List of levels for 71GA

Authors: Balraj Singh and Jun Chen | Citation: Nucl. Data Sheets 188, 1 (2023) | Cutoff date: 17-Jan-2023

⁷¹Ga identified by 1923As03 through mass spectroscopy.

Mass measurement: 2016Al30, 2013Fr13, 1991Zl01

Other reaction: ⁷⁰Zn(¹⁶O,¹⁵N): 1973Ko01.

Theoretical calculations:

2021Ro19: calculated energy and spin of the ground state, and energy of the first excited states

2012Sr01: shell model calculations of level energies, Jπ, B(E2), and moments

2012Ve03: projected shell-model calculations (with deformed basis from Nilsson model) of level energies, Jπ, positive and negative parity yrast bands, backbending, moments of inertia, B(E2), quadrupole moments

Levels: B(E2)|^ values given under comments are from Coulomb excitation, unless otherwise noted.

Gammas: Transition strengths under comments are deduced by evaluators from adopted T_1/2, branching ratios and mixing ratios, unless the adopted T_1/2 is deduced from measured B(E2)|^ and/or B(M1)|^ in Coulomb excitation and/or (e,e’) for which case B(E2)(W.u.) and B(M1)(W.u.) are directly converted from measured B(E2)|^ and B(M1)|^, respectively

Q-value: S(2n)=16953.9 14, S(2p)=18980.8 16 (2021Wa16)

E(level) (keV)	J^π(level)	T_1/2(level)	E(γ) (keV)	Multipolarity	Mixing Ratio	Conversion Coefficient	Additional Data
389.983	1/2-	0.40 ps +28-12	389.979 10	(M1+E2)	0.0047 +35-30	2.21×10^-3	B(E2)(W.u.)=0.19 16 (<a href= "http://www.nndc.bnl.gov/nsr/nsrlink.jsp?1994Ri07 ">1994Ri07</a>), B(M1)(W.u.)=0.93 38 (<a href= "http://www.nndc.bnl.gov/nsr/nsrlink.jsp?1991Ri08 ">1991Ri08</a>), α=2.21E-3 3
487.401	5/2-	62 ps 38	487.402 10	(M1+E2)	-0.024 13	1.32×10^-3	B(E2)(W.u.)=0.011 +22-9, B(M1)(W.u.)=0.0031 +31-12, α=1.32E-3 2
511.563	3/2-	1.5 ps 7	121.587 10	(M1(+E2))	-0.01 +13-16	0.041	B(M1)(W.u.)=0.6 +6-2, α=0.041 8, α(K)=0.037 7, α(L)=0.0039 9, α(M)=0.00057 13, α(N)=3.0×10^-5 6
511.563	3/2-	1.5 ps 7	511.556 12	M1+E2	-0.37 6	1.28×10^-3	B(E2)(W.u.)=7E1 +6-3, B(M1)(W.u.)=0.09 +7-3, α=1.28E-3 4
910.164	3/2-	0.46 ps 22	398.63 5	[M1,E2]		0.0033	α=0.0033 12
	3/2-	0.46 ps 22	423.2 3	[M1,E2]		0.0028	α=0.0028 9
	3/2-	0.46 ps 22	520.5 2	[M1,E2]		0.0015	α=0.0015 4
	3/2-	0.46 ps 22	910.187 21	(M1+E2)	0.09 5		B(E2)(W.u.)=0.8 +16-7, B(M1)(W.u.)=0.058 +46-19
964.695	5/2-	1.3 ps 2	453.145 10	[M1,E2]		0.0023	α=0.0023 7
	5/2-	1.3 ps 2	477.316 26	[M1,E2]		0.0019	α=0.0019 6
	5/2-	1.3 ps 2	574.684 17	[E2]		1.42×10^-3	B(E2)(W.u.)=9.2 +19-13, α=1.42E-3 2
	5/2-	1.3 ps 2	964.670 10	M1+E2	+1.3 3		B(E2)(W.u.)=14.3 +32-35, B(M1)(W.u.)=0.0054 +22-14
1107.497	7/2-	0.48 ps +14-10	142.820 10	(M1(+E2))	-0.05 4	0.0274	B(E2)(W.u.)=1.3×10² +23-13, B(M1)(W.u.)=0.69 18, α=0.0274 9, α(K)=0.0244 8, α(L)=0.00257 10, α(M)=0.000375 14, α(N)=2.00E-5 6
	7/2-	0.48 ps +14-10	595.916 10	E2		1.27×10^-3	B(E2)(W.u.)=2.9E2 +8-6, α=1.27E-3 2
	7/2-	0.48 ps +14-10	620.084 10	M1+E2	+0.96 24		B(E2)(W.u.)=2.2E2 8, B(M1)(W.u.)=0.061 +24-18
	7/2-	0.48 ps +14-10	1107.335 10	[E2]			B(E2)(W.u.)=0.83 +23-19
1109.31	1/2-	95 fs 12	1109.3 2	(M1+E2)	0.19 2		B(E2)(W.u.)=7.1 +19-15, B(M1)(W.u.)=0.164 +24-19
1395.263	7/2-	0.77 ps 6	430.31 21	[M1,E2]		0.0026	α=0.0026 9
	7/2-	0.77 ps 6	883.74 6	[E2]			B(E2)(W.u.)=3.92 +50-47
	7/2-	0.77 ps 6	1395.254 19	E2			B(E2)(W.u.)=3.57 +30-26
1476.004	5/2-	> 0.6 ps	368.499 22	[M1,E2]		0.0042	α=0.0042 17
	5/2-	> 0.6 ps	565.852 12	[M1,E2]		0.00121	α=0.00121 27
	5/2-	> 0.6 ps	988.638 11	(M1+E2)	+0.17 5		B(E2)(W.u.)<1.3, B(M1)(W.u.)<0.019
1493.864	9/2+	154 ps 15	98.611 25	[E1]		0.0670	B(E1)(W.u.)=1.66E-6 +21-17, α=0.0670 9
	9/2+	154 ps 15	386.371 14	(E1)		1.25×10^-3	B(E1)(W.u.)=4.39E-5 +49-39, α=1.25E-3 2
	9/2+	154 ps 15	982.292 10	[E3]			B(E3)(W.u.)=3.5 +16-15
	9/2+	154 ps 15	1006.439 10	[M2]			B(M2)(W.u.)=0.096 +11-9
	9/2+	154 ps 15	1493.802 19	[E3]			B(E3)(W.u.)=1.10 +14-12
E(level) (keV)	J^π(level)	T_1/2(level)	E(γ) (keV)	Multipolarity	Mixing Ratio	Conversion Coefficient	Additional Data
1699.21	1/2+	> 0.25 ps	1188.2 2	[E1]			B(E1)(W.u.)<4.5E-4
1699.21	1/2+	> 0.25 ps	1699.16 8	[E1]			B(E1)(W.u.)<2.1E-4
1719.567	5/2-	0.12 ps +5-2	1719.562 34	M1+E2	+1.4 5		B(E2)(W.u.)=4.8 +13-22, B(M1)(W.u.)=0.0049 +31-21
1752.32	3/2-	0.26 ps +24-10	1362.29 7	M1+E2	+1.5 5		B(E2)(W.u.)=3.6 +23-20, B(M1)(W.u.)=0.0020 +21-11
1905.39	5/2-	0.24 ps +11-6	1904.83 9	M1+E2	+0.8 3		B(E2)(W.u.)=0.93 +49-54, B(M1)(W.u.)=0.0036 +17-15
2247.269	7/2+	0.021 ps +6-5	527.71 4	[E1]			B(E1)(W.u.)=0.00096 +31-21
	7/2+	0.021 ps +6-5	753.395 10	M1+E2	-0.085 15		B(E2)(W.u.)=25 +13-9, B(M1)(W.u.)=1.31 +41-29
	7/2+	0.021 ps +6-5	852.02 5	[E1]			B(E1)(W.u.)=9.7E-5 +34-25
	7/2+	0.021 ps +6-5	1139.752 12	[E1]			B(E1)(W.u.)=0.00048 +15-11
	7/2+	0.021 ps +6-5	1282.562 15	[E1]			B(E1)(W.u.)=0.00038 +12-8
	7/2+	0.021 ps +6-5	1759.865 18	[E1]			B(E1)(W.u.)=5.4E-5 +17-12
2600.883	(9/2)+		1107.334 10	(E2+M1)	+3 +10-1
2815.792	7/2+	0.19 ps +13-6	1339.80 6	[E1]			B(E1)(W.u.)=2.9E-5 +14-11
2815.792	7/2+	0.19 ps +13-6	1708.311 19	[E1]			B(E1)(W.u.)=1.07E-4 +50-40

