Isotopes of zinc

Naturally occurring zinc (₃₀Zn) is composed of the 5 stable isotopes ⁶⁴Zn, ⁶⁶Zn, ⁶⁷Zn, ⁶⁸Zn, and ⁷⁰Zn with ⁶⁴Zn being the most abundant (48.6% natural abundance). Twenty-eight radioisotopes have been characterised with the most stable being ⁶⁵Zn with a half-life of 243.94 days, and then ⁷²Zn with a half-life of 46.5 hours. All of the remaining radioactive isotopes have half-lives that are less than 14 hours and the majority of these have half-lives that are less than a second. This element also has 10 meta states.

Quick facts Main isotopes, Decay ...

Isotopes of zinc (₃₀Zn)

Main isotopes^[1]			Decay
Isotope	abundance	half-life (t_1/2)	mode	product
⁶⁴Zn	49.2%	stable
⁶⁵Zn	synth	243.94 d	β⁺	⁶⁵Cu
⁶⁶Zn	27.7%	stable
⁶⁷Zn	4.04%	stable
⁶⁸Zn	18.4%	stable
⁶⁹Zn	synth	56.4 min	β⁻	⁶⁹Ga
^69mZn	synth	13.75 h	IT	⁶⁹Zn
^69mZn	synth	13.75 h	β⁻	⁶⁹Ga
⁷⁰Zn	0.610%	stable
^71mZn	synth	4.15 h	β⁻	⁷¹Ga
⁷²Zn	synth	46.5 h	β⁻	⁷²Ga

Standard atomic weight A_r°(Zn)

65.38±0.02^[2]
65.38±0.02 (abridged)^[3]

Zinc has been proposed as a "salting" material for nuclear weapons. A jacket of isotopically enriched ⁶⁴Zn, irradiated by the intense high-energy neutron flux from an exploding thermonuclear weapon, would be transmuted to ⁶⁵Zn, which emits 1.115 MeV of gamma radiation in about half of decays,^[4] and would significantly increase the radioactivity of the weapon's fallout for several years. Such a weapon is not known to have ever been built, tested, or used.^[5]

List of isotopes

More information Nuclide, Z ...

