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Effects of isotropic strain on the structure and transport properties of half-Heusler alloy BiBaK: a first-principles investigation

Junhong Wei, Yongliang Guo, Guangtao Wang

2024RSC Advances22 citationsDOIOpen Access PDF

Abstract

In this study, using density functional and Boltzmann transport theories, we systematically investigated the effects of tensile and compressive strains on the elastic properties, phonon dispersion relation, electronic structure, and transport properties of the half-Heusler compound BiBaK. We calculated the elastic constants and phonon dispersion curves for BiBaK, which demonstrated its mechanical and thermodynamic stability, respectively, under different isotropic strains. Further, calculations showed that the electronic structure and energy bandgap of BiBaK changed with the application of isotropic strain. A high power factor and low thermal conductivity are key to improving the performance of thermoelectric materials. The figure of merit of BiBaK is 0.6 when it is unstrained and reaches a maximum value of 0.93 at -9% compressive strain and a temperature of 1200 K, indicating that under isotropic compressive strain, BiBaK compounds are efficient thermoelectric materials for high-temperature applications.

Topics & Concepts

Materials scienceIsotropyThermoelectric effectCondensed matter physicsSeebeck coefficientPhononThermal conductivityFigure of meritBoltzmann constantUltimate tensile strengthDispersion (optics)Boltzmann equationCompressive strengthAlloyThermodynamicsComposite materialOptoelectronicsPhysicsOpticsAdvanced Thermoelectric Materials and DevicesHeusler alloys: electronic and magnetic properties2D Materials and Applications