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Abstract
We consider the effects of active-sterile secret neutrino interactions, mediated by a new pseudoscalar particle, on high- and ultra high-energy neutrino fluxes. In particular, we focus on the case of 3 active and 1 sterile neutrino coupled by a flavor dependent interaction, extending the case of 1 active and 1 sterile neutrino we have recently examined. We find that, depending on the kind of interaction of sterile neutrino with the active sector, new regions of the parameter space for secret interactions are now allowed leading to interesting phenomenological implications on two benchmark fluxes we consider, namely an astrophysical power law flux, in the range below 100 PeV, and a cosmogenic flux, in the Ultrahigh energy range. First of all, the final active fluxes can present a measurable depletion observable in future experiments. Especially, in the case of only tau neutrino interacting, we find that the effects on the astrophysical power law flux can be so large to be already probed by the IceCube experiment. Moreover, we find intriguing features in the energy dependence of the flavor ratio.
Highlights
High energy neutrinos can be produced by the interactions of high and ultrahigh energy cosmic rays
In our previous paper [34], we found that the regeneration was unimportant for a limited region of the parameter space, with masses of sterile neutrino and scalar mediator around 250 MeV
We have investigated the effects on high and ultrahigh energy active neutrino fluxes due to active-sterile secret interactions mediated by a new pseudoscalar particle
Summary
High energy neutrinos can be produced by the interactions of high and ultrahigh energy cosmic rays. We approach this issue, investigating the more general case 3 and 1 (three active and one sterile neutrino νs), where the interaction is possibly flavor dependent and mediated by a pseudoscalar particle φ. We reach the conclusion that a combined analysis of the energy and flavor structure of the astrophysical neutrino fluxes in the energy region above the PeV would allow us to provide definite information about the possibility of active-neutrino sterile interactions. If the scalar mediator were completely stable, with no other decay channels, the t resonance comes unregulated, giving rise to a nonintegrable pole in the differential cross section and a diverging total cross section. IV B, the dependence of our results on this assumption
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