A JWST project on 47 Tucanae. Binaries among multiple populations (2503.19214v1)

Abstract: Almost all globular clusters (GCs) contain multiple populations consisting of stars with varying helium and light-element abundances. These populations include first-population stars, which exhibit similar chemical compositions to halo-field stars with comparable [Fe/H], and second-population stars, characterized by enhanced He and N abundances along with reduced levels of O and C. Nowadays, one of the most intriguing open questions about GCs pertains to the formation and evolution of their multiple populations. Recent works based on N-body simulations of GCs show that the fractions and characteristics of binary stars can serve as dynamic indicators of the formation period of multiple-population in GCs and their subsequent dynamical evolution. Nevertheless, the incidence of binaries among multiple populations is still poorly studied. Moreover, the few available observational studies are focused only on the bright stars of a few GCs. In this work, we use deep images of the GC 47 Tucanae collected with the JWST and HST to investigate the incidence of binaries among multiple populations of M-dwarfs and bright main-sequence stars. To reach this objective, we use UV, optical, and near infrared filters to construct photometric diagrams that allow us to disentangle binary systems and multiple populations. Moreover, we compared these observations with a large sample of simulated binaries. In the cluster central regions, the incidence of binaries among first-population stars is only slightly higher than that of second-population stars. In contrast, in the external regions, the majority (>85%) of the studied binaries are composed of first population stars. Results are consistent with the GC formation scenarios where the second-population stars originate in the cluster's central region, forming a compact and dense stellar group within a more extended system of first-population stars