List of levels for 58NI

Authors: Caroline D. Nesaraja, Scott D. Geraedts and Balraj Singh | Citation: Nucl. Data Sheets 111, 897 (2010) | Cutoff date: 12-Jan-2010

Other reactions:

⁵⁶Fe(¹²C,¹⁰Be): 1998Pa43: E=60 MeV, σ(θ)

⁵⁸Ni(⁶Li,⁶Li’): 1994Sa33,1989Na11; elastic and inelastic scattering. Extracted deformation parameters, optical model potential.

⁵⁸Ni(⁶Li,⁶Li): 2000Sc11: E=600 MeV; 2009Ag02: E=9.9, 11.2, 12.1, 13.0, 14.0 MeV; measured σ, σ(θ)

⁵⁸Ni(⁷Li,⁷Li’): 2000Gu17, 1999Gu02: E=42 MeV, σ(θ)

⁵⁸Ni(pol ⁷Li,⁷Li): 1995De06: E=70.5 MeV, σ(θ), Ay(θ)

⁵⁸Ni(⁷Be,⁷Be): 2009Ag02: E=15.1, 17.1, 18.5, 19.9, 21.4 MeV; measured σ, σ(θ)

⁵⁸Ni(⁸B,⁸B): 2009Ag02: E=20.7, 23.4, 25.3, 27.2, 29.3 MeV; measured σ(θ)

⁵⁸Ni(⁸β,p⁷Be): 2008Ag11: E=25.0, 26.9, 28.4 MeV; measured light fragment energy spectra, σ(θ), excitation functions

⁵⁸Ni(¹²C,¹²C), (¹²C,¹²C’): 1987FeZX; DWBA analysis extracted deformation parameters.

⁵⁸Ni(¹⁴N,¹⁴N’): 1990Ga07; studied relationship between centroid and Γ of giant quadrupole resonance and neutron binding energy.

⁵⁸Ni(¹⁸O,¹⁸O): 1997Si13: E=35.1-55.1 MeV, σ(θ)

⁵⁸Ni(²⁸Si,²⁸Si): 2003Ga18: E=74-77 MeV, σ(θ)

⁵⁸Ni(⁴⁶Ti,⁴⁶Ti’), (⁵⁸Ni,⁵⁸Ni’), (⁶²Ni,⁶²Ni’): 2000Va28: E=96.9-116.5 MeV, σ(θ)

⁵⁸Ni(⁵⁸Ni,⁵⁸Ni): 2007Hi06: E=220-260 MeV, σ(θ)

⁵⁸Ni(⁵⁸Ni,⁵⁸Ni): 1996Va10: E=220-240 MeV, σ(θ)

⁵⁸Ni(⁵⁸Ni,⁵⁸Ni): 1994Me24: E=200 MeV, σ(θ)

⁵⁸Ni(π,π), ⁵⁸Ni(π⁺,π⁺’), ⁵⁸Ni(π^-,π^-’): 1996La04, 1991Ra22, 1989Oa01; strong absorption model analysis of elastic scattering to extract deformation

⁵⁸Ni mesic atoms, pionic x-rays: 1990Ku08, interaction shifts, and widths.

⁵⁸Ni(d,n): 1993InZZ; deduced occupation probabilities of proton orbits

⁵⁸Ni(α,α): 1992Du08; analysis of total cross section data to extract mean square radii of matter distribution.

Cu(K-,γ): 1972Ba55.

Structure calculations (levels, transition probabilities, etc.): 2009Be24, 2007Sv01, 2006Va21, 2004Ho08, 1999Ha21, 1977Ko02, 1975Va08, 1974Pa13, 1972Gl05, 1972Ob02

Levels: Individual values of |t in ps for first 2⁺ state at 1454 keV that were used in averaging are given below:

Levels: 1. Deduced from B(E2) measurement in Coulomb excitation: 0.82 16 (1960An07, earlier value of 0.67 17 in 1959Al95), 0.95 6 and 1.04 22 (1960Go08), 0.88 9 (1962St02), 0.860 20 (1970Le17), 0.924 28 (1971ChZF), 0.83 17 (2004Yu10).

Levels: 2. From Γ in (γ,γ’): 0.62 20 (1964Bo22), 0.98 9 (1970Me18), 1.07 8 (1972ArZD), 0.90 11 (1981Ca10).

