U(N) lattice Yang-Mills in the 't Hooft regime
Abstract
We establish a mass gap, prove the existence of a unique infinite volume limit, and give a new proof of the large N limit for U(N) lattice Yang-Mills theory in the 't Hooft regime. These results were previously obtained for SU(N) and SO(N) lattice Yang-Mills theories as applications of the mixing of the associated Langevin dynamics, which is verified via the Bakry-\'Emery criterion [SZZ23]. For U(N), however, this approach fails because its Ricci curvature is not uniformly positive, and as a result the Bakry-\'Emery condition cannot be easily verified. To overcome this obstacle, we recast the U(N) theory as a random-environment SU(N) model, where the randomness arises from a U(1) field, and combine cluster-expansion and Langevin-dynamics techniques to analyze the resulting U(1)×SU(N) model.
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