Star Clusters Across Cosmic Time
Abstract
Star clusters stand at the intersection of much of modern astrophysics: the interstellar medium, gravitational dynamics, stellar evolution, and cosmology. Here we review observations and theoretical models for the formation, evolution, and eventual disruption of star clusters. Current literature suggests a picture of this life cycle with several phases: (1) Clusters form in hierarchically-structured, accreting molecular clouds that convert gas into stars at a low rate per dynamical time until feedback disperses the gas. (2) The densest parts of the hierarchy resist gas removal long enough to reach high star formation efficiency, becoming dynamically-relaxed and well-mixed. These remain bound after gas removal. (3) In the first Myr after gas removal, clusters disperse moderately fast, through a combination of mass loss and tidal shocks by dense molecular structures in the star-forming environment. (4) After Myr, clusters lose mass via two-body relaxation and shocks by giant molecular clouds, processes that preferentially affect low-mass clusters and cause a turnover in the cluster mass function to appear on Gyr timescales. (5) Even after dispersal, some clusters remain coherent and thus detectable in chemical or action space for multiple galactic orbits. In the next decade a new generation of space- and AO-assisted ground-based telescopes will enable us to test and refine this picture.
Cite
@article{arxiv.1812.01615,
title = {Star Clusters Across Cosmic Time},
author = {Mark R. Krumholz and Christopher F. McKee and Joss Bland-Hawthorn},
journal= {arXiv preprint arXiv:1812.01615},
year = {2019}
}
Comments
To appear in Annual Reviews of Astronomy and Astrophysics; 76 pages, 15 figures; compared to previous version, this has some typo fixes, minor wording changes, and one new reference