List of levels for 97TC

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
96.57	1/2-	91.0 d 6 % IT = 96.06 18 % ε = 3.94 18	96.5 1	M4		311	B(M4)(W.u.)=12.14 22, α=311, α(K)=197 3, α(L)=92.1 15, α(M)=18.5 3, α(N)=2.77 5, α(O)=0.0919 14, α(N+)=2.87 5
215.718	7/2+	69 ps 19	215.718 24	M1+E2	+0.27 2	0.0378	B(E2)(W.u.)=43 14, B(M1)(W.u.)=0.029 8, α=0.0378 7, α(K)=0.0330 6, α(L)=0.00398 8, α(M)=0.000723 15, α(N)=0.0001143 23, α(O)=7.30E-6 12, α(N+)=0.0001216 24
324.476	5/2+	0.45 ns 8	108.79 3	M1+E2	+1.6 5	0.73	B(E2)(W.u.)=26 12, B(M1)(W.u.)=0.00012 8, α=0.73 13, α(K)=0.59 10, α(L)=0.111 21, α(M)=0.020 4, α(N)=0.0030 6, α(O)=0.000111 16, α(N+)=0.0031 6
324.476	5/2+	0.45 ns 8	324.48 3	E2		0.0196	B(E2)(W.u.)=12.7 23, α=0.0196, α(K)=0.01696 24, α(L)=0.00219 3, α(M)=0.000399 6, α(N)=6.21E-5 9, α(O)=3.51E-6 5, α(N+)=6.56E-5 10
580.19	3/2-		483.62 2	M1+E2	-0.6 5	0.0049	α=0.0049 3, α(K)=0.00425 24, α(L)=0.00050 4, α(M)=9.0×10^-5 7, α(N)=1.43E-5 11, α(O)=9.3E-7 4, α(N+)=1.52E-5 11
656.90	5/2-	≥ 0.76 ps	332.4 3	[E1]		0.00444	B(E1)(W.u.)<6.7E-5, α=0.00444, α(K)=0.00390 6, α(L)=0.000443 7, α(M)=8.00E-5 12, α(N)=1.267E-5 18, α(O)=8.24E-7 12, α(N+)=1.349E-5 20
	5/2-	≥ 0.76 ps	441.2	[E1]		0.00214	B(E1)(W.u.)<7.2E-5, α=0.00214, α(K)=0.00189 3, α(L)=0.000213 3, α(M)=3.85E-5 6, α(N)=6.11E-6 9, α(O)=4.02E-7 6, α(N+)=6.51E-6 10
	5/2-	≥ 0.76 ps	560.34 4	E2		0.00362	B(E2)(W.u.)≤500, α=0.00362, α(K)=0.00316 5, α(L)=0.000380 6, α(M)=6.88E-5 10, α(N)=1.084E-5 16, α(O)=6.78E-7 10, α(N+)=1.152E-5 17
772.68	13/2+	≥ 0.35 ps	772.70 7	E2		1.53×10^-3	B(E2)(W.u.)≤220, α=1.53E-3, α(K)=0.001343 19, α(L)=0.0001566 22, α(M)=2.83E-5 4, α(N)=4.49E-6 7, α(O)=2.91E-7 4, α(N+)=4.78E-6 7
777.98	(7/2+,9/2+)		777.90 20	(M1+E2)		1.52×10^-3	α=1.52×10^-3 2, α(K)=0.001331 22, α(L)=0.0001528 25, α(M)=2.76E-5 5, α(N)=4.39E-6 7, α(O)=2.92E-7 7, α(N+)=4.69E-6 7
785.034	5/2+	0.33 ps +17-10	460.57 3	M1+E2	-0.6 +4-3	0.0055	B(E2)(W.u.)=9.×10¹ +10-9, B(M1)(W.u.)=0.05 +3-4, α=0.0055 3, α(K)=0.0048 3, α(L)=0.00056 4, α(M)=0.000102 8, α(N)=1.62E-5 11, α(O)=1.06E-6 5, α(N+)=1.73E-5 11
	5/2+	0.33 ps +17-10	569.31 4	M1+E2	+0.128 14	0.00313	B(E2)(W.u.)=14 +6-8, B(M1)(W.u.)=0.29 +9-15, α=0.00313, α(K)=0.00275 4, α(L)=0.000314 5, α(M)=5.68E-5 8, α(N)=9.04E-6 13, α(O)=6.12E-7 9, α(N+)=9.66E-6 14
	5/2+	0.33 ps +17-10	785.06 4	(E2)		1.47×10^-3	B(E2)(W.u.)=15 +5-8, α=1.47E-3, α(K)=0.001291 18, α(L)=0.0001503 21, α(M)=2.72E-5 4, α(N)=4.31E-6 6, α(O)=2.80E-7 4, α(N+)=4.59E-6 7
832.80	11/2(+)	≥ 0.35 ps	832.85 7	(M1+E2)		0.00129	α=0.00129 3, α(K)=0.001134 24, α(L)=0.0001297 19, α(M)=2.35×10^-5 4, α(N)=3.73E-6 6, α(O)=2.49E-7 8, α(N+)=3.98E-6 7
855.45	7/2+	≥ 0.37 ps	639.72 2	(M1+E2)	-2.3 +6-1	0.00249	B(E2)(W.u.)<69, B(M1)(W.u.)<0.0073, α=0.00249, α(K)=0.00218 4, α(L)=0.000256 5, α(M)=4.65E-5 8, α(N)=7.35E-6 12, α(O)=4.72E-7 7, α(N+)=7.82E-6 13
855.45	7/2+	≥ 0.37 ps	855.53 14	M1+E2	+0.3 2	1.23×10^-3	B(E2)(W.u.)<18, B(M1)(W.u.)<0.077, α=1.23E-3, α(K)=0.001082 16, α(L)=0.0001223 18, α(M)=2.21E-5 4, α(N)=3.53E-6 5, α(O)=2.39E-7 4, α(N+)=3.77E-6 6
861.90	(9/2+)	≥ 0.38 ps	861.70 10	(M1+E2)	-0.51 21	1.21×10^-3	B(E2)(W.u.)≤34, B(M1)(W.u.)≤0.071, α=1.21E-3 2, α(K)=0.001060 16, α(L)=0.0001201 17, α(M)=2.17E-5 3, α(N)=3.46E-6 5, α(O)=2.34E-7 4, α(N+)=3.70E-6 6
946.73	3/2-	0.22 ps +9-6	290.0	(M1)		0.01621	B(M1)(W.u.)=0.08 3, α=0.01621, α(K)=0.01420 20, α(L)=0.001652 24, α(M)=0.000299 5, α(N)=4.77×10^-5 7, α(O)=3.19E-6 5, α(N+)=5.08E-5 8
	3/2-	0.22 ps +9-6	366.6 2	(M1)		0.00901	B(M1)(W.u.)=0.31 +10-14, α=0.00901, α(K)=0.00790 12, α(L)=0.000912 13, α(M)=0.0001653 24, α(N)=2.63×10^-5 4, α(O)=1.768E-6 25, α(N+)=2.81E-5 4
	3/2-	0.22 ps +9-6	622.4	(E1)		9.49×10^-4	B(E1)(W.u.)≈0.0002, α=9.49E-4, α(K)=0.000835 12, α(L)=9.38E-5 14, α(M)=1.693E-5 24, α(N)=2.69E-6 4, α(O)=1.79E-7 3, α(N+)=2.87E-6 4
	3/2-	0.22 ps +9-6	850.10 10	M1+E2		0.00123	α=0.00123 3, α(K)=0.001081 25, α(L)=0.0001235 19, α(M)=2.24×10^-5 4, α(N)=3.56E-6 6, α(O)=2.37E-7 8, α(N+)=3.79E-6 7
970.03	7/2+		645.27 20	M1+E2	-1.2 +8-9	0.00240	α=0.00240 7, α(K)=0.00211 6, α(L)=0.000245 10, α(M)=4.44×10^-5 19, α(N)=7.0E-6 3, α(O)=4.60E-7 7, α(N+)=7.5E-6 3
970.03	7/2+		754.01 20	M1+E2	-2.2 8	1.63×10^-3	α=1.63×10^-3, α(K)=0.001430 21, α(L)=0.0001662 25, α(M)=3.01E-5 5, α(N+)=5.08E-6 8
994.68	(3/2+)	0.17 ps +7-4	670.21 2	(M1+E2)		0.00218	α=0.00218 5, α(K)=0.00191 4, α(L)=0.000221 9, α(M)=4.00×10^-5 15, α(N)=6.35E-6 22, α(O)=4.18E-7 6, α(N+)=6.77E-6 22
994.68	(3/2+)	0.17 ps +7-4	898.06 16	(E1)		4.37×10^-4	B(E1)(W.u.)=7.E-5 7, α=4.37E-4, α(K)=0.000385 6, α(L)=4.29E-5 6, α(M)=7.74E-6 11, α(N)=1.233E-6 18, α(O)=8.31E-8 12, α(N+)=1.316E-6 19
E(level) (keV)	J^π(level)	T_1/2(level)	E(γ) (keV)	Multipolarity	Mixing Ratio	Conversion Coefficient	Additional Data
1049.22	3/2-	≥ 0.21 ps	392.2 1	(M1)		0.00763	B(M1)(W.u.)≤0.71, α=0.00763, α(K)=0.00670 10, α(L)=0.000771 11, α(M)=0.0001398 20, α(N)=2.23×10^-5 4, α(O)=1.497E-6 21, α(N+)=2.38E-5 4
	3/2-	≥ 0.21 ps	469.2 1	(M1)		0.00494	B(M1)(W.u.)≤0.25, α=0.00494, α(K)=0.00434 6, α(L)=0.000497 7, α(M)=9.00×10^-5 13, α(N)=1.434E-5 20, α(O)=9.68E-7 14, α(N+)=1.531E-5 22
	3/2-	≥ 0.21 ps	724.7 1	[E1]		6.80×10^-4	B(E1)(W.u.)≤0.0014, α=6.80E-4, α(K)=0.000598 9, α(L)=6.70E-5 10, α(M)=1.209E-5 17, α(N)=1.92E-6 3, α(O)=1.289E-7 18, α(N+)=2.05E-6 3
1126.64	11/2(+)		910.92 2	(E2)		1.03×10^-3	α=1.03×10^-3, α(K)=0.000901 13, α(L)=0.0001038 15, α(M)=1.88E-5 3, α(N)=2.98E-6 5, α(O)=1.96E-7 3, α(N+)=3.18E-6 5
1126.64	11/2(+)		1126.6 1	(M1+E2)	-0.8 +3-5	6.62×10^-4	α=6.62×10^-4 14, α(K)=0.000581 13, α(L)=6.55E-5 13, α(M)=1.185E-5 23, α(N)=1.89E-6 4, α(O)=1.28E-7 3, α(N+)=3.21E-6 6
1141.23	(7/2+)	0.28 ps +25-10	356.1 3	(M1+E2)	-0.3 2	0.0101	B(E2)(W.u.)=(3.×10² +4-3), B(M1)(W.u.)=(0.40 +18-38), α=0.0101 6, α(K)=0.0088 5, α(L)=0.00103 8, α(M)=0.000187 14, α(N)=2.97E-5 21, α(O)=1.96E-6 9, α(N+)=3.17E-5 22
1141.23	(7/2+)	0.28 ps +25-10	816.7 1	(M1+E2)	-0.8 +4-9	1.36×10^-3	B(E2)(W.u.)=(6.×10¹ +5-6), B(M1)(W.u.)=(0.06 +4-6), α=1.36E-3 2, α(K)=0.001190 20, α(L)=0.0001359 19, α(M)=2.46E-5 4, α(N)=3.91E-6 6, α(O)=2.62E-7 6, α(N+)=4.17E-6 6
1199.62	(9/2+)	0.24 ps +37-10	875.18 20	(E2)		1.13×10^-3	B(E2)(W.u.)=43 +18-43, α=1.13E-3, α(K)=0.000991 14, α(L)=0.0001144 16, α(M)=2.07E-5 3, α(N)=3.28E-6 5, α(O)=2.15E-7 3, α(N+)=3.50E-6 5
1199.62	(9/2+)	0.24 ps +37-10	983.81 20	(M1+E2)	-0.58 4	8.95×10^-4	B(E2)(W.u.)=(9 +4-9), B(M1)(W.u.)=(0.026 +11-26), α=8.95E-4, α(K)=0.000787 11, α(L)=8.89E-5 13, α(M)=1.608E-5 23, α(N)=2.56E-6 4, α(O)=1.736E-7 25, α(N+)=2.74E-6 4
1219.87	(7/2+)		895.4 2	(M1+E2)	-0.8 +4-7	1.10×10^-3	α=1.10×10^-3 2, α(K)=0.000964 19, α(L)=0.0001096 17, α(M)=1.98E-5 3, α(N)=3.16E-6 6, α(O)=2.12E-7 5, α(N+)=3.37E-6 6
	(7/2+)		1004.2 2	(M1+E2)		0.00084	α=0.00084 3, α(K)=0.000742 25, α(L)=8.41×10^-5 22, α(M)=1.52E-5 4, α(N)=2.42E-6 7, α(O)=1.63E-7 7, α(N+)=2.58E-6 8
	(7/2+)		1219.8 2	(M1+E2)		5.63×10^-4	α=5.63×10^-4 20, α(K)=0.000487 19, α(L)=5.48E-5 18, α(M)=9.9E-6 4, α(N)=1.58E-6 6, α(O)=1.07E-7 5, α(N+)=1.12E-5 10
1240.02	(7/2-)	≥ 0.26 ps	583.16 5	(M1+E2)	-0.34 24	0.00298	B(E2)(W.u.)<1.0×10², B(M1)(W.u.)<0.16, α=0.00298 6, α(K)=0.00262 5, α(L)=0.000300 8, α(M)=5.43E-5 14, α(N)=8.64E-6 21, α(O)=5.80E-7 10, α(N+)=9.22E-6 22
