List of levels for 92ZR

Author: Coral M. Baglin | Citation: Nucl. Data Sheets 113, 2187 (2012) | Cutoff date: 15-Sep-2012

See ⁹¹Zr(n,γ) E=res for neutron resonance information; it has not been included in the present dataset.

Other Reactions:

⁹Be(⁸⁶Kr,3nγ): 2007SuZN: E(⁸⁶Kr)=280 MeV; GEMINI-II γ detector array; measured T_1/2 using DSAM for high-spin states; data analysis not yet complete.

⁹¹Zr(⁷Li,⁶Li): 1993Yo01: E(⁷Li)=210 MeV, magnetic spectrograph, FWHM≈500 keV, 88.5% ⁹¹Zr target; observed resonances at E=0.0 MeV (Γ=0.6 MeV), 1.3 MeV (Γ=0.9 MeV), 3.6 MeV (Γ=1.2 MeV), 4.7 MeV (Γ=0.9 MeV), 5.5 MeV (Γ=1.0 MeV), 6.8 MeV (Γ=1.6 MeV) and 15.8 MeV (Γ=6.0 MeV); interpreted these resonances as single-particle states.

⁹²Zr(⁶Li,⁶Li’): 1993Ho02: E(⁶Li)=70 MeV, magnetic spectrometer, particle identification, 94.57% ⁹²Zr target, FWHM≈225 keV, θ(lab)≈4|’-45|’; measured σ(θ) for 934 and 2340 levels (Jπ=2⁺ and 3-, respectively); deduced isospin character of transitions to the above two states (deformed optical model analysis). See also 1992Ho12.

For relativistic mean field calculation of g.s. properties of ⁹²Zr, see 2004He24.

For shell-model calculation of g factors and electromagnetic decay rates for lowest-energy 2⁺ (934) and 3- (2340) levels, see 2004St11.

Levels: Above 3 MeV, the correspondence between levels from different reactions is sometimes ambiguous. This is due, in part, to particle reaction energy resolution being inadequate for the existing level density, but also results from particle reaction data for which the authors do not state ΔE (viz., (α,³He), (p,t), (³He,³He’), (t,t’), (d,³He)) and/or data for which the energy scale appears to include an unstated systematic uncertainty (viz.: (α,³He), 10-30 keV low; (p,t), 5-10 keV low; (p,p’) from 1966St15, 10-20 keV low).

Levels: For theoretical work see, e.g., 1972Wa09, 1975Gl07, 1976Te02, 1976Pr07, 1993Ha37, 2000Ho15.

Q-value: Note: Current evaluation has used the following Q record -2005.9 18 8634.7911 9396.8 19-2964.3 23 2011AuZZ

Q-value: Q(β^-),S(n),S(p),Q(α): from 2011AuZZ; -2005.5 18, 8634.80 11, 9397.8 18, -2957.1 25, respectively, from 2003Au03.

