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Combustion Synthesis of Composite Materials

Published online by Cambridge University Press:  15 February 2011

J. J. Moore*
Affiliation:
Department of Metallurgical and Materials Engineering, Colorado School of Mines, Golden, CO 80401
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Abstract

This paper discusses the of application of combustion synthesis of ceramic and ceramic-metal composites. Several model exothermic combustion synthesis reactions are being used to investigate the effect of reaction parameters, eg. stoichiometry, green density, combustion environment and mode, particle size, physical properties of reactants and products, on the stability and control of the synthesis reaction, product morphology and properties and performance.

Type
Research Article
Copyright
Copyright © Materials Research Society 1993

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References

1. Munir, Z. A., Ceramic Bulletin, 67(2) (1988) 342.Google Scholar
2. Holt, J. B., Material Bulletin, Oct -Nov (1987) 60.Google Scholar
3. Feng, H.J., Moore, J.J., Wirth, D.G., “The Combustion Synthesis of Ceramic-Metal Composites: The TiC-Al2O3-Al System”, accepted for publication in Met. Trans.Google Scholar
4. Feng, H.J., Moore, J.J., Wirth, D.G., “Combustion Synthesis of TiB2-Al2O3-Al Composite Materials” to be published in proceedings of the Symposium on Developments in Ceramic and Metal Matrix Composites, TMS Annual Meeting, San Diego, March 1–5, 1992. Pub by TMS, pp 219–239.Google Scholar
5. Feng, H.J., Moore, J.J., Wirth, D.G., “Combustion Synthesis of Ceramic Metal Composite Materials: The ZrB2-A2O5-Al System” to be published in proceedings of the International Symposium on Self-Propagating High Temperature Synthesis (SHS), Alma-Ata, USSR, Sept 23–28, 1991; pub by Soviet Academy of Sciences.Google Scholar
6. Feng, H.J., Moore, J.J., Wirth, D.G., “The Combustion Synthesis of B4C-A120 3-AI Composite Materials” to be published in proceedings of the Symposium on Synthesis and Processing of Ceramics: Scientific Issues MRS Fall Meeting, Boston Dec 2–6 1991; pub by MRS.Google Scholar
7. Filonenko, A. K. Vershinnikov, V. I., Combustion Explosion Shock Waves, 11 (1975) 301.CrossRefGoogle Scholar
8. Perkins, N., Readey, D.W., Moore, J.J., Synergistic Effects of Coupled Combustion Synthesis and Vapor Phase Transport in the Synthesis of Advanced Materials”, ASM Conference, San Francisco, CA, 1992.Google Scholar
9. Perkins, N., Readey, D.W., Moore, J.J., presentation at the Annual Meeting of American Ceramic Society, Minneapolis, April 12–16, 1992.Google Scholar
10. Eriksson, Gunner, “Thermodynamic Studies of High Temperature Equilibria, III. SOLGAS, A computer Program for Calculating the Composition and Heat Condition of an Equilibrium Mixture”, Acta Chemica Scandinavia, 25 (1971), pp. 26512658.Google Scholar
11. Readey, D.W., Lee, J., and Quadir, T., 1984. Vapor Transport and Sintering of Ceramics, Sintering and Homogeneous Catalysis. Ed. by Kuczynski, G.C., Miller, Albert E., and Sargent, Gordon A., New York: Plenum.Google Scholar