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Self‐consistent Thermal Accretion Disk Corona Models for Compact Objects. II. Application to Cygnus X‐1

James B. DoveJILA, University of Colorado and National Institute of Standards and Technology, Campus Box 440, Boulder, CO 80309-0440; and Department of Astrophysical, Planetary, and Atmospheric Sciences, University of Colorado, Boulder, Boulder, CO 80309-0391J. WilmsAlso JILA, University of Colorado and National Institute of Standards and TechnologyM. MaisackInstitut für Astronomie und Astrophysik, Abteilung Astronomie, Waldhäuser Straße 64, D-72076 Tübingen, GermanyMitchell C. BegelmanJILA, University of Colorado and National Institute of Standards and Technology, Campus Box 440, Boulder, CO 80309-0440
1997en
ABI

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We apply our self-consistent accretion disk corona (ADC) model, with two different geometries, to the broad-band X-ray spectrum of the black hole candidate Cygnus X-1. As shown in a companion paper (Dove, Wilms, and Begelman), models where the Comptonizing medium is a slab surrounding the cold accretion disk cannot have a temperature higher than about 120 keV for optical depths greater than 0.2, resulting in spectra that are much softer than the observed 10-30 keV spectrum of Cyg X-1. In addition, the slab geometry models predict a substantial ``soft excess'' at low energies, a feature not observed for Cyg X-1, and Fe K\alpha fluorescence lines that are stronger than observed. Previous Comptonization models in the literature invoke a slab geometry with the optical depth \tau_T \gta 0.3 and the coronal temperature T_c \sim 150 keV, but they are not self-consistent. Therefore, ADC models with a slab geometry are not appropriate for explaining the X-ray spectrum of Cyg X-1. Models with a spherical corona and an exterior disk, however, predict much higher self-consistent coronal temperatures than the slab geometry models. The higher coronal temperatures are due to the lower amount of reprocessing of coronal radiation in the accretion disk, giving rise to a lower Compton cooling rate. Therefore, for the sphere+disk geometry, the predicted spectrum can be hard enough to describe the observed X-ray continuum of Cyg X-1 while predicting Fe fluorescence lines having an equivalent width of \sim 40 eV. Our best-fit parameter values for the sphere+disk geometry are \tau_T \approx 1.5 and T_c \approx 90 keV.

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