	(7/2-)	≥ 0.26 ps	659.6 1	[E2]		0.00231	B(E2)(W.u.)≤210, α=0.00231, α(K)=0.00202 3, α(L)=0.000239 4, α(M)=4.33E-5 6, α(N)=6.84E-6 10, α(O)=4.36E-7 7, α(N+)=7.27E-6 11
	(7/2-)	≥ 0.26 ps	915.7 2	(E1)		4.20×10^-4	B(E1)(W.u.)≤1.2E-4, α=4.20E-4, α(K)=0.000370 6, α(L)=4.13E-5 6, α(M)=7.45E-6 11, α(N)=1.186E-6 17, α(O)=8.00E-8 12, α(N+)=1.266E-6 18
	(7/2-)	≥ 0.26 ps	1024.4 2	[E1]		3.38×10^-4	B(E1)(W.u.)≤1.2E-4, α=3.38E-4, α(K)=0.000298 5, α(L)=3.31E-5 5, α(M)=5.98E-6 9, α(N)=9.53E-7 14, α(O)=6.44E-8 9, α(N+)=1.017E-6 15
1274.54	(3/2-,5/2-,7/2-)		617.60 20	(M1+E2)		0.00267	α=0.00267 10, α(K)=0.00234 8, α(L)=0.000273 15, α(M)=4.9×10^-5 3, α(N)=7.8E-6 4, α(O)=5.12E-7 11, α(N+)=8.3E-6 4
1274.54	(3/2-,5/2-,7/2-)		694.45 20	(E2)		0.00202	α=0.00202, α(K)=0.001765 25, α(L)=0.000208 3, α(M)=3.76×10^-5 6, α(N)=5.95E-6 9, α(O)=3.81E-7 6, α(N+)=6.33E-6 9
1277.82	(9/2-)		620.88 9	(E2)		0.00272	α=0.00272, α(K)=0.00238 4, α(L)=0.000283 4, α(M)=5.12×10^-5 8, α(N)=8.08E-6 12, α(O)=5.12E-7 8, α(N+)=8.60E-6 12
1277.82	(9/2-)		1062.0 4	[E1]		3.16×10^-4	α=3.16×10^-4, α(K)=0.000279 4, α(L)=3.10E-5 5, α(M)=5.58E-6 8, α(N)=8.90E-7 13, α(O)=6.02E-8 9, α(N+)=9.50E-7 14
1310.17	9/2+		1094.5 2	(M1+E2)		6.98×10^-4	α=6.98×10^-4 25, α(K)=0.000614 23, α(L)=6.94E-5 21, α(M)=1.25E-5 4, α(N)=2.00E-6 7, α(O)=1.35E-7 6, α(N+)=2.13E-6 7
1310.17	9/2+		1310.0 3	M1+E2	-0.63 +11-14	5.08×10^-4	α=5.08×10^-4, α(K)=0.000426 7, α(L)=4.77E-5 8, α(M)=8.63E-6 13, α(N)=1.377E-6 21, α(O)=9.38E-8 15, α(N+)=2.60E-5 6
1365.8	(3/2+)		1269	[E1]		3.11×10^-4	α=3.11×10^-4, α(K)=0.000202 3, α(L)=2.23E-5 4, α(M)=4.03E-6 6, α(N)=6.42E-7 9, α(O)=4.36E-8 7, α(N+)=8.28E-5 12
1373.32	(3/2,5/2-)		1276.68 20	(M1+E2)		5.22×10^-4	α=5.22×10^-4 18, α(K)=0.000443 17, α(L)=4.98E-5 17, α(M)=9.0E-6 3, α(N)=1.43E-6 5, α(O)=9.7E-8 5, α(N+)=2.05E-5 19
1379.89	(9/2+)	0.09 ps +5-3	547.2 2	(M1+E2)	+0.33 +10-8	0.00347	B(E2)(W.u.)=(2.2×10² +14-17), B(M1)(W.u.)=(0.61 +21-35), α=0.00347 6, α(K)=0.00305 5, α(L)=0.000350 7, α(M)=6.33E-5 12, α(N)=1.008E-5 18, α(O)=6.76E-7 10, α(N+)=1.076E-5 19
1379.89	(9/2+)	0.09 ps +5-3	1163.9 3	(M1+E2)		6.15×10^-4	α=6.15×10^-4 23, α(K)=0.000538 21, α(L)=6.07E-5 20, α(M)=1.10E-5 4, α(N)=1.75E-6 6, α(O)=1.18E-7 6, α(N+)=5.1E-6 4
E(level) (keV)	J^π(level)	T_1/2(level)	E(γ) (keV)	Multipolarity	Mixing Ratio	Conversion Coefficient	Additional Data
1393.33	(13/2+)		560.48 20	(M1+E2)		0.00343	α=0.00343 20, α(K)=0.00300 17, α(L)=0.00035 3, α(M)=6.4×10^-5 5, α(N)=1.01E-5 8, α(O)=6.55E-7 24, α(N+)=1.08E-5 8
	(13/2+)		620.63 20	(E2)		0.00272	α=0.00272, α(K)=0.00238 4, α(L)=0.000283 4, α(M)=5.13×10^-5 8, α(N)=8.09E-6 12, α(O)=5.12E-7 8, α(N+)=8.61E-6 12
	(13/2+)		1393.33 20	(E2)		4.54×10^-4	α=4.54×10^-4, α(K)=0.000357 5, α(L)=4.02E-5 6, α(M)=7.26E-6 11, α(N)=1.156E-6 17, α(O)=7.78E-8 11, α(N+)=5.00E-5 7
1400.99	(3/2-,5/2-)		820.79 20	(M1+E2)		1.34×10^-3	α=1.34×10^-3 3, α(K)=0.001173 24, α(L)=0.0001343 19, α(M)=2.43E-5 4, α(N)=3.86E-6 6, α(O)=2.57E-7 8, α(N+)=4.12E-6 6
1409.5	(7/2-)		830.0	[E2]		1.28×10^-3	α=1.28×10^-3, α(K)=0.001126 16, α(L)=0.0001305 19, α(M)=2.36E-5 4, α(N)=3.74E-6 6, α(O)=2.44E-7 4, α(N+)=3.99E-6 6
	(7/2-)		1084.9 4	[E1]		3.04×10^-4	α=3.04×10^-4, α(K)=0.000268 4, α(L)=2.97E-5 5, α(M)=5.36E-6 8, α(N)=8.55E-7 12, α(O)=5.79E-8 9, α(N+)=9.13E-7 13
	(7/2-)		1193.8	[E1]		2.91×10^-4	α=2.91×10^-4, α(K)=0.000225 4, α(L)=2.49E-5 4, α(M)=4.50E-6 7, α(N)=7.17E-7 10, α(O)=4.86E-8 7, α(N+)=3.71E-5 6
1471.21	(7/2+,9/2+)		615.66 20	(M1+E2)		0.00269	α=0.00269 10, α(K)=0.00236 9, α(L)=0.000275 16, α(M)=5.0×10^-5 3, α(N)=7.9E-6 4, α(O)=5.16E-7 11, α(N+)=8.4E-6 5
1471.21	(7/2+,9/2+)		1471.35 20	(M1+E2)		4.43×10^-4	α=4.43×10^-4 10, α(K)=0.000331 13, α(L)=3.70E-5 13, α(M)=6.69E-6 23, α(N)=1.07E-6 4, α(O)=7.3E-8 3, α(N+)=6.8E-5 6
1518.39	(3/2-)	0.21 ps +22-8	938.18 20	(M1(+E2))		0.00098	α=0.00098 3, α(K)=0.00086 3, α(L)=9.82×10^-5 21, α(M)=1.78E-5 4, α(N)=2.83E-6 7, α(O)=1.90E-7 8, α(N+)=3.02E-6 7
1538.01	(11/2+,13/2+)		765.28 20	(M1+E2)		1.58×10^-3	α=1.58×10^-3 2, α(K)=0.001384 21, α(L)=0.000159 3, α(M)=2.88E-5 5, α(N)=4.57E-6 7, α(O)=3.04E-7 7, α(N+)=4.88E-6 8
1581.47	(11/2+,13/2+)		748.75 20	(M1+E2)		1.66×10^-3	α=1.66×10^-3, α(K)=0.001458 21, α(L)=0.000168 4, α(M)=3.03E-5 6, α(N)=4.82E-6 9, α(O)=3.20E-7 7, α(N+)=5.14E-6 9
1581.47	(11/2+,13/2+)		808.70 20	(M1+E2)		1.38×10^-3	α=1.38×10^-3 3, α(K)=0.001215 23, α(L)=0.0001391 20, α(M)=2.52E-5 4, α(N)=4.00E-6 6, α(O)=2.67E-7 8, α(N+)=4.27E-6 6
1585.8	(3/2+,5/2+,7/2+)		1261.3 3	(M1+E2)		5.32×10^-4	α=5.32×10^-4 18, α(K)=0.000454 18, α(L)=5.11E-5 17, α(M)=9.2E-6 3, α(N)=1.47E-6 6, α(O)=1.00E-7 5, α(N+)=1.78E-5 16
1654.48	17/2+		881.8 1	E2		1.11×10^-3	α=1.11×10^-3, α(K)=0.000973 14, α(L)=0.0001123 16, α(M)=2.03E-5 3, α(N)=3.22E-6 5, α(O)=2.11E-7 3, α(N+)=3.44E-6 5
1677.5	(5/2-)		1097.1 10	(M1+E2)		6.95×10^-4	α=6.95×10^-4 25, α(K)=0.000611 23, α(L)=6.90E-5 21, α(M)=1.25E-5 4, α(N)=1.99E-6 7, α(O)=1.34E-7 6, α(N+)=2.12E-6 7
1685.47	15/2(+)		852.7 1	E2		1.20×10^-3	α=1.20×10^-3, α(K)=0.001054 15, α(L)=0.0001220 17, α(M)=2.21E-5 3, α(N)=3.50E-6 5, α(O)=2.29E-7 4, α(N+)=3.73E-6 6
1685.47	15/2(+)		912.8 1	(M1+E2)		0.00105	α=0.00105 3, α(K)=0.00092 3, α(L)=0.0001046 20, α(M)=1.89×10^-5 4, α(N)=3.01E-6 7, α(O)=2.02E-7 8, α(N+)=3.21E-6 7
1690.04	(5/2+,7/2+)		1474.31 20	(M1+E2)		4.43×10^-4	α=4.43×10^-4 10, α(K)=0.000330 12, α(L)=3.69E-5 13, α(M)=6.67E-6 23, α(N)=1.06E-6 4, α(O)=7.2E-8 3, α(N+)=6.9E-5 6
1692.9	(3/2+,5/2,7/2)		1477.2 3	(M1+E2)		4.42×10^-4	α=4.42×10^-4 10, α(K)=0.000328 12, α(L)=3.67E-5 13, α(M)=6.64E-6 23, α(N)=1.06E-6 4, α(O)=7.2E-8 3, α(N+)=7.0E-5 6
1721.0	(1/2+,3/2+,5/2+)		726.3 3	(M1+E2)		0.00179	α=0.00179, α(K)=0.001569 23, α(L)=0.000181 5, α(M)=3.27×10^-5 8, α(N)=5.20E-6 11, α(O)=3.44E-7 7, α(N+)=5.54E-6 11
1722.61	(5/2+)		752.4 3	(M1+E2)		1.64×10^-3	α=1.64×10^-3 2, α(K)=0.001441 21, α(L)=0.000166 4, α(M)=3.00E-5 6, α(N)=4.77E-6 8, α(O)=3.16E-7 7, α(N+)=5.08E-6 9
1815.7	(9/2+)		1491.1 5	[E2]		4.33×10^-4	α=4.33×10^-4, α(K)=0.000311 5, α(L)=3.50E-5 5, α(M)=6.32E-6 9, α(N)=1.006E-6 15, α(O)=6.80E-8 10, α(N+)=8.09E-5 12
1815.7	(9/2+)		1600.2 6	(M1+E2)		4.32×10^-4	α=4.32×10^-4 7, α(K)=0.000280 10, α(L)=3.13E-5 10, α(M)=5.65E-6 19, α(N)=9.0E-7 3, α(O)=6.14E-8 24, α(N+)=0.000115 9
1834.75	(11/2+)		363.54 20	(M1+E2)		0.0114	α=0.0114 22, α(K)=0.0099 19, α(L)=0.0012 3, α(M)=0.00022 5, α(N)=3.5×10^-5 8, α(O)=2.1E-6 4, α(N+)=3.7E-5 8
E(level) (keV)	J^π(level)	T_1/2(level)	E(γ) (keV)	Multipolarity	Mixing Ratio	Conversion Coefficient	Additional Data
1834.81	(13/2-)		557.0 1	E2		0.00368	α=0.00368, α(K)=0.00322 5, α(L)=0.000386 6, α(M)=7.00×10^-5 10, α(N)=1.103E-5 16, α(O)=6.89E-7 10, α(N+)=1.172E-5 17
1834.81	(13/2-)		1062.0 2	[E1]		3.16×10^-4	α=3.16×10^-4, α(K)=0.000279 4, α(L)=3.10E-5 5, α(M)=5.58E-6 8, α(N)=8.90E-7 13, α(O)=6.02E-8 9, α(N+)=9.50E-7 14
1841.87			901.89 20	(M1+E2)		0.00107	α=0.00107 3, α(K)=0.00094 3, α(L)=0.0001075 20, α(M)=1.95×10^-5 4, α(N)=3.10E-6 7, α(O)=2.07E-7 8, α(N+)=3.30E-6 7
1849.79	(15/2+)		195.3 1	(M1(+E2))		0.0451	α=0.0451, α(K)=0.0395 6, α(L)=0.00465 7, α(M)=0.000844 12, α(N)=0.0001341 19, α(O)=8.90×10^-6 13, α(N+)=0.0001430 21
	(15/2+)		456.4 1	(M1+E2)		0.0060	α=0.0060 7, α(K)=0.0052 6, α(L)=0.00062 9, α(M)=0.000112 17, α(N)=1.78×10^-5 25, α(O)=1.13E-6 10, α(N+)=1.9E-5 3
