Visit ASIAA Homepage Registration Deadline: February 15, 2016 (Taiwan Time)
M87 Workshop: Towards the 100th Anniversary of the Discovery of Cosmic Jets
May 23(Mon)-27(Fri), 2016
Taipei, Taiwan

Invited Presentation

Stimulated AGN Feedback in Massive Galaxies

Author(s): Brian McNamara (University of Waterloo)

Presenter: Brian Mcnamara (University of Waterloo)

Observation shows that cooling instabilities leading to nebular emission, molecular gas, and star formation in giant galaxies are formed behind buoyantly rising X-ray bubbles inflated by radio jets launched from massive nuclear black holes. We propose a model where molecular clouds condense from hot but relatively low entropy gas lifted by X-ray bubbles to an altitude where its cooling time is shorter than the time required for it to fall to its equilibrium location in the galaxy i.e., t_c/t_I <~1$. Here the infall time is can exceed the free-fall time, t_ff, by factors of a few, limited by the terminal speed of a cooling parcel. This mechanism, which we refer to as stimulated feedback, is motivated by recent ALMA observations of central galaxies in clusters and groups revealing molecular clouds apparently forming in the wakes of rising X-ray bubbles and with surprisingly low cloud velocities. Supported by recent numerical simulations, our model would naturally sustain a continual feedback-loop in galaxies fuelled by cooling gas stimulated by radio-mechanical feedback itself, that otherwise stabilizes cooling atmospheres on larger scales. The observed cooling time threshold for the onset of nebular emission and star formation of ~ 5x10^8 yr may result from the limited ability of radio bubbles to lift low entropy gas to an altitude where thermal instabilities can ensue. The molecular clouds condensing from the outflowing hot gas are unlikely to escape, but instead return to the central galaxy in a circulating flow.

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