E(level) (keV)	J^π(level)	T_1/2(level)	E(γ) (keV)	Multipolarity	Mixing Ratio	Conversion Coefficient	Additional Data
934.51	2+	5.0 ps 4	934.47 4	E2			B(E2)(W.u.)=6.4 6
1382.77	0+	88 ps 3	448.26 7	E2			B(E2)(W.u.)=14.4 5
1495.46	4+	102 ps 3	560.92 15	E2			B(E2)(W.u.)=4.05 12
1847.27	2+	96 fs 10	912.72 6	(M1(+E2))	-0.002 25		B(E2)(W.u.)=0.001 +25-1, B(M1)(W.u.)=0.201 22
1847.27	2+	96 fs 10	1847.27 5	E2			B(E2)(W.u.)=3.7 5
2066.65	2+	> 0.76 ps	1132.12 5	(M1+E2)	-3.2 +5-4		B(E2)(W.u.)<15, B(M1)(W.u.)<0.0022
2066.65	2+	> 0.76 ps	2066.7 4	E2			B(E2)(W.u.)<0.0042
2339.66	3-	0.28 ps 3	492.37 10	(E1(+M2))	0.009 LE		B(E1)(W.u.)=0.00067, B(M2)(W.u.)≤1.3
	3-	0.28 ps 3	844.12 6	(E1+M2)	0.02 LE		B(E1)(W.u.)≥0.00036, B(M2)(W.u.)≤1.2
	3-	0.28 ps 3	1405.06 5	(E1)			B(E1)(W.u.)=0.00030 4
	3-	0.28 ps 3	2339.9 1	E3		0.00049	B(E3)(W.u.)=18.3 11, α=0.00049
2398.36	4+	149 fs 16	902.92 7	M1+E2	-0.11 +3-2		B(E2)(W.u.)=2.3 13, B(M1)(W.u.)=0.147 17
2398.36	4+	149 fs 16	1463.81 10	E2(+M3)			B(E2)(W.u.)=5.9 7
2486.01	5-	≤ 3.5 ns	990.52 9	(E1)			B(E1)(W.u.)≥9.8E-8
2743.55	4-	> 2.63 ps	257.57 10	(M1(+E2))	-0.01 +2-3	0.01624	B(M1)(W.u.)<0.30, α=0.01624
	4-	> 2.63 ps	403.83 9	(M1(+E2))	+0.04 2		B(E2)(W.u.)<0.57, B(M1)(W.u.)<0.028
	4-	> 2.63 ps	1248.00 11	(E1(+M2))	+0.02 +6-4		B(E1)(W.u.)<2.5E-5, B(M2)(W.u.)<0.20
2819.54	2+	64 fs 7	972.30 9	(M1(+E2))	+0.01 2		B(E2)(W.u.)=0.022 +87-22, B(M1)(W.u.)=0.196 24
2819.54	2+	64 fs 7	2819.8 3	E2			B(E2)(W.u.)=0.048 7
2864.66	4+	0.24 ps 3	465.94 21	(M1(+E2))	-0.01 +15-13		B(E2)(W.u.)=0.03 +99-3, B(M1)(W.u.)=0.068 15
	4+	0.24 ps 3	1369.25 10	M1+E2	-0.49 5		B(E2)(W.u.)=2.7 6, B(M1)(W.u.)=0.021 3
	4+	0.24 ps 3	1930.13 18	E2(+M3)	-0.02 4		B(E2)(W.u.)=0.76 15
2904.08	0+	0.83 ps +57-24	1969.6 3	E2			B(E2)(W.u.)=0.28 +9-20
2909.43	3+	216 fs 24	842.69 15	M1+E2	-0.25 +7-9		B(E2)(W.u.)=2.4 14, B(M1)(W.u.)=0.026 5
2909.43	3+	216 fs 24	1974.93 10	M1+E2	+0.13 +0-4		B(E2)(W.u.)=0.030 7, B(M1)(W.u.)=0.0066 15
E(level) (keV)	J^π(level)	T_1/2(level)	E(γ) (keV)	Multipolarity	Mixing Ratio	Conversion Coefficient	Additional Data
2957.4	6+	≤ 3.5 ns	1461.93 26	(E2)			B(E2)(W.u.)≥0.00098
3039.70	3	91 fs 10	700.10 9	D(+Q)	+0.08 10
	3	91 fs 10	1192.49 27	D(+Q)	+0.02 +3-2
	3	91 fs 10	2105.18 8	D(+Q)	-0.04 +4-9
3057.40	2+	98 fs 10	717.9 2	D(+Q)	-0.03 7
	2+	98 fs 10	1674.9 5	E2			B(E2)(W.u.)=0.64 20
	2+	98 fs 10	2123.0 3	M1+E2	+0.69 16		B(E2)(W.u.)=0.37 16, B(M1)(W.u.)=0.0034 11
	2+	98 fs 10	3057.2 5	E2			B(E2)(W.u.)=0.039 12
3178.31	4+	54 fs 6	779.94 10	M1(+E2)	-0.04 4		B(E2)(W.u.)=1.9 +38-19, B(M1)(W.u.)=0.68 8
3178.31	4+	54 fs 6	2243.80 26	E2(+M3)	+0.06 +10-9		B(E2)(W.u.)=1.53 20
3190.99	(4-)	153 fs 18	1695.5 2	D(+Q)	-0.02 +4-3
3236.9	4+		1741.8 2	D+Q	-1.09 +9-10
3262.62	2+	12.5 fs 14	2328.17 13	(M1+E2)	-0.06 3		B(E2)(W.u.)=0.07 +8-7, B(M1)(W.u.)=0.108 13
