Anisotropic Surface Spin Waves as Signature of A-type Altermagnets

TL;DR

This paper identifies unique anisotropic surface spin waves in A-type altermagnets, providing a potential experimental signature for their detection and implications for spintronic devices.

Contribution

The discovery of anisotropic surface spin waves as a signature of A-type altermagnets, which are absent in ferromagnets and conventional antiferromagnets.

Findings

Anisotropic surface spin waves are unique to A-type altermagnets.

These waves exhibit chirality-dependent top-bottom positions.

Experimental detection methods include stray field measurement and resonance absorption spectrum.

Abstract

Altermagnets have attracted intense interest because they have the advantages of both ferromagnets and antiferromagnets. However, their experimental identification remains challenging, in particular for the A-type altermagnets that account for a large group of material candidates. Here, we discover a kind of anisotropic surface spin waves in A-type altermagnets, which is absent in ferromagnets and conventional antiferromagnets. The anisotropic surface spin waves arise directly from the nature of altermagnets, i.e., the spin-opposite sublattices cannot be related by translation or inversion, which breaks the combined spatial-inversion and time-reversal symmetry, leading to the anisotropic surface spin waves with two properties, the chirality-dependent top-bottom positions and chiral split constant frequency contours. We further show that these two properties can be measured experimentally from the stray field and by resonance absorption spectrum, respectively. Our results provide a signature for detecting altermagnets and will inspire spin-based logic and information-storage devices.