Red Giants in the Small Magellanic Cloud. I. Disk and Tidal Stream Kinematics

TL;DR

This study provides a detailed spectroscopic analysis of red giant stars in the Small Magellanic Cloud, revealing complex kinematic structures, evidence of rotation, and tidal interactions with the Magellanic Bridge and Counter-Bridge.

Contribution

It offers new insights into the kinematic behavior of SMC stars, including rotation patterns and tidal features, challenging previous models and enhancing understanding of its dynamical state.

Findings

Detection of rotation with specific position angle and inclination.

Identification of tidal tail and Counter-Bridge kinematic signatures.

Variation in velocity dispersion between metal-poor and metal-rich stars.

Abstract

We present results from an extensive spectroscopic survey of field stars in the Small Magellanic Cloud (SMC). 3037 sources, predominantly first-ascent red giants, spread across roughly 37.5 sq. deg, are analysed. The line of sight velocity field is dominated by the projection of the orbital motion of the SMC around the LMC/Milky Way. The residuals are inconsistent with both a non-rotating spheroid and a nearly face on disk system. The current sample and previous stellar and HI kinematics can be reconciled by rotating disk models with line of nodes position angle, theta, ~ 120-130 deg., moderate inclination (i ~ 25-70 deg.), and rotation curves rising at 20-40 km/s/kpc. The metal-poor stars exhibit a lower velocity gradient and higher velocity dispersion than the metal-rich stars. If our interpretation of the velocity patterns as bulk rotation is appropriate, then some revision to simulations of the SMC orbit is required since these are generally tuned to the SMC disk line-of-nodes lying in a NE-SW direction. Residuals show strong spatial structure indicative of non-circular motions that increase in importance with increasing distance from the SMC centre. Kinematic substructure in the north-west part of our survey area is associated with the tidal tail or Counter-Bridge predicted by simulations. Lower line-of-sight velocities towards the Wing and the larger velocities just beyond the SW end of the SMC Bar are probably associated with stellar components of the Magellanic Bridge and Counter-Bridge, respectively. Our results reinforce the notion that the intermediate-age stellar population of the SMC is subject to substantial stripping by external forces.