List of levels for 91MO

ADOPTED LEVELS, GAMMAS for ⁹¹Mo

Author: Coral M. Baglin | Citation: Nucl. Data Sheets 114, 1293 (2013) | Cutoff date: 1-Sep-2013

Full ENSDF file | Adopted Levels (PDF version)

Q(β-)=-6222 keV 7	S(n)= 10107 keV 7	S(p)= 6835 keV 7	Q(α)= -5287 keV 8
Reference: 2012WA38

References:
A	⁹⁰Zr(α,3nγ), ⁹²Mo(α,α’nγ)	B	⁹¹Mo IT decay (64.6 S)
C	⁹¹Tc ε decay (3.14 M)	D	⁹¹Tc ε decay (3.3 M)
E	⁹²Mo(p,d),(d,t),(³He,α)	F	⁹²Mo(pol p,d)
G	⁶⁶Zn(²⁸Si,2pnγ)	H	⁶³Cu(³¹P,N2PG)
I	⁹²Mo(p,PN):RADIUS,MOM

Other experiment: (p,π^-), 1982Vi05.

Theory (partial list):

Nuclear structure calculations:

1996Ru02, 1992Si15, 1976Gr07, 1976Se01 (shell model)

1973Ki04, 1984Ng01 (quasi-particle phonon coupling model)

Levels: See 1993Hi12 for spectroscopic strength functions for p_1/2, p_3/2, f_5/2, f_7/2 and g_9/2 hole states in ⁹¹Mo.

Q-value: Q(εp)=-724 6 (2012Wa38).

