Critical behavior of gauge theories and Coulomb gases in three and four dimensions

Abstract

Gauge theories with matter often have critical regions in their parameter space where gapless degrees of freedom emerge. Using controlled semiclassical calculations, we explore such critical regions in SU(N) gauge theories with a topological θ term and NF fundamental fermions in four dimensions, as well as related field theories in three dimensions. In four-dimensional theories, we find that for all NF 1 the critical behavior always occurs at a point in parameter space. For NF>1 this is consistent with the standard QCD expectations, while for NF=1 our results are consistent with recent observations concerning 't Hooft anomalies. We also show how the N-branched structure of observables transmutes into the NF-branched structure seen in chiral Lagrangians as the mass parameter is dialed. As a side benefit, our analysis of these 4D theories implies the unexpected result that 3D Coulomb gases can have gapless critical points. We also consider QCD-like parity-invariant theories in three dimensions, and find that their critical behavior is quite different. In particular, we show that their gapless region is an interval in parameter space, rather than a point. Our results have non-trivial implications for the infrared behavior of three-dimensional compact QED.