List of levels for 52CR

ADOPTED LEVELS, GAMMAS for ⁵²Cr

Authors: Yang Dong, Huo Junde | Citation: Nucl. Data Sheets 128, 185 (2015) | Cutoff date: 10-Jul-2015

Full ENSDF file | Adopted Levels (PDF version)

Q(β-)=-4711.2 keV 19	S(n)= 12038.4 keV 9	S(p)= 10503.4 keV 9	Q(α)= -9351.3 keV 6
Reference: 2012WA38

References:
A	⁵²V β^- decay (3.743 M)	B	⁵²Mn ε decay (5.591 d)
C	⁵²Mn ε decay (21.1 M)	D	(HI,xnγ)
E	⁵⁰Ti(³He,n)	F	⁵²Cr(p,p’γ)
G	⁵²Cr(p,p’)	H	⁵⁰Cr(t,p)
I	⁵¹V(p,γ) E=RES:IAR	J	⁵¹V(³He,d)
K	⁵¹V(³He,dγ)	L	⁵⁵Mn(p,α)
M	⁵²Cr(γ,γ’),(pol γ,γ’)	N	⁵²Cr(E,E’)
O	⁵²Cr(π⁺,π⁺),(π⁺,π⁺’)	P	⁵²Cr(n,n’)
Q	⁵²Cr(n,n’γ)	R	⁵⁰V(α,d)
S	⁵⁰Ti(¹⁶O,¹⁴C)	T	⁵²Cr(d,d’)
U	⁵²Cr(³He,³He’)	V	⁵²Cr(α,α’)
W	⁵²Cr(⁷Li,⁷Li’)	X	⁵²Cr(¹²C,¹²C’),(¹³C,¹³C’)
Y	⁵²Cr(¹⁶O,¹⁶O’),(¹⁸O,¹⁸O’)	Z	Coulomb Excitation
a	⁵⁰Cr(α,²He)	b	⁵³Cr(p,d)
c	⁵³Cr(d,t),(pol d,t)	d	⁵³Cr(³He,α)
e	⁵⁴Cr(p,t)	f	⁵⁵Mn(μ^-,3nγ)
g	⁵¹V(α,t)	h	⁵⁶Fe(d,⁶Li)
i	NI(K-,xγ),(π⁺,xγ),(π^-,xγ)

Other reactions: ⁴⁸Ti(α,γ) E=6-12 MeV, 1976Fo04; ⁴⁸Ti(¹⁶O,¹²C) E=120 MeV (1979Da07); ⁵³Cr(¹²C,¹³C) E=18.5-33 MeV (1974PaZZ); ⁵⁴Fe(¹⁸O,²⁰Ne) E=48,50 MeV (1972SiYD,1975PeZM)

Levels: E(d) From ⁵³Cr(³He,α).

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 Q S U V W X Y Z a b c d e f g h i	0+	STABLE
1434.091 14	A B C D E F G H I J K L M N O P Q S T U V W X Y Z b c d e f g h i	2+	0.783 ps 21	1434.068 14	100	E2	0.0	0+
2369.630 18	A B C D F G I J K L N O P Q S T V W Z b c d e f g h	4+	6.7 ps +35-17	935.538 11	100	E2	1434.091	2+
2646.9 6	A F G H L N O Q S V b c e h	0+		1212.8 6	100	E2	1434.091	2+
2767.767 21	A B C D F G I J K L N O Q S T V W a b c d e g	4+	1.9 ps 5	398.08 9 1333.649 17	1.76 14 100 1	E2 E2	2369.630 1434.091	4+ 2+
2964.786 17	A C F G H I J K L N O Q S T V b	2+	0.42 ps 8	1530.67 1 2965 1	100 4 0.9 6	M1+E2 E2	1434.091 0.0	2+ 0+
3113.858 21	B D G I J K L N Q S V W a b g h	6+	41.4 ps 14	346.02 4 744.233 13	1.09 1 100.0 9	E2 E2	2767.767 2369.630	4+ 4+
3161.74 6	A C F G H I K L M N O Q V W b e h	2+	0.035 ps 7	1727.53 7 3161.8 1	100 5 10.0 14	M1+E2 E2	1434.091 0.0	2+ 0+
3415.32 3	A B D F G I J K L O Q V b d	4+	0.26 ps 7	647.47 6 766.0 10 ? 1045.73 4 1981.12 4	100 5 17 5 8.5 8	M1+E2 [E2]	2767.767 2646.9 2369.630 1434.091	4+ 0+ 4+ 2+
3472.25 15	A C D F G I K L Q S b c d g	3+	7.2 ps 8	704.6 2 2038.0 2	100 44.2 12	M1+E2	2767.767 1434.091	4+ 2+
3615.924 22	B D G I J K L b	5+	2.6 ps 12	200.58 4 502.06 5 848.18 5 1246.278 15	1.80 5 5.0 5 78.9 7 100.0 14	M1	3415.32 3113.858 2767.767 2369.630	4+ 6+ 4+ 4+
3739.6	M	1+,1-,2+
3771.72 14	A C E F G H J K L M N O Q S V b c d g	2+	9 fs 2	2337.44 19 3771.7 2	100 14 26 6	M1+E2 [E2]	1434.091 0.0	2+ 0+
3947.5 6	G I K L Q b	2+	0.014 ps 7	1578			2369.630	4+
3951.2 10	C G H J	2+		3951 1			0.0	0+
4015.51 3	B D G I J K L d	5+	0.61 ps +27-19	399.57 5 600.16 5 901.89 18 1247.88 9 1645.82 4	46.9 18 100 3 11.3 11 97 10 12.1 8	M1 M1	3615.924 3415.32 3113.858 2767.767 2369.630	5+ 4+ 6+ 4+ 4+
E(level) (keV)	XREF	J^π(level)	T_1/2(level)	E(γ) (keV)	I(γ)	M(γ)	Final Levels
4039.1 11	D G I J K L N O V b	4+	26 fs 4	566.8	100		3472.25	3+
4.10E3 10	P c g	3-
4470	U	3-
4563.0 8	C G H J K L N O P Q S V X	3-	40 fs 6	791 3129 1			3771.72 1434.091	2+ 2+
4584.0 7	D	(6+)		1470.1 7	100		3113.858	6+
4611	I d	(3,4)+
4627.32 19	B G J L O g	4+		2257.42 19	100		2369.630	4+
4702 5	E G J L O	2+
4730	J V	4+
4742.3 11	G H I L S	0+
4750.31 20	D Q R a	8+	0.08 ps 10	1636.4 2	100	E2	3113.858	6+
4800.1	M	1+,1-,2+
4805.96 24	D G I L a	6+	0.49 ps +28-14	790.0 3 1189.7 1693.9 6	100 8 20 5 23 3	(M1+E2)	4015.51 3615.924 3113.858	5+ 5+ 6+
4815.69 9	C d	1+,2+		3381.5 1 4815.4 2	100 20 100 16		1434.091 0.0	2+ 0+
4841.3 11	G I J L M d	1+,1-,2+
4951 4	G L S	4+
5054.3 11	I V	4+
5095 5	G J L V g	4+
5098.6 4	I M	1	0.045 eV 10	3664.5 5 5098.3 5	79 22 100		1434.091 0.0	2+ 0+
5139 5	G J L	(6+)
5213.7 5	G L M S	1	0.013 eV 3	5213.4 5	100		0.0	0+
5285 5	G J L
5346 4	G L a	4+,6+
5396.9 3	D	7+	0.14 ps +12-9	590.9 3 1381.5 5	100 6 15.2 16	M1+E2 E2	4805.96 4015.51	6+ 5+
E(level) (keV)	XREF	J^π(level)	T_1/2(level)	E(γ) (keV)	I(γ)	M(γ)	Final Levels
5410 4	G H J L d	(2+)
5425 5	G J L	4+
5432 6	G
5446.4 5	H I J L V g	4+
5490.8	G L M	1+,1-,2+
5500	G N	3-
5526.0 5	M	1	0.016 eV 3	5525.7 5			0.0	0+
5541 5	G L	4+
5544.7 10	G L M d	(1+)	0.112 eV 7	5544.4	100		0.0	0+
5563.5 8	G I L	+
5584 6	G J L	+
5600 15	E H	0+
5633.4 11	D V	(8+)		1049.4 8	100		4584.0	(6+)
5664.4 11	G I J L d	(2)+
5725.3 12	G I J L S d	+
5737.5 11	G I	(4+)
5755 15	H J	+
5796.0	G J L M	1+,2+
5811 5	G	5,6+
5818 6	G
5824.7 4	D	8+	1.0 ps +6-4	427.9 3	100	M1(+E2)	5396.9	7+
5860.5 11	G I J g	+
5865 6	G
5873 5	G	3-
5891	J V	3-,4-
5919 5	G	5,6+
5953 5	G J S	2+
5960 5	G
5996 5	G J L a	3-
6026 6	G H J	+
E(level) (keV)	XREF	J^π(level)	T_1/2(level)	E(γ) (keV)	I(γ)	M(γ)	Final Levels
6035.3 12	G I
6055 5	G	2+
6065 7	G H
6106 6	E G J S	0+
6137.0 10	G M	2+		6136.6	100		0.0	0+
6153 8	G H	2+
6164 12	G V	3-
6175 7	G d	2+
6193 6	G J	+
6205.4 12	G I
6210 10	G
6220 6	G
6233 10	G J	+
6243 5	G	3-
6252 6	G
6272 6	G
6293 7	G
6324 10	G S
6349 5	G J	+
6356.6 12	D	(9+)		725.5 12 ?	100		5633.4	(8+)
6365.3 11	D	(10+)		1615.0 10	100		4750.31	8+
6375.4 12	G I
6381.0 10	D	(6+)		2765.0	100		3615.924	5+
6389.9 5	G J L M	1+	0.069 eV 7	6389.5 5	100		0.0	0+
6392 10	G	3-
6426 5	G
6437 10	G
6453.4 4	D	9+	0.14 ps +9-8	628.9 5 1056.0 10 1702.9 5	35 18 26 2 100 5	M1+E2 M1+E2	5824.7 5396.9 4750.31	8+ 7+ 8+
E(level) (keV)	XREF	J^π(level)	T_1/2(level)	E(γ) (keV)	I(γ)	M(γ)	Final Levels
6462.4 5	G M	1	0.074 eV 7	6462.0 5	100		0.0	0+
6482 5	G	5,6+
6493 10	G J S d	2+
6495.5 5	M	1	0.131 eV 9	6495.1 5	100		0.0	0+
6541 10	G V	3-
6568 10	G
