1995
DOI: 10.1086/175897
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The Inverse Compton Thermostat in Hot Plasmas near Accreting Black Holes

Abstract: The X-ray spectra of accreting black hole systems generally contain components (sometimes dominating the total emission) which are well-fit by thermal Comptonization models with temperatures ∼ 100 keV. We demonstrate why, over many orders of magnitude in heating rate and seed photon supply, hot plasmas radiate primarily by inverse Compton scattering, and find equilibrium temperatures within a factor of a few of 100 keV. We also determine quantitatively the (wide) bounds on heating rate and seed photon supply f… Show more

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Cited by 44 publications
(51 citation statements)
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“…The PLI of the Comptonized component is a function of the temperature and optical depth of the Comptonizing plasma. Pietrini & Krolik (1995) have modeled coronae above the disk and found that, for accretion rates much less than Eddington, the halo temperature is nearly constant at a value of about kT ¼ 100 keV even as the accretion rate varies by up to 4 orders of magnitude. A similar result was found by Chakrabarti & Titarchuk (1995), but the hot region was a shocked plasma, originating from a sub-Keplerian flow and occupying the radially innermost part of the accretion flow.…”
Section: Correlating Photon Flux and Derived Halo Depthmentioning
confidence: 99%
“…The PLI of the Comptonized component is a function of the temperature and optical depth of the Comptonizing plasma. Pietrini & Krolik (1995) have modeled coronae above the disk and found that, for accretion rates much less than Eddington, the halo temperature is nearly constant at a value of about kT ¼ 100 keV even as the accretion rate varies by up to 4 orders of magnitude. A similar result was found by Chakrabarti & Titarchuk (1995), but the hot region was a shocked plasma, originating from a sub-Keplerian flow and occupying the radially innermost part of the accretion flow.…”
Section: Correlating Photon Flux and Derived Halo Depthmentioning
confidence: 99%
“…Generally, the feedback consists of reprocessing of radiation from the hot phase by the cool phase, which increases the luminosity of the cool phase, as well as pair creation in the hot phase which alters the optical depth. Pietrini & Krolik (1995) Ðnd that the plasma parameters can be described by two scaling laws that are weak functions of the ratio of hard and soft luminosity :…”
Section: T Hermal Comptonizationmentioning
confidence: 99%
“…We recall that the optical depth does not appear explicitly but is related to the temperature by the balance equation for the corona (see also Pietrini and Krolik 1995). Values of T C in the range 30-300 keV, as suggested by observations (Maisak et al 1993, Johnson et al 1993, Madejski et al 1995, correspond to optical depths between 1 and 0.1.…”
Section: Diagnostics Of Coronal Models: Broad Band X-ray Variabilitymentioning
confidence: 94%