You Shall Not Pass! The propagation of low/moderate powered jets through a turbulent interstellar medium

TL;DR

This study uses simulations to explore how low and intermediate power jets from black holes interact with turbulent interstellar media, revealing different propagation behaviors and their effects on galaxy environments.

Contribution

The paper provides new insights into jet-ISM interactions at low and intermediate powers, highlighting conditions under which jets influence their host galaxies.

Findings

Jets can easily penetrate, stall, or become disturbed in the ISM.

Low-power jets can drive outflows in hot gas phases.

Warm ionized outflows occur under specific conditions.

Abstract

Feedback from black hole-powered jets has been invoked in many cosmological simulations to regulate star formation and quench galaxies. Despite this, observational evidence of how jets might be able to affect their hosts remains scarce, especially for low power jets in halos smaller than clusters. Recent observations of outflows around FR0 galaxies, that host compact radio-loud sources, imply that lower-power jetted active galactic nuclei (AGN) may have a significant impact on their hosts through jet interactions with the interstellar medium (ISM). Using the Arepo code, we launch jets of low and intermediate power (10$^{38}$ - 10$^{43}$ erg s$^{-1}$) within a ~kpc-scale periodic box with driven turbulence to study how the jets propagate through a turbulent ISM. Our simulation results broadly fit into three different scenarios $\unicode{x2013}$ jets penetrating easily through the ISM, becoming completely stalled, or the interesting intermediate stage, when jets are highly disturbed and redirected. We suggest that intermediate power jets do not have enough ram pressure to affect the turbulent structure of the ISM, and so only fill pre-existing cavities. Low-power jets are able to drive outflows in a hot phase ($>10^{4.4}$ K). However, warm (~$10^4$ K) ionized gas outflows appear under certain conditions. This work is part of the ''Learning the Universe'' collaboration, aiming to build next-generation cosmological simulations that incorporate a new prescription for AGN feedback.