The GLEAMing of the first supermassive black holes: III. Radio sources with ultra-faint host galaxies
Abstract
We present deep near-infrared K s-band imaging for 35 of the 53 sources from the high-redshift (z > 2) radio galaxy candidate sample defined in Broderick et al. (2022). These images were obtained using the High-Acuity Widefield K-band Imager (HAWK-I) on the Very Large Telescope. Host galaxies are detected for 27 of the sources, with K s ≈ 21.6-23.0 mag (2'' diameter apertures; AB). The remaining eight targets are not detected to a median 3σ depth of K s ≈ 23.3 mag (2'' diameter apertures). We examine the radio and near-infrared flux densities of the 35 sources, comparing them to the known z > 3 powerful radio galaxies with 500-MHz radio luminosities L500\, MHz > 1027 W Hz-1. By plotting 150-MHz flux density versus K s-band flux density, we find that, similar to the sources from the literature, these new targets have large radio to near-infrared flux density ratios, but extending the distribution to fainter flux densities. Five of the eight HAWK-I deep non-detections have a median 3σ lower limit of K s 23.8 mag (1.5'' diameter apertures); these five targets, along with a further source from Broderick et al. (2022) with a deep non-detection (K s 23.7 mag; 3σ; 2'' diameter aperture) in the Southern H-ATLAS Regions K s-band Survey, are considered candidates to be ultra-high-redshift (z > 5) radio galaxies. The extreme radio to near-infrared flux density ratios (>105) for these six sources are comparable to TN J0924-2201, GLEAM J0856+0223 and TGSS J1530+1049, the three known powerful radio galaxies at z > 5. For a selection of galaxy templates with different stellar masses, we show that z 4.2 is a plausible scenario for our ultra-high-redshift candidates if the stellar mass M * 1010.5\, M. [abridged]
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