isotopes of zirconium

{{Anchor}}

{{Isotopes table

|symbol=Zr

|refs=NUBASE2020, AME2020 II

|notes=m, unc(), mass#, hl#, hl-nst, spin(), spin#, daughter-st

}}

|-id=Zirconium-77

| ⁷⁷Zr

| style="text-align:right" | 40

| style="text-align:right" | 37

| 76.96608(43)#

| 100# μs

|

|

| 3/2−#

|

|

|-id=Zirconium-78

| ⁷⁸Zr

| style="text-align:right" | 40

| style="text-align:right" | 38

| 77.95615(43)#

| 50# ms
[>200 ns]

|

|

| 0+

|

|

|-id=Zirconium-79

| ⁷⁹Zr

| style="text-align:right" | 40

| style="text-align:right" | 39

| 78.94979(32)#

| 56(30) ms

| β⁺

| ⁷⁹Y

| 5/2+#

|

|

|-id=Zirconium-80

| ⁸⁰Zr

| style="text-align:right" | 40

| style="text-align:right" | 40

| 79.94121(32)#

| 4.6(6) s

| β⁺

| ⁸⁰Y

| 0+

|

|

|-id=Zirconium-81

| rowspan=2|⁸¹Zr

| rowspan=2 style="text-align:right" | 40

| rowspan=2 style="text-align:right" | 41

| rowspan=2|80.938245(99)

| rowspan=2|5.5(4) s

| β⁺ (99.88%)

| ⁸¹Y

| rowspan=2|(3/2−)

| rowspan=2|

| rowspan=2|

|-

| β⁺, p (0.12%)

| ⁸⁰Sr

|-id=Zirconium-82

| ⁸²Zr

| style="text-align:right" | 40

| style="text-align:right" | 42

| 81.9317075(17)

| 32(5) s

| β⁺

| ⁸²Y

| 0+

|

|

|-id=Zirconium-83

| rowspan=2|⁸³Zr

| rowspan=2 style="text-align:right" | 40

| rowspan=2 style="text-align:right" | 43

| rowspan=2|82.9292409(69)

| rowspan=2|42(2) s

| β⁺

| ⁸³Y

| rowspan=2|1/2−#

| rowspan=2|

| rowspan=2|

|-

| β⁺, p (?%)

| ⁸²Sr

|-id=Zirconium-83m1

| style="text-indent:1em" | ^83m1Zr

| colspan="3" style="text-indent:2em" | 52.72(5) keV

| 0.53(12) μs

| IT

| ⁸³Zr

| (5/2−)

|

|

|-id=Zirconium-83m2

| style="text-indent:1em" | ^83m2Zr

| colspan="3" style="text-indent:2em" | 77.04(7) keV

| 1.8(1) μs

| IT

| ⁸³Zr

| (7/2+)

|

|

|-id=Zirconium-84

| ⁸⁴Zr

| style="text-align:right" | 40

| style="text-align:right" | 44

| 83.9233257(59)

| 25.8(5) min

| β⁺

| ⁸⁴Y

| 0+

|

|

|-id=Zirconium-85

| ⁸⁵Zr

| style="text-align:right" | 40

| style="text-align:right" | 45

| 84.9214432(69)

| 7.86(4) min

| β⁺

| ⁸⁵Y

| (7/2+)

|

|

|-id=Zirconium-85m

| rowspan=2 style="text-indent:1em" | ^85mZr

| rowspan=2 colspan="3" style="text-indent:2em" | 292.2(3) keV

| rowspan=2|10.9(3) s

| IT (?%)

| ⁸⁵Zr

| rowspan=2|1/2−#

| rowspan=2|

| rowspan=2|

|-

| β⁺ (?%)

| ⁸⁵Y

|-id=Zirconium-86

| ⁸⁶Zr

| style="text-align:right" | 40

| style="text-align:right" | 46

| 85.9162968(38)

| 16.5(1) h

| β⁺

| ⁸⁶Y

| 0+

|

|

|-id=Zirconium-87

| ⁸⁷Zr

| style="text-align:right" | 40

| style="text-align:right" | 47

| 86.9148173(45)

| 1.68(1) h

| β⁺

| ⁸⁷Y

| 9/2+

|

|

|-id=Zirconium-87m

| style="text-indent:1em" | ^87mZr

| colspan="3" style="text-indent:2em" | 335.84(19) keV

| 14.0(2) s

| IT

| ⁸⁷Zr

| 1/2−

|

|

|-

| ⁸⁸ZrSecond most powerful known neutron absorber

| style="text-align:right" | 40

| style="text-align:right" | 48

| 87.9102207(58)

