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Isotopes of caesium

April 08, 2024

Caesium (55Cs) has 41 known isotopes, the atomic masses of these isotopes range from 112 to 152. Only one isotope, 133Cs, is stable. The longest-lived radioisotopes are 135Cs with a half-life of 1.33 million years, 137
Cs
 with a half-life of 30.1671 years and 134Cs with a half-life of 2.0652 years. All other isotopes have half-lives less than 2 weeks, most under an hour.

Isotopes of caesium (55Cs)
Main isotopes[1] Decay
abun­dance half-life (t1/2) mode pro­duct
131Cs synth 9.7 d ε 131Xe
133Cs 100% stable
134Cs synth 2.0648 y ε 134Xe
β 134Ba
135Cs trace 1.33×106 y β 135Ba
137Cs synth 30.17 y[2] β 137Ba
Standard atomic weight Ar°(Cs)

Beginning in 1945 with the commencement of nuclear testing, caesium radioisotopes were released into the atmosphere where caesium is absorbed readily into solution and is returned to the surface of the Earth as a component of radioactive fallout. Once caesium enters the ground water, it is deposited on soil surfaces and removed from the landscape primarily by particle transport. As a result, the input function of these isotopes can be estimated as a function of time.

List of isotopes edit

Nuclide
[n 1]		 Z N Isotopic mass (Da)
[n 2][n 3]		 Half-life
 Decay
mode
[n 4]		 Daughter
isotope
[n 5][n 6]		 Spin and
parity
[n 7][n 8]		 Natural abundance (mole fraction)
Excitation energy[n 8] Normal proportion Range of variation
112Cs 55 57 111.95030(33)# 500(100) μs p 111Xe 1+#
α 108I
113Cs 55 58 112.94449(11) 16.7(7) μs p (99.97%) 112Xe 5/2+#
β+ (.03%) 113Xe
114Cs 55 59 113.94145(33)# 0.57(2) s β+ (91.09%) 114Xe (1+)
β+, p (8.69%) 113I
β+, α (.19%) 110Te
α (.018%) 110I
115Cs 55 60 114.93591(32)# 1.4(8) s β+ (99.93%) 115Xe 9/2+#
β+, p (.07%) 114I
116Cs 55 61 115.93337(11)# 0.70(4) s β+ (99.67%) 116Xe (1+)
β+, p (.279%) 115I
β+, α (.049%) 112Te
116mCs 100(60)# keV 3.85(13) s β+ (99.48%) 116Xe 4+, 5, 6
β+, p (.51%) 115I
β+, α (.008%) 112Te
117Cs 55 62 116.92867(7) 8.4(6) s β+ 117Xe (9/2+)#
117mCs 150(80)# keV 6.5(4) s β+ 117Xe 3/2+#
118Cs 55 63 117.926559(14) 14(2) s β+ (99.95%) 118Xe 2
β+, p (.042%) 117I
β+, α (.0024%) 114Te
118mCs 100(60)# keV 17(3) s β+ (99.95%) 118Xe (7−)
β+, p (.042%) 117I
β+, α (.0024%) 114Te
119Cs 55 64 118.922377(15) 43.0(2) s β+ 119Xe 9/2+
β+, α (2×10−6%) 115Te
119mCs 50(30)# keV 30.4(1) s β+ 119Xe 3/2(+)
120Cs 55 65 119.920677(11) 61.2(18) s β+ 120Xe 2(−#)
β+, α (2×10−5%) 116Te
β+, p (7×10−6%) 119I
120mCs 100(60)# keV 57(6) s β+ 120Xe (7−)
β+, α (2×10−5%) 116Te
β+, p (7×10−6%) 119I
121Cs 55 66 120.917229(15) 155(4) s β+ 121Xe 3/2(+)
121mCs 68.5(3) keV 122(3) s β+ (83%) 121Xe 9/2(+)
IT (17%) 121Cs
122Cs 55 67 121.91611(3) 21.18(19) s β+ 122Xe 1+
β+, α (2×10−7%) 118Te
122m1Cs 45.8 keV >1 μs (3)+
122m2Cs 140(30) keV 3.70(11) min β+ 122Xe 8−
122m3Cs 127.0(5) keV 360(20) ms (5)−
123Cs 55 68 122.912996(13) 5.88(3) min β+ 123Xe 1/2+
123m1Cs 156.27(5) keV 1.64(12) s IT 123Cs (11/2)−
123m2Cs 231.63+X keV 114(5) ns (9/2+)
