Generation as Compositeness: A Subconstituent Interpretation of the B-Lattice Flavor Hierarchy

Abstract

We interpret the B-lattice flavor framework as a compositeness hierarchy: all three fermion generations are elementary chiral fields, but third-generation Yukawa couplings are undressed (Q=0), while lighter generations acquire their Yukawa couplings through chains of spin-0 subconstituents (``hops'') whose depth is counted by the Z9 discrete gauge symmetry. The Z9 charge admits a two-index decomposition q9(a,b) that identifies two hop species (α, β) and organizes all fundamental scales from v EW to M Pl on a ``ninths ladder'' Λ×εn/9. The lattice structure yields the CKM and PMNS mixing parameterizations (with all mixing exponents expressible as charge differences ΔQ dressed by a universal Fritzsch--Xing phase shift of 1/9), a seesaw benchmark m3 51~meV, the axion mass window ma 7--12\;μeV, and the prediction β 10--16 (from the chain internal factor combined with the DFSZ-II two-Higgs-doublet structure), all from two parameters (Λ and ε= 14/75). Generation-dependent Peccei--Quinn charges restore the axion--photon coupling (Caγ 0.6--1.0) from ``back to invisible'' suppression. An illustrative UV realization in terms of hypercolor-confined scalars communicated to the SM by a gauge-invariant messenger chain is presented as an existence proof.