A Surrogate model of gravitational waveforms from numerical relativity simulations of precessing binary black hole mergers

We present the first surrogate model for gravitational waveforms from the coalescence of precessing binary black holes. We call this surrogate model NRSur4d2s. Our methodology significantly extends recently introduced reduced-order and surrogate modeling techniques, and is capable of directly modeli...

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Bibliographic Details
Published in:Physical review. D 2017-05, Vol.95 (10), Article 104023
Main Authors: Blackman, Jonathan, Field, Scott E., Scheel, Mark A., Galley, Chad R., Hemberger, Daniel A., Schmidt, Patricia, Smith, Rory
Format: Article
Language:English
Subjects:
Angular momentum
Black holes
Coalescing
Computer simulation
Dimensionless numbers
Gravitation
Gravitational waves
Mass ratios
Mathematical models
Numerical relativity
Parameter estimation
Reduced order models
Relativity
Spherical harmonics
State of the art
Theory of relativity
Waveforms
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Summary:We present the first surrogate model for gravitational waveforms from the coalescence of precessing binary black holes. We call this surrogate model NRSur4d2s. Our methodology significantly extends recently introduced reduced-order and surrogate modeling techniques, and is capable of directly modeling numerical relativity waveforms without introducing phenomenological assumptions or approximations to general relativity. Motivated by GW150914, LIGO’s first detection of gravitational waves from merging black holes, the model is built from a set of 276 numerical relativity (NR) simulations with mass ratios q≤2, dimensionless spin magnitudes up to 0.8, and the restriction that the initial spin of the smaller black hole lies along the axis of orbital angular momentum. It produces waveforms which begin ∼30 gravitational wave cycles before merger and continue through ringdown, and which contain the effects of precession as well as all ℓ∈{2,3} spin-weighted spherical-harmonic modes. We perform cross-validation studies to compare the model to NR waveforms not used to build the model and find a better agreement within the parameter range of the model than other, state-of-the-art precessing waveform models, with typical mismatches of 10−3. We also construct a frequency domain surrogate model (called NRSur4d2s_FDROM) which can be evaluated in 50 ms and is suitable for performing parameter estimation studies on gravitational wave detections similar to GW150914.
ISSN:2470-0010
2470-0029
DOI:10.1103/PhysRevD.95.104023