Common Origin for CP Violation in Cosmology and in Neutrino Oscillations

Abstract

We suggest predictive scenarios for neutrino masses which provide a common origin for CP violation in early universe cosmology and in neutrino oscillations. Our setup is the seesaw mechanism in the context of MSSM with two quasi-degenerate right-handed neutrinos, with baryon asymmetry generated via resonant leptogenesis. Three different models are found with specific textures in the Yukawa coupling matrices, each with a single phase which controls leptogenesis and neutrino CP violation. One model leads to normal hierarchy of light neutrino masses and the prediction tan theta13 = sin theta12 m2/m3, resulting in a value of the reactor mixing angle theta13 very close to the current experimental lower limit. The other two models predict inverted hierarchical neutrino mass spectrum with the sum rules sin2 theta12 = 1/2-tan theta23 sin theta 13 cos delta and sin2 theta12 = 1/2+cot theta23 sin theta13 cos delta respectively. We obtain a lower bound for the phase |delta| in the normal hierarchical model, and a narrow range for |delta| for the inverted hierarchical model from cosmology. In our scenario, the mass-splitting between the quasi-degenerate right-handed neutrinos arise via renormalization group flow, which provides a lower limit on the MSSM parameter tan beta > 12. The right-handed neutrino masses can be as low as TeV, which would avoid the gravitino problem generic to supersymmetric models.