	(15/2+)		1077.2 2	(M1+E2)		0.00072	α=0.00072 3, α(K)=0.000636 23, α(L)=7.19×10^-5 21, α(M)=1.30E-5 4, α(N)=2.07E-6 7, α(O)=1.40E-7 6, α(N+)=2.21E-6 7
1864.84	(9/2+)		1539.8 6	[E2]		4.30×10^-4	α=4.30×10^-4, α(K)=0.000292 4, α(L)=3.28E-5 5, α(M)=5.92E-6 9, α(N)=9.43E-7 14, α(O)=6.38E-8 9, α(N+)=9.92E-5 14
1879.39	(9/2+,17/2+)		1106.7 1	(E2)		6.60×10^-4	α=6.60×10^-4, α(K)=0.000579 9, α(L)=6.59E-5 10, α(M)=1.192E-5 17, α(N)=1.90E-6 3, α(O)=1.263E-7 18, α(N+)=2.76E-6 4
1892.61	(13/2+,15/2+)		1120.24 20	(M1+E2)		6.65×10^-4	α=6.65×10^-4 24, α(K)=0.000584 22, α(L)=6.59E-5 20, α(M)=1.19E-5 4, α(N)=1.90E-6 6, α(O)=1.28E-7 6, α(N+)=3.04E-6 8
1897.42	(5/2+,7/2+,9/2+)		1681.69 20	(M1+E2)		4.36×10^-4	α=4.36×10^-4 7, α(K)=0.000254 9, α(L)=2.83E-5 9, α(M)=5.11E-6 16, α(N)=8.2E-7 3, α(O)=5.57E-8 21, α(N+)=0.000148 11
1949.00	(9/2+)		1163.92 20	[E2]		5.94×10^-4	α=5.94×10^-4, α(K)=0.000519 8, α(L)=5.89E-5 9, α(M)=1.066E-5 15, α(N)=1.695E-6 24, α(O)=1.132E-7 16, α(N+)=5.46E-6 8
2121.79	(13/2+,15/2,17/2+)		467.3 1	(E2)		0.00616	α=0.00616, α(K)=0.00537 8, α(L)=0.000658 10, α(M)=0.0001193 17, α(N)=1.87×10^-5 3, α(O)=1.140E-6 16, α(N+)=1.99E-5 3
2331.39	(19/2+)		676.9 1	(M1+E2)		0.00212	α=0.00212 5, α(K)=0.00186 4, α(L)=0.000216 8, α(M)=3.90×10^-5 14, α(N)=6.19E-6 20, α(O)=4.08E-7 6, α(N+)=6.60E-6 20
2337.62	(17/2-)		487.8 1	(E1)		1.68×10^-3	α=1.68×10^-3, α(K)=0.001474 21, α(L)=0.0001664 24, α(M)=3.00E-5 5, α(N)=4.77E-6 7, α(O)=3.15E-7 5, α(N+)=5.08E-6 8
	(17/2-)		502.8 1	[E2]		0.00496	α=0.00496, α(K)=0.00432 6, α(L)=0.000525 8, α(M)=9.52×10^-5 14, α(N)=1.496E-5 21, α(O)=9.21E-7 13, α(N+)=1.589E-5 23
	(17/2-)		652.2 1	(E1)		8.55×10^-4	α=8.55×10^-4, α(K)=0.000753 11, α(L)=8.44E-5 12, α(M)=1.524E-5 22, α(N)=2.42E-6 4, α(O)=1.618E-7 23, α(N+)=2.58E-6 4
2533.78	(21/2+)		202.4 1	(M1+E2)		0.07	α=0.07 3, α(K)=0.060 25, α(L)=0.008 4, α(M)=0.0015 8, α(N)=0.00023 11, α(O)=1.2×10^-5 5, α(N+)=0.00024 12
2533.78	(21/2+)		879.3 1	E2		1.12×10^-3	α=1.12×10^-3, α(K)=0.000980 14, α(L)=0.0001131 16, α(M)=2.05E-5 3, α(N)=3.25E-6 5, α(O)=2.13E-7 3, α(N+)=3.46E-6 5
2733.80	(21/2+)		1079.3 1	E2		6.97×10^-4	α=6.97×10^-4, α(K)=0.000612 9, α(L)=6.98E-5 10, α(M)=1.262E-5 18, α(N)=2.01E-6 3, α(O)=1.334E-7 19, α(N+)=2.14E-6 3
3143.24	(21/2-)		609.5 2	[E1]		9.95×10^-4	α=9.95×10^-4, α(K)=0.000876 13, α(L)=9.84E-5 14, α(M)=1.776E-5 25, α(N)=2.82E-6 4, α(O)=1.88E-7 3, α(N+)=3.01E-6 5
3143.24	(21/2-)		805.6 1	E2		1.38×10^-3	α=1.38×10^-3, α(K)=0.001211 17, α(L)=0.0001407 20, α(M)=2.55E-5 4, α(N)=4.04E-6 6, α(O)=2.63E-7 4, α(N+)=4.30E-6 6
3530.19	(25/2+)		996.4 1	(E2)		8.34×10^-4	α=8.34×10^-4, α(K)=0.000732 11, α(L)=8.39E-5 12, α(M)=1.517E-5 22, α(N)=2.41E-6 4, α(O)=1.594E-7 23, α(N+)=2.57E-6 4
3575.59	(23/2+)		841.8 2	(M1+E2)		0.00126	α=0.00126 3, α(K)=0.001106 24, α(L)=0.0001264 19, α(M)=2.29×10^-5 4, α(N)=3.64E-6 6, α(O)=2.43E-7 8, α(N+)=3.88E-6 7
3575.59	(23/2+)		1041.8 1	(M1)		8.01×10^-4	α=8.01×10^-4, α(K)=0.000705 10, α(L)=7.92E-5 11, α(M)=1.433E-5 20, α(N)=2.29E-6 4, α(O)=1.562E-7 22, α(N+)=2.44E-6 4
3643.68	(25/2+)		1109.9 2	(E2)		6.56×10^-4	α=6.56×10^-4, α(K)=0.000576 8, α(L)=6.55E-5 10, α(M)=1.185E-5 17, α(N)=1.88E-6 3, α(O)=1.255E-7 18, α(N+)=2.83E-6 4
E(level) (keV)	J^π(level)	T_1/2(level)	E(γ) (keV)	Multipolarity	Mixing Ratio	Conversion Coefficient	Additional Data
3731.09	(25/2+)		155.5 1	(M1+E2)		0.17	α=0.17 9, α(K)=0.14 7, α(L)=0.021 13, α(M)=0.0039 24, α(N)=0.0006 4, α(O)=2.9×10^-5 13, α(N+)=0.0006 4
4334.0	(27/2+)		803.8 3	(M1+E2)		1.40×10^-3	α=1.40×10^-3 2, α(K)=0.001232 23, α(L)=0.0001412 21, α(M)=2.55E-5 4, α(N)=4.06E-6 6, α(O)=2.70E-7 8, α(N+)=4.33E-6 7
4376.1	(27/2+)		645.0 3	(M1+E2)		0.00240	α=0.00240 7, α(K)=0.00210 6, α(L)=0.000244 11, α(M)=4.41×10^-5 20, α(N)=7.0E-6 3, α(O)=4.60E-7 7, α(N+)=7.5E-6 3
4430.1	(29/2+)		96.0	(M1+E2)		0.9	α=0.9 6, α(K)=0.7 5, α(L)=0.14 11, α(M)=0.026 20, α(N)=0.004 3, α(O)=0.00013 8, α(N+)=0.004 3
	(29/2+)		786.9	(E2)		1.46×10^-3	α=1.46×10^-3, α(K)=0.001284 18, α(L)=0.0001494 21, α(M)=2.70E-5 4, α(N)=4.28E-6 6, α(O)=2.78E-7 4, α(N+)=4.56E-6 7
	(29/2+)		899.7	(E2)		1.06×10^-3	α=1.06×10^-3, α(K)=0.000928 13, α(L)=0.0001069 15, α(M)=1.94E-5 3, α(N)=3.07E-6 5, α(O)=2.02E-7 3, α(N+)=3.27E-6 5
4681.0	(29/2+)		304.8	(M1+E2)		0.019	α=0.019 5, α(K)=0.017 5, α(L)=0.0021 7, α(M)=0.00038 12, α(N)=6.0×10^-5 18, α(O)=3.6E-6 8, α(N+)=6.3E-5 19
4681.0	(29/2+)		950.0	(E2)		9.31×10^-4	α=9.31×10^-4, α(K)=0.000817 12, α(L)=9.38E-5 14, α(M)=1.697E-5 24, α(N)=2.69E-6 4, α(O)=1.777E-7 25, α(N+)=2.87E-6 4
5051.4	(29/2+)		1407.5	(E2)		4.50×10^-4	α=4.50×10^-4, α(K)=0.000349 5, α(L)=3.93E-5 6, α(M)=7.11E-6 10, α(N)=1.132E-6 16, α(O)=7.63E-8 11, α(N+)=5.39E-5 8
5322.7	(31/2+)		641.6	(M1(+E2))		0.00243	α=0.00243 7, α(K)=0.00213 6, α(L)=0.000247 12, α(M)=4.47×10^-5 21, α(N)=7.1E-6 3, α(O)=4.66E-7 8, α(N+)=7.6E-6 3
5461.2	(31/2+)		409.7	(M1+E2)		0.0080	α=0.0080 12, α(K)=0.0070 10, α(L)=0.00085 16, α(M)=0.00015 3, α(N)=2.4×10^-5 5, α(O)=1.52E-6 18, α(N+)=2.6E-5 5
5461.2	(31/2+)		1031.3	(M1+E2)		0.00080	α=0.00080 3, α(K)=0.000699 24, α(L)=7.92×10^-5 21, α(M)=1.43E-5 4, α(N)=2.28E-6 7, α(O)=1.54E-7 7, α(N+)=2.43E-6 8
5535.8	(33/2+)		213.1	(M1(+E2))		0.059	α=0.059 24, α(K)=0.051 20, α(L)=0.007 4, α(M)=0.0013 6, α(N)=0.00019 9, α(O)=1.1×10^-5 4, α(N+)=0.00020 10
5535.8	(33/2+)		854.7	(E2)		1.20×10^-3	α=1.20×10^-3, α(K)=0.001048 15, α(L)=0.0001213 17, α(M)=2.20E-5 3, α(N)=3.48E-6 5, α(O)=2.28E-7 4, α(N+)=3.71E-6 6
5587.3	(33/2+)		126.1	(M1+E2)		0.34	α=0.34 20, α(K)=0.29 16, α(L)=0.05 4, α(M)=0.009 6, α(N)=0.0013 9, α(O)=6.E-5 3, α(N+)=0.0014 9
7016.6	(37/2+)		1480.8	(E2)		4.35×10^-4	α=4.35×10^-4, α(K)=0.000316 5, α(L)=3.54E-5 5, α(M)=6.40E-6 9, α(N)=1.020E-6 15, α(O)=6.89E-8 10, α(N+)=7.73E-5 11
7714.0	(39/2+)		697.4	(M1+E2)		0.00197	α=0.00197 4, α(K)=0.00173 3, α(L)=0.000200 6, α(M)=3.62×10^-5 11, α(N)=5.75E-6 16, α(O)=3.79E-7 6, α(N+)=6.13E-6 16
8345.1	(43/2+)		631.1	(E2)		0.00260	α=0.00260, α(K)=0.00228 4, α(L)=0.000270 4, α(M)=4.89×10^-5 7, α(N)=7.72E-6 11, α(O)=4.90E-7 7, α(N+)=8.21E-6 12

Q(β-)=-1100 keV 5	S(n)= 9470 keV 7	S(p)= 5714 keV 4	Q(α)= -2431 keV 5
Reference: 2012WA38

References:
A	⁹⁷Ru ε decay	B	⁹⁷Tc IT decay
C	⁸²Se(¹⁹F,4nγ)	D	⁹⁴Zr(⁶Li,3nγ)
E	⁹⁶Mo(p,γ) E=RES: AV	F	⁹⁶Mo(p,p’) IAR
G	⁹⁶Mo(³He,d),(d,n)	H	⁹⁶Mo(³He,pnγ)
I	⁹⁷Mo(p,n)	J	⁹⁷Mo(p,nγ)

E(level)	E(gamma)	Comments
96.57	96.5	M(γ): from α(exp) ratios in 96.5-keV IT decay
324.476	108.79	M(γ): Also from α(K)exp or α ratios in ⁹⁷Ru ε decay
324.476	324.48	M(γ): from α(K)exp in ⁹⁷Ru ε decay and (p,γ) res; γ(θ) in (p,nγ)
580.19	483.62	M(γ): transition between L=1 states
777.98	777.90	E(γ): From ⁹⁶Mo(³He,pnγ) M(γ): ΔJ=0,1 transition. From γ(θ), excitation function, and DCO in ⁹⁶Mo(³He,pnγ) (when available). Because of the light projectile, the A₂ coefficients (A₄’s are not given) are smaller than the typical values, particularly for small spins, which makes the assignments weak. Unless noted otherwise, the transitions are assumed to Be stretched
785.034	460.57	M(γ): also from (⁶Li,3nγ), (p,nγ). Also from α(K)exp or α ratios in ⁹⁷Ru ε decay
	569.31	M(γ): Also from α(K)exp or α ratios in ⁹⁷Ru ε decay
	785.06	M(γ): M1,E2 γ from α data in ⁹⁷Ru ε decay
855.45	855.53	M(γ): Also from α(K)exp or α ratios in ⁹⁷Ru ε decay
939.88	615.52	E(γ): From ⁹⁶Mo(³He,pnγ) I(γ): From ⁹⁶Mo(³He,pnγ)
939.88	843.27	E(γ): From ⁹⁶Mo(³He,pnγ) I(γ): From ⁹⁶Mo(³He,pnγ)
