Your search keyword '"Vu, Nils"' showing total 73 results

1. Signatures of Quantum Gravity in Gravitational Wave Memory

Author

Deppe, Nils, Heisenberg, Lavinia, Kidder, Lawrence E., Maibach, David, Ma, Sizheng, Moxon, Jordan, Nelli, Kyle C., Throwe, William, and Vu, Nils L.

Subjects

General Relativity and Quantum Cosmology, High Energy Physics - Phenomenology, High Energy Physics - Theory

Abstract

We study the impact of quantum corrections to gravitational waveforms on the gravitational wave memory effect. In certain quantum gravity theories and semi-classical frameworks, black holes (or other exotic compact objects) exhibit reflective properties that cause quasi-normal modes of a binary merger waveform to partially reflect off the horizon. If these reflections reach the detector, the measured gravitational wave signal may show echo-like features following the initial ringdown phase. Detecting such echoes, or their indirect signatures, would offer compelling evidence for the quantum nature of black holes. Given that direct detection of echoes requires finely tuned waveform templates, exploring alternative imprints of this phenomenon is crucial. In this work, we pursue this goal by calculating corrections to the null memory arising from echo-like features, formulated in terms of the Newman-Penrose scalar ${\Psi}_0$. We demonstrate that the morphology of the resulting features is model-independent rendering them conceptually much easier to detect in real interferometer data than the raw echo. The corresponding signal-to-noise ratio of echo-induced features appearing in the gravitational wave memory is estimated subsequently. We further compute the physical fluxes associated to the echo at both the black hole horizon and null infinity and identify novel distinguishing features of the underlying reflectivity models in measurement data.

Published

2025

2. The robustness of extracting quasinormal mode information from black hole merger simulations

Author

Gao, Leda, Cook, Gregory B., Kidder, Lawrence E., Pfeiffer, Harald P., Scheel, Mark A., Deppe, Nils, Throwe, William, Vu, Nils L., Nelli, Kyle C., Moxon, Jordan, and Boyle, Michael

Subjects

General Relativity and Quantum Cosmology

Abstract

In linear perturbation theory, the ringdown of a gravitational wave (GW) signal is described by a linear combination of quasinormal modes (QNMs). Detecting QNMs from GW signals is a promising way to test GR, central to the developing field of black-hole spectroscopy. More robust black-hole spectroscopy tests could also consider the ringdown amplitude-phase consistency. That requires an accurate understanding of the excitation and stability of the QNM expansion coefficients. In this paper, we investigate the robustness of the extracted $m=2$ QNM coefficients obtained from a high-accuracy numerical relativity waveform. We explore a framework to assess the robustness of QNM coefficients. Within this framework, we not only consider the traditional criterion related to the constancy of a QNM's expansion coefficients over a window in time, but also emphasize the importance of consistency among fitting models. In addition, we implement an iterative greedy approach within which we fix certain QNM coefficients. We apply this approach to linear fitting, and to nonlinear fitting where the properties of the remnant black hole are treated as unknown variables. We find that the robustness of overtone coefficients is enhanced by our greedy approach, particularly for the $(2,2,2,+)$ overtone. Based on our robustness criteria applied to the $m=2$ signal modes, we find the $(2\!\sim\!4,2,0,+)$ and $(2,2,1\!\sim\!2,+)$ modes are robust, while the $(3,2,1,+)$ subdominant mode is only marginally robust. After we subtract the contributions of the $(2\!\sim\!4,2,0,+)$ and $(2\!\sim\!3,2,1,+)$ QNMs from signal mode $(4,2)$, we also find evidence for the quadratic QNM $(2,1,0,+)\times(2,1,0,+)$.

Published

2025

3. Late-time tails in nonlinear evolutions of merging black holes

Author

De Amicis, Marina, Rüter, Hannes, Carullo, Gregorio, Albanesi, Simone, Ferrus, C. Melize, Mitman, Keefe, Stein, Leo C., Cardoso, Vitor, Bernuzzi, Sebastiano, Boyle, Michael, Deppe, Nils, Kidder, Lawrence E., Moxon, Jordan, Nagar, Alessandro, Nelli, Kyle C., Pfeiffer, Harald P., Scheel, Mark A., Throwe, William, Vu, Nils L., and Zenginoğlu, Anıl

Subjects

General Relativity and Quantum Cosmology, High Energy Physics - Theory, Mathematical Physics

Abstract

We uncover late-time gravitational-wave tails in fully nonlinear 3+1 dimensional numerical relativity simulations of merging black holes, using the highly accurate SpEC code. We achieve this result by exploiting the strong magnification of late-time tails due to binary eccentricity, recently observed in perturbative evolutions, and showcase here the tail presence in head-on configurations for several mass ratios close to unity. We validate the result through a large battery of numerical tests and detailed comparison with perturbative evolutions, which display striking agreement with full nonlinear ones. Our results offer yet another confirmation of the highly predictive power of black hole perturbation theory in the presence of a source, even when applied to nonlinear solutions. The late-time tail signal is much more prominent than anticipated until recently, and possibly within reach of gravitational-wave detectors measurements, unlocking observational investigations of an additional set of general relativistic predictions on the long-range gravitational dynamics., Comment: 5+7 pages, 2+5 figures, 1+1 tables

Published

2024

4. Merging black holes with Cauchy-characteristic matching: Computation of late-time tails

Author

Ma, Sizheng, Scheel, Mark A., Moxon, Jordan, Nelli, Kyle C., Deppe, Nils, Kidder, Lawrence E., Throwe, William, and Vu, Nils L.

Subjects

General Relativity and Quantum Cosmology, Astrophysics - High Energy Astrophysical Phenomena, High Energy Physics - Theory

Abstract

We present successful evolutions of binary black hole mergers using a novel numerical-relativity technique known as Cauchy-characteristic matching (CCM). This approach eliminates systematic errors associated with boundary conditions, effectively extending the computational domain to infinity. As an important application, we use CCM to resolve a late-time power-law tail in the gravitational wave from a head-on collision, and show that the tail is highly suppressed in a quasi-circular binary. Our results for the two extreme cases (orbital eccentricity $=0,1$) support the fact that tails increase with orbital eccentricity. Therefore, CCM paves the way for a detailed understanding of tails in eccentric systems. For the head-on case, we find that the tail behavior is consistent with predictions in the intermediate regime from black hole linear perturbation theory. However, we also raise the possibility that the power-law tail could be generated nonlinearly by quasinormal modes. The nonlinear contribution is expected to decay slower than predicted by Price's law, potentially dominating the signal at late times. If confirmed as nonlinear, this would be an example where nonlinearity prevails over linearity in the late-time regime of black hole dynamics.

Published

2024

5. Overtones and Nonlinearities in Binary Black Hole Ringdowns

Author

Giesler, Matthew, Ma, Sizheng, Mitman, Keefe, Oshita, Naritaka, Teukolsky, Saul A., Boyle, Michael, Deppe, Nils, Kidder, Lawrence E., Moxon, Jordan, Nelli, Kyle C., Pfeiffer, Harald P., Scheel, Mark A., Throwe, William, and Vu, Nils L.

Subjects

General Relativity and Quantum Cosmology

Abstract

Using high-accuracy numerical relativity waveforms, we confirm the presence of numerous overtones of the $\ell=2$, $m=2$ quasinormal mode early in the ringdown of binary black hole mergers. We do this by demonstrating the stability of the mode amplitudes at different fit times, ruling out the possibility that a linear superposition of modes unphysically fits a highly nonlinear part of the waveform. We also find a number of previously unidentified subdominant second-order quasinormal modes in the $(2,2)$ mode. Even though these modes are mathematically nonlinear, they nevertheless confirm the validity of perturbation theory as a good approximation for describing much of the ringdown., Comment: 17 pages, 14 figures

Published

2024

6. Echoes from Beyond: Detecting Gravitational Wave Quantum Imprints with LISA

Author

Deppe, Nils, Heisenberg, Lavinia, Inchauspé, Henri, Kidder, Lawrence E., Maibach, David, Ma, Sizheng, Moxon, Jordan, Nelli, Kyle C., Throwe, William, and Vu, Nils L.

