Obscuration-dependent evolution of Active Galactic Nuclei

TL;DR

This study investigates how the evolution of Active Galactic Nuclei (AGN) depends on obscuration levels using a large X-ray survey, revealing that obscuration influences AGN evolution and the distribution of their properties over cosmic time.

Contribution

The paper introduces a novel non-parametric method to robustly infer AGN population distributions considering uncertainties, advancing understanding of obscuration-dependent AGN evolution.

Findings

Obscured AGN with N_H > 10^22 cm^-2 constitute about 77% of the AGN population.

Approximately half of the obscured AGN are Compton-thick, contributing significantly to the total luminosity.

The obscured fraction increases with redshift for Compton-thin AGN, but remains constant for Compton-thick AGN.

Abstract

We aim to constrain the evolution of AGN as a function of obscuration using an X-ray selected sample of $\sim2000$ AGN from a multi-tiered survey including the CDFS, AEGIS-XD, COSMOS and XMM-XXL fields. The spectra of individual X-ray sources are analysed using a Bayesian methodology with a physically realistic model to infer the posterior distribution of the hydrogen column density and intrinsic X-ray luminosity. We develop a novel non-parametric method which allows us to robustly infer the distribution of the AGN population in X-ray luminosity, redshift and obscuring column density, relying only on minimal smoothness assumptions. Our analysis properly incorporates uncertainties from low count spectra, photometric redshift measurements, association incompleteness and the limited sample size. We find that obscured AGN with $N_{H}>{\rm 10^{22}\, cm^{-2}}$ account for ${77}^{+4}_{-5}\%$ of the number density and luminosity density of the accretion SMBH population with $L_{{\rm X}}>10^{43}\text{ erg/s}$, averaged over cosmic time. Compton-thick AGN account for approximately half the number and luminosity density of the obscured population, and ${38}^{+8}_{-7}\%$ of the total. We also find evidence that the evolution is obscuration-dependent, with the strongest evolution around $N_{H}\thickapprox10^{23}\text{ cm}^{-2}$. We highlight this by measuring the obscured fraction in Compton-thin AGN, which increases towards $z\sim3$, where it is $25\%$ higher than the local value. In contrast the fraction of Compton-thick AGN is consistent with being constant at $\approx35\%$, independent of redshift and accretion luminosity. We discuss our findings in the context of existing models and conclude that the observed evolution is to first order a side-effect of anti-hierarchical growth.