Thermodynamic stability, thermoelectric, elastic and electronic structure properties of ScMN2-type (M = V, Nb, Ta) phases studied by ab initio calculations

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Abstract

ScMN2-type (M = V, Nb, Ta) phases are layered materials that have been experimentally reported for M = Ta and Nb, but they have up to now not been much studied. However, based on the properties of binary ScN and its alloys, it is reasonable to expect these phases to be of relevance in a range of applications, including thermoelectrics. Here, we have used first-principles calculations to study their thermodynamic stability, elastic, thermoelectric and electronic properties. We have used density functional theory to calculate lattice parameters, the mixing enthalpy of formation and electronic density of states as well as the thermoelectric properties and elastic constants (cij), bulk (B), shear (G) and Young’s (E) modulus, which were compared with available experimental data. Our results indicate that the considered systems are thermodynamically and elastically stable and that all are semiconductors with small band gaps. All three materials display anisotropic thermoelectric properties and indicate the possibility to tune these properties by doping. In particular, ScVN2, featuring the largest band gap exhibits a particularly large and strongly doping-sensitive Seebeck coefficient.

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Pilemalm, R., Pourovskii, L., Mosyagin, I., Simak, S., & Eklund, P. (2019). Thermodynamic stability, thermoelectric, elastic and electronic structure properties of ScMN2-type (M = V, Nb, Ta) phases studied by ab initio calculations. Condensed Matter, 4(2), 1–14. https://doi.org/10.3390/condmat4020036

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