Evolution of Structure in Late-type Spiral Galaxies I: Ionized Gas Kinematics in NGC 628

TL;DR

This study uses two-dimensional ionized gas kinematic data from NGC 628 to analyze galaxy structure, dynamics, and feedback processes, revealing a rapidly rotating inner disk, gas inflow, and feedback effects on velocity dispersion.

Contribution

It introduces new analytical tools for studying spiral galaxy evolution through detailed two-dimensional kinematic observations of ionized gas.

Findings

Detection of a rapidly rotating inner disk component.

Evidence of gas inflow towards the central regions.

Velocity dispersion remains nearly constant out to 12 kpc.

Abstract

We study two dimensional Fabry-Perot interferometric observations of the nearby face-on late-type spiral galaxy, NGC 628, in order to analyse the ionized gas component of the interstellar medium. Covering the galaxy out to a radius larger than 12 kpc, and with a spatial sampling of 1.6 arcsec, we investigate the large-scale dynamics as well as feedback from individual HII regions into their surrounding medium. We study the role of gravitational perturbations along with that of external triggers which can disturb the kinematics and morphology of NGC 628. We verify the presence of an inner rapidly rotating disc-like component in NGC 628, which we interpret as caused by slow secular evolution of the large-scale spiral arms and oval structure. In combination with auxiliary data, we find indication for that gas is falling in from the outer parts towards the central regions, where a nuclear ring has formed at the location of the inner Lindblad resonance radius of an m=2 perturbation which could help build a pseudo-bulge in NGC 628. Moreover, we calculate radial profiles of the emission-line velocity dispersion which we use to study the role of feedback from individual HII regions. The mean velocity dispersion for the ionized gas (even when excluding pixels belonging to individual HII regions) is almost constant out to 12 kpc, although it varies from 14 to 20 km/s, with a steady decline in the outer parts. The current paper demonstrates a number of tools that we have developed for building a solid frame work for studying the evolution of structure in spiral galaxies using two dimensional kinematic observations.