Inferring the star formation histories of the most massive and passive early-type galaxies at z<0.3

TL;DR

This study uses full-spectrum analysis of SDSS data to reconstruct the star formation histories of massive, passive early-type galaxies at low redshift, revealing their formation epochs and evolutionary trends.

Contribution

It introduces a method to infer detailed star formation histories of massive galaxies using full-spectrum fitting, linking low-redshift ETGs to their high-redshift progenitors.

Findings

Massive ETGs have slightly supersolar metallicities.

ETGs show an anti-hierarchical, downsizing evolution.

Most stars formed at z ~ 4-5, with quiescence by z ~ 1.5-2.

Abstract

Massive galaxies are key probes to understand how the baryonic matter evolves within the dark matter halos. We use the "archaeological" approach to infer the stellar population properties and star formation histories of the most massive (M > 10^10.75 Msun) and passive early-type galaxies (ETGs) at 0 < z < 0.3, based on stacked, high signal to noise ratio (SNR), Sloan Digital Sky Survey spectra. We exploit the information present in the full-spectrum by means of the STARLIGHT public code to retrieve the ETGs evolutionary properties, such as age, metallicity and star formation history. We find that the stellar metallicities are slightly supersolar (Z ~ 0.027 +/- 0.002) and do not depend on redshift. Dust extinction is very low, with a mean of Av ~ 0.08 +/- 0.03 mag. The ETGs show an anti-hierarchical evolution (downsizing) where more massive galaxies are older. The SFHs can be approximated by a parametric function of the form SFR(t) \propto \tau^-(c+1) t^(c) exp(-t/\tau), with typical short e-folding times of \tau ~ 0.6 - 0.8 Gyr (and a dispersion of +/- 0.1 Gyr) and c ~ 0.1 (and a dispersion of +/- 0.05). The inferred SFHs are also used to place constraints on the properties and evolution of the ETG progenitors. In particular, the ETGs of our samples should have formed most stars through a phase of vigorous star formation (SFRs > 350-400 Msun yr^-1) at z ~ 4 - 5, and are quiescent by z ~ 1.5 -2. Our results represent an attempt to demonstrate quantitatively the evolutionary link between the most massive ETGs at z < 0.3 and the properties of suitable progenitors at high redshifts, also showing that the full-spectrum fitting is a powerful approach to reconstruct the star formation histories of massive quiescent galaxies.