Nucleosynthesis in the Innermost Ejecta of Neutrino-Drive Supernova Explosions in Two Dimensions

Abstract

We examine the nucleosynthesis in the innermost, neutrino-processed ejecta (a few 10-3\,M) of self-consistent, two-dimensional explosion models of core-collapse supernovae for six progenitor stars with different initial masses. Three models have initial masses near the low-mass end of the supernova range, 8.8\,M (e8.8; electron-capture supernova), 9.6\,M (z9.6), and 8.1\,M (u8.1), with initial metallicities of 1, 0, and 10-4 times the solar metallicity, respectively. The other three are solar-metallicity models with initial masses of 11.2\,M (s11), 15\,M (s15), and 27\,M (s27). The low-mass models e8.8, z9.6, and u8.1 exhibit high production factors (nucleosynthetic abundances relative to the solar ones) of 100--200 for light trans-iron elements from Zn to Zr. This is associated with appreciable ejection of neutron-rich matter in these models. Remarkably, the nucleosynthetic outcomes for progenitors e8.8 and z9.6 are almost identical, including interesting productions of 48Ca and 60Fe, irrespective of their quite different (O-Ne-Mg and Fe) cores prior to collapse. In the more massive models s11, s15, and s27, several proton-rich isotopes of light trans-iron elements, including the p-isotope 92Mo (for s27) are made, up to production factors of 30. Both electron-capture and core-collapse supernovae near the low-mass end can therefore be dominant contributors to the Galactic inventory of light trans-iron elements from Zn to Zr and probably 48Ca and live 60Fe. The innermost ejecta of more massive supernovae may have only sub-dominant contributions to the chemical enrichment of the Galaxy except for 92Mo.