Nucleosynthesis in Electron Capture Supernovae of AGB Stars

TL;DR

This study investigates nucleosynthesis in electron capture supernovae of AGB stars, revealing unique element production patterns and implications for faint supernova observations and galactic chemical evolution.

Contribution

It provides detailed nucleosynthesis results for electron capture supernovae from AGB stars, highlighting distinct element yields and their astrophysical implications.

Findings

Small 56Ni production explains faint supernovae properties.

Large production of 64Zn, 70Ge, and light p-nuclei observed.

Overproduction of 90Zr is sensitive to Y_e variations.

Abstract

We examine nucleosynthesis in the electron capture supernovae of progenitor AGB stars with an O-Ne-Mg core (with the initial stellar mass of 8.8 M_\odot). Thermodynamic trajectories for the first 810 ms after core bounce are taken from a recent state-of-the-art hydrodynamic simulation. The presented nucleosynthesis results are characterized by a number of distinct features that are not shared with those of other supernovae from the collapse of stars with iron core (with initial stellar masses of more than 10 M_\odot). First is the small amount of 56Ni (= 0.002-0.004 M_\odot) in the ejecta, which can be an explanation for observed properties of faint supernovae such as SNe 2008S and 1997D. In addition, the large Ni/Fe ratio is in reasonable agreement with the spectroscopic result of the Crab nebula (the relic of SN 1054). Second is the large production of 64Zn, 70Ge, light p-nuclei (74Se, 78Kr, 84Sr, and 92Mo), and in particular, 90Zr, which originates from the low Y_e (= 0.46-0.49, the number of electrons per nucleon) ejecta. We find, however, that only a 1-2% increase of the minimum Y_e moderates the overproduction of 90Zr. In contrast, the production of 64Zn is fairly robust against a small variation of Y_e. This provides the upper limit of the occurrence of this type of events to be about 30% of all core-collapse supernovae.