Q(β-)=-232.47 keV 9	S(n)= 9300.3 keV 14	S(p)= 7863.3 keV 21	Q(α)= -5244.5 keV 12
Reference: 2021WA16

References:
A	⁷¹Zn β^- decay (2.42 M)	B	⁷¹Zn β^- decay (4.140 H)
C	⁷¹Ge ε decay (11.43 d)	D	⁶⁸Zn(α,p)
E	⁶⁹Ga(t,p)	F	⁷⁰Zn(pol p,p),(p,n):RES
G	⁷⁰Zn(³He,d)	H	⁷⁰Zn(⁷Li,α2nγ)
I	⁷¹Ga(γ,γ’)	J	⁷¹Ga(E,E’)
K	⁷¹Ga(n,n’γ)	L	Coulomb Excitation
M	⁷²Ge(d,³He)	N	⁷⁴Ge(p,α)
O	²³⁸U(⁷⁶Ge,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 G H I J K L M N O	3/2-	STABLE
389.983 8	A B D G H I J K L M N O	1/2-	0.40 ps +28-12	389.979 10	100	(M1+E2)	0.0	3/2-
487.401 7	A B D G H I J K L M N O	5/2-	62 ps 38	487.402 10	100	(M1+E2)	0.0	3/2-
511.563 7	A B D E G H I J K L M N O	3/2-	1.5 ps 7	121.587 10 511.556 12	8.25 23 100.0 10	(M1(+E2)) M1+E2	389.983 0.0	1/2- 3/2-
714?	G J
910.164 12	A B E G I J K L M N	3/2-	0.46 ps 22	398.63 5 423.2 3 520.5 2 910.187 21	7.9 19 0.49 4 1.02 8 100.0 11	[M1,E2] [M1,E2] [M1,E2] (M1+E2)	511.563 487.401 389.983 0.0	3/2- 5/2- 1/2- 3/2-
964.695 8	A B E G H I J K L M N O	5/2-	1.3 ps 2	453.145 10 477.316 26 574.684 17 964.670 10	26.46 20 1.25 4 3.01 4 100 8	[M1,E2] [M1,E2] [E2] M1+E2	511.563 487.401 389.983 0.0	3/2- 5/2- 1/2- 3/2-
1107.497 7	B D E H I J K L N O	7/2-	0.48 ps +14-10	142.820 10 595.916 10 620.084 10 1107.335 10	8.46 23 52.2 18 100.0 10 3.37 15	(M1(+E2)) E2 M1+E2 [E2]	964.695 511.563 487.401 0.0	5/2- 3/2- 5/2- 3/2-
1109.31 20	A D E G I J K L M N	1/2-	95 fs 12	1109.3 2	100	(M1+E2)	0.0	3/2-
1395.263 14	B E G I J K L M N	7/2-	0.77 ps 6	430.31 21 883.74 6 907.91 5 1395.254 19	16.1 22 11.2 11 95.7 22 100.0 11	[M1,E2] [E2] [M1,E2] E2	964.695 511.563 487.401 0.0	5/2- 3/2- 5/2- 3/2-
1476.004 8	B D G I K L M N	5/2-	> 0.6 ps	368.499 22 565.852 12 964.670 10 988.638 11 1085.3? 1475.969 14	5.82 28 17.53 21 39 7 100.0 7 46.6 7	[M1,E2] [M1,E2] [M1,E2] (M1+E2) [E2] (M1+E2)	1107.497 910.164 511.563 487.401 389.983 0.0	7/2- 3/2- 3/2- 5/2- 1/2- 3/2-
1493.864 7	B D E G H I J K M N O	9/2+	154 ps 15	98.611 25 386.371 14 982.292 10 1006.439 10 1493.802 19	0.063 3 100.0 10 0.012 5 0.850 10 0.070 4	[E1] (E1) [E3] [M2] [E3]	1395.263 1107.497 511.563 487.401 0.0	7/2- 7/2- 3/2- 5/2- 3/2-
E(level) (keV)	XREF	J^π(level)	T_1/2(level)	E(γ) (keV)	I(γ)	M(γ)	Final Levels
1498.336 13	B H I J K N O	9/2-		1010.926 15	100	Q	487.401	5/2-
1631.43 5	A E G I J K M	3/2-	0.15 ps +12-6	666.75 6 721.09 11 1119.85 16 1144.2 3 1241.5 5 1631.46 10	46 5 19 6 100 9 3.7 6 1.5 2 18.1 15	[M1,E2] [M1,E2] [M1,E2] [M1,E2] [M1,E2] (M1+E2)	964.695 910.164 511.563 487.401 389.983 0.0	5/2- 3/2- 3/2- 5/2- 1/2- 3/2-
1699.21 8	G I J K	1/2+	> 0.25 ps	1188.2 2 1699.16 8	72 11 100 11	[E1] [E1]	511.563 0.0	3/2- 3/2-
1719.567 14	B D E I J K	5/2-	0.12 ps +5-2	1208.010 22 1232.172 28 1719.562 34	75.5 21 71.4 21 100.0 21	[M1,E2] [M1,E2] M1+E2	511.563 487.401 0.0	3/2- 5/2- 3/2-
1752.32 5	J K	3/2-	0.26 ps +24-10	788.06 6 1264.89 6 1362.29 7	42 4 100 12 35 4	[M1,E2] [M1,E2] M1+E2	964.695 487.401 389.983	5/2- 5/2- 1/2-
1905.39 4	E J K M N	5/2-	0.24 ps +11-6	797.82 7 940.70 7 1418.07 7 1904.83 9	8.6 14 27 5 91 9 100 18	[M1,E2] [M1,E2] [M1,E2] M1+E2	1107.497 964.695 487.401 0.0	7/2- 5/2- 5/2- 3/2-
1941.6 5	H	(9/2-)		976.9	100	Q	964.695	5/2-
1941.71 5	E J K	(3/2-)		546.57 14 976.95 6 1454.52 15	100 14 <1740 79 14		1395.263 964.695 487.401	7/2- 5/2- 5/2-
1992 6	J M	5/2-,7/2-
2064.16 21	A E G I K	1/2-,3/2-	82 fs 40	1552.4 3 2064.3 3	57 7 100 14	[M1,E2] [M1,E2]	511.563 0.0	3/2- 3/2-
2069.6 3	H O	11/2(-)		570.7 5 961.9 5	41 8 100 8	D Q	1498.336 1107.497	9/2- 7/2-
2082.461 18	B H O	(13/2+)		588.602 17	100	Q	1493.864	9/2+
2134.12 4	E K	5/2-,7/2-		635.7 1 1026.69 6 1169.34 7 1646.69 8 2134.19 13	18 100 9 91 9 82 9 55 9		1498.336 1107.497 964.695 487.401 0.0	9/2- 7/2- 5/2- 5/2- 3/2-