Subjects

General Relativity and Quantum Cosmology, Astrophysics - Cosmology and Nongalactic Astrophysics, High Energy Physics - Theory

Abstract

We assess the prospects for detecting gravitational wave echoes arising due to the quantum nature of black hole horizons with LISA. In a recent proposal, Bekenstein's black hole area quantization is connected to a discrete absorption spectrum for black holes in the context of gravitational radiation. Consequently, for incoming radiation at the black hole horizon, not all frequencies are absorbed, raising the possibility that the unabsorbed radiation is reflected, producing an echo-like signal closely following the binary coalescence waveform. In this work, we further develop this proposal by introducing a robust, phenomenologically motivated model for black hole reflectivity. Using this model, we calculate the resulting echoes for an ensemble of Numerical Relativity waveforms and examine their detectability with the LISA space-based interferometer. Our analysis demonstrates promising detection prospects and shows that, upon detection, LISA provides a direct probe of the Bekenstein-Hawking entropy. In addition, we find that the information extractable from LISA data offers valuable constraints on a wide range of quantum gravity theories., Comment: 9 pages, 8 Figures

Published

2024

7. Relieving scale disparity in binary black hole simulations

Author

Wittek, Nikolas A., Barack, Leor, Pfeiffer, Harald P., Pound, Adam, Deppe, Nils, Kidder, Lawrence E., Macedo, Alexandra, Nelli, Kyle C., Throwe, William, and Vu, Nils L.

Subjects

General Relativity and Quantum Cosmology

Abstract

Worldtube excision is a method of reducing computational burden in Numerical Relativity simulations of binary black holes in situations where there is a good analytical model of the geometry around (one or both of) the objects. Two such scenarios of relevance in gravitational-wave astronomy are (1) the case of mass-disparate systems, and (2) the early inspiral when the separation is still large. Here we illustrate the utility and flexibility of this technique with simulations of the fully self-consistent radiative evolution in the model problem of a scalar charge orbiting a Schwarzschild black hole under the effect of scalar-field radiation reaction. We explore a range of orbital configurations, including inspirals with large eccentricity (which we follow through to the final plunge and ringdown) and hyperbolic scattering., Comment: 8 pages, 4 figures

Published

2024

8. Simulating binary black hole mergers using discontinuous Galerkin methods

Author

Lovelace, Geoffrey, Nelli, Kyle C., Deppe, Nils, Vu, Nils L., Throwe, William, Bonilla, Marceline S., Carpenter, Alexander, Kidder, Lawrence E., Macedo, Alexandra, Scheel, Mark A., Afram, Azer, Boyle, Michael, Ceja, Andrea, Giesler, Matthew, Habib, Sarah, Jones, Ken Z., Kumar, Prayush, Lara, Guillermo, Melchor, Denyz, Mendes, Iago B., Mitman, Keefe, Morales, Marlo, Moxon, Jordan, O'Shea, Eamonn, Pannone, Kyle, Pfeiffer, Harald P., Ramirez-Aguilar, Teresita, Sanchez, Jennifer, Tellez, Daniel, Teukolsky, Saul A., and Wittek, Nikolas A.

Subjects

General Relativity and Quantum Cosmology

Abstract

Binary black holes are the most abundant source of gravitational-wave observations. Gravitational-wave observatories in the next decade will require tremendous increases in the accuracy of numerical waveforms modeling binary black holes, compared to today's state of the art. One approach to achieving the required accuracy is using spectral-type methods that scale to many processors. Using the SpECTRE numerical-relativity code, we present the first simulations of a binary black hole inspiral, merger, and ringdown using discontinuous Galerkin methods. The efficiency of discontinuous Galerkin methods allows us to evolve the binary through ~18 orbits at reasonable computational cost. We then use SpECTRE's Cauchy Characteristic Evolution (CCE) code to extract the gravitational waves at future null infinity. The open-source nature of SpECTRE means this is the first time a spectral-type method for simulating binary black hole evolutions is available to the entire numerical-relativity community., Comment: 32 pages, 12 figures, 28 ancillary input files

Published

2024

9. Einstein-Klein-Gordon system via Cauchy-characteristic evolution: Computation of memory and ringdown tail

Author

Ma, Sizheng, Nelli, Kyle C., Moxon, Jordan, Scheel, Mark A., Deppe, Nils, Kidder, Lawrence E., Throwe, William, and Vu, Nils L.

Subjects

General Relativity and Quantum Cosmology

Abstract

Cauchy-characteristic evolution (CCE) is a powerful method for accurately extracting gravitational waves at future null infinity. In this work, we extend the previously implemented CCE system within the numerical relativity code SpECTRE by incorporating a scalar field. This allows the system to capture features of beyond-general-relativity theories. We derive scalar contributions to the equations of motion, Weyl scalar computations, Bianchi identities, and balance laws at future null infinity. Our algorithm, tested across various scenarios, accurately reveals memory effects induced by both scalar and tensor fields and captures Price's power-law tail ($u^{-l-2}$) in scalar fields at future null infinity, in contrast to the $t^{-2l-3}$ tail at future timelike infinity.

Published

2024

10. High-Precision Ringdown Surrogate Model for Non-Precessing Binary Black Holes

Author

Zertuche, Lorena Magaña, Stein, Leo C., Mitman, Keefe, Field, Scott E., Varma, Vijay, Boyle, Michael, Deppe, Nils, Kidder, Lawrence E., Moxon, Jordan, Pfeiffer, Harald P., Scheel, Mark A., Nelli, Kyle C., Throwe, William, and Vu, Nils L.

Subjects

General Relativity and Quantum Cosmology

Abstract

Highly precise and robust waveform models are required as improvements in detector sensitivity enable us to test general relativity with more precision than ever before. In this work, we introduce a spin-aligned surrogate ringdown model. This ringdown surrogate, NRSur3dq8_RD, is built with numerical waveforms produced using Cauchy-characteristic evolution. In addition, these waveforms are in the superrest frame of the remnant black hole allowing us to do a correct analysis of the ringdown spectrum. The novel prediction of our surrogate model is complex-valued quasinormal mode (QNM) amplitudes, with median relative errors of $10^{-2}-10^{-3}$ over the parameter space. Like previous remnant surrogates, we also predict the remnant black hole's mass and spin. The QNM mode amplitude errors translate into median errors on ringdown waveforms of $10^{-4}$. The high accuracy and QNM mode content provided by our surrogate will enable high-precision ringdown analyses such as tests of general relativity. Our ringdown model is publicly available through the python package surfinBH., Comment: 11+2 pages, 13 figures, 1 table. This new model is publicly available through surfinBH https://pypi.org/project/surfinBH/

Published

2024

11. Binary neutron star mergers using a discontinuous Galerkin-finite difference hybrid method

Author

Deppe, Nils, Foucart, Francois, Bonilla, Marceline S., Boyle, Michael, Corso, Nicholas J., Duez, Matthew D., Giesler, Matthew, Hébert, François, Kidder, Lawrence E., Kim, Yoonsoo, Kumar, Prayush, Legred, Isaac, Lovelace, Geoffrey, Most, Elias R., Moxon, Jordan, Nelli, Kyle C., Pfeiffer, Harald P., Scheel, Mark A., Teukolsky, Saul A., Throwe, William, and Vu, Nils L.

Subjects

General Relativity and Quantum Cosmology

Abstract

We present a discontinuous Galerkin-finite difference hybrid scheme that allows high-order shock capturing with the discontinuous Galerkin method for general relativistic magnetohydrodynamics in dynamical spacetimes. We present several optimizations and stability improvements to our algorithm that allow the hybrid method to successfully simulate single, rotating, and binary neutron stars. The hybrid method achieves the efficiency of discontinuous Galerkin methods throughout almost the entire spacetime during the inspiral phase, while being able to robustly capture shocks and resolve the stellar surfaces. We also use Cauchy-Characteristic evolution to compute the first gravitational waveforms at future null infinity from binary neutron star mergers. The simulations presented here are the first successful binary neutron star inspiral and merger simulations using discontinuous Galerkin methods., Comment: 31 pages, 8 figures, minor wording updates

Published

2024

12. Quasistationary hair for binary black hole initial data in scalar Gauss-Bonnet gravity

Author

Nee, Peter James, Lara, Guillermo, Pfeiffer, Harald P., and Vu, Nils L.

