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Plutonium-244

January 01, 1970

Main article: Isotopes of plutonium

Plutonium-244 (244Pu) is an isotope of plutonium that has a half-life of 80 million years. This is longer than any of the other isotopes of plutonium and longer than any other actinide isotope except for the three naturally abundant ones: uranium-235 (704 million years), uranium-238 (4.468 billion years), and thorium-232 (14.05 billion years). Given the mathematics of the decay of plutonium-244, an exceedingly small amount should still be present in the Earth's composition, making plutonium a likely although unproven candidate as the shortest lived primordial element.

Plutonium-244, 244Pu
A concentrated solution of plutonium-244
General
Symbol244Pu
Namesplutonium-244, 244Pu, Pu-244
Protons (Z)94
Neutrons (N)150
Nuclide data
Natural abundanceTrace
Half-life (t1/2)8×107 years[1]
Isotope mass244.0642044[2] Da
Spin0+
Parent isotopes248Cm (α)
244Np (β)
Decay products240U
Decay modes
Decay modeDecay energy (MeV)
α (99.879%) 
SF (0.121%) 
Isotopes of plutonium
Complete table of nuclides

Natural occurrence edit

Accurate measurements, beginning in the early 1970s, appeared to detect primordial plutonium-244,[3] making it the shortest-lived primordial nuclide. The amount of 244Pu in the pre-Solar nebula (4.57×109 years ago) was estimated as 0.8% the amount of 238U.[4] As the age of the Earth is about 57 half-lives of 244Pu, the amount of plutonium-244 left should be very small; Hoffman et al. estimated its content in the rare-earth mineral bastnasite as c244 = 1.0×10−18 g/g, which corresponded to the content in the Earth crust as low as 3×10−25 g/g[3] (i.e. the total mass of plutonium-244 in Earth's crust is about 9 g). Since plutonium-244 cannot be easily produced by natural neutron capture in the low neutron activity environment of uranium ores (see below), its presence cannot plausibly be explained by any other means than creation by r-process nucleosynthesis in supernovae or neutron star mergers.

However, the detection of primordial 244Pu in 1971 is not confirmed by recent, more sensitive measurements[4] using the method of accelerator mass spectrometry. In a 2012 study, no traces of plutonium-244 in the samples of bastnasite (taken from the same mine as in the early study) were observed, so only an upper limit on the 244Pu content was obtained: c244 < 1.5×10−19 g/g, which is 370 (or less) atoms per gram of the sample, at least seven times lower than the abundance measured by Hoffman et al.[4] A 2022 study, once again using accelerator mass spectrometry, could not detect 244Pu in Bayan Obo bastnasite, finding an upper limit of < 2.1×10−20 g/g (about seven times lower than the 2012 study). Thus, the 1971 detection cannot have been a signal of primordial 244Pu. Considering the likely abundance ratio of 244Pu to 238U in the early solar system (~0.008), this upper limit is still 18 times greater than the expected present 244Pu content in the bastnasite sample (1.2×10−21 g/g).[5]

Trace amounts of 244Pu (that arrived on Earth within the last 10 million years) were found in rock from the Pacific ocean by a Japanese oil exploration company.[6]

Live interstellar plutonium-244 has been detected in meteorite dust in marine sediments, although the levels detected are much lower than would be expected from current modelling of the in-fall from the interstellar medium.[7] It is important to recall, however, that in order to be a primordial nuclide – one constituting the amalgam orbiting the Sun that ultimately coalesced into the Earth – that plutonium-244 must have comprised some of the solar nebula, rather than having been replenished by extrasolar meteoritic dust. The presence of plutonium-244 in meteoritic composition without evidence the meteor originated from the formational disc of the Solar System supports the hypothesis that 244Pu was abundant enough to have been a part of that disc, if an extrasolar meteor contained it in some other gravitationally supported system, but such a meteor cannot prove the hypothesis. Only the unlikely discovery of live 244Pu within the Earth's composition could do that.

