List of levels for 172YB

Author: Balraj Singh | Citation: Nucl. Data Sheets 75,199 (1995) | Cutoff date: 31-May-1995

Other reaction: (n,n): 1986Ko07 at E=0.5 milliev. Measured cross section and neutron scattering lengths

Hyperfine structure studies: 1992Ku21, 1991Ma48, 1991Ki14, 1991Ji06, 1991Ho27, 1990Sp05, 1990Bi08, 1985Ne09, 1983Ma49, 1982Bu21, 1979Gr17, 1973Le16

Nuclear structure calculations (levels, moments, deformation, etc.):

1994Ze07, 1994Vo19, 1994Al23, 1994Mi14, 1994Co20, 1994Tr04, 1994Ku01, 1993El03, 1993Kn01, 1993Sa08, 1993Ba17, 1992Wo11, 1992Vo02, 1992So22, 1992Ch21, 1992Ca08, 1991Su08, 1991So11, 1991Ch09, 1990Zi05, 1990So16, 1990Sa42, 1989So11, 1988Pe06, 1988Du15, 1987Li11, 1986So09, 1986Ba56, 1985An12, 1982Zh03, 1981Ma17, 1979Si13, 1976Ne05, 1975Dz03, 1975An03, 1974Ma05, 1974Ha54, 1972Mo05, 1971Ha56, 1971Fr02, 1970Wa03, 1970Ne02, 1963Ya06

Levels: Levels marked with XREF=O correspond to the following reactions and level energies therein:

Levels: ¹⁷⁵Lu(p,α): 0, 79, 261, 543, 1172, 1263, 1375, 1510, 1662, 1701, 1749, 1800, 1860, 1924, 2002, 2073, 2154, 2190, 2213, 2274, 2298, 2333, 2409, 2467, 2547, 2628, 2667, 2720, 2740, 2819, 2844

Levels: ¹⁷³Yb(p,d): 78, 260, 540, 1118, 1173, 1222, 1263, 1287, 1331, 1353, 1376, 1467, 1477, 1496, 1510, 1540, 1551, 1609, 1635, 1663, 1672, 1701, 1751, 1759, 1778, 1804, 1811, 1926, 1966, 2010

Levels: ¹⁷²Yb(d,d’): 0, 79, 260, 543, 1116, 1222, 1262, 1355, 1465, 1605, 1631, 1660, 1708, 1747, 1789, 1820, 2032, 2050

Levels: ¹⁷⁰Yb(t,p): 0, 78, 260, 1043, 1118, 1263, 1287, 1466, 1654, 1823, 1853, 2046, 2177, 2228, 2466

Levels: Muonic atom: 0, 79, 260, 1043, 1118, 1155, 1172, 1757, 1821

Levels: ¹⁷²Yb(γ,γ) Mossbauer: 0, 79

Q-value: Note: Current evaluation has used the following Q record -2519.3 24 8019.7 3 7333.8 10 1310.2 14 1993Au05,1993Au07

