ADOPTED LEVELS, GAMMAS for 110In

Authors: G. G~urdal and F.G. Kondev |  Citation: Nucl. Data Sheets 113, 1315 (2012) |  Cutoff date: 1-Aug-2011 

 Full ENSDF file | Adopted Levels (PDF version) 


Q(β-)=-629 keV 18S(n)= 8054 keV 13S(p)= 5255 keV 12Q(α)= -1953 keV 12
Reference: 2012WA38

References:
  A  110Sn ε decay  B  96Zr(19F,5nγ)
  C  100Mo(14N,4nγ)  D  107Ag(α,nγ)
  E  110Cd(p,n)  F  110Cd(p,nγ)








E(level)
(keV)		XREFJπ(level) T1/2(level)E(γ)
(keV)		I(γ)M(γ)Final Levels
      0.0 BCD   7+ 4.92 h 8 
% ε = 100
     
     62.08 4 A  D F 2+ 69.1 m 5 
% ε = 100
     
    202.38 4    D F 3+      140.304 6 
  100
M1(+E2)
     62.08
2+
    321.20 4    D F 4+      118.819 6 
   259.12 5 
  100 3 
    2.90 14 
M1+E2

    202.38
     62.08
3+
2+
    334.09 5    D F 2+ ≥ 4.9 ps    131.63 8 
   272.018 15 
    0.39 3 
  100 3 

M1+E2
    202.38
     62.08
3+
2+
    342.55 5 A  DEF 1+ ≥ 4.9 ps    280.459 15 
  100 4 
M1(+E2)
     62.08
2+
    346.32 4    D F 4+      143.940 6 
   284.24 10 
  100 5 
    4.3 3 
M1+E2

    202.38
     62.08
3+
2+
    366.52 5    D F (5+)       45.32 2 
  100

    321.20
4+
    413.482 18  BCD   7+      413.52 5 
  100
M1+E2
      0.0
7+
    437.15 4    D F (5)+       90.826 8 
   115.951 6 
   234.70 6 
   76.2 23 
  100 3 
    6.4 6 
M1(+E2)
M1(+E2)

    346.32
    321.20
    202.38
4+
4+
3+
    541.24 5    D F 3+ 2.4 ps +17-6     194.92 10 
   207.17 3 
   220.09 10 
   338.85 5 
   479.15 3 
    2.1 3 
   72 4 
    2.1 3 
    8.8 15 
  100 3 
[M1]
M1
[M1]
M1+E2
M1(+E2)
    346.32
    334.09
    321.20
    202.38
     62.08
4+
2+
4+
3+
2+
    568.40 3    D   (6)+ 1.9 ps +9-6     131.28 8 
   154.90 14 
   568.41 6 
    2.4 3 
 
  100.0 23 
[M1]
[M1]
M1+E2
    437.15
    413.482
      0.0
(5)+
7+
7+
    714.47 4  BCD   8+ 1.4 ps +15-5     300.99 3 
   714.37 10 
    9.2 7 
  100 4 
M1+E2
M1+E2
    413.482
      0.0
7+
7+
    756.45 5    D F (4,5)+ 1.0 ps +4-2     389.93 3 
   410.11 2 
   435.32 4 
   24.2 18 
   80.5 22 
  100 8 
M1+E2

M1+E2
    366.52
    346.32
    321.20
(5+)
4+
4+
E(level)
(keV)		XREFJπ(level) T1/2(level)E(γ)
(keV)		I(γ)M(γ)Final Levels
    756.55 5    D F 2-      215.36 5 
   413.99 2 
   422.48 4 
   554.09 7 
   694.44 5 
   21.8 25 
  100 12 
   20 2 
    3.6 3 
   42 4 

E1(+M2)
E1(+M2)

E1
    541.24
    342.55
    334.09
    202.38
     62.08
3+
1+
2+
3+
2+
    793.04 5    D F 4+ 1.7 ps +10-5     251.81 3 
   471.79 6 
   590.65 2 
  100 5 
    3 4 
   77 4 
M1(+E2)
[M1]
M1(+E2)
    541.24
    321.20
    202.38
3+
4+
3+
    799.851 16  BCD   7- ≥ 2.0 ps    231.52 10 
   386.36 2 
   799.83 2 
    2.14 20 
   23.1 6 
  100.0 20 
[E1]
E1
E1
    568.40
    413.482
      0.0
(6)+
7+
7+
    808.072 21  BCD   8- ≥ 2.4 ps      8.0 10 S
    93.44 20 
   394.59 2 
   808.09 3 
    0.37 19 
    1.67 19 
   42.8 11 
  100.0 25 
[M1+E2]
E1
E1
E1
    799.851
    714.47
    413.482
      0.0
7-
8+
7+
7+
    856.266 22    D   6,7-       56.40 2 
   287.93 5 
   442.82 7 
   856.5 3 
 
  ≤93
  ≤88
  100




    799.851
    568.40
    413.482
      0.0
7-
(6)+
7+
7+
    886.41 3    D   5+,6+,7+      449.22 4 
   472.95 3 
   46 4 
  100 6 
M1,E2
M1,E2
    437.15
    413.482
(5)+
7+
    887.40 6    D F 4+,5+,6+       94.35 10 
   319.01 4 
   520.75 13 
   541.03 8 
   566.24 7 
   14 3 
   13.2 11 
   10.8 15 
   22.6 15 
  100 4 



M1,E2
M1,E2
    793.04
    568.40
    366.52
    346.32
    321.20
4+
(6)+
(5+)
4+
4+
    958.46 5    D F 3+      165.42 9 
   417.16 5 
   592.04 14 
   612.19 5 
   615.95 10 
   624.41 6 
   637.27 3 
   756.03 6 
   896.31 6 
    4.8 14 
   35 4 
    3.1 10 
  100 8 
   14 3 
   36 4 
   85 10 
   59 11 
   37 7 



M1+E2

M1+E2
M1(+E2)
M1+E2
M1+E2
    793.04
    541.24
    366.52
    346.32
    342.55
    334.09
    321.20
    202.38
     62.08
4+
3+
(5+)
4+
1+
2+
4+
3+
2+
E(level)
(keV)		XREFJπ(level) T1/2(level)E(γ)
(keV)		I(γ)M(γ)Final Levels
    970.87 6    D F 3+,4,5+      429.63 15 
   533.83 11 
   649.68 5 
   768.45 5 
   15 5 
   71 8 
   90 10 
  100 8 




    541.24
    437.15
    321.20
    202.38
3+
(5)+
4+
3+
    989.84 5    D F 2-      233.31 4 
   448.61 5 
   647.27 4 
   655.73 5 
   787.48 6 
   927.74 5 
   17 3 
   17.8 11 
  100 9 
   10.6 8 
   78 8 
   57 9 
M1(+E2)
E1
E1(+M2)

E1(+M2)
E1(+M2)
    756.55
    541.24
    342.55
    334.09
    202.38
     62.08
2-
3+
1+
2+
3+
2+
   1006.06 3    D   (5,6) ≥ 1.7 ps    149.80 2 
   569.06 19 
  100 5 
    7.2 9 
M1

    856.266
    437.15
6,7-
(5)+
   1017.93 4  BCD   9- ≥ 1.2 ps    209.80 4 
  100
M1+E2
    808.072
8-
   1020.81 4    D   5+,6+      452.35 5 
   674.53 5 
  1020.84 6 
   40 3 
   50 9 
  100 7 
M1,E2

M1,E2
    568.40
    346.32
      0.0
(6)+
4+
7+
   1023.40 5    D F 3-      266.87 10 
   677.12 15 
   689.27 10 
   702.07 19 
   821.00 17 
   961.32 3 
   13 5 
   15 3 
    4.1 6 
    5.1 25 
   17 3 
  100 7 





E1
    756.55
    346.32
    334.09
    321.20
    202.38
     62.08
2-
4+
2+
4+
3+
2+
   1049.88 5    D F 1+,2+ 1.0 ps +9-4     707.34 4 
   715.72 8 
   987.81 4 
  100 12 
   12.0 24 
   35.0 14 
M1(+E2)
(M1)
M1(+E2)
    342.55
    334.09
     62.08
1+
2+
2+
   1062.71 6    D F 4,5,6+      696.18 4 
   716.37 10 
   741.52 10 
  100 10 
   25 3 
   14 4 



    366.52
    346.32
    321.20
(5+)
4+
4+
   1118.45 11    D        751.93 10 
  100
M1,E2
    366.52
(5+)
   1119.82 6    D F (0)-      363.24 4 
   777.32 6 
   35.5 14 
  100 15 
E2
E1
    756.55
    342.55
2-
1+
E(level)
(keV)		XREFJπ(level) T1/2(level)E(γ)
(keV)		I(γ)M(γ)Final Levels
   1134.07 5    D F 3-,4-      377.51 2 
   813.00 15 
  100 5 
   33 8 
M1,E2

    756.55
    321.20
2-
4+
   1176.23 6    D F 2+,3      419.65 8 
   829.86 10 
   842.22 10 
   855.01 10 
  1114.15 6 
   24.8 25 
    8.3 17 
   18.2 17 
   11 5 
  100 10 





    756.55
    346.32
    334.09
    321.20
     62.08
2-
4+
2+
4+
2+
   1190.93 5    D F 1-,2-,3-      201.10 4 
   434.35 3 
   857.11 14 
    9.0 7 
  100 8 
    2.0 4 

M1(+E2)

    989.84
    756.55
    334.09
2-
2-
2+
   1204.87 5    D   4-,5-,6- ≥ 1.1 ps    198.81 4 
  100
M1+E2
   1006.06
(5,6)
   1216.80 7    D F 2+,3+,4+      870.39 10 
   882.69 7 
   895.70 10 
  100 17 
   87 6 
   12.3 6 
M1,E2
M1,E2

    346.32
    334.09
    321.20
4+
2+
4+
   1230.05 4    D   3-,4,5,6+      223.98 3 
   883.76 8 
   57 5 
  100 10 


   1006.06
    346.32
(5,6)
4+
   1239.93 6    D F 1-,2-,3-      249.96 15 
   483.34 5 
   905.92 10 
  1177.93 10 
   38 15 
   87 9 
   58 4 
  100 15 

M1,E2
E1

    989.84
    756.55
    334.09
     62.08
2-
2-
2+
2+
   1254.91 7    D F 0-,1-,2-      498.31 7 
   912.41 8 
   59 9 
  100 7 
M1,E2
E1
    756.55
    342.55
2-
1+
   1259.39 8    D        502.95 9 
   822.21 10 
   20 3 
  100 6 


    756.45
    437.15
(4,5)+
(5)+
   1280.23 10    D   +      487.19 8 
  100
(M1,E2)
    793.04
4+
   1303.23 16    D F      969.14 15 
  100

    334.09
2+
   1390.70 10    D        256.63 8 
  100

   1134.07
3-,4-
   1396.34 8  B     9+      681.5 10 
  1396.4 1 
   24 4 
  100 28 
M1+E2
E2
    714.47
      0.0
8+
7+
   1441.75 6    D        873.35 5 
  100

    568.40
(6)+
E(level)
(keV)		XREFJπ(level) T1/2(level)E(γ)
(keV)		I(γ)M(γ)Final Levels
   1482.35 6    D   ≥ 1.8 ps    277.48 3 
  100

   1204.87
4-,5-,6-
   1494.00 18    D   -      487.94 17 
  100
(M1,E2)
   1006.06
(5,6)
   1507.10 6    D        501.10 6 
   650.74 10 
  1069.92 6 
  1140.60 20 
  100 12 
   89 15 
   90 16 
   68 11 




   1006.06
    856.266
    437.15
    366.52
(5,6)
6,7-
(5)+
(5+)
   1529.70 24    D        773.24 23 
  100

    756.45
(4,5)+
   1561.59 6  BCD   10-      543.7 1 
   753.6 7 
  100 4 
    0.46 11 
M1+E2
(E2)
   1017.93
    808.072
9-
8-
   1562.99 8    D   0.97 ps +21-14     358.12 6 
  100

   1204.87
4-,5-,6-
   1617.49 6  B D   8-      599.3 1 
   809.9 1 
   817.4 1 
  1617.0 4 
  100 4 
   32.4 20 
   48.0 20 
    5.9 10 
M1+E2
M1+E2
M1+E2
E1
   1017.93
    808.072
    799.851
      0.0
9-
8-
7-
7+
   1693.65 9    D        186.55 7 
  100

   1507.10

   1886.23 7  B     10-     1078.1 1 
  100
E2
    808.072
8-
   2110.15 13  B     10+      713.8 1 
  100
M1+E2
   1396.34
9+
   2129.14 6  BC    10-      243.0 1 
   567.2 1 
   732.3 2 
  1111.2 2 
  1321.2 1 
   32.3 3 
  100 6 
   25.8 3 
   48.4 3 
   87 6 
M1+E2
M1+E2
E1
M1+E2
E2
   1886.23
   1561.59
   1396.34
   1017.93
    808.072
10-
10-
9+
9-
8-
   2174.91 7  BC    11-      613.0 1 
  1157.0 1 
  100 3 
   11.4 4 
M1+E2
E2
   1561.59
   1017.93
10-
9-
   2201.99 7  B     10-      315.6 1 
   584.4 1 
   640.6 1 
   805.3 2 
  1183.2 3 
   23.0 14 
  100 4 
   37.8 14 
   24.3 14 
    9.5 14 
M1+E2
E2
M1+E2
E1
M1+E2
   1886.23
   1617.49
   1561.59
   1396.34
   1017.93
10-
8-
10-
9+
9-
   2220.65 8  B     9-      603.2 1 
   825.4 2 
  1202.3 2 
  100 4 
   11.2 10 
   13.3 10 
M1+E2
E1
M1+E2
   1617.49
   1396.34
   1017.93
8-
9+
9-
E(level)
(keV)		XREFJπ(level) T1/2(level)E(γ)
(keV)		I(γ)M(γ)Final Levels
   2275.59 7  B     10-     1257.3 1 
  1467.5 1 
   86 9 
  100 9 
M1+E2
E2
   1017.93
    808.072
9-
8-
   2492.59 9  BC    (11)-      363.3 1 
  100
M1+E2
   2129.14
10-
   2596.95 8  BC    12-      104.2 1 
   421.9 1 
  1035.6 1 
    4.68 25 
  100 3 
   13.6 5 
M1+E2
M1+E2
E2
   2492.59
   2174.91
   1561.59
(11)-
11-
10-
   2607.45 7  B     11-      331.5 1 
  1046.1 1 
  1589.9 1 
   97 3 
   90 7 
  100 7 
M1+E2
M1+E2
E2
   2275.59
   1561.59
   1017.93
10-
10-
9-
   2687.0 5  B     (10+)     1290.7 5 
  100
M1+E2
   1396.34
9+
   2764.86 8  BC    12-      590.1 1 
  1203.2 1 
  100 3 
   10.0 5 
M1+E2
E2
   2174.91
   1561.59
11-
10-
   2798.43 8  B     11-      578.0 1 
   596.2 1 
   669.3 1 
  100 4 
   61.4 24 
   13.2 12 
E2
M1+E2
M1+E2
   2220.65
   2201.99
   2129.14
9-
10-
10-
   2837.98 10  BC    13-      241.1 1 
  100 3 
M1+E2
   2596.95
12-
   2854.35 24  B     (11+)      744.2 2 
  100 12 
M1+E2
   2110.15
10+
   2901.99 13  B           63.9 1 
  100

