ADOPTED LEVELS, GAMMAS for 212Rn

Authors: K. Auranen and E.A. Mccutchan |  Citation: Nucl. Data Sheets 168, 117 (2020) |  Cutoff date: 1-Aug-2020 

 Full ENSDF file | Adopted Levels (PDF version) 


Q(β-)=-5144 keV 9S(n)= 7976 keV 7S(p)= 4301 keV 4Q(α)= 6385.1 keV 26
Reference: 2017Wa10

References:
  A  212Fr ε decay  B  216Ra α decay
  C  (HI,xnγ)  D  209Bi(6Li,3nγ)

General Comments:

The adopted level scheme is mostly that proposed in 2009Dr12 and 2020Li12 with some details filled in from earlier studies as indicated. The configurations are assigned based on empirical shell model calculations in 2009Dr12. See also 2008Dr01, 1990Dr07, 1990Dr12, 1989Lo02, 1988St17, 1979Ho06, 1978Ha50, 1977Ho17, 1976Ha62, 1975Wi01, and 1971MaXH

Q-value: S(2n)=15197 6, S(2p)=7284.4 29 (2017Wa10).










E(level)
(keV)		XREFJπ(level) T1/2(level)E(γ)
(keV)		I(γ)M(γ)Final Levels
      0.0ABCD 0+ 23.9 m 12 
% α = 100
     
   1273.70 10 A CD 2+     1273.7 1 
  100
E2
      0.0
0+
   1501.42 14 A CD 4+ 8.80 ns 35     227.7 1 
  100
E2
   1273.70
2+
   1639.68 15 A CD 6+ 118 ns 14     138.3 1 
  100
E2
   1501.42
4+
   1694.1 3   CD 8+ 0.91 µs 3      54.2 3 
  100
E2
   1639.68
6+
   2116.2 3   CD 8+      422.0 1 
  100
M1
   1694.1
8+
   2120.99 14    D 3      619.5 2 
   847.3 1 
   22 4 
  100 13 
D
D
   1501.42
   1273.70
4+
2+
   2171.87 16    D (6+)      532.2 1 
   670.4 1 
  100 15 
   32 6 
(E2)
(E2)
   1639.68
   1501.42
6+
4+
   2305.61 22 A CD 5(+)      133.7 2 
   666.0 3 
   804.3
   <6
   18 6 
  100 24 

D+Q
D+Q
   2171.87
   1639.68
   1501.42
(6+)
6+
4+
   2313.60 21    D 7(+)      141.8 3 
   197.3 2 
   674.0 2 
   <8
  100 8 
   25 8 

D+Q
D+Q
   2171.87
   2116.2
   1639.68
(6+)
8+
6+
   2324.43 18    D 4+      152.4 2 
   684.9 2 
   823.0 2 
  1050.9
   <8
   42 8 
  100 17 
   33 8 

(E2)
(E2)
(E2)
   2171.87
   1639.68
   1501.42
   1273.70
(6+)
6+
4+
2+
   2402.82 24    D      901.4 2 
  100
(E2)
   1501.42
4+
   2437.92 24    D      936.5 2 
  100
(E2)
   1501.42
4+
   2455.42 24    D      954.0 2 
  100
(E2)
   1501.42
4+
   2613.1 3    D      973.4 2 
  100
(E2)
   1639.68
6+
   2654.9 3   CD 10+      960.8 1 
  100
E2
   1694.1
8+
   2686.29 19 A  D (6+)     1046.6 2 
  1184.9 2 
   21 5 
  100 11 
(E2)
(E2)
   1639.68
   1501.42
6+
4+
   2696.2 4   C      1002.1 3 
  100

   1694.1
8+
   2760.6 3   CD 11- 5.5 ns 2     105.8 1 
   644.5 3 
  1066.4 3 
  100 4 
    3.8 7 
    8.5 10 
E1
[E3]
[E3]
   2654.9
   2116.2
   1694.1
10+
8+
8+
E(level)
(keV)		XREFJπ(level) T1/2(level)E(γ)
(keV)		I(γ)M(γ)Final Levels
   2833.4 3    D      147.1 2 
  100

   2686.29
(6+)
   2865.47 23    D (6+)      179.2 2 
  1364.0 3 
   70 30 
  100 30 

(E2)
   2686.29
   1501.42
(6+)
4+
   2881.3 3   CD 12+ 2.08 ns 14     120.7 3 
   226.4 1 
    0.61 14 
  100.0 11 
[E1]
E2
   2760.6
   2654.9
11-
10+
   2967.1 3   CD      206.5 1 
  100
D
   2760.6
11-
   3066.1 3   CD (10+)      305.5 2 
   949.9 1 
   17 4 
  100 9 
D
(E2)
   2760.6
   2116.2
11-
8+
   3250.4 3    D      564.1 2 
  100
(E2)
   2686.29
(6+)
   3278.2 3   CD (11)      212.1 2 
   396.6 2 
   623.5 2 
   26.7 16 
   87 13 
  100 13 
(D+Q)
(D+Q)
(D+Q)
   3066.1
   2881.3
   2654.9
(10+)
12+
10+
   3297.7 3   CD 12+       19.5S
   231.5 3 
   416.3 1 
   537.1 1 
    0.063 12 
   12.0 24 
  100 5 
   87 5 

(E2)
M1
E1
   3278.2
   3066.1
   2881.3
   2760.6
(11)
(10+)
12+
11-
   3357.5 3   CD 14+ 7.4 ns 9      59.8 6 S
   476.2 1 
    0.28 5 
  100.0 19 
(E2)
E2
   3297.7
   2881.3
12+
12+
   3476.4 3    D      595.1 2 
  100
D
   2881.3
12+
   3494.2 3    D      733.6 2 
  100
(E2)
   2760.6
11-
   3510.2 4   C       628.9 3 
  100

   2881.3
12+
   3687.1 3    D (12+)      806.1 2 
  1031.9 2 
  100 13 
   50 13 
(E2)
(E2)
   2881.3
   2654.9
12+
10+
   3735.1 3   CD (13-)      974.4 3 
  100
(E2)
   2760.6
11-
   3990.9 3   CD 15-      255.6 3 
   633.4 1 
    0.56 15 
  100 3 

E1
   3735.1
   3357.5
(13-)
14+
   3998.0 4   CD      640.5 3 
  100

   3357.5
14+
   4046.2 3    D     1164.9 2 
  100
(E2)
   2881.3
12+
   4066.6 3   CD 17- 28.9 ns 14      75.7 2 
   709.1 1 
   23.0 12 
  100 4 
[E2]
E3
   3990.9
   3357.5
15-
14+
E(level)
(keV)		XREFJπ(level) T1/2(level)E(γ)
(keV)		I(γ)M(γ)Final Levels
   4134.5 3   C  (16-)       67.9 3 
   143.7 3 
  100 13 
   59 7 
(M1+E2)

