Galaxy formation and evolution

Cooling, Gravity and Geometry: Flow-driven Massive Core Formation

ArXiv 0709.2451 (2007)

Authors:

Fabian Heitsch, Lee Hartmann, Adrianne D Slyz, Julien EG Devriendt, Andreas Burkert

Abstract:

We study numerically the formation of molecular clouds in large-scale colliding flows including self-gravity. The models emphasize the competition between the effects of gravity on global and local scales in an isolated cloud. Global gravity builds up large-scale filaments, while local gravity -- triggered by a combination of strong thermal and dynamical instabilities -- causes cores to form. The dynamical instabilities give rise to a local focusing of the colliding flows, facilitating the rapid formation of massive protostellar cores of a few 100 M$_\odot$. The forming clouds do not reach an equilibrium state, though the motions within the clouds appear comparable to ``virial''. The self-similar core mass distributions derived from models with and without self-gravity indicate that the core mass distribution is set very early on during the cloud formation process, predominantly by a combination of thermal and dynamical instabilities rather than by self-gravity.

Cooling, Gravity and Geometry: Flow-driven Massive Core Formation

(2007)

Authors:

Fabian Heitsch, Lee Hartmann, Adrianne D Slyz, Julien EG Devriendt, Andreas Burkert

The central parsecs of Centaurus A: High Excitation Gas, a Molecular Disk, and the Mass of the Black Hole

(2007)

Authors:

N Neumayer, M Cappellari, J Reunanen, H-W Rix, PP van der Werf, PT de Zeeuw, RI Davies

Recent Star Formation in Nearby Early-type Galaxies

(2007)

Authors:

M Sarzi, R Bacon, M Cappellari, RL Davies, E Emsellem, J Falcon-Barroso, D Krajnovic, H Kuntschner, RM McDermid, RF Peletier, T de Zeeuw, G van de Ven

Low accretion rates at the AGN cosmic downsizing epoch

ArXiv 0709.0786 (2007)

Authors:

A Babic, L Miller, MJ Jarvis, TJ Turner, DM Alexander, SM Croom

Abstract:

Context: X-ray surveys of Active Galactic Nuclei (AGN) indicate `cosmic downsizing', with the comoving number density of high-luminosity objects peaking at higher redshifts (z about 2) than low-luminosity AGN (z<1). Aims: We test whether downsizing is caused by activity shifting towards low-mass black holes accreting at near-Eddington rates, or by a change in the average rate of accretion onto supermassive black holes. We estimate the black hole masses and Eddington ratios of an X-ray selected sample of AGN in the Chandra Deep Field South at z<1, probing the epoch where AGN cosmic downsizing has been reported. Methods: Black hole masses are estimated both from host galaxy stellar masses, which are estimated from fitting to published optical and near-infrared photometry, and from near-infrared luminosities, applying established correlations between black hole mass and host galaxy properties. Both methods give consistent results. Comparison and calibration of possible redshift-dependent effects is also made using published faint host galaxy velocity dispersion measurements. Results: The Eddington ratios in our sample span the range 10^{-5} to 1, with median log(L_bol/L_Edd)=-2.87, and with typical black hole masses about 10^{8} solar masses. The broad distribution of Eddington ratios is consistent with that expected for AGN samples at low and moderate luminosity. We find no evidence that the CDF-S AGN population is dominated by low-mass black holes accreting at near-Eddington ratios and the results suggest that diminishing accretion rates onto average-sized black holes are responsible for the reported AGN downsizing at redshifts below unity.