JYFLTRAP: Published neutron-deficient masses
Last update:			2009-06-28 10:15
GROUND STATES
				AME2003		JYFLTRAP
N	Z	A	Nuclide	ME(keV)		r = fref/fmeas		Ref. nuclide	ME(keV)		Reference	Notes
13	13	26	26Al	-12210.31	0.06	1.0001654660	6.40E-09	26Mg	-12209.95	0.16	T. Eronen et al., PRL 97, 232501 (2006).	Data from direct freq. ratio measurement only
12	14	26	26Si	-7145	3	1.0001999808	4.60E-09	26Alm	-7140.9	0.17	T. Eronen et al., Phys. Rev. C 79, 032802R (2009).	Data from direct freq. ratio measurement only
21	21	42	42Sc	-32121.24	0.27				-32120.93	0.32	T. Eronen et al., PRL 97, 232501 (2006).	Derived from QEC = 6426.13(21) keV
23	23	46	46V	-37073.0	1.0	1.000164767	7.10E-09	46Ti	-37070.68	0.86	T. Eronen et al., PRL 97, 232501 (2006).	Derived from QEC = 7052.72(31) keV
25	25	50	50Mn	-42626.8	1.0				-42625.02	1.0	T. Eronen et al., PRL 100, 132502 (2008)	Derived from QEC = 7634.48(7) keV
27	27	54	54Co	-48009.5	0.7				-48007.96	0.7	T. Eronen et al., PRL 100, 132502 (2008)	Derived from QEC = 8244.54(10) keV
33	29	62	62Cu	-62798	4	1.000068629	8.20E-09	62Ni	-62787.2	0.9	T. Eronen et al., Phys. Lett. B 636, 191 (2006).
32	30	62	62Zn	-61171	10	1.000096701	9.40E-09	62Ni	-61167.9	0.9	T. Eronen et al., Phys. Lett. B 636, 191 (2006).
31	31	62	62Ga	-52000	28				-51986.5	1.0	T. Eronen et al., Phys. Lett. B 636, 191 (2006).	QEC = 9181.07(54) keV; mass excess from Ga-Ni freq. ratio
41	39	80	80Y	-61220	180	1.00025645	7.00E-08	96Mo	-61144	7	A. Kankainen et al., EPJA 29, 271 (2006).	Measured as 80YO
42	39	81	81Y	-66020	60	1.00018938	6.00E-08	97Mo	-65709	6	A. Kankainen et al., EPJA 29, 271 (2006).	Measured as 81YO
43	39	82	82Y	-68190	100	1.00016793	6.00E-08	98Mo	-68060	6	A. Kankainen et al., EPJA 29, 271 (2006).	Measured as 82YO
44	39	83	83Y	-72330	40	1.01033685	6.00E-08	98Mo	-72170	6	A. Kankainen et al., EPJA 29, 271 (2006).	Measured as 83YO. Possible contribution from 83Ym at 61.98(11) keV.
43	40	83	83Zr	-66460	100	1.01040553	7.00E-08	98Mo	-65908	7	A. Kankainen et al., EPJA 29, 271 (2006).	Measured as 83ZrO
45	39	84	84Y	-74160	90	1.031056762	5.30E-08	97Mo	-73922	19	C. Weber et al., Phys. Rev. C  78, 054310  (2008)	Measured as YO+. The original value of −73888.8(5.2) keV was modified for an unknown mixture of isomeric states.
44	40	84	84Zr	-71490#	200#	1.02055911	6.00E-08	98Mo	-71418	6	A. Kankainen et al., EPJA 29, 271 (2006).	Measured as 84ZrO
45	40	85	85Zr	-73150	100	1.03075388	7.00E-08	98Mo	-73170	6	A. Kankainen et al., EPJA 29, 271 (2006).	Measured as 85ZrO
44	41	85	85Nb	-67150	220	1.03082952	7.00E-08	98Mo	-66273	7	A. Kankainen et al., EPJA 29, 271 (2006).	Measured as 85NbO. Possible contribution from 85Nbm at > 69 keV.
