List of levels for 63ZN

Authors: Huo Junde, Yang Dong, Huo Meirong, | Citation: ENSDF | Cutoff date: 28-Aug-2008

Authors: Bai Erjun, Huo Junde | Citation: Nucl. Data Sheets 92, 147 (2001) | Cutoff date: 1-Mar-1999

E(level) (keV)	J^π(level)	T_1/2(level)	E(γ) (keV)	Multipolarity	Mixing Ratio	Conversion Coefficient	Additional Data
192.92	5/2-	0.53 ns 12	192.94 6	M1+E2	+0.07 3	0.01116	B(E2)(W.u.)=1.3 12, B(M1)(W.u.)=0.0057 13, α=0.01116 8
637.07	3/2-	> 0.53 ps	389.26 9	M1+E2	-0.05 +3-4	0.00201	B(E2)(W.u.)<1.8, B(M1)(W.u.)<0.028, α=0.00201
637.07	3/2-	> 0.53 ps	637.04 7	M1+E2	+0.04 2		B(E2)(W.u.)<2.1, B(M1)(W.u.)<0.15
650.10	5/2-	> 0.28 ps	457.19 6	M1+E2	-0.08 +1-2	0.00138	B(E2)(W.u.)<7.4, B(M1)(W.u.)<0.11, α=0.00138
650.10	5/2-	> 0.28 ps	650.14 6	M1+E2	-0.57 3		B(E2)(W.u.)<2.7×10², B(M1)(W.u.)<0.19
1023.22	3/2-	> 3.5 ps	373.06 8	(M1+E2)	-0.82 +4-5		B(E2)(W.u.)<2.5×10², B(M1)(W.u.)<0.029
	3/2-	> 3.5 ps	396.10 10	(M1+E2)	+0.57 +6-3		B(E2)(W.u.)<21, B(M1)(W.u.)<0.0053
	3/2-	> 3.5 ps	775.43 8	(M1+E2)	-0.91 +24-6		B(E2)(W.u.)<6.2, B(M1)(W.u.)<0.0025
	3/2-	> 3.5 ps	1023.22 8	(M1+E2)	+1.9 2		B(E2)(W.u.)<2.2, B(M1)(W.u.)<0.00040
1063.34	7/2-	> 0.29 ps	1063.2 2	E2(+M3)	0.00 3		B(E2)(W.u.)<64
1206.38	7/2-	> 0.42 ps	556.3 2	D+Q	-1.24 9
	7/2-	> 0.42 ps	1013.45 10	M1+E2	+4.7 +1-7		B(E2)(W.u.)<38, B(M1)(W.u.)<0.0011
	7/2-	> 0.42 ps	1206.34 11	E2(+M3)	-0.03 2		B(E2)(W.u.)<18, B(M3)(W.u.)<1.8×10⁵
1284.26	5/2-	> 0.40 ps	1036.34 8	E2(+M3)	-0.01 1		B(E2)(W.u.)<22, B(M3)(W.u.)<4.3×10⁴
1284.26	5/2-	> 0.40 ps	1284.21 15	M1+E2	-0.7 2		B(E2)(W.u.)<0.79, B(M1)(W.u.)<0.0013
1395.44	3/2-	0.097 ps 21	1395.39 15	M1+E2	+0.36 +14-10		B(E2)(W.u.)=6 5, B(M1)(W.u.)=0.051 13
1436.26	9/2-	0.69 ps 21	1243.28 10	E2(+M3)	-0.01 2		B(E2)(W.u.)=19 6, B(M3)(W.u.)=1.×10⁴ 4
1664.86	7/2-	0.24 ps +6-5	1472.0 1	M1+E2	+0.18 3		B(E2)(W.u.)=0.43 18, B(M1)(W.u.)=0.017 5
1664.86	7/2-	0.24 ps +6-5	1664.8 2	E2(+M3)	+0.03 3		B(E2)(W.u.)=1.9 5, B(M3)(W.u.)=4.×10³ 9
1691.22	5/2-	0.069 ps +14-12	1691.2 1	M1+E2	-0.10 3		B(E2)(W.u.)=0.33 21, B(M1)(W.u.)=0.055 12
1702.96	9/2+	32 ps 4	496.56 12	E1(+M2)	+0.02 2		B(E1)(W.u.)=1.7E-5 3, B(M2)(W.u.)=0.12 25
1702.96	9/2+	32 ps 4	639.5 6	D(+Q)	+0.00 2
