List of levels for 106PD

Authors: D. De Frenne and A. Negret | Citation: Nucl. Data Sheets 109, 943 (2008) | Cutoff date: 1-May-2007

E(level) (keV)	J^π(level)	T_1/2(level)	E(γ) (keV)	Multipolarity	Mixing Ratio	Conversion Coefficient	Additional Data
511.850	2+	12.2 ps 4	511.842 28	E2			B(E2)(W.u.)=44.3 15
1128.02	2+	3.12 ps 25	616.174 24	M1+E2+E0	-9.4 20		B(E2)(W.u.)=44 4, B(M1)(W.u.)=0.00022 10
1128.02	2+	3.12 ps 25	1128.00 6	E2			B(E2)(W.u.)=1.17 10
1133.76	0+	5.8 ps 13	621.94 3	E2			B(E2)(W.u.)=35 8
1229.30	4+	1.31 ps 18	717.24 6	E2			B(E2)(W.u.)=76 11
1557.68	3+		429.64 5	M1+E2	-7.9 8
1557.68	3+		1045.83 8	M1+E2	-3.8 4
1562.25	2+		1050.39 5	(M1+E2)	+0.24 1
1706.44	0+	2.8 ps 5	578.38 9	E2			B(E2)(W.u.)=14 3
1706.44	0+	2.8 ps 5	1194.53 4	E2			B(E2)(W.u.)=2.4 5
1932.32	4+	1.16 ps 16	703.11 7	M1+E2	-2.30 2		B(E2)(W.u.)=21 3, B(M1)(W.u.)=0.0022 4
1932.32	4+	1.16 ps 16	804.34 13	E2			B(E2)(W.u.)=35 6
2077.01	6+	0.49 ps 5	848.0 2	E2			B(E2)(W.u.)=88 9
2083.92	3-	1.2 ps 3	1572.35 15	E1			B(E1)(W.u.)=5.9E-5 17
2083.92	3-	1.2 ps 3	2084.0 4	[E3]			B(E3)(W.u.)=29 10
2242.48	2+		1114.48 5	M1+E2	+1.5 +3-2
2305.62	4-	2.0 ns 5	221.701 10	M1+E2	-0.11 2		B(E2)(W.u.)=0.048 21, B(M1)(W.u.)=0.00022 6
	4-	2.0 ns 5	748.44 7	E1			B(E1)(W.u.)=2.5E-7 7
	4-	2.0 ns 5	1178.07 21	[M2]			B(M2)(W.u.)=0.0020 6
	4-	2.0 ns 5	1794.01 27	[M2]			B(M2)(W.u.)=4.7×10^-5 22
2308.82	2+		1180.72 6	M1+E2	-0.06 12
2308.82	2+		1796.97 7	M1+E2	+0.25 2
2350.86	4+		793.30 25	M1+E2	-7.5 15
2366.01	5+		808.37 10	(M1+E2)	+1.0 8
2397.41	(5)-		1168.25 25	E1+M2	-0.04 2
E(level) (keV)	J^π(level)	T_1/2(level)	E(γ) (keV)	Multipolarity	Mixing Ratio	Conversion Coefficient	Additional Data
2439.10	2+		1927.27 10	[M1+E2]	-0.07 +3-7
2500.31	2-		1988.44 8	E1+M2	-0.05 +3-5
2699.37	(6)-	0.5 ns 1	301.99 10	M1+E2	+0.64 22		B(E2)(W.u.)=3.9 21, B(M1)(W.u.)=0.0010 3
2699.37	(6)-	0.5 ns 1	393.36 20	E2			B(E2)(W.u.)=0.50 13
2705.30	(1)+		2193.30 10	M1+E2	-0.17 6
2757.06	5+	< 3.6 ns	391.039 30	E2(+M1)			B(E2)(W.u.)>0.012, B(M1)(W.u.)>2.1E-6
	5+	< 3.6 ns	406.17 3	M1+E2	-3.2 2		B(E2)(W.u.)>0.063, B(M1)(W.u.)>1.1E-6
	5+	< 3.6 ns	450.97 3	E1			B(E1)(W.u.)>2.8E-7
	5+	< 3.6 ns	474.060 30	M1+E2	-4.0 +9-6		B(E2)(W.u.)>0.0021, B(M1)(W.u.)>2.0E-8
	5+	< 3.6 ns	824.79 15	M1+E2	-6.5 6		B(E2)(W.u.)>0.0023, B(M1)(W.u.)>3.5E-8
	5+	< 3.6 ns	1199.39 10	E2			B(E2)(W.u.)>0.00026
	5+	< 3.6 ns	1527.65 19	M1+E2	-2.46 9		B(E2)(W.u.)>9.7E-5, B(M1)(W.u.)>4.1E-8
2902.48	2+		2390.60 10	(M1+E2)	-0.10 +7-10
2917.86	2+		2405.96 9	M1+E2	-0.05 +2-5
2951.84	5+	< 2.0 ns	195.06 15	M1(+E2)	0.13 +22-13	0.061	α=0.061
	5+	< 2.0 ns	585.97 10	M1(+E2)	0.13 +22-13
	5+	< 2.0 ns	601.17 7	M1+E2	-3.0 7		B(E2)(W.u.)>0.021, B(M1)(W.u.)>6.0E-7
	5+	< 2.0 ns	646.02 5	E1			B(E1)(W.u.)>1.0E-7
	5+	< 2.0 ns	1394.35 14	[E2]			B(E2)(W.u.)>0.00034
	5+	< 2.0 ns	1722.76 18	(M1+E2)	-2.5 14		B(E2)(W.u.)>6.9E-5, B(M1)(W.u.)>1.5E-9
2963.0	8+	0.33 ps 7	886.0 3	E2			B(E2)(W.u.)=105 23
2998.77	(8-)	< 0.2 ns	205.11 5	(M1+E2)	+0.21 2		B(E2)(W.u.)>4.6, B(M1)(W.u.)>0.0062
2998.77	(8-)	< 0.2 ns	299.39 10	(E2)			B(E2)(W.u.)>19
3054.97	1+		2542.70 10	[M1+E2]	+0.07 7
3289.65	(9-)	0.2 ns 1	290.89 10	D+Q	+0.36 4
3289.65	(9-)	0.2 ns 1	495.97 5	E2			B(E2)(W.u.)=1.9 10
E(level) (keV)	J^π(level)	T_1/2(level)	E(γ) (keV)	Multipolarity	Mixing Ratio	Conversion Coefficient	Additional Data
3461.89	9(-)	0.25 ns 10	285.0 5	D+Q	-0.9 5
3461.89	9(-)	0.25 ns 10	463.03 20	D+Q	-0.9 5
5106.6	(12+)		1017.9 4	(D+Q)	-0.36 30

Q(β-)=-2965 keV 3	S(n)= 9561.0 keV 3	S(p)= 9345.8 keV 24	Q(α)= -3229.4 keV 16
Reference: 2012WA38

References:
A	¹⁰⁶Rh β^- decay (30.07 S)	B	¹⁰⁶Rh β^- decay (131 M)
C	¹⁰⁶Ag ε decay (23.96 M)	D	¹⁰⁶Ag ε decay (8.28 d)
E	⁹⁶Zr(¹³C,3nγ)	F	¹⁰⁴Ru(α,2nγ)
G	¹⁰⁵Pd(n,γ),(n,E) E=THERMAL	H	¹⁰⁵Pd(n,γ) E=resonance
I	¹⁰⁵Pd(n,γ) E=RES: AV	J	¹⁰⁵Pd(n,γ) E=2 KEV RES
K	¹⁰⁵Pd(n,γ) E=24 KEV RES	L	¹⁰⁵Pd(d,p)
M	¹⁰⁶Pd(γ,γ’)	N	¹⁰⁶Pd(E,E’)
O	¹⁰⁶Pd(n,n’γ)	P	¹⁰⁶Pd(p,p’),(d,d’)
Q	¹⁰⁶Pd(p,p’γ)	R	¹⁰⁶Pd(α,α’)
S	Coulomb Excitation	T	¹⁰⁸Pd(p,t)
U	¹⁰⁹Ag(p,α)	V	¹⁰⁶Cd 2β⁺ decay

E(level) (keV)	XREF	J^π(level)	T_1/2(level)	E(γ) (keV)	I(γ)	M(γ)	Final Levels
0.0	A B C D E F G H I J K L M N O P R S T U V	0+	STABLE
511.850 23	A B C D E F G H I J K L M N O P R S T U V	2+	12.2 ps 4	511.842 28	100	E2	0.0	0+
1128.02 3	A B C D E F G H I J K L N O P R S T U V	2+	3.12 ps 25	616.174 24 1128.00 6	100.0 24 54.4 8	M1+E2+E0 E2	511.850 0.0	2+ 0+
1133.76 4	A C G H J K O R S T V	0+	5.8 ps 13	6 1 621.94 3 1133.7 7	100.0 12	[E2] E2 E0	1128.02 511.850 0.0	2+ 2+ 0+
1220	U
1229.30 4	A B C D E F G H I J K L N O P R S T	4+	1.31 ps 18	101 1 717.24 6	100	[E2] E2	1128.02 511.850	2+ 2+
1557.68 4	A B D E F G H I J K O	3+		328.460 20 429.64 5 1045.83 8	3.86 17 44.5 12 100 5	E2(+M1) M1+E2 M1+E2	1229.30 1128.02 511.850	4+ 2+ 2+
1562.25 3	A C D F G H I J K L O P T U	2+		333 1 428.56 9 434.25 21 1050.39 5 1562.24 5	4.53 13 1.30 13 100.0 17 10.43 12	[E2] [E2] (M1+E2)	1229.30 1133.76 1128.02 511.850 0.0	4+ 0+ 2+ 2+ 0+
1700	U
1706.44 5	A C G I J K O P T	0+	2.8 ps 5	578.38 9 1194.53 4	15.1 11 100.0 7	E2 E2	1128.02 511.850	2+ 2+
1904.21 9	G	2-,3-		347.14 13 775.75 11	≤198 100 11	E1	1557.68 1128.02	3+ 2+
1909.37 16	A C G H I J K L O P T	2+		781.6 5 1397.4 2 1909.5 3	2.8 9 100.0 10 35 4		1128.02 511.850 0.0	2+ 2+ 0+
1920	U
1932.32 6	B D E F G H I J K L N O P T	4+	1.16 ps 16	374.46 13 703.11 7 804.34 13 1419.4 8	2.12 28 35.8 13 100 4 0.28 14	M1(+E2) M1+E2 E2	1557.68 1229.30 1128.02 511.850	3+ 4+ 2+ 2+
E(level) (keV)	XREF	J^π(level)	T_1/2(level)	E(γ) (keV)	I(γ)	M(γ)	Final Levels
2001.48 5	A C G H I J K O P T	0+		439.19 26 873.48 4 1489.60 19 2002 1	2.9 5 100.0 12 0.75 13	E2 E0	1562.25 1128.02 511.850 0.0	2+ 2+ 2+ 0+
2076.69 4	F H I O	4+		847.270 20 949.52 25 1565.76 11	100 33 12.2 22 5.9 7	E2	1229.30 1128.02 511.850	4+ 2+ 2+
2077.01 6	B D E F G J K	6+	0.49 ps 5	848.0 2	100	E2	1229.30	4+
2083.92 5	B D E F G H I J K L O P R S T	3-	1.2 ps 3	522.30 30 956.22 22 1572.35 15 2084.0 4	1.33 27 7.2 12 100 8 0.35 7	E1 [E3]	1562.25 1128.02 511.850 0.0	2+ 2+ 2+ 0+
2229.20 21	E F			999.9 2	100		1229.30	4+
2242.48 5	A C G H I J K L O P T U	2+		680.22 8 684.80 20 1108.76 12 1114.48 5 1730.35 23 2242.46 12	78 14 42.8 16 47 4 100 7 17.9 13 15.8 7	M1,E2 M1+E2	1562.25 1557.68 1133.76 1128.02 511.850 0.0	2+ 3+ 0+ 2+ 2+ 0+
2278.11 9	A C G J K O	0+		715.90 20 1150.20 20 1766.20 10	29.2 12 8.9 6 100.0 18	[E2] E2	1562.25 1128.02 511.850	2+ 2+ 2+
2283.05 5	D G H I J K L O P R T	4+		1053.77 21 1771.1 3	100 15 4.2 7	M1,E2	1229.30 511.850	4+ 2+
2305.62 5	B D E F G H I J K O T	4-	2.0 ns 5	221.701 10 228.630 20 748.44 7 1077.2 5 1178.07 21 1794.01 27	32.3 11 10.2 5 100.0 26 0.26 9 0.94 13 0.18 7	M1+E2 E1 [M2] [M2]	2083.92 2077.01 1557.68 1229.30 1128.02 511.850	3- 6+ 3+ 4+ 2+ 2+
E(level) (keV)	XREF	J^π(level)	T_1/2(level)	E(γ) (keV)	I(γ)	M(γ)	Final Levels
2308.82 5	A C G H I J K L O U	2+		751.30 20 1180.72 6 1796.97 7 2309.30 20	3.9 8 52.6 13 100.0 15 ≤9.0	M1+E2 M1+E2	1557.68 1128.02 511.850 0.0	3+ 2+ 2+ 0+
2350.86 5	B D F G I J K L O T	4+		418.71 28 793.30 25 1121.60 18 1222.88 12 1839.05 10	5.2 10 83 4 8.1 9 100 5 29 4	M1+E2 E2 E2	1932.32 1557.68 1229.30 1128.02 511.850	4+ 3+ 4+ 2+ 2+
