Gas-rich meteorites are meteorites with high levels of primordial gases, such as helium, neon, argon, krypton, xenon and sometimes other elements.[1] Though these gases are present "in virtually all meteorites,"[2] the Fayetteville meteorite has ~2,000,000 x10−8 ccSTP/g helium,[3] or ~2% helium by volume equivalent. In comparison, background level is a few ppm.
The identification of gas-rich meteorites is based on the presence of light noble gases in large amounts, at levels which cannot be explained without involving an additional component over and above the well-known noble gas components that are present in all meteorites.[3]
History
William Ramsay was the first to report helium in an iron meteorite, in 1895- not long after its first Earth sample, instead of via Solar observation.[4]
The use of decay products to date meteorites was suggested by Bauer in 1947,[5] and explicitly published by Gerling and Pavlova in 1951.[6] However, this soon resulted in wildly varying ages; it was realized excess helium (including helium-3, rare on Earth) was generated by radiation, too.[7]
The first explicit publication of a gas-rich meteorite was Staroe Pesyanoe (often shortened to Pesyanoe), by Gerling and Levskii in 1956. In family with the later Fayetteville, Pesyanoe's helium level is ~1 million x10−8 ccSTP/g.[8]
Reynolds' publication of a "general Xe anomaly",[9] including 129I decay products and more, touched off the subfield of xenology,[10][11][12][13] continuing to today.[14][15]
The first publication of presolar grains in the 1980s[16] was precipitated by workers searching for noble gases;[17] PSGs were not simply checked via their gas contents.[18][19]
Lines of inquiry
As unreactive components, they are tracers of processes throughout and predating the Solar System:
Material age can be determined by relative exposure to direct solar and cosmic radiation (by cosmic ray tracks), and indirect creation of resultant nuclides. This includes Ar-Ar dating, I-Xe dating, and U to its various decay products including helium.[20][21][22]
The parent body of a meteorite can be traced in part via comparison of trace elements.[23][24][25] That meteorites are fragments of asteroids, and conditions on such asteroids, were partially deduced from gas evidence.[26][27][28][29]
This includes meteorite pairing, the re-association of meteorites which had split before recovery.[30][31]
Meteorite, parent, and Solar System histories are indicated by tracer elements,[32][33][34] including thermometry, a record of material temperature.[35]
- Presolar activity.[36][19]
- A supernova thought to have preceded the Solar System.[37][36]
- The history of the Sun.[38][39][40][41] This record extends to billion-year timescales,[42][43] back to "very early in the life of the Sun".[44]
- The history of cosmic ray fluence. Meteorites do not show significant variation of cosmic rays over time.[45]
The Lost City Meteor was tracked, allowing an orbit determination back to the asteroid belt. Measurement of relatively short-half-life isotopes in the subsequent Lost City Meteorite then indicate radiation levels in that region of the Solar System.[46]
Gas study
The field of meteoritic gases follows progress in analytical methods.[47]
The first analyses were basic laboratory chemistry, such as acid dissolution. Various acids were necessary, due to mixtures of various soluble and insoluble minerals. Stepped etching gave higher levels of resolution and discrimination.
Pyrolysis was used, such as on highly acid resistant minerals. These two methods were alternately lauded and derided as "burning the haystack to find the needle."[48][49][50]
Meteoritical studies have tracked the progress of mass spectrometry,[51] a continual and rapid progression[52][53] comparable to or greater than Moore's Law.[54]
Meteorites
[58] This meteoritics-related list is incomplete; you can help by expanding it.
