Impact of supernova dynamics on the \nu p-process

TL;DR

This study examines how the late-time dynamics of supernova ejecta influence u p-process nucleosynthesis, revealing that slower expansion and shock effects enable the formation of heavier elements beyond iron.

Contribution

It introduces the impact of dynamical evolution, including reverse shocks, on u p-process nucleosynthesis and identifies the NiCu cycle affecting element production.

Findings

Faster expansion limits heavy element synthesis beyond A=64.

Reverse shocks extend high-temperature conditions, promoting heavier element formation.

Identification of the NiCu cycle at high temperatures.

Abstract

We study the impact of the late time dynamical evolution of ejecta from core-collapse supernovae on \nu p-process nucleosynthesis. Our results are based on hydrodynamical simulations of neutrino wind ejecta. Motivated by recent two-dimensional wind simulations, we vary the dynamical evolution during the \nu p-process and show that final abundances strongly depend on the temperature evolution. When the expansion is very fast, there is not enough time for antineutrino absorption on protons to produce enough neutrons to overcome the \beta-decay waiting points and no heavy elements beyond A=64 are produced. The wind termination shock or reverse shock dramatically reduces the expansion speed of the ejecta. This extends the period during which matter remains at relatively high temperatures and is exposed to high neutrino fluxes, thus allowing for further (p,\gamma) and (n,p) reactions to occur and to synthesize elements beyond iron. We find that the \nu p-process starts to efficiently produce heavy elements only when the temperature drops below ~3 GK. At higher temperatures, due to the low alpha separation energy of 60Zn (S_{\alpha} = 2.7 MeV) the reaction 59Cu(p,\alpha)56Ni is faster than the reaction 59Cu(p,\gamma)60Zn. This results in the closed NiCu cycle that we identify and discuss here for the first time. We also investigate the late phase of the \nu p-process when the temperatures become too low to maintain proton captures. Depending on the late neutron density, the evolution to stability is dominated by \beta decays or by (n,\gamma) reactions. In the latter case, the matter flow can even reach the neutron-rich side of stability and the isotopic composition of a given element is then dominated by neutron-rich isotopes.