As an extinct radionuclide edit

 
A comparison of the relative fissiogenic xenon yields found in the meteorites Pasamonte and Kapoeta with those of a laboratory sample of plutonium-244.[8]

Plutonium-244 is one of several extinct radionuclides that preceded the formation of the Solar System. Its half-life of 80 million years ensured its circulation across the solar system before its extinction,[9] and indeed, 244Pu has not yet been found in matter other than meteorites.[10] Radionuclides such as 244Pu undergo decay to produce fissiogenic (i.e., arising from fission) xenon isotopes that can then be used to time the events of the early Solar System. In fact, by analyzing data from Earth's mantle which indicates that about 30% of the existing fissiogenic xenon is attributable to 244Pu decay, the timing of Earth's formation can be inferred to have occurred nearly 50–70 million years following the formation of the Solar System.[11]

Preceding the analysis of mass spectra data obtained by analyzing samples found in meteorites, it was inferential at best to accredit 244Pu as being the nuclide responsible for the fissiogenic xenon found. However, an analysis of a laboratory sample of 244Pu compared with that of fissiogenic xenon gathered from the meteorites Pasamonte and Kapoeta produced matching spectra that immediately left little doubt as to the source of the isotopic xenon anomalies. Spectra data was further acquired for another actinide isotope, 244Cm, but such data proved contradictory and helped erase further doubts that the fission was appropriately attributed to 244Pu.[12]

Both the examination of spectra data and study of fission tracks led to several findings of plutonium-244. In Western Australia, the analysis of the mass spectrum of xenon within 4.1–4.2 billion-year-old zircons was met with findings of diverse levels of 244Pu fission.[9] Presence of 244Pu fission tracks can be established by using the initial ratio of 244Pu to 238U (Pu/U)0 at a time T0 = 4.58×109 years, when Xe formation first began in meteorites, and by considering how the ratio of Pu/U fission tracks varies over time. Examination of a whitlockite crystal within a lunar rock specimen brought over from the Apollo 14 mission established proportions of Pu/U fission tracks consistent with the (Pu/U)0 time dependence.[10]

Production edit

Unlike plutonium-238, plutonium-239, plutonium-240, plutonium-241, and plutonium-242, plutonium-244 is not produced in quantity by the nuclear fuel cycle, because further neutron capture on plutonium-242 produces plutonium-243 which has a short half-life (5 hours) and quickly beta decays to americium-243 before having much opportunity to further capture neutrons in any but very high neutron flux environments.[13] The global inventory of 244Pu is roughly 20 grams.[14] Plutonium-244 is also a minor constituent of thermonuclear fallout, with a global 244Pu/239Pu fallout ratio of (5.7 ± 1.0) × 10−5.[15]

Applications edit

Plutonium-244 is used as an internal standard for isotope dilution mass spectrometry analysis of plutonium.[14]

