Moduli in General SU(3)-Structure Heterotic Compactifications

Abstract

In this thesis, we study moduli in compactifications of ten-dimensional heterotic supergravity. We consider supersymmetric compactifications to four-dimensional maximally symmetric space, commonly referred to as the Strominger system. The compact part of space-time X is a six-dimensional manifold of what we refer to as a heterotic SU(3)-structure. We show that this system can be put in terms of a holomorphic operator D on a bundle Q=T*X(TX)(V) TX, defined by a series of extensions. We proceed to compute the infinitesimal deformation space of this structure, given by TM=H(0,1)(Q), which constitutes the infinitesimal spectrum of the four-dimensional theory. In doing so, we find an over counting of moduli by H(0,1)(End(TX)), which can be reinterpreted as O(α') field redefinitions. We next consider non-maximally symmetric domain wall compactifications of the form M10=M3× Y, where M3 is three-dimensional Minkowski space, and Y=R× X is a seven-dimensional non-compact manifold with a G2-structure. Here X is a six dimensional compact space of half-flat SU(3)-structure, non-trivially fibered over R. By focusing on coset compactifications, we show that the compact space X can be endowed with non-trivial torsion, which can be used in a combination with α'-effects to stabilise all geometric moduli. The domain wall can further be lifted to a maximally symmetric AdS vacuum by inclusion of non-perturbative effects. Finally, we consider domain wall compactifications where X is a Calabi-Yau. We show that by considering such compactifications, one can evade the usual no-go theorems for flux in Calabi-Yau compactifications, allowing flux to be used as a tool in such compactifications, even when X is K\"ahler.