6580 5	G J N
6637 5	G J
6678 5	E G J	+
6700 20	d	-
6704 5	G J	5,6+
6752.0 5	J M S V	1+	0.089 eV 10	6751.5 5	100		0.0	0+
6795.4 12	G I O	3-
6810 30	G J a d	2+
6871 5	G	5-
6894	J	+
6928	J	+
6956 5	G	5,6+
6993 5	G J S	3-
7014.5 4	M	1	0.210 eV 30	5580.5 5 7013.6 5	24 6 100		1434.091 0.0	2+ 0+
7030 10	J N	1+
7090.8 5	G J M	1+	0.062 eV 11	7090.3 5	100		0.0	0+
7100	N V	3-
7140 7	G N	+
7166.2 5	J M N	+	0.054 eV 11	7165.7 5	100		0.0	0+
7217 10	G J	2+
7223	J	+
7237.9 6	D	10+	0.16 ps +15-8	784.5 5 883.7 10 ? 1413.6 10 ? 1606.0 20 ?	100 12 28 3 8 4 15 4	M1+E2 [E2] [E2]	6453.4 6356.6 5824.7 5633.4	9+ (9+) 8+ (8+)
E(level) (keV)	XREF	J^π(level)	T_1/2(level)	E(γ) (keV)	I(γ)	M(γ)	Final Levels
7260 10	J N	+
7278 10	G J S	4+
7310	J	+
7322	J	+
7342 7	G J N	1+
7368.8 5	J M	1+	0.229 eV 18	7368.2 5	100		0.0	0+
7376 10	G	5-
7395 10	J a	5+
7401.6 15	D	(12+)		1036.3	100	(E2)	6365.3	(10+)
7403.2 5	M	1	0.107 eV 15	7402.6 5	100		0.0	0+
7409 10	G O	3-
7450 50	E	0+,2+
7458 10	G	5,6+
7482 10	G	3-
7487	J	+
7524.1 5	G J M N	1+	0.400 eV 28	7523.5 5	100		0.0	0+
7560 20	G J N S	+
7585 10	G J	3-
7590	J	+
7679 10	G J	5,6+
7700 10	N	1+
7731.9 5	J M	1-	0.960 eV 24	7731.3 5	100		0.0	0+
7738 10	G	3-
7750	J a	+
7760	J	+
7810	g	-
7820 10	G J	1+
7823 10	G	3-
7854 7	G J N S	4+
7865.1 5	M	1+	0.435 eV 27	7864.5 5	100		0.0	0+
E(level) (keV)	XREF	J^π(level)	T_1/2(level)	E(γ) (keV)	I(γ)	M(γ)	Final Levels
7889.0 5	M	1	0.480 eV 45	7888.4 5	100		0.0	0+
7893 10	G J	4+
7897.4 5	M	1-	3.38 eV 17	7896.8 5	100		0.0	0+
7900	N V	3-
7920	J	+
7930 50	E J	+
7967 10	G	3-
8010	G J g	+
8015.4 4	M	1	0.260 eV 59	6580.9 5 8014.6 5	54 16 100		1434.091 0.0	2+ 0+
8022 10	G J	2+
8083	J M N	+
8087 9	G	3-
8091.3 5	M	1	0.734 eV 44	8090.6 5	100		0.0	0+
8100 20	N	8-
8121 10	G J	+
8179.3 4	G J M O	1+	0.90 eV 18	6744.8 5 8178.5 5	326 50 100		1434.091 0.0	2+ 0+
8190	g	+
8213 10	G	0+
8216.4 9	D J	11+	0.24 ps +17-9	978.5 5 1763.3 10	97 9 100 11	M1+E2 E2	7237.9 6453.4	10+ 9+
8250	J	+
8281 10	G	3-
8283	J	+
8337 10	G J	(4+)
8350	J	+
8374 10	G	3-
8390 10	J N	+
8412 10	G J O	+
E(level) (keV)	XREF	J^π(level)	T_1/2(level)	E(γ) (keV)	I(γ)	M(γ)	Final Levels
8420	N g	6-
8451	J	+
8457 10	G	3-
8505 10	G	3-
8569 10	G J S	0+
8600 10	N	3-
8617 10	G J
8679 10	G	3-
8710 50	E J N	+
8728 10	G	3-
8765.9 5	M	1	0.441 eV 37	8765.1 5	100		0.0	0+
8778 10	G	3-
8790 10	N	2
8827 10	G
8860 10	N	1+,(2-)
8890 20	N S	1+,(2-)
8940 20	N	(8-,6-)
8958.4 5	M	1	0.233 eV 36	8957.6 5	100		0.0	0+
9004 9	G N	1+
9050 10	N	1+,(2-)
9080 20	N	(8-)
9140.3 5	G M N	1+	2.65 eV 15	9139.4 5	100		0.0	0+
9200	a	5-
9211.9 5	G M N	1+	2.11 eV 14	9211.0 5	100		0.0	0+
9245 10	G	1+
9327.0 5	G N	1+	0.746 eV 80	9326.1 5	100		0.0	0+
9370 20	N	1+,2-
9429.0 5	G M N	1+	0.95 eV 11	9428.1 5	100		0.0	0+
9438.5 9	D N	12(+)		1222.4 8 2200.0 10	100 5 16.8 11		8216.4 7237.9	11+ 10+
E(level) (keV)	XREF	J^π(level)	T_1/2(level)	E(γ) (keV)	I(γ)	M(γ)	Final Levels
9450 20	N g	8-
9470 20	N	1+,2+
9580 10	E N	0+
9612 9	G N	1+
9660 20	N g	8-
9724 9	G M N	1+
9787 3	M	1-
9830 10	N	1+
9878 9	E G N	1+
9910 20	N	8-
9981 3	M	(-)
10008 9	G N	1+
10110 20	N g	(8-)
10130 20	N O	1,2-
10161.3 12	D	(13+)		721.3 10 1943.6 7	4.7 6 100.0 17	E2	9438.5 8216.4	12(+) 11+
10180 10	N	2-
10240 20	N	1
10270 20	N	1,(2-)
10300 20	N
10330 20	N g	6-
10340 20	N	1
10380 14	G N	1+
10433 4	M N	1+
10464 9	G N	1+
10500 20	N	1
10510 20	N	(-)
10604 12	G N	1+
10710 10	N	1
10760 10	N a	6+,8+
E(level) (keV)	XREF	J^π(level)	T_1/2(level)	E(γ) (keV)	I(γ)	M(γ)	Final Levels
10790 9	G N	1+
10800 20	N	(-)
10820 10	N	1+,(2-)
10927 3	M N	1+,2-
10970 20	G	0+
11000 20	N	8-
11070 10	N	1
11140 10	G N	0+
11160 20	N	(1+),2
11170 20	N g	8-
11229 3	I
11256.5 7	E I			8291 8488	100 85		2964.786 2767.767	2+ 4+
11264.9 4	E I a	+		7648 7792 7850 8150 8299 8496 8895 9830	<9 <5 39 7 25 9 <5 11 7 100 16 34 5	(M1+E2) (M1+E2) (M1+E2)	3615.924 3472.25 3415.32 3113.858 2964.786 2767.767 2369.630 1434.091	5+ 3+ 4+ 6+ 2+ 4+ 4+ 2+
11270 20	N O	8-
11274.6 6	E I	+		4479 4899 5069 5239 5549 7258 7326 7859 8904	72 12 24 8 36 12 20 8 100 12 60 12 24 8 8 4 56 8	(M1+E2) (M1+E2)	6795.4 6375.4 6205.4 6035.3 5725.3 4015.51 3947.5 3415.32 2369.630	3- + 5+ 2+ 4+ 4+
E(level) (keV)	XREF	J^π(level)	T_1/2(level)	E(γ) (keV)	I(γ)	M(γ)	Final Levels
11291.1 10	I d			9856	100		1434.091	2+
11330 20	N	(1+),2-
11370 20	N g	8-
11400.0 4	I	4+		5836 5953 7360 7384 7783 7985 8285 9030	61 5 29 5 26 3 21 3 5 3 100 5	(M1+E2)	5563.5 5446.4 4039.1 4015.51 3615.924 3415.32 3113.858 2369.630	+ 4+ 4+ 5+ 5+ 4+ 6+ 4+
11402 9	G N	1+
11510 10	N	2-
11550 20	N	8-
11570 20	N	(1+),2
11610 10	N	2
11656 3	I N	1+,2-
11660 20	N g	8-
11691.8 4	I N			5302 6027 6245 6637 6854 6883 6949 7652 7676 8219 8277 8529 8726 8923 9322 10257	33 3 23 3 53 3 13 7 37 3 30 7 7 3 13 3 27 7 10 3 27 3 100 7		6389.9 5664.4 5446.4 5054.3 4841.3 4805.96 4742.3 4039.1 4015.51 3472.25 3415.32 3161.74 2964.786 2767.767 2369.630 1434.091	1+ (2)+ 4+ 4+ 1+,1-,2+ 6+ 0+ 4+ 5+ 3+ 4+ 2+ 2+ 4+ 4+ 2+
E(level) (keV)	XREF	J^π(level)	T_1/2(level)	E(γ) (keV)	I(γ)	M(γ)	Final Levels
11713 3	I
11725 3	I
11745 3	I
11765 3	M
11770 20	N g	8-
11780 20	N	(1+),2-
11837 3	M
11880 20	N	8-
11960 20	N	8-
12034.8 4	I N g	-		6471 6588 7404 8562 8620 9069 9266 9665 10600	22 4 22 4 48 4 17 9 100 9 17 9 74 4 78 4 48 4		5563.5 5446.4 4627.32 3472.25 3415.32 2964.786 2767.767 2369.630 1434.091	+ 4+ 4+ 3+ 4+ 2+ 4+ 4+ 2+
12041.8 4	I	4+		6595 7233 8569 8627 8879 9076 9273 9672 10607	42 4 19 4 46 4 19 4 62 4 7 4 31 4 100 4 54 4		5446.4 4805.96 3472.25 3415.32 3161.74 2964.786 2767.767 2369.630 1434.091	4+ 6+ 3+ 4+ 2+ 2+ 4+ 4+ 2+
12050	g	-