E(level) (keV)	XREF	J^π(level)	T_1/2(level)	E(γ) (keV)	I(γ)	M(γ)	Final Levels
2191 3	E G	5/2-,7/2
2247.269 8	B E G K	7/2+	0.021 ps +6-5	527.71 4 753.395 10 771.265 10 852.02 5 1139.752 12 1282.562 15 1759.865 18	1.40 8 100.0 11 65.8 6 0.59 9 7.00 8 7.96 9 2.91 6	[E1] M1+E2 [E1] [E1] [E1] [E1] [E1]	1719.567 1493.864 1476.004 1395.263 1107.497 964.695 487.401	5/2- 9/2+ 5/2- 7/2- 7/2- 5/2- 5/2-
2294.41 23	A E G K	1/2-		1383.8 5 1904.4 3 2294.8 5	20.8 19 100 10 15.1 19		910.164 389.983 0.0	3/2- 1/2- 3/2-
2327 3	E G	1/2-,3/2-
2396 3	E	-
2421 3	E G	1/2-,3/2-
2450.661 10	B E K	7/2+		952.352 29 956.785 15 974.659 12 1343.129 21 1485.874 19 1963.41 7	8.8 5 63.8 7 100.0 9 10.9 5 12.90 23 1.81 23		1498.336 1493.864 1476.004 1107.497 964.695 487.401	9/2- 9/2+ 5/2- 7/2- 5/2- 5/2-
2488.244 12	B E	(7/2)+		994.395 19 1012.231 22 1093.02 6 1380.713 15 2000.75 10 2488.37 9	19.2 8 71.6 21 2.81 26 100.0 10 1.53 26 2.05 26	[M2,E3]	1493.864 1476.004 1395.263 1107.497 487.401 0.0	9/2+ 5/2- 7/2- 7/2- 5/2- 3/2-
2528 10	D E G	1/2-,3/2-
2551 10	D E	+
2600.883 23	B	(9/2)+		518.430 18 1102.46 5 1107.334 10 1493.802 19	14.55 22 3.01 22 100 10 0.65 43	(E2+M1)	2082.461 1498.336 1493.864 1107.497	(13/2+) 9/2- 9/2+ 7/2-
E(level) (keV)	XREF	J^π(level)	T_1/2(level)	E(γ) (keV)	I(γ)	M(γ)	Final Levels
2614 10	E	+
2658 10	E	-
2683.72 18	H O	13/2(-)		613.6 1185.6 2	≈13 100 8	D Q	2069.6 1498.336	11/2(-) 9/2-
2720.019 14	B E	7/2+		472.754 22 1226.152 30 1243.989 17 1612.55 4	100.0 44 38.2 15 97.1 30 22.1 15		2247.269 1493.864 1476.004 1107.497	7/2+ 9/2+ 5/2- 7/2-
2747 10	E	-
2804.918 13	B	(7/2)+		1085.381 25 1306.565 21 1311.016 22 1697.35 6 1840.183 22 2317.54 4	33.3 16 100.0 16 98.4 16 6.4 8 39.7 8 54.0 16		1719.567 1498.336 1493.864 1107.497 964.695 487.401	5/2- 9/2- 9/2+ 7/2- 5/2- 5/2-
2812 10	E G	(-)
2815.792 13	B G K	7/2+	0.19 ps +13-6	1321.891 14 1339.80 6 1708.311 19 1905.65 8	100.0 16 4.8 4 37.0 4 2.4 4	[E1] [E1] [M2+E3]	1493.864 1476.004 1107.497 910.164	9/2+ 5/2- 7/2- 3/2-
2852 30	G
2932 10	E G	(+)
2941.67 20	H O	(17/2+)		859.2 2	100	Q	2082.461	(13/2+)
2967 30	G	(3/2+,5/2+)
2974 10	E	(-)
3016 30	G
3034.6 7	H	(13/2-)		1093.0	100	Q	1941.6	(9/2-)
3153 30	G	3/2+,5/2+
3153.7 3	H	(15/2-)		470.4 1070.4 1084.0	≈25 ≈25 ≈100	(D) D Q	2683.72 2082.461 2069.6	13/2(-) (13/2+) 11/2(-)
E(level) (keV)	XREF	J^π(level)	T_1/2(level)	E(γ) (keV)	I(γ)	M(γ)	Final Levels
3227 30	G	1/2-,3/2-
3438 30	G
3506 30	G
3607 30	G	3/2+,5/2+
3683	G
3695.2 3	H O	(17/2-)		541.1 1011.5 2	16 16 100	D Q	3153.7 2683.72	(15/2-) 13/2(-)
3749 30	G	3/2+,5/2+
3813 30	G	1/2+
3839.7 5	H	(17/2-)		1156.0	100	(Q)	2683.72	13/2(-)
3863 30	G
3909.7 9	H	(17/2-)		875.1	100	(Q)	3034.6	(13/2-)
3999.0 5	O			1057.3 5	100		2941.67	(17/2+)
4028.5 3	H O	(21/2+)		1086.8 2	100	Q	2941.67	(17/2+)
4060 30	G
4130 30	G	1/2+
4164.9 6	H O	(21/2-)		469.7 5	100	Q	3695.2	(17/2-)
4199.7 6	H	(19/2-)		1046.0	100	(Q)	3153.7	(15/2-)
4211 30	G	1/2+
4278 30	G
4382 30	G
4487 30	G
4644 30	G	1/2+
4692 30	G
4813 30	G	(3/2+,5/2+)
4873.1?	H	(21/2-)		964.0?			3909.7	(17/2-)
5221 30	G	1/2+
5228.2 6	H	(25/2+)		1199.7	100	Q	4028.5	(21/2+)
6573.7 8	H	(29/2+)		1345.5	100	(Q)	5228.2	(25/2+)
11590 10	F	1/2-	20 keV 5
E(level) (keV)	XREF	J^π(level)	T_1/2(level)	E(γ) (keV)	I(γ)	M(γ)	Final Levels
11671 3	F	(3/2+)	2.0 keV 2
11702 3	F	(3/2+)	7.0 keV 7
11728 3	F	(3/2+)	0.50 keV 5
11740 3	F	(3/2+)	4.0 keV 4
11885 10	F		23 keV 5
12067 10	F		34 keV 5
12264 10	F	3/2-	39 keV 4
12453 10	F	5/2+	15 keV 2
12862	F	5/2+	19 keV 1
13012 10	F	3/2-	11 keV 1
13215 10	F	1/2+	42 keV 2
13267 10	F	5/2+	38 keV 1
13773 10	F	5/2+	35 keV 5
13918 10	F	1/2+	55 keV 15