Nuclide ^{[n 1]}	Z	N	Isotopic mass (Da)^[6] ^{[n 2]}^{[n 3]}	Discovery year^[7]^[8]	Half-life^[1] ^{[n 4]}	Decay mode^[1] ^{[n 5]}	Daughter isotope ^{[n 6]}	Spin and parity^[1] ^{[n 7]}^{[n 4]}	Natural abundance (mole fraction)
Nuclide ^{[n 1]}	Excitation energy			Discovery year^[7]^[8]	Half-life^[1] ^{[n 4]}	Decay mode^[1] ^{[n 5]}	Daughter isotope ^{[n 6]}	Spin and parity^[1] ^{[n 7]}^{[n 4]}	Normal proportion^[1]	Range of variation
⁵⁴Zn	30	24	53.99388(23)#	2005	1.8(5) ms	2p	⁵²Ni	0+
⁵⁵Zn	30	25	54.98468(43)#	2001	19.8(13) ms	β⁺, p (91.0%)	⁵⁴Ni	5/2−#
⁵⁵Zn	30	25	54.98468(43)#	2001	19.8(13) ms	β⁺ (9.0%)	⁵⁵Cu	5/2−#
⁵⁶Zn	30	26	55.97274(43)#	2001	32.4(7) ms	β⁺, p (88.0%)	⁵⁵Ni	0+
⁵⁶Zn	30	26	55.97274(43)#	2001	32.4(7) ms	β⁺ (12.0%)	⁵⁶Cu	0+
⁵⁷Zn	30	27	56.96506(22)#	1976	45.7(6) ms	β⁺, p (87%)	⁵⁶Ni	7/2−#
⁵⁷Zn	30	27	56.96506(22)#	1976	45.7(6) ms	β⁺ (13%)	⁵⁷Cu	7/2−#
⁵⁸Zn	30	28	57.954590(54)	1986	86.0(19) ms	β⁺ (99.3%)	⁵⁸Cu	0+
⁵⁸Zn	30	28	57.954590(54)	1986	86.0(19) ms	β⁺, p (0.7%)	⁵⁷Ni	0+
⁵⁹Zn	30	29	58.94931189(81)	1981	178.7(13) ms	β⁺ (99.90%)	⁵⁹Cu	3/2−
⁵⁹Zn	30	29	58.94931189(81)	1981	178.7(13) ms	β⁺, p (0.10%)	⁵⁸Ni	3/2−
⁶⁰Zn	30	30	59.94184132(59)	1955	2.38(5) min	β⁺	⁶⁰Cu	0+
⁶¹Zn	30	31	60.939507(17)	1955	89.1(2) s	β⁺	⁶¹Cu	3/2−
⁶²Zn	30	32	61.93433336(66)	1948	9.193(15) h	β⁺	⁶²Cu	0+
⁶³Zn	30	33	62.9332111(17)	1937	38.47(5) min	β⁺	⁶³Cu	3/2−
⁶⁴Zn	30	34	63.92914178(69)	1922	Observationally Stable^{[n 8]}			0+	0.4917(75)
⁶⁵Zn	30	35	64.92924053(69)	1939	243.94(4) d	EC (98.579(7)%)	⁶⁵Cu	5/2−
⁶⁵Zn	30	35	64.92924053(69)	1939	243.94(4) d	β⁺ (1.421(7)%)^[4]	⁶⁵Cu	5/2−
^65mZn	53.928(10) keV			1960	1.6(6) μs	IT	⁶⁵Zn	1/2−
⁶⁶Zn	30	36	65.92603364(80)	1922	Stable			0+	0.2773(98)
⁶⁷Zn	30	37	66.92712742(81)	1928	Stable			5/2−	0.0404(16)
^67m1Zn	93.312(5) keV			1953	9.15(7) μs	IT	⁶⁷Zn	1/2−
^67m2Zn	604.48(5) keV			1971	333(14) ns	IT	⁶⁷Zn	9/2+
⁶⁸Zn	30	38	67.92484423(84)	1922	Stable			0+	0.1845(63)
⁶⁹Zn	30	39	68.92655036(85)	1937	56.4(9) min	β⁻	⁶⁹Ga	1/2−
^69mZn	438.636(18) keV			1939	13.747(11) h	IT (99.97%)	⁶⁹Zn	9/2+
