Black holes in an expanding universe and supersymmetry

TL;DR

This paper explores supersymmetric black hole solutions in higher-dimensional supergravity theories, revealing a novel supersymmetry breaking mechanism during dimensional reduction that connects black holes with cosmological models.

Contribution

It introduces a new supersymmetry breaking mechanism arising from non-commuting Killing vectors during dimensional reduction of supergravity solutions.

Findings

Charged nonextremal black holes in FLRW universe

Black holes in Kantowski-Sachs universe

Novel supersymmetry breaking mechanism

Abstract

This paper analyzes the supersymmetric solutions to five and six-dimensional minimal (un)gauged supergravities for which the bilinear Killing vector constructed from the Killing spinor is null. We focus on the spacetimes which admit an additional ${\rm SO}(1,1)$ boost symmetry. Upon the toroidal dimensional reduction along the Killing vector corresponding to the boost, we show that the solution in the ungauged case describes a charged, nonextremal black hole in a Friedmann-Lema\^itre-Robertson-Walker (FLRW) universe with an expansion driven by a massless scalar field. For the gauged case, the solution corresponds to a charged, nonextremal black hole embedded conformally into a Kantowski-Sachs universe. It turns out that these dimensional reductions break supersymmetry since the bilinear Killing vector and the Killing vector corresponding to the boost fail to commute. This represents a new mechanism of supersymmetry breaking that has not been considered in the literature before.