E(level) (keV)	J^π(level)	T_1/2(level)	E(γ)	I(γ)	M(γ)	Final Levels
Band 1 - Band based on 9/2⁺.
1493.864 7	9/2+	154 ps 15
2082.461 18	(13/2+)		588.602 17	100	Q	1493.864	9/2+
2941.67 20	(17/2+)		859.2 2	100	Q	2082.461	(13/2+)
4028.5 3	(21/2+)		1086.8 2	100	Q	2941.67	(17/2+)
5228.2 6	(25/2+)
6573.7 8	(29/2+)		1345.5	100	(Q)	5228.2	(25/2+)
E(level) (keV)	J^π(level)	T_1/2(level)	E(γ)	I(γ)	M(γ)	Final Levels
Band 2 - γ cascade based on 9/2-. Possible configuration=πf_5/2~#(even Zn core)
1498.336 13	9/2-
2683.72 18	13/2(-)		613.6 1185.6 2	≈13 100 8	D Q	2069.6 1498.336	11/2(-) 9/2-
3695.2 3	(17/2-)		541.1 1011.5 2	16 16 100	D Q	3153.7 2683.72	(15/2-) 13/2(-)
4164.9 6	(21/2-)		469.7 5	100	Q	3695.2	(17/2-)
E(level) (keV)	J^π(level)	T_1/2(level)	E(γ)	I(γ)	M(γ)	Final Levels
Band 3 - γ cascade based on 3/2- g.s.
0.0	3/2-	STABLE
487.401 7	5/2-	62 ps 38	487.402 10	100	(M1+E2)	0.0	3/2-
1107.497 7	7/2-	0.48 ps +14-10	142.820 10 595.916 10 620.084 10 1107.335 10	8.46 23 52.2 18 100.0 10 3.37 15	(M1(+E2)) E2 M1+E2 [E2]	964.695 511.563 487.401 0.0	5/2- 3/2- 5/2- 3/2-
2069.6 3	11/2(-)		570.7 5 961.9 5	41 8 100 8	D Q	1498.336 1107.497	9/2- 7/2-
3153.7 3	(15/2-)
4199.7 6	(19/2-)		1046.0	100	(Q)	3153.7	(15/2-)
E(level) (keV)	J^π(level)	T_1/2(level)	E(γ)	I(γ)	M(γ)	Final Levels
Band 4 - γ cascade based on 5/2-
964.695 8	5/2-	1.3 ps 2
1941.6 5	(9/2-)		976.9	100	Q	964.695	5/2-
3034.6 7	(13/2-)		1093.0	100	Q	1941.6	(9/2-)
3909.7 9	(17/2-)		875.1	100	(Q)	3034.6	(13/2-)
4873.1?	(21/2-)