References edit

  1. ^ Audi, G.; Kondev, F. G.; Wang, M.; Huang, W. J.; Naimi, S. (2017). "The NUBASE2016 evaluation of nuclear properties" (PDF). Chinese Physics C. 41 (3): 030001. Bibcode:2017ChPhC..41c0001A. doi:10.1088/1674-1137/41/3/030001.
  2. ^ Wang, M.; Audi, G.; Kondev, F. G.; Huang, W. J.; Naimi, S.; Xu, X. (2017). "The AME2016 atomic mass evaluation (II). Tables, graphs, and references" (PDF). Chinese Physics C. 41 (3): 030003-1–030003-442. doi:10.1088/1674-1137/41/3/030003.
  3. ^ a b Hoffman, D. C.; Lawrence, F. O.; Mewherter, J. L.; Rourke, F. M. (1971). "Detection of Plutonium-244 in Nature". Nature. 234 (5325): 132–134. Bibcode:1971Natur.234..132H. doi:10.1038/234132a0. S2CID 4283169.
  4. ^ a b c Lachner, J.; et al. (2012). "Attempt to detect primordial 244Pu on Earth". Physical Review C. 85 (1): 015801. Bibcode:2012PhRvC..85a5801L. doi:10.1103/PhysRevC.85.015801.
  5. ^ Wu, Yang; Dai, Xiongxin; Xing, Shan; Luo, Maoyi; Christl, Marcus; Synal, Hans-Arno; Hou, Shaochun (2022). "Direct search for primordial 244Pu in Bayan Obo bastnaesite". Chinese Chemical Letters. 33 (7): 3522–3526. doi:10.1016/j.cclet.2022.03.036. Retrieved 29 January 2024.
  6. ^ Greenfieldboyce, Nell (May 13, 2021). "Freshly-made plutonium from outer space found on ocean floor". NPR.
  7. ^ Wallner, A.; Faestermann, T.; Feige, J.; Feldstein, C.; Knie, K.; Korschinek, G.; Kutschera, W.; Ofan, A.; Paul, M.; Quinto, F.; Rugel, G.; Steier, P. (2015). "Abundance of live 244Pu in deep-sea reservoirs on Earth points to rarity of actinide nucleosynthesis". Nature Communications. 6: 5956. arXiv:1509.08054. Bibcode:2015NatCo...6.5956W. doi:10.1038/ncomms6956. ISSN 2041-1723. PMC 4309418. PMID 25601158.
  8. ^ Alexander, E. C.; Lewis, R. S.; Reynolds, J. H.; Michel, M. C. (1971-01-01). "Plutonium-244: Confirmation as an Extinct Radioactivity". Science. 172 (3985): 837–840. Bibcode:1971Sci...172..837A. doi:10.1126/science.172.3985.837. JSTOR 1731927. PMID 17792940. S2CID 35389103.
  9. ^ a b Turner, Grenville; Harrison, T. Mark; Holland, Greg; Mojzsis, Stephen J.; Gilmour, Jamie (2004-01-01). "Extinct 244Pu in Ancient Zircons". Science. 306 (5693): 89–91. Bibcode:2004Sci...306...89T. doi:10.1126/science.1101014. JSTOR 3839259. PMID 15459384. S2CID 11625563.
  10. ^ a b Hutcheon, I. D.; Price, P. B. (1972-01-01). "Plutonium-244 Fission Tracks: Evidence in a Lunar Rock 3.95 Billion Years Old". Science. 176 (4037): 909–911. Bibcode:1972Sci...176..909H. doi:10.1126/science.176.4037.909. JSTOR 1733798. PMID 17829301. S2CID 25831210.
  11. ^ Kunz, Joachim; Staudacher, Thomas; Allègre, Claude J. (1998-01-01). "Plutonium-Fission Xenon Found in Earth's Mantle". Science. 280 (5365): 877–880. Bibcode:1998Sci...280..877K. doi:10.1126/science.280.5365.877. JSTOR 2896480. PMID 9572726.
  12. ^ Alexander, E. C.; Lewis, R. S.; Reynolds, J. H.; Michel, M. C. (1971-01-01). "Plutonium-244: Confirmation as an Extinct Radioactivity". Science. 172 (3985): 837–840. Bibcode:1971Sci...172..837A. doi:10.1126/science.172.3985.837. JSTOR 1731927. PMID 17792940. S2CID 35389103.
  13. ^ Armstrong, Christopher R.; Brant, Heather A.; Nuessle, Patterson R.; Hall, Gregory; Cadieux, James R. (22 February 2016). "Anthropogenic plutonium-244 in the environment: Insights into plutonium's longest-lived isotope". Scientific Reports. 6 (1): 21512. Bibcode:2016NatSR...621512A. doi:10.1038/srep21512. eISSN 2045-2322. PMC 4761908. PMID 26898531.
  14. ^ a b Patton, Bradley D; Alexander, Charles W; Benker, Dennis; Collins, Emory D; Romano, Catherine E; Wham, Robert M (January 2011). "Preserving Plutonium-244 as a National Asset". osti.gov. OSTI 1024694. Retrieved 2022-10-02.
  15. ^ Steier, P.; Hrnecek, E.; Priller, A.; Quinto, F.; Srncik, M.; Wallner, A.; Wallner, G.; Winkler, S. (January 2013). "AMS of the Minor Plutonium Isotopes". Nuclear Instruments and Methods in Physics Research Section B: Beam Interactions with Materials and Atoms. 294 (2): 160–164. Bibcode:2013NIMPB.294..160S. doi:10.1016/j.nimb.2012.06.017. ISSN 0168-583X. PMC 3617651. PMID 23565016.

