Accelerating boundary analog of a Kerr black hole
Michael R. R. Good, Joshua Foo, Eric V. Linder
Abstract
Abstract An accelerated boundary correspondence (i.e. a flat spacetime accelerating mirror trajectory) is derived for the Kerr spacetime, with a general formula that ranges from the Schwarzschild limit (zero angular momentum) to the extreme maximal spin case (yielding asymptotic uniform acceleration). The beta Bogoliubov coefficients reveal the particle spectrum is a Planck distribution at late times with temperature cooler than a Schwarzschild black hole, due to the ‘spring constant’ analog of angular momentum. The quantum stress tensor indicates a constant emission of energy flux at late times consistent with eternal thermal equilibrium.
Topics & Concepts
PhysicsSchwarzschild radiusKerr metricRotating black holeQuantum field theory in curved spacetimeAngular momentumSchwarzschild metricClassical mechanicsSpacetimeBlack hole (networking)Quantum electrodynamicsQuantum mechanicsMathematical physicsQuantumQuantum gravityGeneral relativityRouting (electronic design automation)Routing protocolComputer scienceComputer networkLink-state routing protocolQuantum Electrodynamics and Casimir EffectExperimental and Theoretical Physics StudiesRelativity and Gravitational Theory