List of levels for 49CR

Author: T. W. Burrows | Citation: Nucl. Data Sheets 109, 1879 (2008) | Cutoff date: 14-Jul-2008

E(level) (keV)	J^π(level)	T_1/2(level)	E(γ) (keV)	Multipolarity	Mixing Ratio	Conversion Coefficient	Additional Data
271.72	7/2-	13 ps 3	271.78 19	M1+E2	-0.115 11	0.00219	B(E2)(W.u.)=36 11, B(M1)(W.u.)=0.083 20, α=0.00219 4, α(K)=0.00197 4, α(L)=0.000185 3, α(M)=2.44E-5 4, α(N)=9.06E-7 15, α(N+)=9.06E-7 15
1083.6	9/2-	0.15 ps 3	812.0 4	M1+E2	-0.21 3	0.000187	B(E2)(W.u.)=40 14, B(M1)(W.u.)=0.25 5, α=0.000187 3, α(K)=0.000169 3, α(L)=1.567E-5 24, α(M)=2.06E-6 3, α(N)=7.76E-8 12, α(N+)=7.76E-8 12
1083.6	9/2-	0.15 ps 3	1083.9 10	(E2)		0.0001280	B(E2)(W.u.)=14 4, α=0.0001280 18, α(K)=0.0001161 17, α(L)=1.074E-5 16, α(M)=1.413E-6 20, α(N)=5.30E-8 8, α(N+)=5.30E-8 8
1562.1	11/2-	0.391 ps 34	478.63 26	M1+E2	-0.058 23	5.70×10^-4	B(E2)(W.u.)=9 8, B(M1)(W.u.)=0.26 3, α=5.70E-4 9, α(K)=0.000515 8, α(L)=4.80E-5 7, α(M)=6.31E-6 10, α(N)=2.37E-7 4, α(N+)=2.37E-7 4
1562.1	11/2-	0.391 ps 34	1290.2 5	E2		0.0001130	B(E2)(W.u.)=18.5 19, α=0.0001130 16, α(K)=7.84E-5 11, α(L)=7.24E-6 11, α(M)=9.52E-7 14, α(N)=3.58E-8 5, α(N+)=2.65E-5 4
1703.2	1/2-	> 3.8 ps	1703.2 5	E2		0.000223	B(E2)(W.u.)<0.98, α=0.000223 4, α(K)=4.43E-5 7, α(L)=4.09E-6 6, α(M)=5.38E-7 8, α(N)=2.03E-8 3, α(N+)=0.0001736 25
1741.4	3/2-	1.1 ps 3	1469.3 5	E2		0.0001420	B(E2)(W.u.)=2.0 6, α=0.0001420 20, α(K)=5.95E-5 9, α(L)=5.50E-6 8, α(M)=7.23E-7 11, α(N)=2.72E-8 4, α(N+)=7.65E-5 11
1741.4	3/2-	1.1 ps 3	1741.3 5	(M1+E2)	+0.106 +18-36	0.000191	B(E2)(W.u.)=0.024 11, B(M1)(W.u.)=0.0027 8, α=0.000191 3, α(K)=3.90E-5 6, α(L)=3.59E-6 5, α(M)=4.72E-7 7, α(N)=1.783E-8 25, α(N+)=0.0001484 21
1981.8	3/2+	> 1.39 ps	240	(E1)		0.00243	B(E1)(W.u.)<0.00044, α=0.00243 4, α(K)=0.00220 3, α(L)=0.000204 3, α(M)=2.67E-5 4, α(N)=9.88E-7 14, α(N+)=9.88E-7 14
	3/2+	> 1.39 ps	278.1 7	(E1(+M2))		0.005	α=0.005 4, α(K)=0.005 4, α(L)=0.0005 4, α(M)=6.E-5 5, α(N)=2.3E-6 17, α(N+)=2.3E-6 17
	3/2+	> 1.39 ps	1709.5 5	(M2+E3)	-0.23 21	1.43×10^-4	B(E3)(W.u.)<2.2×10³, B(M2)(W.u.)<13, α=1.43E-4 4, α(K)=7.23E-5 11, α(L)=6.68E-6 10, α(M)=8.80E-7 13, α(N)=3.32E-8 5, α(N+)=6.28E-5 25
	3/2+	> 1.39 ps	1981.3 5	(E1+M2)		0.00042	α=0.00042 23, α(K)=3.6×10^-5 17, α(L)=3.3E-6 16, α(M)=4.4E-7 21, α(N)=1.7E-8 8, α(N+)=0.00038 25
2168.5	5/2	1.04 ps 35	2168.2 5	D+Q	-2.14 LT
2431.8	5/2+	0.66 ps 19	450.2 7	M1+E2	+0.21 9	0.00069	B(E2)(W.u.)=8.×10¹ 8, B(M1)(W.u.)=0.16 6, α=0.00069 4, α(K)=0.00062 4, α(L)=5.8E-5 4, α(M)=7.6E-6 5, α(N)=2.85E-7 16, α(N+)=2.85E-7 16
	5/2+	0.66 ps 19	690	(E1)		1.47×10^-4	B(E1)(W.u.)=7.E-5 3, α=1.47E-4 21, α(K)=0.0001328 19, α(L)=1.227E-5 18, α(M)=1.613E-6 23, α(N)=6.05E-8 9, α(N+)=6.05E-8 9
	5/2+	0.66 ps 19	2161	(E1)		0.000769	B(E1)(W.u.)=9.E-7 4, α=0.000769 11, α(K)=1.708E-5 24, α(L)=1.568E-6 22, α(M)=2.06E-7 3, α(N)=7.79E-9 11, α(N+)=0.000750 11
	5/2+	0.66 ps 19	2431.4 5	(E1(+M2))	+0.5 5	0.00081	B(E1)(W.u.)=2.1E-5 11, B(M2)(W.u.)=4 +7-4, α=0.00081 19, α(K)=1.9E-5 7, α(L)=1.7E-6 6, α(M)=2.3E-7 8, α(N)=9.E-9 3, α(N+)=0.00079 20
2500.1	13/2-	0.110 ps 18	937.4 7	(M1(+E2))	-0.03 4	0.0001380	B(E2)(W.u.)=(0.5 +15-5), B(M1)(W.u.)=(0.22 4), α=0.0001380 20, α(K)=0.0001245 18, α(L)=1.150E-5 17, α(M)=1.514E-6 22, α(N)=5.70E-8 8, α(N+)=5.70E-8 8
2500.1	13/2-	0.110 ps 18	1416.4 4	(E2)		0.0001300	B(E2)(W.u.)=8 4, α=0.0001300 19, α(K)=6.42E-5 9, α(L)=5.93E-6 9, α(M)=7.80E-7 11, α(N)=2.93E-8 5, α(N+)=5.92E-5 9
2502.6	7/2-	< 8 fs	2232.1 7	D(+Q)	-0.23 23
2502.6	7/2-	< 8 fs	2503.4 7	M1(+E2)	-0.11 10	4.92×10^-4	B(M1)(W.u.)>0.11, α=4.92×10^-4 8, α(K)=2.11E-5 3, α(L)=1.94E-6 3, α(M)=2.55E-7 4, α(N)=9.63E-9 14, α(N+)=0.000469 8
2578.1	1/2+		836.5 6	(E1)		9.67×10^-5	α=9.67×10^-5 14, α(K)=8.75E-5 13, α(L)=8.07E-6 12, α(M)=1.062E-6 15, α(N)=3.99E-8 6, α(N+)=3.99E-8 6
2578.1	1/2+		875.3 6	(E1)		8.81×10^-5	α=8.81×10^-5 13, α(K)=7.97E-5 12, α(L)=7.35E-6 11, α(M)=9.67E-7 14, α(N)=3.63E-8 6, α(N+)=3.63E-8 6
2613.1	3/2-	45 fs 14	2341.7 6	E2		0.000507	B(E2)(W.u.)=10 3, α=0.000507 8, α(K)=2.48E-5 4, α(L)=2.28E-6 4, α(M)=3.00E-7 5, α(N)=1.131E-8 16, α(N+)=0.000480 7
2613.1	3/2-	45 fs 14	2611.8 10	M1		0.000537	B(M1)(W.u.)=0.011 4, α=0.000537 8, α(K)=1.97×10^-5 3, α(L)=1.81E-6 3, α(M)=2.38E-7 4, α(N)=8.98E-9 13, α(N+)=0.000515 8
E(level) (keV)	J^π(level)	T_1/2(level)	E(γ) (keV)	Multipolarity	Mixing Ratio	Conversion Coefficient	Additional Data
2911.7	(7/2+)	0.52 ps 10	930	E2		0.000186	B(E2)(W.u.)=19 6, α=0.000186 3, α(K)=0.0001682 24, α(L)=1.559E-5 22, α(M)=2.05E-6 3, α(N)=7.67E-8 11, α(N+)=7.67E-8 11
2911.7	(7/2+)	0.52 ps 10	2640	E1		0.001060	B(E1)(W.u.)=1.6E-5 5, α=0.001060 15, α(K)=1.292E-5 18, α(L)=1.186E-6 17, α(M)=1.560E-7 22, α(N)=5.89E-9 9, α(N+)=0.001044 15
2978.7	(3/2+)	> 0.69 ps	810	(E1)		0.0001030	B(E1)(W.u.)<0.00022, α=0.0001030 15, α(K)=9.36E-5 14, α(L)=8.64E-6 12, α(M)=1.136E-6 16, α(N)=4.26E-8 6, α(N+)=4.26E-8 6
	(3/2+)	> 0.69 ps	997	(M1)		6.80×10^-5	B(M1)(W.u.)<0.0035, α=6.80×10^-5 10, α(K)=0.0001102 16, α(L)=1.017E-5 15, α(M)=1.339E-6 19, α(N)=5.05E-8 7, α(N+)=5.05E-8 7
	(3/2+)	> 0.69 ps	1237	(E1)		1.22×10^-4	B(E1)(W.u.)<3.9E-5, α=1.22E-4 2, α(K)=4.13E-5 6, α(L)=3.81E-6 6, α(M)=5.01E-7 7, α(N)=1.88E-8 3, α(N+)=7.77E-5 11
	(3/2+)	> 0.69 ps	2979	(E1)		0.001240	α=0.001240 18, α(K)=1.100×10^-5 16, α(L)=1.009E-6 15, α(M)=1.328E-7 19, α(N)=5.02E-9 7, α(N+)=0.001227 18
3190.1	15/2-	0.083 ps 21	690.2 4	(M1(+E2))	0.2 LT	2.60×10^-4	B(E2)(W.u.)<97, B(M1)(W.u.)>0.27, α=2.60E-4 5, α(K)=0.000236 5, α(L)=2.18E-5 4, α(M)=2.87E-6 6, α(N)=1.079E-7 20, α(N+)=1.079E-7 20
3190.1	15/2-	0.083 ps 21	1627.8 4	(E2)		0.000194	B(E2)(W.u.)=29 9, α=0.000194 3, α(K)=4.85E-5 7, α(L)=4.47E-6 7, α(M)=5.88E-7 9, α(N)=2.21E-8 4, α(N+)=0.0001404 20
3250.9	(5/2+)	0.139 ps 35	819	(M1)		1.81×10^-4	B(M1)(W.u.)=0.12 4, α=1.81×10^-4 3, α(K)=0.0001634 23, α(L)=1.511E-5 22, α(M)=1.99E-6 3, α(N)=7.49E-8 11, α(N+)=7.49E-8 11
3250.9	(5/2+)	0.139 ps 35	3251	(E1)		0.001370	B(E1)(W.u.)=1.2E-5 5, α=0.001370 20, α(K)=9.82E-6 14, α(L)=9.01E-7 13, α(M)=1.185E-7 17, α(N)=4.48E-9 7, α(N+)=0.001362 19
3511	(7/2)-		3.51E+3	D(+Q)	-0.08 8
3527.6	13/2-	0.29 ps 4	337.2 4	M1		0.001260	B(M1)(W.u.)=1.55 23, α=0.001260 18, α(K)=0.001138 17, α(L)=0.0001064 16, α(M)=1.400×10^-5 20, α(N)=5.23E-7 8, α(N+)=5.23E-7 8