2366.01 5	D E F G H J K O	5+		433.9 4 808.37 10 1136.85 19	2.2 9 100 5 5.7 7	(M1+E2)	1932.32 1557.68 1229.30	4+ 3+ 4+
2397.41 25	D E G L P R T U	(5)-		1168.25 25	100	E1+M2	1229.30	4+
2400.84 25	G H I J K O	2-,3-		1272.4 3 1889.7 4	100 12 52 12		1128.02 511.850	2+ 2+
2439.10 7	A C G I J K L O T	2+		1209.80 20 1305.20 20 1927.27 10 2439.07 12	2.9 7 8.7 9 100.0 26 30.1 13	[M1+E2] [E2]	1229.30 1133.76 511.850 0.0	4+ 0+ 2+ 0+
2472.26 10	G I L O	1+,2+		471.5 2 765.67 12 1960.17 20	83 8 100 17		2001.48 1706.44 511.850	0+ 0+ 2+
2484.66 20	A G H I J K O	(1-)		1973.5 10 2484.60 20	20 11 100 7		511.850 0.0	2+ 0+
2495 1	P R	1-
2500 4	A G T U	2+
2500.31 8	C H I L O	2-		942.6 4 1372.30 30 1988.44 8	2.2 5 7.9 7 100.0 8	E1+M2	1557.68 1128.02 511.850	3+ 2+ 2+
2578.56 24	D E F G H I L O P T U	(5-)		1020.7 3 1349.5 6	50 8 100 11		1557.68 1229.30	3+ 4+
E(level) (keV)	XREF	J^π(level)	T_1/2(level)	E(γ) (keV)	I(γ)	M(γ)	Final Levels
2591.6 4	H I L O	(2,3)+		659.3 3	100		1932.32	4+
2624.40 5	A C G O	0+		1062.14 5 1496.33 13 2112.54 6	92.9 12 64.5 18 100 5	[E2]	1562.25 1128.02 511.850	2+ 2+ 2+
2626.84 9	G I L	(2,3)+		1064.60 11 1498.80 20 2114.95 13	12 2 ≤100 49 7		1562.25 1128.02 511.850	2+ 2+ 2+
2648.9 5	I L O P R T	4+		1086.5 5	100		1562.25	2+
2699.37 15	E F L	(6)-	0.5 ns 1	301.99 10 393.36 20	100 3 14 2	M1+E2 E2	2397.41 2305.62	(5)- 4-
2705.30 8	A C I O	(1)+		702.8 10 1572.40 20 1577.20 20 2193.30 10 2705.02 18	6 4 3.8 4 22 4 100 6 50.5 20	M1+E2	2001.48 1133.76 1128.02 511.850 0.0	0+ 0+ 2+ 2+ 0+
2712 5	P	(4+)
2713.89 8	A G I L	2+,3+		1156.28 12 1484.49 11 2202.07 15	100 13 50 7 30 5		1557.68 1229.30 511.850	3+ 4+ 2+
2717.59 21	A			1159.90 20	100		1557.68	3+
2737	L T
2741.0 5	G O P	4+		2229.5 10 2740.9 5	51 13 100 28		511.850 0.0	2+ 0+
2748.2 4	H I O T	2,3-		2236.3 4	100		511.850	2+
2757.06 4	B D F L R	5+	< 3.6 ns	178.2 5 391.039 30 406.17 3 450.97 3 474.060 30 680.420 10 824.79 15 1199.39 10 1527.65 19	0.19 6 13.3 5 47.6 11 100.0 22 3.31 19 5.50 28 54.7 14 40.0 19 58 15	E2(+M1) M1+E2 E1 M1+E2 M1,E2 M1+E2 E2 M1+E2	2578.56 2366.01 2350.86 2305.62 2283.05 2076.69 1932.32 1557.68 1229.30	(5-) 5+ 4+ 4- 4+ 4+ 4+ 3+ 4+
E(level) (keV)	XREF	J^π(level)	T_1/2(level)	E(γ) (keV)	I(γ)	M(γ)	Final Levels
2775.9 8	G T	(4+)		533.53 12 1218.26 14 1546.64 16 2263.84 17	64 8 100 17 36 6 64 11		2242.48 1557.68 1229.30 511.850	2+ 3+ 4+ 2+
2783.74 21	A G I L O P T	2+		1554.50 15 1655.66 17 2271.84 15	3.7 10 7.3 10 100 16		1229.30 1128.02 511.850	4+ 2+ 2+
2793.67 16	E F L	(7-)		396.26 5 717.1 4	100 2 81 5	(E2) (E1)	2397.41 2077.01	(5)- 6+
2820.97 9	A G L O P	2+		1258.80 20 1687.40 30 1693.20 30 2309.00 10 2821.10 30	13.3 19 13 3 15 3 100.0 29 28 1		1562.25 1133.76 1128.02 511.850 0.0	2+ 0+ 2+ 2+ 0+
2828.29 9	A C G L T	0+		1266.00 20 2316.42 9	16.3 16 100.0 9	E2	1562.25 511.850	2+ 2+
2847 5	I P	(4+)
2850.6 5	G L O	2+,3+		1621.3 4	100		1229.30	4+
2861.4 4	G I O	(+)		1303.4 4 1631.7 6	100 28 52 12		1557.68 1229.30	3+ 4+
2877.92 7	A C G I	0+		1315.70 20 2366.04 7	14.9 9 100.0 9	[E2] [E2]	1562.25 511.850	2+ 2+
2879 5	L P	(1-)
2886.5 7	G I O	(-)		2374.6 7	100		511.850	2+
2898.1 7	G I O	(1-,4-)		1668.8 7	100		1229.30	4+
2902.48 10	A G L O	2+		1774.5 7 2390.60 10 2902.5 8	19 3 100.0 22 1.0 3	(M1+E2)	1128.02 511.850 0.0	2+ 2+ 0+
2908.7 7	G I O P	(1-)		2396.8 7	100		511.850	2+
2917.86 8	A G I L O T	2+		1355.70 30 1360.20 30 1784.10 30 2405.96 9 2917.90 30	4.4 10 15.4 4 3.0 8 100.0 28 6.34 28	M1+E2	1562.25 1557.68 1133.76 511.850 0.0	2+ 3+ 0+ 2+ 0+
E(level) (keV)	XREF	J^π(level)	T_1/2(level)	E(γ) (keV)	I(γ)	M(γ)	Final Levels
2930 5	G P	4+
