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Aluminium-26

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(Redirected from Aluminum-26g)
Aluminium-26, 26Al
General
Symbol26Al
Namesaluminium-26, 26Al, Al-26
Protons (Z)13
Neutrons (N)13
Nuclide data
Natural abundancetrace (cosmogenic)
Half-life (t1/2)7.17×105 years
Spin5+
Decay modes
Decay modeDecay energy (MeV)
β+4.00414
ε4.00414
Isotopes of aluminium
Complete table of nuclides

Aluminium-26 (26Al, Al-26) is a radioactive isotope of the chemical element aluminium, decaying by either positron emission or electron capture to stable magnesium-26. The half-life of 26Al is 717,000 years. This is far too short for the isotope to survive as a primordial nuclide, but a small amount of it is produced by collisions of atoms with cosmic ray protons.[1]

Decay of aluminium-26 also produces gamma rays and x-rays.[2] The x-rays and Auger electrons are emitted by the excited atomic shell of the daughter 26Mg after the electron capture which typically leaves a hole in one of the lower sub-shells.

Because it is radioactive, it is typically stored behind at least 5 centimetres (2 in) of lead. Contact with 26Al may result in radiological contamination. This necessitates special tools for transfer, use, and storage.[3]

Dating

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Aluminium-26 can be used to calculate the terrestrial age of meteorites and comets. It is produced in significant quantities in extraterrestrial objects via spallation of silicon alongside beryllium-10, though after falling to Earth, 26Al production ceases and its abundance relative to other cosmogenic nuclides decreases. Absence of aluminium-26 sources on Earth is a consequence of Earth's atmosphere obstructing silicon on the surface and low troposphere from interaction with cosmic rays. Consequently, the amount of 26Al in the sample can be used to calculate the date the meteorite fell to Earth.[1]

Occurrence in the interstellar medium

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The distribution of 26Al in Milky Way

The gamma ray emission from the decay of aluminium-26 at 1809 keV was the first observed gamma emission from the Galactic Center. The observation was made by the HEAO-3 satellite in 1984.[4][5]

26Al is mainly produced in supernovae ejecting many radioactive nuclides in the interstellar medium. The isotope is believed to be crucial for the evolution of planetary objects, providing enough heat to melt and differentiate accreting planetesimals. This is known to have happened during the early history of the asteroids 1 Ceres and 4 Vesta.[6][7][8] 26Al has been hypothesized to have played a role in the unusual shape of Saturn's moon Iapetus. Iapetus is noticeably flattened and oblate, indicating that it rotated significantly faster early in its history, with a rotation period possibly as short as 17 hours. Heating from 26Al could have provided enough heat in Iapetus to allow it to conform to this rapid rotation period, before the moon cooled and became too rigid to relax back into hydrostatic equilibrium.[9]

The presence of aluminium monofluoride molecule as the 26Al isotopologue in CK Vulpeculae, which is an unknown type of nova, constitutes the first solid evidence of an extrasolar radioactive molecule.[10]

Aluminium-26 in the early Solar System

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In considering the known melting of small planetary bodies in the early Solar System, H. C. Urey noted that the naturally occurring long-lived radioactive nuclei (40K, 238U, 235U and 232Th) were insufficient heat sources. He proposed that the heat sources from short lived nuclei from newly formed stars might be the source and identified 26Al as the most likely choice.[11][12] This proposal was made well before the general problems of stellar nucleosynthesis of the nuclei were known or understood. This conjecture was based on the discovery of 26Al in a Mg target by Simanton, Rightmire, Long & Kohman.[13]

Their search was undertaken because hitherto there was no known radioactive isotope of Al that might be useful as a tracer. Theoretical considerations suggested that a state of 26Al should exist. The life time of 26Al was not then known; it was only estimated between 104 and 106 years. The search for 26Al took place over many years, long after the discovery of the extinct radionuclide 129I which showed that contribution from stellar sources formed ~108 years before the Sun had contributed[how?] to the Solar System mix. The asteroidal materials that provide meteorite samples were long known to be from the early Solar System.[14]

The Allende meteorite, which fell in 1969, contained abundant calcium–aluminium-rich inclusions (CAIs). These are very refractory materials and were interpreted as being condensates from a hot solar nebula.[15][16] then discovered that the oxygen in these objects was enhanced in 16O by ~5% while the 17O/18O was the same as terrestrial. This clearly showed a large effect in an abundant element that might be nuclear, possibly from a stellar source. These objects were then found to contain strontium with very low 87Sr/86Sr indicating that they were a few million years older than previously analyzed meteoritic material and that this type of material would merit a search for 26Al.[17] 26Al is only present today in the Solar System materials as the result of cosmic reactions on unshielded materials at an extremely[quantify] low level. Thus, any original 26Al in the early Solar System is now extinct.

