Imprints of changing mass and spin on black hole ringdown

Creators: Zhu, Hengrui¹; Pretorius, Frans¹; Ma, Sizheng²; Owen, Robert³; Chen, Yitian⁴; Deppe, Nils⁴; Kidder, Lawrence E.⁴; Okounkova, Maria⁵; Pfeiffer, Harald P.⁶; Scheel, Mark A.⁷; Stein, Leo C.⁸

1. Princeton University
2. Perimeter Institute
3. Oberlin College
4. Cornell University
5. Pasadena City College
6. Max Planck Institute for Gravitational Physics
7. California Institute of Technology
8. University of Mississippi

Abstract

We numerically investigate the imprints of gravitational radiation-reaction driven changes to a black hole’s mass and spin on the corresponding ringdown waveform. We do so by comparing the dynamics of a perturbed black hole evolved with the full (nonlinear) versus linearized Einstein equations. As expected, we find that the quasinormal mode amplitudes extracted from nonlinear evolution deviate from their linear counterparts at third order in initial perturbation amplitude. For perturbations leading to a change in the black hole mass and spin of ∼5%, which is reasonable for a remnant formed in an astrophysical merger, we find that nonlinear distortions to the complex amplitudes of some quasinormal modes can be as large as ∼50% at the peak of the waveform. Furthermore, the change in the mass and spin results in a drift in the quasinormal mode frequencies, which for large amplitude perturbations causes the nonlinear waveform to rapidly dephase with respect to its linear counterpart. Surprisingly, despite these nonlinear effects creating significant deviations in the nonlinear waveform, we show that a linear quasinormal mode model still performs quite well from close to the peak amplitude onward. Comparing the quality of quasinormal mode fits for the linear and nonlinear waveforms, we show that the main obstruction to measuring high-𝑛 overtones is the transient part of the waveform, already present at the linear level.

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Acknowledgement

We thank Emanuele Berti, Alejandro Cárdenas-Avendaño, William East, Will Farr, Maximiliano Isi, Luis Lehner, Lionel London, Taillte May, Keefe Mitman, Justin Ripley, Harrison Siegel, Nils Siemonsen, and Huan Yang for helpful discussions regarding various aspects of this project. H. Z. especially thanks Alejandro Cárdenas-Avendaño and Justin Ripley for discussions at early phase of this project; Will Farr, Maximiliano Isi, and Harrison Siegel for hosting stimulating discussions at the Flatiron institute; and Nils Siemonsen for suggesting time-symmetric initial data. The authors are pleased to acknowledge that the work reported on in this paper was substantially performed using the Princeton Research Computing resources at Princeton University which is a consortium of groups led by the Princeton Institute for Computational Science and Engineering (PICSciE) and Office of Information Technology’s Research Computing. This work was supported in part by the Sherman Fairchild Foundation and NSF Grants No. PHY-2011968, No. PHY-2011961, No. PHY-2309211, No. PHY-2309231, and No. OAC-2209656 at Caltech and NSF Grants No. PHY-2207342 and No. OAC-2209655 at Cornell. F. P. acknowledges support from the NSF through the Award No. PHY-2207286. L. C. S. was supported by NSF CAREER Award No. PHY-2047382 and a Sloan Foundation Research Fellowship.

Funding

This work was supported in part by the Sherman Fairchild Foundation and NSF Grants No. PHY-2011968, No. PHY-2011961, No. PHY-2309211, No. PHY-2309231, and No. OAC-2209656 at Caltech and NSF Grants No. PHY-2207342 and No. OAC-2209655 at Cornell. F. P. acknowledges support from the NSF through the Award No. PHY-2207286. L. C. S. was supported by NSF CAREER Award No. PHY-2047382 and a Sloan Foundation Research Fellowship.

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PhysRevD.110.124028.pdf

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