Axion Cloud Decay due to the Axion-photon Conversion with Background Magnetic Fields

TL;DR

This paper calculates the decay rate of an axion cloud around a black hole due to axion-photon conversion in magnetic fields, revealing how different magnetic configurations influence the decay and growth rates.

Contribution

It provides a novel calculation of axion cloud decay rates in monopole and uniform magnetic fields using perturbation methods, with implications for black hole physics.

Findings

Decay rate in monopole background: ~ q^2 κ^2 (GM)^5 μ^8

Decay rate in uniform magnetic field: ~ B_0^2 κ^2 (GM)^7 μ^6

Decay rate can be comparable to superradiant growth rate for certain parameters

Abstract

We consider an axion cloud around a black hole with background magnetic fields. We calculate the decay rate of the axion cloud due to the axion-photon conversion associated with the axion-photon coupling. For simplicity, we consider the situation where the axion configuration is dominated by a solution for the eigenvalue equation equivalent to that for the Hydrogen atom, and the coupling term can be evaluated by a successive perturbation method. For the monopole background, we find the decay rate of the axion cloud is given by $\sim q^2\kappa^2(GM)^5\mu^8$, where $\mu$, $M$, $G$, $\kappa$ and $q$ are the axion mass, black hole mass, gravitational constant, coupling constant of the axion-photon coupling and monopole charge, respectively. For the uniform background magnetic field, we obtain the decay rate of the axion cloud $\sim B_0^2\kappa^2 (GM)^7\mu^6$, where $B_0$ is the magnetic field strength. Applying our formula to the central black hole in our galaxy, we find that the value of the decay rate for the case of the uniform magnetic field is comparable to the growth rate of the superradiant instability with $\kappa\sim 10^{-12}{\rm GeV^{-1}}$, $B_0\sim 10^3{\rm G}$ and $\mu\sim 10^{-18}{\rm eV}$. The ratio is $10^5$ times larger for the monopole magnetic field with the same values of the parameters.