Modulated structures stabilised by spin softening: an expansion in inverse spin anisotropy

TL;DR

This paper presents an analytic expansion method in inverse spin anisotropy to study complex behaviors in spin models with competing interactions, revealing various phase transition phenomena as anisotropy decreases.

Contribution

It introduces a comprehensive analytic approach to analyze spin models with large anisotropy, capturing the emergence of diverse phases as spins soften.

Findings

Identification of multiple phase behaviors near degeneracy points

Demonstration of the method on soft chiral clock and clock models

Results depend strongly on the value of p in the models

Abstract

We develop an analytic approach which allows us to study the behaviour of spin models with competing interactions and $p$-fold spin anisotropy, $D$, in the limit where the pinning potential which results from $D$ is large. This is an expansion in inverse spin anisotropy which must be carried out to all orders where necessary. Interesting behaviour occurs near where the boundary between different ground states is infinitely degenerate for infinite $D$. Here as $D$ decreases and the spins are allowed to soften, we are able to demonstrate the existence of several different behaviours ranging from a single first-order boundary to infinite series of commensurate phases. The method is illustrated by considering the soft chiral clock model and the soft clock model with first- and second-neighbour competing interactions. In the latter case the results are strongly dependent on the value of $p$.