Zirconium-96

Isotopes of zirconium (₄₀Zr)
γ	–
β+	89Y
γ	–
Standard atomic weight Ar°(Zr)
	91.224±0.002; 91.224±0.002 (abridged);
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Isotopes of zirconium

Nuclides with atomic number of 40 but with different mass numbers

Naturally occurring zirconium (₄₀Zr) is composed of four stable isotopes (of which one may in the future be found radioactive), and one very long-lived radioisotope (⁹⁶Zr), a primordial nuclide that decays via double beta decay with an observed half-life of 2.0×10¹⁹ years;^[5] it can also undergo single beta decay, which is not yet observed, but the theoretically predicted value of t_1/2 is 2.4×10²⁰ years.^[6] The second most stable radioisotope is ⁹³Zr, which has a half-life of 1.53 million years. Thirty other radioisotopes have been observed. All have half-lives less than a day except for ⁹⁵Zr (64.02 days), ⁸⁸Zr (83.4 days), and ⁸⁹Zr (78.41 hours). The primary decay mode is electron capture for isotopes lighter than ⁹²Zr, and the primary mode for heavier isotopes is beta decay.

Quick Facts Main isotopes, Decay ...

List of isotopes

More information Nuclide, Z ...

Nuclide ^{[n 1]}	Z	N	Isotopic mass (Da) ^{[n 2]}^{[n 3]}	Half-life ^{[n 4]}^{[n 5]}	Decay mode	Daughter isotope ^{[n 6]}	Spin and parity ^{[n 7]}^{[n 5]}	Natural abundance (mole fraction)
Nuclide ^{[n 1]}	Excitation energy			Half-life ^{[n 4]}^{[n 5]}	Decay mode	Daughter isotope ^{[n 6]}	Spin and parity ^{[n 7]}^{[n 5]}	Normal proportion	Range of variation
⁷⁸Zr	40	38	77.95523(54)#	50# ms [>170 ns]			0+
⁷⁹Zr	40	39	78.94916(43)#	56(30) ms	β⁺, p	⁷⁸Sr	5/2+#
⁷⁹Zr	40	39	78.94916(43)#	56(30) ms	β⁺	⁷⁹Y	5/2+#
⁸⁰Zr	40	40	79.9404(16)	4.6(6) s	β⁺	⁸⁰Y	0+
⁸¹Zr	40	41	80.93721(18)	5.5(4) s	β⁺ (>99.9%)	⁸¹Y	(3/2−)#
⁸¹Zr	40	41	80.93721(18)	5.5(4) s	β⁺, p (<.1%)	⁸⁰Sr	(3/2−)#
⁸²Zr	40	42	81.93109(24)#	32(5) s	β⁺	⁸²Y	0+
⁸³Zr	40	43	82.92865(10)	41.6(24) s	β⁺ (>99.9%)	⁸³Y	(1/2−)#
⁸³Zr	40	43	82.92865(10)	41.6(24) s	β⁺, p (<.1%)	⁸²Sr	(1/2−)#
⁸⁴Zr	40	44	83.92325(21)#	25.9(7) min	β⁺	⁸⁴Y	0+
⁸⁵Zr	40	45	84.92147(11)	7.86(4) min	β⁺	⁸⁵Y	7/2+
^85mZr	292.2(3) keV			10.9(3) s	IT (92%)	⁸⁵Zr	(1/2−)
^85mZr	292.2(3) keV			10.9(3) s	β⁺ (8%)	⁸⁵Y	(1/2−)
⁸⁶Zr	40	46	85.91647(3)	16.5(1) h	β⁺	⁸⁶Y	0+
⁸⁷Zr	40	47	86.914816(9)	1.68(1) h	β⁺	⁸⁷Y	(9/2)+
^87mZr	335.84(19) keV			14.0(2) s	IT	⁸⁷Zr	(1/2)−
⁸⁸Zr^{[n 8]}	40	48	87.910227(11)	83.4(3) d	EC	⁸⁸Y	0+
⁸⁹Zr	40	49	88.908890(4)	78.41(12) h	β⁺	⁸⁹Y	9/2+
^89mZr	587.82(10) keV			4.161(17) min	IT (93.77%)	⁸⁹Zr	1/2−
^89mZr	587.82(10) keV			4.161(17) min	β⁺ (6.23%)	⁸⁹Y	1/2−
⁹⁰Zr^{[n 9]}	40	50	89.9047044(25)	Stable			0+	0.5145(40)