   4066.6
   3990.9
17-
15-
   4151.2 3   CD (15-)      416.2 3 
   793.7 3 
   ≈6
  100 17 

D
   3735.1
   3357.5
(13-)
14+
   4582.3 3   CD 17-      447.8 2 
   515.7 1 
   20.0 13 
  100 3 

M1
   4134.5
   4066.6
(16-)
17-
   4929.4 3   C       778.3 3 
   862.8 3 
   938.3 3 
   38 10 
   77 6 
  100 15 



   4151.2
   4066.6
   3990.9
(15-)
17-
15-
   5114.1 3   C  18-      531.7 1 
   979.6 3 
  1047.4 1 
  100 3 
    8.1 10 
   57 4 
M1
[E2]
M1+E2
   4582.3
   4134.5
   4066.6
17-
(16-)
17-
   5357.1 4   C       774.8 3 
  1290.5 3 
   70 13 
  100 14 


   4582.3
   4066.6
17-
17-
   5426.9 3   C  20+ 5.2 ns 5      69.8 6 S
   844.5 2 
  1360.3 1 
    0.43 6 
   18 3 
  100 6 

[E3]
E3
   5357.1
   4582.3
   4066.6

17-
17-
   5771.7 3   C  19-      344.8 2 
   657.6 1 
  1705.1 3 
    6.2 5 
  100.0 23 
    0.86 14 
[E1]
M1
[E2]
   5426.9
   5114.1
   4066.6
20+
18-
17-
   5794.4 3   C       865.0 2 
  1212.3 3 
  100 3 
   20 4 


   4929.4
   4582.3

17-
   6166.7 3   C  20+      372.3 2 
   395.0 1 
   739.7 1 
    4.2 5 
  100.0 25 
    9.8 7 

E1

   5794.4
   5771.7
   5426.9

19-
20+
   6174.2 3   C  (22+) 101.8 ns 35       7.5 6 S
   402.5 3 
   747.3 1 
    0.0011 6 
   15 3 
  100 5 
[E2]
[E3]
[E2]
   6166.7
   5771.7
   5426.9
20+
19-
20+
   6709.3 3   C  (23+)      535.0 1 
  100
D
   6174.2
(22+)
   6821.4 4   C       647.2 2 
  100

   6174.2
(22+)
E(level)
(keV)		XREFJπ(level) T1/2(level)E(γ)
(keV)		I(γ)M(γ)Final Levels
   7142.0 3   C  (25-) 18.0 ns 6     432.5 2 
   967.8 1 
    4.9 3 
  100.0 20 
(M2)
E3
   6709.3
   6174.2
(23+)
(22+)
   7177.7 5   C       356.3 3 
  100
D
   6821.4

   7524.6 4   C  (25-)      382.6 2 
  100
D
   7142.0
(25-)
   7819.1 3   C  (26-)      294.5 3 
   677.1 1 
    6.9 8 
  100 7 
D
D
   7524.6
   7142.0
(25-)
(25-)
   7862.8 3   C  (26-)      720.8 1 
  100
D
   7142.0
(25-)
   7878.3 3   C  (27-) 14 ns 4      15.5 6 S
    59.2 6 S
   353.8 3 
   736.3 1 
    0.137 12 
    1.40 16 
    3.1 9 
  100 4 
M1
[M1]
[E2]
E2
   7862.8
   7819.1
   7524.6
   7142.0
(26-)
(26-)
(25-)
(25-)
   8361.9 4   C  (27-)      483.7 2 
  100
D
   7878.3
(27-)
   8497.3 4   C  (28+)      619.0 1 
  1355.4 3 
  100 6 
   31 3 
D
O
   7878.3
   7142.0
(27-)
(25-)
   8557.3 4   C  (28+)      195.5 3 
   679.0 1 
    3.7 7 
  100 8 

D
   8361.9
   7878.3
(27-)
(27-)
   8579.2 4   C  (30+) 154 ns 14      21.9 6 S
    81.9 6 S
   700.9 1 
    9.6E-4 25 
    0.65 9 
  100 3 
(E2)
[E2]
E3
   8557.3
   8497.3
   7878.3
(28+)
(28+)
(27-)
   8932.9 4   C  (30+)      353.7 2 
  100
D
   8579.2
(30+)
   9028.4 5   C       449.2 3 
  100
D
   8579.2
(30+)
   9446.7 4   C  (31+)      867.5 2 
  100
D
   8579.2
(30+)
   9509.5 4   C  (31+)      930.3 2 
  100
D
   8579.2
(30+)
   9608.4 4   C  (31)     1029.2 2 
  100
D
   8579.2
(30+)
   9695.8 4   C  (33-) 4.9 ns 7    1116.6 1 
  100 6 
E3
   8579.2
(30+)
  10102.4 5   C       406.6 3 
  100
D
   9695.8
(33-)
  10124.7 5   C  (32+)      615.2 3 
  100
D
   9509.5
(31+)
  10619.5 4   C  (34-) ≈ 20 ns    923.7 1 
  100
(M1)
   9695.8
(33-)
  10843.4 5   C  (32)     1334.0 3 
  100
D
   9509.5
(31+)
  10961.4 5   C  (33)      118.0 3 
   859 1 
   52 9 
  100 40 


  10843.4
  10102.4
(32)

E(level)
(keV)		XREFJπ(level) T1/2(level)E(γ)
(keV)		I(γ)M(γ)Final Levels
  11086.0 5   C      1390.2 3 
  100

   9695.8
(33-)
  11175.3 5 ?  C  (34)      214.0 3 ?
  100
D
  10961.4
(33)
  11262.0 4   C  (35-)      642.7 3 
  100
D
  10619.5
(34-)
  11354.5 4   C  (35-) < 3.5 ns     92.5 8 S
   179.3 3 ?
   735.1 2 
  1658.4 3 
    3.5 9 
   13.0 14 
  100 6 
   23 4 
[M1]
D
D
[E2]
  11262.0
  11175.3
  10619.5
   9695.8
(35-)
(34)
(34-)
(33-)
  11462.5 5   C       843.0 3 
  100

  10619.5
(34-)
  11670.8 5   C       316.3 3 
  100

  11354.5
(35-)
  11827.3 5   C  (36-)      472.8 3 
  100
D
  11354.5
(35-)
  11880.3 5   C      1260.8 3 
  100

  10619.5
(34-)
  12052.8 5   C  37(-)      698.1 3 
  100
Q
  11354.5
(35-)
  12165.7 6   C       285.4 3 
  100
D
  11880.3

  12211.3 4   C  37(-) 17.3 ns 14     158.4 3 
   856.7 2 
   949.5 3 
    3.9 7 
  100 7 
   22 6 
D
(E2)
[E2]
  12052.8
  11354.5
  11262.0
37(-)
(35-)
(35-)
  12547.6 5   C  (38+) 8.3 ns 14     336.3 3 
  100
(E1)
  12211.3
37(-)
  13375.3 11   C      1164 1 
  100

  12211.3
37(-)
  13444.6 5   C      1233.3 3 
  100

  12211.3
37(-)

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

Jπ(level): Based on multipolarities deduced from γ(θ), γ(pol), γ(θ,H,t), and conversion coefficients measurements in (HI,xnγ) studies. Specific support is provided in the comments. Assignments are made under the general assumption that spin increases with increasing excitation energy in (HI,xnγ) reactions.

