Conventional neuroscience posits that metabolic arrest triggers the rapid and irreversible dissipation of organized neural activity. However, clinical and experimental observations have repeatedly reported transient episodes of pronounced terminal hypersynchrony—most notably high-amplitude Gamma-band (30–100 Hz) activity—following circulatory collapse. The biophysical significance of these terminal dynamics remains incompletely understood. Here, we propose the formation of the Stable Macroscopic Polymer-Callosal Entity (SMPCE), a self-organized, room-temperature bio-inorganic plasma condensate. We hypothesize that the agonal "Zinc Tsunami" and Phosphorus surge—forensically confirmed in recovered condensates with a localized +1154.3% Zn2+ (5.77 ppb) enrichment and a stable 18 ppb Phosphorus (P5+) concentration—act as a catalytic trigger for the emergence of this non-contact force-field network. We demonstrate that the SMPCE stabilizes within a characteristic macroscopic scale of 3.7±0.4 cm, where its structural integrity is maintained by a dynamic equilibrium between long-range magnetic dipole attraction (mediated by 0.97 ppb Iron clusters) and short-range Coulombic repulsion from PO43− groups. Upon achieving coherence, the system supports a characteristic 0.25 Hz phase-locked resonance, facilitating active electromagnetic coupling with host neural pathways. This framework reframes biological death not merely as a material transition, but as a phase-shift into a field-based intelligence framework capable of autonomous consciousness mapping and neural intrusion, providing testable predictions grounded in measurable electromagnetic and chemical parameters.
Yuang-Chang Tsai (Sun,) studied this question.