Levels: 3. From B(E2) in (e,e’): 0.956 16 (1967Du07), 1.14 6 (1969Af01), 1.07 9 (1983Kl09). Uncertainties in B(E2) are statistical, 15% for systematic uncertainty as suggested in 1967Du07 is added in quadrature. Other: 0.65 9 (1961Cr01), not included in the averaging procedure

Levels: 4. From DSAM in (p,p’γ): 0.94 12 (1969Be48), 0.92 17 (1973BeYD)

Levels: 5. From DSAM in (n,n’γ): 1.00 ps +15-10 (2008Or02,weighted average of two measurements at E(n)=1.6 and 1.8 MeV). Value of 42 fs 12 from 1989Ge09 is discrepant and highly suspect.

Levels: 6. From DSAM in Coulomb excitation: 1.27 2 (2001Ke08), uncertainty is increased to 0.07 to take into account 5% systematic uncertainty due to stopping powers, as suggested by one of the authors of 2001Ke08 in an e-mail reply in December 2007. It should be pointed that this value stands as the highest amongst all the others and is higher by ≈35% from the precise values deduced from B(E2) values in Coulomb excitation. In the e-mail reply, the author of 2001Ke08 claimed that their measurements are reliable for two main reasons: a) the γ rays were detected in coincidence with scattered ¹²C ions thus giving clean γ-ray spectra, b) high ion velocities in inverse kinematics used for the first time. In a thesis by 2005NiZS where lifetime of first 2⁺ state in ²²Ne was measured using Coulomb excitation technique and ^natNi and {107Ag as targets, the results for first 2⁺ state in ²²Ne were found to be consistent in the two measurements only when B(E2) value for first 2⁺ state from Coulomb excitation data was used. Use of the lifetime from 2001Ke08 gave inconsistent results.

Q-value: Note: Current evaluation has used the following Q record -8565.6 1412217.0 188172.4 5 -6400.0 6 2009AuZZ,2003Au03

Q-value: S(2n)=22467 11, S(2p)=14200.2 6 (2009AuZZ)

E(level): From a least-squares fit to Eγ’s for levels populated in γ-ray studies. For levels populated in particle-transfer and inelastic scattering studies, the values are averaged over all available data. For levels populated in (γ,γ’), values are as given in the ⁵⁸Ni(γ,γ’) dataset.

J^π(level): For high-spin (J>6) levels, all assignments are from γ-ray cascades observed in in-beam γ-ray studies: ²⁸Si(³⁶Ar,α2pγ),²⁸Si(³²S,2pγ); ⁴⁰Ca(²⁴Mg,α2pγ); ⁴⁵Sc(¹⁶O,p2nγ); ⁴⁸Ti(¹²C,2nγ) and ⁵⁶Fe(α,2nγ). For many transitions angular distribution/correlation data support these assignments. For a few transitions, supporting γ(lin pol) data are available. In addition, ascending spins are assumed in these reactions as the excitation energy rises. Arguments for individual are given for levels below 10 MeV. Above this energy, all assignments are as proposed in ²⁸Si(³⁶Ar,α2pγ) reaction by 2009Jo03 and their previous papers, based on DCO data for selected transitions and γ cascades. The parentheses have been added by the evaluators since strong supporting arguments from polarization or other parity-sensitive seem to be lacking. When Jπ is deduced from L-transfers, target Jπ=0⁺ in all reactions.

T_1/2(level): From ΔS(a) in (p,p’γ) (1969Be48), except where noted otherwise. Weighted or unweighted averages are taken when values are available from different reactions. Values from (γ,γ’) are deduced from measured Γ₀²/Γ and branching ratios.

