ENTRY O0204 20190823 O071O020400000001 SUBENT O0204001 20190823 O071O020400100001 BIB 12 36 O020400100002 TITLE Nuclear reactions in Rb,Sr,Y and Zr targets O020400100003 AUTHOR (S.Regnier, B.Lavielle, M.Simonoff, G.N.Simonoff) O020400100004 INSTITUTE (2FR GRA) O020400100005 REFERENCE (J,PR/C,26,931,1982) O020400100006 SAMPLE Pure (99.9% or 3N) target foils of Y,Zr and in some O020400100007 gases vapor deposited Sr were stacked with monitor O020400100008 and guard aluminum (5N) foils, each being about 20 mum.O020400100009 MONITOR ((MONIT)13-AL-27(P,X)11-NA-22,CUM,SIG,,,EVAL) O020400100010 MONIT-REF (,J.Tobailem+,R,CEA-N-1466(1),1971) O020400100011 Exact thickness was determined by weighting O020400100012 FACILITY (ISOCY,2BLGLVN) Louvain-La-Neuve (59,75 and 80 MeV) O020400100013 (ISOCY,2FR PAR) Orsay-SC (150,168 and 200 MeV) O020400100014 (LINAC,2FR SAC) Saturne-II (1 and 2.5 GeV) O020400100015 (SYNCY,2ZZZCER) CERN-PS (24 GeV) O020400100016 METHOD (STTA,EXTB) O020400100017 STATUS (TABLE) O020400100018 ERR-ANALYS (ERR-T) Total uncertainty includes: O020400100019 (ERR-1,,1.) Error in homogeneity and purity of O020400100020 target foils O020400100021 (ERR-2,2.,4.) Errors associated with monitoring were O020400100022 2-4% for counting of Na O020400100023 (MONIT-ERR) uncertainty in monitor reaction O020400100024 cross section. O020400100025 (ERR-3,5.,10.) Uncertainty in the efficiency of the O020400100026 detector O020400100027 (ERR-4,3.,10.) Uncertainty in the photopeak integrationO020400100028 and statistical errors O020400100029 HISTORY (19960415C) O020400100030 (19960929A) Numerous corrections in BIB and DATA O020400100031 sections O020400100032 (19980612A) Some reaction lines are corrected O020400100033 (20000425A) DATE is corrected O020400100034 (20081015A) Subent 009 is corrected according O020400100035 N.Otsuka remarks. O020400100036 (20190823A) SD: Corrections in all Subents. ERR-ANALYS O020400100037 updated. Subent 066 deleted. O020400100038 ENDBIB 36 0 O020400100039 COMMON 1 3 O020400100040 MONIT-ERR O020400100041 PER-CENT O020400100042 10. O020400100043 ENDCOMMON 3 0 O020400100044 ENDSUBENT 43 0 O020400199999 SUBENT O0204002 20190823 O071O020400200001 BIB 6 7 O020400200002 REACTION (39-Y-89(P,X)33-AS-74,,SIG) Shielded. O020400200003 DETECTOR (GELI) O020400200004 METHOD (ACTIV) O020400200005 DECAY-DATA (33-AS-74,17.79D,DG,596.0,0.60) O020400200006 STATUS (TABLE) Tbl.III from Phys.Rev.,C26(1982)931 O020400200007 HISTORY (20190823A) SD: SF5=IND deleted from REACTION code. O020400200008 DATA-ERR -> ERR-T. STATUS added. O020400200009 ENDBIB 7 0 O020400200010 NOCOMMON 0 0 O020400200011 DATA 4 2 O020400200012 EN DATA ERR-T MONIT O020400200013 MEV MB MB MB O020400200014 1000. 9.5 1.9 15.3 O020400200015 2500. 5.6 1.1 11.3 O020400200016 ENDDATA 4 0 O020400200017 ENDSUBENT 16 0 O020400299999 SUBENT O0204003 20190823 O071O020400300001 BIB 6 6 O020400300002 REACTION (39-Y-89(P,X)34-SE-75,CUM,SIG) O020400300003 METHOD (ACTIV) O020400300004 DETECTOR (GELI) O020400300005 DECAY-DATA (34-SE-75,118.45D,DG,265.,0.58) O020400300006 STATUS (TABLE) Tbl.III from Phys.Rev.,C26(1982)931 O020400300007 HISTORY (20190823U) SD: DATA-ERR -> ERR-T. STATUS added. O020400300008 ENDBIB 6 0 O020400300009 NOCOMMON 0 0 O020400300010 DATA 4 5 O020400300011 EN DATA ERR-T MONIT O020400300012 MEV MB MB MB O020400300013 168. 3.8 0.8 16.6 O020400300014 200. 8.5 1.7 16.1 O020400300015 1000. 46. 9. 15.3 O020400300016 2500. 21.3 4.2 11.3 O020400300017 24000. 16.1 3.2 10.1 O020400300018 ENDDATA 7 0 O020400300019 ENDSUBENT 18 0 O020400399999 SUBENT O0204004 20190823 O071O020400400001 BIB 6 6 O020400400002 REACTION (39-Y-89(P,X)37-RB-83,CUM,SIG) O020400400003 METHOD (ACTIV) O020400400004 DETECTOR (GELI) O020400400005 DECAY-DATA (37-RB-83,86.2D,DG,520.,0.46) O020400400006 STATUS (TABLE) Tbl.III from Phys.Rev.,C26(1982)931 O020400400007 HISTORY (20190823U) SD: DATA-ERR -> ERR-T. STATUS added. O020400400008 ENDBIB 6 0 O020400400009 NOCOMMON 0 0 O020400400010 DATA 4 6 O020400400011 EN DATA ERR-T MONIT O020400400012 MEV MB MB MB O020400400013 75. 29. 6. 23.7 O020400400014 168. 54. 11. 16.6 O020400400015 200. 55. 11. 16.1 O020400400016 1000. 45. 9. 15.3 O020400400017 2500. 23. 5. 11.3 O020400400018 24000. 19.2 3.8 10.1 O020400400019 ENDDATA 8 0 O020400400020 ENDSUBENT 19 0 O020400499999 SUBENT O0204005 20190823 O071O020400500001 BIB 6 8 O020400500002 REACTION (39-Y-89(P,X)37-RB-84-G,M+,SIG) Shielded. O020400500003 METHOD (ACTIV) O020400500004 DETECTOR (GELI) O020400500005 DECAY-DATA (37-RB-84-G,32.77D,DG,882.,0.74) O020400500006 (37-RB-84-M,20.5MIN) 100% Isomer transition. O020400500007 STATUS (TABLE) Tbl.III from Phys.Rev.,C26(1982)931 O020400500008 HISTORY (20190823A) SD: SF5=IND/M+ -> M+ in REACTION code. O020400500009 DATA-ERR -> ERR-T. STATUS added. O020400500010 ENDBIB 8 0 O020400500011 NOCOMMON 0 0 O020400500012 DATA 4 6 O020400500013 EN DATA ERR-T MONIT O020400500014 MEV MB MB MB O020400500015 75. 5.4 1.1 23.7 O020400500016 168. 13.3 2.6 16.6 O020400500017 200. 14.4 2.8 16.1 O020400500018 1000. 14.8 3. 15.3 O020400500019 2500. 12. 2.4 11.3 O020400500020 24000. 11.8 2.3 10.1 O020400500021 ENDDATA 8 0 O020400500022 ENDSUBENT 21 0 O020400599999 SUBENT O0204006 20190823 O071O020400600001 BIB 6 8 O020400600002 REACTION (39-Y-89(P,X)37-RB-86-G,M+,SIG) Shielded. O020400600003 METHOD (ACTIV) O020400600004 DETECTOR (GELI) O020400600005 DECAY-DATA (37-RB-86-G,18.82D,DG,1077.,0.0879) O020400600006 (37-RB-86-M,1.02MIN) 100% Isomer transition. O020400600007 STATUS (TABLE) Tbl.III from Phys.Rev.,C26(1982)931 O020400600008 HISTORY (20190823A) SD: SF5=IND/M+ -> M+ in REACTION code. O020400600009 DATA-ERR -> ERR-T. STATUS added. O020400600010 ENDBIB 8 0 O020400600011 NOCOMMON 0 0 O020400600012 DATA 4 2 O020400600013 EN DATA ERR-T MONIT O020400600014 MEV MB MB MB O020400600015 1000. 6.9 1.6 15.3 O020400600016 2500. 4.8 1.1 11.3 O020400600017 ENDDATA 4 0 O020400600018 ENDSUBENT 17 0 O020400699999 SUBENT O0204007 20190823 O071O020400700001 BIB 6 8 O020400700002 REACTION (39-Y-89(P,X)38-SR-85-G,CUM,SIG) O020400700003 METHOD (ACTIV) O020400700004 DETECTOR (GELI) O020400700005 DECAY-DATA (38-SR-85-G,64.85D,DG,514.,1.) O020400700006 (38-SR-85-M,67.7MIN) 86.6% Isomer transition (ENSDF). O020400700007 STATUS (TABLE) Tbl.III from Phys.Rev.,C26(1982)931 O020400700008 HISTORY (20190823A) SD: SF3=3N+2P -> X in REACTION code. O020400700009 DATA-ERR -> ERR-T. STATUS added. O020400700010 ENDBIB 8 0 O020400700011 NOCOMMON 0 0 O020400700012 DATA 4 6 O020400700013 EN DATA ERR-T MONIT O020400700014 MEV MB MB MB O020400700015 75. 17. 7. 23.7 O020400700016 168. 39. 8. 16.6 O020400700017 200. 46. 9. 16.1 O020400700018 1000. 50. 22. 15.3 O020400700019 2500. 34.5 9.3 11.3 O020400700020 24000. 18.2 3.6 10.1 O020400700021 ENDDATA 8 0 O020400700022 ENDSUBENT 21 0 O020400799999 SUBENT O0204008 20190823 O071O020400800001 BIB 6 8 O020400800002 REACTION (39-Y-89(P,X)39-Y-88,,SIG) O020400800003 METHOD (ACTIV) O020400800004 DETECTOR (GELI) O020400800005 DECAY-DATA (39-Y-88,106.61D,DG,898.,0.943, O020400800006 DG,1836.,0.9934) O020400800007 STATUS (TABLE) Tbl.III from Phys.Rev.,C26(1982)931 O020400800008 HISTORY (20190823A) SD: SF5=IND deleted from REACTION code. O020400800009 DATA-ERR -> ERR-T. STATUS added. O020400800010 ENDBIB 8 0 O020400800011 NOCOMMON 0 0 O020400800012 DATA 4 6 O020400800013 EN DATA ERR-T MONIT O020400800014 MEV MB MB MB O020400800015 59. 195. 42. 28. O020400800016 75. 165. 37. 23.7 O020400800017 168. 110. 24. 16.6 O020400800018 200. 115. 25. 16.1 O020400800019 2500. 63. 13. 11.3 O020400800020 24000. 61. 12. 10.1 O020400800021 ENDDATA 8 0 O020400800022 ENDSUBENT 21 0 O020400899999 SUBENT O0204009 20190823 O071O020400900001 BIB 6 6 O020400900002 REACTION (39-Y-89(P,2N)40-ZR-88,,SIG) O020400900003 METHOD (ACTIV) O020400900004 DETECTOR (GELI) O020400900005 DECAY-DATA (40-ZR-88,83.4D,DG,394.,0.973) O020400900006 STATUS (TABLE) Tbl.III from Phys.Rev.,C26(1982)931 O020400900007 HISTORY (20190823U) SD: DATA-ERR -> ERR-T. STATUS added. O020400900008 ENDBIB 6 0 O020400900009 NOCOMMON 0 0 O020400900010 DATA 4 6 O020400900011 EN DATA ERR-T MONIT O020400900012 MEV MB MB MB O020400900013 59. 126. 25. 28. O020400900014 75. 55. 11. 23.7 O020400900015 168. 18.3 3.7 16.6 O020400900016 200. 19.2 3.8 16.1 O020400900017 2500. 5.9 1.5 11.3 O020400900018 24000. 4.2 0.8 10.1 O020400900019 ENDDATA 8 0 O020400900020 ENDSUBENT 19 0 O020400999999 SUBENT O0204010 20190823 O071O020401000001 BIB 6 7 O020401000002 REACTION (40-ZR-0(P,X)33-AS-74,,SIG) Shielded. O020401000003 METHOD (ACTIV) O020401000004 DETECTOR (GELI) O020401000005 DECAY-DATA (33-AS-74,17.79D,DG,596.,0.60) O020401000006 STATUS (TABLE) Tbl.IV from Phys.Rev.,C26(1982)931 O020401000007 HISTORY (20190823A) SD: SF5=IND deleted from REACTION code. O020401000008 DATA-ERR -> ERR-T. STATUS added. O020401000009 ENDBIB 7 0 O020401000010 NOCOMMON 0 0 O020401000011 DATA 4 2 O020401000012 EN DATA ERR-T MONIT O020401000013 MEV MB MB MB O020401000014 1000. 7.4 1.5 15.3 O020401000015 2500. 4.8 1.0 11.3 O020401000016 ENDDATA 4 0 O020401000017 ENDSUBENT 16 0 O020401099999 SUBENT O0204011 20190823 O071O020401100001 BIB 6 6 O020401100002 REACTION (40-ZR-0(P,X)34-SE-75,CUM,SIG) O020401100003 METHOD (ACTIV) O020401100004 DETECTOR (GELI) O020401100005 DECAY-DATA (34-SE-75,118.45D,DG,265.,0.58) O020401100006 STATUS (TABLE) Tbl.IV from Phys.Rev.,C26(1982)931 O020401100007 HISTORY (20190823U) SD: DATA-ERR -> ERR-T. STATUS added. O020401100008 ENDBIB 6 0 O020401100009 NOCOMMON 0 0 O020401100010 DATA 4 5 O020401100011 EN DATA ERR-T MONIT O020401100012 MEV MB MB MB O020401100013 168. 1.7 0.8 16.6 O020401100014 200. 3.9 0.8 16.1 O020401100015 1000. 37. 7. 15.3 O020401100016 2500. 22. 4. 11.3 O020401100017 24000. 14.5 2.9 10.1 O020401100018 ENDDATA 7 0 O020401100019 ENDSUBENT 18 0 O020401199999 SUBENT O0204012 20190823 O071O020401200001 BIB 6 6 O020401200002 REACTION (40-ZR-0(P,X)37-RB-83,CUM,SIG) O020401200003 METHOD (ACTIV) O020401200004 DETECTOR (GELI) O020401200005 DECAY-DATA (37-RB-83,86.2D,DG,520.,0.46) O020401200006 STATUS (TABLE) Tbl.IV from Phys.Rev.,C26(1982)931 O020401200007 HISTORY (20190823U) SD: DATA-ERR -> ERR-T. STATUS added. O020401200008 ENDBIB 6 0 O020401200009 NOCOMMON 0 0 O020401200010 DATA 4 7 O020401200011 EN DATA ERR-T MONIT O020401200012 MEV MB MB MB O020401200013 59. 2.9 0.6 28.0 O020401200014 75. 27. 5. 23.7 O020401200015 168. 37. 15. 16.6 O020401200016 200. 38. 8. 16.1 O020401200017 1000. 34. 7. 15.3 O020401200018 2500. 