The stellar mass versus stellar metallicity relation of star-forming galaxies at 1.6 z3.0 and implications for the evolution of the α-enhancement

Abstract

We measure the relationship between stellar mass and stellar metallicity, the stellar mass--metallicity relation (MZR), for 1336 star-forming galaxies at 1.6 z3.0 (<z>=2.2) using rest-frame far-ultraviolet spectra from the zCOSMOS-deep survey. High signal-to-noise composite spectra containing stellar absorption features are fit with population synthesis model spectra of a range of metallicity. We find stellar metallicities, which mostly reflect iron abundances, scaling as (ZFe,/ZFe,)=-(0.810.01)+(0.32+0.03)(M/1010M) across the mass range of 109 M/M1011, being ≈6× lower than seen locally at the same masses. The instantaneous oxygen-to-iron ratio (α-enhancement) inferred using the gas-phase oxygen MZRs, is on average found to be [O/Fe]≈0.47, being higher than the local [O/Fe]≈0. The observed changes in [O/Fe] and [Fe/H] are reproduced in simple flow-through gas-regulator models with steady star-formation histories (SFHs) that follow the evolving main sequence. Our models show that the [O/Fe] is determined almost entirely by the instantaneous specific star formation rate alone while being independent of the SFHs, mass, and the gas-regulation characteristics of the systems. We find that the locations of 1010M galaxies at z~2 in the [O/Fe]--metallicity planes are in remarkable agreement with the sequence of low-metallicity thick-disk stars in our Galaxy. This manifests a beautiful concordance between the results of Galactic archaeology and observations of high-redshift Milky Way progenitors. However, there remains a question of how and when the old metal-rich, low-α/Fe stars seen in the bulge had formed by z~2 because such a stellar population is not seen in our data and difficult to explain in the context of our models.