Co-production of light p-, s- and r-process isotopes in the high-entropy wind of type II supernovae

Abstract

We have performed large-scale nucleosynthesis calculations within the high-entropy-wind (HEW) scenario of type II supernovae. The primary aim was to constrain the conditions for the production of the classical "p-only" isotopes of the light trans-Fe elements. We find, however, that for electron fractions in the range 0.458 Ye 0.478, sizeable abundances of p-, s- and r-process nuclei between 64Zn and 98Ru are coproduced in the HEW at low entropies (S 100) by a primary charged-particle process after an α-rich freezeout. With the above Ye -- S correlation, most of the predicted isotopic abundance ratios within a given element (e.g. 64Zn(p)/70Zn(r) or 92Mo(p)/94Mo(p)), as well as of neighboring elements (e.g. 70Ge(s+p)/74Se(p) or 74Se(p)/78Kr(p)) agree with the observed Solar-System ratios. Taking the Mo isotopic chain as a particularly challenging example, we show that our HEW model can account for the production of all 7 stable isotopes, from "p-only" 92Mo, via "s-only" 96Mo up to "r-only" 100Mo. Furthermore, our model is able to reproduce the isotopic composition of Mo in presolar SiC X-grains.