First‐principles study of the thermal properties of Zr2C and Zr2CO

First‐principles study of the thermal properties of Zr2C and Zr2CO

First‐principles calculations of lattice thermal conductivities and thermodynamic properties of Zr2C and Zr2CO were performed using the quasi‐harmonic approximation. Oxygen in the lattice gives Zr2CO higher bonding strength than Zr2C. Thus, the mechanical properties of Zr2C are enhanced when the vac...

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Veröffentlicht in:Journal of the American Ceramic Society 2022-07, Vol.105 (7), p.4921-4929
Hauptverfasser: Zhou, Yue, Fahrenholtz, William G., Graham, Joseph, Hilmas, Gregory E.
Format: Artikel
Sprache:eng
Schlagworte:
Bonding strength
Conductivity
Crystal structure
first‐principles theory
Gruneisen parameter
Heat conductivity
Heat transfer
Lattice vacancies
Mathematical analysis
Mechanical properties
Oxygen
Principles
Stiffness
Thermal conductivity
Thermal expansion
Thermodynamic properties
Zirconium carbide
zirconium/zirconium compounds
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Zusammenfassung:First‐principles calculations of lattice thermal conductivities and thermodynamic properties of Zr2C and Zr2CO were performed using the quasi‐harmonic approximation. Oxygen in the lattice gives Zr2CO higher bonding strength than Zr2C. Thus, the mechanical properties of Zr2C are enhanced when the vacancies in its crystal structure are filled with oxygen. Among the critical parameters that determine the lattice thermal conductivity, Zr2C has significantly higher Grüneisen parameters, thus Zr2C has lower lattice thermal conductivity than Zr2CO. In addition, Zr2CO has a higher heat capacity and thermal expansion coefficient than Zr2C at most temperatures. These results indicate that the addition of oxygen has increased the stiffness and thermal conductivity of zirconium carbide that contains a large fraction of carbon vacancies due to the filling of vacancies in the Zr2C lattice and the formation of Zr–O bonds.
ISSN:0002-7820
1551-2916
DOI:10.1111/jace.18461