On the cosmic evolution of AGN obscuration and the X-ray luminosity function: XMM-Newton and Chandra spectral analysis of the 31.3 deg2 Stripe 82X

Abstract

We present X-ray spectral analysis of XMM and Chandra observations in the 31.3 deg2 Stripe-82X (S82X) field. Of the 6181 X-ray sources in this field, we analyze a sample of 2937 active galactic nuclei (AGN) with solid redshifts and sufficient counts determined by simulations. Our results show a population with median values of spectral index =1.94-0.39+0.31, column density log\,NH/cm-2=20.7-0.5+1.2 and intrinsic, de-absorbed, 2-10 keV luminosity log\,LX/erg\,s-1=44.0-1.0+0.7, in the redshift range 0-4. We derive the intrinsic fraction of AGN that are obscured (22≤log\,NH/cm-2<24), finding a significant increase in the obscured AGN fraction with redshift and a decline with increasing luminosity. The average obscured AGN fraction is 574\% for log\,LX/erg\,s-1>43. This work constrains the AGN obscuration and spectral shape of the still uncertain high-luminosity and high-redshift regimes (log\,LX/erg\,s-1>45.5, z>3), where the obscured AGN fraction rises to 6412\%. We report a luminosity and density evolution of the X-ray luminosity function, with obscured AGN dominating at all luminosities at z>2 and unobscured sources prevailing at log\,LX/erg\,s-1>45 at lower redshifts. Our results agree with evolutionary models in which the bulk of AGN activity is triggered by gas-rich environments and in a downsizing scenario. Also, the black hole accretion density (BHAD) is found to evolve similarly to the star formation rate density, confirming the co-evolution between AGN and host-galaxy, but suggesting different time scales in their growing history. The derived BHAD evolution shows that Compton-thick AGN contribute to the accretion history of AGN as much as all other AGN populations combined.