Name | Classification | Date | Provenance | Ref |
---|---|---|---|---|
Pantar | H5 | 1938 | Fall | ,[59][60] |
Fayetteville | H4 | 1934 | Fall | ,[60][61][62] |
Gladstone | H4 | 1936 | Find | [63][64] |
Noblesville | H4 | 1991 | Fall | [65][66] |
Tsukuba | H5-6 | 1996 | Fall | [67][68] |
Weston | H4 | 1807 | Fall | ,[59][60][69] |
Willard | H3 | 1934 | Find | [70][64] |
Elm Creek | H4 | 1906 | Find | [60] |
Leighton | H5 | 1907 | Fall | [60][71] |
Djermaia | H | 1961 | Fall | [60] |
Acfer 111 | -H3 | 1990 | Find | [72][73] |
Ghubara | L5 | 1954 | Find | [74][75] |
St. Mesmin | L5 | 1866 | Fall | [76][77][69] |
(Staroe) Pesyanoe | Aubrite | 1933 | Fall | [78][62][79] |
Khor Temiki | Aubrite | 1932 | Fall | ,[80][69] |
Bustee | Aubrite | 1852 | Fall | [81][82] |
Jodzie | Howardite | 1877 | Fall | [83] |
Kapoeta | Howardite | 1942 | Fall | ,[84] 3,[85] |
South Oman | -EH | 1958 | Find | [86][87] |
Interplanetary dust, like c-chondrites and enstatites, contain hosts for these gases and often measurable gas contents.[88][89][90] So too do a fraction of micrometeorites.[91][92][93]
Gas
Gas components were first named by descriptors, then letter codes;[94][95] the letter taxonomy "has become increasingly complicated and confusing with time."[96][97]
By Element and Isotope
Primordial/trapped
Solar wind/solar flare
Cosmic ray/spallogenic
3He 83Kr 126Xe[7][99][100][101]
Radiogenic/fissile
By Component
Planetary
"Planetary" gases (P, Q, P1) are depleted in light elements (He, Ne) compared to solar abundances (see below), or conversely, enriched in Kr, Xe.[103][104][105] This name originally implied an origin, the gas blend observed in terrestrial planets. Scientists wished to stop implying this,[106][105] but the habit was retained.[107][105]
Solar, subsolar
This gas component corresponds to the solar wind.[108][105] Solar flare gas can be distinguished by its greater depth,[109] and a slightly variant composition.[110] "Subsolar" is intermediary between solar and planetary.[111]
E
"Exotic" neon- aberrant 20Ne/22Ne values.[112][113]
H
"Heavy" isotopes of xenon,[114][97] primarily r-process isotopes, plus p-process. Thus, sometimes seen as "HL," anomalous heavy and light isotopes.
G
"Giant", after asymptotic giant branch (while A and B had been taken[112][113]); contains their s-process isotopes.[115]
See also
References
- ↑ Suess, H. E.; Wänke, H.; Wlotzka, F. (1964-05-01). "On the origin of gas-rich meteorites". Geochimica et Cosmochimica Acta. 28 (5): 595–607. Bibcode:1964GeCoA..28..595S. doi:10.1016/0016-7037(64)90080-8.
- ↑ Swindle, T. (1988). Trapped noble gases in meteorites. Tucson: University of Arizona Press. p. 535. in Meteorites and the early solar system, J. F. Kerridge & M. S. Matthews Eds.
- 1 2 Goswami, J.; Lal, D.; Wilkening, L. (1983). "Gas-Rich meteorites: Probes for particle environment and dynamical processes in the inner solar system". Space Science Reviews. 37 (1–2): 111–59. Bibcode:1984SSRv...37..111G. doi:10.1007/BF00213959. S2CID 121335431.
- ↑ Ramsay, W. (4 Jul 1895). "Argon and Helium in Meteoritic Iron". Nature. 52 (1340): 224–25. Bibcode:1895Natur..52..224R. doi:10.1038/052224a0.
- ↑ Bauer, C. (15 August 1947). "Production of Helium in Meteorites by Cosmic Radiation". Physical Review. 72 (4): 354. Bibcode:1947PhRv...72..354B. doi:10.1103/PhysRev.72.354.
- ↑ Gerling, E.; Pavlova, T. (1951). "Determination of the geological age of two stony meteorites by the argon method". Doklady Akademii Nauk SSSR. 77: 85–97.
- 1 2 Paneth, F.; Reasbeck, P.; Mayne, K. (Aug 1953). "Production by cosmic rays of helium-3 in meteorites". Nature. 172 (4370): 200–01. Bibcode:1953Natur.172..200P. doi:10.1038/172200a0. PMID 13087152. S2CID 4149773.