1860.84	9/2-	0.43 ps +16-11	797.5 2	M1+E2	-0.03 2		B(E2)(W.u.)=0.06 8, B(M1)(W.u.)=0.024 9
1860.84	9/2-	0.43 ps +16-11	1210.7 2	E2(+M3)	+0.01 2		B(E2)(W.u.)=21 8, B(M3)(W.u.)=1.×10⁴ 4
1978.40	-	0.19 ps +7-5	1328.0 5	E2(+M3)	-0.01 2		B(E2)(W.u.)=13 5, B(M3)(W.u.)=5.×10³ 21
1978.40	-	0.19 ps +7-5	1785.5 2	E2+M3	-0.10 5		B(E2)(W.u.)=8 3, B(M3)(W.u.)=1.8×10⁵ 19
E(level) (keV)	J^π(level)	T_1/2(level)	E(γ) (keV)	Multipolarity	Mixing Ratio	Conversion Coefficient	Additional Data
2158.10	3/2-	0.028 ps +14-10	1530.8 3	M1+E2	-2.0 2		B(E2)(W.u.)=5.×10¹ 3, B(M1)(W.u.)=0.018 10
2158.10	3/2-	0.028 ps +14-10	1910.4 3	M1+E2	-2.3 2		B(E2)(W.u.)=27 14, B(M1)(W.u.)=0.011 6
2233.30	11/2-	> 1.4 ps	570.2 5	E2(+M3)	-0.03 3		B(E2)(W.u.)<1.7×10², B(M3)(W.u.)<9.9E+6
2249.2	-	0.12 ps 3	1185.4 5	M1+E2	+0.9 2		B(E2)(W.u.)=43 16, B(M1)(W.u.)=0.043 14
2249.2	-	0.12 ps 3	1599.5 5	E2(+M3)	-0.04 3		B(E2)(W.u.)=8.8 23, B(M3)(W.u.)=4.×10⁴ 6
2261.53	3/2-	0.07 ps +3-2	1634.4 2	D+Q	-0.5 +3-4
2291.46	3/2-	0.06 ps +3-2	2043.6 3	M1+E2	-0.6 3		B(E2)(W.u.)=1.3 12, B(M1)(W.u.)=0.009 5
2293.0	(3/2-)	0.030 ps +15-10	2045.1 3	D+Q	+2 +8-1
2318.8	11/2-	0.35 ps 9	1255.6 4	E2(+M3)	-0.05 +5-2		B(E2)(W.u.)=35 9, B(M3)(W.u.)=4.×10⁵ 8
2377.86	9/2+	> 1.39 ps	674.9 2	(M1+E2)	-2.5 +5-12		B(E2)(W.u.)<1.8×10², B(M1)(W.u.)<0.0096
2584.5	13/2+	3.54 ps 28	881.3 3	E2+M3	-0.25 10		B(E2)(W.u.)=19.0 18, B(M3)(W.u.)=1.1×10⁷ 8
2634.53	5/2-,7/2-	0.19 ps 5	1428.1 3	M1(+E2)	+0.02 7		B(E2)(W.u.)=0.01 5, B(M1)(W.u.)=0.018 5
2826.2	11/2+	291 fs 90	1123.3 4	M1+E2	+0.7 1		B(E2)(W.u.)=24 9, B(M1)(W.u.)=0.036 12
2911.9	9/2	> 1.4 ps	1705.5 5	D+Q	-1.7 1
2933.5	13/2-	215 fs 62	1497.2 5	E2(+M3)	-0.02 3		B(E2)(W.u.)=23 7, B(M3)(W.u.)=3.×10⁴ 9
3762.8	(17/2+)		1177.7 5	E2+M3	-0.20 3
5346.5	(21/2)+	< 280 fs	1584.1 6	E2			B(E2)(W.u.)>14

Q(β-)=-5666.0 keV 21	S(n)= 9116.9 keV 17	S(p)= 6715.1 keV 17	Q(α)= -3481.9 keV 16
Reference: 2012WA38

References:
A	⁶³Ga ε decay	B	⁶⁰Ni(α,nγ), (HI,xnγ)
C	⁶³Cu(p,n)	D	⁶³Cu(p,nγ)
E	⁶⁴Zn(p,d), (pol p,d)	F	⁶⁴Zn(pol d,t)
G	⁶⁴Zn(³He,α)

E(level) (keV)	XREF	J^π(level)	T_1/2(level)	E(γ) (keV)	I(γ)	M(γ)	Final Levels
0	A B C D E F G	3/2-	38.47 m 5 % ε = 100
192.92 4	A B C D E F G	5/2-	0.53 ns 12	192.94 6	100	M1+E2	0	3/2-
