Geometric confinement in gauge theories

TL;DR

This paper demonstrates that the phenomenological soliton bag model of hadrons naturally emerges from a geometric framework involving warped product metrics on principal bundles, explaining confinement as a geometric collapse of the gauge group.

Contribution

It introduces a geometric interpretation of the soliton bag model using warped metrics, linking confinement to the collapse of the gauge bundle outside a compact region.

Findings

Confinement arises from the collapse of the bundle manifold outside region S.

The model is derived from a warped product metric on the principal G-bundle.

The formation of confined regions is controlled by the order parameter field ρ.

Abstract

In 1978, Friedberg and Lee introduced the phenomenological soliton bag model of hadrons, generalizing the MIT bag model developed in 1974 shortly after the formulation of QCD. In this model, quarks and gluons are confined due to coupling with a real scalar field $\rho$ which tends to zero outside some compact region $S\subset{\mathbb R}^3$ determined dynamically from the equations of motion. The gauge coupling in the soliton bag model is running as the inverse power of $\rho$ already at the semiclassical level. We show that this model arises naturally as a consequence of introducing the warped product metric ${\mathrm{d}}s^2_M + \rho^2{\mathrm{d}}s^2_G$ on the principal $G$-bundle $P(M,G)\cong M\times G$ with a non-Abelian group $G$ over Minkowski space $M={\mathbb R}^{3,1}$. Confinement of quarks and gluons in a compact domain $S\subset{\mathbb R}^3$ is a consequence of the collapse of the bundle manifold $M\times G$ to $M$ outside $S$ due to shrinking of the group manifold $G$ to a point. We describe the formation of such regions $S$ as a dynamical process controlled by the order parameter field $\rho$.