List of levels for 192OS

Author: Coral M. Baglin | Citation: Nucl. Data Sheets 113, 1871 (2012) | Cutoff date: 15-Jun-2012

For isotopes and/or isotope shift data, see, e.g., 1974Ba77, 1981Ho22, 1985Au04, 2006Av09.

Theory (partial list only):

2011Ra05 (level energies, B(E2) and staggering calculated for g.s., β and γ bands).

Interacting-boson-model calculation of collective structural evolution: 2011No15.

Q-value: Note: Current evaluation has used the following Q record -1046.3 24 7558.4 22 8821 10 361 4 2003Au03,2011AuZZ

Q-value: Q(β), S(n), Q(α) from 2011AuZZ (Q(β)=-1047.3 23, S(n)=7558.1 21, Q(α)=362 4, respectively, in 2003Au03).

E(level): From least-squares fit to Eγ, omitting the 760.85γ, except where cross references clearly indicate other source.

J^π(level): Values given without comment are based on excitation-function shapes and γ(θ) for set of π=+ states in ¹⁹²Os(n,n’γ) (1983Kl06); authors incorporated (t,α), (t,p), and (d,d’) information in finalizing Jπ values.

T_1/2(level): Deduced from measured B(E2) (adopted values, as reported in Coulomb excitation) and adopted γ-ray properties, except where noted.

E(γ): From (n,n’γ), except as noted.

I(γ): Relative photon branching from each level; values are from ¹⁹²Os(n,n’γ), unless noted to the contrary.

E(level) (keV)	J^π(level)	T_1/2(level)	E(γ) (keV)	Multipolarity	Mixing Ratio	Conversion Coefficient	Additional Data
205.79442	2+	288 ps 4	205.79430 9	E2		0.302	B(E2)(W.u.)=62.1 7, α=0.302
489.0601	2+	32.6 ps +9-10	283.2668 8	M1+E2	-3.8 7	0.121	B(E2)(W.u.)=46.0 +26-12, B(M1)(W.u.)=6.9E-4 24, α=0.121 6
489.0601	2+	32.6 ps +9-10	489.038 13	E2		0.0241	B(E2)(W.u.)=5.62 +21-12, α=0.0241
580.2800	4+	14.7 ps 4	374.4852 8	E2		0.0484	B(E2)(W.u.)=75.6 20, α=0.0484
690.3705	3+		110.33 17	M1+E2	0.52 +22-24	3.96	α=3.96 20
	3+		201.3112 7	M1+E2	-2.7 3	0.379	α=0.379 14
	3+		484.5751 4	M1+E2	-5.9 2	0.0259	α=0.0259
909.592	4+	9.8 ps 4	219.24 6	[M1,E2]		0.43	α=0.43 19
	4+	9.8 ps 4	329.310 9	M1+E2	-1.51 +13-22	0.110	B(E2)(W.u.)=30.9 +36-18, B(M1)(W.u.)=0.0037 6, α=0.110 8
	4+	9.8 ps 4	420.530 10	E2		0.0354	B(E2)(W.u.)=45.2 +14-18, α=0.0354
	4+	9.8 ps 4	703.94 12	E2		0.01031	B(E2)(W.u.)=0.29 3, α=0.01031
956.54	0+	10.3 ps +10-11	467.47 3	[E2]		0.0270	B(E2)(W.u.)=30.4 +30-23, α=0.0270
956.54	0+	10.3 ps +10-11	750.96 15	[E2]		0.00896	B(E2)(W.u.)=0.57 12, α=0.00896
1069.541	4+	6.5 ps +11-9	159.9	[E2]		0.724	B(E2)(W.u.)=24 +6-7, α=0.724
	4+	6.5 ps +11-9	379.154 10	M1+E2	+3.3 +15-12	0.054	B(E2)(W.u.)=56 +14-15, B(M1)(W.u.)=0.0019 17, α=0.054 10
	4+	6.5 ps +11-9	580.43 7	(E2)		0.01593	B(E2)(W.u.)=10.6 +18-21, α=0.01593
	4+	6.5 ps +11-9	863.7	[E2]			B(E2)(W.u.)=0.22 +21-10
1089.23	6+	2.47 ps +8-13	508.97 7	E2		0.0218	B(E2)(W.u.)=100 +5-3, α=0.0218
1127.51	(2+)		437.13 9	(M1+E2)			B(E2)(W.u.)=1.10 10
1127.51	(2+)		638.50 14	(M1+E2)			B(E2)(W.u.)=0.41 4
1143.519	5+		233.92 7	[M1,E2]		0.35	α=0.35 16
	5+		453.10 3	[E2]		0.0292	α=0.0292
	5+		563.27 7	[M1,E2]		0.033	α=0.033 16
1206.29	0+	35 ps 13	1000.1 4	[E2]			B(E2)(W.u.)=0.24 9
1341.162	3-	78 ps 10	431.4 4	[E1]			B(E1)(W.u.)=4.0E-6 7
	3-	78 ps 10	650.81 15	[E1]			B(E1)(W.u.)=4.4E-7 7
	3-	78 ps 10	852.19 2	(E1)			B(E1)(W.u.)=1.53E-6 22
	3-	78 ps 10	1135.5 3	(E1)			B(E1)(W.u.)=1.8E-7 3
	3-	78 ps 10	1341.4 3	(E3)		0.00582	B(E3)(W.u.)=8.6 6, α=0.00582
E(level) (keV)	J^π(level)	T_1/2(level)	E(γ) (keV)	Multipolarity	Mixing Ratio	Conversion Coefficient	Additional Data
1362.016	(5+)		218.488 14	[M1,E2]		0.43	α=0.43 19
	(5+)		292.478 8	(M1+E2)		0.19	α=0.19 9
	(5+)		452.2 10	[M1,E2]		0.06	α=0.06 3
	(5+)		671.54 16	[E2]		0.01144	α=0.01144
1465.34	6+	2.73 ps +36-21	376.1	[E2]		0.0478	B(E2)(W.u.)=26.0 +55-21, α=0.0478
1465.34	6+	2.73 ps +36-21	555.75 9	(E2)		0.01765	B(E2)(W.u.)=52 +3-6, α=0.01765
1645.2	(6+)		575.5	[E2]		0.01625	α=0.01625
1708.39	8+	0.81 ps 4	619.3 3	E2		0.01372	B(E2)(W.u.)=115 6, α=0.01372
1712.91	7+		247.5	[M1,E2]		0.30	α=0.30 14
	7+		569.36 9	[E2]		0.01667	α=0.01667
	7+		624.0 4	[M1,E2]		0.025	α=0.025 12
1968.01	(7+)		322.7	[M1,E2]		0.14	α=0.14 7
	(7+)		502.5	[M1,E2]		0.044	α=0.044 22
	(7+)		606.0 2	[E2]		0.01442	α=0.01442
2015.40	(10-)	5.9 s 1 % IT > 87 % β^- < 13	47.4 2	[E3]		7.56×10³	B(E3)(W.u.)=0.0026 6, α=7.56E3 22
	(10-)	5.9 s 1 % IT > 87 % β^- < 13	302.48 6	(E3)		0.426	B(E3)(W.u.)=1.98E-4 22, α=0.426
	(10-)	5.9 s 1 % IT > 87 % β^- < 13	307.02 9	(M2)		0.941	B(M2)(W.u.)=3.8×10^-9 5, α=0.941
2133.9	8+	1.34 ps +16-20	668.6	(E2)		0.01155	B(E2)(W.u.)=47 +7-6, α=0.01155
2418.8	10+	0.45 ps +11-4	710.4	E2		0.01011	B(E2)(W.u.)=105 +10-26, α=0.01011
3103.8	(12+)	≥ 2.1 ps	685	(E2)		0.01094	B(E2)(W.u.)<27, α=0.01094
4113.8	(16+)	0.19 µs 10 % IT = 100	446	[E2]		0.0304	B(E2)(W.u.)=0.0025 14, α=0.0304

