a7f186c3b..af0bdc4cb 100644 --- a/HEN_HOUSE/spectra/lnhb/Sc-44.txt +++ b/HEN_HOUSE/spectra/lnhb/Sc-44.txt @@ -1,39 +1,39 @@ - 44CA 44SC EC DECAY (3.97 H) - 44CA T Auger electrons and X ray energies and emission intensities: - 44CA T {U Energy (keV)} {U Intensity} {U Line} - 44CA T - 44CA T 3.68813 0.255 7 XKA2 - 44CA T 3.69172 0.504 13 XKA1 - 44CA T - 44CA T 4.0128 |] 0.098 3 XKB1 - 44CA T 4.0325 |] XKB5II - 44CA T - 44CA T - 44CA T 0.35-0.412 0.019 4 XL (total) - 44CA T 0.35 XLL - 44CA T -0.412 XLG - 44CA T - 44CA T 3.123-3.307 |] KLL AUGER - 44CA T 3.543-3.666 |] 4.21 3 KLX AUGER - 44CA T 3.951-3.987 |] KXY AUGER - 44CA T 0.044-0.387 8.71 5 L AUGER - 44SC P 0.0 2+ 3.97 H 4 3653.3 19 - 44CA N 1.0 1.0 1 1.0 - 44CA L 0 0+ STABLE - 44CA L 1157.039 152+ 2.61 PS 14 - 44CA E 94.27 54.70 55.3 - 44CA2 E EAV=632.0 9$CK=0.8970 19$CL=0.0897 16$CM=0.0133 7 - 44CA G 1157.020 1599.875 3E2 6.48E-519 - 44CA2 G KC=5.90E-5 18$LC=4.99E-6 15$MC=8.1E-7 2 - 44CA L 2656.530 242+ 30 FS 3 - 44CA E 1.02 25.2 - 44CA2 E CK=0.8966 19$CL=0.0900 16$CM=0.0134 7 - 44CA G 1499.460 200.908 15M1+E2 0.137 17 3.19E-510 - 44CA2 G KC=2.9E-5 1$LC=2.43E-6 7$MC=4.7E-7 2 - 44CA G 2656.48 7 0.112 3[E2] - 44CA L 3301.46 6 2+ 35 FS 18 - 44CA E 0.00440 116.6 - 44CA2 E CK=0.8954 20$CL=0.0911 16$CM=0.0135 7 - 44CA G 2144.33 100.0036 7[M1+E2+] - 44CA G 3301.35 6 0.0017 2[E2] - + 44CA 44SC EC DECAY (3.97 H) + 44CA T Auger electrons and X ray energies and emission intensities: + 44CA T {U Energy (keV)} {U Intensity} {U Line} + 44CA T + 44CA T 3.68813 0.255 7 XKA2 + 44CA T 3.69172 0.504 13 XKA1 + 44CA T + 44CA T 4.0128 |] 0.098 3 XKB1 + 44CA T 4.0325 |] XKB5II + 44CA T + 44CA T + 44CA T 0.35-0.412 0.019 4 XL (total) + 44CA T 0.35 XLL + 44CA T -0.412 XLG + 44CA T + 44CA T 3.123-3.307 |] KLL AUGER + 44CA T 3.543-3.666 |] 4.21 3 KLX AUGER + 44CA T 3.951-3.987 |] KXY AUGER + 44CA T 0.044-0.387 8.71 5 L AUGER + 44SC P 0.0 2+ 3.97 H 4 3653.3 19 + 44CA N 1.0 1.0 1 1.0 + 44CA L 0 0+ STABLE + 44CA L 1157.039 152+ 2.61 PS 14 + 44CA E 94.27 54.70 55.3 + 44CA2 E EAV=632.0 9$CK=0.04260 9$CL=0.00426 8$CM=0.000632 33 + 44CA G 1157.020 1599.875 3E2 6.48E-519 + 44CA2 G KC=5.90E-5 18$LC=4.99E-6 15$MC=8.1E-7 2 + 44CA L 2656.530 242+ 30 FS 3 + 44CA E 1.02 25.2 + 44CA2 E CK=0.8966 19$CL=0.0900 16$CM=0.0134 7 + 44CA G 1499.460 200.908 15M1+E2 0.137 17 3.19E-510 + 44CA2 G KC=0.000029 1$LC=2.43E-6 7$MC=4.7E-7 2 + 44CA G 2656.48 7 0.112 3[E2] + 44CA L 3301.46 6 2+ 35 FS 18 + 44CA E 0.00440 116.6 + 44CA2 E CK=0.8954 20$CL=0.0911 16$CM=0.0135 7 + 44CA G 2144.33 100.0036 7[M1+E2+E0] + 44CA G 3301.35 6 0.0017 2[E2] + diff --git a/HEN_HOUSE/spectra/lnhb/Sc-46.txt b/HEN_HOUSE/spectra/lnhb/Sc-46.txt index b41dbdfa5..cc1fe0bb8 100644 --- a/HEN_HOUSE/spectra/lnhb/Sc-46.txt +++ b/HEN_HOUSE/spectra/lnhb/Sc-46.txt @@ -1,47 +1,46 @@ - 46TI 46SC B- DECAY (83.787 D) - 46TI H TYP=UPD$AUT=N.K. Kuzmenko$CUT=23-JUN-2014$ - 46TI2 H TYP=FUL$AUT=R.G. Helmer$CUT=01-FEB-2001$ - 46TI C Evaluation history: Type=UPD;Author=N.K. Kuzmenko;Cutoff date=23-JUN-2014 - 46TI2C Type=FUL;Author=R.G. Helmer;Cutoff date=01-FEB-2001 - 46TI C References: 1940Wa01, 1950So57, 1950Mo62, 1954Ke04, 1956Wo09, 1956Sc87, - 46TI2C 1957Ge07, 1957Wr37, 1963Ho17, 1965An07, 1967Wa29, 1972BaWG, 1974Cr05, - 46TI3C 1977MeZP, 1979Sc31, 1980Ho17, 1980Ol03, 1980Fu07, 1980RuZY, 1982HoZJ, - 46TI4C 1982RuZV, 1983Wa26, 1986Al19, 1992Un01, 1998Si17, 2000He14, 2000Wu08, - 46TI5C 2002Ba85, 2004BeZR, 2008Ki07, 2012Fi12, 2012Wa38, 2014Un01 - 46TI T Auger electrons and X ray energies and emission intensities: - 46TI T {U Energy (keV)} {U Intensity} {U Line} - 46TI T - 46TI T 4.50491 0.00155 4 XKA2 - 46TI T 4.5109 0.00306 8 XKA1 - 46TI T - 46TI T 4.93186 |] 0.00061218 XKB1 - 46TI T 4.9623 |] XKB5II - 46TI T - 46TI T - 46TI T 0.3967-0.5614 0.00012 3 XL (total) - 46TI T 0.3967 XLL - 46TI T 0.4556- XLA - 46TI T 0.403 XLC - 46TI T 0.46072-0.5614 XLB - 46TI T 0.46703-0.46703 XLG - 46TI T - 46TI T 3.796-4.014 |] KLL AUGER - 46TI T 4.328-4.507 |] 0.01791 22 KLX AUGER - 46TI T 4.846-4.959 |] KXY AUGER - 46TI T 0.3349-0.5596 0.00207222 L AUGER - 46SC P 0.0 4+ 83.787 D 16 2366.5 7 - 46TI N 1.0 1.0 1 1.0 - 46TI L 0 0+ STABLE - 46TI L 889.280 2 2+ 5.32 PS 15 - 46TI B 1477.2 7 0.02 2 12.2 2 - 46TIS B EAV=580.7 3 - 46TI G 889.271 2 99.9837425E2 1625E-723 - 46TI2 G KC=1475E-7 21$LC=1322E-8 19$MC=1690E-9 24 - 46TI L 2009.832 4 4+ 1.62 PS 10 - 46TI B 356.7 7 99.98 2 6.2 - 46TIS B EAV=111.7 3 - 46TI G 1120.537 3 99.97 2E2 9.41E-514 - 46TI2 G KC=8.39E-5 12$LC=7.50E-6 11$MC=9.59E-7 14 - 46TI G 2009.785 4 0.00001310E4 6.97E-510 - 46TI2 G KC=6.32E-5 9$LC=5.67E-6 8$MC=7.25E-7 11 - + 46TI 46SC B- DECAY (83.787 D) + 46TI H TYP=UPD$AUT=N.K.KUZMENKO$CUT=23-JUN-2014$ + 46TI2 H TYP=FUL$AUT=R.G.HELMER$CUT=01-FEB-2001$ + 46TI C References:1940Wa01, 1950So57, 1950Mo62, 1954Ke04, 1956Wo09, 1956Sc87, + 46TI2C 1957Ge07, 1957Wr37, 1963Ho17, 1965An07, 1967Wa29, 1972BaWG, 1974Cr05, + 46TI3C 1977MeZP, 1979Sc31, 1980Ho17, 1980Ol03, 1980Fu07, 1980RuZY, 1982HoZJ, + 46TI4C 1982RuZV, 1983Wa26, 1986Al19, 1992Un01, 1998Si17, 2000He14, 2000Wu08, + 46TI5C 2002Ba85, 2004BeZR, 2008Ki07, 2012Fi12, 2012Wa38, 2014Un01 + 46TI T Auger electrons and X ray energies and emission intensities: + 46TI T {U Energy (keV)} {U Intensity} {U Line} + 46TI T + 46TI T 4.50491 0.00155 4 XKA2 + 46TI T 4.5109 0.00306 8 XKA1 + 46TI T + 46TI T 4.93186 |] 0.00061218 XKB1 + 46TI T 4.9623 |] XKB5II + 46TI T + 46TI T + 46TI T 0.3967-0.5614 0.00012 3 XL (total) + 46TI T 0.3967 XLL + 46TI T 0.4556- XLA + 46TI T 0.403 XLC + 46TI T 0.46072-0.5614 XLB + 46TI T 0.46703-0.46703 XLG + 46TI T + 46TI T 3.796-4.014 |] KLL AUGER + 46TI T 4.328-4.507 |] 0.01791 22 KLX AUGER + 46TI T 4.846-4.959 |] KXY AUGER + 46TI T 0.3349-0.5596 0.00207222 L AUGER + 46SC P 0.0 4+ 83.787 D 16 2366.5 7 + 46TI N 1.0 1.0 1 1.0 + 46TI L 0 0+ STABLE + 46TI L 889.280 2 2+ 5.32 PS 15 + 46TI B 1477.2 7 0.02 2 12.2 2 + 46TIS B EAV=580.7 3 + 46TI G 889.271 2 99.9837425E2 1625E-723 + 46TI2 G KC=1.475E-4 21$LC=1.322E-5 19$MC=1.690E-6 24$NC=9.14E-8 13 + 46TI L 2009.832 4 4+ 1.62 PS 10 + 46TI B 356.7 7 99.98 2 6.2 + 46TIS B EAV=111.7 3 + 46TI G 1120.537 3 99.97 2E2 9.41E-514 + 46TI2 G KC=8.39E-5 12$LC=7.50E-6 11$MC=9.59E-7 14$NC=5.20E-8 8 + 46TI3 G IPC=1.692E-6 24 + 46TI G 2009.785 4 0.00001310E4 6.97E-510 + 46TI2 G KC=6.32E-5 9$LC=5.67E-6 8$MC=7.25E-7 11$NC=3.93E-8 6 + diff --git a/HEN_HOUSE/spectra/lnhb/Sc-47.txt b/HEN_HOUSE/spectra/lnhb/Sc-47.txt index 1f29ca6a2..6505f5e87 100644 --- a/HEN_HOUSE/spectra/lnhb/Sc-47.txt +++ b/HEN_HOUSE/spectra/lnhb/Sc-47.txt @@ -1,38 +1,37 @@ - 47TI 47SC B- DECAY (3.3485 D) - 47TI H TYP=Full$AUT=X.Mougeot$CUT=30-NOV-2013$ - 47TI C Evaluation history: Type=Full;Author=X.Mougeot;Cutoff date=30-NOV-2013 - 47TI C References: 1945HI04, 1949KR12, 1953MA64, 1953CH16, 1953CO44, 1953DU22, - 47TI2C 1955LY34, 1955NI15, 1956LI38, 1956GR12, 1959PO64, 1963HO17, 1964MI07, - 47TI3C 1967KO01, 1968BA33, 1968ME07, 1969WO02, 1969RA16, 1972GEZG, 1980MO26, - 47TI4C 1986RE12, 1996SC06, 2007BU08, 2008KI07, 2012WA38 - 47TI T Auger electrons and X ray energies and emission intensities: - 47TI T {U Energy (keV)} {U Intensity} {U Line} - 47TI T - 47TI T 4.50491 0.0256 9 XKA2 - 47TI T 4.5109 0.0505 16 XKA1 - 47TI T - 47TI T 4.93186 |] 0.0101 4 XKB1 - 47TI T 4.9623 |] XKB5II - 47TI T - 47TI T - 47TI T 0.3967 XLL - 47TI T 0.4556- XLA - 47TI T 0.403 XLC - 47TI T 0.46072-0.5614 XLB - 47TI T 0.46703-0.46703 XLG - 47TI T - 47TI T 3.79-4.01 |] KLL AUGER - 47TI T 4.33-4.48 |] 0.295 7 KLX AUGER - 47TI T 4.83-4.9 |] KXY AUGER - 47TI T 0.3-0.5 0.0349 8 L AUGER - 47SC P 0.0 7/2- 3.3485 D 9 600.8 19 - 47TI N 1.0 1.0 1 1.0 - 47TI L 0 5/2- STABLE - 47TI B 600.8 1931.5 5 6.1 - 47TIS B EAV=204.2 8 - 47TI L 159.373 127/2- 210 PS 6 - 47TI B 441.4 1968.5 5 5.3 - 47TIS B EAV=142.8 7 - 47TI G 159.373 1268.1 5M1+()E2 -0.099 9 0.0061813 - 47TI2 G KC=0.00560 12$LC=5.12E-4 11$MC=6.54E-5 14 - + 47TI 47SC B- DECAY (3.3485 D) + 47TI H TYP=FUL$AUT=X.MOUGEOT$CUT=30-NOV-2013$ + 47TI C References:1945HI04, 1949KR12, 1953MA64, 1953CH16, 1953CO44, 1953DU22, + 47TI2C 1955LY34, 1955NI15, 1956LI38, 1956GR12, 1959PO64, 1963HO17, 1964MI07, + 47TI3C 1967KO01, 1968BA33, 1968ME07, 1969WO02, 1969RA16, 1972GEZG, 1980MO26, + 47TI4C 1986RE12, 1996SC06, 2007BU08, 2008Ki07, 2012WA38 + 47TI T Auger electrons and X ray energies and emission intensities: + 47TI T {U Energy (keV)} {U Intensity} {U Line} + 47TI T + 47TI T 4.50491 0.0256 9 XKA2 + 47TI T 4.5109 0.0505 16 XKA1 + 47TI T + 47TI T 4.93186 |] 0.0101 4 XKB1 + 47TI T 4.9623 |] XKB5II + 47TI T + 47TI T + 47TI T 0.3967 XLL + 47TI T 0.4556- XLA + 47TI T 0.403 XLC + 47TI T 0.46072-0.5614 XLB + 47TI T 0.46703-0.46703 XLG + 47TI T + 47TI T 3.79-4.01 |] KLL AUGER + 47TI T 4.33-4.48 |] 0.295 7 KLX AUGER + 47TI T 4.83-4.9 |] KXY AUGER + 47TI T 0.3-0.5 0.0349 8 L AUGER + 47SC P 0.0 7/2- 3.3485 D 9 600.8 19 + 47TI N 1.0 1.0 1 1.0 + 47TI L 0 5/2- STABLE + 47TI B 600.8 1931.5 5 6.1 + 47TIS B EAV=204.2 8 + 47TI L 159.373 127/2- 210 PS 6 + 47TI B 441.4 1968.5 5 5.3 + 47TIS B EAV=142.8 7 + 47TI G 159.373 1268.1 5M1+E2 -0.099 9 0.0061813 + 47TI2 G KC=0.00560 12$LC=0.000512 11$MC=6.54E-5 14$NC=3.48E-6 7 + diff --git a/HEN_HOUSE/spectra/lnhb/Se-73.txt b/HEN_HOUSE/spectra/lnhb/Se-73.txt index 99b52a136..15bdb52cb 100644 --- a/HEN_HOUSE/spectra/lnhb/Se-73.txt +++ b/HEN_HOUSE/spectra/lnhb/Se-73.txt @@ -1,173 +1,185 @@ - 73AS 73SE EC DECAY (7.10 H) - 73AS H TYP=FULL$AUT=A.L.Nichols$CUT=23-NOV-2013$ - 73AS C Evaluation history: Type=FULL;Author=A.L.Nichols;Cutoff date=23-NOV-2013 - 73AS C References: 1948Co07, 1951Sc70, 1955Ha85, 1956Ha10, 1957Be46, 1957Ku57, - 73AS2C 1960Ri09, 1960Ku06, 1963Bo26, 1963Bo16, 1966Ol04, 1967Ra08, 1968At04, - 73AS3C 1968Ak03, 1968Iv02, 1969Iv02, 1969Ma21, 1970Me20, 1970MeZZ, 1970Qu03, - 73AS4C 1971Go40, 1972ReZN, 1974Be54, 1975Va03, 1976Sc13, 1976Bo19, 1977La19, - 73AS5C 1977KeZY, 1978TeZY, 1980Te01, 1988Be39, 1992Sc21, 1995ScZY, 1996Sc06, - 73AS6C 1997So08, 1998Sc28, 1998ScZM, 1999ScZX, 2000Sc47, 2002Ba85, 2002Ra45, - 73AS7C 2004Si08, 2008Ki07, 2012Wa38 - 73AS T Auger electrons and X ray energies and emission intensities: - 73AS T {U Energy (keV)} {U Intensity} {U Line} - 73AS T - 73AS T 10.50814 8.3 3 XKA2 - 73AS T 10.5438 16.2 6 XKA1 - 73AS T - 73AS T 11.7204 |] XKB3 - 73AS T 11.7263 |] 3.70 14 XKB1 - 73AS T 11.821 |] XKB5II - 73AS T - 73AS T 11.8643 |] XKB2 - 73AS T |] 0.140 7 XKB4 - 73AS T - 73AS T 1.12-1.524 1.05 3 XL (total) - 73AS T 1.12 0.027 1 XLL - 73AS T 1.282- 0.613 21 XLA - 73AS T 1.155 0.0152 7 XLC - 73AS T 1.317-1.388 0.397 17 XLB - 73AS T 1.524- 0.00230 9 XLG - 73AS T - 73AS T 8.746-9.149 |] KLL AUGER - 73AS T 10.114-10.541 |] 21.0 8 KLX AUGER - 73AS T 11.46-11.862 |] KXY AUGER - 73AS T 0.9-1.23 65.3 15 L AUGER - 73SE P 0.0 9/2+ 7.10 H 9 2725 7 - 73AS N 1.0 1.0 1 1.0 - 73AS G 600.3 3 0.020 3 - 73AS G 793.0 5 0.064 2 - 73AS G 930.09 150.005 1 - 73AS G 1215.4 8 0.063 10 - 73AS G 1249.9 2 0.004 1 - 73AS G 1323.81 200.007 1 - 73AS G 1738.4 5 0.002 1 - 73AS G 1847.8 3 0.008 1 - 73AS G 1889.57 200.003 1 - 73AS G 2023.9 3 0.002 1 - 73AS G 2170.5 3 0.002 1 - 73AS L 0 0 3/2- 80.30 D 6 - 73AS L 67.039 8 5/2- 4.97 NS 7 - 73AS E 0.69 110.51 98.7 1U - 73AS2 E EAV=745 3$CK=0.8811 15$CL=0.1000 12$CM=0.0172 4$CN=0.0017 1 - 73AS G 67.039 8 71 7M1 0.272 4 - 73AS2 G KC=0.241 4$LC=0.0264 4$MC=0.00404 6 - 73AS L 427.906 219/2+ 5.75 US 20 - 73AS E 63.9 533.3 55.36 - 73AS2 E EAV=555 3$CK=0.8810 15$CL=0.1001 12$CM=0.0172 4$CN=0.0017 1 - 73AS G 360.866 2396.91 20M2+E3 -0.035 10 0.0131519 - 73AS2 G KC=0.01165 17$LC=1286E-6 18$MC=1.97E-4 3 - 73AS G 427.905 210.078 14E3 0.0135719 - 73AS2 G KC=0.01195 17$LC=1397E-6 20$MC=2.13E-4 3 - 73AS L 510.055 17(5/2)+ - 73AS G 443.015 190.050 3(E1) 1037E-615 - 73AS2 G KC=9.26E-4 13$LC=9.55E-5 14$MC=1454E-8 21 - 73AS G 510.053 170.26 3(E1) 7.28E-411 - 73AS2 G KC=0.00065 1$LC=6.7E-5 1$MC=1020E-8 15 - 73AS L 993.766 12(7/2)- - 73AS G 926.721 140.004 1(M1+E2) - 73AS G 993.759 120.005 1(E2) 3.92E-4 6 - 73AS2 G KC=3.50E-4 5$LC=3.63E-5 5$MC=5.52E-6 8 - 73AS L 1037.13 3 (13/2)+ - 73AS G 609.22 4 0.049 4(E2) 1412E-620 - 73AS2 G KC=1258E-6 18$LC=1327E-7 19$MC=2.02E-5 3 - 73AS L 1178.052 21(7/2)- - 73AS E 0.017 10.178 27.3 1 - 73AS2 E EAV=228 3$CK=0.8805 15$CL=0.1005 12$CM=0.0173 4$CN=0.0017 1 - 73AS G 1111.004 230.201 2(M1+E2) - 73AS L 1275.14 7 (7/2)+ - 73AS E 0.0003 10.0057 198.7 - 73AS2 E EAV=187 3$CK=0.8804 15$CL=0.1006 12$CM=0.0173 4$CN=0.0017 1 - 73AS G 765.09 7 0.127 2(M1+E2) - 73AS G 847.22 7 0.078 6(M1+E2) - 73AS G 1208.09 7 0.004 1(E1) 1700E-724 - 73AS2 G KC=1050E-7 15$LC=1072E-8 15$MC=1632E-9 23 - 73AS G 1275.13 7 0.007 1(M2) 4.46E-4 7 - 73AS2 G KC=3.94E-4 6$LC=4.08E-5 6$MC=6.23E-6 9 - 73AS L 1293.09 10(11/2)+ - 73AS E 0.017 20.435 196.8 - 73AS2 E EAV=179 3$CK=0.8804 15$CL=0.1006 12$CM=0.0173 4$CN=0.0017 1 - 73AS G 865.17 100.50 2(M1+E2) - 73AS L 1293.37 3 (7/2)+ - 73AS G 783.32 4 0.058 2(M1+E2) - 73AS G 865.45 3 0.02 1(M1+E2) - 73AS G 1226.32 3 0.003 2(E1) 1.79E-4 3 - 73AS2 G KC=1023E-7 15$LC=1043E-8 15$MC=1589E-9 23 - 73AS L 1328.89 5 (7/2,9/2)+ - 73AS E 0.0034 20.129 37.3 - 73AS2 E EAV=164 3$CK=0.8804 15$CL=0.1006 12$CM=0.0173 4$CN=0.0017 1 - 73AS G 818.84 5 0.036 2(M1+E2) - 73AS G 900.97 5 0.135 2(M1+E2) - 73AS L 1850.59 5 (9/2)+ - 73AS E 0.433 116.4 - 73AS2 E CK=0.8794 15$CL=0.1014 12$CM=0.0175 4$CN=0.0017 1 - 73AS G 557.50 110.052 2(M1+E2) - 73AS G 575.45 9 0.146 7(M1+E2) - 73AS G 813.46 6 0.009 1(E2) 6.42E-4 9 - 73AS2 G KC=5.73E-4 8$LC=5.97E-5 9$MC=9.10E-6 13 - 73AS G 856.81 5 0.023 6(E1) 2.27E-4 4 - 73AS2 G KC=2.03E-4 3$LC=2.07E-5 3$MC=3.16E-6 5 - 73AS G 1340.53 5 0.069 2(E2) 2.39E-4 4 - 73AS2 G KC=1.80E-4 3$LC=1.85E-5 3$MC=2.82E-6 4 - 73AS G 1422.67 6 0.135 5(M1+E2) - 73AS L 1910.13 12(9/2,11/2)+ - 73AS E 0.060 77.2 - 73AS2 E CK=0.8792 15$CL=0.1016 13$CM=0.0175 4$CN=0.0017 1 - 73AS G 872.99 120.038 7(E2) 5.37E-4 8 - 73AS2 G KC=4.79E-4 7$LC=4.99E-5 7$MC=7.60E-6 11 - 73AS G 1482.20 6 0.022 1(M1+E2) - 73AS L 1961.8 2 (3/2,5/2,7/2)+ - 73AS E 0.017 57.7 2U - 73AS2 E CK=0.8790 15$CL=0.1017 13$CM=0.0176 4$CN=0.0017 1 - 73AS G 968.0 2 0.012 5 - 73AS G 1451.7 2 0.006 2 - 73AS L 1975.41 11(7/2,9/2,11/2)+ - 73AS E 0.094 36.9 - 73AS2 E CK=0.8789 15$CL=0.1018 13$CM=0.0176 4$CN=0.0017 1 - 73AS G 682.04 110.019 2(E1) 3.69E-4 6 - 73AS2 G KC=3.30E-4 5$LC=3.38E-5 5$MC=5.15E-6 8 - 73AS G 700.27 130.044 2(M1+E2) - 73AS G 1547.48 110.031 1(M1+E2) - 73AS L 2180.66 10(7/2,9/2)+ - 73AS E 0.030 87.1 - 73AS2 E CK=0.8778 15$CL=0.1027 13$CM=0.0178 4$CN=0.0017 1 - 73AS G 887.28 100.011 8(M1+E2) - 73AS G 1002.60 100.004 1(E1) 1660E-724 - 73AS2 G KC=1484E-7 21$LC=1517E-8 22$MC=2.31E-6 4 - 73AS G 1670.59 100.005 1(M1+E2) - 73AS G 1752.73 100.011 1(M1+E2) - 73AS L 2311.63 6 (7/2,9/2)+ - 73AS E 0.157 66.2 - 73AS2 E CK=0.8764 16$CL=0.1038 13$CM=0.0180 4$CN=0.0018 1 - 73AS G 982.73 8 0.034 1(M1+E2) - 73AS G 1018.25 7 0.053 2(M1+E2) - 73AS G 1036.48 9 0.015 1(M1+E2) - 73AS G 1317.85 6 0.006 1(E1) 2.27E-4 4 - 73AS2 G KC=9.02E-5 13$LC=9.19E-6 13$MC=1.40E-6 2 - 73AS G 1801.56 6 0.019 5(M1+E2) - 73AS G 1883.69 6 0.030 2(M1+E2) - 73AS L 2434.1 4 3/2,5/2+ - 73AS E 0.0048 197.4 2U - 73AS2 E CK=0.8740 16$CL=0.1058 13$CM=0.0184 4$CN=0.0018 1 - 73AS G 1159.0 4 0.003 1 - 73AS G 2006.2 4 0.002 1 - 73AS L 2476.1 2 (11/2,15/2)+ - 73AS E 0.0029 107.5 - 73AS2 E CK=0.8726 16$CL=0.1070 13$CM=0.0186 4$CN=0.0018 2 - 73AS G 1439.0 2 0.002 1 - 73AS G 2048.2 2 0.001 1 - 73AS L 2482.87 23(7/2,9/2)+ - 73AS E 0.0087 207 - 73AS2 E CK=0.8723 16$CL=0.1072 13$CM=0.0186 4$CN=0.0018 2 - 73AS G 1153.97 240.005 1(M1+E2) - 73AS G 1972.79 230.001 1(M1+E2) - 73AS G 2054.93 230.003 1(M1+E2) - 73AS L 2584.09 11(7/2,9/2)- - 73AS E 0.0155 206.2 1 - 73AS2 E CK=0.8646 19$CL=0.1136 16$CM=0.0199 5$CN=0.0020 2 - 73AS G 1308.94 130.004 1(E1) 2.22E-4 4 - 73AS2 G KC=9.12E-5 13$LC=9.30E-6 13$MC=1417E-9 20 - 73AS G 1406.03 110.002 1(M1+E2) - 73AS G 2156.15 110.005 1(E1) 7.85E-411 - 73AS2 G KC=4.13E-5 6$LC=4.19E-6 6$MC=6.38E-7 9 - 73AS G 2517.00 110.005 1(M1+E2) - + 73AS 73SE EC DECAY (7.10 H) + 73AS H TYP=FUL$AUT=A.L.NICHOLS$CUT=23-NOV-2013$ + 73AS C References:1948Co07, 1951Sc70, 1955Ha85, 1956Ha10, 1957Be46, 1957Ku57, + 73AS2C 1960Ri09, 1960Ku06, 1963Bo26, 1963Bo16, 1966Ol04, 1967Ra08, 1968At04, + 73AS3C 1968Ak03, 1968Iv02, 1969Iv02, 1969Ma21, 1970Me20, 1970MeZZ, 1970Qu03, + 73AS4C 1971Go40, 1972ReZN, 1974Be54, 1975Va03, 1976Sc13, 1976Bo19, 1977La19, + 73AS5C 1977KeZY, 1978TeZY, 1980Te01, 1988Be39, 1992Sc21, 1995ScZY, 1996Sc06, + 73AS6C 1997So08, 1998Sc28, 1998ScZM, 1999ScZX, 2000Sc47, 2002Ba85, 2002Ra45, + 73AS7C 2004Si08, 2008Ki07, 2012Wa38 + 73AS T Auger electrons and X ray energies and emission intensities: + 73AS T {U Energy (keV)} {U Intensity} {U Line} + 73AS T + 73AS T 10.50814 8.3 3 XKA2 + 73AS T 10.5438 16.2 6 XKA1 + 73AS T + 73AS T 11.7204 |] XKB3 + 73AS T 11.7263 |] 3.70 14 XKB1 + 73AS T 11.821 |] XKB5II + 73AS T + 73AS T 11.8643 |] XKB2 + 73AS T |] 0.140 7 XKB4 + 73AS T + 73AS T 1.12-1.524 1.05 3 XL (total) + 73AS T 1.12 0.027 1 XLL + 73AS T 1.282- 0.613 21 XLA + 73AS T 1.155 0.0152 7 XLC + 73AS T 1.317-1.388 0.397 17 XLB + 73AS T 1.524- 0.00230 9 XLG + 73AS T + 73AS T 8.746-9.149 |] KLL AUGER + 73AS T 10.114-10.541 |] 21.0 8 KLX AUGER + 73AS T 11.46-11.862 |] KXY AUGER + 73AS T 0.9-1.23 65.3 15 L AUGER + 73SE P 0.0 9/2+ 7.10 H 9 2725 7 + 73AS N 1.0 1.0 1 1.0 + 73AS G 600.3 3 0.020 3 + 73AS G 793.0 5 0.064 2 + 73AS G 930.09 150.005 1 + 73AS G 1215.4 8 0.063 10 + 73AS G 1249.9 2 0.004 1 + 73AS G 1323.81 200.007 1 + 73AS G 1738.4 5 0.002 1 + 73AS G 1847.8 3 0.008 1 + 73AS G 1889.57 200.003 1 + 73AS G 2023.9 3 0.002 1 + 73AS G 2170.5 3 0.002 1 + 73AS L 0 3/2- 80.30 D 6 + 73AS L 67.039 8 5/2- 4.97 NS 7 + 73AS E 0.69 110.51 98.7 1U + 73AS2 E EAV=745 3$CK=0.3745 6$CL=0.0425 5$CM=0.00731 17 + 73AS3 E CN=0.000722 43 + 73AS G 67.039 8 71 7M1 0.272 4 + 73AS2 G KC=0.241 4$LC=0.0264 4$MC=0.00404 6$NC=0.000304 5 + 73AS L 427.906 219/2+ 5.75 US 20 + 73AS E 63.9 533.3 55.36 + 73AS2 E EAV=555 3$CK=0.3018 5$CL=0.03429 41$CM=0.00589 14 + 73AS3 E CN=0.000582 34 + 73AS G 360.866 2396.91 20M2+E3 -0.035 10 0.0131519 + 73AS2 G KC=0.01165 17$LC=0.001286 18$MC=0.000197 3$NC=1.486E-5 21 + 73AS G 427.905 210.078 14E3 0.0135719 + 73AS2 G KC=0.01195 17$LC=0.001397 20$MC=0.000213 3$NC=1.538E-5 22 + 73AS L 510.055 17(5/2)+ + 73AS G 443.015 190.050 3(E1) 1037E-615 + 73AS2 G KC=0.000926 13$LC=9.55E-5 14$MC=1.454E-5 21$NC=1.104E-6 16 + 73AS G 510.053 170.26 3(E1) 7.28E-411 + 73AS2 G KC=0.00065 1$LC=0.000067 1$MC=1.020E-5 15$NC=7.75E-7 11 + 73AS L 993.766 12(7/2)- + 73AS G 926.721 140.004 1(M1+E2) + 73AS G 993.759 120.005 1(E2) 3.92E-4 6 + 73AS2 G KC=0.000350 5$LC=3.63E-5 5$MC=5.52E-6 8$NC=4.20E-7 6 + 73AS L 1037.13 3 (13/2)+ + 73AS G 609.22 4 0.049 4(E2) 1412E-620 + 73AS2 G KC=0.001258 18$LC=1.327E-4 19$MC=2.02E-5 3$NC=1.523E-6 22 + 73AS L 1178.052 21(7/2)- + 73AS E 0.017 10.178 27.3 1 + 73AS2 E EAV=228 3$CK=0.8037 14$CL=0.0917 11$CM=0.01579 37 + 73AS3 E CN=0.00155 9 + 73AS G 1111.004 230.201 2(M1+E2) + 73AS L 1275.14 7 (7/2)+ + 73AS E 0.0003 10.0057 198.7 + 73AS2 E EAV=187 3$CK=0.8364 14$CL=0.0956 11$CM=0.01644 38 + 73AS3 E CN=0.00162 10 + 73AS G 765.09 7 0.127 2(M1+E2) + 73AS G 847.22 7 0.078 6(M1+E2) + 73AS G 1208.09 7 0.004 1(E1) 1700E-724 + 73AS2 G KC=1.050E-4 15$LC=1.072E-5 15$MC=1.632E-6 23$NC=1.248E-7 18 + 73AS3 G IPC=5.25E-5 8 + 73AS G 1275.13 7 0.007 1(M2) 4.46E-4 7 + 73AS2 G KC=0.000394 6$LC=4.08E-5 6$MC=6.23E-6 9$NC=4.77E-7 7 + 73AS3 G IPC=4.16E-6 6 + 73AS L 1293.09 10(11/2)+ + 73AS E 0.017 20.435 196.8 + 73AS2 E EAV=179 3$CK=0.8473 14$CL=0.0968 12$CM=0.01665 38 + 73AS3 E CN=0.00164 10 + 73AS G 865.17 100.50 2(M1+E2) + 73AS L 1293.37 3 (7/2)+ + 73AS G 783.32 4 0.058 2(M1+E2) + 73AS G 865.45 3 0.02 1(M1+E2) + 73AS G 1226.32 3 0.003 2(E1) 1.79E-4 3 + 73AS2 G KC=1.023E-4 15$LC=1.043E-5 15$MC=1.589E-6 23$NC=1.215E-7 17 + 73AS3 G IPC=6.43E-5 9 + 73AS L 1328.89 5 (7/2,9/2)+ + 73AS E 0.0034 20.129 37.3 + 73AS2 E EAV=164 3$CK=0.8578 15$CL=0.0980 12$CM=0.01686 39 + 73AS3 E CN=0.00166 10 + 73AS G 818.84 5 0.036 2(M1+E2) + 73AS G 900.97 5 0.135 2(M1+E2) + 73AS L 1850.59 5 (9/2)+ + 73AS E 0.433 116.4 + 73AS2 E CK=0.8794 15$CL=0.1014 12$CM=0.0175 4$CN=0.0017 1 + 73AS G 557.50 110.052 2(M1+E2) + 73AS G 575.45 9 0.146 7(M1+E2) + 73AS G 813.46 6 0.009 1(E2) 6.42E-4 9 + 73AS2 G KC=0.000573 8$LC=5.97E-5 9$MC=9.10E-6 13$NC=6.9E-7 1 + 73AS G 856.81 5 0.023 6(E1) 2.27E-4 4 + 73AS2 G KC=0.000203 3$LC=2.07E-5 3$MC=3.16E-6 5$NC=2.41E-7 4 + 73AS G 1340.53 5 0.069 2(E2) 2.39E-4 4 + 73AS2 G KC=0.000180 3$LC=1.85E-5 3$MC=2.82E-6 4$NC=2.15E-7 3 + 73AS3 G IPC=3.76E-5 6 + 73AS G 1422.67 6 0.135 5(M1+E2) + 73AS L 1910.13 12(9/2,11/2)+ + 73AS E 0.060 77.2 + 73AS2 E CK=0.8792 15$CL=0.1016 13$CM=0.0175 4$CN=0.0017 1 + 73AS G 872.99 120.038 7(E2) 5.37E-4 8 + 73AS2 G KC=0.000479 7$LC=4.99E-5 7$MC=7.60E-6 11$NC=5.77E-7 8 + 73AS G 1482.20 6 0.022 1(M1+E2) + 73AS L 1961.8 2 (3/2,5/2,7/2)+ + 73AS E 0.017 57.7 2U + 73AS2 E CK=0.8790 15$CL=0.1017 13$CM=0.0176 4$CN=0.0017 1 + 73AS G 968.0 2 0.012 5 + 73AS G 1451.7 2 0.006 2 + 73AS L 1975.41 11(7/2,9/2,11/2)+ + 73AS E 0.094 36.9 + 73AS2 E CK=0.8789 15$CL=0.1018 13$CM=0.0176 4$CN=0.0017 1 + 73AS G 682.04 110.019 2(E1) 3.69E-4 6 + 73AS2 G KC=0.000330 5$LC=3.38E-5 5$MC=5.15E-6 8$NC=3.92E-7 6 + 73AS G 700.27 130.044 2(M1+E2) + 73AS G 1547.48 110.031 1(M1+E2) + 73AS L 2180.66 10(7/2,9/2)+ + 73AS E 0.030 87.1 + 73AS2 E CK=0.8778 15$CL=0.1027 13$CM=0.0178 4$CN=0.0017 1 + 73AS G 887.28 100.011 8(M1+E2) + 73AS G 1002.60 100.004 1(E1) 1660E-724 + 73AS2 G KC=1.484E-4 21$LC=1.517E-5 22$MC=2.31E-6 4$NC=1.764E-7 25 + 73AS G 1670.59 100.005 1(M1+E2) + 73AS G 1752.73 100.011 1(M1+E2) + 73AS L 2311.63 6 (7/2,9/2)+ + 73AS E 0.157 66.2 + 73AS2 E CK=0.8764 16$CL=0.1038 13$CM=0.0180 4$CN=0.0018 1 + 73AS G 982.73 8 0.034 1(M1+E2) + 73AS G 1018.25 7 0.053 2(M1+E2) + 73AS G 1036.48 9 0.015 1(M1+E2) + 73AS G 1317.85 6 0.006 1(E1) 2.27E-4 4 + 73AS2 G KC=9.02E-5 13$LC=9.19E-6 13$MC=1.40E-6 2$NC=1.071E-7 15 + 73AS3 G IPC=1.261E-4 18 + 73AS G 1801.56 6 0.019 5(M1+E2) + 73AS G 1883.69 6 0.030 2(M1+E2) + 73AS L 2434.1 4 3/2,5/2+ + 73AS E 0.0048 197.4 2U + 73AS2 E CK=0.8740 16$CL=0.1058 13$CM=0.0184 4$CN=0.0018 1 + 73AS G 1159.0 4 0.003 1 + 73AS G 2006.2 4 0.002 1 + 73AS L 2476.1 2 (11/2,15/2)+ + 73AS E 0.0029 107.5 + 73AS2 E CK=0.8726 16$CL=0.1070 13$CM=0.0186 4$CN=0.0018 2 + 73AS G 1439.0 2 0.002 1 + 73AS G 2048.2 2 0.001 1 + 73AS L 2482.87 23(7/2,9/2)+ + 73AS E 0.0087 207 + 73AS2 E CK=0.8723 16$CL=0.1072 13$CM=0.0186 4$CN=0.0018 2 + 73AS G 1153.97 240.005 1(M1+E2) + 73AS G 1972.79 230.001 1(M1+E2) + 73AS G 2054.93 230.003 1(M1+E2) + 73AS L 2584.09 11(7/2,9/2)- + 73AS E 0.0155 206.2 1 + 73AS2 E CK=0.8646 19$CL=0.1136 16$CM=0.0199 5$CN=0.0020 2 + 73AS G 1308.94 130.004 1(E1) 2.22E-4 4 + 73AS2 G KC=9.12E-5 13$LC=9.30E-6 13$MC=1.417E-6 20$NC=1.083E-7 16 + 73AS3 G IPC=1.203E-4 17 + 73AS G 1406.03 110.002 1(M1+E2) + 73AS G 2156.15 110.005 1(E1) 7.85E-411 + 73AS2 G KC=4.13E-5 6$LC=4.19E-6 6$MC=6.38E-7 9$NC=4.89E-8 7 + 73AS3 G IPC=0.000739 11 + 73AS G 2517.00 110.005 1(M1+E2) + diff --git a/HEN_HOUSE/spectra/lnhb/Se-75.txt b/HEN_HOUSE/spectra/lnhb/Se-75.txt index 2ed86ba6c..64689803c 100644 --- a/HEN_HOUSE/spectra/lnhb/Se-75.txt +++ b/HEN_HOUSE/spectra/lnhb/Se-75.txt @@ -1,108 +1,106 @@ - 75AS 75SE EC DECAY (119.781 D) - 75AS H TYP=Update$AUT=M.M. Bé$CUT= -- $ - 75AS2 H TYP=Full$AUT=V. Chisté$CUT=30-JUN-2009$ - 75AS3 H TYP=Full$AUT=Browne$CUT= -- $ - 75AS C Evaluation history: Type=Update;Author=M.M. Bé;Cutoff date= -- - 75AS2C Type=Full;Author=V. Chisté;Cutoff date=30-JUN-2009 - 75AS3C Type=Full;Author=Browne;Cutoff date= -- - 75AS C References: 1947Fr08, 1948Co07, 1950Co58, 1955Sc09, 1957Wr37, 1959Me76, - 75AS2C 1960Ea02, 1960Gr03, 1960De06, 1961Ed02, 1965Br19, 1966Ra09, 1969Pa05, - 75AS3C 1969Pa05, 1970Pr07, 1973Su10, 1973Th07, 1974Ca29, 1975La16, 1976MaZW, - 75AS4C 1971Ge07, 1977Ge12, 1977Pr08, 1977Kr13, 1980Ho17, 1980Sc07, 1982HoZJ, - 75AS5C 1983Si25, 1983Yo03, 1984Si02, 1987JeZZ, 1990Wa03, 1990Me15, 1990Je01, - 75AS6C 1990An07, 1991BaZS, 1992Sc09, 1994Iw04, 1994Mi22, 1996Sa22, 1996Sc06, - 75AS7C 1997Lo10, 1999Fa05, 2002Un02, 2002He19, 2003Au03, 2005Ra29, 2008Ki07 - 75AS T Auger electrons and X ray energies and emission intensities: - 75AS T {U Energy (keV)} {U Intensity} {U Line} - 75AS T - 75AS T 10.50814 16.5 6 XKA2 - 75AS T 10.5438 31.9 11 XKA1 - 75AS T - 75AS T 11.7204 |] XKB3 - 75AS T 11.7263 |] 7.30 25 XKB1 - 75AS T 11.821 |] XKB5II - 75AS T - 75AS T 11.8643 |] XKB2 - 75AS T |] 0.276 13 XKB4 - 75AS T - 75AS T 1.1195-1.5312 1.93 5 XL (total) - 75AS T 1.1195 0.0489 18 XLL - 75AS T 1.2816-1.2824 1.11 4 XLA - 75AS T 1.1552 0.0287 12 XLC - 75AS T 1.3152-1.4892 0.742 30 XLB - 75AS T 1.3508-1.5312 0.00393 15 XLG - 75AS T - 75AS T 8.75-9.1 |] KLL AUGER - 75AS T 10.12-10.54 |] 41.4 14 KLX AUGER - 75AS T 11.44-11.8 |] KXY AUGER - 75AS T 1.1-1.3 119.6 15 L AUGER - 75SE P 0.0 5/2+ 119.781 D 24 863.6 8 - 75AS N 1.0 1.0 1 1.0 - 75AS L 0 3/2- STABLE - 75AS E 1.42 228.5 1 - 75AS2 E CK=0.8794 15$CL=0.1014 12$CM=0.0175 4$CN=0.0017 1$CO=0 0 - 75AS L 198.6063 131/2- 0.885 NS 21 - 75AS G 198.6060 121.46 6M1+E2 0.315 39 0.0189 11 - 75AS2 G KC=0.0167 9$LC=0.00182 11$MC=2.77E-4 16 - 75AS L 264.6581 103/2- 0.0112 NS 3 - 75AS E 1.4 28.2 1 - 75AS2 E CK=0.8782 15$CL=0.1024 13$CM=0.0177 4$CN=0.0017 1$CO=0 0 - 75AS G 66.0518 8 1.085 35M1+E2 0.121 33 0.33 3 - 75AS2 G KC=0.29 3$LC=0.034 5$MC=0.0052 7 - 75AS G 264.6576 9 58.75 19M1+E2 -0.095 70 0.0072 3 - 75AS2 G KC=0.00646 25$LC=0.00068 3$MC=1.04E-4 5 - 75AS L 279.5428 115/2- 0.273 NS 3 - 75AS E 2.1 148 - 75AS2 E CK=0.8781 15$CL=0.1025 13$CM=0.0177 4$CN=0.0017 1$CO=0 0 - 75AS G 14.8847 130.0206 6M1(+E2) - 75AS G 80.9365 150.0095 5[E2] 1.736 25 - 75AS2 G KC=1.486 21$LC=0.216 3$MC=0.0326 5 - 75AS G 279.5422 1024.89 9M1+E2 -0.578 44 0.0091 4 - 75AS2 G KC=0.0081 4$LC=0.00087 4$MC=1.33E-4 6 - 75AS L 303.9243 119/2+ 17.62 MS 23 - 75AS G 24.3815 140.027 6M2 204 3 - 75AS2 G KC=165 24$LC=32.6 5$MC=5.13 10 - 75AS G 303.9236 101.308 5E3 0.0538 8 - 75AS2 G KC=0.0469 7$LC=0.00592 9$MC=8.99E-4 13 - 75AS L 400.6585 8 5/2++ 1.67 NS 5 - 75AS E 94.5 216.1 - 75AS2 E CK=0.8770 16$CL=0.1033 13$CM=0.0179 4$CN=0.0018 1$CO=0 0 - 75AS G 96.7340 9 3.35 7E2 0.893 13 - 75AS2 G KC=0.772 11$LC=0.1044 15$MC=0.01576 22 - 75AS G 121.1155 1116.86 36E1 0.0417 6 - 75AS2 G KC=0.0372 6$LC=0.00388 6$MC=5.88E-4 9 - 75AS G 136.0001 6 57.7 20E1 0.0295 5 - 75AS2 G KC=0.0263 4$LC=0.00274 4$MC=4.15E-4 6 - 75AS G 400.6572 8 11.388 42E1 1346E-619 - 75AS2 G KC=1202E-6 17$LC=1241E-7 18$MC=1.89E-5 3 - 75AS L 468.6 4 1/2,3/2- - 75AS E 0.00036 511.1 1U - 75AS2 E CK=0.8762 16$CL=0.1041 13$CM=0.0180 4$CN=0.0018 1$CO=0 0 - 75AS G 468.6 4 0.00036 5[M1E2] 0.0025 7 - 75AS2 G KC=0.0022 6$LC=0.00023 7$MC=3.5E-5 10 - 75AS L 572.22 245/2- 2.9 PS 3 - 75AS E 0.03484 359.1 - 75AS2 E CK=0.8740 16$CL=0.1058 13$CM=0.0184 4$CN=0.0018 1$CO=0 0 - 75AS G 373.61 240.00256 11[E2] 0.0065310 - 75AS2 G KC=0.00580 9$LC=6.28E-4 9$MC=9.54E-5 14 - 75AS G 572.22 240.03622 31M1+E2 0.19 1 1165E-617 - 75AS2 G KC=1040E-6 15$LC=1079E-7 16$MC=1646E-8 24 - 75AS L 617.7 4 1/2,3/2- - 75AS E 0.0126 68.8 1U - 75AS2 E CK=0.8724 16$CL=0.1071 13$CM=0.0186 4$CN=0.0018 2$CO=0 0 - 75AS G 419.1 4 0.0121 6[M1E2] 0.0034 11 - 75AS2 G KC=0.003 1$LC=0.00032 11$MC=4.9E-5 16 - 75AS G 617.8 4 0.00453 5[M1E2] 0.0011620 - 75AS2 G KC=0.00103 18$LC=1.08E-4 20$MC=1.7E-5 3 - 75AS L 821.6 2 7/2- 3.0 PS 3 - 75AS E 0.00734 187.9 1 - 75AS2 E CK=0.8038 32$CL=0.1633 26$CM=0.0300 8$CN=0.0030 2$CO=0 0 - 75AS G 249.3 3 0.00394 12[M1E2] 0.017 10 - 75AS2 G KC=0.015 9$LC=0.0017 10$MC=0.00026 15 - 75AS G 542.02 180.000435 6[M1E2] 0.0016 4 - 75AS2 G KC=0.0015 3$LC=0.00015 4$MC=2.3E-5 6 - 75AS G 557.8 9 0.00276 12[E2] 0.00183 3 - 75AS2 G KC=1628E-6 25$LC=1.72E-4 3$MC=2.62E-5 4 - 75AS G 821.56 180.000134 8[E2] 6.26E-4 9 - 75AS2 G KC=5.58E-4 8$LC=5.82E-5 9$MC=8.87E-6 13 - + 75AS 75SE EC DECAY (119.781 D) + 75AS H TYP=UPD$AUT=M.-M.BE$CUT=09-AUG-2013$ + 75AS2 H TYP=FUL$AUT=V.CHISTE$CUT=30-JUN-2009$ + 75AS3 H TYP=FUL$AUT=E.BROWNE$CUT=18-JAN-1999$ + 75AS C References:1947Fr08, 1948Co07, 1950Co58, 1955Sc09, 1957Wr37, 1959Me76, + 75AS2C 1960Ea02, 1960Gr03, 1960De06, 1961Ed02, 1965Br19, 1966Ra09, 1969Pa05, + 75AS3C 1969Pa05, 1970Pr07, 1973Su10, 1973Th07, 1974Ca29, 1975La16, 1976MaZW, + 75AS4C 1971Ge07, 1977Ge12, 1977Pr08, 1977Kr13, 1980Ho17, 1980Sc07, 1982HoZJ, + 75AS5C 1983Si25, 1983Yo03, 1984Si02, 1987JeZZ, 1990Wa03, 1990Me15, 1990Je01, + 75AS6C 1990An07, 1991BaZS, 1992Sc09, 1994Iw04, 1994Mi22, 1996Sa22, 1996Sc06, + 75AS7C 1997Lo10, 1999Fa05, 2000Zh**, 2002Un02, 2002He19, 2003Au03, 2005Ra29, + 75AS8C 2008Ki07 + 75AS T Auger electrons and X ray energies and emission intensities: + 75AS T {U Energy (keV)} {U Intensity} {U Line} + 75AS T + 75AS T 10.50814 16.5 6 XKA2 + 75AS T 10.5438 31.9 11 XKA1 + 75AS T + 75AS T 11.7204 |] XKB3 + 75AS T 11.7263 |] 7.30 25 XKB1 + 75AS T 11.821 |] XKB5II + 75AS T + 75AS T 11.8643 |] XKB2 + 75AS T |] 0.276 13 XKB4 + 75AS T + 75AS T 1.1195-1.5312 1.93 5 XL (total) + 75AS T 1.1195 0.0489 18 XLL + 75AS T 1.2816-1.2824 1.11 4 XLA + 75AS T 1.1552 0.0287 12 XLC + 75AS T 1.3152-1.4892 0.742 30 XLB + 75AS T 1.3508-1.5312 0.00393 15 XLG + 75AS T + 75AS T 8.75-9.1 |] KLL AUGER + 75AS T 10.12-10.54 |] 41.4 14 KLX AUGER + 75AS T 11.44-11.8 |] KXY AUGER + 75AS T 1.1-1.3 119.6 15 L AUGER + 75SE P 0.0 5/2+ 119.781 D 24 863.6 8 + 75AS N 1.0 1.0 1 1.0 + 75AS L 0 3/2- STABLE + 75AS E 1.42 228.5 1 + 75AS2 E CK=0.8794 15$CL=0.1014 12$CM=0.0175 4$CN=0.0017 1 + 75AS L 198.6063 131/2- 0.885 NS 21 + 75AS G 198.6060 121.46 6M1+E2 0.315 39 0.0189 11 + 75AS2 G KC=0.0167 9$LC=0.00182 11$MC=0.000277 16$NC=2.07E-5 12 + 75AS L 264.6581 103/2- 0.0112 NS 3 + 75AS E 1.4 28.2 1 + 75AS2 E CK=0.8782 15$CL=0.1024 13$CM=0.0177 4$CN=0.0017 1 + 75AS G 66.0518 8 1.085 35M1+E2 0.121 33 0.33 3 + 75AS2 G KC=0.29 3$LC=0.034 5$MC=0.0052 7$NC=0.00038 4 + 75AS G 264.6576 9 58.75 19M1+E2 -0.095 70 0.0072 3 + 75AS2 G KC=0.00646 25$LC=0.00068 3$MC=0.000104 5$NC=7.9E-6 3 + 75AS L 279.5428 115/2- 0.273 NS 3 + 75AS E 2.1 148 + 75AS2 E CK=0.8781 15$CL=0.1025 13$CM=0.0177 4$CN=0.0017 1 + 75AS G 14.8847 130.0206 6M1(+E2) + 75AS G 80.9365 150.0095 5[E2] 1.736 25 + 75AS2 G KC=1.486 21$LC=0.216 3$MC=0.0326 5$NC=0.00213 3 + 75AS G 279.5422 1024.89 9M1+E2 -0.578 44 0.0091 4 + 75AS2 G KC=0.0081 4$LC=0.00087 4$MC=0.000133 6$NC=9.9E-6 4 + 75AS L 303.9243 119/2+ 17.62 MS 23 + 75AS G 24.3815 140.027 6M2 204 3 + 75AS2 G KC=165 24$LC=32.6 5$MC=5.13 10$NC=0.358 5 + 75AS G 303.9236 101.308 5E3 0.0538 8 + 75AS2 G KC=0.0469 7$LC=0.00592 9$MC=0.000899 13$NC=6.30E-5 9 + 75AS L 400.6585 8 5/2+ 1.67 NS 5 + 75AS E 94.5 216.1 + 75AS2 E CK=0.8770 16$CL=0.1033 13$CM=0.0179 4$CN=0.0018 1 + 75AS G 96.7340 9 3.35 7E2 0.893 13 + 75AS2 G KC=0.772 11$LC=0.1044 15$MC=0.01576 22$NC=0.001058 15 + 75AS G 121.1155 1116.86 36E1 0.0417 6 + 75AS2 G KC=0.0372 6$LC=0.00388 6$MC=0.000588 9$NC=4.37E-5 7 + 75AS G 136.0001 6 57.7 20E1 0.0295 5 + 75AS2 G KC=0.0263 4$LC=0.00274 4$MC=0.000415 6$NC=3.10E-5 5 + 75AS G 400.6572 8 11.388 42E1 1346E-619 + 75AS2 G KC=0.001202 17$LC=1.241E-4 18$MC=1.89E-5 3$NC=1.432E-6 20 + 75AS L 468.6 4 1/2,3/2- + 75AS E 0.00036 511.1 1U + 75AS2 E CK=0.8762 16$CL=0.1041 13$CM=0.0180 4$CN=0.0018 1 + 75AS G 468.6 4 0.00036 5[M1,E2] 0.0025 7 + 75AS2 G KC=0.0022 6$LC=0.00023 7$MC=0.000035 10$NC=2.7E-6 8 + 75AS L 572.22 245/2- 2.9 PS 3 + 75AS E 0.03484 359.1 + 75AS2 E CK=0.8740 16$CL=0.1058 13$CM=0.0184 4$CN=0.0018 1 + 75AS G 373.61 240.00256 11[E2] 0.0065310 + 75AS2 G KC=0.00580 9$LC=0.000628 9$MC=9.54E-5 14$NC=7.09E-6 11 + 75AS G 572.22 240.03622 31M1+E2 0.19 1 1165E-617 + 75AS2 G KC=0.001040 15$LC=1.079E-4 16$MC=1.646E-5 24$NC=1.256E-6 18 + 75AS L 617.7 4 1/2,3/2- + 75AS E 0.0126 68.8 1U + 75AS2 E CK=0.8724 16$CL=0.1071 13$CM=0.0186 4$CN=0.0018 2 + 75AS G 419.1 4 0.0121 6[M1,E2] 0.0034 11 + 75AS2 G KC=0.003 1$LC=0.00032 11$MC=0.000049 16$NC=3.7E-6 12 + 75AS G 617.8 4 0.00453 5[M1,E2] 0.0011620 + 75AS2 G KC=0.00103 18$LC=0.000108 20$MC=0.000017 3$NC=1.25E-6 22 + 75AS L 821.6 2 7/2- 3.0 PS 3 + 75AS E 0.00734 187.9 1 + 75AS2 E CK=0.8038 32$CL=0.1633 26$CM=0.0300 8$CN=0.0030 2 + 75AS G 249.3 3 0.00394 12[M1,E2] 0.017 10 + 75AS2 G KC=0.015 9$LC=0.0017 10$MC=0.00026 15$NC=0.000019 11 + 75AS G 542.02 180.000435 6[M1,E2] 0.0016 4 + 75AS2 G KC=0.0015 3$LC=0.00015 4$MC=0.000023 6$NC=1.8E-6 4 + 75AS G 557.8 9 0.00276 12[E2] 0.00183 3 + 75AS2 G KC=0.001628 25$LC=0.000172 3$MC=2.62E-5 4$NC=1.97E-6 3 + 75AS G 821.56 180.000134 8[E2] 6.26E-4 9 + 75AS2 G KC=0.000558 8$LC=5.82E-5 9$MC=8.87E-6 13$NC=6.73E-7 10 + diff --git a/HEN_HOUSE/spectra/lnhb/Se-79.txt b/HEN_HOUSE/spectra/lnhb/Se-79.txt index 1d9b9c303..c10e779e2 100644 --- a/HEN_HOUSE/spectra/lnhb/Se-79.txt +++ b/HEN_HOUSE/spectra/lnhb/Se-79.txt @@ -1,21 +1,20 @@ - 79BR 79SE B- DECAY (3.56E5 Y) - 79BR H TYP=Full$AUT=M.-M. Bé$CUT=30-JAN-2006$ - 79BR C Evaluation history: Type=Full;Author=M.-M. Bé;Cutoff date=30-JAN-2006 - 79BR T Auger electrons and X ray energies and emission intensities: - 79BR T {U Energy (keV)} {U Intensity} {U Line} - 79BR T - 79BR T 11.8778 XKA2 - 79BR T 11.9244 XKA1 - 79BR T - 79BR T 13.2847 |] XKB3 - 79BR T 13.2916 |] XKB1 - 79BR T 13.396 |] XKB5II - 79BR T - 79BR T 13.4696 |] XKB2 - 79BR T - 79SE P 0.0 7/2+ 3.56E5 Y 40 150.9 17 - 79BR N 1.0 1.0 1 1.0 - 79BR L 0 3/2- STABLE - 79BR B 150.9 17100 10.81 1U - 79BRS B EAV=52.9 6 - + 79BR 79SE B- DECAY (3.56E5 Y) + 79BR H TYP=FUL$AUT=M.-M.BE$CUT=30-JAN-2006$ + 79BR T Auger electrons and X ray energies and emission intensities: + 79BR T {U Energy (keV)} {U Intensity} {U Line} + 79BR T + 79BR T 11.8778 XKA2 + 79BR T 11.9244 XKA1 + 79BR T + 79BR T 13.2847 |] XKB3 + 79BR T 13.2916 |] XKB1 + 79BR T 13.396 |] XKB5II + 79BR T + 79BR T 13.4696 |] XKB2 + 79BR T + 79SE P 0.0 7/2+ 3.56E5 Y 40 150.9 17 + 79BR N 1.0 1.0 1 1.0 + 79BR L 0 3/2- STABLE + 79BR B 150.9 17100 10.81 1U + 79BRS B EAV=52.9 6 + diff --git a/HEN_HOUSE/spectra/lnhb/Sm-151.txt b/HEN_HOUSE/spectra/lnhb/Sm-151.txt index e23e483f6..c562861cd 100644 --- a/HEN_HOUSE/spectra/lnhb/Sm-151.txt +++ b/HEN_HOUSE/spectra/lnhb/Sm-151.txt @@ -1,43 +1,43 @@ -151EU 151SM B- DECAY (94.7 Y) -151EU H TYP=Full$AUT=M.M. Bé$CUT=30-NOV-2014$ -151EU C Evaluation history: Type=Full;Author=M.M. Bé;Cutoff date=30-NOV-2014 -151EU C References: 1950In01, 1952Ru10, 1952Ka26, 1955Me52, 1959Ac28, 1965Fl02, -151EU2C 1966Av05, 1968Re04, 1968Gr25, 1970Fo02, 1970An17, 1971Ca44, 1975La20, -151EU3C 1975Fr01, 1977Ve01, 1980La02, 1981Ar17, 1981Un02, 2008Ki07, 2009He22, -151EU4C 2012Wa38, 2015Bé** -151EU T Auger electrons and X ray energies and emission intensities: -151EU T {U Energy (keV)} {U Intensity} {U Line} -151EU T -151EU T 40.9024 XKA2 -151EU T 41.5427 XKA1 -151EU T -151EU T 46.904 |] XKB3 -151EU T 47.0384 |] XKB1 -151EU T 47.373 |] XKB5II -151EU T -151EU T 48.257 |] XKB2 -151EU T 48.386 |] XKB4 -151EU T 48.497 |] XKO23 -151EU T -151EU T 5.175-7.791 0.121 4 XL (total) -151EU T 5.175 0.00140 7 XLL -151EU T 5.815-5.846 0.0343 15 XLA -151EU T 5.815 0.00074 4 XLC -151EU T 6.436-6.839 0.0695 19 XLB -151EU T 7.254-7.791 0.0154 4 XLG -151EU T -151EU T 32.241-34.378 |] KLL AUGER -151EU T 38.592-41.52 |] KLX AUGER -151EU T 44.92-48.48 |] KXY AUGER -151EU T 3.377-7.786 0.581 19 L AUGER -151SM P 0.0 5/2- 94.7 Y 6 76.4 5 -151EU N 1.0 1.0 1 1.0 -151EU L 0 5/2+ STABLE -151EU B 76.4 5 99.07 4 9 -151EUS B EAV=19.7 2 -151EU L 21.541 3 7/2+ 9.6 NS 3 -151EU B 54.9 5 0.93 4 7.5 1 -151EUS B EAV=14.0 2 -151EU G 21.541 3 0.0324 13M1+()E2 0.029 2 27.6 5 -151EU2 G LC=21.7 4$MC=4.71 8 - +151EU 151SM B- DECAY (94.7 Y) +151EU H TYP=FUL$AUT=M.-M.BE$CUT=30-NOV-2014$ +151EU C References:1950In01, 1952Ru10, 1952Ka26, 1955Me52, 1959Ac28, 1965Fl02, +151EU2C 1966Av05, 1968Re04, 1968Gr25, 1970Fo02, 1970An17, 1971Ca44, 1975La20, +151EU3C 1975Fr01, 1977Ve01, 1980La02, 1981Ar17, 1981Un02, 2008Ki07, 2009He22, +151EU4C 2012Wa38, 2015Be** +151EU T Auger electrons and X ray energies and emission intensities: +151EU T {U Energy (keV)} {U Intensity} {U Line} +151EU T +151EU T 40.9024 XKA2 +151EU T 41.5427 XKA1 +151EU T +151EU T 46.904 |] XKB3 +151EU T 47.0384 |] XKB1 +151EU T 47.373 |] XKB5II +151EU T +151EU T 48.257 |] XKB2 +151EU T 48.386 |] XKB4 +151EU T 48.497 |] XKO23 +151EU T +151EU T 5.175-7.791 0.121 4 XL (total) +151EU T 5.175 0.00140 7 XLL +151EU T 5.815-5.846 0.0343 15 XLA +151EU T 5.815 0.00074 4 XLC +151EU T 6.436-6.839 0.0695 19 XLB +151EU T 7.254-7.791 0.0154 4 XLG +151EU T +151EU T 32.241-34.378 |] KLL AUGER +151EU T 38.592-41.52 |] KLX AUGER +151EU T 44.92-48.48 |] KXY AUGER +151EU T 3.377-7.786 0.581 19 L AUGER +151SM P 0.0 5/2- 94.7 Y 6 76.4 5 +151EU N 1.0 1.0 1 1.0 +151EU L 0 5/2+ STABLE +151EU B 76.4 5 99.07 4 9 +151EUS B EAV=19.7 2 +151EU L 21.541 3 7/2+ 9.6 NS 3 +151EU B 54.9 5 0.93 4 7.5 1 +151EUS B EAV=14.0 2 +151EU G 21.541 3 0.0324 13M1+E2 0.029 2 27.6 5 +151EU2 G LC=21.7 4$MC=4.71 8$NC=1.074 18 +151EU3 G OC=0.168 3 + diff --git a/HEN_HOUSE/spectra/lnhb/Sm-153.txt b/HEN_HOUSE/spectra/lnhb/Sm-153.txt index e3a43a742..d5c9e538b 100644 --- a/HEN_HOUSE/spectra/lnhb/Sm-153.txt +++ b/HEN_HOUSE/spectra/lnhb/Sm-153.txt @@ -1,168 +1,181 @@ -153EU 153SM B- DECAY (1.92855 D) -153EU H TYP=Update$AUT=mmbe$CUT= -- $ -153EU2 H TYP=Update$AUT=mmbe$CUT= -- $ -153EU3 H TYP=Full$AUT=mmbe$CUT=01-JUN-2005$ -153EU C Evaluation history: Type=Update;Author=mmbe;Cutoff date= -- -153EU2C Type=Update;Author=mmbe;Cutoff date= -- -153EU3C Type=Full;Author=mmbe;Cutoff date=01-JUN-2005 -153EU T Auger electrons and X ray energies and emission intensities: -153EU T {U Energy (keV)} {U Intensity} {U Line} -153EU T -153EU T 40.9024 16.6 4 XKA2 -153EU T 41.5427 30.0 7 XKA1 -153EU T -153EU T 46.904 |] XKB3 -153EU T 47.0384 |] 9.45 25 XKB1 -153EU T 47.373 |] XKB5II -153EU T -153EU T 48.257 |] XKB2 -153EU T 48.386 |] 2.44 8 XKB4 -153EU T 48.497 |] XKO23 -153EU T -153EU T 5.175-7.791 10.88 21 XL (total) -153EU T 5.175 0.213 7 XLL -153EU T 5.815-5.8461 5.20 15 XLA -153EU T 5.8149 0.0825 25 XLC -153EU T 6.4365-6.9193 4.63 10 XLB -153EU T 7.2538-7.791 0.755 17 XLG -153EU T -153EU T 32.24-34.38 |] KLL AUGER -153EU T 38.59-41.52 |] 4.47 28 KLX AUGER -153EU T 44.9-48.5 |] KXY AUGER -153EU T 3.4-7.8 53.0 5 L AUGER -153SM P 0.0 3/2+ 1.92855 D 5 807.6 7 -153EU N 1.0 1.0 1 1.0 -153EU L 0 0 5/2+ STABLE -153EU B 807.6 7 19.5 15 7.3 -153EUS B EAV=264.3 3 -153EU L 83.36720 177/2+ -153EU G 83.36717 210.193 6M1+E2 0.81 4 3.74 11 -153EU2 G KC=2.30 7$LC=1.119 34$MC=0.258 8 -153EU L 97.43103 175/2- -153EU B 710.2 7 0.62 8 8.6 1 -153EUS B EAV=227.4 3 -153EU G 14.06383 24 E1 10.78 32 -153EU2 G LC=8.43 25$MC=1.90 6 -153EU G 97.43100 210.767 14E1 0.302 9 -153EU2 G KC=0.254 8$LC=0.0382 11$MC=0.00823 25 -153EU L 103.18016 133/2+ 3.8 NS -153EU B 704.7 7 49.2 17 6.7 -153EUS B EAV=225.3 3 -153EU G 19.81296 210.00010522E2 3.22E3 10 -153EU2 G LC=2490 70$MC=578 17 -153EU G 103.18012 1729.19 16M1+E2 0.119 3 1.69 5 -153EU2 G KC=1.417 43$LC=0.213 6$MC=0.0462 14 -153EU L 151.6257 5 7/2- -153EU B 656.0 7 0.042 8 10 1U -153EUS B EAV=221.2 3 -153EU G 54.1936 120.0019 4M1+E2 18.2 5 -153EU2 G KC=6.19 19$LC=9.30 28$MC=2.17 7 -153EU G 68.2574 120.0013 4E1 0.781 23 -153EU2 G KC=0.648 19$LC=0.1040 31$MC=0.0225 7 -153EU G 151.6244 120.01033 27E1 0.0916 27 -153EU2 G KC=0.0775 23$LC=0.01112 33$MC=0.00239 7 -153EU L 172.85320 135/2+ 0.14 NS -153EU B 634.7 7 30.4 8 6.7 -153EUS B EAV=199.7 3 -153EU G 69.67300 134.691 41M1+E2 0.136 4 5.28 16 -153EU2 G KC=4.37 13$LC=0.719 22$MC=0.1571 47 -153EU G 75.42213 230.169 7E1+M2 0.055 10 0.752 23 -153EU2 G KC=0.610 18$LC=0.1111 33$MC=0.0245 7 -153EU G 89.48595 220.158 15M1+E2 0.25 10 2.59 8 -153EU2 G KC=2.10 6$LC=0.383 11$MC=0.0845 25 -153EU G 172.85307 210.0736 21M1+E2 0.81 8 0.375 11 -153EU2 G KC=0.293 9$LC=0.0638 19$MC=0.01427 43 -153EU L 269.7370 7 7/2+ -153EU B 537.8 7 0.0216 3 11 2 -153EUS B EAV=164.7 3 -153EU G 96.8824 7 0.007 1M1+E2 2.35 10 -153EU2 G KC=1.475 44$LC=0.68 2$MC=0.1570 47 -153EU G 118.1105 100.00023 6[E1] 0.180 5 -153EU2 G KC=0.1516 45$LC=0.0223 7$MC=0.00479 14 -153EU G 166.5546 150.00061 6[E2] 0.396 12 -153EU2 G KC=0.263 8$LC=0.1034 31$MC=0.0238 7 -153EU G 172.3032 130.0004 (E1) 0.065 2 -153EU2 G KC=0.0551 17$LC=0.00782 23$MC=0.00168 5 -153EU L 585.02 15 + -153EU B 222.6 8 0.00227 5 9.4 -153EUS B EAV=61.3 3 -153EU G 412.05 200.00191 5 -153EU G 487.75 230.00036 -153EU L 634.59 6 1/2+ -153EU B 172.9 8 0.0565 7 7.6 -153EUS B EAV=46.7 2 -153EU G 462.00 300.00158 26 -153EU G 531.40 150.0544 7 -153EU G 634.80 300.00050 3 -153EU L 636.522 183/2- -153EU B 171.1 7 0.0648 6 7.5 -153EUS B EAV=46.1 2 -153EU G 463.60 200.01270 24 -153EU G 533.20 200.0294 5 -153EU G 539.10 200.02070 21 -153EU G 636.50 200.00195 7 -153EU L 657.67 14 + -153EU B 149.9 8 0.00090 6 9.3 -153EUS B EAV=40.1 2 -153EU G 485.00 200.00038 3 -153EU G 574.10 300.00016 5 -153EU G 657.55 250.00037 2 -153EU L 681.88 8 5/2- -153EU B 125.7 7 0.0085 6 7.9 1 -153EUS B EAV=33.2 2 -153EU G 509.15 200.00190 18 -153EU G 578.75 200.0034 5 -153EU G 584.55 200.00107 3 -153EU G 598.54 100.0020 1 -153EU G 682.0 6 0.00015 12 -153EU L 694.180 235/2+ -153EU B 113.4 7 0.0221 8 7.4 -153EUS B EAV=29.8 2 -153EU G 424.40 300.00195 6 -153EU G 521.30 250.0067 1 -153EU G 542.70 200.00234 10 -153EU G 590.96 200.00122 9 -153EU G 596.70 200.0099 8 -153EU G 694.10 300.000020 6 -153EU L 701.46 24 + -153EU B 106.1 8 0.0076 6 8.8 -153EUS B EAV=27.8 2 -153EU G 598.30 300.0020 1 -153EU G 604.03 240.0049 6 -153EU G 617.90 300.00067 6 -153EU G 701.80 400.000029 6 -153EU L 706.622 235/2+ -153EU B 101.0 8 0.0241 7 7.3 -153EUS B EAV=26.4 3 -153EU G 436.9 3 0.00158 5 -153EU G 554.94 100.0047 1 -153EU G 603.6 4 0.0049 6 -153EU G 609.5 3 0.0129 4 -153EU G 706.8 5 0.00002312 -153EU L 713.12 20 + -153EU B 94.5 8 0.0141 5 7.4 -153EUS B EAV=24.6 2 -153EU G 443.2 5 0.00041 32 -153EU G 609.95 200.0129 4 -153EU G 615.80 400.00050 6 -153EU G 630.50 400.00009915 -153EU G 713.9 3 0.00023120 -153EU L 718.69 143/2+ -153EU B 88.9 8 0.00143 10 8.4 -153EUS B EAV=23.1 2 -153EU G 545.75 150.0009 1 -153EU G 615.51 140.00050 6 -153EU G 719.00 400.000025 5 -153EU L 760.39 17 + -153EU B 47.2 8 0.00098 5 7.9 -153EUS B EAV=12.0 2 -153EU G 587.60 250.00048 4 -153EU G 657.21 7 0.00037 2 -153EU G 662.4 6 0.00007 7 -153EU G 677.00 300.00004415 -153EU G 760.50 400.000032 5 -153EU L 763.8 6 + -153EU B 44.0 7 0.00004412 8.9 -153EUS B EAV=11.1 3 -153EU G 763.8 6 0.00004412 - +153EU 153SM B- DECAY (1.92855 D) +153EU H TYP=UPD$AUT=M.-M.BE$CUT=30-MAR-2006$ +153EU2 H TYP=UPD$AUT=M.-M.BE$CUT=12-JAN-2006$ +153EU3 H TYP=FUL$AUT=M.