A multiwavelength-motivated X-ray model for the Circinus Galaxy

TL;DR

This paper develops a comprehensive multi-component X-ray model for the Circinus Galaxy, integrating various physical structures to accurately reproduce observed spectra and inform future X-ray observations.

Contribution

It introduces a self-consistent, multiwavelength-motivated X-ray model including accretion disk, BLR, flared disk, and hollow cone, advancing the understanding of AGN environments.

Findings

Model reproduces 3-70 keV spectra of Circinus

Flared disk is Compton thick and geometrically thick

Hollow cone has a Compton-thin column density

Abstract

Reprocessed X-ray emission in Active Galactic Nuclei (AGN) can provide fundamental information about the circumnuclear environments of supermassive black holes. Recent mid-infrared studies have shown evidence of an extended dusty structure perpendicular to the torus plane. In this work, we build a self-consistent X-ray model for the Circinus Galaxy including the different physical components observed at different wavelengths and needed to reproduce both the morphological and spectral properties of this object in the mid-infrared. The model consists of four components: the accretion disk, the broad line region (BLR), a flared disk in the equatorial plane and a hollow cone in the polar direction. Our final model reproduces well the 3--70 keV Chandra and NuSTAR spectra of Circinus, including the complex Fe K$\alpha$ zone and the spectral curvature, although several additional Gaussian lines, associated to either ionized iron or to broadened Fe K$\alpha$/K$\beta$ lines, are needed. We find that the flared disk is Compton thick ($ N_{\rm H,d}= \rm 1.01^{+0.03}_{-0.24}\times 10^{25}\: cm^{-2}$) and geometrically thick ($CF=0.55^{+0.01}_{-0.05}$), and that the hollow cone has a Compton-thin column density ($ N_{\rm H,c}= \rm 2.18^{+0.47}_{-0.43}\times 10^{23}\: cm^{-2}$), which is consistent with the values inferred by mid-infrared studies. Including also the BLR, the effective line of sight column density is $ N_{\rm H}= \rm 1.47^{+0.03}_{-0.24}\times 10^{25}\: cm^{-2}$. This approach to X-ray modelling, i.e. including all the different reprocessing structures, will be very important to fully exploit data from future X-ray missions.