Your search keyword '"Daniel A. Hemberger"' showing total 18 results

1. Systematic effects from black hole-neutron star waveform model uncertainties on the neutron star equation of state

Author

Anuradha Gupta, B. D. Lackey, Masaru Shibata, Koutarou Kyutoku, Francois Foucart, Wyatt Brege, Sourav Ghosh, Suvadeep Bose, Matthew D. Duez, Daniel A. Hemberger, Kabir Chakravarti, Mark A. Scheel, Harald P. Pfeiffer, Jesus Caro, and Lawrence E. Kidder

Subjects

Physics, Equation of state, 010308 nuclear & particles physics, Gravitational wave, Binary number, FOS: Physical sciences, General Relativity and Quantum Cosmology (gr-qc), 01 natural sciences, General Relativity and Quantum Cosmology, Computational physics, Black hole, Numerical relativity, Neutron star, Binary black hole, Astrophysics - Solar and Stellar Astrophysics, 0103 physical sciences, Neutron, 010306 general physics, Solar and Stellar Astrophysics (astro-ph.SR)

Abstract

We identify various contributors of systematic effects in the measurement of the neutron star (NS) tidal deformability and quantify their magnitude for several types of neutron star—black hole (NSBH) binaries. Gravitational waves from NSBH mergers contain information about the components’ masses and spins as well as the NS equation of state. Extracting this information requires comparison of the signal in noisy detector data with theoretical templates derived from some combination of post-Newtonian (PN) approximants, effective one-body (EOB) models, and numerical relativity (NR) simulations. The accuracy of these templates is limited by errors in the NR simulations, by the approximate nature of the PN/EOB waveforms, and by the hybridization procedure used to combine them. In this paper, we estimate the impact of these errors by constructing and comparing a set of PN-NR hybrid waveforms, for the first time with NR waveforms from two different codes, namely, SpEC and sacra, for such systems. We then attempt to recover the parameters of the binary using two non-precessing template approximants. As expected, these errors have negligible effect on detectability. Mass and spin estimates are moderately affected by systematic errors for near equal-mass binaries, while the recovered masses can be inaccurate at higher mass ratios. Large uncertainties are also found in the tidal deformability Λ , due to differences in PN base models used in hybridization, numerical relativity NR errors, and inherent limitations of the hybridization method. We find that systematic errors are too large for tidal effects to be accurately characterized for any realistic NS equation of state model. We conclude that NSBH waveform models must be significantly improved if they are to be useful for the extraction of NS equation of state information or even for distinguishing NSBH systems from binary black holes.

Published

2019

2. On the properties of the massive binary black hole merger GW170729

Author

Vivien Raymond, Bela Szilagyi, Andrea Taracchini, Gregorio Carullo, Mark Hannam, Juan Calderón Bustillo, Daniel A. Hemberger, Alejandro Bohé, R. Cotesta, Alyssa Garcia, Richard O'Shaughnessy, Lawrence E. Kidder, Manuela Campanelli, Michael Pürrer, Patricia Schmidt, Kevin Barkett, Alessandra Buonanno, Michael Boyle, Sebastian Khan, Pablo Laguna, Geoffrey Lovelace, Margaret Millhouse, Lionel London, Salvatore Vitale, Nousha Afshari, Carl-Johan Haster, Harald P. Pfeiffer, Katerina Chatziioannou, H. Fong, Yosef Zlochower, I. W. Harry, Ian Hinder, Prayush Kumar, Francesco Pannarale, Lijing Shao, Eric B. Flynn, James S. Clark, Deirdre Shoemaker, Matthew Giesler, M. Haney, Carlos O. Lousto, Frank Ohme, Stanislav Babak, S. Ghonge, Saul A. Teukolsky, Mark A. Scheel, Tony Chu, Bhavesh Khamersa, Ken K. Y. Ng, L. K. Nuttall, Tyson Littenberg, James Healy, J. S. Lange, Jonathan Blackman, Karan Jani, S. Ossokine, AstroParticule et Cosmologie (APC (UMR_7164)), Institut National de Physique Nucléaire et de Physique des Particules du CNRS (IN2P3)-Centre National de la Recherche Scientifique (CNRS)-Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Observatoire de Paris, PSL Research University (PSL)-PSL Research University (PSL)-Université Paris Diderot - Paris 7 (UPD7), Centre National d'Études Spatiales [Toulouse] (CNES), Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Institut National de Physique Nucléaire et de Physique des Particules du CNRS (IN2P3)-Observatoire de Paris, Université Paris sciences et lettres (PSL)-Université Paris sciences et lettres (PSL)-Centre National de la Recherche Scientifique (CNRS)-Université de Paris (UP), Observatoire de Paris, PSL Research University (PSL)-PSL Research University (PSL)-Université Paris Diderot - Paris 7 (UPD7)-Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Institut National de Physique Nucléaire et de Physique des Particules du CNRS (IN2P3)-Centre National de la Recherche Scientifique (CNRS), and Université Paris sciences et lettres (PSL)-Université Paris sciences et lettres (PSL)-Centre National de la Recherche Scientifique (CNRS)-Université Paris Cité (UPCité)

