Black holes in an expanding universe from fake supergravity

TL;DR

This paper constructs new multi-centered black hole solutions in an expanding universe within fake supergravity, revealing their properties and connections to previous solutions, with implications for black hole physics in cosmological settings.

Contribution

It introduces a method to generate multi-centered black hole solutions in an expanding universe using fake supergravity, linking them to known solutions and analyzing their physical properties.

Findings

Constructed new multi-centered black hole solutions in FLRW universe.

Identified the role of prepotential exponents in solution parameters.

Analyzed horizon structure and thermodynamic properties.

Abstract

In arXiv:0902.4814, a general recipe to construct fake supersymmetric solutions to fake N=2, d=4 gauged supergravity coupled to abelian vector multiplets was presented. We use these results to find new multi-centered black hole solutions in an asymptotically FLRW universe. These satisfy the weak energy condition and are maximally charged under two U(1) gauge fields coupled to a scalar, which drives the cosmic expansion while rolling down its potential. As a special subcase, our black holes include the ones constructed previously by Gibbons and Maeda in arXiv:0912.2809. The latter contain two non-negative real numbers n_S, n_T obeying the constraint n_S+n_T=4, with the cases n_T=4 and n_T=1 corresponding to the Kastor-Traschen and the Maeda-Ohta-Uzawa solution respectively. We show that n_S, n_T arise directly as exponents in the prepotential of the fake supergravity theory, and that the above constraint stems from the fact that the prepotential must be a homogeneous function of degree two. Finally, some physical properties of the black holes, like asymptotic behaviour, curvature singularities and trapping horizons, are also discussed. Similar to other solutions that appeared previously in the literature, there is a symmetry enhancement near the event horizon, which becomes therefore a Killing horizon, in spite of the highly dynamical nature of the original spacetime. The temperature associated to this Killing horizon turns out to be nonvanishing.