# Merging black holes in young star clusters

**Authors:** Ugo N. Di Carlo, Nicola Giacobbo, Michela Mapelli, Mario Pasquato,, Mario Spera, Long Wang, Francesco Haardt

arXiv: 1901.00863 · 2019-06-26

## TL;DR

This study uses N-body simulations to explore how young star cluster dynamics influence the properties and formation channels of merging binary black holes, revealing distinctive mass and merger time signatures.

## Contribution

It introduces a novel population-synthesis approach combined with N-body simulations to analyze the impact of star cluster dynamics on black hole mergers.

## Key findings

- Dynamical exchanges form over 50% of merging BBHs in young star clusters.
- Merging BBHs in star clusters are significantly more massive than those in isolated binaries.
- Star cluster dynamics accelerate the merger process and can produce black holes in the pair-instability mass gap.

## Abstract

Searching for distinctive signatures, which characterize different formation channels of binary black holes (BBHs), is a crucial step towards the interpretation of current and future gravitational wave detections. Here, we investigate the demography of merging BBHs in young star clusters (SCs), which are the nursery of massive stars. We performed $4\times{} 10^3$ N-body simulations of SCs with metallicity $Z=0.002$, initial binary fraction $0.4$ and fractal initial conditions, to mimic the clumpiness of star forming regions. Our simulations include a novel population-synthesis approach based on the code MOBSE. We find that SC dynamics does not affect the merger rate significantly, but leaves a strong fingerprint on the properties of merging BBHs. More than 50 % of merging BBHs in young SCs form by dynamical exchanges in the first few Myr. Dynamically formed merging BBHs are significantly heavier than merging BBHs in isolated binaries: merging BBHs with total mass up to $\sim{}120$ M$_\odot$ form in young SCs, while the maximum total mass of merging BBHs in isolated binaries with the same metallicity is only $\sim{}70$ M$_\odot$. Merging BBHs born via dynamical exchanges tend to have smaller mass ratios than BBHs in isolated binaries. Furthermore, SC dynamics speeds up the merger: the delay time between star formation and coalescence is significantly shorter in young SCs. In our simulations, massive systems such as GW170729 form only via dynamical exchanges. Finally $\sim{}2$ % of merging BBHs in young SCs have mass in the pair-instability mass gap ($\sim{}60-120$ M$_\odot$). This represents a unique fingerprint of merging BBHs in SCs.

## Full text

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## Figures

27 figures with captions in the complete paper: https://tomesphere.com/paper/1901.00863/full.md

## References

157 references — full list in the complete paper: https://tomesphere.com/paper/1901.00863/full.md

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Source: https://tomesphere.com/paper/1901.00863