DEVILS: Cosmic evolution of SED-derived metallicities and their connection to star-formation histories

TL;DR

This study uses SED fitting to self-consistently measure galaxy metallicities and explore their evolution and connection to star formation histories, revealing a nearly constant mass-metallicity relation and links to star formation activity.

Contribution

It introduces a method to derive metallicities from SED fitting with evolving metallicity histories, providing new insights into the evolution of the mass-metallicity relation.

Findings

Mass-metallicity relation evolves only slightly in normalization.

No difference in MZR between galaxies with or without AGN activity at low redshift.

Higher metallicity galaxies formed their mass over shorter timescales.

Abstract

Gas-phase metallicities of galaxies are typically measured through auroral or nebular emission lines, but metallicity also leaves an imprint on the overall spectral energy distribution (SED) of a galaxy and can be estimated through SED fitting. We use the ProSpect SED fitting code with a flexible parametric star formation history and an evolving metallicity history to self-consistently measure metallicities, stellar mass, and other galaxy properties for $\sim90\,000$ galaxies from the Deep Extragalactic VIsible Legacy Survey (DEVILS) and Galaxy and Mass Assembly (GAMA) survey. We use these to trace the evolution of the mass-metallicity relation (MZR) and show that the MZR only evolves in normalisation by $\sim0.1\,$dex at stellar mass $M_\star = 10^{10.5}\,M_\odot$. We find no difference in the MZR between galaxies with and without SED evidence of active galactic nuclei emission at low redshifts ($z<0.3$). Our results suggest an anti-correlation between metallicity and star formation activity at fixed stellar mass for galaxies with $M_\star > 10^{10.5}\,M_\odot$ for $z<0.3$. Using the star formation histories extracted using ProSpect we explore higher-order correlations of the MZR with properties of the star formation history including age, width, and shape. We find that at a given stellar mass, galaxies with higher metallicities formed most of their mass over shorter timescales, and before their peak star formation rate. This work highlights the value of exploring the connection of a galaxy's current gas-phase metallicity to its star formation history in order to understand the physical processes shaping the MZR.