Subjects

gr-qc, ST/L000962/1, FOS: Physical sciences, alternative theories of gravity, Astophysics, General Relativity and Quantum Cosmology (gr-qc), spin, gravitational radiation: direct detection, 01 natural sciences, General Relativity and Quantum Cosmology, Gravitational waves, Binary black hole, Consistency (statistics), 0103 physical sciences, Prior probability, black hole, Waveform, ST/N000633/1, 010306 general physics, 10. No inequality, STFC, Spin-½, High Energy Astrophysical Phenomena (astro-ph.HE), Physics, astro-ph.HE, spin: precession, black holes, 010308 nuclear & particles physics, Gravitational wave, gravitational radiation, RCUK, Mass ratio, binary: compact, effect: higher-order, Computational physics, Black hole, General relativity, black hole: binary, gravitational radiation: emission, [PHYS.GRQC]Physics [physics]/General Relativity and Quantum Cosmology [gr-qc], mass ratio, Astrophysics - High Energy Astrophysical Phenomena, [PHYS.ASTR]Physics [physics]/Astrophysics [astro-ph]

Abstract

We present a detailed investigation into the properties of GW170729, the gravitational wave with the most massive and distant source confirmed to date. We employ an extensive set of waveform models, including new improved models that incorporate the effect of higher-order waveform modes which are particularly important for massive systems. We find no indication of spin-precession, but the inclusion of higher-order modes in the models results in an improved estimate for the mass ratio of $(0.3-0.8)$ at the 90\% credible level. Our updated measurement excludes equal masses at that level. We also find that models with higher-order modes lead to the data being more consistent with a smaller effective spin, with the probability that the effective spin is greater than zero being reduced from $99\%$ to $94\%$. The 90\% credible interval for the effective spin parameter is now $(-0.01-0.50)$. Additionally, the recovered signal-to-noise ratio increases by $\sim0.3$ units compared to analyses without higher-order modes. We study the effect of common spin priors on the derived spin and mass measurements, and observe small shifts in the spins, while the masses remain unaffected. We argue that our conclusions are robust against systematic errors in the waveform models. We also compare the above waveform-based analysis which employs compact-binary waveform models to a more flexible wavelet- and chirplet-based analysis. We find consistency between the two, with overlaps of $\sim 0.9$, typical of what is expected from simulations of signals similar to GW170729, confirming that the data are well-described by the existing waveform models. Finally, we study the possibility that the primary component of GW170729 was the remnant of a past merger of two black holes and find this scenario to be indistinguishable from the standard formation scenario., Comment: 14 pages, 8 figures, final published version, samples available at https://git.ligo.org/katerina.chatziioannou/gw170729hm_datarelease

Published

2019

3. Parameter estimation method that directly compares gravitational wave observations to numerical relativity

Author

P. Kumar, John A. Clark, N. Demos, Richard O'Shaughnessy, Lawrence E. Kidder, Mark A. Scheel, H. Fong, Deirdre Shoemaker, Yosef Zlochower, J. Calderón Bustillo, Manuela Campanelli, Carlos O. Lousto, Geoffrey Lovelace, B. Khamesra, Pablo Laguna, Harald P. Pfeiffer, Béla Szilágyi, Michael Boyle, Daniel A. Hemberger, Ian Hinder, J. S. Lange, Saul A. Teukolsky, T. K. Chu, James Healy, Karan Jani, and S. Ossokine

Subjects

Physics, 010308 nuclear & particles physics, Gravitational wave, Estimation theory, Numerical analysis, Statistical parameter, FOS: Physical sciences, Binary number, General Relativity and Quantum Cosmology (gr-qc), 01 natural sciences, General Relativity and Quantum Cosmology, Numerical relativity, Theoretical physics, Theory of relativity, Binary black hole, 0103 physical sciences, Statistical physics, 010306 general physics

Abstract

We present and assess a Bayesian method to interpret gravitational wave signals from binary black holes. Our method directly compares gravitational wave data to numerical relativity simulations. This procedure bypasses approximations used in semi-analytical models for compact binary coalescence. In this work, we use only the full posterior parameter distribution for generic nonprecessing binaries, drawing inferences away from the set of NR simulations used, via interpolation of a single scalar quantity (the marginalized log-likelihood, $\ln {\cal L}$) evaluated by comparing data to nonprecessing binary black hole simulations. We also compare the data to generic simulations, and discuss the effectiveness of this procedure for generic sources. We specifically assess the impact of higher order modes, repeating our interpretation with both $l\le2$ as well as $l\le3$ harmonic modes. Using the $l\le3$ higher modes, we gain more information from the signal and can better constrain the parameters of the gravitational wave signal. We assess and quantify several sources of systematic error that our procedure could introduce, including simulation resolution and duration; most are negligible. We show through examples that our method can recover the parameters for equal mass, zero spin; GW150914-like; and unequal mass, precessing spin sources. Our study of this new parameter estimation method demonstrates we can quantify and understand the systematic and statistical error. This method allows us to use higher order modes from numerical relativity simulations to better constrain the black hole binary parameters., 30 pages, 22 figures; submitted to PRD