	13/2-	0.29 ps 4	1965.4 4	(M1)		0.000272	B(M1)(W.u.)=0.00040 8, α=0.000272 4, α(K)=3.15×10^-5 5, α(L)=2.90E-6 4, α(M)=3.82E-7 6, α(N)=1.443E-8 21, α(N+)=0.000238 4
	13/2-	0.29 ps 4	2444.0 4	(E2)		0.000555	B(E2)(W.u.)=0.034 11, α=0.000555 8, α(K)=2.30E-5 4, α(L)=2.12E-6 3, α(M)=2.78E-7 4, α(N)=1.051E-8 15, α(N+)=0.000529 8
3628.6	(9/2+)	0.125 ps 28	1197	(E2)		0.0001110	B(E2)(W.u.)=19 6, α=0.0001110 16, α(K)=9.24E-5 13, α(L)=8.55E-6 12, α(M)=1.125E-6 16, α(N)=4.22E-8 6, α(N+)=8.69E-6 13
	(9/2+)	0.125 ps 28	2066	(E1)		0.000705	B(E1)(W.u.)=1.8E-5 6, α=0.000705 10, α(K)=1.82E-5 3, α(L)=1.673E-6 24, α(M)=2.20E-7 3, α(N)=8.31E-9 12, α(N+)=0.000685 10
	(9/2+)	0.125 ps 28	2545	(E1)		0.001000	B(E1)(W.u.)=6.2E-5 18, α=0.001000 14, α(K)=1.358E-5 19, α(L)=1.246E-6 18, α(M)=1.640E-7 23, α(N)=6.19E-9 9, α(N+)=0.000988 14
	(9/2+)	0.125 ps 28	3357	(E1)		0.001420	B(E1)(W.u.)=3.2E-5 10, α=0.001420 20, α(K)=9.43E-6 14, α(L)=8.64E-7 13, α(M)=1.138E-7 16, α(N)=4.30E-9 6, α(N+)=0.001412 20
3802.4	(11/2-)	0.069 ps 21	3530	(E2)		0.001010	B(E2)(W.u.)=0.8 3, α=0.001010 15, α(K)=1.270E-5 18, α(L)=1.166E-6 17, α(M)=1.534E-7 22, α(N)=5.80E-9 9, α(N+)=0.000999 14
3843.9	(7/2+)	0.21 ps 4	3572	(E1)		0.001510	α=0.001510 22, α(K)=8.72×10^-6 13, α(L)=7.99E-7 12, α(M)=1.051E-7 15, α(N)=3.97E-9 6, α(N+)=0.001504 21
3843.9	(7/2+)	0.21 ps 4	3844	(E1)		0.001630	α=0.001630 23, α(K)=7.95×10^-6 12, α(L)=7.29E-7 11, α(M)=9.59E-8 14, α(N)=3.63E-9 5, α(N+)=0.001620 23
3892.2	13/2+	> 6.9 ps	364.4 4	E1		0.000734	B(E1)(W.u.)<0.00017, α=0.000734 11, α(K)=0.000664 10, α(L)=6.14E-5 9, α(M)=8.07E-6 12, α(N)=3.00E-7 5, α(N+)=3.00E-7 5
	13/2+	> 6.9 ps	702.2 5	(E1)		0.0001410	B(E1)(W.u.)<1.4E-5, α=0.0001410 20, α(K)=0.0001277 18, α(L)=1.179E-5 17, α(M)=1.551E-6 22, α(N)=5.81E-8 9, α(N+)=5.81E-8 9
	13/2+	> 6.9 ps	1395 1	(E1)		0.000221	B(E1)(W.u.)<3.0E-6, α=0.000221 4, α(K)=3.36E-5 5, α(L)=3.09E-6 5, α(M)=4.07E-7 6, α(N)=1.533E-8 22, α(N+)=0.000184 3
	13/2+	> 6.9 ps	2332 1	(E1)		0.000878	B(E1)(W.u.)<4.1E-6, α=0.000878 13, α(K)=1.533E-5 22, α(L)=1.407E-6 20, α(M)=1.85E-7 3, α(N)=6.99E-9 10, α(N+)=0.000861 12
E(level) (keV)	J^π(level)	T_1/2(level)	E(γ) (keV)	Multipolarity	Mixing Ratio	Conversion Coefficient	Additional Data
3899.1	(15/2-)	0.28 ps 5	2337	(E2)		0.000505	B(E2)(W.u.)=0.82 22, α=0.000505 8, α(K)=2.48E-5 4, α(L)=2.29E-6 4, α(M)=3.01E-7 5, α(N)=1.135E-8 16, α(N+)=0.000478 7
4051.5	(9/2+)	0.180 ps 28	2489	(E1)		0.000971	B(E1)(W.u.)=4.9E-5 12, α=0.000971 14, α(K)=1.400E-5 20, α(L)=1.285E-6 18, α(M)=1.691E-7 24, α(N)=6.38E-9 9, α(N+)=0.000955 14
4051.5	(9/2+)	0.180 ps 28	2968	(E1)		0.001230	B(E1)(W.u.)=6.8E-5 14, α=0.001230 18, α(K)=1.106E-5 16, α(L)=1.014E-6 15, α(M)=1.334E-7 19, α(N)=5.04E-9 7, α(N+)=0.001221 17
4105.7	(13/2)-	< 0.021 ps	3021	(E2)		0.000810	B(E2)(W.u.)>4.7, α=0.000810 12, α(K)=1.621E-5 23, α(L)=1.489E-6 21, α(M)=1.96E-7 3, α(N)=7.40E-9 11, α(N+)=0.000792 11
4201.7	(13/2)-	< 0.021 ps	3117	(E2)		0.000850	B(E2)(W.u.)>3.8, α=0.000850 12, α(K)=1.542E-5 22, α(L)=1.416E-6 20, α(M)=1.86E-7 3, α(N)=7.04E-9 10, α(N+)=0.000833 12
4218.1	17/2-	0.107 ps 50	1717.4 4	(E2)		0.000228	B(E2)(W.u.)=9 5, α=0.000228 4, α(K)=4.36E-5 7, α(L)=4.02E-6 6, α(M)=5.29E-7 8, α(N)=1.99E-8 3, α(N+)=0.000180 3
4279.5	(11/2+)	0.21 ps 4	1368	(E2)		0.0001220	B(E2)(W.u.)=22 6, α=0.0001220 18, α(K)=6.91E-5 10, α(L)=6.38E-6 9, α(M)=8.40E-7 12, α(N)=3.16E-8 5, α(N+)=4.56E-5 7
	(11/2+)	0.21 ps 4	2717	(E1)		0.001100	B(E1)(W.u.)=2.2E-5 6, α=0.001100 16, α(K)=1.243E-5 18, α(L)=1.141E-6 16, α(M)=1.501E-7 21, α(N)=5.67E-9 8, α(N+)=0.001090 16
	(11/2+)	0.21 ps 4	3196	(E1)		0.001350	B(E1)(W.u.)=9.4E-6 25, α=0.001350 19, α(K)=1.004E-5 14, α(L)=9.21E-7 13, α(M)=1.212E-7 17, α(N)=4.58E-9 7, α(N+)=0.001335 19
4296.8	(9/2+)	0.035 ps 14	4025	(E1)		0.001700	α=0.001700 24, α(K)=7.51×10^-6 11, α(L)=6.89E-7 10, α(M)=9.06E-8 13, α(N)=3.43E-9 5, α(N+)=0.001690 24
4366.0	19/2-	1.67 ps 14	1176.6 4	E2		0.0001120	B(E2)(W.u.)=13.3 12, α=0.0001120 16, α(K)=9.61E-5 14, α(L)=8.89E-6 13, α(M)=1.169E-6 17, α(N)=4.39E-8 7, α(N+)=6.04E-6 10
4459.7	(11/2+)	0.159 ps 28	3376	(E1)		0.001430	B(E1)(W.u.)=8.3E-5 15, α=0.001430 21, α(K)=9.36E-6 14, α(L)=8.58E-7 12, α(M)=1.129E-7 16, α(N)=4.27E-9 6, α(N+)=0.001420 20
4467.1	15/2+	1.2 ps 3	575.2 4	M1+E2	-0.20 5	3.92×10^-4	B(E2)(W.u.)=21 12, B(M1)(W.u.)=0.073 20, α=3.92E-4 9, α(K)=0.000355 8, α(L)=3.29E-5 8, α(M)=4.33E-6 10, α(N)=1.63E-7 4, α(N+)=1.63E-7 4
	15/2+	1.2 ps 3	939.3 4	(E1)		7.64×10^-5	B(E1)(W.u.)=3.0E-5 13, α=7.64E-5 11, α(K)=6.92E-5 10, α(L)=6.38E-6 9, α(M)=8.39E-7 12, α(N)=3.15E-8 5, α(N+)=3.15E-8 5
	15/2+	1.2 ps 3	1276.7 4	(E1)		0.0001480	B(E1)(W.u.)=2.2E-5 7, α=0.0001480 21, α(K)=3.91E-5 6, α(L)=3.60E-6 5, α(M)=4.74E-7 7, α(N)=1.783E-8 25, α(N+)=0.0001049 15
4571.5	17/2-	0.139 ps 28	2072	(E2)		0.000382	B(E2)(W.u.)=4.9 13, α=0.000382 6, α(K)=3.07E-5 5, α(L)=2.83E-6 4, α(M)=3.72E-7 6, α(N)=1.404E-8 20, α(N+)=0.000348 5
4716.2	(13/2+)	0.49 ps 7	2216	(E1)		0.000805	B(E1)(W.u.)=5.3E-5 13, α=0.000805 12, α(K)=1.647E-5 23, α(L)=1.512E-6 22, α(M)=1.99E-7 3, α(N)=7.51E-9 11, α(N+)=0.000786 11
4716.2	(13/2+)	0.49 ps 7	3154	(E1)		0.001330	B(E1)(W.u.)=1.5E-5 4, α=0.001330 19, α(K)=1.022E-5 15, α(L)=9.37E-7 14, α(M)=1.233E-7 18, α(N)=4.66E-9 7, α(N+)=0.001314 19
4764	(7/2)-		≈4.49E+3	D(+Q)	-0.052 90
4943.6	(11/2+)	0.049 ps 14	3860	(E1)		0.001630	α=0.001630 23, α(K)=7.91×10^-6 11, α(L)=7.25E-7 11, α(M)=9.54E-8 14, α(N)=3.61E-9 5, α(N+)=0.001626 23
5048.4	(13/2+)	< 0.069 ps	3486	(E1)		0.001480	B(E1)(W.u.)>6.7E-5, α=0.001480 21, α(K)=8.99E-6 13, α(L)=8.24E-7 12, α(M)=1.084E-7 16, α(N)=4.10E-9 6, α(N+)=0.001468 21
5302.7	17/2+	0.76 ps 14	835.5 4	M1+E2	-0.34 10	1.81×10^-4	B(E2)(W.u.)=13 8, B(M1)(W.u.)=0.032 7, α=1.81E-4 5, α(K)=0.000164 5, α(L)=1.51E-5 5, α(M)=1.99E-6 6, α(N)=7.49E-8 20, α(N+)=7.49E-8 20
5302.7	17/2+	0.76 ps 14	1410.8 4	E2		0.0001290	B(E2)(W.u.)=3.5 8, α=0.0001290 19, α(K)=6.48E-5 9, α(L)=5.98E-6 9, α(M)=7.87E-7 11, α(N)=2.96E-8 5, α(N+)=5.75E-5 9
5962.4	23/2-	0.444 ps 31	1596.3 4	(E2)		0.000182	B(E2)(W.u.)=11.5 8, α=0.000182 3, α(K)=5.04E-5 7, α(L)=4.64E-6 7, α(M)=6.11E-7 9, α(N)=2.30E-8 4, α(N+)=0.0001268 18
6134.1	21/2-	0.069 ps 21	1915.0 4	(E2)		0.000311	B(E2)(W.u.)=16 5, α=0.000311 5, α(K)=3.55E-5 5, α(L)=3.27E-6 5, α(M)=4.30E-7 6, α(N)=1.622E-8 23, α(N+)=0.000272 4
