Updated Global 3+1 Analysis of Short-BaseLine Neutrino Oscillations

Abstract

We present the results of an updated fit of short-baseline neutrino oscillation data in the framework of 3+1 active-sterile neutrino mixing. We first consider e and e disappearance in the light of the Gallium and reactor anomalies. We discuss the implications of the recent measurement of the reactor e spectrum in the NEOS experiment, which shifts the allowed regions of the parameter space towards smaller values of |Ue4|2. The beta-decay constraints allow us to limit the oscillation length between about 2 cm and 7 m at 3σ for neutrinos with an energy of 1 MeV. We then consider the global fit of the data in the light of the LSND anomaly, taking into account the constraints from e and μ disappearance experiments, including the recent data of the MINOS and IceCube experiments. The combination of the NEOS constraints on |Ue4|2 and the MINOS and IceCube constraints on |Uμ4|2 lead to an unacceptable appearance-disappearance tension which becomes tolerable only in a pragmatic fit which neglects the MiniBooNE low-energy anomaly. The minimization of the global 2 in the space of the four mixing parameters m241, |Ue4|2, |Uμ4|2, and |Uτ4|2 leads to three allowed regions with narrow m241 widths at m241 ≈ 1.7 (best-fit), 1.3 (at 2σ), 2.4 (at 3σ) eV2. The restrictions of the allowed regions of the mixing parameters with respect to our previous global fits are mainly due to the NEOS constraints. We present a comparison of the allowed regions of the mixing parameters with the sensitivities of ongoing experiments, which show that it is likely that these experiments will determine in a definitive way if the reactor, Gallium and LSND anomalies are due to active-sterile neutrino oscillations or not.