E(level)	J^π(level)	T_1/2(level)	Comments
0.0	3/2-	STABLE	μ=+2.56033 9 (1954Wa37,2019StZV), Q=+0.107 1 (1972St38,2018Py01,2016St14,2021StZZ) Magnetic octupole moment=+0.180 5 (1957Sc28 recalculated original measurement of 0.146 20 in 1954Da26 by atomic and molecular beams). E(level): From (⁷Li,α2nγ).
389.983	1/2-	0.40 ps +28-12	B(E2)=0.00017 14 (1994Ri07), BM1=0.83 34 (1991Ri08) B(M1)\|^ and B(E2)\|^ from (e,e’). Other: B(E2)\|^<0.00017 in Coulomb excitation. E(level): B(M1)\|^ and B(E2)\|^ from (e,e’). Other: B(E2)\|^<0.00017 in Coulomb excitation.
487.401	5/2-	62 ps 38	B(E2)<0.00034 (1972An17) E(level): From (⁷Li,α2nγ).
910.164	3/2-	0.46 ps 22	B(E2)=0.0013 7 B(E2)\|^: unweighted average of 0.0020 3 from Coulomb excitation and 0.00056 33 in (e,e’).
964.695	5/2-	1.3 ps 2	B(E2)=0.022 6 B(E2)\|^: unweighted average of 0.032 5 (1972An17) and 0.024 13 (2010Di14) in Coulomb excitation, and 0.0112 37 in (e,e’).
1107.497	7/2-	0.48 ps +14-10	B(E2)=0.0029 5 (1972An17) E(level): From (⁷Li,α2nγ).
1493.864	9/2+	154 ps 15	E(level): From (n,n’γ). Band based on 9/2⁺.
1498.336	9/2-		E(level): From (⁷⁶Ge,Xγ).
1631.43	3/2-	0.15 ps +12-6	B(E2)=0.0012 4 (1994Ri07) B(E2)\|^ from (e,e’).
1699.21	1/2+	> 0.25 ps	XREF: γ(1713).
1941.71	(3/2-)		XREF: E(1937)J(1936).
2064.16	1/2-,3/2-	82 fs 40	XREF: γ(2075).
2069.6	11/2(-)		E(level): From (⁷Li,α2nγ).
2082.461	(13/2+)		E(level): From (n,n’γ). Band based on 9/2⁺.
2191	5/2-,7/2		XREF: γ(2206).
2247.269	7/2+	0.021 ps +6-5	XREF: γ(2260).
2294.41	1/2-		XREF: γ(2310).
2327	1/2-,3/2-		XREF: γ(2346).
2421	1/2-,3/2-		XREF: γ(2447).
2683.72	13/2(-)		E(level): From (⁷⁶Ge,Xγ).
2932	(+)		XREF: γ(2924).
2941.67	(17/2+)		E(level): From (n,n’γ). Band based on 9/2⁺.
3153.7	(15/2-)		E(level): From (⁷Li,α2nγ).
3695.2	(17/2-)		E(level): From (⁷⁶Ge,Xγ).
4028.5	(21/2+)		E(level): From (n,n’γ). Band based on 9/2⁺.
E(level)	J^π(level)	T_1/2(level)	Comments
4164.9	(21/2-)		E(level): From (⁷⁶Ge,Xγ).
4199.7	(19/2-)		E(level): From (⁷Li,α2nγ).
5228.2	(25/2+)		E(level): From (n,n’γ). Band based on 9/2⁺.
6573.7	(29/2+)		E(level): From (n,n’γ). Band based on 9/2⁺.
11590	1/2-	20 keV 5	J^π(level): From polarized proton elastic scattering differential cross section and analyzing power excitation function data or from optical model plus Breit-Wigner resonance analysis of IAR in (pol p,p),(p,n):resonance.
11671	(3/2+)	2.0 keV 2	J^π(level): From polarized proton elastic scattering differential cross section and analyzing power excitation function data or from optical model plus Breit-Wigner resonance analysis of IAR in (pol p,p),(p,n):resonance.
11702	(3/2+)	7.0 keV 7	E(level): Components of the IAR of the 286 level in ⁷¹Zn. J^π(level): From polarized proton elastic scattering differential cross section and analyzing power excitation function data or from optical model plus Breit-Wigner resonance analysis of IAR in (pol p,p),(p,n):resonance.
11728	(3/2+)	0.50 keV 5	E(level): Components of the IAR of the 286 level in ⁷¹Zn. J^π(level): From polarized proton elastic scattering differential cross section and analyzing power excitation function data or from optical model plus Breit-Wigner resonance analysis of IAR in (pol p,p),(p,n):resonance.
11740	(3/2+)	4.0 keV 4	E(level): Components of the IAR of the 286 level in ⁷¹Zn. J^π(level): From polarized proton elastic scattering differential cross section and analyzing power excitation function data or from optical model plus Breit-Wigner resonance analysis of IAR in (pol p,p),(p,n):resonance.
12264	3/2-	39 keV 4	J^π(level): From polarized proton elastic scattering differential cross section and analyzing power excitation function data or from optical model plus Breit-Wigner resonance analysis of IAR in (pol p,p),(p,n):resonance.
12453	5/2+	15 keV 2	J^π(level): From polarized proton elastic scattering differential cross section and analyzing power excitation function data or from optical model plus Breit-Wigner resonance analysis of IAR in (pol p,p),(p,n):resonance.
12862	5/2+	19 keV 1	J^π(level): From polarized proton elastic scattering differential cross section and analyzing power excitation function data or from optical model plus Breit-Wigner resonance analysis of IAR in (pol p,p),(p,n):resonance.
13012	3/2-	11 keV 1	J^π(level): From polarized proton elastic scattering differential cross section and analyzing power excitation function data or from optical model plus Breit-Wigner resonance analysis of IAR in (pol p,p),(p,n):resonance.
13215	1/2+	42 keV 2	J^π(level): From polarized proton elastic scattering differential cross section and analyzing power excitation function data or from optical model plus Breit-Wigner resonance analysis of IAR in (pol p,p),(p,n):resonance.
13267	5/2+	38 keV 1	J^π(level): From polarized proton elastic scattering differential cross section and analyzing power excitation function data or from optical model plus Breit-Wigner resonance analysis of IAR in (pol p,p),(p,n):resonance.
13773	5/2+	35 keV 5	J^π(level): From polarized proton elastic scattering differential cross section and analyzing power excitation function data or from optical model plus Breit-Wigner resonance analysis of IAR in (pol p,p),(p,n):resonance.
13918	1/2+	55 keV 15	J^π(level): From polarized proton elastic scattering differential cross section and analyzing power excitation function data or from optical model plus Breit-Wigner resonance analysis of IAR in (pol p,p),(p,n):resonance.

