List of levels for 68ZN

Author: E.A. Mccutchan | Citation: Nucl. Data Sheets 113, 1735 (2012) | Cutoff date: 1-Mar-2012

E(level) (keV)	J^π(level)	T_1/2(level)	E(γ) (keV)	Multipolarity	Mixing Ratio	Conversion Coefficient	Additional Data
1077.37	2+	1.61 ps 2	1077.34 5	E2		0.000247	B(E2)(W.u.)=14.69 19, α=0.000247 4, α(K)=0.000221 4, α(L)=2.22E-5 4, α(M)=3.18E-6 5, α(N+)=1.273E-7 18
1655.91	0+	96 ps 16	578.52 13	E2		0.001272	B(E2)(W.u.)=5.5 10, α=0.001272 18, α(K)=0.001139 16, α(L)=0.0001160 17, α(M)=1.659E-5 24, α(N+)=6.50E-7 10
1883.20	2+	1.01 ps 5	227.31 15	(E2)		0.0300	B(E2)(W.u.)=16 6, α=0.0300, α(K)=0.0268 4, α(L)=0.00286 4, α(M)=0.000406 6, α(N+)=1.476E-5 21
	2+	1.01 ps 5	805.83 7	M1+E2	-1.55 5	0.000471	B(E2)(W.u.)=28.6 18, B(M1)(W.u.)=0.0050 4, α=0.000471 7, α(K)=0.000422 6, α(L)=4.24E-5 7, α(M)=6.08E-6 9, α(N+)=2.43E-7 4
	2+	1.01 ps 5	1883.16 6	(E2)		0.000333	B(E2)(W.u.)=0.85 5, α=0.000333 5, α(K)=6.97E-5 10, α(L)=6.91E-6 10, α(M)=9.91E-7 14, α(N+)=0.000255 4
2338.45	2+	0.31 ps 3	682.57 16	(E2)		0.000789	B(E2)(W.u.)=2.4 3, α=0.000789 11, α(K)=0.000707 10, α(L)=7.16E-5 10, α(M)=1.025E-5 15, α(N+)=4.05E-7
	2+	0.31 ps 3	1261.08 6	M1+E2	-0.16 2	0.0001725	B(E2)(W.u.)=0.85 23, B(M1)(W.u.)=0.034 4, α=0.0001725 25, α(K)=0.0001418 20, α(L)=1.410E-5 20, α(M)=2.02E-6 3, α(N+)=8.20E-8 12
	2+	0.31 ps 3	2338.40 8	(E2)		0.000529	B(E2)(W.u.)=0.019 4, α=0.000529 8, α(K)=4.71E-5 7, α(L)=4.67E-6 7, α(M)=6.69E-7 10, α(N+)=0.000476 7
2417.40	4+	0.73 ps 7	534.22 20	(E2)		0.001618	B(E2)(W.u.)=6.0 19, α=0.001618 23, α(K)=0.001448 21, α(L)=0.0001478 21, α(M)=2.11E-5 3, α(N+)=8.25E-7
2417.40	4+	0.73 ps 7	1339.96 5	E2		0.000190	B(E2)(W.u.)=10.8 12, α=0.000190 3, α(K)=0.0001368 20, α(L)=1.364E-5 20, α(M)=1.95E-6 3, α(N+)=3.77E-5 7
2750.76	3-	0.257 ps 6	412.41 12	(E1)		0.000964	B(E1)(W.u.)=0.00161 17, α=0.000964 14, α(K)=0.000865 13, α(L)=8.65E-5 13, α(M)=1.237E-5 18, α(N+)=4.92E-7
2750.76	3-	0.257 ps 6	1673.29 10	(E1)		0.000445	B(E1)(W.u.)=0.00031 3, α=0.000445 7, α(K)=4.66E-5 7, α(L)=4.61E-6 7, α(M)=6.60E-7 10, α(N+)=0.000393 6
2821.79	2+	0.15 ps 3	483.35 16	M1+E2		0.0017	α=0.0017 5, α(K)=0.0015 5, α(L)=0.00016 5, α(M)=2.2×10^-5 7, α(N+)=9.E-7 3
	2+	0.15 ps 3	938.61 20	M1+E2	-0.7 3	0.000304	B(E2)(W.u.)=1.8 11, B(M1)(W.u.)=0.0020 8, α=0.000304 12, α(K)=0.000272 11, α(L)=2.72E-5 11, α(M)=3.90E-6 16, α(N+)=1.57E-7 6
	2+	0.15 ps 3	1165.92 15	E2		0.000211	B(E2)(W.u.)=0.16 11, α=0.000211 3, α(K)=0.000185 3, α(L)=1.85E-5 3, α(M)=2.65E-6 4, α(N+)=4.67E-6 7
	2+	0.15 ps 3	1744.42 13	M1+E2	+0.27 5	0.000241	B(E2)(W.u.)=0.9 4, B(M1)(W.u.)=0.023 5, α=0.000241 4, α(K)=7.70E-5 11, α(L)=7.63E-6 11, α(M)=1.094E-6 16, α(N+)=0.0001550
	2+	0.15 ps 3	2821.73 14	(E2)		0.000740	B(E2)(W.u.)=0.057 13, α=0.000740 11, α(K)=3.43E-5 5, α(L)=3.39E-6 5, α(M)=4.86E-7 7, α(N+)=0.000702 10
3009.27	3+	0.28 ps +14-8	1126.07 6	M1+E2	-0.36 +20-27	0.000201	B(E2)(W.u.)=6 +7-6, B(M1)(W.u.)=0.040 +13-21, α=0.000201 6, α(K)=0.000179 5, α(L)=1.79E-5 5, α(M)=2.56E-6 7, α(N+)=1.39E-6 10
3009.27	3+	0.28 ps +14-8	1932.1 3	(M1+E2)	-0.15 3	0.000301	B(E2)(W.u.)=0.010 +5-7, B(M1)(W.u.)=0.0010 +4-6, α=0.000301 5, α(K)=6.39E-5 9, α(L)=6.33E-6 9, α(M)=9.07E-7 13, α(N+)=0.000230 4
3102.51	0+		1219.3 1	[E2]		0.000199	α=0.000199 3, α(K)=0.0001676 24, α(L)=1.674×10^-5 24, α(M)=2.40E-6 4, α(N+)=1.185E-5
3287.09	2+	0.08 ps +2-1	2209.75 16	(M1+E2)		0.00044	α=0.00044 4, α(K)=5.12×10^-5 12, α(L)=5.07E-6 12, α(M)=7.27E-7 16, α(N+)=0.00038 4
