Overview We investigate a candidate geometric mechanism for generating a small electron-like boundary mass within the Origin Geometry (OG) framework. Earlier Parts of the program introduced a discrete H4-derived geometric substrate, identified mass-like inertia with metric deformation cost, and proposed that mass hierarchy may arise from sector-dependent geometric participation 1, 5, 6, 22–26. In that setting, bulk metric excitations carry large inertial cost because they deform extended four-dimensional substrate structure, while boundary-supported or phase-like excitations can avoid most volumetric stiffness 5, 6, 27–31. Discretization-Induced Phase Pinning The present Part addresses the next question: if boundary phase modes are nearly isometric and therefore nearly massless in the ideal geometric limit, what mechanism can generate a small but nonzero electron-like mass scale? We propose that the relevant mechanism is discretization-induced phase pinning. A boundary-supported phase excitation may behave as a Goldstone-like or near-zero mode in a continuum approximation. However, once the substrate is treated as genuinely discrete, continuous phase translation is no longer exact. The boundary phase coordinate encounters a small lattice-induced energy ripple analogous to a Peierls–Nabarro pinning barrier in discrete soliton systems 34–37, 41. Scaling Ansatz and Mass Hierarchy This pinning energy is not interpreted as a completed derivation of the observed electron rest mass. Rather, it is proposed as a candidate geometric contribution to the rest-energy scale of an electron-like boundary collective coordinate 14–17, 20, 21, 37. In many discrete soliton systems, Peierls–Nabarro barriers are exponentially suppressed with soliton width 36, 37, 39, 40. We therefore adopt the scaling form: ΔEPN ~ A_Π exp (−κ_Π σ) as an expected structural ansatz for boundary phase solitons in H4-derived geometry, where σ is an effective soliton width and (A_Π, κ_Π) encode reduced-sector geometric data. This scaling must be verified by future numerical phase-sweep computations on explicit H4-derived boundary networks. Scope and Limitations The proposed mechanism naturally separates bulk and boundary inertial scales. Bulk metric modes are controlled by volumetric stiffness, while boundary phase modes acquire only residual pinning energy from discreteness. This provides a structural route to a large bulk–boundary hierarchy without adding new scalar fields, fitting Yukawa couplings, or modifying established low-energy effective descriptions 5–17, 36, 37. The result is not a full Standard Model mass derivation. It is a falsifiable geometric mechanism for small boundary mass generation within the stated scope of Origin Geometry.
The Duy Tan Truong (Fri,) studied this question.