Tracing Radio AGN-Driven Quenching in Post-Starburst Galaxies at Cosmic Noon

Abstract

We present a radio continuum study of photometrically selected cosmic noon (0.5<z<3) post-starburst galaxies (PSBs) in the UKIDSS Deep Survey (UDS) field to assess if radio-mode Active Galactic Nuclei (AGN) are linked to the quenching of star formation at cosmic noon. Our cross-matching using the deep Very Large Array (VLA) imaging at 1.4 GHz results in a mean radio detection fraction (fdet) of only 0.8\% for PSBs above a radio luminosity threshold of L 1.4 GHz ≥ 1024 W Hz-1, increasing to 52\% for massive PSBs with stellar masses M*>1011M. Massive PSBs have a comparable detection fraction to that of massive quiescent galaxies (fdet=81\%), and both classes have lower fractions than that of massive star-forming galaxies (fdet=131\%) in the same field. The radio luminosities of detected PSBs, L1.4 1022.8-1024.9W/Hz, exceed those from star formation by a median factor of 37 indicative of a possible AGN origin. Their compact morphologies (15 kpc at zmed=1.5) suggest low-luminosity AGN with less powerful jets. Stacking the undetected PSBs reveals a weak radio detection (3.9σ) in the highest mass bin (M*>1011M). In contrast, 1.4 GHz detected quiescent galaxies have radio luminosities reaching radio-loud levels, and a higher prevalence of extended morphologies indicative of large-scale jetted AGN. The AGN contribution is also detected in stacked measurements of quiescent galaxies. Overall, our results support a short radio AGN duty cycle for PSBs, characterized by weak radio jets, suggesting radio-driven maintenance mode feedback may become important at older ages.