E(level) (keV)	J^π(level)	T_1/2(level)	E(γ) (keV)	Multipolarity	Mixing Ratio	Conversion Coefficient	Additional Data
6341.9	19/2+	0.28 ps 7	1874.4 4	E2		0.000293	B(E2)(W.u.)=5.3 15, α=0.000293 5, α(K)=3.70E-5 6, α(L)=3.40E-6 5, α(M)=4.48E-7 7, α(N)=1.688E-8 24, α(N+)=0.000252 4
7269.2	21/2+	0.18 ps 4	1966.6 4	E2		0.000334	B(E2)(W.u.)=8.0 21, α=0.000334 5, α(K)=3.38E-5 5, α(L)=3.11E-6 5, α(M)=4.10E-7 6, α(N)=1.544E-8 22, α(N+)=0.000297 5
8007.4	27/2-	0.190 ps 15	2045 1	(E2)		0.000370	B(E2)(W.u.)=7.8 7, α=0.000370 6, α(K)=3.15E-5 5, α(L)=2.90E-6 4, α(M)=3.81E-7 6, α(N)=1.438E-8 21, α(N+)=0.000335 5
8333.3	25/2-	0.29 ps 6	325.9 4	M1		0.001360	B(M1)(W.u.)=1.8 5, α=0.001360 20, α(K)=0.001232 18, α(L)=0.0001152 17, α(M)=1.517×10^-5 22, α(N)=5.66E-7 8, α(N+)=5.66E-7 8
10700.3	31/2-	0.069 ps 14	478.4 14	M1		5.68×10^-4	B(M1)(W.u.)=1.5 3, α=5.68×10^-4 9, α(K)=0.000514 8, α(L)=4.78E-5 8, α(M)=6.29E-6 10, α(N)=2.36E-7 4, α(N+)=2.36E-7 4
10700.3	31/2-	0.069 ps 14	2692.6 10	(E2)		0.000667	B(E2)(W.u.)=2.7 6, α=0.000667 10, α(K)=1.96E-5 3, α(L)=1.80E-6 3, α(M)=2.36E-7 4, α(N)=8.93E-9 13, α(N+)=0.000646 9

Q(β-)=-7696 keV 11	S(n)= 10582 keV 8	S(p)= 8145 keV 3	Q(α)= -8748 keV 3
Reference: 2012WA38

References:
A	⁴⁹Mn β⁺ decay	B	¹²C(⁴⁰Ca,N2PG),⁴⁰Ca(¹²C,N2PG),
C	⁴⁶Ti(α,nγ)	D	⁵⁰Cr(p,d),(³He,α),(³He,αγ)

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	5/2-	42.3 m 1 % ε = 100
271.72 16	A B C D	7/2-	13 ps 3	271.78 19	100	M1+E2	0.0	5/2-
1083.6 3	B C D	9/2-	0.15 ps 3	812.0 4 1083.9 10	100.0 11 6.3 11	M1+E2 (E2)	271.72 0.0	7/2- 5/2-
1562.1 3	B C D	11/2-	0.391 ps 34	478.63 26 1290.2 5	100 4 95 4	M1+E2 E2	1083.6 271.72	9/2- 7/2-
1703.2 4	B C D	1/2-	> 3.8 ps	1703.2 5	100	E2	0.0	5/2-
1741.4 3	C D	3/2-	1.1 ps 3	39? 1469.3 5 1741.3 5	<0.14 40 3 100 3	E2 (M1+E2)	1703.2 271.72 0.0	1/2- 7/2- 5/2-
1981.8 3	B C D	3/2+	> 1.39 ps	240 278.1 7 1709.5 5 1981.3 5	2.4 6 26 3 16 3 100 3	(E1) (E1(+M2)) (M2+E3) (E1+M2)	1741.4 1703.2 271.72 0.0	3/2- 1/2- 7/2- 5/2-
2168.5 4	C	5/2	1.04 ps 35	427 465? 1897.0 5 2168.2 5	3.8 11 <0.18 82 4 100 4	D,E2 D+Q D+Q	1741.4 1703.2 271.72 0.0	3/2- 1/2- 7/2- 5/2-
2431.8 3	B C D	5/2+	0.66 ps 19	450.2 7 690 2161 2431.4 5	92 12 6.2 12 2.4 8 100 12	M1+E2 (E1) (E1) (E1(+M2))	1981.8 1741.4 271.72 0.0	3/2+ 3/2- 7/2- 5/2-
2500.1 4	B C	13/2-	0.110 ps 18	937.4 7 1416.4 4	100 4 11 4	(M1(+E2)) (E2)	1562.1 1083.6	11/2- 9/2-
2502.6 5	A C	7/2-	< 8 fs	335? 1420? 2232.1 7 2503.4 7	<7.4 <7.4 49 8 100 8	D(+Q) M1(+E2)	2168.5 1083.6 271.72 0.0	5/2 9/2- 7/2- 5/2-
2578.1 5	C D	1/2+		596 836.5 6 875.3 6	20 6 100 8 60 8	(E1) (E1)	1981.8 1741.4 1703.2	3/2+ 3/2- 1/2-
E(level) (keV)	XREF	J^π(level)	T_1/2(level)	E(γ) (keV)	I(γ)	M(γ)	Final Levels
2613.1 6	C D	3/2-	45 fs 14	2341.7 6 2611.8 10	100.0 10 69 4	E2 M1	271.72 0.0	7/2- 5/2-
2911.7 5	C D	(7/2+)	0.52 ps 10	480 930 2640 2912	100 15 39 9 94 15 70 12	D E2 E1	2431.8 1981.8 271.72 0.0	5/2+ 3/2+ 7/2- 5/2-
2978.7 5	C D	(3/2+)	> 0.69 ps	401 547 810 997 1237 2979?	59 11 100 11 40 7 27 5 25 5	(E1) (M1) (E1) (E1)	2578.1 2431.8 2168.5 1981.8 1741.4 0.0	1/2+ 5/2+ 5/2 3/2+ 3/2- 5/2-
3051.7 8	C	(9/2)-	< 0.028 ps	1968 2780 3052?	100 9 79 9	D,E2 D,E2	1083.6 271.72 0.0	9/2- 7/2- 5/2-
3190.1 4	B C	15/2-	0.083 ps 21	690.2 4 1627.8 4	92 10 100 10	(M1(+E2)) (E2)	2500.1 1562.1	13/2- 11/2-
3201.7 8	C	(9/2-)	< 0.028 ps	2118 2930 3202?	45 9 100 9	D,E2 D,E2	1083.6 271.72 0.0	9/2- 7/2- 5/2-
3250.9 6	C D	(5/2+)	0.139 ps 35	819 1269 2979 3251	100 14 100 14 <11.4 27 7	(M1) D,E2 (E1)	2431.8 1981.8 271.72 0.0	5/2+ 3/2+ 7/2- 5/2-
3407 5	C D	(5/2)-		794?			2613.1	3/2-
3499.7 11	C	(11/2-)	< 0.021 ps	2416	100	D,E2	1083.6	9/2-
3511 5	C D	(7/2)-		2.44E+3 3.24E+3? 3.51E+3	92 20 100 22	D(+Q)	1083.6 271.72 0.0	9/2- 7/2- 5/2-
3527.6 4	B C	13/2-	0.29 ps 4	337.2 4 1027.6 4 1965.4 4 2444.0 4	100.0 31 20.9 21 5.1 6 2.1 6	M1 D,E2 (M1) (E2)	3190.1 2500.1 1562.1 1083.6	15/2- 13/2- 11/2- 9/2-
E(level) (keV)	XREF	J^π(level)	T_1/2(level)	E(γ) (keV)	I(γ)	M(γ)	Final Levels
3628.6 5	C	(9/2+)	0.125 ps 28	717 1197 2066 2545 3357	97 17 37 7 13.3 20 83 14 100 17	D,E2 (E2) (E1) (E1) (E1)	2911.7 2431.8 1562.1 1083.6 271.72	(7/2+) 5/2+ 11/2- 9/2- 7/2-
3687.4 8	C	(11/2-)	< 0.021 ps	2125 2604	45 6 100 6	D,E2 D,E2	1562.1 1083.6	11/2- 9/2-
3717 5	C D	(1/2)-
3802.4 7	C	(11/2-)	0.069 ps 21	1301 2718 3530	27 6 55 8 100 9	D,E2 D,Q (E2)	2500.1 1083.6 271.72	13/2- 9/2- 7/2-
3843.9 11	C	(7/2+)	0.21 ps 4	1412 3572? 3844?	100	D,E2 (E1) (E1)	2431.8 271.72 0.0	5/2+ 7/2- 5/2-
3892.2 4	B C	13/2+	> 6.9 ps	364.4 4 702.2 5 1395 1 2332 1	15.6 9.6 15.6 100	E1 (E1) (E1) (E1)	3527.6 3190.1 2500.1 1562.1	13/2- 15/2- 13/2- 11/2-
3899.1 7	C	(15/2-)	0.28 ps 5	709 1399 2337	100 15 100 15 86 15	D,E2 D,E2 (E2)	3190.1 2500.1 1562.1	15/2- 13/2- 11/2-
3913 5	C D	(3/2)-		≈1.33E+3? ≈1.33E+3? 1.95E+3 ≈2.20E+3? ≈2.20E+3?			2613.1 2578.1 1981.8 1741.4 1703.2	3/2- 1/2+ 3/2+ 3/2- 1/2-
3928.8 11	C			1947			1981.8	3/2+
3938 5	D	3/2+,5/2+
3975 5	D
4019 5	C D	(1/2+)
E(level) (keV)	XREF	J^π(level)	T_1/2(level)	E(γ) (keV)	I(γ)	M(γ)	Final Levels
4051.5 7	C	(9/2+)	0.180 ps 28	1140 2489 2968	15.9 32 43 7 100 10	D,E2 (E1) (E1)	2911.7 1562.1 1083.6	(7/2+) 11/2- 9/2-
4052 5	C D	(5/2)-
4105.7 8	C	(13/2)-	< 0.021 ps	1604 3021	100 9 89 9	D,E2 (E2)	2500.1 1083.6	13/2- 9/2-
4151 5	D	5/2-,7/2-
4186 5	D	(1/2+)
4201.7 8	C	(13/2)-	< 0.021 ps	1700 3117	100 6 79 6	D,E2 (E2)	2500.1 1083.6	13/2- 9/2-
4218.1 5	B C	17/2-	0.107 ps 50	1027.8 4 1717.4 4	100 38	D (E2)	3190.1 2500.1	15/2- 13/2-
4259 5	D	3/2+,5/2+
4279.5 6	C	(11/2+)	0.21 ps 4	651 1368 2717 3196	67 10 100 12 44 7 31 5	D (E2) (E1) (E1)	3628.6 2911.7 1562.1 1083.6	(9/2+) (7/2+) 11/2- 9/2-
4296.8 11	C	(9/2+)	0.035 ps 14	1385 4025?	100	D,E2 (E1)	2911.7 271.72	(7/2+) 7/2-
4323 5	D
4366.0 5	B C	19/2-	1.67 ps 14	148.1 4 1176.6 4	5.8 100	D E2	4218.1 3190.1	17/2- 15/2-
4379 5	D
4426 5	C D	5/2-,7/2-		2440			1981.8	3/2+
4459.7 11	C	(11/2+)	0.159 ps 28	3376	100	(E1)	1083.6	9/2-
4467.1 4	B C	15/2+	1.2 ps 3	575.2 4 939.3 4 1276.7 4 1966.8 4	100.0 51 7.6 25 13.9 25 5.1 25	M1+E2 (E1) (E1) D,Q	3892.2 3527.6 3190.1 2500.1	13/2+ 13/2- 15/2- 13/2-
4493 5	D	(3/2+,5/2+)
E(level) (keV)	XREF	J^π(level)	T_1/2(level)	E(γ) (keV)	I(γ)	M(γ)	Final Levels