3262.62	2+	12.5 fs 14	3262.54 4	E2			B(E2)(W.u.)=1.13 15
3275.76	2+,3+	53 fs 6	2340.90 16	M1+E2	+4.4 +8-5		B(E2)(W.u.)=1.46 22, B(M1)(W.u.)=0.00040 15
3289.13	3+	174 fs 19	1441.2 3	M1+E2	+0.24 5		B(E2)(W.u.)=0.09 4, B(M1)(W.u.)=0.0031 5
	3+	174 fs 19	1793.87 23	M1+E2	+0.22 5		B(E2)(W.u.)=0.033 15, B(M1)(W.u.)=0.0021 3
	3+	174 fs 19	2354.80 13	M1+E2	+0.29 3		B(E2)(W.u.)=0.042 10, B(M1)(W.u.)=0.0027 4
3308.7	(8+)	1.18 ns 7	351.3 2	E2		0.01276	B(E2)(W.u.)=3.59 22, α=0.01276
3371.48	1(-)	27 fs 3	1988.71 10	(E1)			B(E1)(W.u.)=0.00079 15
3371.48	1(-)	27 fs 3	3371.2 3	(E1)			B(E1)(W.u.)=8.2E-5 14
3407.83	2-,3-	0.30 ps 4	2473.2 3	(E1(+M2))	+0.08 6		B(E1)(W.u.)=3.1E-5 5, B(M2)(W.u.)=0.15 +22-15
3452.17	(2)+	58 fs 6	1604.86 10	M1+E2	-1.5 +5-8		B(E2)(W.u.)=7.4 18, B(M1)(W.u.)=0.008 4
3452.17	(2)+	58 fs 6	2517.73 11	M1+E2	+2.0 12		B(E2)(W.u.)=1.0 3, B(M1)(W.u.)=0.0016 16
3463.04	(4)+	137 fs +21-17	2528.7 5	E2(+M3)	+0.005 LE		B(E2)(W.u.)=0.41 +6-7
E(level) (keV)	J^π(level)	T_1/2(level)	E(γ) (keV)	Multipolarity	Mixing Ratio	Conversion Coefficient	Additional Data
3471.88	1+	5.3 fs 6	2089.6 5	(M1)			B(M1)(W.u.)=0.052 8
	1+	5.3 fs 6	2537.1 2	M1			B(M1)(W.u.)=0.063 9
	1+	5.3 fs 6	3471.9 5	M1			B(M1)(W.u.)=0.063 9
3499.88	2+	53 fs 5	1159.54 16	(E1(+M2))	-0.04 15		B(E1)(W.u.)=0.00038 5, B(M2)(W.u.)=2.1 +155-21
3499.88	2+	53 fs 5	3499.8 5	E2			B(E2)(W.u.)=0.35 4
3638.2	1-	8.4 fs 11	2255.4 3	(E1)			B(E1)(W.u.)=0.00043 8
3638.2	1-	8.4 fs 11	3638.0 5	E1			B(E1)(W.u.)=0.00072 10
3649.22	3+	56 fs 7	2714.1 4	M1+E2	-0.73 +12-18		B(E2)(W.u.)=0.28 9, B(M1)(W.u.)=0.0038 10
3675.8	3+,4+,5+	116 fs +24-20	2180.3 4	M1+E2	+3.6 +6-5		B(E2)(W.u.)=3.7 +7-8, B(M1)(W.u.)=0.0013 5
3696.8	1(+)	17.3 fs 28	2762.3 4	(M1+E2)	+1.3 +28-8		B(E2)(W.u.)=3 +5-3, B(M1)(W.u.)=0.011 +31-11
3696.8	1(+)	17.3 fs 28	3696.5 7	(M1)			B(M1)(W.u.)=0.0127 24
4947.2	(12+)	≤ 3.5 ns	650.6 5	(E2)			B(E2)(W.u.)≥0.056

Q(β-)=-2005.9 keV 18	S(n)= 8634.79 keV 11	S(p)= 9396.7 keV 19	Q(α)= -2963.2 keV 21
Reference: 2012WA38

References:
A	⁹²Y β^- decay	B	⁹²Nb ε decay (10.15 d)
C	⁴⁸Ca(⁴⁸Ca,4nγ)	D	⁸⁸Sr(⁷Li,2npγ)
E	⁹⁰Zr(t,p)	F	⁹¹Zr(n,γ) E=THERMAL
G	⁹¹Zr(d,p), (pol d,p)	H	⁹¹Zr(α,³He)
I	⁹²Zr(n,n’γ)	J	⁹²Zr(p,p’), (pol p,p’)
K	⁹²Zr(α,α’)	L	⁹²Zr(d,d’), (pol d,d)
M	⁹²Zr(t,t’)	N	⁹⁴Zr(p,t)
O	⁹²Zr(p,p’γ)	P	⁹²Zr(³He,³He’)
Q	⁹³Nb(μ^-,nγ)	R	⁹³Nb(d,³He), (pol d,³He)
S	⁹⁴Mo(⁶Li,⁸B)	T	⁹²Zr(¹⁶O,¹⁶O’), (¹⁸O,¹⁸O’)
U	⁹²Nb ε decay (3.47×10⁷ Y)	V	⁹⁰Zr(α,²He)
W	Coulomb Excitation	X	⁹²Zr(n,n’)
Y	⁹⁵Mo(n,α)	Z	⁹²Zr(E,E’)
a	⁸⁹Y(α,p)	b	⁹²Zr(γ,XN), (γ,PN)
c	⁹⁴Mo(¹⁴C,¹⁶O)	d	⁹⁶Mo(d,⁶Li)
e	⁹¹Zr(¹⁶O,¹⁵O)	f	⁹¹Zr(n,γ),(n,n) E=RES
g	¹⁷³Yb(²⁴Mg,Fγ),¹⁷⁶Yb(²⁸Si,xγ),	h	⁹²Zr(pol γ,γ’), (γ,γ’)
i	²⁰⁸Pb(⁹⁰Zr,xγ)	j	⁸²Se(¹³C,3nγ)
k	⁹²Zr(α,α’γ)	l	⁹¹Zr(n,γ) E=292 EV

