The Rise of the s-Process in the Galaxy

Astronomy; C. Sneden (1); J. Collier (2); J. E. Lawler (4) ((1) Department of Astronomy; J. J. Cowan (2); J. Simmerer (1); University of Oklahoma (3) Department of Astronomy; University of Texas at Austin (2) Department of Physics; University of Washington (4) Department of Physics; University of Wisconsin)

arxiv: astro-ph/0410396 · v1 · submitted 2004-10-15 · 🌌 astro-ph

The Rise of the s-Process in the Galaxy

J. Simmerer (1) , C. Sneden (1) , J. J. Cowan (2) , J. Collier (2) , V. M. Woolf (3) , J. E. Lawler (4) ((1) Department of Astronomy , University of Texas at Austin (2) Department of Physics , Astronomy

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University of Oklahoma (3) Department of Astronomy University of Washington (4) Department of Physics University of Wisconsin)

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keywords s-processstarsabundancesmetallicitysolarabundancechangingelements

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From newly-obtained high-resolution, high signal-to-noise ratio spectra the abundances of the elements La and Eu have been determined over the stellar metallicity range -3<[Fe/H]<+0.3 in 159 giant and dwarf stars. Lanthanum is predominantly made by the s-process in the solar system, while Eu owes most of its solar system abundance to the r-process. The changing ratio of these elements in stars over a wide metallicity range traces the changing contributions of these two processes to the Galactic abundance mix. Large s-process abundances can be the result of mass transfer from very evolved stars, so to identify these cases, we also report carbon abundances in our metal-poor stars. Results indicate that the s-process may be active as early as [Fe/H]=-2.6, alalthough we also find that some stars as metal-rich as [Fe/H]=-1 show no strong indication of s-process enrichment. There is a significant spread in the level of s-process enrichment even at solar metallicity.

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Reviewed papers in the Pith corpus that reference this work. Sorted by Pith novelty score.

Observational Signatures and Constraints on the Intermediate Neutron-Capture Process. The Case of the CEMP star TYC 6044-714-1 (RAVE J094921.8-161722)
astro-ph.SR 2026-05 conditional novelty 5.0

Abundances and Ba isotopic ratios in TYC 6044-714-1 are best reproduced by s+r nucleosynthesis models; i+s+r models require extreme conditions and fail to match the full pattern.
Observational Signatures and Constraints on the Intermediate Neutron-Capture Process. The Case of the CEMP star TYC 6044-714-1 (RAVE J094921.8-161722)
astro-ph.SR 2026-05 conditional novelty 4.0

High-precision abundances and Ba isotopic ratios in TYC 6044-714-1 favor an s+r nucleosynthesis scenario over i-process models, which require implausible conditions and mismatch isotopic data.