Characterizing the effect of eccentricity on the dynamics of binary black hole mergers in numerical relativity
Abstract
Many articles have partially studied the configuration of eccentric orbital binary black hole (BBH) mergers. However, there is a scarcity of systematic and comprehensive research on the effect of eccentricity on BBH dynamics. Thanks to the rich and numerous numerical relativistic simulations of eccentric orbital BBH mergers from RIT catalog, this paper aims to investigate the impact of initial eccentricity e0 on various dynamic quantities such as merger time Tmerger, peak luminosity Lpeak of gravitational waves, recoil velocity Vf, mass Mf, and spin αf of merger remnants. We cover configurations of no spin, spin alignment, and spin precession, as well as a broad parameter space of mass ratio ranging from 1/32 to 1 and initial eccentricity from 0 to 1. For non-spinning BBH with an initial coordinate separation of 11.3M (M is the total mass of BBH), we make the first discovery of a ubiquitous oscillation in the relationship between dynamic quantities Lpeak, Vf, Mf, αf, and initial eccentricity e0. Additionally, at 24.6M, we observe the same oscillation phenomenon in the case of mass ratio q=1, but do not see it in other mass ratios, suggesting that this oscillation will be evident in numerical simulations with sufficiently dense initial eccentricity. abbreviated
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