On Resolving the Dark LMA Solution at Neutrino Oscillation Experiments

Abstract

In presence of non standard interactions, the solar neutrino data is consistent with two solutions, one close to the standard LMA solution with 2θ12 0.3 and another with 2θ12D 0.7(=2θ12). The latter has been called the Dark LMA (DLMA) solution in the literature. This issue is hard to resolve via oscillations because of the existence of the so-called "generalised mass hierarchy" degeneracy of the neutrino mass matrix in presence of NSI. However, if the mass hierarchy is independently determined in a non-oscillation experiment such as neutrino-less double beta decay, the invariance of neutrino oscillation probabilities under 2θ12 2θ12 is lost and the possibility of resolving the LMA vs DLMA opens up. We point out that the Pμμ channel can distinguish θ12 from θ12D and study the corresponding difference in long-baseline experiments. We show that a key ingredient required is the input from the Pee channel measured at a reactor experiment. We find that if the mass hierarchy is determined by neutrino-less double beta decay, then a combined measurement of the effective mass squared differences in long-baseline experiments such as T2HK and DUNE and reactor experiment such as JUNO can resolve the DLMA conundrum to better than 3σ within 1 year for T2HK and little more than 3 years for DUNE.