146SM 146EU EC DECAY 1995VA40,1992AD04,1976AD0816NDS 201609
146SM H TYP=FUL$AUT=Yu. KHAZOV, A. RODIONOV AND G. SHULYAK$
146SM2 H CIT=NDS 136, 163 (2016)$CUT=14-Jul-2016$
146SM c 1965Ad06,1969AdZW,1970An18,1976Ad08,1992Ad04: {+146}Eu |e decay [from
146SM2c Ta,Er(p,X), E=660 MeV]; measured E|g, I|g, |g|g coin, E(ce), I(ce).
146SM3c {+146}Sm; deduced levels, |a, J|p, |d, log| {Ift}. Synchrocyclotron,
146SM4c chemical separation, Ge(Li) detectors, anti-Compton spectrometer,
146SM5c magnetic spectrometer.
146SM c 1995Va40: {+146}Eu |e decay [from {+146}Gd(|e) produced in Ta(p,X),
146SM2c E=660 MeV]; measured E|g, I|g, |g|g coin. {+146}Sm; deduced levels,
146SM3c J|p, |g transitions. Synchrocyclotron, chemical separation, Ge(Li)
146SM4c detectors, sum-coincidence method.
146SM c 1984Kr02,1985Fi06: {+146}Eu |e decay [from Er(p,X), E=660 MeV];
146SM2c measured |g(|q), oriented nuclei. {+146}Sm; deduced levels, J|p, |d,
146SM3c X(E0/E2).
146SM c 1975Si03: {+146}Eu |e decay [from {+144}Sm(|a,2n|g){+146}Gd,
146SM2c E=24 MeV]; measured E|g, I|g, |g|g(|q) coin, |d, I(ce). {+146}Sm;
146SM3c deduced levels, J|p.
146SM c Others: 1988Sa06, 1968Ha39, 1968Pa13, 1967Av01, 1965Ba43, 1962Fu16,
146SM2c 1964Ta11
146SM c The level scheme of {+146}Sm containing 94 levels and 303 transitions
146SM2c is constructed mainly by 1992Ad04 and 1995Va40 on the basis of |g,
146SM3c |g|g and (ce) spectra measured in {+146}Eu (|e+|b{++}) decay. The
146SM4c 3488.46 keV and 3720.50 keV levels of 1992Ad04 scheme were not
146SM5c confirmed but 27 new levels were inserted by 1995Va40. It should be
146SM6c noted that energies of a dozen |g's observed in coincidence, do not
146SM7c agree to 4-5 uncertainties with the energy differences between the
146SM8c respective levels (normalized |h{+2}=2.03). Some of them were in
146SM9c not taken to account in a least-square fitting.
146SM cE $Warning: There is a large number of unplaced |g's; thus, intenstities
146SM2cE of |e transitions and log| {Ift} values aren't very reliable.
146SM cE E,IB$In |b{++} spectra the following components were observed: 2107
146SM2cE keV {I11}, I|b{++}|?4%; 1466 keV {I24}, I|b{++}|?85%; 798 keV {I15},
146SM3cE I|b{++}|?11%; I|b{++}=4.2% {I3} was obtained by 1962Fu16, 1964Ta11
146SM4cE from |b{++}/ce(K)(747|g). I|b{++}=5.8% {I5} was obtained by 1968Pa13
146SM5cE from I|g({+|+})/I|g(747)=0.115 {I10}
146SM cE TI$Feedings were determined from intensity balance.
146SM cG ECC$calculated by the evaluators from I(ce) and I|g values; |a(K)exp
146SM2cG are normalized to |a(K)(747|g, E2)=0.00397.
146SM cG E,RI$From 1992Ad04, except where noted otherwise. I|g and I(ce) data
146SM2cG are normalized to 747.2|g. I|g=2.45 for the doublet of 1551|g and
146SM3cG 1552|g from the 2932 keV level divided by evaluators using data from
146SM4cG (|a,x|g) reaction
146SM cG M$From |a(K)exp, |g(|q) from oriented nuclei.
146SM cG MR$From 1992Ad04 except as noted; data from 1984Kr02 were reanalyzed
146SM2cG by 1992Ad04 because of changes in decay scheme and values of J|p. For
146SM3cG details see 1992Ad04.
146SM cG MR(M)$From |g|g(|q) of 1975Si03
146SM cG E(a)$Not taken in to account in a least-squares fitting.
146SM cG E(A)$Transition reported by 1995Va40
146SM cG E(B)$Placement from 1995Va40. Unplaced (or placed elsewhere) in
146SMxcG 1992Ad04.
146SM cG E(C) Observed only by 1968Ha39
146SM cG E(D) Observed only by 1988Sa06
146SM cG E(F)$Placed by the evaluators from unplaced |g's
146SM cG M(G)$From L1/K ratio (1968Ha39)
146SM cG E(H),RI(H)$From 1993GrZX
146SM cG RI(v)$From 1995Va40
146SM cL E$From a least-squares fit to E|g's; normalized |h{+2}=1.6.
146SM cL J$From 'Adopted Levels'
146SM cL E(A)$Level introduced by 1995Va40
146SM DG CC$FROM BrIcc v2.3a (10-Sep-2014) 2008Ki07, "Frozen Orbitals" appr.
146SM cG MR$If no value given it was assumed |d=1.00 for E2/M1
146SM2cG and |d=0.10 for the other multipolarities
146EU P 0.0 4- 4.61 D 3 3879 6
146EU cP $T{-1/2} from 'Adopted Levels', Q(g.s.) from 2012Wa38
146SM N 0.981 19 1.0 1.0
146SM cN NR$with the assumption |SI|g(1+|a) to g.s.=100
146SM PN 4
146SM G 67.4 1 C
146SM G 68.6 1 C
146SM G 71.0 1 (D)
146SMF G FLAG=GC
146SM G 75.1 1 (M1) 3.85
146SMF G FLAG=GC
146SMS G KC=3.26 5$LC=0.465 7$MC=0.0999 15
146SMS G NC=0.0226 4$OC=0.00339 5$PC=0.000209 3
146SM G 95.0 5 D
146SM G 122.1 2 C
146SM G 123.9 5
146SMF G FLAG=CD
146SM G 134.6 2 C
146SM G 140.5 2 C
146SM G 143.0 2 C
146SM G 144.1 2 C
146SM G 144.8 2 C
146SM G 146.21 5 0.0323 17M1 0.575
146SM2 G K/L1=4.8 (1968Ha39)
146SMS G KC=0.488 7$LC=0.0688 10$MC=0.01478 21
146SMS G NC=0.00335 5$OC=0.000502 7$PC=3.11E-5 5
146SM G 146.9 2 C
146SM G 148.2 2 C
146SM G 151.1 2 C
146SM G 152.7 2 C
146SM G 165.2 2 C
146SM G 169.11 90.0092 10
146SM G 174.73 190.0145 15
146SM G 175.4 3 C
146SM G 186.8 3 C
146SM G 201.24 220.0106 25
146SM G 235.02 70.0221 14
146SM G 246.3 4 C
146SM G 252.7 4 C
146SM G 255.8 4 C
146SM G 261.53 180.0058 12
146SM G 265.2 4 C
146SM G 296.59 250.0068 15
146SM G 300.4 5 C
146SM G 308.3 5 C
146SM G 318.75 230.0056 15
146SM G 324.63 250.0070 13
146SM G 348.9 30.007 3
146SM G 355.48 60.044 3
146SM G 357.45 160.0178 25
146SM G 358.2 5 C
146SM G 360.1 C
146SM G 361.1 30.0059 22
146SM G 364.7 5 C
146SM G 368.94 210.0127 18
146SM G 370.5 6 C
146SM G 387.36 140.0197 25
146SM G 390.7 6 C
146SM G 434.3 50.13 5 D
146SM G 463.32 7 2.48 27
146SM G 482.3 50.034 D
146SM G 488.3 7 C
146SM G 501.8 8 C
146SM G 519.25 90.043 3
146SM G 529.15 150.032 3
146SM G 559.3 8 C
146SM G 567.5 5
146SM G 593.15 200.019 4
146SM G 651.68 240.046 6
146SM G 667.3 100.19 7 C
146SM G 673.40 90.031 3
146SM G 692.55 110.049 4
146SM G 712.0 11 C
146SM G 713.6 11 C
146SM G 738.54 9 0.098 8
146SM G 769.7 12 C
146SM G 797.56 220.041 5
146SM G 818.7 12 C
146SM G 821.1 12 C
146SM G 927.78 170.0150 20
146SM G 971.47 60.067 4
146SM G 972.5 15 C
146SM G 1053.0 30.10 3
146SM G 1081.2 16 C
146SM G 1102.64 150.0113 23
146SM G 1107.20 80.044 3
146SM G 1118.0 17 C
146SM G 1164.7 17 C
146SM G 1251.8 19 C
146SM G 1266.0 5 C
146SM G 1273.6 190.10 2 C
146SM G 1362.93 120.0215 20
146SM G 1402.20 190.038 9
146SM G 1434.42 180.0142 15
146SM G 1452.67 130.0281 20
146SM G 1458.8 22 C
146SM G 1530.7 23 C
146SM G 1537.9 50.024 4
146SM G 1605.9 24 C
146SM G 1619.2 24 C
146SM G 1638.39 60.0467 24
146SM G 1716.1 5 C
146SM G 1746.9 C
146SM G 1754.17 250.054 18
146SM G 1793 30.07 3 C
146SM G 1833 3 C
146SM G 1859.75 140.046 3
146SM G 1917 3 C
146SM G 1963.01 100.0183 13
146SM G 2032.15 210.0087 13
146SM G 2113.62 50.0106 7
146SM G 2178 3 C
146SM G 2189.3 3 C
146SM G 2193.2 50.0018 16
146SM G 2196.3 40.0051 14
146SM G 2213.4 50.0065 14
