New Hubble Space Telescope Observations of Heavy Elements in Four Metal-Poor Stars

TL;DR

This study uses Hubble and ground-based telescopes to analyze heavy element abundances in four metal-poor stars, revealing r-process nucleosynthesis signatures and detecting elements only observable in the near-ultraviolet.

Contribution

First detailed heavy element abundance patterns in metal-poor stars using near-ultraviolet spectroscopy, including detection of seven elements only observable in this range.

Findings

Heavy elements in stars are mainly produced by r-process nucleosynthesis.

Detected up to 34 elements heavier than zinc in four stars.

Tellurium scales with rare earth and third r-process peak elements.

Abstract

Elements heavier than the iron group are found in nearly all halo stars. A substantial number of these elements, key to understanding neutron-capture nucleosynthesis mechanisms, can only be detected in the near-ultraviolet. We report the results of an observing campaign using the Space Telescope Imaging Spectrograph on board the Hubble Space Telescope to study the detailed heavy element abundance patterns in four metal-poor stars. We derive abundances or upper limits from 27 absorption lines of 15 elements produced by neutron-capture reactions, including seven elements (germanium, cadmium, tellurium, lutetium, osmium, platinum, and gold) that can only be detected in the near-ultraviolet. We also examine 202 heavy element absorption lines in ground-based optical spectra obtained with the Magellan Inamori Kyocera Echelle Spectrograph on the Magellan-Clay Telescope at Las Campanas Observatory and the High Resolution Echelle Spectrometer on the Keck I Telescope on Mauna Kea. We have detected up to 34 elements heavier than zinc. The bulk of the heavy elements in these four stars are produced by r-process nucleosynthesis. These observations affirm earlier results suggesting that the tellurium found in metal-poor halo stars with moderate amounts of r-process material scales with the rare earth and third r-process peak elements. Cadmium often follows the abundances of the neighboring elements palladium and silver. We identify several sources of systematic uncertainty that must be considered when comparing these abundances with theoretical predictions. We also present new isotope shift and hyperfine structure component patterns for Lu II and Pb I lines of astrophysical interest.