946.73	290.0	M(γ): d from RUL, Δπ=no from level scheme
	366.6	M(γ): d from RUL, Δπ=no from level scheme
	622.4	M(γ): d,E2 from RUL, Δπ=yes from level scheme
	850.10	M(γ): transition between L=1 levels
970.03	645.27	M(γ): Also from α(K)exp or α ratios in ⁹⁷Ru ε decay
970.03	754.01	M(γ): Also from α(K)exp or α ratios in ⁹⁷Ru ε decay
994.68	670.21	M(γ): From γ(θ), excitation function, and DCO in ⁹⁶Mo(³He,pnγ) (when available). Because of the light projectile, the A₂ coefficients (A₄’s are not given) are smaller than the typical values, particularly for small spins, which makes the assignments weak. Unless noted otherwise, the transitions are assumed to Be stretched
1049.22	392.2	M(γ): d from γ(θ) in (p,nγ), Δπ=no from level scheme
1049.22	469.2	M(γ): d from γ(θ) in (p,nγ), Δπ=no from level scheme
1126.64	910.92	M(γ): From γ(θ) in (⁶Li,3nγ)
1199.62	366.92	E(γ): From ⁹⁶Mo(³He,pnγ) I(γ): From ⁹⁶Mo(³He,pnγ)
	421.56	E(γ): From ⁹⁶Mo(³He,pnγ) I(γ): From ⁹⁶Mo(³He,pnγ)
	875.18	E(γ): From ⁹⁶Mo(³He,pnγ) I(γ): From ⁹⁶Mo(³He,pnγ)
	983.81	E(γ): From ⁹⁶Mo(³He,pnγ) I(γ): From ⁹⁶Mo(³He,pnγ)
E(level)	E(gamma)	Comments
1219.87	1004.2	M(γ): From γ(θ), excitation function, and DCO in ⁹⁶Mo(³He,pnγ) (when available). Because of the light projectile, the A₂ coefficients (A₄’s are not given) are smaller than the typical values, particularly for small spins, which makes the assignments weak. Unless noted otherwise, the transitions are assumed to Be stretched
1219.87	1219.8	M(γ): From γ(θ), excitation function, and DCO in ⁹⁶Mo(³He,pnγ) (when available). Because of the light projectile, the A₂ coefficients (A₄’s are not given) are smaller than the typical values, particularly for small spins, which makes the assignments weak. Unless noted otherwise, the transitions are assumed to Be stretched
1240.02	659.6	M(γ): (M1⁺E2) in ⁹⁶Mo(³He,pnγ)
1240.02	915.7	M(γ): d from γ(θ) in (p,nγ), Δπ=yes from level scheme
1274.54	617.60	E(γ): From ⁹⁶Mo(³He,pnγ) I(γ): From ⁹⁶Mo(³He,pnγ) M(γ): From γ(θ), excitation function, and DCO in ⁹⁶Mo(³He,pnγ) (when available). Because of the light projectile, the A₂ coefficients (A₄’s are not given) are smaller than the typical values, particularly for small spins, which makes the assignments weak. Unless noted otherwise, the transitions are assumed to Be stretched
	694.45	E(γ): From ⁹⁶Mo(³He,pnγ) I(γ): From ⁹⁶Mo(³He,pnγ) M(γ): From γ(θ), excitation function, and DCO in ⁹⁶Mo(³He,pnγ) (when available). Because of the light projectile, the A₂ coefficients (A₄’s are not given) are smaller than the typical values, particularly for small spins, which makes the assignments weak. Unless noted otherwise, the transitions are assumed to Be stretched
	949.9	E(γ): From ⁹⁶Mo(³He,pnγ) I(γ): From ⁹⁶Mo(³He,pnγ)
1277.82	422.47	M(γ): Δπ=yes from level scheme, therefore, E1(+M2) transition
1277.82	620.88	M(γ): Q from γ(θ) in (p,nγ), Δπ=no from level scheme
1310.17	1310.0	M(γ): L=4 to L=4 transition
1311.87	1096.15	E(γ): From ⁹⁶Mo(³He,pnγ) I(γ): From ⁹⁶Mo(³He,pnγ)
1373.32	426.41	E(γ): From ⁹⁶Mo(³He,pnγ) I(γ): From ⁹⁶Mo(³He,pnγ)
	716.8	E(γ): From ⁹⁶Mo(³He,pnγ) I(γ): From ⁹⁶Mo(³He,pnγ)
	1049.0	E(γ): From ⁹⁶Mo(³He,pnγ) I(γ): From ⁹⁶Mo(³He,pnγ)
	1276.68	E(γ): From ⁹⁶Mo(³He,pnγ) I(γ): From ⁹⁶Mo(³He,pnγ) M(γ): From γ(θ), excitation function, and DCO in ⁹⁶Mo(³He,pnγ) (when available). Because of the light projectile, the A₂ coefficients (A₄’s are not given) are smaller than the typical values, particularly for small spins, which makes the assignments weak. Unless noted otherwise, the transitions are assumed to Be stretched
1393.33	531.23	E(γ): From ⁹⁶Mo(³He,pnγ) I(γ): From ⁹⁶Mo(³He,pnγ)
	560.48	E(γ): From ⁹⁶Mo(³He,pnγ) I(γ): From ⁹⁶Mo(³He,pnγ) M(γ): From γ(θ) and DCO (when available) in ⁸²Se(¹⁹F,4nγ). Unless noted otherwise, the transitions are assumed to Be stretched
	620.63	E(γ): From ⁹⁶Mo(³He,pnγ) I(γ): From ⁹⁶Mo(³He,pnγ) M(γ): ΔJ=0 transition. From γ(θ) and DCO (when available) in ⁸²Se(¹⁹F,4nγ). Unless noted otherwise, the transitions are assumed to Be stretched
	1393.33	E(γ): From ⁹⁶Mo(³He,pnγ) I(γ): From ⁹⁶Mo(³He,pnγ) M(γ): From γ(θ) and DCO (when available) in ⁸²Se(¹⁹F,4nγ). Unless noted otherwise, the transitions are assumed to Be stretched
1400.99	820.79	E(γ): From ⁹⁶Mo(³He,pnγ) M(γ): ΔJ=0,1 transition. From γ(θ), excitation function, and DCO in ⁹⁶Mo(³He,pnγ) (when available). Because of the light projectile, the A₂ coefficients (A₄’s are not given) are smaller than the typical values, particularly for small spins, which makes the assignments weak. Unless noted otherwise, the transitions are assumed to Be stretched
1409.5	1084.9	M(γ): (M1⁺E2) in ⁹⁶Mo(³He,pnγ)
1409.5	1193.8	M(γ): (M1⁺E2) in ⁹⁶Mo(³He,pnγ)
1471.21	609.18	E(γ): From ⁹⁶Mo(³He,pnγ) I(γ): From ⁹⁶Mo(³He,pnγ)
	615.66	E(γ): From ⁹⁶Mo(³He,pnγ) I(γ): From ⁹⁶Mo(³He,pnγ) M(γ): From γ(θ), excitation function, and DCO in ⁹⁶Mo(³He,pnγ) (when available). Because of the light projectile, the A₂ coefficients (A₄’s are not given) are smaller than the typical values, particularly for small spins, which makes the assignments weak. Unless noted otherwise, the transitions are assumed to Be stretched
	1471.35	E(γ): From ⁹⁶Mo(³He,pnγ) I(γ): From ⁹⁶Mo(³He,pnγ) M(γ): ΔJ=0,1 transition. From γ(θ), excitation function, and DCO in ⁹⁶Mo(³He,pnγ) (when available). Because of the light projectile, the A₂ coefficients (A₄’s are not given) are smaller than the typical values, particularly for small spins, which makes the assignments weak. Unless noted otherwise, the transitions are assumed to Be stretched
E(level)	E(gamma)	Comments
1512.32	855.45	M(γ): Deduced from RUL
	932.8	M(γ): Deduced from RUL
	1188.0	M(γ): Deduced from RUL
	1295.8	E(γ): From ⁹⁶Mo(³He,pnγ)
1518.39	938.18	E(γ): From ⁹⁶Mo(³He,pnγ) I(γ): From ⁹⁶Mo(³He,pnγ) M(γ): From γ(θ), excitation function, and DCO in ⁹⁶Mo(³He,pnγ) (when available). Because of the light projectile, the A₂ coefficients (A₄’s are not given) are smaller than the typical values, particularly for small spins, which makes the assignments weak. Unless noted otherwise, the transitions are assumed to Be stretched
	1194.2	E(γ): From ⁹⁶Mo(³He,pnγ) I(γ): From ⁹⁶Mo(³He,pnγ)
	1421.69	E(γ): From ⁹⁶Mo(³He,pnγ) I(γ): From ⁹⁶Mo(³He,pnγ)
1523.1	1198.7	M(γ): Deduced from RUL
	1307.2	M(γ): Deduced from RUL
	1523.5	M(γ): Deduced from RUL
1527.3	1202.8	E(γ): From ⁹⁶Mo(³He,pnγ)
1538.01	765.28	E(γ): From ⁹⁶Mo(³He,pnγ) I(γ): From ⁹⁶Mo(³He,pnγ) M(γ): From γ(θ), excitation function, and DCO in ⁹⁶Mo(³He,pnγ) (when available). Because of the light projectile, the A₂ coefficients (A₄’s are not given) are smaller than the typical values, particularly for small spins, which makes the assignments weak. Unless noted otherwise, the transitions are assumed to Be stretched
1538.01	1538.1	E(γ): From ⁹⁶Mo(³He,pnγ) I(γ): From ⁹⁶Mo(³He,pnγ)
1580.0	1000.0	M(γ): From γ(θ), excitation function, and DCO in ⁹⁶Mo(³He,pnγ) (when available). Because of the light projectile, the A₂ coefficients (A₄’s are not given) are smaller than the typical values, particularly for small spins, which makes the assignments weak. Unless noted otherwise, the transitions are assumed to Be stretched