^69mZn	438.636(18) keV			1939	13.747(11) h	β⁻ (0.033%)	⁶⁹Ga	9/2+
⁷⁰Zn	30	40	69.9253192(21)	1922	Observationally Stable^{[n 9]}			0+	0.0061(10)
⁷¹Zn	30	41	70.9277196(28)	1955	2.40(5) min	β⁻	⁷¹Ga	1/2−
^71mZn	157.7(13) keV			1955	4.148(12) h	β⁻	⁷¹Ga	9/2+
^71mZn	157.7(13) keV			1955	4.148(12) h	IT?	⁷¹Zn	9/2+
⁷²Zn	30	42	71.9268428(23)	1951	46.5(1) h	β⁻	⁷²Ga	0+
⁷³Zn	30	43	72.9295826(20)	1972	24.5(2) s	β⁻	⁷³Ga	1/2−
^73mZn	195.5(2) keV			1998	13.0(2) ms	IT	⁷³Zn	5/2+
⁷⁴Zn	30	44	73.9294073(27)	1972	95.6(12) s	β⁻	⁷⁴Ga	0+
⁷⁵Zn	30	45	74.9328402(21)	1974	10.2(2) s	β⁻	⁷⁵Ga	7/2+
^75mZn	126.94(9) keV			2011	5# s	β⁻?	⁷⁵Ga	1/2−
^75mZn	126.94(9) keV			2011	5# s	IT?	⁷⁵Zn	1/2−
⁷⁶Zn	30	46	75.9331150(16)	1974	5.7(3) s	β⁻	⁷⁶Ga	0+
⁷⁷Zn	30	47	76.9368872(21)	1977	2.08(5) s	β⁻	⁷⁷Ga	7/2+
^77mZn	772.440(15) keV			1986	1.05(10) s	β⁻ (66%)	⁷⁷Ga	1/2−
^77mZn	772.440(15) keV			1986	1.05(10) s	IT (34%)	⁷⁷Zn	1/2−
⁷⁸Zn	30	48	77.9382892(21)	1977	1.47(15) s	β⁻	⁷⁸Ga	0+
⁷⁸Zn	30	48	77.9382892(21)	1977	1.47(15) s	β⁻, n?	⁷⁷Ga	0+
^78mZn	2673.7(6) keV			2000	320(6) ns	IT	⁷⁸Zn	(8+)
⁷⁹Zn	30	49	78.9426381(24)	1986	746(42) ms	β⁻ (98.3%)	⁷⁹Ga	9/2+
⁷⁹Zn	30	49	78.9426381(24)	1986	746(42) ms	β⁻, n (1.7%)	⁷⁸Ga	9/2+
^79mZn	942(10) keV^[9]			2015	>200 ms	β⁻?	⁷⁹Ga	1/2+
^79mZn	942(10) keV^[9]			2015	>200 ms	IT?	⁷⁹Zn	1/2+
⁸⁰Zn	30	50	79.9445529(28)	1986	562.2(30) ms	β⁻ (98.64%)	⁸⁰Ga	0+
⁸⁰Zn	30	50	79.9445529(28)	1986	562.2(30) ms	β⁻, n (1.36%)	⁷⁹Ga	0+
⁸¹Zn	30	51	80.9504026(54)	1991	299.4(21) ms	β⁻ (77%)	⁸¹Ga	(1/2+, 5/2+)
						β⁻, n (23%)	⁸⁰Ga
						β⁻, 2n?	⁷⁹Ga
⁸²Zn	30	52	81.9545741(33)	1997	177.9(25) ms	β⁻, n (69%)	⁸¹Ga	0+
						β⁻ (31%)	⁸²Ga
						β⁻, 2n?	⁸⁰Ga
⁸³Zn	30	53	82.96104(32)#	1997	100(3) ms	β⁻, n (71%)	⁸²Ga	3/2+#
						β⁻ (29%)	⁸³Ga
						β⁻, 2n?	⁸¹Ga
⁸⁴Zn	30	54	83.96583(43)#	2010	54(8) ms	β⁻, n (73%)	⁸³Ga	0+
						β⁻ (27%)	⁸⁴Ga
						β⁻, 2n?	⁸²Ga
⁸⁵Zn	30	55	84.97305(54)#	2010	40# ms [>400 ns]	β⁻?	⁸⁵Ga	5/2+#
						β⁻, n?	⁸⁴Ga
						β⁻, 2n?	⁸³Ga
⁸⁶Zn^[10]	30	56	85.97846(54)#	2024		β⁻?	⁸⁶Ga	0+
⁸⁶Zn^[10]	30	56	85.97846(54)#	2024		β⁻, n?	⁸⁵Ga	0+
⁸⁷Zn^[10]	30	57		2024
This table header & footer: view