12099.9 4	I	4+		6239 6362 6653 7002 7469 8060 8084 8152 8483 8627 8685 9331 9730	39 9 39 9 30 9 13 4 30 4 30 4 13 2 22 4 26 4 17 3 52 9 35 4 100 9		5860.5 5737.5 5446.4 5098.6 4627.32 4039.1 4015.51 3947.5 3615.924 3472.25 3415.32 2767.767 2369.630	+ (4+) 4+ 1 4+ 4+ 5+ 2+ 5+ 3+ 4+ 4+ 4+
E(level) (keV)	XREF	J^π(level)	T_1/2(level)	E(γ) (keV)	I(γ)	M(γ)	Final Levels
12130 20	N	(8-,6-)
12240 20	N	6-
12260	a	6+,8+
12500	g	-
12560 20	G g	1+
12665 6	I	3+
12730 20	N g	-
12734 6	I
12794.8 7	I	4+		9178 10424	81 100		3615.924 2369.630	5+ 4+
12900 20	G	1+
12977 6	I g	-
12994 6	I	+
13038 6	I	+
13220 20	N	8-
13319	I
13393	I N	6-
13419	E I	0+
13570 20	N	6-
13580 20	d	(1,2)-
13630 10	E	0+
13710 20	N	6-
13950 50	E
14030 20	N	6-
14110 20	E	2+
14340 20	N	6-
14430 20	N g	8-
15270 20	N g	6-
15482 7	N g	8-
16400 20	N	6-
E(level) (keV)	XREF	J^π(level)	T_1/2(level)	E(γ) (keV)	I(γ)	M(γ)	Final Levels
16690 20	N	(8-)

E(level): Levels connected by gammas are from least squares fit, others from ⁵²Cr(p,p’) for E(level)<8830 keV and from ⁵²Cr(e,e’) for E(level)>8830 keV, except as noted.

T_1/2(level): From (HI,xnγ), DSAM, except as noted.

E(level) (keV)	J^π(level)	T_1/2(level)	E(γ)	I(γ)	M(γ)	Final Levels
Band 1 - GS Band.
0.0	0+	STABLE
1434.091 14	2+	0.783 ps 21	1434.068 14	100	E2	0.0	0+
2369.630 18	4+	6.7 ps +35-17	935.538 11	100	E2	1434.091	2+
3113.858 21	6+	41.4 ps 14	346.02 4 744.233 13	1.09 1 100.0 9	E2 E2	2767.767 2369.630	4+ 4+
4750.31 20	8+	0.08 ps 10	1636.4 2	100	E2	3113.858	6+
6365.3 11	(10+)		1615.0 10	100		4750.31	8+
E(level) (keV)	J^π(level)	T_1/2(level)	E(γ)	I(γ)	M(γ)	Final Levels
Band 2 - Band based on 5⁺
3415.32 3	4+	0.26 ps 7
4015.51 3	5+	0.61 ps +27-19	399.57 5 600.16 5 901.89 18 1247.88 9 1645.82 4	46.9 18 100 3 11.3 11 97 10 12.1 8	M1 M1	3615.924 3415.32 3113.858 2767.767 2369.630	5+ 4+ 6+ 4+ 4+
4805.96 24	6+	0.49 ps +28-14	790.0 3 1189.7 1693.9 6	100 8 20 5 23 3	(M1+E2)	4015.51 3615.924 3113.858	5+ 5+ 6+
5396.9 3	7+	0.14 ps +12-9	590.9 3 1381.5 5	100 6 15.2 16	M1+E2 E2	4805.96 4015.51	6+ 5+
5824.7 4	8+	1.0 ps +6-4	427.9 3	100	M1(+E2)	5396.9	7+
6453.4 4	9+	0.14 ps +9-8	628.9 5 1056.0 10 1702.9 5	35 18 26 2 100 5	M1+E2 M1+E2	5824.7 5396.9 4750.31	8+ 7+ 8+
7237.9 6	10+	0.16 ps +15-8	784.5 5 883.7 10 ? 1413.6 10 ? 1606.0 20 ?	100 12 28 3 8 4 15 4	M1+E2 [E2] [E2]	6453.4 6356.6 5824.7 5633.4	9+ (9+) 8+ (8+)
8216.4 9	11+	0.24 ps +17-9	978.5 5 1763.3 10	97 9 100 11	M1+E2 E2	7237.9 6453.4	10+ 9+
9140.3 5	1+	2.65 eV 15	9139.4 5	100		0.0	0+
9438.5 9	12(+)		1222.4 8 2200.0 10	100 5 16.8 11		8216.4 7237.9	11+ 10+
10161.3 12	(13+)		721.3 10 1943.6 7	4.7 6 100.0 17	E2	9438.5 8216.4	12(+) 11+

E(level) (keV)	J^π(level)	T_1/2(level)	E(γ) (keV)	Multipolarity	Mixing Ratio	Additional Data
1434.091	2+	0.783 ps 21	1434.068 14	E2		B(E2)(W.u.)=10.3 3
2369.630	4+	6.7 ps +35-17	935.538 11	E2		B(E2)(W.u.)=1.0E-11 +3-6
2767.767	4+	1.9 ps 5	398.08 9	E2		B(E2)(W.u.)=45 13
2767.767	4+	1.9 ps 5	1333.649 17	E2		B(E2)(W.u.)=6.0 16
2964.786	2+	0.42 ps 8	1530.67 1	M1+E2	-6.25 15	B(E2)(W.u.)=13 3, B(M1)(W.u.)=0.00036 8
2964.786	2+	0.42 ps 8	2965 1	E2		B(E2)(W.u.)=0.005 4
3113.858	6+	41.4 ps 14	346.02 4	E2		B(E2)(W.u.)=2.58 10
3113.858	6+	41.4 ps 14	744.233 13	E2		B(E2)(W.u.)=5.14 19
3161.74	2+	0.035 ps 7	1727.53 7	M1+E2	-0.18 7	B(E2)(W.u.)=2.6 21, B(M1)(W.u.)=0.107 23
3161.74	2+	0.035 ps 7	3161.8 1	E2		B(E2)(W.u.)=0.40 10
3415.32	4+	0.26 ps 7	647.47 6	M1+E2	0.22 8	B(E2)(W.u.)=6.×10¹ 5, B(M1)(W.u.)=0.24 7
3415.32	4+	0.26 ps 7	1981.12 4	[E2]		B(E2)(W.u.)=0.42 13
3472.25	3+	7.2 ps 8	704.6 2	M1+E2	-0.14 6	B(E2)(W.u.)=0.5 5, B(M1)(W.u.)=0.0059 7
3615.924	5+	2.6 ps 12	848.18 5	M1		B(M1)(W.u.)=0.006 3
3771.72	2+	9 fs 2	2337.44 19	M1+E2	-0.20 8	B(E2)(W.u.)=2.4 20, B(M1)(W.u.)=0.15 5
3771.72	2+	9 fs 2	3771.7 2	[E2]		B(E2)(W.u.)=1.5 5
4015.51	5+	0.61 ps +27-19	600.16 5	M1		B(M1)(W.u.)=0.062 +20-28
4015.51	5+	0.61 ps +27-19	1247.88 9	M1		B(M1)(W.u.)=0.0067 +23-31
4750.31	8+	0.08 ps 10	1636.4 2	E2		B(E2)(W.u.)=5.×10¹ +7-5
4805.96	6+	0.49 ps +28-14	790.0 3	(M1+E2)	-0.16 5	B(E2)(W.u.)=(6 +4-5), B(M1)(W.u.)=(0.062 +19-37)
5396.9	7+	0.14 ps +12-9	590.9 3	M1+E2	-0.27 6	B(E2)(W.u.)=2.9×10² +22-28, B(M1)(W.u.)=0.6 +4-6
5396.9	7+	0.14 ps +12-9	1381.5 5	E2		B(E2)(W.u.)=9 +6-8
5824.7	8+	1.0 ps +6-4	427.9 3	M1(+E2)	-0.03 4	B(E2)(W.u.)=(3 +9-3), B(M1)(W.u.)=(0.28 +12-17), α(K)=0.00166, α(L)=0.00016
6453.4	9+	0.14 ps +9-8	628.9 5	M1+E2	+0.22 +15-8	B(E2)(W.u.)=4.×10¹ +6-4, B(M1)(W.u.)=0.13 11
6453.4	9+	0.14 ps +9-8	1702.9 5	M1+E2	-0.04 +7-3	B(E2)(W.u.)=0.02 +9-2, B(M1)(W.u.)=0.020 +12-13
E(level) (keV)	J^π(level)	T_1/2(level)	E(γ) (keV)	Multipolarity	Mixing Ratio	Additional Data
7237.9	10+	0.16 ps +15-8	784.5 5	M1+E2	-0.06 +3-5	B(E2)(W.u.)=2 +3-2, B(M1)(W.u.)=0.19 +10-18
	10+	0.16 ps +15-8	1413.6 10	[E2]		B(E2)(W.u.)=2.9 +21-29
	10+	0.16 ps +15-8	1606.0 20	[E2]		B(E2)(W.u.)=2.9 +17-28
8216.4	11+	0.24 ps +17-9	978.5 5	M1+E2	+0.10 +5-8	B(E2)(W.u.)=1.1 +12-11, B(M1)(W.u.)=0.048 +19-35
8216.4	11+	0.24 ps +17-9	1763.3 10	E2		B(E2)(W.u.)=6.1 +25-44
11264.9	+		7850	(M1+E2)	+0.06 9
	+		8895	(M1+E2)	+0.9 +10-5
	+		9830	(M1+E2)	-0.30 6
11274.6	+		7859	(M1+E2)	+0.47 10
11274.6	+		8904	(M1+E2)	+0.19 10
11400.0	4+		9030	(M1+E2)	0.5 2

E(level)	J^π(level)	T_1/2(level)	Comments
0.0	0+	STABLE	rms charge radius=3.6424 fm 21 (2004An14). others: rms charge radius=3.61 fm 8, muonic x-ray (1962Jo05), rms charge radius=3.674 fm 15 (1976Li19) (e,e’). E(level): rms charge radius=3.6424 fm 21 (2004An14). others: rms charge radius=3.61 fm 8, muonic x-ray (1962Jo05), rms charge radius=3.674 fm 15 (1976Li19) (e,e’). GS Band.
