Ionized gas kinematics within the inner kiloparsec of the Seyfert galaxy NGC 1365

TL;DR

This study uses integral field spectroscopy to analyze ionized gas kinematics in the inner kiloparsec of NGC 1365, revealing dominant rotation, a potential outflow, and complex gas motions possibly linked to angular momentum loss.

Contribution

First detailed integral field spectroscopic analysis of ionized gas kinematics within NGC 1365's inner kiloparsec, highlighting rotation, outflows, and gas inflow signatures.

Findings

Gas kinematics consistent with galaxy rotation.

Evidence of a fan-shaped outflow in ionized gas.

No clear signs of gas inflowing along nuclear spirals.

Abstract

We observed the nuclear region of the galaxy NGC 1365 with the integral field unit of the Gemini Multi Object Spectrograph mounted on the GEMINI-South telescope. The field of view covers $13^{\prime\prime} \times 6^{\prime\prime}$ ($1173 \times 541$ pc$^{2}$) centered on the nucleus, at a spatial resolution of $52$ pc. The spectral coverage extends from $5600$ \AA\ to $7000$ \AA, at a spectral resolution $R=1918$. NGC 1365 hosts a Seyfert 1.8 nucleus, and exhibits a prominent bar extending out to $100^{\prime\prime}$ (9 kpc) from the nucleus. The field of view lies within the inner Lindblad resonance. Within this region, we found that the kinematics of the ionized gas (as traced by [OI], [NII], H$\alpha$, and [SII]) is consistent with rotation in the large-scale plane of the galaxy. While rotation dominates the kinematics, there is also evidence for a fan-shaped outflow, as found in other studies based on the [OIII] emission lines. Although evidence for gas inflowing along nuclear spirals has been found in a few barred galaxies, we find no obvious signs of such features in the inner kiloparsec of NGC 1365. However, the emission lines exhibit a puzzling asymmetry that could originate from gas which is slower than the gas responsible for the bulk of the narrow-line emission. We speculate that it could be tracing gas which lost angular momentum, and is slowly migrating from the inner Lindblad resonance towards the nucleus of the galaxy.