Your search keyword '"BINARY black holes"' showing total 82 results

1. Galactic Stellar Black Hole Binaries: Spin Effects on Jet Emissions of High-Energy Gamma-Rays.

Author

Rarras, Dimitrios, Kosmas, Theocharis, Papavasileiou, Theodora, and Kosmas, Odysseas

Subjects

STELLAR black holes, BINARY black holes, KERR black holes, INVERSE Compton scattering, BLACK holes

Abstract

In the last few decades, galactic stellar black hole X-ray binary systems (BHXRBs) have aroused intense observational and theoretical research efforts specifically focusing on their multi-messenger emissions (radio waves, X-rays, γ -rays, neutrinos, etc.). In this work, we investigate jet emissions of high-energy neutrinos and gamma-rays created through several hadronic and leptonic processes taking place within the jets. We pay special attention to the effect of the black hole's spin (Kerr black holes) on the differential fluxes of photons originating from synchrotron emission and inverse Compton scattering and specifically on their absorption due to the accretion disk's black-body radiation. The black hole's spin (dimensionless spin parameter a * ) enters into the calculations through the radius of the innermost circular orbit around the black hole, the R I S C O parameter, assumed to be the inner radius of the accretion disk, which determines its optical depth τ d i s k . In our results, the differential photon fluxes after the absorption effect are depicted as a function of the photon energy in the range 1 GeV ≤ E ≤ 10 3 GeV. It is worth noting that when the black holes' spin ( α * ) increases, the differential photon flux becomes significantly lower. [ABSTRACT FROM AUTHOR]

Published

2024

2. Black Hole's Spin-Dependence of γ -Ray and Neutrino Emissions from MAXI J1820+070, XTE J1550-564, and XTE J1859+226.

Author

Rarras, Dimitrios, Kosmas, Odysseas, Papavasileiou, Theodora, and Kosmas, Theocharis

Subjects

STELLAR black holes, BINARY black holes, KERR black holes, BLACK holes, PAIR production, ACCRETION disks

Abstract

A black hole's spin effects on the jet emissions of high-energy neutrinos and γ -rays from black hole X-ray binary systems (BHXRBs) are investigated. The BHXRBs consist of a stellar black hole, a companion (donor) star, a BH accretion disk, a BH corona, and two jets emitted from the black hole perpendicular to the accretion disk. For their description, properties of the accretion disk, specifically the accretion disk's inner radius R i n and the accretion disk's temperature profile T (R) , play key roles since they depend on the black hole's dimensionless spin parameter α ∗ . In this work, we focus on the main reaction mechanisms taking place inside jets from which high-energy γ -rays and neutrinos are created. The intensities and integral fluxes of neutrinos and γ -rays are obtained by integrating the respective source functions. Lastly, the γ -ray absorption due to e − - e + pair production is considered, particularly absorption from the accretion disk. For concrete applications, we have chosen the BHXRB systems MAXI J1820+070, XTE J1550-564, and XTE J1859+226. [ABSTRACT FROM AUTHOR]

Published

2024

3. A Study of the Accretion–Jet Coupling of Black Hole Objects at Different Scales.

Author

Yang, Zhou, Long, Qing-Chen, Yang, Wei-Jia, and Dong, Ai-Jun

Subjects

*BLACK holes, *BINARY black holes, *BLACKBODY radiation, *ACTIVE galactic nuclei, *ENERGY bands

Abstract

The fundamental plane of black hole activity is a very important tool to study accretion and jets. However, we found that the SEDs of AGNs and XRBs are different in the 2–10 keV energy band, and it seems inappropriate to use 2–10 keV X-ray luminosities to study the fundamental plane. In this work, we use the luminosity near the peak of the blackbody radiation of the active galactic nuclei and black hole binaries to replace the 2–10 keV luminosity. We re-explore the fundamental plane of black hole activity by using the 2500 A ˚ luminosity as the peak luminosity of the blackbody radiation of AGNs and 1 keV luminosity as the peak luminosity of the blackbody radiation of XRBs. We compile samples of black hole binaries and active galactic nuclei with luminosity near the peak luminosity of blackbody radiation and study the fundamental plane between radio luminosity ( L R ), the peak luminosity of blackbody radiation ( L peak ), and black hole mass ( M BH ). We find that the radio–peak luminosity correlations are L 5 GHz / L Edd ∝ (L 2500 A ˚ / L Edd) 1.55 and L 5 GHz / L Edd ∝ (L 1 keV / L Edd) 1.53 for AGN and XRB, respectively, in the radiatively efficient sample, and L 5 GHz / L Edd ∝ (L 2500 A ˚ / L Edd) 0.48 and L 5 GHz / L Edd ∝ (L 1 keV / L Edd) 0.53 in the radiatively inefficient sample, respectively. Based on the similarities in radio–peak correlations, we further propose a fundamental plane in radio luminosity, the peak luminosity of blackbody radiation, and black hole mass, which is radiatively efficient: log L 5 GHz = 1. 57 − 0.01 + 0.01 log L peak − 0. 32 − 0.16 + 0.16 log M BH − 27. 73 − 0.34 + 0.34 with a scatter of σ R = 0.48 dex, and radiatively inefficient: log L 5 GHz = 0. 45 − 0.01 + 0.01 log L peak + 0. 91 − 0.10 + 0.12 log M BH + 12. 58 − 0.38 + 0.38 with a scatter of σ R = 0.63 dex. Our results are similar to those of previous studies on the fundamental plane for radiatively efficient and radiatively inefficient black hole activity. However, our results exhibit a smaller scatter, so when using the same part of blackbody radiation (i.e., the peak luminosity of the blackbody radiation), the fundamental plane becomes a little bit tighter. [ABSTRACT FROM AUTHOR]

Published

2024

4. Investigating the Performance of a Novel Modified Binary Black Hole Optimization Algorithm for Enhancing Feature Selection.

Author

Al-Eiadeh, Mohammad Ryiad, Qaddoura, Raneem, and Abdallah, Mustafa

Subjects

OPTIMIZATION algorithms, FEATURE selection, BINARY black holes, CLASSIFICATION algorithms, BLACK holes, TRANSFER functions

Abstract

High-dimensional datasets often harbor redundant, irrelevant, and noisy features that detrimentally impact classification algorithm performance. Feature selection (FS) aims to mitigate this issue by identifying and retaining only the most pertinent features, thus reducing dataset dimensions. In this study, we propose an FS approach based on black hole algorithms (BHOs) augmented with a mutation technique termed MBHO. BHO typically comprises two primary phases. During the exploration phase, a set of stars is iteratively modified based on existing solutions, with the best star selected as the "black hole". In the exploration phase, stars nearing the event horizon are replaced, preventing the algorithm from being trapped in local optima. To address the potential randomness-induced challenges, we introduce inversion mutation. Moreover, we enhance a widely used objective function for wrapper feature selection by integrating two new terms based on the correlation among selected features and between features and classification labels. Additionally, we employ a transfer function, the V2 transfer function, to convert continuous values into discrete ones, thereby enhancing the search process. Our approach undergoes rigorous evaluation experiments using fourteen benchmark datasets, and it is compared favorably against Binary Cuckoo Search (BCS), Mutual Information Maximization (MIM), Joint Mutual Information (JMI), and minimum Redundancy Maximum Eelevance (mRMR), approaches. The results demonstrate the efficacy of our proposed model in selecting superior features that enhance classifier performance metrics. Thus, MBHO is presented as a viable alternative to the existing state-of-the-art approaches. We make our implementation source code available for community use and further development. [ABSTRACT FROM AUTHOR]

Published

2024

5. The Pulsar Timing Array Signal from Infrared Regions of Scalar-Induced Gravitational Waves.

Author

Fei, Qin

Subjects

*BINARY black holes, *SUPERMASSIVE black holes, *PULSARS, *BAYESIAN analysis, *ENERGY density, *GRAVITATIONAL waves

Abstract

The common-spectrum process, characterized by the Hellings–Downs angular correlation and observed by pulsar timing array collaborations, such as NANOGrav, PPTA, EPTA, and CPTA, can be explained by the scalar-induced gravitational waves (SIGWs). The energy density of SIGWs exhibits universal behavior in the infrared regions. Utilizing a broken power law parameterization for the primordial curvature power spectrum, we clarify the PTA signal through the infrared characteristics of the SIGWs, using Bayesian analysis to provide posterior distributions. Bayesian factors emphasize the statistical preference for the SIGW model over explanations involving supermassive black hole binaries. [ABSTRACT FROM AUTHOR]

Published

2024

6. A Supermassive Binary Black Hole Candidate in Mrk 501.

Author

Magallanes-Guijón, Gustavo and Mendoza, Sergio

Subjects

SUPERMASSIVE black holes, DISCRETE Fourier transforms, BINARY black holes, BL Lacertae objects, GRAVITATIONAL waves, LIGHT curves, ECLIPSING binaries

