Slow and steady does the trick: Slow outflows enhance the fragmentation of molecular clouds

TL;DR

This study uses simulations to show that slow, warm-hot outflows from active galactic nuclei can compress gas clouds and promote star formation, especially at velocities below 200 km/s, highlighting conditions for positive feedback.

Contribution

It demonstrates through numerical simulations that slow outflows can enhance gas fragmentation and star formation, identifying specific conditions and scenarios for positive feedback in galaxies.

Findings

Warm outflows compress clouds and increase fragmentation at velocities ≤200 km/s.

Hot outflows (10^6 K) promote fragmentation even at higher velocities (~400 km/s).

Cloud acceleration by outflows is generally inefficient, with dense gas reaching less than 10% of outflow velocity.

Abstract

Most massive galaxies host a supermassive black hole at their centre. Matter accretion creates an active galactic nucleus (AGN), forming a relativistic particle wind. The wind heats and pushes the interstellar medium, producing galactic-wide outflows. Fast outflows remove the gas from galaxies and quench star formation, and while slower ($v<500$ km s$^{-1}$) outflows are ubiquitous, their effect is less clear but can be both positive and negative. We wish to understand the conditions required for positive feedback. We investigated the effect that slow and warm-hot outflows have on the dense gas clouds in the host galaxy. We aim to constrain the region of outflow and cloud parameter space, if any, where the passage of the outflow enhances star formation. We used numerical simulations of virtual `wind tunnels' to investigate the interaction of isolated turbulent spherical clouds ($10^{3;4;5}$ M$_{\odot}$) with slow outflows ($10$ km s$^{-1} - 400$ km s$^{-1}$) spanning a wide range of temperatures ($10^{4;5;6}$ K). We find that warm outflows compress the clouds and enhance gas fragmentation at velocities ${\leq}200$ km s$^{-1}$, while hot ($T_{\rm out} = 10^6$ K) outflows increase fragmentation rates even at moderate velocities of $400$ km s$^{-1}$. Cloud acceleration, on the other hand, is typically inefficient, with dense gas only attaining velocities of ${<}0.1 v_{\rm out}$. We suggest three primary scenarios where positive feedback on star formation is viable: stationary cloud compression by slow outflows in low-powered AGN, sporadic enhancement in shear flow layers formed by luminous AGN, and self-compression in fragmenting AGN-driven outflows. Our results are consistent with current observational constraints and with previous works investigating triggered star formation in these disparate domains.