E(level)	E(gamma)	Comments
389.983	389.979	E(γ): others: 390.0 3 from ⁷¹Zn β^- decay (2.45 min), 389.92 8 from (n,n’γ), and 390.2 5 from (⁷⁶Ge,Xγ) M(γ): d, ΔJ=1 from γ(ADO) in (⁷Li,α2nγ); quadrupole component observed in (e,e’); M1⁺E2 from level scheme
487.401	487.402	E(γ): others: 487.3 1 from ⁷¹Zn β^- decay (2.45 min), 487.41 5 from (n,n’γ), and 487.5 2 from (⁷⁶Ge,Xγ) M(γ): D+Q from γγ(θ) in β^- decay (4.140 h); d, ΔJ=1 from γ(ADO) in (⁷Li,α2nγ); M1⁺E2 from level scheme
511.563	121.587	E(γ): weighted average of 121.52 5 from ⁷¹Zn β^- decay (2.45 min), 121.591 10 from ⁷¹Zn β^- decay (4.140 h), 121.54 8 from (n,n’γ), and 121.1 5 from (⁷⁶Ge,Xγ) I(γ): weighted average of 9.3 9 from ⁷¹Zn β^- decay (2.45 min), 8.19 16 from ⁷¹Zn β^- decay (4.140 h), 9 5 from (⁷Li,α2nγ), 8.0 7 from (n,n’γ), and 12.6 16 from (⁷⁶Ge,Xγ)
511.563	511.556	E(γ): others: 511.6 1 from ⁷¹Zn β^- decay (2.45 min), 511.60 9 from (n,n’γ), and 511.3 2 from (⁷⁶Ge,Xγ) I(γ): others: 100 15 from (⁷Li,α2nγ), 100 10 from (n,n’γ), and 100 16 from (⁷⁶Ge,Xγ)
910.164	398.63	E(γ): weighted average of 398.6 2 from ⁷¹Zn β^- decay (2.45 min), 398.69 5 from ⁷¹Zn β^- decay (4.140 h), and 398.58 5 from (n,n’γ) I(γ): unweighted average of 7.8 8 from ⁷¹Zn β^- decay (2.45 min), 11.2 7 from ⁷¹Zn β^- decay (4.140 h), and 4.8 8 from (n,n’γ)
910.164	910.187	E(γ): weighted average of 910.3 1 from ⁷¹Zn β^- decay (2.45 min), 910.181 21 from ⁷¹Zn β^- decay (4.140 h), 910 1 from (γ,γ’), and 910.3 2 from (n,n’γ) I(γ): others: 100 8 from ⁷¹Zn β^- decay (2.45 min) and 100 11 from (n,n’γ) M(γ): quadrupole component observed in Coulomb excitation; M1⁺E2 from level scheme
964.695	453.145	E(γ): others: 453.1 2 from ⁷¹Zn β^- decay (2.45 min), 453.12 5 from (n,n’γ), and 452.5 5 from (⁷⁶Ge,Xγ) I(γ): weighted average of 22.9 25 from ⁷¹Zn β^- decay (2.45 min), 26.47 20 from ⁷¹Zn β^- decay (4.140 h), and 25 11 from (⁷Li,α2nγ). Others: 33.2 8 from (n,n’γ) and 100 9 from (⁷⁶Ge,Xγ) are discrepant M(γ): Q, ΔJ=2 from γ(ADO) in (Li,α2nγ) inconsistent with level scheme
	574.684	E(γ): others: 575.1 5 from ⁷¹Zn β^- decay (2.45 min); 574.17 15 from (n,n’γ) is discrepant I(γ): from β^- decay (4.140 h). Others: 3.8 4 (β^- decay (2.45 min)); 7.0 8 (n,n’γ)
	964.670	E(γ): others: 964.8 2 from ⁷¹Zn β^- decay (2.45 min), 965 1 from (γ,γ’), 964.62 6 from (n,n’γ), and 963.8 5 from (⁷⁶Ge,Xγ). Multiply placed with intensity suitably divided I(γ): Multiply placed with intensity suitably divided
1107.497	142.820	E(γ): others: 142.98 5 from (n,n’γ), and 143.4 5 from (⁷⁶Ge,Xγ) I(γ): weighted average of 8.43 16 from ⁷¹Zn β^- decay (4.140 h), 6 5 from (⁷Li,α2nγ), 10.0 7 from (n,n’γ), and 7.5 7 from (⁷⁶Ge,Xγ) M(γ): d(+Q) from γγ(θ) in β^- decay (4.140 h); M1⁺E2 from level scheme
	595.916	E(γ): others: 595.9 2 from (⁷⁶Ge,Xγ); 596.21 5 from (n,n’γ) is discrepant I(γ): unweighted average of 51.3 5 from ⁷¹Zn β^- decay (4.140 h), 50 10 from (⁷Li,α2nγ), 50 7 from (n,n’γ), and 57.6 9 from (⁷⁶Ge,Xγ) M(γ): Q from γγ(θ) in β^- decay (4.140 h); Q, ΔJ=2 from γ(ADO) in (⁷⁶Ge,Xγ); M2 ruled out by RUL
	620.084	E(γ): others: 620.18 5 from (n,n’γ); 619.7 2 from (⁷⁶Ge,Xγ) is discrepant I(γ): others: 100 13 from (⁷Li,α2nγ), 100 7 from (n,n’γ), and 100.0 12 from (⁷⁶Ge,Xγ) M(γ): D+Q from γγ(θ) in β^- decay (4.140 h) and γ(θ) in (n,n’γ); M2 ruled out by RUL
	1107.335	E(γ): weighted average of 1107.334 10 from ⁷¹Zn β^- decay (4.140 h), 1107.6 2 from (n,n’γ), and 1107.2 5 from (⁷⁶Ge,Xγ). Multiply placed with intensity suitably divided I(γ): others: 4.6 5 from (⁷⁶Ge,Xγ); 3.6 from (n,n’γ) and Coulomb excitation. Multiply placed with intensity suitably divided
1109.31	1109.3	E(γ): from (n,n’γ). Others: 1109.3 5 from ⁷¹Zn β^- decay (2.45 min) and 1109 1 from (γ,γ’). From (n,n’γ) M(γ): quadrupole component observed in Coulomb excitation; M1⁺E2 from level scheme
1395.263	430.31	E(γ): unweighted average of 430.52 7 from ⁷¹Zn β^- decay (4.140 h) and 430.10 5 from (n,n’γ) I(γ): other: 31.0 35 from (n,n’γ) is in disagreement