   2837.98
13-
   2908.48 9  B     (12-)      301.3 1 
   733.4 1 
  1346.5 2 
  100 3 
   31 3 
   42 3 
M1+E2
M1+E2
E2
   2607.45
   2174.91
   1561.59
11-
11-
10-
   3080.00 12  B     12-      878.0 1 
  100 4 
E2
   2201.99
10-
   3192.14 12  BC    14- 0.868 ps +24-25     354.6 1 
  100 3 
M1+E2
   2837.98
13-
   3196.98 14  B     (13-)      288.5 1 
  100 5 
M1+E2
   2908.48
(12-)
   3245.11 8  B     (10,11)-     1070.1 1 
  1115.9 1 
  1684.1 5 
  100 9 
  100 9 
   18 9 
M1+E2
M1+E2
M1+E2
   2174.91
   2129.14
   1561.59
11-
10-
10-
   3326.98 10  B     11+     1765.5 1 
  100
E1
   1561.59
10-
   3344.78 14  B     (14)-      506.8 1 
  100 5 
M1+E2
   2837.98
13-
   3371.31 21  B     13-     1196.4 2 
  100
E2
   2174.91
11-
E(level)
(keV)		XREFJπ(level) T1/2(level)E(γ)
(keV)		I(γ)M(γ)Final Levels
   3373.9 10   C         609 1 
 

   2764.86
12-
   3438.41 13  B          536.0 2 
  100

   2901.99

   3512.46 9  BC    12+      185.6 1 
   267.2 1 
   610.7 1 ?
  1337.7 1 
    6.3 6 
   13.3 6 
    6.3 6 
  100 3 
M1+E2
E1

E1
   3326.98
   3245.11
   2901.99
   2174.91
11+
(10,11)-

11-
   3629.03 13  B     13-      830.6 1 
  100
E2
   2798.43
11-
   3697.69 10  B     12-     1522.6 1 
  1587.4
  100 8 
 
M1+E2

   2174.91
   2110.15
11-
10+
   3713.24 16  B     15- 0.50 ps +4-3     521.1 1 
  100
M1+E2
   3192.14
14-
   3719.82 9  BC    13+      207.5 1 
   281.3 1 
   955.3 1 
  1122.7 1 
  100 3 
    3.6 6 
   37.9 12 
    8.3 6 
M1+E2

E1
E1
   3512.46
   3438.41
   2764.86
   2596.95
12+

12-
12-
   3732.99 17  B     (14-)      536.0 1 
  100
M1+E2
   3196.98
(13-)
   3821.18 17  B     (15-)      476.4 1 
  100
M1+E2
   3344.78
(14)-
   3833.00 16  B     (14-)      753.0 1 
  100
E2
   3080.00
12-
   3914.94 10  BC    13+      217.2 1 
  1077.6 2 
  1318.0 1 
   22 2 
   16 2 
  100 4 
E1
E1
E1
   3697.69
   2837.98
   2596.95
12-
13-
12-
   3943.39 11  BC    14+      223.8 1 
  1105.0 1 
  100 3 
    7.5 4 
M1+E2
E1
   3719.82
   2837.98
13+
13-
   3995.62 10  B     13-      297.8 1 
  1230.5 1 
   26.2 24 
  100 5 
M1+E2
M1+E2
   3697.69
   2764.86
12-
12-
   4081.70 11  BC    14+      166.9 1 
  1243.8 1 
   81.1 19 
  100 4 
M1+E2
E1
   3914.94
   2837.98
13+
13-
   4156.50 16  B     14-     1076.5 1 
  100
E2
   3080.00
12-
   4228.98 12  BC    15+ 0.435 ps +17-16     147.4 1 
   285.4 1 
    1.9 4 
  100 3 
M1+E2
M1+E2
   4081.70
   3943.39
14+
14+
   4263.99 12  B     14-      268.0 1 
  1425.6 2 
  100 3 
   26 3 
M1+E2
M1+E2
   3995.62
   2837.98
13-
13-
E(level)
(keV)		XREFJπ(level) T1/2(level)E(γ)
(keV)		I(γ)M(γ)Final Levels
   4323.05 24  B     13-,14-,15-     1130.9 2 
  100 10 
M1+E2
   3192.14
14-
   4370.60 13  BC    15+      289.0 1 
  1178.3 2 
  100
    8.6 11 
M1+E2
E1
   4081.70
   3192.14
14+
14-
   4528.31 18  BC    16-      815.0 1 
  100
M1+E2
   3713.24
15-
   4561.77 13  B     15(-)      297.3 1 
  1370.1 1 
  100 4 
   29.2 21 
M1+E2
M1+E2
   4263.99
   3192.14
14-
14-
   4598.02 14  BC    16+ 0.297 ps +6-11     369.0 1 
  100
M1+E2
   4228.98
15+
   4602.10 19  B     (16-)      769.1 1 
  100
E2
   3833.00
(14-)
   4606.03 16  B     15-      977.0 1 
  100
E2
   3629.03
13-
   4802.89 20  B     (17-)      981.7 1 
  100
E2
   3821.18
(15-)
   4802.95 15  BC    16+      432.4 1 
  100
M1+E2
   4370.60
15+
   4942.2 4  B     16-     1750.0 3 
  100
E2
   3192.14
14-
   4995.57 17  B     16(-)      433.8 1 
  100 4 
M1+E2
   4561.77
15(-)
   5045.60 15  B     13+,14+,15+     1102.2 1 
  100
M1+E2
   3943.39
14+
   5084.90 14  BC    17+ 0.159 ps +24-18     486.9 1 
   855.9 1 
  100 3 
    8.1 5 
M1+E2
E2
   4598.02
   4228.98
16+
15+
   5180.81 19  B     16-     1024.3 1 
  100
E2
   4156.50
14-
   5265.18 19  B     17-      736.8 1 
  1552.0 2 
  100 4 
   35 4 
M1+E2
E2
   4528.31
   3713.24
16-
15-
   5283.39 14  BC    17(+)      480.5 1 
  100 3 
M1+E2
   4802.95
16+
   5403.27 21  B     17-     1690.2 2 
  100
E2
   3713.24
15-
   5545.88 19  B     (17-)      550.3 1 
  100
M1+E2
   4995.57
16(-)
   5556.44 19  B     17(-) 0.54 ps +7-6     950.4 1 
  100
E2
   4606.03
15-
   5561.68 19  B     (17-)      566.1 1 
  100
M1+E2
   4995.57
16(-)
   5650.39 14  BC    18+ 0.136 ps +15-13     366.9 1 
   565.6 1 
  1052.3 1 
    6.2 8 
  100 3 
   11.5 8 
M1+E2
M1+E2
E2
   5283.39
   5084.90
   4598.02
17(+)
17+
16+
   5687.23 20  B     16-,17-,18-      284.0 1 
   422.0 1 
   52 4 
  100 4 
M1+E2
M1+E2
   5403.27
   5265.18
17-
17-
   5825.10 17  B     (16+,17+,18+)      740.2 1 
  100
M1+E2
   5084.90
17+
E(level)
(keV)		XREFJπ(level) T1/2(level)E(γ)
(keV)		I(γ)M(γ)Final Levels
   5833.45 15  B     (18+)      550.2 1 
   748.4 1 
  100 4 
   39 4 
M1+E2
M1+E2
   5283.39
   5084.90
17(+)
17+
   5839.27 17  B     (18+)      555.9 1 
   754.3 2 
  100 5 
   29 5 
M1+E2
M1+E2
   5283.39
   5084.90
17(+)
17+
   6062.11 21  B     18-      881.3 1 
  100 4 
E2
   5180.81
16-
   6095.43 23  B     (19)-      408.2 1 
  100
M1+E2
   5687.23
16-,17-,18-
   6223.33 17  B     19+ 0.073 ps +6-9     572.9 1 
  1138.6 2 
  100 3 
   14.5 16 
M1+E2
E2
   5650.39
   5084.90
18+
17+
   6296.99 18  B     (19)+      646.6 1 
  100
M1+E2
   5650.39
18+
   6445.54 22  B     19(-) 0.38 ps +4-3     889.1 1 
  100
E2
   5556.44
17(-)
   6707.23 19  B     (20+)      483.9 1 
  100
M1+E2
   6223.33
19+
   6992.09 20  B     (20+)      695.1 1 
  100
M1+E2
   6296.99
(19)+
   6999.21 24  B     20-      937.1 1 
  100
E2
   6062.11
18-
   7240.6 4  B     (19)+     1590.2 3 
  100
M1+E2
   5650.39
18+
   7272.63 22  B     (21+)      565.4 1 
  100
M1+E2
   6707.23
(20+)
   7391.75 24  B     21(-) 0.279 ps +16-12     946.2 1 
  100
E2
   6445.54
19(-)
   7980.84 24  B     (22+)      708.2 1 
  100
M1+E2
   7272.63
(21+)
   8087.8 3  B     (22-)     1088.6 1 
  100
E2
   6999.21
20-
   8463.8 3  B     (23-) 0.142 ps +13-10    1072.0 1 
  100
E2
   7391.75
21(-)
   8747.7 3  B     (23+)      766.9 1 
  100
M1+E2
   7980.84
(22+)
   8768 59     E  0+        
   9398.2 4  B     (24-)     1310.4 2 
  100
E2
   8087.8
(22-)
   9438 59     E  2+        
   9698.7 3  B     (25-)     1234.9 1 
  100
E2
   8463.8
(23-)
  10268 59     E  (0+,2+,4+)        
  10568 59     E         
  10858 59     E  3-        
  11068 59     E  4+        
  11117.8 3  B     (27-)     1419.1 1 
  100
E2
   9698.7
(25-)
  11268 59     E         
E(level)
(keV)		XREFJπ(level) T1/2(level)E(γ)
(keV)		I(γ)M(γ)Final Levels
  11468 59     E         
  11768 59     E         
  12744.6 7  B     (29-)     1626.8 6 
  100
E2
  11117.8
(27-)

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

T1/2(level): From Doppler Shift Attenuation method in 107Ag(α,nγ), unless otherwise stated

M(γ): From α(K)exp and/or γ(θ) in 110Cd(p,nγ) (1987Kr15), unless otherwise stated

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Band Transitions:

E(level)
(keV)		Jπ(level) T1/2(level)E(γ)I(γ)M(γ)Final Levels
Band 1 - Magnetic-rotational band #1.
    808.072 21  8- ≥ 2.4 ps      
   1017.93 4  9- ≥ 1.2 ps      
   1561.59 6  10-      543.7 1 
   753.6 7 
  100 4 
    0.46 11 
M1+E2
(E2)
   1017.93
    808.072
9-
8-
   2174.91 7  11-      613.0 1 
  1157.0 1 
  100 3 
   11.4 4 
M1+E2
E2
   1561.59
   1017.93
10-
9-
E(level)
(keV)		Jπ(level) T1/2(level)E(γ)I(γ)M(γ)Final Levels
Band 2 - Magnetic-rotational band #2.
   2596.95 8  12-        
   2837.98 10  13-        
   3192.14 12  14- 0.868 ps +24-25     354.6 1 
  100 3 
M1+E2
   2837.98
13-
   3713.24 16  15- 0.50 ps +4-3     521.1 1 
  100
M1+E2
   3192.14
14-
   4528.31 18  16-      815.0 1 
  100
M1+E2
   3713.24
15-
   5265.18 19  17-      736.8 1 
  1552.0 2 
  100 4 
   35 4 
M1+E2
E2
   4528.31
   3713.24
16-
15-
E(level)
(keV)		Jπ(level) T1/2(level)E(γ)I(γ)M(γ)Final Levels
Band 3 - Magnetic-rotational band #3.
   3326.98 10  11+        
   3512.46 9  12+        
   3719.82 9  13+      207.5 1 
   281.3 1 
   955.3 1 
  1122.7 1 
  100 3 
    3.6 6 
   37.9 12 
    8.3 6 
M1+E2

