List of levels for 97RH

Author: N. Nica | Citation: Nucl. Data Sheets 111, 525 (2010) | Cutoff date: 19-Nov-2009

E(level) (keV)	J^π(level)	T_1/2(level)	E(γ) (keV)	Multipolarity	Mixing Ratio	Conversion Coefficient	Additional Data
258.76	1/2-	46.2 m 16 % IT = 5.6 6 % ε = 94.4 6	258.76 18	M4		2.57	B(M4)(W.u.)=24 3, α=2.57, α(K)=2.03 3, α(L)=0.440 7, α(M)=0.0862 13, α(N)=0.01388 20, α(O)=0.000508 8, α(N+)=0.01439 21
265.36	(7/2+)		265.26 9	(M1+E2)		0.034	α=0.034 9, α(K)=0.029 8, α(L)=0.0039 13, α(M)=0.00072 25, α(N)=0.00012 4, α(O)=5.0×10^-6 11, α(N+)=0.00012 4
475.11	(5/2+,7/2)		475.2 1	[E2]		0.00657	α=0.00657, α(K)=0.00570 8, α(L)=0.000718 10, α(M)=0.0001336 19, α(N)=2.19×10^-5 3, α(O)=9.95E-7 14, α(N+)=2.29E-5 4
850.1	(5/2-)		591.1 5	(E2)		0.00352	α=0.00352, α(K)=0.00306 5, α(L)=0.000375 6, α(M)=6.96×10^-5 10, α(N)=1.145E-5 17, α(O)=5.41E-7 8, α(N+)=1.199E-5 17
857.71	(13/2+)		857.69 13	E2		1.35×10^-3	α=1.35×10^-3, α(K)=0.001180 17, α(L)=0.0001393 20, α(M)=2.58E-5 4, α(N)=4.27E-6 6, α(O)=2.11E-7 3, α(N+)=4.48E-6 7
1242.6	(11/2+)		977.5 5	[E2]		9.94×10^-4	α=9.94×10^-4, α(K)=0.000870 13, α(L)=0.0001018 15, α(M)=1.89E-5 3, α(N)=3.12E-6 5, α(O)=1.560E-7 22, α(N+)=3.28E-6 5
1242.6	(11/2+)		1242.7 5	(M1+E2)	0.3 AP	6.56×10^-4	α6.56×10^-4 AP, α(K)≈0.000566, α(L)≈6.45E-5, α(M)≈1.194E-5, α(N)≈1.99E-6, α(O)≈1.032E-7, α(N+)≈1.390E-5
1375.6	(9/2-)		525.3 5	(E2)		0.00490	α=0.00490, α(K)=0.00426 6, α(L)=0.000529 8, α(M)=9.84×10^-5 14, α(N)=1.614E-5 23, α(O)=7.48E-7 11, α(N+)=1.689E-5 25
	(9/2-)		1109.9 5	[E1]		3.38×10^-4	α=3.38×10^-4, α(K)=0.000292 4, α(L)=3.29E-5 5, α(M)=6.08E-6 9, α(N)=1.009E-6 15, α(O)=5.19E-8 8, α(N+)=7.12E-6 13
	(9/2-)		1376.4 5	[E1]		3.74×10^-4	α=3.74×10^-4, α(K)=0.000199 3, α(L)=2.23E-5 4, α(M)=4.13E-6 6, α(N)=6.86E-7 10, α(O)=3.55E-8 5, α(N+)=0.0001485 21
1463.64	(15/2+)		605.81 17	(M1+E2)	+0.27 5	0.00324	α=0.00324, α(K)=0.00284 4, α(L)=0.000330 5, α(M)=6.11×10^-5 9, α(N)=1.016E-5 15, α(O)=5.20E-7 8, α(N+)=1.068E-5 15
1553.15	(17/2+)		89.27 24	(M1(+E2))		1.2	α=1.2 8, α(K)=1.0 6, α(L)=0.22 17, α(M)=0.04 4, α(N)=0.006 5, α(O)=0.00015 8, α(N+)=0.007 5
1553.15	(17/2+)		695.53 15	(E2)		0.00227	α=0.00227, α(K)=0.00198 3, α(L)=0.000239 4, α(M)=4.43×10^-5 7, α(N)=7.31E-6 11, α(O)=3.53E-7 5, α(N+)=7.66E-6 11
1928.3	(13/2-)		552.8 5	(E2)		0.00424	α=0.00424, α(K)=0.00368 6, α(L)=0.000455 7, α(M)=8.46×10^-5 12, α(N)=1.389E-5 20, α(O)=6.49E-7 10, α(N+)=1.454E-5 21
1928.3	(13/2-)		1070.4 5	[E1]		3.55×10^-4	α=3.55×10^-4, α(K)=0.000312 5, α(L)=3.52E-5 5, α(M)=6.50E-6 10, α(N)=1.080E-6 16, α(O)=5.55E-8 8, α(N+)=1.136E-6 16
1961.98	(19/2+)		408.79 20	(M1+E2)	-0.04 4	0.00831	α=0.00831, α(K)=0.00727 11, α(L)=0.000853 12, α(M)=0.0001583 23, α(N)=2.63×10^-5 4, α(O)=1.344E-6 19, α(N+)=2.76E-5 4
2225.40	(17/2-)		672.23 18	[E1]		9.08×10^-4	α=9.08×10^-4, α(K)=0.000798 12, α(L)=9.09E-5 13, α(M)=1.680E-5 24, α(N)=2.79E-6 4, α(O)=1.412E-7 20, α(N+)=2.93E-6 5
2617.27	(21/2+)		1064.16 22	(E2)		8.21×10^-4	α=8.21×10^-4, α(K)=0.000719 10, α(L)=8.37E-5 12, α(M)=1.550E-5 22, α(N)=2.57E-6 4, α(O)=1.291E-7 18, α(N+)=2.70E-6 4
2895.8	(23/2+)		933.8 3	E2		1.10×10^-3	α=1.10×10^-3, α(K)=0.000966 14, α(L)=0.0001134 16, α(M)=2.10E-5 3, α(N)=3.48E-6 5, α(O)=1.731E-7 25, α(N+)=3.65E-6 6
3055.7	(21/2-)		830.33 18	(E2)		1.46×10^-3	α=1.46×10^-3, α(K)=0.001275 18, α(L)=0.0001510 22, α(M)=2.80E-5 4, α(N)=4.63E-6 7, α(O)=2.28E-7 4, α(N+)=4.86E-6 7
3259.7	(23/2+)		1297.79 23	(E2)		5.62×10^-4	α=5.62×10^-4, α(K)=0.000471 7, α(L)=5.42E-5 8, α(M)=1.003E-5 14, α(N)=1.665E-6 24, α(O)=8.47E-8 12, α(N+)=2.63E-5 4
3551.3	(25/2+)		291.61 21	(M1+E2)	+0.05 8	0.0194	α=0.0194 4, α(K)=0.0169 3, α(L)=0.00201 4, α(M)=0.000373 7, α(N)=6.19×10^-5 12, α(O)=3.14E-6 5, α(N+)=6.51E-5 12
	(25/2+)		655.5 3	(M1)		0.00269	α=0.00269, α(K)=0.00236 4, α(L)=0.000273 4, α(M)=5.05×10^-5 7, α(N)=8.41E-6 12, α(O)=4.33E-7 6, α(N+)=8.84E-6 13