January 01, 1970
plutonium, main, article, isotopes, plutonium, 244pu, isotope, plutonium, that, half, life, million, years, this, longer, than, other, isotopes, plutonium, longer, than, other, actinide, isotope, except, three, naturally, abundant, ones, uranium, million, year. Main article Isotopes of plutonium Plutonium 244 244Pu is an isotope of plutonium that has a half life of 80 million years This is longer than any of the other isotopes of plutonium and longer than any other actinide isotope except for the three naturally abundant ones uranium 235 704 million years uranium 238 4 468 billion years and thorium 232 14 05 billion years Given the mathematics of the decay of plutonium 244 an exceedingly small amount should still be present in the Earth s composition making plutonium a likely although unproven candidate as the shortest lived primordial element Plutonium 244 244PuA concentrated solution of plutonium 244GeneralSymbol244PuNamesplutonium 244 244Pu Pu 244Protons Z 94Neutrons N 150Nuclide dataNatural abundanceTraceHalf life t1 2 8 107 years 1 Isotope mass244 0642044 2 DaSpin0 Parent isotopes248Cm a 244Np b Decay products240UDecay modesDecay modeDecay energy MeV a 99 879 SF 0 121 Isotopes of plutonium Complete table of nuclides Contents 1 Natural occurrence 1 1 As an extinct radionuclide 2 Production 3 Applications 4 ReferencesNatural occurrence editAccurate measurements beginning in the early 1970s appeared to detect primordial plutonium 244 3 making it the shortest lived primordial nuclide The amount of 244Pu in the pre Solar nebula 4 57 109 years ago was estimated as 0 8 the amount of 238U 4 As the age of the Earth is about 57 half lives of 244Pu the amount of plutonium 244 left should be very small Hoffman et al estimated its content in the rare earth mineral bastnasite as c244 1 0 10 18 g g which corresponded to the content in the Earth crust as low as 3 10 25 g g 3 i e the total mass of plutonium 244 in Earth s crust is about 9 g Since plutonium 244 cannot be easily produced by natural neutron capture in the low neutron activity environment of uranium ores see below its presence cannot plausibly be explained by any other means than creation by r process nucleosynthesis in supernovae or neutron star mergers However the detection of primordial 244Pu in 1971 is not confirmed by recent more sensitive measurements 4 using the method of accelerator mass spectrometry In a 2012 study no traces of plutonium 244 in the samples of bastnasite taken from the same mine as in the early study were observed so only an upper limit on the 244Pu content was obtained c244 lt 1 5 10 19 g g which is 370 or less atoms per gram of the sample at least seven times lower than the abundance measured by Hoffman et al 4 A 2022 study once again using accelerator mass spectrometry could not detect 244Pu in Bayan Obo bastnasite finding an upper limit of lt 2 1 10 20 g g about seven times lower than the 2012 study Thus the 1971 detection cannot have been a signal of primordial 244Pu Considering the likely abundance ratio of 244Pu to 238U in the early solar system 0 008 this upper limit is still 18 times greater than the expected present 244Pu content in the bastnasite sample 1 2 10 21 g g 5 Trace amounts of 244Pu that arrived on Earth within the last 10 million years were found in rock from the Pacific ocean by a Japanese oil exploration company 6 Live interstellar plutonium 244 has been detected in meteorite dust in marine sediments although the levels detected are much lower than would be expected from current modelling of the in fall from the interstellar medium 7 It is important to recall however that in order to be a primordial nuclide