Subjects

General Relativity and Quantum Cosmology

Abstract

Recent efforts to numerically simulate compact objects in alternative theories of gravity have largely focused on the time-evolution equations. Another critical aspect is the construction of constraint-satisfying initial data with precise control over the properties of the systems under consideration. Here, we augment the extended conformal thin sandwich framework to construct quasistationary initial data for black hole systems in scalar Gauss-Bonnet theory and numerically implement it in the open-source SpECTRE code. Despite the resulting elliptic system being singular at black hole horizons, we demonstrate how to construct numerical solutions that extend smoothly across the horizon. We obtain quasistationary scalar hair configurations in the test-field limit for black holes with linear/angular momentum as well as for black hole binaries. For isolated black holes, we explicitly show that the scalar profile obtained is stationary by evolving the system in time and compare against previous formulations of scalar Gauss-Bonnet initial data. In the case of the binary, we find that the scalar hair near the black holes can be markedly altered by the presence of the other black hole. The initial data constructed here enables targeted simulations in scalar Gauss-Bonnet simulations with reduced initial transients., Comment: 13 pages, 11 figures

Published

2024

13. A Review of Gravitational Memory and BMS Frame Fixing in Numerical Relativity

Author

Mitman, Keefe, Boyle, Michael, Stein, Leo C., Deppe, Nils, Kidder, Lawrence E., Moxon, Jordan, Pfeiffer, Harald P., Scheel, Mark A., Teukolsky, Saul A., Throwe, William, and Vu, Nils L.

Subjects

General Relativity and Quantum Cosmology, High Energy Physics - Theory

Abstract

Gravitational memory effects and the BMS freedoms exhibited at future null infinity have recently been resolved and utilized in numerical relativity simulations. With this, gravitational wave models and our understanding of the fundamental nature of general relativity have been vastly improved. In this paper, we review the history and intuition behind memory effects and BMS symmetries, how they manifest in gravitational waves, and how controlling the infinite number of BMS freedoms of numerical relativity simulations can crucially improve the waveform models that are used by gravitational wave detectors. We reiterate the fact that, with memory effects and BMS symmetries, not only can these next-generation numerical waveforms be used to observe never-before-seen physics, but they can also be used to test GR and learn new astrophysical information about our universe., Comment: 22 pages, 8 figures. Matches published version in CGQ's focus issue: Gravitational-Wave Memory Effects: From Theory to Observation

Published

2024

14. Improved frequency spectra of gravitational waves with memory in a binary-black-hole simulation

Author

Chen, Yitian, Boyle, Michael, Deppe, Nils, Kidder, Lawrence E., Mitman, Keefe, Moxon, Jordan, Nelli, Kyle C., Pfeiffer, Harald P., Scheel, Mark A., Throwe, William, Vu, Nils L., and Teukolsky, Saul A.

Subjects

General Relativity and Quantum Cosmology

Abstract

Numerical relativists can now produce gravitational waveforms with memory effects routinely and accurately. The gravitational-wave memory effect contains very low-frequency components, including a persistent offset. The presence of these components violates basic assumptions about time-shift behavior underpinning standard data-analysis techniques in gravitational-wave astronomy. This poses a challenge to the analysis of waveform spectra: How to preserve the low-frequency characteristics when transforming a time-domain waveform to the frequency domain. To tackle this challenge, we revisit the preprocessing procedures applied to the waveforms that contain memory effects. We find inconsistency between the zero-frequency limit of displacement memory and the low- frequency spectrum of the same memory preprocessed using the common scheme in literature. To resolve the inconsistency, we propose a new robust preprocessing scheme that produces the spectra of memory waveforms more faithfully. Using this new scheme, we inspect several characteristics of the spectrum of a memory waveform. In particular, we find a discernible beating pattern formed by the dominant oscillatory mode and the displacement memory. This pattern is absent in the spectrum of a waveform without memory. The difference between the memory and no-memory waveforms is too small to be observed by current-generation detectors in a single binary-black-hole event. Detecting the memory in a single event is likely to occur in the era of next-generation detectors., Comment: 24 pages, 11 figures, 5 tables

Published

2024

15. Discontinuous Galerkin scheme for elliptic equations on extremely stretched grids

Author

Vu, Nils L.

Subjects

General Relativity and Quantum Cosmology, Mathematics - Numerical Analysis

Abstract

Discontinuous Galerkin (DG) methods for solving elliptic equations are gaining popularity in the computational physics community for their high-order spectral convergence and their potential for parallelization on computing clusters. However, problems in numerical relativity with extremely stretched grids, such as initial data problems for binary black holes that impose boundary conditions at large distances from the black holes, have proven challenging for DG methods. To alleviate this problem we have developed a primal DG scheme that is generically applicable to a large class of elliptic equations, including problems on curved and extremely stretched grids. The DG scheme accommodates two widely used initial data formulations in numerical relativity, namely the puncture formulation and the extended conformal thin-sandwich (XCTS) formulation. We find that our DG scheme is able to stretch the grid by a factor of $\sim 10^9$ and hence allows to impose boundary conditions at large distances. The scheme converges exponentially with resolution both for the smooth XCTS problem and for the nonsmooth puncture problem. With this method we are able to generate high-quality initial data for binary black hole problems using a parallelizable DG scheme. The code is publicly available in the open-source SpECTRE numerical relativity code., Comment: 14 pages, 10 figures. Results are reproducible with the ancillary input files

Published

2024

16. Scalarization of isolated black holes in scalar Gauss-Bonnet theory in the fixing-the-equations approach

Author

Lara, Guillermo, Pfeiffer, Harald P., Wittek, Nikolas A., Vu, Nils L., Nelli, Kyle C., Carpenter, Alexander, Lovelace, Geoffrey, Scheel, Mark A., and Throwe, William

Subjects

General Relativity and Quantum Cosmology

Abstract

One of the most promising avenues to perform numerical evolutions in theories beyond General Relativity is the fixing-the-equations approach, a proposal in which new ``driver'' equations are added to the evolution equations in a way that allows for stable numerical evolutions. In this direction, we extend the numerical relativity code SpECTRE to evolve a ``fixed'' version of scalar Gauss-Bonnet theory in the decoupling limit, a phenomenologically interesting theory that allows for hairy black hole solutions in vacuum. We focus on isolated black hole systems both with and without linear and angular momentum, and propose a new driver equation to improve the recovery of such stationary solutions. We demonstrate the effectiveness of the latter by numerically evolving black holes that undergo spontaneous scalarization using different driver equations. Finally, we evaluate the accuracy of the obtained solutions by comparing with the original unaltered theory., Comment: 16 pages, 12 figures

Published

2024

17. Striking the right tone: toward a self-consistent framework for measuring black hole ringdowns

Author

Clarke, Teagan A., Isi, Maximiliano, Lasky, Paul D., Thrane, Eric, Boyle, Michael, Deppe, Nils, Kidder, Lawrence E., Mitman, Keefe, Moxon, Jordan, Nelli, Kyle C., Throwe, William, and Vu, Nils L.

Subjects

General Relativity and Quantum Cosmology, Astrophysics - High Energy Astrophysical Phenomena

Abstract

The ringdown portion of a binary black hole merger consists of a sum of modes, each containing an infinite number of tones that are exponentially damped sinusoids. In principle, these can be measured as gravitational-waves with observatories like LIGO/Virgo/KAGRA, however in practice it is unclear how many tones can be meaningfully resolved. We investigate the consistency and resolvability of the overtones of the quadrupolar $\ell = m = 2$ mode by starting at late times when the gravitational waveform is expected to be well-approximated by the $\ell m n = 220$ tone alone. We present a Bayesian inference framework to measure the tones in numerical relativity data. We measure tones at different start times, checking for consistency: we classify a tone as stably recovered if and only if the 95\% credible intervals for amplitude and phase at time $t$ overlap with the credible intervals at all subsequent times. We test a set of tones including the first four overtones of the fundamental mode and the 320 tone and find that the 220 and 221 tones can be measured consistently with the inclusion of additional overtones. The 222 tone measurements can be stabilised when we include the 223 tone, but only in a narrow time window, after which it is too weak to measure. The 223 tone recovery appears to be unstable, and does not become stable with the introduction of the 224 tone. We find that $N=3$ tones can be stably recovered simultaneously. However, when analysing $N \geq 4$ tones, the amplitude of one tone is consistent with zero. Thus, within our framework, one can identify only $N=3$ tones with non-zero amplitude that are simultaneously stable., Comment: 14 pages, 8 figures, 2 tables. Published in PRD

Published

2024

18. Nonlinear Effects In Black Hole Ringdown From Scattering Experiments I: spin and initial data dependence of quadratic mode coupling

Author

Zhu, Hengrui, Ripley, Justin L., Pretorius, Frans, Ma, Sizheng, Mitman, Keefe, Owen, Robert, Boyle, Michael, Chen, Yitian, Deppe, Nils, Kidder, Lawrence E., Moxon, Jordan, Nelli, Kyle C., Pfeiffer, Harald P., Scheel, Mark A., Throwe, William, and Vu, Nils L.