146SM G 2279.59 220.0055 14
146SM G 2300.4 40.0038 10
146SM G 2379.90 200.0093 11
146SM G 2711.8 210.013
146SM G 2740.8 30.0013 2
146SM G 2851.0 30.0011 2
146SM G 2860.4 40.0012 4
146SM G 3082.0 50.0006 2
146SM L 0.0 0+
146SM L 747.169 132+
146SM E 0.43 LT 2.4 LT 10.7 GT 2.8 LT 1U
146SMS E EAV=909 53$CK=0.712 5$CL=0.1056 8$CM+=0.03051 21
146SM G 747.159 16100 2E2 0.00473 C
146SM2 G CEK=100$ K/L=6.2 4 (1965Ba43)$
146SMS G KC=0.00397 6$LC=0.000596 9$MC=0.0001289 18
146SMS G NC=2.90E-5 4$OC=4.25E-6 6$PC=2.34E-7 4
146SM L 1380.289 163-
146SM E 2488 24 1.79 15 10.5 9 8.24 4 12.3 10
146SMS E EAV=667.2 27$CK=0.7201 14$CL=0.10459 21$CM+=0.03014 6
146SM G 633.083 2336.4 8E1 0.00257
146SM2 G CEK=22.4 18 (1970An18)$ EKC=0.0024 2
146SMS G KC=0.00220 3$LC=0.000289 4$MC=6.15E-5 9
146SMS G NC=1.389E-5 20$OC=2.07E-6 3$PC=1.262E-7 18
146SM L 1381.292 154+
146SM E 2488 24 2.45 19 14.5 11 8.10 4 16.9 13
146SMS E EAV=666.8 27$CK=0.7203 14$CL=0.10463 21$CM+=0.03015 6
146SM G 634.137 2145.7 10E2 0.00699 C
146SM2 G CEK=65.6 28 (1970An18)$ (L1+L2)/L3=9 3$ EKC=0.0057 3
146SMS G KC=0.00582 9$LC=0.000916 13$MC=0.000199 3
146SMS G NC=4.47E-5 7$OC=6.50E-6 9$PC=3.41E-7 5
146SM L 1647.980 152+
146SM E 0.02 LT 0.2 LT 9.9 GT 0.2 LT 1U
146SMS E EAV=548.5 27$CK=0.7741 11$CL=0.11287 17$CM+=0.03254 5
146SM G 267.59 30.099 8 F
146SM G 900.797 182.99 21E2+M1 -2.2 5 0.0034418 M
146SM2 G CEK=2.4 4 (1970An18)$ EKC=0.0032 6
146SMS G KC=0.00292 15$LC=0.000412 18$MC=8.9E-5 4
146SMS G NC=2.00E-5 9$OC=2.97E-6 14$PC=1.75E-7 10
146SM G 1648.00 3 0.583 18E2 1.05E-3
146SM2 G CEK=0.154 14 (1976Ad08)$ EKC=0.00075 7
146SMS G KC=0.000789 11$LC=0.0001043 15$MC=2.22E-5 4
146SMS G NC=5.04E-6 7$OC=7.54E-7 11$PC=4.70E-8 7$IPC=0.0001308 19
146SM L 1811.694 186+
146SM E 0.106 7 1.98 13 8.80 3 2.09 14
146SMS E EAV=476.3 27$CK=0.7988 8$CL=0.11682 13$CM+=0.03369 4
146SM G 430.386 184.79 10E2 0.0193 C
146SM2 G CEK=17.7 14 (1976Ad08)$ EKC=0.0147 13$
146SM3 G K/L=5.2 4$ K/L1 AP 5.2 $ K/L3 AP 28 (1968Ha39)
146SMS G KC=0.01567 22$LC=0.00286 4$MC=0.000628 9
146SMS G NC=0.0001407 20$OC=1.99E-5 3$PC=8.88E-7 13
146SM L 2045.689 174-
146SM E 1820 15 0.18 1 8.2 5 8.08 3 8.4 5
146SMS E EAV=373.5 27$CK=0.8228 5$CL=0.12092 9$CM+=0.03490 3
146SM cE $|b{++}/(|e+|b{++})=0.0224 {I21}; |e/|b{++}=43.7 {I42} (1988Sa06)
146SM G 664.65 14 0.48 42[E1+M2] 0.0026 3
146SM2 G CEK=1.7 4 (1970An18)$
146SMS G KC=0.00222 24$LC=0.00029 4$MC=6.3E-5 8
146SMS G NC=1.42E-5 18$OC=2.1E-6 3$PC=1.30E-7 16
146SM cG E$determined by 1970An18 from internal conversion spectra.
146SM cG RI$from I(ce)K and |a(K){-th}
146SM cG M$see comment to 665.4|g
146SM G 665.424 1510.52 15M1+E2 -2.7 5 0.0067424 MC
146SM2 G CEK=13.1 6 (1970An18)$
146SMS G KC=0.00565 21$LC=0.000854 24$MC=0.000185 5
146SMS G NC=4.16E-5 12$OC=6.10E-6 18$PC=3.36E-7 14
146SM cG E$665.40 {I13} in 1970An18
146SM cG RI$from I(ce)K and |a(K){-th}
146SM cG M$deduced from I(664.7|g+665.4|g), |a(K){-th} and acceptable
146SM2cG multipolarities for both |g's (1970An18)
146SM L 2083.426 165-
146SM E 0.044 3 2.39 18 8.59 4 2.43 18
146SMS E EAV=357.0 27$CK=0.8255 4$CL=0.12143 8$CM+=0.03505 3
146SM G 271.683 210.886 18E1 0.0189
146SM2 G CEK=2.7 3 (1969AdZW)$ K/L1=4.7 6 (1970An18)$ K/L1=5.5 (1968Ha39)$
146SM3 G EKC=0.0121 13$
146SMS G KC=0.01615 23$LC=0.00220 3$MC=0.000470 7
146SMS G NC=0.0001058 15$OC=1.550E-5 22$PC=8.80E-7 13
146SM G 702.099 193.88 11E1 0.00207 C
146SM2 G CEK=1.99 34 (1970An18)$ EKC=0.00204 35
146SMS G KC=0.001775 25$LC=0.000232 4$MC=4.93E-5 7
146SMS G NC=1.113E-5 16$OC=1.660E-6 24$PC=1.020E-7 15
146SM G 703.089 223.80 11E2 0.00545 C
146SM2 G CEK=3.9 5 (1970An18)$ EKC=0.0041 5$ K/L1=4.7 6 (1970An18)$
146SM3 G K/L1=5.5 (1968Ha39)
146SMS G KC=0.00457 7$LC=0.000697 10$MC=0.0001508 22
146SMS G NC=3.40E-5 5$OC=4.96E-6 7$PC=2.69E-7 4
146SM L 2155.818 172+
146SM E 0.0035818 1.50 5 9.796 16 1.50 5 1U
146SMS E EAV=343.1 27$CK=0.8309$CL=0.12909 6$CM+=0.03758 2
146SM G 775.533 250.097 3
146SM G 1408.66 3 1.25 3M1+E2 0.0016 3 C
146SM2 G CEK=0.7 1 (1969AdZW)$ EKC=0.0022 3$
146SMS G KC=0.00129 23$LC=0.00017 3$MC=3.6E-5 6
146SMS G NC=8.3E-6 14$OC=1.24E-6 22$PC=7.8E-8 15$IPC=4.85E-5 21
146SM cG M$possible E0 admixture (1984Kr02)
146SM cG MR$-3.2|<|d|<-0.9 (1984Kr02)
146SM G 2155.76 3 0.529 12E2 9.24E-4
146SM2 G CEK=0.076 17 (1969AdZW)$ EKC=0.00057 13$
146SMS G KC=0.000482 7$LC=6.24E-5 9$MC=1.328E-5 19
146SMS G NC=3.01E-6 5$OC=4.52E-7 7$PC=2.87E-8 4$IPC=0.000363 5
146SM L 2222.451 256+
146SM E 0.000465 0.30 3 10.42 5 0.30 3 1U
146SMS E EAV=313.4 27$CK=0.8310$CL=0.12965 6$CM+=0.03777 2
146SM G 410.766 190.656 14E2+M1 0.029 7
146SM2 G CEK=4.3 3 (1969AdZW)$ K/L1=5.5 12 (1968Ha39)$ EKC=0.0261 19
146SMS G KC=0.024 7$LC=0.0037 5$MC=0.00081 8
146SMS G NC=0.000183 20$OC=2.7E-5 4$PC=1.5E-6 5
146SM cG M$possible E0 admixture (1984Kr02)
146SM G 840.94 100.0205 11
146SM L 2224.99 7 (2+) A
146SM E 0.0010020 0.116 23 9.83 9 0.117 23
146SMS E EAV=294.9 27$CK=0.8329 3$CL=0.12299 6$CM+=0.03552 2
146SM G 844.72 150.055 20 BC
146SM G 1477.83 170.030 10 AC
146SM G 2224.98 150.052 3 B
146SM L 2269.879 173+
146SM E 0.008 3 1.3 4 8.76 14 1.3 4
146SMS E EAV=275.2 27$CK=0.8345 2$CL=0.12339 6$CM+=0.03565 2
146SM G 621.85 3 0.555 15M1+E2 0.010 3 C
146SM2 G CEK=1.0 3 (1976Ad08)$ EKC=0.0085 25$
146SMS G KC=0.0084 23$LC=0.00120 24$MC=0.00026 5
146SMS G NC=5.8E-5 12$OC=8.7E-6 19$PC=5.1E-7 16
146SM G 888.46 151.10 25E2+M1 -0.36 +11-180.0049924 C
146SMS G KC=0.00426 21$LC=0.000572 25$MC=0.000122 5
146SMS G NC=2.77E-5 12$OC=4.17E-6 19$PC=2.63E-7 14
146SM cG MR$-0.42 {I5} (1975Si03)
146SM cG $Ice(K)(888|g+889|g)=14.5 {I16} (1976Ad08), |a(K)exp=0.0047 {I11}
146SM2cG calculated taking into account of |a(K)(889|g,E1)=0.0011
146SM G 889.44 150.59 17[E1] 1.29E-3 C
146SMS G KC=0.001108 16$LC=0.0001431 20$MC=3.04E-5 5
146SMS G NC=6.88E-6 10$OC=1.028E-6 15$PC=6.40E-8 9
146SM G 1522.712 190.897 19M1+E2 1.2 5 0.0013211 MC
146SM2 G CEK=0.19 3 (1976Ad08)$ EKC=0.000843 13$
146SMS G KC=0.00106 10$LC=0.000140 12$MC=3.0E-5 3
146SMS G NC=6.8E-6 6$OC=1.02E-6 9$PC=6.4E-8 7$IPC=8.62E-5 23
146SM cG MR$the 2{+nd} value of |d=0.5 {I1} (1975Si03)
146SM L 2280.882 164+
146SM E 0.0424 23 6.99 24 8.024 16 7.03 24
146SMS E EAV=270.4 27$CK=0.8348 2$CL=0.12348 5$CM+=0.03568 2
146SM G 234.9 20.022 1 H
146SM G 632.888 401.30 2 BC
146SM G 899.486 221.38 10M1+E2 0.12 10 0.0050410 MC
146SM2 G CEK=1.4 4 (1970An18)$ EKC=0.0040 12$
146SM3 G FL=1381.292
146SM3 G FLAG=a
146SMS G KC=0.00431 9$LC=0.000576 11$MC=0.0001229 22
146SMS G NC=2.79E-5 5$OC=4.20E-6 8$PC=2.67E-7 6
146SM cG MR$the 2{+nd} value of |d=-1.25 {I25} (1975Si03)
146SM cG E$poor fit; the level energy difference equals 899.614 {I12}.
