The environmental dependence of gas accretion onto galaxies: quenching satellites through starvation

TL;DR

This study uses the EAGLE simulation to show that dense environments significantly suppress gas accretion onto satellite galaxies, likely leading to star formation quenching, especially at lower redshifts.

Contribution

It provides a detailed analysis of how environment affects gas accretion onto galaxies, highlighting the role of starvation in galaxy quenching across different conditions.

Findings

Gas accretion is strongly suppressed in dense environments, especially for satellites.

Suppression of accretion increases at lower redshift.

Galaxies in dense environments exhaust their gas faster, leading to quenching.

Abstract

Galaxies that have fallen into massive haloes may no longer be able to accrete gas from their surroundings, a process referred to as 'starvation' or 'strangulation' of satellites. We study the environmental dependence of gas accretion onto galaxies using the cosmological, hydrodynamical EAGLE simulation. We quantify the dependence of gas accretion on stellar mass, redshift, and environment, using halo mass and galaxy overdensity as environmental indicators. We find a strong suppression, by many orders of magnitude, of the gas accretion rate in dense environments, primarily for satellite galaxies. This suppression becomes stronger at lower redshift. However, the scatter in accretion rates is very large for satellites. This is (at least in part) due to the variation in halocentric radius, since gas accretion is more suppressed at smaller radii. Central galaxies are influenced less strongly by their environment and exhibit less scatter in their gas accretion rates. The star formation rates of both centrals and satellites show similar behaviour to their gas accretion rates. The relatively small differences between gas accretion and star formation rates demonstrate that galaxies generally exhaust their gas reservoir somewhat faster at higher stellar mass, lower redshift, and in denser environments. We conclude that the environmental suppression of gas accretion could directly result in the quenching of star formation.