Heavy elements in barium stars

TL;DR

This study presents new measurements of neutron-capture element abundances in 180 barium giant stars, revealing overabundances linked to past nucleosynthesis in binary systems and highlighting areas where current models need improvement.

Contribution

It provides a comprehensive set of elemental abundances for barium stars and compares them with nucleosynthesis models, identifying discrepancies that suggest the need for new theoretical developments.

Findings

Barium stars show overabundance of neutron-capture elements except Eu.

Re-determined La abundances are significantly lower than previous reports.

Observed element ratios challenge existing nucleosynthesis models.

Abstract

New elemental abundances for the neutron-capture elements Sr, Nb, Mo, Ru, La, Sm, and Eu are presented for a large sample of 180 barium (Ba) giant stars, a class of chemically peculiar objects that exhibit in their spectra enhancements of the elements created by the $s$-process, as a consequence of mass transfer between the components of a binary system. The content of heavy elements in these stars, in fact, points to nucleosynthesis mechanisms that took place within a former asymptotic giant branch (AGB) companion, now an invisible white dwarf. From high-resolution ($R=48000$) spectra in the optical, we derived the abundances either by equivalent width measurements or synthetic spectra computations, and compared them with available data for field giant and dwarf stars in the same range of metallicity. A re-determination of La abundances resulted in [La/Fe] ratios up to 1.2 dex lower than values previously reported in literature. The program Ba stars show overabundance of neutron-capture elements, except for Eu, for which the observational data set behave similarly to field stars. Comparison to model predictions are satisfactory for second-to-first $s$-process peak ratios (e.g., [La/Sr]) and the ratios of the predominantly $r$-process element Eu to La. However, the observed [Nb,Mo,Ru/Sr] and [Ce,Nd,Sm/La] ratios show median values higher or at the upper limits of the ranges of the model predictions. This unexplained feature calls for new neutron capture models to be investigated.