148SM 148EU EC DECAY 1985SI16,1987AD08 26NDS 202601
148SM H TYP=FUL$AUT=N. NICA$CIT=NDS 208, 1 (2026)$CUT=17-Jan-2026$
148SM dL E$Least-squares fitting is done by GLSC (version 19-Aug-2025)
148SM c Measured: E|g, I|g (1987Ad08,1985Si16,1985AdZU,1984LaZZ,1978Ad07,
148SM2c \1973To01,1967Cl01), |g|g (1987Ad08,1985Si16,1984LaZZ,1978Ad07,
148SM3c \1967Cl01),ce (1967Cl01,1968Ha39,1978Ad07),
148SM4c |g|g(|q), (1985Si16,1962Su02,1962Sc04), |g(|q) of polarized nuclei
148SMxc (1984Kr09), |b{++} (1970Ag01,1963Ba32)
148SM c Level scheme is that of 1987Ad08 in general with some changes in
148SM2c placement from 1985Si16
148SM c E|b+=920 {I30} 0.13% {I4} (1963Ba32); 940 {I40} (0.13%), 540 {I30}
148SM2c (0.06% {I2}) (1970Ag01)
148SM cE IE From analysis of 1987Ad08 data
148SM cE TI From intensity balance at each level
148SM cG $In table comments the internal coefficients ratios from 1968Ha38
148SM2cG are obtained from conversion line intensity measurements
148SM2cG normalized to 470 units for the 630 keV K electron line. Supporting
148SM2cG data for Mult are also given from 1978Ad07, 1984Kr02 and 1985Si06
148SM cG M,MR From Ice, |g(|q) of polarized nuclei, and |g|g(|q)
148SM2cG data of 1968Ha39, 1978Ad07, 1984Kr09, 1985Si16, 1987Ad08
148SM cG E,RI From 1987Ad08, except as noted otherwise
148SM cG E(C) From 1985Si16
148SM cG E(D) Placement by 1985Si16
148SM cG E(E) Placement by 1987Ad08
148SM cG E(F) Placement by 1987Ad08 changed to match level energy
148SM2cG differences with E|g
148SM cG M,MR Same as adopted gammas. Supporting data from this decay are
148SM2cG given in comments
148SM cG RI(A) Renormalized I|g from 1985Si16
148SM cG RI(B) From 1987Ad08, divided in the same ratio as in 1985Si16
148SM cL E From a least-squares fit to E|g data,
148SM2cL with reduced |h{+2}=44.5 > critical |h{+2}=1.3 due to the fact that
148SM2cL that more than fifty E|g values of 1987Ad08 are reported with
148SM2cL unrealistic precision
148SM cL J Adopted values; supporting arguments from this data set are
148SM2cL indicated in comments
148SM dG CC$From BrIcc v2.3e (17-Jun-2020) 2008Ki07, "Frozen Orbitals" appr.
148SM cL T$Adopted values
148SM DE LOGFT$FROM BetaShape v2.4 (Jun-2024) 2019MO35.
148SM DE EAV,LOGFT$FROM BetaShape v2.4 (Jun-2024) 2023MO21.
148EU P 0.0 5- 54.5 D 5 3039 10
148EU cP QP$From 2021Wa16
148SM N 0.0719 16 1.0 1.0
148SM cN NR from |SI(|g+ce) to g.s.=100, assuming |e decay to g.s.=0.0
148SM PN 3
148SM G 151.6 3 0.160 20
148SM2 G %IG=0.0115 15
148SM cG RI <0.14 (1985Si16)
148SM G 218.3 3 0.110 20
148SM2 G %IG=0.0079 15
148SM G 255.35 130.310 20
148SM2 G %IG=0.0223 15
148SM G 856.9 2 0.44 6
148SM2 G %IG=0.032 4
148SM G 961.4 5 0.14 7 C
148SM2 G %IG=0.010 5
