The Astrophysical Journal (Jan 2023)

SPLUS J142445.34–254247.1: An r-process–enhanced, Actinide-boost, Extremely Metal-poor Star Observed with GHOST

  • Vinicius M. Placco,
  • Felipe Almeida-Fernandes,
  • Erika M. Holmbeck,
  • Ian U. Roederer,
  • Mohammad K. Mardini,
  • Christian R. Hayes,
  • Kim Venn,
  • Kristin Chiboucas,
  • Emily Deibert,
  • Roberto Gamen,
  • Jeong-Eun Heo,
  • Miji Jeong,
  • Venu Kalari,
  • Eder Martioli,
  • Siyi Xu,
  • Ruben Diaz,
  • Manuel Gomez-Jimenez,
  • David Henderson,
  • Pablo Prado,
  • Carlos Quiroz,
  • Roque Ruiz-Carmona,
  • Chris Simpson,
  • Cristian Urrutia,
  • Alan W. McConnachie,
  • John Pazder,
  • Gregory Burley,
  • Michael Ireland,
  • Fletcher Waller,
  • Trystyn A. M. Berg,
  • J. Gordon Robertson,
  • Zachary Hartman,
  • David O. Jones,
  • Kathleen Labrie,
  • Gabriel Perez,
  • Susan Ridgway,
  • Joanna Thomas-Osip

DOI
https://doi.org/10.3847/1538-4357/ad077e
Journal volume & issue
Vol. 959, no. 1
p. 60

Abstract

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We report on a chemo-dynamical analysis of SPLUS J142445.34−254247.1 (SPLUS J1424−2542), an extremely metal-poor halo star enhanced in elements formed by the rapid neutron-capture process ( r -process). This star was first selected as a metal-poor candidate from its narrowband S-PLUS photometry and followed up spectroscopically in medium resolution with Gemini-South/GMOS, which confirmed its low-metallicity status. High-resolution spectroscopy was gathered with GHOST at Gemini-South, allowing for the determination of the chemical abundances for 36 elements, from carbon to thorium. At [Fe/H] = −3.39, SPLUS J1424−2542 is one of the lowest-metallicity stars with measured Th and has the highest $\mathrm{log}\epsilon (\mathrm{Th}/\mathrm{Eu})$ observed to date, making it part of the “actinide-boost” category of r -process–enhanced stars. The analysis presented here suggests that the gas cloud from which SPLUS J1424−2542 formed must have been enriched by at least two progenitor populations. The light-element ( Z ≤ 30) abundance pattern is consistent with the yields from a supernova explosion of metal-free stars with 11.3–13.4 M _⊙ , and the heavy-element ( Z ≥ 38) abundance pattern can be reproduced by the yields from a neutron star merger (1.66 M _⊙ and 1.27 M _⊙ ) event. A kinematical analysis also reveals that SPLUS J1424−2542 is a low-mass, old halo star with a likely in situ origin, not associated with any known early merger events in the Milky Way.

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