Abstract

Using multifrequency observations, from radio to γ -rays of the blazar Mrk 501, we constructed their corresponding light curves and built periodograms using RobPer and Lomb–Scargle algorithms. Long-term variability was also studied using the power density spectrum and the detrended function analysis. Using the software VARTOOLS Version 1.40, we also computed the analysis of variance, box-least squares and discrete fourier transform. The result of these techniques showed an achromatic periodicity ≲ 229 d . This, combined with the result of pink-color noise in the spectra, led us to propose that the periodicity was produced via a secondary eclipsing supermassive binary black hole orbiting the primary one locked inside the central engine of Mrk 501. We built a relativistic eclipsing model of this phenomenon using Jacobi elliptical functions, finding a periodic relativistic eclipse occurring every ∼ 224 d in all the studied wavebands. This implies that the frequency of the emitted gravitational waves falls slightly above 0.1 mHz, well within the operational range of the upcoming LISA space-based interferometer, and as such, these gravitational waves must be considered as a prime science target for future LISA observations. [ABSTRACT FROM AUTHOR]

Published

2024

7. Measuring a Gravitomagnetic Effect with the Triple Pulsar PSR J0337+1715.

Author

Iorio, Lorenzo

Subjects

*PULSARS, *ANGULAR momentum (Mechanics), *BINARY pulsars, *GRAVITATIONAL potential, *MULTIPLE stars, *ORBITS (Astronomy), *BINARY black holes

Abstract

To the first post-Newtonian order, the orbital angular momentum of the fast-revolving inner binary of the triple system PSR J0337+1715, made of a millisecond pulsar and a white dwarf, induces an annular gravitomagnetic field which displaces the line of apsides of the slower orbit of the other, distant white dwarf by − 1.2 milliarcseconds per year. The current accuracy in determining the periastron of the outer orbit is 63.9 milliarcseconds after 1.38 years of data collection. By hypothesizing a constant rate of measurement of the pulsar's times of arrivals over the next 10 years, assumed equal to the present one, it can be argued that the periastron will be finally known to a ≃ 0.15 milliarcseconds level, while its cumulative gravitomagnetic retrograde shift will be as large as − 12 milliarcseconds. The competing post-Newtonian gravitolectric periastron advance due to the inner binary's masses, nominally amounting to 74.3 milliarcseconds per year, can be presently modelled to an accuracy level as good as ≃ 0.04 milliarcseconds per year. The mismodeling in the much larger Newtonian periastron rate due to the quadrupolar term of the multipolar expansion of the gravitational potential of a massive ring representing the inner binary, whose nominal size for PSR J0337+1715 is 0.17 degrees per year, might be reduced down to the ≃ 0.5 milliarcseconds per year level over the next 10 years. Thus, a first measurement of such a novel form of gravitomagnetism, although undoubtedly challenging, might be, perhaps, feasible in a not too distant future. [ABSTRACT FROM AUTHOR]

Published

2024

8. Search for Extreme Mass Ratio Inspirals Using Particle Swarm Optimization and Reduced Dimensionality Likelihoods.

Author

Zou, Xiao-Bo, Mohanty, Soumya D., Luo, Hong-Gang, and Liu, Yu-Xiao

Subjects

*PARTICLE swarm optimization, *GRAVITATIONAL wave detectors, *GALACTIC dynamics, *GRAPHICS processing units, *GRAVITATIONAL waves, *BINARY black holes, *STELLAR dynamics, *STELLAR activity

Abstract

Extreme-mass-ratio inspirals (EMRIs) are significant observational targets for spaceborne gravitational wave detectors, namely, LISA, Taiji, and Tianqin, which involve the inspiral of stellar-mass compact objects into massive black holes (MBHs) with a mass range of approximately 10 4 ∼ 10 7 M ⊙ . EMRIs are estimated to produce long-lived gravitational wave signals with more than 10 5 cycles before plunge, making them an ideal laboratory for exploring the strong-gravity properties of the spacetimes around the MBHs, stellar dynamics in galactic nuclei, and properties of the MBHs itself. However, the complexity of the waveform model, which involves the superposition of multiple harmonics, as well as the high-dimensional and large-volume parameter space, make the fully coherent search challenging. In our previous work, we proposed a 10-dimensional search using Particle Swarm Optimization (PSO) with local maximization over the three initial angles. In this study, we extend the search to an 8-dimensional PSO with local maximization over both the three initial angles and the angles of spin direction of the MBH, where the latter contribute a time-independent amplitude to the waveforms. Additionally, we propose a 7-dimensional PSO search by using a fiducial value for the initial orbital frequency and shifting the corresponding 8-dimensional Time Delay Interferometry responses until a certain lag returns the corresponding 8-dimensional log-likelihood ratio's maximum. The reduced dimensionality likelihoods enable us to successfully search for EMRI signals with a duration of 0.5 years and signal-to-noise ratio of 50 within a wider search range than our previous study. However, the ranges used by both the LISA Data Challenge (LDC) and Mock LISA Data Challenge (MLDC) to generate their simulated signals are still wider than the those we currently employ in our direct searches. Consequently, we discuss further developments, such as using a hierarchical search to narrow down the search ranges of certain parameters and applying Graphics Processing Units to speed up the code. These advances aim to improve the efficiency, accuracy, and generality of the EMRI search algorithm. [ABSTRACT FROM AUTHOR]

Published

2024

9. Tidal Forces in Majumdar-Papapetrou Spacetimes.

Author

Albacete, Eduardo and Richartz, Maurício

Subjects

*TIDAL forces (Mechanics), *SCHWARZSCHILD black holes, *BLACK holes, *GEODESIC equation, *ENERGY function, *BINARY black holes

Abstract

Tidal disruption events occur when astrophysical objects are destroyed by black holes due to strong tidal force effects. Tidal forces have been studied in a variety of black hole spacetimes, including Reissner-Nordström and Kerr spacetimes. Despite the vast literature on the subject, tidal forces around black holes in static equilibrium have never been investigated before. The aim of this work is to fill in this gap and explore tidal forces in the Majumdar-Papapetrou spacetime describing two extremely charged binary black holes in equilibrium. We focus on tidal forces associated with radial and circular geodesics of massive neutral particles moving on the plane equidistant to the black holes. In particular, we study the behavior of the tidal forces as a function of the distance from the black holes and as a function of the energy of the geodesics. We also investigate the numerical solutions of the geodesic deviation equation for different initial conditions. [ABSTRACT FROM AUTHOR]

Published

2024

10. Comparing Numerical Relativity and Perturbation Theory Waveforms for a Non-Spinning Equal-Mass Binary.

Author

Islam, Tousif, Field, Scott E., and Khanna, Gaurav

Subjects

*RELATIVITY (Physics), *PERTURBATION theory, *BLACK holes, *MERGERS & acquisitions, *BINARY black holes

Abstract

Past studies have empirically demonstrated a surprising agreement between gravitational waveforms computed using adiabatic–driven–inspiral point–particle black hole perturbation theory (ppBHPT) and numerical relativity (NR) following a straightforward calibration step, sometimes referred to as α - β scaling. Specifically focusing on the quadrupole mode, this calibration technique necessitates only two time-independent parameters to scale the overall amplitude and time coordinate. In this article, part of a Special Issue, we investigate this scaling for non-spinning binaries at the equal-mass limit. Even without calibration, NR and ppBHPT waveforms exhibit an unexpected degree of similarity after accounting for different mass scale definitions. Post-calibration, good agreement between ppBHPT and NR waveforms extends nearly up to the point of the merger. We also assess the breakdown of the time-independent assumption of the scaling parameters, shedding light on current limitations and suggesting potential generalizations for the α - β scaling technique. [ABSTRACT FROM AUTHOR]

Published

2024

11. Integral Fluxes of Neutrinos and Gamma-Rays Emitted from Neighboring X-ray Binaries †.

Author

Kosmas, Odysseas, Papavasileiou, Theodora, and Kosmas, Theocharis

Subjects

*X-ray binaries, *STELLAR black holes, *BINARY black holes, *BINARY stars, *LARGE magellanic cloud, *NEUTRINOS, *NEUTRINO detectors

Abstract

Astrophysical plasma ejections (jets) are formed and powered by black holes that accrete material from their companion star in binary systems. Black hole X-ray binary systems constitute potential powerful galactic and extragalactic neutrino and gamma-ray sources. After being accelerated to highly relativistic velocities and subjected to various energy-consuming interactions, the lepto-hadronic content of the jets produces secondary particles such as pions and muons that decay to gamma-ray photons and neutrinos heading towards the Earth. In this work, we employ a jet emission model in order to predict the neutrino and gamma-ray integral fluxes emanating from some of the most investigated and prominent stellar black hole X-ray binary systems in the Milky Way, such as GRO J1655-40, Cygnus X-1, SS 433, and GRS 1915+105. For the sake of comparison, we also include an extragalactic system, namely, LMC X-1, located in the Large Magellanic Cloud. For the case of gamma-ray emissions, we also include absorption effects due to X-ray emission from the accretion disk and the black hole corona, as well as ultraviolet (UV) emission from the binary system's companion star. [ABSTRACT FROM AUTHOR]

