An ALMA CO(1-0) survey of the 2Jy sample: large and massive molecular disks in radio AGN host galaxies

TL;DR

This study uses ALMA CO(1-0) observations to reveal large, massive molecular disks in radio AGN host galaxies, suggesting mergers or gas cooling as triggers for AGN activity.

Contribution

It provides the first systematic ALMA survey of molecular gas in a complete sample of powerful radio AGN, highlighting the prevalence of large, rotating molecular disks.

Findings

34% detection rate of large molecular gas reservoirs in host galaxies

Most molecular gas is in rotating disk structures up to 25 kpc in size

Molecular gas properties suggest merger activity or gas cooling as AGN triggers

Abstract

The jets of radio AGN provide one of the most important forms of AGN feedback, yet considerable uncertainties remain about how they are triggered. Since the molecular gas reservoirs of the host galaxies can supply key information about the dominant triggering mechanism(s), here we present Atacama Large Millimeter/sub-millimeter Array (ALMA) CO(1-0) observations of a complete sample of 29 powerful radio AGN ($P_{1.4GHz} > 10^{25}$ W Hz$^{-1}$ and $0.05 < z < 0.3$) with an angular resolution of about 2 - 3 arcsec (corresponding to 2 - 8 kpc). We detect molecular gas with masses in the range $10^{8.9} < M_{H_2} < 10^{10.2}$ M$_{\odot}$ in the early-type host galaxies of 10 targets, while for the other 19 sources we derive upper limits. The detection rate of objects with such large molecular masses -- $34\pm9$% -- is higher than in the general population of non-active early-type galaxies (ETG: $<$10%). The kinematics of the molecular gas are dominated in most cases by rotating disk-like structures, with diameters up to 25 kpc. Compared with the results for samples of quiescent ETG in the literature, we find a larger fraction of more massive, more extended and less settled molecular gas structures. In most of the CO-detected sources, the results are consistent with triggering of the AGN as the gas settles following a merger or close encounter with a gas-rich companion. However, in a minority of objects at the centres of rich clusters of galaxies, the accretion of gas cooling from the hot X-ray halos is a plausible alternative to galaxy interactions as a triggering mechanisms.