Chemical evolution of local galaxies in a hierarchical model

TL;DR

This paper models the chemical evolution of local galaxies within a hierarchical framework, successfully reproducing observed metallicity relations and exploring the impact of star formation, outflows, and initial mass function variations.

Contribution

It introduces a semi-analytic hierarchical galaxy formation model that accounts for chemical enrichment and reproduces key observed relations across galaxy types.

Findings

Reproduces [O-Fe] vs [Fe/H] in Milky Way disc stars.

Matches stellar metallicity vs mass in dwarf galaxies.

Explains [alpha/Fe] trends in ellipticals with variable IMF.

Abstract

We investigate the chemical properties of local galaxies within a cosmological framework in the hierarchical picture of galaxy formation. To this aim, we use a hierarchical semi-analytic model which includes the contribution from (i) low and intermediate mass stars, (ii) type Ia Supernovae (SNe) and (iii) massive stars. - Abridged - We compare our predictions with available observations in the Milky Way (MW), in local dwarf galaxies and in local ellipticals. For Milky-Way-like galaxies, we can successfully reproduce the [O-Fe] vs [Fe/H] relation observed in disc stars and the stellar metallicity distribution (SMD). For dwarf galaxies, the stellar metallicity vs mass relation is reproduced by assuming that a substantial fraction of the heavy elements is lost through metal-enhanced outflows and a type Ia SN realization probability lower than the one of MW-like galaxies. - Abridged - In ellipticals, the observations indicate higher [alpha/Fe] values in larger galaxies. - Abridged - Our results computed with a standard Salpeter initial mass function (IMF) indicate a flat [alpha/Fe]-sigma relation. However, we suggest a possible solution to this problem and show how, by assuming a star formation-dependent IMF with a slope x=1.35 in systems with star formation rates < 100 M_sun/yr and slightly flatter (i.e. with x=1) in object with stronger star formation, the observed correlation between [alpha/Fe] and sigma can be accounted for on a large velocity dispersion range. Fundamental roles are played also by interaction-triggered starbursts and AGN.