146SM G 1533.711 186.17 15E2 1.14E-3 C
146SM2 G CEK=1.42 7 (1976Ad08)$ EKC=0.000916 23$
146SMS G KC=0.000903 13$LC=0.0001203 17$MC=2.57E-5 4
146SMS G NC=5.81E-6 9$OC=8.69E-7 13$PC=5.38E-8 8$IPC=8.70E-5 13
146SM L 2400.92 32+
146SM E 0.000423 0.176 10 9.55 3 0.176 10
146SMS E EAV=217.6 26$CK=0.8373$CL=0.12436 4$CM+=0.03595 2
146SM G 1653.72 80.0573 20 C
146SM G 2400.94 4 0.245 8E2 9.42E-4
146SM2 G CEK=0.031 3 (1976Ad08)$ EKC=0.00050 5$
146SMS G KC=0.000397 6$LC=5.12E-5 8$MC=1.087E-5 16
146SMS G NC=2.46E-6 4$OC=3.71E-7 6$PC=2.36E-8 4$IPC=0.000480 7
146SM L 2439.070 20 4+
146SM E 0.010 1 6.1 6 7.99 5 6.1 6
146SMS E EAV=200.7 27$CK=0.8377$CL=0.12460 4$CM+=0.03603 2
146SM G 158.5 8 0.018 10E2+M1 0.459 10
146SM2 G CEK=0.88 13 (1968Ha39)$ EKC=0.19 11$
146SMS G KC=0.35 5$LC=0.09 4$MC=0.019 8
146SMS G NC=0.0043 17$OC=0.00059 19$PC=2.0E-5 6
146SM G 791.107 190.463 10E2 0.00415 C
146SMS G KC=0.00349 5$LC=0.000517 8$MC=0.0001115 16
146SMS G NC=2.52E-5 4$OC=3.69E-6 6$PC=2.06E-7 3
146SM cG M$E2+M3, |d=-0.09 {I10} in 1984Kr02; |a=0.0044 {I10} from BrIcc
146SM G 1057.62 102.3 4E2+M1 0.0028 7 C
146SMS G KC=0.0024 6$LC=0.00033 7$MC=7.0E-5 14
146SMS G NC=1.6E-5 4$OC=2.4E-6 5$PC=1.5E-7 4
146SM cG $Ice(K)(1057.62|g+1058.71|g)=2.09 {I10} (1976Ad08), |a(K)exp=0.0022
146SM2cG {I17} calculated taking into account of |a(K)(1058|g,E1)=0.000798 {I12}
146SM cG MR |<-0.88 or |>+11 (1992Ad04)
146SM G 1058.71 104.0 4[E1] 9.28E-4 C
146SMS G KC=0.000798 12$LC=0.0001023 15$MC=2.17E-5 3
146SMS G NC=4.92E-6 7$OC=7.36E-7 11$PC=4.62E-8 7
146SM L 2513.414 183-
146SM E 0.0012110 1.62 6 8.518 17 1.62 6
146SMS E EAV=167.6 27$CK=0.8380$CL=0.12504 4$CM+=0.03617 2
146SM G 467.762 250.068 4
146SM G 865.353 230.139 3E1+(M2) -0.10 +20-260.0015 14 C
146SMS G KC=0.0013 12$LC=0.00017 17$MC=4.E-5 4
146SMS G NC=8.E-6 9$OC=1.2E-6 13$PC=7.E-8 8
146SM G 1132.05 7 0.12 3[E1] 8.26E-4 C
146SMS G KC=0.000706 10$LC=9.03E-5 13$MC=1.92E-5 3
146SMS G NC=4.34E-6 6$OC=6.50E-7 10$PC=4.09E-8 6$IPC=5.73E-6 9
146SM G 1133.11 7 0.70 3M1+E2 +0.07 +9-7 0.002935 C
146SMS G KC=0.00251 4$LC=0.000332 6$MC=7.08E-5 11
146SMS G NC=1.606E-5 25$OC=2.42E-6 4$PC=1.546E-7 25$IPC=1.109E-6 16
146SM cG $Ice(K)(1132|g+1133|g)=0.42 {I10} (1976Ad08), |a(K)exp=0.0023 {I6}
146SM2cG calculated taking into account of |a(K)(1132|g, E1)=0.000706 {I10}
146SM cG MR$the 2{+nd} value is +1.14 {I18}, |a(K)=0.00201 {I8}
146SM G 1766.277 210.678 14E1 7.89E-4 C
146SM2 G CEK=0.054 8 (1969AdZW)$ EKC=0.00032 5$
146SMS G KC=0.000329 5$LC=4.15E-5 6$MC=8.80E-6 13
146SMS G NC=1.99E-6 3$OC=3.00E-7 5$PC=1.92E-8 3$IPC=0.000407 6
146SM L 2531.933 164+
146SM E 0.0016414 2.79 8 8.270 14 2.79 8
146SMS E EAV=159.3 27$CK=0.8381$CL=0.12514 4$CM+=0.03621 2
146SM G 251.2 4 C
146SM G 376.11 4 0.056 9 AC
146SM G 1150.626 152.15 4M1+E2 -0.42 5 0.002685 MC
146SM2 G CEK=1.31 9$ EKC=0.00243 17 (1969AdZW)$
146SMS G KC=0.00230 5$LC=0.000305 6$MC=6.51E-5 12
146SMS G NC=1.48E-5 3$OC=2.22E-6 4$PC=1.41E-7 3$IPC=1.87E-6 3
146SM G 1784.762 130.722 16E2 9.83E-4 C
146SM2 G CEK=0.12 2 (1976Ad08)$ EKC=0.00066 1$
146SMS G KC=0.000680 10$LC=8.93E-5 13$MC=1.90E-5 3
146SMS G NC=4.31E-6 6$OC=6.46E-7 9$PC=4.05E-8 6$IPC=0.000189 3
146SM L 2544.17 5(2+)
146SM E 0.061 4 9.92 3 0.061 4
146SMS E CK=0.8381$CL=0.12521 4$CM+=0.03623 2
146SM G 1796.89 80.0348 18 C
146SM G 2544.21 6 0.0492 15E2 9.64E-4
146SM2 G CEK=0.0052 8 (1976Ad08)$ EKC=0.00042 7$
146SMS G KC=0.000358 5$LC=4.60E-5 7$MC=9.78E-6 14
146SMS G NC=2.22E-6 4$OC=3.34E-7 5$PC=2.13E-8 3$IPC=0.000547 8
146SM L 2551.97 18 A
146SM E 0.087 17 9.76 9 0.087 17
146SMS E CK=0.8381$CL=0.12526 4$CM+=0.03624 2
146SM G 903.98 250.051 13 AC
146SM G 1804.79 240.037 11 C
146SMF G FLAG=Bv
146SM L 2605.10 6 A
146SM E 0.084 12 9.74 7 0.084 12
146SMS E CK=0.8379$CL=0.12556 4$CM+=0.03634 2
146SM G 1857.92 5 0.093 10 AC
146SM L 2636.01 7 A
146SM E 0.030 4 10.17 6 0.030 4
146SMS E CK=0.8378$CL=0.12573 4$CM+=0.03640 2
146SM G 1255.72 6 0.030 4 BC
146SM cG E$doublet line in 1995Va40, |DE|g from coincidence measurement can not
146SM2cG define what of 1380-1381 doublet levels is populated.
146SM L 2649.59 6(2+)
146SM E 0.017 4 10.40 11 0.017 4
146SMS E CK=0.8377$CL=0.12581 4$CM+=0.03643 2
146SM G 210.5 5 0.006 2 H
146SM G 1902.45 60.0392 17 C
146SM G 2650.35 170.0078 6 & ?
146SMF G FLAG=a
146SM cG E$doublet line, poor fit; the level energy difference equals
146SM2cG 2649.56 {I6}. The |g ray is placed from 3397.65 keV level also.
146SM L 2667.19 3 4-
146SM E 0.29 7 9.16 11 0.29 7
146SMS E CK=0.8376$CL=0.12592 4$CM+=0.03647 2
146SM G 397.31 6 0.18 7 BC
146SM G 583.76 30.114 6
146SM L 2678.274 174+
146SM E 6.77 21 7.782 15 6.77 21
146SMS E CK=0.8375$CL=0.12599 4$CM+=0.03649 2
146SM G 397.325 190.67 7E2+M1 0.031 8 vC
146SM2 G CEK=5.2 3 (1969AdZW)$ EKC=0.031 5$
146SMS G KC=0.026 7$LC=0.0041 5$MC=0.00089 8
146SMS G NC=0.000201 19$OC=2.9E-5 4$PC=1.6E-6 5
146SM cG E$poor fit; the level energy difference equals 397.392 {I12}.
146SM G 522.2 20.139 4
146SMF G FLAG=BF
146SM G 1030.274 370.0171 14 C
146SMF G FLAG=Bv
146SM G 1297.028 165.47 11E2+(M1) -1.25 25 0.001758 MC
146SM cG MR$the 2{+nd} value of |d=0.15 {I5} (1975Si03)
146SM2 G CEK=2.17 10 (1976Ad08)$ EKC=0.00158 8$
146SMS G KC=0.00148 7$LC=0.000197 9$MC=4.22E-5 18
146SMS G NC=9.6E-6 4$OC=1.43E-6 7$PC=8.9E-8 5$IPC=2.05E-5 4
146SM cG E$poor fit; the level energy difference equals 1296.938 {I11}.
