Impacts of the observed theta13 on the running behaviors of Dirac and Majorana neutrino mixing angles and CP-violating phases

Abstract

The recent observation of the smallest neutrino mixing angle θ13 in the Daya Bay and RENO experiments motivates us to examine whether θ13 9 at the electroweak scale can be generated from θ13 = 0 at a superhigh-energy scale via the radiative corrections. We find that it is difficult but not impossible in the minimal supersymmetric standard model (MSSM), and a relatively large θ13 may have some nontrivial impacts on the running behaviors of the other two mixing angles and CP-violating phases. In particular, we demonstrate that the CP-violating phases play a crucial role in the evolution of the mixing angles by using the one-loop renormalization-group equations of the Dirac or Majorana neutrinos in the MSSM. We also take the "correlative" neutrino mixing pattern with θ12 35.3, θ23 = 45 and θ13 9.7 at a presumable flavor symmetry scale as an example to illustrate that the three mixing angles can receive comparably small radiative corrections and thus evolve to their best-fit values at the electroweak scale if the CP-violating phases are properly adjusted.