A divergent volume for black holes calls for no "firewall"
- URL: http://arxiv.org/abs/2002.09823v1
- Date: Sun, 23 Feb 2020 04:11:19 GMT
- Title: A divergent volume for black holes calls for no "firewall"
- Authors: Baocheng Zhang and Li You
- Abstract summary: This paper proposes a scenario that rescinds firewall by introducing the concept of volume for a black hole.
We show that the volume and its associated entropy for a collapsed black hole diverges if the final evaporation stage is treated using noncommutative space.
- Score: 8.747032648802117
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: The presumption that Hawking radiations are thermally distributed can be
considered to result from their entanglement with the internal degrees of
freedom for a black hole. This leads to the "firewall" paradox if unitary
evolution continues into Page's time when a black hole evaporates away half of
its initial entropy. However, if the interior of a black hole houses sufficient
degrees of freedom to maintain entanglement with the outside at all times,
unitarity can be preserved during the complete radiation process and no
firewall will be required. This paper proposes a scenario that rescinds
firewall by introducing the concept of volume for a black hole. Based on the
operational definition by Christodoulou and Rovelli [1], we show that the
volume and its associated entropy for a collapsed black hole diverges if the
final evaporation stage is treated using noncommutative space. This implicates
the interior of a black hole possesses adequate space to store information for
a black hole of any mass, like the inside of a "magician's bag".
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