Published

2023

12. Binary Black Hole Spins: Model Selection with GWTC-3.

Author

Périgois, Carole, Mapelli, Michela, Santoliquido, Filippo, Bouffanais, Yann, and Rufolo, Roberta

Subjects

*BINARY black holes, *BLACK holes, *SUPERGIANT stars, *BAYESIAN field theory, *ANGULAR momentum (Mechanics)

Abstract

The origin of the spins of stellar-mass black holes is still controversial, and angular momentum transport inside massive stars is one of the main sources of uncertainty. Here, we apply hierarchical Bayesian inference to derive constraints on spin models from the 59 most confident binary black hole merger events in the third gravitational-wave transient catalogue (GWTC-3). We consider up to five parameters: chirp mass, mass ratio, redshift, effective spin, and precessing spin. For the model selection, we use a set of binary population synthesis simulations spanning drastically different assumptions for black hole spins and natal kicks. In particular, our spin models range from the maximal to minimal efficiency of angular momentum transport in stars. We find that if we include the precessing spin parameter into our analysis, models predicting only vanishingly small spins are in tension with GWTC-3 data. On the other hand, models in which most spins are vanishingly small but that also include a subpopulation of tidally spun-up black holes are a good match to the data. Our results show that the precessing spin parameter has a crucial impact on model selection. [ABSTRACT FROM AUTHOR]

Published

2023

13. Random Convolutional Kernels for Space-Detector Based Gravitational Wave Signals.

Author

Poghosyan, Ruben and Luo, Yuan

Subjects

GRAVITATIONAL waves, BINARY black holes, ARTIFICIAL neural networks, SIGNAL-to-noise ratio

Abstract

Neural network models have entered the realm of gravitational wave detection, proving their effectiveness in identifying synthetic gravitational waves. However, these models rely on learned parameters, which necessitates time-consuming computations and expensive hardware resources. To address this challenge, we propose a gravitational wave detection model tailored specifically for binary black hole mergers, inspired by the Random Convolutional Kernel Transform (ROCKET) family of models. We conduct a rigorous analysis by factoring in realistic signal-to-noise ratios in our datasets, demonstrating that conventional techniques lose predictive accuracy when applied to ground-based detector signals. In contrast, for space-based detectors with high signal-to-noise ratios, our method not only detects signals effectively but also enhances inference speed due to its streamlined complexity—a notable achievement. Compared to previous gravitational wave models, we observe a significant acceleration in training time while maintaining acceptable performance metrics for ground-based detector signals and achieving equal or even superior metrics for space-based detector signals. Our experiments on synthetic data yield impressive results, with the model achieving an AUC score of 96.1 % and a perfect recall rate of 100 % on a dataset with a 1:3 class imbalance for ground-based detectors. For high signal-to-noise ratio signals, we achieve flawless precision and recall of 100 % without losing precision on datasets with low-class ratios. Additionally, our approach reduces inference time by a factor of 1.88 . [ABSTRACT FROM AUTHOR]

Published

2023

14. A Close Binary Supermassive Black Hole Model for the Galaxy 3C 273.

Author

Volvach, Alexandr, Volvach, Larisa, and Larionov, Mikhail

Subjects

BINARY black holes, GRAVITATIONAL wave detectors, SUPERMASSIVE black holes, ACTIVE galactic nuclei, GRAVITATIONAL waves, KINETIC energy

Abstract

The data from the last 60 years on the programs of long-term multi-frequency monitoring of active galactic nucleus (AGN) 3C 273 were analyzed. A model is proposed for finding the parameters of close binary systems (CBSs) from supermassive black holes (SMBHs), including a harmonic analysis of observational data series obtained in the optical and radio ranges. The purpose of this research was to show that in the absence of optical information on AGNs, only radio data can be used and the necessary information on the physical objects can be obtained. Regarding the example of the blazar 3C 273, the following parameters were obtained: the masses of the companions; their orbital characteristics, such as the speeds of movement in orbits; the reserves of the kinetic energy of the system; and others. It was found that AGN 3C 273 can be a very massive binary system at the stage of evolution close to merging. Based on the obtained parameters, the characteristics of the gravitational waves (GWs) of this system, its lifetime before the merger, and the possible observation of 3C 273 using gravitational wave detectors were considered. [ABSTRACT FROM AUTHOR]

Published

2023

15. Binary Neutron-Star Mergers with a Crossover Transition to Quark Matter.

Author

Mathews, Grant J., Kedia, Atul, Kim, Hee Il, and Suh, In-Saeng

Subjects

*QUARK matter, *QUARK-gluon plasma, *NUCLEOSYNTHESIS, *BINARY black holes, *GRAVITATIONAL waves, *NEUTRON stars

Abstract

This paper summarizes recent work on the possible gravitational-wave signal from binary neutron-star mergers in which there is a crossover transition to quark matter. Although this is a small piece of a much more complicated problem, we discuss how the power spectral density function may reveal the presence of a crossover transition to quark matter. [ABSTRACT FROM AUTHOR]

Published

2023

16. Parameter Inference for Coalescing Massive Black Hole Binaries Using Deep Learning.

Author

Ruan, Wenhong, Wang, He, Liu, Chang, and Guo, Zongkuan

Subjects

*DEEP learning, *GRAVITATIONAL waves, *BINARY black holes, *MATCHED filters, *LASER interferometers, *SIGNAL-to-noise ratio, *ANTENNAS (Electronics)

Abstract

In the 2030s, a new era of gravitational wave (GW) observations will dawn as multiple space-based GW detectors, such as the Laser Interferometer Space Antenna, Taiji, and TianQin, will open the millihertz window for GW astronomy. These detectors are poised to detect a multitude of GW signals emitted by different sources. It is a challenging task for GW data analysis to recover the parameters of these sources at a low computational cost. Generally, the matched filtering approach entails exploring an extensive parameter space for all resolvable sources, incurring a substantial cost owing to the generation of GW waveform templates. To alleviate the challenge, we make an attempt to perform parameter inference for coalescing massive black hole binaries (MBHBs) using deep learning. The model trained in this work has the capability to produce 50,000 posterior samples for the redshifted total mass, mass ratio, coalescence time, and luminosity distance of an MBHB in about twenty seconds. Our model can serve as an effective data pre-processing tool, reducing the volume of parameter space by more than four orders of magnitude for MBHB signals with a signal-to-noise ratio larger than 100. Moreover, the model exhibits robustness when handling input data that contain multiple MBHB signals. [ABSTRACT FROM AUTHOR]

Published

2023

17. Pre/Post-Merger Consistency Test for Gravitational Signals from Binary Neutron Star Mergers.

Author

Breschi, Matteo, Carullo, Gregorio, and Bernuzzi, Sebastiano

Subjects

NEUTRON stars, BINARY stars, STELLAR mergers, BINARY black holes, EQUATIONS of state, STELLAR radiation, GRAVITATIONAL waves, DEGREES of freedom

Abstract

Gravitational waves from binary neutron star (BNS) mergers can constrain nuclear models, predicting their equation of state (EOS). Matter effects on the inspiral-merger signal are encoded in the multipolar tidal polarizability parameters, whose leading order combination is sufficient to capture, with high accuracy, the key features of the merger waveform. Similar EOS-insensitive relations exist for the post-merger signal and can be used to model the emissions from the remnant. Several works suggested that the appearance of new degrees of freedom in high-density post-merger matter can be inferred by observing a violation of these EOS-insensitive relations. Here, we demonstrate a Bayesian method to test such an EOS-insensitive relation between the tidal polarizability parameters (or any other equivalent parameter) and the dominant post-merger frequency using information from the pre-and-post-merger signal. Technically, the method is similar to the inspiral-merger-ringdown consistency tests of General Relativity with binary black holes. However, differently from the latter, BNS pre/post-merger consistency tests are conceptually less informative and they only address the consistency of the assumed EOS-insensitive relation. Specifically, we discuss how such tests cannot conclusively discriminate between an EOS without respecting such a relation and the appearance of new degrees of freedom (or phase transitions) in high-density matter. [ABSTRACT FROM AUTHOR]

Published

2023

18. AI in Gravitational Wave Analysis, an Overview.

Author

Benedetto, Vincenzo, Gissi, Francesco, Ciaparrone, Gioele, and Troiano, Luigi

Subjects

DEEP learning, GRAVITATIONAL waves, WAVE analysis, BINARY black holes, ARTIFICIAL intelligence, SOFTWARE frameworks

Abstract

Gravitational wave research presents a range of intriguing challenges, each of which has driven significant progress in the field. Key research problems include glitch classification, glitch cancellation, gravitational wave denoising, binary black hole signal detection, gravitational wave bursts, and minor issues that contribute to the overall understanding of gravitational wave phenomena. This paper explores the applications of artificial intelligence, deep learning, and machine learning techniques in addressing these challenges. The main goal of the paper is to provide an effective view of AI and deep learning usage for gravitational wave analysis. Thanks to the advancements in artificial intelligence and machine learning techniques, aided by GPUs and specialized software frameworks, these techniques have played a key role over the last decade in the identification, classification, and cancellation of gravitational wave signals, as presented in our results. This paper provides a comprehensive exploration of the adoption rate of these techniques, with reference to the software and hardware involved, their effectiveness, and potential limitations, offering insights into the advancements in the analysis of gravitational wave data. [ABSTRACT FROM AUTHOR]

