Possible effects of collective neutrino oscillations in the three flavor multi-angle simulations on supernova p process

Abstract

We study the effects of collective neutrino oscillations on p process nucleosynthesis in proton-rich neutrino-driven winds by including both the multi-angle 3×3 flavor mixing and the nucleosynthesis network calculation. The number flux of energetic electron antineutrinos is raised by collective neutrino oscillations in a 1D supernova model for 40 M progenitor. When the gas temperature decreases down to 2-3×109 K, the increased flux of electron antineutrinos promotes p process more actively, resulting in the enhancement of p-nuclei. In the early phase of neutrino-driven wind, blowing at 0.6 s after core bounce, oscillation effects are prominent in inverted mass hierarchy and p-nuclei are synthesized up to 106Cd and 108Cd. On the other hand, in the later wind trajectory at 1.1 s after core bounce, abundances of p-nuclei are increased remarkably by 10-104 times in normal mass hierarchy and even reaching heavier p-nuclei such as 124Xe, 126Xe and 130Ba. The averaged overproduction factor of p-nuclei is dominated by the later wind trajectories. Our results demonstrate that collective neutrino oscillations can strongly influence p process, which indicates that they should be included in the network calculations in order to obtain precise abundances of p-nuclei. The conclusions of this paper depend on the difference of initial neutrino parameters between electron and non-electron antineutrino flavors which is large in our case. Further systematic studies on input neutrino physics and wind trajectories are necessary to draw a robust conclusion. However, this finding would help understand the origin of solar-system isotopic abundances of p-nuclei such as 92,94Mo and 96,98Ru.