Published

2017

4. Numerical binary black hole mergers in dynamical Chern-Simons gravity: Scalar field

Author

Maria Okounkova, Daniel A. Hemberger, Mark A. Scheel, and Leo C. Stein

Subjects

High Energy Astrophysical Phenomena (astro-ph.HE), High Energy Physics - Theory, Physics, 010308 nuclear & particles physics, Gravitational wave, General relativity, FOS: Physical sciences, General Relativity and Quantum Cosmology (gr-qc), 01 natural sciences, General Relativity and Quantum Cosmology, LIGO, Pseudoscalar, Theoretical physics, Classical mechanics, High Energy Physics - Theory (hep-th), Binary black hole, Tests of general relativity, 0103 physical sciences, Astrophysics - High Energy Astrophysical Phenomena, 010306 general physics, Scalar field, Phenomenology (particle physics)

Abstract

Testing general relativity in the non-linear, dynamical, strong-field regime of gravity is one of the major goals of gravitational wave astrophysics. Performing precision tests of general relativity (GR) requires numerical inspiral, merger, and ringdown waveforms for binary black hole (BBH) systems in theories beyond GR. Currently, GR and scalar-tensor gravity are the only theories amenable to numerical simulations. In this article, we present a well-posed perturbation scheme for numerically integrating beyond-GR theories that have a continuous limit to GR. We demonstrate this scheme by simulating BBH mergers in dynamical Chern-Simons gravity (dCS), to linear order in the perturbation parameter. We present mode waveforms and energy fluxes of the dCS pseudoscalar field from our numerical simulations. We find good agreement with analytic predictions at early times, including the absence of pseudoscalar dipole radiation. We discover new phenomenology only accessible through numerics: a burst of dipole radiation during merger. We also quantify the self-consistency of the perturbation scheme. Finally, we estimate bounds that GR-consistent LIGO detections could place on the new dCS length scale, approximately $\ell \lesssim \mathcal{O}(10)~\mathrm{km}$., 14+4 pages, 8 figures, 1 table; visualization available at http://www.youtube.com/watch?v=WQH-1b_XUM4 . Matches published version

Published

2017

5. A Surrogate Model of Gravitational Waveforms from Numerical Relativity Simulations of Precessing Binary Black Hole Mergers

Author

Jonathan Blackman, Rory Smith, Daniel A. Hemberger, Chad R. Galley, Scott E. Field, Patricia Schmidt, and Mark A. Scheel

Subjects

Physics, Gravitational-wave observatory, 010308 nuclear & particles physics, General relativity, Gravitational wave, FOS: Physical sciences, General Relativity and Quantum Cosmology (gr-qc), 01 natural sciences, General Relativity and Quantum Cosmology, Black hole, Numerical relativity, Classical mechanics, Binary black hole, Tests of general relativity, 0103 physical sciences, 010306 general physics, Gravitational redshift

Abstract

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 $q \leq 2$, 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 $\sim 30$ gravitational wave cycles before merger and continue through ringdown, and which contain the effects of precession as well as all $\ell \in \{2, 3\}$ spin-weighted spherical-harmonic modes. We perform cross-validation studies to compare the model to NR waveforms \emph{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 $50\, \mathrm{ms}$ and is suitable for performing parameter estimation studies on gravitational wave detections similar to GW150914., Comment: 34 pages, 26 figures

Published

2017

6. The SXS collaboration catalog of binary black hole simulations

Author

Geoffrey Lovelace, E. Foley, T. D. Ramirez, Daniel A. Hemberger, Mark A. Scheel, Tony Chu, Nils Fischer, Alyssa Garcia, Francois Hebert, H. Khan, Vijay Varma, Ian Hinder, Serguei Ossokine, S. Rodriguez, Lawrence E. Kidder, Patricia Schmidt, Nils Deppe, Béla Szilágyi, Nousha Afshari, Maria Okounkova, Matthew Giesler, Nicholas Demos, Scott E. Field, Kevin Kuper, Heather Fong, Harald P. Pfeiffer, Dante A. B. Iozzo, Hannes R. Rüter, Leo C. Stein, Saul A. Teukolsky, Jonathan Blackman, Halston Lim, Aaron Zimmerman, Prayush Kumar, Reza Katebi, Katerina Chatziioannou, Charles J. Woodford, Michelle E. Walker, Kevin Barkett, and Michael Boyle

Subjects

High Energy Astrophysical Phenomena (astro-ph.HE), Physics, Angular momentum, Physics and Astronomy (miscellaneous), 010308 nuclear & particles physics, Gravitational wave, Astrophysics::High Energy Astrophysical Phenomena, FOS: Physical sciences, General Relativity and Quantum Cosmology (gr-qc), Parameter space, 01 natural sciences, General Relativity and Quantum Cosmology, Computational physics, Numerical relativity, Binary black hole, 0103 physical sciences, Precession, Waveform, Astrophysics - High Energy Astrophysical Phenomena, 010306 general physics, Order of magnitude