Published

2023

19. Observational Implications of OJ 287's Predicted 2022 Disk Impact in the Black Hole Binary Model.

Author

Valtonen, Mauri J., Dey, Lankeswar, Gopakumar, Achamveedu, Zola, Staszek, Lähteenmäki, Anne, Tornikoski, Merja, Gupta, Alok C., Pursimo, Tapio, Knudstrup, Emil, Gomez, Jose L., Hudec, Rene, Jelínek, Martin, Štrobl, Jan, Berdyugin, Andrei V., Ciprini, Stefano, Reichart, Daniel E., Kouprianov, Vladimir V., Matsumoto, Katsura, Drozdz, Marek, and Mugrauer, Markus

Subjects

BINARY black holes, ROCHE equipotentials, BLACK holes, SUPERMASSIVE black holes, BL Lacertae objects, ACCRETION disks

Abstract

We present a summary of the results of the OJ 287 observational campaign, which was carried out during the 2021/2022 observational season. This season is special in the binary model because the major axis of the precessing binary happens to lie almost exactly in the plane of the accretion disc of the primary. This leads to pairs of almost identical impacts between the secondary black hole and the accretion disk in 2005 and 2022. In 2005, a special flare called "blue flash" was observed 35 days after the disk impact, which should have also been verifiable in 2022. We did observe a similar flash and were able to obtain more details of its properties. We describe this in the framework of expanding cloud models. In addition, we were able to identify the flare arising exactly at the time of the disc crossing from its photo-polarimetric and gamma-ray properties. This is an important identification, as it directly confirms the orbit model. Moreover, we saw a huge flare that lasted only one day. We may understand this as the lighting up of the jet of the secondary black hole when its Roche lobe is suddenly flooded by the gas from the primary disk. Therefore, this may be the first time we directly observed the secondary black hole in the OJ 287 binary system. [ABSTRACT FROM AUTHOR]

Published

2023

20. Higgs Field-Induced Triboluminescence in Binary Black Hole Mergers.

Author

Chitishvili, Mariam, Gogberashvili, Merab, Konoplich, Rostislav, and Sakharov, Alexander S.

Subjects

*GAMMA rays, *ASTRONOMICAL observations, *BINARY black holes, *GRAVITATIONAL waves, *HAWKING radiation, *GAMMA ray bursts, *NEUTRINOS

Abstract

We conjecture that the Higgs potential can be significantly modified when it is in close proximity to the horizon of an astrophysical black hole, leading to the destabilization of the electroweak vacuum. In this situation, the black hole should be encompassed by a shell consisting of a "bowling substance" of the nucleating new-phase bubbles. In a binary black-hole merger, just before the coalescence, the nucleated bubbles can be prevented from falling under their seeding horizons, as they are simultaneously attracted by the gravitational potential of the companion. For a short time, the unstable vacuum will be "sandwiched" between two horizons of the binary black hole, and therefore the bubbles may collide and form micro-black holes, which are rapidly evaporated by thermal emission of Hawking radiation of all Standard Model species. This evaporation, being triggered by a gravitational wave signal from the binary black-hole merger, can manifest itself in observations of gamma rays and very-high-energy neutrinos, which makes it a perfect physics case for multi-messenger astronomical observations. [ABSTRACT FROM AUTHOR]

Published

2023

21. Strong Gravitational Lensing of Gravitational Waves: A Review.

Author

Grespan, Margherita and Biesiada, Marek

Subjects

*GRAVITATIONAL lenses, *GRAVITATIONAL waves, *GENERAL relativity (Physics), *NEUTRON stars, *BINARY stars, *BINARY black holes, *GALAXY clusters

Abstract

The first successful detection of gravitational waves (GWs) opened up a new window to study a realm of the most violent phenomena in the universe, such as coalescences of binary black holes (BH–BH), binary neutron stars (NS–NS), and mixed (BH–NS) systems, which are mostly inaccessible in the electromagnetic window. On the other hand, strong gravitational lensing of distant sources, such as galaxies and quasars, by other massive objects lying closer along the line of sight has become a powerful tool in cosmology and astrophysics. With the increasing sensitivity of the new generation of GW detectors, the chances to detect a strongly lensed GW signal are increasing. When GWs are strongly lensed, magnification of the signal intensity is expected, unveiling binary compact objects otherwise too distant to be detected. Such systems are important for their plethora of applications. Lensed GWs can be a test for general relativity, constrain mass distribution in galaxies or galaxy clusters, and provide cosmography information independently of the local cosmic ladders. In this review, we will provide a theoretical background of the gravitational lensing of GWs, including the wave optics regime, which becomes important in this context. Then we will describe the possible cosmological and astrophysical insight hidden in these signals, and present the state-of-the-art searches of lensed GWs in the present and future GW observatories. [ABSTRACT FROM AUTHOR]

Published

2023

22. Quiescent and Active Galactic Nuclei as Factories of Merging Compact Objects in the Era of Gravitational Wave Astronomy.

Author

Arca Sedda, Manuel, Naoz, Smadar, and Kocsis, Bence

Subjects

*ACTIVE galactic nuclei, *GRAVITATIONAL wave astronomy, *GALACTIC nuclei, *STAR formation, *BLACK holes, *HOSPITAL mergers, *BINARY black holes

Abstract

Galactic nuclei harbouring a central supermassive black hole (SMBH), possibly surrounded by a dense nuclear cluster (NC), represent extreme environments that house a complex interplay of many physical processes that uniquely affect stellar formation, evolution, and dynamics. The discovery of gravitational waves (GWs) emitted by merging black holes (BHs) and neutron stars (NSs), funnelled a huge amount of work focused on understanding how compact object binaries (COBs) can pair up and merge together. Here, we review from a theoretical standpoint how different mechanisms concur with the formation, evolution, and merger of COBs around quiescent SMBHs and active galactic nuclei (AGNs), summarising the main predictions for current and future (GW) detections and outlining the possible features that can clearly mark a galactic nuclei origin. [ABSTRACT FROM AUTHOR]

Published

2023

23. Gravitational Waves from the Merger of Two Primordial Black Hole Clusters.

Author

Eroshenko, Yury and Stasenko, Viktor

Subjects

*BLACK holes, *MERGERS & acquisitions, *GRAVITATIONAL interactions, *BINARY black holes, *SYMMETRY breaking, *ENERGY dissipation, *GRAVITATIONAL waves

Abstract

The orbital evolution of a binary system consisting of two primordial black hole clusters is investigated. Such clusters are predicted in some theoretical models with broken symmetry in the inflation Lagrangian. A cluster consists of the most massive central black hole surrounded by many smaller black holes. Similar to single primordial black holes, clusters can form gravitationally bounded pairs and merge during their orbital evolution. The replacement of single black holes by such clusters significantly changes the entire merger process and the final rate of gravitational wave bursts in some parameter ranges (with sufficiently large cluster radii). A new important factor is the tidal gravitational interaction of the clusters. It leads to an additional dissipation of the orbital energy, which is transferred into the internal energy of the clusters or carried away by black holes flying out of the clusters. Comparison with the data of gravitational-wave telescopes allows one to constrain the fractions of primordial black holes in clusters, depending on their mass and compactness. Even the primordial black hole fraction in the composition of dark matter ≃ 1 turns out to be compatible with LIGO/Virgo observational data, if the black holes are in clusters. [ABSTRACT FROM AUTHOR]

Published

2023

24. Gravitational Waves and Electromagnetic Radiation from Charged Black Hole Binaries.

Author

Benavides-Gallego, Carlos A. and Han, Wen-Biao

Subjects

*GRAVITATIONAL waves, *ELECTROMAGNETIC waves, *ELECTROMAGNETIC radiation, *BLACK holes, *FOURIER transforms, *BINARY black holes, *QUADRUPOLES

Abstract

In this manuscript, we investigate the electromagnetic radiation of a binary system of electrically charged black holes. Using the results of previous works, we compute the analytical expression for the waveform, the phase, and the Fourier transform during the inspiral phase for both the electromagnetic and gravitational radiations. To do so, we consider the quasi-circular approximation and small values for the charge-to-mass ratio in each black hole. In the case of electromagnetic radiation, we focus on the dipole contribution, but we also include the quadrupole term to complete our discussion. We found that the gravitational and electromagnetic waveforms contain two terms, and so does the Fourier transform. However, the behavior is dominated only by one of them. In the frequency-domain waves, for example, the dipole and quadrupole contributions and the gravitational wave are dominated by terms proportional to f−3/6, f−1/6, and f−7/6, respectively. As expected, the gravitational radiation and the quadrupole contribution have the same phase, in contrast to the dipole contribution. Moreover, the electromagnetic wave is more sensitive to changes in the charge-to-mass ratio than the gravitational wave. [ABSTRACT FROM AUTHOR]

Published

2023

25. Observational Imprints of Enhanced Scalar Power on Small Scales in Ultra Slow Roll Inflation and Associated Non-Gaussianities.

