Electron Spin as Torsional Lock-in of MID Oscillation
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.
Oscillation mode locking, MID/QC, Tension field, Emergent phenomena, Coherence substrate, FOS: Physical sciences, Spin quantization, Gradient tensor, General Relativity and Quantum Cosmology, Theoretical Physics, Torsal dynamics, Substrate dynamics, Handedness locking, Foundational physics, Electron spin, Torsillation, Coherence formation, Field Theory, Scientific Frameworks, Quantum Physics, Coherence wells, Phase‑gradient orientation, Geometric foundations, Physics, Complex Systems, Spinor structure, Magnetic coupling, Philosophy of Physics, Rank‑3 torsion, Quantum coherence, Emergent Phenomena, Torsional lock‑in, Nonlinear Dynamics, Chirality selection, electron spin; torsional lock in; MID oscillation; substrate torsion; coherence fields; chirality; phase gradient orientation; emergent spin; quantum structure; torsion mode dynamics; MID/QC, Conceptual Modeling, Interdisciplinary Physics, Foundations of Physics, Spin emergence, Substrate‑level physics
Oscillation mode locking, MID/QC, Tension field, Emergent phenomena, Coherence substrate, FOS: Physical sciences, Spin quantization, Gradient tensor, General Relativity and Quantum Cosmology, Theoretical Physics, Torsal dynamics, Substrate dynamics, Handedness locking, Foundational physics, Electron spin, Torsillation, Coherence formation, Field Theory, Scientific Frameworks, Quantum Physics, Coherence wells, Phase‑gradient orientation, Geometric foundations, Physics, Complex Systems, Spinor structure, Magnetic coupling, Philosophy of Physics, Rank‑3 torsion, Quantum coherence, Emergent Phenomena, Torsional lock‑in, Nonlinear Dynamics, Chirality selection, electron spin; torsional lock in; MID oscillation; substrate torsion; coherence fields; chirality; phase gradient orientation; emergent spin; quantum structure; torsion mode dynamics; MID/QC, Conceptual Modeling, Interdisciplinary Physics, Foundations of Physics, Spin emergence, Substrate‑level physics
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