First-Principle Calculations of Hardness and Melting Point of Mo2C

Abstract

Abstract:

This paper has constructed two kinds of atomic and electronic models for hexagonal β-Mo₂C and orthorhombic α-Mo₂C. The optimized lattice parameters, elastic constant matrixes and overlap population for Mo₂C crystal cells have been obtained to realize the characterization of the hardness and melting point of the two structures by the first-principles plane wave pseudo potential method based on the density functional theory. The results reveal that the calculated lattice parameters of the Mo₂C crystal cells agree with the experimental and other calculated data. The calculated melting point/hardness are 2715 K/11.38 GPa for β-Mo₂C and 2699 K/10.57~12.67 GPa for α-Mo₂C, respectively. The calculated results from the density of states (DOS) demonstrate that the hybridization effect between Mo-3d and C-2p states in α-Mo2C crystal cell is much
stronger than that in β-Mo₂C one.

Key words: First-principle; Mo₂C, Hardness, Melting point, Density of states

X.R. Wang,M.F. Yan,H.T. Chen. First-Principle Calculations of Hardness and Melting Point of Mo₂C[J]. J Mater Sci Technol, 2009, 25(03): 419-422.

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First-Principle Calculations of Hardness and Melting Point of Mo₂C

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