Shadowing of the Nascent Jet in NGC 4261 by a Line-Emitting Supersonic Accretion Disk

NGC 4261 (3C 270) is a low-luminosity radio galaxy with two symmetric kiloparsec-scale jets. Earlier Hubble Space Telescope observations indicated the presence of a hundred-parsec scale disk of cool dust and gas surrounding a central, supermassive (\sim 4.9\times 10^8\msun) black hole. The recent detection of free-free radio absorption by a small, geometrically-thin disk, combined with earlier studies of the disk's large scale properties, provide the strictest constraints to date on the nature of the accretion process in this system. We show here that a supersonic disk, illuminated by the active galactic nucleus (AGN), can not only account for the observed radio shadowing, but can also produce the optical broad lines emitted from this region. Beyond a critical radius $r_c$, line cooling dominates over gravitational dissipation and the gas is effectively cooled down to temperatures below $10^4$ K. Within $r_c$, however, heating due to the release of gravitational energy overwhelms line cooling and the plasma is heated very quickly to a temperature close to its virial value as it falls toward the central engine. The disk is optically-thin to UV and X-ray radiation within $r_c$, so the ionizing radiation from the AGN is preferentially absorbed near $r_c$, affecting the disk structure significantly. To include the ensuing photoionization effect, we have used the algorithm Cloudy with additional heating introduced by gravitational dissipation to calculate the temperature profile and line emission from the disk in a self-consistent manner. The results of our model calculation are consistent with current multiwavelength observations of the disk in this source.Comment: 28 pages, 9 figures. To appear in Ap