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Atmospheric and Solar Neutrinos with a Heavy Singlet

Abstract

We follow a minimalistic approach to neutrino masses, by introducing a single heavy singlet NN into the standard model (or supersymmetric standard model) with a heavy Majorana mass MM, which couples as a single right-handed neutrino in a Dirac fashion to leptons, and induces a single light see-saw mass mν5×102eVm_{\nu}\sim 5\times 10^{-2} eV, leaving two neutrinos massless. This trivial extension to the standard model may account for the atomospheric neutrino data via νμντ\nu_{\mu}\to \nu_{\tau} oscillations with near maximal mixing angle θ23π/4\theta_{23}\sim \pi/4 and Δmμτ22.5×103eV2\Delta m_{\mu \tau}^2 \sim 2.5\times 10^{-3} eV^2. In order to account for the solar neutrino data the model is extended to SUSY GUT/ string-inspired type models which can naturally yield an additional light tau neutrino mass mντfew×103eVm_{\nu_{\tau}}\sim few \times 10^{-3} eV leading to νeL(cosθ23νμLsinθ23ντL)\nu_{e L}\to (\cos \theta_{23}{\nu}_{\mu L} -\sin \theta_{23}{\nu}_{\tau L}) oscillations with Δme12105eV2\Delta m_{e1}^2\sim 10^{-5} eV^2 and a mixing angle sin22θ1102\sin^2 2 \theta_1 \approx 10^{-2} in the correct range for the small angle MSW solution to the solar neutrino problem. The model predicts νeL(sinθ23νμL+cosθ23ντL)\nu_{e L}\to (\sin \theta_{23}{\nu}_{\mu L} +\cos \theta_{23}{\nu}_{\tau L}) oscillations with a similar angle but a larger splitting Δme222.5×103eV2\Delta m_{e2}^2 \sim 2.5\times 10^{-3} eV^2 .Comment: 10 pages, Latex. Expanded discussion of mixing angles mainly in an Appendi

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