The miniJPAS survey: The role of group environment in quenching the star formation
Abstract
The miniJPAS survey has observed 1 deg2 on the AEGIS field with 60 bands (spectral resolution of R 60) in order to demonstrate the capabilities of the Javalambre-Physics of the Accelerating Universe Astrophysical Survey (J-PAS) that will map 8000 deg2 of the northern sky in the next years. This paper shows the power of J-PAS to detect low mass groups and characterise their galaxy populations up to z 1. We use the spectral energy distribution fitting code BaySeAGal to derive the stellar population properties of the galaxy members in 80 groups at z ≤ 0.8 previously detected by the AMICO code, as well as for a galaxy field sample retrieved from the whole miniJPAS sample. We identify blue, red, quiescent, and transition galaxy populations through their rest-frame (extinction corrected) colour, stellar mass (M) and specific star formation rate. We measure their abundance as a function of M and environment. We find: (i) The fraction of red and quiescent galaxies in groups increases with M and it is always higher in groups than in the field. (ii) The quenched fraction excess (QFE) in groups strongly increases with M, (from a few percent to higher than 60% in the mass range 1010 - 3 × 10 11 M. (iii) The abundance excess of transition galaxies in groups shows a modest dependence with M (iv) The fading time scale is very short (<1.5 Gyr), indicating that the star formation declines very rapidly in groups. (v) The evolution of the galaxy quenching rate in groups shows a modest but significant evolution since z0.8, compatible with an evolution with constant QFE=0.4, previously measured for satellites in the nearby Universe, and consistent with a scenario where the low-mass star-forming galaxies in clusters at z= 1-1.4 are environmentally quenched.
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