Your search keyword '"Lovelace, Geoffrey"' showing total 4 results

1. Numerical-relativity surrogate modeling with nearly extremal black-hole spins.

Author

Walker, Marissa, Varma, Vijay, Lovelace, Geoffrey, and Scheel, Mark A

Subjects

BINARY black holes, GRAVITATIONAL waves, BLACK holes

Abstract

Numerical relativity (NR) simulations of binary black hole (BBH) systems provide the most accurate gravitational wave predictions, but at a high computational cost—especially when the black holes have nearly extremal spins (i.e. spins near the theoretical upper limit) or very unequal masses. Recently, the technique of reduced order modeling has enabled the construction of 'surrogate models' trained on an existing set of NR waveforms. Surrogate models enable the rapid computation of the gravitational waves emitted by BBHs. Typically these models are used for interpolation to compute gravitational waveforms for BBHs with mass ratios and spins within the bounds of the training set. Because simulations with nearly extremal spins are so technically challenging, surrogate models almost always rely on training sets with only moderate spins. In this paper, we explore how well surrogate models can extrapolate to nearly extremal spins when the training set only includes moderate spins. For simplicity, we focus on one-dimensional surrogate models trained on NR simulations of BBHs with equal masses and equal, aligned spins. We assess the performance of the surrogate models at higher spin magnitudes by calculating the mismatches between extrapolated surrogate model waveforms and NR waveforms, by calculating the differences between extrapolated and NR measurements of the remnant black-hole mass, and by testing how the surrogate model improves as the training set extends to higher spins. We find that while extrapolation in this one-dimensional case is viable for current detector sensitivities, surrogate models for next-generation detectors should use training sets that extend to nearly extremal spins. [ABSTRACT FROM AUTHOR]

Published

2023

2. Massive disc formation in the tidal disruption of a neutron star by a nearly extremal black hole.

Author

Lovelace, Geoffrey, Duez, Matthew D., Foucart, Francois, Kidder, Lawrence E., Pfeiffer, Harald P., Scheel, Mark A., and Szitógyi, Béla

Subjects

*BLACK holes, *GRAVITATIONAL waves, *SPACETIME, *NEUTRON stars, *INTERFEROMETERS, *GAMMA-ray diffraction

Abstract

Black hole-neutron star (BHNS) binaries are important sources of gravitational waves for second-generation interferometers, and BHNS mergers are also a proposed engine for short, hard gamma-ray bursts. The behavior of both the spacetime (and thus the emitted gravitational waves) and the neutron-star matter in a BHNS merger depend strongly and nonlinearly on the black hole's spin. While there is a significant possibility that astrophysical black holes could have spins that are nearly extremal (i.e. near the theoretical maximum), to date fully relativistic simulations of BHNS binaries have included black-hole spins only up to S/M² = 0.9, which corresponds to the black hole having approximately half as much rotational energy as possible, given the black hole's mass. In this paper, we present a new simulation of a BHNS binary with a mass ratio q = 3 and black-hole spin S/M² = 0.97, the highest simulated to date. We find that the black hole's large spin leads to the most massive accretion disc and the largest tidal tail outflow of any fully relativistic BHNS simulations to date, even exceeding the results implied by extrapolating results from simulations with lower black-hole spin. The disc appears to be remarkably stable. We also find that the high black-hole spin persists until shortly before the time of merger; afterward, both merger and accretion spin down the black hole. [ABSTRACT FROM AUTHOR]

Published

2013

3. Generalization of Ryan's theorem: Probing tidal coupling with gravitational waves from nearly circular, nearly equatorial, extreme-mass-ratio inspirals

Author

Lovelace, Geoffrey [Center for Radiophysics and Space Research, Cornell University, Ithaca, New York 14853 (United States)]

Published

2008

4. Tidal coupling of a Schwarzschild black hole and circularly orbiting moon

Author

Lovelace, Geoffrey [Theoretical Astrophysics, California Institute of Technology, Pasadena, California 91125 (United States)]

Published

2005