E(level) (keV)	J^π(level)	T_1/2(level)	E(γ) (keV)	Multipolarity	Mixing Ratio	Conversion Coefficient	Additional Data
78.7427	2+	1.65 ns 5	78.7426 6	E2		8.4	B(E2)(W.u.)=212 2, α=8.4
260.268	4+	0.122 ns 8	181.528 4	E2		0.376	B(E2)(W.u.)=301 20, α=0.376
539.977	6+	16.6 ps 15	279.717 5	E2		0.092	B(E2)(W.u.)=3.2×10² 3, α=0.092
912.12	8+	3.5 ps 3	372.06 10	E2			B(E2)(W.u.)=4.0×10² 4
1042.914	0+	3.3 ps 9	964.09 5	[E2]			B(E2)(W.u.)=3.6 10
1117.874	2+	3.7 ps 4	857.636 7	E2			B(E2)(W.u.)=2.5 3
	2+	3.7 ps 4	1039.149 10	M1+E2+E0	+2.3 +5-3		B(E2)(W.u.)=0.79 12, B(M1)(W.u.)=0.00036 9
	2+	3.7 ps 4	1117.94 3	E2			B(E2)(W.u.)=0.24 1
1172.385	3+	8.14 ns 17	912.125 25	M1+E2	-2.36 15		B(E2)(W.u.)=0.000325 15, B(M1)(W.u.)=1.07E-7 13
1172.385	3+	8.14 ns 17	1093.657 13	M1+E2	-4.0 3		B(E2)(W.u.)=0.000591 21, B(M1)(W.u.)=9.8E-8 15
1263.028	4+	0.49 ns 3	90.6440 17	M1+E2	-1.64 2	4.72	B(E2)(W.u.)=3.5×10² 3, B(M1)(W.u.)=0.00233 21, α=4.72
	4+	0.49 ns 3	723.02 2	E2			B(E2)(W.u.)=0.00140 11
	4+	0.49 ns 3	1002.75 2	M1+E2	+13 +76-6		B(E2)(W.u.)=0.0032 4, B(M1)(W.u.)<1.5E-7
	4+	0.49 ns 3	1184.28 3	E2			B(E2)(W.u.)=9.E-5 4
1286.54	4+		1026.27 6	M1+E2(+E0)	+0.87 13
1370.07	10+	1.32 ps 8	457.86 10	E2			B(E2)(W.u.)=375 23
1375.815	5+	0.21 ns 6	112.778 3	M1+E2	1.43 3	2.19	B(E2)(W.u.)=1.9×10² 6, B(M1)(W.u.)=0.0027 8, α=2.19
	5+	0.21 ns 6	203.438 5	E2		0.26	B(E2)(W.u.)=60 18, α=0.26
	5+	0.21 ns 6	835.85 7	M1+E2	1.0 6		B(E2)(W.u.)=0.0026 18, B(M1)(W.u.)=4.E-6 3
	5+	0.21 ns 6	1115.54 5	E2			B(E2)(W.u.)=0.0011 4
1405.008	0+	0.42 ns 6	250.035 7	[E1]			B(E1)(W.u.)=9.7E-7 17
	0+	0.42 ns 6	287.139 3	[E2]			B(E2)(W.u.)=5.9 13
	0+	0.42 ns 6	1326.10 7	[E2]			B(E2)(W.u.)=0.0025 4
1465.875	2+	0.47 ps 3	267.14 20	[E1]		0.027	B(E1)(W.u.)=5.4E-6 14, α=0.027
	2+	0.47 ps 3	293.61 6	[M1,E2]			B(E2)(W.u.)=5.4 7, B(M1)(W.u.)=0.00102 13
	2+	0.47 ps 3	348.04 6	[M1,E2]		0.08	B(E2)(W.u.)=3.4 4, B(M1)(W.u.)=0.00092 10, α=0.08 3
	2+	0.47 ps 3	423.04 6	[E2]		0.028	B(E2)(W.u.)=2.42 24, α=0.028
	2+	0.47 ps 3	1205.62 8	(E2)			B(E2)(W.u.)=0.129 10
	2+	0.47 ps 3	1387.093 4	M1+E2(+E0)	-5.1 +11-16		B(M1)(W.u.)=0.0094 8
	2+	0.47 ps 3	1465.93 4	E2			B(E2)(W.u.)=1.33 11
E(level) (keV)	J^π(level)	T_1/2(level)	E(γ) (keV)	Multipolarity	Mixing Ratio	Conversion Coefficient	Additional Data
1476.784	2+	48 ps 11	321.82 11	E1		0.017	B(E1)(W.u.)=5.5E-7 20, α=0.017
	2+	48 ps 11	358.86 6	(E2)		0.044	B(E2)(W.u.)=0.28 8, α=0.044
	2+	48 ps 11	1397.92 5	M1+E2(+E0)	0.8 5		B(E2)(W.u.)=0.010 7, B(M1)(W.u.)=7.E-5 4
	2+	48 ps 11	1476.77 7	E2			B(E2)(W.u.)=0.0071 17
1510.179	6+		134.363 18	M1+E2	1.3 3	1.23	α=1.23 6
1510.179	6+		247.155 6	E2		0.136	α=0.136
1537.50	6+		997.42 6	M1+E2	+0.63 7
1549.150	3+		286.30 20	(M1)		0.183	α=0.183
	3+		431.29 8	(M1)		0.062	α=0.062
	3+		1288.82 3	M1+E2	2.8 +7-10
	3+		1470.42 3	M1+E2	-7.6 +19-36
1550.43	6-	3.6 µs 1	174.7 10	(E1)		0.079	B(E1)(W.u.)=7.6E-9 5, α=0.079
	6-	3.6 µs 1	197.6 3	[M1,E2]			B(E2)(W.u.)=0.00021 4, B(M1)(W.u.)=1.9E-8 3
	6-	3.6 µs 1	1010.45 6	E1+M2	-0.38 5		B(E1)(W.u.)=1.20E-11 8, B(M2)(W.u.)=7.8E-6 19
1599.870	1-	11 fs 3	1521.114 24	E1			B(E1)(W.u.)=0.00122938 6
1599.870	1-	11 fs 3	1599.79 7	[E1]			B(E1)(W.u.)=0.0018 5
1608.490	2+	1.1 ps 2	131.83 4	[M1,E2]		1.4	α=1.4 2
	2+	1.1 ps 2	142.56 2	[M1,E2]		1.1	α=1.1 2
	2+	1.1 ps 2	1529.72 4	E2+M1(+E0)	+10 3		B(E2)(W.u.)=0.55 3, B(M1)(W.u.)=2.9E-5 15
	2+	1.1 ps 2	1608.56 15	E2			B(E2)(W.u.)=0.35 6
1640.557	4-	0.5 ns 2	264.738 9	E1(+M2)	-0.09 6	0.035	B(E1)(W.u.)=(4.2E-6 17), B(M2)(W.u.)=(2 3), α=0.035 14
	4-	0.5 ns 2	377.540 8	E1(+M2)	-0.05 4	0.012	B(E1)(W.u.)=(6.E-6 3), B(M2)(W.u.)=(0.5 9), α=0.012 2
	4-	0.5 ns 2	1380.23 10	[E1]			B(E1)(W.u.)=1.6E-9 9
1657.790	(4)+	0.05 ps 3	1397.50 3	M1+E2	-1.1 +2-5		B(E2)(W.u.)=13 9, B(M1)(W.u.)=0.05 3
1657.790	(4)+	0.05 ps 3	1578.87 12	E2			B(E2)(W.u.)=7 5
E(level) (keV)	J^π(level)	T_1/2(level)	E(γ) (keV)	Multipolarity	Mixing Ratio	Conversion Coefficient	Additional Data
1662.810	3+		186.11 20	[M1,E2]		0.5	α=0.5 1
	3+		197.02 6	[M1,E2]		0.4	α=0.4 1
	3+		399.750 15	M1(+E2)	-0.07 7	0.075	α=0.075
	3+		490.444 8	M1(+E2)	+0.04 4	0.044	α=0.044
	3+		1402.53 3	E2(+M1)	+12 +9-4
	3+		1584.08 10	E2(+M1)	+55 +94-22
1700.639	3+		151.55 6	[M1,E2]		0.88	α=0.88 18
	3+		437.60 2	M1(+E2)	+0.09 10	0.059	α=0.059
	3+		528.260 14	M1(+E2)	+0.01 3	0.037	α=0.037
	3+		1440.38 3	E2+M1	+6.5 +22-14
	3+		1621.92 3	E2+M1	+17 4
1706.447	5-		65.8 3	[M1,E2]		14	α=14 3
	5-		196.38 4	(E1)		0.058	α=0.058
	5-		330.619 21	E1(+M2)	0.13 LT	0.020	α=0.020 4
1749.205	4+		200.5 4	E2		0.27	α=0.27
	4+		486.160 18	M1+E2	+0.41 14	0.041	α=0.041 2
	4+		576.835 18	M1+E2	0.24 6	0.0284	α=0.0284
	4+		1488.94 3	E2(+M1)	-6 LT
1757.367	(2)-		558.931 10	M1(+E2)	0.7 LT
1757.367	(2)-		602.472 6	M1+E2	1.0 4
1778.86	5+		1238.73 8	M1(+E2)	0.8 LT
1794.08	0+	< 0.15 ns	1715.37 5	E2			B(E2)(W.u.)>0.0044
1803.108	4+		145.21 5	M1(+E2)	1.4 LT	1.07	α=1.07 13
	4+		337.85 9	(E2)		0.052	α=0.052
	4+		427.19 5	M1+E2	1.6 6	0.037	α=0.037 8
	4+		540.187 16	M1(+E2)	-0.03 +10-8	0.035	α=0.035
	4+		630.706 17	M1(+E2)	-0.10 +14-17	0.023	α=0.023
	4+		1542.850 23	E2(+M1)	+9 +11-3
E(level) (keV)	J^π(level)	T_1/2(level)	E(γ) (keV)	Multipolarity	Mixing Ratio	Conversion Coefficient	Additional Data
1849.173	2+	0.8 ps 5	1849.06 3	(E2)			B(E2)(W.u.)=0.17 11
1862.799	(5)+		200.5 4	E2		0.27	α=0.27
	(5)+		352.55 4	E2(+M1)	2.7 GT	0.050	α=0.050 4
	(5)+		599.86 4	E2+M1	1 GT
	(5)+		1322.66 9	E2(+M1)	1.6 GT
	(5)+		1602.54 3	E2(+M1)	+21 +45-9
1869.634	(4,5)-		163.165 20	M1(+E2)	0.8 LT	0.80	α=0.80 7
1869.634	(4,5)-		229.080 10	M1(+E2)	1.4 LT	0.28	α=0.28 6
1894.616	0+	< 0.15 ns	776.71 7	(E2)			B(E2)(W.u.)>0.0047
1894.616	0+	< 0.15 ns	1815.70 7	E2			B(E2)(W.u.)>0.0032
1907.48	(12+)	0.52 ps 7	537.4 1	(E2)			B(E2)(W.u.)=4.3×10² 6
1927.016	5+		416.65 8	M1(+E2)	0.7 LT	0.061	α=0.061 7
	5+		551.078 19	M1+E2	+1.5 5	0.020	α=0.020 4
	5+		664.07 5	M1(+E2)	1.2 LT	0.017	α=0.017 4
	5+		1666.38 20	E2+M1	+6.9 +19-12
1956.351	2+	0.29 ps 15	1956.90 18	[E2]			B(E2)(W.u.)=0.33 16
2073.114	4+		146.03 4	M1(+E2)	1.4 LT	1.05	α=1.05 13
	4+		210.28 3	M1(+E2)	1.1 LT	0.37	α=0.37 6
	4+		270.028 8	M1+E2	+0.79 +21-31	0.172	α=0.172 15
	4+		323.889 15	M1+E2	+0.40 8	0.121	α=0.121 4
	4+		366.684 24	E1		0.0123	α=0.0123
	4+		372.507 12	M1+E2	+0.71 7	0.073	α=0.073 2
	4+		410.308 12	M1+E2	+0.74 9	0.056	α=0.056 2
	4+		415.7 4	(M1,E2)		0.048	α=0.048 20
	4+		432.549 13	E1(+M2)	+0.04 +9-7
	4+		524.05 4	E2+M1	+2.8 5	0.018	α=0.018
	4+		607.141 18	E2		0.0112	α=0.0112
	4+		697.300 16	M1(+E2)	-0.014 10	0.0181	α=0.0181
	4+		810.064 15	M1+E2	-0.08 4	0.0124	α=0.0124
	4+		900.724 20	M1+E2	+0.068 9
	4+		1812.85 4	E2+M1	+6.0 +57-19
E(level) (keV)	J^π(level)	T_1/2(level)	E(γ) (keV)	Multipolarity	Mixing Ratio	Conversion Coefficient	Additional Data
2175.059	3+		566.49 5	E2(+M1)	0.8 GT
	3+		625.95 4	E2(+M1)	3 GT
	3+		709.133 17	E2+M1	+4.9 +10-8
	3+		1914.80 3	M1+E2	-0.291 24
	3+		2096.33 5	M1+E2	+0.68 +16-11
2176.20	(1)-		576.31 7	M1+E2	0.8 4
2181.97	(4,5,6)+		319.174 22	M1(+E2)	0.5 LT
2192.130	5+		119.023 15	[M1,E2]		1.9	α=1.9 2
	5+		329.39 5	M1(+E2)	1 LT	0.108	α=0.108 18
	5+		413.2 3	[M1,E2]		0.049	α=0.049 20
	5+		534.29 7	M1(+E2)	2 LT	0.027	α=0.027 9
	5+		681.82 4	M1+E2	+0.10 7	0.0191	α=0.0191
	5+		816.327 20	M1+E2	+0.20 14	0.0120	α=0.0120 5
	5+		929.106 20	M1+E2	-0.066 9
2210	1(-)	4.6 fs 9	2210	[E1]			B(E1)(W.u.)=0.00175 33
2213.307	3+,4+		512.54 5	M1+E2	0.6 3	0.034	α=0.034 5
	3+,4+		664.07 5	M1(+E2)	1.2 LT	0.017	α=0.017 4
	3+,4+		1040.99 3	M1(+E2)	0.9 LT
2285.399	4+		358.45 3	M1+E2	1.3 2	0.065	α=0.065 5
	4+		422.61 3	(M1,E2)		0.046	α=0.046 19
	4+		482.23 4	M1+E2	-0.10 7	0.046	α=0.046
	4+		536.194 19	M1+E2	-0.17 7	0.035	α=0.035
	4+		584.725 17	M1(+E2)	+0.06 9	0.0282	α=0.0282
	4+		622.605 22	M1(+E2)	0.4 LT	0.023	α=0.023 1
	4+		909.70 6	E2(+M1)	1.3 GT
	4+		1022.370 21	M1+E2	+0.75 17
	4+		1113.05 5	M1+E2	-0.18 4
	4+		2024.9 3	M1(+E2)	+0.46 44
E(level) (keV)	J^π(level)	T_1/2(level)	E(γ) (keV)	Multipolarity	Mixing Ratio	Conversion Coefficient	Additional Data
2343.715	4+		151.55 6	[M1,E2]		0.88	α=0.88 18
	4+		416.65 8	M1(+E2)	0.7 LT	0.061	α=0.061 7
	4+		480.84 10	M1(+E2)	1.3 LT	0.038	α=0.038 9
	4+		594.538 19	M1(+E2)	+0.23 +18-31	0.026	α=0.026
	4+		643.04 3	M1(+E2)	0.6 LT	0.0222	α=0.0222
	4+		967.89 5	M1+E2	-0.93 13
	4+		1080.68 4	M1+E2	-0.22 12
	4+		2083.41 6	M1+E2	+0.41 14
2518.7	(14+)	0.29 ps 4	611.2 3	(E2)			B(E2)(W.u.)=394 +60-45
3072	1(-)	6.1 fs 20	3072	[E1]			B(E1)(W.u.)=0.00053 17
3118	1(-)	8 fs 4	3118	[E1]			B(E1)(W.u.)=0.00037 17
3160	1(-)	3.4 fs 10	3160	[E1]			B(E1)(W.u.)=0.00072 22
3174	1(-)	3.7 fs 11	3174	[E1]			B(E1)(W.u.)=0.00057 17
3246	1(-)	5.6 fs 23	3246	[E1]			B(E1)(W.u.)=0.00048 20
3393	1(-)	2.7 fs 7	3393	[E1]			B(E1)(W.u.)=0.00075 19
3545	1(-)	1.6 fs 5	3545	[E1]			B(E1)(W.u.)=0.00085 28
3635	1(-)	1.3 fs 3	3635	[E1]			B(E1)(W.u.)=0.00135 32

