http://arxiv.org/abs/1609.09322
Black holes surrounded by accretion disks are present in the Universe in different scales of masses, from microquasars up to the Active Galactic Nuclei. The current picture of the accretion disk theory remains still ad hoc, due the complexity of the magnetic field action. In addition, the accretion disks at high Eddington rates can be radiation-pressure dominated and, according to some of the heating prescriptions, thermally unstable. The observational verification of their resulting variability patterns may shed the light on both the role of radiation pressure and magnetic field in the accretion process. We compute the structure and time evolution of an accretion disk. We supplement this model with a modified viscosity prescription, which can to some extent describe the magnetization of the disk. We study the results for a large grid of models and derive conclusions separately for different scales of black hole masses. We show the dependences between the flare, or outburst, duration, its amplitude and period, on the accretion rate and viscosity scaling. We present the results for the three grids of models, designed for different black hole systems. We show that if the heating rate in the accretion disk grows more rapidly with the total pressure and temperature, the instability results in the longer, and sharper flares. In general, we find that the disks around the supermassive black holes are more radiation-pressure dominated and present relatively brighter bursts. Our method can also be used as an independent tool for the black hole mass determination, which we confront now for the intermediate black hole in the source HLX-1. For both the microquasars and Ultraluminous X-ray sources, we reproduce their observed lighcurves. We also compare the duration times of the model outbursts with the ages and bolometric luminosities of AGN.
M. Grzedzielski, A. Janiuk, B. Czerny, et. al.
Fri, 30 Sep 16
44/75
Comments: 15 pages, 23 figures
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