Villain model with long-range couplings

TL;DR

This paper investigates whether the long-range Villain model in two dimensions shares the same critical behavior as the long-range XY model, revealing differences in universality classes and connections to the 1D Ising model with inverse-square interactions.

Contribution

The authors generalize the Villain model to include long-range couplings and derive renormalization-group equations, showing that for certain decay exponents, the models differ in universality class.

Findings

Models differ for decay exponent σ<2

Villain model exhibits behavior similar to 1D Ising with 1/r^2 interactions

Decoupling of spin-waves and topological defects is invalid in this regime

Abstract

The nearest-neighbor Villain, or periodic Gaussian, model is a useful tool to understand the physics of the topological defects of the two-dimensional nearest-neighbor $XY$ model, as the two models share the same symmetries and are in the same universality class. The long-range counterpart of the two-dimensional $XY$ model has been recently shown to exhibit a non-trivial critical behavior, with a complex phase diagram including a range of values of the power-law exponent of the couplings decay, $\sigma$, in which there are a magnetized, a disordered and a critical phase (arXiv:2104.13217). Here we address the issue of whether the critical behavior of the two-dimensional $XY$ model with long-range couplings can be described by the Villain counterpart of the model. After introducing a suitable generalization of the Villain model with long-range couplings, we derive a set of renormalization-group equations for the vortex-vortex potential, which differs from the one of the long-range $XY$ model, signaling that the decoupling of spin-waves and topological defects is no longer justified in this regime. The main results are that for $\sigma<2$ the two models no longer share the same universality class. Remarkably, within a large region of its phase diagram, the Villain model is found to behave similarly to the one-dimensional Ising model with $1/r^2$ interactions.