3346.09	1+	6.1 fs 16	3346.0 2	(M1)		0.000856	B(M1)(W.u.)=0.060 21, α=0.000856 12, α(K)=2.53×10^-5 4, α(L)=2.50E-6 4, α(M)=3.58E-7 5, α(N+)=0.000828 12
3458.83	5-		1041.26 16	(E1+M2)	+0.07 5	0.000120	α=0.000120 4, α(K)=0.000108 4, α(L)=1.07×10^-5 4, α(M)=1.53E-6 6, α(N+)=6.17E-8 22
3610.8	(6)-	< 2.5 ns	152.0 5	M1(+E2)	-0.05 +8-6	0.0205	B(M1)(W.u.)>0.0024, α=0.0205 12, α(K)=0.0183 10, α(L)=0.00190 12, α(M)=0.000272 16, α(N+)=1.07×10^-5 6
3687.5	(6+)		1270.1 5	(E2+M3)	+0.14 5	0.000201	α=0.000201 8, α(K)=0.000161 7, α(L)=1.61×10^-5 7, α(M)=2.30E-6 10, α(N+)=2.13E-5 5
E(level) (keV)	J^π(level)	T_1/2(level)	E(γ) (keV)	Multipolarity	Mixing Ratio	Conversion Coefficient	Additional Data
3849.30	4+	0.16 ps +15-6	1511.1 7	[E2]		0.000210	B(E2)(W.u.)=3.1 +19-31, α=0.000210 3, α(K)=0.0001068 15, α(L)=1.063E-5 15, α(M)=1.523E-6 22, α(N)=6.15E-8 9
3942.9	(7-)	< 6 ns	332.1 5			0.00771	α=0.00771 12
4396.8	(8+)		709.3 5	E2(+M3)	+0.05 +2-8	0.000716	α=0.000716 12, α(K)=0.000642 11, α(L)=6.49×10^-5 11, α(M)=9.30E-6 16, α(N+)=3.67E-7 7
4466.2	1-	7.0 fs +29-16	4466 2	[E1]		0.00186	B(E1)(W.u.)=0.00065 +15-27, α=0.00186 3, α(K)=1.208E-5 17, α(L)=1.188E-6 17, α(M)=1.702E-7 24, α(N+)=0.00184 3

Q(β-)=-2921.1 keV 12	S(n)= 10198.10 keV 19	S(p)= 9977.0 keV 16	Q(α)= -5333.3 keV 9
Reference: 2012WA38

References:
A	⁶⁸Cu β^- decay (30.9 S)	B	⁶⁸Cu β^- decay (3.75 M)
C	⁶⁸Ga ε decay	D	⁶⁵Cu(α,pγ)
E	⁶⁶Zn(t,p)	F	⁶⁷Zn(n,γ) E=THERMAL
G	⁶⁷Zn(d,p)	H	⁶⁸Zn(γ,γ’)
I	⁶⁸Zn(n,n’γ)	J	⁶⁸Zn(p,p’)
K	⁶⁸Zn(E,E’)	L	Coulomb Excitation
M	Coulomb Excitation: PROJECTILE	N	⁷⁰Zn(p,t)
O	⁶⁸Zn(α,α’)	P	⁶⁸Zn(p,p’γ)
Q	⁶⁸Zn(²⁸Si,²⁹Si),(²⁸Si,³⁰Si)	R	⁶⁸Zn(d,d’),(³He,³He’)
S	²⁶Mg(⁴⁸Ca,α2nγ)	T	⁶⁵Cu(α,p)
U	⁶⁴Ni(⁶Li,d)	V	⁶⁶Zn(α,²He)
W	⁶⁹Ga(d,³He)	X	²⁰⁸Pb(⁶⁴Ni,xγ)

E(level) (keV)	XREF	J^π(level)	T_1/2(level)	E(γ) (keV)	I(γ)	M(γ)	Final Levels
0.0	A B C D E F G H I J K L M N O P R T U V W X	0+	STABLE
1077.37 4	A B C D E F G H I J K L M N O P Q R T U V W X	2+	1.61 ps 2	1077.34 5	100	E2	0.0	0+
1655.91 8	A C E F H I J M N O P R W	0+	96 ps 16	578.52 13 1659 7	100 5	E2 E0	1077.37 0.0	2+ 0+
1883.20 5	A C D E F G I J K M N O P R T U W	2+	1.01 ps 5	227.31 15 805.83 7 1883.16 6	0.049 16 68.0 17 100.0 19	(E2) M1+E2 (E2)	1655.91 1077.37 0.0	0+ 2+ 0+
2338.45 5	A B C E F G I J M N O U W	2+	0.31 ps 3	682.57 16 1261.08 6 2338.40 8	0.331 21 100.0 21 1.19 17	(E2) M1+E2 (E2)	1655.91 1077.37 0.0	0+ 2+ 0+
2370.3 15	A B R T V			1292.9 15	100		1077.37	2+
2417.40 6	B D E F G I J M N O U W X	4+	0.73 ps 7	534.22 20 1339.96 5	0.56 16 100 3	(E2) E2	1883.20 1077.37	2+ 2+
2510.2 15	A B N			1432.8 15	100		1077.37	2+
2750.76 8	A E F G I J K L M N O Q R U V	3-	0.257 ps 6	412.41 12 1673.29 10	7.7 6 100 7	(E1) (E1)	2338.45 1077.37	2+ 2+
2821.79 8	A B C E F G H I J N U W	2+	0.15 ps 3	483.35 16 938.61 20 1165.92 15 1744.42 13 2821.73 14	2.8 3 1.86 17 0.17 10 100 5 4.9 4	M1+E2 M1+E2 E2 M1+E2 (E2)	2338.45 1883.20 1655.91 1077.37 0.0	2+ 2+ 0+ 2+ 0+
2955.9 22	B E G J N W			585.6 15	100		2370.3
2959.49 13	E F G I N O U W X	(4+)		542.05 16 1883.1 5	12.0 20 100 27		2417.40 1077.37	4+ 2+
3009.27 7	F G I J W	3+	0.28 ps +14-8	591.71 16 670.89 17 1126.07 6 1932.1 3	5.7 6 4.8 6 100 5 11.7 12	M1+E2 (M1+E2)	2417.40 2338.45 1883.20 1077.37	4+ 2+ 2+ 2+
3102.51 11	E F I P	0+		1219.3 1 2025.1?	100 ≤3	[E2]	1883.20 1077.37	2+ 2+
E(level) (keV)	XREF	J^π(level)	T_1/2(level)	E(γ) (keV)	I(γ)	M(γ)	Final Levels
3153.8 4 ?	E I			815.7 5 ? 1270.0 5 ?	100 21 <79		2338.45 1883.20	2+ 2+