E(level) (keV)	J^π(level)	T_1/2(level)	E(γ) (keV)	Multipolarity	Mixing Ratio	Conversion Coefficient	Additional Data
1454.21	2+	0.652 ps 21	1454.28 10	E2			B(E2)(W.u.)=10.0 4
2459.21	4+	3.7 ps 4	1004.80 15	E2			B(E2)(W.u.)=11.2 12
2775.42	2+	0.38 ps +12-9	1321.2 2	E2+M1	-1.1 1		B(E2)(W.u.)=15 +4-5, B(M1)(W.u.)=0.011 +3-4
2775.42	2+	0.38 ps +12-9	2775.5 4	E2			B(E2)(W.u.)=0.029 +8-10
2902.15	1+	69 fs +15-14	2901.3 5	(M1)			B(M1)(W.u.)=0.00079 +18-19
2942.56	0+	1.46 ns 14	40.3 4	[M1]		0.581	B(M1)(W.u.)=0.116 14, α=0.581 19, α(K)=0.519 17, α(L)=0.0541 18, α(M)=0.000762 25
	0+	1.46 ns 14	167.2 2	[E2]		0.0809	B(E2)(W.u.)=21 3, α=0.0809, α(K)=0.0722, α(L)=0.00761, α(M)=0.001063
	0+	1.46 ns 14	1488.3 3	[E2]			B(E2)(W.u.)=0.00040 6
3037.86	2+	57 fs 8	262.6 3	M1(+E2)	-0.03 5		B(E2)(W.u.)=5 +18-5, B(M1)(W.u.)=0.21 5
	2+	57 fs 8	1583.8 3	M1+E2	+0.21 3		B(E2)(W.u.)=1.8 6, B(M1)(W.u.)=0.055 8
	2+	57 fs 8	3037.7 3	[E2]			B(E2)(W.u.)=1.15 17
3263.66	2+	37 fs 5	1809.5 3	M1+E2	+0.7 4		B(E2)(W.u.)=8 6, B(M1)(W.u.)=0.027 11
3263.66	2+	37 fs 5	3263.4 4	[E2]			B(E2)(W.u.)=1.9 3
3420.55	3+	0.26 ps +22-10	382.9 3	(M1(+E2))	+0.08 9		B(E2)(W.u.)=(7 +15-7), B(M1)(W.u.)=(0.08 +3-7)
3420.55	3+	0.26 ps +22-10	961.0 2	(M1(+E2))	-0.02 3		B(E2)(W.u.)=(0.07 +23-7), B(M1)(W.u.)=(0.09 +4-8)
3531.1	0+	0.19 ps 6	2076.9 3	[E2]			B(E2)(W.u.)=5.6 18
3620.09	4+	0.11 ps +8-5	1161.2 3	(M1(+E2))	+0.6 +3-6		B(E2)(W.u.)=(4.×10¹ 4), B(M1)(W.u.)=(0.07 +4-6)
3620.09	4+	0.11 ps +8-5	2166.3 5	E2			B(E2)(W.u.)=1.3 +7-10
3775.0	3+	0.28 ps +14-7	354.5 3	(M1(+E2))	+0.05 +21-12		B(E2)(W.u.)=(1.×10¹ +11-1), B(M1)(W.u.)=(0.33 +9-17)
3775.0	3+	0.28 ps +14-7	1316.4 15	M1(+E2)	+0.19 15		B(E2)(W.u.)=(0.8 +12-8), B(M1)(W.u.)=(0.019 +5-10)
3898.8	2+	23 fs 6	2444.7 4	[M1]			B(M1)(W.u.)=0.050 13
3898.8	2+	23 fs 6	3898.0 7	[E2]			B(E2)(W.u.)=0.50 14
4108.4	2+	128 fs 55	1332.5	[M1]			B(M1)(W.u.)=0.0044 24
	2+	128 fs 55	2654.6 4	M1+E2	-0.58 +8-9		B(E2)(W.u.)=0.26 13, B(M1)(W.u.)=0.0028 13
	2+	128 fs 55	4107.4 7	[E2]			B(E2)(W.u.)=0.13 6
E(level) (keV)	J^π(level)	T_1/2(level)	E(γ) (keV)	Multipolarity	Mixing Ratio	Conversion Coefficient	Additional Data
4294.7	4+	24 fs +22-18	2840.8 10	[E2]			B(E2)(W.u.)=6 +5-6
4383.0	(5+)		763.0 3	(M1+E2)	-0.38 5
4383.0	(5+)		1923.9 7	D+Q	+0.27 10
4404.3	4+	43 fs +17-14	2951.3 11	E2			B(E2)(W.u.)=4.4 +15-18
4474.6	3-	22 fs 6	1697.5 9	[E1]			B(E1)(W.u.)=0.0008 4
4474.6	3-	22 fs 6	3021.1 6	[E1]			B(E1)(W.u.)=0.00060 22
4538.0	0+	31 fs 11	3083.7 6	[E2]			B(E2)(W.u.)=4.9 18
4964.7	(5+)		2503.8 13	D+Q	-0.42 4
5127.5	6+		744.6 3	(M1+E2)	-0.42 4
5905.3	1+	25 fs 4	5905.3 7	M1			B(M1)(W.u.)=0.0043 7
6027.3	1-	0.85 fs 5	6027.3 7	E1			B(E1)(W.u.)=0.00197 17
6067.5	(7+)		322.8 2	(M1+E2)	-0.18 10
	(7+)		682.7 5	(M1+E2)	-0.11 8
	(7+)		940.1 4	(M1+E2)	-0.36 4
6084.7	7-		699.6 8	E1(+M2)	-0.06 13
6084.7	7-		957.1 7	E1(+M2)	-0.06 5
