Magnetic Flares and the Observed Optical Depth in Seyfert Galaxies
arXiv:astro-ph/9705255 · doi:10.1086/310998
Abstract
We here consider the pressure equilibrium during an intense magnetic flare above the surface of a cold accretion disk. Under the assumption that the heating source for the plasma trapped within the flaring region is an influx of energy transported inwards with a group velocity close to $c$, e.g., by magnetohydrodynamic waves, this pressure equilibrium can constrain the Thomson optical depth $Ï_T$ to be of order unity. We suggest that this may be the reason why $Ï_T\sim 1$ in Seyfert Galaxies. We also consider whether current data can distinguish between the spectrum produced by a single X-ray emitting region with $Ï_T\sim 1$ and that formed by many different flares spanning a range of $Ï_T$. We find that the current observations do not yet have the required energy resolution to permit such a differentiation. Thus, it is possible that the entire X-ray/$γ$-ray spectrum of Seyfert Galaxies is produced by many independent magnetic flares with an optical depth $0.5<Ï_T<2$.
submitted to ApJL, 6 pages, 1 figure, uses aas2pp4.sty