Isotopes of strontium

The alkaline earth metal strontium (Sr) has four stable, naturally occurring isotopes: ⁸⁴Sr (0.56%), ⁸⁶Sr (9.86%), ⁸⁷Sr (7.0%) and ⁸⁸Sr (82.58%). It has a relative atomic mass of 87.62(1).

Only ⁸⁷Sr is radiogenic; it is produced by decay from the radioactive alkali metal ⁸⁷Rb, which has a half-life of 4.88 × 10¹⁰ years. Thus, there are two sources of ⁸⁷Sr in any material: primordial that formed during nucleosynthesis along with ⁸⁴Sr, ⁸⁶Sr and ⁸⁸Sr, as well as that formed by radioactive decay of ⁸⁷Rb. The ratio ⁸⁷Sr/⁸⁶Sr is the parameter typically reported in geologic investigations; ratios in minerals and rocks have values ranging from about 0.7 to greater than 4.0. Because strontium has an electron configuration similar to that of calcium, it readily substitutes for Ca in minerals.

Thirty-one unstable isotopes are known to exist, the longest-lived of which are ⁹⁰Sr with a half-life of 28.9 years and ⁸⁵Sr with a half-life of 64.853 days. Of importance are strontium-89 (⁸⁹Sr) with a half-life of 50.57 days, and strontium-90 (⁹⁰Sr). They decay by emitting an electron and an antineutrino ( $\bar{\nu}_e$ ) in beta decay (β⁻ decay) to become yttrium:

\mathrm{{}^{89}_{38}Sr}\rightarrow\mathrm{{}^{89}_{39}Y} + e^- + \bar{\nu}_e

\mathrm{{}^{90}_{38}Sr}\rightarrow\mathrm{{}^{90}_{39}Y} + e^- + \bar{\nu}_e

⁸⁹Sr is an artificial radioisotope used in treatment of bone cancer. In circumstances where cancer patients have widespread and painful bony metastases, the administration of ⁸⁹Sr results in the delivery of beta particles directly to the area of bony problem, where calcium turnover is greatest.

⁹⁰Sr is a by-product of nuclear fission found in nuclear fallout and presents a health problem since it substitutes for calcium in bone, preventing expulsion from the body. Because it is a long-lived high-energy beta emitter, it is used in SNAP (Systems for Nuclear Auxiliary Power) devices. These devices hold promise for use in spacecraft, remote weather stations, navigational buoys, etc., where a lightweight, long-lived, nuclear-electric power source is required. The 1986 Chernobyl nuclear accident contaminated a vast area with ⁹⁰Sr.

The lightest isotope is ⁷³Sr and the heaviest being ¹⁰⁷Sr.

All other isotopes have half-lives shorter than 55 days, most under 100 minutes.

