140EU 140GD EC DECAY 1991FI03 18NDS 201812
140EU H TYP=FUL$AUT=N. NICA$CIT=NDS 154, 1 (2018)$CUT=20-Nov-2018$
140EU c Measured: |g, |g|g, X|g (1991Fi03,1988Tu05); ce (1988Tu05)
140EU cE $Strong |e decay to {+140}Eu g.s.
140EU cE $Level 185 has non-zero I(|e+|b{++}) feeding although |DJ=3 and |D|p=no
140EU cG E,RI From 1991Fi03; for many |g's I|g(1991Fi03) strongly differs
140EU2cG from I|g(1988Tu05)
140EU cG M From |a(K)exp and |a(L)exp(174.7|g) (1988Tu05), except where
140EUxcG noted
140EU DG CC$FROM BrIcc v2.3b (16-Dec-2014) 2008Ki07, "Frozen Orbitals" appr.
140EU cG MR$If no value given it was assumed |d=1.00 for E2/M1,
140EU2cG |d=1.00 for E3/M2 and |d=0.10 for the other multipolarities
140EU cL E$From fit of |g's to levels (GTOL)
140EU cL J Adopted values
140GD P 0.0 0+ 15.8 S 4 5200 60
140GD cP E,J,T$from {+140}Gd Adopted Levels
140GD cP QP$from 2017Wa10
140EU N 0.110 15 1.00
140EU cN $0.110 15 1.0 1.0
140EU cN NR$Based on I(K| x ray)/I|g from 1991Fi03. The normalization value
140EU2cN considered by 1994Pe19 from 1991Fi03 (Table XI), 0.70 {I8}, is wrong
140EU2cN because it leads to negative (|e+|b{++}) feeding of g.s. (and aberrant
140EU2cN net feedings of excited levels).
140EU2cN This also happened when I(K| x ray)=75 {I2} from 1991Fi03 (Table XI)
140EU2cN was used by evaluator to calculate the normalization.
140EU2cN The actual normalization value is from Table IV of 1991Fi03 and it can
140EU2cN be obtained by calculation if the I(K| x ray) is multiplied by a factor
140EU2cN of 2.4
140EU PN 3
140EU G 532.0 49 5
140EU cG %I|g=1.0 {I6}, using the calculated normalization.
140EU cG E,RI from 1988Tu05
140EU G 686.2 46 4
140EU cG %I|g=0.7 {I5}, using the calculated normalization.
140EU cG E,RI from 1988Tu05
140EU G 774.6 3
140EU cG E from 1988Tu05. Seen only in |g|g
140EU G 982.9 4
140EU cG E from 1988Tu05. Seen only in |g|g
140EU L 0.0 1+ 1.51 S 2
140EU2 L %EC+%B+=100
140EU cL T,%EC+%B+$from Adopted Levels
140EU E 36 7 9.6 19 4.56 9 46 9
140EUS E EAV=1907 29$CK=0.176 6$CL=0.0254 9$CM+=0.0073 3
140EU L 174.59 92+
140EU E 2 2 0.7 7 5.7 5 3 3 2 ?
140EUS E EAV=1825 29$CK=0.194 7$CL=0.0280 10$CM+=0.0081 3
140EU cE LOGFT,IB,IE$Allowed spectrum assumed for calcuations by log| {Ift}
140EU cE TI$estimated upper limit (90% C.L.) gives 7.39 (method 1) and 7.08
140EU2cE (method 2; see documentation of program GTOL)
140EU G 174.8 2 108 19M1 0.381
140EUS G KC=0.323 5$LC=0.0458 7$MC=0.00989 15
140EUS G NC=0.00227 4$OC=0.000360 6$PC=3.56E-5 6
140EU cG %I|g=11.9 {I24}, using the calculated normalization.
140EU cG Mult: |a(K)exp=0.34 {I4}, |a(L)exp=0.053 {I12}
140EU L 185.30 203+
140EU cL E$from Fig. 13 - decay scheme (1991Fi03)
140EU G 185.3 2 10 2 (E2) 0.278
140EUS G KC=0.193 3$LC=0.0666 10$MC=0.01525 23
140EUS G NC=0.00341 5$OC=0.000482 7$PC=1.618E-5 24
140EU cG %I|g=1.1 {I3}, using the calculated normalization.