21. 4. 11.3 O020401200019 24000. 16. 3. 10.1 O020401200020 ENDDATA 9 0 O020401200021 ENDSUBENT 20 0 O020401299999 SUBENT O0204013 20190823 O071O020401300001 BIB 6 8 O020401300002 REACTION (40-ZR-0(P,X)37-RB-84-G,M+,SIG) Shielded. O020401300003 METHOD (ACTIV) O020401300004 DETECTOR (GELI) O020401300005 DECAY-DATA (37-RB-84-G,32.77D,DG,882.,0.74) O020401300006 (37-RB-84-M,20.5MIN) 100% Isomer transition. O020401300007 STATUS (TABLE) Tbl.IV from Phys.Rev.,C26(1982)931 O020401300008 HISTORY (20190823A) SD: SF5=IND/M+ -> M+ in REACTION code. O020401300009 DATA-ERR -> ERR-T. STATUS added. O020401300010 ENDBIB 8 0 O020401300011 NOCOMMON 0 0 O020401300012 DATA 4 5 O020401300013 EN DATA ERR-T MONIT O020401300014 MEV MB MB MB O020401300015 75. 2.1 0.4 23.7 O020401300016 200. 4.5 1.6 16.1 O020401300017 1000. 8.9 1.8 15.3 O020401300018 2500. 6.0 1.2 11.3 O020401300019 24000. 5.8 1.2 10.1 O020401300020 ENDDATA 7 0 O020401300021 ENDSUBENT 20 0 O020401399999 SUBENT O0204014 20190823 O071O020401400001 BIB 6 8 O020401400002 REACTION (40-ZR-0(P,X)37-RB-86-G,,SIG) Shielded. O020401400003 METHOD (ACTIV) O020401400004 DETECTOR (GELI) O020401400005 DECAY-DATA (37-RB-86-G,18.82D,DG,1077.,0.0879) O020401400006 (37-RB-86-M,1.02MIN) 100% Isomer Transition. O020401400007 STATUS (TABLE) Tbl.IV from Phys.Rev.,C26(1982)931 O020401400008 HISTORY (20190823A) SD: SF5=IND deleted from REACTION code. O020401400009 DATA-ERR -> ERR-T. STATUS added. O020401400010 ENDBIB 8 0 O020401400011 NOCOMMON 0 0 O020401400012 DATA 4 2 O020401400013 EN DATA ERR-T MONIT O020401400014 MEV MB MB MB O020401400015 1000. 5. 1. 15.3 O020401400016 2500. 2.9 0.6 11.3 O020401400017 ENDDATA 4 0 O020401400018 ENDSUBENT 17 0 O020401499999 SUBENT O0204015 20190823 O071O020401500001 BIB 6 7 O020401500002 REACTION (40-ZR-0(P,X)38-SR-85-G,CUM,SIG) O020401500003 METHOD (ACTIV) O020401500004 DETECTOR (GELI) O020401500005 DECAY-DATA (38-SR-85-G,64.85D,DG,514.,1.) O020401500006 (38-SR-85-M,67.7MIN) 86.6% Isomer transition (ENSDF) O020401500007 STATUS (TABLE) Tbl.IV from Phys.Rev.,C26(1982)931 O020401500008 HISTORY (20190823U) SD: DATA-ERR -> ERR-T. STATUS added. O020401500009 ENDBIB 7 0 O020401500010 NOCOMMON 0 0 O020401500011 DATA 4 6 O020401500012 EN DATA ERR-T MONIT O020401500013 MEV MB MB MB O020401500014 75. 22. 7. 23.7 O020401500015 168. 28. 12. 16.6 O020401500016 200. 32. 8. 16.1 O020401500017 1000. 30. 13. 15.3 O020401500018 2500. 22. 8. 11.3 O020401500019 24000. 18.8 5.4 10.1 O020401500020 ENDDATA 8 0 O020401500021 ENDSUBENT 20 0 O020401599999 SUBENT O0204016 20190823 O071O020401600001 BIB 6 8 O020401600002 REACTION (40-ZR-0(P,X)39-Y-88,,SIG) O020401600003 METHOD (ACTIV) O020401600004 DETECTOR (GELI) O020401600005 DECAY-DATA (39-Y-88,106.61D,DG,898.,0.943, O020401600006 DG,1836.,0.9934) O020401600007 STATUS (TABLE) Tbl.IV from Phys.Rev.,C26(1982)931 O020401600008 HISTORY (20190823A) SD: SF5=IND deleted from REACTION code. O020401600009 DATA-ERR -> ERR-T. STATUS added. O020401600010 ENDBIB 8 0 O020401600011 NOCOMMON 0 0 O020401600012 DATA 4 4 O020401600013 EN DATA ERR-T MONIT O020401600014 MEV MB MB MB O020401600015 168. 52. 10. 16.6 O020401600016 200. 56. 11. 16.1 O020401600017 2500. 27. 5.4 11.3 O020401600018 24000. 20. 4. 10.1 O020401600019 ENDDATA 6 0 O020401600020 ENDSUBENT 19 0 O020401699999 SUBENT O0204017 20190823 O071O020401700001 BIB 6 6 O020401700002 REACTION (40-ZR-0(P,X)40-ZR-88,CUM,SIG) O020401700003 METHOD (ACTIV) O020401700004 DETECTOR (GELI) O020401700005 DECAY-DATA (40-ZR-88,83.4D,DG,394.,0.973) O020401700006 STATUS (TABLE) Tbl.IV from Phys.Rev.,C26(1982)931 O020401700007 HISTORY (20190823U) SD: DATA-ERR -> ERR-T. STATUS added. O020401700008 ENDBIB 6 0 O020401700009 NOCOMMON 0 0 O020401700010 DATA 4 7 O020401700011 EN DATA ERR-T MONIT O020401700012 MEV MB MB MB O020401700013 59. 456. 91. 28.0 O020401700014 75. 232. 46. 23.7 O020401700015 168. 80. 16. 16.6 O020401700016 200. 79. 16. 16.1 O020401700017 1000. 39. 8. 15.3 O020401700018 2500. 28. 6. 11.3 O020401700019 24000. 24.5 5. 10.1 O020401700020 ENDDATA 9 0 O020401700021 ENDSUBENT 20 0 O020401799999 SUBENT O0204018 20190823 O071O020401800001 BIB 6 7 O020401800002 REACTION (40-ZR-0(P,X)41-NB-92-M,,SIG) Shielded. O020401800003 METHOD (ACTIV) O020401800004 DETECTOR (GELI) O020401800005 DECAY-DATA (41-NB-92-M,10.14D,DG,934.,0.992) O020401800006 STATUS (TABLE) Tbl.IV from Phys.Rev.,C26(1982)931 O020401800007 HISTORY (20190823A) SD: SF5=IND deleted from REACTION code. O020401800008 DATA-ERR -> ERR-T. STATUS added. O020401800009 ENDBIB 7 0 O020401800010 NOCOMMON 0 0 O020401800011 DATA 4 2 O020401800012 EN DATA ERR-T MONIT O020401800013 MEV MB MB MB O020401800014 1000. 0.70 0.14 15.3 O020401800015 2500. 1.20 0.24 11.3 O020401800016 ENDDATA 4 0 O020401800017 ENDSUBENT 16 0 O020401899999 SUBENT O0204019 20190823 O071O020401900001 BIB 4 21 O020401900002 REACTION (39-Y-89(P,X)36-KR-78,CUM,SIG) O020401900003 METHOD (ASEP) Several months after irradiation targets and O020401900004 blank foils were stored (ten a time) in an extraction O020401900005 system in which an ultrahigh vacuum (better than O020401900006 10**(-9) Torr) was progressively attained by pumping O020401900007 and baking all elements. Targets were baked several O020401900008 days at 80. to 100. degr.C and authors checked that O020401900009 this procedure did not outgas any spallogenic O020401900010 krypton. Each foil was then melted inside a O020401900011 molybdenum crucible heated by an electronic O020401900012 bombardment oven routinely operating at 1900.degr.C. O020401900013 Extracted gases were exposed in two step to Ti and O020401900014 Cu-O-Pd getters between 700. and 200.degr.C for O020401900015 eliminating active species. Krypton(95-98%) was then O020401900016 adsorbed on a first activated charcoal trap at -120 O020401900017 degr. The remainder was adsorbed together with 98-99% O020401900018 argon on a second trap at -196 degr.C. Argon and O020401900019 krypton were successively introduced into mass O020401900020 spectrometer. O020401900021 STATUS (TABLE) Tbl.V from Phys.Rev.,C26(1982)931 O020401900022 HISTORY (20190823U) DATA-ERR -> ERR-T. STATUS added. O020401900023 ENDBIB 21 0 O020401900024 NOCOMMON 0 0 O020401900025 DATA 4 9 O020401900026 EN DATA ERR-T MONIT O020401900027 MEV MB MB MB O020401900028 59. 0.0024 0.0005 28.0 O020401900029 75. 0.32 0.03 23.7 O020401900030 80. 0.47 0.16 22.7 O020401900031 150. 9.1 1.0 17.2 O020401900032 168. 14.8 1.5 16.6 O020401900033 200. 24.4 2.4 16.1 O020401900034 1005. 29.2 2.9 15.3 O020401900035 2500. 13.7 1.3 11.3 O020401900036 24000. 10.9 2.6 10.1 O020401900037 ENDDATA 11 0 O020401900038 ENDSUBENT 37 0 O020401999999 SUBENT O0204020 20190823 O071O020402000001 BIB 4 21 O020402000002 REACTION (39-Y-89(P,X)36-KR-80,CUM,SIG) O020402000003 METHOD (ASEP) Several months after irradiation targets and O020402000004 blank foils were stored (ten a time) in an extraction O020402000005 system in which an ultrahigh vacuum (better than O020402000006 10**(-9) Torr) was progressively attained by pumping O020402000007 and baking all elements. Targets were baked several O020402000008 days at 80. to 100. degr.C and authors checked that O020402000009 this procedure did not outgas any spallogenic O020402000010 krypton. Each foil was then melted inside a O020402000011 molybdenum crucible heated by an electronic O020402000012 bombardment oven routinely operating at 1900.degr.C. O020402000013 Extracted gases were exposed in two step to Ti and O020402000014 Cu-O-Pd getters between 700. and 200.degr.C for O020402000015 eliminating active species. Krypton(95-98%) was then O020402000016 adsorbed on a first activated charcoal trap at -120 O020402000017 degr. The remainder was adsorbed together with 98-99% O020402000018 argon on a second trap at -196 degr.C. Argon and O020402000019 krypton were successively introduced into mass O020402000020 spectrometer. O020402000021 STATUS (TABLE) Tbl.V from Phys.Rev.,C26(1982)931 O020402000022 HISTORY (20190823U) DATA-ERR -> ERR-T. STATUS added. O020402000023 ENDBIB 21 0 O020402000024 NOCOMMON 0 0 O020402000025 DATA 4 9 O020402000026 EN DATA ERR-T MONIT O020402000027 MEV MB MB MB O020402000028 59. 2.25 0.23 28.0 O020402000029 75. 3.0 0.3 23.7 O020402000030 80. 2.1 0.7 22.7 O020402000031 150. 31.7 3.3 17.2 O020402000032 168. 42.8 4.3 16.6 O020402000033 200. 59.4 6.0 16.1 O020402000034 1005. 51.8 5.2 15.3 O020402000035 2500. 26.3 2.6 11.3 O020402000036 24000. 22.7 5.5 10.1 O020402000037 ENDDATA 11 0 O020402000038 ENDSUBENT 37 0 O020402099999 SUBENT O0204021 20190823 O071O020402100001 BIB 4 21 O020402100002 REACTION (39-Y-89(P,X)36-KR-81,CUM,SIG) O020402100003 METHOD (ASEP) Several months after irradiation targets and O020402100004 blank foils were stored (ten a time) in an extraction O020402100005 system in which an ultrahigh vacuum (better than O020402100006 10**(-9) Torr) was progressively attained by pumping O020402100007 and baking all elements. Targets were baked several O020402100008 days at 80. to 100. degr.C and authors checked that O020402100009 this procedure did not outgas any spallogenic O020402100010 krypton. Each foil was then melted inside a O020402100011 molybdenum crucible heated by an electronic O020402100012 bombardment oven routinely operating at 1900.degr.C. O020402100013 Extracted gases were exposed in two step to Ti and O020402100014 Cu-O-Pd getters between 700. and 200.degr.C for O020402100015 eliminating active species. Krypton(95-98%) was then O020402100016 adsorbed on a first activated charcoal trap at -120 O020402100017 degr. The remainder was adsorbed together with 98-99% O020402100018 argon on a second trap at -196 degr.C. Argon and O020402100019 krypton were successively introduced into mass O020402100020 spectrometer. O020402100021 STATUS (TABLE) Tbl.V from Phys.Rev.,C26(1982)931 O020402100022 HISTORY (20190823U) DATA-ERR -> ERR-T. STATUS added. O020402100023 ENDBIB 21 0 O020402100024 NOCOMMON 0 0 O020402100025 DATA 4 9 O020402100026 EN DATA ERR-T MONIT O020402100027 MEV MB MB MB O020402100028 59. 1.0 0.1 28.0 O020402100029 75. 12.5 1.2 23.7 O020402100030 80. 12.8 4.1 22.7 O020402100031 150. 44.7 4.6 17.2 O020402100032 168. 55.8 5.6 16.6 O020402100033 200. 74.0 7.5 16.1 O020402100034 1005. 53.0 5.3 15.3 O020402100035 2500. 27.3 2.7 11.3 O020402100036 24000. 