Gravitational waves from binary black holes in a self-interacting scalar dark matter cloud
Alexis Boudon, Philippe Brax, Patrick Valageas, Leong Khim Wong
Abstract
We investigate the imprints of accretion and dynamical friction on the gravitational-wave signals emitted by binary black holes embedded in a scalar dark matter cloud. As a key feature in this work, we focus on scalar fields with a repulsive self-interaction that balances against the self-gravity of the cloud. To a first approximation, the phase of the gravitational-wave signal receives extra correction terms at $\ensuremath{-}3\mathrm{PN}$, $\ensuremath{-}4\mathrm{PN}$, and $\ensuremath{-}5.5\mathrm{PN}$ orders, relative to the prediction of vacuum general relativity, due to cloud gravity, accretion and dynamical friction. Future observations by LISA and DECIGO have the potential to detect these effects for a large range of scalar masses ${m}_{\mathrm{DM}}$ and self-interaction couplings ${\ensuremath{\lambda}}_{4}$. This would correspond to scenarios with dark matter clouds smaller than 0.1 pc, which would be difficult to detect by other probes.