E(level) (keV)	XREF	J^π(level)	T_1/2(level)	E(γ) (keV)	I(γ)	M(γ)	Final Levels
0	A B C D E F G H I	9/2+	15.49 m 1 % ε = 100
653.01 9	B C D E F	1/2-	64.6 s 6 % IT = 50.0 16 % ε = 50.0 16	652.9 1	100	M4	0	9/2+
1156.10 13	C D E F	3/2-		502.9 2	100		653.01	1/2-
1362.01 8	C D E F	5/2+		205.6 4 1362.0 1	1.1 4 100 4	[E1]	1156.10 0	3/2- 9/2+
1414.11 13	A C E G	13/2(+)		1414.10 13	100	(E2)	0	9/2+
1531.90 24	C E F	5/2-		375.8 2	100		1156.10	3/2-
1564.92 9	C			1564.9 1	100		0	9/2+
1605.32 7	C E			1605.2 1	100		0	9/2+
1639.95 8	C E	(7/2,9/2+)		277.9 2 1639.9 1	6.7 7 100 3		1362.01 0	5/2+ 9/2+
1844 5	E	5/2-,7/2-
1902.49 7	C E F	9/2+		297.1 2 337.5 2 1902.3 1	3.9 4 19 3 100 3		1605.32 1564.92 0	9/2+
2067.91 24	A G H	17/2(+)		653.8 2	100	E2	1414.11	13/2(+)
2083.66 14	D E F	3/2-		927.6 1 1430.4 2	100 6 53 3		1156.10 653.01	3/2- 1/2-
2201 6	E
2233.69 9	C E F	9/2+		628.4 3 668.8 10 2233.8 1	56 11 24 12 100 4		1605.32 1564.92 0	9/2+
2243	E
2267.4 4	A G H	21/2(+)	47 ns 1	199.5 2	100	E2	2067.91	17/2(+)
2279.6 4	A	(17/2-)	38 ns 4	211.7 2	100	[E1]	2067.91	17/2(+)
2302	E F	(1/2-&9/2+)
2345 4	E	(7/2+,9/2+)
E(level) (keV)	XREF	J^π(level)	T_1/2(level)	E(γ) (keV)	I(γ)	M(γ)	Final Levels
2450.99 9	C E F	9/2+		217.8 2 548.7 3 811.0 5 844.9 3 1088.9 4 2450.9 1	1.04 12 12.2 7 37.1 23 8.8 9 4.25 27 100 3		2233.69 1902.49 1639.95 1605.32 1362.01 0	9/2+ 9/2+ (7/2,9/2+) 5/2+ 9/2+
2492.16 17	C E			851.8 3 2492.3 2	100 13 71 3		1639.95 0	(7/2,9/2+) 9/2+
2537 4	E F	3/2+,5/2+
2566 4	E	7/2+,9/2+
2624 6	E
2663 6	E
2690.44 11	D E	(3/2)-		606.7 3 1328.4 2 1534.4 2 2037.4 1	58 4 100 4 98 4 20.8 19		2083.66 1362.01 1156.10 653.01	3/2- 5/2+ 3/2- 1/2-
2716 4	E F	5/2-
2716.44 7	C	(7/2,9/2)+		483.2 6 813.9 5 1076.5 2 1111.1 1 1354.4 2 2716.4 1	34.2 25 55 10 29.6 20 100 4 22.9 10 58.8 20		2233.69 1902.49 1639.95 1605.32 1362.01 0	9/2+ 9/2+ (7/2,9/2+) 5/2+ 9/2+
2772 6 ?	E	(7/2+,9/2+)
2781.12 8	C	(7/2+,9/2+,11/2+)		878.4 1 2781.3 1	34.3 25 100 4		1902.49 0	9/2+ 9/2+
2818 4	E F	9/2+
2851 6	E	9/2-,11/2-
2867 6	E	9/2-,11/2-
2883 4	E	1/2-,3/2-
