English

Simple models of cooling flows

Astrophysics 2009-11-07 v2

Abstract

A semi-analytic model of cluster cooling flows is presented. The model assumes that episodic nuclear activity followed by radiative cooling without mass-dropout cycles the cluster gas between a relatively homogeneous, nearly isothermal post-outburst state and a cuspy configuration in which a cooling catastrophe initiates the next nuclear outburst. Fitting the model to Chandra data for the Hydra cluster, a lower limit of 284\Myr284\Myr until the next outburst of Hydra A is derived. Density, temperature and emission-measure profiles at several times prior to the cooling catastrophe are presented. It proves possible to fit the mass M(σ)M(\sigma) with entropy index PργP\rho^{-\gamma} less than σ\sigma to a simple power-law form, which is almost invariant as the cluster cools. We show that radiative cooling automatically establishes this power-law form if the entropy index was constant throughout the cluster gas at some early epoch or after an AGN activity cycle. To high precision, the central value of σ\sigma decreases linearly in time. The fraction of clusters in a magnitude-limited sample that have gas cooler than TT is calculated, and is shown to be small for T=2\keVT=2\keV. Similarly, only 1 percent of clusters in such a sample contain gas with Pργ<2\keV\cm2P\rho^{-\gamma} < 2\keV\cm^2. Entropy production in shocks is shown to be small. The entropy that is radiated from the cluster can be replaced if a few percent of the cluster gas passes through bubbles heated during an outburst of the AGN.

Keywords

Cite

@article{arxiv.astro-ph/0207111,
  title  = {Simple models of cooling flows},
  author = {Christian R. Kaiser and James J. Binney},
  journal= {arXiv preprint arXiv:astro-ph/0207111},
  year   = {2009}
}

Comments

Accepted for publication by MNRAS, revised version to fit published version, now includes discussion of power-law mass distribution