Paper Titles
Preface
The Study of Ignition Parameters for Energy Efficient Processing of High Temperature Non-Oxide Ceramics by the Micropyretic Synthesis Route
p.1
Self-Propagating High-Temperature Synthesis (SHS) of Advanced High-Temperature Ceramics
p.15
Densification and High Temperature Deformation in Oxide Ceramics
p.39
Mechanical, Thermal and Oxidation Behaviour of Zirconium Diboride Based Ultra-High Temperature Ceramic Composites
p.55
Processing of Refractory Metal Borides, Carbides and Nitrides
p.69
Development of High Temperature TiB2-Based Ceramics
p.89
Boron Rich Boron Carbide: An Emerging High Performance Material
p.125
High Temperature Use Fractal Insulation Materials Utilizing Nano Particles
p.143

Self-Propagating High-Temperature Synthesis (SHS) of Advanced High-Temperature Ceramics

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Abstract:

Over the years, the self-propagating high-temperature synthesis (SHS) has become an interesting research field to prepare a large numbers of advanced materials. Recently, the demands for high temperature advanced ceramics have further intensified the research on SHS for efficient material preparation. Several reviews, large numbers of papers and patents on various aspects of material production by SHS are available in literature. These are scattered and it is desirable to have a comprehensive review of the literatures that not only helps the researchers but also guide the beginners in this area. In this paper, we have emphasized our contributions on synthesis of various advanced high temperature ceramics, the borides, carbides, oxides and their composites by SHS processes. Several advantages and disadvantages of the SHS technique for advanced high temperature (HT) materials are highlighted. The preparation of nano-sized powders and finegrained in-situ high temperature ceramic composites through SHS is specially mentioned.

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Periodical:

Key Engineering Materials (Volume 395)

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15-38

DOI:

https://doi.org/10.4028/www.scientific.net/KEM.395.15

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Online since:

October 2008

Authors:

Suman K. Mishra, Lokesh C. Pathak

Keywords:

Composite, Diboride, High Temperature Ceramic, Self-Propagation High-Temperature Synthesis (SHS), SHS Dynamic Compaction, Sintering

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References

[1] Munir Z.A., Am. Ceram. Soc. Bull. Vol. 67 (1988), p.342.

Google Scholar

[2] Novikov N.P., Borovinskaya J.P. and Merzhanov A.G. In Combustion processes in chemical technology and metallurgy, Ed. A.G. Merzhanov, Vol. 174 (1975), Chernogolovka.

Google Scholar

[3] Bowen C.R. and Derby,B. Br. Ceram. Trans. Vol. 96 (1997), p.25.

Google Scholar

[4] A. G. Merzhanov, Self Propagating High Temperature Synthesis: Twenty Years of Research and Findings, VCH, New York, (1990), pp.1-53.

Google Scholar

[5] P. Mossino, Ceram. Intl. Vol. 30 (2004), pp.311-332.

Google Scholar

[6] Z. A. Munir and U. A. Tamburini, Mater. Sci. Rep. Vol. 3 (1989), pp.277-365.

Google Scholar

[7] R. Pampuch, Advanced HT Ceramic Materials via Solid Combustion, J. Euro. Ceram. Soc. Vol. 19 (1999), pp.2395-2404.

DOI: 10.1016/s0955-2219(99)00113-2

Google Scholar

[8] J. Subrahmanyam and M. Vijayakumar, J. Mater. Sci. Vol. 27 (1992), pp.6249-6273.

Google Scholar

[9] R. W. Rice, J. Mater. Sci. Vol. 26 (1991), pp.6533-6541.

Google Scholar

[10] J. J. Moore and H. J. Feng, Prog. Mater. Sci. Vol. 39 (1995), pp.243-277.

Google Scholar

[11] I. G. Cano, I. P. Borovinskaya, M. A. Rodriguez and V. V. Grachev, J. Am. Ceram. Soc. Vol. 85 (2002), pp.2209-2211.

Google Scholar

[12] Y. Li, J. Zhao and J. Han, Mater. Res. Bull. Vol. 37 (2002), pp.583-592.

Google Scholar

[13] S. K. Roy and A. Biswas, J. Mater. Sci. Lett. Vol. 13 (1994), 371-373.

Google Scholar

[14] R. W. Rice, G. Y. Richardson, J. M. Kunetz, T. Schroeter and W. J. Mcdonough, Ceram. Engg. Sci and Proc. Vol. 7 (1986), pp.737-751.

