The significant influence of carbon content on mechanical and thermal properties of (VNbTaMoW)0.5Cx high entropy carbides

The high-entropy formation possibility of (VNbTaMoW)_0.5C_x was first analyzed by phase diagram and then a series of single-phase (VNbTaMoW)_0.5C_x was fabricated by SPS. We investigated the mechanical properties and thermal conductivity of (VNbTaMoW)_0.5C_x as C stoichiometry is varied. As C stoichiometry is increased from 0.345 to 0.35, multi-phase evolves into a single rock-salt phase. The high entropy phase formation depends on C atoms and vacancies, which increase the total number of microscopic states, and then increases the overall configuration entropy and lattice distortion energy. A highly carbon-deficient condition (C=0.345) leads to FCC structure disintegration and drives metal rich Mo₂C phase evolution. As the carbon stoichiometry increases from 0.35 to 0.5, the nanohardness and flexure strength of (VNbTaMoW)_0.5C_x first increase and reach the peak values of 48 GPa and 410 MPa ((VNbTaMoW)_0.5C_0.4), then decrease. The point defects concentration in (VNbTaMoW)_0.5C_x drastically change with carbon stoichiometry, which affects the structure, mechanical properties and thermal conductivity of high-entropy (VNbTaMoW)_0.5C_x. The thermal conductivity of (VNbTaMoW)C_x first decreases and then gradually increases with an increase in carbon content. Low carbon content (VNbTaMoW)C with primarily metallic bonding is electronically thermal conductivity. As the carbon content increase, the high-entropy (VNbTaMoW)C is covalent bonding and phonon contribution to thermal conductivity plays a great role.