Q(β-)=-1046.3 keV 24	S(n)= 7558.4 keV 23	S(p)= 8821 keV 10	Q(α)= 361 keV 4
Reference: 2012WA38

References:
A	¹⁹²Re β^- decay	B	¹⁹²Os IT decay (5.9 S)
C	¹⁹²Ir ε decay (73.829 d)	D	¹⁹⁰Os(t,p)
E	¹⁹¹Os(n,γ) E=THERMAL	F	¹⁹²Os(E,E’)
G	¹⁹²Os(p,p’), (pol p,p’)	H	¹⁹²Os(p,p’γ), (d,d’γ)
I	¹⁹²Os(n,n’γ)	J	¹⁹²Os(d,d’)
K	¹⁹²Os(α,α’)	L	Coulomb Excitation
M	¹⁹³Ir(d,³He)	N	¹⁹³Ir(t,α), (pol t,α)
O	¹⁹²Os(γ,XN)	P	muonic atom
Q	¹⁹²Os(¹²C,¹²C’)	R	¹⁹²Os(n,n’)
S	¹⁹⁸Pt(¹³⁶Xe,xγ)	T	¹⁹²Os(γ,γ’)

E(level) (keV)	XREF	J^π(level)	T_1/2(level)	E(γ) (keV)	I(γ)	M(γ)	Final Levels
0.0	A B C D E F G H I J K L M N O P Q R S T	0+	STABLE
205.79442 9	A B C D E F G H I J K L M N P Q R S T	2+	288 ps 4	205.79430 9	100	E2	0.0	0+
489.0601 6	A B C D E F G H I J K L M N P Q R T	2+	32.6 ps +9-10	283.2668 8 489.038 13	60.7 6 100 3	M1+E2 E2	205.79442 0.0	2+ 0+
580.2800 8	B C D E F G H I J K L N R S	4+	14.7 ps 4	374.4852 8	100	E2	205.79442	2+
690.3705 4	B C E H I L N P	3+		110.33 17 201.3112 7 484.5751 4	0.40 2 14.74 16 100.0 3	M1+E2 M1+E2 M1+E2	580.2800 489.0601 205.79442	4+ 2+ 2+
909.592 7	B C E G H I J K L M N	4+	9.8 ps 4	219.24 6 329.310 9 420.530 10 703.94 12	3.3 8 28.6 17 100 5 7.7 7	[M1,E2] M1+E2 E2 E2	690.3705 580.2800 489.0601 205.79442	3+ 4+ 2+ 2+
956.54 3	A D I J L	0+	10.3 ps +10-11	467.47 3 750.96 15	100 9 20 3	[E2] [E2]	489.0601 205.79442	2+ 2+
1069.541 9	B E G H I J K L M N	4+	6.5 ps +11-9	159.9S 379.154 10 580.43 7 863.7	0.36 6 69 11 100 15 14	[E2] M1+E2 (E2) [E2]	909.592 690.3705 489.0601 205.79442	4+ 3+ 2+ 2+
1089.23 7	B H I J L S	6+	2.47 ps +8-13	508.97 7	100	E2	580.2800	4+
1127.51 6	I L	(2+)		437.13 9 638.50 14 921.5 3 1127.6 3	100 9 89 6 51 6 13.1 10	(M1+E2) (M1+E2) [E2]	690.3705 489.0601 205.79442 0.0	3+ 2+ 2+ 0+
1143.519 15	B E H I L	5+		233.92 7 453.10 3 563.27 7	3.3 7 100 6 19.0 26	[M1,E2] [E2] [M1,E2]	909.592 690.3705 580.2800	4+ 3+ 4+
1206.29 20	D I L	0+	35 ps 13	1000.1 4	100	[E2]	205.79442	2+
1341.162 13	D E F G H I J K L N R	3-	78 ps 10	271.584 13 431.4 4 650.81 15 852.19 2 1135.5 3 1341.4 3 ?	98 10 34 3 12.8 11 100 5 28.2 15 2.6 5	(E1+M2) [E1] [E1] (E1) (E1) (E3)	1069.541 909.592 690.3705 489.0601 205.79442 0.0	4+ 4+ 3+ 2+ 2+ 0+
E(level) (keV)	XREF	J^π(level)	T_1/2(level)	E(γ) (keV)	I(γ)	M(γ)	Final Levels
1362.016 12	B E I L	(5+)		218.488 14 292.478 8 452.2 10 671.54 16	9.0 23 60 10 100 17 15.4 21	[M1,E2] (M1+E2) [M1,E2] [E2]	1143.519 1069.541 909.592 690.3705	5+ 4+ 4+ 3+
1409.86 6	I	(2+)		719.25 17 829.63 8 920.9 3 1204.3 2 1409.5 2	55 4 34 3 14 8 100 8 19 3	D Q	690.3705 580.2800 489.0601 205.79442 0.0	3+ 4+ 2+ 2+ 0+
1450.31 5	D I	(2+)		540.63 7 760.85 10 870.10 8 1244.8 3 1450.40 16	75 7 31 4 100 5 98 8 32 5		909.592 690.3705 580.2800 205.79442 0.0	4+ 3+ 4+ 2+ 0+
1456.6 3	D I	(4+)		967.5 3	100		489.0601	2+
1465.34 9	B E I L	6+	2.73 ps +36-21	376.1? 555.75 9 884.8	7.1 15 100 12 ≤11	[E2] (E2)	1089.23 909.592 580.2800	6+ 4+ 4+
1560.6 7 ?	H	(4-)		219.6? 417?			1341.162 1143.519	3- 5+
1591.75 4	I	(3)		250.59 3 901.31 15 1011.1 4 1102.7 3	100 15 65 4 13.2 17 51 4		1341.162 690.3705 580.2800 489.0601	3- 3+ 4+ 2+
1612.87 10	I N	(2+)		1124.1 3 1406.92 12 1613.0 2	100 5 50 4 13.4 22		489.0601 205.79442 0.0	2+ 2+ 0+
1645.2 6	B L	(6+)		283.2 575.5 735.6?		[E2]	1362.016 1069.541 909.592	(5+) 4+ 4+
E(level) (keV)	XREF	J^π(level)	T_1/2(level)	E(γ) (keV)	I(γ)	M(γ)	Final Levels
1665.09 9	D I N	(1+,2+)		458.7 2 708.2 3 974.1 5 1176.4 3 1459.33 10	16 5 10 3 19 4 100 10 82 6	D	1206.29 956.54 690.3705 489.0601 205.79442	0+ 0+ 3+ 2+ 2+
1708.39 13	B L S	8+	0.81 ps 4	619.3 3	100	E2	1089.23	6+
1712.91 9	B	7+		247.5 569.36 9 624.0 4	0.75 100 9 1.9 4	[M1,E2] [E2] [M1,E2]	1465.34 1143.519 1089.23	6+ 5+ 6+
1733.79 12	I	(2+)		824.23 16 1043.7 4 1153.8 5 1527.84 18	15 3 100 7 19 4 32 5		909.592 690.3705 580.2800 205.79442	4+ 3+ 4+ 2+
1780.34 11	D I N	(2+,3,4+)		370.46 18 1089.9 4 1200.1 2 1291.4 2 1574.3 3	100 41 19 3 16 6 48 4 11 3	D(+Q)	1409.86 690.3705 580.2800 489.0601 205.79442	(2+) 3+ 4+ 2+ 2+
1807.71 11	I N	2(+)		1117.2 3 1227.4 2 1318.70 16 1601.9 3	45 4 26.5 25 100 6 14.1 18	D(+Q) Q D+Q	690.3705 580.2800 489.0601 205.79442	3+ 4+ 2+ 2+
1826.51 6	D I	1		1337.77 16 1620.95 12 1826.36 7	28 4 55 6 100 6	D D D	489.0601 205.79442 0.0	2+ 2+ 0+
1837.40 11	D I	(1,2)+		1146.7 5 1348.59 17 1837.22 15	33 7 100 11 66 9	D(+Q)	690.3705 489.0601 0.0	3+ 2+ 0+
1857.97 8	I	(2,3)+		788.42 8 948.2 3 1167.9 3	100 6 24 3 27 3		1069.541 909.592 690.3705	4+ 4+ 3+
E(level) (keV)	XREF	J^π(level)	T_1/2(level)	E(γ) (keV)	I(γ)	M(γ)	Final Levels
1867.87 12	D I	(2+)		958.3 4 1378.80 12	22 5 100 8	D+Q	909.592 489.0601	4+ 2+
1868.70 9	D I	(2,3)		741.04 12 1663.05 12	100 7 41 4	D+Q	1127.51 205.79442	(2+) 2+