124Cs 55 69 123.912258(9) 30.9(4) s β+ 124Xe 1+
124mCs 462.55(17) keV 6.3(2) s IT 124Cs (7)+
125Cs 55 70 124.909728(8) 46.7(1) min β+ 125Xe 1/2(+)
125mCs 266.6(11) keV 900(30) ms (11/2−)
126Cs 55 71 125.909452(13) 1.64(2) min β+ 126Xe 1+
126m1Cs 273.0(7) keV >1 μs
126m2Cs 596.1(11) keV 171(14) μs
127Cs 55 72 126.907418(6) 6.25(10) h β+ 127Xe 1/2+
127mCs 452.23(21) keV 55(3) μs (11/2)−
128Cs 55 73 127.907749(6) 3.640(14) min β+ 128Xe 1+
129Cs 55 74 128.906064(5) 32.06(6) h β+ 129Xe 1/2+
130Cs 55 75 129.906709(9) 29.21(4) min β+ (98.4%) 130Xe 1+
β (1.6%) 130Ba
130mCs 163.25(11) keV 3.46(6) min IT (99.83%) 130Cs 5−
β+ (.16%) 130Xe
131Cs 55 76 130.905464(5) 9.689(16) d EC 131Xe 5/2+
132Cs 55 77 131.9064343(20) 6.480(6) d β+ (98.13%) 132Xe 2+
β (1.87%) 132Ba
133Cs[n 9][n 10] 55 78 132.905451933(24) Stable 7/2+ 1.0000
134Cs[n 10] 55 79 133.906718475(28) 2.0652(4) y β 134Ba 4+
EC (3×10−4%) 134Xe
134mCs 138.7441(26) keV 2.912(2) h IT 134Cs 8−
135Cs[n 10] 55 80 134.9059770(11) 2.3 x106 y β 135Ba 7/2+
135mCs 1632.9(15) keV 53(2) min IT 135Cs 19/2−
136Cs 55 81 135.9073116(20) 13.16(3) d β 136Ba 5+
136mCs 518(5) keV 19(2) s β 136Ba 8−
IT 136Cs
137Cs[n 10] 55 82 136.9070895(5) 30.1671(13) y β (95%) 137mBa 7/2+
β (5%) 137Ba
138Cs 55 83 137.911017(10) 33.41(18) min β 138Ba 3−
138mCs 79.9(3) keV 2.91(8) min IT (81%) 138Cs 6−
β (19%) 138Ba
139Cs 55 84 138.913364(3) 9.27(5) min β 139Ba 7/2+
140Cs 55 85 139.917282(9) 63.7(3) s β 140Ba 1−
141Cs 55 86 140.920046(11) 24.84(16) s β (99.96%) 141Ba 7/2+
β, n (.0349%) 140Ba
142Cs 55 87 141.924299(11) 1.689(11) s β (99.9%) 142Ba 0−
β, n (.091%) 141Ba
143Cs 55 88 142.927352(25) 1.791(7) s β (98.38%) 143Ba 3/2+
β, n (1.62%) 142Ba
144Cs 55 89 143.932077(28) 994(4) ms β (96.8%) 144Ba 1(−#)
β, n (3.2%) 143Ba
144mCs 300(200)# keV <1 s β 144Ba (>3)
IT 144Cs
145Cs 55 90 144.935526(12) 582(6) ms β (85.7%) 145Ba 3/2+
β, n (14.3%) 144Ba
146Cs 55 91 145.94029(8) 0.321(2) s β (85.8%) 146Ba 1−
β, n (14.2%) 145Ba
147Cs 55 92 146.94416(6) 0.235(3) s β (71.5%) 147Ba (3/2+)
β, n (28.49%) 146Ba
148Cs 55 93 147.94922(62) 146(6) ms β (74.9%) 148Ba
β, n (25.1%) 147Ba
149Cs 55 94 148.95293(21)# 150# ms [>50 ms] β 149Ba 3/2+#
β, n 148Ba
150Cs 55 95 149.95817(32)# 100# ms [>50 ms] β 150Ba
β, n 149Ba
151Cs 55 96 150.96219(54)# 60# ms [>50 ms] β 151Ba 3/2+#
β, n 150Ba
This table header & footer:
  1. ^ mCs – 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. ^ Modes of decay:
  5. ^ Bold italics symbol as daughter – Daughter product is nearly stable.
  6. ^ Bold symbol as daughter – Daughter product is stable.
  7. ^ ( ) spin value – Indicates spin with weak assignment arguments.
  8. ^ a b # – Values marked # are not purely derived from experimental data, but at least partly from trends of neighboring nuclides (TNN).
  9. ^ Used to define the second
  10. ^ a b c d Fission product

Caesium-131 edit

Caesium-131, introduced in 2004 for brachytherapy by Isoray,[5] has a half-life of 9.7 days and 30.4 keV energy.

