Sky localization of complete inspiral-merger-ringdown signals for nonspinning massive black hole binaries

McWilliams, S. T.; Lang, R. N.; Baker, John G.; Thorpe, James

doi:10.1103/physrevd.84.064003

Cited by 24 publications

(22 citation statements)

References 49 publications

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“…While acknowledging that there is currently considerable uncertainty about when and how the first space-based GW instrument will be developed, we choose to study the classic LISA configuration to make contact with the large body of work that has already been dedicated to black-hole merger parameter estimation (e.g., see Refs. [31,32,[80][81][82]). To compare with other concepts, the most relevant alteration from the classic LISA design is the arm length (e.g., from 5 Gm for classic LISA down to 1 Gm for eLISA), which sets the overall scale for parameter-estimation capabilities; our results for a more modest detector configuration would be very similar to those for classic LISA, after appropriately rescaling the total mass of the black-hole system.…”

Section: Results For Space-based Detectorsmentioning

confidence: 99%

“…These waveforms have already been used to search for GWs from highmass [27,28] and intermediate-mass [29] binary black holes in LIGO and Virgo data, and also to carry out preliminary parameter-estimation studies for ground-based detectors [30] and space-based detectors, such as classic LISA [31,32]. In this paper we shall study a set of inspiral-merger-ringdown waveforms based on the Effective-One-Body (EOB) framework [33][34][35][36][37].…”

Section: Introductionmentioning

confidence: 99%

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Systematic biases in parameter estimation of binary black-hole mergers

et al. 2013

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Parameter estimation of binary-black-hole merger events in gravitational-wave data relies on matched-filtering techniques, which, in turn, depend on accurate model waveforms. Here we characterize the systematic biases introduced in measuring astrophysical parameters of binary black holes by applying the currently most accurate effective-one-body templates to simulated data containing non-spinning numerical-relativity waveforms. For advanced ground-based detectors, we find that the systematic biases are well within the statistical error for realistic signal-to-noise ratio (SNR). These biases grow to be comparable to the statistical errors at high ground-based-instrument SNRs (SNR ∼ 50), but never dominate the error budget. At the much larger signal-to-noise ratios expected for space-based detectors, these biases will become large compared to the statistical errors, but for astrophysical black hole mass estimates the absolute biases (of at most a few percent) are still fairly small.

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Section: Results For Space-based Detectorsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Systematic biases in parameter estimation of binary black-hole mergers

et al. 2013

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“…Later studies [322] considered the angular resolution of detectors in precessing-plane configurations like LISA's, as well as ecliptic-plane interferometers that lie flat in the ecliptic as they orbit the sun. More recent studies have considered more complete MBH-binary waveforms with spin effects, higher harmonics, and with merger and ringdown signals, and have looked at the effect of these corrections on LISA's parameter-estimation ability [455,29,442,365,33,266,307]. These papers indicate that observations with a LISA-like detector will be able to determine the masses of the two binary components to 0.01 -0.1%, the spins to 0.001 -0.1%, the sky position of the binary to 1 -10 deg 2 , and the luminosity distance to 0.1 -10%.…”

Section: Massive Black-hole Coalescencesmentioning

confidence: 99%

Testing General Relativity with Low-Frequency, Space-Based Gravitational-Wave Detectors

Gair¹,

Vallisneri

Larson

et al. 2013

Living Rev. Relativ.

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296

310

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We review the tests of general relativity that will become possible with space-based gravitational-wave detectors operating in the ∼ 10−5 − 1 Hz low-frequency band. The fundamental aspects of gravitation that can be tested include the presence of additional gravitational fields other than the metric; the number and tensorial nature of gravitational-wave polarization states; the velocity of propagation of gravitational waves; the binding energy and gravitational-wave radiation of binaries, and therefore the time evolution of binary inspirals; the strength and shape of the waves emitted from binary mergers and ringdowns; the true nature of astrophysical black holes; and much more. The strength of this science alone calls for the swift implementation of a space-based detector; the remarkable richness of astrophysics, astronomy, and cosmology in the low-frequency gravitational-wave band make the case even stronger.

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“…Additionally, the EM chirp template should be useful in breaking parameter-degeneracies in the GW waveforms. As an example, the sky position is correlated with the orbital plane orientation; this degeneracy is broken by spin precession [49] and by higher harmonics [50], but only near the end of the inspiral, when these effects are large.…”

Section: Discussionmentioning

confidence: 99%

Electromagnetic chirp of a compact binary black hole: A phase template for the gravitational wave inspiral

Haiman

2017

Phys. Rev. D

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The gravitational waves (GWs) from a binary black hole (BBH) with masses 10 4 ∼ < M ∼ < 10 7 M can be detected with the Laser Interferometer Space Antenna (LISA) once their orbital frequency exceeds 10 −4 − 10 −5 Hz. The binary separation at this stage is a = O(100)Rg (gravitational radius), and the orbital speed is v/c = O(0.1). We argue that at this stage, the binary will be producing bright electromagnetic (EM) radiation via gas bound to the individual BHs. Both BHs will have their own photospheres in X-ray and possibly also in optical bands. Relativistic Doppler modulations and lensing effects will inevitably imprint periodic variability in the EM light-curve, tracking the phase of the orbital motion, and serving as a template for the GW inspiral waveform. Advanced localization of the source by LISA weeks to months prior to merger will enable a measurement of this EM chirp by wide-field X-ray or optical instruments. A comparison of the phases of the GW and EM chirp signals will help break degeneracies between system parameters, and probe a fractional difference difference ∆v in the propagation speed of photons and gravitons as low as ∆v/c ≈ 10 −17 .

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Sky localization of complete inspiral-merger-ringdown signals for nonspinning massive black hole binaries

Cited by 24 publications

References 49 publications

Systematic biases in parameter estimation of binary black-hole mergers

Systematic biases in parameter estimation of binary black-hole mergers

Testing General Relativity with Low-Frequency, Space-Based Gravitational-Wave Detectors

Electromagnetic chirp of a compact binary black hole: A phase template for the gravitational wave inspiral

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