A holistic abundance analysis of r-rich stars

TL;DR

This study analyzes the chemical abundances in r-rich metal-poor stars to understand the contributions of weak and main r-process nucleosynthesis, revealing distinct patterns and their relation to light and heavy neutron-capture elements.

Contribution

It introduces a model to distinguish the relative contributions of weak and main r-processes in metal-poor stars, linking abundance patterns to nucleosynthesis processes.

Findings

Light element patterns match weak r-process stars

Heavy neutron-capture elements resemble main r-process stars

Most stars' abundances are explained by mixed r-process material

Abstract

The chemical abundances of metal-poor stars are an excellent test bed by which to set new constraints on models of neutron-capture processes at low metallicity. Some r-process-rich (hereafter r-rich) metal-poor stars, such as HD221170, show an overabundance of the heavier neutron-capture elements and excesses of lighter neutron-capture elements. The study of these r-rich stars could give us a better understanding of weak and main r-process nucleosynthesis at low metallicity. Based on conclusions from the observation of metal-poor stars and neutron-capture element nucleosynthesis theory, we set up a model to determine the relative contributions from weak and main r-processes to the heavy-element abundances in metal-poor stars. Using this model, we find that the abundance patterns of light elements for most sample stars are close to the pattern of weak r-process stars, and those of heavier neutron-capture elements very similar to the pattern of main r-process stars, while the lighter neutron-capture elements can be fitted by the mixing of weak and main r-process material. The production of weak r-process elements appears to be associated with the light elements, while the production of main r-process elements is almost decoupled from that of the light elements. We compare our results with the observed data at low metallicities, showing that the predicted trends are in good agreement with the observed trends, at least for the metallicity range [Fe/H] < -2.1. For most sample stars, the abundance patterns of both neutron-capture elements and light elements could be best explained by a star formed in a molecular cloud that has been polluted by both weak and main r-process material.