1434.091	2+	0.783 ps 21	μ=+2.41 13 (2000Er01), Q=-0.082 16 (1989Ra17) E(level): GS Band.
2369.630	4+	6.7 ps +35-17	XREF: K(2368)L(2371)t(2372)d(2380). E(level): GS Band.
2646.9	0+		XREF: H(2660)L(2650)n(2650)O(2650)S(2640)V(2650)c(2640)h(2650).
2767.767	4+	1.9 ps 5	XREF: n(2770)O(2770)V(2770)a(2770)c(2770)d(2780)g(2770).
2964.786	2+	0.42 ps 8	XREF: H(2974)n(2970)O(2960)V(2960).
3113.858	6+	41.4 ps 14	XREF: n(3110)V(3110)a(3110)g(3110)h(3110). E(level): GS Band.
3161.74	2+	0.035 ps 7	XREF: H(3175)e(3168). E(level): From weighted average of values in ⁵²Mn ε decay (21.1 min) and ⁵²V β^- decay. T_1/2(level): From (n,n’γ).
3415.32	4+	0.26 ps 7	XREF: J(3420)O(3420)V(3450)b(3432)d(3418). E(level): Band based on 5⁺.
3472.25	3+	7.2 ps 8	XREF: S(3440)b(3494)c(3460)g(3440).
3615.924	5+	2.6 ps 12	XREF: J(3620)L(3619).
3739.6	1+,1-,2+		E(level): From ⁵²Mn ε decay (21.1 min). From ⁵²Cr(γ,γ’),(pol γ,γ’).
3771.72	2+	9 fs 2	XREF: E(3700)H(3781)S(3780)V(3780)b(3767)c(3800)g(3800).
3947.5	2+	0.014 ps 7	XREF: γ(3949)b(3926). E(level): From weighted average of values in ⁵²Mn ε decay (21.1 min) and ⁵²V β^- decay. T_1/2(level): From (n,n’γ).
3951.2	2+		XREF: γ(3949)H(3957).
4015.51	5+	0.61 ps +27-19	XREF: J(4020)d(4017). E(level): Band based on 5⁺.
4039.1	4+	26 fs 4	XREF: J(4033)V(4010)b(4030). E(level): From weighted average of values in ⁵²Mn ε decay (21.1 min) and ⁵²V β^- decay. T_1/2(level): From (n,n’γ).
4.10E3	3-		XREF: p(4200)c(4090). E(level): From ⁵¹V(α,t).
4563.0	3-	40 fs 6	B(E3)=0.0066 3 B(E3) from weighted average of values 0.0065 4 in (e,e’) and 0.0068 5 in (π⁺,π⁺),(π⁺,π⁺’). E(level): B(E3) from weighted average of values 0.0065 4 in (e,e’) and 0.0068 5 in (π⁺,π⁺),(π⁺,π⁺’). From weighted average of values in ⁵²Mn ε decay (21.1 min) and ⁵²V β^- decay. T_1/2(level): From (n,n’γ).
4611	(3,4)+		XREF: d(4605).
4627.32	4+		XREF: γ(4630)L(4630)O(4630)g(4680).
4702	2+		XREF: E(4710)L(4706)O(4710).
4730	4+		E(level): From ⁵²Cr(α,α’).
4742.3	0+		XREF: γ(4738)H(4745).
4750.31	8+	0.08 ps 10	XREF: a(4770). E(level): From weighted average of values in ⁵²Mn ε decay (21.1 min) and ⁵²V β^- decay. GS Band. T_1/2(level): From (n,n’γ).
E(level)	J^π(level)	T_1/2(level)	Comments
4800.1	1+,1-,2+		E(level): From ⁵²Mn ε decay (21.1 min). From ⁵²Cr(γ,γ’),(pol γ,γ’).
4805.96	6+	0.49 ps +28-14	XREF: I(4808)L(4808)a(4770). E(level): Band based on 5⁺.
4841.3	1+,1-,2+		XREF: γ(4832). E(level): From ⁵²Mn ε decay (21.1 min). From ⁵²Cr(γ,γ’),(pol γ,γ’).
4951	4+		XREF: L(4950)S(4980).
5054.3	4+		XREF: V(5070).
5095	4+		XREF: V(5070)g(5120).
5098.6	1	0.045 eV 10	E(level): From ⁵²Mn ε decay (21.1 min). From ⁵²Cr(γ,γ’),(pol γ,γ’). T_1/2(level): Partial decay width into ground state in ⁵²Cr(γ,γ’),(pol γ,γ’).
5213.7	1	0.013 eV 3	E(level): From ⁵²Mn ε decay (21.1 min). From ⁵²Cr(γ,γ’),(pol γ,γ’). T_1/2(level): Partial decay width into ground state in ⁵²Cr(γ,γ’),(pol γ,γ’).
5285			XREF: L(5281).
5346	4+,6+		XREF: a(5320).
5396.9	7+	0.14 ps +12-9	E(level): Band based on 5⁺.
5410	(2+)		XREF: H(5423)d(5400).
5425	4+		XREF: L(5422).
5446.4	4+		XREF: H(5443)J(5450)L(5450)V(5450)g(5450).
5490.8	1+,1-,2+		E(level): From ⁵²Mn ε decay (21.1 min). From ⁵²Cr(γ,γ’),(pol γ,γ’).
5500	3-		E(level): From ⁵²V β^- decay. From ⁵²Cr(e,e’).
5526.0	1	0.016 eV 3	E(level): From ⁵²Mn ε decay (21.1 min). From ⁵²Cr(γ,γ’),(pol γ,γ’). T_1/2(level): Partial decay width into ground state in ⁵²Cr(γ,γ’),(pol γ,γ’).
5541	4+		XREF: L(5538).
5544.7	(1+)	0.112 eV 7	XREF: γ(5546)d(5560). E(level): From ⁵²Mn ε decay (21.1 min). From ⁵²Cr(γ,γ’),(pol γ,γ’). T_1/2(level): Partial decay width into ground state in ⁵²Cr(γ,γ’),(pol γ,γ’).
5563.5	+		XREF: γ(5569)L(5571).
5584	+		XREF: J(5594).
5600	0+		XREF: E(5650). E(level): From ⁵⁰Cr(t,p).
5633.4	(8+)		XREF: V(5640).
5664.4	(2)+		XREF: γ(5661)J(5660)d(5670).
5725.3	+		XREF: γ(5727)J(5720)S(5700)d(5710).
E(level)	J^π(level)	T_1/2(level)	Comments
5755	+		E(level): From ⁵⁰Cr(t,p).
5796.0	1+,2+		XREF: J(5790). E(level): From ⁵²Mn ε decay (21.1 min). From ⁵²Cr(γ,γ’),(pol γ,γ’).