24.0 5.8 10.1 O020402100037 ENDDATA 11 0 O020402100038 ENDSUBENT 37 0 O020402199999 SUBENT O0204022 20190823 O071O020402200001 BIB 4 21 O020402200002 REACTION (39-Y-89(P,X)36-KR-82,CUM,SIG) O020402200003 METHOD (ASEP) Several months after irradiation targets and O020402200004 blank foils were stored (ten a time) in an extraction O020402200005 system in which an ultrahigh vacuum (better than O020402200006 10**(-9) Torr) was progressively attained by pumping O020402200007 and baking all elements. Targets were baked several O020402200008 days at 80. to 100. degr.C and authors checked that O020402200009 this procedure did not outgas any spallogenic O020402200010 krypton. Each foil was then melted inside a O020402200011 molybdenum crucible heated by an electronic O020402200012 bombardment oven routinely operating at 1900.degr.C. O020402200013 Extracted gases were exposed in two step to Ti and O020402200014 Cu-O-Pd getters between 700. and 200.degr.C for O020402200015 eliminating active species. Krypton(95-98%) was then O020402200016 adsorbed on a first activated charcoal trap at -120 O020402200017 degr. The remainder was adsorbed together with 98-99% O020402200018 argon on a second trap at -196 degr.C. Argon and O020402200019 krypton were successively introduced into mass O020402200020 spectrometer. O020402200021 STATUS (TABLE) Tbl.V from Phys.Rev.,C26(1982)931 O020402200022 HISTORY (20190823U) DATA-ERR -> ERR-T. STATUS added. O020402200023 ENDBIB 21 0 O020402200024 NOCOMMON 0 0 O020402200025 DATA 4 9 O020402200026 EN DATA ERR-T MONIT O020402200027 MEV MB MB MB O020402200028 59. 3.9 0.4 28.0 O020402200029 75. 65. 6. 23.7 O020402200030 80. 47. 15. 22.7 O020402200031 150. 63. 6. 17.2 O020402200032 168. 72. 7. 16.6 O020402200033 200. 89. 9. 16.1 O020402200034 1005. 57. 6. 15.3 O020402200035 2500. 30. 3. 11.3 O020402200036 24000. 28. 7. 10.1 O020402200037 ENDDATA 11 0 O020402200038 ENDSUBENT 37 0 O020402299999 SUBENT O0204023 20190823 O071O020402300001 BIB 4 21 O020402300002 REACTION (39-Y-89(P,X)36-KR-83-G,CUM,SIG) O020402300003 METHOD (ASEP) Several months after irradiation targets and O020402300004 blank foils were stored (ten a time) in an extraction O020402300005 system in which an ultrahigh vacuum (better than O020402300006 10**(-9) Torr) was progressively attained by pumping O020402300007 and baking all elements. Targets were baked several O020402300008 days at 80. to 100. degr.C and authors checked that O020402300009 this procedure did not outgas any spallogenic O020402300010 krypton. Each foil was then melted inside a O020402300011 molybdenum crucible heated by an electronic O020402300012 bombardment oven routinely operating at 1900.degr.C. O020402300013 Extracted gases were exposed in two step to Ti and O020402300014 Cu-O-Pd getters between 700. and 200.degr.C for O020402300015 eliminating active species. Krypton(95-98%) was then O020402300016 adsorbed on a first activated charcoal trap at -120 O020402300017 degr. The remainder was adsorbed together with 98-99% O020402300018 argon on a second trap at -196 degr.C. Argon and O020402300019 krypton were successively introduced into mass O020402300020 spectrometer. O020402300021 STATUS (TABLE) Tbl.V from Phys.Rev.,C26(1982)931 O020402300022 HISTORY (20190823U) DATA-ERR -> ERR-T. STATUS added. O020402300023 ENDBIB 21 0 O020402300024 NOCOMMON 0 0 O020402300025 DATA 4 9 O020402300026 EN DATA ERR-T MONIT O020402300027 MEV MB MB MB O020402300028 59. 71. 9. 28.0 O020402300029 75. 50. 5. 23.7 O020402300030 80. 32. 10. 22.7 O020402300031 150. 88. 9. 17.2 O020402300032 168. 74. 7. 16.6 O020402300033 200. 88. 9. 16.1 O020402300034 1005. 63. 6. 15.3 O020402300035 2500. 34.7 3.5 11.3 O020402300036 24000. 32.4 7.8 10.1 O020402300037 ENDDATA 11 0 O020402300038 ENDSUBENT 37 0 O020402399999 SUBENT O0204024 20190823 O071O020402400001 BIB 4 21 O020402400002 REACTION (39-Y-89(P,X)36-KR-84,CUM,SIG) O020402400003 METHOD (ASEP) Several months after irradiation targets and O020402400004 blank foils were stored (ten a time) in an extraction O020402400005 system in which an ultrahigh vacuum (better than O020402400006 10**(-9) Torr) was progressively attained by pumping O020402400007 and baking all elements. Targets were baked several O020402400008 days at 80. to 100. degr.C and authors checked that O020402400009 this procedure did not outgas any spallogenic O020402400010 krypton. Each foil was then melted inside a O020402400011 molybdenum crucible heated by an electronic O020402400012 bombardment oven routinely operating at 1900.degr.C. O020402400013 Extracted gases were exposed in two step to Ti and O020402400014 Cu-O-Pd getters between 700. and 200.degr.C for O020402400015 eliminating active species. Krypton(95-98%) was then O020402400016 adsorbed on a first activated charcoal trap at -120 O020402400017 degr. The remainder was adsorbed together with 98-99% O020402400018 argon on a second trap at -196 degr.C. Argon and O020402400019 krypton were successively introduced into mass O020402400020 spectrometer. O020402400021 STATUS (TABLE) Tbl.V from Phys.Rev.,C26(1982)931 O020402400022 HISTORY (20190823U) DATA-ERR -> ERR-T. STATUS added. O020402400023 ENDBIB 21 0 O020402400024 NOCOMMON 0 0 O020402400025 DATA 4 9 O020402400026 EN DATA ERR-T MONIT O020402400027 MEV MB MB MB O020402400028 59. 7.3 1.0 28.0 O020402400029 75. 8.1 0.8 23.7 O020402400030 80. 6.1 2.0 22.7 O020402400031 150. 11.9 1.2 17.2 O020402400032 168. 13.8 1.4 16.6 O020402400033 200. 17.9 2.0 16.1 O020402400034 1005. 19.1 1.9 15.3 O020402400035 2500. 11.4 1.1 11.3 O020402400036 24000. 11.5 2.8 10.1 O020402400037 ENDDATA 11 0 O020402400038 ENDSUBENT 37 0 O020402499999 SUBENT O0204025 20190823 O071O020402500001 BIB 4 21 O020402500002 REACTION (39-Y-89(P,X)36-KR-85-G,CUM,SIG) O020402500003 METHOD (ASEP) Several months after irradiation targets and O020402500004 blank foils were stored (ten a time) in an extraction O020402500005 system in which an ultrahigh vacuum (better than O020402500006 10**(-9) Torr) was progressively attained by pumping O020402500007 and baking all elements. Targets were baked several O020402500008 days at 80. to 100. degr.C and authors checked that O020402500009 this procedure did not outgas any spallogenic O020402500010 krypton. Each foil was then melted inside a O020402500011 molybdenum crucible heated by an electronic O020402500012 bombardment oven routinely operating at 1900.degr.C. O020402500013 Extracted gases were exposed in two step to Ti and O020402500014 Cu-O-Pd getters between 700. and 200.degr.C for O020402500015 eliminating active species. Krypton(95-98%) was then O020402500016 adsorbed on a first activated charcoal trap at -120 O020402500017 degr. The remainder was adsorbed together with 98-99% O020402500018 argon on a second trap at -196 degr.C. Argon and O020402500019 krypton were successively introduced into mass O020402500020 spectrometer. O020402500021 STATUS (TABLE) Tbl.V from Phys.Rev.,C26(1982)931 O020402500022 HISTORY (20190823U) DATA-ERR -> ERR-T. STATUS added. O020402500023 ENDBIB 21 0 O020402500024 NOCOMMON 0 0 O020402500025 DATA 4 8 O020402500026 EN DATA ERR-T MONIT O020402500027 MEV MB MB MB O020402500028 75. 0.0039 0.0007 23.7 O020402500029 80. 0.0071 0.0023 22.7 O020402500030 150. 0.035 0.004 17.2 O020402500031 168. 0.060 0.006 16.6 O020402500032 200. 0.095 0.010 16.1 O020402500033 1005. 0.350 0.035 15.3 O020402500034 2500. 0.22 0.08 11.3 O020402500035 24000. 0.234 0.064 10.1 O020402500036 ENDDATA 10 0 O020402500037 ENDSUBENT 36 0 O020402599999 SUBENT O0204026 20190823 O071O020402600001 BIB 4 22 O020402600002 REACTION (39-Y-89(P,4P)36-KR-86,,SIG) O020402600003 METHOD (ASEP) Several months after irradiation targets and O020402600004 blank foils were stored (ten a time) in an extraction O020402600005 system in which an ultrahigh vacuum (better than O020402600006 10**(-9) Torr) was progressively attained by pumping O020402600007 and baking all elements. Targets were baked several O020402600008 days at 80. to 100. degr.C and authors checked that O020402600009 this procedure did not outgas any spallogenic O020402600010 krypton. Each foil was then melted inside a O020402600011 molybdenum crucible heated by an electronic O020402600012 bombardment oven routinely operating at 1900.degr.C. O020402600013 Extracted gases were exposed in two step to Ti and O020402600014 Cu-O-Pd getters between 700. and 200.degr.C for O020402600015 eliminating active species. Krypton(95-98%) was then O020402600016 adsorbed on a first activated charcoal trap at -120 O020402600017 degr. The remainder was adsorbed together with 98-99% O020402600018 argon on a second trap at -196 degr.C. Argon and O020402600019 krypton were successively introduced into mass O020402600020 spectrometer. O020402600021 STATUS (TABLE) Tbl.V from Phys.Rev.,C26(1982)931 O020402600022 HISTORY (20190823A) SF5=IND deleted from REACTION code. O020402600023 DATA-ERR -> ERR-T. STATUS added. O020402600024 ENDBIB 22 0 O020402600025 NOCOMMON 0 0 O020402600026 DATA 4 6 O020402600027 EN DATA ERR-T MONIT O020402600028 MEV MB MB MB O020402600029 150. 0.0058 0.0021 17.2 O020402600030 168. 0.007 0.0047 16.6 O020402600031 200. 0.014 0.009 16.1 O020402600032 1005. 0.105 0.017 15.3 O020402600033 2500. 0.044 0.01 11.3 O020402600034 24000. 0.061 0.017 10.1 O020402600035 ENDDATA 8 0 O020402600036 ENDSUBENT 35 0 O020402699999 SUBENT O0204027 20190823 O071O020402700001 BIB 4 21 O020402700002 REACTION (40-ZR-90(P,X)36-KR-78,CUM,SIG) O020402700003 METHOD (ASEP) Several months after irradiation targets and O020402700004 blank foils were stored (ten a time) in an extraction O020402700005 system in which an ultrahigh vacuum (better than O020402700006 10**(-9) Torr) was progressively attained by pumping O020402700007 and baking all elements. Targets were baked several O020402700008 days at 80. to 100. degr.C and authors checked that O020402700009 this procedure did not outgas any spallogenic O020402700010 krypton. Each foil was then melted inside a O020402700011 molybdenum crucible heated by an electronic O020402700012 bombardment oven routinely operating at 1900.degr.C. O020402700013 Extracted gases were exposed in two step to Ti and O020402700014 Cu-O-Pd getters between 700. and 200.degr.C for O020402700015 eliminating active species. Krypton(95-98%) was then O020402700016 adsorbed on a first activated charcoal trap at -120 O020402700017 degr. The remainder was adsorbed together with 98-99% O020402700018 argon on a second trap at -196 degr.C. Argon and O020402700019 krypton were successively introduced into mass O020402700020 spectrometer. O020402700021 STATUS (TABLE) Tbl.VI from Phys.Rev.,C26(1982)931 O020402700022 HISTORY (20190823U) DATA-ERR -> ERR-T. STATUS added. O020402700023 ENDBIB 21 0 O020402700024 NOCOMMON 0 0 O020402700025 DATA 4 6 O020402700026 EN DATA ERR-T MONIT O020402700027 MEV MB MB MB O020402700028 75. 