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The Barea, Dyarrl Island, and Emery meteorites, and a review of the mesosiderites

Published online by Cambridge University Press:  05 July 2018

Brian Mason  and
E. Jarosewich
Brian Mason
Affiliation:
Smithsonian Institution, Washington, D.C., U.S.A.
E. Jarosewich
Affiliation:
Smithsonian Institution, Washington, D.C., U.S.A.
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Summary

Barea and Emery are typical mesosiderites, whereas Dyarrl Island is unique in having the lowest metal content and the highest FeO/(FeO + MgO) ratio of any meteorite of this class. Average pyroxene compositions have been determined for the individual mesosiderites, and show a sequential increase in FeSiO3 content, ranging from a mean of 21 mole % for Veramin to 45 mole % for Dyarrl Island. Steinbach may possibly be classed as a mesosiderite, since its mineralogy is identical except for the absence of plagioclase. Dalgaranga and Mt. Padbury may be a paired fall. The chemical and mineralogical composition of the silicate material of the mesosiderites is similar to, but not identical with the howardites; the overall range of composition is greater in the mesosiderites.

Type
Research Article
Information
Mineralogical Magazine , Volume 39 , Issue 302 , June 1973 , pp. 204 - 215
Copyright
Copyright © The Mineralogical Society of Great Britain and Ireland 1973

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References

Alderman, (A. R.), 1940. A siderolite from Pinnaroo, South Australia. Trans. Roy. Soc. South Australia, 64, 109–13.Google Scholar
Chou, (Chen-Lin), 1972. Distribution of nickel, gallium, germanium, and iridium in metal and silicate portions of H-group chondrites. Trans. Amer. Geophys. Union, 53, 437.Google Scholar
Clarke, (R. S.), ed. 1972. The Meteoritical Bulletin, no. 51. Meteoritics, 7, 215–32.Google Scholar
Fuchs, (L. H.), 1969. The phosphate mineralogy of meteorites, Meteorite Research (ed. P. M. Mill- man), D. Riedel Publ. Co. 683-95.CrossRefGoogle Scholar
Hillebrand, (W. F.), Lundell, (G. E. F.), Bright, (H. A.), and Hoffman, (J. I.), 1953. Applied Inorganic Analysis (2nd edn). Wiley, New York.Google Scholar
Hodge-Smith, (T.), 1933. A meteorite from New Ireland. Australian Mus. Mag., 5, 56.Google Scholar
Jarosewich, (E.), 1966. Chemical analyses of ten stony meteorites. Geochimica Acta, 30, 1261–5.CrossRefGoogle Scholar
Jarosewich, (E.) and Mason, (B.), 1969. Chemical analyses with notes on one mesosiderite and seven chondrites. Ibid. 33, 411-16.CrossRefGoogle Scholar
[Kirova, (O. A.) and Dyakonova, (M. I.)] , (Meteoritika), 27, 167-77.Google Scholar
Lacroix, (A.), 1924. Sur un nouveau type de fer meteorique trouve dans le desert de l’Adrar in Mauritanie. Compt. Rend. Acad. Sci. Paris, 179, 309–13.Google Scholar
Mason, (B.) and Wme, (H. B.), 1966. The composition of the Barratta, Carraweena, Kapoeta, Moores-fort, and Ngawi meteorites. Amer. Mus. Novitates, 2273, 1–25.Google Scholar
McCarthy, (T. S.) and Ahrens, (L. H.), 1971. The composition of stony meteorites (X). The Ca/Al ratio in mesosiderites. Earth Planet Sci. Letters, 11, 35–6.CrossRefGoogle Scholar
Nininger, (H. H.) and Huss, (G. L.), i960. The unique meteorite crater at Dalgaranga, Western Australia. Min. Mag., 32, 619–39.Google Scholar
Peck, (L. C.), 1964. Systematic analysis of silicates. U.S. Geol. Surv. Bull., 1170.Google Scholar
Powell, (B. N.), 1969. Petrology and chemistry of mesosiderites. I. Textures and composition of nickel-iron. Geochimica Acta, 33, 789–810.CrossRefGoogle Scholar
Powell, (B. N.) 1971. Petrology and chemistry of mesosiderites. II. Silicate textures and compositions and metal-silicate relationships. Ibid. 35, 534.Google Scholar
Prior, (G. T.), 1918. On the mesosiderite-grahamite group of meteorites: with analyses of Vaca Muerta, Hainholz, Simondium, and Powder Mill Creek. Min. Mag., 18, 151–72.Google Scholar
Prior, (G. T.) 1920. The classification of meteorites. Ibid. 19, 5163.Google Scholar
Rose, (G.), 1B63. Beschreibung und Eintheilung der Meteoriten auf Grund der Sammlung im minera- logischen Museum zu Berlin. Physik. Abhandl. Akad. Wiss Berlin, 23-161.Google Scholar
Simpson, (E. S.), 1938. Some new and little-known meteorites found in Western Australia. Min. Mag. 25, 157-71.Google Scholar
Tschermak, (G.), 1885. Die mikroskopische Beschaffenheit der Meteoriten.Facsimile reprint, with English translation, published 1964 in Smithsonian Contributions to Astrophysics, 4, 137-239.Google Scholar
Wiik, (H. B.), 1969. On regular discontinuities in the composition of meteorites. Soc. Sci. Fennica, Comm. Phys. Math., 34, 135–45.Google Scholar