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Gravitational Pair Production and Black Hole Evaporation

Michael F. Wondrak, Walter D. van Suijlekom, H. Falcke

2023Physical Review Letters34 citationsDOIOpen Access PDF

Abstract

We present a new avenue to black hole evaporation using a heat-kernel approach analogous as for the Schwinger effect. Applying this method to an uncharged massless scalar field in a Schwarzschild spacetime, we show that spacetime curvature takes a similar role as the electric field strength in the Schwinger effect. We interpret our results as local pair production in a gravitational field and derive a radial production profile. The resulting emission peaks near the unstable photon orbit. Comparing the particle number and energy flux to the Hawking case, we find both effects to be of similar order. However, our pair production mechanism itself does not explicitly make use of the presence of a black hole event horizon.

Topics & Concepts

PhysicsEvent horizonPenrose processBlack hole (networking)Massless particleHawking radiationSchwarzschild radiusSpacetimeCharged black holeScalar fieldGravitational fieldWhite holeSchwarzschild metricCurvatureQuantum field theory in curved spacetimePhoton sphereQuantum electrodynamicsClassical mechanicsGravitationHorizonGravitational collapseQuantum mechanicsGeneral relativityQuantum gravityAstronomyGeometryLink-state routing protocolRouting (electronic design automation)Computer scienceRouting protocolQuantumMathematicsComputer networkQuantum Electrodynamics and Casimir EffectCosmology and Gravitation TheoriesBlack Holes and Theoretical Physics
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