- ↑ Gerling, E.; Levskii, L. (1956). "On the origin of the rare gases in stony meteorites". Doklady Akademii Nauk SSSR. 110: 750.
- ↑ Reynolds, J. (15 May 1963). "Xenology". Journal of Geophysical Research. 68 (10): 2939–56. Bibcode:1963JGR....68.2939R. doi:10.1029/JZ068i010p02939.
- ↑ Fleischer, R.; Price, P.; Walker, R. (1975). "6.5 Study of Nucleosynthesis and the Early History of the Solar System by Extinct Isotopes". Nuclear Tracks in Solids: Principles and Applications. University of California Press. ISBN 9780520026650.
- ↑ Hintenberger, H. (Jul 1972). "Xenon in irdischer und in extraterrestrischer Materie (Xenologie)". Naturwissenschaften. 59 (7): 285–91. Bibcode:1972NW.....59..285H. doi:10.1007/BF00593352. S2CID 33097923.
- ↑ Kuroda, P. (Jan 1976). "Xenology: The enigma of xenon in carbonaceous chondrite". Geochemical Journal. 10 (3): 121–36. Bibcode:1976GeocJ..10..121K. doi:10.2343/geochemj.10.121.
- ↑ Staudacher, T. Allègre C. (Oct 1982). "Terrestrial xenology". Earth and Planetary Science Letters. 60 (3): 389–406. Bibcode:1982E&PSL..60..389S. doi:10.1016/0012-821X(82)90075-9.
- ↑ Tolstikhin, I.; Marty, B.; Porcelli, D.; Hofmann, A. (Jul 2014). "Evolution of volatile species in the earth's mantle: A view from xenology". Geochimica et Cosmochimica Acta. 136: 229–46. Bibcode:2014GeCoA.136..229T. doi:10.1016/j.gca.2013.08.034.
- ↑ Diehl, R.; Hartmann, D.; Prantzos, N. (2018). "2.2.4 Extinct Radioactivity and Immediate Pre-Solar Nucleosynthesis". Astrophysics with Radioactive Isotopes (2nd ed.). Springer. ISBN 978-3319919294.
- ↑ Lewis, R.; Ming, T.; Wacker, J.; Anders, E.; Steel, E. (Mar 1987). "Interstellar diamonds in meteorites". Nature. 326 (6109): 160–62. Bibcode:1987Natur.326..160L. doi:10.1038/326160a0. S2CID 4324489.
- ↑ Zinner, E.; Ming, T.; Anders, E. (24 Dec 1987). "Large isotopic anomalies of Si, C, N and noble gases in interstellar silicon carbide from the Murray meteorite". Nature. 330 (6150): 730–32. Bibcode:1987Natur.330..730Z. doi:10.1038/330730a0. S2CID 4306270.
- ↑ Ott, U. (Jul 1993). "Interstellar grains in meteorites". Nature. 364 (6432): 25–33. Bibcode:1993Natur.364...25O. doi:10.1038/364025a0. S2CID 4271084.
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- ↑ Martin, G. (1953). "Recent studies of iron meteorites. IV The origin of meteoritic helium and the age of meteorites". Geochimica et Cosmochimica Acta. 3 (6): 288–309. Bibcode:1953GeCoA...3..288M. doi:10.1016/0016-7037(53)90037-4.
- ↑ Gerling, E.; Pavlova, T. (1951). "Determination of the geological age of two stony meteorites by the argon method". Doklady Akademii Nauk SSSR. 77: 85–97.
- ↑ Wasserburg, G.; Hayden, R. (1955). "Age of meteorites by the Ar40-K40 method" (PDF). Physical Review. 97 (1): 86–87. Bibcode:1955PhRv...97...86W. doi:10.1103/PhysRev.97.86.