Google Scholar

[15] L. J. Kecskes and A. Niiler, J. Am. Ceram. Soc. Vol. 72 (1989), pp.655-661.

Google Scholar

[16] J. B. Holt and Z. A. Munir, J. Mater. Sci. Vol. 21 (1986), pp.251-259.

Google Scholar

[17] J. F. Crider, Ceram. Engg. Sci. and Proc. Vol. 3 (1982), pp.519-531.

Google Scholar

[18] A. Biswas, S. K. Roy, J. B. Singh, K. Madangopal and N. Prabhu, J. Mater. Sci. Vol. 37 (2002), pp.1189-1195.

Google Scholar

[19] C. L. Yeh, H. C. Chung, Ceram. Intl. Vol. 30 (2004), pp.705-714.

Google Scholar

[20] Y. Choi, M. E. Mullins, K. Vijayatilleka and J. K. Lee, Met. Trans. Vol. 23A (1992), pp.2387-2392.

Google Scholar

[21] K. A. Philpot, Z. A. Munir and J. B. Holt, J. Mater. Sci. Vol. 22 (1987), pp.159-169.

Google Scholar

[22] L. C. Pathak, D. Bandopadhyay, S. Srikanth, S. K. Das and P. Ramachandrarao, J. Am. Ceram. Soc. Vol. 84 (2001), pp.915-920.

Google Scholar

[23] D. Bandopadhyay, L. C. Pathak, I. Mukherjee, S. K. Das, R. Ganguli and P. Ramachandrarao, Mater. Res. Bull. Vol. 32 (1997), pp.75-82.

Google Scholar

[24] H.C. Yi and J.J. Moore. J. Mater. Sci. Vol. 24 (1989), pp.3456-3462.

Google Scholar

[25] A. W. Weimer, W. G. Moore, R. P. Roach, J. E. Hitt and R. S. Dixit, J. Am. Ceram. Soc. Vol. 75 (1992), pp.2509-2514.

Google Scholar

[26] F. Monteverde, A. Bellosi, Luigi Scatteia, Mater. Sci. Eng. A, (2007), in press.

Google Scholar

[27] L. M. Sheppard, Adv. Mater. Proc., Vol. 2(2), (1986) pp.25-32.

Google Scholar

[28] A. Makino, C. K. Law, J. Am. Ceram. Soc. Vol. 77(3), (1984) pp.778-786.

Google Scholar

[29] J. Kecskes,T. Kottke, J. Am. Ceram. Soc. Vol. 73 (1990) p.1274.

Google Scholar

[30] Y.M. Cheng and A. M. Gadalla, Mater. Manufacturing Proc. Vol. 11(4), (1996) pp.575-587.

Google Scholar

[31] M. Einarsud, E. Hagen, G. Petersen and T. Granede, J. Am. Ceram. Soc., Vol. 80(12), (1997) p.3013.

Google Scholar

[32] Duabdesselam and Z. A. Munir, J. Mater. Sci. Vol. 22, (1987) p.1799.

Google Scholar

[33] K. B. Shim, M. J. Edirisinghe and B. Ralph, Brit. Ceram. Trans., Vol. 95 (1) (1996) pp.15-22.

Google Scholar

[34] P. Ramachandrarao P. and S. K. Mishra, Refractories & Furnaces- New options and new values, (2000) pp.31-39, Allied Pubi.

Google Scholar

[35] S. K. Mishra, S. Das and L.C. Pathak, Mater. Sci & Eng. Vol. A 364 (1-2) (2004) pp.249-255.

Google Scholar

[36] R. M. German, Metal Powder Industries Federation, Princeton, New Jercy, (1994) p.145.

Google Scholar

[37] S. K. Mishra (Pathak), S. Das, S. K. Das and P. Ramachandrarao, J. Mater. Res. Vol. 15 (2000) p.2499.

Google Scholar

[38] S. K. Mishra (Pathak), S.K. Das, A .K. Ray and P. Ramchandrarao, J. Am. Ceram. Soc. Vol. 85 (2002), pp.2846-2848.

Google Scholar

[39] S.K. Mishra, S. Das and P. Ramachandrarao, J. Mater. Res. Vol. 17(11), (2002) p.2809.

Google Scholar

[40] S.K. Mishra and S. K. Das, Mater. Lett. Vol. 59 (2005), pp.3467-3470.

