Rapid and Bright Stellar-mass Binary Black Hole Mergers in Active Galactic Nuclei (1602.03831v3)

Abstract: The Laser Interferometer Gravitational-Wave Observatory, LIGO, found direct evidence for double black hole binaries emitting gravitational waves. Galactic nuclei are expected to harbor the densest population of stellar-mass black holes. A significant fraction ($\sim30\%$) of these black holes can reside in binaries. We examine the fate of the black hole binaries in active galactic nuclei, which get trapped in the inner region of the accretion disk around the central supermassive black hole. We show that binary black holes can migrate into and then rapidly merge within the disk well within a Salpeter time. The binaries may also accrete a significant amount of gas from the disk, well above the Eddington rate. This could lead to detectable X-ray or gamma-ray emission, but would require hyper-Eddington accretion with a few percent radiative efficiency, comparable to thin disks. We discuss implications for gravitational wave observations and black hole population studies. We estimate that Advanced LIGO may detect $\sim20$ such, gas-induced binary mergers per year.

• The paper demonstrates that dense AGN disks facilitate rapid BBH mergers through gas-induced migration and enhanced accretion rates.
• It quantifies potential merger rates detected by Advanced LIGO, estimating around 20 gas-induced BBH events per year.
• The study highlights the possibility of observable electromagnetic counterparts from hyper-Eddington accretion accompanying these mergers.

Rapid and Bright Stellar-mass Binary Black Hole Mergers in Active Galactic Nuclei

The paper presents a comprehensive paper focused on the evolution and detectability of stellar-mass binary black holes (BBHs) immersed within the dense accretion disks of active galactic nuclei (AGN). This paper emerges in the backdrop of direct gravitational wave (GW) detection from BBH mergers by the Laser Interferometer Gravitational-Wave Observatory (LIGO), revealing critical insights into BBH dynamics in high-density environments.

The authors explore multiple facets of BBH evolution in AGN disks, asserting that a significant fraction of BBHs can rapidly merge within these disks owing to gravitational interactions with the dense gas, combined with gravitational wave emissions, potentially leading to distinct electromagnetic (EM) signatures accompanying the GW signals.

Key Observations and Methodology

1. BBH Population and Migration: The densest stellar-mass black hole populations are anticipated to reside within AGN, with approximately 30% of these populating in binaries. The authors evaluate the mechanism through which BBHs, influenced by dynamical friction, migrate into the accretion disk and subsequently undergo rapid mergers within a timeframe shorter than a Salpeter time.
2. Merger Rates and Accretion Dynamics: Within the AGN accretion disk, BBHs are shown to migrate inward and merge rapidly due to interactions with the surrounding gas. These binaries can accrete mass at rates surpassing the Eddington limit, possibly rendering these events detectable through EM emissions if the accretion achieves hyper-Eddington levels.
3. Gravitational Wave Observations: The paper implies that Advanced LIGO may potentially detect around 20 gas-induced binary mergers per year, situating these mergers as significant contributors to the BBH merger detection rate. This rate assessment derives from considering a range of plausible AGN and BBH properties along with sophisticated modeling of the disk-binary interaction.
4. Predicted Electromagnetic Counterparts: Given the possibility of gas accretion at hyper-Eddington rates, detectable X-ray or gamma-ray emissions might accompany these mergers. The authors posit that for such emissions to be observable, radiative efficiency must reach a few percent, paralleling thin-disk efficiency.

Implications and Future Directions

The research carries substantial implications for both observational astronomy and theoretical studies concerning black hole mergers:

• Gravitational Wave Astronomy: It provides a framework for future observations of BBH mergers within AGNs, suggesting a prospective correlation between gravitational wave events and electromagnetic counterparts, thereby enhancing multi-messenger astrophysical research.
• Astrophysical Environments: The findings provoke further investigations of dynamic processes in AGNs and their potential to foster rapid BBH mergers, contributing to a deeper understanding of galactic nuclei environments.
• Theoretical Developments: Future theoretical exploration could refine models describing gaseous interactions with BBHs, enhancing predictions of merger rates and EM detectability under varied astrophysical conditions.

The paper establishes a robust foundation for understanding BBH dynamics in dense astrophysical contexts, emphasizing the interplay between GWs and EM observations as a promising avenue for advancing the frontier of astrophysics. Further empirical confirmation of the predictions and theoretical enhancement of the model parameters will substantiate these projections.