3160.1 3	E I O			2082.7 3	100		1077.37	2+
3164.4 14	I J O			747.0 14 ?	100		2417.40	4+
3184.18 13	F G I R W	1,2+	22 fs 6	845.2 6 1300.87 20 2106.83 18 3184.3 6	6.5 15 25.5 20 100 15 32 4		2338.45 1883.20 1077.37 0.0	2+ 2+ 2+ 0+
3186.6 11	A G J R W	(1,2+)		1529.7 15 2110.1 15	56 17 100 28		1655.91 1077.37	0+ 2+
3281.58 16	E F I N R W	4+		864.17 14 1397.0 6 ?	100 9 18 3		2417.40 1883.20	4+ 2+
3287.09 13	F G I J N R W	2+	0.08 ps +2-1	465.20 18 ? 1403.7 3 1630.9 3 2209.75 16 3287.2 3	1.6 3 4.3 14 14.5 14 100 12 48 5	(M1+E2)	2821.79 1883.20 1655.91 1077.37 0.0	2+ 2+ 0+ 2+ 0+
3334.7?	F			996.2 5 ? 1451.8 6 ? 2257.2 7 ?	52 14 62 14 100 19		2338.45 1883.20 1077.37	2+ 2+ 2+
3346.09 20	H I J N T W	1+	6.1 fs 16	1462.0 23 ? 2270 3 3346.0 2	27 10 34 11 100 17	(M1)	1883.20 1077.37 0.0	2+ 2+ 0+
3386 3 ?	I			2310 3 ? 3383 5 ?	100 50 30 17		1077.37 0.0	2+ 0+
3400.9 5	I	1,2+	45 fs +17-14	1517.7 5 2322 3 ? 3402 5	89 22 100 45 24 12		1883.20 1077.37 0.0	2+ 2+ 0+
3425.07 15	E F G I W			1542.0 2 2347.5 2	53 5 100 15		1883.20 1077.37	2+ 2+
E(level) (keV)	XREF	J^π(level)	T_1/2(level)	E(γ) (keV)	I(γ)	M(γ)	Final Levels
3429.46 15	E F I J R W	1,2+		1091.04 18 ? 1546.13 16 2352.4 3 3430.2 11	28 2 100 8 50 10 12 4		2338.45 1883.20 1077.37 0.0	2+ 2+ 2+ 0+
3451.0 3	I N O R			630.0 13 1114.0 18 ? 2373.5 3 ?	46 19 95 40 100 26		2821.79 2338.45 1077.37	2+ 2+ 2+
3458.83 16	B D E F G I J N O U X	5-		499.9 5 ? 1041.26 16		(E1+M2)	2959.49 2417.40	(4+) 4+
3487.7 15	A E W			736.9 15	100		2750.76	3-
3496.08 11	E F I J W	3+,4+	62 fs 10	744.8 6 1612.2 6 2418.7 1	3.1 15 5.4 15 100 12		2750.76 1883.20 1077.37	3- 2+ 2+
3586.64 10	E F G I J N R	4+		835.87 6 2508 4	100 19 46 13		2750.76 1077.37	3- 2+
3610.8 6	B D G O X	(6)-	< 2.5 ns	152.0 5	100	M1(+E2)	3458.83	5-
3622 5	E J	3-
3624.32 21	I	(1,2+)		2546.9 2 3626 5	100 25 26 12		1077.37 0.0	2+ 0+
3630.32 11	F I R	(2+)		348.7 3 ? 621.06 14 879.59 15 1212.7 3 3630.2 6	3.5 7 42 4 100 13 23 3 68 9		3281.58 3009.27 2750.76 2417.40 0.0	4+ 3+ 3- 4+ 0+
3664.7 3	F G I J W	(1,2)+		1781.5 3 2587.2 7 3664.8 10	100 10 65 19 36 9		1883.20 1077.37 0.0	2+ 2+ 0+
3687.5 5	D E I X	(6+)		1270.1 5	100	(E2+M3)	2417.40	4+
3709.8 3	E I J N	(2+)		1371.6 3 3708.2 8	100 19 71 10		2338.45 0.0	2+ 0+
E(level) (keV)	XREF	J^π(level)	T_1/2(level)	E(γ) (keV)	I(γ)	M(γ)	Final Levels
3717.47 20	E H I O	1,2+		2061.5 2 3717.5 5	58 9 100 10		1655.91 0.0	0+ 0+
3725.79 17	B F I J O		33 fs +9-6	904.6 4 975.4 4 ? 1387.21 19 2648.1 6	11 3 13 3 63 5 100 30		2821.79 2750.76 2338.45 1077.37	2+ 3- 2+ 2+
3732.4 10 ?	B V			1222.2 15 ?	100		2510.2
3776.32 23	F G I J R U	1,2+		1437.76 24 2699.5 10 3777.0 9 ?	62 5 35 11 100 18		2338.45 1077.37 0.0	2+ 2+ 0+
3814 4	E G	(3)-
3814.83 21	F I	1,2+	24 fs +8-6	2737.4 2 3817 5	100 27 37 6		1077.37 0.0	2+ 0+
3849.30 22	E F G I J O	4+	0.16 ps +15-6	1431.86 22 1511.1 7	100 9 13 6	[E2]	2417.40 2338.45	4+ 2+
3895.83 17	E F I J N	4+		936.7 3 1478.31 18 1557.1 6	22 5 100 8 8 4		2959.49 2417.40 2338.45	(4+) 4+ 2+
3910.99 24	F G I R	(3)-		629.3 3 ? 1493.5 3 1572.5 9 2027.9 4	29 7 95 12 22 7 100 15		3281.58 2417.40 2338.45 1883.20	4+ 4+ 2+ 2+
3929 4 ?	E I R			2852 4 ?	100		1077.37	2+
3935.08 18	E F I J O	3+		1113.34 20 1184.5 3 ? 1596.3 5 2857.6 4 3935.1 13	9.6 12 12 3 7.6 20 100 28 6 3		2821.79 2750.76 2338.45 1077.37 0.0	2+ 3- 2+ 2+ 0+
3942.9 8	D G O T V X	(7-)	< 6 ns	332.1 5	100		3610.8	(6)-
3970.7 12 ?	B J			1014.5 15 ? 1149.4 20 ?	100 45 32 13		2955.9 2821.79	2+