148SM G 1201.3 5 0.14 7 C
148SM2 G %IG=0.010 5
148SM G 1377.4 5 0.14 7 C
148SM2 G %IG=0.010 5
148SM G 1419.6 5 0.07 3 C
148SM2 G %IG=0.0050 22
148SM G 1843.5 5 0.03 1 C
148SM2 G %IG=0.0022 7
148SM G 1917.50 160.029 5
148SM2 G %IG=0.0021 4
148SM L 0.0 0+ 6.5E15 Y +12-13
148SM L 550.268 11 2+ 7.71 PS 32
148SM cL J|p=2+ (1984Kr09)
148SM G 550.284 121370 30E2 0.0099814 N
148SMS G KC=0.00825 12$LC=0.001360 19$MC=0.000296 4
148SMS G NC=6.66E-5 9$OC=9.59E-6 13$PC=4.78E-7 7
148SM2 G %IG=98.560 20
148SM cG $K/L=900/135 (1968Ha38), |a(K)exp=0.0077 (1978Ad07),
148SM2cG A{-2}=-0.574 {I65} (1984Kr09)
148SM L 1161.534 12 3- 0.6 PS +4-2
148SM cL J|p=3- (1984Kr09)
148SM G 611.293 8 285 6E1 0.00277 4
148SMS G KC=0.002374 33$LC=0.000312 4$MC=6.63E-5 9
148SMS G NC=1.498E-5 21$OC=2.230E-6 31$PC=1.358E-7 19
148SM2 G %IG=20.5 6
148SM cG |d(M2/E1)=+0.03 {I2} from |g(|q,t) (1984Kr09)
148SM cG $|a(K)exp=0.00208 (1978Ad07), A{-2}=0.297 {I40} (1984Kr09)
148SM L 1180.257 12 4+ 2.37 PS 22
148SM cL J|p=4+ (1984Kr09)
148SM E 1942 300.09 73.9 309.5 3 4.0 30
148SMS E EAV=383.5 44$CK=0.8219 9$CL=0.11872 18$CM+=0.03657 13
148SM G 629.987 8 1000 22E2 0.0071010
148SMS G KC=0.00591 8$LC=0.000932 13$MC=0.0002023 28
148SMS G NC=4.55E-5 6$OC=6.61E-6 9$PC=3.46E-7 5
148SM2 G %IG=71.9 22
148SM cG |d(M3/E2)=-0.01 {I6} from |g(|q,t) (1984Kr09)
148SM cG $K/L=470/80 (1968Ha38)
148SM cG $|a(K)exp=0.0056 (1978Ad07), A{-2}=-0.436 {I63} (1984Kr09)
148SM L 1454.143 13 2+ 285 FS 28
148SM G 903.831 155.15 11M1+E2 +2.32 10 0.00339 5
148SMS G KC=0.00287 4$LC=0.000406 6$MC=8.72E-5 13
148SMS G NC=1.970E-5 30$OC=2.92E-6 4$PC=1.722E-7 28
148SM2 G %IG=0.371 11
148SM cG $|a(K)exp=0.00604 (1978Ad07)
148SM G 1454.110 205.13 12E2 1.23E-3 2 N
148SMS G KC=0.001000 14$LC=0.0001338 19$MC=2.86E-5 4
148SMS G NC=6.46E-6 9$OC=9.66E-7 14$PC=5.96E-8 8$IPC=6.03E-5 8
148SM2 G %IG=0.369 12
148SM cG $|a(K)exp=0.0014 (1978Ad07)
148SM L 1465.19 25 1- 92 FS 8
148SM cL J|p=1- (1987Ad08)
148SM G 1465.2 3 0.22 7 E1 7.04E-410 N
148SMS G KC=0.000449 6$LC=5.70E-5 8$MC=1.208E-5 17
148SMS G NC=2.73E-6 4$OC=4.11E-7 6$PC=2.61E-8 4$IPC=0.0001829 26
148SM2 G %IG=0.016 5
148SM L 1594.252 12 5-
148SM cL J|p=5- (1984Kr09),
148SM G 414.028 12143 4E1+M2 -0.013 10 0.0067010
148SMS G KC=0.00573 9$LC=0.000766 12$MC=0.0001633 26
148SMS G NC=3.68E-5 6$OC=5.45E-6 9$PC=3.22E-7 5
148SM2 G %IG=10.3 4
148SM cG $|a(K)exp=0.014 (1978Ad07, for doublet)
148SM G 432.745 8 39.5 21E2 0.0190327 @
148SMS G KC=0.01544 22$LC=0.00281 4$MC=0.000617 9
148SMS G NC=0.0001382 19$OC=1.959E-5 27$PC=8.75E-7 12
148SM2 G %IG=2.84 16
148SM cG |d(M3/E2)=-0.04 {I8} from |g(|q,t)(1984Kr09)
148SM cG $K/L=57/9 (1968Ha38), |a(K)exp=0.0125 (1978Ad07, for doublet),
