Topological defects in helical magnets

TL;DR

This paper reviews the topological defects in helical magnets, discusses recent experimental discoveries of domain walls with novel properties, and presents theoretical insights into their formation, types, and characteristics.

Contribution

It provides a theoretical explanation for the existence of domain walls with arbitrary angles in helical magnets and analyzes their properties and spin textures.

Findings

Existence of smooth and zig-zag domain walls depends on the angle between helical wave vectors.

Domain wall width varies with the angle between wave vectors.

Theoretical predictions align with recent experimental observations.

Abstract

Helical magnets which violated space inversion symmetry have rather peculiar topological defects. In isotropic helical magnets with exchange and Dzyaloshinskii-Moriya interactions there are only three types of linear defects: $\pm\pi$ and $2\pi$-disclinations. Weak crystal anysotropy suppresses linear defects on large scale. Instead planar defects appear: domain walls that separate domains with different preferential directions of helical wave vectors. The appearance of such domain walls in the bulk helical magnets and some of their properties were predicted in the work \cite{Li 2012}. In a recent work by an international team of experimenters and theorists \cite{Schoenherr 2018} the existence of new types of domain walls on crystal faces of helical magnet FeGe was discovered. They have many features predicted by theory \cite{Li 2012}, but display also unexpected properties, one of them is the possibility of arbitrary angle between helical wave vectors. Depending on this angle the domain walls observed in \cite{Schoenherr 2018} can be divided in two classes: smooth and zig-zag. This article contains a mini-review of the existing theory and experiment. It also contains new results that explain why in a system with continuos orientation of helical wave vectors domain walls are possible. We discuss why and at what conditions smooth and zig-zag domain walls appear, analyze spin textures associated with helical domain walls and find the dependence of their width on angle between helical wave vectors.