ADOPTED LEVELS, GAMMAS for 112Cd

Authors: S. Lalkovski, F.G. Kondev |  Citation: Nucl. Data Sheets 124, 157 (2015) |  Cutoff date: 1-Aug-2014 

 Full ENSDF file | Adopted Levels (PDF version) 


Q(β-)=-2585 keV 4S(n)= 9394.0 keV 5S(p)= 9648.5 keV 14Q(α)= -3476.4 keV 12
Reference: 2012Wa38

References:
  A  112Ag β- decay (3.130 H)  B  112In ε decay (14.88 M)
  C  Coulomb Excitation  D  110Pd(α,2nγ)
  E  112Cd(n,n’γ)  F  112Cd(p,p’γ)
  G  111Cd(n,γ) E=TH:PRIMARY  H  111Cd(n,γ) E=TH:SECONDARY
  I  112Cd(γ,pol γ’)  J  112Cd(γ,γ’)
  K  111Cd(d,pγ)  L  112Cd(pol d,d’)
  M  112Cd(d,d’)  N  112Cd(π-,X)
  O  112Cd(E,E’)  P  110Pd(3He,n)
  Q  110Cd(t,p)  R  113Cd(pol d,t)
  S  112Cd(α,α’)  T  111Cd(d,p)
  U  112Cd(pol p,p’)  V  112Cd(p,p’)
  W  114Cd(p,t) 








E(level)
(keV)
XREFJπ(level) T1/2(level)E(γ)
(keV)
I(γ)M(γ)Final Levels
     0.0ABCDEFGHIJKLMNOPQRSTUVW 0+ STABLE      
   617.518 3 ABCDEFGHIJKLMNO QRSTUVW 2+ 6.46 ps 4     617.517 3 
  100
E2
     0.0
0+
  1224.341 7 ABCDEFGH JKLM  PQ  TUV  0+ 4.2 ps 11     606.821 6 
  1224.341 7 
  100
 
E2
E0
   617.518
     0.0
2+
0+
  1312.390 8 ABCDEFGH JKLM   QRS UVW 2+ 1.9 ps 3     694.872 7 
  1312.36 4 
  100 3 
   37.7 4 
E2+M1
E2
   617.518
     0.0
2+
0+
  1415.480 25 A CDEF H  KLM   QRS UV  4+ 0.87 ps 10     798.04 10 
  100
E2
   617.518
2+
  1433.27 3 AB DEFGH JKL    Q  T V  0+ 1.9 ns 1     120.68 10 
   208.93 3 
   815.79 3 
  1433.27 3 
   58 7 
 
  100 10 
 
E2
E0
E2
E0
  1312.390
  1224.341
   617.518
     0.0
2+
0+
2+
0+
  1468.822 14 ABCDEFGH JKLM   QRST VW 2+ 2.7 ps 5     244.86 23 
   851.285 15 
  1468.84 10 
    1.0 3 
  100.0 10 
   58.3 8 
(E2)
M1+E2+E0
E2
  1224.341
   617.518
     0.0
0+
2+
0+
  1870.68 4 A  DEF                  4+      401.88 13 
   455.26 13 
   558.39 11 
  1253.16 12 
   58 3 
   32.0 17 
  100.0 25 
   89 3 
E2
M1+E2
E2
E2
  1468.822
  1415.480
  1312.390
   617.518
2+
4+
2+
2+
  1870.96 5 AB DEFGH J LM   QR T V  0+      402.50 16 
   558.7
  1253.56 12 
   11.2 12 
    3.5 9 
  100.0 12 
E2
E2
E2
  1468.822
  1312.390
   617.518
2+
2+
2+
  2005.200 21 A CDEF H J LM   QRSTUV  3- 0.26 ps 5     536.31 10 
   692.82 3 
  1387.68 10 
    1.11 12 
   22.2 6 
  100.0 6 
E1
E1
E1
  1468.822
  1312.390
   617.518
2+
2+
2+
  2064.53 3 A  DEFGH   L     R      3+ 0.47 ps 13     648.91 10 
   752.14 3 
  1447.00 10 
   28.3 7 
  100.0 13 
   87.7 13 
M1+E2
M1+E2
M1+E2
  1415.480
  1312.390
   617.518
4+
2+
2+
  2081.64 4    DEF H J L    QR T V  4+ 0.35 ps 10     211.0 3 
   612.88 25 
   666.17 6 
   769.36 10 
  1464.04 10 
    4.9 7 
   23 4 
  100.0 22 
   70.4 18 
   27.7 9 
[M1]
E2
M1+E2
E2
E2
  1870.68
  1468.822
  1415.480
  1312.390
   617.518
4+
2+
4+
2+
2+
E(level)
(keV)
XREFJπ(level) T1/2(level)E(γ)
(keV)
I(γ)M(γ)Final Levels
  2121.62 4  B DE GH J LM   QR T V  2+ 0.51 ps 14     688.23 10 
   808.82 19 
   897.07 10 
  1504.04 10 
  2121.49 13 
   14.9 9 
    3.73 12 
   11.9 3 
  100.0 9 
    2.80 13 
E2
M1+E2
E2
M1+E2
E2
  1433.27
  1312.390
  1224.341
   617.518
     0.0
0+
2+
0+
2+
0+
  2156.18 5 AB DE GH J LM   QR T V  2+ 0.2 ps 2     687.41 10 
   842.8 15 
  1538.68 10 
  2156.20 10 
    5.6 8 
    2.5 7 
  100
    8.8 3 
M1+E2
[M1]
M1+E2
E2
  1468.822
  1312.390
   617.518
     0.0
2+
2+
2+
0+
  2167.76 5    DE      L            6+      297.29 12 
   752.14 10 
    0.58 9 
  100 3 
E2
E2
  1870.68
  1415.480
4+
4+
  2231.12 5 A  DE GH J LM   QR T V  2+ 0.15 ps 14     226.0 3 
   762.41 10 
   918.72 10 
  1006.81 10 
  1613.66 10 
    0.61 15 
    2.07 11 
    2.72 11 
    4.03 11 
  100.0 2 
[E1]
M1+E2
M1+E2
E2
M1+E2
  2005.200
  1468.822
  1312.390
  1224.341
   617.518
3-
2+
2+
0+
2+
  2300.68 7  B  E GH J LM   QR T V  0+ > 623 fs    831.79 10 
  1683.22 10 
   48.4 12 
  100.0 12 
E2
E2
  1468.822
   617.518
2+
2+
  2373.19 5    DE      LM   QR TUV  5- 0.4 ps +6-2     291.5 1 
   367.9 1 
   957.72 10 
    1.08 11 
    0.98 20 
  100
E1
E2
E1
  2081.64
  2005.200
  1415.480
4+
3-
4+
  2402.98 5    DE GH         R      3+ 0.24 ps +10-6     531.89 10 
   934.19 10 
   987.89 10 
  1090.56 10 
  1785.48 10 
   10.4 12 
   61.2 12 
  100
   57.7 12 
   66.6 15 
M1+E2
M1+E2
M1(+E2)
M1+E2
M1+E2
  1870.68
  1468.822
  1415.480
  1312.390
   617.518
4+
2+
4+
2+
2+
  2416.00 5 A  DE  H   LM    R   V  3- 0.15 ps 3     411.39 23 
   946.92 10 
   983.8 3 
  1103.58 10 
  1798.50 10 
   12.9 14 
    9.5 12 
    5.7 3 
   47.0 14 
  100.0 17 
M1+E2
E1

E1
E1
  2005.200
  1468.822
  1433.27
  1312.390
   617.518
3-
2+
0+
2+
2+
E(level)
(keV)
XREFJπ(level) T1/2(level)E(γ)
(keV)
I(γ)M(γ)Final Levels
  2418.0 10         I         ST    (1,2+) 1.29 ps 3    2418 1 
  100

     0.0
0+
  2454.51 8    DE      LM   QR   V  4+ 0.35 ps +9-6    1038.93 10 
  1142.21 10 
  100.0 3 
    8.7 3 
M1+E2
E2
  1415.480
  1312.390
4+
2+
  2493.15 6    DE  H   LM   QR   V  4+ 0.4 ps +4-1    1024.29 10 
  1077.60 10 
  1875.70 10 
   13.7 5 
  100.0 6 
    5.6 5 
E2
M1+E2
E2
  1468.822
  1415.480
   617.518
2+
4+
2+
  2506.36 7 A  DE  H J L    QR T    (2)+ 0.21 ps 3    1194.00 10 
  1888.79 10 
   17.9 5 
  100.0 5 
M1+E2
M1+E2
  1312.390
   617.518
2+
2+
  2506.70 6 A   E GHIJ  M       UV  1- 36.6 fs 19    1037.9 3 
  1073.32 17 
  1282.29 10 
  2506.70 10 
    6.8 7 
    4.8 5 
    5.5 5 
  100.0 6 
E1
E1
E1
E1
  1468.822
  1433.27
  1224.341
     0.0
2+
0+
0+
0+
  2532.20 12    D  GH   L     R      2+     1063.56 22 
  1099.0 3 
  1116.83 20 
   76 12 
   45 12 
  100 15 



  1468.822
  1433.27
  1415.480
2+
0+
4+
  2561.27 16       GH                (1,2+)     1248.92 24 
  2561.13 22 
   61 11 
  100 11 


  1312.390
     0.0
2+
0+
  2570.21 6    DE            R      5- > 693 fs    197.03 10 
   565.10 20 
   699.59 10 
  1154.75 10 
   95 9 
   31 3 
   71 4 
  100
M1
E2
E1
E1
  2373.19
  2005.200
  1870.68
  1415.480
5-
3-
4+
4+
  2571.47 6    DE      LM   Q  T V  6+ > 693 fs    403.55 10 
   700.89 10 
  1156.21 10 
    5.9 7 
  100 3 
   89 5 
M1+E2
E2
E2
  2167.76
  1870.68
  1415.480
6+
4+
4+
  2591.05 5    DE  H   LM    R   V  4- > 693 fs    526.52 10 
   585.78 10 
   720.44 10 
  1175.50 10 
   48.0 11 
   23.0 7 
   11.7 7 
  100.0 11 
E1
M1+E2
E1
E1
  2064.53
  2005.200
  1870.68
  1415.480
3+
3-
4+
4+
  2632 5             M        V  (5)-        
  2634.99 5    DE  H   L     R T    3+      570.5 1 
   629.80 10 
  1219.4 1 
  1322.59 10 
  2017.5 1 
   10.15 16 
   38.1 8 
 
  100.0 5 
    8.67 16 
M1+E2
E1
M1+E2
M1+E2
M1+E2
  2064.53
  2005.200
  1415.480
  1312.390
   617.518
3+
3-
4+
2+
2+
E(level)
(keV)
XREFJπ(level) T1/2(level)E(γ)
(keV)
I(γ)M(γ)Final Levels
  2650.15 8     E      L   P R      0+ 0.23 ps +12-6    1337.75 11 
  2032.62 10 
   14.2 17 
  100
E2
E2
  1312.390
   617.518
2+
2+
  2657 1            LM      T V  1-        
  2665.64 6    DE      L            5+ > 208 fs    583.92 10 
   601.01 10 
   795.08 13 
  1250.17 10 
  100
   60 4 
   40 3 
   65.6 24 
M1+E2
E2
M1(+E2)
M1+E2
  2081.64
  2064.53
  1870.68
  1415.480
4+
3+
4+
4+
  2668.92 6 A  DE GH    M   Q    V  (2)- 0.21 ps 3     663.59 15 
  1356.52 10 
  2051.50 10 
    6.47 25 
  100
   17.9 8 
M1+E2
E1
E1
  2005.200
  1312.390
   617.518
3-
2+
2+
  2674.00 10 A  DE GH   L     R T    2+ 35 fs 3    2056.48 10 
  100
M1(+E2)
   617.518
2+
  2694.0 10         I               (1) 0.72 ps 14    2694 1 
  100
M1
     0.0
0+
  2711.19 8    DE      LM    R   V  4+ 0.26 ps +15-7     705.95 10 
  1295.74 10 
    6.3 9 
  100
E1
M1+E2
  2005.200
  1415.480
3-
4+
  2723.96 7 A  DE  H J LM   QR T V  2+ 159 fs 24     718.89 10 
  1411.8 8 
  2106.31 10 
  2723.6 3 
    7.0 7 
    1.4 4 
  100.0 6 
    4.1 4 
E1
[M1+E2]
M1(+E2)
[E2]
  2005.200
  1312.390
   617.518
     0.0
3-
2+
2+
0+
  2765.72 5 A   E GH   LM   QR T V  2+ 34 fs 3     894.5 1 
  1296.9 1 
  1453.4 1 
  2148.21 10 
  2765.7 3 
    7.2 10 
   16 4 
    8.9 5 
  100 4 
    5.85 24 
E2
M1+E2
M1+E2
M1(+E2)
E2
  1870.96
  1468.822
  1312.390
   617.518
     0.0
0+
2+
2+
2+
0+
  2773.08 8     E      L            (0)+ > 693 fs    541.80 10 
  1460.83 10 
   19.2 10 
  100.0 10 
E2
E2
  2231.12
  1312.390
2+
2+
  2791.79 11     E      LM        V  (4)- > 97 fs    786.59 10 
  100
M1+E2
  2005.200
3-
  2793.80 6    DE                   7-      222.17 10 
   420.68 19 
   625.97 10 
    3.2 4 
   63 4 
  100 4 
(E1)
E2
E1
  2571.47
  2373.19
  2167.76
6+
5-
6+
  2816.71 7     E      LM    R   V  4+ > 416 fs    735.20 10 
   811.3 1 
  1401.3 1 
 
 
 
M1+E2
E1
M1+E2
  2081.64
  2005.200
  1415.480
4+
3-
4+
E(level)
(keV)
XREFJπ(level) T1/2(level)E(γ)
(keV)
I(γ)M(γ)Final Levels
  2817.74 9    DE      L     RST    6-      247.54 10 
   444.54 10 
   10.6 9 
  100.0 28 
M1(+E2)
M1+E2
  2570.21
  2373.19
5-
5-
  2829.19 6 A   E GHI               1- 27 fs 3     957.80 19 
  1604.6 4 
  2211.65 10 
  2829.20 10 
    8.0 10 
    5.0 14 
  100.0 21 
   78.6 21 
E1
[E1]
E1
E1
  1870.96
  1224.341
   617.518
     0.0
0+
0+
2+
0+
  2834.27 7     E GH J L    QR      0+ > 347 fs    712.68 10 
  1521.82 12 
  2216.74 10 
   19 4 
   26.2 19 
  100
E2
E2
E2
  2121.62
  1312.390
   617.518
2+
2+
2+
  2840.22 11    DE      LM      T V  (4)+ > 485 fs   1424.73 10 
  100
M1+E2
  1415.480
4+
  2852.90 5     E  H J L     R      2+ 0.44 ps +21-10     850 2 
  1419.6 1 
  1540.4 1 
  2235.46 10 
  2852.87 10 
 
   12.2 4 
   52.8 22 
   34.8 8 
  100 3 

E2
M1+E2
M1+E2
E2
  2005.200
  1433.27
  1312.390
   617.518
     0.0
3-
0+
2+
2+
0+
  2866.75 6 A  DE  H   LM   Q    V  3- 0.6 ps +8-2     450.75 10 
   784.91 10 
   802.3 4 
   861.68 10 
  1451.30 10 
   16.5 7 
   18.3 15 
   14 4 
  100.0 11 
   64.7 13 
M1+E2
E1
[E1]
M1(+E2)
E1
  2416.00
  2081.64
  2064.53
  2005.200
  1415.480
3-
4+
3+
3-
4+
  2867.48 6 A   E      L     R T    (3)+ 0.09 ps +8-3    1398.64 10 
  1555.1 1 
  2249.91 10 
 
 
  100
M1+E2
M1+E2
M1+E2
  1468.822
  1312.390
   617.518
2+
2+
2+
  2881.02 8    D                    8+      713.23 10 
  100
E2
  2167.76
6+
  2882.82 8     E      L     R      0+ > 693 fs    726.79 14 
  1413.86 10 
  1570.51 14 
   36 5 
  100 5 
   28.5 25 
E2
E2
E2
  2156.18
  1468.822
  1312.390
2+
2+
2+
  2893.51 6     E      LM    R   V  4+ > 416 fs    771.76 10 
   811.9 1 
  2276.07 10 
   37 4 
 
  100 4 
E2
M1+E2
E2
  2121.62
  2081.64
   617.518
2+
4+
2+
E(level)
(keV)
XREFJπ(level) T1/2(level)E(γ)
(keV)
I(γ)M(γ)Final Levels
  2899.02 5    DE      L            (3-,5-) 0.13 ps 3    1483.53 4 
  100
(E1)
  1415.480
4+
  2921.53 9    DE      L       T    6+      840.00 10 
  1505.5 3 
  100 8 
   40 5 
E2
E2
  2081.64
  1415.480
4+
4+
  2924 29                  R      0+        
  2924.83 5     E      L            4- > 139 fs    333.72 10 
   551.63 10 
   919.58 10 
  1054.24 10 
  1509.36 10 
   60 3 
   28 3 
  100 3 
   62 3 
   75.9 23 
M1+E2
M1+E2
M1+E2
E1
E1
  2591.05
  2373.19
  2005.200
  1870.68
  1415.480
4-
5-
3-
4+
4+
  2928 5            LM        V  (5)-        
  2931.46 6     E GHI        R      1+ 17 fs 4    1618.84 11 
  2314.12 10 
  2931.42 10 
   47.5 20 
   53 3 
  100 3 
M1+E2
M1+E2
M1
  1312.390
   617.518
     0.0
2+
2+
0+
  2931.97 8    DE      L            6-      361.80 20 
   558.7 1 
 
  100
M1+E2
M1+E2
  2570.21
  2373.19
5-
5-
  2935.50 6    D                    7-      141.69 11 
   365.38 10 
   562.39 10 
   767.65 10 
    5.6 14 
    3.9 16 
  100 3 
   61 3 
M1+E2
E2
(E2)
E1
  2793.80
  2570.21
  2373.19
  2167.76
7-
5-
5-
6+
  2944.94 7     E GH   LM      T V  2+ 0.4 ps +3-1    2327.44 10 
  2944.78 10 
  100 4 
   73 4 
M1+E2
E2
   617.518
     0.0
2+
0+
  2947.76 10     E      L     R      (2,3)+ 83 fs 24    2330.22 10 
  100
M1+E2
   617.518
2+
  2961.92 6     E            R      4-      370.86 10 
   588.83 10 
   956.7 1 
  1546.35 10 
   37.1 22 
   60.2 24 
 
  100 3 
M1(+E2)
M1+E2
M1+E2
E1
  2591.05
  2373.19
  2005.200
  1415.480
4-
5-
3-
4+
  2962.0 7 A          LM      T V  2+      957.1 10 
  2961.7 10 
   50 25 
  100 25 


  2005.200
     0.0
3-
0+
  2970.02 10    DE                   (4,5)+      398.57 10 
  1554.49 16 
   75 5 
  100 11 

M1+E2
  2571.47
  1415.480
6+
4+
E(level)
(keV)
XREFJπ(level) T1/2(level)E(γ)
(keV)
I(γ)M(γ)Final Levels
  2972.45 7    DE                   5+ 0.6 ps +11-2     804.89 10 
   890.77 10 
  1556.8 1 
   32.3 17 
   25 3 
  100 3 
M1+E2
M1+E2
M1+E2
  2167.76
  2081.64
  1415.480
6+
4+
4+
  2980.85 9     E      L    QR T    2+ 0.14 ps 3    1512.13 17 
  1668.4
  2363.27 10 
   15 3 
    9.6 23 
  100 4 
M1+E2
M1+E2
M1(+E2)
  1468.822
  1312.390
   617.518
2+
2+
2+
  3002.06 6     E            R      3+ 0.19 ps +12-6     996.75 14 
  1586.57 10 
  1689.7 1 
  2384.54 11 
   37 6 
   79 3 
 
  100 4 
E1
M1+E2
M1+E2
M1+E2
  2005.200
  1415.480
  1312.390
   617.518
3-
4+
2+
2+
  3011.08 11     E      L            (4,5,6)-      637.89 10 
  100
M1+E2
  2373.19
5-
  3027.97 10    DE            R      6+      859.83 25 
   946.39 10 
   45 9 
  100 7 
M1+E2
E2
  2167.76
  2081.64
6+
4+
  3046 5             M        V  1-        
  3049.08 8     E      L            (4+) 0.08 ps +12-3     967.63 10 
  1633.39 10 
   28.4 22 
  100.0 22 
[M1]
[M1]
  2081.64
  1415.480
4+
4+
  3051.19 11     E      L            (5)+     1635.70 10 
  100
M1+E2
  1415.480
4+
  3066.23 10     E G    L            (2,3)- > 207 fs   1753.8
  2448.76 10 
   56.3 23 
  100.0 23 
E1
E1
  1312.390
   617.518
2+
2+
  3068.62 6 A   E           QR T V  4+ > 555 fs   1063.49 10 
  1599.70 10 
  1653.09 10 
  1756.30 14 
  100.0 19 
   93.4 22 
   44.8 17 
   36.5 22 
E1
E2
M1+E2
E2
  2005.200
  1468.822
  1415.480
  1312.390
3-
2+
4+
2+
  3071.46 8     E       M      T V  (4)+ > 249 fs   1006.9 1 
  1066.28 10 
  100 4 
   39 4 


  2064.53
  2005.200
3+
3-
  3071.74 5     E                   (1,2+)      840.613 10 
   949.65 11 
  1638.4 10 
  3071.2 10 
 
 
 
 




  2231.12
  2121.62
  1433.27
     0.0
2+
2+
0+
0+
  3075.19 11    DE      L            (4,5)+ 0.3 ps +5-1    1659.70 10 
  100
M1+E2
  1415.480
4+
E(level)
(keV)
XREFJπ(level) T1/2(level)E(γ)
(keV)
I(γ)M(γ)Final Levels
  3081.65 19     E      L     R      2+     3081.60 19 
  100
E2
     0.0
0+
  3093.02 8    D                    8-      157.50 10 
   299.19 10 
   16.0 9 
  100 11 
M1+E2
M1+E2
  2935.50
  2793.80
7-
7-
  3102 5            LM        V  4+        
  3102.15 10     E            R      (2)+ 21 fs 6    3102.10 10 
  100
[E2]
     0.0
0+
  3102.59 8     E      L            (4,5)      729.41 10 
  1687.08 10 
   26.7 25 
  100.0 25 


  2373.19
  1415.480
5-
4+
  3105.50 5     E           QR      (2)+ 0.3 ps +5-1    1636.7 1 
  1690.1 1 
  1792.77 10 
  2488.14 10 
 
 
   50 3 
  100 3 
[M1]
[E2]
[M1]
[M1]
  1468.822
  1415.480
  1312.390
   617.518
2+
4+
2+
2+
  3109.98 7     E G  J         T    (2)+ 0.13 ps +6-3    1641.14 10 
  2492.24 10 
  3110.01 16 
   84.0 20 
  100.0 22 
   37.7 18 
[M1]
[M1]
[E2]
  1468.822
   617.518
     0.0
2+
2+
0+
  3130.83 7 A   E      LM    R   V  5-      714.84 10 
  1125.78 10 
  1715.08 12 
   30.0 21 
  100
   23.0 12 
E2
E2
E1
  2416.00
  2005.200
  1415.480
3-
3-
4+
  3133.42 9 A   E GHI       Q       1- 27 fs 5    1909.53 17 
  3133.21 10 
   38.7 16 
  100 5 
[E1]
E1
  1224.341
     0.0
0+
0+
  3135.84 6     E GH                (2,3+) 0.3 ps +3-1    1071.26 10 
  1667.01 25 
  1823.39 10 
  2518.43 10 
   28 3 
   27 5 
  100 5 
   68 6 




  2064.53
  1468.822
  1312.390
   617.518
3+
2+
2+
2+
  3145.28 8     E            R      3+,4+,5+ 0.13 ps +5-3    1063.6 1 
  1729.82 10 
 
  100
M1+E2
M1+E2
  2081.64
  1415.480
4+
4+
  3163.51 9     E GH                2+ 0.26 ps +12-7     656.74 10 
  3163.4 3 
  100
   58 9 
E1
E2
  2506.70
     0.0
1-
0+
  3165.46 11     E      L            4-,5-,6-      792.27 10 
  100
M1+E2
  2373.19
5-
  3169.46 6 A   E GH                2+ 146 fs 14    1164.2 1 
  1945.14 17 
  2552.01 10 
  3170.0 15 
 
   74 3 
  100 3 
    4
E1
E2
M1+E2
[E2]
  2005.200
  1224.341
   617.518
     0.0
3-
0+
2+
0+
E(level)
(keV)
XREFJπ(level) T1/2(level)E(γ)
(keV)
I(γ)M(γ)Final Levels
  3175 4                 Q       (3)-        
  3176.47 8    D                    8+      295.19 14 
   382.37 13 
   604.98 10 
    8.2 20 
   10.6 23 
  100 5 
M1+E2

E2
  2881.02
  2793.80
  2571.47
8+
7-
6+
  3176.83 13     E                   (4)+     2559.28 13 
  100
E2
   617.518
2+
  3178.79 7     E      LM    R T V  2+ 104 fs 24    2561.23 10 
  3178.76 10 
  100.0 15 
   35.7 15 
M1+E2
E2
   617.518
     0.0
2+
0+
  3189.82 9     E                   4+,5,6+ > 354 fs   1022.09 13 
  1774.30 10 
   83 4 
  100 4 


  2167.76
  1415.480
6+
4+
  3190.06 9     E GH J L            0+,1,2,3+ 22.2 fs 14    2572.51 10 
  100

   617.518
2+
  3194.46 6     E    J       R      (2)+ 0.10 ps 4    1189.41 10 
  1882.1 1 
  2576.72 10 
   59.0 18 
 
  100.0 18 
[E1]
[M1]
[M1]
  2005.200
  1312.390
   617.518
3-
2+
2+
  3201.32 10     E                   5- 0.5 ps +5-2    1196.21 19 
  1785.8 1 
  100
 
E2
E1
  2005.200
  1415.480
3-
4+
  3203.25 10     E            R      (2,3)+ 0.12 ps +9-4    2585.70 10 
  100
(M1+E2)
   617.518
2+
  3205.74 12     E                   2+,3,4 > 111 fs   1736.90 12 
  1790.2
  100
 


  1468.822
  1415.480
2+
4+
  3206.48 8     E      LM        V  (4)+ 76 fs 24    1084.93 10 
  2588.85 10 
   76 4 
  100
[E2]
[E2]
  2121.62
   617.518
2+
2+
  3206.71 3     E                   2+,3,4 0.4 ps +3-1    1792.1
  1894.30 3 
 
  100


  1415.480
  1312.390
4+
2+
  3230.29 9    D                    8+      349.26 10 
   436.92 6 ?
   658.83 10 
   27 4 
 
  100 14 
M1+E2
E1
E2
  2881.02
  2793.80
  2571.47
8+
7-
6+
  3231.59 6 A   E GHI        R      1+ 35 fs 4    1919.4 1 
  2614.02 14 
  3231.35 10 
 
   38.9 22 
  100.0 22 
M1+E2
M1+E2
M1
  1312.390
   617.518
     0.0
2+
2+
0+
  3239.04 7    D                    7+      573.31 10 
   668.18 18 
  1071.24 10 
  100 4 
   35 4 
   54 6 
E2
M1+E2
E2(+M1)
  2665.64
  2571.47
  2167.76
5+
6+
6+
E(level)
(keV)
XREFJπ(level) T1/2(level)E(γ)
(keV)
I(γ)M(γ)Final Levels
  3242.64 6     E GH   L    QR T    2+ 0.2 ps +3-1    1161.08 12 
  2625.07 10 
  3242.49 10 
  100 8 
   92 6 
   64 5 
E2
M1+E2
E2
  2081.64
   617.518
     0.0
4+
2+
0+
  3246.86 8     E    J              (1,2)+ 0.16 ps 3    1778.0 1 
  2629.34 10 
 
  100


  1468.822
   617.518
2+
2+
  3247.17 11     E       M        V  (6+)     1831.67 10 
  100

  1415.480
4+
  3248.25 8    D                    7-      155.21 10 
   312.94 10 
   316.19 10 
    1.02 23 
    9.9 5 
  100
M1+E2
M1(+E2)
M1+E2
  3093.02
  2935.50
  2931.97
8-
7-
6-
  3251.86 13     E            R      (0)+ < 0.8 ps   2634.31 13 
  100
E2
   617.518
2+
  3252.55 12    D                    (6,7,8)-      458.75 10 
  100
M1(+E2)
  2793.80
7-
  3254.21 7     E GH                (0+,1,2) 0.2 ps +8-1    1785.2
  1942.01 10 
  2636.62 11 
 
  100 3 
   70 3 



  1468.822
  1312.390
   617.518
2+
2+
2+
  3254.30 8     E                   (3,4)+ 57 fs 17    1249.01 10 
  1838.89 10 
  100 3 
   57 3 
E1
M1+E2
  2005.200
  1415.480
3-
4+
  3258.01 11     E                   (3,4+)     1252.8 1 
  100

  2005.200
3-
  3266.54 11     E      LM    R   V  4+ 0.19 ps 5    1851.04 10 
  100
[M1]
  1415.480
4+
  3269.50 8     E                   2+,3,4,5- 0.17 ps +21-7    1264.25 10 
  1854.04 10 
  100.0 25 
   44.3 25 