To establish the presence of 26Al in very ancient materials requires demonstrating that samples must contain clear excesses of 26Mg/24Mg which correlates with the ratio of 27Al/24Mg. The stable 27Al is then a surrogate for extinct 26Al. The different 27Al/24Mg ratios are coupled to different chemical phases in a sample and are the result of normal chemical separation processes associated with the growth of the crystals in the CAIs. Clear evidence of the presence of 26Al at an abundance ratio of 5×10−5 was shown by Lee et al.[18][19] The value (26Al/27Al ~ 5×10−5) has now been generally established as the high value in early Solar System samples and has been generally used as a refined time scale chronometer for the early Solar System. Lower values imply a more recent time of formation. If this 26Al is the result of pre-solar stellar sources, then this implies a close connection in time between the formation of the Solar System and the production in some exploding star. Many materials which had been presumed to be very early (e.g. chondrules) appear to have formed a few million years later.[20] Other extinct radioactive nuclei, which clearly had a stellar origin, were then being discovered.[21]

That 26Al was present in the interstellar medium as a major gamma ray source was not explored until the development of the high-energy astronomical observatory program. The HEAO-3 spacecraft with cooled Ge detectors allowed the clear detection of 1.808 MeV gamma lines from the central part of the galaxy from a distributed 26Al source.[4] This represents a quasi steady state inventory corresponding to two solar masses of 26Al was distributed.[clarification needed] This discovery was greatly expanded on by observations from the Compton Gamma Ray Observatory using the COMPTEL telescope in the galaxy.[22] Subsequently, the 60Fe lines (1.173 MeV and 1.333 Mev) were also detected showing the relative rates of decays from 60Fe to 26Al to be 60Fe/26Al ~ 0.11.[23]

In pursuit of the carriers of 22Ne in the sludge produced by chemical destruction of some meteorites, carrier grains in micron size, acid-resistant ultra-refractory materials (e.g. C, SiC) were found by E. Anders & the Chicago group. The carrier grains were clearly shown to be circumstellar condensates from earlier stars and often contained very large enhancements in 26Mg/24Mg from the decay of 26Al with 26Al/27Al sometimes approaching 0.2.[24][25] These studies on micron scale grains were possible as a result of the development of surface ion mass spectrometry at high mass resolution with a focused beam developed by G. Slodzian & R. Castaing with the CAMECA Co.

The production of 26Al by cosmic ray interactions in unshielded materials is used as a monitor of the time of exposure to cosmic rays. The amounts are far below the initial inventory that is found in very early solar system debris.

Metastable states

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Before 1954, the half-life of aluminium-26m was measured to be 6.3 seconds.[26] After it was theorized that this could be the half-life of a metastable state (isomer) of aluminium-26, the ground state was produced by bombardment of magnesium-26 and magnesium-25 with deuterons in the cyclotron of the University of Pittsburgh.[13] The first half-life was determined to be in the range of 106 years. The Fermi beta decay half-life of the aluminium-26 metastable state is of interest in the experimental testing of two components of the Standard Model, namely, the conserved-vector-current hypothesis and the required unitarity of the Cabibbo–Kobayashi–Maskawa matrix.[27] The decay is superallowed. The 2011 measurement of the half life of 26mAl is 6346.54 ± 0.46(statistical) ± 0.60(system) milliseconds.[28]

