Tight-Binding Spectra of Finite Incidence Geometries: From Spatial Localization to SU(6) Flavor Symmetry

Abstract

We investigate the spectral properties of tight-binding quantum Hamiltonians defined on the bipartite Levi graphs of finite geometric configurations. In Part I, we analyze the 103 Desargues and Kantor configurations, demonstrating how deterministic spatial deformations induced by real planar embeddings (RP2) destroy translational symmetry, leading to structural wave localization. We show how embedding in the complex projective plane (CP2) restores Bloch wave propagation via synthetic gauge phases. In Part II, we evaluate the Schläfli double six (125, 302) and the Cremona-Richmond (153) configurations in R3. We analytically derive their exact spectral decompositions, confirming the existence of macroscopic zero-energy flat bands (E=0) driven entirely by geometric frustration. In Part III, we establish a formal structural isomorphism between these discrete tight-binding networks and the flavor symmetry sector of the Standard Model. We map the Schläfli graph to the SU(6) flavor multiplets, where the flat band corresponds to the kinematic freezing of ultra-heavy baryons. Finally, we discuss the complementary Cremona-Richmond 153 topology, demonstrating how its distinct geometric nature (based on tritangent planes rather than point intersections) provides a purely algebraic, topological completion to the W(E6) symmetry of the 27 lines.