1581.47	748.75	E(γ): From ⁹⁶Mo(³He,pnγ) I(γ): From ⁹⁶Mo(³He,pnγ) M(γ): From γ(θ), excitation function, and DCO in ⁹⁶Mo(³He,pnγ) (when available). Because of the light projectile, the A₂ coefficients (A₄’s are not given) are smaller than the typical values, particularly for small spins, which makes the assignments weak. Unless noted otherwise, the transitions are assumed to Be stretched
1581.47	808.70	E(γ): From ⁹⁶Mo(³He,pnγ) I(γ): From ⁹⁶Mo(³He,pnγ) M(γ): From γ(θ), excitation function, and DCO in ⁹⁶Mo(³He,pnγ) (when available). Because of the light projectile, the A₂ coefficients (A₄’s are not given) are smaller than the typical values, particularly for small spins, which makes the assignments weak. Unless noted otherwise, the transitions are assumed to Be stretched
1582.20	925.16	E(γ): From ⁹⁶Mo(³He,pnγ) I(γ): From ⁹⁶Mo(³He,pnγ)
	1257.96	E(γ): From ⁹⁶Mo(³He,pnγ) I(γ): From ⁹⁶Mo(³He,pnγ)
	1366.2	E(γ): From ⁹⁶Mo(³He,pnγ) I(γ): From ⁹⁶Mo(³He,pnγ)
1585.8	1261.3	E(γ): From ⁹⁶Mo(³He,pnγ) I(γ): From ⁹⁶Mo(³He,pnγ) M(γ): From γ(θ), excitation function, and DCO in ⁹⁶Mo(³He,pnγ) (when available). Because of the light projectile, the A₂ coefficients (A₄’s are not given) are smaller than the typical values, particularly for small spins, which makes the assignments weak. Unless noted otherwise, the transitions are assumed to Be stretched
1625.26	483.79	E(γ): From ⁹⁶Mo(³He,pnγ) I(γ): From ⁹⁶Mo(³He,pnγ)
1625.26	685.61	E(γ): From ⁹⁶Mo(³He,pnγ) I(γ): From ⁹⁶Mo(³He,pnγ)
1649.63	679.9	M(γ): Deduced from RUL
	793.7	M(γ): Deduced from RUL
	1324.9	M(γ): Deduced from RUL
E(level)	E(gamma)	Comments
1654.48	881.8	M(γ): From γ(θ) in (⁶Li,3nγ)
1677.5	1020.6	E(γ): From ⁹⁶Mo(³He,pnγ) I(γ): From ⁹⁶Mo(³He,pnγ)
1677.5	1097.1	M(γ): ΔJ=0,1 transition. From γ(θ), excitation function, and DCO in ⁹⁶Mo(³He,pnγ) (when available). Because of the light projectile, the A₂ coefficients (A₄’s are not given) are smaller than the typical values, particularly for small spins, which makes the assignments weak. Unless noted otherwise, the transitions are assumed to Be stretched
1685.47	852.7	M(γ): From γ(θ) in (⁶Li,3nγ)
1685.47	912.8	M(γ): From γ(θ) and DCO (when available) in ⁸²Se(¹⁹F,4nγ). Unless noted otherwise, the transitions are assumed to Be stretched
1690.04	1474.31	E(γ): From ⁹⁶Mo(³He,pnγ) M(γ): ΔJ=0,1 transition. From γ(θ), excitation function, and DCO in ⁹⁶Mo(³He,pnγ) (when available). Because of the light projectile, the A₂ coefficients (A₄’s are not given) are smaller than the typical values, particularly for small spins, which makes the assignments weak. Unless noted otherwise, the transitions are assumed to Be stretched
1692.9	1477.2	M(γ): From γ(θ), excitation function, and DCO in ⁹⁶Mo(³He,pnγ) (when available). Because of the light projectile, the A₂ coefficients (A₄’s are not given) are smaller than the typical values, particularly for small spins, which makes the assignments weak. Unless noted otherwise, the transitions are assumed to Be stretched
1697.8	1482.1	E(γ): From ⁹⁶Mo(³He,pnγ)
1706.95	429.13	E(γ): From ⁹⁶Mo(³He,pnγ)
1707.7	922.7	M(γ): Deduced from RUL
	1383.0	M(γ): Deduced from RUL
	1492.2	M(γ): Deduced from RUL
1721.0	726.3	E(γ): From ⁹⁶Mo(³He,pnγ) M(γ): ΔJ=0,1 transition. From γ(θ), excitation function, and DCO in ⁹⁶Mo(³He,pnγ) (when available). Because of the light projectile, the A₂ coefficients (A₄’s are not given) are smaller than the typical values, particularly for small spins, which makes the assignments weak. Unless noted otherwise, the transitions are assumed to Be stretched
1722.61	728.1	E(γ): From ⁹⁶Mo(³He,pnγ) I(γ): From ⁹⁶Mo(³He,pnγ)
1722.61	752.4	E(γ): From ⁹⁶Mo(³He,pnγ) I(γ): From ⁹⁶Mo(³He,pnγ) M(γ): ΔJ=0,1 transition. From γ(θ), excitation function, and DCO in ⁹⁶Mo(³He,pnγ) (when available). Because of the light projectile, the A₂ coefficients (A₄’s are not given) are smaller than the typical values, particularly for small spins, which makes the assignments weak. Unless noted otherwise, the transitions are assumed to Be stretched
1801.29	1476.80	E(γ): From ⁹⁶Mo(³He,pnγ)
1815.7	1600.2	M(γ): D+Q from γ(θ) in (p,nγ), Δπ=no from level scheme
1834.75	363.54	E(γ): From ⁹⁶Mo(³He,pnγ) M(γ): From γ(θ), excitation function, and DCO in ⁹⁶Mo(³He,pnγ) (when available). Because of the light projectile, the A₂ coefficients (A₄’s are not given) are smaller than the typical values, particularly for small spins, which makes the assignments weak. Unless noted otherwise, the transitions are assumed to Be stretched
1834.81	557.0	M(γ): From γ(θ) in (⁶Li,3nγ)
1841.87	847.4	E(γ): From ⁹⁶Mo(³He,pnγ) I(γ): From ⁹⁶Mo(³He,pnγ)
1841.87	901.89	E(γ): From ⁹⁶Mo(³He,pnγ) I(γ): From ⁹⁶Mo(³He,pnγ) M(γ): From γ(θ), excitation function, and DCO in ⁹⁶Mo(³He,pnγ) (when available). Because of the light projectile, the A₂ coefficients (A₄’s are not given) are smaller than the typical values, particularly for small spins, which makes the assignments weak. Unless noted otherwise, the transitions are assumed to Be stretched
1849.79	195.3	M(γ): (d) from ⁹⁴Zr(⁶Li,3nγ) dataset, Δπ=no from level scheme; (M1⁺E2) from ⁸²Se(¹⁹F,4nγ) dataset
	456.4	M(γ): ΔJ=1 from γ(θ) in (⁶Li,3nγ), Δπ=no from level scheme. From γ(θ) and DCO (when available) in ⁸²Se(¹⁹F,4nγ). Unless noted otherwise, the transitions are assumed to Be stretched
	1077.2	M(γ): From γ(θ) and DCO (when available) in ⁸²Se(¹⁹F,4nγ). Unless noted otherwise, the transitions are assumed to Be stretched
1858.61	1201.70	E(γ): From ⁹⁶Mo(³He,pnγ)
E(level)	E(gamma)	Comments
1862.36	1537.87	E(γ): From ⁹⁶Mo(³He,pnγ)
1864.84	1009.6	I(γ): From ⁹⁶Mo(³He,pnγ)
1879.39	1106.7	E(γ): From ⁹⁶Mo(³He,pnγ) M(γ): From γ(θ), excitation function, and DCO in ⁹⁶Mo(³He,pnγ) (when available). Because of the light projectile, the A₂ coefficients (A₄’s are not given) are smaller than the typical values, particularly for small spins, which makes the assignments weak. Unless noted otherwise, the transitions are assumed to Be stretched
1892.61	765.64	E(γ): From ⁹⁶Mo(³He,pnγ) I(γ): From ⁹⁶Mo(³He,pnγ)
1892.61	1120.24	E(γ): From ⁹⁶Mo(³He,pnγ) I(γ): From ⁹⁶Mo(³He,pnγ) M(γ): ΔJ=0,1 transition. From γ(θ), excitation function, and DCO in ⁹⁶Mo(³He,pnγ) (when available). Because of the light projectile, the A₂ coefficients (A₄’s are not given) are smaller than the typical values, particularly for small spins, which makes the assignments weak. Unless noted otherwise, the transitions are assumed to Be stretched
1897.42	1681.69	M(γ): ΔJ=0,1 transition. From γ(θ), excitation function, and DCO in ⁹⁶Mo(³He,pnγ) (when available). Because of the light projectile, the A₂ coefficients (A₄’s are not given) are smaller than the typical values, particularly for small spins, which makes the assignments weak. Unless noted otherwise, the transitions are assumed to Be stretched
1947.59	1623.10	E(γ): From ⁹⁶Mo(³He,pnγ)
1949.00	1093.69	E(γ): From ⁹⁶Mo(³He,pnγ) I(γ): From ⁹⁶Mo(³He,pnγ)
1949.00	1163.92	E(γ): From ⁹⁶Mo(³He,pnγ) I(γ): From ⁹⁶Mo(³He,pnγ)
1964.46	1024.51	E(γ): From ⁹⁶Mo(³He,pnγ) I(γ): From ⁹⁶Mo(³He,pnγ)
1964.46	1640.1	E(γ): From ⁹⁶Mo(³He,pnγ) I(γ): From ⁹⁶Mo(³He,pnγ)
1976.63	698.81	E(γ): From ⁹⁶Mo(³He,pnγ)
1979.3	1146.5	E(γ): From ⁹⁶Mo(³He,pnγ)
1992.6	714.8	E(γ): From ⁹⁶Mo(³He,pnγ)
2004.21	1009.52	E(γ): From ⁹⁶Mo(³He,pnγ)
2033.04	1171.13	E(γ): From ⁹⁶Mo(³He,pnγ)