247.84 5	A B C D E F	1/2-	33 ps 8	247.84 7	100		0	3/2-
627.11 6	A B C D E	1/2-		627.10 7	100		0	3/2-
637.07 6	A B C D G	3/2-	> 0.53 ps	389.26 9 637.04 7	4.2 4 100.0 4	M1+E2 M1+E2	247.84 0	1/2- 3/2-
650.10 4	A B C D	5/2-	> 0.28 ps	457.19 6 650.14 6	16 1 100 1	M1+E2 M1+E2	192.92 0	5/2- 3/2-
1023.22 5	B C D E	3/2-	> 3.5 ps	373.06 8 396.10 10 775.43 8 1023.22 8	100 5 17 1 71 4 70 3	(M1+E2) (M1+E2) (M1+E2) (M1+E2)	650.10 627.11 247.84 0	5/2- 1/2- 1/2- 3/2-
1063.34 7	A B D E G	7/2-	> 0.29 ps	413.2 1 870.25 10 1063.2 2	28 2 24 1 100 2	D+Q D+Q E2(+M3)	650.10 192.92 0	5/2- 5/2- 3/2-
1065.28 12	B C D E G	1/2-	> 0.22 ps	415.2 2 872.4 2 1065.2 2	4.2 4 5.3 4 100.0 7		650.10 192.92 0	5/2- 5/2- 3/2-
1206.38 7	B C D E G	7/2-	> 0.42 ps	556.3 2 1013.45 10 1206.34 11	4.3 4 92 4 100 4	D+Q M1+E2 E2(+M3)	650.10 192.92 0	5/2- 5/2- 3/2-
1284.26 6	B C D E	5/2-	> 0.40 ps	634.5 5 1036.34 8 1091.40 8 1284.21 15	13 1 48 2 100 3 11 1	E2(+M3) D+Q M1+E2	650.10 247.84 192.92 0	5/2- 1/2- 5/2- 3/2-
1395.44 10	A B C D E	3/2-	0.097 ps 21	768.36 12 1147.3 4 1202.8 5 1395.39 15	28 2 10 1 5.7 7 100 2	D+Q D+Q D+Q M1+E2	627.11 247.84 192.92 0	1/2- 1/2- 5/2- 3/2-
E(level) (keV)	XREF	J^π(level)	T_1/2(level)	E(γ) (keV)	I(γ)	M(γ)	Final Levels
1420	E G	1/2-,3/2-
1436.26 11	B C D E	9/2-	0.69 ps 21	1243.28 10	100	E2(+M3)	192.92	5/2-
1664.86 9	B D E	7/2-	0.24 ps +6-5	1014 1 1027.8 2 1472.0 1 1664.8 2	22 2 20 1 100 4 25 2	Q+O M1+E2 E2(+M3)	650.10 637.07 192.92 0	5/2- 3/2- 5/2- 3/2-
1691.22 9	A B D	5/2-	0.069 ps +14-12	1054.1 3 1498.3 2 1691.2 1	6.3 8 11.9 8 100.0 1	D+Q M1+E2	637.07 192.92 0	3/2- 5/2- 3/2-
1702.96 14	B D	9/2+	32 ps 4	496.56 12 639.5 6	18 2 100 2	E1(+M2) D(+Q)	1206.38 1063.34	7/2- 7/2-
1704 15	G	5/2-,7/2-
1860.84 14	B D	9/2-	0.43 ps +16-11	797.5 2 1210.7 2 1668.0 4	38 2 100 3 25 3	M1+E2 E2(+M3)	1063.34 650.10 192.92	7/2- 5/2- 5/2-
1909.26 14	D E G	1/2,3/2-	> 0.28 ps	1272.3 2 1716.3 2 1909.0 3	9.7 7 32 2 100 2	D+Q D+Q D+Q	637.07 192.92 0	3/2- 5/2- 3/2-
1978.40 19	B D	-	0.19 ps +7-5	1328.0 5 1785.5 2	36 3 100 3	E2(+M3) E2+M3	650.10 192.92	5/2- 5/2-
2050.42 19	B D	9/2-	> 0.31 ps	844.1 4 987.1 2	64 5 100 5	D+Q	1206.38 1063.34	7/2- 7/2-
2158.10 22	B D E G	3/2-	0.028 ps +14-10	1530.8 3 1910.4 3	67 3 100 3	M1+E2 M1+E2	627.11 247.84	1/2- 1/2-
