Residual eccentricity of inspiralling orbits at the gravitational-wave detection threshold: Accurate estimates using post-Newtonian theory

TL;DR

This paper accurately estimates the residual eccentricities of inspiraling binary systems at gravitational-wave detection thresholds using advanced post-Newtonian equations, improving upon previous approximations.

Contribution

It provides a new analytic formula incorporating higher-order post-Newtonian effects for late-time eccentricity estimates of inspiraling binaries.

Findings

Final eccentricities are smaller than quadrupole predictions by up to 30%.

The formula accounts for higher-order post-Newtonian effects.

Final eccentricities are nearly independent of mass ratio.

Abstract

We use equations of motion containing gravitational radiation-reaction terms through 4.5 post-Newtonian order to calculate the late-time eccentricities of inspiraling binary systems of non-spinning compact bodies as they cross the detection threshold of ground-based gravitational-wave interferometers. The initial eccentricities can be as large as 0.999. We find that the final eccentricities are systematically smaller than those predicted by the leading quadrupole approximation, by as much as 30 percent for a 300 solar mass binary crossing the LIGO/Virgo detection threshold at 10 Hz, or eight percent smaller for a 60 solar mass binary. We find an analytic formula for the late-time eccentricity that accurately accounts for the higher-order post-Newtonian effects, generalizing a formula derived by Peters and Mathews in the 1960s. We also find that the final eccentricities are independent of the ratio of the masses of the two compact bodies to better than two percent.