Spin Orientation Driven Polarization in Collinear Magnets

TL;DR

This paper develops a universal symmetry-based theory for spin orientation driven polarization in collinear magnets, explaining mechanisms in multiferroics and guiding materials discovery for spintronics applications.

Contribution

It introduces a symmetry classification framework for spin orientation driven polarization in collinear magnets, integrating relativistic effects and first-principles simulations.

Findings

Classifies spin point groups related to polarization

Explains polarization mechanisms in type-II multiferroics

Predicts polarization in nonpolar collinear antiferromagnets

Abstract

In a collinear magnet, the predominant magnetic moments are collectively aligned along a specific spatial orientation, and this alignment may yield intriguing phenomena such as spin orientation driven polarization. It is well known that spin orientation driven polarization is a relativistic effect that widely occurs in various type-II multiferroics. However, a universal theory that describes such a phenomenon and directs the corresponding materials discovery is lacking. Here, we revisit the magnetic structures of collinear magnets and explore the spin-orientation-dependent phenomena therein. Based on symmetry principles, we analyze the spin point groups (SPGs) that are associated with collinear magnets in the non-relativistic regime, demonstrate how relativistic spin-orbit interaction reduces each SPG to various magnetic point groups that are associated with different magnetic alignments, and classify the SPGs with respect to spin orientation driven polarization. We employ our theory to elucidate the mechanisms of spin orientation driven polarization in a variety of type-II multiferroics. Combined with first-principles simulations, we further show that polarization may be driven in nonpolar collinear antiferromagnets (e.g., CuFeS$_2$) by reorienting their magnetic alignments. Our theory provides guidelines for designing and discovering materials with spin orientation driven polarization, which will benefit the development of spintronics based on type-II multiferroics and related materials.