0.0028 0.0005 23.7 O020402700029 168. 7.11 0.71 16.6 O020402700030 200. 13.1 1.3 16.1 O020402700031 1000. 28.3 2.8 15.3 O020402700032 2500. 17.2 1.7 11.3 O020402700033 24000. 11.6 1.2 10.1 O020402700034 ENDDATA 8 0 O020402700035 ENDSUBENT 34 0 O020402799999 SUBENT O0204028 20190823 O071O020402800001 BIB 4 21 O020402800002 REACTION (40-ZR-90(P,X)36-KR-80,CUM,SIG) O020402800003 METHOD (ASEP) Several months after irradiation targets and O020402800004 blank foils were stored (ten a time) in an extraction O020402800005 system in which an ultrahigh vacuum (better than O020402800006 10**(-9) Torr) was progressively attained by pumping O020402800007 and baking all elements. Targets were baked several O020402800008 days at 80. to 100. degr.C and authors checked that O020402800009 this procedure did not outgas any spallogenic O020402800010 krypton. Each foil was then melted inside a O020402800011 molybdenum crucible heated by an electronic O020402800012 bombardment oven routinely operating at 1900.degr.C. O020402800013 Extracted gases were exposed in two step to Ti and O020402800014 Cu-O-Pd getters between 700. and 200.degr.C for O020402800015 eliminating active species. Krypton(95-98%) was then O020402800016 adsorbed on a first activated charcoal trap at -120 O020402800017 degr. The remainder was adsorbed together with 98-99% O020402800018 argon on a second trap at -196 degr.C. Argon and O020402800019 krypton were successively introduced into mass O020402800020 spectrometer. O020402800021 STATUS (TABLE) Tbl.VI from Phys.Rev.,C26(1982)931 O020402800022 HISTORY (20190823U) DATA-ERR -> ERR-T. STATUS added. O020402800023 ENDBIB 21 0 O020402800024 NOCOMMON 0 0 O020402800025 DATA 4 7 O020402800026 EN DATA ERR-T MONIT O020402800027 MEV MB MB MB O020402800028 59. 0.046 0.014 28.0 O020402800029 75. 3.14 0.31 23.7 O020402800030 168. 21.1 2.1 16.6 O020402800031 200. 31.6 3.2 16.1 O020402800032 1000. 46.4 4.6 15.3 O020402800033 2500. 28.9 2.9 11.3 O020402800034 24000. 21.0 2.1 10.1 O020402800035 ENDDATA 9 0 O020402800036 ENDSUBENT 35 0 O020402899999 SUBENT O0204029 20190823 O071O020402900001 BIB 4 21 O020402900002 REACTION (40-ZR-90(P,X)36-KR-81-G,CUM,SIG) O020402900003 METHOD (ASEP) Several months after irradiation targets and O020402900004 blank foils were stored (ten a time) in an extraction O020402900005 system in which an ultrahigh vacuum (better than O020402900006 10**(-9) Torr) was progressively attained by pumping O020402900007 and baking all elements. Targets were baked several O020402900008 days at 80. to 100. degr.C and authors checked that O020402900009 this procedure did not outgas any spallogenic O020402900010 krypton. Each foil was then melted inside a O020402900011 molybdenum crucible heated by an electronic O020402900012 bombardment oven routinely operating at 1900.degr.C. O020402900013 Extracted gases were exposed in two step to Ti and O020402900014 Cu-O-Pd getters between 700. and 200.degr.C for O020402900015 eliminating active species. Krypton(95-98%) was then O020402900016 adsorbed on a first activated charcoal trap at -120 O020402900017 degr. The remainder was adsorbed together with 98-99% O020402900018 argon on a second trap at -196 degr.C. Argon and O020402900019 krypton were successively introduced into mass O020402900020 spectrometer. O020402900021 STATUS (TABLE) Tbl.VI from Phys.Rev.,C26(1982)931 O020402900022 HISTORY (20190823U) DATA-ERR -> ERR-T. STATUS added. O020402900023 ENDBIB 21 0 O020402900024 NOCOMMON 0 0 O020402900025 DATA 4 7 O020402900026 EN DATA ERR-T MONIT O020402900027 MEV MB MB MB O020402900028 59. 1.33 0.13 28.0 O020402900029 75. 3.54 0.21 23.7 O020402900030 168. 30.8 3.1 16.6 O020402900031 200. 41.7 4.2 16.1 O020402900032 1000. 46.7 4.6 15.3 O020402900033 2500. 29.8 3.0 11.3 O020402900034 24000. 21.8 2.2 10.1 O020402900035 ENDDATA 9 0 O020402900036 ENDSUBENT 35 0 O020402999999 SUBENT O0204030 20190823 O071O020403000001 BIB 4 21 O020403000002 REACTION (40-ZR-90(P,X)36-KR-82,CUM,SIG) O020403000003 METHOD (ASEP) Several months after irradiation targets and O020403000004 blank foils were stored (ten a time) in an extraction O020403000005 system in which an ultrahigh vacuum (better than O020403000006 10**(-9) Torr) was progressively attained by pumping O020403000007 and baking all elements. Targets were baked several O020403000008 days at 80. to 100. degr.C and authors checked that O020403000009 this procedure did not outgas any spallogenic O020403000010 krypton. Each foil was then melted inside a O020403000011 molybdenum crucible heated by an electronic O020403000012 bombardment oven routinely operating at 1900.degr.C. O020403000013 Extracted gases were exposed in two step to Ti and O020403000014 Cu-O-Pd getters between 700. and 200.degr.C for O020403000015 eliminating active species. Krypton(95-98%) was then O020403000016 adsorbed on a first activated charcoal trap at -120 O020403000017 degr. The remainder was adsorbed together with 98-99% O020403000018 argon on a second trap at -196 degr.C. Argon and O020403000019 krypton were successively introduced into mass O020403000020 spectrometer. O020403000021 STATUS (TABLE) Tbl.VI from Phys.Rev.,C26(1982)931 O020403000022 HISTORY (20190823U) DATA-ERR -> ERR-T. STATUS added. O020403000023 ENDBIB 21 0 O020403000024 NOCOMMON 0 0 O020403000025 DATA 4 7 O020403000026 EN DATA ERR-T MONIT O020403000027 MEV MB MB MB O020403000028 59. 1.62 0.16 28.0 O020403000029 75. 6.6 0.6 23.7 O020403000030 168. 41.3 4.1 16.6 O020403000031 200. 52.6 5.3 16.1 O020403000032 1000. 50. 5. 15.3 O020403000033 2500. 32.1 3.2 11.3 O020403000034 24000. 24.2 2.4 10.1 O020403000035 ENDDATA 9 0 O020403000036 ENDSUBENT 35 0 O020403099999 SUBENT O0204031 20190823 O071O020403100001 BIB 4 21 O020403100002 REACTION (40-ZR-90(P,X)36-KR-83-G,CUM,SIG) O020403100003 METHOD (ASEP) Several months after irradiation targets and O020403100004 blank foils were stored (ten a time) in an extraction O020403100005 system in which an ultrahigh vacuum (better than O020403100006 10**(-9) Torr) was progressively attained by pumping O020403100007 and baking all elements. Targets were baked several O020403100008 days at 80. to 100. degr.C and authors checked that O020403100009 this procedure did not outgas any spallogenic O020403100010 krypton. Each foil was then melted inside a O020403100011 molybdenum crucible heated by an electronic O020403100012 bombardment oven routinely operating at 1900.degr.C. O020403100013 Extracted gases were exposed in two step to Ti and O020403100014 Cu-O-Pd getters between 700. and 200.degr.C for O020403100015 eliminating active species. Krypton(95-98%) was then O020403100016 adsorbed on a first activated charcoal trap at -120 O020403100017 degr. The remainder was adsorbed together with 98-99% O020403100018 argon on a second trap at -196 degr.C. Argon and O020403100019 krypton were successively introduced into mass O020403100020 spectrometer. O020403100021 STATUS (TABLE) Tbl.VI from Phys.Rev.,C26(1982)931 O020403100022 HISTORY (20190823U) DATA-ERR -> ERR-T. STATUS added. O020403100023 ENDBIB 21 0 O020403100024 NOCOMMON 0 0 O020403100025 DATA 4 7 O020403100026 EN DATA ERR-T MONIT O020403100027 MEV MB MB MB O020403100028 59. 2.55 0.26 28.0 O020403100029 150. 39.1 3.9 17.2 O020403100030 168. 54.8 5.4 16.6 O020403100031 200. 64. 6. 16.1 O020403100032 1000. 52. 5. 15.3 O020403100033 2500. 34.4 3.4 11.3 O020403100034 24000. 26.9 2.7 10.1 O020403100035 ENDDATA 9 0 O020403100036 ENDSUBENT 35 0 O020403199999 SUBENT O0204032 20190823 O071O020403200001 BIB 4 21 O020403200002 REACTION (40-ZR-90(P,X)36-KR-84,CUM,SIG) O020403200003 METHOD (ASEP) Several months after irradiation targets and O020403200004 blank foils were stored (ten a time) in an extraction O020403200005 system in which an ultrahigh vacuum (better than O020403200006 10**(-9) Torr) was progressively attained by pumping O020403200007 and baking all elements. Targets were baked several O020403200008 days at 80. to 100. degr.C and authors checked that O020403200009 this procedure did not outgas any spallogenic O020403200010 krypton. Each foil was then melted inside a O020403200011 molybdenum crucible heated by an electronic O020403200012 bombardment oven routinely operating at 1900.degr.C. O020403200013 Extracted gases were exposed in two step to Ti and O020403200014 Cu-O-Pd getters between 700. and 200.degr.C for O020403200015 eliminating active species. Krypton(95-98%) was then O020403200016 adsorbed on a first activated charcoal trap at -120 O020403200017 degr. The remainder was adsorbed together with 98-99% O020403200018 argon on a second trap at -196 degr.C. Argon and O020403200019 krypton were successively introduced into mass O020403200020 spectrometer. O020403200021 STATUS (TABLE) Tbl.VI from Phys.Rev.,C26(1982)931 O020403200022 HISTORY (20190823U) DATA-ERR -> ERR-T. STATUS added. O020403200023 ENDBIB 21 0 O020403200024 NOCOMMON 0 0 O020403200025 DATA 4 7 O020403200026 EN DATA ERR-T MONIT O020403200027 MEV MB MB MB O020403200028 59. 0.90 0.09 28.0 O020403200029 75. 2.64 0.26 23.7 O020403200030 168. 5.6 0.6 16.6 O020403200031 200. 7.45 0.75 16.1 O020403200032 1000. 10.7 1.1 15.3 O020403200033 2500. 7.6 0.76 11.3 O020403200034 24000. 6.6 0.7 10.1 O020403200035 ENDDATA 9 0 O020403200036 ENDSUBENT 35 0 O020403299999 SUBENT O0204033 20190823 O071O020403300001 BIB 4 21 O020403300002 REACTION (40-ZR-90(P,X)36-KR-85-G,CUM,SIG) O020403300003 METHOD (ASEP) Several months after irradiation targets and O020403300004 blank foils were stored (ten a time) in an extraction O020403300005 system in which an ultrahigh vacuum (better than O020403300006 10**(-9) Torr) was progressively attained by pumping O020403300007 and baking all elements. Targets were baked several O020403300008 days at 80. to 100. degr.C and authors checked that O020403300009 this procedure did not outgas any spallogenic O020403300010 krypton. Each foil was then melted inside a O020403300011 molybdenum crucible heated by an electronic O020403300012 bombardment oven routinely operating at 1900.degr.C. O020403300013 Extracted gases were exposed in two step to Ti and O020403300014 Cu-O-Pd getters between 700. and 200.degr.C for O020403300015 eliminating active species. Krypton(95-98%) was then O020403300016 adsorbed on a first activated charcoal trap at -120 O020403300017 degr. The remainder was adsorbed together with 98-99% O020403300018 argon on a second trap at -196 degr.C. Argon and O020403300019 krypton were successively introduced into mass O020403300020 spectrometer. O020403300021 STATUS (TABLE) Tbl.VI from Phys.Rev.,C26(1982)931 O020403300022 HISTORY (20190823U) DATA-ERR -> ERR-T. STATUS added. O020403300023 ENDBIB 21 0 O020403300024 NOCOMMON 0 0 O020403300025 DATA 5 7 O020403300026 EN DATA DATA-MAX ERR-T MONIT O020403300027 MEV MB MB MB MB O020403300028 59. 