Neutrino Nucleosynthesis of radioactive nuclei in supernovae

Abstract

We study the neutrino-induced production of nuclides in explosive supernova nucleosynthesis for progenitor stars with solar metallicity and initial main sequence masses between 15 M and 40 M. We improve previous investigations i) by using a global set of partial differential cross sections for neutrino-induced charged- and neutral-current reactions on nuclei with charge numbers Z < 76 and ii) by considering modern supernova neutrino spectra which have substantially lower average energies compared to those previously adopted in neutrino nucleosynthesis studies. We confirm the production of 7Li, 11B, 138La, and 180Ta by neutrino nucleosynthesis, albeit at slightly smaller abundances due to the changed neutrino spectra. We find that for stars with a mass smaller than 20 M, 19F is produced mainly by explosive nucleosynthesis while for higher mass stars it is produced by the process. We also find that neutrino-induced reactions, either directly or indirectly by providing an enhanced abundance of light particles, noticeably contribute to the production of the radioactive nuclides 22Na and 26Al. Both nuclei are prime candidates for gamma-ray astronomy. Other prime targets, 44Ti and 60Fe, however, are insignificantly produced by neutrino-induced reactions. We also find a large increase in the production of the long-lived nuclei 92Nb and 98Tc due to charged-current neutrino capture.