The duty cycle of radio-mode feedback in complete samples of clusters

TL;DR

This study investigates the frequency and impact of AGN-driven bubbles in galaxy clusters, revealing a high duty cycle of radio-mode feedback that likely plays a crucial role in regulating cooling flows and galaxy evolution.

Contribution

It provides the first comprehensive estimates of the duty cycle of AGN outbursts in galaxy clusters using complete samples and simulations, indicating near-continuous feedback activity.

Findings

Radio luminosity correlates with cooling flow clusters.

Duty cycle of AGN feedback exceeds 60%.

Most undetected bubbles could still have significant power.

Abstract

The Chandra X-ray Observatory has revealed X-ray bubbles in the intracluster medium (ICM) of many nearby cooling flow clusters. The bubbles trace feedback that is thought to couple the central active galactic nucleus (AGN) to the ICM, helping to stabilize cooling flows and govern the evolution of massive galaxies. However, the prevalence and duty cycle of such AGN outbursts is not well understood. To this end, we study how cooling is balanced by bubble heating for complete samples of clusters (the Brightest 55 clusters of galaxies, hereafter B55, and the HIghest X-ray FLUx Galaxy Cluster Sample, HIFLUGCS). We find that the radio luminosity of the central galaxy only exceeds 2.5 x 10^30 erg s^-1 Hz^-1 in cooling flow clusters. This result implies a connection between the central radio source and the ICM, as expected if AGN feedback is operating. Additionally, we find a duty cycle for radio mode feedback, the fraction of time that a system possesses bubbles inflated by its central radio source, of > 69 per cent for B55 and > 63 per cent for HIFLUGCS. These duty cycles are lower limits since some bubbles are likely missed in existing images. We used simulations to constrain the bubble power that might be present and remain undetected in the cooling flow systems without detected bubbles. Among theses systems, almost all could have significant bubble power. Therefore, our results imply that the duty cycle of AGN outbursts with the potential to heat the gas significantly in cooling flow clusters is at least 60 per cent and could approach 100 per cent.