E(level) (keV)	XREF	J^π(level)	T_1/2(level)	E(γ) (keV)	I(γ)	M(γ)	Final Levels
3989 5 ?	I			3989 5 ?	100		0.0	0+
4027.7 4	F G I N	(1-,2+)		1018.3 4 1276.9 6 4028.3 8	16 5 27 11 100 14		3009.27 2750.76 0.0	3+ 3- 0+
4061.0 3	E G I J	(2)+	62 fs +21-17	1724 3 2983.5 3	65 20 100 15		2338.45 1077.37	2+ 2+
4096 10	J
4102 5 ?	I			4102 5 ?	100		0.0	0+
4110	N	4+
4124 10	J	(4-,5-,6-)
4139.2 17	F G I	1-	33 fs +12-9	3062.4 5 ? 4139.1 17	100 10 19 9		1077.37 0.0	2+ 0+
4148 7	E J R	0+
4215.4 6	F G I J	1+,2+		3137.8 6 4215.9 15	100 16 27 12		1077.37 0.0	2+ 0+
4229 4 ?	I O			3152 4 ?	100		1077.37	2+
4234 4	I J O	(0,1,2)-		3157 4 ?	100		1077.37	2+
4252	E N
4284.0 4	E F G I J	(2,3)+		1274.8 8 1533.2 4 3206.4 9	20 8 39 8 100 14		3009.27 2750.76 1077.37	3+ 3- 2+
4325 6	G I R			4325 6	100		0.0	0+
4339.1 20	H I O	(1)	12.0 fs +43-25	4339 2	100		0.0	0+
4345 10	J	3+,4+,5+
4355 10	G
4393 7	G J	3+,4+
4396.8 7	D V X	(8+)		709.3 5	100	E2(+M3)	3687.5	(6+)
4408.4 4	F I J			1448.8 5 3331.0 4	13 3 100 10		2959.49 1077.37	(4+) 2+
4414 6	I J	1+,2+		4414 6	100		0.0	0+
E(level) (keV)	XREF	J^π(level)	T_1/2(level)	E(γ) (keV)	I(γ)	M(γ)	Final Levels
4437 5	G I J			3360 5 ? 4440 6	100 17 <164		1077.37 0.0	2+ 0+
4444 6	I J	(1,2+)		4444 6	100		0.0	0+
4466.2 20	G H I	1-	7.0 fs +29-16	4466 2	100	[E1]	0.0	0+
4496 6	I J	(1,2+)		4496 6	100		0.0	0+
4503.2 20	H I	(1)		3427 5 ? 4503 2	≤150 100 40		1077.37 0.0	2+ 0+
4512.2 3	F	(2+)		2094.6 3 3434.9 8 4513.3 8	100 12 78 16 80 14		2417.40 1077.37 0.0	4+ 2+ 0+
4520.6 4	F I J	1,2+		1698.0 8 ? 2181.7 5 4521.0 6	25 7 46 8 100 9		2821.79 2338.45 0.0	2+ 2+ 0+
4535.6 4	F I J U	1,2+		3458.1 4 4535.5 9	100 12 30 6		1077.37 0.0	2+ 0+
4578 6	I U	(1,2+)		4578 6	100		0.0	0+
4587 4	I J	(1+,2+)		3511 5 4585 6	100 16 28 9		1077.37 0.0	2+ 0+
4608 6	G I J	(1-)		4608 6	100		0.0	0+
4642 4	F I J	1,2+		2300 3 ? 3567 5 4639 6	37 30 100 18 42 18		2338.45 1077.37 0.0	2+ 2+ 0+
4656 10	G	2-,3-
4670 6	I	(1,2+)		3592 5 ? 4670 6	100 56 62 41		1077.37 0.0	2+ 0+
4680 6	I J			4680 6	100		0.0	0+
4724.1 5	F I J	1+,2+		1902.2 5 4724.3 8	61 16 100 14		2821.79 0.0	2+ 0+
4732.8 11	F	1,2+		1723.5 5 ? 3077.2 8 ? 3655.2 16 4732.8 14	42 9 100 20 44 22 38 11		3009.27 1655.91 1077.37 0.0	3+ 0+ 2+ 0+
E(level) (keV)	XREF	J^π(level)	T_1/2(level)	E(γ) (keV)	I(γ)	M(γ)	Final Levels
4743 5	G I J	2-,3-		3666 5 ?	100		1077.37	2+
4792 6	I J			4792 6	100		0.0	0+
4851.2 6	F G J	2-,3-		916.1 4 ? 1186.9 6 ? 2512.7 6	9 4 16 5 100 30		3935.08 3664.7 2338.45	3+ (1,2)+ 2+
4857.9 6	F I	1,2+		3201.1 9 4858.4 8	88 21 100 18		1655.91 0.0	0+ 0+
4865.9 8	X	(9-)		923.0 5	100		3942.9	(7-)
4873 4	I J	2-,3-,4-		2122 3 ? 2990 4	100 58 ≤344		2750.76 1883.20	3- 2+
4910.6 4	F I	1,2+		3027.7 14 ? 3254.4 10 3833.1 4	11 6 13 6 100 12		1883.20 1655.91 1077.37	2+ 0+ 2+
4951.5 4	F G I	1-,2-,3-		1767.2 4 3068.8 8 3874.1 8	30 6 37 9 100 23		3184.18 1883.20 1077.37	1,2+ 2+ 2+
4963.0 7	F			3885.5 7	100		1077.37	2+
4982 6	I			4982 6	100		0.0	0+
4992.0 10	F I	1,2+		3107.5 15 ? 3913.9 18 4992.0 11	85 41 100 29 76 18		1883.20 1077.37 0.0	2+ 2+ 0+
5019 10	G U	-
5120 10	G V	-
5146 5	I			2732 4 ? 4069 5 ?	100 47 <6		2417.40 1077.37	4+ 2+
5162 10	G
5187.7 7	F			2770.4 7 4109.8 13	100 30 31 14		2417.40 1077.37	4+ 2+
5200 10	G	2-,3-
5283.4 6	F G			2866.1 7 2944.5 9 ? 3399.8 11	100 30 52 15 52 17		2417.40 2338.45 1883.20	4+ 2+ 2+
E(level) (keV)	XREF	J^π(level)	T_1/2(level)	E(γ) (keV)	I(γ)	M(γ)	Final Levels