| 83.4(3) d

| EC

| ⁸⁸Y

| 0+

|

|

|-id=Zirconium-88m

| style="text-indent:1em" | ^88mZr

| colspan="3" style="text-indent:2em" | 2887.79(6) keV

| 1.320(25) μs

| IT

| ⁸⁸Zr

| 8+

|

|

|-

| ⁸⁹Zr

| style="text-align:right" | 40

| style="text-align:right" | 49

| 88.9088798(30)

| 78.360(23) h

| β⁺

| ⁸⁹Y

| 9/2+

|

|

|-id=Zirconium-89m

| rowspan=2 style="text-indent:1em" | ^89mZr

| rowspan=2 colspan="3" style="text-indent:2em" | 587.82(10) keV

| rowspan=2|4.161(10) min

| IT (93.77%)

| ⁸⁹Zr

| rowspan=2|1/2−

| rowspan=2|

| rowspan=2|

|-

| β⁺ (6.23%)

| ⁸⁹Y

|-id=Zirconium-90

| ⁹⁰ZrFission product

| style="text-align:right" | 40

| style="text-align:right" | 50

| 89.90469876(13)

| colspan=3 align=center|Stable

| 0+

| 0.5145(4)

|

|-id=Zirconium-90m1

| style="text-indent:1em" | ^90m1Zr

| colspan="3" style="text-indent:2em" | 2319.000(9) keV

| 809.2(20) ms

| IT

| ⁹⁰Zr

| 5-

|

|

|-id=Zirconium-90m2

| style="text-indent:1em" | ^90m2Zr

| colspan="3" style="text-indent:2em" | 3589.418(15) keV

| 131(4) ns

| IT

| ⁹⁰Zr

| 8+

|

|

|-id=Zirconium-91

| ⁹¹Zr

| style="text-align:right" | 40

| style="text-align:right" | 51

| 90.90564021(10)

| colspan=3 align=center|Stable

| 5/2+

| 0.1122(5)

|

|-id=Zirconium-91m

| style="text-indent:1em" | ^91mZr

| colspan="3" style="text-indent:2em" | 3167.3(4) keV

| 4.35(14) μs

| IT

| ⁹¹Zr

| (21/2+)

|

|

|-id=Zirconium-92

| ⁹²Zr

| style="text-align:right" | 40

| style="text-align:right" | 52

| 91.90503534(10)

| colspan=3 align=center|Stable

| 0+

| 0.1715(3)

|

|-

| rowspan=2 | ⁹³ZrLong-lived fission product

| rowspan=2 style="text-align:right" | 40

| rowspan=2 style="text-align:right" | 53

| rowspan=2 | 92.90647066(49)

| rowspan=2 | 1.61(5)×10⁶ y

| β⁻ (73%)

| ^93m1Nb

| rowspan=2 | 5/2+

| rowspan=2 |

| rowspan=2 |

|-

| β⁻ (27%)

| ⁹³Nb

|-id=Zirconium-94

| ⁹⁴Zr

| style="text-align:right" | 40

| style="text-align:right" | 54

| 93.90631252(18)

| colspan=3 align=center|Observationally stableBelieved to decay by β⁻β⁻ to ⁹⁴Mo with a half-life over 1.1×10¹⁷ years

| 0+

| 0.1738(4)

|

|-id=Zirconium-95

| ⁹⁵Zr

| style="text-align:right" | 40

| style="text-align:right" | 55

| 94.90804028(93)

| 64.032(6) d

| β⁻

| ⁹⁵Nb

| 5/2+

|

|

|-id=Zirconium-96

| ⁹⁶ZrPrimordial radionuclidePredicted to be capable of undergoing triple beta decay and quadruple beta decay with very long partial half-lives

| style="text-align:right" | 40

| style="text-align:right" | 56

| 95.90827762(12)

| 2.34(17)×10¹⁹ y

| β⁻β⁻{{refn|group="n"|Theorized to also undergo β⁻ decay to ⁹⁶Nb with a partial half-life greater than 2.4×10¹⁹ y{{cite journal |last1=Finch |first1=S.W. |last2=Tornow |first2=W. |title=Search for the β decay of ⁹⁶Zr |date=2016 |journal=Nuclear Instruments and Methods in Physics Research Section A: Accelerators, Spectrometers, Detectors and Associated Equipment |volume=806 |pages=70–74 |doi=10.1016/j.nima.2015.09.098 |bibcode=2016NIMPA.806...70F |doi-access=free }}}}