Q(β-)=-2518.0 keV 24	S(n)= 8019.47 keV 14	S(p)= 7333.7 keV 10	Q(α)= 1309.6 keV 13
Reference: 2012WA38

References:
A	¹⁷²Tm β^- decay (63.6 H)	B	¹⁷²Lu ε decay (6.70 d)
C	¹⁷⁰Er(α,2nγ)	D	¹⁷¹Yb(n,γ) E=THERMAL
E	¹⁷¹Yb(n,γ) E=2 KEV	F	¹⁷¹Yb(d,p)
G	¹⁷²Yb(γ,γ’)	H	¹⁷²Yb(n,n’γ)
I	¹⁷²Yb(³He,³He’γ)	J	¹⁷²Yb(α,α’)
K	Coulomb Excitation	L	¹⁷³Yb(d,t)
M	¹⁷³Yb(³He,α), (³He,αγ)	N	¹⁷⁴Yb(p,t)
O	¹⁷⁵Lu(p,α)	P	¹⁷³Yb(p,d)
Q	¹⁷²Yb(d,d’)	R	¹⁷⁰Yb(t,p)
S	muonic atom	T	¹⁷²Yb(γ,γ):MOSSBAUER
U	¹⁷¹Yb(n,γ) E=RES	V	¹⁷²Yb(pol p,p), (p,p’)