146SM G 1931.087 201.21 3E2 9.42E-4 C
146SM2 G CEK=0.130 13 (1976Ad08)$ EKC=0.00043 5$
146SMS G KC=0.000588 9$LC=7.68E-5 11$MC=1.635E-5 23
146SMS G NC=3.70E-6 6$OC=5.56E-7 8$PC=3.50E-8 5$IPC=0.000257 4
146SM cG M$for (E2+M3) |d=+0.03 {I3} (1984Kr02), |d=0.05 {I5} (1975Si03)
146SM L 2684.712 24 (2+)
146SM E 0.082 15 10.40 8 0.082 15 1U
146SMS E CK=0.8258 2$CL=0.1347 1$CM+=0.03952 4
146SM cE IB$first-forbidden unique transition determined form of the spectrum
146SM2cE by 1964Ta11
146SM G 403.73 4 0.074 8 C
146SMF G FLAG=Bv
146SM G 1036.71 100.052 3 C
146SM G 1303.46 40.079 4 C
146SM G 1937.57 110.076 5 C
146SM L 2740.7 5 A
146SM G 1994.0 100.014 4 AC
146SM L 2788.223 215-
146SM E 4.43 16 7.879 17 4.43 16
146SMS E CK=0.8365$CL=0.12671 5$CM+=0.03674 2
146SM G 704.774 191.91 4M1 0.00915 C
146SM2 G CEK=4.0 6$ EKC=0.0083 12$
146SMS G KC=0.00782 11$LC=0.001052 15$MC=0.000225 4
146SMS G NC=5.10E-5 8$OC=7.68E-6 11$PC=4.87E-7 7
146SM G 742.65 150.72 10 C
146SM G 976.51 5 0.19 7 C
146SMF G FLAG=Bv
146SM G 1406.98 3 1.75 4(E1) 7.01E-4 C
146SM2 G CEK=0.21 (1976Ad08)$ EKC=0.00048$
146SMS G KC=0.000481 7$LC=6.11E-5 9$MC=1.296E-5 19
146SMS G NC=2.93E-6 5$OC=4.41E-7 7$PC=2.80E-8 4$IPC=0.0001418 20
146SM L 2799.93 4 3+
146SM E 0.60 3 8.738 23 0.60 3
146SMS E CK=0.8364$CL=0.12680 5$CM+=0.03677 2
146SM G 715.1 11 C
146SM G 753.80 80.027 3 ?
146SMF G FL=2045.689
146SMF G FLAG=a
146SM cG E$poor fit; the level energy difference equals 754.17 {I4}. |g ray
146SM2cG not reported in 1995Va40.
146SM G 2052.71 5 0.673 23M1+E2 +0.501 +25-231.07E-32 C
146SM2 G CEK=0.12 2$ EKC=0.00071 12$
146SMS G KC=0.000625 9$LC=8.14E-5 12$MC=1.732E-5 25
146SMS G NC=3.93E-6 6$OC=5.92E-7 9$PC=3.80E-8 6$IPC=0.000343 5
146SM cG MR$the 2{+nd} value is +4.4 {I+5-3}, at that |a(K)=0.000532 {I8}
146SM L 2829.24 16 (2+) A
146SM E 0.11 LT 9.4 GT 0.11 LT
146SMS E CK=0.8361$CL=0.12703 5$CM+=0.03684 2
146SM G 549.1 100.14 3 AC
146SM G 1448.1 2 0.18 7 AC
146SM G 2081.7 3 0.1 AP AC
146SM L 2850.304 234+
146SM E 0.400 16 8.871 19 0.400 16
146SMS E CK=0.8359$CL=0.12720 5$CM+=0.03690 2
146SM G 172.1 3 C
146SM G 569.53 5 0.118 7M1 0.01551 vC
146SM2 G CEK=0.37 2 (1969AdZW)$ EKC=0.0124 24
146SMS G KC=0.01323 19$LC=0.00179 3$MC=0.000384 6
146SMS G NC=8.70E-5 13$OC=1.309E-5 19$PC=8.27E-7 12
146SM G 766.838 230.0922 24 C
146SM G 804.67 6 0.095 3(E1+M2) 0.79 +29-240.0078 25
146SM2 G CEK=0.16 5 (1965Ba43)$ EKC=0.0067 21$
146SMS G KC=0.0066 21$LC=0.0009 3$MC=0.00020 7
146SMS G NC=4.6E-5 15$OC=6.9E-6 23$PC=4.3E-7 14
146SM cG M$M1 from |a(K)exp (calculated |a(K)=0.00566), but decay scheme
146SM2cG requires E1. Hence, if placement is correct, it must be E1+M2
146SM G 1038.35 200.024 3
146SM G 1469.86 70.098 4 C
146SM G 2103.16 5 0.075 3E2 9.25E-4 C
146SMS G KC=0.000504 7$LC=6.54E-5 10$MC=1.391E-5 20
146SMS G NC=3.15E-6 5$OC=4.73E-7 7$PC=3.00E-8 5$IPC=0.000338 5
146SM cG M$from |g(|q)
146SM L 2879.11 7
146SM E 0.0515 24 9.735 22 0.0515 24
146SMS E CK=0.8356$CL=0.12744 6$CM+=0.03699 2
146SM G 833.1 2 0.012 1 H
146SM G 1231.03 100.0167 16 C
146SM G 2132.09 100.0238 11 C
146SM L 2898.322 205+
146SM E 1.25 3 8.333 13 1.25 3
146SMS E CK=0.8353$CL=0.12761 6$CM+=0.03704 2
146SM G 814.70 250.0088 16
146SM G 1086.637 150.573 12M1 0.00323
146SM2 G CEK=0.41 8$ EKC=0.0028 6$
146SMS G KC=0.00277 4$LC=0.000367 6$MC=7.83E-5 11
146SMS G NC=1.777E-5 25$OC=2.68E-6 4$PC=1.710E-7 24
146SM G 1517.000 200.680 14M1+E2 0.0013722 C
146SM2 G CEK=0.18 3 (1976Ad08)$ EKC=0.0011 3$
146SMS G KC=0.00110 18$LC=0.000145 23$MC=3.1E-5 5
146SMS G NC=7.0E-6 11$OC=1.06E-6 17$PC=6.7E-8 12$IPC=8.5E-5 4
146SM cG MR$1.0 {I17} from BriccMixing
146SM L 2905.98 8 (4+) A
146SM E 0.22 8 9.08 16 0.22 8
146SMS E CK=0.8352$CL=0.12768 6$CM+=0.03707 2
146SM G 636.22 130.19 8 AC
146SM G 1094.10 110.0275 24 BC
146SM G 2158.92 130.0052 22 AC
146SM L 2932.33 5 (4+) A
146SM E 0.36 7 8.84 9 0.36 7
146SMS E CK=0.8349$CL=0.12793 6$CM+=0.03715 2
146SM G 848.84 9 0.14 3 @C
146SM2 G FLAG=B
146SM G 1120.79 90.0266 15 C
146SM G 1550.98 110.148 27 BC
146SM cG M$for (1551.99|g+1550.98|g) doublet ce(K)=0.039 {I8} (1969AdZW)
146SM G 1551.99 110.097 32 BC
146SM cG M$for (1551.99|g+1550.98|g) doublet ce(K)=0.039 {I8} (1969AdZW)
146SM L 2968.83 42+,3+
146SM E 0.117 11 9.29 5 0.117 11
146SMS E CK=0.83441 9$CL=0.12831 7$CM+=0.03728 3
146SM G 1587.53 80.011 7 C
146SM G 1588.53 80.014 7 C
146SM G 2221.64 5 0.094 4M1 1.08E-3 C
146SM2 G CEK=0.0170 26 (1969AdZW)$ EKC=0.00072 11$
146SMS G KC=0.000547 8$LC=7.10E-5 10$MC=1.511E-5 22
146SMS G NC=3.43E-6 5$OC=5.17E-7 8$PC=3.34E-8 5$IPC=0.000441 7
146SM L 2973.34 3 3+,4+
146SM E 0.66 7 8.54 5 0.66 7
146SMS E CK=0.83434 9$CL=0.12836 7$CM+=0.03730 3
146SM G 534.26 9 0.13 4 C
146SMF G FLAG=Bv
146SM G 703.46 6 0.108 20 AC
146SM G 1325.35 40.090 3 C
146SM G 1592.04 6 0.17 3(M1+E2) 0.0012719 C
146SMF G FLAG=Bv
146SM2 G CEK=0.083 20$ EKC=0.0019 8$
146SMS G KC=0.00099 16$LC=0.000131 20$MC=2.8E-5 5
146SMS G NC=6.3E-6 10$OC=9.5E-7 15$PC=6.0E-8 11$IPC=0.000114 6
146SM cG EKC$calculated from ce(K)(1592|g+1593|g)=0.10 {I2} (1969AdZw) and
146SM2cG |a(K)(1593|g, E1)=0.000390 {I6}
146SM G 1593.05 6 0.17 3[E1] 7.31E-4 C
146SMF G FLAG=Bv
146SMS G KC=0.000390 6$LC=4.94E-5 7$MC=1.047E-5 15
146SMS G NC=2.37E-6 4$OC=3.56E-7 5$PC=2.27E-8 4$IPC=0.000278 4
146SM L 2974.39 15 3- A
146SM E 0.15 3 9.18 9 0.15 3
146SMS E CK=0.83433 9$CL=0.12837 7$CM+=0.03730 3
146SM G 295.59 250.022 5 AC
146SM G 891.29 200.12 3 AC
146SM G 2227.2 4 0.01 AP C
146SMF G FLAG=Bv
146SM L 3014.624 233+
146SM E 0.93 3 8.346 16 0.93 3
146SMS E CK=0.8337 1$CL=0.12882 8$CM+=0.03746 3
146SM G 575.64 160.021 6
146SM G 733.97 130.048 6
146SM G 968.83 9 0.047 3 F
146SM G 1366.69 8 0.0351 24 BC
146SM G 1633.30 3 0.418 9M1 1.40E-3 C
146SM2 G CEK=0.13 3 (1976Ad08)$ EKC=0.0012 3$
146SMS G KC=0.001083 16$LC=0.0001419 20$MC=3.02E-5 5
146SMS G NC=6.86E-6 10$OC=1.034E-6 15$PC=6.64E-8 10$IPC=0.0001372 20
146SM G 2267.49 4 0.444 12M1 1.08E-3 C
146SM2 G CEK=0.068 5 (1976Ad08)$ EKC=0.00061 5$
146SMS G KC=0.000523 8$LC=6.78E-5 10$MC=1.444E-5 21
146SMS G NC=3.28E-6 5$OC=4.94E-7 7$PC=3.19E-8 5$IPC=0.000466 7
146SM L 3020.611 0+ A
146SM G 2273.4 150.048 5 AC
146SM L 3039.510 A
146SM E 0.20 4 8.99 9 0.20 4
146SMS E CK=0.8333 1$CL=0.12913 8$CM+=0.03756 3
146SM G 600.4 100.20 4 AC
146SM L 3058.08 6
146SM E 0.038 8 9.69 10 0.038 8
146SMS E CK=0.8330 1$CL=0.12937 8$CM+=0.03765 3
146SM G 833.11 9 0.0122 13 BC
146SM G 974.9 1 0.100 5 H
146SM cG E$Obviously, 274.9 keV is a misprint in 1993GrZX
146SM G 2310.81 80.0208 10 C
146SM L 3067.705 213+
146SM E 0.747 25 8.384 17 0.747 25
146SMS E CK=0.8328 2$CL=0.12950 9$CM+=0.03769 3
146SM G 1022.05 9 0.023 7 AC
146SM G 1419.70 30.131 5 C
146SM G 1686.397 210.637 13M1+E2 -0.52 +7-10 0.001273 C