  2005.200
  1415.480
3-
4+
  3290.40 12     E                   (2+)     1419.43 10 
  100

  1870.96
0+
  3291.13 7     E      LM   Q    V  2+,3,4,5- 0.2 ps +5-1    1209.4 1 
  1285.95 10 
  1875.7 1 
 
  100
 



  2081.64
  2005.200
  1415.480
4+
3-
4+
  3291.17 9    D                    7-      917.73 10 
  1123.96 15 
  100 8 
   95 10 
E2
E1
  2373.19
  2167.76
5-
6+
  3297.01 8     E            R      (2,3)+ 0.38 ps +24-11    1881.5 1 
  2679.46 10 
  100.0 20 
   31.2 20 


  1415.480
   617.518
4+
2+
  3300.99 16     E   I               (1) 0.10 ps +12-4    3300.94 16 
  100.0 4 

     0.0
0+
  3303.24 11 A   E GH           T    (2,3)+ 173 fs 24     629.2 4 
   886.99 23 
  2685.83 17 
    6.8 17 
   17 3 
  100 5 



  2674.00
  2416.00
   617.518
2+
3-
2+
E(level)
(keV)
XREFJπ(level) T1/2(level)E(γ)
(keV)
I(γ)M(γ)Final Levels
  3312.24 6     E    J L     R      (1-,2) 76 fs 17    1306.97 10 
  2000.01 10 
  2694.56 10 
   46.9 13 
   43.8 19 
  100.0 21 



  2005.200
  1312.390
   617.518
3-
2+
2+
  3318.09 8    D                    9-      382.37 13 
   524.28 10 
   14 3 
  100
E2
E2
  2935.50
  2793.80
7-
7-
  3319.83 6     E                   1-,2,3,4+ 0.17 ps 3    1314.6 1 
  1851.04 10 
  2702.24 10 
 
  100 3 
   62 3 



  2005.200
  1468.822
   617.518
3-
2+
2+
  3322.40 10    D                    10+      145.87 10 
   441.45 10 
   11.8 10 
  100 5 
E2
E2
  3176.47
  2881.02
8+
8+
  3325.96 11     E                V  (3)-      734.91 10 
  100

  2591.05
4-
  3329.17 11     E      LM        V  (5-)     1913.67 10 
  100

  1415.480
4+
  3332.11 8     E           QR      2+,3,4,5- 0.12 ps 3    1326.83 10 
  1916.72 12 
  100 8 
   54 8 


  2005.200
  1415.480
3-
4+
  3332.46 10     E                   1,2,3,4+ 97 fs 24    2714.91 10 
  100

   617.518
2+
  3336.03 10     E            R      (2)+ 0.10 ps 3    2718.48 10 
  100
[M1+E2]
   617.518
2+
  3341.86 10     E              T V  (3)+ 37 fs 4    2724.31 10 
  100
E2+M1
   617.518
2+
  3353.36 10     E      L     R      0+ 0.13 ps 4    2735.81 10 
  100
[E2]
   617.518
2+
  3363.55 7     E G    LM   QR   V  2+ 0.24 ps +10-6    2745.86 10 
  3363.67 10 
  100 3 
   58 3 
M1+E2
E2
   617.518
     0.0
2+
0+
  3363.99 13     E                   2+,3,4,5,6+ 0.2 ps +7-1     909.48 10 
  100

  2454.51
4+
  3369.62 7 A   E      L            2+,3,4+ 35 fs 3    1900.77 10 
  1952.9 10 
  2752.08 10 
   26.9 14 
   50
  100.0 14 



  1468.822
  1415.480
   617.518
2+
4+
2+
  3375.45 12    D                    (6,7,8)      439.95 10 
  100
D
  2935.50
7-
  3375.50 9     E   I               (1) 52 fs 8    2758.02 14 
  3375.40 10 
   95 3 
  100 3 


   617.518
     0.0
2+
0+
  3376.46 11    D                    7-      283.40 12 
   444.53 10 
    4.7 10 
  100 3 
M1+E2
M1+E2
  3093.02
  2931.97
8-
6-
  3378.52 8     E G    L     R      (2)+ 0.4 ps +3-1    1909.63 10 
  2761.18 14 
  100.0 21 
   33.9 21 
[M1]
[M1]
  1468.822
   617.518
2+
2+
E(level)
(keV)
XREFJπ(level) T1/2(level)E(γ)
(keV)
I(γ)M(γ)Final Levels
  3383.71 9     E                   0+:4+ 97 fs 17    1227.70 13 
  2766.05 10 
   30 3 
  100


  2156.18
   617.518
2+
2+
  3392.78 12     E                   1,2+ > 693 fs   3392.72 12 
  100

     0.0
0+
  3393.39 4     E                   0+:4+ > 970 fs   2775.83 4 
  100

   617.518
2+
  3393.45 10 A   E GH        Q       (1,2+)     2775.78 18 
  3393.35 20 
  100
   31 4 


   617.518
     0.0
2+
0+
  3393.60 7     E                   1-:5- 0.2 ps +3-1     977.59 5 
  100

  2416.00
3-
  3398.88 8    D                    8+      222.17 10 
   517.99 12 
   827.54 10 
   28 4 
   51 9 
  100 9 
(M1)
M1+E2
E2
  3176.47
  2881.02
  2571.47
8+
8+
6+
  3400.35 10     E                   0+:4+     2087.94 10 
  100

  1312.390
2+
  3402.93 10     E            R      1+,2+,3+ > 527 fs   2785.37 10 
  100
M1+E2
   617.518
2+
  3422.55 9     E      LM   QR   V  (4)+     1953.71 16 
  2805.0 1 
  100.0 24 
   35.7 24 


  1468.822
   617.518
2+
2+
  3425.60 5     E                   0+:4+ 0.09 ps 3    2113.19 5 
  100

  1312.390
2+
  3426.32 14     E                   0+:4+ 33 fs +17-10    2808.76 14 
  100

   617.518
2+
  3428.87 7     E GH                2+ 0.08 ps +5-3    2811.2 1 
  3428.71 14 
  100.0 16 
   14.2 16 
M1+E2
E2
   617.518
     0.0
2+
0+
  3429.6 3     E                       2014.1 3 
  100

  1415.480
4+
  3429.98 16    D                    (5,6,7)     1262.21 15 
  100
D(+Q)
  2167.76
6+
  3433.73 11     E            R      (2+:6+) 0.11 ps +6-3    2018.23 10 
  100

  1415.480
4+
  3451.97 8     E                   (0+)      945.26 5 
  100
E1
  2506.70
1-
  3452 5             M        V  6(+)        
  3452.47 7     E GH                2+ 0.2 ps +4-1    2037.4 3 
  2835.33 10 
  3452.1 4 
   59 8 
  100 8 
 
[E2]
[M1]
[E2]
  1415.480
   617.518
     0.0
4+
2+
0+
  3453.8 3     E                   0+:4+     1985.0 3 
  100

  1468.822
2+
  3455.48 9     E GH   L            0+,1,2 0.3 ps +3-1    2837.85 10 
  100

   617.518
2+
  3470.3 12 A                       0+:4+     2852.7 12 
  100

   617.518
2+
  3471.32 22     E                   2+:6+     1389.7 3 
  2055.8 3 
  100
  100


  2081.64
  1415.480
4+
4+
E(level)
(keV)
XREFJπ(level) T1/2(level)E(γ)
(keV)
I(γ)M(γ)Final Levels
  3478.58 7     E GH                0+,1,2+ 0.2 ps +7-1    2166.06 10 
  2861.0 1 
  3479.2 3 
  100
   37 5 
  100



  1312.390
   617.518
     0.0
2+
2+
0+
  3478.7 9 A                       0+:4+     1322.0 10 
  2863.0 20 
  100 17 
   33 17 


  2156.18
   617.518
2+
2+
  3487 5                      V  (6+)        
  3487.55 10     E                V  (4)+ 83 fs 17    2869.99 10 
  100
E2
   617.518
2+
  3489.85 6     E      L            2+,3,4+ 68 fs 13    1368.12 10 
  2074.36 10 
  2872.4 1 
   39 4 
  100 4 
   55.8 10 



  2121.62
  1415.480
   617.518
2+
4+
2+
  3493.92 13    D                    (6,7)     1326.15 12 
  100
D(+Q)
  2167.76
6+
  3500.45 8     E GH                0+:3+ 0.15 ps 3    2882.85 10 
  100

   617.518
2+
  3511.6 3     E                   3-:7- > 485 fs   1138.4 3 
  100

  2373.19
5-
  3512.97 10     E G                 (1,2,3)+ 0.10 ps 3    2895.23 10 
  100
M1+E2
   617.518
2+
  3522.51 10     E                   0+:4+ 33 fs 3    2904.95 10 
  100

   617.518
2+
  3528.92 9    D                    7-      593.45 10 
   735.08 10 
   82 11 
  100
M1+E2
M1+E2
  2935.50
  2793.80
7-
7-
  3530.90 5     E                       1525.69 4 
  100

  2005.200
3-
  3531.32 7     E      LM        V  4+ 76 fs 24    2218.9 1 
  2913.77 10 
 
  100

M1+E2
  1312.390
   617.518
2+
2+
  3540.24 9     E GH                1,2+ 15.3 fs 21    2922.72 10 
  3539.8 4 
  100 7 
   24 6 


   617.518
     0.0
2+
0+
  3542.84 10    D                    8+      621.41 15 
  1375.02 10 
   78 8 
  100 6 
E2
E2
  2921.53
  2167.76
6+
6+
  3556.88 10     E G I               (1,2+) 48 fs 4    3556.78 12 
  100

     0.0
0+
  3557.33 10     E  H   LM        V  (3)- 0.07 ps 3    2939.77 10 
  100
[E1]
   617.518
2+
  3568.05 6     E GHI               2+ 62 fs 10    2099.17 10 
  2950.52 12 
  3568.00 10 
  100 5 
   94 4 
   75 5 
M1+E2
M1+E2
E2
  1468.822
   617.518
     0.0
2+
2+
0+
  3571.05 10    D                    9-      252.88 10 
   478.22 4 ?
   635.7 3 
   777.36 15 
  100 6 
 
   51 17 
   76 13 
M1+E2
M1+E2
E2
E2
  3318.09
  3093.02
  2935.50
  2793.80
9-
8-
7-
7-
E(level)
(keV)
XREFJπ(level) T1/2(level)E(γ)
(keV)
I(γ)M(γ)Final Levels
  3572.28 20       GH                (1,2+)     3572.37 23 
  100

     0.0
0+
  3574.49 9     E                   0+:4+ ≤ 2.5 ps   2262.06 10 
  2956.96 18 
   57 4 
  100 4 


  1312.390
   617.518
2+
2+
  3577.2 3     E                   0+:4+     2264.8 3 
  100

  1312.390
2+
  3577.55 11       GH                2+     2352.94 19 
  2960.13 16 
  3577.53 18 
   21.9 19 
  100 4 
   18.1 19 



  1224.341
   617.518
     0.0
0+
2+
0+
  3579.44 7     E                   0+:4+ 0.13 ps 3    2267.21 10 
  2961.69 10 
   40 3 
  100


  1312.390
   617.518
2+
2+
  3583.80 24    D                    5,6,7     1416.03 23 
  100
D(+Q)
  2167.76
6+
  3586 5             M        V  3-        
  3594.64 9     E   I  L            1,2+ 76 fs 14    2977.24 14 
  3594.49 10 
   43 4 
  100


   617.518
     0.0
2+
0+
  3598.81 10     E                   1+,2+,3+ 31 fs 8    2981.25 10 
  100
M1+E2
   617.518
2+
  3608.91 10     E G                 0+,1,2,3+ 0.12 ps 3    2991.30 10 
  100

   617.518
2+
  3613.26 10     E                   1+,2+,3+ 0.10 ps +6-3    2143.97 19 
  2995.85 11 
   96 6 
  100

M1+E2
  1468.822
   617.518
2+
2+
  3618.48 14     E      LM        V  3- 0.06 ps +6-2    1613.8 3 
  2202.7 3 
  3000.83 18 
 
 
  100


[E1]
  2005.200
  1415.480
   617.518
3-
4+
2+
  3622.18 11     E                   0+:4+ 0.033 ps 10    3004.62 11 
  100

   617.518
2+
  3627.6 3     E      L            2+:6+     2212.1 3 
  100

  1415.480
4+
  3646.54 10     E G                 0+,1,2,3+ 0.24 ps +8-5    3028.88 10 
  100

   617.518
2+
  3652.18 9     E G                 1,2+ 0.12 ps 4    3034.60 10 
  3652.07 23 
  100 4 
   19 4 


   617.518
     0.0
2+
0+
  3658.74 11    D                    8-      340.50 15 
   410.55 10 
  100
 
M1+E2
M1+E2
  3318.09
  3248.25
9-
7-
  3665.78 10     E      LM        V  3- 132 fs 24    3048.22 10 
  100
[E1]
   617.518
2+
  3676.73 8     E                   0+:4+ 0.09 ps 3    2208.09 11 
  3059.00 10 
  100 4 
   75 4 


  1468.822
   617.518
2+
2+
E(level)
(keV)
XREFJπ(level) T1/2(level)E(γ)
(keV)
I(γ)M(γ)Final Levels
  3682.83 12     E   I               1,2+ 32 fs 8    3682.76 12 
  100

     0.0
0+
  3684.02 12    D                    10+      802.98 10 
  100
E2
  2881.02
8+
  3685.55 15    D                    6-,7-,8-      309.09 10 
  100
M1+E2
  3376.46
7-
  3687.93 10     E                   (1,2+) 0.13 ps 5    3687.86 10 
  100

     0.0
0+
  3690.68 13     E      LM        V  (4)+ 0.10 ps +11-4    3073.12 13 
  100
[E2]
   617.518
2+
  3696.15 11       GH                0+,1,2,3+     2383.81 17 
  100

  1312.390
2+
  3697.74 12     E      L            1-,2,3,4+ 0.3 ps +10-1    1692.8 3 
  3080.13 12 
 
  100


  2005.200
   617.518
3-
2+
  3703.81 10     E   I               1,2+ 22 fs 4    3703.74 10 
  100

     0.0
0+
  3707.45 9     E GH                1-,2,3+ 36 fs 8     840.71 18 
  2395.00 18 
  3090.04 18 
   40 4 
   57 4 
  100 6 



  2866.75
  1312.390
   617.518
3-
2+
2+
  3719.75 20     E G    L            (2+,3+)     2305.1 3 
  100

  1415.480
4+
  3723.25 17     E G                 0+,1,2,3+ 16 fs +12-8    3105.13 24 
  100

   617.518
2+
  3731.95 10     E                   0+:4+ 0.125 ps +9-4    3114.39 10 
  100

   617.518
2+
  3736.5 3    D                    8+     1165.0 3 
  100
E2
  2571.47
6+
  3739.55 10     E      L            (1,2,3)+ 66 fs 20    3121.99 10 
  100
M1+E2
   617.518
2+
  3743.76 10     E G                 (1,2,3)+ 54 fs 8    3126.22 10 
  100
M1+E2
   617.518
2+
  3746.8 3     E       M        V  (4)+     2331.3 3 
  100

  1415.480
4+
  3754.09 11     E                   2+:6+ > 416 fs   2338.58 10 
  100

  1415.480
4+
  3755.46 13     E      L            (2+) 28 fs 9    3755.39 13 
  100
[E2]
     0.0
0+
  3763.95 10     E       M        V  (4)+ 104 fs 14    3146.38 10 
  100
[E2]
   617.518
2+
  3770.47 10     E                   0+:4+ 26 fs 6    3152.90 10 
  100

   617.518
2+
  3783.197 11     E                   (1,2,3)+ 0.2 ps +4-1    3165.631 10 
  100
M1+E2
   617.518
2+
  3785.69 13    D                    9-      692.67 10 
  100

  3093.02
8-
  3787.3 3     E G                 2+     3787.2 3 
  100
E2
     0.0
0+
  3801.2 3     E       M        V  (4)+     2385.7 3 
  100

  1415.480
4+
  3804.87 14     E                   0+:4+ 0.2 ps +5-1    3187.30 14 
  100

   617.518
2+
  3809.39 9    D                    10-      238.32 10 
   491.30 10 
   716.38 10 
 
 
 
M1+E2
M1+E2
E2
  3571.05
  3318.09
  3093.02
9-
9-
8-
E(level)
(keV)
XREFJπ(level) T1/2(level)E(γ)
(keV)
I(γ)M(γ)Final Levels
  3810.04 10     E   I               1,2+ 9.7 fs 21    3809.97 10 
 

     0.0
0+
  3810.88 10     E       M        V  (3-) 0.07 ps +3-2    3193.31 10 
  100
[E1]
   617.518
2+
  3832.66 11     E       M        V  (4+) 22 fs 7    3215.09 11 
  100
[E2]
   617.518
2+
  3838.85 23       GH                (1,2+)     3838.84 24 
  100

     0.0
0+
  3844.25 10     E                   0+:4+ 263 fs   3226.68 10 
  100

   617.518
2+
  3846.48 10     E GHI               (1,2+) 40 fs 9    3846.41 10 
  100

     0.0
0+
  3854.4 3     E                   2+     3854.3 3 
  100
E2
     0.0
0+
  3864.51 11     E       M        V  (4)+     2449.0 1 
  100

  1415.480
4+
  3869.00 10     E   I               (1,2+) 13 fs 3    3868.93 10 
  100 11 

     0.0
0+
  3878.62 13     E                   0+:4+ 53 fs 24    3261.05 13 
  100

   617.518
2+
  3892.48 14       GH    M        V  0+,1,2,3+     2579.77 23 
  100

  1312.390
2+
  3913.69 9    D                    9+      514.75 10 
   674.71 10 
  1032.66 10 
 
 
 
M1+E2
E2
M1(+E2)
  3398.88
  3239.04
  2881.02
8+
7+
8+
  3929.21 21     E          P        (0)+ ≤ 0.9 ps   3311.64 21 
  100
[E2]
   617.518
2+
  3930.78 17    D                    12+      608.5 4 
  100
E2
  3322.40
10+
  3932.18 12     E                   0+:4+ 0.09 ps +6-3    3314.61 12 
  100

   617.518
2+
  3933.07 13     E   I               (1,2+) 12 fs 4    3933.00 13 
  100

     0.0
0+
  3939.27 14     E       M        V  (4)+ 0.05 fs +3-2    3321.70 14 
  100

   617.518
2+
  3951.57 13     E GH                1,2+ 43 fs 6    3333.9 10 
  3951.4 10 
  100 5 
   12.5 18 


   617.518
     0.0
2+
0+
  3963.8 4     E                   (1,2+) 0.03 ps +4-2    3963.7 4 
  100

     0.0
0+
  3966.44 14    D                    (9,10,11)+      644.04 10 
 
M1+E2
  3322.40
10+
  3970.08 19     E GH                (1,2+) 0.05 ps +7-2    3352.4 4 
  3970.0 3 
   44 11 
  100 9 


   617.518
     0.0
2+
0+
  3990.40 11    D                    10+      306.23 25 
   591.57 10 
   813.86 15 
   21 5 
 
  100 12 
M1+E2
E2
(E2)
  3684.02
  3398.88
  3176.47
10+
8+
8+
  3997.75 14       GHI               1,2+ 2.4 fs 6    2685.83 17 
  3997.6 3 
  100 5 
   27 3 


  1312.390
     0.0
2+
0+
E(level)
(keV)
XREFJπ(level) T1/2(level)E(γ)
(keV)
I(γ)M(γ)Final Levels
  4003.9 3       GH    M        V  (3-)     3386.50 31 
  100

   617.518
2+
  4033.88 20     E       M        V  (3-) 0.06 ps +5-2    3416.31 20 
  100
[E1]
   617.518
2+
  4060 5             M        V  (4+)        
  4090 5             M        V  (3-)        
  4118 5             M        V  (4+)        
  4125.91 13    D                    10+      949.44 10 
  100
E2
  3176.47
8+
  4172 5             M        V  (3-)        
  4174.50 13    D                    10+      856.41 10 
  100
E1
  3318.09
9-
  4221 5             M        V  (7-)        
  4248 5             M        V  (3-)        
  4279 5             M        V  (3-)        
  4283.47 14    D                    10+      740.63 10 
  100
E2
  3542.84
8+
  4284.76 15    D                    (9)-      908.29 10 
  100
E2
  3376.46
7-
  4285.20 13    D                    11-      967.10 10 
  100
E2
  3318.09
9-
  4320 5             M        V  (4+)        
  4338 5             M        V  (7-)        
  4364 5             M        V  (4+)        
  4383.05 14    D                    11+      452.27 10 
  1060.63 10 
 
 
M1(+E2)
M1+E2
  3930.78
  3322.40
12+
10+
  4385 5             M        V  (3-)        
  4385.16 13    D                    10-     1067.06 10 
  100
M1+E2
  3318.09
9-
  4419 5             M        V  (4+)        
  4467.74 14    D                    11-      896.68 10 
  100
E2
  3571.05
9-
  4468 5             M        V  3        
  4499 5             M        V  (3-)        
  4546 5                      V  (2+)        
  4587.15 16    D                    12+      903.12 10 
  100
E2
  3684.02
10+
  4687.17 13    D                    11+      773.48 10 
  100
E2
  3913.69
9+
  4720               P        0+,2+        
  4871.47 20    D                    14+      940.68 10 
  100
E2
  3930.78
12+
E(level)
(keV)
XREFJπ(level) T1/2(level)E(γ)
(keV)
I(γ)M(γ)Final Levels
  5106.22 20    D                    (13)-     1175.43 10 
  100
E1
  3930.78
12+
  7633.0 5          J              1- 5.3 fs 9    4323 6 
  4385 6 
  4439 6 
  4522
  4782 3 
  4800 3 
  4909 2 
  5126 2 
  5337 4 
  5403 2 
  5477 2 
  5512 2 
  5551 4 
  5763 2 
  6164 2 
  6203 3 
  6409 2 
  7015 2 
  7632 1 
    0.36 18 
    0.91 18 
    0.36 18 
    0.91 18 
    3.5 4 
    3.09 18 
    0.36 18 
    0.73 18 
    0.91 18 
    0.36 18 
    0.73 18 
    1.27 18 
    0.91 18 
   21.1 16 
    3.5 4 
    4.0 4 
   14.6 11 
   21.3 16 
  100 7 

E1
E1(+M2)
E1(+M2)
E1(+M2)
E1
[E1]
[E1]
[E1]
[E1]
[E1]
[E1]
[E3]
E1
E1(+M2)
E1
E1
E1+M2
E1
  3312.24
  3246.86
  3190.06
  3109.98
  2852.90
  2834.27
  2723.96
  2506.36
  2300.68
  2231.12
  2156.18
  2121.62
  2081.64
  1870.96
  1468.822
  1433.27
  1224.341
   617.518
     0.0
(1-,2)
(1,2)+
0+,1,2,3+
(2)+
2+
0+
2+
(2)+
0+
2+
2+
2+
4+
0+
2+
0+
0+
2+
0+
  9394.20 3 S      G                 (1)+     5390.5 5 
  5397.8 3 
  5423.9 3 
  5442.48 13 
  5498.9 6 
  5501.62 17 
  5547.5 4 
  5555.6 6 
  5650.8 5 
  5670.24 24 
  5674.88 25 
  5686.66 14 
  5697.93 13 
  5741.76 18 
  5746.95 24 
  5784.3 4 
  5822.2 4 
  5825.99 20 
  5837.08 18 
  5853.86 21 
  5879.4 3 
  5893.51 13 
  5914.9 3 
  5938.41 14 
  5942.00 10 
  5965.00 10 
  6000.49 13 
  6015.63 15 
  6030.58 16 
  6090.77 16 
  6140.26 16 
  6150.4 4 
  6162.45 16 
  6203.94 15 
  6224.68 15 
  6230.36 14 
  6258.35 19 
  6260.63 25 
  6282.6 3 
  6328.5 3 
  6448.4 3 
  6463.7 6 
  6559.8 6 
  6564.67 13 
  6627.97 15 
  6720.8 6 
  6725.22 15 
  6832.3 5 
  6862.10 21 
  6887.26 13 
  6991.18 23 
  7093.29 17 
  7162.1 5 
  7237.56 23 
  7272.28 17 
  7328.6 7 
  7522.80 25 
  7924.8 4 
  7961.03 11 
  8081.34 14 
  8169.41 23 
  8776.11 14 
  9393.63 18 
    2.9 6 
    5.5 9 
    4.4 6 
   62.3 16 
    4.3 12 
   24.5 19 
    5.3 8 
    2.6 6 
    3.4 8 
    6.2 7 
    5.9 7 
   62.6 19 
   58.7 19 
   14.3 8 
    7.5 7 
    4.5 8 
    4.7 7 
   11.3 9 
   11.0 7 
   13.6 13 
    4.4 6 
   30.5 10 
    5.7 7 
   35.6 13 
    8.7 11 
    3.9 5 
   28.8 10 
   25.7 10 
   12.1 7 
   22.3 13 
   14.5 8 
    2.9 5 
   13.0 7 
   18.8 9 
   20.1 9 
   27.7 11 
   41 5 
   29 5 
    8.7 8 
    6.4 8 
    2.7 4 
    1.4 3 
    2.7 6 
   85 3 
    3.0 7 
    3.0 7 
   38.1 19 
    3.4 5 
    9.5 7 
  100 4 
    6.1 6 
   10.3 7 
    2.3 5 
    6.1 6 
   12.7 8 
    1.5 5 
    5.9 6 
    1.9 3 
    0.45 19 
   16.8 12 
    8.8 8 
   25.8 3 
    4.1 5 































































  4003.9
  3997.75
  3970.08
  3951.57
  3892.48
  3892.48
  3846.48
  3838.85
  3743.76
  3723.25
  3719.75
  3707.45
  3696.15
  3652.18
  3646.54
  3608.91
  3572.28
  3568.05
  3556.88
  3540.24
  3512.97
  3500.45
  3478.58
  3455.48
  3452.47
  3428.87
  3393.45
  3378.52
  3363.55
  3303.24
  3254.21
  3242.64
  3231.59
  3190.06
  3169.46
  3163.51
  3135.84
  3133.42
  3109.98
  3066.23
  2944.94
  2931.46
  2834.27
  2829.19
  2765.72
  2674.00
  2668.92
  2561.27
  2532.20
  2506.70
  2402.98
  2300.68
  2231.12
  2156.18
  2121.62
  2064.53
  1870.96
  1468.822
  1433.27
  1312.390
  1224.341
   617.518
     0.0
(3-)
1,2+
(1,2+)
1,2+
0+,1,2,3+
0+,1,2,3+
(1,2+)
(1,2+)
(1,2,3)+
0+,1,2,3+
(2+,3+)
1-,2,3+
0+,1,2,3+
1,2+
0+,1,2,3+
0+,1,2,3+
(1,2+)
2+
(1,2+)
1,2+
(1,2,3)+
0+:3+
0+,1,2+
0+,1,2
2+
2+
(1,2+)
(2)+
2+
(2,3)+
(0+,1,2)
2+
1+
0+,1,2,3+
2+
2+
(2,3+)
1-
(2)+
(2,3)-
2+
1+
0+
1-
2+
2+
(2)-
(1,2+)
2+
1-
3+
0+
2+
2+
2+
3+
0+
2+
0+
2+
0+
2+
0+

E(level): From a least-squares fit to Eγ

T1/2(level): From DSAM in 112Cd(n,n’γ) (2007Ga22), unless otherwise stated

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Additional Gamma Data:















E(level)
(keV)
Jπ(level)T1/2(level)E(γ)
(keV)
MultipolarityMixing
Ratio
Conversion
Coefficient
Additional Data
   617.518 2+ 6.46 ps 4     617.517 3 E2 0.00371B(E2)(W.u.)=30.31 19, α=0.00371, α(K)=0.00321 5, α(L)=0.000407 6, α(M)=7.82E-5 11, α(N)=1.381E-5 20, α(O)=7.37E-7 11
  1224.341 0+ 4.2 ps 11     606.821 6 E2 0.00388B(E2)(W.u.)=51 14, α=0.00388, α(K)=0.00336 5, α(L)=0.000427 6, α(M)=8.21E-5 12, α(N)=1.450E-5 21, α(O)=7.71E-7 11
  1312.390 2+ 1.9 ps 3     694.872 7 E2+M1-4.0 70.00274B(E2)(W.u.)=39 7, B(M1)(W.u.)=0.0015 6, α=0.00274, α(K)=0.00238 4, α(L)=0.000296 5, α(M)=5.68E-5 8, α(N)=1.007E-5 15, α(O)=5.50E-7 8
2+ 1.9 ps 3    1312.36 4 E2 6.64×10-4B(E2)(W.u.)=0.65 11, α=6.64E-4, α(K)=0.000557 8, α(L)=6.58E-5 10, α(M)=1.258E-5 18, α(N)=2.24E-6 4, α(O)=1.302E-7 19
  1415.480 4+ 0.87 ps 10     798.04 10 E2 0.00193B(E2)(W.u.)=63 8, α=0.00193, α(K)=0.001676 24, α(L)=0.000206 3, α(M)=3.95E-5 6, α(N)=7.01E-6 10, α(O)=3.89E-7 6
  1433.27 0+ 1.9 ns 1     120.68 10 E2 0.766B(E2)(W.u.)=99 16, α=0.766, α(K)=0.597 9, α(L)=0.1367 20, α(M)=0.0270 4, α(N)=0.00453 7, α(O)=0.0001141 17
0+ 1.9 ns 1     815.79 3 E2 0.00183B(E2)(W.u.)=0.0121 17, α=0.00183, α(K)=0.001589 23, α(L)=0.000195 3, α(M)=3.74E-5 6, α(N)=6.63E-6 10, α(O)=3.69E-7 6
  1468.822 2+ 2.7 ps 5     244.86 23 (E2) 0.0641B(E2)(W.u.)=1.2×102 5, α=0.0641, α(K)=0.0538 8, α(L)=0.00840 13, α(M)=0.001633 24, α(N)=0.000282 4, α(O)=1.143E-5 17
2+ 2.7 ps 5     851.285 15 M1+E2+E0+0.050 180.00195B(M1)(W.u.)=2.1×10-6 16, α=0.00195, α(K)=0.001667 24, α(L)=0.000196 3, α(M)=3.76E-5 6, α(N)=6.72E-6 10, α(O)=3.98E-7 6
2+ 2.7 ps 5    1468.84 10 E2 5.79×10-4B(E2)(W.u.)=0.88 17, α=5.79E-4, α(K)=0.000444 7, α(L)=5.21E-5 8, α(M)=9.96E-6 14, α(N)=1.777E-6 25, α(O)=1.039E-7 15
  1870.68 4+      401.88 13 E2 0.01277α=0.01277, α(K)=0.01093 16, α(L)=0.001492 21, α(M)=0.000288 4, α(N)=5.04×10-5 7, α(O)=2.44E-6 4
4+      455.26 13 M1+E2+2.7 +4-30.00871α=0.00871, α(K)=0.00750 11, α(L)=0.000987 15, α(M)=0.000190 3, α(N)=3.35×10-5 5, α(O)=1.706E-6 24
4+      558.39 11 E2 0.00487α=0.00487, α(K)=0.00421 6, α(L)=0.000542 8, α(M)=0.0001042 15, α(N)=1.84×10-5 3, α(O)=9.62E-7 14
4+     1253.16 12 E2 7.17×10-4α=7.17×10-4, α(K)=0.000612 9, α(L)=7.25E-5 11, α(M)=1.387E-5 20, α(N)=2.47E-6 4, α(O)=1.431E-7 20
  1870.96 0+      402.50 16 E2 0.01271α=0.01271, α(K)=0.01088 16, α(L)=0.001485 21, α(M)=0.000287 4, α(N)=5.02×10-5 7, α(O)=2.43E-6 4
0+      558.7E2 0.00487α=0.00487, α(K)=0.00420 6, α(L)=0.000541 8, α(M)=0.0001041 15, α(N)=1.83×10-5 3, α(O)=9.61E-7 14
0+     1253.56 12 E2 7.16×10-4α=7.16×10-4, α(K)=0.000612 9, α(L)=7.25E-5 11, α(M)=1.386E-5 20, α(N)=2.47E-6 4, α(O)=1.430E-7 20
  2005.200 3- 0.26 ps 5     536.31 10 E1 0.00181B(E1)(W.u.)=6.5E-5 15, α=0.00181, α(K)=0.001581 23, α(L)=0.000186 3, α(M)=3.54E-5 5, α(N)=6.30E-6 9, α(O)=3.61E-7 5
3- 0.26 ps 5     692.82 3 E1 1.02×10-3B(E1)(W.u.)=0.00061 12, α=1.02E-3, α(K)=0.000893 13, α(L)=0.0001041 15, α(M)=1.99E-5 3, α(N)=3.54E-6 5, α(O)=2.05E-7 3
3- 0.26 ps 5    1387.68 10 E1 4.19×10-4B(E1)(W.u.)=0.00034 7, α=4.19E-4, α(K)=0.000235 4, α(L)=2.70E-5 4, α(M)=5.15E-6 8, α(N)=9.19E-7 13, α(O)=5.44E-8 8
  2064.53 3+ 0.47 ps 13     648.91 10 M1+E2-1.20 +20-150.00338B(E2)(W.u.)=25 8, B(M1)(W.u.)=0.009 4, α=0.00338 6, α(K)=0.00294 5, α(L)=0.000361 6, α(M)=6.93E-5 10, α(N)=1.230E-5 19, α(O)=6.89E-7 14
3+ 0.47 ps 13     752.14 3 M1+E2-2.75 +23-170.00227B(E2)(W.u.)=64 18, B(M1)(W.u.)=0.0059 19, α=0.00227, α(K)=0.00197 3, α(L)=0.000242 4, α(M)=4.65E-5 7, α(N)=8.24E-6 12, α(O)=4.58E-7 7
3+ 0.47 ps 13    1447.00 10 M1+E2-1.70 +10-126.04×10-4B(E2)(W.u.)=1.8 5, B(M1)(W.u.)=0.0016 5, α=6.04E-4, α(K)=0.000474 7, α(L)=5.55E-5 8, α(M)=1.062E-5 16, α(N)=1.89E-6 3, α(O)=1.114E-7 17
  2081.64 4+ 0.35 ps 10     211.0 3 [M1] 0.0597B(M1)(W.u.)=0.14 5, α=0.0597, α(K)=0.0519 8, α(L)=0.00638 10, α(M)=0.001226 18, α(N)=0.000218 4, α(O)=1.261×10-5 19
4+ 0.35 ps 10     612.88 25 E2 0.00378B(E2)(W.u.)=59 20, α=0.00378, α(K)=0.00327 5, α(L)=0.000415 6, α(M)=7.99E-5 12, α(N)=1.411E-5 20, α(O)=7.52E-7 11
4+ 0.35 ps 10     666.17 6 M1+E2-0.41 30.00331B(E2)(W.u.)=24 8, B(M1)(W.u.)=0.080 24, α=0.00331, α(K)=0.00289 4, α(L)=0.000345 5, α(M)=6.62E-5 10, α(N)=1.181E-5 17, α(O)=6.89E-7 10
4+ 0.35 ps 10     769.36 10 E2 0.00211B(E2)(W.u.)=58 17, α=0.00211, α(K)=0.00183 3, α(L)=0.000226 4, α(M)=4.34E-5 6, α(N)=7.69E-6 11, α(O)=4.24E-7 6
4+ 0.35 ps 10    1464.04 10 E2 5.81×10-4B(E2)(W.u.)=0.9 3, α=5.81E-4, α(K)=0.000447 7, α(L)=5.25E-5 8, α(M)=1.003E-5 14, α(N)=1.79E-6 3, α(O)=1.046E-7 15
E(level)
(keV)
Jπ(level)T1/2(level)E(γ)
(keV)
MultipolarityMixing
Ratio
Conversion
Coefficient
Additional Data
  2121.62 2+ 0.51 ps 14     688.23 10 E2 0.00279B(E2)(W.u.)=25 7, α=0.00279, α(K)=0.00242 4, α(L)=0.000302 5, α(M)=5.81E-5 9, α(N)=1.028E-5 15, α(O)=5.58E-7 8
2+ 0.51 ps 14     808.82 19 M1+E2 0.00215α=0.00215, α(K)=0.00187 3, α(L)=0.000221 3, α(M)=4.23×10-5 6, α(N)=7.56E-6 11, α(O)=4.48E-7 7
2+ 0.51 ps 14     897.07 10 E2 1.46×10-3B(E2)(W.u.)=5.3 15, α=1.46E-3, α(K)=0.001271 18, α(L)=0.0001545 22, α(M)=2.96E-5 5, α(N)=5.26E-6 8, α(O)=2.96E-7 5
2+ 0.51 ps 14    1504.04 10 M1+E2+1.36 75.88×10-4B(E2)(W.u.)=2.2 6, B(M1)(W.u.)=0.0033 10, α=5.88E-4, α(K)=0.000444 7, α(L)=5.19E-5 8, α(M)=9.92E-6 15, α(N)=1.77E-6 3, α(O)=1.045E-7 15
2+ 0.51 ps 14    2121.49 13 E2 6.14×10-4B(E2)(W.u.)=0.017 5, α=6.14E-4, α(K)=0.000222 4, α(L)=2.57E-5 4, α(M)=4.90E-6 7, α(N)=8.75E-7 13, α(O)=5.19E-8 8
  2156.18 2+ 0.2 ps 2     687.41 10 M1+E2-2.3 190.00285B(E2)(W.u.)=23 +25-23, B(M1)(W.u.)=0.003 +5-3, α=0.00285 24, α(K)=0.00247 22, α(L)=0.000307 15, α(M)=5.9E-5 3, α(N)=1.04E-5 6, α(O)=5.7E-7 7
2+ 0.2 ps 2     842.8 15 [M1] 0.00195B(M1)(W.u.)=0.004 4, α=0.00195, α(K)=0.001706 25, α(L)=0.000201 3, α(M)=3.85×10-5 6, α(N)=6.88E-6 10, α(O)=4.08E-7 6
2+ 0.2 ps 2    1538.68 10 M1+E2+0.085 +25-226.11×10-4B(E2)(W.u.)=0.06 +8-6, B(M1)(W.u.)=0.03 3, α=6.11E-4, α(K)=0.000459 7, α(L)=5.33E-5 8, α(M)=1.019E-5 15, α(N)=1.82E-6 3, α(O)=1.089E-7 16
2+ 0.2 ps 2    2156.20 10 E2 6.23×10-4B(E2)(W.u.)=0.14 +15-14, α=6.23E-4, α(K)=0.000216 3, α(L)=2.49E-5 4, α(M)=4.75E-6 7, α(N)=8.49E-7 12, α(O)=5.04E-8 7
  2167.76 6+      297.29 12 E2 0.0334α=0.0334, α(K)=0.0283 4, α(L)=0.00416 6, α(M)=0.000806 12, α(N)=0.0001400 20, α(O)=6.15×10-6 9
6+      752.14 10 E2 0.00223α=0.00223, α(K)=0.00194 3, α(L)=0.000240 4, α(M)=4.60×10-5 7, α(N)=8.15E-6 12, α(O)=4.48E-7 7
  2231.12 2+ 0.15 ps 14     226.0 3 [E1] 0.01665B(E1)(W.u.)=0.0009 9, α=0.01665, α(K)=0.01452 21, α(L)=0.00174 3, α(M)=0.000332 5, α(N)=5.87E-5 9, α(O)=3.18E-6 5
2+ 0.15 ps 14     762.41 10 M1+E2-1.4 +8-340.00226B(E2)(W.u.)=6 6, B(M1)(W.u.)=0.0021 +26-21, α=0.00226 13, α(K)=0.00196 12, α(L)=0.000239 10, α(M)=4.58E-5 18, α(N)=8.1E-6 4, α(O)=4.6E-7 4
2+ 0.15 ps 14     918.72 10 M1+E2+0.21 +20-130.00160B(E2)(W.u.)=0.19 +39-19, B(M1)(W.u.)=0.005 5, α=0.00160 4, α(K)=0.00140 3, α(L)=0.000164 3, α(M)=3.14E-5 6, α(N)=5.62E-6 11, α(O)=3.33E-7 8
2+ 0.15 ps 14    1006.81 10 E2 1.12×10-3B(E2)(W.u.)=4 4, α=1.12E-3, α(K)=0.000979 14, α(L)=0.0001177 17, α(M)=2.25E-5 4, α(N)=4.01E-6 6, α(O)=2.28E-7 4
2+ 0.15 ps 14    1613.66 10 M1+E2-0.020 +20-275.90×10-4B(E2)(W.u.)=0.004 +9-4, B(M1)(W.u.)=0.03 3, α=5.90E-4, α(K)=0.000416 6, α(L)=4.83E-5 7, α(M)=9.23E-6 13, α(N)=1.650E-6 24, α(O)=9.86E-8 14
  2300.68 0+ > 623 fs    831.79 10 E2 1.75×10-3B(E2)(W.u.)<23, α=1.75E-3, α(K)=0.001517 22, α(L)=0.000186 3, α(M)=3.56E-5 5, α(N)=6.32E-6 9, α(O)=3.52E-7 5
0+ > 623 fs   1683.22 10 E2 5.45×10-4B(E2)(W.u.)<1.4, α=5.45E-4, α(K)=0.000341 5, α(L)=3.98E-5 6, α(M)=7.60E-6 11, α(N)=1.356E-6 19, α(O)=7.98E-8 12
  2373.19 5- 0.4 ps +6-2     291.5 1 E1 0.00834B(E1)(W.u.)=0.00031 +16-31, α=0.00834, α(K)=0.00728 11, α(L)=0.000867 13, α(M)=0.0001656 24, α(N)=2.93E-5 5, α(O)=1.619E-6 23
5- 0.4 ps +6-2     367.9 1 E2 0.01681B(E2)(W.u.)=6.×101 +4-6, α=0.01681, α(K)=0.01435 21, α(L)=0.00200 3, α(M)=0.000386 6, α(N)=6.74E-5 10, α(O)=3.19E-6 5
5- 0.4 ps +6-2     957.72 10 E1 5.28×10-4B(E1)(W.u.)=0.0008 +4-8, α=5.28E-4, α(K)=0.000462 7, α(L)=5.34E-5 8, α(M)=1.020E-5 15, α(N)=1.82E-6 3, α(O)=1.065E-7 15
  2402.98 3+ 0.24 ps +10-6     531.89 10 M1+E2-0.6 +4-250.00569B(E2)(W.u.)=16 +17-16, B(M1)(W.u.)=0.016 +7-9, α=0.00569 13, α(K)=0.00495 14, α(L)=0.000605 20, α(M)=0.000116 4, α(N)=2.06E-5 6, α(O)=1.17E-6 7
3+ 0.24 ps +10-6     934.19 10 M1+E2-4.0 61.34×10-3B(E2)(W.u.)=20 +5-9, B(M1)(W.u.)=0.0014 +6-7, α=1.34E-3 2, α(K)=0.001170 17, α(L)=0.0001413 21, α(M)=2.71E-5 4, α(N)=4.81E-6 7, α(O)=2.73E-7 4
3+ 0.24 ps +10-6     987.89 10 M1(+E2)-0.025 +27-361.37×10-3B(E2)(W.u.)=(0.02 +4-2), B(M1)(W.u.)=(0.032 +8-14), α=1.37E-3, α(K)=0.001194 17, α(L)=0.0001401 20, α(M)=2.68E-5 4, α(N)=4.79E-6 7, α(O)=2.85E-7 4
3+ 0.24 ps +10-6    1090.56 10 M1+E2+0.099 +27-361.10×10-3B(E2)(W.u.)=0.09 +6-7, B(M1)(W.u.)=0.014 +4-6, α=1.10E-3, α(K)=0.000958 14, α(L)=0.0001122 16, α(M)=2.15E-5 3, α(N)=3.84E-6 6, α(O)=2.28E-7 4
3+ 0.24 ps +10-6    1785.48 10 M1+E2-0.107 +36-435.71×10-4B(E2)(W.u.)=0.010 8, B(M1)(W.u.)=0.0036 +9-15, α=5.71E-4, α(K)=0.000338 5, α(L)=3.91E-5 6, α(M)=7.47E-6 11, α(N)=1.336E-6 19, α(O)=7.99E-8 12
E(level)
(keV)
Jπ(level)T1/2(level)E(γ)
(keV)
MultipolarityMixing
Ratio
Conversion
Coefficient
Additional Data
  2416.00 3- 0.15 ps 3     411.39 23 M1+E2-0.35 +18-230.01087B(E2)(W.u.)=8.×101 8, B(M1)(W.u.)=0.14 4, α=0.01087 23, α(K)=0.00945 18, α(L)=0.00115 4, α(M)=0.000222 8, α(N)=3.95E-5 13, α(O)=2.26E-6 4
3- 0.15 ps 3     946.92 10 E1 5.39×10-4B(E1)(W.u.)=0.00012 3, α=5.39E-4, α(K)=0.000472 7, α(L)=5.46E-5 8, α(M)=1.043E-5 15, α(N)=1.86E-6 3, α(O)=1.089E-7 16
3- 0.15 ps 3    1103.58 10 E1 4.08×10-4B(E1)(W.u.)=0.00039 8, α=4.08E-4, α(K)=0.000354 5, α(L)=4.08E-5 6, α(M)=7.78E-6 11, α(N)=1.387E-6 20, α(O)=8.16E-8 12
3- 0.15 ps 3    1798.50 10 E1 6.36×10-4B(E1)(W.u.)=0.00019 4, α=6.36E-4, α(K)=0.0001535 22, α(L)=1.751E-5 25, α(M)=3.34E-6 5, α(N)=5.96E-7 9, α(O)=3.55E-8 5
  2454.51 4+ 0.35 ps +9-6    1038.93 10 M1+E2-0.27 181.21×10-3B(E2)(W.u.)=3 +4-3, B(M1)(W.u.)=0.048 +10-14, α=1.21E-3 3, α(K)=0.001057 22, α(L)=0.0001241 24, α(M)=2.37E-5 5, α(N)=4.24E-6 8, α(O)=2.52E-7 6
4+ 0.35 ps +9-6    1142.21 10 E2 8.55×10-4B(E2)(W.u.)=2.1 +4-6, α=8.55E-4, α(K)=0.000744 11, α(L)=8.86E-5 13, α(M)=1.696E-5 24, α(N)=3.02E-6 5, α(O)=1.736E-7 25
  2493.15 4+ 0.4 ps +4-1    1024.29 10 E2 1.08×10-3B(E2)(W.u.)=4.5 +12-45, α=1.08E-3, α(K)=0.000942 14, α(L)=0.0001132 16, α(M)=2.17E-5 3, α(N)=3.85E-6 6, α(O)=2.20E-7 3
4+ 0.4 ps +4-1    1077.60 10 M1+E2+0.13 +6-51.12×10-3B(E2)(W.u.)=0.4 4, B(M1)(W.u.)=0.036 +9-36, α=1.12E-3, α(K)=0.000983 14, α(L)=0.0001151 17, α(M)=2.20E-5 4, α(N)=3.94E-6 6, α(O)=2.34E-7 4
4+ 0.4 ps +4-1    1875.70 10 E2 5.60×10-4B(E2)(W.u.)=0.089 +24-89, α=5.60E-4, α(K)=0.000278 4, α(L)=3.23E-5 5, α(M)=6.17E-6 9, α(N)=1.101E-6 16, α(O)=6.51E-8 10
  2506.36 (2)+ 0.21 ps 3    1194.00 10 M1+E2+0.20 +16-129.01×10-4B(E2)(W.u.)=0.20 +32-20, B(M1)(W.u.)=0.0090 15, α=9.01E-4 16, α(K)=0.000783 14, α(L)=9.16E-5 16, α(M)=1.75E-5 3, α(N)=3.13E-6 6, α(O)=1.86E-7 4
(2)+ 0.21 ps 3    1888.79 10 M1+E2-0.18 65.76×10-4B(E2)(W.u.)=0.09 7, B(M1)(W.u.)=0.0128 19, α=5.76E-4, α(K)=0.000301 5, α(L)=3.48E-5 5, α(M)=6.64E-6 10, α(N)=1.188E-6 17, α(O)=7.11E-8 10
  2506.70 1- 36.6 fs 19    1037.9 3 E1 4.53×10-4B(E1)(W.u.)=0.00041 5, α=4.53E-4, α(K)=0.000396 6, α(L)=4.58E-5 7, α(M)=8.73E-6 13, α(N)=1.557E-6 22, α(O)=9.15E-8 13
1- 36.6 fs 19    1073.32 17 E1 4.25×10-4B(E1)(W.u.)=0.00026 3, α=4.25E-4, α(K)=0.000372 6, α(L)=4.29E-5 6, α(M)=8.19E-6 12, α(N)=1.462E-6 21, α(O)=8.59E-8 12
1- 36.6 fs 19    1282.29 10 E1 3.90×10-4B(E1)(W.u.)=0.000177 19, α=3.90E-4, α(K)=0.000270 4, α(L)=3.10E-5 5, α(M)=5.92E-6 9, α(N)=1.056E-6 15, α(O)=6.24E-8 9
1- 36.6 fs 19    2506.70 10 E1 1.04×10-3B(E1)(W.u.)=0.000431 23, α=1.04E-3, α(K)=9.25E-5 13, α(L)=1.050E-5 15, α(M)=2.00E-6 3, α(N)=3.58E-7 5, α(O)=2.14E-8 3
  2570.21 5- > 693 fs    197.03 10 M1 0.0717B(M1)(W.u.)<1.3, α=0.0717, α(K)=0.0622 9, α(L)=0.00767 11, α(M)=0.001474 21, α(N)=0.000263 4, α(O)=1.514×10-5 22
5- > 693 fs    565.10 20 E2 0.00472B(E2)(W.u.)<45, α=0.00472, α(K)=0.00407 6, α(L)=0.000523 8, α(M)=0.0001007 15, α(N)=1.776E-5 25, α(O)=9.32E-7 13
5- > 693 fs    699.59 10 E1 1.00×10-3B(E1)(W.u.)<0.00029, α=1.00E-3, α(K)=0.000874 13, α(L)=0.0001020 15, α(M)=1.95E-5 3, α(N)=3.47E-6 5, α(O)=2.01E-7 3
5- > 693 fs   1154.75 10 E1 3.88×10-4B(E1)(W.u.)<9.0E-5, α=3.88E-4, α(K)=0.000326 5, α(L)=3.75E-5 6, α(M)=7.15E-6 10, α(N)=1.276E-6 18, α(O)=7.52E-8 11
  2571.47 6+ > 693 fs    403.55 10 M1+E2-0.57 60.01159B(E2)(W.u.)<20, B(M1)(W.u.)<0.012, α=0.01159, α(K)=0.01005 15, α(L)=0.001253 21, α(M)=0.000241 4, α(N)=4.28E-5 7, α(O)=2.38E-6 4
6+ > 693 fs    700.89 10 E2 0.00266B(E2)(W.u.)<77, α=0.00266, α(K)=0.00231 4, α(L)=0.000288 4, α(M)=5.53E-5 8, α(N)=9.80E-6 14, α(O)=5.33E-7 8
6+ > 693 fs   1156.21 10 E2 8.34×10-4B(E2)(W.u.)<5.6, α=8.34E-4, α(K)=0.000725 11, α(L)=8.63E-5 12, α(M)=1.651E-5 24, α(N)=2.94E-6 5, α(O)=1.692E-7 24
  2591.05 4- > 693 fs    526.52 10 E1 0.00189B(E1)(W.u.)<0.00076, α=0.00189, α(K)=0.001650 24, α(L)=0.000194 3, α(M)=3.70E-5 6, α(N)=6.58E-6 10, α(O)=3.76E-7 6
4- > 693 fs    585.78 10 M1+E2+0.47 +8-70.00450B(E2)(W.u.)<11, B(M1)(W.u.)<0.017, α=0.00450, α(K)=0.00392 6, α(L)=0.000473 7, α(M)=9.06E-5 13, α(N)=1.616E-5 23, α(O)=9.34E-7 15
4- > 693 fs    720.44 10 E1 9.39×10-4B(E1)(W.u.)<7.2E-5, α=9.39E-4, α(K)=0.000822 12, α(L)=9.57E-5 14, α(M)=1.83E-5 3, α(N)=3.25E-6 5, α(O)=1.89E-7 3
4- > 693 fs   1175.50 10 E1 3.84×10-4B(E1)(W.u.)<0.00014, α=3.84E-4, α(K)=0.000315 5, α(L)=3.63E-5 5, α(M)=6.92E-6 10, α(N)=1.235E-6 18, α(O)=7.28E-8 11
E(level)
(keV)
Jπ(level)T1/2(level)E(γ)
(keV)
MultipolarityMixing
Ratio
Conversion
Coefficient
Additional Data
  2634.99 3+      570.5 1 M1+E2 0.00485α=0.00485, α(K)=0.00423 6, α(L)=0.000504 7, α(M)=9.66×10-5 14, α(N)=1.725E-5 25, α(O)=1.015E-6 15
3+      629.80 10 E1 1.26×10-3α=1.26×10-3, α(K)=0.001099 16, α(L)=0.0001285 18, α(M)=2.45E-5 4, α(N)=4.37E-6 7, α(O)=2.52E-7 4
3+     1219.4 1 M1+E2 8.69×10-4α=8.69×10-4, α(K)=0.000753 11, α(L)=8.79E-5 13, α(M)=1.680E-5 24, α(N)=3.00E-6 5, α(O)=1.79E-7 3
3+     1322.59 10 M1+E2-1.37 +16-156.88×10-4α=6.88×10-4 11, α(K)=0.000577 10, α(L)=6.78E-5 11, α(M)=1.297E-5 21, α(N)=2.31E-6 4, α(O)=1.358E-7 23
3+     2017.5 1 M1+E2 5.94×10-4α=5.94×10-4, α(K)=0.000264 4, α(L)=3.05E-5 5, α(M)=5.83E-6 9, α(N)=1.042E-6 15, α(O)=6.25E-8 9
  2650.15 0+ 0.23 ps +12-6    1337.75 11 E2 6.46×10-4B(E2)(W.u.)=2.2 +7-12, α=6.46E-4, α(K)=0.000536 8, α(L)=6.32E-5 9, α(M)=1.208E-5 17, α(N)=2.15E-6 3, α(O)=1.252E-7 18
0+ 0.23 ps +12-6    2032.62 10 E2 5.92×10-4B(E2)(W.u.)=1.9 +5-11, α=5.92E-4, α(K)=0.000240 4, α(L)=2.78E-5 4, α(M)=5.30E-6 8, α(N)=9.47E-7 14, α(O)=5.61E-8 8
  2665.64 5+ > 208 fs    583.92 10 M1+E2+0.30 40.00456B(E2)(W.u.)<48, B(M1)(W.u.)<0.19, α=0.00456, α(K)=0.00398 6, α(L)=0.000477 7, α(M)=9.13E-5 13, α(N)=1.630E-5 23, α(O)=9.52E-7 14
5+ > 208 fs    601.01 10 E2 0.00399B(E2)(W.u.)<2.4×102, α=0.00399, α(K)=0.00345 5, α(L)=0.000439 7, α(M)=8.44E-5 12, α(N)=1.490E-5 21, α(O)=7.91E-7 11
5+ > 208 fs    795.08 13 M1(+E2)+0.14 +18-170.00223B(E2)(W.u.)<2.7, B(M1)(W.u.)<0.033, α=0.00223, α(K)=0.00194 4, α(L)=0.000230 4, α(M)=4.39E-5 7, α(N)=7.85E-6 13, α(O)=4.64E-7 9
5+ > 208 fs   1250.17 10 M1+E2-0.12 +6-58.26×10-4B(E2)(W.u.)<0.19, B(M1)(W.u.)<0.013, α=8.26E-4, α(K)=0.000712 10, α(L)=8.31E-5 12, α(M)=1.588E-5 23, α(N)=2.84E-6 4, α(O)=1.692E-7 24
  2668.92 (2)- 0.21 ps 3     663.59 15 M1+E2+1.3 +23-80.00319B(E2)(W.u.)=21 +29-21, B(M1)(W.u.)=0.007 +16-7, α=0.00319 15, α(K)=0.00277 14, α(L)=0.000340 9, α(M)=6.53E-5 17, α(N)=1.16E-5 4, α(O)=6.5E-7 5
(2)- 0.21 ps 3    1356.52 10 E1 4.08×10-4B(E1)(W.u.)=0.00045 7, α=4.08E-4, α(K)=0.000245 4, α(L)=2.81E-5 4, α(M)=5.36E-6 8, α(N)=9.56E-7 14, α(O)=5.66E-8 8
(2)- 0.21 ps 3    2051.50 10 E1 7.86×10-4B(E1)(W.u.)=2.3E-5 4, α=7.86E-4, α(K)=0.0001249 18, α(L)=1.422E-5 20, α(M)=2.71E-6 4, α(N)=4.84E-7 7, α(O)=2.89E-8 4
  2674.00 2+ 35 fs 3    2056.48 10 M1(+E2)+0.05 +7-86.01×10-4B(E2)(W.u.)=(0.03 +10-3), B(M1)(W.u.)=(0.072 7), α=6.01E-4, α(K)=0.000254 4, α(L)=2.93E-5 5, α(M)=5.61E-6 8, α(N)=1.003E-6 14, α(O)=6.01E-8 9
  2694.0 (1) 0.72 ps 14    2694 1 M1 7.88×10-4B(M1)(W.u.)=0.0016 3, α=7.88×10-4, α(K)=0.0001505 21, α(L)=1.729E-5 25, α(M)=3.30E-6 5, α(N)=5.90E-7 9, α(O)=3.55E-8 5
  2711.19 4+ 0.26 ps +15-7     705.95 10 E1 9.80×10-4B(E1)(W.u.)=0.00019 +6-12, α=9.80E-4, α(K)=0.000858 12, α(L)=0.0001000 14, α(M)=1.91E-5 3, α(N)=3.40E-6 5, α(O)=1.97E-7 3
4+ 0.26 ps +15-7    1295.74 10 M1+E2-0.08 67.74×10-4B(E2)(W.u.)=0.11 +17-11, B(M1)(W.u.)=0.036 +10-21, α=7.74E-4, α(K)=0.000660 10, α(L)=7.69E-5 11, α(M)=1.471E-5 21, α(N)=2.63E-6 4, α(O)=1.568E-7 23
  2723.96 2+ 159 fs 24     718.89 10 E1 9.43×10-4B(E1)(W.u.)=0.00031 6, α=9.43E-4, α(K)=0.000825 12, α(L)=9.62E-5 14, α(M)=1.84E-5 3, α(N)=3.27E-6 5, α(O)=1.90E-7 3
2+ 159 fs 24    1411.8 8 [M1+E2] 6.75×10-4α=6.75×10-4, α(K)=0.000550 8, α(L)=6.40E-5 9, α(M)=1.224E-5 18, α(N)=2.19E-6 3, α(O)=1.306E-7 19
2+ 159 fs 24    2106.31 10 M1(+E2)+0.05 +6-56.12×10-4B(E2)(W.u.)=(0.006 +15-6), B(M1)(W.u.)=(0.0131 20), α=6.12E-4, α(K)=0.000242 4, α(L)=2.80E-5 4, α(M)=5.34E-6 8, α(N)=9.56E-7 14, α(O)=5.73E-8 8
2+ 159 fs 24    2723.6 3 [E2] 8.09×10-4B(E2)(W.u.)=0.027 5, α=8.09E-4, α(K)=0.0001430 20, α(L)=1.641E-5 23, α(M)=3.13E-6 5, α(N)=5.59E-7 8, α(O)=3.34E-8 5
  2765.72 2+ 34 fs 3     894.5 1 E2 1.47×10-3B(E2)(W.u.)=47 8, α=1.47E-3, α(K)=0.001280 18, α(L)=0.0001555 22, α(M)=2.98E-5 5, α(N)=5.29E-6 8, α(O)=2.98E-7 5
2+ 34 fs 3    1296.9 1 M1+E2 7.74×10-4α=7.74×10-4, α(K)=0.000659 10, α(L)=7.68E-5 11, α(M)=1.469E-5 21, α(N)=2.63E-6 4, α(O)=1.567E-7 22
2+ 34 fs 3    1453.4 1 M1+E2 6.50×10-4α=6.50×10-4, α(K)=0.000518 8, α(L)=6.02E-5 9, α(M)=1.150E-5 17, α(N)=2.06E-6 3, α(O)=1.228E-7 18
2+ 34 fs 3    2148.21 10 M1(+E2)+0.06 +7-66.22×10-4B(E2)(W.u.)=(0.03 +7-3), B(M1)(W.u.)=(0.047 5), α=6.22E-4, α(K)=0.000233 4, α(L)=2.69E-5 4, α(M)=5.14E-6 8, α(N)=9.19E-7 13, α(O)=5.51E-8 8
2+ 34 fs 3    2765.7 3 E2 8.23×10-4B(E2)(W.u.)=0.136 15, α=8.23E-4, α(K)=0.0001393 20, α(L)=1.597E-5 23, α(M)=3.05E-6 5, α(N)=5.45E-7 8, α(O)=3.25E-8 5
E(level)
(keV)
Jπ(level)T1/2(level)E(γ)
(keV)
MultipolarityMixing
Ratio
Conversion
Coefficient
Additional Data
  2773.08 (0)+ > 693 fs    541.80 10 E2 0.00530B(E2)(W.u.)<88, α=0.00530, α(K)=0.00457 7, α(L)=0.000592 9, α(M)=0.0001138 16, α(N)=2.01E-5 3, α(O)=1.044E-6 15
(0)+ > 693 fs   1460.83 10 E2 5.82×10-4B(E2)(W.u.)<3.2, α=5.82E-4, α(K)=0.000449 7, α(L)=5.27E-5 8, α(M)=1.008E-5 15, α(N)=1.80E-6 3, α(O)=1.050E-7 15
  2791.79 (4)- > 97 fs    786.59 10 M1+E2+0.038 +49-140.00229B(E2)(W.u.)<3.1, B(M1)(W.u.)<0.47, α=0.00229, α(K)=0.00200 3, α(L)=0.000236 4, α(M)=4.51E-5 7, α(N)=8.06E-6 12, α(O)=4.77E-7 7
  2793.80 7-      222.17 10 (E1) 0.01746α=0.01746, α(K)=0.01522 22, α(L)=0.00182 3, α(M)=0.000348 5, α(N)=6.15×10-5 9, α(O)=3.33E-6 5
7-      420.68 19 E2 0.01110α=0.01110, α(K)=0.00952 14, α(L)=0.001287 19, α(M)=0.000248 4, α(N)=4.35×10-5 7, α(O)=2.14E-6 3
7-      625.97 10 E1 1.27×10-3α=1.27×10-3, α(K)=0.001114 16, α(L)=0.0001302 19, α(M)=2.49E-5 4, α(N)=4.43E-6 7, α(O)=2.55E-7 4