E(level) (keV)	XREF	J^π(level)	T_1/2(level)	E(γ) (keV)	I(γ)	M(γ)	Final Levels
2887.50 12	C	(9/2+,11/2+)		985.0 4 1322.6 2 1731.0 2 2887.8 2	15.8 10 49.9 23 9.9 9 100 3		1902.49 1564.92 1156.10 0	9/2+ 3/2- 9/2+
2901	F	3/2-
2914 5	E	(5/2-,7/2-)
2940.1 4	A G H	(23/2+)	0.08 ps	672.6 2	100	M1	2267.4	21/2(+)
2941 5	E	(5/2-,7/2-)
2964 6	E
2984 6	E F
3010 5	E F	(5/2-,7/2-)
3031 6	E	(1/2-,3/2-)
3085 6	E F
3126 6	E	(1/2-,3/2-)
3162 6	E
3191 6	E F	3/2-
3230 6	E	(5/2-,7/2-)
3307 6	E
3328 6	E F	(9/2+)
3351 6	E	(5/2-,7/2-)
3398 6	E
3413 6	E	(5/2-,7/2-)
3447 6	E F	7/2-
3472 6	E	(1/2-,3/2-)
3524 6	E
3545.6 4	A G H	(25/2+)	0.11 ps	605.5 2	100	D(+Q)	2940.1	(23/2+)
3585 6	E F	(7/2-)
3631 6	E	(1/2-,3/2-)
3645 6	E F	5/2+
3696 6	E
E(level) (keV)	XREF	J^π(level)	T_1/2(level)	E(γ) (keV)	I(γ)	M(γ)	Final Levels
3729 6	E
3759 6	E F
3806 6	E
3809.7 4	A G H	(25/2+)	17 ps 3	264.2 2 869.6 2	12.2 7 100 3	(M1) D(+Q)	3545.6 2940.1	(25/2+) (23/2+)
3836 6	E F	(7/2-)
3930 6	E F	(9/2+)
3956 6	E F	(7/2-)
4022 6	E	(1/2-,3/2-)
4060 20	E	(5/2-,7/2-)
4069 6	E F	9/2+
4091 6	E
4116 7	E
4133 6	E F	5/2-,7/2-
4157 7	E F	(9/2+)
4186 7	E
4228 7	E
4258 7	E
4276 7	E F	(9/2+)
4301 6	E	(5/2-,7/2-)
4341.9 5	A G H	(27/2+)	0.20 ps	532.2 2	100	D+Q	3809.7	(25/2+)
4349 7	E
4385 7	E F	(5/2-&7/2-)
4408 7	E
4432 7	E	(5/2-,7/2-)
4445.1 4	G H	25/2(+)		1504.2 2177.8 3	5.3 4 100 10	Q	2940.1 2267.4	(23/2+) 21/2(+)
4456.5 11	H	(27/2)		646.8	100		3809.7	(25/2+)
4481	F	5/2-
4522 7	E
E(level) (keV)	XREF	J^π(level)	T_1/2(level)	E(γ) (keV)	I(γ)	M(γ)	Final Levels
4560 7	E
4577 7	E
4603 7	E
4643 7	E F	3/2-
4683 7	E	(7/2+,9/2+)
4707 7	E
4768 7	E
4780 7	E	(1/2-,3/2-)
4796?	F	7/2-
4815 7	E
4841 7	E
4869 7	E
4899 7	E F
4952.6 4	G H	(27/2+)		507.6 3 1406.6 2012.4 3	100.0 16 9.9 6 42 5	D+Q D Q	4445.1 3545.6 2940.1	25/2(+) (25/2+) (23/2+)
4958.8 5	A G H	(29/2+)	0.12 ps	616.9 2	100	D(+Q)	4341.9	(27/2+)
5.03E+3 2	E F	(1/2-,3/2-)
5.13E+3 2	E F
5.19E+3 2	E	(1/2-,3/2-)
5.23E+3 2	E	(5/2-,7/2-)
5243.3 6	A G	(31/2+)	0.40 ps	284.5 2	100	M1	4958.8	(29/2+)
5295	F	7/2-
