Gravitational Radiation from Plunging Orbits - Perturbative Study -

TL;DR

This study uses black hole perturbation theory to analyze gravitational waves from the plunging phase of extreme mass ratio mergers, revealing universal oscillatory features and spin-dependent energy and momentum emission.

Contribution

It provides a detailed perturbative analysis of gravitational radiation during black hole plunges, emphasizing spin effects and identifying universal oscillatory behaviors.

Findings

Damped oscillatory gravitational waves during plunge

Maximum radiated energy at spin a/M=0.86

Linear momentum emission depends on impact angle

Abstract

Numerical relativity has recently yielded a plethora of results about kicks from spinning mergers which has, in turn, vastly increased our knowledge about the spin interactions of black hole systems. In this work we use black hole perturbation theory to calculate accurately the gravitational waves emanating from the end of the plunging stage of an extreme mass ratio merger in order to further understand this phenomenon. This study focuses primarily on spin induced effects with emphasis on the maximally spinning limit and the identification of possible causes of generic behavior. We find that gravitational waves emitted during the plunging phase exhibit damped oscillatory behavior, corresponding to a coherent excitation of quasi-normal modes by the test particle. This feature is universal in the sense that the frequencies and damping time do not depend on the orbital parameters of the plunging particle. Furthermore, the observed frequencies are distinct from those associated with the usual free quasi-normal ringing. Our calculation suggests that a maximum in radiated energy and momentum occurs at spin parameters equal to $a/M=0.86$ and $a/M=0.81$, respectively for the plunge stage of a polar orbit. The dependence of linear momentum emission on the angle at which a polar orbit impacts the horizon is quantified. One of the advantages of the perturbation approach adopted here is that insight into the actual mechanism of radiation emission and its relationship to black hole ringing is obtained by carefully identifying the dominant terms in the expansions used.