Google Scholar

[41] A. Khanra, L.C. Pathak, S.K. Mishra, M.M. Godkhindi, Mater. Lett. Vol. 58(5), (2004) pp.733-738.

Google Scholar

[42] A. Khanra, L.C. Pathak and M.M. Godkhindi, J. Am. Cearm. Soc. Vol. 88, (2005) pp.1619-1621.

Google Scholar

[43] A. Khanra, L.C. Pathak, M.M. Godkhindi, Mater. Sci. Engg. A Vol. 454-455, (2007) pp.281-287.

Google Scholar

[44] J. Liu an and P. D. Ownby, J. Am. Ceramic society, Vol. 74(1), (1991) pp.241-43.

Google Scholar

[45] S. Postrach and J. Potschke, J. Euro. Ceram. Soc., Vol. 20 (2000) p.1459.

Google Scholar

[46] V. Sundaram, K. V. Logan and R. F. Speyer, J. Mater. Res., Vol. 12 (1997), pp.1681-1684.

Google Scholar

[47] S. P. Ray, Metall. Trans. A, Vol. 23A (1992) p.2381.

Google Scholar

[48] H. J. Feng and J. J. Moore, Met. Mater. Trans. B, Vol. 26, (1995) p.265.

Google Scholar

[49] S. K. Mishra(Pathak), S. K. Das, P. Ramachandra Rao, D. Belov, S. S. Mamyan, Mater. Trans. A, Vol. 34, (1973) p.2003.

Google Scholar

[50] S. K. Mishra, S. K. Das, P. Ramachandrarao, D. Belov, S. S. Mamyan, Phil. Mag. Lett, Vol. 84(1), (2004) pp.41-46.

Google Scholar

[51] S.K. Mishra, S. K. Das and L.C. Pathak, Mater. Sci. Engg. A Vol. 426 (2006) p.229.

Google Scholar

[52] S. K. Mishra (Pathak), S. Das, R. P. Goel and P. Ramachandrarao, J. Mater. Sci. Vol. 16 (1997) p.965.

Google Scholar

[53] T. Ya. Kosolapova, Editor, Hand book of high temperature compounds, Ohemisphere Publishing Corporation, Taylor and Francis Group, (1990) pp.864-867.

Google Scholar

[54] S. K. Mishra (Pathak), S. K. Das, Roy A. and P. Ramchandrarao, J. Mater. Res. Vol. 14 (1999) p.3594.

Google Scholar

[55] E. Y. Gutmanas and I. Gotman. J. Euro. Ceram. Soc. Vol. 19 (1999) pp.2381-2393.

Google Scholar

[56] L. Wang, M.R. Wixom, L.T. Thompson, J. Mater. Sci. Vol. 29 (1994) pp.534-543.

Google Scholar

[57] M. A. Meyers, E. A. Olevsky, J. Ma and M. Jamet, Mater. Sci. Eng. A, Vol. 311 (2001) pp.83-99.

Google Scholar

[58] H. J. Feng and J. J. Moore. Metall Mater Trans B Vol 26 (1995) pp.265-273.

Google Scholar

[59] A. H. Darren and M. A. Meyers. J. Am. Ceram. Soc. Vol. 78(2) (1995) pp.275-81.

Google Scholar

[60] F. Monteverde, A. Bellosi and S. Guicciardi, J. Euro. Ceram. Soc. Vol. 22 (2002) pp.279-288.

Google Scholar

[61] S. K. Mishra and V. Shcherbakov, U.S. Patent Filed No. 0238NF2003/US, Ind. Patent Filed No. 1654/del/(2004).

Google Scholar

[62] S. K. Mishra, S. K. Das and V. Shcherbakov, Compo. Sci. Technol., Vol. 67 (2007) p.2447.

Google Scholar

[63] A. Shiryaev Intl. J. Self -Prop. High Temp. Synth., Vol. 4 (1995) pp.351-362.

Google Scholar

[64] S. K. Mishra, P.K. P. Rupa, S. K. Das and V. Shcherbokov, Metall. Mater. Trans. B, Vol. 37B (2006) p.641.

Google Scholar

[65] S. K. Mishra, P.K. P. Rupa, S. K. Das and V. Shcherbokov, Compos. Sci. Technol. Vol. 67 (2007) pp.1734-39.

Google Scholar