Heavy-neutrino decays at neutrino telescopes

Abstract

It has been recently proposed that a sterile neutrino h of mass mh=40--80 MeV, mixing |Uμ h|2=10-3--10-2, lifetime τh 10-9 s, and a dominant decay mode (h μ γ) could be the origin of the experimental anomalies observed at LSND, KARMEN and MiniBooNE. Such a particle would be abundant inside air showers, as it can be produced in kaon decays (K -> h μ, KL -> h π μ). We use the Z-moment method to evaluate its atmospheric flux and the frequency of its decays inside neutrino telescopes. We show that the h would imply around 104 contained showers per year inside a 0.03 km3 telescope like ANTARES or the DeepCore in IceCube. These events would have a characteristic energy and zenith-angle distribution (E = 0.1--10 TeV and θ < 90o), which results from a balance between the reach of the heavy neutrino (that disfavors low energies) and a sizeable production rate and decay probability. The standard background from contained neutrino events (e N e X and neutral-current interactions of high inelasticity) is 100 times smaller. Therefore, although it may be challenging from an experimental point of view, a search at ANTARES and IceCube could confirm this heavy-neutrino possibility.