  2816.71 4+ > 416 fs    735.20 10 M1+E2+4.0 +39-130.00238α=0.00238, α(K)=0.00207 4, α(L)=0.000255 4, α(M)=4.90×10-5 8, α(N)=8.69E-6 14, α(O)=4.79E-7 9
4+ > 416 fs    811.3 1 E1 7.33×10-4α=7.33×10-4, α(K)=0.000642 9, α(L)=7.46E-5 11, α(M)=1.423E-5 20, α(N)=2.54E-6 4, α(O)=1.477E-7 21
4+ > 416 fs   1401.3 1 M1+E2 6.82×10-4α=6.82×10-4, α(K)=0.000559 8, α(L)=6.51E-5 10, α(M)=1.243E-5 18, α(N)=2.22E-6 4, α(O)=1.327E-7 19
  2817.74 6-      247.54 10 M1(+E2)+0.03 30.0392α=0.0392, α(K)=0.0341 5, α(L)=0.00417 6, α(M)=0.000801 12, α(N)=0.0001429 21, α(O)=8.27×10-6 12
6-      444.54 10 M1+E2-0.29 +5-70.00891α=0.00891, α(K)=0.00776 11, α(L)=0.000940 15, α(M)=0.000180 3, α(N)=3.22×10-5 5, α(O)=1.86E-6 3
  2829.19 1- 27 fs 3     957.80 19 E1 5.28×10-4B(E1)(W.u.)=0.00051 9, α=5.28E-4, α(K)=0.000462 7, α(L)=5.34E-5 8, α(M)=1.019E-5 15, α(N)=1.82E-6 3, α(O)=1.065E-7 15
1- 27 fs 3    1604.6 4 [E1] 5.24×10-4B(E1)(W.u.)=6.8E-5 21, α=5.24E-4, α(K)=0.000185 3, α(L)=2.11E-5 3, α(M)=4.02E-6 6, α(N)=7.19E-7 10, α(O)=4.27E-8 6
1- 27 fs 3    2211.65 10 E1 8.80×10-4B(E1)(W.u.)=0.00052 6, α=8.80E-4, α(K)=0.0001114 16, α(L)=1.267E-5 18, α(M)=2.41E-6 4, α(N)=4.31E-7 6, α(O)=2.58E-8 4
1- 27 fs 3    2829.20 10 E1 1.22×10-3B(E1)(W.u.)=0.000195 23, α=1.22E-3, α(K)=7.77E-5 11, α(L)=8.80E-6 13, α(M)=1.677E-6 24, α(N)=3.00E-7 5, α(O)=1.79E-8 3
  2834.27 0+ > 347 fs    712.68 10 E2 0.00255B(E2)(W.u.)<36, α=0.00255, α(K)=0.00221 4, α(L)=0.000276 4, α(M)=5.29E-5 8, α(N)=9.37E-6 14, α(O)=5.12E-7 8
0+ > 347 fs   1521.82 12 E2 5.64×10-4B(E2)(W.u.)<1.1, α=5.64E-4, α(K)=0.000415 6, α(L)=4.85E-5 7, α(M)=9.28E-6 13, α(N)=1.655E-6 24, α(O)=9.69E-8 14
0+ > 347 fs   2216.74 10 E2 6.40×10-4B(E2)(W.u.)<0.65, α=6.40E-4, α(K)=0.000205 3, α(L)=2.37E-5 4, α(M)=4.52E-6 7, α(N)=8.07E-7 12, α(O)=4.80E-8 7
  2840.22 (4)+ > 485 fs   1424.73 10 M1+E2-1.28 +18-246.23×10-4B(E2)(W.u.)<4.3, B(M1)(W.u.)<0.0070, α=6.23E-4 11, α(K)=0.000498 9, α(L)=5.82E-5 10, α(M)=1.113E-5 19, α(N)=1.99E-6 4, α(O)=1.171E-7 22
  2852.90 2+ 0.44 ps +21-10    1419.6 1 E2 5.99×10-4B(E2)(W.u.)=0.42 +10-21, α=5.99E-4, α(K)=0.000475 7, α(L)=5.59E-5 8, α(M)=1.068E-5 15, α(N)=1.90E-6 3, α(O)=1.111E-7 16
2+ 0.44 ps +21-10    1540.4 1 M1+E2 6.11×10-4α=6.11×10-4, α(K)=0.000458 7, α(L)=5.32E-5 8, α(M)=1.017E-5 15, α(N)=1.82E-6 3, α(O)=1.087E-7 16
2+ 0.44 ps +21-10    2235.46 10 M1+E2-0.39 +20-256.44×10-4B(E2)(W.u.)=0.017 +16-17, B(M1)(W.u.)=0.00068 +18-34, α=6.44E-4, α(K)=0.000214 4, α(L)=2.47E-5 5, α(M)=4.71E-6 8, α(N)=8.42E-7 15, α(O)=5.04E-8 10
2+ 0.44 ps +21-10    2852.87 10 E2 8.54×10-4B(E2)(W.u.)=0.106 +25-51, α=8.54E-4, α(K)=0.0001321 19, α(L)=1.514E-5 22, α(M)=2.89E-6 4, α(N)=5.16E-7 8, α(O)=3.09E-8 5
  2866.75 3- 0.6 ps +8-2     450.75 10 M1+E2+0.73 +69-710.00873B(E2)(W.u.)=4.×101 +6-4, B(M1)(W.u.)=0.020 +15-20, α=0.00873 20, α(K)=0.00757 15, α(L)=0.00094 5, α(M)=0.000182 10, α(N)=3.22E-5 16, α(O)=1.78E-6 3
3- 0.6 ps +8-2     784.91 10 E1 7.85×10-4B(E1)(W.u.)=9.E-5 +3-9, α=7.85E-4, α(K)=0.000687 10, α(L)=7.99E-5 12, α(M)=1.524E-5 22, α(N)=2.72E-6 4, α(O)=1.580E-7 23
3- 0.6 ps +8-2     802.3 4 [E1] 7.50×10-4B(E1)(W.u.)=6.E-5 +3-6, α=7.50E-4, α(K)=0.000657 10, α(L)=7.63E-5 11, α(M)=1.456E-5 21, α(N)=2.59E-6 4, α(O)=1.511E-7 22
3- 0.6 ps +8-2     861.68 10 M1(+E2)+0.069 +89-690.00186B(E2)(W.u.)=(0.1 +4-1), B(M1)(W.u.)=(0.027 +9-27), α=0.00186, α(K)=0.001621 24, α(L)=0.000191 3, α(M)=3.66E-5 6, α(N)=6.53E-6 10, α(O)=3.87E-7 6
3- 0.6 ps +8-2    1451.30 10 E1 4.45×10-4B(E1)(W.u.)=4.8E-5 +16-48, α=4.45E-4, α(K)=0.000218 3, α(L)=2.50E-5 4, α(M)=4.77E-6 7, α(N)=8.51E-7 12, α(O)=5.04E-8 7
E(level)
(keV)
Jπ(level)T1/2(level)E(γ)
(keV)
MultipolarityMixing
Ratio
Conversion
Coefficient
Additional Data
  2867.48 (3)+ 0.09 ps +8-3    1398.64 10 M1+E2 6.84×10-4α=6.84×10-4, α(K)=0.000561 8, α(L)=6.53E-5 10, α(M)=1.249E-5 18, α(N)=2.23E-6 4, α(O)=1.333E-7 19
(3)+ 0.09 ps +8-3    1555.1 1 M1+E2 6.06×10-4α=6.06×10-4, α(K)=0.000449 7, α(L)=5.22E-5 8, α(M)=9.97E-6 14, α(N)=1.783E-6 25, α(O)=1.066E-7 15
(3)+ 0.09 ps +8-3    2249.91 10 M1+E2 6.48×10-4α=6.48×10-4, α(K)=0.000213 3, α(L)=2.45E-5 4, α(M)=4.69E-6 7, α(N)=8.38E-7 12, α(O)=5.03E-8 7
  2881.02 8+      713.23 10 E2 0.00255α=0.00255, α(K)=0.00221 3, α(L)=0.000275 4, α(M)=5.28×10-5 8, α(N)=9.36E-6 14, α(O)=5.11E-7 8
  2882.82 0+ > 693 fs    726.79 14 E2 0.00243B(E2)(W.u.)<27, α=0.00243, α(K)=0.00211 3, α(L)=0.000262 4, α(M)=5.03E-5 7, α(N)=8.91E-6 13, α(O)=4.88E-7 7
0+ > 693 fs   1413.86 10 E2 6.02×10-4B(E2)(W.u.)<2.7, α=6.02E-4, α(K)=0.000479 7, α(L)=5.63E-5 8, α(M)=1.077E-5 15, α(N)=1.92E-6 3, α(O)=1.120E-7 16
0+ > 693 fs   1570.51 14 E2 5.54×10-4B(E2)(W.u.)<0.46, α=5.54E-4, α(K)=0.000390 6, α(L)=4.56E-5 7, α(M)=8.71E-6 13, α(N)=1.554E-6 22, α(O)=9.12E-8 13
  2893.51 4+ > 416 fs    771.76 10 E2 0.00209B(E2)(W.u.)<42, α=0.00209, α(K)=0.00182 3, α(L)=0.000224 4, α(M)=4.30E-5 6, α(N)=7.63E-6 11, α(O)=4.21E-7 6
4+ > 416 fs    811.9 1 M1+E2 0.00213α=0.00213, α(K)=0.00186 3, α(L)=0.000219 3, α(M)=4.19×10-5 6, α(N)=7.50E-6 11, α(O)=4.44E-7 7
4+ > 416 fs   2276.07 10 E2 6.58×10-4B(E2)(W.u.)<0.51, α=6.58E-4, α(K)=0.000196 3, α(L)=2.26E-5 4, α(M)=4.31E-6 6, α(N)=7.70E-7 11, α(O)=4.58E-8 7
  2899.02 (3-,5-) 0.13 ps 3    1483.53 4 (E1) 4.60×10-4B(E1)(W.u.)=0.00069 16, α=4.60E-4, α(K)=0.000210 3, α(L)=2.41E-5 4, α(M)=4.59E-6 7, α(N)=8.20E-7 12, α(O)=4.86E-8 7
  2921.53 6+      840.00 10 E2 1.70×10-3α=1.70×10-3, α(K)=0.001482 21, α(L)=0.000181 3, α(M)=3.48E-5 5, α(N)=6.17E-6 9, α(O)=3.44E-7 5
6+     1505.5 3 E2 5.68×10-4α=5.68×10-4, α(K)=0.000423 6, α(L)=4.96E-5 7, α(M)=9.48E-6 14, α(N)=1.691E-6 24, α(O)=9.90E-8 14
  2924.83 4- > 139 fs    333.72 10 M1+E2-0.21 +18-170.0184B(E2)(W.u.)<6.3×102, B(M1)(W.u.)<0.80, α=0.0184 5, α(K)=0.0160 4, α(L)=0.00195 8, α(M)=0.000375 16, α(N)=6.7E-5 3, α(O)=3.84E-6 7
4- > 139 fs    551.63 10 M1+E2 0.00525α=0.00525, α(K)=0.00458 7, α(L)=0.000547 8, α(M)=0.0001048 15, α(N)=1.87×10-5 3, α(O)=1.101E-6 16
4- > 139 fs    919.58 10 M1+E2-0.22 101.59×10-3B(E2)(W.u.)<5.1, B(M1)(W.u.)<0.062, α=1.59E-3 3, α(K)=0.001392 22, α(L)=0.0001639 25, α(M)=3.14E-5 5, α(N)=5.60E-6 9, α(O)=3.32E-7 6
4- > 139 fs   1054.24 10 E1 4.40×10-4B(E1)(W.u.)<0.00034, α=4.40E-4, α(K)=0.000385 6, α(L)=4.44E-5 7, α(M)=8.48E-6 12, α(N)=1.512E-6 22, α(O)=8.88E-8 13
4- > 139 fs   1509.36 10 E1 4.73×10-4B(E1)(W.u.)<0.00014, α=4.73E-4, α(K)=0.000204 3, α(L)=2.34E-5 4, α(M)=4.46E-6 7, α(N)=7.96E-7 12, α(O)=4.72E-8 7
  2931.46 1+ 17 fs 4    1618.84 11 M1+E2 5.89×10-4α=5.89×10-4, α(K)=0.000413 6, α(L)=4.80E-5 7, α(M)=9.16E-6 13, α(N)=1.639E-6 23, α(O)=9.80E-8 14
1+ 17 fs 4    2314.12 10 M1+E2 6.66×10-4α=6.66×10-4, α(K)=0.000202 3, α(L)=2.32E-5 4, α(M)=4.43E-6 7, α(N)=7.93E-7 12, α(O)=4.76E-8 7
1+ 17 fs 4    2931.42 10 M1 8.72×10-4B(M1)(W.u.)=0.026 7, α=8.72×10-4, α(K)=0.0001284 18, α(L)=1.473E-5 21, α(M)=2.81E-6 4, α(N)=5.03E-7 7, α(O)=3.02E-8 5
  2931.97 6-      361.80 20 M1+E2 0.01480α=0.01480, α(K)=0.01289 19, α(L)=0.001558 22, α(M)=0.000299 5, α(N)=5.33×10-5 8, α(O)=3.11E-6 5
6-      558.7 1 M1+E2 0.00510α=0.00510, α(K)=0.00445 7, α(L)=0.000530 8, α(M)=0.0001016 15, α(N)=1.81×10-5 3, α(O)=1.068E-6 15
  2935.50 7-      141.69 11 M1+E2-0.52 90.230α=0.230 16, α(K)=0.193 12, α(L)=0.030 3, α(M)=0.0058 6, α(N)=0.00101 10, α(O)=4.37×10-5 19
7-      365.38 10 E2 0.01718α=0.01718, α(K)=0.01467 21, α(L)=0.00204 3, α(M)=0.000395 6, α(N)=6.90×10-5 10, α(O)=3.25E-6 5
7-      562.39 10 (E2) 0.00478α=0.00478, α(K)=0.00413 6, α(L)=0.000531 8, α(M)=0.0001021 15, α(N)=1.80×10-5 3, α(O)=9.44E-7 14
7-      767.65 10 E1 8.22×10-4α=8.22×10-4, α(K)=0.000719 10, α(L)=8.37E-5 12, α(M)=1.597E-5 23, α(N)=2.84E-6 4, α(O)=1.653E-7 24
E(level)
(keV)
Jπ(level)T1/2(level)E(γ)
(keV)
MultipolarityMixing
Ratio
Conversion
Coefficient
Additional Data
  2944.94 2+ 0.4 ps +3-1    2327.44 10 M1+E2+1.4 +11-146.73×10-4B(E2)(W.u.)=0.25 +15-23, B(M1)(W.u.)=0.0009 +10-9, α=6.73E-4, α(K)=0.000192 8, α(L)=2.21E-5 9, α(M)=4.22E-6 18, α(N)=7.5E-7 4, α(O)=4.50E-8 22
2+ 0.4 ps +3-1    2944.78 10 E2 8.87×10-4B(E2)(W.u.)=0.084 +22-64, α=8.87E-4, α(K)=0.0001252 18, α(L)=1.433E-5 20, α(M)=2.73E-6 4, α(N)=4.89E-7 7, α(O)=2.92E-8 4
  2947.76 (2,3)+ 83 fs 24    2330.22 10 M1+E2-3.6 +10-166.75×10-4B(E2)(W.u.)=2.9 9, B(M1)(W.u.)=0.0015 9, α=6.75E-4, α(K)=0.000189 3, α(L)=2.17E-5 4, α(M)=4.15E-6 6, α(N)=7.41E-7 11, α(O)=4.41E-8 7
  2961.92 4-      370.86 10 M1(+E2)+0.06 +15-100.01392α=0.01392 22, α(K)=0.01212 19, α(L)=0.00146 3, α(M)=0.000281 6, α(N)=5.01×10-5 10, α(O)=2.92E-6 5
4-      588.83 10 M1+E2 0.00450α=0.00450, α(K)=0.00392 6, α(L)=0.000467 7, α(M)=8.95×10-5 13, α(N)=1.598E-5 23, α(O)=9.41E-7 14
4-      956.7 1 M1+E2 1.47×10-3α=1.47×10-3, α(K)=0.001282 18, α(L)=0.0001506 21, α(M)=2.88E-5 4, α(N)=5.15E-6 8, α(O)=3.06E-7 5
4-     1546.35 10 E1 4.92×10-4α=4.92×10-4, α(K)=0.000196 3, α(L)=2.24E-5 4, α(M)=4.28E-6 6, α(N)=7.64E-7 11, α(O)=4.53E-8 7
  2970.02 (4,5)+     1554.49 16 M1+E2+0.42 125.99×10-4α=5.99×10-4 10, α(K)=0.000442 8, α(L)=5.14E-5 9, α(M)=9.81E-6 16, α(N)=1.75E-6 3, α(O)=1.046E-7 18
  2972.45 5+ 0.6 ps +11-2     804.89 10 M1+E2-2.5 +7-120.00193B(E2)(W.u.)=15 +6-15, B(M1)(W.u.)=0.0020 +12-20, α=0.00193 4, α(K)=0.00168 4, α(L)=0.000205 4, α(M)=3.92E-5 7, α(N)=6.97E-6 13, α(O)=3.91E-7 9
5+ 0.6 ps +11-2     890.77 10 M1+E2+0.17 +7-61.72×10-3B(E2)(W.u.)=0.23 +21-23, B(M1)(W.u.)=0.008 +3-8, α=1.72E-3 3, α(K)=0.001499 22, α(L)=0.000177 3, α(M)=3.38E-5 5, α(N)=6.04E-6 9, α(O)=3.58E-7 6
5+ 0.6 ps +11-2    1556.8 1 M1+E2+0.42 125.98×10-4B(E2)(W.u.)=0.31 +18-31, B(M1)(W.u.)=0.0053 +19-53, α=5.98E-4 10, α(K)=0.000441 8, α(L)=5.12E-5 9, α(M)=9.78E-6 16, α(N)=1.75E-6 3, α(O)=1.043E-7 18
  2980.85 2+ 0.14 ps 3    1512.13 17 M1+E2 6.22×10-4α=6.22×10-4, α(K)=0.000476 7, α(L)=5.53E-5 8, α(M)=1.058E-5 15, α(N)=1.89E-6 3, α(O)=1.130E-7 16
2+ 0.14 ps 3    1668.4M1+E2 5.80×10-4α=5.80×10-4, α(K)=0.000388 6, α(L)=4.50E-5 7, α(M)=8.60E-6 12, α(N)=1.539E-6 22, α(O)=9.20E-8 13
2+ 0.14 ps 3    2363.27 10 M1(+E2)-0.01 66.81×10-4B(E2)(W.u.)=(0.00014 +165-14), B(M1)(W.u.)=(0.0096 22), α=6.81E-4, α(K)=0.000193 3, α(L)=2.23E-5 4, α(M)=4.25E-6 6, α(N)=7.61E-7 11, α(O)=4.57E-8 7
  3002.06 3+ 0.19 ps +12-6     996.75 14 E1 4.89×10-4B(E1)(W.u.)=0.00026 +10-18, α=4.89E-4, α(K)=0.000428 6, α(L)=4.95E-5 7, α(M)=9.44E-6 14, α(N)=1.683E-6 24, α(O)=9.87E-8 14
3+ 0.19 ps +12-6    1586.57 10 M1+E2+0.12 65.96×10-4B(E2)(W.u.)=0.05 5, B(M1)(W.u.)=0.010 +4-7, α=5.96E-4, α(K)=0.000430 6, α(L)=4.99E-5 7, α(M)=9.54E-6 14, α(N)=1.707E-6 25, α(O)=1.020E-7 15
3+ 0.19 ps +12-6    1689.7 1 M1+E2 5.77×10-4α=5.77×10-4, α(K)=0.000378 6, α(L)=4.39E-5 7, α(M)=8.38E-6 12, α(N)=1.499E-6 21, α(O)=8.97E-8 13
3+ 0.19 ps +12-6    2384.54 11 M1+E2+8.3 +44-206.93×10-4B(E2)(W.u.)=0.55 +18-35, B(M1)(W.u.)=6.E-5 +7-6, α=6.93E-4, α(K)=0.000180 3, α(L)=2.08E-5 3, α(M)=3.96E-6 6, α(N)=7.08E-7 10, α(O)=4.22E-8 6
  3011.08 (4,5,6)-      637.89 10 M1+E2+3.5 +27-140.00342α=0.00342 6, α(K)=0.00297 6, α(L)=0.000373 6, α(M)=7.16×10-5 11, α(N)=1.267E-5 19, α(O)=6.85E-7 15
  3027.97 6+      859.83 25 M1+E2-0.39 90.00183α=0.00183, α(K)=0.00160 3, α(L)=0.000189 3, α(M)=3.62×10-5 6, α(N)=6.47E-6 10, α(O)=3.81E-7 7
6+      946.39 10 E2 1.29×10-3α=1.29×10-3, α(K)=0.001124 16, α(L)=0.0001360 19, α(M)=2.61E-5 4, α(N)=4.63E-6 7, α(O)=2.62E-7 4
  3049.08 (4+) 0.08 ps +12-3     967.63 10 [M1] 1.43×10-3B(M1)(W.u.)=0.07 +3-7, α=1.43×10-3, α(K)=0.001250 18, α(L)=0.0001468 21, α(M)=2.81E-5 4, α(N)=5.02E-6 7, α(O)=2.98E-7 5
(4+) 0.08 ps +12-3    1633.39 10 [M1] 5.86×10-4B(M1)(W.u.)=0.049 +19-49, α=5.86×10-4, α(K)=0.000406 6, α(L)=4.71E-5 7, α(M)=8.99E-6 13, α(N)=1.608E-6 23, α(O)=9.62E-8 14
  3051.19 (5)+     1635.70 10 M1+E2+0.35 +14-95.81×10-4α=5.81×10-4, α(K)=0.000400 7, α(L)=4.64E-5 8, α(M)=8.87E-6 15, α(N)=1.59E-6 3, α(O)=9.46E-8 17
  3066.23 (2,3)- > 207 fs   1753.8E1 6.09×10-4B(E1)(W.u.)<9.4E-5, α=6.09E-4, α(K)=0.0001598 23, α(L)=1.82E-5 3, α(M)=3.48E-6 5, α(N)=6.21E-7 9, α(O)=3.69E-8 6
(2,3)- > 207 fs   2448.76 10 E1 1.01×10-3B(E1)(W.u.)<6.1E-5, α=1.01E-3, α(K)=9.57E-5 14, α(L)=1.087E-5 16, α(M)=2.07E-6 3, α(N)=3.70E-7 6, α(O)=2.21E-8 3
E(level)
(keV)
Jπ(level)T1/2(level)E(γ)
(keV)
MultipolarityMixing
Ratio
Conversion
Coefficient
Additional Data
  3068.62 4+ > 555 fs   1063.49 10 E1 4.32×10-4B(E1)(W.u.)<0.00016, α=4.32E-4, α(K)=0.000379 6, α(L)=4.37E-5 7, α(M)=8.34E-6 12, α(N)=1.487E-6 21, α(O)=8.74E-8 13
4+ > 555 fs   1599.70 10 E2 5.50×10-4B(E2)(W.u.)<1.0, α=5.50E-4, α(K)=0.000376 6, α(L)=4.40E-5 7, α(M)=8.40E-6 12, α(N)=1.499E-6 21, α(O)=8.80E-8 13
4+ > 555 fs   1653.09 10 M1+E2-0.54 215.74×10-4B(E2)(W.u.)<0.15, B(M1)(W.u.)<0.0013, α=5.74E-4 10, α(K)=0.000386 8, α(L)=4.48E-5 9, α(M)=8.57E-6 17, α(N)=1.53E-6 3, α(O)=9.13E-8 20
4+ > 555 fs   1756.30 14 E2 5.47×10-4B(E2)(W.u.)<0.25, α=5.47E-4, α(K)=0.000315 5, α(L)=3.66E-5 6, α(M)=7.00E-6 10, α(N)=1.249E-6 18, α(O)=7.36E-8 11
  3075.19 (4,5)+ 0.3 ps +5-1    1659.70 10 M1+E2+0.13 55.81×10-4B(E2)(W.u.)=0.08 +7-8, B(M1)(W.u.)=0.016 +6-16, α=5.81E-4, α(K)=0.000392 6, α(L)=4.54E-5 7, α(M)=8.68E-6 13, α(N)=1.553E-6 22, α(O)=9.29E-8 14
  3081.65 2+     3081.60 19 E2 9.35×10-4α=9.35×10-4, α(K)=0.0001160 17, α(L)=1.326E-5 19, α(M)=2.53E-6 4, α(N)=4.52E-7 7, α(O)=2.71E-8 4
  3093.02 8-      157.50 10 M1+E2-0.59 180.174α=0.174 20, α(K)=0.147 15, α(L)=0.022 4, α(M)=0.0043 8, α(N)=0.00075 12, α(O)=3.30×10-5 24
8-      299.19 10 M1+E2+0.55 60.0260α=0.0260 5, α(K)=0.0225 5, α(L)=0.00289 8, α(M)=0.000557 14, α(N)=9.85×10-5 24, α(O)=5.28E-6 9
  3102.15 (2)+ 21 fs 6    3102.10 10 [E2] 9.42×10-4B(E2)(W.u.)=2.9 9, α=9.42E-4, α(K)=0.0001147 16, α(L)=1.312E-5 19, α(M)=2.50E-6 4, α(N)=4.47E-7 7, α(O)=2.68E-8 4
  3105.50 (2)+ 0.3 ps +5-1    1636.7 1 [M1] 5.85×10-4α=5.85×10-4, α(K)=0.000404 6, α(L)=4.69E-5 7, α(M)=8.96E-6 13, α(N)=1.602E-6 23, α(O)=9.58E-8 14
(2)+ 0.3 ps +5-1    1690.1 1 [E2] 5.45×10-4α=5.45×10-4, α(K)=0.000339 5, α(L)=3.95E-5 6, α(M)=7.54E-6 11, α(N)=1.345E-6 19, α(O)=7.92E-8 11
(2)+ 0.3 ps +5-1    1792.77 10 [M1] 5.72×10-4B(M1)(W.u.)=0.0042 +15-42, α=5.72×10-4, α(K)=0.000335 5, α(L)=3.88E-5 6, α(M)=7.41E-6 11, α(N)=1.326E-6 19, α(O)=7.94E-8 12
(2)+ 0.3 ps +5-1    2488.14 10 [M1] 7.19×10-4B(M1)(W.u.)=0.0032 +11-32, α=7.19×10-4, α(K)=0.0001751 25, α(L)=2.01E-5 3, α(M)=3.85E-6 6, α(N)=6.88E-7 10, α(O)=4.13E-8 6
  3109.98 (2)+ 0.13 ps +6-3    1641.14 10 [M1] 5.84×10-4B(M1)(W.u.)=0.015 +4-7, α=5.84×10-4, α(K)=0.000402 6, α(L)=4.66E-5 7, α(M)=8.91E-6 13, α(N)=1.593E-6 23, α(O)=9.52E-8 14
(2)+ 0.13 ps +6-3    2492.24 10 [M1] 7.20×10-4B(M1)(W.u.)=0.0049 +12-23, α=7.20×10-4, α(K)=0.0001746 25, α(L)=2.01E-5 3, α(M)=3.83E-6 6, α(N)=6.86E-7 10, α(O)=4.12E-8 6
(2)+ 0.13 ps +6-3    3110.01 16 [E2] 9.45×10-4B(E2)(W.u.)=0.079 +19-37, α=9.45E-4, α(K)=0.0001142 16, α(L)=1.306E-5 19, α(M)=2.49E-6 4, α(N)=4.45E-7 7, α(O)=2.67E-8 4
  3130.83 5-      714.84 10 E2 0.00253α=0.00253, α(K)=0.00220 3, α(L)=0.000274 4, α(M)=5.25×10-5 8, α(N)=9.30E-6 13, α(O)=5.08E-7 8
5-     1125.78 10 E2 8.81×10-4α=8.81×10-4, α(K)=0.000767 11, α(L)=9.15E-5 13, α(M)=1.751E-5 25, α(N)=3.12E-6 5, α(O)=1.79E-7 3
5-     1715.08 12 E1 5.86×10-4α=5.86×10-4, α(K)=0.0001656 24, α(L)=1.89E-5 3, α(M)=3.61E-6 5, α(N)=6.44E-7 9, α(O)=3.83E-8 6
  3133.42 1- 27 fs 5    1909.53 17 [E1] 7.02×10-4B(E1)(W.u.)=0.00043 9, α=7.02E-4, α(K)=0.0001396 20, α(L)=1.592E-5 23, α(M)=3.03E-6 5, α(N)=5.42E-7 8, α(O)=3.23E-8 5
1- 27 fs 5    3133.21 10 E1 1.35×10-3B(E1)(W.u.)=0.00025 5, α=1.35E-3, α(K)=6.73E-5 10, α(L)=7.62E-6 11, α(M)=1.451E-6 21, α(N)=2.59E-7 4, α(O)=1.554E-8 22
  3145.28 3+,4+,5+ 0.13 ps +5-3    1063.6 1 M1+E2 1.16×10-3α=1.16×10-3, α(K)=0.001014 15, α(L)=0.0001188 17, α(M)=2.27E-5 4, α(N)=4.06E-6 6, α(O)=2.42E-7 4
3+,4+,5+ 0.13 ps +5-3    1729.82 10 M1+E2-0.43 +11-125.69×10-4B(E2)(W.u.)=1.4 +7-8, B(M1)(W.u.)=0.028 +7-11, α=5.69E-4 9, α(K)=0.000355 6, α(L)=4.11E-5 7, α(M)=7.86E-6 13, α(N)=1.405E-6 23, α(O)=8.39E-8 14
  3163.51 2+ 0.26 ps +12-7     656.74 10 E1 1.15×10-3B(E1)(W.u.)=0.0025 +7-12, α=1.15E-3, α(K)=0.001002 14, α(L)=0.0001171 17, α(M)=2.23E-5 4, α(N)=3.98E-6 6, α(O)=2.30E-7 4
2+ 0.26 ps +12-7    3163.4 3 E2 9.64×10-4B(E2)(W.u.)=0.079 +25-39, α=9.64E-4, α(K)=0.0001110 16, α(L)=1.269E-5 18, α(M)=2.42E-6 4, α(N)=4.33E-7 6, α(O)=2.59E-8 4
E(level)
(keV)
Jπ(level)T1/2(level)E(γ)
(keV)
MultipolarityMixing
Ratio
Conversion
Coefficient
Additional Data
  3165.46 4-,5-,6-      792.27 10 M1+E2 0.00225α=0.00225, α(K)=0.00196 3, α(L)=0.000232 4, α(M)=4.44×10-5 7, α(N)=7.93E-6 12, α(O)=4.70E-7 7
  3169.46 2+ 146 fs 14    1164.2 1 E1 3.86×10-4α=3.86×10-4, α(K)=0.000321 5, α(L)=3.69E-5 6, α(M)=7.04E-6 10, α(N)=1.257E-6 18, α(O)=7.41E-8 11
2+ 146 fs 14    1945.14 17 E2 5.72×10-4B(E2)(W.u.)=1.80 20, α=5.72E-4, α(K)=0.000260 4, α(L)=3.02E-5 5, α(M)=5.76E-6 8, α(N)=1.028E-6 15, α(O)=6.09E-8 9
2+ 146 fs 14    2552.01 10 M1+E2-0.68 +13-207.43×10-4B(E2)(W.u.)=0.20 6, B(M1)(W.u.)=0.0035 6, α=7.43E-4, α(K)=0.0001647 25, α(L)=1.89E-5 3, α(M)=3.61E-6 6, α(N)=6.46E-7 10, α(O)=3.87E-8 6
2+ 146 fs 14    3170.0 15 [E2] 9.66×10-4B(E2)(W.u.)=0.0085 9, α=9.66E-4, α(K)=0.0001106 16, α(L)=1.264E-5 18, α(M)=2.41E-6 4, α(N)=4.31E-7 6, α(O)=2.58E-8 4
  3176.47 8+      295.19 14 M1+E2-0.14 100.0250α=0.0250 5, α(K)=0.0217 4, α(L)=0.00266 7, α(M)=0.000511 14, α(N)=9.10×10-5 23, α(O)=5.25E-6 9
8+      604.98 10 E2 0.00392α=0.00392, α(K)=0.00339 5, α(L)=0.000431 6, α(M)=8.28×10-5 12, α(N)=1.463E-5 21, α(O)=7.78E-7 11
  3176.83 (4)+     2559.28 13 E2 7.52×10-4α=7.52×10-4, α(K)=0.0001593 23, α(L)=1.83E-5 3, α(M)=3.49E-6 5, α(N)=6.24E-7 9, α(O)=3.72E-8 6
  3178.79 2+ 104 fs 24    2561.23 10 M1+E2 7.43×10-4α=7.43×10-4, α(K)=0.0001657 24, α(L)=1.90E-5 3, α(M)=3.64E-6 5, α(N)=6.51E-7 10, α(O)=3.91E-8 6
2+ 104 fs 24    3178.76 10 E2 9.70×10-4B(E2)(W.u.)=0.14 4, α=9.70E-4, α(K)=0.0001101 16, α(L)=1.259E-5 18, α(M)=2.40E-6 4, α(N)=4.29E-7 6, α(O)=2.57E-8 4
  3194.46 (2)+ 0.10 ps 4    1189.41 10 [E1] 3.83×10-4B(E1)(W.u.)=0.0006 3, α=3.83E-4, α(K)=0.000309 5, α(L)=3.55E-5 5, α(M)=6.77E-6 10, α(N)=1.209E-6 17, α(O)=7.13E-8 10
(2)+ 0.10 ps 4    1882.1 1 [M1] 5.76×10-4α=5.76×10-4, α(K)=0.000304 5, α(L)=3.51E-5 5, α(M)=6.71E-6 10, α(N)=1.200E-6 17, α(O)=7.19E-8 10
(2)+ 0.10 ps 4    2576.72 10 [M1] 7.48×10-4B(M1)(W.u.)=0.008 4, α=7.48×10-4, α(K)=0.0001638 23, α(L)=1.88E-5 3, α(M)=3.59E-6 5, α(N)=6.43E-7 9, α(O)=3.86E-8 6
  3201.32 5- 0.5 ps +5-2    1196.21 19 E2 7.80×10-4B(E2)(W.u.)=14 +6-14, α=7.80E-4, α(K)=0.000675 10, α(L)=8.01E-5 12, α(M)=1.533E-5 22, α(N)=2.73E-6 4, α(O)=1.576E-7 22
5- 0.5 ps +5-2    1785.8 1 E1 6.28×10-4α=6.28×10-4, α(K)=0.0001552 22, α(L)=1.771E-5 25, α(M)=3.38E-6 5, α(N)=6.03E-7 9, α(O)=3.59E-8 5
  3203.25 (2,3)+ 0.12 ps +9-4    2585.70 10 (M1+E2)-0.10 +5-67.51×10-4B(E2)(W.u.)=(0.013 +14-13), B(M1)(W.u.)=(0.011 +4-8), α=7.51E-4, α(K)=0.0001626 23, α(L)=1.87E-5 3, α(M)=3.57E-6 5, α(N)=6.38E-7 9, α(O)=3.83E-8 6
  3206.48 (4)+ 76 fs 24    1084.93 10 [E2] 9.53×10-4B(E2)(W.u.)=67 22, α=9.53E-4, α(K)=0.000831 12, α(L)=9.93E-5 14, α(M)=1.90E-5 3, α(N)=3.38E-6 5, α(O)=1.94E-7 3
(4)+ 76 fs 24    2588.85 10 [E2] 7.62×10-4B(E2)(W.u.)=1.1 4, α=7.62E-4, α(K)=0.0001561 22, α(L)=1.79E-5 3, α(M)=3.42E-6 5, α(N)=6.12E-7 9, α(O)=3.65E-8 6
