The Circumnuclear Molecular Gas in the Seyfert Galaxy NGC4945

TL;DR

This study maps the molecular gas and dust in the central region of NGC 4945, revealing an inclined rotating disk with a potential circumnuclear torus, providing insights into the galaxy's active nucleus and starburst activity.

Contribution

First high-resolution mapping of molecular gas and dust in NGC 4945's nucleus, identifying a kinematically-decoupled component as a potential AGN torus.

Findings

Detected an inclined rotating molecular disk with solid-body rotation within 95 pc.

Discovered a dense, kinematically-decoupled central component as a candidate for the AGN torus.

Most dust emission is likely heated by star formation, not the AGN.

Abstract

We have mapped the central region of NGC 4945 in the $J=2\to1$ transition of $^{12}$CO, $^{13}$CO, and C$^{18}$O, as well as the continuum at 1.3 mm, at an angular resolution of $5\farc \times 3\farc$ with the Submillimeter Array. The relative proximity of NGC 4945 (distance of only 3.8 Mpc) permits a detailed study of the circumnuclear molecular gas and dust in a galaxy exhibiting both an AGN (classified as a Seyfert 2) and a circumnuclear starburst in an inclined ring with radius $\sim$2\farcs5 ($\sim$50 pc). We find that all three molecular lines trace an inclined rotating disk with major axis aligned with that of the starburst ring and large-scale galactic disk, and which exhibits solid-body rotation within a radius of $\sim$5\farc ($\sim$95 pc). We infer an inclination for the nuclear disk of $62^{\circ} \pm 2^{\circ}$, somewhat smaller than the inclination of the large-scale galactic disk of $\sim$$78^{\circ}$. The continuum emission at 1.3 mm also extends beyond the starburst ring, and is dominated by thermal emission from dust. If it traces the same dust emitting in the far-infrared, then the bulk of this dust must be heated by star-formation activity rather than the AGN. We discover a kinematically-decoupled component at the center of the disk with a radius smaller than $1\farcs4$ (27 pc), but which spans approximately the same range of velocities as the surrounding disk. This component has a higher density than its surroundings, and is a promising candidate for the circumnuclear molecular torus invoked by AGN unification models.