Informational effect of ultra-weak radiation of biological systems on complementary biological systems

Abstract

Informational effect of ultra-weak radiation of biological systems on complementary biological systems

Y. M. Gorovoy1*, N.V. Penkov2

The specificity of biological systems from the point of view of statistical physics is that they are metastable, multistationary systems with structure and symmetry. Statistical physics describes these systems as complex systems consisting of interacting subsystems, and interaction deforms the structure and symmetry of these subsystems
The theorems of Liouville and Noether were proved for the complex systems described above [1]. It is proved that the parameter that characterizes the depth of deformation and symmetry changes of a complex system, Ic, is equal to the entropy difference between non–interacting subsystems and a complex system consisting of the same subsystems, but already in a state of interaction.
The physical meaning of this parameter is ambiguous: statistically – the logarithm of the volume of the deformed part of the Gibbs phase space of complex system, thermodynamic - a description of specific work – work on transferring a complex system to a more energy-saturated metastable state through a change in this parameter, informational – the amount of mutual information - characteristics of the bandwidth of the communication channel – the closeness of the connection between the source and the receiver.
Biological macromolecules (one of the most important biological systems) have a supramolecular structure. The interaction of supramolecular systems may be non-local: it may not be limited to the interaction of individual molecules. The specific reaction of supramolecular systems is the reaction of molecular recognition, during which supramolecular systems "recognize" each other, changing their conformation during interaction. It was shown [1,2] that the molecular recognition reaction can be performed as a contact method (i.e. chemical interaction), and in a distant method (due to the intrinsic electromagnetic emission). It has been shown that supramolecular systems can interact distantly due to the intrinsic electromagnetic emission in the IR [3] and THz [4] ranges. Such interaction can be characterized by information parameters: the amount of mutual information (Ic) and the connectivity matrix, which characterizes the structure of the supramolecular system.
If we extend the proposed concept to the description of mitogenetic radiation, then the following conclusions can be drawn: only complex quantum systems can be the source of mitogenetic radiation. Such systems should emit not single photons, but a group of bound (entangled) photons. The structure of such a group of photons should correspond to the structure of the density matrix of the emitter. Perhaps that is why biological detectors with a structure complementary to the structure of the emitter are the most effective.

Speaker

Yuriy Gorovoy
Yaroslavl State Technical University
Russia

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