2936.0 6	I O	(2-,3-)		2424.1 6	100		511.850	2+
2951.84 6	B D L	5+	< 2.0 ns	195.06 15 585.97 10 601.17 7 646.02 5 874.81 18 1019.9 3 1394.35 14 1722.76 18	19.5 20 28.2 26 100 4 90 4 20.7 27 66 5 93 11 74 14	M1(+E2) M1(+E2) M1+E2 E1 M1,E2 [E2] (M1+E2)	2757.06 2366.01 2350.86 2305.62 2077.01 1932.32 1557.68 1229.30	5+ 5+ 4+ 4- 6+ 4+ 3+ 4+
2963.0 4	E F	8+	0.33 ps 7	886.0 3	100	E2	2077.01	6+
2968.68 21	A G H I O P T	3-		2456.8 2	100		511.850	2+
2977.4 20	I L	+
2977.93 21	E U	(7-)		901.1 2	100	(E1)	2077.01	6+
2998.77 16	E F	(8-)	< 0.2 ns	205.11 5 299.39 10	100 6 96 10	(M1+E2) (E2)	2793.67 2699.37	(7-) (6)-
3026 3	L	+
3037.32 17	A G O	1,2		1909.30 20 2525.2 6 3037.30 30	100 7 14.3 29 71.4 29		1128.02 511.850 0.0	2+ 2+ 0+
3042.7 25	I L P	4+
3054.97 9	A G I L O	1+		1498.80 20 2542.70 10 3055.0 4	100 6 44 2 5 1	[M1+E2]	1557.68 511.850 0.0	3+ 2+ 0+
3069 5	L P	2+
3069.9 6	G I O	(2,3)-		2558.0 6	100		511.850	2+
3083.91 18	A L O P	0		1954.6 4 2571.10 20	12.7 28 100 4	Q	1128.02 511.850	2+ 2+
3097 3	L	(1-,2+)
3120.0 10	L O	2+,3+		2608.1 10	100		511.850	2+
E(level) (keV)	XREF	J^π(level)	T_1/2(level)	E(γ) (keV)	I(γ)	M(γ)	Final Levels
3123 5	P	(6+)
3144 3	L	2+,3+
3161.0 5	L O	2+		1602.2 12 2649.3 5	23 12 100 18	Q	1557.68 511.850	3+ 2+
3163.7 3	A O P	(1,2+)		2651.7 3 3165.4 13			511.850 0.0	2+ 0+
3173.8 6	G L O	(2+,3+)		1616.4 6 2045.1 9	93 28 100 23		1557.68 1128.02	3+ 2+
3176.77 20	E F	(8-)		199.0 3 383.11 20 477.0 3	46 8 100 12 62 12	(D+Q) D+Q	2977.93 2793.67 2699.37	(7-) (7-) (6)-
3217 5	P T	3-
3221.37 25	A G	0+		2093.3 4 2709.5 3	9.8 22 100 27	[E2] [E2]	1128.02 511.850	2+ 2+
3249.9 5	A P T	2+		3249.8 5	100		0.0	0+
3252.0 4	A	2+		2740.1 4	100		511.850	2+
3273.5 7	A	1,2		3273.4 7	100		0.0	0+
3275 5	P	3-
3289.65 16	E F	(9-)	0.2 ns 1	290.89 10 495.97 5	63 2 100 5	D+Q E2	2998.77 2793.67	(8-) (7-)
3299.2 7	A			2787.3 7	100		511.850	2+
3320.5 3	A G	0+		2185.7 5 ? 2809.00 30	35 9 100 6	[E2]	1133.76 511.850	0+ 2+
3321 5	P	5-
3359 5	P	(5-,6+)
3397 5	A P	4+
3414 5	P	3-
3449 5	P	2+
3461.89 20	E F	9(-)	0.25 ns 10	285.0 5 463.03 20 484.2 3 668.1 3	27 9 64 9 41 9 100 14	D+Q D+Q	3176.77 2998.77 2977.93 2793.67	(8-) (8-) (7-) (7-)
E(level) (keV)	XREF	J^π(level)	T_1/2(level)	E(γ) (keV)	I(γ)	M(γ)	Final Levels
3490 5	P	2+
3532 5	P	(5-)
3533.5 4	E F	10+		570.47 5	100	E2	2963.0	8+
3575 5	P	5-
3607 5	P	(3-)
3647 5	P	2+
3654.16 20	E F	10(-)		655.40 15	100	(E2)	2998.77	(8-)
3708 5	P	(5-)
3761 5	P	3-
3805 5	P	(3-)
3825 5	P	3-
3874.80 12	E	(10-)		412.8 3 697.96 20 876.3 3	30 8 100 8 44 26	(Q)	3461.89 3176.77 2998.77	9(-) (8-) (8-)
3879 5	P	3-
3903 5	P	3-
3938 5	P	2+
3949.1 5	E F	(10+)		986.1 3	100	(E2)	2963.0	8+
3998 5	P	4+
4021.73 11	E F	11(-)		367.6 2 732.07 10	8 2 100 6	(Q)	3654.16 3289.65	10(-) (9-)
4042 5	P	4+
4054 5	P	2+
4088.7 1	E	12+		555.2 2	100 5	E2	3533.5	10+
4106 5	P	4+
4134 5	P	3-
4156 5	P	3-
4193 5	P
4224 5	P	4+
4259.8 4	E	(11-)		797.9 3	100 15		3461.89	9(-)
E(level) (keV)	XREF	J^π(level)	T_1/2(level)	E(γ) (keV)	I(γ)	M(γ)	Final Levels
4640.2 4	E	(12-)		986.1 3	100		3654.16	10(-)
4721.8 4	E	12(+)		633.1 3 1188.3 2	100 25 100 17	Q	4088.7 3533.5	12+ 10+
4752.3 4	E	(12-)		877.5 3	100		3874.80	(10-)
4893.8 3	E	14+		805.1 2	100	E2	4088.7	12+
4990.1 4	E	(13-)		968.4 3	100	(Q)	4021.73	11(-)
5106.6 6	E	(12+)		1017.9 4	100	(D+Q)	4088.7	12+
5404.0 5	E	(14+)		682.2 2 1315.3 3	100 12 76 12	(Q) (Q)	4721.8 4088.7	12(+) 12+
5895.0 6	E	(16+)		1001.2 3	100		4893.8	14+

E(level)	J^π(level)	T_1/2(level)	Comments
0.0	0+	STABLE	rms charge radius: 4.5322 fm 28 (2004An14). E(level): possible MEMBER OF ΔJ=2 band BUILT ON γ.S.