2233.30 23	B	11/2-	> 1.4 ps	570.2 5 796.6 3 1169.6 4	90 3 48 5 100 5	E2(+M3)	1664.86 1436.26 1063.34	7/2- 9/2- 7/2-
2249.2 4	B D	-	0.12 ps 3	1185.4 5 1599.5 5	100 3 41 3	M1+E2 E2(+M3)	1063.34 650.10	7/2- 5/2-
2261.53 17	D	3/2-	0.07 ps +3-2	1634.4 2 2261.5 3	100 3 35 3	D+Q D+Q	627.11 0	1/2- 3/2-
E(level) (keV)	XREF	J^π(level)	T_1/2(level)	E(γ) (keV)	I(γ)	M(γ)	Final Levels
2288.31 17	D	7/2-	> 0.21 ps	1081.9 3 1638.2 2	47 3 100 3	D+Q	1206.38 650.10	7/2- 5/2-
2291.46 15	B D	3/2-	0.06 ps +3-2	1641.7 3 1654.2 2 2043.6 3	87 5 100 5 69 5	D+Q M1+E2	650.10 637.07 247.84	5/2- 3/2- 1/2-
2293.0 3	D	(3/2-)	0.030 ps +15-10	2045.1 3	100	D+Q	247.84	1/2-
2318.8 4	B	11/2-	0.35 ps 9	1255.6 4	100	E2(+M3)	1063.34	7/2-
2377.86 24	B D	9/2+	> 1.39 ps	674.9 2	100	(M1+E2)	1702.96	9/2+
2403.28 19	D		0.11 ps +7-4	1380.0 2 1776.4 5	100 8 54 8		1023.22 627.11	3/2- 1/2-
2521.14 15	D E G	3/2-		1456.9 2 1871.9 2	100 8 96 8		1063.34 650.10	7/2- 5/2-
2584.5 3	B	13/2+	3.54 ps 28	881.3 3	100	E2+M3	1702.96	9/2+
2600.1 3	D	1/2-,3/2-,5/2-		1950.5 4 2351.7 4 2599.8 8	98 9 100 9 30 7		650.10 247.84 0	5/2- 1/2- 3/2-
2609.1 4	D			1959.0 7 1971.9 8 2609.1 5	100 11 38 11 84 11		650.10 637.07 0	5/2- 3/2- 3/2-
2634.53 22	B D E G	5/2-,7/2-	0.19 ps 5	1428.1 3 2441.6 3	82 5 100 5	M1(+E2)	1206.38 192.92	7/2- 5/2-
2690.9 10	D			2443 1	100		247.84	1/2-
2750.7 4	D E G	(5/2,7/2)-		2100.6 4 2557.7 6	100 15 85 15		650.10 192.92	5/2- 5/2-
2826.2 4	B	11/2+	291 fs 90	1123.3 4	100	M1+E2	1702.96	9/2+
2850	E G	(5/2,7/2)-
2911.9 5	B	9/2	> 1.4 ps	1705.5 5	100	D+Q	1206.38	7/2-
2933.5 5	B	13/2-	215 fs 62	1497.2 5	100	E2(+M3)	1436.26	9/2-
2940	G	(5/2,7/2)-
3010	E G	(5/2,7/2)-
E(level) (keV)	XREF	J^π(level)	T_1/2(level)	E(γ) (keV)	I(γ)	M(γ)	Final Levels
3380	E G	(5/2,7/2)-
3480.3 7	B	13/2+		654 1778	100		2826.2 1702.96	11/2+ 9/2+
3527.4 6	B	13/2-		1209 1478	100 7 72 4		2318.8 2050.42	11/2- 9/2-
3762.8 5	B	(17/2+)		1177.7 5	100	E2+M3	2584.5	13/2+
3769.7 7	B	(15/2)+		944 1185	79 6 100 2	Q	2826.2 2584.5	11/2+ 13/2+
3890.9 9	B			1306	100		2584.5	13/2+
≈4000	E G	(1/2,3/2)-
4320	E G	(5/2,7/2)-
4354.6 6	B	(15/2)-		591 875 1770 2036S	100 48 13.3 14 88 48	E1 M2	3762.8 3480.3 2584.5 2318.8	(17/2+) 13/2+ 13/2+ 11/2-