-M.BE$CUT=01-JUN-2005$ +153EU T Auger electrons and X ray energies and emission intensities: +153EU T {U Energy (keV)} {U Intensity} {U Line} +153EU T +153EU T 40.9024 16.6 4 XKA2 +153EU T 41.5427 30.0 7 XKA1 +153EU T +153EU T 46.904 |] XKB3 +153EU T 47.0384 |] 9.45 25 XKB1 +153EU T 47.373 |] XKB5II +153EU T +153EU T 48.257 |] XKB2 +153EU T 48.386 |] 2.44 8 XKB4 +153EU T 48.497 |] XKO23 +153EU T +153EU T 5.175-7.791 10.88 21 XL (total) +153EU T 5.175 0.213 7 XLL +153EU T 5.815-5.8461 5.20 15 XLA +153EU T 5.8149 0.0825 25 XLC +153EU T 6.4365-6.9193 4.63 10 XLB +153EU T 7.2538-7.791 0.755 17 XLG +153EU T +153EU T 32.24-34.38 |] KLL AUGER +153EU T 38.59-41.52 |] 4.47 28 KLX AUGER +153EU T 44.9-48.5 |] KXY AUGER +153EU T 3.4-7.8 53.0 5 L AUGER +153SM P 0.0 3/2+ 1.92855 D 5 807.6 7 +153EU N 1.0 1.0 1 1.0 +153EU L 0 5/2+ STABLE +153EU B 807.6 7 19.5 15 7.3 +153EUS B EAV=264.3 3 +153EU L 83.36720 177/2+ +153EU G 83.36717 210.193 6M1+E2 0.81 4 3.74 11 +153EU2 G KC=2.30 7$LC=1.119 34$MC=0.258 8$NC=0.0576 17 +153EU3 G OC=0.00804 24 +153EU L 97.43103 175/2- +153EU B 710.2 7 0.62 8 8.6 1 +153EUS B EAV=227.4 3 +153EU G 14.06383 24 E1 10.78 32 +153EU2 G LC=8.43 25$MC=1.90 6$NC=0.404 12 +153EU3 G OC=0.0478 14 +153EU G 97.43100 210.767 14E1 0.302 9 +153EU2 G KC=0.254 8$LC=0.0382 11$MC=0.00823 25$NC=0.00185 6 +153EU3 G OC=0.000278 8 +153EU L 103.18016 133/2+ 3.8 NS +153EU B 704.7 7 49.2 17 6.7 +153EUS B EAV=225.3 3 +153EU G 19.81296 210.00010522E2 3.22E3 10 +153EU2 G LC=2490 70$MC=578 17$NC=127.1 38 +153EU3 G OC=16.7 5 +153EU G 103.18012 1729.19 16M1+E2 0.119 3 1.69 5 +153EU2 G KC=1.417 43$LC=0.213 6$MC=0.0462 14$NC=0.01057 32 +153EU3 G OC=0.00166 5 +153EU L 151.6257 5 7/2- +153EU B 656.0 7 0.042 8 10 1U +153EUS B EAV=221.2 3 +153EU G 54.1936 120.0019 4M1+E2 18.2 5 +153EU2 G KC=6.19 19$LC=9.30 28$MC=2.17 7$NC=0.481 14 +153EU3 G OC=0.0649 19 +153EU G 68.2574 120.0013 4E1 0.781 23 +153EU2 G KC=0.648 19$LC=0.1040 31$MC=0.0225 7$NC=0.00503 15 +153EU3 G OC=0.000739 22 +153EU G 151.6244 120.01033 27E1 0.0916 27 +153EU2 G KC=0.0775 23$LC=0.01112 33$MC=0.00239 7$NC=0.000541 16 +153EU3 G OC=8.26E-5 25 +153EU L 172.85320 135/2+ 0.14 NS +153EU B 634.7 7 30.4 8 6.7 +153EUS B EAV=199.7 3 +153EU G 69.67300 134.691 41M1+E2 0.136 4 5.28 16 +153EU2 G KC=4.37 13$LC=0.719 22$MC=0.1571 47$NC=0.0358 11 +153EU3 G OC=0.00555 17 +153EU G 75.42213 230.169 7E1+M2 0.055 10 0.752 23 +153EU2 G KC=0.610 18$LC=0.1111 33$MC=0.0245 7$NC=0.00555 17 +153EU3 G OC=0.000830 25 +153EU G 89.48595 220.158 15M1+E2 0.25 10 2.59 8 +153EU2 G KC=2.10 6$LC=0.383 11$MC=0.0845 25$NC=0.0192 6 +153EU3 G OC=0.00293 9 +153EU G 172.85307 210.0736 21M1+E2 0.81 8 0.375 11 +153EU2 G KC=0.293 9$LC=0.0638 19$MC=0.01427 43$NC=0.00322 10 +153EU3 G OC=0.000478 14 +153EU L 269.7370 7 7/2+ +153EU B 537.8 7 0.0216 3 11 2 +153EUS B EAV=164.7 3 +153EU G 96.8824 7 0.007 1M1+E2 2.35 10 +153EU2 G KC=1.475 44$LC=0.68 2$MC=0.1570 47$NC=0.0350 11 +153EU3 G OC=0.00489 15 +153EU G 118.1105 100.00023 6[E1] 0.180 5 +153EU2 G KC=0.1516 45$LC=0.0223 7$MC=0.00479 14$NC=0.001081 32 +153EU3 G OC=1.636E-4 49 +153EU G 166.5546 150.00061 6[E2] 0.396 12 +153EU2 G KC=0.263 8$LC=0.1034 31$MC=0.0238 7$NC=0.00531 16 +153EU3 G OC=0.000745 22 +153EU G 172.3032 130.0004 (E1) 0.065 2 +153EU2 G KC=0.0551 17$LC=0.00782 23$MC=0.00168 5$NC=0.000381 11 +153EU3 G OC=5.84E-5 18 +153EU L 585.02 15 +153EU B 222.6 8 0.00227 5 9.4 +153EUS B EAV=61.3 3 +153EU G 412.05 200.00191 5 +153EU G 487.75 230.00036 +153EU L 634.59 6 1/2+ +153EU B 172.9 8 0.0565 7 7.6 +153EUS B EAV=46.7 2 +153EU G 462.00 300.00158 26 +153EU G 531.40 150.0544 7 +153EU G 634.80 300.00050 3 +153EU L 636.522 183/2- +153EU B 171.1 7 0.0648 6 7.5 +153EUS B EAV=46.1 2 +153EU G 463.60 200.01270 24 +153EU G 533.20 200.0294 5 +153EU G 539.10 200.02070 21 +153EU G 636.50 200.00195 7 +153EU L 657.67 14 +153EU B 149.9 8 0.00090 6 9.3 +153EUS B EAV=40.1 2 +153EU G 485.00 200.00038 3 +153EU G 574.10 300.00016 5 +153EU G 657.55 250.00037 2 +153EU L 681.88 8 5/2- +153EU B 125.7 7 0.0085 6 7.9 1 +153EUS B EAV=33.2 2 +153EU G 509.15 200.00190 18 +153EU G 578.75 200.0034 5 +153EU G 584.55 200.00107 3 +153EU G 598.54 100.0020 1 +153EU G 682.0 6 0.00015 12 +153EU L 694.180 235/2+ +153EU B 113.4 7 0.0221 8 7.4 +153EUS B EAV=29.8 2 +153EU G 424.40 300.00195 6 +153EU G 521.30 250.0067 1 +153EU G 542.70 200.00234 10 +153EU G 590.96 200.00122 9 +153EU G 596.70 200.0099 8 +153EU G 694.10 300.000020 6 +153EU L 701.46 24 +153EU B 106.1 8 0.0076 6 8.8 +153EUS B EAV=27.8 2 +153EU G 598.30 300.0020 1 +153EU G 604.03 240.0049 6 +153EU G 617.90 300.00067 6 +153EU G 701.80 400.000029 6 +153EU L 706.622 235/2+ +153EU B 101.0 8 0.0241 7 7.3 +153EUS B EAV=26.4 3 +153EU G 436.9 3 0.00158 5 +153EU G 554.94 100.0047 1 +153EU G 603.6 4 0.0049 6 +153EU G 609.5 3 0.0129 4 +153EU G 706.8 5 0.00002312 +153EU L 713.12 20 +153EU B 94.5 8 0.0141 5 7.4 +153EUS B EAV=24.6 2 +153EU G 443.2 5 0.00041 32 +153EU G 609.95 200.0129 4 +153EU G 615.80 400.00050 6 +153EU G 630.50 400.00009915 +153EU G 713.9 3 0.00023120 +153EU L 718.69 143/2+ +153EU B 88.9 8 0.00143 10 8.4 +153EUS B EAV=23.1 2 +153EU G 545.75 150.0009 1 +153EU G 615.51 140.00050 6 +153EU G 719.00 400.000025 5 +153EU L 760.39 17 +153EU B 47.2 8 0.00098 5 7.9 +153EUS B EAV=12.0 2 +153EU G 587.60 250.00048 4 +153EU G 657.21 7 0.00037 2 +153EU G 662.4 6 0.00007 7 +153EU G 677.00 300.00004415 +153EU G 760.50 400.000032 5 +153EU L 763.8 6 +153EU B 44.0 7 0.00004412 8.9 +153EUS B EAV=11.1 3 +153EU G 763.8 6 0.00004412 + diff --git a/HEN_HOUSE/spectra/lnhb/Sn-113.txt b/HEN_HOUSE/spectra/lnhb/Sn-113.txt index a5c35a251..c376e54cc 100644 --- a/HEN_HOUSE/spectra/lnhb/Sn-113.txt +++ b/HEN_HOUSE/spectra/lnhb/Sn-113.txt @@ -1,51 +1,50 @@ -113IN 113SN EC DECAY (115.09 D) -113IN H TYP=Upadte$AUT=M.M. Bé$CUT= -- $ -113IN2 H TYP=Full$AUT=R.G.Helmer$CUT= -- $ -113IN C Evaluation history: Type=Upadte;Author=M.M. Bé;Cutoff date= -- -113IN2C Type=Full;Author=R.G.Helmer;Cutoff date= -- -113IN C References: 1961Gr11, 1993Mu14, 1994DeZX -113IN T Auger electrons and X ray energies and emission intensities: -113IN T {U Energy (keV)} {U Intensity} {U Line} -113IN T -113IN T 24.0023 27.69 21 XKA2 -113IN T 24.21 51.9 3 XKA1 -113IN T -113IN T 27.238 |] XKB3 -113IN T 27.2762 |] 14.58 17 XKB1 -113IN T 27.495 |] XKB5II -113IN T -113IN T 27.861 |] XKB2 -113IN T 27.928 |] 2.77 10 XKB4 -113IN T 27.939 |] XKO23 -113IN T -113IN T 2.9-4.16 8.48 19 XL (total) -113IN T 2.9 0.183 7 XLL -113IN T 3.28-3.29 4.90 15 XLA -113IN T 3.11 0.0621 14 XLC -113IN T 3.49-3.79 3.01 6 XLB -113IN T 3.82-4.16 0.330 7 XLG -113IN T -113IN T 19.34-20.35 |] KLL AUGER -113IN T 22.83-24.19 |] 17.0 5 KLX AUGER -113IN T 26.25-27.9 |] KXY AUGER -113IN T 2-4.2 116.3 6 L AUGER -113SN P 0.0 1/2+ 115.09 D 3 1036.0 28 -113IN N 1.0 1.0 1 1.0 -113IN L 0 9/2+ STABLE -113IN L 391.699 3 1/2- 1.6579 H 38 -113IN E 97.79 87.01 -113IN2 E CK=0.855 1$CL=0.116 1$CM=0.0241 5 -113IN G 391.698 3 64.97 17M4 0.540 4 -113IN2 G KC=0.437 4$LC=0.0858 26$MC=0.0170 5 -113IN L 646.833 103/2-+ -113IN E 2.21 88.2 -113IN2 E CK=0.8490 14$CL=0.121 1$CM=0.0254 5 -113IN G 255.134 102.11 8M1+E2 0.0464 14 -113IN2 G KC=0.0396 12$LC=0.00549 16$MC=1078E-6 32 -113IN G 646.83 1 0.000004 2[E3] -113IN L 1029.73 8 1/2,3/2+ 0.33 NS -113IN E 0.00103 46.5 -113IN2 E CL=0.3 3$CM=0.54 20 -113IN G 382.90 8 0.000060 3 -113IN G 638.03 8 0.00097 4 - +113IN 113SN EC DECAY (115.09 D) +113IN H TYP=UPD$AUT=M.-M.BE$CUT=17-FEB-2004$ +113IN2 H TYP=FUL$AUT=R.G.HELMER$CUT=30-JUN-1998$ +113IN C References:1961Gr11, 1993Mu14, 1994DeZX +113IN T Auger electrons and X ray energies and emission intensities: +113IN T {U Energy (keV)} {U Intensity} {U Line} +113IN T +113IN T 24.0023 27.69 21 XKA2 +113IN T 24.21 51.9 3 XKA1 +113IN T +113IN T 27.238 |] XKB3 +113IN T 27.2762 |] 14.58 17 XKB1 +113IN T 27.495 |] XKB5II +113IN T +113IN T 27.861 |] XKB2 +113IN T 27.928 |] 2.77 10 XKB4 +113IN T 27.939 |] XKO23 +113IN T +113IN T 2.9-4.16 8.48 19 XL (total) +113IN T 2.9 0.183 7 XLL +113IN T 3.28-3.29 4.90 15 XLA +113IN T 3.11 0.0621 14 XLC +113IN T 3.49-3.79 3.01 6 XLB +113IN T 3.82-4.16 0.330 7 XLG +113IN T +113IN T 19.34-20.35 |] KLL AUGER +113IN T 22.83-24.19 |] 17.0 5 KLX AUGER +113IN T 26.25-27.9 |] KXY AUGER +113IN T 2-4.2 116.3 6 L AUGER +113SN P 0.0 1/2+ 115.09 D 3 1036.0 28 +113IN N 1.0 1.0 1 1.0 +113IN L 0 9/2+ STABLE +113IN L 391.699 3 1/2- 1.6579 H 38 +113IN E 97.79 87.01 +113IN2 E CK=0.855 1$CL=0.116 1$CM=0.0241 5 +113IN G 391.698 3 64.97 17M4 0.540 4 +113IN2 G KC=0.437 4$LC=0.0858 26$MC=0.0170 5$NC=0.00377 11 +113IN L 646.833 103/2- +113IN E 2.21 88.2 +113IN2 E CK=0.8490 14$CL=0.121 1$CM=0.0254 5 +113IN G 255.134 102.11 8M1+E2 0.0464 14 +113IN2 G KC=0.0396 12$LC=0.00549 16$MC=0.001078 32$NC=0.000211 6 +113IN3 G OC=1.79E-5 5 +113IN G 646.83 1 0.000004 2[E3] +113IN L 1029.73 8 1/2,3/2+ 0.33 NS +113IN E 0.00103 46.5 +113IN2 E CL=0.3 3$CM=0.54 20 +113IN G 382.90 8 0.000060 3 +113IN G 638.03 8 0.00097 4 + diff --git a/HEN_HOUSE/spectra/lnhb/Sr-82.txt b/HEN_HOUSE/spectra/lnhb/Sr-82.txt index 5c1c0a7e9..bf1e2562d 100644 --- a/HEN_HOUSE/spectra/lnhb/Sr-82.txt +++ b/HEN_HOUSE/spectra/lnhb/Sr-82.txt @@ -1,35 +1,34 @@ - 82RB 82SR EC DECAY (25.347 D) - 82RB H TYP=FuLL$AUT=M.M. Bé$CUT=01-DEC-2014$ - 82RB C Evaluation history: Type=FuLL;Author=M.M. Bé;Cutoff date=01-DEC-2014 - 82RB C References: 1953Li27, 1953Kr10, 1958Sa20, 1978Gr17, 1987Ju02, 1987Ho06, - 82RB2C 1996Sc06, 1998Sc28, 2000Sc47, 2009Pi02, 2012Wa38 - 82RB T Auger electrons and X ray energies and emission intensities: - 82RB T {U Energy (keV)} {U Intensity} {U Line} - 82RB T - 82RB T 13.3359 16.79 14 XKA2 - 82RB T 13.3955 32.32 22 XKA1 - 82RB T - 82RB T 14.9519 |] XKB3 - 82RB T 14.9614 |] 7.87 9 XKB1 - 82RB T 15.085 |] XKB5II - 82RB T - 82RB T 15.1856 |] XKB2 - 82RB T 15.205 |] 0.91 4 XKB4 - 82RB T - 82RB T 1.484-2.051 2.52 5 XL (total) - 82RB T 1.484 0.0619 17 XLL - 82RB T 1.693-1.695 1.56 4 XLA - 82RB T 1.543 0.0272 8 XLC - 82RB T 1.752-1.954 0.855 21 XLB - 82RB T 1.831-2.051 0.01242 27 XLG - 82RB T - 82RB T 10.987-11.503 |] KLL AUGER - 82RB T 12.782-13.381 |] 28.0 4 KLX AUGER - 82RB T 14.556-15.172 |] KXY AUGER - 82RB T 1.16-2.05 105.7 5 L AUGER - 82SR P 0.0 0+ 25.347 D 17 178 7 - 82RB N 1.0 1.0 1 1.0 - 82RB L 0 1+ STABLE - 82RB E 100 4.7 - 82RB2 E CK=0.859 2$CL=0.116 2$CM=0.022 1$CN=0.0031 2 - + 82RB 82SR EC DECAY (25.347 D) + 82RB H TYP=FUL$AUT=M.-M.BE$CUT=01-DEC-2014$ + 82RB C References:1953Li27, 1953Kr10, 1958Sa20, 1978Gr17, 1987Ju02, 1987Ho06, + 82RB2C 1996Sc06, 1998Sc28, 2000Sc47, 2009Pi02, 2012Wa38 + 82RB T Auger electrons and X ray energies and emission intensities: + 82RB T {U Energy (keV)} {U Intensity} {U Line} + 82RB T + 82RB T 13.3359 16.79 14 XKA2 + 82RB T 13.3955 32.32 22 XKA1 + 82RB T + 82RB T 14.9519 |] XKB3 + 82RB T 14.9614 |] 7.87 9 XKB1 + 82RB T 15.085 |] XKB5II + 82RB T + 82RB T 15.1856 |] XKB2 + 82RB T 15.205 |] 0.91 4 XKB4 + 82RB T + 82RB T 1.484-2.051 2.52 5 XL (total) + 82RB T 1.484 0.0619 17 XLL + 82RB T 1.693-1.695 1.56 4 XLA + 82RB T 1.543 0.0272 8 XLC + 82RB T 1.752-1.954 0.855 21 XLB + 82RB T 1.831-2.051 0.01242 27 XLG + 82RB T + 82RB T 10.987-11.503 |] KLL AUGER + 82RB T 12.782-13.381 |] 28.0 4 KLX AUGER + 82RB T 14.556-15.172 |] KXY AUGER + 82RB T 1.16-2.05 105.7 5 L AUGER + 82SR P 0.0 0+ 25.347 D 17 178 7 + 82RB N 1.0 1.0 1 1.0 + 82RB L 0 1+ STABLE + 82RB E 100 4.7 + 82RB2 E CK=0.859 2$CL=0.116 2$CM=0.022 1$CN=0.0031 2 + diff --git a/HEN_HOUSE/spectra/lnhb/Sr-85.txt b/HEN_HOUSE/spectra/lnhb/Sr-85.txt index f011b6b07..0c75b16b6 100644 --- a/HEN_HOUSE/spectra/lnhb/Sr-85.txt +++ b/HEN_HOUSE/spectra/lnhb/Sr-85.txt @@ -1,56 +1,65 @@ - 85RB 85SR EC DECAY (64.850 D) - 85RB C References: 1977La19 - 85RB T Auger electrons and X ray energies and emission intensities: - 85RB T {U Energy (keV)} {U Intensity} {U Line} - 85RB T - 85RB T 13.3359 17.16 17 XKA2 - 85RB T 13.3955 33.04 29 XKA1 - 85RB T - 85RB T 14.9519 |] XKB3 - 85RB T 14.9614 |] 8.04 10 XKB1 - 85RB T 15.085 |] XKB5II - 85RB T - 85RB T 15.1856 |] XKB2 - 85RB T 15.205 |] 0.93 4 XKB4 - 85RB T - 85RB T 1.48-2.05 2.30 5 XL (total) - 85RB T 1.48 0.0559 16 XLL - 85RB T - 1.41 4 XLA - 85RB T 0.0264 7 XLC - 85RB T - 0.800 21 XLB - 85RB T -2.05 0.00801 18 XLG - 85RB T - 85RB T 10.987-11.503 |] KLL AUGER - 85RB T 12.782-13.381 |] 28.6 4 KLX AUGER - 85RB T 14.556-15.172 |] KXY AUGER - 85RB T 1.1-2 96.5 4 L AUGER - 85SR P 0.0 9/2+ 64.850 D 7 1065 3 - 85RB N 1.0 1.0 1 1.0 - 85RB L 0 5/2- STABLE - 85RB E 0.8 49.3 1U - 85RB2 E CK=0.85 3$CL=0.12 3$CM=0.03 1 - 85RB L 151.161 3/2- 0.71 NS 5 - 85RB E 0.0005 11.5 3 - 85RB G 151.160 6 0.0012 9M1+E2 0.0488 15 - 85RB2 G KC=0.0430 13$LC=0.00485 15$MC=8.17E-4 25 - 85RB L 280.986 1/2- 40 PS 3 - 85RB E 0.0005 11.8 3U - 85RB G 129.826 100.0005 (M1) 0.0721 22 - 85RB2 G KC=0.0635 19$LC=0.00717 21$MC=1208E-6 36 - 85RB L 514.007 9/2+ 1.015 US 1 - 85RB E 99.2 46.2 - 85RB2 E CK=0.8718 15$CL=0.1059 12$CM=0.0195 4 - 85RB G 362.847 6 0.0014 3(E3) 0.0339 10 - 85RB2 G KC=0.0292 9$LC=0.00397 12$MC=0.00067 2 - 85RB G 514.0048 2298.5 4M2 0.0072122 - 85RB2 G KC=0.00635 19$LC=7.22E-4 22$MC=1219E-7 37 - 85RB L 868.98 7/2- 2.5 PS 3 - 85RB E 0.0129 49.1 1 - 85RB2 E CK=0.8610 16$CL=0.1146 13$CM=0.0214 4 - 85RB G 354.97 5 0.0005 2(E1) 0.00253 8 - 85RB2 G KC=0.00225 7$LC=2.42E-4 7$MC=4.05E-5 12 - 85RB G 717.81 5 0.00032 3(E2) 0.00124 4 - 85RB2 G KC=0.00109 3$LC=1.20E-4 4$MC=2.02E-5 6 - 85RB G 868.98 5 0.0121 4M1+E2 0.00073 3 - 85RB2 G KC=0.00065 2$LC=7.0E-5 2$MC=1176E-8 35 - + 85RB 85SR EC DECAY (64.850 D) + 85RB C References:1977La19 + 85RB T Auger electrons and X ray energies and emission intensities: + 85RB T {U Energy (keV)} {U Intensity} {U Line} + 85RB T + 85RB T 13.3359 17.16 17 XKA2 + 85RB T 13.3955 33.04 29 XKA1 + 85RB T + 85RB T 14.9519 |] XKB3 + 85RB T 14.9614 |] 8.04 10 XKB1 + 85RB T 15.085 |] XKB5II + 85RB T + 85RB T 15.1856 |] XKB2 + 85RB T 15.205 |] 0.93 4 XKB4 + 85RB T + 85RB T 1.48-2.05 2.30 5 XL (total) + 85RB T 1.48 0.0559 16 XLL + 85RB T - 1.41 4 XLA + 85RB T 0.0264 7 XLC + 85RB T - 0.800 21 XLB + 85RB T -2.05 0.00801 18 XLG + 85RB T + 85RB T 10.987-11.503 |] KLL AUGER + 85RB T 12.782-13.381 |] 28.6 4 KLX AUGER + 85RB T 14.556-15.172 |] KXY AUGER + 85RB T 1.1-2 96.5 4 L AUGER + 85SR P 0.0 9/2+ 64.850 D 7 1065 3 + 85RB N 1.0 1.0 1 1.0 + 85RB L 0 5/2- STABLE + 85RB E 0.8 49.3 1U + 85RB2 E CK=0.8745 15$CL=0.1037 12$CM=0.0190 4$CN=0.0027 2 + 85RB L 151.161 3/2- 0.71 NS 5 + 85RB E 0.0005 11.5 3 + 85RB2 E CK=0.8740 15$CL=0.1041 12$CM=0.0191 4$CN=0.0027 2 + 85RB G 151.160 6 0.0012 9M1+E2 0.0488 15 + 85RB2 G KC=0.0430 13$LC=0.00485 15$MC=0.000817 25$NC=1.093E-4 33 + 85RB3 G OC=5.80E-6 17 + 85RB L 280.986 1/2- 40 PS 3 + 85RB E 0.0005 11.8 3U + 85RB2 E CK=0.8735 15$CL=0.1045 12$CM=0.0192 4$CN=0.0028 2 + 85RB G 129.826 100.0005 (M1) 0.0721 22 + 85RB2 G KC=0.0635 19$LC=0.00717 21$MC=0.001208 36$NC=1.616E-4 48 + 85RB3 G OC=8.60E-6 26 + 85RB L 514.007 9/2+ 1.015 US 1 + 85RB E 99.2 46.2 + 85RB2 E CK=0.8718 15$CL=0.1059 12$CM=0.0195 4$CN=0.0028 2 + 85RB G 362.847 6 0.0014 3(E3) 0.0339 10 + 85RB2 G KC=0.0292 9$LC=0.00397 12$MC=0.00067 2$NC=8.56E-5 26 + 85RB3 G OC=3.71E-6 11 + 85RB G 514.0048 2298.5 4M2 0.0072122 + 85RB2 G KC=0.00635 19$LC=0.000722 22$MC=1.219E-4 37$NC=1.634E-5 49 + 85RB3 G OC=8.77E-7 26 + 85RB L 868.98 7/2- 2.5 PS 3 + 85RB E 0.0129 49.1 1 + 85RB2 E CK=0.861 9$CL=0.114 7$CM=0.0213 14$CN=0.0031 3 + 85RB G 354.97 5 0.0005 2(E1) 0.00253 8 + 85RB2 G KC=0.00225 7$LC=0.000242 7$MC=4.05E-5 12$NC=5.42E-6 16 + 85RB3 G OC=2.89E-7 9 + 85RB G 717.81 5 0.00032 3(E2) 0.00124 4 + 85RB2 G KC=0.00109 3$LC=0.000120 4$MC=2.02E-5 6$NC=2.70E-6 8 + 85RB3 G OC=1.432E-7 43 + 85RB G 868.98 5 0.0121 4M1+E2 0.00073 3 + 85RB2 G KC=0.00065 2$LC=0.000070 2$MC=1.176E-5 35$NC=1.579E-6 47 + 85RB3 G OC=8.56E-8 26 + diff --git a/HEN_HOUSE/spectra/lnhb/Sr-89.txt b/HEN_HOUSE/spectra/lnhb/Sr-89.txt index c991f236e..f911a10eb 100644 --- a/HEN_HOUSE/spectra/lnhb/Sr-89.txt +++ b/HEN_HOUSE/spectra/lnhb/Sr-89.txt @@ -1,26 +1,26 @@ - 89Y 89SR B- DECAY (50.57 D) - 89Y C References: 1977La19 - 89Y T Auger electrons and X ray energies and emission intensities: - 89Y T {U Energy (keV)} {U Intensity} {U Line} - 89Y T - 89Y T 14.8829 XKA2 - 89Y T 14.9585 0.086 7 XKA1 - 89Y T - 89Y T 16.7259 |] XKB3 - 89Y T 16.7381 |] XKB1 - 89Y T 16.88 |] XKB5II - 89Y T - 89Y T 17.0156 |] XKB2 - 89Y T 17.0362 |] XKB4 - 89Y T - 89SR P 0.0 5/2+ 50.57 D 3 1495.1 22 - 89Y N 1.0 1.0 1 1.0 - 89Y L 0 1/2- STABLE - 89Y B 1495.1 2299.99036 4 9.4 1U - 89Y S B EAV=584.6 10 - 89Y L 909 9/2+ 16.05 S 4 - 89Y B 586.1 220.00964 6 11.1 2 - 89Y S B EAV=189.1 9 - 89Y G 909.0 1 0.00956 6(M4) 0.0085026 - 89Y 2 G KC=0.00746 23$LC=0.00091 3 - + 89Y 89SR B- DECAY (50.57 D) + 89Y C References:1977La19 + 89Y T Auger electrons and X ray energies and emission intensities: + 89Y T {U Energy (keV)} {U Intensity} {U Line} + 89Y T + 89Y T 14.8829 XKA2 + 89Y T 14.9585 0.086 7 XKA1 + 89Y T + 89Y T 16.7259 |] XKB3 + 89Y T 16.7381 |] XKB1 + 89Y T 16.88 |] XKB5II + 89Y T + 89Y T 17.0156 |] XKB2 + 89Y T 17.0362 |] XKB4 + 89Y T + 89SR P 0.0 5/2+ 50.57 D 3 1495.1 22 + 89Y N 1.0 1.0 1 1.0 + 89Y L 0 1/2- STABLE + 89Y B 1495.1 2299.99036 4 9.4 1U + 89Y S B EAV=584.6 10 + 89Y L 909 9/2+ 16.05 S 4 + 89Y B 586.1 220.00964 6 11.1 2 + 89Y S B EAV=189.1 9 + 89Y G 909.0 1 0.00956 6(M4) 0.0085026 + 89Y 2 G KC=0.00746 23$LC=0.00091 3 + diff --git a/HEN_HOUSE/spectra/lnhb/Sr-90.txt b/HEN_HOUSE/spectra/lnhb/Sr-90.txt index 22b90cc2a..ed12bafce 100644 --- a/HEN_HOUSE/spectra/lnhb/Sr-90.txt +++ b/HEN_HOUSE/spectra/lnhb/Sr-90.txt @@ -1,33 +1,32 @@ - 90Y 90SR B- DECAY (28.80 Y) - 90Y H TYP=Full$AUT=Chisté$CUT= -- $ - 90Y C Evaluation history: Type=Full;Author=Chisté;Cutoff date= -- - 90Y T Auger electrons and X ray energies and emission intensities: - 90Y T {U Energy (keV)} {U Intensity} {U Line} - 90Y T - 90Y T 14.883 XKA2 - 90Y T 14.9581 XKA1 - 90Y T - 90Y T 16.7268 |] XKB3 - 90Y T 16.7384 |] XKB1 - 90Y T 16.8792 |] XKB5II - 90Y T 16.8814 |] XKB5I - 90Y T - 90Y T 17.0137 |] XKB2 - 90Y T 17.0409 |] XKB4 - 90Y T - 90Y T 1.6865 XLL - 90Y T 1.9211-1.9233 XLA - 90Y T 1.7617 XLC - 90Y T 1.9962-2.0713 XLB - 90Y T 2.1118-2.3482 XLG - 90Y T - 90Y T 12.205-12.784 |] KLL AUGER - 90Y T 14.238-14.956 |] KLX AUGER - 90Y T 16.251-17.034 |] KXY AUGER - 90Y T 0.06-2.3677 L AUGER - 90SR P 0.0 0+ 28.80 Y 7 545.9 14 - 90Y N 1.0 1.0 1 1.0 - 90Y L 0 2- 2.6684 D 13 - 90Y B 545.9 14100 9.4 1U - 90Y S B EAV=195.7 5 - + 90Y 90SR B- DECAY (28.80 Y) + 90Y H TYP=FUL$AUT=V.CHISTE$CUT=09-NOV-2005$ + 90Y T Auger electrons and X ray energies and emission intensities: + 90Y T {U Energy (keV)} {U Intensity} {U Line} + 90Y T + 90Y T 14.883 XKA2 + 90Y T 14.9581 XKA1 + 90Y T + 90Y T 16.7268 |] XKB3 + 90Y T 16.7384 |] XKB1 + 90Y T 16.8792 |] XKB5II + 90Y T 16.8814 |] XKB5I + 90Y T + 90Y T 17.0137 |] XKB2 + 90Y T 17.0409 |] XKB4 + 90Y T + 90Y T 1.6865 XLL + 90Y T 1.9211-1.9233 XLA + 90Y T 1.7617 XLC + 90Y T 1.9962-2.0713 XLB + 90Y T 2.1118-2.3482 XLG + 90Y T + 90Y T 12.205-12.784 |] KLL AUGER + 90Y T 14.238-14.956 |] KLX AUGER + 90Y T 16.251-17.034 |] KXY AUGER + 90Y T 0.06-2.3677 L AUGER + 90SR P 0.0 0+ 28.80 Y 7 545.9 14 + 90Y N 1.0 1.0 1 1.0 + 90Y L 0 2- 2.6684 D 13 + 90Y B 545.9 14100 9.4 1U + 90Y S B EAV=195.7 5 + diff --git a/HEN_HOUSE/spectra/lnhb/Ta-182.txt b/HEN_HOUSE/spectra/lnhb/Ta-182.txt index d1965cd4b..c04563e2a 100644 --- a/HEN_HOUSE/spectra/lnhb/Ta-182.txt +++ b/HEN_HOUSE/spectra/lnhb/Ta-182.txt @@ -1,164 +1,204 @@ -182W 182TA B- DECAY (114.61 D) -182W H TYP=Full$AUT=V.Chisté$CUT=30-SEP-2010$ -182W 2 H TYP=update$AUT=v. chisté$CUT= -- $ -182W C Evaluation history: Type=Full;Author=V.Chisté;Cutoff date=30-SEP-2010 -182W 2C Type=update;Author=v. chisté;Cutoff date= -- -182W C References: 1943Zu**, 1947Se33, 1948Me**, 1951Si25, 1952Ei12, 1957Wr37, -182W 2C 1958Ke26, 1958Sp17, 1959Vo27, 1960Gv01, 1961Ry03, 1961Vi07, 1961Vo05, -182W 3C 1964Ba12, 1964Da15, 1964Ba47, 1965He07, 1965Ed01, 1966Dz01, 1966Ko12, -182W 4C 1966Gr21, 1967Ni03, 1967Wa29, 1969Wh03, 1969Sa15, 1969Ga23, 1970Wh03, -182W 5C 1971Ja21, 1971Ml01, 1972Em01, 1972Ga23, 1972Kr05, 1972He10, 1973Vi13, -182W 6C 1974La15, 1975We22, 1975Qu01, 1976He18, 1977Ge12, 1978MeZK, 1980Sc07, -182W 7C 1980Sp01, 1980Ro22, 1981Ka22, 1981Is08, 1983Ji01, 1983Ri05, 1983El02, -182W 8C 1986Wa35, 1988Fi05, 1989Ka20, 1990Me15, 1990Ja02, 1992Ch26, 1992Ke02, -182W 9C 1992Su09, 1996Sc06, 1998Mi17, 2000He14, 2002Ba85, 2003Au03, 2008Ki07, -182W 10C 2010Si13 -182W T Auger electrons and X ray energies and emission intensities: -182W T {U Energy (keV)} {U Intensity} {U Line} -182W T -182W T 57.9823 10.06 17 XKA2 -182W T 59.3189 17.48 29 XKA1 -182W T -182W T 66.952 |] XKB3 -182W T 67.2451 |] 5.79 13 XKB1 -182W T 67.664 |] XKB5II -182W T -182W T 69.033 |] XKB2 -182W T 69.295 |] 1.59 5 XKB4 -182W T 69.484 |] XKO23 -182W T -182W T 7.3881-11.6761 24.4 5 XL (total) -182W T 7.3881 0.461 14 XLL -182W T 8.3352-8.3976 9.82 26 XLA -182W T 8.725 0.219 6 XLC -182W T 9.526-9.9485 11.74 24 XLB -182W T 10.9501-11.6761 2.21 5 XLG -182W T -182W T 45.109-48.882 |] KLL AUGER -182W T 54.514-59.312 |] 1.68 15 KLX AUGER -182W T 63.89-69.51 |] KXY AUGER -182W T 4.5-12.1 59.5 7 L AUGER -182TA P 0.0 3- 114.61 D 13 1814.3 17 -182W N 1.0 1.0 1 1.0 -182W L 0 0+ STABLE -182W L 100.10598 7 2+ 1.40 NS 2 -182W B 1714.2 17 12.2 1 -182W S B EAV=625.2 70 -182W G 100.10595 7 14.22 16E2 3.89 6 -182W 2 G KC=0.878 13$LC=2.28 4$MC=0.576 8 -182W L 329.4268 6 4+ 62 PS 3 -182W B 1484.9 17 13 1 -182W S B EAV=529.0 7 -182W G 229.3207 6 3.634 36E2 0.196 3 -182W 2 G KC=0.1167 17$LC=0.0605 9$MC=0.01497 21 -182W L 680.45 6 6+ 8.2 PS 9 -182W G 351.02 6 0.01157 37E2 0.0538 8 -182W 2 G KC=0.0380 6$LC=0.01210 17$MC=0.00293 5 -182W L 1135.91 140+ -182W G 1035.80 140.0060 21E2 0.00420 6 -182W 2 G KC=0.00346 5$LC=5.75E-4 8$MC=1317E-7 19 -182W G 1135.91 14 -182W L 1221.4001 102+ 0.434 PS 11 -182W B 592.9 171.6 22 9.9 1 -182W S B EAV=181.8 6 -182W G 891.9710 120.0570 25E2 0.00569 8 -182W 2 G KC=0.00464 7$LC=8.10E-4 12$MC=1.87E-4 3 -182W G 1121.290 3 35.17 33M1+E2 30 5 0.00360 5 -182W 2 G KC=0.00297 5$LC=4.83E-4 7$MC=1104E-7 16 -182W G 1221.395 3 27.27 27E2 0.00305 5 -182W 2 G KC=0.00252 4$LC=4.02E-4 6$MC=9.15E-5 13 -182W L 1257.4121 112+ 1.71 PS 13 -182W B 556.9 170.22 21 10.7 1 -182W S B EAV=169.2 6 -182W G 121.50 140.0021 7[E2] 1.83 3 -182W 2 G KC=0.596 9$LC=0.936 15$MC=0.236 4 -182W G 927.9828 130.614 7E2 0.00524 8 -182W 2 G KC=0.00429 6$LC=7.38E-4 11$MC=1698E-7 24 -182W G 1157.3022 110.83 13M1+E2 1.3 7 0.0046 13 -182W 2 G KC=0.0039 11$LC=0.00060 15$MC=0.00014 4 -182W G 1257.407 3 1.511 15E2 0.00289 4 -182W 2 G KC=0.00239 4$LC=3.78E-4 6$MC=8.60E-5 12 -182W L 1289.1498 102- 1.12 NS 4 -182W B 525.2 1745.1 23 8.3 -182W S B EAV=158.2 6 -182W G 31.7377 150.84 6E1 1.628 23 -182W 2 G LC=1.259 18$MC=0.293 4 -182W G 67.7497 1 43.6 15E1+M2 0.018 9 0.22 3 -182W 2 G LC=0.173 21$MC=0.040 6 -182W G 959.7203 120.348 5M2+E3 -5.48 44 0.0115719 -182W 2 G KC=0.00901 15$LC=0.00196 3$MC=4.63E-4 7 -182W G 1189.040 3 16.58 16E1+M2+E3 4567E-641 -182W 2 G KC=3732E-6 33$LC=6.38E-4 6$MC=1468E-7 14 -182W G 1289.145 3 1.374 17M2 0.0123118 -182W 2 G KC=0.01019 15$LC=1630E-6 23$MC=3.72E-4 6 -182W L 1331.1153 103+ -182W B 483.2 172.39 15 9.5 -182W S B EAV=143.9 6 -182W G 1001.6856 122.07 5M1+E2 -8.9 20 0.00455 8 -182W 2 G KC=0.00374 6$LC=6.27E-4 10$MC=1438E-7 23 -182W G 1231.004 3 11.62 11M1+E2 -33 8 0.00301 5 -182W 2 G KC=0.00249 4$LC=3.95E-4 6$MC=9.01E-5 13 -182W L 1373.8301 103- 78 PS 10 -182W B 440.5 1719.9 7 8.4 -182W S B EAV=129.6 6 -182W G 42.7148 140.269 7E1 0.72 1 -182W 2 G LC=0.557 8$MC=0.1286 18 -182W G 84.68024 262.62 6M1+E2 0.309 12 7.66 11 -182W 2 G KC=5.88 9$LC=1.36 4$MC=0.321 8 -182W G 116.4179 6 0.445 5E1 0.253 4 -182W 2 G KC=0.207 3$LC=0.0353 5$MC=0.00805 12 -182W G 152.42991 267.01 13E1 0.1258 18 -182W 2 G KC=0.1038 15$LC=0.01703 24$MC=0.00387 6 -182W G 1044.4001 120.2381 42E1+M2 0.48 1 0.0053515 -182W 2 G KC=0.00444 12$LC=7.03E-4 20$MC=1.60E-4 5 -182W G 1273.719 3 0.658 7E1+M2+E3 2781E-625 -182W 2 G KC=2278E-6 21$LC=3583E-7 31$MC=8.16E-5 8 -182W G 1373.824 3 0.2226 32E3 0.00496 7 -182W 2 G KC=0.00400 6$LC=7.28E-4 11$MC=1685E-7 24 -182W L 1442.836 9 4+ 0.32 PS 3 -182W B 371.5 170.563 10 9.7 1 -182W S B EAV=107.0 6 -182W G 1113.406 9 0.442 8M1+E2 -5.6 12 0.0037610 -182W 2 G KC=0.00311 8$LC=5.04E-4 12$MC=1.15E-4 3 -182W G 1342.72 5 0.2562 28E2+M3 -0.11 11 0.0028 6 -182W 2 G KC=0.0023 5$LC=0.00036 9$MC=8.2E-5 21 -182W L 1487.5018 104- -182W B 326.8 171.5 7 9.1 -182W S B EAV=92.8 5 -182W G 113.67170 221.869 20M1+E2 0.338 12 3.19 5 -182W 2 G KC=2.50 5$LC=0.529 16$MC=0.124 4 -182W G 156.3864 3 2.662 27E1 0.1177 17 -182W 2 G KC=0.0972 14$LC=0.01590 23$MC=0.00362 5 -182W G 198.35187 291.461 15E2 0.317 5 -182W 2 G KC=0.1725 25$LC=0.1097 16$MC=0.0273 4 -182W G 1158.0711 120.295 18E1 1377E-620 -182W 2 G KC=1159E-6 17$LC=1632E-7 23$MC=3.66E-5 6 -182W G 1387.390 3 0.0725 11M2+E3 2.6 3 0.0055418 -182W 2 G KC=0.00450 15$LC=7.91E-4 22$MC=1.83E-4 5 -182W L 1510.25 7 4+ -182W B 304.0 170.1414 39 10 1 -182W S B EAV=85.7 5 -182W G 829.80 9 0.0141 25[E2] 0.0066110 -182W 2 G KC=0.00536 8$LC=9.62E-4 14$MC=2.22E-4 4 -182W G 1180.82 7 0.0869 29E2+M1 -2.8 10 0.0036 4 -182W 2 G KC=0.0030 4$LC=0.00047 5$MC=1.08E-4 11 -182W G 1410.14 7 0.0400 8E2 0.00235 4 -182W 2 G KC=0.00193 3$LC=2.98E-4 5$MC=6.76E-5 10 -182W L 1553.224 1 4- 1.27 NS 4 -182W B 261.1 1729.0 7 7.5 -182W S B EAV=72.5 5 -182W G 65.72215 152.97 8M1+E2 0.094 43 2.92 20 -182W 2 G LC=2.25 15$MC=0.52 4 -182W G 110.388 9 0.1073 33[E1] 0.290 4 -182W 2 G KC=0.238 4$LC=0.0408 6$MC=0.00931 13 -182W G 179.39381 253.099 31M1+E2 1.21 29 0.63 7 -182W 2 G KC=0.44 8$LC=0.148 7$MC=0.0358 21 -182W G 222.1085 3 7.54 7E1 0.0480 7 -182W 2 G KC=0.0399 6$LC=0.00630 9$MC=1429E-6 20 -182W G 264.0740 3 3.602 36E2 0.1254 18 -182W 2 G KC=0.0799 12$LC=0.0347 5$MC=0.00852 12 -182W G 1223.7928 120.204 21E1+M2 0.38 7 0.0029 6 -182W 2 G KC=0.0024 5$LC=0.00037 8$MC=8.3E-5 17 -182W G 1453.1118 100.037 7M2+E3 2.1 4 0.0053 4 -182W 2 G KC=0.0043 3$LC=0.00074 5$MC=1.69E-4 10 - +182W 182TA B- DECAY (114.61 D) +182W H TYP=FUL$AUT=V.CHISTE$CUT=30-SEP-2010$ +182W 2 H TYP=UPD$AUT=V.CHISTE$CUT=21-MAY-2005$ +182W C References:1943Zu**, 1947Se33, 1948Me**, 1951Si25, 1952Ei12, 1957Wr37, +182W 2C 1958Ke26, 1958Sp17, 1959Vo27, 1960Gv01, 1961Ry03, 1961Vi07, 1961Vo05, +182W 3C 1964Ba12, 1964Da15, 1964Ba47, 1965He07, 1965Ed01, 1966Dz01, 1966Ko12, +182W 4C 1966Gr21, 1967Ni03, 1967Wa29, 1969Wh03, 1969Sa15, 1969Ga23, 1970Wh03, +182W 5C 1971Ja21, 1971Ml01, 1972Em01, 1972Ga23, 1972Kr05, 1972He10, 1973Vi13, +182W 6C 1974La15, 1975We22, 1975Qu01, 1976He18, 1977Ge12, 1978MeZK, 1980Sc07, +182W 7C 1980Sp01, 1980Ro22, 1981Ka22, 1981Is08, 1983Ji01, 1983Ri05, 1983El02, +182W 8C 1986Wa35, 1988Fi05, 1989Ka20, 1990Me15, 1990Ja02, 1992Ch26, 1992Ke02, +182W 9C 1992Su09, 1996Sc06, 1998Mi17, 2000He14, 2002Ba85, 2003Au03, 2008Ki07, +182W AC 2010Si13 +182W T Auger electrons and X ray energies and emission intensities: +182W T {U Energy (keV)} {U Intensity} {U Line} +182W T +182W T 57.9823 10.06 17 XKA2 +182W T 59.3189 17.48 29 XKA1 +182W T +182W T 66.952 |] XKB3 +182W T 67.2451 |] 5.79 13 XKB1 +182W T 67.664 |] XKB5II +182W T +182W T 69.033 |] XKB2 +182W T 69.295 |] 1.59 5 XKB4 +182W T 69.484 |] XKO23 +182W T +182W T 7.3881-11.6761 24.4 5 XL (total) +182W T 7.3881 0.461 14 XLL +182W T 8.3352-8.3976 9.82 26 XLA +182W T 8.725 0.219 6 XLC +182W T 9.526-9.9485 11.74 24 XLB +182W T 10.9501-11.6761 2.21 5 XLG +182W T +182W T 45.109-48.882 |] KLL AUGER +182W T 54.514-59.312 |] 1.68 15 KLX AUGER +182W T 63.89-69.51 |] KXY AUGER +182W T 4.5-12.1 59.5 7 L AUGER +182TA P 0.0 3- 114.61 D 13 1814.3 17 +182W N 1.0 1.0 1 1.0 +182W L 0 0+ STABLE +182W L 100.10598 7 2+ 1.40 NS 2 +182W B 1714.2 171E-9 12.2 1 +182W S B EAV=625.2 70 +182W G 100.10595 7 14.22 16E2 3.89 6 +182W 2 G KC=0.878 13$LC=2.28 4$MC=0.576 8$NC=0.1358 19 +182W 3 G OC=0.0186 3 +182W L 329.4268 6 4+ 62 PS 3 +182W B 1484.9 171E-9 13 1 +182W S B EAV=529.0 7 +182W G 229.3207 6 3.634 36E2 0.196 3 +182W 2 G KC=0.1167 17$LC=0.0605 9$MC=0.01497 21$NC=0.00354 5 +182W 3 G OC=0.000505 7 +182W L 680.45 6 6+ 8.2 PS 9 +182W G 351.02 6 0.01157 37E2 0.0538 8 +182W 2 G KC=0.0380 6$LC=0.01210 17$MC=0.00293 5$NC=0.000696 10 +182W 3 G OC=1.026E-4 15 +182W L 1135.91 140+ +182W G 1035.80 140.0060 21E2 0.00420 6 +182W 2 G KC=0.00346 5$LC=0.000575 8$MC=1.317E-4 19$NC=3.16E-5 5 +182W 3 G OC=5.05E-6 7 +182W G 1135.91 14 E0 +182W L 1221.4001 102+ 0.434 PS 11 +182W B 592.9 171.6 22 9.9 1 +182W S B EAV=181.8 6 +182W G 891.9710 120.0570 25E2 0.00569 8 +182W 2 G KC=0.00464 7$LC=0.000810 12$MC=0.000187 3$NC=4.47E-5 7 +182W 3 G OC=7.09E-6 10 +182W G 1121.290 3 35.17 33M1+E2 30 5 0.00360 5 +182W 2 G KC=0.00297 5$LC=0.000483 7$MC=1.104E-4 16$NC=2.65E-5 4 +182W 3 G OC=4.25E-6 6 +182W G 1221.395 3 27.27 27E2 0.00305 5 +182W 2 G KC=0.00252 4$LC=0.000402 6$MC=9.15E-5 13$NC=2.20E-5 3 +182W 3 G OC=3.53E-6 5 +182W L 1257.4121 112+ 1.71 PS 13 +182W B 556.9 170.22 21 10.7 1 +182W S B EAV=169.2 6 +182W G 121.50 140.0021 7[E2] 1.83 3 +182W 2 G KC=0.596 9$LC=0.936 15$MC=0.236 4$NC=0.0556 9 +182W 3 G OC=0.00765 13 +182W G 927.9828 130.614 7E2 0.00524 8 +182W 2 G KC=0.00429 6$LC=0.000738 11$MC=1.698E-4 24$NC=4.07E-5 6 +182W 3 G OC=6.47E-6 9 +182W G 1157.3022 110.83 13M1+E2 1.3 7 0.0046 13 +182W 2 G KC=0.0039 11$LC=0.00060 15$MC=0.00014 4$NC=0.000033 8 +182W 3 G OC=5.3E-6 13 +182W G 1257.407 3 1.511 15E2 0.00289 4 +182W 2 G KC=0.00239 4$LC=0.000378 6$MC=8.60E-5 12$NC=2.06E-5 3 +182W 3 G OC=3.33E-6 5 +182W L 1289.1498 102- 1.12 NS 4 +182W B 525.2 1745.1 23 8.3 +182W S B EAV=158.2 6 +182W G 31.7377 150.84 6E1 1.628 23 +182W 2 G LC=1.259 18$MC=0.293 4$NC=0.0675 10 +182W 3 G OC=0.00910 13 +182W G 67.7497 1 43.6 15E1+M2 0.018 9 0.22 3 +182W 2 G LC=0.173 21$MC=0.040 6$NC=0.0094 13 +182W 3 G OC=0.00140 21 +182W G 959.7203 120.348 5M2+E3 -5.48 44 0.0115719 +182W 2 G KC=0.00901 15$LC=0.00196 3$MC=0.000463 7$NC=1.111E-4 17 +182W 3 G OC=1.73E-5 3 +182W G 1189.040 3 16.58 16E1+M2+E3 4567E-641 +182W 2 G KC=0.003732 33$LC=0.000638 6$MC=1.468E-4 14$NC=3.527E-5 33 +182W 3 G OC=5.66E-6 5 +182W G 1289.145 3 1.374 17M2 0.0123118 +182W 2 G KC=0.01019 15$LC=0.001630 23$MC=0.000372 6$NC=8.98E-5 13 +182W 3 G OC=1.466E-5 21 +182W L 1331.1153 103+ +182W B 483.2 172.39 15 9.5 +182W S B EAV=143.9 6 +182W G 1001.6856 122.07 5M1+E2 -8.9 20 0.00455 8 +182W 2 G KC=0.00374 6$LC=0.000627 10$MC=1.438E-4 23$NC=3.45E-5 6 +182W 3 G OC=5.51E-6 9 +182W G 1231.004 3 11.62 11M1+E2 -33 8 0.00301 5 +182W 2 G KC=0.00249 4$LC=0.000395 6$MC=9.01E-5 13$NC=2.16E-5 3 +182W 3 G OC=3.48E-6 5 +182W L 1373.8301 103- 78 PS 10 +182W B 440.5 1719.9 7 8.4 +182W S B EAV=129.6 6 +182W G 42.7148 140.269 7E1 0.72 1 +182W 2 G LC=0.557 8$MC=0.1286 18$NC=0.0299 5 +182W 3 G OC=0.00419 6 +182W G 84.68024 262.62 6M1+E2 0.309 12 7.66 11 +182W 2 G KC=5.88 9$LC=1.36 4$MC=0.321 8$NC=0.0768 19 +182W 3 G OC=0.0118 3 +182W G 116.4179 6 0.445 5E1 0.253 4 +182W 2 G KC=0.207 3$LC=0.0353 5$MC=0.00805 12$NC=0.00191 3 +182W 3 G OC=0.000290 4 +182W G 152.42991 267.01 13E1 0.1258 18 +182W 2 G KC=0.1038 15$LC=0.01703 24$MC=0.00387 6$NC=0.000919 13 +182W 3 G OC=1.421E-4 20 +182W G 1044.4001 120.2381 42E1+M2 0.48 1 0.0053515 +182W 2 G KC=0.00444 12$LC=0.000703 20$MC=0.000160 5$NC=3.86E-5 11 +182W 3 G OC=6.29E-6 18 +182W G 1273.719 3 0.658 7E1+M2+E3 2781E-625 +182W 2 G KC=0.002278 21$LC=3.583E-4 31$MC=8.16E-5 8$NC=1.964E-5 17 +182W 3 G OC=3.188E-6 29 +182W G 1373.824 3 0.2226 32E3 0.00496 7 +182W 2 G KC=0.00400 6$LC=0.000728 11$MC=1.685E-4 24$NC=4.05E-5 6 +182W 3 G OC=6.44E-6 9 +182W L 1442.836 9 4+ 0.32 PS 3 +182W B 371.5 170.563 10 9.7 1 +182W S B EAV=107.0 6 +182W G 1113.406 9 0.442 8M1+E2 -5.6 12 0.0037610 +182W 2 G KC=0.00311 8$LC=0.000504 12$MC=0.000115 3$NC=2.76E-5 7 +182W 3 G OC=4.43E-6 11 +182W G 1342.72 5 0.2562 28E2+M3 -0.11 11 0.0028 6 +182W 2 G KC=0.0023 5$LC=0.00036 9$MC=0.000082 21$NC=0.000020 5 +182W 3 G OC=3.2E-6 8 +182W L 1487.5018 104- +182W B 326.8 171.5 7 9.1 +182W S B EAV=92.8 5 +182W G 113.67170 221.869 20M1+E2 0.338 12 3.19 5 +182W 2 G KC=2.50 5$LC=0.529 16$MC=0.124 4$NC=0.0297 10 +182W 3 G OC=0.00462 13 +182W G 156.3864 3 2.662 27E1 0.1177 17 +182W 2 G KC=0.0972 14$LC=0.01590 23$MC=0.00362 5$NC=0.000858 12 +182W 3 G OC=1.328E-4 19 +182W G 198.35187 291.461 15E2 0.317 5 +182W 2 G KC=0.1725 25$LC=0.1097 16$MC=0.0273 4$NC=0.00646 9 +182W 3 G OC=9.100E-4 13 +182W G 1158.0711 120.295 18E1 1377E-620 +182W 2 G KC=0.001159 17$LC=1.632E-4 23$MC=3.66E-5 6$NC=8.79E-6 13 +182W 3 G OC=1.432E-6 20 +182W G 1387.390 3 0.0725 11M2+E3 2.6 3 0.0055418 +182W 2 G KC=0.00450 15$LC=0.000791 22$MC=0.000183 5$NC=4.39E-5 12 +182W 3 G OC=7.03E-6 20 +182W L 1510.25 7 4+ +182W B 304.0 170.1414 39 10 1 +182W S B EAV=85.7 5 +182W G 829.80 9 0.0141 25[E2] 0.0066110 +182W 2 G KC=0.00536 8$LC=0.000962 14$MC=0.000222 4$NC=5.33E-5 8 +182W 3 G OC=8.42E-6 12 +182W G 1180.82 7 0.0869 29E2+M1 -2.8 10 0.0036 4 +182W 2 G KC=0.0030 4$LC=0.00047 5$MC=0.000108 11$NC=2.59E-5 25 +182W 3 G OC=4.2E-6 5 +182W G 1410.14 7 0.0400 8E2 0.00235 4 +182W 2 G KC=0.00193 3$LC=0.000298 5$MC=6.76E-5 10$NC=1.624E-5 23 +182W 3 G OC=2.62E-6 4 +182W L 1553.224 1 4- 1.27 NS 4 +182W B 261.1 1729.0 7 7.5 +182W S B EAV=72.5 5 +182W G 65.72215 152.97 8M1+E2 0.094 43 2.92 20 +182W 2 G LC=2.25 15$MC=0.52 4$NC=0.124 9 +182W 3 G OC=0.0200 12 +182W G 110.388 9 0.1073 33[E1] 0.290 4 +182W 2 G KC=0.238 4$LC=0.0408 6$MC=0.00931 13$NC=0.00220 3 +182W 3 G OC=0.000335 5 +182W G 179.39381 253.099 31M1+E2 1.21 29 0.63 7 +182W 2 G KC=0.44 8$LC=0.148 7$MC=0.0358 21$NC=0.0085 5 +182W 3 G OC=0.00125 5 +182W G 222.1085 3 7.54 7E1 0.0480 7 +182W 2 G KC=0.0399 6$LC=0.00630 9$MC=0.001429 20$NC=0.000340 5 +182W 3 G OC=5.34E-5 8 +182W G 264.0740 3 3.602 36E2 0.1254 18 +182W 2 G KC=0.0799 12$LC=0.0347 5$MC=0.00852 12$NC=0.00202 3 +182W 3 G OC=0.000291 4 +182W G 1223.7928 120.204 21E1+M2 0.38 7 0.0029 6 +182W 2 G KC=0.0024 5$LC=0.00037 8$MC=0.000083 17$NC=0.000020 4 +182W 3 G OC=3.3E-6 7 +182W G 1453.1118 100.037 7M2+E3 2.1 4 0.0053 4 +182W 2 G KC=0.0043 3$LC=0.00074 5$MC=0.000169 10$NC=4.07E-5 23 +182W 3 G OC=6.5E-6 4 + diff --git a/HEN_HOUSE/spectra/lnhb/Tc-94m.txt b/HEN_HOUSE/spectra/lnhb/Tc-94m.txt index 0e8ce6fab..216642291 100644 --- a/HEN_HOUSE/spectra/lnhb/Tc-94m.txt +++ b/HEN_HOUSE/spectra/lnhb/Tc-94m.txt @@ -1,190 +1,233 @@ - 94MO 94TC EC DECAY (51.9 M) - 94MO H TYP=FUL$AUT=A.L. Nichols$CUT=01-APR-2014$ - 94MO C Evaluation history: Type=FUL;Author=A.L. Nichols;Cutoff date=01-APR-2014 - 94MO C References: 1948Mo19, 1950Me21, 1962Mo06, 1963Ma21, 1965Ba48, 1967Ei01, - 94MO2C 1968Bo27, 1968Ar06, 1969Ba09, 1971Go40, 1976Su04, 1977La19, 1986AgZX, - 94MO3C 1995ScZY, 1996Sc06, 1998ScZM, 1998Sc28, 1999ScZX, 2000Sc47, 2002Ba85, - 94MO4C 2002Ra45, 2003Fr02, 2006Ab37, 2008Ki07, 2012Wa38 - 94MO T Auger electrons and X ray energies and emission intensities: - 94MO T {U Energy (keV)} {U Intensity} {U Line} - 94MO T - 94MO T 17.3745 5.93 11 XKA2 - 94MO T 17.47954 11.31 19 XKA1 - 94MO T - 94MO T 19.5904 |] XKB3 - 94MO T 19.6085 |] 2.97 6 XKB1 - 94MO T 19.774 |] XKB5II - 94MO T - 94MO T 19.9653 |] XKB2 - 94MO T 19.998 |] 0.457 18 XKB4 - 94MO T - 94MO T 2.016-2.831 1.198 22 XL (total) - 94MO T 2.016 0.0279 8 XLL - 94MO T 2.29-2.293 0.750 18 XLA - 94MO T 2.12 0.0100 3 XLC - 94MO T 2.395-2.518 0.389 10 XLB - 94MO T 2.623-2.831 0.0208 4 XLG - 94MO T - 94MO T 14.172-14.855 |] KLL AUGER - 94MO T 16.592-17.478 |] 6.28 15 KLX AUGER - 94MO T 18.99-19.996 |] KXY AUGER - 94MO T 1.48-2.25 29.8 4 L AUGER - 94TC P 76 3 (2)+ 51.9 M 10 4256 6 - 94MO N 1.0 1.0 1 1.0 - 94MO G 1022 0.027 14 - 94MO G 1037.2 3 0.044 14 - 94MO G 1357.4 150.19 8 - 94MO G 3065.6 3 0.011 4 - 94MO G 3085.8 3 0.016 4 - 94MO G 3640.6 3 0.007 2 - 94MO G 4136.2 3 0.007 1 - 94MO L 0 0+ STABLE - 94MO L 871.098 162+ - 94MO E 67.2 412.8 15.6 - 94MO2 E EAV=1094.4 24$CK=0.8704 14$CL=0.1055 11$CM=0.0205 4$CN=0.0037 2 - 94MO G 871.094 1694.04 21E2 1068E-615 - 94MO2 G KC=9.39E-4 14$LC=1073E-7 15$MC=1.92E-5 3 - 94MO L 1573.76 4 4+ - 94MO G 702.66 4 0.18 2E2 0.00183 3 - 94MO2 G KC=1608E-6 23$LC=1.87E-4 3$MC=3.34E-5 5 - 94MO L 1741.65 150+ - 94MO G 870.55 220.26 3E2 1070E-615 - 94MO2 G KC=9.40E-4 14$LC=1075E-7 15$MC=1.92E-5 3 - 94MO L 1864.31 5 2+ - 94MO E 0.41 100.39 96.82 - 94MO2 E EAV=639.6 23$CK=0.8699 14$CL=0.1059 11$CM=0.0206 4$CN=0.0037 2 - 94MO G 993.20 5 2.21 18M1+E2 -2 1 7.91E-415 - 94MO2 G KC=6.96E-4 13$LC=7.86E-5 13$MC=1403E-8 22 - 94MO G 1864.29 5 0.23 3E2 4.55E-4 7 - 94MO2 G KC=1.89E-4 3$LC=2.09E-5 3$MC=3.72E-6 6 - 94MO L 2067.35 6 2+ - 94MO E 0.22 30.34 56.8 - 94MO2 E EAV=548.7 23$CK=0.8697 14$CL=0.1060 11$CM=0.0206 4$CN=0.0037 2 - 94MO G 1196.24 6 0.71 7M1+E2 0.15 4 5.53E-4 8 - 94MO2 G KC=4.83E-4 7$LC=5.36E-5 8$MC=9.57E-6 14 - 94MO G 2067.33 6 0.11 1E2 5.15E-4 8 - 94MO2 G KC=1562E-7 22$LC=1722E-8 25$MC=3.07E-6 5 - 94MO L 2294.79 164+ - 94MO L 2393.02 6 2+ - 94MO E 0.91 64.0 25.6 - 94MO2 E EAV=404.8 22$CK=0.8694 14$CL=0.1062 11$CM=0.0207 4$CN=0.0037 2 - 94MO G 325.67 9 0.027 2M1+E2 1.0 2 0.0147 9 - 94MO2 G KC=0.0128 8$LC=0.00156 11$MC=2.80E-4 19 - 94MO G 528.71 8 0.032 2M1+E2 1.0 2 0.00371 9 - 94MO2 G KC=0.00325 8$LC=3.78E-4 11$MC=6.76E-5 19 - 94MO G 1521.91 6 4.48 28M1+E2 -0.12 3 4.11E-4 6 - 94MO2 G KC=2.95E-4 5$LC=3.26E-5 5$MC=5.81E-6 9 - 94MO G 2392.99 6 0.50 4E2 6.33E-4 9 - 94MO2 G KC=1203E-7 17$LC=1322E-8 19$MC=2.35E-6 4 - 94MO L 2423.45 9 6+ - 94MO L 2533.87 123- - 94MO L 2610.57 165- - 94MO L 2739.91 7 1+ - 94MO E 0.427 2110.1 45.03 - 94MO2 E EAV=254.3 22$CK=0.8690 14$CL=0.1066 11$CM=0.0207 4$CN=0.0037 2 - 94MO G 672.56 9 0.17 3M1+E2 1.0 2 0.00200 3 - 94MO2 G KC=0.00176 3$LC=2.01E-4 4$MC=3.59E-5 7 - 94MO G 875.60 9 1.0 3M1+E2 -0.10 2 1072E-615 - 94MO2 G KC=9.45E-4 14$LC=1056E-7 15$MC=1.89E-5 3 - 94MO G 998.25 170.24 2M1 8.06E-412 - 94MO2 G KC=0.00071 1$LC=7.92E-5 11$MC=1413E-8 20 - 94MO G 1868.79 7 5.49 28M1+E2 -0.12 2 4.38E-4 7 - 94MO2 G KC=1.96E-4 3$LC=2.16E-5 3$MC=3.85E-6 6 - 94MO G 2739.87 7 3.53 20M1 7.25E-411 - 94MO2 G KC=9.59E-5 14$LC=1051E-8 15$MC=1.87E-6 3 - 94MO L 2805.04 193+ - 94MO L 2869.90 8 2+ - 94MO E 0.0024 50.15 36.8 - 94MO2 E EAV=198.5 22$CK=0.8688 14$CL=0.1067 11$CM=0.0208 4$CN=0.0037 2 - 94MO G 802.55 100.0246 14M1+E2 1.0 2 1303E-619 - 94MO2 G KC=1146E-6 16$LC=1301E-7 19$MC=2.32E-5 4 - 94MO G 1005.58 9 0.09 3M1+E2 -0.05 4 7.93E-412 - 94MO2 G KC=6.99E-4 10$LC=7.79E-5 11$MC=1.39E-5 2 - 94MO G 1998.78 8 0.0123 6M1+E2 1.30 9 4.84E-410 - 94MO2 G KC=1.68E-4 3$LC=1.86E-5 3$MC=3.31E-6 6 - 94MO G 2869.85 8 0.016 2E2 8.16E-412 - 94MO2 G KC=8.81E-5 13$LC=9.64E-6 14$MC=1717E-9 24 - 94MO L 2872.40 116+ - 94MO L 2955.55 13(8)+ - 94MO L 2965.41 6 3+ - 94MO E 0.00058 90.093 146.9 - 94MO2 E EAV=157.5 22$CK=0.8686 14$CL=0.1069 11$CM=0.0208 4$CN=0.0037 2 - 94MO G 898.06 9 0.0098 5M1+E2 2.0 9 9.97E-415 - 94MO2 G KC=8.77E-4 13$LC=9.96E-5 14$MC=1778E-8 25 - 94MO G 1101.09 8 0.042 14M1+E2 -0.09 6 6.53E-410 - 94MO2 G KC=5.76E-4 8$LC=6.40E-5 9$MC=1142E-8 16 - 94MO G 1391.64 7 0.0267 10M1+E2 -0.08 6 4.41E-4 7 - 94MO2 G KC=3.53E-4 5$LC=3.91E-5 6$MC=6.98E-6 10 - 94MO G 2094.28 6 0.0156 6M1+E2 1.1 7 5.12E-414 - 94MO2 G KC=1.55E-4 3$LC=1.71E-5 4$MC=3.04E-6 6 - 94MO L 3128.66 7 1+ - 94MO E 1.63 95.57 - 94MO2 E CK=0.8682 14$CL=0.1072 11$CM=0.0209 4$CN=0.0037 2 - 94MO G 1061.30 9 0.016 2M1+E2 -0.57 16 6.99E-411 - 94MO2 G KC=6.16E-4 10$LC=6.88E-5 10$MC=1227E-8 18 - 94MO G 1264.34 9 0.22 2M1+E2 -0.08 3 5.03E-4 7 - 94MO2 G KC=4.31E-4 6$LC=4.78E-5 7$MC=8.52E-6 12 - 94MO G 2257.53 7 0.057 5M1+E2 0.74 19 5.61E-4 9 - 94MO2 G KC=1356E-7 20$LC=1491E-8 22$MC=2.66E-6 4 - 94MO G 3128.60 7 1.34 9M1 8.71E-413 - 94MO2 G KC=7.58E-5 11$LC=8.29E-6 12$MC=1476E-9 21 - 94MO L 3163.29 19(3)+ - 94MO E 0.058 177 - 94MO2 E CK=0.8681 14$CL=0.1073 11$CM=0.0209 4$CN=0.0037 2 - 94MO G 358.3 3 0.0084 7M1+E2 -0.35 12 0.0092 4 - 94MO2 G KC=0.0080 4$LC=0.00093 5$MC=1.67E-4 8 - 94MO G 2292.16 190.050 17M1+E2 0.17 4 5.62E-4 8 - 94MO2 G KC=1330E-7 19$LC=1461E-8 21$MC=2.60E-6 4 - 94MO L 3165.77 9 6+ - 94MO L 3331.74 17(3)+ - 94MO E 0.234 206.3 - 94MO2 E CK=0.8675 14$CL=0.1078 11$CM=0.0210 4$CN=0.0038 2 - 94MO G 1467.42 180.072 5M1+E2 0.3 16 4.19E-4 9 - 94MO2 G KC=3.16E-4 15$LC=3.50E-5 15$MC=6.2E-6 3 - 94MO G 1757.96 170.15 2M1+E2 -0.10 3 4.18E-4 6 - 94MO2 G KC=2.21E-4 3$LC=2.44E-5 4$MC=4.35E-6 6 - 94MO G 2460.61 170.011 2(M1+E2) - 94MO L 3339.54 176+ - 94MO L 3400.83 17 + - 94MO E 0.36 46 - 94MO2 E CK=0.8672 14$CL=0.1080 11$CM=0.0211 4$CN=0.0038 2 - 94MO G 1536.51 180.014 3 - 94MO G 2529.69 170.34 4 - 94MO G 3400.76 170.005 2 - 94MO L 3447.6 4 (1,2)+ - 94MO E 0.118 196.4 - 94MO2 E CK=0.8669 14$CL=0.1082 11$CM=0.0211 4$CN=0.0038 2 - 94MO G 2576.5 4 0.11 2M1+E2 -1.9 6 6.94E-412 - 94MO2 G KC=1061E-7 15$LC=1164E-8 17$MC=2.07E-6 3 - 94MO G 3447.5 4 0.006 1 - 94MO L 3511.86 141+ - 94MO E 0.121 106.4 - 94MO2 E CK=0.8666 15$CL=0.1085 11$CM=0.0212 4$CN=0.0038 2 - 94MO G 1770.19 210.025 6(M1+E2) - 94MO G 2640.72 140.033 4(M1+E2) - 94MO G 3511.79 140.063 7(M1+E2) - 94MO L 3534.32 9 2+ - 94MO E 0.106 36.4 - 94MO2 E CK=0.8664 15$CL=0.1086 11$CM=0.0212 4$CN=0.0038 2 - 94MO G 1669.99 100.037 2M1+E2 0.15 19 4.10E-4 6 - 94MO2 G KC=2.45E-4 4$LC=2.70E-5 4$MC=4.81E-6 7 - 94MO G 2663.18 9 0.066 2M1+E2 -0.3 2 6.99E-411 - 94MO2 G KC=1009E-7 15$LC=1106E-8 16$MC=1.97E-6 3 - 94MO G 3534.25 9 0.0034 4E2 1065E-615 - 94MO2 G KC=6.25E-5 9$LC=6.82E-6 10$MC=1215E-9 17 - 94MO L 3792.87 152+ - 94MO E 0.169 205.9 - 94MO2 E CK=0.8639 15$CL=0.1106 11$CM=0.0216 4$CN=0.0039 2 - 94MO G 1399.84 160.041 3M1+E2 - 94MO G 1928.54 160.075 19M1+E2 - 94MO G 3792.79 150.052 5E2 1149E-616 - 94MO2 G KC=5.59E-5 8$LC=6.09E-6 9$MC=1084E-9 16 - 94MO L 3892.16 7 (2)+ - 94MO E 0.212 135.6 - 94MO2 E CK=0.8620 15$CL=0.1121 12$CM=0.0220 4$CN=0.0039 2 - 94MO G 1499.13 9 0.067 11M1+E2 - 94MO G 1824.79 9 0.023 1(M1+E2) - 94MO G 2027.83 9 0.021 4(M1+E2) - 94MO G 3021.01 7 0.087 14(M1+E2) - 94MO G 3892.07 7 0.014 2 - + 94MO 94TC EC DECAY (51.9 M) + 94MO H TYP=FUL$AUT=A.L.NICHOLS$CUT=01-APR-2014$ + 94MO C References:1948Mo19, 1950Me21, 1962Mo06, 1963Ma21, 1965Ba48, 1967Ei01, + 94MO2C 1968Bo27, 1968Ar06, 1969Ba09, 1971Go40, 1976Su04, 1977La19, 1986AgZX, + 94MO3C 1995ScZY, 1996Sc06, 1998ScZM, 1998Sc28, 1999ScZX, 2000Sc47, 2002Ba85, + 94MO4C 2002Ra45, 2003Fr02, 2006Ab37, 2008Ki07, 2012Wa38 + 94MO T Auger electrons and X ray energies and emission intensities: + 94MO T {U Energy (keV)} {U Intensity} {U Line} + 94MO T + 94MO T 17.3745 5.93 11 XKA2 + 94MO T 17.47954 11.31 19 XKA1 + 94MO T + 94MO T 19.5904 |] XKB3 + 94MO T 19.6085 |] 2.97 6 XKB1 + 94MO T 19.774 |] XKB5II + 94MO T + 94MO T 19.9653 |] XKB2 + 94MO T 19.998 |] 0.457 18 XKB4 + 94MO T + 94MO T 2.016-2.831 1.198 22 XL (total) + 94MO T 2.016 0.0279 8 XLL + 94MO T 2.29-2.293 0.750 18 XLA + 94MO T 2.12 0.0100 3 XLC + 94MO T 2.395-2.518 0.389 10 XLB + 94MO T 2.623-2.831 0.0208 4 XLG + 94MO T + 94MO T 14.172-14.855 |] KLL AUGER + 94MO T 16.592-17.478 |] 6.28 15 KLX AUGER + 94MO T 18.99-19.996 |] KXY AUGER + 94MO T 1.48-2.25 29.8 4 L AUGER + 94TC P 76 3 (2)+ 51.9 M 10 4256 6 + 94MO N 1.0 1.0 1 1.0 + 94MO G 1022 0.027 14 + 94MO G 1037.2 3 0.044 14 + 94MO G 1357.4 150.19 8 + 94MO G 3065.6 3 0.011 4 + 94MO G 3085.8 3 0.016 4 + 94MO G 3640.6 3 0.007 2 + 94MO G 4136.2 3 0.007 1 + 94MO L 0 0+ STABLE + 94MO L 871.098 162+ + 94MO E 67.2 412.8 15.6 + 94MO2 E EAV=1094.4 24$CK=0.13926 22$CL=0.01688 18$CM=0.00328 6 + 94MO3 E CN=0.000592 32 + 94MO G 871.094 1694.04 21E2 1068E-615 + 94MO2 G KC=0.000939 14$LC=1.073E-4 15$MC=1.92E-5 3$NC=2.90E-6 4 + 94MO3 G OC=1.606E-7 23 + 94MO L 1573.76 4 4+ + 94MO G 702.66 4 0.18 2E2 0.00183 3 + 94MO2 G KC=0.001608 23$LC=0.000187 3$MC=3.34E-5 5$NC=5.04E-6 7 + 94MO3 G OC=2.74E-7 4 + 94MO L 1741.65 150+ + 94MO G 870.55 220.26 3E2 1070E-615 + 94MO2 G KC=0.000940 14$LC=1.075E-4 15$MC=1.92E-5 3$NC=2.91E-6 4 + 94MO3 G OC=1.609E-7 23 + 94MO L 1864.31 5 2+ + 94MO E 0.41 100.39 96.82 + 94MO2 E EAV=639.6 23$CK=0.4241 7$CL=0.0516 5$CM=0.01004 20 + 94MO3 E CN=0.0018 1 + 94MO G 993.20 5 2.21 18M1+E2 -2 1 7.91E-415 + 94MO2 G KC=0.000696 13$LC=7.86E-5 13$MC=1.403E-5 22$NC=2.13E-6 4 + 94MO3 G OC=1.20E-7 3 + 94MO G 1864.29 5 0.23 3E2 4.55E-4 7 + 94MO2 G KC=0.000189 3$LC=2.09E-5 3$MC=3.72E-6 6$NC=5.67E-7 8 + 94MO3 G OC=3.25E-8 5$IPC=0.000241 4 + 94MO L 2067.35 6 2+ + 94MO E 0.22 30.34 56.8 + 94MO2 E EAV=548.7 23$CK=0.5280 8$CL=0.0644 7$CM=0.01251 24 + 94MO3 E CN=0.00225 12 + 94MO G 1196.24 6 0.71 7M1+E2 0.15 4 5.53E-4 8 + 94MO2 G KC=0.000483 7$LC=5.36E-5 8$MC=9.57E-6 14$NC=1.460E-6 21 + 94MO3 G OC=8.40E-8 12$IPC=5.77E-6 9 + 94MO G 2067.33 6 0.11 1E2 5.15E-4 8 + 94MO2 G KC=1.562E-4 22$LC=1.722E-5 25$MC=3.07E-6 5$NC=4.68E-7 7 + 94MO3 G OC=2.69E-8 4$IPC=0.000338 5 + 94MO L 2294.79 164+ + 94MO L 2393.02 6 2+ + 94MO E 0.91 64.0 25.6 + 94MO2 E EAV=404.8 22$CK=0.7083 11$CL=0.0865 9$CM=0.01686 33 + 94MO3 E CN=0.00301 16 + 94MO G 325.67 9 0.027 2M1+E2 1.0 2 0.0147 9 + 94MO2 G KC=0.0128 8$LC=0.00156 11$MC=0.000280 19$NC=0.000042 3 + 94MO3 G OC=2.15E-6 11 + 94MO G 528.71 8 0.032 2M1+E2 1.0 2 0.00371 9 + 94MO2 G KC=0.00325 8$LC=0.000378 11$MC=6.76E-5 19$NC=1.02E-5 3 + 94MO3 G OC=5.58E-7 11 + 94MO G 1521.91 6 4.48 28M1+E2 -0.12 3 4.11E-4 6 + 94MO2 G KC=0.000295 5$LC=3.26E-5 5$MC=5.81E-6 9$NC=8.86E-7 13 + 94MO3 G OC=5.11E-8 8$IPC=7.76E-5 11 + 94MO G 2392.99 6 0.50 4E2 6.33E-4 9 + 94MO2 G KC=1.203E-4 17$LC=1.322E-5 19$MC=2.35E-6 4$NC=3.59E-7 5 + 94MO3 G OC=2.07E-8 3$IPC=0.000496 7 + 94MO L 2423.45 9 6+ + 94MO L 2533.87 123- + 94MO L 2610.57 165- + 94MO L 2739.91 7 1+ + 94MO E 0.427 2110.1 45.03 + 94MO2 E EAV=254.3 22$CK=0.8338 13$CL=0.1023 11$CM=0.01986 38 + 94MO3 E CN=0.00355 19 + 94MO G 672.56 9 0.17 3M1+E2 1.0 2 0.00200 3 + 94MO2 G KC=0.00176 3$LC=0.000201 4$MC=3.59E-5 7$NC=5.45E-6 10 + 94MO3 G OC=3.03E-7 5 + 94MO G 875.60 9 1.0 3M1+E2 -0.10 2 1072E-615 + 94MO2 G KC=0.000945 14$LC=1.056E-4 15$MC=1.89E-5 3$NC=2.88E-6 4 + 94MO3 G OC=1.649E-7 23 + 94MO G 998.25 170.24 2M1 8.06E-412 + 94MO2 G KC=0.00071 1$LC=7.92E-5 11$MC=1.413E-5 20$NC=2.16E-6 3 + 94MO3 G OC=1.238E-7 18 + 94MO G 1868.79 7 5.49 28M1+E2 -0.12 2 4.38E-4 7 + 94MO2 G KC=0.000196 3$LC=2.16E-5 3$MC=3.85E-6 6$NC=5.88E-7 9 + 94MO3 G OC=3.40E-8 5$IPC=0.000215 3 + 94MO G 2739.87 7 3.53 20M1 7.25E-411 + 94MO2 G KC=9.59E-5 14$LC=1.051E-5 15$MC=1.87E-6 3$NC=2.86E-7 4 + 94MO3 G OC=1.657E-8 24$IPC=0.000616 9 + 94MO L 2805.04 193+ + 94MO L 2869.90 8 2+ + 94MO E 0.0024 50.15 36.8 + 94MO2 E EAV=198.5 22$CK=0.8551 14$CL=0.1050 11$CM=0.02047 39 + 94MO3 E CN=0.00364 20 + 94MO G 802.55 100.0246 14M1+E2 1.0 2 1303E-619 + 94MO2 G KC=0.001146 16$LC=1.301E-4 19$MC=2.32E-5 4$NC=3.53E-6 5 + 94MO3 G OC=1.98E-7 3 + 94MO G 1005.58 9 0.09 3M1+E2 -0.05 4 7.93E-412 + 94MO2 G KC=0.000699 10$LC=7.79E-5 11$MC=1.39E-5 2$NC=2.12E-6 3 + 94MO3 G OC=1.219E-7 17 + 94MO G 1998.78 8 0.0123 6M1+E2 1.30 9 4.84E-410 + 94MO2 G KC=0.000168 3$LC=1.86E-5 3$MC=3.31E-6 6$NC=5.05E-7 7 + 94MO3 G OC=2.91E-8 4$IPC=0.000293 9 + 94MO G 2869.85 8 0.016 2E2 8.16E-412 + 94MO2 G KC=8.81E-5 13$LC=9.64E-6 14$MC=1.717E-6 24$NC=2.62E-7 4 + 94MO3 G OC=1.514E-8 22$IPC=0.000717 10 + 94MO L 2872.40 116+ + 94MO L 2955.55 13(8)+ + 94MO L 2965.41 6 3+ + 94MO E 0.00058 90.093 146.9 + 94MO2 E EAV=157.5 22$CK=0.8632 14$CL=0.1062 11$CM=0.02067 40 + 94MO3 E CN=0.00368 20 + 94MO G 898.06 9 0.0098 5M1+E2 2.0 9 9.97E-415 + 94MO2 G KC=0.000877 13$LC=9.96E-5 14$MC=1.778E-5 25$NC=2.70E-6 4 + 94MO3 G OC=1.51E-7 3 + 94MO G 1101.09 8 0.042 14M1+E2 -0.09 6 6.53E-410 + 94MO2 G KC=0.000576 8$LC=6.40E-5 9$MC=1.142E-5 16$NC=1.743E-6 25 + 94MO3 G OC=1.003E-7 14$IPC=4.92E-7 8 + 94MO G 1391.64 7 0.0267 10M1+E2 -0.08 6 4.41E-4 7 + 94MO2 G KC=0.000353 5$LC=3.91E-5 6$MC=6.98E-6 10$NC=1.065E-6 15 + 94MO3 G OC=6.14E-8 9$IPC=4.04E-5 6 + 94MO G 2094.28 6 0.0156 6M1+E2 1.1 7 5.12E-414 + 94MO2 G KC=0.000155 3$LC=1.71E-5 4$MC=3.04E-6 6$NC=4.64E-7 9 + 94MO3 G OC=2.67E-8 6$IPC=0.000336 15 + 94MO L 3128.66 7 1+ + 94MO E 1.63 95.57 + 94MO2 E CK=0.8682 14$CL=0.1072 11$CM=0.0209 4$CN=0.0037 2 + 94MO G 1061.30 9 0.016 2M1+E2 -0.57 16 6.99E-411 + 94MO2 G KC=0.000616 10$LC=6.88E-5 10$MC=1.227E-5 18$NC=1.87E-6 3 + 94MO3 G OC=1.069E-7 17 + 94MO G 1264.34 9 0.22 2M1+E2 -0.08 3 5.03E-4 7 + 94MO2 G KC=0.000431 6$LC=4.78E-5 7$MC=8.52E-6 12$NC=1.300E-6 19 + 94MO3 G OC=7.49E-8 11$IPC=1.516E-5 22 + 94MO G 2257.53 7 0.057 5M1+E2 0.74 19 5.61E-4 9 + 94MO2 G KC=1.356E-4 20$LC=1.491E-5 22$MC=2.66E-6 4$NC=4.06E-7 6 + 94MO3 G OC=2.34E-8 4$IPC=0.000407 8 + 94MO G 3128.60 7 1.34 9M1 8.71E-413 + 94MO2 G KC=7.58E-5 11$LC=8.29E-6 12$MC=1.476E-6 21$NC=2.26E-7 4 + 94MO3 G OC=1.308E-8 19$IPC=0.000785 11 + 94MO L 3163.29 19(3)+ + 94MO E 0.058 177 + 94MO2 E CK=0.8681 14$CL=0.1073 11$CM=0.0209 4$CN=0.0037 2 + 94MO G 358.3 3 0.0084 7M1+E2 -0.35 12 0.0092 4 + 94MO2 G KC=0.0080 4$LC=0.00093 5$MC=0.000167 8$NC=2.53E-5 12 + 94MO3 G OC=1.40E-6 5 + 94MO G 2292.16 190.050 17M1+E2 0.17 4 5.62E-4 8 + 94MO2 G KC=1.330E-4 19$LC=1.461E-5 21$MC=2.60E-6 4$NC=3.97E-7 6 + 94MO3 G OC=2.30E-8 4$IPC=0.000411 6 + 94MO L 3165.77 9 6+ + 94MO L 3331.74 17(3)+ + 94MO E 0.234 206.3 + 94MO2 E CK=0.8675 14$CL=0.1078 11$CM=0.0210 4$CN=0.0038 2 + 94MO G 1467.42 180.072 5M1+E2 0.3 16 4.19E-4 9 + 94MO2 G KC=0.000316 15$LC=3.50E-5 15$MC=6.2E-6 3$NC=9.5E-7 4 + 94MO3 G OC=5.5E-8 3$IPC=0.000061 10 + 94MO G 1757.96 170.15 2M1+E2 -0.10 3 4.18E-4 6 + 94MO2 G KC=0.000221 3$LC=2.44E-5 4$MC=4.35E-6 6$NC=6.64E-7 10 + 94MO3 G OC=3.84E-8 6$IPC=1.677E-4 24 + 94MO G 2460.61 170.011 2(M1+E2) + 94MO L 3339.54 176+ + 94MO L 3400.83 17 + 94MO E 0.36 46 + 94MO2 E CK=0.8672 14$CL=0.1080 11$CM=0.0211 4$CN=0.0038 2 + 94MO G 1536.51 180.014 3 + 94MO G 2529.69 170.34 4 + 94MO G 3400.76 170.005 2 + 94MO L 3447.6 4 (1,2)+ + 94MO E 0.118 196.4 + 94MO2 E CK=0.8669 14$CL=0.1082 11$CM=0.0211 4$CN=0.0038 2 + 94MO G 2576.5 4 0.11 2M1+E2 -1.9 6 6.94E-412 + 94MO2 G KC=1.061E-4 15$LC=1.164E-5 17$MC=2.07E-6 3$NC=3.17E-7 5 + 94MO3 G OC=1.83E-8 3$IPC=0.000574 11 + 94MO G 3447.5 4 0.006 1 + 94MO L 3511.86 141+ + 94MO E 0.121 106.4 + 94MO2 E CK=0.8666 15$CL=0.1085 11$CM=0.0212 4$CN=0.0038 2 + 94MO G 1770.19 210.025 6(M1+E2) + 94MO G 2640.72 140.033 4(M1+E2) + 94MO G 3511.79 140.063 7(M1+E2) + 94MO L 3534.32 9 2+ + 94MO E 0.106 36.4 + 94MO2 E CK=0.8664 15$CL=0.1086 11$CM=0.0212 4$CN=0.0038 2 + 94MO G 1669.99 100.037 2M1+E2 0.15 19 4.10E-4 6 + 94MO2 G KC=0.000245 4$LC=2.70E-5 4$MC=4.81E-6 7$NC=7.35E-7 11 + 94MO3 G OC=4.24E-8 7$IPC=0.000132 3 + 94MO G 2663.18 9 0.066 2M1+E2 -0.3 2 6.99E-411 + 94MO2 G KC=1.009E-4 15$LC=1.106E-5 16$MC=1.97E-6 3$NC=3.01E-7 5 + 94MO3 G OC=1.742E-8 25$IPC=0.000585 10 + 94MO G 3534.25 9 0.0034 4E2 1065E-615 + 94MO2 G KC=6.25E-5 9$LC=6.82E-6 10$MC=1.215E-6 17$NC=1.86E-7 3 + 94MO3 G OC=1.074E-8 15$IPC=0.000994 14 + 94MO L 3792.87 152+ + 94MO E 0.169 205.9 + 94MO2 E CK=0.8639 15$CL=0.1106 11$CM=0.0216 4$CN=0.0039 2 + 94MO G 1399.84 160.041 3M1+E2 + 94MO G 1928.54 160.075 19M1+E2 + 94MO G 3792.79 150.052 5E2 1149E-616 + 94MO2 G KC=5.59E-5 8$LC=6.09E-6 9$MC=1.084E-6 16$NC=1.656E-7 24 + 94MO3 G OC=9.59E-9 14$IPC=0.001086 16 + 94MO L 3892.16 7 (2)+ + 94MO E 0.212 135.6 + 94MO2 E CK=0.8620 15$CL=0.1121 12$CM=0.0220 4$CN=0.0039 2 + 94MO G 1499.13 9 0.067 11M1+E2 + 94MO G 1824.79 9 0.023 1(M1+E2) + 94MO G 2027.83 9 0.021 4(M1+E2) + 94MO G 3021.01 7 0.087 14(M1+E2) + 94MO G 3892.07 7 0.014 2 + diff --git a/HEN_HOUSE/spectra/lnhb/Tc-99.txt b/HEN_HOUSE/spectra/lnhb/Tc-99.txt index b9a855a55..fd5d1554d 100644 --- a/HEN_HOUSE/spectra/lnhb/Tc-99.txt +++ b/HEN_HOUSE/spectra/lnhb/Tc-99.txt @@ -1,46 +1,44 @@ - 99RU 99TC B- DECAY (211.5E3 Y) - 99RU H TYP=Full$AUT=X. Mougeot$CUT=15-MAR-2010$ - 99RU2 H TYP=update$AUT=MMBé$CUT= -- $ - 99RU C Evaluation history: Type=Full;Author=X. Mougeot;Cutoff date=15-MAR-2010 - 99RU2C Type=update;Author=MMBé;Cutoff date= -- - 99RU C References: 1947MO15, 1950KE02, 1951TA05, 1951FR05, 1952FE16, 1954GO69, - 99RU2C 1960BO08, 1961RO33, 1964KI01, 1964BO28, 1965KI01, 1965MA27, 1966GO10, - 99RU3C 1966SN02, 1966KI02, 1967MO20, 1967ST36, 1968HA52, 1971GO40, 1971LE20, - 99RU4C 1970AN12, 1972GU01, 1972WA32, 1973BE72, 1973LE10, 1974RE11, 1974EN02, - 99RU5C 1974HA12, 1976KI02, 1977IS05, 1980LA02, 1984CO30, 1986MU09, 1990GA13, - 99RU6C 1996SC06, 2003AU03, 2008KI07 - 99RU T Auger electrons and X ray energies and emission intensities: - 99RU T {U Energy (keV)} {U Intensity} {U Line} - 99RU T - 99RU T 19.1506 0.00015530 XKA2 - 99RU T 19.2794 0.00029 6 XKA1 - 99RU T - 99RU T 21.6349 |] XKB3 - 99RU T 21.6565 |] 0.00007915 XKB1 - 99RU T 21.832 |] XKB5II - 99RU T - 99RU T 22.074 |] XKB2 - 99RU T 22.104 |] 1.28E-5 25 XKB4 - 99RU T - 99RU T 2.2538-3.1825 0.000039 4 XL (total) - 99RU T 2.2538 8.6E-7 12 XLL - 99RU T 2.5542-2.5591 2.34E-5 29 XLA - 99RU T 2.3826 3.2E-7 6 XLC - 99RU T 2.6831-2.9436 1.32E-5 18 XLB - 99RU T 2.8959-3.1825 9.1E-7 12 XLG - 99RU T - 99RU T 15.565-16.329 |] KLL AUGER - 99RU T 18.267-19.277 |] 0.00013927 KLX AUGER - 99RU T 20.947-22.113 |] KXY AUGER - 99RU T 1.75-3.12 0.00080 4 L AUGER - 99TC P 0.0 9/2+ 211.5E3 Y 11 293.8 14 - 99RU N 1.0 1.0 1 1.0 - 99RU L 0 5/2+ STABLE - 99RU B 293.8 1499.9985530 12.3 2 - 99RUS B EAV=94.6 17 - 99RU L 89.52 153/2+ 20.36 NS 25 - 99RU B 204.3 140.00145 30 15.8 2U - 99RUS B EAV= - 99RU G 89.52 150.00058 11M1+()E2 -1.56 2 1.495 25 - 99RU2 G KC=1.173 19$LC=0.265 5$MC=0.0497 9 - + 99RU 99TC B- DECAY (211.5E3 Y) + 99RU H TYP=FUL$AUT=X.MOUGEOT$CUT=15-MAR-2010$ + 99RU2 H TYP=UPD$AUT=M.