Abundances in Metal-Poor Stars and Chemical Evolution of the Early Galaxy

TL;DR

This study refines models of early galactic chemical evolution by incorporating hypernovae as key sources of certain elements, aligning predictions with observed metal-poor star compositions.

Contribution

It introduces a three-component model including hypernovae, resolving previous conflicts and better matching observed element abundances in metal-poor stars.

Findings

Hypernovae contribute ~24% of solar Fe

Normal supernovae contribute ~9% of solar Fe

Model accurately fits observed element abundances in metal-poor stars

Abstract

We have attributed the elements from Sr through Ag in stars of low metallicities ([Fe/H] < -1.5) to charged-particle reactions (CPR) in neutrino-driven winds, which are associated with neutron star formation in low-mass and normal supernovae (SNe) from progenitors of ~ 8 to 11 M_sun and ~ 12 to 25 M_sun, respectively. Using this rule and attributing all Fe production to normal SNe, we previously developed a phenomenological two-component model, which predicts that [Sr/Fe] > -0.32 for all metal-poor stars. This is in direct conflict with the high-resolution data now available, which show that there is a great shortfall of Sr relative to Fe in many stars with [Fe/H] < -3. The same conflict also exists for the CPR elements Y and Zr. We show that the data require a stellar source leaving behind black holes and that hypernovae (HNe) from progenitors of ~ 25 to 50 M_sun are the most plausible candidates. If we expand our previous model to include three components (low-mass and normal SNe and HNe), we find that essentially all of the data are very well described by the new model. The HN yield pattern for the low-A elements from Na through Zn (including Fe) is inferred from the stars deficient in Sr, Y, and Zr. We estimate that HNe contributed ~ 24% of the bulk solar Fe inventory while normal SNe contributed only ~ 9% (not the usually assumed ~ 33%). This implies a greatly reduced role of normal SNe in the chemical evolution of the low-A elements.