The Astrophysical Journal (Jan 2024)

Metals in Star-forming Galaxies with KCWI. I. Methodology and First Results on the Abundances of Iron, Magnesium, and Oxygen

  • Zhuyun Zhuang,
  • Evan N. Kirby,
  • Charles C. Steidel,
  • Mithi A. C. de los Reyes,
  • Nikolaus Z. Prusinski,
  • N. Leethochawalit,
  • Minjung Park,
  • Charlie Conroy,
  • Evan H. Nuñez

DOI
https://doi.org/10.3847/1538-4357/ad5ff8
Journal volume & issue
Vol. 972, no. 2
p. 182

Abstract

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Understanding the chemical enrichment of different elements is crucial to gaining a complete picture of galaxy chemical evolution. In this study, we present a new sample of 46 low-redshift, low-mass star-forming galaxies at M _* ∼ 10 ^8−10 M _⊙ along with two quiescent galaxies at M _* ∼ 10 ^8.8 M _⊙ observed with the Keck Cosmic Web Imager, aiming to investigate the chemical evolution of galaxies in the transition zone between Local Group satellites and massive field galaxies. We develop a novel method to simultaneously determine stellar abundances of iron and magnesium in star-forming galaxies. With the gas-phase oxygen abundance (O/H) _g measured using the strong-line method, we are able to make the first-ever apples-to-apples comparison of α elements in the stars and the interstellar medium. We find that the [Mg/H] _* –[O/H] _g relation is much tighter than the [Fe/H] _* –[O/H] _g relation, which can be explained by the similar production processes of α elements. Most galaxies in our sample exhibit higher [O/H] _g than [Fe/H] _* and [Mg/H] _* . In addition, we construct mass–metallicity relations (MZRs) measured as three different elements (Fe _* , Mg _* , O _g ). Compared to the gas O-MZR, the stellar Fe- and Mg-MZRs show larger scatter driven by variations in specific star formation rates (sSFR), with star-forming galaxies exhibiting higher sSFR and lower stellar abundances at fixed mass. The excess of [O/H] _g compared to stellar abundances as well as the anticorrelation between sSFR and stellar abundance suggests that galaxy quenching of intermediate-mass galaxies at M _* ∼ 10 ^8−10 M _⊙ is primarily driven by starvation.

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