A Unified Biophysical Model of Coherent Energy Transport in Microtubules: Re-framing Anesthetic Action as a Parameter-Driven Phase Transition in a Resonant Medium
This report introduces a novel quantitative framework to describe biophysical energy transport within neuronal microtubules (MTs), applying a unified model of solid-state phonon dynamics to the experimentally observed phenomena of exciton diffusion and the quantum theories of consciousness.
A Unified Mechanistic Framework for Non-Debye Anomalies in Solids and its Application to Biological Systems
The “Unified theory of phonon in solids” (2025) recently resolved a long-standing controversy in condensed matter physics regarding the relationship between the Boson Peak (BP) and the Van Hove Singularity (VHS). By modeling solids as elastic continua embedded with local “scatterers,” this theory demonstrated that these vibrational anomalies are governed by a unified phase diagram defined by two parameters: the scatterer size and the phonon mean free path.