Kosterlitz-Thouless-like deconfinement mechanism in the 2+1 dimensional Abelian Higgs model

TL;DR

This paper demonstrates that the confinement in a 2+1D Abelian Higgs model is destroyed by matter fields, leading to a Kosterlitz-Thouless-like deconfinement transition characterized by an anomalous gauge field dimension.

Contribution

It introduces a dual sine-Gordon-like theory with anomalous gradient energy to analyze the deconfinement transition and relates critical couplings to compute critical exponents.

Findings

Deconfinement transition is Kosterlitz-Thouless-like.

The theory exhibits a universal jump in stiffness at the transition.

Critical exponents match one-loop RG calculations for the 3D XY-model.

Abstract

We point out that the permanent confinement in a compact 2+1-dimensional U(1) Abelian Higgs model is destroyed by matter fields in the fundamental representation. The deconfinement transition is Kosterlitz-Thouless like. The dual theory is shown to describe a three-dimensional gas of point charges with logarithmic interactions which arises from an anomalous dimension of the gauge field caused by critical matter field fluctuations. The theory is equivalent to a sine-Gordon-like theory in 2+1 dimensions with an anomalous gradient energy proportional to $k^3$. The Callan-Symanzik equation is used to demonstrate that this theory has a massless and a massive phase. The renormalization group equations for the fugacity $y(l)$ and stiffness parameter $K(l)$ of the theory show that the renormalization of $K(l)$ induces an anomalous scaling dimension $\eta_y$ of $y(l)$. The stiffness parameter of the theory has a universal jump at the transition determined by the dimensionality and $\eta_y$. As a byproduct of our analysis, we relate the critical coupling of the sine-Gordon-like theory to an {\it a priori} arbitrary constant that enters into the computation of critical exponents in the Abelian Higgs model at the charged infrared-stable fixed point of the theory, enabling a determination of this parameter. This facilitates the computation of the critical exponent $\nu$ at the charged fixed point in excellent agreement with one-loop renormalization group calculations for the three-dimensional XY-model, thus confirming expectations based on duality transformations.