Gravitational Collapse and Black Hole Formation in a Braneworld

TL;DR

This thesis presents the first numerical analysis of gravitational collapse in braneworlds, demonstrating black hole formation with unique geometries and suggesting a no-hair theorem in RSII models.

Contribution

It introduces a novel numerical relativity framework adapted for braneworld scenarios, confirming black hole properties consistent with static solutions.

Findings

Black holes extend into the bulk with shape changing from sphere to pancake or cigar.

Black hole geometries are similar regardless of initial data profiles, supporting a no-hair theorem.

The ADM mass on the brane equals the total mass of the braneworld system.

Abstract

In this thesis we present the first numerical study of gravitational collapse in braneworlds within the framework of the single brane model proposed by Randall and Sundrum (RSII). We directly show that the evolutions of sufficiently strong initial data configurations result in black holes (BHs) with finite extension into the bulk. The extension changes from sphere to pancake (or cigar, seen from a different perspective) as the size of BH increases. We find preliminary evidences that BHs of the same size generated from distinct initial data profiles are geometrically indistinguishable. As such, a no-hair theorem of BH (uniqueness of BH) is suggested to hold in the RSII spacetimes studied in this thesis---these spacetimes are axisymmetric without angular momentum and non-gravitational charges. In particular, the BHs we obtained as the results of the dynamical system, are consistent with the ones previously obtained from a static vacuum system by Figueras and Wiseman. We also obtained some results in closed form without numerical computation such as the equality of ADM mass of the brane with the total mass of the braneworld. The calculation within the braneworld requires advances in the formalism of numerical relativity (NR). The regularity problem in previous numerical calculations in axisymmetric (and spherically symmetric) spacetimes, is actually associated with neither coordinate systems nor the machine precision. The fundamental variables (the unknown functions to be solved for in numerical calculations) are more important to make the numerical calculations in cylindrical coordinates regular. The generalized harmonic (GH) formalism and the BSSN formalism for general relativity are developed to make them suitable for calculations in non-Cartesian coordinates under non-flat background. A conformal function of the metric is included into the GH formalism to simulate the braneworld.