Numerical relativity in higher dimensions

TL;DR

This paper reviews recent advances in numerical relativity for higher-dimensional spacetimes, focusing on black-hole dynamics, collision modeling, and anti-de Sitter space studies within the gauge-gravity duality framework.

Contribution

It provides a comprehensive overview of numerical techniques and recent findings in higher-dimensional black-hole research, highlighting new applications and theoretical insights.

Findings

Insights into black-hole properties in higher dimensions

Modeling of black-hole collisions relevant to Trans-Planckian scattering

Numerical analysis of anti-de Sitter spacetimes in gauge-gravity duality

Abstract

We present an overview of recent developments in numerical relativity studies of higher dimensional spacetimes with a focus on time evolutions of black-hole systems. After a brief review of the numerical techniques employed for these studies, we summarize results grouped into the following three areas: (i) Numerical studies of fundamental properties of black holes, (ii) Applications of black-hole collisions to the modeling of Trans-Planckian scattering, (iii) Numerical studies of asymptotically anti-de Sitter spacetimes in the context of the gauge-gravity duality.