5298.0 4	F	1-,2+		2547.0 4 2959.7 8 ? 3415.6 9 4221.7 17 5297.3 11	100 30 43 13 91 26 29 15 30 7		2750.76 2338.45 1883.20 1077.37 0.0	3- 2+ 2+ 2+ 0+
5307.5 10	F G	-		3651.5 10	100		1655.91	0+
5400.4 5	F			2391.2 6 2982.9 6	50 11 100 30		3009.27 2417.40	3+ 4+
5403.2 5	F I	1,2+		3519.4 6 5403.9 8	100 22 76 10		1883.20 0.0	2+ 0+
5415.3 8	F G	1,2+		4337.3 15 5415.3 9	100 37 57 12		1077.37 0.0	2+ 0+
5420?	G
5565.0 8	F			2814.4 11 3147.3 11 3226.4 7 ?	58 18 52 16 100 14		2750.76 2417.40 2338.45	3- 4+ 2+
5610?	G
5635 10	G	(-)
5693.8 6	F			3276.3 6	100		2417.40	4+
5860	G	-
5990.7 9	X	(11-)		1124.7 5	100		4865.9	(9-)
6760	G	-
7110	G	2-,3-
7362.3 5	H	1-	0.240 fs +14-12	4540 5706 6285 7362		E1	2821.79 1655.91 1077.37 0.0	2+ 0+ 2+ 0+
X	S	J
1506.0+X 10	S	J+2		1506		Q	X	J
3223.0+X 15	S	J+4		1717		Q	1506.0+X	J+2
E(level) (keV)	XREF	J^π(level)	T_1/2(level)	E(γ) (keV)	I(γ)	M(γ)	Final Levels
5141.1+X 18	S	J+6		1918		Q	3223.0+X	J+4
7262.1+X 20	S	J+8		2121		Q	5141.1+X	J+6
9593.1+X 23	S	J+10		2331		Q	7262.1+X	J+8
12148.2+X 25	S	J+12		2555		Q	9593.1+X	J+10
14943+X 3	S	J+14		2795			12148.2+X	J+12
18016+X?	S	J+16		3073?			14943+X	J+14

E(level)	J^π(level)	T_1/2(level)	Comments
0.0	0+	STABLE	E(level): Yrast band (2000Wi18,1997Be77). From ⁶⁸Ga ε decay.
1077.37	2+	1.61 ps 2	Q=-0.106 16, μ=+1.08 6 E(level): Yrast band (2000Wi18,1997Be77). From ⁶⁸Ga ε decay. J^π(level): From L transfer in (t,p) and (p,t).
2338.45	2+	0.31 ps 3	J^π(level): From L transfer in (t,p) and (p,t).
2417.40	4+	0.73 ps 7	μ=+0.56 52 E(level): Yrast band (2000Wi18,1997Be77). From ⁶⁸Ga ε decay.
2510.2			XREF: n(?).
2750.76	3-	0.257 ps 6	μ=1.08 72 J^π(level): From L transfer in (t,p) and (p,t).
2821.79	2+	0.15 ps 3	J^π(level): From L transfer in (t,p) and (p,t). T_1/2(level): From DSAM in (n,n’γ).
2955.9			E(level): From ²⁰⁸Pb(⁶⁴Ni,Xγ). ΔEγ=0.5 keV assumed by evaluator. J^π(level): L(t,p)=4 for E=2955 10, L(p,t)=4, 4⁺(2) for E=2957, L(d,p)=(1)+(3) for E=2958 4.
2959.49	(4+)		E(level): From ²⁰⁸Pb(⁶⁴Ni,Xγ). ΔEγ=0.5 keV assumed by evaluator. J^π(level): L(t,p)=4 for E=2955 10, L(p,t)=4, 4⁺(2) for E=2957, L(d,p)=(1)+(3) for E=2958 4.
3009.27	3+	0.28 ps +14-8	T_1/2(level): From DSAM in (n,n’γ).
3153.8			E(level): From (n,n’γ). J^π(level): L(t,p)=0 for possible doublet at 3157 10.
3160.1			E(level): From (n,n’γ). J^π(level): L(t,p)=0 for possible doublet at 3157 10.
3184.18	1,2+	22 fs 6	J^π(level): γ’s to 0⁺ and 2⁺; primary γ from 2-,3- capture state. T_1/2(level): From DSAM in (n,n’γ).
3281.58	4+		J^π(level): From L transfer in (t,p) and (p,t).
3287.09	2+	0.08 ps +2-1	T_1/2(level): From DSAM in (n,n’γ).
3346.09	1+	6.1 fs 16	T_1/2(level): From Γ measurement in (γ,γ’). For the 4339 and 4466 levels, Γ_γ0/Γ_γ is assumed to be 1. Thus, the deduced half-life may be an upper limit.
3400.9	1,2+	45 fs +17-14	J^π(level): d,E2 γ to g.s. T_1/2(level): From DSAM in (n,n’γ).
3425.07			J^π(level): L(t,p)=2 for 3427 10, L(d,p)=1 for 3424 4.
3429.46	1,2+		J^π(level): γ’s to 0⁺ and 2⁺; primary γ from 2-,3- capture state. L(t,p)=2 for 3427 10, L(d,p)=1 for 3424 4.
3458.83	5-		XREF: J(3465). J^π(level): From L transfer in (t,p) and (p,t).
3496.08	3+,4+	62 fs 10	T_1/2(level): From DSAM in (n,n’γ).
3586.64	4+		XREF: J(3595)n(3577). J^π(level): From L transfer in (t,p) and (p,t).
3664.7	(1,2)+		XREF: J(3658).
3687.5	(6+)		E(level): Yrast band (2000Wi18,1997Be77). From ⁶⁸Ga ε decay.
3709.8	(2+)		XREF: J(3701)n(3701).
E(level)	J^π(level)	T_1/2(level)	Comments
3717.47	1,2+		J^π(level): d,E2 γ to g.s.