1878.79 8	D I N	(2+)		809.28 10 1389.68 11	21 3 100 6		1069.541 489.0601	4+ 2+
1894.93 17	D I N	(3+)		986.0 4 1314.51 18	84 5 100 11	D	909.592 580.2800	4+ 4+
1902.68 9	D I N	(1,2)+		1413.75 15 1697.46 16 1902.02 15	100 9 93 16 69 9		489.0601 205.79442 0.0	2+ 2+ 0+
1921.68 15	I	1,3		1432.5 3 1715.92 17	56 10 100 12	D+Q	489.0601 205.79442	2+ 2+
1924	D	0+
1936.9 4	I	(2+)		980.4 4	100		956.54	0+
1940	D F N	(4+)
1940.80 16	D I N	(0+,1,2)		1735.00 16	100		205.79442	2+
1947.77 8	D I N	(2)		334.6 3 820.32 17 1257.3 2 1742.00 10	33 10 8.7 20 38 3 100 7	D+Q	1612.87 1127.51 690.3705 205.79442	(2+) (2+) 3+ 2+
1951.54 7	D I N	(1,2+)		1746.08 15 1951.43 8	66 9 100 21		205.79442 0.0	2+ 0+
1960 20	M
1968.01 20	B L	(7+)		322.7 502.5 606.0 2	13.3 9.3 100 27	[M1,E2] [M1,E2] [E2]	1645.2 1465.34 1362.016	(6+) 6+ (5+)
1984.5 4	I	(1,2+)		1028.0 4	100		956.54	0+
1996.93 10	I	1		1040.5 4 1996.91 10	30 3 100 7	D	956.54 0.0	0+ 0+
E(level) (keV)	XREF	J^π(level)	T_1/2(level)	E(γ) (keV)	I(γ)	M(γ)	Final Levels
2015.40 11	B	(10-)	5.9 s 1 % IT > 87 % β^- < 13	47.4 2 S 302.48 6 307.02 9	0.0031 6 100 6 13.3 10	[E3] (E3) (M2)	1968.01 1712.91 1708.39	(7+) 7+ 8+
2016 8	N
2030 20	M
2043.26 19	I			916.0 2 1553.2 4	100 11 44 6		1127.51 489.0601	(2+) 2+
2047.40 6	I	(1+,2)		1357.4 2 1558.16 9 1841.66 7	21 4 100 6 58 6		690.3705 489.0601 205.79442	3+ 2+ 2+
2051.83 11	I N	(2,3)		1361.51 14 1562.68 18	100 8 85 11	D+Q	690.3705 489.0601	3+ 2+
2081.17 12	I	(1,2+)		1875.52 15 2080.91 19	100 11 69 5		205.79442 0.0	2+ 0+
2099.00 10	D I N	(2+)		1893.20 10	100	D	205.79442	2+
2127.92 17	D I			1922.12 17	100		205.79442	2+
2133.9 10	L	8+	1.34 ps +16-20	668.6	100	(E2)	1465.34	6+
2147.15 9	I	(0+,1,2)		1020.2 4 1941.32 9	66 6 100 6		1127.51 205.79442	(2+) 2+
2173.02 11	I N	(1,2+)		1967.26 13 2172.9 2	100 9 44 5		205.79442 0.0	2+ 0+
2187.26 8	I	(2+,3)		1607.00 9 1981.38 16	100 15 24 3		580.2800 205.79442	4+ 2+
2208.36 14	I N	(LE4)		2002.55 14	100		205.79442	2+
2223.48 9	I			1532.9 12 2017.68 9	4.4 22 100 3		690.3705 205.79442	3+ 2+
2258.18 20	I N			1567.8 2	100		690.3705	3+
2275.32 8	I N	(3,4+)		1584.95 9 2069.48 14	100 4 57 7		690.3705 205.79442	3+ 2+
2308.6 20	I N	(2+,3,4)		1399 2	100		909.592	4+
E(level) (keV)	XREF	J^π(level)	T_1/2(level)	E(γ) (keV)	I(γ)	M(γ)	Final Levels
2337.32 8	I N	(1,2)		2131.51 8	100	D+Q	205.79442	2+
2358.88 20	I N			1668.5 2	100		690.3705	3+
2391.2 10	N T	1	104 fs 9	2391.2	100	D	0.0	0+
2418.8 10	L S	10+	0.45 ps +11-4	710.4	100	E2	1708.39	8+
2423 8	N
2466 8	N
2478.3 7	T	1	35 fs 13	2272.5 2478.3	100 24 56	D	205.79442 0.0	2+ 0+
2489 8	N
2508 8	N
2619 8	N
2643 8	N
2694.2 7	N T	1	31 fs 8	2488.4 2694.2	100 18 66	D	205.79442 0.0	2+ 0+
2748.3 7	N T	1	57 fs 14	2542.5 2748.3	75 18 100	D	205.79442 0.0	2+ 0+
2788 8	N
2804.9 10	T	1	66 fs 5	2804.9	100	D	0.0	0+
2814.3 7	T	1	22 fs 4	2608.5 2814.3	143 20 100	D	205.79442 0.0	2+ 0+
2820.0 10	T	1	123 fs 13	2820.0	100	D	0.0	0+
2864.5 10	T	1	84 fs 6	2864.5	100	D	0.0	0+
2887 8	N
2894.2 15	L	10+		760.3	100	(E2)	2133.9	8+
2903.5 7	T	1	23.2 fs 16	2414.4 2903.5	12 3 100	D	489.0601 0.0	2+ 0+
2915.2 7	N T	1	10.4 fs 15	2709.4 2915.2	100 9 47	D	205.79442 0.0	2+ 0+
2941.3 10	N T	1	91 fs 7	2941.3	100	D	0.0	0+
2948.0 6	N T	1	7.8 fs 5	2458.9 2742.2 2948.0	11.6 25 47.0 23 100	D	489.0601 205.79442 0.0	2+ 2+ 0+
E(level) (keV)	XREF	J^π(level)	T_1/2(level)	E(γ) (keV)	I(γ)	M(γ)	Final Levels
2965.6 10	T	1	95 fs 8	2965.6	100	D	0.0	0+
2978 8	N
2986.8 15	S	(12+)		568	100		2418.8	10+
3046.4 6	T	1	11.3 fs 12	2557.3 2840.6 3046.4	26 7 79 6 100	D	489.0601 205.79442 0.0	2+ 2+ 0+
3088 10	N
3103.8 15	L	(12+)	≥ 2.1 ps	685	100	(E2)	2418.8	10+
3148.9 10	T	1	127 fs 14	3148.9	100	D	0.0	0+
3196.3 10	T	1	62 fs 4	3196.3	100	D	0.0	0+
3207.0 10	T	1	109 fs 13	3207.0	100		0.0	0+
3210.8 15	L	12+		792	100		2418.8	10+
3217.1 10	T	1	69 fs 5	3217.1	100	D	0.0	0+
3239.9 7	T	1	29 fs 5	3034.1 3239.9	77 11 100	D	205.79442 0.0	2+ 0+
3257.6 10	T	1	123 fs 13	3257.6	100	D	0.0	0+
3273.3 10	T	1	39.7 fs 24	3273.3	100	D	0.0	0+
3281.0 10	T	1	72 fs 7	3281.0	100	D	0.0	0+
3289.5 7	T	1	6.0 fs 7	3083.7 3289.5	100 7 51	D	205.79442 0.0	2+ 0+
3428.9 7	T	1	28 fs 4	3223.1 3428.9	44 8 100	D	205.79442 0.0	2+ 0+
3536.4 7	T	1	9.8 fs 25	3330.6 3536.4	100 16 41	D	205.79442 0.0	2+ 0+
3667.8 18	S	(14+)		681	100		2986.8	(12+)
3756.8 10	T	1	38 fs 4	3756.8	100	D	0.0	0+
3836.5 10	T	1	29 fs 3	3836.5	100	D	0.0	0+
3864.7 10	T	1	71 fs 14	3864.7	100	D	0.0	0+
3890.5 10	T			3890.5	100		0.0	0+
4113.8 20	S	(16+)	0.19 µs 10 % IT = 100	446	100	[E2]	3667.8	(14+)
E(level) (keV)	XREF	J^π(level)	T_1/2(level)	E(γ) (keV)	I(γ)	M(γ)	Final Levels
12.68E3 6	O	1-	2.49 MeV 23
14.35E3 12	O	1-	4.41 MeV 13

