Theory of coupled electromagnetic circuits, the connection to quantum mechanical resonance interactions and relevance to chronobiology

TL;DR

This paper explores the physical mechanisms behind biological biorhythms, linking electromagnetic circuit theory and quantum resonance interactions to molecular processes like DNA tunneling and ATP breakdown, with implications for chronobiology.

Contribution

It introduces a novel framework connecting electromagnetic circuit theory and quantum resonance to biological molecular processes, advancing understanding of chronobiological phenomena.

Findings

Quantum resonance methods characterize molecular interactions.

DNA base pair tunneling modeled as circuit resonance.

Implications for understanding biological biorhythms.

Abstract

The existence of specific biorhythms and the role of geomagnetic and/or solar magnetic activities are well-established by appropriate correlations in chronobiology. From a physical viewpoint, there are two different accesses to biorhythms to set up connections to molecular processes: 1. Diffusion of charged molecules in magnetic fields. 2. Quantum mechanical perturbation theoretical methods and their resonance dominators to characterize specific interactions between constituents. The methods of point 2 permit the treatment of molecular processes by circuits with characteristic resonances and 'beat-frequencies', which result from the primarily fast physical processes. As examples the tunneling processes between DNA base pairs (H bonds) and the ATP decomposition are considered.