3725.79		33 fs +9-6	T_1/2(level): From DSAM in (n,n’γ).
3776.32	1,2+		XREF: γ(3769)J(3783). J^π(level): γ’s to 0⁺ and 2⁺; primary γ from 2-,3- capture state.
3814	(3)-		XREF: E(3806)γ(3815).
3814.83	1,2+	24 fs +8-6	J^π(level): d,E2 γ to g.s. T_1/2(level): From DSAM in (n,n’γ).
3849.30	4+	0.16 ps +15-6	XREF: E(3841)J(3840). T_1/2(level): From DSAM in (n,n’γ).
3895.83	4+		XREF: E(3886)J(3888).
3942.9	(7-)	< 6 ns	Configuration: (f_5/2g_9/2)_7- (1990Fi07,1985Ja02). E(level): Configuration: (f_5/2g_9/2)_7- (1990Fi07,1985Ja02).
4027.7	(1-,2+)		XREF: n(4017).
4061.0	(2)+	62 fs +21-17	XREF: E(4049). T_1/2(level): From DSAM in (n,n’γ).
4139.2	1-	33 fs +12-9	T_1/2(level): From DSAM in (n,n’γ).
4148	0+		XREF: R(4170).
4215.4	1+,2+		XREF: J(4205).
4234	(0,1,2)-		XREF: J(4240).
4284.0	(2,3)+		XREF: J(4278).
4325			XREF: γ(4303).
4339.1	(1)	12.0 fs +43-25	T_1/2(level): From Γ measurement in (γ,γ’). For the 4339 and 4466 levels, Γ_γ0/Γ_γ is assumed to be 1. Thus, the deduced half-life may be an upper limit.
4396.8	(8+)		Configuration: (g_9/2)² (1990Fi07,1985Ja02). E(level): Configuration: (g_9/2)² (1990Fi07,1985Ja02). Yrast band (2000Wi18,1997Be77). From ⁶⁸Ga ε decay.
4437			XREF: γ(4425).
4466.2	1-	7.0 fs +29-16	XREF: γ(4452). T_1/2(level): From Γ measurement in (γ,γ’). For the 4339 and 4466 levels, Γ_γ0/Γ_γ is assumed to be 1. Thus, the deduced half-life may be an upper limit.
4520.6	1,2+		J^π(level): γ’s to 0⁺ and 2⁺; primary γ from 2-,3- capture state.
4535.6	1,2+		XREF: J(4545). J^π(level): γ’s to 0⁺ and 2⁺; primary γ from 2-,3- capture state.
4642	1,2+		J^π(level): γ’s to 0⁺ and 2⁺; primary γ from 2-,3- capture state.
4724.1	1+,2+		XREF: I(4718).
4732.8	1,2+		J^π(level): γ’s to 0⁺ and 2⁺; primary γ from 2-,3- capture state.
E(level)	J^π(level)	T_1/2(level)	Comments
4792			XREF: J(4782).
4851.2	2-,3-		XREF: J(4841).
4910.6	1,2+		J^π(level): γ’s to 0⁺ and 2⁺; primary γ from 2-,3- capture state.
4992.0	1,2+		XREF: I(4998). J^π(level): γ’s to 0⁺ and 2⁺; primary γ from 2-,3- capture state.
5307.5	-		XREF: γ(5317).
5403.2	1,2+		J^π(level): γ’s to 0⁺ and 2⁺; primary γ from 2-,3- capture state.
5415.3	1,2+		J^π(level): γ’s to 0⁺ and 2⁺; primary γ from 2-,3- capture state.
7362.3	1-	0.240 fs +14-12	T_1/2(level): From Γ measurement in (γ,γ’). For the 4339 and 4466 levels, Γ_γ0/Γ_γ is assumed to be 1. Thus, the deduced half-life may be an upper limit.
X	J		E(level): Super-deformed band (1999De20).
1506.0+X	J+2		E(level): Super-deformed band (1999De20).
3223.0+X	J+4		E(level): Super-deformed band (1999De20).
5141.1+X	J+6		E(level): Super-deformed band (1999De20).
7262.1+X	J+8		E(level): Super-deformed band (1999De20).
9593.1+X	J+10		E(level): Super-deformed band (1999De20).
12148.2+X	J+12		E(level): Super-deformed band (1999De20).
14943+X	J+14		E(level): Super-deformed band (1999De20).
18016+X	J+16		E(level): Super-deformed band (1999De20).

E(level)	E(gamma)	Comments
1077.37	1077.34	E(γ): Yrast band (2000Wi18,1997Be77).. From ⁶⁸Ga ε decay. M(γ): Q from γγ(θ) in (n,γ) and ⁶⁸Ga ε decay; E2 from comparison to RUL
1655.91	578.52	E(γ): Yrast band (2000Wi18,1997Be77).. From ⁶⁸Ga ε decay. I(γ): From ⁶⁸Ga ε decay. M(γ): Q from γγ(θ) in (n,γ) and ⁶⁸Ga ε decay; E2 from comparison to RUL.
1655.91	1659	E(γ): Yrast band (2000Wi18,1997Be77).. From ⁶⁸Ga ε decay. M(γ): From ce data in (p,p’γ) or ⁶⁸Ga ε decay.
1883.20	227.31	E(γ): Yrast band (2000Wi18,1997Be77).. From ⁶⁸Ga ε decay. I(γ): weighted average of 0.043 16 from (n,γ), E=thermal and 0.09 4 from ⁶⁸Ga ε decay M(γ): d,E2 from RUL; ΔJπ=2,no from level scheme
	805.83	E(γ): Yrast band (2000Wi18,1997Be77).. From ⁶⁸Ga ε decay. I(γ): weighted average of 65 3 from (n,γ), E=thermal and 68.9 17 from ⁶⁸Ga ε decay M(γ): D+Q from γγ(θ), M1⁺E2 from comparison to RUL.
	1883.16	E(γ): Yrast band (2000Wi18,1997Be77).. From ⁶⁸Ga ε decay. I(γ): From ⁶⁸Ga ε decay. M(γ): d,E2 from RUL; ΔJπ=2,no from level scheme
2338.45	682.57	E(γ): Yrast band (2000Wi18,1997Be77).. From ⁶⁸Ga ε decay. I(γ): From ⁶⁸Ga ε decay. M(γ): d,E2 from RUL; ΔJπ=2,no from level scheme
	1261.08	E(γ): Yrast band (2000Wi18,1997Be77).. From ⁶⁸Ga ε decay. I(γ): From ⁶⁸Ga ε decay. M(γ): D+Q from γγ(θ), M1⁺E2 from comparison to RUL.