E(level) (keV)	J^π(level)	T_1/2(level)	E(γ)	I(γ)	M(γ)	Final Levels
Band 1 - K^π=0⁺ GS band.
0.0	0+	STABLE
78.7427 6	2+	1.65 ns 5	78.7426 6	100	E2	0.0	0+
260.268 5	4+	0.122 ns 8	181.528 4	100	E2	78.7427	2+
539.977 6	6+	16.6 ps 15	279.717 5	100	E2	260.268	4+
912.12 7	8+	3.5 ps 3	372.06 10	100	E2	539.977	6+
1370.07 10	10+	1.32 ps 8	457.86 10	100	E2	912.12	8+
1907.48 14	(12+)	0.52 ps 7	537.4 1	100	(E2)	1370.07	10+
2518.7 4	(14+)	0.29 ps 4	611.2 3	100	(E2)	1907.48	(12+)
3198.4 6	(16+)		679.7 5	100		2518.7	(14+)
E(level) (keV)	J^π(level)	T_1/2(level)	E(γ)	I(γ)	M(γ)	Final Levels
Band 2 - K^π=0⁺ BETA-BAND.
1042.914 18	0+	3.3 ps 9
1117.874 5	2+	3.7 ps 4	857.636 7 1039.149 10 1117.94 3	100 3 100 3 36 3	E2 M1+E2+E0 E2	260.268 78.7427 0.0	4+ 2+ 0+
1286.54 3	4+		746.60 3 1026.27 6 1208.0 3	35 5 100 3 29 5	M1+E2(+E0)	539.977 260.268 78.7427	6+ 4+ 2+
1537.50 6	6+		251.43 12 625.1 5 997.42 6	8.2 19 9.4 19 100 4	M1+E2	1286.54 912.12 539.977	4+ 8+ 6+
1853.46 11	8+		316.3 3 483.26 12 941.37 10	35 8 73 7 100 6	(M1)	1537.50 1370.07 912.12	6+ 10+ 8+
2212.52 24	(10+)		358.9 3 842.6 3	81 13 100 19		1853.46 1370.07	8+ 10+
2607.2 4	(12+)		394.7 3	100		2212.52	(10+)
3043.9 5	(14+)		436.7 3	100 40		2607.2	(12+)
E(level) (keV)	J^π(level)	T_1/2(level)	E(γ)	I(γ)	M(γ)	Final Levels
Band 3 - K^π=1- octupole band.
1154.935 6	1-
1198.472 7	2-		1119.780 13	100	E1	78.7427	2+
1221.720 7	3-		961.478 12 1143.020 15	100 3 84 7	E1 E1	260.268 78.7427	4+ 2+
1330.693 14	4-		132.227 13 1070.40 3	1.8 9 100 2	E1	1198.472 260.268	2- 4+
1352.95 9	(5-)		812.96 10 1092.90 25	55 3 100 10		539.977 260.268	6+ 4+
1540.61 6	6-		187.5 3 ? 209.96 10 1000.62 6	5 3 24.1 11 100 4	(E2) E1	1352.95 1330.693 539.977	(5-) 4- 6+
1557.58 6	7-		645.41 10 1017.63 6	45 6 100 4	E1	912.12 539.977	8+ 6+
1828.76 15	8-		288.0 3 916.66 16	87 38 100 8	(E2) E1	1540.61 912.12	6- 8+
1839.80 11	9-		282.3 2 469.75 20 927.68 10	7 3 15 5 100 5	E1	1557.58 1370.07 912.12	7- 10+ 8+
2193.02 24	(10-)		364.2 3 823.0 3	100 7 22 7	(E2)	1828.76 1370.07	8- 10+
2199.47 21	(11-)		359.9 3 829.2 3	19 6 100 8		1839.80 1370.07	9- 10+
2629.8 4	(12-)		436.8 3	100		2193.02	(10-)
2636.1 3	(13-)		436.7 3 728.6 3	42 17 100 17		2199.47 1907.48	(11-) (12+)
3134.6 5	(14-)		504.8 3	100		2629.8	(12-)
E(level) (keV)	J^π(level)	T_1/2(level)	E(γ)	I(γ)	M(γ)	Final Levels
Band 4 - K^π=3⁺ band.
1172.385 6	3+	8.14 ns 17
1263.028 6	4+	0.49 ns 3	90.6440 17 723.02 2 1002.75 2 1184.28 3	89 3 8.5 3 100 2 6.7 24	M1+E2 E2 M1+E2 E2	1172.385 539.977 260.268 78.7427	3+ 6+ 4+ 2+
1375.815 7	5+	0.21 ns 6	112.778 3 203.438 5 835.85 7 1115.54 5	25 1 100 2 10 2 9.3 10	M1+E2 E2 M1+E2 E2	1263.028 1172.385 539.977 260.268	4+ 3+ 6+ 4+
1510.179 8	6+		134.363 18 247.155 6 969.81 18	10.5 7 100 4 6.9 5	M1+E2 E2	1375.815 1263.028 539.977	5+ 4+ 6+
1666.12 5	(7+)		155.99 8 290.28 6	15.5 17 100 5	(E2)	1510.179 1375.815	6+ 5+
1841.84 8	(8+)		175.2 3 331.67 8	100 4	(E2)	1666.12 1510.179	(7+) 6+
2039.38 22	(9+)		197.2 3 373.6 3	100	(E2)	1841.84 1666.12	(8+) (7+)
2256.3 3	(10+)		414.5 3	100		1841.84	(8+)
2492.2 4	(11+)		452.8 3	100	(E2)	2039.38	(9+)
2746.5 5	(12+)		490.2 3	100		2256.3	(10+)
3020.0 5	(13+)		527.8 3	100		2492.2	(11+)
3309.5 6	(14+)		563.0 3	100		2746.5	(12+)
E(level) (keV)	J^π(level)	T_1/2(level)	E(γ)	I(γ)	M(γ)	Final Levels
Band 5 - K^π=0⁺ band.
1405.008 6	0+	0.42 ns 6
1476.784 17	2+	48 ps 11	321.82 11 358.86 6 1216.35 11 1397.92 5 1476.77 7	0.60 16 1.22 15 12 2 100 3 36 1	E1 (E2) M1+E2(+E0) E2	1154.935 1117.874 260.268 78.7427 0.0	1- 2+ 4+ 2+ 0+
1633.14 6	(4)+		1372.88 6 1554.38 15	100 5 27 4	M1,E2 M1,E2	260.268 78.7427	4+ 2+
E(level) (keV)	J^π(level)	T_1/2(level)	E(γ)	I(γ)	M(γ)	Final Levels
Band 6 - K^π=2⁺ γ band
1465.875 4	2+	0.47 ps 3
1549.150 16	3+		286.30 20 431.29 8 1288.82 3 1470.42 3	0.34 6 0.32 3 29 1 100 3	(M1) (M1) M1+E2 M1+E2	1263.028 1117.874 260.268 78.7427	4+ 2+ 4+ 2+
1657.790 24	(4)+	0.05 ps 3	1397.50 3 1578.87 12	100 10 55 10	M1+E2 E2	260.268 78.7427	4+ 2+
1778.86 5	5+		1238.73 8 1518.68 6	100 12 79 6	M1(+E2) M1,E2	539.977 260.268	6+ 4+
E(level) (keV)	J^π(level)	T_1/2(level)	E(γ)	I(γ)	M(γ)	Final Levels
Band 7 - K^π=(6-) band.
1550.43 6	6-	3.6 µs 1
1670.55 11	(7-)		120.21 10	100	D+Q	1550.43	6-
1810.32 12	(8-)		139.87 6 259.3 3	100 10 11 1	D+Q	1670.55 1550.8	(7-)
1968.20 14	(9-)		157.92 8 297.1 3	100 9 29 3	D+Q	1810.32 1670.55	(8-) (7-)
2145.03 22	(10-)		176.9 3 334.8 3	100 8 47 5	(E2)	1968.20 1810.32	(9-) (8-)
2340.7 3	(11-)		195.7 3 372.3 3	100 8 60 8		2145.03 1968.20	(10-) (9-)
2554.2 3	(12-)		213.6 3 409.3 3	100 14 100 14		2340.7 2145.03	(11-) (10-)
2786.8 4	(13-)		232.7 3 446.0 3	50 10 100 20		2554.2 2340.7	(12-) (11-)
3034.2 4	(14-)		247.4 3 480.0 3	40 20 100 40		2786.8 2554.2	(13-) (12-)
E(level) (keV)	J^π(level)	T_1/2(level)	E(γ)	I(γ)	M(γ)	Final Levels
Band 8 - K^π=0- octupole band.
1599.870 12	1-	11 fs 3
1710.480 18	3(-)		538.126 23 1450.24 7 1631.67 6	9.1 6 59 7 100 7	D D	1172.385 260.268 78.7427	3+ 4+ 2+
E(level) (keV)	J^π(level)	T_1/2(level)	E(γ)	I(γ)	M(γ)	Final Levels
Band 9 - K^π=2⁺ band.
1608.490 11	2+	1.1 ps 2
1700.639 9	3+		151.55 6 437.60 2 528.260 14 1440.38 3 1621.92 3	0.99 17 5.8 2 100 2 14.8 5 53 1	[M1,E2] M1(+E2) M1(+E2) E2+M1 E2+M1	1549.150 1263.028 1172.385 260.268 78.7427	3+ 4+ 3+ 4+ 2+
1803.108 8	4+		145.21 5 162.20 25 ? 337.85 9 427.19 5 540.187 16 630.706 17 1263.16 9 1542.850 23 1724.35 3	2.6 5 3.3 5 8.8 5 100 3 31 1 3.1 4 73 2 31 1	M1(+E2) (E2) M1+E2 M1(+E2) M1(+E2) (E2) E2(+M1) E2	1657.790 1640.557 1465.875 1375.815 1263.028 1172.385 539.977 260.268 78.7427	(4)+ 4- 2+ 5+ 4+ 3+ 6+ 4+ 2+
