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Quantum black hole–white hole entangled states

S. Jalalzadeh

2022Physics Letters B19 citationsDOIOpen Access PDF

Abstract

We investigate the quantum deformation of the Wheeler–DeWitt equation of a Schwarzchild black hole. Specifically, the quantum deformed black hole is a quantized model constructed from the quantum Heisenberg–Weyl Uq(h4) group. We show that the event horizon area and the mass are quantized, degenerate, and bounded. The degeneracy of states indicates entangled quantum black hole/white hole states. Accordingly, quantum deformation provides a new framework to examine Einstein–Rosen wormhole solutions. Besides, we obtain the mass, the temperature, and the entropy of the q-deformed quantum Schwarzschild black hole. We find an upper bound on the mass of a black hole/white hole pair. Also, at the quantum deformation level, the entropy of the black hole contains three parts: the usual Bekenstein–Hawking entropy, the logarithmic term, and a Cube of usual black hole entropy.

Topics & Concepts

PhysicsWhite holeExtremal black holeBlack hole (networking)Black hole thermodynamicsQuantum mechanicsEvent horizonQuantum discordQuantumOpen quantum systemEntropy (arrow of time)Computer scienceComputer networkRouting (electronic design automation)Event (particle physics)Routing protocolLink-state routing protocolBlack Holes and Theoretical PhysicsCosmology and Gravitation TheoriesNoncommutative and Quantum Gravity Theories
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