A Multi-Wavelength Characterization of the Obscuring Medium at the Center of NGC 6300

TL;DR

This study combines X-ray to infrared observations of NGC 6300 to analyze the properties of its obscuring torus and central black hole, revealing a stable line-of-sight column density and a radiatively inefficient accretion rate.

Contribution

It provides a comprehensive multi-wavelength analysis of the obscuring medium in NGC 6300, constraining the torus structure and accretion properties using advanced spectral fitting models.

Findings

No significant column density variability over 13 years.

Detection of an inner Compton-thick gaseous ring.

Measured low Eddington ratio indicating radiatively inefficient accretion.

Abstract

Most of the super-massive black holes in the Universe accrete material in an obscured phase. While it is commonly accepted that the "dusty torus" is responsible for the nuclear obscuration, its geometrical, physical, and chemical properties are far from being properly understood. In this paper, we take advantage of the multiple X-ray observations taken between 2007 and 2020, as well as of optical to far infra-red (FIR) observations of NGC 6300, a nearby ($z=0.0037$) Seyfert 2 galaxy. The goal of this project is to study the nuclear emission and the properties of the obscuring medium, through a multi-wavelength study conducted from X-ray to IR. We perform a simultaneous X-ray spectral fitting and optical-FIR spectral energy distribution (SED) fitting to investigate the obscuring torus. For the X-ray spectral fitting, physically motivated torus models, such as borus02, UXClumpy and XClumpy are used. The SED fitting is done using XCIGALE. Through joint analysis, we constrain the physical parameters of the torus and the emission properties of the accreting supermassive black hole. Through X-ray observations taken in the last 13 years, we have not found any significant line-of-sight column density variability for this source, but observed the X-ray flux dropping $\sim40-50\%$ in 2020 with respect to previous observations. The UXClumpy model predicts the presence of an inner ring of Compton-thick gaseous medium, responsible for the reflection dominated spectra above 10 keV. Through multi-wavelength SED fitting, we measure an Eddington accretion rate $\lambda_{\rm{Edd}}\sim2\times10^{-3}$, which falls in the range of the radiatively inefficient accretion solutions.