Caesium-133 edit

Caesium-133 is the only stable isotope of caesium. The SI base unit of time, the second, is defined by a specific caesium-133 transition. Since 1967, the official definition of a second is:

The second, symbol s, is defined by taking the fixed numerical value of the caesium frequency, ΔνCs, the unperturbed ground-state hyperfine transition frequency of the caesium-133 atom,[6] to be 9192631770 when expressed in the unit Hz, which is equal to s−1.

Caesium-134 edit

Caesium-134 has a half-life of 2.0652 years. It is produced both directly (at a very small yield because 134Xe is stable) as a fission product and via neutron capture from nonradioactive 133Cs (neutron capture cross section 29 barns), which is a common fission product. Caesium-134 is not produced via beta decay of other fission product nuclides of mass 134 since beta decay stops at stable 134Xe. It is also not produced by nuclear weapons because 133Cs is created by beta decay of original fission products only long after the nuclear explosion is over.

The combined yield of 133Cs and 134Cs is given as 6.7896%. The proportion between the two will change with continued neutron irradiation. 134Cs also captures neutrons with a cross section of 140 barns, becoming long-lived radioactive 135Cs.

Caesium-134 undergoes beta decay), producing 134Ba directly and emitting on average 2.23 gamma ray photons (mean energy 0.698 MeV).[7]

Caesium-135 edit

Long-lived fission products
Nuclide t12 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
  1. ^ Decay energy is split among β, neutrino, and γ if any.
  2. ^ Per 65 thermal neutron fissions of 235U and 35 of 239Pu.
  3. ^ Has decay energy 380 keV, but its decay product 126Sb has decay energy 3.67 MeV.
  4. ^ Lower in thermal reactors because 135Xe, its predecessor, readily absorbs neutrons.

Caesium-135 is a mildly radioactive isotope of caesium with a half-life of 2.3 million years. It decays via emission of a low-energy beta particle into the stable isotope barium-135. Caesium-135 is one of the seven long-lived fission products and the only alkaline one. In most types of nuclear reprocessing, it stays with the medium-lived fission products (including 137
Cs which can only be separated from Cs-135 via isotope separation) rather than with other long-lived fission products. Except in the Molten salt reactor, where Cs-135 is created as a completely separate stream outside the fuel (after the decay of bubble-separated Xe-135). The low decay energy, lack of gamma radiation, and long half-life of 135Cs make this isotope much less hazardous than 137Cs or 134Cs.

Its precursor 135Xe has a high fission product yield (e.g. 6.3333% for 235U and thermal neutrons) but also has the highest known thermal neutron capture cross section of any nuclide. Because of this, much of the 135Xe produced in current thermal reactors (as much as >90% at steady-state full power)[8] will be converted to extremely long-lived (half-life on the order of 1021 years) 136
Xe before it can decay to 135
Cs despite the relatively short half life of 135
Xe. Little or no 135
Xe will be destroyed by neutron capture after a reactor shutdown, or in a molten salt reactor that continuously removes xenon from its fuel, a fast neutron reactor, or a nuclear weapon. The xenon pit is a phenomenon of excess neutron absorption through 135
Xe buildup in the reactor after a reduction in power or a shutdown and is often managed by letting the 135
Xe decay away to a level at which neutron flux can be safely controlled via control rods again.

A nuclear reactor will also produce much smaller amounts of 135Cs from the nonradioactive fission product 133Cs by successive neutron capture to 134Cs and then 135Cs.

The thermal neutron capture cross section and resonance integral of 135Cs are 8.3 ± 0.3 and 38.1 ± 2.6 barns respectively.[9] Disposal of 135Cs by nuclear transmutation is difficult, because of the low cross section as well as because neutron irradiation of mixed-isotope fission caesium produces more 135Cs from stable 133Cs. In addition, the intense medium-term radioactivity of 137Cs makes handling of nuclear waste difficult.[10]

    Caesium-136 edit

    Caesium-136 has a half-life of 13.16 days. It is produced both directly (at a very small yield because 136Xe is beta-stable) as a fission product and via neutron capture from long-lived 135Cs (neutron capture cross section 8.702 barns), which is a common fission product. Caesium-136 is not produced via beta decay of other fission product nuclides of mass 136 since beta decay stops at almost-stable 136Xe. It is also not produced by nuclear weapons because 135Cs is created by beta decay of original fission products only long after the nuclear explosion is over. 136Cs also captures neutrons with a cross section of 13.00 barns, becoming medium-lived radioactive 137Cs. Caesium-136 undergoes beta decay (β−), producing 136Ba directly.