5824.7	8+	1.0 ps +6-4	E(level): Band based on 5⁺.
5860.5	+		XREF: γ(5853)J(5828)g(5830).
5891	3-,4-		XREF: V(5910). E(level): From ⁵¹V(³He,d).
5953	2+		XREF: J(5945).
5996	3-		XREF: J(5992)a(5990).
6065			XREF: H(6069).
6106	0+		XREF: E(6100)J(6089)S(6130).
6137.0	2+		E(level): From ⁵²Mn ε decay (21.1 min). From ⁵²Cr(γ,γ’),(pol γ,γ’).
6164	3-		XREF: V(6160).
6175	2+		XREF: d(6180).
6324			XREF: S(6330).
6349	+		XREF: J(6364).
6365.3	(10+)		E(level): GS Band.
6375.4			XREF: γ(6372).
6389.9	1+	0.069 eV 7	XREF: J(5790). E(level): From ⁵²Mn ε decay (21.1 min). From ⁵²Cr(γ,γ’),(pol γ,γ’). T_1/2(level): Partial decay width into ground state in ⁵²Cr(γ,γ’),(pol γ,γ’).
6453.4	9+	0.14 ps +9-8	E(level): Band based on 5⁺.
6462.4	1	0.074 eV 7	E(level): From ⁵²Mn ε decay (21.1 min). From ⁵²Cr(γ,γ’),(pol γ,γ’). T_1/2(level): Partial decay width into ground state in ⁵²Cr(γ,γ’),(pol γ,γ’).
6493	2+		XREF: J(6500)d(6490). E(level): From ⁵²Cr(p,p’).
6495.5	1	0.131 eV 9	E(level): From ⁵²Mn ε decay (21.1 min). From ⁵²Cr(γ,γ’),(pol γ,γ’). T_1/2(level): Partial decay width into ground state in ⁵²Cr(γ,γ’),(pol γ,γ’).
6580			XREF: J(6610)n(6600).
6637			XREF: J(6625).
6678	+		XREF: E(6670).
6704	5,6+		XREF: J(6720).
E(level)	J^π(level)	T_1/2(level)	Comments
6752.0	1+	0.089 eV 10	XREF: J(6760)S(6740)V(6760). E(level): From ⁵²Mn ε decay (21.1 min). From ⁵²Cr(γ,γ’),(pol γ,γ’). T_1/2(level): Partial decay width into ground state in ⁵²Cr(γ,γ’),(pol γ,γ’).
6795.4	3-		XREF: γ(6786).
6810	2+		XREF: J(6814)a(6800)d(6790).
6894	+		E(level): From ⁵¹V(³He,d).
6928	+		E(level): From ⁵¹V(³He,d).
7014.5	1	0.210 eV 30	E(level): From ⁵²Mn ε decay (21.1 min). From ⁵²Cr(γ,γ’),(pol γ,γ’). T_1/2(level): Partial decay width into ground state in ⁵²Cr(γ,γ’),(pol γ,γ’).
7030	1+		XREF: J(6993). E(level): From ⁵²V β^- decay. From ⁵²Cr(e,e’).
7090.8	1+	0.062 eV 11	E(level): From ⁵²Mn ε decay (21.1 min). From ⁵²Cr(γ,γ’),(pol γ,γ’). T_1/2(level): Partial decay width into ground state in ⁵²Cr(γ,γ’),(pol γ,γ’).
7100	3-		E(level): From ⁵²Cr(α,α’).
7140	+		E(level): From weighted average of values in ⁵²Cr(e,e’) and ⁵²Cr(p,p’).
7166.2	+	0.054 eV 11	XREF: n(7170). E(level): From ⁵²Mn ε decay (21.1 min). From ⁵²Cr(γ,γ’),(pol γ,γ’). T_1/2(level): Partial decay width into ground state in ⁵²Cr(γ,γ’),(pol γ,γ’).
7217	2+		XREF: J(7210).
7223	+		E(level): From ⁵¹V(³He,d).
7237.9	10+	0.16 ps +15-8	E(level): Band based on 5⁺.
7260	+		E(level): From ⁵²V β^- decay. From ⁵²Cr(e,e’).
7278	4+		XREF: J(7273)S(7290).
7310	+		E(level): From ⁵¹V(³He,d).
7322	+		E(level): From ⁵¹V(³He,d).
7342	1+		XREF: J(7350)n(7340). E(level): From weighted average of values in ⁵²Cr(e,e’) and ⁵²Cr(p,p’).
7368.8	1+	0.229 eV 18	E(level): From ⁵²Mn ε decay (21.1 min). From ⁵²Cr(γ,γ’),(pol γ,γ’). T_1/2(level): Partial decay width into ground state in ⁵²Cr(γ,γ’),(pol γ,γ’).
7395	5+		XREF: J(7400)a(7390).
7403.2	1	0.107 eV 15	B(M1)=0.069 10, B(E1)=0.76×10^-5 11. E(level): From ⁵²Mn ε decay (21.1 min). From ⁵²Cr(γ,γ’),(pol γ,γ’). T_1/2(level): Partial decay width into ground state in ⁵²Cr(γ,γ’),(pol γ,γ’).
7450	0+,2+		E(level): Close doublet; not resolved in (³He,n) tof spectra, but separated in angular distribution procedure. From ⁵⁰Ti(³He,n).
7524.1	1+	0.400 eV 28	XREF: n(7520). E(level): From (HI,xnγ). From ⁵²Mn ε decay (21.1 min). From ⁵²Cr(γ,γ’),(pol γ,γ’). J^π(level): Dipole transition in ⁵²Cr(γ,γ’),(pol γ,γ’). T_1/2(level): Partial decay width into ground state in ⁵²Cr(γ,γ’),(pol γ,γ’).
7560	+		XREF: S(7570). E(level): From ⁵²V β^- decay. From ⁵²Cr(e,e’).
E(level)	J^π(level)	T_1/2(level)	Comments
7679	5,6+		XREF: J(7686).
7700	1+		E(level): From ⁵²V β^- decay. From ⁵²Cr(e,e’).
7731.9	1-	0.960 eV 24	Γ²_γ0/Γ=1.75 eV 32 (1979Ku14). E(level): Γ²_γ0/Γ=1.75 eV 32 (1979Ku14). From (HI,xnγ). From ⁵²Mn ε decay (21.1 min). From ⁵²Cr(γ,γ’),(pol γ,γ’). J^π(level): Dipole transition in ⁵²Cr(γ,γ’),(pol γ,γ’). T_1/2(level): Partial decay width into ground state in ⁵²Cr(γ,γ’),(pol γ,γ’).
7750	+		XREF: J(7729).
7760	+		E(level): From ⁵¹V(³He,d).
7810	-		E(level): From ⁵¹V(α,t).
7820	1+		XREF: J(7815).
7823	3-		E(level): From ⁵¹V(³He,d).
7854	4+		XREF: γ(7848)n(7860)S(7870). E(level): From weighted average of values in ⁵²Cr(e,e’) and ⁵²Cr(p,p’).
7865.1	1+	0.435 eV 27	E(level): From ⁵²Mn ε decay (21.1 min). From ⁵²Cr(γ,γ’),(pol γ,γ’). T_1/2(level): Partial decay width into ground state in ⁵²Cr(γ,γ’),(pol γ,γ’).
7889.0	1	0.480 eV 45	E(level): From ⁵²Mn ε decay (21.1 min). From ⁵²Cr(γ,γ’),(pol γ,γ’). T_1/2(level): Partial decay width into ground state in ⁵²Cr(γ,γ’),(pol γ,γ’).
7893	4+		XREF: J(7905).
7897.4	1-	3.38 eV 17	E(level): From (HI,xnγ). From ⁵²Mn ε decay (21.1 min). From ⁵²Cr(γ,γ’),(pol γ,γ’). J^π(level): Dipole transition in ⁵²Cr(γ,γ’),(pol γ,γ’). T_1/2(level): Partial decay width into ground state in ⁵²Cr(γ,γ’),(pol γ,γ’).
7900	3-		E(level): From ⁵²V β^- decay. From ⁵²Cr(e,e’).
7920	+		E(level): From ⁵¹V(³He,d).
7930	+		XREF: J(7967). E(level): From ⁵⁰Ti(³He,n).
8010	+		XREF: J(7967).
8015.4	1	0.260 eV 59	B(M1)=0.131 30, B(E1)=1.45×10^-5 33. E(level): From ⁵²Mn ε decay (21.1 min). From ⁵²Cr(γ,γ’),(pol γ,γ’). T_1/2(level): Partial decay width into ground state in ⁵²Cr(γ,γ’),(pol γ,γ’).
8083	+		XREF: n(8080).
8087	3-		E(level): From ⁵¹V(³He,d).
8091.3	1	0.734 eV 44	E(level): From ⁵²Mn ε decay (21.1 min). From ⁵²Cr(γ,γ’),(pol γ,γ’). T_1/2(level): Partial decay width into ground state in ⁵²Cr(γ,γ’),(pol γ,γ’).
8121	+		XREF: J(8130).
8179.3	1+	0.90 eV 18	XREF: J(8183). E(level): From ⁵²Mn ε decay (21.1 min). From ⁵²Cr(γ,γ’),(pol γ,γ’). T_1/2(level): Partial decay width into ground state in ⁵²Cr(γ,γ’),(pol γ,γ’).