1927.016 12	5+		416.65 8 551.078 19 664.07 5 1387.18 2 1666.38 20	<21 100 4 26 2 <30 68 2	M1(+E2) M1+E2 M1(+E2) E2+M1	1510.179 1375.815 1263.028 539.977 260.268	6+ 5+ 4+ 6+ 4+
2075.27 11	(6+)		565.6 3 1535.18 12 1815.2 3	72 19 100 10 38 6		1510.179 539.977 260.268	6+ 6+ 4+
E(level) (keV)	J^π(level)	T_1/2(level)	E(γ)	I(γ)	M(γ)	Final Levels
Band 10 - K^π=(4-) band.
1640.557 8	4-	0.5 ns 2
1706.447 13	5-		65.8 3 196.38 4 330.619 21 443.29 4 1166.50 5 1446.20 6	6 3 19 1 100 5 26 1 13 1 6.6 6	[M1,E2] (E1) E1(+M2) E1 E1	1640.557 1510.179 1375.815 1263.028 539.977 260.268	4- 6+ 5+ 4+ 6+ 4+
1802.65 5	6-		95.9 3 161.8 3 292.2 3 426.5 3	17 6 11 6 100 11 50 11	D+Q D+Q	1706.447 1640.557 1510.179 1375.815	5- 4- 6+ 5+
1921.80 20	(7-)		119.3 5 215.4 5 255.7 5 411.4 5	33 8 100 17 42 8 92 17		1802.65 1706.447 1666.12 1510.179	6- 5- (7+) 6+
2064.04 20	(8-)		142.3 3 261.6 3 397.7 3	28 6 100 11 17 6		1921.80 1802.65 1666.12	(7-) 6- (7+)
2225.3 3	9-		161.3 3 303.4 3	25 6 100 19		2064.04 1921.80	(8-) (7-)
2411.4 3	(10-)		186.2 3 347.4 3	13 6 100 13		2225.3 2064.04	9- (8-)
2609.2 4	(11-)		383.9 3	100	(E2)	2225.3	9-
2840.8 5	(12-)		429.4 3	100	(E2)	2411.4	(10-)
E(level) (keV)	J^π(level)	T_1/2(level)	E(γ)	I(γ)	M(γ)	Final Levels
Band 11 - K^π=3⁺ band.
1662.810 8	3+
1749.205 9	4+		200.5 4 373? 486.160 18 576.835 18 1209.13 10 1488.94 3 1670.49 3	<4 58 3 26.3 12 4.5 4 100 2 46 1	E2 M1+E2 M1+E2 (E2) E2(+M1) E2	1549.150 1375.815 1263.028 1172.385 539.977 260.268 78.7427	3+ 5+ 4+ 3+ 6+ 4+ 2+
1862.799 15	(5)+		200.5 4 352.55 4 599.86 4 1322.66 9 1602.54 3	<17 21 3 46 6 33 3 100 3	E2 E2(+M1) E2+M1 E2(+M1) E2(+M1)	1662.810 1510.179 1263.028 539.977 260.268	3+ 6+ 4+ 6+ 4+
2007.98 14	(6+)		350.65 20 1468.42 25 1746.58 25	100 11 80 7 38 4		1657.790 539.977 260.268	(4)+ 6+ 4+
E(level) (keV)	J^π(level)	T_1/2(level)	E(γ)	I(γ)	M(γ)	Final Levels
Band 12 - K^π=2- octupole band
1757.367 5	(2)-
1821.583 9	3-		272.31 3 490 1 599.862 19 623.114 7 649.26 3 666.08 12 1743.27 15	10 5 11 1 18 2 10 1 30 6 100 14		1549.150 1330.693 1221.720 1198.472 1172.385 1154.935 78.7427	3+ 4- 3- 2- 3+ 1- 2+
E(level) (keV)	J^π(level)	T_1/2(level)	E(γ)	I(γ)	M(γ)	Final Levels
Band 13 - K^π=0⁺ band
1794.08 5	0+	< 0.15 ns
1849.173 22	2+	0.8 ps 5	1589.03 7 1770.9 4 1849.06 3	51 5 100 7 63 4	M1+E2+E0 (E2)	260.268 78.7427 0.0	4+ 2+ 0+
1975.63 14	(4+)		1435.23 25 1714.95 25 1897.42 20	36 6 100 19 53 6		539.977 260.268 78.7427	6+ 4+ 2+
2156.43 3	(6+)		1616.45 3	100		539.977	6+
E(level) (keV)	J^π(level)	T_1/2(level)	E(γ)	I(γ)	M(γ)	Final Levels
Band 14 - K^π=0⁺ band
1894.616 25	0+	< 0.15 ns
1956.351 25	2+	0.29 ps 15	734.77 4 839.4 4 1696.00 10 1877.89 16 1956.90 18	6.7 13 6.43 16 81 5 100 9 75 9	M1+E2+E0 [E2]	1221.720 1117.874 260.268 78.7427 0.0	3- 2+ 4+ 2+ 0+
2100.22 17	(4+)		1560.09 20 1840.3 3	48 19 100 19		539.977 260.268	6+ 4+
E(level) (keV)	J^π(level)	T_1/2(level)	E(γ)	I(γ)	M(γ)	Final Levels
Band 15 - K^π=(1⁺) band.
2009.80 3	1+
2046.99 3	(2)+		90.645 4 892.11 4 1787.85 20 1968.19 9	16 3 6.0 4 44 5 100 20	E2	1956.351 1154.935 260.268 78.7427	2+ 1- 4+ 2+
2108 5	(3+)
2193.16 12	(4+)		816.95 25 930.13 16 1653.64 25	23 8 100 8 75 14		1375.815 1263.028 539.977	5+ 4+ 6+
E(level) (keV)	J^π(level)	T_1/2(level)	E(γ)	I(γ)	M(γ)	Final Levels
Band 16 - K^π=(4⁺) band.
2073.114 7	4+
2192.130 11	5+		119.023 15 329.39 5 389.44 5 413.2 3 534.29 7 681.82 4 816.327 20 929.106 20 1019.79 4 1652.32 10 1931.76 7	1.0 2 4.5 4 2.3 3 1.2 5 4.1 6 22.8 8 37.8 8 100.0 23 3.8 3 0.47 10 1.23 12	[M1,E2] M1(+E2) [M1,E2] M1(+E2) M1+E2 M1+E2 M1+E2 (E2) (M1,E2)	2073.114 1862.799 1802.65 1778.86 1657.790 1510.179 1375.815 1263.028 1172.385 539.977 260.268	4+ (5)+ 6- 5+ (4)+ 6+ 5+ 4+ 3+ 6+ 4+
2333 5	(6+)
E(level) (keV)	J^π(level)	T_1/2(level)	E(γ)	I(γ)	M(γ)	Final Levels
Band 17 - K^π=(3⁺) band MEMBER
2175.059 12	3+
2285.399 11	4+		358.45 3 422.61 3 482.23 4 536.194 19 584.725 17 622.605 22 644.86 6 909.70 6 1022.370 21 1113.05 5 2024.9 3 2206.72 15 ?	7.3 4 8.3 4 35 2 39 2 20.7 6 9.7 7 7.1 6 39 3 85 2 100 5 3.4 4 0.5 3	M1+E2 (M1,E2) M1+E2 M1+E2 M1(+E2) M1(+E2) E2(+M1) M1+E2 M1+E2 M1(+E2) (E2)	1927.016 1862.799 1803.108 1749.205 1700.639 1662.810 1640.557 1375.815 1263.028 1172.385 260.268 78.7427	5+ (5)+ 4+ 4+ 3+ 3+ 4- 5+ 4+ 3+ 4+ 2+
E(level) (keV)	J^π(level)	T_1/2(level)	E(γ)	I(γ)	M(γ)	Final Levels
Band 18 - K^π=(5-) band.
2180 5	(6-)
2346 5	(7-)
2545 5	(8-)
2741 5	(9-)
E(level) (keV)	J^π(level)	T_1/2(level)	E(γ)	I(γ)	M(γ)	Final Levels
Band 19 - K^π=(1⁺) band
2194.331 14	(1+)
2228.63 4	2+		272.31 3 565.02 3 ? 1185.60 12 1968.19 9	3.8 21 14.4 9 12.1 4 100 20		1956.351 1662.810 1042.914 260.268	2+ 3+ 0+ 4+
E(level) (keV)	J^π(level)	T_1/2(level)	E(γ)	I(γ)	M(γ)	Final Levels
Band 20 - K^π=(4⁺) band
2343.715 15	4+
E(level) (keV)	J^π(level)	T_1/2(level)	E(γ)	I(γ)	M(γ)	Final Levels
Band 21 - K^π=(4⁺) band.
2599.7 5	(4+)
2697 5	(5+)
2818.5 7	(6+)
E(level) (keV)	J^π(level)	T_1/2(level)	E(γ)	I(γ)	M(γ)	Final Levels
Band 22 - K^π=(9-) band.
2689.8 4	(9-)	0.7 ns 1
2856.4 5	(10-)		166.6 3	100		2689.8	(9-)
3044.5 6	(11-)		188.1 3	100		2856.4	(10-)
3252.9 7	(12-)		208.4 3	100		3044.5	(11-)
3481.6 8	(13-)		228.7 3	100		3252.9	(12-)
E(level) (keV)	J^π(level)	T_1/2(level)	E(γ)	I(γ)	M(γ)	Final Levels
Band 23 - K^π=(8⁺) band.
2787 5	(8+)