E(level)	J^π(level)	T_1/2(level)	Comments
0.0	0+	STABLE	T_1/2(2β^-)>9.8×10¹² y (specific activity measurements, 1952Fr23, as reassessed by 1995Tr07 assuming Q(2β^-)=413 3). E(level): T_1/2(2β^-)>9.8×10¹² y (specific activity measurements, 1952Fr23, as reassessed by 1995Tr07 assuming Q(2β^-)=413 3). K=0 GS band (1996Wu07). J^π(level): Based on smooth progression of level energies and independently established Jπ(g.s.) and mult(374γ), definite Jπ has been assigned to all members of the g.s. band.
205.79442	2+	288 ps 4	Q=-0.96 3, μ=+0.792 20 β₂(nuclear)=0.14, β₂(Coulomb)=0.164 from (α,α’). E(level): β₂(nuclear)=0.14, β₂(Coulomb)=0.164 from (α,α’). K=0 GS band (1996Wu07). J^π(level): Based on smooth progression of level energies and independently established Jπ(g.s.) and mult(374γ), definite Jπ has been assigned to all members of the g.s. band.
489.0601	2+	32.6 ps +9-10	Q=-0.8 3, μ=+0.58 4 E(level): From ¹⁹¹Os(n,γ) E=thermal. K=2 QUASI-G band (1993Os05,1996Wu07). J^π(level): Based on smooth progression of level energies and independently established Jπ(489) and mult(201γ), definite Jπ has been assigned to all members of the γ band.
580.2800	4+	14.7 ps 4	μ=+1.56 12 B(E4): weighted average of 0.037 4 and 0.048 4 from (e,e’). E(level): B(E4): weighted average of 0.037 4 and 0.048 4 from (e,e’). K=0 GS band (1996Wu07). J^π(level): Based on smooth progression of level energies and independently established Jπ(g.s.) and mult(374γ), definite Jπ has been assigned to all members of the g.s. band.
690.3705	3+		E(level): From ¹⁹¹Os(n,γ) E=thermal. K=2 QUASI-G band (1993Os05,1996Wu07). J^π(level): Based on smooth progression of level energies and independently established Jπ(489) and mult(201γ), definite Jπ has been assigned to all members of the γ band.
909.592	4+	9.8 ps 4	μ=+1.72 36 β₄(nuclear)=+0.005 from (α,α’); E4 matrix element is 1160 e×fm⁴ 290 from (pol p,p’). E(level): β₄(nuclear)=+0.005 from (α,α’); E4 matrix element is 1160 e×fm⁴ 290 from (pol p,p’). From ¹⁹¹Os(n,γ) E=thermal. K=2 QUASI-G band (1993Os05,1996Wu07). J^π(level): Based on smooth progression of level energies and independently established Jπ(489) and mult(201γ), definite Jπ has been assigned to all members of the γ band.
956.54	0+	10.3 ps +10-11	E(level): From ¹⁹²Os IT decay (5.9 s). possible K=0 band (1993Os05).
1069.541	4+	6.5 ps +11-9	β₄(nuclear)=-0.010 from (α,α’); E4 matrix element is 1080 e×fm⁴ 270 from (pol p,p’). E(level): β₄(nuclear)=-0.010 from (α,α’); E4 matrix element is 1080 e×fm⁴ 270 from (pol p,p’). K=4 band (1993Os05).
1089.23	6+	2.47 ps +8-13	E(level): K=0 GS band (1996Wu07). J^π(level): Based on smooth progression of level energies and independently established Jπ(g.s.) and mult(374γ), definite Jπ has been assigned to all members of the g.s. band.
1127.51	(2+)		E(level): From ¹⁹²Os IT decay (5.9 s). possible K=0 band (1993Os05).
1143.519	5+		E(level): From ¹⁹¹Os(n,γ) E=thermal. K=2 QUASI-G band (1993Os05,1996Wu07). J^π(level): Based on smooth progression of level energies and independently established Jπ(489) and mult(201γ), definite Jπ has been assigned to all members of the γ band.
1362.016	(5+)		E(level): K=4 band (1993Os05).
1465.34	6+	2.73 ps +36-21	E(level): From ¹⁹¹Os(n,γ) E=thermal. K=2 QUASI-G band (1993Os05,1996Wu07). J^π(level): Based on smooth progression of level energies and independently established Jπ(489) and mult(201γ), definite Jπ has been assigned to all members of the γ band.
1645.2	(6+)		E(level): From ¹⁹²Os IT decay (5.9 s). K=4 band (1993Os05). J^π(level): Continuing Jπ pattern established by band structure and coincidence data.
1708.39	8+	0.81 ps 4	E(level): K=0 GS band (1996Wu07). J^π(level): Based on smooth progression of level energies and independently established Jπ(g.s.) and mult(374γ), definite Jπ has been assigned to all members of the g.s. band.
1712.91	7+		E(level): From ¹⁹²Os IT decay (5.9 s). K=2 QUASI-G band (1993Os05,1996Wu07). J^π(level): Continuing Jπ pattern established by band structure and coincidence data.
1878.79	(2+)		XREF: n(1883).
1940	(4+)		B(E4): from (e,e’). E(level): B(E4): from (e,e’).
1968.01	(7+)		E(level): From ¹⁹²Os IT decay (5.9 s). K=4 band (1993Os05). J^π(level): Continuing Jπ pattern established by band structure and coincidence data.
2015.40	(10-)	5.9 s 1 % IT > 87 % β^- < 13	Identification: excitation functions for neutrons on ¹⁹²Os and absence of β^- activity (1973Pa21, 1979KaYT); decay to known levels in ¹⁹²Os (1965Bl12, 1973Pa21, 1979KaYT). E(level): Identification: excitation functions for neutrons on ¹⁹²Os and absence of β^- activity (1973Pa21, 1979KaYT); decay to known levels in ¹⁹²Os (1965Bl12, 1973Pa21, 1979KaYT).
2133.9	8+	1.34 ps +16-20	E(level): From ¹⁹²Os IT decay (5.9 s). K=2 QUASI-G band (1993Os05,1996Wu07). J^π(level): Continuing Jπ pattern established by band structure and coincidence data.
