The growth of intermediate mass black holes through tidal captures and tidal disruption events

TL;DR

This study uses N-body simulations to explore how tidal interactions and disruptions in dense star clusters can lead to the growth of intermediate-mass black holes, highlighting the importance of TDEs in black hole evolution.

Contribution

The paper introduces detailed N-body simulations including post-Newtonian effects to quantify TDE rates and demonstrate black hole growth via tidal interactions in dense star clusters.

Findings

TDE rates depend on black hole mass, density, and velocity dispersion.

Most TDEs originate from stars in the Bahcall-Wolf cusp.

TDEs can significantly increase black hole mass within a Gyr.

Abstract

We present $N\mathrm{-body} $ simulations, including post-Newtonian dynamics, of dense clusters of low-mass stars harbouring central black holes (BHs) with initial masses of 50, 300, and 2000 $\mathrm{M_{\odot}}$. The models are evolved with the $N\mathrm{-body} $ code \textsc{bifrost} to investigate the possible formation and growth of massive BHs by the tidal capture of stars and tidal disruption events (TDEs). We model star-BH tidal interactions using a velocity-dependent drag force, which causes orbital energy and angular momentum loss near the BH. About $\sim 20-30$ per cent of the stars within the spheres of influence of the black holes form Bahcall-Wolf cusps and prevent the systems from core collapse. Within the first 40 Myr of evolution, the systems experience 500 up to 1300 TDEs, depending on the initial cluster structure. Most ($> 95$ per cent) of the TDEs originate from stars in the Bahcall-Wolf cusp. We derive an analytical formula for the TDE rate as a function of the central BH mass, density and velocity dispersion of the clusters ($\dot{N}_{\mathrm{TDE}} \propto M\mathrm{_{BH}} \rho \sigma^{-3}$). We find that TDEs can lead a 300 $\mathrm{M_{\odot}}$ BH to reach $\sim 7000 \mathrm{M_{\odot}}$ within a Gyr. This indicates that TDEs can drive the formation and growth of massive BHs in sufficiently dense environments, which might be present in the central regions of nuclear star clusters.