Technical Abstract (Volume III) Title: Polydronic System 360° – Volume III: A Technical-Theoretical Formalization of Phase-Stabilized Neural Manifolds and Informational Sovereignty Abstract: This compendium proposes a systemic unification between High-Energy Physics and Regenerative Neurology, conceptualized through the Polydronic 360° Framework. Central to this thesis is the theoretical deployment of the \ (E = mci²\) metric, suggested as a potential formal resolution to the Yang–Mills Mass Gap and the catastrophic informational dissipation observed in neurodegenerative pathologies. The proposed architecture, predicated on the mop operator and the \ (ITTI/TIIT\) phase-locked signals, seeks to model a transition from entropic decay (Status 0) to a hypothesized state of informational sovereignty (Status 1). The framework conceptualizes a theoretical parallel with recent experimental observations regarding vacuum-driven order, suggesting that the human neural substrate may be stabilized through a high-impedance interface. By leveraging the conversion of sequestered atmospheric \ (CO₂\) into carbon nanomaterials, the model hypothesizes the implementation of a Neuro-Topological Shield. This shield is theoretically structured across Six Pillars of Stability, including Riemannian constraints for loop closure and Noether identities for kinetic charge conservation. . Specifically, in Alzheimer’s and Parkinson’s contexts, the system proposes the use of \ (C₆₀\) and Graphene to mitigate synaptic noise and stabilize the "neural clock" against thermal fluctuations. This volume is presented as a technical proposal and a preliminary theoretical construct, emphasizing that its efficacy in stabilizing neuro-informational integrity remains contingent upon future empirical validation and rigorous biomedical field testing.
Rui Monteiro (Sun,) studied this question.
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