Chromosome maps of Globular Clusters from wide-field ground-based photometry

TL;DR

This study develops a ground-based wide-field photometric method using chromosome maps to analyze multiple stellar populations in globular clusters, overcoming HST's limited field of view.

Contribution

It introduces a new wide-field chromosome map technique based on ground-based photometry to study the spatial distribution and properties of multiple populations in GCs.

Findings

Successfully applied to 43 GCs, revealing diverse population structures.

Identified significant variation in 1G/2G star fractions and subpopulation complexity.

Detected distinct sequences for metal-poor and metal-rich stars in Type II GCs.

Abstract

Hubble Space Telescope (HST) photometry is providing an extensive analysis of globular clusters (GCs). In particular, the pseudo two-colour diagram dubbed 'chromosome map (ChM)' allowed to detect and characterize their multiple populations with unprecedented detail. The main limitation of these studies is the small field of view of HST, which makes it challenging to investigate some important aspects of the multiple populations, such as their spatial distributions and the internal kinematics in the outermost cluster regions. To overcome this limitation, we analyse state-of-art wide-field photometry of 43 GCs obtained from ground-based facilities. We derived high-resolution reddening maps and corrected the photometry for differential reddening when needed. We use photometry in the U, B, and I bands to introduce the $\Delta c_{\rm U,B,I}$ vs. $\Delta_{\rm B,I}$ ChM of red-giant branch (RGB) and asymptotic-giant branch (AGB) stars. We demonstrate that this ChM, which is built with wide-band ground-based photometry, is an efficient tool to identify first- and second-generation stars (1G and 2G) over a wide field of view. To illustrate its potential, we derive the radial distribution of multiple populations in NGC 288 and infer their chemical composition. We present the ChMs of RGB stars in 29 GCs and detect a significant degree of variety. The fraction of 1G and 2G stars, the number of subpopulations, and the extension of the ChMs significantly change from one cluster to another. Moreover, the metal-poor and metal-rich stars of Type II GCs define distinct sequences in the ChM. We confirm the presence of extended 1G sequences.