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Quantum Gravity of Dust Collapse: Shock Waves from Black Holes

Viqar Husain, Jarod George Kelly, Robert Santacruz, Edward Wilson-Ewing

2022Physical Review Letters79 citationsDOIOpen Access PDF

Abstract

We study the quantum gravitational collapse of spherically symmetric pressureless dust. Using an effective equation derived from a polymer quantization in the connection-triad phase space variables of general relativity, we find numerically, for a variety of initial dust configurations, that (i) trapped surfaces form and disappear as an initially collapsing density profile evolves into an outgoing shock wave; (ii) black hole lifetime is proportional to the square of its mass; and (iii) there is no mass inflation at inner apparent horizons. These results provide a substantially different view of black hole formation and subsequent evolution than found from semiclassical analyses.

Topics & Concepts

PhysicsSemiclassical physicsQuantization (signal processing)Black hole (networking)Shock waveGravitational collapsePrimordial black holeGravitational waveClassical mechanicsInflation (cosmology)QuantumPhase spaceWhite holeHawking radiationQuantum fluctuationVirtual black holeQuantum electrodynamicsGravitationGravitational fieldExtremal black holeQuantum mechanicsQuantum gravityPhase (matter)Rotating black holeCharged black holeShock (circulatory)CosmologySquare (algebra)Space (punctuation)Cosmology and Gravitation TheoriesPulsars and Gravitational Waves ResearchQuantum Electrodynamics and Casimir Effect
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