Bubbles, Jets and Clouds in Active Galactic Nuclei
M. D. Smith, L. Smarr, M. L. Norman, and J. R. Wilson, Astrophysical Journal, 264, 432-445 (1983).
Abstract
The Blandford and Rees 1974 fluid twin-exhaust model for jet formation is thoroughly investigated. We perform detailed analytic calculations of all aspects of the cavity-nozzle structures for the nonrelativistic case: the preshock flow, the central shock, cavity flow, and the nozzle. Our analytic results are in excellent agreement with recent sophisticated numerical calculations. We find that for a given central confining gas cloud, only a finite range of jet powers is possible. The sound speed ratio between cavity and cloud must be less than 30. Central masses of – 109 M0 within I pc are necessary for high-powered (1046 ergs s- 1) extragalactic jets. For a fixed confining cloud sound speed C0, there are three regimes determined by the central engine’s luminosity. For low luminosity, a stream of bubbles emerges; for a middle range of luminosities, a jet forms; for too high a luminosity, large clouds are emitted. In the jet regime, we find that L1 – CJ. The critical dependence of jet power on confining cloud sound speed enables a schematic picture for active galactic nuclei to be proposed. Seyfert galaxies and quasars are placed in the bubble regime. Variable compact radio sources reach the cloud regime. Evolutionary paths are suggested and may provide an indirect test for this picture.