Angular momentum drives proton-rich nucleosynthesis in hyperaccreting neutron stars in common envelopes

TL;DR

This paper investigates how angular momentum in hyperaccreting neutron stars during common envelope evolution influences nucleosynthesis, revealing new pathways for element formation and contributions to galactic chemical evolution.

Contribution

It introduces a detailed nucleosynthesis model for accretion disk ejected material in neutron star common envelope systems, highlighting the role of angular momentum in element synthesis.

Findings

Significant rp-process element production in accretion disk ejecta.

Formation of alpha-rich, supernova-like nucleosynthesis products such as $^{44}$Ti and $^{56}$Ni.

Potential contribution of these processes to galactic chemical evolution.

Abstract

Interacting binaries can produce a wide range of exotic systems, including X-ray binaries and merging neutron stars, through a mass transfer phase called Common Envelope (CE) evolution. A CE phase can occur during rapid expansion as a star as it moves off the main sequence. If the engulfed star is a compact object (e.g. neutron star), a CE phase can lead to hyperaccretion onto the neutron star. Previous work focused on systems in which the accreting material has low angular momentum, studying turbulent outflows. This study investigates the impact of angular momentum on accreting material leading to the formation of an accretion disk. Disk accretion systems lead to very different nuclear burning conditions. This paper presents the results of nucleosynthesis modelling of material ejected from an accretion disk surrounding a 1.5 M$_{\odot}$ neutron star in a CE with a 15 M$_{\odot}$ companion. As material is accreted towards the neutron star, sufficient heating will occur to eject a fracton of the material back into the surrounding envelope, producing a nucleosynthetic yield signature that differs from other explosions. We find that significant mass fractions of rp-process products are synthesised, thereby providing another mechanism for rp-process contribution to galactic chemical evolution, following ejection of the CE. Furthermore, later stages of the CE evolution the accrete helium leading to alpha-rich, supernova-like nucleosynthesis, producing $^{44}$Ti and $^{56}$Ni. Further work on modelling both the accretion disk wind, and the companion envelope ejection, is vital to understand the contributions of these scenarios to chemical evolution.