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LITERATURE CITED

  • Cabrera, N., and Mott, N. F. “Theory of the Oxidation of Metals,”, Prog. Phys. Rep., 12, 163 ( 1949).
  • Claycomb, J. R., W. LeGrand, J. H. Miller Jr., M. D. Nersesyan, J. T. Ritchie and D. Luss, “Chemomagnetic Characterization of Chemical Reactions Using High-Tc SQUIDs,” Phisica C, 341, 2641 ( 2000).
  • Debye, P., “Der Erste Electronenring der Atome,” Phys. Z. 18, 276 ( 1917).
  • Fromm, E., “Model Calculations of Metal Oxidation at Ambient Temperatures,” Non-Stoichiometric Compounds, Surfaces, Grain Boundaries and Structural Defects, J.Nowotny and W.Weppner, eds., Kluwer, New York, p ( 1989).
  • Fromhold, A. T., Theory of Metal Oxidation (Defects in Crystalline Solids), Vol. 1, North-Holland, Amsterdam ( 1976).
  • Fromhold, A. T., Theory of Metal Oxidation (Defects in Solids), Vol. 2, North-Holland, Amsterdam ( 1980).
  • Grigoriev, I. S., and E. Z. Melikhov, Handbook of Physical Quantities, CRC Press, Boca Raton, p 1548 ( 1997).
  • Kapila, D., and J. L. Plawsky, “Solid State Film Diffusion for the Production of Integrated Optical Waveguides,” AIChE J., 39, 1186 ( 1993).
  • Kroger, F. A., and H. J. Vink, “Relations Between the Concentrations of Imperfections in Crystalline Solids,” Solid State Physics Vol. 3, F.Seitz and D.Turnbull, eds, Academic Press, New York, p 307 ( 1956).
  • Kroger, F. A., The Chemistry of Imperfect Crystals, Wiley, New York ( 1964).
  • Kudryashov, V. A., A. S. Mukasyan, and I. A. Filimonov, “Chemoionization Waves in Heterogeneous Combustion Processes,” J. Mater. Synth. Process, 4(5) 353 ( 1996).
  • Maksimov, Yu. M., A. I. Kirdyashkin, V. S. Korogodov, and V. L. Polyakov, “Generation and Transfer of an Electric Charge in Self-Propagating High-Temperature Synthesis Using the Co-S System as an Example,” Combust. Explos. Shock Waves, 36(5) 130 ( 2000).
  • Manning, P. S., J. D. Sirman, R. A. DeSouza, and J. A. Kilner, “The Kinetics of Oxygen Transport in 9.5 mol % Single Crystal Yttria Stabilised Zirconia,” Solid State Ionics, 100, 1 ( 1997).
  • Martirosyan, K. S., I. A. Filimonov, M. D. Nersesyan, and D. Luss, “Electric Field Formation during Combustion of Single Metal Particles,” J. Electrochem. Soc., 150(5), 9 ( 2003a).
  • Martirosyan, K. S. I. A. Filimonov, and D. Luss, “New Measuring Techniques of Electric Field Generated by Combustion Synthesis,” Int. J. SHS., J. Electrochem. Soc., 11(4), 325 ( 2003b).
  • Merzhanov, A. G., S. O. Mkrtchyan, M. D. Nersesyan, P. B. Avakyan, and K. S. Martirosyan, “Magnetic Field Caused by SHS Process,” Dokl. Akad. Nauk. RA, 93(2), 81 ( 1992).
  • Morozov, Y. G., M. V. Kuznetsov, M. D. Nersesyan, and A. G. Merzhanov, “Electrochemical Phenomena in the Processes of the SHS,” Dokl. Akad. Nauk. Rossii, 351(6), 780 ( 1996).
  • Nernst, W., “Zur Kinetik der in Losung Befindlichen Korper,” Z. Phys. Chem., 2, 613 ( 1888).
  • Nersesyan, M. D., J. R. Claycomb, Q. Ming, J. H. Miller, J. T. Richardson, and D. Luss, “Chemomagnetic Fields Produced by Solid Combustion Reactions,” Appl. Phys. Lett., 75(8), 1170 ( 1999).
  • Nersesyan, M. D., J. R. Claycomb, J. T. Ritchie, J. H. Miller, J. T. Richardson, and D. Luss, “Electric and Magnetic Fields Generated by SHS,” J. Mater. Synth. Process, 9(2), 63 ( 2001a).
  • Nersesyan, M. D., D. Luss, J. R. Claycomb, J. T. Ritchie, and J. H. Miller, Jr., “Magnetic Fields Produced by Combustion of Metals in Oxygen,” Combust. Sci. Technol., 169, 89 ( 2001b).
  • Nersesyan, M. D., J. T. Ritchie, I. A. Filimonov, J. T. Richardson, and D. Luss, “Electric Fields Produced by High-Temperature Metal Oxidation,” J. Electrochem. Soc., 149(1), J11 ( 2002).
  • Rode, H., D. Orlicki, and V. Hlavacek, “Reaction Rate Modeling in Noncatalytic Gas-Solid Systems: Species Transport and Mechanical Stress,” AIChE J., 41(12), 2614 ( 1995a).
  • Rode, H., D. Orlicki, and V. Hlavacek, “Noncatalytic Gas-Solid Reactions and Mechanical Stress Generation,” AIChE J., 41(5), 1235 ( 1995b).
  • Shire, E. S., Classical Electricity and Magnetism, Cambridge Univ. Press, Cambridge, p. 396 ( 1960).
  • Wagner, C., “Uber den Zusammenhang Zwischen Ionenbeweglichkeit und Diffusionsgeschwindigkeit in Festen Salzen,” Z. Phys. Chem., B11, 139 ( 1930).
  • Wagner, C., “Beitrag zur Theorie des Anlaufvorgangs,” Z. Phys. Chem. B21, 25 ( 1933).
  • Wagner, C., “Equations for Transport in Solid Oxides and Sulfides of Transition Metals,” Prog. Solid State Chem., 10(1), 3 ( 1975).