Ionized Gas Outflows in Low Excitation Radio Galaxies Are Radiation Driven

TL;DR

This study investigates ionized gas outflows in low excitation radio galaxies (LERGs), finding they are likely driven by radiation pressure from the accretion disk rather than jets, with implications for galaxy feedback processes.

Contribution

It provides the first evidence that ionized outflows in LERGs are driven by radiation pressure, not jets, and characterizes their properties and potential impact on galaxy evolution.

Findings

Ionized outflows are present in about 1.5% of LERGs.

Outflows are associated with higher Eddington-scaled accretion rates (~1%).

Mass outflow rates are higher than in luminous quasars for similar luminosities.

Abstract

Low excitation radio galaxies (LERGs) are weakly accreting active galactic nuclei (AGN) believed to be fuelled by radiatively inefficient accretion processes. Despite this, recent works have shown evidence for ionized and neutral hydrogen gas outflows in these galaxies. To investigate the potential drivers of such outflows we select a sample of 802 LERGs using the Best & Heckman (2012) catalogue of radio galaxies. By modelling the [O III] $\lambda 5007$ profile in Sloan Digital Sky Survey spectra of a sample of 802 LERGs, we determine that the ionized outflows are present in $\sim 1.5\%$ of the population. Using $1.4~\text{GHz}$ imaging from the Faint Images of the Radio Sky at Twenty Centimeters survey we analyze the radio morphology of LERGs with outflows and find these to be consistent with the parent LERG population. However, we note that unlike the majority of the LERG population, those LERGs showing outflows have Eddington scaled accretion rates close to $1\%$. This is indicative that ionized outflows in LERGs are driven by the radiation pressure from the accretion disk of the AGN rather than the radio jets. We report specific star formation rates in the range of $10^{-12} < \text{sSFR} < 10^{-9}~\text{yr}^{-1}$. Moreover, we observe higher mass outflow rates of $7-150~M_{\odot}~\text{yr}^{-1}$ for these LERGs than luminous quasars for a given bolometric luminosity, which could possibly be due to the radio source in LERGs boosting the mass-loading. This scenario could indicate that these outflows could potentially drive feedback in LERGs.