Spectral Properties and the Effect on Redshift Cut-off of Compact AGNs from the AT20G Survey

TL;DR

This study uses high-resolution data from the AT20G survey to analyze the spectral and size properties of compact AGNs, confirming spectral classification criteria and demonstrating the impact of spectral curvature on redshift cut-off observations.

Contribution

It provides a physical basis for spectral classification of sources and quantifies how spectral curvature affects redshift cut-off detection in high-frequency surveys.

Findings

Strong correlation between compactness and spectral type.

Spectral steepening occurs at ~30 GHz for most sources.

Redshift cut-off is genuine at low frequencies, not due to spectral curvature.

Abstract

We use high angular resolution data, measured from visibility of sources at the longest baseline of 4500 m of the Australia Telescope Compact Array (ATCA), for the Australia Telescope 20 GHz (AT20G) survey to obtain angular size information for > 94% of AT20G sources. We confirm the previous AT20G result that due to the high survey frequency of 20 GHz, the source population is strongly dominated by compact sources (79%). At 0.15 arcseconds angular resolution limit, we show a very strong correlation between the compact and extended sources with flat and steep-spectrum sources respectively. Thus, we provide a firm physical basis for the traditional spectral classification into flat and steep-spectrum sources to separate compact and extended sources. We find the cut-off of -0.46 to be optimum for spectral indices between 1 and 5 GHz and, hence, recommend the continued use of -0.5 for future studies. We study the effect of spectral curvature on redshift cut-off of compact AGNs using recently published redshift data. Using spectral indices at different frequencies, we correct for the redshift effect and produce restframe frequency spectra for compact sources for redshift up to ~5. We show that the flat spectra of most compact sources start to steepen at ~30 GHz. At higher frequencies, the spectra of both populations are steep so the use of spectral index does not separate the compact and extended source populations as well as in lower frequencies. We find that due to the spectral steepening, surveys of compact sources at higher frequencies (>5 GHz) will have redshift cut-off due to spectral curvature but at lower frequencies, the surveys are not significantly affected by spectral curvature, thus, the evidence for a strong redshift cut-off in AGNs found in lower frequency surveys is a real cut-off and not a result of K-correction.