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Additional Gamma Data:















E(level)
(keV)		Jπ(level)T1/2(level)E(γ)
(keV)		MultipolarityMixing
Ratio		Conversion
Coefficient		Additional Data
   1273.70 2+     1273.7 1 E2 0.00515α=0.00515, α(K)=0.00411 6, α(L)=0.000786 11, α(M)=0.000188 3, α(N)=4.90×10-5 7, α(O)=1.060E-5 15, α(P)=1.501E-6 21
   1501.42 4+ 8.80 ns 35     227.7 1 E2 0.333B(E2)(W.u.)=1.050 +44-40, α=0.333, α(K)=0.1252 18, α(L)=0.1540 22, α(M)=0.0409 6, α(N)=0.01066 15, α(O)=0.00218 3, α(P)=0.000254 4
   1639.68 6+ 118 ns 14     138.3 1 E2 2.13B(E2)(W.u.)=0.40 +6-4, α=2.13, α(K)=0.316 5, α(L)=1.340 20, α(M)=0.361 6, α(N)=0.0939 14, α(O)=0.0190 3, α(P)=0.00213 3
   1694.1 8+ 0.91 µs 3      54.2 3 E2 150B(E2)(W.u.)=0.117 7, α=150 5, α(L)=111 4, α(M)=29.8 10, α(N)=7.73 24, α(O)=1.55 5, α(P)=0.170 6
   2116.2 8+      422.0 1 M1 0.236α=0.236, α(K)=0.192 3, α(L)=0.0340 5, α(M)=0.00806 12, α(N)=0.00210 3, α(O)=0.000460 7, α(P)=6.72×10-5 10
   2171.87 (6+)      532.2 1 (E2) 0.0304α=0.0304, α(K)=0.0209 3, α(L)=0.00713 10, α(M)=0.00180 3, α(N)=0.000469 7, α(O)=9.88×10-5 14, α(P)=1.280E-5 18
(6+)      670.4 1 (E2) 0.0182α=0.0182, α(K)=0.01333 19, α(L)=0.00366 6, α(M)=0.000911 13, α(N)=0.000237 4, α(O)=5.03×10-5 7, α(P)=6.72E-6 10
   2324.43 4+      684.9 2 (E2) 0.01739α=0.01739, α(K)=0.01280 18, α(L)=0.00346 5, α(M)=0.000858 12, α(N)=0.000223 4, α(O)=4.75×10-5 7, α(P)=6.35E-6 9
4+      823.0 2 (E2) 0.01192α=0.01192, α(K)=0.00908 13, α(L)=0.00215 3, α(M)=0.000526 8, α(N)=0.0001369 20, α(O)=2.93×10-5 5, α(P)=4.00E-6 6
4+     1050.9(E2) 0.00739α=0.00739, α(K)=0.00580 9, α(L)=0.001201 17, α(M)=0.000290 4, α(N)=7.55×10-5 11, α(O)=1.626E-5 23, α(P)=2.27E-6 4
   2402.82      901.4 2 (E2) 0.00995α=0.00995, α(K)=0.00768 11, α(L)=0.001718 24, α(M)=0.000419 6, α(N)=0.0001089 16, α(O)=2.34×10-5 4, α(P)=3.22E-6 5
   2437.92      936.5 2 (E2) 0.00923α=0.00923, α(K)=0.00716 10, α(L)=0.001568 22, α(M)=0.000381 6, α(N)=9.92×10-5 14, α(O)=2.13E-5 3, α(P)=2.95E-6 5
   2455.42      954.0 2 (E2) 0.00890α=0.00890, α(K)=0.00692 10, α(L)=0.001501 21, α(M)=0.000365 6, α(N)=9.49×10-5 14, α(O)=2.04E-5 3, α(P)=2.83E-6 4
   2613.1      973.4 2 (E2) 0.00856α=0.00856, α(K)=0.00667 10, α(L)=0.001432 20, α(M)=0.000348 5, α(N)=9.04×10-5 13, α(O)=1.94E-5 3, α(P)=2.70E-6 4
   2654.9 10+      960.8 1 E2 0.00878α=0.00878, α(K)=0.00683 10, α(L)=0.001476 21, α(M)=0.000359 5, α(N)=9.33×10-5 13, α(O)=2.00E-5 3, α(P)=2.78E-6 4
   2686.29 (6+)     1046.6 2 (E2) 0.00745α=0.00745, α(K)=0.00585 9, α(L)=0.001212 17, α(M)=0.000293 5, α(N)=7.62×10-5 11, α(O)=1.642E-5 23, α(P)=2.29E-6 4
(6+)     1184.9 2 (E2) 0.00589α=0.00589, α(K)=0.00467 7, α(L)=0.000919 13, α(M)=0.000221 3, α(N)=5.74×10-5 8, α(O)=1.241E-5 18, α(P)=1.750E-6 25
   2760.6 11- 5.5 ns 2     105.8 1 E1 0.405B(E1)(W.u.)=1.91E-5 +8-7, α=0.405, α(K)=0.316 5, α(L)=0.0679 10, α(M)=0.01624 24, α(N)=0.00417 6, α(O)=0.000869 13, α(P)=0.0001114 16
11- 5.5 ns 2     644.5 3 [E3] 0.0581B(E3)(W.u.)=27 +10-7, α=0.0581, α(K)=0.0342 5, α(L)=0.0178 3, α(M)=0.00464 7, α(N)=0.001214 18, α(O)=0.000254 4, α(P)=3.25E-5 5
11- 5.5 ns 2    1066.4 3 [E3] 0.01672B(E3)(W.u.)=1.8 +6-4, α=0.01672, α(K)=0.01212 17, α(L)=0.00345 5, α(M)=0.000863 13, α(N)=0.000225 4, α(O)=4.82E-5 7, α(P)=6.54E-6 10
   2865.47 (6+)     1364.0 3 (E2) 0.00455α=0.00455, α(K)=0.00363 5, α(L)=0.000680 10, α(M)=0.0001624 23, α(N)=4.22×10-5 6, α(O)=9.15E-6 13, α(P)=1.302E-6 19
   2881.3 12+ 2.08 ns 14     120.7 3 [E1] 0.295B(E1)(W.u.)=2.4E-7 6, α=0.295, α(K)=0.232 4, α(L)=0.0479 8, α(M)=0.01144 18, α(N)=0.00294 5, α(O)=0.000616 10, α(P)=7.99E-5 13
12+ 2.08 ns 14     226.4 1 E2 0.340B(E2)(W.u.)=4.52 +32-29, α=0.340, α(K)=0.1268 18, α(L)=0.1577 23, α(M)=0.0419 6, α(N)=0.01092 16, α(O)=0.00223 4, α(P)=0.000259 4
