Lepton Mixing from a Lattice Flavon Model: A Two-Branch Octant-delta Prediction

Abstract

We extend the single-flavon B-lattice Froggatt--Nielsen (FN) framework, previously successful for quark masses and Cabibbo-Kobayashi-Maskawa (CKM) mixing, to the lepton sector. The same B-lattice power structure (ε 1/B 0.19) generates charged-lepton mass hierarchies and a normal-ordered neutrino spectrum; large neutrino mixing angles require an additional approximate Z2 mu--tau reflection symmetry, broken at O(ε) to generate a nonzero reactor angle and CP-violating phase. The PMNS matrix factorizes as U PMNS=Ue Uν, with near-tribimaximal Uν corrected by small charged-lepton rotations whose phases are aligned by the single-flavon origin of the Yukawa textures. A single interference relation expresses the observed Dirac phase δ as the neutrino-sector phase δν shifted by a calculable charged-lepton correction, and correlates the sign of that shift with the atmospheric octant; this produces a two-branch prediction in the (θ23,δ) plane: a lower-octant solution with θ23≈ 43, δ≈ 286, and an upper-octant solution with θ23≈ 46, δ≈ 299. This structure has a geometric form as a ν3-column normalization triangle whose base angle is 2θ23, with maximal mixing the 90 limit and the octant fixed by the side of 90 on which the base angle falls. The lower octant is mildly favored, by a margin that depends on the coefficient prior. Both branches place the Dirac phase above 270, i.e. near-maximal leptonic CP violation, favored by T2K. The Jarlskog invariant J CP -0.03 is nearly branch-independent; only precision measurements of the atmospheric octant and Dirac phase at DUNE, Hyper-Kamiokande, IceCube, and JUNO can distinguish the two solutions.