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 Q R S T U V W X Y Z a c d f g h i j k l	0+	STABLE
934.51 4	A B C D E F G H I J K L M N O P Q R S T U W X Y Z a c d f g i j k l	2+	5.0 ps 4	934.47 4	100	E2	0.0	0+
1382.77 7	A E F G I J L N O Q R S W X a c d h	0+	88 ps 3	448.26 7 1383	100	E2 E0	934.51 0.0	2+ 0+
1495.46 5	A C D E F G H I J K L M N P Q S T U V W X a c d f g h i j k l	4+	102 ps 3	560.92 15	100	E2	934.51	2+
1847.27 4	A B E F G H I J K L M N P R T W X Z a c d f h	2+	96 fs 10	912.72 6 1847.27 5	100.0 23 51 3	(M1(+E2)) E2	934.51 0.0	2+ 0+
2066.65 5	A B E F G H I J K L M W X c d f l	2+	> 0.76 ps	219.07 15 ? 571.28 15 1132.12 5 2066.7 4	0.64 10 0.60 20 100 3 0.53 7	(M1+E2) E2	1847.27 1495.46 934.51 0.0	2+ 4+ 2+ 0+
2182 10	K	(2+)
2339.66 4	A E F G H I J K L M N P R T V W X d l	3-	0.28 ps 3	272.85 24 ? 492.37 10 844.12 6 1405.06 5 2339.9 1	10.8 5 29.9 19 100 4 ≈0.11	(E1(+M2)) (E1+M2) (E1) E3	2066.65 1847.27 1495.46 934.51 0.0	2+ 2+ 4+ 2+ 0+
2398.36 6	E F G H I K N W X b d f g	4+	149 fs 16	902.92 7 1463.81 10	100.0 21 35 3	M1+E2 E2(+M3)	1495.46 934.51	4+ 2+
2473.4 5 ?	A	(LE2)		2473.6 2 ?	100		0.0	0+
2486.01 9	D E F I J K L N R W X b c d e g	5-	≤ 3.5 ns	990.52 9	100	(E1)	1495.46	4+
2666 30	J X a b e f
2743.55 7	F I R	4-	> 2.63 ps	257.57 10 344.8 3 403.83 9 1248.00 11	90 5 4.0 16 57 3 100 5	(M1(+E2)) (M1(+E2)) (E1(+M2))	2486.01 2398.36 2339.66 1495.46	5- 4+ 3- 4+
2752 11 ?	K L M X b g h	3-
2819.54 7	A E F G I J K X b g h	2+	64 fs 7	972.30 9 1436.2 6 ? 1885.00 12 2819.8 3	100 4 4.7 21 38.7 23 4.6 4	(M1(+E2)) (M1+E2) E2	1847.27 1382.77 934.51 0.0	2+ 0+ 2+ 0+
E(level) (keV)	XREF	J^π(level)	T_1/2(level)	E(γ) (keV)	I(γ)	M(γ)	Final Levels
2864.66 9	E G I J K L M X b d e f	4+	0.24 ps 3	465.94 21 1369.25 10 1930.13 18	10.6 17 100 4 30 4	(M1(+E2)) M1+E2 E2(+M3)	2398.36 1495.46 934.51	4+ 4+ 2+
2904.08 18	E F I	0+	0.83 ps +57-24	837.4 2 1969.6 3	100 5 44 5	E2	2066.65 934.51	2+ 2+
2909.43 7	F G I X	3+	216 fs 24	569.47 17 842.69 15 1414.01 11 1974.93 10	3.9 11 32 4 60 4 100 17	M1+E2 M1+E2 M1+E2	2339.66 2066.65 1495.46 934.51	3- 2+ 4+ 2+
2957.4 3	C D E G H J K b c g i j	6+	≤ 3.5 ns	471.3? 559.6? 1461.93 26	100	(E2)	2486.01 2398.36 1495.46	5- 4+ 4+
3039.70 6	A E F I L M X c d f l	3	91 fs 10	295.77 19 700.10 9 1192.49 27 2105.18 8	4.2 8 23.8 21 4.6 12 100 7	D(+Q) D(+Q) D(+Q)	2743.55 2339.66 1847.27 934.51	4- 3- 2+ 2+
3057.40 13	E G I J K L M X c d f	2+	98 fs 10	717.9 2 990.5 2 1674.9 5 2123.0 3 3057.2 5	31.5 19 ≈100 6.7 5 39.1 21 8.2 7	D(+Q) E2 M1+E2 E2	2339.66 2066.65 1382.77 934.51 0.0	3- 2+ 0+ 2+ 0+
3124.61 11	G I a b d f	1(+)	58 fs 6	1057.97 10 1741.6 3 2190.3 5 3124.5 5	49 3 100 5 27.3 17 31.4 18	D(+Q) D D	2066.65 1382.77 934.51 0.0	2+ 0+ 2+ 0+
3178.31 11	F I J K M X a c d g h	4+	54 fs 6	779.94 10 2243.80 26	100.0 15 25.8 15	M1(+E2) E2(+M3)	2398.36 934.51	4+ 2+
3190.99 21	G H I J X a b d e g h	(4-)	153 fs 18	1695.5 2	100	D(+Q)	1495.46	4+
3236.9 6	E G H J K L a b d e	4+		1741.8 2 ?	100	D+Q	1495.46	4+
3262.62 4	A F G H I K L M X b c d e g h	2+	12.5 fs 14	2328.17 13 3262.54 4	100.0 17 29.3 17	(M1+E2) E2	934.51 0.0	2+ 0+
E(level) (keV)	XREF	J^π(level)	T_1/2(level)	E(γ) (keV)	I(γ)	M(γ)	Final Levels
3275.76 8	F I K X b d e g	2+,3+	53 fs 6	366.62 19 ? 877.45 10 1209.22 10 1428.7 5 2340.90 16	8.3 17 23.1 15 100 6 4.2 5 45 4	D,Q Q(+D) M1+E2	2909.43 2398.36 2066.65 1847.27 934.51	3+ 4+ 2+ 2+ 2+
3289.13 7	F G I K X b d e g	3+	174 fs 19	379.60 10 891.0 4 1222.47 9 1441.2 3 1793.87 23 2354.80 13	78 4 5 3 93 5 26.4 18 33.8 26 100 9	D(+Q) M1+E2 M1+E2 M1+E2 M1+E2	2909.43 2398.36 2066.65 1847.27 1495.46 934.51	3+ 4+ 2+ 2+ 4+ 2+
3304 10	E M b d	6+
3308.7 4	C D M R a b d g i j	(8+)	1.18 ns 7	351.3 2	100	E2	2957.4	6+
3325 8 ?	G H J M R a b d g	(+)
3345 20	H J K M b d g	5-
3371.48 8	A E F G I c d g h	1(-)	27 fs 3	1032.0 3 1988.71 10 2436.92 10 3371.2 3	2.8 7 100 13 45.1 20 51 5	(E1) (E1(+M2)) (E1)	2339.66 1382.77 934.51 0.0	3- 0+ 2+ 0+
3379.8 10	D g	(7-)	≤ 3.5 ns	893.8	100		2486.01	5-
3382 20	G K N a c d g	3-
3407.83 17	I N a c d	2-,3-	0.30 ps 4	1068.2 2 2473.2 3	100 4 73 4	M1+E2 (E1(+M2))	2339.66 934.51	3- 2+
3446 14	J K L M c d	3-
3452.17 7	F I J c d	(2)+	58 fs 6	632.12 24 ? 1112.65 22 1604.86 10 1956.60 12 2069.5 4 2517.73 11	7.7 19 21.7 90 4 67 6 16 5 100 4	M1+E2 M1+E2	2819.54 2339.66 1847.27 1495.46 1382.77 934.51	2+ 3- 2+ 4+ 0+ 2+
E(level) (keV)	XREF	J^π(level)	T_1/2(level)	E(γ) (keV)	I(γ)	M(γ)	Final Levels
3463.04 15	E I J M a c d e	(4)+	137 fs +21-17	1967.53 15 2528.7 5	100.0 23 33.8 23	E2(+M3)	1495.46 934.51	4+ 2+
3471.88 16	F G H I c d f g h i	1+	5.3 fs 6	2089.6 5 2537.1 2 3471.9 5	17.9 14 39.2 23 100 5	(M1) M1 M1	1382.77 934.51 0.0	0+ 2+ 0+