E1
E1
   3512.46
   3438.41
   2764.86
   2596.95
12+

12-
12-
   3943.39 11  14+      223.8 1 
  1105.0 1 
  100 3 
    7.5 4 
M1+E2
E1
   3719.82
   2837.98
13+
13-
   4228.98 12  15+ 0.435 ps +17-16     147.4 1 
   285.4 1 
    1.9 4 
  100 3 
M1+E2
M1+E2
   4081.70
   3943.39
14+
14+
   4598.02 14  16+ 0.297 ps +6-11     369.0 1 
  100
M1+E2
   4228.98
15+
   5084.90 14  17+ 0.159 ps +24-18     486.9 1 
   855.9 1 
  100 3 
    8.1 5 
M1+E2
E2
   4598.02
   4228.98
16+
15+
   5650.39 14  18+ 0.136 ps +15-13     366.9 1 
   565.6 1 
  1052.3 1 
    6.2 8 
  100 3 
   11.5 8 
M1+E2
M1+E2
E2
   5283.39
   5084.90
   4598.02
17(+)
17+
16+
   6223.33 17  19+ 0.073 ps +6-9     572.9 1 
  1138.6 2 
  100 3 
   14.5 16 
M1+E2
E2
   5650.39
   5084.90
18+
17+
   6707.23 19  (20+)      483.9 1 
  100
M1+E2
   6223.33
19+
   7272.63 22  (21+)      565.4 1 
  100
M1+E2
   6707.23
(20+)
   7980.84 24  (22+)      708.2 1 
  100
M1+E2
   7272.63
(21+)
   8747.7 3  (23+)      766.9 1 
  100
M1+E2
   7980.84
(22+)
E(level)
(keV)		Jπ(level) T1/2(level)E(γ)I(γ)M(γ)Final Levels
Band 4 - Anti-magnetic rotational band #1.
   1617.49 6  8-        
   2201.99 7  10-        
   3080.00 12  12-      878.0 1 
  100 4 
E2
   2201.99
10-
   4156.50 16  14-     1076.5 1 
  100
E2
   3080.00
12-
   5180.81 19  16-     1024.3 1 
  100
E2
   4156.50
14-
   6062.11 21  18-      881.3 1 
  100 4 
E2
   5180.81
16-
   6999.21 24  20-      937.1 1 
  100
E2
   6062.11
18-
   8087.8 3  (22-)     1088.6 1 
  100
E2
   6999.21
20-
   9398.2 4  (24-)     1310.4 2 
  100
E2
   8087.8
(22-)
E(level)
(keV)		Jπ(level) T1/2(level)E(γ)I(γ)M(γ)Final Levels
Band 5 - π((g9/2-2)(g7/2))#νh11/2 band.
   2220.65 8  9-        
   2798.43 8  11-        
   3629.03 13  13-      830.6 1 
  100
E2
   2798.43
11-
   4606.03 16  15-      977.0 1 
  100
E2
   3629.03
13-
   5556.44 19  17(-) 0.54 ps +7-6     950.4 1 
  100
E2
   4606.03
15-
   6445.54 22  19(-) 0.38 ps +4-3     889.1 1 
  100
E2
   5556.44
17(-)
   7391.75 24  21(-) 0.279 ps +16-12     946.2 1 
  100
E2
   6445.54
19(-)
   8463.8 3  (23-) 0.142 ps +13-10    1072.0 1 
  100
E2
   7391.75
21(-)
   9698.7 3  (25-)     1234.9 1 
  100
E2
   8463.8
(23-)
  11117.8 3  (27-)     1419.1 1 
  100
E2
   9698.7
(25-)
  12744.6 7  (29-)     1626.8 6 
  100
E2
  11117.8
(27-)
E(level)
(keV)		Jπ(level) T1/2(level)E(γ)I(γ)M(γ)Final Levels
Band 6 - π(g9/2-1)#νg7/2 band.
    714.47 4  8+ 1.4 ps +15-5       
   1396.34 8  9+        
   2110.15 13  10+      713.8 1 
  100
M1+E2
   1396.34
9+
   2854.35 24  (11+)      744.2 2 
  100 12 
M1+E2
   2110.15
10+
E(level)
(keV)		Jπ(level) T1/2(level)E(γ)I(γ)M(γ)Final Levels
Band 7 - π(g9/2-1)#ν(((g7/2/d5/2))2(h11/2)) band.
   2275.59 7  10-        
   2607.45 7  11-        
   2908.48 9  (12-)      301.3 1 
   733.4 1 
  1346.5 2 
  100 3 
   31 3 
   42 3 
M1+E2
M1+E2
E2
   2607.45
   2174.91
   1561.59
11-
11-
10-
   3196.98 14  (13-)      288.5 1 
  100 5 
M1+E2
   2908.48
(12-)
   3732.99 17  (14-)      536.0 1 
  100
M1+E2
   3196.98
(13-)
E(level)
(keV)		Jπ(level) T1/2(level)E(γ)I(γ)M(γ)Final Levels
Band 8 - π(g9/2-1)#ν((g7/2/d5/2)(h11/2)2) band.
   3914.94 10  13+        
   4081.70 11  14+        
   4370.60 13  15+      289.0 1 
  1178.3 2 
  100
    8.6 11 
M1+E2
E1
   4081.70
   3192.14
14+
14-
   4802.95 15  16+      432.4 1 
  100
M1+E2
   4370.60
15+
   5283.39 14  17(+)      480.5 1 
  100 3 
M1+E2
   4802.95
16+
   5833.45 15  (18+)      550.2 1 
   748.4 1 
  100 4 
   39 4 
M1+E2
M1+E2
   5283.39
   5084.90
17(+)
17+
E(level)
(keV)		Jπ(level) T1/2(level)E(γ)I(γ)M(γ)Final Levels
Band 9 - π(g9/2-1)#ν(h11/2)3 band.
   3697.69 10  12-        
   3995.62 10  13-        
   4263.99 12  14-      268.0 1 
  1425.6 2 
  100 3 
   26 3 
M1+E2
M1+E2
   3995.62
   2837.98
13-
13-
   4561.77 13  15(-)      297.3 1 
  1370.1 1 
  100 4 
   29.2 21 
M1+E2
M1+E2
   4263.99
   3192.14
14-
14-
   4995.57 17  16(-)      433.8 1 
  100 4 
M1+E2
   4561.77
15(-)
   5561.68 19  (17-)      566.1 1 
  100
M1+E2
   4995.57
16(-)

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Additional Gamma Data:















E(level)
(keV)		Jπ(level)T1/2(level)E(γ)
(keV)		MultipolarityMixing
Ratio		Conversion
Coefficient		Additional Data
    202.38 3+      140.304 6 M1(+E2)-0.04 60.199α=0.199 4, α(K)=0.172 3, α(L)=0.0216 6, α(M)=0.00421 12, α(N)=0.000770 20, α(O)=5.68×10-5 10, α(N+)=0.000827 21
    321.20 4+      118.819 6 M1+E2-0.05 30.316α=0.316, α(K)=0.273 4, α(L)=0.0346 7, α(M)=0.00673 14, α(N)=0.001230 24, α(O)=9.05×10-5 14, α(N+)=0.001321 25
    334.09 2+ ≥ 4.9 ps    272.018 15 M1+E2+0.06 40.0337B(E2)(W.u.)<20, B(M1)(W.u.)<0.22, α=0.0337, α(N)=0.0001280 19, α(O)=9.53E-6 14
    342.55 1+ ≥ 4.9 ps    280.459 15 M1(+E2)+0.04 220.0311B(E2)(W.u.)<40, B(M1)(W.u.)<0.20, α=0.0311 9, α(K)=0.0270 7, α(L)=0.00332 14, α(M)=0.00064 3, α(N)=0.000118 5, α(O)=8.80E-6 20, α(N+)=0.000127 5
    346.32 4+      143.940 6 M1+E2-0.07 50.186α=0.186 4, α(N)=0.000722 20, α(O)=5.31×10-5 10
    413.482 7+      413.52 5 M1+E2 0.0119α=0.0119 4, α(K)=0.0103 3, α(L)=0.00134 12, α(M)=0.000260 24, α(N)=4.7×10-5 4, α(O)=3.29E-6 6, α(N+)=5.1E-5 4
    437.15 (5)+       90.826 8 M1(+E2)-0.13 130.70α=0.70 7, α(K)=0.60 5, α(L)=0.081 20, α(M)=0.016 4, α(N)=0.0029 7, α(O)=0.000199 19, α(N+)=0.0031 7
(5)+      115.951 6 M1(+E2)-0.03 130.337α=0.337 15, α(K)=0.292 11, α(L)=0.037 4, α(M)=0.0072 7, α(N)=0.00131 12, α(O)=9.7×10-5 4, α(N+)=0.00141 12
    541.24 3+ 2.4 ps +17-6     194.92 10 [M1] 0.0810B(M1)(W.u.)=0.014 +4-10, α=0.0810, α(K)=0.0703 10, α(L)=0.00874 13, α(M)=0.001697 24, α(N)=0.000311 5, α(O)=2.31×10-5 4, α(N+)=0.000334 5
3+ 2.4 ps +17-6     207.17 3 M1 0.0688B(M1)(W.u.)=0.39 +10-28, α=0.0688, α(K)=0.0597 9, α(L)=0.00742 11, α(M)=0.001439 21, α(N)=0.000264 4, α(O)=1.96×10-5 3, α(N+)=0.000283 4
3+ 2.4 ps +17-6     220.09 10 [M1] 0.0586B(M1)(W.u.)=0.009 +3-7, α=0.0586, α(K)=0.0508 8, α(L)=0.00630 9, α(M)=0.001223 18, α(N)=0.000224 4, α(O)=1.667×10-5 24, α(N+)=0.000241 4
3+ 2.4 ps +17-6     338.85 5 M1+E2 0.0210α=0.0210 19, α(K)=0.0180 15, α(L)=0.0024 4, α(M)=0.00047 8, α(N)=8.5×10-5 14, α(O)=5.8E-6 4, α(N+)=9.1E-5 14
3+ 2.4 ps +17-6     479.15 3 M1(+E2)+0.03 30.00806B(E2)(W.u.)=(0.1 +3-1), B(M1)(W.u.)=(0.044 +11-31), α=0.00806 12, α(K)=0.00702 10, α(L)=0.000848 12, α(M)=0.0001643 23, α(N)=3.01E-5 5, α(O)=2.26E-6 4, α(N+)=3.24E-5
    568.40 (6)+ 1.9 ps +9-6     131.28 8 [M1] 0.238B(M1)(W.u.)=0.12 +4-6, α=0.238, α(K)=0.206 3, α(L)=0.0259 4, α(M)=0.00504 8, α(N)=0.000923 13, α(O)=6.82×10-5 10, α(N+)=0.000991 14
(6)+ 1.9 ps +9-6     154.90 14 [M1] 0.1511α=0.1511, α(K)=0.1309 19, α(L)=0.01639 24, α(M)=0.00318 5, α(N)=0.000583 9, α(O)=4.32×10-5 7, α(N+)=0.000626 9
(6)+ 1.9 ps +9-6     568.41 6 M1+E2 0.00512α=0.00512 23, α(K)=0.00443 22, α(L)=0.000554 9, α(M)=0.0001075 17, α(N)=1.96×10-5 4, α(O)=1.41E-6 8, α(N+)=2.10E-5 5
    714.47 8+ 1.4 ps +15-5     300.99 3 M1+E2 0.030α=0.030 4, α(K)=0.025 3, α(L)=0.0035 8, α(M)=0.00068 15, α(N)=0.00012 3, α(O)=8.2×10-6 9, α(N+)=0.00013 3
8+ 1.4 ps +15-5     714.37 10 M1+E2 0.00290α=0.00290 22, α(K)=0.00252 20, α(L)=0.000308 16, α(M)=6.0×10-5 3, α(N)=1.09E-5 6, α(O)=8.0E-7 7, α(N+)=1.17E-5 7
    756.45 (4,5)+ 1.0 ps +4-2     389.93 3 M1+E2 0.0141α=0.0141 7, α(K)=0.0121 5, α(L)=0.00159 17, α(M)=0.00031 4, α(N)=5.6×10-5 6, α(O)=3.88E-6 12, α(N+)=6.0E-5 6
(4,5)+ 1.0 ps +4-2     435.32 4 M1+E2 0.01037α=0.01037 22, α(K)=0.00894 14, α(L)=0.00115 8, α(M)=0.000224 17, α(N)=4.1×10-5 3, α(O)=2.86E-6 4, α(N+)=4.4E-5 3
    756.55 2-      413.99 2 E1(+M2)+0.05 30.00366α=0.00366 16, α(K)=0.00319 14, α(L)=0.000381 18, α(M)=7.4×10-5 4, α(N)=1.34E-5 7, α(O)=9.7E-7 5, α(N+)=1.44E-5 7
2-      422.48 4 E1(+M2)-0.04 270.003α=0.003 3, α(K)=0.003 3, α(L)=0.0004 4, α(M)=7.E-5 7, α(N)=1.3E-5 13, α(O)=9.E-7 10, α(N+)=1.4E-5 14
2-      694.44 5 E1 0.001077α=0.001077 15, α(K)=0.000941 14, α(L)=0.0001106 16, α(M)=2.13×10-5 3, α(N)=3.90E-6 6, α(O)=2.87E-7 4, α(N+)=4.19E-6
    793.04 4+ 1.7 ps +10-5     251.81 3 M1(+E2)-0.01 150.0411B(E2)(W.u.)=(1 +18-1), B(M1)(W.u.)=(0.44 +14-26), α=0.0411 8, α(K)=0.0357 7, α(L)=0.00440 11, α(M)=0.000854 22, α(N)=0.000157 4, α(O)=1.166E-5 20, α(N+)=0.000168 4
4+ 1.7 ps +10-5     471.79 6 [M1] 0.00837B(M1)(W.u.)=0.002 +3-2, α=0.00837 12, α(K)=0.00729 11, α(L)=0.000882 13, α(M)=0.0001707 24, α(N)=3.13×10-5 5, α(O)=2.35E-6 4, α(N+)=3.37E-5
4+ 1.7 ps +10-5     590.65 2 M1(+E2)-0.05 160.00486B(E2)(W.u.)=(0.2 +10-2), B(M1)(W.u.)=(0.026 +8-16), α=0.00486 7, α(K)=0.00424 7, α(L)=0.000509 8, α(M)=9.85E-5 14, α(N)=1.81E-5 3, α(O)=1.359E-6 20, α(N+)=1.94E-5 3
E(level)
(keV)		Jπ(level)T1/2(level)E(γ)
(keV)		MultipolarityMixing
Ratio		Conversion
Coefficient		Additional Data
    799.851 7- ≥ 2.0 ps    231.52 10 [E1] 0.01638B(E1)(W.u.)<0.00020, α=0.01638, α(K)=0.01426 20, α(L)=0.001724 25, α(M)=0.000332 5, α(N)=6.04E-5 9, α(O)=4.21E-6 6, α(N+)=6.46E-5 9
7- ≥ 2.0 ps    386.36 2 E1 0.00423B(E1)(W.u.)<0.00047, α=0.00423 6, α(K)=0.00369 6, α(L)=0.000441 7, α(M)=8.50E-5 12, α(N)=1.550E-5 22, α(O)=1.113E-6 16, α(N+)=1.661E-5 24
7- ≥ 2.0 ps    799.83 2 E1 0.000801B(E1)(W.u.)<0.00023, α=0.000801 12, α(K)=0.000700 10, α(L)=8.20E-5 12, α(M)=1.580E-5 23, α(N)=2.89E-6 4, α(O)=2.14E-7 3, α(N+)=3.11E-6
    808.072 8- ≥ 2.4 ps      8.0 10 [M1+E2] 4.E4α=4.E4 6, α(L)=3.E4 5, α(M)=7.E3 9, α(N)=1.1E3 15, α(O)=16 23, α(N+)=1.1E3 16
8- ≥ 2.4 ps     93.44 20 E1 0.211B(E1)(W.u.)<1.7E-5, α=0.211, α(K)=0.183 3, α(L)=0.0230 4, α(M)=0.00443 7, α(N)=0.000794 13, α(O)=5.08E-5 8, α(N+)=0.000844 13
8- ≥ 2.4 ps    394.59 2 E1 0.00401B(E1)(W.u.)<5.7E-6, α=0.00401 6, α(K)=0.00350 5, α(L)=0.000418 6, α(M)=8.06E-5 12, α(N)=1.470E-5 21, α(O)=1.056E-6 15, α(N+)=1.575E-5 22
8- ≥ 2.4 ps    808.09 3 E1 0.000784B(E1)(W.u.)<1.6E-6, α=0.000784 11, α(K)=0.000686 10, α(L)=8.03E-5 12, α(M)=1.547E-5 22, α(N)=2.83E-6 4, α(O)=2.09E-7 3, α(N+)=3.04E-6
    886.41 5+,6+,7+      449.22 4 M1,E2 0.00951α=0.00951 15, α(K)=0.00821 12, α(L)=0.00106 7, α(M)=0.000205 13, α(N)=3.73×10-5 20, α(O)=2.63E-6 5, α(N+)=3.99E-5 20
5+,6+,7+      472.95 3 M1,E2 0.00828α=0.00828 13, α(K)=0.00716 14, α(L)=0.00091 4, α(M)=0.000177 9, α(N)=3.23×10-5 13, α(O)=2.29E-6 6, α(N+)=3.46E-5 13
    887.40 4+,5+,6+      541.03 8 M1,E2 0.00581α=0.00581 22, α(K)=0.00503 21, α(L)=0.000632 10, α(M)=0.0001226 19, α(N)=2.24×10-5 4, α(O)=1.60E-6 8, α(N+)=2.40E-5
4+,5+,6+      566.24 7 M1,E2 0.00517α=0.00517 23, α(K)=0.00448 22, α(L)=0.000560 9, α(M)=0.0001086 16, α(N)=1.98×10-5 4, α(O)=1.43E-6 8, α(N+)=2.12E-5 5
    958.46 3+      612.19 5 M1+E2+0.23 160.00444α=0.00444 8, α(K)=0.00387 7, α(L)=0.000466 7, α(M)=9.02×10-5 13, α(N)=1.654E-5 25, α(O)=1.239E-6 22, α(N+)=1.78E-5 3
3+      624.41 6 M1+E2 0.00403α=0.00403 24, α(K)=0.00350 22, α(L)=0.000433 14, α(M)=8.40×10-5 25, α(N)=1.53E-5 6, α(O)=1.11E-6 8, α(N+)=1.65E-5 6
3+      637.27 3 M1(+E2)-0.05 160.00406α=0.00406 6, α(K)=0.00354 6, α(L)=0.000424 6, α(M)=8.20×10-5 12, α(N)=1.506E-5 22, α(O)=1.133E-6 17, α(N+)=1.619E-5 24
3+      756.03 6 M1+E2 0.00253α=0.00253 20, α(K)=0.00220 18, α(L)=0.000268 16, α(M)=5.2×10-5 3, α(N)=9.5E-6 6, α(O)=7.0E-7 7, α(N+)=1.02E-5 7
3+      896.31 6 M1+E2-0.23 160.00183α=0.00183 4, α(K)=0.00160 3, α(L)=0.000190 4, α(M)=3.67×10-5 7, α(N)=6.73E-6 12, α(O)=5.07E-7 10, α(N+)=7.24E-6 13
    989.84 2-      233.31 4 M1(+E2) 0.065α=0.065 15, α(K)=0.055 11, α(L)=0.008 3, α(M)=0.0016 6, α(N)=0.00028 10, α(O)=1.8×10-5 4, α(N+)=0.00030 10
2-      448.61 5 E1 0.00292α=0.00292 4, α(K)=0.00255 4, α(L)=0.000303 5, α(M)=5.85×10-5 9, α(N)=1.068E-5 15, α(O)=7.72E-7 11, α(N+)=1.146E-5 16
2-      647.27 4 E1(+M2)-0.03 120.00126α=0.00126 22, α(K)=0.00110 19, α(L)=0.000130 24, α(M)=2.5×10-5 5, α(N)=4.6E-6 9, α(O)=3.4E-7 7, α(N+)=4.9E-6 10
2-      787.48 6 E1(+M2)-0.18 300.0010α=0.0010 9, α(K)=0.0009 8, α(L)=0.00010 10, α(M)=2.0×10-5 20, α(N)=4.E-6 4, α(O)=3.E-7 3, α(N+)=4.E-6 4
2-      927.74 5 E1(+M2)-0.03 140.00060α=0.00060 10, α(K)=0.00052 9, α(L)=6.1×10-5 11, α(M)=1.18E-5 21, α(N)=2.2E-6 4, α(O)=1.6E-7 3, α(N+)=2.3E-6 5
   1006.06 (5,6) ≥ 1.7 ps    149.80 2 M1 0.1656B(M1)(W.u.)<3.1, α=0.1656, α(K)=0.1434 20, α(L)=0.0180 3, α(M)=0.00349 5, α(N)=0.000639 9, α(O)=4.73×10-5 7, α(N+)=0.000687 10
   1017.93 9- ≥ 1.2 ps    209.80 4 M1+E2 0.090α=0.090 24, α(K)=0.076 18, α(L)=0.012 5, α(M)=0.0023 9, α(N)=0.00041 16, α(O)=2.5×10-5 6, α(N+)=0.00043 16
   1020.81 5+,6+      452.35 5 M1,E2 0.00934α=0.00934 14, α(K)=0.00806 12, α(L)=0.00103 6, α(M)=0.000201 12, α(N)=3.66×10-5 19, α(O)=2.58E-6 5, α(N+)=3.92E-5 19
5+,6+     1020.84 6 M1,E2 0.00127α=0.00127 11, α(K)=0.00110 10, α(L)=0.000132 11, α(M)=2.55×10-5 20, α(N)=4.7E-6 4, α(O)=3.5E-7 4, α(N+)=5.0E-6 4
E(level)
(keV)		Jπ(level)T1/2(level)E(γ)
(keV)		MultipolarityMixing
Ratio		Conversion
Coefficient		Additional Data
   1023.40 3-      961.32 3 E1 0.000556α=0.000556 8, α(K)=0.000486 7, α(L)=5.67×10-5 8, α(M)=1.092E-5 16, α(N)=2.00E-6 3, α(O)=1.484E-7 21, α(N+)=2.15E-6 3
   1049.88 1+,2+ 1.0 ps +9-4     707.34 4 M1(+E2)+0.05 50.00318B(E2)(W.u.)=(0.2 +4-2), B(M1)(W.u.)=(0.042 +18-39), α=0.00318 5, α(K)=0.00277 4, α(L)=0.000331 5, α(M)=6.40E-5 9, α(N)=1.175E-5 17, α(O)=8.85E-7 13, α(N+)=1.264E-5 18
1+,2+ 1.0 ps +9-4     715.72 8 (M1) 0.00309B(M1)(W.u.)=0.0049 +23-46, α=0.00309 5, α(K)=0.00270 4, α(L)=0.000322 5, α(M)=6.23×10-5 9, α(N)=1.143E-5 16, α(O)=8.61E-7 12, α(N+)=1.229E-5 18
1+,2+ 1.0 ps +9-4     987.81 4 M1(+E2)+0.07 210.00148B(E2)(W.u.)=(0.02 +14-2), B(M1)(W.u.)=(0.0054 +23-49), α=0.00148 3, α(K)=0.001292 23, α(L)=0.000153 3, α(M)=2.95E-5 5, α(N)=5.43E-6 10, α(O)=4.10E-7 8, α(N+)=5.84E-6 10
   1118.45      751.93 10 M1,E2 0.00256α=0.00256 20, α(K)=0.00223 18, α(L)=0.000272 16, α(M)=5.3×10-5 3, α(N)=9.6E-6 6, α(O)=7.1E-7 7, α(N+)=1.03E-5 7
   1119.82 (0)-      363.24 4 E2 0.0183α=0.0183, α(K)=0.01561 22, α(L)=0.00222 4, α(M)=0.000435 6, α(N)=7.80×10-5 11, α(O)=4.95E-6 7, α(N+)=8.30E-5 12
(0)-      777.32 6 E1 0.000849α=0.000849 12, α(K)=0.000742 11, α(L)=8.70×10-5 13, α(M)=1.677E-5 24, α(N)=3.07E-6 5, α(O)=2.26E-7 4, α(N+)=3.30E-6
   1134.07 3-,4-      377.51 2 M1,E2 0.0154α=0.0154 9, α(K)=0.0133 7, α(L)=0.00175 21, α(M)=0.00034 5, α(N)=6.2×10-5 7, α(O)=4.25E-6 16, α(N+)=6.6E-5 8
   1190.93 1-,2-,3-      434.35 3 M1(+E2)0.02 110.01026α=0.01026, α(K)=0.00893 13, α(L)=0.001083 16, α(M)=0.000210 3, α(N)=3.85×10-5 6, α(O)=2.88E-6 4, α(N+)=4.14E-5 6
   1204.87 4-,5-,6- ≥ 1.1 ps    198.81 4 M1+E2 0.11α=0.11 3, α(K)=0.090 23, α(L)=0.014 6, α(M)=0.0028 12, α(N)=0.00049 20, α(O)=2.9×10-5 8, α(N+)=0.00052 21
   1216.80 2+,3+,4+      870.39 10 M1,E2 0.00182α=0.00182 16, α(K)=0.00158 14, α(L)=0.000191 14, α(M)=3.7×10-5 3, α(N)=6.8E-6 5, α(O)=5.0E-7 5, α(N+)=7.3E-6 6
2+,3+,4+      882.69 7 M1,E2 0.00176α=0.00176 16, α(K)=0.00153 14, α(L)=0.000185 14, α(M)=3.6×10-5 3, α(N)=6.5E-6 5, α(O)=4.8E-7 5, α(N+)=7.0E-6 6
   1239.93 1-,2-,3-      483.34 5 M1,E2 0.00781α=0.00781 14, α(K)=0.00675 15, α(L)=0.00086 4, α(M)=0.000167 7, α(N)=3.04×10-5 10, α(O)=2.16E-6 7, α(N+)=3.26E-5 10
1-,2-,3-      905.92 10 E1 0.000624α=0.000624 9, α(K)=0.000546 8, α(L)=6.37×10-5 9, α(M)=1.227E-5 18, α(N)=2.25E-6 4, α(O)=1.665E-7 24, α(N+)=2.41E-6 4