5299.0 6 ?	G H	(31/2)		340.2 3	100	D+Q	4958.8	(29/2+)
5.34E+3 2	E	1/2-,3/2-
5.42E+3 2	E F	7/2-
5488.4 5	G H	(29/2+)		535.8 3 1942.8 3	100 3 72 5	D+Q Q	4952.6 3545.6	(27/2+) (25/2+)
5.50E+3 2	E	1/2-,3/2-
5516	F	7/2-
E(level) (keV)	XREF	J^π(level)	T_1/2(level)	E(γ) (keV)	I(γ)	M(γ)	Final Levels
5690	F	(7/2-)
5796	F
5817.8 6 ?	G			329.4 3 ?	100		5488.4	(29/2+)
5.90E+3 2	E F	-
5929.3 12	H			686.0	100		5243.3	(31/2+)
5963.8 12	H	(35/2)		664.8	100	E2	5299.0	(31/2)
5.99E+3 2	E	1/2-,3/2-
6.06E+3 2	E F	7/2-
6106.6 8	H	(29/2+)		1154.1 1661.3	45 3 100 10	D Q	4952.6 4445.1	(27/2+) 25/2(+)
6232.7 6	G H	(31/2+)		744.3 3	100	D+Q	5488.4	(29/2+)
6327.8 15	H	(31/2)		1871.3	100 9	Q	4456.5	(27/2)
6437.9 12	H	(33/2)		1138.9	100 6	D	5299.0	(31/2)
6444.8 15	H			515.5	100 6		5929.3
6469.2 6	G H	(33/2+)		236.4 3 981.5	100 4 56.0 26	M1(+E2) Q	6232.7 5488.4	(31/2+) (29/2+)
6658.6 8	H	(31/2+)		551.7 1705.8	100 5 60.00 6	Q	6106.6 4952.6	(29/2+) (27/2+)
6813.1 12 ?	H			1569.8?	100		5243.3	(31/2+)
6959.4 12 ?	H			2000.5?	100		4958.8	(29/2+)
6.99E+3 3	E F	9/2+
7.12E+3 3	E F	1/2-
7262.8 9	H	(33/2+)		603.9 1774.8	28 14 100 11	Q	6658.6 5488.4	(31/2+) (29/2+)
7321.2 12	H	(35/2+)		2077.8	100 8	E2	5243.3	(31/2+)
7336.5 11	H	(33/2+)		1848.1	100	Q	5488.4	(29/2+)
7469.4 14	H	(35/2+)		206.6	100 5	D+Q	7262.8	(33/2+)
7805.7 12	H	(33/2)		2562.3	100 10	D	5243.3	(31/2+)
8001.6 16	H	(39/2+)		2037.7	100 10	Q	5963.8	(35/2)
8112.5 17	H	(37/2+)		643.1	100 6	(M1)	7469.4	(35/2+)
E(level) (keV)	XREF	J^π(level)	T_1/2(level)	E(γ) (keV)	I(γ)	M(γ)	Final Levels
8153.6 16	H	(39/2+)		2189.7	100	Q	5963.8	(35/2)
8.17E+3	E	(5/2-)
8173.7 15	H			2244.3	100		5929.3
8278.7 12	H	(37/2+)		1809.5	100	(E2)	6469.2	(33/2+)
8.34E+3 3	E F	3/2-
8578.3 20 ?	H			465.8?	100		8112.5	(37/2+)
8626.6 12	H	(37/2+)		2157.4	100	Q	6469.2	(33/2+)
8.66E+3 3	E F	3/2-
8708.2 19	H			706.6	100		8001.6	(39/2+)
8749.4 20	H	(39/2+)		636.9	100	M1	8112.5	(37/2+)
8.87E+3 3	E F	5/2-
9282.2 15	H	(39/2+)		1961.0	100	(Q)	7321.2	(35/2+)
10.15E+3	E
10.40E+3	E
10749.4 16 ?	H			2470.7?	100		8278.7	(37/2+)
12.42E+3	E