	(25/2+)		934.1 4	(E2)		1.10×10^-3	α=1.10×10^-3, α(K)=0.000965 14, α(L)=0.0001133 16, α(M)=2.10E-5 3, α(N)=3.48E-6 5, α(O)=1.730E-7 25, α(N+)=3.65E-6 6
4015.5	(27/2+)		464.18 20	(M1+E2)	+0.09 GT	0.0066	α=0.0066 5, α(K)=0.0057 4, α(L)=0.00070 8, α(M)=0.000130 14, α(N)=2.14×10^-5 22, α(O)=1.03E-6 5, α(N+)=2.24E-5 22
4015.5	(27/2+)		755.71 15	(E2)		0.00184	α=0.00184, α(K)=0.001607 23, α(L)=0.000192 3, α(M)=3.56×10^-5 5, α(N)=5.88E-6 9, α(O)=2.86E-7 4, α(N+)=6.16E-6 9
E(level) (keV)	J^π(level)	T_1/2(level)	E(γ) (keV)	Multipolarity	Mixing Ratio	Conversion Coefficient	Additional Data
4074.4	(25/2-)		1018.78 20	(E2)		9.05×10^-4	α=9.05×10^-4, α(K)=0.000793 12, α(L)=9.24E-5 13, α(M)=1.713E-5 24, α(N)=2.84E-6 4, α(O)=1.422E-7 20, α(N+)=2.98E-6 5
4275.1	(29/2+)		723.91 15	(E2)		0.00205	α=0.00205, α(K)=0.00179 3, α(L)=0.000215 3, α(M)=3.99×10^-5 6, α(N)=6.57E-6 10, α(O)=3.19E-7 5, α(N+)=6.89E-6 10
4824.4	(31/2+)		808.89 20	(E2)		1.55×10^-3	α=1.55×10^-3, α(K)=0.001358 19, α(L)=0.0001612 23, α(M)=2.99E-5 5, α(N)=4.94E-6 7, α(O)=2.43E-7 4, α(N+)=5.18E-6 8
5159.4	(29/2-)		1084.92 22	(E2)		7.87×10^-4	α=7.87×10^-4, α(K)=0.000690 10, α(L)=8.01E-5 12, α(M)=1.484E-5 21, α(N)=2.46E-6 4, α(O)=1.238E-7 18, α(N+)=2.58E-6 4
5516.2	(33/2+)		1241.04 25	(E2)		6.03×10^-4	α=6.03×10^-4, α(K)=0.000517 8, α(L)=5.96E-5 9, α(M)=1.103E-5 16, α(N)=1.83E-6 3, α(O)=9.29E-8 13, α(N+)=1.561E-5 23
6191.6	(35/2+)		1367.2 4	(E2)		5.24×10^-4	α=5.24×10^-4, α(K)=0.000424 6, α(L)=4.86E-5 7, α(M)=8.99E-6 13, α(N)=1.493E-6 21, α(O)=7.62E-8 11, α(N+)=4.26E-5 6

Q(β-)=-4.79×10³ keV 4	S(n)= 1.098×10⁴ keV 4	S(p)= 3.81×10³ keV 4	Q(α)= -1.42×10³ keV 4
Reference: 2012WA38

References:
A	⁹⁷Rh IT decay	B	⁹⁷Pd ε decay
C	⁹⁸Ag εp decay (47.5 S)	D	⁶⁰Ni(⁴⁰Ca,3PG)
E	⁶⁵Cu(³⁶S,4nγ)	F	⁹⁴Mo(⁶Li,3nγ)
G	⁹⁶Ru(p,γ)	H	⁹⁶Ru(p,p) IAR
I	⁹⁶Ru(³He,pnγ), (d,nγ)	J	⁹⁶Ru(α,p2nγ)

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 I J	9/2+	30.7 m 6 % ε = 100
258.76 18	A B D G I	1/2-	46.2 m 16 % IT = 5.6 6 % ε = 94.4 6	258.76 18	100	M4	0.0	9/2+
265.36 8	B D G I	(7/2+)		265.26 9	100	(M1+E2)	0.0	9/2+
475.11 9	B D I	(5/2+,7/2)		209.5 3 475.2 1	3.8 13 100 3	[E2]	265.36 0.0	(7/2+) 9/2+
845.3 3	G	(1/2+)		586.5 2	100		258.76	1/2-
850.1 4	G I	(5/2-)		591.1 5	100	(E2)	258.76	1/2-
857.71 13	D E F I J	(13/2+)		857.69 13	100	E2	0.0	9/2+
863.55 24	I	(9/2)		597.7 5 863.1 5	<4 100 5	D(+Q)	265.36 0.0	(7/2+) 9/2+
1004.5 4	B	(3/2-)		745.7 5	100		258.76	1/2-
1058.04 11	B D G I	(5/2+)		583.0 3 792.70 9 1058.5 4	14.6 7 100 4 18.6 8	D(+Q)	475.11 265.36 0.0	(5/2+,7/2) (7/2+) 9/2+
1199.1 3	B I	(5/2+,7/2)		933.7 4 1199.2 4	100 5 53 12		265.36 0.0	(7/2+) 9/2+
1242.6 3	I	(11/2+)		977.5 5 1242.7 5	17 2 100 5	[E2] (M1+E2)	265.36 0.0	(7/2+) 9/2+
1375.6 3	I	(9/2-)		525.3 5 1109.9 5 1376.4 5	100 5 12.7 6 10.8 5	(E2) [E1] [E1]	850.1 265.36 0.0	(5/2-) (7/2+) 9/2+
1415.51 25	B I	(3/2+,5/2,7/2)		940.3 3 1150.3 4	100 6 29.4 14		475.11 265.36	(5/2+,7/2) (7/2+)
1463.64 18	D E F I J	(15/2+)		599.7 5 605.81 17	<9 100	(M1+E2)	863.55 857.71	(9/2) (13/2+)
1470.6 7	I	(3/2,7/2)		620.5 5	100	D(+Q)	850.1	(5/2-)
1528.7 4	B I	(3/2,5/2,7/2)		1053.6 4	100		475.11	(5/2+,7/2)
E(level) (keV)	XREF	J^π(level)	T_1/2(level)	E(γ) (keV)	I(γ)	M(γ)	Final Levels
1541.8 3	I			678.5 5 1276.5 5 1541.4 5	100 5 <65 15 7		863.55 265.36 0.0	(9/2) (7/2+) 9/2+
1553.15 18	D E F I J	(17/2+)		89.27 24 695.53 15	8.3 7 100 1	(M1(+E2)) (E2)	1463.64 857.71	(15/2+) (13/2+)
1619.0 3	B I	(3/2+,5/2,7/2)		614.4 5 1354.1 4	36 2 100 10		1004.5 265.36	(3/2-) (7/2+)
1635.0 5	I			1159.9 5	100		475.11	(5/2+,7/2)
1759.55 9	B I	(5/2+,7/2+)		230.1 5 ? 895.2 5 1494.2 2 1759.60 10	12 4 48 5 90 5 100 7		1528.7 863.55 265.36 0.0	(3/2,5/2,7/2) (9/2) (7/2+) 9/2+
1775.1 4	I	(11/2+,13/2,15/2+)		311.4 5 532.6 5 912.6 5 ?	<63 100 10 <240		1463.64 1242.6 863.55	(15/2+) (11/2+) (9/2)
1906.5 3	B I	(3/2,5/2,7/2)		1641.1 3	100		265.36	(7/2+)
1928.3 4	I	(13/2-)		552.8 5 685.7 5 1070.4 5	100 5 50 3 41 4	(E2) [E1]	1375.6 1242.6 857.71	(9/2-) (11/2+) (13/2+)
