Abstract
Low thermal conductivity is an important materials property for thermoelectricity. The lattice thermal conductivity (LTC) can be reduced by introducing sublattice disorder through partial isovalent substitution. Yet, large-scale screening of materials has seldom taken this opportunity into account. The present study aims to investigate the effect of partial sublattice substitution on the LTC. The study relies on the temperature-dependent effective potential method based on forces obtained from density functional theory. Solid solutions are simulated within a virtual crystal approximation, and the effect of grain-boundary scattering is also included. This is done to systematically probe the effect of sublattice substitution on the LTC of 122 half-Heusler compounds. It is found that substitution on the three different crystallographic sites leads to a reduction of the LTC that varies significantly both between the sites and between the different compounds. Nevertheless, some common criteria are identified as most efficient for reduction of the LTC: The mass contrast should be large within the parent compound, and substitution should be performed on the heaviest atoms. It is also found that the combined effect of sublattice substitution and grain-boundary scattering can lead to a drastic reduction of the LTC. The lowest LTC of the current set of half-Heusler compounds is around 2 W/Km at 300 K for two of the parent compounds. Four additional compounds can reach similarly low LTC with the combined effect of sublattice disorder and grain boundaries. Two of these four compounds have an intrinsic LTC above ∼15 W/Km, underlining that materials with high intrinsic LTC could still be viable for thermoelectric applications.
Highlights
IntroductionThe ability to convert excess heat into electricity and vice versa makes thermoelectricity interesting for a range of niche applications requiring local cooling or electricity generation
The ability to convert excess heat into electricity and vice versa makes thermoelectricity interesting for a range of niche applications requiring local cooling or electricity generation.More effective thermoelectric materials could increase the applicability of thermoelectricity and thereby contribute to reducing energy consumption and carbon emissions [1,2]
The lattice thermal conductivity (LTC) is calculated with the temperature-dependent effective potential (TDEP) approach [68,69], in which the finite-temperature second- and third-order force constants are extracted based on atomic displacements and forces
Summary
The ability to convert excess heat into electricity and vice versa makes thermoelectricity interesting for a range of niche applications requiring local cooling or electricity generation. More effective thermoelectric materials could increase the applicability of thermoelectricity and thereby contribute to reducing energy consumption and carbon emissions [1,2]. The figure-of-merit of a thermoelectric material is at an operational temperature T given by Licensee MDPI, Basel, Switzerland. This article is an open access article σS2 T , κe + κ (1). Distributed under the terms and conditions of the Creative Commons. Where S is the Seebeck coefficient, σ is the electrical conductivity, and κe and κare the electronic and lattice thermal conductivity (LTC), respectively. The electronic contributions to ZT exhibit conflicting dependency of the charge carrier concentration, requiring opti- 4.0/).
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