^90m1Zr	2319.000(10) keV			809.2(20) ms	IT	⁹⁰Zr	5-
^90m2Zr	3589.419(16) keV			131(4) ns			8+
⁹¹Zr^{[n 9]}	40	51	90.9056458(25)	Stable			5/2+	0.1122(5)
^91mZr	3167.3(4) keV			4.35(14) μs			(21/2+)
⁹²Zr^{[n 9]}	40	52	91.9050408(25)	Stable			0+	0.1715(8)
⁹³Zr^{[n 10]}	40	53	92.9064760(25)	1.53(10)×10⁶ y	β⁻ (73%)	^93mNb	5/2+
⁹³Zr^{[n 10]}	40	53	92.9064760(25)	1.53(10)×10⁶ y	β⁻ (27%)	⁹³Nb	5/2+
⁹⁴Zr^{[n 9]}	40	54	93.9063152(26)	Observationally stable^{[n 11]}			0+	0.1738(28)
⁹⁵Zr^{[n 9]}	40	55	94.9080426(26)	64.032(6) d	β⁻	⁹⁵Nb	5/2+
⁹⁶Zr^{[n 12]}^{[n 9]}^{[n 13]}	40	56	95.9082734(30)	2.0(4)×10¹⁹ y	β⁻β⁻^{[n 14]}	⁹⁶Mo	0+	0.0280(9)
⁹⁷Zr	40	57	96.9109531(30)	16.744(11) h	β⁻	^97mNb	1/2+
⁹⁸Zr	40	58	97.912735(21)	30.7(4) s	β⁻	⁹⁸Nb	0+
⁹⁹Zr	40	59	98.916512(22)	2.1(1) s	β⁻	^99mNb	1/2+
¹⁰⁰Zr	40	60	99.91776(4)	7.1(4) s	β⁻	¹⁰⁰Nb	0+
¹⁰¹Zr	40	61	100.92114(3)	2.3(1) s	β⁻	¹⁰¹Nb	3/2+
¹⁰²Zr	40	62	101.92298(5)	2.9(2) s	β⁻	¹⁰²Nb	0+
¹⁰³Zr	40	63	102.92660(12)	1.3(1) s	β⁻	¹⁰³Nb	(5/2−)
¹⁰⁴Zr	40	64	103.92878(43)#	1.2(3) s	β⁻	¹⁰⁴Nb	0+
¹⁰⁵Zr	40	65	104.93305(43)#	0.6(1) s	β⁻ (>99.9%)	¹⁰⁵Nb
¹⁰⁵Zr	40	65	104.93305(43)#	0.6(1) s	β⁻, n (<.1%)	¹⁰⁴Nb
¹⁰⁶Zr	40	66	105.93591(54)#	200# ms [>300 ns]	β⁻	¹⁰⁶Nb	0+
¹⁰⁷Zr	40	67	106.94075(32)#	150# ms [>300 ns]	β⁻	¹⁰⁷Nb
¹⁰⁸Zr	40	68	107.94396(64)#	80# ms [>300 ns]	β⁻	¹⁰⁸Nb	0+
¹⁰⁹Zr	40	69	108.94924(54)#	60# ms [>300 ns]
¹¹⁰Zr	40	70	109.95287(86)#	30# ms [>300 ns]			0+
¹¹¹Zr^[8]	40	71
¹¹²Zr^[8]	40	72					0+
¹¹³Zr^[9]	40	73
¹¹⁴Zr^[10]	40	74					0+
This table header & footer: view

[n 1]
^mZr – Excited nuclear isomer.
[n 2]
( ) – Uncertainty (1σ) is given in concise form in parentheses after the corresponding last digits.
[n 3]
# – Atomic mass marked #: value and uncertainty derived not from purely experimental data, but at least partly from trends from the Mass Surface (TMS).
[n 4]
Bold half-life – nearly stable, half-life longer than age of universe.
[n 5]
# – Values marked # are not purely derived from experimental data, but at least partly from trends of neighboring nuclides (TNN).
[n 6]
Bold symbol as daughter – Daughter product is stable.
[n 7]
( ) spin value – Indicates spin with weak assignment arguments.
[n 8]
Second most powerful known neutron absorber
[n 9]
Fission product
[N 10]
Long-lived fission product
[N 11]
Believed to decay by β⁻β⁻ to ⁹⁴Mo with a half-life over 1.1×10¹⁷ years
[N 12]
Primordial radionuclide
[N 13]
Predicted to be capable of undergoing triple beta decay and quadruple beta decay with very long partial half-lives
[N 14]
Theorized to also undergo β⁻ decay to ⁹⁶Nb with a partial half-life greater than 2.4×10¹⁹ y^[7]

Zirconium-93

More information Thermal, Fast ...