8190	+		E(level): From ⁵¹V(α,t).
8216.4	11+	0.24 ps +17-9	XREF: J(8234). E(level): Band based on 5⁺.
E(level)	J^π(level)	T_1/2(level)	Comments
8250	+		E(level): From ⁵¹V(³He,d).
8281	3-		E(level): From ⁵²Cr(p,p’).
8337	(4+)		XREF: J(8330). E(level): From ⁵²Cr(p,p’).
8350	+		E(level): From ⁵¹V(³He,d).
8374	3-		E(level): From ⁵²Cr(p,p’).
8390	+		XREF: J(8371). E(level): From ⁵²V β^- decay. From ⁵²Cr(e,e’).
8412	+		XREF: J(8400). E(level): From ⁵²Cr(p,p’).
8420	6-		XREF: n(8450). E(level): From ⁵¹V(α,t).
8451	+		E(level): From ⁵¹V(³He,d).
8569	0+		XREF: J(8579)S(8580).
8600	3-		B(E3)=0.0022 3 (1964Be32) E(level): From ⁵²V β^- decay. From ⁵²Cr(e,e’).
8617			XREF: J(8614).
8679	3-		E(level): From ⁵²Cr(p,p’).
8710	+		XREF: J(8700)n(8690). E(level): Close doublet; not resolved in (³He,n) tof spectra, but separated in angular distribution procedure. From ⁵⁰Ti(³He,n).
8765.9	1	0.441 eV 37	E(level): From ⁵²Mn ε decay (21.1 min). From ⁵²Cr(γ,γ’),(pol γ,γ’). T_1/2(level): Partial decay width into ground state in ⁵²Cr(γ,γ’),(pol γ,γ’).
8958.4	1	0.233 eV 36	E(level): From ⁵²Mn ε decay (21.1 min). From ⁵²Cr(γ,γ’),(pol γ,γ’). T_1/2(level): Partial decay width into ground state in ⁵²Cr(γ,γ’),(pol γ,γ’).
9004	1+		XREF: γ(9020). E(level): From weighted average of values in ⁵²Cr(e,e’) and ⁵²Cr(p,p’).
9050	1+,(2-)		E(level): From ⁵¹V(³He,d).
9140.3	1+	2.65 eV 15	B(M1)=0.90 5. E(level): Band based on 5⁺. From (HI,xnγ). From ⁵²Mn ε decay (21.1 min). From ⁵²Cr(γ,γ’),(pol γ,γ’). J^π(level): Dipole transition in ⁵²Cr(γ,γ’),(pol γ,γ’). T_1/2(level): Partial decay width into ground state in ⁵²Cr(γ,γ’),(pol γ,γ’).
9200	5-		E(level): From ⁵⁰Cr(α,²He).
9211.9	1+	2.11 eV 14	XREF: γ(9221)n(9210). E(level): From ⁵²Mn ε decay (21.1 min). From ⁵²Cr(γ,γ’),(pol γ,γ’). T_1/2(level): Partial decay width into ground state in ⁵²Cr(γ,γ’),(pol γ,γ’).
9245	1+		E(level): From ⁵²Cr(p,p’).
9327.0	1+	0.746 eV 80	E(level): From ⁵²Mn ε decay (21.1 min). From ⁵²Cr(γ,γ’),(pol γ,γ’). J^π(level): Based on σ(θ), DWIA calculations in ⁵²Cr(p,p’). T_1/2(level): Partial decay width into ground state in ⁵²Cr(γ,γ’),(pol γ,γ’).
9429.0	1+	0.95 eV 11	XREF: γ(9440). E(level): From ⁵²Mn ε decay (21.1 min). From ⁵²Cr(γ,γ’),(pol γ,γ’). T_1/2(level): Partial decay width into ground state in ⁵²Cr(γ,γ’),(pol γ,γ’).
9438.5	12(+)		E(level): Band based on 5⁺.
E(level)	J^π(level)	T_1/2(level)	Comments
9450	8-		XREF: g(9480).
9612	1+		XREF: γ(9620). E(level): From weighted average of values in ⁵²Cr(e,e’) and ⁵²Cr(p,p’). J^π(level): Based on σ(θ), DWIA calculations in ⁵²Cr(p,p’).
9660	8-		XREF: g(9630).
9724	1+		XREF: γ(9740)M(9736)n(9720). E(level): From weighted average of values in ⁵²Cr(e,e’) and ⁵²Cr(p,p’). J^π(level): Based on σ(θ), DWIA calculations in ⁵²Cr(p,p’).
9787	1-		E(level): From (HI,xnγ). From ⁵²Mn ε decay (21.1 min). From ⁵²Cr(γ,γ’),(pol γ,γ’). J^π(level): Dipole transition in ⁵²Cr(γ,γ’),(pol γ,γ’).
9878	1+		XREF: E(9870)γ(9870)n(9880). E(level): From weighted average of values in ⁵²Cr(e,e’) and ⁵²Cr(p,p’). J^π(level): Based on σ(θ), DWIA calculations in ⁵²Cr(p,p’).
9981	(-)		E(level): From ⁵²Mn ε decay (21.1 min). From ⁵²Cr(γ,γ’),(pol γ,γ’).
10008	1+		XREF: γ(10000)n(10010). E(level): From weighted average of values in ⁵²Cr(e,e’) and ⁵²Cr(p,p’). J^π(level): Based on σ(θ), DWIA calculations in ⁵²Cr(p,p’).
10110	(8-)		XREF: g(10130).
10161.3	(13+)		E(level): Band based on 5⁺.
10330	6-		XREF: g(10280).
10380	1+		E(level): From weighted average of values in ⁵²Cr(e,e’) and ⁵²Cr(p,p’). J^π(level): Based on σ(θ), DWIA calculations in ⁵²Cr(p,p’).
10433	1+		E(level): From ⁵²Mn ε decay (21.1 min). From ⁵²Cr(γ,γ’),(pol γ,γ’).
10464	1+		XREF: γ(10480)n(10460). J^π(level): Based on σ(θ), DWIA calculations in ⁵²Cr(p,p’).
10604	1+		XREF: γ(10580)n(10610). E(level): From weighted average of values in ⁵²Cr(e,e’) and ⁵²Cr(p,p’). J^π(level): Based on σ(θ), DWIA calculations in ⁵²Cr(p,p’).
10760	6+,8+		XREF: a(10750).
10790	1+		J^π(level): Based on σ(θ), DWIA calculations in ⁵²Cr(p,p’).
10927	1+,2-		XREF: n(10920). E(level): From ⁵²Mn ε decay (21.1 min). From ⁵²Cr(γ,γ’),(pol γ,γ’).
10970	0+		J^π(level): Based on σ(θ), DWIA calculations in ⁵²Cr(p,p’).
11140	0+		XREF: γ(11120). J^π(level): Based on σ(θ), DWIA calculations in ⁵²Cr(p,p’).
11264.9	+		T=3 IAS (⁵²V g.s.). Some authors identify 11256.5 state as g.s. IAS. However, from a comparison of relative M1 transition rates from 11264.9 state with Gamow-Teller β decay matrix elements for ⁵²V g.s. 1973Fa12 concluded that most of the IAS strength lies in the 11265 state. The 11256 state might still be a fragment of the g.s. IAS. E(level): IAS (⁵²V g.s.). Some authors identify 11256.5 state as g.s. IAS. However, from a comparison of relative M1 transition rates from 11264.9 state with Gamow-Teller β decay matrix elements for ⁵²V g.s. 1973Fa12 concluded that most of the IAS strength lies in the 11265 state. The 11256 state might still be a fragment of the g.s. IAS. J^π(level): IAS in ⁵¹V(p,γ) E=res.
11274.6	+		T=3 Identified as fragment of IAS (⁵²V 23 keV). E(level): Identified as fragment of IAS (⁵²V 23 keV). From ⁵²Cr(γ,γ’),(pol γ,γ’). From ⁵¹V(p,γ). J^π(level): IAS in ⁵¹V(p,γ) E=res.
11291.1			E(level): From ⁵²Cr(γ,γ’),(pol γ,γ’). From ⁵¹V(p,γ).
11370	8-		XREF: g(11350).
11400.0	4+		T=3 Identified by 1974Ro44 as IAS (⁵²V 148 keV, 4⁺). E(level): Identified by 1974Ro44 as IAS (⁵²V 148 keV, 4⁺). From ⁵²Cr(γ,γ’),(pol γ,γ’). From ⁵¹V(p,γ).
E(level)	J^π(level)	T_1/2(level)	Comments
11402	1+		XREF: γ(11410)n(11400). E(level): From weighted average of values in ⁵²Cr(e,e’) and ⁵²Cr(p,p’).
11656	1+,2-		XREF: n(11650). E(level): From ⁵²Cr(γ,γ’),(pol γ,γ’). From ⁵¹V(p,γ).
11691.8			T=3 IAS (⁵²V 437 keV, 2⁺). E(level): IAS (⁵²V 437 keV, 2⁺). From ⁵²Cr(γ,γ’),(pol γ,γ’). From ⁵¹V(p,γ).
11713			E(level): From ⁵²Cr(γ,γ’),(pol γ,γ’). From ⁵¹V(p,γ).
11725			E(level): From ⁵²Cr(γ,γ’),(pol γ,γ’). From ⁵¹V(p,γ).
11745			E(level): From ⁵²Cr(γ,γ’),(pol γ,γ’). From ⁵¹V(p,γ).
11765			E(level): From ⁵²Mn ε decay (21.1 min). From ⁵²Cr(γ,γ’),(pol γ,γ’).
11770	8-		XREF: g(11790).