Abstract

Accurate models of gravitational waves from merging black holes are necessary for detectors to observe as many events as possible while extracting the maximum science. Near the time of merger, the gravitational waves from merging black holes can be computed only using numerical relativity. In this paper, we present a major update of the Simulating eXtreme Spacetimes (SXS) Collaboration catalog of numerical simulations for merging black holes. The catalog contains 2018 distinct configurations (a factor of 11 increase compared to the 2013 SXS catalog), including 1426 spin-precessing configurations, with mass ratios between 1 and 10, and spin magnitudes up to 0.998. The median length of a waveform in the catalog is 39 cycles of the dominant $\ell=m=2$ gravitational-wave mode, with the shortest waveform containing 7.0 cycles and the longest 351.3 cycles. We discuss improvements such as correcting for moving centers of mass and extended coverage of the parameter space. We also present a thorough analysis of numerical errors, finding typical truncation errors corresponding to a waveform mismatch of $\sim 10^{-4}$. The simulations provide remnant masses and spins with uncertainties of 0.03% and 0.1% ($90^{\text{th}}$ percentile), about an order of magnitude better than analytical models for remnant properties. The full catalog is publicly available at https://www.black-holes.org/waveforms ., Comment: 33+18 pages, 13 figures, 4 tables, 2,018 binaries. Catalog metadata in ancillary JSON file. v2: Matches version accepted by CQG. Catalog available at https://www.black-holes.org/waveforms

Published

2019

7. An improved effective-one-body model of spinning, nonprecessing binary black holes for the era of gravitational-wave astrophysics with advanced detectors

Author

P. Kumar, Mark A. Scheel, Ian Hinder, H. Fong, Béla Szilágyi, Geoffrey Lovelace, Michael Pürrer, Daniel A. Hemberger, Alessandra Buonanno, Lijing Shao, Harald P. Pfeiffer, Michael Boyle, Andrea Taracchini, Lawrence E. Kidder, Vivien Raymond, I. W. Harry, Stanislav Babak, T. K. Chu, Alejandro Bohé, and S. Ossokine

Subjects

Physics, 010308 nuclear & particles physics, Gravitational wave, gr-qc, Extrapolation, Phase (waves), FOS: Physical sciences, Astrophysics, General Relativity and Quantum Cosmology (gr-qc), Parameter space, 01 natural sciences, LIGO, General Relativity and Quantum Cosmology, Orders of magnitude (time), Binary black hole, 0103 physical sciences, Waveform, 010306 general physics

Abstract

We improve the accuracy of the effective-one-body (EOB) waveforms that were employed during the first observing run of Advanced LIGO for binaries of spinning, nonprecessing black holes by calibrating them to a set of 141 numerical-relativity (NR) waveforms. The NR simulations expand the domain of calibration towards larger mass ratios and spins, as compared to the previous EOBNR model. Merger-ringdown waveforms computed in black-hole perturbation theory for Kerr spins close to extremal provide additional inputs to the calibration. For the inspiral-plunge phase, we use a Markov-chain Monte Carlo algorithm to efficiently explore the calibration space. For the merger-ringdown phase, we fit the NR signals with phenomenological formulae. After extrapolation of the calibrated model to arbitrary mass ratios and spins, the (dominant-mode) EOBNR waveforms have faithfulness --- at design Advanced-LIGO sensitivity --- above $99\%$ against all the NR waveforms, including 16 additional waveforms used for validation, when maximizing only on initial phase and time. This implies a negligible loss in event rate due to modeling for these binary configurations. We find that future NR simulations at mass ratios $\gtrsim 4$ and double spin $\gtrsim 0.8$ will be crucial to resolve discrepancies between different ways of extrapolating waveform models. We also find that some of the NR simulations that already exist in such region of parameter space are too short to constrain the low-frequency portion of the models. Finally, we build a reduced-order version of the EOBNR model to speed up waveform generation by orders of magnitude, thus enabling intensive data-analysis applications during the upcoming observation runs of Advanced LIGO., 27 pages, 15 figures

Published

2016

8. Accuracy of binary black hole waveform models for aligned-spin binaries

Author

H. Fong, Bela Szilagyi, Daniel A. Hemberger, Lawrence E. Kidder, Michael Boyle, P. Kumar, Mark A. Scheel, Harald P. Pfeiffer, and T. K. Chu

Subjects

Physics, J.2, 010308 nuclear & particles physics, FOS: Physical sciences, General Relativity and Quantum Cosmology (gr-qc), 01 natural sciences, General Relativity and Quantum Cosmology, Computational physics, Black hole, Numerical relativity, Binary black hole, Rotating black hole, Quantum mechanics, 0103 physical sciences, Extremal black hole, Waveform, Spin-flip, 83C35, 010306 general physics, Schwarzschild radius

Abstract

Coalescing binary black holes are among the primary science targets for second generation ground-based gravitational wave (GW) detectors. Reliable GW models are central to detection of such systems and subsequent parameter estimation. This paper performs a comprehensive analysis of the accuracy of recent waveform models for binary black holes with aligned spins, utilizing a new set of $84$ high-accuracy numerical relativity simulations. Our analysis covers comparable mass binaries ($1\le m_1/m_2\le 3$), and samples independently both black hole spins up to dimensionless spin-magnitude of $0.9$ for equal-mass binaries and $0.85$ for unequal mass binaries. Furthermore, we focus on the high-mass regime (total mass $\gtrsim 50M_\odot$). The two most recent waveform models considered (PhenomD and SEOBNRv2) both perform very well for signal detection, losing less than 0.5\% of the recoverable signal-to-noise ratio $\rho$, except that SEOBNRv2's efficiency drops mildly for both black hole spins aligned with large magnitude. For parameter estimation, modeling inaccuracies of SEOBNRv2 are found to be smaller than systematic uncertainties for moderately strong GW events up to roughly $\rho\lesssim 15$. PhenomD's modeling errors are found to be smaller than SEOBNRv2's, and are generally irrelevant for $\rho\lesssim 20$. Both models' accuracy deteriorates with increased mass-ratio, and when at least one black hole spin is large and aligned. The SEOBNRv2 model shows a pronounced disagreement with the numerical relativity simulation in the merger phase, for unequal masses and simultaneously both black hole spins very large and aligned. Two older waveform models (PhenomC and SEOBNRv1) are found to be distinctly less accurate than the more recent PhenomD and SEOBNRv2 models. Finally, we quantify the bias expected from all GW models during parameter estimation for recovery of binary's masses and spins., Comment: 24 pages, 15 figures, minor changes