2358.88			1669γ to 3⁺ 690. E(level): 1669γ to 3⁺ 690.
2391.2	1	104 fs 9	E(level): From (γ,γ’). Eγ is from level energy difference. From (γ,γ’). J^π(level): From (γ,γ’). T_1/2(level): From (γ,γ’).
2418.8	10+	0.45 ps +11-4	E(level): K=0 GS band (1996Wu07). J^π(level): Based on smooth progression of level energies and independently established Jπ(g.s.) and mult(374γ), definite Jπ has been assigned to all members of the g.s. band.
2694.2	1	31 fs 8	XREF: n(2686). E(level): From (γ,γ’). Eγ is from level energy difference. From (γ,γ’). J^π(level): From (γ,γ’). T_1/2(level): From (γ,γ’).
E(level)	J^π(level)	T_1/2(level)	Comments
2748.3	1	57 fs 14	XREF: n(2756). E(level): From (γ,γ’). Eγ is from level energy difference. From (γ,γ’). J^π(level): From (γ,γ’). T_1/2(level): From (γ,γ’).
2804.9	1	66 fs 5	E(level): From (γ,γ’). Eγ is from level energy difference. From (γ,γ’). J^π(level): From (γ,γ’). T_1/2(level): From (γ,γ’).
2814.3	1	22 fs 4	E(level): From (γ,γ’). Eγ is from level energy difference. From (γ,γ’). J^π(level): From (γ,γ’). T_1/2(level): From (γ,γ’).
2820.0	1	123 fs 13	E(level): From (γ,γ’). Eγ is from level energy difference. From (γ,γ’). J^π(level): From (γ,γ’). T_1/2(level): From (γ,γ’).
2864.5	1	84 fs 6	E(level): From (γ,γ’). Eγ is from level energy difference. From (γ,γ’). J^π(level): From (γ,γ’). T_1/2(level): From (γ,γ’).
2894.2	10+		E(level): From ¹⁹²Os IT decay (5.9 s). K=2 QUASI-G band (1993Os05,1996Wu07). J^π(level): Continuing Jπ pattern established by band structure and coincidence data.
2903.5	1	23.2 fs 16	E(level): From (γ,γ’). Eγ is from level energy difference. From (γ,γ’). J^π(level): From (γ,γ’). T_1/2(level): From (γ,γ’).
2915.2	1	10.4 fs 15	E(level): From (γ,γ’). Eγ is from level energy difference. From (γ,γ’). J^π(level): From (γ,γ’). T_1/2(level): From (γ,γ’).
2941.3	1	91 fs 7	E(level): From (γ,γ’). Eγ is from level energy difference. From (γ,γ’). J^π(level): From (γ,γ’). T_1/2(level): From (γ,γ’).
2948.0	1	7.8 fs 5	E(level): From (γ,γ’). Eγ is from level energy difference. From (γ,γ’). J^π(level): From (γ,γ’). T_1/2(level): From (γ,γ’).
2965.6	1	95 fs 8	E(level): From (γ,γ’). Eγ is from level energy difference. From (γ,γ’). J^π(level): From (γ,γ’). T_1/2(level): From (γ,γ’).
3046.4	1	11.3 fs 12	E(level): From (γ,γ’). Eγ is from level energy difference. From (γ,γ’). J^π(level): From (γ,γ’). T_1/2(level): From (γ,γ’).
3148.9	1	127 fs 14	E(level): From (γ,γ’). Eγ is from level energy difference. From (γ,γ’). J^π(level): From (γ,γ’). T_1/2(level): From (γ,γ’).
3196.3	1	62 fs 4	E(level): From (γ,γ’). Eγ is from level energy difference. From (γ,γ’). J^π(level): From (γ,γ’). T_1/2(level): From (γ,γ’).
3207.0	1	109 fs 13	E(level): From (γ,γ’). Eγ is from level energy difference. From (γ,γ’). J^π(level): From (γ,γ’). T_1/2(level): From (γ,γ’).
3210.8	12+		E(level): K=0 GS band (1996Wu07). J^π(level): Based on smooth progression of level energies and independently established Jπ(g.s.) and mult(374γ), definite Jπ has been assigned to all members of the g.s. band.
3217.1	1	69 fs 5	E(level): From (γ,γ’). Eγ is from level energy difference. From (γ,γ’). J^π(level): From (γ,γ’). T_1/2(level): From (γ,γ’).
3239.9	1	29 fs 5	E(level): From (γ,γ’). Eγ is from level energy difference. From (γ,γ’). J^π(level): From (γ,γ’). T_1/2(level): From (γ,γ’).
3257.6	1	123 fs 13	E(level): From (γ,γ’). Eγ is from level energy difference. From (γ,γ’). J^π(level): From (γ,γ’). T_1/2(level): From (γ,γ’).
3273.3	1	39.7 fs 24	E(level): From (γ,γ’). Eγ is from level energy difference. From (γ,γ’). J^π(level): From (γ,γ’). T_1/2(level): From (γ,γ’).
3281.0	1	72 fs 7	E(level): From (γ,γ’). Eγ is from level energy difference. From (γ,γ’). J^π(level): From (γ,γ’). T_1/2(level): From (γ,γ’).
3289.5	1	6.0 fs 7	E(level): From (γ,γ’). Eγ is from level energy difference. From (γ,γ’). J^π(level): From (γ,γ’). T_1/2(level): From (γ,γ’).
3428.9	1	28 fs 4	E(level): From (γ,γ’). Eγ is from level energy difference. From (γ,γ’). J^π(level): From (γ,γ’). T_1/2(level): From (γ,γ’).
3536.4	1	9.8 fs 25	E(level): From (γ,γ’). Eγ is from level energy difference. From (γ,γ’). J^π(level): From (γ,γ’). T_1/2(level): From (γ,γ’).
3756.8	1	38 fs 4	E(level): From (γ,γ’). Eγ is from level energy difference. From (γ,γ’). J^π(level): From (γ,γ’). T_1/2(level): From (γ,γ’).
E(level)	J^π(level)	T_1/2(level)	Comments
3836.5	1	29 fs 3	E(level): From (γ,γ’). Eγ is from level energy difference. From (γ,γ’). J^π(level): From (γ,γ’). T_1/2(level): From (γ,γ’).
3864.7	1	71 fs 14	E(level): From (γ,γ’). Eγ is from level energy difference. From (γ,γ’). J^π(level): From (γ,γ’). T_1/2(level): From (γ,γ’).
12.68E3	1-	2.49 MeV 23	Component of GDR; Jπ=1-. E(level): Component of GDR; Jπ=1-.
14.35E3	1-	4.41 MeV 13	Component of GDR; Jπ=1-. E(level): Component of GDR; Jπ=1-.