    Caesium-137 edit

    Main article: Caesium-137

    Caesium-137, with a half-life of 30.17 years, is one of the two principal medium-lived fission products, along with 90Sr, which are responsible for most of the radioactivity of spent nuclear fuel after several years of cooling, up to several hundred years after use. It constitutes most of the radioactivity still left from the Chernobyl accident and is a major health concern for decontaminating land near the Fukushima nuclear power plant.[11] 137Cs beta decays to barium-137m (a short-lived nuclear isomer) then to nonradioactive barium-137. Caesium-137 does not emit gamma radiation directly, all observed radiation is due to the daughter isotope barium-137m.

    137Cs has a very low rate of neutron capture and cannot yet be feasibly disposed of in this way unless advances in neutron beam collimation (not otherwise achievable by magnetic fields), uniquely available only from within muon catalyzed fusion experiments (not in the other forms of Accelerator Transmutation of Nuclear Waste) enables production of neutrons at high enough intensity to offset and overcome these low capture rates; until then, therefore, 137Cs must simply be allowed to decay.

    137Cs has been used as a tracer in hydrologic studies, analogous to the use of 3H.

    Other isotopes of caesium edit

    The other isotopes have half-lives from a few days to fractions of a second. Almost all caesium produced from nuclear fission comes from beta decay of originally more neutron-rich fission products, passing through isotopes of iodine then isotopes of xenon. Because these elements are volatile and can diffuse through nuclear fuel or air, caesium is often created far from the original site of fission.

    References edit

    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. ^ "NIST Radionuclide Half-Life Measurements". NIST. Retrieved 2011-03-13.
    3. ^ "Standard Atomic Weights: Caesium". CIAAW. 2013.
    4. ^ 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.
    5. ^ Isoray. "Why Cesium-131".
    6. ^ Although the phase used here is more terse than in the previous definition, it still has the same meaning. This is made clear in the 9th SI Brochure, which almost immediately after the definition on p. 130 states: "The effect of this definition is that the second is equal to the duration of 9192631770 periods of the radiation corresponding to the transition between the two hyperfine levels of the unperturbed ground state of the 133Cs atom."
    7. ^ . Japan Atomic Energy Agency. Archived from the original on 2016-03-04. Retrieved 2014-10-23.
    8. ^ John L. Groh (2004). (PDF). CANTEACH project. Archived from the original (PDF) on 10 June 2011. Retrieved 14 May 2011.
    9. ^ Hatsukawa, Y.; Shinohara, N; Hata, K.; et al. (1999). "Thermal neutron cross section and resonance integral of the reaction of135Cs(n,γ)136Cs: Fundamental data for the transmutation of nuclear waste". Journal of Radioanalytical and Nuclear Chemistry. 239 (3): 455–458. doi:10.1007/BF02349050. S2CID 97425651.
    10. ^ Ohki, Shigeo; Takaki, Naoyuki (2002). "Transmutation of Cesium-135 With Fast Reactors" (PDF). Proceedings of the Seventh Information Exchange Meeting on Actinide and Fission Product Partitioning & Transmutation, Cheju, Korea.
    11. ^ Dennis (1 March 2013). "Cooling a Hot Zone". Science. 339 (6123): 1028–1029. doi:10.1126/science.339.6123.1028. PMID 23449572.
    • Isotope masses from:
      • Audi, Georges; Bersillon, Olivier; Blachot, Jean; Wapstra, Aaldert Hendrik (2003), "The NUBASE evaluation of nuclear and decay properties", Nuclear Physics A, 729: 3–128, Bibcode:2003NuPhA.729....3A, doi:10.1016/j.nuclphysa.2003.11.001
    • Isotopic compositions and standard atomic masses from:
      • de Laeter, John Robert; Böhlke, John Karl; De Bièvre, Paul; Hidaka, Hiroshi; Peiser, H. Steffen; Rosman, Kevin J. R.; Taylor, Philip D. P. (2003). "Atomic weights of the elements. Review 2000 (IUPAC Technical Report)". Pure and Applied Chemistry. 75 (6): 683–800. doi:10.1351/pac200375060683.
      • Wieser, Michael E. (2006). "Atomic weights of the elements 2005 (IUPAC Technical Report)". Pure and Applied Chemistry. 78 (11): 2051–2066. doi:10.1351/pac200678112051.
    • "News & Notices: Standard Atomic Weights Revised". International Union of Pure and Applied Chemistry. 19 October 2005.
    • Half-life, spin, and isomer data selected from the following sources.

