This work extends the original framework of the electron as a non-perturbative toroidal soliton, providing a fully topological and geometric derivation of its quantum properties. By embedding the electron in Born–Infeld electrodynamics and incorporating a Hopf-type topological charge, we demonstrate how mass, spin, and charge emerge from self-consistent field configurations. The model resolves classical challenges such as self-repulsion, naturally explains spin-½ through 4π topological periodicity, and interprets pair production as a topological bifurcation. Importantly, it predicts a measurable 2.4% deviation in electron diffraction patterns between high-Z and low-Z targets, offering a concrete experimental test of the soliton hypothesis. This paper not only reinforces the soliton perspective but also bridges geometric intuition with observable quantum phenomena.
Ashaz Rahman (Fri,) studied this question.