The microscopic origin of the spin-induced linear and quadratic magnetoelectric effects

TL;DR

This paper introduces a simple, symmetry-based microscopic approach to understand the origins of linear and quadratic magnetoelectric effects in magnetic materials, providing detailed insights into specific spin contributions.

Contribution

A novel, general method based on local symmetry analysis that identifies microscopic origins of magnetoelectric effects, applicable to various magnetic materials.

Findings

Applied to Cr₂O₃ and RMnO₃, successfully identifying all microscopic mechanisms of ME effects.

Able to locate contributions to ME coefficients down to specific spins or pairs.

Provides a detailed guide for exploring spin-induced magnetoelectric phenomena.

Abstract

Understanding of the intimate cross-coupling between electric and magnetic degrees of freedom in solids usually requires sophisticated models and time-consuming calculation methods. Instead of macroscopic symmetry analysis, we present a simple but general approach to explore the microscopic mechanism of magnetoelectric (ME) effects in magnetic ordered materials based on local spin and lattice symmetry analysis. Our methods are successfully applied to Cr$_2$O$_3$ and orthorhombic RMnO$_3$ with linear and quadratic ME effects, respectively. We revealed all the possible microscopic origins of every non-zero ME coefficients that cannot be easily fulfilled by other theoretical methods. Moreover, the contribution from each mechanism can be located down to specific spins or spin pairs. Our theoretical approach is capable of providing a detailed guide to explore rich spin-induced magnetoelectrics with strong ME effects.