Study of Thermal Conductivity of Materials Based on Silicon Carbide and Silicon Nitride

被引:1
|
作者
Perevislov S.N. [1 ]
Markov M.A. [2 ]
Kuznetsov Y.A. [3 ]
Kravchenko I.N. [4 ,5 ]
Krasikov A.V. [2 ]
机构
[1] Institute of Chemistry of Silicates named after I.V. Grebenshchikov of the Russian Academy of Sciences, St. Petersburg
[2] National Research Center “Kurchatov Institute”—CRISM “Prometey”, St. Petersburg
[3] Federal State Budgetary Educational Institution of Higher Education “Oryol State Agrarian University named after N.V. Parakhina”, Orel
[4] Federal State Budgetary Educational Institution of Higher Education “Russian State Agrarian University— Moscow Agricultural Academy named after K.A. Timiryazev”, Moscow
[5] A.A. Blagonravov Mechanical Engineering Institute of the Russian Academy of Sciences, Moscow
来源
Steel in Translation | 2023年 / 53卷 / 09期
关键词
liquid-phase sintering; reaction sintering; silicon carbide; silicon nitride; thermal conductivity;
D O I
10.3103/S0967091223090115
中图分类号
学科分类号
摘要
Abstract: This paper presents the temperature dependences of the thermal conductivity of materials based on silicon carbide and silicon nitride, obtained by different methods. Thermal conductivity of silicon carbide materials obtained by reaction (SiSiC) and liquid-phase (LPSSiC) sintering, as well as silicon nitride materials obtained by liquid-phase sintering (SSN) has been studied. The dependences of the thermal conductivity coefficient on density, porosity and oxide additive content (for LPSSiC and SSN materials) are given. © 2023, Allerton Press, Inc.
引用
收藏
页码:752 / 760
页数:8
相关论文
共 50 条
  • [1] Thermal Conductivity of the Materials Based on Silicon Carbide and Silicon Nitride
    Perevislov, S. N.
    Markov, M. A.
    Kuznetsov, Yu. A.
    Kravchenko, I. N.
    Krasikov, A. V.
    RUSSIAN METALLURGY, 2020, 2020 (13): : 1477 - 1484
  • [2] Thermal Conductivity of the Materials Based on Silicon Carbide and Silicon Nitride
    S. N. Perevislov
    M. A. Markov
    Yu. A. Kuznetsov
    I. N. Kravchenko
    A. V. Krasikov
    Russian Metallurgy (Metally), 2020, 2020 : 1477 - 1484
  • [3] Study of Coefficient of Thermal Expansion of Materials Based on Silicon Nitride
    Perevislov, S. N.
    Tomkovich, M. V.
    INORGANIC MATERIALS-APPLIED RESEARCH, 2025,
  • [4] Modelling amorphous materials: Silicon nitride and silicon carbide
    Justo, JF
    da Silva, CRS
    DEFECTS AND DIFFUSION IN CERAMICS: AN ANNUAL RETROSPECTIVE IV, 2002, 206-2 : 19 - 29
  • [5] Development of calculation of thermal conductivity of silicon carbide
    Zhang, Chi
    Liang, Hanqin
    Li, Yinsheng
    Chen, Jian
    Zhang, Jingxian
    Kuei Suan Jen Hsueh Pao/Journal of the Chinese Ceramic Society, 2015, 43 (03): : 268 - 275
  • [6] The crystallography of interphase boundaries between silicon carbide and silicon nitride in silicon nitride - Silicon carbide particulate composites
    Turan, S
    Knowles, KM
    INTERFACE SCIENCE, 2000, 8 (2-3) : 279 - 294
  • [7] High Thermal Conductivity Silicon Nitride Ceramics
    Hirao, Kiyoshi
    Zhou, You
    Hyuga, Hideki
    Ohji, Tatsuki
    Kusano, Dai
    JOURNAL OF THE KOREAN CERAMIC SOCIETY, 2012, 49 (04) : 380 - 384
  • [8] Silicon Carbide-Silicon Nitride Refractory Materials: Part 1 Materials Science and Processing
    Yurkov, Andrey
    PROCESSES, 2023, 11 (07)
  • [9] Thermal conductivity improvement in silicon nitride ceramics via grain purification
    Imamura, Hisayuki
    Kawata, Tsunehiro
    Honda, Sawao
    Iwamoto, Yuji
    JOURNAL OF THE AMERICAN CERAMIC SOCIETY, 2024, 107 (02) : 1159 - 1169
  • [10] Tuning the thermal conductivity of silicon carbide by twin boundary: a molecular dynamics study
    Liu, Qunfeng
    Luo, Hao
    Wang, Liang
    Shen, Shengping
    JOURNAL OF PHYSICS D-APPLIED PHYSICS, 2017, 50 (06)
12345