English

Ultra-massive spacetimes

General Relativity and Quantum Cosmology 2022-12-07 v5 High Energy Physics - Theory

Abstract

A positive cosmological constant Λ>0\Lambda >0 sets an upper limit for the area of marginally future-trapped surfaces enclosing a black hole (BH). Does this mean that the mass of the BH cannot increase beyond the corresponding limit? I analyze some simple spherically symmetric models where regions within a dynamical horizon keep gaining mass-energy so that eventually the Λ\Lambda limit is surpassed. This shows that the black hole proper transmutes into a collapsing universe, and no observers will ever reach infinity, which dematerializes together with the event horizon and the `cosmological horizon'. The region containing the dynamical horizon cannot be causally influenced by the vast majority of the spacetime, its past being just a finite portion of the total, spatially infinite, spacetime. Thereby, a new type of horizon arises, but now relative to past null infinity: the boundary of the past of all marginally trapped spheres, which contains in particular one with the maximum area 4π/Λ4\pi/\Lambda. The singularity is universal and extends mostly outside the collapsing matter. The resulting spacetimes models turn out to be inextendible and globally hyperbolic. It is remarkable that they cannot exist if Λ\Lambda vanishes. Given the accepted value of Λ\Lambda deduced from cosmological observations, such ultra-massive objects will need to contain a substantial portion of the total {\it present} mass of the {\it observable} Universe.

Keywords

Cite

@article{arxiv.2209.14585,
  title  = {Ultra-massive spacetimes},
  author = {José M. M. Senovilla},
  journal= {arXiv preprint arXiv:2209.14585},
  year   = {2022}
}

Comments

22 pages, 11 figures with conformal diagrams. Final version to be published in Portugaliae Mathematica. Minor adjustments and typos corrected. A couple of references added

R2 v1 2026-06-28T02:20:53.017Z