6220.0	(7+)		835.5 6	D+Q	-0.08 4
6604.6	(8+)		537.0 3	(M1+E2)	-0.18 3
7048.2	1-	0.83 fs 3	7048.2 9	E1			B(E1)(W.u.)=0.00155 6
7273.7	7-		2146.4 15	E1+M2	-0.19 6
7314.8	(8+)		1245.9 9	D+Q	-0.15 5
7388.8	1+	1.00 fs 5	7388.8 4	M1			B(M1)(W.u.)=0.055 3
7446.2	(9+)		841.6 4	(M1+E2)	-0.18 3
7709.7	1+	0.72 fs 3	7709.7 6	M1			B(M1)(W.u.)=0.067 3
7807.3	1-	0.81 fs 10	7807.3 5	E1			B(E1)(W.u.)=0.00117 15
E(level) (keV)	J^π(level)	T_1/2(level)	E(γ) (keV)	Multipolarity	Mixing Ratio	Conversion Coefficient	Additional Data
7973.6	(8+)		1752.0 11	D+Q	-0.37 8
7982.8	(8-)		709.2 5	(M1+E2)	-0.15 3
7982.8	(8-)		1915.6 13	D+Q	-0.17 6
8068.6	(1-)	1.38 fs 17	8068.6 12	(E1)			B(E1)(W.u.)=0.00062 8
8074.5	(8+)		1854.3 13	D+Q	-0.21 8
8120.8	(9+)		1516.6 7	D+Q	-0.13 4
8237.3	1-	0.15 fs +3-2	8237.3 4	E1			B(E1)(W.u.)=0.0054 +8-11
8395.1	1-	0.40 fs 8	8395.1 12	E1			B(E1)(W.u.)=0.0019 6
8461.0	1+	0.51 fs 3	8461.0 7	M1			B(M1)(W.u.)=0.071 5
8514.1	1-	0.66 fs 5	8514.1 4	E1			B(E1)(W.u.)=0.00111 9
8552.7	1(+)	0.97 fs 8	8552.7 13	[M1]			B(M1)(W.u.)=0.036 3
8600.5	1+	0.57 fs 6	8600.5 7	M1			B(M1)(W.u.)=0.061 7
8679.3	1+	0.223 fs 11	8679.3 8	M1			B(M1)(W.u.)=0.151 8
8718.1	(9-)		735.4 5	(M1+E2)	-0.16 3
	(9-)		1403.2 10	D+Q	-0.13 10
	(9-)		2114.0 15	D(+Q)	-0.03 4
8857.4	1(+)	0.61 fs 12	8857.4 6	[M1]			B(M1)(W.u.)=0.052 11
8880.2	1-	0.390 fs 17	8880.2 6	E1			B(E1)(W.u.)=0.00165 8
8934.6	1(-)	0.310 fs 11	8934.6 5	(E1)			B(E1)(W.u.)=0.00204 8
8961.3	1+	1.20 fs 13	8961.3 7	[M1]			B(M1)(W.u.)=0.026 3
9062.7	(10+)		941.1 7	M1+E2	-0.24 6
9073.4	1+	0.51 fs 3	9073.4 6	(M1)			B(M1)(W.u.)=0.058 4
9156.9	1+	0.77 fs 10	9156.9 7	M1			B(M1)(W.u.)=0.037 5
9190.7	1-	0.58 fs 6	9190.7 5	E1			B(E1)(W.u.)=0.00100 11
9345.5	(10-)		627.5 5	(M1+E2)	-0.15 3
9345.5	(10-)		1899.9 13	D+Q	-0.16 3
E(level) (keV)	J^π(level)	T_1/2(level)	E(γ) (keV)	Multipolarity	Mixing Ratio	Conversion Coefficient	Additional Data
9368.5	1(+)	0.37 fs 4	9368.5 6	[M1]			B(M1)(W.u.)=0.072 8
9523.3	1-	0.118 fs 13	9523.3 13	E1			B(E1)(W.u.)=0.0026 5
9723.0	1(-)	0.109 fs 16	9723.0 9	(E1)			B(E1)(W.u.)=0.0019 4
9843	1+	0.26 fs +27-10	9842 5	[M1]			B(M1)(W.u.)=0.09 +4-9
10180.8	(11-)		835.6 6	(M1+E2)	-0.09 4
10192.5	(11+)		1129.4 8	D+Q	-0.45 6
11117.0	(11-)		1229.9 9	D+Q	-0.09 7
11255.2	(11-)		560.6 4	(M1+E2)	-0.26 5
11297.7	(12-)		707.0 5	(M1+E2)	-0.15 5
11297.7	(12-)		1116.3 8	D+Q	-0.22 3
11474.5	(12+)		1281.8 9	D+Q	-0.55 8
11474.5	(12+)		2152.4 15	D+Q	-0.39 7
11579.3	(12+)		1386.7 10	D+Q	-0.35 8
11814.3	(12-)		1223.8 9	D+Q	-0.08 2
11814.3	(12-)		1633.8 11	D+Q	-0.07 2
11824.7	(12+)		1632.0 10	D+Q	-0.61 14
12155.1	(12-)		1564.0 12	D+Q	+0.15 11
12155.1	(12-)		1974.1 14	D+Q	-0.27 10
12570.1	(12+)	% p = 3.7 14	3248.0 23	D+Q	-0.44 11
15294.3	(14+)		2462.2 17	D+Q	-0.13 7
15709.3	(15+)		1581.3 11	D+Q	-0.22 4
18341.5	(16-)		3489.4 24	D(+Q)	-0.02 14
18461.0	(17-)		1170.5 8	D+Q	-0.10 6

