VLT/UVES Abundances in Four Nearby Dwarf Spheroidal Galaxies. II. Implications for Understanding Galaxy Evolution

Abstract

We have used UVES on VLT-UT2 to take spectra of 15 individual red giant stars in the centers of four nearby dwarf spheroidal galaxies: Sculptor, Fornax, Carina and Leo I. We measure the abundance variations of numerous elements in these low mass stars with a range of ages (1-15Gyr old). This means that we can effectively measure the chemical evolution of these galaxies WITH TIME. Our results show a significant spread in metallicity with age, but an overall trend consistent with what might be expected from a closed (or perhaps leaky) box chemical evolution scenario over the last 10-15Gyr. We notice that each of these galaxies show broadly similar abundance patterns for all elements measured. This suggests a fairly uniform progression of chemical evolution with time, despite quite a large range of star formation histories. It seems likely that these galaxies had similar initial conditions, and evolve in a similar manner with star formation occurring at a uniformly low rate, even if at different times. With our accurate measurements we find evidence for small variations in abundances which are correlated to variations in star formation histories. The alpha-elements suggest that dSph chemical evolution has not been affected by very high mass stars (>15-20 Msun). The abundance patterns we measure for stars in dwarf spheroidal galaxies are significantly different from those typically observed in the disk, bulge and inner-halo of our Galaxy. This suggests that it is NOT possible to construct a significant fraction of our Galaxy from STARS formed in these dwarf spheroidal galaxies which subsequently merged into our own. Any merger scenario involving dSph has to occur in the very early Universe whilst they are still gas rich, so the majority of mass transfer is gas, and few stars.