J^π(level): Due to the large number of unplaced γ’s in ε decay (3.14 min), Jπ arguments based on log ft for weakly fed levels should be treated with caution.

T_1/2(level): From Doppler-shift attenuation or time-differential perturbed angular distribution observed in (α,3nγ), if not indicated otherwise.

M(γ): From γ(θ) in (²⁸Si,2pnγ), if not noted otherwise.

E(level) (keV)	J^π(level)	T_1/2(level)	E(γ)	I(γ)	M(γ)	Final Levels
Band 1 - π=+, SENIORITY=3 STATES (1993Si14).
1414.11 13	13/2(+)
2067.91 24	17/2(+)		653.8 2	100	E2	1414.11	13/2(+)
2267.4 4	21/2(+)	47 ns 1	199.5 2	100	E2	2067.91	17/2(+)
3545.6 4	(25/2+)	0.11 ps	605.5 2	100	D(+Q)	2940.1	(23/2+)
E(level) (keV)	J^π(level)	T_1/2(level)	E(γ)	I(γ)	M(γ)	Final Levels
Band 2 - π=+, SENIORITY=5 STATES (1993Si14).
4445.1 4	25/2(+)
4952.6 4	(27/2+)		507.6 3 1406.6 2012.4 3	100.0 16 9.9 6 42 5	D+Q D Q	4445.1 3545.6 2940.1	25/2(+) (25/2+) (23/2+)
5488.4 5	(29/2+)		535.8 3 1942.8 3	100 3 72 5	D+Q Q	4952.6 3545.6	(27/2+) (25/2+)
6232.7 6	(31/2+)		744.3 3	100	D+Q	5488.4	(29/2+)
6469.2 6	(33/2+)		236.4 3 981.5	100 4 56.0 26	M1(+E2) Q	6232.7 5488.4	(31/2+) (29/2+)

