Second generation star formation in globular clusters of different masses

TL;DR

This study uses hydrodynamical simulations to explore how second-generation stars form in globular clusters of varying masses, revealing how cluster mass and environmental density influence the distribution and composition of these stars.

Contribution

It provides new insights into the formation and distribution of second-generation stars in globular clusters across different masses and environmental conditions.

Findings

Lower density environments produce compact, He-rich second-generation stars.

Higher density environments lead to more extended, less He-enhanced second-generation populations.

Positive correlation between second-generation star ratio and initial cluster mass.

Abstract

By means of three-dimensional hydrodynamical simulations, we investigate the formation of second generation (SG) stars in young globular clusters of different masses. We consider clusters with a first generation of asymptotic giant branch (AGB) stars with mass 10^5 and 10^6 Msun moving at constant velocity through a uniform gas with density 10^(-24) and 10^(-23) g cm^(-3). Our setup is designed to reproduce the encounter of a young cluster with a reservoir of dense gas, e. g. during its orbital motion in the host galaxy. In the low-density models, as a result of the cooling AGB ejecta which collect in the centre, weakly perturbed by the external ram pressure, a compact central He-rich SG stellar component is formed on a timescale which decreases with increasing initial cluster mass. Our high-density models are subject to stronger ram pressure, which prevents the accumulation of the most He-rich AGB ejecta in the cluster centre. As a result, the SG is more extended and less He-enhanced than in the low-density models. By combining our results with previous simulations, we are able to study relevant, cluster-related scaling relations across a dynamical range of two orders of magnitude in mass (from 10^5 Msun to 10^7 Msun). In agreement with current observationally-based estimates, we find positive correlations between the SG-to-total number ratio and maximum He enhancement in SG stars as a function of the initial cluster mass.