The influence of the mean anomaly on the dynamical quantities of binary black hole mergers in eccentric orbits

Abstract

In studies of binary black hole (BBH) mergers in eccentric orbits, the mean anomaly, traditionally regarded as less significant than eccentricity, has been thought to encode only the orbital phase, leading to the assumption that it exerts minimal influence on the dynamics of eccentric mergers. In a previous investigation, we identified consistent oscillations in dynamical quantities peak luminosity Lpeak, remnant mass Mrem, spin αrem, and recoil velocity Vrem in relation to the initial eccentricity e0. These oscillations are associated with integer orbital cycles within a phenomenological framework. In this paper, we aim to explore the underlying physical nature of these oscillations through gravitational waveforms. Our examination of remnant mass and spin reveals that while the initial ADM mass MADM and orbital angular momentum L0 exhibit gradual variations with e0, the radiated energy Erad and angular momentum Lrad display oscillatory patterns akin to those observed in Mrem and αrem. By decomposing the waveforms into three distinct phases inspiral, late inspiral to merger, and ringdown, we demonstrate that these oscillations persist across all phases, suggesting a common origin. Through a comparative analysis of Erad and Lrad derived from numerical relativity (NR), post-Newtonian (PN) waveforms, and orbital-averaged PN fluxes during the inspiral phase, we identify the initial mean anomaly l0 as the source of the observed oscillations. ...

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