Abstract
Corrosion resistance has been examined for composites in the AlN – SiC – TiB2 ternary system. They have high corrosion resistance in air up to 1500°C because mullite and β-tialite are formed in the outer layer of scale. Their corrosion resistance substantially exceeds that of other ceramic materials because of the formation of the mullite phase on prolonged exposure (up to 200 h) to gaseous combustion products from kerosene and diesel fuel in the presence of sea salt at 900 and 1000°C. Also, AlN – SiC – TiB2 ceramics have higher bending strength than does AlN – TiB2 ceramic.
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REFERENCES
V. A. Lavrenko, D. Baxter, A. D. Panasyuk, and M. Desmaison-Brut, “High-temperature corrosion of a composite ceramic based on AlN in air and in industrial fuel combustion products. Part 1,” Poroshk. Metall., Nos. 3–4, 81-90 (2004).
V. A. Lavrenko, J. Desmaison, A. D. Panasyuk, et al., “Corrosion-resistant composites in AlN–SiC system with TiB 2 additives,” Proc. 6th Conf. Europ. Ceramic Soc., Brighton, Vol. 1 (1999), pp. 445-446.
Y. G. Gogotsi, J. Desmaison, R. A. Andrievski, et al., “AlN-based ceramics: An alternative to Si3 N4 and SiC in high-temperature application,” Key Eng. Mat., 132–136, 600-1603 (1997).
A. Tampieri and A. Bellosi, “Oxidation resistance of Al–Ti–N and Al–Ti–C composites,” J. Amer. Ceram. Soc., 75, No. 6, 1688-1690 (1992).
F. A. Costa Oliveira, D. J. Baxter, and J. Ungeheuer, “The oxidation kinetics of an yttria-doped hot pressed ilicon nitride,” Key Eng. Mat., 132–137, 1580-1583 (1997).
M. S. Jacobson, “Corrosion of silicon-based ceramics in combustion environments,” J. Amer. Ceram. Soc., 76, No. 1, 3-28 (1993).
M. A. Janney, “Mechanical properties and oxidation behavior of a hot pressed SiC–15 vol.% TiB2 composite,” Amer. Ceram. Soc. Bull., 66, 322-324 (1987).
S. V. Schneider, M. Desmaison-Brut, Y. G. Gogotsi, and J. Desmaison, “Oxidation behaviour of a hot isostatically pressed TiB2–AlN composite,” Key Eng. Mat., 113, 49-58 (1996).
V. A. Lavrenko, M. Desmaison-Brut, A. D. Panasyuk, and J. Desmaison, “Features of corrosion resistance of AlN–SiC ceramics in air up to 1600°C,” J. Eur. Ceram. Soc., 18, No. 16, 2339-2344 (1998).
Y. Xu, A. Zangvil, and R. Ruh, “Formation of SiAlON as intermediate oxidation product of SiC–AlN ceramics,” J. Amer. Ceram. Soc., 78, No. 10, 2753-2762 (1995).
“Advanced materials and powders,” Amer. Ceram. Soc. Bull., 45 (2000).
J. Desmaison and M. Desmaison-Brut, Materials Science of Carbides, Nitrides, and Borides, Kluwer Academic Publ. (1999).
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Lavrenko, V.A., Baxter, D., Panasyuk, A.D. et al. High-Temperature Corrosion of AlN-Based Composite Ceramic in Air and in Combustion Products of Commercial Fuel. Part 2. Corrosion of Ceramic Composites in the AlN – SiC – TiB2 System in Air and in Combustion Products of Kerosene and Diesel Fuel. Powder Metallurgy and Metal Ceramics 43, 295–304 (2004). https://doi.org/10.1023/B:PMMC.0000042466.23104.b9
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DOI: https://doi.org/10.1023/B:PMMC.0000042466.23104.b9