Intermediate mass black holes from stellar mergers in young star clusters

TL;DR

This study uses extensive simulations to explore how intermediate mass black holes form in young star clusters, highlighting the roles of stellar collisions, metallicity, and cluster mass in their formation and pairing with other black holes.

Contribution

It provides new insights into IMBH formation channels, especially the efficiency of runaway stellar collisions versus binary mergers, and the impact of metallicity and cluster mass.

Findings

Runaway stellar collisions are the primary IMBH formation channel at low metallicity.

Binary BH mergers are a rare IMBH formation pathway, suppressed by low escape velocities.

Higher mass clusters are more efficient in forming IMBHs, with up to 8% hosting at least one IMBH.

Abstract

Intermediate mass black holes (IMBHs) in the mass range $10^2-10^5\,\mathrm{M_{\odot}}$ bridge the gap between stellar black holes (BHs) and supermassive BHs. Here, we investigate the possibility that IMBHs form in young star clusters via runaway collisions and BH mergers. We analyze $10^4$ simulations of dense young star clusters, featuring up-to-date stellar wind models and prescriptions for core collapse and (pulsational) pair instability. In our simulations, only 9 IMBHs out of 218 form via binary BH mergers, with a mass $\sim{}100-140$ M$_\odot$. This channel is strongly suppressed by the low escape velocity of our star clusters. In contrast, IMBHs with masses up to $\sim{}438$ M$_{\odot}$ efficiently form via runaway stellar collisions, especially at low metallicity. Up to $\sim{}0.2$~% of all the simulated BHs are IMBHs, depending on progenitor's metallicity. The runaway formation channel is strongly suppressed in metal-rich ($Z=0.02$) star clusters, because of stellar winds. IMBHs are extremely efficient in pairing with other BHs: $\sim{}70$% of them are members of a binary BH at the end of the simulations. However, we do not find any IMBH-BH merger. More massive star clusters are more efficient in forming IMBHs: $\sim{}8$% ($\sim{}1$%) of the simulated clusters with initial mass $10^4-3\times{}10^4$ M$_\odot$ ($10^3-5\times{}10^3$ M$_\odot$) host at least one IMBH.