0.001 28.0 O020403300029 75. 0.0039 0.0018 23.7 O020403300030 168. 0.048 0.011 16.6 O020403300031 200. 0.088 0.010 16.1 O020403300032 1000. 0.24 0.06 15.3 O020403300033 2500. 0.19 0.02 11.3 O020403300034 24000. 0.28 0.03 10.1 O020403300035 ENDDATA 9 0 O020403300036 ENDSUBENT 35 0 O020403399999 SUBENT O0204034 20190823 O071O020403400001 BIB 4 21 O020403400002 REACTION (40-ZR-90(P,X)36-KR-86,CUM,SIG) O020403400003 METHOD (ASEP) Several months after irradiation targets and O020403400004 blank foils were stored (ten a time) in an extraction O020403400005 system in which an ultrahigh vacuum (better than O020403400006 10**(-9) Torr) was progressively attained by pumping O020403400007 and baking all elements. Targets were baked several O020403400008 days at 80. to 100. degr.C and authors checked that O020403400009 this procedure did not outgas any spallogenic O020403400010 krypton. Each foil was then melted inside a O020403400011 molybdenum crucible heated by an electronic O020403400012 bombardment oven routinely operating at 1900.degr.C. O020403400013 Extracted gases were exposed in two step to Ti and O020403400014 Cu-O-Pd getters between 700. and 200.degr.C for O020403400015 eliminating active species. Krypton(95-98%) was then O020403400016 adsorbed on a first activated charcoal trap at -120 O020403400017 degr. The remainder was adsorbed together with 98-99% O020403400018 argon on a second trap at -196 degr.C. Argon and O020403400019 krypton were successively introduced into mass O020403400020 spectrometer. O020403400021 STATUS (TABLE) Tbl.VI from Phys.Rev.,C26(1982)931 O020403400022 HISTORY (20190823U) DATA-ERR -> ERR-T. STATUS added. O020403400023 ENDBIB 21 0 O020403400024 NOCOMMON 0 0 O020403400025 DATA 4 5 O020403400026 EN DATA ERR-T MONIT O020403400027 MEV MB MB MB O020403400028 168. 0.0124 0.0016 16.6 O020403400029 200. 0.038 0.006 16.1 O020403400030 1005. 0.074 0.019 15.3 O020403400031 2500. 0.07 0.007 11.3 O020403400032 24000. 0.11 0.01 10.1 O020403400033 ENDDATA 7 0 O020403400034 ENDSUBENT 33 0 O020403499999 SUBENT O0204035 20190823 O071O020403500001 BIB 6 6 O020403500002 REACTION (40-ZR-0(P,X)4-BE-7,,SIG) O020403500003 METHOD (ACTIV) O020403500004 DETECTOR (GELI) O020403500005 DECAY-DATA (4-BE-7,53.3D,DG,478.0,0.1035) O020403500006 STATUS (TABLE) Tbl.IX from Phys.Rev.,C26(1982)931 O020403500007 HISTORY (20190823U) DATA-ERR -> ERR-T. STATUS added. O020403500008 ENDBIB 6 0 O020403500009 NOCOMMON 0 0 O020403500010 DATA 4 1 O020403500011 EN DATA ERR-T MONIT O020403500012 MEV MB MB MB O020403500013 2500. 10. 4.5 11.3 O020403500014 ENDDATA 3 0 O020403500015 ENDSUBENT 14 0 O020403599999 SUBENT O0204036 20190823 O071O020403600001 BIB 6 6 O020403600002 REACTION (40-ZR-0(P,X)11-NA-22,CUM,SIG) O020403600003 METHOD (ACTIV) O020403600004 DETECTOR (GELI) O020403600005 DECAY-DATA (11-NA-22,2.602YR,DG,1275.,0.9993) O020403600006 STATUS (TABLE) Tbl.IX from Phys.Rev.,C26(1982)931 O020403600007 HISTORY (20190823U) DATA-ERR -> ERR-T. STATUS added. O020403600008 ENDBIB 6 0 O020403600009 NOCOMMON 0 0 O020403600010 DATA 4 1 O020403600011 EN DATA ERR-T MONIT O020403600012 MEV MB MB MB O020403600013 24000. 1.6 0.3 10.1 O020403600014 ENDDATA 3 0 O020403600015 ENDSUBENT 14 0 O020403699999 SUBENT O0204037 20190823 O071O020403700001 BIB 6 7 O020403700002 REACTION (40-ZR-0(P,X)21-SC-46-G,M+,SIG) O020403700003 METHOD (ACTIV) O020403700004 DETECTOR (GELI) O020403700005 DECAY-DATA (21-SC-46-G,83.8D,DG,889.,1., O020403700006 DG,1120.,1.) O020403700007 STATUS (TABLE) Tbl.IX from Phys.Rev.,C26(1982)931 O020403700008 HISTORY (20190823U) DATA-ERR -> ERR-T. STATUS added. O020403700009 ENDBIB 7 0 O020403700010 NOCOMMON 0 0 O020403700011 DATA 4 2 O020403700012 EN DATA ERR-T MONIT O020403700013 MEV MB MB MB O020403700014 2500. 3.1 0.4 11.3 O020403700015 24000. 3.1 0.4 10.1 O020403700016 ENDDATA 4 0 O020403700017 ENDSUBENT 16 0 O020403799999 SUBENT O0204038 20190823 O071O020403800001 BIB 6 6 O020403800002 REACTION (40-ZR-0(P,X)23-V-48,CUM,SIG) O020403800003 METHOD (ACTIV) O020403800004 DETECTOR (GELI) O020403800005 DECAY-DATA (23-V-48,15.98D,DG,984.,1.) O020403800006 STATUS (TABLE) Tbl.IX from Phys.Rev.,C26(1982)931 O020403800007 HISTORY (20190823U) DATA-ERR -> ERR-T. STATUS added. O020403800008 ENDBIB 6 0 O020403800009 NOCOMMON 0 0 O020403800010 DATA 4 2 O020403800011 EN DATA ERR-T MONIT O020403800012 MEV MB MB MB O020403800013 1005. 0.95 0.15 15.3 O020403800014 2500. 3.3 0.4 11.3 O020403800015 ENDDATA 4 0 O020403800016 ENDSUBENT 15 0 O020403899999 SUBENT O0204039 20190823 O071O020403900001 BIB 6 6 O020403900002 REACTION (40-ZR-0(P,X)24-CR-51,CUM,SIG) O020403900003 METHOD (ACTIV) O020403900004 DETECTOR (GELI) O020403900005 DECAY-DATA (24-CR-51,27.7D,DG,320.,0.102) O020403900006 STATUS (TABLE) Tbl.IX from Phys.Rev.,C26(1982)931 O020403900007 HISTORY (20190823U) DATA-ERR -> ERR-T. STATUS added. O020403900008 ENDBIB 6 0 O020403900009 NOCOMMON 0 0 O020403900010 DATA 4 2 O020403900011 EN DATA ERR-T MONIT O020403900012 MEV MB MB MB O020403900013 1005. 3.8 1.3 15.3 O020403900014 2500. 8.6 2.8 11.3 O020403900015 ENDDATA 4 0 O020403900016 ENDSUBENT 15 0 O020403999999 SUBENT O0204040 20190823 O071O020404000001 BIB 6 6 O020404000002 REACTION (40-ZR-0(P,X)25-MN-54,,SIG) O020404000003 METHOD (ACTIV) O020404000004 DETECTOR (GELI) O020404000005 DECAY-DATA (25-MN-54,312.2D,DG,835.,1.) O020404000006 STATUS (TABLE) Tbl.IX from Phys.Rev.,C26(1982)931 O020404000007 HISTORY (20190823U) DATA-ERR -> ERR-T. STATUS added. O020404000008 ENDBIB 6 0 O020404000009 NOCOMMON 0 0 O020404000010 DATA 4 3 O020404000011 EN DATA ERR-T MONIT O020404000012 MEV MB MB MB O020404000013 1005. 9.5 5.0 15.3 O020404000014 2500. 14. 7. 11.3 O020404000015 24000. 6. 3. 10.1 O020404000016 ENDDATA 5 0 O020404000017 ENDSUBENT 16 0 O020404099999 SUBENT O0204041 20190823 O071O020404100001 BIB 6 6 O020404100002 REACTION (40-ZR-0(P,X)27-CO-56,CUM,SIG) O020404100003 METHOD (ACTIV) O020404100004 DETECTOR (GELI) O020404100005 DECAY-DATA (27-CO-56,78.76D,DG,847.,0.9995) O020404100006 STATUS (TABLE) Tbl.IX from Phys.Rev.,C26(1982)931 O020404100007 HISTORY (20190823U) DATA-ERR -> ERR-T. STATUS added. O020404100008 ENDBIB 6 0 O020404100009 NOCOMMON 0 0 O020404100010 DATA 4 3 O020404100011 EN DATA ERR-T MONIT O020404100012 MEV MB MB MB O020404100013 1005. 1.2 0.2 15.3 O020404100014 2500. 2.3 0.5 11.3 O020404100015 24000. 1.5 0.2 10.1 O020404100016 ENDDATA 5 0 O020404100017 ENDSUBENT 16 0 O020404199999 SUBENT O0204042 20190823 O071O020404200001 BIB 6 6 O020404200002 REACTION (40-ZR-0(P,X)27-CO-58-G,M+,SIG) O020404200003 METHOD (ACTIV) O020404200004 DETECTOR (GELI) O020404200005 DECAY-DATA (27-CO-58-G,70.78D,DG,811.,1.) O020404200006 STATUS (TABLE) Tbl.IX from Phys.Rev.,C26(1982)931 O020404200007 HISTORY (20190823U) DATA-ERR -> ERR-T. STATUS added. O020404200008 ENDBIB 6 0 O020404200009 NOCOMMON 0 0 O020404200010 DATA 4 3 O020404200011 EN DATA ERR-T MONIT O020404200012 MEV MB MB MB O020404200013 1005. 10.3 3.0 15.3 O020404200014 2500. 12.2 1.5 11.3 O020404200015 24000. 10.7 2.0 10.1 O020404200016 ENDDATA 5 0 O020404200017 ENDSUBENT 16 0 O020404299999 SUBENT O0204043 20190823 O071O020404300001 BIB 6 6 O020404300002 REACTION (40-ZR-0(P,X)30-ZN-65,CUM,SIG) O020404300003 METHOD (ACTIV) O020404300004 DETECTOR (GELI) O020404300005 DECAY-DATA (30-ZN-65,244.D,DG,1116.,0.5075) O020404300006 STATUS (TABLE) Tbl.IX from Phys.Rev.,C26(1982)931 O020404300007 HISTORY (20190823U) DATA-ERR -> ERR-T. STATUS added. O020404300008 ENDBIB 6 0 O020404300009 NOCOMMON 0 0 O020404300010 DATA 4 3 O020404300011 EN DATA ERR-T MONIT O020404300012 MEV MB MB MB O020404300013 1005. 17.2 2.5 15.3 O020404300014 2500. 16. 2. 11.3 O020404300015 24000. 10. 1.5 10.1 O020404300016 ENDDATA 5 0 O020404300017 ENDSUBENT 16 0 O020404399999 SUBENT O0204044 20190823 O071O020404400001 BIB 6 6 O020404400002 REACTION (39-Y-89(P,X)4-BE-7,,SIG) O020404400003 METHOD (ACTIV) O020404400004 DETECTOR (GELI) O020404400005 DECAY-DATA (4-BE-7,53.3D,DG,478.0,0.1035) O020404400006 STATUS (TABLE) Tbl.IX from Phys.Rev.,C26(1982)931 O020404400007 HISTORY (20190823U) DATA-ERR -> ERR-T. STATUS added. O020404400008 ENDBIB 6 0 O020404400009 NOCOMMON 0 0 O020404400010 DATA 4 2 O020404400011 EN DATA ERR-T MONIT O020404400012 MEV MB MB MB O020404400013 1005. 10.0 2.0 15.3 O020404400014 2500. 12.0 2.4 11.3 O020404400015 ENDDATA 4 0 O020404400016 ENDSUBENT 15 0 O020404499999 SUBENT O0204045 20190823 O071O020404500001 BIB 6 6 O020404500002 REACTION (39-Y-89(P,X)11-NA-22,CUM,SIG) O020404500003 METHOD (ACTIV) O020404500004 DETECTOR (GELI) O020404500005 DECAY-DATA (11-NA-22,2.602YR,DG,1275.,0.9993) O020404500006 STATUS (TABLE) Tbl.IX from Phys.Rev.,C26(1982)931 O020404500007 HISTORY (20190823U) DATA-ERR -> ERR-T. STATUS added. O020404500008 ENDBIB 6 0 O020404500009 NOCOMMON 0 0 O020404500010 DATA 4 2 O020404500011 EN DATA ERR-T MONIT O020404500012 MEV MB MB MB O020404500013 2500. 1.6 0.3 11.3 O020404500014 24000. 2.2 0.4 10.1 O020404500015 ENDDATA 4 0 O020404500016 ENDSUBENT 15 0 O020404599999 SUBENT O0204046 20190823 O071O020404600001 BIB 6 7 O020404600002 REACTION (39-Y-89(P,X)21-SC-46-G,M+,SIG) O020404600003 METHOD (ACTIV) O020404600004 DETECTOR (GELI) O020404600005 DECAY-DATA (21-SC-46-G,83.8D,DG,889.,1., O020404600006 DG,1120.,1.) O020404600007 STATUS (TABLE) Tbl.IX from Phys.Rev.,C26(1982)931 O020404600008 HISTORY (20190823U) DATA-ERR -> ERR-T. STATUS added. O020404600009 ENDBIB 7 0 O020404600010 NOCOMMON 0 0 O020404600011 DATA 4 2 O020404600012 EN DATA ERR-T MONIT O020404600013 MEV MB MB MB O020404600014 2500. 3.4 0.4 11.3 O020404600015 24000. 3.5 0.4 10.1 O020404600016 ENDDATA 4 0 O020404600017 ENDSUBENT 16 0 O020404699999 SUBENT O0204047 20190823 O071O020404700001 BIB 6 6 O020404700002 REACTION (39-Y-89(P,X)23-V-48,CUM,SIG) O020404700003 METHOD (ACTIV) O020404700004 DETECTOR (GELI) O020404700005 DECAY-DATA (23-V-48,15.98D,DG,984.,1.) O020404700006 STATUS (TABLE) Tbl.IX from Phys.Rev.,C26(1982)931 O020404700007 HISTORY (20190823U) DATA-ERR -> ERR-T. STATUS added. O020404700008 ENDBIB 6 0 O020404700009 NOCOMMON 0 0 O020404700010 DATA 4 2 O020404700011 EN DATA ERR-T MONIT O020404700012 MEV MB MB MB O020404700013 1005. 