    April 08, 2024
    isotopes, caesium, caesium, 55cs, known, isotopes, atomic, masses, these, isotopes, range, from, only, isotope, 133cs, stable, longest, lived, radioisotopes, 135cs, with, half, life, million, years, with, half, life, 1671, years, 134cs, with, half, life, 0652,. Caesium 55Cs has 41 known isotopes the atomic masses of these isotopes range from 112 to 152 Only one isotope 133Cs is stable The longest lived radioisotopes are 135Cs with a half life of 1 33 million years 137 Cs with a half life of 30 1671 years and 134Cs with a half life of 2 0652 years All other isotopes have half lives less than 2 weeks most under an hour Isotopes of caesium 55Cs Main isotopes 1 Decayabun dance half life t1 2 mode pro duct131Cs synth 9 7 d e 131Xe133Cs 100 stable134Cs synth 2 0648 y e 134Xeb 134Ba135Cs trace 1 33 106 y b 135Ba137Cs synth 30 17 y 2 b 137BaStandard atomic weight Ar Cs 132 905451 96 0 000000 06 3 132 91 0 01 abridged 4 viewtalkeditBeginning in 1945 with the commencement of nuclear testing caesium radioisotopes were released into the atmosphere where caesium is absorbed readily into solution and is returned to the surface of the Earth as a component of radioactive fallout Once caesium enters the ground water it is deposited on soil surfaces and removed from the landscape primarily by particle transport As a result the input function of these isotopes can be estimated as a function of time Contents 1 List of isotopes 2 Caesium 131 3 Caesium 133 4 Caesium 134 5 Caesium 135 6 Caesium 136 7 Caesium 137 8 Other isotopes of caesium 9 ReferencesList of isotopes editNuclide n 1 Z N Isotopic mass Da n 2 n 3 Half life Decaymode n 4 Daughterisotope n 5 n 6 Spin andparity n 7 n 8 Natural abundance mole fraction Excitation energy n 8 Normal proportion Range of variation112Cs 55 57 111 95030 33 500 100 ms p 111Xe 1 a 108I113Cs 55 58 112 94449 11 16 7 7 ms p 99 97 112Xe 5 2 b 03 113Xe114Cs 55 59 113 94145 33 0 57 2 s b 91 09 114Xe 1 b p 8 69 113Ib a 19 110Tea 018 110I115Cs 55 60 114 93591 32 1 4 8 s b 99 93 115Xe 9 2 b p 07 114I116Cs 55 61 115 93337 11 0 70 4 s b 99 67 116Xe 1 b p 279 115Ib a 049 112Te116mCs 100 60 keV 3 85 13 s b 99 48 116Xe 4 5 6b p 51 115Ib a 008 112Te117Cs 55 62 116 92867 7 8 4 6 s b 117Xe 9 2 117mCs 150 80 keV 6 5 4 s b 117Xe 3 2 118Cs 55 63 117 926559 14 14 2 s b 99 95 118Xe 2b p 042 117Ib a 0024 114Te118mCs 100 60 keV 17 3 s b 99 95 118Xe 7 b p 042 117Ib a 0024 114Te119Cs 55 64 118 922377 15 43 0 2 s b 119Xe 9 2 b a 2 10 6 115Te119mCs 50 30 keV 30 4 1 s b 119Xe 3 2 120Cs 55 65 119 920677 11 61 2 18 s b 120Xe 2 b a 2 10 5 116Teb p 7 10 6 119I120mCs 100 60 keV 57 6 s b 120Xe 7 b a 2 10 5 116Teb p 7 10 6 119I121Cs 55 66 120 917229 15 155 4 s b 121Xe 3 2 121mCs 68 5 3 keV 122 3 s b 83 121Xe 9 2 IT 17 121Cs122Cs 55 67 121 91611 3 21 18 19 s b 122Xe 1 b a 2 10 7 118Te122m1Cs 45 8 keV gt 1 ms 3 122m2Cs 140 30 keV 3 70 11 min b 122Xe 8 122m3Cs 127 0 5 keV 360 20 ms 5 123Cs 55 68 122 912996 13 5 88 3 min b 123Xe 1 2 123m1Cs 156 27 5 keV 1 64 12 s IT 123Cs 11 2 123m2Cs 231 63 X keV 114 5 ns 9 2 124Cs 55 69 123 912258 9 30 9 4 s b 124Xe 1 124mCs 462 55 17 keV 6 3 2 s IT 124Cs 7 125Cs 55 70 124 909728 8 46 7 1 min b 125Xe 1 2 125mCs 266 6 11 keV 900 30 ms 11 2 126Cs 55 71 125 909452 13 1 64 2 min b 126Xe 1 126m1Cs 273 0 7 keV gt 1 ms126m2Cs 596 1 11 keV 171 14 ms127Cs 55 72 126 907418 6 6 25 10 h b 127Xe 1 2 127mCs 452 23 21 keV 55 3 ms 11 2 128Cs 55 73 127 907749 6 3 640 14 min b 128Xe 1 129Cs 55 74 128 906064 5 32 06 6 h b 129Xe 1 2 130Cs 55 75 129 906709 9 29 21 4 min b 98 4 130Xe 1 b 1 6 130Ba130mCs 163 25 11 keV 3 46 6 min IT 99 83 130Cs 5 b 16 130Xe131Cs 55 76 130 905464 5 9 689 16 d EC 131Xe 5 2 132Cs 55 77 131 9064343 20 6 480 6 d b 98 13 132Xe 2 b 1 87 132Ba133Cs n 9 n 10 55 78 132 905451933 24 Stable 7 2 1 0000134Cs n 10 55 79 133 906718475 28 2 0652 4 y b 134Ba 4 EC 3 10 4 134Xe134mCs 138 7441 26 keV 2 912 2 h IT 134Cs 8 135Cs n 10 55 80 134 9059770 11 2 3 x106 y b 135Ba 7 2 