1961.98 24	D E F I J	(19/2+)		408.79 20	100	(M1+E2)	1553.15	(17/2+)
1984.1 5	I	(11/2+,13/2,15/2+)		519 741.9 5			1463.64 1242.6	(15/2+) (11/2+)
1994.2 3	B I	(5/2+,7/2+)		1519.8 5 1729.1 5 1993.6 4	100 5 19 2 53 5		475.11 265.36 0.0	(5/2+,7/2) (7/2+) 9/2+
2062.1 5	I			1796.7 5 ?	100		265.36	(7/2+)
2068.0 4	B I	(3/2,5/2,7/2)		1592.9 4	100		475.11	(5/2+,7/2)
2097.5 6	I			721.9 5	100		1375.6	(9/2-)
2103.6 11	I			640	100		1463.64	(15/2+)
2113.25 18	B I	(5/2+,7/2+)		354.4 4 571 1055.4 4 1638.7 4 1846.8 3 2111.4 10	21.2 15 100 7 66 4 50 4 7.1 6		1759.55 1541.8 1058.04 475.11 265.36 0.0	(5/2+,7/2+) (5/2+) (5/2+,7/2) (7/2+) 9/2+
E(level) (keV)	XREF	J^π(level)	T_1/2(level)	E(γ) (keV)	I(γ)	M(γ)	Final Levels
2126.6 7	I			1276.5 5	100		850.1	(5/2-)
2147.3 6	I			904.7 5	100		1242.6	(11/2+)
2187.2 6	B I	(3/2,5/2,7/2)		658.5 4	100		1528.7	(3/2,5/2,7/2)
2225.40 20	D E F I J	(17/2-)		672.23 18 761.76 15	20 3 100 4	[E1] D(+Q)	1553.15 1463.64	(17/2+) (15/2+)
2229.6 3	B	(5/2+,7/2+)		1171.8 3 2231.3 10	100 12 15.3 8		1058.04 0.0	(5/2+) 9/2+
2271.1 7	I			1421.0 5	100		850.1	(5/2-)
2272.5 3 ?	D			310.53 20	100		1961.98	(19/2+)
2295.4 3	B I	(3/2+,5/2+,7/2+)		1237.8 4 2029.5 4	81 10 100 5		1058.04 265.36	(5/2+) (7/2+)
2297.7 6	I			922.1 5	100		1375.6	(9/2-)
2353.7 6	I			425.4 5	100		1928.3	(13/2-)
2372.8 6	I			1515.1 5 ?	100		857.71	(13/2+)
2617.27 24	D E F	(21/2+)		655.23 14 1064.16 22	100 3 43 4	D(+Q) (E2)	1961.98 1553.15	(19/2+) (17/2+)
2895.8 4	J	(23/2+)		933.8 3	100	E2	1961.98	(19/2+)
2903.58 25	B I	(5/2+,7/2+)		1285.0 4 2428.4 4 2637.1 10 2903.3 4	100 5 89 4 37 7 47 9		1619.0 475.11 265.36 0.0	(3/2+,5/2,7/2) (5/2+,7/2) (7/2+) 9/2+
2950.1 7	B	(5/2+,7/2+)		2684.4 10 2950.3 10	100 8 29.5 14		265.36 0.0	(7/2+) 9/2+
3055.7 3	D E F J	(21/2-)		830.33 18	100	(E2)	2225.40	(17/2-)
3091.2 4	B	(3/2+,5/2+,7/2+)		862.7 5 976.7 5 2826.3 10	100 17 53 11 68 9		2229.6 2113.25 265.36	(5/2+,7/2+) (5/2+,7/2+) (7/2+)
3095.9 4	D E	(21/2)		823.3 4 1134.0 3	64 7 100 14	D(+Q)	2272.5 1961.98	(19/2+)
3240.0 5	B	(5/2+,7/2+)		1480.5 5 2974.6 10 3239.8 10	100 4 90 14 36 5		1759.55 265.36 0.0	(5/2+,7/2+) (7/2+) 9/2+
E(level) (keV)	XREF	J^π(level)	T_1/2(level)	E(γ) (keV)	I(γ)	M(γ)	Final Levels
3259.7 3	D E F J	(23/2+)		163.8 4 642.29 25 1297.79 23	4 3 15 6 100 3	D(+Q) (E2)	3095.9 2617.27 1961.98	(21/2) (21/2+) (19/2+)
3345.4 4 ?	D E	(23/2)		289.58 25	100	D(+Q)	3055.7	(21/2-)
3551.3 3	D E F J	(25/2+)		291.61 21 655.5 3 934.1 4	57 9 78 14 100 3	(M1+E2) (M1) (E2)	3259.7 2895.8 2617.27	(23/2+) (23/2+) (21/2+)
3607.1 5	B	(3/2+,5/2+,7/2+)		1377.4 5 2408.0 10 3342.1 10	57 8 100 11 100 18		2229.6 1199.1 265.36	(5/2+,7/2+) (5/2+,7/2) (7/2+)
4015.5 3	D E	(27/2+)		464.18 20 755.71 15	99 2 100 10	(M1+E2) (E2)	3551.3 3259.7	(25/2+) (23/2+)
4074.4 4	D E	(25/2-)		728.93 20 1018.78 20	100 8 43 6	D(+Q) (E2)	3345.4 3055.7	(23/2) (21/2-)
4275.1 3	D E	(29/2+)		259.62 15 723.91 15	100 8 93 9	D(+Q) (E2)	4015.5 3551.3	(27/2+) (25/2+)
4824.4 4	D	(31/2+)		808.89 20	100	(E2)	4015.5	(27/2+)
5159.4 4	D E	(29/2-)		1084.92 22	100	(E2)	4074.4	(25/2-)
5516.2 4	D E	(33/2+)		1241.04 25	100	(E2)	4275.1	(29/2+)
5965.1 11	E			1690 1	100		4275.1	(29/2+)
5973.8 5	D E	(31/2-)		814.41 20	100	D(+Q)	5159.4	(29/2-)
6191.6 6	D E	(35/2+)		674.4 4 ? 1367.2 4	<4 100 12	(E2)	5516.2 4824.4	(33/2+) (31/2+)
6441.2 5	D E	(33/2-)		467.47 20	100	D(+Q)	5973.8	(31/2-)
6472.5 6	E	(33/2)		498.7 4	100	D(+Q)	5973.8	(31/2-)
6502.5 7	E			310.9 4	100		6191.6	(35/2+)
6774.1 7	D E	(37/2+)		1257.9 5	100		5516.2	(33/2+)
6912.1 6	E	(35/2)		1395.9 4	100	D(+Q)	5516.2	(33/2+)
6973.2 6	E			1457.0 4			5516.2	(33/2+)
7079.2 11	E			1563 1	100		5516.2	(33/2+)
E(level) (keV)	XREF	J^π(level)	T_1/2(level)	E(γ) (keV)	I(γ)	M(γ)	Final Levels
7327.6 8	E			825.1 4	100		6502.5
7584.2 11	E			2068 1	100		5516.2	(33/2+)
7687.2 11	E			2171 1	100		5516.2	(33/2+)
7699.2 7	E	(35/2-)		1257.9 4	100		6441.2	(33/2-)
