Overview Previous Parts of the Origin Geometry program established geometric mechanisms associated with mass hierarchy, boundary-localized fermion-like excitations, topological winding sectors, bulk-boundary stratification, and dynamical localization within discrete H4-derived geometry 1–16. These developments provide a natural foundation for asking whether additional particle-like properties may also admit geometric precursors. Topological Charge and Projection Triality The present Part investigates whether charge-like quantization, composite-like boundary structure, and confinement-like behavior may share a common geometric origin 23–28, 35–41. The framework introduced here is intentionally conservative. It does not claim to derive electric charge, Quantum Chromodynamics, gauge interactions, color charge, quark dynamics, or hadronic spectra. Instead, it proposes a geometric candidate model in which several qualitative particle-like features arise from bulk-boundary topology, boundary winding, and projection structure 23–34, 42–46. We introduce three related concepts: Topological Charge: Associated with conserved boundary winding sectors. Boundary-Anchored Bulk Defects: Providing a geometric mechanism linking massive volumetric excitations to observable boundary manifestations. Projection Triality: Describing the emergence of three preferred boundary projection loci associated with stable anchoring configurations 17–22, 29–34. Quark-Like Boundary Projections and Confinement Within this framework, a single bulk-supported defect may appear to a boundary observer as a multi-locus projected structure. The projected loci are not interpreted as physical quarks. They are quark-like only in the limited structural sense that a single underlying geometric object may display a three-component boundary manifestation. Similarly, the charge-like quantities discussed here are not identified with measured electric charge. They are topological winding quantities whose distributed boundary projections may produce effective fractionalized boundary weights. Taken together, these ingredients suggest a unified geometric framework in which charge-like behavior, projection structure, and confinement-like behavior may arise from common topological principles. The validity of this proposal remains open and must be tested through future analytical and computational investigations.
The Duy Tan Truong (Tue,) studied this question.