More information Nuclide, t1⁄2 ...

⁹³Zr is a radioisotope of zirconium with a half-life of 1.53 million years, decaying through emission of a low-energy beta particle. 73% of decays populate an excited state of niobium-93, which decays with a halflife of 14 years and a low-energy gamma ray to the stable ground state of ⁹³Nb, while the remaining 27% of decays directly populate the ground state.^[15] It is one of only 7 long-lived fission products. The low specific activity and low energy of its radiations limit the radioactive hazards of this isotope.

Nuclear fission produces it at a fission yield of 6.3% (thermal neutron fission of ²³⁵U), on a par with the other most abundant fission products. Nuclear reactors usually contain large amounts of zirconium as fuel rod cladding (see zircaloy), and neutron irradiation of ⁹²Zr also produces some ⁹³Zr, though this is limited by ⁹²Zr's low neutron capture cross section of 0.22 barns. Indeed, one of the primary reasons for using zirconium in fuel rod cladding is its low cross section.

⁹³Zr also has a low neutron capture cross section of 0.7 barns.^[16]^[17] Most fission zirconium consists of other isotopes; the other isotope with a significant neutron absorption cross section is ⁹¹Zr with a cross section of 1.24 barns. ⁹³Zr is a less attractive candidate for disposal by nuclear transmutation than are ⁹⁹Tc and ¹²⁹I. Mobility in soil is relatively low, so that geological disposal may be an adequate solution. Alternatively, if the effect on the neutron economy of ⁹³
Zr's higher cross section is deemed acceptable, irradiated cladding and fission product Zirconium (which are mixed together in most current nuclear reprocessing methods) could be used to form new zircalloy cladding. Once the cladding is inside the reactor, the relatively low level radioactivity can be tolerated, but transport and manufacturing might require special precautions.

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This article uses material from the Wikipedia article Zirconium-96, and is written by contributors. Text is available under a CC BY-SA 4.0 International License; additional terms may apply. Images, videos and audio are available under their respective licenses.

[7] [n 1]
^mZr – Excited nuclear isomer.

[8] [n 2]
( ) – Uncertainty (1σ) is given in concise form in parentheses after the corresponding last digits.

[TMS-9] [n 3]
# – Atomic mass marked #: value and uncertainty derived not from purely experimental data, but at least partly from trends from the Mass Surface (TMS).

[10] [n 4]
Bold half-life – nearly stable, half-life longer than age of universe.

[TNN-11] [n 5]
# – Values marked # are not purely derived from experimental data, but at least partly from trends of neighboring nuclides (TNN).

[12] [n 6]
Bold symbol as daughter – Daughter product is stable.

[13] [n 7]
( ) spin value – Indicates spin with weak assignment arguments.

[14] [n 8]
Second most powerful known neutron absorber

[FP-15] [n 9]
Fission product

[16] [N 10]
Long-lived fission product

[17] [N 11]
Believed to decay by β⁻β⁻ to ⁹⁴Mo with a half-life over 1.1×10¹⁷ years

[18] [N 12]
Primordial radionuclide

[19] [N 13]
Predicted to be capable of undergoing triple beta decay and quadruple beta decay with very long partial half-lives

[21] [N 14]
Theorized to also undergo β⁻ decay to ⁹⁶Nb with a partial half-life greater than 2.4×10¹⁹ y^[7]

[29] [a 1]
Decay energy is split among β, neutrino, and γ if any.

[30] [a 2]
Per 65 thermal neutron fissions of ²³⁵U and 35 of ²³⁹Pu.

[31] [a 3]
Has decay energy 380 keV, but its decay product ¹²⁶Sb has decay energy 3.67 MeV.

[32] [a 4]
Lower in thermal reactors because ¹³⁵Xe, its predecessor, readily absorbs neutrons.

