Litcius/Paper detail

Data-driven approach for potential iron-based half-Heusler thermoelectrics with chemical bonding characteristics

Xiaoqian Nan, Kei Hayashi, Zhicheng Huang, Yuzuru Miyazaki

2025Science Advances6 citationsDOIOpen Access PDF

Abstract

Chemical bonding influences various physical properties and holds promise for guiding the discovery of high-performance materials. In XYZ half-Heusler (HH) compounds, complex interactions between constituent atoms, featuring both covalent and ionic characters, are supposed to affect mechanical and thermoelectric behavior. We use a data-driven approach based on first-principles calculations to identify promising HH compounds and explore the correlations between bonding-related features and functional properties. Our analysis suggests that enhanced Y ─ Z bonding correlates with greater bulk modulus ( B ), larger Grüneisen parameter, and enhanced power factor. Tungsten-iron-lead stands out with excellent B = 162.4 gigapascals and a low lattice thermal conductivity of ~7.7 watts per meter per kelvin, leading to a figure of merit of ~0.52 (at 526 kelvin) without any nanostructuring, surpassing that of vanadium-iron-antimony by ~80.8%. These findings highlight how chemical bonding characteristics, interpreted from electronic structure and orbital-resolved bonding analysis, provide in-depth insights into the structure-to-property correlation to accelerate the screening out of potential thermoelectrics.

Topics & Concepts

Thermoelectric materialsChemical bondMaterials scienceIonic bondingValence (chemistry)Thermoelectric effectVanadiumNanotechnologyRietveld refinementCovalent bondChemical physicsFigure of meritCrystal structureChemistryThermal conductivityCrystallographyThermodynamicsMetallurgyOptoelectronicsPhysicsIonComposite materialOrganic chemistryAdvanced Thermoelectric Materials and DevicesHeusler alloys: electronic and magnetic propertiesMachine Learning in Materials Science