-M.BE$CUT=14-FEB-2008$ + 99RU C References:1947MO15, 1950KE02, 1951TA05, 1951FR05, 1952FE16, 1954GO69, + 99RU2C 1960BO08, 1961RO33, 1964KI01, 1964BO28, 1965KI01, 1965MA27, 1966GO10, + 99RU3C 1966SN02, 1966KI02, 1967MO20, 1967ST36, 1968HA52, 1971GO40, 1971LE20, + 99RU4C 1970AN12, 1972GU01, 1972WA32, 1973BE72, 1973LE10, 1974RE11, 1974EN02, + 99RU5C 1974HA12, 1976KI02, 1977IS05, 1980LA02, 1984CO30, 1986MU09, 1990GA13, + 99RU6C 1996SC06, 2003Au03, 2008Ki07 + 99RU T Auger electrons and X ray energies and emission intensities: + 99RU T {U Energy (keV)} {U Intensity} {U Line} + 99RU T + 99RU T 19.1506 0.00015530 XKA2 + 99RU T 19.2794 0.00029 6 XKA1 + 99RU T + 99RU T 21.6349 |] XKB3 + 99RU T 21.6565 |] 0.00007915 XKB1 + 99RU T 21.832 |] XKB5II + 99RU T + 99RU T 22.074 |] XKB2 + 99RU T 22.104 |] 1.28E-5 25 XKB4 + 99RU T + 99RU T 2.2538-3.1825 0.000039 4 XL (total) + 99RU T 2.2538 8.6E-7 12 XLL + 99RU T 2.5542-2.5591 2.34E-5 29 XLA + 99RU T 2.3826 3.2E-7 6 XLC + 99RU T 2.6831-2.9436 1.32E-5 18 XLB + 99RU T 2.8959-3.1825 9.1E-7 12 XLG + 99RU T + 99RU T 15.565-16.329 |] KLL AUGER + 99RU T 18.267-19.277 |] 0.00013927 KLX AUGER + 99RU T 20.947-22.113 |] KXY AUGER + 99RU T 1.75-3.12 0.00080 4 L AUGER + 99TC P 0.0 9/2+ 211.5E3 Y 11 293.8 14 + 99RU N 1.0 1.0 1 1.0 + 99RU L 0 5/2+ STABLE + 99RU B 293.8 1499.9985530 12.3 2 + 99RUS B EAV=94.6 17 + 99RU L 89.52 153/2+ 20.36 NS 25 + 99RU B 204.3 140.00145 30 15.8 2U + 99RU G 89.52 150.00058 11M1+E2 -1.56 2 1.495 25 + 99RU2 G KC=1.173 19$LC=0.265 5$MC=0.0497 9$NC=0.00745 13 + 99RU3 G OC=0.000173 3 + diff --git a/HEN_HOUSE/spectra/lnhb/Tc-99m.txt b/HEN_HOUSE/spectra/lnhb/Tc-99m.txt index 5dac3985f..2c5edd382 100644 --- a/HEN_HOUSE/spectra/lnhb/Tc-99m.txt +++ b/HEN_HOUSE/spectra/lnhb/Tc-99m.txt @@ -1,69 +1,71 @@ - 99TC 99TC IT DECAY (6.0067 H) - 99TC T Auger electrons and X ray energies and emission intensities: - 99TC T {U Energy (keV)} {U Intensity} {U Line} - 99TC T - 99TC T 18.251 2.22 7 XKA2 - 99TC T 18.3672 4.21 12 XKA1 - 99TC T - 99TC T 20.599 |] XKB3 - 99TC T 20.619 |] 1.12 4 XKB1 - 99TC T 20.789 |] XKB5II - 99TC T - 99TC T 21.005 |] XKB2 - 99TC T 21.042 |] 0.177 8 XKB4 - 99TC T - 99TC T 2.134-3.002 0.482 12 XL (total) - 99TC T 2.134 0.0110 4 XLL - 99TC T 2.42-2.425 0.298 10 XLA - 99TC T 2.25 0.00395 15 XLC - 99TC T 2.456-2.788 0.159 5 XLB - 99TC T 2.726-3.002 0.00984 26 XLG - 99TC T - 99TC T 14.86-15.58 |] KLL AUGER - 99TC T 17.43-18.33 |] 2.15 8 KLX AUGER - 99TC T 19.93-21 |] KXY AUGER - 99TC T 1.6-2.9 10.89 9 L AUGER - 99TC P 142.683 1 1/2- 6.0067 H 10 - 99TC N 1.0 1.0 1 1.0 - 99TC L 0 9/2+ 211.5E3 Y 11 - 99TC L 140.5108 107/2+ 0.221 NS 20 - 99TC G 140.511 1 88.5 2M1+E2 0.119 3 - 99TC2 G KC=0.104 3$LC=0.01290 39$MC=0.00236 7 - 99TC L 142.6833 111/2- 6.0067 H 10 - 99TC G 2.1726 4 7.4E-9 2E3 135E8 4 - 99TC2 G MC=119E8 3 - 99TC G 142.6830 100.023 2M4 40.9 8 - 99TC2 G KC=29.3 6$LC=9.35 20$MC=1.86 6 - - 99RU 99TC B- DECAY (6.0067 H) - 99RU T Auger electrons and X ray energies and emission intensities: - 99RU T {U Energy (keV)} {U Intensity} {U Line} - 99RU T - 99RU T 19.1506 XKA2 - 99RU T 19.2794 XKA1 - 99RU T - 99RU T 21.6349 |] XKB3 - 99RU T 21.6565 |] XKB1 - 99RU T 21.832 |] XKB5II - 99RU T - 99RU T 22.074 |] XKB2 - 99RU T 22.104 |] XKB4 - 99RU T - 99TC P 142.683 1 1/2- 6.0067 H 10 293.52 20 - 99RU N 2.50E4 2.50E4 0.00004 2.50E4 - 99RU L 0 5/2+ STABLE - 99RU B 436.3 2 0.0010 3 9.4 1U - 99RUS B EAV=152.3 5 - 99RU L 89.68 5 3/2+ 20.5 NS 1 - 99RU B 346.7 2 0.0026 5 8.7 1 - 99RUS B EAV=102.1 5 - 99RU G 89.6 3 0.00104 20M1+E2 1.49 5 - 99RU2 G KC=1.17 4$LC=0.27 1 - 99RU L 322.38 6 (3/2)+ - 99RU B 113.9 2 0.000106 6 8.5 1 - 99RUS B EAV=37.8 6 - 99RU G 232.7 2 8.4E-6 15 0.048 2 - 99RU2 G KC=0.0412 15 - 99RU G 322.4 1 0.000096 6 0.0175 5 - 99RU2 G KC=0.0152 5 - + 99TC 99TC IT DECAY (6.0067 H) + 99TC T Auger electrons and X ray energies and emission intensities: + 99TC T {U Energy (keV)} {U Intensity} {U Line} + 99TC T + 99TC T 18.251 2.22 7 XKA2 + 99TC T 18.3672 4.21 12 XKA1 + 99TC T + 99TC T 20.599 |] XKB3 + 99TC T 20.619 |] 1.12 4 XKB1 + 99TC T 20.789 |] XKB5II + 99TC T + 99TC T 21.005 |] XKB2 + 99TC T 21.042 |] 0.177 8 XKB4 + 99TC T + 99TC T 2.134-3.002 0.482 12 XL (total) + 99TC T 2.134 0.0110 4 XLL + 99TC T 2.42-2.425 0.298 10 XLA + 99TC T 2.25 0.00395 15 XLC + 99TC T 2.456-2.788 0.159 5 XLB + 99TC T 2.726-3.002 0.00984 26 XLG + 99TC T + 99TC T 14.86-15.58 |] KLL AUGER + 99TC T 17.43-18.33 |] 2.15 8 KLX AUGER + 99TC T 19.93-21 |] KXY AUGER + 99TC T 1.6-2.9 10.89 9 L AUGER + 99TC P 142.683 1 1/2- 6.0067 H 10 + 99TC N 1.0 1.0 1 + 99TC L 0 9/2+ 211.5E3 Y 11 + 99TC L 140.5108 107/2+ 0.221 NS 20 + 99TC G 140.511 1 88.5 2M1+E2 0.119 3 + 99TC2 G KC=0.104 3$LC=0.01290 39$MC=0.00236 7$NC=0.000414 12 + 99TC3 G OC=3.36E-5 10 + 99TC L 142.6833 111/2- 6.0067 H 10 + 99TC G 2.1726 4 7.4E-9 2E3 135E8 4 + 99TC2 G MC=119E8 3$NC=1.58E9 5 + 99TC G 142.6830 100.023 2M4 40.9 8 + 99TC2 G KC=29.3 6$LC=9.35 20$MC=1.86 6$NC=0.314 9 + 99TC3 G OC=0.01600 48 + + 99RU 99TC B- DECAY (6.0067 H) + 99RU T Auger electrons and X ray energies and emission intensities: + 99RU T {U Energy (keV)} {U Intensity} {U Line} + 99RU T + 99RU T 19.1506 XKA2 + 99RU T 19.2794 XKA1 + 99RU T + 99RU T 21.6349 |] XKB3 + 99RU T 21.6565 |] XKB1 + 99RU T 21.832 |] XKB5II + 99RU T + 99RU T 22.074 |] XKB2 + 99RU T 22.104 |] XKB4 + 99RU T + 99TC P 142.683 1 1/2- 6.0067 H 10 293.52 20 + 99RU N 2.50E4 2.50E4 0.00004 2.50E4 + 99RU L 0 5/2+ STABLE + 99RU B 436.3 2 0.0010 3 9.4 1U + 99RUS B EAV=152.3 5 + 99RU L 89.68 5 3/2+ 20.5 NS 1 + 99RU B 346.7 2 0.0026 5 8.7 1 + 99RUS B EAV=102.1 5 + 99RU G 89.6 3 0.00104 20M1+E2 1.49 5 + 99RU2 G KC=1.17 4$LC=0.27 1 + 99RU L 322.38 6 (3/2)+ + 99RU B 113.9 2 0.000106 6 8.5 1 + 99RUS B EAV=37.8 6 + 99RU G 232.7 2 8.4E-6 15 0.048 2 + 99RU2 G KC=0.0412 15 + 99RU G 322.4 1 0.000096 6 0.0175 5 + 99RU2 G KC=0.0152 5 + diff --git a/HEN_HOUSE/spectra/lnhb/Te-123m.txt b/HEN_HOUSE/spectra/lnhb/Te-123m.txt index b6b005b4f..46fc9b28d 100644 --- a/HEN_HOUSE/spectra/lnhb/Te-123m.txt +++ b/HEN_HOUSE/spectra/lnhb/Te-123m.txt @@ -1,42 +1,45 @@ -123TE 123TE IT DECAY (119.3 D) -123TE C References: 1955Fa40, 1955Go21, 1964Ch18, 1964Ch08, 1964Al28, 1966Ha03, -123TE2C 1966Gu02, 1969To02, 1968Ka20, 1970EmZY, 1972Ra07, 1973Ra32, 1973RaZO, -123TE3C 1977Kr13, 1992Ja15, 1992Co11, 1996Sc06, 2002Ba85 -123TE T Auger electrons and X ray energies and emission intensities: -123TE T {U Energy (keV)} {U Intensity} {U Line} -123TE T -123TE T 27.202 13.9 5 XKA2 -123TE T 27.4726 26.0 9 XKA1 -123TE T -123TE T 30.9446 |] XKB3 -123TE T 30.996 |] 7.43 26 XKB1 -123TE T 31.236 |] XKB5II -123TE T 31.241 |] XKB5I -123TE T -123TE T 31.7008 |] XKB2 -123TE T 31.774 |] 1.61 7 XKB4 -123TE T 31.812 |] XKO23 -123TE T -123TE T 3.336-4.82 8.25 21 XL (total) -123TE T 3.336 0.174 7 XLL -123TE T 3.76-3.77 4.60 15 XLA -123TE T 3.606 0.0469 18 XLC -123TE T 4.02-4.37 3.02 7 XLB -123TE T 4.44-4.82 0.411 11 XLG -123TE T -123TE T 21.804-22.989 |] KLL AUGER -123TE T 25.814-27.47 |] 7.0 4 KLX AUGER -123TE T 29.8-31.81 |] KXY AUGER -123TE T 2.3-4.8 89.7 7 L AUGER -123TE P 247.4 2 11/2- 119.3 D 1 -123TE N 1.0 1.0 1 1.0 -123TE L 0 1/2+ 12E12 Y -123TE L 158.99 3/2+ 196 PS 9 -123TE G 158.97 5 83.99 8M1+E2 0.0111 0.1918 19 -123TE2 G KC=0.1648 16$LC=0.02160 22$MC=0.00433 13 -123TE L 247.4 11/2- 119.5 D 1 -123TE G 88.46 7 0.0909 27M4 1099 33 -123TE2 G KC=463 14$LC=493 15$MC=118.0 35 -123TE G 247.4 2 0.00034434E5 7.75 30 -123TE2 G KC=3.0 1$LC=3.75 21$MC=0.84 3 - +123TE 123TE IT DECAY (119.3 D) +123TE C References:1955Fa40, 1955Go21, 1964Ch18, 1964Ch08, 1964Al28, 1966Ha03, +123TE2C 1966Gu02, 1969To02, 1968Ka20, 1970EmZY, 1972Ra07, 1973Ra32, 1973RaZO, +123TE3C 1977Kr13, 1992Ja15, 1992Co11, 1996Sc06, 2002Ba85 +123TE T Auger electrons and X ray energies and emission intensities: +123TE T {U Energy (keV)} {U Intensity} {U Line} +123TE T +123TE T 27.202 13.9 5 XKA2 +123TE T 27.4726 26.0 9 XKA1 +123TE T +123TE T 30.9446 |] XKB3 +123TE T 30.996 |] 7.43 26 XKB1 +123TE T 31.236 |] XKB5II +123TE T 31.241 |] XKB5I +123TE T +123TE T 31.7008 |] XKB2 +123TE T 31.774 |] 1.61 7 XKB4 +123TE T 31.812 |] XKO23 +123TE T +123TE T 3.336-4.82 8.25 21 XL (total) +123TE T 3.336 0.174 7 XLL +123TE T 3.76-3.77 4.60 15 XLA +123TE T 3.606 0.0469 18 XLC +123TE T 4.02-4.37 3.02 7 XLB +123TE T 4.44-4.82 0.411 11 XLG +123TE T +123TE T 21.804-22.989 |] KLL AUGER +123TE T 25.814-27.47 |] 7.0 4 KLX AUGER +123TE T 29.8-31.81 |] KXY AUGER +123TE T 2.3-4.8 89.7 7 L AUGER +123TE P 247.4 2 11/2- 119.3 D 1 +123TE N 1.0 1.0 1 +123TE L 0 1/2+ 12E12 Y +123TE L 158.99 3/2+ 196 PS 9 +123TE G 158.97 5 83.99 8M1+E2 0.0111 0.1918 19 +123TE2 G KC=0.1648 16$LC=0.02160 22$MC=0.00433 13$NC=0.000916 27 +123TE3 G OC=1.187E-4 36 +123TE L 247.4 11/2- 119.5 D 1 +123TE G 88.46 7 0.0909 27M4 1099 33 +123TE2 G KC=463 14$LC=493 15$MC=118.0 35$NC=22.8 7 +123TE3 G OC=1.97 6 +123TE G 247.4 2 0.00034434E5 7.75 30 +123TE2 G KC=3.0 1$LC=3.75 21$MC=0.84 3$NC=0.1572 47 +123TE3 G OC=0.01227 37 + diff --git a/HEN_HOUSE/spectra/lnhb/Te-127.txt b/HEN_HOUSE/spectra/lnhb/Te-127.txt index 5eabefd58..8b9abe8f6 100644 --- a/HEN_HOUSE/spectra/lnhb/Te-127.txt +++ b/HEN_HOUSE/spectra/lnhb/Te-127.txt @@ -1,73 +1,81 @@ -127I 127TE B- DECAY (9.35 H) -127I H TYP=Full$AUT=A.L. Nichols$CUT=31-MAY-2012$ -127I C Evaluation history: Type=Full;Author=A.L. Nichols;Cutoff date=31-MAY-2012 -127I C References: 1940Se01, 1956Kn20, 1963Ma20, 1965Au01, 1966Ne02, 1967Ge10, -127I 2C 1968Qa02, 1970Ap02, 1970Bo22, 1977La19, 1977Ge10, 1977Kr13, 1980Kr22, -127I 3C 1996Sc06, 1998ScZM, 1999ScZX, 2002Ba25, 2002Ra45, 2003Au03, 2003De44, -127I 4C 2008Ki07, 2011Ha31, 2012Au06 -127I T Auger electrons and X ray energies and emission intensities: -127I T {U Energy (keV)} {U Intensity} {U Line} -127I T -127I T 28.3175 0.0309 7 XKA2 -127I T 28.6123 0.0574 12 XKA1 -127I T -127I T 32.2397 |] XKB3 -127I T 32.2951 |] 0.0165 4 XKB1 -127I T 32.539 |] XKB5II -127I T 32.55 |] XKB5I -127I T -127I T 33.042 |] XKB2 -127I T 33.12 |] 0.00374 12 XKB4 -127I T 33.166 |] XKO23 -127I T -127I T 3.485-5.06 0.0119 6 XL (total) -127I T 3.485 0.000226 8 XLL -127I T 3.927-3.938 0.00597 18 XLA -127I T 3.779 0.000088 3 XLC -127I T 4.221-4.508 0.00476 11 XLB -127I T 4.801-5.06 0.00067817 XLG -127I T -127I T 22.659-23.909 |] KLL AUGER -127I T 26.853-28.609 |] 0.0145 6 KLX AUGER -127I T 31.02-33.16 |] KXY AUGER -127I T 2.38-3.88 0.1174 18 L AUGER -127TE P 0.0 3/2+ 9.35 H 10 702 4 -127I N 1.0 1.0 1 1.0 -127I L 0 5/2+ STABLE -127I B 702 4 98.780 14 5.49 -127I S B EAV=227.8 16 -127I L 57.608 117/2+ -127I G 57.608 110.0306 6M1+E2 -0.083 5 3.72 6 -127I 2 G KC=3.16 5$LC=0.449 8$MC=0.0910 16 -127I L 202.860 8 3/2+ -127I B 499 4 0.025 3 8.57 -127I S B EAV=153.0 15 -127I G 145.252 140.0040 6E2 0.471 7 -127I 2 G KC=0.357 5$LC=0.0907 13$MC=0.0189 3 -127I G 202.860 8 0.056 2M1+E2 0.52 5 0.1143 22 -127I 2 G KC=0.0965 17$LC=0.0142 5$MC=0.00289 10 -127I L 374.992 9 1/2+ -127I B 327 4 0.0006 3 9.58 -127I S B EAV=94.5 13 -127I G 172.132 120.0003 2M1+E2 -0.085 6 0.1650 24 -127I 2 G KC=0.1419 20$LC=0.0185 3$MC=0.00373 6 -127I G 374.991 9 0.0003 2E2 0.0199 3 -127I 2 G KC=0.01671 24$LC=0.00257 4$MC=5.24E-4 8 -127I L 417.99 6 5/2+ -127I B 284 4 1.19 2 6.086 -127I S B EAV=80.7 13 -127I G 215.13 6 0.039 2M1+E2 -0.203 15 0.0910 13 -127I 2 G KC=0.0782 11$LC=0.01031 16$MC=0.00208 4 -127I G 360.38 6 0.136 2M1+E2 0.194 15 0.0232 4 -127I 2 G KC=0.0201 3$LC=0.00256 4$MC=5.14E-4 8 -127I G 417.99 6 0.997 11M1+E2 -0.08 3 0.0159823 -127I 2 G KC=0.01381 20$LC=1741E-6 25$MC=3.50E-4 5 -127I L 618.31 133/2+ -127I B 84 4 0.00013 2 8.38 -127I S B EAV=21.8 11 -127I G 618.31 130.00013 2M1+E2 1.0 5 0.0055 4 -127I 2 G KC=0.0047 4$LC=0.00061 3$MC=1.23E-4 6 -127I L 628.69 167/2+ -127I L 650.92 8 9/2+ -127I L 716.50 6 (11/2)+ - +127I 127TE B- DECAY (9.35 H) +127I H TYP=FUL$AUT=A.L.NICHOLS$CUT=31-MAY-2012$ +127I C References:1940Se01, 1956Kn20, 1963Ma20, 1965Au01, 1966Ne02, 1967Ge10, +127I 2C 1968Qa02, 1970Ap02, 1970Bo22, 1977La19, 1977Ge10, 1977Kr13, 1980Kr22, +127I 3C 1996Sc06, 1998ScZM, 1999ScZX, 2002Ba25, 2002Ra45, 2003Au03, 2003De44, +127I 4C 2008Ki07, 2011Ha31, 2012Au06 +127I T Auger electrons and X ray energies and emission intensities: +127I T {U Energy (keV)} {U Intensity} {U Line} +127I T +127I T 28.3175 0.0309 7 XKA2 +127I T 28.6123 0.0574 12 XKA1 +127I T +127I T 32.2397 |] XKB3 +127I T 32.2951 |] 0.0165 4 XKB1 +127I T 32.539 |] XKB5II +127I T 32.55 |] XKB5I +127I T +127I T 33.042 |] XKB2 +127I T 33.12 |] 0.00374 12 XKB4 +127I T 33.166 |] XKO23 +127I T +127I T 3.485-5.06 0.0119 6 XL (total) +127I T 3.485 0.000226 8 XLL +127I T 3.927-3.938 0.00597 18 XLA +127I T 3.779 0.000088 3 XLC +127I T 4.221-4.508 0.00476 11 XLB +127I T 4.801-5.06 0.00067817 XLG +127I T +127I T 22.659-23.909 |] KLL AUGER +127I T 26.853-28.609 |] 0.0145 6 KLX AUGER +127I T 31.02-33.16 |] KXY AUGER +127I T 2.38-3.88 0.1174 18 L AUGER +127TE P 0.0 3/2+ 9.35 H 10 702 4 +127I N 1.0 1.0 1 1.0 +127I L 0 5/2+ STABLE +127I B 702 4 98.780 14 5.49 +127I S B EAV=227.8 16 +127I L 57.608 117/2+ +127I G 57.608 110.0306 6M1+E2 -0.083 5 3.72 6 +127I 2 G KC=3.16 5$LC=0.449 8$MC=0.0910 16$NC=0.0183 4 +127I 3 G OC=0.00209 4 +127I L 202.860 8 3/2+ +127I B 499 4 0.025 3 8.57 +127I S B EAV=153.0 15 +127I G 145.252 140.0040 6E2 0.471 7 +127I 2 G KC=0.357 5$LC=0.0907 13$MC=0.0189 3$NC=0.00369 6 +127I 3 G OC=0.000362 5 +127I G 202.860 8 0.056 2M1+E2 0.52 5 0.1143 22 +127I 2 G KC=0.0965 17$LC=0.0142 5$MC=0.00289 10$NC=0.000580 18 +127I 3 G OC=6.50E-5 17 +127I L 374.992 9 1/2+ +127I B 327 4 0.0006 3 9.58 +127I S B EAV=94.5 13 +127I G 172.132 120.0003 2M1+E2 -0.085 6 0.1650 24 +127I 2 G KC=0.1419 20$LC=0.0185 3$MC=0.00373 6$NC=0.000754 11 +127I 3 G OC=8.82E-5 13 +127I G 374.991 9 0.0003 2E2 0.0199 3 +127I 2 G KC=0.01671 24$LC=0.00257 4$MC=0.000524 8$NC=1.044E-4 15 +127I 3 G OC=1.144E-5 16 +127I L 417.99 6 5/2+ +127I B 284 4 1.19 2 6.086 +127I S B EAV=80.7 13 +127I G 215.13 6 0.039 2M1+E2 -0.203 15 0.0910 13 +127I 2 G KC=0.0782 11$LC=0.01031 16$MC=0.00208 4$NC=0.000420 7 +127I 3 G OC=4.89E-5 7 +127I G 360.38 6 0.136 2M1+E2 0.194 15 0.0232 4 +127I 2 G KC=0.0201 3$LC=0.00256 4$MC=0.000514 8$NC=1.041E-4 15 +127I 3 G OC=1.222E-5 18 +127I G 417.99 6 0.997 11M1+E2 -0.08 3 0.0159823 +127I 2 G KC=0.01381 20$LC=0.001741 25$MC=0.000350 5$NC=7.08E-5 10 +127I 3 G OC=8.34E-6 12 +127I L 618.31 133/2+ +127I B 84 4 0.00013 2 8.38 +127I S B EAV=21.8 11 +127I G 618.31 130.00013 2M1+E2 1.0 5 0.0055 4 +127I 2 G KC=0.0047 4$LC=0.00061 3$MC=0.000123 6$NC=2.47E-5 13 +127I 3 G OC=2.87E-6 18 +127I L 628.69 167/2+ +127I L 650.92 8 9/2+ +127I L 716.50 6 (11/2)+ + diff --git a/HEN_HOUSE/spectra/lnhb/Te-127m.txt b/HEN_HOUSE/spectra/lnhb/Te-127m.txt index db89df7d7..c8f7a75d9 100644 --- a/HEN_HOUSE/spectra/lnhb/Te-127m.txt +++ b/HEN_HOUSE/spectra/lnhb/Te-127m.txt @@ -1,104 +1,108 @@ -127TE 127TE IT DECAY (106.1 D) -127TE H TYP=Full$AUT=A.L. Nichols$CUT=31-MAY-2012$ -127TE C Evaluation history: Type=Full;Author=A.L. Nichols;Cutoff date=31-MAY-2012 -127TE C References: 1940Se01, 1951Co34, 1956Kn20, 1965Au01, 1965An05, 1966Ne02, -127TE2C 1967Ge10, 1970Ap02, 1972Ka31, 1972Ka61, 1977So06, 1977Kr13, 1977La19, -127TE3C 1980Kr22, 1996Sc06, 1998ScZM, 1999ScZX, 2002Ba25, 2002Ra45, 2003Au03, -127TE4C 2003De44, 2008Ea01, 2008Ki07, 2011Ha31, 2012Au06 -127TE T Auger electrons and X ray energies and emission intensities: -127TE T {U Energy (keV)} {U Intensity} {U Line} -127TE T -127TE T 27.202 10.3 3 XKA2 -127TE T 27.4726 19.3 5 XKA1 -127TE T -127TE T 30.9446 |] XKB3 -127TE T 30.996 |] 5.51 15 XKB1 -127TE T 31.232 |] XKB5II -127TE T 31.242 |] XKB5I -127TE T -127TE T 31.7008 |] XKB2 -127TE T 31.774 |] 1.20 5 XKB4 -127TE T 31.182 |] XKO23 -127TE T -127TE T 3.335-4.829 7.0 3 XL (total) -127TE T 3.335 0.146 5 XLL -127TE T 3.759-3.77 3.86 11 XLA -127TE T 3.605 0.0369 13 XLC -127TE T 4.03-4.302 2.45 5 XLB -127TE T 4.572-4.829 0.333 8 XLG -127TE T -127TE T 21.804-22.989 |] KLL AUGER -127TE T 25.814-27.47 |] 5.19 21 KLX AUGER -127TE T 29.8-31.81 |] KXY AUGER -127TE T 2.29-3.72 74.3 10 L AUGER -127TE P 88.23 7 11/2- 106.1 D 7 -127TE N 1.028E0 1.028E0 0.972699 1.028E0 -127TE L 0 3/2+ 9.35 H 10 -127TE L 61.161 191/2+ -127TE L 88.23 7 11/2- 106.1 D 7 -127TE G 88.23 7 0.0854 16M4 1138 17 -127TE2 G KC=486 7$LC=506 8$MC=120.4 18 - -127I 127TE B- DECAY (106.1 D) -127I H TYP=Full$AUT=A.L. Nichols$CUT=31-MAY-2012$ -127I C Evaluation history: Type=Full;Author=A.L. Nichols;Cutoff date=31-MAY-2012 -127I C References: 1940Se01, 1951Co34, 1956Kn20, 1965Au01, 1965An05, 1966Ne02, -127I 2C 1967Ge10, 1970Ap02, 1972Ka31, 1972Ka61, 1977So06, 1977Kr13, 1977La19, -127I 3C 1980Kr22, 1996Sc06, 1998ScZM, 1999ScZX, 2002Ba25, 2002Ra45, 2003Au03, -127I 4C 2003De44, 2008Ea01, 2008Ki07, 2011Ha31, 2012Au06 -127I T Auger electrons and X ray energies and emission intensities: -127I T {U Energy (keV)} {U Intensity} {U Line} -127I T -127I T 28.3175 0.459 12 XKA2 -127I T 28.6123 0.852 21 XKA1 -127I T -127I T 32.2397 |] XKB3 -127I T 32.2951 |] 0.245 7 XKB1 -127I T 32.539 |] XKB5II -127I T 32.55 |] XKB5I -127I T -127I T 33.042 |] XKB2 -127I T 33.12 |] 0.0555 19 XKB4 -127I T 33.166 |] XKO23 -127I T -127I T 3.485-5.06 0.177 9 XL (total) -127I T 3.485 0.00336 11 XLL -127I T 3.927-3.938 0.089 3 XLA -127I T 3.779 0.00130 5 XLC -127I T 4.221-4.508 0.0707 17 XLB -127I T 4.801-5.06 0.0101 3 XLG -127I T -127I T 22.659-23.909 |] KLL AUGER -127I T 26.853-28.609 |] 0.216 9 KLX AUGER -127I T 31.02-33.16 |] KXY AUGER -127I T 2.37-3.88 1.74 3 L AUGER -127TE P 88.23 7 11/2- 106.1 D 7 701.8 40 -127I N 3.663E1 3.663E1 0.0273 3.663E1 -127I L 0 5/2+ STABLE -127I L 57.608 117/2+ -127I B 732 4 2.71 7 9.873 1U -127I S B EAV=255.9 15 -127I G 57.608 110.578 10M1+E2 -0.083 5 3.72 6 -127I 2 G KC=3.16 5$LC=0.449 8$MC=0.0910 16 -127I L 202.860 8 3/2+ -127I L 374.992 9 1/2+ -127I L 417.99 6 5/2+ -127I L 618.31 133/2+ -127I L 628.69 167/2+ -127I B 161 4 0.00009 2 11.3 1U -127I S B EAV=52.9 14 -127I G 628.69 160.00009 2M1+E2 1.0 5 0.0052 4 -127I 2 G KC=0.0045 4$LC=0.00058 3$MC=1.17E-4 6 -127I L 650.92 8 9/2+ -127I B 139 4 0.0027 2 10.18 1 -127I S B EAV=37.2 12 -127I G 593.31 8 0.0024 2M1+E2 -0.23 3 0.0066810 -127I 2 G KC=0.00578 9$LC=7.22E-4 11$MC=1448E-7 21 -127I G 650.92 8 0.0003 2E2 0.00423 6 -127I 2 G KC=0.00362 5$LC=4.88E-4 7$MC=9.85E-5 14 -127I L 716.50 6 11/2+ -127I B 74 4 0.0141 6 8.61 -127I S B EAV=19.1 11 -127I G 658.89 6 0.0140 6E2 0.00410 6 -127I 2 G KC=0.00351 5$LC=4.72E-4 7$MC=9.53E-5 14 - +127TE 127TE IT DECAY (106.1 D) +127TE H TYP=FUL$AUT=A.L.NICHOLS$CUT=31-MAY-2012$ +127TE C References:1940Se01, 1951Co34, 1956Kn20, 1965Au01, 1965An05, 1966Ne02, +127TE2C 1967Ge10, 1970Ap02, 1972Ka31, 1972Ka61, 1977So06, 1977Kr13, 1977La19, +127TE3C 1980Kr22, 1996Sc06, 1998ScZM, 1999ScZX, 2002Ba25, 2002Ra45, 2003Au03, +127TE4C 2003De44, 2008Ea01, 2008Ki07, 2011Ha31, 2012Au06 +127TE T Auger electrons and X ray energies and emission intensities: +127TE T {U Energy (keV)} {U Intensity} {U Line} +127TE T +127TE T 27.202 10.3 3 XKA2 +127TE T 27.4726 19.3 5 XKA1 +127TE T +127TE T 30.9446 |] XKB3 +127TE T 30.996 |] 5.51 15 XKB1 +127TE T 31.232 |] XKB5II +127TE T 31.242 |] XKB5I +127TE T +127TE T 31.7008 |] XKB2 +127TE T 31.774 |] 1.20 5 XKB4 +127TE T 31.182 |] XKO23 +127TE T +127TE T 3.335-4.829 7.0 3 XL (total) +127TE T 3.335 0.146 5 XLL +127TE T 3.759-3.77 3.86 11 XLA +127TE T 3.605 0.0369 13 XLC +127TE T 4.03-4.302 2.45 5 XLB +127TE T 4.572-4.829 0.333 8 XLG +127TE T +127TE T 21.804-22.989 |] KLL AUGER +127TE T 25.814-27.47 |] 5.19 21 KLX AUGER +127TE T 29.8-31.81 |] KXY AUGER +127TE T 2.29-3.72 74.3 10 L AUGER +127TE P 88.23 7 11/2- 106.1 D 7 +127TE N 1.028E0 1.028E0 0.972700 +127TE L 0 3/2+ 9.35 H 10 +127TE L 61.161 191/2+ +127TE L 88.23 7 11/2- 106.1 D 7 +127TE G 88.23 7 0.0854 16M4 1138 17 +127TE2 G KC=486 7$LC=506 8$MC=120.4 18$NC=23.2 4 +127TE3 G OC=2.00 3 + +127I 127TE B- DECAY (106.1 D) +127I H TYP=FUL$AUT=A.L.NICHOLS$CUT=31-MAY-2012$ +127I C References:1940Se01, 1951Co34, 1956Kn20, 1965Au01, 1965An05, 1966Ne02, +127I 2C 1967Ge10, 1970Ap02, 1972Ka31, 1972Ka61, 1977So06, 1977Kr13, 1977La19, +127I 3C 1980Kr22, 1996Sc06, 1998ScZM, 1999ScZX, 2002Ba25, 2002Ra45, 2003Au03, +127I 4C 2003De44, 2008Ea01, 2008Ki07, 2011Ha31, 2012Au06 +127I T Auger electrons and X ray energies and emission intensities: +127I T {U Energy (keV)} {U Intensity} {U Line} +127I T +127I T 28.3175 0.459 12 XKA2 +127I T 28.6123 0.852 21 XKA1 +127I T +127I T 32.2397 |] XKB3 +127I T 32.2951 |] 0.245 7 XKB1 +127I T 32.539 |] XKB5II +127I T 32.55 |] XKB5I +127I T +127I T 33.042 |] XKB2 +127I T 33.12 |] 0.0555 19 XKB4 +127I T 33.166 |] XKO23 +127I T +127I T 3.485-5.06 0.177 9 XL (total) +127I T 3.485 0.00336 11 XLL +127I T 3.927-3.938 0.089 3 XLA +127I T 3.779 0.00130 5 XLC +127I T 4.221-4.508 0.0707 17 XLB +127I T 4.801-5.06 0.0101 3 XLG +127I T +127I T 22.659-23.909 |] KLL AUGER +127I T 26.853-28.609 |] 0.216 9 KLX AUGER +127I T 31.02-33.16 |] KXY AUGER +127I T 2.37-3.88 1.74 3 L AUGER +127TE P 88.23 7 11/2- 106.1 D 7 701.8 40 +127I N 3.663E1 3.663E1 0.0273 3.663E1 +127I L 0 5/2+ STABLE +127I L 57.608 117/2+ +127I B 732 4 2.71 7 9.873 1U +127I S B EAV=255.9 15 +127I G 57.608 110.578 10M1+E2 -0.083 5 3.72 6 +127I 2 G KC=3.16 5$LC=0.449 8$MC=0.0910 16$NC=0.0183 4 +127I 3 G OC=0.00209 4 +127I L 202.860 8 3/2+ +127I L 374.992 9 1/2+ +127I L 417.99 6 5/2+ +127I L 618.31 133/2+ +127I L 628.69 167/2+ +127I B 161 4 0.00009 2 11.3 1U +127I S B EAV=52.9 14 +127I G 628.69 160.00009 2M1+E2 1.0 5 0.0052 4 +127I 2 G KC=0.0045 4$LC=0.00058 3$MC=0.000117 6$NC=2.37E-5 13 +127I 3 G OC=2.75E-6 17 +127I L 650.92 8 9/2+ +127I B 139 4 0.0027 2 10.18 1 +127I S B EAV=37.2 12 +127I G 593.31 8 0.0024 2M1+E2 -0.23 3 0.0066810 +127I 2 G KC=0.00578 9$LC=0.000722 11$MC=1.448E-4 21$NC=2.93E-5 5 +127I 3 G OC=3.46E-6 5 +127I G 650.92 8 0.0003 2E2 0.00423 6 +127I 2 G KC=0.00362 5$LC=0.000488 7$MC=9.85E-5 14$NC=1.98E-5 3 +127I 3 G OC=2.26E-6 4 +127I L 716.50 6 11/2+ +127I B 74 4 0.0141 6 8.61 +127I S B EAV=19.1 11 +127I G 658.89 6 0.0140 6E2 0.00410 6 +127I 2 G KC=0.00351 5$LC=0.000472 7$MC=9.53E-5 14$NC=1.92E-5 3 +127I 3 G OC=2.19E-6 3 + diff --git a/HEN_HOUSE/spectra/lnhb/Te-132.txt b/HEN_HOUSE/spectra/lnhb/Te-132.txt index 8d60b0b3c..0be7bb556 100644 --- a/HEN_HOUSE/spectra/lnhb/Te-132.txt +++ b/HEN_HOUSE/spectra/lnhb/Te-132.txt @@ -1,50 +1,51 @@ -132I 132TE B- DECAY (3.230 D) -132I H TYP=Full$AUT=A.Nichols$CUT=31-MAR-2009$ -132I 2 H TYP=Full$AUT=A.Nichols$CUT=31-MAR-2009$ -132I C Evaluation history: Type=Full;Author=A.Nichols;Cutoff date=31-MAR-2009 -132I 2C Type=Full;Author=A.Nichols;Cutoff date=31-MAR-2009 -132I C References: 1956Fl15, 1958Ch28, 1965An05, 1966Fr02, 1971BaZW, 1977La19, -132I 2C 1979Bo26, 1981Yo02, 1983Wa26, 1996Sc06, 1998ScZM, 1999ScZX, 2002Ba85, -132I 3C 2002Ra45, 2003Au03, 2005Kh07, 2008Ki07 -132I T Auger electrons and X ray energies and emission intensities: -132I T {U Energy (keV)} {U Intensity} {U Line} -132I T -132I T 28.3175 20.6 5 XKA2 -132I T 28.6123 38.2 9 XKA1 -132I T -132I T 32.2397 |] XKB3 -132I T 32.2951 |] 11.0 3 XKB1 -132I T 32.544 |] XKB5II -132I T -132I T 33.042 |] XKB2 -132I T 33.12 |] 2.49 9 XKB4 -132I T 33.166 |] XKO23 -132I T -132I T 3.485-5.065 7.9 4 XL (total) -132I T 3.485 XLL -132I T 3.926-3.938 3.96 12 XLA -132I T 3.78 0.0583 20 XLC -132I T 4.221-4.508 3.16 8 XLB -132I T 4.802-5.065 0.451 12 XLG -132I T -132I T 22.659-23.909 |] KLL AUGER -132I T 26.853-28.609 |] 9.7 3 KLX AUGER -132I T 31.02-33.16 |] KXY AUGER -132I T 2.37-3.88 78.0 13 L AUGER -132TE P 0.0 0+ 3.230 D 13 518 4 -132I N 1.0 1.0 1 1.0 -132I L 0 4+ 2.295 H 13 -132I L 49.72 1 3+ 7.14 NS 14 -132I G 49.72 1 15.1 3M1 5.62 8 -132I 2 G KC=4.83 7$LC=0.638 9$MC=0.1286 18 -132I L 161.52 7 2+ 3.57 NS 7 -132I G 111.81 8 1.85 18M1+E2 0.58 6 0.71 3 -132I 2 G KC=0.562 17$LC=0.115 9$MC=0.0238 18 -132I L 277.86 6 1+ 1.42 NS 2 -132I B 240 4 100 4.85 -132I S B EAV=67.0 13 -132I G 116.34 131.97 7M1+E2 0.53 5 0.606 20 -132I 2 G KC=0.489 13$LC=0.093 6$MC=0.0193 13 -132I G 228.327 3 88.12 13E2 0.0990 14 -132I 2 G KC=0.0802 12$LC=0.01507 21$MC=0.00311 5 - +132I 132TE B- DECAY (3.230 D) +132I H TYP=FUL$AUT=A.L.NICHOLS$CUT=31-MAR-2009$ +132I C References:1956Fl15, 1958Ch28, 1965An05, 1966Fr02, 1971BaZW, 1977La19, +132I 2C 1979Bo26, 1981Yo02, 1983Wa26, 1996Sc06, 1998ScZM, 1999ScZX, 2002Ba85, +132I 3C 2002Ra45, 2003Au03, 2005Kh07, 2008Ki07 +132I T Auger electrons and X ray energies and emission intensities: +132I T {U Energy (keV)} {U Intensity} {U Line} +132I T +132I T 28.3175 20.6 5 XKA2 +132I T 28.6123 38.2 9 XKA1 +132I T +132I T 32.2397 |] XKB3 +132I T 32.2951 |] 11.0 3 XKB1 +132I T 32.544 |] XKB5II +132I T +132I T 33.042 |] XKB2 +132I T 33.12 |] 2.49 9 XKB4 +132I T 33.166 |] XKO23 +132I T +132I T 3.485-5.065 7.9 4 XL (total) +132I T 3.485 XLL +132I T 3.926-3.938 3.96 12 XLA +132I T 3.78 0.0583 20 XLC +132I T 4.221-4.508 3.16 8 XLB +132I T 4.802-5.065 0.451 12 XLG +132I T +132I T 22.659-23.909 |] KLL AUGER +132I T 26.853-28.609 |] 9.7 3 KLX AUGER +132I T 31.02-33.16 |] KXY AUGER +132I T 2.37-3.88 78.0 13 L AUGER +132TE P 0.0 0+ 3.230 D 13 518 4 +132I N 1.0 1.0 1 1.0 +132I L 0 4+ 2.295 H 13 +132I L 49.72 1 3+ 7.14 NS 14 +132I G 49.72 1 15.1 3M1 5.62 8 +132I 2 G KC=4.83 7$LC=0.638 9$MC=0.1286 18$NC=0.0260 4 +132I 3 G OC=0.00303 5 +132I L 161.52 7 2+ 3.57 NS 7 +132I G 111.81 8 1.85 18M1+E2 0.58 6 0.71 3 +132I 2 G KC=0.562 17$LC=0.115 9$MC=0.0238 18$NC=0.0047 4 +132I 3 G OC=0.00048 3 +132I L 277.86 6 1+ 1.42 NS 2 +132I B 240 4 100 4.85 +132I S B EAV=67.0 13 +132I G 116.34 131.97 7M1+E2 0.53 5 0.606 20 +132I 2 G KC=0.489 13$LC=0.093 6$MC=0.0193 13$NC=0.00380 24 +132I 3 G OC=0.000400 22 +132I G 228.327 3 88.12 13E2 0.0990 14 +132I 2 G KC=0.0802 12$LC=0.01507 21$MC=0.00311 5$NC=0.000612 9 +132I 3 G OC=6.37E-5 9 + diff --git a/HEN_HOUSE/spectra/lnhb/Th-228.txt b/HEN_HOUSE/spectra/lnhb/Th-228.txt index 121c11713..23eb827cf 100644 --- a/HEN_HOUSE/spectra/lnhb/Th-228.txt +++ b/HEN_HOUSE/spectra/lnhb/Th-228.txt @@ -1,83 +1,96 @@ -224RA 228TH A DECAY (1.9126 Y) -224RA H TYP=Update$AUT=A.L.Nichols$CUT=30-APR-2010$ -224RA C Evaluation history: Type=Update;Author=A.L.Nichols;Cutoff date=30-APR-2010 -224RA C References: 1918Me01, 1953As31, 1956Ki16, 1962Ma57, 1966Co40, 1968Da21, -224RA2C 1968Du06, 1969Pe17, 1970Ba20, 1970SpZW, 1971Jo14, 1971Gr07, 1976BaZZ, -224RA3C 1977La19, 1977Ku15, 1981Ku02, 1982Sa36, 1984Ge07, 1991Ry01, 1992Un01, -224RA4C 1993Bo20, 1993Ba72, 1995Ar33, 1996Sc06, 1997Ar05, 1997Tr17, 1998Ak04, -224RA5C 1998ScZM, 1999ScZX, 2002Un02, 2002Ba85, 2002Ra45, 2003Au03, 2007BeZP, -224RA6C 2008Ki07 -224RA T Auger electrons and X ray energies and emission intensities: -224RA T {U Energy (keV)} {U Intensity} {U Line} -224RA T -224RA T 85.43 0.0180 3 XKA2 -224RA T 88.47 0.0295 5 XKA1 -224RA T -224RA T 99.432 |] XKB3 -224RA T 100.13 |] 0.01034 21 XKB1 -224RA T 100.738 |] XKB5II -224RA T -224RA T 102.89 |] XKB2 -224RA T 103.295 |] 0.00339 9 XKB4 -224RA T 103.74 |] XKO23 -224RA T -224RA T 10.6241-18.3539 8.6 4 XL (total) -224RA T 10.6241 0.166 6 XLL -224RA T 12.1957-12.3381 2.86 9 XLA -224RA T 13.6624 0.109 4 XLC -224RA T 14.2373-16.1261 4.67 15 XLB -224RA T 17.2756-18.3539 1.09 4 XLG -224RA T -224RA T 65.149-72.729 |] KLL AUGER -224RA T 79.721-88.466 |] 0.0020 3 KLX AUGER -224RA T 94.27-103.91 |] KXY AUGER -224RA T 5.71-12.04 10.4 4 L AUGER -228TH P 0.0 0+ 1.9126 Y 9 5520.08 22 -224RA N 1.0 1.0 1 1.0 -224RA L 0 0+ 3.631 D 2 -224RA A 5423.24 2273.4 5 1 -224RA L 84.373 3 2+ -224RA A 5340.35 2226.0 5 0.958 -224RA G 84.373 3 1.19 3E2 21.2 3 -224RA2 G LC=15.57 22$MC=4.24 6 -224RA L 215.985 4 1- -224RA A 5211.05 220.408 7 10.7 -224RA G 131.612 5 0.127 2E1 0.247 4 -224RA2 G KC=0.194 3$LC=0.0406 6$MC=0.00977 14 -224RA G 215.985 4 0.246 4E1 0.0752 11 -224RA2 G KC=0.0600 9$LC=0.01148 16$MC=0.00274 4 -224RA L 250.783 5 4+ -224RA A 5176.86 220.218 4 12.5 -224RA G 166.410 4 0.1004 14E2 1.164 17 -224RA2 G KC=0.225 4$LC=0.691 10$MC=0.187 3 -224RA L 290.36 4 (3)- -224RA A 5137.97 220.036 6 44 -224RA G 74.38 4 0.00039 14[E2] 38.6 6 -224RA2 G LC=28.3 4$MC=7.71 11 -224RA G 205.99 4 0.0188 5[E1] 0.0841 12 -224RA2 G KC=0.0671 10$LC=0.01292 18$MC=0.00309 5 -224RA L 433.07 10(5)- -224RA A 4997.76 2410000E-92 21400 -224RA G 142.71 111.3E-6 4[E2] 2.14 3 -224RA2 G KC=0.279 4$LC=1.368 20$MC=0.372 6 -224RA G 182.29 105.1E-6 18[E1] 0.1126 16 -224RA2 G KC=0.0894 13$LC=0.01757 25$MC=0.00421 6 -224RA L 479.20 18(6)+ -224RA A 4952.5 3 24000E-95 4600 -224RA G 228.42 180.000018 4[E2] 0.366 6 -224RA2 G KC=0.1244 18$LC=0.178 3$MC=0.0479 7 -224RA L 916.34 7 0+ -224RA A 4522.97 2317000E-93 7 -224RA G 700.36 7 0.000003 1E1 0.00611 9 -224RA2 G KC=0.00502 7$LC=8.34E-4 12$MC=1.96E-4 3 -224RA G 831.97 7 0.000014 2E2 0.0128918 -224RA2 G KC=0.00970 14$LC=0.00240 4$MC=5.94E-4 9 -224RA L 992.65 6 (2)+ -224RA A 4448.00 2345000E-17 7.2 -224RA G 741.87 6 1.4E-6 4[E2] 0.0162523 -224RA2 G KC=0.01196 17$LC=0.00322 5$MC=8.03E-4 12 -224RA G 908.28 6 1.7E-6 5[M1+E2] 1.0 2 0.024 3 -224RA2 G KC=0.0190 24$LC=0.0036 4$MC=0.00087 9 -224RA G 992.65 6 1.4E-6 4[E2] 0.0091313 -224RA2 G KC=0.00705 10$LC=1569E-6 22$MC=3.84E-4 6 - +224RA 228TH A DECAY (1.9126 Y) +224RA H TYP=UPD$AUT=A.L.NICHOLS$CUT=30-APR-2010$ +224RA C References:1918Me01, 1953As31, 1956Ki16, 1962Ma57, 1966Co40, 1968Da21, +224RA2C 1968Du06, 1969Pe17, 1970Ba20, 1970SpZW, 1971Jo14, 1971Gr07, 1976BaZZ, +224RA3C 1977La19, 1977Ku15, 1977Ku25, 1981Ku02, 1982Sa36, 1984Ge07, 1991Ry01, +224RA4C 1992Un01, 1993Bo20, 1993Ba72, 1995Ar33, 1996Sc06, 1997Ar05, 1997Tr17, +224RA5C 1998Ak04, 1998ScZM, 1999ScZX, 2002Un02, 2002Ba85, 2002Ra45, 2003Au03, +224RA6C 2007BeZP, 2008Ki07 +224RA T Auger electrons and X ray energies and emission intensities: +224RA T {U Energy (keV)} {U Intensity} {U Line} +224RA T +224RA T 85.43 0.0180 3 XKA2 +224RA T 88.47 0.0295 5 XKA1 +224RA T +224RA T 99.432 |] XKB3 +224RA T 100.13 |] 0.01034 21 XKB1 +224RA T 100.738 |] XKB5II +224RA T +224RA T 102.89 |] XKB2 +224RA T 103.295 |] 0.00339 9 XKB4 +224RA T 103.74 |] XKO23 +224RA T +224RA T 10.6241-18.3539 8.6 4 XL (total) +224RA T 10.6241 0.166 6 XLL +224RA T 12.1957-12.3381 2.86 9 XLA +224RA T 13.6624 0.109 4 XLC +224RA T 14.2373-16.1261 4.67 15 XLB +224RA T 17.2756-18.3539 1.09 4 XLG +224RA T +224RA T 65.149-72.729 |] KLL AUGER +224RA T 79.721-88.466 |] 0.0020 3 KLX AUGER +224RA T 94.27-103.91 |] KXY AUGER +224RA T 5.71-12.04 10.4 4 L AUGER +228TH P 0.0 0+ 1.9126 Y 9 5520.08 22 +224RA N 1.0 1.0 1 +224RA L 0 0+ 3.631 D 2 +224RA A 5423.24 2273.4 51 +224RA L 84.373 3 2+ +224RA A 5340.35 2226.0 50.958 +224RA G 84.373 3 1.19 3E2 21.2 3 +224RA2 G LC=15.57 22$MC=4.24 6$NC=1.119 16 +224RA3 G OC=0.238 4 +224RA L 215.985 4 1- +224RA A 5211.05 220.408 710.7 +224RA G 131.612 5 0.127 2E1 0.247 4 +224RA2 G KC=0.194 3$LC=0.0406 6$MC=0.00977 14$NC=0.00254 4 +224RA3 G OC=0.000559 8 +224RA G 215.985 4 0.246 4E1 0.0752 11 +224RA2 G KC=0.0600 9$LC=0.01148 16$MC=0.00274 4$NC=0.000717 10 +224RA3 G OC=1.593E-4 23 +224RA L 250.783 5 4+ +224RA A 5176.86 220.218 412.5 +224RA G 166.410 4 0.1004 14E2 1.164 17 +224RA2 G KC=0.225 4$LC=0.691 10$MC=0.187 3$NC=0.0495 7 +224RA3 G OC=0.01056 15 +224RA L 290.36 4 (3)- +224RA A 5137.97 220.036 644 +224RA G 74.38 4 0.00039 14[E2] 38.6 6 +224RA2 G LC=28.3 4$MC=7.71 11$NC=2.03 3 +224RA3 G OC=0.432 7 +224RA G 205.99 4 0.0188 5[E1] 0.0841 12 +224RA2 G KC=0.0671 10$LC=0.01292 18$MC=0.00309 5$NC=0.000807 12 +224RA3 G OC=0.000179 3 +224RA L 433.07 10(5)- +224RA A 4997.76 240.000010 221400 +224RA G 142.71 111.3E-6 4[E2] 2.14 3 +224RA2 G KC=0.279 4$LC=1.368 20$MC=0.372 6$NC=0.0982 15 +224RA3 G OC=0.0209 3 +224RA G 182.29 105.1E-6 18[E1] 0.1126 16 +224RA2 G KC=0.0894 13$LC=0.01757 25$MC=0.00421 6$NC=0.001098 16 +224RA3 G OC=0.000243 4 +224RA L 479.20 18(6)+ +224RA A 4952.5 3 0.000024 54600 +224RA G 228.42 180.000018 4[E2] 0.366 6 +224RA2 G KC=0.1244 18$LC=0.178 3$MC=0.0479 7$NC=0.01266 19 +224RA3 G OC=0.00272 4 +224RA L 916.34 7 0+ +224RA A 4522.97 230.000017 37 +224RA G 700.36 7 0.000003 1E1 0.00611 9 +224RA2 G KC=0.00502 7$LC=0.000834 12$MC=0.000196 3$NC=5.15E-5 8 +224RA3 G OC=1.166E-5 17 +224RA G 831.97 7 0.000014 2E2 0.0128918 +224RA2 G KC=0.00970 14$LC=0.00240 4$MC=0.000594 9$NC=1.565E-4 22 +224RA3 G OC=3.50E-5 5 +224RA L 992.65 6 (2)+ +224RA A 4448.00 234.5E-6 77.2 +224RA G 741.87 6 1.4E-6 4[E2] 0.0162523 +224RA2 G KC=0.01196 17$LC=0.00322 5$MC=0.000803 12$NC=0.000212 3 +224RA3 G OC=4.71E-5 7 +224RA G 908.28 6 1.7E-6 5[M1+E2] 1.0 2 0.024 3 +224RA2 G KC=0.0190 24$LC=0.0036 4$MC=0.00087 9$NC=0.000228 23 +224RA3 G OC=0.000052 6 +224RA G 992.65 6 1.4E-6 4[E2] 0.0091313 +224RA2 G KC=0.00705 10$LC=0.001569 22$MC=0.000384 6$NC=1.011E-4 15 +224RA3 G OC=2.27E-5 4 + diff --git a/HEN_HOUSE/spectra/lnhb/Th-231.txt b/HEN_HOUSE/spectra/lnhb/Th-231.txt index d7e624e52..302056c76 100644 --- a/HEN_HOUSE/spectra/lnhb/Th-231.txt +++ b/HEN_HOUSE/spectra/lnhb/Th-231.txt @@ -1,168 +1,212 @@ -231PA 231TH B- DECAY (25.522 H) -231PA H TYP=Full$AUT=X. Huang$CUT=31-MAY-2007$ -231PA C Evaluation history: Type=Full;Author=X. Huang;Cutoff date=31-MAY-2007 -231PA C References: 2008Ki07 -231PA T Auger electrons and X ray energies and emission intensities: -231PA T {U Energy (keV)} {U Intensity} {U Line} -231PA T -231PA T 92.288 0.37 4 XKA2 -231PA T 95.869 0.59 7 XKA1 -231PA T -231PA T 107.595 |] XKB3 -231PA T 108.422 |] 0.21 2 XKB1 -231PA T 109.072 |] XKB5II -231PA T -231PA T 111.405 |] XKB2 -231PA T 111.87 |] 0.071 8 XKB4 -231PA T 112.38 |] XKO23 -231PA T -231PA T 11.3676-20.1126 65 3 XL (total) -231PA T 11.3676 XLL -231PA T 13.1215-13.2887 XLA -231PA T 14.9488 XLC -231PA T 15.3584-17.6655 XLB -231PA T 18.9396-20.1126 XLG -231PA T -231PA T 70.081-78.822 |] KLL AUGER -231PA T 85.989-95.858 |] 0.038 5 KLX AUGER -231PA T 101.87-112.59 |] KXY AUGER -231PA T 5.9-21 68 3 L AUGER -231TH P 0.0 5/2+ 25.522 H 10 391.6 15 -231PA N 1.0 1.0 1 1.0 -231PA L 0 3/2- 32670 Y 260 -231PA B 391.6 150.022 7 9.57 1 -231PAS B EAV=111.6 5 -231PA L 9.206 251/2- -231PA G 9.2 -231PA L 58.5699 247/2- 274 PS 10 -231PA B 333.0 150.17 17 8.2 1 -231PAS B EAV=93.4 5 -231PA G 58.5700 240.480 16E2 155.5 22 -231PA2 G LC=113.6 16$MC=31.3 5 -231PA L 77.685 175/2- -231PA B 313.9 150.43 2 7.97 -231PAS B EAV=87.6 5 -231PA G 68.5 1 0.00590 15E2 73.3 12 -231PA2 G LC=53.5 8$MC=14.8 3 -231PA G 77.69 0.0042 7 -231PA L 84.2148 135/2+ 45.1 NS 13 -231PA B 307.4 1529 18 6.1 -231PAS B EAV=85.6 5 -231PA G 25.64 2 13.9 7E1 4.37 7 -231PA2 G LC=3.26 5$MC=0.843 12 -231PA G 84.2140 136.70 7E1 2.50 25 -231PA2 G LC=1.77 2$MC=0.57 10 -231PA L 101.4092 217/2+ 0.7 NS -231PA B 290.2 1541 16 5.88 -231PAS B EAV=80.4 5 -231PA G 17.2 (M1) 193 -231PA2 G MC=135.7 -231PA G 42.86 7 0.0596 15[E1] 1.14 2 -231PA2 G LC=0.85 2$MC=0.21 1 -231PA L 102.2692 133/2+ 0.7 NS -231PA B 289.3 1513 8 6.4 -231PAS B EAV=80.1 5 -231PA G 18.07 M1+E2 0.14 12 800 -231PA2 G LC=349 $MC=304 -231PA G 93.02 4 0.040 3[E1] 0.1463 21 -231PA2 G LC=0.110 2$MC=0.0269 4 -231PA G 102.2700 130.441 11E1 0.1141 16 -231PA2 G LC=0.086 1$MC=0.0210 3 -231PA L 111.653 12(9/2)+ -231PA G 10.25 -231PA L 174.161 4 (5/2)- -231PA B 217.4 151.36 24 6.96 -231PAS B EAV=58.9 5 -231PA G 72.7510 250.260 17[E1] 0.280 4 -231PA2 G LC=0.211 3$MC=0.0517 7 -231PA G 89.95 2 1.01 3E1 0.1598 22 -231PA2 G LC=0.121 2$MC=0.0294 4 -231PA G 115.63 3 0.00110 16[M1+E2] 10 4 -231PA2 G KC=5 5$LC=3.3 12$MC=0.9 4 -231PA G 165.00 5 0.00348 14[E2] 1.464 2 -231PA2 G KC=0.209 3$LC=0.917 13$MC=0.252 4 -231PA G 174.15 2 0.0180 6[M1+E2] 2.7 15 -231PA2 G KC=1.8 16$LC=0.68 5$MC=0.177 22 -231PA L 183.4962 175/2+ 0.19 NS -231PA B 208.1 1512.2 15 5.95 -231PAS B EAV=56.2 5 -231PA G 81.2280 140.905 23M1(+E2) 0.14 14 8.1 14 -231PA2 G LC=6.1 10$MC=1.5 3 -231PA G 82.0870 130.418 13M1(+E2) 0.14 14 7.9 13 -231PA2 G LC=5.9 9$MC=1.5 3 -231PA G 99.2780 300.137 6M1+E2 0.50 6 6.0 4 -231PA2 G LC=4.43 24$MC=1.13 7 -231PA G 105.81 3 0.0079 5[E1] 0.1043 15 -231PA2 G LC=0.0787 11$MC=0.0192 3 -231PA G 124.914 170.0590 15E1 0.294 4 -231PA2 G KC=0.226 4$LC=0.0511 8$MC=0.01241 18 -231PA G 183.480 250.0335 8E1 0.1181 17 -231PA2 G KC=0.0928 13$LC=0.0191 3$MC=0.00463 7 -231PA L 218.240 13(7/2)- -231PA B 173.4 150.31 23 7.3 1 -231PAS B EAV=46.2 5 -231PA G 44.08 170.00074 21[M1+E2] 3E2 3 -231PA2 G LC=2.4E2 21$MC=70 60 -231PA G 106.61 3 0.0179 7[E1] 0.1023 14 -231PA2 G LC=0.0772 11$MC=0.0188 3 -231PA G 116.820 200.0225 9E1 0.342 5 -231PA2 G KC=0.262 4$LC=0.0608 9$MC=0.01478 21 -231PA G 134.03 2 0.0255 8E1 0.249 4 -231PA2 G KC=0.192 3$LC=0.0426 6$MC=0.01033 15 -231PA G 140.54 4 0.00074 7[M1+E2] 5.3 25 -231PA2 G KC=3 3$LC=1.5 4$MC=0.40 12 -231PA L 247.320 5 7/2+ -231PA B 144.3 152.7 4 6.11 -231PAS B EAV=38.1 5 -231PA G 63.86 3 0.0235 21M1+E2 0.52 20 34 15 -231PA2 G LC=25 11$MC=6.6 31 -231PA G 135.664 110.0797 22M1(+E2) 0.33 33 8.0 11 -231PA2 G KC=6.1 14$LC=1.40 19$MC=0.35 6 -231PA G 145.060 400.0058 3[E2] 2.46 3 -231PA2 G KC=0.237 4$LC=1.627 23$MC=0.448 7 -231PA G 145.940 200.0324 12M1+E2 0.82 28 5.1 8 -231PA2 G KC=3.4 10$LC=1.27 10$MC=0.33 4 -231PA G 163.101 4 0.156 5M1(+E2) 0.2 2 4.9 4 -231PA2 G KC=3.9 4$LC=0.783 22$MC=0.190 9 -231PA G 169.66 3 0.00141 7[E1] 0.1421 20 -231PA2 G KC=0.1113 16$LC=0.0233 4$MC=0.00564 8 -231PA G 188.76 2 0.0034 3[E1] 0.1105 15 -231PA2 G KC=0.0869 13$LC=0.01782 25$MC=0.00431 6 -231PA L 317.95 4 (3/2)+ -231PA B 73.6 150.00078 5 8.76 -231PAS B EAV=18.9 4 -231PA G 240.27 5 0.00029 4[E1] 0.0630 9 -231PA2 G KC=0.0500 7$LC=0.00984 14$MC=0.00237 4 -231PA G 308.78 7 3.618E-418[E1] 0.0358 5 -231PA2 G KC=0.0287 4$LC=0.00544 8$MC=1306E-6 19 -231PA G 317.87 8 1.005E-4 5[E1] 0.0336 5 -231PA2 G KC=0.0269 4$LC=0.00508 8$MC=1221E-6 18 -231PA L 320.209 183/2- -231PA B 71.4 150.066 2 6.79 1 -231PAS B EAV=18.3 4 -231PA G 136.75 7 0.00442 15[E1] 0.237 3 -231PA2 G KC=0.184 3$LC=0.0404 6$MC=0.00981 14 -231PA G 217.94 3 0.0402 8E1 0.0789 11 -231PA2 G KC=0.0624 9$LC=0.01248 18$MC=0.00301 5 -231PA G 236.01 3 0.0094 3[E1] 0.0657 9 -231PA2 G KC=0.0521 8$LC=0.01028 15$MC=0.00248 4 -231PA G 242.50 4 0.00082 5[M1+E2] 1.0 7 -231PA2 G KC=0.7 6$LC=0.22 4$MC=0.055 7 -231PA G 311.00 5 0.00315 14M1+E2 0.8 8 0.6 3 -231PA2 G KC=0.5 3$LC=0.11 3$MC=0.027 6 -231PA G 320.15 8 0.00015 3[M1+E2] 0.5 4 -231PA2 G KC=0.34 27$LC=0.09 4$MC=0.023 7 -231PA L 351.84 4 (5/2)- -231PA B 39.8 150.0032 2 7.33 -231PAS B EAV=10.1 5 -231PA G 249.60 7 0.00080 7[E1] 0.0578 8 -231PA2 G KC=0.0459 7$LC=0.00898 13$MC=0.00216 3 -231PA G 250.45 7 0.00067 7[E1] 0.0573 8 -231PA2 G KC=0.0455 7$LC=0.00891 13$MC=0.00215 3 -231PA G 267.62 8 0.00141 14[E1] 0.0493 7 -231PA2 G KC=0.0393 6$LC=0.00760 11$MC=0.00183 3 -231PA G 274.1 1 0.00003412[M1+E2] 0.7 5 -231PA2 G KC=0.5 4$LC=0.15 4$MC=0.038 8 -231PA G 351.80 100.00006713[M1+E2] 0.35 25 -231PA2 G KC=0.26 21$LC=0.066 24$MC=0.016 6 - +231PA 231TH B- DECAY (25.522 H) +231PA H TYP=FUL$AUT=X.HUANG$CUT=31-MAY-2007$ +231PA C References:2008Ki07 +231PA T Auger electrons and X ray energies and emission intensities: +231PA T {U Energy (keV)} {U Intensity} {U Line} +231PA T +231PA T 92.288 0.37 4 XKA2 +231PA T 95.869 0.59 7 XKA1 +231PA T +231PA T 107.595 |] XKB3 +231PA T 108.422 |] 0.21 2 XKB1 +231PA T 109.072 |] XKB5II +231PA T +231PA T 111.405 |] XKB2 +231PA T 111.87 |] 0.071 8 XKB4 +231PA T 112.38 |] XKO23 +231PA T +231PA T 11.3676-20.1126 65 3 XL (total) +231PA T 11.3676 XLL +231PA T 13.1215-13.2887 XLA +231PA T 14.9488 XLC +231PA T 15.3584-17.6655 XLB +231PA T 18.9396-20.1126 XLG +231PA T +231PA T 70.081-78.822 |] KLL AUGER +231PA T 85.989-95.858 |] 0.038 5 KLX AUGER +231PA T 101.87-112.59 |] KXY AUGER +231PA T 5.9-21 68 3 L AUGER +231TH P 0.0 5/2+ 25.522 H 10 391.6 15 +231PA N 1.0 1.0 1 1.0 +231PA L 0 3/2- 32670 Y 260 +231PA B 391.6 150.022 7 9.57 1 +231PAS B EAV=111.6 5 +231PA L 9.206 251/2- +231PA G 9.2 +231PA L 58.5699 247/2- 274 PS 10 +231PA B 333.0 150.17 17 8.2 1 +231PAS B EAV=93.4 5 +231PA G 58.5700 240.480 16E2 155.5 22 +231PA2 G LC=113.6 16$MC=31.3 5$NC=8.43 12 +231PA3 G OC=1.90 3 +231PA L 77.685 175/2- +231PA B 313.9 150.43 2 7.97 +231PAS B EAV=87.6 5 +231PA G 68.5 1 0.00590 15E2 73.3 12 +231PA2 G LC=53.5 8$MC=14.8 3$NC=3.98 6 +231PA3 G OC=0.9 1 +231PA G 77.69 0.0042 7 +231PA L 84.2148 135/2+ 45.1 NS 13 +231PA B 307.4 1529 18 6.1 +231PAS B EAV=85.6 5 +231PA G 25.64 2 13.9 7E1 4.37 7 +231PA2 G LC=3.26 5$MC=0.843 12$NC=0.219 4 +231PA3 G OC=0.0471 7 +231PA G 84.2140 136.70 7E1 2.50 25 +231PA2 G LC=1.77 2$MC=0.57 10$NC=0.13 2 +231PA L 101.4092 217/2+ 0.7 NS +231PA B 290.2 1541 16 5.88 +231PAS B EAV=80.4 5 +231PA G 17.2 (M1) 193 +231PA2 G MC=135.7 $NC=36.4 +231PA3 G OC=8.7 +231PA G 42.86 7 0.0596 15[E1] 1.14 2 +231PA2 G LC=0.85 