A stellar census in globular clusters with MUSE: The contribution of rotation to cluster dynamics studied with 200 000 stars

TL;DR

This study uses MUSE spectroscopic data of 200,000 stars in 22 globular clusters to analyze their internal rotation and dynamics, revealing significant rotation in most clusters and its relation to cluster properties.

Contribution

First comprehensive analysis of internal rotation in a large sample of globular clusters using integral-field spectroscopy and advanced source deblending techniques.

Findings

Majority of clusters show significant internal rotation.

Rotation correlates with cluster ellipticity and relaxation times.

Dynamical distances are refined and agree better with other methods.

Abstract

This is the first of a series of papers presenting the results from our survey of 25 Galactic globular clusters with the MUSE integral-field spectrograph. In combination with our dedicated algorithm for source deblending, MUSE provides unique multiplex capabilities in crowded stellar fields and allows us to acquire samples of up to 20 000 stars within the half-light radius of each cluster. The present paper focuses on the analysis of the internal dynamics of 22 out of the 25 clusters, using about 500 000 spectra of 200 000 individual stars. Thanks to the large stellar samples per cluster, we are able to perform a detailed analysis of the central rotation and dispersion fields using both radial profiles and two-dimensional maps. The velocity dispersion profiles we derive show a good general agreement with existing radial velocity studies but typically reach closer to the cluster centres. By comparison with proper motion data we derive or update the dynamical distance estimates to 14 clusters. Compared to previous dynamical distance estimates for 47 Tuc, our value is in much better agreement with other methods. We further find significant (>3sigma) rotation in the majority (13/22) of our clusters. Our analysis seems to confirm earlier findings of a link between rotation and the ellipticities of globular clusters. In addition, we find a correlation between the strengths of internal rotation and the relaxation times of the clusters, suggesting that the central rotation fields are relics of the cluster formation that are gradually dissipated via two-body relaxation.