Efficient early stellar feedback can suppress galactic outflows by reducing supernova clustering

TL;DR

This paper introduces advanced stellar feedback models in galaxy simulations, showing that early feedback like photoionization can suppress supernova clustering and outflows, affecting star formation regulation.

Contribution

The study develops and tests new feedback models that explicitly include individual massive stars and their effects, revealing the impact of early feedback on supernova clustering and galactic outflows.

Findings

Photoionization and supernova feedback independently regulate star formation.

Photoionization smooths star formation history compared to supernovae.

Combined feedback slightly suppresses star formation but significantly reduces outflows.

Abstract

We present a novel set of stellar feedback models, implemented in the moving-mesh code Arepo, designed for galaxy formation simulations with near-parsec (or better) resolution. These include explicit sampling of stars from the IMF, allowing feedback to be linked to individual massive stars, an improved method for the modelling of H II regions, photoelectric heating from a spatially varying FUV field and supernova feedback. We perform a suite of 32 simulations of isolated $M_\mathrm{vir} = 10^{10}\,\mathrm{M_\odot}$ galaxies with a baryonic mass resolution of $20\,\mathrm{M_\odot}$ in order to study the non-linear coupling of the different feedback channels. We find that photoionization and supernova feedback are both independently capable of regulating star formation to the same level, while photoelectric heating is inefficient. Photoionization produces a considerably smoother star formation history than supernovae. When all feedback channels are combined, the additional suppression of star formation rates is minor. However, outflow rates are substantially reduced relative to the supernova only simulations. We show that this is directly caused by a suppression of supernova clustering by the photoionization feedback, disrupting star forming clouds prior to the first supernovae. We demonstrate that our results are robust to variations of our star formation prescription, feedback models and the gas fraction of the disk. Our results also imply that the burstiness of star formation and the mass loading of outflows may be overestimated if the adopted star particle mass is considerably larger than the mass of individual stars because this imposes a minimum cluster size.