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Physical and Mineralogical Properties of Anhydrous Interplanetary Dust Particles in the Analytical Electron Microscope

Published online by Cambridge University Press:  12 April 2016

J. P. Bradley*
Affiliation:
McCrone Associates, Westmont, Illinois 60559, USA

Abstract

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The fine grained mineralogy and petrography of anhydrous “pyroxene” and “olivine” classes of chondritic interplanetary dust have been investigated by numerous electron microscopic studies. The “pyroxene” interplanetary dust particles (IDPs) are porous, unequilibrated assemblages of mineral grains, metal, glass, and carbonaceous material. They contain enstatite whiskers, FeNi carbides, and high-Mn olivines and pyroxenes, all of which are likely to be well preserved products of nebular gas reactions. Solar flare tracks are prominent in most “pyroxene” IDPs, indicating that they were not strongly heated during atmospheric entry. The “olivine” IDPs are coarse grained, equilibrated mineral assemblages that have probably experienced strong heating. Since most “olivine” IDPs do not contain tracks, it is possible that this heating occurred during atmospheric entry.

Type
Interplanetary Dust: Physical and Chemical Analysis
Copyright
Copyright © Kluwer 1991

References

[1] Schramm, L. S., Brownlee, D. E. and Wheelock, M. M. (1989) Major element composition of statospheric micrometeorites. Meteoritics. 24, 99112.Google Scholar
[2] Sandford, S. A. (1987) The collection and analysis of extraterrestrial particles. Fund. Cosmic Phys., 12. 173.Google Scholar
[3] Sandford, S. A. and Bradley, J. P. (1989) Interplanetary dust particles collected in the stratosphere: observations of atmospheric heating and constraints on their interrelationships and sources, Icarus. 82. 146166.CrossRefGoogle ScholarPubMed
[4] Bradley, J. P. and Brownlee, D. E. (1986) Cometary particles: thin-sectioning and electron beam analysis, Science. 231. 15421544.Google Scholar
[5] Germani, M. S.., Bradley, J. P. and Brownlee, D. E. (1990) Automated thin-film analyses of hydrated interplanetary dust particles in the analytical electron microscope, Earth Planet. Sci. Lett., in press.CrossRefGoogle Scholar
[6] Klock, W., Thomas, K. L., McKay, D. S. and Palme, H.(1989) Unusual olivine and pyroxene composition in interplanetary dust and unequlibrated ordinary chondrites, Nature. 339.126128.Google Scholar
[7] McKeegan, K. D., Walker, R. M. and Zinner, E. (1985) Ion microprobe isotopic measurements of individual interplanetary dust particles, Geochim. Cosmochim. Acta, 49, 19711987.CrossRefGoogle Scholar
[8] Mackinnon, I. D. R. and Rietmeijer, F. J. M (1987) Mineralogy of chondritic interplanetary dust particles, Rev. Geophys., 25(7). 15271553.Google Scholar
[9] Bregman, J. D., Campins, H., Witteborn, S. C., Wooden, D. H., Frank, D. M., Allamandolla, L. J., Cohen, M. and Tielens, A. G. G. M. (1987) Airborne and ground based spectrophotometry of comet P/Halley from 5-13 micrometers, Astron. Astrophvs., 187. 616620.Google Scholar
[10] Jessberger, E. K., Chrlstoforidis, A. and Kissel, J. (1988) Aspects of the major element composition of Halley’s dust, Nature. 332. 691695.Google Scholar
[11] Bradley, J. P. (1988) Analysis of chondritic interplanetary dust thin-sections, Geochim. Cosmochim. Acta. 52. 889900.Google Scholar
[12] Sandford, S. A. and Walker, R. M. (1985) Laboratory infrared transmission spectra of individual interplanetary dust particles from 2.5 to 25 microns. Astrophvs. J., 291. 838951.Google Scholar
[13] Christoffersen, R. and Buseck, P. R. (1986) Mineralogy of interplanetary dust particles from the “olivine” infrared class, Earth Planet. Sci. Lett., 78, 5366.Google Scholar
[14] Tomeoka, K. and Buseck, P. R. (1985) A carbonate-rich, hydrated, interplanetary dust particle: possible residue from protostellar clouds. Science 231. 15441546.Google Scholar
[15] Bradley, J. P., Brownlee, D. E. and Veblen, D. R. (1983) Pyroxene whiskers and platelets in interplanetary dust: evidence of vapor phase growth, Nature 301. 473477.Google Scholar
[16] Bradley, J. P., Brownlee, D. E. and Fraundorf, P. (1984) Discovery of nuclear tracks in interplanetary dust, Science 226. 14321434.Google Scholar
[17] Blanford, G. E., Thomas, K. L. and McKay, D. S. (1988) Microbeam analysis of four chondritic interplanetary dust particles for major elements, carbon, and oxygen, Meteoritics. 23. 113122.Google Scholar
[18] Rietmeijer, F. J. M. (1989) Ultrfine-grained mineralogy and matrix chemistry of olivine-rich chondritic interplanetary dust particles, Proc. 19th Lunar Planet. Sci. Conf.. 513521.Google Scholar
[19] Christoffersen, R. and Buseck, P. R. (1983) Epsilon carbide: a low temperature component of interplanetary dust particles, Science. 222. 13271329.Google Scholar
[20] Klock, W., Thomas, K. L., McKay, D. S. and Zolensky, M. E. (1989) Olivine compositions in anhydrous and hydrated IDPs compared to olivines in matrices of primitive meteorites (abstract), Lunar Planet. Sci. XXI. 637638.Google Scholar
[21] Bradley, J. P., Germani, M. S. and Brownlee, D. E. (1989) Automated thin-film analyses of anhydrous interplanetary dust particles in the analytical electron microscope, Earth Planet. Sci. Lett., 93, 113.Google Scholar