E(level)	E(gamma)	Comments
205.79442	205.79430	E(γ): From ¹⁹²Ir ε decay (73.827 d). I(γ): From ¹⁹²Ir ε decay (73.827 d).
489.0601	283.2668	E(γ): From ¹⁹²Ir ε decay (73.827 d). I(γ): from ε decay; consistent with 59 4 from IT decay, 54 6 from (n,γ) E=thermal and 63 8 from (n,n’γ) but not with 49 3 from Coulomb excitation or 94 from muonic atom.. From ¹⁹²Ir ε decay (73.827 d).
489.0601	489.038	E(γ): weighted average of 489.032 15 from (n,n’γ), 489.04 4 from (n,γ) E=thermal) and 489.06 3 from ε decay.. Weighted average from ¹⁹²Ir ε decay (73.827 d), (n,n’γ) and (n,γ). I(γ): from ¹⁹²Ir ε decay (73.829 d).
580.2800	374.4852	E(γ): From ¹⁹²Ir ε decay (73.827 d). I(γ): From ¹⁹²Ir ε decay (73.827 d).
690.3705	110.33	E(γ): From ¹⁹²Ir ε decay (73.827 d). I(γ): From ¹⁹²Ir ε decay (73.827 d).
	201.3112	E(γ): From ¹⁹²Ir ε decay (73.827 d). I(γ): From ¹⁹²Ir ε decay (73.827 d).
	484.5751	E(γ): From ¹⁹²Ir ε decay (73.827 d). I(γ): From ¹⁹²Ir ε decay (73.827 d).
909.592	219.24	E(γ): From ¹⁹¹Os(n,γ) E=thermal. I(γ): weighted average of 3.2 16 from (n,γ) and 3.3 9 (n,n’γ).
	329.310	E(γ): From ¹⁹¹Os(n,γ) E=thermal. I(γ): unweighted average of 25.2 8 from ε decay, 32 3 from (n,γ) E=thermal, 31 4 from (n,n’γ), 26 6 from IT decay (5.9 s). Other Iγ: 13.9 16 from Coulomb excitation. M(γ): D+Q from γγ(θ) in ε decay; not E1⁺M2 from RUL.
	420.530	E(γ): From ¹⁹¹Os(n,γ) E=thermal. I(γ): Weighted average from ¹⁹²Ir ε decay (73.827 d), ¹⁹²Os IT decay (5.9 s), ¹⁹¹Os(n,γ) E=thermal, ¹⁹²Os(n,n’γ). M(γ): from γ(θ) in (n,n’γ) and RUL.
	703.94	E(γ): weighted average of 703.78 19 from ε decay, 704.03 14 from (n,n’γ), 703.96 10 from IT decay (5.9 s). I(γ): unweighted average of 7.7 10 from ε decay, 8.3 10 from Coulomb excitation, 9 3 from IT decay (59 s) and 5.7 7 from (n,n’γ) (the weighted average is 6.9 7). M(γ): from γ(θ) in (n,n’γ) and RUL.
1069.541	159.9	E(γ): From Coulomb excitation. I(γ): from Coulomb excitation.
	379.154	E(γ): From ¹⁹¹Os(n,γ) E=thermal. I(γ): Iγ(379)/Iγ(580)=0.50 15, 0.73 18, 0.89 12, 1.10 18, 0.42 12 and 0.51 17, respectively, from IT decay, (n,γ), (n,n’γ), (d,d’γ), (p,p’γ) and Coulomb excitation. The unweighted average of all data (viz., 0.69 11) is adopted; the weighted average is 0.67 11. M(γ): D+Q from γ(θ) in (n,n’γ); not E1⁺M2 from RUL.
	580.43	E(γ): weighted average of 580.39 10 from (n,γ) E=thermal, 580.46 13 from IT decay (5.9 s) and 580.48 13 from (n,n’γ). I(γ): Iγ(379)/Iγ(580)=0.50 15, 0.73 18, 0.89 12, 1.10 18, 0.42 12 and 0.51 17, respectively, from IT decay, (n,γ), (n,n’γ), (d,d’γ), (p,p’γ) and Coulomb excitation. The unweighted average of all data (viz., 0.69 11) is adopted; the weighted average is 0.67 11. M(γ): from γ(θ) in (n,n’γ) and RUL.
	863.7	E(γ): From Coulomb excitation. I(γ): 15 +14-7 from Coulomb excitation.
1089.23	508.97	M(γ): from Coulomb excitation.
1127.51	437.13	M(γ): D+Q from γ(θ) in (n,n’γ); Δπ=(no) from level scheme.
1127.51	638.50	M(γ): D+Q from γ(θ) in (n,n’γ); Δπ=(no) from level scheme.
1143.519	233.92	E(γ): From ¹⁹²Os IT decay (5.9 s). I(γ): from IT decay (5.9 s). Other Iγ: 6 3 from (n,γ) E=thermal.
	453.10	E(γ): From ¹⁹²Os IT decay (5.9 s). I(γ): from IT decay (5.9 s).
	563.27	E(γ): Weighted average from ¹⁹²Os IT decay and (n,n’γ). I(γ): unweighted average of 16.4 11 from IT decay (5.9 s) and 21.6 25 from (n,n’γ).
1341.162	271.584	E(γ): weighted average of 271.584 13 from (n,n’γ) and 271.60 10 from (n,γ) E=thermal. M(γ): D+Q from γ(θ) in (n,n’γ); Δπ=yes from level scheme.
	852.19	E(γ): fits placement poorly. M(γ): d from γ(θ) in (n,n’γ); Δπ=yes from level scheme.
	1135.5	M(γ): d from γ(θ) in (n,n’γ); Δπ=yes from level scheme.
	1341.4	E(γ): γ expected based on direct excitation of parent level in (e,e’) and Coulomb excitation. Eγ=1341.4 3 in (n,n’γ) presumed to be this transition. M(γ): E3 excitation of 1351 level in (e,e’) and 1341 level in Coulomb excitation.
E(level)	E(gamma)	Comments
1362.016	218.488	E(γ): From ¹⁹¹Os(n,γ) E=thermal.
	292.478	E(γ): From ¹⁹¹Os(n,γ) E=thermal. M(γ): D+Q from γ(θ) in (n,n’γ) for intraband γ.
	452.2	E(γ): from IT decay (5.9 s). Other Eγ: 452.42 12 from (n,γ) E=thermal.
	671.54	E(γ): Weighted average from ¹⁹²Os IT decay and (n,n’γ).
1409.86	719.25	M(γ): from γ(θ) in (n,n’γ).
1409.86	829.63	M(γ): from γ(θ) in (n,n’γ).
1450.31	760.85	E(γ): fits placement poorly; γ omitted from least-squares fit.
