A chemical close-up of the main body of the Sagittarius dwarf galaxy

TL;DR

This study analyzes the chemical composition of 37 stars in the Sagittarius dwarf galaxy, revealing its unique nucleosynthetic history and differences from the Milky Way through high-resolution spectroscopic data.

Contribution

It provides detailed chemical abundances for stars in Sagittarius dwarf galaxy, highlighting its star formation history and nucleosynthetic processes with new high-resolution spectroscopic analysis.

Findings

Identifies the chemical transition point at [Fe/H]~-1.3 to -1.5 dex.

Shows lower contribution of hypernovae to Sagittarius compared to Milky Way.

Reveals high production of neutron-capture elements like Europium.

Abstract

We present the chemical composition of a sample of 37 red giant branch (RGB) stars belonging to the main body of the remnant of the Sagittarius (Sgr) dwarf spheroidal galaxy. All stars were observed with the FLAMES-UVES high-resolution spectrograph. Twenty-three new targets are selected along the blue side of the RGB of Sgr, but outside the galaxy stellar nucleus, in order to avoid contamination by the stars of the metal-poor globular cluster M54. Additionally, we re-analyzed archival spectra of fourteen targets located on the red RGB. For this sample, we derive the abundances of 21 chemical species (from Oxygen to Europium) representing different nucleosynthetic sites. The sample covers a large range of metallicity, from [Fe/H]~-2 to ~ -0.4 dex and we can identify the transition between the enrichment phases dominated by core-collapse (CC-SNe) and Type Ia (SNe-Ia) supernovae. The observed [{\alpha}/Fe] trend suggests a knee occurring at [Fe/H]~-1.5/-1.3 dex, compatible with the rather low star formation efficiency of Sgr. At lower [Fe/H], Sgr stars exhibit a chemical composition compatible with Milky Way stars of similar [Fe/H]. The only relevant exceptions are [Mn/Fe], [Zn/Fe], and [Eu/Fe]. At [Fe/H] higher than ~ -1.5/-1.3 dex, instead, the chemical pattern of Sgr significantly deviates from that of the Milky Way for almost all the elements analyzed in this study. Some of the abundance patterns reveal a lower contribution by very massive stars exploding as hypernovae (e.g. [Mn/Fe], [Zn/Fe]), a higher contribution by sub-Chandrasekhar progenitors of SNe Ia (e.g. [Ni/Fe]) and a high production efficiency of rapid neutron-capture elements ([Eu/Fe]).