	2338.40	E(γ): Yrast band (2000Wi18,1997Be77).. From ⁶⁸Ga ε decay. I(γ): From ⁶⁸Ga ε decay. M(γ): d,E2 from RUL; ΔJπ=2,no from level scheme
2417.40	534.22	M(γ): d,E2 from RUL; ΔJπ=2,no from level scheme
2417.40	1339.96	M(γ): Q from γγ(θ) in (n,γ), E2 from comparison to RUL.
2750.76	412.41	M(γ): d from RUL; Δπ=yes from level scheme
2750.76	1673.29	M(γ): d,E2 from RUL; Δπ=yes from level scheme
2821.79	483.35	E(γ): Yrast band (2000Wi18,1997Be77).. From ⁶⁸Ga ε decay. I(γ): From ⁶⁸Ga ε decay. M(γ): D+Q from γγ(θ), M1⁺E2 from comparison to RUL.
	938.61	E(γ): Yrast band (2000Wi18,1997Be77).. From ⁶⁸Ga ε decay. I(γ): From ⁶⁸Ga ε decay. M(γ): D+Q from γγ(θ), M1⁺E2 from comparison to RUL.
	1165.92	E(γ): Yrast band (2000Wi18,1997Be77).. From ⁶⁸Ga ε decay. I(γ): From ⁶⁸Ga ε decay. M(γ): d,E2 from RUL; ΔJπ=2,no from level scheme
	1744.42	E(γ): Yrast band (2000Wi18,1997Be77).. From ⁶⁸Ga ε decay. I(γ): From ⁶⁸Ga ε decay. M(γ): D+Q from γγ(θ), M1⁺E2 from comparison to RUL.
	2821.73	E(γ): Yrast band (2000Wi18,1997Be77).. From ⁶⁸Ga ε decay. I(γ): Other: 10 3 in (n,γ), E=thermal.. From ⁶⁸Ga ε decay. M(γ): d,E2 from RUL; ΔJπ=2,no from level scheme
2959.49	1883.1	E(γ): From ²⁰⁸Pb(⁶⁴Ni,Xγ). ΔEγ=0.5 keV assumed by evaluator.
3009.27	670.89	I(γ): Other: 18 3 in (n,n’γ).
3009.27	1126.07	M(γ): D+Q from γγ(θ), M1⁺E2 from comparison to RUL.
3102.51	1219.3	E(γ): From (n,n’γ). I(γ): From (n,n’γ).
3153.8	815.7	E(γ): From (n,n’γ). I(γ): From (n,n’γ).
3153.8	1270.0	E(γ): From (n,n’γ). I(γ): the 1270γ is a doublet with Iγ=68 11. From (n,n’γ).
3160.1	2082.7	E(γ): From (n,n’γ). I(γ): From (n,n’γ).
E(level)	E(gamma)	Comments
3164.4	747.0	E(γ): From (n,n’γ). I(γ): From (n,n’γ).
3281.58	864.17	I(γ): weighted average of (n,γ) and (n,n’γ). From (n,n’γ).
3281.58	1397.0	E(γ): From (n,n’γ). I(γ): weighted average of (n,γ) and (n,n’γ). From (n,n’γ).
3287.09	1630.9	I(γ): Other: 38 15 in (n,n’γ).
	2209.75	M(γ): D+Q from γγ(θ), M1⁺E2 from comparison to RUL.
	3287.2	I(γ): Other: 5 4 in (n,n’γ).
3346.09	1462.0	E(γ): From (n,n’γ). I(γ): From (n,n’γ).
	2270	E(γ): From (n,n’γ). I(γ): From (n,n’γ).
	3346.0	E(γ): From (n,n’γ). I(γ): From (n,n’γ). M(γ): d,E2 from comparison to RUL, from level scheme transition is 1⁺ to 0⁺.
3386	2310	E(γ): From (n,n’γ). I(γ): From (n,n’γ).
3386	3383	E(γ): From (n,n’γ). I(γ): From (n,n’γ).
3400.9	1517.7	E(γ): From (n,n’γ). I(γ): From (n,n’γ).
	2322	E(γ): From (n,n’γ). I(γ): From (n,n’γ).
	3402	E(γ): From (n,n’γ). I(γ): From (n,n’γ).
3451.0	630.0	E(γ): From (n,n’γ). I(γ): From (n,n’γ).
	1114.0	E(γ): From (n,n’γ). I(γ): From (n,n’γ).
	2373.5	E(γ): From (n,n’γ). I(γ): From (n,n’γ).
3458.83	499.9	E(γ): observed only in {208Pb(⁶⁴Ni,Xγ) as sole depopulating transition from a 3459 level.. From ²⁰⁸Pb(⁶⁴Ni,Xγ). ΔEγ=0.5 keV assumed by evaluator.
3458.83	1041.26	M(γ): D+Q from γ(θ) in ⁶⁵Cu(α,pγ), Δπ=yes from level scheme
3586.64	835.87	E(γ): From (n,n’γ). I(γ): From (n,n’γ).
3586.64	2508	E(γ): From (n,n’γ). I(γ): From (n,n’γ).
3610.8	152.0	E(γ): from ⁶⁵Cu(α,pγ). M(γ): D+Q from γ(θ) in ⁶⁵Cu(α,pγ), Δπ=no from level scheme
3624.32	2546.9	E(γ): From (n,n’γ). I(γ): From (n,n’γ).
3624.32	3626	E(γ): From (n,n’γ). I(γ): From (n,n’γ).
3687.5	1270.1	E(γ): from ⁶⁵Cu(α,pγ). M(γ): Q+O from γ(θ) in ⁶⁵Cu(α,pγ), Δπ=no from level scheme
E(level)	E(gamma)	Comments
3709.8	1371.6	E(γ): From (n,n’γ). I(γ): From (n,n’γ).
3709.8	3708.2	E(γ): From (n,n’γ). I(γ): From (n,n’γ).
3717.47	2061.5	E(γ): From (n,n’γ). I(γ): From (n,n’γ).
3717.47	3717.5	E(γ): From (n,n’γ). I(γ): From (n,n’γ).
3725.79	975.4	E(γ): Other: 978.0 17 in (n,n’γ). I(γ): Other: 30 17 in (n,n’γ).