See also

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References

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  1. ^ a b Barbuzano, Javier (2020). "Radioactive Aluminum Sheds Light On Solar System History". Sky & Telescope. p. 9.
  2. ^ "Nuclide Safety Data Sheet Aluminum-26" (PDF). www.nchps.org.
  3. ^ "Nuclide Safety Data Sheet Aluminum-26" (PDF). National Health& Physics Society. Retrieved 2009-04-13.
  4. ^ a b Mahoney, W. A.; Ling, J. C.; Wheaton, W. A.; Jacobson, A. S. (1984). "HEAO 3 discovery of Al-26 in the interstellar medium". The Astrophysical Journal. 286: 578. Bibcode:1984ApJ...286..578M. doi:10.1086/162632.
  5. ^ Kohman, T. P. (1997). "Aluminum-26: A nuclide for all seasons". Journal of Radioanalytical and Nuclear Chemistry. 219 (2): 165–176. Bibcode:1997JRNC..219..165K. doi:10.1007/BF02038496. S2CID 96683475.
  6. ^ Moskovitz, Nicholas; Gaidos, Eric (2011). "Differentiation of planetesimals and the thermal consequences of melt migration". Meteoritics & Planetary Science. 46 (6): 903–918. arXiv:1101.4165. Bibcode:2011M&PS...46..903M. doi:10.1111/j.1945-5100.2011.01201.x. S2CID 45803132.
  7. ^ Zolotov, M. Yu. (2009). "On the Composition and Differentiation of Ceres". Icarus. 204 (1): 183–193. Bibcode:2009Icar..204..183Z. doi:10.1016/j.icarus.2009.06.011.
  8. ^ Zuber, Maria T.; McSween, Harry Y.; Binzel, Richard P.; Elkins-Tanton, Linda T.; Konopliv, Alexander S.; Pieters, Carle M.; Smith, David E. (2011). "Origin, Internal Structure and Evolution of 4 Vesta". Space Science Reviews. 163 (1–4): 77–93. Bibcode:2011SSRv..163...77Z. doi:10.1007/s11214-011-9806-8. S2CID 7658841.
  9. ^ Kerr, Richard A. (2006-01-06). "How Saturn's Icy Moons Get a (Geologic) Life". Science. 311 (5757): 29. doi:10.1126/science.311.5757.29. PMID 16400121. S2CID 28074320.
  10. ^ Kamiński, T; Menten, K. M; Tylenda, R; Karakas, A; Belloche, A; Patel, N. A (2017). "Organic molecules, ions, and rare isotopologues in the remnant of the stellar-merger candidate, CK Vulpeculae (Nova 1670)". Astronomy & Astrophysics. 607: A78. arXiv:1708.02261. Bibcode:2017A&A...607A..78K. doi:10.1051/0004-6361/201731287. S2CID 62829732.
  11. ^ Urey, H.C. (1955). "The Cosmic Abundances of Potassium, Uranium, and Thorium and the Heat Balances of the Earth, the Moon, and Mars". PNAS. 41 (3): 127–144. Bibcode:1955PNAS...41..127U. doi:10.1073/pnas.41.3.127. PMC 528039. PMID 16589631.
  12. ^ Urey, H.C. (1956). "The Cosmic Abundances of Potassium, Uranium, and Thorium and the Heat Balances of the Earth, the Moon, and Mars". PNAS. 42 (12): 889–891. Bibcode:1956PNAS...42..889U. doi:10.1073/pnas.42.12.889. PMC 528364. PMID 16589968.
  13. ^ a b Simanton, James R.; Rightmire, Robert A.; Long, Alton L.; Kohman, Truman P. (1954). "Long-Lived Radioactive Aluminum 26". Physical Review. 96 (6): 1711–1712. Bibcode:1954PhRv...96.1711S. doi:10.1103/PhysRev.96.1711.
  14. ^ Black, D.C.; Pepin, R.O. (11 July 1969). "Trapped neon in meteorites — II". Earth and Planetary Science Letters. 6 (5): 395. Bibcode:1969E&PSL...6..395B. doi:10.1016/0012-821X(69)90190-3.
  15. ^ Grossman, L. (June 1972). "Condensation in the primitive solar nebula". Geochimica et Cosmochimica Acta. 36 (5): 597. Bibcode:1972GeCoA..36..597G. doi:10.1016/0016-7037(72)90078-6.
