Numerical Relativity and High Energy Physics: Recent Developments

TL;DR

This paper reviews recent advances in numerical relativity applied to astrophysics and high-energy physics, highlighting developments in black hole dynamics, scalar-tensor theories, and analog gravity models.

Contribution

It summarizes recent progress within the 'Numerical Relativity and High Energy Physics' network, covering diverse topics like black hole collisions and scalar-tensor solutions.

Findings

Progress in spin evolution of black hole binaries

Insights into high-energy black hole collisions

Development of analog gravity models for phenomena

Abstract

We review recent progress in the application of numerical relativity techniques to astrophysics and high-energy physics. We focus on some developments that took place within the "Numerical Relativity and High Energy Physics" network, a Marie Curie IRSES action that we coordinated, namely: spin evolution in black hole binaries, high-energy black hole collisions, compact object solutions in scalar-tensor gravity, superradiant instabilities and hairy black hole solutions in Einstein's gravity coupled to fundamental fields, and the possibility to gain insight into these phenomena using analog gravity models.