Table

nuclide symbol	Z(p)	N(n)	isotopic mass (u)	half-life	decay mode(s)^[1]^{[n 1]}	daughter isotope(s)^{[n 2]}	nuclear spin	representative isotopic composition (mole fraction)	range of natural variation (mole fraction)
nuclide symbol	excitation energy			half-life	decay mode(s)^[1]^{[n 1]}	daughter isotope(s)^{[n 2]}	nuclear spin	representative isotopic composition (mole fraction)	range of natural variation (mole fraction)
⁷³Sr	38	35	72.96597(64)#	>25 ms	β⁺ (>99.9%)	⁷³Rb	1/2−#
⁷³Sr	38	35	72.96597(64)#	>25 ms	β⁺, p (<.1%)	⁷²Kr	1/2−#
⁷⁴Sr	38	36	73.95631(54)#	50# ms [>1.5 µs]	β⁺	⁷⁴Rb	0+
⁷⁵Sr	38	37	74.94995(24)	88(3) ms	β⁺ (93.5%)	⁷⁵Rb	(3/2−)
⁷⁵Sr	38	37	74.94995(24)	88(3) ms	β⁺, p (6.5%)	⁷⁴Kr	(3/2−)
⁷⁶Sr	38	38	75.94177(4)	7.89(7) s	β⁺	⁷⁶Rb	0+
⁷⁷Sr	38	39	76.937945(10)	9.0(2) s	β⁺ (99.75%)	⁷⁷Rb	5/2+
⁷⁷Sr	38	39	76.937945(10)	9.0(2) s	β⁺, p (.25%)	⁷⁶Kr	5/2+
⁷⁸Sr	38	40	77.932180(8)	159(8) s	β⁺	⁷⁸Rb	0+
⁷⁹Sr	38	41	78.929708(9)	2.25(10) min	β⁺	⁷⁹Rb	3/2(−)
⁸⁰Sr	38	42	79.924521(7)	106.3(15) min	β⁺	⁸⁰Rb	0+
⁸¹Sr	38	43	80.923212(7)	22.3(4) min	β⁺	⁸¹Rb	1/2−
⁸²Sr	38	44	81.918402(6)	25.36(3) d	EC	⁸²Rb	0+
⁸³Sr	38	45	82.917557(11)	32.41(3) h	β⁺	⁸³Rb	7/2+
^83mSr	259.15(9) keV			4.95(12) s	IT	⁸³Sr	1/2−
⁸⁴Sr	38	46	83.913425(3)	Observationally Stable^{[n 3]}			0+	0.0056(1)	0.0055–0.0058
⁸⁵Sr	38	47	84.912933(3)	64.853(8) d	EC	⁸⁵Rb	9/2+
^85mSr	238.66(6) keV			67.63(4) min	IT (86.6%)	⁸⁵Sr	1/2−
^85mSr	238.66(6) keV			67.63(4) min	β⁺ (13.4%)	⁸⁵Rb	1/2−
⁸⁶Sr	38	48	85.9092607309(91)	Stable			0+	0.0986(1)	0.0975–0.0999
^86mSr	2955.68(21) keV			455(7) ns			8+
⁸⁷Sr^{[n 4]}	38	49	86.9088774970(91)	Stable			9/2+	0.0700(1)	0.0694–0.0714
^87mSr	388.533(3) keV			2.815(12) h	IT (99.7%)	⁸⁷Sr	1/2−
^87mSr	388.533(3) keV			2.815(12) h	EC (.3%)	⁸⁷Rb	1/2−
⁸⁸Sr^{[n 5]}	38	50	87.9056122571(97)	Stable			0+	0.8258(1)	0.8229–0.8275
⁸⁹Sr^{[n 5]}	38	51	88.9074507(12)	50.57(3) d	β⁻	⁸⁹Y	5/2+
⁹⁰Sr^{[n 5]}	38	52	89.907738(3)	28.90(3) y	β⁻	⁹⁰Y	0+
⁹¹Sr	38	53	90.910203(5)	9.63(5) h	β⁻	⁹¹Y	5/2+
⁹²Sr	38	54	91.911038(4)	2.66(4) h	β⁻	⁹²Y	0+
⁹³Sr	38	55	92.914026(8)	7.423(24) min	β⁻	⁹³Y	5/2+
⁹⁴Sr	38	56	93.915361(8)	75.3(2) s	β⁻	⁹⁴Y	0+
⁹⁵Sr	38	57	94.919359(8)	23.90(14) s	β⁻	⁹⁵Y	1/2+
⁹⁶Sr	38	58	95.921697(29)	1.07(1) s	β⁻	⁹⁶Y	0+
⁹⁷Sr	38	59	96.926153(21)	429(5) ms	β⁻ (99.95%)	⁹⁷Y	1/2+
⁹⁷Sr	38	59	96.926153(21)	429(5) ms	β⁻, n (.05%)	⁹⁶Y	1/2+
^97m1Sr	308.13(11) keV			170(10) ns			(7/2)+
^97m2Sr	830.8(2) keV			255(10) ns			(11/2−)#
⁹⁸Sr	38	60	97.928453(28)	0.653(2) s	β⁻ (99.75%)	⁹⁸Y	0+
⁹⁸Sr	38	60	97.928453(28)	0.653(2) s	β⁻, n (.25%)	⁹⁷Y	0+
⁹⁹Sr	38	61	98.93324(9)	0.269(1) s	β⁻ (99.9%)	⁹⁹Y	3/2+
⁹⁹Sr	38	61	98.93324(9)	0.269(1) s	β⁻, n (.1%)	⁹⁸Y	3/2+
¹⁰⁰Sr	38	62	99.93535(14)	202(3) ms	β⁻ (99.02%)	¹⁰⁰Y	0+
¹⁰⁰Sr	38	62	99.93535(14)	202(3) ms	β⁻, n (.98%)	⁹⁹Y	0+
¹⁰¹Sr	38	63	100.94052(13)	118(3) ms	β⁻ (97.63%)	¹⁰¹Y	(5/2−)
¹⁰¹Sr	38	63	100.94052(13)	118(3) ms	β⁻, n (2.37%)	¹⁰⁰Y	(5/2−)
¹⁰²Sr	38	64	101.94302(12)	69(6) ms	β⁻ (94.5%)	¹⁰²Y	0+
¹⁰²Sr	38	64	101.94302(12)	69(6) ms	β⁻, n (5.5%)	¹⁰¹Y	0+
¹⁰³Sr	38	65	102.94895(54)#	50# ms [>300 ns]	β⁻	¹⁰³Y
¹⁰⁴Sr	38	66	103.95233(75)#	30# ms [>300 ns]	β⁻	¹⁰⁴Y	0+
¹⁰⁵Sr	38	67	104.95858(75)#	20# ms [>300 ns]

