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  1. 1
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  2. 2
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  11. 11
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  12. 12
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  13. 13
    Yuanwen Wu, Hanrui Zhuang, Fengying Wu, David Dollimore, Baolin Zhang, Shen Chen, Wenlan Li, Mechanism of the formation of β–Sialon by self-propagating high-temperature synthesis, Journal of Materials Research, 1998, 13, 01, 166

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  14. 14
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  15. 15
    Chao M. Huang, Youren Xu, Dong Zhu, Waltraud M. Kriven, Combustion-synthesized β′-SiAlON reinforced with SiC monofilaments, Materials Science and Engineering: A, 1994, 188, 1-2, 341

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  16. 16
    J. ZENG, Y. MIYAMOTO, O. YAMADA, ChemInform Abstract: Combustion Synthesis of Sialon Powders (Si6-zAlzOzN8-z, z = 0.3, 0.6)., ChemInform, 1991, 22, 10
  17. 17
    Jianren Zeng, Yoshinari Miyamoto, Osamu Yamada, Combustion Synthesis of Si3N4–SiC Composite Powders, Journal of the American Ceramic Society, 1991, 74, 9