  3230.29 8+      349.26 10 M1+E2+0.42 200.0167α=0.0167 6, α(K)=0.0145 5, α(L)=0.00181 9, α(M)=0.000347 18, α(N)=6.2×10-5 3, α(O)=3.45E-6 7
8+      436.92 6 E1 0.00295α=0.00295, α(K)=0.00258 4, α(L)=0.000304 5, α(M)=5.81×10-5 9, α(N)=1.032E-5 15, α(O)=5.84E-7 9
8+      658.83 10 E2 0.00312α=0.00312, α(K)=0.00271 4, α(L)=0.000340 5, α(M)=6.54×10-5 10, α(N)=1.156E-5 17, α(O)=6.24E-7 9
  3231.59 1+ 35 fs 4    1919.4 1 M1+E2 5.80×10-4α=5.80×10-4, α(K)=0.000292 4, α(L)=3.37E-5 5, α(M)=6.45E-6 9, α(N)=1.153E-6 17, α(O)=6.91E-8 10
1+ 35 fs 4    2614.02 14 M1+E2 7.61×10-4α=7.61×10-4, α(K)=0.0001594 23, α(L)=1.83E-5 3, α(M)=3.50E-6 5, α(N)=6.25E-7 9, α(O)=3.76E-8 6
1+ 35 fs 4    3231.35 10 M1 9.79×10-4B(M1)(W.u.)=0.0134 16, α=9.79×10-4, α(K)=0.0001073 15, α(L)=1.229E-5 18, α(M)=2.35E-6 4, α(N)=4.20E-7 6, α(O)=2.52E-8 4
  3239.04 7+      573.31 10 E2 0.00453α=0.00453, α(K)=0.00392 6, α(L)=0.000502 7, α(M)=9.66×10-5 14, α(N)=1.704E-5 24, α(O)=8.97E-7 13
7+      668.18 18 M1+E2+2.6 100.00305α=0.00305 7, α(K)=0.00265 6, α(L)=0.000330 6, α(M)=6.33×10-5 11, α(N)=1.122E-5 19, α(O)=6.14E-7 17
7+     1071.24 10 E2(+M1)-7.2 259.83×10-4α=9.83×10-4 15, α(K)=0.000857 13, α(L)=0.0001025 15, α(M)=1.96E-5 3, α(N)=3.49E-6 5, α(O)=2.00E-7 3
E(level)
(keV)
Jπ(level)T1/2(level)E(γ)
(keV)
MultipolarityMixing
Ratio
Conversion
Coefficient
Additional Data
  3242.64 2+ 0.2 ps +3-1    1161.08 12 E2 8.27×10-4B(E2)(W.u.)=16 +9-16, α=8.27E-4, α(K)=0.000719 10, α(L)=8.55E-5 12, α(M)=1.636E-5 23, α(N)=2.91E-6 4, α(O)=1.677E-7 24
2+ 0.2 ps +3-1    2625.07 10 M1+E2+1.9 +15-97.72×10-4B(E2)(W.u.)=0.20 +13-20, B(M1)(W.u.)=0.0005 +7-5, α=7.72E-4 12, α(K)=0.000154 3, α(L)=1.76E-5 4, α(M)=3.37E-6 6, α(N)=6.02E-7 11, α(O)=3.60E-8 7
2+ 0.2 ps +3-1    3242.49 10 E2 9.92×10-4B(E2)(W.u.)=0.06 +4-6, α=9.92E-4, α(K)=0.0001065 15, α(L)=1.217E-5 17, α(M)=2.32E-6 4, α(N)=4.15E-7 6, α(O)=2.49E-8 4
  3248.25 7-      155.21 10 M1+E2+0.18 120.142α=0.142 10, α(K)=0.123 8, α(L)=0.0158 18, α(M)=0.0030 4, α(N)=0.00054 6, α(O)=2.96×10-5 12
7-      312.94 10 M1(+E2)-0.1 10.0214α=0.0214 4, α(K)=0.0187 3, α(L)=0.00227 5, α(M)=0.000436 10, α(N)=7.78×10-5 16, α(O)=4.51E-6 7
7-      316.19 10 M1+E2+0.28 40.0213α=0.0213 4, α(K)=0.0185 3, α(L)=0.00228 4, α(M)=0.000439 8, α(N)=7.81×10-5 14, α(O)=4.43E-6 7
  3251.86 (0)+ < 0.8 ps   2634.31 13 E2 7.77×10-4B(E2)(W.u.)>0.17, α=7.77E-4, α(K)=0.0001515 22, α(L)=1.739E-5 25, α(M)=3.32E-6 5, α(N)=5.93E-7 9, α(O)=3.54E-8 5
  3252.55 (6,7,8)-      458.75 10 M1(+E2)-0.02 50.00821α=0.00821, α(K)=0.00716 10, α(L)=0.000859 12, α(M)=0.0001647 23, α(N)=2.94×10-5 5, α(O)=1.723E-6 25
  3254.30 (3,4)+ 57 fs 17    1249.01 10 E1 3.86×10-4B(E1)(W.u.)=0.0017 5, α=3.86E-4, α(K)=0.000283 4, α(L)=3.25E-5 5, α(M)=6.20E-6 9, α(N)=1.107E-6 16, α(O)=6.53E-8 10
(3,4)+ 57 fs 17    1838.89 10 M1+E2+3.1 +30-115.57×10-4B(E2)(W.u.)=4.8 18, B(M1)(W.u.)=0.0021 +38-21, α=5.57E-4, α(K)=0.000292 6, α(L)=3.38E-5 6, α(M)=6.46E-6 12, α(N)=1.154E-6 21, α(O)=6.83E-8 13
  3266.54 4+ 0.19 ps 5    1851.04 10 [M1] 5.74×10-4B(M1)(W.u.)=0.018 5, α=5.74×10-4, α(K)=0.000314 5, α(L)=3.63E-5 5, α(M)=6.94E-6 10, α(N)=1.242E-6 18, α(O)=7.43E-8 11
  3291.17 7-      917.73 10 E2 1.39×10-3α=1.39×10-3, α(K)=0.001206 17, α(L)=0.0001463 21, α(M)=2.80E-5 4, α(N)=4.98E-6 7, α(O)=2.81E-7 4
7-     1123.96 15 E1 3.98×10-4α=3.98×10-4, α(K)=0.000342 5, α(L)=3.94E-5 6, α(M)=7.52E-6 11, α(N)=1.341E-6 19, α(O)=7.89E-8 11
  3318.09 9-      382.37 13 E2 0.01489α=0.01489, α(K)=0.01274 18, α(L)=0.001757 25, α(M)=0.000339 5, α(N)=5.93×10-5 9, α(O)=2.84E-6 4
9-      524.28 10 E2 0.00581α=0.00581, α(K)=0.00501 7, α(L)=0.000652 10, α(M)=0.0001255 18, α(N)=2.21×10-5 3, α(O)=1.143E-6 16
  3322.40 10+      145.87 10 E2 0.390α=0.390, α(K)=0.313 5, α(L)=0.0627 9, α(M)=0.01232 18, α(N)=0.00208 3, α(O)=6.18×10-5 9
10+      441.45 10 E2 0.00960α=0.00960, α(K)=0.00824 12, α(L)=0.001104 16, α(M)=0.000213 3, α(N)=3.74×10-5 6, α(O)=1.86E-6 3
  3336.03 (2)+ 0.10 ps 3    2718.48 10 [M1+E2] 7.97×10-4α=7.97×10-4, α(K)=0.0001479 21, α(L)=1.699E-5 24, α(M)=3.24E-6 5, α(N)=5.80E-7 9, α(O)=3.49E-8 5
  3341.86 (3)+ 37 fs 4    2724.31 10 E2+M1+7.4 +17-168.09×10-4B(E2)(W.u.)=3.1 4, B(M1)(W.u.)=0.00053 25, α=8.09E-4, α(K)=0.0001430 20, α(L)=1.641E-5 23, α(M)=3.13E-6 5, α(N)=5.60E-7 8, α(O)=3.34E-8 5
  3353.36 0+ 0.13 ps 4    2735.81 10 [E2] 8.13×10-4B(E2)(W.u.)=0.9 3, α=8.13E-4, α(K)=0.0001419 20, α(L)=1.628E-5 23, α(M)=3.11E-6 5, α(N)=5.55E-7 8, α(O)=3.32E-8 5
  3363.55 2+ 0.24 ps +10-6    2745.86 10 M1+E2-0.49 +15-178.08×10-4B(E2)(W.u.)=0.06 4, B(M1)(W.u.)=0.0023 +7-10, α=8.08E-4, α(K)=0.0001444 21, α(L)=1.657E-5 24, α(M)=3.16E-6 5, α(N)=5.66E-7 9, α(O)=3.40E-8 5
2+ 0.24 ps +10-6    3363.67 10 E2 1.03×10-3B(E2)(W.u.)=0.063 +16-27, α=1.03E-3, α(K)=0.0001002 14, α(L)=1.144E-5 16, α(M)=2.18E-6 3, α(N)=3.90E-7 6, α(O)=2.34E-8 4
  3376.46 7-      283.40 12 M1+E2-2.2 70.0372α=0.0372 17, α(K)=0.0316 14, α(L)=0.0046 3, α(M)=0.00089 6, α(N)=0.000155 10, α(O)=6.93×10-6 21
7-      444.53 10 M1+E2-0.37 130.00894α=0.00894 14, α(K)=0.00777 12, α(L)=0.000947 18, α(M)=0.000182 4, α(N)=3.24×10-5 6, α(O)=1.86E-6 3
  3378.52 (2)+ 0.4 ps +3-1    1909.63 10 [M1] 5.79×10-4B(M1)(W.u.)=0.0059 +15-45, α=5.79×10-4, α(K)=0.000295 5, α(L)=3.41E-5 5, α(M)=6.51E-6 10, α(N)=1.165E-6 17, α(O)=6.98E-8 10
(2)+ 0.4 ps +3-1    2761.18 14 [M1] 8.12×10-4B(M1)(W.u.)=0.00066 +18-50, α=8.12×10-4, α(K)=0.0001437 21, α(L)=1.650E-5 23, α(M)=3.15E-6 5, α(N)=5.63E-7 8, α(O)=3.38E-8 5
E(level)
(keV)
Jπ(level)T1/2(level)E(γ)
(keV)
MultipolarityMixing
Ratio
Conversion
Coefficient
Additional Data
  3398.88 8+      222.17 10 (M1) 0.0521α=0.0521, α(K)=0.0452 7, α(L)=0.00556 8, α(M)=0.001067 15, α(N)=0.000190 3, α(O)=1.099×10-5 16
8+      517.99 12 M1+E2-0.16 140.00611α=0.00611, α(K)=0.00533 8, α(L)=0.000638 10, α(M)=0.0001223 18, α(N)=2.18×10-5 4, α(O)=1.279E-6 19
8+      827.54 10 E2 1.77×10-3α=1.77×10-3, α(K)=0.001536 22, α(L)=0.000188 3, α(M)=3.61E-5 5, α(N)=6.40E-6 9, α(O)=3.57E-7 5
  3402.93 1+,2+,3+ > 527 fs   2785.37 10 M1+E2-1.8 +3-48.28×10-4B(E2)(W.u.)<0.16, B(M1)(W.u.)<0.00057, α=8.28E-4, α(K)=0.0001385 20, α(L)=1.588E-5 23, α(M)=3.03E-6 5, α(N)=5.42E-7 8, α(O)=3.24E-8 5
  3428.87 2+ 0.08 ps +5-3    2811.2 1 M1+E2 8.30×10-4α=8.30×10-4, α(K)=0.0001389 20, α(L)=1.594E-5 23, α(M)=3.04E-6 5, α(N)=5.44E-7 8, α(O)=3.27E-8 5
2+ 0.08 ps +5-3    3428.71 14 E2 1.06×10-3B(E2)(W.u.)=0.058 +23-37, α=1.06E-3, α(K)=9.71E-5 14, α(L)=1.108E-5 16, α(M)=2.11E-6 3, α(N)=3.78E-7 6, α(O)=2.27E-8 4
  3429.98 (5,6,7)     1262.21 15 D(+Q)-0.04 5 
  3451.97 (0+)      945.26 5 E1 5.41×10-4α=5.41×10-4, α(K)=0.000474 7, α(L)=5.48E-5 8, α(M)=1.046E-5 15, α(N)=1.87E-6 3, α(O)=1.092E-7 16
  3452.47 2+ 0.2 ps +4-1    2037.4 3 [E2] 5.93×10-4B(E2)(W.u.)=0.9 +5-9, α=5.93E-4, α(K)=0.000239 4, α(L)=2.77E-5 4, α(M)=5.28E-6 8, α(N)=9.43E-7 14, α(O)=5.59E-8 8
2+ 0.2 ps +4-1    2835.33 10 [M1] 8.38×10-4B(M1)(W.u.)=0.0030 +16-30, α=8.38×10-4, α(K)=0.0001367 20, α(L)=1.569E-5 22, α(M)=2.99E-6 5, α(N)=5.36E-7 8, α(O)=3.22E-8 5
2+ 0.2 ps +4-1    3452.1 4 [E2] 1.06×10-3α=1.06×10-3, α(K)=9.60E-5 14, α(L)=1.096E-5 16, α(M)=2.09E-6 3, α(N)=3.74E-7 6, α(O)=2.24E-8 4
  3487.55 (4)+ 83 fs 17    2869.99 10 E2 8.60×10-4B(E2)(W.u.)=1.09 23, α=8.60E-4, α(K)=0.0001308 19, α(L)=1.498E-5 21, α(M)=2.86E-6 4, α(N)=5.11E-7 8, α(O)=3.05E-8 5
  3493.92 (6,7)     1326.15 12 D(+Q)+0.02 3 
  3512.97 (1,2,3)+ 0.10 ps 3    2895.23 10 M1+E2-0.18 68.60×10-4B(E2)(W.u.)=0.027 20, B(M1)(W.u.)=0.009 3, α=8.60E-4, α(K)=0.0001314 19, α(L)=1.507E-5 22, α(M)=2.88E-6 4, α(N)=5.15E-7 8, α(O)=3.09E-8 5
  3528.92 7-      593.45 10 M1+E2+1.0 50.00427α=0.00427 11, α(K)=0.00371 10, α(L)=0.000457 7, α(M)=8.76×10-5 13, α(N)=1.556E-5 23, α(O)=8.7E-7 4
7-      735.08 10 M1+E2-0.11 60.00267α=0.00267, α(K)=0.00233 4, α(L)=0.000276 4, α(M)=5.28×10-5 8, α(N)=9.43E-6 14, α(O)=5.57E-7 8
  3531.32 4+ 76 fs 24    2913.77 10 M1+E2-0.18 +10-98.66×10-4B(E2)(W.u.)=0.03 +4-3, B(M1)(W.u.)=0.011 4, α=8.66E-4, α(K)=0.0001298 19, α(L)=1.489E-5 21, α(M)=2.84E-6 4, α(N)=5.08E-7 8, α(O)=3.06E-8 5
  3542.84 8+      621.41 15 E2 0.00364α=0.00364, α(K)=0.00315 5, α(L)=0.000400 6, α(M)=7.68×10-5 11, α(N)=1.358E-5 19, α(O)=7.25E-7 11
8+     1375.02 10 E2 6.22×10-4α=6.22×10-4, α(K)=0.000507 7, α(L)=5.97E-5 9, α(M)=1.141E-5 16, α(N)=2.03E-6 3, α(O)=1.185E-7 17
  3557.33 (3)- 0.07 ps 3    2939.77 10 [E1] 1.27×10-3B(E1)(W.u.)=0.00016 7, α=1.27E-3, α(K)=7.36E-5 11, α(L)=8.34E-6 12, α(M)=1.588E-6 23, α(N)=2.84E-7 4, α(O)=1.700E-8 24
  3568.05 2+ 62 fs 10    2099.17 10 M1+E2+0.29 LE6.10×10-4B(E2)(W.u.)<0.24, B(M1)(W.u.)>0.011, α=6.10E-4, α(K)=0.000243 4, α(L)=2.81E-5 4, α(M)=5.36E-6 8, α(N)=9.60E-7 14, α(O)=5.75E-8 9
2+ 62 fs 10    2950.52 12 M1+E2+1.6 +12-88.86×10-4B(E2)(W.u.)=0.32 15, B(M1)(W.u.)=0.0014 +15-14, α=8.86E-4, α(K)=0.0001254 19, α(L)=1.436E-5 22, α(M)=2.74E-6 5, α(N)=4.90E-7 8, α(O)=2.93E-8 5
2+ 62 fs 10    3568.00 10 E2 1.10×10-3B(E2)(W.u.)=0.137 25, α=1.10E-3, α(K)=9.10E-5 13, α(L)=1.038E-5 15, α(M)=1.98E-6 3, α(N)=3.54E-7 5, α(O)=2.12E-8 3
  3571.05 9-      252.88 10 M1+E2+0.82 130.0453α=0.0453 18, α(K)=0.0387 14, α(L)=0.0054 3, α(M)=0.00104 6, α(N)=0.000181 10, α(O)=8.82×10-6 24
9-      478.22 4 M1+E2-0.10 60.00742α=0.00742, α(K)=0.00647 9, α(L)=0.000776 11, α(M)=0.0001487 21, α(N)=2.66×10-5 4, α(O)=1.555E-6 22
9-      635.7 3 E2 0.00343α=0.00343, α(K)=0.00297 5, α(L)=0.000375 6, α(M)=7.21×10-5 11, α(N)=1.275E-5 18, α(O)=6.84E-7 10
9-      777.36 15 E2 0.00206α=0.00206, α(K)=0.00179 3, α(L)=0.000220 3, α(M)=4.22×10-5 6, α(N)=7.49E-6 11, α(O)=4.14E-7 6
E(level)
(keV)
Jπ(level)T1/2(level)E(γ)
(keV)
MultipolarityMixing
Ratio
Conversion
Coefficient
Additional Data
  3583.80 5,6,7     1416.03 23 D(+Q)-0.06 4 
  3598.81 1+,2+,3+ 31 fs 8    2981.25 10 M1+E2-0.16 +8-108.90×10-4B(E2)(W.u.)=0.06 6, B(M1)(W.u.)=0.026 7, α=8.90E-4, α(K)=0.0001244 18, α(L)=1.427E-5 20, α(M)=2.72E-6 4, α(N)=4.87E-7 7, α(O)=2.93E-8 5
  3613.26 1+,2+,3+ 0.10 ps +6-3    2995.85 11 M1+E2+2.0 +21-159.03×10-4B(E2)(W.u.)=0.30 +16-22, B(M1)(W.u.)=0.0008 +15-8, α=9.03E-4 14, α(K)=0.0001220 20, α(L)=1.396E-5 24, α(M)=2.66E-6 5, α(N)=4.76E-7 9, α(O)=2.85E-8 6
  3618.48 3- 0.06 ps +6-2    3000.83 18 [E1] 1.29×10-3B(E1)(W.u.)=0.00018 +6-18, α=1.29E-3, α(K)=7.15E-5 10, α(L)=8.10E-6 12, α(M)=1.542E-6 22, α(N)=2.76E-7 4, α(O)=1.651E-8 24
  3658.74 8-      340.50 15 M1+E2-0.18 40.0174α=0.0174 3, α(K)=0.01512 22, α(L)=0.00184 3, α(M)=0.000354 6, α(N)=6.31×10-5 10, α(O)=3.64E-6 6
8-      410.55 10 M1+E20.50 250.01103α=0.01103 25, α(K)=0.00957 19, α(L)=0.00118 5, α(M)=0.000227 9, α(N)=4.04×10-5 15, α(O)=2.27E-6 4
  3665.78 3- 132 fs 24    3048.22 10 [E1] 1.32×10-3B(E1)(W.u.)=7.8E-5 15, α=1.32E-3, α(K)=6.99E-5 10, α(L)=7.92E-6 11, α(M)=1.508E-6 22, α(N)=2.70E-7 4, α(O)=1.615E-8 23
  3684.02 10+      802.98 10 E2 0.00190α=0.00190, α(K)=0.001651 24, α(L)=0.000203 3, α(M)=3.89×10-5 6, α(N)=6.90E-6 10, α(O)=3.83E-7 6
  3685.55 6-,7-,8-      309.09 10 M1+E2-0.29 90.0226α=0.0226 5, α(K)=0.0196 4, α(L)=0.00243 8, α(M)=0.000468 14, α(N)=8.32×10-5 24, α(O)=4.71E-6 8
  3690.68 (4)+ 0.10 ps +11-4    3073.12 13 [E2] 9.32×10-4B(E2)(W.u.)=0.6 +3-6, α=9.32E-4, α(K)=0.0001165 17, α(L)=1.333E-5 19, α(M)=2.54E-6 4, α(N)=4.55E-7 7, α(O)=2.72E-8 4
  3736.5 8+     1165.0 3 E2 8.21×10-4α=8.21×10-4, α(K)=0.000713 10, α(L)=8.49E-5 12, α(M)=1.624E-5 23, α(N)=2.89E-6 4, α(O)=1.666E-7 24
  3739.55 (1,2,3)+ 66 fs 20    3121.99 10 M1+E2-0.32 +14-209.41×10-4B(E2)(W.u.)=0.08 8, B(M1)(W.u.)=0.010 4, α=9.41E-4, α(K)=0.0001142 16, α(L)=1.309E-5 19, α(M)=2.50E-6 4, α(N)=4.47E-7 7, α(O)=2.69E-8 4
  3743.76 (1,2,3)+ 54 fs 8    3126.22 10 M1+E2-12 +4-209.51×10-4B(E2)(W.u.)=1.09 16, B(M1)(W.u.)=9.E-5 7, α=9.51E-4, α(K)=0.0001132 16, α(L)=1.295E-5 19, α(M)=2.47E-6 4, α(N)=4.42E-7 7, α(O)=2.64E-8 4
  3755.46 (2+) 28 fs 9    3755.39 13 [E2] 1.17×10-3B(E2)(W.u.)=0.8 3, α=1.17E-3, α(K)=8.37E-5 12, α(L)=9.54E-6 14, α(M)=1.82E-6 3, α(N)=3.25E-7 5, α(O)=1.95E-8 3
  3763.95 (4)+ 104 fs 14    3146.38 10 [E2] 9.58×10-4B(E2)(W.u.)=0.55 8, α=9.58E-4, α(K)=0.0001120 16, α(L)=1.280E-5 18, α(M)=2.44E-6 4, α(N)=4.37E-7 7, α(O)=2.61E-8 4
  3783.197 (1,2,3)+ 0.2 ps +4-1    3165.631 10 M1+E2-2.7 +10-149.64×10-4B(E2)(W.u.)=0.24 +13-24, B(M1)(W.u.)=0.0004 4, α=9.64E-4, α(K)=0.0001109 16, α(L)=1.268E-5 18, α(M)=2.42E-6 4, α(N)=4.33E-7 6, α(O)=2.59E-8 4
  3787.3 2+     3787.2 3 E2 1.18×10-3α=1.18×10-3, α(K)=8.26E-5 12, α(L)=9.41E-6 14, α(M)=1.79E-6 3, α(N)=3.21E-7 5, α(O)=1.93E-8 3
  3809.39 10-      238.32 10 M1+E2 0.0433α=0.0433, α(K)=0.0376 6, α(L)=0.00461 7, α(M)=0.000885 13, α(N)=0.0001579 23, α(O)=9.13×10-6 13
10-      491.30 10 M1+E2-0.78 350.00697α=0.00697, α(K)=0.00605 9, α(L)=0.000751 19, α(M)=0.000144 4, α(N)=2.56×10-5 6, α(O)=1.42E-6 3
10-      716.38 10 E2 0.00252α=0.00252, α(K)=0.00219 3, α(L)=0.000272 4, α(M)=5.22×10-5 8, α(N)=9.25E-6 13, α(O)=5.05E-7 7
  3810.88 (3-) 0.07 ps +3-2    3193.31 10 [E1] 1.38×10-3B(E1)(W.u.)=0.00013 +4-6, α=1.38E-3, α(K)=6.55E-5 10, α(L)=7.42E-6 11, α(M)=1.413E-6 20, α(N)=2.53E-7 4, α(O)=1.514E-8 22
  3832.66 (4+) 22 fs 7    3215.09 11 [E2] 9.83×10-4B(E2)(W.u.)=2.3 8, α=9.83E-4, α(K)=0.0001080 16, α(L)=1.235E-5 18, α(M)=2.35E-6 4, α(N)=4.21E-7 6, α(O)=2.52E-8 4
  3854.4 2+     3854.3 3 E2 1.20×10-3α=1.20×10-3, α(K)=8.03E-5 12, α(L)=9.14E-6 13, α(M)=1.743E-6 25, α(N)=3.12E-7 5, α(O)=1.87E-8 3
  3913.69 9+      514.75 10 M1+E20.31 70.00620α=0.00620, α(K)=0.00540 8, α(L)=0.000651 10, α(M)=0.0001247 18, α(N)=2.22×10-5 4, α(O)=1.292E-6 19
9+      674.71 10 E2 0.00294α=0.00294, α(K)=0.00254 4, α(L)=0.000319 5, α(M)=6.13×10-5 9, α(N)=1.084E-5 16, α(O)=5.87E-7 9
9+     1032.66 10 M1(+E2)0.09 71.24×10-3α=1.24×10-3, α(K)=0.001081 16, α(L)=0.0001267 18, α(M)=2.42E-5 4, α(N)=4.33E-6 7, α(O)=2.58E-7 4
E(level)
(keV)
Jπ(level)T1/2(level)E(γ)
(keV)
MultipolarityMixing
Ratio
Conversion
Coefficient
Additional Data
  3929.21 (0)+ ≤ 0.9 ps   3311.64 21 [E2] 1.02×10-3B(E2)(W.u.)>0.049, α=1.02E-3, α(K)=0.0001028 15, α(L)=1.175E-5 17, α(M)=2.24E-6 4, α(N)=4.01E-7 6, α(O)=2.40E-8 4
  3930.78 12+      608.5 4 E2 0.00385α=0.00385, α(K)=0.00333 5, α(L)=0.000424 6, α(M)=8.15×10-5 12, α(N)=1.439E-5 21, α(O)=7.66E-7 11
  3966.44 (9,10,11)+      644.04 10 M1+E2-0.16 20.00363α=0.00363, α(K)=0.00317 5, α(L)=0.000377 6, α(M)=7.21×10-5 11, α(N)=1.288E-5 18, α(O)=7.59E-7 11
  3990.40 10+      306.23 25 M1+E2-0.50 100.0241α=0.0241 6, α(K)=0.0209 5, α(L)=0.00266 10, α(M)=0.000512 19, α(N)=9.1×10-5 4, α(O)=4.93E-6 9
10+      591.57 10 E2 0.00416α=0.00416, α(K)=0.00360 5, α(L)=0.000459 7, α(M)=8.83×10-5 13, α(N)=1.558E-5 22, α(O)=8.25E-7 12
10+      813.86 15 (E2) 0.00184α=0.00184, α(K)=0.001598 23, α(L)=0.000196 3, α(M)=3.76×10-5 6, α(N)=6.67E-6 10, α(O)=3.71E-7 6
  4033.88 (3-) 0.06 ps +5-2    3416.31 20 [E1] 1.49×10-3B(E1)(W.u.)=0.00012 +4-11, α=1.49E-3, α(K)=5.97E-5 9, α(L)=6.75E-6 10, α(M)=1.287E-6 18, α(N)=2.30E-7 4, α(O)=1.379E-8 20
  4125.91 10+      949.44 10 E2 1.28×10-3α=1.28×10-3, α(K)=0.001116 16, α(L)=0.0001349 19, α(M)=2.59E-5 4, α(N)=4.60E-6 7, α(O)=2.60E-7 4
  4174.50 10+      856.41 10 E1 6.57×10-4α=6.57×10-4, α(K)=0.000576 8, α(L)=6.68E-5 10, α(M)=1.274E-5 18, α(N)=2.27E-6 4, α(O)=1.325E-7 19
  4283.47 10+      740.63 10 E2 0.00232α=0.00232, α(K)=0.00201 3, α(L)=0.000249 4, α(M)=4.79×10-5 7, α(N)=8.48E-6 12, α(O)=4.65E-7 7
  4284.76 (9)-      908.29 10 E2 1.42×10-3α=1.42×10-3, α(K)=0.001235 18, α(L)=0.0001499 21, α(M)=2.87E-5 4, α(N)=5.10E-6 8, α(O)=2.87E-7 4
  4285.20 11-      967.10 10 E2 1.23×10-3α=1.23×10-3, α(K)=0.001071 15, α(L)=0.0001292 18, α(M)=2.48E-5 4, α(N)=4.40E-6 7, α(O)=2.49E-7 4
  4383.05 11+      452.27 10 M1(+E2)0.05 30.00850α=0.00850, α(K)=0.00741 11, α(L)=0.000890 13, α(M)=0.0001706 24, α(N)=3.05×10-5 5, α(O)=1.784E-6 25
11+     1060.63 10 M1+E20.75 300.00111α=0.00111 4, α(K)=0.00097 4, α(L)=0.000114 4, α(M)=2.18×10-5 7, α(N)=3.90E-6 12, α(O)=2.29E-7 9
  4385.16 10-     1067.06 10 M1+E20.38 101.13×10-3α=1.13×10-3 2, α(K)=0.000988 17, α(L)=0.0001161 19, α(M)=2.22E-5 4, α(N)=3.97E-6 7, α(O)=2.35E-7 4
  4467.74 11-      896.68 10 E2 1.46×10-3α=1.46×10-3, α(K)=0.001272 18, α(L)=0.0001546 22, α(M)=2.96E-5 5, α(N)=5.26E-6 8, α(O)=2.96E-7 5
  4587.15 12+      903.12 10 E2 1.44×10-3α=1.44×10-3, α(K)=0.001251 18, α(L)=0.0001520 22, α(M)=2.91E-5 4, α(N)=5.17E-6 8, α(O)=2.91E-7 4
  4687.17 11+      773.48 10 E2 0.00208α=0.00208, α(K)=0.00181 3, α(L)=0.000223 4, α(M)=4.28×10-5 6, α(N)=7.59E-6 11, α(O)=4.19E-7 6
  4871.47 14+      940.68 10 E2 1.31×10-3α=1.31×10-3, α(K)=0.001140 16, α(L)=0.0001379 20, α(M)=2.64E-5 4, α(N)=4.70E-6 7, α(O)=2.65E-7 4
  5106.22 (13)-     1175.43 10 E1 3.84×10-4α=3.84×10-4, α(K)=0.000315 5, α(L)=3.63E-5 5, α(M)=6.92E-6 10, α(N)=1.235E-6 18, α(O)=7.28E-8 11
  7633.0 1- 5.3 fs 9    4385 6 E1 0.00186B(E1)(W.u.)=3.3E-6 9, α=0.00186, α(K)=4.28E-5 6, α(L)=4.83E-6 7, α(M)=9.20E-7 13, α(N)=1.645E-7 24, α(O)=9.88E-9 14
1- 5.3 fs 9    4439 6 E1(+M2)0.6 LE0.00177B(E1)(W.u.)>4.4E-7, B(M2)(W.u.)<0.12, α=0.00177 11, α(K)=5.0E-5 8, α(L)=5.7E-6 10, α(M)=1.08E-6 18, α(N)=1.9E-7 4, α(O)=1.16E-8 19
1- 5.3 fs 9    4522E1(+M2)-0.28 GT0.0015B(E1)(W.u.)<3.5E-6, B(M2)(W.u.)>0.036, α=0.0015 4, α(K)=7.E-5 3, α(L)=8.E-6 3, α(M)=1.6E-6 6, α(N)=2.8E-7 11, α(O)=1.7E-8 7
1- 5.3 fs 9    4782 3 E1(+M2)+0.21 LE0.00197B(E1)(W.u.)>7.4E-6, B(M2)(W.u.)<0.10, α=0.00197 4, α(K)=3.93E-5 12, α(L)=4.44E-6 14, α(M)=8.4E-7 3, α(N)=1.51E-7 5, α(O)=9.1E-9 3
1- 5.3 fs 9    4800 3 E1 0.00199B(E1)(W.u.)=8.6E-6 16, α=0.00199, α(K)=3.81E-5 6, α(L)=4.29E-6 6, α(M)=8.18E-7 12, α(N)=1.462E-7 21, α(O)=8.79E-9 13
1- 5.3 fs 9    4909 2 [E1] 0.00203B(E1)(W.u.)=9.E-7 5, α=0.00203, α(K)=3.70E-5 6, α(L)=4.17E-6 6, α(M)=7.94E-7 12, α(N)=1.421E-7 20, α(O)=8.54E-9 12
1- 5.3 fs 9    5126 2 [E1] 0.00209B(E1)(W.u.)=1.7E-6 5, α=0.00209, α(K)=3.50E-5 5, α(L)=3.95E-6 6, α(M)=7.52E-7 11, α(N)=1.344E-7 19, α(O)=8.08E-9 12
1- 5.3 fs 9    5337 4 [E1] 0.00215B(E1)(W.u.)=1.8E-6 5, α=0.00215, α(K)=3.33E-5 5, α(L)=3.75E-6 6, α(M)=7.14E-7 10, α(N)=1.277E-7 18, α(O)=7.68E-9 11
1- 5.3 fs 9    5403 2 [E1] 0.00217B(E1)(W.u.)=7.E-7 4, α=0.00217, α(K)=3.28E-5 5, α(L)=3.69E-6 6, α(M)=7.03E-7 10, α(N)=1.257E-7 18, α(O)=7.56E-9 11
1- 5.3 fs 9    5477 2 [E1] 0.00219B(E1)(W.u.)=1.4E-6 5, α=0.00219, α(K)=3.22E-5 5, α(L)=3.63E-6 5, α(M)=6.91E-7 10, α(N)=1.236E-7 18, α(O)=7.43E-9 11
1- 5.3 fs 9    5512 2 [E1] 0.00220B(E1)(W.u.)=2.3E-6 6, α=0.00220, α(K)=3.20E-5 5, α(L)=3.60E-6 5, α(M)=6.86E-7 10, α(N)=1.226E-7 18, α(O)=7.37E-9 11
1- 5.3 fs 9    5551 4 [E3] 1.40×10-3B(E3)(W.u.)=10 3, α=1.40E-3, α(K)=6.29E-5 9, α(L)=7.18E-6 10, α(M)=1.370E-6 20, α(N)=2.45E-7 4, α(O)=1.475E-8 21
1- 5.3 fs 9    5763 2 E1 0.00226B(E1)(W.u.)=3.4E-5 7, α=0.00226, α(K)=3.02E-5 5, α(L)=3.41E-6 5, α(M)=6.48E-7 9, α(N)=1.159E-7 17, α(O)=6.98E-9 10
1- 5.3 fs 9    6164 2 E1(+M2)0.15 LEB(E1)(W.u.)>3.5E-6, B(M2)(W.u.)<0.015
1- 5.3 fs 9    6203 3 E1 B(E1)(W.u.)=5.1E-6 11
1- 5.3 fs 9    6409 2 E1 B(E1)(W.u.)=1.7E-5 4
1- 5.3 fs 9    7015 2 E1+M20.06 2B(E1)(W.u.)=1.9E-5 4, B(M2)(W.u.)=0.006 5
1- 5.3 fs 9    7632 1 E1 B(E1)(W.u.)=6.9E-5 13
E(level)
(keV)
Jπ(level)T1/2(level)E(γ)
(keV)
MultipolarityMixing
Ratio
Conversion
Coefficient
Additional Data

