QSOFEED: The relationship between star formation and AGN Feedback

TL;DR

This study investigates the impact of AGN-driven outflows on star formation in low-redshift quasars, finding that outflows do not significantly suppress star formation on the scales and timescales examined.

Contribution

It provides direct observational evidence linking AGN outflows, radio luminosity, and star formation, highlighting that outflows do not significantly affect star formation in the studied sample.

Findings

85% of QSO2s show gas outflows exceeding stellar velocity dispersions.

No correlation between outflow properties and star formation rates.

Positive correlation between stellar ages and black hole mass.

Abstract

Large-scale cosmological simulations suggest that feedback from active galactic nuclei (AGN) plays a crucial role in galaxy evolution. In this study, we directly test this hypothesis utilising SDSS spectra of a sample of 48 low redshift (z<0.14) type 2 quasars (QSO2s). We characterised the kinematics of the warm ionised gas by performing a non-parametric analysis of the [OIII]$\lambda 5007$ emission line, as well as constrain the properties of the young stellar populations (YSP) of their host galaxies through spectral synthesis modelling. These analyses revealed that 85% of the QSO2s display gas velocity dispersions larger than that of the stellar component of their host galaxies, indicating the presence of AGN-driven outflows. Comparing the gas kinematics to the AGN properties, we found a positive correlation between gas velocity dispersion and 1.4 GHz radio luminosity but not with AGN bolometric luminosity or Eddington ratio, suggesting that, either the radio luminosity is the key factor in driving outflows or that the outflows themselves are shocking the ISM and producing synchrotron emission. We found that 98% of the sample host YSPs to varying degrees, with star formation rates (SFR) $0 \le SFR \le 92 \mbox{ M}_{\odot} \mbox{yr}^{-1}$, averaged over 100 Myr. We compared the gas kinematics and outflow properties to the SFRs to establish possible correlations which may suggest that the presence of the outflowing gas is impacting SF and find that none exists, leading to the conclusion that, on the scales probed by the SDSS fibre, AGN-driven outflows do not impact SF on the timescales probed in this study. However, we found a positive correlation between the light-weighted stellar ages of the QSO2s and the black hole mass, which may indicate that successive AGN episodes lead to the suppression of SF over the course of galaxy evolution.