Resolving the nuclear obscuring disk in the Compton-thick Seyfert galaxy NGC5643 with ALMA

TL;DR

This study uses high-resolution ALMA observations to resolve the nuclear molecular gas disk in NGC5643, revealing its structure, kinematics, and role as the obscuring torus and collimating structure of the ionization cone in this Compton-thick Seyfert galaxy.

Contribution

First high-resolution ALMA imaging of NGC5643's nuclear molecular disk, elucidating its structure, kinematics, and role as the obscuring torus in a Compton-thick Seyfert galaxy.

Findings

Detected a 26 pc inclined nuclear CO(2--1) disk.

Identified non-circular motions possibly due to radial outflows.

Estimated nuclear gas mass of 1.1×10^7 solar masses.

Abstract

We present ALMA Band 6 $^{12}$CO(2--1) line and rest-frame 232GHz continuum observations of the nearby Compton-thick Seyfert galaxy NGC5643 with angular resolutions 0.11-0.26arcsec (9-21pc). The CO(2--1) integrated line map reveals emission from the nuclear and circumnuclear region with a two-arm nuclear spiral extending 10arcsec on each side. The circumnuclear CO(2--1) kinematics can be fitted with a rotating disk, although there are regions with large residual velocities and/or velocity dispersions. The CO(2--1) line profiles of these regions show two different velocity components. One is ascribed to the circular component and the other to the interaction of the AGN outflow, as traced by the [O III]5007AA emission, with molecular gas in the disk a few hundred parsecs from the AGN. On nuclear scales, we detected an inclined CO(2--1) disk (diameter 26 pc, FWHM) oriented almost in a north-south direction. The CO(2--1) nuclear kinematics can be fitted with a rotating disk which appears to be tilted with respect to the large scale disk. There are strong non-circular motions in the central 0.2-0.3 arcsec with velocities of up to 110km/s. In the absence of a nuclear bar, these motions could be explained as radial outflows in the nuclear disk. We estimate a total molecular gas mass for the nuclear disk of $M({\rm H}_2)=1.1\times 10^7\,M_\odot$ and an H$_2$ column density toward the location of the AGN of $N({\rm H}_2)\sim 5 \times 10^{23}\,{\rm cm}^{-2}$, for a standard CO-to-H$_2$ conversion factor. We interpret this nuclear molecular gas disk as the obscuring torus of NGC5643 as well as the collimating structure of the ionization cone.