4559 5	D	3/2+,5/2+
4571.5 7	C	17/2-	0.139 ps 28	352 1382 2072	<10 100 14 100 14	D,E2 (E2)	4218.1 3190.1 2500.1	17/2- 15/2- 13/2-
4586.5 11	C			2605			1981.8	3/2+
4594 5	D	3/2+,5/2+
4651 5	D	5/2-,7/2-
4698 5 ?	D
4716.2 8	C	(13/2+)	0.49 ps 7	2216 3154	100 15 79 15	(E1) (E1)	2500.1 1562.1	13/2- 11/2-
4749.4 8	C		< 0.035 ps	2248 3186	69 14 100 14	D,E2 D,E2	2500.1 1562.1	13/2- 11/2-
4764 5	D	(7/2)-		≈3.69E+3 ≈4.49E+3 ≈4.76E+3	47 10 100 21 9.4 16	D(+Q)	1083.6 271.72 0.0	9/2- 7/2- 5/2-
4773	C
4809.1 8	C		< 0.035 ps	1619 2309	79 15 100 15	D,E2 D,E2	3190.1 2500.1	15/2- 13/2-
4837.2 11	C			3275			1562.1	11/2-
4852 5	D	5/2-,7/2-
4879 5	D
4913 5	D	1/2-,3/2-
4942 5	D	(1/2-,3/2-)
4943.6 11	C	(11/2+)	0.049 ps 14	1315 3860?	100	D,E2 (E1)	3628.6 1083.6	(9/2+) 9/2-
4994 5	D
5032.3 11	C			3470			1562.1	11/2-
5048.4 6	C	(13/2+)	< 0.069 ps	769 1420 2548 3486	<25 51 8 93 10 100 13	D,E2 D,E2 (E1)	4279.5 3628.6 2500.1 1562.1	(11/2+) (9/2+) 13/2- 11/2-
E(level) (keV)	XREF	J^π(level)	T_1/2(level)	E(γ) (keV)	I(γ)	M(γ)	Final Levels
5058 5	C D			3500			1562.1	11/2-
5179.7 11	C			2677			2502.6	7/2-
5189 5	D	3/2+,5/2+
5273 5	D	5/2-,7/2-
5302.7 5	B C	17/2+	0.76 ps 14	835.5 4 1410.8 4	100 4 39 4	M1+E2 E2	4467.1 3892.2	15/2+ 13/2+
5384 5	D	1/2-,3/2-
5428 5	D	3/2+,5/2+
5495 5	D	1/2-,3/2-
5573 5	D	(3/2)+		3.14E+3 3.59E+3 5.57E+3	50 10 100 20 50 10	D+Q	2431.8 1981.8 0.0	5/2+ 3/2+ 5/2-
5625 5	D
5637 5	D	(5/2-,7/2-)
5660 5 ?	D	(5/2-,7/2-)
5696 5	D	(1/2-,3/2-)
5747 5	D	1/2+
5784 5	D	(3/2+,5/2+)
5934 5	D
5962.4 6	B	23/2-	0.444 ps 31	1596.3 4	100	(E2)	4366.0	19/2-
5981 5	D	(3/2+,5/2+)
6006 6	D	1/2+
6036 6	D	3/2+,5/2+
6090 6	D	3/2+,5/2+
6127 6	D
6134.1 5	B	21/2-	0.069 ps 21	171 1 ? 1768.9 4 1915.0 4	<3.3 86.7 100	D (E2)	5962.4 4366.0 4218.1	23/2- 19/2- 17/2-
6278 6	D
6309 6	D
E(level) (keV)	XREF	J^π(level)	T_1/2(level)	E(γ) (keV)	I(γ)	M(γ)	Final Levels
6341.9 5	B	19/2+	0.28 ps 7	1039.4 4 1874.4 4	54 8 100 8	D,E2 E2	5302.7 4467.1	17/2+ 15/2+
6342 6	D
6380 6	D	(1/2-,3/2-)
6.41E+3?	D
6423 6	D	(1/2-,3/2-)		≈2.50E+3? ≈3.83E+3? ≈3.83E+3? ≈4.70E+3? ≈4.70E+3?	81 17 100 22 100 22 31.9 22 31.9 22		3913 2613.1 2578.1 1741.4 1703.2	(3/2)- 3/2- 1/2+ 3/2- 1/2-
6470 6	D	1/2+		≈2.54E+3 ≈3.87E+3? ≈3.87E+3? ≈4.74E+3? ≈4.74E+3?	40.5 24 100 22 100 22 98 22 98 22		3938 2613.1 2578.1 1741.4 1703.2	3/2+,5/2+ 3/2- 1/2+ 3/2- 1/2-
6548 6	D	(3/2+,5/2+)
6639 6 ?	D
6705 6	D	3/2+,5/2+
6734 6	D	3/2+,5/2+
6765 6	D	1/2+		2.83E+3 ≈4.16E+3? ≈4.16E+3? ≈5.03E+3? ≈5.03E+3?			3938 2613.1 2578.1 1741.4 1703.2	3/2+,5/2+ 3/2- 1/2+ 3/2- 1/2-
6823 6	D	5/2-,7/2-
6884 6	D	3/2+,5/2+
6948 6	D	(3/2+,5/2+)
6995 6	D	1/2-,3/2-
7005 7	D
7084 7	D	(5/2-,7/2-)
E(level) (keV)	XREF	J^π(level)	T_1/2(level)	E(γ) (keV)	I(γ)	M(γ)	Final Levels
7115 7	D
7161 7	D
7186 7	D	(5/2-,7/2-)
7225 7	D	5/2-,7/2-
7264 7	D	5/2-,7/2-
7269.2 6	B	21/2+	0.18 ps 4	927.2 4 1966.6 4	25 8 100 8	D,E2 E2	6341.9 5302.7	19/2+ 17/2+
7308 7	D	(5/2-,7/2-)
7350 7	D
7391 7	D
7432 7	D	(3/2+,5/2+)
7480 7	D	1/2+
7503 7 ?	D
7537 7	D
7584 7	D	1/2+
7601 7	D
7627 7	D	1/2+
7889 7	D	5/2-,7/2-
8007.4 12	B	27/2-	0.190 ps 15	2045 1	100	(E2)	5962.4	23/2-
8020 8	D	1/2+
8050 8	D	1/2+
8092 8	D
8128 8	D
8157 8	D
8231 8	D	1/2+
8265 8	D	1/2+
8331 8	D	1/2+
8333.3 13	B	25/2-	0.29 ps 6	325.9 4 2199 1 ? 2370 1 ?	100 <25 <25	M1	8007.4 6134.1 5962.4	27/2- 21/2- 23/2-
E(level) (keV)	XREF	J^π(level)	T_1/2(level)	E(γ) (keV)	I(γ)	M(γ)	Final Levels
8368 8	D	3/2+,5/2+
8405 8	D
8441 8	D
8476 8	D	3/2+,5/2+
8527 8	D	3/2+,5/2+
8548 8	D
8557 8	D
8655 8	D
8683 8	D
8716 8	D	3/2+,5/2+
8770 8	D
8830 8	D	(1/2+)
8896 8	D	(1/2+)
9031 9	D
9064 9	D	3/2+,5/2+
9123 9	D
9131 9	D
9145 9	D	3/2+,5/2+
9198 9	D	(1/2+)
9265 9	D
9292 9	D
9321 9	D
9365 9	D
9399 9	D
9447 9	D	(3/2+,5/2+)
9521 9	D
9662 9	D	(1/2+)
9711 9	D
9745 9	D	(3/2+,5/2+)
9788 9	D	1/2+
E(level) (keV)	XREF	J^π(level)	T_1/2(level)	E(γ) (keV)	I(γ)	M(γ)	Final Levels
9857 9	D
9945 9	D
9968 9	D
10039 10	D
10105 10	D	(3/2+,5/2+)
10125 10	D	(3/2+,5/2+)
10170 10	D
10218 10	D
10222.4 15	B	29/2-	0.0324 ps 8	1889 1 ? 2215.1 9	<12 100	D	8333.3 8007.4	25/2- 27/2-
10266 10	D	1/2+
10302 10	D	1/2+
10374 10	D	(3/2+,5/2+)
10428 10	D
10526 10	D
10700.3 15	B	31/2-	0.069 ps 14	478.4 14 2692.6 10	100 100	M1 (E2)	10222.4 8007.4	29/2- 27/2-

E(level) (keV)	J^π(level)	T_1/2(level)	E(γ)	I(γ)	M(γ)	Final Levels
Band 1 - K^π=5/2-, α=1/2⁺ GS ROTATIONAL band.
0.0	5/2-	42.3 m 1 % ε = 100
1083.6 3	9/2-	0.15 ps 3	812.0 4 1083.9 10	100.0 11 6.3 11	M1+E2 (E2)	271.72 0.0	7/2- 5/2-
2500.1 4	13/2-	0.110 ps 18	937.4 7 1416.4 4	100 4 11 4	(M1(+E2)) (E2)	1562.1 1083.6	11/2- 9/2-
4218.1 5	17/2-	0.107 ps 50	1027.8 4 1717.4 4	100 38	D (E2)	3190.1 2500.1	15/2- 13/2-
6134.1 5	21/2-	0.069 ps 21	171 1 ? 1768.9 4 1915.0 4	<3.3 86.7 100	D (E2)	5962.4 4366.0 4218.1	23/2- 19/2- 17/2-
8333.3 13	25/2-	0.29 ps 6	325.9 4 2199 1 ? 2370 1 ?	100 <25 <25	M1	8007.4 6134.1 5962.4	27/2- 21/2- 23/2-
10222.4 15	29/2-	0.0324 ps 8	1889 1 ? 2215.1 9	<12 100	D	8333.3 8007.4	25/2- 27/2-
E(level) (keV)	J^π(level)	T_1/2(level)	E(γ)	I(γ)	M(γ)	Final Levels
Band 2 - K^π=5/2-, α=1/2- GS ROTATIONAL band.
271.72 16	7/2-	13 ps 3
1562.1 3	11/2-	0.391 ps 34	478.63 26 1290.2 5	100 4 95 4	M1+E2 E2	1083.6 271.72	9/2- 7/2-
3190.1 4	15/2-	0.083 ps 21	690.2 4 1627.8 4	92 10 100 10	(M1(+E2)) (E2)	2500.1 1562.1	13/2- 11/2-
4366.0 5	19/2-	1.67 ps 14	148.1 4 1176.6 4	5.8 100	D E2	4218.1 3190.1	17/2- 15/2-
5962.4 6	23/2-	0.444 ps 31	1596.3 4	100	(E2)	4366.0	19/2-
8007.4 12	27/2-	0.190 ps 15	2045 1	100	(E2)	5962.4	23/2-
10700.3 15	31/2-	0.069 ps 14	478.4 14 2692.6 10	100 100	M1 (E2)	10222.4 8007.4	29/2- 27/2-
E(level) (keV)	J^π(level)	T_1/2(level)	E(γ)	I(γ)	M(γ)	Final Levels
Band 3 - K^π=1/2- band.
1703.2 4	1/2-	> 3.8 ps
1741.4 3	3/2-	1.1 ps 3	39? 1469.3 5 1741.3 5	<0.14 40 3 100 3	E2 (M1+E2)	1703.2 271.72 0.0	1/2- 7/2- 5/2-
2168.5 4	5/2	1.04 ps 35	427 465? 1897.0 5 2168.2 5	3.8 11 <0.18 82 4 100 4	D,E2 D+Q D+Q	1741.4 1703.2 271.72 0.0	3/2- 1/2- 7/2- 5/2-
3051.7 8	(9/2)-	< 0.028 ps	1968 2780 3052?	100 9 79 9	D,E2 D,E2	1083.6 271.72 0.0	9/2- 7/2- 5/2-
3499.7 11	(11/2-)	< 0.021 ps	2416	100	D,E2	1083.6	9/2-
4105.7 8	(13/2)-	< 0.021 ps	1604 3021	100 9 89 9	D,E2 (E2)	2500.1 1083.6	13/2- 9/2-
E(level) (keV)	J^π(level)	T_1/2(level)	E(γ)	I(γ)	M(γ)	Final Levels
Band 4 - K^π=3/2⁺ band.
