The charged black-hole bomb: A lower bound on the charge-to-mass ratio of the explosive scalar field

TL;DR

This paper analytically derives a lower bound on the charge-to-mass ratio of a scalar field necessary for superradiant instability in a charged black-hole bomb system, confirming previous numerical results.

Contribution

It provides the first analytical lower bound on the charge-to-mass ratio for superradiant instability in the charged black-hole bomb system, aligning with numerical findings.

Findings

Derived an analytical lower bound for q/μ for instability

Confirmed the bound matches numerical instability spectra

Enhanced understanding of superradiant instability conditions

Abstract

The well-known superradiant amplification mechanism allows a charged scalar field of proper mass $\mu$ and electric charge $q$ to extract the Coulomb energy of a charged Reissner-Nordstr\"om black hole. The rate of energy extraction can grow exponentially in time if the system is placed inside a reflecting cavity which prevents the charged scalar field from escaping to infinity. This composed black-hole-charged-scalar-field-mirror system is known as the {\it charged black-hole bomb}. Previous numerical studies of this composed physical system have shown that, in the linearized regime, the inequality $q/\mu>1$ provides a necessary condition for the development of the superradiant instability. In the present paper we use analytical techniques to study the instability properties of the charged black-hole bomb in the regime of linearized scalar fields. In particular, we prove that the lower bound ${{q}\over{\mu}}>\sqrt{{{r_{\text{m}}/r_--1}\over{r_{\text{m}}/r_+-1}}}$ provides a necessary condition for the development of the superradiant instability in this composed physical system (here $r_{\pm}$ are the horizon radii of the charged Reissner-Nordstr\"om black hole and $r_{\text{m}}$ is the radius of the confining mirror). This {\it analytically} derived lower bound on the superradiant instability regime of the composed black-hole-charged-scalar-field-mirror system is shown to agree with direct {\it numerical} computations of the instability spectrum.