E(level) (keV)	J^π(level)	T_1/2(level)	E(γ) (keV)	Multipolarity	Conversion Coefficient	Additional Data
653.01	1/2-	64.6 s 6 % IT = 50.0 16 % ε = 50.0 16	652.9 1	M4	0.0374	B(M4)(W.u.)=8.8 3, α=0.0374
1362.01	5/2+		205.6 4	[E1]	0.01572	α=0.01572
2267.4	21/2(+)	47 ns 1	199.5 2	E2	0.1000	B(E2)(W.u.)=1.42 4, α=0.1000
2279.6	(17/2-)	38 ns 4	211.7 2	[E1]	0.01447	B(E1)(W.u.)=9.1E-7 10, α=0.01447
2940.1	(23/2+)	0.08 ps	672.6 2	M1		B(M1)(W.u.)=0.90
3545.6	(25/2+)	0.11 ps	605.5 2	D(+Q)		B(M1)(W.u.)≈0.90
3809.7	(25/2+)	17 ps 3	264.2 2	(M1)	0.0186	B(E1)(W.u.)=0.0076 15, α=0.0186
4341.9	(27/2+)	0.20 ps	532.2 2	D+Q		B(M1)(W.u.)=0.7
5243.3	(31/2+)	0.40 ps	284.5 2	M1	0.01542	B(M1)(W.u.)=2.35, α=0.01542
6469.2	(33/2+)		236.4 3	M1(+E2)	0.0248	α=0.0248

E(level)	J^π(level)	T_1/2(level)	Comments
0	9/2+	15.49 m 1 % ε = 100	μ=-0.932 3 (2009Ch09) Δ<r²>(⁹¹Mo,⁹²Mo)=+0.021 fm² 1 (2009Ch09); uncertainty is statistical only. E(level): Δ<r²>(⁹¹Mo,⁹²Mo)=+0.021 fm² 1 (2009Ch09); uncertainty is statistical only.
653.01	1/2-	64.6 s 6 % IT = 50.0 16 % ε = 50.0 16	%ε+%β⁺, %IT: from ⁹¹Mo ε decay (64.6 s). E(level): %ε+%β⁺, %IT: from ⁹¹Mo ε decay (64.6 s).
1414.11	13/2(+)		E(level): π=+, SENIORITY=3 STATES (1993Si14).
2067.91	17/2(+)		E(level): π=+, SENIORITY=3 STATES (1993Si14).
2243			E(level): Doublet.
2267.4	21/2(+)	47 ns 1	μ=+8.89 8 E(level): π=+, SENIORITY=3 STATES (1993Si14).
2302	(1/2-&9/2+)		XREF: E(2300)F(2304). E(level): Triplet.
2537	3/2+,5/2+		XREF: F(2548).
3545.6	(25/2+)	0.11 ps	E(level): π=+, SENIORITY=3 STATES (1993Si14).
3836	(7/2-)		XREF: F(3823).
4157	(9/2+)		E(level): Doublet.
4341.9	(27/2+)	0.20 ps	Other T_1/2: <1.4 ps from RDM in (²⁸Si,2pnγ). E(level): Other T_1/2: <1.4 ps from RDM in (²⁸Si,2pnγ).
4408			See comment on 4385 level. E(level): See comment on 4385 level.
4445.1	25/2(+)		E(level): π=+, SENIORITY=5 STATES (1993Si14).
4643	3/2-		XREF: F(4664).
4869			L(³He,α)=1 for 4869⁺4899 doublet. E(level): L(³He,α)=1 for 4869⁺4899 doublet.
4899			L(³He,α)=1 for 4869⁺4899 doublet. E(level): L(³He,α)=1 for 4869⁺4899 doublet.
4952.6	(27/2+)		E(level): π=+, SENIORITY=5 STATES (1993Si14).
4958.8	(29/2+)	0.12 ps	Other T_1/2: <1.4 ps from RDM in (²⁸Si,2pnγ). E(level): Other T_1/2: <1.4 ps from RDM in (²⁸Si,2pnγ).
5.03E+3	(1/2-,3/2-)		XREF: F(5056).
5.13E+3			XREF: F(5177). E(level): Doublet.
5.42E+3	7/2-		XREF: F(5394).
5488.4	(29/2+)		E(level): π=+, SENIORITY=5 STATES (1993Si14).
5.90E+3	-		E(level): Doublet.
6.06E+3	7/2-		XREF: F(6070).
E(level)	J^π(level)	T_1/2(level)	Comments
6232.7	(31/2+)		E(level): π=+, SENIORITY=5 STATES (1993Si14).
6469.2	(33/2+)		E(level): π=+, SENIORITY=5 STATES (1993Si14).
6.99E+3	9/2+		XREF: F(7026).
7.12E+3	1/2-		XREF: F(7158).
8.34E+3	3/2-		XREF: F(8433).
8.66E+3	3/2-		XREF: F(8742).
8.87E+3	5/2-		XREF: F(8938).