Author

Ragavendra, H. V. and Sriramkumar, L.

Subjects

INFLATIONARY universe, BINARY black holes, BLACK holes, COSMIC background radiation, SCALAR field theory, POWER spectra, GRAVITATIONAL waves

Abstract

The discovery of gravitational waves from merging binary black holes has generated considerable interest in examining whether these black holes could have a primordial origin. If a significant number of black holes have to be produced in the early universe, the primordial scalar power spectrum should have an enhanced amplitude on small scales, when compared to the COBE normalized values on the large scales that is strongly constrained by the anisotropies in the cosmic microwave background. In the inflationary scenario driven by a single, canonical scalar field, such power spectra can be achieved in models that permit a brief period of ultra slow roll inflation during which the first slow roll parameter decreases exponentially. In this review, we shall consider a handful of such inflationary models as well as a reconstructed scenario and examine the extent of formation of primordial black holes and the generation of secondary gravitational waves in these cases. We shall also discuss the strength and shape of the scalar bispectrum and the associated non-Gaussianity parameter that arise in such situations. We shall conclude with an outlook wherein we discuss the wider implications of the increased strengths of the non-Gaussianities on smaller scales. [ABSTRACT FROM AUTHOR]

Published

2023

26. Description and Application of the Surfing Effect.

Author

Maiorano, Michele, De Paolis, Francesco, and Nucita, Achille A.

Subjects

*BINARY pulsars, *BINARY black holes, *GRAVITATIONAL waves, *SUPERMASSIVE black holes, *SURFING, *PULSARS

Abstract

The standard technique for very low-frequency gravitational wave detection is mainly based on searching for a specific spatial correlation in the variation of the times of arrival of the radio pulses emitted by millisecond pulsars with respect to a timing model. This spatial correlation, which in the case of the gravitational wave background must have the form described by the Hellings and Downs function, has not yet been observed. Therefore, despite the numerous hints of a common red noise in the timing residuals of many millisecond pulsars compatible with that expected for the gravitational wave background, its detection has not yet been achieved. By now, the reason is not completely clear and, from some recent works, the urgency to adopt new detection techniques, possibly complementary to the standard one, is emerging clearly. Of course, this demand also applies to the detection of continuous gravitational waves emitted by supermassive black hole binaries populating the Universe. In the latter case, important information could, in principle, emerge from the millisecond pulsars considered individually in a single-pulsar search of continuous GWs. In this context, the surfing effect can then be exploited, helping to select the best pulsars to carry out such analysis. This paper aims to clarify when the surfing effect occurs and describe it exhaustively. A possible application to the case of the supermassive black hole binary candidate PKS 2131–021 and millisecond pulsar J2145–0750 is also analyzed. [ABSTRACT FROM AUTHOR]

Published

2022

27. Gravitational Waves, Event Horizons and Black Hole Observation: A New Frontier in Fundamental Physics.

Author

Giammarchi, Marco and Ricci, Fulvio

Subjects

*BINARY black holes, *GRAVITATIONAL waves, *SUPERMASSIVE black holes, *PHYSICS, *GENERAL relativity (Physics), *GRAVITATIONAL fields

Abstract

The observation of supermassive black holes by the Event Horizon Telescope Collaboration and the detection of gravitational waves emitted during the merging phase of compact binary objects to stellar-mass black holes by the LIGO–Virgo–KAGRA collaboration constitute major achievements of modern science. Gravitational wave signals emitted by stellar-mass black holes are being used to test general relativity in an unprecedented way in the regime of strong gravitational fields, as well as to address other physics questions such as the formation of heavy elements or the Hawking Area Theorem. These discoveries require further research in order to answer critical questions about the population density and the formation processes of binary systems. The detection of supermassive black holes considerably extends the range of scientific investigation by making it possible to probe the structure of spacetime around the horizon of the central mass of our galaxy as well as other galaxies. The huge amount of information collected by the VLBI worldwide network will be used to investigate general relativity in a further range of physical conditions. These investigations hold the potential to pave the way for the detection of quantum-mechanical effects such as a possible graviton mass. In this paper we will review, in a cursory way, some of the results of both the LIGO–Virgo–KAGRA and the EHT collaborations. [ABSTRACT FROM AUTHOR]

Published

2022

28. Neutron Star Binary Mergers: The Legacy of GW170817 and Future Prospects.

Author

Stratta, Giulia and Pannarale, Francesco

Subjects

*STELLAR mergers, *BINARY stars, *GRAVITATIONAL waves, *BINARY black holes, *ELECTROMAGNETIC radiation, *GAMMA ray bursts, *ASTROPHYSICS

Abstract

In 2015, the Advanced Laser Interferometer Gravitational-wave Observatory (LIGO) and Advanced Virgo began observing the Universe in a revolutionary way. Gravitational waves from cosmic sources were detected for the first time, confirming their existence predicted almost one century before, and also directly revealing the existence of black holes in binary systems and characterizing their properties. In 2017, a new revolution was achieved with the first observation of a binary neutron star merger, GW170817, and its associated electromagnetic emission. The combination of the information from gravitational-wave and electromagnetic radiation produced a wealth of results, still growing, spectacularly demonstrating the power of the newly born field of gravitational-wave Multi Messenger Astrophysics. We discuss the discovery of GW170817 in the context of the achievements it brought to Gamma-Ray Burst astrophysics, and we also provide a few examples of advancements in fundamental physics and cosmology. The detection rates of binary neutron star mergers expected in the next decade for third generation gravitational-wave interferometers will open the new perspective of a statistical approach to the study of these multi-messenger sources. [ABSTRACT FROM AUTHOR]

Published

2022

29. Present and Future of Gravitational Wave Astronomy.

Author

Vajente, Gabriele

Subjects

GRAVITATIONAL wave astronomy, GRAVITATIONAL waves, GRAVITATIONAL wave detectors, GENERAL relativity (Physics), BINARY black holes

Abstract

Gravitational waves (GW) are propagating perturbations of the space-time metric, generated by time-varying mass distributions. Graph: Figure 2 Time-frequency maps of the LIGO and Virgo detector outputs during the gravitational-wave event GW170817, created by the collision of two neutron stars. Many sources of noises had to be understood and overcome [[3]], so that the two Advanced LIGO observatories [[4]] were sensitive enough to detect this event with high signal-to-noise ratio, opening the era of gravitational-wave astronomy and astrophysics. The sky localization provided by the gravitational wave observation by multiple detectors, LIGO and Virgo, allowed optical telescopes to identify the aftermath of the collision, and subsequently follow up in the entire electromagnetic spectrum. [Extracted from the article]

Published

2022

30. Explaining the 'Outliers' Track in Black Hole X-ray Binaries with a BZ-Jet and Inner-Disk Coupling.

Author

Chang, Ning, Liu, Xiang, Xie, Fu-Guo, Cui, Lang, and Shan, Hao

Subjects

*BINARY black holes, *BLACK holes, *X-ray binaries, *ACCRETION disks

Abstract

In this paper, we investigate the black hole (BH) spin contribution to jet power, especially for the magnetic arrested disk (MAD), where only inner accretion disk luminosity is closely coupled with the spin-jet power, and try to explain the 'outliers' track of the radio L R to X-ray luminosity L X in two black hole X-ray binaries (BHXBs). Our results suggest that the BZ-jet and the inner-disk coupling could account for the 'outliers' track of the radio/X-ray correlation in two BHXBs, H1743-322 and MAXI J1348-630. Although the accretion disk of H1743-322 in the outburst could be in the MAD state, there is a lower probability that MAXI J1348-630 is in the MAD state due to its low jet production efficiency. The difference in the inner-disk bolometric luminosity ratio of the two sources implies that these two BHXBs are in different inner-disk accretion states. We further investigate the phase-changing regime of MAXI J1348-630 and find that there is a phase transition around L X / L Edd ∼ 10 − 3 . The assumption of sub-MAD is discussed as well. [ABSTRACT FROM AUTHOR]

Published

2022

31. Binary X-ray Sources in Massive Brans–Dicke Gravity.

Author

Panotopoulos, Grigoris, Rincón, Ángel, and Lopes, Ilídio

Subjects

*ACCRETION disks, *BINARY black holes, *GRAVITY, *GRAVITATIONAL fields, *SCALAR field theory, *BLACK holes, *X-ray binaries