46	40	86	86Zr	-77800	30	1.04091538	7.00E-08	98Mo	-77958	7	A. Kankainen et al., EPJA 29, 271 (2006).	Measured as 86ZrO
45	41	86	86Nb	-69830	90	1.04101219	6.00E-08	98Mo	-69129	6	A. Kankainen et al., EPJA 29, 271 (2006).	Measured as 86NbO
47	40	87	87Zr	-79348	8	1.061954361	5.40E-08	97Mo	-79341.4	5.3	C. Weber et al., Phys. Rev. C  78, 054310  (2008)	Measured as ZrO+.
46	41	87	87Nb	-74180	60	1.05117423	7.00E-08	98Mo	-73868	7	A. Kankainen et al., EPJA 29, 271 (2006).	Measured as 87NbO. Possible contribution from 87Nbm at 3.84(14) keV
48	40	88	88Zr	-83623	10	1.06128125	7.00E-08	98Mo	-83624	7	A. Kankainen et al., EPJA 29, 271 (2006).	Measured as 88ZrO
47	41	88	88Nb	-76070	100	1.06136322	7.00E-08	98Mo	-76149	7	A. Kankainen et al., EPJA 29, 271 (2006).	Measured as 88NbO. Possible contribution from 88Nbm at 40(140) keV.
46	42	88	88Mo	-72700	20	1.035450878	4.80E-08	85Rb	-72686.5	3.8	C. Weber et al., Phys. Rev. C  78, 054310  (2008)
45	43	88	88Tc	-62710	200#	1.035590047	4.80E-08	85Rb	-61679	87	C. Weber et al., Phys. Rev. C  78, 054310  (2008)	The original error of 3.8 keV was increased due to the unknown level scheme of isomeric states.
47	42	89	89Mo	-75004	15	1.047198443	4.90E-08	85Rb	-75015	3.9	C. Weber et al., Phys. Rev. C  78, 054310  (2008)
46	43	89	89Tc	-67840	200#	1.047294786	4.70E-08	85Rb	-67394.8	3.7	C. Weber et al., Phys. Rev. C  78, 054310  (2008)	Weighted average of SHIPTRAP & JYFLTRAP result.
47	43	90	90Tc	-71210	240	1.059029702	4.30E-08	85Rb	-70723.7	3.4	C. Weber et al., Phys. Rev. C  78, 054310  (2008)	Weighted average of SHIPTRAP & JYFLTRAP result.
46	44	90	90Ru	-65310	300#	1.059103543	5.00E-08	85Rb	-64883.3	4.0	C. Weber et al., Phys. Rev. C  78, 054310  (2008)	Weighted average of SHIPTRAP & JYFLTRAP result.
48	43	91	91Tc	-75980	200			85Rb / 94Mo	-75984.8	3.3	C. Weber et al., Phys. Rev. C  78, 054310  (2008)	Weighted average of SHIPTRAP & JYFLTRAP result.
47	44	91	91Ru	-68660	580#			85Rb / 94Mo	-68237.1	2.9	C. Weber et al., Phys. Rev. C  78, 054310  (2008)	Weighted average of SHIPTRAP & JYFLTRAP result.
49	43	92	92Tc	-78935	26	1.082480023	4.70E-08	85Rb	-78924.7	3.7	C. Weber et al., Phys. Rev. C  78, 054310  (2008)	Weighted average of SHIPTRAP & JYFLTRAP result.
48	44	92	92Ru	-74410	300#	1.082538507	4.10E-08	85Rb	-74299	3.2	C. Weber et al., Phys. Rev. C  78, 054310  (2008)	Weighted average of SHIPTRAP & JYFLTRAP result.
47	45	92	92Rh	-63360	400#	1.082681379	5.50E-08	85Rb	-62999	15	C. Weber et al., Phys. Rev. C  78, 054310  (2008)	Weighted average of SHIPTRAP & JYFLTRAP result. The original error of 4.3 keV was increased due to the unknown level scheme of isomeric states.
49	44	93	93Ru	-77270	90	1.094278655	5.10E-08	85Rb	-77214	4.0	C. Weber et al., Phys. Rev. C  78, 054310  (2008)
48	45	93	93Rh	-69170	400#	1.094382362	5.00E-08	85Rb	-69011.3	3.9	C. Weber et al., Phys. Rev. C  78, 054310  (2008)	Weighted average of SHIPTRAP & JYFLTRAP result
50	44	94	94Ru	-82568	13	1.105987808	5.20E-08	85Rb	-82580.6	4.1	C. Weber et al., Phys. Rev. C  78, 054310  (2008)	Weighted average of SHIPTRAP & JYFLTRAP result.
