Beyond Simple AGN Unification with Chandra-observed 3CRR Sources

TL;DR

This study uses Chandra X-ray observations of a complete, orientation-unbiased radio galaxy sample to explore how both orientation and accretion rate influence active galactic nuclei unification, revealing new intermediate-inclination NLRGs and redshift-dependent obscuration properties.

Contribution

It introduces a radiation-regulated unification model that accounts for the influence of accretion rate and orientation, expanding beyond traditional orientation-only models.

Findings

Identification of intermediate-inclination NLRGs with low obscuration

Higher fraction of Compton-thin NLRGs at intermediate redshifts

Obscuration properties vary with redshift and accretion rate

Abstract

Low-frequency radio selection finds radio-bright galaxies regardless of the amount of obscuration by gas and dust. We report \chandra\ observations of a complete 178~MHz-selected, and so orientation unbiased, sample of 44 $0.5<z<1$ 3CRR sources. The sample is comprised of quasars and narrow-line radio galaxies (NLRGs) with similar radio luminosities, and the radio structure serves as both an age and an orientation indicator. Consistent with Unification, intrinsic obscuration (measured by \nh, X-ray hardness ratio, and X-ray luminosity) generally increases with inclination. However, the sample includes a population not seen in high-$z$ 3CRR sources: NLRGs viewed at intermediate inclination angles with \nh~$<10^{22}$~cm$^{-2}$. Multiwavelength analysis suggests these objects have lower $L/L_{\rm Edd}$ than typical NLRGs at similar orientation. Thus both orientation and $L/L_{\rm Edd}$ are important, and a "radiation-regulated Unification" provides a better explanation of the sample's observed properties. In comparison with the 3CRR sample at $1<z<2$, our lower-redshift sample shows a higher fraction of Compton-thin NLRGs (45\% vs.\ 29\%) but similar Compton-thick fraction (20\%), implying a larger covering factor of Compton-thin material at intermediate viewing angles and so a more "puffed-up" torus atmosphere. We posit that this is due to a range of $L/L_{\rm Edd}$ extending to lower values in this sample. In contrast, at high redshifts the narrower range and high $L/L_{\rm Edd}$ values allowed orientation (and so simple Unification) to dominate the sample's observed properties.