Stability of skyrmion lattices and symmetries of quasi-two-dimensional chiral magnets

TL;DR

This paper analyzes the stability and symmetry properties of skyrmion lattices in quasi-two-dimensional chiral magnets, predicting robust skyrmion phases under various symmetries and exploring their dynamic behaviors for potential memory applications.

Contribution

It provides a comprehensive theoretical framework for understanding skyrmion stability and symmetry in 2D systems, including predictions for new lattice phases and their dynamic responses.

Findings

Skyrmion phase remains stable even without in-plane rotational symmetry.

Lowered symmetry enhances stability of vortex-antivortex lattices and in-plane spirals.

Isolated skyrmions can move along currents without side motion, relevant for memory devices.

Abstract

Recently, there has been substantial interest in realizations of skyrmions, in particular in 2D systems due to increased stability resulting from reduced dimensionality. A stable skyrmion, representing the smallest realizable magnetic texture, could be an ideal element for ultra-dense magnetic memories. Here, we use the most general form of the 2D free energy with Dzyaloshinskii-Moriya interactions constructed from general symmetry considerations reflecting the underlying system. We predict that skyrmion phase is robust and it is present even when the system lacks the in-plane rotational symmetry. In fact, the lowered symmetry leads to increased stability of vortex-antivortex lattices with four-fold symmetry and in-plane spirals, in some instances even in the absence of an external magnetic field. Our results relate different hexagonal and square cell phases to the symmetries of materials used for realizations of skyrmions. This will give clear directions for experimental realizations of hexagonal and square cell phases, and will allow engineering of skyrmions with unusual properties. We also predict striking differences in gyro-dynamics induced by spin currents for isolated skyrmions and for crystals where spin currents can be induced by charge carriers or by thermal magnons. We find that under certain conditions, isolated skyrmions can move along the current without a side motion which can have implications for realizations of magnetic memories.