2$MC=0.21 1$NC=0.0558 9 +231PA3 G OC=0.01240 19 +231PA L 102.2692 133/2+ 0.7 NS +231PA B 289.3 1513 8 6.4 +231PAS B EAV=80.1 5 +231PA G 18.07 M1+E2 0.14 12 800 +231PA2 G LC=349 $MC=304 $NC=81.7 +231PA3 G OC=18.8 +231PA G 93.02 4 0.040 3[E1] 0.1463 21 +231PA2 G LC=0.110 2$MC=0.0269 4$NC=0.0071 1 +231PA3 G OC=0.00163 2 +231PA G 102.2700 130.441 11E1 0.1141 16 +231PA2 G LC=0.086 1$MC=0.0210 3$NC=0.0055 1 +231PA3 G OC=0.0013 1 +231PA L 111.653 12(9/2)+ +231PA G 10.25 +231PA L 174.161 4 (5/2)- +231PA B 217.4 151.36 24 6.96 +231PAS B EAV=58.9 5 +231PA G 72.7510 250.260 17[E1] 0.280 4 +231PA2 G LC=0.211 3$MC=0.0517 7$NC=0.0136 2 +231PA3 G OC=0.0031 1 +231PA G 89.95 2 1.01 3E1 0.1598 22 +231PA2 G LC=0.121 2$MC=0.0294 4$NC=0.0078 1 +231PA3 G OC=0.00178 3 +231PA G 115.63 3 0.00110 16[M1+E2] 10 4 +231PA2 G KC=5 5$LC=3.3 12$MC=0.9 4$NC=0.24 10 +231PA3 G OC=0.05 2 +231PA G 165.00 5 0.00348 14[E2] 1.464 2 +231PA2 G KC=0.209 3$LC=0.917 13$MC=0.252 4$NC=0.0681 10 +231PA3 G OC=0.0154 2 +231PA G 174.15 2 0.0180 6[M1+E2] 2.7 15 +231PA2 G KC=1.8 16$LC=0.68 5$MC=0.177 22$NC=0.048 6 +231PA3 G OC=0.011 1 +231PA L 183.4962 175/2+ 0.19 NS +231PA B 208.1 1512.2 15 5.95 +231PAS B EAV=56.2 5 +231PA G 81.2280 140.905 23M1(+E2) 0.14 14 8.1 14 +231PA2 G LC=6.1 10$MC=1.5 3$NC=0.40 7 +231PA3 G OC=0.10 2 +231PA G 82.0870 130.418 13M1(+E2) 0.14 14 7.9 13 +231PA2 G LC=5.9 9$MC=1.5 3$NC=0.4 1 +231PA3 G OC=0.1 1 +231PA G 99.2780 300.137 6M1+E2 0.50 6 6.0 4 +231PA2 G LC=4.43 24$MC=1.13 7$NC=0.30 2 +231PA3 G OC=0.07 1 +231PA G 105.81 3 0.0079 5[E1] 0.1043 15 +231PA2 G LC=0.0787 11$MC=0.0192 3$NC=0.0051 1 +231PA3 G OC=0.0012 1 +231PA G 124.914 170.0590 15E1 0.294 4 +231PA2 G KC=0.226 4$LC=0.0511 8$MC=0.01241 18$NC=0.0033 1 +231PA3 G OC=7.6 1 +231PA G 183.480 250.0335 8E1 0.1181 17 +231PA2 G KC=0.0928 13$LC=0.0191 3$MC=0.00463 7$NC=0.00120 2 +231PA3 G OC=0.000290 4 +231PA L 218.240 13(7/2)- +231PA B 173.4 150.31 23 7.3 1 +231PAS B EAV=46.2 5 +231PA G 44.08 170.00074 21[M1+E2] 3E2 3 +231PA2 G LC=2.4E2 21$MC=70 60$NC=18 16 +231PA3 G OC=4 4 +231PA G 106.61 3 0.0179 7[E1] 0.1023 14 +231PA2 G LC=0.0772 11$MC=0.0188 3$NC=0.0050 1 +231PA3 G OC=0.0011 1 +231PA G 116.820 200.0225 9E1 0.342 5 +231PA2 G KC=0.262 4$LC=0.0608 9$MC=0.01478 21$NC=0.00391 6 +231PA3 G OC=0.00090 1 +231PA G 134.03 2 0.0255 8E1 0.249 4 +231PA2 G KC=0.192 3$LC=0.0426 6$MC=0.01033 15$NC=0.0027 1 +231PA3 G OC=6.34 9 +231PA G 140.54 4 0.00074 7[M1+E2] 5.3 25 +231PA2 G KC=3 3$LC=1.5 4$MC=0.40 12$NC=0.11 3 +231PA3 G OC=0.025 7 +231PA L 247.320 5 7/2+ +231PA B 144.3 152.7 4 6.11 +231PAS B EAV=38.1 5 +231PA G 63.86 3 0.0235 21M1+E2 0.52 20 34 15 +231PA2 G LC=25 11$MC=6.6 31$NC=1.8 8 +231PA3 G OC=0.4 2 +231PA G 135.664 110.0797 22M1(+E2) 0.33 33 8.0 11 +231PA2 G KC=6.1 14$LC=1.40 19$MC=0.35 6$NC=0.09 2 +231PA3 G OC=0.022 3 +231PA G 145.060 400.0058 3[E2] 2.46 3 +231PA2 G KC=0.237 4$LC=1.627 23$MC=0.448 7$NC=0.121 2 +231PA3 G OC=0.027 1 +231PA G 145.940 200.0324 12M1+E2 0.82 28 5.1 8 +231PA2 G KC=3.4 10$LC=1.27 10$MC=0.33 4$NC=0.088 9 +231PA3 G OC=0.021 2 +231PA G 163.101 4 0.156 5M1(+E2) 0.2 2 4.9 4 +231PA2 G KC=3.9 4$LC=0.783 22$MC=0.190 9$NC=0.051 23 +231PA3 G OC=0.012 1 +231PA G 169.66 3 0.00141 7[E1] 0.1421 20 +231PA2 G KC=0.1113 16$LC=0.0233 4$MC=0.00564 8$NC=0.0015 1 +231PA3 G OC=0.00035 1 +231PA G 188.76 2 0.0034 3[E1] 0.1105 15 +231PA2 G KC=0.0869 13$LC=0.01782 25$MC=0.00431 6$NC=0.00114 2 +231PA3 G OC=2.67 4 +231PA L 317.95 4 (3/2)+ +231PA B 73.6 150.00078 5 8.76 +231PAS B EAV=18.9 4 +231PA G 240.27 5 0.00029 4[E1] 0.0630 9 +231PA2 G KC=0.0500 7$LC=0.00984 14$MC=0.00237 4$NC=6.31 9 +231PA3 G OC=1.48 2 +231PA G 308.78 7 3.618E-418[E1] 0.0358 5 +231PA2 G KC=0.0287 4$LC=0.00544 8$MC=0.001306 19$NC=3.48 5 +231PA3 G OC=8.19 12 +231PA G 317.87 8 1.005E-4 5[E1] 0.0336 5 +231PA2 G KC=0.0269 4$LC=0.00508 8$MC=0.001221 18$NC=3.25 5 +231PA3 G OC=7.66 1 +231PA L 320.209 183/2- +231PA B 71.4 150.066 2 6.79 1 +231PAS B EAV=18.3 4 +231PA G 136.75 7 0.00442 15[E1] 0.237 3 +231PA2 G KC=0.184 3$LC=0.0404 6$MC=0.00981 14$NC=0.0026 1 +231PA3 G OC=6.03 8 +231PA G 217.94 3 0.0402 8E1 0.0789 11 +231PA2 G KC=0.0624 9$LC=0.01248 18$MC=0.00301 5$NC=8.0 1 +231PA3 G OC=1.88 3 +231PA G 236.01 3 0.0094 3[E1] 0.0657 9 +231PA2 G KC=0.0521 8$LC=0.01028 15$MC=0.00248 4$NC=6.60 9 +231PA3 G OC=1.55 2 +231PA G 242.50 4 0.00082 5[M1+E2] 1.0 7 +231PA2 G KC=0.7 6$LC=0.22 4$MC=0.055 7$NC=0.015 2 +231PA3 G OC=0.0035 5 +231PA G 311.00 5 0.00315 14M1+E2 0.8 8 0.6 3 +231PA2 G KC=0.5 3$LC=0.11 3$MC=0.027 6$NC=0.0069 14 +231PA3 G OC=0.0016 4 +231PA G 320.15 8 0.00015 3[M1+E2] 0.5 4 +231PA2 G KC=0.34 27$LC=0.09 4$MC=0.023 7$NC=0.0059 16 +231PA3 G OC=0.0014 4 +231PA L 351.84 4 (5/2)- +231PA B 39.8 150.0032 2 7.33 +231PAS B EAV=10.1 5 +231PA G 249.60 7 0.00080 7[E1] 0.0578 8 +231PA2 G KC=0.0459 7$LC=0.00898 13$MC=0.00216 3$NC=5.75 8 +231PA3 G OC=1.35 2 +231PA G 250.45 7 0.00067 7[E1] 0.0573 8 +231PA2 G KC=0.0455 7$LC=0.00891 13$MC=0.00215 3$NC=5.71 8 +231PA3 G OC=1.34 2 +231PA G 267.62 8 0.00141 14[E1] 0.0493 7 +231PA2 G KC=0.0393 6$LC=0.00760 11$MC=0.00183 3$NC=4.87 7 +231PA3 G OC=1.14 2 +231PA G 274.1 1 0.00003412[M1+E2] 0.7 5 +231PA2 G KC=0.5 4$LC=0.15 4$MC=0.038 8$NC=0.010 2 +231PA3 G OC=0.0023 5 +231PA G 351.80 100.00006713[M1+E2] 0.35 25 +231PA2 G KC=0.26 21$LC=0.066 24$MC=0.016 6$NC=0.0044 14 +231PA3 G OC=0.0010 4 + diff --git a/HEN_HOUSE/spectra/lnhb/Th-232.txt b/HEN_HOUSE/spectra/lnhb/Th-232.txt index b9b2c9288..bbfb4be4b 100644 --- a/HEN_HOUSE/spectra/lnhb/Th-232.txt +++ b/HEN_HOUSE/spectra/lnhb/Th-232.txt @@ -1,45 +1,46 @@ -228RA 232TH A DECAY (14.02E9 Y) -228RA H TYP=Full$AUT=A. Arinc$CUT=30-APR-2009$ -228RA C Evaluation history: Type=Full;Author=A. Arinc;Cutoff date=30-APR-2009 -228RA C References: 1938Ko01, 1952Du12, 1956Ma43, 1956Al30, 1956Pi42, 1956Se17, -228RA2C 1957Ha08, 1959Ko58, 1960Be25, 1960Fa07, 1961Ko11, 1962Ko12, 1963Le21, -228RA3C 1973Ta25, 1982Sa36, 1983Mi30, 1983Ro23, 1989Sa01, 1990Ho28, 1991Ry01, -228RA4C 1995Bo18, 1996Sc06, 1997Ar08, 2002Ba85, 2003Au03, 2005KiWZ -228RA T Auger electrons and X ray energies and emission intensities: -228RA T {U Energy (keV)} {U Intensity} {U Line} -228RA T -228RA T 85.43 0.0017 5 XKA2 -228RA T 88.47 0.0028 8 XKA1 -228RA T -228RA T 99.432 |] XKB3 -228RA T 100.13 |] 0.00097 28 XKB1 -228RA T 100.738 |] XKB5II -228RA T -228RA T 102.89 |] XKB2 -228RA T 103.295 |] 0.00032 10 XKB4 -228RA T 103.74 |] XKO23 -228RA T -228RA T 10.6241-18.3539 7.2 3 XL (total) -228RA T 10.6241 0.141 8 XLL -228RA T 12.1957-12.3381 2.43 13 XLA -228RA T 13.6624 0.084 6 XLC -228RA T 14.2373-16.1261 3.66 20 XLB -228RA T 17.2756-18.3539 0.84 5 XLG -228RA T -228RA T 65.149-72.729 |] KLL AUGER -228RA T 79.721-88.466 |] 0.00019 6 KLX AUGER -228RA T 94.27-103.91 |] KXY AUGER -228RA T 5.71-19.09 8.18 29 L AUGER -232TH P 0.0 0+ 14.02E9 Y 6 4081.6 14 -228RA N 1.0 1.0 1 1.0 -228RA L 0 0+ 5.75 Y 3 -228RA A 4011.2 1478.9 131 -228RA L 63.823 202+ 0.55 NS 4 -228RA A 3948.5 1421.0 131.02 -228RA G 63.811 100.259 15E2 80.4 12 -228RA2 G LC=59.1 9$MC=16.05 23 -228RA L 204.68 3 4+ -228RA A 3810.0 140.068 2016 -228RA G 140.88 1 0.021 6E2 2.26 4 -228RA2 G KC=0.283 4$LC=1.450 21$MC=0.394 6 - +228RA 232TH A DECAY (14.02E9 Y) +228RA H TYP=FUL$AUT=A.ARINC$CUT=30-APR-2009$ +228RA C References:1938Ko01, 1952Du12, 1954Ph**, 1956Ma43, 1956Al30, 1956Pi42, +228RA2C 1956Se17, 1957Ha08, 1959Ko58, 1960Be25, 1960Fa07, 1961Ko11, 1962Ko12, +228RA3C 1963Le21, 1973Ta25, 1982Sa36, 1983Mi30, 1983Ro23, 1989Sa01, 1990Ho28, +228RA4C 1991Ry01, 1995Bo18, 1996Sc06, 1997Ar08, 2002Ba85, 2003Au03, 2005KiWZ +228RA T Auger electrons and X ray energies and emission intensities: +228RA T {U Energy (keV)} {U Intensity} {U Line} +228RA T +228RA T 85.43 0.0017 5 XKA2 +228RA T 88.47 0.0028 8 XKA1 +228RA T +228RA T 99.432 |] XKB3 +228RA T 100.13 |] 0.00097 28 XKB1 +228RA T 100.738 |] XKB5II +228RA T +228RA T 102.89 |] XKB2 +228RA T 103.295 |] 0.00032 10 XKB4 +228RA T 103.74 |] XKO23 +228RA T +228RA T 10.6241-18.3539 7.2 3 XL (total) +228RA T 10.6241 0.141 8 XLL +228RA T 12.1957-12.3381 2.43 13 XLA +228RA T 13.6624 0.084 6 XLC +228RA T 14.2373-16.1261 3.66 20 XLB +228RA T 17.2756-18.3539 0.84 5 XLG +228RA T +228RA T 65.149-72.729 |] KLL AUGER +228RA T 79.721-88.466 |] 0.00019 6 KLX AUGER +228RA T 94.27-103.91 |] KXY AUGER +228RA T 5.71-19.09 8.18 29 L AUGER +232TH P 0.0 0+ 14.02E9 Y 6 4081.6 14 +228RA N 1.0 1.0 1 +228RA L 0 0+ 5.75 Y 3 +228RA A 4011.2 1478.9 131 +228RA L 63.823 202+ 0.55 NS 4 +228RA A 3948.5 1421.0 131.02 +228RA G 63.811 100.259 15E2 80.4 12 +228RA2 G LC=59.1 9$MC=16.05 23$NC=4.23 6 +228RA3 G OC=0.898 13 +228RA L 204.68 3 4+ +228RA A 3810.0 140.068 2016 +228RA G 140.88 1 0.021 6E2 2.26 4 +228RA2 G KC=0.283 4$LC=1.450 21$MC=0.394 6$NC=0.1041 15 +228RA3 G OC=0.0222 4 + diff --git a/HEN_HOUSE/spectra/lnhb/Th-233.txt b/HEN_HOUSE/spectra/lnhb/Th-233.txt index b8326feda..fb641e5c4 100644 --- a/HEN_HOUSE/spectra/lnhb/Th-233.txt +++ b/HEN_HOUSE/spectra/lnhb/Th-233.txt @@ -1,306 +1,381 @@ -233PA 233TH B- DECAY (22.15 M) -233PA H TYP=Full$AUT=V. Chechev$CUT=31-JAN-2009$ -233PA C Evaluation history: Type=Full;Author=V. Chechev;Cutoff date=31-JAN-2009 -233PA C References: 1952Ru10, 1955Je26, 1957Dr46, 1957Fr55, 1968Da24, 1968Br25, -233PA2C 1969HoZY, 1969Va06, 1970Se06, 1972SeZI, 1972Vo08, 1972De67, 1976Sk01, -233PA3C 1976JeZU, 1979Go12, 1979Bo30, 1988Wo01, 1989Ab05, 1998Us01, 2003Au03, -233PA4C 2005Si15, 2008De31, 2008Ki07, 2008Go10, 2008De10 -233PA T Auger electrons and X ray energies and emission intensities: -233PA T {U Energy (keV)} {U Intensity} {U Line} -233PA T -233PA T 92.288 0.39 1 XKA2 -233PA T 95.869 0.615 13 XKA1 -233PA T -233PA T 107.595 |] XKB3 -233PA T 108.422 |] 0.235 6 XKB1 -233PA T 109.072 |] XKB5II -233PA T -233PA T 111.405 |] XKB2 -233PA T 111.87 |] 0.079 3 XKB4 -233PA T 112.38 |] XKO23 -233PA T -233PA T 11.366-21.6 8.2 9 XL (total) -233PA T 11.366 0.14 2 XLL -233PA T 13.122-13.291 2.84 32 XLA -233PA T 14.946 XLC -233PA T 15.3-16.7 4.3 5 XLB -233PA T 19.9-21.6 0.95 11 XLG -233PA T -233PA T 70.081-78.822 |] KLL AUGER -233PA T 88.03-95.56 |] 0.041 5 KLX AUGER -233PA T 101.78-112.4 |] KXY AUGER -233PA T 5.9-21.6 8.6 10 L AUGER -233TH P 0.0 1/2+ 22.15 M 8 1243.1 14 -233PA N 1.0 1.0 1 1.0 -233PA G 80 -233PA G 105.2 1 0.041 -233PA G 147.5 0.0018 6 -233PA G 211.3 2 0.0202 9 -233PA G 242.3 0.0029 6 -233PA G 309.9 0.0032 3 -233PA G 383.5 0.0019 6 -233PA G 408.8 5 0.0005 4 -233PA G 418.4 5 0.0091 7 -233PA G 454.2 5 0.04 -233PA G 464.8 0.0026 3 -233PA G 473.9 5 0.0033 7 -233PA G 497.1 4 0.0128 4 -233PA G 505.5 6 0.0055 3 -233PA G 513.4 4 0.0133 4 -233PA G 517.0 4 0.0046 3 -233PA G 531.8 4 0.0070 7 -233PA G 553.7 0.0030 3 -233PA G 554.9 0.0031 3 -233PA G 578.7 0.0017 5 -233PA G 583.2 0.0016 5 -233PA G 681.2 6 0.0143 4 -233PA G 690 0.0021 5 -233PA G 698.5 6 0.0106 5 -233PA G 703.7 6 0.0091 5 -233PA G 727.8 0.0029 2 -233PA G 744.9 5 0.0053 2 -233PA G 751.6 6 0.0023 4 -233PA G 767.5 0.0032 2 -233PA G 774.0 4 0.0108 5 -233PA G 784.2 5 0.0022 2 -233PA G 832.0 3 0.0075 -233PA G 846.8 7 0.0013 -233PA G 870.7 7 0.0031 2 -233PA G 874.0 5 0.00120 4 -233PA G 918.9 5 0.006 -233PA G 935.2 7 0.0369 7 -233PA G 941.9 8 0.0048 3 -233PA G 942.8 0.0019 3 -233PA G 955 1 0.0002 3 -233PA G 960.8 8 0.0041 2 -233PA G 962.8 9 0.0015 2 -233PA G 968.2 9 0.0083 3 -233PA G 994 1 0.0006 1 -233PA G 1001 1 0.0008 2 -233PA G 1007 1 0.0014 2 -233PA G 1011 1 0.0019 2 -233PA G 1026.5 100.0075 -233PA G 1092.5 100.006 -233PA G 1132.1 0.0006 2 -233PA G 1139.1 0.0004 1 -233PA G 1144 1 0.0027 -233PA G 1201 1 0.006 -233PA L 0 3/2- 26.98 D 2 -233PA B 1243.1 1434 6 6.2 1 -233PAS B EAV=413.8 6 -233PA L 6.65 5 1/2- -233PA B 1236.4 1450 6 6.1 -233PAS B EAV=411.2 6 -233PA G 6.65 5 0.0165 18(M1) 3080 60 -233PA2 G MC=2280 50 -233PA L 57.10 2 7/2- -233PA G 57.10 2 0.0498 15E2 176 4 -233PA2 G LC=128.4 26$MC=35.4 7 -233PA L 70.49 105/2- -233PA G 63.92 6 0.0007 3(E2) 102.1 21 -233PA2 G LC=74.6 15$MC=20.6 4 -233PA G 70.49 100.0007 4[M1+E2] 1 1 40 30 -233PA2 G LC=28 19$MC=7 6 -233PA L 86.477 105/2+ -233PA G 29.373 102.17 7E1 3.07 6 -233PA2 G LC=2.29 5$MC=0.586 12 -233PA G 86.477 101.843 22E1 1.43 8 -233PA2 G LC=1.13 4$MC=0.22 6 -233PA L 94.65 5 3/2+ -233PA B 1148.4 1410.4 4 6.6 -233PAS B EAV=377.8 6 -233PA G 8.22 5 (M1+E2) -233PA G 87.99 3 0.1698 20[E1] 0.169 3 -233PA2 G LC=0.128 3$MC=0.0312 6 -233PA G 94.65 5 0.775 9E1 0.140 3 -233PA2 G LC=0.105 2$MC=0.0257 5 -233PA L 103.8 1 7/2+ -233PA G 17.40 5 -233PA G 46.53 4 -233PA L 169.159 101/2+ -233PA B 1073.9 140.692 12 7.7 -233PAS B EAV=349.7 6 -233PA G 74.51 5 0.0402 17[M1] 9.85 20 -233PA2 G LC=7.43 15$MC=1.79 4 -233PA G 162.504 120.1674 26[E1] 0.157 3 -233PA2 G KC=0.123 3$LC=0.0260 5$MC=0.0063 1 -233PA G 169.162 100.251 4[E1] 0.1431 29 -233PA2 G KC=0.1120 22$LC=0.0235 5$MC=0.00568 12 -233PA L 201.62 5 3/2+ -233PA B 1041.4 140.074 8 8.6 -233PAS B EAV=337.6 6 -233PA G 115.14 5 0.003 7[M1+E2] 10 4 -233PA2 G KC=5 6$LC=3.4 13$MC=0.9 4 -233PA G 131.101 250.0508 13E1 0.262 5 -233PA2 G KC=0.202 4$LC=0.0451 9$MC=0.01094 22 -233PA G 194.97 7 0.1073 17E1 0.1024 20 -233PA2 G KC=0.0806 16$LC=0.0164 3$MC=0.00397 8 -233PA G 201.62 5 0.0221 8E1 0.0946 19 -233PA2 G KC=0.0746 15$LC=0.0151 3$MC=0.00365 7 -233PA L 212.34 5 5/2+ -233PA G 108.5 1 0.0006 M1+E2 0.22 22 3.5 6 -233PA2 G KC=0.00303 5$LC=2.7 5$MC=0.65 13 -233PA G 117.692 200.0029 3M1+E2 0.30 9 12.2 4 -233PA2 G KC=9.3 5$LC=2.16 12$MC=0.53 4 -233PA G 141.74 10 -233PA G 155.239 200.00023 3E1 0.176 4 -233PA2 G KC=0.137 3$LC=0.0292 6$MC=0.00708 10 -233PA G 212.34 5 0.0065 6E1 0.0839 17 -233PA2 G KC=0.0662 12$LC=0.01331 26$MC=0.00321 6 -233PA L 237.86 2 5/2+ -233PA G 134.285 200.0018 5[M1+E2] 0.4 4 8.0 14 -233PA2 G KC=6.1 17$LC=1.48 24$MC=0.37 8 -233PA G 143.23 2 0.0114 7M1+E2 0.4 4 6.7 12 -233PA2 G KC=5.0 14$LC=1.21 16$MC=0.30 6 -233PA G 151.409 200.0067 3[M1+E2] 0.69 20 4.9 6 -233PA2 G KC=3.4 7$LC=1.08 6$MC=0.276 19 -233PA G 180.76 3 0.00011 3[E1] 0.1223 24 -233PA2 G KC=0.096 2$LC=0.0199 4$MC=0.0048 1 -233PA G 237.86 6 0.0019 4[E1] 0.0645 13 -233PA2 G KC=0.0511 10$LC=0.0101 2$MC=0.00243 5 -233PA L 257.30 155/2- -233PA B 985.8 140.60 3 8.1 1U -233PAS B EAV=317.0 6 -233PA G 153.49 180.0407 7[E1] 0.180 4 -233PA2 G KC=0.140 3$LC=0.0301 6$MC=0.00728 14 -233PA G 162.504 0.16 [E1] 0.157 3 -233PA2 G KC=0.1230 18$LC=0.0260 5$MC=0.0063 1 -233PA G 170.60 6 0.507 9[E1] 0.1403 28 -233PA2 G KC=0.1099 20$LC=0.0230 5$MC=0.00556 11 -233PA G 186.80 180.0209 9[M1+E2] 2.2 13 -233PA2 G KC=1.5 13$LC=0.531 9$MC=0.137 10 -233PA G 250.65 160.0047 3[E2] 0.317 6 -233PA2 G KC=0.1043 21$LC=0.156 3$MC=0.0423 8 -233PA G 257.30 150.0524 12[M1+E2] 1 1 0.8 6 -233PA2 G KC=0.6 6$LC=0.18 4$MC=0.045 7 -233PA L 447.762 203/2- -233PA B 795.3 140.821 14 7.2 1 -233PAS B EAV=247.8 5 -233PA G 190.552 140.0861 15M1 3.26 6 -233PA2 G KC=2.60 5$LC=0.499 10$MC=0.1204 24 -233PA G 246.14 6 0.0041 6[E1] 0.0596 12 -233PA2 G KC=0.0473 9$LC=0.00929 19$MC=0.00224 4 -233PA G 278.7 4 0.0047 6 -233PA G 361.285 220.0218 6[E1] 0.0255 5 -233PA2 G KC=0.0205 4$LC=0.00380 8$MC=9.12E-4 2 -233PA G 377.27 110.0275 9[M1+E2] 0.3 3 0.46 8 -233PA2 G KC=0.36 7$LC=0.071 8$MC=0.0172 17 -233PA G 440.94 4 0.1912 23(M1+E2) 0.3 3 0.30 5 -233PA2 G KC=0.24 4$LC=0.046 6$MC=0.0111 13 -233PA G 447.762 200.1043 14[M1+E2] 0.27 27 0.29 4 -233PA2 G KC=0.23 4$LC=0.045 5$MC=0.0108 11 -233PA L 454.40 7 3/2+ -233PA B 788.7 140.217 13 7.7 -233PAS B EAV=245.5 5 -233PA G 216.54 8 0.0130 7(M1+E2) 1 1 1.4 9 -233PA2 G KC=1.0 9$LC=0.32 4$MC=0.081 4 -233PA G 252.78 9 0.0066 3[M1+E2] 0.4 4 1.3 3 -233PA2 G KC=1.0 3$LC=0.215 20$MC=0.052 4 -233PA G 285.24 7 0.0154 9[M1+E2] 0.4 4 0.94 22 -233PA2 G KC=0.74 20$LC=0.152 18$MC=0.037 4 -233PA G 359.74 4 0.0869 12M1 0.559 11 -233PA2 G KC=0.446 9$LC=0.0848 19$MC=0.0204 4 -233PA G 367.92 7 0.0037 7[M1] 0.525 10 -233PA2 G KC=0.420 8$LC=0.0797 16$MC=0.0192 4 -233PA L 553.88 6 1/2,3/2+ -233PA B 689.2 141.23 3 6.8 -233PAS B EAV=210.5 5 -233PA G 316.1 0.0037 4E1 0.0340 7 -233PA2 G KC=0.0272 4$LC=0.00515 10$MC=0.00124 2 -233PA G 459.222 7 0.989 12M1 0.288 6 -233PA2 G KC=0.230 5$LC=0.0435 9$MC=0.01047 21 -233PA G 467.40 6 0.0144 4[M1E2] 0.16 11 -233PA2 G KC=0.13 10$LC=0.029 13$MC=0.007 -233PA L 585.50 5 3/2+ -233PA B 657.6 140.15 3 7.6 -233PAS B EAV=199.6 5 -233PA G 347.64 6 0.0145 8[M1] 0.613 12 -233PA2 G KC=0.49 1$LC=0.0932 18$MC=0.0224 5 -233PA G 490.80 6 0.1078 16M1 0.241 5 -233PA2 G KC=0.193 4$LC=0.0363 7$MC=0.00874 18 -233PA G 499.02 4 0.1576 21M1 0.230 5 -233PA2 G KC=0.184 3$LC=0.0347 5$MC=0.00835 12 -233PA L 669.9 5 (3/2)- -233PA B 573.2 140.0174 22 8.4 1 -233PAS B EAV=170.8 5 -233PA G 412.5 5 0.0083 7[M1] 0.385 8 -233PA2 G KC=0.308 6$LC=0.0583 12$MC=0.0140 3 -233PA G 663.3 5 0.0037 5[M1] 0.1075 22 -233PA2 G KC=0.0862 17$LC=0.0161 3$MC=0.00388 8 -233PA G 669.9 5 0.0018 -233PA L 764.55 6 1/2,3/2+ -233PA B 478.5 141.19 3 6.3 -233PAS B EAV=139.5 5 -233PA G 179.05 8 0.0278 7(M1+E2) 0.4 4 3.5 8 -233PA2 G KC=2.7 8$LC=0.602 15$MC=0.148 10 -233PA G 210.67 8 0.0178 11[M1+E2] 0.97 97 1.5 10 -233PA2 G KC=1.1 9$LC=0.35 3$MC=0.0890 21 -233PA G 526.69 6 0.0463 11[M1E2] 0.12 8 -233PA2 G KC=0.09 7$LC=0.02 1$MC=0.005 3 -233PA G 552.21 8 0.0165 5(M1) 0.1754 35 -233PA2 G KC=0.1404 28$LC=0.0264 5$MC=0.00635 13 -233PA G 562.93 8 0.0545 7[M1] 0.167 3 -233PA2 G KC=0.1334 27$LC=0.0251 5$MC=0.00603 12 -233PA G 595.39 6 0.1178 16(M1) 0.143 3 -233PA2 G KC=0.1148 22$LC=0.0216 4$MC=0.00518 10 -233PA G 669.901 160.504 6[M1] 0.1047 21 -233PA2 G KC=0.0839 17$LC=0.0157 3$MC=0.00377 8 -233PA G 678.04 100.0647 9[M1E2] 0.06 4 -233PA2 G KC=0.05 4$LC=0.010 5$MC=0.0025 12 -233PA G 757.90 7 0.0324 7 -233PA G 764.55 6 0.0891 13 -233PA L 811.6 2 (3/2)+ -233PA B 431.5 140.385 4 6.6 -233PAS B EAV=124.3 5 -233PA G 226.1 2 0.0171 7M1+(E2) 2.02 4 -233PA2 G KC=1.61 3$LC=0.308 6$MC=0.0743 15 -233PA G 573.7 4 0.0332 10[M1] 0.158 3 -233PA2 G KC=0.1268 25$LC=0.0238 5$MC=0.00573 12 -233PA G 599.3 2 0.0294 5[M1] 0.141 3 -233PA2 G KC=0.1129 22$LC=0.0212 4$MC=0.00509 10 -233PA G 610.0 3 0.0567 12[M1] 0.134 3 -233PA2 G KC=0.1077 20$LC=0.0202 4$MC=0.00485 9 -233PA G 642.4 2 0.0202 5[M1] 0.1171 23 -233PA2 G KC=0.0938 19$LC=0.0176 4$MC=0.00422 8 -233PA G 707.8 3 0.0091 5[E2] 0.0209 4 -233PA2 G KC=0.0148 3$LC=0.00455 9$MC=0.00115 2 -233PA G 717.0 2 0.0421 9(M1) 0.0874 17 -233PA2 G KC=0.0701 14$LC=0.0131 3$MC=0.00314 6 -233PA G 725.1 2 0.0633 10(M1) 0.0848 17 -233PA2 G KC=0.068 1$LC=0.01271 25$MC=0.00305 6 -233PA G 741.1 2 0.0236 5[E1] 0.0061512 -233PA2 G KC=0.00502 10$LC=8.60E-4 17$MC=2.04E-4 4 -233PA G 805.0 2 0.0214 6[E1] 0.0052911 -233PA2 G KC=0.00432 9$LC=0.00073 2$MC=1.74E-4 4 -233PA G 811.6 2 0.0060 2[E1] 0.0052110 -233PA2 G KC=0.00426 9$LC=7.20E-4 15$MC=1.71E-4 4 -233PA L 984.8 5 (3/2)+ -233PA B 258.3 140.205 2 6.2 -233PAS B EAV=70.8 4 -233PA G 398.8 5 0.0111 7[M1] 0.422 8 -233PA2 G KC=0.337 7$LC=0.0639 13$MC=0.0154 3 -233PA G 430.9 4 0.0178 4(M1) 0.342 6 -233PA2 G KC=0.273 5$LC=0.0517 10$MC=0.01245 24 -233PA G 783.2 5 0.0056 3[M1] 0.0692 14 -233PA2 G KC=0.05550 11$LC=0.01034 20$MC=0.00248 5 -233PA G 815.9 4 0.0195 6[M1] 0.0621 12 -233PA2 G KC=0.0498 10$LC=0.0093 2$MC=0.00223 5 -233PA G 880.9 5 0.0097 4E2 0.0135 3 -233PA2 G KC=0.0100 2$LC=0.00258 5$MC=6.40E-4 13 -233PA G 890.1 5 0.1052 14[M1] 0.0493 10 -233PA2 G KC=0.0396 8$LC=0.00735 15$MC=0.00176 4 -233PA G 898.3 5 0.0022 4[M1] 0.0481 10 -233PA2 G KC=0.0386 8$LC=0.00717 14$MC=0.00172 3 -233PA G 978.2 5 0.0058 3[E1] 0.00374 7 -233PA2 G KC=0.00306 6$LC=0.00051 1$MC=1.21E-4 2 -233PA G 984.8 5 0.0102 3[E1] 0.00369 7 -233PA2 G KC=0.00303 6$LC=0.00051 1$MC=1.20E-4 2 -233PA L 1018.7 5 (3/2)+ -233PA B 224.4 140.0434 9 6.7 -233PAS B EAV=60.9 4 -233PA G 433.2 4 0.0117 4 -233PA G 806.4 5 0.0123 5 -233PA G 817.0 6 0.0095 5 -233PA G 849.5 5 0.0039 3 -233PA G 948.3 5 0.0060 3 - +233PA 233TH B- DECAY (22.15 M) +233PA H TYP=FUL$AUT=V.P.CHECHEV$CUT=31-JAN-2009$ +233PA C References:1952Ru10, 1955Je26, 1957Dr46, 1957Fr55, 1968Da24, 1968Br25, +233PA2C 1969HoZY, 1969Va06, 1970Se06, 1972SeZI, 1972Vo08, 1972De67, 1976Sk01, +233PA3C 1976JeZU, 1979Go12, 1979Bo30, 1988Wo01, 1989Ab05, 1998Us01, 2002Be**, +233PA4C 2003Au03, 2005Si15, 2008De31, 2008Ki07, 2008Go10, 2008De10 +233PA T Auger electrons and X ray energies and emission intensities: +233PA T {U Energy (keV)} {U Intensity} {U Line} +233PA T +233PA T 92.288 0.39 1 XKA2 +233PA T 95.869 0.615 13 XKA1 +233PA T +233PA T 107.595 |] XKB3 +233PA T 108.422 |] 0.235 6 XKB1 +233PA T 109.072 |] XKB5II +233PA T +233PA T 111.405 |] XKB2 +233PA T 111.87 |] 0.079 3 XKB4 +233PA T 112.38 |] XKO23 +233PA T +233PA T 11.366-21.6 8.2 9 XL (total) +233PA T 11.366 0.14 2 XLL +233PA T 13.122-13.291 2.84 32 XLA +233PA T 14.946 XLC +233PA T 15.3-16.7 4.3 5 XLB +233PA T 19.9-21.6 0.95 11 XLG +233PA T +233PA T 70.081-78.822 |] KLL AUGER +233PA T 88.03-95.56 |] 0.041 5 KLX AUGER +233PA T 101.78-112.4 |] KXY AUGER +233PA T 5.9-21.6 8.6 10 L AUGER +233TH P 0.0 1/2+ 22.15 M 8 1243.1 14 +233PA N 1.0 1.0 1 1.0 +233PA G 80 +233PA G 105.2 1 0.041 +233PA G 147.5 0.0018 6 +233PA G 211.3 2 0.0202 9 +233PA G 242.3 0.0029 6 +233PA G 309.9 0.0032 3 +233PA G 383.5 0.0019 6 +233PA G 408.8 5 0.0005 4 +233PA G 418.4 5 0.0091 7 +233PA G 454.2 5 0.04 +233PA G 464.8 0.0026 3 +233PA G 473.9 5 0.0033 7 +233PA G 497.1 4 0.0128 4 +233PA G 505.5 6 0.0055 3 +233PA G 513.4 4 0.0133 4 +233PA G 517.0 4 0.0046 3 +233PA G 531.8 4 0.0070 7 +233PA G 553.7 0.0030 3 +233PA G 554.9 0.0031 3 +233PA G 578.7 0.0017 5 +233PA G 583.2 0.0016 5 +233PA G 681.2 6 0.0143 4 +233PA G 690 0.0021 5 +233PA G 698.5 6 0.0106 5 +233PA G 703.7 6 0.0091 5 +233PA G 727.8 0.0029 2 +233PA G 744.9 5 0.0053 2 +233PA G 751.6 6 0.0023 4 +233PA G 767.5 0.0032 2 +233PA G 774.0 4 0.0108 5 +233PA G 784.2 5 0.0022 2 +233PA G 832.0 3 0.0075 +233PA G 846.8 7 0.0013 +233PA G 870.7 7 0.0031 2 +233PA G 874.0 5 0.00120 4 +233PA G 918.9 5 0.006 +233PA G 935.2 7 0.0369 7 +233PA G 941.9 8 0.0048 3 +233PA G 942.8 0.0019 3 +233PA G 955 1 0.0002 3 +233PA G 960.8 8 0.0041 2 +233PA G 962.8 9 0.0015 2 +233PA G 968.2 9 0.0083 3 +233PA G 994 1 0.0006 1 +233PA G 1001 1 0.0008 2 +233PA G 1007 1 0.0014 2 +233PA G 1011 1 0.0019 2 +233PA G 1026.5 100.0075 +233PA G 1092.5 100.006 +233PA G 1132.1 0.0006 2 +233PA G 1139.1 0.0004 1 +233PA G 1144 1 0.0027 +233PA G 1201 1 0.006 +233PA L 0 3/2- 26.98 D 2 +233PA B 1243.1 1434 6 6.2 1 +233PAS B EAV=413.8 6 +233PA L 6.65 5 1/2- +233PA B 1236.4 1450 6 6.1 +233PAS B EAV=411.2 6 +233PA G 6.65 5 0.0165 18(M1) 3080 60 +233PA2 G MC=2280 50$NC=618 17 +233PA3 G OC=148 4 +233PA L 57.10 2 7/2- +233PA G 57.10 2 0.0498 15E2 176 4 +233PA2 G LC=128.4 26$MC=35.4 7$NC=9.53 14 +233PA3 G OC=2.15 3 +233PA L 70.49 105/2- +233PA G 63.92 6 0.0007 3(E2) 102.1 21 +233PA2 G LC=74.6 15$MC=20.6 4$NC=5.54 9 +233PA3 G OC=1.250 19 +233PA G 70.49 100.0007 4[M1+E2] 1 1 40 30 +233PA2 G LC=28 19$MC=7 6$NC=2.0 15 +233PA3 G OC=0.5 4 +233PA L 86.477 105/2+ +233PA G 29.373 102.17 7E1 3.07 6 +233PA2 G LC=2.29 5$MC=0.586 12$NC=0.1528 22 +233PA3 G OC=0.0331 5 +233PA G 86.477 101.843 22E1 1.43 8 +233PA2 G LC=1.13 4$MC=0.22 6 +233PA L 94.65 5 3/2+ +233PA B 1148.4 1410.4 4 6.6 +233PAS B EAV=377.8 6 +233PA G 8.22 5 (M1+E2) +233PA G 87.99 3 0.1698 20[E1] 0.169 3 +233PA2 G LC=0.128 3$MC=0.0312 6$NC=0.00824 12 +233PA3 G OC=0.00189 3 +233PA G 94.65 5 0.775 9E1 0.140 3 +233PA2 G LC=0.105 2$MC=0.0257 5$NC=0.00679 10 +233PA3 G OC=0.001560 22 +233PA L 103.8 1 7/2+ +233PA G 17.40 5 +233PA G 46.53 4 +233PA L 169.159 101/2+ +233PA B 1073.9 140.692 12 7.7 +233PAS B EAV=349.7 6 +233PA G 74.51 5 0.0402 17[M1] 9.85 20 +233PA2 G LC=7.43 15$MC=1.79 4$NC=0.481 7 +233PA3 G OC=0.1155 17 +233PA G 162.504 120.1674 26[E1] 0.157 3 +233PA2 G KC=0.123 3$LC=0.0260 5$MC=0.0063 1$NC=0.001670 24 +233PA3 G OC=0.000389 6 +233PA G 169.162 100.251 4[E1] 0.1431 29 +233PA2 G KC=0.1120 22$LC=0.0235 5$MC=0.00568 12$NC=0.001508 22 +233PA3 G OC=0.000351 5 +233PA L 201.62 5 3/2+ +233PA B 1041.4 140.074 8 8.6 +233PAS B EAV=337.6 6 +233PA G 115.14 5 0.003 7[M1+E2] 10 4 +233PA2 G KC=5 6$LC=3.4 13$MC=0.9 4$NC=0.24 11 +233PA3 G OC=0.056 23 +233PA G 131.101 250.0508 13E1 0.262 5 +233PA2 G KC=0.202 4$LC=0.0451 9$MC=0.01094 22$NC=0.00290 4 +233PA3 G OC=0.000672 10 +233PA G 194.97 7 0.1073 17E1 0.1024 20 +233PA2 G KC=0.0806 16$LC=0.0164 3$MC=0.00397 8$NC=0.001055 15 +233PA3 G OC=0.000247 4 +233PA G 201.62 5 0.0221 8E1 0.0946 19 +233PA2 G KC=0.0746 15$LC=0.0151 3$MC=0.00365 7$NC=0.000970 14 +233PA3 G OC=0.000227 4 +233PA L 212.34 5 5/2+ +233PA G 108.5 1 0.0006 M1+E2 0.22 22 3.5 6 +233PA2 G KC=0.00303 5$LC=2.7 5$MC=0.65 13$NC=0.18 4 +233PA3 G OC=0.042 8 +233PA G 117.692 200.0029 3M1+E2 0.30 9 12.2 4 +233PA2 G KC=9.3 5$LC=2.16 12$MC=0.53 4$NC=0.143 10 +233PA3 G OC=0.0340 21 +233PA G 141.74 10 +233PA G 155.239 200.00023 3E1 0.176 4 +233PA2 G KC=0.137 3$LC=0.0292 6$MC=0.00708 10$NC=0.00188 3 +233PA3 G OC=0.000437 7 +233PA G 212.34 5 0.0065 6E1 0.0839 17 +233PA2 G KC=0.0662 12$LC=0.01331 26$MC=0.00321 6$NC=0.000854 12 +233PA3 G OC=0.000200 3 +233PA L 237.86 2 5/2+ +233PA G 134.285 200.0018 5[M1+E2] 0.4 4 8.0 14 +233PA2 G KC=6.1 17$LC=1.48 24$MC=0.37 8$NC=0.099 22 +233PA3 G OC=0.023 5 +233PA G 143.23 2 0.0114 7M1+E2 0.4 4 6.7 12 +233PA2 G KC=5.0 14$LC=1.21 16$MC=0.30 6$NC=0.080 14 +233PA3 G OC=0.019 3 +233PA G 151.409 200.0067 3[M1+E2] 0.69 20 4.9 6 +233PA2 G KC=3.4 7$LC=1.08 6$MC=0.276 19$NC=0.074 5 +233PA3 G OC=0.0174 11 +233PA G 180.76 3 0.00011 3[E1] 0.1223 24 +233PA2 G KC=0.096 2$LC=0.0199 4$MC=0.0048 1$NC=0.001276 18 +233PA3 G OC=0.000298 5 +233PA G 237.86 6 0.0019 4[E1] 0.0645 13 +233PA2 G KC=0.0511 10$LC=0.0101 2$MC=0.00243 5$NC=0.000646 9 +233PA3 G OC=1.516E-4 22 +233PA L 257.30 155/2- +233PA B 985.8 140.60 3 8.1 1U +233PAS B EAV=317.0 6 +233PA G 153.49 180.0407 7[E1] 0.180 4 +233PA2 G KC=0.140 3$LC=0.0301 6$MC=0.00728 14$NC=0.00193 3 +233PA3 G OC=0.000449 7 +233PA G 162.504 0.16 [E1] 0.157 3 +233PA2 G KC=0.1230 18$LC=0.0260 5$MC=0.0063 1$NC=0.001670 24 +233PA3 G OC=0.000389 6 +233PA G 170.60 6 0.507 9[E1] 0.1403 28 +233PA2 G KC=0.1099 20$LC=0.0230 5$MC=0.00556 11$NC=0.001476 21 +233PA3 G OC=0.000344 5 +233PA G 186.80 180.0209 9[M1+E2] 2.2 13 +233PA2 G KC=1.5 13$LC=0.531 9$MC=0.137 10$NC=0.037 3 +233PA3 G OC=0.0086 5 +233PA G 250.65 160.0047 3[E2] 0.317 6 +233PA2 G KC=0.1043 21$LC=0.156 3$MC=0.0423 8$NC=0.01141 17 +233PA3 G OC=0.00260 4 +233PA G 257.30 150.0524 12[M1+E2] 1 1 0.8 6 +233PA2 G KC=0.6 6$LC=0.18 4$MC=0.045 7$NC=0.0121 19 +233PA3 G OC=0.0028 5 +233PA L 447.762 203/2- +233PA B 795.3 140.821 14 7.2 1 +233PAS B EAV=247.8 5 +233PA G 190.552 140.0861 15M1 3.26 6 +233PA2 G KC=2.60 5$LC=0.499 10$MC=0.1204 24$NC=0.0323 5 +233PA3 G OC=0.00774 11 +233PA G 246.14 6 0.0041 6[E1] 0.0596 12 +233PA2 G KC=0.0473 9$LC=0.00929 19$MC=0.00224 4$NC=0.000595 9 +233PA3 G OC=1.397E-4 20 +233PA G 278.7 4 0.0047 6 +233PA G 361.285 220.0218 6[E1] 0.0255 5 +233PA2 G KC=0.0205 4$LC=0.00380 8$MC=0.000912 2$NC=0.000243 4 +233PA3 G OC=5.73E-5 8 +233PA G 377.27 110.0275 9[M1+E2] 0.3 3 0.46 8 +233PA2 G KC=0.36 7$LC=0.071 8$MC=0.0172 17$NC=0.0046 5 +233PA3 G OC=0.00110 12 +233PA G 440.94 4 0.1912 23(M1+E2) 0.3 3 0.30 5 +233PA2 G KC=0.24 4$LC=0.046 6$MC=0.0111 13$NC=0.0030 4 +233PA3 G OC=0.00072 8 +233PA G 447.762 200.1043 14[M1+E2] 0.27 27 0.29 4 +233PA2 G KC=0.23 4$LC=0.045 5$MC=0.0108 11$NC=0.0029 3 +233PA3 G OC=0.00069 7 +233PA L 454.40 7 3/2+ +233PA B 788.7 140.217 13 7.7 +233PAS B EAV=245.5 5 +233PA G 216.54 8 0.0130 7(M1+E2) 1 1 1.4 9 +233PA2 G KC=1.0 9$LC=0.32 4$MC=0.081 4$NC=0.0217 9 +233PA3 G OC=0.0051 4 +233PA G 252.78 9 0.0066 3[M1+E2] 0.4 4 1.3 3 +233PA2 G KC=1.0 3$LC=0.215 20$MC=0.052 4$NC=0.0141 10 +233PA3 G OC=0.0034 3 +233PA G 285.24 7 0.0154 9[M1+E2] 0.4 4 0.94 22 +233PA2 G KC=0.74 20$LC=0.152 18$MC=0.037 4$NC=0.0099 10 +233PA3 G OC=0.00236 24 +233PA G 359.74 4 0.0869 12M1 0.559 11 +233PA2 G KC=0.446 9$LC=0.0848 19$MC=0.0204 4$NC=0.00547 8 +233PA3 G OC=0.001313 19 +233PA G 367.92 7 0.0037 7[M1] 0.525 10 +233PA2 G KC=0.420 8$LC=0.0797 16$MC=0.0192 4$NC=0.00514 8 +233PA3 G OC=0.001234 18 +233PA L 553.88 6 1/2,3/2+ +233PA B 689.2 141.23 3 6.8 +233PAS B EAV=210.5 5 +233PA G 316.1 0.0037 4E1 0.0340 7 +233PA2 G KC=0.0272 4$LC=0.00515 10$MC=0.00124 2$NC=0.000329 5 +233PA3 G OC=7.76E-5 11 +233PA G 459.222 7 0.989 12M1 0.288 6 +233PA2 G KC=0.230 5$LC=0.0435 9$MC=0.01047 21$NC=0.00280 4 +233PA3 G OC=0.000673 10 +233PA G 467.40 6 0.0144 4[M1,E2] 0.16 11 +233PA2 G KC=0.13 10$LC=0.029 13$MC=0.007 $NC=0.0019 8 +233PA3 G OC=0.00045 20 +233PA L 585.50 5 3/2+ +233PA B 657.6 140.15 3 7.6 +233PAS B EAV=199.6 5 +233PA G 347.64 6 0.0145 8[M1] 0.613 12 +233PA2 G KC=0.49 1$LC=0.0932 18$MC=0.0224 5$NC=0.00601 9 +233PA3 G OC=0.001442 21 +233PA G 490.80 6 0.1078 16M1 0.241 5 +233PA2 G KC=0.193 4$LC=0.0363 7$MC=0.00874 18$NC=0.00234 4 +233PA3 G OC=0.000562 8 +233PA G 499.02 4 0.1576 21M1 0.230 5 +233PA2 G KC=0.184 3$LC=0.0347 5$MC=0.00835 12$NC=0.00224 4 +233PA3 G OC=0.000537 8 +233PA L 669.9 5 (3/2)- +233PA B 573.2 140.0174 22 8.4 1 +233PAS B EAV=170.8 5 +233PA G 412.5 5 0.0083 7[M1] 0.385 8 +233PA2 G KC=0.308 6$LC=0.0583 12$MC=0.0140 3$NC=0.00376 6 +233PA3 G OC=0.000902 13 +233PA G 663.3 5 0.0037 5[M1] 0.1075 22 +233PA2 G KC=0.0862 17$LC=0.0161 3$MC=0.00388 8$NC=0.001038 15 +233PA3 G OC=0.000249 4 +233PA G 669.9 5 0.0018 +233PA L 764.55 6 1/2,3/2+ +233PA B 478.5 141.19 3 6.3 +233PAS B EAV=139.5 5 +233PA G 179.05 8 0.0278 7(M1+E2) 0.4 4 3.5 8 +233PA2 G KC=2.7 8$LC=0.602 15$MC=0.148 10$NC=0.0397 24 +233PA3 G OC=0.0095 5 +233PA G 210.67 8 0.0178 11[M1+E2] 0.97 97 1.5 10 +233PA2 G KC=1.1 9$LC=0.35 3$MC=0.0890 21$NC=0.0239 5 +233PA3 G OC=0.00560 25 +233PA G 526.69 6 0.0463 11[M1,E2] 0.12 8 +233PA2 G KC=0.09 7$LC=0.02 1$MC=0.005 3$NC=0.0013 6 +233PA3 G OC=0.00032 15 +233PA G 552.21 8 0.0165 5(M1) 0.1754 35 +233PA2 G KC=0.1404 28$LC=0.0264 5$MC=0.00635 13$NC=0.001701 24 +233PA3 G OC=0.000408 6 +233PA G 562.93 8 0.0545 7[M1] 0.167 3 +233PA2 G KC=0.1334 27$LC=0.0251 5$MC=0.00603 12$NC=0.001615 23 +233PA3 G OC=0.000387 6 +233PA G 595.39 6 0.1178 16(M1) 0.143 3 +233PA2 G KC=0.1148 22$LC=0.0216 4$MC=0.00518 10$NC=0.001388 20 +233PA3 G OC=0.000333 5 +233PA G 669.901 160.504 6[M1] 0.1047 21 +233PA2 G KC=0.0839 17$LC=0.0157 3$MC=0.00377 8$NC=0.001011 15 +233PA3 G OC=0.000243 4 +233PA G 678.04 100.0647 9[M1,E2] 0.06 4 +233PA2 G KC=0.05 4$LC=0.010 5$MC=0.0025 12$NC=0.0007 4 +233PA3 G OC=0.00016 8 +233PA G 757.90 7 0.0324 7 +233PA G 764.55 6 0.0891 13 +233PA L 811.6 2 (3/2)+ +233PA B 431.5 140.385 4 6.6 +233PAS B EAV=124.3 5 +233PA G 226.1 2 0.0171 7M1+(E2) 2.02 4 +233PA2 G KC=1.61 3$LC=0.308 6$MC=0.0743 15$NC=0.0199 3 +233PA3 G OC=0.00478 7 +233PA G 573.7 4 0.0332 10[M1] 0.158 3 +233PA2 G KC=0.1268 25$LC=0.0238 5$MC=0.00573 12$NC=0.001534 22 +233PA3 G OC=0.000368 6 +233PA G 599.3 2 0.0294 5[M1] 0.141 3 +233PA2 G KC=0.1129 22$LC=0.0212 4$MC=0.00509 10$NC=0.001364 20 +233PA3 G OC=0.000327 5 +233PA G 610.0 3 0.0567 12[M1] 0.134 3 +233PA2 G KC=0.1077 20$LC=0.0202 4$MC=0.00485 9$NC=0.001301 19 +233PA3 G OC=0.000312 5 +233PA G 642.4 2 0.0202 5[M1] 0.1171 23 +233PA2 G KC=0.0938 19$LC=0.0176 4$MC=0.00422 8$NC=0.001132 16 +233PA3 G OC=0.000271 4 +233PA G 707.8 3 0.0091 5[E2] 0.0209 4 +233PA2 G KC=0.0148 3$LC=0.00455 9$MC=0.00115 2$NC=0.000310 5 +233PA3 G OC=7.26E-5 11 +233PA G 717.0 2 0.0421 9(M1) 0.0874 17 +233PA2 G KC=0.0701 14$LC=0.0131 3$MC=0.00314 6$NC=0.000843 12 +233PA3 G OC=0.000202 3 +233PA G 725.1 2 0.0633 10(M1) 0.0848 17 +233PA2 G KC=0.068 1$LC=0.01271 25$MC=0.00305 6$NC=0.000818 12 +233PA3 G OC=0.000196 3 +233PA G 741.1 2 0.0236 5[E1] 0.0061512 +233PA2 G KC=0.00502 10$LC=0.000860 17$MC=0.000204 4$NC=5.43E-5 8 +233PA3 G OC=1.294E-5 19 +233PA G 805.0 2 0.0214 6[E1] 0.0052911 +233PA2 G KC=0.00432 9$LC=0.00073 2$MC=0.000174 4$NC=4.64E-5 7 +233PA3 G OC=1.106E-5 16 +233PA G 811.6 2 0.0060 2[E1] 0.0052110 +233PA2 G KC=0.00426 9$LC=0.000720 15$MC=0.000171 4$NC=4.57E-5 7 +233PA3 G OC=1.089E-5 16 +233PA L 984.8 5 (3/2)+ +233PA B 258.3 140.205 2 6.2 +233PAS B EAV=70.8 4 +233PA G 398.8 5 0.0111 7[M1] 0.422 8 +233PA2 G KC=0.337 7$LC=0.0639 13$MC=0.0154 3$NC=0.00412 6 +233PA3 G OC=0.000989 15 +233PA G 430.9 4 0.0178 4(M1) 0.342 6 +233PA2 G KC=0.273 5$LC=0.0517 10$MC=0.01245 24$NC=0.00334 5 +233PA3 G OC=0.000800 12 +233PA G 783.2 5 0.0056 3[M1] 0.0692 14 +233PA2 G KC=0.05550 11$LC=0.01034 20$MC=0.00248 5$NC=0.000665 10 +233PA3 G OC=1.596E-4 23 +233PA G 815.9 4 0.0195 6[M1] 0.0621 12 +233PA2 G KC=0.0498 10$LC=0.0093 2$MC=0.00223 5$NC=0.000596 9 +233PA3 G OC=1.431E-4 21 +233PA G 880.9 5 0.0097 4E2 0.0135 3 +233PA2 G KC=0.0100 2$LC=0.00258 5$MC=0.000640 13$NC=1.730E-4 25 +233PA3 G OC=4.08E-5 6 +233PA G 890.1 5 0.1052 14[M1] 0.0493 10 +233PA2 G KC=0.0396 8$LC=0.00735 15$MC=0.00176 4$NC=0.000473 7 +233PA3 G OC=1.134E-4 16 +233PA G 898.3 5 0.0022 4[M1] 0.0481 10 +233PA2 G KC=0.0386 8$LC=0.00717 14$MC=0.00172 3$NC=0.000461 7 +233PA3 G OC=1.107E-4 16 +233PA G 978.2 5 0.0058 3[E1] 0.00374 7 +233PA2 G KC=0.00306 6$LC=0.00051 1$MC=0.000121 2$NC=3.23E-5 5 +233PA3 G OC=7.71E-6 11 +233PA G 984.8 5 0.0102 3[E1] 0.00369 7 +233PA2 G KC=0.00303 6$LC=0.00051 1$MC=0.000120 2$NC=3.19E-5 5 +233PA3 G OC=7.62E-6 11 +233PA L 1018.7 5 (3/2)+ +233PA B 224.4 140.0434 9 6.7 +233PAS B EAV=60.9 4 +233PA G 433.2 4 0.0117 4 +233PA G 806.4 5 0.0123 5 +233PA G 817.0 6 0.0095 5 +233PA G 849.5 5 0.0039 3 +233PA G 948.3 5 0.0060 3 + diff --git a/HEN_HOUSE/spectra/lnhb/Th-234.txt b/HEN_HOUSE/spectra/lnhb/Th-234.txt index 07457478e..d989c5af9 100644 --- a/HEN_HOUSE/spectra/lnhb/Th-234.txt +++ b/HEN_HOUSE/spectra/lnhb/Th-234.txt @@ -1,79 +1,88 @@ -234PA 234TH B- DECAY (24.10 D) -234PA H TYP=Update$AUT=A.Luca$CUT= -- $ -234PA2 H TYP=Full$AUT=A. Luca$CUT=31-DEC-2008$ -234PA C Evaluation history: Type=Update;Author=A.Luca;Cutoff date= -- -234PA2C Type=Full;Author=A. Luca;Cutoff date=31-DEC-2008 -234PA C References: 1920KI01, 1931CU01, 1939SA11, 1948KN23, 1961GE13, 1962BR05, -234PA2C 1963BJ02, 1964AB04, 1965FO12, 1973TA25, 1973GO40, 1973SA33, 1978CH06, -234PA3C 1982MO30, 1990SC09, 1990CO08, 1993SU37, 1998AD08, 2003Au03, 2004AB03, -234PA4C 2006AL28, 2007BR04 -234PA T Auger electrons and X ray energies and emission intensities: -234PA T {U Energy (keV)} {U Intensity} {U Line} -234PA T -234PA T 92.288 0.013 9 XKA2 -234PA T 95.869 0.021 13 XKA1 -234PA T -234PA T 107.595 |] XKB3 -234PA T 108.422 |] 0.007 5 XKB1 -234PA T 109.072 |] XKB5II -234PA T -234PA T 111.405 |] XKB2 -234PA T 111.87 |] 0.0025 16 XKB4 -234PA T 112.38 |] XKO23 -234PA T -234PA T 11.3676-20.1126 7.1 3 XL (total) -234PA T 11.3676 0.178 12 XLL -234PA T 13.1215-13.2887 2.92 18 XLA -234PA T 14.9488 0.0423 29 XLC -234PA T 15.3584-17.6655 3.21 13 XLB -234PA T 18.9396-20.1126 0.766 29 XLG -234PA T -234PA T 70.081-78.822 |] KLL AUGER -234PA T 85.989-95.858 |] 0.0014 9 KLX AUGER -234PA T 101.87-112.59 |] KXY AUGER -234PA T 5.9-21.6 7.7 6 L AUGER -234TH P 0.0 0+ 24.10 D 3 272 10 -234PA N 1.0 1.0 1 1.0 -234PA L 0 4+ 6.70 H 5 -234PA L 73.92 (0)- 1.159 M 11 -234PA B 198 1077.8 15 6.4 -234PAS B EAV=53 3 -234PA G 73.92 2 0.0133 14M1+E2 0.11 3 10.6 4 -234PA2 G LC=7.96 25$MC=1.94 7 -234PA L 73.92 2 (3)+ -234PA B 198 1077.8 15 6.4 2U -234PAS B EAV=53 3 -234PA G 73.92 2 0.0133 14M1+E2 0.11 3 10.6 4 -234PA2 G LC=7.96 25$MC=1.94 7 -234PA L 103.42 (2)- 0.5 NS -234PA G 29.50 2 0.00123 14E2 4390 70 -234PA2 G LC=3210 50$MC=880 13 -234PA L 166.3 (1)- 0.1 NS -234PA B 106 1014.1 12 6.3 1 -234PAS B EAV=28 3 -234PA G 62.88 2 0.0164 28M1+E2 0.33 8 25 5 -234PA2 G LC=19 4$MC=4.8 9 -234PA G 92.38 1 2.18 19M1 5.27 8 -234PA2 G LC=3.98 6$MC=0.960 14 -234PA L 166.72 (1)+ 0.55 NS 10 -234PA B 105 106.5 7 6.7 -234PAS B EAV=27 3 -234PA G 63.30 2 3.75 8E1 0.405 6 -234PA2 G LC=0.305 5$MC=0.0749 11 -234PA G 92.80 2 2.15 19E1 0.1472 21 -234PA2 G LC=0.1110 16$MC=0.0271 4 -234PA L 177.27 1- -234PA B 95 100.016 5 9.1 1 -234PAS B EAV=25 3 -234PA G 103.35 100.0032 10M1 3.81 6 -234PA2 G LC=2.88 5$MC=0.694 10 -234PA L 186.73 (1)+ -234PA B 85 101.6 6 7 -234PAS B EAV=22 3 -234PA G 20.01 2 0.0051 21M1+E2 0.08 2 240 70 -234PA2 G LC=70 40$MC=124 21 -234PA G 83.31 5 0.061 5E1 0.196 3 -234PA2 G LC=0.1475 21$MC=0.0361 5 -234PA G 112.81 5 0.215 22E1 0.23 14 -234PA2 G KC=0.21 13$LC=0.0666 10$MC=0.01620 23 - +234PA 234TH B- DECAY (24.10 D) +234PA H TYP=UPD$AUT=A.LUCA$CUT=01-FEB-2010$ +234PA2 H TYP=FUL$AUT=A.LUCA$CUT=31-DEC-2008$ +234PA C References:1920KI01, 1931CU01, 1939SA11, 1948KN23, 1961GE13, 1962BR05, +234PA2C 1963BJ02, 1964AB04, 1965FO12, 1973TA25, 1973GO40, 1973SA33, 1978CH06, +234PA3C 1982MO30, 1990SC09, 1990CO08, 1993SU37, 1998AD08, 2003Au03, 2004Ab03, +234PA4C 2006AL28, 2007BR04 +234PA T Auger electrons and X ray energies and emission intensities: +234PA T {U Energy (keV)} {U Intensity} {U Line} +234PA T +234PA T 92.288 0.013 9 XKA2 +234PA T 95.869 0.021 13 XKA1 +234PA T +234PA T 107.595 |] XKB3 +234PA T 108.422 |] 0.007 5 XKB1 +234PA T 109.072 |] XKB5II +234PA T +234PA T 111.405 |] XKB2 +234PA T 111.87 |] 0.0025 16 XKB4 +234PA T 112.38 |] XKO23 +234PA T +234PA T 11.3676-20.1126 7.1 3 XL (total) +234PA T 11.3676 0.178 12 XLL +234PA T 13.1215-13.2887 2.92 18 XLA +234PA T 14.9488 0.0423 29 XLC +234PA T 15.3584-17.6655 3.21 13 XLB +234PA T 18.9396-20.1126 0.766 29 XLG +234PA T +234PA T 70.081-78.822 |] KLL AUGER +234PA T 85.989-95.858 |] 0.0014 9 KLX AUGER +234PA T 101.87-112.59 |] KXY AUGER +234PA T 5.9-21.6 7.7 6 L AUGER +234TH P 0.0 0+ 24.10 D 3 272 10 +234PA N 1.0 1.0 1 1.0 +234PA L 0 4+ 6.70 H 5 +234PA L 73.92 (0)- 1.159 M 11 +234PA B 198 1077.8 15 6.4 +234PAS B EAV=53 3 +234PA G 73.92 2 0.0133 14M1+E2 0.11 3 10.6 4 +234PA2 G LC=7.96 25$MC=1.94 7$NC=0.520 18 +234PA3 G OC=0.124 4 +234PA L 73.92 2 (3)+ +234PA B 198 1077.8 15 6.4 2U +234PAS B EAV=53 3 +234PA G 73.92 2 0.0133 14M1+E2 0.11 3 10.6 4 +234PA2 G LC=7.96 25$MC=1.94 7$NC=0.520 18 +234PA3 G OC=0.124 4 +234PA L 103.42 (2)- 0.5 NS +234PA G 29.50 2 0.00123 14E2 4390 70 +234PA2 G LC=3210 50$MC=880 13$NC=237 4 +234PA3 G OC=53.3 8 +234PA L 166.3 (1)- 0.1 NS +234PA B 106 1014.1 12 6.3 1 +234PAS B EAV=28 3 +234PA G 62.88 2 0.0164 28M1+E2 0.33 8 25 5 +234PA2 G LC=19 4$MC=4.8 9$NC=1.30 24 +234PA3 G OC=0.30 6 +234PA G 92.38 1 2.18 19M1 5.27 8 +234PA2 G LC=3.98 6$MC=0.960 14$NC=0.258 4 +234PA3 G OC=0.0618 9 +234PA L 166.72 (1)+ 0.55 NS 10 +234PA B 105 106.5 7 6.7 +234PAS B EAV=27 3 +234PA G 63.30 2 3.75 8E1 0.405 6 +234PA2 G LC=0.305 5$MC=0.0749 11$NC=0.0197 3 +234PA3 G OC=0.00447 7 +234PA G 92.80 2 2.15 19E1 0.1472 21 +234PA2 G LC=0.1110 16$MC=0.0271 4$NC=0.00716 10 +234PA3 G OC=0.001643 23 +234PA L 177.27 1- +234PA B 95 100.016 5 9.1 1 +234PAS B EAV=25 3 +234PA G 103.35 100.0032 10M1 3.81 6 +234PA2 G LC=2.88 5$MC=0.694 10$NC=0.186 3 +234PA3 G OC=0.0446 7 +234PA L 186.73 (1)+ +234PA B 85 101.6 6 7 +234PAS B EAV=22 3 +234PA G 20.01 2 0.0051 21M1+E2 0.08 2 240 70 +234PA2 G LC=70 40$MC=124 21$NC=33 6 +234PA3 G OC=7.8 13 +234PA G 83.31 5 0.061 5E1 0.196 3 +234PA2 G LC=0.1475 21$MC=0.0361 5$NC=0.00952 14 +234PA3 G OC=0.00218 3 +234PA G 112.81 5 0.215 22E1 0.23 14 +234PA2 G KC=0.21 13$LC=0.0666 10$MC=0.01620 23$NC=0.00429 6 +234PA3 G OC=0.000989 14 + diff --git a/HEN_HOUSE/spectra/lnhb/Ti-44.txt b/HEN_HOUSE/spectra/lnhb/Ti-44.txt index 677de8965..095cacad0 100644 --- a/HEN_HOUSE/spectra/lnhb/Ti-44.txt +++ b/HEN_HOUSE/spectra/lnhb/Ti-44.txt @@ -1,35 +1,35 @@ - 44SC 44TI EC DECAY (60.0 Y) - 44SC T Auger electrons and X ray energies and emission intensities: - 44SC T {U Energy (keV)} {U Intensity} {U Line} - 44SC T - 44SC T 4.0862 5.76 18 XKA2 - 44SC T 4.0906 11.4 4 XKA1 - 44SC T - 44SC T 4.4604 |] 2.26 8 XKB1 - 44SC T 4.4866 |] XKB5II - 44SC T - 44SC T - 44SC T 0.348-0.468 0.45 9 XL (total) - 44SC T 0.348 XLL - 44SC T -0.468 XLG - 44SC T - 44SC T 3.45-3.65 |] KLL AUGER - 44SC T 3.93-4.08 |] 79.5 21 KLX AUGER - 44SC T 4.38-4.48 |] KXY AUGER - 44SC T 0.3-0.5 167.5 24 L AUGER - 44TI P 0.0 0+ 60.0 Y 11 267.5 19 - 44SC N 1.0 1.0 1 1.0 - 44SC L 0 2+ 3.97 H 4 - 44SC L 67.8680 141- 154.2 NS 8 - 44SC E 0.4 119.3 1 - 44SC2 E CK=0.8917 19$CL=0.0938 16$CM=0.0145 7 - 44SC G 67.8679 1493.0 15E1 0.0845 25 - 44SC2 G KC=0.0766 23$LC=0.00665 $MC=0.00125 - 44SC L 146.22 3 0- 50.4 US 7 - 44SC E 99.6 116.5 - 44SC2 E CK=0.8891 20$CL=0.0960 16$CM=0.0149 7 - 44SC G 78.36 3 96.4 11M1 0.032 1 - 44SC2 G KC=0.0273 8$LC=0.00244 $MC=0.00046 - 44SC G 146.22 3 0.092 3[M2] 0.046 1 - 44SC2 G KC=0.0414 12$LC=0.00385 $MC=0.00075 - + 44SC 44TI EC DECAY (60.0 Y) + 44SC T Auger electrons and X ray energies and emission intensities: + 44SC T {U Energy (keV)} {U Intensity} {U Line} + 44SC T + 44SC T 4.0862 5.76 18 XKA2 + 44SC T 4.0906 11.4 4 XKA1 + 44SC T + 44SC T 4.4604 |] 2.26 8 XKB1 + 44SC T 4.4866 |] XKB5II + 44SC T + 44SC T + 44SC T 0.348-0.468 0.45 9 XL (total) + 44SC T 0.348 XLL + 44SC T -0.468 XLG + 44SC T + 44SC T 3.45-3.65 |] KLL AUGER + 44SC T 3.93-4.08 |] 79.5 21 KLX AUGER + 44SC T 4.38-4.48 |] KXY AUGER + 44SC T 0.3-0.5 167.5 24 L AUGER + 44TI P 0.0 0+ 60.0 Y 11 267.5 19 + 44SC N 1.0 1.0 1 1.0 + 44SC L 0 2+ 3.97 H 4 + 44SC L 67.8680 141- 154.2 NS 8 + 44SC E 0.4 119.3 1 + 44SC2 E CK=0.8917 19$CL=0.0938 16$CM=0.0145 7 + 44SC G 67.8679 1493.0 15E1 0.0845 25 + 44SC2 G KC=0.0766 23$LC=0.00665 $MC=0.00125 + 44SC L 146.22 3 0- 50.4 US 7 + 44SC E 99.6 116.5 + 44SC2 E CK=0.8891 20$CL=0.0960 16$CM=0.0149 7 + 44SC G 78.36 3 96.4 11M1 0.032 1 + 44SC2 G KC=0.0273 8$LC=0.00244 $MC=0.00046 + 44SC G 146.22 3 0.092 3[M2] 0.046 1 + 44SC2 G KC=0.0414 12$LC=0.00385 $MC=0.00075 + diff --git a/HEN_HOUSE/spectra/lnhb/Tl-201.txt b/HEN_HOUSE/spectra/lnhb/Tl-201.txt index 2acb724e8..ddec91af3 100644 --- a/HEN_HOUSE/spectra/lnhb/Tl-201.txt +++ b/HEN_HOUSE/spectra/lnhb/Tl-201.txt @@ -1,59 +1,72 @@ -201HG 201TL EC DECAY (3.0421 D) -201HG T Auger electrons and X ray energies and emission intensities: -201HG T {U Energy (keV)} {U Intensity} {U Line} -201HG T -201HG T 68.895 27.3 5 XKA2 -201HG T 70.82 46.4 7 XKA1 -201HG T -201HG T 79.823 |] XKB3 -201HG T 80.254 |] 15.7 4 XKB1 -201HG T 80.762 |] XKB5II -201HG T -201HG T 82.435 |] XKB2 -201HG T 82.776 |] 4.61 13 XKB4 -201HG T 83.028 |] XKO23 -201HG T -201HG T 8.72-14.85 42.7 18 XL (total) -201HG T 8.72 0.88 15 XLL -201HG T 9.898-9.989 17.1 27 XLA -201HG T 10.651 0.26 6 XLC -201HG T 11.563-12.56 14.9 21 XLB -201HG T 13.41-14.85 2.8 5 XLG -201HG T -201HG T 53.178-58.277 |] KLL AUGER -201HG T 64.594-68.43 |] 3.7 4 KLX AUGER -201HG T 75.98-83.09 |] KXY AUGER -201HG T 5.1-14.8 57.7 7 L AUGER -201TL P 0.0 1/2+ 3.0421 D 17 483 15 -201HG N 1.0 1.0 1 1.0 -201HG L 0 3/2- STABLE -201HG E 21 216.5 1 -201HG2 E CK=0.763 3$CL=0.178 3$CM=0.0451 12 -201HG L 1.565 1/2- -201HG E 25 226.5 -201HG2 E CK=0.763 3$CL=0.178 3$CM=0.0451 12 -201HG G 1.565 6 0.00081 47M1+E2 0.0105 15 4.7E4 7 -201HG L 26.269 5/2- 630 PS -201HG E 0.23 8.5 1U -201HG G 26.269 7 0.0082 9M1(+E2) 0.02 76.9 23 -201HG2 G LC=58.8 18$MC=13.74 41 -201HG L 32.138 3/2- 0.2 NS -201HG E 13.0 56.9 1 -201HG2 E CK=0.758 3$CL=0.181 3$CM=0.0461 12 -201HG G 5.869 260.5 [M1+E2] -201HG G 30.573 170.258 5M1+E2 0.011 4 48.5 2 -201HG2 G LC=36.9 4$MC=8.79 26 -201HG G 32.138 160.263 5M1+E2 0.017 40 41.9 2 -201HG2 G LC=32.0 4$MC=7.62 23 -201HG L 167.45 1/2- 2 NS -201HG E 40.9 96.1 -201HG2 E CK=0.724 7$CL=0.206 7$CM=0.054 2 -201HG G 135.312 342.604 22M1+E2 -0.06 1 3.45 10 -201HG2 G KC=2.83 3$LC=0.48 5$MC=0.1138 34 -201HG G 141.18 4 0.008 [E2] 1.41 4 -201HG2 G KC=0.372 11$LC=0.774 23$MC=0.202 6 -201HG G 165.885 310.147 2M1(+E2) 0.4 1.86 8 -201HG2 G KC=1.57 3$LC=0.270 5$MC=0.0634 19 -201HG G 167.45 3 10.0 1M1+E2 0.08 1.89 8 -201HG2 G KC=1.55 3$LC=0.262 5$MC=0.0620 19 - +201HG 201TL EC DECAY (3.0421 D) +201HG T Auger electrons and X ray energies and emission intensities: +201HG T {U Energy (keV)} {U Intensity} {U Line} +201HG T +201HG T 68.895 27.3 5 XKA2 +201HG T 70.82 46.4 7 XKA1 +201HG T +201HG T 79.823 |] XKB3 +201HG T 80.254 |] 15.7 4 XKB1 +201HG T 80.762 |] XKB5II +201HG T +201HG T 82.435 |] XKB2 +201HG T 82.776 |] 4.61 13 XKB4 +201HG T 83.028 |] XKO23 +201HG T +201HG T 8.72-14.85 42.7 18 XL (total) +201HG T 8.72 0.88 15 XLL +201HG T 9.898-9.989 17.1 27 XLA +201HG T 10.651 0.26 6 XLC +201HG T 11.563-12.56 14.9 21 XLB +201HG T 13.41-14.85 2.8 5 XLG +201HG T +201HG T 53.178-58.277 |] KLL AUGER +201HG T 64.594-68.43 |] 3.7 4 KLX AUGER +201HG T 75.98-83.09 |] KXY AUGER +201HG T 5.1-14.8 57.7 7 L AUGER +201TL P 0.0 1/2+ 3.0421 D 17 483 15 +201HG N 1.0 1.0 1 1.0 +201HG L 0 3/2- STABLE +201HG E 21 216.5 1 +201HG2 E CK=0.7630 28$CL=0.1776 20$CM=0.0451 9$CN=0.0120 5 +201HG3 E CO=0.0024 1 +201HG L 1.565 1/2- +201HG E 25 226.5 +201HG2 E CK=0.7628 28$CL=0.1777 20$CM=0.0451 9$CN=0.0120 5 +201HG3 E CO=0.0024 1 +201HG G 1.565 6 0.00081 47M1+E2 0.0105 15 4.7E4 7 +201HG L 26.269 5/2- 630 PS +201HG E 0.23 8.5 1U +201HG2 E CK=0.7591 31$CL=0.1803 22$CM=0.0459 10$CN=0.0123 5 +201HG3 E CO=0.0024 1 +201HG G 26.269 7 0.0082 9M1(+E2) 0.02 76.9 23 +201HG2 G LC=58.8 18$MC=13.74 41$NC=3.53 11 +201HG3 G OC=0.725 22 +201HG L 32.138 3/2- 0.2 NS +201HG E 13.0 56.9 1 +201HG2 E CK=0.7582 31$CL=0.1810 22$CM=0.0461 10$CN=0.0123 5 +201HG3 E CO=0.0024 1 +201HG G 5.869 260.5 [M1+E2] +201HG G 30.573 170.258 5M1+E2 0.011 4 48.5 2 +201HG2 G LC=36.9 4$MC=8.79 26$NC=2.26 7 +201HG3 G OC=0.464 14 +201HG G 32.138 160.263 5M1+E2 0.017 40 41.9 2 +201HG2 G LC=32.0 4$MC=7.62 23$NC=1.96 6 +201HG3 G OC=0.402 12 +201HG L 167.45 1/2- 2 NS +201HG E 40.9 96.1 +201HG2 E CK=0.724 6$CL=0.2056 46$CM=0.0536 15$CN=0.0144 7 +201HG3 E CO=0.0028 1 +201HG G 135.312 342.604 22M1+E2 -0.06 1 3.45 10 +201HG2 G KC=2.83 3$LC=0.48 5$MC=0.1138 34$NC=0.0292 9 +201HG3 G OC=0.00601 18 +201HG G 141.18 4 0.008 [E2] 1.41 4 +201HG2 G KC=0.372 11$LC=0.774 23$MC=0.202 6$NC=0.0511 15 +201HG3 G OC=0.00935 28 +201HG G 165.885 310.147 2M1(+E2) 0.4 1.86 8 +201HG2 G KC=1.57 3$LC=0.270 5$MC=0.0634 19$NC=0.01628 49 +201HG3 G OC=0.00335 10 +201HG G 167.45 3 10.0 1M1+E2 0.08 1.89 8 +201HG2 G KC=1.55 3$LC=0.262 5$MC=0.0620 19$NC=0.01590 48 +201HG3 G OC=0.00327 10 + diff --git a/HEN_HOUSE/spectra/lnhb/Tl-204.txt b/HEN_HOUSE/spectra/lnhb/Tl-204.txt index f2530b8cd..61e91ea8c 100644 --- a/HEN_HOUSE/spectra/lnhb/Tl-204.txt +++ b/HEN_HOUSE/spectra/lnhb/Tl-204.txt @@ -1,53 +1,53 @@ -204HG 204TL EC DECAY (3.788 Y) -204HG T Auger electrons and X ray energies and emission intensities: -204HG T {U Energy (keV)} {U Intensity} {U Line} -204HG T -204HG T 68.895 0.474 20 XKA2 -204HG T 70.82 0.812 34 XKA1 -204HG T -204HG T 79.823 |] XKB3 -204HG T 80.254 |] 0.273 10 XKB1 -204HG T 80.762 |] XKB5II -204HG T -204HG T 82.435 |] XKB2 -204HG T 82.776 |] 0.081 3 XKB4 -204HG T 83.028 |] XKO23 -204HG T -204HG T 8.721-14.847 0.787 20 XL (total) -204HG T 8.721 0.0202 8 XLL -204HG T 9.898-9.989 0.395 14 XLA -204HG T 10.647 0.00488 22 XLC -204HG T 11.924-11.822 0.315 9 XLB -204HG T -14.847 0.0574 18 XLG -204HG T -204HG T 53.17-58.28 |] KLL AUGER -204HG T 64.59-70.81 |] 0.065 8 KLX AUGER -204HG T 75.92-83.08 |] KXY AUGER -204HG T 5.1-14.8 1.48 3 L AUGER -204TL P 0.0 2- 3.788 Y 15 345.0 13 -204HG N 3.425E1 3.425E1 0.0292 3.425E1 -204HG L 0 0+ STABLE -204HG E 2.92 139.6 1U -204HG2 E CK=0.5843 14$CL=0.3024 10$CM=0.1133 5 - -204PB 204TL B- DECAY (3.788 Y) -204PB T Auger electrons and X ray energies and emission intensities: -204PB T {U Energy (keV)} {U Intensity} {U Line} -204PB T -204PB T 72.8049 0.0044 3 XKA2 -204PB T 74.97 0.0061 3 XKA1 -204PB T -204PB T 84.451 |] XKB3 -204PB T 84.937 |] 0.0027 2 XKB1 -204PB T 85.47 |] XKB5II -204PB T -204PB T 87.238 |] XKB2 -204PB T 87.58 |] 0.00073 2 XKB4 -204PB T 87.911 |] XKO23 -204PB T -204TL P 0.0 2- 3.788 Y 15 763.72 18 -204PB N 1.03E0 1.03E0 0.9708 1.03E0 -204PB L 0 0+ STABLE -204PB B 763.7 2 97.08 13 10.1 1U -204PBS B EAV=243.9 1 - +204HG 204TL EC DECAY (3.788 Y) +204HG T Auger electrons and X ray energies and emission intensities: +204HG T {U Energy (keV)} {U Intensity} {U Line} +204HG T +204HG T 68.895 0.474 20 XKA2 +204HG T 70.82 0.812 34 XKA1 +204HG T +204HG T 79.823 |] XKB3 +204HG T 80.254 |] 0.273 10 XKB1 +204HG T 80.762 |] XKB5II +204HG T +204HG T 82.435 |] XKB2 +204HG T 82.776 |] 0.081 3 XKB4 +204HG T 83.028 |] XKO23 +204HG T +204HG T 8.721-14.847 0.787 20 XL (total) +204HG T 8.721 0.0202 8 XLL +204HG T 9.898-9.989 0.395 14 XLA +204HG T 10.647 0.00488 22 XLC +204HG T 11.924-11.822 0.315 9 XLB +204HG T -14.847 0.0574 18 XLG +204HG T +204HG T 53.17-58.28 |] KLL AUGER +204HG T 64.59-70.81 |] 0.065 8 KLX AUGER +204HG T 75.92-83.08 |] KXY AUGER +204HG T 5.1-14.8 1.48 3 L AUGER +204TL P 0.0 2- 3.788 Y 15 345.0 13 +204HG N 3.425E1 3.425E1 0.0292 3.425E1 +204HG L 0 0+ STABLE +204HG E 2.92 139.6 1U +204HG2 E CK=0.5843 14$CL=0.3024 10$CM=0.1133 5 + +204PB 204TL B- DECAY (3.788 Y) +204PB T Auger electrons and X ray energies and emission intensities: +204PB T {U Energy (keV)} {U Intensity} {U Line} +204PB T +204PB T 72.8049 0.0044 3 XKA2 +204PB T 74.97 0.0061 3 XKA1 +204PB T +204PB T 84.451 |] XKB3 +204PB T 84.937 |] 0.0027 2 XKB1 +204PB T 85.47 |] XKB5II +204PB T +204PB T 87.238 |] XKB2 +204PB T 87.58 |] 0.00073 2 XKB4 +204PB T 87.911 |] XKO23 +204PB T +204TL P 0.0 2- 3.788 Y 15 763.72 18 +204PB N 1.03E0 1.03E0 0.9708 1.03E0 +204PB L 0 0+ STABLE +204PB B 763.7 2 97.08 13 10.1 1U +204PBS B EAV=243.9 1 + diff --git a/HEN_HOUSE/spectra/lnhb/Tl-206.txt b/HEN_HOUSE/spectra/lnhb/Tl-206.txt index 62cd0fe00..40d878866 100644 --- a/HEN_HOUSE/spectra/lnhb/Tl-206.txt +++ b/HEN_HOUSE/spectra/lnhb/Tl-206.txt @@ -1,46 +1,47 @@ -206PB 206TL B- DECAY (4.202 M) -206PB H TYP=Full$AUT=F. Kondev$CUT=01-OCT-2006$ -206PB C Evaluation history: Type=Full;Author=F. Kondev;Cutoff date=01-OCT-2006 -206PB C References: 1977La19, 2002Ba85, 2003Au03, 2005KiZW -206PB T Auger electrons and X ray energies and emission intensities: -206PB T {U Energy (keV)} {U Intensity} {U Line} -206PB T -206PB T 72.8049 0.026 3 XKA2 -206PB T 74.97 0.044 5 XKA1 -206PB T -206PB T 84.451 |] XKB3 -206PB T 84.937 |] 0.0150 17 XKB1 -206PB T 85.47 |] XKB5II -206PB T -206PB T 87.238 |] XKB2 -206PB T 87.58 |] 0.0045 6 XKB4 -206PB T 87.911 |] XKO23 -206PB T -206PB T 9.19-15.217 0.035 4 XL (total) -206PB T 9.19 XLL -206PB T 10.449-10.551 XLA -206PB T 11.349 XLC -206PB T 12.144-12.795 XLB -206PB T 14.308-15.217 XLG -206PB T -206PB T 56.028-61.669 |] KLL AUGER -206PB T 68.181-74.969 |] 0.0034 6 KLX AUGER -206PB T 80.3-88 |] KXY AUGER -206PB T 5.2-15.7 L AUGER -206TL P 0.0 0- 4.202 M 11 1532.4 6 -206PB N 1.0 1.0 1 1.0 -206PB L 0 0+ STABLE -206PB B 1532.4 6 99.885 14 5.2 -206PBS B EAV=538.86 25 -206PB L 803.06 3 2+ 8.14 PS 8 -206PB B 729.3 6 0.0051 3 8.6 1U -206PBS B EAV=232.39 21 -206PB G 803.06 3 0.0050 3E2 0.0103031 -206PB2 G KC=0.00801 24$LC=0.00174 5$MC=4.19E-4 13 -206PB L 1166.4 5 0+ 0.75 NS 4 -206PB B 366.0 8 0.110 14 6 -206PBS B EAV=104.52 25 -206PB G 363.3 5 0.00014 14E2 0.0663 20 -206PB2 G KC=0.0414 12$LC=0.0187 6$MC=0.00476 14 -206PB G 1165 2 - +206PB 206TL B- DECAY (4.202 M) +206PB H TYP=FUL$AUT=F.G.KONDEV$CUT=01-OCT-2006$ +206PB C References:1977La19, 2002Ba85, 2003Au03, 2005KiZW +206PB T Auger electrons and X ray energies and emission intensities: +206PB T {U Energy (keV)} {U Intensity} {U Line} +206PB T +206PB T 72.8049 0.026 3 XKA2 +206PB T 74.97 0.044 5 XKA1 +206PB T +206PB T 84.451 |] XKB3 +206PB T 84.937 |] 0.0150 17 XKB1 +206PB T 85.47 |] XKB5II +206PB T +206PB T 87.238 |] XKB2 +206PB T 87.58 |] 0.0045 6 XKB4 +206PB T 87.911 |] XKO23 +206PB T +206PB T 9.19-15.217 0.035 4 XL (total) +206PB T 9.19 XLL +206PB T 10.449-10.551 XLA +206PB T 11.349 XLC +206PB T 12.144-12.795 XLB +206PB T 14.308-15.217 XLG +206PB T +206PB T 56.028-61.669 |] KLL AUGER +206PB T 68.181-74.969 |] 0.0034 6 KLX AUGER +206PB T 80.3-88 |] KXY AUGER +206PB T 5.2-15.7 L AUGER +206TL P 0.0 0- 4.202 M 11 1532.4 6 +206PB N 1.0 1.0 1 1.0 +206PB L 0 0+ STABLE +206PB B 1532.4 6 99.885 14 5.2 +206PBS B EAV=538.86 25 +206PB L 803.06 3 2+ 8.14 PS 8 +206PB B 729.3 6 0.0051 3 8.6 1U +206PBS B EAV=232.39 21 +206PB G 803.06 3 0.0050 3E2 0.0103031 +206PB2 G KC=0.00801 24$LC=0.00174 5$MC=0.000419 13$NC=1.063E-4 32 +206PB3 G OC=2.06E-5 6 +206PB L 1166.4 5 0+ 0.75 NS 4 +206PB B 366.0 8 0.110 14 6 +206PBS B EAV=104.52 25 +206PB G 363.3 5 0.00014 14E2 0.0663 20 +206PB2 G KC=0.0414 12$LC=0.0187 6$MC=0.00476 14$NC=0.001204 36 +206PB3 G OC=0.000223 7 +206PB G 1165 2 E0 + diff --git a/HEN_HOUSE/spectra/lnhb/Tl-207.txt b/HEN_HOUSE/spectra/lnhb/Tl-207.txt index 811772020..92b0ac3f6 100644 --- a/HEN_HOUSE/spectra/lnhb/Tl-207.txt +++ b/HEN_HOUSE/spectra/lnhb/Tl-207.txt @@ -1,51 +1,53 @@ -207PB 207TL B- DECAY (4.774 M) -207PB H TYP=Full$AUT=F.Kondev$CUT=12-DEC-2010$ -207PB C Evaluation history: Type=Full;Author=F.Kondev;Cutoff date=12-DEC-2010 -207PB C References: 1931Cu01, 1940Fa04, 1950Ev03, 1953Sa11, 1961Cu05, 1963Ch09, -207PB2C 1967Da10, 1967Tr01, 1968Br17, 1970Kl03, 1971Go40, 1972Ha59, 1973Ba38, -207PB3C 1974Ha34, 1976Av01, 1977La19, 1988Hi14, 1991Ar04, 1996Sc06, 1998ScZM, -207PB4C 1999ScZX, 2000Sc47, 2000He14, 2003De44, 2003Au03, 2008Ki07, 2008DuZX, -207PB5C 2011Ko04 -207PB T Auger electrons and X ray energies and emission intensities: -207PB T {U Energy (keV)} {U Intensity} {U Line} -207PB T -207PB T 72.8049 0.00154 6 XKA2 -207PB T 74.97 0.00258 10 XKA1 -207PB T -207PB T 84.451 |] XKB3 -207PB T 84.937 |] 0.00088 4 XKB1 -207PB T 85.47 |] XKB5II -207PB T -207PB T 87.238 |] XKB2 -207PB T 87.58 |] 0.00026612 XKB4 -207PB T 87.911 |] XKO23 -207PB T -207PB T 9.186-15.2169 0.00201 6 XL (total) -207PB T 9.186 5.00E-5 19 XLL -207PB T 10.4495-10.5512 0.00095 4 XLA -207PB T 11.3495 1.50E-5 7 XLC -207PB T 12.1443-13.3763 0.00084124 XLB -207PB T 14.3078-15.2169 0.000159 5 XLG -207PB T -207PB T 56.028-61.669 |] KLL AUGER -207PB T 68.181-74.969 |] 0.00020223 KLX AUGER -207PB T 80.3-88 |] KXY AUGER -207PB T 5.33-15.82 0.00333 6 L AUGER -207TL P 0.0 1/2+ 4.774 M 12 1418 5 -207PB N 1.0 1.0 1 1.0 -207PB L 0 0 1/2- STABLE -207PB B 1418 5 99.729 10 5.11 -207PBS B EAV=492.5 21 -207PB L 569.6982 205/2- -207PB B 848 5 0.00008 10.8 1U -207PBS B EAV=273.2 18 -207PB G 569.698 2 0.00185 19E2 0.0216 3 -207PB2 G KC=0.01584 23$LC=0.00439 7$MC=1081E-6 16 -207PB L 897.698 173/2- -207PB B 520 5 0.271 10 6.15 1 -207PBS B EAV=155.0 17 -207PB G 328.10 120.00142 14[M1] 0.334 5 -207PB2 G KC=0.273 4$LC=0.0466 7$MC=0.01090 16 -207PB G 897.77 120.263 9M1+E2 0.091 9000 0.0233 4 -207PB2 G KC=0.0192 3$LC=0.00318 5$MC=7.41E-4 11 - +207PB 207TL B- DECAY (4.774 M) +207PB H TYP=FUL$AUT=F.G.KONDEV$CUT=12-DEC-2010$ +207PB C References:1931Cu01, 1940Fa04, 1950Ev03, 1953Sa11, 1961Cu05, 1963Ch09, +207PB2C 1967Da10, 1967Tr01, 1968Br17, 1970Kl03, 1971Go40, 1972Ha59, 1973Ba38, +207PB3C 1974Ha34, 1976Av01, 1977La19, 1988Hi14, 1991Ar04, 1996Sc06, 1998ScZM, +207PB4C 1999ScZX, 2000Sc47, 2000He14, 2003De44, 2003Au03, 2008Ki07, 2008DuZX, +207PB5C 2011Ko04 +207PB T Auger electrons and X ray energies and emission intensities: +207PB T {U Energy (keV)} {U Intensity} {U Line} +207PB T +207PB T 72.8049 0.00154 6 XKA2 +207PB T 74.97 0.00258 10 XKA1 +207PB T +207PB T 84.451 |] XKB3 +207PB T 84.937 |] 0.00088 4 XKB1 +207PB T 85.47 |] XKB5II +207PB T +207PB T 87.238 |] XKB2 +207PB T 87.58 |] 0.00026612 XKB4 +207PB T 87.911 |] XKO23 +207PB T +207PB T 9.186-15.2169 0.00201 6 XL (total) +207PB T 9.186 5.00E-5 19 XLL +207PB T 10.4495-10.5512 0.00095 4 XLA +207PB T 11.3495 1.50E-5 7 XLC +207PB T 12.1443-13.3763 0.00084124 XLB +207PB T 14.3078-15.2169 0.000159 5 XLG +207PB T +207PB T 56.028-61.669 |] KLL AUGER +207PB T 68.181-74.969 |] 0.00020223 KLX AUGER +207PB T 80.3-88 |] KXY AUGER +207PB T 5.33-15.82 0.00333 6 L AUGER +207TL P 0.0 1/2+ 4.774 M 12 1418 5 +207PB N 1.0 1.0 1 1.0 +207PB L 0 1/2- STABLE +207PB B 1418 5 99.729 10 5.11 +207PBS B EAV=492.5 21 +207PB L 569.6982 205/2- +207PB B 848 5 0.00008 10.8 1U +207PBS B EAV=273.2 18 +207PB G 569.698 2 0.00185 19E2 0.0216 3 +207PB2 G KC=0.01584 23$LC=0.00439 7$MC=0.001081 16$NC=0.000274 4 +207PB3 G OC=5.21E-5 8 +207PB L 897.698 173/2- +207PB B 520 5 0.271 10 6.15 1 +207PBS B EAV=155.0 17 +207PB G 328.10 120.00142 14[M1] 0.334 5 +207PB2 G KC=0.273 4$LC=0.0466 7$MC=0.01090 16$NC=0.00277 4 +207PB3 G OC=0.000552 8 +207PB G 897.77 120.263 9M1+E2 0.091 9000 0.0233 4 +207PB2 G KC=0.0192 3$LC=0.00318 5$MC=0.000741 11$NC=0.000188 3 +207PB3 G OC=3.76E-5 4 + diff --git a/HEN_HOUSE/spectra/lnhb/Tl-208.txt b/HEN_HOUSE/spectra/lnhb/Tl-208.txt index 75c1cfe73..db74d430d 100644 --- a/HEN_HOUSE/spectra/lnhb/Tl-208.txt +++ b/HEN_HOUSE/spectra/lnhb/Tl-208.txt @@ -1,142 +1,167 @@ -208PB 208TL B- DECAY (3.058 M) -208PB H TYP=Update$AUT=A.L. Nichols$CUT=30-MAY-2011$ -208PB2 H TYP=Full$AUT=A.L. Nichols$CUT=30-AUG-2001$ -208PB C Evaluation history: Type=Update;Author=A.L. Nichols;Cutoff date=30-MAY-2011 -208PB2C Type=Full;Author=A.L. Nichols;Cutoff date=30-AUG-2001 -208PB C References: 1954El07, 1957Ba05, 1957Kr56, 1957Vo22, 1960Em01, 1960Sc07, -208PB2C 1961Si11, 1963Da11, 1967Os01, 1967La20, 1969La23, 1969Au10, 1969Pa02, -208PB3C 1970Mu21, 1971Ac02, 1972Ja25, 1972DaZA, 1973Da38, 1975Ko02, 1976Av03, -208PB4C 1977Ge12, 1977La19, 1978Av01, 1982Sa36, 1983Va22, 1983Sc13, 1984Ge07, -208PB5C 1990Go33, 1992Li05, 1993El08, 1996Sc06, 1997Sc21, 1998ScZM, 1999ScZX, -208PB6C 2000He14, 2002Ba85, 2002Ra45, 2003Au03, 2006Va23, 2007Ma45, 2008Ki07 -208PB T Auger electrons and X ray energies and emission intensities: -208PB T {U Energy (keV)} {U Intensity} {U Line} -208PB T -208PB T 72.8049 2.03 5 XKA2 -208PB T 74.97 3.42 7 XKA1 -208PB T -208PB T 84.451 |] XKB3 -208PB T 84.937 |] 1.17 3 XKB1 -208PB T 85.47 |] XKB5II -208PB T -208PB T 87.238 |] XKB2 -208PB T 87.58 |] 0.353 11 XKB4 -208PB T 87.911 |] XKO23 -208PB T -208PB T 9.184-15.216 2.75 12 XL (total) -208PB T 9.184 0.0671 19 XLL -208PB T 10.45-10.551 1.27 4 XLA -208PB T 11.349 0.0209 7 XLC -208PB T 12.142-13.015 1.155 25 XLB -208PB T 14.765-15.216 0.220 5 XLG -208PB T -208PB T 56.028-61.669 |] KLL AUGER -208PB T 68.181-74.969 |] 0.27 3 KLX AUGER -208PB T 80.3-88 |] KXY AUGER -208PB T 5.262-10.398 4.50 13 L AUGER -208TL P 0.0 5+ 3.058 M 6 4999.0 17 -208PB N 1.0 1.0 1 1.0 -208PB G 808.32 130.030 7 -208PB G 835.90 110.076 11 -208PB L 0 0+ STABLE -208PB L 2614.552 103- -208PB G 2614.511 1099.755 4E3 0.00246 4 -208PB2 G KC=1708E-6 24$LC=2.92E-4 4$MC=6.85E-5 10 -208PB L 3197.711 105- -208PB B 1801.3 1749.2 6 5.61 -208PBS B EAV=649.5 7 -208PB G 583.187 2 85.0 3E2 0.0205 3 -208PB2 G KC=0.01509 22$LC=0.00410 6$MC=1009E-6 15 -208PB L 3475.078 114- -208PB B 1523.9 1722.1 5 5.69 1 -208PBS B EAV=535.4 7 -208PB G 277.37 2 6.6 3[M1+E2] 0.02 1 0.529 8 -208PB2 G KC=0.432 6$LC=0.0739 11$MC=0.01730 25 -208PB G 860.53 2 12.4 1[M1+E2] 0.015 0.0262 4 -208PB2 G KC=0.0215 3$LC=0.00356 5$MC=8.31E-4 12 -208PB L 3708.451 125- -208PB B 1290.5 1724.1 2 5.38 -208PBS B EAV=441.5 7 -208PB G 233.37 2 0.31 1[M1+E2] 0.70 7 0.66 3 -208PB2 G KC=0.51 3$LC=0.1136 18$MC=0.0275 4 -208PB G 510.74 2 22.5 2[M1+E2] -0.05 5 0.1019 16 -208PB2 G KC=0.0835 13$LC=0.01406 21$MC=0.00329 5 -208PB G 1093.90 2 0.44 1E2 0.00560 8 -208PB2 G KC=0.00449 7$LC=8.44E-4 12$MC=2.00E-4 3 -208PB L 3919.966 136- -208PB B 1079.0 170.63 4 6.68 1 -208PBS B EAV=358.6 7 -208PB G 211.52 2 0.18 1M1+E2 0.18 2 1.096 17 -208PB2 G KC=0.890 14$LC=0.1570 22$MC=0.0369 6 -208PB G 722.26 2 0.24 4M1+E2 0.31 3 0.0387 7 -208PB2 G KC=0.0317 6$LC=0.00534 10$MC=1248E-6 22 -208PB L 3946.578 144- -208PB B 1052.4 170.048 3 7.76 1 -208PBS B EAV=348.4 7 -208PB G 748.87 2 0.046 3[M1] 0.0375 6 -208PB2 G KC=0.0308 5$LC=0.00512 8$MC=1196E-6 17 -208PB L 3961.162 135- -208PB B 1037.8 173.17 4 5.92 -208PBS B EAV=342.8 7 -208PB G 252.71 2 0.78 2[M1+E2] -0.40 4 0.616 15 -208PB2 G KC=0.495 14$LC=0.0926 14$MC=0.0220 4 -208PB G 486.08 2 0.049 4[M1] 0.1164 17 -208PB2 G KC=0.0954 14$LC=0.01608 23$MC=0.00376 6 -208PB G 763.45 2 1.80 2[M1+E2] -0.10 1 0.0354 5 -208PB2 G KC=0.0291 4$LC=0.00484 7$MC=1130E-6 16 -208PB L 3995.438 134- -208PB B 1003.6 170.007 3 8.5 1 -208PBS B EAV=329.7 7 -208PB G 1380.89 2 0.007 3[M1] 0.0078511 -208PB2 G KC=0.00643 9$LC=1050E-6 15$MC=2.45E-4 4 -208PB L 4125.347 125- -208PB B 873.7 170.174 9 6.92 -208PBS B EAV=280.8 6 -208PB G 650.27 2 0.041 5[M1] 0.0541 8 -208PB2 G KC=0.0444 7$LC=0.00742 11$MC=1733E-6 25 -208PB G 927.64 2 0.128 7[M1] 0.0216 3 -208PB2 G KC=0.01774 25$LC=0.00293 5$MC=6.84E-4 10 -208PB L 4180.414 145- -208PB B 818.6 170.231 9 6.7 -208PBS B EAV=260.4 6 -208PB G 705.34 2 0.022 4[M1] 0.0438 7 -208PB2 G KC=0.0360 5$LC=0.00599 9$MC=1399E-6 20 -208PB G 982.70 2 0.204 8[M1] 0.0186 3 -208PB2 G KC=0.01530 22$LC=0.00253 4$MC=5.89E-4 9 -208PB L 4261.871 134- -208PB B 737.1 170.002 1 8.6 1 -208PBS B EAV=230.8 6 -208PB G 1647.32 2 0.002 1[M1] 0.00518 8 -208PB2 G KC=0.00411 6$LC=6.69E-4 10$MC=1556E-7 22 -208PB L 4296.560 135- -208PB B 702.4 170.102 11 6.82 -208PBS B EAV=218.3 6 -208PB G 588.108 180.06 1[M1] 0.0704 10 -208PB2 G KC=0.0577 8$LC=0.00968 14$MC=0.00226 4 -208PB G 821.48 2 0.041 4M1 0.0295 5 -208PB2 G KC=0.0242 4$LC=0.00402 6$MC=9.39E-4 14 -208PB L 4323.946 144+ -208PB B 675.1 170.005 2 8.1 -208PBS B EAV=208.6 6 -208PB G 1126.24 2 0.005 2E1 0.00203 3 -208PB2 G KC=1691E-6 24$LC=2.56E-4 4$MC=5.90E-5 9 -208PB L 4358.670 134- -208PB B 640.3 170.045 4 7.04 1 -208PBS B EAV=196.4 6 -208PB G 883.59 2 0.031 3[M1] 0.0244 4 -208PB2 G KC=0.0201 3$LC=0.00333 5$MC=7.76E-4 11 -208PB G 1160.96 2 0.011 3[M1] 0.0121417 -208PB2 G KC=0.01000 14$LC=1641E-6 23$MC=3.82E-4 6 -208PB G 1744.120 160.002 1M1+E2 0.00457 7 -208PB2 G KC=0.00356 5$LC=5.78E-4 8$MC=1344E-7 19 -208PB L 4383.285 176- -208PB B 615.7 170.017 5 7.41 1 -208PBS B EAV=187.7 6 -208PB G 1185.57 2 0.017 5[M1] 0.0115117 -208PB2 G KC=0.00947 14$LC=1555E-6 22$MC=3.62E-4 5 -208PB L 4480.746 166- -208PB B 518.3 170.052 5 6.67 1 -208PBS B EAV=154.3 6 -208PB G 1283.04 2 0.052 5[M1] 0.0094314 -208PB2 G KC=0.00775 11$LC=1269E-6 18$MC=2.95E-4 5 - +208PB 208TL B- DECAY (3.058 M) +208PB H TYP=UPD$AUT=A.L.NICHOLS$CUT=30-MAY-2011$ +208PB2 H TYP=FUL$AUT=A.L.NICHOLS$CUT=30-AUG-2001$ +208PB C References:1954El07, 1957Ba05, 1957Kr56, 1957Vo22, 1960Em01, 1960Sc07, +208PB2C 1961Si11, 1963Da11, 1967Os01, 1967La20, 1969La23, 1969Au10, 1969Pa02, +208PB3C 1970Mu21, 1971Ac02, 1972Ja25, 1972DaZA, 1973Da38, 1975Ko02, 1976Av03, +208PB4C 1977Ge12, 1977La19, 1978Av01, 1982Sa36, 1983Va22, 1983Sc13, 1984Ge07, +208PB5C 1990Go33, 1992Li05, 1993El08, 1996Sc06, 1997Sc21, 1998ScZM, 1999ScZX, +208PB6C 2000He14, 2002Ba85, 2002Ra45, 2003Au03, 2006Va23, 2007Ma45, 2008Ki07 +208PB T Auger electrons and X ray energies and emission intensities: +208PB T {U Energy (keV)} {U Intensity} {U Line} +208PB T +208PB T 72.8049 2.03 5 XKA2 +208PB T 74.97 3.42 7 XKA1 +208PB T +208PB T 84.451 |] XKB3 +208PB T 84.937 |] 1.17 3 XKB1 +208PB T 85.47 |] XKB5II +208PB T +208PB T 87.238 |] XKB2 +208PB T 87.58 |] 0.353 11 XKB4 +208PB T 87.911 |] XKO23 +208PB T +208PB T 9.184-15.216 2.75 12 XL (total) +208PB T 9.184 0.0671 19 XLL +208PB T 10.45-10.551 1.27 4 XLA +208PB T 11.349 0.0209 7 XLC +208PB T 12.142-13.015 1.155 25 XLB +208PB T 14.765-15.216 0.220 5 XLG +208PB T +208PB T 56.028-61.669 |] KLL AUGER +208PB T 68.181-74.969 |] 0.27 3 KLX AUGER +208PB T 80.3-88 |] KXY AUGER +208PB T 5.262-10.398 4.50 13 L AUGER +208TL P 0.0 5+ 3.058 M 6 4999.0 17 +208PB N 1.0 1.0 1 1.0 +208PB G 808.32 130.030 7 +208PB G 835.90 110.076 11 +208PB L 0 0+ STABLE +208PB L 2614.552 103- +208PB G 2614.511 1099.755 4E3 0.00246 4 +208PB2 G KC=0.001708 24$LC=0.000292 4$MC=6.85E-5 10$NC=1.738E-5 25 +208PB3 G OC=3.45E-6 5$IPC=0.000371 6 +208PB L 3197.711 105- +208PB B 1801.3 1749.2 6 5.61 +208PBS B EAV=649.5 7 +208PB G 583.187 2 85.0 3E2 0.0205 3 +208PB2 G KC=0.01509 22$LC=0.00410 6$MC=0.001009 15$NC=0.000255 4 +208PB3 G OC=4.87E-5 7 +208PB L 3475.078 114- +208PB B 1523.9 1722.1 5 5.69 1 +208PBS B EAV=535.4 7 +208PB G 277.37 2 6.6 3[M1+E2] 0.02 1 0.529 8 +208PB2 G KC=0.432 6$LC=0.0739 11$MC=0.01730 25$NC=0.00440 7 +208PB3 G OC=0.000877 13 +208PB G 860.53 2 12.4 1[M1+E2] 0.015 0.0262 4 +208PB2 G KC=0.0215 3$LC=0.00356 5$MC=0.000831 12$NC=0.000211 3 +208PB3 G OC=4.21E-5 6 +208PB L 3708.451 125- +208PB B 1290.5 1724.1 2 5.38 +208PBS B EAV=441.5 7 +208PB G 233.37 2 0.31 1[M1+E2] 0.70 7 0.66 3 +208PB2 G KC=0.51 3$LC=0.1136 18$MC=0.0275 4$NC=0.00697 10 +208PB3 G OC=0.001351 21 +208PB G 510.74 2 22.5 2[M1+E2] -0.05 5 0.1019 16 +208PB2 G KC=0.0835 13$LC=0.01406 21$MC=0.00329 5$NC=0.000835 13 +208PB3 G OC=1.666E-4 25 +208PB G 1093.90 2 0.44 1E2 0.00560 8 +208PB2 G KC=0.00449 7$LC=0.000844 12$MC=0.000200 3$NC=5.07E-5 7 +208PB3 G OC=9.93E-6 14 +208PB L 3919.966 136- +208PB B 1079.0 170.63 4 6.68 1 +208PBS B EAV=358.6 7 +208PB G 211.52 2 0.18 1M1+E2 0.18 2 1.096 17 +208PB2 G KC=0.890 14$LC=0.1570 22$MC=0.0369 6$NC=0.00938 14 +208PB3 G OC=0.00186 3 +208PB G 722.26 2 0.24 4M1+E2 0.31 3 0.0387 7 +208PB2 G KC=0.0317 6$LC=0.00534 10$MC=0.001248 22$NC=0.000317 6 +208PB3 G OC=6.32E-5 11 +208PB L 3946.578 144- +208PB B 1052.4 170.048 3 7.76 1 +208PBS B EAV=348.4 7 +208PB G 748.87 2 0.046 3[M1] 0.0375 6 +208PB2 G KC=0.0308 5$LC=0.00512 8$MC=0.001196 17$NC=0.000304 5 +208PB3 G OC=6.06E-5 9 +208PB L 3961.162 135- +208PB B 1037.8 173.17 4 5.92 +208PBS B EAV=342.8 7 +208PB G 252.71 2 0.78 2[M1+E2] -0.40 4 0.616 15 +208PB2 G KC=0.495 14$LC=0.0926 14$MC=0.0220 4$NC=0.00557 9 +208PB3 G OC=0.001100 17 +208PB G 486.08 2 0.049 4[M1] 0.1164 17 +208PB2 G KC=0.0954 14$LC=0.01608 23$MC=0.00376 6$NC=0.000955 14 +208PB3 G OC=0.000190 3 +208PB G 763.45 2 1.80 2[M1+E2] -0.10 1 0.0354 5 +208PB2 G KC=0.0291 4$LC=0.00484 7$MC=0.001130 16$NC=0.000287 4 +208PB3 G OC=5.73E-5 8 +208PB L 3995.438 134- +208PB B 1003.6 170.007 3 8.5 1 +208PBS B EAV=329.7 7 +208PB G 1380.89 2 0.007 3[M1] 0.0078511 +208PB2 G KC=0.00643 9$LC=0.001050 15$MC=0.000245 4$NC=6.21E-5 9 +208PB3 G OC=1.240E-5 18$IPC=5.46E-5 8 +208PB L 4125.347 125- +208PB B 873.7 170.174 9 6.92 +208PBS B EAV=280.8 6 +208PB G 650.27 2 0.041 5[M1] 0.0541 8 +208PB2 G KC=0.0444 7$LC=0.00742 11$MC=0.001733 25$NC=0.000440 7 +208PB3 G OC=8.79E-5 13 +208PB G 927.64 2 0.128 7[M1] 0.0216 3 +208PB2 G KC=0.01774 25$LC=0.00293 5$MC=0.000684 10$NC=1.737E-4 25 +208PB3 G OC=3.47E-5 5 +208PB L 4180.414 145- +208PB B 818.6 170.231 9 6.7 +208PBS B EAV=260.4 6 +208PB G 705.34 2 0.022 4[M1] 0.0438 7 +208PB2 G KC=0.0360 5$LC=0.00599 9$MC=0.001399 20$NC=0.000356 5 +208PB3 G OC=7.09E-5 10 +208PB G 982.70 2 0.204 8[M1] 0.0186 3 +208PB2 G KC=0.01530 22$LC=0.00253 4$MC=0.000589 9$NC=1.495E-4 21 +208PB3 G OC=2.99E-5 5 +208PB L 4261.871 134- +208PB B 737.1 170.002 1 8.6 1 +208PBS B EAV=230.8 6 +208PB G 1647.32 2 0.002 1[M1] 0.00518 8 +208PB2 G KC=0.00411 6$LC=0.000669 10$MC=1.556E-4 22$NC=3.95E-5 6 +208PB3 G OC=7.90E-6 11$IPC=0.000194 3 +208PB L 4296.560 135- +208PB B 702.4 170.102 11 6.82 +208PBS B EAV=218.3 6 +208PB G 588.108 180.06 1[M1] 0.0704 10 +208PB2 G KC=0.0577 8$LC=0.00968 14$MC=0.00226 4$NC=0.000575 8 +208PB3 G OC=1.146E-4 16 +208PB G 821.48 2 0.041 4M1 0.0295 5 +208PB2 G KC=0.0242 4$LC=0.00402 6$MC=0.000939 14$NC=0.000238 4 +208PB3 G OC=4.76E-5 7 +208PB L 4323.946 144+ +208PB B 675.1 170.005 2 8.1 +208PBS B EAV=208.6 6 +208PB G 1126.24 2 0.005 2E1 0.00203 3 +208PB2 G KC=0.001691 24$LC=0.000256 4$MC=5.90E-5 9$NC=1.492E-5 21 +208PB3 G OC=2.96E-6 5$IPC=2.06E-6 3 +208PB L 4358.670 134- +208PB B 640.3 170.045 4 7.04 1 +208PBS B EAV=196.4 6 +208PB G 883.59 2 0.031 3[M1] 0.0244 4 +208PB2 G KC=0.0201 3$LC=0.00333 5$MC=0.000776 11$NC=0.000197 3 +208PB3 G OC=3.93E-5 6 +208PB G 1160.96 2 0.011 3[M1] 0.0121417 +208PB2 G KC=0.01000 14$LC=0.001641 23$MC=0.000382 6$NC=9.71E-5 14 +208PB3 G OC=1.94E-5 3$IPC=2.59E-6 4 +208PB G 1744.120 160.002 1M1+E2 0.00457 7 +208PB2 G KC=0.00356 5$LC=0.000578 8$MC=1.344E-4 19$NC=3.41E-5 5 +208PB3 G OC=6.82E-6 10$IPC=0.000255 4 +208PB L 4383.285 176- +208PB B 615.7 170.017 5 7.41 1 +208PBS B EAV=187.7 6 +208PB G 1185.57 2 0.017 5[M1] 0.0115117 +208PB2 G KC=0.00947 14$LC=0.001555 22$MC=0.000362 5$NC=9.20E-5 13 +208PB3 G OC=1.84E-5 3$IPC=5.01E-6 7 +208PB L 4480.746 166- +208PB B 518.3 170.052 5 6.67 1 +208PBS B EAV=154.3 6 +208PB G 1283.04 2 0.052 5[M1] 0.0094314 +208PB2 G KC=0.00775 11$LC=0.001269 18$MC=0.000295 5$NC=7.51E-5 11 +208PB3 G OC=1.499E-5 21$IPC=2.32E-5 4 + diff --git a/HEN_HOUSE/spectra/lnhb/Tl-209.txt b/HEN_HOUSE/spectra/lnhb/Tl-209.txt index 1bfcff467..cc589817f 100644 --- a/HEN_HOUSE/spectra/lnhb/Tl-209.txt +++ b/HEN_HOUSE/spectra/lnhb/Tl-209.txt @@ -1,102 +1,113 @@ -209PB 209TL B- DECAY (2.161 M) -209PB H TYP=Full$AUT=F.G. Kondev$CUT=30-MAY-2011$ -209PB C Evaluation history: Type=Full;Author=F.G. Kondev;Cutoff date=30-MAY-2011 -209PB C References: 1950Ha64, 1971Go40, 1977Vy02, 1980Da15, 1981Di14, 1986He06, -209PB2C 1989Ko26, 1991Ma16, 1993El08, 1996Sc06, 1998ScZM, 1998Ar03, 1999GrZT, -209PB3C 1999ScZX, 2000Sc47, 2000Gr35, 2003Au03, 2003De44, 2003ChZV, 2008Ki07, -209PB4C 2008DuZX -209PB T Auger electrons and X ray energies and emission intensities: -209PB T {U Energy (keV)} {U Intensity} {U Line} -209PB T -209PB T 72.8049 5.85 10 XKA2 -209PB T 74.97 9.84 16 XKA1 -209PB T -209PB T 84.451 |] XKB3 -209PB T 84.937 |] 3.36 8 XKB1 -209PB T 85.47 |] XKB5II -209PB T -209PB T 87.238 |] XKB2 -209PB T 87.58 |] 1.016 28 XKB4 -209PB T 87.911 |] XKO23 -209PB T -209PB T 9.186-15.2169 8.04 14 XL (total) -209PB T 9.186 0.196 6 XLL -209PB T 10.4495-10.5512 3.72 9 XLA -209PB T 11.3495 0.0637 18 XLC -209PB T 12.1443-13.3763 3.41 7 XLB -209PB T 14.3078-15.2169 0.648 14 XLG -209PB T -209PB T 56.028-61.669 |] KLL AUGER -209PB T 68.181-74.969 |] 0.77 9 KLX AUGER -209PB T 80.3-88 |] KXY AUGER -209PB T 5.34-15.82 13.23 15 L AUGER -209TL P 0.0 1/2+ 2.161 M 7 3976 8 -209PB N 1.0 1.0 1 1.0 -209PB G 469.7 3 0.12 3 -209PB G 860.5 3 0.26 4 -209PB G 890.0 4 0.12 3 -209PB G 902.8 4 0.10 2 -209PB G 970.3 0.054 15 -209PB G 1661.1 5 0.10 2 -209PB G 1673.2 4 0.48 4 -209PB G 1781.7 5 0.04 2 -209PB G 2005.3 2 0.020 5 -209PB G 2032.1 5 0.001 -209PB G 2548.2 0.015 6 -209PB L 0 9/2+ 3.277 H 15 -209PB L 1566.94 5 5/2+ -209PB G 1566.93 5 99.707 5E2 0.00294 5 -209PB2 G KC=0.00234 4$LC=3.96E-4 6$MC=9.26E-5 13 -209PB L 2032.07 6 1/2+ -209PB B 1944 8 0.1 8.3 -209PBS B EAV=709.0 34 -209PB G 465.128 2496.62 5E2 0.0350 5 -209PB2 G KC=0.0242 4$LC=0.00815 12$MC=0.00204 3 -209PB L 2149.29 6 1/2- -209PB B 1827 8 97.70 15 5.2 -209PBS B EAV=660.0 34 -209PB G 117.224 7 77.22 27E1 0.295 5 -209PB2 G KC=0.235 4$LC=0.0455 7$MC=0.01072 15 -209PB G 582.4 2 0.312 24[M2] 0.200 3 -209PB2 G KC=0.1574 22$LC=0.0322 5$MC=0.00774 11 -209PB G 2149 1 0.015 5[M4] 0.0152922 -209PB2 G KC=0.01218 18$LC=0.00237 4$MC=5.65E-4 8 -209PB L 2315.68 13(3/2)- -209PB B 1660 8 0.32 11 7.5 1 -209PBS B EAV=591.2 33 -209PB G 284.04 230.14 7[M1] 0.495 7 -209PB2 G KC=0.405 6$LC=0.0692 10$MC=0.01620 23 -209PB G 748.30 200.080 21[E1] 0.00428 6 -209PB2 G KC=0.00356 5$LC=5.53E-4 8$MC=1280E-7 18 -209PB G 2315.80 210.0288 21[E3] 0.00292 4 -209PB2 G KC=0.00216 3$LC=3.80E-4 6$MC=8.93E-5 13 -209PB L 2460.8 3 (5/2)- -209PB B 1515 8 0.031 16 9.2 1U -209PBS B EAV=518.1 31 -209PB G 311.50 300.028 14[E2] 0.1034 15 -209PB2 G KC=0.0596 9$LC=0.0329 5$MC=0.00842 13 -209PB L 2524.79 21(1/2,3/2)+ -209PB B 1451 8 0.070 15 8 -209PBS B EAV=505.9 33 -209PB G 375.50 200.070 15 -209PB L 2905.14 253/2- -209PB B 1071 8 0.70 9 6.5 1 -209PBS B EAV=355.5 31 -209PB G 755.60 300.11 2[M1] 0.0366 6 -209PB2 G KC=0.0301 5$LC=0.00500 7$MC=1168E-6 17 -209PB G 873.50 400.59 8[E1] 0.00320 5 -209PB2 G KC=0.00267 4$LC=4.10E-4 6$MC=9.47E-5 14 -209PB L 3069.72 133/2- -209PB B 906 8 0.645 16 6.3 1 -209PBS B EAV=292.9 30 -209PB G 920.43 110.631 15[M1] 0.0220 3 -209PB2 G KC=0.0181 3$LC=0.00299 5$MC=6.98E-4 10 -209PB L 3361.36 17(1/2,3/2)+ -209PB B 615 8 0.10 3 -209PBS B EAV=187.4 28 -209PB G 1329.29 160.10 3 -209PB L 3388.96 13(1/2,3/2)+ -209PB B 587 8 0.420 22 -209PBS B EAV=177.8 28 -209PB G 1239.66 110.420 22 - +209PB 209TL B- DECAY (2.161 M) +209PB H TYP=FUL$AUT=F.G.KONDEV$CUT=30-MAY-2011$ +209PB C References:1950Ha64, 1971Go40, 1977Vy02, 1980Da15, 1981Di14, 1986He06, +209PB2C 1989Ko26, 1991Ma16, 1993El08, 1996Sc06, 1998ScZM, 1998Ar03, 1999GrZT, +209PB3C 1999ScZX, 2000Sc47, 2000Gr35, 2003Au03, 2003De44, 2003ChZV, 2008Ki07, +209PB4C 2008DuZX +209PB T Auger electrons and X ray energies and emission intensities: +209PB T {U Energy (keV)} {U Intensity} {U Line} +209PB T +209PB T 72.8049 5.85 10 XKA2 +209PB T 74.97 9.84 16 XKA1 +209PB T +209PB T 84.451 |] XKB3 +209PB T 84.937 |] 3.36 8 XKB1 +209PB T 85.47 |] XKB5II +209PB T +209PB T 87.238 |] XKB2 +209PB T 87.58 |] 1.016 28 XKB4 +209PB T 87.911 |] XKO23 +209PB T +209PB T 9.186-15.2169 8.04 14 XL (total) +209PB T 9.186 0.196 6 XLL +209PB T 10.4495-10.5512 3.72 9 XLA +209PB T 11.3495 0.0637 18 XLC +209PB T 12.1443-13.3763 3.41 7 XLB +209PB T 14.3078-15.2169 0.648 14 XLG +209PB T +209PB T 56.028-61.669 |] KLL AUGER +209PB T 68.181-74.969 |] 0.77 9 KLX AUGER +209PB T 80.3-88 |] KXY AUGER +209PB T 5.34-15.82 13.23 15 L AUGER +209TL P 0.0 1/2+ 2.161 M 7 3976 8 +209PB N 1.0 1.0 1 1.0 +209PB G 469.7 3 0.12 3 +209PB G 860.5 3 0.26 4 +209PB G 890.0 4 0.12 3 +209PB G 902.8 4 0.10 2 +209PB G 970.3 0.054 15 +209PB G 1661.1 5 0.10 2 +209PB G 1673.2 4 0.48 4 +209PB G 1781.7 5 0.04 2 +209PB G 2005.3 2 0.020 5 +209PB G 2032.1 5 0.001 +209PB G 2548.2 0.015 6 +209PB L 0 9/2+ 3.277 H 15 +209PB L 1566.94 5 5/2+ +209PB G 1566.93 5 99.707 5E2 0.00294 5 +209PB2 G KC=0.00234 4$LC=0.000396 6$MC=9.26E-5 13$NC=2.35E-5 4 +209PB3 G OC=4.64E-6 7 +209PB L 2032.07 6 1/2+ +209PB B 1944 8 0.1 8.3 +209PBS B EAV=709.0 34 +209PB G 465.128 2496.62 5E2 0.0350 5 +209PB2 G KC=0.0242 4$LC=0.00815 12$MC=0.00204 3$NC=0.000515 8 +209PB3 G OC=9.70E-5 14 +209PB L 2149.29 6 1/2- +209PB B 1827 8 97.70 15 5.2 +209PBS B EAV=660.0 34 +209PB G 117.224 7 77.22 27E1 0.295 5 +209PB2 G KC=0.235 4$LC=0.0455 7$MC=0.01072 15$NC=0.00268 4 +209PB3 G OC=0.000507 7 +209PB G 582.4 2 0.312 24[M2] 0.200 3 +209PB2 G KC=0.1574 22$LC=0.0322 5$MC=0.00774 11$NC=0.00198 3 +209PB3 G OC=0.000392 6 +209PB G 2149 1 0.015 5[M4] 0.0152922 +209PB2 G KC=0.01218 18$LC=0.00237 4$MC=0.000565 8$NC=1.441E-4 21 +209PB3 G OC=2.86E-5 4 +209PB L 2315.68 13(3/2)- +209PB B 1660 8 0.32 11 7.5 1 +209PBS B EAV=591.2 33 +209PB G 284.04 230.14 7[M1] 0.495 7 +209PB2 G KC=0.405 6$LC=0.0692 10$MC=0.01620 23$NC=0.00412 6 +209PB3 G OC=0.000821 12 +209PB G 748.30 200.080 21[E1] 0.00428 6 +209PB2 G KC=0.00356 5$LC=0.000553 8$MC=1.280E-4 18$NC=3.24E-5 5 +209PB3 G OC=6.39E-6 9 +209PB G 2315.80 210.0288 21[E3] 0.00292 4 +209PB2 G KC=0.00216 3$LC=0.000380 6$MC=8.93E-5 13$NC=2.27E-5 4 +209PB3 G OC=4.49E-6 7 +209PB L 2460.8 3 (5/2)- +209PB B 1515 8 0.031 16 9.2 1U +209PBS B EAV=518.1 31 +209PB G 311.50 300.028 14[E2] 0.1034 15 +209PB2 G KC=0.0596 9$LC=0.0329 5$MC=0.00842 13$NC=0.00213 3 +209PB3 G OC=0.000392 6 +209PB L 2524.79 21(1/2,3/2)+ +209PB B 1451 8 0.070 15 8 +209PBS B EAV=505.9 33 +209PB G 375.50 200.070 15 +209PB L 2905.14 253/2- +209PB B 1071 8 0.70 9 6.5 1 +209PBS B EAV=355.5 31 +209PB G 755.60 300.11 2[M1] 0.0366 6 +209PB2 G KC=0.0301 5$LC=0.00500 7$MC=0.001168 17$NC=0.000297 5 +209PB3 G OC=5.92E-5 9 +209PB G 873.50 400.59 8[E1] 0.00320 5 +209PB2 G KC=0.00267 4$LC=0.000410 6$MC=9.47E-5 14$NC=2.40E-5 4 +209PB3 G OC=4.74E-6 7 +209PB L 3069.72 133/2- +209PB B 906 8 0.645 16 6.3 1 +209PBS B EAV=292.9 30 +209PB G 920.43 110.631 15[M1] 0.0220 3 +209PB2 G KC=0.0181 3$LC=0.00299 5$MC=0.000698 10$NC=1.772E-4 25 +209PB3 G OC=3.54E-5 5 +209PB L 3361.36 17(1/2,3/2)+ +209PB B 615 8 0.10 3 +209PBS B EAV=187.4 28 +209PB G 1329.29 160.10 3 +209PB L 3388.96 13(1/2,3/2)+ +209PB B 587 8 0.420 22 +209PBS B EAV=177.8 28 +209PB G 1239.66 110.420 22 + diff --git a/HEN_HOUSE/spectra/lnhb/Tl-210.txt b/HEN_HOUSE/spectra/lnhb/Tl-210.txt index c4b00f849..f8c8704ec 100644 --- a/HEN_HOUSE/spectra/lnhb/Tl-210.txt +++ b/HEN_HOUSE/spectra/lnhb/Tl-210.txt @@ -1,81 +1,83 @@ -210PB 210TL B- DECAY (1.30 M) -210PB H TYP=Full$AUT=V.Chisté$CUT=31-AUG-2007$ -210PB C Evaluation history: Type=Full;Author=V.Chisté;Cutoff date=31-AUG-2007 -210PB C References: 1931Cu01, 1957Ko42, 1961St20, 1964We06, 1981Ha54, 1996Sc06, -210PB2C 2002Ba85, 2003Au03, 2003Br13 -210PB T Auger electrons and X ray energies and emission intensities: -210PB T {U Energy (keV)} {U Intensity} {U Line} -210PB T -210PB T 72.805 7 4 XKA2 -210PB T 74.97 11 6 XKA1 -210PB T -210PB T 84.451 |] XKB3 -210PB T 84.937 |] 3.8 19 XKB1 -210PB T 85.47 |] XKB5II -210PB T -210PB T 87.238 |] XKB2 -210PB T 87.58 |] 1.1 6 XKB4 -210PB T 87.911 |] XKO23 -210PB T -210PB T 9.186 XLL -210PB T 10.449-10.551 XLA -210PB T 11.349 XLC -210PB T 12.144-13.376 XLB -210PB T 14.308-15.217 XLG -210TL P 0.0 (5)+ 1.30 M 3 5482 12 -210PB N 1.0 1.0 1 1.0 -210PB G 83 301.98 40[E2] 14 -210PB G 356 104 2[M1] 0.270 22 -210PB G 382 103 2[M1] 0.223 17 -210PB G 670 202 1 -210PB G 910 303 2 -210PB G 1490 202 1 -210PB G 1540 302 1 -210PB G 1650 302 1 -210PB G 2090 304.9 20 -210PB L 0 0+ 22.23 Y 12 -210PB L 799.6 3 2+ 17 PS 5 -210PB G 799.6 3 98.969 30E2 0.0104231 -210PB2 G KC=0.00811 24$LC=0.00176 5$MC=4.25E-4 13 -210PB L 1096 3 4+ 0.6 NS 1 -210PB B 4386 1213 7.3 -210PBS B EAV=1763 5 -210PB G 296 3 79 10E2 0.120 5 -210PB2 G KC=0.0671 19$LC=0.0399 17$MC=0.0103 5 -210PB L 1192 246+ 49 NS 6 -210PB B 4290 1231 6.9 -210PBS B EAV=1721 11 -210PB G 97 304 2M1+E2 1 9 -210PB2 G KC=4 $LC=3 $MC=0.8 -210PB L 1869 103- -210PB G 1070 2011.9 49[E1] 0.00222 7 -210PB2 G KC=0.00185 6$LC=2.81E-4 8$MC=6.5E-5 2 -210PB L 2208 13(2)+ -210PB G 1110 206.9 20 -210PB G 1410 204.9 20 -210PB L 2412 13 + -210PB G 1310 2020.8 49 -210PB L 3069 12(2)+ -210PB B 2413 1210 6.4 2U -210PBS B EAV=907 7 -210PB G 860 306.9 20 -210PB G 2280 123 2 -210PB L 3458 22(4)+ -210PB B 2024 1210 6.1 -210PBS B EAV=743 10 -210PB G 1590 302 1 -210PB G 2360 307.9 30 -210PB L 3622 21 + -210PB B 1860 1224 5.6 -210PBS B EAV=674 10 -210PB G 1210 2016.8 40 -210PB G 2430 308.9 30 -210PB L 3879 32 + -210PB B 1603 127 5.9 -210PBS B EAV=568 14 -210PB G 2010 306.9 20 -210PB L 4102 29 + -210PB B 1380 122 6.2 -210PBS B EAV=477 13 -210PB G 480 362 1 - +210PB 210TL B- DECAY (1.30 M) +210PB H TYP=FUL$AUT=V.CHISTE$CUT=31-AUG-2007$ +210PB C References:1931Cu01, 1957Ko42, 1961St20, 1964We06, 1981Ha54, 1996Sc06, +210PB2C 2002Ba85, 2003Au03, 2003Br13 +210PB T Auger electrons and X ray energies and emission intensities: +210PB T {U Energy (keV)} {U Intensity} {U Line} +210PB T +210PB T 72.805 7 4 XKA2 +210PB T 74.97 11 6 XKA1 +210PB T +210PB T 84.451 |] XKB3 +210PB T 84.937 |] 3.8 19 XKB1 +210PB T 85.47 |] XKB5II +210PB T +210PB T 87.238 |] XKB2 +210PB T 87.58 |] 1.1 6 XKB4 +210PB T 87.911 |] XKO23 +210PB T +210PB T 9.186 XLL +210PB T 10.449-10.551 XLA +210PB T 11.349 XLC +210PB T 12.144-13.376 XLB +210PB T 14.308-15.217 XLG +210TL P 0.0 (5)+ 1.30 M 3 5482 12 +210PB N 1.0 1.0 1 1.0 +210PB G 83 301.98 40[E2] 14 +210PB G 356 104 2[M1] 0.270 22 +210PB G 382 103 2[M1] 0.223 17 +210PB G 670 202 1 +210PB G 910 303 2 +210PB G 1490 202 1 +210PB G 1540 302 1 +210PB G 1650 302 1 +210PB G 2090 304.9 20 +210PB L 0 0+ 22.23 Y 12 +210PB L 799.6 3 2+ 17 PS 5 +210PB G 799.6 3 98.969 30E2 0.0104231 +210PB2 G KC=0.00811 24$LC=0.00176 5$MC=0.000425 13$NC=1.077E-4 32 +210PB3 G OC=0.000021 6 +210PB L 1096 3 4+ 0.6 NS 1 +210PB B 4386 1213 7.3 +210PBS B EAV=1763 5 +210PB G 296 3 79 10E2 0.120 5 +210PB2 G KC=0.0671 19$LC=0.0399 17$MC=0.0103 5$NC=0.00259 11 +210PB3 G OC=0.000476 20 +210PB L 1192 246+ 49 NS 6 +210PB B 4290 1231 6.9 +210PBS B EAV=1721 11 +210PB G 97 304 2M1+E2 1 9 +210PB2 G KC=4 $LC=3 $MC=0.8 +210PB L 1869 103- +210PB G 1070 2011.9 49[E1] 0.00222 7 +210PB2 G KC=0.00185 6$LC=0.000281 8$MC=0.000065 2$NC=1.64E-5 5 +210PB3 G OC=3.3E-6 1 +210PB L 2208 13(2)+ +210PB G 1110 206.9 20 +210PB G 1410 204.9 20 +210PB L 2412 13 +210PB G 1310 2020.8 49 +210PB L 3069 12(2)+ +210PB B 2413 1210 6.4 2U +210PBS B EAV=907 7 +210PB G 860 306.9 20 +210PB G 2280 123 2 +210PB L 3458 22(4)+ +210PB B 2024 1210 6.1 +210PBS B EAV=743 10 +210PB G 1590 302 1 +210PB G 2360 307.9 30 +210PB L 3622 21 +210PB B 1860 1224 5.6 +210PBS B EAV=674 10 +210PB G 1210 2016.8 40 +210PB G 2430 308.9 30 +210PB L 3879 32 +210PB B 1603 127 5.9 +210PBS B EAV=568 14 +210PB G 2010 306.9 20 +210PB L 4102 29 +210PB B 1380 122 6.2 +210PBS B EAV=477 13 +210PB G 480 362 1 + diff --git a/HEN_HOUSE/spectra/lnhb/Tm-170.txt b/HEN_HOUSE/spectra/lnhb/Tm-170.txt index 23b481bc0..52cd6d550 100644 --- a/HEN_HOUSE/spectra/lnhb/Tm-170.txt +++ b/HEN_HOUSE/spectra/lnhb/Tm-170.txt @@ -1,72 +1,72 @@ -170ER 170TM EC DECAY (127.8 D) -170ER C References: 1962Bo12, 1977La19 -170ER T Auger electrons and X ray energies and emission intensities: -170ER T {U Energy (keV)} {U Intensity} {U Line} -170ER T -170ER T 48.2212 0.332 16 XKA2 -170ER T 49.1276 0.0590 24 XKA1 -170ER T -170ER T 55.4797 |] XKB3 -170ER T 55.6737 |] 0.0191 10 XKB1 -170ER T 56.0322 |] XKB5II -170ER T 56.0762 |] XKB5I -170ER T -170ER T 57.142 |] XKB2 -170ER T 57.313 |] 0.0050 3 XKB4 -170ER T 57.456 |] XKO23 -170ER T -170ER T 6.15-9.43 0.0306 19 XL (total) -170ER T 6.15 XLL -170ER T -9.43 XLG -170ER T -170ER T 37.79-40.56 |] KLL AUGER -170ER T 45.47-49.1 |] 0.0072 6 KLX AUGER -170ER T 53.02-57.43 |] KXY AUGER -170TM P 0.0 1- 127.8 D 6 314.4 18 -170ER N 6.803E2 6.803E2 0.00147 6.803E2 -170ER L 0 0+ STABLE -170ER E 0.118 79.906 1 -170ER2 E CK=0.7838 19$CL=0.1645 13$CM=0.0401 8 -170ER L 78.59 2 2+ -170ER E 0.029 310.21 1 -170ER2 E CK=0.7595 22$CL=0.1822 15$CM=0.0451 9 -170ER G 78.59 2 0.0034 3E2 7.6 5 -170ER2 G KC=1.72 11$LC=4.51 30$MC=1.10 7 - -170YB 170TM B- DECAY (127.8 D) -170YB C References: 1962Bo12, 1977La19 -170YB T Auger electrons and X ray energies and emission intensities: -170YB T {U Energy (keV)} {U Intensity} {U Line} -170YB T -170YB T 51.3546 0.95 4 XKA2 -170YB T 52.3895 1.67 7 XKA1 -170YB T -170YB T 59.15 |] XKB3 -170YB T 59.37 |] 0.55 3 XKB1 -170YB T 59.782 |] XKB5II -170YB T -170YB T 60.98 |] XKB2 -170YB T 61.141 |] 0.144 7 XKB4 -170YB T 61.309 |] XKO23 -170YB T -170YB T 6.548-10.142 3.22 13 XL (total) -170YB T 6.548 0.0590 29 XLL -170YB T 7.369-7.416 1.42 7 XLA -170YB T 7.583 XLC -170YB T 8.026-8.756 1.50 7 XLB -170YB T 9.736-10.142 0.242 12 XLG -170YB T -170YB T 40.16-43.23 |] KLL AUGER -170YB T 48.36-52.36 |] 0.182 14 KLX AUGER -170YB T 56.48-61.29 |] KXY AUGER -170TM P 0.0 1- 127.8 D 6 968.0 8 -170YB N 1.001E0 1.001E0 0.999 1.001E0 -170YB L 0 0+ STABLE -170YB B 968.0 8 81.6 7 9.432 1 -170YBS B EAV=323.1 3 -170YB L 84.25477 8 2+ -170YB B 883.7 8 18.3 7 8.924 1 -170YBS B EAV=290.5 3 -170YB G 84.25474 8 2.48 9E2 6.39 10 -170YB2 G KC=1.39 2$LC=3.81 6$MC=0.94 1 - +170ER 170TM EC DECAY (127.8 D) +170ER C References:1962Bo12, 1977La19 +170ER T Auger electrons and X ray energies and emission intensities: +170ER T {U Energy (keV)} {U Intensity} {U Line} +170ER T +170ER T 48.2212 0.332 16 XKA2 +170ER T 49.1276 0.0590 24 XKA1 +170ER T +170ER T 55.4797 |] XKB3 +170ER T 55.6737 |] 0.0191 10 XKB1 +170ER T 56.0322 |] XKB5II +170ER T 56.0762 |] XKB5I +170ER T +170ER T 57.142 |] XKB2 +170ER T 57.313 |] 0.0050 3 XKB4 +170ER T 57.456 |] XKO23 +170ER T +170ER T 6.15-9.43 0.0306 19 XL (total) +170ER T 6.15 XLL +170ER T -9.43 XLG +170ER T +170ER T 37.79-40.56 |] KLL AUGER +170ER T 45.47-49.1 |] 0.0072 6 KLX AUGER +170ER T 53.02-57.43 |] KXY AUGER +170TM P 0.0 1- 127.8 D 6 314.4 18 +170ER N 6.803E2 6.803E2 0.00147 6.803E2 +170ER L 0 0+ STABLE +170ER E 0.118 79.906 1 +170ER2 E CK=0.7838 19$CL=0.1645 13$CM=0.0401 8 +170ER L 78.59 2 2+ +170ER E 0.029 310.21 1 +170ER2 E CK=0.7595 22$CL=0.1822 15$CM=0.0451 9 +170ER G 78.59 2 0.0034 3E2 7.6 5 +170ER2 G KC=1.72 11$LC=4.51 30$MC=1.10 7 + +170YB 170TM B- DECAY (127.8 D) +170YB C References:1962Bo12, 1977La19 +170YB T Auger electrons and X ray energies and emission intensities: +170YB T {U Energy (keV)} {U Intensity} {U Line} +170YB T +170YB T 51.3546 0.95 4 XKA2 +170YB T 52.3895 1.67 7 XKA1 +170YB T +170YB T 59.15 |] XKB3 +170YB T 59.37 |] 0.55 3 XKB1 +170YB T 59.782 |] XKB5II +170YB T +170YB T 60.98 |] XKB2 +170YB T 61.141 |] 0.144 7 XKB4 +170YB T 61.309 |] XKO23 +170YB T +170YB T 6.548-10.142 3.22 13 XL (total) +170YB T 6.548 0.0590 29 XLL +170YB T 7.369-7.416 1.42 7 XLA +170YB T 7.583 XLC +170YB T 8.026-8.756 1.50 7 XLB +170YB T 9.736-10.142 0.242 12 XLG +170YB T +170YB T 40.16-43.23 |] KLL AUGER +170YB T 48.36-52.36 |] 0.182 14 KLX AUGER +170YB T 56.48-61.29 |] KXY AUGER +170TM P 0.0 1- 127.8 D 6 968.0 8 +170YB N 1.001E0 1.001E0 0.999 1.001E0 +170YB L 0 0+ STABLE +170YB B 968.0 8 81.6 7 9.432 1 +170YBS B EAV=323.1 3 +170YB L 84.25477 8 2+ +170YB B 883.7 8 18.3 7 8.924 1 +170YBS B EAV=290.5 3 +170YB G 84.25474 8 2.48 9E2 6.39 10 +170YB2 G KC=1.39 2$LC=3.81 6$MC=0.94 1 + diff --git a/HEN_HOUSE/spectra/lnhb/U-232.txt b/HEN_HOUSE/spectra/lnhb/U-232.txt index 43b389ef8..aeaaaf954 100644 --- a/HEN_HOUSE/spectra/lnhb/U-232.txt +++ b/HEN_HOUSE/spectra/lnhb/U-232.txt @@ -1,82 +1,95 @@ -228TH 232U A DECAY (70.6 Y) -228TH H TYP=Full$AUT=A.Pearce$CUT=31-JAN-2008$ -228TH C Evaluation history: Type=Full;Author=A.Pearce;Cutoff date=31-JAN-2008 -228TH C References: 1949Go01, 1949Ja01, 1954Se26, 1955Go32, 1955As28, 1963Le17, -228TH2C 1964Ch05, 1965Be15, 1966Ah02, 1966Ba49, 1971He23, 1973Ta25, 1977Ku15, -228TH3C 1979Bo30, 1979He10, 1979Ag04, 1982Ma52, 1984Ge07, 1985Ba18, 1987Da28, -228TH4C 1990Bo16, 1995Ba42, 1996Sc06, 2000Bo46, 2000He14, 2003Wa32, 2003Au03 -228TH T Auger electrons and X ray energies and emission intensities: -228TH T {U Energy (keV)} {U Intensity} {U Line} -228TH T -228TH T 89.954 0.00524 11 XKA2 -228TH T 93.351 0.00847 16 XKA1 -228TH T -228TH T 104.819 |] XKB3 -228TH T 105.604 |] 0.00301 7 XKB1 -228TH T 106.239 |] XKB5II -228TH T -228TH T 108.509 |] XKB2 -228TH T 108.955 |] 0.00101629 XKB4 -228TH T 109.442 |] XKO23 -228TH T -228TH T 11.1177-19.5043 11.00 24 XL (total) -228TH T 11.1177 0.223 7 XLL -228TH T 12.8085-12.967 3.71 11 XLA -228TH T 14.509 0.129 5 XLC -228TH T 14.972-16.4253 5.61 16 XLB -228TH T 18.3633-19.5043 1.32 4 XLG -228TH T -228TH T 68.406-76.745 |] KLL AUGER -228TH T 83.857-93.345 |] 0.00057 8 KLX AUGER -228TH T 99.29-109.64 |] KXY AUGER -228TH T 5.8-20.3 11.62 22 L AUGER -232U P 0.0 0+ 70.6 Y 11 5413.63 9 -228TH N 1.0 1.0 1 1.0 -228TH L 0 0+ 1.9126 Y 9 -228TH A 5320.24 9 69.1 6 1 -228TH L 57.759 4 2+ 0.405 NS 7 -228TH A 5263.48 9 30.6 6 1.04 -228TH G 57.752 130.200 4E2 153.2 22 -228TH2 G KC=$LC=112.2 16$MC=30.7 5 -228TH L 186.823 4 4+ 0.164 NS 4 -228TH A 5136.64 9 0.325 6 16.4 -228TH G 129.065 3 0.0686 7E2 3.74 6 -228TH2 G KC=0.264 4$LC=2.54 4$MC=0.697 10 -228TH L 328.003 4 1- -228TH A 4997.90 9 0.00622 9 112 -228TH G 270.245 7 0.00317 7E1 0.0470 7 -228TH2 G KC=0.0376 6$LC=0.00716 10$MC=1717E-6 24 -228TH G 328.004 7 0.00283 7E1 0.0305 5 -228TH2 G KC=0.0245 4$LC=0.00455 7$MC=1089E-6 16 -228TH L 378.179 106+ -228TH A 4948.59 9 51000E-96 6490 -228TH G 191.351 110.000031 3E2 0.776 11 -228TH2 G KC=0.1710 24$LC=0.443 7$MC=0.1209 17 -228TH L 396.078 103- -228TH A 4931.00 9 48000E-94 5270 -228TH G 209.252 6 0.000011 3E1 0.0848 12 -228TH2 G KC=0.0672 10$LC=0.01333 19$MC=0.00321 5 -228TH G 338.320 5 3.70E-5 18E1 0.0285 4 -228TH2 G KC=0.0229 4$LC=0.00424 6$MC=1014E-6 15 -228TH L 519.192 6 5- -228TH A 4810.01 9 54000E-94 712 -228TH G 140.999 203.1E-6 13E1 0.217 3 -228TH2 G KC=0.1690 24$LC=0.0362 5$MC=0.00876 13 -228TH G 332.371 6 0.000049 3E1 0.0297 5 -228TH2 G KC=0.0238 4$LC=0.00441 7$MC=1056E-6 15 -228TH L 831.823 100+ -228TH A 4502.77 9 21400E-91610.6 -228TH G 503.819 231.45E-5 9E1 0.0124318 -228TH2 G KC=0.01009 15$LC=1775E-6 25$MC=4.22E-4 6 -228TH G 774.05 9 4.7E-6 8E2 0.0164923 -228TH2 G KC=0.01204 17$LC=0.00333 5$MC=8.35E-4 12 -228TH G 831.823 10 -228TH L 874.473 182+ -228TH A 4460.86 9 33000E-19 33 -228TH G 478.41 5 1.4E-6 6E1 0.0137920 -228TH2 G KC=1118E-5 2$LC=0.00198 3$MC=4.71E-4 7 -228TH G 546.454 211.0E-6 6E1 0.0105815 -228TH2 G KC=0.00861 12$LC=1500E-6 21$MC=3.57E-4 5 -228TH G 817 7 8E-7 3M1+E2 1 0.0359 5 -228TH2 G KC=0.0284 4$LC=0.00566 8$MC=1369E-6 20 - +228TH 232U A DECAY (70.6 Y) +228TH H TYP=FUL$AUT=A.PEARCE$CUT=31-JAN-2008$ +228TH C References:1949Go01, 1949Ja01, 1954Se26, 1955Go32, 1955As28, 1963Le17, +228TH2C 1964Ch05, 1965Be15, 1966Ah02, 1966Ba49, 1971He23, 1973Ta25, 1977Ku15, +228TH3C 1979Bo30, 1979He10, 1979Ag04, 1982Ma52, 1984Ge07, 1985Ba18, 1987Da28, +228TH4C 1990Bo16, 1995Ba42, 1996Sc06, 2000Bo46, 2000He14, 2003Wa32, 2003Au03 +228TH T Auger electrons and X ray energies and emission intensities: +228TH T {U Energy (keV)} {U Intensity} {U Line} +228TH T +228TH T 89.954 0.00524 11 XKA2 +228TH T 93.351 0.00847 16 XKA1 +228TH T +228TH T 104.819 |] XKB3 +228TH T 105.604 |] 0.00301 7 XKB1 +228TH T 106.239 |] XKB5II +228TH T +228TH T 108.509 |] XKB2 +228TH T 108.955 |] 0.00101629 XKB4 +228TH T 109.442 |] XKO23 +228TH T +228TH T 11.1177-19.5043 11.00 24 XL (total) +228TH T 11.1177 0.223 7 XLL +228TH T 12.8085-12.967 3.71 11 XLA +228TH T 14.509 0.129 5 XLC +228TH T 14.972-16.4253 5.61 16 XLB +228TH T 18.3633-19.5043 1.32 4 XLG +228TH T +228TH T 68.406-76.745 |] KLL AUGER +228TH T 83.857-93.345 |] 0.00057 8 KLX AUGER +228TH T 99.29-109.64 |] KXY AUGER +228TH T 5.8-20.3 11.62 22 L AUGER +232U P 0.0 0+ 70.6 Y 11 5413.63 9 +228TH N 1.0 1.0 1 +228TH L 0 0+ 1.9126 Y 9 +228TH A 5320.24 9 69.1 61 +228TH L 57.759 4 2+ 0.405 NS 7 +228TH A 5263.48 9 30.6 61.04 +228TH G 57.752 130.200 4E2 153.2 22 +228TH2 G LC=112.2 16$MC=30.7 5$NC=8.23E-5 12 +228TH3 G OC=1.83E-5 3 +228TH L 186.823 4 4+ 0.164 NS 4 +228TH A 5136.64 9 0.325 616.4 +228TH G 129.065 3 0.0686 7E2 3.74 6 +228TH2 G KC=0.264 4$LC=2.54 4$MC=0.697 10$NC=1.87E-6 3 +228TH3 G OC=4.17E-7 6 +228TH L 328.003 4 1- +228TH A 4997.90 9 0.00622 9112 +228TH G 270.245 7 0.00317 7E1 0.0470 7 +228TH2 G KC=0.0376 6$LC=0.00716 10$MC=0.001717 24$NC=4.54E-9 7 +228TH3 G OC=1.054E-9 15 +228TH G 328.004 7 0.00283 7E1 0.0305 5 +228TH2 G KC=0.0245 4$LC=0.00455 7$MC=0.001089 16$NC=2.88E-9 4 +228TH3 G OC=6.71E-5 10 +228TH L 378.179 106+ +228TH A 4948.59 9 0.000051 66490 +228TH G 191.351 110.000031 3E2 0.776 11 +228TH2 G KC=0.1710 24$LC=0.443 7$MC=0.1209 17$NC=3.24E-7 5 +228TH3 G OC=7.26E-8 11 +228TH L 396.078 103- +228TH A 4931.00 9 0.000048 45270 +228TH G 209.252 6 0.000011 3E1 0.0848 12 +228TH2 G KC=0.0672 10$LC=0.01333 19$MC=0.00321 5$NC=8.48E-9 12 +228TH3 G OC=1.96E-9 3 +228TH G 338.320 5 3.70E-5 18E1 0.0285 4 +228TH2 G KC=0.0229 4$LC=0.00424 6$MC=0.001014 15$NC=2.69E-9 4 +228TH3 G OC=6.25E-5 9 +228TH L 519.192 6 5- +228TH A 4810.01 9 0.000054 4712 +228TH G 140.999 203.1E-6 13E1 0.217 3 +228TH2 G KC=0.1690 24$LC=0.0362 5$MC=0.00876 13$NC=2.31E-8 4 +228TH3 G OC=5.29E-9 8 +228TH G 332.371 6 0.000049 3E1 0.0297 5 +228TH2 G KC=0.0238 4$LC=0.00441 7$MC=0.001056 15$NC=2.80E-9 4 +228TH3 G OC=651E-12 10 +228TH L 831.823 100+ +228TH A 4502.77 9 2.14E-5 1610.6 +228TH G 503.819 231.45E-5 9E1 0.0124318 +228TH2 G KC=0.01009 15$LC=0.001775 25$MC=0.000422 6$NC=1.119E-9 16 +228TH3 G OC=2.62E-5 4 +228TH G 774.05 9 4.7E-6 8E2 0.0164923 +228TH2 G KC=0.01204 17$LC=0.00333 5$MC=0.000835 12$NC=2.23E-9 4 +228TH3 G OC=5.17E-5 8 +228TH G 831.823 10 E0 +228TH L 874.473 182+ +228TH A 4460.86 9 3.3E-6 933 +228TH G 478.41 5 1.4E-6 6E1 0.0137920 +228TH2 G KC=0.011180 16$LC=0.00198 3$MC=0.000471 7$NC=1.249E-9 18 +228TH3 G OC=2.92E-5 5 +228TH G 546.454 211.0E-6 6E1 0.0105815 +228TH2 G KC=0.00861 12$LC=0.001500 21$MC=0.000357 5$NC=9.45E-5 14 +228TH3 G OC=2.22E-5 4 +228TH G 816.62 7 8E-7 3M1+E2 