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Additional Level Data and Comments:

E(level)Jπ(level)T1/2(level)Comments
     0.00+ STABLE XREF: R(618)S(616)t(619).
E(level): Member of the gsb.
   617.5182+ 6.46 ps 4  β2=0.173 11 (1968Ma34), 0.20 1 (1968St18) and 0.19 (1967BaZV).
E(level): Member of the gsb.
  1224.3410+ 4.2 ps 11  XREF: J(1223.2)p(1250)Q(1223)t(1228).
E(level): Member of the band based on the 0+ state at 1224 keV. From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV.
  1312.3902+ 1.9 ps 3  XREF: R(1314)S(1310)W(1313).
E(level): Member of the band based on the 2+ state at 1312 keV. From 112Ag β- decay (3.130 h).
  1415.4804+ 0.87 ps 10  XREF: M(1416)Q(1414)R(1417)S(1414)V(1416).
E(level): Member of the gsb.
  1433.270+ 1.9 ns 1  XREF: B(1431.5)J(1429)Q(1431)t(1436).
  1468.8222+ 2.7 ps 5  XREF: M(1469)Q(1467)R(1470)S(1470)t(1474)V(1469).
E(level): Member of the band based on the 0+ state at 1224 keV. From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV.
  1870.684+   E(level): Member of the band based on the 0+ state at 1224 keV. From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV.
  1870.960+   XREF: J(1869.7)Q(1873)R(1872)t(1876).
  2005.2003- 0.26 ps 5  XREF: J(2000)Q(2006)S(2003)t(2009).
E(level): Member of the band based on the 3- state at 2005 keV.
  2064.533+ 0.47 ps 13  XREF: L(2064)R(2065).
E(level): Member of the band based on the 2+ state at 1312 keV. From 112Ag β- decay (3.130 h).
  2081.644+ 0.35 ps 10  XREF: J(2082)Q(2085)R(2082).
E(level): Member of the band based on the 2+ state at 1312 keV. From 112Ag β- decay (3.130 h).
  2121.622+ 0.51 ps 14  XREF: B(2124.7)J(2120.2)L(2122)Q(2123)t(2123).
  2156.182+ 0.2 ps 2  XREF: J(2155.2)Q(2162)R(2155)t(2159).
  2167.766+   XREF: L(2167).
E(level): Member of the gsb.
  2231.122+ 0.15 ps 14  XREF: J(2229.2)R(2230)t(2235).
  2300.680+ > 623 fs XREF: J(2295)M(2299)Q(2306)R(2299,2305)t(2302)V(2299).
  2373.195- 0.4 ps +6-2  β5=0.048 or 0.044 if two-step contributions through 2+ and 3- states are included (1984Pi01).
E(level): Member of the band based on the 3- state at 2005 keV.
  2402.983+ 0.24 ps +10-6  XREF: R(2402).
  2416.003- 0.15 ps 3  XREF: R(2414).
E(level): Member of the band based on the 3- state at 2415 keV.
  2418.0(1,2+) 1.29 ps 3  XREF: S(2420)t(2424).
  2454.514+ 0.35 ps +9-6  XREF: Q(2457)R(2453).
  2493.154+ 0.4 ps +4-1  XREF: M(2492)R(2491)V(2492).
  2506.36(2)+ 0.21 ps 3  XREF: L(2507)Q(2505)R(2505)t(2507).
  2506.701- 36.6 fs 19  XREF: U(2507).
E(level)Jπ(level)T1/2(level)Comments
  2532.202+   XREF: L(2533).
  2570.215- > 693 fs XREF: R(2569).
E(level): Member of the band based on the 5- state at 2570 keV.
  2571.476+ > 693 fs XREF: L(2570)M(2569)Q(2570)t(2570)V(2569).
E(level): Member of the band based on the 0+ state at 1224 keV. From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV.
  2591.054- > 693 fs XREF: H(2590)L(2589)M(2590)R(2589)V(2590).
E(level): Member of the band based on the 3- state at 2415 keV.
  2634.993+   XREF: t(2637).
  2650.150+ 0.23 ps +12-6  XREF: L(2649)p(2640)R(2649).
  26571-   XREF: L(2653).
  2665.645+ > 208 fs XREF: L(2667).
E(level): Member of the band based on the 2+ state at 1312 keV. From 112Ag β- decay (3.130 h).
  2668.92(2)- 0.21 ps 3  XREF: M(2667)Q(2671)V(2667).
  2674.002+ 35 fs 3  XREF: d(2673)γ(2673.0)L(2673)R(2673)t(2678).
  2694.0(1) 0.72 ps 14  T1/2(level): From 112Cd(γ,pol γ’).
  2711.194+ 0.26 ps +15-7  XREF: R(2710).
  2723.962+ 159 fs 24  XREF: L(2722)M(2724)Q(2718)R(2724)t(2725)V(2724).
  2765.722+ 34 fs 3  XREF: L(2763)Q(2763)t(2770).
  2773.08(0)+ > 693 fs XREF: L(2775).
  2791.79(4)- > 97 fs XREF: L(2793).
  2793.807-   E(level): Member of the band based on the 3- state at 2005 keV.
  2816.714+ > 416 fs XREF: M(2815)R(2799)V(2815).
  2817.746-   XREF: L(2819)R(2818)S(2820)t(2822).
E(level): Member of the band based on the 3- state at 2415 keV.
  2834.270+ > 347 fs XREF: J(2832.2)L(2832)Q(2829).
  2840.22(4)+ > 485 fs XREF: L(2835)M(2836)t(2840)V(2836).
  2852.902+ 0.44 ps +21-10  XREF: J(2850.1)L(2850).
  2866.753- 0.6 ps +8-2  XREF: L(2867)M(2866)Q(2865)V(2866).
  2867.48(3)+ 0.09 ps +8-3  XREF: α(2866.0)L(2877)R(2868)t(2875).
  2881.028+   E(level): Member of the gsb.
E(level)Jπ(level)T1/2(level)Comments
  2893.514+ > 416 fs XREF: L(2892)M(2895)R(2894)V(2895 ).
  2899.02(3-,5-) 0.13 ps 3  XREF: L(2897).
  2921.536+   XREF: L(2916)t(2901).
E(level): Member of the band based on the 2+ state at 1312 keV. From 112Ag β- decay (3.130 h).
  2924.834- > 139 fs XREF: L(2926).
  2928(5)-   XREF: L(2922).
  2931.461+ 17 fs 4  XREF: γ(2930.2)I(2931)R(2931).
  2931.976-   XREF: L(2932).
E(level): Member of the band based on the 5- state at 2570 keV.
  2935.507-   E(level): Member of the band based on the 5- state at 2570 keV.
  2944.942+ 0.4 ps +3-1  XREF: L(2942)M(2942)t(2936)V(2942).
  2947.76(2,3)+ 83 fs 24  XREF: L(2946,2949)R(2946).
  2962.02+   XREF: L(2967)M(2969)t(2965)V(2969).
  2980.852+ 0.14 ps 3  XREF: L(2976,2980)Q(2974)t(2988).
  3011.08(4,5,6)-   XREF: L(3022).
  3027.976+   XREF: R(3026).
  3049.08(4+) 0.08 ps +12-3  XREF: L(3046,3050).
  3051.19(5)+   XREF: L(3058).
  3066.23(2,3)- > 207 fs XREF: γ(3065.4)L(3065).
  3068.624+ > 555 fs XREF: Q(3071)R(3069).
  3071.46(4)+ > 249 fs XREF: M(3072).
  3075.19(4,5)+ 0.3 ps +5-1  XREF: d(3075.65)L(3074,3080).
  3081.652+   XREF: L(3091)R(3085).
  3093.028-   E(level): Member of the band based on the 5- state at 2570 keV.
  31024+   XREF: L(3100).
E(level): Unresolved multiplet in (p,p’) and (pol d, t).
  3102.15(2)+ 21 fs 6  XREF: R(3101).
E(level): Unresolved multiplet in (p,p’) and (pol d, t).
  3102.59(4,5)   XREF: L(3104).
E(level)Jπ(level)T1/2(level)Comments
  3105.50(2)+ 0.3 ps +5-1  XREF: Q(3108)R(3109).
  3109.98(2)+ 0.13 ps +6-3  XREF: γ(3111.3)J(3110)t(3113).
  3130.835-   XREF: L(3124,3131)M(3131)R(3128)V(3131).
  3145.283+,4+,5+ 0.13 ps +5-3  XREF: R(3146).
  3165.464-,5-,6-   XREF: L(3168).
  3178.792+ 104 fs 24  XREF: L(3177)M(3176)R(3177)t(3184)V(3176).
  3190.060+,1,2,3+ 22.2 fs 14  XREF: γ(3189.93)L(3188).
  3194.46(2)+ 0.10 ps 4  XREF: J(3193).
  3203.25(2,3)+ 0.12 ps +9-4  XREF: R(3204).
  3206.48(4)+ 76 fs 24  XREF: M(3204)V(3204).
  3231.591+ 35 fs 4  XREF: I(3231)R(3230).
  3239.047+   E(level): Member of the band based on the 2+ state at 1312 keV. From 112Ag β- decay (3.130 h).
  3242.642+ 0.2 ps +3-1  XREF: L(3246)t(3240).
  3247.17(6+)   XREF: M(3244)V(3244).
  3248.257-   E(level): Member of the band based on the 3- state at 2415 keV.
  3251.86(0)+ < 0.8 ps XREF: R(3252).
  3266.544+ 0.19 ps 5  XREF: L(3265)M(3265)R(3259)V(3265).
  3291.132+,3,4,5- 0.2 ps +5-1  XREF: L(3293)M(3292)Q(3302)V(3292).
  3297.01(2,3)+ 0.38 ps +24-11  XREF: R(3296).
  3303.24(2,3)+ 173 fs 24  XREF: t(3304).
  3312.24(1-,2) 76 fs 17  XREF: J(3309)L(3309).
  3318.099-   E(level): Member of the band based on the 3- state at 2005 keV.
  3325.96(3)-   B(E3)=0.00045 (1985De57), β3=0.0073 20 (1985De57)
XREF: V(3326).
  3329.17(5-)   XREF: M(3327)V(3327).
  3332.112+,3,4,5- 0.12 ps 3  XREF: Q(3335)R(3330).
E(level)Jπ(level)T1/2(level)Comments
  3336.03(2)+ 0.10 ps 3  XREF: R(3340).
  3341.86(3)+ 37 fs 4  XREF: t(3344)V(3344).
  3353.360+ 0.13 ps 4  XREF: L(3350)R(3352).
  3363.552+ 0.24 ps +10-6  XREF: L(3366)M(3359)Q(3365)R(3361)V(3359).
  3369.622+,3,4+ 35 fs 3  XREF: L(3372).
  3378.52(2)+ 0.4 ps +3-1  XREF: L(3380)R(3381).
  3393.45(1,2+)   XREF: Q(3393).
  3398.888+   E(level): Member of the band based on the 0+ state at 1224 keV. From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV.
  3402.931+,2+,3+ > 527 fs XREF: R(3402).
  3422.55(4)+   XREF: L(3417,3422)M(3417)Q(3415)V(3417).
  3433.73(2+:6+) 0.11 ps +6-3  XREF: R(3433).
  3452.472+ 0.2 ps +4-1  XREF: γ(3451.9).
  3455.480+,1,2 0.3 ps +3-1  XREF: L(3457).
  3487.55(4)+ 83 fs 17  XREF: V(3489).
  3489.852+,3,4+ 68 fs 13  XREF: L(3492).
  3528.927-   E(level): Member of the band based on the 3- state at 2415 keV.
  3531.324+ 76 fs 24  XREF: L(3543).
  3542.848+   E(level): Member of the band based on the 2+ state at 1312 keV. From 112Ag β- decay (3.130 h).
  3557.33(3)- 0.07 ps 3  XREF: L(3560)M(3557)V(3557).
  3571.059-   E(level): Member of the band based on the 5- state at 2570 keV.
  3594.641,2+ 76 fs 14  XREF: L(3590).
  3618.483- 0.06 ps +6-2  XREF: L(3616)M(3614)V(3614).
  3627.62+:6+   XREF: L(3625).
  3665.783- 132 fs 24  XREF: M(3664)V(3664).
  3684.0210+   E(level): Member of the gsb.
E(level)Jπ(level)T1/2(level)Comments
  3690.68(4)+ 0.10 ps +11-4  XREF: L(3691)M(3691)V(3691).
  3697.741-,2,3,4+ 0.3 ps +10-1  XREF: L(3700).
  3739.55(1,2,3)+ 66 fs 20  XREF: L(3740).
  3746.8(4)+   XREF: M(3748)V(3748).
  3763.95(4)+ 104 fs 14  XREF: M(3764)V(3764).
  3785.699-   E(level): Member of the band based on the 3- state at 2415 keV.
  3787.32+   XREF: γ(3795).
  3801.2(4)+   XREF: M(3800)V(3800).
  3809.3910-   E(level): Member of the band based on the 5- state at 2570 keV.
  3810.88(3-) 0.07 ps +3-2  XREF: M(3815)V(3815).
  3832.66(4+) 22 fs 7  XREF: M(3835)V(3835).
  3864.51(4)+   XREF: M(3863)V(3863).
  3913.699+   E(level): Member of the band based on the 2+ state at 1312 keV. From 112Ag β- decay (3.130 h).
  3929.21(0)+ ≤ 0.9 ps XREF: p(3920).
  3939.27(4)+ 0.05 fs +3-2  XREF: M(3945)V(3945).
  3951.571,2+ 43 fs 6  XREF: E(3952.25)γ(3951.43)H(3951.50).
  3970.08(1,2+) 0.05 ps +7-2  XREF: E(3969.28).
  3997.751,2+ 2.4 fs 6  XREF: γ(3996.1).
T1/2(level): From 112Cd(γ,pol γ’).
  4003.9(3-)   XREF: M(4010)V(4010).
  4033.88(3-) 0.06 ps +5-2  XREF: M(4034)V(4034).
  4283.4710+   E(level): Member of the band based on the 2+ state at 1312 keV. From 112Ag β- decay (3.130 h).
  4285.2011-   E(level): Member of the band based on the 3- state at 2005 keV.
  4385.1610-   E(level): Member of the band based on the 3- state at 2415 keV.
  4467.7411-   E(level): Member of the band based on the 5- state at 2570 keV.
  4587.1512+   E(level): Member of the gsb.
E(level)Jπ(level)T1/2(level)Comments
  4687.1711+   E(level): Member of the band based on the 2+ state at 1312 keV. From 112Ag β- decay (3.130 h).

