Accretion properties of X-ray AGN: Evidence for radiation-regulated obscuration with redshift-dependent host galaxy contribution

Abstract

We adopt a Bayesian X-ray spectral approach to investigate the accretion properties of unobscured (20<(N H/ cm-2<22) and obscured (22< (N H/ cm-2<24) active galactic nuclei (AGN) to shed light on the orientation vs evolution scenarios for the origin of the obscuring material. For a sample of 3882 X-ray-selected AGN from the Chandra COSMOS Legacy, AEGIS and CDFS extragalactic surveys, we constrain their stellar masses, M, intrinsic X-ray luminosities, L X, obscuring column densities, N H, and specific accretion rates λ L X/M. By combining these observables within a Bayesian non-parametric approach, we infer, for the first time, the specific accretion rate distribution (SARD) of obscured and unobscured AGN to z≈3, i.e. the probability of a galaxy with mass M at redshift z hosting an AGN with column density N H and specific accretion rate λ. Our findings indicate that (1) both obscured and unobscured SARDs share similar shapes, shifting towards higher accretion rates with redshift, (2) unobscured SARDs exhibit a systematic offset towards higher λ compared to obscured SARD for all redshift intervals, (3) the obscured AGN fraction declines sharply at λ break -2 for z <0.5, but shifts to higher λ values with increasing redshift, (4) the incidence of AGN within the theoretically unstable blow-out region of the λ-N H plane increases with redshift. These observations provide compelling evidence for AGN "downsizing" and radiation-regulated nuclear-scale obscuration with an increasing host galaxy contribution towards higher redshifts.