Published

2016

9. On the accuracy and precision of numerical waveforms: Effect of waveform extraction methodology

Author

Michael Boyle, Béla Szilágyi, H. Fong, Lawrence E. Kidder, Prayush Kumar, Mark A. Scheel, Tony Chu, Daniel A. Hemberger, and Harald P. Pfeiffer

Subjects

Physics, Truncation error, Physics and Astronomy (miscellaneous), 010308 nuclear & particles physics, Gravitational wave, Mathematical analysis, Extrapolation, FOS: Physical sciences, General Relativity and Quantum Cosmology (gr-qc), Mass ratio, 01 natural sciences, General Relativity and Quantum Cosmology, Numerical relativity, Cover (topology), Binary black hole, 0103 physical sciences, Waveform, 010306 general physics

Abstract

We present a new set of 95 numerical relativity simulations of non-precessing binary black holes (BBHs). The simulations sample comprehensively both black-hole spins up to spin magnitude of 0.9, and cover mass ratios 1 to 3. The simulations cover on average 24 inspiral orbits, plus merger and ringdown, with low initial orbital eccentricities $e, 22 pages, 9 figures

Published

2015

10. Fast and accurate prediction of numerical relativity waveforms from binary black hole coalescences using surrogate models

Author

Mark A. Scheel, Chad R. Galley, Béla Szilágyi, Jonathan Blackman, Scott E. Field, Daniel A. Hemberger, and Manuel Tiglio

Subjects

Physics, High Energy Astrophysical Phenomena (astro-ph.HE), FOS: Computer and information sciences, Millisecond, Gravitational wave, Numerical analysis, General Physics and Astronomy, FOS: Physical sciences, General Relativity and Quantum Cosmology (gr-qc), General Relativity and Quantum Cosmology, LIGO, Computational Engineering, Finance, and Science (cs.CE), Theoretical physics, Numerical relativity, Theory of relativity, Surrogate model, Binary black hole, Physics - Data Analysis, Statistics and Probability, Statistical physics, Astrophysics - High Energy Astrophysical Phenomena, Computer Science - Computational Engineering, Finance, and Science, Data Analysis, Statistics and Probability (physics.data-an)

Abstract

Simulating a binary black hole (BBH) coalescence by solving Einstein's equations is computationally expensive, requiring days to months of supercomputing time. Using reduced order modeling techniques, we construct an accurate surrogate model, which is evaluated in a millisecond to a second, for numerical relativity (NR) waveforms from non-spinning BBH coalescences with mass ratios in $[1, 10]$ and durations corresponding to about $15$ orbits before merger. We assess the model's uncertainty and show that our modeling strategy predicts NR waveforms {\em not} used for the surrogate's training with errors nearly as small as the numerical error of the NR code. Our model includes all spherical-harmonic ${}_{-2}Y_{\ell m}$ waveform modes resolved by the NR code up to $\ell=8.$ We compare our surrogate model to Effective One Body waveforms from $50$-$300 M_\odot$ for advanced LIGO detectors and find that the surrogate is always more faithful (by at least an order of magnitude in most cases)., Comment: Updated to published version, which includes a section comparing the surrogate and effective-one-body models. The surrogate is publicly available for download at http://www.black-holes.org/surrogates/ . 6 pages, 6 figures

Published

2015

11. Nearly extremal apparent horizons in simulations of merging black holes

Author

Lawrence E. Kidder, Matthew Giesler, Reza Katebi, Daniel A. Hemberger, Béla Szilágyi, Nousha Afshari, Geoffrey Lovelace, Mark A. Scheel, Tony Chu, Harald P. Pfeiffer, Robert Owen, and Nicholas Demos

Subjects

Physics, Surface (mathematics), Angular momentum, Physics and Astronomy (miscellaneous), 010308 nuclear & particles physics, Astrophysics::High Energy Astrophysical Phenomena, FOS: Physical sciences, General Relativity and Quantum Cosmology (gr-qc), 01 natural sciences, Measure (mathematics), Upper and lower bounds, General Relativity and Quantum Cosmology, Rotating black hole, Binary black hole, Apparent horizon, 0103 physical sciences, 010306 general physics, Spin (physics), Mathematical physics