   3066.1 (10+)      949.9 1 (E2) 0.00898α=0.00898, α(K)=0.00697 10, α(L)=0.001516 22, α(M)=0.000369 6, α(N)=9.59×10-5 14, α(O)=2.06E-5 3, α(P)=2.85E-6 4
   3250.4      564.1 2 (E2) 0.0266α=0.0266, α(K)=0.0186 3, α(L)=0.00599 9, α(M)=0.001507 22, α(N)=0.000393 6, α(O)=8.28×10-5 12, α(P)=1.081E-5 16
E(level)
(keV)		Jπ(level)T1/2(level)E(γ)
(keV)		MultipolarityMixing
Ratio		Conversion
Coefficient		Additional Data
   3297.7 12+      231.5 3 (E2) 0.315α=0.315, α(K)=0.1209 18, α(L)=0.1438 22, α(M)=0.0382 6, α(N)=0.00995 15, α(O)=0.00203 3, α(P)=0.000237 4
12+      416.3 1 M1 0.245α=0.245, α(K)=0.199 3, α(L)=0.0353 5, α(M)=0.00837 12, α(N)=0.00218 3, α(O)=0.000477 7, α(P)=6.97×10-5 10
12+      537.1 1 E1 0.00952α=0.00952, α(K)=0.00781 11, α(L)=0.001303 19, α(M)=0.000306 5, α(N)=7.93×10-5 12, α(O)=1.715E-5 24, α(P)=2.43E-6 4
   3357.5 14+ 7.4 ns 9      59.8 6 (E2) 93B(E2)(W.u.)=2.9 6, α=93 5, α(L)=69 4, α(M)=18.5 10, α(N)=4.81 25, α(O)=0.97 5, α(P)=0.106 6
14+ 7.4 ns 9     476.2 1 E2 0.0395B(E2)(W.u.)=0.0319 +45-36, α=0.0395, α(K)=0.0261 4, α(L)=0.01008 15, α(M)=0.00257 4, α(N)=0.000670 10, α(O)=0.0001402 20, α(P)=1.79E-5 3
   3494.2      733.6 2 (E2) 0.01507α=0.01507, α(K)=0.01125 16, α(L)=0.00288 4, α(M)=0.000711 10, α(N)=0.000185 3, α(O)=3.94×10-5 6, α(P)=5.32E-6 8
   3687.1 (12+)      806.1 2 (E2) 0.01243α=0.01243, α(K)=0.00943 14, α(L)=0.00226 4, α(M)=0.000555 8, α(N)=0.0001444 21, α(O)=3.09×10-5 5, α(P)=4.21E-6 6
(12+)     1031.9 2 (E2) 0.00765α=0.00765, α(K)=0.00600 9, α(L)=0.001252 18, α(M)=0.000303 5, α(N)=7.88×10-5 11, α(O)=1.696E-5 24, α(P)=2.37E-6 4
   3735.1 (13-)      974.4 3 (E2) 0.00855α=0.00855, α(K)=0.00666 10, α(L)=0.001429 20, α(M)=0.000347 5, α(N)=9.02×10-5 13, α(O)=1.94E-5 3, α(P)=2.69E-6 4
   3990.9 15-      633.4 1 E1 0.00687α=0.00687, α(K)=0.00566 8, α(L)=0.000929 13, α(M)=0.000218 3, α(N)=5.64×10-5 8, α(O)=1.223E-5 18, α(P)=1.742E-6 25
   4046.2     1164.9 2 (E2) 0.00608α=0.00608, α(K)=0.00482 7, α(L)=0.000954 14, α(M)=0.000229 4, α(N)=5.97×10-5 9, α(O)=1.289E-5 18, α(P)=1.82E-6 3
   4066.6 17- 28.9 ns 14      75.7 2 [E2] 30.1B(E2)(W.u.)=2.94 +17-15, α=30.1 6, α(L)=22.2 5, α(M)=5.98 12, α(N)=1.55 3, α(O)=0.313 6, α(P)=0.0344 7
17- 28.9 ns 14     709.1 1 E3 0.0449B(E3)(W.u.)=21.3 +17-15, α=0.0449, α(K)=0.0279 4, α(L)=0.01263 18, α(M)=0.00327 5, α(N)=0.000855 12, α(O)=0.000180 3, α(P)=2.33E-5 4
   4134.5 (16-)       67.9 3 (M1+E2)0.45 +22-2815.1α=15.1 61, α(L)=11.3 45, α(M)=2.9 13, α(N)=0.75 32, α(O)=0.156 63, α(P)=0.0196 65
   4582.3 17-      515.7 1 M1 0.1381α=0.1381, α(K)=0.1121 16, α(L)=0.0198 3, α(M)=0.00469 7, α(N)=0.001222 18, α(O)=0.000267 4, α(P)=3.91×10-5 6
   5114.1 18-      531.7 1 M1 0.1273α=0.1273, α(K)=0.1034 15, α(L)=0.0182 3, α(M)=0.00432 6, α(N)=0.001125 16, α(O)=0.000246 4, α(P)=3.60×10-5 5
18-      979.6 3 [E2] 0.00846α=0.00846, α(K)=0.00659 10, α(L)=0.001411 20, α(M)=0.000342 5, α(N)=8.91×10-5 13, α(O)=1.92E-5 3, α(P)=2.66E-6 4
18-     1047.4 1 M1+E21.4 20.0122α=0.0122 11, α(K)=0.0098 9, α(L)=0.00183 14, α(M)=0.00044 4, α(N)=0.000113 9, α(O)=2.47×10-5 18, α(P)=3.5E-6 3
   5426.9 20+ 5.2 ns 5     844.5 2 [E3] 0.0288B(E3)(W.u.)=37 7, α=0.0288, α(K)=0.0195 3, α(L)=0.00702 10, α(M)=0.00179 3, α(N)=0.000468 7, α(O)=9.91E-5 14, α(P)=1.311E-5 19
20+ 5.2 ns 5    1360.3 1 E3 0.00984B(E3)(W.u.)=7.4 8, α=0.00984, α(K)=0.00748 11, α(L)=0.001777 25, α(M)=0.000436 7, α(N)=0.0001139 16, α(O)=2.45E-5 4, α(P)=3.40E-6 5
   5771.7 19-      344.8 2 [E1] 0.0243α=0.0243, α(K)=0.0198 3, α(L)=0.00346 5, α(M)=0.000817 12, α(N)=0.000211 3, α(O)=4.54×10-5 7, α(P)=6.30E-6 9
