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V. A. Lavrenko, A. F. Alekseev, E. S. Lugovskaya (1980)
Hightemperature oxidation of aluminum nitride in oxygenDokl. Akad. Nauk SSSR, Fiz. Khim., 255
S. V. Lysak, B. G. Alapin, B. Y. Sukharevskii (1976)
A study into the structure and polymorphism of cristobalitic aluminum orthophosphate by x-ray diffractometry and infrared spectroscopyKristallografiya, 21
K. Hauffe (1955)
Reaktionen in und an festen Stoffen
A. Brown, M. Norton (1998)
Oxidation Kinetics of AlN PowderJournal of Materials Science Letters, 17
Martin Sterntzke, G. Müller (1994)
EELS Study of Oxygen Diffusion in Aluminum NitrideJournal of the American Ceramic Society, 77
G. V. Samsonov (1969)
Nonmetallic Nitrides [in Russian]
V. I. Tokmantsev, A. R. Beketov, D. A. Beketov (2000)
Vestnik UPI, Ser. Electromechanics and Controlled Electric Engineering Systems [in Russian]
M. D. Lyutaya, V. F. Bukhanevich (1962)
Chemical and thermal stability of nitrides of the third group elementsZh. Neorg. Khim., 7
P. Kofstad (1972)
Nonstoichiometry, Diffusion and Electrical Conductivity in Binary Metal Oxides
L. Blaginina (1996)
Microstructure and properties of AlN ceramics heat-treated in airInorganic Materials, 32
R. F. Voitovich (1981)
Oxidation of Carbides and Nitrides [in Russian]
T. Y. Kosolapova (1983)
High-Melting Nitrides [in Russian]
A. Garshin, V. Shvaiko-Shvaikovskii, V. Shvarts (1996)
Point defects and disordering processes in aluminum nitrideInorganic Materials, 32
A. L. Brown, M. G. Norton (1998)
Oxidation kinetics of aluminium nitrideJ. Mater. Sci. Lett., 17
L. A. Blaginina (1996)
Microstructure and properties of the AlN ceramic heat-treated in airNeorg. Mater., 32
D. Suryanarayana (1990)
Oxidation Kinetics of Aluminum NitrideJournal of the American Ceramic Society, 73
A. P. Garshin, V. E. Shvaiko-Shvaikovskii (1996)
Point defects and disordering processes in aluminum nitrideNeorg. Mater., 32
A. A. Mayer (1968)
Special Ceramics [Russian translation]
A method for studying the heat resistance of composite aluminum nitride-based ceramic materials in air at 1073 – 1273 K is developed that allows the change in mass to be measured with an accuracy of 0.15 – 0.17 mg. The interaction between AlN-based composite materials and a phosphate binder (H3PO4) is studied and compared with hot-pressed specimens. A mechanism for the effect of the binder on the kinetics of oxidation is proposed. The relatively low activation energies (152 and 205 kJ/mole) suggest that the oxidation process is mainly determined by the diffusion of aluminum ions through the α-Al2O3 film.
Refractories and Industrial Ceramics – Springer Journals
Published: Oct 13, 2004
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