   1254.91 0-,1-,2-      498.31 7 M1,E2 0.00721α=0.00721 16, α(K)=0.00623 18, α(L)=0.000790 23, α(M)=0.000153 5, α(N)=2.79×10-5 7, α(O)=1.99E-6 7, α(N+)=2.99E-5 7
0-,1-,2-      912.41 8 E1 0.000615α=0.000615 9, α(K)=0.000538 8, α(L)=6.28×10-5 9, α(M)=1.210E-5 17, α(N)=2.22E-6 4, α(O)=1.642E-7 23, α(N+)=2.38E-6 4
   1280.23 +      487.19 8 (M1,E2) 0.00765α=0.00765 15, α(K)=0.00661 16, α(L)=0.00084 3, α(M)=0.000163 7, α(N)=2.97×10-5 10, α(O)=2.11E-6 7, α(N+)=3.19E-5 9
   1396.34 9+      681.5 10 M1+E2 0.00325α=0.00325 23, α(K)=0.00282 21, α(L)=0.000347 16, α(M)=6.7×10-5 3, α(N)=1.23E-5 6, α(O)=9.0E-7 8, α(N+)=1.32E-5 7
9+     1396.4 1 E2 0.000647α=0.000647 9, α(K)=0.000523 8, α(L)=6.20×10-5 9, α(M)=1.197E-5 17, α(N)=2.19E-6 3, α(O)=1.629E-7 23, α(N+)=5.00E-5 7
   1494.00 -      487.94 17 (M1,E2) 0.00762α=0.00762 15, α(K)=0.00659 16, α(L)=0.00084 3, α(M)=0.000163 6, α(N)=2.96×10-5 9, α(O)=2.10E-6 7, α(N+)=3.17E-5 9
   1561.59 10-      543.7 1 M1+E2 0.00574α=0.00574 22, α(K)=0.00497 22, α(L)=0.000624 9, α(M)=0.0001210 18, α(N)=2.21×10-5 4, α(O)=1.58E-6 8, α(N+)=2.37E-5 4
10-      753.6 7 (E2) 0.00235α=0.00235 4, α(K)=0.00204 3, α(L)=0.000255 4, α(M)=4.95×10-5 7, α(N)=9.01E-6 13, α(O)=6.42E-7 10, α(N+)=9.65E-6 14
   1617.49 8-      599.3 1 M1+E2 0.00447α=0.00447 24, α(K)=0.00388 23, α(L)=0.000482 12, α(M)=9.35×10-5 21, α(N)=1.71E-5 5, α(O)=1.23E-6 8, α(N+)=1.83E-5 6
8-      809.9 1 M1+E2 0.00215α=0.00215 18, α(K)=0.00187 16, α(L)=0.000227 15, α(M)=4.4×10-5 3, α(N)=8.0E-6 6, α(O)=5.9E-7 6, α(N+)=8.6E-6 6
8-      817.4 1 M1+E2 0.00210α=0.00210 18, α(K)=0.00183 16, α(L)=0.000222 15, α(M)=4.3×10-5 3, α(N)=7.9E-6 6, α(O)=5.8E-7 6, α(N+)=8.4E-6 6
8-     1617.0 4 E1 0.000541α=0.000541 8, α(K)=0.000193 3, α(L)=2.22×10-5 4, α(M)=4.28E-6 6, α(N)=7.86E-7 11, α(O)=5.89E-8 9, α(N+)=0.000322 5
E(level)
(keV)		Jπ(level)T1/2(level)E(γ)
(keV)		MultipolarityMixing
Ratio		Conversion
Coefficient		Additional Data
   1886.23 10-     1078.1 1 E2 0.001027α=0.001027 15, α(K)=0.000894 13, α(L)=0.0001080 16, α(M)=2.09×10-5 3, α(N)=3.82E-6 6, α(O)=2.80E-7 4, α(N+)=4.10E-6
   2110.15 10+      713.8 1 M1+E2 0.00290α=0.00290 22, α(K)=0.00252 20, α(L)=0.000309 16, α(M)=6.0×10-5 3, α(N)=1.09E-5 6, α(O)=8.0E-7 7, α(N+)=1.17E-5 7
   2129.14 10-      243.0 1 M1+E2 0.057α=0.057 12, α(K)=0.048 9, α(L)=0.0070 22, α(M)=0.0014 5, α(N)=0.00025 8, α(O)=1.6×10-5 3, α(N+)=0.00026 8
10-      567.2 1 M1+E2 0.00514α=0.00514 23, α(K)=0.00446 22, α(L)=0.000557 9, α(M)=0.0001081 17, α(N)=1.97×10-5 4, α(O)=1.42E-6 8, α(N+)=2.11E-5 5
10-      732.3 2 E1 0.000962α=0.000962 14, α(K)=0.000841 12, α(L)=9.87×10-5 14, α(M)=1.90E-5 3, α(N)=3.48E-6 5, α(O)=2.56E-7 4, α(N+)=3.74E-6 6
10-     1111.2 2 M1+E2 0.00105α=0.00105 9, α(K)=0.00092 8, α(L)=0.000109 9, α(M)=2.11×10-5 17, α(N)=3.9E-6 3, α(O)=2.9E-7 3, α(N+)=4.8E-6 3
10-     1321.2 1 E2 0.000698α=0.000698 10, α(K)=0.000584 9, α(L)=6.96×10-5 10, α(M)=1.343E-5 19, α(N)=2.46E-6 4, α(O)=1.82E-7 3, α(N+)=3.06E-5 5
   2174.91 11-      613.0 1 M1+E2 0.00422α=0.00422 24, α(K)=0.00366 23, α(L)=0.000455 13, α(M)=8.81×10-5 23, α(N)=1.61E-5 5, α(O)=1.17E-6 8, α(N+)=1.73E-5 6
11-     1157.0 1 E2 0.000886α=0.000886 13, α(K)=0.000769 11, α(L)=9.24×10-5 13, α(M)=1.79E-5 3, α(N)=3.27E-6 5, α(O)=2.40E-7 4, α(N+)=6.31E-6 9
   2201.99 10-      315.6 1 M1+E2 0.026α=0.026 3, α(K)=0.0221 23, α(L)=0.0030 6, α(M)=0.00059 12, α(N)=0.000106 20, α(O)=7.1×10-6 7, α(N+)=0.000113 21
10-      584.4 1 E2 0.00454α=0.00454 7, α(K)=0.00392 6, α(L)=0.000508 8, α(M)=9.87×10-5 14, α(N)=1.79E-5 3, α(O)=1.238E-6 18, α(N+)=1.91E-5 3
10-      640.6 1 M1+E2 0.00378α=0.00378 24, α(K)=0.00328 22, α(L)=0.000406 15, α(M)=7.9×10-5 3, α(N)=1.44E-5 6, α(O)=1.04E-6 8, α(N+)=1.54E-5 7
10-      805.3 2 E1 0.000790α=0.000790 11, α(K)=0.000690 10, α(L)=8.08×10-5 12, α(M)=1.558E-5 22, α(N)=2.85E-6 4, α(O)=2.11E-7 3, α(N+)=3.06E-6
10-     1183.2 3 M1+E2 0.00092α=0.00092 8, α(K)=0.00080 7, α(L)=9.5×10-5 8, α(M)=1.84E-5 14, α(N)=3.4E-6 3, α(O)=2.52E-7 23, α(N+)=8.36E-6 14
   2220.65 9-      603.2 1 M1+E2 0.00440α=0.00440 24, α(K)=0.00381 23, α(L)=0.000474 12, α(M)=9.19×10-5 22, α(N)=1.68E-5 5, α(O)=1.21E-6 8, α(N+)=1.80E-5 6
9-      825.4 2 E1 0.000751α=0.000751 11, α(K)=0.000657 10, α(L)=7.68×10-5 11, α(M)=1.481E-5 21, α(N)=2.71E-6 4, α(O)=2.00E-7 3, α(N+)=2.91E-6
9-     1202.3 2 M1+E2 0.00089α=0.00089 8, α(K)=0.00077 7, α(L)=9.2×10-5 7, α(M)=1.77E-5 14, α(N)=3.3E-6 3, α(O)=2.43E-7 22, α(N+)=1.03E-5 3
   2275.59 10-     1257.3 1 M1+E2 0.00082α=0.00082 7, α(K)=0.00070 6, α(L)=8.3×10-5 7, α(M)=1.61E-5 12, α(N)=2.95E-6 23, α(O)=2.21E-7 20, α(N+)=1.78E-5 8
10-     1467.5 1 E2 0.000613α=0.000613 9, α(K)=0.000474 7, α(L)=5.60×10-5 8, α(M)=1.082E-5 16, α(N)=1.98E-6 3, α(O)=1.475E-7 21, α(N+)=7.22E-5 11
   2492.59 (11)-      363.3 1 M1+E2 0.0172α=0.0172 12, α(K)=0.0148 9, α(L)=0.0020 3, α(M)=0.00038 6, α(N)=6.9×10-5 9, α(O)=4.73E-6 23, α(N+)=7.4E-5 9
   2596.95 12-      104.2 1 M1+E2 0.9α=0.9 5, α(K)=0.7 3, α(L)=0.16 12, α(M)=0.032 23, α(N)=0.006 4, α(O)=0.00024 12, α(N+)=0.006 4
12-      421.9 1 M1+E2 0.0113α=0.0113 4, α(K)=0.00974 20, α(L)=0.00126 10, α(M)=0.000245 21, α(N)=4.5×10-5 4, α(O)=3.12E-6 5, α(N+)=4.8E-5 4
12-     1035.6 1 E2 0.001122α=0.001122 16, α(K)=0.000976 14, α(L)=0.0001183 17, α(M)=2.29×10-5 4, α(N)=4.18E-6 6, α(O)=3.06E-7 5, α(N+)=4.49E-6
   2607.45 11-      331.5 1 M1+E2 0.0224α=0.0224 22, α(K)=0.0192 17, α(L)=0.0026 5, α(M)=0.00051 9, α(N)=9.1×10-5 15, α(O)=6.2E-6 5, α(N+)=9.8E-5 16
11-     1046.1 1 M1+E2 0.00120α=0.00120 11, α(K)=0.00105 10, α(L)=0.000125 10, α(M)=2.42×10-5 19, α(N)=4.4E-6 4, α(O)=3.3E-7 4, α(N+)=4.8E-6 4
11-     1589.9 1 E2 0.000579α=0.000579 9, α(K)=0.000405 6, α(L)=4.77×10-5 7, α(M)=9.21E-6 13, α(N)=1.689E-6 24, α(O)=1.260E-7 18, α(N+)=0.0001173 17
E(level)
(keV)		Jπ(level)T1/2(level)E(γ)
(keV)		MultipolarityMixing
Ratio		Conversion
Coefficient		Additional Data
   2687.0 (10+)     1290.7 5 M1+E2 0.00078α=0.00078 6, α(K)=0.00067 6, α(L)=7.9×10-5 6, α(M)=1.52E-5 12, α(N)=2.79E-6 21, α(O)=2.09E-7 18, α(N+)=2.33E-5 12
   2764.86 12-      590.1 1 M1+E2 0.00465α=0.00465 24, α(K)=0.00403 23, α(L)=0.000502 11, α(M)=9.74×10-5 20, α(N)=1.78E-5 5, α(O)=1.28E-6 8, α(N+)=1.91E-5 5
12-     1203.2 1 E2 0.000820α=0.000820 12, α(K)=0.000708 10, α(L)=8.49×10-5 12, α(M)=1.640E-5 23, α(N)=3.00E-6 5, α(O)=2.21E-7 3, α(N+)=1.065E-5
   2798.43 11-      578.0 1 E2 0.00468α=0.00468 7, α(K)=0.00403 6, α(L)=0.000524 8, α(M)=0.0001019 15, α(N)=1.85×10-5 3, α(O)=1.275E-6 18, α(N+)=1.97E-5 3
11-      596.2 1 M1+E2 0.00453α=0.00453 24, α(K)=0.00393 23, α(L)=0.000489 12, α(M)=9.48×10-5 21, α(N)=1.73E-5 5, α(O)=1.25E-6 8, α(N+)=1.85E-5 6
11-      669.3 1 M1+E2 0.00340α=0.00340 23, α(K)=0.00295 21, α(L)=0.000363 16, α(M)=7.0×10-5 3, α(N)=1.29E-5 6, α(O)=9.4E-7 8, α(N+)=1.38E-5 7
   2837.98 13-      241.1 1 M1+E2 0.058α=0.058 13, α(K)=0.049 10, α(L)=0.0072 23, α(M)=0.0014 5, α(N)=0.00025 8, α(O)=1.6×10-5 3, α(N+)=0.00027 8
   2854.35 (11+)      744.2 2 M1+E2 0.00263α=0.00263 21, α(K)=0.00228 19, α(L)=0.000279 16, α(M)=5.4×10-5 3, α(N)=9.9E-6 6, α(O)=7.2E-7 7, α(N+)=1.06E-5 7
   2908.48 (12-)      301.3 1 M1+E2 0.030α=0.030 4, α(K)=0.025 3, α(L)=0.0035 8, α(M)=0.00068 15, α(N)=0.00012 3, α(O)=8.1×10-6 9, α(N+)=0.00013 3
(12-)      733.4 1 M1+E2 0.00272α=0.00272 21, α(K)=0.00236 19, α(L)=0.000289 16, α(M)=5.6×10-5 3, α(N)=1.02E-5 6, α(O)=7.5E-7 7, α(N+)=1.10E-5 7
(12-)     1346.5 2 E2 0.000678α=0.000678 10, α(K)=0.000562 8, α(L)=6.69×10-5 10, α(M)=1.291E-5 18, α(N)=2.37E-6 4, α(O)=1.753E-7 25, α(N+)=3.66E-5 6
   3080.00 12-      878.0 1 E2 0.001630α=0.001630 23, α(K)=0.001416 20, α(L)=0.0001743 25, α(M)=3.37×10-5 5, α(N)=6.16E-6 9, α(O)=4.45E-7 7, α(N+)=6.60E-6
   3192.14 14- 0.868 ps +24-25     354.6 1 M1+E2 0.0184α=0.0184 14, α(K)=0.0158 11, α(L)=0.0021 3, α(M)=0.00041 6, α(N)=7.4×10-5 11, α(O)=5.1E-6 3, α(N+)=7.9E-5 11
   3196.98 (13-)      288.5 1 M1+E2 0.034α=0.034 5, α(K)=0.029 4, α(L)=0.0040 10, α(M)=0.00078 19, α(N)=0.00014 4, α(O)=9.3×10-6 11, α(N+)=0.00015 4
   3245.11 (10,11)-     1070.1 1 M1+E2 0.00114α=0.00114 10, α(K)=0.00100 9, α(L)=0.000119 10, α(M)=2.30×10-5 18, α(N)=4.2E-6 4, α(O)=3.1E-7 3, α(N+)=4.5E-6 4
(10,11)-     1115.9 1 M1+E2 0.00104α=0.00104 9, α(K)=0.00091 8, α(L)=0.000108 9, α(M)=2.09×10-5 16, α(N)=3.8E-6 3, α(O)=2.9E-7 3, α(N+)=4.9E-6 3
(10,11)-     1684.1 5 M1+E2 0.000591α=0.000591 23, α(K)=0.000386 25, α(L)=4.5×10-5 3, α(M)=8.7E-6 6, α(N)=1.60E-6 10, α(O)=1.21E-7 9, α(N+)=0.000151 6
   3326.98 11+     1765.5 1 E1 0.000625α=0.000625 9, α(K)=0.0001675 24, α(L)=1.93×10-5 3, α(M)=3.71E-6 6, α(N)=6.80E-7 10, α(O)=5.10E-8 8, α(N+)=0.000435 6
   3344.78 (14)-      506.8 1 M1+E2 0.00689α=0.00689 18, α(K)=0.00596 19, α(L)=0.000755 19, α(M)=0.000146 4, α(N)=2.67×10-5 6, α(O)=1.90E-6 8, α(N+)=2.86E-5 6
   3371.31 13-     1196.4 2 E2 0.000829α=0.000829 12, α(K)=0.000717 10, α(L)=8.59×10-5 12, α(M)=1.660E-5 24, α(N)=3.04E-6 5, α(O)=2.24E-7 4, α(N+)=9.84E-6
   3512.46 12+      185.6 1 M1+E2 0.13α=0.13 4, α(K)=0.11 3, α(L)=0.018 8, α(M)=0.0035 16, α(N)=0.0006 3, α(O)=3.6×10-5 10, α(N+)=0.0007 3
12+      267.2 1 E1 0.01109α=0.01109, α(K)=0.00966 14, α(L)=0.001164 17, α(M)=0.000224 4, α(N)=4.08×10-5 6, α(O)=2.87E-6 4, α(N+)=4.37E-5 7
12+     1337.7 1 E1 0.000418α=0.000418 6, α(K)=0.000266 4, α(L)=3.07×10-5 5, α(M)=5.92E-6 9, α(N)=1.086E-6 16, α(O)=8.11E-8 12, α(N+)=0.0001154 17
   3629.03 13-      830.6 1 E2 0.00186α=0.00186 3, α(K)=0.001612 23, α(L)=0.000200 3, α(M)=3.87×10-5 6, α(N)=7.05E-6 10, α(O)=5.07E-7 7, α(N+)=7.56E-6 11
   3697.69 12-     1522.6 1 M1+E2 0.00063α=0.00063 4, α(K)=0.00047 4, α(L)=5.6×10-5 4, α(M)=1.07E-5 8, α(N)=1.97E-6 14, α(O)=1.48E-7 12, α(N+)=8.8E-5 4
E(level)
(keV)		Jπ(level)T1/2(level)E(γ)
(keV)		MultipolarityMixing
Ratio		Conversion
Coefficient		Additional Data
   3713.24 15- 0.50 ps +4-3     521.1 1 M1+E2 0.00641α=0.00641 19, α(K)=0.00554 20, α(L)=0.000699 14, α(M)=0.000136 3, α(N)=2.47×10-5 5, α(O)=1.77E-6 8, α(N+)=2.65E-5 4
   3719.82 13+      207.5 1 M1+E2 0.093α=0.093 25, α(K)=0.078 19, α(L)=0.012 5, α(M)=0.0024 10, α(N)=0.00042 16, α(O)=2.5×10-5 6, α(N+)=0.00045 17
13+      955.3 1 E1 0.000563α=0.000563 8, α(K)=0.000492 7, α(L)=5.74×10-5 8, α(M)=1.105E-5 16, α(N)=2.02E-6 3, α(O)=1.502E-7 21, α(N+)=2.17E-6 3
13+     1122.7 1 E1 0.000423α=0.000423 6, α(K)=0.000363 5, α(L)=4.22×10-5 6, α(M)=8.12E-6 12, α(N)=1.489E-6 21, α(O)=1.109E-7 16, α(N+)=8.93E-6 13
   3732.99 (14-)      536.0 1 M1+E2 0.00595α=0.00595 21, α(K)=0.00515 21, α(L)=0.000648 10, α(M)=0.0001258 21, α(N)=2.29×10-5 4, α(O)=1.64E-6 8, α(N+)=2.46E-5
   3821.18 (15-)      476.4 1 M1+E2 0.00812α=0.00812 13, α(K)=0.00702 14, α(L)=0.00089 4, α(M)=0.000174 8, α(N)=3.16×10-5 12, α(O)=2.24E-6 6, α(N+)=3.39E-5 12
   3833.00 (14-)      753.0 1 E2 0.00236α=0.00236 4, α(K)=0.00204 3, α(L)=0.000256 4, α(M)=4.96×10-5 7, α(N)=9.03E-6 13, α(O)=6.43E-7 9, α(N+)=9.67E-6 14
