Litcius/Paper detail

Extending black-hole remnant surrogate models to extreme mass ratios

Matteo Boschini, Davide Gerosa, Vijay Varma, Cristóbal Armaza, Michael Boyle, M. S. Bonilla, A. Ceja, Yitian Chen, Nils Deppe, Matthew Giesler, Larry Kidder, P. Kumar, Guillermo Lara, Oliver Long, Sizheng Ma, Keefe Mitman, Peter James Nee, Harald Pfeiffer, A. Ramos-Buades, Mark Scheel, Nils L. Vu, J. Yoo

2023Physical review. D/Physical review. D.15 citationsDOIOpen Access PDF

Abstract

Numerical-relativity surrogate models for both black-hole merger waveforms and remnants have emerged as important tools in gravitational-wave astronomy. While producing very accurate predictions, their applicability is limited to the region of the parameter space where numerical-relativity simulations are available and computationally feasible. Notably, this excludes extreme mass ratios. We present a machine-learning approach to extend the validity of existing and future numerical-relativity surrogate models toward the test-particle limit, targeting in particular the mass and spin of postmerger black-hole remnants. Our model is trained on both numerical-relativity simulations at comparable masses and analytical predictions at extreme mass ratios. We extend the gaussian-process-regression model NRSur7dq4Remnant, validate its performance via cross validation, and test its accuracy against additional numerical-relativity runs. Our fit, which we dub NRSur7dq4EmriRemnant, reaches an accuracy that is comparable to or higher than that of existing remnant models while providing robust predictions for arbitrary mass ratios.

Topics & Concepts

Numerical relativityTheory of relativityPhysicsSurrogate modelBlack hole (networking)General relativityStatistical physicsComputer scienceTheoretical physicsMachine learningComputer networkLink-state routing protocolRouting (electronic design automation)Routing protocolPulsars and Gravitational Waves ResearchAstrophysical Phenomena and ObservationsGamma-ray bursts and supernovae