| ⁹⁶Mo

| 0+

| 0.0280(2)

|

|-id=Zirconium-97

| ⁹⁷Zr

| style="text-align:right" | 40

| style="text-align:right" | 57

| 96.91096380(13)

| 16.749(8) h

| β⁻

| ^97mNb

| 1/2+

|

|

|-id=Zirconium-97m

| style="text-indent:1em" | ^97mZr

| colspan="3" style="text-indent:2em" | 1264.35(16) keV

| 104.8(17) ns

| IT

| ⁹⁷Zr

| 7/2+

|

|

|-id=Zirconium-98

| ⁹⁸Zr

| style="text-align:right" | 40

| style="text-align:right" | 58

| 97.9127404(91)

| 30.7(4) s

| β⁻

| ⁹⁸Nb

| 0+

|

|

|-id=Zirconium-98m

| style="text-indent:1em" | ^98mZr

| colspan="3" style="text-indent:2em" | 6601.9(11) keV

| 1.9(2) μs

| IT

| ⁹⁸Zr

| (17−)

|

|

|-id=Zirconium-99

| ⁹⁹Zr

| style="text-align:right" | 40

| style="text-align:right" | 59

| 98.916675(11)

| 2.1(1) s

| β⁻

| ^99mNb

| 1/2+

|

|

|-id=Zirconium-99m

| style="text-indent:1em" | ^99mZr

| colspan="3" style="text-indent:2em" | 251.96(9) keV

| 336(5) ns

| IT

| ⁹⁹Zr

| 7/2+

|

|

|-id=Zirconium-100

| ¹⁰⁰Zr

| style="text-align:right" | 40

| style="text-align:right" | 60

| 99.9180105(87)

| 7.1(4) s

| β⁻

| ¹⁰⁰Nb

| 0+

|

|

|-id=Zirconium-101

| ¹⁰¹Zr

| style="text-align:right" | 40

| style="text-align:right" | 61

| 100.9214585(89)

| 2.29(8) s

| β⁻

| ¹⁰¹Nb

| 3/2+

|

|

|-id=Zirconium-102

| ¹⁰²Zr

| style="text-align:right" | 40

| style="text-align:right" | 62

| 101.9231542(94)

| 2.01(8) s

| β⁻

| ¹⁰²Nb

| 0+

|

|

|-id=Zirconium-103

| rowspan=2|¹⁰³Zr

| rowspan=2 style="text-align:right" | 40

| rowspan=2 style="text-align:right" | 63

| rowspan=2|102.9272041(99)

| rowspan=2|1.38(7) s

| β⁻ (>99%)

| ¹⁰³Nb

| rowspan=2|(5/2−)

| rowspan=2|

| rowspan=2|

|-

| β⁻, n (<1%)

| ¹⁰²Nb

|-id=Zirconium-104

| rowspan=2|¹⁰⁴Zr

| rowspan=2 style="text-align:right" | 40

| rowspan=2 style="text-align:right" | 64

| rowspan=2|103.929449(10)

| rowspan=2|920(28) ms

| β⁻ (>99%)

| ¹⁰⁴Nb

| rowspan=2|0+

| rowspan=2|

| rowspan=2|

|-

| β⁻, n (<1%)

| ¹⁰³Nb

|-id=Zirconium-105

| rowspan=2|¹⁰⁵Zr

| rowspan=2 style="text-align:right" | 40

| rowspan=2 style="text-align:right" | 65

| rowspan=2|104.934022(13)

| rowspan=2|670(28) ms

| β⁻ (>98%)

| ¹⁰⁵Nb

| rowspan=2|1/2+#

| rowspan=2|

| rowspan=2|

|-

| β⁻, n (<2%)

| ¹⁰⁴Nb

|-id=Zirconium-106

| rowspan=2|¹⁰⁶Zr

| rowspan=2 style="text-align:right" | 40

| rowspan=2 style="text-align:right" | 66

| rowspan=2|105.93693(22)#

| rowspan=2|179(6) ms

| β⁻ (>98%)

| ¹⁰⁶Nb

| rowspan=2|0+

| rowspan=2|

| rowspan=2|

|-

| β⁻, n (<2%)

| ¹⁰⁵Nb

|-id=Zirconium-107

| rowspan=2|¹⁰⁷Zr

| rowspan=2 style="text-align:right" | 40

| rowspan=2 style="text-align:right" | 67

| rowspan=2|106.94201(32)#

| rowspan=2|145.7(24) ms

| β⁻ (>77%)

