Nucleosynthesis and the Inhomogeneous Chemical Evolution of the Carina Dwarf Galaxy

TL;DR

This study analyzes the chemical abundances of stars in the Carina dwarf galaxy, revealing inhomogeneous mixing, star formation history, and evidence for supernova-driven winds affecting its chemical evolution.

Contribution

It provides the first detailed chemical abundance analysis of Carina's stars, linking star formation events to supernova enrichment and wind-driven mass loss in a dwarf galaxy.

Findings

Evidence for inhomogeneous mixing in Carina.

Star formation occurred in alpha-enriched gas.

Low [Sr/Ba], [Na/Fe], [Mn/Fe], and [Cr/Fe] suggest SN II driven winds.

Abstract

The detailed abundances of 23 elements in nine bright RGB stars in the Carina dSph are presented based on high resolution spectra gathered at the VLT and Magellan telescopes. A spherical model atmospheres analysis is applied using standard methods to spectra ranging from 380 to 680 nm. The stars in this analysis range from -2.9 < [Fe/H] < -1.3, and adopting the ages determined by Lemasle et al. (2012), we are able to examine the chemical evolution of Carina's old and intermediate-aged populations. One of the main results from this work is the evidence for inhomogeneous mixing in Carina; a large dispersion in [Mg/Fe] indicates poor mixing in the old population, an offset in the [alpha/Fe] ratios between the old and intermediate-aged populations (when examined with previously published results) suggests that the second star formation event occurred in alpha-enriched gas, and one star, Car-612, seems to have formed in a pocket enhanced in SN Ia/II products. This latter star provides the first direct link between the formation of stars with enhanced SN Ia/II ratios in dwarf galaxies to those found in the outer Galactic halo (Ivans et al. 2003). Another important result is the potential evidence for SN II driven winds. We show that the very metal-poor stars in Carina have not been enhanced in AGB or SN Ia products, and therefore their very low ratios of [Sr/Ba] suggests the loss of contributions from the early SNe II. Low ratios of [Na/Fe], [Mn/Fe], and [Cr/Fe] in two of these stars support this scenario, with additional evidence from the low [Zn/Fe] upper limit for one star. It is interesting that the chemistry of the metal-poor stars in Carina is not similar to those in the Galaxy, most of the other dSphs, or the UFDs, and suggests that Carina may be at the critical mass where some chemical enrichment events are lost through SN II driven winds.