Prediction of gamma-ray emission from Cygnus X-1, SS 433, and GRS 1915+105 after absorption

Papavasileiou, Th. V.; Kosmas, O. T.; Sinatkas, I.

doi:10.1051/0004-6361/202345869

Cited by 6 publications

(5 citation statements)

References 61 publications

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“…That leaves the jet region at the distance z = 10 11 cm with the highest probability of emitting detectable VHE gamma-ray fluxes, as seen also in Ref. [40].…”

Section: Resultssupporting

confidence: 71%

“…The binary system's inclination also impacts the disk luminosity measured by an observer. However, in this case, the deviation from similar calculations in other works would be attributed to the maximum temperature since a decrease of even half an order of magnitude could reproduce these results [40]. It should be noted, however, that the disk modeling is rather simplistic.…”

Section: Resultsmentioning

confidence: 51%

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Studying the Spectral Energy Distributions Emanating from Regular Galactic XRBs

2023

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X-ray binary systems (XRBs) exhibit similar dynamics and multimessenger emission mechanisms to active galactic nuclei (AGNs) with the benefit of shorter time scaling. Those systems produce rich spectral energy distributions (SEDs) ranging from the radio band to the very high energy gamma rays. The emission origin varies between the system’s accretion disk (X-rays) to the corona and, most notably, to the two twin plasma ejections (jets) that often meet the interstellar medium forming highly observable radio lobes. Modeling of the jets offers an excellent opportunity to understand the intrinsic mechanisms and the jet particles, such as electrons, positrons, and protons. In this work, we employ a lepto-hadronic jet model that assumes particle acceleration through shock waves over separate zonal regions of the jet. The hadronic models consider proton–proton collisions that end up in gamma-ray photons through neutral pion decays. The main leptonic mechanisms involve synchrotron radiation (from both electrons and protons) and inverse Compton scattering of ambient photons (coming from the disk, the corona, and the companion star) on jet electrons. The emissions from the disk, the corona, and the donor star are also included in the SED calculations, along with the photon absorption effects due to their interaction with higher-energy jet photons. We apply the model on a 10M⊙ black hole accreting at the Eddington rate out of a 20M⊙ companion star. One of our goals is to investigate and determine an optimal frame concerning the values for the free parameters that enter our calculations to produce higher integral fluxes.

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“…That leaves the jet region at the distance z = 10 11 cm with the highest probability of emitting detectable VHE gamma-ray fluxes, as seen also in Ref. [40].…”

Section: Resultssupporting

confidence: 71%

Section: Resultsmentioning

confidence: 51%

Studying the Spectral Energy Distributions Emanating from Regular Galactic XRBs

2023

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“…The dependence of the jet gamma-ray photon absorption on the disk's geometry and radiative efficiency is better illustrated in Refs. [39,40]. In those works, we conducted similar calculations which are, in the present work, extended by applications on two additional X-ray binaries, namely, GRO J1655-40 and LMC X-1.…”

Section: Photon Annihilation In the X-ray Binary Environmentmentioning

confidence: 84%

“…In previous works, we assumed purely hadronic jets focusing on multiple independent acceleration zones [39], or we studied primarily the lepton-induced mechanisms investigating the dependence on the jet parameterization [40]. In both cases, priority was given only to the multi-wavelength photon emission from X-ray binary systems and not the production of neutrinos, which is included in this work.…”

Section: Model Calculations For the Astrophysical Outflows From X-ray...mentioning

confidence: 99%

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

Kosmas,

Papavasileiou,

Kosmas

2023

Universe

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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.

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

Rarras,

Kosmas,

Papavasileiou

et al. 2024

Particles

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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 RISCO parameter, assumed to be the inner radius of the accretion disk, which determines its optical depth τdisk. In our results, the differential photon fluxes after the absorption effect are depicted as a function of the photon energy in the range 1GeV ≤E≤103GeV. It is worth noting that when the black holes’ spin (α*) increases, the differential photon flux becomes significantly lower.

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Prediction of gamma-ray emission from Cygnus X-1, SS 433, and GRS 1915+105 after absorption

Cited by 6 publications

References 61 publications

Studying the Spectral Energy Distributions Emanating from Regular Galactic XRBs

Studying the Spectral Energy Distributions Emanating from Regular Galactic XRBs

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

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

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