Chemical Evolution Models for Spiral Disks: the Milky Way, M31 and M33

TL;DR

This study uses a chemical evolution model to analyze how star formation efficiency and gas density thresholds influence the chemical gradients and evolution of spiral galaxy disks like the Milky Way, M31, and M33.

Contribution

It introduces a scaled one-infall model to reproduce observed chemical gradients and their evolution in multiple spiral galaxies, highlighting the impact of star formation parameters.

Findings

Radial oxygen abundance gradients are more sensitive to gas density thresholds.

Temporal evolution of gradients depends on star formation efficiency.

More massive disks evolve faster, indicating downsizing in star formation.

Abstract

The distribution of chemical abundances and their variation in time are important tools to understand the chemical evolution of galaxies: in particular, the study of chemical evolution models can improve our understanding of the basic assumptions made for modelling our Galaxy and other spirals. To test a standard chemical evolution model for spiral disks in the Local Universe and study the influence of a threshold gas density and different efficiencies in the star formation rate (SFR) law on radial gradients (abundance, gas and SFR). We adopt a one-infall chemical evolution model where the Galactic disk forms inside-out by means of infall of gas, and we test different thresholds and efficiencies in the SFR. The model is scaled to the disk properties of three Local Group galaxies (the Milky Way, M31 and M33) by varying its dependence on the star formation efficiency and the time scale for the infalling gas into the disk. Using this simple model we are able to reproduce most of the observed constraints available in the literature for the studied galaxies. The radial oxygen abundance gradients and their time evolution are studied in detail. The present day abundance gradients are more sensitive to the threshold than to other parameters, while their temporal evolutions are more dependent on the chosen SFR efficiency. The most massive disks seem to have evolved faster (i.e. with more efficient star formation) than the less massive ones, thus suggesting a downsizing in star formation for spirals. The threshold and the efficiency of star formation play a very important role in the chemical evolution of spiral disks and an efficiency varying with radius can be used to regulate the star formation. The oxygen abundance gradient can steepen or flatten in time depending on the choice of this parameter