Title:Imprinting electrically switchable scalar spin chirality by anisotropic strain in a Kagome antiferromagnet

Abstract:Applying strain to epitaxial thin films has proven to be an effective approach for controlling material properties, paving the way for "materials by design". In this study, we explore this concept in the context of topological Kagome antiferromagnets, which can exhibit a range of exotic magnetic states. One such material, Mn$_{3}$Sn, features a non-collinear yet coplanar inverse triangular spin order that lacks scalar spin chirality. By applying anisotropic strain to reduce the point group symmetry of the Kagome triangles from $C_{3v}$ to $C_{1}$, and utilizing the Dzyaloshinskii-Moriya interaction in epitaxial Mn$_{3}$Sn heterostructures, we achieve a canting of the manganese spins out of the Kagome plane. This newly induced magnetic state introduces a finite scalar spin chirality and results in a significant Berry phase in momentum space. Consequently, a large anomalous Hall effect emerges in the Kagome plane at room temperature, which can be fully controlled by charge current, enabling the realization of multiple-stable antiferromagnetic memory states.