Paper detail

DFT insights into the new Hf-based chalcogenide MAX phase Hf2SeC

The physical characteristics of the novel chalcogenide MAX phase Hf2SeC have been investigated using the DFT method. The obtained lattice constant and elastic constants (Cij) are compared with previous results to check the consistency of our setting parameters during calculations Moreover, the elastic properties such as elastic constants, moduli, anisotropy, and hardness are also compared with preexisting MAX phases of its kind. The checking of mechanical stability has been done based on Cij in accordance with the previously stated stability criteria. The reason for the higher hardness of Hf2SeC compared to Hf2SC is explained using the density of states (DOS). The brittleness character of Hf2SeC has been revealed using the Pugh ratio, Poisson ratio, and Cauchy pressure. The electronic properties (band structure and charge density mapping) of Hf2SeC are studied to disclose the metallic nature as well as bonding nature within the titled chalcogenide. The anisotropy in both electronic conductivity and mechanical properties is investigated. The temperature and pressure dependence of volume, Grüneisen parameter, Debye temperature, thermal expansion coefficient (TEC), and specific heat at constant volume (Cv) are explored. In addition, minimum thermal conductivity (Kmin) and melting point (Tm) are studied to explore its suitability for high-temperature applications.