Driving factors behind multiple populations

Star clusters were historically considered simple stellar populations, with all stars sharing the same age and initial chemical composition. However, the presence of chemical anomalies in globular clusters (GCs), called multiple stellar populations (MPs), has challenged star formation theories in de...

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Published inarXiv.org
Main Authors Huang, Ruoyun, Tang, Baitian, Li, Chengyuan, Geisler, Doug, Mateo, Mario, Ying-Yi, Song, Baumgardt, Holger, Carballo-Bello, Julio A, Wang, Yue, Nie, Jundan, Dias, Bruno, Fernández-Trincado, José G
Format Paper Journal Article
LanguageEnglish
Published Ithaca Cornell University Library, arXiv.org 31.01.2024
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Summary:Star clusters were historically considered simple stellar populations, with all stars sharing the same age and initial chemical composition. However, the presence of chemical anomalies in globular clusters (GCs), called multiple stellar populations (MPs), has challenged star formation theories in dense environments. Literature studies show that mass, metallicity, and age are likely controlling parameters for the manifestation of MPs. Identifying the limit between clusters with/without MPs in physical parameter space is crucial to reveal the driving mechanism behind their presence. In this study, we look for MP signals in Whiting 1, traditionally considered a young GC. Using the Magellan telescope, we obtained low-resolution spectra within \(\rm \lambda\lambda = 3850-5500 Å\) for eight giants of Whiting 1. We measured the C and N abundances from the CN and CH spectral indices. C and N abundances have variations comparable with their measurement errors (\(\sim0.1\) dex), suggesting that MPs are absent from Whiting 1. Combining these findings with literature studies, we propose a limit in the metallicity vs. cluster compactness index parameter space, which relatively clearly separates star clusters with/without MPs (GCs/open clusters). This limit is physically motivated. On a larger scale, the galactic environment determines cluster compactness and metallicity, leading to metal-rich, diffuse, old clusters formed ex situ. Our proposed limit also impacts our understanding of the formation of the Sagittarius dwarf galaxy: star clusters formed after the first starburst (age\(\lesssim 8-10\) Gyr). These clusters are simple stellar populations because the enriched galactic environment is no longer suitable for MP formation.
ISSN:2331-8422
DOI:10.48550/arxiv.2401.17584