5,425 research outputs found

    Revising the Solution of the Neutrino Oscillation Parameter Degeneracies at Neutrino Factories

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    In the context of neutrino factories, we review the solution of the degeneracies in the neutrino oscillation parameters. In particular, we have set limits to sin22θ13\sin^2 2\theta_{13} in order to accomplish the unambiguous determination of θ23\theta_{23} and δ\delta. We have performed two different analysis. In the first, at a baseline of 3000 km, we simulate a measurement of the channels νeνμ\nu_e\to\nu_\mu, νeντ\nu_e\to\nu_\tau and νˉμνˉμ\bar{\nu}_\mu\to\bar{\nu}_\mu, combined with their respective conjugate ones, with a muon energy of 50 GeV and a running time of five years. In the second, we merge the simulated data obtained at L=3000 km with the measurement of νeνμ\nu_e\to\nu_\mu channel at 7250 km, the so called 'magic baseline'. In both cases, we have studied the impact of varying the ντ\nu_\tau detector efficiency-mass product, (ϵντ×Mτ)(\epsilon_{\nu_\tau}\times M_\tau), at 3000 km, keeping unchanged the νμ\nu_\mu detector mass and its efficiency. At L=3000 km, we found the existance of degenerate zones, that corresponds to values of θ13\theta_{13}, which are equal or almost equal to the true ones. These zones are extremely difficult to discard, even when we increase the number of events. However, in the second scenario, this difficulty is overcomed, demostrating the relevance of the 'magic baseline'. From this scenario, the best limits of sin22θ13\sin^2 2\theta_{13}, reached at 3σ3\sigma, for sin22θ23=0.95\sin^2 2\theta_{23}=0.95, 0.975 and 0.99 are: 0.008, 0.015 and 0.045, respectively, obtained at δ=0\delta=0, and considering (ϵντ×Mτ)125(\epsilon_{\nu_\tau}\times M_\tau) \approx 125, which is five times the initial efficiency-mass combination.Comment: 40 pages, 18 figures; added references, corrected typos, updated Eq (15c

    Three Generation Long-wavelength Vacuum Oscillation Solution to the Solar Neutrino Problem

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    We investigate the current status of the long-wavelength vacuum oscillation solution to the solar neutrino problem and to what extent the presence of a third neutrino can affect and modify it. Assuming that the smaller mass squared difference that can induce such oscillations, Δm122\Delta m^2_{12}, is in the range 101110810^{-11}-10^{-8} eV2^2 and the larger one, Δm232\Delta m^2_{23}, in the range relevant to atmospheric neutrino observations, we analyze the most recent solar neutrino data coming from Homestake, SAGE, GALLEX, GNO and Super-Kamiokande experiments in the context of three neutrino generations. We include in our vacuum oscillation analysis the MSW effect in the Sun, which is relevant for some of the parameter space scrutinized. We have also performed, as an extreme exercise, the fit without Homestake data. % While we found that the MSW effect basically does not affect the best fitted parameters, it significantly modifies the allowed parameter space for Δm122\Delta m^2_{12} larger than 3×1010\sim 3 \times 10^{-10} eV2^2, in good agreement with the result obtained by A. Friedland in the case of two generations. % Although the presence of a third neutrino does not essentially improve the quality of the fit, the solar neutrino data alone can give an upper bound on θ13\theta_{13}, which is constrained to be less than 60\sim 60^\circ at 95 % C.L.Comment: 35 pages, 14 png figures: good quality postscript figures can be found in http://neutrinos.if.usp.br/gefan/papers/publicados/ps/GNZ
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