Subjects

General Relativity and Quantum Cosmology, Astrophysics - Cosmology and Nongalactic Astrophysics

Abstract

We investigate quadratic quasinormal mode coupling in black hole spacetime through numerical simulations of single perturbed black holes using both numerical relativity and second-order black hole perturbation theory. Focusing on the dominant $\ell=|m|=2$ quadrupolar modes, we find good agreement (within $\sim10\%$) between these approaches, with discrepancies attributed to truncation error and uncertainties from mode fitting. Our results align with earlier studies extracting the coupling coefficients from select binary black hole merger simulations, showing consistency for the same remnant spins. Notably, the coupling coefficient is insensitive to a diverse range of initial data, including configurations that led to a significant (up to $5\%$) increase in the remnant black hole mass. These findings present opportunities for testing the nonlinear dynamics of general relativity with ground-based gravitational wave observatories. Lastly, we provide evidence of a bifurcation in coupling coefficients between counter-rotating and co-rotating quasinormal modes as black hole spin increases.

Published

2024

19. Black Hole Spectroscopy for Precessing Binary Black Hole Coalescences

Author

Zhu, Hengrui, Siegel, Harrison, Mitman, Keefe, Isi, Maximiliano, Farr, Will M., Boyle, Michael, Deppe, Nils, Kidder, Lawrence E., Ma, Sizheng, Moxon, Jordan, Nelli, Kyle C., Pfeiffer, Harald P., Scheel, Mark A., Teukolsky, Saul A., Throwe, William, Varma, Vijay, and Vu, Nils L.

Subjects

General Relativity and Quantum Cosmology, Astrophysics - Cosmology and Nongalactic Astrophysics, Astrophysics - Solar and Stellar Astrophysics

Abstract

The spectroscopic study of black hole quasinormal modes in gravitational-wave ringdown observations is hindered by our ignorance of which modes should dominate astrophysical signals for different binary configurations, limiting tests of general relativity and astrophysics. In this work, we present a description of the quasinormal modes that are excited in the ringdowns of comparable mass, quasi-circular precessing binary black hole coalescences -- a key region of parameter space that has yet to be fully explored within the framework of black hole spectroscopy. We suggest that the remnant perturbation for precessing and non-precessing systems is approximately the same up to a rotation, which implies that the relative amplitudes of the quasinormal modes in both systems are also related by a rotation. We present evidence for this by analyzing an extensive catalog of numerical relativity simulations. Additional structure in the amplitudes is connected to the system's kick velocity and other asymmetries in the orbital dynamics. We find that the ringdowns of precessing systems need not be dominated by the ${(\ell,m)=(2,\pm 2)}$ quasinormal modes, and that instead the $(2,\pm 1)$~or~$(2,0)$ quasinormal modes can dominate. Our results are consistent with a ringdown analysis of the LIGO-Virgo gravitational wave signal GW190521, and may also help in understanding phenomenological inspiral-merger-ringdown waveform model systematics., Comment: Data Release and Analysis Scripts: https://github.com/HengruiPrinceton/precession_ringdown

Published

2023

20. Fully relativistic three-dimensional Cauchy-characteristic matching for physical degrees of freedom

Author

Ma, Sizheng, Moxon, Jordan, Scheel, Mark A., Nelli, Kyle C., Deppe, Nils, Bonilla, Marceline S., Kidder, Lawrence E., Kumar, Prayush, Lovelace, Geoffrey, Throwe, William, and Vu, Nils L.

Subjects

General Relativity and Quantum Cosmology

Abstract

A fully relativistic three-dimensional Cauchy-characteristic matching (CCM) algorithm is implemented for physical degrees of freedom in a numerical relativity code SpECTRE. The method is free of approximations and can be applied to any physical system. We test the algorithm with various scenarios involving smooth data, including the propagation of Teukolsky waves within a flat background, the perturbation of a Kerr black hole with a Teukolsky wave, and the injection of a gravitational-wave pulse from the characteristic grid. Our investigations reveal no numerical instabilities in the simulations. In addition, the tests indicate that the CCM algorithm effectively directs characteristic information into the inner Cauchy system, yielding higher precision in waveforms and smaller violations of Bondi-gauge constraints, especially when the outer boundary of the Cauchy evolution is at a smaller radius.

Published

2023

21. Extending black-hole remnant surrogate models to extreme mass ratios

Author

Boschini, Matteo, Gerosa, Davide, Varma, Vijay, Armaza, Cristobal, Boyle, Michael, Bonilla, Marceline S., Ceja, Andrea, Chen, Yitian, Deppe, Nils, Giesler, Matthew, Kidder, Lawrence E., Kumar, Prayush, Lara, Guillermo, Long, Oliver, Ma, Sizheng, Mitman, Keefe, Nee, Peter James, Pfeiffer, Harald P., Ramos-Buades, Antoni, Scheel, Mark A., Vu, Nils L., and Yoo, Jooheon

Subjects

General Relativity and Quantum Cosmology, Astrophysics - High Energy Astrophysical Phenomena

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 post-merger 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., Comment: 10 pages, 3 figures. Published in PRD. Model publicly available at https://pypi.org/project/surfinBH

Published

2023

22. A positivity-preserving adaptive-order finite-difference scheme for GRMHD

Author

Deppe, Nils, Kidder, Lawrence E., Teukolsky, Saul A., Bonilla, Marceline S., Hébert, François, Kim, Yoonsoo, Scheel, Mark A., Throwe, William, and Vu, Nils L.

Subjects

Astrophysics - High Energy Astrophysical Phenomena, General Relativity and Quantum Cosmology

Abstract

We present an adaptive-order positivity-preserving conservative finite-difference scheme that allows a high-order solution away from shocks and discontinuities while guaranteeing positivity and robustness at discontinuities. This is achieved by monitoring the relative power in the highest mode of the reconstructed polynomial and reducing the order when the polynomial series no longer converges. Our approach is similar to the multidimensional optimal order detection (MOOD) strategy, but differs in several ways. The approach is a priori and so does not require retaking a time step. It can also readily be combined with positivity-preserving flux limiters that have gained significant traction in computational astrophysics and numerical relativity. This combination ultimately guarantees a physical solution both during reconstruction and time stepping. We demonstrate the capabilities of the method using a standard suite of very challenging 1d, 2d, and 3d general relativistic magnetohydrodynamics test problems., Comment: 48 pages, 17 figures. Matches published version, minor changes only

Published

2023

23. Numerical relativity surrogate model with memory effects and post-Newtonian hybridization

Author

Yoo, Jooheon, Mitman, Keefe, Varma, Vijay, Boyle, Michael, Field, Scott E., Deppe, Nils, Hébert, François, Kidder, Lawrence E., Moxon, Jordan, Pfeiffer, Harald P., Scheel, Mark A., Stein, Leo C., Teukolsky, Saul A., Throwe, William, and Vu, Nils L.

