Multipolar Anisotropy in Anomalous Hall Effect from Spin-Group Symmetry Breaking

TL;DR

This paper proposes a new theoretical framework for the anomalous Hall effect in ferromagnets, emphasizing spin-group symmetry breaking and spin-orbit interactions, explaining recent experimental observations of in-plane AHE.

Contribution

It introduces a multipolar symmetry-breaking perspective based on spin-group theory, expanding the understanding of AHE beyond traditional magnetization-based models.

Findings

Identifies spin-orbit vectors as key to symmetry breaking.

Develops a multipolar expansion of AHE in powers of spin-orbit coupling.

Explains in-plane AHE through dipolar and octupolar structures.

Abstract

Traditional view of the anomalous Hall effect~(AHE) in ferromagnets is that it arises from the magnetization perpendicular to the measurement plane and that there is a linear dependence on the latter. Underlying such a view is the thinking that the AHE is a time-reversal symmetry breaking phenomenon and can therefore be treated in terms of a power series in the magnetic order. However, this view is squarely challenged by a number of experiments recently, urging for a thorough theoretical investigation on the fundamental level. We find that for strong magnets, it is more appropriate and fruitful to regard the AHE as a spin-group symmetry breaking phenomenon where the critical parameter is the spin-orbit interaction strength, which involves a much smaller energy scale. In ferromagnets, the spin-orbit coupling breaks the $\infty 2^\prime$ spin rotation symmetry, and the key to characterizing such symmetry breaking is the identification of spin-orbit vectors which transform regularly under spin group operations. Born out of our framework is a rich multi-polar relationship between the anomalous Hall conductivity and the magnetization direction, with each pole being expanded progressively in powers of the spin-orbit coupling strength. For the leading order contribution, i.e., the dipole, its isotropic part corresponds to the traditional view, and its anisotropic part can lead to the in-plane AHE where the magnetization lies within the measurement plane. Beyond the dipolar one, the octupolar structure offers the leading order source of nonlinearity and hence introduces unique anisotropy where the dipolar structure cannot. The dipolar and octupolar structure offers a unified explanation for the in-plane AHE recently observed in various ferromagnets, and our comprehensive analysis further extends the candidate material systems.