11837			E(level): From ⁵²Mn ε decay (21.1 min). From ⁵²Cr(γ,γ’),(pol γ,γ’).
12034.8	-		XREF: g(12050). E(level): From ⁵²Cr(γ,γ’),(pol γ,γ’). From ⁵¹V(p,γ).
12041.8	4+		T=3 IAS (⁵²V 793 keV, 3⁺). E(level): IAS (⁵²V 793 keV, 3⁺). From ⁵²Cr(γ,γ’),(pol γ,γ’). From ⁵¹V(p,γ). J^π(level): IAS in ⁵¹V(p,γ) E=res.
12099.9	4+		T=3 IAS (⁵²V 846 keV, 4⁺). E(level): IAS (⁵²V 846 keV, 4⁺). J^π(level): IAS in ⁵¹V(p,γ) E=res.
12260	6+,8+		E(level): From ⁵⁰Cr(α,²He).
12500	-		E(level): From ⁵¹V(α,t).
12560	1+		J^π(level): Based on σ(θ), DWIA calculations in ⁵²Cr(p,p’).
12665	3+		T=3 IAS (⁵²V 1419 keV, 3⁺)?. E(level): From ⁵²Cr(γ,γ’),(pol γ,γ’). From ⁵¹V(p,γ).
12730	-		XREF: g(12700).
12734			T=3 IAS (⁵²V 1493 keV, 7⁺)?. E(level): From ⁵²Cr(γ,γ’),(pol γ,γ’). From ⁵¹V(p,γ).
12794.8	4+		T=3 IAS (⁵²V 1559 keV, 4⁺)?. J^π(level): IAS in ⁵¹V(p,γ) E=res.
12900	1+		J^π(level): Based on σ(θ), DWIA calculations in ⁵²Cr(p,p’).
12977	-		T=3 XREF: g(13010). E(level): From ⁵²Cr(γ,γ’),(pol γ,γ’). From ⁵¹V(p,γ). J^π(level): IAS in ⁵¹V(p,γ) E=res.
12994	+		IAS (⁵²V 1760 keV, 3⁺)?. E(level): From ⁵²Cr(γ,γ’),(pol γ,γ’). From ⁵¹V(p,γ). J^π(level): IAS in ⁵¹V(p,γ) E=res.
13038	+		IAS (⁵²V 1843 keV, +)?. E(level): From ⁵²Cr(γ,γ’),(pol γ,γ’). From ⁵¹V(p,γ). J^π(level): IAS in ⁵¹V(p,γ) E=res.
13319			E(level): From ⁵²Cr(γ,γ’),(pol γ,γ’). From ⁵¹V(p,γ).
13393	6-		E(level): From ⁵²Cr(γ,γ’),(pol γ,γ’). From ⁵¹V(p,γ).
E(level)	J^π(level)	T_1/2(level)	Comments
13419	0+		T=3 E(level): From ⁵²Cr(γ,γ’),(pol γ,γ’). From ⁵¹V(p,γ).
13630	0+		T=3 IAS (⁵²V 2396 keV, 0⁺, (1⁺))?. E(level): From ⁵⁰Ti(³He,n).
13950			E(level): From ⁵⁰Ti(³He,n).
14110	2+		T=3 IAS (⁵²V 2881 keV, +)?. E(level): From ⁵⁰Ti(³He,n).
14430	8-		XREF: g(11470).
15270	6-		XREF: g(15280).
15482	8-		T=3 E(level): From ⁵¹V(α,t).

E(level)	E(gamma)	Comments
1434.091	1434.068	E(γ): From weighted average of values in ⁵²Mn ε decay (5.591 d) and ⁵²V β^- decay. M(γ): From (HI,xnγ).
2369.630	935.538	E(γ): From weighted average of values in ⁵²Mn ε decay (5.591 d) and ⁵²V β^- decay. M(γ): From (HI,xnγ).
2646.9	1212.8	E(γ): from (p,p’γ).
2767.767	398.08	E(γ): From ⁵²V β^- decay.. From ⁵²Cr(e,e’). I(γ): other: 1.36 17 in ⁵²V β^- decay. M(γ): From (HI,xnγ).
2767.767	1333.649	M(γ): From (HI,xnγ).
2964.786	1530.67	E(γ): From ⁵²Mn ε decay (21.1 min).. From ⁵²Cr(γ,γ’),(pol γ,γ’).. From ⁵²Cr(p,p’). I(γ): From ⁵²Mn ε decay (21.1 min).
2964.786	2965	E(γ): From ⁵²Mn ε decay (21.1 min).. From ⁵²Cr(γ,γ’),(pol γ,γ’).. From ⁵²Cr(p,p’). I(γ): From ⁵²Mn ε decay (21.1 min). M(γ): From ⁵²V β^- decay.
3161.74	1727.53	E(γ): From ⁵²Cr(p,p’).. From ⁵²Mn ε decay (21.1 min).. From ⁵²Cr(γ,γ’),(pol γ,γ’). I(γ): From ⁵²Mn ε decay (21.1 min).
3161.74	3161.8	E(γ): From ⁵²Cr(p,p’).. From ⁵²Mn ε decay (21.1 min).. From ⁵²Cr(γ,γ’),(pol γ,γ’). I(γ): From ⁵²Mn ε decay (21.1 min).
3415.32	647.47	M(γ): From (HI,xnγ).. From ⁵¹V(p,γ).
	766.0	E(γ): From ⁵²V β^- decay.. From ⁵²Cr(e,e’).
	1045.73	E(γ): From weighted average of values in ⁵²Mn ε decay (5.591 d) and ⁵²V β^- decay.
3472.25	704.6	E(γ): From ⁵²Mn ε decay (21.1 min).. From ⁵²Cr(γ,γ’),(pol γ,γ’). I(γ): From (n,n’γ).
3472.25	2038.0	E(γ): From ⁵²Mn ε decay (21.1 min).. From ⁵²Cr(γ,γ’),(pol γ,γ’). I(γ): From (n,n’γ).
3615.924	848.18	M(γ): From (HI,xnγ).
3771.72	2337.44	E(γ): From ⁵²Cr(p,p’).. From weighted average of values in ⁵²Mn ε decay (21.1 min) and ⁵²V β^- decay. I(γ): From ⁵²Mn ε decay (21.1 min).
3771.72	3771.7	E(γ): From ⁵²Mn ε decay (21.1 min).. From ⁵²Cr(γ,γ’),(pol γ,γ’).. From ⁵²Cr(p,p’). I(γ): From ⁵²Mn ε decay (21.1 min).
3947.5	1578	E(γ): From ⁵¹V(³He,dγ).
3951.2	3951	E(γ): From ⁵²Mn ε decay (21.1 min).. From ⁵²Cr(γ,γ’),(pol γ,γ’).. From ⁵²Cr(p,p’). I(γ): From ⁵²Mn ε decay (21.1 min).
4015.51	399.57	I(γ): other: 33.3 5 in (HI,xnγ).
	600.16	M(γ): From (HI,xnγ).
	1247.88	M(γ): From (HI,xnγ).
4039.1	566.8	E(γ): From (HI,xnγ). I(γ): From (HI,xnγ).
4563.0	791	E(γ): From ⁵¹V(³He,dγ).
4563.0	3129	E(γ): From ⁵²Mn ε decay (21.1 min).. From ⁵²Cr(γ,γ’),(pol γ,γ’).
E(level)	E(gamma)	Comments
4584.0	1470.1	E(γ): From (HI,xnγ). I(γ): From (HI,xnγ).
4750.31	1636.4	E(γ): From (HI,xnγ). I(γ): From (HI,xnγ). M(γ): From (HI,xnγ).
4805.96	790.0	E(γ): From (HI,xnγ). I(γ): From (HI,xnγ). M(γ): From (HI,xnγ).. From ⁵¹V(p,γ).
	1189.7	E(γ): From (HI,xnγ). I(γ): From (HI,xnγ).
	1693.9	E(γ): From (HI,xnγ). I(γ): From (HI,xnγ).
4815.69	3381.5	E(γ): From ⁵²Cr(p,p’).. From ⁵²Mn ε decay (21.1 min).. From ⁵²Cr(γ,γ’),(pol γ,γ’). I(γ): From ⁵²Mn ε decay (21.1 min).
4815.69	4815.4	E(γ): From ⁵²Cr(p,p’).. From ⁵²Mn ε decay (21.1 min).. From ⁵²Cr(γ,γ’),(pol γ,γ’). I(γ): From ⁵²Mn ε decay (21.1 min).
5098.6	3664.5	E(γ): From ⁵²Cr(γ,γ’),(pol γ,γ’).. From ⁵¹V(p,γ). I(γ): From ⁵²Cr(γ,γ’),(pol γ,γ’).
5098.6	5098.3	E(γ): From ⁵²Cr(γ,γ’),(pol γ,γ’).. From ⁵¹V(p,γ). I(γ): From ⁵²Cr(γ,γ’),(pol γ,γ’).
5213.7	5213.4	E(γ): From ⁵²Cr(γ,γ’),(pol γ,γ’).. From ⁵¹V(p,γ). I(γ): From ⁵²Cr(γ,γ’),(pol γ,γ’).
5396.9	590.9	E(γ): From (HI,xnγ). I(γ): From (HI,xnγ). M(γ): From (HI,xnγ).. From ⁵¹V(p,γ).