one constituting the amalgam orbiting the Sun that ultimately coalesced into the Earth that plutonium 244 must have comprised some of the solar nebula rather than having been replenished by extrasolar meteoritic dust The presence of plutonium 244 in meteoritic composition without evidence the meteor originated from the formational disc of the Solar System supports the hypothesis that 244Pu was abundant enough to have been a part of that disc if an extrasolar meteor contained it in some other gravitationally supported system but such a meteor cannot prove the hypothesis Only the unlikely discovery of live 244Pu within the Earth s composition could do that As an extinct radionuclide edit nbsp A comparison of the relative fissiogenic xenon yields found in the meteorites Pasamonte and Kapoeta with those of a laboratory sample of plutonium 244 8 Plutonium 244 is one of several extinct radionuclides that preceded the formation of the Solar System Its half life of 80 million years ensured its circulation across the solar system before its extinction 9 and indeed 244Pu has not yet been found in matter other than meteorites 10 Radionuclides such as 244Pu undergo decay to produce fissiogenic i e arising from fission xenon isotopes that can then be used to time the events of the early Solar System In fact by analyzing data from Earth s mantle which indicates that about 30 of the existing fissiogenic xenon is attributable to 244Pu decay the timing of Earth s formation can be inferred to have occurred nearly 50 70 million years following the formation of the Solar System 11 Preceding the analysis of mass spectra data obtained by analyzing samples found in meteorites it was inferential at best to accredit 244Pu as being the nuclide responsible for the fissiogenic xenon found However an analysis of a laboratory sample of 244Pu compared with that of fissiogenic xenon gathered from the meteorites Pasamonte and Kapoeta produced matching spectra that immediately left little doubt as to the source of the isotopic xenon anomalies Spectra data was further acquired for another actinide isotope 244Cm but such data proved contradictory and helped erase further doubts that the fission was appropriately attributed to 244Pu 12 Both the examination of spectra data and study of fission tracks led to several findings of plutonium 244 In Western Australia the analysis of the mass spectrum of xenon within 4 1 4 2 billion year old zircons was met with findings of diverse levels of 244Pu fission 9 Presence of 244Pu fission tracks can be established by using the initial ratio of 244Pu to 238U Pu U 0 at a time T0 4 58 109 years when Xe formation first began in meteorites and by considering how the ratio of Pu U fission tracks varies over time Examination of a whitlockite crystal within a lunar rock specimen brought over from the Apollo 14 mission established proportions of Pu U fission tracks consistent with the Pu U 0 time dependence 10 Production editUnlike plutonium 238 plutonium 239 plutonium 240 plutonium 241 and plutonium 242 plutonium 244 is not produced in quantity by the nuclear fuel cycle because further neutron capture on plutonium 242 produces plutonium 243 which has a short half life 5 hours and quickly beta decays to americium 243 before having much opportunity to further capture neutrons in any but very high neutron flux environments 13 The global inventory of 244Pu is roughly 20 grams 14 Plutonium 244 is also a minor constituent of thermonuclear fallout with a global 244Pu 239Pu fallout ratio of 5 7 1 0 10 5 15 Applications editPlutonium 244 is used as an internal standard for isotope dilution mass spectrometry analysis of plutonium 14 