Evolution of the Barium abundance in the early Galaxy from a NLTE analysis of the Ba lines in a homogeneous sample of EMP stars

TL;DR

This study investigates the evolution of barium in the early Galaxy by applying non-LTE analysis to a sample of extremely metal-poor stars, revealing nuanced abundance trends and suggesting complex nucleosynthesis processes.

Contribution

It introduces a non-LTE method for more accurate Ba abundance measurements in EMP stars, improving understanding of early galactic chemical evolution.

Findings

[Ba/Fe] ratios are slightly closer to solar with NLTE corrections.

The [Ba/Fe] trend decreases with metallicity, with a slope of about 1.4.

Large scatter in [Ba/Fe] indicates complex production and mixing processes.

Abstract

Barium is a key element in constraining the evolution of the (not well understood) r-process in the first galactic stars and currently the Ba abundances in these very metal-poor stars were mostly measured under the Local Thermodynamical Equilibrium (LTE) assumption, which may lead in general to an underestimation of Ba. We present here determinations of the barium abundance taking into account the non-LTE (NLTE) effects in a sample of extremely metal-poor stars (EMP stars): 6 turnoff stars and 35 giants. The NLTE profiles of the three unblended Ba II lines (455.4, 585.3, 649.6nm) have been computed. The computations were made with a modified version of the MULTI code, applied to an atomic model of the Ba atom with 31 levels of Ba I, 101 levels of Ba II, and compared to the observations. The ratios of the NLTE abundances of barium relative to Fe are slightly shifted towards the solar ratio. In the plot of [Ba/Fe] versus [Fe/H], the slope of the regression line is slightly reduced as is the scatter. In the interval -3.3 <[Fe/H] < -2.6, [Ba/Fe] decreases with a slope of about 1.4 and a scatter close to 0.44. For [Fe/H] <-3.3 the number of stars is not sufficient to decide whether [Ba/Fe] keeps decreasing (and then CD-38:245 should be considered as a peculiar "barium-rich star") or if a plateau is reached as soon as [Ba/Fe] ~ -1. In both cases the scatter remains quite large, larger than what can be accounted for by the measurement and determination errors, suggesting the influence of a complex process of Ba production, and/or inefficient mixing in the early Galaxy.