The impact of gas accretion and AGN feedback on the scatter of the mass-metallicity relation

TL;DR

This study investigates the causes of scatter in the galaxy mass-metallicity relation, highlighting the roles of gas accretion, halo mass, and AGN feedback across different galaxy mass regimes.

Contribution

It provides new insights into how gas accretion and AGN feedback influence metallicity scatter, especially linking halo mass to metallicity variations in low-mass galaxies.

Findings

Gas mass and metallicity are anti-correlated in low-mass galaxies.

Halo mass correlates with metallicity offset in low-mass galaxies.

AGN activity may influence metallicity scatter in high-mass galaxies.

Abstract

The gas-phase metallicity of galaxies encodes important information about galaxy evolution processes, in particular star formation, feedback, outflows and gas accretion, the relative importance of which can be extracted from systematic trends in the scatter of the mass-metallicity relation (MZR). Here, we use a sample of low redshift (0.02 < z < 0.055) galaxies from SDSS to investigate the nature of the scatter around the MZR, the observables and physical processes causing it, and its dependence on galaxy mass. We use cold gas masses inferred from optical emission lines using the technique of Scholte & Saintonge (2023) to confirm that at fixed stellar mass, metallicity and gas mass are anti-correlated, but only for galaxies up to M*= 10^{10.5} Msun. In that mass regime, we find a link between the offset of a galaxy from the MZR and halo mass, using the amplitude of the two-point correlation function as a proxy for halo mass; at fixed stellar mass, the most gas-poor galaxies reside in the most massive halos. This observation is consistent with changes in gas accretion rates onto galaxies as a function of halo mass, with environmental effects acting on satellite galaxies also contributing. At higher stellar masses, the scatter of the MZR does no longer correlate with gas or halo mass. Instead, there is some indication of a link with AGN activity, as expected from models and simulations that metallicity is set by the interplay between gas in- and outflows, star formation, and AGN feedback, shaping the MZR and its scatter.