Ordered phases and phase transitions in the fully frustrated XY model on a honeycomb lattice

TL;DR

This paper explores the complex phase diagram of the fully frustrated XY model on a honeycomb lattice, revealing three ordered phases with unique transition mechanisms, including a first-order transition involving fractional vortices.

Contribution

It identifies a novel ordered phase related to zero-energy domain walls and analyzes the nature of phase transitions in the model, highlighting the effects of spin waves and fractional vortices.

Findings

Three distinct ordered phases identified.

First-order phase transition involving fractional vortices.

Long-range order related to domain wall orientation.

Abstract

The phase diagram of the fully frustrated XY model on a honeycomb lattice is shown to incorporate three different ordered phases. In the most unusual of them, a long-range order is related not to the dominance of a particular periodic vortex pattern but to the orientation of zero-energy domain walls separating domains with different orientations of vortex stripes. The phase transition leading to the destruction of this phase can be associated with the appearance of free fractional vortices and is of the first order. The stabilization of the two other ordered phases (existing at lower temperatures) relies a positive contribution to domain-wall free energy induced by the presence of spin waves. This effect has a substantial numerical smallness, in accordance with which these two phases can be observed only in the systems of really macroscopic sizes. In physical systems (like magnetically frustrated Josephson junction arrays and superconducting wire networks), the presence of additional interactions must lead to a better stabilization of the phase with the long-range order in terms of vortex pattern and improve the possibilities of its observation.