   3914.94 13+      217.2 1 E1 0.0195α=0.0195, α(K)=0.01699 24, α(L)=0.00206 3, α(M)=0.000397 6, α(N)=7.20×10-5 11, α(O)=5.00E-6 7, α(N+)=7.70E-5 11
13+     1077.6 2 E1 0.000448α=0.000448 7, α(K)=0.000392 6, α(L)=4.55×10-5 7, α(M)=8.77E-6 13, α(N)=1.608E-6 23, α(O)=1.196E-7 17, α(N+)=1.727E-6 25
13+     1318.0 1 E1 0.000413α=0.000413 6, α(K)=0.000273 4, α(L)=3.16×10-5 5, α(M)=6.08E-6 9, α(N)=1.114E-6 16, α(O)=8.32E-8 12, α(N+)=0.0001027 15
   3943.39 14+      223.8 1 M1+E2 0.073α=0.073 18, α(K)=0.062 14, α(L)=0.009 4, α(M)=0.0018 7, α(N)=0.00033 12, α(O)=2.0×10-5 5, α(N+)=0.00035 12
14+     1105.0 1 E1 0.000432α=0.000432 6, α(K)=0.000374 6, α(L)=4.34×10-5 6, α(M)=8.37E-6 12, α(N)=1.534E-6 22, α(O)=1.142E-7 16, α(N+)=6.11E-6 9
   3995.62 13-      297.8 1 M1+E2 0.031α=0.031 5, α(K)=0.026 4, α(L)=0.0036 8, α(M)=0.00071 16, α(N)=0.00013 3, α(O)=8.4×10-6 9, α(N+)=0.00014 3
13-     1230.5 1 M1+E2 0.00085α=0.00085 7, α(K)=0.00074 7, α(L)=8.7×10-5 7, α(M)=1.69E-5 13, α(N)=3.09E-6 24, α(O)=2.31E-7 21, α(N+)=1.38E-5 6
   4081.70 14+      166.9 1 M1+E2 0.19α=0.19 7, α(K)=0.16 5, α(L)=0.026 13, α(M)=0.005 3, α(N)=0.0009 5, α(O)=5.1×10-5 16, α(N+)=0.0010 5
14+     1243.8 1 E1 0.000404α=0.000404 6, α(K)=0.000302 5, α(L)=3.50×10-5 5, α(M)=6.74E-6 10, α(N)=1.235E-6 18, α(O)=9.22E-8 13, α(N+)=6.00E-5 9
   4156.50 14-     1076.5 1 E2 0.001030α=0.001030 15, α(K)=0.000897 13, α(L)=0.0001084 16, α(M)=2.10×10-5 3, α(N)=3.83E-6 6, α(O)=2.81E-7 4, α(N+)=4.11E-6
   4228.98 15+ 0.435 ps +17-16     147.4 1 M1+E2 0.28α=0.28 11, α(K)=0.23 8, α(L)=0.042 23, α(M)=0.008 5, α(N)=0.0015 8, α(O)=8.E-5 3, α(N+)=0.0015 9
15+ 0.435 ps +17-16     285.4 1 M1+E2 0.035α=0.035 6, α(K)=0.030 4, α(L)=0.0041 10, α(M)=0.00081 20, α(N)=0.00015 4, α(O)=9.6×10-6 12, α(N+)=0.00016 4
   4263.99 14-      268.0 1 M1+E2 0.042α=0.042 8, α(K)=0.036 6, α(L)=0.0051 14, α(M)=0.0010 3, α(N)=0.00018 5, α(O)=1.15×10-5 17, α(N+)=0.00019 5
14-     1425.6 2 M1+E2 0.00067α=0.00067 5, α(K)=0.00054 4, α(L)=6.4×10-5 5, α(M)=1.23E-5 9, α(N)=2.26E-6 16, α(O)=1.70E-7 14, α(N+)=5.6E-5 3
   4323.05 13-,14-,15-     1130.9 2 M1+E2 0.00101α=0.00101 9, α(K)=0.00088 8, α(L)=0.000105 8, α(M)=2.03×10-5 16, α(N)=3.7E-6 3, α(O)=2.8E-7 3, α(N+)=5.27E-6 23
   4370.60 15+      289.0 1 M1+E2 0.034α=0.034 5, α(K)=0.029 4, α(L)=0.0040 10, α(M)=0.00078 19, α(N)=0.00014 4, α(O)=9.2×10-6 11, α(N+)=0.00015 4
15+     1178.3 2 E1 0.000405α=0.000405 6, α(K)=0.000333 5, α(L)=3.86×10-5 6, α(M)=7.43E-6 11, α(N)=1.363E-6 19, α(O)=1.015E-7 15, α(N+)=2.63E-5 4
   4528.31 16-      815.0 1 M1+E2 0.00212α=0.00212 18, α(K)=0.00184 16, α(L)=0.000223 15, α(M)=4.3×10-5 3, α(N)=7.9E-6 6, α(O)=5.8E-7 6, α(N+)=8.5E-6 6
E(level)
(keV)		Jπ(level)T1/2(level)E(γ)
(keV)		MultipolarityMixing
Ratio		Conversion
Coefficient		Additional Data
   4561.77 15(-)      297.3 1 M1+E2 0.031α=0.031 5, α(K)=0.026 4, α(L)=0.0036 8, α(M)=0.00071 16, α(N)=0.00013 3, α(O)=8.5×10-6 10, α(N+)=0.00014 3
15(-)     1370.1 1 M1+E2 0.00071α=0.00071 5, α(K)=0.00059 5, α(L)=6.9×10-5 5, α(M)=1.34E-5 10, α(N)=2.46E-6 18, α(O)=1.84E-7 16, α(N+)=4.06E-5 21
   4598.02 16+ 0.297 ps +6-11     369.0 1 M1+E2 0.0164α=0.0164 11, α(K)=0.0141 8, α(L)=0.00187 24, α(M)=0.00036 5, α(N)=6.6×10-5 8, α(O)=4.53E-6 20, α(N+)=7.1E-5 9
   4602.10 (16-)      769.1 1 E2 0.00224α=0.00224 4, α(K)=0.00194 3, α(L)=0.000242 4, α(M)=4.69×10-5 7, α(N)=8.55E-6 12, α(O)=6.10E-7 9, α(N+)=9.16E-6 13
   4606.03 15-      977.0 1 E2 0.001277α=0.001277 18, α(K)=0.001110 16, α(L)=0.0001353 19, α(M)=2.62×10-5 4, α(N)=4.78E-6 7, α(O)=3.48E-7 5, α(N+)=5.13E-6
   4802.89 (17-)      981.7 1 E2 0.001263α=0.001263 18, α(K)=0.001098 16, α(L)=0.0001338 19, α(M)=2.59×10-5 4, α(N)=4.73E-6 7, α(O)=3.44E-7 5, α(N+)=5.07E-6
   4802.95 16+      432.4 1 M1+E2 0.01056α=0.01056 24, α(K)=0.00911 15, α(L)=0.00118 9, α(M)=0.000229 17, α(N)=4.2×10-5 3, α(O)=2.91E-6 4, α(N+)=4.4E-5 3
   4942.2 16-     1750.0 3 E2 0.000570α=0.000570 8, α(K)=0.000337 5, α(L)=3.96×10-5 6, α(M)=7.63E-6 11, α(N)=1.400E-6 20, α(O)=1.048E-7 15, α(N+)=0.000185 3
   4995.57 16(-)      433.8 1 M1+E2 0.01047α=0.01047 23, α(K)=0.00903 15, α(L)=0.00117 9, α(M)=0.000227 17, α(N)=4.1×10-5 3, α(O)=2.89E-6 4, α(N+)=4.4E-5 3
   5045.60 13+,14+,15+     1102.2 1 M1+E2 0.00107α=0.00107 10, α(K)=0.00093 9, α(L)=0.000111 9, α(M)=2.15×10-5 17, α(N)=3.9E-6 3, α(O)=2.9E-7 3, α(N+)=4.7E-6 3
   5084.90 17+ 0.159 ps +24-18     486.9 1 M1+E2 0.00766α=0.00766 14, α(K)=0.00662 16, α(L)=0.00084 3, α(M)=0.000164 7, α(N)=2.98×10-5 10, α(O)=2.12E-6 7, α(N+)=3.19E-5 9
17+ 0.159 ps +24-18     855.9 1 E2 0.001730B(E2)(W.u.)=18.5 +25-31, α=0.001730 25, α(K)=0.001502 21, α(L)=0.000185 3, α(M)=3.59E-5 5, α(N)=6.55E-6 10, α(O)=4.72E-7 7, α(N+)=7.02E-6 10
   5180.81 16-     1024.3 1 E2 0.001149α=0.001149 16, α(K)=0.001000 14, α(L)=0.0001213 17, α(M)=2.35×10-5 4, α(N)=4.29E-6 6, α(O)=3.13E-7 5, α(N+)=4.60E-6
   5265.18 17-      736.8 1 M1+E2 0.00269α=0.00269 21, α(K)=0.00234 19, α(L)=0.000286 16, α(M)=5.5×10-5 3, α(N)=1.01E-5 6, α(O)=7.4E-7 7, α(N+)=1.09E-5 7
17-     1552.0 2 E2 0.000587α=0.000587 9, α(K)=0.000425 6, α(L)=5.01×10-5 7, α(M)=9.67E-6 14, α(N)=1.772E-6 25, α(O)=1.321E-7 19, α(N+)=0.0001025 15
   5283.39 17(+)      480.5 1 M1+E2 0.00794α=0.00794 14, α(K)=0.00686 15, α(L)=0.00087 4, α(M)=0.000170 7, α(N)=3.09×10-5 11, α(O)=2.19E-6 7, α(N+)=3.31E-5 11
   5403.27 17-     1690.2 2 E2 0.000570α=0.000570 8, α(K)=0.000360 5, α(L)=4.23×10-5 6, α(M)=8.17E-6 12, α(N)=1.498E-6 21, α(O)=1.120E-7 16, α(N+)=0.0001590 23
   5545.88 (17-)      550.3 1 M1+E2 0.00556α=0.00556 22, α(K)=0.00482 22, α(L)=0.000604 9, α(M)=0.0001172 17, α(N)=2.14×10-5 4, α(O)=1.54E-6 8, α(N+)=2.29E-5 4
   5556.44 17(-) 0.54 ps +7-6     950.4 1 E2 0.001359B(E2)(W.u.)=43 +5-6, α=0.001359 19, α(K)=0.001181 17, α(L)=0.0001443 21, α(M)=2.79E-5 4, α(N)=5.10E-6 8, α(O)=3.71E-7 6, α(N+)=5.47E-6
   5561.68 (17-)      566.1 1 M1+E2 0.00517α=0.00517 23, α(K)=0.00448 22, α(L)=0.000560 9, α(M)=0.0001086 16, α(N)=1.98×10-5 4, α(O)=1.43E-6 8, α(N+)=2.12E-5 5
   5650.39 18+ 0.136 ps +15-13     366.9 1 M1+E2 0.0167α=0.0167 11, α(K)=0.0144 8, α(L)=0.00190 25, α(M)=0.00037 5, α(N)=6.7×10-5 9, α(O)=4.60E-6 21, α(N+)=7.2E-5 9
18+ 0.136 ps +15-13     565.6 1 M1+E2 0.00518α=0.00518 23, α(K)=0.00449 22, α(L)=0.000561 9, α(M)=0.0001089 16, α(N)=1.99×10-5 4, α(O)=1.43E-6 8, α(N+)=2.13E-5 5
18+ 0.136 ps +15-13    1052.3 1 E2 0.001083B(E2)(W.u.)=10.1 +13-14, α=0.001083 16, α(K)=0.000942 14, α(L)=0.0001141 16, α(M)=2.21E-5 3, α(N)=4.03E-6 6, α(O)=2.95E-7 5, α(N+)=4.33E-6
   5687.23 16-,17-,18-      284.0 1 M1+E2 0.035α=0.035 6, α(K)=0.030 4, α(L)=0.0042 10, α(M)=0.00082 21, α(N)=0.00015 4, α(O)=9.7×10-6 12, α(N+)=0.00016 4
16-,17-,18-      422.0 1 M1+E2 0.0113α=0.0113 3, α(K)=0.00973 20, α(L)=0.00126 10, α(M)=0.000245 21, α(N)=4.5×10-5 4, α(O)=3.11E-6 5, α(N+)=4.8E-5 4
E(level)
(keV)		Jπ(level)T1/2(level)E(γ)
(keV)		MultipolarityMixing
Ratio		Conversion
Coefficient		Additional Data
   5825.10 (16+,17+,18+)      740.2 1 M1+E2 0.00266α=0.00266 21, α(K)=0.00231 19, α(L)=0.000282 16, α(M)=5.5×10-5 3, α(N)=1.00E-5 6, α(O)=7.3E-7 7, α(N+)=1.07E-5 7
   5833.45 (18+)      550.2 1 M1+E2 0.00556α=0.00556 22, α(K)=0.00482 22, α(L)=0.000604 9, α(M)=0.0001172 17, α(N)=2.14×10-5 4, α(O)=1.54E-6 8, α(N+)=2.29E-5 4
(18+)      748.4 1 M1+E2 0.00259α=0.00259 21, α(K)=0.00225 19, α(L)=0.000275 16, α(M)=5.3×10-5 3, α(N)=9.7E-6 6, α(O)=7.1E-7 7, α(N+)=1.04E-5 7
   5839.27 (18+)      555.9 1 M1+E2 0.00542α=0.00542 23, α(K)=0.00469 22, α(L)=0.000588 9, α(M)=0.0001140 16, α(N)=2.08×10-5 4, α(O)=1.50E-6 8, α(N+)=2.23E-5 4
(18+)      754.3 2 M1+E2 0.00254α=0.00254 20, α(K)=0.00221 18, α(L)=0.000270 16, α(M)=5.2×10-5 3, α(N)=9.5E-6 6, α(O)=7.0E-7 7, α(N+)=1.02E-5 7
   6062.11 18-      881.3 1 E2 0.001616α=0.001616 23, α(K)=0.001403 20, α(L)=0.0001727 25, α(M)=3.34×10-5 5, α(N)=6.10E-6 9, α(O)=4.41E-7 7, α(N+)=6.54E-6
   6095.43 (19)-      408.2 1 M1+E2 0.0124α=0.0124 5, α(K)=0.0107 3, α(L)=0.00139 13, α(M)=0.00027 3, α(N)=4.9×10-5 5, α(O)=3.41E-6 7, α(N+)=5.2E-5 5
   6223.33 19+ 0.073 ps +6-9     572.9 1 M1+E2 0.00501α=0.00501 23, α(K)=0.00434 23, α(L)=0.000543 10, α(M)=0.0001053 17, α(N)=1.92×10-5 4, α(O)=1.38E-6 8, α(N+)=2.06E-5
19+ 0.073 ps +6-9    1138.6 2 E2 0.000915B(E2)(W.u.)=16.4 +28-23, α=0.000915 13, α(K)=0.000796 12, α(L)=9.57E-5 14, α(M)=1.85E-5 3, α(N)=3.38E-6 5, α(O)=2.49E-7 4, α(N+)=5.35E-6 8
   6296.99 (19)+      646.6 1 M1+E2 0.00370α=0.00370 24, α(K)=0.00321 22, α(L)=0.000396 15, α(M)=7.7×10-5 3, α(N)=1.40E-5 6, α(O)=1.02E-6 8, α(N+)=1.51E-5 7
   6445.54 19(-) 0.38 ps +4-3     889.1 1 E2 0.001583B(E2)(W.u.)=86 +7-9, α=0.001583 23, α(K)=0.001375 20, α(L)=0.0001690 24, α(M)=3.27E-5 5, α(N)=5.97E-6 9, α(O)=4.32E-7 6, α(N+)=6.41E-6
   6707.23 (20+)      483.9 1 M1+E2 0.00779α=0.00779 14, α(K)=0.00673 15, α(L)=0.00086 4, α(M)=0.000166 7, α(N)=3.03×10-5 10, α(O)=2.15E-6 7, α(N+)=3.25E-5 10
   6992.09 (20+)      695.1 1 M1+E2 0.00310α=0.00310 22, α(K)=0.00269 21, α(L)=0.000330 16, α(M)=6.4×10-5 3, α(N)=1.17E-5 6, α(O)=8.5E-7 7, α(N+)=1.25E-5 7
   6999.21 20-      937.1 1 E2 0.001403α=0.001403 20, α(K)=0.001219 17, α(L)=0.0001491 21, α(M)=2.89×10-5 4, α(N)=5.27E-6 8, α(O)=3.83E-7 6, α(N+)=5.65E-6
   7240.6 (19)+     1590.2 3 M1+E2 0.00061α=0.00061 3, α(K)=0.00043 3, α(L)=5.1×10-5 4, α(M)=9.8E-6 7, α(N)=1.80E-6 12, α(O)=1.36E-7 10, α(N+)=0.000113 5
   7272.63 (21+)      565.4 1 M1+E2 0.00519α=0.00519 23, α(K)=0.00449 22, α(L)=0.000562 9, α(M)=0.0001090 16, α(N)=1.99×10-5 4, α(O)=1.43E-6 8, α(N+)=2.13E-5 5
   7391.75 21(-) 0.279 ps +16-12     946.2 1 E2 0.001372B(E2)(W.u.)=85 +4-5, α=0.001372 20, α(K)=0.001193 17, α(L)=0.0001458 21, α(M)=2.82E-5 4, α(N)=5.15E-6 8, α(O)=3.74E-7 6, α(N+)=5.53E-6
   7980.84 (22+)      708.2 1 M1+E2 0.00296α=0.00296 22, α(K)=0.00257 20, α(L)=0.000315 16, α(M)=6.1×10-5 3, α(N)=1.12E-5 6, α(O)=8.2E-7 7, α(N+)=1.20E-5 7
   8087.8 (22-)     1088.6 1 E2 0.001006α=0.001006 14, α(K)=0.000876 13, α(L)=0.0001057 15, α(M)=2.04×10-5 3, α(N)=3.74E-6 6, α(O)=2.74E-7 4, α(N+)=4.01E-6
   8463.8 (23-) 0.142 ps +13-10    1072.0 1 E2 0.001040B(E2)(W.u.)=90 +7-9, α=0.001040 15, α(K)=0.000905 13, α(L)=0.0001094 16, α(M)=2.12E-5 3, α(N)=3.87E-6 6, α(O)=2.83E-7 4, α(N+)=4.15E-6
   8747.7 (23+)      766.9 1 M1+E2 0.00244α=0.00244 20, α(K)=0.00212 18, α(L)=0.000259 16, α(M)=5.0×10-5 3, α(N)=9.2E-6 6, α(O)=6.7E-7 6, α(N+)=9.8E-6 7
   9398.2 (24-)     1310.4 2 E2 0.000707α=0.000707 10, α(K)=0.000594 9, α(L)=7.08×10-5 10, α(M)=1.367E-5 20, α(N)=2.50E-6 4, α(O)=1.85E-7 3, α(N+)=2.83E-5 4
   9698.7 (25-)     1234.9 1 E2 0.000782α=0.000782 11, α(K)=0.000671 10, α(L)=8.02×10-5 12, α(M)=1.551E-5 22, α(N)=2.84E-6 4, α(O)=2.10E-7 3, α(N+)=1.498E-5
  11117.8 (27-)     1419.1 1 E2 0.000634α=0.000634 9, α(K)=0.000506 7, α(L)=6.00×10-5 9, α(M)=1.158E-5 17, α(N)=2.12E-6 3, α(O)=1.577E-7 22, α(N+)=5.68E-5 8
  12744.6 (29-)     1626.8 6 E2 0.000574α=0.000574 8, α(K)=0.000388 6, α(L)=4.56×10-5 7, α(M)=8.80E-6 13, α(N)=1.614E-6 23, α(O)=1.205E-7 17, α(N+)=0.0001323 19