7954.1 8	E			1180.0 4	100		6774.1	(37/2+)
8003.6 12	E			1812 1	100		6191.6	(35/2+)
8282.1 12	E			1508 1	100		6774.1	(37/2+)
8364.1 12	E	(39/2)		1590 1	100	D(+Q)	6774.1	(37/2+)
8492.2 8	E			793.0 4	100		7699.2	(35/2-)
8510 40	H	(5/2+)
8594.1 12	E			1820 1	100		6774.1	(37/2+)
9078.6 15 ?	E			1075.0 4 ?	100		8003.6
9204.2 12	E			1505 1	100		7699.2	(35/2-)
9242.2 12	E			1543 1	100		7699.2	(35/2-)
9400 40	H	(1/2+)

E(level)	E(gamma)	Comments
850.1	591.1	E(γ): from (³He,pnγ),(d,nγ) (also observed in (p,γ)) M(γ): from γ(θ) ((³He,pnγ),(d,nγ))
857.71	857.69	M(γ): from γ(θ) (⁴⁰Ca,3pγ), (⁶Li,3nγ), (α,p2nγ)
863.55	597.7	E(γ): Seen only in ((³He,pnγ),(d,nγ)) experiment I(γ): Seen only in ((³He,pnγ),(d,nγ)) experiment
863.55	863.1	E(γ): Seen only in ((³He,pnγ),(d,nγ)) experiment I(γ): Seen only in ((³He,pnγ),(d,nγ)) experiment M(γ): ΔJ=0 transition suggested by γ(θ) ((³He,pnγ),(d,nγ))
1004.5	745.7	E(γ): Seen only in ⁹⁷Pd ε decay
1058.04	792.70	M(γ): from γ(θ) ((³He,pnγ),(d,nγ))
1242.6	977.5	E(γ): Seen only in ((³He,pnγ),(d,nγ)) experiment I(γ): Seen only in ((³He,pnγ),(d,nγ)) experiment
1242.6	1242.7	E(γ): Seen only in ((³He,pnγ),(d,nγ)) experiment I(γ): Seen only in ((³He,pnγ),(d,nγ)) experiment
1375.6	525.3	E(γ): Seen only in ((³He,pnγ),(d,nγ)) experiment I(γ): Seen only in ((³He,pnγ),(d,nγ)) experiment M(γ): from γ(θ) ((³He,pnγ),(d,nγ))
	1109.9	E(γ): Seen only in ((³He,pnγ),(d,nγ)) experiment I(γ): Seen only in ((³He,pnγ),(d,nγ)) experiment
	1376.4	E(γ): Seen only in ((³He,pnγ),(d,nγ)) experiment I(γ): Seen only in ((³He,pnγ),(d,nγ)) experiment
1463.64	599.7	E(γ): Seen only in ((³He,pnγ),(d,nγ)) experiment I(γ): Seen only in ((³He,pnγ),(d,nγ)) experiment
1463.64	605.81	M(γ): from γ(θ) (⁴⁰Ca,3pγ), (⁶Li,3nγ)
1470.6	620.5	E(γ): Seen only in ((³He,pnγ),(d,nγ)) experiment M(γ): from γ(θ) ((³He,pnγ),(d,nγ))
1541.8	678.5	E(γ): Seen only in ((³He,pnγ),(d,nγ)) experiment I(γ): Seen only in ((³He,pnγ),(d,nγ)) experiment
	1276.5	E(γ): Multiply placed. Seen only in ((³He,pnγ),(d,nγ)) experiment I(γ): Seen only in ((³He,pnγ),(d,nγ)) experiment
	1541.4	E(γ): Seen only in ((³He,pnγ),(d,nγ)) experiment I(γ): Seen only in ((³He,pnγ),(d,nγ)) experiment
1553.15	89.27	I(γ): from (α,p2nγ); (⁴⁰Ca,3pγ) gives I(γ+ce)=15 3 (Iγ=10.2 20); (³⁶S,4nγ) gives Iγ=14.3 14 M(γ): d γ from γ(θ) (α,p2nγ) or d(+Q) γ from DCO (³⁶S,4nγ); Δπ=no from level scheme
1553.15	695.53	M(γ): from γ(θ) (⁴⁰Ca,3pγ), (⁶Li,3nγ), (α,p,2nγ)
1619.0	614.4	E(γ): Seen only in ⁹⁷Pd ε decay I(γ): Seen only in ⁹⁷Pd ε decay
1635.0	1159.9	E(γ): Seen only in ((³He,pnγ),(d,nγ)) experiment
1759.55	230.1	E(γ): Seen only in ((³He,pnγ),(d,nγ)) experiment I(γ): Seen only in ((³He,pnγ),(d,nγ)) experiment
1759.55	895.2	E(γ): Seen only in ((³He,pnγ),(d,nγ)) experiment I(γ): Seen only in ((³He,pnγ),(d,nγ)) experiment
1775.1	311.4	E(γ): Seen only in ((³He,pnγ),(d,nγ)) experiment I(γ): Seen only in ((³He,pnγ),(d,nγ)) experiment
	532.6	E(γ): Seen only in ((³He,pnγ),(d,nγ)) experiment I(γ): Seen only in ((³He,pnγ),(d,nγ)) experiment
	912.6	E(γ): Seen only in ((³He,pnγ),(d,nγ)) experiment I(γ): Seen only in ((³He,pnγ),(d,nγ)) experiment
E(level)	E(gamma)	Comments
1928.3	552.8	E(γ): Seen only in ((³He,pnγ),(d,nγ)) experiment I(γ): Seen only in ((³He,pnγ),(d,nγ)) experiment M(γ): from γ(θ) ((³He,pnγ),(d,nγ))
	685.7	E(γ): Seen only in ((³He,pnγ),(d,nγ)) experiment I(γ): Seen only in ((³He,pnγ),(d,nγ)) experiment
	1070.4	E(γ): Seen only in ((³He,pnγ),(d,nγ)) experiment I(γ): Seen only in ((³He,pnγ),(d,nγ)) experiment
1984.1	519	E(γ): Seen only in ((³He,pnγ),(d,nγ)) experiment
1984.1	741.9	E(γ): Seen only in ((³He,pnγ),(d,nγ)) experiment
1994.2	1729.1	E(γ): Seen only in ⁹⁷Pd ε decay I(γ): Seen only in ⁹⁷Pd ε decay
2062.1	1796.7	E(γ): Seen only in ((³He,pnγ),(d,nγ)) experiment
2097.5	721.9	E(γ): Seen only in ((³He,pnγ),(d,nγ)) experiment
2103.6	640	E(γ): Seen only in ((³He,pnγ),(d,nγ)) experiment
