The VANDELS survey: the relation between UV continuum slope and stellar metallicity in star-forming galaxies at z~3

TL;DR

This study uses deep FUV spectra from the VANDELS survey to measure stellar metallicities in high-redshift star-forming galaxies, revealing a correlation with UV continuum slope and insights into galaxy evolution.

Contribution

It provides the first direct measurement of stellar metallicity dependence on UV slope at z~3, calibrated with stellar models, and compares the mass-metallicity relation across redshifts.

Findings

Stellar metallicity increases by ~0.5 dex from beta ~ -2 to -1.

Metallicity correlates with UV slope at fixed stellar mass and luminosity.

No significant evolution of the mass-metallicity relation between z=2 and z=3.5.

Abstract

The estimate of stellar metallicities (Z*) of high-z galaxies are of paramount importance in order to understand the complexity of dust effects and the reciprocal interrelations among stellar mass, dust attenuation, stellar age, and metallicity. Benefiting from uniquely deep FUV spectra of >500 star-forming galaxies at redshifts 2<z<5 extracted from the VANDELS survey and stacked in bins of stellar mass (M*) and UV continuum slope (beta), we estimate their stellar metallicities Z* from stellar photospheric absorption features at 1501 and 1719 Angstrom, which are calibrated with Starburst99 models and are largely unaffected by stellar age, dust, IMF, nebular continuum or interstellar absorption. Comparing them to photometric based spectral slopes in the range 1250-1750 Angstrom, we find that the stellar metallicity increases by ~0.5 dex from beta ~ -2 to beta ~ -1 (1 < A(1600) < 3.2), and a dependence with beta holds at fixed UV absolute luminosity M(UV) and stellar mass up to 10^(9.65) Msun. As a result, the metallicity is a fundamental ingredient for properly rescaling dust corrections based on M(UV) and M*. Using the same absorption features, we analyze the mass-metallicity relation (MZR) and find it is consistent with the previous VANDELS estimation based on a global fit of the FUV spectra. Similarly, we do not find a significant evolution between z=2 and z=3.5. Finally, the slopes of our MZR and Z*-beta relation are in agreement with the predictions of well-studied semi-analytic models of galaxy formation (SAM), while some tensions with observations remain as to the absolute metallicity normalization. The relation between UV slope and stellar metallicity is fundamental for the exploitation of large volume surveys with next-generation telescopes and for the physical characterization of galaxies in the first billion years of our Universe.