The mid-infrared properties and gas content of active galaxies over large look-back times

TL;DR

This study investigates the properties and gas content of active galaxies across various redshifts, revealing how factors like UV radiation and star formation influence 21-cm absorption detection rates.

Contribution

It provides new insights into the evolution of gas properties and galaxy activity over large look-back times, especially regarding the role of UV photons and star formation.

Findings

Detection rate of 21-cm absorption decreases at high redshift due to photo-ionisation.

Spin temperature of gas appears to evolve with redshift, indicating heating by UV photons.

Radio galaxies become more quasar-like in activity with increasing redshift.

Abstract

Upon an expansion of all of the searches for redshifted HI 21-cm absorption (0.0021 < z 5.19), we update recent results regarding the detection of 21-cm in the non-local Universe. Specifically, we confirm that photo-ionisation of the gas is the mostly likely cause of the low detection rate at high redshift, in addition to finding that at z < 0.1 there may also be a decrease in the detection rate, which we suggest is due to the dilution of the absorption strength by 21-cm emission. By assuming that associated and intervening absorbers have similar cosmological mass densities, we find evidence that the spin temperature of the gas evolves with redshift, consistent with heating by ultra-violet photons. From the near--infrared (3.4, 4.6 and 12 micron) colours, we see that radio galaxies become more quasar-like in their activity with increasing redshift. We also find that the non-detection of 21-cm absorption at high redshift is not likely to be due to the selection of gas-poor ellipticals, in addition to a strong correlation between the ionising photon rate and the [3.4] - [4.6] colour, indicating that the UV photons arise from AGN activity. Like previous studies, we find a correlation between the detection of 21-cm absorption and the [4.6] - [12] colour, which is a tracer of star-forming activity. However, this only applies at the lowest redshifts (z < 0.1), the range considered by the other studies.