Consistent truncations from the geometry of sphere bundles

TL;DR

This paper offers a geometric framework for understanding sphere consistent truncations using the global angular form, providing universal formulas for flux ansatzes that incorporate nonabelian symmetries and scalar deformations, with implications for supersymmetry.

Contribution

It introduces a unified geometric approach to sphere truncations based on the global angular form, deriving universal flux formulas and fixing scalar shifts through supersymmetry-inspired conditions.

Findings

Universal formula for flux threading the n-sphere

Scalar deformations captured by coset structures

Fixing scalar shifts via supersymmetry conditions

Abstract

In this paper, we present a unified perspective on sphere consistent truncations based on the classical geometric properties of sphere bundles. The backbone of our approach is the global angular form for the sphere. A universal formula for the Kaluza-Klein ansatz of the flux threading the $n$-sphere captures the full nonabelian isometry group $SO(n+1)$ and scalar deformations associated to the coset $SL(n+1,\mathbb R)/SO(n+1)$. In all cases, the scalars enter the ansatz in a shift by an exact form. We find that the latter can be completely fixed by imposing mild conditions, motivated by supersymmetry, on the scalar potential arising from dimensional reduction of the higher dimensional theory. We comment on the role of the global angular form in the derivation of the topological couplings of the lower-dimensional theory, and on how this perspective could provide inroads into the study of consistent truncations with less supersymmetry.