electromagnetic structure within Earth's geomagnetic field, proposing a novel bioelectromagnetic framework for sensory filtering and emotion–memory processing. The model interprets phase synchronization between the cardiac electromagnetic field, the Reticular Activating System (RAS), and the Schumann Resonance as a physiological regulatory mechanism governing emotion and memory. HBAM integrates the Intrinsic Cardiac Nervous System, the Autonomic Nervous System, and higher-order cortical centers, dynamically resonating with internal and geomagnetic stimuli. Within this model, emotion is conceptualized as pressure-based phase energy condensation, while memory reflects a real-time process governed by phase coherence. To empirically test this model, we analyzed time series data of heart rate variability (HRV) and Schumann resonance. Cross-correlation analysis revealed a statistically significant, though modest, positive correlation (r = 0.038, p = 0.023), with peak alignment at a lag of 2775 seconds. These findings provide initial support for the hypothesis that cardiac rhythms may intermittently synchronize with geophysical electromagnetic activity.
Doha Lee (Mon,) studied this question.