Q(β-)=-8561.0 keV 5	S(n)= 12216.3 keV 5	S(p)= 8172.2 keV 5	Q(α)= -6399.2 keV 4
Reference: 2012WA38

References:
A	⁵⁸Cu ε decay (3.204 S)	B	⁵⁹Zn εp decay (182.0 MS)
C	²⁸Si(³⁶Ar,α2pγ)	D	²⁸Si(³⁶Ar,αpγ):PROMPT p decay
E	⁴⁰Ca(²⁴Mg,α2pγ)	F	⁴⁵Sc(¹⁶O,p2nγ)
G	⁴⁸Ti(¹²C,2nγ)	H	⁵⁴Fe(⁶Li,d)
I	⁵⁴Fe(⁷Li,t)	J	⁵⁴Fe(¹²C,⁸Be)
K	⁵⁴Fe(¹⁶O,¹²C)	L	⁵⁶Fe(³He,n)
M	⁵⁶Fe(α,2nγ)	N	⁵⁸Ni(γ,γ’),(pol γ,γ’)
O	⁵⁸Ni(E,E’)	P	⁵⁸Ni(n,n’),(n,n’γ)
Q	⁵⁸Ni(p,p’),(pol p,p’),(p,p’γ)	R	⁵⁸Ni(d,d’)
S	⁵⁸Ni(³He,³He’)	T	⁵⁸Ni(α,α’)
U	⁵⁸Ni(⁶Li,⁶Li’)	V	Coulomb Excitation
W	⁶⁰Ni(p,t)	X	NI(K-,xγ)
Y	⁵⁸Ni(¹⁶O,¹⁶O’)	Z	⁵⁸Ni(¹⁸O,¹⁸O’)

