Abstract

Abstract The astrophysical origin of gravitational wave (GW) events discovered by LIGO/VIRGO remains an outstanding puzzle. In active galactic nuclei (AGNs), 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 semianalytical model that includes the formation, disruption, and evolution of binaries self-consistently. We point out that binaries can form in single–single interactions through 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 preexisting binaries. We find the merger rate to be in the range of ∼0.02–60 Gpc−3 yr−1. The results are insensitive to the assumptions on the gaseous hardening processes: we find that once they are formed, binaries merge efficiently via binary–single interactions even if these gaseous processes are ignored. We find that the average number of mergers per black hole (BH) is 0.4, and the probability for repeated mergers in 30 Myr is ∼0.21–0.45. High BH masses due to repeated mergers, high eccentricities, and a significant Doppler drift of GWs are promising signatures that distinguish this merger channel from others. Furthermore, we find that gas-capture binaries reproduce the distribution of low-mass X-ray binaries in the Galactic center, including an outer cutoff at ∼1 pc due to the competition between migration and hardening by gas torques.

Highlights

  • Recent detections of gravitational waves (GWs) have shown evidence for a high rate of black hole (BH)–BH and neutron star (NS)–NS mergers in the universe (Abbott et al 2016a, 2016b, 2017a, 2017b, 2017c, 2019a; Zackay et al 2019, 2020; Venumadhav et al 2020)

  • The binary migrates toward the supermassive BH (SMBH) due to type I/II torque of the active galactic nucleus (AGN) disk (orange line in panel (a))

  • We show the properties of the system at 30 Myr, namely, the number of merged binaries (Nmer), surviving binaries (Nbin), the fraction of mergers among preexisting binaries, gas-capture-formed binaries, and dynamically formed binaries compared to the total number of mergers, the fraction of repeated mergers to total mergers, the number of BHs that migrate within the inner boundary rin (Nacc), and the number of mergers among BHs formed in situ due to the fragmentation of the AGN disk (Nmer,SF)

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Summary

Introduction

Recent detections of gravitational waves (GWs) have shown evidence for a high rate of black hole (BH)–BH and neutron star (NS)–NS mergers in the universe (Abbott et al 2016a, 2016b, 2017a, 2017b, 2017c, 2019a; Zackay et al 2019, 2020; Venumadhav et al 2020). Generozov et al (2018) proposed that the density profile of these hard binaries can be explained by the tidal capture mechanism and stellar relaxation processes. This model predicts the radial distribution of LMXBs to be μr-(0.9-1.4), the outer cutoff at ∼1 pc remains unexplained

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