Self-force on a scalar charge in a circular orbit about a Reissner-Nordstr\"om black hole

Abstract

Motivated by applications to the study of self-force effects in scalar-tensor theories of gravity, we calculate the self-force exerted on a scalar charge in a circular orbit about a Reissner-Nordstr\"om black hole. We obtain the self-force via a mode-sum calculation, and find that our results differ from recent post-Newtonian calculations even in the slow-motion regime. We compute the radiative fluxes towards infinity and down the black hole, and verify that they are balanced by energy dissipated through the local self-force - in contrast to the reported post-Newtonian results. The self-force and radiative fluxes depend solely on the black hole's charge-to-mass ratio, the controlling parameter of the Reissner-Nordstr\"om geometry. They both monotonically decrease as the black hole reaches extremality. With respect to an extremality parameter ε, the energy flux through the event horizon is found to scale as ε5/4 as ε → 0.