Why Quarks and Leptons Demand Different Symmetries: A Systematic Z3 Froggatt-Nielsen Analysis

Abstract

We present a systematic analysis of a minimal supersymmetric Z3 discrete flavor symmetry as a solution to the fermion mass hierarchy problem. With generation-dependent Z3 charges on the right-handed chiral superfields and a single flavon chiral superfield, holomorphy of the superpotential restricts the Yukawa operators so that a single expansion parameter ε 0.015 structurally accounts for the hierarchical pattern of quark and charged lepton mass ratios with O(1) Yukawa couplings. A Monte Carlo scan over 105 random O(1) coefficient sets confirms that adjacent-generation mass ratios generically fall within the experimental ranges. The CKM mixing angles are reproducible with specific coefficient choices (2/dof 1.6) but are not structurally predicted. Extended to neutrinos within a type-I seesaw, the framework fails decisively on two fronts. First, the mass spectrum is far too hierarchical: m212/ m312 10-4, two orders of magnitude below the observed 0.030. Second, the PMNS mixing angles are generically O(1) random -- consistent with Haar-distributed unitaries -- providing no mechanism to predict the observed pattern. When MR carries the Z3 charge structure dictated by the Majorana charge algebra, an unsuppressed off-diagonal entry combines with the hierarchical column texture of the Dirac mass: the seesaw congruence transformation over-suppresses both light masses m1, m2 to O(ε3), deepening the ratio m212/ m312 to O(ε6) 10-11. These results motivate a sectorial view of flavor where different fermion sectors arise from distinct symmetry mechanisms.

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