Formation and Evolution of Compact Object Binaries in AGN Disks

TL;DR

This paper investigates how compact object binaries form, evolve, and merge in AGN disks, revealing a dominant gas capture formation channel and predicting high merger rates with distinctive observational signatures.

Contribution

It introduces a semi-analytical model combined with N-body simulations to demonstrate that gas capture is a major binary formation channel in AGN disks, leading to high merger rates and observable features.

Findings

Gas capture accounts for up to 97% of mergers.

Merger rates range from 0.02 to 60 Gpc^{-3} yr^{-1}.

High eccentricities and Doppler shifts are key observational signatures.

Abstract

The astrophysical origin of gravitational wave (GW) events discovered by LIGO/VIRGO remains an outstanding puzzle. In active galactic nuclei (AGN), compact-object binaries form, evolve, and interact with a dense star cluster and a gas disk. An important question is whether and how binaries merge in these environments. To address this question, we have performed one-dimensional $N$-body simulations combined with a semi-analytical model which includes the formation, disruption, and evolution of binaries self-consistently. We point out that binaries can form in single-single interactions by the dissipation of kinetic energy in a gaseous medium. This ``gas capture'' binary formation channel contributes up to $97\,\%$ of gas-driven mergers and leads to a high merger rate in AGN disks even without pre-existing binaries. We find the merger rate to be in the range $\sim 0.02-60\,\mathrm{Gpc^{-3}yr^{-1}}$. The results are insensitive to the assumptions on gaseous hardening processes: we find that once they are formed, binaries merge efficiently via binary-single interactions even if these gaseous processes are neglected. We find that the average number of mergers per BH is $0.4$, and the probability for repeated mergers in 30 Myr is $\sim 0.21-0.45$. High BH masses due to repeated mergers, high eccentricities, and a significant Doppler drift of GWs are promising signatures which distinguish this merger channel from others. Furthermore, we find that gas-capture binaries reproduce the distribution of LMXBs in the Galactic center, including an outer cutoff at $\sim1$ pc due to the competition between migration and hardening by gas torques.