Center vortex and confinement in Yang-Mills theory and QCD with anomaly-preserving compactifications

Abstract

We construct an anomaly-preserving compactification of 4d gauge theories, including SU(N) Yang-Mills theory, N=1 supersymmetric Yang-Mills theory, and QCD, down to 2d by turning on 't Hooft flux through T2. It provides a new framework to analytically calculate nonperturbative properties such as confinement, chiral symmetry breaking, and multi-branch structure of vacua. We give the semiclassical description of these phenomena based on the center vortex and show that it enjoys the same anomaly matching condition with the original 4d gauge theory. We conjecture that the weak-coupling vacuum structure on small T2 × R2 is adiabatically connected to the strong-coupling regime on R4 without any phase transitions. In QCD with fundamental quarks as well, we can turn on 't Hooft flux either by activating SU(Nf)V symmetry twist for Nf=N flavors or by introducing a magnetic flux of baryon number U(1)B for arbitrary Nf flavors. In both cases, the weak-coupling center-vortex theory gives the prediction consistent with chiral Lagrangian of 4d QCD.