148SM2cG A{-2}=-0.374 {I88} (1984Kr09)
148SM L 1664.303 22 2+ 0.25 PS 8
148SM G 1113.92 3 1.90 5 M1+E2 -0.565 21 0.00279 4
148SMS G KC=0.00239 4$LC=0.000319 5$MC=6.81E-5 10
148SMS G NC=1.544E-5 23$OC=2.322E-6 34$PC=1.466E-7 22$IPC=5.65E-7 8
148SM2 G %IG=0.137 5
148SM G 1664.20 4 0.98 3 E2 1.04E-3 2 N
148SMS G KC=0.000775 11$LC=0.0001023 14$MC=2.182E-5 31
148SMS G NC=4.94E-6 7$OC=7.40E-7 10$PC=4.62E-8 6$IPC=0.0001375 19
148SM2 G %IG=0.0705 27
148SM L 1733.476 12 4+
148SM cL J|p=4+ (1984Kr09), 4+ (1985Si16), 4+ (1987Ad08)
148SM E 0.0040 1112.7 268.70 9 12.7 26
148SMS E EAV=140.3 45$CK=0.83830 35$CL=0.12330 15$CM+=0.03809 13
148SM G 279.30 5 1.17 5E2 0.0703 10
148SMS G KC=0.0542 8$LC=0.01261 18$MC=0.00282 4
148SMS G NC=0.000627 9$OC=8.56E-5 12$PC=2.87E-6 4
148SM2 G %IG=0.084 4
148SM cG $|a(K)exp=0.074 (1978Ad07)
148SM G 553.231 14180 30M1+E2 +1.66 20 0.0117 4
148SMS G KC=0.00976 35$LC=0.00150 4$MC=0.000324 8
148SMS G NC=7.31E-5 18$OC=1.069E-5 29$PC=5.83E-7 24
148SM2 G %IG=13.0 22
148SM cG M |d from |g(|q,t) (1984Kr09)
148SM cG $The mixing ratio, q(E{-0}/E{-2})=0.55 {I14}; and the
148SM2cG ratio X(E{-0}/E{-2})=0.014 {I7}, both calculated using the given |d,
148SM3cG Rossel conversion coefficients (1978Ro22), and weighted average of
148SM4cG |a(K)exp= 11.7|*10{+-3} {I10} (1984Kr09)
148SM cG $|a(K)exp=0.0105 (1978Ad07, for doublet),
148SM2cG A{-2}=-0.216 {I48} (1984Kr09)
148SM G 571.962 7 133 3E1 0.00320 4
148SMS G KC=0.00274 4$LC=0.000361 5$MC=7.68E-5 11
148SMS G NC=1.735E-5 24$OC=2.58E-6 4$PC=1.564E-7 22
148SM2 G %IG=9.57 30
148SM cG |d(M2/E1)=+0.05 {I2} (1984Kr09), -0.10 {I10}, +0.00 {I5},
148SM2cG >+9, or >+0.65 (1985Si16)
148SM cG $|a(K)exp=0.00263 (1978Ad07),
148SM2cG A{-2}=0.219 {I39} (1984Kr09),
148SM2cG A{-2}=0.10 {I4}, A{-4}=-0.16 {I8} (1985Si16, 572|g-611|g cascade),
148SM2cG A{-2}=0.07 {I3}, A{-4}=-0.01 {I4} (1985Si16, 572|g-(611|g)-550|g
148SM2cG cascade)
148SM G 1183.208 1623.1 5E2 1.76E-3 3
148SMS G KC=0.001496 21$LC=0.0002054 29$MC=4.40E-5 6
148SMS G NC=9.94E-6 14$OC=1.480E-6 21$PC=8.91E-8 12$IPC=4.04E-6 6
148SM2 G %IG=1.66 5
148SM cG $|a(K)exp=0.00136 (1978Ad07),
148SM2cG A{-2}=0.11 {I4}, A{-4}=-0.02 {I4} (1985Si16, 1183|g-550|g cascade)
148SM cG M |g|g(|q) consistent with pure Q transition (1985Si16)
148SM L 1894.832 13 4+
148SM cL J|p=4+ (1984Kr09), 4+ (1985Si16), 4+ (1987Ad08)
148SM E 1.5E-5 82.63 189.27 3 2.63 18
148SMS E EAV=65.0 49$CK=0.83733 37$CL=0.12423 17$CM+=0.03843 13
148SM G 300.65 7 0.76 4 [E1] 0.0146321
148SMS G KC=0.01248 17$LC=0.001694 24$MC=0.000362 5
148SMS G NC=8.14E-5 11$OC=1.195E-5 17$PC=6.86E-7 10
148SM2 G %IG=0.0547 31
148SM G 714.769 1323.9 5M1+E2 0.0070 18
148SM2 G FL=1180.257
148SMS G KC=0.0060 16$LC=0.00084 17$MC=0.00018 4
