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ABSTRACT We present determinations of the gas-phase and stellar metallicities of a sample of 65 star-forming galaxies at z 3. 5 using rest-frame far-ultraviolet (FUV) spectroscopy from the VANDELS survey in combination with follow-up rest-frame optical spectroscopy from VLT/KMOS and Keck/MOSFIRE. We infer gas-phase oxygen abundances (Z₆; tracing O/H) via strong optical nebular lines and stellar iron abundances (Z ; tracing Fe/H) from full spectral fitting to the FUV continuum. Our sample spans the stellar mass range 8. 5 log (M /M) 10. 5 and shows clear evidence for both a stellar and gas-phase mass-metallicity relation (MZR). We find that our O and Fe abundance estimates both exhibit a similar mass-dependence, such that Fe/H M ^0. 30 0. 11 and O/H M ^0. 32 0. 09. At fixed M we find that, relative to their solar values, O abundances are systematically larger than Fe abundances (i. e. α-enhancement). We estimate an average enhancement of (O/Fe) = 2. 65 0. 16 (O/Fe) _ which appears to be independent of M. We employ analytic chemical evolution models to place a constraint on the strength of galactic-level outflows via the mass-outflow factor (). We show that outflow efficiencies that scale as M ^-0. 32 can simultaneously explain the functional form of of the stellar and gas-phase MZR, as well as the degree of α-enhancement at fixed Fe/H. Our results add further evidence to support a picture in which α-enhanced abundance ratios are ubiquitous in high-redshift star-forming galaxies, as expected for young systems whose interstellar medium is primarily enriched by core-collapse supernovae.
Stanton et al. (Thu,) studied this question.