49	45	94	94Rh	-72940	450#	1.106110107	5.40E-08	85Rb	-72907.5	4.2	C. Weber et al., Phys. Rev. C  78, 054310  (2008)
48	46	94	94Pd	-66350	400#	1.000255075	4.90E-08	94Mo	-66097.9	4.7	C. Weber et al., Phys. Rev. C  78, 054310  (2008)
50	45	95	95Rh	-78340	150	1.117818397	5.30E-08	85Rb	-78342.3	4.2	C. Weber et al., Phys. Rev. C  78, 054310  (2008)
49	46	95	95Pd	-70150	400#	1.010860017	5.00E-08	94Mo	-69961.6	4.8	C. Weber et al., Phys. Rev. C  78, 054310  (2008)
54	42	96	96Mo	-88790.5	1.9	0.98966683	6.00E-08	97Mo	-88789	6	A. Kankainen et al., EPJA 29, 271 (2006).
50	46	96	96Pd	-76230	150	1.021438050	4.80E-08	94Mo	-76179	4.7	C. Weber et al., Phys. Rev. C  78, 054310  (2008)
51	46	97	97Pd	-77800	300	1.141379187	2.10E-08	85Rb	-77805.9	4.9	V.-V. Elomaa et al., Eur. Phys. J. A 40, 1 (2009)	Uncertainty of the Mass Excess has a residual 5e-8 included, uncertainty of the Freq. Ratio not.
56	42	98	98Mo	-88111.7	1.9	1.01031302	6.00E-08	97Mo	-88111	6	A. Kankainen et al., EPJA 29, 271 (2006).
52	46	98	98Pd	-81300	21	1.153111745	1.80E-08	85Rb	-81321.3	4.8	V.-V. Elomaa et al., Eur. Phys. J. A 40, 1 (2009)	Uncertainty of the Mass Excess has a residual 5e-8 included, uncertainty of the Freq. Ratio not.
53	46	99	99Pd	-82188	15	1.0313552482	8.30E-09	96Mo	-82178.9	5.1	V.-V. Elomaa et al., Eur. Phys. J. A 40, 1 (2009)	Uncertainty of the Mass Excess has a residual 5e-8 included, uncertainty of the Freq. Ratio not.
53	47	100	100Ag	-78150	80	1.176706087	1.80E-08	85Rb	-78131	4.9	V.-V. Elomaa et al., Eur. Phys. J. A 40, 1 (2009)	Modification with the treatment of unknown mixture of isomers gives -78139(7) keV. Uncertainty of the Mass Excess has a residual 5e-8 included, uncertainty of the Freq. Ratio not.
55	46	101	101Pd	-85428	18	1.0521730471	7.90E-09	96Mo	-85427.1	5.2	V.-V. Elomaa et al., Eur. Phys. J. A 40, 1 (2009)	Uncertainty of the Mass Excess has a residual 5e-8 included, uncertainty of the Freq. Ratio not.
53	48	101	101Cd	-75750	150	1.052280501	2.30E-08	96Mo	-75827.8	5.6	V.-V. Elomaa et al., Eur. Phys. J. A 40, 1 (2009)	Uncertainty of the Mass Excess has a residual 5e-8 included, uncertainty of the Freq. Ratio not.
54	48	102	102Cd	-79678	29	1.0626647323	9.40E-09	96Mo	-79655.6	5.3	V.-V. Elomaa et al., Eur. Phys. J. A 40, 1 (2009)	Uncertainty of the Mass Excess has a residual 5e-8 included, uncertainty of the Freq. Ratio not.
53	49	102	102In	-70710	110	1.062765089	1.50E-08	96Mo	-70690.4	5.4	V.-V. Elomaa et al., Eur. Phys. J. A 40, 1 (2009)	Uncertainty of the Mass Excess has a residual 5e-8 included, uncertainty of the Freq. Ratio not.
55	48	103	103Cd	-80649	15	1.0730806977	9.00E-09	96Mo	-80648.5	5.3	V.-V. Elomaa et al., Eur. Phys. J. A 40, 1 (2009)	Uncertainty of the Mass Excess has a residual 5e-8 included, uncertainty of the Freq. Ratio not.
