Supersymmetric QCD: Exact Results and Strong Coupling

TL;DR

This paper explores exact results in supersymmetric QCD, clarifying the holomorphy of couplings, the validity of the NSVZ beta function, and the limitations of instanton computations due to infrared divergences.

Contribution

It extends the understanding of holomorphy and the NSVZ scheme, and explains the unreliability of instanton calculations in pure supersymmetric gauge theories.

Findings

Holomorphy of couplings can be made manifest with suitable regularization.

The NSVZ scheme is one among many schemes where the exact beta function holds.

Infrared divergences affect instanton computations, leading to additional contributions in compactified theories.

Abstract

We revisit two longstanding puzzles in supersymmetric gauge theories. The first concerns the question of the holomorphy of the coupling, and related to this the possible definition of an exact (NSVZ) beta function. The second concerns instantons in pure gluodynamics, which appear to give sensible, exact results for certain correlation functions, which nonetheless differ from those obtained using systematic weak coupling expansions. For the first question, we extend an earlier proposal of Arkani-Hamed and Murayama, showing that if their regulated action is written suitably, the holomorphy of the couplings is manifest, and it is easy to determine the renormalization scheme for which the NSVZ formula holds. This scheme, however, is seen to be one of an infinite class of schemes, each leading to an exact beta function; the NSVZ scheme, while simple, is not selected by any compelling physical consideration. For the second question, we explain why the instanton computation in the pure supersymmetric gauge theory is not reliable, even at short distances. The semiclassical expansion about the instanton is purely formal; if infrared divergences appear, they spoil arguments based on holomorphy. We demonstrate that infrared divergences do not occur in the perturbation expansion about the instanton, but explain that there is no reason to think this captures all contributions from the sector with unit topological charge. That one expects additional contributions is illustrated by dilute gas corrections. These are infrared divergent, and so difficult to define, but if non-zero give order one, holomorphic, corrections to the leading result. Exploiting an earlier analysis of Davies et al, we demonstrate that in the theory compactified on a circle of radius beta, due to infrared effects, finite contributions indeed arise which are not visible in the formal limit that beta goes to infinity.