Complete waveform model for compact binaries on eccentric orbits

TL;DR

This paper introduces a comprehensive time-domain waveform model for non-spinning compact binaries on eccentric orbits, improving gravitational wave data analysis by accurately capturing inspiral, merger, and ringdown phases.

Contribution

The paper develops a novel eccentric waveform model combining post-Newtonian and numerical relativity data, extending existing models to include eccentricity effects in gravitational wave signals.

Findings

Model accurately reproduces eccentric binary coalescence features.

Effectively recovers GW150914 and GW151226 signals with moderate eccentricity.

Provides a tool for better detection of eccentric gravitational wave sources.

Abstract

We present a time domain waveform model that describes the inspiral-merger-ringdown (IMR) of compact binary systems whose components are non-spinning, and which evolve on orbits with low to moderate eccentricity. The inspiral evolution is described using third order post-Newtonian equations both for the equations of motion of the binary, and its far-zone radiation field. This latter component also includes instantaneous, tails and tails-of-tails contributions, and a contribution due to non-linear memory. This framework reduces to the post-Newtonian approximant TaylorT4 at third post-Newtonian order in the zero eccentricity limit. To improve phase accuracy, we incorporate higher-order post-Newtonian corrections for the energy flux of quasi-circular binaries and gravitational self-force corrections to the binding energy of compact binaries. This enhanced inspiral evolution prescription is combined with an analytical prescription for the merger-ringdown evolution using a catalog of numerical relativity simulations. This IMR waveform model reproduces effective-one-body waveforms for systems with mass-ratios between 1 to 15 in the zero eccentricity limit. Using a set of eccentric numerical relativity simulations, not used during calibration, we show that our eccentric model accurately reproduces the features of eccentric compact binary coalescence throughout the merger. Using this model we show that the gravitational wave transients GW150914 and GW151226 can be effectively recovered with template banks of quasi-circular, spin-aligned waveforms if the eccentricity $e_0$ of these systems when they enter the aLIGO band at a gravitational wave frequency of 14 Hz satisfies $e_0^{\rm GW150914}\leq0.15$ and $e_0^{\rm GW151226}\leq0.1$.