2048.47	1053.78	E(γ): From ⁹⁶Mo(³He,pnγ)
2054.90	400.41	E(γ): From ⁹⁶Mo(³He,pnγ)
2056.1	1283.4	E(γ): From ⁹⁶Mo(³He,pnγ)
2095.87	1101.4	E(γ): From ⁹⁶Mo(³He,pnγ) I(γ): From ⁹⁶Mo(³He,pnγ)
2095.87	1240.2	E(γ): From ⁹⁶Mo(³He,pnγ) I(γ): From ⁹⁶Mo(³He,pnγ)
2098.0	823.5	E(γ): From ⁹⁶Mo(³He,pnγ)
2117.56	1255.9	E(γ): From ⁹⁶Mo(³He,pnγ) I(γ): From ⁹⁶Mo(³He,pnγ)
2117.56	1537.1	E(γ): From ⁹⁶Mo(³He,pnγ) I(γ): From ⁹⁶Mo(³He,pnγ)
2119.72	1539.51	E(γ): From ⁹⁶Mo(³He,pnγ)
E(level)	E(gamma)	Comments
2121.79	467.3	M(γ): From γ(θ) in (⁶Li,3nγ)
2130.8	1160.8	E(γ): From ⁹⁶Mo(³He,pnγ)
2134.8	1362.1	E(γ): From ⁹⁶Mo(³He,pnγ)
2257.3	1677.1	E(γ): From ⁹⁶Mo(³He,pnγ)
2257.88	980.05	E(γ): From ⁹⁶Mo(³He,pnγ)
2264.60	1294.56	E(γ): From ⁹⁶Mo(³He,pnγ)
2331.39	676.9	M(γ): From γ(θ) and DCO (when available) in ⁸²Se(¹⁹F,4nγ). Unless noted otherwise, the transitions are assumed to Be stretched
2337.62	487.8	M(γ): ΔJ=1 from γ(θ) (⁶Li,3nγ); Δπ=yes from level scheme
2337.62	652.2	M(γ): d from γ(θ) in (⁶Li,3nγ); Δπ=yes from level scheme
2417.5	1143.0	E(γ): From ⁹⁶Mo(³He,pnγ)
2446.8	612.0	E(γ): From ⁹⁶Mo(³He,pnγ)
2449.2	911.2	E(γ): From ⁹⁶Mo(³He,pnγ)
2533.78	202.4	M(γ): From γ(θ) and DCO (when available) in ⁸²Se(¹⁹F,4nγ). Unless noted otherwise, the transitions are assumed to Be stretched
2533.78	879.3	M(γ): From γ(θ) in (⁶Li,3nγ)
2564.71	227.1	M(γ): From γ(θ) in (⁶Li,3nγ)
2733.80	169.1	M(γ): From γ(θ) in (⁶Li,3nγ)
2733.80	1079.3	M(γ): From γ(θ) in (⁶Li,3nγ)
3143.24	805.6	M(γ): From γ(θ) in (⁶Li,3nγ)
3530.19	996.4	M(γ): From γ(θ) and DCO (when available) in ⁸²Se(¹⁹F,4nγ). Unless noted otherwise, the transitions are assumed to Be stretched
3575.59	841.8	M(γ): From γ(θ) and DCO (when available) in ⁸²Se(¹⁹F,4nγ). Unless noted otherwise, the transitions are assumed to Be stretched
3575.59	1041.8	M(γ): d from γ(θ) in (⁶Li,3nγ), Δπ=no from level scheme
3643.68	1109.9	M(γ): From γ(θ) and DCO (when available) in ⁸²Se(¹⁹F,4nγ). Unless noted otherwise, the transitions are assumed to Be stretched
3731.09	155.5	M(γ): From γ(θ) and DCO (when available) in ⁸²Se(¹⁹F,4nγ). Unless noted otherwise, the transitions are assumed to Be stretched
4334.0	803.8	M(γ): From γ(θ) and DCO (when available) in ⁸²Se(¹⁹F,4nγ). Unless noted otherwise, the transitions are assumed to Be stretched
4376.1	645.0	M(γ): From γ(θ) and DCO (when available) in ⁸²Se(¹⁹F,4nγ). Unless noted otherwise, the transitions are assumed to Be stretched
E(level)	E(gamma)	Comments
4430.1	96.0	E(γ): From ⁸²Se(¹⁹F,4nγ) I(γ): From ⁸²Se(¹⁹F,4nγ) M(γ): From γ(θ) and DCO (when available) in ⁸²Se(¹⁹F,4nγ). Unless noted otherwise, the transitions are assumed to Be stretched
	786.9	E(γ): From ⁸²Se(¹⁹F,4nγ) I(γ): From ⁸²Se(¹⁹F,4nγ) M(γ): From γ(θ) and DCO (when available) in ⁸²Se(¹⁹F,4nγ). Unless noted otherwise, the transitions are assumed to Be stretched
	899.7	E(γ): From ⁸²Se(¹⁹F,4nγ) I(γ): From ⁸²Se(¹⁹F,4nγ) M(γ): From γ(θ) and DCO (when available) in ⁸²Se(¹⁹F,4nγ). Unless noted otherwise, the transitions are assumed to Be stretched
4681.0	304.8	E(γ): From ⁸²Se(¹⁹F,4nγ) I(γ): From ⁸²Se(¹⁹F,4nγ) M(γ): From γ(θ) and DCO (when available) in ⁸²Se(¹⁹F,4nγ). Unless noted otherwise, the transitions are assumed to Be stretched
4681.0	950.0	E(γ): From ⁸²Se(¹⁹F,4nγ) I(γ): From ⁸²Se(¹⁹F,4nγ) M(γ): From γ(θ) and DCO (when available) in ⁸²Se(¹⁹F,4nγ). Unless noted otherwise, the transitions are assumed to Be stretched
5051.4	1407.5	E(γ): From ⁸²Se(¹⁹F,4nγ) M(γ): From γ(θ) and DCO (when available) in ⁸²Se(¹⁹F,4nγ). Unless noted otherwise, the transitions are assumed to Be stretched
5322.7	641.6	E(γ): From ⁸²Se(¹⁹F,4nγ) I(γ): From ⁸²Se(¹⁹F,4nγ) M(γ): From γ(θ) and DCO (when available) in ⁸²Se(¹⁹F,4nγ). Unless noted otherwise, the transitions are assumed to Be stretched
5322.7	946.7	E(γ): From ⁸²Se(¹⁹F,4nγ) I(γ): From ⁸²Se(¹⁹F,4nγ) M(γ): From γ(θ) and DCO (when available) in ⁸²Se(¹⁹F,4nγ). Unless noted otherwise, the transitions are assumed to Be stretched
5461.2	409.7	E(γ): From ⁸²Se(¹⁹F,4nγ) I(γ): From ⁸²Se(¹⁹F,4nγ) M(γ): From γ(θ) and DCO (when available) in ⁸²Se(¹⁹F,4nγ). Unless noted otherwise, the transitions are assumed to Be stretched
5461.2	1031.3	E(γ): From ⁸²Se(¹⁹F,4nγ) I(γ): From ⁸²Se(¹⁹F,4nγ) M(γ): From γ(θ) and DCO (when available) in ⁸²Se(¹⁹F,4nγ). Unless noted otherwise, the transitions are assumed to Be stretched
5535.8	213.1	E(γ): From ⁸²Se(¹⁹F,4nγ) I(γ): From ⁸²Se(¹⁹F,4nγ) M(γ): From γ(θ) and DCO (when available) in ⁸²Se(¹⁹F,4nγ). Unless noted otherwise, the transitions are assumed to Be stretched
5535.8	854.7	E(γ): From ⁸²Se(¹⁹F,4nγ) I(γ): From ⁸²Se(¹⁹F,4nγ) M(γ): From γ(θ) and DCO (when available) in ⁸²Se(¹⁹F,4nγ). Unless noted otherwise, the transitions are assumed to Be stretched
5587.3	126.1	E(γ): From ⁸²Se(¹⁹F,4nγ) M(γ): From γ(θ) and DCO (when available) in ⁸²Se(¹⁹F,4nγ). Unless noted otherwise, the transitions are assumed to Be stretched
7016.6	1480.8	E(γ): From ⁸²Se(¹⁹F,4nγ) M(γ): From γ(θ) and DCO (when available) in ⁸²Se(¹⁹F,4nγ). Unless noted otherwise, the transitions are assumed to Be stretched
7714.0	697.4	E(γ): From ⁸²Se(¹⁹F,4nγ) M(γ): From γ(θ) and DCO (when available) in ⁸²Se(¹⁹F,4nγ). Unless noted otherwise, the transitions are assumed to Be stretched
8345.1	631.1	E(γ): From ⁸²Se(¹⁹F,4nγ) M(γ): From γ(θ) and DCO (when available) in ⁸²Se(¹⁹F,4nγ). Unless noted otherwise, the transitions are assumed to Be stretched

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 G H J	9/2+	4.21×10⁺⁶ y 16 % ε = 100
96.57 6	A B D E G H I J	1/2-	91.0 d 6 % IT = 96.06 18 % ε = 3.94 18	96.5 1	100	M4	0.0	9/2+
215.718 19	A D E G H I J	7/2+	69 ps 19	215.718 24	100	M1+E2	0.0	9/2+
324.476 21	A D E G H I J	5/2+	0.45 ns 8	108.79 3 324.48 3	1.2 4 100 2	M1+E2 E2	215.718 0.0	7/2+ 9/2+
580.19 6	A E G H I J	3/2-		483.62 2	100	M1+E2	96.57	1/2-
656.90 6	A D E G H I J	5/2-	≥ 0.76 ps	332.4 3 441.2? 560.34 4	0.6 1 <3 100 2	[E1] [E1] E2	324.476 215.718 96.57	5/2+ 7/2+ 1/2-
765.68 21	D			441.2 2	100		324.476	5/2+
772.68 6	C D H J	13/2+	≥ 0.35 ps	772.70 7	100	E2	0.0	9/2+
777.98 16	H	(7/2+,9/2+)		777.90 20	100	(M1+E2)	0.0	9/2+
785.034 24	A D E G H I J	5/2+	0.33 ps +17-10	460.57 3 569.31 4 785.06 4	13.3 9 100 2 8.3 3	M1+E2 M1+E2 (E2)	324.476 215.718 0.0	5/2+ 7/2+ 9/2+
832.80 6	C D H J	11/2(+)	≥ 0.35 ps	832.85 7	100	(M1+E2)	0.0	9/2+
833.52 20	D			617.8 2	100		215.718	7/2+
852	G	(3/2+,5/2+)
855.45 3	A D E H I J	7/2+	≥ 0.37 ps	531.16 11 639.72 2 855.53 14	7.6 6 17.7 10 100 2	(M1+E2) M1+E2	324.476 215.718 0.0	5/2+ 7/2+ 9/2+
861.90 8	D H I J	(9/2+)	≥ 0.38 ps	646.78 20 861.70 10	19 9 100 1	(M1+E2)	215.718 0.0	7/2+ 9/2+
939.88 12	H			615.52 20 843.27 20	48 100		324.476 96.57	5/2+ 1/2-
941.95 15	D I			617.5 2 726.2 2			324.476 215.718	5/2+ 7/2+
E(level) (keV)	XREF	J^π(level)	T_1/2(level)	E(γ) (keV)	I(γ)	M(γ)	Final Levels
946.73 10	A E G H I J	3/2-	0.22 ps +9-6	290.0 366.6 2 622.4 850.10 10	2.4 5 19 3 ≈4 100 2	(M1) (M1) (E1) M1+E2	656.90 580.19 324.476 96.57	5/2- 3/2- 5/2+ 1/2-
970.03 3	A D E H I J	7/2+		114.4 2 185.00 1 645.27 20 754.01 20 969.72 15	2.3 4 6 3 80 4 100 3 1.10 16	M1+E2 M1+E2	855.45 785.034 324.476 215.718 0.0	7/2+ 5/2+ 5/2+ 7/2+ 9/2+
994.68 3	A E H I J	(3/2+)	0.17 ps +7-4	670.21 2 898.06 16	100 3 2.8 24	(M1+E2) (E1)	324.476 96.57	5/2+ 1/2-
1003.58 11	D			679.1 1	100		324.476	5/2+
