Nucleosynthesis in neutrino-driven winds in hypernovae

Abstract

We investigate the nucleosynthesis in the neutrino-driven winds blown off from a 3M massive proto-neutron star (mPNS) temporarily formed during the collapse of a 100M star. Such mPNSs would be formed in hypernovae. We construct steady and spherically symmetric wind solutions. We set large neutrino luminosities of 1053\ erg\ s-1 and average energies of electron neutrinos and antineutrinos in the ranges of ε_e=9-16\ MeV and ε_e=11-18\ MeV based on a recent numerical relativity simulation. The wind solutions indicate much shorter temperature-decrease timescale than that of the winds from ordinary PNSs and, depending on ε, the winds can be both neutron-rich and proton-rich. In the neutron-rich wind, the r-process occurs and the abundance distribution of a fiducial wind model of the mPNS gives an approximate agreement with the abundance pattern of metal-poor weak r star HD~122563, although the third-peak elements are produced only when the e energy is much larger than the e energy. In the proton-rich wind, the strong p-process occurs and A>100 nuclides are synthesized. The synthesized nuclei can be neutron-rich in some cases because the large neutrino luminosity of the mPNS supplies a sufficient amount of neutrons.