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- ↑ Obase, T.; Nakashima, D. (12 Jul 2019). "Past Solar Wind Fluxes at the Locations of Gas-Rich Meteorite Parent Bodies Based on Noble Gas Studies: Implications to the Past Heliocentric Distances". Proc. 82nd Annual Meeting of the Meteoritical Society. 82 (2157): 6270. Bibcode:2019LPICo2157.6270O.
{{cite journal}}
: CS1 maint: multiple names: authors list (link) - ↑ Schultz, L.; Kruse, H. "He, Ne, and Ar in meteorites. A detailed compilation". Meteoritics. 24: 155–72. doi:10.1111/j.1945-5100.1989.tb00958.x.
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- ↑ Pepin, R.; Eddy, J.; Merrill, R., eds. (1980). The Ancient Sun: Fossil record in the Earth, Moon and Meteorites. New York: Pergamon Press. ISBN 978-0080263243.
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- ↑ Heber, V.; Baur, H.; Wieler, R. (Nov 2001). Solar Krypton and Xenon in gas-rich meteorites: New insights into a unique archive of solar wind. American Institute of Physics. p. 387. ISBN 0-7354-0042-3. in Solar and Galactic Composition: A Joint SOHO/ACE Workshop, R. F. Wimmer-Schweingruber, ed.
- ↑ Pepin, R. Palma R. Schlutter D. (Feb 2010). "Noble gases in interplanetary dust particles, II: Excess helium-3 in cluster particles and modeling constraints on interplanetary dust particle exposures to cosmic-ray irradiation". Meteoritics & Planetary Science. 36 (11): 1515–34. doi:10.1111/j.1945-5100.2001.tb01843.x.
- ↑ Wieler, R.; Pedroni, A.; Leya, I. (4 Feb 2010). "Cosmogenic neon in mineral separates from Kapoeta: No evidence for an irradiation of its parent body regolith by an early active Sun". Meteoritics & Planetary Science. 35 (2): 251–57. doi:10.1111/j.1945-5100.2000.tb01774.x.
- ↑ Smith, T.; Cook, D.; Merchel, S.; Pavetich, S.; Rugel, G.; Scharf, A.; Leya, I. (Dec 2019). "The constancy of galactic cosmic rays as recorded by cosmogenic nuclides in iron meteorites". Meteoritics & Planetary Science. 54 (12): 2951–76. Bibcode:2019M&PS...54.2951S. doi:10.1111/maps.13417. hdl:20.500.11850/382444.
- ↑ Begemann, F. (10 Jul 1972). "Argon 37/argon 39 activity ratios in meteorites and the spatial constancy of the cosmic radiation". Journal of Geophysical Research. 77 (20): 3650–59. Bibcode:1972JGR....77.3650B. doi:10.1029/JB077i020p03650.
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- ↑ Manavi. "Stardust from meteorites". ANSMET, The Antarctic Search for Meteorites. Case Western Reserve University. Retrieved 15 Dec 2019.
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- ↑ Merrill, G. (Jun 1909). "The composition of stony meteorites compared with that of terrestrial igneous rocks, and considered with reference to their efficacy in world-making". American Journal of Science. 27 (162): 469–74. Bibcode:1909AmJS...27..469M. doi:10.2475/ajs.s4-27.162.469.
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- ↑ Baur, H. (1999). "A noble gas mass spectrometer compressor source with two orders of magnitude improvement in sensitivity". EOS, Trans. Am. Geophys. Union. 46: F1118.
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- ↑ Takaoka, N.; Nagao, K.; Miura, Y. (1991). Noble Gas Study of Unique Meteorite Yamato-74063 by Laser Extraction. NIPR (Japan). p. 92. in 16th Symposium on Antarctic Meteorites, Jun 5-7 1991
- ↑ Osawa, T.; Nagao, K.; Nakamura, T.; Takaoka, N. (2000). "Noble gas measurement in individual micrometeorites using laser gas-extraction system". Antarctic Meteorite Research. 13: 322–41. Bibcode:2000AMR....13..322O.
