English

Firewalls, smoke and mirrors

High Energy Physics - Theory 2014-01-08 v1 General Relativity and Quantum Cosmology

Abstract

The radiation emitted by a black hole (BH) during its evaporation has to have some degree of quantum coherence to accommodate a unitary time evolution. We parametrize the degree of coherence by the number of coherently emitted particles NcohN_{coh} and show that it is severely constrained by the equivalence principle. We discuss, in this context, the fate of a shell of matter that falls into a Schwarzschild BH. Two points of view are considered, that of a stationary external observer and that of the shell itself. From the perspective of the shell, the near-horizon region has an energy density proportional to Ncoh2N_{coh}^2 in Schwarzschild units. So, if NcohN_{coh} is parameterically larger than the square root of the BH entropy SBH1/2S_{BH}^ {1/2}, a firewall or more generally a "wall of smoke" forms and the equivalence principle is violated while the BH is still semiclassical. To have a degree of coherence that is parametrically smaller than SBH1/2S_{BH}^{1/2}, one has to introduce a new sub-Planckian gravitational length scale, which likely also violates the equivalence principle. And so our previously proposed model which has Ncoh=SBH1/2N_{coh}=S_{BH}^{1/2} is singled out. From the external-observer perspective, we find that the time it takes for the information about the state of the shell to get re-emitted from the BH is inversely proportional to NcohN_{coh}. When the rate of information release becomes order unity, the semiclassical approximation starts to break down and the BH becomes a perfect reflecting information mirror.

Keywords

Cite

@article{arxiv.1401.1401,
  title  = {Firewalls, smoke and mirrors},
  author = {Ram Brustein and A. J. M. Medved},
  journal= {arXiv preprint arXiv:1401.1401},
  year   = {2014}
}

Comments

18 pages

R2 v1 2026-06-22T02:40:27.986Z