4800	E G	(5/2,7/2)-
4902.2 9	B			1139	100		3762.8	(17/2+)
5076.3 7	B	(19/2)+		1185 1307 1313	43.1 21 100 6	Q	3890.9 3769.7 3762.8	(15/2)+ (17/2+)
5346.5 7	B	(21/2)+	< 280 fs	1584.1 6	100	E2	3762.8	(17/2+)
≈5400	C E G	(1/2,3/2)-
5405.9 7	B	17/2-		1879 2472	100 6 28 6	Q	3527.4 2933.5	13/2- 13/2-
5423.4 6	B	17/2-		1659 1897 2490	78 5 100 6 10 4	Q	3762.8 3527.4 2933.5	(17/2+) 13/2- 13/2-
5915.7 6	B	19/2-		492 510 1013 1561	57 4 47 6 100 6		5423.4 5405.9 4902.2 4354.6	17/2- 17/2- (15/2)-
E(level) (keV)	XREF	J^π(level)	T_1/2(level)	E(γ) (keV)	I(γ)	M(γ)	Final Levels
≈6000	C	1/2-
6233.8 6	B	21/2-		318 810 828 888 1157	29 2 54 3 49 4 9.2 7 100 5	Q Q	5915.7 5423.4 5405.9 5346.5 5076.3	19/2- 17/2- 17/2- (21/2)+ (19/2)+
≈6300	C	5/2-
6487.3 12	B	(23/2)+		1411	100 7		5076.3	(19/2)+
6570.0 8	B	23/2(-)		336 654 1224	10.1 6 10.5 6 100 5	Q	6233.8 5915.7 5346.5	21/2- 19/2- (21/2)+
≈6700	C E G	(5/2,7/2)-
≈7200	E G	(5/2,7/2)-
7610.8 12	B	25/2-		1377	100 5	Q	6233.8	21/2-
7927.0 13	B	27/2(-)		1357	100 5	Q	6570.0	23/2(-)
9096.8 16	B	(29/2-)		1486	100 6	Q	7610.8	25/2-
9774.0 16	B	(31/2-)		1847	100 10		7927.0	27/2(-)

E(level)	J^π(level)	T_1/2(level)	Comments
0	3/2-	38.47 m 5 % ε = 100	Q=+0.29 3, μ=-0.28164 5 E(level): K=3/2- band.
192.92	5/2-	0.53 ns 12	E(level): K=3/2- band. J^π(level): From vector-analyzing power in ⁶⁴Zn(pol p,d). T_1/2(level): From RDM in (α,nγ).
247.84	1/2-	33 ps 8	J^π(level): From vector-analyzing power in ⁶⁴Zn(pol p,d). T_1/2(level): From RDM in (α,nγ).
627.11	1/2-		J^π(level): From vector-analyzing power in ⁶⁴Zn(pol p,d).
1023.22	3/2-	> 3.5 ps	J^π(level): From vector-analyzing power in ⁶⁴Zn(pol p,d).
1063.34	7/2-	> 0.29 ps	E(level): K=3/2- band.
1065.28	1/2-	> 0.22 ps	J^π(level): From vector-analyzing power in ⁶⁴Zn(pol p,d).
1206.38	7/2-	> 0.42 ps	J^π(level): From vector-analyzing power in ⁶⁴Zn(pol p,d).
1436.26	9/2-	0.69 ps 21	T_1/2(level): From DSAM in (α,nγ).
1702.96	9/2+	32 ps 4	E(level): K=3/2- band. T_1/2(level): From RDM in (α,nγ).
2050.42	9/2-	> 0.31 ps	E(level): K=3/2- band. J^π(level): From γ(θ) analysis in ⁶³Cu(p,nγ).
2233.30	11/2-	> 1.4 ps	T_1/2(level): From DSAM in (α,nγ).
2261.53	3/2-	0.07 ps +3-2	J^π(level): From γ(θ) analysis in ⁶³Cu(p,nγ).