3814.83	2737.4	E(γ): From (n,n’γ).
3814.83	3817	E(γ): From (n,n’γ).
3895.83	1557.1	I(γ): Other: 47 20 in (n,n’γ).
3929	2852	E(γ): From (n,n’γ). I(γ): From (n,n’γ).
3935.08	1596.3	I(γ): Other: 29 14 in (n,n’γ).
3989	3989	E(γ): From (n,n’γ). I(γ): From (n,n’γ).
4061.0	1724	E(γ): From (n,n’γ). I(γ): From (n,n’γ).
4061.0	2983.5	E(γ): From (n,n’γ). I(γ): From (n,n’γ).
4102	4102	E(γ): From (n,n’γ). I(γ): From (n,n’γ).
4229	3152	E(γ): From (n,n’γ). I(γ): From (n,n’γ).
4234	3157	E(γ): From (n,n’γ). I(γ): From (n,n’γ).
4325	4325	E(γ): From (n,n’γ). I(γ): From (n,n’γ).
4339.1	4339	E(γ): From (γ,γ’). I(γ): From (γ,γ’).
4396.8	709.3	M(γ): Q+O from γ(θ) in ⁶⁵Cu(α,pγ), Δπ=no from level scheme
4414	4414	E(γ): From (n,n’γ). I(γ): From (n,n’γ).
4437	3360	E(γ): From (n,n’γ). I(γ): From (n,n’γ).
4437	4440	E(γ): From (n,n’γ). I(γ): From (n,n’γ).
4444	4444	E(γ): From (n,n’γ). I(γ): From (n,n’γ).
4466.2	4466	E(γ): From (γ,γ’). I(γ): From (γ,γ’).
4496	4496	E(γ): From (n,n’γ). I(γ): From (n,n’γ).
E(level)	E(gamma)	Comments
4503.2	3427	E(γ): From (n,n’γ). I(γ): From (n,n’γ).
4503.2	4503	E(γ): From (γ,γ’). I(γ): From (n,n’γ).
4520.6	1698.0	I(γ): Other: 200 120 in (n,n’γ), relative to Iγ(4521γ)=100 65.
4520.6	2181.7	I(γ): Other: 300 130 in (n,n’γ), relative to Iγ(4521γ)=100 65.
4578	4578	E(γ): From (n,n’γ). I(γ): From (n,n’γ).
4587	3511	E(γ): From (n,n’γ). I(γ): From (n,n’γ).
4587	4585	E(γ): From (n,n’γ). I(γ): From (n,n’γ).
4608	4608	E(γ): From (n,n’γ). I(γ): From (n,n’γ).
4642	2300	E(γ): From (n,n’γ). I(γ): From (n,n’γ).
	3567	E(γ): From (n,n’γ). I(γ): From (n,n’γ).
	4639	E(γ): From (n,n’γ). I(γ): From (n,n’γ).
4670	3592	E(γ): From (n,n’γ). I(γ): From (n,n’γ).
4670	4670	E(γ): From (n,n’γ). I(γ): From (n,n’γ).
4680	4680	E(γ): From (n,n’γ). I(γ): From (n,n’γ).
4743	3666	E(γ): From (n,n’γ). I(γ): From (n,n’γ).
4792	4792	E(γ): From (n,n’γ). I(γ): From (n,n’γ).
4865.9	923.0	E(γ): From ²⁰⁸Pb(⁶⁴Ni,Xγ). ΔEγ=0.5 keV assumed by evaluator. I(γ): From ²⁰⁸Pb(⁶⁴Ni,Xγ). ΔEγ=0.5 keV assumed by evaluator.
4873	2122	E(γ): From (n,n’γ). I(γ): From (n,n’γ).
4873	2990	E(γ): From (n,n’γ). I(γ): From (n,n’γ).
4982	4982	E(γ): From (n,n’γ). I(γ): From (n,n’γ).
5146	2732	E(γ): From (n,n’γ).
5146	4069	E(γ): From (n,n’γ).
5990.7	1124.7	E(γ): From ²⁰⁸Pb(⁶⁴Ni,Xγ). ΔEγ=0.5 keV assumed by evaluator. I(γ): From ²⁰⁸Pb(⁶⁴Ni,Xγ). ΔEγ=0.5 keV assumed by evaluator.
7362.3	4540	E(γ): From (γ,γ’).
	5706	E(γ): From (γ,γ’).
	6285	E(γ): From (γ,γ’).
	7362	E(γ): From (γ,γ’). M(γ): from γ(θ) (lin pol) in (γ,γ’)
E(level)	E(gamma)	Comments
1506.0+X	1506	E(γ): From ²⁶Mg(⁴⁸Ca,α2nγ). ΔEγ=1 keV assumed by evaluator. M(γ): From γ(θ) in ²⁶Mg(⁴⁸Ca,α2nγ).
3223.0+X	1717	E(γ): From ²⁶Mg(⁴⁸Ca,α2nγ). ΔEγ=1 keV assumed by evaluator. M(γ): From γ(θ) in ²⁶Mg(⁴⁸Ca,α2nγ).
5141.1+X	1918	E(γ): From ²⁶Mg(⁴⁸Ca,α2nγ). ΔEγ=1 keV assumed by evaluator. M(γ): From γ(θ) in ²⁶Mg(⁴⁸Ca,α2nγ).
7262.1+X	2121	E(γ): From ²⁶Mg(⁴⁸Ca,α2nγ). ΔEγ=1 keV assumed by evaluator. M(γ): From γ(θ) in ²⁶Mg(⁴⁸Ca,α2nγ).
9593.1+X	2331	E(γ): From ²⁶Mg(⁴⁸Ca,α2nγ). ΔEγ=1 keV assumed by evaluator. M(γ): From γ(θ) in ²⁶Mg(⁴⁸Ca,α2nγ).
12148.2+X	2555	E(γ): From ²⁶Mg(⁴⁸Ca,α2nγ). ΔEγ=1 keV assumed by evaluator. M(γ): From γ(θ) in ²⁶Mg(⁴⁸Ca,α2nγ).
14943+X	2795	E(γ): From ²⁶Mg(⁴⁸Ca,α2nγ). ΔEγ=1 keV assumed by evaluator.
18016+X	3073	E(γ): From ²⁶Mg(⁴⁸Ca,α2nγ). ΔEγ=1 keV assumed by evaluator.