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Material Descriptors for the Discovery of Efficient Thermoelectrics

Patrizio Graziosi, Chathurangi Kumarasinghe, Neophytos Neophytou

2020ACS Applied Energy Materials56 citationsDOIOpen Access PDF

Abstract

The predictive performance screening of novel compounds can significantly promote the discovery of efficient, cheap, and nontoxic thermoelectric (TE) materials. Large efforts to implement machine-learning techniques coupled to materials databases are currently being undertaken, but the adopted computational methods can dramatically affect the outcome. With regards to electronic transport and power factor (PF) calculations, the most widely adopted and computationally efficient method is the constant relaxation time approximation (CRT). This work goes beyond the CRT and adopts the proper, full energy and momentum dependencies of electron–phonon and ionized impurity scattering to compute the electronic transport and perform PF optimization for a group of half-Heusler alloys. Then, the material parameters that determine the optimal PF based on this more advanced treatment are identified. This enables the development of a set of significantly improved descriptors that can be used in material screening studies, which offer deeper insights into the underlying nature of high-performance TE materials. We have identified nvεr/Do2mcond as the most useful and generic descriptor, a combination of the number of valleys, the dielectric constant, the conductivity effective mass, and the deformation potential for the dominant electron–phonon process. The proposed descriptors can accelerate the discovery of new efficient and environment-friendly TE materials in a much more accurate and reliable manner, and some predictions for very high-performance materials are presented.

Topics & Concepts

Thermoelectric materialsComputer scienceWork (physics)Power (physics)Materials scienceDielectricThermoelectric effectRelaxation (psychology)Materials informaticsSet (abstract data type)Efficient energy useEnergy (signal processing)Power factorMaterial propertiesConductivityNanotechnologyField (mathematics)Machine Learning in Materials ScienceAdvanced Thermoelectric Materials and DevicesHeusler alloys: electronic and magnetic properties