Exploring the mid-infrared SEDs of six AGN dusty torus models I: synthetic spectra

TL;DR

This study compares six AGN dusty torus models using synthetic mid-infrared spectra to determine their distinguishability and parameter constraints, highlighting the importance of high-resolution data from future telescopes like JWST.

Contribution

First to systematically compare six dusty torus models with synthetic spectra, assessing their discriminability and parameter constraints with current and future instruments.

Findings

Models can be distinguished based on continuum slopes and silicate features.

Parameters can be constrained within 15% error for most models.

High spatial resolution spectra are essential for accurate parameter estimation.

Abstract

At distances from the active galaxy nucleus (AGN) where the ambient temperature falls below ~1500-1800 K, dust is able to survive. It is thus possible to have a large dusty structure present which surrounds the AGN. This is the first of two papers aiming at comparing six dusty torus models with available SEDs, namely Fritz et al. (2006), Nenkova et al. (2008B), Hoenig & Kishimoto (2010), Siebenmorgen et al. (2015), Stalevski et al. (2016), and Hoenig & Kishimoto (2017). In this first paper we use synthetic spectra to explore the discrimination between these models and under which circumstances they allow to restrict the torus parameters, while our second paper analyzes the best model to describe the mid-infrared spectroscopic data. We have produced synthetic spectra from current instruments: GTC/CanariCam and Spitzer /IRS and future JWST/MIRI and JWST/NIRSpec instruments. We find that for a reasonable brightness (F12um > 100mJy) we can actually distinguish among models except for the two pair of parent models. We show that these models can be distinguished based on the continuum slopes and the strength of the silicate features. Moreover, their parameters can be constrained within 15% of error, irrespective of the instrument used, for all the models but Hoenig & Kishimoto (2017). However, the parameter estimates are ruined when more than 50% of circumnuclear contributors are included. Therefore, future high spatial resolution spectra as those expected from JWST will provide enough coverage and spatial resolution to tackle this topic.