Subjects

General Relativity and Quantum Cosmology

Abstract

Numerical relativity simulations provide the most precise templates for the gravitational waves produced by binary black hole mergers. However, many of these simulations use an incomplete waveform extraction technique -- extrapolation -- that fails to capture important physics, such as gravitational memory effects. Cauchy-characteristic evolution (CCE), by contrast, is a much more physically accurate extraction procedure that fully evolves Einstein's equations to future null infinity and accurately captures the expected physics. In this work, we present a new surrogate model, NRHybSur3dq8$\_$CCE, built from CCE waveforms that have been mapped to the post-Newtonian (PN) BMS frame and then hybridized with PN and effective one-body (EOB) waveforms. This model is trained on 102 waveforms with mass ratios $q\leq8$ and aligned spins $\chi_{1z}, \, \chi_{2z} \in \left[-0.8, 0.8\right]$. The model spans the entire LIGO-Virgo-KAGRA (LVK) frequency band (with $f_{\text{low}}=20\text{Hz}$) for total masses $M\gtrsim2.25M_{\odot}$ and includes the $\ell\leq4$ and $(\ell,m)=(5,5)$ spin-weight $-2$ spherical harmonic modes, but not the $(3,1)$, $(4,2)$ or $(4,1)$ modes. We find that NRHybSur3dq8$\_$CCE can accurately reproduce the training waveforms with mismatches $\lesssim2\times10^{-4}$ for total masses $2.25M_{\odot}\leq M\leq300M_{\odot}$ and can, for a modest degree of extrapolation, capably model outside of its training region. Most importantly, unlike previous waveform models, the new surrogate model successfully captures memory effects., Comment: 14 pages, 11 figures. Accepted for publication in PRD

Published

2023

24. Worldtube excision method for intermediate-mass-ratio inspirals: scalar-field model in 3+1 dimensions

Author

Wittek, Nikolas A., Dhesi, Mekhi, Barack, Leor, Pfeiffer, Harald P., Pound, Adam, Rüter, Hannes R., Bonilla, Marceline S., Deppe, Nils, Kidder, Lawrence E., Kumar, Prayush, Scheel, Mark A., Throwe, William, and Vu, Nils L.

Subjects

General Relativity and Quantum Cosmology

Abstract

Binary black hole simulations become increasingly more computationally expensive with smaller mass ratios, partly because of the longer evolution time, and partly because the lengthscale disparity dictates smaller time steps. The program initiated by Dhesi et al. (arXiv:2109.03531) explores a method for alleviating the scale disparity in simulations with mass ratios in the intermediate astrophysical range ($10^{-4} \lesssim q \lesssim 10^{-2}$), where purely perturbative methods may not be adequate. A region ("worldtube") much larger than the small black hole is excised from the numerical domain, and replaced with an analytical model approximating a tidally deformed black hole. Here we apply this idea to a toy model of a scalar charge in a fixed circular geodesic orbit around a Schwarzschild black hole, solving for the massless Klein-Gordon field. This is a first implementation of the worldtube excision method in full 3+1 dimensions. We demonstrate the accuracy and efficiency of the method, and discuss the steps towards applying it for evolving orbits and, ultimately, in the binary black-hole scenario. Our implementation is publicly accessible in the SpECTRE numerical relativity code., Comment: 19 pages, 10 figures; remove typo in Eq. (9c)

Published

2023

25. Laying the foundation of the effective-one-body waveform models SEOBNRv5: improved accuracy and efficiency for spinning non-precessing binary black holes

Author

Pompili, Lorenzo, Buonanno, Alessandra, Estellés, Héctor, Khalil, Mohammed, van de Meent, Maarten, Mihaylov, Deyan P., Ossokine, Serguei, Pürrer, Michael, Ramos-Buades, Antoni, Mehta, Ajit Kumar, Cotesta, Roberto, Marsat, Sylvain, Boyle, Michael, Kidder, Lawrence E., Pfeiffer, Harald P., Scheel, Mark A., Rüter, Hannes R., Vu, Nils, Dudi, Reetika, Ma, Sizheng, Mitman, Keefe, Melchor, Denyz, Thomas, Sierra, and Sanchez, Jennifer

Subjects

General Relativity and Quantum Cosmology

Abstract

We present SEOBNRv5HM, a more accurate and faster inspiral-merger-ringdown gravitational waveform model for quasi-circular, spinning, nonprecessing binary black holes within the effective-one-body (EOB) formalism. Compared to its predecessor, SEOBNRv4HM, the waveform model i) incorporates recent high-order post- Newtonian results in the inspiral, with improved resummations, ii) includes the gravitational modes (l, |m|) = (3, 2), (4, 3), in addition to the (2, 2), (3, 3), (2, 1), (4, 4), (5, 5) modes already implemented in SEOBNRv4HM, iii) is calibrated to larger mass-ratios and spins using a catalog of 442 numerical-relativity (NR) simulations and 13 additional waveforms from black-hole perturbation theory, iv) incorporates information from second-order gravitational self-force (2GSF) in the nonspinning modes and radiation-reaction force. Computing the unfaithfulness against NR simulations, we find that for the dominant (2, 2) mode the maximum unfaithfulness in the total mass range $10-300 M_{\odot}$ is below $10^{-3}$ for 90% of the cases (38% for SEOBNRv4HM). When including all modes up to l = 5 we find 98% (49%) of the cases with unfaithfulness below $10^{-2} (10^{-3})$, while these numbers reduce to 88% (5%) when using SEOBNRv4HM. Furthermore, the model shows improved agreement with NR in other dynamical quantities (e.g., the angular momentum flux and binding energy), providing a powerful check of its physical robustness. We implemented the waveform model in a high-performance Python package (pySEOBNR), which leads to evaluation times faster than SEOBNRv4HM by a factor 10 to 50, depending on the configuration, and provides the flexibility to easily include spin-precession and eccentric effects, thus making it the starting point for a new generation of EOBNR waveform models (SEOBNRv5) to be employed for upcoming observing runs of the LIGO-Virgo-KAGRA detectors.

Published

2023

26. Nonlinearities in Black Hole Ringdowns

Author

Mitman, Keefe, Lagos, Macarena, Stein, Leo C., Ma, Sizheng, Hui, Lam, Chen, Yanbei, Deppe, Nils, Hébert, François, Kidder, Lawrence E., Moxon, Jordan, Scheel, Mark A., Teukolsky, Saul A., Throwe, William, and Vu, Nils L.

Subjects

General Relativity and Quantum Cosmology, Astrophysics - High Energy Astrophysical Phenomena, High Energy Physics - Theory

Abstract

The gravitational wave strain emitted by a perturbed black hole (BH) ringing down is typically modeled analytically using first-order BH perturbation theory. In this Letter we show that second-order effects are necessary for modeling ringdowns from BH merger simulations. Focusing on the strain's $(\ell,m)=(4,4)$ angular harmonic, we show the presence of a quadratic effect across a range of binary BH mass ratios that agrees with theoretical expectations. We find that the quadratic $(4,4)$ mode's amplitude exhibits quadratic scaling with the fundamental $(2,2)$ mode -- its parent mode. The nonlinear mode's amplitude is comparable to or even larger than that of the linear $(4,4)$ mode. Therefore, correctly modeling the ringdown of higher harmonics -- improving mode mismatches by up to 2 orders of magnitude -- requires the inclusion of nonlinear effects., Comment: 6+2 pages, 4 figures, 1 table. Matches PRL version

Published

2022

27. Fixing the BMS frame of numerical relativity waveforms with BMS charges

Author

Mitman, Keefe, Stein, Leo C., Boyle, Michael, Deppe, Nils, Hébert, François, Kidder, Lawrence E., Moxon, Jordan, Scheel, Mark A., Teukolsky, Saul A., Throwe, William, and Vu, Nils L.

Subjects

General Relativity and Quantum Cosmology, High Energy Physics - Theory

Abstract

The Bondi-van der Burg-Metzner-Sachs (BMS) group, which uniquely describes the symmetries of asymptotic infinity and therefore of the gravitational waves that propagate there, has become increasingly important for accurate modeling of waveforms. In particular, waveform models, such as post-Newtonian (PN) expressions, numerical relativity (NR), and black hole perturbation theory, produce results that are in different BMS frames. Consequently, to build a model for the waveforms produced during the merging of compact objects, which ideally would be a hybridization of PN, NR, and black hole perturbation theory, one needs a fast and robust method for fixing the BMS freedoms. In this work, we present the first means of fixing the entire BMS freedom of NR waveforms to match the frame of either PN waveforms or black hole perturbation theory. We achieve this by finding the BMS transformations that change certain charges in a prescribed way -- e.g., finding the center-of-mass transformation that maps the center-of-mass charge to a mean of zero. We find that this new method is 20 times faster, and more correct when mapping to the superrest frame, than previous methods that relied on optimization algorithms. Furthermore, in the course of developing this charge-based frame fixing method, we compute the PN expression for the Moreschi supermomentum to 3PN order without spins and 2PN order with spins. This Moreschi supermomentum is effectively equivalent to the energy flux or the null memory contribution at future null infinity $\mathscr{I}^{+}$. From this PN calculation, we also compute oscillatory ($m\not=0$ modes) and spin-dependent memory terms that have not been identified previously or have been missing from strain expressions in the post-Newtonian literature., Comment: 16+4 pages with 2 appendices, 4 figures, 1 table

