The mass--metallicity relation AKARI-FMOS infrared galaxies at z0.88 in the AKARI North Ecliptic Pole Deep Survey Field

Abstract

Mass, metallicity, and star formation rate (SFR) of a galaxy are crucial parameters in understanding galaxy formation and evolution. However, the relation among these is still a matter of debate for luminous infrared galaxies, which carry a bulk of SFR budget of the universe at z1. We have investigated the relation among stellar mass, gas-phase oxygen abundance, and SFR of AKARI-detected mid-IR galaxies at z0.88 in the AKARI NEP deep field. We observed about 350 AKARI sources with Subaru/FMOS NIR spectrograph, and detected secure and expected Hα emission lines from 25 and 44 galaxies, respectively. The SFR of our sample is almost constant ( 25M/yr) over the stellar mass range of our sample. Compared with main-sequence (MS) galaxies at a similar redshift range, the average SFR of our detected sample is comparable for massive galaxies (1010.58~M), while higher by 0.6dex for less massive galaxies ( 1010.05~M). We measure metallicities from the [NII]/Hα emission line ratio. We find that the mass-metallicity relation of our individually measured sources agrees with that for optical-selected star-forming galaxies at z0.1, while metallicities of stacked spectra agree with that of MS galaxies at z0.78. Considering high SFR of individually measured sources, FMR of the IR galaxies is different from that at z0.1. However, on the mass-metallicity plane, they are consistent with the MS galaxies, highlighting higher SFR of the IR galaxies. This suggests the evolutionary path of our IR galaxies is different from that of MS galaxies. A possible physical interpretation includes that the star-formation activities of IR galaxies at z0.88 in our sample are enhanced by interaction and/or merger of galaxies, but the inflow of metal-poor gas is not yet induced, keeping the metallicity intact.