Black ring formation in particle systems

TL;DR

This paper investigates the conditions under which black ring horizons form in higher-dimensional particle systems, finding that fewer particles are needed for black ring formation as the number of dimensions increases.

Contribution

It provides the first analysis of black ring formation in multi-particle systems across various dimensions, identifying the minimum particle number needed for formation.

Findings

Black ring horizons do not form at collision in high-energy particle systems.

A minimum particle number for black ring formation depends on the spacetime dimension.

Black rings are easier to form in higher dimensions, requiring fewer particles.

Abstract

It is known that the formation of apparent horizons with non-spherical topology is possible in higher-dimensional spacetimes. One of these is the black ring horizon with $S^1\times S^{D-3}$ topology where $D$ is the spacetime dimension number. In this paper, we investigate the black ring horizon formation in systems with $n$-particles. We analyze two kinds of system: the high-energy $n$-particle system and the momentarily-static $n$-black-hole initial data. In the high-energy particle system, we prove that the black ring horizon does not exist at the instant of collision for any $n$. But there remains a possibility that the black ring forms after the collision and this result is not sufficient. Because calculating the metric of this system after the collision is difficult, we consider the momentarily-static $n$-black-hole initial data that can be regarded as a simplified $n$-particle model and numerically solve the black ring horizon that surrounds all the particles. Our results show that there is the minimum particle number that is necessary for the black ring formation and this number depends on $D$. Although many particle number is required in five-dimensions, $n=4$ is sufficient for the black ring formation in the $D\ge 7$ cases. The black ring formation becomes easier for larger $D$. We provide a plausible physical interpretation of our results and discuss the validity of Ida and Nakao's conjecture for the horizon formation in higher-dimensions. Finally we briefly discuss the probable methods of producing the black rings in accelerators.