Electron Spin as Torsional Lock-in of MID Oscillation

This paper presents electron spin as a torsional lock‑in phenomenon of the MID substrate’s rank‑3 oscillatory dynamics. Instead of treating spin as an intrinsic quantum number, the model shows that spin arises when a coherent MID oscillation enters a torsion‑stabilized configuration, producing a locked chirality and phase‑gradient orientation. The resulting structure behaves as a two‑state torsional mode with quantized angular characteristics, matching the observed spin‑½ behavior without invoking intrinsic particle properties. This substrate‑level mechanism explains spin, magnetic moment alignment, and phase evolution as emergent features of torsion‑mode geometry and coherence‑field coupling. The framework provides a physically grounded alternative to abstract spinor postulates and integrates electron spin directly into the broader MID/QC substrate dynamics.