2288.31	7/2-	> 0.21 ps	J^π(level): From γ(θ) analysis in ⁶³Cu(p,nγ).
2291.46	3/2-	0.06 ps +3-2	J^π(level): From γ(θ) analysis in ⁶³Cu(p,nγ).
2293.0	(3/2-)	0.030 ps +15-10	J^π(level): From γ(θ) analysis in ⁶³Cu(p,nγ).
2318.8	11/2-	0.35 ps 9	E(level): K=3/2- band. T_1/2(level): From DSAM in (α,nγ).
2377.86	9/2+	> 1.39 ps	J^π(level): From γ(θ) analysis in ⁶³Cu(p,nγ).
2584.5	13/2+	3.54 ps 28	T_1/2(level): From RDM in (α,nγ).
2634.53	5/2-,7/2-	0.19 ps 5	XREF: γ(2650).
2911.9	9/2	> 1.4 ps	T_1/2(level): From DSAM in (α,nγ).
3527.4	13/2-		E(level): K=3/2- band.
4354.6	(15/2)-		E(level): K=3/2- band.
5346.5	(21/2)+	< 280 fs	J^π(level): From γ(θ) in (α,nγ), large cross section in (¹²C,2pnγ), and systematics of particle-core coupling states.
5400	(1/2,3/2)-		Possible IAS of ⁶³Cu 3/2- g.s. observed in (p,n).
E(level)	J^π(level)	T_1/2(level)	Comments
5423.4	17/2-		E(level): K=3/2- band.
5915.7	19/2-		E(level): K=3/2- band.
6233.8	21/2-		E(level): K=3/2- band.
6570.0	23/2(-)		E(level): K=3/2- band.
6700	(5/2,7/2)-		Possible IAS of ⁶³Cu 7/2- 1327 level observed in (p,n).
7610.8	25/2-		E(level): K=3/2- band.
7927.0	27/2(-)		E(level): K=3/2- band.
9096.8	(29/2-)		E(level): K=3/2- band.
9774.0	(31/2-)		E(level): K=3/2- band.

E(level)	E(gamma)	Comments
1063.34	413.2	M(γ): From γ(θ) analysis in (p,nγ)
	870.25	M(γ): From γ(θ) analysis in (p,nγ)
	1063.2	M(γ): RUL has been used to determine the parity change. From γ(θ) analysis in (p,nγ)
1284.26	1091.40	M(γ): From γ(θ) analysis in (p,nγ)
1395.44	768.36	E(γ): K=3/2- band. I(γ): Inconsistent with (51 6) from ⁶³Ga ε decay and (90 4) from (α,nγ) M(γ): From γ(θ) analysis in (p,nγ)
	1147.3	M(γ): From γ(θ) analysis in (p,nγ)
	1202.8	M(γ): From γ(θ) analysis in (p,nγ)
1664.86	1027.8	M(γ): From γ(θ) analysis in (p,nγ)
1691.22	1498.3	M(γ): From γ(θ) analysis in (p,nγ)
1702.96	639.5	M(γ): From γ(θ) analysis in (p,nγ)
1909.26	1272.3	M(γ): From γ(θ) analysis in (p,nγ)
	1716.3	M(γ): From γ(θ) analysis in (p,nγ)
	1909.0	M(γ): From γ(θ) analysis in (p,nγ)
2050.42	987.1	M(γ): From γ(θ) analysis in (p,nγ)
2158.10	1530.8	I(γ): Branching ratios from (α,nγ) are different since 1910γ is not recognized as a doublet
2158.10	1910.4	I(γ): Branching ratios from (α,nγ) are different since 1910γ is not recognized as a doublet
2233.30	570.2	E(γ): From ⁶⁰Ni(α,nγ), (HI,xnγ) I(γ): From ⁶⁰Ni(α,nγ), (HI,xnγ)
	796.6	E(γ): From ⁶⁰Ni(α,nγ), (HI,xnγ) I(γ): From ⁶⁰Ni(α,nγ), (HI,xnγ)
	1169.6	E(γ): From ⁶⁰Ni(α,nγ), (HI,xnγ) I(γ): From ⁶⁰Ni(α,nγ), (HI,xnγ)
2249.2	1185.4	I(γ): From (α,nγ). α 50-50 branching ratio obtained from (p,nγ)
2249.2	1599.5	I(γ): From (α,nγ). α 50-50 branching ratio obtained from (p,nγ)
2261.53	1634.4	M(γ): From γ(θ) analysis in (p,nγ)
2261.53	2261.5	M(γ): From γ(θ) analysis in (p,nγ)
2288.31	1638.2	M(γ): From γ(θ) analysis in (p,nγ)
2291.46	1654.2	M(γ): From γ(θ) analysis in (p,nγ)
E(level)	E(gamma)	Comments
2293.0	2045.1	M(γ): From γ(θ) analysis in (p,nγ)
2318.8	1255.6	E(γ): From ⁶⁰Ni(α,nγ), (HI,xnγ) I(γ): From ⁶⁰Ni(α,nγ), (HI,xnγ)
2377.86	674.9	E(γ): From ⁶³Cu(p,nγ).