  16. ^ Clayton, Robert N.; Grossman, L.; Mayeda, Toshiko K. (2 November 1973). "A component of primitive nuclear composition in carbonaceous meteorites". Science. 182 (4111): 485–8. Bibcode:1973Sci...182..485C. doi:10.1126/science.182.4111.485. PMID 17832468. S2CID 22386977.
  17. ^ Gray (1973). "The identification of early condensates from the solar nebula". Icarus. 20 (2): 213. Bibcode:1973Icar...20..213G. doi:10.1016/0019-1035(73)90052-3.
  18. ^ Lee, Typhoon; Papanastassiou, D. A; Wasserburg, G. J (1976). "Demonstration of 26Mg excess in Allende and evidence for 26 Al". Geophysical Research Letters. 3 (1): 41. Bibcode:1976GeoRL...3...41L. doi:10.1029/GL003i001p00041.
  19. ^ Lee, T.; Papanastassiou, D. A.; Wasserburg, G. J. (1977). "Aluminum-26 in the early solar system - Fossil or fuel". Astrophysical Journal Letters. 211: 107. Bibcode:1977ApJ...211L.107L. doi:10.1086/182351. ISSN 2041-8205.
  20. ^ Hutcheon, I. D.; Hutchison, R. (1989). "Evidence from the Semarkona ordinary chondrite for 26Al heating of small planets". Nature. 337 (6204): 238–241. Bibcode:1989Natur.337..238H. doi:10.1038/337238a0.
  21. ^ Kelly; Wasserburg (December 1978). "Evidence for the existence of 107Pd in the early solar system". Geophysical Research Letters. 5 (12): 1079. Bibcode:1978GeoRL...5.1079K. doi:10.1029/GL005i012p01079. (t1/2=6.5x10^6 yr)
  22. ^ Diehl, R.; Dupraz, C.; Bennett, K.; et al. (1995). "COMPTEL observations of Galactic 26Al emission". Astronomy & Astrophysics. 298: 445. Bibcode:1995A&A...298..445D.
  23. ^ Harris, M. J.; Knödlseder, J.; Jean, P.; Cisana, E.; Diehl, R.; Lichti, G. G.; Roques, J.-P.; Schanne, S.; Weidenspointner, G. (29 March 2005). "Detection of γ-ray lines from interstellar 60Fe by the high resolution spectrometer SPI". Astronomy & Astrophysics. 433 (3): L49. arXiv:astro-ph/0502219. Bibcode:2005A&A...433L..49H. doi:10.1051/0004-6361:200500093. S2CID 5358047.
  24. ^ Anders, E.; Zinner, E. (September 1993). "Interstellar grains in primitive meteorites: Diamond, silicon carbide, and graphite". Meteoritics. 28 (4): 490–514. Bibcode:1993Metic..28..490A. doi:10.1111/j.1945-5100.1993.tb00274.x.
  25. ^ Zinner, E. (2014). "Presolar grains". In H. D. Holland; K. K. Turekian; A. M. Davis (eds.). Treatise on Geochemistry, Second Edition. Vol. 1. pp. 181–213. doi:10.1016/B978-0-08-095975-7.00101-7. ISBN 9780080959757.
  26. ^ Hollander, J. M.; Perlman, I.; Seaborg, G. T. (1953). "Table of Isotopes". Reviews of Modern Physics. 25 (2): 469–651. Bibcode:1953RvMP...25..469H. doi:10.1103/RevModPhys.25.469.
  27. ^ Scott, Rebecca J; o'Keefe, Graeme J; Thompson, Maxwell N; Rassool, Roger P (2011). "Precise measurement of the half-life of the Fermi β-decay of 26Al(m)". Physical Review C. 84 (2): 024611. Bibcode:2011PhRvC..84b4611S. doi:10.1103/PhysRevC.84.024611.
  28. ^ Finlay, P; Ettenauer, S; Ball, G. C; Leslie, J. R; Svensson, C. E; Andreoiu, C; Austin, R. A. E; Bandyopadhyay, D; Cross, D. S; Demand, G; Djongolov, M; Garrett, P. E; Green, K. L; Grinyer, G. F; Hackman, G; Leach, K. G; Pearson, C. J; Phillips, A. A; Sumithrarachchi, C. S; Triambak, S; Williams, S. J (2011). "High-Precision Half-Life Measurement for the Superallowed β+ Emitter 26Al(m)". Physical Review Letters. 106 (3): 032501. doi:10.1103/PhysRevLett.106.032501. PMID 21405268.