3491 20	K V c d e	(3-)
3499.88 10	E F H V c d e g h i	2+	53 fs 5	224.7 3 590.67 22 680.65 21 1159.54 16 1433.6 4 1652.8 3 2565.6 5 3499.8 5	3.6 12 10.8 24 9.6 24 22.4 18 19.3 14 56 3 15.8 13 100 5	(E1(+M2)) M1+E2 M1+E2 E2	3275.76 2909.43 2819.54 2339.66 2066.65 1847.27 934.51 0.0	2+,3+ 3+ 2+ 3- 2+ 2+ 2+ 0+
3589 10	E K V c d e g h	0+
3602 9	E G H K M b d e f g h i	(5-)
3609.5 4	I	(0+)	151 fs +26-23	1762.3 5 2674.8 5	29 4 100 4		1847.27 934.51	2+ 2+
3628.33 7	E F H I J K c d e f g i	(4+)	26 fs 3	588.32 24 808.67 22 884.74 11 1229.81 22 2132.90 11 2693.86 12	1.6 4 2.9 4 17.5 17 3.6 7 25.8 25 100 11		3039.70 2819.54 2743.55 2398.36 1495.46 934.51	3 2+ 4- 4+ 4+ 2+
3638.2 3	I J K b c d f h	1-	8.4 fs 11	2255.4 3 3638.0 5	14.1 16 100.0 16	(E1) E1	1382.77 0.0	0+ 0+
3640.28 11	E F H I J K b c d e f g i	(2)+	128 fs 15	601.1 3 ? 821.0 3 1301.0 5 2705.76 12	3.3 13 4.0 13 9 3 100 15	M1+E2	3039.70 2819.54 2339.66 934.51	3 2+ 3- 2+
E(level) (keV)	XREF	J^π(level)	T_1/2(level)	E(γ) (keV)	I(γ)	M(γ)	Final Levels
3649.22 12	F G H I L X d e g i	3+	56 fs 7	1162.7 3 1251.16 18 1800.74 27 ? 2153.68 18 2714.1 4	35 8 52 4 26 4 100 7 73 5	M1+E2 D(+Q) M1+E2 M1+E2	2486.01 2398.36 1847.27 1495.46 934.51	5- 4+ 2+ 4+ 2+
3667.1 10	h	1		3667	100	D	0.0	0+
3675.8 4	I	3+,4+,5+	116 fs +24-20	2180.3 4	100	M1+E2	1495.46	4+
3696.8 4	I h	1(+)	17.3 fs 28	2762.3 4 3696.5 7	99 7 100 7	(M1+E2) (M1)	934.51 0.0	2+ 0+
3704 7	E G H K a d f g h	(4)+
3725 9	G H K a d f g h	+
3760 10	E H d f h	2+
3767 20	K	5-
3774.6 3	I	(1,2+)	17 fs 5	1708.1 5 1927.1 5 2839.9 5 3774.6 8	49 10 35 7 100 20 46 9		2066.65 1847.27 934.51 0.0	2+ 2+ 2+ 0+
3783 7	E G H d f h	(4)+
3804.7 5	I	(LE4)	9 fs +6-5	2870.1 5	100		934.51	2+
3814 10	G H N b d h	(4)+
3819.4 12	D g	(8-)	≤ 3.5 ns	439.6 5	100	D	3379.8	(7-)
3830.31 9	F H I K b d h	(1-,2+)		378.21 16 790.70 11 1490.7 3 1763.39 18 2447.3 3 2895.1 10	38 6 75 15 92 18 58 6 34 6 100 18		3452.17 3039.70 2339.66 2066.65 1382.77 934.51	(2)+ 3 3- 2+ 0+ 2+
3891 10	G H J K L b d g h i
3902 10	E G K L d g h i
3915 1	h	1		3915	100	D	0.0	0+
E(level) (keV)	XREF	J^π(level)	T_1/2(level)	E(γ) (keV)	I(γ)	M(γ)	Final Levels
3944 20	H J K R c d i	5-
3971 10	G J N R c d i
3983 10	G J K N c d i
3992 10	E J K c d	0+
3998.7 12 ?	D g	(9-)	≤ 3.5 ns	179.4 5 ? 618.8?	57 6 ≈100	D	3819.4 3379.8	(8-) (7-)
4012 10	E G H K c d h i	+
4040 7	E G H J K L a b c d h i	4+
4082 7	E G K a c d g i	4+
4142 10	G H a c e i	2+,3+
4161 10	E H J a c e i	4+
4181 20	K	3-
4183 10	G H a c e i	(+)
4213 11	G H a c e i	2+,3+
4256 10	G K	4+
4270	N R b c h	(5-)
4283 10	E R b c h	0+
4296.6 4	C D g i j	(10+)	≤ 3.5 ns	987.9 2	100	(Q)	3308.7	(8+)
4332 10	E J K a b c d f	2+
4380	N	(4+)
4397 20	K	2+
4453 11	G H J K L c d f	(2)+
4465 11	G H J K L c d f	4+
4494 11	G
4504 11	G
4539 20	K	3-
4604 12	G H	+
4606 20	K	(5-)
4640 12	G	-
4670 12	G	+
E(level) (keV)	XREF	J^π(level)	T_1/2(level)	E(γ) (keV)	I(γ)	M(γ)	Final Levels
4720 10	G J K	(2+,3+)
4785 10	G H K c g h	(2+,3+)
4807 20	H K L a c g h	(3-)
4813 12	G H L a c g h
4821 12	G H K L a c d g h
4847 12	G K c d g h	(-)
4894 12	G	(+)
4928 10	G K	5-
4947.2 7	C D g i j	(12+)	≤ 3.5 ns	650.6 5	100	(E2)	4296.6	(10+)
4977 12	G
4982 12	G
5012 11	G K	-
5040 13	G	(-)
5056 20	K	4+
5067 13	G	2+,3+
5091 13	G	+
5115 11	G K N	(4)+
5197 13	G
5215 13	G
5278 13	G H b e f i
5310 13	G H b e f i	(2+,3+)
5358 13	G	-
5455 20	K
5490	L N a e	(0+)
5537 20	K L a e
5581 20	K	(2+)
5680	N	(4+)
5685 20	K	3-
5885 20	K V	3-
6045.5 12	C g i j	(14+)		1098.3	100		4947.2	(12+)
E(level) (keV)	XREF	J^π(level)	T_1/2(level)	E(γ) (keV)	I(γ)	M(γ)	Final Levels
6056	K	3-
6125 20	K
6187	K	3-
6240	N	(4+)
6334	K	3-
6436	K	3-
6990 90	V
7.0E+03 4	P
7.4E+3 1	V
7445.8 16	C g i j	(16+)		1400.3	100		6045.5	(14+)
8039.1 19 ?	C j	(17,18+)	42 ps 14	593?	100	D,E2	7445.8	(16+)
8634.82 8 S	F	2+		4804.7 4985.1 7 4995.0 3 5006.1 3 5134.6 3 5162.5 3 5183.0 5 5263.2 5 5347.1 5359.5 5371.2 5 5594.7 4 5815.0 3 6237.2 6 6294.88 12 6568.2 7139.5 7251.8 9 7701.2 8634.4 2	2.8 8 6.7 8 11.8 8 3.6 4 3.6 4 7.0 14 21.6 24 6.1 14 1.6 4 1.2 4 1.2 4 100 3 0.4 4 5.1 4		3830.31 3649.22 3640.28 3628.33 3499.88 3471.88 3452.17 3371.48 3289.13 3275.76 3262.62 3039.70 2819.54 2398.36 2339.66 2066.65 1495.46 1382.77 934.51 0.0	(1-,2+) 3+ (2)+ (4+) 2+ 1+ (2)+ 1(-) 3+ 2+,3+ 2+ 3 2+ 4+ 3- 2+ 4+ 0+ 2+ 0+
E(level) (keV)	XREF	J^π(level)	T_1/2(level)	E(γ) (keV)	I(γ)	M(γ)	Final Levels
8.8E+03 2	J	1+	1.4 MeV 2
9127.5 19	g	(18+)		1681.3?	100		7445.8	(16+)
9722.2 22	j	(LE20)		1683?			8039.1	(17,18+)
13.2E+3 1	Z	2+	3.8 MeV 2
13.7E+3 5	J	2+ AND 4+
15.7E+3 1	Z	0+	4.0 MeV 2
16.20E3 5	Z b	1-	4.68 MeV
17.5E+3 3	J	0+ AND 4+	3.3 MeV
25.1E+3 3	P Z	3-	6.3 MeV 3
28.1E+3 3	Z	2+	5.9 MeV 2