Abstract

This study focuses on the X-ray emission of low-mass black hole binaries in massive Brans–Dicke gravity. First, we compute the accretion disk with the well-known Shakura–Sunyaev model for an optically thick, cool, and geometrically thin disk. Moreover, we assume that the gravitational field generated by the stellar-mass black hole is an analogue of the Schwarzschild space-time of Einstein's theory in massive Brans–Dicke gravity. We compute the most relevant quantities of interest, i.e., (i) the radial velocity, (ii) the energy and surface density, and (iii) the pressure as a function entirely of the radial coordinate. We also compute the soft spectral component of the X-ray emission produced by the disk. Furthermore, we investigate in detail how the mass of the scalar field modifies the properties of the binary as described by the more standard Schwarzschild solution. [ABSTRACT FROM AUTHOR]

Published

2022

32. Spectral and Timing Properties of H 1743-322 in the "Faint" 2005 Normal Outburst.

Author

Dong, Aijun, Liu, Chang, Zhi, Qijun, You, Ziyi, Sun, Qibin, and Du, Bowen

Subjects

*BINARY black holes, *X-ray binaries, *X-ray spectra, *PHOTON correlation, *BLACK holes, *ACCRETION disks

Abstract

H 1743-322 is a well-known black hole X-ray binary (BH XRBs) that has been observed in several outbursts over the past. In this work, we have performed the spectral and timing analysis of H 1743-322 during the "faint" 2005 outburst for the first time with the RXTE/PCA data. In this outburst, the spectral and timing parameters (e.g., T in , Γ , R in , r m s and QPOs, etc.) presented an obvious change and a q-like pattern was found in the Hardness Intensity Diagram (HID), which often named as the hysteresis effect of BH XRBs. The radius of the innermost stable circular orbit was constrained as R ISCO ∼3.50 R g , which predicts that H 1743-322 is a lower-spin black hole. We further explored the correlation between timing and spectral properties. The relation of photon index Γ and X-ray flux, F 3 – 25 keV , presented a transition between negative and positive correlation when the X-ray luminosity, L 3 – 25 keV , is above and below a critical X-ray luminosity, L X , crit ≃ 2.55 × 10 − 3   L Edd , which can be well explained by the Shakura-Sunyaev disk–corona model (SSD-corona) and advection-dominated accretion flow (ADAF). We also found the tight linear, negative correlation between photon index Γ and the total fractional r m s . Since the amount of soft photons from the accretion disk seems invariable, an increase of the number of soft photons will dilute the variability from the harder photons. Therefore, the softer the X-ray spectra will result in the smaller total fractional r m s . The above results suggested that the 2005 outburst of H 1743-322 was a normal outburst and H 1743-322 represented similar properties with other black hole X-ray binaries. [ABSTRACT FROM AUTHOR]

Published

2022

33. Why Masses of Binary Black Hole Mergers Are Overestimated? †.

Author

Křížek, Michal and Somer, Lawrence

Subjects

BINARY black holes, BLACK holes, BINARY stars, TIME dilation

Abstract

We show that masses of binary black hole mergers are overestimated, since a large gravitational redshift is not taken into account. Such a phenomenon occurs due to time dilation in a close neighborhood of any black hole. This fact allows us to explain a high mass gap between observed binary neutron stars and calculated binary black hole mergers. We also present other reasons why masses of black hole mergers are determined incorrectly. [ABSTRACT FROM AUTHOR]

Published

2022

34. An Eccentric Binary Blackhole in Post-Newtonian Theory.

Author

Chowdhury, Sourav Roy and Khlopov, Maxim

Subjects

*BINARY black holes, *GRAVITATIONAL wave detectors, *GRAVITATIONAL waves

Abstract

Gravitational waves radiated during binary black hole coalescence are a perfect probe for studying the characteristics of strong gravity. Advanced techniques for creating numerical relativity substitute models for eccentric binary black hole systems are presumed to be crucial in existing and anticipated gravitational wave detectors. The imprint on the observation data of the gravitational wave emitted by the binary coalescence enhances two-body system studies. The aim of this study is to present an overview of the change in characteristic behaviors of hierarchical massive astrophysical objects merger, which are the databank of the early universe. We present results from numerical relativity simulations of an equal-mass and unequal mass nonspinning inspiral binary-black-hole system in the Post-Newtonian framework. We also consider the time evolution of eccentricity for an initial eccentric system. The eccentric Post-Newtonian equations are expanded in the form of the frequency related variable x = (M ω) 2 / 3 . The model is restricted to the (2, 2) spin-weighted spherical harmonic modes. We conclude that for higher eccentricity as well as mass ratio, there is higher oscillation in orbital radius and in eccentricity. [ABSTRACT FROM AUTHOR]

Published

2022

35. Constraints on Cosmic Ray Acceleration Capabilities of Black Holes in X-ray Binaries and Active Galactic Nuclei.

Author

Tursunov, Arman, Kološ, Martin, and Stuchlík, Zdeněk

Subjects

*BINARY black holes, *COSMIC rays, *ACTIVE galactic nuclei, *X-ray binaries, *SYNCHROTRON radiation, *GRAVITATIONAL waves, *PARTICLE accelerators

Abstract

Rotating black holes (BHs) are likely the largest energy reservoirs in the Universe as predicted by BH thermodynamics, while cosmic rays (CRs) are the most energetic among particles detected on Earth. Magnetic fields surrounding BHs combined with strong gravity effects, thanks to the spacetime symmetries, turn the BHs into powerful accelerators of charged particles. At the same time, in the age of multi-wavelength and multi-messenger astronomy, BHs and their environments have not yet been probed with CR messengers, despite being observed across most of the electromagnetic spectrum, and neutrino and gravitational waves. In this paper, we probe the acceleration capabilities of BHs in 8 galactic X-ray binaries and 25 local active galactic nuclei (AGNs) within 100 Mpc, based on the ultra-efficient regime of the magnetic Penrose process of a BH energy extraction combined with observational data. We find that the maximum energy of the galactic BHs can reach only up to the knee of the CR spectrum, including supermassive BH Sgr A* at the Galactic Center. On the other hand, for supermassive BHs in AGNs, we find that the mean energy of primary CRs is of the order of 10 19 eV. It is therefore likely that local supermassive BHs give sufficient contribution to the ankle—a sharp change in the slope of the cosmic ray spectrum around 10 18.6 eV energy. We also discuss the energy losses of primary CRs close to the acceleration zones. In the galactic BH cases, it is likely dominated by synchrotron radiation losses. [ABSTRACT FROM AUTHOR]

Published

2022

36. Fundamental Tone and Overtones of Quasinormal Modes in Ringdown Gravitational Waves: A Detailed Study in Black Hole Perturbation.

Author

Norichika Sago, Soichiro Isoyama, and Hiroyuki Nakano

Subjects

*GRAVITATIONAL waves, *BLACK holes, *DATA analysis, *PERTURBATION theory, *COMPUTER simulation

Abstract

Ringdown gravitational waves of compact object binaries observed by ground-based gravitational-wave detectors encapsulate rich information to understand remnant objects after the merger and to test general relativity in the strong field. In this work, we investigate the ringdown gravitational waves in detail to better understand their property, assuming that the remnant objects are black holes. For this purpose, we perform numerical simulations of post-merger phase of binary black holes by using the black hole perturbation scheme with the initial data given under the close-limit approximation, and we generate data of ringdown gravitational waves with smaller numerical errors than that associated with currently available numerical relativity simulations. Based on the analysis of the data, we propose an orthonormalization of the quasinormal mode functions describing the fundamental tone and overtones to model ringdown gravitational waves. Finally, through some demonstrations of the proposed model, we briefly discuss the prospects for ringdown gravitational-wave data analysis including the overtones of quasinormal modes. [ABSTRACT FROM AUTHOR]

Published

2021

37. Global Understanding of Accretion and Ejection around Black Holes.

Author

Mondal, Santanu

Subjects

BLACK holes, ACCRETION (Astrophysics), BINARY black holes, BL Lacertae objects, SUPERMASSIVE black holes

Abstract

Authors suggested that the cooling and viscosity are important to make the corona variable, similar to low mass black hole candidates (LMBHCs, ref. [[3]]), which actually depends on the variation of the mass accretion rate (ref. [[4]]). Accretion and ejection around compact objects, mainly around black holes, both in low mass, and supermassive, is rich and has been studied exhaustively. 10.3390/galaxies10010006 13 Mondal S., Adhikari T.P., Singh C.B. Emission lines from X-ray illuminated accretion disc in black hole binaries. 10.1093/mnras/stt361 6 Ramírez-Velásquez J., Sigalotti L., Gabbasov R., Klapp J., Contreras E. The Radiative Newtonian 1 < <= 1.66 and the Paczy'nski-Wiita = 5/3 Regime of Non-Isothermal Bondi Accretion onto a Massive Black Hole with an Accretion Disc. [Extracted from the article]

Published

2022

38. Review of the Advanced LIGO Gravitational Wave Observatories Leading to Observing Run Four.

Author

Cahillane, Craig and Mansell, Georgia

Subjects

GRAVITATIONAL waves, BINARY black holes, OPTICAL detectors, GRAVITATIONAL wave detectors, OBSERVATORIES, STELLAR mergers, NEUTRON stars

Abstract

Gravitational waves from binary black hole and neutron star mergers are being regularly detected. As of 2021, 90 confident gravitational wave detections have been made by the LIGO and Virgo detectors. Work is ongoing to further increase the sensitivity of the detectors for the fourth observing run, including installing some of the A+ upgrades designed to lower the fundamental noise that limits the sensitivity to gravitational waves. In this review, we will provide an overview of the LIGO detectors optical configuration and lock acquisition procedure, discuss the detectors' fundamental and technical noise limits, show the current measured sensitivity, and explore the A+ upgrades currently being installed in the detectors. [ABSTRACT FROM AUTHOR]

Published

2022

39. Promise of Persistent Multi-Messenger Astronomy with the Blazar OJ 287.

Author

Valtonen, Mauri J., Dey, Lankeswar, Gopakumar, Achamveedu, Zola, Staszek, Komossa, S., Pursimo, Tapio, Gomez, Jose L., Hudec, Rene, Jermak, Helen, and Berdyugin, Andrei V.