↑ Abbreviations:
EC: Electron capture
IT: Isomeric transition
↑ Bold for stable isotopes, bold italic for nearly-stable isotopes (half-life longer than the age of the universe)
↑ Believed to decay by β⁺β⁺ to ⁸⁴Kr
↑ Used in rubidium-strontium dating
↑ ^5.0 ^5.1 ^5.2 Fission product

Notes

Evaluated isotopic composition is for most but not all commercial samples.
The precision of the isotope abundances and atomic mass is limited through variations. The given ranges should be applicable to any normal terrestrial material.
Geologically exceptional samples are known in which the isotopic composition lies outside the reported range. The uncertainty in the atomic mass may exceed the stated value for such specimens.
Values marked # are not purely derived from experimental data, but at least partly from systematic trends. Spins with weak assignment arguments are enclosed in parentheses.
Uncertainties are given in concise form in parentheses after the corresponding last digits. Uncertainty values denote one standard deviation, except isotopic composition and standard atomic mass from IUPAC, which use expanded uncertainties.

References

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Isotope masses from:
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Isotopic compositions and standard atomic masses from:
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Half-life, spin, and isomer data selected from the following sources. See editing notes on this article's talk page.
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Isotopes of rubidium	Isotopes of strontium	Isotopes of yttrium
Table of nuclides

[2] Abbreviations:
EC: Electron capture
IT: Isomeric transition

[3] Bold for stable isotopes, bold italic for nearly-stable isotopes (half-life longer than the age of the universe)

[4] Believed to decay by β⁺β⁺ to ⁸⁴Kr

[5] Used in rubidium-strontium dating

[FP-6] 5.0 ^5.1 ^5.2 Fission product

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[1]

[n 1]

[n 2]

[n 3]

[n 4]

[n 5]

v t e Isotopes of the chemical elements
1 H																	2 He
3 Li	4 Be											5 B	6 C	7 N	8 O	9 F	10 Ne
11 Na	12 Mg											13 Al	14 Si	15 P	16 S	17 Cl	18 Ar
19 K	20 Ca	21 Sc	22 Ti	23 V	24 Cr	25 Mn	26 Fe	27 Co	28 Ni	29 Cu	30 Zn	31 Ga	32 Ge	33 As	34 Se	35 Br	36 Kr
37 Rb	38 Sr	39 Y	40 Zr	41 Nb	42 Mo	43 Tc	44 Ru	45 Rh	46 Pd	47 Ag	48 Cd	49 In	50 Sn	51 Sb	52 Te	53 I	54 Xe
55 Cs	56 Ba		72 Hf	73 Ta	74 W	75 Re	76 Os	77 Ir	78 Pt	79 Au	80 Hg	81 Tl	82 Pb	83 Bi	84 Po	85 At	86 Rn
87 Fr	88 Ra		104 Rf	105 Db	106 Sg	107 Bh	108 Hs	109 Mt	110 Ds	111 Rg	112 Cn	113 Uut	114 Fl	115 Uup	116 Lv	117 Uus	118 Uuo

		57 La	58 Ce	59 Pr	60 Nd	61 Pm	62 Sm	63 Eu	64 Gd	65 Tb	66 Dy	67 Ho	68 Er	69 Tm	70 Yb	71 Lu
		89 Ac	90 Th	91 Pa	92 U	93 Np	94 Pu	95 Am	96 Cm	97 Bk	98 Cf	99 Es	100 Fm	101 Md	102 No	103 Lr
Table of nuclides Categories: Isotopes Tables of nuclides Metastable isotopes Isotopes by element

Isotopes of strontium

Table

Notes

References

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