2113.25	571	E(γ): Seen only in ((³He,pnγ),(d,nγ)) experiment
2113.25	2111.4	E(γ): Seen only in ⁹⁷Pd ε decay I(γ): Seen only in ⁹⁷Pd ε decay
2126.6	1276.5	E(γ): Multiply placed. Seen only in ((³He,pnγ),(d,nγ)) experiment
2147.3	904.7	E(γ): Seen only in ((³He,pnγ),(d,nγ)) experiment
2225.40	761.76	M(γ): d(+Q) from γ(θ) (⁴⁰Ca,3pγ), ((³He,pnγ),(d,nγ))
2229.6	1171.8	E(γ): Seen only in ⁹⁷Pd ε decay I(γ): Seen only in ⁹⁷Pd ε decay
2229.6	2231.3	E(γ): Seen only in ⁹⁷Pd ε decay I(γ): Seen only in ⁹⁷Pd ε decay
2271.1	1421.0	E(γ): Seen only in ((³He,pnγ),(d,nγ)) experiment
2272.5	310.53	E(γ): Seen only in (⁴⁰Ca,3pγ) experiment
2297.7	922.1	E(γ): Seen only in ((³He,pnγ),(d,nγ)) experiment
2353.7	425.4	E(γ): Seen only in ((³He,pnγ),(d,nγ)) experiment
2372.8	1515.1	E(γ): Seen only in ((³He,pnγ),(d,nγ)) experiment
2617.27	655.23	M(γ): from DCO (³⁶S,4nγ)
2617.27	1064.16	M(γ): from γ(θ) (⁴⁰Ca,3pγ) and from DCO (³⁶S,4nγ)
2895.8	933.8	E(γ): Seen only in (α,p2nγ) experiment M(γ): from γ(θ) (α,p2nγ)
2903.58	2637.1	E(γ): Seen only in ⁹⁷Pd ε decay I(γ): Seen only in ⁹⁷Pd ε decay
E(level)	E(gamma)	Comments
2950.1	2684.4	E(γ): Seen only in ⁹⁷Pd ε decay I(γ): Seen only in ⁹⁷Pd ε decay
2950.1	2950.3	E(γ): Seen only in ⁹⁷Pd ε decay I(γ): Seen only in ⁹⁷Pd ε decay
3055.7	830.33	M(γ): (E2) from γ(θ) (α,p2nγ) and DCO (³⁶S,4nγ)
3091.2	862.7	E(γ): Seen only in ⁹⁷Pd ε decay I(γ): Seen only in ⁹⁷Pd ε decay
	976.7	E(γ): Seen only in ⁹⁷Pd ε decay I(γ): Seen only in ⁹⁷Pd ε decay
	2826.3	E(γ): Seen only in ⁹⁷Pd ε decay I(γ): Seen only in ⁹⁷Pd ε decay
3095.9	823.3	E(γ): Seen only in (⁴⁰Ca,3pγ) experiment I(γ): Seen only in (⁴⁰Ca,3pγ) experiment
3095.9	1134.0	M(γ): from DCO (³⁶S,4nγ)
3240.0	1480.5	E(γ): Seen only in ⁹⁷Pd ε decay I(γ): Seen only in ⁹⁷Pd ε decay
	2974.6	E(γ): Seen only in ⁹⁷Pd ε decay I(γ): Seen only in ⁹⁷Pd ε decay
	3239.8	E(γ): Seen only in ⁹⁷Pd ε decay I(γ): Seen only in ⁹⁷Pd ε decay
3259.7	642.29	M(γ): from DCO (³⁶S,4nγ)
3259.7	1297.79	M(γ): from γ(θ) (⁴⁰Ca,3pγ), (α,p2nγ), and DCO (³⁶S,4nγ)
3345.4	289.58	M(γ): from DCO (³⁶S,4nγ)
3551.3	655.5	E(γ): Seen only in (α,p2nγ) experiment I(γ): Seen only in (α,p2nγ) experiment M(γ): d γ from γ(θ) (α,p2nγ); Δπ=no from level scheme
3551.3	934.1	M(γ): from γ(θ) (⁴⁰Ca,3pγ)
3607.1	1377.4	E(γ): Seen only in ⁹⁷Pd ε decay I(γ): Seen only in ⁹⁷Pd ε decay
	2408.0	E(γ): Seen only in ⁹⁷Pd ε decay I(γ): Seen only in ⁹⁷Pd ε decay
	3342.1	E(γ): Seen only in ⁹⁷Pd ε decay I(γ): Seen only in ⁹⁷Pd ε decay
4015.5	755.71	M(γ): from DCO (⁴⁰Ca,3pγ)
4074.4	728.93	M(γ): from DCO (³⁶S,4nγ)
4074.4	1018.78	M(γ): from γ(θ) (⁴⁰Ca,3pγ) and DCO (³⁶S,4nγ)
4275.1	259.62	M(γ): from DCO (³⁶S,4nγ)
4275.1	723.91	M(γ): from DCO (³⁶S,4nγ)
4824.4	808.89	E(γ): Seen only in (⁴⁰Ca,3pγ) experiment M(γ): from γ(θ) (⁴⁰Ca,3pγ), DCO (³⁶S,4nγ)
E(level)	E(gamma)	Comments
5159.4	1084.92	M(γ): from γ(θ) (⁴⁰Ca,3pγ), DCO (³⁶S,4nγ)
5516.2	1241.04	M(γ): from DCO (³⁶S,4nγ)
5965.1	1690	E(γ): Seen only in (³⁶S,4nγ) experiment. The ordering of the 289.6- and 728.9-keV transitions has not been determined; therefore, this level could be either at 3345.4 or at 3784.7 keV.
5973.8	814.41	M(γ): from DCO (³⁶S,4nγ)
6191.6	674.4	E(γ): Seen only in (³⁶S,4nγ) experiment. The ordering of the 289.6- and 728.9-keV transitions has not been determined; therefore, this level could be either at 3345.4 or at 3784.7 keV. I(γ): Seen only in (³⁶S,4nγ) experiment
6191.6	1367.2	M(γ): from DCO (³⁶S,4nγ)
6441.2	467.47	M(γ): from DCO (³⁶S,4nγ)
6472.5	498.7	E(γ): Seen only in (³⁶S,4nγ) experiment. The ordering of the 289.6- and 728.9-keV transitions has not been determined; therefore, this level could be either at 3345.4 or at 3784.7 keV. M(γ): from DCO (³⁶S,4nγ)
6502.5	310.9	E(γ): Seen only in (³⁶S,4nγ) experiment. The ordering of the 289.6- and 728.9-keV transitions has not been determined; therefore, this level could be either at 3345.4 or at 3784.7 keV.