	883.74	E(γ): weighted average of 883.80 7 from ⁷¹Zn β^- decay (4.140 h) and 883.69 6 from (n,n’γ) I(γ): weighted average of 10.8 11 from ⁷¹Zn β^- decay (4.140 h) and 12.1 17 from (n,n’γ)
	907.91	E(γ): weighted average of 907.92 3 from ⁷¹Zn β^- decay (4.140 h) and 907.6 2 from (n,n’γ) I(γ): other: 35 7 from (n,n’γ) (1984Ar09) in disagreement, although, 108 12 in another (n,n’γ) study (1977SmZI) is in agreement with β^- decay
	1395.254	M(γ): Q, ΔJ=2 from γγ(θ) in β^- decay (4.140 h) and γ(θ) in (n,n’γ); M2 ruled out by RUL
1476.004	565.852	E(γ): weighted average of 565.854 12 from ⁷¹Zn β^- decay (4.140 h) and 565.82 5 from (n,n’γ) I(γ): other: 26.8 25 (n,n’γ) is in disagreement
	964.670	E(γ): Multiply placed with intensity suitably divided I(γ): from (n,n’γ). Other: 27 27 in β^- decay (4.140 h). Multiply placed with intensity suitably divided
	988.638	E(γ): uncertainty multiplied by a factor of 2 in the fitting; level-energy difference=988.596. weighted average of 988.640 10 from ⁷¹Zn β^- decay (4.140 h) and 988.57 6 from (n,n’γ) I(γ): other: 100 10 from (n,n’γ) M(γ): D+Q from γγ(θ) in β^- decay (4.140 h); M1⁺E2 from level scheme
	1085.3	E(γ): from Coulomb excitation only
	1475.969	E(γ): weighted average of 1475.972 14 from ⁷¹Zn β^- decay (4.140 h) and 1475.90 7 from (n,n’γ) I(γ): other: 76 7 (n,n’γ) is in disagreement M(γ): quadruple component observed in Coulomb excitation; M1⁺E2 from level scheme
1493.864	386.371	E(γ): weighted average of 386.371 10 from ⁷¹Zn β^- decay (4.140 h), 386.50 16 from (n,n’γ), and 386.0 2 from (⁷⁶Ge,Xγ) M(γ): d from γγ(θ) in β^- decay (4.140 h); d, ΔJ=1 from γ(ADO) in (⁷⁶Ge,Xγ); E1 from level scheme
1493.864	1493.802	E(γ): Multiply placed with intensity suitably divided I(γ): Multiply placed with intensity suitably divided
E(level)	E(gamma)	Comments
1498.336	1010.926	E(γ): others: 1010.92 6 from (n,n’γ) and 1010.9 2 from (⁷⁶Ge,Xγ) M(γ): From γ(ADO) in (⁷Li,α2nγ) with ΔJ=2 for Q an ΔJ=1 for d
1631.43	666.75	E(γ): weighted average of 666.8 2 from ⁷¹Zn β^- decay (2.45 min) and 666.74 6 from (n,n’γ) I(γ): weighted average of 41 5 from ⁷¹Zn β^- decay (2.45 min) and 50 5 from (n,n’γ)
	721.09	E(γ): weighted average of 721.4 3 from ⁷¹Zn β^- decay (2.45 min) and 721.05 11 from (n,n’γ) I(γ): unweighted average of 25.0 30 from ⁷¹Zn β^- decay (2.45 min) and 13.2 14 from (n,n’γ)
	1119.85	E(γ): unweighted average of 1120.0 1 from ⁷¹Zn β^- decay (2.45 min) and 1119.69 6 from (n,n’γ) I(γ): from (n,n’γ). Other: 100 10 from ⁷¹Zn β^- decay (2.45 min)
	1241.5	E(γ): From (n,n’γ) I(γ): From (n,n’γ)
	1631.46	E(γ): weighted average of 1631.6 2 from ⁷¹Zn β^- decay (2.45 min) and 1631.42 10 from (n,n’γ) I(γ): weighted average of 17.7 15 from ⁷¹Zn β^- decay (2.45 min) and 23 5 from (n,n’γ) M(γ): quadrupole component observed in (e,e’); M1⁺E2 from level scheme
1699.21	1188.2	E(γ): uncertainty multiplied by a factor of 2 in the fitting; level-energy difference=1187.63. From (n,n’γ) I(γ): From (n,n’γ)
1699.21	1699.16	E(γ): From (n,n’γ) I(γ): From (n,n’γ)
1719.567	1208.010	E(γ): weighted average of 1208.005 22 from ⁷¹Zn β^- decay (4.140 h) and 1208.06 7 from (n,n’γ) I(γ): other: 64 9 from (n,n’γ)
	1232.172	E(γ): weighted average of 1232.181 24 from ⁷¹Zn β^- decay (4.140 h) and 1232.09 7 from (n,n’γ) I(γ): other: 100 9 from (n,n’γ)
	1719.562	E(γ): weighted average of 1719.574 23 from ⁷¹Zn β^- decay (4.140 h), 1719 1 from (γ,γ’), and 1719.38 9 from (n,n’γ) I(γ): other: 100 9 from (n,n’γ)
1752.32	788.06	E(γ): uncertainty multiplied by a factor of 3 in the fitting; level-energy difference=787.62. From (n,n’γ) I(γ): From (n,n’γ)
	1264.89	E(γ): From (n,n’γ) I(γ): From (n,n’γ)
	1362.29	E(γ): From (n,n’γ) I(γ): From (n,n’γ)
1905.39	797.82	E(γ): From (n,n’γ) I(γ): From (n,n’γ)
	940.70	E(γ): From (n,n’γ) I(γ): From (n,n’γ)
	1418.07	E(γ): From (n,n’γ) I(γ): From (n,n’γ)
	1904.83	E(γ): uncertainty multiplied by a factor of 3 in the fitting; level-energy difference=1905.36. From (n,n’γ) I(γ): From (n,n’γ)
1941.6	976.9	E(γ): From (⁷Li,α2nγ) M(γ): From γ(ADO) in (⁷Li,α2nγ) with ΔJ=2 for Q an ΔJ=1 for d