- ↑ Avice, G.; Bekaert, D.; Chennaoui Aoudjehane, H.; Marty, B. (9 Feb 2018). "Noble gases and nitrogen in Tissint reveal the composition of the Mars atmosphere". Geochemical Perspectives Letters. 6: 11–16. doi:10.7185/geochemlet.1802.
- ↑ Padia, J.; Rao, M. (Jun 1989). "Neon isotope studies of Fayetteville and Kapoeta meteorites and clues to ancient solar activity". Geochimica et Cosmochimica Acta. 53 (6): 1461–67. Bibcode:1989GeCoA..53.1461P. doi:10.1016/0016-7037(89)90078-1.
- 1 2 Eugster, O. (2003). "Cosmic-ray Exposure Ages of Meteorites and Lunar Rocks and Their Significance". Geochemistry. 63 (1): 3–30. Bibcode:2003ChEG...63....3E. doi:10.1078/0009-2819-00021.
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- ↑ Padia, J., Rao, M. "Neon isotope studies of Fayetteville and Kapoeta meteorites and clues to ancient solar activity ". (Jun 1989). Geochimica et Cosmochimica Acta. 53(6): 1461-67.
- 1 2 Mueller, O., Zahringer, J. "Chemische Unterschiede bei urdelgashaltigen Steinmeteoriten". (1966). Earth Planet. Sci. Lett. (1): 25.
- ↑ Miura, Y.; Nagao, K. (1992). "Noble gases and 81Kr-Kr exposure ages of non-Antarctic ordinary chondrites: An attempt to measure terrestrial ages of Antarctic meteorites" (PDF). In Yanai, K. (ed.). Proceedings of the NIPR Symposium, No. 5. Sixteenth Symposium on Antarctic Meteorites, held June 5–7, 1991, at the National Institute of Polar Research, Tokyo. National Institute of Polar Research (Japan). pp. 298–309. Bibcode:1992AMR.....5..298M. Retrieved 2020-02-04.
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- ↑ Lipschutz, M.; Wolf, S.; Vogt, S. (Sep 1993). "Consortium study of the unusual H chondrite regolith breccia, Noblesville". Meteoritics. 28 (4): 528–537. Bibcode:1993Metic..28..528L. doi:10.1111/j.1945-5100.1993.tb00276.x.
- ↑ Murer, C.; Baur, H.; Signer, P.; Wieler, R. (Mar 1997). "Helium, neon, and argon abundances in the solar wind: In vacuo etching of meteoritic iron-nickel". Geochimica et Cosmochimica Acta. 61 (6): 1303–14. Bibcode:1997GeCoA..61.1303M. doi:10.1016/S0016-7037(97)83772-6.
- ↑ Jabeen, I.; Kusakabe, M.; Nagao, K.; Nakamura, T. (1998). "Tsukuba meteorite: H chondrite, or a new parent body?". Meteoritics & Planetary Science. 33: 77.
- ↑ Nakashima, D.; Nakamura, T.; Sekiya, M.; Takaoka, N. (2002). "Cosmic-ray exposure age and heliocentric distance of the parent body of H chondrites Y75029 and Tsukuba". Antarctic Meteorite Research. 15: 97–113.
- 1 2 3 Schultz, L., Kruse, H. "Helium, Neon, and Argon in Meteorites: A Data Compilation". Max-Planck-Institut fur Chemie, Mainz. (1983).
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- ↑ Gerling, E.; Levskii, L. (1956). "On the origin of the rare gases in stony meteorites". Doklady Akademii Nauk SSSR. 110: 750.
- ↑ Murty, S.; Marti, K. (Sep 1990). "Search for solar-type nitrogen in the gas-rich Pesyanoe meteorite". Meteoritics. 25 (3): 227–30. Bibcode:1990Metic..25..227M. doi:10.1111/j.1945-5100.1990.tb01000.x.
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- ↑ Poupeau, G.; Kirsten, T.; Steinbrunn, F.; Storzer, D. (Dec 1974). "The records of solar wind and solar flares in aubrites". Earth and Planetary Science Letters. 24 (2): 229–41. Bibcode:1974E&PSL..24..229P. doi:10.1016/0012-821X(74)90101-0.
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