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[2] [2]
Pritychenko, Boris; Tretyak, V. "Adopted Double Beta Decay Data". National Nuclear Data Center. Retrieved 2008-02-11.

[3] [3]
"Standard Atomic Weights: Zirconium". CIAAW. 1983.

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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.

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"List of Adopted Double Beta (ββ) Decay Values". National Nuclear Data Center, Brookhaven National Laboratory.

[6] [6]
H Heiskanen; M T Mustonen; J Suhonen (30 March 2007). "Theoretical half-life for beta decay of ⁹⁶Zr". Journal of Physics G: Nuclear and Particle Physics. 34 (5): 837–843. doi:10.1088/0954-3899/34/5/005.

[20] [7]
Finch, S.W.; Tornow, W. (2016). "Search for the β decay of ⁹⁶Zr". Nuclear Instruments and Methods in Physics Research Section A: Accelerators, Spectrometers, Detectors and Associated Equipment. 806: 70–74. Bibcode:2016NIMPA.806...70F. doi:10.1016/j.nima.2015.09.098.

[Ohnishi-22] [8]
Ohnishi, Tetsuya; Kubo, Toshiyuki; Kusaka, Kensuke; et al. (2010). "Identification of 45 New Neutron-Rich Isotopes Produced by In-Flight Fission of a ²³⁸U Beam at 345 MeV/nucleon". J. Phys. Soc. Jpn. 79 (7). Physical Society of Japan: 073201. arXiv:1006.0305. Bibcode:2010JPSJ...79g3201T. doi:10.1143/JPSJ.79.073201.

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Shimizu, Yohei; et al. (2018). "Observation of New Neutron-rich Isotopes among Fission Fragments from In-flight Fission of 345MeV=nucleon 238U: Search for New Isotopes Conducted Concurrently with Decay Measurement Campaigns". Journal of the Physical Society of Japan. 87 (1): 014203. Bibcode:2018JPSJ...87a4203S. doi:10.7566/JPSJ.87.014203.

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Sumikama, T.; et al. (2021). "Observation of new neutron-rich isotopes in the vicinity of Zr110". Physical Review C. 103 (1): 014614. Bibcode:2021PhRvC.103a4614S. doi:10.1103/PhysRevC.103.014614. hdl:10261/260248. S2CID 234019083.

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[Zr93-33] [15]
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[4]

[n 1]

[n 2]

[n 3]

[n 4]

[n 5]

[n 6]

[n 7]

[n 8]

[n 9]

[n 10]

[n 11]

[n 12]

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[n 14]

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[9]

[10]

[7]

[11]

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[14]

[a 1]

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[a 4]

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[17]

	Thermal	Fast	14 MeV
²³²Th	not fissile	6.70 ± 0.40	5.58 ± 0.16
²³³U	6.979 ± 0.098	6.94 ± 0.07	5.38 ± 0.32
²³⁵U	6.346 ± 0.044	6.25 ± 0.04	5.19 ± 0.31
²³⁸U	not fissile	4.913 ± 0.098	4.53 ± 0.13
²³⁹Pu	3.80 ± 0.03	3.82 ± 0.03	3.0 ± 0.3
²⁴¹Pu	2.98 ± 0.04	2.98 ± 0.33	?

Nuclide	t_1⁄2	Yield	Q^{[a 1]}	βγ
	(Ma)	(%)^{[a 2]}	(keV)
⁹⁹Tc	0.211	6.1385	294	β
¹²⁶Sn	0.230	0.1084	4050^{[a 3]}	βγ
⁷⁹Se	0.327	0.0447	151	β
¹³⁵Cs	1.33	6.9110^{[a 4]}	269	β
⁹³Zr	1.53	5.4575	91	βγ
¹⁰⁷Pd	6.5	1.2499	33	β
¹²⁹I	15.7	0.8410	194	βγ
[a 1] Decay energy is split among β, neutrino, and γ if any. [a 2] Per 65 thermal neutron fissions of ²³⁵U and 35 of ²³⁹Pu. [a 3] Has decay energy 380 keV, but its decay product ¹²⁶Sb has decay energy 3.67 MeV. [a 4] Lower in thermal reactors because ¹³⁵Xe, its predecessor, readily absorbs neutrons.

Zirconium-96

Isotopes of zirconium

List of isotopes

Zirconium-88

Zirconium-89

Zirconium-93

References

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