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Additional Level Data and Comments:

E(level)Jπ(level)T1/2(level)Comments
      0.07+ 4.92 h 8 
% ε = 100
μ=4.713 8, Q=+1.000 22
δ<r2>(115,110)=-0.361 5 (1985Ul03).
E(level): δ<r2>(115,110)=-0.361 5 (1985Ul03).
    714.478+ 1.4 ps +15-5  E(level): π(g9/2-1)#νg7/2 band.
    808.0728- ≥ 2.4 ps E(level): Magnetic-rotational band #1.
   1017.939- ≥ 1.2 ps E(level): Magnetic-rotational band #1.
   1396.349+   E(level): π(g9/2-1)#νg7/2 band.
   1561.5910-   E(level): Magnetic-rotational band #1.
   1617.498-   E(level): Anti-magnetic rotational band #1.
   2110.1510+   E(level): π(g9/2-1)#νg7/2 band.
   2174.9111-   E(level): Magnetic-rotational band #1.
   2201.9910-   E(level): Anti-magnetic rotational band #1.
   2220.659-   E(level): π((g9/2-2)(g7/2))#νh11/2 band.
   2275.5910-   E(level): π(g9/2-1)#ν(((g7/2/d5/2))2(h11/2)) band.
   2596.9512-   E(level): Magnetic-rotational band #2.
   2607.4511-   E(level): π(g9/2-1)#ν(((g7/2/d5/2))2(h11/2)) band.
   2798.4311-   E(level): π((g9/2-2)(g7/2))#νh11/2 band.
   2837.9813-   E(level): Magnetic-rotational band #2.
   2854.35(11+)   E(level): π(g9/2-1)#νg7/2 band.
   2908.48(12-)   E(level): π(g9/2-1)#ν(((g7/2/d5/2))2(h11/2)) band.
   3080.0012-   E(level): Anti-magnetic rotational band #1.
   3192.1414- 0.868 ps +24-25  E(level): Magnetic-rotational band #2.
   3196.98(13-)   E(level): π(g9/2-1)#ν(((g7/2/d5/2))2(h11/2)) band.
   3326.9811+   E(level): Magnetic-rotational band #3.
   3512.4612+   E(level): Magnetic-rotational band #3.
   3629.0313-   E(level): π((g9/2-2)(g7/2))#νh11/2 band.
   3697.6912-   E(level): π(g9/2-1)#ν(h11/2)3 band.
E(level)Jπ(level)T1/2(level)Comments
   3713.2415- 0.50 ps +4-3  E(level): Magnetic-rotational band #2.
   3719.8213+   E(level): Magnetic-rotational band #3.
   3732.99(14-)   E(level): π(g9/2-1)#ν(((g7/2/d5/2))2(h11/2)) band.
   3914.9413+   E(level): π(g9/2-1)#ν((g7/2/d5/2)(h11/2)2) band.
   3943.3914+   E(level): Magnetic-rotational band #3.
   3995.6213-   E(level): π(g9/2-1)#ν(h11/2)3 band.
   4081.7014+   E(level): π(g9/2-1)#ν((g7/2/d5/2)(h11/2)2) band.
   4156.5014-   E(level): Anti-magnetic rotational band #1.
   4228.9815+ 0.435 ps +17-16  E(level): Magnetic-rotational band #3.
   4263.9914-   E(level): π(g9/2-1)#ν(h11/2)3 band.
   4370.6015+   E(level): π(g9/2-1)#ν((g7/2/d5/2)(h11/2)2) band.
   4528.3116-   XREF: C(4532.6).
E(level): Magnetic-rotational band #2.
   4561.7715(-)   E(level): π(g9/2-1)#ν(h11/2)3 band.
   4598.0216+ 0.297 ps +6-11  E(level): Magnetic-rotational band #3.
   4606.0315-   E(level): π((g9/2-2)(g7/2))#νh11/2 band.
   4802.9516+   E(level): π(g9/2-1)#ν((g7/2/d5/2)(h11/2)2) band.
   4995.5716(-)   E(level): π(g9/2-1)#ν(h11/2)3 band.
   5084.9017+ 0.159 ps +24-18  E(level): Magnetic-rotational band #3.
   5180.8116-   E(level): Anti-magnetic rotational band #1.
   5265.1817-   E(level): Magnetic-rotational band #2.
   5283.3917(+)   E(level): π(g9/2-1)#ν((g7/2/d5/2)(h11/2)2) band.
   5556.4417(-) 0.54 ps +7-6  E(level): π((g9/2-2)(g7/2))#νh11/2 band.
   5561.68(17-)   E(level): π(g9/2-1)#ν(h11/2)3 band.
   5650.3918+ 0.136 ps +15-13  E(level): Magnetic-rotational band #3.
   5833.45(18+)   E(level): π(g9/2-1)#ν((g7/2/d5/2)(h11/2)2) band.
E(level)Jπ(level)T1/2(level)Comments
   6062.1118-   E(level): Anti-magnetic rotational band #1.
   6223.3319+ 0.073 ps +6-9  E(level): Magnetic-rotational band #3.
   6445.5419(-) 0.38 ps +4-3  E(level): π((g9/2-2)(g7/2))#νh11/2 band.
   6707.23(20+)   E(level): Magnetic-rotational band #3.
   6999.2120-   E(level): Anti-magnetic rotational band #1.
   7272.63(21+)   E(level): Magnetic-rotational band #3.
   7391.7521(-) 0.279 ps +16-12  E(level): π((g9/2-2)(g7/2))#νh11/2 band.
   7980.84(22+)   E(level): Magnetic-rotational band #3.
   8087.8(22-)   E(level): Anti-magnetic rotational band #1.
   8463.8(23-) 0.142 ps +13-10  E(level): π((g9/2-2)(g7/2))#νh11/2 band.
   8747.7(23+)   E(level): Magnetic-rotational band #3.
   87680+   IAS of 110Cd g.s.
E(level): IAS of 110Cd g.s. From 110Cd(p,n).
Jπ(level): From Jπ of parent analog state in 110Cd.
   9398.2(24-)   E(level): Anti-magnetic rotational band #1.
   94382+   IAS of 110Cd(657.8) level.
E(level): From 110Cd(p,n).
Jπ(level): From Jπ of parent analog state in 110Cd.
   9698.7(25-)   E(level): π((g9/2-2)(g7/2))#νh11/2 band.
  10268(0+,2+,4+)   Unresolved triplet IAS of 110Cd(1473.1, 1475.8, 1542.4) levels.
E(level): From 110Cd(p,n).
Jπ(level): From Jπ of parent analog state in 110Cd.
  10568   E(level): From 110Cd(p,n).
  108583-   IAS of 110Cd(2078.5) level.
E(level): From 110Cd(p,n).
Jπ(level): From Jπ of parent analog state in 110Cd.
  110684+   IAS of 110Cd(2220.1) level.
E(level): From 110Cd(p,n).
Jπ(level): From Jπ of parent analog state in 110Cd.
  11117.8(27-)   E(level): π((g9/2-2)(g7/2))#νh11/2 band.
  11268   E(level): From 110Cd(p,n).
  11468   E(level): From 110Cd(p,n).
  11768   E(level): From 110Cd(p,n).
  12744.6(29-)   E(level): π((g9/2-2)(g7/2))#νh11/2 band.

