This document formulates the MEON framework as an effective topological spin-torsion field theory in a 4-dimensional spacetime. It marks the structural transition from an empirically motivated curve-fitting approach to a formally consistent, phenomenological Effective Field Theory (EFT) candidate. Version R173 (Audit M024) introduces the Quantum Effective Action () to rigorously incorporate non-local expectation values of the spectral dimension and internal Lorentz spin-Casimir operators as macroscopic infrared order parameters. The classical field equations feature a massive Proca sector with a corrected positive mass signature and a dynamically consistent negative source coupling (-gT S_ J₅^), ensuring absolute linear stability against tachyon and ghost instabilities for the free vector sector. The framework relies on a phenomenological topological selection rule based on the Fibonacci-Lucas global attractor (F₄ L₄ = 21), aligning the dimensionless spin sector (j=4) with the macroscopic 4D geometry. A highly suggestive macroscopic resonance proximity (N 194. 0000436) emerges via the fine-structure constant (), suggesting a correlation between the geometric sector and the axial field. The application to astrophysical phenomena, such as the Bullet Cluster, is framed qualitatively through macroscopic coherent axial spin densities acting as field sources. The fundamental microscopic derivation of the non-local topological constraints from a UV-complete quantum gravity theory, as well as explicit quantitative lensing potential calculations, are explicitly declared as open research questions (Theory Gap).
Asil Karahan (Sat,) studied this question.