The M4 Core Project with HST is designed to exploit the Hubble Space Telescope to investigate the central regions of M4, the Globular Cluster closest to the Sun. In this paper we combine optical and near-infrared photometry to study multiple stellar
populations in M4. We detected two sequences of M-dwarfs containing ~38% (MS_I) and ~62% (MS_II) of MS stars below the main-sequence (MS) knee. We compare our observations with those of NGC2808, which is the only other GCs where multiple MSs of very low-mass stars have been studied to date. We calculate synthetic spectra for M-dwarfs, assuming the chemical composition mixture inferred from spectroscopic studies of stellar populations along the red giant branch, and different Helium abundances, and we compare predicted and observed colors. Observations are consistent with two populations, one with primordial abundance and another with enhanced nitrogen and depleted oxygen.
We present a general overview and the first results of the SUMO project (a SUrvey of Multiple pOpulations in Globular Clusters). The objective of this survey is the study of multiple stellar populations in the largest sample of globular clusters homo
geneously analysed to date. To this aim we obtained high signal-to-noise (S/N>50) photometry for main sequence stars with mass down to ~0.5 M_SUN in a large sample of clusters using both archival and proprietary U, B, V, and I data from ground-based telescopes. In this paper, we focus on the occurrence of multiple stellar populations in twenty three clusters. We have defined a new photometric index cubi= (U-B)-(B-I), that turns out to be very effective for identifying multiple sequences along the red giant branch (RGB). We found that in the V-cubi diagram all clusters presented in this paper show broadened or multimodal RGBs, with the presence of two or more components. We found a direct connection with the chemical properties of different sequences, that display different abundances of light elements (O, Na, C, N, and Al). The cubi index is also a powerful tool to identify distinct sequences of stars along the horizontal branch and, for the first time in the case of NGC104 (47 Tuc), along the asymptotic giant branch. Our results demonstrate that i) the presence of more than two stellar populations is a common feature among globular clusters, as already highlighted in previous work; ii) multiple sequences with different chemical contents can be easily identified by using standard Johnson photometry obtained with ground-based facilities; iii) in the study of GC multiple stellar populations the cubi index is alternative to spectroscopy, and has the advantage of larger statistics.
The discovery of multiple MSs in NGC2808 and Omega Centauri, and multiple SGBs in NGC1851 and NGC6388 has challenged the long-held paradigm that GCs consist of simple stellar populations. This picture has been further complicated by recent studies of
the LMC intermediate-age clusters, where the MSTO was found to be bimodal or broadened. We have undertaken a study of archival HST images of LMC and SMC clusters with the aim of measuring the frequency of clusters with evidence of multiple or prolonged star formation events and determining their main properties. In this paper, we analyse the CMD of 16 intermediate-age LMC clusters. We find that 11 clusters show an anomalous spread (or split) in color and magnitude around the MSTO. We demonstrate that the observed feature is unequivocally associated to the clusters and that it is not an artifact due to photometric errors, differential reddening or binaries. We confirm that NGC 1806 and NGC 1846 clearly exhibit two distinct MSTOs and observe, for the first time, a double MSTO in NGC 1751. In these three clusters the population corresponding to the brighter MSTO includes more than two-thirds of cluster stellar population. We confirm the presence of multiple stellar populations in NGC 1783 and suggest that the MSTO of this cluster is formed by two distinct branches. In 7 clusters (ESO057-SC075, HODGE7, NGC1852, NGC1917, NGC1987, NGC2108, and NGC2154) we observed an intrinsic broadening of the MSTO that may suggest that these clusters have experienced a prolonged period of star formation (150-250 Myr). The CMDs of IC2146, NGC1644, NGC1652, NGC1795 and NGC1978 show no evidence of spread or bimodality. In summary 70$pm$25% of our sample are not consistent with the simple, single stellar population hypotesis.