6912.1	1395.9	E(γ): Seen only in (³⁶S,4nγ) experiment. The ordering of the 289.6- and 728.9-keV transitions has not been determined; therefore, this level could be either at 3345.4 or at 3784.7 keV. M(γ): from DCO (³⁶S,4nγ)
6973.2	1457.0	E(γ): Seen only in (³⁶S,4nγ) experiment. The ordering of the 289.6- and 728.9-keV transitions has not been determined; therefore, this level could be either at 3345.4 or at 3784.7 keV.
7079.2	1563	E(γ): Seen only in (³⁶S,4nγ) experiment. The ordering of the 289.6- and 728.9-keV transitions has not been determined; therefore, this level could be either at 3345.4 or at 3784.7 keV.
7327.6	825.1	E(γ): Seen only in (³⁶S,4nγ) experiment. The ordering of the 289.6- and 728.9-keV transitions has not been determined; therefore, this level could be either at 3345.4 or at 3784.7 keV.
7584.2	2068	E(γ): Seen only in (³⁶S,4nγ) experiment. The ordering of the 289.6- and 728.9-keV transitions has not been determined; therefore, this level could be either at 3345.4 or at 3784.7 keV.
7687.2	2171	E(γ): Seen only in (³⁶S,4nγ) experiment. The ordering of the 289.6- and 728.9-keV transitions has not been determined; therefore, this level could be either at 3345.4 or at 3784.7 keV.
7699.2	1257.9	E(γ): Seen only in (³⁶S,4nγ) experiment. The ordering of the 289.6- and 728.9-keV transitions has not been determined; therefore, this level could be either at 3345.4 or at 3784.7 keV.
7954.1	1180.0	E(γ): Seen only in (³⁶S,4nγ) experiment. The ordering of the 289.6- and 728.9-keV transitions has not been determined; therefore, this level could be either at 3345.4 or at 3784.7 keV.
8003.6	1812	E(γ): Seen only in (³⁶S,4nγ) experiment. The ordering of the 289.6- and 728.9-keV transitions has not been determined; therefore, this level could be either at 3345.4 or at 3784.7 keV.
8282.1	1508	E(γ): Seen only in (³⁶S,4nγ) experiment. The ordering of the 289.6- and 728.9-keV transitions has not been determined; therefore, this level could be either at 3345.4 or at 3784.7 keV.
8364.1	1590	E(γ): Seen only in (³⁶S,4nγ) experiment. The ordering of the 289.6- and 728.9-keV transitions has not been determined; therefore, this level could be either at 3345.4 or at 3784.7 keV. M(γ): from DCO (³⁶S,4nγ)
8492.2	793.0	E(γ): Seen only in (³⁶S,4nγ) experiment. The ordering of the 289.6- and 728.9-keV transitions has not been determined; therefore, this level could be either at 3345.4 or at 3784.7 keV.
8594.1	1820	E(γ): Seen only in (³⁶S,4nγ) experiment. The ordering of the 289.6- and 728.9-keV transitions has not been determined; therefore, this level could be either at 3345.4 or at 3784.7 keV.
9078.6	1075.0	E(γ): Seen only in (³⁶S,4nγ) experiment. The ordering of the 289.6- and 728.9-keV transitions has not been determined; therefore, this level could be either at 3345.4 or at 3784.7 keV.
9204.2	1505	E(γ): Seen only in (³⁶S,4nγ) experiment. The ordering of the 289.6- and 728.9-keV transitions has not been determined; therefore, this level could be either at 3345.4 or at 3784.7 keV.
9242.2	1543	E(γ): Seen only in (³⁶S,4nγ) experiment. The ordering of the 289.6- and 728.9-keV transitions has not been determined; therefore, this level could be either at 3345.4 or at 3784.7 keV.

E(level)	J^π(level)	T_1/2(level)	Comments
0.0	9/2+	30.7 m 6 % ε = 100	J^π(level): log ft=5.184 from g.s. to 7/2⁺ 421.54-keV level in ⁹⁷Ru, Jπ(g.s.)=5/2⁺,7/2⁺,9/2⁺. M4 transition from 258.85 level to g.s. gives Jπ(258.85)=1/2-,13/2-,15/2-,17/2-. log ft=6.77 from 258.85 level to L=0 908.30 level in ⁹⁷Ru rules out high spins. Possible E3 admixture >20% in M4 transition ruled out by α(K)exp(258γ).
258.76	1/2-	46.2 m 16 % IT = 5.6 6 % ε = 94.4 6	J^π(level): log ft=5.184 from g.s. to 7/2⁺ 421.54-keV level in ⁹⁷Ru, Jπ(g.s.)=5/2⁺,7/2⁺,9/2⁺. M4 transition from 258.85 level to g.s. gives Jπ(258.85)=1/2-,13/2-,15/2-,17/2-. log ft=6.77 from 258.85 level to L=0 908.30 level in ⁹⁷Ru rules out high spins. Possible E3 admixture >20% in M4 transition ruled out by α(K)exp(258γ).
850.1	(5/2-)		E(level): Negative parity yrast state, established by cascading γ’s (from ((³He,pnγ),(d,nγ)) for J\|<13/2 and from (⁴⁰Ca,3pγ) and (³⁶S,4nγ) for J\|>17/2); increasing spins with increasing excitation energies of levels were tacitly assumed. J^π(level): Negative parity yrast state, established by cascading γ’s (from ((³He,pnγ),(d,nγ)) for J\|<13/2 and from (⁴⁰Ca,3pγ) and (³⁶S,4nγ) for J\|>17/2); increasing spins with increasing excitation energies of levels were tacitly assumed.
857.71	(13/2+)		E(level): Yrast state, established by cascading γ’s (⁴⁰Ca,3pγ) and (³⁶S,4nγ) (also (⁶Li,3nγ), and/or ((³He,pnγ),(p,nγ)), and/or (α,p2nγ) for levels with J\|<25/2⁺); increasing spins with increasing excitation energies of levels were tacitly assumed. J^π(level): Yrast state, established by cascading γ’s (⁴⁰Ca,3pγ) and (³⁶S,4nγ) (also (⁶Li,3nγ), and/or ((³He,pnγ),(p,nγ)), and/or (α,p2nγ) for levels with J\|<25/2⁺); increasing spins with increasing excitation energies of levels were tacitly assumed.