140EU cG E,RI,M$from Fig. 13 - decay scheme (1991Fi03). Uncertainties assumed
140EU2cG by evaluator.
140EU L 191.24 8
140EU G 191.2 149 9
140EU cG %I|g=5.4 {I13}, using the calculated normalization.
140EU L 361.3 4
140EU E 0.31 12 0.11 4 6.45 17 0.42 16
140EUS E EAV=1738 28$CK=0.216 8$CL=0.0312 11$CM+=0.0090 4
140EU G 186.7 33.8 13
140EU cG %I|g=0.42 {I16}, using the calculated normalization.
140EU L 379.00 10
140EU E 4.4 9 1.5 3 5.29 10 5.9 12
140EUS E EAV=1729 28$CK=0.218 8$CL=0.0315 12$CM+=0.0091 4
140EU G 379.0 154 8
140EU cG %I|g=5.9 {I13}, using the calculated normalization.
140EU L 417.72 10
140EU E 3.0 6 1.1 2 5.43 9 4.1 8
140EUS E EAV=1711 28$CK=0.223 8$CL=0.0322 12$CM+=0.0093 4
140EU G 417.7 139 4
140EU cG %I|g=4.3 {I8}, using the calculated normalization.
140EU L 427.92 10
140EU E 2.3 4 0.85 16 5.54 9 3.2 6
140EUS E EAV=1706 28$CK=0.224 8$CL=0.0324 12$CM+=0.0094 4
140EU G 236.7 18.9 13
140EU cG %I|g=0.98 {I22}, using the calculated normalization.
140EU G 253.3 28.9 19
140EU cG %I|g=1.0 {I3}, using the calculated normalization.
140EU G 427.9 211.4 13
140EU cG %I|g=1.25 {I25}, using the calculated normalization.
140EU L 446.98 13
140EU E 0.58 18 0.21 7 6.13 14 0.79 24
140EUS E EAV=1698 28$CK=0.227 8$CL=0.0328 12$CM+=0.0095 4
140EU G 272.4 10.9
140EU cG %I|g=0.099 {I16}, using the calculated normalization.
140EU cG RI from 1991Fi03; 10.8 in 1988Tu05
140EU G 446.9 36.3 19
140EU cG %I|g=0.69 {I24}, using the calculated normalization.
140EU L 453.25 11
140EU E 1.8 6 0.65 22 5.65 15 2.4 8
140EUS E EAV=1695 28$CK=0.228 8$CL=0.0329 12$CM+=0.0095 4
140EU G 261.8 2 7.6 13M1 0.1265
140EUS G KC=0.1074 16$LC=0.01507 22$MC=0.00325 5
140EUS G NC=0.000745 11$OC=0.0001183 17$PC=1.179E-5 17
140EU cG %I|g=0.84 {I20}, using the calculated normalization.
140EU cG M |a(K)exp=0.095 {I30}
140EU G 278.4 510.1 13
140EU cG %I|g=1.11 {I23}, using the calculated normalization.
140EU G 453.4 219 6
140EU cG %I|g=2.1 {I8}, using the calculated normalization.
140EU L 488.1 4
140EU E 0.9 3 0.36 11 5.90 14 1.3 4
140EUS E EAV=1678 28$CK=0.232 9$CL=0.0336 12$CM+=0.0097 4
140EU G 313.5 312.0 25
140EU cG %I|g=1.3 {I4}, using the calculated normalization.
140EU L 535.7 4
140EU E 0.15 11 0.06 4 6.7 4 0.21 15
140EUS E EAV=1656 28$CK=0.239 9$CL=0.0345 13$CM+=0.0100 4
140EU G 344.5 41.9 13
140EU cG %I|g=0.21 {I15}, using the calculated normalization.
140EU L 546.54 15
140EU E 1.9 4 0.77 15 5.56 9 2.7 5
140EUS E EAV=1651 28$CK=0.240 9$CL=0.0347 13$CM+=0.0100 4
140EU G 372.0 23.8 13
140EU cG %I|g=0.42 {I16}, using the calculated normalization.