Abstract

The spin angular momentum $S$ of an isolated Kerr black hole is bounded by the surface area $A$ of its apparent horizon: $8\pi S \le A$, with equality for extremal black holes. In this paper, we explore the extremality of individual and common apparent horizons for merging, rapidly spinning binary black holes. We consider simulations of merging black holes with equal masses $M$ and initial spin angular momenta aligned with the orbital angular momentum, including new simulations with spin magnitudes up to $S/M^2 = 0.994$. We measure the area and (using approximate Killing vectors) the spin on the individual and common apparent horizons, finding that the inequality $8\pi S < A$ is satisfied in all cases but is very close to equality on the common apparent horizon at the instant it first appears. We also introduce a gauge-invariant lower bound on the extremality by computing the smallest value that Booth and Fairhurst's extremality parameter can take for any scaling. Using this lower bound, we conclude that the common horizons are at least moderately close to extremal just after they appear. Finally, following Lovelace et al. (2008), we construct quasiequilibrium binary-black-hole initial data with "overspun" marginally trapped surfaces with $8\pi S > A$ and for which our lower bound on their Booth-Fairhurst extremality exceeds unity. These superextremal surfaces are always surrounded by marginally outer trapped surfaces (i.e., by apparent horizons) with $8\pi S, Comment: 12 pages, 7 figures

Published

2014

12. Error-analysis and comparison to analytical models of numerical waveforms produced by the NRAR Collaboration

Author

Manuela Campanelli, Harald P. Pfeiffer, Denis Pollney, Ulrich Sperhake, Luisa T. Buchman, Lionel London, Barry Wardell, Geoffrey Lovelace, Mark Hannam, Tanja Bode, Jason D. Grigsby, Abdul Mroue, Michael Boyle, Thibault Damour, Philipp Mösta, Andrea Taracchini, Yi Pan, Lawrence E. Kidder, Daniel A. Hemberger, Daniela Alic, Helvi Witek, Marcus Thierfelder, Hiroyuki Nakano, Richard A. Matzner, George Reifenberger, Anil Zenginoglu, Saul A. Teukolsky, Deirdre Shoemaker, Vasileios Paschalidis, Wolfgang Tichy, Roland Haas, Alessandro Nagar, Luciano Rezzolla, Carlos O. Lousto, Nicholas Taylor, Pedro Marronetti, Béla Szilágyi, Stuart L. Shapiro, Doreen Müller, M. Pürrer, Pablo Laguna, Nathan K. Johnson-McDaniel, Sascha Husa, Ian Hinder, Christian Reisswig, Mark A. Scheel, Tony Chu, Erik Schnetter, Bernd Brügmann, Bruno C. Mundim, Sebastiano Bernuzzi, Yosef Zlochower, James Healy, Andrea Nerozzi, Zachariah B. Etienne, Alessandra Buonanno, and The NRAR Collaboration

Subjects

Physics, Solar mass, Physics and Astronomy (miscellaneous), 83C35, 83C57, 010308 nuclear & particles physics, FOS: Physical sciences, Binary number, General Relativity and Quantum Cosmology (gr-qc), Mass ratio, 01 natural sciences, General Relativity and Quantum Cosmology, LIGO, Numerical relativity, Theory of relativity, Binary black hole, 0103 physical sciences, Waveform, 010306 general physics, Algorithm

Abstract

The Numerical-Relativity-Analytical-Relativity (NRAR) collaboration is a joint effort between members of the numerical relativity, analytical relativity and gravitational-wave data analysis communities. The goal of the NRAR collaboration is to produce numerical-relativity simulations of compact binaries and use them to develop accurate analytical templates for the LIGO/Virgo Collaboration to use in detecting gravitational-wave signals and extracting astrophysical information from them. We describe the results of the first stage of the NRAR project, which focused on producing an initial set of numerical waveforms from binary black holes with moderate mass ratios and spins, as well as one non-spinning binary configuration which has a mass ratio of 10. All of the numerical waveforms are analysed in a uniform and consistent manner, with numerical errors evaluated using an analysis code created by members of the NRAR collaboration. We compare previously-calibrated, non-precessing analytical waveforms, notably the effective-one-body (EOB) and phenomenological template families, to the newly-produced numerical waveforms. We find that when the binary's total mass is ~100-200 solar masses, current EOB and phenomenological models of spinning, non-precessing binary waveforms have overlaps above 99% (for advanced LIGO) with all of the non-precessing-binary numerical waveforms with mass ratios, 51 pages, 10 figures; published version

Published

2014

13. Periastron advance in spinning black hole binaries: Gravitational self-force from numerical relativity

Author

Lawrence E. Kidder, Abdul Mroue, Saul A. Teukolsky, Mark A. Scheel, Nicholas Taylor, Alessandra Buonanno, Harald P. Pfeiffer, Béla Szilágyi, Geoffrey Lovelace, Daniel A. Hemberger, and Alexandre Le Tiec

Subjects

Physics, Nuclear and High Energy Physics, 010308 nuclear & particles physics, Astrophysics::High Energy Astrophysical Phenomena, FOS: Physical sciences, General Relativity and Quantum Cosmology (gr-qc), Charged black hole, 01 natural sciences, General Relativity and Quantum Cosmology, Black hole, Classical mechanics, Rotating black hole, Binary black hole, 0103 physical sciences, Extremal black hole, Stellar black hole, Spin-flip, 010306 general physics, Schwarzschild radius