1049.22 7	G H I J	3/2-	≥ 0.21 ps	392.2 1 469.2 1 724.7 1	100 5 61 5 84 18	(M1) (M1) [E1]	656.90 580.19 324.476	5/2- 3/2- 5/2+
1059.6 9	E	(5/2,7/2+)		844	100		215.718	7/2+
1126.64 3	D H J	11/2(+)		910.92 2 1126.6 1	48 13 100 4	(E2) (M1+E2)	215.718 0.0	7/2+ 9/2+
1138 2	E I	(5/2)		559?	100		580.19	3/2-
1141.23 9	D H I J	(7/2+)	0.28 ps +25-10	356.1 3 816.7 1 925.5 3	36 7 100 5 5.7 14	(M1+E2) (M1+E2)	785.034 324.476 215.718	5/2+ 5/2+ 7/2+
1165.2 5	J	(9/2,7/2)		949.5 5	100		215.718	7/2+
1167.20 22	D			305.3 2	100		861.90	(9/2+)
1199.62 11	D H I J	(9/2+)	0.24 ps +37-10	366.92 20 421.56 20 875.18 20 983.81 20	50 60 70 100	(E2) (M1+E2)	832.80 777.98 324.476 215.718	11/2(+) (7/2+,9/2+) 5/2+ 7/2+
1219.87 12	H J	(7/2+)		895.4 2 1004.2 2 1219.8 2	93 7 22 7 100 7	(M1+E2) (M1+E2) (M1+E2)	324.476 215.718 0.0	5/2+ 7/2+ 9/2+
E(level) (keV)	XREF	J^π(level)	T_1/2(level)	E(γ) (keV)	I(γ)	M(γ)	Final Levels
1240.02 7	H I J	(7/2-)	≥ 0.26 ps	293.6 583.16 5 659.6 1 915.7 2 1024.4 2	35 100 3 88 4 20 6 29 8	(M1+E2) [E2] (E1) [E1]	946.73 656.90 580.19 324.476 215.718	3/2- 5/2- 3/2- 5/2+ 7/2+
1271.5 4	D I			416.0 4	100		855.45	7/2+
1274.54 14	H J	(3/2-,5/2-,7/2-)		617.60 20 694.45 20 949.9 3 1179?	100 15 4	(M1+E2) (E2)	656.90 580.19 324.476 96.57	5/2- 3/2- 5/2+ 1/2-
1277.82 7	D H J	(9/2-)		422.47 12 620.88 9 1062.0 4	15.2 21 100 12 ≤6	D+Q (E2) [E1]	855.45 656.90 215.718	7/2+ 5/2- 7/2+
1310.17 17	G H J	9/2+		1094.5 2 1310.0 3	100 4 97 12	(M1+E2) M1+E2	215.718 0.0	7/2+ 9/2+
1311.87 20	H			1096.15 20	100		215.718	7/2+
1348.33 17	D J			1024.1 3 1132.5 2	100		324.476 215.718	5/2+ 7/2+
1365.8 7	E	(3/2+)		581 1269		[E1]	785.034 96.57	5/2+ 1/2-
1373.32 13	H I J	(3/2,5/2-)		426.41 20 716.8 3 1049.0 3 1276.68 20	20 11 30 100	(M1+E2)	946.73 656.90 324.476 96.57	3/2- 5/2- 5/2+ 1/2-
1379	G I J	3/2+,5/2+		1054? 1379?			324.476 0.0	5/2+ 9/2+
1379.89 18	H I J	(9/2+)	0.09 ps +5-3	547.2 2 1163.9 3	84 4 100 4	(M1+E2) (M1+E2)	832.80 215.718	11/2(+) 7/2+
1382.33 20	D I			1166.6 2	100		215.718	7/2+
1387 4	E	(3/2+,5/2)
E(level) (keV)	XREF	J^π(level)	T_1/2(level)	E(γ) (keV)	I(γ)	M(γ)	Final Levels
1393.33 9	C D H	(13/2+)		531.23 20 560.48 20 620.63 20 1393.33 20	20 30 31 100	(M1+E2) (E2) (E2)	861.90 832.80 772.68 0.0	(9/2+) 11/2(+) 13/2+ 9/2+
1396.90 12	J			816.7 1	100		580.19	3/2-
1400.99 21	H	(3/2-,5/2-)		820.79 20	100	(M1+E2)	580.19	3/2-
1409.5 3	H I J	(7/2-)		752.7 4 830.0 1084.9 4 1193.8	65 6 28 52 7 100 3	[E2] [E1] [E1]	656.90 580.19 324.476 215.718	5/2- 3/2- 5/2+ 7/2+
1441.1 10	J		≥ 0.21 ps	1116.6	100		324.476	5/2+
1471.21 11	H	(7/2+,9/2+)		609.18 20 615.66 20 1255.56 20 1471.35 20	42 18 13 100	(M1+E2) (M1+E2)	861.90 855.45 215.718 0.0	(9/2+) 7/2+ 7/2+ 9/2+
1480.3 6	J			823.4 6	100		656.90	5/2-
1512.32 9	H I J	(3/2,5/2,7/2)	0.25 ps +18-9	855.45 7 932.8 1188.0 3 1295.8 3	61 4 18 100 3	D,E2 D,E2 D,E2	656.90 580.19 324.476 215.718	5/2- 3/2- 5/2+ 7/2+
1518.39 14	E H I J	(3/2-)	0.21 ps +22-8	938.18 20 1194.2 3 1421.69 20	100 16 42	(M1(+E2))	580.19 324.476 96.57	3/2- 5/2+ 1/2-
1523.1 4	H I J	(5/2+,7/2,9/2+)	0.044 ps +14-10	1198.7 4 1307.2 6 1523.5	100 3 36 20 25	D,E2 D,E2 D,E2	324.476 215.718 0.0	5/2+ 7/2+ 9/2+
1527.3 3	H			1202.8 3	100		324.476	5/2+
1537	G	1/2+
1538.01 17	H	(11/2+,13/2+)		765.28 20 1538.1 3	100 100	(M1+E2)	772.68 0.0	13/2+ 9/2+
E(level) (keV)	XREF	J^π(level)	T_1/2(level)	E(γ) (keV)	I(γ)	M(γ)	Final Levels
1573 3	E I	(3/2+,5/2)
1580.0 4	D H I J	(5/2,7/2-)		340.4 924.2 1000.0 10 1255.7 6 1363.3 7	20 9 100 4 65 4 24 2 28 2	D(+Q)	1240.02 656.90 580.19 324.476 215.718	(7/2-) 5/2- 3/2- 5/2+ 7/2+
1581.47 15	H	(11/2+,13/2+)		748.75 20 808.70 20	100 95	(M1+E2) (M1+E2)	832.80 772.68	11/2(+) 13/2+
1582.20 13	H	(3/2+,5/2,7/2)		925.16 20 1257.96 20 1366.2 3	100 33 16		656.90 324.476 215.718	5/2- 5/2+ 7/2+
1585.8 3	H	(3/2+,5/2+,7/2+)		1261.3 3	100	(M1+E2)	324.476	5/2+
1599	G	3/2+,5/2+
1625.26 17	H			483.79 20 685.61 20	100 61		1141.23 939.88	(7/2+)
1649.63 22	G H J	3/2+,5/2+	0.4 ps 3	679.9 3 793.7 5 1324.9 4	100 19 16	D,E2 D,E2 D,E2	970.03 855.45 324.476	7/2+ 7/2+ 5/2+
1654.48 8	C D H	17/2+		881.8 1	100	E2	772.68	13/2+
1675.5 9	E G	3/2+,5/2+		616 820			1059.6 855.45	(5/2,7/2+) 7/2+
1677.5 3	H J	(5/2-)		1020.6 3 1097.1 10 1352.7 10 1462.0?	43 100 10 47 6	(M1+E2)	656.90 580.19 324.476 215.718	5/2- 3/2- 5/2+ 7/2+
1685.47 8	C D H	15/2(+)		852.7 1 912.8 1	67 3 100 5	E2 (M1+E2)	832.80 772.68	11/2(+) 13/2+
1690.04 20	H	(5/2+,7/2+)		1474.31 20	100	(M1+E2)	215.718	7/2+
1692.9 3	H J	(3/2+,5/2,7/2)		698.5 1368.2 6 1477.2 3	38 14 100 5	(M1+E2)	994.68 324.476 215.718	(3/2+) 5/2+ 7/2+
E(level) (keV)	XREF	J^π(level)	T_1/2(level)	E(γ) (keV)	I(γ)	M(γ)	Final Levels
1697.8 3	H			1482.1 3	100		215.718	7/2+
1706.95 22	H			429.13 20	100		1277.82	(9/2-)
1707.7 3	H J	(7/2)	0.025 ps +9-6	922.7 5 1383.0 5 1492.2 5	100 16 89 13 46 13	D,E2 D,E2 D,E2	785.034 324.476 215.718	5/2+ 5/2+ 7/2+
1712	G	1/2+
1721.0 3	H	(1/2+,3/2+,5/2+)		726.3 3	100	(M1+E2)	994.68	(3/2+)
1722.61 22	H J	(5/2+)		728.1 3 752.4 3	100 89	(M1+E2)	994.68 970.03	(3/2+) 7/2+
1733.3 4	H J	(3/2+,5/2,7/2-)	≥ 0.54 ps	1153.0 6 1517.6 4	31 21 100 5		580.19 215.718	3/2- 7/2+
1779.1 5	H J	(5/2,7/2)		993.5 8 1563.5 6 1779.4	100 8 61 3		785.034 215.718 0.0	5/2+ 7/2+ 9/2+
1796.7 4	H J	(3/2,5/2,7/2)		1011.1 6 1141.3 10 1472.3 6	100 10 60 10 90 13		785.034 656.90 324.476	5/2+ 5/2- 5/2+
1801.29 21	H			1476.80 20	100		324.476	5/2+
1815.7 4	H J	(9/2+)		615.9 1491.1 5 1600.2 6	100 9 43 6	[E2] (M1+E2)	1199.62 324.476 215.718	(9/2+) 5/2+ 7/2+
1834.75 23	H	(11/2+)		363.54 20	100	(M1+E2)	1471.21	(7/2+,9/2+)
1834.81 9	D H	(13/2-)		557.0 1 1062.0 2	100 3 43 2	E2 [E1]	1277.82 772.68	(9/2-) 13/2+
1841.87 19	H			847.4 3 901.89 20	29 100	(M1+E2)	994.68 939.88	(3/2+)
1847	G	1/2+
1849.79 9	C D H	(15/2+)		164.3 3 195.3 1 456.4 1 1077.2 2	16 1 61 4 100 5	(M1(+E2)) (M1+E2) (M1+E2)	1685.47 1654.48 1393.33 772.68	15/2(+) 17/2+ (13/2+) 13/2+
E(level) (keV)	XREF	J^π(level)	T_1/2(level)	E(γ) (keV)	I(γ)	M(γ)	Final Levels
1850.6 3	H J	(3/2)	0.21 ps +22-8	1193.7 3 1754.2			656.90 96.57	5/2- 1/2-
1856.1 5	J	(3/2+,5/2-)		1276.3 1530.8 10 1640.5 8 1759.8	47 4 100 7		580.19 324.476 215.718 96.57	3/2- 5/2+ 7/2+ 1/2-
1858.61 21	H			1201.70 20	100		656.90	5/2-
1862.36 21	H			1537.87 20	100		324.476	5/2+
1864.84 24	H J	(9/2+)		1009.6 3 1539.8 6 1648.9 5	86 100 7 16 3	[E2]	855.45 324.476 215.718	7/2+ 5/2+ 7/2+
1879.39 12	D H	(9/2+,17/2+)		1106.7 1	100	(E2)	772.68	13/2+
1892.61 15	H	(13/2+,15/2+)		765.64 20 1120.24 20	81 100	(M1+E2)	1126.64 772.68	11/2(+) 13/2+
1896.0 10	H J			1063.2 1896?			832.80 0.0	11/2(+) 9/2+
1897.42 20	H J	(5/2+,7/2+,9/2+)		1681.69 20	100	(M1+E2)	215.718	7/2+
1907.04 21	H			1134.35 20	100		772.68	13/2+
1913.9 3	H			1589.4 3	100		324.476	5/2+
1914.1 4	H J	(3/2,5/2)		944.3 1058.7 1128.8 5 1589.9 6 1698.5	100 7 33 4		970.03 855.45 785.034 324.476 215.718	7/2+ 7/2+ 5/2+ 5/2+ 7/2+
1919.3 3	H			1594.8 3	100		324.476	5/2+
1922.5 3	H			1265.6 3	100		656.90	5/2-
1924.6 4	H J	(3/2,5/2)		1267.7 6 1344.3 7 1599.8 10 1709.4	100 5 24 4 8 4		656.90 580.19 324.476 215.718	5/2- 3/2- 5/2+ 7/2+
E(level) (keV)	XREF	J^π(level)	T_1/2(level)	E(γ) (keV)	I(γ)	M(γ)	Final Levels
1940	G	1/2-,3/2-
1940.6 7	H J	(7/2)		1616.1 1724.9			324.476 215.718	5/2+ 7/2+
1947.59 21	H J			1623.10 20	100		324.476	5/2+