References edit Audi G Kondev F G Wang M Huang W J Naimi S 2017 The NUBASE2016 evaluation of nuclear properties PDF Chinese Physics C 41 3 030001 Bibcode 2017ChPhC 41c0001A doi 10 1088 1674 1137 41 3 030001 Wang M Audi G Kondev F G Huang W J Naimi S Xu X 2017 The AME2016 atomic mass evaluation II Tables graphs and references PDF Chinese Physics C 41 3 030003 1 030003 442 doi 10 1088 1674 1137 41 3 030003 a b Hoffman D C Lawrence F O Mewherter J L Rourke F M 1971 Detection of Plutonium 244 in Nature Nature 234 5325 132 134 Bibcode 1971Natur 234 132H doi 10 1038 234132a0 S2CID 4283169 a b c Lachner J et al 2012 Attempt to detect primordial 244Pu on Earth Physical Review C 85 1 015801 Bibcode 2012PhRvC 85a5801L doi 10 1103 PhysRevC 85 015801 Wu Yang Dai Xiongxin Xing Shan Luo Maoyi Christl Marcus Synal Hans Arno Hou Shaochun 2022 Direct search for primordial 244Pu in Bayan Obo bastnaesite Chinese Chemical Letters 33 7 3522 3526 doi 10 1016 j cclet 2022 03 036 Retrieved 29 January 2024 Greenfieldboyce Nell May 13 2021 Freshly made plutonium from outer space found on ocean floor NPR Wallner A Faestermann T Feige J Feldstein C Knie K Korschinek G Kutschera W Ofan A Paul M Quinto F Rugel G Steier P 2015 Abundance of live 244Pu in deep sea reservoirs on Earth points to rarity of actinide nucleosynthesis Nature Communications 6 5956 arXiv 1509 08054 Bibcode 2015NatCo 6 5956W doi 10 1038 ncomms6956 ISSN 2041 1723 PMC 4309418 PMID 25601158 Alexander E C Lewis R S Reynolds J H Michel M C 1971 01 01 Plutonium 244 Confirmation as an Extinct Radioactivity Science 172 3985 837 840 Bibcode 1971Sci 172 837A doi 10 1126 science 172 3985 837 JSTOR 1731927 PMID 17792940 S2CID 35389103 a b Turner Grenville Harrison T Mark Holland Greg Mojzsis Stephen J Gilmour Jamie 2004 01 01 Extinct 244Pu in Ancient Zircons Science 306 5693 89 91 Bibcode 2004Sci 306 89T doi 10 1126 science 1101014 JSTOR 3839259 PMID 15459384 S2CID 11625563 a b Hutcheon I D Price P B 1972 01 01 Plutonium 244 Fission Tracks Evidence in a Lunar Rock 3 95 Billion Years Old Science 176 4037 909 911 Bibcode 1972Sci 176 909H doi 10 1126 science 176 4037 909 JSTOR 1733798 PMID 17829301 S2CID 25831210 Kunz Joachim Staudacher Thomas Allegre Claude J 1998 01 01 Plutonium Fission Xenon Found in Earth s Mantle Science 280 5365 877 880 Bibcode 1998Sci 280 877K doi 10 1126 science 280 5365 877 JSTOR 2896480 PMID 9572726 Alexander E C Lewis R S Reynolds J H Michel M C 1971 01 01 Plutonium 244 Confirmation as an Extinct Radioactivity Science 172 3985 837 840 Bibcode 1971Sci 172 837A doi 10 1126 science 172 3985 837 JSTOR 1731927 PMID 17792940 S2CID 35389103 Armstrong Christopher R Brant Heather A Nuessle Patterson R Hall Gregory Cadieux James R 22 February 2016 Anthropogenic plutonium 244 in the environment Insights into plutonium s longest lived isotope Scientific Reports 6 1 21512 Bibcode 2016NatSR 621512A doi 10 1038 srep21512 eISSN 2045 2322 PMC 4761908 PMID 26898531 a b Patton Bradley D Alexander Charles W Benker Dennis Collins Emory D Romano Catherine E Wham Robert M January 2011 Preserving Plutonium 244 as a National Asset osti gov OSTI 1024694 Retrieved 2022 10 02 Steier P Hrnecek E Priller A Quinto F Srncik M Wallner A Wallner G Winkler S January 2013 AMS of the Minor Plutonium Isotopes Nuclear Instruments and Methods in Physics Research Section B Beam Interactions with Materials and Atoms 294 2 160 164 Bibcode 2013NIMPB 294 160S doi 10 1016 j nimb 2012 06 017 ISSN 0168 583X PMC 3617651 PMID 23565016 Retrieved from https en wikipedia org w index php title Plutonium 244 amp oldid 1215397840, wikipedia, wiki, book, books, library,

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