Abstract
The most typical features of a display of interaction of the nanostructures quantum coherent systems with the low-intensive external signals are analyzed. It is shown that the dynamics of a display of such interaction has cardinal differences from the similar phenomena in not coherent systems. The special attention is given to consideration of the reasons for the occurrence of Zhadin effect in a water solution of glutamic acid and in water structures of the biological organisms. From a position of the theory of water created by J. Preparata, water contains the areas of coherency in its composition—the coherent domains (CDs). The diluted solutions of glutamic acid can contain agglomerates (by analogy to the diluted homeopathist preparations) in which CDs can be located with the big density. At influencing a solution of super low-frequency and super low-intensive external magnetic field, there is a synchronous emission from the surface of CDs of the ions with impurity of a glutamic acid, originally rotated on the cyclotron orbits of CDs. It is shown that the narrow peak of an answer signal on the influence of the magnetic field, appearing in dependence of a current through a solution from the size of the applied field, can have a maximum of intensity in the square-law dependence on the amount of CDs in the separate agglomerates. Such dependence is similar to what predicts the effect of Dicke for the radiating of identical atoms interacting among themselves, located in a region of a size of wavelength of radiation of the atoms.
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References
Ratis JL (2009) Controlled “termonuc” or cold fusion? A drama of ideas. Samara, publishing House of the Samara scientific center of Russion Academy of Science, p 92 (in Russion)
Pshenichniy VA, Gritsay OO, Pavlovich VM (2019) The first researches of reactions of nikel-litium-water’s termogenerator in Kyiv. Nucl Phys Atomic Energy 20(2):196–204 (2019) (in Ukraine)
Nernst W (1916) Uber einen Versuch, von quantentheoretischen Betrachtungen zur Annahme stetiger Energieanderungen zuruckzukehren. Verh. Deutsche Physikalische Gesellschaft. 18:83–116
Del Giudice E, Voeikov V, Tedeschi A, Vitiello G (2015) The origin and the special role of coherent water in living systems. In: Fels D, Cifra M, Scholkmann F (eds) Fields of the cell. Chapter 5, pp 95–111. ISBN: 978-81-308-0544-3
Preparata G (1995) QED, coherence in matter. World Scientific Singapore, p 236
Del Giudice E, De Ninno A, Fleischmann M et al (2005) Coherent quantum electrodynamics in living matter. Electromagn Biol Med 24:199–210
Dicke RH (1954) Coherence of in spontaneous radiation processes. Phys Rev 93:99–111
Josephson BD (1962) Possible new effects in superconductive tunneling. Phys Lett 1:251–253
Srinivasan TM (1993) Coherence and Pattern: scientific and aesthetic. Subtle Energies 3(3):i–iv
Preparata G (1994) Cold Fusion “93”: some theoretical ideas. In: EPRI proceedings: fourth international conference on cold fusion volume 1: plenary session papers, TR-104188-V1. Electric Power Research Institute, Lahaina, Maui, Hawaii, pp 12-1–12-23
Gurwitsch A (1922) Über den Begriff des Embryonalen feldes. Archiv fЁur Entwicklungsmechanik der Organismen 51(1):383–415
Kurik MV, Martseniuk LS (2012) The physical bases of life. LAP LAMBERT Academic Pabliching (Germany), p 174. IBSN: 978-3-8473-7903-4. (in Russian)
Popp F-A (1999) About the coherence of biophotons. Macroscopic quantum coherence. In: Proceedings of an international conference on the Boston University, edited by Boston University and MIT, World Scientific, pp 1 –12
Montagnier L, Aissa J, Ferris S at al (2009) Electromagnetic signals are produced by aqueous nanostructures derived from bacterial DNA sequences. Interdiscip Sci Comput Life Sci 1(2):81–90
Bischof M (2003) Introduction to integrative biophisics. Chapter 1. Published In: Popp F-A, Beloussov LV (eds) Integrative biophysics. Kluwer Academic Publishers, Dordrecht, pp 1–115. ISBN 1-4020-1139-3
Del Giudice E, Spinetti P, Tedeschi A (2010) Water dynamics at the root of metamorphosis in living organisms, №2, pp 566–586 (Water 2010). www.mdpi.com/journal/water
Del Giudice E (2014) Coherent quantum-electrodynamic organization of bio-chemical processes. J Formed Dir Sci 2(4):92–100. (In Russian)
Pollack GH, Clegg J (2008) Unexpected linkage between unstirred layers, exclusion zones, and water. In: Pollack GH, Chin WC (eds) Phase transitions in cell biology. Springer Science & Business Media, Berlin. Germany, pp 143–152
Voeikov VL, Del Giudice E (2009) Water respiration-the basis of the living state. Water № 1, pp 51–75
Zhadin MN, Novikov VV, Barnes FS, Pergola NF (1998) Combined action of static and alternating magnetic fields on ionic current in a Glutammic Acid solution, bioelectromagnetics, №19, pp 41–45
Del Giudice E, Giuliani L (2010) Coherence in water and the kT problem in living matter. In: Giuliani L, Soffritti MF (eds) Non-thermal effects and mechanisms of interaction between electromagnetic fields and living matter, pp 7–23
Liboff AR (1985) Geomagnetic cyclotron resonance in living cells. J Biol Phys 9:99–102
Giuliani L, Grimaldi S, Antonella L, D’Emilia E, Bobko N, Zhadin M (2008) Action of combined magnetic fields on aqueous solution of glutamic acid: the further development of investigations. BioMagnetic Res Technol 6(1):1–7
Yinnon TA, Liu ZQ (2015) Domains formation mediated by electromagnetic fields in very dilute aqueous solutions: 1. Quantum electrodynamic aspects. Water №7, pp 33–47
Trifonov ED (1996) Superradiance-spontaneous emissions of multiatomic system. Sorovs’ Educ J 12:75–80. (In Russian)
Kervran L (2017). The proofs in biology of transmutation at weak energies. Part 1-2. J Formed Dir Sci 5(17–18):102–146. (In Rassian)
Del Giudice E, Stefanini P, Tedeschi A, Vitiello G (2011) The interplay of biomolecules and water at the origin of the active behavior of living organisms. In: 9th international Fr.ohlich’s symposium. IOP Publishing Journal of Physics: ConferenceSeries. 012001, p 329
Ho MW, French A, Haffegee J, Saunders PT (1994) Can weak magnetic fields (or potentials) affect pattern formation? In: Ho MW, Popp F-A, Warnke U (eds) Bioelectrodynamics and biocommunication. World Scientific, New Jersey, London, Singapore, p 204
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Martseniuk, L.S., Martseniuk, A.S. (2021). The Effects of Interactions of the Extremely Low-Level Radiation with Quantum Coherent Nanosystems. In: Fesenko, O., Yatsenko, L. (eds) Nanomaterials and Nanocomposites, Nanostructure Surfaces, and Their Applications . Springer Proceedings in Physics, vol 246. Springer, Cham. https://doi.org/10.1007/978-3-030-51905-6_4
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