E(level)	E(gamma)	Comments
653.01	652.9	M(γ): from α(exp)=0.052 14 as deduced in IT decay.
1414.11	1414.10	E(γ): weighted average from ⁹¹Tc ε decay, (²⁸Si,2pnγ), (α,3nγ). M(γ): Q from γ(θ), Δπ=no from level scheme.
1564.92	1564.9	E(γ): weighted average from ε decay and (α,3nγ).
2067.91	653.8	E(γ): From ⁹⁰Zr(α,3nγ), ⁹²Mo(α,α’nγ). M(γ): Q from γ(θ); not M2 from RUL, assuming T_1/2<10 ns based on prompt coincidence component in 654γ in (α,3nγ).
2083.66	927.6	E(γ): From ⁹¹Tc ε decay (3.3 min). I(γ): From ⁹¹Tc ε decay (3.3 min).
2083.66	1430.4	E(γ): From ⁹¹Tc ε decay (3.3 min). I(γ): From ⁹¹Tc ε decay (3.3 min).
2267.4	199.5	E(γ): From ⁹⁰Zr(α,3nγ), ⁹²Mo(α,α’nγ). M(γ): Q from γ(θ); not M2 from RUL.
2279.6	211.7	E(γ): From ⁹⁰Zr(α,3nγ), ⁹²Mo(α,α’nγ). M(γ): not M2 or higher from RUL. γ(θ) in (α,3nγ) consistent with Q (ΔJ=2) or D+Q (ΔJ=1) or d(+Q) (ΔJ=0); the level scheme implies the latter.
2690.44	606.7	E(γ): From ⁹¹Tc ε decay (3.3 min). I(γ): From ⁹¹Tc ε decay (3.3 min).
	1328.4	E(γ): From ⁹¹Tc ε decay (3.3 min). I(γ): From ⁹¹Tc ε decay (3.3 min).
	1534.4	E(γ): From ⁹¹Tc ε decay (3.3 min). I(γ): From ⁹¹Tc ε decay (3.3 min).
	2037.4	E(γ): From ⁹¹Tc ε decay (3.3 min). I(γ): From ⁹¹Tc ε decay (3.3 min).
2940.1	672.6	E(γ): From ⁹⁰Zr(α,3nγ), ⁹²Mo(α,α’nγ). M(γ): from (³¹P,n2pγ).
3545.6	605.5	E(γ): From ⁹⁰Zr(α,3nγ), ⁹²Mo(α,α’nγ). M(γ): d(+Q) (ΔJ=1) from γ(θ) in (α,3nγ).
3809.7	264.2	E(γ): 265.1 3 in (²⁸Si,2pnγ), 265.0 in (³¹P,n2pγ).. From ⁹⁰Zr(α,3nγ), ⁹²Mo(α,α’nγ). I(γ): weighted average of 12.0 8 from (²⁸Si,2pnγ) and 12.8 13 from (α,3nγ). Other: 20.0 7 from (³¹P,n2pγ). M(γ): Q (ΔJ=2) or d (ΔJ=0) from anisotropy and γ(θ) in (²⁸Si,2pnγ); magnetic d from (³¹P,n2pγ); ΔJ=0 favored by level scheme.
3809.7	869.6	E(γ): From ⁹⁰Zr(α,3nγ), ⁹²Mo(α,α’nγ). I(γ): weighted average from (²⁸Si,2pnγ) and (α,3nγ).
4341.9	532.2	E(γ): From ⁹⁰Zr(α,3nγ), ⁹²Mo(α,α’nγ).
4445.1	1504.2	E(γ): From ⁶³Cu(³¹P,n2pγ). I(γ): From ⁶³Cu(³¹P,n2pγ).
4445.1	2177.8	E(γ): From (²⁸Si,2pnγ). I(γ): From (²⁸Si,2pnγ).
4456.5	646.8	E(γ): From ⁶³Cu(³¹P,n2pγ). I(γ): From ⁶³Cu(³¹P,n2pγ).
4952.6	507.6	E(γ): From (²⁸Si,2pnγ). I(γ): From (²⁸Si,2pnγ).
	1406.6	E(γ): From ⁶³Cu(³¹P,n2pγ). I(γ): From ⁶³Cu(³¹P,n2pγ). M(γ): from (³¹P,n2pγ).
	2012.4	E(γ): From (²⁸Si,2pnγ). I(γ): From (²⁸Si,2pnγ).
4958.8	616.9	E(γ): From ⁹⁰Zr(α,3nγ), ⁹²Mo(α,α’nγ). M(γ): D+Q from (²⁸Si,2pnγ), d from (³¹P,n2pγ). B(E1)(W.u.) exceeds RUL if pure E1.
5243.3	284.5	E(γ): From ⁹⁰Zr(α,3nγ), ⁹²Mo(α,α’nγ). M(γ): d, ΔJ=1 from (³¹P,n2pγ); polarization favors M1; B(E1)(W.u.) exceeds RUL if E1.
E(level)	E(gamma)	Comments
5299.0	340.2	E(γ): From (²⁸Si,2pnγ). I(γ): From (²⁸Si,2pnγ).
