Frustration-driven topological textures on the honeycomb lattice: antiferromagnetic meron-antimeron and skyrmion crystals emerging from spiral spin liquids

TL;DR

This paper demonstrates that weak next-nearest-neighbor Dzyaloshinskii-Moriya interactions in a frustrated honeycomb antiferromagnet induce various topological magnetic textures, including meron-antimeron pairs and skyrmion crystals, with phase behavior influenced by frustration and temperature.

Contribution

It reveals the emergence of antiferromagnetic meron-antimeron and skyrmion phases in a frustrated honeycomb lattice due to weak DM interactions, expanding understanding of topological textures in antiferromagnets.

Findings

Meron-antimeron pair crystals and gases appear at low frustration.

A two-layer-like antiferromagnetic skyrmion crystal stabilizes at higher frustration.

Distinct skyrmion phases with different sizes occur at low temperatures.

Abstract

Skyrmions -- topologically nontrivial magnetic quasi-particles -- can emerge in two-dimensional chiral magnets due to moderate or high strength of the Dzyaloshinskii-Moriya (DM) interaction. In this work, we show that the inclusion of weak next-nearest-neighbor DM interaction in the frustrated $J_1$-$J_2$ honeycomb-lattice Heisenberg antiferromagnet leads to the emergence of field-induced incommensurate antiferromagnetic meron-antimeron pairs and antiferromagnetic skyrmion structures. Using the Luttinger-Tisza approximation and large-scale Monte Carlo simulations, we report that for lower frustration values, antiferromagnetic meron-antimeron pair crystal and gas phases emerge within a small magnetic field window. In these meron phases, the fundamental unit consists of a meron-antimeron pair residing on different sublattices of the honeycomb lattice, even in the gas phase, where they exhibit greater mobility. For larger frustration, a two-layer-like three-sublattice antiferromagnetic skyrmion crystal phase is stabilized over a wider magnetic field range. At lower temperatures, this region splits into two distinct antiferromagnetic skyrmion phases with skyrmions of different sizes, reflecting the influence of frustration and thermal effects on the stabilization of these topological textures. Interestingly, both meron and skyrmion low-temperature phases connect to spiral spin liquid phases of the honeycomb lattice at higher temperatures. Additionally, we analyze the emergent single-$q$ and double-$q$ phases at low temperatures, constructing a comprehensive phase diagram.