List of levels for 101PD

ADOPTED LEVELS, GAMMAS for ¹⁰¹Pd

Author: Jean Blachot | Citation: ENSDF | Cutoff date: 1-Jul-2006

Full ENSDF file | Adopted Levels (PDF version)

Q(β-)=-4096 keV 7	S(n)= 8275 keV 19	S(p)= 7131 keV 19	Q(α)= -1736 keV 6
Reference: 2012WA38

References:
A	¹⁰¹Ag ε decay (11.1 M)	B	⁹²Zr(¹²C,3nγ)
C	¹⁰²Pd(³He,αγ)	D	¹⁰²Pd(d,t)

1976Sm06 analyzed (HI,xnγ) results on levels in ¹⁰¹Pd,¹⁰³Pd,¹⁰⁵Pd using the Nilsson model with Coriolis coupling at deformation≈0.12.

Q-value: Note: Current evaluation has used the following Q record -4200 1082730 217133 25-1741 20 2003Au03

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+	8.47 h 6 % ε = 100
80.3 1	A C	(3/2)+	4.8 ns 5	80.26 12	100	M1+E2	0.0	5/2+
261.0 1	A B C D	7/2+		180.5 5 260.97 5	0.5 2 100 20	M1	80.3 0.0	(3/2)+ 5/2+
274.7 2	A C D	(7/2,9/2+)		274.68 15	100		0.0	5/2+
400 15	D	1/2+
588.0 2	A B C D	(7/2+)		326.91 15 507.6 4 588.00 15	18.9 16 20 5 100 5		261.0 80.3 0.0	7/2+ (3/2)+ 5/2+
600 15	D	3/2+,5/2+
623.6 2	A	(7/2+)		543.32 15 623.58 15	100 7 33.4 23		80.3 0.0	(3/2)+ 5/2+
667.3 2	A B C	9/2+		406.29 5 667.23 5	7.1 9 100 3	M1(+E2) E2	261.0 0.0	7/2+ 5/2+
730 15	D	1/2+
734.7 2	A	(7/2+)		459.9 3 654.4 2 734.7 2	11.3 16 48 3 100 8		274.7 80.3 0.0	(7/2,9/2+) (3/2)+ 5/2+
745 1	C			484 1	100		261.0	7/2+
938.9 2	A B C	11/2+		271.7 1 677.9 1	5 3 100 11	E2	667.3 261.0	9/2+ 7/2+
980 15	D	3/2+,5/2+
1081.7 5	A D	3/2+,5/2+		494.0 5 806.9 5	100 20 40 12		588.0 274.7	(7/2+) (7/2,9/2+)
1173.9 2	A	(7/2)+		439.2 2 506.6 3 550.2 2 585.9 4 899.4 2 912.9 2 1093.6 2 1173.9 2	31.9 11 6.5 12 4.4 5 12 3 5.4 6 6.5 6 29.4 12 100 3		734.7 667.3 623.6 588.0 274.7 261.0 80.3 0.0	(7/2+) 9/2+ (7/2+) (7/2+) (7/2,9/2+) 7/2+ (3/2)+ 5/2+
E(level) (keV)	XREF	J^π(level)	T_1/2(level)	E(γ) (keV)	I(γ)	M(γ)	Final Levels
1199.3 2	A			532.0 3 575.6 2 611.3 2 938.3 2	23 4 26 3 48 5 100 8		667.3 623.6 588.0 261.0	9/2+ (7/2+) (7/2+) 7/2+
1205.3 2	A	(7/2+)		470.6 3 537.9 2 581.3 5 617.6 3 930.5 3 944.3 2 1125.3 3 1205.3 2	12 2 53 3 8 2 6 2 12 2 44 4 16 3 100 4		734.7 667.3 623.6 588.0 274.7 261.0 80.3 0.0	(7/2+) 9/2+ (7/2+) (7/2+) (7/2,9/2+) 7/2+ (3/2)+ 5/2+
1250 15	D	3/2+,5/2+
1265.6 3	A B	(11/2+)		327 1 598.2 2 677.7 2	11 1 53 4 100 9	Q	938.9 667.3 588.0	11/2+ 9/2+ (7/2+)
1337.4 1	B C D	11/2-		398.56 7 670.17 5	6.0 22 100 9	E1	938.9 667.3	11/2+ 9/2+
1380 15	D	1/2+
1403.5 2	A B C	13/2+		138 1 464.5 2 736.3 2	2.1 2 9 3 100 10	(M1+E2) E2	1265.6 938.9 667.3	(11/2+) 11/2+ 9/2+
1534.5 2	A	(7/2+)		799.7 3 867.2 3 910.8 5 1454.0 3	67 6 63 14 14 6 100 18		734.7 667.3 623.6 80.3	(7/2+) 9/2+ (7/2+) (3/2)+
