Direct evidence of AGN-feedback: a post starburst galaxy stripped of its gas by AGN-driven winds

TL;DR

This study provides direct spatially-resolved evidence of AGN-driven winds in a post starburst galaxy, demonstrating how AGN feedback can rapidly expel gas and quench star formation.

Contribution

First detailed spatial analysis of AGN-driven winds in a post starburst galaxy, linking gas outflows to AGN activity and galaxy quenching.

Findings

Gas outflows extend up to 17 kpc from the galaxy.

Mass outflow rate is approximately 24 solar masses per year.

The outflowing gas mass exceeds the galaxy's remaining gas mass.

Abstract

Post starburst E+A galaxies show indications of a powerful starburst that was quenched abruptly. Their disturbed, bulge-dominated morphologies suggest that they are merger remnants. The more massive E+A galaxies are suggested to be quenched by AGN feedback, yet little is known about AGN-driven winds in this short-lived phase. We present spatially-resolved IFU spectroscopy by the Keck Cosmic Web Imager of SDSS J003443.68+251020.9, at z=0.118. The system consists of two galaxies, the larger of which is a post starburst E+A galaxy hosting an AGN. Our modelling suggests a 400 Myrs starburst, with a peak star formation rate of 120 Msun/yr. The observations reveal stationary and outflowing gas, photoionized by the central AGN. We detect gas outflows to a distance of 17 kpc from the central galaxy, far beyond the region of the stars (about 3 kpc), inside a conic structure with an opening angle of 70 degrees. We construct self-consistent photoionization and dynamical models for the different gas components and show that the gas outside the galaxy forms a continuous flow, with a mass outflow rate of about 24 Msun/yr. The gas mass in the flow, roughly $10^9$ Msun, is larger than the total gas mass within the galaxy, some of which is outflowing too. The continuity of the flow puts a lower limit of 60 Myrs on the duration of the AGN feedback. Such AGN are capable of removing, in a single episode, most of the gas from their host galaxies and expelling enriched material into the surrounding CGM.