E(level) (keV)	J^π(level)	T_1/2(level)	E(γ)	I(γ)	M(γ)	Final Levels
Band 1 - π=+ ΔJ=2 SEQUENCE.
0.0	0+	STABLE
934.51 4	2+	5.0 ps 4	934.47 4	100	E2	0.0	0+
1495.46 5	4+	102 ps 3	560.92 15	100	E2	934.51	2+
2957.4 3	6+	≤ 3.5 ns	471.3? 559.6? 1461.93 26	100	(E2)	2486.01 2398.36 1495.46	5- 4+ 4+
3308.7 4	(8+)	1.18 ns 7	351.3 2	100	E2	2957.4	6+
4296.6 4	(10+)	≤ 3.5 ns	987.9 2	100	(Q)	3308.7	(8+)
4947.2 7	(12+)	≤ 3.5 ns
6045.5 12	(14+)		1098.3	100		4947.2	(12+)
7445.8 16	(16+)		1400.3	100		6045.5	(14+)
9127.5 19	(18+)		1681.3?	100		7445.8	(16+)

E(level)	J^π(level)	T_1/2(level)	Comments
0.0	0+	STABLE	Δ<r²>(92,90)=0.224 26 (1999GaZX), 0.224 25 (1988GaZS); Δ<r²>(92,94)=0.170 19 (1988GaZS). E(level): Δ<r²>(92,90)=0.224 26 (1999GaZX), 0.224 25 (1988GaZS); Δ<r²>(92,94)=0.170 19 (1988GaZS). π=+ ΔJ=2 SEQUENCE.
934.51	2+	5.0 ps 4	μ=-0.360 20 (1999Ja13) E(level): π=+ ΔJ=2 SEQUENCE.
1495.46	4+	102 ps 3	μ=-2.0 4 (1999Ja13) E(level): π=+ ΔJ=2 SEQUENCE.
1847.27	2+	96 fs 10	μ=+1.5 10 (2008We07) Level exhibits structure expected for a mixed symmetry one-phonon Q excitation (2002We15). E(level): Level exhibits structure expected for a mixed symmetry one-phonon Q excitation (2002We15). T_1/2(level): From DSAM in (n,n’γ).
2066.65	2+	> 0.76 ps	T_1/2(level): From DSAM in (n,n’γ).
2182	(2+)		Probably same level as in (p,p’) at E=2180? 22. E(level): Probably same level as in (p,p’) at E=2180? 22.
2339.66	3-	0.28 ps 3	For summary of B(E3)\|^ data, see 1989Sp01; recommended value is 0.067 22 based on b₃ from angular distribution in (p,p’). This corresponds to 4.4% 15 of energy-weighted E3 sum rule. E(level): For summary of B(E3)\|^ data, see 1989Sp01; recommended value is 0.067 22 based on b₃ from angular distribution in (p,p’). This corresponds to 4.4% 15 of energy-weighted E3 sum rule. T_1/2(level): From DSAM in (n,n’γ).
2398.36	4+	149 fs 16	XREF: X(2360). T_1/2(level): From DSAM in (n,n’γ).
2486.01	5-	≤ 3.5 ns	XREF: R(2450).
2666			Excitation of level in (p,p’) is not certain. E(level): Excitation of level in (p,p’) is not certain.
2743.55	4-	> 2.63 ps	T_1/2(level): From DSAM in (n,n’γ).
2752	3-		E(level): State reported also in numerous ⁹²Zr inelastic scattering spectra. Evaluator believes these observations can be attributed largely, if not entirely, to a known 3- ⁹⁰Zr state contributing in these experiments via the typical ≈3% ⁹⁰Zr target impurity. It is unclear whether excitation of the 4- 2744 level via inelastic scattering is masked by the impurity or absent altogether.
2819.54	2+	64 fs 7	T_1/2(level): From DSAM in (n,n’γ).
2864.66	4+	0.24 ps 3	XREF: J(2650). T_1/2(level): From DSAM in (n,n’γ).
2904.08	0+	0.83 ps +57-24	T_1/2(level): From DSAM in (n,n’γ).
2909.43	3+	216 fs 24	T_1/2(level): From DSAM in (n,n’γ).
2957.4	6+	≤ 3.5 ns	XREF: H(2944). E(level): π=+ ΔJ=2 SEQUENCE.
3039.70	3	91 fs 10	T_1/2(level): From DSAM in (n,n’γ).
3057.40	2+	98 fs 10	XREF: J(3040). T_1/2(level): From DSAM in (n,n’γ).
3124.61	1(+)	58 fs 6	XREF: γ(3126). T_1/2(level): From DSAM in (n,n’γ).
3178.31	4+	54 fs 6	XREF: K(3187)M(3140). T_1/2(level): From DSAM in (n,n’γ).
3190.99	(4-)	153 fs 18	T_1/2(level): From DSAM in (n,n’γ).
3262.62	2+	12.5 fs 14	XREF: M(3240). T_1/2(level): From DSAM in (n,n’γ).
3275.76	2+,3+	53 fs 6	T_1/2(level): From DSAM in (n,n’γ).
3289.13	3+	174 fs 19	T_1/2(level): From DSAM in (n,n’γ).
E(level)	J^π(level)	T_1/2(level)	Comments
3308.7	(8+)	1.18 ns 7	E(level): π=+ ΔJ=2 SEQUENCE.
3371.48	1(-)	27 fs 3	T_1/2(level): From DSAM in (n,n’γ).
3407.83	2-,3-	0.30 ps 4	T_1/2(level): From DSAM in (n,n’γ).
3452.17	(2)+	58 fs 6	T_1/2(level): From DSAM in (n,n’γ).
3463.04	(4)+	137 fs +21-17	XREF: E(3451). T_1/2(level): From DSAM in (n,n’γ).
3471.88	1+	5.3 fs 6	XREF: γ(3469). T_1/2(level): From DSAM in (n,n’γ).
3499.88	2+	53 fs 5	L=2 in (t,p). E(level): L=2 in (t,p). T_1/2(level): From DSAM in (n,n’γ).
3602	(5-)		XREF: M(3620).
3609.5	(0+)	151 fs +26-23	2675γ to 2⁺ 934; J=(0) from excit in (n,n’γ). E(level): 2675γ to 2⁺ 934; J=(0) from excit in (n,n’γ). T_1/2(level): From DSAM in (n,n’γ).
3628.33	(4+)	26 fs 3	2694γ to 2⁺ 934; 885γ to 4- 2744; 2133γ to 4⁺ 1495; L(t,p)=2⁺(4) for 3628⁺3640 doublet so this is presumed to be the L=(4) component. E(level): 2694γ to 2⁺ 934; 885γ to 4- 2744; 2133γ to 4⁺ 1495; L(t,p)=2⁺(4) for 3628⁺3640 doublet so this is presumed to be the L=(4) component. T_1/2(level): From DSAM in (n,n’γ).
3638.2	1-	8.4 fs 11	T_1/2(level): From DSAM in (n,n’γ).
3640.28	(2)+	128 fs 15	T_1/2(level): From DSAM in (n,n’γ).
3649.22	3+	56 fs 7	T_1/2(level): From DSAM in (n,n’γ).
3675.8	3+,4+,5+	116 fs +24-20	T_1/2(level): From DSAM in (n,n’γ).
3696.8	1(+)	17.3 fs 28	T_1/2(level): From DSAM in (n,n’γ).
3774.6	(1,2+)	17 fs 5	T_1/2(level): From DSAM in (n,n’γ).
3804.7	(LE4)	9 fs +6-5	T_1/2(level): From DSAM in (n,n’γ).
3891			XREF: J(3870).
3944	5-		XREF: H(3909).
4040	4+		XREF: E(4031)J(4020).
4082	4+		XREF: E(4071)γ(4093).
4161	4+		XREF: J(4150).
4296.6	(10+)	≤ 3.5 ns	E(level): π=+ ΔJ=2 SEQUENCE.
4332	2+		XREF: E(4332)J(4300)K(4316).
4947.2	(12+)	≤ 3.5 ns	E(level): π=+ ΔJ=2 SEQUENCE.
E(level)	J^π(level)	T_1/2(level)	Comments
6045.5	(14+)		E(level): π=+ ΔJ=2 SEQUENCE. ΔE=3 keV if 1 keV is assumed for unknown ΔE(γ).
7.0E+03			Possible low energy octupole resonance (1981Ya02). Note: E(res)≈6.3 MeV from (α,α’) (1980ToZS). E(level): Possible low energy octupole resonance (1981Ya02). Note: E(res)≈6.3 MeV from (α,α’) (1980ToZS).
7445.8	(16+)		E(level): π=+ ΔJ=2 SEQUENCE. ΔE=3 keV if 1 keV is assumed for unknown ΔE(γ).
8039.1	(17,18+)	42 ps 14	E(level): ΔE=3 keV if 1 keV is assumed for unknown ΔE(γ).
8634.82	2+		J^π(level): Jπ=2⁺,3⁺ for thermal n capture on 5/2⁺ target. Jπ=2⁺ is adopted because γγ(θ) data indicate very little, if any, mixing for 6295γ to 3- state if J=2 but considerable mixing if J=3. Also, γ decay to both 0⁺ and 4⁺ levels is observed from the capture state.
8.8E+03	1+	1.4 MeV 2	M1 giant resonance. E(level): M1 giant resonance.
9127.5	(18+)		E(level): π=+ ΔJ=2 SEQUENCE.
13.2E+3	2+	3.8 MeV 2	GQR. t=0. E(level): GQR. t=0.
13.7E+3	2+ AND 4+		GMR including 13200, 2⁺ resonance seen in (e,e’). E(level): GMR including 13200, 2⁺ resonance seen in (e,e’).
15.7E+3	0+	4.0 MeV 2	Isoscalar giant monopole resonance. E(level): Isoscalar giant monopole resonance.
16.20E3	1-	4.68 MeV	Γ: from (γ,xn)+(γ,np). E(level): Γ: from (γ,xn)+(γ,np).
17.5E+3	0+ AND 4+	3.3 MeV	Γ: from (p,p’). E(level): Γ: from (p,p’).
25.1E+3	3-	6.3 MeV 3	t=0. High energy isoscalar octupole giant resonance. E(level): t=0. High energy isoscalar octupole giant resonance.
28.1E+3	2+	5.9 MeV 2	Isovector GQR. E(level): Isovector GQR.