1981.8 3	3/2+	> 1.39 ps
2431.8 3	5/2+	0.66 ps 19	450.2 7 690 2161 2431.4 5	92 12 6.2 12 2.4 8 100 12	M1+E2 (E1) (E1) (E1(+M2))	1981.8 1741.4 271.72 0.0	3/2+ 3/2- 7/2- 5/2-
2911.7 5	(7/2+)	0.52 ps 10	480 930 2640 2912	100 15 39 9 94 15 70 12	D E2 E1	2431.8 1981.8 271.72 0.0	5/2+ 3/2+ 7/2- 5/2-
3628.6 5	(9/2+)	0.125 ps 28	717 1197 2066 2545 3357	97 17 37 7 13.3 20 83 14 100 17	D,E2 (E2) (E1) (E1) (E1)	2911.7 2431.8 1562.1 1083.6 271.72	(7/2+) 5/2+ 11/2- 9/2- 7/2-
4279.5 6	(11/2+)	0.21 ps 4	651 1368 2717 3196	67 10 100 12 44 7 31 5	D (E2) (E1) (E1)	3628.6 2911.7 1562.1 1083.6	(9/2+) (7/2+) 11/2- 9/2-
4716.2 8	(13/2+)	0.49 ps 7	2216 3154	100 15 79 15	(E1) (E1)	2500.1 1562.1	13/2- 11/2-
E(level) (keV)	J^π(level)	T_1/2(level)	E(γ)	I(γ)	M(γ)	Final Levels
Band 5 - K^π=3/2-, ν=3.
2613.1 6	3/2-	45 fs 14
E(level) (keV)	J^π(level)	T_1/2(level)	E(γ)	I(γ)	M(γ)	Final Levels
Band 6 - K^π=1/2⁺ BAND?
2978.7 5	(3/2+)	> 0.69 ps
3843.9 11	(7/2+)	0.21 ps 4	1412 3572? 3844?	100	D,E2 (E1) (E1)	2431.8 271.72 0.0	5/2+ 7/2- 5/2-
4051.5 7	(9/2+)	0.180 ps 28	1140 2489 2968	15.9 32 43 7 100 10	D,E2 (E1) (E1)	2911.7 1562.1 1083.6	(7/2+) 11/2- 9/2-
4943.6 11	(11/2+)	0.049 ps 14	1315 3860?	100	D,E2 (E1)	3628.6 1083.6	(9/2+) 9/2-
E(level) (keV)	J^π(level)	T_1/2(level)	E(γ)	I(γ)	M(γ)	Final Levels
Band 7 - K^π=7/2- BAND?
3201.7 8	(9/2-)	< 0.028 ps
3687.4 8	(11/2-)	< 0.021 ps	2125 2604	45 6 100 6	D,E2 D,E2	1562.1 1083.6	11/2- 9/2-
4201.7 8	(13/2)-	< 0.021 ps	1700 3117	100 6 79 6	D,E2 (E2)	2500.1 1083.6	13/2- 9/2-
E(level) (keV)	J^π(level)	T_1/2(level)	E(γ)	I(γ)	M(γ)	Final Levels
Band 8 - K^π=1/2⁺ BAND?
3250.9 6	(5/2+)	0.139 ps 35
E(level) (keV)	J^π(level)	T_1/2(level)	E(γ)	I(γ)	M(γ)	Final Levels
Band 9 - K^π=3/2- BAND?
3407 5	(5/2)-
3511 5	(7/2)-		2.44E+3 3.24E+3? 3.51E+3	92 20 100 22	D(+Q)	1083.6 271.72 0.0	9/2- 7/2- 5/2-
3802.4 7	(11/2-)	0.069 ps 21	1301 2718 3530	27 6 55 8 100 9	D,E2 D,Q (E2)	2500.1 1083.6 271.72	13/2- 9/2- 7/2-
E(level) (keV)	J^π(level)	T_1/2(level)	E(γ)	I(γ)	M(γ)	Final Levels
Band 10 - K^π=13/2-, 3qp band.
3527.6 4	13/2-	0.29 ps 4
3899.1 7	(15/2-)	0.28 ps 5	709 1399 2337	100 15 100 15 86 15	D,E2 D,E2 (E2)	3190.1 2500.1 1562.1	15/2- 13/2- 11/2-
4571.5 7	17/2-	0.139 ps 28	352 1382 2072	<10 100 14 100 14	D,E2 (E2)	4218.1 3190.1 2500.1	17/2- 15/2- 13/2-
E(level) (keV)	J^π(level)	T_1/2(level)	E(γ)	I(γ)	M(γ)	Final Levels
Band 11 - K^π=1/2- BAND?
3717 5	(1/2)-
3913 5	(3/2)-		≈1.33E+3? ≈1.33E+3? 1.95E+3 ≈2.20E+3? ≈2.20E+3?			2613.1 2578.1 1981.8 1741.4 1703.2	3/2- 1/2+ 3/2+ 3/2- 1/2-
4052 5	(5/2)-
E(level) (keV)	J^π(level)	T_1/2(level)	E(γ)	I(γ)	M(γ)	Final Levels
Band 12 - band BASED ON 13/2⁺
3892.2 4	13/2+	> 6.9 ps
4467.1 4	15/2+	1.2 ps 3	575.2 4 939.3 4 1276.7 4 1966.8 4	100.0 51 7.6 25 13.9 25 5.1 25	M1+E2 (E1) (E1) D,Q	3892.2 3527.6 3190.1 2500.1	13/2+ 13/2- 15/2- 13/2-
6341.9 5	19/2+	0.28 ps 7	1039.4 4 1874.4 4	54 8 100 8	D,E2 E2	5302.7 4467.1	17/2+ 15/2+
7269.2 6	21/2+	0.18 ps 4	927.2 4 1966.6 4	25 8 100 8	D,E2 E2	6341.9 5302.7	19/2+ 17/2+

E(level)	J^π(level)	T_1/2(level)	Comments
0.0	5/2-	42.3 m 1 % ε = 100	μ=0.476 3 (2005St24,1970Jo27), T=1/2 E(level): K^π=5/2-, α=1/2⁺ GS ROTATIONAL band.
271.72	7/2-	13 ps 3	E(level): K^π=5/2-, α=1/2- GS ROTATIONAL band.
1083.6	9/2-	0.15 ps 3	E(level): K^π=5/2-, α=1/2⁺ GS ROTATIONAL band.
1562.1	11/2-	0.391 ps 34	E(level): K^π=5/2-, α=1/2- GS ROTATIONAL band.
1703.2	1/2-	> 3.8 ps	E(level): K^π=1/2- band.
1741.4	3/2-	1.1 ps 3	E(level): K^π=1/2- band.
1981.8	3/2+	> 1.39 ps	E(level): K^π=3/2⁺ band. From (α,nγ).
2168.5	5/2	1.04 ps 35	E(level): K^π=1/2- band.
2431.8	5/2+	0.66 ps 19	E(level): K^π=3/2⁺ band. From (α,nγ).
2500.1	13/2-	0.110 ps 18	E(level): K^π=5/2-, α=1/2⁺ GS ROTATIONAL band.
2613.1	3/2-	45 fs 14	T=1/2 Antianalog state of 6423 state. See (p,d). E(level): K^π=3/2-, ν=3.
2911.7	(7/2+)	0.52 ps 10	E(level): K^π=3/2⁺ band. From (α,nγ). J^π(level): Proposed by 2006Br03 in (α,nγ) based on their level scheme, particle-rotor and shell model calculations, and comparison with neighboring nuclides.
2978.7	(3/2+)	> 0.69 ps	E(level): K^π=1/2⁺ BAND?.
3051.7	(9/2)-	< 0.028 ps	E(level): K^π=1/2- band. Unweighted ave of 1084.9 4 from ¹²C(⁴⁰Ca,n2pγ),⁴⁰Ca(¹²C,n2pγ),... And 1083.0 10 from (α,nγ). J^π(level): Proposed by 2006Br03 in (α,nγ) based on their level scheme, particle-rotor and shell model calculations, and comparison with neighboring nuclides. 9/2-, 11/2- and 13/2- members in Kπ=1/2- and Kπ=7/2- bands.
3190.1	15/2-	0.083 ps 21	E(level): K^π=5/2-, α=1/2- GS ROTATIONAL band.
3201.7	(9/2-)	< 0.028 ps	E(level): Unweighted ave of 1084.9 4 from ¹²C(⁴⁰Ca,n2pγ),⁴⁰Ca(¹²C,n2pγ),... And 1083.0 10 from (α,nγ). K^π=7/2- BAND?. J^π(level): Proposed by 2006Br03 in (α,nγ) based on their level scheme, particle-rotor and shell model calculations, and comparison with neighboring nuclides. 9/2-, 11/2- and 13/2- members in Kπ=1/2- and Kπ=7/2- bands.
3250.9	(5/2+)	0.139 ps 35	E(level): K^π=1/2⁺ BAND?. J^π(level): Proposed by 2006Br03 in (α,nγ) based on their level scheme, particle-rotor and shell model calculations, and comparison with neighboring nuclides; parentheses added by evaluator.
3407	(5/2)-		E(level): Level energy held fixed in least-squares adjustment. K^π=3/2- BAND?. J^π(level): Proposed by 2006Br03 in (α,nγ) based on their level scheme, particle-rotor and shell model calculations, and comparison with neighboring nuclides.
3499.7	(11/2-)	< 0.021 ps	E(level): K^π=1/2- band. J^π(level): Proposed by 2006Br03 in (α,nγ) based on their level scheme, particle-rotor and shell model calculations, and comparison with neighboring nuclides; parentheses added by evaluator.
3511	(7/2)-		E(level): Level energy held fixed in least-squares adjustment. K^π=3/2- BAND?. J^π(level): Proposed by 2006Br03 in (α,nγ) based on their level scheme, particle-rotor and shell model calculations, and comparison with neighboring nuclides.
3527.6	13/2-	0.29 ps 4	E(level): K^π=13/2-, 3qp band.
3628.6	(9/2+)	0.125 ps 28	E(level): K^π=3/2⁺ band. From (α,nγ).
3687.4	(11/2-)	< 0.021 ps	E(level): Unweighted ave of 1084.9 4 from ¹²C(⁴⁰Ca,n2pγ),⁴⁰Ca(¹²C,n2pγ),... And 1083.0 10 from (α,nγ). K^π=7/2- BAND?. J^π(level): 9/2-, 11/2- and 13/2- members in Kπ=1/2- and Kπ=7/2- bands. Proposed by 2006Br03 in (α,nγ) based on their level scheme, particle-rotor and shell model calculations, and comparison with neighboring nuclides; parentheses added by evaluator.
3717	(1/2)-		E(level): Level energy held fixed in least-squares adjustment. K^π=1/2- BAND?. J^π(level): Proposed by 2006Br03 in (α,nγ) based on their level scheme, particle-rotor and shell model calculations, and comparison with neighboring nuclides.
3802.4	(11/2-)	0.069 ps 21	E(level): K^π=3/2- BAND?. J^π(level): Proposed by 2006Br03 in (α,nγ) based on their level scheme, particle-rotor and shell model calculations, and comparison with neighboring nuclides.
E(level)	J^π(level)	T_1/2(level)	Comments
3843.9	(7/2+)	0.21 ps 4	E(level): K^π=1/2⁺ BAND?. J^π(level): Proposed by 2006Br03 in (α,nγ) based on their level scheme, particle-rotor and shell model calculations, and comparison with neighboring nuclides.
3892.2	13/2+	> 6.9 ps	E(level): band BASED ON 13/2⁺.
3899.1	(15/2-)	0.28 ps 5	E(level): K^π=13/2-, 3qp band. J^π(level): Proposed by 2006Br03 in (α,nγ) based on their level scheme, particle-rotor and shell model calculations, and comparison with neighboring nuclides.
3913	(3/2)-		E(level): Level energy held fixed in least-squares adjustment. K^π=1/2- BAND?. J^π(level): Proposed by 2006Br03 in (α,nγ) based on their level scheme, particle-rotor and shell model calculations, and comparison with neighboring nuclides.
3938	3/2+,5/2+		E(level): Level energy held fixed in least-squares adjustment.
4019	(1/2+)		E(level): Level energy held fixed in least-squares adjustment.
4051.5	(9/2+)	0.180 ps 28	E(level): K^π=1/2⁺ BAND?. J^π(level): Proposed by 2006Br03 in (α,nγ) based on their level scheme, particle-rotor and shell model calculations, and comparison with neighboring nuclides.
