Altermagnetism: an unconventional spin-ordered phase of matter

TL;DR

Altermagnetism is a newly identified spin-ordered phase that uniquely breaks both spin-space and real-space symmetries, offering potential advantages over traditional magnetic phases due to its robustness and symmetry properties.

Contribution

This paper connects altermagnetism to fundamental condensed matter concepts, highlighting its unique symmetry-breaking features and distinguishing it from other spin-ordered states like superfluid 3He.

Findings

Altermagnetism involves collinear compensated spin order with specific wave symmetries.

It spontaneously breaks both spin-space and real-space rotation symmetries.

Initial experiments support the predicted robustness and utility of altermagnetism.

Abstract

The Pauli exclusion principle combined with interactions between fermions is a basic mechanism across condensed-matter systems giving rise to a spontaneous breaking of the spin-space rotation symmetry of spin-ordered phases. Ferromagnetism is a conventional manifestation of spin ordering which leads to numerous applications, e.g., in spintronic information technologies. Altermagnetism, whose recent discovery was largely motivated by spintronics, stands apart from conventional magnetism in the sense that it spontaneously breaks not only spin-space but also real-space rotation symmetries, while it preserves a symmetry combining spin-space and real-space rotations. This is realized on crystals by a collinear compensated ordering of spins with a characteristic d, g or i-wave symmetry. Our Perspective goes beyond the theory of spin arrangements on crystals by connecting altermagnetism to basic notions in condensed matter physics. Specifically, we reflect on the analogies and distinctions of altermagnetism as compared to superfluid 3He and theories of spin ordering in the momentum space generated by other higher-partial-wave instabilities of a Fermi-liquid. On one hand, all these physical systems have in common the extraordinary combination of spontaneous breaking of spin-space and real-space rotation symmetries. On the other hand, we point out that there are key differences, both at the symmetry level and, particularly, at the level of microscopic mechanisms of ordering. These explain the comparatively large abundance, robustness and utility of altermagnetism, as predicted by the symmetry-classification of spin arrangements on crystals and ab initio calculations, and supported by initial experiments.