Effects of transition metals on physical properties of M2BC (M = V, Nb, Mo and Ta): a DFT calculation

TL;DR

This study uses DFT calculations to analyze the electronic, mechanical, optical, and thermodynamic properties of M2BC compounds with transition metals V, Nb, Mo, and Ta, revealing their potential for protective coatings and thermal barriers.

Contribution

First comprehensive DFT analysis of M2BC compounds' properties, highlighting their stability, conductivity, hardness, and optical features for coating applications.

Findings

Mo2BC is the stiffest among the compounds.

Ta2BC shows potential as a thermal barrier coating.

All compounds exhibit metallic conductivity with d-orbital contributions.

Abstract

The electronic band structures along with Fermi surface, anisotropy, Vickers hardness, analysis of Mulliken populations, optical and thermodynamic properties were studied for the first time. The optimized unit cell parameters are compared with available theoretical and experimental results and a reasonable agreement is recorded. The mechanical stability of these compounds is confirmed. All the compounds herein exhibit metallic conductivity where major contribution comes from d-orbital electrons. The hardness values of 10.71, 12.44, 8.52 and 16.80 GPa were recorded for M2BC (M = V, Nb, Mo and Ta) compounds, respectively. The value of bulk modulus, B is found to increase in the sequence B (V2BC) < B (Nb2BC) < B (Ta2BC) < B (Mo2BC), indicates Mo2BC is highly stiff among all compounds. The Mo2BC and Ta2BC compound might be considered as potential candidates for protection of cutting and forming tools due to the moderately ductile and highly stiff behavior compared to other benchmark hard coating materials such as TiN, TiAlN, Ti0.5Al0.5N and c-BN. Ta2BC compound could also be a promising thermal barrier coating (TBC) material due to the reasonable results of minimum thermal conductivity, Debye temperature and damage tolerance behavior. Various optical functions such as dielectric constants, refractive index, photo-conductivity, absorption, loss function and reflectivity) are calculated and discussed in details. The amount of reflectivity was always more than around 50% with no significant change in the near infrared, visible light and near ultraviolet region (up to ~6 eV), which results a promising coating material to diminish solar heating as well.