Particle Identity from Boundary Stabilized Redistribution in ψ₀–OCM

This work presents a redistribution-first account of particle identity within the ψ₀–OCM (Osborne Cosmological Model), in which particles are not taken as fundamental entities but arise as stabilized outcomes of boundary-mediated energy redistribution. The framework defines particle identity through a boundary-stabilization data structure, P䃐 = (C, ₁, I₁, K, O, M_, ᵢ, C) which encodes admissibility, stabilization, topology, orientation, boundary-derived mass, sector projection, and closure stability within a single generative architecture. Within this formulation, particles, antiparticles, confined hadrons, resonances, and dark-sector candidates are unified as distinct stabilization regimes of a common underlying redistribution process. Version 1. 1 expands the electron-sector treatment by developing electron class identity, spatial occupancy, and the rejection of literal single-electron ontology. The electron is treated as the minimal compact charged-lepton stabilization node: many electrons are distinct realized nodes of the same admissible electron class, not one universal electron appearing repeatedly. Standard QFT/Fock-space structure, fermionic antisymmetry, Dirac conjugacy, Feynman diagram orientation, and Wheeler–DeWitt-style global admissibility are recovered as effective descriptions of this class-identity structure. This version also adds a comprehensive reader-friendly glossary of symbols, terms, operators, stabilization quantities, particle-sector classes, and standard-science translation terms. The glossary is designed for readers new to ψ₀–OCM and clarifies how ψ₀, redistribution flux, boundary invariants, PDS states, RZLs, Hamiltonian/Lagrangian structures, Euler–Lagrange recovery, Wheeler–DeWitt recovery, and stabilization invariants differ from standard scientific usage. Standard quantum field theory and particle phenomenology are recovered as effective descriptions of redistribution-locked regimes, while the present work provides a deeper organizational structure that explains why such descriptions hold and where they are expected to fail. Observable consequences emerge not as arbitrary new particle species but as structured residuals arising from boundary-sensitive redistribution dynamics. The paper establishes a set of testable discriminators, including boundary-resolution-dependent deviations in high-energy scattering, structured residual correlations across particle and cosmological sectors, rare-decay residuals, and stabilization-driven hierarchy relations. These predictions provide a direct pathway for empirical validation or falsification. This work is positioned as a priority paper defining the particle-sector architecture of ψ₀–OCM and its relationship to established physics.