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Additional Gamma Comments:

E(level)E(gamma)Comments
   617.518   617.517E(γ): From curved crustal spectrometer measurements in 111Cd(n,γ) E=th:secondary (1997Dr03)
M(γ): α(K)exp=0.00317 16, α(L)exp=0.00039 4, and α(M)exp=0.000138 15 in 111Cd(n,γ) E=th:secondary (1997Dr03); α(K)exp=0.0038 7 in 112In ε decay (14.88 min) (1962Ru05); A2=+0.44 2, A4=-0.05 2 from γγ(θ) in 110Pd(α,2nγ) (1997Dr03)
  1224.341   606.821M(γ): α(K)exp=0.0034 3 in 111Cd(n,γ) E=th:secondary (1997Dr03); A2=-0.02 7; A4=-0.08 10 in 110Pd(α,2nγ) (1992Ku01)
  1224.341E(γ): transition energy from level energy differences
M(γ): from ce measurements 1979Gi05, 1980Ju05 and 1997Dr03; Ice(K)(1224.341γ)/Ice(K)(606.821γ)=0.300 22, weighted average of 0.30 4 (1979Gi05), 0.33 5 (1980Ju05) and 0.29 3 (1997Dr03)
  1312.390   694.872E(γ): From curved crustal spectrometer measurements in 111Cd(n,γ) E=th:secondary (1997Dr03)
I(γ): From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
M(γ): α(K)exp=0.00242 18 in 111Cd(n,γ) E=th:secondary (1997Dr03); A2=-0.224 7; A4=0.008 10 from γγ(θ) in 110Pd(α,2nγ) (1993De09)
  1312.36I(γ): From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
M(γ): α(K)exp=0.00052 6 in 111Cd(n,γ) E=th:secondary (1997Dr03); A2=+0.46 2, A4=-0.04 3 from γγ(θ) in 110Pd(α,2nγ) (1997Dr03)
  1415.480   798.04M(γ): α(K)exp=0.00155 15 in 111Cd(n,γ) E=th:secondary (1997Dr03); A2=+0.58 4, A4=-0.15 5 from γγ(θ) in 110Pd(α,2nγ) (1997Dr03)
  1433.27   120.68E(γ): Member of the band based on the 0+ state at 1224 keV. From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
I(γ): Others: 61 10 in 112Cd(p,p’γ), but 27 4 in 110Pd(α,2nγ). From 112Ag β- decay (3.130 h)
   208.93E(γ): transition energy from level energy differences
M(γ): from α measurements in 1980Ju05 and 1997Dr03
   815.79E(γ): B(E2)(|_)=0.017 4 (1980Ju05). From curved crustal spectrometer measurements in 111Cd(n,γ) E=th:secondary (1997Dr03)
I(γ): From 112Ag β- decay (3.130 h)
  1433.27E(γ): transition energy from level energy differences
M(γ): from α measurements in 1980Ju05 and 1997Dr03
  1468.822   244.86E(γ): Member of the band based on the 0+ state at 1224 keV. From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
M(γ): from γγ(θ) in 110Pd(α,2nγ) (1997Dr03)
   851.285E(γ): From curved crustal spectrometer measurements in 111Cd(n,γ) E=th:secondary (1997Dr03)
M(γ): from α(K)exp=0.00235 18 in 111Cd(n,γ) E=th (1997Dr03) and α(K)exp=0.00234 12 in 112In ε decay (14.88 min) (1991Gi05); A2=0.50 2 from γγ(θ) in 110Pd(α,2nγ) (1997Dr03); Others: A2=0.07 7 and A4=0.03 16 in 112Ag β- decay (3.130 h) (1972Wa03)
  1468.84M(γ): α(K)exp=0.00050 7 in 111Cd(n,γ) E=th (1997Dr03). a0=15.6 2; A2=0.210 13; A4=-0.036 19 from γγ(θ) in 110Pd(α,2nγ) (1993De09)
  1870.68   401.88M(γ): A2=+0.60 2, A4=-0.10 2 in 110Pd(α,2nγ) (1997Dr03)
   455.26M(γ): A2=0.06 23, A4=-0.41 24 from γγ(θ) in 110Pd(α,2nγ) (1997Dr03)
   558.39M(γ): A2=+0.64 3, A4=-0.12 4 from γγ(θ) in 110Pd(α,2nγ) (1997Dr03)
  1253.16M(γ): A2=+0.52 4, A4=-0.15 6 from γγ(θ) in 110Pd(α,2nγ) (1997Dr03)
  1870.96   402.50M(γ): A2=+0.60 2, A4=-0.10 2 from γγ(θ) in 110Pd(α,2nγ) (1997Dr03)
   558.7I(γ): From 112Ag β- decay (3.130 h)
  1253.56M(γ): A2=0.218 42 and A4=0.990 51 in 112In ε decay (14.88 min) (1972Ka34)
  2005.200   536.31M(γ): A2=-0.17 15 from γγ(θ) in 110Pd(α,2nγ) (1997Dr03)
   692.82E(γ): From curved crustal spectrometer measurements in 111Cd(n,γ) E=th:secondary (1997Dr03)
M(γ): A2/A0=-0.046 17 in 110Pd(α,2nγ) (1993De09)
  1387.68M(γ): A2=-0.07 6 from γγ(θ) in 110Pd(α,2nγ) (1997Dr03); Also, A2=-0.11 3 and A4=-0.02 5 in 112Ag β- decay (3.130 h) (1972Wa03). Possible M2 admixture; δ=-0.06 2 from 112Ag β- decay (3.130 h)
  2064.53   648.91M(γ): A2=+0.45 7 from γγ(θ) in 110Pd(α,2nγ) (1997Dr03)
   752.14E(γ): From curved crustal spectrometer measurements in 111Cd(n,γ) E=th:secondary (1997Dr03)
M(γ): A2=0.303 6; A4=-0.092 8 from γγ(θ) in 110Pd(α,2nγ) (1993De09)
  1447.00M(γ): A2=-0.47 6, A4=+0.10 10 from γγ(θ) in 110Pd(α,2nγ) (1997Dr03)
E(level)E(gamma)Comments
  2081.64   211.0E(γ): Member of the band based on the 0+ state at 1224 keV. From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
I(γ): From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
   612.88M(γ): A2=+0.51 18, A4=-0.12 10 from γγ(θ) in 110Pd(α,2nγ) (1997Dr03)
   666.17E(γ): From curved crustal spectrometer measurements in 111Cd(n,γ) E=th:secondary (1997Dr03)
M(γ): A2=+0.36 2 from γγ(θ) in 110Pd(α,2nγ) (1997Dr03)
   769.36M(γ): A2=+0.34 16 from γγ(θ) in 110Pd(α,2nγ) (1997Dr03)
  1464.04M(γ): A2=0.11 6; A4=0.05 8 from γγ(θ) in 110Pd(α,2nγ) (1993De09)
  2121.62   688.23M(γ): A2=+0.52 19 from γγ(θ) in 110Pd(α,2nγ) (1997Dr03)
  1504.04E(γ): seen as 1507.3 keV 3 in 112In ε decay (14.97 min)
M(γ): α(K)exp=0.00030 10 in 111Cd(n,γ) E=th (1997Dr03); A2=0.16 4 from γγ(θ) in (1993De09)
  2156.18   842.8E(γ): Member of the band based on the 2+ state at 1312 keV. From 112Ag β- decay (3.130 h)
I(γ): From 112Ag β- decay (3.130 h)
  1538.68E(γ): From curved crustal spectrometer measurements in 111Cd(n,γ) E=th:secondary (1997Dr03)
M(γ): A2=-0.02 7 from γγ(θ) in 110Pd(α,2nγ) (1993De09)
  2167.76   297.29E(γ): Member of the band based on the 0+ state at 1224 keV. From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
I(γ): From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
M(γ): A2=0.37 7; A4=0.02 10 from γγ(θ) in 110Pd(α,2nγ) (1993De09)
   752.14E(γ): Member of the band based on the 0+ state at 1224 keV. From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
I(γ): From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
M(γ): A2=+0.41 5, A4=-0.11 7 from γγ(θ) in 110Pd(α,2nγ) (1997Dr03)
  2231.12   226.0E(γ): Member of the band based on the 2+ state at 1312 keV. From 112Ag β- decay (3.130 h)
I(γ): From 112Ag β- decay (3.130 h)
  1006.81M(γ): A2=0.14 14 from γγ(θ) in 110Pd(α,2nγ) (1997Dr03)
  1613.66M(γ): A2=-0.05 3 from γγ(θ) in 110Pd(α,2nγ) (1993De09)
  2373.19   291.5M(γ): A2=-0.16 13 from γγ(θ) in 110Pd(α,2nγ) (1997Dr03)
   367.9M(γ): A2=0.38 4; A4=-0.09 5 from γγ(θ) in 110Pd(α,2nγ) (1993De09)
   957.72M(γ): A2=-0.233 7 from γγ(θ) in 110Pd(α,2nγ) (1993De09)
  2402.98   934.19M(γ): A2=0.09 5 from γγ(θ) in 110Pd(α,2nγ) (1993De09)
  1785.48M(γ): A2=-0.26 4 from γγ(θ) in 110Pd(α,2nγ) (1993De09)
  2416.00   411.39I(γ): From 112Ag β- decay (3.130 h)
M(γ): A2=0.46 9; A4=0.19 13 from γγ(θ) in 110Pd(α,2nγ) (1993De09)
   983.8E(γ): Member of the band based on the 2+ state at 1312 keV. From 112Ag β- decay (3.130 h)
I(γ): From 112Ag β- decay (3.130 h)
  1103.58M(γ): A2=+0.31 14 from γγ(θ) in 110Pd(α,2nγ) (1997Dr03)
  1798.50M(γ): A2=-0.20 3 from γγ(θ) in 110Pd(α,2nγ) (1993De09)
  2418.0  2418E(γ): From 112Cd(γ, pol γ’)
  2454.51  1038.93M(γ): A2=+0.40 9 from γγ(θ) in 110Pd(α,2nγ) (1997Dr03)
E(level)E(gamma)Comments
  2493.15  1077.60M(γ): A2=+0.47 23 from γγ(θ) in 110Pd(α,2nγ) (1997Dr03)
  2506.36  1194.00M(γ): A2=-0.18 17 from γγ(θ) in 110Pd(α,2nγ) (1997Dr03)
  2506.70  1037.9E(γ): Member of the band based on the 2+ state at 1312 keV. From 112Ag β- decay (3.130 h)
I(γ): From 112Ag β- decay (3.130 h)
  1073.32E(γ): Member of the band based on the 2+ state at 1312 keV. From 112Ag β- decay (3.130 h)
I(γ): From 112Ag β- decay (3.130 h)
  2506.70M(γ): ε=-0.10 8 from polarization measurements in 112Cd(γ,pol γ’) (2005Ko32)
  2532.20  1063.56E(γ): From 111Cd(n,γ) E=th:secondary. ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV, unless value measured with a curved crustal spectrometer
I(γ): From 111Cd(n,γ) E=th:secondary. ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV, unless value measured with a curved crustal spectrometer
  1099.0E(γ): From 111Cd(n,γ) E=th:secondary. ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV, unless value measured with a curved crustal spectrometer
I(γ): From 111Cd(n,γ) E=th:secondary. ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV, unless value measured with a curved crustal spectrometer
  1116.83E(γ): From 111Cd(n,γ) E=th:secondary. ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV, unless value measured with a curved crustal spectrometer
I(γ): From 111Cd(n,γ) E=th:secondary. ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV, unless value measured with a curved crustal spectrometer
  2561.27  1248.92E(γ): From 111Cd(n,γ) E=th:secondary. ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV, unless value measured with a curved crustal spectrometer
I(γ): From 111Cd(n,γ) E=th:secondary. ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV, unless value measured with a curved crustal spectrometer
  2561.13E(γ): From 111Cd(n,γ) E=th:secondary. ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV, unless value measured with a curved crustal spectrometer
I(γ): From 111Cd(n,γ) E=th:secondary. ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV, unless value measured with a curved crustal spectrometer
  2570.21   197.03I(γ): 100 in 110Pd(α,2nγ) (1997Dr03)
M(γ): A2=+0.61 13 from γγ(θ) in 110Pd(α,2nγ) (1993De09); possible E2 admixture with δ=0.00 15 in 110Pd(α,2nγ) (1997Dr03)
   565.10M(γ): A2=0.26 7 from γγ(θ) in 110Pd(α,2nγ) (1993De09)
   699.59M(γ): A2=-0.21 5 from γγ(θ) in 110Pd(α,2nγ) (1993De09); possible M2 admixture with δ=0.02 5 in 110Pd(α,2nγ) (1993De09)
  1154.75M(γ): A2=-0.35 10 from γγ(θ) in 110Pd(α,2nγ) (1993De09); Possible M2 admixture with δ=-0.13 13 in 110Pd(α,2nγ) (1993De09)
  2571.47   403.55E(γ): Member of the band based on the 0+ state at 1224 keV. From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
I(γ): From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
M(γ): From γγ(θ) in 110Pd(α,2nγ) (1997Dr03)
   700.89E(γ): Member of the band based on the 0+ state at 1224 keV. From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
I(γ): From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
M(γ): A2=+0.13 54 from γγ(θ) in 110Pd(α,2nγ) (1997Dr03)
  1156.21E(γ): Member of the band based on the 0+ state at 1224 keV. From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
I(γ): From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
M(γ): A2=+0.68 22 from γγ(θ) in 110Pd(α,2nγ) (1997Dr03)
  2591.05   526.52M(γ): A2=-0.13 3 from γγ(θ) in 110Pd(α,2nγ) (1993De09); possible M2 admixture with δ=0.03 5 (1993De09)
   585.78M(γ): A2=0.09 6 from γγ(θ) in 110Pd(α,2nγ) (1993De09)
  1175.50M(γ): A2=0.334 18; A4=0.111 25 from γγ(θ) in 110Pd(α,2nγ) (1993De09)
  2665.64   601.01M(γ): A2=0.32 6; A4=-0.11 9 from γγ(θ) in 110Pd(α,2nγ) (1993De09)
  1250.17M(γ): A2=-0.58 5; A4=0.19 6 from γγ(θ) in 110Pd(α,2nγ) (1993De09)
  2668.92  1356.52M(γ): A2=0.05 4 from γγ(θ) in 110Pd(α,2nγ) (1993De09)
  2694.0  2694E(γ): From 112Cd(γ, pol γ’)
  2711.19  1295.74M(γ): A2=0.09 3 from γγ(θ) in 110Pd(α,2nγ) (1993De09)
E(level)E(gamma)Comments
  2723.96   718.89I(γ): 11.5 6 in 112Cd(n,n’γ). From 112Ag β- decay (3.130 h)
  1411.8E(γ): Member of the band based on the 2+ state at 1312 keV. From 112Ag β- decay (3.130 h)
I(γ): From 112Ag β- decay (3.130 h)
  2723.6E(γ): Member of the band based on the 2+ state at 1312 keV. From 112Ag β- decay (3.130 h)
I(γ): From 112Ag β- decay (3.130 h)
  2765.72  1296.9I(γ): from 110Cd(n,γ) E=th
  2793.80   222.17E(γ): Member of the band based on the 0+ state at 1224 keV. From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
I(γ): From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
M(γ): A2=-0.32 22 from γγ(θ) in 110Pd(α,2nγ) (1997Dr03)
   420.68M(γ): A2=0.323 7; A4=-0.112 10 from γγ(θ) in 110Pd(α,2nγ) (1993De09)
   625.97M(γ): A2=-0.250 6 from γγ(θ) in 110Pd(α,2nγ) (1993De09)
  2817.74   247.54E(γ): Member of the band based on the 0+ state at 1224 keV. From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
I(γ): From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
M(γ): A2=-0.18 4 from γγ(θ) in 110Pd(α,2nγ) (1993De09)
   444.54M(γ): A2=-0.73 2; A4=0.05 2 from γγ(θ) in 110Pd(α,2nγ) (1993De09)
  2829.19   957.80I(γ): From 112Ag β- decay (3.130 h)
  1604.6I(γ): From 112Ag β- decay (3.130 h)
  2840.22  1424.73M(γ): A2=-0.33 2 from γγ(θ) in 110Pd(α,2nγ) (1993De09)
  2852.90   850E(γ): From 112Cd(γ,γ’); Mult and δ based on γ(θ) in 1971Mo31, where applicable
  2866.75   802.3E(γ): Member of the band based on the 2+ state at 1312 keV. From 112Ag β- decay (3.130 h)
I(γ): From 112Ag β- decay (3.130 h)
  2881.02   713.23E(γ): Member of the band based on the 0+ state at 1224 keV. From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
I(γ): From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
M(γ): A2=0.341 9; A4=-0.121 13 from γγ(θ) in 110Pd(α,2nγ) (1993De09)
  2899.02  1483.53M(γ): A2=-0.29 3; A4=0.07 4 from γγ(θ) in 110Pd(α,2nγ) (1993De09). stretched transition; δ=+0.014 +33-30 from γ(θ) in 2001Ga44
  2921.53   840.00I(γ): From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
M(γ): A2=0.28 3; A4=-0.12 4 from γγ(θ) in 110Pd(α,2nγ) (1993De09)
  1505.5E(γ): Member of the band based on the 0+ state at 1224 keV. From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
I(γ): From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
M(γ): A2=0.13 12 from γγ(θ) in 110Pd(α,2nγ) (1993De09)
  2931.46  2931.42M(γ): ε=+0.08 10 from polarization measurements in 112Cd(γ,pol γ’) (2005Ko32)
  2931.97   361.80E(γ): Member of the band based on the 0+ state at 1224 keV. From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
M(γ): A2=-0.20 17 from γγ(θ) in 110Pd(α,2nγ) (1993De09)
   558.7M(γ): A2=+0.64 3, A4=-0.12 4 from γγ(θ) in 110Pd(α,2nγ) (1997Dr03)
  2935.50   141.69E(γ): Member of the band based on the 0+ state at 1224 keV. From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
I(γ): From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
M(γ): From γγ(θ) in 110Pd(α,2nγ) (1997Dr03)
   365.38E(γ): Member of the band based on the 0+ state at 1224 keV. From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
I(γ): From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
M(γ): A2=0.63 10; A4=-0.15 12 from γγ(θ) in 110Pd(α,2nγ) (1993De09)
   562.39E(γ): Member of the band based on the 0+ state at 1224 keV. From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
I(γ): From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
M(γ): A2=+0.24 8 (1997Dr03)
   767.65E(γ): Member of the band based on the 0+ state at 1224 keV. From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
I(γ): From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
M(γ): A2=-0.249 14 from γγ(θ) in 110Pd(α,2nγ) (1993De09)
E(level)E(gamma)Comments
  2962.0   957.1E(γ): Member of the band based on the 2+ state at 1312 keV. From 112Ag β- decay (3.130 h)
I(γ): From 112Ag β- decay (3.130 h)
  2961.7E(γ): Member of the band based on the 2+ state at 1312 keV. From 112Ag β- decay (3.130 h)
I(γ): From 112Ag β- decay (3.130 h)
  2970.02   398.57E(γ): Member of the band based on the 0+ state at 1224 keV. From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
I(γ): From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
  1554.49E(γ): Member of the band based on the 0+ state at 1224 keV. From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
I(γ): From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
M(γ): A2=0.27 3 from γγ(θ) in 110Pd(α,2nγ) (1993De09). From γγ(θ) in 110Pd(α,2nγ) (1997Dr03)
  2972.45   890.77M(γ): A2=-0.55 8 from γγ(θ) in 110Pd(α,2nγ) (1993De09)
  1556.8M(γ): A2=0.02 6 from γγ(θ) in 110Pd(α,2nγ) (1993De09). From γγ(θ) in 110Pd(α,2nγ) (1997Dr03)
  3027.97   859.83E(γ): Member of the band based on the 0+ state at 1224 keV. From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
I(γ): From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
M(γ): A2=0.15 5; A4=0.10 8 from γγ(θ) in 110Pd(α,2nγ) (1993De09). From γγ(θ) in 110Pd(α,2nγ) (1997Dr03)
   946.39E(γ): Member of the band based on the 0+ state at 1224 keV. From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
I(γ): From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
M(γ): A2=0.16 2; A4=-0.08 3 from γγ(θ) in 110Pd(α,2nγ) (1993De09)
  3075.19  1659.70M(γ): A2=-0.20 6 from γγ(θ) in 110Pd(α,2nγ) (1993De09)
  3093.02   157.50E(γ): Member of the band based on the 0+ state at 1224 keV. From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
I(γ): From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
M(γ): A2=-1.01 2; A4=0.13 3 from γγ(θ) in 110Pd(α,2nγ) (1993De09). From γγ(θ) in 110Pd(α,2nγ) (1997Dr03)
   299.19E(γ): Member of the band based on the 0+ state at 1224 keV. From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
I(γ): From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
M(γ): From γγ(θ) in 110Pd(α,2nγ) (1997Dr03)
  3133.42  1909.53E(γ): From 111Cd(n,γ) E=th:secondary. ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV, unless value measured with a curved crustal spectrometer
I(γ): From 111Cd(n,γ) E=th:secondary. ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV, unless value measured with a curved crustal spectrometer
  3133.21E(γ): From 111Cd(n,γ) E=th:secondary. ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV, unless value measured with a curved crustal spectrometer
I(γ): From 111Cd(n,γ) E=th:secondary. ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV, unless value measured with a curved crustal spectrometer
M(γ): ε=-0.13 6 from polarization measurements in 112Cd(γ,pol γ’) 2005Ko32
  3135.84  1071.26I(γ): 96 6 in 111Cd(n,γ) E=th:secondary (1997Dr03)
  1667.01E(γ): From 111Cd(n,γ) E=th:secondary. ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV, unless value measured with a curved crustal spectrometer
I(γ): From 111Cd(n,γ) E=th:secondary. ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV, unless value measured with a curved crustal spectrometer
  3163.51   656.74E(γ): From 111Cd(n,γ) E=th:secondary. ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV, unless value measured with a curved crustal spectrometer
I(γ): From 111Cd(n,γ) E=th:secondary. ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV, unless value measured with a curved crustal spectrometer
  3163.4E(γ): From 111Cd(n,γ) E=th:secondary. ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV, unless value measured with a curved crustal spectrometer
I(γ): 100 in 112Cd(n,n’γ) (2001Ga44). From 111Cd(n,γ) E=th:secondary. ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV, unless value measured with a curved crustal spectrometer
  3169.46  3170.0E(γ): Member of the band based on the 2+ state at 1312 keV. From 112Ag β- decay (3.130 h)
I(γ): From 112Ag β- decay (3.130 h)
  3176.47   295.19E(γ): Member of the band based on the 0+ state at 1224 keV. From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
I(γ): From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
M(γ): A2=0.36 3; A4=-0.02 2 from γγ(θ) in 110Pd(α,2nγ) (1993De09). From γγ(θ) in 110Pd(α,2nγ) (1997Dr03)
   382.37E(γ): Member of the band based on the 0+ state at 1224 keV. From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
I(γ): From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
M(γ): A2=+0.07 2 from γγ(θ) in 110Pd(α,2nγ) (1993De09)
   604.98E(γ): Member of the band based on the 0+ state at 1224 keV. From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
I(γ): From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
M(γ): A2=0.334 12; A4=-0.12 2 from γγ(θ) in 110Pd(α,2nγ) (1993De09)
  3230.29   349.26E(γ): Member of the band based on the 0+ state at 1224 keV. From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
I(γ): From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
M(γ): A2=0.42 3; A4=-0.03 4 from γγ(θ) in 110Pd(α,2nγ) (1993De09). From γγ(θ) in 110Pd(α,2nγ) (1997Dr03)
   436.92E(γ): Member of the band based on the 0+ state at 1224 keV. From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
I(γ): From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
M(γ): A0=3.3 1; A2/A0=0.02 10 (1993De09)
   658.83E(γ): Member of the band based on the 0+ state at 1224 keV. From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
I(γ): From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
M(γ): A2=+0.43 6 (1997Dr03)
  3231.59  1919.4I(γ): 100 in 112Ag β- decay (3.130 h) (1970Ma45)
  3231.35M(γ): ε=+0.27 12 from polarization measurements in 112Cd(γ,pol γ’) (2005Ko32)
E(level)E(gamma)Comments
  3239.04   573.31E(γ): Member of the band based on the 0+ state at 1224 keV. From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
I(γ): From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
M(γ): A2=0.34 2 from γγ(θ) in 110Pd(α,2nγ) (1993De09)
   668.18E(γ): Member of the band based on the 0+ state at 1224 keV. From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
I(γ): From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
M(γ): A2=+0.68 4 from γγ(θ) in 110Pd(α,2nγ) (1993De09). From γγ(θ) in 110Pd(α,2nγ) (1997Dr03)
  1071.24E(γ): Member of the band based on the 0+ state at 1224 keV. From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
I(γ): From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
M(γ): A2=-0.26 2; A4=0.28 3 from γγ(θ) in 110Pd(α,2nγ) (1993De09). From γγ(θ) in 110Pd(α,2nγ) (1997Dr03)
  3248.25   155.21E(γ): Member of the band based on the 0+ state at 1224 keV. From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
I(γ): From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
M(γ): a0=0.96 6; A2=-0.40 10; A4=0.15 16 from γγ(θ) in 110Pd(α,2nγ) (1993De09). From γγ(θ) in 110Pd(α,2nγ) (1997Dr03)
   312.94E(γ): Member of the band based on the 0+ state at 1224 keV. From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
I(γ): From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
M(γ): A2=0.34 1; A4=-0.01 1 from γγ(θ) in 110Pd(α,2nγ) (1993De09). From γγ(θ) in 110Pd(α,2nγ) (1997Dr03)
   316.19E(γ): Member of the band based on the 0+ state at 1224 keV. From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
I(γ): From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
M(γ): A2=0.19 2; A4=-0.02 2 from γγ(θ) in 110Pd(α,2nγ) (1993De09). From γγ(θ) in 110Pd(α,2nγ) (1997Dr03)
  3252.55   458.75E(γ): Member of the band based on the 0+ state at 1224 keV. From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
I(γ): From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
M(γ): A2=+0.39 22 (1997Dr03). From γγ(θ) in 110Pd(α,2nγ) (1997Dr03)
  3254.21  2636.62I(γ): 100 in 111Cd(n,γ) E=th:secondary (1997Dr03)
  3291.17   917.73E(γ): Member of the band based on the 0+ state at 1224 keV. From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
I(γ): From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
M(γ): A2=+0.07 2 (1997Dr03)
  1123.96E(γ): Member of the band based on the 0+ state at 1224 keV. From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
I(γ): From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
M(γ): A2=-0.23 2 from γγ(θ) in 110Pd(α,2nγ) (1993De09);
  3303.24   629.2E(γ): Member of the band based on the 2+ state at 1312 keV. From 112Ag β- decay (3.130 h)
I(γ): From 112Ag β- decay (3.130 h)
   886.99E(γ): From 111Cd(n,γ) E=th:secondary. ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV, unless value measured with a curved crustal spectrometer
I(γ): From 111Cd(n,γ) E=th:secondary. ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV, unless value measured with a curved crustal spectrometer
  2685.83E(γ): From 111Cd(n,γ) E=th:secondary. ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV, unless value measured with a curved crustal spectrometer
I(γ): From 111Cd(n,γ) E=th:secondary. ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV, unless value measured with a curved crustal spectrometer
  3318.09   382.37E(γ): Member of the band based on the 0+ state at 1224 keV. From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
I(γ): From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
   524.28E(γ): Member of the band based on the 0+ state at 1224 keV. From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
I(γ): From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
M(γ): a2=0.340 10; a4=-0.132 14 from γγ(θ) in 110Pd(α,2nγ) (1993De09)
  3322.40   145.87E(γ): Member of the band based on the 0+ state at 1224 keV. From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
I(γ): From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
   441.45E(γ): Member of the band based on the 0+ state at 1224 keV. From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
I(γ): From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
M(γ): A2=+0.72 23 (1997Dr03)
  3369.62  1952.9E(γ): Member of the band based on the 2+ state at 1312 keV. From 112Ag β- decay (3.130 h)
I(γ): From 112Ag β- decay (3.130 h)
  3375.45   439.95E(γ): Member of the band based on the 0+ state at 1224 keV. From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
I(γ): From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
M(γ): A2=-0.281 12 from γγ(θ) in 110Pd(α,2nγ) (1993De09). From γγ(θ) in 110Pd(α,2nγ) (1997Dr03)
  3376.46   283.40E(γ): Member of the band based on the 0+ state at 1224 keV. From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
I(γ): From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
M(γ): A2=0.32 6; A4=0.17 8 from γγ(θ) in 110Pd(α,2nγ) (1993De09). From γγ(θ) in 110Pd(α,2nγ) (1997Dr03)
   444.53E(γ): Member of the band based on the 0+ state at 1224 keV. From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