19-      657.6 1 M1 0.0726α=0.0726, α(K)=0.0590 9, α(L)=0.01035 15, α(M)=0.00245 4, α(N)=0.000638 9, α(O)=0.0001396 20, α(P)=2.04×10-5 3
19-     1705.1 3 [E2] 0.00314α=0.00314, α(K)=0.00244 4, α(L)=0.000431 6, α(M)=0.0001021 15, α(N)=2.65×10-5 4, α(O)=5.77E-6 8, α(P)=8.30E-7 12
   6166.7 20+      395.0 1 E1 0.0181α=0.0181, α(K)=0.01473 21, α(L)=0.00254 4, α(M)=0.000599 9, α(N)=0.0001549 22, α(O)=3.33×10-5 5, α(P)=4.66E-6 7
   6174.2 (22+) 101.8 ns 35       7.5 6 [E2] 6.8×105B(E2)(W.u.)=4.0 +35-18, α=6.8×105 35, α(M)=5.1E+5 27, α(N)=1.34E+5 69, α(O)=2.7E+4 14, α(P)=2.9E+3 15
(22+) 101.8 ns 35     402.5 3 [E3] 0.258B(E3)(W.u.)=45 +52-21, α=0.258, α(K)=0.0951 14, α(L)=0.1202 18, α(M)=0.0325 5, α(N)=0.00851 13, α(O)=0.00176 3, α(P)=0.000212 3
(22+) 101.8 ns 35     747.3 1 [E2] 0.01450B(E2)(W.u.)=3.7E-5 +34-16, α=0.01450, α(K)=0.01086 16, α(L)=0.00274 4, α(M)=0.000677 10, α(N)=0.0001762 25, α(O)=3.76E-5 6, α(P)=5.08E-6 8
E(level)
(keV)		Jπ(level)T1/2(level)E(γ)
(keV)		MultipolarityMixing
Ratio		Conversion
Coefficient		Additional Data
   7142.0 (25-) 18.0 ns 6     432.5 2 (M2) 0.663B(M2)(W.u.)=0.142 10, α=0.663, α(K)=0.505 8, α(L)=0.1195 17, α(M)=0.0295 5, α(N)=0.00775 11, α(O)=0.001689 24, α(P)=0.000242 4
(25-) 18.0 ns 6     967.8 1 E3 0.0209B(E3)(W.u.)=28.8 10, α=0.0209, α(K)=0.01473 21, α(L)=0.00460 7, α(M)=0.001158 17, α(N)=0.000302 5, α(O)=6.44E-5 9, α(P)=8.66E-6 13
   7878.3 (27-) 14 ns 4      15.5 6 M1 153B(M1)(W.u.)=4.0×10-4 +19-10, α=153
(27-) 14 ns 4      59.2 6 [M1] 11.8B(M1)(W.u.)=7.4×10-5 +31-18, α=11.8 4, α(L)=8.9 3, α(M)=2.13 8, α(N)=0.554 19, α(O)=0.121 4, α(P)=0.0177 6
(27-) 14 ns 4     353.8 3 [E2] 0.0856B(E2)(W.u.)=0.0021 +11-7, α=0.0856, α(K)=0.0483 7, α(L)=0.0278 4, α(M)=0.00723 11, α(N)=0.00188 3, α(O)=0.000390 6, α(P)=4.77E-5 7
(27-) 14 ns 4     736.3 1 E2 0.01495B(E2)(W.u.)=0.0017 +7-4, α=0.01495, α(K)=0.01117 16, α(L)=0.00285 4, α(M)=0.000704 10, α(N)=0.000183 3, α(O)=3.91E-5 6, α(P)=5.27E-6 8
   8497.3 (28+)     1355.4 3 O 0.00992α=0.00992, α(K)=0.00753 11, α(L)=0.00179 3, α(M)=0.000441 7, α(N)=0.0001150 17, α(O)=2.47×10-5 4, α(P)=3.44E-6 5
   8579.2 (30+) 154 ns 14      21.9 6 (E2) 1.28×104B(E2)(W.u.)=0.072 21, α=1.28E4 19, α(L)=9.5E3 14, α(M)=2.5E3 4, α(N)=6.5E2 10, α(O)=131 20, α(P)=14.2 21
(30+) 154 ns 14      81.9 6 [E2] 20.7B(E2)(W.u.)=0.066 +12-10, α=20.7 8, α(L)=15.3 6, α(M)=4.11 16, α(N)=1.07 4, α(O)=0.215 9, α(P)=0.0237 9
(30+) 154 ns 14     700.9 1 E3 0.0463B(E3)(W.u.)=27.1 +29-24, α=0.0463, α(K)=0.0286 4, α(L)=0.01316 19, α(M)=0.00341 5, α(N)=0.000891 13, α(O)=0.000187 3, α(P)=2.42E-5 4
   9695.8 (33-) 4.9 ns 7    1116.6 1 E3 0.01508B(E3)(W.u.)=43 6, α=0.01508, α(K)=0.01105 16, α(L)=0.00303 5, α(M)=0.000755 11, α(N)=0.000197 3, α(O)=4.21E-5 6, α(P)=5.75E-6 8
  10619.5 (34-) ≈ 20 ns    923.7 1 (M1) 0.0298B(M1)(W.u.)=1.4×10-6 +14-5, α=0.0298, α(K)=0.0243 4, α(L)=0.00422 6, α(M)=0.000997 14, α(N)=0.000260 4, α(O)=5.69E-5 8, α(P)=8.32E-6 12
  11354.5 (35-) < 3.5 ns     92.5 8 [M1] 3.20α=3.20 10, α(L)=2.44 7, α(M)=0.579 17, α(N)=0.151 5, α(O)=0.0330 10, α(P)=0.00482 14
(35-) < 3.5 ns   1658.4 3 [E2] 0.00328α=0.00328, α(K)=0.00256 4, α(L)=0.000455 7, α(M)=0.0001080 16, α(N)=2.81×10-5 4, α(O)=6.11E-6 9, α(P)=8.77E-7 13
  12211.3 37(-) 17.3 ns 14     856.7 2 (E2) 0.01100B(E2)(W.u.)=7.5E-4 7, α=0.01100, α(K)=0.00843 12, α(L)=0.00194 3, α(M)=0.000475 7, α(N)=0.0001237 18, α(O)=2.65E-5 4, α(P)=3.63E-6 5
37(-) 17.3 ns 14     949.5 3 [E2] 0.00899B(E2)(W.u.)=9.8E-5 +23-25, α=0.00899, α(K)=0.00698 10, α(L)=0.001518 22, α(M)=0.000369 6, α(N)=9.60E-5 14, α(O)=2.06E-5 3, α(P)=2.86E-6 4
  12547.6 (38+) 8.3 ns 14     336.3 3 (E1) 0.0257B(M1)(W.u.)=5.9×10-7 +12-9, α=0.0257, α(K)=0.0209 3, α(L)=0.00366 6, α(M)=0.000866 13, α(N)=0.000224 4, α(O)=4.81E-5 7, α(P)=6.67E-6 10