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Additional Gamma Comments:

E(level)E(gamma)Comments
    202.38    140.304M(γ): α(K)exp=0.18 4 and A2=-0.192 19, A4=0.069 23 (1987Kr15). Other: α(K)exp=0.133 9 (1989Kr12). From α(K)exp in 107Ag(α,nγ) (1989Kr12)
    321.20    118.819M(γ): α(K)exp=0.31 6 and A2=-0.23 4, A4=0.03 5 (1987Kr15)
    334.09    131.63I(γ): From 110Cd(p,nγ)
    272.018I(γ): From 110Cd(p,nγ)
M(γ): α(K)exp=0.032 3 and A2=-0.193 11, A4=-0.009 13 (1987Kr15)
    342.55    280.459M(γ): α(K)exp=0.0291 23 and A2=-0.004 13, A4=-0.011 15 (1987Kr15)
    346.32    143.940M(γ): α(K)exp=0.19 5 and A2=-0.31 4, A4=-0.05 5 (1987Kr15). Other: M1 from α(K)exp=0.14 3 (1989Kr12). From α(K)exp in 107Ag(α,nγ) (1989Kr12)
    413.482    413.52M(γ): DCO=1.75 6. From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
    437.15     90.826M(γ): A2=-0.40 17, A4=-0.009 18 (1987Kr15)
    115.951M(γ): A2=-0.31 11, A4=-0.08 15 (1987Kr15)
    541.24    207.17M(γ): α(K)exp=0.058 4 (1989Kr12). From α(K)exp in 107Ag(α,nγ) (1989Kr12)
    338.85M(γ): α(K)exp=0.019 3 (1987Kr15). From α(K)exp in 107Ag(α,nγ) (1989Kr12)
    479.15M(γ): α(K)exp=0.0067 4 and A2=-0.164 18, A4=-0.021 25 (1987Kr15)
    568.40    568.41M(γ): α(K)exp=0.0052 3 (1989Kr12). From α(K)exp in 107Ag(α,nγ) (1989Kr12)
    714.47    300.99M(γ): α(K)exp=0.029 3 (1989Kr12)
    714.37M(γ): α(K)exp=0.0028 2 (1989Kr12)
    756.45    389.93M(γ): α(K)exp=0.0157 14 (1989Kr12). From α(K)exp in 107Ag(α,nγ) (1989Kr12)
    435.32M(γ): α(K)exp=0.0101 6 (1989Kr12). From α(K)exp in 107Ag(α,nγ) (1989Kr12)
    756.55    413.99M(γ): α(K)exp=0.0039 10 and A2=-0.154 15, A4=-0.010 20 (1987Kr15)
    422.48M(γ): α(K)exp=0.0029 6 and A2=0.18 8, A4=0.028 11 (1987Kr15)
    554.09I(γ): From 110Cd(p,nγ)
    694.44M(γ): α(K)exp=0.0090 27 (1987Kr15)
    793.04    251.81M(γ): α(K)exp=0.035 3 and A2=-0.33 12, A4=-0.17 16 (1987Kr15)
    471.79I(γ): Other: 12.4 9 in 110Cd(p,nγ)
    590.65M(γ): α(K)exp=0.0044 4 and A2=-0.32 13, A4=-0.069 18 (1987Kr15)
    799.851    386.36M(γ): α(K)exp=0.005 3 (1989Kr12) in 107Ag(α,nγ) and from DCO=2.14 16 (2001Ch71) in 96Zr(19F,5nγ)
    799.83M(γ): α(K)exp=0.00082 4 (1989Kr12) in 107Ag(α,nγ) and from DCO=2.04 10 in 96Zr(19F,5nγ)
E(level)E(gamma)Comments
    808.072      8.0E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
    394.59M(γ): DCO=0.94 4. From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
    808.09M(γ): DCO=0.96 3 (2001Ch71) (DCO(ΔJ=2,Q gated)=0.67 15); α(K)exp=0.00066 5 (1989Kr12). From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
    886.41    449.22M(γ): α(K)exp=0.0093 9 (1989Kr12). From α(K)exp in 107Ag(α,nγ) (1989Kr12)
    472.95M(γ): α(K)exp=0.0094 16 (1989Kr12). From α(K)exp in 107Ag(α,nγ) (1989Kr12)
    887.40    541.03M(γ): α(K)exp=0.0061 7 (1989Kr12). From α(K)exp in 107Ag(α,nγ) (1989Kr12)
    566.24M(γ): α(K)exp=0.0054 4 (1989Kr12). From α(K)exp in 107Ag(α,nγ) (1989Kr12)
    958.46    165.42I(γ): From 110Cd(p,nγ)
    592.04I(γ): From 110Cd(p,nγ)
    612.19M(γ): α(K)exp=0.0041 3 and A2=-0.35 9, A4=-0.026 11 (1987Kr15)
    624.41M(γ): α(K)exp=0.0039 10 (1987Kr15)
    637.27M(γ): α(K)exp=0.0038 9 and A2=-0.06 6, A4=0.15 12 (1987Kr15)
    756.03M(γ): α(K)exp=0.023 5 (1987Kr15)
    896.31I(γ): Other: 84 7 in 110Cd(p,nγ)
M(γ): A2=-0.530 10, A4=-0.019 12 (1987Kr15)
    970.87    533.83I(γ): Other: 59 12 in 110Cd(p,nγ)
    649.68I(γ): Other: 64.0 13 in 110Cd(p,nγ)
    989.84    233.31I(γ): Other: 19 1 in 110Cd(p,nγ)
M(γ): α(K)exp=0.041 21 (1987Kr15)
    448.61I(γ): From 110Cd(p,nγ)
M(γ): α(K)exp=0.0025 10 (1987Kr15)
    647.27M(γ): A2=-0.21 6, A4=0.02 9 (1987Kr15)
    655.73I(γ): From 110Cd(p,nγ)
    787.48I(γ): Other: 40 4 in 110Cd(p,nγ)
M(γ): α(K)exp=0.0058 19 and A2=0.03 6, A4=0.17 11 (1987Kr15)
    927.74M(γ): α(K)exp=0.0054 9 and A2=0.19 7, A4=-0.03 9 (1987Kr15)
   1006.06    149.80M(γ): α(K)exp=0.14 3 (1989Kr12). From α(K)exp in 107Ag(α,nγ) (1989Kr12)
   1017.93    209.80M(γ): DCO=1.04 2, DCO(ΔJ=2,Q gated)=0.63 13. From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
   1020.81    452.35M(γ): α(K)exp=0.0093 13
   1020.84M(γ): α(K)exp=0.0014 5
E(level)E(gamma)Comments
   1023.40    266.87I(γ): From 110Cd(p,nγ)
    677.12I(γ): From 110Cd(p,nγ)
    689.27I(γ): From 110Cd(p,nγ)
    702.07I(γ): From 110Cd(p,nγ)
    821.00I(γ): From 110Cd(p,nγ)
    961.32M(γ): α(K)exp=0.00044 11 (1989Kr12). From α(K)exp in 107Ag(α,nγ) (1989Kr12)
   1049.88    707.34M(γ): α(K)exp=0.0264 18 and A2=-0.121 29, A4=0.060 41 (1987Kr15)
    715.72M(γ): α(K)exp=0.0314 78 (1987Kr15)
    987.81I(γ): From 110Cd(p,nγ)
M(γ): α(K)exp=0.0128 14 and A2=0.303 58, A4=0.099 79 (1987Kr15)
   1118.45    751.93M(γ): α(K)exp=0.0026 3 (1987Kr15). From α(K)exp in 107Ag(α,nγ) (1989Kr12)
   1119.82    363.24I(γ): From 110Cd(p,nγ)
M(γ): α(K)exp=0.0165 15 (1987Kr15)
    777.32M(γ): α(K)exp=0.0077 15 and A2=-0.080 80, A4=-0.025 11 (1987Kr15)
   1134.07    377.51M(γ): α(K)exp=0.0169 12 (1989Kr12). From α(K)exp in 107Ag(α,nγ) (1989Kr12)
   1176.23    419.65I(γ): 100 13 in 107Ag(α,nγ). From 110Cd(p,nγ)
    829.86I(γ): 90 19 in 107Ag(α,nγ). From 110Cd(p,nγ)
    842.22I(γ): From 110Cd(p,nγ)
    855.01I(γ): From 110Cd(p,nγ)
   1114.15I(γ): From 110Cd(p,nγ)
   1190.93    201.10I(γ): From 110Cd(p,nγ)
    434.35M(γ): α(K)exp=0.0093 10 and A2=-0.23 12, A4=0.074 15 (1987Kr15)
    857.11I(γ): From 110Cd(p,nγ)
   1204.87    198.81M(γ): α(K)exp=0.087 6 (1989Kr12). From α(K)exp in 107Ag(α,nγ) (1989Kr12)
   1216.80    870.39M(γ): α(K)exp=0.0014 4 (1989Kr12). From α(K)exp in 107Ag(α,nγ) (1989Kr12)
    882.69M(γ): α(K)exp=0.0173 35 (1987Kr15). From α(K)exp in 107Ag(α,nγ) (1989Kr12)
    895.70I(γ): From 110Cd(p,nγ)
E(level)E(gamma)Comments
   1239.93    249.96I(γ): From 110Cd(p,nγ)
    483.34I(γ): From 110Cd(p,nγ)
M(γ): α(K)exp=0.0078 11 (1987Kr15)
    905.92I(γ): From 110Cd(p,nγ)
M(γ): α(K)exp=0.0072 33 (1987Kr15)
   1177.93I(γ): From 110Cd(p,nγ)
   1254.91    498.31I(γ): From 110Cd(p,nγ)
M(γ): α(K)exp=0.0059 10 (1987Kr15)
    912.41I(γ): From 110Cd(p,nγ)
M(γ): α(K)exp=0.0069 17 (1987Kr15)
   1280.23    487.19M(γ): α(K)exp=0.0096 22 for 487.19γ+487.94γ (1989Kr12). From α(K)exp in 107Ag(α,nγ) (1989Kr12)
   1396.34    681.5E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
   1396.4E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
   1494.00    487.94M(γ): α(K)exp=0.0096 22 for 487.19γ+487.94γ (1989Kr12). From α(K)exp in 107Ag(α,nγ) (1989Kr12)
   1561.59    543.7E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): DCO=1.04 4
    753.6E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
   1617.49    599.3E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): DCO=1.22 24, DCO(ΔJ=2,Q gated)=0.77 15; α(K)exp=0.0029 4. From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
    809.9E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
    817.4E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): DCO(ΔJ=2,Q gated)=1.03 23. From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
   1617.0E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
   1886.23   1078.1E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): DCO(ΔJ=2,Q gated)=1.01 12 for doublet. From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
   2110.15    713.8E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
   2129.14    243.0E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
    567.2E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
    732.3E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
   1111.2E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
   1321.2E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
   2174.91    613.0E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): DCO=0.94 3. From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
   1157.0E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
E(level)E(gamma)Comments
   2201.99    315.6E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): DCO(ΔJ=2,Q gated)=0.98 19. From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
    584.4E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): DCO(ΔJ=2,Q gated)=0.89 10. From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
    640.6E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
    805.3E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
   1183.2E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
   2220.65    603.2E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): DCO=0.84 19. From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
    825.4E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
   1202.3E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
   2275.59   1257.3E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
   1467.5E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
   2492.59    363.3E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): DCO=0.96 25. From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
   2596.95    104.2E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
    421.9E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): DCO=0.87 2. From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
   1035.6E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): DCO=1.7 4. From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
   2607.45    331.5E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): DCO=0.88 16. From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
   1046.1E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
   1589.9E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
   2687.0   1290.7E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
   2764.86    590.1E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): DCO=0.99 8. From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
   1203.2E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
   2798.43    578.0E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): DCO=1.08 14. From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
    596.2E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): DCO=0.43 8. From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
    669.3E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
   2837.98    241.1E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): DCO=0.89 2. From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
   2854.35    744.2E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
E(level)E(gamma)Comments
   2901.99     63.9E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
   2908.48    301.3E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): DCO=0.89 19. From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
    733.4E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): DCO=1.2 4. From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
   1346.5E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
   3080.00    878.0M(γ): DCO=1.7 4. From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
   3192.14    354.6E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): DCO=0.77 4. From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
   3196.98    288.5E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): DCO=0.92 5. From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
   3245.11   1070.1E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
   1115.9E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
   1684.1E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
   3326.98   1765.5E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
   3344.78    506.8E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
   3371.31   1196.4E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
   3438.41    536.0E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
   3512.46    185.6E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): DCO=1.29 24. From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
    267.2E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): DCO=0.85 9. From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
    610.7E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
   1337.7E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): DCO=1.22 20. From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
   3629.03    830.6E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): DCO(ΔJ=2,Q gated)=1.12 12. From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
   3697.69   1522.6E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
   3713.24    521.1E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): DCO=0.62 7. From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
   3719.82    207.5E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): DCO=1.02 5. From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
    281.3E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
    955.3E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): DCO=0.88 21. From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
   1122.7E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): DCO=1.0 3. From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
E(level)E(gamma)Comments
   3732.99    536.0E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
   3821.18    476.4E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
   3833.00    753.0E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
   3914.94    217.2E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): DCO=0.97 11. From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
   1077.6E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
   1318.0E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): DCO=0.93 19. From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
   3943.39    223.8E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): DCO=0.90 3. From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
   1105.0E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
   3995.62    297.8E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): DCO=0.63 10. From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
   1230.5E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
   4081.70    166.9E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): DCO=0.68 8. From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
   1243.8E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): DCO=0.87 15. From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
   4156.50   1076.5E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): DCO(ΔJ=2,Q gated)=1.01 12 for doublet. From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
   4228.98    147.4E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
    285.4E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): DCO=0.85 3. From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
   4263.99    268.0E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): DCO=0.68 11. From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
   1425.6E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
   4323.05   1130.9E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
   4370.60    289.0E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): DCO=0.92 5. From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
   1178.3E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
   4528.31    815.0E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): DCO=1.3 3. From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
   4561.77    297.3E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): DCO=0.63 10. From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
   1370.1E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
   4598.02    369.0E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): DCO=0.69 5. From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
   4602.10    769.1E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
E(level)E(gamma)Comments
   4606.03    977.0E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
   4802.89    981.7E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
   4802.95    432.4E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): DCO=0.75 21. From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
   4942.2   1750.0E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
   4995.57    433.8E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): DCO=0.53 11. From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
   5045.60   1102.2E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
   5084.90    486.9E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
    855.9E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
   5180.81   1024.3E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): DCO(ΔJ=2,Q gated)=0.96 12. From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
   5265.18    736.8E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): DCO=0.84 13. From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
   1552.0E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
   5283.39    480.5E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
   5403.27   1690.2E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
   5545.88    550.3E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
   5556.44    950.4E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): DCO(ΔJ=2,Q gated)=0.92 12 for doublet. From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
   5561.68    566.1E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
   5650.39    366.9E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
    565.6E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
   1052.3E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
   5687.23    284.0E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
    422.0E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
   5825.10    740.2E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
   5833.45    550.2E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
    748.4E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
   5839.27    555.9E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
    754.3E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
E(level)E(gamma)Comments
   6062.11    881.3E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): DCO=1.6 4. From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
   6095.43    408.2E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
   6223.33    572.9E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
   1138.6E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
   6296.99    646.6E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
   6445.54    889.1E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
   6707.23    483.9E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
   6992.09    695.1E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
   6999.21    937.1E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
   7240.6   1590.2E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
   7272.63    565.4E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
   7391.75    946.2E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): DCO(ΔJ=2,Q gated)=0.92 12 for doublet. From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
   7980.84    708.2E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
   8087.8   1088.6E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
   8463.8   1072.0E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
   8747.7    766.9E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
   9398.2   1310.4E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
   9698.7   1234.9E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
  11117.8   1419.1E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated
  12744.6   1626.8E(γ): From 62Zr(19F,5nγ)
I(γ): From 62Zr(19F,5nγ)
M(γ): From measured DCO ratios and band structure in 96Zr(19F,5nγ) (2001Ch71). DCO ratios correspond to gates on ΔI=1 dipole transitions, unless otherwise stated

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