E(level)	E(gamma)	Comments
934.51	934.47	E(γ): weighted average of 934.47 7 from β^- decay, 934.44 10 from ε decay (10.15 d), 934.46 5 from (n,γ) E=thermal and 934.5 1 from (n,n’γ). M(γ): Q to 0⁺, from γ(θ) in (⁷Li,2npγ); Δπ=no from RUL. E2 confirmed by α(exp) in ⁹²Nb ε decay (10.15 d).
1382.77	448.26	E(γ): weighted average of 448.5 1 (from β^- decay), 448.13 7, 448.22 10, 448.3 2 (all from (n,γ) E=thermal) and 448.3 1 (from (n,n’γ)). (the unweighted average is 448.29 6.) M(γ): mult=Q to 2⁺, from γγ(θ) in ⁹²Y β^- decay; not M2, from RUL.
1495.46	560.92	E(γ): weighted average of 561.1 1 from β^- decay and (n,n’γ), 561.0 2 from (⁷Li,2npγ) and 560.93 5 from (n,γ) E=thermal. M(γ): mult=Q from γ(θ) in (⁷Li,2npγ); not M2 from RUL.
1847.27	912.72	I(γ): from (n,n’γ). M(γ): mult=d(+Q) from ⁹²Nb(10.15 d) ε decay; Δπ=no from level scheme.
1847.27	1847.27	E(γ): weighted average of 1847.3 1, 1847.5 3, 1847.27 9 and 1847.2 1 from β^- decay, ε decay (10.15 d), (n,γ) E=thermal and (n,n’γ), respectively. I(γ): unweighted average of 58 4, 47.8 22, 52 8 and 44.6 23 from β^- decay, ε decay (10.15 d), (n,γ) E=thermal and (n,n’γ), respectively (weighted average is 47.9 25).
2066.65	219.07	I(γ): weighted average of 0.61 12 from (n,n’γ), 0.71 20 from (n,γ) E=thermal
	1132.12	E(γ): weighted average of 1132.17 14, 1132.11 6 and 1132.1 1 from ε decay, (n,γ) E=thermal and (n,n’γ), respectively. Other Eγ: 1132.4 1 from β^- decay. M(γ): D+Q from γγ(θ) in (n,γ) and (n,n’γ); adopted Δπ=no.
	2066.7	E(γ): From (n,n’γ). I(γ): From (n,n’γ).
2339.66	492.37	I(γ): unweighted average of 11.7 7 from (n,n’γ), 10.6 9 from (n,γ) E=thermal and 10.1 6 from β^- decay. Weighted average is 10.7 5. M(γ): d(+Q) from γ(θ) in (n,n’γ), Δπ=yes from level scheme.
	844.12	I(γ): unweighted average of 32.3 18 from (n,n’γ), 31.1 22 from (n,γ) E=thermal and 26.2 17 from β^- decay. Weighted average is 29.6 20. M(γ): D+Q from γ(θ) in (n,n’γ), Δπ=yes from level scheme.
	1405.06	I(γ): weighted average from (n,n’γ), (n,γ) E=thermal and β^- decay. M(γ): mult=d(+Q) from γγ(θ) in (n,γ), ⁹²Y β^- decay, and from γ(θ) in (n,n’γ); adopted Δπ=yes.
	2339.9	M(γ): from form factor in (e,e’).
2398.36	902.92	I(γ): weighted average from (n,n’γ) and (n,γ) E=thermal.
2398.36	1463.81	I(γ): weighted average of 35.9 23 from (n,n’γ) and 27 7 from (n,γ) E=thermal.
2486.01	990.52	M(γ): mult=d or d(+Q) to 4⁺, from γ(θ) in (⁷Li,2npγ) and (n,n’γ), respectively; Δπ=yes from level scheme.
2743.55	257.57	I(γ): from (n,n’γ). 72 7 from (n,γ) E=thermal if I(404γ)=57. M(γ): d(+Q) from (n,n’γ); Δπ=no from level scheme.
	344.8	I(γ): from (n,γ) E=thermal branching renormalized so I(404γ)=57.
	403.83	I(γ): from (n,n’γ). M(γ): d(+Q) from (n,n’γ); Δπ=no from level scheme.
	1248.00	I(γ): from (n,n’γ). M(γ): d(+Q) from (n,n’γ); Δπ=yes from level scheme.
2819.54	972.30	I(γ): weighted average from β^- decay, (n,n’γ) and (n,γ) E=thermal. M(γ): from γ(θ) in (n,n’γ), assuming Δπ from level scheme.
	1885.00	I(γ): unweighted average of 34.2 19 from (n,n’γ), 41 4 from from (n,γ) E=thermal and 41 5 from β^- decay. Weighted average is 36.0 21. M(γ): D+Q from γ(θ) in (n,n’γ), Δπ=no from level scheme.
	2819.8	E(γ): from β^- decay. Other: 2819.3 7 from (n,n’γ). I(γ): weighted average of 4.5 4 from (n,n’γ) and 6.1 18 from β^- decay.
2864.66	465.94	I(γ): weighted average of 11.1 10 from (n,n’γ) and 8.0 22 from (n,γ) E=thermal. M(γ): d(+Q) from (n,n’γ); Δπ=no from level scheme.
	1369.25	I(γ): weighted average of 100 5 from (n,n’γ) and 100 5 from (n,γ) E=thermal.
	1930.13	I(γ): unweighted average of 26.7 17 from (n,n’γ) and 34 3 from (n,γ) E=thermal.
E(level)	E(gamma)	Comments
2904.08	837.4	E(γ): From (n,n’γ). I(γ): From (n,n’γ).
2904.08	1969.6	E(γ): From (n,n’γ). I(γ): From (n,n’γ).
2957.4	471.3	E(γ): from ¹⁷³Yb(²⁴Mg,Fγ)⁹²Zr; unconfirmed in ¹⁷⁶Yb(²⁸Si,Xγ) or ¹⁷⁶Yb(³¹P,Xγ) so placement shown as tentative here.
	559.6	E(γ): from ¹⁷³Yb(²⁴Mg,Fγ)⁹²Zr; unconfirmed in ¹⁷⁶Yb(²⁸Si,Xγ) or ¹⁷⁶Yb(³¹P,Xγ) so placement shown as tentative here.
	1461.93	E(γ): weighted average of 1461.8 3 in (n,γ) E=thermal and 1462.3 5 from (⁷Li,2npγ). M(γ): mult=(Q) from γ(θ) in (⁷Li,2npγ); (6)+ to 4⁺ transition.
3057.40	717.9	E(γ): From (n,n’γ). I(γ): From (n,n’γ). M(γ): d(+Q) from γ(θ) in (n,n’γ); Δπ=no from level scheme.
	990.5	E(γ): From (n,n’γ). I(γ): From (n,n’γ).
	1674.9	E(γ): From (n,n’γ). I(γ): From (n,n’γ).
	2123.0	E(γ): From (n,n’γ). I(γ): From (n,n’γ).
	3057.2	E(γ): From (n,n’γ). I(γ): From (n,n’γ).
3124.61	1057.97	E(γ): from (n,γ) E=thermal. Other Eγ: 1058.0 3 from (n,n’γ). I(γ): from (n,n’γ).
	1741.6	E(γ): From (n,n’γ). I(γ): From (n,n’γ).
