The narrow Fe K$\alpha$ line and the molecular torus in active galactic nuclei - an IR/X-ray view

TL;DR

This study investigates the connection between the narrow Fe Kα line in X-ray spectra and the properties of the molecular torus in AGN, using IR and X-ray data to explore their physical relationship.

Contribution

It provides the first empirical link between Fe Kα line strength and torus parameters derived from IR models, supporting the torus origin of the line.

Findings

Fe Kα EW correlates with torus covering factor, consistent with theoretical expectations.

Fe Kα EW shows a trend with torus column density, supporting a common origin.

Results support the idea that the narrow Fe Kα line originates from the same material as MIR emission.

Abstract

The narrow component of the iron K$\alpha$ is an almost ubiquitous feature in the X-ray spectra of active galactic nuclei (AGN) and is believed to originate in neutral material, possibly located in the molecular torus. This would imply a tight connection between the Fe K$\alpha$ equivalent width (EW) and the physical properties of the torus. In a recent work we have shown that the decrease of the covering factor of the torus with the luminosity, as expected by luminosity-dependent unification models, would be able to explain the decrease of Fe K$\alpha$ EW with the luminosity (i.e., the X-ray Baldwin effect). Recent developments in the study of the mid-IR (MIR) spectrum of AGN allow important parameters of the torus to be deduced, such as its covering factor ($f_{\rm\,obs}$) and equatorial column density ($N_{\rm\,H}^{\rm\,T}$), by applying clumpy torus models. Using XMM-Newton/EPIC observations of a sample of 24 type-I AGN, we investigate the relation between the physical parameters of the torus obtained by recent MIR works and the properties of the Fe K$\alpha$ line. We correct the values of the Fe K$\alpha$ EW by taking the inclination angle, the photon index, the equatorial column density, and half-opening angle of the torus into account using a physical torus model of X-ray reprocessed radiation. We find that the relation between Fe K$\alpha$ EW and $f_{\rm\,obs}$ shows a slope that is consistent with the expected value, albeit with a low statistical significance. A trend that is consistent with the theoretical prediction is also found when comparing the Fe K$\alpha$ EW to $N_{\rm\,H}^{\rm\,T}$. Our work seems to confirm that the bulk of the narrow Fe K$\alpha$ line is produced by the same material responsible for the MIR emission.