Abstract

We study the general relativistic periastron advance in spinning black hole binaries on quasi-circular orbits, with spins aligned or anti-aligned with the orbital angular momentum, using numerical-relativity simulations, the post-Newtonian approximation, and black hole perturbation theory. By imposing a symmetry by exchange of the bodies' labels, we devise an improved version of the perturbative result, and use it as the leading term of a new type of expansion in powers of the symmetric mass ratio. This allows us to measure, for the first time, the gravitational self-force effect on the periastron advance of a non-spinning particle orbiting a Kerr black hole of mass M and spin S = -0.5 M^2, down to separations of order 9M. Comparing the predictions of our improved perturbative expansion with the exact results from numerical simulations of equal-mass and equal-spin binaries, we find a remarkable agreement over a wide range of spins and orbital separations., Comment: 18 pages, 12 figures; matches version to appear in Phys. Rev. D

Published

2013

14. Periastron advance in spinning black hole binaries: comparing effective-one-body and Numerical Relativity

Author

Alessandra Buonanno, Nicholas Taylor, Harald P. Pfeiffer, Geoffrey Lovelace, Tanja Hinderer, Daniel A. Hemberger, Lawrence E. Kidder, Saul A. Teukolsky, Béla Szilágyi, Abdul Mroue, and Mark A. Scheel

Subjects

Larmor precession, Physics, Nuclear and High Energy Physics, Angular momentum, 010308 nuclear & particles physics, Equations of motion, FOS: Physical sciences, General Relativity and Quantum Cosmology (gr-qc), 01 natural sciences, General Relativity and Quantum Cosmology, Gravitation, Numerical relativity, Classical mechanics, Binary black hole, 0103 physical sciences, Spin-flip, 010306 general physics, Spin (physics)

Abstract

We compute the periastron advance using the effective-one-body formalism for binary black holes moving on quasi-circular orbits and having spins collinear with the orbital angular momentum. We compare the predictions with the periastron advance recently computed in accurate numerical-relativity simulations and find remarkable agreement for a wide range of spins and mass ratios. These results do not use any numerical-relativity calibration of the effective-one-body model, and stem from two key ingredients in the effective-one-body Hamiltonian: (i) the mapping of the two-body dynamics of spinning particles onto the dynamics of an effective spinning particle in a (deformed) Kerr spacetime, fully symmetrized with respect to the two-body masses and spins, and (ii) the resummation, in the test-particle limit, of all post-Newtonian (PN) corrections linear in the spin of the particle. In fact, even when only the leading spin PN corrections are included in the effective-one-body spinning Hamiltonian but all the test-particle corrections linear in the spin of the particle are resummed we find very good agreement with the numerical results (within the numerical error for equal-mass binaries and discrepancies of at most 1% for larger mass ratios). Furthermore, we specialize to the extreme mass-ratio limit and derive, using the equations of motion in the gravitational skeleton approach, analytical expressions for the periastron advance, the meridional Lense-Thirring precession and spin precession frequency in the case of a spinning particle on a nearly circular equatorial orbit in Kerr spacetime, including also terms quadratic in the spin., minor changes to match published version

Published

2013

15. Final spin and radiated energy in numerical simulations of binary black holes with equal masses and equal, aligned or anti-aligned spins

Author

Thomas J. Loredo, Nicholas Taylor, Bela Szilagyi, Mark A. Scheel, Geoffrey Lovelace, Saul A. Teukolsky, Lawrence E. Kidder, and Daniel A. Hemberger

Subjects

Physics, Nuclear and High Energy Physics, 010308 nuclear & particles physics, Gravitational wave, Astrophysics::High Energy Astrophysical Phenomena, FOS: Physical sciences, General Relativity and Quantum Cosmology (gr-qc), 01 natural sciences, General Relativity and Quantum Cosmology, Computational physics, Black hole, Numerical relativity, Classical mechanics, Binary black hole, Rotating black hole, 0103 physical sciences, Stellar black hole, Spin-flip, 010306 general physics, Hawking radiation

Abstract

The behavior of merging black holes (including the emitted gravitational waves and the properties of the remnant) can currently be computed only by numerical simulations. This paper introduces ten numerical relativity simulations of binary black holes with equal masses and equal spins aligned or anti-aligned with the orbital angular momentum. The initial spin magnitudes have $|\chi_i| \lesssim 0.95$ and are more concentrated in the aligned direction because of the greater astrophysical interest of this case. We combine this data with five previously reported simulations of the same configuration, but with different spin magnitudes, including the highest spin simulated to date, $\chi_i \approx 0.97$. This data set is sufficiently accurate to enable us to offer improved analytic fitting formulae for the final spin and for the energy radiated by gravitational waves as a function of initial spin. The improved fitting formulae can help to improve our understanding of the properties of binary black hole merger remnants and can be used to enhance future approximate waveforms for gravitational wave searches, such as Effective-One-Body waveforms., Comment: 13 pages, 10 figures

