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Lifetime of scalar cloud formation around a rotating regular black hole

Mohsen Khodadi, Reza Pourkhodabakhshi

2022Physical review. D/Physical review. D.22 citationsDOI

Abstract

Does circumventing the curvature singularity of the Kerr black hole affect the timescale of the scalar cloud formation around it? By definition, the scalar cloud, forms a gravitational atom with hydrogen-like bound states, lying on the threshold of a massive scalar field's superradiant instability regime (time-growing quasibound states) and beyond (time-decaying quasibound states). By taking a novel type of rotating hollow regular black hole proposed by Simpson and Visser which unlike its standard rivals has an asymptotically Minkowski core, we address this question. The metric has a minimal extension relative to the standard Kerr, originating from a single regularization parameter $\ensuremath{\ell}$, with length dimension. We show with the inclusion of the regularization length scale $\ensuremath{\ell}$ into the Kerr spacetime, without affecting the standard superradiant instability regime, the timescale of scalar cloud formation gets shorter. Since the scalar cloud after its formation, via energy dissipation, can play the role of a continuum source for gravitational waves, such a reduction in the instability growth time improves the phenomenological detection prospects of new physics because the shorter the time, the more astrophysically important.

Topics & Concepts

PhysicsScalar fieldScalar (mathematics)Rotating black holeSuperradianceGravitational collapseInstabilitySpacetimeBlack hole (networking)Classical mechanicsMathematical physicsQuantum mechanicsAngular momentumGeometryComputer networkRouting (electronic design automation)Computer scienceRouting protocolLink-state routing protocolMathematicsLaserAstrophysical Phenomena and ObservationsPulsars and Gravitational Waves ResearchBlack Holes and Theoretical Physics
Lifetime of scalar cloud formation around a rotating regular black hole | Litcius