1 0.0359 5 +228TH2 G KC=0.0284 4$LC=0.00566 8$MC=0.001369 20$NC=3.65E-9 6 +228TH3 G OC=8.60E-5 12 + diff --git a/HEN_HOUSE/spectra/lnhb/U-234.txt b/HEN_HOUSE/spectra/lnhb/U-234.txt index 002a8ad14..278163226 100644 --- a/HEN_HOUSE/spectra/lnhb/U-234.txt +++ b/HEN_HOUSE/spectra/lnhb/U-234.txt @@ -1,65 +1,72 @@ -230TH 234U A DECAY (2.455E5 Y) -230TH H TYP=Full$AUT=V. Chisté$CUT=07-DEC-2005$ -230TH C Evaluation history: Type=Full;Author=V. Chisté;Cutoff date=07-DEC-2005 -230TH C References: 1939Ni03, 1930Cu02, 1946Ch02, 1949Hy03, 1949Ki26, 1949Go18, -230TH2C 1949Ba41, 1952Fl20, 1952Ki19, 1952Gh27, 1960Ba44, 1961At01, 1961ko11, -230TH3C 1963Bj03, 1965Ne03, 1965Wh05, 1966Ah02, 1970MeZN, 1972DeYN, 1972LoZL, -230TH4C 1972Sc01, 1973Ta25, 1974HeYW, 1980Ge13, 1980Me01, 1981Vo02, 1981HoZI, -230TH5C 1983Ak12, 1984Di08, 1984Va41, 1986LoZT, 1987Bo25, 1987Sh27, 1989Ho24, -230TH6C 1991Ry01, 1993Ak02, 1993Ak05, 1995Jo23, 1996Sc06, 2002Ba85, 2003Au03 -230TH T Auger electrons and X ray energies and emission intensities: -230TH T {U Energy (keV)} {U Intensity} {U Line} -230TH T -230TH T 89.954 0.00269 25 XKA2 -230TH T 93.351 0.0044 4 XKA1 -230TH T -230TH T 104.819 |] XKB3 -230TH T 105.604 |] 0.00155 15 XKB1 -230TH T 106.239 |] XKB5II -230TH T -230TH T 108.509 |] XKB2 -230TH T 108.955 |] 0.00052 5 XKB4 -230TH T 109.442 |] XKO23 -230TH T -230TH T 11.118-19.504 10.2 4 XL (total) -230TH T 11.118 0.209 12 XLL -230TH T 12.8085-12.967 3.48 17 XLA -230TH T 14.509 0.118 7 XLC -230TH T 14.972-16.4253 5.16 26 XLB -230TH T 18.3633-19.504 1.21 6 XLG -230TH T -230TH T 68.406-76.745 |] KLL AUGER -230TH T 83.857-93.345 |] 0.00029 5 KLX AUGER -230TH T 99.29-109.64 |] KXY AUGER -230TH T 5.8-20.3 10.8 4 L AUGER -234U P 0.0 0+ 2.455E5 Y 6 4857.7 7 -230TH N 1.0 1.0 1 1.0 -230TH L 0 0+ 75.38E3 Y 30 -230TH A 4774.6 7 71.37 2 1 -230TH L 53.20 2 2+ 0.354 NS 9 -230TH A 4722.4 7 28.42 2 1.1 -230TH G 53.20 2 0.1253 40E2+M3 228 7 -230TH2 G LC=167 5$MC=45.6 14 -230TH L 174.10 4 4+ 0.166 NS 5 -230TH A 4603.5 7 0.210 2 21 -230TH G 120.900 400.0386 32E2 4.92 15 -230TH2 G KC=0.244 7$LC=3.42 10$MC=0.940 28 -230TH L 508.16 4 1- -230TH A 4275.2 7 0.00004 1 288 -230TH G 454.96 5 0.000025 6E1 0.0152646 -230TH2 G KC=0.01235 37$LC=0.00220 7$MC=5.25E-4 16 -230TH G 508.16 5 1.50E-5 39E1 0.0122137 -230TH2 G KC=0.00991 30$LC=0.00174 5$MC=4.15E-4 12 -230TH L 634.90 7 0+ -230TH A 4150.6 7 26000E-9 39 -230TH G 581.7 1 0.000012 5E2 0.0300 9 -230TH2 G KC=0.0202 6$LC=0.00734 22$MC=0.00188 6 -230TH G 634.9 1 -230TH L 677.60 6 2+ -230TH A 4108.6 7 70000E-1 63 -230TH G 503.5 1 9.5E-7 [E2] 0.0418 13 -230TH2 G KC=0.0264 8$LC=0.01141 34$MC=0.00296 9 -230TH G 624.4 1 8.2E-7 +E2+M1 5.1 20 -230TH G 677.6 1 0.000001 [E2] 0.0216 6 -230TH2 G KC=0.01526 46$LC=0.00475 14$MC=1204E-6 36 - +230TH 234U A DECAY (2.455E5 Y) +230TH H TYP=FUL$AUT=V.CHISTE$CUT=07-DEC-2005$ +230TH C References:1939Ni03, 1930Cu02, 1946Ch02, 1949Hy03, 1949Ki26, 1949Go18, +230TH2C 1949Ba41, 1952Fl20, 1952Ki19, 1952Gh27, 1960Ba44, 1961At01, 1961ko11, +230TH3C 1963Bj03, 1965Ne03, 1965Wh05, 1966Ah02, 1969Ha**, 1970MeZN, 1972DeYN, +230TH4C 1972LoZL, 1972Sc01, 1973Ta25, 1974HeYW, 1980Ge13, 1980Me01, 1981Vo02, +230TH5C 1981HoZI, 1983Ak12, 1983Po**, 1984Di08, 1984Va41, 1985Po**, 1985Ax**, +230TH6C 1986LoZT, 1987Bo25, 1987Sh27, 1989Ho24, 1991Ry01, 1993Ak02, 1993Ak05, +230TH7C 1995Jo23, 1996Sc06, 2002Ba85, 2003Au03 +230TH T Auger electrons and X ray energies and emission intensities: +230TH T {U Energy (keV)} {U Intensity} {U Line} +230TH T +230TH T 89.954 0.00269 25 XKA2 +230TH T 93.351 0.0044 4 XKA1 +230TH T +230TH T 104.819 |] XKB3 +230TH T 105.604 |] 0.00155 15 XKB1 +230TH T 106.239 |] XKB5II +230TH T +230TH T 108.509 |] XKB2 +230TH T 108.955 |] 0.00052 5 XKB4 +230TH T 109.442 |] XKO23 +230TH T +230TH T 11.118-19.504 10.2 4 XL (total) +230TH T 11.118 0.209 12 XLL +230TH T 12.8085-12.967 3.48 17 XLA +230TH T 14.509 0.118 7 XLC +230TH T 14.972-16.4253 5.16 26 XLB +230TH T 18.3633-19.504 1.21 6 XLG +230TH T +230TH T 68.406-76.745 |] KLL AUGER +230TH T 83.857-93.345 |] 0.00029 5 KLX AUGER +230TH T 99.29-109.64 |] KXY AUGER +230TH T 5.8-20.3 10.8 4 L AUGER +234U P 0.0 0+ 2.455E5 Y 6 4857.7 7 +230TH N 1.0 1.0 1 +230TH L 0 0+ 75.38E3 Y 30 +230TH A 4774.6 7 71.37 21 +230TH L 53.20 2 2+ 0.354 NS 9 +230TH A 4722.4 7 28.42 21.1 +230TH G 53.20 2 0.1253 40E2+M3 228 7 +230TH2 G LC=167 5$MC=45.6 14$NC=12.22 37 +230TH3 G OC=2.72 8 +230TH L 174.10 4 4+ 0.166 NS 5 +230TH A 4603.5 7 0.210 221 +230TH G 120.900 400.0386 32E2 4.92 15 +230TH2 G KC=0.244 7$LC=3.42 10$MC=0.940 28$NC=0.252 8 +230TH3 G OC=0.0562 17 +230TH L 508.16 4 1- +230TH A 4275.2 7 0.00004 1288 +230TH G 454.96 5 0.000025 6E1 0.0152646 +230TH2 G KC=0.01235 37$LC=0.00220 7$MC=0.000525 16$NC=1.390E-4 42 +230TH3 G OC=3.25E-5 10 +230TH G 508.16 5 1.50E-5 39E1 0.0122137 +230TH2 G KC=0.00991 30$LC=0.00174 5$MC=0.000415 12$NC=1.099E-4 33 +230TH3 G OC=2.57E-5 8 +230TH L 634.90 7 0+ +230TH A 4150.6 7 0.000026 39 +230TH G 581.7 1 0.000012 5E2 0.0300 9 +230TH2 G KC=0.0202 6$LC=0.00734 22$MC=0.00188 6$NC=0.000503 15 +230TH3 G OC=1.158E-4 35 +230TH G 634.9 1 E0 +230TH L 677.60 6 2+ +230TH A 4108.6 7 0.000007 63 +230TH G 503.5 1 9.5E-7 [E2] 0.0418 13 +230TH2 G KC=0.0264 8$LC=0.01141 34$MC=0.00296 9$NC=0.000792 24 +230TH3 G OC=0.000181 5 +230TH G 624.4 1 8.2E-7 E0+E2+M1 5.1 20 +230TH G 677.6 1 0.000001 [E2] 0.0216 6 +230TH2 G KC=0.01526 46$LC=0.00475 14$MC=0.001204 36$NC=0.000322 10 +230TH3 G OC=7.43E-5 22 + diff --git a/HEN_HOUSE/spectra/lnhb/U-235.txt b/HEN_HOUSE/spectra/lnhb/U-235.txt index 775c322db..aa18bd8a9 100644 --- a/HEN_HOUSE/spectra/lnhb/U-235.txt +++ b/HEN_HOUSE/spectra/lnhb/U-235.txt @@ -1,189 +1,236 @@ -231TH 235U A DECAY (704E6 Y) -231TH H TYP=Update$AUT=M.M. Bé$CUT= -- $ -231TH2 H TYP=update$AUT=M.M. Bé$CUT= -- $ -231TH3 H TYP=Full$AUT=X. Huang$CUT=30-JUN-2008$ -231TH C Evaluation history: Type=Update;Author=M.M. Bé;Cutoff date= -- -231TH2C Type=update;Author=M.M. Bé;Cutoff date= -- -231TH3C Type=Full;Author=X. Huang;Cutoff date=30-JUN-2008 -231TH C References: 2008Ki07 -231TH T Auger electrons and X ray energies and emission intensities: -231TH T {U Energy (keV)} {U Intensity} {U Line} -231TH T -231TH T 89.954 3.56 7 XKA2 -231TH T 93.351 5.75 11 XKA1 -231TH T -231TH T 104.819 |] XKB3 -231TH T 105.604 |] 2.05 5 XKB1 -231TH T 106.239 |] XKB5II -231TH T -231TH T 108.509 |] XKB2 -231TH T 108.955 |] 0.690 19 XKB4 -231TH T 109.442 |] XKO23 -231TH T -231TH T 11.1177-19.5043 40 22 XL (total) -231TH T 11.1177 1.2 10 XLL -231TH T 12.8085-12.967 21 15 XLA -231TH T 14.509 0.243 24 XLC -231TH T 14.972-17.1383 15 4 XLB -231TH T 18.3633-19.5043 2.70 21 XLG -231TH T -231TH T 68.406-76.745 |] KLL AUGER -231TH T 83.857-93.345 |] 0.39 5 KLX AUGER -231TH T 99.29-109.64 |] KXY AUGER -231TH T 5.8-20.3 47 22 L AUGER -235U P 0.0 Null+ 704E6 Y 1 4678.3 7 -231TH N 1.0 1.0 1 1.0 -231TH L 0 5/2+ 25.52 H 1 -231TH A 4596.4 134.74 6 2571 -231TH L 41.954 4 7/2+ -231TH A 4556.0 4 3.79 6 1586 -231TH G 42.01 6 0.056 9M1+E2 1.2 1 440 30 -231TH2 G LC=325 22$MC=88 6 -231TH L 96.170 129/2+ -231TH A 4502.4 7 1.28 5 1856 -231TH G 54.25 5 0.0285 [M1+E2] 0.60 2 71 3 -231TH2 G LC=52.7 20$MC=14.0 6 -231TH G 96.09 2 0.091 11[E2] 13.58 19 -231TH2 G LC=9.93 14$MC=2.73 4 -231TH L 162.06 3 11/2+ -231TH A 4437.9 400.236 253170 -231TH G 120.35 5 0.026 [M1] 10.95 16 -231TH2 G KC=8.73 13$LC=1.678 24$MC=0.404 6 -231TH L 185.721 4 5/2- 0.77 NS 12 -231TH A 4414.9 5 3.01 16164 -231TH G 143.767 3 10.94 6E1 0.207 3 -231TH2 G KC=0.1615 23$LC=0.0344 5$MC=0.00833 12 -231TH G 185.720 4 57.0 3E1 0.1124 16 -231TH2 G KC=0.0887 13$LC=0.0179 3$MC=0.00433 6 -231TH L 205.313 4 7/2- -231TH A 4397.8 1357.19 206.08 -231TH G 19.592 6 0.006 6[M1+E2] 1E4 1 -231TH2 G LC=6E3 6$MC=3E3 3 -231TH G 109.19 7 1.66 13[E1] 0.0932 14 -231TH2 G LC=0.0704 10$MC=0.01708 24 -231TH G 163.356 3 5.08 3(E1) 0.1526 22 -231TH2 G KC=0.1197 17$LC=0.0248 4$MC=0.00599 9 -231TH G 205.316 4 5.02 3(E1) 0.0887 13 -231TH2 G KC=0.0703 10$LC=0.01397 20$MC=0.00336 5 -231TH L 221.386 143/2+ -231TH A 4381.1 7 0.106 162460 -231TH G 221.386 140.118 5M1 1.96 3 -231TH2 G KC=1.566 22$LC=0.296 5$MC=0.0712 10 -231TH L 236.902 7 9/2- -231TH A 4366.1 2018.80 1310.47 -231TH G 31.60 5 0.017 6M1+E2 0.5 666 11 -231TH2 G LC=490 8$MC=131.5 21 -231TH G 51.21 4 0.034 7[E2] 274 4 -231TH2 G LC=201 3$MC=54.9 8 -231TH G 74.94 3 0.051 6[E1] 0.252 4 -231TH2 G LC=0.190 3$MC=0.0464 7 -231TH G 140.76 2 0.20 1[E1] 0.218 3 -231TH2 G KC=0.1696 24$LC=0.0364 5$MC=0.00879 13 -231TH G 194.940 6 0.63 1[E1] 0.1002 14 -231TH2 G KC=0.0792 11$LC=0.01589 23$MC=0.00383 6 -231TH L 240.858 145/2+ -231TH A 4361.9 7 0.206 21890 -231TH G 198.894 140.036 2M1 2.64 4 -231TH2 G KC=2.11 3$LC=0.401 6$MC=0.0963 14 -231TH G 240.88 4 0.074 4M1(+E2) 0.3 3 1.45 22 -231TH2 G KC=1.14 21$LC=0.228 13$MC=0.0553 21 -231TH L 275.459 197/2+ -231TH A 4327.9 7 0.405 13241 -231TH G 54.1 1 0.00115 [E2] 210 4 -231TH2 G LC=154 3$MC=42.1 7 -231TH G 233.500 200.038 4M1 1.687 24 -231TH2 G KC=1.350 19$LC=0.255 4$MC=0.0613 9 -231TH G 275.49 6 0.032 M1(+E2) 0.25 25 1.02 12 -231TH2 G KC=0.81 11$LC=0.157 9$MC=0.0379 18 -231TH L 277.56 6 (11/2)- -231TH A 4322 4 3.33 6 28.1 -231TH G 41.4 3 0.029 11[M1] 49.9 13 -231TH2 G LC=37.7 10$MC=9.08 24 -231TH G 72.7 2 0.116 20M1+E2 0.4 1 15 3 -231TH2 G LC=11.4 19$MC=2.9 6 -231TH G 115.45 5 0.03 1[E1] 0.348 5 -231TH2 G KC=0.267 4$LC=0.0609 9$MC=0.01475 21 -231TH G 182.1 -231TH L 301.7 1 (5/2)+ -231TH A 4302.1 7 0.00959 136260 -231TH G 301.7 1 0.0053 M1 0.829 12 -231TH2 G KC=0.664 10$LC=0.1249 18$MC=0.0300 5 -231TH L 317.15 7 5/2+ -231TH A 4286.9 7 0.065 13690 -231TH G 95.7 -231TH G 275.35 150.051 6M1+E2 0.6 1 0.84 6 -231TH2 G KC=0.65 5$LC=0.144 5$MC=0.0355 10 -231TH G 317.10 8 0.0011 M1 0.723 11 -231TH2 G KC=0.579 9$LC=0.1088 16$MC=0.0261 4 -231TH L 324.91 4 (9/2)+ -231TH A 4279.3 7 0.0329 5 1185 -231TH G 228.76 5 0.0074 M1 1.79 3 -231TH2 G KC=1.429 20$LC=0.270 4$MC=0.0649 9 -231TH G 282.94 5 0.0063 [M1] 0.990 14 -231TH2 G KC=0.792 12$LC=0.1493 21$MC=0.0359 5 -231TH L 334 4 (13/2)- -231TH A 4266 5 0.22 3 150 -231TH G 97 4 0.016 4[E2] 13 3 -231TH2 G LC=9.5 21$MC=2.6 6 -231TH L 351.565 167/2+ -231TH A 4248 5 0.069 10343 -231TH G 255.365 100.0074 M1 1.315 19 -231TH2 G KC=1.052 15$LC=0.199 3$MC=0.0477 7 -231TH G 310.69 6 0.0094 (E2) 0.1517 22 -231TH2 G KC=0.068 1$LC=0.0616 9$MC=0.01650 24 -231TH G 350 5 0.006 M1 0.552 24 -231TH2 G KC=0.442 19$LC=0.083 4$MC=0.0199 9 -231TH L 377.50 4 (7/2)+ -231TH A 4227.6 7 0.122 6 119 -231TH G 136.55 5 0.012 [M1] 7.66 11 -231TH2 G KC=6.11 9$LC=1.168 17$MC=0.281 4 -231TH G 173 1 0.006 5[E1] 0.133 3 -231TH2 G KC=0.1047 21$LC=0.0215 5$MC=0.00518 11 -231TH G 281.42 5 0.0063 M1 1.005 14 -231TH2 G KC=0.804 12$LC=0.1515 22$MC=0.0364 5 -231TH L 385.72 4 (11/2)+ -231TH A 4219.5 7 0.01732 12714 -231TH G 289.56 4 0.0074 [M1] 0.929 13 -231TH2 G KC=0.743 11$LC=0.140 2$MC=0.0336 5 -231TH G 343.5 2 0.0032 -231TH L 387.841 8 7/2- -231TH A 4214.7 195.95 122 -231TH G 147 -231TH G 150.936 150.09 3[M1] 5.76 8 -231TH2 G KC=4.60 7$LC=0.877 13$MC=0.211 3 -231TH G 182.62 5 0.39 5[M1] 3.36 5 -231TH2 G KC=2.69 4$LC=0.510 8$MC=0.1226 18 -231TH G 202.12 1 1.08 2[M1] 2.53 4 -231TH2 G KC=2.02 3$LC=0.383 6$MC=0.0920 13 -231TH G 291.65 3 0.040 6[E1] 0.0396 6 -231TH2 G KC=0.0317 5$LC=0.00598 9$MC=1433E-6 20 -231TH G 345.92 3 0.040 6[E1] 0.0272 4 -231TH2 G KC=0.0219 3$LC=0.00403 6$MC=9.64E-4 14 -231TH G 387.84 3 0.040 6[E1] 0.0213 3 -231TH2 G KC=0.01717 24$LC=0.00312 5$MC=7.45E-4 11 -231TH L 452.182 159/2- -231TH A 4152 5 0.294 1311.6 -231TH G 64.45 5 0.018 [M1] 13.6 2 -231TH2 G LC=10.28 15$MC=2.47 4 -231TH G 215.28 4 0.029 3[M1] 2.12 3 -231TH2 G KC=1.693 24$LC=0.321 5$MC=0.0770 11 -231TH G 246.830 200.055 3[M1] 1.445 21 -231TH2 G KC=1.157 17$LC=0.218 3$MC=0.0525 8 -231TH G 266.47 4 0.0078 6[E2] 0.245 4 -231TH2 G KC=0.0921 13$LC=0.1121 16$MC=0.0303 5 -231TH G 291.2 -231TH G 356.03 5 0.0053 [E1] 0.0255 4 -231TH2 G KC=0.0206 3$LC=0.00377 6$MC=9.03E-4 13 -231TH G 410.29 4 0.0032 [E1] 0.0189 3 -231TH2 G KC=0.01527 22$LC=0.00275 4$MC=6.57E-4 10 -231TH L 530.24 5 (11/2)- -231TH A 4077.5 7 0.016 1246 -231TH G 142.40 5 0.0051 [E2] 2.48 4 -231TH2 G KC=0.253 4$LC=1.627 23$MC=0.446 7 -231TH L 595.58 205/2- -231TH A 4013.2 8 0.0396 104.86 -231TH G 390.27 200.040 1 -231TH L 634.12 6 7/2- -231TH A 3976 5 0.0011 79 -231TH G 448.40 6 0.0011 - +231TH 235U A DECAY (704E6 Y) +231TH H TYP=UPD$AUT=M.-M.BE$CUT=05-FEB-2014$ +231TH2 H TYP=UPD$AUT=M.-M.BE$CUT=29-JAN-2013$ +231TH3 H TYP=FUL$AUT=X.HUANG$CUT=30-JUN-2008$ +231TH C References:2008Ki07 +231TH T Auger electrons and X ray energies and emission intensities: +231TH T {U Energy (keV)} {U Intensity} {U Line} +231TH T +231TH T 89.954 3.56 7 XKA2 +231TH T 93.351 5.75 11 XKA1 +231TH T +231TH T 104.819 |] XKB3 +231TH T 105.604 |] 2.05 5 XKB1 +231TH T 106.239 |] XKB5II +231TH T +231TH T 108.509 |] XKB2 +231TH T 108.955 |] 0.690 19 XKB4 +231TH T 109.442 |] XKO23 +231TH T +231TH T 11.1177-19.5043 40 22 XL (total) +231TH T 11.1177 1.2 10 XLL +231TH T 12.8085-12.967 21 15 XLA +231TH T 14.509 0.243 24 XLC +231TH T 14.972-17.1383 15 4 XLB +231TH T 18.3633-19.5043 2.70 21 XLG +231TH T +231TH T 68.406-76.745 |] KLL AUGER +231TH T 83.857-93.345 |] 0.39 5 KLX AUGER +231TH T 99.29-109.64 |] KXY AUGER +231TH T 5.8-20.3 47 22 L AUGER +235U P 0.0 7/2- 704E6 Y 1 4678.3 7 +231TH N 1.0 1.0 1 +231TH L 0 5/2+ 25.52 H 1 +231TH A 4596.4 134.74 62571 +231TH L 41.954 4 7/2+ +231TH A 4556.0 4 3.79 61586 +231TH G 42.01 6 0.056 9M1+E2 1.2 1 440 30 +231TH2 G LC=325 22$MC=88 6$NC=23.6 16 +231TH3 G OC=5.3 4 +231TH L 96.170 129/2+ +231TH A 4502.4 7 1.28 51856 +231TH G 54.25 5 0.0285 [M1+E2] 0.60 2 71 3 +231TH2 G LC=52.7 20$MC=14.0 6$NC=3.75 15 +231TH3 G OC=0.85 4 +231TH G 96.09 2 0.091 11[E2] 13.58 19 +231TH2 G LC=9.93 14$MC=2.73 4$NC=0.731 11 +231TH3 G OC=0.1629 23 +231TH L 162.06 3 11/2+ +231TH A 4437.9 400.236 253170 +231TH G 120.35 5 0.026 [M1] 10.95 16 +231TH2 G KC=8.73 13$LC=1.678 24$MC=0.404 6$NC=0.1077 16 +231TH3 G OC=0.0255 4 +231TH L 185.721 4 5/2- 0.77 NS 12 +231TH A 4414.9 5 3.01 16164 +231TH G 143.767 3 10.94 6E1 0.207 3 +231TH2 G KC=0.1615 23$LC=0.0344 5$MC=0.00833 12$NC=0.00220 3 +231TH3 G OC=0.000503 7 +231TH G 185.720 4 57.0 3E1 0.1124 16 +231TH2 G KC=0.0887 13$LC=0.0179 3$MC=0.00433 6$NC=0.001142 16 +231TH3 G OC=0.000263 4 +231TH L 205.313 4 7/2- +231TH A 4397.8 1357.19 206.08 +231TH G 19.592 6 0.006 6[M1+E2] 1E4 1 +231TH2 G LC=6E3 6$MC=3E3 3$NC=8E2 8 +231TH3 G OC=1.8E2 18 +231TH G 109.19 7 1.66 13[E1] 0.0932 14 +231TH2 G LC=0.0704 10$MC=0.01708 24$NC=0.00449 7 +231TH3 G OC=0.001023 15 +231TH G 163.356 3 5.08 3(E1) 0.1526 22 +231TH2 G KC=0.1197 17$LC=0.0248 4$MC=0.00599 9$NC=0.001581 23 +231TH3 G OC=0.000364 5 +231TH G 205.316 4 5.02 3(E1) 0.0887 13 +231TH2 G KC=0.0703 10$LC=0.01397 20$MC=0.00336 5$NC=0.000889 13 +231TH3 G OC=0.000205 3 +231TH L 221.386 143/2+ +231TH A 4381.1 7 0.106 162460 +231TH G 221.386 140.118 5M1 1.96 3 +231TH2 G KC=1.566 22$LC=0.296 5$MC=0.0712 10$NC=0.0190 3 +231TH3 G OC=0.00450 7 +231TH L 236.902 7 9/2- +231TH A 4366.1 2018.80 1310.47 +231TH G 31.60 5 0.017 6M1+E2 0.5 666 11 +231TH2 G LC=490 8$MC=131.5 21$NC=35.1 6 +231TH3 G OC=7.86 13 +231TH G 51.21 4 0.034 7[E2] 274 4 +231TH2 G LC=201 3$MC=54.9 8$NC=14.70 22 +231TH3 G OC=3.27 5 +231TH G 74.94 3 0.051 6[E1] 0.252 4 +231TH2 G LC=0.190 3$MC=0.0464 7$NC=0.01216 17 +231TH3 G OC=0.00274 4 +231TH G 140.76 2 0.20 1[E1] 0.218 3 +231TH2 G KC=0.1696 24$LC=0.0364 5$MC=0.00879 13$NC=0.00232 4 +231TH3 G OC=0.000531 8 +231TH G 194.940 6 0.63 1[E1] 0.1002 14 +231TH2 G KC=0.0792 11$LC=0.01589 23$MC=0.00383 6$NC=0.001011 15 +231TH3 G OC=0.000233 4 +231TH L 240.858 145/2+ +231TH A 4361.9 7 0.206 21890 +231TH G 198.894 140.036 2M1 2.64 4 +231TH2 G KC=2.11 3$LC=0.401 6$MC=0.0963 14$NC=0.0257 4 +231TH3 G OC=0.00608 9 +231TH G 240.88 4 0.074 4M1(+E2) 0.3 3 1.45 22 +231TH2 G KC=1.14 21$LC=0.228 13$MC=0.0553 21$NC=0.0148 6 +231TH3 G OC=0.00348 16 +231TH L 275.459 197/2+ +231TH A 4327.9 7 0.405 13241 +231TH G 54.1 1 0.00115 [E2] 210 4 +231TH2 G LC=154 3$MC=42.1 7$NC=11.27 19 +231TH3 G OC=2.51 5 +231TH G 233.500 200.038 4M1 1.687 24 +231TH2 G KC=1.350 19$LC=0.255 4$MC=0.0613 9$NC=0.01635 23 +231TH3 G OC=0.00387 6 +231TH G 275.49 6 0.032 M1(+E2) 0.25 25 1.02 12 +231TH2 G KC=0.81 11$LC=0.157 9$MC=0.0379 18$NC=0.0101 5 +231TH3 G OC=0.00239 13 +231TH L 277.56 6 (11/2)- +231TH A 4322 4 3.33 628.1 +231TH G 41.4 3 0.029 11[M1] 49.9 13 +231TH2 G LC=37.7 10$MC=9.08 24$NC=2.42 7 +231TH3 G OC=0.574 15 +231TH G 72.7 2 0.116 20M1+E2 0.4 1 15 3 +231TH2 G LC=11.4 19$MC=2.9 6$NC=0.78 15 +231TH3 G OC=0.18 4 +231TH G 115.45 5 0.03 1[E1] 0.348 5 +231TH2 G KC=0.267 4$LC=0.0609 9$MC=0.01475 21$NC=0.00388 6 +231TH3 G OC=0.000885 13 +231TH G 182.1 +231TH L 301.7 1 (5/2)+ +231TH A 4302.1 7 0.00959 136260 +231TH G 301.7 1 0.0053 M1 0.829 12 +231TH2 G KC=0.664 10$LC=0.1249 18$MC=0.0300 5$NC=0.00800 12 +231TH3 G OC=0.00189 3 +231TH L 317.15 7 5/2+ +231TH A 4286.9 7 0.065 13690 +231TH G 95.7 +231TH G 275.35 150.051 6M1+E2 0.6 1 0.84 6 +231TH2 G KC=0.65 5$LC=0.144 5$MC=0.0355 10$NC=0.00946 25 +231TH3 G OC=0.00222 7 +231TH G 317.10 8 0.0011 M1 0.723 11 +231TH2 G KC=0.579 9$LC=0.1088 16$MC=0.0261 4$NC=0.00697 10 +231TH3 G OC=0.001650 24 +231TH L 324.91 4 (9/2)+ +231TH A 4279.3 7 0.0329 51185 +231TH G 228.76 5 0.0074 M1 1.79 3 +231TH2 G KC=1.429 20$LC=0.270 4$MC=0.0649 9$NC=0.01732 25 +231TH3 G OC=0.00410 6 +231TH G 282.94 5 0.0063 [M1] 0.990 14 +231TH2 G KC=0.792 12$LC=0.1493 21$MC=0.0359 5$NC=0.00956 14 +231TH3 G OC=0.00226 4 +231TH L 334 4 (13/2)- +231TH A 4266 5 0.22 3150 +231TH G 97 4 0.016 4[E2] 13 3 +231TH2 G LC=9.5 21$MC=2.6 6$NC=0.70 16 +231TH3 G OC=0.16 4 +231TH L 351.565 167/2+ +231TH A 4248 5 0.069 10343 +231TH G 255.365 100.0074 M1 1.315 19 +231TH2 G KC=1.052 15$LC=0.199 3$MC=0.0477 7$NC=0.01273 18 +231TH3 G OC=0.00301 5 +231TH G 310.69 6 0.0094 (E2) 0.1517 22 +231TH2 G KC=0.068 1$LC=0.0616 9$MC=0.01650 24$NC=0.00442 7 +231TH3 G OC=0.000999 14 +231TH G 350 5 0.006 M1 0.552 24 +231TH2 G KC=0.442 19$LC=0.083 4$MC=0.0199 9$NC=0.00531 23 +231TH3 G OC=0.00126 6 +231TH L 377.50 4 (7/2)+ +231TH A 4227.6 7 0.122 6119 +231TH G 136.55 5 0.012 [M1] 7.66 11 +231TH2 G KC=6.11 9$LC=1.168 17$MC=0.281 4$NC=0.0749 11 +231TH3 G OC=0.01774 25 +231TH G 173 1 0.006 5[E1] 0.133 3 +231TH2 G KC=0.1047 21$LC=0.0215 5$MC=0.00518 11$NC=0.00137 3 +231TH3 G OC=0.000315 7 +231TH G 281.42 5 0.0063 M1 1.005 14 +231TH2 G KC=0.804 12$LC=0.1515 22$MC=0.0364 5$NC=0.00971 14 +231TH3 G OC=0.00230 4 +231TH L 385.72 4 (11/2)+ +231TH A 4219.5 7 0.01732 12714 +231TH G 289.56 4 0.0074 [M1] 0.929 13 +231TH2 G KC=0.743 11$LC=0.140 2$MC=0.0336 5$NC=0.00897 13 +231TH3 G OC=0.00212 3 +231TH G 343.5 2 0.0032 +231TH L 387.841 8 7/2- +231TH A 4214.7 195.95 122 +231TH G 147 +231TH G 150.936 150.09 3[M1] 5.76 8 +231TH2 G KC=4.60 7$LC=0.877 13$MC=0.211 3$NC=0.0563 8 +231TH3 G OC=0.01332 19 +231TH G 182.62 5 0.39 5[M1] 3.36 5 +231TH2 G KC=2.69 4$LC=0.510 8$MC=0.1226 18$NC=0.0327 5 +231TH3 G OC=0.00774 11 +231TH G 202.12 1 1.08 2[M1] 2.53 4 +231TH2 G KC=2.02 3$LC=0.383 6$MC=0.0920 13$NC=0.0245 4 +231TH3 G OC=0.00581 9 +231TH G 291.65 3 0.040 6[E1] 0.0396 6 +231TH2 G KC=0.0317 5$LC=0.00598 9$MC=0.001433 20$NC=0.000379 6 +231TH3 G OC=8.81E-5 13 +231TH G 345.92 3 0.040 6[E1] 0.0272 4 +231TH2 G KC=0.0219 3$LC=0.00403 6$MC=0.000964 14$NC=0.000255 4 +231TH3 G OC=5.95E-5 9 +231TH G 387.84 3 0.040 6[E1] 0.0213 3 +231TH2 G KC=0.01717 24$LC=0.00312 5$MC=0.000745 11$NC=0.000197 3 +231TH3 G OC=4.60E-5 7 +231TH L 452.182 159/2- +231TH A 4152 5 0.294 1311.6 +231TH G 64.45 5 0.018 [M1] 13.6 2 +231TH2 G LC=10.28 15$MC=2.47 4$NC=0.66 1 +231TH3 G OC=0.1564 23 +231TH G 215.28 4 0.029 3[M1] 2.12 3 +231TH2 G KC=1.693 24$LC=0.321 5$MC=0.0770 11$NC=0.0205 3 +231TH3 G OC=0.00487 7 +231TH G 246.830 200.055 3[M1] 1.445 21 +231TH2 G KC=1.157 17$LC=0.218 3$MC=0.0525 8$NC=0.0140 2 +231TH3 G OC=0.00331 5 +231TH G 266.47 4 0.0078 6[E2] 0.245 4 +231TH2 G KC=0.0921 13$LC=0.1121 16$MC=0.0303 5$NC=0.00810 12 +231TH3 G OC=0.00183 3 +231TH G 291.2 +231TH G 356.03 5 0.0053 [E1] 0.0255 4 +231TH2 G KC=0.0206 3$LC=0.00377 6$MC=0.000903 13$NC=0.000239 4 +231TH3 G OC=5.57E-5 8 +231TH G 410.29 4 0.0032 [E1] 0.0189 3 +231TH2 G KC=0.01527 22$LC=0.00275 4$MC=0.000657 10$NC=1.741E-4 25 +231TH3 G OC=4.07E-5 6 +231TH L 530.24 5 (11/2)- +231TH A 4077.5 7 0.016 1246 +231TH G 142.40 5 0.0051 [E2] 2.48 4 +231TH2 G KC=0.253 4$LC=1.627 23$MC=0.446 7$NC=0.1196 17 +231TH3 G OC=0.0267 4 +231TH L 595.58 205/2- +231TH A 4013.2 8 0.0396 104.86 +231TH G 390.27 200.040 1 +231TH L 634.12 6 7/2- +231TH A 3976 5 0.0011 79 +231TH G 448.40 6 0.0011 + diff --git a/HEN_HOUSE/spectra/lnhb/U-236.txt b/HEN_HOUSE/spectra/lnhb/U-236.txt index b9d28d35a..f13693caf 100644 --- a/HEN_HOUSE/spectra/lnhb/U-236.txt +++ b/HEN_HOUSE/spectra/lnhb/U-236.txt @@ -1,48 +1,50 @@ -232TH 236U A DECAY (23.43E6 Y) -232TH H TYP=Full$AUT=A.Luca$CUT=28-FEB-2008$ -232TH C Evaluation history: Type=Full;Author=A.Luca;Cutoff date=28-FEB-2008 -232TH C References: 1951JA09, 1952FL20, 1960KO04, 1971CO35, 1972FL03, 1972Sc01, -232TH2C 1981VO02, 1983BE66, 1988WoZO, 1989Ho24, 1992IT01, 1994Tr12, 2002GE02, -232TH3C 2003AU03, 2006BR19 -232TH T Auger electrons and X ray energies and emission intensities: -232TH T {U Energy (keV)} {U Intensity} {U Line} -232TH T -232TH T 89.954 0.00128 22 XKA2 -232TH T 93.351 0.0021 4 XKA1 -232TH T -232TH T 104.819 |] XKB3 -232TH T 105.604 |] 0.00074 13 XKB1 -232TH T 106.239 |] XKB5II -232TH T -232TH T 108.509 |] XKB2 -232TH T 108.955 |] 0.00025 5 XKB4 -232TH T 109.442 |] XKO23 -232TH T -232TH T 11.118-19.599 9.4 10 XL (total) -232TH T 11.118 0.194 26 XLL -232TH T 12.809-12.968 3.2 4 XLA -232TH T 14.511 0.108 17 XLC -232TH T 14.97-16.426 4.7 6 XLB -232TH T 18.98-19.599 1.11 14 XLG -232TH T -232TH T 68.406-76.745 |] KLL AUGER -232TH T 83.857-93.345 |] 0.00013930 KLX AUGER -232TH T 99.29-109.64 |] KXY AUGER -232TH T 5.8-20.3 10.1 12 L AUGER -236U P 0.0 0+ 23.43E6 Y 6 4573.1 9 -232TH N 1.0 1.0 1 1.0 -232TH L 0 0+ 14.02E9 Y 6 -232TH A 4494 3 73.8 401 -232TH L 49.46 102+ 345 PS 15 -232TH A 4445 5 26.1 401.2 -232TH G 49.46 100.081 12E2 324 10 -232TH2 G LC=237 7$MC=65.0 19 -232TH L 162.25 154+ 164 PS 13 -232TH A 4332 8 0.149 2227.3 -232TH G 112.79 100.0195 31E2 6.67 20 -232TH2 G KC=0.229 7$LC=4.71 14$MC=1.295 39 -232TH L 333.40 256+ 62 PS 4 -232TH A 4168 0.00014 5 1160 -232TH G 171.15 200.00006522E2 1.186 36 -232TH2 G KC=0.204 6$LC=0.719 22$MC=0.197 6 - +232TH 236U A DECAY (23.43E6 Y) +232TH H TYP=FUL$AUT=A.LUCA$CUT=28-FEB-2008$ +232TH C References:1951JA09, 1952FL20, 1960KO04, 1971CO35, 1972FL03, 1972Sc01, +232TH2C 1981VO02, 1983BE66, 1988WoZO, 1989Ho24, 1992IT01, 1994Tr12, 2002GE02, +232TH3C 2003Au03, 2006BR19 +232TH T Auger electrons and X ray energies and emission intensities: +232TH T {U Energy (keV)} {U Intensity} {U Line} +232TH T +232TH T 89.954 0.00128 22 XKA2 +232TH T 93.351 0.0021 4 XKA1 +232TH T +232TH T 104.819 |] XKB3 +232TH T 105.604 |] 0.00074 13 XKB1 +232TH T 106.239 |] XKB5II +232TH T +232TH T 108.509 |] XKB2 +232TH T 108.955 |] 0.00025 5 XKB4 +232TH T 109.442 |] XKO23 +232TH T +232TH T 11.118-19.599 9.4 10 XL (total) +232TH T 11.118 0.194 26 XLL +232TH T 12.809-12.968 3.2 4 XLA +232TH T 14.511 0.108 17 XLC +232TH T 14.97-16.426 4.7 6 XLB +232TH T 18.98-19.599 1.11 14 XLG +232TH T +232TH T 68.406-76.745 |] KLL AUGER +232TH T 83.857-93.345 |] 0.00013930 KLX AUGER +232TH T 99.29-109.64 |] KXY AUGER +232TH T 5.8-20.3 10.1 12 L AUGER +236U P 0.0 0+ 23.43E6 Y 6 4573.1 9 +232TH N 1.0 1.0 1 +232TH L 0 0+ 14.02E9 Y 6 +232TH A 4494 3 73.8 401 +232TH L 49.46 102+ 345 PS 15 +232TH A 4445 5 26.1 401.2 +232TH G 49.46 100.081 12E2 324 10 +232TH2 G LC=237 7$MC=65.0 19$NC=17.4 5 +232TH3 G OC=3.87 12 +232TH L 162.25 154+ 164 PS 13 +232TH A 4332 8 0.149 2227.3 +232TH G 112.79 100.0195 31E2 6.67 20 +232TH2 G KC=0.229 7$LC=4.71 14$MC=1.295 39$NC=0.347 10 +232TH3 G OC=0.0774 23 +232TH L 333.40 256+ 62 PS 4 +232TH A 4168 0.00014 51160 +232TH G 171.15 200.00006522E2 1.186 36 +232TH2 G KC=0.204 6$LC=0.719 22$MC=0.197 6$NC=0.0527 16 +232TH3 G OC=0.01180 35 + diff --git a/HEN_HOUSE/spectra/lnhb/U-237.txt b/HEN_HOUSE/spectra/lnhb/U-237.txt index 153adc869..617ae5149 100644 --- a/HEN_HOUSE/spectra/lnhb/U-237.txt +++ b/HEN_HOUSE/spectra/lnhb/U-237.txt @@ -1,122 +1,130 @@ -237NP 237U B- DECAY (6.749 D) -237NP H TYP=Full$AUT=V.P.Chechev$CUT=30-AUG-2005$ -237NP2 H TYP=Full$AUT=V.P.Chechev$CUT=30-AUG-2005$ -237NP3 H TYP=Full$AUT=V.P.Chechev$CUT=30-AUG-2005$ -237NP4 H TYP=Full$AUT=V.P.Chechev$CUT=30-AUG-2005$ -237NP5 H TYP=Full$AUT=V.P.Chechev$CUT=30-AUG-2005$ -237NP6 H TYP=Full$AUT=V.P.Chechev$CUT=30-AUG-2005$ -237NP7 H TYP=Full$AUT=V.P.Chechev$CUT=30-AUG-2005$ -237NP8 H TYP=Full$AUT=V.P.Chechev$CUT=30-AUG-2005$ -237NP C Evaluation history: Type=Full;Author=V.P.Chechev;Cutoff date=30-AUG-2005 -237NP2C Type=Full;Author=V.P.Chechev;Cutoff date=30-AUG-2005 -237NP3C Type=Full;Author=V.P.Chechev;Cutoff date=30-AUG-2005 -237NP4C Type=Full;Author=V.P.Chechev;Cutoff date=30-AUG-2005 -237NP5C Type=Full;Author=V.P.Chechev;Cutoff date=30-AUG-2005 -237NP6C Type=Full;Author=V.P.Chechev;Cutoff date=30-AUG-2005 -237NP7C Type=Full;Author=V.P.Chechev;Cutoff date=30-AUG-2005 -237NP8C Type=Full;Author=V.P.Chechev;Cutoff date=30-AUG-2005 -237NP C References: 1949Me43, 1953Wa05, 1957Ra04, 1958Ca16, 1959Sa10, 1960As02, -237NP2C 1963Ak04, 1964Wo03, 1966Ya05, 1966Le13, 1967Pa23, 1966Ko06, 1968Da24, -237NP3C 1971Cl03, 1970Gr36, 1976GuZN, 1982BuZF, 1984BAYS, 1985He02, 1985Wi04, -237NP4C 1986LoZT, 1996Jo28, 1996Sc06, 1996Ya05, 1998Ko61, 2000He14, 2003Au03, -237NP5C 2006Ba41, 2008Ki07 -237NP T Auger electrons and X ray energies and emission intensities: -237NP T {U Energy (keV)} {U Intensity} {U Line} -237NP T -237NP T 97.069 14.8 4 XKA2 -237NP T 101.059 23.5 6 XKA1 -237NP T -237NP T 113.303 |] XKB3 -237NP T 114.234 |] 8.57 27 XKB1 -237NP T 114.912 |] XKB5II -237NP T -237NP T 117.476 |] XKB2 -237NP T 117.876 |] 2.95 10 XKB4 -237NP T 118.429 |] XKO23 -237NP T -237NP T 11.89-22.2 59.0 21 XL (total) -237NP T 11.89 1.56 8 XLL -237NP T 13.76-13.94 24.7 11 XLA -237NP T 15.88 0.433 29 XLC -237NP T 16.13-17.99 26.2 11 XLB -237NP T 20.12-22.2 5.99 25 XLG -237NP T -237NP T 73.5-83.13 |] KLL AUGER -237NP T 90.36-97.28 |] 1.49 21 KLX AUGER -237NP T 107.1-114.58 |] KXY AUGER -237NP T 5.04-13.52 58.5 21 L AUGER -237U P 0.0 1/2+ 6.749 D 16 518.6 6 -237NP N 1.0 1.0 1 1.0 -237NP G 114.09 5 -237NP G 340.45 0.0016 3 -237NP L 0 5/2+ 2.144E6 Y 7 -237NP L 33.19629 227/2+ 54 PS -237NP G 33.19629 220.130 5M1+E2 0.13 3 175 24 -237NP2 G LC=131 17$MC=33 5 -237NP L 59.54092 105/2- 67 NS 5 -237NP B 459.1 6 7 4 8.1 1U -237NPS B EAV=137.6 2 -237NP G 26.34463 242.43 6E1 8 2 -237NP2 G LC=6 2$MC=1.6 2 -237NP G 59.54091 1034.1 9E1 1.16 7 -237NP2 G LC=0.84 6$MC=0.226 7 -237NP L 75.899 5 9/2+ 56 PS -237NP G 42.704 5 0.0085 M1+E2 0.13 4 75 9 -237NP2 G LC=56 7$MC=13.9 19 -237NP G 75.899 5 0.00091 (E2) 53.4 11 -237NP2 G LC=38.9 8$MC=10.8 2 -237NP L 102.959 3 7/2- 80 PS -237NP G 27.020 7 -237NP G 43.420 3 0.024 2M1+E2 0.45 5 180 23 -237NP2 G LC=132 17$MC=35 5 -237NP G 69.76 3 0.00095 19(E1) 0.330 7 -237NP2 G LC=0.248 5$MC=0.0612 12 -237NP G 102.959 3 0.0064 9E1 0.119 3 -237NP2 G LC=0.0894 18$MC=0.0219 4 -237NP L 267.556 123/2- 5.2 NS -237NP B 251.1 6 40.9 31 6.54 1 -237NPS B EAV=68.6 2 -237NP G 164.61 2 1.86 3E2 1.70 4 -237NP2 G KC=0.195 4$LC=1.095 20$MC=0.304 6 -237NP G 208.00 1 21.3 3M1+E2 0.156 5 2.98 7 -237NP2 G KC=2.35 5$LC=0.473 10$MC=0.115 3 -237NP G 234.40 4 0.0205 8M2 8.24 16 -237NP2 G KC=5.560 12$LC=1.95 4$MC=0.511 10 -237NP G 267.556 120.721 10E1+M2 0.490 15 1.06 6 -237NP2 G KC=0.74 4$LC=0.238 12$MC=0.062 3 -237NP L 281.356 181/2- -237NP B 237.2 6 48.2 25 6.39 -237NPS B EAV=64.5 2 -237NP G 13.81 2 0.099 4M1+E2 0.0321 10 492 16 -237NP2 G MC=364 13 -237NP G 221.80 4 0.0204 8E2 0.547 11 -237NP2 G KC=0.130 3$LC=0.304 6$MC=0.0839 17 -237NP L 332.376 161/2+ 1 NS -237NP B 186.2 6 2.9 9 7.28 -237NPS B EAV=49.8 2 -237NP G 51.01 3 0.340 14E1 0.753 15 -237NP2 G LC=0.565 12$MC=0.140 3 -237NP G 64.83 2 1.286 17E1 0.400 8 -237NP2 G LC=0.301 6$MC=0.0744 15 -237NP G 332.376 161.199 16E2 0.146 3 -237NP2 G KC=0.0631 12$LC=0.0611 12$MC=0.0164 4 -237NP L 368.602 205/2+ -237NP G 292.77 6 0.0025 7(E2) 0.215 4 -237NP2 G KC=0.0796 16$LC=0.0991 19$MC=0.0270 6 -237NP G 309.1 3 0.00027 (E1) 0.0377 8 -237NP2 G KC=0.0300 6$LC=0.00585 12$MC=0.00143 3 -237NP G 335.38 4 0.0958 22M1+E2 0.46 17 0.69 8 -237NP2 G KC=0.54 7$LC=0.113 8$MC=0.0278 17 -237NP G 368.602 200.0416 17M1(+E2) 0.31 0.622 13 -237NP2 G KC=0.494 10$LC=0.0963 20$MC=0.0233 5 -237NP L 370.928 233/2+ -237NP B 147.7 6 1.3 9 7.32 -237NPS B EAV=39.0 2 -237NP G 2.3 -237NP G 38.54 3 0.0033 20M1+E2 0.42 25 2.8E2 21 -237NP2 G LC=2.1E2 16$MC=60 50 -237NP G 337.7 2 0.0089 5(E2) 0.139 3 -237NP2 G KC=0.0612 12$LC=0.0575 12$MC=0.0157 3 -237NP G 370.928 230.109 2M1+E2 0.43 21 0.53 7 -237NP2 G KC=0.42 6$LC=0.086 8$MC=0.0211 17 - +237NP 237U B- DECAY (6.749 D) +237NP H TYP=FUL$AUT=V.P.CHECHEV$CUT=30-AUG-2005$ +237NP C References:1949Me43, 1953Wa05, 1957Ra04, 1958Ca16, 1959Sa10, 1960As02, +237NP2C 1963Ak04, 1964Wo03, 1966Ya05, 1966Le13, 1967Pa23, 1966Ko06, 1968Da24, +237NP3C 1971Cl03, 1970Gr36, 1976GuZN, 1982BuZF, 1984BAYS, 1985He02, 1985Wi04, +237NP4C 1986LoZT, 1996Jo28, 1996Sc06, 1996Ya05, 1998Ko61, 2000He14, 2003Au03, +237NP5C 2006Ba41, 2008Ki07 +237NP T Auger electrons and X ray energies and emission intensities: +237NP T {U Energy (keV)} {U Intensity} {U Line} +237NP T +237NP T 97.069 14.8 4 XKA2 +237NP T 101.059 23.5 6 XKA1 +237NP T +237NP T 113.303 |] XKB3 +237NP T 114.234 |] 8.57 27 XKB1 +237NP T 114.912 |] XKB5II +237NP T +237NP T 117.476 |] XKB2 +237NP T 117.876 |] 2.95 10 XKB4 +237NP T 118.429 |] XKO23 +237NP T +237NP T 11.89-22.2 59.0 21 XL (total) +237NP T 11.89 1.56 8 XLL +237NP T 13.76-13.94 24.7 11 XLA +237NP T 15.88 0.433 29 XLC +237NP T 16.13-17.99 26.2 11 XLB +237NP T 20.12-22.2 5.99 25 XLG +237NP T +237NP T 73.5-83.13 |] KLL AUGER +237NP T 90.36-97.28 |] 1.49 21 KLX AUGER +237NP T 107.1-114.58 |] KXY AUGER +237NP T 5.04-13.52 58.5 21 L AUGER +237U P 0.0 1/2+ 6.749 D 16 518.6 6 +237NP N 1.0 1.0 1 1.0 +237NP G 114.09 5 +237NP G 340.45 0.0016 3 +237NP L 0 5/2+ 2.144E6 Y 7 +237NP L 33.19629 227/2+ 54 PS +237NP G 33.19629 220.130 5M1+E2 0.13 3 175 24 +237NP2 G LC=131 17$MC=33 5$NC=8.9 13 +237NP3 G OC=2.2 3 +237NP L 59.54092 105/2- 67 NS 5 +237NP B 459.1 6 7 4 8.1 1U +237NPS B EAV=137.6 2 +237NP G 26.34463 242.43 6E1 8 2 +237NP2 G LC=6 2$MC=1.6 2 +237NP G 59.54091 1034.1 9E1 1.16 7 +237NP2 G LC=0.84 6$MC=0.226 7$NC=0.0248 4 +237NP3 G OC=0.00576 8 +237NP L 75.899 5 9/2+ 56 PS +237NP G 42.704 5 0.0085 M1+E2 0.13 4 75 9 +237NP2 G LC=56 7$MC=13.9 19$NC=3.8 5 +237NP3 G OC=0.92 12 +237NP G 75.899 5 0.00091 (E2) 53.4 11 +237NP2 G LC=38.9 8$MC=10.8 2$NC=2.96 6 +237NP3 G OC=0.688 13 +237NP L 102.959 3 7/2- 80 PS +237NP G 27.020 7 +237NP G 43.420 3 0.024 2M1+E2 0.45 5 180 23 +237NP2 G LC=132 17$MC=35 5$NC=9.7 13 +237NP3 G OC=2.3 3 +237NP G 69.76 3 0.00095 19(E1) 0.330 7 +237NP2 G LC=0.248 5$MC=0.0612 12$NC=0.01633 23 +237NP3 G OC=0.00381 6 +237NP G 102.959 3 0.0064 9E1 0.119 3 +237NP2 G LC=0.0894 18$MC=0.0219 4$NC=0.00586 9 +237NP3 G OC=0.001387 20 +237NP L 267.556 123/2- 5.2 NS +237NP B 251.1 6 40.9 31 6.54 1 +237NPS B EAV=68.6 2 +237NP G 164.61 2 1.86 3E2 1.70 4 +237NP2 G KC=0.195 4$LC=1.095 20$MC=0.304 6$NC=0.0831 12 +237NP3 G OC=0.0194 3 +237NP G 208.00 1 21.3 3M1+E2 0.156 5 2.98 7 +237NP2 G KC=2.35 5$LC=0.473 10$MC=0.115 3$NC=0.0311 5 +237NP3 G OC=0.00766 11 +237NP G 234.40 4 0.0205 8M2 8.24 16 +237NP2 G KC=5.560 12$LC=1.95 4$MC=0.511 10$NC=0.1406 20 +237NP3 G OC=0.0345 5 +237NP G 267.556 120.721 10E1+M2 0.490 15 1.06 6 +237NP2 G KC=0.74 4$LC=0.238 12$MC=0.062 3$NC=0.0170 9 +237NP3 G OC=0.00417 21 +237NP L 281.356 181/2- +237NP B 237.2 6 48.2 25 6.39 +237NPS B EAV=64.5 2 +237NP G 13.81 2 0.099 4M1+E2 0.0321 10 492 16 +237NP2 G MC=364 13$NC=98.9 17 +237NP3 G OC=24.2 4 +237NP G 221.80 4 0.0204 8E2 0.547 11 +237NP2 G KC=0.130 3$LC=0.304 6$MC=0.0839 17$NC=0.0229 4 +237NP3 G OC=0.00537 8 +237NP L 332.376 161/2+ 1 NS +237NP B 186.2 6 2.9 9 7.28 +237NPS B EAV=49.8 2 +237NP G 51.01 3 0.340 14E1 0.753 15 +237NP2 G LC=0.565 12$MC=0.140 3$NC=0.0374 6 +237NP3 G OC=0.00863 13 +237NP G 64.83 2 1.286 17E1 0.400 8 +237NP2 G LC=0.301 6$MC=0.0744 15$NC=0.0198 3 +237NP3 G OC=0.00462 7 +237NP G 332.376 161.199 16E2 0.146 3 +237NP2 G KC=0.0631 12$LC=0.0611 12$MC=0.0164 4$NC=0.00451 7 +237NP3 G OC=0.001066 15 +237NP L 368.602 205/2+ +237NP G 292.77 6 0.0025 7(E2) 0.215 4 +237NP2 G KC=0.0796 16$LC=0.0991 19$MC=0.0270 6$NC=0.00738 11 +237NP3 G OC=0.001738 25 +237NP G 309.1 3 0.00027 (E1) 0.0377 8 +237NP2 G KC=0.0300 6$LC=0.00585 12$MC=0.00143 3$NC=0.000380 6 +237NP3 G OC=9.20E-5 13 +237NP G 335.38 4 0.0958 22M1+E2 0.46 17 0.69 8 +237NP2 G KC=0.54 7$LC=0.113 8$MC=0.0278 17$NC=0.0075 5 +237NP3 G OC=0.00185 12 +237NP G 368.602 200.0416 17M1(+E2) 0.31 0.622 13 +237NP2 G KC=0.494 10$LC=0.0963 20$MC=0.0233 5$NC=0.00631 9 +237NP3 G OC=0.001555 22 +237NP L 370.928 233/2+ +237NP B 147.7 6 1.3 9 7.32 +237NPS B EAV=39.0 2 +237NP G 2.3 +237NP G 38.54 3 0.0033 20M1+E2 0.42 25 2.8E2 21 +237NP2 G LC=2.1E2 16$MC=60 50$NC=15 12 +237NP3 G OC=4 3 +237NP G 337.7 2 0.0089 5(E2) 0.139 3 +237NP2 G KC=0.0612 12$LC=0.0575 12$MC=0.0157 3$NC=0.00425 6 +237NP3 G OC=0.001003 15 +237NP G 370.928 230.109 2M1+E2 0.43 21 0.53 7 +237NP2 G KC=0.42 6$LC=0.086 8$MC=0.0211 17$NC=0.0057 5 +237NP3 G OC=0.00140 12 + diff --git a/HEN_HOUSE/spectra/lnhb/U-238.txt b/HEN_HOUSE/spectra/lnhb/U-238.txt index 741c84003..3ef0417ab 100644 --- a/HEN_HOUSE/spectra/lnhb/U-238.txt +++ b/HEN_HOUSE/spectra/lnhb/U-238.txt @@ -1,49 +1,50 @@ -234TH 238U A DECAY (4.468E9 Y) -234TH H TYP=Full$AUT=V. Chisté$CUT=01-APR-2006$ -234TH C Evaluation history: Type=Full;Author=V. Chisté;Cutoff date=01-APR-2006 -234TH C References: 1949Ki26, 1952Se67, 1955Ko13, 1957Le21, 1957Cl16, 1959St45, -234TH2C 1959Ko58, 1959Ku81, 1961Ko11, 1964Fl07, 1967Sp12, 1968Ro15, 1970Ga27, -234TH3C 1971Le11, 1971Th17, 1971Kl14, 1971Ja07, 1973Kh10, 1974Iv01, 1975Wa37, -234TH4C 1975Em03, 1976Th12, 1978Ri07, 1978Ka40, 1980Sp10, 1980Po09, 1981Ba70, -234TH5C 1982De22, 1983El11, 1983Be66, 1984Va35, 1984Va34, 1984Ro21, 1985Iv01, -234TH6C 1987Al28, 1990Ko40, 1991Ry01, 1994Ak05, 1994Du15, 1996Sc06, 1996Ru11, -234TH7C 1998Ad08, 2000Ho27, 2000Ga05, 2002Ba85, 2002Ch52, 2003Au03, 2003Ha06, -234TH8C 2004Sc03 -234TH T Auger electrons and X ray energies and emission intensities: -234TH T {U Energy (keV)} {U Intensity} {U Line} -234TH T -234TH T 89.954 0.00109 30 XKA2 -234TH T 93.351 0.0018 5 XKA1 -234TH T -234TH T 104.819 |] XKB3 -234TH T 105.604 |] 0.00063 17 XKB1 -234TH T 106.239 |] XKB5II -234TH T -234TH T 108.509 |] XKB2 -234TH T 108.955 |] 0.00021 6 XKB4 -234TH T 109.442 |] XKO23 -234TH T -234TH T 11.118-19.504 7.94 28 XL (total) -234TH T 11.118 0.164 8 XLL -234TH T 12.8085-12.967 2.74 12 XLA -234TH T 14.509 0.092 5 XLC -234TH T 14.972-17.1383 4.01 18 XLB -234TH T 18.3633-19.504 0.94 4 XLG -234TH T -234TH T 68.406-76.745 |] KLL AUGER -234TH T 83.857-93.345 |] 0.00012 4 KLX AUGER -234TH T 99.29-109.64 |] KXY AUGER -234TH T 5.8-20.3 8.43 25 L AUGER -238U P 0.0 0+ 4.468E9 Y 5 4269.7 29 -234TH N 1.0 1.0 1 1.0 -234TH L 0 0 0+ 24.10 D 3 -234TH A 4198 3 77.5 5 1 -234TH L 49.55 6 2+ 0.37 NS 3 -234TH A 4151 5 22.3 5 1.33 -234TH G 49.55 6 0.0697 26E2 321 10 -234TH2 G LC=235 7$MC=64.4 19 -234TH L 163.0 1 4+ -234TH A 4038 5 0.13 3 24 -234TH G 113.5 1 0.0174 47[E2] 6.47 19 -234TH2 G KC=0.219 7$LC=4.57 14$MC=1.257 38 - +234TH 238U A DECAY (4.468E9 Y) +234TH H TYP=FUL$AUT=V.CHISTE$CUT=01-APR-2006$ +234TH C References:1949Ki26, 1950Wh**, 1952Se67, 1955Ko13, 1956Ku**, 1957Le21, +234TH2C 1957Cl16, 1957Ku**, 1958Pa**, 1959St45, 1959Ko58, 1959Ku81, 1961Ko11, +234TH3C 1964Fl07, 1967Sp12, 1968Ro15, 1970Ga27, 1971Le11, 1971Th17, 1971Kl14, +234TH4C 1971Ja07, 1973Kh10, 1974Iv01, 1975Wa37, 1975Em03, 1976Th12, 1978Ri07, +234TH5C 1978Ka40, 1980Sp10, 1980Po09, 1981Ba70, 1982De22, 1983El11, 1983Be66, +234TH6C 1984Va35, 1984Va34, 1984Ro21, 1985Iv01, 1987Al28, 1990Ko40, 1991Ry01, +234TH7C 1994Ak05, 1994Du15, 1996Sc06, 1996Ru11, 1998Ad08, 2000Ho27, 2000Ga05, +234TH8C 2002Ba85, 2002Ch52, 2003Au03, 2003Ha06, 2004Sc03 +234TH T Auger electrons and X ray energies and emission intensities: +234TH T {U Energy (keV)} {U Intensity} {U Line} +234TH T +234TH T 89.954 0.00109 30 XKA2 +234TH T 93.351 0.0018 5 XKA1 +234TH T +234TH T 104.819 |] XKB3 +234TH T 105.604 |] 0.00063 17 XKB1 +234TH T 106.239 |] XKB5II +234TH T +234TH T 108.509 |] XKB2 +234TH T 108.955 |] 0.00021 6 XKB4 +234TH T 109.442 |] XKO23 +234TH T +234TH T 11.118-19.504 7.94 28 XL (total) +234TH T 11.118 0.164 8 XLL +234TH T 12.8085-12.967 2.74 12 XLA +234TH T 14.509 0.092 5 XLC +234TH T 14.972-17.1383 4.01 18 XLB +234TH T 18.3633-19.504 0.94 4 XLG +234TH T +234TH T 68.406-76.745 |] KLL AUGER +234TH T 83.857-93.345 |] 0.00012 4 KLX AUGER +234TH T 99.29-109.64 |] KXY AUGER +234TH T 5.8-20.3 8.43 25 L AUGER +238U P 0.0 0+ 4.468E9 Y 5 4269.7 29 +234TH N 1.0 1.0 1 +234TH L 0 0+ 24.10 D 3 +234TH A 4198 3 77.5 51 +234TH L 49.55 6 2+ 0.37 NS 3 +234TH A 4151 5 22.3 51.33 +234TH G 49.55 6 0.0697 26E2 321 10 +234TH2 G LC=235 7$MC=64.4 19$NC=17.2 5 +234TH3 G OC=3.83 11 +234TH L 163.0 1 4+ +234TH A 4038 5 0.13 324 +234TH G 113.5 1 0.0174 47[E2] 6.47 19 +234TH2 G KC=0.219 7$LC=4.57 14$MC=1.257 38$NC=0.337 10 +234TH3 G OC=0.0752 23 + diff --git a/HEN_HOUSE/spectra/lnhb/U-239.txt b/HEN_HOUSE/spectra/lnhb/U-239.txt index 8e9e2eea8..18208d76c 100644 --- a/HEN_HOUSE/spectra/lnhb/U-239.txt +++ b/HEN_HOUSE/spectra/lnhb/U-239.txt @@ -1,313 +1,353 @@ -239NP 239U B- DECAY (23.46 M) -239NP H TYP=Update$AUT=V.Chechev$CUT=31-MAR-2009$ -239NP2 H TYP=Full$AUT=V. Chechev$CUT=01-AUG-2005$ -239NP3 H TYP=Update$AUT=MMBé$CUT= -- $ -239NP C Evaluation history: Type=Update;Author=V.Chechev;Cutoff date=31-MAR-2009 -239NP2C Type=Full;Author=V. Chechev;Cutoff date=01-AUG-2005 -239NP3C Type=Update;Author=MMBé;Cutoff date= -- -239NP C References: 1943Mi10, 1947Fe05, 1957Ho07, 1964Bl11, 1968Ma06, 1969Hu21, -239NP2C 1969Cl12, 1969En02, 1971Ar47, 1975Pa04, 1979Bo30, 1982Ah04, 1989Ab05, -239NP3C 1996Sa23, 2003Au03, 2003Br12, 2006WoO3, 2008Ki07 -239NP T Auger electrons and X ray energies and emission intensities: -239NP T {U Energy (keV)} {U Intensity} {U Line} -239NP T -239NP T 97.069 0.091 3 XKA2 -239NP T 101.059 0.144 5 XKA1 -239NP T -239NP T 113.303 |] XKB3 -239NP T 114.234 |] 0.052 2 XKB1 -239NP T 114.912 |] XKB5II -239NP T -239NP T 117.463 |] XKB2 -239NP T 117.876 |] 0.018 1 XKB4 -239NP T 118.429 |] XKO23 -239NP T -239NP T 11.871-21.491 16.1 5 XL (total) -239NP T 11.871 0.38 2 XLL -239NP T 13.671-13.946 7.0 2 XLA -239NP T 15.861 0.108 4 XLC -239NP T 16.109-17.992 6.9 2 XLB -239NP T 20.784-21.491 1.68 4 XLG -239NP T -239NP T 73.501-83.134 |] KLL AUGER -239NP T 90.358-101.054 |] 0.0091 13 KLX AUGER -239NP T 107.19-118.66 |] KXY AUGER -239NP T 6.04-13.12 14.7 7 L AUGER -239U P 0.0 5/2+ 23.46 M 5 1261.5 16 -239NP N 1.0 1.0 1 1.0 -239NP G 46.6 0.009 4 -239NP G 134.71 130.0019 3 -239NP G 142.5 1 0.0045 6 -239NP G 174.07 6 0.0097 3 -239NP G 220.52 4 0.0282 7 -239NP G 236.28 140.00092 18 -239NP G 262.89 190.0008 3 -239NP G 265.44 170.0009 3 -239NP G 330.14 140.00069 13 -239NP G 332.06 140.0012 2 -239NP G 348.23 180.0007 3 -239NP G 351.33 150.0007 2 -239NP G 361.83 8 0.0044 3 -239NP G 393.01 180.0006 2 -239NP G 400.55 150.0009 2 -239NP G 404.84 180.0009 3 -239NP G 445.81 120.0011 2 -239NP G 452.17 120.0016 2 -239NP G 478.13 190.00055 23 -239NP G 479.55 140.0010 2 -239NP G 490.33 130.0007 1 -239NP G 502.12 170.0006 2 -239NP G 506.80 140.0010 2 -239NP G 541.32 100.0029 3 -239NP G 558.46 170.0006 2 -239NP G 567.88 180.0004 1 -239NP G 575.27 5 0.0131 4 -239NP G 577.15 140.0014 3 -239NP G 585.49 140.0012 2 -239NP G 591.82 190.0009 4 -239NP G 599.13 150.0007 2 -239NP G 602.79 8 0.0048 3 -239NP G 604.85 6 0.00096 27 -239NP G 614.53 170.0006 2 -239NP G 618.03 160.0007 2 -239NP G 629.00 110.0027 3 -239NP G 649.79 190.0009 4 -239NP G 668.76 180.00055 18 -239NP G 670.88 200.0006 3 -239NP G 691.01 6 0.0074 3 -239NP G 692.61 130.0016 3 -239NP G 701.21 100.0024 2 -239NP G 714.22 9 0.0030 3 -239NP G 730.95 6 0.0090 3 -239NP G 746.06 110.0043 5 -239NP G 764.04 110.0026 3 -239NP G 768.15 110.0020 2 -239NP G 769.52 170.0004 1 -239NP G 795.13 150.0008 2 -239NP G 829.59 170.00046 13 -239NP G 831.89 9 0.0021 2 -239NP G 862.56 180.0004 1 -239NP G 913.68 9 0.0019 1 -239NP G 948.88 190.00024 10 -239NP G 970.07 140.0009 2 -239NP G 988.51 140.00044 9 -239NP G 1002.40 130.00049 9 -239NP G 1005.27 130.0006 1 -239NP G 1009.38 180.0003 1 -239NP G 1101.99 160.00031 1 -239NP L 0 5/2+ 2.356 D 3 -239NP B 1261.5 1614.4 22 6.7 -239NPS B EAV=418.6 5 -239NP L 31.1310 127/2+ -239NP B 1230.4 169.4 15 6.83 -239NPS B EAV=406.8 5 -239NP G 31.1310 120.072 4M1+E2 0.17 1 263 13 -239NP2 G LC=195 10$MC=50 3 -239NP L 71.210 2 9/2+ -239NP G 71.210 2 0.00193 4E2 71.9 14 -239NP2 G LC=52.3 10$MC=14.6 3 -239NP L 74.664 1 5/2- 1.39 NS 3 -239NP B 1186.5 1672.8 19 5.91 -239NPS B EAV=390.4 5 -239NP G 43.533 1 4.35 28E1 1.14 3 -239NP2 G LC=0.856 17$MC=0.215 4 -239NP G 74.664 1 51.6 13E1 0.276 6 -239NP2 G LC=0.207 4$MC=0.0512 10 -239NP L 117.727 207/2- 40 PS -239NP B 1143.9 162.2 4 7.4 1 -239NPS B EAV=374.0 5 -239NP G 43.06 2 0.013 2M1+E2 0.38 38 154 18 -239NP2 G LC=114 13$MC=30 4 -239NP G 86.72 7 0.055 5E1 0.186 4 -239NP2 G LC=0.140 3$MC=0.0344 7 -239NP G 117.727 200.113 9E1 0.0841 17 -239NP2 G LC=0.0632 13$MC=0.0155 3 -239NP L 122.5 10(11/2)+ -239NP L 173.10 4 9/2- -239NP G 55.37 5 8.36E-5 20M1+E2 0.6 2 90 30 -239NP2 G LC=63 20$MC=17 6 -239NP L 241.36 5 (11/2-)- -239NP G 170.15 5 0.031 1 -239NP L 260.799 17(3/2)- -239NP G 186.15 4 0.0288 7[M1+E2] 2.6 16 -239NP2 G KC=1.7 16$LC=0.645 13$MC=0.167 14 -239NP G 260.80 2 0.0031 2[E1] 0.0549 11 -239NP2 G KC=0.0434 9$LC=0.0087 2$MC=0.00211 4 -239NP L 438.83 5 (11/2+)+ -239NP G 197.28 120.0024 3 -239NP L 448.178 16(3/2-)- -239NP G 187.28 8 0.0056 3[M1+E2] 2.6 16 -239NP2 G KC=1.7 16$LC=0.631 13$MC=0.164 14 -239NP G 373.51 4 0.025 6[M1+E2] 0.35 22 -239NP2 G KC=0.26 22$LC=0.07 3$MC=0.017 6 -239NP G 448.18 2 0.0090 3[E1] 0.0173 4 -239NP2 G KC=0.0139 3$LC=0.00258 5$MC=0.00062 1 -239NP L 452.736 2 (5/2+,7/2-)+ -239NP G 378.06 6 0.0101 4 -239NP G 381.27 160.0006 2 -239NP L 474.36 6 + -239NP B 787.1 160.0033 4 -239NPS B EAV=244.0 5 -239NP G 399.13 130.0016 3 -239NP G 474.36 6 0.0017 2 -239NP L 517.998 20(7/2-)- -239NP B 743.5 160.063 2 1 -239NPS B EAV=228.6 5 -239NP G 486.87 3 0.0618 14[E1] 0.0147 4 -239NP2 G KC=0.0118 3$LC=0.00217 5$MC=0.00052 1 -239NP G 518.00 2 0.0045 3[E1] 0.0130019 -239NP2 G KC=0.01050 15$LC=0.00190 4$MC=0.00046 1 -239NP L 530.29 6 + -239NP B 731.2 160.0029 4 -239NPS B EAV=224.3 5 -239NP G 455.63 6 0.0008 3 -239NP G 499.1 1 0.0021 2 -239NP L 563.89 4 + -239NP B 697.6 160.0247 7 -239NPS B EAV=212.6 5 -239NP G 111.0 2 0.0202 5 -239NP G 492.76 7 0.0050 2 -239NP G 532.86 100.0023 2 -239NP G 563.89 4 0.0004 2 -239NP L 579.40 4 (9/2-)- -239NP G 504.76 8 0.0052 3[E2] 0.0488 10 -239NP2 G KC=0.0293 6$LC=0.0143 3$MC=0.0038 1 -239NP G 547.99 120.0020 3[E1] 0.0117024 -239NP2 G KC=0.00941 19$LC=0.00170 4$MC=0.00041 1 -239NP L 662.282 17(5/2-)- -239NP B 599.2 160.261 6 7.35 -239NPS B EAV=179.0 5 -239NP G 544.48 9 0.0036 3[M1+E2] 0.13 9 -239NP2 G KC=0.10 8$LC=0.022 11$MC=0.005 3 -239NP G 587.62 2 0.0193 5[M1+E2] 0.11 7 -239NP2 G KC=0.08 6$LC=0.018 9$MC=0.004 2 -239NP G 631.10 3 0.067 2[E1] 0.0089217 -239NP2 G KC=0.0072 2$LC=0.00128 3$MC=0.00031 1 -239NP G 662.28 2 0.170 5[E1] 0.0081516 -239NP2 G KC=0.00660 13$LC=1170E-6 17$MC=0.00028 1 -239NP L 695.229 23(7/2-)- -239NP B 566.3 160.0118 11 1 -239NPS B EAV=168.0 5 -239NP G 522.12 100.0024 2[M1+E2] 0.14 10 -239NP2 G KC=0.11 9$LC=0.025 13$MC=0.006 3 -239NP G 624.11 7 0.0062 3[E1] 0.0091 2 -239NP2 G KC=0.00737 15$LC=0.00131 3$MC=0.00031 1 -239NP G 664.17 9 0.0054 4[E1] 0.0081116 -239NP2 G KC=0.00657 13$LC=1160E-6 17$MC=0.00028 1 -239NP G 695.23 2 0.0036 3[E1] 0.0074515 -239NP2 G KC=0.00604 13$LC=1060E-6 15$MC=0.00025 1 -239NP L 781.93 4 + -239NP G 707.38 9 0.0022 2 -239NP L 784.94 5 + -239NP G 710.35 150.003 -239NP L 819.26 3 (7/2)+ -239NP B 442.2 160.228 3 -239NPS B EAV=127.4 5 -239NP G 239.86 5 0.00087 23 -239NP G 255.37 5 0.0011 2 -239NP G 646.26 100.0029 3 -239NP G 748.09 3 0.0890 4 -239NP G 788.19 7 0.0049 2 -239NP G 819.26 3 0.129 3 -239NP L 844.10 3 (5/2,7/2)+ -239NP B 417.4 160.215 3 -239NPS B EAV=119.6 5 -239NP G 326.21 7 0.0044 2 -239NP G 772.94 9 0.0029 2 -239NP G 812.89 3 0.0685 3 -239NP G 844.10 3 0.139 3 -239NP L 849.44 9 + -239NP B 412.0 160.0264 4 -239NPS B EAV=117.8 5 -239NP G 588.70 8 0.0055 3 -239NP G 607.96 150.0013 3 -239NP G 727.52 100.0026 3 -239NP G 774.77 4 0.015 4 -239NP G 849.44 9 0.0020 2 -239NP L 863.46 6 (3/2,5/2,7/2)+ -239NP B 398.1 160.0005 2 -239NPS B EAV=113.4 5 -239NP G 201.18 6 0.0005 2 -239NP L 959.18 3 + -239NP B 302.3 160.0284 7 -239NPS B EAV=83.9 5 -239NP G 296.93 13 [M1+E2] 0.7 5 -239NP2 G KC=0.5 4$LC=0.13 4$MC=0.034 9 -239NP G 395.19 110.0021 2 -239NP G 841.45 4 0.0025 4 -239NP G 884.45 5 0.0086 2 -239NP G 887.97 3 0.0023 2 -239NP G 928.05 3 0.0051 2 -239NP G 959.18 3 0.0078 3 -239NP L 964.234 20(7/2-)- -239NP B 297.3 160.211 3 1 -239NPS B EAV=82.4 5 -239NP G 301.95 3 0.0011 3[M1+E2] 0.6 5 -239NP2 G KC=0.5 4$LC=0.13 4$MC=0.032 9 -239NP G 703.63 100.0023 2[E2] 0.0234 5 -239NP2 G KC=0.0162 3$LC=0.00537 11$MC=0.00138 3 -239NP G 722.85 4 0.0270 7[E2] 0.0222 4 -239NP2 G KC=0.0155 3$LC=0.00499 10$MC=1060E-6 18 -239NP G 791.13 5 0.0075 2 -239NP G 846.39 4 0.0312 8[M1+E2] 0.04 3 -239NP2 G KC=0.032 21$LC=0.007 4$MC=0.0016 8 -239NP G 889.49 4 0.0209 5[M1+E2] 0.036 22 -239NP2 G KC=0.029 18$LC=0.006 3$MC=0.0014 7 -239NP G 933.09 3 0.0262 6[E1] 0.00439 9 -239NP2 G KC=0.00358 7$LC=0.00061 1$MC=0.00015 1 -239NP G 964.23 2 0.0905 20[E1] 0.00415 8 -239NP2 G KC=0.00338 7$LC=0.00058 1$MC=0.00014 1 -239NP L 966.55 5 (7/2,9/2-)- -239NP B 295.0 160.0008 2 1 -239NPS B EAV=81.7 5 -239NP G 895.15 150.0008 2 -239NP L 992.158 22(7/2-)- -239NP B 269.3 160.0262 9 1 -239NPS B EAV=74.0 5 -239NP G 296.93 130.0014 2[M1+E2] 0.7 5 -239NP2 G KC=0.5 4$LC=0.13 4$MC=0.034 9 -239NP G 869.57 9 0.0016 1 -239NP G 874.43 3 0.0033 2[M1+E2] 0.038 23 -239NP2 G KC=0.030 19$LC=0.006 4$MC=0.0015 8 -239NP G 917.40 8 0.0027 1[M1+E2] 0.034 22 -239NP2 G KC=0.026 17$LC=0.005 3$MC=0.0013 7 -239NP G 920.95 8 0.0026 1[E1] 0.00450 9 -239NP2 G KC=0.00366 6$LC=0.00063 1$MC=0.00015 1 -239NP G 960.99 5 0.0105 3[E1] 0.00417 9 -239NP2 G KC=0.00340 7$LC=0.00058 1$MC=0.00014 1 -239NP G 992.16 2 0.0028 1[E1] 0.00395 8 -239NP2 G KC=0.00322 7$LC=0.00055 1$MC=0.00013 1 -239NP L 1013.64 8 - -239NP B 247.9 160.0074 4 -239NPS B EAV=67.6 5 -239NP G 560.63 7 0.0058 3 -239NP G 752.84 8 0.0013 3 -239NP G 938.98 8 0.00031 8 -239NP L 1040.37 4 (5/2-,7/2)+ -239NP B 221.1 160.0077 4 -239NPS B EAV=59.9 5 -239NP G 258.44 6 0.00073 18 -239NP G 345.13 8 0.0039 2 -239NP G 779.57 140.0006 1 -239NP G 867.11 110.00076 8 -239NP G 922.83 130.0006 1 -239NP G 1040.37 4 0.0011 1 -239NP L 1049.24 4 (9/2-)- -239NP B 212.3 160.0059 4 1U -239NPS B EAV=57.3 5 -239NP G 931.51 5 0.0053 3[M1+E2] 0.032 19 -239NP2 G KC=0.026 16$LC=0.005 3$MC=0.0013 7 -239NP G 974.58 4 0.00040 8[E2] 0.0123 5 -239NP2 G KC=0.00917 18$LC=0.00234 5$MC=0.00059 1 -239NP L 1096.99 3 - -239NP B 164.5 160.0060 5 -239NPS B EAV=43.7 5 -239NP G 312.05 3 0.0006 -239NP G 434.71 4 0.0012 2(E1) 0.0184 4 -239NP2 G KC=0.0148 3$LC=0.00276 5$MC=0.00066 1 -239NP G 644.253 300.0019 4 -239NP G 1065.76 120.00059 8[M1+E2] 0.023 13 -239NP2 G KC=0.018 11$LC=0.004 2$MC=0.0009 4 -239NP G 1096.99 3 0.0016 1[M1+E2] 0.022 13 -239NP2 G KC=0.017 11$LC=0.003 2$MC=0.0008 4 - +239NP 239U B- DECAY (23.46 M) +239NP H TYP=UPD$AUT=V.P.CHECHEV$CUT=31-MAR-2009$ +239NP2 H TYP=FUL$AUT=V.P.CHECHEV$CUT=01-AUG-2005$ +239NP3 H TYP=UPD$AUT=M.