146SM2 G CEK=0.17 3 (1976Ad08)$ EKC=0.00106 18$
146SMS G KC=0.000954 21$LC=0.000125 3$MC=2.66E-5 6
146SMS G NC=6.04E-6 14$OC=9.10E-7 21$PC=5.82E-8 14$IPC=0.0001587 25
146SM cG M$from 1984Kr02
146SM G 2320.54 4 0.0970 23M1+E2 0.001008 C
146SM2 G CEK=0.017 4 (1976Ad08)$ EKC=0.00049 12$
146SMS G KC=0.00046 4$LC=5.9E-5 5$MC=1.26E-5 11
146SMS G NC=2.87E-6 25$OC=4.3E-7 4$PC=2.8E-8 3$IPC=0.00047 3
146SM L 3072.932 235+
146SM E 0.801 23 8.348 15 0.801 23
146SMS E CK=0.8327 2$CL=0.12957 9$CM+=0.03771 3
146SM G 222.33 100.0145 10M1 0.181
146SM2 G CEK=0.81 16 (1968Ha39)$ EKC=0.22 5$
146SMS G KC=0.1535 22$LC=0.0214 3$MC=0.00460 7
146SMS G NC=0.001044 15$OC=0.0001566 22$PC=9.74E-6 14
146SM G 850.49 100.236 13M1 0.00580
146SM2 G CEK=0.42 6$ EKC=0.0071 10 (1976Ad08)$
146SMS G KC=0.00496 7$LC=0.000663 10$MC=0.0001415 20
146SMS G NC=3.21E-5 5$OC=4.84E-6 7$PC=3.07E-7 5
146SM G 989.49 40.0661 22 C
146SM G 1027.26 50.073 3 C
146SM G 1691.643 220.419 9E2+M1 -0.17 5 1.32E-32 C
146SM2 G CEK=0.095 19 (1968Ha39)$ EKC=0.00090 18$
146SMS G KC=0.000993 15$LC=0.0001300 19$MC=2.77E-5 4
146SMS G NC=6.28E-6 10$OC=9.48E-7 14$PC=6.09E-8 9$IPC=0.0001640 24
146SM cG MR$the 2{+nd} value of |d=-3.0 {I5} corresponds to |a(K)=0.000776
146SM2cG {I15}. I(ce)=0.09 {I3} (1976Ad08)
146SM L 3093.117 183+
146SM E 1.03 3 8.215 15 1.03 3
146SMS E CK=0.8323 2$CL=0.12986 9$CM+=0.03781 3
146SM G 812.21 3 0.0802 25M1 0.00648 C
146SM2 G CEK=0.19 5 (1965Ba43)$ EKC=0.0094 25$
146SMS G KC=0.00554 8$LC=0.000742 11$MC=0.0001584 23
146SMS G NC=3.59E-5 5$OC=5.41E-6 8$PC=3.44E-7 5
146SM G 823.21 3 0.0562 20E2 0.00379 C
146SM2 G CEK=0.04 2$ EKC=0.0028 14 (1976Ad08)$
146SMS G KC=0.00320 5$LC=0.000469 7$MC=0.0001011 15
146SMS G NC=2.28E-5 4$OC=3.35E-6 5$PC=1.89E-7 3
146SM G 937.29 4 0.034 4 C
146SMF G FLAG=Av
146SM G 1047.36 50.0497 15 C
146SM G 1445.136 230.371 10M1+E2 0.0014925 C
146SM2 G CEK=0.14 4$ EKC=0.0015 4
146SM cG $K:L:M=0.14 4:0.045:0.015 (1965Ba43)
146SMS G KC=0.00122 21$LC=0.00016 3$MC=3.4E-5 6
146SMS G NC=7.8E-6 13$OC=1.17E-6 20$PC=7.4E-8 14$IPC=6.0E-5 3
146SM cG RI$according to the table 6 of 1995Va40, 1447.12, 1448.21, 1448.1 |g'
146SM2cG bring the insignificant contribution to intensity of the 1445.1
146SM3cG transition.
146SM G 1711.844 220.211 5M1+E2 0.0011615 C
146SMS G KC=0.00085 12$LC=0.000112 16$MC=2.4E-5 4
146SMS G NC=5.4E-6 8$OC=8.1E-7 12$PC=5.2E-8 8$IPC=0.000166 9
146SM cG $ce(K)=0.043 {I7} (1969AdZW); |a(K)exp=0.00081 {I8}
146SM G 2345.91 30.400 9 M1+E2 0.001007 C
146SM2 G CEK=0.054 5 (1976Ad08)$ EKC=0.00054 5$
146SMS G KC=0.00045 4$LC=5.8E-5 5$MC=1.24E-5 11
146SMS G NC=2.81E-6 24$OC=4.2E-7 4$PC=2.7E-8 3$IPC=0.00048 3
146SM L 3105.37 5(2+,3,4+)
146SM E 0.158 15 9.01 5 0.158 15
146SMS E CK=0.8321 2$CL=0.1300 1$CM+=0.03788 4
146SM G 1724.07 60.070 10 C
146SM G 1725.08 60.060 10 C
146SM G 2358.17 130.0305 18 C
146SM L 3123.28 22 (2+,3,4+) A
146SM E 0.21 4 8.87 9 0.21 4
146SMS E CK=0.8317 2$CL=0.1303 1$CM+=0.03797 4
146SM G 445.0 3 0.20 4 AC
146SM G 1475.3 3 0.011 3 BC
146SM L 3129.7 3 A
146SM E 0.018 7 9.93 17 0.018 7
146SMS E CK=0.8316 2$CL=0.1304 1$CM+=0.03801 4
146SM G 848.85 300.018 7 @C
146SM2 G FLAG=B
146SM L 3136.460 223-
146SM E 1.22 6 8.090 23 1.22 6
146SMS E CK=0.8314 2$CL=0.1305 1$CM+=0.03804 4
146SM G 1090.844 210.218 5M1 0.00321 C
146SMF G FLAG=a
146SM2 G CEK=0.19 7$ EKC=0.0036 13 (1965Ba43)$
146SMS G KC=0.00274 4$LC=0.000364 5$MC=7.76E-5 11
146SMS G NC=1.761E-5 25$OC=2.65E-6 4$PC=1.695E-7 24
146SM cG E$poor fit; the level energy difference equals 1090.664 {I25}.
146SM G 1488.48 130.035 4 C
146SM G 1756.08 3 0.93 3M1+E2 -0.10 4 1.27E-3 C
146SM2 G CEK=0.20 2 (1976Ad08)$ EKC=0.00086 8$
146SMS G KC=0.000918 13$LC=0.0001200 17$MC=2.56E-5 4
146SMS G NC=5.80E-6 9$OC=8.75E-7 13$PC=5.62E-8 8$IPC=0.000196 3
146SM cG MR$the 2{+nd} value is +1.62 {I+15-14}, |a(K)=0.000761 {I4}
146SM G 2389.13 4 0.156 6E1+M2 -0.05 +4-5 1.08E-32 C
146SMF G FLAG=v
146SM2 G CEK=0.019 2 (1976Ad08)$ EKC=0.0035 4$
146SMS G KC=0.000206 7$LC=2.58E-5 9$MC=5.47E-6 19
146SMS G NC=1.24E-6 5$OC=1.87E-7 7$PC=1.20E-8 4$IPC=0.000840 13
146SM cG EKC$Excess of experimental value above calculated, apparently, is
146SM2cG caused by the contribution to a conversion line of a doublet
146SM3cG 2389.00|g, I|g=0.057.
146SM cG E$poor fit; the level energy difference equals 2389.283 {I18}.
146SM L 3151.43 3 A
146SM E 0.046 5 9.49 5 0.046 5
146SMS E CK=0.8311 2$CL=0.1308 1$CM+=0.03813 4
146SM G 870.55 6 0.011 4 AC
146SM G 881.55 3 0.0355 16 C
146SM L 3183.924 203+
146SM E 1.87 5 7.843 15 1.87 5
146SMS E CK=0.8303 2$CL=0.1314 2$CM+=0.03833 4
146SM G 914.031 160.630 14M1 0.00488 C
146SM2 G CEK=0.7 1$ CEL=0.12 6 (1965Ba43)$ EKC=0.0044 6$ ELC=0.0008 4
146SMS G KC=0.00417 6$LC=0.000556 8$MC=0.0001188 17
146SMS G NC=2.69E-5 4$OC=4.06E-6 6$PC=2.58E-7 4
146SM G 1028.10 5 0.021 3 AC
146SM G 1535.93 5 0.176 15 AC
146SM G 1802.76 7 0.156 8M1+E2 0.0011013 C
146SM2 G CEK=0.072$ CEL=0.016 (1965Ad06)$ EKC=0.0018$ ELC=0.0004$
146SMS G KC=0.00077 10$LC=0.000100 13$MC=2.1E-5 3
146SMS G NC=4.8E-6 7$OC=7.3E-7 10$PC=4.6E-8 7$IPC=0.000208 12
146SM G 2436.74 4 0.946 20M1+E2 0.35 10 1.06E-32 MC
146SM2 G CEK=0.114$ CEL=0.016 (1965Ad06)$ EKC=0.00048$ ELC=0.000067$
146SMS G KC=0.000441 8$LC=5.70E-5 10$MC=1.214E-5 20
146SMS G NC=2.75E-6 5$OC=4.15E-7 7$PC=2.68E-8 5$IPC=0.000551 9
146SM cG MR$the 2{+nd} value of |d=1.75 {I50} (1975Si03)
146SM L 3200.014 194-
146SM E 0.761 19 8.212 14 0.761 19
146SMS E CK=0.8299 2$CL=0.1317 2$CM+=0.03844 5
146SM G 686.54 100.0322 24
146SM G 760.963 230.094 3 C
146SM G 918.94 60.071 3 C
146SM G 930.39 110.020 5
146SM G 1116.566 150.429 9M1+E2 -0.30 +9-12 0.002959 C
146SM2 G CEK=0.35 6$ CEL AP 0.06 (1965Ba43)$ EKC=0.0033 6$ ELC AP 0.00056$
146SMS G KC=0.00252 8$LC=0.000335 9$MC=7.15E-5 19
146SMS G NC=1.62E-5 5$OC=2.44E-6 7$PC=1.55E-7 5$IPC=6.29E-7 10
146SM cG MR$the 2{+nd} value -2.5 {I+4-6}, at that |a(K)=0.00181
146SM G 1818.78 30.125 3 C
146SM L 3220.85 6 (3-,4,5-) A
146SM E 0.20 3 8.76 7 0.20 3
146SMS E CK=0.8293 2$CL=0.1321 2$CM+=0.03859 5
146SM G 1137.66 130.043 3 C
146SMF G FLAG=Bv
146SM G 1175.09 110.14 3 C
146SMF G FLAG=Bv
146SM G 1840.52 6 0.020 8 C
146SMF G FLAG=Bv
146SM L 3223.915 (2+,3,4+) A
146SM E 0.12 4 8.98 15 0.12 4
146SMS E CK=0.8292 2$CL=0.13218 14$CM+=0.03861 5
146SM G 394.7 150.12 4 AC
146SM L 3231.63 64+
146SM E 0.41 7 8.44 8 0.41 7
146SMS E CK=0.8290 2$CL=0.13235 14$CM+=0.03867 5
146SM G 553.35 110.38 7 AC
146SM G 1009.27 110.0119 12
146SM G 2484.39 80.0202 8 C
146SM L 3238.639 234+
146SM E 0.520 12 8.323 14 0.520 12
146SMS E CK=0.8288 2$CL=0.13251 14$CM+=0.03872 5
146SM G 224.05 30.043 3
146SM G 837.72 8 0.0061 8 C
146SMF G FLAG=Bv
146SM G 1155.08 40.192 6 C
146SM cG E$poor fit; the level energy difference equals 1155.215 {I20}.