135mCs 1632 9 15 keV 53 2 min IT 135Cs 19 2 136Cs 55 81 135 9073116 20 13 16 3 d b 136Ba 5 136mCs 518 5 keV 19 2 s b 136Ba 8 IT 136Cs137Cs n 10 55 82 136 9070895 5 30 1671 13 y b 95 137mBa 7 2 b 5 137Ba138Cs 55 83 137 911017 10 33 41 18 min b 138Ba 3 138mCs 79 9 3 keV 2 91 8 min IT 81 138Cs 6 b 19 138Ba139Cs 55 84 138 913364 3 9 27 5 min b 139Ba 7 2 140Cs 55 85 139 917282 9 63 7 3 s b 140Ba 1 141Cs 55 86 140 920046 11 24 84 16 s b 99 96 141Ba 7 2 b n 0349 140Ba142Cs 55 87 141 924299 11 1 689 11 s b 99 9 142Ba 0 b n 091 141Ba143Cs 55 88 142 927352 25 1 791 7 s b 98 38 143Ba 3 2 b n 1 62 142Ba144Cs 55 89 143 932077 28 994 4 ms b 96 8 144Ba 1 b n 3 2 143Ba144mCs 300 200 keV lt 1 s b 144Ba gt 3 IT 144Cs145Cs 55 90 144 935526 12 582 6 ms b 85 7 145Ba 3 2 b n 14 3 144Ba146Cs 55 91 145 94029 8 0 321 2 s b 85 8 146Ba 1 b n 14 2 145Ba147Cs 55 92 146 94416 6 0 235 3 s b 71 5 147Ba 3 2 b n 28 49 146Ba148Cs 55 93 147 94922 62 146 6 ms b 74 9 148Bab n 25 1 147Ba149Cs 55 94 148 95293 21 150 ms gt 50 ms b 149Ba 3 2 b n 148Ba150Cs 55 95 149 95817 32 100 ms gt 50 ms b 150Bab n 149Ba151Cs 55 96 150 96219 54 60 ms gt 50 ms b 151Ba 3 2 b n 150BaThis table header amp footer view mCs Excited nuclear isomer Uncertainty 1s is given in concise form in parentheses after the corresponding last digits Atomic mass marked value and uncertainty derived not from purely experimental data but at least partly from trends from the Mass Surface TMS Modes of decay EC Electron captureIT Isomeric transitionn Neutron emissionp Proton emission Bold italics symbol as daughter Daughter product is nearly stable Bold symbol as daughter Daughter product is stable spin value Indicates spin with weak assignment arguments a b Values marked are not purely derived from experimental data but at least partly from trends of neighboring nuclides TNN Used to define the second a b c d Fission productCaesium 131 editCaesium 131 introduced in 2004 for brachytherapy by Isoray 5 has a half life of 9 7 days and 30 4 keV energy Caesium 133 editCaesium 133 is the only stable isotope of caesium The SI base unit of time the second is defined by a specific caesium 133 transition Since 1967 the official definition of a second is The second symbol s is defined by taking the fixed numerical value of the caesium frequency DnCs the unperturbed ground state hyperfine transition frequency of the caesium 133 atom 6 to be 9192 631 770 when expressed in the unit Hz which is equal to s 1 Caesium 134 editCaesium 134 has a half life of 2 0652 years It is produced both directly at a very small yield because 134Xe is stable as a fission product and via neutron capture from nonradioactive 133Cs neutron capture cross section 29 barns which is a common fission product Caesium 134 is not produced via beta decay of other fission product nuclides of mass 134 since beta decay stops at stable 134Xe It is also not produced by nuclear weapons because 133Cs is created by beta decay of original fission products only long after the nuclear explosion is over The combined yield of 133Cs and 134Cs is given as 6 7896 The proportion between the two will change with continued neutron irradiation 134Cs also captures neutrons with a cross section of 140 barns becoming long lived radioactive 135Cs Caesium 134 undergoes beta decay b producing 134Ba directly and emitting on average 2 23 gamma ray photons mean energy 0 698 MeV 7 Caesium 135 editLong lived fission productsvte Nuclide t1 2 Yield Q a 1 bg Ma a 2 keV 99Tc 0 211 6 1385 294 b126Sn 0 230 0 1084 4050 a 3 bg79Se 0 327 0 0447 151 b135Cs 1 33 6 9110 a 4 269 b93Zr 1 53 5 4575 91 bg107Pd 6 5 1 2499 33 b129I 15 7 0 8410 194 bg Decay energy is split among b neutrino and g if any Per 65 thermal neutron fissions of 235U and 35 of 239Pu Has decay energy 380 keV but its decay product 126Sb has decay energy 3 67 MeV Lower in thermal reactors because 135Xe its predecessor readily absorbs neutrons Caesium 135 is a mildly radioactive isotope of caesium with a half