1941.71	546.57	E(γ): From (n,n’γ) I(γ): From (n,n’γ)
	976.95	E(γ): Multiply placed with undivided intensity. From (n,n’γ) I(γ): Multiply placed with undivided intensity. From (n,n’γ)
	1454.52	E(γ): From (n,n’γ) I(γ): From (n,n’γ)
2064.16	1552.4	E(γ): weighted average of 1553.0 5 from ⁷¹Zn β^- decay (2.45 min) and 1552.3 2 from (n,n’γ) I(γ): from β^- decay (2.45 min). Other: 20 in (n,n’γ)
2064.16	2064.3	E(γ): weighted average of 2064.6 2 from ⁷¹Zn β^- decay (2.45 min), 2064 1 from (γ,γ’), and 2063.9 2 from (n,n’γ) I(γ): from β^- decay (2.45 min). Other: 100 20 from (n,n’γ)
2069.6	570.7	E(γ): From (⁷⁶Ge,Xγ) I(γ): From (⁷⁶Ge,Xγ) M(γ): From γ(ADO) in (⁷Li,α2nγ) with ΔJ=2 for Q an ΔJ=1 for d
2069.6	961.9	E(γ): From (⁷⁶Ge,Xγ) I(γ): From (⁷⁶Ge,Xγ) M(γ): From γ(ADO) in (⁷Li,α2nγ) with ΔJ=2 for Q an ΔJ=1 for d
E(level)	E(gamma)	Comments
2082.461	588.602	E(γ): other: 588.3 2 from (⁷⁶Ge,Xγ) M(γ): From γ(ADO) in (⁷Li,α2nγ) with ΔJ=2 for Q an ΔJ=1 for d
2134.12	635.7	E(γ): From (n,n’γ) I(γ): From (n,n’γ)
	1026.69	E(γ): From (n,n’γ) I(γ): From (n,n’γ)
	1169.34	E(γ): From (n,n’γ) I(γ): From (n,n’γ)
	1646.69	E(γ): From (n,n’γ) I(γ): From (n,n’γ)
	2134.19	E(γ): From (n,n’γ) I(γ): From (n,n’γ)
2247.269	753.395	E(γ): other: 753.72 5 from (n,n’γ) is discrepant M(γ): D+Q and δ from γγ(θ) in β^- decay (4.140 h); M2 component ruled out by RUL
2450.661	974.659	E(γ): other: 976.95 6 from (n,n’γ) for a doublet
	1485.874	E(γ): uncertainty multiplied by a factor of 2 in the fitting; level-energy difference=1485.949. Other: 1485.86 14 from (n,n’γ)
	1963.41	E(γ): uncertainty multiplied by a factor of 2 in the fitting; level-energy difference=1963.231
2600.883	1107.334	E(γ): Multiply placed with intensity suitably divided I(γ): Multiply placed with intensity suitably divided M(γ): large mixing ratio and ΔJπ suggest (E2⁺M1)
2600.883	1493.802	E(γ): Multiply placed with intensity suitably divided I(γ): Multiply placed with intensity suitably divided
2683.72	613.6	E(γ): From (⁷Li,α2nγ) I(γ): 13 17 from (⁷Li,α2nγ). From (⁷Li,α2nγ) M(γ): From γ(ADO) in (⁷Li,α2nγ) with ΔJ=2 for Q an ΔJ=1 for d
2683.72	1185.6	E(γ): From (⁷⁶Ge,Xγ) I(γ): from (⁷Li,α2nγ) M(γ): From γ(ADO) in (⁷Li,α2nγ) with ΔJ=2 for Q an ΔJ=1 for d
2815.792	1321.891	E(γ): other: 1322.30 9 from (n,n’γ)
2815.792	1905.65	E(γ): 1905.65γ to 3/2- seems too strong for pure M2 or pure E3, as B(M2)(W.u.) and B(E3)(W.u.) exceed respective RUL=1 and 100. It is possible that the main intensity of this γ is due to coincidence summing
2941.67	859.2	E(γ): From (⁷⁶Ge,Xγ) M(γ): From γ(ADO) in (⁷Li,α2nγ) with ΔJ=2 for Q an ΔJ=1 for d
3034.6	1093.0	E(γ): From (⁷Li,α2nγ) M(γ): From γ(ADO) in (⁷Li,α2nγ) with ΔJ=2 for Q an ΔJ=1 for d
3153.7	470.4	E(γ): From (⁷Li,α2nγ) I(γ): 25 86 from (⁷Li,α2nγ). From (⁷Li,α2nγ)
	1070.4	E(γ): From (⁷Li,α2nγ) I(γ): 25 25 from (⁷Li,α2nγ). From (⁷Li,α2nγ) M(γ): From γ(ADO) in (⁷Li,α2nγ) with ΔJ=2 for Q an ΔJ=1 for d
	1084.0	E(γ): From (⁷Li,α2nγ) I(γ): 100 134 from (⁷Li,α2nγ). From (⁷Li,α2nγ) M(γ): From γ(ADO) in (⁷Li,α2nγ) with ΔJ=2 for Q an ΔJ=1 for d
3695.2	541.1	E(γ): From (⁷Li,α2nγ) I(γ): From (⁷Li,α2nγ) M(γ): From γ(ADO) in (⁷Li,α2nγ) with ΔJ=2 for Q an ΔJ=1 for d
3695.2	1011.5	E(γ): From (⁷Li,α2nγ) I(γ): From (⁷Li,α2nγ) M(γ): From γ(ADO) in (⁷Li,α2nγ) with ΔJ=2 for Q an ΔJ=1 for d
3839.7	1156.0	E(γ): From (⁷Li,α2nγ) M(γ): From γ(ADO) in (⁷Li,α2nγ) with ΔJ=2 for Q an ΔJ=1 for d
3909.7	875.1	M(γ): From γ(ADO) in (⁷Li,α2nγ) with ΔJ=2 for Q an ΔJ=1 for d
E(level)	E(gamma)	Comments
3999.0	1057.3	E(γ): From (⁷⁶Ge,Xγ)
4028.5	1086.8	E(γ): From (⁷⁶Ge,Xγ) M(γ): From γ(ADO) in (⁷Li,α2nγ) with ΔJ=2 for Q an ΔJ=1 for d
4164.9	469.7	E(γ): From (⁷⁶Ge,Xγ) M(γ): From γ(ADO) in (⁷Li,α2nγ) with ΔJ=2 for Q an ΔJ=1 for d
4199.7	1046.0	E(γ): From (⁷Li,α2nγ) M(γ): From γ(ADO) in (⁷Li,α2nγ) with ΔJ=2 for Q an ΔJ=1 for d
4873.1	964.0	E(γ): From (⁷Li,α2nγ)
5228.2	1199.7	E(γ): From (⁷Li,α2nγ) M(γ): From γ(ADO) in (⁷Li,α2nγ) with ΔJ=2 for Q an ΔJ=1 for d
6573.7	1345.5	M(γ): From γ(ADO) in (⁷Li,α2nγ) with ΔJ=2 for Q an ΔJ=1 for d