1.1 0.2 15.3 O020404700014 2500. 3.5 0.4 11.3 O020404700015 ENDDATA 4 0 O020404700016 ENDSUBENT 15 0 O020404799999 SUBENT O0204048 20190823 O071O020404800001 BIB 6 6 O020404800002 REACTION (39-Y-89(P,X)24-CR-51,CUM,SIG) O020404800003 METHOD (ACTIV) O020404800004 DETECTOR (GELI) O020404800005 DECAY-DATA (24-CR-51,27.7D,DG,320.,0.102) O020404800006 STATUS (TABLE) Tbl.IX from Phys.Rev.,C26(1982)931 O020404800007 HISTORY (20190823U) DATA-ERR -> ERR-T. STATUS added. O020404800008 ENDBIB 6 0 O020404800009 NOCOMMON 0 0 O020404800010 DATA 4 2 O020404800011 EN DATA ERR-T MONIT O020404800012 MEV MB MB MB O020404800013 1005. 6.0 2.0 15.3 O020404800014 2500. 9.4 3.5 11.3 O020404800015 ENDDATA 4 0 O020404800016 ENDSUBENT 15 0 O020404899999 SUBENT O0204049 20190823 O071O020404900001 BIB 6 6 O020404900002 REACTION (39-Y-89(P,X)25-MN-54,,SIG) O020404900003 METHOD (ACTIV) O020404900004 DETECTOR (GELI) O020404900005 DECAY-DATA (25-MN-54,312.2D,DG,835.,1.) O020404900006 STATUS (TABLE) Tbl.IX from Phys.Rev.,C26(1982)931 O020404900007 HISTORY (20190823U) DATA-ERR -> ERR-T. STATUS added. O020404900008 ENDBIB 6 0 O020404900009 NOCOMMON 0 0 O020404900010 DATA 4 3 O020404900011 EN DATA ERR-T MONIT O020404900012 MEV MB MB MB O020404900013 1005. 11.5 6. 15.3 O020404900014 2500. 14. 7. 11.3 O020404900015 24000. 6.2 3.0 10.1 O020404900016 ENDDATA 5 0 O020404900017 ENDSUBENT 16 0 O020404999999 SUBENT O0204050 20190823 O071O020405000001 BIB 6 6 O020405000002 REACTION (39-Y-89(P,X)27-CO-56,CUM,SIG) O020405000003 METHOD (ACTIV) O020405000004 DETECTOR (GELI) O020405000005 DECAY-DATA (27-CO-56,78.76D,DG,847.,0.9995) O020405000006 STATUS (TABLE) Tbl.IX from Phys.Rev.,C26(1982)931 O020405000007 HISTORY (20190823U) DATA-ERR -> ERR-T. STATUS added. O020405000008 ENDBIB 6 0 O020405000009 NOCOMMON 0 0 O020405000010 DATA 4 3 O020405000011 EN DATA ERR-T MONIT O020405000012 MEV MB MB MB O020405000013 1005. 1.9 0.4 15.3 O020405000014 2500. 1.9 0.4 11.3 O020405000015 24000. 1.7 0.3 10.1 O020405000016 ENDDATA 5 0 O020405000017 ENDSUBENT 16 0 O020405099999 SUBENT O0204051 20190823 O071O020405100001 BIB 6 6 O020405100002 REACTION (39-Y-89(P,X)27-CO-58-G,M+,SIG) O020405100003 METHOD (ACTIV) O020405100004 DETECTOR (GELI) O020405100005 DECAY-DATA (27-CO-58-G,70.78D,DG,811.,1.) O020405100006 STATUS (TABLE) Tbl.IX from Phys.Rev.,C26(1982)931 O020405100007 HISTORY (20190823U) DATA-ERR -> ERR-T. STATUS added. O020405100008 ENDBIB 6 0 O020405100009 NOCOMMON 0 0 O020405100010 DATA 4 3 O020405100011 EN DATA ERR-T MONIT O020405100012 MEV MB MB MB O020405100013 1005. 14.3 3.6 15.3 O020405100014 2500. 14.2 2.3 11.3 O020405100015 24000. 10.3 2.0 10.1 O020405100016 ENDDATA 5 0 O020405100017 ENDSUBENT 16 0 O020405199999 SUBENT O0204052 20190823 O071O020405200001 BIB 6 6 O020405200002 REACTION (39-Y-89(P,X)30-ZN-65,CUM,SIG) O020405200003 METHOD (ACTIV) O020405200004 DETECTOR (GELI) O020405200005 DECAY-DATA (30-ZN-65,244.D,DG,1116.,0.5075) O020405200006 STATUS (TABLE) Tbl.IX from Phys.Rev.,C26(1982)931 O020405200007 HISTORY (20190823U) DATA-ERR -> ERR-T. STATUS added. O020405200008 ENDBIB 6 0 O020405200009 NOCOMMON 0 0 O020405200010 DATA 4 3 O020405200011 EN DATA ERR-T MONIT O020405200012 MEV MB MB MB O020405200013 1005. 22.4 3.0 15.3 O020405200014 2500. 15. 4. 11.3 O020405200015 24000. 11. 3. 10.1 O020405200016 ENDDATA 5 0 O020405200017 ENDSUBENT 16 0 O020405299999 SUBENT O0204053 20190823 O071O020405300001 BIB 6 6 O020405300002 REACTION (39-Y-89(P,X)25-MN-52-G,CUM,SIG) O020405300003 METHOD (ACTIV) O020405300004 DETECTOR (GELI) O020405300005 DECAY-DATA (25-MN-52-G,5.59D,DG,1434.,1.) O020405300006 STATUS (TABLE) Tbl.IX from Phys.Rev.,C26(1982)931 O020405300007 HISTORY (20190823U) DATA-ERR -> ERR-T. STATUS added. O020405300008 ENDBIB 6 0 O020405300009 NOCOMMON 0 0 O020405300010 DATA 4 2 O020405300011 EN DATA ERR-T MONIT O020405300012 MEV MB MB MB O020405300013 1005. 2.5 0.8 15.3 O020405300014 2500. 2.2 0.4 11.3 O020405300015 ENDDATA 4 0 O020405300016 ENDSUBENT 15 0 O020405399999 SUBENT O0204054 20190823 O071O020405400001 BIB 6 6 O020405400002 REACTION (39-Y-89(P,X)26-FE-59,CUM,SIG) O020405400003 METHOD (ACTIV) O020405400004 DETECTOR (GELI) O020405400005 DECAY-DATA (26-FE-59,44.56D,DG,1099.,0.565) O020405400006 STATUS (TABLE) Tbl.IX from Phys.Rev.,C26(1982)931 O020405400007 HISTORY (20190823U) DATA-ERR -> ERR-T. STATUS added. O020405400008 ENDBIB 6 0 O020405400009 NOCOMMON 0 0 O020405400010 DATA 4 2 O020405400011 EN DATA ERR-T MONIT O020405400012 MEV MB MB MB O020405400013 1005. 4.3 1.0 15.3 O020405400014 2500. 5.4 1.2 11.3 O020405400015 ENDDATA 4 0 O020405400016 ENDSUBENT 15 0 O020405499999 SUBENT O0204055 20190823 O071O020405500001 BIB 6 8 O020405500002 REACTION (39-Y-89(P,X)27-CO-60,,SIG) O020405500003 METHOD (ACTIV) O020405500004 DETECTOR (GELI) O020405500005 DECAY-DATA (27-CO-60-G,5.272YR,DG,1173.,1.) O020405500006 STATUS (TABLE) Tbl.IX from Phys.Rev.,C26(1982)931 O020405500007 HISTORY (20190823A) SF3=17N+13P -> X, SF4=Co-60g -> Co-60, SF5 O020405500008 deleted from REACTION code. DATA-ERR -> ERR-T. O020405500009 STATUS added. O020405500010 ENDBIB 8 0 O020405500011 NOCOMMON 0 0 O020405500012 DATA 4 1 O020405500013 EN DATA ERR-T MONIT O020405500014 MEV MB MB MB O020405500015 2500. 2.7 0.8 11.3 O020405500016 ENDDATA 3 0 O020405500017 ENDSUBENT 16 0 O020405599999 SUBENT O0204056 20190823 O071O020405600001 BIB 4 22 O020405600002 REACTION (39-Y-89(P,X)18-AR-36,,SIG) O020405600003 METHOD (ASEP) Several months after irradiation targets and O020405600004 blank foils were stored (ten a time) in an extraction O020405600005 system in which an ultrahigh vacuum (better than O020405600006 10**(-9) Torr) was progressively attained by pumping O020405600007 and baking all elements. Targets were baked several O020405600008 days at 80. to 100. degr.C and authors checked that O020405600009 this procedure did not outgas any spallogenic O020405600010 krypton. Each foil was then melted inside a O020405600011 molybdenum crucible heated by an electronic O020405600012 bombardment oven routinely operating at 1900.degr.C. O020405600013 Extracted gases were exposed in two step to Ti and O020405600014 Cu-O-Pd getters between 700. and 200.degr.C for O020405600015 eliminating active species. Krypton(95-98%) was then O020405600016 adsorbed on a first activated charcoal trap at -120 O020405600017 degr. The remainder was adsorbed together with 98-99% O020405600018 argon on a second trap at -196 degr.C. Argon and O020405600019 krypton were successively introduced into mass O020405600020 spectrometer. O020405600021 STATUS (TABLE) Tbl.X from Phys.Rev.,C26(1982)931 O020405600022 HISTORY (20190823A) SD: SF5=IND deleted from REACTION code. O020405600023 DATA-ERR -> ERR-T. O020405600024 ENDBIB 22 0 O020405600025 NOCOMMON 0 0 O020405600026 DATA 4 1 O020405600027 EN DATA ERR-T MONIT O020405600028 MEV MB MB MB O020405600029 24000. 0.5 0.1 10.1 O020405600030 ENDDATA 3 0 O020405600031 ENDSUBENT 30 0 O020405699999 SUBENT O0204057 20190823 O071O020405700001 BIB 4 21 O020405700002 REACTION (39-Y-89(P,X)18-AR-38,CUM,SIG) O020405700003 METHOD (ASEP) Several months after irradiation targets and O020405700004 blank foils were stored (ten a time) in an extraction O020405700005 system in which an ultrahigh vacuum (better than O020405700006 10**(-9) Torr) was progressively attained by pumping O020405700007 and baking all elements. Targets were baked several O020405700008 days at 80. to 100. degr.C and authors checked that O020405700009 this procedure did not outgas any spallogenic O020405700010 krypton. Each foil was then melted inside a O020405700011 molybdenum crucible heated by an electronic O020405700012 bombardment oven routinely operating at 1900.degr.C. O020405700013 Extracted gases were exposed in two step to Ti and O020405700014 Cu-O-Pd getters between 700. and 200.degr.C for O020405700015 eliminating active species. Krypton(95-98%) was then O020405700016 adsorbed on a first activated charcoal trap at -120 O020405700017 degr. The remainder was adsorbed together with 98-99% O020405700018 argon on a second trap at -196 degr.C. Argon and O020405700019 krypton were successively introduced into mass O020405700020 spectrometer. O020405700021 STATUS (TABLE) Tbl.X from Phys.Rev.,C26(1982)931 O020405700022 HISTORY (20190823U) SD: DATA-ERR -> ERR-T. O020405700023 ENDBIB 21 0 O020405700024 NOCOMMON 0 0 O020405700025 DATA 4 3 O020405700026 EN DATA ERR-T MONIT O020405700027 MEV MB MB MB O020405700028 1005. 1.1 0.2 15.3 O020405700029 2500. 3.0 1.0 11.3 O020405700030 24000. 5.6 1.0 10.1 O020405700031 ENDDATA 5 0 O020405700032 ENDSUBENT 31 0 O020405799999 SUBENT O0204058 20190823 O071O020405800001 BIB 4 21 O020405800002 REACTION (39-Y-89(P,X)18-AR-39,CUM,SIG) O020405800003 METHOD (ASEP) Several months after irradiation targets and O020405800004 blank foils were stored (ten a time) in an extraction O020405800005 system in which an ultrahigh vacuum (better than O020405800006 10**(-9) Torr) was progressively attained by pumping O020405800007 and baking all elements. Targets were baked several O020405800008 days at 80. to 100. degr.C and authors checked that O020405800009 this procedure did not outgas any spallogenic O020405800010 krypton. Each foil was then melted inside a O020405800011 molybdenum crucible heated by an electronic O020405800012 bombardment oven routinely operating at 1900.degr.C. O020405800013 Extracted gases were exposed in two step to Ti and O020405800014 Cu-O-Pd getters between 700. and 200.degr.C for O020405800015 eliminating active species. Krypton(95-98%) was then O020405800016 adsorbed on a first activated charcoal trap at -120 O020405800017 degr. The remainder was adsorbed together with 98-99% O020405800018 argon on a second trap at -196 degr.C. Argon and O020405800019 krypton were successively introduced into mass O020405800020 spectrometer. O020405800021 STATUS (TABLE) Tbl.X from Phys.Rev.,C26(1982)931 O020405800022 HISTORY (20190823U) SD: DATA-ERR -> ERR-T. O020405800023 ENDBIB 21 0 O020405800024 NOCOMMON 0 0 O020405800025 DATA 4 3 O020405800026 EN DATA ERR-T MONIT O020405800027 MEV MB MB MB O020405800028 1005. 0.54 0.15 15.3 O020405800029 2500. 2.7 0.5 11.3 O020405800030 24000. 