| ¹⁰⁷Nb

| rowspan=2|5/2+#

| rowspan=2|

| rowspan=2|

|-

| β⁻, n (<23%)

| ¹⁰⁶Nb

|-id=Zirconium-108

| ¹⁰⁸Zr

| style="text-align:right" | 40

| style="text-align:right" | 68

| 107.94530(43)#

| 78.5(20) ms

| β⁻

| ¹⁰⁸Nb

| 0+

|

|

|-id=Zirconium-108m

| style="text-indent:1em" | ^108mZr

| colspan="3" style="text-indent:2em" | 2074.5(8) keV

| 540(30) ns

| IT

| ¹⁰⁸Zr

| (6+)

|

|

|-id=Zirconium-109

| ¹⁰⁹Zr

| style="text-align:right" | 40

| style="text-align:right" | 69

| 108.95091(54)#

| 56(3) ms

| β⁻

| ¹⁰⁹Nb

| 5/2+#

|

|

|-id=Zirconium-110

| ¹¹⁰Zr

| style="text-align:right" | 40

| style="text-align:right" | 70

| 109.95468(54)#

| 37.5(20) ms

| β⁻

| ¹¹⁰Nb

| 0+

|

|

|-id=Zirconium-111

| ¹¹¹Zr

| style="text-align:right" | 40

| style="text-align:right" | 71

| 110.96084(64)#

| 24.0(5) ms

| β⁻

| ¹¹¹Nb

| 5/2+#

|

|

|-id=Zirconium-112

| ¹¹²Zr

| style="text-align:right" | 40

| style="text-align:right" | 72

| 111.96520(75)#

| 43(21) ms

| β⁻

| ¹¹²Nb

| 0+

|

|

|-id=Zirconium-113

| ¹¹³Zr

| style="text-align:right" | 40

| style="text-align:right" | 73

| 112.97172(32)#

| 15# ms
[>550 ns]

|

|

| 3/2+

|

|

|-id=Zirconium-114

| ¹¹⁴Zr{{Cite journal|url=https://journals.aps.org/prc/abstract/10.1103/PhysRevC.103.014614|doi = 10.1103/PhysRevC.103.014614|title = Observation of new neutron-rich isotopes in the vicinity of Zr110|year = 2021|last1 = Sumikama|first1 = T.|last2 = Fukuda|first2 = N.|last3 = Inabe|first3 = N.|last4 = Kameda|first4 = D.|last5 = Kubo|first5 = T.|last6 = Shimizu|first6 = Y.|last7 = Suzuki|first7 = H.|last8 = Takeda|first8 = H.|last9 = Yoshida|first9 = K.|last10 = Baba|first10 = H.|last11 = Browne|first11 = F.|last12 = Bruce|first12 = A. M.|last13 = Carroll|first13 = R.|last14 = Chiga|first14 = N.|last15 = Daido|first15 = R.|last16 = Didierjean|first16 = F.|last17 = Doornenbal|first17 = P.|last18 = Fang|first18 = Y.|last19 = Gey|first19 = G.|last20 = Ideguchi|first20 = E.|last21 = Isobe|first21 = T.|last22 = Lalkovski|first22 = S.|last23 = Li|first23 = Z.|last24 = Lorusso|first24 = G.|last25 = Lozeva|first25 = R.|last26 = Nishibata|first26 = H.|last27 = Nishimura|first27 = S.|last28 = Nishizuka|first28 = I.|last29 = Odahara|first29 = A.|last30 = Patel|first30 = Z.|journal = Physical Review C|volume = 103| issue=1 | page=014614 | bibcode=2021PhRvC.103a4614S |s2cid = 234019083|display-authors = 1|hdl = 10261/260248|hdl-access = free}}

| style="text-align:right" | 40

| style="text-align:right" | 74

|

|

|

|

| 0+

|

|

{{Isotopes table/footer}}

⁸⁸Zr is a radioisotope of zirconium with a half-life of 83.4 days. In January 2019, this isotope was discovered to have a neutron capture cross section of approximately 861,000 barns; this is several orders of magnitude greater than predicted, and greater than that of any other nuclide except xenon-135.{{cite journal |last1=Shusterman |first1=J.A. |last2=Scielzo |first2=N.D. |last3=Thomas |first3=K.J. |last4=Norman |first4=E.B. |last5=Lapi |first5=S.E. |last6=Loveless |first6=C.S. |last7=Peters |first7=N.J. |last8=Robertson |first8=J.D. |last9=Shaughnessy |first9=D.A. |last10=Tonchev |first10=A.P. |title=The surprisingly large neutron capture cross-section of ⁸⁸Zr |journal=Nature |date=2019 |volume=565 |issue=7739 |pages=328–330 |doi=10.1038/s41586-018-0838-z |pmid=30617314 |bibcode=2019Natur.565..328S |osti=1512575 |s2cid=57574387 |url=https://www.osti.gov/biblio/1512575 }}

⁸⁹Zr is a radioisotope of zirconium with a half-life of 78.41 hours. It is produced by proton irradiation of natural yttrium-89. Its most prominent gamma photon has an energy of 909 keV.