148SMS G NC=4.1E-5 8$OC=6.1E-6 13$PC=3.6E-7 11
148SM2 G %IG=1.72 5
148SM cG $|a(K)exp=0.0.00957 (1978Ad07),
148SM2cG A{-2}=-0.53 {I11} (1984Kr09),
148SM2cG A{-2}=0.11 {I3}, A{-4}=0.05 {I5} (1985Si16, 715|g-630|g cascade)
148SM cG MR +0.25 {I10} or -1.5 {I5}, from |g|g(|q) (1985Si16),
148SM2cG -0.03|<|d|<+1.02 from |g(|q,t) (1984Kr09)
148SM cG $The mixing ratio, 1.1|0.47 if J=3- (1984Kr09)
148SM L 2583.861 16 4(-)
148SM cL J|p=4-,5- (1987Ad08)
148SM E 0.479 159.16 3 0.479 15
148SMS E CK=0.821 1$CL=0.1362 6$CM+=0.04284 27
148SM G 989.606 106.45 14M1,E2 0.0033 7
148SMS G KC=0.0028 7$LC=0.00038 8$MC=8.2E-5 16
148SMS G NC=1.9E-5 4$OC=2.8E-6 6$PC=1.7E-7 4
148SM2 G %IG=0.464 14
148SM cG $|a(K)exp=0.00443 (1978Ad07)
148SM G 1422.21 180.186 16
148SM2 G %IG=0.0134 12
148SM L 2641.237 17 5+
148SM cL J|p=4+,5+ (1984Kr09), 4+ (1985Si16), 4+,5+ (1987Ad08)
148SM E 1.44 68.55 3 1.44 6
148SMS E CK=0.8167 12$CL=0.1393 8$CM+=0.04400 33
148SM G 493.51 200.8 3 C
148SM2 G %IG=0.058 22
148SM G 735.00 5 1.7 3 M1+E2 -1.1 6 0.0064 12 @
148SM3 G FL=1905.864
148SMS G KC=0.0055 10$LC=0.00077 11$MC=0.000165 24
148SMS G NC=3.7E-5 5$OC=5.6E-6 9$PC=3.3E-7 7
148SM2 G %IG=0.122 22
148SM cG $A{-2}=-0.440 {I84} (1984Kr09, from 5+)
148SM cG MR from 1984Kr09
148SM G 736.90 200.29 7 F
148SM2 G %IG=0.021 5
148SM G 745.87 5 0.74 5 F
148SM2 G FL=1894.832
148SM2 G %IG=0.053 4
148SM G 1047.570 200.7 4 @
148SM2 G FLAG=B
148SM3 G FL=1594.252
148SM2 G %IG=0.050 29
148SM G 1460.630 1916.2 4M1+E2 +2.1 16 0.0013129
148SM2 G FL=1180.257
148SMS G KC=0.00107 25$LC=0.000142 31$MC=3.0E-5 7
148SMS G NC=6.9E-6 15$OC=1.03E-6 23$PC=6.4E-8 16$IPC=6.33E-5 34
148SM2 G %IG=1.17 4
148SM cG $|a(K)exp=0.00112 (1978Ad07),
148SM2cG A{-2}=-0.73 {I30} (1984Kr09, from 4+),
148SM2cG A{-2}=-0.76 {I31} (1984Kr09, from 5+),
148SM2cG A{-2}=0.20 {I5}, A{-4}=0.32 {I10} (1985Si16, 1461|g-630|g cascade),
148SM2cG A{-2}=0.23 {I5}, A{-4}=-0.08 {I8} (1985Si16, 1461|g-(630|g)-550
148SM2cG cascade)
148SM cG M |d from |g(|q,t) (1984Kr09). Other: -1.25<|d<+0.10
148SM2cG (1985Si16)
148SM L 2673.067 324+
148SM cL J|p=4+ (1987Ad08)
148SM E 0.218 159.29 4 0.218 15
148SMS E CK=0.8136 14$CL=0.1415 9$CM+=0.04483 37
148SM G 478.4 4 0.30 4
148SM2 G %IG=0.0216 29
148SM G 1219.01 9 0.70 6
148SM2 G %IG=0.050 5
148SM G 1492.81 4 1.37 4
148SM2 G %IG=0.099 4
148SM G 1511.49 7 0.58 4
148SM2 G %IG=0.0417 30
148SM cG $|a(K)exp=0.00186 (1978Ad07)
148SM G 2122.75 8 0.190 8
148SM2 G %IG=0.0137 7
148SM L 2675.20 14 (3+,4,5-)
148SM E 0.035 1210.08 15 0.035 12
148SMS E CK=0.8134 14$CL=0.1417 9$CM+=0.04489 37
148SM G 460.80 200.26 3 &
148SM2 G %IG=0.0187 22
148SM cG Placement proposed by 1987Ad08
148SM G 643.90 200.218 19
148SM2 G %IG=0.0157 14
