Thermodynamic stability and superconductivity of tantalum carbides from first-principles cluster expansion and isotropic Eliashberg theory

The phase stability of tantalum carbides, particularly cubic rocksalt TaCx and hexagonal Ta2Cx, where 0 ⩽x⩽ 1 due to the presence of vacancies on the C sites, is explored using a first-principles cluster-expansion method. Our results demonstrate that at 0 K, in addition to stoichiometric cubic TaC a...

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Published in:Computational materials science 2022-02, Vol.202, p.111004, Article 111004
Main Authors: Tsuppayakorn-aek, P., Ektarawong, A., Sukmas, W., Alling, B., Bovornratanaraks, T.
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Language:English
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First-principles calculations
Isotropic Eliashberg theory
Superconductivity
Tantalum carbides
Thermodynamic stability
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description The phase stability of tantalum carbides, particularly cubic rocksalt TaCx and hexagonal Ta2Cx, where 0 ⩽x⩽ 1 due to the presence of vacancies on the C sites, is explored using a first-principles cluster-expansion method. Our results demonstrate that at 0 K, in addition to stoichiometric cubic TaC and hexagonal Ta2C both widely known in the literature, carbon-deficient face-centered orthorhombic TaC0.833 is identified as a thermodynamically stable phase in the binary Ta−C system. By investigating their vibrational and electronic properties, the three carbides are dynamically stable and are metallic. We further demonstrate, by adopting phonon mediated superconductivity based on the Bardeen–Cooper–Schrieffer theory, that cubic TaC, face-centered orthorhombic TaC0.833, and hexagonal Ta2C superconduct, whose transition temperatures are estimated by the Allen–Dynes equation to be 10.0 K, 6.8 K, and 1.4 K, respectively. The physical origin of superconductivity in these stable carbides are discussed and described, based on the detailed analysis of the materials’ electronic and phonon properties. [Display omitted] •A novel phase of carbon-deficient TaC0.833 is predicted to be stable even at 0 K.•Ordering pattern of carbon atoms and vacancies in TaC0.833 is expected below 1780 K.•TaC0.833 is a superconductor with the critical temperature of 6.8 K.•The origin of superconductivity in TaCx is analyzed and discussed in details.
doi_str_mv 10.1016/j.commatsci.2021.111004
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subjects First-principles calculations
Isotropic Eliashberg theory
Superconductivity
Tantalum carbides
Thermodynamic stability
title Thermodynamic stability and superconductivity of tantalum carbides from first-principles cluster expansion and isotropic Eliashberg theory
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