	2190.3	E(γ): From (n,n’γ). I(γ): From (n,n’γ).
	3124.5	E(γ): From (n,n’γ). I(γ): From (n,n’γ).
3178.31	779.94	I(γ): from (n,n’γ). M(γ): D+Q from (n,n’γ); Δπ=no from level scheme.
3178.31	2243.80	I(γ): from (n,n’γ); 27 4 from (n,γ) E=thermal.
3262.62	2328.17	I(γ): from (n,n’γ). M(γ): D+Q from γ(θ) in (n,n’γ); Δπ=no from level scheme.
3262.62	3262.54	I(γ): from (n,n’γ). M(γ): Q from (γ,γ’); not M2 from RUL.
3275.76	877.45	I(γ): from (n,n’γ). Other: 29 6 from (n,γ) E=thermal.
3275.76	1428.7	E(γ): From (n,n’γ). I(γ): From (n,n’γ).
3289.13	379.60	I(γ): from (n,n’γ). Other Iγ: 55 12 in (n,γ) E=thermal.
	1222.47	I(γ): from (n,n’γ). Data from (n,γ) E=thermal are discrepant.
	1441.2	E(γ): weighted average of 1441.6 5 from (n,n’γ) and 1441.0 4 from (n,γ) E=thermal. I(γ): from (n,n’γ). Other: 12 3 from (n,γ) E=thermal.
	1793.87	I(γ): weighted average of 35.2 22 from (n,n’γ) and 29 4 from (n,γ) E=thermal.
3308.7	351.3	M(γ): Q from γ(θ) in (⁷Li,2npγ); not M2, from RUL.
E(level)	E(gamma)	Comments
3371.48	1988.71	M(γ): d from γ(θ) in (n,n’γ); Δπ from level scheme.
	2436.92	I(γ): average of 43.1 26 from (n,n’γ) and 47.0 26 from (n,γ) E=thermal. M(γ): d(+Q)) from γ(θ) in (n,n’γ), Δπ=yes from level scheme.
	3371.2	I(γ): unweighted average of 43 3 from (n,n’γ), 60 7 from (n,γ) E=thermal, 50 7 from β^- decay. (weighted average is 46 4.) M(γ): d from (γ,γ’); Δπ from level scheme.
3379.8	893.8	E(γ): from ¹⁷³Yb(²⁴Mg,Fγ)⁹²Zr.
3407.83	1068.2	E(γ): From (n,n’γ). I(γ): From (n,n’γ).
3407.83	2473.2	E(γ): From (n,n’γ). I(γ): From (n,n’γ). M(γ): d(+Q) from (n,n’γ); Δπ=yes from level scheme.
3452.17	1112.65	I(γ): from (n,n’γ). Other Iγ: 23 8 from (n,γ) E=thermal.
3452.17	1604.86	I(γ): weighted average of 86 6 from (n,γ) E=thermal and 92 5 from (n,n’γ). M(γ): For additional mult and δ information, see γ(θ) from (n,n’γ).
3463.04	1967.53	I(γ): from (n,n’γ).
3463.04	2528.7	E(γ): From (n,n’γ). I(γ): From (n,n’γ).
3471.88	2089.6	E(γ): From (n,n’γ). I(γ): From (n,n’γ). M(γ): d from γ(θ) in (n,n’γ); Δπ=no from level scheme.
	2537.1	I(γ): from (n,n’γ); 37 3 from (n,γ) E=thermal.
	3471.9	E(γ): From (n,n’γ). I(γ): From (n,n’γ). M(γ): from (pol γ,γ’); confirmed by γ(θ) in (n,n’γ).
3499.88	1159.54	I(γ): from (n,n’γ). Other: 30 4 from (n,γ) E=thermal. M(γ): d(+Q) from γ(θ) in (n,n’γ); Δπ=yes from level scheme.
	1433.6	E(γ): From (n,n’γ). I(γ): From (n,n’γ).
	1652.8	E(γ): From (n,n’γ). I(γ): From (n,n’γ).
	2565.6	E(γ): From (n,n’γ). I(γ): From (n,n’γ).
	3499.8	E(γ): From (n,n’γ). I(γ): From (n,n’γ).
3609.5	1762.3	E(γ): From (n,n’γ). I(γ): From (n,n’γ).
3609.5	2674.8	E(γ): From (n,n’γ). I(γ): From (n,n’γ).
3638.2	2255.4	E(γ): From (n,n’γ). I(γ): From (n,n’γ). M(γ): d from γ(θ) in (n,n’γ); Δπ=yes from level scheme.
3638.2	3638.0	E(γ): From (n,n’γ). I(γ): From (n,n’γ). M(γ): from (pol γ,γ’).
3640.28	1301.0	I(γ): from (n,n’γ).
3640.28	2705.76	I(γ): 100.0 26 from (n,n’γ).
3649.22	1251.16	I(γ): weighted average of 56 6 from (n,γ) E=thermal and 50 5 from (n,n’γ).
	1800.74	I(γ): from (n,n’γ); 43 11 from (n,γ) E=thermal.
	2153.68	I(γ): from (n,n’γ); 100 11 from (n,γ) E=thermal.
	2714.1	I(γ): from (n,n’γ); 97 16 from (n,γ) E=thermal.
E(level)	E(gamma)	Comments
3667.1	3667	E(γ): from level-energy difference. M(γ): from (γ,γ’); if M1, B(M1)(W.u.)=0.0037 6 (2002We15 in (γ,γ’)).
3675.8	2180.3	E(γ): From (n,n’γ). I(γ): From (n,n’γ). M(γ): D+Q from γ(θ) in (n,n’γ); Δπ=no from RUL.
3696.8	2762.3	E(γ): From (n,n’γ). I(γ): From (n,n’γ). M(γ): D+Q from γ(θ) in (n,n’γ); Δπ=(no) from RUL.
3696.8	3696.5	E(γ): From (n,n’γ). I(γ): From (n,n’γ). M(γ): d from (γ,γ’); Δπ=no from level scheme.
3774.6	1708.1	E(γ): From (n,n’γ). I(γ): From (n,n’γ).
	1927.1	E(γ): From (n,n’γ). I(γ): From (n,n’γ).
	2839.9	E(γ): From (n,n’γ). I(γ): From (n,n’γ).
	3774.6	E(γ): From (n,n’γ). I(γ): From (n,n’γ). M(γ): not M2 from RUL.
3804.7	2870.1	E(γ): From (n,n’γ). I(γ): From (n,n’γ).
3819.4	439.6	M(γ): from γ(θ) in (⁷Li,2npγ).
3830.31	1490.7	I(γ): from (n,n’γ).
3830.31	2895.1	E(γ): From (n,n’γ). I(γ): From (n,n’γ).
3915	3915	E(γ): from level-energy difference. M(γ): from (γ,γ’); if M1, B(M1)(W.u.)=0.022 3 (2002We15 in (γ,γ’)).
3998.7	179.4	M(γ): from γ(θ) in (⁷Li,2npγ).
3998.7	618.8	E(γ): from ¹⁷³Yb(²⁴Mg,Fγ)⁹²Zr.
4296.6	987.9	M(γ): from γ(θ) in (⁷Li,2npγ).
4947.2	650.6	M(γ): (Q) from γ(θ) in (⁷Li,2npγ); not M2, from RUL.
6045.5	1098.3	E(γ): from ¹⁷³Yb(²⁴Mg,Fγ)⁹²Zr.
7445.8	1400.3	E(γ): from ¹⁷³Yb(²⁴Mg,Fγ)⁹²Zr.
8039.1	593	M(γ): from RUL.
9127.5	1681.3	E(γ): from ¹⁷³Yb(²⁴Mg,Fγ)⁹²Zr; unconfirmed in ¹⁷⁶Yb(²⁸Si,Xγ) or ¹⁷⁶Yb(³¹P,Xγ) so placement shown as tentative here.
9722.2	1683	E(γ): from (¹³C,3nγ) only.