Subjects

SUPERMASSIVE black holes, ASTRONOMY, BL Lacertae objects, BLACK holes, GRAVITATIONAL waves, ACCRETION disks, BINARY black holes

Abstract

Successful observations of the seven predicted bremsstrahlung flares from the unique bright blazar OJ 287 firmly point to the presence of a nanohertz gravitational wave (GW) emitting supermassive black hole (SMBH) binary central engine. We present arguments for the continued monitoring of the source in several electromagnetic windows to firmly establish various details of the SMBH binary central engine description for OJ 287. In this article, we explore what more can be known about this system, particularly with regard to accretion and outflows from its two accretion disks. We mainly concentrate on the expected impact of the secondary black hole on the disk of the primary on 3 December 2021 and the resulting electromagnetic signals in the following years. We also predict the times of exceptional fades, and outline their usefulness in the study of the host galaxy. A spectral survey has been carried out, and spectral lines from the secondary were searched for but were not found. The jet of the secondary has been studied and proposals to discover it in future VLBI observations are mentioned. In conclusion, the binary black hole model explains a large number of observations of different kinds in OJ 287. Carefully timed future observations will be able to provide further details of its central engine. Such multi-wavelength and multidisciplinary efforts will be required to pursue multi-messenger nanohertz GW astronomy with OJ 287 in the coming decades. [ABSTRACT FROM AUTHOR]

Published

2022

40. Can We Prescribe the Physical Parameters of Multiple Black Holes?

Author

Rácz, István

Subjects

*BLACK holes, *BINARY black holes, *BLACK people

Abstract

The parabolic-hyperbolic form of the constraints and superposed Kerr-Schild black holes have already been used to provide a radically new initialization of binary black hole configurations. The method generalizes straightforwardly to multiple black hole systems. This paper is to verify that each of the global Arnowitt-Deser-Misner quantities of the constructed multiple black hole initial data can always be prescribed, as desired, in advance of solving the constraints. These global charges are shown to be uniquely determined by the physical parameters of the involved individual Kerr-Schild black holes. [ABSTRACT FROM AUTHOR]

Published

2021

41. Principles of Gravitational-Wave Detection with Pulsar Timing Arrays.

Author

Maiorano, Michele, De Paolis, Francesco, and Nucita, Achille A.

Subjects

*BINARY black holes, *GRAVITATIONAL waves, *GRAVITATIONAL wave detectors, *COSMIC strings, *CORRELATORS, *GLOBULAR clusters, PULSAR detection

Abstract

Pulsar timing uses the highly stable pulsar spin period to investigate many astrophysical topics. In particular, pulsar timing arrays make use of a set of extremely well-timed pulsars and their time correlations as a challenging detector of gravitational waves. It turns out that pulsar timing arrays are particularly sensitive to ultra-low-frequency gravitational waves, which makes them complementary to other gravitational-wave detectors. Here, we summarize the basics, focusing especially on supermassive black-hole binaries and cosmic strings, which have the potential to form a stochastic gravitational-wave background in the pulsar timing array detection band, and the scientific goals on this challenging topic. We also briefly outline the recent interesting results of the main pulsar timing array collaborations, which have found strong evidence of a common-spectrum process compatible with a stochastic gravitational-wave background and mention some new perspectives that are particularly interesting in view of the forthcoming radio observatories such as the Five hundred-meter Aperture Spherical Telescope, the MeerKAT telescope, and the Square Kilometer Array. [ABSTRACT FROM AUTHOR]

Published

2021

42. The Origin of Radio Emission in Black Hole X-ray Binaries.

Author

Liu, Xiang, Chang, Ning, Wang, Xin, and Yuan, Qi

Subjects

BINARY black holes, ACCRETION (Astrophysics), BLACK holes, ACCRETION disks, ACCOUNTING standards

Abstract

We studied the relation of accretion-jet power and disk luminosity, especially the jet efficiencies and disk radiative efficiencies for different accretion disks as well as black hole (BH) spin, in order to explore the origin of radio emission in black hole X-ray binaries (BHXBs). We found that jet efficiency increases more rapidly (efficient) than the nearly constant disk radiative efficiency for thin disk component in high accretion regime, which could account for the steep track ( μ > 1 ) in the observed radio and X-ray luminosity relations ( L R ∝ L X μ ), but the thin disk component may not be able to explain the standard track ( μ ≈ 0.6 ) in the BHXBs. For hot accretion flows (HAF), the resulting jet efficiency changes along with the large range of accretions from quiescent state to nearly Eddington state, which could account for the standard track in the BHXBs. The BH spin-jet is discussed for the magnetic arrested disk (MAD) state; in this state, the spin-jet power might contribute to a linear correlation between jet power and mass accretion rate for a given source. More accurate observations are required to test the results. [ABSTRACT FROM AUTHOR]

Published

2021

43. Mass and Rate of Hierarchical Black Hole Mergers in Young, Globular and Nuclear Star Clusters.

Author

Mapelli, Michela, Santoliquido, Filippo, Bouffanais, Yann, Arca Sedda, Manuel, Artale, Maria Celeste, and Ballone, Alessandro

Subjects

*BLACK holes, *GLOBULAR clusters, *BINARY black holes, *STAR clusters, *CLUSTER theory (Nuclear physics), *STELLAR mergers

Abstract

Hierarchical mergers are one of the distinctive signatures of binary black hole (BBH) formation through dynamical evolution. Here, we present a fast semi-analytic approach to simulate hierarchical mergers in nuclear star clusters (NSCs), globular clusters (GCs) and young star clusters (YSCs). Hierarchical mergers are more common in NSCs than they are in both GCs and YSCs because of the different escape velocity. The mass distribution of hierarchical BBHs strongly depends on the properties of first-generation BBHs, such as their progenitor's metallicity. In our fiducial model, we form black holes (BHs) with masses up to ∼ 10 3 M ⊙ in NSCs and up to ∼ 10 2 M ⊙ in both GCs and YSCs. When escape velocities in excess of 100 km s − 1 are considered, BHs with mass > 10 3 M ⊙ are allowed to form in NSCs. Hierarchical mergers lead to the formation of BHs in the pair instability mass gap and intermediate-mass BHs, but only in metal-poor environments. The local BBH merger rate in our models ranges from ∼10 to ∼60 Gpc − 3 yr − 1 ; hierarchical BBHs in NSCs account for ∼ 10 − 2 – 0.2 Gpc − 3 yr − 1 , with a strong upper limit of ∼10 Gpc − 3 yr − 1 . When comparing our models with the second gravitational-wave transient catalog, we find that multiple formation channels are favored to reproduce the observed BBH population. [ABSTRACT FROM AUTHOR]

Published

2021

44. Deep Learning for Gravitational-Wave Data Analysis: A Resampling White-Box Approach.

Author

Morales, Manuel D., Antelis, Javier M., Moreno, Claudia, and Nesterov, Alexander I.

