Cosmic evolution of radio-excess AGNs in quiescent and star-forming galaxies across 0 < z < 4

Abstract

Recent deep and wide radio surveys extend the studies for radio-excess active galactic nuclei (radio-AGNs) to lower luminosities and higher redshifts, providing new insights into the abundance and physical origin of radio-AGNs. Here we focus on the cosmic evolution, physical properties and AGN-host galaxy connections of radio-AGNs selected from a sample of ~ 500,000 galaxies at 0 < z < 4 in GOODS-N, GOODS-S, and COSMOS fields. Combining deep radio data with multi-band, de-blended far-infrared (FIR) and sub-millimeter data, we identify 1162 radio-AGNs through radio excess relative to the FIR-radio relation. We study the cosmic evolution of 1.4 GHz radio luminosity functions (RLFs) for star-forming galaxies (SFGs) and radio-AGNs, which are well described by a pure luminosity evolution of L* (1+z)-0.31z+3.41 and a pure density evolution of * (1+z)-0.80z+2.88, respectively. We derive the turnover luminosity above which the number density of radio-AGNs surpasses that of SFGs. This crossover luminosity increases as increasing redshift, from 1022.9 W Hz-1 at z ~ 0 to 1025.2 W Hz-1 at z ~ 4. At full redshift range (0 < z < 4), we further derive the probability (pradio) of SFGs and quiescent galaxies (QGs) hosting a radio-AGN as a function of stellar mass (M*), radio luminosity (LR), and redshift (z), which yields pradio (1+z)3.54M*1.02LR-0.90 for SFGs, and pradio (1+z)2.38M*1.39LR-0.60 for QGs, respectively. It indicates that radio-AGNs in QGs prefer to reside in more massive galaxies with larger LR than those in SFGs, and radio-AGN fraction increases towards higher redshift in both SFGs and QGs with a more rapid increase in SFGs. Further, we find that the radio-AGN fraction depends on accretion states of BHs and redshift in SFGs, while in QGs it also depends on BH (or galaxy) mass.