1560.5 3	A	(7/2+,9/2+,11/2+)		386.7 4 825.9 3 893.2 2 1299.5 2	21 3 22 4 100 9 83 7		1173.9 734.7 667.3 261.0	(7/2)+ (7/2+) 9/2+ 7/2+
E(level) (keV)	XREF	J^π(level)	T_1/2(level)	E(γ) (keV)	I(γ)	M(γ)	Final Levels
1614.6 6	A			1353.6 3	100		261.0	7/2+
1816.6 2	B	15/2+		877.67 5	100	E2	938.9	11/2+
1823.6 6	A			420.1 4	100		1403.5	13/2+
1892.9 2	B C	15/2-		490 1 555.54 5	6.4 7 100 10	E2	1403.5 1337.4	13/2+ 11/2-
1932.9 6	A			1671.9 4	100		261.0	7/2+
1981.7 9 ?	A			577.9 5	100		1403.5	13/2+
2041.6 3	A	(7/2+,9/2+,11/2+)		1306.7 5 1418.1 2 2041.8 2	100 14 57 11 84 6		734.7 623.6 0.0	(7/2+) (7/2+) 5/2+
2050 15	D	1/2-,3/2-
2063.0 5	B	(15/2+)		660.0 7 797.0 7	13.6 14 100 10	Q	1403.5 1265.6	13/2+ (11/2+)
2141 2	C D	(15/2+)
2207.5 2	B	17/2+		390.90 7 804.02 5	6 3 100 8	(M1+E2) E2	1816.6 1403.5	15/2+ 13/2+
2220.3 4	A D	(7/2+,9/2+)		1632.9 6 1959.0 3	100 33 52 17		588.0 261.0	(7/2+) 7/2+
2221 2	C	7/2+,9/2,11/2-		1554 1	100		667.3	9/2+
2245.4 8	B	(13/2)		908.0 7	100		1337.4	11/2-
2265.3 6	A	(7/2+,9/2+,11/2+)		1326.1 5 1641.8 3	100 15 24 5		938.9 623.6	11/2+ (7/2+)
2290 15	D	1/2-,3/2-
2291 1	B	(17/2)		887	100		1403.5	13/2+
2300.2 6	A B			1632.8 4	100 5		667.3	9/2+
2393.4 9	A C D	9/2+		988 2 1454 2 1726 2 1805 2 2131.8 4	8 4 26 8 9 5 16 8 100 20	D+Q	1403.5 938.9 667.3 588.0 261.0	13/2+ 11/2+ 9/2+ (7/2+) 7/2+
E(level) (keV)	XREF	J^π(level)	T_1/2(level)	E(γ) (keV)	I(γ)	M(γ)	Final Levels
2512.0 9	B	(15/2)		619.0 7			1892.9	15/2-
2641.1 3	B	19/2-		748.2 2	100 11	E2	1892.9	15/2-
2641.2 3	A	(7/2+,9/2+,11/2+)		2053.1 3	100		588.0	(7/2+)
2721.0 10	B	19/2+		904.4 10	100	E2	1816.6	15/2+
2802.8 5	A			1399.3 5	100		1403.5	13/2+
2864.6 2	B	21/2+		657.07 5	100	E2	2207.5	17/2+
2891.0 5	A			1487.5 4	100		1403.5	13/2+
2895.8 5	A	(7/2+,9/2+,11/2+)		2307.8 3 2635.1 5	100 17 47 7		588.0 261.0	(7/2+) 7/2+
2960.1 5	A	(7/2+,9/2+,11/2+)		2699.1 3	100		261.0	7/2+
2983 1	B	(17/2-)		1090	100		1892.9	15/2-
3034.6 7	B			170.0 7	100		2864.6	21/2+
3227.5 5	B	(21/2+)		363 1 1020 1			2864.6 2207.5	21/2+ 17/2+
3304.7 9	A	(7/2+,9/2+,11/2+)		1901.2 5	100		1403.5	13/2+
3327.1 8	B	(19/2-)		686 1	100		2641.1	19/2-
3404.3 8	A	(7/2+,9/2+,11/2+)		3143.3 8	100		261.0	7/2+
3532.2 3	B	23/2-		891.04 5	100	E2	2641.1	19/2-
3625.4 3	B	(23/2)+		904.4 10	100	E2	2721.0	19/2+
3812.0 3	B	25/2+		947.47 5	100	E2	2864.6	21/2+
4443.0 6	B	27/2-		910.78 10	100	(E2)	3532.2	23/2-
4896.4 5	B	(29/2+)		1084.4 2	100	(E2)	3812.0	25/2+
5414.5 6	B	(31/2-)		971.56 10	100		4443.0	27/2-
6488.2 10	B			1073.7 5	100		5414.5	(31/2-)