140EU G 546.5 220.3 19
140EU cG %I|g=2.2 {I5}, using the calculated normalization.
140EU L 610.99 22
140EU E 0.54 13 0.23 5 6.07 11 0.77 18
140EUS E EAV=1621 28$CK=0.250 9$CL=0.0361 13$CM+=0.0104 4
140EU G 436.4 27.0 13
140EU cG %I|g=0.77 {I19}, using the calculated normalization.
140EU L 687.04 22
140EU E 0.73 15 0.32 7 5.91 10 1.05 21
140EUS E EAV=1586 28$CK=0.261 10$CL=0.0377 14$CM+=0.0109 4
140EU G 495.8 29.5 13
140EU cG %I|g=1.04 {I22}, using the calculated normalization.
140EU L 722.28 9
140EU E 2.3 5 1.0 2 5.39 10 3.3 7
140EUS E EAV=1569 28$CK=0.266 10$CL=0.0385 14$CM+=0.0111 4
140EU G 269.0 21.9 6
140EU cG %I|g=0.21 {I8}, using the calculated normalization.
140EU G 304.5 21.3 6
140EU cG %I|g=0.14 {I7}, using the calculated normalization.
140EU G 722.3 127 4
140EU cG %I|g=3.0 {I7}, using the calculated normalization.
140EU L 749.94 81+
140EU E 14 2 6.7 10 4.58 7 21 3
140EUS E EAV=1557 28$CK=0.271 10$CL=0.0391 14$CM+=0.0113 4
140EU G 296.6 2 12.7 13M1 0.0907
140EUS G KC=0.0769 11$LC=0.01076 16$MC=0.00232 4
140EUS G NC=0.000532 8$OC=8.45E-5 12$PC=8.43E-6 12
140EU cG %I|g=1.4 {I3}, using the calculated normalization.
140EU cG M |a(K)exp=0.071 {I18}
140EU G 558.7 333 3
140EU cG %I|g=3.6 {I7}, using the calculated normalization.
140EU G 575.4 1 39 4M1 0.01638
140EUS G KC=0.01395 20$LC=0.00191 3$MC=0.000411 6
140EUS G NC=9.41E-5 14$OC=1.497E-5 21$PC=1.511E-6 22
140EU cG %I|g=4.3 {I8}, using the calculated normalization.
140EU cG M |a(K)exp=0.016 {I5}
140EU G 749.9 1100 6
140EU cG %I|g=11.0 {I19}, using the calculated normalization.
140EU cG RI 41 {I12} in 1988Tu05 (I|g=38 if I|g(174.8|g)=100)
140EU L 882.69 22
140EU E 0.69 14 0.36 7 5.82 10 1.05 21
140EUS E EAV=1495 28$CK=0.292 11$CL=0.0423 16$CM+=0.0122 5
140EU G 708.1 29.5 13
140EU cG %I|g=1.04 {I22}, using the calculated normalization.
140EU L 1077.8 4
140EU E 0.21 9 0.14 6 6.20 19 0.35 15
140EUS E EAV=1405 28$CK=0.328 12$CL=0.0475 18$CM+=0.0137 5
140EU G 903.2 33.2 13
140EU cG %I|g=0.35 {I16}, using the calculated normalization.
140EU L 1092.6 10
140EU E 0.6 3 0.39 20 5.74 22 1.0 5
140EUS E EAV=1398 28$CK=0.331 12$CL=0.0479 18$CM+=0.0138 5
140EU G 918 19 4
140EU cG %I|g=1.0 {I5}, using the calculated normalization.
140EU L 1131.1 3
140EU E 0.34 10 0.22 7 5.97 14 0.56 17
140EUS E EAV=1380 28$CK=0.338 12$CL=0.0490 18$CM+=0.0142 6
140EU G 1131.1 35.1 13
140EU cG %I|g=0.56 {I17}, using the calculated normalization.
140EU L 1215.99 22
140EU E 0.8 4 0.6 3 5.54 22 1.4 7
140EUS E EAV=1341 28$CK=0.356 13$CL=0.0515 19$CM+=0.0149 6
140EU G 1041.4 213 6
140EU cG %I|g=1.4 {I7}, using the calculated normalization.