5488.4	535.8	E(γ): From (²⁸Si,2pnγ). I(γ): From (²⁸Si,2pnγ).
5488.4	1942.8	E(γ): From (²⁸Si,2pnγ). I(γ): From (²⁸Si,2pnγ).
5817.8	329.4	E(γ): From (²⁸Si,2pnγ). I(γ): From (²⁸Si,2pnγ).
5929.3	686.0	E(γ): From ⁶³Cu(³¹P,n2pγ). I(γ): From ⁶³Cu(³¹P,n2pγ).
5963.8	664.8	E(γ): From ⁶³Cu(³¹P,n2pγ). I(γ): From ⁶³Cu(³¹P,n2pγ). M(γ): from (³¹P,n2pγ).
6106.6	1154.1	E(γ): From ⁶³Cu(³¹P,n2pγ). I(γ): From ⁶³Cu(³¹P,n2pγ). M(γ): from (³¹P,n2pγ).
6106.6	1661.3	E(γ): From ⁶³Cu(³¹P,n2pγ). I(γ): From ⁶³Cu(³¹P,n2pγ). M(γ): from (³¹P,n2pγ).
6232.7	744.3	E(γ): From (²⁸Si,2pnγ). I(γ): From (²⁸Si,2pnγ).
6327.8	1871.3	M(γ): from (³¹P,n2pγ).
6437.9	1138.9	M(γ): from (³¹P,n2pγ).
6444.8	515.5	E(γ): From ⁶³Cu(³¹P,n2pγ). I(γ): From ⁶³Cu(³¹P,n2pγ).
6469.2	236.4	E(γ): From (²⁸Si,2pnγ). I(γ): From (²⁸Si,2pnγ). M(γ): M1 from (³¹P,n2pγ); D+Q from (²⁸Si,2pnγ).
6469.2	981.5	E(γ): From ⁶³Cu(³¹P,n2pγ). I(γ): From ⁶³Cu(³¹P,n2pγ). M(γ): from (³¹P,n2pγ).
6658.6	551.7	E(γ): From ⁶³Cu(³¹P,n2pγ). I(γ): From ⁶³Cu(³¹P,n2pγ).
6658.6	1705.8	E(γ): From ⁶³Cu(³¹P,n2pγ). I(γ): From ⁶³Cu(³¹P,n2pγ). M(γ): from (³¹P,n2pγ).
6813.1	1569.8	E(γ): From ⁶³Cu(³¹P,n2pγ). I(γ): From ⁶³Cu(³¹P,n2pγ).
6959.4	2000.5	E(γ): From ⁶³Cu(³¹P,n2pγ). I(γ): From ⁶³Cu(³¹P,n2pγ).
7262.8	603.9	E(γ): From ⁶³Cu(³¹P,n2pγ). I(γ): From ⁶³Cu(³¹P,n2pγ).
7262.8	1774.8	E(γ): From ⁶³Cu(³¹P,n2pγ). I(γ): From ⁶³Cu(³¹P,n2pγ). M(γ): from (³¹P,n2pγ).
7321.2	2077.8	E(γ): From ⁶³Cu(³¹P,n2pγ). I(γ): From ⁶³Cu(³¹P,n2pγ). M(γ): from (³¹P,n2pγ).
7336.5	1848.1	E(γ): From ⁶³Cu(³¹P,n2pγ). I(γ): From ⁶³Cu(³¹P,n2pγ). M(γ): from (³¹P,n2pγ).
7469.4	206.6	E(γ): From ⁶³Cu(³¹P,n2pγ). I(γ): From ⁶³Cu(³¹P,n2pγ). M(γ): from (³¹P,n2pγ).
7805.7	2562.3	E(γ): From ⁶³Cu(³¹P,n2pγ). I(γ): From ⁶³Cu(³¹P,n2pγ). M(γ): from (³¹P,n2pγ).
8001.6	2037.7	E(γ): From ⁶³Cu(³¹P,n2pγ). I(γ): From ⁶³Cu(³¹P,n2pγ). M(γ): from (³¹P,n2pγ).
E(level)	E(gamma)	Comments
8112.5	643.1	E(γ): From ⁶³Cu(³¹P,n2pγ). I(γ): From ⁶³Cu(³¹P,n2pγ). M(γ): from (³¹P,n2pγ).
8153.6	2189.7	E(γ): From ⁶³Cu(³¹P,n2pγ). I(γ): From ⁶³Cu(³¹P,n2pγ). M(γ): from (³¹P,n2pγ).
8173.7	2244.3	E(γ): From ⁶³Cu(³¹P,n2pγ). I(γ): From ⁶³Cu(³¹P,n2pγ).
8278.7	1809.5	E(γ): From ⁶³Cu(³¹P,n2pγ). I(γ): From ⁶³Cu(³¹P,n2pγ). M(γ): from (³¹P,n2pγ).
8578.3	465.8	E(γ): From ⁶³Cu(³¹P,n2pγ). I(γ): From ⁶³Cu(³¹P,n2pγ).
8626.6	2157.4	E(γ): From ⁶³Cu(³¹P,n2pγ). I(γ): From ⁶³Cu(³¹P,n2pγ). M(γ): from (³¹P,n2pγ).
8708.2	706.6	E(γ): From ⁶³Cu(³¹P,n2pγ). I(γ): From ⁶³Cu(³¹P,n2pγ).
8749.4	636.9	E(γ): From ⁶³Cu(³¹P,n2pγ). I(γ): From ⁶³Cu(³¹P,n2pγ). M(γ): from (³¹P,n2pγ).
9282.2	1961.0	E(γ): From ⁶³Cu(³¹P,n2pγ). I(γ): From ⁶³Cu(³¹P,n2pγ). M(γ): from (³¹P,n2pγ).
10749.4	2470.7	E(γ): From ⁶³Cu(³¹P,n2pγ). I(γ): From ⁶³Cu(³¹P,n2pγ).