Symmetry-driven giant magneto-optical Kerr effects in altermagnet hematite

TL;DR

This paper demonstrates giant magneto-optical Kerr effects in altermagnet hematite, enabling optical detection of altermagnetic domains and providing new insights into their spintronic applications.

Contribution

It reveals the connection between MOKE responses and Neel vector orientations in altermagnet hematite, offering a novel method to identify and study altermagnets.

Findings

Giant Kerr rotation angles observed in hematite at room temperature.

MOKE signals correlate with Neel vector orientations.

Optical imaging of altermagnetic domains demonstrated.

Abstract

Altermagnets have attracted tremendous interest for revealing intriguing physics and promising spintronics applications. In contrast to conventional antiferromagnets, altermagnets break both PT and Tt symmetries, and simultaneously exhibit spin-split band structures with a vanishing net magnetization. To quantify insulating altermagnets without conduction electron, we propose to use magneto-optical Kerr effect (MOKE) to identify the altermagnetic fingerprints. In particular, we demonstrate not only the giant MOKE responses, but also their connection with the orientations of Neel vectors at room temperature in altermagnet hematite alpha-Fe_2O_3. Specifically, under the Neel vector along the [1-100] axis, we find a giant polar Kerr rotation angle 93.4 mdeg in the (11-20) plane, which is allowed by the magnetic space group C2'/c'. Under the Neel vector along the [11-20] axis, we find a longitudinal Kerr angle 9.6 mdeg in the (0001) plane, which is allowed by the magnetic space group C2/c. Further, we show that such pronounced MOKE effects directly enable an optical imaging of altermagnetic domains, together with their reversible domain wall (DW) motion. Our studies not only suggest MOKE can be used to identify altermagnet candidates, but also signify the feasibility of exploring altermagnetic optical and DW spintronics, which could largely expand the current research paradigm of altermagnetism.