4052	(5/2)-		E(level): Level energy held fixed in least-squares adjustment. K^π=1/2- BAND?.
4105.7	(13/2)-	< 0.021 ps	E(level): K^π=1/2- band. J^π(level): Proposed by 2006Br03 in (α,nγ) based on their level scheme, particle-rotor and shell model calculations, and comparison with neighboring nuclides.
4201.7	(13/2)-	< 0.021 ps	E(level): Unweighted ave of 1084.9 4 from ¹²C(⁴⁰Ca,n2pγ),⁴⁰Ca(¹²C,n2pγ),... And 1083.0 10 from (α,nγ). K^π=7/2- BAND?. J^π(level): Proposed by 2006Br03 in (α,nγ) based on their level scheme, particle-rotor and shell model calculations, and comparison with neighboring nuclides. 9/2-, 11/2- and 13/2- members in Kπ=1/2- and Kπ=7/2- bands.
4218.1	17/2-	0.107 ps 50	E(level): K^π=5/2-, α=1/2⁺ GS ROTATIONAL band. From (³He,αγ). T_1/2(level): From DSAM or Narrow Gate on Transitions Below in ¹²C(⁴⁰Ca,n2pγ),⁴⁰Ca(¹²C,n2pγ),...
4279.5	(11/2+)	0.21 ps 4	E(level): K^π=3/2⁺ band. From (α,nγ). J^π(level): Proposed by 2006Br03 in (α,nγ) based on their level scheme, particle-rotor and shell model calculations, and comparison with neighboring nuclides.
4296.8	(9/2+)	0.035 ps 14	J^π(level): Proposed by 2006Br03 in (α,nγ) based on their level scheme, particle-rotor and shell model calculations, and comparison with neighboring nuclides.
4323			E(level): Possible doublet. See (p,d).
4366.0	19/2-	1.67 ps 14	μ=+7.4 11 (2005St24) E(level): K^π=5/2-, α=1/2- GS ROTATIONAL band. From (³He,αγ). T_1/2(level): From DSAM or Narrow Gate on Transitions Below in ¹²C(⁴⁰Ca,n2pγ),⁴⁰Ca(¹²C,n2pγ),...
4426	5/2-,7/2-		E(level): Level energy held fixed in least-squares adjustment.
4459.7	(11/2+)	0.159 ps 28	J^π(level): Proposed by 2006Br03 in (α,nγ) based on their level scheme, particle-rotor and shell model calculations, and comparison with neighboring nuclides.
4467.1	15/2+	1.2 ps 3	E(level): band BASED ON 13/2⁺. From (³He,αγ). T_1/2(level): From DSAM or Narrow Gate on Transitions Below in ¹²C(⁴⁰Ca,n2pγ),⁴⁰Ca(¹²C,n2pγ),...
4493	(3/2+,5/2+)		E(level): Possible doublet. See (p,d).
4571.5	17/2-	0.139 ps 28	E(level): K^π=13/2-, 3qp band. J^π(level): Proposed by 2006Br03 in (α,nγ) based on their level scheme, particle-rotor and shell model calculations, and comparison with neighboring nuclides.
4716.2	(13/2+)	0.49 ps 7	E(level): K^π=3/2⁺ band. From (α,nγ). J^π(level): Proposed by 2006Br03 in (α,nγ) based on their level scheme, particle-rotor and shell model calculations, and comparison with neighboring nuclides.
4764	(7/2)-		T=3/2 E(level): Level energy held fixed in least-squares adjustment. Strongest member of various possible IAS’s of ⁴⁹V. See (p,d) for details.
4943.6	(11/2+)	0.049 ps 14	E(level): K^π=1/2⁺ BAND?. J^π(level): Proposed by 2006Br03 in (α,nγ) based on their level scheme, particle-rotor and shell model calculations, and comparison with neighboring nuclides; parentheses added by evaluator.
4994			E(level): Possible doublet. See (p,d).
5048.4	(13/2+)	< 0.069 ps	J^π(level): Proposed by 2006Br03 in (α,nγ) based on their level scheme, particle-rotor and shell model calculations, and comparison with neighboring nuclides.
E(level)	J^π(level)	T_1/2(level)	Comments
5058			E(level): Level energy held fixed in least-squares adjustment. Possible doublet. See (p,d).
5302.7	17/2+	0.76 ps 14	E(level): From (³He,αγ). T_1/2(level): From DSAM or Narrow Gate on Transitions Below in ¹²C(⁴⁰Ca,n2pγ),⁴⁰Ca(¹²C,n2pγ),...
5573	(3/2)+		T=3/2 E(level): Level energy held fixed in least-squares adjustment. Strongest member of various possible IAS’s of ⁴⁹V. See (p,d) for details.
5637	(5/2-,7/2-)		E(level): Possible doublet. See (p,d).
5660	(5/2-,7/2-)		E(level): Possible doublet. See (p,d).
5962.4	23/2-	0.444 ps 31	E(level): K^π=5/2-, α=1/2- GS ROTATIONAL band. From (³He,αγ). T_1/2(level): From DSAM or Narrow Gate on Transitions Below in ¹²C(⁴⁰Ca,n2pγ),⁴⁰Ca(¹²C,n2pγ),...
6036	3/2+,5/2+		E(level): Strongest member of various possible IAS’s of ⁴⁹V. See (p,d) for details.
6134.1	21/2-	0.069 ps 21	E(level): K^π=5/2-, α=1/2⁺ GS ROTATIONAL band. From (³He,αγ). T_1/2(level): From DSAM or Narrow Gate on Transitions Below in ¹²C(⁴⁰Ca,n2pγ),⁴⁰Ca(¹²C,n2pγ),...
6341.9	19/2+	0.28 ps 7	E(level): band BASED ON 13/2⁺. From (³He,αγ). T_1/2(level): From DSAM or Narrow Gate on Transitions Below in ¹²C(⁴⁰Ca,n2pγ),⁴⁰Ca(¹²C,n2pγ),...
6423	(1/2-,3/2-)		E(level): Strongest member of various possible IAS’s of ⁴⁹V. See (p,d) for details.
6470	1/2+		T=3/2 E(level): Level energy held fixed in least-squares adjustment. Strongest member of various possible IAS’s of ⁴⁹V. See (p,d) for details.
6765	1/2+		E(level): Level energy held fixed in least-squares adjustment.
6884	3/2+,5/2+		E(level): Strongest member of various possible IAS’s of ⁴⁹V. See (p,d) for details.
6995	1/2-,3/2-		E(level): Strongest member of various possible IAS’s of ⁴⁹V. See (p,d) for details.
7269.2	21/2+	0.18 ps 4	E(level): band BASED ON 13/2⁺. From (³He,αγ). T_1/2(level): From DSAM or Narrow Gate on Transitions Below in ¹²C(⁴⁰Ca,n2pγ),⁴⁰Ca(¹²C,n2pγ),...
8007.4	27/2-	0.190 ps 15	E(level): K^π=5/2-, α=1/2- GS ROTATIONAL band. From (³He,αγ). T_1/2(level): From DSAM or Narrow Gate on Transitions Below in ¹²C(⁴⁰Ca,n2pγ),⁴⁰Ca(¹²C,n2pγ),...
8331	1/2+		E(level): Strongest member of various possible IAS’s of ⁴⁹V. See (p,d) for details.
8333.3	25/2-	0.29 ps 6	E(level): K^π=5/2-, α=1/2⁺ GS ROTATIONAL band.
8527	3/2+,5/2+		T=(3/2) E(level): Strongest member of various possible IAS’s of ⁴⁹V. See (p,d) for details.
8770			E(level): Possible doublet. See (p,d).
8830	(1/2+)		E(level): Possible doublet. See (p,d).
8896	(1/2+)		E(level): Possible doublet. See (p,d).
9064	3/2+,5/2+		T=(3/2) E(level): Possible doublet. See (p,d). Strongest member of various possible IAS’s of ⁴⁹V. See (p,d) for details.
9198	(1/2+)		E(level): Possible doublet. See (p,d).
9365			E(level): Possible doublet. See (p,d).
E(level)	J^π(level)	T_1/2(level)	Comments
9745	(3/2+,5/2+)		E(level): Strongest member of various possible IAS’s of ⁴⁹V. See (p,d) for details.
9788	1/2+		E(level): Strongest member of various possible IAS’s of ⁴⁹V. See (p,d) for details.
10105	(3/2+,5/2+)		E(level): Strongest member of various possible IAS’s of ⁴⁹V. See (p,d) for details.
10125	(3/2+,5/2+)		E(level): Strongest member of various possible IAS’s of ⁴⁹V. See (p,d) for details.
10222.4	29/2-	0.0324 ps 8	E(level): K^π=5/2-, α=1/2⁺ GS ROTATIONAL band. From (³He,αγ). J^π(level): J\|)J or J\|)J-2 E2 γ for 10702\|)8009 and J\|)J-1 M1 and J\|)J-1 for 10702\|)10224\|)8009 establish Jπ(10224)=29/2- and Jπ(10702)=31/2-. T_1/2(level): From DSAM or Narrow Gate on Transitions Below in ¹²C(⁴⁰Ca,n2pγ),⁴⁰Ca(¹²C,n2pγ),...
10266	1/2+		E(level): Strongest member of various possible IAS’s of ⁴⁹V. See (p,d) for details.
10374	(3/2+,5/2+)		E(level): Strongest member of various possible IAS’s of ⁴⁹V. See (p,d) for details.
10700.3	31/2-	0.069 ps 14	E(level): K^π=5/2-, α=1/2- GS ROTATIONAL band. From (³He,αγ). J^π(level): J\|)J or J\|)J-2 E2 γ for 10702\|)8009 and J\|)J-1 M1 and J\|)J-1 for 10702\|)10224\|)8009 establish Jπ(10224)=29/2- and Jπ(10702)=31/2-. T_1/2(level): From DSAM or Narrow Gate on Transitions Below in ¹²C(⁴⁰Ca,n2pγ),⁴⁰Ca(¹²C,n2pγ),...

E(level)	E(gamma)	Comments
271.72	271.78	M(γ): D+Q from γ(θ) in (α,nγ) and (³He,αγ). Ne E1⁺M2 from δ and comparison to RUL. ΔJ=1 dipole transition from recoil-γ(θ) in ¹²C(⁴⁰Ca,n2pγ),⁴⁰Ca(¹²C,n2pγ),...
1083.6	812.0	I(γ): From (α,nγ) M(γ): from γ(θ), γγ(θ), and γ(linear pol) in (α,nγ). ΔJ=1 dipole transition from recoil-γ(θ) in ¹²C(⁴⁰Ca,n2pγ),⁴⁰Ca(¹²C,n2pγ),...
1083.6	1083.9	E(γ): Unweighted ave of 1084.9 4 from ¹²C(⁴⁰Ca,n2pγ),⁴⁰Ca(¹²C,n2pγ),... And 1083.0 10 from (α,nγ) I(γ): From (α,nγ) M(γ): d,Q from recoil-γ(θ) in ¹²C(⁴⁰Ca,n2pγ),⁴⁰Ca(¹²C,n2pγ),...; Ne M2 from comparison to RUL. ΔJπ=2,no from level scheme. ΔJ=2 quadrupole or ΔJ=0 dipole transition from recoil-Γ(\|Q) in ¹²C(⁴⁰calc,N2PΓ),⁴⁰calc(¹²C,N2PΓ),...
1562.1	478.63	I(γ): From (α,nγ). Branching ratios from (³He,αγ) are discrepant M(γ): from γ(θ), γγ(θ), and γ(linear pol) in (α,nγ). ΔJ=1 dipole transition from recoil-γ(θ) in ¹²C(⁴⁰Ca,n2pγ),⁴⁰Ca(¹²C,n2pγ),...
1562.1	1290.2	I(γ): From (α,nγ). Branching ratios from (³He,αγ) are discrepant M(γ): from γ(θ), γγ(θ), and γ(linear pol) in (α,nγ). ΔJ=2 quadrupole or ΔJ=0 dipole transition from recoil-Γ(\|Q) in ¹²C(⁴⁰calc,N2PΓ),⁴⁰calc(¹²C,N2PΓ),...