1949.00 19	H J	(9/2+)		1093.69 20 ? 1163.92 20 1733.5 5	100 54	[E2]	855.45 785.034 215.718	7/2+ 5/2+ 7/2+
1951	G	3/2+,5/2+
1964.46 19	H			1024.51 20 1640.1 3	100 54		939.88 324.476	5/2+
1976.63 22	H			698.81 20	100		1277.82	(9/2-)
1979.3 3	H			1146.5 3	100		832.80	11/2(+)
1987.0 5	H J	(3/2)		1330.1 6 1406.8 7 1890.4	96 8 100 8		656.90 580.19 96.57	5/2- 3/2- 1/2-
1992.6 3	H			714.8 3	100		1277.82	(9/2-)
1995.0 6	H J			1025.2 1670.4 1779.2			970.03 324.476 215.718	7/2+ 5/2+ 7/2+
2001.3 5	H J			1344.2 7 1421.2 6	39 4 100 7		656.90 580.19	5/2- 3/2-
2004.21 21	H			1009.52 20	100		994.68	(3/2+)
2013	G	3/2+,5/2+
2023.7 6	J			1443.5 6	100		580.19	3/2-
2033.04 22	H			1171.13 20	100		861.90	(9/2+)
2036.0 6	H J	(1/2-,3/2,5/2-)		1379.0 6 1939.5			656.90 96.57	5/2- 1/2-
2048.47 21	H			1053.78 20	100		994.68	(3/2+)
2054.90 22	H			400.41 20	100		1654.48	17/2+
2056.1 3	H			1283.4 3	100		772.68	13/2+
E(level) (keV)	XREF	J^π(level)	T_1/2(level)	E(γ) (keV)	I(γ)	M(γ)	Final Levels
2060.0 7	H J	(9/2,11/2)		1198.2 1844.2			861.90 215.718	(9/2+) 7/2+
2069.0 5	J			1412.1 5	100		656.90	5/2-
2095.87 22	H			1101.4 3 1240.2 3	88 100		994.68 855.45	(3/2+) 7/2+
2098.0 4	H			823.5 3	100		1274.54	(3/2-,5/2-,7/2-)
2111	G	3/2+,5/2+
2117.56 22	H			1255.9 3 1537.1 3	100 70		861.90 580.19	(9/2+) 3/2-
2119.72 21	H			1539.51 20	100		580.19	3/2-
2121.79 10	D H	(13/2+,15/2,17/2+)		467.3 1 1349.1 1	67 8 100 3	(E2)	1654.48 772.68	17/2+ 13/2+
2130.8 3	H			1160.8 3	100		970.03	7/2+
2134.8 3	H			1362.1 3	100		772.68	13/2+
2150.1 5	H J	(3/2+,5/2,7/2)		1493.0 7 1825.8 1934.6			656.90 324.476 215.718	5/2- 5/2+ 7/2+
2151	G	1/2+
2168.8 6	J			858.4 1953.3 2168.9			1310.17 215.718 0.0	9/2+ 7/2+ 9/2+
2208.2 7	J			1628.0 7	100		580.19	3/2-
2217.4 6	J			1362.0 1892.9 2001.7			855.45 324.476 215.718	7/2+ 5/2+ 7/2+
2255.1 5	J	(5/2+,7/2-)		1393.8 1675.4 1930.5 2038.3			861.90 580.19 324.476 215.718	(9/2+) 3/2- 5/2+ 7/2+
2257.3 3	H			1677.1 3	100		580.19	3/2-
E(level) (keV)	XREF	J^π(level)	T_1/2(level)	E(γ) (keV)	I(γ)	M(γ)	Final Levels
2257.88 22	H			980.05 20	100		1277.82	(9/2-)
2260	G	3/2+,5/2+
2264	G	1/2+
2264.60 21	H			1294.56 20	100		970.03	7/2+
2307	G	3/2+,5/2+
2331.39 11	C D H	(19/2+)		676.9 1	100	(M1+E2)	1654.48	17/2+
2337.62 8	D H	(17/2-)		487.8 1 502.8 1 652.2 1	100 6 65 6 72 4	(E1) [E2] (E1)	1849.79 1834.81 1685.47	(15/2+) (13/2-) 15/2(+)
2417.5 4	H			1143.0 3	100		1274.54	(3/2-,5/2-,7/2-)
2446.8 4	H			612.0 3	100		1834.81	(13/2-)
2449.2 4	H			911.2 3	100		1538.01	(11/2+,13/2+)
2480	G
2491.59 22	D			837.1 2	100		1654.48	17/2+
2533.78 11	C D H	(21/2+)		202.4 1 879.3 1	4.1 5 100 2	(M1+E2) E2	2331.39 1654.48	(19/2+) 17/2+
2564.71 11	D	(19/2)		227.1 1	100	(D)	2337.62	(17/2-)
2653	G	1/2+
2661.79 14	D			540.0 1 1007.3 2 ?	100 13 43 4		2121.79 1654.48	(13/2+,15/2,17/2+) 17/2+
2672.2 4	D			1017.7 3	100		1654.48	17/2+
2713	G	3/2+,5/2+
2730	G
2733.80 11	C D	(21/2+)		169.1 1 1079.3 1	20 1 100 2	(D) E2	2564.71 1654.48	(19/2) 17/2+
2783	G	3/2+,5/2+
2878	G	3/2+,5/2+
2908	G	3/2+,5/2+
2916.79 20	D	(17/2+,19/2,21/2+)		383.0 4 1262.3 2	100		2533.78 1654.48	(21/2+) 17/2+
E(level) (keV)	XREF	J^π(level)	T_1/2(level)	E(γ) (keV)	I(γ)	M(γ)	Final Levels
3018	G	3/2+,5/2+
3060	G	3/2+,5/2+
3143.24 12	D	(21/2-)		609.5 2 805.6 1	29 3 100 9	[E1] E2	2533.78 2337.62	(21/2+) (17/2-)
3145	G	1/2+
3214	G	1/2+
3254.39 22	D			337.6 1	100		2916.79	(17/2+,19/2,21/2+)
3296.59 15	D			762.8 1	100		2533.78	(21/2+)
3372	G	(3/2+,5/2+)
3486	G	(3/2+,5/2+)
3530.19 15	C D	(25/2+)		996.4 1	100	(E2)	2533.78	(21/2+)
3575.59 14	C D	(23/2+)		841.8 2 1041.8 1	100 4 96 6	(M1+E2) (M1)	2733.80 2533.78	(21/2+) (21/2+)
3585.99 23	D			1052.2 2	100		2533.78	(21/2+)
3600 20	G	3/2+,5/2+
3643.68 23	C D	(25/2+)		1109.9 2	100	(E2)	2533.78	(21/2+)
3720 20	G	3/2+,5/2+
3731.09 17	C D	(25/2+)		155.5 1	100	(M1+E2)	3575.59	(23/2+)
4060 20	G
4330 20	G
4334.0 4	C	(27/2+)		803.8 3	100	(M1+E2)	3530.19	(25/2+)
4376.1 4	C D	(27/2+)		645.0 3	100	(M1+E2)	3731.09	(25/2+)
4430.1 6	C	(29/2+)		96.0 786.9 899.7	12 4 28 5 100 19	(M1+E2) (E2) (E2)	4334.0 3643.68 3530.19	(27/2+) (25/2+) (25/2+)
4580 20	G
4681.0 7	C	(29/2+)		304.8 950.0	15.8 20 100.0 23	(M1+E2) (E2)	4376.1 3731.09	(27/2+) (25/2+)
4780 20	G
4990 20	G
E(level) (keV)	XREF	J^π(level)	T_1/2(level)	E(γ) (keV)	I(γ)	M(γ)	Final Levels
5051.4 9	C	(29/2+)		1407.5	100	(E2)	3643.68	(25/2+)
5322.7 8	C	(31/2+)		641.6 946.7	85 10 100 39	(M1(+E2))	4681.0 4376.1	(29/2+) (27/2+)
5461.2 10	C	(31/2+)		409.7 1031.3	22.5 17 100 8	(M1+E2) (M1+E2)	5051.4 4430.1	(29/2+) (29/2+)
5535.8 10	C	(33/2+)		213.1 854.7	16.3 8 100.0 25	(M1(+E2)) (E2)	5322.7 4681.0	(31/2+) (29/2+)
5587.3 14	C	(33/2+)		126.1	100	(M1+E2)	5461.2	(31/2+)
7016.6 14	C	(37/2+)		1480.8	100	(E2)	5535.8	(33/2+)
7714.0 17	C	(39/2+)		697.4	100	(M1+E2)	7016.6	(37/2+)
8345.1 20	C	(43/2+)		631.1	100	(E2)	7714.0	(39/2+)
11050 20	F G	5/2+
11730	F	1/2+
11810 20	G
11840	F	3/2+,5/2+
11980	F
12120	F	(1/2+)
12360	F	3/2+,5/2+
12550 20	G	11/2-
12600	F
12680	F	(5/2-,7/2-)
12820	F	(1/2+)
12960	F	(1/2+)
13080	F	(1/2+)
13200	F	3/2+,5/2+

E(level)	J^π(level)	T_1/2(level)	Comments
0.0	9/2+	4.21×10⁺⁶ y 16 % ε = 100	E(level): g_9/2 band.
215.718	7/2+	69 ps 19	T_1/2(level): From ⁹⁷Ru ε decay.
324.476	5/2+	0.45 ns 8	T_1/2(level): From ⁹⁷Ru ε decay.
772.68	13/2+	≥ 0.35 ps	E(level): g_9/2 band.
970.03	7/2+		XREF: I(962).
1379	3/2+,5/2+		XREF: γ(1374).
1654.48	17/2+		E(level): g_9/2 band.
1675.5	3/2+,5/2+		XREF: γ(1670).
1849.79	(15/2+)		J^π(level): Assignment from (⁶Li,3nγ) data set, based on γ(θ), γ excit, and branching ratios.
2331.39	(19/2+)		J^π(level): Assignment from (⁶Li,3nγ) data set, based on γ(θ), γ excit, and branching ratios.
2337.62	(17/2-)		J^π(level): Assignment from (⁶Li,3nγ) data set, based on γ(θ), γ excit, and branching ratios.
2533.78	(21/2+)		E(level): g_9/2 band. J^π(level): Assignment from (⁶Li,3nγ) data set, based on γ(θ), γ excit, and branching ratios.
2733.80	(21/2+)		E(level): γ sequence based on 21/2⁺. J^π(level): Assignment from (⁶Li,3nγ) data set, based on γ(θ), γ excit, and branching ratios.
3143.24	(21/2-)		J^π(level): Assignment from (⁶Li,3nγ) data set, based on γ(θ), γ excit, and branching ratios.
3530.19	(25/2+)		E(level): Band based on 25/2⁺. J^π(level): Assignment from (⁶Li,3nγ) data set, based on γ(θ), γ excit, and branching ratios.
3575.59	(23/2+)		E(level): γ sequence based on 21/2⁺. J^π(level): Assignment from (⁶Li,3nγ) data set, based on γ(θ), γ excit, and branching ratios.
3643.68	(25/2+)		E(level): g_9/2 band.
3731.09	(25/2+)		E(level): γ sequence based on 21/2⁺. J^π(level): Assignment from (⁶Li,3nγ) data set, based on γ(θ), γ excit, and branching ratios.
4334.0	(27/2+)		E(level): Band based on 25/2⁺.
4376.1	(27/2+)		E(level): γ sequence based on 21/2⁺.
4430.1	(29/2+)		E(level): Band based on 25/2⁺.
4681.0	(29/2+)		E(level): γ sequence based on 21/2⁺.
5051.4	(29/2+)		E(level): g_9/2 band.
5322.7	(31/2+)		E(level): γ sequence based on 21/2⁺.
5461.2	(31/2+)		E(level): Band based on 25/2⁺.
E(level)	J^π(level)	T_1/2(level)	Comments
5535.8	(33/2+)		E(level): γ sequence based on 21/2⁺.
5587.3	(33/2+)		E(level): Band based on 25/2⁺.
7016.6	(37/2+)		E(level): γ sequence based on 21/2⁺.
7714.0	(39/2+)		E(level): γ sequence based on 21/2⁺.
8345.1	(43/2+)		E(level): γ sequence based on 21/2⁺.
11050	5/2+		XREF: F(11040).