2584.5	881.3	E(γ): From ⁶⁰Ni(α,nγ), (HI,xnγ) I(γ): From ⁶⁰Ni(α,nγ), (HI,xnγ)
2634.53	1428.1	I(γ): Branching ratios from (α,nγ) are very different because of unresolved 2442γ and 2443γ
2634.53	2441.6	I(γ): Branching ratios from (α,nγ) are very different because of unresolved 2442γ and 2443γ
2826.2	1123.3	E(γ): From ⁶⁰Ni(α,nγ), (HI,xnγ) I(γ): From ⁶⁰Ni(α,nγ), (HI,xnγ)
2911.9	1705.5	E(γ): From ⁶⁰Ni(α,nγ), (HI,xnγ) I(γ): From ⁶⁰Ni(α,nγ), (HI,xnγ)
2933.5	1497.2	E(γ): From ⁶⁰Ni(α,nγ), (HI,xnγ) I(γ): From ⁶⁰Ni(α,nγ), (HI,xnγ)
3480.3	654	E(γ): From ⁶⁰Ni(α,nγ), (HI,xnγ) I(γ): From ⁶⁰Ni(α,nγ), (HI,xnγ)
3480.3	1778	E(γ): From ⁶⁰Ni(α,nγ), (HI,xnγ) I(γ): From ⁶⁰Ni(α,nγ), (HI,xnγ)
3527.4	1209	E(γ): From ⁶⁰Ni(α,nγ), (HI,xnγ) I(γ): From ⁶⁰Ni(α,nγ), (HI,xnγ)
3527.4	1478	E(γ): From ⁶⁰Ni(α,nγ), (HI,xnγ) I(γ): From ⁶⁰Ni(α,nγ), (HI,xnγ)
3762.8	1177.7	E(γ): From ⁶⁰Ni(α,nγ), (HI,xnγ) I(γ): From ⁶⁰Ni(α,nγ), (HI,xnγ)
3769.7	944	E(γ): From ⁶⁰Ni(α,nγ), (HI,xnγ) I(γ): From ⁶⁰Ni(α,nγ), (HI,xnγ)
3769.7	1185	E(γ): From ⁶⁰Ni(α,nγ), (HI,xnγ) I(γ): From ⁶⁰Ni(α,nγ), (HI,xnγ)
3890.9	1306	E(γ): From ⁶⁰Ni(α,nγ), (HI,xnγ) I(γ): From ⁶⁰Ni(α,nγ), (HI,xnγ)
4354.6	591	E(γ): From ⁶⁰Ni(α,nγ), (HI,xnγ) I(γ): From ⁶⁰Ni(α,nγ), (HI,xnγ)
	875	E(γ): From ⁶⁰Ni(α,nγ), (HI,xnγ) I(γ): From ⁶⁰Ni(α,nγ), (HI,xnγ)
	1770	E(γ): From ⁶⁰Ni(α,nγ), (HI,xnγ) I(γ): From ⁶⁰Ni(α,nγ), (HI,xnγ)
4902.2	1139	E(γ): From ⁶⁰Ni(α,nγ), (HI,xnγ) I(γ): From ⁶⁰Ni(α,nγ), (HI,xnγ)
5076.3	1185	E(γ): From ⁶⁰Ni(α,nγ), (HI,xnγ) I(γ): From ⁶⁰Ni(α,nγ), (HI,xnγ)
	1307	E(γ): From ⁶⁰Ni(α,nγ), (HI,xnγ) I(γ): From ⁶⁰Ni(α,nγ), (HI,xnγ)
	1313	E(γ): From ⁶⁰Ni(α,nγ), (HI,xnγ) I(γ): From ⁶⁰Ni(α,nγ), (HI,xnγ)