life of 2 3 million years It decays via emission of a low energy beta particle into the stable isotope barium 135 Caesium 135 is one of the seven long lived fission products and the only alkaline one In most types of nuclear reprocessing it stays with the medium lived fission products including 137 Cs which can only be separated from Cs 135 via isotope separation rather than with other long lived fission products Except in the Molten salt reactor where Cs 135 is created as a completely separate stream outside the fuel after the decay of bubble separated Xe 135 The low decay energy lack of gamma radiation and long half life of 135Cs make this isotope much less hazardous than 137Cs or 134Cs Its precursor 135Xe has a high fission product yield e g 6 3333 for 235U and thermal neutrons but also has the highest known thermal neutron capture cross section of any nuclide Because of this much of the 135Xe produced in current thermal reactors as much as gt 90 at steady state full power 8 will be converted to extremely long lived half life on the order of 1021 years 136 Xe before it can decay to 135 Cs despite the relatively short half life of 135 Xe Little or no 135 Xe will be destroyed by neutron capture after a reactor shutdown or in a molten salt reactor that continuously removes xenon from its fuel a fast neutron reactor or a nuclear weapon The xenon pit is a phenomenon of excess neutron absorption through 135 Xe buildup in the reactor after a reduction in power or a shutdown and is often managed by letting the 135 Xe decay away to a level at which neutron flux can be safely controlled via control rods again A nuclear reactor will also produce much smaller amounts of 135Cs from the nonradioactive fission product 133Cs by successive neutron capture to 134Cs and then 135Cs The thermal neutron capture cross section and resonance integral of 135Cs are 8 3 0 3 and 38 1 2 6 barns respectively 9 Disposal of 135Cs by nuclear transmutation is difficult because of the low cross section as well as because neutron irradiation of mixed isotope fission caesium produces more 135Cs from stable 133Cs In addition the intense medium term radioactivity of 137Cs makes handling of nuclear waste difficult 10 ANL factsheetCaesium 136 editCaesium 136 has a half life of 13 16 days It is produced both directly at a very small yield because 136Xe is beta stable as a fission product and via neutron capture from long lived 135Cs neutron capture cross section 8 702 barns which is a common fission product Caesium 136 is not produced via beta decay of other fission product nuclides of mass 136 since beta decay stops at almost stable 136Xe It is also not produced by nuclear weapons because 135Cs is created by beta decay of original fission products only long after the nuclear explosion is over 136Cs also captures neutrons with a cross section of 13 00 barns becoming medium lived radioactive 137Cs Caesium 136 undergoes beta decay b producing 136Ba directly Caesium 137 editMain article Caesium 137 Caesium 137 with a half life of 30 17 years is one of the two principal medium lived fission products along with 90Sr which are responsible for most of the radioactivity of spent nuclear fuel after several years of cooling up to several hundred years after use It constitutes most of the radioactivity still left from the Chernobyl accident and is a major health concern for decontaminating land near the Fukushima nuclear power plant 11 137Cs beta decays to barium 137m a short lived nuclear isomer then to nonradioactive barium 137 Caesium 137 does not emit gamma radiation directly all observed radiation is due to the daughter isotope barium 137m 137Cs has a very low rate of neutron capture and cannot yet be feasibly disposed of in this way unless advances in neutron beam collimation not otherwise achievable by magnetic fields uniquely available only from within muon catalyzed fusion experiments not in the other forms of Accelerator Transmutation of