Published

2022

28. Quasinormal-mode filters: a new approach to analyze the gravitational-wave ringdown of binary black-hole mergers

Author

Ma, Sizheng, Mitman, Keefe, Sun, Ling, Deppe, Nils, Hébert, François, Kidder, Lawrence E., Moxon, Jordan, Throwe, William, Vu, Nils L., and Chen, Yanbei

Subjects

General Relativity and Quantum Cosmology

Abstract

We propose two frequency-domain filters to analyze ringdown signals of binary black hole mergers. The first rational filter is constructed based on a set of (arbitrary) quasi-normal modes (QNMs) of the remnant black holes, whereas the second full filter comes from the transmissivity of the remnant black holes. The two filters can remove corresponding QNMs from original time-domain ringdowns, while changing early inspiral signals in a trivial way - merely a time and phase shift. After filtering out dominant QNMs, we can visualize the existence of various subdominant effects. For example, by applying our filters to a GW150914-like numerical relativity (NR) waveform, we find second-order effects in the (l = 4, m = 4), (l = 5, m = 4) and (l = 5, m = 5) harmonics; the spherical-spheroidal mixing mode in the (l = 2,m = 2) harmonic; and a mixing mode in the (l = 2,m = 1) harmonic due to a gravitational recoil. In another NR simulation where two component spins are anti-aligned with the orbital angular momentum, we also find retrograde modes. The filters are sensitive to the remnant properties (i.e., mass and spin) and thus have a potential application to future data analyses and parameter estimations. We also investigate the stability of the full filter. Its connection to the instability of QNM spectra is discussed.

Published

2022

29. Gravitational-wave echoes from numerical-relativity waveforms via space-time construction near merging compact objects

Author

Ma, Sizheng, Wang, Qingwen, Deppe, Nils, Hébert, François, Kidder, Lawrence E., Moxon, Jordan, Throwe, William, Vu, Nils L., Scheel, Mark A., and Chen, Yanbei

Subjects

General Relativity and Quantum Cosmology

Abstract

We propose a new approach toward reconstructing the late-time near-horizon geometry of merging binary black holes, and toward computing gravitational-wave echoes from exotic compact objects. A binary black-hole merger spacetime can be divided by a time-like hypersurface into a Black-Hole Perturbation (BHP) region, in which the space-time geometry can be approximated by homogeneous linear perturbations of the final Kerr black hole, and a nonlinear region. At late times, the boundary between the two regions is an infalling shell. The BHP region contains late-time gravitational-waves emitted toward the future horizon, as well as those emitted toward future null infinity. In this region, by imposing no-ingoing wave conditions at past null infinity, and matching out-going waves at future null infinity with waveforms computed from numerical relativity, we can obtain waves that travel toward the future horizon. In particular, the Newman-Penrose $\psi_0$ associated with the in-going wave on the horizon is related to tidal deformations measured by fiducial observers floating above the horizon. We further determine the boundary of the BHP region on the future horizon by imposing that $\psi_0$ inside the BHP region can be faithfully represented by quasi-normal modes. Using a physically-motivated way to impose boundary conditions near the horizon, and applying the so-called Boltzmann reflectivity, we compute the quasi-normal modes of non-rotating ECOs, as well as gravitational-wave echoes. We also investigate the detectability of these echoes in current and future detectors, and prospects for parameter estimation.

Published

2022

30. High-accuracy numerical models of Brownian thermal noise in thin mirror coatings

Author

Vu, Nils L., Rodriguez, Samuel, Włodarczyk, Tom, Lovelace, Geoffrey, Pfeiffer, Harald P., Bonilla, Gabriel S., Deppe, Nils, Hébert, François, Kidder, Lawrence E., Moxon, Jordan, and Throwe, William

Subjects

Astrophysics - Instrumentation and Methods for Astrophysics, General Relativity and Quantum Cosmology, Physics - Computational Physics, Physics - Instrumentation and Detectors

Abstract

Brownian coating thermal noise in detector test masses is limiting the sensitivity of current gravitational-wave detectors on Earth. Therefore, accurate numerical models can inform the ongoing effort to minimize Brownian coating thermal noise in current and future gravitational-wave detectors. Such numerical models typically require significant computational resources and time, and often involve closed-source commercial codes. In contrast, open-source codes give complete visibility and control of the simulated physics, enable direct assessment of the numerical accuracy, and support the reproducibility of results. In this article, we use the open-source SpECTRE numerical relativity code and adopt a novel discontinuous Galerkin numerical method to model Brownian coating thermal noise. We demonstrate that SpECTRE achieves significantly higher accuracy than a previous approach at a fraction of the computational cost. Furthermore, we numerically model Brownian coating thermal noise in multiple sub-wavelength crystalline coating layers for the first time. Our new numerical method has the potential to enable fast exploration of realistic mirror configurations, and hence to guide the search for optimal mirror geometries, beam shapes and coating materials for gravitational-wave detectors., Comment: 15 pages, 5 figures. Results are reproducible with the ancillary input files

Published

2021

31. A scalable elliptic solver with task-based parallelism for the SpECTRE numerical relativity code

Author

Vu, Nils L., Pfeiffer, Harald P., Bonilla, Gabriel S., Deppe, Nils, Hébert, François, Kidder, Lawrence E., Lovelace, Geoffrey, Moxon, Jordan, Scheel, Mark A., Teukolsky, Saul A., Throwe, William, Wittek, Nikolas A., and Włodarczyk, Tom

Subjects

General Relativity and Quantum Cosmology, Physics - Computational Physics

Abstract

Elliptic partial differential equations must be solved numerically for many problems in numerical relativity, such as initial data for every simulation of merging black holes and neutron stars. Existing elliptic solvers can take multiple days to solve these problems at high resolution and when matter is involved, because they are either hard to parallelize or require a large amount of computational resources. Here we present a new solver for linear and nonlinear elliptic problems that is designed to scale with resolution and to parallelize on computing clusters. To achieve this we employ a discontinuous Galerkin discretization, an iterative multigrid-Schwarz preconditioned Newton-Krylov algorithm, and a task-based parallelism paradigm. To accelerate convergence of the elliptic solver we have developed novel subdomain-preconditioning techniques. We find that our multigrid-Schwarz preconditioned elliptic solves achieve iteration counts that are independent of resolution, and our task-based parallel programs scale over 200 million degrees of freedom to at least a few thousand cores. Our new code solves a classic initial data problem for binary black holes faster than the spectral code SpEC when distributed to only eight cores, and in a fraction of the time on more cores. It is publicly accessible in the next-generation SpECTRE numerical relativity code. Our results pave the way for highly parallel elliptic solves in numerical relativity and beyond., Comment: 25 pages, 20 figures, published version. Results are reproducible with the ancillary input files

Published

2021

32. High Precision Ringdown Modeling: Multimode Fits and BMS Frames

Author

Zertuche, Lorena Magaña, Mitman, Keefe, Khera, Neev, Stein, Leo C., Boyle, Michael, Deppe, Nils, Hébert, François, Iozzo, Dante A. B., Kidder, Lawrence E., Moxon, Jordan, Pfeiffer, Harald P., Scheel, Mark A., Teukolsky, Saul A., Throwe, William, and Vu, Nils

Subjects

General Relativity and Quantum Cosmology, Astrophysics - High Energy Astrophysical Phenomena, High Energy Physics - Theory