E(level) (keV)	J^π(level)	T_1/2(level)	E(γ)	I(γ)	M(γ)	Final Levels
Band 1 - Band based on (16-), α=0.
18341.5 24	(16-)
20135.4 25	(18-)	% p < 10	930.0 10 1794.0 13	33 11 100 11	Q	19205.4 18341.5	(17-) (16-)
22211.3 25	(20-)		1105.0 10 2076.0 15	22 11 100 11	D+Q Q	21106.3 20135.4	(19-) (18-)
24611 3	(22-)		1280 2400.0 17	100 17	Q	23331 22211.3	(21-) (20-)
27366 4	(24-)		2755.0 20	100	Q	24611	(22-)
30491 4	(26-)		3125			27366	(24-)
33972 4	(28-)		3480			30491	(26-)
37810 4	(30-)		3838			33972	(28-)
42007 4	(32-)		4197			37810	(30-)
E(level) (keV)	J^π(level)	T_1/2(level)	E(γ)	I(γ)	M(γ)	Final Levels
Band 2 - Band based on (17-), α=1.
19205.4 25	(17-)
21106.3 25	(19-)	% p < 10	971.0 10 1901.0 14	14 14 100 14	D+Q Q	20135.4 19205.4	(18-) (17-)
23331 3	(21-)		1120 2225.0 16	100	Q	22211.3 21106.3	(20-) (19-)
25918 3	(23-)		2587.0 18	100	Q	23331	(21-)
28931 3	(25-)		3014.0 21 3379	100	Q	25918 25552	(23-) (23-)
32495 3	(27-)		3564 3786			28931 28709	(25-) (25-)
36535 3	(29-)		4040			32495	(27-)
40931 3	(31-)		4396			36535	(29-)
E(level) (keV)	J^π(level)	T_1/2(level)	E(γ)	I(γ)	M(γ)	Final Levels
Band 3 - yrast STRUCTURE
0.0	0+	STABLE
1454.21 9	2+	0.652 ps 21	1454.28 10	100	E2	0.0	0+
2459.21 14	4+	3.7 ps 4	1004.80 15 2459.1	100 ≤0.5	E2	1454.21 0.0	2+ 0+
5127.5 4	6+		723.2 2 744.6 3 832.0 7 ? 1020.3 7 2668.6 10	0.6 2 100.0 21 0.4 2 1.46 21 45.8 21	(M1+E2) Q	4404.3 4383.0 4294.7 4105.9 2459.21	4+ (5+) 4+ (4+) 4+
6604.6 4	(8+)		384.8 3 519.5 4 537.0 3 1476.8 10	2.6 3 2.1 3 100 3 70 3	(M1+E2) Q	6220.0 6084.7 6067.5 5127.5	(7+) 7- (7+) 6+
E(level) (keV)	J^π(level)	T_1/2(level)	E(γ)	I(γ)	M(γ)	Final Levels
Band 4 - Band based on 15323,14⁺
15324.1 12	(14+)
17163.1 13	(16+)		992.1 10 1839.1 13 1896.6 13	100 33 67 13 67 13	D+Q Q	16171.0 15324.1 15266.3	(15+) (14+) (14+)
19482.5 16	(18+)		1221.1 10 2320.0 16	50 50 100 50	(Q)	18261.1 17163.1	(17+) (16+)
22239.6 25	(20+)		2757.0 19	100	Q	19482.5	(18+)
E(level) (keV)	J^π(level)	T_1/2(level)	E(γ)	I(γ)	M(γ)	Final Levels
Band 5 - Band based on 14455,13⁺
14455.8 16	(13+)
16171.0 13	(15+)		847.0 10 1715.0 12	67 33 100 33	Q	15324.1 14455.8	(14+) (13+)
18261.1 14	(17+)		1097.9 10 2090.0 10	17 17 100 33	D+Q Q	17163.1 16171.0	(16+) (15+)
20826.2 23	(19+)		2565.0 18	100	Q	18261.1	(17+)
23741 4	(21+)		2914.5 25	100	Q	20826.2	(19+)
E(level) (keV)	J^π(level)	T_1/2(level)	E(γ)	I(γ)	M(γ)	Final Levels
Band 6 - Band based on 9585,9-
9585.2 8	(9-)
11117.0 8	(11-)		1229.9 9 1531.2 11 2090.0 15	100 13 88 13 38 13	D+Q Q	9886.8 9585.2 9027.2	(10+) (9-) (9-)
12831.6 9	(13-)		1534.1 11 1713.6 12 2652.2 19	100 5 77 5 41 5	Q Q	11297.7 11117.0 10180.8	(12-) (11-) (11-)
14853.1 11	(15-)		1835.6 13 2021.2 14	8 4 100 12	Q	13016.6 12831.6	(13-) (13-)
17019.6 19			2166.5 15	100		14853.1	(15-)
E(level) (keV)	J^π(level)	T_1/2(level)	E(γ)	I(γ)	M(γ)	Final Levels
Band 7 - ΔJ=1 band based on 10694,10-
10694.7 7	(10-)
11255.2 7	(11-)		560.6 4 1074.1 8	100 5 42 5	(M1+E2)	10694.7 10180.8	(10-) (11-)
11996.4 7	(12-)		741.4 5 1301.0 10 1406.2 10 1813.8 13	100 6 12 6 12 6 18 6	D+Q Q	11255.2 10694.7 10590.9 10180.8	(11-) (10-) (11-) (11-)
12912.1 9	(13-)		915.7 6 1657.0 12	100 5 30 5	D+Q	11996.4 11255.2	(12-) (11-)
13850.1 10	(14-)		938.0 7 1853.8 13	100 5 47 5	D+Q Q	12912.1 11996.4	(13-) (12-)
14934.7 12	(15-)		1084.8 8 2022.2 14	100 11 78 11	D+Q Q	13850.1 12912.1	(14-) (13-)
16246.6 14	(16-)		1312.0 9 2396.1 17	80 20 100 20	D+Q Q	14934.7 13850.1	(15-) (14-)
