Inhomogeneity in the early Galactic chemical enrichment exposed by beryllium abundances in extremely metal-poor stars

TL;DR

This study investigates beryllium abundances in extremely metal-poor stars to understand early Galactic chemical inhomogeneity, revealing a potential flattening in Be abundance at very low metallicities linked to inhomogeneous star formation.

Contribution

It provides new measurements of Be in extremely metal-poor stars and discusses the implications for early Galactic chemical inhomogeneity and star formation conditions.

Findings

Be abundances are mostly constant at low metallicities.

Some stars show Be levels below the typical plateau.

Inhomogeneous star formation explains the observed flattening.

Abstract

Abundances of beryllium in metal-poor stars scale linearly with metallicity down to [Fe/H] ~ -3.0. In the stars where Be has been detected at this extremely metal-poor regime, an increased abundance scatter has been previously reported. This scatter could indicate a flattening of the relation between Be and [Fe/H]. Our aim is to perform a new investigation of Be abundances in extremely metal-poor stars and try to clarify whether a Be abundance plateau exists. We revisited the Be abundances in a sample of nine dwarfs with [Fe/H] ~ -3.0. Additionally, we analysed the Be lines in the spectra of stars BPS BS 16968-0061 and CD-33 1173 for the first time. We took advantage of Gaia DR2 parallaxes to refine values of the surface gravity of the stars. Abundances of Be were determined using spectrum synthesis. Some of the stars indeed suggest a flattening. Between [Fe/H] ~ -2.70 and -3.26, the Be abundances stay mostly constant at log(Be/H) ~ -13.2 dex. Nevertheless, for several stars we could only place upper limits that are below that level. Most of the sample stars are consistent with having been formed at the progenitor of the so-called Gaia-Enceladus merger. Two out of the three stars likely formed in-situ are the ones that deviate the most from the linear relation. The mixed origin of these stars offers a clue to understanding the flattening. We suggest that our observations can be understood as a consequence of the inhomogeneous star forming conditions in the early Galaxy. Without efficient mixing, the early ISM would be characterised by a large scatter in Fe abundances at a given moment. Beryllium, on the other hand, because of its origins in cosmic-ray spallation, would have more homogeneous abundances (in a Galaxy-wide sense). We therefore suggest that the observed flattening of the Be-versus-Fe relation reflects a stronger scatter in the Galactic Fe abundances at a given age [abridged].