Chiral symmetry breaking of magnetic vortices by sample roughness

TL;DR

This paper uses finite-element micromagnetic simulations to demonstrate that surface roughness in thin magnetic films causes chiral symmetry breaking of vortices, explaining experimentally observed core polarization asymmetries.

Contribution

It reveals that small surface roughness can break vortex symmetry, a novel insight into the effects of sample imperfections on magnetic vortex behavior.

Findings

Surface roughness induces asymmetry in vortex core switching fields.

Small roughness levels reproduce experimental asymmetries.

Broken mirror-symmetry causes different dynamics for vortex handedness.

Abstract

Finite-element micromagnetic simulations are employed to study the chiral symmetry breaking of magnetic vortices, caused by the surface roughness of thin-film magnetic structures. An asymmetry between vortices with different core polarizations has been experimentally observed for square-shaped platelets. E.g., the threshold fields for vortex core switching were found to differ for core up and down. This asymmetry was however not expected for these symmetrically-shaped structures, where both core polarizations should behave symmetrically. Three-dimensional finite element simulations are employed to show that a small surface roughness can break the symmetry between vortex cores pointing up and down. A relatively small sample roughness is found sufficient to reproduce the experimentally observed asymmetries. It arises from the lack of mirror-symmetry of the rough thin-film structures, which causes vortices with different handedness to exhibit asymmetric dynamics.