Common Origin of mu-tau and CP Breaking in Neutrino Seesaw, Baryon Asymmetry, and Hidden Flavor Symmetry

Abstract

We conjecture that all CP violations (both Dirac and Majorana types) arise from a common origin in neutrino seesaw. With this conceptually attractive and simple conjecture, we deduce that mu-tau breaking shares the common origin with all CP violations. We study the common origin of mu-tau and CP breaking in the Dirac mass matrix of seesaw Lagrangian (with right-handed neutrinos being mu-tau blind), which uniquely leads to inverted mass-ordering of light neutrinos. We then predict a very different correlation between the two small mu-tau breaking observables theta13-0 and theta23-45, which can saturate the present experimental upper limit on theta13. This will be tested against our previous normal mass-ordering scheme by the on-going oscillation experiments. We also analyze the correlations of theta13 with Jarlskog invariant and neutrinoless double-beta-decay observable. From the common origin of CP and mu-tau breaking in the neutrino seesaw, we establish a direct link between the low energy CP violations and the cosmological CP violation for baryon asymmetry. With these we further predict a lower bound on theta13, supporting the on-going probes of theta13 at Daya Bay, Double Chooz and RENO experiments. Finally, we analyze the general model-independent Z2 x Z2 symmetry structure of the light neutrino sector, and map it into the seesaw sector, where one of the Z2's corresponds to the mu-tau symmetry and another the hidden symmetry Z2s (revealed in our previous work) which dictates the solar mixing angle θ12. We derive the physical consequences of this Z2s and its possible partial violation in the presence of mu-tau breaking (without or with neutrino seesaw), regarding the theta12 determination and the correlation between mu-tau breaking observables.