Scale and Conformal Invariance in 2d Sigma Models, with an Application to N=4 Supersymmetry

TL;DR

This paper proves that in two-dimensional sigma models with compact target spaces, scale invariance leads to conformal invariance, using Ricci flow and c-theorem arguments, and explores conditions affecting this relation.

Contribution

It provides a direct perturbative proof linking scale and conformal invariance in 2D sigma models and clarifies the role of target space compactness in this equivalence.

Findings

Scale invariance implies conformal invariance in compact target space models.

Obstructions to conformal invariance can occur in non-compact or incomplete target spaces.

Compactness of the target space is necessary and sufficient for the scale-conformal invariance relation.

Abstract

By adapting previously known arguments concerning Ricci flow and the c-theorem, we give a direct proof that in a two-dimensional sigma-model with compact target space, scale invariance implies conformal invariance in perturbation theory. This argument, which applies to a general sigma-model constructed with a target space metric and B-field, is in accord with a more general proof in the literature that applies to arbitrary two-dimensional quantum field theories. Models with extended supersymmetry and a B-field are known to provide interesting test cases for the relation between scale invariance and conformal invariance in sigma-model perturbation theory. We give examples showing that in such models, the obstructions to conformal invariance suggested by general arguments can actually occur in models with target spaces that are not compact or complete. Thus compactness of the target space, or at least a suitable condition of completeness, is necessary as well as sufficient to ensure that scale invariance implies conformal invariance in models of this type.