1465.34	376.1	E(γ): From Coulomb excitation. I(γ): 7.1 +15-6 from Coulomb excitation.
	555.75	E(γ): unweighted average of 555.75 16 from ¹⁹²Os IT decay, 555.59 10 from (n,γ) and 555.90 10 from (n,n’γ). I(γ): 100 +6-12 from Coulomb excitation. M(γ): from γ(θ) in (n,n’γ) and RUL.
	884.8	E(γ): From Coulomb excitation. I(γ): 1 +10-1 from Coulomb excitation.
1560.6	417	E(γ): possibly the unplaced 416.85 13 transition seen in (n,n’γ).
1645.2	283.2	E(γ): From Coulomb excitation.
	575.5	E(γ): From ¹⁹²Os IT decay (5.9 s).
	735.6	E(γ): From Coulomb excitation.
1665.09	1459.33	M(γ): from γ(θ) in (n,n’γ).
1708.39	619.3	E(γ): From ¹⁹²Os IT decay (5.9 s). I(γ): From ¹⁹²Os IT decay (5.9 s). M(γ): from Coulomb excitation.
1712.91	247.5	E(γ): From ¹⁹²Os IT decay (5.9 s). I(γ): From ¹⁹²Os IT decay (5.9 s).
	569.36	E(γ): From ¹⁹²Os IT decay (5.9 s). I(γ): From ¹⁹²Os IT decay (5.9 s).
	624.0	E(γ): From ¹⁹²Os IT decay (5.9 s). I(γ): From ¹⁹²Os IT decay (5.9 s).
1780.34	1089.9	M(γ): from γ(θ) in (n,n’γ).
1807.71	1117.2	M(γ): from γ(θ) in (n,n’γ).
	1227.4	M(γ): from γ(θ) in (n,n’γ).
	1601.9	M(γ): from γ(θ) in (n,n’γ).
1826.51	1620.95	M(γ): from γ(θ) in (n,n’γ).
1826.51	1826.36	M(γ): from γ(θ) in (n,n’γ).
E(level)	E(gamma)	Comments
1837.40	1348.59	M(γ): from γ(θ) in (n,n’γ).
1867.87	1378.80	M(γ): from γ(θ) in (n,n’γ).
1868.70	741.04	M(γ): from γ(θ) in (n,n’γ).
1894.93	986.0	M(γ): from γ(θ) in (n,n’γ).
1902.68	1697.46	E(γ): fits placement poorly.
1902.68	1902.02	E(γ): fits placement poorly.
1921.68	1715.92	M(γ): from γ(θ) in (n,n’γ).
1947.77	1257.3	M(γ): from γ(θ) in (n,n’γ).
1968.01	322.7	E(γ): From ¹⁹²Os IT decay (5.9 s). I(γ): From ¹⁹²Os IT decay (5.9 s).
	502.5	E(γ): From ¹⁹²Os IT decay (5.9 s). I(γ): From ¹⁹²Os IT decay (5.9 s).
	606.0	E(γ): From ¹⁹²Os IT decay (5.9 s). I(γ): From ¹⁹²Os IT decay (5.9 s).
1996.93	1996.91	M(γ): from γ(θ) in (n,n’γ).
2015.40	47.4	E(γ): From ¹⁹²Os IT decay (5.9 s). I(γ): From ¹⁹²Os IT decay (5.9 s). M(γ): not M4 from RUL.
	302.48	E(γ): From ¹⁹²Os IT decay (5.9 s). I(γ): From ¹⁹²Os IT decay (5.9 s). M(γ): From ¹⁹²Os IT decay (5.9 s).
	307.02	E(γ): From ¹⁹²Os IT decay (5.9 s). I(γ): From ¹⁹²Os IT decay (5.9 s). M(γ): From ¹⁹²Os IT decay (5.9 s).
2051.83	1361.51	M(γ): from γ(θ) in (n,n’γ).
2099.00	1893.20	M(γ): from γ(θ) in (n,n’γ).
2133.9	668.6	E(γ): From Coulomb excitation. M(γ): from Coulomb excitation.
2337.32	2131.51	M(γ): from γ(θ) in (n,n’γ).
2391.2	2391.2	E(γ): From (γ,γ’). Eγ is from level energy difference.. From (γ,γ’). I(γ): From (γ,γ’). Eγ is from level energy difference.
2418.8	710.4	E(γ): From Coulomb excitation. M(γ): from Coulomb excitation.
2478.3	2272.5	E(γ): From (γ,γ’). Eγ is from level energy difference.. From (γ,γ’). I(γ): From (γ,γ’). Eγ is from level energy difference.
2478.3	2478.3	E(γ): From (γ,γ’). Eγ is from level energy difference.. From (γ,γ’). I(γ): From (γ,γ’). Eγ is from level energy difference.
2694.2	2488.4	E(γ): From (γ,γ’). Eγ is from level energy difference.. From (γ,γ’). I(γ): From (γ,γ’). Eγ is from level energy difference.
2694.2	2694.2	E(γ): From (γ,γ’). Eγ is from level energy difference.. From (γ,γ’). I(γ): From (γ,γ’). Eγ is from level energy difference.
E(level)	E(gamma)	Comments
2748.3	2542.5	E(γ): From (γ,γ’). Eγ is from level energy difference.. From (γ,γ’). I(γ): From (γ,γ’). Eγ is from level energy difference.
2748.3	2748.3	E(γ): From (γ,γ’). Eγ is from level energy difference.. From (γ,γ’). I(γ): From (γ,γ’). Eγ is from level energy difference.
2804.9	2804.9	E(γ): From (γ,γ’). Eγ is from level energy difference.. From (γ,γ’). I(γ): From (γ,γ’). Eγ is from level energy difference.
2814.3	2608.5	E(γ): From (γ,γ’). Eγ is from level energy difference.. From (γ,γ’). I(γ): From (γ,γ’). Eγ is from level energy difference.
2814.3	2814.3	E(γ): From (γ,γ’). Eγ is from level energy difference.. From (γ,γ’). I(γ): From (γ,γ’). Eγ is from level energy difference.
2820.0	2820.0	E(γ): From (γ,γ’). Eγ is from level energy difference.. From (γ,γ’). I(γ): From (γ,γ’). Eγ is from level energy difference.
2864.5	2864.5	E(γ): From (γ,γ’). Eγ is from level energy difference.. From (γ,γ’). I(γ): From (γ,γ’). Eγ is from level energy difference.
2894.2	760.3	E(γ): From Coulomb excitation. M(γ): from Coulomb excitation.
2903.5	2414.4	E(γ): From (γ,γ’). Eγ is from level energy difference.. From (γ,γ’). I(γ): From (γ,γ’). Eγ is from level energy difference.
