Confinement on $R^{3}\times S^{1}$: continuum and lattice

TL;DR

This paper reviews recent advances in understanding confinement in SU(N) gauge theories on $R^{3} imes S^{1}$, highlighting continuum and lattice approaches that utilize topological effects and symmetry reduction to explain confinement mechanisms.

Contribution

It compares continuum and lattice methods for studying confinement, emphasizing the role of topological effects and symmetry reduction in both frameworks.

Findings

Analytic computation of string tension from topological effects in continuum.

Lattice models exhibit confinement behavior similar to continuum models.

Reduction of symmetry from SU(N) to U(1)^{N-1} is key to understanding confinement.

Abstract

There has been substantial progress in understanding confinement in a class of four-dimensional SU(N) gauge theories using semiclassical methods. These models have one or more compact directions, and much of the analysis is based on the physics of finite-temperature gauge theories. The topology $R^{3}\times S^{1}$ has been most often studied, using a small compactification circumference $L$ such that the running coupling $g^{2}\left(L\right)$ is small. The gauge action is modified by a double-trace Polyakov loop deformation term, or by the addition of periodic adjoint fermions. The additional terms act to preserve $Z(N)$ symmetry and thus confinement. An area law for Wilson loops is induced by a monopole condensate. In the continuum, the string tension can be computed analytically from topological effects. Lattice models display similar behavior, but the theoretical analysis of topological effects is based on Abelian lattice duality rather than on semiclassical arguments. In both cases the key step is reducing the low-energy symmetry group from $SU(N)$ to the maximal Abelian subgroup $U(1)^{N-1}$ while maintaining $Z(N)$ symmetry.