Fermion Mixing Matrices and the Exceptional Jordan Algebra

Abstract

We extend the exceptional-Jordan spectral framework for fermion mass hierarchies to the problem of quark and lepton mixing. Following the companion mass paper~Teli:2026jgr, each fermion sector is associated with a Hermitian element of J3(OC), where adjacent square-root mass ratios are obtained from cubic ladders in Sym3( 3). Here, these ratios are used as inputs to an adjacent-edge lift from spectral hierarchy data to two-generation mixing angles. The lift is derived from a Fritzsch-type two-state texture~Fritzsch:1977za, Fritzsch:1979zq and should be regarded as an effective bridge ansatz rather than a theorem of the Jordan spectrum alone. The exact CP-transport input is supplied by the companion CP Letter~GuptaTeli:2026aqf. In the quark sector, the octonionic ladder operator α2 generates a real local rotor in the (e1,e3) plane, and the up- and down-sector local Cabibbo-edge amplitudes are complex conjugates, giving the exact local law ϕ12=-2χ. This is a transport-level Cabibbo-rung phase law, not by itself a prediction of the standard CKM Dirac phase. With the fitted companion mass ratios, the minimal two-angle extraction from the measured |Vus| gives an effective Cabibbo-block phase ϕ12 105.7; this number is a bridge diagnostic, while the balanced octonionic rotor remains the distinguished quadrature reference point. The (2,3) sector requires a phenomenological normalization κ230.56, and the direct (1,3) element remains a long-edge bridge problem. [Truncated]

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