Octant sensitivity for large theta(13) in atmospheric and long baseline neutrino experiments

Abstract

One of the unknown parameters in neutrino oscillations is the octant of the mixing angle theta23. In this paper, we discuss the possibility of determining the octant of theta23 in the long baseline experiments T2K and NOvA in conjunction with future atmospheric neutrino detectors, in light of non-zero value of theta13 measured by reactor experiments. We consider two detector technologies for atmospheric neutrinos - magnetized iron calorimeter and non-magnetized Liquid Argon Time Projection Chamber. We present the octant sensitivity for T2K/NOvA and atmospheric neutrino experiments separately as well as combined. For the long baseline experiments, a precise measurement of theta13, which can exclude degenerate solutions in the wrong octant, increases the sensitivity drastically. For theta23 = 39o and sin2 2 theta13 = 0.1, at least ~2 sigma sensitivity can be achieved by T2K+NOvA for all values of deltaCP for both normal and inverted hierarchy. For atmospheric neutrinos, the moderately large value of theta13 measured in the reactor experiments is conducive to octant sensitivity because of enhanced matter effects. A magnetized iron detector can give a 2 sigma octant sensitivity for 500 kT yr exposure for theta23 = 39o, deltaCP = 0 and normal hierarchy. This increases to 3 sigma for both hierarchies by combining with T2K+NOvA. This is due to a preference of different theta23 values at the minimum chi2 by T2K/NOvA and atmospheric neutrino experiments. A Liquid Argon detector for atmospheric neutrinos with the same exposure can give higher octant sensitivity, due to the interplay of muon and electron contributions and superior resolutions. We obtain a ~3 sigma sensitivity for theta23 = 39o for normal hierarchy. This increases to > ~4 sigma for all values of deltaCP if combined with T2K+NOvA. For inverted hierarchy the combined sensitivity is ~3 sigma.