Room-temperature flexible manipulation of the quantum-metric structure in a topological chiral antiferromagnet
カイラル反強磁性体における量子計量構造の室温下制御
Han, J.*; 内村 友宏*; 荒木 康史
; Yoon, J.-Y.*; 竹内 祐太郎*; 山根 結太*; 金井 駿*; 家田 淳一
; 大野 英男*; 深見 俊輔*
Han, J.*; Uchimura, Tomohiro*; Araki, Yasufumi; Yoon, J.-Y.*; Takeuchi, Yutaro*; Yamane, Yuta*; Kanai, Shun*; Ieda, Junichi; Ohno, Hideo*; Fukami, Shunsuke*
The quantum metric and Berry curvature are two fundamental and distinct factors that describe the geometry of quantum eigenstates. While the role of the Berry curvature in governing various condensed-matter states has been investigated extensively, the quantum metric, which was also predicted to induce topological phenomena of equal importance, has rarely been studied. Recently, a breakthrough has been made in observing the quantum-metric nonlinear transport in a van der Waals magnet, but the effect is limited at cryogenic temperature and is tuned by strong magnetic fields of several teslas. In our study, we demonstrate room-temperature manipulation of the quantum-metric structure of electronic states through its interplay with the interfacial spin texture in a topological chiral antiferromagnet/heavy metal Mn3Sn/Pt heterostructure, which is manifested in a time-reversal-odd second-order Hall effect (ScHE). We show the flexibility of controlling the quantum-metric structure with moderate magnetic fields and verify the quantum-metric origin of the observed ScHE by theoretical modeling. Our results open the possibility of building applicable nonlinear devices by harnessing the quantum-metric structure of electronic states.