Atomic-scale visualization of strain-tailored noncollinear spin textures in an antiferromagnetic ultrathin film

Oral-In-person

Abstract

Crystalline strain is typically considered as an effective approach to engineer low-dimensional antiferromagnets. However, a direct visualization of strained-tailored noncollinear spin textures in antiferromagnetic atomic layers has so far not been achieved. Here, we uncover a strain-induced transition from a three-dimensional noncollinear spin state in pseudomorphic Mn bilayer to a cycloidal spin spiral with a canted rotation plane in reconstructed Mn bilayer on the Ag(111) surface. These spin states are spatially imaged on the atomic scale by spin-polarized scanning tunneling microscopy revealing the correlation of atomic and magnetic structures. As demonstrated via first-principles electronic structure theory, the three-dimensional noncollinear spin state arises from the superposition of spin spiral and antiferromagnetic order due to higher-order exchange interactions. In reconstructed Mn bilayer, by contrast, the antiferromagnetic order is hindered by interlayer exchange coupling resulting in a pure spin spiral state. Our work highlights the complex interplay of atomic structure, intra- and interlayer exchange, as well as higher-order exchange interactions at antiferromagnetically coupled interfaces.

Publication: Chen, CJ., Drevelow, T., Lin, YT. et al. Atomic-scale visualization of strain-tailored noncollinear spin textures in an antiferromagnetic ultrathin film. Nat Commun., 16, 7423 (2025). https://doi.org/10.1038/s41467-025-62465-8

Presenters

  • Pin-Jui Hsu

    • National Tsing Hua University

Authors

  • Pin-Jui Hsu

    • National Tsing Hua University
  • Chia-Ju Chen

  • Tim Drevelow

  • Yu-Tung Lin

  • Yi-Pin Chen

  • Tzu-Yen Cheng

  • Yen-Hui Lin

  • Stefan Heinze