Integrating out lattice gauge fields

TL;DR

This paper introduces an exact, link-variable-free representation of lattice gauge theory's partition function, potentially aiding in solving the sign problem in finite-density QCD through diagrammatic Monte Carlo methods.

Contribution

It presents a novel exact representation of lattice gauge theory without link variables, extendable to include fermions, improving upon previous strong coupling limited methods.

Findings

Exact link-variable-free representation of lattice gauge theories.

Extension to include staggered fermions and fermionic loops.

Application to compact lattice QED as a concrete example.

Abstract

The sign problem is a major obstacle to our understanding of the phase diagram of QCD at finite baryon density. Several numerical methods have been proposed to tackle this problem, but a full solution to the sign problem is still elusive. Motivated by this problem and by recent advances in diagrammatic Monte Carlo methods, we find a new exact representation of the partition function of pure lattice gauge theory that contains no link variables. This approach can be easily extended to include staggered fermions, and results in a diagrammatic representation of fermionic states as arrangements of monomers, dimers, and fermionic loops saturating the spacetime lattice. Our representations are exact for any value of the lattice coupling, and extend previous representations that are only valid in the strong coupling limit and at $O(\beta)$. As a concrete example, we construct a monomer-dimer-loop representation of compact lattice QED.