19196 4			2949.0 30	100		16246.6	(16-)
E(level) (keV)	J^π(level)	T_1/2(level)	E(γ)	I(γ)	M(γ)	Final Levels
Band 8 - ΔJ=1 band based on 3422,3⁺
3420.55 18	3+	0.26 ps +22-10
3620.09 22	4+	0.11 ps +8-5	582.4 844.8 1161.2 3 2166.3 5 3620.0?	<3.8 <3.8 100.0 24 20.5 24 <4.4	(M1(+E2)) E2	3037.86 2775.42 2459.21 1454.21 0.0	2+ 2+ 4+ 2+ 0+
4383.0 3	(5+)		276.7 6 763.0 3 962 1 1923.9 7	3.8 7 100.0 20 0.2 2 31.2 20	D+Q (M1+E2) D+Q	4105.9 3620.09 3420.55 2459.21	(4+) 4+ 3+ 4+
5384.5 4	6+		1000.8 8 1088.9 10 1764.5 11 2926.6 15	100 10 4 2 100 10 66 8	D+Q Q Q	4383.0 4294.7 3620.09 2459.21	(5+) 4+ 4+ 4+
6067.5 4	(7+)		322.8 2 682.7 5 940.1 4 1684.6 10	1.6 3 16.1 13 100 5 42 3	(M1+E2) (M1+E2) (M1+E2) Q	5744.7 5384.5 5127.5 4383.0	(6+) 6+ 6+ (5+)
7314.8 5	(8+)		709.7 5 1095.7 9 1245.9 9 1930.3 14	48 4 78 7 100 7 81 7	D+Q Q	6604.6 6220.0 6067.5 5384.5	(8+) (7+) (7+) 6+
7446.2 5	(9+)		841.6 4 1226.1 9 1378.6 10	100 3 14.1 17 5.5 3	(M1+E2) Q	6604.6 6220.0 6067.5	(8+) (7+) (7+)
9322.1 9	(11+)		1876.4 13	100	Q	7446.2	(9+)
E(level) (keV)	J^π(level)	T_1/2(level)	E(γ)	I(γ)	M(γ)	Final Levels
Band 9 - ΔJ=1 band based on 7724,8⁺
7724.3 5	(8+)
8120.8 5	(9+)		396.5 1 805.5 5 1516.6 7	6.4 9 6.4 9 100 5	D+Q D+Q D+Q	7724.3 7314.8 6604.6	(8+) (8+) (8+)
9062.7 6	(10+)		941.1 7 1336.5 28 1617.0 11 2459.9 17	100 4 4.3 14 14.3 14 40 3	M1+E2 Q	8120.8 7724.3 7446.2 6604.6	(9+) (8+) (9+) (8+)
10192.5 7	(11+)		1129.4 8 2072.7 15 2746.6 19	100 4 22.4 15 39 3	D+Q Q Q	9062.7 8120.8 7446.2	(10+) (9+) (9+)
11474.5 7	(12+)		1281.8 9 1807.5 13 2152.4 15 2410.9 17	100 5 35 3 32 3 30 3	D+Q Q D+Q Q	10192.5 9666.9 9322.1 9062.7	(11+) (10+) (11+) (10+)
13356.6 9	(13+)		1881.5 13 3164.1 22	100 17 83 17	Q	11474.5 10192.5	(12+) (11+)
14920.9 11	(14+)		1564.3 10 3445 2	14 14 100 14	Q	13356.6 11474.5	(13+) (12+)
E(level) (keV)	J^π(level)	T_1/2(level)	E(γ)	I(γ)	M(γ)	Final Levels
Band 10 - Band based on 18638,18⁺
18638.9 10	(18+)
21248.0 13	(20+)		1301.8 9 2609.0 18	50 7 100 14	Q	19945.7 18638.9	(19+) (18+)
24211.9 17	(22+)		1444.0 10 2964.0 19	29 14 100 14	Q	22767.9 21248.0	(21+) (20+)
E(level) (keV)	J^π(level)	T_1/2(level)	E(γ)	I(γ)	M(γ)	Final Levels
Band 11 - Band based on 19945,19⁺
19945.7 11	(19+)
22767.9 15	(21+)		1519.2 11 2824.3 20	37 13 100 13	Q	21248.0 19945.7	(20+) (19+)
26059.7 20	(23+)		1848.0 13 3291.0 23	50 50 100 50	Q	24211.9 22767.9	(22+) (21+)
E(level) (keV)	J^π(level)	T_1/2(level)	E(γ)	I(γ)	M(γ)	Final Levels
Band 12 - γ CASCADE
X
2868.1+X 10			2868			X
6083.2+X 15			3215			2868.1+X
9667.3+X 18			3584			6083.2+X
E(level) (keV)	J^π(level)	T_1/2(level)	E(γ)	I(γ)	M(γ)	Final Levels
Band 13 - SD-1 Band.
16798.0 10	(15-)	17 ps 11 % p = 7 2 % α = 2.6 3
18461.0 12	(17-)		1170.5 8 1664.0 12	17 6 100 6	D+Q Q	17290.0 16798.0	(16+) (15-)
20450.1 18	(19-)		1988.7 14	100	Q	18461.0	(17-)
22800.4 22	(21-)		2349.7 16	100	E2	20450.1	(19-)
25552 3	(23-)		2750.5 19	100	Q	22800.4	(21-)
28709 3	(25-)		3157.0 22	100	Q	25552	(23-)
E(level) (keV)	J^π(level)	T_1/2(level)	E(γ)	I(γ)	M(γ)	Final Levels
Band 14 - SD-2 band.
13606.8 13	(12+)
15294.3 10	(14+)		1688.0 12 2277.9 16 2462.2 17	100 11 22 11 44 11	Q D+Q	13606.8 13016.6 12831.6	(12+) (13-) (13-)
17290.0 11	(16+)		1965.0 14 1996.0 14 2023.9 12 2436	15 8 100 8 15 8	Q Q	15324.1 15294.3 15266.3 14853.1	(14+) (14+) (14+) (15-)
19566.9 19	(18+)		2276.9 16	100	Q	17290.0	(16+)
22138 3	(20+)		2570.9 18	100	Q	19566.9	(18+)
25141 4	(22+)		3002.8 21	100	Q	22138	(20+)

