Oxygen-enhanced extremely metal-poor DLAs: A signpost of the first stars?

TL;DR

This study measures oxygen and iron abundances in two extremely metal-poor DLAs, providing insights into early star nucleosynthesis and suggesting signatures of Population III star enrichment.

Contribution

It offers the most precise [O/Fe] measurements in the most metal-poor DLAs, supporting the idea of elevated [O/Fe] at very low metallicities and linking observations to Population III supernova models.

Findings

[O/Fe] ratios are higher in the most metal-poor DLAs.

Enrichment consistent with Population III supernova yields.

Supports the existence of chemical signatures from the first stars.

Abstract

We present precise abundance determinations of two near-pristine damped Ly$\alpha$ systems (DLAs) to assess the nature of the [O/Fe] ratio at [Fe/H] < -3 (i.e. <1/1000 of the solar metallicity). Prior observations indicate that the [O/Fe] ratio is consistent with a constant value, [O/Fe] ~ +0.4, when -3 < [Fe/H] < -2, but this ratio may increase when [Fe/H] < -3. In this paper, we test this picture by reporting new, high-precision [O/Fe] abundances in two of the most metal-poor DLAs currently known. We derive values of [O/Fe] = +0.50 +/- 0.10 and [O/Fe] = +0.62 +/- 0.05 for these two z ~ 3 near-pristine gas clouds. These results strengthen the idea that the [O/Fe] abundances of the most metal-poor DLAs are elevated compared to DLAs with [Fe/H] > -3. We compare the observed abundance pattern of the latter system to the nucleosynthetic yields of Population III supernovae (SNe), and find that the enrichment can be described by a (19-25) M$_{\odot}$ Population III SN that underwent a (0.9-2.4)$\times 10^{51}$ erg explosion. These high-precision measurements showcase the behaviour of [O/Fe] in the most metal-poor environments. Future high-precision measurements in new systems will contribute to a firm detection of the relationship between [O/Fe] and [Fe/H]. These data will reveal whether we are witnessing a chemical signature of enrichment from Population III stars and allow us to rule out contamination from Population II stars.