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Additional Level Data and Comments:

E(level)Jπ(level)T1/2(level)Comments
      0.00+ 23.9 m 12 
% α = 100
Isotope shift (2000Ga58).
E(level): Isotope shift (2000Ga58).
   1273.702+   Configuration=πh9/24.
   1501.424+ 8.80 ns 35  μ=4.0 2
configuration=πh9/24.
   1639.686+ 118 ns 14  μ=5.45 5
Configuration=πh9/24.
   1694.18+ 0.91 µs 3  μ=+7.15 2
Configuration=πh9/24.
   2116.28+   Configuration=π(h9/23f7/2).
   2305.615(+)   Configuration=πh9/24.
   2654.910+   Configuration=πh9/24.
   2696.2   Configuration=πh9/24.
   2760.611- 5.5 ns 2  Configuration=π(h9/23i13/2).
   2881.312+ 2.08 ns 14  Configuration=πh9/24.
   3297.712+   Configuration=π(h9/23f7/2).
   3357.514+ 7.4 ns 9  μ=15.0 4
Configuration=π(h9/23f7/2).
   3510.2   Configuration=π(h9/23f7/2).
   3990.915-   Configuration=π(h9/23i13/2).
   4066.617- 28.9 ns 14  μ=17.9 2
Configuration=π(h9/23i13/2).
   4134.5(16-)   Configuration=π(h9/23i13/2).
   4582.317-   Configuration=π(h9/22f7/2i13/2).
   5114.118-   Configuration=π(h9/22f7/2i13/2).
   5426.920+ 5.2 ns 5  Configuration=π(h9/23i13/2).
   5771.719-   Configuration=π(h9/23f7/2)# ν(p1/2-1g9/2).
   6166.720+   Configuration=π(h9/23i13/2)# ν(p1/2-1g9/2).
   6174.2(22+) 101.8 ns 35  μ=15.8 2
Configuration=π(h9/23i13/2)17-~# ν(p1/2-1g9/2).
   6709.3(23+)   Configuration=π(h9/23i13/2)17-~# ν(p1/2-1i11/2).
   7142.0(25-) 18.0 ns 6  μ=17.8 5
Configuration=π(h9/22i13/22)20+~# ν(p1/2-1g9/2).
E(level)Jπ(level)T1/2(level)Comments
   7524.6(25-)   Configuration=π(h9/23i13/2)17-~# ν(p1/2-1j15/2).
   7819.1(26-)   Configuration=π(h9/22i13/22)# ν(f5/2g9/2).
   7862.8(26-)   Configuration=π(h9/23i13/2)17-~# ν(f5/2j15/2).
   7878.3(27-) 14 ns 4  μ=17.0 8
Configuration=π(h9/23i13/2)17-~# ν(p1/2-2g9/2i11/2).
   8361.9(27-)   Configuration=π(h9/23i13/2)17-~# ν(f5/2-1j15/2).
   8497.3(28+)   O 1355.4γ to (25-), d 618γ to (27-) level, configuration assignment.
   8579.2(30+) 154 ns 14  μ=19.71 9
Configuration=π(h9/22i13/22)20+~# ν(p1/2-2g9/2i11/2).
   8932.9(30+)   Configuration=π(h9/23i13/2)17-~# ν(p1/2-2i11/2j15/2).
   9446.7(31+)   Configuration=π(h9/22i13/22)# ν(p1/2-1f5/2-1g9/2i11/2).
   9509.5(31+)   Configuration=π(h9/23i13/2)# ν(p1/2-1f5/2-1g9/2j15/2).
   9608.4(31)   Possible configuration=π(h9/22i13/22)# ν(p1/2-2g9/2j15/2).
   9695.8(33-) 4.9 ns 7  Configuration=π(h9/22i13/22)20+~# ν(p1/2-2i11/2j15/2).
  10124.7(32+)   Possible configuration=π(h9/22i13/22)# ν(p1/2-1f5/2-1g9/2i11/2).
  10619.5(34-) ≈ 20 ns Configuration=π(h9/22i13/22)# ν(p1/2-1f5/2-1g9/2j15/2).
  11175.3(34)   Possible configuration=π(h9/23i13/2)17-~# ν(f5/2-2i11/2j15/2) or π(h9/22i13/22)20+ ν(f5/2-2g9/2i11/2).
  11262.0(35-)   Configuration=π(h9/22i13/22)# ν(p1/2-1f5/2-1i11/2j15/2) or ν(p1/2-1f5/2-1g9/2j15/2).
  11354.5(35-) < 3.5 ns Configuration=π(h9/22i13/22)# ν(p1/2-1f5/2-1i11/2j15/2) or ν(p1/2-1f5/2-1g9/2j15/2).
  11827.3(36-)   Possible configuration=π(h9/22i13/22)# ν(p1/2-2f5/2-1g9/22j15/2).
  12052.837(-)   Possible configuration=π(h9/22i13/22)# ν(p1/2-1i13/2-1g9/2j15/2).
  12211.337(-) 17.3 ns 14  Configuration=π(h9/22f7/2i13/2)# ν(p1/2-2f5/2-1g9/2i11/2j15/2).
  12547.6(38+) 8.3 ns 14  Configuration=π(h9/22i13/22)# ν(p1/2-2f5/2-1g9/2i11/2j15/2).

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Additional Gamma Comments:

E(level)E(gamma)Comments
   1273.70   1273.7E(γ): others: 1274.8 20 in 212Fr ε decay, 1273.7 1 in 209Bi(6Li,3nγ)
   1501.42    227.7E(γ): others: 227.72 10 in 212Fr ε decay, 227.6 1 in 209Bi(6Li,3nγ)
M(γ): from ce measurements in 212Fr ε decay
   1639.68    138.3E(γ): others: 138.30 10 in 212Ft ε decay, 138.2 1 in 209Bi(6Li,3nγ)
   2116.2    422.0E(γ): from 209Bi(6Li,3nγ). Other: 422.0 2 in (HI,xnγ)
M(γ): Q is assigned in 209Bi(6Li,3nγ) based on DCO ratio, however, the DCO is also consistent with a (D+Q) ΔJ=0 transition.t
   2120.99    619.5E(γ): From 209Bi(6Li,3nγ)
I(γ): From 209Bi(6Li,3nγ)
M(γ): From DCO in 209Bi(6Li,3nγ)
    847.3E(γ): From 209Bi(6Li,3nγ)
I(γ): From 209Bi(6Li,3nγ)
M(γ): From DCO in 209Bi(6Li,3nγ)
   2171.87    532.2E(γ): From 209Bi(6Li,3nγ)
I(γ): From 209Bi(6Li,3nγ)
M(γ): From DCO in 209Bi(6Li,3nγ)
    670.4E(γ): From 209Bi(6Li,3nγ)
I(γ): From 209Bi(6Li,3nγ)
M(γ): From DCO in 209Bi(6Li,3nγ)
   2305.61    133.7E(γ): From 209Bi(6Li,3nγ)
I(γ): From 209Bi(6Li,3nγ)
    666.0E(γ): From 209Bi(6Li,3nγ)
I(γ): From 209Bi(6Li,3nγ)
M(γ): From DCO in 209Bi(6Li,3nγ)
    804.3E(γ): others: 801.9 15 in 212Fr ε decay, 804.8 2 in (HI,xnγ). From 209Bi(6Li,3nγ)
I(γ): From 209Bi(6Li,3nγ)
M(γ): From DCO in 209Bi(6Li,3nγ)
   2313.60    141.8E(γ): From 209Bi(6Li,3nγ)
I(γ): From 209Bi(6Li,3nγ)
    197.3E(γ): From 209Bi(6Li,3nγ)
I(γ): From 209Bi(6Li,3nγ)
M(γ): From DCO in 209Bi(6Li,3nγ)
    674.0E(γ): From 209Bi(6Li,3nγ)
I(γ): From 209Bi(6Li,3nγ)
M(γ): From DCO in 209Bi(6Li,3nγ)
   2324.43    152.4E(γ): From 209Bi(6Li,3nγ)
I(γ): From 209Bi(6Li,3nγ)
    684.9E(γ): From 209Bi(6Li,3nγ)
I(γ): From 209Bi(6Li,3nγ)
M(γ): From DCO in 209Bi(6Li,3nγ)
    823.0E(γ): From 209Bi(6Li,3nγ)
I(γ): From 209Bi(6Li,3nγ)
M(γ): From DCO in 209Bi(6Li,3nγ)
   1050.9E(γ): From 209Bi(6Li,3nγ)
I(γ): From 209Bi(6Li,3nγ)
M(γ): From DCO in 209Bi(6Li,3nγ)
   2402.82    901.4E(γ): From 209Bi(6Li,3nγ)
I(γ): From 209Bi(6Li,3nγ)
M(γ): From DCO in 209Bi(6Li,3nγ)
   2437.92    936.5E(γ): From 209Bi(6Li,3nγ)
I(γ): From 209Bi(6Li,3nγ)
M(γ): From DCO in 209Bi(6Li,3nγ)
   2455.42    954.0E(γ): From 209Bi(6Li,3nγ)
I(γ): From 209Bi(6Li,3nγ)
M(γ): From DCO in 209Bi(6Li,3nγ)
   2613.1    973.4E(γ): From 209Bi(6Li,3nγ)
I(γ): From 209Bi(6Li,3nγ)
M(γ): From DCO in 209Bi(6Li,3nγ)
   2686.29   1046.6E(γ): other: 1047.3 20 from 212Fr ε decay. From 209Bi(6Li,3nγ)
I(γ): other: 52 5 from 212Fr ε decay. From 209Bi(6Li,3nγ)
M(γ): From DCO in 209Bi(6Li,3nγ)
   1184.9E(γ): other: 1185.6 20 from 212Fr ε decay. From 209Bi(6Li,3nγ)
I(γ): from 212Fr ε decay. From 209Bi(6Li,3nγ)
M(γ): From DCO in 209Bi(6Li,3nγ)
   2760.6    105.8E(γ): other: 105.8 1 in 209Bi(6Li,3nγ)
I(γ): other: 100 8 in 209Bi(6Li,3nγ)
    644.5E(γ): other: 644.4 5 in 209Bi(6Li,3nγ)
I(γ): other: < 2 in 209Bi(6Li,3nγ)
   1066.4E(γ): other: 1067.1 3 in 209Bi(6Li,3nγ)
I(γ): other: 3.8 19 in 209Bi(6Li,3nγ)
E(level)E(gamma)Comments
   2833.4    147.1E(γ): From 209Bi(6Li,3nγ)
I(γ): From 209Bi(6Li,3nγ)
   2865.47    179.2E(γ): From 209Bi(6Li,3nγ)
I(γ): From 209Bi(6Li,3nγ)
   1364.0E(γ): From 209Bi(6Li,3nγ)
I(γ): From 209Bi(6Li,3nγ)
M(γ): From DCO in 209Bi(6Li,3nγ)
   2881.3    120.7E(γ): other: 120.3 2 in 209Bi(6Li,3nγ)
I(γ): other: < 0.8 in 209Bi(6Li,3nγ)
    226.4E(γ): other: 226.3 1 in 209Bi(6Li,3nγ)
I(γ): other: 100 8 in 209Bi(6Li,3nγ)
M(γ): Q from γ(θ) in (HI,xnγ), M2 excluded by comparison to RUL.
   2967.1    206.5E(γ): other: 206.6 3 in (HI,xnγ). From 209Bi(6Li,3nγ)
I(γ): From 209Bi(6Li,3nγ)
M(γ): From DCO in 209Bi(6Li,3nγ)
   3066.1    305.5E(γ): From 209Bi(6Li,3nγ)
I(γ): From 209Bi(6Li,3nγ)
M(γ): From DCO in 209Bi(6Li,3nγ)
    949.9E(γ): other: 950.3 2 in (HI,xnγ). From 209Bi(6Li,3nγ)
I(γ): From 209Bi(6Li,3nγ)
M(γ): From DCO in 209Bi(6Li,3nγ)
   3250.4    564.1E(γ): From 209Bi(6Li,3nγ)
I(γ): From 209Bi(6Li,3nγ)
M(γ): From DCO in 209Bi(6Li,3nγ)
   3278.2    212.1E(γ): other: 211.8 3 in (HI,xnγ). From 209Bi(6Li,3nγ)
I(γ): other: 20 13 in 209Bi(6Li,3nγ)
M(γ): From DCO in 209Bi(6Li,3nγ)
    396.6E(γ): From 209Bi(6Li,3nγ)
I(γ): From 209Bi(6Li,3nγ)
M(γ): From DCO in 209Bi(6Li,3nγ)
    623.5E(γ): other: 623.3 2 in (HI,xnγ). From 209Bi(6Li,3nγ)
M(γ): From DCO in 209Bi(6Li,3nγ)
   3297.7     19.5E(γ): This γ not seen in (HI,xnγ) data of 2009Dr12, but implied by γγ data. Eγ is deduced by the evaluators from the level-energy difference. The Iγ is deduced by the evaluators from the measured I(γ+ce) reported in (HI,xnγ) and total conversion coefficient.
    231.5I(γ): other: 9 5 in 209Bi(6Li,3nγ)
    416.3M(γ): Q is assigned in 209Bi(6Li,3nγ) based on DCO ratio, however, the DCO is also consistent with a (D+Q) ΔJ=0 transition.
    537.1I(γ): other: 73 14 in 209Bi(6Li,3nγ)
M(γ): d from γ(θ) in (HI,xnγ), Δπ=yes from level scheme
   3357.5     59.8E(γ): This γ not seen in (HI,xnγ) data of 2009Dr12, but implied by γγ data. Eγ is deduced by the evaluators from the level-energy difference. The Iγ is deduced by the evaluators from the measured I(γ+ce) reported in (HI,xnγ) and total conversion coefficient.
I(γ): This γ not seen in (HI,xnγ) data of 2009Dr12, but implied by γγ data. Eγ is deduced by the evaluators from the level-energy difference. The Iγ is deduced by the evaluators from the measured I(γ+ce) reported in (HI,xnγ) and total conversion coefficient.
