A spectroscopic census of the M82 stellar cluster population

TL;DR

This spectroscopic study of 49 star clusters in M82 reveals their ages, velocities, and formation history, indicating recent cluster formation linked to galaxy interactions and ongoing starburst activity.

Contribution

It provides the largest spectroscopic dataset of extragalactic young clusters, offering detailed insights into their ages, kinematics, and the galaxy's structure and interaction history.

Findings

Clusters formed mainly during the last 270 Myr.

Clusters in the disk are on regular orbits consistent with galaxy rotation.

Potential discovery of two old halo clusters over 8 Gyr old.

Abstract

We present a spectroscopic study of the stellar cluster population of M82, the archetype starburst galaxy, based primarily on new Gemini-North multi-object spectroscopy of 49 star clusters. These observations constitute the largest to date spectroscopic dataset of extragalactic young clusters, giving virtually continuous coverage across the galaxy; we use these data to deduce information about the clusters as well as the M82 post-starburst disk and nuclear starburst environments. Spectroscopic age-dating places clusters in the nucleus and disk between (7, 15) and (30, 270) Myr, with distribution peaks at ~10 and ~140 Myr respectively. We find cluster radial velocities in the range (-160, 220) km/s (wrt the galaxy centre) and line of sight Na I D interstellar absorption line velocities in (-75, 200) km/s, in many cases entirely decoupled from the clusters. As the disk cluster radial velocities lie on the flat part of the galaxy rotation curve, we conclude that they comprise a regularly orbiting system. Our observations suggest that the largest part of the population was created as a result of the close encounter with M81 ~220 Myr ago. Clusters in the nucleus are found in solid body rotation on the bar. The possible detection of WR features in their spectra indicates that cluster formation continues in the central starburst zone. We also report the potential discovery of two old populous clusters in the halo of M82, aged >8 Gyr. Using these measurements and simple dynamical considerations, we derive a toy model for the invisible physical structure of the galaxy, and confirm the existence of two dominant spiral arms.