1703.2	1703.2	E(γ): From (α,nγ) I(γ): From (α,nγ) M(γ): ΔJ=2 quadrupole or ΔJ=0 dipole transition from recoil-Γ(\|Q) in ¹²C(⁴⁰calc,N2PΓ),⁴⁰calc(¹²C,N2PΓ),.... From γ(θ) and γ(linear pol) in (α,nγ)
1741.4	39	E(γ): From (α,nγ) I(γ): From (α,nγ)
	1469.3	E(γ): From (α,nγ) I(γ): From (α,nγ) M(γ): Q from γ(θ) and γγ(θ) in (α,nγ). Ne M2 from comparison to RUL
	1741.3	E(γ): From (α,nγ) I(γ): From (α,nγ) M(γ): from γ(θ) and γγ(θ). Δπ=no from level scheme. From γ(θ) and γγ(θ) in (α,nγ), except as noted
1981.8	240	E(γ): From (α,nγ) I(γ): Unweighted average of Iγ(240γ)/Iγ(279γ)/Iγ(1710γ)/Iγ(1982γ)=2.4 6/10 2/6 2/81 7 (2006Br03) and Iγ(278.2γ)/Iγ(1709.5γ)/Iγ(1981.4γ)=18 \.5 20/11.4 20/70.1 20 (1977Ka19) in (α,nγ) M(γ): Assigned as E1 by 2006Br03 in (α,nγ). Parentheses added by evaluator
	278.1	I(γ): Unweighted average of Iγ(240γ)/Iγ(279γ)/Iγ(1710γ)/Iγ(1982γ)=2.4 6/10 2/6 2/81 7 (2006Br03) and Iγ(278.2γ)/Iγ(1709.5γ)/Iγ(1981.4γ)=18 \.5 20/11.4 20/70.1 20 (1977Ka19) in (α,nγ)
	1709.5	E(γ): From (α,nγ) I(γ): Unweighted average of Iγ(240γ)/Iγ(279γ)/Iγ(1710γ)/Iγ(1982γ)=2.4 6/10 2/6 2/81 7 (2006Br03) and Iγ(278.2γ)/Iγ(1709.5γ)/Iγ(1981.4γ)=18 \.5 20/11.4 20/70.1 20 (1977Ka19) in (α,nγ)
	1981.3	I(γ): Unweighted average of Iγ(240γ)/Iγ(279γ)/Iγ(1710γ)/Iγ(1982γ)=2.4 6/10 2/6 2/81 7 (2006Br03) and Iγ(278.2γ)/Iγ(1709.5γ)/Iγ(1981.4γ)=18 \.5 20/11.4 20/70.1 20 (1977Ka19) in (α,nγ)
2168.5	427	E(γ): From (α,nγ) I(γ): From (α,nγ)
	465	E(γ): From (α,nγ) I(γ): From (α,nγ)
	1897.0	E(γ): From (α,nγ) I(γ): From (α,nγ)
	2168.2	E(γ): From (α,nγ) I(γ): From (α,nγ)
2431.8	450.2	I(γ): From (α,nγ) M(γ): From γ(θ) and γ(linear pol) in (α,nγ)
	690	E(γ): From (α,nγ) I(γ): From (α,nγ) M(γ): d,E2 from comparison to RUL. Δπ=yes from level scheme
	2161	E(γ): From (α,nγ) I(γ): From (α,nγ) M(γ): Assigned as E1 by 2006Br03 in (α,nγ). Parentheses added by evaluator
	2431.4	E(γ): weighted av (int.) of 2431.5 6 from (α,nγ) and 2431 1 from ¹²C(⁴⁰Ca,n2pγ),⁴⁰Ca(¹²C,n2pγ),... I(γ): From (α,nγ)
2500.1	937.4	I(γ): From (α,nγ) M(γ): d(+Q) from γ(θ) in (α,nγ). Δπ=no from level scheme. ΔJ=1 dipole transition from recoil-γ(θ) in ¹²C(⁴⁰Ca,n2pγ),⁴⁰Ca(¹²C,n2pγ),...
2500.1	1416.4	I(γ): From (α,nγ) M(γ): d,Q from recoil-γ(θ) in ¹²C(⁴⁰Ca,n2pγ),⁴⁰Ca(¹²C,n2pγ),...; Ne M2 from comparison to RUL. ΔJπ=2,no from level scheme. ΔJ=2 quadrupole or ΔJ=0 dipole transition from recoil-Γ(\|Q) in ¹²C(⁴⁰calc,N2PΓ),⁴⁰calc(¹²C,N2PΓ),...
2502.6	335	E(γ): From (α,nγ) I(γ): From (α,nγ)
	1420	E(γ): From (α,nγ) I(γ): From (α,nγ)
	2232.1	E(γ): weighted av (int.) of 2231.5 10 from β⁺ decay and 2232.6 10 from (α,nγ) I(γ): From (α,nγ) M(γ): From γ(θ) and γγ(θ) in (α,nγ), except as noted
	2503.4	E(γ): weighted av (ext.) of 2504.8 10 from β⁺ decay and 2503.1 5 from (α,nγ). Level energy held fixed in least-squares adjustment I(γ): From (α,nγ) M(γ): From γ(θ) and γ(linear pol) in (α,nγ)
E(level)	E(gamma)	Comments
2578.1	596	E(γ): From (α,nγ) I(γ): From (α,nγ)
	836.5	E(γ): From (α,nγ) I(γ): From (α,nγ) M(γ): Assigned as E1 by 2006Br03 in (α,nγ). Parentheses added by evaluator
	875.3	E(γ): From (α,nγ) I(γ): From (α,nγ) M(γ): Assigned as E1 by 2006Br03 in (α,nγ). Parentheses added by evaluator
2613.1	2341.7	E(γ): From (α,nγ) I(γ): From (α,nγ)
2613.1	2611.8	E(γ): From (α,nγ) I(γ): From (α,nγ) M(γ): From γ(θ) and γ(linear pol) in (α,nγ)
2911.7	480	E(γ): From (α,nγ) I(γ): From (α,nγ) M(γ): from comparison to RUL. Assigned as E1 by 2006Br03 in (α,nγ)
	930	E(γ): From (α,nγ) I(γ): From (α,nγ) M(γ): assigned as E1 by 2006Br03 in (α,nγ). d,E2 from comparison to RUL. ΔJπ=2,no from level scheme
	2640	E(γ): From (α,nγ) I(γ): From (α,nγ) M(γ): d,E2 from comparison to RUL. Δπ=yes from level scheme
	2912	E(γ): From (α,nγ) I(γ): From (α,nγ)
2978.7	401	E(γ): From (α,nγ) I(γ): From (α,nγ)
	547	E(γ): From (α,nγ) I(γ): From (α,nγ)
	810	E(γ): From (α,nγ) I(γ): From (α,nγ) M(γ): Assigned as (E1) by 2006Br03 in (α,nγ)
	997	E(γ): From (α,nγ) I(γ): From (α,nγ) M(γ): Assigned as (E1) by 2006Br03 in (α,nγ)
	1237	E(γ): From (α,nγ) I(γ): From (α,nγ) M(γ): Assigned as (E1) by 2006Br03 in (α,nγ)
	2979	E(γ): From (α,nγ) M(γ): Assigned as (E1) by 2006Br03 in (α,nγ)
3051.7	1968	E(γ): From (α,nγ) I(γ): From (α,nγ)
	2780	E(γ): From (α,nγ) I(γ): From (α,nγ)
	3052	E(γ): From (α,nγ)
3190.1	690.2	I(γ): From (α,nγ) M(γ): ΔJ=1 dipole transition from recoil-γ(θ) in ¹²C(⁴⁰Ca,n2pγ),⁴⁰Ca(¹²C,n2pγ),...
3190.1	1627.8	I(γ): From (α,nγ) M(γ): ΔJ=0 d or ΔJ=2 Q γ from AD in ¹²C(⁴⁰Ca,n2pγ),⁴⁰Ca(¹²C,n2pγ),... Ne M2 from comparison to RUL. ΔJπ=2,no from level scheme
3201.7	2118	E(γ): From (α,nγ) I(γ): From (α,nγ)
	2930	E(γ): From (α,nγ) I(γ): From (α,nγ)
	3202	E(γ): From (α,nγ)
3250.9	819	E(γ): From (α,nγ) I(γ): From (α,nγ) M(γ): d from comparison to RUL. Δπ=no from level scheme
	1269	E(γ): From (α,nγ) I(γ): From (α,nγ) M(γ): Assigned as (E1) by 2006Br03 in (α,nγ)
	2979	E(γ): From (α,nγ) I(γ): From (α,nγ)
	3251	E(γ): From (α,nγ) I(γ): From (α,nγ) M(γ): d,Q from comparison to RUL. Δπ=yes from level scheme
E(level)	E(gamma)	Comments
3407	794	E(γ): From (α,nγ)
3499.7	2416	E(γ): From (α,nγ) I(γ): From (α,nγ)
3511	2.44E+3	E(γ): From (³He,αγ). Possible doublet. See (p,d) I(γ): From (³He,αγ)
	3.24E+3	E(γ): From (³He,αγ)
	3.51E+3	E(γ): From (³He,αγ). Possible doublet. See (p,d) I(γ): From (³He,αγ)
3527.6	337.2	I(γ): weighted av (int.) from ¹²C(⁴⁰Ca,n2pγ),⁴⁰Ca(¹²C, \n2pγ),... And (α,nγ)
	1027.6	I(γ): weighted av (int.) from ¹²C(⁴⁰Ca,n2pγ),⁴⁰Ca(¹²C, \n2pγ),... And (α,nγ) M(γ): ΔJ=0 d or ΔJ=2 Q γ from AD in ¹²C(⁴⁰Ca,n2pγ),⁴⁰Ca(¹²C,n2pγ),... Ne M2 from comparison to RUL
	1965.4	M(γ): J\|)J-1 γ from AD in ¹²C(⁴⁰Ca,n2pγ),⁴⁰Ca(¹²C, \n2pγ),... Δπ=no from level scheme
	2444.0	M(γ): d,Q from comparison to RUL. ΔJπ=2,no from level scheme
3628.6	717	E(γ): From (α,nγ) I(γ): From (α,nγ)
	1197	E(γ): From (α,nγ) I(γ): From (α,nγ) M(γ): d,E2 from comparison to RUL. ΔJπ=2,no from level scheme
	2066	E(γ): From (α,nγ) I(γ): From (α,nγ) M(γ): Assigned as E1 by 2006Br03 in (α,nγ). Parentheses added by evaluator
	2545	E(γ): From (α,nγ) I(γ): From (α,nγ) M(γ): Assigned as E1 by 2006Br03 in (α,nγ). Parentheses added by evaluator
	3357	E(γ): From (α,nγ) I(γ): From (α,nγ) M(γ): Assigned as E1 by 2006Br03 in (α,nγ). Parentheses added by evaluator
3687.4	2125	E(γ): From (α,nγ) I(γ): From (α,nγ)
3687.4	2604	E(γ): From (α,nγ) I(γ): From (α,nγ)
3802.4	1301	E(γ): From (α,nγ) I(γ): From (α,nγ)
	2718	E(γ): From (α,nγ) I(γ): From (α,nγ)
	3530	E(γ): From (α,nγ) I(γ): From (α,nγ) M(γ): d,Q from comparison to RUL. ΔJπ=2,no from level scheme
3843.9	1412	E(γ): From (α,nγ) I(γ): From (α,nγ)
	3572	M(γ): Assigned as (E1) by 2006Br03 in (α,nγ)
	3844	M(γ): Assigned as (E1) by 2006Br03 in (α,nγ)
3892.2	364.4	M(γ): ΔJ=0 d or ΔJ=2 Q γ from AD in ¹²C(⁴⁰Ca,n2pγ),⁴⁰Ca(¹²C,n2pγ),... E1 consistent with AD ratios for 364 and 702 γ’s in ¹²C(⁴⁰Ca,n2pγ),⁴⁰Ca(¹²C,n2pγ),... (1999Br40).
