One String to Rule Them All: Neutrino Masses and Mixing Angles

Abstract

The correct quark and charged lepton mass matrices along with a nearly correct CKM matrix may be naturally accommodated in a Pati-Salam model constructed from intersecting D6 branes on a T6/(2 × 2) orientifold. Furthermore, near-tribimaximal mixing for neutrinos may arise naturally due to the structure of the Yukawa matrices. Consistency with the quark and charged lepton mass matrices in combination with obtaining near-tribimaximal mixing fixes the Dirac neutrino mass matrix completely. Then, applying the seesaw mechanism for different choices of right-handed neutrino masses and running the obtained neutrino parameters down to the electroweak scale via the RGEs, we are able to make predictions for the neutrino masses and mixing angles. We obtain lepton mixing angles which are close to the observed values, θ12 =33.81.2, θ23=46.90.9, and θ13=8.560.20. In addition, the neutrino mass-squared differences are found to be m232 = 0.00250.0001~eV2 and m221 = 0.0000750.000003~eV with m1=0.01500.0002~eV, m2=0.01730.0002~eV, and m3=0.053 0.002~eV so that Σi mi = 0.0850.002~eV, consistent with experimental observations.