Topological spin textures in an antiferromagnetic monolayer

TL;DR

This study demonstrates the stabilization and control of topological spin textures, including antiferromagnetic skyrmions, in an intrinsic monolayer material using advanced microscopy and theoretical modeling.

Contribution

It provides the first experimental evidence of topological spin structures in an intrinsic antiferromagnetic monolayer and shows how to manipulate them via heterostructure configurations.

Findings

Antiferromagnetic spin spirals observed in Mn monolayer.

Half-skyrmions form near the boundary of monolayer and double-layer.

Topological states can be controlled by heterostructure configuration.

Abstract

Topological spin structures such as magnetic skyrmions are of fundamental interest and promising for various types of applications in spintronics. Skyrmions have been predicted to emerge also in antiferromagnetic materials where they exhibit superior transport properties. They were experimentally revealed in synthetic antiferromagnets, however, still remain elusive in intrinsic antiferromagnets. Here, we demonstrate the stabilization of topological spin structures in an antiferromagnetic monolayer. Using spin-polarized scanning tunneling microscopy, we observe an antiferromagnetic spin spiral in the Mn monolayer and a collinear antiferromagnetic state in the Mn double-layer on Ta(110). Near the boundary to the double-layer half-skyrmions form in the monolayer as revealed in combination with first-principles calculations and micromagnetic simulations. Our work shows how the topological state in antiferromagnetic material systems can be controlled by the configuration within a lateral heterostructure, resulting in trivial non-coplanar states or antiferromagnetic skyrmions.