Unveiling the merger structure of black hole binaries in generic planar orbits

TL;DR

This paper develops a new analytical model for the complex merger dynamics of binary black holes in generic planar orbits, enhancing gravitational wave data interpretation and understanding of diverse formation channels.

Contribution

It introduces a gauge-invariant, quasi-universal framework for describing generic binary black hole mergers, validated against extensive numerical simulations.

Findings

Accurate analytical relations for merger parameters in generic orbits.

Validation with 311 numerical simulations and additional datasets.

Foundation for complete waveform models in arbitrary orbital configurations.

Abstract

The precise modeling of binary black hole coalescences in generic planar orbits is a crucial step to disentangle dynamical and isolated binary formation channels through gravitational-wave observations. The merger regime of such coalescences exhibits a significantly higher complexity compared to the quasicircular case, and cannot be readily described through standard parameterizations in terms of eccentricity and anomaly. In the spirit of the Effective One Body formalism, we build on the study of the test-mass limit, and introduce a new modelling strategy to describe the general-relativistic dynamics of two-body systems in generic orbits. This is achieved through gauge-invariant combinations of the binary energy and angular momentum, such as a dynamical "impact parameter" at merger. These variables reveal simple "quasi-universal" structures of the pivotal merger parameters, allowing to build an accurate analytical representation of generic (bounded and dynamically-bounded) orbital configurations. We demonstrate the validity of these analytical relations using 311 numerical simulations of bounded noncircular binaries with progenitors from the RIT and SXS catalogs, together with a custom dataset of dynamical captures generated using the Einstein Toolkit, and test-mass data in bound orbits. Our modeling strategy lays the foundations of accurate and complete waveform models for systems in arbitrary orbits, bolstering observational explorations of dynamical formation scenarios and the discovery of new classes of gravitational wave sources.