I(γ): From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
M(γ): A2=-0.73 2; A4=0.05 2 from γγ(θ) in 110Pd(α,2nγ) (1993De09). From γγ(θ) in 110Pd(α,2nγ) (1997Dr03)
  3393.45  2775.78E(γ): From 111Cd(n,γ) E=th:secondary. ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV, unless value measured with a curved crustal spectrometer
I(γ): From 111Cd(n,γ) E=th:secondary. ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV, unless value measured with a curved crustal spectrometer
  3393.35E(γ): From 111Cd(n,γ) E=th:secondary. ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV, unless value measured with a curved crustal spectrometer
I(γ): From 111Cd(n,γ) E=th:secondary. ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV, unless value measured with a curved crustal spectrometer
  3398.88   222.17E(γ): Member of the band based on the 0+ state at 1224 keV. From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
I(γ): From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
M(γ): A2=-0.32 22 from γγ(θ) in 110Pd(α,2nγ) (1997Dr03)
   517.99E(γ): Member of the band based on the 0+ state at 1224 keV. From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
I(γ): From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
M(γ): A2=+0.23 5from γγ(θ) in 110Pd(α,2nγ) (1997Dr03). From γγ(θ) in 110Pd(α,2nγ) (1997Dr03)
   827.54E(γ): Member of the band based on the 0+ state at 1224 keV. From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
I(γ): From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
M(γ): A2=0.316 9; A4=-0.111 12 from γγ(θ) in 110Pd(α,2nγ) (1993De09)
E(level)E(gamma)Comments
  3429.98  1262.21E(γ): Member of the band based on the 0+ state at 1224 keV. From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
I(γ): From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
M(γ): A2=-0.30 6 from γγ(θ) in 110Pd(α,2nγ) (1993De09). From γγ(θ) in 110Pd(α,2nγ) (1997Dr03)
  3452.47  3452.1E(γ): from ce in 111Cd(n,γ) E=th:secondary (1997Dr03)
  3470.3  2852.7E(γ): Member of the band based on the 2+ state at 1312 keV. From 112Ag β- decay (3.130 h)
I(γ): From 112Ag β- decay (3.130 h)
  3478.58  3479.2E(γ): From 111Cd(n,γ) E=th:secondary. ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV, unless value measured with a curved crustal spectrometer
I(γ): From 111Cd(n,γ) E=th:secondary. ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV, unless value measured with a curved crustal spectrometer
  3478.7  1322.0E(γ): Member of the band based on the 2+ state at 1312 keV. From 112Ag β- decay (3.130 h)
I(γ): From 112Ag β- decay (3.130 h)
  2863.0E(γ): Member of the band based on the 2+ state at 1312 keV. From 112Ag β- decay (3.130 h)
I(γ): From 112Ag β- decay (3.130 h)
  3493.92  1326.15E(γ): Member of the band based on the 0+ state at 1224 keV. From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
I(γ): From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
M(γ): A2=-0.21 3 from γγ(θ) in 110Pd(α,2nγ) (1993De09). From γγ(θ) in 110Pd(α,2nγ) (1997Dr03)
  3528.92   593.45E(γ): Member of the band based on the 0+ state at 1224 keV. From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
I(γ): From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
M(γ): A2=+0.51 13 from γγ(θ) in 110Pd(α,2nγ) (1997Dr03). From γγ(θ) in 110Pd(α,2nγ) (1997Dr03)
   735.08E(γ): Member of the band based on the 0+ state at 1224 keV. From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
I(γ): From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
M(γ): A2=+0.12 7 from γγ(θ) in 110Pd(α,2nγ) (1997Dr03). From γγ(θ) in 110Pd(α,2nγ) (1997Dr03)
  3540.24  3539.8E(γ): From 111Cd(n,γ) E=th:secondary. ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV, unless value measured with a curved crustal spectrometer
I(γ): From 111Cd(n,γ) E=th:secondary. ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV, unless value measured with a curved crustal spectrometer
  3542.84   621.41E(γ): Member of the band based on the 0+ state at 1224 keV. From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
I(γ): From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
M(γ): A2=0.26 10; A4=-0.26 13 from γγ(θ) in 110Pd(α,2nγ) (1993De09)
  1375.02E(γ): Member of the band based on the 0+ state at 1224 keV. From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
I(γ): From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
M(γ): A2=0.31 3; A4=-0.07 4 from γγ(θ) in 110Pd(α,2nγ) (1993De09)
  3571.05   252.88E(γ): Member of the band based on the 0+ state at 1224 keV. From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
I(γ): From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
M(γ): A2=0.28 4; A4=-0.11 5 from γγ(θ) in 110Pd(α,2nγ) (1993De09). From γγ(θ) in 110Pd(α,2nγ) (1997Dr03)
   478.22E(γ): transition seen only in 1993De09. Member of the band based on the 0+ state at 1224 keV. From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
I(γ): From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
M(γ): A0=3.74 15; A2/A0=-0.43 8 (1993De09)
   635.7E(γ): Member of the band based on the 0+ state at 1224 keV. From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
I(γ): From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
M(γ): A2=0.34 3; A4=-0.12 5 from γγ(θ) in 110Pd(α,2nγ) (1993De09)
   777.36E(γ): Member of the band based on the 0+ state at 1224 keV. From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
I(γ): From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
M(γ): A2=0.352 10; A4=-0.120 14 from γγ(θ) in 110Pd(α,2nγ) (1993De09)
  3572.28  3572.37E(γ): From 111Cd(n,γ) E=th:secondary. ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV, unless value measured with a curved crustal spectrometer
I(γ): From 111Cd(n,γ) E=th:secondary. ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV, unless value measured with a curved crustal spectrometer
  3577.55  2352.94E(γ): From 111Cd(n,γ) E=th:secondary. ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV, unless value measured with a curved crustal spectrometer
I(γ): From 111Cd(n,γ) E=th:secondary. ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV, unless value measured with a curved crustal spectrometer
  2960.13E(γ): From 111Cd(n,γ) E=th:secondary. ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV, unless value measured with a curved crustal spectrometer
I(γ): From 111Cd(n,γ) E=th:secondary. ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV, unless value measured with a curved crustal spectrometer
  3577.53E(γ): From 111Cd(n,γ) E=th:secondary. ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV, unless value measured with a curved crustal spectrometer
I(γ): From 111Cd(n,γ) E=th:secondary. ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV, unless value measured with a curved crustal spectrometer
  3583.80  1416.03E(γ): Member of the band based on the 0+ state at 1224 keV. From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
I(γ): From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
M(γ): A2=-0.13 26 from γγ(θ) in 110Pd(α,2nγ) (1997Dr03). From γγ(θ) in 110Pd(α,2nγ) (1997Dr03)
  3658.74   340.50E(γ): Member of the band based on the 0+ state at 1224 keV. From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
I(γ): From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
M(γ): A2=0.09 4 from γγ(θ) in 110Pd(α,2nγ) (1993De09). From γγ(θ) in 110Pd(α,2nγ) (1997Dr03)
   410.55E(γ): Member of the band based on the 0+ state at 1224 keV. From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
M(γ): A2=0.46 9; A4=0.19 13 from γγ(θ) in 110Pd(α,2nγ) (1993De09). From γγ(θ) in 110Pd(α,2nγ) (1997Dr03)
  3684.02   802.98E(γ): Member of the band based on the 0+ state at 1224 keV. From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
I(γ): From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
M(γ): A2=+0.53 16, A4=-0.48 20 from γγ(θ) in 110Pd(α,2nγ) (1997Dr03)
  3685.55   309.09E(γ): Member of the band based on the 0+ state at 1224 keV. From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
I(γ): From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
M(γ): A2=0.24 2; A4=-0.04 3 from γγ(θ) in 110Pd(α,2nγ) (1993De09). From γγ(θ) in 110Pd(α,2nγ) (1997Dr03)
E(level)E(gamma)Comments
  3696.15  2383.81E(γ): From 111Cd(n,γ) E=th:secondary. ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV, unless value measured with a curved crustal spectrometer
I(γ): From 111Cd(n,γ) E=th:secondary. ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV, unless value measured with a curved crustal spectrometer
  3707.45   840.71E(γ): From 111Cd(n,γ) E=th:secondary. ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV, unless value measured with a curved crustal spectrometer
I(γ): From 111Cd(n,γ) E=th:secondary. ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV, unless value measured with a curved crustal spectrometer
  2395.00E(γ): From 111Cd(n,γ) E=th:secondary. ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV, unless value measured with a curved crustal spectrometer
I(γ): From 111Cd(n,γ) E=th:secondary. ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV, unless value measured with a curved crustal spectrometer
  3090.04E(γ): From 111Cd(n,γ) E=th:secondary. ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV, unless value measured with a curved crustal spectrometer
I(γ): From 111Cd(n,γ) E=th:secondary. ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV, unless value measured with a curved crustal spectrometer
  3736.5  1165.0E(γ): Member of the band based on the 0+ state at 1224 keV. From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
I(γ): From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
M(γ): A2=0.36 7; A4=-0.04 9 from γγ(θ) in 110Pd(α,2nγ) (1993De09)
  3785.69   692.67E(γ): Member of the band based on the 0+ state at 1224 keV. From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
I(γ): From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
  3809.39   238.32E(γ): Member of the band based on the 0+ state at 1224 keV. From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
   491.30E(γ): Member of the band based on the 0+ state at 1224 keV. From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
   716.38E(γ): Member of the band based on the 0+ state at 1224 keV. From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
M(γ): A2=0.445 24; A4=-0.139 33 from γγ(θ) in 110Pd(α,2nγ) (1993De09)
  3838.85  3838.84E(γ): From 111Cd(n,γ) E=th:secondary. ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV, unless value measured with a curved crustal spectrometer
I(γ): From 111Cd(n,γ) E=th:secondary. ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV, unless value measured with a curved crustal spectrometer
  3892.48  2579.77E(γ): From 111Cd(n,γ) E=th:secondary. ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV, unless value measured with a curved crustal spectrometer
I(γ): From 111Cd(n,γ) E=th:secondary. ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV, unless value measured with a curved crustal spectrometer
  3913.69   514.75E(γ): Member of the band based on the 0+ state at 1224 keV. From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
   674.71E(γ): Member of the band based on the 0+ state at 1224 keV. From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
M(γ): A2=0.322 14; A4=-0.15 2 from γγ(θ) in 110Pd(α,2nγ) (1993De09)
  1032.66E(γ): Member of the band based on the 0+ state at 1224 keV. From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
  3930.78   608.5E(γ): Member of the band based on the 0+ state at 1224 keV. From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
I(γ): From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
M(γ): A2=0.340 16; A4=-0.139 22 from γγ(θ) in 110Pd(α,2nγ) (1993De09)
  3951.57  3333.9E(γ): a rounded off value and ΔEγ=1.0 keV set by the evaluators. From 111Cd(n,γ) E=th:secondary. ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV, unless value measured with a curved crustal spectrometer
I(γ): From 111Cd(n,γ) E=th:secondary. ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV, unless value measured with a curved crustal spectrometer
  3951.4E(γ): a rounded off value and ΔEγ=1.0 keV set by the evaluators. From 111Cd(n,γ) E=th:secondary. ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV, unless value measured with a curved crustal spectrometer
I(γ): From 111Cd(n,γ) E=th:secondary. ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV, unless value measured with a curved crustal spectrometer
  3966.44   644.04E(γ): Member of the band based on the 0+ state at 1224 keV. From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
  3970.08  3352.4E(γ): 3351.72 20 in 112Cd(n,n’γ). From 111Cd(n,γ) E=th:secondary. ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV, unless value measured with a curved crustal spectrometer
I(γ): From 111Cd(n,γ) E=th:secondary. ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV, unless value measured with a curved crustal spectrometer
  3970.0E(γ): From 111Cd(n,γ) E=th:secondary. ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV, unless value measured with a curved crustal spectrometer
I(γ): From 111Cd(n,γ) E=th:secondary. ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV, unless value measured with a curved crustal spectrometer
  3990.40   306.23E(γ): Member of the band based on the 0+ state at 1224 keV. From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
M(γ): A2=0.17 2 from γγ(θ) in 110Pd(α,2nγ) (1993De09). From γγ(θ) in 110Pd(α,2nγ) (1997Dr03)
   591.57E(γ): Member of the band based on the 0+ state at 1224 keV. From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
I(γ): From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
M(γ): A2=0.397 24; A4=-0.22 4 from γγ(θ) in 110Pd(α,2nγ) (1993De09)
   813.86E(γ): Member of the band based on the 0+ state at 1224 keV. From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
I(γ): From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
M(γ): A2=+0.25 22 from γγ(θ) in 110Pd(α,2nγ) (1997Dr03)
  3997.75  2685.83E(γ): From 111Cd(n,γ) E=th:secondary. ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV, unless value measured with a curved crustal spectrometer
I(γ): From 111Cd(n,γ) E=th:secondary. ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV, unless value measured with a curved crustal spectrometer
  3997.6E(γ): From 111Cd(n,γ) E=th:secondary. ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV, unless value measured with a curved crustal spectrometer
I(γ): From 111Cd(n,γ) E=th:secondary. ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV, unless value measured with a curved crustal spectrometer
E(level)E(gamma)Comments
  4003.9  3386.50E(γ): From 111Cd(n,γ) E=th:secondary. ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV, unless value measured with a curved crustal spectrometer
I(γ): From 111Cd(n,γ) E=th:secondary. ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV, unless value measured with a curved crustal spectrometer
  4125.91   949.44E(γ): Member of the band based on the 0+ state at 1224 keV. From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
I(γ): From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
M(γ): A2=0.33 5; A4=-0.17 7 from γγ(θ) in 110Pd(α,2nγ) (1993De09)
  4174.50   856.41E(γ): Member of the band based on the 0+ state at 1224 keV. From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
I(γ): From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
M(γ): A2=-0.39 5 from γγ(θ) in 110Pd(α,2nγ) (1993De09)
  4283.47   740.63E(γ): Member of the band based on the 0+ state at 1224 keV. From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
I(γ): From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
M(γ): A2=0.43 4; A4=-0.08 6 from γγ(θ) in 110Pd(α,2nγ) (1993De09)
  4284.76   908.29E(γ): Member of the band based on the 0+ state at 1224 keV. From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
I(γ): From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
M(γ): A2=0.27 7; A4=-0.13 10 from γγ(θ) in 110Pd(α,2nγ) (1993De09)
  4285.20   967.10E(γ): Member of the band based on the 0+ state at 1224 keV. From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
I(γ): From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
M(γ): A2=0.285 39; A4=-0.13 6 from γγ(θ) in 110Pd(α,2nγ) (1993De09)
  4383.05   452.27E(γ): Member of the band based on the 0+ state at 1224 keV. From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
M(γ): a0/A2=-0.28 10 from γγ(θ) in 110Pd(α,2nγ) (1993De09)
  1060.63E(γ): Member of the band based on the 0+ state at 1224 keV. From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
  4385.16  1067.06E(γ): Member of the band based on the 0+ state at 1224 keV. From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
I(γ): From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
  4467.74   896.68E(γ): Member of the band based on the 0+ state at 1224 keV. From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
I(γ): From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
M(γ): A2=0.364 23; A4=-0.06 3 from γγ(θ) in 110Pd(α,2nγ) (1993De09)
  4587.15   903.12E(γ): Member of the band based on the 0+ state at 1224 keV. From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
I(γ): From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
M(γ): A2=0.367 19; A4=-0.124 28 from γγ(θ) in 110Pd(α,2nγ) (1993De09)
  4687.17   773.48E(γ): Member of the band based on the 0+ state at 1224 keV. From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
I(γ): From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
M(γ): A2=0.31 6; A4=-0.09 8 from γγ(θ) in 110Pd(α,2nγ) (1993De09)
  4871.47   940.68E(γ): Member of the band based on the 0+ state at 1224 keV. From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
I(γ): From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
M(γ): A2=0.35 3; A4=-0.14 4 from γγ(θ) in 110Pd(α,2nγ) (1993De09)
  5106.22  1175.43E(γ): Member of the band based on the 0+ state at 1224 keV. From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
I(γ): From 110Pd(α,2nγ). ΔEγ=0.10 was set by the evaluators in cases where the authors quoted ΔEγ<0.10 keV
M(γ): A2=0.334 18; A4=0.111 25 from γγ(θ) in 110Pd(α,2nγ) (1993De09)
  7633.0  4323E(γ): From 112Cd(γ,γ’); Mult and δ based on γ(θ) in 1971Mo31, where applicable
  4385E(γ): From 112Cd(γ,γ’); Mult and δ based on γ(θ) in 1971Mo31, where applicable
M(γ): A2=0.4 1 (1971Mo31)
  4439E(γ): From 112Cd(γ,γ’); Mult and δ based on γ(θ) in 1971Mo31, where applicable
M(γ): A2=0.16 17 (1971Mo31)
  4522E(γ): From 112Cd(γ,γ’); Mult and δ based on γ(θ) in 1971Mo31, where applicable
M(γ): A2=0.04 18 (1971Mo31)
  4782E(γ): From 112Cd(γ,γ’); Mult and δ based on γ(θ) in 1971Mo31, where applicable
M(γ): A2=0.11 8 (1971Mo31)
  4800E(γ): From 112Cd(γ,γ’); Mult and δ based on γ(θ) in 1971Mo31, where applicable
M(γ): A2=0.5 1 (1971Mo31)
  4909E(γ): From 112Cd(γ,γ’); Mult and δ based on γ(θ) in 1971Mo31, where applicable
  5126E(γ): From 112Cd(γ,γ’); Mult and δ based on γ(θ) in 1971Mo31, where applicable
  5337E(γ): From 112Cd(γ,γ’); Mult and δ based on γ(θ) in 1971Mo31, where applicable
  5403E(γ): From 112Cd(γ,γ’); Mult and δ based on γ(θ) in 1971Mo31, where applicable
  5477E(γ): From 112Cd(γ,γ’); Mult and δ based on γ(θ) in 1971Mo31, where applicable
  5512E(γ): From 112Cd(γ,γ’); Mult and δ based on γ(θ) in 1971Mo31, where applicable
  5551E(γ): From 112Cd(γ,γ’); Mult and δ based on γ(θ) in 1971Mo31, where applicable
  5763E(γ): From 112Cd(γ,γ’); Mult and δ based on γ(θ) in 1971Mo31, where applicable
M(γ): A2=0.51 2 (1971Mo31)
  6164E(γ): From 112Cd(γ,γ’); Mult and δ based on γ(θ) in 1971Mo31, where applicable
M(γ): A2=0.08 7 (1971Mo31)
  6203E(γ): From 112Cd(γ,γ’); Mult and δ based on γ(θ) in 1971Mo31, where applicable
M(γ): A2=0.57 7 (1971Mo31)
  6409E(γ): From 112Cd(γ,γ’); Mult and δ based on γ(θ) in 1971Mo31, where applicable
M(γ): A2=0.52 4 (1971Mo31)
  7015M(γ): A2=0.09 2 (1971Mo31)
  7632E(γ): From 112Cd(γ,γ’); Mult and δ based on γ(θ) in 1971Mo31, where applicable
M(γ): from γ(θ) and γ(pol) (1970Mo26). A2=0.51 1 (1971Mo31)
E(level)E(gamma)Comments
  9394.20  5390.5E(γ): From 111Cd(n,γ) E=th:primary
I(γ): From 111Cd(n,γ) E=th:primary
  5397.8E(γ): From 111Cd(n,γ) E=th:primary
I(γ): From 111Cd(n,γ) E=th:primary
  5423.9E(γ): From 111Cd(n,γ) E=th:primary
I(γ): From 111Cd(n,γ) E=th:primary
  5442.48E(γ): From 111Cd(n,γ) E=th:primary
I(γ): From 111Cd(n,γ) E=th:primary
  5498.9E(γ): From 111Cd(n,γ) E=th:primary
I(γ): From 111Cd(n,γ) E=th:primary
  5501.62E(γ): From 111Cd(n,γ) E=th:primary
I(γ): From 111Cd(n,γ) E=th:primary
  5547.5E(γ): From 111Cd(n,γ) E=th:primary
I(γ): From 111Cd(n,γ) E=th:primary
  5555.6E(γ): From 111Cd(n,γ) E=th:primary
I(γ): From 111Cd(n,γ) E=th:primary
  5650.8E(γ): From 111Cd(n,γ) E=th:primary
I(γ): From 111Cd(n,γ) E=th:primary
  5670.24E(γ): From 111Cd(n,γ) E=th:primary
I(γ): From 111Cd(n,γ) E=th:primary
  5674.88E(γ): From 111Cd(n,γ) E=th:primary
I(γ): From 111Cd(n,γ) E=th:primary
  5686.66E(γ): From 111Cd(n,γ) E=th:primary
I(γ): From 111Cd(n,γ) E=th:primary
  5697.93E(γ): From 111Cd(n,γ) E=th:primary
I(γ): From 111Cd(n,γ) E=th:primary
  5741.76E(γ): From 111Cd(n,γ) E=th:primary
I(γ): From 111Cd(n,γ) E=th:primary
  5746.95E(γ): From 111Cd(n,γ) E=th:primary
I(γ): From 111Cd(n,γ) E=th:primary
  5784.3E(γ): From 111Cd(n,γ) E=th:primary
I(γ): From 111Cd(n,γ) E=th:primary
  5822.2E(γ): From 111Cd(n,γ) E=th:primary
I(γ): From 111Cd(n,γ) E=th:primary
  5825.99E(γ): From 111Cd(n,γ) E=th:primary
I(γ): From 111Cd(n,γ) E=th:primary
  5837.08E(γ): From 111Cd(n,γ) E=th:primary
I(γ): From 111Cd(n,γ) E=th:primary
  5853.86E(γ): From 111Cd(n,γ) E=th:primary
I(γ): From 111Cd(n,γ) E=th:primary
  5879.4E(γ): From 111Cd(n,γ) E=th:primary
I(γ): From 111Cd(n,γ) E=th:primary
  5893.51E(γ): From 111Cd(n,γ) E=th:primary
I(γ): From 111Cd(n,γ) E=th:primary
  5914.9E(γ): From 111Cd(n,γ) E=th:primary
I(γ): From 111Cd(n,γ) E=th:primary
  5938.41E(γ): From 111Cd(n,γ) E=th:primary
I(γ): From 111Cd(n,γ) E=th:primary
  5942.00E(γ): From 111Cd(n,γ) E=th:primary
I(γ): From 111Cd(n,γ) E=th:primary
  5965.00E(γ): From 111Cd(n,γ) E=th:primary
I(γ): From 111Cd(n,γ) E=th:primary
  6000.49E(γ): From 111Cd(n,γ) E=th:primary
I(γ): From 111Cd(n,γ) E=th:primary
  6015.63E(γ): From 111Cd(n,γ) E=th:primary
I(γ): From 111Cd(n,γ) E=th:primary
  6030.58E(γ): From 111Cd(n,γ) E=th:primary
I(γ): From 111Cd(n,γ) E=th:primary
  6090.77E(γ): From 111Cd(n,γ) E=th:primary
I(γ): From 111Cd(n,γ) E=th:primary
  6140.26E(γ): From 111Cd(n,γ) E=th:primary
I(γ): From 111Cd(n,γ) E=th:primary
  6150.4E(γ): From 111Cd(n,γ) E=th:primary
I(γ): From 111Cd(n,γ) E=th:primary
  6162.45E(γ): From 111Cd(n,γ) E=th:primary
I(γ): From 111Cd(n,γ) E=th:primary
  6203.94E(γ): From 111Cd(n,γ) E=th:primary
I(γ): From 111Cd(n,γ) E=th:primary
  6224.68E(γ): From 111Cd(n,γ) E=th:primary
I(γ): From 111Cd(n,γ) E=th:primary
  6230.36E(γ): From 111Cd(n,γ) E=th:primary
I(γ): From 111Cd(n,γ) E=th:primary
  6258.35E(γ): From 111Cd(n,γ) E=th:primary
I(γ): From 111Cd(n,γ) E=th:primary
  6260.63E(γ): From 111Cd(n,γ) E=th:primary
I(γ): From 111Cd(n,γ) E=th:primary
  6282.6E(γ): From 111Cd(n,γ) E=th:primary
I(γ): From 111Cd(n,γ) E=th:primary
  6328.5E(γ): From 111Cd(n,γ) E=th:primary
I(γ): From 111Cd(n,γ) E=th:primary
  6448.4E(γ): From 111Cd(n,γ) E=th:primary
I(γ): From 111Cd(n,γ) E=th:primary
  6463.7E(γ): From 111Cd(n,γ) E=th:primary
I(γ): From 111Cd(n,γ) E=th:primary
  6559.8E(γ): From 111Cd(n,γ) E=th:primary
I(γ): From 111Cd(n,γ) E=th:primary
  6564.67E(γ): From 111Cd(n,γ) E=th:primary
I(γ): From 111Cd(n,γ) E=th:primary
  6627.97E(γ): From 111Cd(n,γ) E=th:primary
I(γ): From 111Cd(n,γ) E=th:primary
  6720.8E(γ): From 111Cd(n,γ) E=th:primary
I(γ): From 111Cd(n,γ) E=th:primary
  6725.22E(γ): From 111Cd(n,γ) E=th:primary
I(γ): From 111Cd(n,γ) E=th:primary
  6832.3E(γ): From 111Cd(n,γ) E=th:primary
I(γ): From 111Cd(n,γ) E=th:primary
  6862.10E(γ): From 111Cd(n,γ) E=th:primary
I(γ): From 111Cd(n,γ) E=th:primary
  6887.26E(γ): From 111Cd(n,γ) E=th:primary
I(γ): From 111Cd(n,γ) E=th:primary
  6991.18E(γ): From 111Cd(n,γ) E=th:primary
I(γ): From 111Cd(n,γ) E=th:primary
  7093.29E(γ): From 111Cd(n,γ) E=th:primary
I(γ): From 111Cd(n,γ) E=th:primary
  7162.1E(γ): From 111Cd(n,γ) E=th:primary
I(γ): From 111Cd(n,γ) E=th:primary
  7237.56E(γ): From 111Cd(n,γ) E=th:primary
I(γ): From 111Cd(n,γ) E=th:primary
  7272.28E(γ): From 111Cd(n,γ) E=th:primary
I(γ): From 111Cd(n,γ) E=th:primary
  7328.6E(γ): From 111Cd(n,γ) E=th:primary
I(γ): From 111Cd(n,γ) E=th:primary
  7522.80E(γ): From 111Cd(n,γ) E=th:primary
I(γ): From 111Cd(n,γ) E=th:primary
  7924.8E(γ): From 111Cd(n,γ) E=th:primary
I(γ): From 111Cd(n,γ) E=th:primary
  7961.03E(γ): From 111Cd(n,γ) E=th:primary
I(γ): From 111Cd(n,γ) E=th:primary
  8081.34E(γ): From 111Cd(n,γ) E=th:primary
I(γ): From 111Cd(n,γ) E=th:primary
  8169.41E(γ): From 111Cd(n,γ) E=th:primary
I(γ): From 111Cd(n,γ) E=th:primary
  8776.11E(γ): From 111Cd(n,γ) E=th:primary
I(γ): From 111Cd(n,γ) E=th:primary
  9393.63E(γ): From 111Cd(n,γ) E=th:primary
I(γ): From 111Cd(n,γ) E=th:primary

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