Does the chemical signature of TYC 8442-1036-1 originate from a rotating massive star that died in a faint explosion?

TL;DR

This study investigates whether the chemical signature of the extremely metal-poor star TYC 8442-1036-1 can be explained by the nucleosynthesis of rotating massive stars and faint supernovae, providing insights into early universe chemical enrichment.

Contribution

It demonstrates that combining models of rotating massive stars with faint supernovae better explains the star's chemical signatures than previous models.

Findings

Star has [Fe/H] = -3.5, lower than low-resolution estimates.

Star is not carbon-enhanced, unlike most at this metallicity.

Chemical patterns suggest a role for both rotating massive stars and faint supernovae.

Abstract

Context. We have recently investigated the origin of chemical signatures observed in Galactic halo stars by means of a stochastic chemical evolution model. We have found that rotating massive stars are a promising way to explain several signatures observed in these fossil stars. Aims. In the present paper we discuss how the extremely metal-poor halo star TYC 8442-1036-1, for which we have now obtained detailed abundances from VLT-UVES spectra, fits into the framework of our previous work. Methods. We apply a standard 1D LTE analysis to the spectrum of this star. We measure the abundances of 14 chemical elements; for Na, Mg, Ca, Sc, Ti, V, Cr, Mn, Fe, Ni and Zn we compute the abundances using equivalent widths; for C, Sr and Ba we obtain the abundances by means of synthetic spectra generated by MOOG. Results. We find an abundance of [Fe/H]= $-$3.5 $\pm$0.13 dex based on our high resolution spectrum; this points to an iron content lower by a factor of three (0.5 dex) compared to the one obtained by a low resolution spectrum. The star has a [C/Fe] = 0.4 dex, and it is not carbon enhanced like most of the stars at this metallicity. Moreover, this star lies in the plane [Ba/Fe] vs. [Fe/H] in a relatively unusual position, shared by a few others galactic halo stars that is only marginally explained by our past results. Conclusions. The comparison of the model results with the chemical abundance characteristics of this group of stars can be improved if we consider in our model the presence of faint supernovae coupled with rotating massive stars. These results seem to imply that rotating massive stars and faint supernovae scenarios are complementary to each other, and are both required in order to match the observed chemistry of the earliest phases of the chemical enrichment of the Universe.