REFERENCES
- Ali-Rachedi , M. , Ramdane , W. , Vrel , D. , Benaldjia , A. , Langlois , P. , and Guerioune , M. 2010 . The role of sintering additives on synthesis of cermets by auto-combustion . Powder Technol. , 197 , 303 .
- Azatyan , T.S. , Mal'tsev , V.M. , Merzhanov , A.G. , and Seleznev , V.A. 1977. Spectral-optical investigation of the mechanism of the combustion of mixtures of titanium and carbon. Combust. Explos. Shock Waves , 13(2), 156.
- Cai , R.J. 1999 . Design Principle of Explosive Device , Beijing Institute of Technology , Beijing , pp. 307 – 309 .
- Contreras , L. , Turrillas , X. , Vaughan , G.B.M. , Kvick , A. , and Rodríguez , M.A. 2004 . Time-resolved XRD study of TiC–TiB2 composites obtained by SHS . Acta Mater. , 52 , 4783 .
- Huque , Z. , and Azad , G.M.S. 2008 . Thermal conductivity effects on steady state propagation speed during self-propagating high-temperature synthesis of Ti + C green compacts . Mat. Sci. Eng. B , 147 , 19 .
- Khina , B.B. , Formanek , B. , and Solpan , I. 2005 . Limits of applicability of the “diffusion-controlled product growth” kinetic approach to modeling SHS . Physica B , 355 , 14 .
- Knyazik , V.A. , Merzhanov , A.G. , Solomonov , V.B. , and Shteinberg , A.S. 1985 . Macrokinetics of high-temperature titanium interaction with carbon under electrothermal explosion conditions . Combust. Explos. Shock Waves , 21 ( 3 ), 333 .
- Kobashi , M. , Ichioka , D. , and Kanetake , N. 2010 . Combustion synthesis of porous TiC/Ti composite by a self-propagating mode . Materials , 3 , 3939 .
- Li , H.P. 2003 . An investigation of the ignition manner effects on combustion synthesis . Mater. Chem. Phys. , 80 , 758 .
- Logan , K.V. , Sparrow , J.T. , and McLemore , W.J.S. 1990 . In Munir , Z.A. , and Holt , J.B. (Eds.), Combustion and Plasma Synthesis High-Temperature Materials , VCH , New York , p. 219 .
- Lu , K.T. , Yang , C.C. , and Ko , Y.H. 2008 . Investigation of the burning properties of slow-propagation tungsten type delay compositions . Propell. Explos. Pyrot. , 33 ( 3 ), 219 .
- Lycas , J. 1974 . Engineering Design Handbook—Explosives Series: Explosive Trains (AMCP 706–179) , U.S. Army Material Command , Washington , pp. G2 – 3 .
- Mas-Guindal , M.J. , Turrillas , X. , Hansen , T. , and Rodríguez , M.A. 2008 . Time-resolved neutron diffraction study of Ti–TiC–Al2O3 composites obtained by SHS . J. Eur. Ceram. Soc. , 28 , 2975 .
- Mossino , P. 2004 . Some aspects in self-propagating high-temperature synthesis . Ceram. Int. , 30 , 311 .
- Moore , J.J. , and Feng , H.J. 1995 . Combustion synthesis of advanced materials, part I: Reaction parameters . Prog. Mater. Sci. , 39 , 243 .
- Patil , K.C. 1993 . Advanced ceramics: Combustion synthesis and properties . Bull. Mater. Sci. , 16 ( 6 ), 533 .
- Rice , R.E. , Richardson , G.Y. , Kunetz , J.M. , Schrooter , T. , and McDonough , W.J. 1987 . Effects of self-propagating synthesis reactant compact character on ignition, propagation, and microstructure . Adv. Ceram. Mater. , 2 ( 3A ), 222 .
- Subrahmanyan , J. , and Vijayakumar , M. 1992 . Self-propagating high-temperature synthesis . J. Mater. Sci. , 27 , 6249 .
- U.S. Army . 1984 . Military Explosives, TM9–1300-214 , Delta Press , Washington , DC , pp. 8 – 32 .
- Vrel , D. , Girodon-Boulandet , N. , Paris , S. , Mazúe , J.F. , Couqueberg , E. , Gailhanou , M. , Thiaudiére , D. , Gaffet , E. , and Bernard , F. 2000 . A new experimental setup for the time-resolved x-ray diffraction study of self-propagating high-temperature synthesis . Rev. Sci. Instr. , 73 ( 2 ), 422 .