Litcius/Paper detail

Recent progress in Fe- and Ru-based full-Heusler bulk thermoelectrics

Fabian Garmroudi, Michael Parzer, Takao Mori, E. Bauer

2025Science and Technology of Advanced Materials7 citationsDOIOpen Access PDF

Abstract

Full-Heusler compounds represent a rich and diverse class of functional materials, covering a large compositional phase space. Representatives with 24 valence electrons are commonly semimetals or narrow-gap semiconductors as per the Slater-Pauling rule, and are thus considered as thermoelectric materials, especially for room-temperature applications. Research on the archetypal thermoelectric full-Heusler compound Fe2VAl began over two decades ago, and since then, significant progress has been made in enhancing its thermoelectric performance. Advances have been achieved through various intrinsic and extrinsic substitutions, grain boundary engineering, and other optimization strategies. Here, recent advancements are reviewed, challenges for the further development of competitive full-Heusler thermoelectrics are identified, and novel routes and concepts are highlighted that could make these materials viable for energy harvesting and cooling applications near room-temperature.

Topics & Concepts

Thermoelectric materialsMaterials scienceThermoelectric effectEngineering physicsNanotechnologyCondensed matter physicsPhysicsThermodynamicsHeusler alloys: electronic and magnetic propertiesAdvanced Thermoelectric Materials and DevicesMXene and MAX Phase Materials
Recent progress in Fe- and Ru-based full-Heusler bulk thermoelectrics | Litcius