   3476.4    595.1E(γ): From 209Bi(6Li,3nγ)
I(γ): From 209Bi(6Li,3nγ)
M(γ): From DCO in 209Bi(6Li,3nγ)
   3494.2    733.6E(γ): From 209Bi(6Li,3nγ)
I(γ): From 209Bi(6Li,3nγ)
M(γ): From DCO in 209Bi(6Li,3nγ)
   3687.1    806.1E(γ): From 209Bi(6Li,3nγ)
I(γ): From 209Bi(6Li,3nγ)
M(γ): From DCO in 209Bi(6Li,3nγ)
   1031.9E(γ): From 209Bi(6Li,3nγ)
I(γ): From 209Bi(6Li,3nγ)
M(γ): From DCO in 209Bi(6Li,3nγ)
   3735.1    974.4M(γ): From DCO in 209Bi(6Li,3nγ)
   4046.2   1164.9E(γ): From 209Bi(6Li,3nγ)
I(γ): From 209Bi(6Li,3nγ)
M(γ): From DCO in 209Bi(6Li,3nγ)
   4151.2    416.2I(γ): other: < 20 in 209Bi(6Li,3nγ)
    793.7M(γ): From DCO in 209Bi(6Li,3nγ)
E(level)E(gamma)Comments
   5426.9     69.8E(γ): This γ not seen in (HI,xnγ) data of 2009Dr12, but implied by γγ data. Eγ is deduced by the evaluators from the level-energy difference. The Iγ is deduced by the evaluators from the measured I(γ+ce) reported in (HI,xnγ) and total conversion coefficient.
   1360.3M(γ): O from γ(θ) in (HI,xnγ), M3 excluded by comparison to RUL
   6174.2      7.5E(γ): This γ not seen in (HI,xnγ) data of 2009Dr12, but implied by γγ data. Eγ is deduced by the evaluators from the level-energy difference. The Iγ is deduced by the evaluators from the measured I(γ+ce) reported in (HI,xnγ) and total conversion coefficient.
I(γ): This γ not seen in (HI,xnγ) data of 2009Dr12, but implied by γγ data. Eγ is deduced by the evaluators from the level-energy difference. The Iγ is deduced by the evaluators from the measured I(γ+ce) reported in (HI,xnγ) and total conversion coefficient.
   7142.0    432.5M(γ): Q from γ(θ) in (HI,xnγ), Δπ=(yes) from level scheme
   7878.3     15.5E(γ): This γ not seen in (HI,xnγ) data of 2009Dr12, but implied by γγ data. Eγ is deduced by the evaluators from the level-energy difference. The Iγ is deduced by the evaluators from the measured I(γ+ce) reported in (HI,xnγ) and total conversion coefficient.
I(γ): This γ not seen in (HI,xnγ) data of 2009Dr12, but implied by γγ data. Eγ is deduced by the evaluators from the level-energy difference. The Iγ is deduced by the evaluators from the measured I(γ+ce) reported in (HI,xnγ) and total conversion coefficient.
     59.2E(γ): This γ not seen in (HI,xnγ) data of 2009Dr12, but implied by γγ data. Eγ is deduced by the evaluators from the level-energy difference. The Iγ is deduced by the evaluators from the measured I(γ+ce) reported in (HI,xnγ) and total conversion coefficient.
I(γ): This γ not seen in (HI,xnγ) data of 2009Dr12, but implied by γγ data. Eγ is deduced by the evaluators from the level-energy difference. The Iγ is deduced by the evaluators from the measured I(γ+ce) reported in (HI,xnγ) and total conversion coefficient.
   8579.2     21.9E(γ): This γ not seen in (HI,xnγ) data of 2009Dr12, but implied by γγ data. Eγ is deduced by the evaluators from the level-energy difference. The Iγ is deduced by the evaluators from the measured I(γ+ce) reported in (HI,xnγ) and total conversion coefficient.
I(γ): This γ not seen in (HI,xnγ) data of 2009Dr12, but implied by γγ data. Eγ is deduced by the evaluators from the level-energy difference. The Iγ is deduced by the evaluators from the measured I(γ+ce) reported in (HI,xnγ) and total conversion coefficient.
M(γ): E3 and M2 are excluded by RUL. E2 remains the only possibility. This point has been discussed in e-mail communication of B. Singh on Dec 18, 2009 with γ.d. Dracoulis, and there is general agreement with the conclusions drawn here, and for implied positive parity of 8557-keV level
     81.9E(γ): This γ not seen in (HI,xnγ) data of 2009Dr12, but implied by γγ data. Eγ is deduced by the evaluators from the level-energy difference. The Iγ is deduced by the evaluators from the measured I(γ+ce) reported in (HI,xnγ) and total conversion coefficient.
I(γ): This γ not seen in (HI,xnγ) data of 2009Dr12, but implied by γγ data. Eγ is deduced by the evaluators from the level-energy difference. The Iγ is deduced by the evaluators from the measured I(γ+ce) reported in (HI,xnγ) and total conversion coefficient.
  10619.5    923.7M(γ): d from γ(θ) in (HI,xnγ), Δπ=no from level scheme
  11175.3    214.0E(γ): ordering of 179-214 cascade is uncertain
  11354.5     92.5E(γ): This γ not seen in (HI,xnγ) data of 2009Dr12, but implied by γγ data. Eγ is deduced by the evaluators from the level-energy difference. The Iγ is deduced by the evaluators from the measured I(γ+ce) reported in (HI,xnγ) and total conversion coefficient.
I(γ): This γ not seen in (HI,xnγ) data of 2009Dr12, but implied by γγ data. Eγ is deduced by the evaluators from the level-energy difference. The Iγ is deduced by the evaluators from the measured I(γ+ce) reported in (HI,xnγ) and total conversion coefficient.
    179.3E(γ): ordering of 179-214 cascade is uncertain
  12211.3    856.7M(γ): Q from γ(θ) in (HI,xnγ), M2 excluded by comparison to RUL
  12547.6    336.3M(γ): d from γ(θ) in (HI,xnγ), Δπ=yes from level scheme

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