Analytic treatment of the system of a Kerr-Newman black hole and a charged massive scalar field

Abstract

Charged rotating Kerr-Newman black holes are known to be superradiantly unstable to perturbations of charged massive bosonic fields whose proper frequencies lie in the bounded regime 0 < ω < min \ωc m H + qH,μ\ [here \H, H\ are respectively the angular velocity and electric potential of the Kerr-Newman black hole, and \m,q,μ\ are respectively the azimuthal harmonic index, the charge coupling constant, and the proper mass of the field]. In this paper we study analytically the complex resonance spectrum which characterizes the dynamics of linearized charged massive scalar fields in a near-extremal Kerr-Newman black-hole spacetime. Interestingly, it is shown that near the critical frequency ωc for superradiant amplification and in the eikonal large-mass regime, the superradiant instability growth rates of the explosive scalar fields are characterized by a non-trivial (non-monotonic) dependence on the dimensionless charge-to-mass ratio q/μ. In particular, for given parameters \M,Q, J\ of the central Kerr-Newman black hole, we determine analytically the optimal charge-to-mass ratio q/μ of the explosive scalar field which maximizes the growth rate of the superradiant instabilities in the composed Kerr-Newman-black-hole-charged-massive-scalar-field system.