J^π(level): ΔJ of intraband and interband transitions are deduced from γ-ray linear pol and γ(θ) in (¹²C,3nγ) study

M(γ): From ¹⁰¹Ag ε decay and ⁹²Zr(¹²C,3nγ)

E(level) (keV)	J^π(level)	T_1/2(level)	E(γ)	I(γ)	M(γ)	Final Levels
Band 1 - ΔJ=2 SEQUENCE BUILT ON 11/2- STATE
1337.4 1	11/2-
1892.9 2	15/2-		490 1 555.54 5	6.4 7 100 10	E2	1403.5 1337.4	13/2+ 11/2-
2641.1 3	19/2-		748.2 2	100 11	E2	1892.9	15/2-
3532.2 3	23/2-		891.04 5	100	E2	2641.1	19/2-
4443.0 6	27/2-
5414.5 6	(31/2-)		971.56 10	100		4443.0	27/2-
E(level) (keV)	J^π(level)	T_1/2(level)	E(γ)	I(γ)	M(γ)	Final Levels
Band 2 - ΔJ=2 SEQUENCE BUILT ON 5/2⁺ GS
0.0	5/2+	8.47 h 6 % ε = 100
667.3 2	9/2+		406.29 5 667.23 5	7.1 9 100 3	M1(+E2) E2	261.0 0.0	7/2+ 5/2+
1403.5 2	13/2+		138 1 464.5 2 736.3 2	2.1 2 9 3 100 10	(M1+E2) E2	1265.6 938.9 667.3	(11/2+) 11/2+ 9/2+
2207.5 2	17/2+		390.90 7 804.02 5	6 3 100 8	(M1+E2) E2	1816.6 1403.5	15/2+ 13/2+
2864.6 2	21/2+
3812.0 3	25/2+		947.47 5	100	E2	2864.6	21/2+
4896.4 5	(29/2+)
E(level) (keV)	J^π(level)	T_1/2(level)	E(γ)	I(γ)	M(γ)	Final Levels
Band 3 - ΔJ=2 SEQUENCE BUILT ON 7/2⁺ STATE
261.0 1	7/2+
938.9 2	11/2+		271.7 1 677.9 1	5 3 100 11	E2	667.3 261.0	9/2+ 7/2+
1816.6 2	15/2+		877.67 5	100	E2	938.9	11/2+
2721.0 10	19/2+		904.4 10	100	E2	1816.6	15/2+
3625.4 3	(23/2)+

