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Black Hole Unitarity and Antipodal Entanglement
Foundations of Physics 46 (9):1185-1198 (2016)
Abstract
Hawking particles emitted by a black hole are usually found to have thermal spectra, if not exactly, then by a very good approximation. Here, we argue differently. It was discovered that spherical partial waves of in-going and out-going matter can be described by unitary evolution operators independently, which allows for studies of space-time properties that were not possible before. Unitarity dictates space-time, as seen by a distant observer, to be topologically non-trivial. Consequently, Hawking particles are only locally thermal, but globally not: we explain why Hawking particles emerging from one hemisphere of a black hole must be 100 % entangled with the Hawking particles emerging from the other hemisphere. This produces exclusively pure quantum states evolving in a unitary manner, and removes the interior region for the outside observer, while it still completely agrees locally with the laws of general relativity. Unitarity is a starting point; no other assumptions are made. Region I and the diametrically opposite region II of the Penrose diagram represent antipodal points in a PT or CPT relation, as was suggested before. On the horizon itself, antipodal points are identified. A candidate instanton is proposed to describe the formation and evaporation of virtual black holes of the type described here.Links
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Citations of this work
Fast Vacuum Fluctuations and the Emergence of Quantum Mechanics.Gerard ’T. Hooft - 2021 - Foundations of Physics 51 (3):1-24.
Time Symmetric Quantum Mechanics and Causal Classical Physics?Fritz W. Bopp - 2017 - Foundations of Physics 47 (4):490-504.
Virtual Black Holes and Space–Time Structure.Gerard ’T. Hooft - 2018 - Foundations of Physics 48 (10):1134-1149.
The Firewall Transformation for Black Holes and Some of Its Implications.Gerard ’T. Hooft - 2017 - Foundations of Physics 47 (12):1503-1542.
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