3.7 0.6 10.1 O020405800031 ENDDATA 5 0 O020405800032 ENDSUBENT 31 0 O020405899999 SUBENT O0204059 20190823 O071O020405900001 BIB 4 22 O020405900002 REACTION (40-ZR-0(P,X)18-AR-36,,SIG) O020405900003 METHOD (ASEP) Several months after irradiation targets and O020405900004 blank foils were stored (ten a time) in an extraction O020405900005 system in which an ultrahigh vacuum (better than O020405900006 10**(-9) Torr) was progressively attained by pumping O020405900007 and baking all elements. Targets were baked several O020405900008 days at 80. to 100. degr.C and authors checked that O020405900009 this procedure did not outgas any spallogenic O020405900010 krypton. Each foil was then melted inside a O020405900011 molybdenum crucible heated by an electronic O020405900012 bombardment oven routinely operating at 1900.degr.C. O020405900013 Extracted gases were exposed in two step to Ti and O020405900014 Cu-O-Pd getters between 700. and 200.degr.C for O020405900015 eliminating active species. Krypton(95-98%) was then O020405900016 adsorbed on a first activated charcoal trap at -120 O020405900017 degr. The remainder was adsorbed together with 98-99% O020405900018 argon on a second trap at -196 degr.C. Argon and O020405900019 krypton were successively introduced into mass O020405900020 spectrometer. O020405900021 STATUS (TABLE) Tbl.X from Phys.Rev.,C26(1982)931 O020405900022 HISTORY (20190823A) SD: SF5=IND deleted from REACTION code. O020405900023 DATA-ERR -> ERR-T. O020405900024 ENDBIB 22 0 O020405900025 NOCOMMON 0 0 O020405900026 DATA 4 1 O020405900027 EN DATA ERR-T MONIT O020405900028 MEV MB MB MB O020405900029 24000. 0.34 0.16 10.1 O020405900030 ENDDATA 3 0 O020405900031 ENDSUBENT 30 0 O020405999999 SUBENT O0204060 20190823 O071O020406000001 BIB 4 21 O020406000002 REACTION (40-ZR-0(P,X)18-AR-38,CUM,SIG) O020406000003 METHOD (ASEP) Several months after irradiation targets and O020406000004 blank foils were stored (ten a time) in an extraction O020406000005 system in which an ultrahigh vacuum (better than O020406000006 10**(-9) Torr) was progressively attained by pumping O020406000007 and baking all elements. Targets were baked several O020406000008 days at 80. to 100. degr.C and authors checked that O020406000009 this procedure did not outgas any spallogenic O020406000010 krypton. Each foil was then melted inside a O020406000011 molybdenum crucible heated by an electronic O020406000012 bombardment oven routinely operating at 1900.degr.C. O020406000013 Extracted gases were exposed in two step to Ti and O020406000014 Cu-O-Pd getters between 700. and 200.degr.C for O020406000015 eliminating active species. Krypton(95-98%) was then O020406000016 adsorbed on a first activated charcoal trap at -120 O020406000017 degr. The remainder was adsorbed together with 98-99% O020406000018 argon on a second trap at -196 degr.C. Argon and O020406000019 krypton were successively introduced into mass O020406000020 spectrometer. O020406000021 STATUS (TABLE) Tbl.X from Phys.Rev.,C26(1982)931 O020406000022 HISTORY (20190823U) SD: DATA-ERR -> ERR-T. O020406000023 ENDBIB 21 0 O020406000024 NOCOMMON 0 0 O020406000025 DATA 4 3 O020406000026 EN DATA ERR-T MONIT O020406000027 MEV MB MB MB O020406000028 1005. 0.9 0.7 15.3 O020406000029 2500. 4.1 1.4 11.3 O020406000030 24000. 5.1 0.8 10.1 O020406000031 ENDDATA 5 0 O020406000032 ENDSUBENT 31 0 O020406099999 SUBENT O0204061 20190823 O071O020406100001 BIB 4 21 O020406100002 REACTION (40-ZR-0(P,X)18-AR-39,CUM,SIG) O020406100003 METHOD (ASEP) Several months after irradiation targets and O020406100004 blank foils were stored (ten a time) in an extraction O020406100005 system in which an ultrahigh vacuum (better than O020406100006 10**(-9) Torr) was progressively attained by pumping O020406100007 and baking all elements. Targets were baked several O020406100008 days at 80. to 100. degr.C and authors checked that O020406100009 this procedure did not outgas any spallogenic O020406100010 krypton. Each foil was then melted inside a O020406100011 molybdenum crucible heated by an electronic O020406100012 bombardment oven routinely operating at 1900.degr.C. O020406100013 Extracted gases were exposed in two step to Ti and O020406100014 Cu-O-Pd getters between 700. and 200.degr.C for O020406100015 eliminating active species. Krypton(95-98%) was then O020406100016 adsorbed on a first activated charcoal trap at -120 O020406100017 degr. The remainder was adsorbed together with 98-99% O020406100018 argon on a second trap at -196 degr.C. Argon and O020406100019 krypton were successively introduced into mass O020406100020 spectrometer. O020406100021 STATUS (TABLE) Tbl.X from Phys.Rev.,C26(1982)931 O020406100022 HISTORY (20190823U) SD: DATA-ERR -> ERR-T. O020406100023 ENDBIB 21 0 O020406100024 NOCOMMON 0 0 O020406100025 DATA 4 3 O020406100026 EN DATA ERR-T MONIT O020406100027 MEV MB MB MB O020406100028 1005. 1.0 0.2 15.3 O020406100029 2500. 2.5 0.3 11.3 O020406100030 24000. 3.3 0.4 10.1 O020406100031 ENDDATA 5 0 O020406100032 ENDSUBENT 31 0 O020406199999 SUBENT O0204062 20190823 O071O020406200001 BIB 4 21 O020406200002 REACTION (40-ZR-0(P,X)18-AR-42,CUM,SIG) O020406200003 METHOD (ASEP) Several months after irradiation targets and O020406200004 blank foils were stored (ten a time) in an extraction O020406200005 system in which an ultrahigh vacuum (better than O020406200006 10**(-9) Torr) was progressively attained by pumping O020406200007 and baking all elements. Targets were baked several O020406200008 days at 80. to 100. degr.C and authors checked that O020406200009 this procedure did not outgas any spallogenic O020406200010 krypton. Each foil was then melted inside a O020406200011 molybdenum crucible heated by an electronic O020406200012 bombardment oven routinely operating at 1900.degr.C. O020406200013 Extracted gases were exposed in two step to Ti and O020406200014 Cu-O-Pd getters between 700. and 200.degr.C for O020406200015 eliminating active species. Krypton(95-98%) was then O020406200016 adsorbed on a first activated charcoal trap at -120 O020406200017 degr. The remainder was adsorbed together with 98-99% O020406200018 argon on a second trap at -196 degr.C. Argon and O020406200019 krypton were successively introduced into mass O020406200020 spectrometer. O020406200021 STATUS (TABLE) Tbl.X from Phys.Rev.,C26(1982)931 O020406200022 HISTORY (20190823U) SD: DATA-ERR -> ERR-T. O020406200023 ENDBIB 21 0 O020406200024 NOCOMMON 0 0 O020406200025 DATA 4 2 O020406200026 EN DATA ERR-T MONIT O020406200027 MEV MB MB MB O020406200028 2500. 0.2 0.06 11.3 O020406200029 24000. 0.17 0.03 10.1 O020406200030 ENDDATA 4 0 O020406200031 ENDSUBENT 30 0 O020406299999 SUBENT O0204063 20190823 O071O020406300001 BIB 7 31 O020406300002 REACTION ((38-SR-0(P,X)36-KR-78,CUM,SIG)/ O020406300003 (38-SR-0(P,X)36-KR-82,CUM,SIG)) O020406300004 METHOD (ASEP) Several months after irradiation targets and O020406300005 blank foils were stored (ten a time) in an extraction O020406300006 system in which an ultrahigh vacuum (better than O020406300007 10**(-9) Torr) was progressively attained by pumping O020406300008 and baking all elements. Targets were baked several O020406300009 days at 80. to 100. degr.C and authors checked that O020406300010 this procedure did not outgas any spallogenic O020406300011 krypton. Each foil was then melted inside a O020406300012 molybdenum crucible heated by an electronic O020406300013 bombardment oven routinely operating at 1900.degr.C. O020406300014 Extracted gases were exposed in two step to Ti and O020406300015 Cu-O-Pd getters between 700. and 200.degr.C for O020406300016 eliminating active species. Krypton(95-98%) was then O020406300017 adsorbed on a first activated charcoal trap at -120 O020406300018 degr. The remainder was adsorbed together with 98-99% O020406300019 argon on a second trap at -196 degr.C. Argon and O020406300020 krypton were successively introduced into mass O020406300021 spectrometer. O020406300022 SAMPLE A Vapor-deposited Sr target,0.16 mg/cm**2 thick O020406300023 ANALYSIS All results average two to four independent measurementO020406300024 weighted by individual errors. O020406300025 COMMENT From authors: Unfortunately, the deposit broke during O020406300026 preparation or handling of the stack, so that only the O020406300027 isotopic composition of spallation produced krypton O020406300028 could be obtained. O020406300029 STATUS (TABLE) text on p.935 of Phys.Rev.,C26(1982)931 O020406300030 HISTORY (20190823A) SD: BIB updated. STATUS, ANALYSIS added. O020406300031 REACTION code corrected: denominator was added. O020406300032 MONIT deleted. DATA-ERR -> ERR-T. MB -> NO-DIM. O020406300033 ENDBIB 31 0 O020406300034 NOCOMMON 0 0 O020406300035 DATA 3 1 O020406300036 EN DATA ERR-T O020406300037 MEV NO-DIM NO-DIM O020406300038 168. 0.23 0.01 O020406300039 ENDDATA 3 0 O020406300040 ENDSUBENT 39 0 O020406399999 SUBENT O0204064 20190823 O071O020406400001 BIB 7 32 O020406400002 REACTION ((38-SR-0(P,X)36-KR-80,CUM,SIG)/ O020406400003 (38-SR-0(P,X)36-KR-82,CUM,SIG)) O020406400004 METHOD (ASEP) Several months after irradiation targets and O020406400005 blank foils were stored (ten a time) in an extraction O020406400006 system in which an ultrahigh vacuum (better than O020406400007 10**(-9) Torr) was progressively attained by pumping O020406400008 and baking all elements. Targets were baked several O020406400009 days at 80. to 100. degr.C and authors checked that O020406400010 this procedure did not outgas any spallogenic O020406400011 krypton. Each foil was then melted inside a O020406400012 molybdenum crucible heated by an electronic O020406400013 bombardment oven routinely operating at 1900.degr.C. O020406400014 Extracted gases were exposed in two step to Ti and O020406400015 Cu-O-Pd getters between 700. and 200.degr.C for O020406400016 eliminating active species. Krypton(95-98%) was then O020406400017 adsorbed on a first activated charcoal trap at -120 O020406400018 degr. The remainder was adsorbed together with 98-99% O020406400019 argon on a second trap at -196 degr.C. Argon and O020406400020 krypton were successively introduced into mass O020406400021 spectrometer. O020406400022 SAMPLE A Vapor-deposited Sr target,0.16 mg/cm**2 thick, was O020406400023 used. O020406400024 ANALYSIS All results average two to four independent measurementO020406400025 weighted by individual errors. O020406400026 COMMENT From authors: Unfortunately, the deposit broke during O020406400027 preparation or handling of the stack, so that only the O020406400028 isotopic composition of spallation produced krypton O020406400029 could be obtained. O020406400030 STATUS (TABLE) text on p.935 of Phys.Rev.,C26(1982)931 O020406400031 HISTORY (20190823A) SD: BIB updated. STATUS, ANALYSIS added. O020406400032 REACTION code corrected: denominator was added. O020406400033 MONIT deleted. DATA-ERR -> ERR-T. MB -> NO-DIM. O020406400034 ENDBIB 32 0 O020406400035 NOCOMMON 0 0 O020406400036 DATA 3 1 O020406400037 EN DATA ERR-T O020406400038 MEV NO-DIM NO-DIM O020406400039 168. 