The X-ray/UV ratio in Active Galactic Nuclei: dispersion and variability

TL;DR

This study investigates the dispersion and variability in the X-ray/UV ratio of Active Galactic Nuclei, analyzing physical parameters influencing this relation to improve its use in cosmological measurements.

Contribution

It quantifies the intrinsic variability and identifies physical parameters affecting the X-ray/UV ratio, proposing ways to select more reliable AGN samples for cosmology.

Findings

Intrinsic variability accounts for 56% of the dispersion.

Weak dependence of the ratio on black-hole mass and Eddington ratio.

Possible viewing angle influence on the X-ray/UV ratio.

Abstract

The relation between the $\alpha_{OX}$ index and the optical/UV luminosity ($L_{UV}$), a by product of the X-ray - optical/UV luminosity relation, is affected by a relatively large dispersion, due to variability in the $\alpha_{OX}$ within single sources (intra-source dispersion) and variations of fundamental physical parameters from source to source (inter-source dispersion). We use archival data from the XMMSSC and from the XMMOM-SUSS3. We select a sub-sample in order to decrease the dispersion of the relation due to the presence of Radio-Loud and Broad Absorption Line objects, and to absorptions in both X-ray and optical/UV bands. We analyse the dependence of the residuals of the relation on various physical parameters in order to characterise the inter-source dispersion. We find a total dispersion of ~0.12 and, using the Structure Function, we find that intrinsic variability contributes for 56% of the variance of the relation. We find weak but significant dependences of the residuals of the relation on black-hole (BH) mass and on Eddington ratio, confirmed by a multivariate regression analysis of $\alpha_{OX}$ as a function of optical/UV luminosity and the above quantities. We find a weak positive correlation of both the $\alpha_{OX}$ and the residuals of the relation with inclination indicators (FWHM(H$\beta$) and EW[O$_{III}$]) suggesting a weak increase of X-ray/UV ratio with the viewing angle. Our results suggest the possibility of selecting a sample of objects, based on their viewing angle and/or BH mass and Eddington ratio, for which the $\alpha_{OX}-L_{UV}$ relation is as tight as possible, in light of the use of the X-ray - optical/UV luminosity relation to build a distance modulus (DM) - $z$ plane and estimate cosmological parameters.