Geometric Aspects of Type IIA Supersymmetric Backgrounds and Heterotic Anomalies

TL;DR

This paper explores the geometric structures and hidden symmetries of supersymmetric backgrounds in type IIA supergravity and heterotic string theory, revealing integrability and anomaly cancellation properties.

Contribution

It introduces twisted covariant form hierarchies for type IIA supergravity backgrounds and analyzes their hidden symmetries and integrability, also studying holonomy and anomalies in heterotic models.

Findings

Killing spinor bilinears satisfy generalized conformal Killing-Yano equations.

Geodesic flow on these backgrounds is completely integrable.

Anomalies in heterotic sigma models are identified and shown to be cancelable.

Abstract

We construct the twisted covariant form hierarchies (TCFH) of (massive) type IIA supergravity for common sector, D-brane and warped product AdS supersymmetric backgrounds and show that the Killing spinor bilinears satisfy a generalisation of the conformal Killing-Yano equation with respect to the TCFH connections. The Killing-St\"ackel, Killing-Yano and closed conformal Killing-Yano tensors of all spherically symmetric (massive) type IIA brane backgrounds are computed and one demonstrates that the geodesic flow on these solutions is completely integrable by giving all independent charges in involution. The Killing spinor form bilinears that generate hidden symmetries for spinning particle and string probe actions on such backgrounds are identified. The interplay between TCFHs and hidden symmetries of probes propagating on these backgrounds is investigated and used to explore the question of whether charges constructed from these bilinears are sufficient to prove the integrability of such probes on this class of backgrounds. Additionally, some of the properties of TCFHs, such as the reduced holonomy of the minimal TCFH connections for generic backgrounds, are investigated. After this, the algebra of holonomy symmetries of sigma models propagating on supersymmetric heterotic backgrounds with a non-compact holonomy group is determined. One demonstrates that these close as a W-algebra that is specified by a Lie algebra structure on the space of covariantly constant forms that generate the holonomy symmetries. In addition, the chiral anomalies associated with these symmetries are identified. Finally, it is argued that these anomalies are consistent and can be cancelled up to two loops in the sigma model perturbation theory.