Power‐Law Tails from Dynamical Comptonization in Converging Flows

Turolla, R.; Zane, S.; Titarchuk, Lev

doi:10.1086/341631

Cited by 23 publications

(26 citation statements)

References 23 publications

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“…More recently, Meier's (2004) model of Magnetically-Dominated Accretion Flows (MDAF) further develops the idea and integrates accretion and jet production as an extension of the ADAF (Esin et al 1998) and Shakura & Sunyaev (1976) disk models. Non thermal emission may also be associated with Compton scattering off relativistic electrons of free infalling matter onto the black hole in the converging flow region near the event horizon (Chakrabarti & Titarchuk 1995;Turolla et al 2002). Over the years.…”

Section: Resultsmentioning

confidence: 99%

Gamma-Ray Spectral Characteristics of Thermal and Non-Thermal Emission from Three Black Holes

Ling

Wheaton

2005

Chin. J. Astron. Astrophys.

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Cygnus X-1 and the gamma-ray transients GRO J0422+32 and GRO J1719 − 24 displayed similar spectral properties when they underwent transitions between the high and low gamma-ray (30 keV to few MeV) intensity states. When these sources were in the high γ-ray intensity state (γ 2 , for Cygnus X-1), their spectra featured two components: a Comptonized shape below 200-300 keV with a soft power-law tail (photon index >3) that extended to ∼1 MeV or beyond. When the sources were in the low-intensity state (γ 0 , for Cygnus X-1), the Comptonized spectral shape below 200 keVtypically vanished and the entire spectrum from 30 keV to ∼1 MeV can be characterized by a single power law with a relatively harder photon index ∼ 2 − 2.7. Consequently the high-and low-intensity gammaray spectra intersect, generally in the ∼400 keV -∼1 MeV range, in contrast to the spectral pivoting seen previously at lower (∼10 keV) energies. The presence of the power-law component in both the high-and low-intensity gamma-ray spectra strongly suggests that the non-thermal process is likely to be at work in both the high and the low-intensity situations. We have suggested a possible scenario (Ling & Wheaton, 2003), by combining the ADAF model of Esin et al. (1998) with a separate jet region that produces the non-thermal gamma-ray emission, and which explains the state transitions. Such a scenario will be discussed in the context of the observational evidence, summarized above, from the database produced by EBOP, JPL's BATSE earth occultation analysis system.

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Section: Resultsmentioning

confidence: 99%

Gamma-Ray Spectral Characteristics of Thermal and Non-Thermal Emission from Three Black Holes

Ling

Wheaton

2005

Chin. J. Astron. Astrophys.

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“…In the LS, the broad‐band spectrum is well studied, both with simple phenomenological models and with complex detailed physical models (see e.g. Frontera et al 2001; Zdziarski et al 2001; Merloni & Fabian 2002; Turolla et al 2002; Falcke, Körding & Markoff 2004; Malzac, Merloni & Fabian 2004).…”

Section: Discussionmentioning

confidence: 99%

INTEGRAL/RXTE high-energy observation of a state transition of GX 339-4

Belloni

Parolin

Santo³

et al. 2006

Monthly Notices of the Royal Astronomical Society

116

115

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On 2004 August 15, we observed a fast (shorter than 10 h) state transition in the bright black hole transient GX 339–4 simultaneously with Rossi X‐Ray Timing Explorer (RXTE) and INTEGRAL. This transition was evident both in timing and spectral properties. Combining the data from the Proportional Counter Array (PCA), the High‐Energy X‐ray Timing Experiment (HEXTE) and the Imager on Board the INTEGRAL Satellite (IBIS), we obtained good quality broad‐band (3–200 keV) energy spectra before and after the transition. These spectra indicate that the hard component steepened. Also, the high‐energy cut‐off that was present at ∼70 keV before the transition was not detected after the transition. This is the first time that an accurate determination of the broad‐band spectrum across such a transition has been measured on a short time‐scale. It shows that, although some spectral parameters do not change abruptly through the transition, the high‐energy cut‐off increases/disappears rather fast. These results constitute a benchmark on which to test theoretical models for the production of the hard component in these systems.

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“…Figure 9 shows the image of this scattering atmosphere Figure 10. Top: Radial photon luminosity (photons/sec) in arbitrary units vs radius in units of rg for spherical Bondi accretion as in Turolla et al (2002). Four models are shown, corresponding to Eddington-scaled mass accretion rates ofṁ = 10 (red), 10 2 (green), 10 3 (magenta), 10 4 (cyan).…”

Section: Gravitational Redshiftmentioning

confidence: 99%

heroic: 3D general relativistic radiative post-processor with comptonization for black hole accretion discs

Narayan

Zhu

Psaltis

et al. 2016

Mon. Not. R. Astron. Soc.

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We describe HEROIC, an upgraded version of the relativistic radiative postprocessor code HERO described in a previous paper, but which now Includes Comptonization. HEROIC models Comptonization via the Kompaneets equation, using a quadratic approximation for the source function in the short characteristics radiation solver. It employs a simple form of accelerated lambda iteration to handle regions of high scattering opacity. In addition to solving for the radiation field, HEROIC also solves for the gas temperature by applying the condition of radiative equilibrium. We present benchmarks and tests of the Comptonization module in HEROIC with simple 1D and 3D scattering problems. We also test the ability of the code to handle various relativistic effects using model atmospheres and accretion flows in a black hole space-time. We present two applications of HEROIC to general relativistic MHD simulations of accretion discs. One application is to a thin accretion disc around a black hole. We find that the gas below the photosphere in the multi-dimensional HEROIC solution is nearly isothermal, quite different from previous solutions based on 1D plane parallel atmospheres. The second application is to a geometrically thick radiation-dominated accretion disc accreting at 11 times the Eddington rate. The multi-dimensional HEROIC solution shows that, for observers who are on axis and look down the polar funnel, the isotropic equivalent luminosity could be more than ten times the Eddington limit, even though the spectrum might still look thermal and show no signs of relativistic beaming.

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Power‐Law Tails from Dynamical Comptonization in Converging Flows

Cited by 23 publications

References 23 publications

Gamma-Ray Spectral Characteristics of Thermal and Non-Thermal Emission from Three Black Holes

Gamma-Ray Spectral Characteristics of Thermal and Non-Thermal Emission from Three Black Holes

INTEGRAL/RXTE high-energy observation of a state transition of GX 339-4

heroic: 3D general relativistic radiative post-processor with comptonization for black hole accretion discs

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