Subjects

*DEEP learning, *GRAVITATIONAL waves, *RESAMPLING (Statistics), *CONVOLUTIONAL neural networks, *DATA analysis, *SIGNAL-to-noise ratio, *BINARY black holes

Abstract

In this work, we apply Convolutional Neural Networks (CNNs) to detect gravitational wave (GW) signals of compact binary coalescences, using single-interferometer data from real LIGO detectors. Here, we adopted a resampling white-box approach to advance towards a statistical understanding of uncertainties intrinsic to CNNs in GW data analysis. We used Morlet wavelets to convert strain time series to time-frequency images. Moreover, we only worked with data of non-Gaussian noise and hardware injections, removing freedom to set signal-to-noise ratio (SNR) values in GW templates by hand, in order to reproduce more realistic experimental conditions. After hyperparameter adjustments, we found that resampling through repeated k-fold cross-validation smooths the stochasticity of mini-batch stochastic gradient descent present in accuracy perturbations by a factor of 3.6 . CNNs are quite precise to detect noise, 0.952 for H1 data and 0.932 for L1 data; but, not sensitive enough to recall GW signals, 0.858 for H1 data and 0.768 for L1 data—although recall values are dependent on expected SNR. Our predictions are transparently understood by exploring tthe distribution of probabilistic scores outputted by the softmax layer, and they are strengthened by a receiving operating characteristic analysis and a paired-sample t-test to compare with a random classifier. [ABSTRACT FROM AUTHOR]

Published

2021

45. Binary Black Hole Information Loss Paradox and Future Prospects.

Author

Mitra, Ayan, Chattopadhyay, Pritam, Paul, Goutam, and Zarikas, Vasilios

Subjects

*BINARY black holes, *BLACK holes, *GRAVITATIONAL waves, *QUANTUM entanglement, *PARADOX, *QUANTUM optics

Abstract

Various techniques to tackle the black hole information paradox have been proposed. A new way out to tackle the paradox is via the use of a pseudo-density operator. This approach has successfully dealt with the problem with a two-qubit entangle system for a single black hole. In this paper, we present the interaction with a binary black hole system by using an arrangement of the three-qubit system of Greenberger–Horne–Zeilinger (GHZ) state. We show that our results are in excellent agreement with the theoretical value. We have also studied the interaction between the two black holes by considering the correlation between the qubits in the binary black hole system. The results depict a complete agreement with the proposed model. In addition to the verification, we also propose how modern detection of gravitational waves can be used on our optical setup as an input source, thus bridging the gap with the gravitational wave's observational resources in terms of studying black hole properties with respect to quantum information and entanglement. [ABSTRACT FROM AUTHOR]

Published

2020

46. Interferometer Sensing and Control for the Advanced Virgo Experiment in the O3 Scientific Run.

Author

Allocca, Annalisa, Bersanetti, Diego, Casanueva Diaz, Julia, De Rossi, Camilla, Mantovani, Maddalena, Masserot, Alain, Rolland, Loïc, Ruggi, Paolo, Swinkels, Bas, Tapia San Martin, Enzo Nicolas, Vardaro, Marco, and Was, Michal

Subjects

BINARY stars, BINARY black holes, GRAVITATIONAL waves

Abstract

Advanced Virgo is a 2nd-generation laser interferometer based in Cascina (Italy) aimed at the detection of gravitational waves (GW) from astrophysical sources. Together with the two USA-based LIGO interferometers they constitute a network which operates in coincidence. The three detectors observed the sky simultaneously during the last part of the second Observing Run (O2) in August 2017, and this led to two paramount discoveries: the first three-detector observation of gravitational waves emitted from the coalescence of a binary black hole system (GW170814), and the first detection ever of gravitational waves emitted from the coalescence of a binary neutron star system (GW170817). Coincident data taking was re-started for the third Observing Run (O3), which started on 1st April 2019 and lasted almost one year. This paper will describe the new techniques implemented for the longitudinal controls with respect to the ones already in use during O2. Then, it will present an extensive description of the full scheme of the angular controls of the interferometer, focusing on the different control strategies that are in place in the different stages of the lock acquisition procedure, which is the complex sequence of operations by which an uncontrolled, "free" laser interferometer is brought to the final working point, which allows the detector to reach the best sensitivity. [ABSTRACT FROM AUTHOR]

Published

2020

47. Shaping Planetary Nebulae with Jets and the Grazing Envelope Evolution.

Author

Soker, Noam

Subjects

PLANETARY nebulae, BINARY black holes, BINARY stars, NEUTRON stars, ACCRETION disks, ENERGY conversion

Abstract

I argue that the high percentage of planetary nebulae (PNe) that are shaped by jets show that main sequence stars in binary systems can accrete mass at a high rate from an accretion disk and launch jets. Not only does this allow jets to shape PNe, but this also points to the importance of jets in other types of binary systems and in other processes. These processes include the grazing envelope evolution (GEE), the common envelope evolution (CEE), and the efficient conversion of kinetic energy to radiation in outflows. Additionally, the jets point to the possibility that many systems launch jets as they enter the CEE, possibly through a GEE phase. The other binary systems in which jets might play significant roles include intermediate-luminosity optical transients (ILOTs), supernova impostors (including pre-explosion outbursts), post-CEE binary systems, post-GEE binary systems, and progenitors of neutron star binary systems and black hole binary systems. One of the immediate consequences is that the outflow of these systems is highly-non-spherical, including bipolar lobes, jets, and rings. [ABSTRACT FROM AUTHOR]

Published

2020

48. Coalescence of Kerr Black Holes—Binary Systems from GW150914 to GW170814.

Author

Gwak, Bogeun

Subjects

*KERR black holes, *BINARY black holes, *GRAVITATIONAL interactions, *GRAVITATIONAL waves, *ANGULAR momentum (Mechanics), *SPIN-orbit interactions

Abstract

We investigate the energy of the gravitational wave from a binary black hole merger by the coalescence of two Kerr black holes with an orbital angular momentum. The coalescence is constructed to be consistent with particle absorption in the limit in which the primary black hole is sufficiently large compared with the secondary black hole. In this limit, we analytically obtain an effective gravitational spin–orbit interaction dependent on the alignments of the angular momenta. Then, binary systems with various parameters including equal masses are numerically analyzed. According to the numerical analysis, the energy of the gravitational wave still depends on the effective interactions, as expected from the analytical form. In particular, we ensure that the final black hole obtains a large portion of its spin angular momentum from the orbital angular momentum of the initial binary black hole. To estimate the angular momentum released by the gravitational wave in the actual binary black hole, we apply our results to observations at the Laser Interferometer Gravitational-Wave Observatory: GW150914, GW151226, GW170104, GW170608 and GW170814. [ABSTRACT FROM AUTHOR]

Published

2019

49. 3C 84: Observational Evidence for Precession and a Possible Relation to TeV Emission.

Author

Britzen, Silke, Fendt, Christian, Zajaček, Michal, Jaron, Frédéric, Pashchenko, Ilya, Aller, Margo F., and Aller, Hugh D.

Subjects

RADIO galaxies, SPIRAL galaxies, BINARY black holes, SUPERMASSIVE black holes, ACTIVE galactic nuclei, GALAXY mergers, SPACE telescopes

Abstract

3C 84 (NGC 1275, Perseus A) is a bright radio source at the center of an ongoing merger, where HST observations show two colliding spiral galaxies. 3C 84 holds promise to improve our understanding about how of the activity of active galactic nuclei, the formation of supermassive binary black holes, feedback processes, and galaxy collisions are interrelated. 3C,84 is one of only six radio galaxies, which reveal TeV emission. The origin of this TeV emission is still a matter of debate. Our present study is based on high resolution radio interferometric observations (15 GHz) of the pc-scale jet in this complex radio galaxy. We have re-modeled and re-analyzed 42 VLBA observations of 3C 84, performed between 1999.99 and 2017.65. In order to enable a proper alignment of the VLBA observations, we developed a method of a "differential" alignment whereby we select one reference point and minimize the deviations from this reference point in the remaining epochs. As a result, we find strong indication for a precession of the 3C 84 jet—not only for its central regions, but also for the outer lobe at 10 mas distance. These findings are further supported by our kinematic precession modeling of the radio flux-density monitoring data provided by the University of Michigan Radio Observatory and the Owens Valley Radio Observatory, which yields a precession time scale of about 40 yr. This time scale is further supported by literature maps obtained about 40 yr ago (1973 and 1974.1) which reveal a similar central radio structure. We suggest that the TeV flare detected by MAGIC may correlate with the precession of 3C 84, as we disentangle a projected reversal point of the precessing motion that correlates with the flaring time. This may physically be explained by a precessing jet sweeping over a new region of so far undisturbed X-ray gas which would then lead to shock-produced TeV-emission. In addition, we perform a correlation analysis between the radio data and GeV data obtained by the Fermi Gamma-ray Space Telescope and find that the γ -ray data are lagging the radio data by 300–400 days. A possible explanation could be that the radio and the GeV data stem from different emission regions. We discuss our findings and propose that the detected jet precession can also account for the observed cavities in the X-ray emission on kpc-scales. [ABSTRACT FROM AUTHOR]

Published

2019

50. Relativistic Aspects of Accreting Supermassive Black Hole Binaries in Their Natural Habitat: A Review.

Author

Gold, Roman

Subjects

BINARY black holes, GRAVITATIONAL waves, SUPERMASSIVE black holes, RELATIVISTIC astrophysics, HABITATS

Abstract

In this review a summary is given on recent theoretical work, on understanding accreting supermassive black hole binaries in the gravitational wave (GW)-driven regime. A particular focus is given to theoretical predictions of properties of disks and jets in these systems during the gravitational wave driven phase. Since a previous review by Schnittman 2013, which focussed on Newtonian aspects of the problem, various relativistic aspects have been studied. In this review we provide an update on these relativistic aspects. Further, a perspective is given on recent observational developments that have seen a surge in the number of proposed supermassive black hole binary candidates. The prospect of bringing theoretical and observational efforts closer together makes this an exciting field of research for years to come. [ABSTRACT FROM AUTHOR]

Published

2019