148SM G 1513.9 4 0.12 3
148SM2 G %IG=0.0086 22
148SM L 2683.464 12 4-,5-
148SM cL J|p=4-,5- (1987Ad08)
148SM E 0.70 78.76 5 0.70 7
148SMS E CK=0.8125 15$CL=0.1424 10$CM+=0.04515 39
148SM G 455.30 150.38 4
148SM2 G %IG=0.0273 29
148SM G 489.2 5 0.27 14 C
148SM2 G %IG=0.019 10
148SM G 587.52 6 1.63 6 &
148SM2 G FLAG=D
148SM3 G FL=2095.594
148SM2 G %IG=0.117 5
148SM G 651.5 5 0.27 14 C
148SM2 G %IG=0.019 10
148SM G 787.98 180.37 5 F
148SM2 G FL=1894.832
148SM2 G %IG=0.027 4
148SM G 1089.154 182.85 7M1 0.00322 5
148SMS G KC=0.00275 4$LC=0.000365 5$MC=7.79E-5 11
148SMS G NC=1.767E-5 25$OC=2.66E-6 4$PC=1.701E-7 24
148SM2 G %IG=0.205 7
148SM cG $|a(K)exp=0.00392 (1978Ad07)
148SM G 1503.200 2 2.59 6
148SM2 G %IG=0.186 6
148SM G 1521.85 3 2.13 6
148SM2 G %IG=0.153 6
148SM L 2698.531 16 5-,6-
148SM cL J|p=5-,6- (1987Ad08)
148SM E 0.88 78.61 5 0.88 7
148SMS E CK=0.8107 16$CL=0.1437 11$CM+=0.04562 42
148SM G 166.15 3 0.94 3M1,E2 0.397 8
148SMS G KC=0.30 4$LC=0.073 25$MC=0.016 6
148SMS G NC=0.0036 13$OC=5.0E-4 15$PC=1.7E-5 5
148SM2 G %IG=0.0676 26
148SM cG $K/L1=22/3 (1968Ha38), |a(K)exp=0.38 (1978Ad07)
148SM G 504.57 7 1.92 7
148SM2 G %IG=0.138 6
148SM G 587.52 6 1.63 6 &
148SM2 G FLAG=E
148SM2 G %IG=0.117 5
148SM G 602.62 3 0.44 22 @
148SM2 G FLAG=BD
148SM3 G FL=2095.594
148SM2 G %IG=0.032 16
148SM G 667.170 200.9 3 @
148SM2 G FLAG=B
148SM2 G %IG=0.065 22
148SM G 792.59 6 1.64 7 F
148SM2 G %IG=0.118 6
148SM G 1104.321 165.11 11M1 0.00311 4
148SMS G KC=0.00267 4$LC=0.000353 5$MC=7.54E-5 11
148SMS G NC=1.710E-5 24$OC=2.58E-6 4$PC=1.646E-7 23$IPC=4.01E-7 6
148SM2 G %IG=0.368 11
148SM L 2701.922 32 4(-),3(-)
148SM E 0.21 19.23 4 0.21 1
148SMS E CK=0.8102 17$CL=0.1440 11$CM+=0.04575 42
148SM G 1107.67 3 1.81 5
148SM2 G %IG=0.130 5
148SM G 1540.27 151.11 11
148SM2 G %IG=0.080 8
148SM L 2713.332 19 3+,4+
148SM cL J|p=3+,4+ (1987Ad08)
148SM E 0.276 149.07 4 0.276 14
148SMS E CK=0.8087 18$CL=0.1451 12$CM+=0.04617 46
148SM G 385.9 6 0.20 9
148SM2 G %IG=0.014 7
148SM G 485.90 140.22 4 &
148SM2 G FLAG=E
148SM3 G FL=2228.057
148SM2 G %IG=0.0158 29
148SM G 979.843 152.98 7
148SM2 G %IG=0.214 7
148SM cG $|a(K)exp=0.0106 (1978Ad07)
148SM G 1533.10 200.45 4
148SM2 G %IG=0.0324 30
148SM G 2163.9 3 0.077 8
148SM2 G %IG=0.0055 6
148SM L 2716.00 4 (4+,5,6+)
148SM E 0.181 69.25 4 0.181 6
148SMS E CK=0.8083 18$CL=0.1454 12$CM+=0.04626 46
148SM G 810.12 4 0.95 3 F
148SM2 G %IG=0.0683 26
148SM G 1121.70 200.29 3
148SM2 G %IG=0.0209 22
148SM G 1535.84 101.27 5
148SM cG $|a(K)exp=0.00261 (1978Ad07)
148SM2 G %IG=0.091 4
148SM L 2723.517 23 4+
148SM cL J|p=4+, (3+) (1984Kr09), 3+,4+ (1987Ad08)
148SM E 1.33 58.36 4 1.33 5
148SMS E CK=0.8072 19$CL=0.1462 12$CM+=0.04656 48
