Litcius/Paper detail

Quantum dynamics of the black hole interior in loop quantum cosmology

Francesco Sartini, Marc Geiller

2021Physical review. D/Physical review. D.27 citationsDOIOpen Access PDF

Abstract

It has been suggested that the homogeneous black hole interior spacetime, when quantized following the techniques of loop quantum cosmology, has a resolved singularity replaced by a black-to-white hole transition. This result has however been derived so far only using effective classical evolution equations, and depends on details of the so-called polymerization scheme for the Hamiltonian constraint. Here we propose to use the unimodular formulation of general relativity to study the full quantum dynamics of this mini-superspace model. When applied to such cosmological models, unimodular gravity has the advantage of trivializing the problem of time by providing a true Hamiltonian which follows a Schr\"odinger evolution equation. By choosing variables adapted to this setup, we show how to write semiclassical states agreeing with that of the Wheeler--DeWitt theory at late times, and how in loop quantum cosmology they evolve through the would-be singularity while remaining sharply peaked. This provides a very simple setup for the study of the full quantum dynamics of these models, which can hopefully serve to tame regularization ambiguities.

Topics & Concepts

Loop quantum cosmologyHamiltonian constraintPhysicsLoop quantum gravityWheeler–DeWitt equationProblem of timeQuantum cosmologyTheoretical physicsClassical mechanicsBlack hole (networking)Initial singularityQuantum gravityBig BounceQuantum dynamicsQuantumQuantum mechanicsComputer scienceDe Sitter universeComputer networkLink-state routing protocolRouting protocolUniverseRouting (electronic design automation)Noncommutative and Quantum Gravity TheoriesBlack Holes and Theoretical PhysicsCosmology and Gravitation Theories