Mu- and Tau-Neutrino Spectra Formation in Supernovae

Abstract

The mu- and tau-neutrinos emitted from a proto-neutron star are produced by nucleonic bremsstrahlung N + N -> N + N + nu + nu-bar and pair annihilation e+ + e- -> nu + nu-bar, reactions which freeze out at the "energy sphere." Before escaping from there to infinity the neutrinos diffuse through the "scattering atmosphere," a layer where their main interaction is elastic scattering on nucleons nu + N -> N + nu. If these collisions are taken to be iso-energetic as in all numerical supernova simulations, the neutrino flux spectrum escaping to infinity depends only on the medium temperature TES and the thermally averaged optical depth tauES at the energy sphere. For tauES = 10-50 one finds for the spectral flux temperature of the escaping neutrinos Tflux = 0.5-0.6 TES. Including energy exchange (nucleon recoil) in nu + N -> N + nu can shift Tflux both up or down. Delta Tflux depends on tauES, on the scattering atmosphere's temperature profile, and on TES. Based on a numerical study we find that for typical conditions Delta Tflux/Tflux is between -10% and -20%, and even for extreme parameter choices does not exceed -30%. The exact value of Delta Tflux/Tflux is surprisingly insensitive to the assumed value of the nucleon mass, i.e. the exact efficiency of energy transfer between neutrinos and nucleons is not important as long as it can occur at all. Therefore, calculating the numu and nutau spectra does not seem to require a precise knowledge of the nuclear medium's dynamical structure functions.

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