Extreme mass ratio inspirals in the cold vector dark matter environment

TL;DR

This paper investigates how a massive vector dark matter environment influences gravitational wave signals from black hole inspirals, exploring detectability with LISA and comparing results to scalar dark matter scenarios.

Contribution

It models the density profile of vector dark matter around black holes across particle and wave regimes and analyzes its impact on gravitational wave signals for the first time.

Findings

Vector dark matter causes measurable dephasing in gravitational waves.

Detectability of vector dark matter is feasible with upcoming LISA observations.

Distinct features in wave and particle regimes help differentiate dark matter types.

Abstract

With regard to the observed dark matter density profile in galaxies and clusters, the scalar dark matter scenario has been previously studied for potential detectability through gravitational wave observations at measurable signal-to-noise ratios. In the present study, we consider the case of dark matter described by a massive vector field, also referred to as the Proca field. The density profile in the vicinity of the black hole is explicitly constructed for a broad range of dark matter mass, $\mu\sim 10^{-10}-10^{-15}{\mathrm eV}$, which allows it to exhibit both particle and wave-like characteristics. While in the particle regime, the computation of the DM density distribution is analytically tractable, we find it convenient to compute the same numerically in the wave regime. Nevertheless, in the outer region, the surrounding dark matter is assumed to follow a broken power-law distribution, represented by a Navarro-Frenk-White (NFW) profile with a central spike. For the purpose of investigating the detectability of the vector dark matter in the gravitational wave spectrum, we have modelled a stellar-mass black hole ($1M_{\odot}$) inspiralling into a Schwarzschild black hole of mass $10^4M_{\odot}$ within such a vector dark matter environment. With this setup, we analyzed the dephasing in the gravitational wave strain induced by vector dark matter and performed a Fisher forecast for upcoming LISA observations, with particular emphasis on the distinctive features in both the particle and wave regimes of the dark matter. Additionally, most of the important results have been compared with the scalar dark matter case.