Resolving the octant of theta23 via radiative mu-tau symmetry breaking

Abstract

We point out that the observed neutrino mixing pattern at low energies is very likely to originate from the 3 times 3 lepton flavor mixing matrix U which possesses the exact mu-tau permutation symmetry |Umu i| = |Utau i| (for i=1,2,3) at a superhigh energy scale Lambdamu tau 1014 GeV. The deviation of theta23 from 45 and that of delta from 270 in the standard parametrization of U are therefore a natural consequence of small mu-tau symmetry breaking via the renormalization-group equations (RGEs) running from Lambdamu tau down to the electroweak scale LambdaEW 102 GeV. In fitting current experimental data we find that the RGE-corrected value of theta23 is uniquely correlated with the neutrino mass ordering: theta23 42.4 reported by Capozzi et al (or theta23 48.9 reported by Forero et al) at LambdaEW can arise from theta23 = 45 at Lambdamu tau in the minimal supersymmetric standard model if the neutrino mass ordering is inverted (or normal). Accordingly, the preliminary best-fit results of delta at LambdaEW can also evolve from delta = 270 at Lambdamu tau no matter whether the massive neutrinos are Dirac or Majorana particles.