56	48	104	104Cd	-83975	9	1.083470676	1.90E-08	96Mo	-83962.9	5.6	V.-V. Elomaa et al., Eur. Phys. J. A 40, 1 (2009)	Uncertainty of the Mass Excess has a residual 5e-8 included, uncertainty of the Freq. Ratio not.
55	49	104	104In	-76110	80	1.223838813	2.00E-08	85Rb	-76176.5	5.1	V.-V. Elomaa et al., Eur. Phys. J. A 40, 1 (2009)	Modification with the treatment of unknown mixture of isomers gives -76223(28) keV. Uncertainty of the Mass Excess has a residual 5e-8 included, uncertainty of the Freq. Ratio not.
54	50	104	104Sn	-71590	100	1.195 767 977	7.40E-08	87Rb	-71625	6	V.-V. Elomaa et al., PRL 102, 252501 (2009)
57	48	105	105Cd	-84330	12	1.093893644	1.10E-08	96Mo	-84330.1	5.5	V.-V. Elomaa et al., Eur. Phys. J. A 40, 1 (2009)	Uncertainty of the Mass Excess has a residual 5e-8 included, uncertainty of the Freq. Ratio not.
55	50	105	105Sn	-73260	80	1.207 253 180	6.40E-08	87Rb	-73336	5	V.-V. Elomaa et al., PRL 102, 252501 (2009)
56	50	106	106Sn	-77430	50	1.218 709 913	8.70E-08	87Rb	-77351	7	V.-V. Elomaa et al., PRL 102, 252501 (2009)
55	51	106	106Sb	-66330	310	1.218 844 285	9.20E-08	87Rb	-66473	7	V.-V. Elomaa et al., PRL 102, 252501 (2009)
57	50	107	107Sn	-78580	80	1.230 201 911	6.50E-08	87Rb	-78512	5	V.-V. Elomaa et al., PRL 102, 252501 (2009)
56	51	107	107Sb	-70650	300	1.230 299 077	6.70E-08	87Rb	-70646	5	V.-V. Elomaa et al., PRL 102, 252501 (2009)
58	50	108	108Sn	-82041	20	1.241 664 284	6.80E-08	87Rb	-82071	6	V.-V. Elomaa et al., PRL 102, 252501 (2009)
57	51	108	108Sb	-72510	210	1.241 783 189	6.80E-08	87Rb	-72445	6	V.-V. Elomaa et al., PRL 102, 252501 (2009)
56	52	108	108Te	-65720	100	1.241 865 478	6.90E-08	87Rb	-65784	6	V.-V. Elomaa et al., PRL 102, 252501 (2009)
58	51	109	109Sb	-76259	19	1.253 242 516	6.80E-08	87Rb	-76251	5	V.-V. Elomaa et al., PRL 102, 252501 (2009)
57	52	109	109Te	-67610	60	1.253 347 956	7.30E-08	87Rb	-67715	6	V.-V. Elomaa et al., PRL 102, 252501 (2009)
59	51	110	110Sb	-77540	200	1.264 734 046	7.30E-08	87Rb	-77450	6	V.-V. Elomaa et al., PRL 102, 252501 (2009)
58	53	111	111I	-64950	300	1.276 394 688	7.00E-08	87Rb	-64958	6	V.-V. Elomaa et al., PRL 102, 252501 (2009)
MASSES OF m-ISOMERS
13	13	26	26Alm	-11982.01	0.06				-11981.75	0.16	T. Eronen et al., PRL 97, 232501 (2006).	Derived from QEC = 4232.83(13) keV
21	21	42	42Scm	-31504.96	0.28	1.000180196	5.40E-09	42Ca	-31504.34	0.33	T. Eronen et al., PRL 97, 232501 (2006).	Data from direct freq. ratio measurement only
25	25	50	50Mnm	-42398	7	1.000168941	1.30E-09	50Cr	-42399.69	1.0	T. Eronen et al., PRL 100, 132502 (2008)	Data from direct freq. ratio measurement only
27	27	54	54Com	-47812.1	0.9	1.000168022	1.70E-09	54Fe	-47810.41	0.7	T. Eronen et al., PRL 100, 132502 (2008)	Data from direct freq. ratio measurement only
49	46	95	95Pdm	-68290	300	1.010881456	4.80E-08	94Mo	-68086.2	4.7	C. Weber et al., Phys. Rev. C  78, 054310  (2008)