Recent Advances in Understanding R-Process Nucleosynthesis in Metal-Poor Stars and Stellar Systems

TL;DR

This review discusses recent progress in understanding the astrophysical origins of r-process nucleosynthesis, emphasizing neutron star mergers and other potential sites, through stellar observations, gravitational wave detections, and theoretical models.

Contribution

It synthesizes recent observational and theoretical advances, highlighting the role of neutron star mergers and exploring the possibility of additional r-process sources in early universe stars.

Findings

Neutron star mergers confirmed as r-process sites by GW170817.

Old stars show r-process signatures suggesting multiple sources.

Synergy of observations and models is advancing understanding.

Abstract

The rapid neutron-capture process (r-process) is responsible for the creation of roughly half of the elements heavier than iron, including precious metals like silver, gold, and platinum, as well as radioactive elements such as thorium and uranium. Despite its importance, the nature of the astrophysical sites where the r-process occurs, and the detailed mechanisms of its formation, remain elusive. The key to resolving these mysteries lies in the study of chemical signatures preserved in ancient, metal-poor stars. In this review, we explore r-process nucleosynthesis, focusing on the sites, progenitors, and formation mechanisms. We discuss the role of potential astrophysical sites such as neutron star mergers, core-collapse supernovae, magneto-rotational supernovae, and collapsars, that can play a key role in producing the heavy elements. We also highlight the importance of studying these signatures through high-resolution spectroscopic surveys, stellar archaeology, and multi-messenger astronomy. Recent advancements, such as the gravitational wave event GW170817 and detection of the r-process in the ejecta of its associated kilonovae, have established neutron star mergers as one of the confirmed sites. However, questions remain regarding whether they are the only sites that could have contributed in early epochs or if additional sources are needed to explain the signatures of r-process found in the oldest stars. Additionally, there are strong indications pointing towards additional sources of r-process-rich nuclei in the context of Galactic evolutionary timescales. This review summarizes what has been learned so far, the challenges that remain, and the exciting prospects for future discoveries. The increasing synergy between observational facilities, computational models, and large-scale surveys is poised to transform our understanding of r-process nucleosynthesis in the coming years.