E(level)	E(gamma)	Comments
2775.42	1321.2	M(γ): large δ(Q+D) from γ(θ)
2902.15	2901.3	M(γ): ΔJ=1, dipole from γ(θ); ΔJπ requires M1
3531.1	588.5	I(γ): \|<1.0, but no γ expected for E0 transition
3593.71	3593.3	I(γ): other: branching=24% 3 in (γ,γ’) work of 2000Ba63 seems in error, the level in (γ,γ’) is considered as the same as in other reactions and decays
3898.8	3898.0	I(γ): from (p,p’γ)
4574.1	4574.1	E(γ): Multiply placed
5359.3	5359.3	E(γ): Multiply placed
5452.2	5452.2	E(γ): Multiply placed
5590.3	5590	E(γ): from (p,p’γ)
5594.2	1819	E(γ): all γ’s from (p,p’γ)
6027.3	4574.1	E(γ): Multiply placed
6084.7	3625.1	M(γ): DCO in (³⁶Ar,α2pγ) consistent with pure octupole or ΔJ=2,Q, not with ΔJ=1, dipole
6424.9	6424.9	E(γ): Multiply placed
6685.0	6685.0	E(γ): Multiply placed
6892.9	6892.9	E(γ): Multiply placed
7271.7	5817	E(γ): from (p,p’γ)
7876.7	6424.9	E(γ): Multiply placed
8068.6	8068.6	E(γ): Multiply placed
8395.1	5359.3	E(γ): Multiply placed I(γ): 35 16 for 5359.3γ+5452.2γ, assuming the main placements of these γ rays are from 8395 level
8395.1	5452.2	E(γ): Multiply placed
9326.4	6424.9	E(γ): Multiply placed
9523.3	8068.6	E(γ): Multiply placed
9630.5	9630.5	I(γ): branching=38% 6 in (γ,γ’), but other two transitions proposed to feed levels for which there is not much evidence from other studies
9667.8	6892.9	E(γ): Multiply placed
9723.0	6685.0	E(γ): Multiply placed
E(level)	E(gamma)	Comments
13238.1	1764.1	E(γ): Multiply placed with intensity suitably divided I(γ): Multiply placed with intensity suitably divided