148SM G 332.91 130.14 3
148SM2 G %IG=0.0101 22
148SM cG E 1985Si16 suggest this |g belongs to {+150}Eu |e decay
148SM G 495.25 6 3.56 11M1 0.0220531 B
148SMS G KC=0.01880 26$LC=0.00256 4$MC=0.000548 8
148SMS G NC=0.0001243 17$OC=1.869E-5 26$PC=1.177E-6 16
148SM2 G %IG=0.256 10
148SM cG $|a(K)exp=0.0193 (1978Ad07, for doublet)
148SM G 575.97 100.64 8 C
148SM2 G %IG=0.046 6
148SM G 817.5 5 0.14 7 &
148SM3 G FLAG=C$
148SM2 G %IG=0.010 5
148SM cG $|a(K)exp=0.00352 (1978Ad07)
148SM G 828.61 120.48 4
148SM2 G %IG=0.0345 30
148SM cG E placement in 1985Si16
148SM G 1058.7 5 0.14 7 C
148SM2 G %IG=0.010 5
148SM G 1269.3 4 0.19 4 &
148SM2 G %IG=0.0137 29
148SM cG E placement in 1985Si16
148SM G 1543.289 2710.3 3M1+E2 0.0013320
148SMS G KC=0.00106 17$LC=0.000140 21$MC=3.0E-5 5
148SMS G NC=6.8E-6 10$OC=1.02E-6 16$PC=6.4E-8 11$IPC=9.5E-5 4
148SM2 G %IG=0.741 27
148SM cG $|a(K)exp=0.00135 (1978Ad07),
148SM2cG A{-2}=-0.305 {I90} (1984Kr09, from 4+),
148SM2cG A{-2}=-0.337 {I99} (1984Kr09, from (3+))
148SM cG M |d=-0.17 {I11} or +1.35 {I30} (1984Kr09)
148SM G 2173.28 4 3.21 8
148SM2 G %IG=0.231 8
148SM cG $A{-2}=0.09 {I3}, A{-4}=0.02 {I5} (1985Si16, 2173|g-550|g cascade)
148SM L 2727.31 5 5+
148SM E 0.191 159.19 5 0.191 15
148SMS E CK=0.8067 19$CL=0.1466 13$CM+=0.04673 49
148SM G 832.82 140.34 2
148SM2 G %IG=0.0245 15
148SM G 1133.12 8 0.65 3
148SM2 G %IG=0.0468 24
148SM G 1547.14 101.23 20 C
148SM2 G %IG=0.089 15
148SM cG RI from 1987Ad08
148SM G 1565.29 110.440 20
148SM2 G FL=1161.534
148SM2 G %IG=0.0317 16
148SM L 2734.45 19 (3)
148SM cL J|p=(3-) (1987Ad08)
148SM E 0.020 99.60 21 0.020 9 1U
148SMS E CK=0.721 7$CL=0.210 5$CM+=0.0696 17
148SM G 1269.3 4 0.19 4 &
148SM2 G %IG=0.0137 29
148SM cG E placement of 1987Ad08
148SM G 1572.90 200.159 14
148SM2 G %IG=0.0114 10
148SM L 2801.736 13 5+
148SM cL J|p=5+ (1984Kr09), 5+ (1985Si16), 5+ (1987Ad08)
148SM E 8.48 227.27 5 8.48 22
148SMS E CK=0.7906 35$CL=0.1583 24$CM+=0.0511 8
148SM G 161.00 6 0.400 20
148SM2 G FL=2641.237
148SM2 G %IG=0.0288 16
148SM G 474.2 4 0.07 4
148SM2 G %IG=0.0050 29
148SM G 574 1 0.27 14 C
148SM2 G %IG=0.019 10
148SM G 654.220 8 22.5 5M1+E2 +0.9 3 0.0090 8
148SMS G KC=0.0076 7$LC=0.00108 8$MC=0.000231 16
148SMS G NC=5.2E-5 4$OC=7.8E-6 6$PC=4.7E-7 5
148SM2 G %IG=1.62 5
148SM cG MR from |g(|q,t) (1984Kr09)
148SM cG $K/L=20.5/3 (1968Ha38), |a(K)exp=0.00614 (1978Ad07),
148SM2cG A{-2}=-0.393 {I95} (1984Kr09)
148SM G 690.74 3 1.69 4
148SM2 G %IG=0.122 4
148SM G 705.91 180.24 6
148SM2 G %IG=0.017 4
148SM G 770.307 105.88 13 F
148SM2 G %IG=0.423 13
148SM G 895.847 109.00 20M1+E2 -0.20 11 0.0050412
148SMS G KC=0.00431 10$LC=0.000576 13$MC=0.0001231 27
148SMS G NC=2.79E-5 6$OC=4.20E-6 9$PC=2.67E-7 7
