Towards a complete reconstruction of supernova neutrino spectra in future large liquid-scintillator detectors

Abstract

In this paper, we show how to carry out a relatively more realistic and complete reconstruction of supernova neutrino spectra in the future large liquid-scintillator detectors, by implementing the method of singular value decomposition with a proper regularization. For a core-collapse supernova at a distance of 10~ kpc in the Milky Way, its e spectrum can be precisely determined from the inverse beta-decay process e + p e+ + n, for which a 20~ kiloton liquid-scintillator detector with the resolution similar to the Jiangmen Underground Neutrino Observatory (JUNO) may register more than 5000 events. We have to rely predominantly on the elastic neutrino-electron scattering + e- + e- and the elastic neutrino-proton scattering + p + p for the spectra of e and x, where denotes collectively neutrinos and antineutrinos of all three flavors and x for μ and τ as well as their antiparticles. To demonstrate the validity of our approach, we also attempt to reconstruct the neutrino spectra by using the time-integrated neutrino data from the latest numerical simulations of delayed neutrino-driven supernova explosions.