AGN feedback: galactic-scale outflows driven by radiation pressure on dust

TL;DR

This paper investigates how radiation pressure on dust can drive galaxy-scale outflows from AGNs, explaining observed high-velocity winds and their momentum flux, and considers the impact of AGN variability on these measurements.

Contribution

It demonstrates that radiation trapping can produce high-velocity outflows with large momentum flux, offering a physical mechanism for observed galactic winds driven by AGNs.

Findings

High-velocity outflows (>1000 km/s) can be driven by radiation pressure on dust.

Momentum fluxes exceeding 10 L/c are achievable with radiation trapping.

Observed powerful outflows may be relics of past AGN activity, not ongoing.

Abstract

Galaxy-scale outflows, which are thought to provide the link connecting the central black hole to its host galaxy, are now starting to be observed. However, the physical origin of the mechanism driving the observed outflows, whether due to energy-driving or radiation-driving, is still debated; and in some cases, it is not clear whether the central source is an active galactic nucleus (AGN) or a nuclear starburst. Here we study the role of radiation pressure on dust in driving galactic-scale AGN outflows, and analyse the dynamics of the outflowing shell as a function of the underlying physical parameters. We show that high-velocity outflows ($\gtrsim$1000 km/s) with large momentum flux ($\gtrsim 10 L/c$) can be obtained, by taking into account the effects of radiation trapping. In particular, the high observed values of the momentum boosts can be reproduced, provided that the shell is initially optically thick to the reprocessed infrared radiation. Alternatively, the inferred measurements of the momentum flux may be significantly biased by AGN variability. In this context, the observations of powerful outflows on kiloparsec scales, with no or weak signs of ongoing nuclear activity at the present time, could be re-interpreted as relics of past AGN episodes.