IN view of the fact that copper has only two stable isotopes and, it is difficult to account for the large number of different half-life periods reported for radioactive copper isotopes. Copper has two isotopes: Cu-63 (abundance = 69.2%, mass = 62.930 amu) and Cu-65 (abundance = 30.8%, mass = 64.928 amu). Calculate the (average) atomic mass of copper. Three magnesium isotopes have atomic masses and relative abundances of 23.985 amu (78.99%), 24.986 amu (10.00%), and 25.982 (11.01%). The recent use of copper isotopes as biomarkers for neoplasia in both human and veterinary medicine is a promising and cost-effective diagnostic tool. Two hundred and twenty-nine serum samples from 10 different species of wild felids under human care were processed through mass spectrometry to determine the ratio of heavy and light copper isotopes ( 65 Cu/ 63 Cu).

Isotopes of the Element Copper

Copper isotope measurements indicates that sample purification through chromatography is unnecessary for reliable analysis of Cu-Fe and Cu sulfide minerals. Copper isotope ratios measured from high-temperature (250°C) mineralization from several hydrothermal.

Copper Isotopes Prices

[Click for Main Data]

Most of the isotope data on this site has been obtained from the National Nuclear Data Center. Please visit their site for more information.

Isotopes With A Known Natural Abundance

Mass Number	Natural Abundance	Half-life
63	69.15%	STABLE
65	30.85%	STABLE

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Copper Isotopes Mass Spectrometry

Mass Number	Half-life	Decay Mode	Branching Percentage
52	No Data Available	Proton Emission	No Data Available
53	< 300 nanoseconds	Electron Capture	No Data Available
Proton Emission	No Data Available
54	< 75 nanoseconds	Proton Emission	No Data Available
55	27 milliseconds	Electron Capture	100.00%
Electron Capture with delayed Proton Emission	15.0%
56	93 milliseconds	Electron Capture	100.00%
Electron Capture with delayed Proton Emission	0.40%
57	196.3 milliseconds	Electron Capture	100.00%
58	3.204 seconds	Electron Capture	100.00%
59	81.5 seconds	Electron Capture	100.00%
60	23.7 minutes	Electron Capture	100.00%
61	3.333 hours	Electron Capture	100.00%
62	9.673 minutes	Electron Capture	100.00%
63	STABLE	-	-
64	12.701 hours	Electron Capture	61.50%
Beta-minus Decay	38.50%
65	STABLE	-	-
66	5.120 minutes	Beta-minus Decay	100.00%
67	61.83 hours	Beta-minus Decay	100.00%
68	30.9 seconds	Beta-minus Decay	100.00%
68m	3.75 minutes	Isomeric Transition	84.00%
Beta-minus Decay	16.00%
69	2.85 minutes	Beta-minus Decay	100.00%
70	44.5 seconds	Beta-minus Decay	100.00%
70m	33 seconds	Beta-minus Decay	52.00%
Isomeric Transition	48.00%
70m1	6.6 seconds	Beta-minus Decay	93.20%
Isomeric Transition	6.80%
71	19.4 seconds	Beta-minus Decay	100.00%
72	6.63 seconds	Beta-minus Decay	100.00%
73	4.2 seconds	Beta-minus Decay	100.00%
74	1.594 seconds	Beta-minus Decay	100.00%
75	1.222 seconds	Beta-minus Decay	100.00%
Beta-minus Decay with delayed Neutron Emission	3.50%
76	637 milliseconds	Beta-minus Decay with delayed Neutron Emission	7.20%
Beta-minus Decay	100.00%
76m	1.27 seconds	Beta-minus Decay	100.00%
77	468.1 milliseconds	Beta-minus Decay	100.00%
Beta-minus Decay with delayed Neutron Emission	30.30%
78	335 milliseconds	Beta-minus Decay	100.00%
Beta-minus Decay with delayed Neutron Emission	> 65.00%
79	188 milliseconds	Beta-minus Decay	100.00%
Beta-minus Decay with delayed Neutron Emission	55.00%
80	0.17 seconds	Beta-minus Decay	No Data Available
81	> 632 nanoseconds	Beta-minus Decay with delayed Neutron Emission	No Data Available
Beta-minus Decay	No Data Available
Beta-minus Decay with delayed Double Neutron Emission	No Data Available
82	> 636 nanoseconds	Beta-minus Decay	No Data Available
Beta-minus Decay with delayed Neutron Emission	No Data Available
Beta-minus Decay with delayed Double Neutron Emission	No Data Available

Naturally Occurring Copper Isotopes

For questions about this page, please contact Steve Gagnon.