E(level)	J^π(level)	T_1/2(level)	Comments
0.0	0+	STABLE	E(level): The least-squares fit gives a poor fit for this transition. The fitted value (level energy difference) deviates up to about four times the quoted uncertainty. K^π=0⁺ GS band.
78.7427	2+	1.65 ns 5	μ=+0.669 16 (1989Ra17,1968Mu01), Q=2.16 37 (1989Ra17,1970WaZS) B(E2)(IS)=7.5 9 (α,α’). E(level): The least-squares fit gives a poor fit for this transition. The fitted value (level energy difference) deviates up to about four times the quoted uncertainty. K^π=0⁺ GS band.
260.268	4+	0.122 ns 8	μ=+1.37 5 (1989Ra17,1972Be94), Q=-2.3 12 (1989Ra17,1970McZQ) B(E4)(IS)<0.010 (α,α’). B(E4)=0.05 +7-4 (Coul. ex.). E(level): The least-squares fit gives a poor fit for this transition. The fitted value (level energy difference) deviates up to about four times the quoted uncertainty. K^π=0⁺ GS band.
539.977	6+	16.6 ps 15	B(E6)(IS)<0.086 (α,α’). E(level): The least-squares fit gives a poor fit for this transition. The fitted value (level energy difference) deviates up to about four times the quoted uncertainty. K^π=0⁺ GS band.
912.12	8+	3.5 ps 3	E(level): The least-squares fit gives a poor fit for this transition. The fitted value (level energy difference) deviates up to about four times the quoted uncertainty. K^π=0⁺ GS band.
1042.914	0+	3.3 ps 9	E(level): K^π=0⁺ BETA-BAND.
1117.874	2+	3.7 ps 4	B(E2)(IS)=0.0015 5 (α,α’). E(level): K^π=0⁺ BETA-BAND.
1154.935	1-		E(level): K^π=1- octupole band.
1172.385	3+	8.14 ns 17	μ=+0.65 4 (1989Ra17,1965Gu01), Q=2.87 41 (1989Ra17,1970Wa25) E(level): K^π=3⁺ band.
1198.472	2-		E(level): K^π=1- octupole band.
1221.720	3-		β₃=0.0132; B(E3)(IS)=0.016 3 (α,α’). E(level): β₃=0.0132; B(E3)(IS)=0.016 3 (α,α’). K^π=1- octupole band.
1263.028	4+	0.49 ns 3	B(E4)(IS)=0.036 7 (α,α’). E(level): K^π=3⁺ band.
1286.54	4+		E(level): K^π=0⁺ BETA-BAND.
1330.693	4-		E(level): K^π=1- octupole band.
1352.95	(5-)		E(level): K^π=1- octupole band.
1370.07	10+	1.32 ps 8	E(level): The least-squares fit gives a poor fit for this transition. The fitted value (level energy difference) deviates up to about four times the quoted uncertainty. K^π=0⁺ GS band.
1375.815	5+	0.21 ns 6	ΔJ=2, E2 γ to 3⁺ and γ’s to 4⁺ and 6⁺. E(level): K^π=3⁺ band.
1405.008	0+	0.42 ns 6	E(level): K^π=0⁺ band.
1465.875	2+	0.47 ps 3	B(E2)(IS)=0.041 9 (α,α’). E(level): K^π=2⁺ γ band.
1476.784	2+	48 ps 11	E(level): K^π=0⁺ band.
1510.179	6+		E(level): K^π=3⁺ band.
1537.50	6+		E(level): K^π=0⁺ BETA-BAND.
1540.61	6-		E(level): K^π=1- octupole band.
1549.150	3+		E(level): K^π=2⁺ γ band.
1550.43	6-	3.6 µs 1	E(level): K^π=(6-) band.
E(level)	J^π(level)	T_1/2(level)	Comments
1557.58	7-		E(level): K^π=1- octupole band.
1599.870	1-	11 fs 3	B(E1)(\|^)=10.7×10^-5 32 (γ,γ’). E(level): K^π=0- octupole band.
1608.490	2+	1.1 ps 2	XREF: n(1604). E(level): K^π=2⁺ band.
1633.14	(4)+		E(level): K^π=0⁺ band.
1640.557	4-	0.5 ns 2	E(level): K^π=(4-) band.
1657.790	(4)+	0.05 ps 3	B(E4)(IS)=0.006 2 (α,α’). E(level): K^π=2⁺ γ band.
1662.810	3+		E(level): K^π=3⁺ band.
1666.12	(7+)		E(level): K^π=3⁺ band.
1670.55	(7-)		E(level): K^π=(6-) band.
1700.639	3+		E(level): K^π=2⁺ band.
1706.447	5-		E(level): K^π=(4-) band.
1710.480	3(-)		β₃=0.0092; B(E3)(IS)=0.0078 16 (α,α’). B(E3)=0.025 6 (Coul. ex.). E(level): K^π=0- octupole band.
1749.205	4+		E(level): K^π=3⁺ band.
1757.367	(2)-		Q=-3.44 10 (1989Ra17,1979Ho23) E(level): K^π=2- octupole band.
1778.86	5+		E(level): K^π=2⁺ γ band.
1794.08	0+	< 0.15 ns	XREF: n(1791). E(level): K^π=0⁺ band.
1802.65	6-		E(level): K^π=(4-) band.
1803.108	4+		B(E4)(IS)\|<0.012 (α,α’). E(level): K^π=2⁺ band.
1810.32	(8-)		E(level): K^π=(6-) band.
1821.583	3-		Q=1.97 10 (1989Ra17,1979Ho23) β₃=0.023; B(E3)(IS)=0.065 13 (α,α’). B(E3)=0.033 7 (Coul. ex.). E(level): K^π=2- octupole band.
1828.76	8-		XREF: M(1838). E(level): K^π=1- octupole band.
1839.80	9-		E(level): K^π=1- octupole band.
1841.84	(8+)		E(level): K^π=3⁺ band.
1849.173	2+	0.8 ps 5	XREF: R(1853). E(level): K^π=0⁺ band.
1853.46	8+		E(level): K^π=0⁺ BETA-BAND.
E(level)	J^π(level)	T_1/2(level)	Comments
1862.799	(5)+		E(level): K^π=3⁺ band.
1887			XREF: M(1879).
1894.616	0+	< 0.15 ns	XREF: n(1892). E(level): K^π=0⁺ band.
1907.48	(12+)	0.52 ps 7	E(level): The least-squares fit gives a poor fit for this transition. The fitted value (level energy difference) deviates up to about four times the quoted uncertainty. K^π=0⁺ GS band.
1919.84	(5,6)		XREF: M(1916).
1921.80	(7-)		Population in (d,t) is uncertain. E(level): K^π=(4-) band.
1927.016	5+		E(level): K^π=2⁺ band.
1956.351	2+	0.29 ps 15	E(level): K^π=0⁺ band.
1968.20	(9-)		E(level): K^π=(6-) band.
1975.63	(4+)		E(level): K^π=0⁺ band.
2007.98	(6+)		E(level): K^π=3⁺ band.
2009.80	1+		XREF: L(2009)M(2007). E(level): K^π=(1⁺) band.
2030	3-		β₃=0.0194; B(E3)(IS)=0.058 12 (α,α’).
2039.38	(9+)		E(level): K^π=3⁺ band.
2046.99	(2)+		XREF: M(2055)n(2041). E(level): K^π=(1⁺) band.
2064.04	(8-)		E(level): K^π=(4-) band.
2073.114	4+		XREF: n(2060). E(level): K^π=(4⁺) band.
2075.27	(6+)		XREF: L(2075). E(level): K^π=2⁺ band.
2100.22	(4+)		XREF: n(2098). E(level): K^π=0⁺ band.
2108	(3+)		E(level): K^π=(1⁺) band.
2115.8	(0-,1-,2-)		XREF: F(2121)L(2119).
2145.03	(10-)		E(level): K^π=(6-) band.
2156.43	(6+)		E(level): K^π=0⁺ band.
2175.059	3+		E(level): K^π=(3⁺) band MEMBER.
2180	(6-)		E(level): K^π=(5-) band.
E(level)	J^π(level)	T_1/2(level)	Comments
2184	(2+)		XREF: R(2177).
2192.130	5+		E(level): K^π=(4⁺) band.
2193.02	(10-)		E(level): K^π=1- octupole band.
2193.16	(4+)		XREF: L(2193). E(level): K^π=(1⁺) band.
2194.331	(1+)		XREF: H(2192.8). E(level): K^π=(1⁺) band.
2199.47	(11-)		E(level): K^π=1- octupole band.
2210	1(-)	4.6 fs 9	B(E1)(\|^)=10.5×10^-5 20 (γ,γ’). J^π(level): Spin is from γγ(θ) data in (γ,γ’). Parity is from a comparison of reduced transition probabilities with Alaga’s rules. T_1/2(level) is deduced from Γ_γ0 (1990Zi01) and branching ratio. It is assumed that the level deexcites only to g.s. and first 2⁺ level. T_1/2(level): Spin is from γγ(θ) data in (γ,γ’). Parity is from a comparison of reduced transition probabilities with Alaga’s rules. T_1/2(level) is deduced from Γ_γ0 (1990Zi01) and branching ratio. It is assumed that the level deexcites only to g.s. and first 2⁺ level.
2212.52	(10+)		E(level): K^π=0⁺ BETA-BAND.
2225.3	9-		E(level): K^π=(4-) band.
2228.63	2+		E(level): K^π=(1⁺) band.
2255	(2+)		XREF: M(2249).
2256.3	(10+)		E(level): K^π=3⁺ band.
2285.399	4+		E(level): K^π=(3⁺) band MEMBER.
2333	(6+)		XREF: n(2337). E(level): K^π=(4⁺) band.
2340.7	(11-)		E(level): K^π=(6-) band.
2343.715	4+		E(level): K^π=(4⁺) band.
2346	(7-)		E(level): K^π=(5-) band.
2356.59	(0-,1-,2-)		XREF: L(2360).
2367	(2+)		XREF: n(2364).
2387.706	(1+,2+)		XREF: n(2396).
2404.8	(0-,1-,2-)		XREF: O(2409).
2411.4	(10-)		E(level): K^π=(4-) band.
2464.09	(2+)		B(E2)(IS)=0.010 2 (α,α’).
2480.037	(1+,2+)		XREF: L(2476).
2492.2	(11+)		E(level): K^π=3⁺ band.
E(level)	J^π(level)	T_1/2(level)	Comments
2518.7	(14+)	0.29 ps 4	E(level): The least-squares fit gives a poor fit for this transition. The fitted value (level energy difference) deviates up to about four times the quoted uncertainty. K^π=0⁺ GS band.
2534.9	(0+)		XREF: n(2540).
2545	(8-)		E(level): K^π=(5-) band.
2554.2	(12-)		E(level): K^π=(6-) band.
2573	1	12 fs 3	B(E1)(\|^)=4.3×10^-5 11. B(M1)(\|^)=0.93 10. J^π(level): Spin is from γγ(θ) data in (γ,γ’). Parity is from a comparison of reduced transition probabilities with Alaga’s rules. T_1/2(level) is deduced from Γ_γ0 (1990Zi01) and branching ratio. It is assumed that the level deexcites only to g.s. and first 2⁺ level. T_1/2(level): Spin is from γγ(θ) data in (γ,γ’). Parity is from a comparison of reduced transition probabilities with Alaga’s rules. T_1/2(level) is deduced from Γ_γ0 (1990Zi01) and branching ratio. It is assumed that the level deexcites only to g.s. and first 2⁺ level.
2575.6	(2+)		B(E2)(IS)=0.0034 7 (α,α’).
2599.7	(4+)		E(level): K^π=(4⁺) band.
2607.2	(12+)		E(level): K^π=0⁺ BETA-BAND.
2609.2	(11-)		E(level): K^π=(4-) band.
2612	1	12 fs 3	B(E1)(\|^)=3.6×10^-5 10. B(M1)(\|^)=0.33 9. J^π(level): Spin is from γγ(θ) data in (γ,γ’). Parity is from a comparison of reduced transition probabilities with Alaga’s rules. T_1/2(level) is deduced from Γ_γ0 (1990Zi01) and branching ratio. It is assumed that the level deexcites only to g.s. and first 2⁺ level. T_1/2(level): Spin is from γγ(θ) data in (γ,γ’). Parity is from a comparison of reduced transition probabilities with Alaga’s rules. T_1/2(level) is deduced from Γ_γ0 (1990Zi01) and branching ratio. It is assumed that the level deexcites only to g.s. and first 2⁺ level.
2627.9			XREF: L(2622).
2629.8	(12-)		E(level): K^π=1- octupole band.
2636.1	(13-)		E(level): K^π=1- octupole band.
2650.0	(2+)		B(E2)(IS)=0.0038 8 (α,α’).
2689.8	(9-)	0.7 ns 1	E(level): K^π=(9-) band.
2697	(5+)		E(level): K^π=(4⁺) band.
2738	(2+)		B(E2)(IS)=0.012 3 (α,α’).
2741	(9-)		E(level): K^π=(5-) band.
2746.5	(12+)		E(level): K^π=3⁺ band.
2786.8	(13-)		E(level): K^π=(6-) band.
2787	(8+)		E(level): K^π=(8⁺) band.
2818.5	(6+)		E(level): K^π=(4⁺) band.
2834.6	(2+)		XREF: J(2836).
2840.8	(12-)		E(level): K^π=(4-) band.
2856.4	(10-)		E(level): K^π=(9-) band.
