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Quantum censors: backreaction builds horizons

Antonia M. Frassino, Robie A. Hennigar, Juan F. Pedraza, Andrew Svesko

Abstract

Cosmic censorship posits spacetime singularities remain concealed behind event horizons, preserving the determinism of General Relativity. While quantum gravity is expected to resolve singularities, we argue that cosmic censorship remains necessary whenever spacetime has a reliable semi-classical description. Using holography to construct exact solutions to semi-classical gravity, we show backreaction of quantum matter generates horizons -- quantum censors -- to thwart potential violations of censorship. Along with a quantum Penrose inequality, this provides compelling evidence cosmic censorship is robust, even nonperturbatively, in semi-classical gravity.

Quantum censors: backreaction builds horizons

Abstract

Cosmic censorship posits spacetime singularities remain concealed behind event horizons, preserving the determinism of General Relativity. While quantum gravity is expected to resolve singularities, we argue that cosmic censorship remains necessary whenever spacetime has a reliable semi-classical description. Using holography to construct exact solutions to semi-classical gravity, we show backreaction of quantum matter generates horizons -- quantum censors -- to thwart potential violations of censorship. Along with a quantum Penrose inequality, this provides compelling evidence cosmic censorship is robust, even nonperturbatively, in semi-classical gravity.
Paper Structure (5 equations, 1 figure)

This paper contains 5 equations, 1 figure.

Figures (1)

  • Figure 1: Left: AdS/CFT setup with a boundary naked singularity. Right: a (quantum) black hole localized on an ETW brane (red line), where a cutoff CFT couples to gravity.