The Star Formation & Chemical Evolution History of the Sculptor Dwarf Spheroidal Galaxy

TL;DR

This study combines deep photometry and spectroscopic data to produce the most detailed star formation and chemical evolution history of the Sculptor dwarf spheroidal galaxy, revealing its complex, radially-dependent stellar populations and enrichment timescales.

Contribution

It provides the first detailed, spatially-resolved star formation and chemical evolution history of Sculptor, linking individual stellar ages with chemical abundance trends.

Findings

Old, metal-poor stars dominate at all radii.

Younger, metal-rich stars are more centrally concentrated.

Sculptor formed 7.8 million solar masses of stars between 14 and 7 Gyr ago.

Abstract

We have combined deep photometry in the B,V and I bands from CTIO/MOSAIC of the Sculptor dwarf spheroidal galaxy, going down to the oldest Main Sequence Turn-Offs, with spectroscopic metallicity distributions of Red Giant Branch stars. This allows us to obtain the most detailed and complete Star Formation History to date, as well as an accurate timescale for chemical enrichment. The Star Formation History shows that Sculptor is dominated by old ($>$10 Gyr), metal-poor stars, but that younger, more metal-rich populations are also present. Using Star Formation Histories determined at different radii from the centre we show that Sculptor formed stars with an increasing central concentration with time. The old, metal-poor populations are present at all radii, while more metal-rich, younger stars are more centrally concentrated. We find that within an elliptical radius of 1 degree, or 1.5 kpc from the centre, a total mass in stars of 7.8$\times10^{6}$ M$_{\odot}$ was formed, between 14 and 7 Gyr ago, with a peak at 13$-$14 Gyr ago. We use the detailed Star Formation History to determine age estimates for individual Red Giant Branch stars with high resolution spectroscopic abundances. Thus, for the first time, we can directly determine detailed timescales for the evolution of individual chemical elements. We find that the trends in alpha-elements match what is expected from an extended, relatively uninterrupted period of star formation continuing for 6$-$7 Gyr. The knee in the alpha-element distribution occurs at an age of 10.9$\pm$1Gyr, suggesting that SNe Ia enrichment began $\approx2\pm$1Gyr after the start of star formation in Sculptor.