E(level)	J^π(level)	T_1/2(level)	Comments
2887.3	(2+)		B(E2)(IS)=0.017 4 (α,α’).
2943.0			XREF: L(2936).
2991.7	(2+)		B(E2)(IS)=0.0087 17 (α,α’).
3002	1	8.7 fs 24	B(E1)(\|^)=3.7×10^-5 10; B(M1)(\|^)=0.34 9 (in γ,γ’). J^π(level): Spin is from γγ(θ) data in (γ,γ’). Parity is from a comparison of reduced transition probabilities with Alaga’s rules. T_1/2(level) is deduced from Γ_γ0 (1990Zi01) and branching ratio. It is assumed that the level deexcites only to g.s. and first 2⁺ level. T_1/2(level): Spin is from γγ(θ) data in (γ,γ’). Parity is from a comparison of reduced transition probabilities with Alaga’s rules. T_1/2(level) is deduced from Γ_γ0 (1990Zi01) and branching ratio. It is assumed that the level deexcites only to g.s. and first 2⁺ level.
3017	1	18 fs 9	B(E1)(\|^)=1.0×10^-5 5 or B(E1)(\|^)=1.2×10^-5 5; B(M1)(\|^)=0.11 4. J^π(level): Spin is from γγ(θ) data in (γ,γ’). Parity is from a comparison of reduced transition probabilities with Alaga’s rules. T_1/2(level) is deduced from Γ_γ0 (1990Zi01) and branching ratio. It is assumed that the level deexcites only to g.s. and first 2⁺ level. T_1/2(level): Spin is from γγ(θ) data in (γ,γ’). Parity is from a comparison of reduced transition probabilities with Alaga’s rules. T_1/2(level) is deduced from Γ_γ0 (1990Zi01) and branching ratio. It is assumed that the level deexcites only to g.s. and first 2⁺ level.
3020.0	(13+)		E(level): K^π=3⁺ band.
3034.2	(14-)		E(level): K^π=(6-) band.
3043.9	(14+)		E(level): K^π=0⁺ BETA-BAND.
3044.5	(11-)		E(level): K^π=(9-) band.
3058.0			XREF: M(3062).
3072	1(-)	6.1 fs 20	B(E1)(\|^)=3.2×10^-5 10 (γ,γ’). J^π(level): Spin is from γγ(θ) data in (γ,γ’). Parity is from a comparison of reduced transition probabilities with Alaga’s rules. T_1/2(level) is deduced from Γ_γ0 (1990Zi01) and branching ratio. It is assumed that the level deexcites only to g.s. and first 2⁺ level. T_1/2(level): Spin is from γγ(θ) data in (γ,γ’). Parity is from a comparison of reduced transition probabilities with Alaga’s rules. T_1/2(level) is deduced from Γ_γ0 (1990Zi01) and branching ratio. It is assumed that the level deexcites only to g.s. and first 2⁺ level.
3074.8			XREF: L(3072).
3096	1	17 fs 9	B(E1)(\|^)=0.9×10^-5 5 or B(E1)(\|^)=1.0×10^-5 4; B(M1)(\|^)=0.09 3. J^π(level): Spin is from γγ(θ) data in (γ,γ’). Parity is from a comparison of reduced transition probabilities with Alaga’s rules. T_1/2(level) is deduced from Γ_γ0 (1990Zi01) and branching ratio. It is assumed that the level deexcites only to g.s. and first 2⁺ level. T_1/2(level): Spin is from γγ(θ) data in (γ,γ’). Parity is from a comparison of reduced transition probabilities with Alaga’s rules. T_1/2(level) is deduced from Γ_γ0 (1990Zi01) and branching ratio. It is assumed that the level deexcites only to g.s. and first 2⁺ level.
3118	1(-)	8 fs 4	B(E1)(\|^)=2.2×10^-5 10. J^π(level): Spin is from γγ(θ) data in (γ,γ’). Parity is from a comparison of reduced transition probabilities with Alaga’s rules. T_1/2(level) is deduced from Γ_γ0 (1990Zi01) and branching ratio. It is assumed that the level deexcites only to g.s. and first 2⁺ level. T_1/2(level): Spin is from γγ(θ) data in (γ,γ’). Parity is from a comparison of reduced transition probabilities with Alaga’s rules. T_1/2(level) is deduced from Γ_γ0 (1990Zi01) and branching ratio. It is assumed that the level deexcites only to g.s. and first 2⁺ level.
3130.6			XREF: L(3127).
3134.6	(14-)		E(level): K^π=1- octupole band.
3141.3			XREF: L(3138).
3160	1(-)	3.4 fs 10	B(E1)(\|^)=4.3×10^-5 13. J^π(level): Spin is from γγ(θ) data in (γ,γ’). Parity is from a comparison of reduced transition probabilities with Alaga’s rules. T_1/2(level) is deduced from Γ_γ0 (1990Zi01) and branching ratio. It is assumed that the level deexcites only to g.s. and first 2⁺ level. T_1/2(level): Spin is from γγ(θ) data in (γ,γ’). Parity is from a comparison of reduced transition probabilities with Alaga’s rules. T_1/2(level) is deduced from Γ_γ0 (1990Zi01) and branching ratio. It is assumed that the level deexcites only to g.s. and first 2⁺ level.
3174	1(-)	3.7 fs 11	B(E1)(\|^)=3.4×10^-5 10. J^π(level): Spin is from γγ(θ) data in (γ,γ’). Parity is from a comparison of reduced transition probabilities with Alaga’s rules. T_1/2(level) is deduced from Γ_γ0 (1990Zi01) and branching ratio. It is assumed that the level deexcites only to g.s. and first 2⁺ level. T_1/2(level): Spin is from γγ(θ) data in (γ,γ’). Parity is from a comparison of reduced transition probabilities with Alaga’s rules. T_1/2(level) is deduced from Γ_γ0 (1990Zi01) and branching ratio. It is assumed that the level deexcites only to g.s. and first 2⁺ level.
3198.4	(16+)		E(level): The least-squares fit gives a poor fit for this transition. The fitted value (level energy difference) deviates up to about four times the quoted uncertainty. K^π=0⁺ GS band.
3246	1(-)	5.6 fs 23	B(E1)(\|^)=2.9×10^-5 12. J^π(level): Spin is from γγ(θ) data in (γ,γ’). Parity is from a comparison of reduced transition probabilities with Alaga’s rules. T_1/2(level) is deduced from Γ_γ0 (1990Zi01) and branching ratio. It is assumed that the level deexcites only to g.s. and first 2⁺ level. T_1/2(level): Spin is from γγ(θ) data in (γ,γ’). Parity is from a comparison of reduced transition probabilities with Alaga’s rules. T_1/2(level) is deduced from Γ_γ0 (1990Zi01) and branching ratio. It is assumed that the level deexcites only to g.s. and first 2⁺ level.
3252.9	(12-)		E(level): K^π=(9-) band.
3253	1	12 fs 4	B(E1)(\|^)=2.1×10^-5 7. B(M1)(\|^)=0.19 6. J^π(level): Spin is from γγ(θ) data in (γ,γ’). Parity is from a comparison of reduced transition probabilities with Alaga’s rules. T_1/2(level) is deduced from Γ_γ0 (1990Zi01) and branching ratio. It is assumed that the level deexcites only to g.s. and first 2⁺ level. T_1/2(level): Spin is from γγ(θ) data in (γ,γ’). Parity is from a comparison of reduced transition probabilities with Alaga’s rules. T_1/2(level) is deduced from Γ_γ0 (1990Zi01) and branching ratio. It is assumed that the level deexcites only to g.s. and first 2⁺ level.
3309.5	(14+)		E(level): K^π=3⁺ band.
3393	1(-)	2.7 fs 7	B(E1)(\|^)=4.5×10^-5 11. J^π(level): Spin is from γγ(θ) data in (γ,γ’). Parity is from a comparison of reduced transition probabilities with Alaga’s rules. T_1/2(level) is deduced from Γ_γ0 (1990Zi01) and branching ratio. It is assumed that the level deexcites only to g.s. and first 2⁺ level. T_1/2(level): Spin is from γγ(θ) data in (γ,γ’). Parity is from a comparison of reduced transition probabilities with Alaga’s rules. T_1/2(level) is deduced from Γ_γ0 (1990Zi01) and branching ratio. It is assumed that the level deexcites only to g.s. and first 2⁺ level.
E(level)	J^π(level)	T_1/2(level)	Comments
3481.6	(13-)		E(level): K^π=(9-) band.
3545	1(-)	1.6 fs 5	B(E1)(\|^)=5.1×10^-5 17. J^π(level): Spin is from γγ(θ) data in (γ,γ’). Parity is from a comparison of reduced transition probabilities with Alaga’s rules. T_1/2(level) is deduced from Γ_γ0 (1990Zi01) and branching ratio. It is assumed that the level deexcites only to g.s. and first 2⁺ level. T_1/2(level): Spin is from γγ(θ) data in (γ,γ’). Parity is from a comparison of reduced transition probabilities with Alaga’s rules. T_1/2(level) is deduced from Γ_γ0 (1990Zi01) and branching ratio. It is assumed that the level deexcites only to g.s. and first 2⁺ level.
3604	1	2.9 fs 8	B(E1)(\|^)=5.4×10^-5 14. B(M1)(\|^)=0.49 12. J^π(level): Spin is from γγ(θ) data in (γ,γ’). Parity is from a comparison of reduced transition probabilities with Alaga’s rules. T_1/2(level) is deduced from Γ_γ0 (1990Zi01) and branching ratio. It is assumed that the level deexcites only to g.s. and first 2⁺ level. T_1/2(level): Spin is from γγ(θ) data in (γ,γ’). Parity is from a comparison of reduced transition probabilities with Alaga’s rules. T_1/2(level) is deduced from Γ_γ0 (1990Zi01) and branching ratio. It is assumed that the level deexcites only to g.s. and first 2⁺ level.
3635	1(-)	1.3 fs 3	B(E1)(\|^)=8.1×10^-5 19. J^π(level): Spin is from γγ(θ) data in (γ,γ’). Parity is from a comparison of reduced transition probabilities with Alaga’s rules. T_1/2(level) is deduced from Γ_γ0 (1990Zi01) and branching ratio. It is assumed that the level deexcites only to g.s. and first 2⁺ level. T_1/2(level): Spin is from γγ(θ) data in (γ,γ’). Parity is from a comparison of reduced transition probabilities with Alaga’s rules. T_1/2(level) is deduced from Γ_γ0 (1990Zi01) and branching ratio. It is assumed that the level deexcites only to g.s. and first 2⁺ level.
3863	1	2.1 fs 6	B(E1)(\|^)=5.0×10^-5 15. B(M1)(\|^)=0.45 14. J^π(level): Spin is from γγ(θ) data in (γ,γ’). Parity is from a comparison of reduced transition probabilities with Alaga’s rules. T_1/2(level) is deduced from Γ_γ0 (1990Zi01) and branching ratio. It is assumed that the level deexcites only to g.s. and first 2⁺ level. T_1/2(level): Spin is from γγ(θ) data in (γ,γ’). Parity is from a comparison of reduced transition probabilities with Alaga’s rules. T_1/2(level) is deduced from Γ_γ0 (1990Zi01) and branching ratio. It is assumed that the level deexcites only to g.s. and first 2⁺ level.

