Using two HST/ACS data-sets that are separated by ~2 years has allowed us to derive the relative proper-motion for the Sagittarius dwarf irregular (SagDIG) and reduce the heavy foreground Galactic contamination. The proper-motion decontaminated SagDI
G catalog provides a much clearer view of the young red-supergiant and intermediate-age asymptotic giant branch populations. We report the identification of 3 Milky Way carbon-rich dwarf stars, probably belonging to the thin disk, and pointing to the high incidence of this class at low Galactic latitudes. A sub-group of 4 oxygen-rich candidate stars depicts a faint, red extension of the well-defined SagDIG carbon-rich sequence. The origin of these oxygen-rich candidate stars remains unclear, reflecting the uncertainty in the ratio of carbon/oxygen rich stars. SagDIG is also a gas-rich galaxy characterized by a single large cavity in the gas disk (HI-hole), which is offset by ~360 pc from the optical centre of the galaxy. We nonetheless investigate the stellar feedback hypothesis by comparing the proper-motion cleaned stellar populations within the HI-hole with appropriately selected comparison regions, having higher HI densities external to the hole. The comparison shows no significant differences. In particular, the centre of the HI-hole (and the comparison regions) lack stellar populations younger than ~400 Myr, which are otherwise abundant in the inner body of the galaxy. We conclude that there is no convincing evidence that the SagDIG HI-hole is the result of stellar feedback, and that gravitational and thermal instabilities in the gas are the most likely mechanism for its formation.
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.