5346.5	1584.1	E(γ): From ⁶⁰Ni(α,nγ), (HI,xnγ) I(γ): From ⁶⁰Ni(α,nγ), (HI,xnγ) M(γ): from γ(θ) and RUL, (α,pγ)
E(level)	E(gamma)	Comments
5405.9	1879	E(γ): From ⁶⁰Ni(α,nγ), (HI,xnγ) I(γ): From ⁶⁰Ni(α,nγ), (HI,xnγ)
5405.9	2472	E(γ): From ⁶⁰Ni(α,nγ), (HI,xnγ) I(γ): From ⁶⁰Ni(α,nγ), (HI,xnγ)
5423.4	1659	E(γ): From ⁶⁰Ni(α,nγ), (HI,xnγ) I(γ): From ⁶⁰Ni(α,nγ), (HI,xnγ)
	1897	E(γ): From ⁶⁰Ni(α,nγ), (HI,xnγ) I(γ): From ⁶⁰Ni(α,nγ), (HI,xnγ)
	2490	E(γ): From ⁶⁰Ni(α,nγ), (HI,xnγ) I(γ): From ⁶⁰Ni(α,nγ), (HI,xnγ)
5915.7	492	E(γ): From ⁶⁰Ni(α,nγ), (HI,xnγ) I(γ): From ⁶⁰Ni(α,nγ), (HI,xnγ)
	510	E(γ): From ⁶⁰Ni(α,nγ), (HI,xnγ) I(γ): From ⁶⁰Ni(α,nγ), (HI,xnγ)
	1013	E(γ): From ⁶⁰Ni(α,nγ), (HI,xnγ) I(γ): From ⁶⁰Ni(α,nγ), (HI,xnγ)
	1561	E(γ): From ⁶⁰Ni(α,nγ), (HI,xnγ) I(γ): From ⁶⁰Ni(α,nγ), (HI,xnγ)
6233.8	318	E(γ): From ⁶⁰Ni(α,nγ), (HI,xnγ) I(γ): From ⁶⁰Ni(α,nγ), (HI,xnγ)
	810	E(γ): From ⁶⁰Ni(α,nγ), (HI,xnγ) I(γ): From ⁶⁰Ni(α,nγ), (HI,xnγ)
	828	E(γ): From ⁶⁰Ni(α,nγ), (HI,xnγ) I(γ): From ⁶⁰Ni(α,nγ), (HI,xnγ)
	888	E(γ): From ⁶⁰Ni(α,nγ), (HI,xnγ) I(γ): From ⁶⁰Ni(α,nγ), (HI,xnγ)
	1157	E(γ): From ⁶⁰Ni(α,nγ), (HI,xnγ) I(γ): From ⁶⁰Ni(α,nγ), (HI,xnγ)
6487.3	1411	E(γ): From ⁶⁰Ni(α,nγ), (HI,xnγ) I(γ): From ⁶⁰Ni(α,nγ), (HI,xnγ)
6570.0	336	E(γ): From ⁶⁰Ni(α,nγ), (HI,xnγ) I(γ): From ⁶⁰Ni(α,nγ), (HI,xnγ)
	654	E(γ): From ⁶⁰Ni(α,nγ), (HI,xnγ) I(γ): From ⁶⁰Ni(α,nγ), (HI,xnγ)
	1224	E(γ): From ⁶⁰Ni(α,nγ), (HI,xnγ) I(γ): From ⁶⁰Ni(α,nγ), (HI,xnγ)
7610.8	1377	E(γ): From ⁶⁰Ni(α,nγ), (HI,xnγ) I(γ): From ⁶⁰Ni(α,nγ), (HI,xnγ)
7927.0	1357	E(γ): From ⁶⁰Ni(α,nγ), (HI,xnγ) I(γ): From ⁶⁰Ni(α,nγ), (HI,xnγ)
9096.8	1486	E(γ): From ⁶⁰Ni(α,nγ), (HI,xnγ) I(γ): From ⁶⁰Ni(α,nγ), (HI,xnγ)
9774.0	1847	E(γ): From ⁶⁰Ni(α,nγ), (HI,xnγ) I(γ): From ⁶⁰Ni(α,nγ), (HI,xnγ)