Kinematics of stellar substructures in the Small Magellanic Cloud

TL;DR

This study provides a detailed kinematic analysis of the Small Magellanic Cloud using spectroscopic data, revealing velocity structures linked to its interaction with the Large Magellanic Cloud and recent star formation episodes.

Contribution

It offers the first comprehensive radial velocity map of the SMC across multiple stellar populations, highlighting dynamical effects of tidal interactions and recent star formation history.

Findings

Mean radial velocity of 159 km/s for the galaxy

Velocity differences linked to tidal interactions with LMC

Star formation episodes influence local stellar velocities

Abstract

We present a kinematic analysis of the Small Magellanic Cloud using 3700 spectra extracted from the European Southern Observatory archive. We used data from Gaia and near-infrared photometry to select stellar populations and discard Galactic foreground stars. The sample includes main-sequence, red giant branch and red clump stars, observed with the Fibre Large Array Multi Wavelength Spectrograph. The spectra have a resolving power lambda/Delta(lambda) from 6500 to 38000. We derive radial velocities by employing a full spectrum fitting method using a penalised pixel fitting routine. We obtain a mean radial velocity for the galaxy of 159+/-2 km/s, with a velocity dispersion of 33+/-2 km/s. Our velocities agree with literature estimates for similar (young or old) stellar populations. The radial velocity of stars in the Wing and bar-like structure differ as a consequence of the dynamical interaction with the Large Magellanic Cloud. The higher radial velocity of young main-sequence stars in the bar compared to that of supergiants can be attributed to star formation around 40 Myr ago from gas already influenced by tidal stripping. Similarly, young main-sequence stars in the northern part of the bar, resulting from a prominent episode 25 Myr ago, have a higher radial velocity than stars in the southern part. Radial velocity differences between the northern and southern bar over densities are also traced by giant stars. They are corroborated by studies of the cold gas and proper motion indicating stretching/tidal stripping of the galaxy.