Symmetry-Breaking Magneto-Optical Effects in Altermagnets

TL;DR

This paper predicts strain-induced magneto-optical effects in altermagnets, providing a practical method to distinguish them from antiferromagnets using optical measurements, thereby advancing their exploration for spintronics.

Contribution

It introduces a universal, experimentally accessible approach using strain to identify altermagnets via their unique magneto-optical responses, supported by first-principles calculations.

Findings

Strain selectively breaks symmetries in altermagnets, activating unique optical responses.

Significant optical signatures predicted for prototypical altermagnets.

Method enables rapid, non-invasive identification of altermagnetism.

Abstract

The recently discovered altermagnets (AMs), hosting momentum-dependent spin splitting and vanishing net magnetization, have attracted intensive attention for their promising application in novel spintronics. However, limited by facility and material constraints, experimentally distinguishing them from conventional antiferromagnets (AFMs) remains a challenge, which hinders the high-throughput screening for AM candidates. Here, we predict strain-mediated magneto-optical responses in AMs, which can serve as a universal and experimentally accessible strategy for efficient identification of AMs. Symmetry analysis reveals that uniaxial strain can selectively breaks rotation or mirror symmetries in AMs while preserving $PT$ symmetry in AFMs, thereby activating distinct linear magneto-optical responses (e.g., optical absorption and Kerr rotation) unique to AMs. First-principles calculations across prototypical systems -- including semiconducting V$_2$Se$_2$O monolayer and metallic CrSb bulk -- show that the strain-induced optical signatures are significant enough for conventional optical measurements. Our work establishes a rapid, non-invasive characterization methodology for altermagnetism across material platforms, accelerating its exploration for spin-based technologies.