Abstract

Quasi-normal mode (QNM) modeling is an invaluable tool for characterizing remnant black holes, studying strong gravity, and testing GR. Only recently have QNM studies begun to focus on multimode fitting to numerical relativity (NR) strain waveforms. As GW observatories become even more sensitive they will be able to resolve higher-order modes. Consequently, multimode QNM fits will be critically important, and in turn require a more thorough treatment of the asymptotic frame at $\mathscr{I}^+$. The first main result of this work is a method for systematically fitting a QNM model containing many modes to a numerical waveform produced using Cauchy-characteristic extraction (CCE), an extraction technique which is known to resolve memory effects. We choose the modes to model based on their power contribution to the residual between numerical and model waveforms. We show that the all-mode strain mismatch improves by a factor of $\sim10^5$ when using multimode fitting as opposed to only fitting the $(2,\pm2,n)$ modes. Our most significant result addresses a critical point that has been overlooked in the QNM literature: the importance of matching the Bondi-van der Burg-Metzner-Sachs (BMS) frame of the numerical waveform to that of the QNM model. We show that by mapping the numerical waveforms$-$which exhibit the memory effect$-$to a BMS frame known as the super rest frame, there is an improvement of $\sim10^5$ in the all-mode strain mismatch compared to using a strain waveform whose BMS frame is not fixed. Furthermore, we find that by mapping CCE waveforms to the super rest frame, we can obtain all-mode mismatches that are, on average, a factor of $\sim4$ better than using the publicly-available extrapolated waveforms. We illustrate the effectiveness of these modeling enhancements by applying them to families of waveforms produced by NR and comparing our results to previous QNM studies., Comment: 17 + 2 pages, 11 figures, 2 tables

Published

2021

33. Simulating magnetized neutron stars with discontinuous Galerkin methods

Author

Deppe, Nils, Hébert, François, Kidder, Lawrence E., Throwe, William, Anantpurkar, Isha, Armaza, Cristóbal, Bonilla, Gabriel S., Boyle, Michael, Chaudhary, Himanshu, Duez, Matthew D., Vu, Nils L., Foucart, Francois, Giesler, Matthew, Guo, Jason S., Kim, Yoonsoo, Kumar, Prayush, Legred, Isaac, Li, Dongjun, Lovelace, Geoffrey, Ma, Sizheng, Macedo, Alexandra, Melchor, Denyz, Morales, Marlo, Moxon, Jordan, Nelli, Kyle C., O'Shea, Eamonn, Pfeiffer, Harald P., Ramirez, Teresita, Rüter, Hannes R., Sanchez, Jennifer, Scheel, Mark A., Thomas, Sierra, Vieira, Daniel, Wittek, Nikolas A., Wlodarczyk, Tom, and Teukolsky, Saul A.

Subjects

General Relativity and Quantum Cosmology, Astrophysics - High Energy Astrophysical Phenomena

Abstract

Discontinuous Galerkin methods are popular because they can achieve high order where the solution is smooth, because they can capture shocks while needing only nearest-neighbor communication, and because they are relatively easy to formulate on complex meshes. We perform a detailed comparison of various limiting strategies presented in the literature applied to the equations of general relativistic magnetohydrodynamics. We compare the standard minmod/$\Lambda\Pi^N$ limiter, the hierarchical limiter of Krivodonova, the simple WENO limiter, the HWENO limiter, and a discontinuous Galerkin-finite-difference hybrid method. The ultimate goal is to understand what limiting strategies are able to robustly simulate magnetized TOV stars without any fine-tuning of parameters. Among the limiters explored here, the only limiting strategy we can endorse is a discontinuous Galerkin-finite-difference hybrid method., Comment: matches published version. 21 pages, 12 figures. Added KH instability, TOV runs with classical limiters. arXiv admin note: text overlap with arXiv:2109.11645

Published

2021

34. Fully relativistic three-dimensional Cauchy-characteristic matching for physical degrees of freedom

Author

Ma, Sizheng, primary, Moxon, Jordan, additional, Scheel, Mark A., additional, Nelli, Kyle C., additional, Deppe, Nils, additional, Bonilla, Marceline S., additional, Kidder, Lawrence E., additional, Kumar, Prayush, additional, Lovelace, Geoffrey, additional, Throwe, William, additional, and Vu, Nils L., additional

Published

2024

35. Toward a self-consistent framework for measuring black hole ringdowns

Author

Clarke, Teagan A., primary, Isi, Maximiliano, additional, Lasky, Paul D., additional, Thrane, Eric, additional, Boyle, Michael, additional, Deppe, Nils, additional, Kidder, Lawrence E., additional, Mitman, Keefe, additional, Moxon, Jordan, additional, Nelli, Kyle C., additional, Throwe, William, additional, and Vu, Nils L., additional

Published

2024

36. A discontinuous Galerkin scheme for elliptic equations on extremely stretched grids

Author

Vu, Nils L. and Vu, Nils L.

Abstract

Discontinuous Galerkin (DG) methods for solving elliptic equations are gaining popularity in the computational physics community for their high-order spectral convergence and their potential for parallelization on computing clusters. However, problems in numerical relativity with extremely stretched grids, such as initial data problems for binary black holes that impose boundary conditions at large distances from the black holes, have proven challenging for DG methods. To alleviate this problem we have developed a primal DG scheme that is generically applicable to a large class of elliptic equations, including problems on curved and extremely stretched grids. The DG scheme accommodates two widely used initial data formulations in numerical relativity, namely the puncture formulation and the extended conformal thin-sandwich (XCTS) formulation. We find that our DG scheme is able to stretch the grid by a factor of $\sim 10^9$ and hence allows to impose boundary conditions at large distances. The scheme converges exponentially with resolution both for the smooth XCTS problem and for the non-smooth puncture problem. With this method we are able to generate high-quality initial data for binary black hole problems using a parallelizable DG scheme. The code is publicly available in the open-source SpECTRE numerical relativity code., Comment: 12 pages, 10 figures. Results are reproducible with the ancillary input files

Published

2024

37. A positivity-preserving adaptive-order finite-difference scheme for GRMHD

Author

Deppe, Nils, primary, Kidder, Lawrence E, additional, Teukolsky, Saul A, additional, Bonilla, Marceline S, additional, Hébert, François, additional, Kim, Yoonsoo, additional, Scheel, Mark A, additional, Throwe, William, additional, and Vu, Nils L, additional

Published

2023

38. Extending black-hole remnant surrogate models to extreme mass ratios

Author

Boschini, Matteo, primary, Gerosa, Davide, additional, Varma, Vijay, additional, Armaza, Cristóbal, additional, Boyle, Michael, additional, Bonilla, Marceline S., additional, Ceja, Andrea, additional, Chen, Yitian, additional, Deppe, Nils, additional, Giesler, Matthew, additional, Kidder, Lawrence E., additional, Kumar, Prayush, additional, Lara, Guillermo, additional, Long, Oliver, additional, Ma, Sizheng, additional, Mitman, Keefe, additional, Nee, Peter James, additional, Pfeiffer, Harald P., additional, Ramos-Buades, Antoni, additional, Scheel, Mark A., additional, Vu, Nils L., additional, and Yoo, Jooheon, additional

Published

2023

39. Numerical relativity surrogate model with memory effects and post-Newtonian hybridization

Author

Yoo, Jooheon, primary, Mitman, Keefe, additional, Varma, Vijay, additional, Boyle, Michael, additional, Field, Scott E., additional, Deppe, Nils, additional, Hébert, François, additional, Kidder, Lawrence E., additional, Moxon, Jordan, additional, Pfeiffer, Harald P., additional, Scheel, Mark A., additional, Stein, Leo C., additional, Teukolsky, Saul A., additional, Throwe, William, additional, and Vu, Nils L., additional

Published

2023

40. Worldtube excision method for intermediate-mass-ratio inspirals: Scalar-field model in 3+1 dimensions

Author

Wittek, Nikolas A., primary, Dhesi, Mekhi, additional, Barack, Leor, additional, Pfeiffer, Harald P., additional, Pound, Adam, additional, Rüter, Hannes R., additional, Bonilla, Marceline S., additional, Deppe, Nils, additional, Kidder, Lawrence E., additional, Kumar, Prayush, additional, Scheel, Mark A., additional, Throwe, William, additional, and Vu, Nils L., additional

Published

2023

41. Laying the foundation of the effective-one-body waveform models SEOBNRv5:Improved accuracy and efficiency for spinning nonprecessing binary black holes