1375.6	(9/2-)		E(level): Negative parity yrast state, established by cascading γ’s (from ((³He,pnγ),(d,nγ)) for J\|<13/2 and from (⁴⁰Ca,3pγ) and (³⁶S,4nγ) for J\|>17/2); increasing spins with increasing excitation energies of levels were tacitly assumed. J^π(level): Negative parity yrast state, established by cascading γ’s (from ((³He,pnγ),(d,nγ)) for J\|<13/2 and from (⁴⁰Ca,3pγ) and (³⁶S,4nγ) for J\|>17/2); increasing spins with increasing excitation energies of levels were tacitly assumed.
1463.64	(15/2+)		E(level): Yrast state, established by cascading γ’s (⁴⁰Ca,3pγ) and (³⁶S,4nγ) (also (⁶Li,3nγ), and/or ((³He,pnγ),(p,nγ)), and/or (α,p2nγ) for levels with J\|<25/2⁺); increasing spins with increasing excitation energies of levels were tacitly assumed. J^π(level): Yrast state, established by cascading γ’s (⁴⁰Ca,3pγ) and (³⁶S,4nγ) (also (⁶Li,3nγ), and/or ((³He,pnγ),(p,nγ)), and/or (α,p2nγ) for levels with J\|<25/2⁺); increasing spins with increasing excitation energies of levels were tacitly assumed.
1553.15	(17/2+)		E(level): Yrast state, established by cascading γ’s (⁴⁰Ca,3pγ) and (³⁶S,4nγ) (also (⁶Li,3nγ), and/or ((³He,pnγ),(p,nγ)), and/or (α,p2nγ) for levels with J\|<25/2⁺); increasing spins with increasing excitation energies of levels were tacitly assumed. J^π(level): Yrast state, established by cascading γ’s (⁴⁰Ca,3pγ) and (³⁶S,4nγ) (also (⁶Li,3nγ), and/or ((³He,pnγ),(p,nγ)), and/or (α,p2nγ) for levels with J\|<25/2⁺); increasing spins with increasing excitation energies of levels were tacitly assumed.
1928.3	(13/2-)		E(level): Negative parity yrast state, established by cascading γ’s (from ((³He,pnγ),(d,nγ)) for J\|<13/2 and from (⁴⁰Ca,3pγ) and (³⁶S,4nγ) for J\|>17/2); increasing spins with increasing excitation energies of levels were tacitly assumed. J^π(level): Negative parity yrast state, established by cascading γ’s (from ((³He,pnγ),(d,nγ)) for J\|<13/2 and from (⁴⁰Ca,3pγ) and (³⁶S,4nγ) for J\|>17/2); increasing spins with increasing excitation energies of levels were tacitly assumed.
1961.98	(19/2+)		E(level): Yrast state, established by cascading γ’s (⁴⁰Ca,3pγ) and (³⁶S,4nγ) (also (⁶Li,3nγ), and/or ((³He,pnγ),(p,nγ)), and/or (α,p2nγ) for levels with J\|<25/2⁺); increasing spins with increasing excitation energies of levels were tacitly assumed. J^π(level): Yrast state, established by cascading γ’s (⁴⁰Ca,3pγ) and (³⁶S,4nγ) (also (⁶Li,3nγ), and/or ((³He,pnγ),(p,nγ)), and/or (α,p2nγ) for levels with J\|<25/2⁺); increasing spins with increasing excitation energies of levels were tacitly assumed.
2225.40	(17/2-)		E(level): Negative parity yrast state, established by cascading γ’s (from ((³He,pnγ),(d,nγ)) for J\|<13/2 and from (⁴⁰Ca,3pγ) and (³⁶S,4nγ) for J\|>17/2); increasing spins with increasing excitation energies of levels were tacitly assumed. J^π(level): Negative parity yrast state, established by cascading γ’s (from ((³He,pnγ),(d,nγ)) for J\|<13/2 and from (⁴⁰Ca,3pγ) and (³⁶S,4nγ) for J\|>17/2); increasing spins with increasing excitation energies of levels were tacitly assumed.
2272.5			E(level): The ordering of the 310.5- and 823.3-keV transitions has not been determined; therefore, this level could be either at 2272.8 or at 2785.9 keV.
2617.27	(21/2+)		E(level): Yrast state, established by cascading γ’s (⁴⁰Ca,3pγ) and (³⁶S,4nγ) (also (⁶Li,3nγ), and/or ((³He,pnγ),(p,nγ)), and/or (α,p2nγ) for levels with J\|<25/2⁺); increasing spins with increasing excitation energies of levels were tacitly assumed. J^π(level): Yrast state, established by cascading γ’s (⁴⁰Ca,3pγ) and (³⁶S,4nγ) (also (⁶Li,3nγ), and/or ((³He,pnγ),(p,nγ)), and/or (α,p2nγ) for levels with J\|<25/2⁺); increasing spins with increasing excitation energies of levels were tacitly assumed.
2895.8	(23/2+)		E(level): Yrast state, established by cascading γ’s (⁴⁰Ca,3pγ) and (³⁶S,4nγ) (also (⁶Li,3nγ), and/or ((³He,pnγ),(p,nγ)), and/or (α,p2nγ) for levels with J\|<25/2⁺); increasing spins with increasing excitation energies of levels were tacitly assumed. J^π(level): Yrast state, established by cascading γ’s (⁴⁰Ca,3pγ) and (³⁶S,4nγ) (also (⁶Li,3nγ), and/or ((³He,pnγ),(p,nγ)), and/or (α,p2nγ) for levels with J\|<25/2⁺); increasing spins with increasing excitation energies of levels were tacitly assumed.
3055.7	(21/2-)		E(level): Negative parity yrast state, established by cascading γ’s (from ((³He,pnγ),(d,nγ)) for J\|<13/2 and from (⁴⁰Ca,3pγ) and (³⁶S,4nγ) for J\|>17/2); increasing spins with increasing excitation energies of levels were tacitly assumed. J^π(level): Negative parity yrast state, established by cascading γ’s (from ((³He,pnγ),(d,nγ)) for J\|<13/2 and from (⁴⁰Ca,3pγ) and (³⁶S,4nγ) for J\|>17/2); increasing spins with increasing excitation energies of levels were tacitly assumed.
3345.4	(23/2)		E(level): Seen only in (³⁶S,4nγ) experiment. The ordering of the 289.6- and 728.9-keV transitions has not been determined; therefore, this level could be either at 3345.4 or at 3784.7 keV.
3551.3	(25/2+)		E(level): Yrast state, established by cascading γ’s (⁴⁰Ca,3pγ) and (³⁶S,4nγ) (also (⁶Li,3nγ), and/or ((³He,pnγ),(p,nγ)), and/or (α,p2nγ) for levels with J\|<25/2⁺); increasing spins with increasing excitation energies of levels were tacitly assumed. J^π(level): Yrast state, established by cascading γ’s (⁴⁰Ca,3pγ) and (³⁶S,4nγ) (also (⁶Li,3nγ), and/or ((³He,pnγ),(p,nγ)), and/or (α,p2nγ) for levels with J\|<25/2⁺); increasing spins with increasing excitation energies of levels were tacitly assumed.