[1]
^mZn – Excited nuclear isomer.
[2]
( ) – Uncertainty (1σ) is given in concise form in parentheses after the corresponding last digits.
[3]
# – Atomic mass marked #: value and uncertainty derived not from purely experimental data, but at least partly from trends from the Mass Surface (TMS).
[4]
# – Values marked # are not purely derived from experimental data, but at least partly from trends of neighboring nuclides (TNN).
[5]
Modes of decay:

IT: Isomeric transition

n: Neutron emission

p: Proton emission
[6]
Bold symbol as daughter – Daughter product is stable.
[7]
( ) spin value – Indicates spin with weak assignment arguments.
[8]
Believed to undergo β⁺β⁺ decay to ⁶⁴Ni with a half-life over 6.0×10¹⁶ y
[9]
Believed to undergo β⁻β⁻ decay to ⁷⁰Ge with a half-life over 3.8×10¹⁸ y

References

[1]
Kondev, F. G.; Wang, M.; Huang, W. J.; Naimi, S.; Audi, G. (2021). "The NUBASE2020 evaluation of nuclear properties" (PDF). Chinese Physics C. 45 (3) 030001. doi:10.1088/1674-1137/abddae.
[2]
"Standard Atomic Weights: Zinc". CIAAW. 2007.
[3]
Prohaska, Thomas; Irrgeher, Johanna; Benefield, Jacqueline; Böhlke, John K.; Chesson, Lesley A.; Coplen, Tyler B.; Ding, Tiping; Dunn, Philip J. H.; Gröning, Manfred; Holden, Norman E.; Meijer, Harro A. J. (2022-05-04). "Standard atomic weights of the elements 2021 (IUPAC Technical Report)". Pure and Applied Chemistry. doi:10.1515/pac-2019-0603. ISSN 1365-3075.
[4]
"⁶⁵Zn ε decay" (PDF). NNDC Chart of Nuclides.
[5]
D. T. Win, M. Al Masum (2003). "Weapons of Mass Destruction" (PDF). Assumption University Journal of Technology. 6 (4): 199–219. Archived from the original (PDF) on 2009-03-26. Retrieved 2015-09-24.
[6]
Wang, Meng; Huang, W.J.; Kondev, F.G.; Audi, G.; Naimi, S. (2021). "The AME 2020 atomic mass evaluation (II). Tables, graphs and references*". Chinese Physics C. 45 (3) 030003. doi:10.1088/1674-1137/abddaf.
[7]
FRIB Nuclear Data Group. "Discovery of Nuclides Project, Isotope Database". doi:10.11578/frib/2279152.
[8]
FRIB Nuclear Data Group. "Discovery of Nuclides Project, Isomer Database". doi:10.11578/frib/2572219.
[9]
Nies, L.; Canete, L.; Dao, D. D.; Giraud, S.; Kankainen, A.; Lunney, D.; Nowacki, F.; Bastin, B.; Stryjczyk, M.; Ascher, P.; Blaum, K.; Cakirli, R. B.; Eronen, T.; Fischer, P.; Flayol, M.; Girard Alcindor, V.; Herlert, A.; Jokinen, A.; Khanam, A.; Köster, U.; Lange, D.; Moore, I. D.; Müller, M.; Mougeot, M.; Nesterenko, D. A.; Penttilä, H.; Petrone, C.; Pohjalainen, I.; de Roubin, A.; Rubchenya, V.; Schweiger, Ch.; Schweikhard, L.; Vilen, M.; Äystö, J. (30 November 2023). "Further Evidence for Shape Coexistence in Zn 79 m near Doubly Magic Ni 78". Physical Review Letters. 131 (22) 222503. arXiv:2310.16915. doi:10.1103/PhysRevLett.131.222503. PMID 38101393.
[10]
Shimizu, Y.; Kubo, T.; Sumikama, T.; Fukuda, N.; Takeda, H.; Suzuki, H.; Ahn, D. S.; Inabe, N.; Kusaka, K.; Ohtake, M.; Yanagisawa, Y.; Yoshida, K.; Ichikawa, Y.; Isobe, T.; Otsu, H.; Sato, H.; Sonoda, T.; Murai, D.; Iwasa, N.; Imai, N.; Hirayama, Y.; Jeong, S. C.; Kimura, S.; Miyatake, H.; Mukai, M.; Kim, D. G.; Kim, E.; Yagi, A. (8 April 2024). "Production of new neutron-rich isotopes near the N = 60 isotones Ge 92 and As 93 by in-flight fission of a 345 MeV/nucleon U 238 beam". Physical Review C. 109 (4) 044313. doi:10.1103/PhysRevC.109.044313.

List of isotopes

See also

References

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