E(level)	E(gamma)	Comments
1465.875	1387.093	E(γ): The least-squares fit gives a poor fit for this transition. The fitted value (level energy difference) deviates up to about four times the quoted uncertainty
1537.50	251.43	E(γ): The least-squares fit gives a poor fit for this transition. The fitted value (level energy difference) deviates up to about four times the quoted uncertainty
1662.810	399.750	E(γ): The least-squares fit gives a poor fit for this transition. The fitted value (level energy difference) deviates up to about four times the quoted uncertainty
1706.447	443.29	E(γ): The least-squares fit gives a poor fit for this transition. The fitted value (level energy difference) deviates up to about four times the quoted uncertainty
1749.205	200.5	E(γ): Multiply placed with undivided intensity I(γ): Multiply placed with undivided intensity
1757.367	602.472	E(γ): The least-squares fit gives a poor fit for this transition. The fitted value (level energy difference) deviates up to about four times the quoted uncertainty
1803.108	337.85	E(γ): The least-squares fit gives a poor fit for this transition. The fitted value (level energy difference) deviates up to about four times the quoted uncertainty
1803.108	540.187	E(γ): The least-squares fit gives a poor fit for this transition. The fitted value (level energy difference) deviates up to about four times the quoted uncertainty
1821.583	272.31	E(γ): The least-squares fit gives a poor fit for this transition. The fitted value (level energy difference) deviates up to about four times the quoted uncertainty
1821.583	666.08	E(γ): The least-squares fit gives a poor fit for this transition. The fitted value (level energy difference) deviates up to about four times the quoted uncertainty
1862.799	200.5	E(γ): Multiply placed with undivided intensity I(γ): Multiply placed with undivided intensity
1919.84	410.8	E(γ): The least-squares fit gives a poor fit for this transition. The fitted value (level energy difference) deviates up to about four times the quoted uncertainty
1927.016	416.65	E(γ): Multiply placed with undivided intensity I(γ): Multiply placed with undivided intensity
	551.078	E(γ): The least-squares fit gives a poor fit for this transition. The fitted value (level energy difference) deviates up to about four times the quoted uncertainty
	1387.18	E(γ): The least-squares fit gives a poor fit for this transition. The fitted value (level energy difference) deviates up to about four times the quoted uncertainty
1956.351	1956.90	E(γ): The least-squares fit gives a poor fit for this transition. The fitted value (level energy difference) deviates up to about four times the quoted uncertainty
2007.98	1746.58	E(γ): The least-squares fit gives a poor fit for this transition. The fitted value (level energy difference) deviates up to about four times the quoted uncertainty
2009.80	854.435	E(γ): The least-squares fit gives a poor fit for this transition. The fitted value (level energy difference) deviates up to about four times the quoted uncertainty
2009.80	892.11	E(γ): The least-squares fit gives a poor fit for this transition. The fitted value (level energy difference) deviates up to about four times the quoted uncertainty
2046.99	1787.85	E(γ): The least-squares fit gives a poor fit for this transition. The fitted value (level energy difference) deviates up to about four times the quoted uncertainty
2073.114	607.141	E(γ): The least-squares fit gives a poor fit for this transition. The fitted value (level energy difference) deviates up to about four times the quoted uncertainty
2076.172	610.963	E(γ): The least-squares fit gives a poor fit for this transition. The fitted value (level energy difference) deviates up to about four times the quoted uncertainty
2175.059	1634.78	E(γ): from (α,2nγ) only. It is suspect since a transition with ΔJ=3 is not expected
2176.20	1133.56	E(γ): The least-squares fit gives a poor fit for this transition. The fitted value (level energy difference) deviates up to about four times the quoted uncertainty
2194.331	585.71	E(γ): The least-squares fit gives a poor fit for this transition. The fitted value (level energy difference) deviates up to about four times the quoted uncertainty
2194.331	995.740	E(γ): The least-squares fit gives a poor fit for this transition. The fitted value (level energy difference) deviates up to about four times the quoted uncertainty
E(level)	E(gamma)	Comments
2214.06	746.598	E(γ): The least-squares fit gives a poor fit for this transition. The fitted value (level energy difference) deviates up to about four times the quoted uncertainty
2228.63	565.02	E(γ): The least-squares fit gives a poor fit for this transition. The fitted value (level energy difference) deviates up to about four times the quoted uncertainty
2341.86	2263.75	E(γ): The least-squares fit gives a poor fit for this transition. The fitted value (level energy difference) deviates up to about four times the quoted uncertainty
2343.715	416.65	E(γ): Multiply placed with undivided intensity I(γ): Multiply placed with undivided intensity
2343.715	540.187	E(γ): The least-squares fit gives a poor fit for this transition. The fitted value (level energy difference) deviates up to about four times the quoted uncertainty
2387.706	630.79	E(γ): Multiply placed with undivided intensity. The least-squares fit gives a poor fit for this transition. The fitted value (level energy difference) deviates up to about four times the quoted uncertainty I(γ): Multiply placed with undivided intensity
	1216.01	E(γ): The least-squares fit gives a poor fit for this transition. The fitted value (level energy difference) deviates up to about four times the quoted uncertainty
	1233.51	E(γ): The least-squares fit gives a poor fit for this transition. The fitted value (level energy difference) deviates up to about four times the quoted uncertainty
	1344.32	E(γ): The least-squares fit gives a poor fit for this transition. The fitted value (level energy difference) deviates up to about four times the quoted uncertainty
2480.037	585.71	E(γ): The least-squares fit gives a poor fit for this transition. The fitted value (level energy difference) deviates up to about four times the quoted uncertainty
	630.79	E(γ): Multiply placed with undivided intensity I(γ): Multiply placed with undivided intensity
	816.35	E(γ): The least-squares fit gives a poor fit for this transition. The fitted value (level energy difference) deviates up to about four times the quoted uncertainty
	1002.81	E(γ): The least-squares fit gives a poor fit for this transition. The fitted value (level energy difference) deviates up to about four times the quoted uncertainty
	1013.85	E(γ): The least-squares fit gives a poor fit for this transition. The fitted value (level energy difference) deviates up to about four times the quoted uncertainty
2607.3	1489.8	E(γ): The least-squares fit gives a poor fit for this transition. The fitted value (level energy difference) deviates up to about four times the quoted uncertainty