4015.5	(27/2+)		E(level): Yrast state, established by cascading γ’s (⁴⁰Ca,3pγ) and (³⁶S,4nγ) (also (⁶Li,3nγ), and/or ((³He,pnγ),(p,nγ)), and/or (α,p2nγ) for levels with J\|<25/2⁺); increasing spins with increasing excitation energies of levels were tacitly assumed. J^π(level): Yrast state, established by cascading γ’s (⁴⁰Ca,3pγ) and (³⁶S,4nγ) (also (⁶Li,3nγ), and/or ((³He,pnγ),(p,nγ)), and/or (α,p2nγ) for levels with J\|<25/2⁺); increasing spins with increasing excitation energies of levels were tacitly assumed.
4074.4	(25/2-)		E(level): Negative parity yrast state, established by cascading γ’s (from ((³He,pnγ),(d,nγ)) for J\|<13/2 and from (⁴⁰Ca,3pγ) and (³⁶S,4nγ) for J\|>17/2); increasing spins with increasing excitation energies of levels were tacitly assumed. J^π(level): Negative parity yrast state, established by cascading γ’s (from ((³He,pnγ),(d,nγ)) for J\|<13/2 and from (⁴⁰Ca,3pγ) and (³⁶S,4nγ) for J\|>17/2); increasing spins with increasing excitation energies of levels were tacitly assumed.
4275.1	(29/2+)		E(level): Yrast state, established by cascading γ’s (⁴⁰Ca,3pγ) and (³⁶S,4nγ) (also (⁶Li,3nγ), and/or ((³He,pnγ),(p,nγ)), and/or (α,p2nγ) for levels with J\|<25/2⁺); increasing spins with increasing excitation energies of levels were tacitly assumed. J^π(level): Yrast state, established by cascading γ’s (⁴⁰Ca,3pγ) and (³⁶S,4nγ) (also (⁶Li,3nγ), and/or ((³He,pnγ),(p,nγ)), and/or (α,p2nγ) for levels with J\|<25/2⁺); increasing spins with increasing excitation energies of levels were tacitly assumed.
4824.4	(31/2+)		E(level): Yrast state, established by cascading γ’s (⁴⁰Ca,3pγ) and (³⁶S,4nγ) (also (⁶Li,3nγ), and/or ((³He,pnγ),(p,nγ)), and/or (α,p2nγ) for levels with J\|<25/2⁺); increasing spins with increasing excitation energies of levels were tacitly assumed. J^π(level): Yrast state, established by cascading γ’s (⁴⁰Ca,3pγ) and (³⁶S,4nγ) (also (⁶Li,3nγ), and/or ((³He,pnγ),(p,nγ)), and/or (α,p2nγ) for levels with J\|<25/2⁺); increasing spins with increasing excitation energies of levels were tacitly assumed.
5159.4	(29/2-)		E(level): Negative parity yrast state, established by cascading γ’s (from ((³He,pnγ),(d,nγ)) for J\|<13/2 and from (⁴⁰Ca,3pγ) and (³⁶S,4nγ) for J\|>17/2); increasing spins with increasing excitation energies of levels were tacitly assumed. J^π(level): Negative parity yrast state, established by cascading γ’s (from ((³He,pnγ),(d,nγ)) for J\|<13/2 and from (⁴⁰Ca,3pγ) and (³⁶S,4nγ) for J\|>17/2); increasing spins with increasing excitation energies of levels were tacitly assumed.
5516.2	(33/2+)		E(level): Yrast state, established by cascading γ’s (⁴⁰Ca,3pγ) and (³⁶S,4nγ) (also (⁶Li,3nγ), and/or ((³He,pnγ),(p,nγ)), and/or (α,p2nγ) for levels with J\|<25/2⁺); increasing spins with increasing excitation energies of levels were tacitly assumed. J^π(level): Yrast state, established by cascading γ’s (⁴⁰Ca,3pγ) and (³⁶S,4nγ) (also (⁶Li,3nγ), and/or ((³He,pnγ),(p,nγ)), and/or (α,p2nγ) for levels with J\|<25/2⁺); increasing spins with increasing excitation energies of levels were tacitly assumed.
5973.8	(31/2-)		E(level): Negative parity yrast state, established by cascading γ’s (from ((³He,pnγ),(d,nγ)) for J\|<13/2 and from (⁴⁰Ca,3pγ) and (³⁶S,4nγ) for J\|>17/2); increasing spins with increasing excitation energies of levels were tacitly assumed. J^π(level): Negative parity yrast state, established by cascading γ’s (from ((³He,pnγ),(d,nγ)) for J\|<13/2 and from (⁴⁰Ca,3pγ) and (³⁶S,4nγ) for J\|>17/2); increasing spins with increasing excitation energies of levels were tacitly assumed.
6191.6	(35/2+)		E(level): Yrast state, established by cascading γ’s (⁴⁰Ca,3pγ) and (³⁶S,4nγ) (also (⁶Li,3nγ), and/or ((³He,pnγ),(p,nγ)), and/or (α,p2nγ) for levels with J\|<25/2⁺); increasing spins with increasing excitation energies of levels were tacitly assumed. J^π(level): Yrast state, established by cascading γ’s (⁴⁰Ca,3pγ) and (³⁶S,4nγ) (also (⁶Li,3nγ), and/or ((³He,pnγ),(p,nγ)), and/or (α,p2nγ) for levels with J\|<25/2⁺); increasing spins with increasing excitation energies of levels were tacitly assumed.
6774.1	(37/2+)		E(level): Yrast state, established by cascading γ’s (⁴⁰Ca,3pγ) and (³⁶S,4nγ) (also (⁶Li,3nγ), and/or ((³He,pnγ),(p,nγ)), and/or (α,p2nγ) for levels with J\|<25/2⁺); increasing spins with increasing excitation energies of levels were tacitly assumed. J^π(level): Yrast state, established by cascading γ’s (⁴⁰Ca,3pγ) and (³⁶S,4nγ) (also (⁶Li,3nγ), and/or ((³He,pnγ),(p,nγ)), and/or (α,p2nγ) for levels with J\|<25/2⁺); increasing spins with increasing excitation energies of levels were tacitly assumed.
E(level)	J^π(level)	T_1/2(level)	Comments
7699.2	(35/2-)		E(level): Negative parity yrast state, established by cascading γ’s (from ((³He,pnγ),(d,nγ)) for J\|<13/2 and from (⁴⁰Ca,3pγ) and (³⁶S,4nγ) for J\|>17/2); increasing spins with increasing excitation energies of levels were tacitly assumed. J^π(level): Negative parity yrast state, established by cascading γ’s (from ((³He,pnγ),(d,nγ)) for J\|<13/2 and from (⁴⁰Ca,3pγ) and (³⁶S,4nγ) for J\|>17/2); increasing spins with increasing excitation energies of levels were tacitly assumed.
8510	(5/2+)		Isobaric analog to ⁹⁷Ru 5/2⁺ g.s. E(level): Isobaric analog to ⁹⁷Ru 5/2⁺ g.s.
9400	(1/2+)		Isobaric analog to ⁹⁷Ru 1/2⁺ 908.28-keV level.