Ages and metallicities for quiescent galaxies in the Shapley Supercluster: Driving parameters of the stellar populations

TL;DR

This study analyzes how stellar populations in quiescent galaxies depend mainly on velocity dispersion, showing that luminosity-related trends are driven by brightness variations at fixed velocity dispersion, not by stellar mass.

Contribution

It demonstrates that stellar population properties depend primarily on velocity dispersion, with luminosity effects explained by brightness differences at fixed velocity dispersion.

Findings

Stellar populations correlate positively with velocity dispersion.

Luminosity trends are due to brightness at fixed sigma, not stellar mass.

Models show dependence mainly on velocity dispersion, not stellar mass.

Abstract

We use high signal-to-noise spectroscopy for a sample of 232 quiescent galaxies in the Shapley Supercluster, to investigate how their stellar populations depend on velocity dispersion, luminosity and stellar mass. The sample spans a large range in velocity dispersion (sigma from 30-300 km/s) and in luminosity (M_R from -18.7 to -23.2). Estimates of age, total metallicity (Z/H) and alpha-element abundance ratio (a/Fe) were derived from absorption-line analysis, using single-burst models. Age, Z/H and a/Fe are all correlated positively with velocity dispersion, but we also find significant residual trends with luminosity: at given sigma, the brighter galaxies are younger, less alpha-enriched, and have higher Z/H. At face value, these results might suggest that the stellar populations depend on stellar mass as well as on velocity dispersion. However, we show that the observed trends can be reproduced by models in which the stellar populations depend systematically only on sigma, and are independent of stellar mass Mstel. For age, the observed luminosity correlation arises because young galaxies are brighter, at fixed Mstel. For metallicity, the observed luminosity dependence arises because metal-rich galaxies, at fixed mass, tend also to be younger, and hence brighter. We find a good match to the observed luminosity correlations with Age ~ sigma^0.40, Z/H ~ sigma^0.35, a/Fe ~ sigma^0.20, where the slopes are close to those found when fitting traditional scaling relations. We conclude that the star formation and enrichment histories of galaxies are determined primarily by the depth of their gravitational potential wells. The observed residual correlations with luminosity do not imply a corresponding dependence on stellar mass.