Characterizing the continuous gravitational-wave signal from boson clouds around Galactic isolated black holes

Zhu, S. J.; Baryakhtar, Masha; Papa, M. A.; Tsuna, D.; Kawanaka, Norita; Eggenstein, H.-B.

doi:10.1103/physrevd.102.063020

Cited by 85 publications

(83 citation statements)

References 107 publications

(211 reference statements)

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“…as recently described in Ref. [71]), as our method to search for a SGWB (described in Sec. IV) is optimized for a Gaussian distributed signal.…”

Section: B Bh Population Modelsmentioning

confidence: 99%

“…We should also note that, for a given boson mass, the GW signals emitted by the galactic population would tend to accumulate in a very narrow frequency window around ω R [see Eq. (3)][71], unlike the extra-galactic component which should be spread over a broader range of frequencies due to the cosmological redshift. Our search method is better suited for signals that emit in a broad range of frequencies.…”

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confidence: 99%

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First search for a stochastic gravitational-wave background from ultralight bosons

et al. 2019

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Ultralight bosons with masses in the range 10 −13 eV ≤ m b ≤ 10 −12 eV can induce a superradiant instability around spinning black holes (BHs) with masses of order 10-100 M⊙. This instability leads to the formation of a rotating "bosonic cloud" around the BH, which can emit gravitational waves (GWs) in the frequency band probed by ground-based detectors. The superposition of GWs from all such systems can generate a stochastic gravitational-wave background (SGWB). In this work, we develop a Bayesian data analysis framework to study the SGWB from bosonic clouds using data from Advanced LIGO and Advanced Virgo, building on previous work by Brito et.al. [1]. We further improve this model by adding a BH population of binary merger remnants. To assess the performance of our pipeline, we quantify the range of boson masses that can be constrained by Advanced LIGO and Advanced Virgo measurements at design sensitivity. Furthermore, we explore our capability to distinguish an ultralight boson SGWB from a stochastic signal due to distant compact binary coalescences (CBC). Finally, we present results of a search for the SGWB from bosonic clouds using data from Advanced LIGO's first observing run. We find no evidence of such a signal. Due to degeneracies between the boson mass and unknown astrophysical quantities such as the distribution of isolated BH spins, our analysis cannot robustly exclude the presence of a bosonic field at any mass. Nevertheless, we show that under optimistic assumptions about the BH formation rate and spin distribution, boson masses in the range 2.0 × 10 −13 eV ≤ m b ≤ 3.8 × 10 −13 eV are excluded at 95% credibility, although with less optimistic spin distributions, no masses can be excluded. The framework established here can be used to learn about the nature of fundamental bosonic fields with future gravitational wave observations.

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“…as recently described in Ref. [71]), as our method to search for a SGWB (described in Sec. IV) is optimized for a Gaussian distributed signal.…”

Section: B Bh Population Modelsmentioning

confidence: 99%

mentioning

confidence: 99%

First search for a stochastic gravitational-wave background from ultralight bosons

et al. 2019

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“…These yet-to-be detected signals are orders of magnitude weaker than compact binary coalescenses [1], requiring long integration times (months to years) to differentiate them from noise. Potentially detectable sources using the current generation of ground-based interferometric detectors, Advanced LIGO [2] and Advanced Virgo [3], are neutron stars (NSs) presenting some nonaxisymmetry such as crustal deformations, r-mode instabilities or free precession [4], or the annihilation of ultralight boson clouds around spinning black holes [5].…”

Section: Introductionmentioning

confidence: 99%

Application of a hierarchical MCMC follow-up to Advanced LIGO continuous gravitational-wave candidates

2021

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We present the first application of a hierarchical Markov Chain Monte Carlo (MCMC) follow-up on continuous gravitational-wave candidates from real-data searches. The follow-up uses an MCMC sampler to draw parameter-space points from the posterior distribution, constructed using the matched-filter as a log-likelihood. As outliers are narrowed down, coherence time increases, imposing more restrictive phaseevolution templates. We introduce a novel Bayes factor to compare results from different stages: The signal hypothesis is derived from first principles, while the noise hypothesis uses extreme value theory to derive a background model. The effectiveness of our proposal is evaluated on fake Gaussian data and applied to a set of 30 outliers produced by different continuous wave searches on O2 Advanced LIGO data. The results of our analysis suggest all but five outliers are inconsistent with an astrophysical origin under the standard continuous wave signal model. We successfully ascribe four of the surviving outliers to instrumental artifacts and a strong hardware injection present in the data. The behavior of the fifth outlier suggests an instrumental origin as well, but we could not relate it to any known instrumental cause.

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“…The search for continuous gravitational-wave signals (CWs), long-duration forms of gravitational radiation, is one of the endeavours of gravitational-wave astronomy. These signals are produced by long-standing quadrupolar variations, such as rapidly spinning neutron star (NSs) sustaining a crustal deformation, undergoing an r-mode instability or in free precession [1][2][3][4], as well as more exotic sources such as the annihilation of ultra-light boson clouds around spinning black holes [5][6][7][8] or compact dark matter objects (CDOs) in the Solar System [9].…”

Section: Introductionmentioning

confidence: 99%

Search Methods for Continuous Gravitational-Wave Signals from Unknown Sources in the Advanced-Detector Era

2021

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Continuous gravitational waves are long-lasting forms of gravitational radiation produced by persistent quadrupolar variations of matter. Standard expected sources for ground-based interferometric detectors are neutron stars presenting non-axisymmetries such as crustal deformations, r-modes or free precession. More exotic sources could include decaying ultralight boson clouds around spinning black holes. A rich suite of data-analysis methods spanning a wide bracket of thresholds between sensitivity and computational efficiency has been developed during the last decades to search for these signals. In this work, we review the current state of searches for continuous gravitational waves using ground-based interferometer data, focusing on searches for unknown sources. These searches typically consist of a main stage followed by several post-processing steps to rule out outliers produced by detector noise. So far, no continuous gravitational wave signal has been confidently detected, although tighter upper limits are placed as detectors and search methods are further developed.

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Characterizing the continuous gravitational-wave signal from boson clouds around Galactic isolated black holes

Cited by 85 publications

References 107 publications

First search for a stochastic gravitational-wave background from ultralight bosons

First search for a stochastic gravitational-wave background from ultralight bosons

Application of a hierarchical MCMC follow-up to Advanced LIGO continuous gravitational-wave candidates

Search Methods for Continuous Gravitational-Wave Signals from Unknown Sources in the Advanced-Detector Era

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