511.850	2+	12.2 ps 4	μ=0.74 3, Q=-0.51 7 E(level): possible MEMBER OF ΔJ=2 band BUILT ON γ.S.
1133.76	0+	5.8 ps 13	B(E2)[2⁺(511 keV) to 0⁺(1133 keV)]=0.021 4: weighted average of 0.0184 (1969Ro05) and 0.026 5(1995Sv01) in Coul. ex. E(level): B(E2)[2⁺(511 keV) to 0⁺(1133 keV)]=0.021 4: weighted average of 0.0184 (1969Ro05) and 0.026 5(1995Sv01) in Coul. ex.
1229.30	4+	1.31 ps 18	B(E2)[2⁺ (511 keV) to 4⁺(1229 keV)]=0.38 3 weighted average of B(E2)[2⁺ (511 keV) to 4⁺(1229 keV)]=0.39 5 (1969Ro05) and 0.38 4 (1995Sv01). Other: 0.51 9 (1962Ec03). E(level): possible MEMBER OF ΔJ=2 band BUILT ON γ.S.
1909.37	2+		E(level): From ¹⁰⁵Pd(n,γ)(n,e). From ¹⁰⁶Pd(n,n’γ).
2077.01	6+	0.49 ps 5	E(level): possible MEMBER OF ΔJ=2 band BUILT ON γ.S.
2400.84	2-,3-		E(level): From ¹⁰⁵Pd(n,γ).
2472.26	1+,2+		E(level): From ¹⁰⁵Pd(n,γ)(n,e). From ¹⁰⁶Pd(n,n’γ).
2578.56	(5-)		E(level): From ¹⁰⁵Pd(n,γ)(n,e). From ¹⁰⁶Pd(n,n’γ).
2591.6	(2,3)+		E(level): From ¹⁰⁵Pd(n,γ)(n,e). From ¹⁰⁶Pd(n,n’γ).
2626.84	(2,3)+		Discrepancies exist for branching ratios of the 2626 and 3054 keV levels in (n,γ) and (n,n’γ) reactions due to unresolved doublet of 1498γ deexciting both levels.
2648.9	4+		E(level): From ¹⁰⁵Pd(n,γ)(n,e). From ¹⁰⁶Pd(n,n’γ).
2699.37	(6)-	0.5 ns 1	E(level): From ⁹⁶Zr(¹³C,3nγ).
2713.89	2+,3+		E(level): From ¹⁰⁵Pd(n,γ).
2741.0	4+		XREF: p(2746). E(level): From ¹⁰⁵Pd(n,γ)(n,e). From ¹⁰⁶Pd(n,n’γ).
2748.2	2,3-		E(level): From ¹⁰⁵Pd(n,γ)(n,e). From ¹⁰⁶Pd(n,n’γ).
2775.9	(4+)		E(level): From ¹⁰⁵Pd(n,γ)(n,e). From ¹⁰⁶Pd(n,n’γ).
2793.67	(7-)		E(level): From ⁹⁶Zr(¹³C,3nγ).
2847	(4+)		L(p,p’)=(4).
2850.6	2+,3+		E(level): From ¹⁰⁵Pd(n,γ)(n,e). From ¹⁰⁶Pd(n,n’γ).
2861.4	(+)		E(level): From ¹⁰⁵Pd(n,γ)(n,e). From ¹⁰⁶Pd(n,n’γ).
2886.5	(-)		E(level): From ¹⁰⁵Pd(n,γ)(n,e). From ¹⁰⁶Pd(n,n’γ).
2898.1	(1-,4-)		E(level): From ¹⁰⁵Pd(n,γ)(n,e). From ¹⁰⁶Pd(n,n’γ).
2908.7	(1-)		E(level): From ¹⁰⁵Pd(n,γ)(n,e). From ¹⁰⁶Pd(n,n’γ).
2936.0	(2-,3-)		E(level): From ¹⁰⁵Pd(n,γ)(n,e). From ¹⁰⁶Pd(n,n’γ).
E(level)	J^π(level)	T_1/2(level)	Comments
2963.0	8+	0.33 ps 7	E(level): From ⁹⁶Zr(¹³C,3nγ); possible member of ΔJ=2 band built on g.s.
2977.4	+		E(level): From ¹⁰⁵Pd(n,γ).
2977.93	(7-)		E(level): From ⁹⁶Zr(¹³C,3nγ).
2998.77	(8-)	< 0.2 ns	E(level): From ⁹⁶Zr(¹³C,3nγ).
3026	+		E(level): From ¹⁰⁵Pd(d,p).
3042.7	4+		E(level): From ¹⁰⁵Pd(n,γ).
3069.9	(2,3)-		E(level): From ¹⁰⁵Pd(n,γ)(n,e). From ¹⁰⁶Pd(n,n’γ).
3097	(1-,2+)		E(level): From ¹⁰⁵Pd(d,p).
3120.0	2+,3+		E(level): From ¹⁰⁵Pd(n,γ)(n,e). From ¹⁰⁶Pd(n,n’γ).
3144	2+,3+		E(level): From ¹⁰⁵Pd(d,p).
3173.8	(2+,3+)		E(level): From ¹⁰⁵Pd(n,γ)(n,e). From ¹⁰⁶Pd(n,n’γ).
3176.77	(8-)		E(level): From ⁹⁶Zr(¹³C,3nγ).
3289.65	(9-)	0.2 ns 1	E(level): From ⁹⁶Zr(¹³C,3nγ).
3461.89	9(-)	0.25 ns 10	E(level): From ⁹⁶Zr(¹³C,3nγ).
3533.5	10+		E(level): From ⁹⁶Zr(¹³C,3nγ).
3874.80	(10-)		E(level): From ⁹⁶Zr(¹³C,3nγ).
3949.1	(10+)		E(level): From ⁹⁶Zr(¹³C,3nγ); possible member of ΔJ=2 band built on g.s.
4021.73	11(-)		E(level): From ⁹⁶Zr(¹³C,3nγ).
4088.7	12+		E(level): From ⁹⁶Zr(¹³C,3nγ).
4259.8	(11-)		E(level): From ⁹⁶Zr(¹³C,3nγ).
4640.2	(12-)		E(level): From ⁹⁶Zr(¹³C,3nγ).
