Evolution of spatially resolved star formation main sequence and surface density profiles in massive disc galaxies at 0 z 1: inside-out stellar mass buildup and quenching

Abstract

We investigate a relation between surface densities of star formation rate (SFR) and stellar mass (M*) at a 1 kpc scale namely spatially resolved star formation main sequence (SFMS) in massive ((M*/M)>10.5) face-on disc galaxies at 0.01<z<0.02 and 0.8<z<1.8 and examine evolution of the relation. The spatially resolved SFMS of z 0 galaxies is discussed in a companion paper. For z 1 sample, we use 8 bands imaging dataset from CANDELS and 3D-HST and perform a pixel-to-pixel SED fitting to derive the spatially resolved SFR and M*. We find a linear spatially resolved SFMS in the z 1 galaxies that lie on the global SFMS, while a 'flattening' at high * end is found in that relation for the galaxies that lie below the global SFMS. Comparison with the spatially resolved SFMS of the z 0 galaxies shows smaller difference in the specific SFR (sSFR) at low * than that at high *. This trend is consistent with the evolution of the sSFR(r) radial profile, which shows a faster decrease in the central region than in the outskirt, agrees with the inside-out quenching scenario. We then derive an empirical model for the evolution of the *(r), SFR(r) and sSFR(r) radial profiles. Based on the empirical model, we estimate the radial profile of the quenching timescale and reproduce the observed spatially resolved SFMS at z 1 and z 0.