146SM G 1857.33 5 0.052 10
146SM G 1858.34 5 0.059 10
146SM G 2491.51 4 0.182 5E2 9.55E-4 C
146SM2 G CEK=0.026 3 (1976Ad08)$ EKC=0.00057 6$
146SMS G KC=0.000372 6$LC=4.78E-5 7$MC=1.016E-5 15
146SMS G NC=2.30E-6 4$OC=3.46E-7 5$PC=2.21E-8 3$IPC=0.000523 8
146SM L 3244.65 4(2+,3,4+)
146SM E 0.355 24 8.48 3 0.355 24
146SMS E CK=0.8286 2$CL=0.13265 14$CM+=0.03877 5
146SM G 843.72 9 0.0033 7 C
146SMF G FL=2400.92
146SMF G FLAG=Av
146SM G 974.77 8 0.149 22 C
146SMF G FLAG=Bv
146SM G 1088.83 8 0.032 3 AC
146SM G 1596.66 70.099 4 C
146SM G 1863.29 170.0144 13
146SM G 2497.46 50.0632 17 C
146SM L 3259.924 195-
146SM E 2.19 9 7.668 21 2.19 9
146SMS E CK=0.8281 2$CL=0.13301 15$CM+=0.03889 5
146SM G 202.2 4 0.010 2 H
146SM G 471.67 40.0365 18 C
146SM G 979.09 100.045 3 C
146SM G 1176.522 231.64 4M1+E2 0.77 10 0.002357 C
146SM2 G CEK=1.09 8$ EKC=0.0026 2$
146SM cG $K:L:M=1.02 15:0.17 6:0.06 (1965Ba43)
146SMS G KC=0.00201 6$LC=0.000268 7$MC=5.73E-5 15
146SMS G NC=1.30E-5 4$OC=1.95E-6 6$PC=1.23E-7 4$IPC=3.62E-6 6
146SM cG MR$other value 0.01 {I6} (1984Kr02), at that |a(K)=0.00230 {I4}
146SM G 1214.209 210.319 7M1+E2 0.75 +26-130.0022013 C
146SMS G KC=0.00188 11$LC=0.000251 14$MC=5.4E-5 3
146SMS G NC=1.21E-5 7$OC=1.82E-6 10$PC=1.15E-7 7$IPC=7.67E-6 13
146SM cG MR$other value 1.9 {I5} (1984Kr02)
146SM G 1448.21 60.093 3 C
146SM G 1878.62 3 0.150 10E1 8.36E-4 C
146SM2 G CEK=0.014$ EKC=0.00037$
146SMS G KC=0.000298 5$LC=3.75E-5 6$MC=7.95E-6 12
146SMS G NC=1.80E-6 3$OC=2.71E-7 4$PC=1.733E-8 25$IPC=0.000491 7
146SM cG EKC$calculated from ce(K)(1878.62|g+1879.63|g)=0.026 (1965Ad06), and
146SM2cG |a(K)(1879|g, E2)=0.000618
146SM G 1879.63 3 0.080 10[E2] 9.53E-4 C
146SMS G KC=0.000618 9$LC=8.09E-5 12$MC=1.722E-5 25
146SMS G NC=3.90E-6 6$OC=5.85E-7 9$PC=3.68E-8 6$IPC=0.000233 4
146SM L 3278.17 13 2+ A
146SM E 0.14 5 8.83 16 0.14 5
146SMS E CK=0.8275 3$CL=0.13347 16$CM+=0.03905 6
146SM G 449.2 5 0.13 5 AC
146SM G 1896.85 190.008 4 C
146SM2 G FLAG=B
146SM cG $for the triplet of 1896.85, 1897.85 and 1898.17 transitions
146SM2cG ce(K)=0.0078 {I26} (1969AdZW)
146SM G 1897.85 190.008 4 C
146SM2 G FLAG=B
146SM cG $see comment to 1896.85|g
146SM L 3288.60 17 (2+,3,4+) A
146SM E 0.22 6 8.62 12 0.22 6
146SMS E CK=0.8271 3$CL=0.13375 17$CM+=0.03915 6
146SM G 459.35 6 0.21 6 C
146SMF G FLAG=Bv
146SM G 548.4 100.014 4 AC
146SM L 3329.90 5 (2+,3,4+)
146SM E 0.148 6 8.726 21 0.148 6
146SMS E CK=0.8255 3$CL=0.13497 20$CM+=0.03956 7
146SM G 1681.94 130.0218 17 C
146SM G 1948.65 60.075 3 C
146SM G 2582.51 110.0099 7 C
146SM L 3338.27 43+
146SM E 0.177 5 8.634 17 0.177 5
146SMS E CK=0.8251 3$CL=0.13524 20$CM+=0.03966 7
146SM G 550.4 30.035 6
146SM G 937.33 8 0.0022 4 C
146SMF G FL=2400.92
146SMF G FLAG=Bv
146SM G 1068.32 70.0343 17 C
146SM G 1956.97 40.124 3 C
146SM G 2591.11 8 0.0192 6M1+(E2) 0.001037 C
146SM2 G CEK=0.0026 8 (1976Ad08)$ EKC=0.00054 16$
146SMS G KC=0.000369 24$LC=4.8E-5 4$MC=1.01E-5 7
146SMS G NC=2.29E-6 16$OC=3.46E-7 24$PC=2.22E-8 17$IPC=0.00060 4
146SM L 3361.07 33-,4-
146SM E 0.189 8 8.565 22 0.189 8
146SMS E CK=0.8240 3$CL=0.13603 22$CM+=0.03993 8
146SM G 1277.55 6 0.0433 19 BC
146SM G 1980.79 3 0.148 6M1 1.13E-3 C
146SM2 G CEK=0.029 5 (1969AdZW)$ EKC=0.00078 14$
146SMS G KC=0.000703 10$LC=9.16E-5 13$MC=1.95E-5 3
146SMS G NC=4.43E-6 7$OC=6.68E-7 10$PC=4.30E-8 6$IPC=0.000311 5
146SM L 3368.75 8(4+)
146SM E 0.038 10 9.25 12 0.038 10
146SMS E CK=0.8237 3$CL=0.13631 23$CM+=0.04002 8
146SM G 1987.44 150.012 7 C
146SM G 1988.45 150.017 7 C
146SM G 2621.56 110.0097 6 C
146SM L 3376.76 44+
146SM E 0.551 25 8.071 23 0.551 25
146SMS E CK=0.8233 4$CL=0.13661 24$CM+=0.04013 9
146SM G 937.68 8 0.044 16 C
146SMF G FLAG=Bv
146SM G 1293.48 130.116 11 C
146SM G 1330.33 200.030 4 C
146SMF G FL=2045.689
146SMF G FLAG=a
146SM cG E$poor fit; the level energy difference equals 1331.06 {I4}.
146SM G 1728.76 7 0.012 3 AC
146SM G 1995.75 9 0.291 11M1+(E2) 0.0010310 C
146SM2 G CEK=0.07 2 (1976Ad08)$ EKC=0.00095 27$
146SMS G KC=0.00062 7$LC=8.1E-5 9$MC=1.73E-5 20
146SMS G NC=3.9E-6 5$OC=5.9E-7 7$PC=3.8E-8 5$IPC=0.000303 17
146SM cG E$poor fit; the level energy difference equals 1995.47 {I4}.