4721.8	12(+)		E(level): From ⁹⁶Zr(¹³C,3nγ).
4893.8	14+		E(level): From ⁹⁶Zr(¹³C,3nγ).
4990.1	(13-)		E(level): From ⁹⁶Zr(¹³C,3nγ).
5106.6	(12+)		E(level): From ⁹⁶Zr(¹³C,3nγ).
E(level)	J^π(level)	T_1/2(level)	Comments
5404.0	(14+)		E(level): From ⁹⁶Zr(¹³C,3nγ).
5895.0	(16+)		E(level): From ⁹⁶Zr(¹³C,3nγ).

E(level)	E(gamma)	Comments
1133.76	6	E(γ): Deduced from level scheme in Coul. ex. (1995Sv01)
1229.30	101	E(γ): calculated from level scheme in (1995Sv01)
1557.68	328.460	M(γ): No δ given in ¹⁰⁶Rh β^- decay (131 min)
1562.25	333	E(γ): Deduced by evaluators from level scheme in Coul. ex. (1995Sv01)
1706.44	1194.53	M(γ): from α(K)exp in (n,γ). M1 excluded if Jπ for the initial and final states are correct
1904.21	347.14	E(γ): No final level within 0.48 keV M(γ): from α(K)exp=0.0041 10 for the 346.59⁺347.14 γ transitions
1909.37	781.6	E(γ): From ¹⁰⁶Pd(n,n’γ) I(γ): From ¹⁰⁶Pd(n,n’γ)
	1397.4	E(γ): From ¹⁰⁶Pd(n,n’γ) I(γ): From ¹⁰⁶Pd(n,n’γ)
	1909.5	E(γ): From ¹⁰⁶Pd(n,n’γ) I(γ): From ¹⁰⁶Pd(n,n’γ)
2001.48	2002	M(γ): from conversion data in ¹⁰⁵Pd(n,γ)(n,e)
2076.69	949.52	E(γ): No final level within 0.79 keV
2076.69	1565.76	E(γ): No final level within 0.48 keV
2242.48	680.22	M(γ): from α(K)exp in (n,γ). α(K)exp also consistent with E1⁺M2 with δ=0.4
2278.11	1766.20	M(γ): from α(K)exp in ¹⁰⁵Pd(n,γ)(n,e)
2283.05	1053.77	M(γ): from α(K)exp in (n,γ)
2305.62	228.630	E(γ): No final level within 0.13 keV
2305.62	748.44	E(γ): no final level within 0.33 keV
2308.82	751.30	I(γ): From ¹⁰⁶Rh β^- decay
	1180.72	I(γ): From ¹⁰⁶Rh β^- decay
	1796.97	I(γ): From ¹⁰⁶Rh β^- decay
	2309.30	I(γ): taken from ¹⁰⁶Rh β^- decay using the ratio Iγ(2309 from 2309) /Iγ(1180γ+1797γ)\|<0.051 8 from ε decay but taking into account the division of the I(2309γ) of the doublet of 2309γ between 2308 and 2821 levels. From ¹⁰⁶Rh β^- decay
2366.01	808.37	M(γ): deduced under the assumption Jπ(2365)=4⁺. γγ(θ) also consistent with mult(808γ)=E2 and Jπ(2365)=5⁺. M1 fraction impossible if Jπ(2566)=5⁺ and Jπ(1557)=3⁺
2472.26	471.5	E(γ): From ¹⁰⁶Pd(n,n’γ) I(γ): From ¹⁰⁶Pd(n,n’γ)
	765.67	E(γ): From ¹⁰⁵Pd(n,γ)(n,e). From ¹⁰⁶Pd(n,n’γ) I(γ): From ¹⁰⁵Pd(n,γ)(n,e)
	1960.17	E(γ): From ¹⁰⁵Pd(n,γ)(n,e). From ¹⁰⁶Pd(n,n’γ) I(γ): From ¹⁰⁵Pd(n,γ)(n,e)
E(level)	E(gamma)	Comments
2578.56	1020.7	E(γ): From ¹⁰⁶Pd(n,n’γ) I(γ): From ¹⁰⁶Pd(n,n’γ)
2578.56	1349.5	E(γ): From ¹⁰⁶Pd(n,n’γ) I(γ): From ¹⁰⁶Pd(n,n’γ)
2591.6	659.3	E(γ): From ¹⁰⁶Pd(n,n’γ) I(γ): From ¹⁰⁶Pd(n,n’γ)
2626.84	1064.60	E(γ): From ¹⁰⁵Pd(n,γ)(n,e). From ¹⁰⁶Pd(n,n’γ). From ¹⁰⁵Pd(d,p) I(γ): From ¹⁰⁵Pd(n,γ)(n,e). The 1498γ is doubly placed in (n,γ),(n,n’γ); however, the branchings in these data sets are not consistent if one assumes that the 2626 level is not fed in β^- decay. These branchings can be made consistent if part of 1498γ intensity in β^- decay is placed from the 2626 level. The 2114 level, which also deexcites 2626 level is not seen in β^- decay, but would be masked by strong 2112.5 γ.
	1498.80	E(γ): From ¹⁰⁵Pd(n,γ)(n,e). From ¹⁰⁶Pd(n,n’γ). From ¹⁰⁵Pd(d,p) I(γ): From ¹⁰⁵Pd(n,γ)(n,e). The 1498γ is doubly placed in (n,γ),(n,n’γ); however, the branchings in these data sets are not consistent if one assumes that the 2626 level is not fed in β^- decay. These branchings can be made consistent if part of 1498γ intensity in β^- decay is placed from the 2626 level. The 2114 level, which also deexcites 2626 level is not seen in β^- decay, but would be masked by strong 2112.5 γ.
	2114.95	E(γ): From ¹⁰⁵Pd(n,γ)(n,e). From ¹⁰⁶Pd(n,n’γ). From ¹⁰⁵Pd(d,p) I(γ): From ¹⁰⁵Pd(n,γ)(n,e). The 1498γ is doubly placed in (n,γ),(n,n’γ); however, the branchings in these data sets are not consistent if one assumes that the 2626 level is not fed in β^- decay. These branchings can be made consistent if part of 1498γ intensity in β^- decay is placed from the 2626 level. The 2114 level, which also deexcites 2626 level is not seen in β^- decay, but would be masked by strong 2112.5 γ.
