A Unified Field Model of the Proton, Neutron, and Electron - A Field Origin Perspective

This work explores the foundational predictions of Field Origin Cosmology (FOC), a theoretical framework in which all physical phenomena arise from distortions and tensions within a continuous field, and tests their applicability at the atomic scale. FOC proposes that mass, charge, and spin are not intrinsic properties of particles, but emergent features of topologically constrained curvature within the field itself.The goal of this study is to determine whether the core tenets of FOC, originally formulated for cosmic structure and large-scale field dynamics, can accurately account for the properties and behaviors of elementary particles, specifically the electron, proton, and neutron. By modeling these particles as stable, self-consistent arrangements of trapped field tension, the analysis reconstructs their known properties from first principles: rest mass, charge behavior, spin-½ statistics, electric field geometry, and decay energetics.The results show that the FOC framework:•Predicts the rest masses of particles within 99.9% of measured values•Derives the Bohr radius and atomic structure from tension equilibrium, without invoking quantization postulates•Explains the electric field as a wake of field stress, not an emission•Interprets charge and spin as topological features of field twist and closure•Resolves beta decay as a partition of vortex curvature, preserving all conservation laws geometricallyThese findings suggest that the macroscopic logic of FOC extends cleanly down to the subatomic domain, unifying large-scale curvature with the stable loops and knots that form matter. The agreement between predicted and observed quantities implies that the atomic realm is not beyond the reach of field-based cosmology, but a natural extension of its geometry.