Morphology and kinematics of the gas in M51: How interaction with NGC5195 has moulded the structure of its arms

TL;DR

This study analyzes the gas morphology and velocity in M51 to understand how interactions with NGC5195 have shaped its spiral arms, revealing resonance zones and kinematic features linked to recent galactic encounters.

Contribution

It provides a detailed kinematic analysis of M51's gas and links observed features to a numerical model of its interaction history with NGC5195, highlighting the impact of recent passes.

Findings

Resonance zones align with spiral arms and are more prominent in the stronger arm.

Kinks in the arms correspond to recent interaction events with NGC5195.

Velocity maps reveal gas flow reversals at specific galactocentric radii.

Abstract

The Whirlpool Galaxy is a well studied grand design galaxy with two major spiral arms, and a large satellite NGC 5195. The arms both show long uniform sections with perturbations ('kinks' or sharp turns) in specific regions. Comparing the two arms shows a small radial offset between the main kinked regions. We analysed the morphology and also the velocity field in the disk of M51 using kinematic maps based on H$\alpha$ and CO line emission. These sample complementary radial ranges, with the CO map covering the central zone and the H$\alpha$ map extending to cover the outer zone. We looked for indicators of density wave resonance, zones where radial flows of gas in the disk plane reverse their sign. These were present in both velocity maps; their two-dimensional localization placed them along or closely parallel to the spiral arms, at a set of well defined galactocentric radii, and notably more concentrated along the southern, stronger arm. The results can be well interpreted quantitatively, using a numerical model of the interaction of M51 and NGC5195 in which the satellite has made two relatively recent passes through the disk plane of M51. During the first pass the pair of dominant spiral arms was stimulated, and during the second pass the strong kinks in both arms were formed at about the same time. The second interaction is particularly well characterised, because the timescale corresponding to the production of the kinks and the recovery of the original pitch angle is identical for the two arms.