Abstract
The heavy elements (Z > 30) are created in neutron (n)-capture processes that are predicted to happen at vastly different nucleosynthetic sites. To study these processes in an environment different from the Milky Way, we targeted the n-capture elements in red giant branch stars in the Sculptor dwarf spheroidal galaxy. Using ESO VLT/FLAMES spectra, we measured the chemical abundances of Y, Ba, La, Nd, and Eu in 98 stars covering the metalliticy range −2.4 < [Fe/H] < −0.9. This is the first paper in a series about the n-capture elements in dwarf galaxies, and here we focus on the relative and absolute timescales of the slow (s)- and rapid (r)-processes in Sculptor. From the abundances of the s-process element Ba and the r-process element Eu, it is clear that the r-process enrichment occurred throughout the entire chemical evolution history of Sculptor. Furthermore, there is no evidence for the r-process to be significantly delayed in time relative to core-collapse supernovae. Neutron star mergers are therefore unlikely the dominant (or only) nucleosynthetic site of the r-process. However, the products of the s-process only become apparent at [Fe/H] ≈ −2 in Sculptor, and the s-process becomes the dominant source of Ba at [Fe/H] ≳ −2. We tested the use of [Y/Mg] and [Ba/Mg] as chemical clocks in Sculptor. Similarly to what is observed in the Milky Way, [Y/Mg] and [Ba/Mg] increase towards younger ages. However, there is an offset in the trends, where the abundance ratios of [Y/Mg] in Sculptor are significantly lower than those of the Milky Way at any given age. This is most likely caused by metallicity dependence of yields from the s-process, as well as by a different relative contribution of the s-process to core-collapse supernovae in these galaxies. Comparisons of our results with data of the Milky Way and the Fornax dwarf spheroidal galaxy furthermore show that these chemical clocks depend on both metallicity and environment.
Highlights
Chemical elements heavier than zinc are created in processes where a seed nucleus undergoes neutron (n)-capture and consequent β-decays to form an isotope with a higher atomic mass (Burbidge et al 1957; Sneden et al 2008; Nomoto et al 2013; Frebel 2018)
The stellar sample consists of 98 red giant branch (RGB) stars, which were previously identified as members of the Sculptor dwarf spheroidal (dSph) by Hill et al (2019)
Spectra obtained with the European Organisation for Astronomical Research (ESO) VLT/FLAMES spectrograph were used to study the heavy elements in 98 stars in the Sculptor dSph galaxy, covering the metallicity range −2.4 < [Fe/H] < −0.9
Summary
Chemical elements heavier than zinc are created in processes where a seed nucleus undergoes neutron (n)-capture and consequent β-decays to form an isotope with a higher atomic mass (Burbidge et al 1957; Sneden et al 2008; Nomoto et al 2013; Frebel 2018). The heavy elements from the s-process are released into the environment through stellar winds, with time delays depending on the lifetimes (and masses) of the stars. A second paper, (Neutron-capture elements in dwarf galaxies II: Challenges for the s- and i-processes at low metallicity, hereafter Paper II; Skúladóttir et al, in prep.), will discuss the implications of these new data for the s-process and LEPP in Sculptor. We can study the n-capture processes in a system that has a very different chemical enrichment history from the Milky Way. Using Sculptor as a laboratory allows us to address some of the most pressing questions of the s- and r-processes, such as their time-delay distribution and the effects of environment on the enrichment processes
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