-M.BE$CUT=10-NOV-2005$ +239NP C References:1943Mi10, 1947Fe05, 1957Ho07, 1964Bl11, 1965Yu**, 1968Ma06, +239NP2C 1969Hu21, 1969Cl12, 1969En02, 1971Ar47, 1975Pa04, 1979Bo30, 1982Ah04, +239NP3C 1984Ho**, 1989Ab05, 1996Sa23, 2002Be**, 2003Au03, 2003Br12, 2006WoO3, +239NP4C 2008Ha**, 2008De**, 2008Ki07 +239NP T Auger electrons and X ray energies and emission intensities: +239NP T {U Energy (keV)} {U Intensity} {U Line} +239NP T +239NP T 97.069 0.091 3 XKA2 +239NP T 101.059 0.144 5 XKA1 +239NP T +239NP T 113.303 |] XKB3 +239NP T 114.234 |] 0.052 2 XKB1 +239NP T 114.912 |] XKB5II +239NP T +239NP T 117.463 |] XKB2 +239NP T 117.876 |] 0.018 1 XKB4 +239NP T 118.429 |] XKO23 +239NP T +239NP T 11.871-21.491 16.1 5 XL (total) +239NP T 11.871 0.38 2 XLL +239NP T 13.671-13.946 7.0 2 XLA +239NP T 15.861 0.108 4 XLC +239NP T 16.109-17.992 6.9 2 XLB +239NP T 20.784-21.491 1.68 4 XLG +239NP T +239NP T 73.501-83.134 |] KLL AUGER +239NP T 90.358-101.054 |] 0.0091 13 KLX AUGER +239NP T 107.19-118.66 |] KXY AUGER +239NP T 6.04-13.12 14.7 7 L AUGER +239U P 0.0 5/2+ 23.46 M 5 1261.5 16 +239NP N 1.0 1.0 1 1.0 +239NP G 46.6 0.009 4 +239NP G 134.71 130.0019 3 +239NP G 142.5 1 0.0045 6 +239NP G 174.07 6 0.0097 3 +239NP G 220.52 4 0.0282 7 +239NP G 236.28 140.00092 18 +239NP G 262.89 190.0008 3 +239NP G 265.44 170.0009 3 +239NP G 330.14 140.00069 13 +239NP G 332.06 140.0012 2 +239NP G 348.23 180.0007 3 +239NP G 351.33 150.0007 2 +239NP G 361.83 8 0.0044 3 +239NP G 393.01 180.0006 2 +239NP G 400.55 150.0009 2 +239NP G 404.84 180.0009 3 +239NP G 445.81 120.0011 2 +239NP G 452.17 120.0016 2 +239NP G 478.13 190.00055 23 +239NP G 479.55 140.0010 2 +239NP G 490.33 130.0007 1 +239NP G 502.12 170.0006 2 +239NP G 506.80 140.0010 2 +239NP G 541.32 100.0029 3 +239NP G 558.46 170.0006 2 +239NP G 567.88 180.0004 1 +239NP G 575.27 5 0.0131 4 +239NP G 577.15 140.0014 3 +239NP G 585.49 140.0012 2 +239NP G 591.82 190.0009 4 +239NP G 599.13 150.0007 2 +239NP G 602.79 8 0.0048 3 +239NP G 604.85 6 0.00096 27 +239NP G 614.53 170.0006 2 +239NP G 618.03 160.0007 2 +239NP G 629.00 110.0027 3 +239NP G 649.79 190.0009 4 +239NP G 668.76 180.00055 18 +239NP G 670.88 200.0006 3 +239NP G 691.01 6 0.0074 3 +239NP G 692.61 130.0016 3 +239NP G 701.21 100.0024 2 +239NP G 714.22 9 0.0030 3 +239NP G 730.95 6 0.0090 3 +239NP G 746.06 110.0043 5 +239NP G 764.04 110.0026 3 +239NP G 768.15 110.0020 2 +239NP G 769.52 170.0004 1 +239NP G 795.13 150.0008 2 +239NP G 829.59 170.00046 13 +239NP G 831.89 9 0.0021 2 +239NP G 862.56 180.0004 1 +239NP G 913.68 9 0.0019 1 +239NP G 948.88 190.00024 10 +239NP G 970.07 140.0009 2 +239NP G 988.51 140.00044 9 +239NP G 1002.40 130.00049 9 +239NP G 1005.27 130.0006 1 +239NP G 1009.38 180.0003 1 +239NP G 1101.99 160.00031 1 +239NP L 0 5/2+ 2.356 D 3 +239NP B 1261.5 1614.4 22 6.7 +239NPS B EAV=418.6 5 +239NP L 31.1310 127/2+ +239NP B 1230.4 169.4 15 6.83 +239NPS B EAV=406.8 5 +239NP G 31.1310 120.072 4M1+E2 0.17 1 263 13 +239NP2 G LC=195 10$MC=50 3$NC=13.7 8 +239NP3 G OC=3.28 17 +239NP L 71.210 2 9/2+ +239NP G 71.210 2 0.00193 4E2 71.9 14 +239NP2 G LC=52.3 10$MC=14.6 3$NC=3.98 6 +239NP3 G OC=0.926 13 +239NP L 74.664 1 5/2- 1.39 NS 3 +239NP B 1186.5 1672.8 19 5.91 +239NPS B EAV=390.4 5 +239NP G 43.533 1 4.35 28E1 1.14 3 +239NP2 G LC=0.856 17$MC=0.215 4$NC=0.0570 8 +239NP3 G OC=0.01304 19 +239NP G 74.664 1 51.6 13E1 0.276 6 +239NP2 G LC=0.207 4$MC=0.0512 10$NC=0.01364 20 +239NP3 G OC=0.00319 5 +239NP L 117.727 207/2- 40 PS +239NP B 1143.9 162.2 4 7.4 1 +239NPS B EAV=374.0 5 +239NP G 43.06 2 0.013 2M1+E2 0.38 38 154 18 +239NP2 G LC=114 13$MC=30 4$NC=8 10 +239NP3 G OC=1.9 24 +239NP G 86.72 7 0.055 5E1 0.186 4 +239NP2 G LC=0.140 3$MC=0.0344 7$NC=0.00920 13 +239NP3 G OC=0.00216 3 +239NP G 117.727 200.113 9E1 0.0841 17 +239NP2 G LC=0.0632 13$MC=0.0155 3$NC=0.00414 6 +239NP3 G OC=0.000983 14 +239NP L 122.5 10(11/2)+ +239NP L 173.10 4 9/2- +239NP G 55.37 5 8.36E-5 20M1+E2 0.6 2 90 30 +239NP2 G LC=63 20$MC=17 6$NC=4.6 16 +239NP3 G OC=1.1 4 +239NP L 241.36 5 (11/2-) +239NP G 170.15 5 0.031 1 +239NP L 260.799 17(3/2)- +239NP G 186.15 4 0.0288 7[M1+E2] 2.6 16 +239NP2 G KC=1.7 16$LC=0.645 13$MC=0.167 14$NC=0.046 3 +239NP3 G OC=0.0109 5 +239NP G 260.80 2 0.0031 2[E1] 0.0549 11 +239NP2 G KC=0.0434 9$LC=0.0087 2$MC=0.00211 4$NC=0.000566 8 +239NP3 G OC=1.366E-4 20 +239NP L 438.83 5 (11/2+) +239NP G 197.28 120.0024 3 +239NP L 448.178 16(3/2-) +239NP G 187.28 8 0.0056 3[M1+E2] 2.6 16 +239NP2 G KC=1.7 16$LC=0.631 13$MC=0.164 14$NC=0.045 3 +239NP3 G OC=0.0107 4 +239NP G 373.51 4 0.025 6[M1+E2] 0.35 22 +239NP2 G KC=0.26 22$LC=0.07 3$MC=0.017 6$NC=0.0045 16 +239NP3 G OC=0.0011 4 +239NP G 448.18 2 0.0090 3[E1] 0.0173 4 +239NP2 G KC=0.0139 3$LC=0.00258 5$MC=0.00062 1$NC=1.668E-4 24 +239NP3 G OC=4.06E-5 6 +239NP L 452.736 2 (5/2+,7/2-) +239NP G 378.06 6 0.0101 4 +239NP G 381.27 160.0006 2 +239NP L 474.36 6 +239NP B 787.1 160.0033 4 +239NPS B EAV=244.0 5 +239NP G 399.13 130.0016 3 +239NP G 474.36 6 0.0017 2 +239NP L 517.998 20(7/2-) +239NP B 743.5 160.063 2 1 +239NPS B EAV=228.6 5 +239NP G 486.87 3 0.0618 14[E1] 0.0147 4 +239NP2 G KC=0.0118 3$LC=0.00217 5$MC=0.00052 1$NC=0.000140 2 +239NP3 G OC=3.41E-5 5 +239NP G 518.00 2 0.0045 3[E1] 0.0130019 +239NP2 G KC=0.01050 15$LC=0.00190 4$MC=0.00046 1$NC=1.231E-4 18 +239NP3 G OC=3.00E-5 5 +239NP L 530.29 6 +239NP B 731.2 160.0029 4 +239NPS B EAV=224.3 5 +239NP G 455.63 6 0.0008 3 +239NP G 499.1 1 0.0021 2 +239NP L 563.89 4 +239NP B 697.6 160.0247 7 +239NPS B EAV=212.6 5 +239NP G 111.0 2 0.0202 5 +239NP G 492.76 7 0.0050 2 +239NP G 532.86 100.0023 2 +239NP G 563.89 4 0.0004 2 +239NP L 579.40 4 (9/2-) +239NP G 504.76 8 0.0052 3[E2] 0.0488 10 +239NP2 G KC=0.0293 6$LC=0.0143 3$MC=0.0038 1$NC=0.001027 15 +239NP3 G OC=0.000245 4 +239NP G 547.99 120.0020 3[E1] 0.0117024 +239NP2 G KC=0.00941 19$LC=0.00170 4$MC=0.00041 1$NC=1.097E-4 16 +239NP3 G OC=2.67E-5 4 +239NP L 662.282 17(5/2-) +239NP B 599.2 160.261 6 7.35 +239NPS B EAV=179.0 5 +239NP G 544.48 9 0.0036 3[M1+E2] 0.13 9 +239NP2 G KC=0.10 8$LC=0.022 11$MC=0.005 3$NC=0.0015 7 +239NP3 G OC=0.00036 18 +239NP G 587.62 2 0.0193 5[M1+E2] 0.11 7 +239NP2 G KC=0.08 6$LC=0.018 9$MC=0.004 2$NC=0.0012 6 +239NP3 G OC=0.00029 15 +239NP G 631.10 3 0.067 2[E1] 0.0089217 +239NP2 G KC=0.0072 2$LC=0.00128 3$MC=0.00031 1$NC=8.26E-5 12 +239NP3 G OC=2.02E-5 3 +239NP G 662.28 2 0.170 5[E1] 0.0081516 +239NP2 G KC=0.00660 13$LC=0.001170 17$MC=0.00028 1$NC=7.52E-5 11 +239NP3 G OC=1.84E-5 3 +239NP L 695.229 23(7/2-) +239NP B 566.3 160.0118 11 1 +239NPS B EAV=168.0 5 +239NP G 522.12 100.0024 2[M1+E2] 0.14 10 +239NP2 G KC=0.11 9$LC=0.025 13$MC=0.006 3$NC=0.0017 8 +239NP3 G OC=0.00041 19 +239NP G 624.11 7 0.0062 3[E1] 0.0091 2 +239NP2 G KC=0.00737 15$LC=0.00131 3$MC=0.00031 1$NC=8.45E-5 12 +239NP3 G OC=2.06E-5 3 +239NP G 664.17 9 0.0054 4[E1] 0.0081116 +239NP2 G KC=0.00657 13$LC=0.001160 17$MC=0.00028 1$NC=7.47E-5 11 +239NP3 G OC=1.83E-5 3 +239NP G 695.23 2 0.0036 3[E1] 0.0074515 +239NP2 G KC=0.00604 13$LC=0.001060 15$MC=0.00025 1$NC=6.84E-5 10 +239NP3 G OC=1.671E-5 24 +239NP L 781.93 4 +239NP G 707.38 9 0.0022 2 +239NP L 784.94 5 +239NP G 710.35 150.003 +239NP L 819.26 3 (7/2)+ +239NP B 442.2 160.228 3 +239NPS B EAV=127.4 5 +239NP G 239.86 5 0.00087 23 +239NP G 255.37 5 0.0011 2 +239NP G 646.26 100.0029 3 +239NP G 748.09 3 0.0890 4 +239NP G 788.19 7 0.0049 2 +239NP G 819.26 3 0.129 3 +239NP L 844.10 3 (5/2,7/2)+ +239NP B 417.4 160.215 3 +239NPS B EAV=119.6 5 +239NP G 326.21 7 0.0044 2 +239NP G 772.94 9 0.0029 2 +239NP G 812.89 3 0.0685 3 +239NP G 844.10 3 0.139 3 +239NP L 849.44 9 +239NP B 412.0 160.0264 4 +239NPS B EAV=117.8 5 +239NP G 588.70 8 0.0055 3 +239NP G 607.96 150.0013 3 +239NP G 727.52 100.0026 3 +239NP G 774.77 4 0.015 4 +239NP G 849.44 9 0.0020 2 +239NP L 863.46 6 (3/2,5/2,7/2)+ +239NP B 398.1 160.0005 2 +239NPS B EAV=113.4 5 +239NP G 201.18 6 0.0005 2 +239NP L 959.18 3 +239NP B 302.3 160.0284 7 +239NPS B EAV=83.9 5 +239NP G 296.93 13 [M1+E2] 0.7 5 +239NP2 G KC=0.5 4$LC=0.13 4$MC=0.034 9 +239NP G 395.19 110.0021 2 +239NP G 841.45 4 0.0025 4 +239NP G 884.45 5 0.0086 2 +239NP G 887.97 3 0.0023 2 +239NP G 928.05 3 0.0051 2 +239NP G 959.18 3 0.0078 3 +239NP L 964.234 20(7/2-) +239NP B 297.3 160.211 3 1 +239NPS B EAV=82.4 5 +239NP G 301.95 3 0.0011 3[M1+E2] 0.6 5 +239NP2 G KC=0.5 4$LC=0.13 4$MC=0.032 9$NC=0.0087 23 +239NP3 G OC=0.0021 6 +239NP G 703.63 100.0023 2[E2] 0.0234 5 +239NP2 G KC=0.0162 3$LC=0.00537 11$MC=0.00138 3$NC=0.000374 6 +239NP3 G OC=9.00E-5 13 +239NP G 722.85 4 0.0270 7[E2] 0.0222 4 +239NP2 G KC=0.0155 3$LC=0.00499 10$MC=0.001060 18$NC=0.000347 5 +239NP3 G OC=8.35E-5 12 +239NP G 791.13 5 0.0075 2 +239NP G 846.39 4 0.0312 8[M1+E2] 0.04 3 +239NP2 G KC=0.032 21$LC=0.007 4$MC=0.0016 8 +239NP G 889.49 4 0.0209 5[M1+E2] 0.036 22 +239NP2 G KC=0.029 18$LC=0.006 3$MC=0.0014 7$NC=0.00039 19 +239NP3 G OC=0.00010 5 +239NP G 933.09 3 0.0262 6[E1] 0.00439 9 +239NP2 G KC=0.00358 7$LC=0.00061 1$MC=0.00015 1$NC=3.94E-5 6 +239NP3 G OC=9.64E-6 14 +239NP G 964.23 2 0.0905 20[E1] 0.00415 8 +239NP2 G KC=0.00338 7$LC=0.00058 1$MC=0.00014 1$NC=3.71E-5 6 +239NP3 G OC=9.08E-6 13 +239NP L 966.55 5 (7/2,9/2-) +239NP B 295.0 160.0008 2 1 +239NPS B EAV=81.7 5 +239NP G 895.15 150.0008 2 +239NP L 992.158 22(7/2-) +239NP B 269.3 160.0262 9 1 +239NPS B EAV=74.0 5 +239NP G 296.93 130.0014 2[M1+E2] 0.7 5 +239NP2 G KC=0.5 4$LC=0.13 4$MC=0.034 9$NC=0.0092 23 +239NP3 G OC=0.0022 6 +239NP G 869.57 9 0.0016 1 +239NP G 874.43 3 0.0033 2[M1+E2] 0.038 23 +239NP2 G KC=0.030 19$LC=0.006 4$MC=0.0015 8$NC=0.00041 20 +239NP3 G OC=0.00010 5 +239NP G 917.40 8 0.0027 1[M1+E2] 0.034 22 +239NP2 G KC=0.026 17$LC=0.005 3$MC=0.0013 7$NC=0.00036 18 +239NP3 G OC=0.00009 5 +239NP G 920.95 8 0.0026 1[E1] 0.00450 9 +239NP2 G KC=0.00366 6$LC=0.00063 1$MC=0.00015 1$NC=4.03E-5 6 +239NP3 G OC=9.87E-6 14 +239NP G 960.99 5 0.0105 3[E1] 0.00417 9 +239NP2 G KC=0.00340 7$LC=0.00058 1$MC=0.00014 1$NC=3.73E-5 6 +239NP3 G OC=9.14E-6 13 +239NP G 992.16 2 0.0028 1[E1] 0.00395 8 +239NP2 G KC=0.00322 7$LC=0.00055 1$MC=0.00013 1$NC=3.52E-5 5 +239NP3 G OC=8.63E-6 12 +239NP L 1013.64 8 +239NP B 247.9 160.0074 4 +239NPS B EAV=67.6 5 +239NP G 560.63 7 0.0058 3 +239NP G 752.84 8 0.0013 3 +239NP G 938.98 8 0.00031 8 +239NP L 1040.37 4 (5/2-,7/2+) +239NP B 221.1 160.0077 4 +239NPS B EAV=59.9 5 +239NP G 258.44 6 0.00073 18 +239NP G 345.13 8 0.0039 2 +239NP G 779.57 140.0006 1 +239NP G 867.11 110.00076 8 +239NP G 922.83 130.0006 1 +239NP G 1040.37 4 0.0011 1 +239NP L 1049.24 4 (9/2-) +239NP B 212.3 160.0059 4 1U +239NPS B EAV=57.3 5 +239NP G 931.51 5 0.0053 3[M1+E2] 0.032 19 +239NP2 G KC=0.026 16$LC=0.005 3$MC=0.0013 7$NC=0.00034 17 +239NP3 G OC=0.00008 5 +239NP G 974.58 4 0.00040 8[E2] 0.0123 5 +239NP2 G KC=0.00917 18$LC=0.00234 5$MC=0.00059 1$NC=3.64E-5 5 +239NP3 G OC=8.91E-6 13 +239NP L 1096.99 3 +239NP B 164.5 160.0060 5 +239NPS B EAV=43.7 5 +239NP G 312.05 3 0.0006 +239NP G 434.71 4 0.0012 2(E1) 0.0184 4 +239NP2 G KC=0.0148 3$LC=0.00276 5$MC=0.00066 1$NC=1.780E-4 25 +239NP3 G OC=4.33E-5 6 +239NP G 644.253 300.0019 4 +239NP G 1065.76 120.00059 8[M1+E2] 0.023 13 +239NP2 G KC=0.018 11$LC=0.004 2$MC=0.0009 4$NC=0.00024 12 +239NP3 G OC=0.00006 3 +239NP G 1096.99 3 0.0016 1[M1+E2] 0.022 13 +239NP2 G KC=0.017 11$LC=0.003 2$MC=0.0008 4$NC=0.00022 11 +239NP3 G OC=0.00006 3 + diff --git a/HEN_HOUSE/spectra/lnhb/Xe-127.txt b/HEN_HOUSE/spectra/lnhb/Xe-127.txt index f2f2536ec..7f4479839 100644 --- a/HEN_HOUSE/spectra/lnhb/Xe-127.txt +++ b/HEN_HOUSE/spectra/lnhb/Xe-127.txt @@ -1,57 +1,63 @@ -127I 127XE EC DECAY (36.358 D) -127I C References: 1940CR06, 1950AN05, 1954BA71, 1958F048, 1962TH12, 1964JH02, -127I 2C 1964BR26, 1965LA01, 1965WI12, 1965GE04, 1966LE09, 1966GE13, 1967SV01, -127I 3C 1967GE10, 1968KO01, 1968SC14, 1969GUZV, 1969LA08, 1969BEZH, 1970AP02, -127I 4C 1974CO05, 1975AN19, 1976LE23, 1977GE10, 1979AL14, 2002UN02, 2011HA31, -127I 5C 2012WA38, 2012FI12 -127I T Auger electrons and X ray energies and emission intensities: -127I T {U Energy (keV)} {U Intensity} {U Line} -127I T -127I T 28.3175 25.0 4 XKA2 -127I T 28.6123 46.5 8 XKA1 -127I T -127I T 32.2397 |] XKB3 -127I T 32.2951 |] 13.39 25 XKB1 -127I T 32.544 |] XKB5II -127I T -127I T 33.042 |] XKB2 -127I T 33.12 |] 3.03 9 XKB4 -127I T 33.166 |] XKO23 -127I T -127I T 3.4848-5.0595 9.60 19 XL (total) -127I T 3.4848 0.184 6 XLL -127I T 3.9269-3.9382 4.85 13 XLA -127I T 3.7791 0.0706 22 XLC -127I T 4.2212-4.5678 3.93 9 XLB -127I T 4.6668-5.0595 0.569 13 XLG -127I T -127I T 22.66-23.91 |] KLL AUGER -127I T 26.85-28.56 |] 11.8 5 KLX AUGER -127I T 30.99-33.07 |] KXY AUGER -127I T 2.4-5.1 96.4 6 L AUGER -127XE P 0.0 1/2+ 36.358 D 31 662.3 20 -127I N 1.0 1.0 1 1.0 -127I L 0 5/2+ STABLE -127I L 57.609 117/2+ 1.95 NS 1 -127I G 57.610 201.272 35M1+()E2 -0.083 5 3.72 6 -127I 2 G KC=3.16 5$LC=0.449 8$MC=0.0910 16 -127I L 202.860 8 3/2+ 0.387 NS 6 -127I E 52.7 146.61 -127I 2 E CK=0.842 8$CL=0.125 1$CM=0.0272 5$CN=0.0062 3 -127I G 145.252 104.23 7E2 0.471 7 -127I 2 G KC=0.357 5$LC=0.0906 13$MC=0.0189 3 -127I G 202.86 1 68.45 45M1+()E2 0.517 27 0.1142 18 -127I 2 G KC=0.0964 15$LC=0.0142 3$MC=0.00289 6 -127I L 374.992 9 1/2+ 31 PS 8 -127I E 47.3 76.21 -127I 2 E CK=0.830 8$CL=0.134 1$CM=0.0294 6$CN=0.0067 4 -127I G 172.132 1025.53 38M1+()E2 -0.085 6 0.1649 24 -127I 2 G KC=0.1419 20$LC=0.0185 3$MC=0.00373 6 -127I G 374.991 1217.26 27E2 0.0199 3 -127I 2 G KC=0.01671 24$LC=0.00257 4$MC=5.24E-4 8 -127I L 618.4 3 3/2+ -127I E 0.0142 97.42 -127I 2 E CK=0.31 6$CL=0.523 44$CM=0.137 12$CN=0.0324 32 -127I G 618.41 140.0141 9M1+()E2 0.081 18 0.00609 9 -127I 2 G KC=0.00528 8$LC=6.56E-4 10$MC=1316E-7 19 - +127I 127XE EC DECAY (36.358 D) +127I C References:1940CR06, 1950AN05, 1954BA71, 1958F048, 1962TH12, 1964JH02, +127I 2C 1964BR26, 1965LA01, 1965WI12, 1965GE04, 1966LE09, 1966GE13, 1967SV01, +127I 3C 1967GE10, 1968KO01, 1968SC14, 1969GUZV, 1969LA08, 1969BEZH, 1970AP02, +127I 4C 1974CO05, 1975AN19, 1976LE23, 1977GE10, 1979AL14, 2002Un02, 2011HA31, +127I 5C 2012WA38, 2012FI12, 2013RO** +127I T Auger electrons and X ray energies and emission intensities: +127I T {U Energy (keV)} {U Intensity} {U Line} +127I T +127I T 28.3175 25.0 4 XKA2 +127I T 28.6123 46.5 8 XKA1 +127I T +127I T 32.2397 |] XKB3 +127I T 32.2951 |] 13.39 25 XKB1 +127I T 32.544 |] XKB5II +127I T +127I T 33.042 |] XKB2 +127I T 33.12 |] 3.03 9 XKB4 +127I T 33.166 |] XKO23 +127I T +127I T 3.4848-5.0595 9.60 19 XL (total) +127I T 3.4848 0.184 6 XLL +127I T 3.9269-3.9382 4.85 13 XLA +127I T 3.7791 0.0706 22 XLC +127I T 4.2212-4.5678 3.93 9 XLB +127I T 4.6668-5.0595 0.569 13 XLG +127I T +127I T 22.66-23.91 |] KLL AUGER +127I T 26.85-28.56 |] 11.8 5 KLX AUGER +127I T 30.99-33.07 |] KXY AUGER +127I T 2.4-5.1 96.4 6 L AUGER +127XE P 0.0 1/2+ 36.358 D 31 662.3 20 +127I N 1.0 1.0 1 1.0 +127I L 0 5/2+ STABLE +127I L 57.609 117/2+ 1.95 NS 1 +127I G 57.610 201.272 35M1+E2 -0.083 5 3.72 6 +127I 2 G KC=3.16 5$LC=0.449 8$MC=0.0910 16$NC=0.0183 4 +127I 3 G OC=0.00209 4 +127I L 202.860 8 3/2+ 0.387 NS 6 +127I E 52.7 146.61 +127I 2 E CK=0.842 8$CL=0.125 1$CM=0.0272 5$CN=0.0062 3 +127I G 145.252 104.23 7E2 0.471 7 +127I 2 G KC=0.357 5$LC=0.0906 13$MC=0.0189 3$NC=0.00369 6 +127I 3 G OC=0.000362 5 +127I G 202.86 1 68.45 45M1+E2 0.517 27 0.1142 18 +127I 2 G KC=0.0964 15$LC=0.0142 3$MC=0.00289 6$NC=0.000579 12 +127I 3 G OC=6.49E-5 12 +127I L 374.992 9 1/2+ 31 PS 8 +127I E 47.3 76.21 +127I 2 E CK=0.830 8$CL=0.134 1$CM=0.0294 6$CN=0.0067 4 +127I G 172.132 1025.53 38M1+E2 -0.085 6 0.1649 24 +127I 2 G KC=0.1419 20$LC=0.0185 3$MC=0.00373 6$NC=0.000754 11 +127I 3 G OC=8.82E-5 13 +127I G 374.991 1217.26 27E2 0.0199 3 +127I 2 G KC=0.01671 24$LC=0.00257 4$MC=0.000524 8$NC=1.044E-4 15 +127I 3 G OC=1.144E-5 16 +127I L 618.4 3 3/2+ +127I E 0.0142 97.42 +127I 2 E CK=0.31 6$CL=0.523 44$CM=0.137 12$CN=0.0324 32 +127I G 618.41 140.0141 9M1+E2 0.081 18 0.00609 9 +127I 2 G KC=0.00528 8$LC=0.000656 10$MC=1.316E-4 19$NC=2.67E-5 4 +127I 3 G OC=3.15E-6 5 + diff --git a/HEN_HOUSE/spectra/lnhb/Xe-131m.txt b/HEN_HOUSE/spectra/lnhb/Xe-131m.txt index a090bc510..a285fb0cd 100644 --- a/HEN_HOUSE/spectra/lnhb/Xe-131m.txt +++ b/HEN_HOUSE/spectra/lnhb/Xe-131m.txt @@ -1,40 +1,39 @@ -131XE 131XE IT DECAY (11.962 D) -131XE H TYP=Full$AUT=M.M. Bé$CUT=30-NOV-2013$ -131XE2 H TYP=Full$AUT=V. Chisté$CUT=30-DEC-2002$ -131XE C Evaluation history: Type=Full;Author=M.M. Bé;Cutoff date=30-NOV-2013 -131XE2C Type=Full;Author=V. Chisté;Cutoff date=30-DEC-2002 -131XE C References: 1952Be55, 1954Be36, 1962Ge01, 1964An08, 1966Kn09, 1969fr04, -131XE2C 1972Em09, 1973Be06, 1974Me21, 1975Ho12, 1976Au08, 1990Ta02, 1994Se07, -131XE3C 1996Sc33, 2002Ba85, 2008Ki07, 2012Wa38, 2012Fi12 -131XE T Auger electrons and X ray energies and emission intensities: -131XE T {U Energy (keV)} {U Intensity} {U Line} -131XE T -131XE T 29.459 15.5 4 XKA2 -131XE T 29.779 28.7 7 XKA1 -131XE T -131XE T 33.562 |] XKB3 -131XE T 33.625 |] 8.31 22 XKB1 -131XE T 33.881 |] XKB5II -131XE T -131XE T 34.415 |] XKB2 -131XE T 34.496 |] 1.96 7 XKB4 -131XE T 34.552 |] XKO23 -131XE T -131XE T 3.64-5.3 8.12 16 XL (total) -131XE T 3.64 0.160 5 XLL -131XE T 4.1-4.11 4.20 11 XLA -131XE T 3.96 0.0537 17 XLC -131XE T 4.42-4.78 3.22 7 XLB -131XE T 4.89-5.3 0.479 10 XLG -131XE T -131XE T 23.512-24.842 |] KLL AUGER -131XE T 27.897-29.77 |] 6.9 4 KLX AUGER -131XE T 32.27-34.54 |] KXY AUGER -131XE T 2.5-5.43 75.8 5 L AUGER -131XE P 163.930 8 11/2- 11.962 D 20 -131XE N 1.0 1.0 1 1.0 -131XE L 0 3/2+ STABLE -131XE L 163.930 8 11/2- 11.962 D 20 -131XE G 163.930 8 1.942 26M4 50.5 7 -131XE2 G KC=31.6 5$LC=14.75 21$MC=3.38 5 - +131XE 131XE IT DECAY (11.962 D) +131XE H TYP=FUL$AUT=M.-M.BE$CUT=30-NOV-2013$ +131XE2 H TYP=FUL$AUT=V.CHISTE$CUT=30-DEC-2002$ +131XE C References:1952Be55, 1954Be36, 1962Ge01, 1964An08, 1966Kn09, 1969fr04, +131XE2C 1972Em09, 1973Be06, 1974Me21, 1975Ho12, 1976Au08, 1990Ta02, 1994Se07, +131XE3C 1996Sc33, 2002Ba85, 2008Ki07, 2012Wa38, 2012Fi12 +131XE T Auger electrons and X ray energies and emission intensities: +131XE T {U Energy (keV)} {U Intensity} {U Line} +131XE T +131XE T 29.459 15.5 4 XKA2 +131XE T 29.779 28.7 7 XKA1 +131XE T +131XE T 33.562 |] XKB3 +131XE T 33.625 |] 8.31 22 XKB1 +131XE T 33.881 |] XKB5II +131XE T +131XE T 34.415 |] XKB2 +131XE T 34.496 |] 1.96 7 XKB4 +131XE T 34.552 |] XKO23 +131XE T +131XE T 3.64-5.3 8.12 16 XL (total) +131XE T 3.64 0.160 5 XLL +131XE T 4.1-4.11 4.20 11 XLA +131XE T 3.96 0.0537 17 XLC +131XE T 4.42-4.78 3.22 7 XLB +131XE T 4.89-5.3 0.479 10 XLG +131XE T +131XE T 23.512-24.842 |] KLL AUGER +131XE T 27.897-29.77 |] 6.9 4 KLX AUGER +131XE T 32.27-34.54 |] KXY AUGER +131XE T 2.5-5.43 75.8 5 L AUGER +131XE P 163.930 8 11/2- 11.962 D 20 +131XE N 1.0 1.0 1 +131XE L 0 3/2+ STABLE +131XE L 163.930 8 11/2- 11.962 D 20 +131XE G 163.930 8 1.942 26M4 50.5 7 +131XE2 G KC=31.6 5$LC=14.75 21$MC=3.38 5$NC=0.691 10 +131XE3 G OC=0.0755 11 + diff --git a/HEN_HOUSE/spectra/lnhb/Xe-133.txt b/HEN_HOUSE/spectra/lnhb/Xe-133.txt index a82b12127..6a1e86b17 100644 --- a/HEN_HOUSE/spectra/lnhb/Xe-133.txt +++ b/HEN_HOUSE/spectra/lnhb/Xe-133.txt @@ -1,60 +1,64 @@ -133CS 133XE B- DECAY (5.2474 D) -133CS H TYP=Update$AUT=M.Galan$CUT= -- $ -133CS2 H TYP=Full$AUT=M.Galan$CUT=01-AUG-2007$ -133CS C Evaluation history: Type=Update;Author=M.Galan;Cutoff date= -- -133CS2C Type=Full;Author=M.Galan;Cutoff date=01-AUG-2007 -133CS C References: 1940WU05, 1941CL02, 1945WU05, 1950MA01, 1952BE55, 1953GR07, -133CS2C 1954BE36, 1955LE18, 1958AL98, 1959BO56, 1961ER04, 1962TH12, 1963GO17, -133CS3C 1965GE04, 1966TH09, 1968AL16, 1972EM01, 1974CA27, 1974FOZY, 1975HO18, -133CS4C 1975WO10, 1977KR13, 1989RA17, 1992UN01, 1992MA05, 1995RA12, 1996SC06, -133CS5C 2000HE14, 2002BA85, 2002UN02, 2003AU03 -133CS T Auger electrons and X ray energies and emission intensities: -133CS T {U Energy (keV)} {U Intensity} {U Line} -133CS T -133CS T 30.6254 13.54 24 XKA2 -133CS T 30.9731 25.0 5 XKA1 -133CS T -133CS T 34.9197 |] XKB3 -133CS T 34.9873 |] 7.31 15 XKB1 -133CS T 35.252 |] XKB5II -133CS T -133CS T 35.822 |] XKB2 -133CS T 35.907 |] 1.78 6 XKB4 -133CS T 35.972 |] XKO23 -133CS T -133CS T 3.795-5.553 5.79 11 XL (total) -133CS T 3.795 0.111 3 XLL -133CS T 4.273-4.287 2.91 8 XLA -133CS T 4.142 0.0429 13 XLC -133CS T 4.62-4.988 2.37 5 XLB -133CS T 5.131-5.553 0.359 8 XLG -133CS T -133CS T 24.411-25.804 |] KLL AUGER -133CS T 28.991-30.961 |] 5.65 24 KLX AUGER -133CS T 33.55-35.96 |] KXY AUGER -133CS T 2.5-5.6 49.9 3 L AUGER -133XE P 0.0 3/2+ 5.2474 D 5 427.4 24 -133CS N 1.0 1.0 1 1.0 -133CS L 0 0 7/2+ STABLE -133CS L 80.9979 115/2+ 6.31 NS 6 -133CS B 346.4 2499.12 8 5.62 -133CSS B EAV=100.6 8 -133CS G 80.9979 1137.0 3M1+E2 -0.151 2 1.698 24 -133CS2 G KC=1.429 20$LC=0.214 3$MC=0.0442 6 -133CS L 160.6120 165/2+ -133CS B 266.8 240.87 8 7.31 -133CSS B EAV=75.2 8 -133CS G 79.6142 120.28 3M1+E2 0.124 15 1.768 26 -133CS2 G KC=1.495 21$LC=0.217 6$MC=0.0447 12 -133CS G 160.6120 160.068 8M1+E2 0.96 5 0.294 5 -133CS2 G KC=0.234 4$LC=0.0471 13$MC=0.0099 3 -133CS L 383.8485 123/2+ -133CS B 43.6 240.0092 9 6.84 -133CSS B EAV=11.1 7 -133CS G 223.2368 130.00017 6M1+E2 -0.114 14 0.0975 14 -133CS2 G KC=0.0836 12$LC=0.01103 16$MC=0.00226 3 -133CS G 302.8508 5 0.0058 8M1+E2 0.022 20 0.0434 6 -133CS2 G KC=0.0373 5$LC=0.00484 7$MC=9.88E-4 14 -133CS G 383.8485 120.0028 4E2 0.0202 3 -133CS2 G KC=0.01684 24$LC=0.00269 4$MC=5.59E-4 8 - +133CS 133XE B- DECAY (5.2474 D) +133CS H TYP=UPD$AUT=M.GALAN$CUT=19-FEB-2008$ +133CS2 H TYP=FUL$AUT=M.GALAN$CUT=01-AUG-2007$ +133CS C References:1940WU05, 1941CL02, 1945WU05, 1950MA01, 1952BE55, 1953GR07, +133CS2C 1954BE36, 1955LE18, 1958AL98, 1959BO56, 1961ER04, 1962TH12, 1963GO17, +133CS3C 1965GE04, 1966TH09, 1968AL16, 1972EM01, 1974CA27, 1974FOZY, 1975HO18, +133CS4C 1975WO10, 1977KR13, 1989RA17, 1992UN01, 1992MA05, 1995RA12, 1996SC06, +133CS5C 2000HE14, 2002Ba85, 2002Un02, 2003Au03 +133CS T Auger electrons and X ray energies and emission intensities: +133CS T {U Energy (keV)} {U Intensity} {U Line} +133CS T +133CS T 30.6254 13.54 24 XKA2 +133CS T 30.9731 25.0 5 XKA1 +133CS T +133CS T 34.9197 |] XKB3 +133CS T 34.9873 |] 7.31 15 XKB1 +133CS T 35.252 |] XKB5II +133CS T +133CS T 35.822 |] XKB2 +133CS T 35.907 |] 1.78 6 XKB4 +133CS T 35.972 |] XKO23 +133CS T +133CS T 3.795-5.553 5.79 11 XL (total) +133CS T 3.795 0.111 3 XLL +133CS T 4.273-4.287 2.91 8 XLA +133CS T 4.142 0.0429 13 XLC +133CS T 4.62-4.988 2.37 5 XLB +133CS T 5.131-5.553 0.359 8 XLG +133CS T +133CS T 24.411-25.804 |] KLL AUGER +133CS T 28.991-30.961 |] 5.65 24 KLX AUGER +133CS T 33.55-35.96 |] KXY AUGER +133CS T 2.5-5.6 49.9 3 L AUGER +133XE P 0.0 3/2+ 5.2474 D 5 427.4 24 +133CS N 1.0 1.0 1 1.0 +133CS L 0 7/2+ STABLE +133CS L 80.9979 115/2+ 6.31 NS 6 +133CS B 346.4 2499.12 8 5.62 +133CSS B EAV=100.6 8 +133CS G 80.9979 1137.0 3M1+E2 -0.151 2 1.698 24 +133CS2 G KC=1.429 20$LC=0.214 3$MC=0.0442 6$NC=0.0093 1 +133CS3 G OC=0.00126 18 +133CS L 160.6120 165/2+ +133CS B 266.8 240.87 8 7.31 +133CSS B EAV=75.2 8 +133CS G 79.6142 120.28 3M1+E2 0.124 15 1.768 26 +133CS2 G KC=1.495 21$LC=0.217 6$MC=0.0447 12$NC=0.0094 24 +133CS3 G OC=0.00128 3 +133CS G 160.6120 160.068 8M1+E2 0.96 5 0.294 5 +133CS2 G KC=0.234 4$LC=0.0471 13$MC=0.0099 3$NC=0.00205 6 +133CS3 G OC=0.000261 7 +133CS L 383.8485 123/2+ +133CS B 43.6 240.0092 9 6.84 +133CSS B EAV=11.1 7 +133CS G 223.2368 130.00017 6M1+E2 -0.114 14 0.0975 14 +133CS2 G KC=0.0836 12$LC=0.01103 16$MC=0.00226 3$NC=0.000477 7 +133CS3 G OC=6.64E-5 9 +133CS G 302.8508 5 0.0058 8M1+E2 0.022 20 0.0434 6 +133CS2 G KC=0.0373 5$LC=0.00484 7$MC=0.000988 14$NC=2.090E-4 29 +133CS3 G OC=2.92E-5 4 +133CS G 383.8485 120.0028 4E2 0.0202 3 +133CS2 G KC=0.01684 24$LC=0.00269 4$MC=0.000559 8$NC=0.000117 2 +133CS3 G OC=1.54E-5 2 + diff --git a/HEN_HOUSE/spectra/lnhb/Xe-133m.txt b/HEN_HOUSE/spectra/lnhb/Xe-133m.txt index 7c4a5af69..f4ad2d5c8 100644 --- a/HEN_HOUSE/spectra/lnhb/Xe-133m.txt +++ b/HEN_HOUSE/spectra/lnhb/Xe-133m.txt @@ -1,38 +1,41 @@ -133XE 133XE IT DECAY (2.198 D) -133XE H TYP=Full$AUT=M.Galan$CUT= -- $ -133XE C Evaluation history: Type=Full;Author=M.Galan;Cutoff date= -- -133XE C References: 1951BE11, 1952BE55, 1954BE36, 1961ER04, 1968AL16, 1969FR09, -133XE2C 1972AC02, 1974FOZY, 1975HO18, 1976ME16, 1989RA17, 1995RA12, 1996SC06, -133XE3C 2002BA85 -133XE T Auger electrons and X ray energies and emission intensities: -133XE T {U Energy (keV)} {U Intensity} {U Line} -133XE T -133XE T 29.459 16.0 4 XKA2 -133XE T 29.779 29.7 6 XKA1 -133XE T -133XE T 33.562 |] XKB3 -133XE T 33.625 |] 8.61 20 XKB1 -133XE T 33.881 |] XKB5II -133XE T -133XE T 34.415 |] XKB2 -133XE T 34.496 |] 2.03 7 XKB4 -133XE T 34.552 |] XKO23 -133XE T -133XE T 3.638-5.296 7.6 4 XL (total) -133XE T 3.638 0.146 5 XLL -133XE T 4.098-4.11 3.84 10 XLA -133XE T 3.958 0.0530 16 XLC -133XE T 4.418-4.776 3.07 7 XLB -133XE T 4.895-5.296 0.457 10 XLG -133XE T -133XE T 23.512-24.842 |] KLL AUGER -133XE T 27.897-29.77 |] 7.1 4 KLX AUGER -133XE T 32.27-34.54 |] KXY AUGER -133XE T 2.4-5.2 70.4 10 L AUGER -133XE P 233.219 1511/2- 2.198 D 13 -133XE N 1.0 1.0 1 1.0 -133XE L 0 0 3/2+ 5.2474 D 5 -133XE L 233.219 1511/2- 2.198 D 13 -133XE G 233.219 1510.16 13M4 8.84 13 -133XE2 G KC=6.25 9$LC=2.04 3$MC=0.453 7 - +133XE 133XE IT DECAY (2.198 D) +133XE H TYP=UPD$AUT=M.GALAN$CUT=31-OCT-2016$ +133XE2 H TYP=FUL$AUT=M.GALAN$CUT=28-FEB-2007$ +133XE C References:1951BE11, 1951BE11, 1952BE55, 1952BE55, 1954BE36, 1954BE36, +133XE2C 1961ER04, 1961ER04, 1968AL16, 1968AL16, 1969FR09, 1969FR09, 1972AC02, +133XE3C 1972AC02, 1974FOZY, 1974FOZY, 1975HO18, 1975HO18, 1976ME16, 1976ME16, +133XE4C 1989RA17, 1989RA17, 1995RA12, 1995RA12, 1996SC06, 1996SC06, 2002BA85, +133XE5C 2002Ba85, 2006RA03, 2008KI07, 2012RI04 +133XE T Auger electrons and X ray energies and emission intensities: +133XE T {U Energy (keV)} {U Intensity} {U Line} +133XE T +133XE T 29.459 15.9 4 XKA2 +133XE T 29.779 29.4 7 XKA1 +133XE T +133XE T 33.562 |] XKB3 +133XE T 33.625 |] 8.54 21 XKB1 +133XE T 33.881 |] XKB5II +133XE T +133XE T 34.415 |] XKB2 +133XE T 34.496 |] 2.01 7 XKB4 +133XE T 34.552 |] XKO23 +133XE T +133XE T 3.6378-5.296 7.55 16 XL (total) +133XE T 3.6378 0.146 5 XLL +133XE T 4.0977-4.1103 3.82 11 XLA +133XE T 3.9576 0.0533 20 XLC +133XE T 4.4176-4.7758 3.07 8 XLB +133XE T 4.895-5.296 0.458 12 XLG +133XE T +133XE T 23.512-24.842 |] KLL AUGER +133XE T 27.897-29.77 |] 7.0 4 KLX AUGER +133XE T 32.27-34.54 |] KXY AUGER +133XE T 2.4-5.2 70 6 L AUGER +133XE P 233.219 1511/2- 2.198 D 13 +133XE N 1.0 1.0 1 +133XE L 0 3/2+ 5.2441 D 37 +133XE L 233.219 1511/2- 2.198 D 13 +133XE G 233.219 1510.12 14M4+E5 0.10 5 8.88 14 +133XE2 G KC=6.22 10$LC=2.08 7$MC=0.464 16$NC=0.095 3 +133XE3 G OC=0.01060 28 + diff --git a/HEN_HOUSE/spectra/lnhb/Xe-135m.txt b/HEN_HOUSE/spectra/lnhb/Xe-135m.txt index d9c46eb5b..afd1d931f 100644 --- a/HEN_HOUSE/spectra/lnhb/Xe-135m.txt +++ b/HEN_HOUSE/spectra/lnhb/Xe-135m.txt @@ -1,88 +1,87 @@ -135XE 135XE IT DECAY (15.30 M) -135XE H TYP=Full$AUT=M. Galan$CUT=30-MAY-2008$ -135XE C Evaluation history: Type=Full;Author=M. Galan;Cutoff date=30-MAY-2008 -135XE C References: 1960AL12, 1960KO02, 1968HA52, 1968AL16, 1968TO20, 1971GO40, -135XE2C 1971HA13, 1972AC02, 1974FOZY, 1974MEZV, 1975FU12, 1976FE04, 1979BO26, -135XE3C 1982WA21, 1989RA17, 1996SC06, 2002BA85, 2003AU03, 2008SI01 -135XE T Auger electrons and X ray energies and emission intensities: -135XE T {U Energy (keV)} {U Intensity} {U Line} -135XE T -135XE T 29.459 3.90 7 XKA2 -135XE T 29.779 7.22 12 XKA1 -135XE T -135XE T 33.562 |] XKB3 -135XE T 33.625 |] 2.09 4 XKB1 -135XE T 33.881 |] XKB5II -135XE T -135XE T 34.415 |] XKB2 -135XE T 34.496 |] 0.494 14 XKB4 -135XE T 34.552 |] XKO23 -135XE T -135XE T 3.638-5.296 1.637 30 XL (total) -135XE T 3.638 0.0313 9 XLL -135XE T 4.0977-4.1103 0.822 21 XLA -135XE T 3.9576 0.0120 4 XLC -135XE T 4.4176-4.7758 0.672 14 XLB -135XE T 4.895-5.296 0.0999 21 XLG -135XE T -135XE T 23.512-24.842 |] KLL AUGER -135XE T 27.897-29.77 |] 1.73 8 KLX AUGER -135XE T 32.27-34.54 |] KXY AUGER -135XE T 2.5-5.3 15.21 9 L AUGER -135XE P 526.570 5 11/2- 15.30 M 3 -135XE N 1.00E0 1.00E0 0.99996 1.00E0 -135XE L 0 3/2+ 9.14 H 2 -135XE L 526.570 5 11/2- 15.30 M 3 -135XE G 526.570 5 80.84 20M4 0.237 3 -135XE2 G KC=0.1908 27$LC=0.0364 5$MC=0.0077 1 - -135CS 135XE B- DECAY (15.30 M) -135CS H TYP=Full$AUT=M. Galan$CUT=30-MAY-2008$ -135CS C Evaluation history: Type=Full;Author=M. Galan;Cutoff date=30-MAY-2008 -135CS C References: 1960AL12, 1960KO02, 1968HA52, 1968AL16, 1968TO20, 1971GO40, -135CS2C 1971HA13, 1972AC02, 1974FOZY, 1974MEZV, 1975FU12, 1976FE04, 1979BO26, -135CS3C 1982WA21, 1989RA17, 1996SC06, 2002BA85, 2003AU03, 2008SI01 -135CS T Auger electrons and X ray energies and emission intensities: -135CS T {U Energy (keV)} {U Intensity} {U Line} -135CS T -135CS T 30.6254 XKA2 -135CS T 30.9731 XKA1 -135CS T -135CS T 34.9197 |] XKB3 -135CS T 34.9873 |] XKB1 -135CS T 35.252 |] XKB5II -135CS T -135CS T 35.822 |] XKB2 -135CS T 35.907 |] XKB4 -135CS T 35.972 |] XKO23 -135CS T -135CS T 3.7946 XLL -135CS T 4.2729-4.2866 XLA -135CS T 4.1418 XLC -135CS T 4.62-4.9881 XLB -135CS T 5.1308-5.5525 XLG -135CS T -135CS T 24.411-25.804 |] KLL AUGER -135CS T 28.991-30.961 |] KLX AUGER -135CS T 33.55-35.96 |] KXY AUGER -135CS T 2.5-5.6 L AUGER -135XE P 526.570 5 11/2- 15.30 M 3 1165.4 40 -135CS N 2.50E4 2.50E4 0.00004 2.50E4 -135CS L 0 7/2+ 2.3E6 Y 3 -135CS L 786.9 11/2+ -135CS B 905.1 400.0036 18 8.7 -135CSS B EAV=306 17 -135CS G 786.89 0.0036 18E2 -135CS L 1133 (9/2)+ -135CS B 559 4 0.00024 9.2 1 -135CSS B EAV=173.9 15 -135CS G 1133 0.00024 -135CS L 1192 (11/2)- -135CS B 500 4 0.000032 9.9 -135CSS B EAV=152.8 15 -135CS G 1192 0.000032 -135CS L 1358 + -135CS B 334 4 0.00016 8.7 -135CSS B EAV=96.4 13 -135CS G 1358 0.00016 E1 - +135XE 135XE IT DECAY (15.30 M) +135XE H TYP=FUL$AUT=M.GALAN$CUT=30-MAY-2008$ +135XE C References:1960AL12, 1960KO02, 1968HA52, 1968AL16, 1968TO20, 1971GO40, +135XE2C 1971HA13, 1972AC02, 1974FOZY, 1974MEZV, 1975FU12, 1976FE04, 1979BO26, +135XE3C 1982WA21, 1989RA17, 1996SC06, 2002Ba85, 2003Au03, 2008SI01 +135XE T Auger electrons and X ray energies and emission intensities: +135XE T {U Energy (keV)} {U Intensity} {U Line} +135XE T +135XE T 29.459 3.90 7 XKA2 +135XE T 29.779 7.22 12 XKA1 +135XE T +135XE T 33.562 |] XKB3 +135XE T 33.625 |] 2.09 4 XKB1 +135XE T 33.881 |] XKB5II +135XE T +135XE T 34.415 |] XKB2 +135XE T 34.496 |] 0.494 14 XKB4 +135XE T 34.552 |] XKO23 +135XE T +135XE T 3.638-5.296 1.637 30 XL (total) +135XE T 3.638 0.0313 9 XLL +135XE T 4.0977-4.1103 0.822 21 XLA +135XE T 3.9576 0.0120 4 XLC +135XE T 4.4176-4.7758 0.672 14 XLB +135XE T 4.895-5.296 0.0999 21 XLG +135XE T +135XE T 23.512-24.842 |] KLL AUGER +135XE T 27.897-29.77 |] 1.73 8 KLX AUGER +135XE T 32.27-34.54 |] KXY AUGER +135XE T 2.5-5.3 15.21 9 L AUGER +135XE P 526.570 5 11/2- 15.30 M 3 +135XE N 1.00E0 1.00E0 0.99996 +135XE L 0 3/2+ 9.14 H 2 +135XE L 526.570 5 11/2- 15.30 M 3 +135XE G 526.570 5 80.84 20M4 0.237 3 +135XE2 G KC=0.1908 27$LC=0.0364 5$MC=0.0077 1$NC=0.001587 22 +135XE3 G OC=1.896E-4 27 + +135CS 135XE B- DECAY (15.30 M) +135CS H TYP=FUL$AUT=M.GALAN$CUT=30-MAY-2008$ +135CS C References:1960AL12, 1960KO02, 1968HA52, 1968AL16, 1968TO20, 1971GO40, +135CS2C 1971HA13, 1972AC02, 1974FOZY, 1974MEZV, 1975FU12, 1976FE04, 1979BO26, +135CS3C 1982WA21, 1989RA17, 1996SC06, 2002Ba85, 2003Au03, 2008SI01 +135CS T Auger electrons and X ray energies and emission intensities: +135CS T {U Energy (keV)} {U Intensity} {U Line} +135CS T +135CS T 30.6254 XKA2 +135CS T 30.9731 XKA1 +135CS T +135CS T 34.9197 |] XKB3 +135CS T 34.9873 |] XKB1 +135CS T 35.252 |] XKB5II +135CS T +135CS T 35.822 |] XKB2 +135CS T 35.907 |] XKB4 +135CS T 35.972 |] XKO23 +135CS T +135CS T 3.7946 XLL +135CS T 4.2729-4.2866 XLA +135CS T 4.1418 XLC +135CS T 4.62-4.9881 XLB +135CS T 5.1308-5.5525 XLG +135CS T +135CS T 24.411-25.804 |] KLL AUGER +135CS T 28.991-30.961 |] KLX AUGER +135CS T 33.55-35.96 |] KXY AUGER +135CS T 2.5-5.6 L AUGER +135XE P 526.570 5 11/2- 15.30 M 3 1165.4 40 +135CS N 2.50E4 2.50E4 0.00004 2.50E4 +135CS L 0 7/2+ 2.3E6 Y 3 +135CS L 786.9 11/2+ +135CS B 905.1 400.0036 18 8.7 +135CSS B EAV=306 17 +135CS G 786.89 0.0036 18E2 +135CS L 1133 (9/2)+ +135CS B 559 4 0.00024 9.2 1 +135CSS B EAV=173.9 15 +135CS G 1133 0.00024 +135CS L 1192 (11/2)- +135CS B 500 4 0.000032 9.9 +135CSS B EAV=152.8 15 +135CS G 1192 0.000032 +135CS L 1358 +135CS B 334 4 0.00016 8.7 +135CSS B EAV=96.4 13 +135CS G 1358 0.00016 E1 + diff --git a/HEN_HOUSE/spectra/lnhb/Y-88.txt b/HEN_HOUSE/spectra/lnhb/Y-88.txt index 3846b4de9..5bb09a52f 100644 --- a/HEN_HOUSE/spectra/lnhb/Y-88.txt +++ b/HEN_HOUSE/spectra/lnhb/Y-88.txt @@ -1,62 +1,69 @@ - 88SR 88Y EC DECAY (106.63 D) - 88SR C References: 1940Du09, 1948Pe13, 1952Me50, 1960Ra20, 1960Pe23, 1961Wy01, - 88SR2C 1964Sh16, 1965An07, 1966Sa08, 1966Ha07, 1969Gr12, 1971Ja21, 1971Go40, - 88SR3C 1971Al06, 1973SC40, 1974BaYZ, 1974Ar12, 1974HeYW, 1975La16, 1976Bo19, - 88SR4C 1977Ko**, 1979An36, 1980Yo05, 1980Ho17, 1982HoZJ, 1982DeYX, 1983Wa26, - 88SR5C 1988Mu09, 1990Sc08, 1992Un01, 1994Ko34, 1997Ma75, 2000Sc47, 2002Ba85, - 88SR6C 2002Un02, 2004BeZR, 2005Am01, 2008Ki07, 2012Fi12, 2012Wa38, 2014Mc01, - 88SR7C 2014Un01 - 88SR T Auger electrons and X ray energies and emission intensities: - 88SR T {U Energy (keV)} {U Intensity} {U Line} - 88SR T - 88SR T 14.098 17.55 16 XKA2 - 88SR T 14.1652 33.71 26 XKA1 - 88SR T - 88SR T 15.8252 |] XKB3 - 88SR T 15.8359 |] 8.32 10 XKB1 - 88SR T 15.969 |] XKB5II - 88SR T - 88SR T 16.0847 |] XKB2 - 88SR T 16.104 |] 1.08 4 XKB4 - 88SR T - 88SR T 1.5833-2.1971 2.76 5 XL (total) - 88SR T 1.5833 0.0670 17 XLL - 88SR T 1.8054-1.8071 1.73 4 XLA - 88SR T 1.6501 0.0285 7 XLC - 88SR T 1.8722-1.9466 0.921 22 XLB - 88SR T 1.9707-2.1971 0.01489 29 XLG - 88SR T - 88SR T 11.587-12.134 |] KLL AUGER - 88SR T 13.498-14.145 |] 26.5 4 KLX AUGER - 88SR T 15.39-16.065 |] KXY AUGER - 88SR T 1.2246-2.1944 103.8 5 L AUGER - 88Y P 0.0 4- 106.63 D 5 3622.6 15 - 88SR N 1.0 1.0 1 1.0 - 88SR L 0 0+ STABLE - 88SR L 1836.090 8 2+ 0.154 PS 8 - 88SR E 0.21 15.7 39.8 1U - 88SR2 E EAV=359.5 7$CK=0.8393 3$CL=0.100085 4$CM=0.02206 8 - 88SR G 1836.070 8 99.346 25E2 1.63E-4 2 - 88SR2 G KC=1449E-7 21$LC=1550E-8 22$MC=2.60E-6 4 - 88SR L 2734.137 8 3- 0.70 PS 5 - 88SR E 94.3 36.9 - 88SR2 E CK=0.8726 15$CL=0.1046 14$CM=0.0229 6$CN=0.0030 2$CO=0 0 - 88SR G 898.042 1193.7 3E1(+M2) -0.002 9 3.07E-4 5 - 88SR2 G KC=2.73E-4 4$LC=2.92E-5 4$MC=4.89E-6 7 - 88SR G 2734.092 8 0.608 25(E3) 1.24E-4 2 - 88SR2 G KC=1098E-7 16$LC=1176E-8 17$MC=1.97E-6 3 - 88SR L 3218.489 222+ 0.154 PS 10 - 88SR E 0.023 49.5 1U - 88SR2 E CK=0.8521 2$CL=0.1209 1$CM=0.02701 3$CN=0.0031 2$CO=0 0 - 88SR G 484.352 230.0009 9[E1] 1217E-617 - 88SR2 G KC=1079E-6 16$LC=1165E-7 17$MC=1.95E-5 3 - 88SR G 1382.387 230.016 3M1+E2 0.04 2 2.88E-4 4 - 88SR2 G KC=2.55E-4 4$LC=2.73E-5 4$MC=4.58E-6 7 - 88SR G 3218.426 220.0071 20E2 6.13E-5 8 - 88SR2 G KC=5.45E-5 8$LC=5.77E-6 8$MC=9.67E-7 14 - 88SR L 3584.784 195- 0.14 NS 4 - 88SR E 0.048 187 - 88SR2 E CK=0.721 12$CL=0.225 10$CM=0.0542 25$CN=0.0072 5$CO=0 0 - 88SR G 850.643 210.048 18E2 8.53E-412 - 88SR2 G KC=7.54E-4 11$LC=8.28E-5 12$MC=1.39E-5 2 - + 88SR 88Y EC DECAY (106.63 D) + 88SR C References:1940Du09, 1948Pe13, 1952Me50, 1960Ra20, 1960Pe23, 1961Wy01, + 88SR2C 1964Sh16, 1965An07, 1966Sa08, 1966Ha07, 1969Gr12, 1971Ja21, 1971Go40, + 88SR3C 1971Al06, 1973SC40, 1974BaYZ, 1974Ar12, 1974HeYW, 1975La16, 1976Bo19, + 88SR4C 1977Ko**, 1979An36, 1980Yo05, 1980Ho17, 1982HoZJ, 1982DeYX, 1983Wa26, + 88SR5C 1988Mu09, 1990Sc08, 1992Un01, 1994Ko34, 1997Ma75, 2000Sc47, 2002Ba85, + 88SR6C 2002Un02, 2004BeZR, 2005Am01, 2008Ki07, 2012Fi12, 2012Wa38, 2014Mc01, + 88SR7C 2014Un01 + 88SR T Auger electrons and X ray energies and emission intensities: + 88SR T {U Energy (keV)} {U Intensity} {U Line} + 88SR T + 88SR T 14.098 17.55 16 XKA2 + 88SR T 14.1652 33.71 26 XKA1 + 88SR T + 88SR T 15.8252 |] XKB3 + 88SR T 15.8359 |] 8.32 10 XKB1 + 88SR T 15.969 |] XKB5II + 88SR T + 88SR T 16.0847 |] XKB2 + 88SR T 16.104 |] 1.08 4 XKB4 + 88SR T + 88SR T 1.5833-2.1971 2.76 5 XL (total) + 88SR T 1.5833 0.0670 17 XLL + 88SR T 1.8054-1.8071 1.73 4 XLA + 88SR T 1.6501 0.0285 7 XLC + 88SR T 1.8722-1.9466 0.921 22 XLB + 88SR T 1.9707-2.1971 0.01489 29 XLG + 88SR T + 88SR T 11.587-12.134 |] KLL AUGER + 88SR T 13.498-14.145 |] 26.5 4 KLX AUGER + 88SR T 15.39-16.065 |] KXY AUGER + 88SR T 1.2246-2.1944 103.8 5 L AUGER + 88Y P 0.0 4- 106.63 D 5 3622.6 15 + 88SR N 1.0 1.0 1 1.0 + 88SR L 0 0+ STABLE + 88SR L 1836.090 8 2+ 0.154 PS 8 + 88SR E 0.21 15.7 39.8 1U + 88SR2 E EAV=359.5 7$CK=0.80948 29$CL=96529E-6 4$CM=0.02128 8 + 88SR G 1836.070 8 99.346 25E2 1.63E-4 2 + 88SR2 G KC=1.449E-4 21$LC=1.550E-5 22$MC=2.60E-6 4$NC=3.27E-7 5 + 88SR3 G OC=2.15E-8 3$IPC=0.000230 4 + 88SR L 2734.137 8 3- 0.70 PS 5 + 88SR E 94.3 36.9 + 88SR2 E CK=0.8726 15$CL=0.1046 14$CM=0.0229 6$CN=0.0030 2 + 88SR G 898.042 1193.7 3E1(+M2) -0.002 9 3.07E-4 5 + 88SR2 G KC=0.000273 4$LC=2.92E-5 4$MC=4.89E-6 7$NC=6.14E-7 9 + 88SR3 G OC=4.02E-8 6 + 88SR G 2734.092 8 0.608 25(E3) 1.24E-4 2 + 88SR2 G KC=1.098E-4 16$LC=1.176E-5 17$MC=1.97E-6 3$NC=2.48E-7 4 + 88SR3 G OC=1.639E-8 23$IPC=0.000440 7 + 88SR L 3218.489 222+ 0.154 PS 10 + 88SR E 0.023 49.5 1U + 88SR2 E CK=0.8521 2$CL=0.1209 1$CM=0.02701 3$CN=0.0031 2 + 88SR G 484.352 230.0009 9[E1] 1217E-617 + 88SR2 G KC=0.001079 16$LC=1.165E-4 17$MC=1.95E-5 3$NC=2.45E-6 4 + 88SR3 G OC=1.576E-7 22 + 88SR G 1382.387 230.016 3M1+E2 0.04 2 2.88E-4 4 + 88SR2 G KC=0.000255 4$LC=2.73E-5 4$MC=4.58E-6 7$NC=5.77E-7 8 + 88SR3 G OC=3.82E-8 6$IPC=3.78E-5 6 + 88SR G 3218.426 220.0071 20E2 6.13E-5 8 + 88SR2 G KC=5.45E-5 8$LC=5.77E-6 8$MC=9.67E-7 14$NC=1.219E-7 17 + 88SR3 G OC=8.08E-9 12$IPC=0.000869 13 + 88SR L 3584.784 195- 0.14 NS 4 + 88SR E 0.048 187 + 88SR2 E CK=0.721 12$CL=0.225 10$CM=0.0542 25$CN=0.0072 5 + 88SR G 850.643 210.048 18E2 8.53E-412 + 88SR2 G KC=0.000754 11$LC=8.28E-5 12$MC=1.39E-5 2$NC=1.739E-6 25 + 88SR3 G OC=1.114E-7 16 + diff --git a/HEN_HOUSE/spectra/lnhb/Y-90.txt b/HEN_HOUSE/spectra/lnhb/Y-90.txt index 51b4e4176..534086189 100644 --- a/HEN_HOUSE/spectra/lnhb/Y-90.txt +++ b/HEN_HOUSE/spectra/lnhb/Y-90.txt @@ -1,51 +1,49 @@ - 90ZR 90Y B- DECAY (2.6684 D) - 90ZR H TYP=Update$AUT=M.M. Bé$CUT= -- $ - 90ZR2 H TYP=Update$AUT=M.M.Bé$CUT= -- $ - 90ZR3 H TYP=Full$AUT=V Chiste$CUT= -- $ - 90ZR C Evaluation history: Type=Update;Author=M.M. Bé;Cutoff date= -- - 90ZR2C Type=Update;Author=M.M.Bé;Cutoff date= -- - 90ZR3C Type=Full;Author=V Chiste;Cutoff date= -- - 90ZR C References: 1937Po04, 1937St01, 1938Sa**, 1940Sa08, 1946Bo09, 1954Ch05, - 90ZR2C 1955Sa13, 1955Vo03, 1956He77, 1957Pe09, 1958Jo33, 1961He09, 1961La07, - 90ZR3C 1961Ni02, 1962Ne02, 1963Vo02, 1964La13, 1964Da16, 1964An12, 1966Ri01, - 90ZR4C 1967Bi02, 1968La10, 1969Gr38, 1971Na09, 1972Le**, 1976Gr16, 1983Ha35, - 90ZR5C 1990Zh20, 1993Gr17, 1996Sc06, 1997Br34, 2002Ba85, 2004Ko18, 2007Se01, - 90ZR6C 2007St**, 2008Ki07, 2012Wa38 - 90ZR T Auger electrons and X ray energies and emission intensities: - 90ZR T {U Energy (keV)} {U Intensity} {U Line} - 90ZR T - 90ZR T 15.6906 XKA2 - 90ZR T 15.7749 XKA1 - 90ZR T - 90ZR T 17.6541 |] XKB3 - 90ZR T 17.6674 |] XKB1 - 90ZR T 17.8152 |] XKB5II - 90ZR T 17.818 |] XKB5I - 90ZR T - 90ZR T 17.9691 |] XKB2 - 90ZR T 18.0001 |] XKB4 - 90ZR T - 90ZR T 1.7932 XLL - 90ZR T 2.0403-2.0431 XLA - 90ZR T 1.8774 XLC - 90ZR T 2.1246-2.2252 XLB - 90ZR T 2.2579-2.5044 XLG - 90ZR T - 90ZR T 12.843-13.455 |] KLL AUGER - 90ZR T 15-15.772 |] KLX AUGER - 90ZR T 17.137-17.992 |] KXY AUGER - 90ZR T 0.04-2.5256 L AUGER - 90Y P 0.0 2- 2.6684 D 13 2278.7 16 - 90ZR N 1.0 1.0 1 1.0 - 90ZR L 0 0+ STABLE - 90ZR B 2278.7 1699.983 7 8.05 1U - 90ZRS B EAV=926.7 8 - 90ZR L 1760.72 200+ - 90ZR B 518.0 160.017 7 9.4 1U - 90ZRS B EAV=163.7 6 - 90ZR G 1760.7 2 - 90ZR L 2186.282 102+ - 90ZR B 92.4 161.4E-6 3 11.1 - 90ZRS B EAV=24.5 5 - 90ZR G 2186.254 101.4E-6 3E2 5.36E-4 8 - + 90ZR 90Y B- DECAY (2.6684 D) + 90ZR H TYP=UPD$AUT=M.-M.BE$CUT=01-FEB-2015$ + 90ZR2 H TYP=UPD$AUT=M.