Nuclear Waste enables production of neutrons at high enough intensity to offset and overcome these low capture rates until then therefore 137Cs must simply be allowed to decay 137Cs has been used as a tracer in hydrologic studies analogous to the use of 3H Other isotopes of caesium editThe other isotopes have half lives from a few days to fractions of a second Almost all caesium produced from nuclear fission comes from beta decay of originally more neutron rich fission products passing through isotopes of iodine then isotopes of xenon Because these elements are volatile and can diffuse through nuclear fuel or air caesium is often created far from the original site of fission References edit 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 NIST Radionuclide Half Life Measurements NIST Retrieved 2011 03 13 Standard Atomic Weights Caesium CIAAW 2013 Prohaska Thomas Irrgeher Johanna Benefield Jacqueline Bohlke John K Chesson Lesley A Coplen Tyler B Ding Tiping Dunn Philip J H Groning 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 Isoray Why Cesium 131 Although the phase used here is more terse than in the previous definition it still has the same meaning This is made clear in the 9th SI Brochure which almost immediately after the definition on p 130 states The effect of this definition is that the second is equal to the duration of 9192 631 770 periods of the radiation corresponding to the transition between the two hyperfine levels of the unperturbed ground state of the 133Cs atom Characteristics of Caesium 134 and Caesium 137 Japan Atomic Energy Agency Archived from the original on 2016 03 04 Retrieved 2014 10 23 John L Groh 2004 Supplement to Chapter 11 of Reactor Physics Fundamentals PDF CANTEACH project Archived from the original PDF on 10 June 2011 Retrieved 14 May 2011 Hatsukawa Y Shinohara N Hata K et al 1999 Thermal neutron cross section and resonance integral of the reaction of135Cs n g 136Cs Fundamental data for the transmutation of nuclear waste Journal of Radioanalytical and Nuclear Chemistry 239 3 455 458 doi 10 1007 BF02349050 S2CID 97425651 Ohki Shigeo Takaki Naoyuki 2002 Transmutation of Cesium 135 With Fast Reactors PDF Proceedings of the Seventh Information Exchange Meeting on Actinide and Fission Product Partitioning amp Transmutation Cheju Korea Dennis 1 March 2013 Cooling a Hot Zone Science 339 6123 1028 1029 doi 10 1126 science 339 6123 1028 PMID 23449572 Isotope masses from Audi Georges Bersillon Olivier Blachot Jean Wapstra Aaldert Hendrik 2003 The NUBASE evaluation of nuclear and decay properties Nuclear Physics A 729 3 128 Bibcode 2003NuPhA 729 3A doi 10 1016 j nuclphysa 2003 11 001 Isotopic compositions and standard atomic masses from de Laeter John Robert Bohlke John Karl De Bievre Paul Hidaka Hiroshi Peiser H Steffen Rosman Kevin J R Taylor Philip D P 2003 Atomic weights of the elements Review 2000 IUPAC Technical Report Pure and Applied Chemistry 75 6 683 800 doi 10 1351 pac200375060683 Wieser Michael E 2006 Atomic weights of the elements 2005 IUPAC Technical Report Pure and Applied Chemistry 78 11 2051 2066 doi 10 1351 pac200678112051 News amp Notices Standard Atomic Weights Revised International Union of Pure and Applied Chemistry 19 October 2005 Half life spin and isomer data selected from the following sources Audi Georges Bersillon Olivier Blachot Jean Wapstra Aaldert Hendrik 2003 The NUBASE evaluation of nuclear and decay properties Nuclear Physics A 729 3 128 Bibcode 2003NuPhA 729 3A doi 10 1016 j nuclphysa 2003 11 001 National Nuclear Data Center NuDat 2 x database Brookhaven National Laboratory Holden Norman E 2004 11 Table of the Isotopes In Lide David R ed CRC Handbook of Chemistry and Physics 85th ed Boca Raton Florida CRC Press ISBN 978 0 8493 0485 9 Retrieved from https en wikipedia org w index php title Isotopes of caesium amp oldid 1197637934 Caesium 135, wikipedia, wiki, book, books, library,

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