Dyonic Kerr-Sen Black Hole's Resonant Scattering: Absorption and Superradiance

TL;DR

This paper analytically studies scalar superradiant scattering in dyonic Kerr-Sen black holes, revealing how electric and magnetic charges influence energy extraction and superradiant amplification.

Contribution

It provides the first controlled analytical treatment of superradiance in dyonic Kerr-Sen black holes using asymptotic matching, deriving explicit formulas for amplification.

Findings

Electric and magnetic charges suppress superradiant amplification.

Lighter scalar fields broaden the superradiant window.

Energy extraction occurs only for co-rotating modes with a < m a_H.

Abstract

We analytically investigate scalar superradiant scattering in the rotating dyonic Kerr-Sen black hole of Einstein-Maxwell-Dilaton-Axion theory. Starting from the separable Klein-Gordon equation for a massive neutral scalar field, we work in the low-frequency and slow-rotation regime and employ the analytical asymptotic matching (AAM) method to compute the reflection coefficient and the associated superradiant amplification factor. Since an exact global scattering solution is not available in this four-charge geometry, the AAM framework enables a controlled analytic treatment of the near-and far-region dynamics. We provide detailed and systematic derivations of the matching procedure leading to the closed-form amplification formula. The superradiant condition is obtained explicitly and we demonstrate that energy extraction occurs exclusively for co-rotating modes satisfying $\Omega < m \Omega_H$. We show that the presence of electric and magnetic charges suppresses the amplification relative to the Kerr limit, whereas lighter co-rotating scalar fields broaden the superradiant window and enhance the efficiency of rotational energy extraction.