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: quantum mechanical perturbation theoretical methods and their resonance dominators to characterize specific interactions between constituents. These methods permit the treatment of molecular processes by circuits with characteristic resonances and “beat-frequencies”, which result from primarily fast physical processes. As examples, the tunneling processes between DNA base pairs (H bonds), the ATP decomposition and the irradiation of tumor cells are accounted for.
Highlights
The description of molecular processes and the energy/ charge transport in/between molecules as mechanical electrical oscillators has a long history [1,2]
The existence of specific biorhythms and the role of geomagnetic and/or solar magnetic activities are well-established by appropriate correlations in chronobiology
There are two different accesses to biorhythms to set up connections to molecular processes: quantum mechanical perturbation theoretical methods and their resonance dominators to characterize specific interactions between constituents
Summary
The description of molecular processes and the energy/ charge transport in/between molecules as mechanical (and more promising) electrical oscillators has a long history [1,2]. The oscillations of between molecule sites (IR spectra) are much slower (usually a factor 10−3 10−4 compared to singlet excitations), but are still faster compared to some biorhythms in cells It appears that the basic principle of coupled electric oscillators is useful to study physiological processes for many reasons: it is possible to regard cells as complex systems of charged layers/structures, and all biomolecules are usually highly charged ions (i.e. multipoles). It is a consequence to consider cellular systems as numerous different charge distributions (capacitances) and currents, induced by charge transfer via H bonds or other molecular deformations This connection indicates that the origin of biochemical resonances is of quantum mechanical nature, since only this tool can determine molecular properties and resonance interactions. Already two coupled electric oscillators are sufficient to study such a model
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