Meteoritic matter and materials manufacturing

• Autorzy: Karczemska A.
• Języki publikacji: EN

Abstrakty

EN

Purpose: The aim of this paper is to show the correlation between materials science and the study of extraterrestrial matter, especially meteorites. Design/methodology/approach: Raman Spectroscopy and Cathodoluminescence (CL) are two main methods used by Author to characterize meteorites. Findings: Understanding laboratory techniques for manufacturing different materials (e.g. diamond) helps to understand the processes taking place in space. Conversely, the new findings and discoveries give new insight applicable to material science and laboratory techniques. Research limitations/implications: The possibilities of creating new materials similar to those found in meteorites is shown in the paper. For instance diamond polytypes are not yet well characterized and could lead to advances in materials science. Originality/value: SEM / CL images of DaG 868 presented in this paper are shown for the first time.

Słowa kluczowe

EN

meteorities; material science; nanomaterials

PL

meteoryty; materiałoznawstwo; nanomateriały

• Wydawca: International OCSCO World Press
• Czasopismo: Archives of Materials Science and Engineering
• Rocznik: 2010
• Tom: Vol. 45, nr 2
• Strony: 114--119
• Opis fizyczny: Bibliogr. 23 poz.

Twórcy

autor

Karczemska A.

• Institute of Turbomachinery, Technical University of Lodz, ul. Wólczańska 219/223, 93-005 Łódź, Poland,

Bibliografia

• [1] L.A. Dobrzański, Significance of materials science for the future development of societies, Journal of Materials Processing Technology 175 (2006) 133-148.
• [2] J.G. Burke, Cosmic Debris, Meteorites in History, University of California Press, 1986.
• [3] A. Kotowiecki, Polskie zabytki wykonane z żelaza meteorytowego, (ang. "Polish monuments made of meteoritic iron"), Proceedings of II Seminar of Polish Meteoritical Society, Olsztyn 2003, 55-64.
• [4] T.J. McCoy, I.M. Steele, K.Keil, B.F. Leonard, M. Endress, Chladniite, A New Mineral Honoring the Father of Meteoritics, Meteoritics 28/3 (1993) 394.
• [5] R.S. Clarke, E.R.D. Scott, Tetrataenite-ordered FeNi, a new mineral in meteorites, American Mineralogist 65 (1980) 624-630.
• [6] Ch. Ma, J.R. Beckett, G.R. Rossman, Discovery of a new chromium sulfide mineral, Cr5S6, in Murchison, 73rd Annual Meteoritical Society Meeting, 2010, 5135
• [7] C. Frondel; U.B. Marvin, Lonsdaleite, a new hexagonal polymorph of diamond, Nature 214 (1967) 587-589.
• [8] F.P. Bundy, Hexagonal Diamond- A New Form of Carbon, Journal of Chemical Physics 46 (1967) 3437.
• [9] S. Mitura, K. Mitura, P. Niedzielski, P. Louda, V. Danilenko, Nanocrystalline diamond: its synthesis, properties and applications, Journal of Achievements in Materials and Manufacturing Engineering 16 (2006) 9-16.
• [10] A.T. Karczemska, Diamonds in meteorites, Raman mapping and cathodoluminescence studies, Journal of Achievments in Materials and Manufacturing Engineering 43/1 (2010) 94-110.
• [11] T. Ferroir, L.Dubrovinsky, A.El Goresy, A.Simionovici, T. Nakamura, P. Gillet, Carbon polymorphism in shocked meteorites, Evidence for new natural ultrahard phases, Earth and Planetary Science Letters 290 (2010) 150-154.
• [12] A. Karczemska, T. Jakubowski, F. Vergas, Different diamonds in meteorites DaG 868 and NWA 3140 ureilites, Journal of Achievements in Materials and Manufacturing Engineering 37/1 (2009) 292-297.
• [13] T. Jakubowski, Analiza odmian węgla w materii pozaziemskiej (Eng. "Analysis of carbon phases in extraterrestrial matter"), PhD thesis, Technical University of Lodz, Poland (in progress).
• [14] S. Bhargava, H.D. Bist, S. Sahli, M. Aslam, H.B. Tripathi, Diamond polytypes in the chemical vapor deposited diamond films, Applied Physics Letters 67(1995) 1706.
• [15] A.B. Sawaoka, Shock compressions of materials and New materials synthesis, in "Shock Compression Technology and Material Science", Edited by A.B. Sawaoka, KTK Scientific Publishers / Terra Scientific Publishing Company, Tokyo, 1992.
• [16] T. Grund, A. Bischoff, Cathodoluminescence properties of diamonds in ureilites, further evidence for a shock-induced origin, 62nd Annual Meteoritical Society Meeting, Abtract #5074.
• [17] A. Karczemska, M. Szurgot, M. Kozanecki, M. Szynkowska, V.Ralchenko, V.V. Danilenko, P. Louda, S.Mitura, Extraterrestrial, terrestrial and laboratory diamonds -differencies and similarieties, Diamond and Related Materials 17/7-10 (2008) 1179-1185.
• [18] U. Ott, Nanodiamonds in meteorites, Journal of Achievements in Materials and Manufacturing Engineering 37 (2009) 779-784.
• [19] A. Gucsik, U. Ott, E. Marosits, A. Karczemska, M. Kozanecki, M. Szurgot, Micro-Raman study of nanodiamonds from Allende meteorite, IAU SYMPOSIA; Organic Matter in Space Proceedings IAU Symposium International Astronomical Union 2008 S. Kwok & S. Sandford, eds. No. 251 (2008) 335-339.
• [20] P.Z. Budka, Meteorites as Specimens for Microgravity Research, Metallurgical Transactions Vol. 19A (1988) 1919- 1923.
• [21] M. Weller, U.G.K. Wegst, Fe-C Snoek peak in iron and stony meteorites, Metallurgical and cosmological aspects, Materials Science and Engineering A 521-522 (2009) 39-42.
• [22] J.J. Petrovic, Review - Mechanical properties of meteorites and their constituents, Journal of Materials Science 36 (2001) 1579-1583.
• [23] www.nasa.gov.