F-theory and Neutrinos: Kaluza-Klein Dilution of Flavor Hierarchy

Abstract

We study minimal implementations of Majorana and Dirac neutrino scenarios in F-theory GUT models. In both cases the mass scale of the neutrinos mnu ~ (Mweak)2/MUV arises from integrating out Kaluza-Klein modes, where MUV is close to the GUT scale. The participation of non-holomorphic Kaluza-Klein mode wave functions dilutes the mass hierarchy in comparison to the quark and charged lepton sectors, in agreement with experimentally measured mass splittings. The neutrinos are predicted to exhibit a "normal" mass hierarchy, with masses m3,m2,m1 ~ .05*(1,(alphaGUT)(1/2),alphaGUT) eV. When the interactions of the neutrino and charged lepton sectors geometrically unify, the neutrino mixing matrix exhibits a mild hierarchical structure such that the mixing angles theta23 and theta12 are large and comparable, while theta13 is expected to be smaller and close to the Cabibbo angle: theta13 ~ thetaC ~ (alphaGUT)(1/2) ~ 0.2. This suggests that theta13 should be near the current experimental upper bound.