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Colossal negative magnetoresistance in field-induced Weyl semimetal of magnetic half-Heusler compound

Kentaro Ueda, Tonghua Yu, Motoaki Hirayama, Ryo Kurokawa, Taro Nakajima, Hiraku Saito, M. Kriener, Manabu Hoshino, Daisuke Hashizume, T. Arima, Ryotaro Arita, Yoshinori Tokura

2023Nature Communications17 citationsDOIOpen Access PDF

Abstract

The discovery of topological insulators and semimetals triggered enormous interest in exploring emergent electromagnetic responses in solids. Particular attention has been focused on ternary half-Heusler compounds, whose electronic structure bears analogy to the topological zinc-blende compounds while also including magnetic rare-earth ions coupled to conduction electrons. However, most of the research in this system has been in band-inverted zero-gap semiconductors such as GdPtBi, which still does not fully exhaust the large potential of this material class. Here, we report a less-studied member of half-Heusler compounds, HoAuSn, which we show is a trivial semimetal or narrow-gap semiconductor at zero magnetic field but undergoes a field-induced transition to a Weyl semimetal, with a negative magnetoresistance exceeding four orders of magnitude at low temperatures. The combined study of Shubnikov-de Haas oscillations and first-principles calculation suggests that the exchange field from Ho 4f moments reconstructs the band structure to induce Weyl points which play a key role in the strong suppression of large-angle carrier scattering. Our findings demonstrate the unique mechanism of colossal negative magnetoresistance and provide pathways towards realizing topological electronic states in a large class of magnetic half-Heusler compounds.

Topics & Concepts

SemimetalMagnetoresistanceCondensed matter physicsHeusler compoundWeyl semimetalTopological insulatorColossal magnetoresistanceMagnetic fieldBand gapHall effectPhysicsElectronic band structureMaterials scienceElectronic structureQuantum mechanicsTopological Materials and Phenomena2D Materials and ApplicationsHeusler alloys: electronic and magnetic properties