We present multi-frequency (1-8 GHz) VLA data, combined with VIMOS IFU data and HST imaging, of a z=0.085 radio-quiet type 2 quasar (with L(1.4GHz)~5e23 W/Hz and L(AGN)~2e45 erg/s). Due to the morphology of its emission-line region, the target (J1430
+1339) has been referred to as the Teacup AGN in the literature. We identify bubbles of radio emission that are extended ~10-12 kpc to both the east and west of the nucleus. The edge of the brighter eastern bubble is co-spatial with an arc of luminous ionized gas. We also show that the Teacup AGN hosts a compact radio structure, located ~0.8 kpc from the core position, at the base of the eastern bubble. This radio structure is co-spatial with an ionized outflow with an observed velocity of v=-740 km/s. This is likely to correspond to a jet, or possibly a quasar wind, interacting with the interstellar medium at this position. The large-scale radio bubbles appear to be inflated by the central AGN, which indicates that the AGN can also interact with the gas on >~10 kpc scales. Our study highlights that even when a quasar is formally radio-quiet the radio emission can be extremely effective for observing the effects of AGN feedback.
We present a study of the radio properties of 870$mu$m-selected submillimetre galaxies (SMGs), observed at high resolution with ALMA in the Extended Chandra Deep Field South. From our initial sample of 76 ALMA SMGs, we detect 52 SMGs at $>3sigma$ sig
nificance in VLA 1400MHz imaging, of which 35 are also detected at $>3sigma$ in new 610MHz GMRT imaging. Within this sample of radio-detected SMGs, we measure a median radio spectral index $alpha_{610}^{1400} = -0.79 pm 0.06$, (with inter-quartile range $alpha=[-1.16,-0.56]$) and investigate the far-infrared/radio correlation via the parameter $q_{rm IR}$, the logarithmic ratio of the rest-frame 8-1000$mu$m flux and monochromatic radio flux. Our median $q_{rm IR} = 2.56 pm 0.05$ (inter-quartile range $q_{rm IR}=[2.42,2.78]$) is higher than that typically seen in single-dish 870$mu$m-selected sources ($q_{rm IR} sim 2.4$), which may reflect the fact that our ALMA-based study is not biased to radio-bright counterparts, as previous samples were. Finally, we search for evidence that $q_{rm IR}$ and $alpha$ evolve with age in a co-dependent manner, as predicted by starburst models: the data populate the predicted region of parameter space, with the stellar mass tending to increase along tracks of $q_{rm IR}$ versus $alpha$ in the direction expected, providing the first observational evidence in support of these models.
