On the perturbative aspects of deformed Yang-Mills theory

Abstract

Centre-stabilised SU(N) Yang-Mills theories on R3 × S1 are QCD-like theories that can be engineered to remain weakly-coupled at all energy scales by taking the S1 circle length L to be sufficiently small. In this regime, these theories admit effective long-distance descriptions as Abelian U(1)N-1 gauge theories on R3, and semiclassics can be reliably employed to study non-perturbative phenomena such as colour confinement and the generation of mass gaps in an analytical setting. At the perturbative tree level, the long-distance effective theory contains (N-1) free photons with identical gauge couplings g23 g2/L. Vacuum polarisation effects, from integrating out heavy charged fields, lift this degeneracy to give N2 distinct values: g2(2L) g3,2 L g2(2πNL) . In this work, we calculate these corrections to one-loop order in theories where the centre-symmetric vacuum is stabilised by 2≤ nf ≤ 5 massive adjoint Weyl fermions with masses of order mλ 2πNL, (also known as "deformed Yang-Mills,") and show that our results agree with those found in previous studies in the mλ 0 limit. Then, we show that our result has an intuitive interpretation as the running of the coupling in a "lattice momentum" in the context of the non-perturbative "emergent latticised fourth dimension" in the N ∞, fixed-NL limit.

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