A Resonance-Based Model of Human Biological Organization

Abstract

We present a resonance-based model of human evolution that integrates concepts from quantum entropy, biological oscillations, and distributed memory systems. Unlike gene-centric and linear Darwinian frameworks, this approach explores the potential roles of bacterial memory, electromagnetic phase coherence, and plasma-related processes in the emergence of complex biological organization and aspects of human cognition.

Biological structures are interpreted as dynamic information-processing fields, incorporating bioelectromagnetic interactions, reticular activating system (RAS) signaling, and pH-dependent regulatory mechanisms. Within this framework, growth, reproduction, and survival may be understood as outcomes of coordinated coherence across molecular, cellular, and ecological scales.

Memory is not considered solely confined to neural circuitry but may involve distributed processes across physiological and bioelectromagnetic systems. Disruptions in coherence between biological systems and environmental electromagnetic conditions are proposed as potential contributors to certain pathological and behavioral states.

This framework proposes an integrative perspective on human evolution grounded in resonance and coherence, drawing on insights from quantum biology, bioelectromagnetics, and cognitive systems.