5396.9	1381.5	E(γ): From (HI,xnγ). I(γ): From (HI,xnγ). M(γ): From (HI,xnγ).
5544.7	5544.4	E(γ): From ⁵²Cr(γ,γ’),(pol γ,γ’).. From ⁵¹V(p,γ). I(γ): From ⁵²Cr(γ,γ’),(pol γ,γ’).
5633.4	1049.4	E(γ): From (HI,xnγ). I(γ): From (HI,xnγ).
5824.7	427.9	E(γ): From (HI,xnγ). I(γ): From (HI,xnγ). M(γ): From (HI,xnγ).. From ⁵¹V(p,γ).
6137.0	6136.6	E(γ): From ⁵²Cr(γ,γ’),(pol γ,γ’).. From ⁵¹V(p,γ). I(γ): From ⁵²Cr(γ,γ’),(pol γ,γ’).
6356.6	725.5	E(γ): From (HI,xnγ). I(γ): From (HI,xnγ).
6365.3	1615.0	E(γ): From (HI,xnγ). I(γ): From (HI,xnγ).
6381.0	2765.0	E(γ): From (HI,xnγ).
6389.9	6389.5	E(γ): From ⁵²Cr(γ,γ’),(pol γ,γ’).. From ⁵¹V(p,γ). I(γ): From ⁵²Cr(γ,γ’),(pol γ,γ’).
6453.4	628.9	E(γ): From (HI,xnγ). I(γ): From (HI,xnγ). M(γ): From (HI,xnγ).. From ⁵¹V(p,γ).
	1056.0	E(γ): From (HI,xnγ). I(γ): From (HI,xnγ).
	1702.9	E(γ): From (HI,xnγ). I(γ): From (HI,xnγ). M(γ): From (HI,xnγ).. From ⁵¹V(p,γ).
6462.4	6462.0	E(γ): From ⁵²Cr(γ,γ’),(pol γ,γ’).. From ⁵¹V(p,γ). I(γ): From ⁵²Cr(γ,γ’),(pol γ,γ’).
6495.5	6495.1	E(γ): From ⁵²Cr(γ,γ’),(pol γ,γ’).. From ⁵¹V(p,γ). I(γ): From ⁵²Cr(γ,γ’),(pol γ,γ’).
E(level)	E(gamma)	Comments
6752.0	6751.5	E(γ): From ⁵²Cr(γ,γ’),(pol γ,γ’).. From ⁵¹V(p,γ). I(γ): From ⁵²Cr(γ,γ’),(pol γ,γ’).
7014.5	5580.5	E(γ): From ⁵²Cr(γ,γ’),(pol γ,γ’).. From ⁵¹V(p,γ). I(γ): From ⁵²Cr(γ,γ’),(pol γ,γ’).
7014.5	7013.6	E(γ): From ⁵²Cr(γ,γ’),(pol γ,γ’).. From ⁵¹V(p,γ). I(γ): From ⁵²Cr(γ,γ’),(pol γ,γ’).
7090.8	7090.3	E(γ): From ⁵²Cr(γ,γ’),(pol γ,γ’).. From ⁵¹V(p,γ). I(γ): From ⁵²Cr(γ,γ’),(pol γ,γ’).
7166.2	7165.7	E(γ): From ⁵²Cr(γ,γ’),(pol γ,γ’).. From ⁵¹V(p,γ). I(γ): From ⁵²Cr(γ,γ’),(pol γ,γ’).
7237.9	784.5	E(γ): From (HI,xnγ). I(γ): From (HI,xnγ). M(γ): From (HI,xnγ).. From ⁵¹V(p,γ).
	883.7	E(γ): From (HI,xnγ). I(γ): From (HI,xnγ).
	1413.6	E(γ): From (HI,xnγ). I(γ): From (HI,xnγ).
	1606.0	E(γ): From (HI,xnγ). I(γ): From (HI,xnγ).
7368.8	7368.2	E(γ): From ⁵²Cr(γ,γ’),(pol γ,γ’).. From ⁵¹V(p,γ). I(γ): From ⁵²Cr(γ,γ’),(pol γ,γ’).
7401.6	1036.3	E(γ): From (HI,xnγ). M(γ): From (HI,xnγ).
7403.2	7402.6	E(γ): From ⁵²Cr(γ,γ’),(pol γ,γ’).. From ⁵¹V(p,γ). I(γ): From ⁵²Cr(γ,γ’),(pol γ,γ’).
7524.1	7523.5	E(γ): From ⁵²Cr(γ,γ’),(pol γ,γ’).. From ⁵¹V(p,γ). I(γ): From ⁵²Cr(γ,γ’),(pol γ,γ’).
7731.9	7731.3	E(γ): From ⁵²Cr(γ,γ’),(pol γ,γ’).. From ⁵¹V(p,γ). I(γ): From ⁵²Cr(γ,γ’),(pol γ,γ’).
7865.1	7864.5	E(γ): From ⁵²Cr(γ,γ’),(pol γ,γ’).. From ⁵¹V(p,γ). I(γ): From ⁵²Cr(γ,γ’),(pol γ,γ’).
7889.0	7888.4	E(γ): From ⁵²Cr(γ,γ’),(pol γ,γ’).. From ⁵¹V(p,γ). I(γ): From ⁵²Cr(γ,γ’),(pol γ,γ’).
7897.4	7896.8	E(γ): From ⁵²Cr(γ,γ’),(pol γ,γ’).. From ⁵¹V(p,γ). I(γ): From ⁵²Cr(γ,γ’),(pol γ,γ’).
8015.4	6580.9	E(γ): From ⁵²Cr(γ,γ’),(pol γ,γ’).. From ⁵¹V(p,γ). I(γ): From ⁵²Cr(γ,γ’),(pol γ,γ’).
8015.4	8014.6	E(γ): From ⁵²Cr(γ,γ’),(pol γ,γ’).. From ⁵¹V(p,γ). I(γ): From ⁵²Cr(γ,γ’),(pol γ,γ’).
8091.3	8090.6	E(γ): From ⁵²Cr(γ,γ’),(pol γ,γ’).. From ⁵¹V(p,γ). I(γ): From ⁵²Cr(γ,γ’),(pol γ,γ’).
8179.3	6744.8	E(γ): if 8179.2 level energy is correct, then Eγ should be 6744.8, not 6740.8 as listed in table I of 2013Pa38. From ⁵²Cr(γ,γ’),(pol γ,γ’).. From ⁵¹V(p,γ). I(γ): From ⁵²Cr(γ,γ’),(pol γ,γ’).
8179.3	8178.5	E(γ): From ⁵²Cr(γ,γ’),(pol γ,γ’).. From ⁵¹V(p,γ). I(γ): From ⁵²Cr(γ,γ’),(pol γ,γ’).
8216.4	978.5	E(γ): From (HI,xnγ). I(γ): From (HI,xnγ). M(γ): From (HI,xnγ).. From ⁵¹V(p,γ).
8216.4	1763.3	E(γ): From (HI,xnγ). I(γ): From (HI,xnγ). M(γ): From (HI,xnγ).
8765.9	8765.1	E(γ): From ⁵²Cr(γ,γ’),(pol γ,γ’).. From ⁵¹V(p,γ). I(γ): From ⁵²Cr(γ,γ’),(pol γ,γ’).
E(level)	E(gamma)	Comments
8958.4	8957.6	E(γ): From ⁵²Cr(γ,γ’),(pol γ,γ’).. From ⁵¹V(p,γ). I(γ): From ⁵²Cr(γ,γ’),(pol γ,γ’).
9140.3	9139.4	E(γ): From ⁵²Cr(γ,γ’),(pol γ,γ’).. From ⁵¹V(p,γ). I(γ): From ⁵²Cr(γ,γ’),(pol γ,γ’).
9211.9	9211.0	E(γ): From ⁵²Cr(γ,γ’),(pol γ,γ’).. From ⁵¹V(p,γ). I(γ): From ⁵²Cr(γ,γ’),(pol γ,γ’).
9327.0	9326.1	E(γ): From ⁵²Cr(γ,γ’),(pol γ,γ’).. From ⁵¹V(p,γ). I(γ): From ⁵²Cr(γ,γ’),(pol γ,γ’).
9429.0	9428.1	E(γ): From ⁵²Cr(γ,γ’),(pol γ,γ’).. From ⁵¹V(p,γ). I(γ): From ⁵²Cr(γ,γ’),(pol γ,γ’).
9438.5	1222.4	E(γ): From (HI,xnγ). I(γ): From (HI,xnγ).
9438.5	2200.0	E(γ): From (HI,xnγ). I(γ): From (HI,xnγ).
10161.3	721.3	E(γ): From (HI,xnγ). I(γ): From (HI,xnγ).
10161.3	1943.6	E(γ): From (HI,xnγ). I(γ): From (HI,xnγ). M(γ): From (HI,xnγ).
11264.9	7850	M(γ): From (HI,xnγ).. From ⁵¹V(p,γ).
	8895	M(γ): From (HI,xnγ).. From ⁵¹V(p,γ).
	9830	M(γ): From (HI,xnγ).. From ⁵¹V(p,γ).
11274.6	7859	M(γ): From (HI,xnγ).. From ⁵¹V(p,γ).
11274.6	8904	M(γ): From (HI,xnγ).. From ⁵¹V(p,γ).
11400.0	9030	M(γ): From (HI,xnγ).. From ⁵¹V(p,γ).