Star formation concentration as a tracer of environmental quenching in action: a study of the Eagle and C-Eagle simulations

Abstract

We study environmental quenching in the Eagle/C-Eagle cosmological hydrodynamic simulations over the last 11 Gyr (i.e. z=0-2). The simulations are compared with observations from the SAMI Galaxy Survey at z=0. We focus on satellite galaxies in galaxy groups and clusters (1012\, M M200 < 3 × 1015\, M). A star-formation concentration index [C-index = 10(r50,SFR / r50,rband)] is defined, which measures how concentrated star formation is relative to the stellar distribution. Both Eagle/C-Eagle and SAMI show a higher fraction of galaxies with low C-index in denser environments at z=0-0.5. Low C-index galaxies are found below the SFR-M main sequence (MS), and display a declining specific star formation rate (sSFR) with increasing radii, consistent with ``outside-in'' environmental quenching. Additionally, we show that C-index can be used as a proxy for how long galaxies have been satellites. These trends become weaker at increasing redshift and are absent by z=1-2. We define a quenching timescale t quench as how long it takes satellites to transition from the MS to the quenched population. We find that simulated galaxies experiencing ``outside-in'' environmental quenching at low redshift (z=00.5) have a long quenching timescale (median t quench > 2 Gyr). The simulated galaxies at higher redshift (z=0.72) experience faster quenching (median t quench < 2Gyr). At z 1-2 galaxies undergoing environmental quenching have decreased sSFR across the entire galaxy with no ``outside-in'' quenching signatures and a narrow range of C-index, showing that on average environmental quenching acts differently than at z 1.