	702.2	M(γ): ΔJ=1 d γ in ¹²C(⁴⁰Ca,n2pγ),⁴⁰Ca(¹²C,n2pγ), \... Δπ=yes from level scheme
	1395	M(γ): Assigned as (E1) by 2006Br03 in (α,nγ)
	2332	M(γ): J\|)J-1 γ from AD in ¹²C(⁴⁰Ca,n2pγ),⁴⁰Ca(¹²C, \n2pγ),... Δπ=yes from level scheme
E(level)	E(gamma)	Comments
3899.1	709	E(γ): From (α,nγ) I(γ): From (α,nγ)
	1399	E(γ): From (α,nγ) I(γ): From (α,nγ)
	2337	E(γ): From (α,nγ) I(γ): From (α,nγ) M(γ): d,Q from comparison to RUL. ΔJπ=2,no from level scheme
3913	1.33E+3	E(γ): Multiply placed. From (³He,αγ)
	1.33E+3	E(γ): Multiply placed. From (³He,αγ)
	1.95E+3	E(γ): From (³He,αγ)
	2.20E+3	E(γ): Multiply placed. From (³He,αγ)
	2.20E+3	E(γ): Multiply placed. From (³He,αγ)
3928.8	1947	E(γ): From (α,nγ)
4051.5	1140	E(γ): From (α,nγ) I(γ): From (α,nγ)
	2489	E(γ): From (α,nγ) I(γ): From (α,nγ) M(γ): Assigned as (E1) by 2006Br03 in (α,nγ)
	2968	E(γ): From (α,nγ) I(γ): From (α,nγ) M(γ): Assigned as (E1) by 2006Br03 in (α,nγ)
4105.7	3021	M(γ): d,E2 from comparison to RUL. ΔJπ=2,no from level scheme
4201.7	1700	E(γ): From (α,nγ) I(γ): From (α,nγ)
4201.7	3117	E(γ): From (α,nγ) I(γ): From (α,nγ) M(γ): d,E2 from comparison to RUL. ΔJπ=2,no from level scheme
4218.1	1027.8	M(γ): J\|)J-1 γ from AD and DCO in ¹²C(⁴⁰Ca,n2pγ),⁴⁰Ca(¹²C,n2pγ),...
4218.1	1717.4	E(γ): Strongest member of various possible IAS’s of ⁴⁹V. See (p,d) for details M(γ): J\|)J d or J\|)J-2 Q γ from AD in ¹²C(⁴⁰Ca,n2pγ),⁴⁰Ca(¹²C,n2pγ),... Ne M2 from comparison to RUL. ΔJπ=2,no from level scheme
4279.5	651	E(γ): From (α,nγ) I(γ): From (α,nγ)
	1368	E(γ): From (α,nγ) I(γ): From (α,nγ) M(γ): d,E2 from comparison to RUL. ΔJπ=2,no from level scheme
	2717	E(γ): From (α,nγ) I(γ): From (α,nγ) M(γ): Assigned as E1 by 2006Br03 in (α,nγ). Parentheses added by evaluator
	3196	E(γ): From (α,nγ) I(γ): From (α,nγ) M(γ): Assigned as E1 by 2006Br03 in (α,nγ). Parentheses added by evaluator
4296.8	1385	E(γ): From (α,nγ) I(γ): From (α,nγ)
4296.8	4025	E(γ): From (α,nγ) M(γ): Assigned as (E1) by 2006Br03 in (α,nγ)
4366.0	148.1	M(γ): J\|)J-1 γ from AD and DCO in ¹²C(⁴⁰Ca,n2pγ),⁴⁰Ca(¹²C,n2pγ),...
4366.0	1176.6	M(γ): J\|)J d or J\|)J-2 Q γ from AD and DCO in ¹²C(⁴⁰Ca,n2pγ),⁴⁰Ca(¹²C,n2pγ),..; large Q component from γ(θ) in ¹²C(⁴⁰Ca,n2pγ),⁴⁰Ca(¹²C,n2pγ),.. Ne M2 from comparison to RUL
E(level)	E(gamma)	Comments
4426	2440	E(γ): From (α,nγ)
4459.7	3376	E(γ): From (α,nγ) I(γ): From (α,nγ) M(γ): Assigned as (E1) by 2006Br03 in (α,nγ)
4467.1	939.3	M(γ): d,E2 from comparison to RUL. Δπ=yes from level scheme
4467.1	1276.7	M(γ): ΔJ=0 d or ΔJ=2 Q γ from AD in ¹²C(⁴⁰Ca,n2pγ),⁴⁰Ca(¹²C,n2pγ),... Ne M2 from comparison to RUL. Δπ=yes from level scheme
4571.5	352	E(γ): From (α,nγ) I(γ): From (α,nγ)
	1382	E(γ): From (α,nγ) I(γ): From (α,nγ)
	2072	E(γ): From (α,nγ) I(γ): From (α,nγ) M(γ): d,E2 from comparison to RUL. ΔJπ=2,no from level scheme
4586.5	2605	E(γ): From (α,nγ)
4716.2	2216	E(γ): From (α,nγ) I(γ): From (α,nγ) M(γ): d,E2 from comparison to RUL. Δπ=yes from level scheme
4716.2	3154	E(γ): From (α,nγ) I(γ): From (α,nγ) M(γ): Assigned as (E1) by 2006Br03 in (α,nγ)
4749.4	2248	E(γ): From (α,nγ) I(γ): From (α,nγ)
4749.4	3186	E(γ): From (α,nγ) I(γ): From (α,nγ)
4764	3.69E+3	E(γ): From (³He,αγ). Possible doublet. See (p,d) I(γ): From (³He,αγ)
	4.49E+3	E(γ): From (³He,αγ). Possible doublet. See (p,d) I(γ): From (³He,αγ)
	4.76E+3	E(γ): From (³He,αγ). Possible doublet. See (p,d) I(γ): From (³He,αγ)
4809.1	1619	E(γ): From (α,nγ) I(γ): From (α,nγ)
4809.1	2309	E(γ): From (α,nγ) I(γ): From (α,nγ)
4837.2	3275	E(γ): From (α,nγ)
4943.6	1315	E(γ): From (α,nγ) I(γ): From (α,nγ)
4943.6	3860	E(γ): From (α,nγ) I(γ): From (α,nγ) M(γ): Assigned as E1 by 2006Br03 in (α,nγ). Parentheses added by evaluator
5032.3	3470	E(γ): From (α,nγ)
5048.4	769	E(γ): From (α,nγ) I(γ): From (α,nγ)
	1420	E(γ): From (α,nγ) I(γ): From (α,nγ)
	2548	E(γ): From (α,nγ) I(γ): From (α,nγ) M(γ): from comparison to RUL. Assigned as (E1) by 2006Br03 in (α,nγ)
	3486	E(γ): From (α,nγ) I(γ): From (α,nγ) M(γ): Assigned as (E1) by 2006Br03 in (α,nγ)
E(level)	E(gamma)	Comments
5179.7	2677	E(γ): From (α,nγ)
5302.7	1410.8	M(γ): ΔJ=2 Q from AD in ¹²C(⁴⁰Ca,n2pγ),⁴⁰Ca(¹²C, \n2pγ),...; Ne M2 from comparison to RUL
5573	3.14E+3	E(γ): From (³He,αγ). Possible doublet. See (p,d) I(γ): From (³He,αγ)
	3.59E+3	E(γ): From (³He,αγ). Possible doublet. See (p,d) I(γ): From (³He,αγ)
	5.57E+3	E(γ): From (³He,αγ). Possible doublet. See (p,d) I(γ): From (³He,αγ)
5962.4	1596.3	E(γ): Strongest member of various possible IAS’s of ⁴⁹V. See (p,d) for details M(γ): J\|)J d or J\|)J-2 Q γ from AD in ¹²C(⁴⁰Ca,n2pγ),⁴⁰Ca(¹²C,n2pγ),... Ne M2 from comparison to RUL. ΔJπ=2,no from level scheme
6134.1	1768.9	M(γ): ΔJ=1 d from AD in ¹²C(⁴⁰Ca,n2pγ),⁴⁰Ca(¹²C, \n2pγ),...
6134.1	1915.0	M(γ): ΔJ=0 d or ΔJ=2 Q γ from AD in ¹²C(⁴⁰Ca,n2pγ),⁴⁰Ca(¹²C,n2pγ),... Ne M2 from comparison to RUL. ΔJπ=2,no from level scheme
6341.9	1874.4	M(γ): ΔJ=2 Q transition from AD in ¹²C(⁴⁰Ca,n2pγ),⁴⁰Ca(¹²C,n2pγ),... Ne M2 from comparison to RUL
6423	2.50E+3	E(γ): From (³He,αγ). Possible doublet. See (p,d) I(γ): From (³He,αγ)
	3.83E+3	E(γ): Multiply placed with undivided intensity. From (³He,αγ). Possible doublet. See (p,d) I(γ): Multiply placed with undivided intensity. From (³He,αγ)
	3.83E+3	E(γ): Multiply placed with undivided intensity. From (³He,αγ). Possible doublet. See (p,d) I(γ): Multiply placed with undivided intensity. From (³He,αγ)
	4.70E+3	E(γ): Multiply placed with undivided intensity. From (³He,αγ). Possible doublet. See (p,d) I(γ): Multiply placed with undivided intensity. From (³He,αγ)
	4.70E+3	E(γ): Multiply placed with undivided intensity. From (³He,αγ). Possible doublet. See (p,d) I(γ): Multiply placed with undivided intensity. From (³He,αγ)
6470	2.54E+3	E(γ): From (³He,αγ). Possible doublet. See (p,d) I(γ): From (³He,αγ)
	3.87E+3	E(γ): Multiply placed with undivided intensity. From (³He,αγ). Possible doublet. See (p,d) I(γ): Multiply placed with undivided intensity. From (³He,αγ)
	3.87E+3	E(γ): Multiply placed with undivided intensity. From (³He,αγ). Possible doublet. See (p,d) I(γ): Multiply placed with undivided intensity. From (³He,αγ)
	4.74E+3	E(γ): Multiply placed with undivided intensity. From (³He,αγ). Possible doublet. See (p,d) I(γ): Multiply placed with undivided intensity. From (³He,αγ)
	4.74E+3	E(γ): Multiply placed with undivided intensity. From (³He,αγ). Possible doublet. See (p,d) I(γ): Multiply placed with undivided intensity. From (³He,αγ)
6765	2.83E+3	E(γ): From (³He,αγ)
	4.16E+3	E(γ): Multiply placed. From (³He,αγ)
	4.16E+3	E(γ): Multiply placed. From (³He,αγ)
	5.03E+3	E(γ): Multiply placed. From (³He,αγ)
	5.03E+3	E(γ): Multiply placed. From (³He,αγ)
7269.2	1966.6	M(γ): d,E2 from comparison to RUL. Recoil-γ(θ) in ¹²C(⁴⁰Ca,n2pγ),⁴⁰Ca(¹²C,n2pγ),... Consistent with pure Q
E(level)	E(gamma)	Comments
8007.4	2045	E(γ): Strongest member of various possible IAS’s of ⁴⁹V. See (p,d) for details M(γ): J\|)J d or J\|)J-2 Q γ from AD in ¹²C(⁴⁰Ca,n2pγ),⁴⁰Ca(¹²C,n2pγ),... Ne M2 from comparison to RUL. ΔJπ=2,no from level scheme
8333.3	325.9	M(γ): ΔJ=1 from AD and DCO in ¹²C(⁴⁰Ca,n2pγ), \⁴⁰Ca(¹²C,n2pγ),... M1 from comparison to RUL
10222.4	2215.1	M(γ): J\|)J-1 γ from AD in ¹²C(⁴⁰Ca,n2pγ),⁴⁰Ca(¹²C, \n2pγ),...
10700.3	478.4	M(γ): J\|)J-1 γ from AD in ¹²C(⁴⁰Ca,n2pγ),⁴⁰Ca(¹²C, \n2pγ),... M1 from comparison to RUL
10700.3	2692.6	E(γ): Strongest member of various possible IAS’s of ⁴⁹V. See (p,d) for details M(γ): J\|)J d or J\|)J-2 Q γ from AD in ¹²C(⁴⁰Ca,n2pγ),⁴⁰Ca(¹²C,n2pγ),... Ne M2 from comparison to RUL. ΔJπ=2,no from level scheme