146SM G 2629.50 5 0.0665 17E2 9.80E-4 C
146SM2 G CEK=0.0089 13 (1976Ad08)$ EKC=0.00041 6$
146SMS G KC=0.000338 5$LC=4.34E-5 6$MC=9.21E-6 13
146SMS G NC=2.09E-6 3$OC=3.14E-7 5$PC=2.01E-8 3$IPC=0.000587 9
146SM L 3378.43 5 (3-,4,5-)
146SM E 0.278 15 8.36 3 0.278 15
146SMS E CK=0.8232 4$CL=0.13668 24$CM+=0.04015 9
146SM G 1332.74 40.193 7D+Q C
146SM G 1998.00 150.089 12 C
146SM L 3391.673 223-
146SM E 0.404 17 8.177 22 0.404 17
146SMS E CK=0.8225 4$CL=0.1372 3$CM+=0.04033 9
146SM G 459.4 20.053 4 H
146SM G 1110.79 5 0.013 3 AC
146SM G 1743.69 30.0378 18 C
146SM G 2010.37 4 0.060 10[E1] 8.97E-4 C
146SMS G KC=0.000267 4$LC=3.36E-5 5$MC=7.12E-6 10
146SMS G NC=1.613E-6 23$OC=2.43E-7 4$PC=1.556E-8 22$IPC=0.000587 9
146SM G 2011.38 4 0.140 10M1+E2 0.0010310 C
146SM2 G CEK=0.022 5 $ EKC=0.00063 15$
146SMS G KC=0.00061 7$LC=8.0E-5 9$MC=1.70E-5 19
146SMS G NC=3.9E-6 5$OC=5.8E-7 7$PC=3.7E-8 5$IPC=0.000311 18
146SM cG EKC$calculated from ce(K)(2010.37|g+2011.38|g)=0.026 {I5} (1969AdZW),
146SM2cG and |a(K)(2010.37|g, E1)=0.000267 {I4}
146SM G 2644.43 5 0.108 3E1 1.20E-3 C
146SM2 G CEK=0.0057 21 (1976Ad08)$ EKC=0.00021 8$
146SMS G KC=0.0001750 25$LC=2.19E-5 3$MC=4.63E-6 7
146SMS G NC=1.049E-6 15$OC=1.580E-7 23$PC=1.019E-8 15$IPC=0.000996 14
146SM L 3397.60 8 (4+)
146SM E 0.07 LT 8.9 GT 0.07 LT
146SMS E CK=0.8221 4$CL=0.1375 3$CM+=0.04042 9
146SM G 1175.09 110.111 19 C
146SM G 2017.40 130.0233 17 C
146SM G 2650.35 170.0078 6 &
146SM L 3418.95 4 3+
146SM E 0.263 9 8.309 20 0.263 9
146SMS E CK=0.8208 4$CL=0.1384 3$CM+=0.04075 10
146SM G 1137.8 30.043 3 H
146SM G 1335.52 9 0.134 6 AC
146SM G 1373.6 20
146SMF G FLAG=C
146SM G 2037.86 70.0728 24 C
146SM2 G CEK=0.023 8 (1969AdZW)$ EKC=0.0013 5
146SM cG ECC$no explanation for the large value of the |a(K)exp
146SM G 2671.65 5 0.0397 11M1+E2 0.001057 C
146SM2 G CEK=0.06 (1965Ad06)$ EKC=0.0006$
146SMS G KC=0.000348 20$LC=4.5E-5 3$MC=9.5E-6 6
146SMS G NC=2.16E-6 14$OC=3.25E-7 21$PC=2.09E-8 15$IPC=0.00064 4
146SM cG MR$-0.21 {I+8-9} or -2.1 {I+4-5}, |a's are for the 1{+st} value
146SM L 3427.76 8
146SM E 0.0175 7 9.468 22 0.0175 7
146SMS E CK=0.8203 4$CL=0.1388 3$CM+=0.04090 11
146SM G 2680.57 70.0178 6 C
146SM L 3431.26 4 3-,4- A
146SM E 0.30 7 8.23 11 0.30 7
146SMS E CK=0.8200 5$CL=0.1390 3$CM+=0.04096 11
146SM G 1347.79 6 0.0433 19 BC
146SM G 1385.60 6 0.12 7 C
146SMF G FLAG=Bv
146SM G 2049.96 8 0.028 4 BC
146SM G 2050.97 8 0.116 15 BC
146SM L 3461.557 21 5-
146SM E 3.0 4 7.16 6 3.0 4
146SMS E CK=0.8178 5$CL=0.1407 4$CM+=0.04152 13
146SM G 948.14 150.0082 13 B
146SM G 1378.135 190.542 12M1+E2 -0.12 8 0.00189 C
146SM2 G CEK=0.28 3 (1969AdZW)$ EKC=0.0021 2$
146SMS G KC=0.00159 3$LC=0.000209 4$MC=4.45E-5 7
146SMS G NC=1.010E-5 16$OC=1.524E-6 24$PC=9.76E-8 16$IPC=4.11E-5 6
146SM cG MR$the 2{+nd} value is +0.97 {I15}, |a's are for the 1{+st} value
146SM G 1415.859 210.219 5M1+E2 +0.45 +7-5 0.001714 C
146SM2 G CEK=0.10 5$ EKC=0.0018 9$
146SMS G KC=0.00142 3$LC=0.000188 4$MC=4.00E-5 8
146SMS G NC=9.07E-6 18$OC=1.37E-6 3$PC=8.72E-8 18$IPC=5.20E-5 8
146SM cG MR$the 2{+nd} value is +3.6 {I+8-6}, at that |a(K)=0.001084 {I22}
146SM G 1649.76 100.135 17 C
146SM G 2080.02 150.66 26[E1] 9.29E-4 C
146SMS G KC=0.000253 4$LC=3.18E-5 5$MC=6.74E-6 10
146SMS G NC=1.527E-6 22$OC=2.30E-7 4$PC=1.474E-8 21$IPC=0.000636 9
146SM cG M$from reanalyzed data of 1984Kr02 by 1992Ad04
146SM G 2081.11 151.51 26E2 9.25E-4 C
146SM2 G CEK=0.180 24$ EKC=0.00047 10$
146SMS G KC=0.000513 8$LC=6.67E-5 10$MC=1.419E-5 20
146SMS G NC=3.21E-6 5$OC=4.83E-7 7$PC=3.06E-8 5$IPC=0.000328 5
146SM cG EKC$calculated from ce(K)(2080.02|g+2081.11|g)=0.222 {I17} (1976Ad08),
146SM2cG and |a(K)(2080.02|g, E1)=0.000253 {I4}
146SM L 3465.82 4 A
146SM E 0.165 6 8.409 22 0.165 6
146SMS E CK=0.8175 5$CL=0.1409 4$CM+=0.04161 13
146SM G 1184.93 3 0.133 3
146SMF G FLAG=Bv
146SM L 3471.90 5 (2+),3+
146SM E 0.052 5 8.90 5 0.052 5
146SMS E CK=0.8170 6$CL=0.1413 4$CM+=0.04174 14
146SM G 1191.01 100.013 4 AC
146SM G 1823.90 100.0087 19 AC
146SM G 2724.70 6 0.0308 10M1 1.12E-3 C
146SM2 G CEK=0.0028 8 (1976Ad08)$ EKC=0.00036 10
146SMS G KC=0.000352 5$LC=4.55E-5 7$MC=9.67E-6 14
146SMS G NC=2.19E-6 3$OC=3.31E-7 5$PC=2.14E-8 3$IPC=0.000709 10
146SM L 3475.11 6 5+,(6+) A
146SM E 0.145 11 8.44 4 0.145 11
146SMS E CK=0.8167 6$CL=0.1415 4$CM+=0.04181 14
146SM G 624.75 140.082 10 B
146SM G 1663.42 6 0.0657 20M1+(E2) 0.0012016 BC
146SM2 G CEK=0.033 (1965Ad06)$ EKC=0.0020$
146SMS G KC=0.00091 14$LC=0.000119 17$MC=2.5E-5 4
146SMS G NC=5.8E-6 9$OC=8.7E-7 13$PC=5.5E-8 9$IPC=0.000144 8
146SM L 3476.95 15 (2+,3,4,5-) A
146SM E 0.045 5 8.95 5 0.045 5
146SMS E CK=0.8165 6$CL=0.1416 4$CM+=0.04185 14
146SM G 2095.64 200.023 3 C
146SM2 G FLAG=B
146SM G 2096.64 200.023 3 C
146SM2 G FLAG=B
146SM L 3509.34 6 (3+)
146SM E 0.102 6 8.51 3 0.102 6
146SMS E CK=0.8135 7$CL=0.1439 5$CM+=0.04264 17
146SM G 441.43 120.027 3
146SM G 721.24 80.054 4
146SM G 1239.86 200.0082 19
146SM G 2762.04 8 0.0146 6(M1+E2) 0.001077 C
146SM2 G CEK=0.0010 3 (1976Ad08)$ EKC=0.00027 8
146SMS G KC=0.000326 17$LC=4.19E-5 24$MC=8.9E-6 5
146SMS G NC=2.02E-6 12$OC=3.05E-7 18$PC=1.96E-8 13$IPC=0.00069 5
146SM L 3517.37 33+
146SM E 0.36 4 7.94 6 0.36 4
146SMS E CK=0.8126 7$CL=0.1445 5$CM+=0.04286 18
146SM G 380.91 7 0.10 4 AC
146SM G 1004.3 40.010 3
146SM G 1078.29 7 0.0380 13 AC
146SM G 1471.64 90.069 3 C
146SM G 1869.86 250.0073 16 C
146SM G 2137.08 4 0.120 3E1+(M2) 9.64E-416 C
146SM2 G CEK=0.0130 26 (1969AdZW)$ EKC=0.00043 9$
146SMS G KC=0.000253 11$LC=3.19E-5 15$MC=6.8E-6 4
146SMS G NC=1.53E-6 7$OC=2.30E-7 11$PC=1.48E-8 7$IPC=0.000670 11
146SM cG M,MR $from reanalyzed data of 1984Kr02 by 1992Ad04; -0.18|<|d|<+2.0 in
146SM2cG this case 0.000259 {I17}|<|a(K)|<0.0007 {I5}
146SM G 2770.12 8 0.0192 7M1+E2 0.001077 C
146SM2 G CEK=0.0018 5 (1976Ad08)$ EKC=0.00037 10$
146SMS G KC=0.000324 17$LC=4.17E-5 23$MC=8.9E-6 5
146SMS G NC=2.01E-6 12$OC=3.03E-7 18$PC=1.95E-8 12$IPC=0.00069 5
146SM L 3530.58 5 4+
146SM E 0.38 3 7.88 4 0.38 3
146SMS E CK=0.8111 8$CL=0.1457 6$CM+=0.04325 19
146SM G 845.81 100.037 8 C
146SMF G FLAG=Av
146SM G 852.28 120.039 9 C
146SM2 G CEK AP 0.015$ EKC AP 0.0015 (1965Ba43)$
146SMF G FLAG=Bv
146SM G 881.5 2 0.036 2 H
146SM G 998.7 30.0046 13 F
146SM G 1017.08 160.0175 21 C
146SM G 1260.89 90.0239 18
146SM G 1447.12 9 0.093 18 A
146SM G 1484.72 8 0.082 4E1 7.07E-4 C
146SM2 G CEK=0.08 2 (1976Ad08)$ EKC=0.00039 10$
146SMS G KC=0.000439 7$LC=5.57E-5 8$MC=1.181E-5 17
146SMS G NC=2.67E-6 4$OC=4.02E-7 6$PC=2.55E-8 4$IPC=0.000197 3
146SM G 2149.2 30.030 10 C
146SM L 3546.17 42+,3+
146SM E 0.104 5 8.40 3 0.104 5
146SMS E CK=0.8091 9$CL=0.1471 6$CM+=0.04376 22
146SM G 1898.17 8 0.015 4 BC
146SM cG $for the triplet of 1896.85, 1897.85 and 1898.17 transitions
146SM2cG ce(K)=0.0078 {I26} (1969AdZW)
146SM G 2164.86 50.0552 16 C
146SM G 2798.97 6 0.0357 11M1+E2 0.001077 C
146SM2 G CEK=0.0026 8 (1976Ad08)$ EKC=0.00029 7$
146SMS G KC=0.000318 16$LC=4.08E-5 22$MC=8.7E-6 5
146SMS G NC=1.97E-6 11$OC=2.97E-7 17$PC=1.91E-8 12$IPC=0.00071 5
146SM L 3583.924 24 4-
146SM E 0.379 12 7.717 25 0.379 12
146SMS E CK=0.8033 11$CL=0.1515 9$CM+=0.0453 3
146SM G 399.81 100.014 4 AC
146SM G 569.11 100.020 6 AC
146SM G 783.96 30.048 2 FC
146SMF G FL=2799.93
146SM G 1500.44 3 0.128 4M1+E2 0.0013922
146SM2 G CEK=0.06 3 (1976Ad08)$ EKC=0.0019 10$
146SMS G KC=0.00113 19$LC=0.000149 24$MC=3.2E-5 5
146SMS G NC=7.2E-6 12$OC=1.08E-6 18$PC=6.8E-8 13$IPC=7.9E-5 4
146SM G 2203.73 3 0.174 4M1+E2 0.001008 C
146SMF G FL=1380.289
146SMF G FLAG=a$
146SM2 G CEK=0.024 3 (1969AdZW)$ EKC=0.00055 7$
146SMS G KC=0.00051 5$LC=6.6E-5 7$MC=1.41E-5 14
146SMS G NC=3.2E-6 3$OC=4.8E-7 5$PC=3.1E-8 4$IPC=0.000409 24
146SM cG MR$+1.4 {I+4-3} or -0.04 {I+11-10} for J=3-, and +4.6 {I+19-12} or
146SM2cG +0.43 {I+8-9} for J=4-
146SM cG E$poor fit; the level energy difference equals 2203.53 {I3}.
