Abstract
Observation of high energy cosmic neutrinos by ICECUBE has ushered in a new era in exploring both cosmos and new physics beyond the Standard Model (SM). In the standard picture, although mostly νμ and νe are produced in the source, oscillation will produce ντen route. Certain beyond SM scenarios, like interaction with ultralight DM can alter this picture. Thus, the flavor composition of the cosmic neutrino flux can open up the possibility of exploring certain beyond the SM scenarios that are inaccessible otherwise. We show that the τ flavor holds a special place among the neutrino flavors in elucidating new physics. Interpreting the two anomalous events observed by ANITA as ντ events makes the tau flavor even more intriguing. We study how the detection of the two tau events by ICECUBE constrains the interaction of the neutrinos with ultralight dark matter and discuss the implications of this interaction for even higher energy cosmic neutrinos detectable by future radio telescopes such as ARA, ARIANNA and GRAND. We also revisit the 3 + 1 neutrino scheme as a solution to the two anomalous ANITA events and clarify a misconception that exists in the literature about the evolution of high energy neutrinos in matter within the 3 + 1 scheme with a possibility of scattering off nuclei. We show that the existing bounds on the flux of ντ with energy of EeV rules out this solution for the ANITA events. We show that the 3 + 1 solution can be saved from both this bound and from the bound on the extra relativistic degrees of freedom in the early universe by turning on the interaction of neutrinos with ultralight dark matter.
Highlights
Produced in the stars or core collapse supernovae, in the atmosphere or in the anthropogenic sources, this induced mass is negligible compared to ∆m212/(2Eν) and its effects are negligible
Arrays of radio telescopes with huge coverage will make a breakthrough in studying the anticipated cosmogenic neutrinos as well as other possible neutrino fluxes with EeV range energies
While GRAND detector will be sensitive to the ντ flux by observing Extensive Air Showers initiated by ντ, ARA and ARIANNA can both detect such showers from ντ as well as the Askaryan radiation from all flavors
Summary
Produced in the stars or core collapse supernovae, in the atmosphere or in the anthropogenic sources, this induced mass is negligible compared to ∆m212/(2Eν) and its effects are negligible. ICECUBE has observed two τ neutrino events with total deposited energies of 100 TeV and 2 PeV [6], shifting the observed flavor pattern towards the SM prediction and ruling out the zero ντ flux hypothesis at 2.8 σ C.L. In this paper, we derive bounds on the parameters of the model considering this new observation and discuss that the dark matter effects proposed in [5] can still be significant for high energy cosmic neutrinos in the energy range of EeV.
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