Author

Pompili, Lorenzo, Buonanno, Alessandra, Estellés, Héctor, Khalil, Mohammed, Van De Meent, Maarten, Mihaylov, Deyan P., Ossokine, Serguei, Pürrer, Michael, Ramos-buades, Antoni, Mehta, Ajit Kumar, Cotesta, Roberto, Marsat, Sylvain, Boyle, Michael, Kidder, Lawrence E., Pfeiffer, Harald P., Scheel, Mark A., Rüter, Hannes R., Vu, Nils, Dudi, Reetika, Ma, Sizheng, Mitman, Keefe, Melchor, Denyz, Thomas, Sierra, Sanchez, Jennifer, Pompili, Lorenzo, Buonanno, Alessandra, Estellés, Héctor, Khalil, Mohammed, Van De Meent, Maarten, Mihaylov, Deyan P., Ossokine, Serguei, Pürrer, Michael, Ramos-buades, Antoni, Mehta, Ajit Kumar, Cotesta, Roberto, Marsat, Sylvain, Boyle, Michael, Kidder, Lawrence E., Pfeiffer, Harald P., Scheel, Mark A., Rüter, Hannes R., Vu, Nils, Dudi, Reetika, Ma, Sizheng, Mitman, Keefe, Melchor, Denyz, Thomas, Sierra, and Sanchez, Jennifer

Published

2023

42. SpECTRE Cauchy-characteristic evolution system for rapid, precise waveform extraction

Author

Moxon, Jordan, primary, Scheel, Mark A., additional, Teukolsky, Saul A., additional, Deppe, Nils, additional, Vu, Nils, additional, Hébert, Francois, additional, Kidder, Lawrence E., additional, and Throwe, William, additional

Published

2023

43. Nonlinearities in Black Hole Ringdowns

Author

Mitman, Keefe, primary, Lagos, Macarena, additional, Stein, Leo C., additional, Ma, Sizheng, additional, Hui, Lam, additional, Chen, Yanbei, additional, Deppe, Nils, additional, Hébert, François, additional, Kidder, Lawrence E., additional, Moxon, Jordan, additional, Scheel, Mark A., additional, Teukolsky, Saul A., additional, Throwe, William, additional, and Vu, Nils L., additional

Published

2023

44. High-accuracy numerical models of Brownian thermal noise in thin mirror coatings

Author

Vu, Nils L, primary, Rodriguez, Samuel, additional, Włodarczyk, Tom, additional, Lovelace, Geoffrey, additional, P Pfeiffer, Harald, additional, S Bonilla, Gabriel, additional, Deppe, Nils, additional, Hébert, François, additional, E Kidder, Lawrence, additional, Moxon, Jordan, additional, and Throwe, William, additional

Published

2023

45. Quasinormal-mode filters: A new approach to analyze the gravitational-wave ringdown of binary black-hole mergers

Author

Ma, Sizheng, primary, Mitman, Keefe, additional, Sun, Ling, additional, Deppe, Nils, additional, Hébert, François, additional, Kidder, Lawrence E., additional, Moxon, Jordan, additional, Throwe, William, additional, Vu, Nils L., additional, and Chen, Yanbei, additional

Published

2022

46. Fixing the BMS frame of numerical relativity waveforms with BMS charges

Author

Mitman, Keefe, primary, Stein, Leo C., additional, Boyle, Michael, additional, Deppe, Nils, additional, Hébert, François, additional, Kidder, Lawrence E., additional, Moxon, Jordan, additional, Scheel, Mark A., additional, Teukolsky, Saul A., additional, Throwe, William, additional, and Vu, Nils L., additional

Published

2022

47. Simulating magnetized neutron stars with discontinuous Galerkin methods

Author

Deppe, Nils, Hebert, Francois, Kidder, Lawrence E., Throwe, William, Anantpurkar, Isha, Armaza, Cristobal, Bonilla, Gabriel S., Boyle, Michael, Chaudhary, Himanshu, Duez, Matthew D., Vu, Nils L., Foucart, Francois, Giesler, Matthew, Guo, Jason S., Kim, Yoonsoo, Kumar, Prayush, Legred, Isaac, Li, Dongjun, Lovelace, Geoffrey, Ma, Sizheng, Macedo, Alexandra, Melchor, Denyz, Morales, Marlo, Moxon, Jordan, Nelli, Kyle C., O'Shea, Eamonn, Pfeiffer, Harald P., Ramirez, Teresita, Ruter, Hannes R., Sanchez, Jennifer, Scheel, Mark A., Thomas, Sierra, Vieira, Daniel, Wittek, Nikolas A., Wlodarczyk, Tom, Teukolsky, Saul A., Deppe, Nils, Hebert, Francois, Kidder, Lawrence E., Throwe, William, Anantpurkar, Isha, Armaza, Cristobal, Bonilla, Gabriel S., Boyle, Michael, Chaudhary, Himanshu, Duez, Matthew D., Vu, Nils L., Foucart, Francois, Giesler, Matthew, Guo, Jason S., Kim, Yoonsoo, Kumar, Prayush, Legred, Isaac, Li, Dongjun, Lovelace, Geoffrey, Ma, Sizheng, Macedo, Alexandra, Melchor, Denyz, Morales, Marlo, Moxon, Jordan, Nelli, Kyle C., O'Shea, Eamonn, Pfeiffer, Harald P., Ramirez, Teresita, Ruter, Hannes R., Sanchez, Jennifer, Scheel, Mark A., Thomas, Sierra, Vieira, Daniel, Wittek, Nikolas A., Wlodarczyk, Tom, and Teukolsky, Saul A.

Abstract

Discontinuous Galerkin methods are popular because they can achieve high order where the solution is smooth, because they can capture shocks while needing only nearest-neighbor communication, and because they are relatively easy to formulate on complex meshes. We perform a detailed comparison of various limiting strategies presented in the literature applied to the equations of general relativistic magnetohydrodynamics. We compare the standard minmod/Lambda Pi(N) limiter, the hierarchical limiter of Krivodonova, the simple WENO limiter, the HWENO limiter, and a discontinuous Galerkin-finite-difference hybrid method. The ultimate goal is to understand what limiting strategies are able to robustly simulate magnetized Tolman-Oppenheimer-Volkoff stars without any fine-tuning of parameters. Among the limiters explored here, the only limiting strategy we can endorse is a discontinuous Galerkin-finitedifference hybrid method.

Published

2022

48. Simulating magnetized neutron stars with discontinuous Galerkin methods

Author

Deppe, Nils, primary, Hébert, François, additional, Kidder, Lawrence E., additional, Throwe, William, additional, Anantpurkar, Isha, additional, Armaza, Cristóbal, additional, Bonilla, Gabriel S., additional, Boyle, Michael, additional, Chaudhary, Himanshu, additional, Duez, Matthew D., additional, Vu, Nils L., additional, Foucart, Francois, additional, Giesler, Matthew, additional, Guo, Jason S., additional, Kim, Yoonsoo, additional, Kumar, Prayush, additional, Legred, Isaac, additional, Li, Dongjun, additional, Lovelace, Geoffrey, additional, Ma, Sizheng, additional, Macedo, Alexandra, additional, Melchor, Denyz, additional, Morales, Marlo, additional, Moxon, Jordan, additional, Nelli, Kyle C., additional, O’Shea, Eamonn, additional, Pfeiffer, Harald P., additional, Ramirez, Teresita, additional, Rüter, Hannes R., additional, Sanchez, Jennifer, additional, Scheel, Mark A., additional, Thomas, Sierra, additional, Vieira, Daniel, additional, Wittek, Nikolas A., additional, Wlodarczyk, Tom, additional, and Teukolsky, Saul A., additional

Published

2022

49. High precision ringdown modeling: Multimode fits and BMS frames

Author

Magaña Zertuche, Lorena, primary, Mitman, Keefe, additional, Khera, Neev, additional, Stein, Leo C., additional, Boyle, Michael, additional, Deppe, Nils, additional, Hébert, François, additional, Iozzo, Dante A. B., additional, Kidder, Lawrence E., additional, Moxon, Jordan, additional, Pfeiffer, Harald P., additional, Scheel, Mark A., additional, Teukolsky, Saul A., additional, Throwe, William, additional, and Vu, Nils, additional

Published

2022

50. Gravitational-wave echoes from numerical-relativity waveforms via spacetime construction near merging compact objects

Author

Ma, Sizheng, primary, Wang, Qingwen, additional, Deppe, Nils, additional, Hébert, François, additional, Kidder, Lawrence E., additional, Moxon, Jordan, additional, Throwe, William, additional, Vu, Nils L., additional, Scheel, Mark A., additional, and Chen, Yanbei, additional

Published

2022