146SM L 3591.72 6 (4+)
146SM E 0.213 8 7.94 3 0.213 8
146SMS E CK=0.8018 12$CL=0.1525 9$CM+=0.0456 3
146SM G 534.1 20.084 5 H
146SM G 1190.1 30.0641 21 F
146SM G 1944.3 30.0081 19 C
146SM G 2210.35 60.0599 22 C
146SM G 2845.0 30.0010 3
146SM L 3605.83 7 3-
146SM E 0.075 6 8.34 5 0.075 6
146SMS E CK=0.7990 14$CL=0.1547 10$CM+=0.0464 4
146SM G 422.3 30.013 4 H
146SMF G FL=3183.924
146SM G 1166.67 100.017 3
146SM G 1336.01 90.044 3 C
146SM G 2858.2 30.0020 5 C
146SM L 3626.038 174+
146SM E 1.25 4 7.04 3 1.25 4
146SMS E CK=0.7942 16$CL=0.1582 12$CM+=0.0476 5
146SM G 532.87 7 0.133 8E2 0.01085
146SM2 G CEK=0.30 2 (1969AdZW)$ EKC=0.0090 8$
146SMS G KC=0.00894 13$LC=0.001493 21$MC=0.000326 5
146SMS G NC=7.31E-5 11$OC=1.051E-5 15$PC=5.17E-7 8
146SM G 611.46 250.015 4
146SM G 826.32 120.0138 20E2,M1 0.0050 13 C
146SM2 G CEK=0.02 1$ EKC=0.006 3 (1976Ad08)$
146SMS G KC=0.0042 11$LC=0.00059 13$MC=0.00013 3
146SMS G NC=2.9E-5 6$OC=4.3E-6 10$PC=2.6E-7 8
146SM G 941.30 30.161 5 C
146SM G 1094.10 4 0.059 22 AC
146SM G 1186.98 100.0315 18 C
146SM G 1225.39 110.0136 14 C
146SM G 1345.176 220.157 4(M1+E2) 0.0017 3 C
146SMS G KC=0.0014 3$LC=0.00019 4$MC=4.0E-5 7
146SMS G NC=9.2E-6 16$OC=1.38E-6 25$PC=8.6E-8 18$IPC=3.11E-5 12
146SM cG M$D+Q from |g(|q). M1+E2 from decay scheme
146SM cG MR$-0.16|<|d|<1.3
146SM G 1356.145 170.321 7M1+(E2) 0.05 +7-8 0.00196 C
146SM2 G CEK=0.17 6 (1976Ad08)$ EKC=0.0013 5$
146SMS G KC=0.001652 24$LC=0.000218 4$MC=4.64E-5 7
146SMS G NC=1.053E-5 16$OC=1.587E-6 23$PC=1.017E-7 15$IPC=3.51E-5 5
146SM cG MR$the 2{+nd} value is -6.9 {I+24-79}, at that |a(K)=0.001154 {I17}
146SM G 1470.21 4 0.020 6 AC
146SM G 1542.56 30.106 3 C
146SM G 1580.16 180.0128 17 C
146SM G 1978.20 60.0512 18 C
146SM G 2244.71 4 0.161 4M1+E2 0.001008 C
146SM2 G CEK=0.038 4 (1976Ad08)$ EKC=0.00084 11$
146SMS G KC=0.00049 5$LC=6.4E-5 6$MC=1.35E-5 13
146SMS G NC=3.1E-6 3$OC=4.6E-7 5$PC=3.0E-8 3$IPC=0.000430 25
146SM cG M,MR$from reanalyzed data of 1984Kr02 by 1992Ad04; -28|<|d|<-1.1
146SM G 2878.76 100.0065 5
146SM L 3646.99 4 (2+,3,4+) A
146SM E 0.051 9 8.34 9 0.051 9
146SMS E CK=0.7881 20$CL=0.1627 15$CM+=0.0492 6
146SM G 553.8 100.026 8 AC
146SM G 1491.16 3 0.026 3 BC
146SM L 3652.21 54+
146SM E 0.123 8 7.94 4 0.123 8
146SMS E CK=0.7864 22$CL=0.1640 16$CM+=0.0496 6
146SM G 1371.33 100.008 3 AC
146SM G 1496.39 100.010 3 C
146SMF G FLAG=Bv
146SM G 1568.93 100.038 5 C
146SM G 2004.25 110.0297 24 C
146SM G 2904.87 9 0.0393 24E2 1.04E-3 C
146SM2 G CEK=0.0041 8 (1976Ad08)$ EKC=0.00042 9$
146SMS G KC=0.000284 4$LC=3.63E-5 5$MC=7.70E-6 11
146SMS G NC=1.745E-6 25$OC=2.63E-7 4$PC=1.687E-8 24$IPC=0.000711 10
146SM L 3654.18 7 (2+,3,4+) A
146SM E 0.064 7 8.21 6 0.064 7
146SMS E CK=0.7857 22$CL=0.1645 17$CM+=0.0498 6
146SM G 415.52 160.0059 20 AC
146SM G 1110.03 160.022 3 BC
146SM G 1373.29 150.014 5 AC
146SM G 1498.35 140.0080 23 C
146SMF G FLAG=Bv
146SM G 2906.99 130.0154 22 C
146SMF G FLAG=Bv
146SM L 3693.43 9 (2+,3,4+)
146SM E 0.0205 18 8.50 6 0.0205 18
146SMS E CK=0.768 4$CL=0.178 3$CM+=0.0544 10
146SM G 1161.75 140.0126 15
146SM G 2946.10 10 0.0082 9
146SM L 3715.61 18
146SM E 0.0028621 9.21 6 0.00286 21
146SMS E CK=0.753 6$CL=0.189 4$CM+=0.0584 14
146SM G 2968.41 180.0029 2 C
146SM L 3720.53 13 3-
146SM E 0.032 8 8.13 12 0.032 8
146SMS E CK=0.748 6$CL=0.192 5$CM+=0.0595 15
146SM G 653.0 30.024 8 F
146SM G 2072.50 150.0076 9
146SM G 2973.3 4 0.0008 2
146SM L 3740.77 7(3,4+)
146SM E 0.061 3 7.69 6 0.061 3
146SMS E CK=0.726 9$CL=0.208 7$CM+=0.0654 23
146SM G 1208.82 80.0297 19 C
146SM G 2360.49 140.0299 18 C
146SM G 2993.61 240.0020 2 C
146SM L 3749.4211 (3-,4+)
146SM E 0.028 6 7.95 11 0.028 6
146SMS E CK=0.713 11$CL=0.218 8$CM+=0.069 3
146SM G 1667.0 70.014 6 C
146SM G 2368.93 220.0078 9
146SM G 3002.24 120.0062 3
146SM L 3770.33 11 2+ A
146SM E 0.180 24 6.91 10 0.180 24
146SMS E CK=0.669 19$CL=0.251 14$CM+=0.081 5
146SM G 372.67 230.071 23 AC
146SM G 749.8 150.050 5 AC
146SM G 838.02 150.0049 10 C
146SMF G FLAG=Bv
146SM G 2389.00 170.057 1 C
146SM2 G FLAG=Bv
146SM L 3786.03 15(2+,3,4+)
146SM E 0.071 3 7.10 10 0.071 3
146SMS E CK=0.61 4$CL=0.293 24$CM+=0.096 9
146SM G 1385.6 3 0.059 2 H
146SM G 2404.74 220.0126 11 C
146SM G 3038.50 230.0009 1
146SM L 3790.06 8 3-,4- A
146SM E 0.025 5 7.49 14 0.025 5
146SMS E CK=0.59 4$CL=0.31 3$CM+=0.102 11
146SM G 606.22 220.017 4 BC
146SM G 1565.02 200.012 LE C
146SMF G FLAG=Bv
146SM G 3042.85 8 0.0026 5 AC
146SM L 3804.25 9 (3-,4,5+) A
146SM E 0.23 6 6.26 18 0.23 6
146SMS E CK=0.48 8$CL=0.39 6$CM+=0.132 21
146SM G 544.32 130.14 6 AC
146SM G 736.55 110.080 8 BC
146SM G 1063.6 7 0.009 3 BC
146SM G 1198.3 100.008 7 BC