2648.9	1086.5	E(γ): From ¹⁰⁶Pd(n,n’γ) I(γ): From ¹⁰⁶Pd(n,n’γ)
2699.37	301.99	E(γ): From ⁹⁶Zr(¹³C,3nγ) I(γ): From ⁹⁶Zr(¹³C,3nγ)
2699.37	393.36	E(γ): From ⁹⁶Zr(¹³C,3nγ) I(γ): From ⁹⁶Zr(¹³C,3nγ)
2705.30	1572.40	E(γ): No final level within 0.68 keV
2713.89	1156.28	E(γ): From ¹⁰⁵Pd(n,γ)(n,e). From ¹⁰⁶Pd(n,n’γ) I(γ): From ¹⁰⁵Pd(n,γ)(n,e)
	1484.49	E(γ): From ¹⁰⁵Pd(n,γ)(n,e). From ¹⁰⁶Pd(n,n’γ) I(γ): From ¹⁰⁵Pd(n,γ)(n,e)
	2202.07	E(γ): From ¹⁰⁵Pd(n,γ)(n,e). From ¹⁰⁶Pd(n,n’γ) I(γ): From ¹⁰⁵Pd(n,γ)(n,e)
2741.0	2229.5	E(γ): From ¹⁰⁶Pd(n,n’γ) I(γ): From ¹⁰⁶Pd(n,n’γ)
2741.0	2740.9	E(γ): From ¹⁰⁶Pd(n,n’γ) I(γ): From ¹⁰⁶Pd(n,n’γ)
2748.2	2236.3	E(γ): From ¹⁰⁶Pd(n,n’γ) I(γ): From ¹⁰⁶Pd(n,n’γ)
2775.9	533.53	E(γ): From ¹⁰⁵Pd(n,γ)(n,e). From ¹⁰⁶Pd(n,n’γ) I(γ): From ¹⁰⁵Pd(n,γ)(n,e)
	1218.26	E(γ): From ¹⁰⁵Pd(n,γ)(n,e). From ¹⁰⁶Pd(n,n’γ) I(γ): From ¹⁰⁵Pd(n,γ)(n,e)
	1546.64	E(γ): From ¹⁰⁵Pd(n,γ)(n,e). From ¹⁰⁶Pd(n,n’γ) I(γ): From ¹⁰⁵Pd(n,γ)(n,e)
	2263.84	E(γ): From ¹⁰⁵Pd(n,γ)(n,e). From ¹⁰⁶Pd(n,n’γ) I(γ): From ¹⁰⁵Pd(n,γ)(n,e)
2783.74	1554.50	E(γ): From ¹⁰⁵Pd(n,γ)(n,e). From ¹⁰⁶Pd(n,n’γ) I(γ): From ¹⁰⁵Pd(n,γ)(n,e)
	1655.66	E(γ): From ¹⁰⁵Pd(n,γ)(n,e). From ¹⁰⁶Pd(n,n’γ) I(γ): From ¹⁰⁵Pd(n,γ)(n,e)
	2271.84	E(γ): From ¹⁰⁵Pd(n,γ)(n,e). From ¹⁰⁶Pd(n,n’γ) I(γ): From ¹⁰⁵Pd(n,γ)(n,e)
2793.67	396.26	E(γ): From ⁹⁶Zr(¹³C,3nγ) I(γ): From ⁹⁶Zr(¹³C,3nγ)
2793.67	717.1	E(γ): From ⁹⁶Zr(¹³C,3nγ) I(γ): From ⁹⁶Zr(¹³C,3nγ)
E(level)	E(gamma)	Comments
2820.97	1258.80	I(γ): From ¹⁰⁶Rh β^- decay
	1687.40	I(γ): From ¹⁰⁶Rh β^- decay
	1693.20	I(γ): From ¹⁰⁶Rh β^- decay
	2309.00	I(γ): taken from ¹⁰⁶Rh β^- decay using the ratio Iγ(2309 from 2309) /Iγ(1180γ+1797γ)\|<0.051 8 from ε decay but taking into account the division of the I(2309γ) of the doublet of 2309γ between 2308 and 2821 levels. From ¹⁰⁶Rh β^- decay
	2821.10	I(γ): From ¹⁰⁶Rh β^- decay
2850.6	1621.3	E(γ): From ¹⁰⁶Pd(n,n’γ) I(γ): From ¹⁰⁶Pd(n,n’γ)
2861.4	1303.4	E(γ): From ¹⁰⁶Pd(n,n’γ) I(γ): From ¹⁰⁶Pd(n,n’γ)
2861.4	1631.7	E(γ): From ¹⁰⁶Pd(n,n’γ) I(γ): From ¹⁰⁶Pd(n,n’γ)
2886.5	2374.6	E(γ): From ¹⁰⁶Pd(n,n’γ) I(γ): From ¹⁰⁶Pd(n,n’γ)
2898.1	1668.8	E(γ): From ¹⁰⁶Pd(n,n’γ) I(γ): From ¹⁰⁶Pd(n,n’γ)
2908.7	2396.8	E(γ): From ¹⁰⁶Pd(n,n’γ) I(γ): From ¹⁰⁶Pd(n,n’γ)
2936.0	2424.1	E(γ): From ¹⁰⁶Pd(n,n’γ) I(γ): From ¹⁰⁶Pd(n,n’γ)
2951.84	1394.35	E(γ): taken from ¹⁰⁶Ag ε decay (8.46 d)
2963.0	886.0	E(γ): From ⁹⁶Zr(¹³C,3nγ) I(γ): From ⁹⁶Zr(¹³C,3nγ)
2968.68	2456.8	E(γ): taken from ¹⁰⁶Rh β^- decay (29.8 s)
2977.93	901.1	E(γ): From ⁹⁶Zr(¹³C,3nγ) I(γ): From ⁹⁶Zr(¹³C,3nγ)
2998.77	205.11	E(γ): From ⁹⁶Zr(¹³C,3nγ) I(γ): From ⁹⁶Zr(¹³C,3nγ) M(γ): from level scheme
2998.77	299.39	E(γ): From ⁹⁶Zr(¹³C,3nγ) I(γ): From ⁹⁶Zr(¹³C,3nγ)
3054.97	1498.80	E(γ): No final level within 0.89 keV. From ¹⁰⁵Pd(d,p) I(γ): From ¹⁰⁶Rh β^- decay. The 1498γ is doubly placed in (n,γ),(n,n’γ); however, the branchings in these data sets are not consistent if one assumes that the 2626 level is not fed in β^- decay. These branchings can be made consistent if part of 1498γ intensity in β^- decay is placed from the 2626 level. The 2114 level, which also deexcites 2626 level is not seen in β^- decay, but would be masked by strong 2112.5 γ.