-M.BE$CUT=21-NOV-2006$ + 90ZR3 H TYP=FUL$AUT=V.CHISTE$CUT=09-NOV-2005$ + 90ZR C References:1937Po04, 1937St01, 1938Sa**, 1940Sa08, 1946Bo09, 1954Ch05, + 90ZR2C 1955Sa13, 1955Vo03, 1956He77, 1957Yu**, 1957Pe09, 1958Jo33, 1961He09, + 90ZR3C 1961La07, 1961Ni02, 1962Ne02, 1963Vo02, 1964La13, 1964Da16, 1964An12, + 90ZR4C 1966Ri01, 1967Bi02, 1968La10, 1969Gr38, 1971Na09, 1972Le**, 1976Gr16, + 90ZR5C 1983Ha35, 1990Zh20, 1993Gr17, 1996Sc06, 1997Br34, 2002Ba85, 2004Ko18, + 90ZR6C 2007Se01, 2007St**, 2008Ki07, 2012Wa38 + 90ZR T Auger electrons and X ray energies and emission intensities: + 90ZR T {U Energy (keV)} {U Intensity} {U Line} + 90ZR T + 90ZR T 15.6906 XKA2 + 90ZR T 15.7749 XKA1 + 90ZR T + 90ZR T 17.6541 |] XKB3 + 90ZR T 17.6674 |] XKB1 + 90ZR T 17.8152 |] XKB5II + 90ZR T 17.818 |] XKB5I + 90ZR T + 90ZR T 17.9691 |] XKB2 + 90ZR T 18.0001 |] XKB4 + 90ZR T + 90ZR T 1.7932 XLL + 90ZR T 2.0403-2.0431 XLA + 90ZR T 1.8774 XLC + 90ZR T 2.1246-2.2252 XLB + 90ZR T 2.2579-2.5044 XLG + 90ZR T + 90ZR T 12.843-13.455 |] KLL AUGER + 90ZR T 15-15.772 |] KLX AUGER + 90ZR T 17.137-17.992 |] KXY AUGER + 90ZR T 0.04-2.5256 L AUGER + 90Y P 0.0 2- 2.6684 D 13 2278.7 16 + 90ZR N 1.0 1.0 1 1.0 + 90ZR L 0 0+ STABLE + 90ZR B 2278.7 1699.983 7 8.05 1U + 90ZRS B EAV=926.7 8 + 90ZR L 1760.72 200+ + 90ZR B 518.0 160.017 7 9.4 1U + 90ZRS B EAV=163.7 6 + 90ZR G 1760.7 2 E0 + 90ZR L 2186.282 102+ + 90ZR B 92.4 161.4E-6 3 11.1 + 90ZRS B EAV=24.5 5 + 90ZR G 2186.254 101.4E-6 3E2 5.36E-4 8 + 90ZR3 G IPC=0.000397 6 + diff --git a/HEN_HOUSE/spectra/lnhb/Y-90m.txt b/HEN_HOUSE/spectra/lnhb/Y-90m.txt index d43c80553..7a4721d34 100644 --- a/HEN_HOUSE/spectra/lnhb/Y-90m.txt +++ b/HEN_HOUSE/spectra/lnhb/Y-90m.txt @@ -1,76 +1,78 @@ - 90Y 90Y IT DECAY (3.19 H) - 90Y H TYP=FULL$AUT=V Chisté$CUT= -- $ - 90Y C Evaluation history: Type=FULL;Author=V Chisté;Cutoff date= -- - 90Y T Auger electrons and X ray energies and emission intensities: - 90Y T {U Energy (keV)} {U Intensity} {U Line} - 90Y T - 90Y T 14.8829 2.02 6 XKA2 - 90Y T 14.9585 3.88 10 XKA1 - 90Y T - 90Y T 16.7259 |] XKB3 - 90Y T 16.7381 |] 0.973 27 XKB1 - 90Y T 16.88 |] XKB5II - 90Y T - 90Y T 17.0156 |] XKB2 - 90Y T 17.0362 |] 0.134 6 XKB4 - 90Y T - 90Y T 1.6865-2.3482 0.343 8 XL (total) - 90Y T 1.6865 0.00823 27 XLL - 90Y T 1.9211-1.9233 0.215 7 XLA - 90Y T 1.7617 0.00343 12 XLC - 90Y T 1.9962-2.0713 0.114 4 XLB - 90Y T 2.1118-2.3482 0.00191 4 XLG - 90Y T - 90Y T 12.205-12.784 |] KLL AUGER - 90Y T 14.238-14.956 |] 2.78 8 KLX AUGER - 90Y T 16.251-17.034 |] KXY AUGER - 90Y T 1.2-2.3 11.56 10 L AUGER - 90Y P 682.04 0 7+ 3.19 H 6 - 90Y N 1.00E0 1.00E0 0.999981 1.00E0 - 90Y L 0 2- 2.6684 D 13 - 90Y L 202.53 3 3+ 250 PS 7 - 90Y G 202.53 3 97.1 14M1+E2 -0.04 4 0.0272 8 - 90Y 2 G KC=0.0240 7$LC=0.00272 8$MC=4.65E-4 14 - 90Y L 682.04 6 7+ 3.18 H 5 - 90Y G 479.51 7 90.97 24M4(+E5) 0.0957 29 - 90Y 2 G KC=0.0818 25$LC=0.01157 35$MC=0.00202 6 - 90Y G 682.04 6 0.322 22E5 0.0225 7 - 90Y 2 G KC=0.0190 6$LC=0.00292 9$MC=5.07E-4 15 - - 90ZR 90Y B- DECAY (3.19 H) - 90ZR H TYP=FULL$AUT=V Chisté$CUT= -- $ - 90ZR C Evaluation history: Type=FULL;Author=V Chisté;Cutoff date= -- - 90ZR T Auger electrons and X ray energies and emission intensities: - 90ZR T {U Energy (keV)} {U Intensity} {U Line} - 90ZR T - 90ZR T 15.6906 1.81E-7 19 XKA2 - 90ZR T 15.7749 3.5E-7 4 XKA1 - 90ZR T - 90ZR T 17.6541 |] XKB3 - 90ZR T 17.6674 |] 8.8E-8 9 XKB1 - 90ZR T 17.8152 |] XKB5II - 90ZR T 17.818 |] XKB5I - 90ZR T - 90ZR T 17.9691 |] XKB2 - 90ZR T 18.0001 |] 1.29E-8 14 XKB4 - 90ZR T - 90ZR T 1.7932-2.5044 3.15E-8 19 XL (total) - 90ZR T 1.7932 75E-11 6 XLL - 90ZR T 2.0403-2.0431 1.99E-8 15 XLA - 90ZR T 1.8774 292E-12 29 XLC - 90ZR T 2.1246-2.2252 1.03E-8 9 XLB - 90ZR T 2.2579-2.5044 320E-12 17 XLG - 90ZR T - 90ZR T 12.843-13.455 |] KLL AUGER - 90ZR T 15-15.772 |] 2.28E-7 23 KLX AUGER - 90ZR T 17.137-17.992 |] KXY AUGER - 90ZR T 1.4-2.1 9.76E-7 27 L AUGER - 90Y P 682.04 0 7+ 3.19 H 6 2279.8 17 - 90ZR N 5.263E4 5.263E4 0.000019 5.263E4 - 90ZR L 0 0+ STABLE - 90ZR L 2318.99 2 5- 809.2 MS 20 - 90ZR B 642.9 170.0019 2 9.6 1U - 90ZRS B EAV=231.9 7 - 90ZR G 2318.958 200.0019 2E5 4.63E-414 - 90ZR2 G KC=4.08E-4 12$LC=4.63E-5 14$MC=8.04E-6 24 - + 90Y 90Y IT DECAY (3.19 H) + 90Y H TYP=FUL$AUT=V.CHISTE$CUT=09-NOV-2005$ + 90Y T Auger electrons and X ray energies and emission intensities: + 90Y T {U Energy (keV)} {U Intensity} {U Line} + 90Y T + 90Y T 14.8829 2.02 6 XKA2 + 90Y T 14.9585 3.88 10 XKA1 + 90Y T + 90Y T 16.7259 |] XKB3 + 90Y T 16.7381 |] 0.973 27 XKB1 + 90Y T 16.88 |] XKB5II + 90Y T + 90Y T 17.0156 |] XKB2 + 90Y T 17.0362 |] 0.134 6 XKB4 + 90Y T + 90Y T 1.6865-2.3482 0.343 8 XL (total) + 90Y T 1.6865 0.00823 27 XLL + 90Y T 1.9211-1.9233 0.215 7 XLA + 90Y T 1.7617 0.00343 12 XLC + 90Y T 1.9962-2.0713 0.114 4 XLB + 90Y T 2.1118-2.3482 0.00191 4 XLG + 90Y T + 90Y T 12.205-12.784 |] KLL AUGER + 90Y T 14.238-14.956 |] 2.78 8 KLX AUGER + 90Y T 16.251-17.034 |] KXY AUGER + 90Y T 1.2-2.3 11.56 10 L AUGER + 90Y P 682.04 6 7+ 3.19 H 6 + 90Y N 1.00E0 1.00E0 0.999981 + 90Y L 0 2- 2.6684 D 13 + 90Y L 202.53 3 3+ 250 PS 7 + 90Y G 202.53 3 97.1 14M1+E2 -0.04 4 0.0272 8 + 90Y 2 G KC=0.0240 7$LC=0.00272 8$MC=0.000465 14$NC=6.25E-5 19 + 90Y 3 G OC=4.30E-6 13 + 90Y L 682.04 6 7+ 3.18 H 5 + 90Y G 479.51 7 90.97 24M4(+E5) 0.0957 29 + 90Y 2 G KC=0.0818 25$LC=0.01157 35$MC=0.00202 6$NC=0.000266 8 + 90Y 3 G OC=1.643E-5 49 + 90Y G 682.04 6 0.322 22E5 0.0225 7 + 90Y 2 G KC=0.0190 6$LC=0.00292 9$MC=0.000507 15$NC=6.50E-5 19 + 90Y 3 G OC=3.38E-6 10 + + 90ZR 90Y B- DECAY (3.19 H) + 90ZR H TYP=FUL$AUT=V.CHISTE$CUT=09-NOV-2005$ + 90ZR T Auger electrons and X ray energies and emission intensities: + 90ZR T {U Energy (keV)} {U Intensity} {U Line} + 90ZR T + 90ZR T 15.6906 1.81E-7 19 XKA2 + 90ZR T 15.7749 3.5E-7 4 XKA1 + 90ZR T + 90ZR T 17.6541 |] XKB3 + 90ZR T 17.6674 |] 8.8E-8 9 XKB1 + 90ZR T 17.8152 |] XKB5II + 90ZR T 17.818 |] XKB5I + 90ZR T + 90ZR T 17.9691 |] XKB2 + 90ZR T 18.0001 |] 1.29E-8 14 XKB4 + 90ZR T + 90ZR T 1.7932-2.5044 3.15E-8 19 XL (total) + 90ZR T 1.7932 75E-11 6 XLL + 90ZR T 2.0403-2.0431 1.99E-8 15 XLA + 90ZR T 1.8774 292E-12 29 XLC + 90ZR T 2.1246-2.2252 1.03E-8 9 XLB + 90ZR T 2.2579-2.5044 320E-12 17 XLG + 90ZR T + 90ZR T 12.843-13.455 |] KLL AUGER + 90ZR T 15-15.772 |] 2.28E-7 23 KLX AUGER + 90ZR T 17.137-17.992 |] KXY AUGER + 90ZR T 1.4-2.1 9.76E-7 27 L AUGER + 90Y P 682.04 6 7+ 3.19 H 6 2279.8 17 + 90ZR N 5.263E4 5.263E4 0.000019 5.263E4 + 90ZR L 0 0+ STABLE + 90ZR L 2318.99 2 5- 809.2 MS 20 + 90ZR B 642.9 170.0019 2 9.6 1U + 90ZRS B EAV=231.9 7 + 90ZR G 2318.958 200.0019 2E5 4.63E-414 + 90ZR2 G KC=0.000408 12$LC=4.63E-5 14$MC=8.04E-6 24$NC=1.140E-6 34 + 90ZR3 G OC=7.96E-8 24 + diff --git a/HEN_HOUSE/spectra/lnhb/Yb-169.txt b/HEN_HOUSE/spectra/lnhb/Yb-169.txt index 8031110f4..4faf871c5 100644 --- a/HEN_HOUSE/spectra/lnhb/Yb-169.txt +++ b/HEN_HOUSE/spectra/lnhb/Yb-169.txt @@ -1,156 +1,166 @@ -169TM 169YB EC DECAY (32.018 D) -169TM T Auger electrons and X ray energies and emission intensities: -169TM T {U Energy (keV)} {U Intensity} {U Line} -169TM T -169TM T 49.7731 52.9 8 XKA2 -169TM T 50.7417 93.5 13 XKA1 -169TM T -169TM T 57.304 |] XKB3 -169TM T 57.516 |] 30.6 6 XKB1 -169TM T 57.925 |] XKB5II -169TM T -169TM T 59.1 |] XKB2 -169TM T 59.21 |] 7.95 21 XKB4 -169TM T 59.357 |] XKO23 -169TM T -169TM T 6.34-9.78 49.4 8 XL (total) -169TM T 6.34 0.956 25 XLL -169TM T 7.13-7.18 21.7 5 XLA -169TM T 7.31 0.437 12 XLC -169TM T 8.18-8.64 22.5 6 XLB -169TM T 9.15-9.78 3.1 1 XLG -169TM T -169TM T 38.96-41.88 |] KLL AUGER -169TM T 46.88-50.71 |] 10.8 8 KLX AUGER -169TM T 54.78-59.32 |] KXY AUGER -169TM T 3.85-7.18 168.2 18 L AUGER -169YB P 0.0 7/2+ 32.018 D 5 909 4 -169TM N 1.0 1.0 1 1.0 -169TM G 328 2 0.00672 43 -169TM G 614.1 5 0.00009714 -169TM L 0 1/2+ STABLE -169TM L 8.4102 3/2+ 4.08 NS -169TM G 8.41016 150.347 17M1+E2 273 13 -169TM2 G MC=218 11 -169TM L 118.1894 5/2+ 62 PS -169TM G 109.77924 4 17.36 9M1+E2 2.45 4 -169TM2 G KC=2.03 3$LC=0.327 5$MC=0.0730 11 -169TM G 118.18940 141.87 1E2 1.66 5 -169TM2 G KC=0.697 21$LC=0.734 22$MC=0.179 6 -169TM L 138.9331 7/2+ 302 PS -169TM G 20.74370 210.1925 43M1+E2 57.3 17 -169TM2 G LC=44.5 13$MC=10.0 3 -169TM G 130.52293 6 11.38 5E2 1.15 4 -169TM2 G KC=0.538 17$LC=0.470 15$MC=0.115 4 -169TM L 316.1463 7/2+ 660 NS -169TM E 5.1 198.33 -169TM2 E CK=0.8093 17$CL=0.1457 12$CM=0.0349 7 -169TM G 177.21307 6 22.32 10M1+E2 0.590 9 -169TM2 G KC=0.484 7$LC=0.0868 13$MC=0.0197 3 -169TM G 197.95675 7 35.93 12M1+E2 0.448 7 -169TM2 G KC=0.370 6$LC=0.0603 9$MC=0.0136 2 -169TM G 307.73757 9 10.046 45E2 0.0666 20 -169TM2 G KC=0.0482 15$LC=0.0141 4$MC=0.00333 10 -169TM G 316.2 7 0.0033 3M3+E4 -169TM L 332.119 9/2+ 18.8 PS -169TM E 0.0142 1610.9 -169TM2 E CK=0.8085 18$CL=0.1463 12$CM=0.0350 7 -169TM G 193.15 5 0.0074 10M1+E2 0.50 3 -169TM2 G KC=0.42 2$LC=0.063 5 -169TM G 213.936 170.00291 22E2 0.21 1 -169TM2 G KC=0.135 7$LC=0.072 6 -169TM L 345.031 (5/2)- -169TM E 0.0138 1311 1 -169TM2 E CK=0.8078 18$CL=0.1469 12$CM=0.0352 7 -169TM G 205.99 6 0.0034 8(E1) 0.050 2 -169TM2 G KC=0.042 2$LC=0.0020 2 -169TM G 226.3 7 0.00025 18 -169TM G 336.621 3 0.0098 9(E1) 0.0146 15 -169TM2 G KC=0.0123 13$LC=0.00179 18$MC=0.00040 4 -169TM L 367.66 11/2+ 41.6 PS -169TM G 51.51 400.0034 1E2 48.6 22 -169TM2 G LC=37.1 15$MC=9.1 4 -169TM L 379.268 7/2- 52.6 NS -169TM E 82.2 187 -169TM2 E CK=0.8057 18$CL=0.1484 12$CM=0.0356 7 -169TM G 63.12044 4 44.05 24E1+M2 1.11 4 -169TM2 G KC=0.899 27$LC=0.163 6$MC=0.0366 12 -169TM G 240.33344 120.115 5E1+M2 0.045 5 -169TM2 G KC=0.037 4$LC=0.0065 7$MC=0.0009 1 -169TM G 261.07712 9 1.687 8E1+M2 0.0283 9 -169TM2 G KC=0.0237 7$LC=0.00355 11$MC=0.00079 30 -169TM G 370.85616 290.00085 11[M2] 0.308 9 -169TM2 G KC=0.249 8$LC=0.0460 14$MC=0.0106 3 -169TM G 379.26630 250.00030 12[E3] 0.128 4 -169TM2 G KC=0.0757 23$LC=0.0401 12$MC=0.0098 3 -169TM L 430.124 (9/2)- -169TM E 0.0044 111.2 1 -169TM2 E CK=0.8020 18$CL=0.1511 13$CM=0.0364 7 -169TM G 291.190 110.00431 14[E1] 0.021 2 -169TM2 G KC=0.018 1$LC=0.0026 2 -169TM L 433.524 (9/2)+ -169TM E 0.121 149.9 -169TM2 E CK=0.8017 18$CL=0.1513 13$CM=0.0365 7 -169TM G 117.377 180.0398 36(M1+E2) 2.03 20 -169TM2 G KC=1.70 17$LC=0.257 26$MC=0.057 6 -169TM G 294.54 110.0011 5 -169TM G 425.0 2 0.00162 29 -169TM L 472.8841 9/2- 0.14 NS -169TM E 12.6 37.6 1 -169TM2 E CK=0.7980 19$CL=0.1540 13$CM=0.0372 7 -169TM G 93.61447 8 2.571 17M1+E2 3.89 12 -169TM2 G KC=3.18 10$LC=0.55 2$MC=0.124 4 -169TM G 105.19 100.0026 8[E1] 0.293 15 -169TM2 G KC=0.24 1$LC=0.039 3 -169TM G 156.73487 9 0.00990 25(E1) 0.102 3 -169TM2 G KC=0.0853 26$LC=0.0132 4$MC=0.0029 1 -169TM G 333.94777 270.00171 9E1 0.0149 15 -169TM2 G KC=0.0126 13$LC=0.00182 19$MC=0.00040 4 -169TM L 474.973 3/2- -169TM E 0.000344 712 1U -169TM G 356.74 5 0.000141 6 -169TM G 474.973 9 0.000203 9 -169TM L 570.827 3/2+ 10 PS -169TM E 0.00030 612 2 -169TM G 452.62 8 0.00003519(M1+E2) -169TM G 562.413 120.00014 4(M1+E2) -169TM G 570.89 3 0.00012726(M1+E2) -169TM L 633.296 5/2+ -169TM E 0.0109 410.3 -169TM2 E CK=0.7692 25$CL=0.1750 18$CM=0.0432 9 -169TM G 494.360 8 0.00157 12 -169TM G 515.107 6 0.00422 16(M1) 0.036 4 -169TM2 G KC=0.0306 30$LC=0.0045 5$MC=0.00099 10 -169TM G 624.886 4 0.00484 27(M1) 0.0222 22 -169TM2 G KC=0.0187 19$LC=0.0027 3$MC=0.00060 6 -169TM G 633.32 107.0E-6 5 -169TM L 646.763 (7/2)- -169TM E 0.00013 712 -169TM G 507.8 3 1.5E-6 8 -169TM G 528.572 100.00013 6 -169TM L 718.791 (7/2)+ -169TM E 0.0037 210.3 -169TM2 E CK=0.725 5$CL=0.2073 35$CM=0.0526 13 -169TM G 386.673 130.00038 4[M1E2] -169TM G 579.854 5 0.00204 16(M1) 0.027 2 -169TM2 G KC=0.023 1$LC=0.0033 3 -169TM G 600.607 8 0.00114 7(M1) -169TM G 710.358 153.13E-5 22 -169TM L 781.803 5/2+ -169TM E 0.0045 310.5 -169TM2 E CK=0.623 15$CL=0.280 11$CM=0.0743 32 -169TM G 465.657 6 0.00023124 -169TM G 642.877 9 0.000081 5 -169TM G 663.603 7 0.00203 15 -169TM G 773.390 140.00219 11 -169TM G 781.64 8 3.0E-6 3 -169TM L 832.41 (9/2)+ -169TM E 1.75E-5 511.2 -169TM G 500.35 108.8E-6 8 -169TM G 693.46 8 8.7E-6 4 -169TM L 878.35 (7/2)+ -169TM E 0.000004 110.8 -169TM G 546.16 221.5E-6 4 -169TM G 739.42 111.83E-6 22 -169TM G 760.24 248.3E-7 22 - +169TM 169YB EC DECAY (32.018 D) +169TM T Auger electrons and X ray energies and emission intensities: +169TM T {U Energy (keV)} {U Intensity} {U Line} +169TM T +169TM T 49.7731 52.9 8 XKA2 +169TM T 50.7417 93.5 13 XKA1 +169TM T +169TM T 57.304 |] XKB3 +169TM T 57.516 |] 30.6 6 XKB1 +169TM T 57.925 |] XKB5II +169TM T +169TM T 59.1 |] XKB2 +169TM T 59.21 |] 7.95 21 XKB4 +169TM T 59.357 |] XKO23 +169TM T +169TM T 6.34-9.78 49.4 8 XL (total) +169TM T 6.34 0.956 25 XLL +169TM T 7.13-7.18 21.7 5 XLA +169TM T 7.31 0.437 12 XLC +169TM T 8.18-8.64 22.5 6 XLB +169TM T 9.15-9.78 3.1 1 XLG +169TM T +169TM T 38.96-41.88 |] KLL AUGER +169TM T 46.88-50.71 |] 10.8 8 KLX AUGER +169TM T 54.78-59.32 |] KXY AUGER +169TM T 3.85-7.18 168.2 18 L AUGER +169YB P 0.0 7/2+ 32.018 D 5 909 4 +169TM N 1.0 1.0 1 1.0 +169TM G 328 2 0.00672 43 +169TM G 614.1 5 0.00009714 +169TM L 0 1/2+ STABLE +169TM L 8.4102 3/2+ 4.08 NS +169TM G 8.41016 150.347 17M1+E2 273 13 +169TM2 G MC=218 11 +169TM L 118.1894 5/2+ 62 PS +169TM G 109.77924 4 17.36 9M1+E2 2.45 4 +169TM2 G KC=2.03 3$LC=0.327 5$MC=0.0730 11 +169TM G 118.18940 141.87 1E2 1.66 5 +169TM2 G KC=0.697 21$LC=0.734 22$MC=0.179 6 +169TM L 138.9331 7/2+ 302 PS +169TM G 20.74370 210.1925 43M1+E2 57.3 17 +169TM2 G LC=44.5 13$MC=10.0 3 +169TM G 130.52293 6 11.38 5E2 1.15 4 +169TM2 G KC=0.538 17$LC=0.470 15$MC=0.115 4 +169TM L 316.1463 7/2+ 660 NS +169TM E 5.1 198.33 +169TM2 E CK=0.8093 17$CL=0.1457 12$CM=0.0349 7 +169TM G 177.21307 6 22.32 10M1+E2 0.590 9 +169TM2 G KC=0.484 7$LC=0.0868 13$MC=0.0197 3 +169TM G 197.95675 7 35.93 12M1+E2 0.448 7 +169TM2 G KC=0.370 6$LC=0.0603 9$MC=0.0136 2 +169TM G 307.73757 9 10.046 45E2 0.0666 20 +169TM2 G KC=0.0482 15$LC=0.0141 4$MC=0.00333 10 +169TM G 316.2 7 0.0033 3M3+E4 +169TM L 332.119 9/2+ 18.8 PS +169TM E 0.0142 1610.9 +169TM2 E CK=0.8085 18$CL=0.1463 12$CM=0.0350 7 +169TM G 193.15 5 0.0074 10M1+E2 0.50 3 +169TM2 G KC=0.42 2$LC=0.063 5 +169TM G 213.936 170.00291 22E2 0.21 1 +169TM2 G KC=0.135 7$LC=0.072 6 +169TM L 345.031 (5/2)- +169TM E 0.0138 1311 1 +169TM2 E CK=0.8078 18$CL=0.1469 12$CM=0.0352 7 +169TM G 205.99 6 0.0034 8(E1) 0.050 2 +169TM2 G KC=0.042 2$LC=0.0020 2 +169TM G 226.3 7 0.00025 18 +169TM G 336.621 3 0.0098 9(E1) 0.0146 15 +169TM2 G KC=0.0123 13$LC=0.00179 18$MC=0.00040 4 +169TM L 367.66 11/2+ 41.6 PS +169TM G 51.51 400.0034 1E2 48.6 22 +169TM2 G LC=37.1 15$MC=9.1 4 +169TM L 379.268 7/2- 52.6 NS +169TM E 82.2 187 +169TM2 E CK=0.8057 18$CL=0.1484 12$CM=0.0356 7 +169TM G 63.12044 4 44.05 24E1+M2 1.11 4 +169TM2 G KC=0.899 27$LC=0.163 6$MC=0.0366 12 +169TM G 240.33344 120.115 5E1+M2 0.045 5 +169TM2 G KC=0.037 4$LC=0.0065 7$MC=0.0009 1 +169TM G 261.07712 9 1.687 8E1+M2 0.0283 9 +169TM2 G KC=0.0237 7$LC=0.00355 11$MC=0.00079 30 +169TM G 370.85616 290.00085 11[M2] 0.308 9 +169TM2 G KC=0.249 8$LC=0.0460 14$MC=0.0106 3 +169TM G 379.26630 250.00030 12[E3] 0.128 4 +169TM2 G KC=0.0757 23$LC=0.0401 12$MC=0.0098 3 +169TM L 430.124 (9/2)- +169TM E 0.0044 111.2 1 +169TM2 E CK=0.8020 18$CL=0.1511 13$CM=0.0364 7 +169TM G 291.190 110.00431 14[E1] 0.021 2 +169TM2 G KC=0.018 1$LC=0.0026 2 +169TM L 433.524 (9/2)+ +169TM E 0.121 149.9 +169TM2 E CK=0.8017 18$CL=0.1513 13$CM=0.0365 7 +169TM G 117.377 180.0398 36(M1+E2) 2.03 20 +169TM2 G KC=1.70 17$LC=0.257 26$MC=0.057 6 +169TM G 294.54 110.0011 5 +169TM G 425.0 2 0.00162 29 +169TM L 472.8841 9/2- 0.14 NS +169TM E 12.6 37.6 1 +169TM2 E CK=0.7980 19$CL=0.1540 13$CM=0.0372 7 +169TM G 93.61447 8 2.571 17M1+E2 3.89 12 +169TM2 G KC=3.18 10$LC=0.55 2$MC=0.124 4 +169TM G 105.19 100.0026 8[E1] 0.293 15 +169TM2 G KC=0.24 1$LC=0.039 3 +169TM G 156.73487 9 0.00990 25(E1) 0.102 3 +169TM2 G KC=0.0853 26$LC=0.0132 4$MC=0.0029 1 +169TM G 333.94777 270.00171 9E1 0.0149 15 +169TM2 G KC=0.0126 13$LC=0.00182 19$MC=0.00040 4 +169TM L 474.973 3/2- +169TM E 0.000344 712 1U +169TM2 E CK=0.7978 19$CL=0.1541 13$CM=0.0372 7$CN=0.0094 5 +169TM3 E CO=0.0014 1 +169TM G 356.74 5 0.000141 6 +169TM G 474.973 9 0.000203 9 +169TM L 570.827 3/2+ 10 PS +169TM E 0.00030 612 2 +169TM2 E CK=0.7844 21$CL=0.1639 15$CM=0.0400 8$CN=0.0101 5 +169TM3 E CO=0.0015 1 +169TM G 452.62 8 0.00003519(M1+E2) +169TM G 562.413 120.00014 4(M1+E2) +169TM G 570.89 3 0.00012726(M1+E2) +169TM L 633.296 5/2+ +169TM E 0.0109 410.3 +169TM2 E CK=0.7692 25$CL=0.1750 18$CM=0.0432 9 +169TM G 494.360 8 0.00157 12 +169TM G 515.107 6 0.00422 16(M1) 0.036 4 +169TM2 G KC=0.0306 30$LC=0.0045 5$MC=0.00099 10 +169TM G 624.886 4 0.00484 27(M1) 0.0222 22 +169TM2 G KC=0.0187 19$LC=0.0027 3$MC=0.00060 6 +169TM G 633.32 107.0E-6 5 +169TM L 646.763 (7/2)- +169TM E 0.00013 712 +169TM2 E CK=0.7647 27$CL=0.1783 19$CM=0.0441 9$CN=0.0112 6 +169TM3 E CO=0.0017 1 +169TM G 507.8 3 1.5E-6 8 +169TM G 528.572 100.00013 6 +169TM L 718.791 (7/2)+ +169TM E 0.0037 210.3 +169TM2 E CK=0.725 5$CL=0.2073 35$CM=0.0526 13 +169TM G 386.673 130.00038 4[M1,E2] +169TM G 579.854 5 0.00204 16(M1) 0.027 2 +169TM2 G KC=0.023 1$LC=0.0033 3 +169TM G 600.607 8 0.00114 7(M1) +169TM G 710.358 153.13E-5 22 +169TM L 781.803 5/2+ +169TM E 0.0045 310.5 +169TM2 E CK=0.623 15$CL=0.280 11$CM=0.0743 32 +169TM G 465.657 6 0.00023124 +169TM G 642.877 9 0.000081 5 +169TM G 663.603 7 0.00203 15 +169TM G 773.390 140.00219 11 +169TM G 781.64 8 3.0E-6 3 +169TM L 832.41 (9/2)+ +169TM E 1.75E-5 511.2 +169TM2 E CK=0.24 8$CL=0.55 6$CM=0.160 17$CN=0.0419 49 +169TM3 E CO=0.0064 7 +169TM G 500.35 108.8E-6 8 +169TM G 693.46 8 8.7E-6 4 +169TM L 878.35 (7/2)+ +169TM E 0.000004 110.8 +169TM2 E CL=0.629 32$CM=0.279 24$CN=0.079 8 +169TM3 E CO=0.0122 12 +169TM G 546.16 221.5E-6 4 +169TM G 739.42 111.83E-6 22 +169TM G 760.24 248.3E-7 22 + diff --git a/HEN_HOUSE/spectra/lnhb/Zn-63.txt b/HEN_HOUSE/spectra/lnhb/Zn-63.txt index 5cd0178db..0f3b80514 100644 --- a/HEN_HOUSE/spectra/lnhb/Zn-63.txt +++ b/HEN_HOUSE/spectra/lnhb/Zn-63.txt @@ -1,178 +1,192 @@ - 63CU 63ZN EC DECAY (38.33 M) - 63CU H TYP=Full$AUT=A.L. Nichols$CUT=30-MAR-2013$ - 63CU C Evaluation history: Type=Full;Author=A.L. Nichols;Cutoff date=30-MAR-2013 - 63CU C References: 1938St05, 1939Bo05, 1939De01, 1947Hu20, 1948Wa13, 1959Ha10, - 63CU2C 1959Ri38, 1960Pr05, 1961Cu02, 1961Va08, 1961Ra06, 1965Pa18, 1967De08, - 63CU3C 1968Go10, 1969Bo11, 1969Bo15, 1970Ki06, 1971Go40, 1971GiZS, 1971Gi03, - 63CU4C 1972Ro21, 1972Cr02, 1974Kl02, 1974Co16, 1976Fu06, 1977La19, 1980Ku08, - 63CU5C 1982Gr10, 1995ScZY, 1996Sc06, 1998Si25, 1998ScZM, 1998Sc28, 1999ScZX, - 63CU6C 2000Sc47, 2001Ba27, 2002Le02, 2002Ba85, 2002Ra45, 2008Ki07, 2011StZZ, - 63CU7C 2012Wa38 - 63CU T Auger electrons and X ray energies and emission intensities: - 63CU T {U Energy (keV)} {U Intensity} {U Line} - 63CU T - 63CU T 8.02792 0.865 12 XKA2 - 63CU T 8.04787 1.686 22 XKA1 - 63CU T - 63CU T 8.90541 |] XKB3 - 63CU T 8.90539 |] 0.355 6 XKB1 - 63CU T 8.9771 |] XKB5II - 63CU T - 63CU T - 63CU T 0.811-1.022 0.0958 16 XL (total) - 63CU T 0.811 0.00311 8 XLL - 63CU T 0.929-0.93 0.0547 13 XLA - 63CU T 0.831 0.00186 5 XLC - 63CU T 0.949-1.022 0.0361 10 XLB - 63CU T 0.952- 0.000052 8 XLG - 63CU T - 63CU T 6.731-7.059 |] KLL AUGER - 63CU T 7.746-8.064 |] 3.50 5 KLX AUGER - 63CU T 8.739-8.982 |] KXY AUGER - 63CU T 0.68-0.8 9.30 9 L AUGER - 63ZN P 0.0 3/2- 38.33 M 10 3366.2 15 - 63CU N 1.0 1.0 1 1.0 - 63CU G 1696.6 100.002 1 - 63CU G 2181.8 7 0.0013 8 - 63CU L 0 3/2- STABLE - 63CU E 80.3 63.75 55.397 - 63CU2 E EAV=1041.9 7$CK=0.8860 16$CL=0.0971 13$CM=0.0158 5$CN=0.0010 1$CO=0 0 - 63CU L 669.93 4 1/2- - 63CU E 7.00 20.92 15.814 - 63CU2 E EAV=732.0 7$CK=0.8859 16$CL=0.0972 13$CM=0.0159 5$CN=0.0010 1 - 63CU G 669.93 4 8.19 32M1+E2 0.11 2 5.19E-4 8 - 63CU2 G KC=4.66E-4 7$LC=4.62E-5 7$MC=6.5E-6 1 - 63CU L 962.02 3 5/2- - 63CU E 4.96 131.19 35.602 - 63CU2 E EAV=599.5 7$CK=0.8858 16$CL=0.0973 13$CM=0.0159 5$CN=0.0010 1 - 63CU G 962.01 3 6.50 16M1+E2 -0.48 2 2.51E-4 4 - 63CU2 G KC=2.26E-4 4$LC=2.23E-5 4$MC=3.14E-6 5 - 63CU L 1326.76 5 7/2- - 63CU G 364.74 6 0.0115 25M1+E2 -0.060 5 0.00205 3 - 63CU2 G KC=0.00184 3$LC=1.84E-4 3$MC=2.59E-5 4 - 63CU G 1326.75 5 0.069 4E2 1757E-725 - 63CU2 G KC=1268E-7 18$LC=1251E-8 18$MC=1758E-9 25 - 63CU L 1412.16 4 5/2- - 63CU E 0.49 20.42 25.87 - 63CU2 E EAV=399.7 7$CK=0.8857 16$CL=0.0974 13$CM=0.0159 5$CN=0.0010 1 - 63CU G 450.14 5 0.229 16M1+E2 0.115 100 0.00127 5 - 63CU2 G KC=0.00114 4$LC=1.13E-4 5$MC=1.60E-5 6 - 63CU G 742.23 6 0.067 8E2 5.71E-4 8 - 63CU2 G KC=5.12E-4 8$LC=5.11E-5 8$MC=7.18E-6 10 - 63CU G 1412.14 4 0.74 3M1+E2 0.76 7 1.66E-4 3 - 63CU2 G KC=1055E-7 16$LC=1038E-8 15$MC=1460E-9 22 - 63CU L 1547.00 5 3/2- - 63CU E 0.042 40.060 76.65 - 63CU2 E EAV=341.0 7$CK=0.8856 16$CL=0.0975 13$CM=0.0159 5$CN=0.0010 1 - 63CU G 584.98 6 0.033 4M1+E2 - 63CU G 877.06 6 0.003 2M1+E2 - 63CU G 1546.98 5 0.124 5M1+E2 0.39 7 1.81E-4 3 - 63CU2 G KC=8.70E-5 13$LC=8.54E-6 13$MC=1201E-9 18 - 63CU L 1860.63 6 7/2- - 63CU G 898.60 7 0.009 3M1+E2 - 63CU G 1860.60 6 0.011 3E2 3.16E-4 5 - 63CU2 G KC=6.46E-5 9$LC=6.35E-6 9$MC=8.92E-7 13 - 63CU L 2012.92 113/2- - 63CU E 0.00039 20.0130 37.063 - 63CU2 E EAV=143.6 6$CK=0.8853 16$CL=0.0977 13$CM=0.0160 5$CN=0.0010 1 - 63CU G 1050.89 110.0044 11M1+E2 - 63CU G 1342.97 120.0025 8M1+E2 - 63CU G 2012.89 110.011 2M1+E2 - 63CU L 2062.45 8 (1/2)- - 63CU E 0.0025 20.153 135.96 - 63CU2 E EAV=123.0 6$CK=0.8853 16$CL=0.0978 13$CM=0.0160 5$CN=0.0010 1 - 63CU G 515.45 9 0.021 8(M1+E2) - 63CU G 1392.50 9 0.10 1(M1+E2) 1.0 2 1.67E-4 4 - 63CU2 G KC=1098E-7 19$LC=1080E-8 19$MC=1.52E-6 3 - 63CU G 2062.41 8 0.034 3(M1+E2) - 63CU L 2081.32 225/2- - 63CU E 0.00043 90.035 76.59 - 63CU2 E EAV=115.1 6$CK=0.8853 16$CL=0.0978 13$CM=0.0160 5$CN=0.0010 1 - 63CU G 534.32 230.005 2(M1+E2) - 63CU G 754.56 230.016 6M1+E2 - 63CU G 2081.28 220.015 2(M1+E2) - 63CU L 2092.13 107/2- - 63CU G 765.37 110.007 3M1+E2 - 63CU G 1130.10 100.013 2M1+E2 - 63CU G 2092.09 100.005 3E2 - 63CU L 2336.54 125/2- - 63CU E 0.141 95.79 - 63CU2 E CK=0.8849 16$CL=0.0980 13$CM=0.0160 5$CN=0.0010 1 - 63CU G 475.91 130.006 3M1+E2 - 63CU G 924.37 130.0099 20M1+E2 - 63CU G 1374.50 120.034 2M1+E2 - 63CU G 1666.59 130.0014 6E2 - 63CU G 2336.49 120.077 5M1+E2 - 63CU L 2497.19 9 (3/2)- - 63CU E 0.0247 206.4 - 63CU2 E CK=0.8846 16$CL=0.0983 13$CM=0.0161 5$CN=0.0010 1 - 63CU G 1827.23 100.0042 11(M1+E2) - 63CU G 2497.14 9 0.020 2(M1+E2) - 63CU L 2511.06 6 1/2,3/2,5/2- - 63CU E 0.011 26.73 - 63CU2 E CK=0.8846 16$CL=0.0983 13$CM=0.0161 5$CN=0.0010 1 - 63CU G 2511.01 6 0.011 2[M1+E2] - 63CU L 2535.83 7 (5/2)- - 63CU E 0.261 145.33 - 63CU2 E CK=0.8846 16$CL=0.0984 13$CM=0.0161 5$CN=0.0010 1 - 63CU G 443.70 120.013 4(M1+E2) 1.0 2 0.0019816 - 63CU2 G KC=0.00177 14$LC=1.79E-4 14$MC=2.51E-5 20 - 63CU G 675.20 9 0.015 3(M1+E2) - 63CU G 988.82 9 0.0038 11(M1+E2) - 63CU G 1123.66 8 0.112 11M1+E2 1.0 2 1.92E-4 4 - 63CU2 G KC=1.71E-4 4$LC=1.69E-5 4$MC=2.37E-6 5 - 63CU G 1209.06 9 0.014 3(M1+E2) - 63CU G 1573.79 8 0.016 2(M1+E2) - 63CU G 1865.87 8 0.0200 21(E2) 3.19E-4 5 - 63CU2 G KC=6.43E-5 9$LC=6.31E-6 9$MC=8.87E-7 13 - 63CU G 2535.78 7 0.067 3(M1+E2) - 63CU L 2696.66 131/2,3/2- - 63CU E 0.122 65.47 - 63CU2 E CK=0.8841 16$CL=0.0988 13$CM=0.0161 5$CN=0.0010 1 - 63CU G 683.74 170.004 2M1+E2 - 63CU G 1149.65 140.019 2M1+E2 - 63CU G 2026.70 140.060 4M1+E2 - 63CU G 2696.60 130.039 3M1+E2 - 63CU L 2716.47 9 3/2,5/2- - 63CU E 0.082 75.62 - 63CU2 E CK=0.8840 16$CL=0.0988 13$CM=0.0162 5$CN=0.0010 1 - 63CU G 624.13 130.011 4(E2) - 63CU G 1169.46 100.0077 16M1+E2 - 63CU G 1388.68 100.043 6(E2) - 63CU G 1754.42 9 0.0043 11M1+E2 - 63CU G 2046.50 100.0035 11M1+E2 - 63CU G 2716.41 9 0.012 1M1+E2 - 63CU L 2780.23 21(1/2,3/2)- - 63CU E 0.0298 215.97 - 63CU2 E CK=0.8837 16$CL=0.0991 13$CM=0.0162 5$CN=0.0010 1 - 63CU G 244.40 220.0053 8(E2) 0.0213 3 - 63CU2 G KC=0.0190 3$LC=0.00198 3$MC=2.77E-4 4 - 63CU G 1233.22 220.0025 8M1+E2 - 63CU G 2110.26 210.0065 13M1+E2 - 63CU G 2780.16 210.0154 12M1+E2 - 63CU L 2808.10 8 3/2- - 63CU E 0.0052 106.68 - 63CU2 E CK=0.8836 16$CL=0.0992 13$CM=0.0162 5$CN=0.0010 1 - 63CU G 1481.32 9 0.0016 8E2 - 63CU G 2808.03 8 0.0036 6M1+E2 - 63CU L 2857.9 3 (1/2,3/2)- - 63CU E 0.0069 126.48 - 63CU2 E CK=0.8833 16$CL=0.0994 13$CM=0.0163 5$CN=0.0010 1 - 63CU G 1445.7 3 0.0025 8(E2) - 63CU G 2188.0 3 0.0016 8M1+E2 - 63CU G 2857.8 3 0.0028 5M1+E2 - 63CU L 2888.9 4 1/2,3/2,5/2- - 63CU E 0.0104 146.24 - 63CU2 E CK=0.8831 16$CL=0.0996 13$CM=0.0163 5$CN=0.0010 1 - 63CU G 1926.9 4 0.0053 11(E2) - 63CU G 2219.0 4 0.0029 8M1+E2 - 63CU G 2888.8 4 0.0021 2M1+E2 - 63CU L 3042.59 8 (5/2)- - 63CU E 0.0048 86.24 - 63CU2 E CK=0.8814 16$CL=0.1010 13$CM=0.0166 5$CN=0.0010 1 - 63CU G 3042.51 8 0.0048 8M1+E2 - 63CU L 3101.4 4 1/2,3/2- - 63CU E 0.0007 26.89 - 63CU2 E CK=0.8802 16$CL=0.1020 13$CM=0.0168 5$CN=0.0011 1$CO=0 0 - 63CU G 3101.3 4 0.0007 2M1+E2 - + 63CU 63ZN EC DECAY (38.33 M) + 63CU H TYP=FUL$AUT=A.L.NICHOLS$CUT=30-MAR-2013$ + 63CU C References:1938St05, 1939Bo05, 1939De01, 1947Hu20, 1948Wa13, 1959Ha10, + 63CU2C 1959Ri38, 1960Pr05, 1961Cu02, 1961Va08, 1961Ra06, 1965Pa18, 1967De08, + 63CU3C 1968Go10, 1969Bo11, 1969Bo15, 1970Ki06, 1971Go40, 1971GiZS, 1971Gi03, + 63CU4C 1972Ro21, 1972Cr02, 1974Kl02, 1974Co16, 1976Fu06, 1977La19, 1980Ku08, + 63CU5C 1982Gr10, 1995ScZY, 1996Sc06, 1998Si25, 1998ScZM, 1998Sc28, 1999ScZX, + 63CU6C 2000Sc47, 2001Ba27, 2002Le02, 2002Ba85, 2002Ra45, 2008Ki07, 2011StZZ, + 63CU7C 2012Wa38 + 63CU T Auger electrons and X ray energies and emission intensities: + 63CU T {U Energy (keV)} {U Intensity} {U Line} + 63CU T + 63CU T 8.02792 0.865 12 XKA2 + 63CU T 8.04787 1.686 22 XKA1 + 63CU T + 63CU T 8.90541 |] XKB3 + 63CU T 8.90539 |] 0.355 6 XKB1 + 63CU T 8.9771 |] XKB5II + 63CU T + 63CU T + 63CU T 0.811-1.022 0.0958 16 XL (total) + 63CU T 0.811 0.00311 8 XLL + 63CU T 0.929-0.93 0.0547 13 XLA + 63CU T 0.831 0.00186 5 XLC + 63CU T 0.949-1.022 0.0361 10 XLB + 63CU T 0.952- 0.000052 8 XLG + 63CU T + 63CU T 6.731-7.059 |] KLL AUGER + 63CU T 7.746-8.064 |] 3.50 5 KLX AUGER + 63CU T 8.739-8.982 |] KXY AUGER + 63CU T 0.68-0.8 9.30 9 L AUGER + 63ZN P 0.0 3/2- 38.33 M 10 3366.2 15 + 63CU N 1.0 1.0 1 1.0 + 63CU G 1696.6 100.002 1 + 63CU G 2181.8 7 0.0013 8 + 63CU L 0 3/2- STABLE + 63CU E 80.3 63.75 55.397 + 63CU2 E EAV=1041.9 7$CK=0.03953 7$CL=0.00433 6$CM=0.000705 22 + 63CU3 E CN=4.46E-5 45 + 63CU L 669.93 4 1/2- + 63CU E 7.00 20.92 15.814 + 63CU2 E EAV=732.0 7$CK=0.10291 19$CL=0.01129 15$CM=0.00185 6 + 63CU3 E CN=0.000116 12 + 63CU G 669.93 4 8.19 32M1+E2 0.11 2 5.19E-4 8 + 63CU2 G KC=0.000466 7$LC=4.62E-5 7$MC=6.5E-6 1$NC=1.99E-7 3 + 63CU L 962.02 3 5/2- + 63CU E 4.96 131.19 35.602 + 63CU2 E EAV=599.5 7$CK=0.17140 31$CL=0.01883 25$CM=0.00308 10 + 63CU3 E CN=0.000193 19 + 63CU G 962.01 3 6.50 16M1+E2 -0.48 2 2.51E-4 4 + 63CU2 G KC=0.000226 4$LC=2.23E-5 4$MC=3.14E-6 5$NC=9.60E-8 14 + 63CU L 1326.76 5 7/2- + 63CU G 364.74 6 0.0115 25M1+E2 -0.060 5 0.00205 3 + 63CU2 G KC=0.00184 3$LC=0.000184 3$MC=2.59E-5 4$NC=7.85E-7 11 + 63CU G 1326.75 5 0.069 4E2 1757E-725 + 63CU2 G KC=1.268E-4 18$LC=1.251E-5 18$MC=1.758E-6 25$NC=5.37E-8 8 + 63CU3 G IPC=3.46E-5 5 + 63CU L 1412.16 4 5/2- + 63CU E 0.49 20.42 25.87 + 63CU2 E EAV=399.7 7$CK=0.4088 7$CL=0.0450 6$CM=0.00734 23 + 63CU3 E CN=0.000462 46 + 63CU G 450.14 5 0.229 16M1+E2 0.115 100 0.00127 5 + 63CU2 G KC=0.00114 4$LC=0.000113 5$MC=1.60E-5 6$NC=4.86E-7 17 + 63CU G 742.23 6 0.067 8E2 5.71E-4 8 + 63CU2 G KC=0.000512 8$LC=5.11E-5 8$MC=7.18E-6 10$NC=2.16E-7 3 + 63CU G 1412.14 4 0.74 3M1+E2 0.76 7 1.66E-4 3 + 63CU2 G KC=1.055E-4 16$LC=1.038E-5 15$MC=1.460E-6 22$NC=4.48E-8 7 + 63CU3 G IPC=4.82E-5 10 + 63CU L 1547.00 5 3/2- + 63CU E 0.042 40.060 76.65 + 63CU2 E EAV=341.0 7$CK=0.5209 9$CL=0.0574 8$CM=0.00935 29 + 63CU3 E CN=0.00059 6 + 63CU G 584.98 6 0.033 4M1+E2 + 63CU G 877.06 6 0.003 2M1+E2 + 63CU G 1546.98 5 0.124 5M1+E2 0.39 7 1.81E-4 3 + 63CU2 G KC=8.70E-5 13$LC=8.54E-6 13$MC=1.201E-6 18$NC=3.70E-8 6 + 63CU3 G IPC=8.44E-5 16 + 63CU L 1860.63 6 7/2- + 63CU G 898.60 7 0.009 3M1+E2 + 63CU G 1860.60 6 0.011 3E2 3.16E-4 5 + 63CU2 G KC=6.46E-5 9$LC=6.35E-6 9$MC=8.92E-7 13$NC=2.74E-8 4 + 63CU3 G IPC=0.000244 4 + 63CU L 2012.92 113/2- + 63CU E 0.00039 20.0130 37.063 + 63CU2 E EAV=143.6 6$CK=0.8595 16$CL=0.0949 13$CM=0.01553 49 + 63CU3 E CN=0.00097 10 + 63CU G 1050.89 110.0044 11M1+E2 + 63CU G 1342.97 120.0025 8M1+E2 + 63CU G 2012.89 110.011 2M1+E2 + 63CU L 2062.45 8 (1/2)- + 63CU E 0.0025 20.153 135.96 + 63CU2 E EAV=123.0 6$CK=0.8711 16$CL=0.0962 13$CM=0.01574 49 + 63CU3 E CN=0.00098 10 + 63CU G 515.45 9 0.021 8(M1+E2) + 63CU G 1392.50 9 0.10 1(M1+E2) 1.0 2 1.67E-4 4 + 63CU2 G KC=1.098E-4 19$LC=1.080E-5 19$MC=1.52E-6 3$NC=4.66E-8 8 + 63CU3 G IPC=4.51E-5 16 + 63CU G 2062.41 8 0.034 3(M1+E2) + 63CU L 2081.32 225/2- + 63CU E 0.00043 90.035 76.59 + 63CU2 E EAV=115.1 6$CK=0.8746 16$CL=0.0966 13$CM=0.01581 49 + 63CU3 E CN=0.00099 10 + 63CU G 534.32 230.005 2(M1+E2) + 63CU G 754.56 230.016 6M1+E2 + 63CU G 2081.28 220.015 2(M1+E2) + 63CU L 2092.13 107/2- + 63CU G 765.37 110.007 3M1+E2 + 63CU G 1130.10 100.013 2M1+E2 + 63CU G 2092.09 100.005 3E2 + 63CU L 2336.54 125/2- + 63CU E 0.141 95.79 + 63CU2 E CK=0.8849 16$CL=0.0980 13$CM=0.0160 5$CN=0.0010 1 + 63CU G 475.91 130.006 3M1+E2 + 63CU G 924.37 130.0099 20M1+E2 + 63CU G 1374.50 120.034 2M1+E2 + 63CU G 1666.59 130.0014 6E2 + 63CU G 2336.49 120.077 5M1+E2 + 63CU L 2497.19 9 (3/2)- + 63CU E 0.0247 206.4 + 63CU2 E CK=0.8846 16$CL=0.0983 13$CM=0.0161 5$CN=0.0010 1 + 63CU G 1827.23 100.0042 11(M1+E2) + 63CU G 2497.14 9 0.020 2(M1+E2) + 63CU L 2511.06 6 1/2,3/2,5/2- + 63CU E 0.011 26.73 + 63CU2 E CK=0.8846 16$CL=0.0983 13$CM=0.0161 5$CN=0.0010 1 + 63CU G 2511.01 6 0.011 2[M1+E2] + 63CU L 2535.83 7 (5/2)- + 63CU E 0.261 145.33 + 63CU2 E CK=0.8846 16$CL=0.0984 13$CM=0.0161 5$CN=0.0010 1 + 63CU G 443.70 120.013 4(M1+E2) 1.0 2 0.0019816 + 63CU2 G KC=0.00177 14$LC=0.000179 14$MC=2.51E-5 20$NC=7.5E-7 6 + 63CU G 675.20 9 0.015 3(M1+E2) + 63CU G 988.82 9 0.0038 11(M1+E2) + 63CU G 1123.66 8 0.112 11M1+E2 1.0 2 1.92E-4 4 + 63CU2 G KC=0.000171 4$LC=1.69E-5 4$MC=2.37E-6 5$NC=7.26E-8 15 + 63CU3 G IPC=1.41E-6 6 + 63CU G 1209.06 9 0.014 3(M1+E2) + 63CU G 1573.79 8 0.016 2(M1+E2) + 63CU G 1865.87 8 0.0200 21(E2) 3.19E-4 5 + 63CU2 G KC=6.43E-5 9$LC=6.31E-6 9$MC=8.87E-7 13$NC=2.73E-8 4 + 63CU3 G IPC=0.000247 4 + 63CU G 2535.78 7 0.067 3(M1+E2) + 63CU L 2696.66 131/2,3/2- + 63CU E 0.122 65.47 + 63CU2 E CK=0.8841 16$CL=0.0988 13$CM=0.0161 5$CN=0.0010 1 + 63CU G 683.74 170.004 2M1+E2 + 63CU G 1149.65 140.019 2M1+E2 + 63CU G 2026.70 140.060 4M1+E2 + 63CU G 2696.60 130.039 3M1+E2 + 63CU L 2716.47 9 3/2,5/2- + 63CU E 0.082 75.62 + 63CU2 E CK=0.8840 16$CL=0.0988 13$CM=0.0162 5$CN=0.0010 1 + 63CU G 624.13 130.011 4(E2) + 63CU G 1169.46 100.0077 16M1+E2 + 63CU G 1388.68 100.043 6(E2) + 63CU G 1754.42 9 0.0043 11M1+E2 + 63CU G 2046.50 100.0035 11M1+E2 + 63CU G 2716.41 9 0.012 1M1+E2 + 63CU L 2780.23 21(1/2,3/2)- + 63CU E 0.0298 215.97 + 63CU2 E CK=0.8837 16$CL=0.0991 13$CM=0.0162 5$CN=0.0010 1 + 63CU G 244.40 220.0053 8(E2) 0.0213 3 + 63CU2 G KC=0.0190 3$LC=0.00198 3$MC=0.000277 4$NC=7.77E-6 12 + 63CU G 1233.22 220.0025 8M1+E2 + 63CU G 2110.26 210.0065 13M1+E2 + 63CU G 2780.16 210.0154 12M1+E2 + 63CU L 2808.10 8 3/2- + 63CU E 0.0052 106.68 + 63CU2 E CK=0.8836 16$CL=0.0992 13$CM=0.0162 5$CN=0.0010 1 + 63CU G 1481.32 9 0.0016 8E2 + 63CU G 2808.03 8 0.0036 6M1+E2 + 63CU L 2857.9 3 (1/2,3/2)- + 63CU E 0.0069 126.48 + 63CU2 E CK=0.8833 16$CL=0.0994 13$CM=0.0163 5$CN=0.0010 1 + 63CU G 1445.7 3 0.0025 8(E2) + 63CU G 2188.0 3 0.0016 8M1+E2 + 63CU G 2857.8 3 0.0028 5M1+E2 + 63CU L 2888.9 4 1/2,3/2,5/2- + 63CU E 0.0104 146.24 + 63CU2 E CK=0.8831 16$CL=0.0996 13$CM=0.0163 5$CN=0.0010 1 + 63CU G 1926.9 4 0.0053 11(E2) + 63CU G 2219.0 4 0.0029 8M1+E2 + 63CU G 2888.8 4 0.0021 2M1+E2 + 63CU L 3042.59 8 (5/2)- + 63CU E 0.0048 86.24 + 63CU2 E CK=0.8814 16$CL=0.1010 13$CM=0.0166 5$CN=0.0010 1 + 63CU G 3042.51 8 0.0048 8M1+E2 + 63CU L 3101.4 4 1/2,3/2- + 63CU E 0.0007 26.89 + 63CU2 E CK=0.8802 16$CL=0.1020 13$CM=0.0168 5$CN=0.0011 1 + 63CU G 3101.3 4 0.0007 2M1+E2 + diff --git a/HEN_HOUSE/spectra/lnhb/Zn-65.txt b/HEN_HOUSE/spectra/lnhb/Zn-65.txt index 6bda6e638..de317d8c3 100644 --- a/HEN_HOUSE/spectra/lnhb/Zn-65.txt +++ b/HEN_HOUSE/spectra/lnhb/Zn-65.txt @@ -1,45 +1,45 @@ - 65CU 65ZN EC DECAY (244.01 D) - 65CU C References: 1953Pe14, 1953To17, 1957Wr37, 1957Ge07, 1959Gl55, 1960Ri06, - 65CU2C 1962Be28, 1963Ta19, 1963Ta04, 1965An07, 1966Ha07, 1966Ra21, 1968St05, - 65CU3C 1968Ha47, 1972Cr02, 1972De24, 1973Ra10, 1973Vi13, 1973Po10, 1974Cr05, - 65CU4C 1975La16, 1976Kr09, 1977Bo10, 1979Sc31, 1982HoZJ, 1982DeYX, 1983Wa26, - 65CU5C 1984ScZP, 1985HaZA, 1990Sc08, 1990Ku11, 1992Un01, 1993Bh04, 1995ScZY, - 65CU6C 1996Sc06, 2000He14, 2002Un02, 2002Ba85, 2003Lu06, 2003Au03, 2004Sc04, - 65CU7C 2004Va02, 2005BeZX, 2006Be34 - 65CU T Auger electrons and X ray energies and emission intensities: - 65CU T {U Energy (keV)} {U Intensity} {U Line} - 65CU T - 65CU T 8.02792 11.76 13 XKA2 - 65CU T 8.04787 22.91 22 XKA1 - 65CU T - 65CU T 8.90539 |] 4.82 7 XKB1 - 65CU T 8.9771 |] XKB5II - 65CU T - 65CU T - 65CU T 0.811-1.022 1.305 21 XL (total) - 65CU T 0.811 0.0424 11 XLL - 65CU T 0.929-0.93 0.745 16 XLA - 65CU T 0.831 0.0253 7 XLC - 65CU T 0.932-1.022 0.491 13 XLB - 65CU T 0.952-0.952 0.00070 11 XLG - 65CU T - 65CU T 6.76-7.12 |] KLL AUGER - 65CU T 7.76-8.05 |] 47.5 4 KLX AUGER - 65CU T 8.73-8.9 |] KXY AUGER - 65CU T 0.7-1 126.6 7 L AUGER - 65ZN P 0.0 5/2- 244.01 D 9 1352.1 3 - 65CU N 1.0 1.0 1 1.0 - 65CU L 0 3/2- STABLE - 65CU E 1.421 748.35 117.46 - 65CU2 E EAV=143.1 1$CK=0.8853 16$CL=0.0977 15$CM=0.017 - 65CU L 770.64 9 1/2- 0.099 PS 5 - 65CU G 770.64 9 0.00269 22M1+E2 0.096 7 3.84E-412 - 65CU2 G KC=3.45E-4 10$LC=3.43E-5 10 - 65CU L 1115.556 4 5/2- 0.285 PS 9 - 65CU E 50.23 115.89 - 65CU2 E CK=0.8794 17$CL=0.1027 16$CM=0.0179 - 65CU G 344.95 200.00254 18[E2] 0.0062019 - 65CU2 G KC=0.00555 17$LC=5.69E-4 19 - 65CU G 1115.539 2 50.22 11M1+E2 -0.437 15 1.84E-4 7 - 65CU2 G KC=1.66E-4 6$LC=1.62E-5 5 - + 65CU 65ZN EC DECAY (244.01 D) + 65CU C References:1953Pe14, 1953To17, 1957Wr37, 1957Ge07, 1959Gl55, 1960Ri06, + 65CU2C 1962Be28, 1963Ta19, 1963Ta04, 1965An07, 1966Ha07, 1966Ra21, 1968St05, + 65CU3C 1968Ha47, 1972Cr02, 1972De24, 1973Ra10, 1973Vi13, 1973Po10, 1974Cr05, + 65CU4C 1975La16, 1976Kr09, 1977Bo10, 1979Sc31, 1982HoZJ, 1982DeYX, 1983Wa26, + 65CU5C 1984ScZP, 1985HaZA, 1990Sc08, 1990Ku11, 1992Un01, 1993Bh04, 1995ScZY, + 65CU6C 1996Sc06, 2000He14, 2002Un02, 2002Ba85, 2003Lu06, 2003Au03, 2004Sc04, + 65CU7C 2004Va02, 2005BeZX, 2006Be34 + 65CU T Auger electrons and X ray energies and emission intensities: + 65CU T {U Energy (keV)} {U Intensity} {U Line} + 65CU T + 65CU T 8.02792 11.76 13 XKA2 + 65CU T 8.04787 22.91 22 XKA1 + 65CU T + 65CU T 8.90539 |] 4.82 7 XKB1 + 65CU T 8.9771 |] XKB5II + 65CU T + 65CU T + 65CU T 0.811-1.022 1.305 21 XL (total) + 65CU T 0.811 0.0424 11 XLL + 65CU T 0.929-0.93 0.745 16 XLA + 65CU T 0.831 0.0253 7 XLC + 65CU T 0.932-1.022 0.491 13 XLB + 65CU T 0.952-0.952 0.00070 11 XLG + 65CU T + 65CU T 6.76-7.12 |] KLL AUGER + 65CU T 7.76-8.05 |] 47.5 4 KLX AUGER + 65CU T 8.73-8.9 |] KXY AUGER + 65CU T 0.7-1 126.6 7 L AUGER + 65ZN P 0.0 5/2- 244.01 D 9 1352.1 3 + 65CU N 1.0 1.0 1 1.0 + 65CU L 0 3/2- STABLE + 65CU E 1.421 748.35 117.46 + 65CU2 E EAV=143.1 1$CK=0.8600 16$CL=0.0949 15$CM=16515E-6 + 65CU L 770.64 9 1/2- 0.099 PS 5 + 65CU G 770.64 9 0.00269 22M1+E2 0.096 7 3.84E-412 + 65CU2 G KC=0.000345 10$LC=3.43E-5 10 + 65CU L 1115.556 4 5/2- 0.285 PS 9 + 65CU E 50.23 115.89 + 65CU2 E CK=0.8794 17$CL=0.1027 16$CM=0.0179 + 65CU G 344.95 200.00254 18[E2] 0.0062019 + 65CU2 G KC=0.00555 17$LC=0.000569 19 + 65CU G 1115.539 2 50.22 11M1+E2 -0.437 15 1.84E-4 7 + 65CU2 G KC=0.000166 6$LC=1.62E-5 5 + diff --git a/HEN_HOUSE/spectra/lnhb/Zr-89.txt b/HEN_HOUSE/spectra/lnhb/Zr-89.txt index 82a20a349..92aa7398c 100644 --- a/HEN_HOUSE/spectra/lnhb/Zr-89.txt +++ b/HEN_HOUSE/spectra/lnhb/Zr-89.txt @@ -1,62 +1,64 @@ - 89Y 89ZR EC DECAY (78.42 H) - 89Y H TYP=FUL$AUT=A.L. Nichols$CUT=31-MAY-2014$ - 89Y C Evaluation history: Type=FUL;Author=A.L. Nichols;Cutoff date=31-MAY-2014 - 89Y C References: 1938Sa01, 1940Du05, 1940Sa08, 1951Go42, 1951Hy24, 1951Sh24, - 89Y 2C 1951Sh89, 1953Ka11, 1953Sh48, 1955Sw92, 1957Ku57, 1960Ha26, 1961Mo12, - 89Y 3C 1961Ra06, 1962Br42, 1962Ho10, 1964Aw02, 1964Va03, 1966Du07, 1967Yu01, - 89Y 4C 1968Bo52, 1968Dr02, 1968Hi10, 1968Hi12, 1969GuZV, 1969Ro02, 1970Ga03, - 89Y 5C 1971Go40, 1971Ar18, 1973Le13, 1973BeYD, 1974HeYW, 1977La19, 1977Ba48, - 89Y 6C 1977Ba48, 1979Ba46, 1984Sk01, 1984HaZC, 1985HaZI, 1992KaZM, 1992Fu04, - 89Y 7C 1995ItZY, 1995ScZY, 1996Sc06, 1996Sc06, 1997La20, 1998ScZM, 1998Sc28, - 89Y 8C 1999ScZX, 2000Sc47, 2002Ba85, 2002Ra45, 2003Au03, 2008Ki07, 2012Wa38, - 89Y 9C 2013Si03 - 89Y T Auger electrons and X ray energies and emission intensities: - 89Y T {U Energy (keV)} {U Intensity} {U Line} - 89Y T - 89Y T 14.8829 14.08 13 XKA2 - 89Y T 14.9585 27.01 20 XKA1 - 89Y T - 89Y T 16.7259 |] XKB3 - 89Y T 16.7381 |] 6.78 8 XKB1 - 89Y T 16.88 |] XKB5II - 89Y T - 89Y T 17.0156 |] XKB2 - 89Y T 17.0362 |] 0.94 4 XKB4 - 89Y T - 89Y T 1.686-2.347 2.36 5 XL (total) - 89Y T 1.686 0.0568 15 XLL - 89Y T 1.92-1.923 1.48 4 XLA - 89Y T 1.762 0.0234 7 XLC - 89Y T 1.996-2.078 0.778 19 XLB - 89Y T 2.153-2.347 0.01331 24 XLG - 89Y T - 89Y T 12.205-12.784 |] KLL AUGER - 89Y T 14.238-14.956 |] 19.4 3 KLX AUGER - 89Y T 16.251-17.034 |] KXY AUGER - 89Y T 1.27-1.89 79.5 7 L AUGER - 89ZR P 0.0 9/2+ 78.42 H 13 2832.8 28 - 89Y N 1.0 1.0 1 1.0 - 89Y L 0 1/2- STABLE - 89Y L 908.97 3 9/2+ 15.84 S 18 - 89Y E 22.8 376.2 36.152 - 89Y 2 E EAV=395.7 14$CK=0.8731 15$CL=0.1041 12$CM=0.0196 4$CN=0.0032 2 - 89Y G 908.97 3 99.03 2M4 0.0085112 - 89Y 2 G KC=0.00743 11$LC=9.06E-4 13$MC=1561E-7 22 - 89Y L 1744.74 185/2- 0.62 PS 14 - 89Y E 0.123 49.09 1U - 89Y 2 E CK=0.8677 15$CL=0.1082 12$CM=0.0208 4$CN=0.0033 2 - 89Y G 1744.72 180.123 4E2 3.82E-4 6 - 89Y 2 G KC=1722E-7 25$LC=1.86E-5 3$MC=3.17E-6 5 - 89Y L 2529.8 2 7/2+ 0.08 PS 3 - 89Y E 0.074 57.52 - 89Y 2 E CK=0.8632 16$CL=0.1120 13$CM=0.0213 4$CN=0.0035 2 - 89Y G 1620.81 200.074 5M1+E2 - 89Y L 2566.55 1511/2+ - 89Y E 0.106 57.25 - 89Y 2 E CK=0.8615 16$CL=0.1134 13$CM=0.0216 5$CN=0.0035 2 - 89Y G 1657.56 150.106 5M1+E2 - 89Y L 2622.1 3 9/2+ 0.21 PS 10 - 89Y E 0.745 106.18 - 89Y 2 E CK=0.8575 17$CL=0.1165 13$CM=0.0223 5$CN=0.0036 2 - 89Y G 1713.1 3 0.745 10M1+E2 - + 89Y 89ZR EC DECAY (78.42 H) + 89Y H TYP=FUL$AUT=A.L.NICHOLS$CUT=31-MAY-2014$ + 89Y C References:1938Sa01, 1940Du05, 1940Sa08, 1951Go42, 1951Hy24, 1951Sh24, + 89Y 2C 1951Sh89, 1953Ka11, 1953Sh48, 1955Sw92, 1957Ku57, 1960Ha26, 1961Mo12, + 89Y 3C 1961Ra06, 1962Br42, 1962Ho10, 1964Aw02, 1964Va03, 1966Du07, 1967Yu01, + 89Y 4C 1968Bo52, 1968Dr02, 1968Hi10, 1968Hi12, 1969GuZV, 1969Ro02, 1970Ga03, + 89Y 5C 1971Go40, 1971Ar18, 1973Le13, 1973BeYD, 1974HeYW, 1977La19, 1977Ba48, + 89Y 6C 1977Ba48, 1979Ba46, 1984Sk01, 1984HaZC, 1985HaZI, 1992KaZM, 1992Fu04, + 89Y 7C 1995ItZY, 1995ScZY, 1996Sc06, 1996Sc06, 1997La20, 1998ScZM, 1998Sc28, + 89Y 8C 1999ScZX, 2000Sc47, 2002Ba85, 2002Ra45, 2003Au03, 2008Ki07, 2012Wa38, + 89Y 9C 2013Si03 + 89Y T Auger electrons and X ray energies and emission intensities: + 89Y T {U Energy (keV)} {U Intensity} {U Line} + 89Y T + 89Y T 14.8829 14.08 13 XKA2 + 89Y T 14.9585 27.01 20 XKA1 + 89Y T + 89Y T 16.7259 |] XKB3 + 89Y T 16.7381 |] 6.78 8 XKB1 + 89Y T 16.88 |] XKB5II + 89Y T + 89Y T 17.0156 |] XKB2 + 89Y T 17.0362 |] 0.94 4 XKB4 + 89Y T + 89Y T 1.686-2.347 2.36 5 XL (total) + 89Y T 1.686 0.0568 15 XLL + 89Y T 1.92-1.923 1.48 4 XLA + 89Y T 1.762 0.0234 7 XLC + 89Y T 1.996-2.078 0.778 19 XLB + 89Y T 2.153-2.347 0.01331 24 XLG + 89Y T + 89Y T 12.205-12.784 |] KLL AUGER + 89Y T 14.238-14.956 |] 19.4 3 KLX AUGER + 89Y T 16.251-17.034 |] KXY AUGER + 89Y T 1.27-1.89 79.5 7 L AUGER + 89ZR P 0.0 9/2+ 78.42 H 13 2832.8 28 + 89Y N 1.0 1.0 1 1.0 + 89Y L 0 1/2- STABLE + 89Y L 908.97 3 9/2+ 15.84 S 18 + 89Y E 22.8 376.2 36.152 + 89Y 2 E EAV=395.7 14$CK=0.6720 12$CL=0.0801 9$CM=0.01509 31 + 89Y 3 E CN=0.00246 15 + 89Y G 908.97 3 99.03 2M4 0.0085112 + 89Y 2 G KC=0.00743 11$LC=0.000906 13$MC=1.561E-4 22$NC=2.09E-5 3 + 89Y 3 G OC=1.394E-6 20 + 89Y L 1744.74 185/2- 0.62 PS 14 + 89Y E 0.123 49.09 1U + 89Y 2 E CK=0.8677 15$CL=0.1082 12$CM=0.0208 4$CN=0.0033 2 + 89Y G 1744.72 180.123 4E2 3.82E-4 6 + 89Y 2 G KC=1.722E-4 25$LC=1.86E-5 3$MC=3.17E-6 5$NC=4.27E-7 6 + 89Y 3 G OC=3.01E-8 5$IPC=0.000188 3 + 89Y L 2529.8 2 7/2+ 0.08 PS 3 + 89Y E 0.074 57.52 + 89Y 2 E CK=0.8632 16$CL=0.1120 13$CM=0.0213 4$CN=0.0035 2 + 89Y G 1620.81 200.074 5M1+E2 + 89Y L 2566.55 1511/2+ + 89Y E 0.106 57.25 + 89Y 2 E CK=0.8615 16$CL=0.1134 13$CM=0.0216 5$CN=0.0035 2 + 89Y G 1657.56 150.106 5M1+E2 + 89Y L 2622.1 3 9/2+ 0.21 PS 10 + 89Y E 0.745 106.18 + 89Y 2 E CK=0.8575 17$CL=0.1165 13$CM=0.0223 5$CN=0.0036 2 + 89Y G 1713.1 3 0.745 10M1+E2 + diff --git a/HEN_HOUSE/spectra/lnhb/Zr-93.txt b/HEN_HOUSE/spectra/lnhb/Zr-93.txt index a84e3d8ca..afbaf08a5 100644 --- a/HEN_HOUSE/spectra/lnhb/Zr-93.txt +++ b/HEN_HOUSE/spectra/lnhb/Zr-93.txt @@ -1,40 +1,40 @@ - 93NB 93ZR B- DECAY (1.61E6 Y) - 93NB H TYP=Full$AUT=M.A. Kellett$CUT=17-SEP-2013$ - 93NB C Evaluation history: Type=Full;Author=M.A. Kellett;Cutoff date=17-SEP-2013 - 93NB C References: 1950St90, 1952Gl**, 1953Gl31, 1972FlZM, 2004BeZQ, 2008DuZX, - 93NB2C 2010Ca01, 2010Ya01, 2012Wa38 - 93NB T Auger electrons and X ray energies and emission intensities: - 93NB T {U Energy (keV)} {U Intensity} {U Line} - 93NB T - 93NB T 16.5213 2.41 18 XKA2 - 93NB T 16.6152 4.6 4 XKA1 - 93NB T - 93NB T 18.607 |] XKB3 - 93NB T 18.623 |] 1.19 9 XKB1 - 93NB T 18.78 |] XKB5II - 93NB T - 93NB T 18.953 |] XKB2 - 93NB T 18.981 |] 0.179 15 XKB4 - 93NB T - 93NB T 1.9-2.67 2.1 1 XL (total) - 93NB T 1.9 0.063 4 XLL - 93NB T 2.16-2.17 1.69 9 XLA - 93NB T 2 0.0064 4 XLC - 93NB T 2.26-2.49 0.325 13 XLB - 93NB T 2.41-2.67 0.0172 6 XLG - 93NB T - 93NB T 13.49-14.14 |] KLL AUGER - 93NB T 15.78-16.61 |] 2.78 21 KLX AUGER - 93NB T 18.05-18.98 |] KXY AUGER - 93NB T 1.4-2.7 59.1 4 L AUGER - 93ZR P 0.0 5/2+ 1.61E6 Y 6 90.3 15 - 93NB N 1.0 1.0 1 1.0 - 93NB L 0 9/2+ STABLE - 93NB B 90.3 1527 5 12.09 2 - 93NBS B EAV=23.64 42 - 93NB L 30.77 2 1/2- 16.12 Y 15 - 93NB B 59.5 1573 5 10.16 1U - 93NBS B EAV=18.75 54 - 93NB G 30.77 2 0.00043 3M4 1.693E525 - 93NB2 G KC=2.60E4 4$LC=1.151E5 17$MC=2.49E4 4 - + 93NB 93ZR B- DECAY (1.61E6 Y) + 93NB H TYP=FUL$AUT=M.A.KELLETT$CUT=17-SEP-2013$ + 93NB C References:1950St90, 1952Gl**, 1953Gl31, 1972FlZM, 2004BeZQ, 2008DuZX, + 93NB2C 2010Ca01, 2010Ya01, 2012Wa38 + 93NB T Auger electrons and X ray energies and emission intensities: + 93NB T {U Energy (keV)} {U Intensity} {U Line} + 93NB T + 93NB T 16.5213 2.41 18 XKA2 + 93NB T 16.6152 4.6 4 XKA1 + 93NB T + 93NB T 18.607 |] XKB3 + 93NB T 18.623 |] 1.19 9 XKB1 + 93NB T 18.78 |] XKB5II + 93NB T + 93NB T 18.953 |] XKB2 + 93NB T 18.981 |] 0.179 15 XKB4 + 93NB T + 93NB T 1.9-2.67 2.1 1 XL (total) + 93NB T 1.9 0.063 4 XLL + 93NB T 2.16-2.17 1.69 9 XLA + 93NB T 2 0.0064 4 XLC + 93NB T 2.26-2.49 0.325 13 XLB + 93NB T 2.41-2.67 0.0172 6 XLG + 93NB T + 93NB T 13.49-14.14 |] KLL AUGER + 93NB T 15.78-16.61 |] 2.78 21 KLX AUGER + 93NB T 18.05-18.98 |] KXY AUGER + 93NB T 1.4-2.7 59.1 4 L AUGER + 93ZR P 0.0 5/2+ 1.61E6 Y 6 90.3 15 + 93NB N 1.0 1.0 1 1.0 + 93NB L 0 9/2+ STABLE + 93NB B 90.3 1527 5 12.09 2 + 93NBS B EAV=23.64 42 + 93NB L 30.77 2 1/2- 16.12 Y 15 + 93NB B 59.5 1573 5 10.16 1U + 93NBS B EAV=18.75 54 + 93NB G 30.77 2 0.00043 3M4 1.693E525 + 93NB2 G KC=2.60E4 4$LC=1.151E5 17$MC=2.49E4 4$NC=3230 50 + 93NB3 G OC=48.2 7 + diff --git a/HEN_HOUSE/spectra/lnhb/Zr-95.txt b/HEN_HOUSE/spectra/lnhb/Zr-95.txt index 694491808..8a9e2edc3 100644 --- a/HEN_HOUSE/spectra/lnhb/Zr-95.txt +++ b/HEN_HOUSE/spectra/lnhb/Zr-95.txt @@ -1,44 +1,42 @@ - 95NB 95ZR B- DECAY (64.032 D) - 95NB H TYP=update$AUT=M.M. Bé$CUT= -- $ - 95NB2 H TYP=Full$AUT=R.G.Helmer$CUT= -- $ - 95NB C Evaluation history: Type=update;Author=M.M. Bé;Cutoff date= -- - 95NB2C Type=Full;Author=R.G.Helmer;Cutoff date= -- - 95NB T Auger electrons and X ray energies and emission intensities: - 95NB T {U Energy (keV)} {U Intensity} {U Line} - 95NB T - 95NB T 16.5213 0.167 11 XKA2 - 95NB T 16.6152 0.319 20 XKA1 - 95NB T - 95NB T 18.6065 |] XKB3 - 95NB T 18.6227 |] 0.082 6 XKB1 - 95NB T 18.78 |] XKB5II - 95NB T - 95NB T 18.953 |] XKB2 - 95NB T 18.981 |] 0.0124 9 XKB4 - 95NB T - 95NB T - 95NB T 13.49-14.14 |] KLL AUGER - 95NB T 15.79-16.58 |] 0.192 13 KLX AUGER - 95NB T 18.02-18.91 |] KXY AUGER - 95NB T 1.4-2.6 0.92 5 L AUGER - 95ZR P 0.0 5/2+ 64.032 D 6 1124.8 19 - 95NB N 1.0 1.0 1 1.0 - 95NB L 0 9/2+ 34.991 D 6 - 95NB B 1124.8 190.10 3 11.22 2 - 95NBS B EAV=406.0 8 - 95NB L 235.69 2 1/2- 3.61 D 3 - 95NB B 889.1 191.08 7 10.28 1U - 95NBS B EAV=327.6 8 - 95NB G 235.69 2 0.27 2M4 2.88 9 - 95NB2 G KC=2.31 8$LC=0.468 14$MC=0.1 - 95NB L 724.195 4 7/2+ - 95NB B 400.6 1944.34 22 6.98 - 95NBS B EAV=120.9 7 - 95NB G 724.193 3 44.27 22M1+E2 0.00157 5 - 95NB2 G KC=0.00132 4$LC=1.47E-4 4 - 95NB L 756.732 127/2+ - 95NB B 368.1 1954.46 22 6.77 - 95NBS B EAV=109.7 7 - 95NB G 756.729 1254.38 22M1+E2 0.00142 4 - 95NB2 G KC=0.00120 4$LC=1.33E-4 4 - + 95NB 95ZR B- DECAY (64.032 D) + 95NB H TYP=UPD$AUT=M.-M.BE$CUT=09-AUG-2012$ + 95NB2 H TYP=FUL$AUT=R.G.HELMER$CUT=30-JUN-1998$ + 95NB T Auger electrons and X ray energies and emission intensities: + 95NB T {U Energy (keV)} {U Intensity} {U Line} + 95NB T + 95NB T 16.5213 0.167 11 XKA2 + 95NB T 16.6152 0.319 20 XKA1 + 95NB T + 95NB T 18.6065 |] XKB3 + 95NB T 18.6227 |] 0.082 6 XKB1 + 95NB T 18.78 |] XKB5II + 95NB T + 95NB T 18.953 |] XKB2 + 95NB T 18.981 |] 0.0124 9 XKB4 + 95NB T + 95NB T + 95NB T 13.49-14.14 |] KLL AUGER + 95NB T 15.79-16.58 |] 0.192 13 KLX AUGER + 95NB T 18.02-18.91 |] KXY AUGER + 95NB T 1.4-2.6 0.92 5 L AUGER + 95ZR P 0.0 5/2+ 64.032 D 6 1124.8 19 + 95NB N 1.0 1.0 1 1.0 + 95NB L 0 9/2+ 34.991 D 6 + 95NB B 1124.8 190.10 3 11.22 2 + 95NBS B EAV=406.0 8 + 95NB L 235.69 2 1/2- 3.61 D 3 + 95NB B 889.1 191.08 7 10.28 1U + 95NBS B EAV=327.6 8 + 95NB G 235.69 2 0.27 2M4 2.88 9 + 95NB2 G KC=2.31 8$LC=0.468 14$MC=0.1 + 95NB L 724.195 4 7/2+ + 95NB B 400.6 1944.34 22 6.98 + 95NBS B EAV=120.9 7 + 95NB G 724.193 3 44.27 22M1+E2 0.00157 5 + 95NB2 G KC=0.00132 4$LC=0.000147 4 + 95NB L 756.732 127/2+ + 95NB B 368.1 1954.46 22 6.77 + 95NBS B EAV=109.7 7 + 95NB G 756.729 1254.38 22M1+E2 0.00142 4 + 95NB2 G KC=0.00120 4$LC=0.000133 4 + From 98b387177640b603a63e9d08240f230cd0173196 Mon Sep 17 00:00:00 2001 From: Reid Townson Date: Thu, 30 Mar 2017 14:53:52 -0400 Subject: [PATCH 30/34] Add radionuclide correlated atomic relaxations Atomic relaxations resulting from internal transitions are now correlated with transitions on an event-by-event basis. Metastable internal transitions are now properly correlated. Instances where multiple internal transitions occur after one disintegration are now handled better. Conversion electrons are now modelled, as well as the resulting relaxations that produce Auger electrons and fluorescence photons. A couple approximations remain. Sub-threshold depositions (edep) from relaxations are neglected, hence energy conservation is not quite achieved. Additionally, the probability for relaxations from subshells is assumed equal within each shell (e.g., given an L shell vacancy, then subshells L1, L2, etc. are assumed equiprobable). Various other small improvements and documentation updates. --- HEN_HOUSE/data/relax_onebyte.data | Bin 0 -> 580923 bytes HEN_HOUSE/egs++/egs_atomic_relaxations.cpp | 12 +- HEN_HOUSE/egs++/egs_atomic_relaxations.h | 5 +- HEN_HOUSE/egs++/egs_base_source.h | 8 - HEN_HOUSE/egs++/egs_ensdf.cpp | 922 ++++++++++++------ HEN_HOUSE/egs++/egs_ensdf.h | 54 +- HEN_HOUSE/egs++/egs_spectra.cpp | 226 +++-- .../egs_radionuclide_source.cpp | 2 +- .../egs_radionuclide_source.h | 9 +- 9 files changed, 825 insertions(+), 413 deletions(-) create mode 100644 HEN_HOUSE/data/relax_onebyte.data diff --git a/HEN_HOUSE/data/relax_onebyte.data b/HEN_HOUSE/data/relax_onebyte.data new file mode 100644 index 0000000000000000000000000000000000000000..c999706a815086e39f2b817e583bad9b3a95ddbc GIT binary patch literal 580923 zcmXV&2Ut#j|Hr@QZttbEr?iyjz3)4vU9x3XA|rceEA1r}+9GLd7$FIj7D|YWLKzuJ zHp%~ee$W4UuI}si&^hPx{fyV^tlKh@L=kcfKY946#LqSS^x|g{gOFYLX~B=02qDYy 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