Compactness bounds in General Relativity
Abstract
A foundational theorem due to Buchdahl states that, within General Relativity (GR), the maximum compactness of a static, spherically symmetric, perfect fluid object of mass and radius is . As a corollary, there exists a compactness gap between perfect fluid stars and black holes (where ). Here we generalize Buchdahl's result by introducing the most general equation of state for elastic matter with constant longitudinal wave speeds and apply it to compute the maximum compactness of regular, self-gravitating objects in GR. We show that: (i) the maximum compactness grows monotonically with the longitudinal wave speed; (ii) elastic matter can exceed Buchdahl's bound and reach the black hole compactness continuously; (iii) however, imposing subluminal wave propagation lowers the maximum compactness bound to , which we conjecture to be the maximum compactness of \emph{any} static elastic object satisfying causality; (iv) imposing also radial stability further decreases the maximum compactness to . Therefore, although anisotropies are often invoked as a mechanism for supporting horizonless ultracompact objects, we argue that the black hole compactness cannot be reached with physically reasonable matter within GR and that true black hole mimickers require either exotic matter or beyond-GR effects.
Cite
@article{arxiv.2202.00043,
title = {Compactness bounds in General Relativity},
author = {Artur Alho and José Natário and Paolo Pani and Guilherme Raposo},
journal= {arXiv preprint arXiv:2202.00043},
year = {2022}
}
Comments
v2: 4 pages, 4 figures; Version submitted to PRD: Major revision extending the class of elastic materials to describe rigid materials beyond spherical-symmetry. Bounds on the compactness modified accordingly but discussion qualitatively similar to the previous version