E(level) (keV)	J^π(level)	T_1/2(level)	E(γ) (keV)	Multipolarity	Mixing Ratio	Conversion Coefficient	Additional Data
80.3	(3/2)+	4.8 ns 5	80.26 12	M1+E2	+0.41 +11-12		B(E2)(W.u.)=9.×10¹ 5, B(M1)(W.u.)=0.0037 6
261.0	7/2+		260.97 5	M1		0.028	α=0.028
667.3	9/2+		406.29 5	M1(+E2)	+0.05 5
1403.5	13/2+		464.5 2	(M1+E2)	+0.18 12
2207.5	17/2+		390.90 7	(M1+E2)	-0.02 4
2393.4	9/2+		2131.8 4	D+Q	+0.34 +3-5

E(level)	J^π(level)	T_1/2(level)	Comments
0.0	5/2+	8.47 h 6 % ε = 100	μ=-0.66 2 (2005St24) E(level): ΔJ=2 SEQUENCE BUILT ON 5/2⁺ GS.
261.0	7/2+		E(level): ΔJ=2 SEQUENCE BUILT ON 7/2⁺ STATE.
667.3	9/2+		E(level): ΔJ=2 SEQUENCE BUILT ON 5/2⁺ GS.
938.9	11/2+		E(level): ΔJ=2 SEQUENCE BUILT ON 7/2⁺ STATE.
1081.7	3/2+,5/2+		XREF: d(1060).
1337.4	11/2-		XREF: d(1310). E(level): ΔJ=2 SEQUENCE BUILT ON 11/2- STATE.
1403.5	13/2+		E(level): ΔJ=2 SEQUENCE BUILT ON 5/2⁺ GS.
1816.6	15/2+		E(level): ΔJ=2 SEQUENCE BUILT ON 7/2⁺ STATE.
1892.9	15/2-		E(level): ΔJ=2 SEQUENCE BUILT ON 11/2- STATE.
2207.5	17/2+		E(level): ΔJ=2 SEQUENCE BUILT ON 5/2⁺ GS.
2220.3	(7/2+,9/2+)		XREF: d(2180).
2393.4	9/2+		XREF: d(2360).
2641.1	19/2-		E(level): ΔJ=2 SEQUENCE BUILT ON 11/2- STATE.
2721.0	19/2+		E(level): ΔJ=2 SEQUENCE BUILT ON 7/2⁺ STATE.
2864.6	21/2+		E(level): ΔJ=2 SEQUENCE BUILT ON 5/2⁺ GS.
3532.2	23/2-		E(level): ΔJ=2 SEQUENCE BUILT ON 11/2- STATE.
3625.4	(23/2)+		E(level): ΔJ=2 SEQUENCE BUILT ON 7/2⁺ STATE.
3812.0	25/2+		E(level): ΔJ=2 SEQUENCE BUILT ON 5/2⁺ GS.
4443.0	27/2-		E(level): ΔJ=2 SEQUENCE BUILT ON 11/2- STATE.
4896.4	(29/2+)		E(level): ΔJ=2 SEQUENCE BUILT ON 5/2⁺ GS.
5414.5	(31/2-)		E(level): ΔJ=2 SEQUENCE BUILT ON 11/2- STATE.

E(level)	E(gamma)	Comments
588.0	326.91	I(γ): from ε decay. Iγ=33 in (¹²C,3nγ). Also placed from 1266 in (¹²C,3nγ). If branching is correct, then Iγ(327γ from 588 in ε decay)=17.4 16
1265.6	327	I(γ): from Iγ/Iγ(598⁺678) in (¹²C,3nγ) and adopted Iγ(598⁺678γ’s)
2393.4	988	E(γ): the evaluator assumes that the 2396 in (³He,αγ) corresponds to the 2393 level in ε decay. So the 991,1457,1729,1808 are lowered by 3 keV to agree with the ε decay Eγ value for 2131.8