L-GALAXIES 2020: The evolution of radial metallicity profiles and global metallicities in disc galaxies

TL;DR

This paper introduces a modified semi-analytic galaxy evolution model that better reproduces observed metallicity profiles and relations in disc galaxies by emphasizing direct metal enrichment of the circumgalactic medium from supernovae.

Contribution

The modified L-GALAXIES 2020 model incorporates increased CGM metal enrichment from supernovae without higher mass-loading, improving agreement with observed metallicity profiles and relations.

Findings

Model reproduces observed radial metallicity profiles in nearby disc galaxies.

Massive galaxies have flatter gas-phase metallicity profiles due to inside-out growth.

Lowering SN-II progenitor mass improves profile matches but fails to capture evolution over cosmic time.

Abstract

We present a modified version of the L-GALAXIES 2020 semi-analytic model of galaxy evolution, which includes significantly increased direct metal enrichment of the circumgalactic medium (CGM) by supernovae (SNe). These more metal-rich outflows do not require increased mass-loading factors, in contrast to some other galaxy evolution models. This modified L-GALAXIES 2020 model is able to simultaneously reproduce the gas-phase metallicity $(Z_{\rm g})$ and stellar metallicity $(Z_{*})$ radial profiles observed in nearby disc galaxies by MaNGA and MUSE, as well as the observed mass - metallicity relations for gas and stars at $z=0$ and their evolution back to $z\sim{}2-3$. A direct CGM enrichment fraction of $\sim{}90\%$ for SNe-II is preferred. We find that massive disc galaxies have slightly flatter $Z_{\rm g}$ profiles than their lower-mass counterparts in L-GALAXIES 2020, due to more efficient enrichment of their outskirts via inside-out growth and metal-rich accretion. Such a weak, positive correlation between stellar mass and $Z_{\rm g}$ profile slope is also seen in our MaNGA-DR15 sample of 571 star-forming disc galaxies. Although, below ${\rm log}(M_{*}/{\rm M}_{\odot})\sim{}10.0$ this observational result is strongly dependent on the metallicity diagnostic and morphological selection chosen. In addition, a lowered maximum SN-II progenitor mass of $25{\rm M}_{\odot}$, reflecting recent theoretical and observational estimates, can also provide a good match to observed metallicity profiles at $z=0$ in L-GALAXIES 2020. However, this model version fails to reproduce an evolution in $Z_{\rm g}$ at fixed mass over cosmic time, or the magnesium abundances observed in the intracluster medium (ICM).