	2542.70	E(γ): From ¹⁰⁵Pd(d,p) I(γ): From ¹⁰⁶Rh β^- decay. The 1498γ is doubly placed in (n,γ),(n,n’γ); however, the branchings in these data sets are not consistent if one assumes that the 2626 level is not fed in β^- decay. These branchings can be made consistent if part of 1498γ intensity in β^- decay is placed from the 2626 level. The 2114 level, which also deexcites 2626 level is not seen in β^- decay, but would be masked by strong 2112.5 γ.
	3055.0	E(γ): From ¹⁰⁵Pd(d,p) I(γ): From ¹⁰⁶Rh β^- decay. The 1498γ is doubly placed in (n,γ),(n,n’γ); however, the branchings in these data sets are not consistent if one assumes that the 2626 level is not fed in β^- decay. These branchings can be made consistent if part of 1498γ intensity in β^- decay is placed from the 2626 level. The 2114 level, which also deexcites 2626 level is not seen in β^- decay, but would be masked by strong 2112.5 γ.
3069.9	2558.0	E(γ): From ¹⁰⁶Pd(n,n’γ) I(γ): From ¹⁰⁶Pd(n,n’γ)
3083.91	2571.10	E(γ): No final level within 0.78 keV
3120.0	2608.1	E(γ): From ¹⁰⁶Pd(n,n’γ) I(γ): From ¹⁰⁶Pd(n,n’γ)
3161.0	1602.2	E(γ): From ¹⁰⁶Pd(n,n’γ) I(γ): From ¹⁰⁶Pd(n,n’γ)
3161.0	2649.3	E(γ): From ¹⁰⁶Pd(n,n’γ) I(γ): From ¹⁰⁶Pd(n,n’γ)
E(level)	E(gamma)	Comments
3163.7	3165.4	E(γ): From ¹⁰⁶Pd(n,n’γ) I(γ): From ¹⁰⁶Pd(n,n’γ)
3173.8	1616.4	E(γ): From ¹⁰⁶Pd(n,n’γ) I(γ): From ¹⁰⁶Pd(n,n’γ)
3173.8	2045.1	E(γ): From ¹⁰⁶Pd(n,n’γ) I(γ): From ¹⁰⁶Pd(n,n’γ)
3176.77	199.0	E(γ): From ⁹⁶Zr(¹³C,3nγ) I(γ): From ⁹⁶Zr(¹³C,3nγ) M(γ): no δ given in ⁹⁶Zr(¹³C,3nγ).
	383.11	E(γ): From ⁹⁶Zr(¹³C,3nγ) I(γ): From ⁹⁶Zr(¹³C,3nγ)
	477.0	E(γ): From ⁹⁶Zr(¹³C,3nγ) I(γ): From ⁹⁶Zr(¹³C,3nγ)
3289.65	290.89	E(γ): From ⁹⁶Zr(¹³C,3nγ) I(γ): From ⁹⁶Zr(¹³C,3nγ)
3289.65	495.97	E(γ): From ⁹⁶Zr(¹³C,3nγ) I(γ): From ⁹⁶Zr(¹³C,3nγ)
3461.89	285.0	E(γ): From ⁹⁶Zr(¹³C,3nγ) I(γ): From ⁹⁶Zr(¹³C,3nγ)
	463.03	E(γ): From ⁹⁶Zr(¹³C,3nγ) I(γ): From ⁹⁶Zr(¹³C,3nγ)
	484.2	E(γ): From ⁹⁶Zr(¹³C,3nγ) I(γ): From ⁹⁶Zr(¹³C,3nγ)
	668.1	E(γ): From ⁹⁶Zr(¹³C,3nγ) I(γ): From ⁹⁶Zr(¹³C,3nγ)
3533.5	570.47	E(γ): From ⁹⁶Zr(¹³C,3nγ) I(γ): From ⁹⁶Zr(¹³C,3nγ)
3654.16	655.40	E(γ): From ⁹⁶Zr(¹³C,3nγ) I(γ): From ⁹⁶Zr(¹³C,3nγ)
3874.80	412.8	E(γ): From ⁹⁶Zr(¹³C,3nγ) I(γ): From ⁹⁶Zr(¹³C,3nγ)
	697.96	E(γ): From ⁹⁶Zr(¹³C,3nγ) I(γ): From ⁹⁶Zr(¹³C,3nγ)
	876.3	E(γ): From ⁹⁶Zr(¹³C,3nγ) I(γ): From ⁹⁶Zr(¹³C,3nγ)
3949.1	986.1	E(γ): From ⁹⁶Zr(¹³C,3nγ) I(γ): From ⁹⁶Zr(¹³C,3nγ)
4021.73	367.6	E(γ): From ⁹⁶Zr(¹³C,3nγ) I(γ): From ⁹⁶Zr(¹³C,3nγ)
4021.73	732.07	E(γ): From ⁹⁶Zr(¹³C,3nγ) I(γ): From ⁹⁶Zr(¹³C,3nγ)
4088.7	555.2	E(γ): From ⁹⁶Zr(¹³C,3nγ) I(γ): From ⁹⁶Zr(¹³C,3nγ)
4259.8	797.9	E(γ): From ⁹⁶Zr(¹³C,3nγ) I(γ): From ⁹⁶Zr(¹³C,3nγ)
4640.2	986.1	E(γ): From ⁹⁶Zr(¹³C,3nγ) I(γ): From ⁹⁶Zr(¹³C,3nγ)
4721.8	633.1	E(γ): From ⁹⁶Zr(¹³C,3nγ) I(γ): From ⁹⁶Zr(¹³C,3nγ)
4721.8	1188.3	E(γ): From ⁹⁶Zr(¹³C,3nγ) I(γ): From ⁹⁶Zr(¹³C,3nγ)
E(level)	E(gamma)	Comments
4893.8	805.1	E(γ): From ⁹⁶Zr(¹³C,3nγ) I(γ): From ⁹⁶Zr(¹³C,3nγ)
4990.1	968.4	E(γ): From ⁹⁶Zr(¹³C,3nγ) I(γ): From ⁹⁶Zr(¹³C,3nγ)
5106.6	1017.9	E(γ): From ⁹⁶Zr(¹³C,3nγ) I(γ): From ⁹⁶Zr(¹³C,3nγ)
5404.0	682.2	E(γ): From ⁹⁶Zr(¹³C,3nγ) I(γ): From ⁹⁶Zr(¹³C,3nγ)
5404.0	1315.3	E(γ): From ⁹⁶Zr(¹³C,3nγ) I(γ): From ⁹⁶Zr(¹³C,3nγ)
5895.0	1001.2	E(γ): From ⁹⁶Zr(¹³C,3nγ) I(γ): From ⁹⁶Zr(¹³C,3nγ)