R.W. Smith, D. Gentner, E. Harzenski, and T. Robisch, The Structure and Properties of Plasma Sprayed TiC Dispersion Hardened Coatings,Thermal Spray Technology: New Ideas & Processes, D.L. Houck, Ed., ASM International, 1989, p 299-306
C. Bartuli, R.W. Smith, and E. Shtessel, Self-Propagating High Tem- perature Synthesis (SHS) of Ceramic and Composite Powders for Ther- mal Spray Applications,Advances in Science and Technology: Ad- vances in Inorganic Films and Coatings, Vol 5, P. Vincenzini, Ed., Techna, 1995, p 131-140
J.W. McCauley, An Historical and Technical Perspective on SHS,Ceram. Eng. Proc, Vol 11, 1990, p 1137–1181
A.G. Merzhanov, Self-Propagating High-Temperature Synthesis: Twenty Years of Search and Findings,Combustion and Plasma Syn- thesis of High Temperature Materials, Z.A. Munir and J.B. Holts, Ed., VCH Publishers, 1990, p 1-53
J. Subrahmanyam and M. Vijayakumar, Review: Self-Propagating High-Temperature,J. Mater. Sci., Vol 27, 1992, p 6249–6273
K.S. Vecchio, J.C. La Salvia, M.A. Meyers, and G.T. Gray III, Micro- structural Characterization of Self-Propagating High-Temperature Synthesis/Dynamically Compacted and Hot-Pressed Titanium Car- bides,Metall. Trans. A, Vol 23, 1992, p 87–97
M. Oyanagi, M. Kanno, and M. Koizumi, Characterization of Titanium Carbide (TiC) Formed by SHS,Int. J. Self. Prop. High Temp. Synth., Vol 1 (No. 1), 1992, p 125–130
T.Y. Kosolapova,Carbides: Properties, Production and Applica- tions, Plenum Press, 1971, p 97-111
E.K. Storms,The Refractory Carbides, Academic Press, 1967, p 1-17
P. Capkova, P. Karen, and L. Dobiasova, Determination of Molar Ratio in AB1-x Rock Salt-Type Compounds by X-Ray Powder Diffraction Method. Application to TiCi-x,Cryst. Res. Technol., Vol 21 (No. 6), 1986, p 735–740
L. Reimer,Transmission Electron Microscopy, Springer-Verlag, 1984
Powder Diffraction File-2 Database, ICDD, 1991, for CD-ROM
H. Lipson and H. Steeple,Interpretation of X-Ray Powder Diffrac- tion Patterns, St. Martin’s, 1970
C. Vincent, J. Dazord, H. Vincent, and J. Bouix, Thermodynamic and Experimental Investigation of the Stoichiometry of Titanium Carbide Obtained from the Reaction between a Graphite Substrate and a Gase- ous Mixture of Titanium Tetrachloride and Hydrogen,Thermochim. Acta, Vol 138, 1989, p 81 -96
S. Ramalingam, Stoichiometry of Titanium Carbide and Its Signifi- cance to the Performance of Hard Metal Compacts,Mater. Sci. Eng., Vol 29, 1977, p 123–130
S. Tsurekawa, H. Kurishita, and H. Yoshinaga, High Temperature Deformation Mechanism in Substoichiometric Titanium Carbide— Correlation with Carbon Vacancy Ordering,J. Nucl. Mater., Vol 169, 1989, p 291–298
E. Breval, Microplasticity at Room Temperature of Single Crystal Tita- nium Carbide with Different Stoichiometry,J. Mater. Sci., Vol 16, 1981, p 2781–2788