Zirconium-89 is employed in specialized diagnostic applications using positron emission tomography{{cite journal |last1=Dilworth |first1=Jonathan R. |last2=Pascu |first2=Sofia I. |title=The chemistry of PET imaging with zirconium-89 |journal=Chemical Society Reviews |date=2018 |volume=47 |issue=8 |pages=2554–2571 |doi=10.1039/C7CS00014F|pmid=29557435 }} imaging, for example, with zirconium-89 labeled antibodies (immuno-PET).{{cite journal |last1=Van Dongen |first1=GA |last2=Vosjan |first2=MJ |title=Immuno-positron emission tomography: shedding light on clinical antibody therapy |journal= Cancer Biotherapy and Radiopharmaceuticals |date=August 2010 |volume=25 |issue=4 |pages=375–85|doi=10.1089/cbr.2010.0812 |pmid=20707716 }} For a decay table, see {{cite web |author=Maria Vosjan |url=https://www.cyclotron.nl/decay-calculator/ |title=Zirconium-89 (⁸⁹Zr) |publisher=Cyclotron.nl}}

{{Chain yield | 6.70 ± 0.40| 5.58 ± 0.16

| 6.979 ± 0.098| 6.94 ± 0.07| 5.38 ± 0.32

| 6.346 ± 0.044| 6.25 ± 0.04| 5.19 ± 0.31

| 4.913 ± 0.098| 4.53 ± 0.13

| 3.80 ± 0.03 | 3.82 ± 0.03| 3.0 ± 0.3

| 2.98 ± 0.04 | 2.98 ± 0.33| ?

|data_ref=M. B. Chadwick et al, "ENDF/B-VII.1: Nuclear Data for Science and Technology: Cross Sections, Covariances, Fission Product Yields and Decay Data", Nucl. Data Sheets 112(2011)2887. (accessed at www-nds.iaea.org/exfor/endf.htm)}}

⁹³Zr is a radioisotope of zirconium with a half-life of 1.61 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 half-life 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.{{cite journal |last1=Cassette |first1=P. |last2=Chartier |first2=F. |last3=Isnard |first3=H. |last4=Fréchou |first4=C. |last5=Laszak |first5=I. |last6=Degros |first6=J.P. |last7=Bé |first7=M.M. |last8=Lépy |first8=M.C. |last9=Tartes |first9=I. |title=Determination of ⁹³Zr decay scheme and half-life |date=2010 |journal=Applied Radiation and Isotopes |volume=68 |issue=1 |pages=122–130 |doi=10.1016/j.apradiso.2009.08.011 |pmid=19734052 |url=https://www.researchgate.net/publication/26793104}} 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.{{cite web |date=2011-12-22 |url=http://www.nndc.bnl.gov/exfor/endf00.jsp |title=ENDF/B-VII.1 Zr-93(n,g) |publisher=National Nuclear Data Center, Brookhaven National Laboratory |access-date=2014-11-20 |archive-date=2009-07-20 |archive-url=https://web.archive.org/web/20090720032108/http://www.nndc.bnl.gov/exfor/endf00.jsp |url-status=dead }}{{cite journal |author=S. Nakamura |display-authors=etal |title=Thermal neutron capture cross-sections of Zirconium-91 and Zirconium-93 by prompt gamma-ray spectroscopy |journal=Journal of Nuclear Science and Technology |volume=44 |issue=1 |pages=21–28| year=2007 |doi=10.1080/18811248.2007.9711252|bibcode=2007JNST...44...21N |s2cid=96087661 }} 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 {{chem|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.

{{Clear}}

{{Reflist}}

• Isotope masses from:
• {{NUBASE 2003}}
• Isotopic compositions and standard atomic masses from:
• {{CIAAW2003}}
• {{CIAAW 2005}}
• Half-life, spin, and isomer data selected from the following sources.
• {{NUBASE 2003}}
• {{NNDC}}
• {{CRC85|chapter=11}}

{{Navbox element isotopes}}

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Zirconium