Published

2013

16. A catalog of 174 binary black-hole simulations for gravitational-wave astronomy

Author

E. Foley, Matthew Giesler, Serguei Ossokine, Geoffrey Lovelace, Luisa T. Buchman, Daniel A. Hemberger, Robert Owen, Michael Boyle, Abdul Mroue, Lawrence E. Kidder, Saul A. Teukolsky, Anil Zenginoglu, Mark A. Scheel, Nicholas Taylor, Harald P. Pfeiffer, Béla Szilágyi, and Tony Chu

Subjects

Physics, 010308 nuclear & particles physics, X-ray binary, FOS: Physical sciences, General Physics and Astronomy, General Relativity and Quantum Cosmology (gr-qc), Astrophysics, 01 natural sciences, General Relativity and Quantum Cosmology, Black hole, Binary black hole, Rotating black hole, 0103 physical sciences, Extremal black hole, Precession, Stellar black hole, Spin-flip, 010306 general physics

Abstract

This paper presents a publicly available catalog of 174 numerical binary black-hole simulations following up to 35 orbits. The catalog includes 91 precessing binaries, mass ratios up to 8:1, orbital eccentricities from a few percent to $10^{-5}$, black-hole spins up to 98% of the theoretical maximum, and radiated energies up to 11.1% of the initial mass. We establish remarkably good agreement with post-Newtonian precession of orbital and spin directions for two new precessing simulations, and we discuss other applications of this catalog. Formidable challenges remain: e.g., precession complicates the connection of numerical and approximate analytical waveforms, and vast regions of the parameter space remain unexplored., 6 pages; text clarified; additional results added

Published

2013

17. Dynamical Excision Boundaries in Spectral Evolutions of Binary Black Hole Spacetimes

Author

Geoffrey Lovelace, Nicholas Taylor, Daniel A. Hemberger, Béla Szilágyi, Mark A. Scheel, Saul A. Teukolsky, and Lawrence E. Kidder

Subjects

Physics, Partial differential equation, Inertial frame of reference, Physics and Astronomy (miscellaneous), 010308 nuclear & particles physics, Astrophysics::High Energy Astrophysical Phenomena, Motion (geometry), FOS: Physical sciences, General Relativity and Quantum Cosmology (gr-qc), 01 natural sciences, Domain (mathematical analysis), General Relativity and Quantum Cosmology, symbols.namesake, Classical mechanics, Binary black hole, 0103 physical sciences, symbols, Outflow, Einstein, 010306 general physics, Spin-½

Abstract

Simulations of binary black hole systems using the Spectral Einstein Code (SpEC) are done on a computational domain that excises the regions inside the black holes. It is imperative that the excision boundaries are outflow boundaries with respect to the hyperbolic evolution equations used in the simulation. We employ a time-dependent mapping between the fixed computational frame and the inertial frame through which the black holes move. The time-dependent parameters of the mapping are adjusted throughout the simulation by a feedback control system in order to follow the motion of the black holes, to adjust the shape and size of the excision surfaces so that they remain outflow boundaries, and to prevent large distortions of the grid. We describe in detail the mappings and control systems that we use. We show how these techniques have been essential in the evolution of binary black hole systems with extreme configurations, such as large spin magnitudes and high mass ratios, especially during the merger, when apparent horizons are highly distorted and the computational domain becomes compressed. The techniques introduced here may be useful in other applications of partial differential equations that involve time-dependent mappings., 40 pages, 12 figures

Published

2012

18. Improved methods for simulating nearly extremal binary black holes

Author

Lawrence E. Kidder, Geoffrey Lovelace, Béla Szilágyi, Mark A. Scheel, Daniel A. Hemberger, Michael Boyle, Matthew Giesler, and Kevin Kuper

Subjects

Coalescence (physics), Physics, Physics and Astronomy (miscellaneous), Spins, 010308 nuclear & particles physics, Gravitational wave, Astrophysics::High Energy Astrophysical Phenomena, FOS: Physical sciences, General Relativity and Quantum Cosmology (gr-qc), Orbital mechanics, 01 natural sciences, Upper and lower bounds, General Relativity and Quantum Cosmology, Computational physics, Black hole, Binary black hole, Accretion disc, 0103 physical sciences, 010306 general physics

Abstract

Astrophysical black holes could be nearly extremal (that is, rotating nearly as fast as possible); therefore, nearly extremal black holes could be among the binaries that current and future gravitational-wave observatories will detect. Predicting the gravitational waves emitted by merging black holes requires numerical-relativity simulations, but these simulations are especially challenging when one or both holes have mass $m$ and spin $S$ exceeding the Bowen-York limit of $S/m^2=0.93$. We present improved methods that enable us to simulate merging, nearly extremal black holes more robustly and more efficiently. We use these methods to simulate an unequal-mass, precessing binary black hole coalescence, where the larger black hole has $S/m^2=0.99$. We also use these methods to simulate a non-precessing binary black hole coalescence, where both black holes have $S/m^2=0.994$, nearly reaching the Novikov-Thorne upper bound for holes spun up by thin accretion disks. We demonstrate numerical convergence and estimate the numerical errors of the waveforms; we compare numerical waveforms from our simulations with post-Newtonian and effective-one-body waveforms; we compare the evolution of the black-hole masses and spins with analytic predictions; and we explore the effect of increasing spin magnitude on the orbital dynamics (the so-called "orbital hangup" effect)., Comment: 18 pages, 18 figures

Published

2015