148SM2 G %IG=0.648 20
148SM cG $|a(K)exp=0.00448(1978Ad07),
148SM2cG A{-2}=-0.13 {I14} (1984Kr09)
148SM cG MR from |g(|q,t) (1984Kr09)
148SM G 906.87 3 2.89 7
148SM2 G %IG=0.208 7
148SM G 1068.25 101.26 11 C
148SM2 G %IG=0.091 8
148SM G 1207.473 148.76 19E1+M2 0.00081 5
148SMS G KC=0.00067 5$LC=8.7E-5 6$MC=1.84E-5 14
148SMS G NC=4.16E-6 31$OC=6.2E-7 5$PC=3.94E-8 29$IPC=2.90E-5 5
148SM2 G %IG=0.630 19
148SM cG $|a(K)exp=0.000341 (1978Ad07),
148SM2cG A{-2}=-0.48 {I29} (1984Kr09)
148SM cG MR -0.36|<|d|<+1.52 (1984Kr09)
148SM G 1621.510 2064.6 15M1+E2 0.0012417
148SMS G KC=0.00096 14$LC=0.000126 18$MC=2.7E-5 4
148SMS G NC=6.1E-6 9$OC=9.2E-7 14$PC=5.8E-8 10$IPC=0.000126 6
148SM2 G %IG=4.65 15
148SM cG $|a(K)exp=0.00085 (1978Ad07),
148SM2cG A{-2}=-0.416 {I44} (1984Kr09),
148SM2cG A{-2}=0.17 {I4}, A{-4}=-0.02 {I6} (1985Si16, 1621|g-630|g cascade)
148SM2cG A{-2}=0.17 {I3}, A{-4}=-0.03 {I5} (1985Si16, 1621|g-(630|g)-550|g
148SM2cG cascade)
148SM cG MR =+4.1 {I6} (1984Kr09), +1.75 {I50} or +0.45 {I10} (1985Si16)
148SM L 2815.583 18 4-
148SM cL J|p=4- (1984Kr09), 4- (1987Ad08)
148SM E 0.74 78.26 6 0.74 7
148SMS E CK=0.7861 41$CL=0.1616 28$CM+=0.0524 9
148SM G 92.6 5 0.27 14 C
148SM2 G FLAG=A
148SM2 G %IG=0.019 10
148SM G 291.3 3 0.150 20
148SM2 G %IG=0.0108 15
148SM G 441.23 140.16 3
148SM2 G %IG=0.0115 22
148SM G 587.52 6 1.63 6 &
148SM2 G FLAG=DE
148SM2 G %IG=0.117 5
148SM G 704.4 3 0.27 7 C
148SM2 G %IG=0.019 5
148SM G 1082.096 172.63 6
148SM2 G %IG=0.189 6
148SM G 1151.3 4 0.27 14 C
148SM2 G %IG=0.019 10
148SM G 1221.37 4 1.91 7M1 2.47E-3 4
148SMS G KC=0.002107 29$LC=0.000278 4$MC=5.94E-5 8
148SMS G NC=1.347E-5 19$OC=2.030E-6 28$PC=1.299E-7 18$IPC=8.80E-6 12
148SM2 G %IG=0.137 6
148SM cG $|a(K)exp=0.00206 (1978Ad07)
148SM G 1635.31 3 2.21 6E1+M2 7.64E-424
148SMS G KC=0.000394 21$LC=5.00E-5 29$MC=1.06E-5 6
148SMS G NC=2.40E-6 14$OC=3.61E-7 21$PC=2.30E-8 13$IPC=0.000307 5
148SM2 G %IG=0.159 6
148SM cG $|a(K)exp=0.00053 (1978Ad07),
148SM2cG A{-2}=-1.11 {I71} (1984Kr09)
148SM cG MR -0.05|<|d|<+1.06 (1984Kr09)
148SM G 1654.02 151.63 19
148SM2 G %IG=0.117 14
148SM L 2830.665 13 5+
148SM cL J|p=5+ (1984Kr09), 5+ (1985Si16), 5+ (1987Ad08)
148SM E 6.98 207.21 6 6.98 20
148SMS E CK=0.7802 49$CL=0.1658 34$CM+=0.0539 12
148SM G 157.8 5 0.14 7 &
148SM2 G FLAG=AC
148SM2 G %IG=0.010 5
148SM G 602.62 3 4.11 8 @
148SM2 G FLAG=BDE
148SM2 G %IG=0.296 9
148SM G 636.86 7 0.40 7
148SM2 G FL=2194.052
148SM2 G %IG=0.029 5
148SM G 683.153 7 17.8 4M1+E2 0.0079 20
148SMS G KC=0.0067 18$LC=0.00094 19$MC=0.00020 4
148SMS G NC=4.6E-5 9$OC=6.8E-6 15$PC=4.1E-7 12
148SM2 G %IG=1.28 4
148SM cG M |d=+0.85 {I+35-50} or -0.06 {I+38-18} (1984Kr09)
148SM cG $|a(K)exp=0.00927 (1978Ad07),