2903.5	2903.5	E(γ): From (γ,γ’). Eγ is from level energy difference.. From (γ,γ’). I(γ): From (γ,γ’). Eγ is from level energy difference.
2915.2	2709.4	E(γ): From (γ,γ’). Eγ is from level energy difference.. From (γ,γ’). I(γ): From (γ,γ’). Eγ is from level energy difference.
2915.2	2915.2	E(γ): From (γ,γ’). Eγ is from level energy difference.. From (γ,γ’). I(γ): From (γ,γ’). Eγ is from level energy difference.
2941.3	2941.3	E(γ): From (γ,γ’). Eγ is from level energy difference.. From (γ,γ’). I(γ): From (γ,γ’). Eγ is from level energy difference.
2948.0	2458.9	E(γ): From (γ,γ’). Eγ is from level energy difference.. From (γ,γ’). I(γ): From (γ,γ’). Eγ is from level energy difference.
	2742.2	E(γ): From (γ,γ’). Eγ is from level energy difference.. From (γ,γ’). I(γ): From (γ,γ’). Eγ is from level energy difference.
	2948.0	E(γ): From (γ,γ’). Eγ is from level energy difference.. From (γ,γ’). I(γ): From (γ,γ’). Eγ is from level energy difference.
2965.6	2965.6	E(γ): From (γ,γ’). Eγ is from level energy difference.. From (γ,γ’). I(γ): From (γ,γ’). Eγ is from level energy difference.
2986.8	568	E(γ): from ¹⁹⁸Pt(¹³⁶Xe,Xγ).
3046.4	2557.3	E(γ): From (γ,γ’). Eγ is from level energy difference.. From (γ,γ’). I(γ): From (γ,γ’). Eγ is from level energy difference.
	2840.6	E(γ): From (γ,γ’). Eγ is from level energy difference.. From (γ,γ’). I(γ): From (γ,γ’). Eγ is from level energy difference.
	3046.4	E(γ): From (γ,γ’). Eγ is from level energy difference.. From (γ,γ’). I(γ): From (γ,γ’). Eγ is from level energy difference.
3103.8	685	E(γ): From Coulomb excitation. M(γ): from Coulomb excitation.
3148.9	3148.9	E(γ): From (γ,γ’). Eγ is from level energy difference.. From (γ,γ’). I(γ): From (γ,γ’). Eγ is from level energy difference.
3196.3	3196.3	E(γ): From (γ,γ’). Eγ is from level energy difference.. From (γ,γ’). I(γ): From (γ,γ’). Eγ is from level energy difference.
3207.0	3207.0	E(γ): From (γ,γ’). Eγ is from level energy difference.. From (γ,γ’). I(γ): From (γ,γ’). Eγ is from level energy difference.
E(level)	E(gamma)	Comments
3210.8	792	E(γ): From Coulomb excitation.
3217.1	3217.1	E(γ): From (γ,γ’). Eγ is from level energy difference.. From (γ,γ’). I(γ): From (γ,γ’). Eγ is from level energy difference.
3239.9	3034.1	E(γ): From (γ,γ’). Eγ is from level energy difference.. From (γ,γ’). I(γ): From (γ,γ’). Eγ is from level energy difference.
3239.9	3239.9	E(γ): From (γ,γ’). Eγ is from level energy difference.. From (γ,γ’). I(γ): From (γ,γ’). Eγ is from level energy difference.
3257.6	3257.6	E(γ): From (γ,γ’). Eγ is from level energy difference.. From (γ,γ’). I(γ): From (γ,γ’). Eγ is from level energy difference.
3273.3	3273.3	E(γ): From (γ,γ’). Eγ is from level energy difference.. From (γ,γ’). I(γ): From (γ,γ’). Eγ is from level energy difference.
3281.0	3281.0	E(γ): From (γ,γ’). Eγ is from level energy difference.. From (γ,γ’). I(γ): From (γ,γ’). Eγ is from level energy difference.
3289.5	3083.7	E(γ): From (γ,γ’). Eγ is from level energy difference.. From (γ,γ’). I(γ): From (γ,γ’). Eγ is from level energy difference.
3289.5	3289.5	E(γ): From (γ,γ’). Eγ is from level energy difference.. From (γ,γ’). I(γ): From (γ,γ’). Eγ is from level energy difference.
3428.9	3223.1	E(γ): From (γ,γ’). Eγ is from level energy difference.. From (γ,γ’). I(γ): From (γ,γ’). Eγ is from level energy difference.
3428.9	3428.9	E(γ): From (γ,γ’). Eγ is from level energy difference.. From (γ,γ’). I(γ): From (γ,γ’). Eγ is from level energy difference.
3536.4	3330.6	E(γ): From (γ,γ’). Eγ is from level energy difference.. From (γ,γ’). I(γ): From (γ,γ’). Eγ is from level energy difference.
3536.4	3536.4	E(γ): From (γ,γ’). Eγ is from level energy difference.. From (γ,γ’). I(γ): From (γ,γ’). Eγ is from level energy difference.
3667.8	681	E(γ): from ¹⁹⁸Pt(¹³⁶Xe,Xγ).
3756.8	3756.8	E(γ): From (γ,γ’). Eγ is from level energy difference.. From (γ,γ’). I(γ): From (γ,γ’). Eγ is from level energy difference.
3836.5	3836.5	E(γ): From (γ,γ’). Eγ is from level energy difference.. From (γ,γ’). I(γ): From (γ,γ’). Eγ is from level energy difference.
3864.7	3864.7	E(γ): From (γ,γ’). Eγ is from level energy difference.. From (γ,γ’). I(γ): From (γ,γ’). Eγ is from level energy difference.
3890.5	3890.5	E(γ): From (γ,γ’). Eγ is from level energy difference.. From (γ,γ’). I(γ): From (γ,γ’). Eγ is from level energy difference.
4113.8	446	E(γ): from ¹⁹⁸Pt(¹³⁶Xe,Xγ).