Black holes as frozen stars: Regular interior geometry

TL;DR

This paper introduces a regularized interior geometry model for frozen stars, a type of black hole mimicker, demonstrating their causal structure and the behavior of infalling objects within this regularized spacetime.

Contribution

The authors develop a fully regularized coordinate system for frozen star interiors, maintaining negative radial pressure and analyzing the causal and dynamical properties of the model.

Findings

Infalling objects effectively stick to the star's surface.

Objects with angular momentum are reflected by a potential barrier.

The causal structure degenerates in the limit as regularization parameter approaches zero.

Abstract

We have proposed a model geometry for the interior of a regular black hole mimicker, the frozen star, whose most startling feature is that each spherical shell in its interior is a surface of infinite redshift. The geometry is a solution of the Einstein equations which is sourced by an exotic matter with maximally negative radial pressure. The frozen star geometry was previously presented in singular coordinates for which $-g_{tt}$ and $g^{rr}$ vanish in the bulk and connect smoothly to the Schwarzschild exterior. Additionally, the geometry was mildly singular in the center of the star. Here, we present regular coordinates for the entirety of the frozen star. Each zero in the metric is replaced with a small, dimensionless parameter $\varepsilon$; the same parameter in both $-g_{tt}$ and $g^{rr}$ so as to maintain maximally negative radial pressure. We also regularize the geometry, energy density and pressure in the center of the star in a smooth way. Our initial analysis uses Schwarzschild-like coordinates and applies the Killing equations to show that an infalling, point-like object will move very slowly, effectively sticking to the surface of the star and never coming out. If one nevertheless follows the trajectory of the object into the interior of the star, it moves along an almost-radial trajectory until it comes within a small distance from the star's center. Once there, if the object has any amount of angular momentum at all, it will be reflected outwards by a potential barrier onto a different almost-radial trajectory. Finally, using Kruskal-like coordinates, we consider the causal structure of the regularized frozen star and discuss its $\varepsilon\to 0$ limit, for which the geometry degenerates and becomes effectively two dimensional.