148SM2cG A{-2}=-0.41 {I12} (1984Kr09)
148SM G 701.9 5 0.27 14 C
148SM2 G %IG=0.019 10
148SM G 719.64 7 3.80 20
148SM2 G %IG=0.273 16
148SM G 735.00 5 0.44 22M1+E2 -1.1 6 0.0064 12 @
148SMS G KC=0.0055 10$LC=0.00077 11$MC=0.000165 24
148SMS G NC=3.7E-5 5$OC=5.6E-6 9$PC=3.3E-7 7
148SM2 G %IG=0.032 16
148SM cG $A{-2}=-0.72 {I27} (1984Kr09)
148SM cG MR from 1984Kr09
148SM G 799.23 3 5.82 16 F
148SM2 G %IG=0.419 15
148SM G 924.75 3 4.38 11M1 0.00474 7
148SMS G KC=0.00406 6$LC=0.000541 8$MC=0.0001155 16
148SMS G NC=2.62E-5 4$OC=3.95E-6 6$PC=2.513E-7 35
148SM2 G %IG=0.315 11
148SM cG $|a(K)exp=0.00744 (1978Ad07)
148SM G 935.20 200.74 7
148SM2 G FL=1894.832
148SM2 G %IG=0.053 5
148SM G 1097.18 3 1.73 6M1 0.00316 4
148SMS G KC=0.00271 4$LC=0.000359 5$MC=7.66E-5 11
148SMS G NC=1.737E-5 24$OC=2.62E-6 4$PC=1.672E-7 23
148SM2 G %IG=0.125 5
148SM G 1236.374 165.68 13E1 7.43E-410
148SMS G KC=0.000603 8$LC=7.69E-5 11$MC=1.632E-5 23
148SMS G NC=3.69E-6 5$OC=5.54E-7 8$PC=3.50E-8 5$IPC=4.26E-5 6
148SM2 G %IG=0.409 13
148SM cG $|a(K)exp=0.00160 (1978Ad07),
148SM cG $A{-2}=-0.30 {I23} (1984Kr09)
148SM cG |d(M2/E1)=-0.2 {I+4-3} (1984Kr09), 0.50 {I11} from E1=80%
148SM2cG {I7} (1987Ad08)
148SM G 1650.436 2451.6 16M1+E2 0.0012116
148SMS G KC=0.00092 14$LC=0.000121 17$MC=2.6E-5 4
148SMS G NC=5.9E-6 8$OC=8.8E-7 13$PC=5.6E-8 9$IPC=0.000138 7
148SM2 G %IG=3.71 14
148SM cG $|a(K)exp=0.00101 (1978Ad07),
148SM2cG A{-2}=-0.540 {I53} (1984Kr09),
148SM2cG A{-2}=0.18 {I4}, A{-4}=0.00 {I8} (1985Si16, 1651|g-630|g cascade)
148SM2cG A{-2}=0.21 {I4}, A{-4}=-0.02 {I4} (1985Si16, 1651|g-(630|g)-550|g
148SM2cG cascade)
148SM cG MR +0.53 {I+6-5} or +2.92 {I42} (1984Kr09), +0.50 {I15} or
148SM2cG +1.75 {I50} (1985Si16)
148SM L 2861.078 29 4-,5-
148SM cL J|p=4-,5- (1987Ad08)
148SM E 0.294 148.42 7 0.294 14
148SMS E CK=0.764 7$CL=0.177 5$CM+=0.0583 17
148SM G 485.90 140.22 4 &
148SM2 G FLAG=D
148SM3 G FL=2374.395
148SM2 G %IG=0.0158 29
148SM G 646.9 5 0.14 7 C
148SM2 G %IG=0.010 5
148SM G 1127.69 4 1.17 4
148SM2 G %IG=0.0842 34
148SM G 1266.76 5 2.02 5M1 2.28E-3 3
148SMS G KC=0.001936 27$LC=0.000255 4$MC=5.45E-5 8
148SMS G NC=1.236E-5 17$OC=1.863E-6 26$PC=1.193E-7 17$IPC=1.581E-5 22
148SM2 G %IG=0.145 5
148SM cG $|a(K)exp=0.00206 (1978Ad07)
148SM G 1680.90 150.41 5
148SM2 G %IG=0.030 4
148SM G 1699.54 6 0.213 8
148SM2 G %IG=0.0153 7
148SM L 2906.4 10 3-,4- ?
148SM cL E from 1985Si16
148SM G 532 1 0.27 14 C ?
148SM2 G %IG=0.019 10
148SM L 2928.84 5 (4,5,6)+
148SM E 0.052 108.59 15 0.052 10
148SMS E CK=0.675 32$CL=0.241 22$CM+=0.083 7
148SM G 817.5 5 0.14 7 &
148SM3 G FLAG=C$
148SM2 G %IG=0.010 5
148SM G 832.9 5 0.14 7 C
148SM2 G %IG=0.010 5
148SM G 1748.58 5 0.478 15
148SM2 G %IG=0.0344 13