0.62 0.02 O020406400040 ENDDATA 3 0 O020406400041 ENDSUBENT 40 0 O020406499999 SUBENT O0204065 20190823 O071O020406500001 BIB 7 32 O020406500002 REACTION ((38-SR-0(P,X)36-KR-81,CUM,SIG)/ O020406500003 (38-SR-0(P,X)36-KR-82,CUM,SIG)) O020406500004 METHOD (ASEP) Several months after irradiation targets and O020406500005 blank foils were stored (ten a time) in an extraction O020406500006 system in which an ultrahigh vacuum (better than O020406500007 10**(-9) Torr) was progressively attained by pumping O020406500008 and baking all elements. Targets were baked several O020406500009 days at 80. to 100. degr.C and authors checked that O020406500010 this procedure did not outgas any spallogenic O020406500011 krypton. Each foil was then melted inside a O020406500012 molybdenum crucible heated by an electronic O020406500013 bombardment oven routinely operating at 1900.degr.C. O020406500014 Extracted gases were exposed in two step to Ti and O020406500015 Cu-O-Pd getters between 700. and 200.degr.C for O020406500016 eliminating active species. Krypton(95-98%) was then O020406500017 adsorbed on a first activated charcoal trap at -120 O020406500018 degr. The remainder was adsorbed together with 98-99% O020406500019 argon on a second trap at -196 degr.C. Argon and O020406500020 krypton were successively introduced into mass O020406500021 spectrometer. O020406500022 SAMPLE A Vapor-deposited Sr target,0.16 mg/cm**2 thick, was O020406500023 used. O020406500024 ANALYSIS All results average two to four independent measurementO020406500025 weighted by individual errors. O020406500026 COMMENT From authors: Unfortunately, the deposit broke during O020406500027 preparation or handling of the stack, so that only the O020406500028 isotopic composition of spallation produced krypton O020406500029 could be obtained. O020406500030 STATUS (TABLE) text on p.935 of Phys.Rev.,C26(1982)931 O020406500031 HISTORY (20190823A) SD: BIB updated. STATUS, ANALYSIS added. O020406500032 REACTION code corrected: denominator was added. O020406500033 MONIT deleted. DATA-ERR -> ERR-T. MB -> NO-DIM. O020406500034 ENDBIB 32 0 O020406500035 NOCOMMON 0 0 O020406500036 DATA 3 1 O020406500037 EN DATA ERR-T O020406500038 MEV NO-DIM NO-DIM O020406500039 168. 0.82 0.02 O020406500040 ENDDATA 3 0 O020406500041 ENDSUBENT 40 0 O020406599999 NOSUBENT O0204066 20190823 O071O020406600001 SUBENT O0204067 20190823 O071O020406700001 BIB 8 34 O020406700002 REACTION ((38-SR-0(P,X)36-KR-83-G,CUM,SIG)/ O020406700003 (38-SR-0(P,X)36-KR-82,CUM,SIG)) O020406700004 CRITIQUE Kr-83 is daughter of Rb-83, but authors did not O020406700005 explain their method to account Rb-83 decay. O020406700006 METHOD (ASEP) Several months after irradiation targets and O020406700007 blank foils were stored (ten a time) in an extraction O020406700008 system in which an ultrahigh vacuum (better than O020406700009 10**(-9) Torr) was progressively attained by pumping O020406700010 and baking all elements. Targets were baked several O020406700011 days at 80. to 100. degr.C and authors checked that O020406700012 this procedure did not outgas any spallogenic O020406700013 krypton. Each foil was then melted inside a O020406700014 molybdenum crucible heated by an electronic O020406700015 bombardment oven routinely operating at 1900.degr.C. O020406700016 Extracted gases were exposed in two step to Ti and O020406700017 Cu-O-Pd getters between 700. and 200.degr.C for O020406700018 eliminating active species. Krypton(95-98%) was then O020406700019 adsorbed on a first activated charcoal trap at -120 O020406700020 degr. The remainder was adsorbed together with 98-99% O020406700021 argon on a second trap at -196 degr.C. Argon and O020406700022 krypton were successively introduced into mass O020406700023 spectrometer. O020406700024 SAMPLE A Vapor-deposited Sr target,0.16 mg/cm**2 thick, was O020406700025 used. O020406700026 ANALYSIS All results average two to four independent measurementO020406700027 weighted by individual errors. O020406700028 COMMENT From authors: Unfortunately, the deposit broke during O020406700029 preparation or handling of the stack, so that only the O020406700030 isotopic composition of spallation produced krypton O020406700031 could be obtained. O020406700032 STATUS (TABLE) text on p.935 of Phys.Rev.,C26(1982)931 O020406700033 HISTORY (20190823A) SD: BIB updated. STATUS, ANALYSIS added. O020406700034 REACTION code corrected: denominator was added. O020406700035 MONIT deleted. DATA-ERR -> ERR-T. MB -> NO-DIM. O020406700036 ENDBIB 34 0 O020406700037 NOCOMMON 0 0 O020406700038 DATA 3 1 O020406700039 EN DATA ERR-T O020406700040 MEV NO-DIM NO-DIM O020406700041 168. 1.13 0.02 O020406700042 ENDDATA 3 0 O020406700043 ENDSUBENT 42 0 O020406799999 SUBENT O0204068 20190823 O071O020406800001 BIB 7 32 O020406800002 REACTION ((38-SR-0(P,X)36-KR-84,CUM,SIG)/ O020406800003 (38-SR-0(P,X)36-KR-82,CUM,SIG)) O020406800004 METHOD (ASEP) Several months after irradiation targets and O020406800005 blank foils were stored (ten a time) in an extraction O020406800006 system in which an ultrahigh vacuum (better than O020406800007 10**(-9) Torr) was progressively attained by pumping O020406800008 and baking all elements. Targets were baked several O020406800009 days at 80. to 100. degr.C and authors checked that O020406800010 this procedure did not outgas any spallogenic O020406800011 krypton. Each foil was then melted inside a O020406800012 molybdenum crucible heated by an electronic O020406800013 bombardment oven routinely operating at 1900.degr.C. O020406800014 Extracted gases were exposed in two step to Ti and O020406800015 Cu-O-Pd getters between 700. and 200.degr.C for O020406800016 eliminating active species. Krypton(95-98%) was then O020406800017 adsorbed on a first activated charcoal trap at -120 O020406800018 degr. The remainder was adsorbed together with 98-99% O020406800019 argon on a second trap at -196 degr.C. Argon and O020406800020 krypton were successively introduced into mass O020406800021 spectrometer. O020406800022 SAMPLE A Vapor-deposited Sr target,0.16 mg/cm**2 thick, was O020406800023 used. O020406800024 ANALYSIS All results average two to four independent measurementO020406800025 weighted by individual errors. O020406800026 COMMENT From authors: Unfortunately, the deposit broke during O020406800027 preparation or handling of the stack, so that only the O020406800028 isotopic composition of spallation produced krypton O020406800029 could be obtained. O020406800030 STATUS (TABLE) text on p.935 of Phys.Rev.,C26(1982)931 O020406800031 HISTORY (20190823A) SD: BIB updated. STATUS, ANALYSIS added. O020406800032 REACTION code corrected: denominator was added. O020406800033 MONIT deleted. DATA-ERR -> ERR-T. MB -> NO-DIM. O020406800034 ENDBIB 32 0 O020406800035 NOCOMMON 0 0 O020406800036 DATA 3 1 O020406800037 EN DATA ERR-T O020406800038 MEV NO-DIM NO-DIM O020406800039 168. 0.24 0.01 O020406800040 ENDDATA 3 0 O020406800041 ENDSUBENT 40 0 O020406899999 SUBENT O0204069 20190823 O071O020406900001 BIB 7 32 O020406900002 REACTION ((38-SR-0(P,X)36-KR-85-G,CUM,SIG)/ O020406900003 (38-SR-0(P,X)36-KR-82,CUM,SIG)) O020406900004 METHOD (ASEP) Several months after irradiation targets and O020406900005 blank foils were stored (ten a time) in an extraction O020406900006 system in which an ultrahigh vacuum (better than O020406900007 10**(-9) Torr) was progressively attained by pumping O020406900008 and baking all elements. Targets were baked several O020406900009 days at 80. to 100. degr.C and authors checked that O020406900010 this procedure did not outgas any spallogenic O020406900011 krypton. Each foil was then melted inside a O020406900012 molybdenum crucible heated by an electronic O020406900013 bombardment oven routinely operating at 1900.degr.C. O020406900014 Extracted gases were exposed in two step to Ti and O020406900015 Cu-O-Pd getters between 700. and 200.degr.C for O020406900016 eliminating active species. Krypton(95-98%) was then O020406900017 adsorbed on a first activated charcoal trap at -120 O020406900018 degr. The remainder was adsorbed together with 98-99% O020406900019 argon on a second trap at -196 degr.C. Argon and O020406900020 krypton were successively introduced into mass O020406900021 spectrometer. O020406900022 SAMPLE A Vapor-deposited Sr target,0.16 mg/cm**2 thick, was O020406900023 used. O020406900024 ANALYSIS All results average two to four independent measurementO020406900025 weighted by individual errors. O020406900026 COMMENT From authors: Unfortunately, the deposit broke during O020406900027 preparation or handling of the stack, so that only the O020406900028 isotopic composition of spallation produced krypton O020406900029 could be obtained. O020406900030 STATUS (TABLE) text on p.935 of Phys.Rev.,C26(1982)931 O020406900031 HISTORY (20190823A) SD: BIB updated. STATUS, ANALYSIS added. O020406900032 REACTION code corrected: denominator was added. O020406900033 MONIT deleted. DATA-ERR -> ERR-T. MB -> NO-DIM. O020406900034 ENDBIB 32 0 O020406900035 NOCOMMON 0 0 O020406900036 DATA 3 1 O020406900037 EN DATA ERR-T O020406900038 MEV NO-DIM NO-DIM O020406900039 168. 0.004 0.002 O020406900040 ENDDATA 3 0 O020406900041 ENDSUBENT 40 0 O020406999999 SUBENT O0204070 20190823 O071O020407000001 BIB 6 6 O020407000002 REACTION (40-ZR-0(P,X)40-ZR-95,CUM,SIG) O020407000003 METHOD (ACTIV) O020407000004 DETECTOR (GELI) O020407000005 DECAY-DATA (40-ZR-95,63.8D,DG,757.,0.546) O020407000006 STATUS (TABLE) Tbl.IV from Phys.Rev.,C26(1982)931 O020407000007 HISTORY (20190823C) SD O020407000008 ENDBIB 6 0 O020407000009 NOCOMMON 0 0 O020407000010 DATA 4 7 O020407000011 EN DATA ERR-T MONIT O020407000012 MEV MB MB MB O020407000013 59. 10. 2. 28.0 O020407000014 75. 5.2 1.0 23.7 O020407000015 168. 2.3 0.9 16.6 O020407000016 200. 2.4 0.6 16.1 O020407000017 1000. 2.8 0.6 15.3 O020407000018 2500. 2.6 0.5 11.3 O020407000019 24000. 2.8 0.5 10.1 O020407000020 ENDDATA 9 0 O020407000021 ENDSUBENT 20 0 O020407099999 ENDENTRY 70 0 O020499999999