Generalised T-Duality and Non-Geometric Backgrounds

TL;DR

This paper systematically explores non-geometric backgrounds in string theory, introducing new classes with dual coordinate dependence, and demonstrates their natural emergence in string field theory and doubled geometry frameworks.

Contribution

It identifies a new class of non-geometric backgrounds with dual coordinate dependence and develops their relation to generalized T-duality and doubled geometry, extending previous flux compactification models.

Findings

Discovery of non-geometric backgrounds with dual coordinate dependence.

Demonstration of generalized T-duality acting without isometries.

Construction of gauged supergravity theories with universal scalar potential.

Abstract

We undertake a systematic analysis of non-geometric backgrounds in string theory by seeking stringy liftings of a class of gauged supergravity theories. In addition to conventional flux compactifications and non-geometric T-folds with T-duality transition functions, we find a new class of non-geometric backgrounds with non-trivial dependence on the dual coordinates that are conjugate to the string winding number. We argue that T-duality acts in our class of theories, including those cases without isometries in which the conventional Buscher rules cannot be applied, and that these generalised T-dualities can take T-folds or flux compactifications on twisted tori to examples of the new non-geometric backgrounds. We show that the new class of non-geometric backgrounds and the generalised T-dualities arise naturally in string field theory, and are readily formulated in terms of a doubled geometry, related to generalised geometry. At special points in moduli space, some of the non-geometric constructions become equivalent to asymmetric orbifolds which are known to provide consistent string backgrounds. We construct the bosonic sector of the corresponding gauged supergravity theories and show that they have a universal form in any dimension, and in particular construct the scalar potential. We apply this to the supersymmetric WZW model, giving the complete non-linear structure for a class of WZW-model deformations.