Abstract
In very dense environments, neutrinos can undergo fast flavor conversions on scales as short as a few centimeters provided that the angular distribution of the neutrino lepton number crosses zero. This work presents the first attempt to establish whether the non-negligible abundance of muons and their interactions with neutrinos in the core of supernovae can affect the occurrence of such crossings. For this purpose we employ state-of-the-art one-dimensional core-collapse supernova simulations, considering models that include muon-neutrino interactions as well as models without these reactions. Although a consistent treatment of muons in the equation of state and neutrino transport does not seem to modify significantly the conditions for the occurrence of fast modes, it allows for the existence of an interesting phenomenon, namely fast instabilities in the $\mu-\tau$ sector. We also show that crossings below the supernova shock are a relatively generic feature of the one-dimensional simulations under investigation, which contrasts with the previous reports in the literature. Our results highlight the importance of multi-dimensional simulations with muon creation, where our results must be tested in the future.
Highlights
At the end of their lives, massive stars (M ≳ 8 M⊙) may undergo a violent explosion, labeled as core-collapse supernova (CCSN)
(ii) D2, presented already in Ref. [39], it includes 11, 15, and 25 M⊙ progenitors, where muons were not included. In these two data sets we look for the presence of electron lepton number (ELN) crossings through the method proposed in Ref. [40], which is based on the moments of the neutrino angular distributions
III we review the mathematical framework proposed in Ref. [40] to assess the presence of crossings by just using the moments of the neutrino angular distributions
Summary
At the end of their lives, massive stars (M ≳ 8 M⊙) may undergo a violent explosion, labeled as core-collapse supernova (CCSN). During such an event, about 1053 ergs of energy is released into neutrinos of all flavors, corresponding to about 99% of the total released gravitational energy. About 1053 ergs of energy is released into neutrinos of all flavors, corresponding to about 99% of the total released gravitational energy Such neutrinos are thought to be a crucial ingredient of the astrophysical processes leading to the final explosion. Neutrinos might deposit enough energy to revive the shock, leading to the explosion.
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