The effects of stellar populations on galaxy scaling relations in the 6dF Galaxy Survey

TL;DR

This study analyzes stellar populations in ~7000 galaxies from the 6dF Galaxy Survey, revealing how age and metallicity influence galaxy scaling relations and the implications for mass-to-light ratios.

Contribution

It provides new insights into the relationship between stellar populations, galaxy mass, and photometric properties, accounting for degeneracies in previous studies.

Findings

Old galaxies show a mass-metallicity relation with slope 0.25.

Young galaxies have a near-zero slope in the mass-metallicity relation.

Young stellar populations are centrally concentrated, especially in lower-mass galaxies.

Abstract

We present an analysis of the stellar populations in a sample of ~7000 galaxies from the 6dF Galaxy Survey (6dFGS). We derive ages and metallicities using stellar population models. We also derive dynamical masses and dynamical mass-to-light ratios by combining central velocity dispersions with global photometry in B, R and K bands. Together, these data allow to reduce the degeneracies between age, metallicity and star formation burst-strength that have limited previous studies. We find old galaxies exhibit a mass-metallicity relation with slope d[Fe/H]/dlogM = 0.25, while young galaxies show slopes consistent with zero. When we account for the effects of the mass-metallicity relation, we obtain a single, consistent relation between mass-to-light ratio and mass for old galaxies in all passbands. As we have accounted for stellar population effects, this relation must have a dynamical origin. However, we demonstrate that any simple trend between mass-to-light-ratio and mass or luminosity is inconsistent with the observations, and that a more complex relationship must exist. We find the central regions of galaxies often exhibit young stellar populations. However it is only in the lowest-mass galaxies (~10^{10} M$_{\odot}$) that these populations are evident in the global photometry. In higher-mass galaxies, young central populations have decreasing influence on the global photometry, with there being no discernible impact in galaxies more massive than ~2x10^{11} M$_{\odot}$. We conclude that the young stellar populations detected in spectroscopic studies are generally centrally concentrated, and that there is an upper limit on the mass of star-forming events in massive galaxies. These results have ramifications for mass-to-light ratios estimated from photometric observations.