S.N. Novikov – Ph.D. (Eng.), Senior Research Scientist, 

National Research University “MIET” (Zelenograd, Moscow)

E-mail: aviary@mail.ru

A.I. Ermolaeva – Ph.D. (Eng.), Associate Professor, 

National Research University “MIET” (Zelenograd, Moscow)

N.E. Korobova – Dr.Sc. (Chem.), Professor, Leading Research Scientist, National Research University “MIET” (Zelenograd, Moscow)

E-mail: korobova3@mail.ru

Formulation of the problem.Over the past decades, scientists have been discussing and cannot agree on the structure of water. Thermodynamic parameters of water are studied depending on temperature; coherent phases of molecules and their anomalous behavior are described using de Broglie/Bohm waves, through wave resonance, quantum electrodynamics, and even string theory. 

Aim of the work – is aimed at determining the basic conditions that change the supramolecular structure of water, as a quantum – mechanical system.

Results. The formation conditions of a coherent phase (coherent domains) in the water structure under the various external influences (introduction of impurity ions, mixing, laser irradiation, etc.) were studied. The gravimetric method (Derivatography) to determine the content of coherent domains in a water sample has been used. The analysis of the obtained results was carried out in accordance with the concept of quantum electrodynamics (QED) thermodynamics of water.

It was shown that the number of coherent domains under various influences form a single dependence on the fluid density, calculated according to the QED theory. It has been suggested that water samples with the maximum content of the coherent phase (activated water, melt water, “snowy” water) have the ability, noted in the literature, to record and transmit electromagnetic information. The obtained results confirm the assumption about the possibility of the quantum entangled states formation between water samples with different contents of coherent domains.

Practical significance. The practical significance of the presented studies is that there are no contradictions between the existing models of the structure of water. Each of the models complements each other and confirms the unity of the nature of electromagnetic frequencies of pure water with the frequencies of biological systems.

1. Arani R., Bono I., Giudice Del E., Preparata G. QED Coherence and Thermodynamics of water. International Journal of Modern Physics B. 1995. V. 9. № 15. P. 1813–1841. doi.org/10.1142/S0217979295000744.
2. Preparata Dzh. Realisticheskaya kvantovaya fizika. M.: Institut komp'yuternyh issledovanij. 2005. 122 s. (In Russian).
3. Novikov S.N., Ermolaeva A.I., Timoshenkov S.P., Minaev V.S. Vliyanie nadmolekulyarnoj struktury vody na kinetiku processa ispareniya. ZhFH. 2010. T. 84. № 4. S. 614–617 (In Russian).
4. Bernal J.D., Fowler R.H. A theory of water and ionic solution with particular reference to hydrogen and hydroxyl ions. J. Chem. Phys. 1933. V.1. № 8. P. 515–548. DOI: 10.1063/1.1749327.
5. Samojlov O.Ya. Struktura vodnyh rastvorov elektrolitov i gidrataciya ionov. M.: Izd. AN SSSR. 1957. 182 s. (In Russian).
6. Novikov S.N., Ermolaeva A.I., Timoshenkov S.P. Vliyanie nadmolekulyarnoj struktury vody na kinetiku izotermicheskogo ispareniya poverhnostnogo sloya Ch.2. Energiya raspada kogerentnyh domenov vody i ee rol' v processe izotermicheskogo ispareniya. Biomedicinskaya elektronika. 2012. № 5. S. 20–27 (In Russian).
7. Distler G.I., Moskvin V.V. Informacionnye svojstva tonkih sloev adsorbirovannoj vody. Dokl. AN SSSR. 1971. T. 201. № 4. S. 891–893 (In Russian).
8. Emoto M. Poslaniya vody. Tajnye kody kristallov l'da. M.: Sofiya. 2005. 96 s. (In Russian).
9. Hu H., Wu M. Evidence of Non-Local Physical, Chemical and Biological Effects Supports Quantum Brain. NeuroQuantology. 2006. V. 4. № 4. P. 291– 306. DOI: 10.14704/nq.2006.4.4.108.
10. Novikov S.N., Ermolaeva A.I., Zhigalov V.A., Korobova N.E., Goryunova E.P., Timoshenkov S.P. Distancionnye vzaimodejstviya fizicheskih sistem – sledstvie obrazovaniya kvantovoj zaputannosti kogerentnyh domenov vody. Biomedicinskaya radioelektronika. 2019. № 2. C. 63–68 (In Russian).
11. Kalinichenko N.N. Energoinformacionnye metody kompleksnoj diagnostiki i vosstanovleniya funkcional'nogo sostoyaniya organizma. Medicina ekstremal'nyh situacij. 2012. T. 39. № 1. S. 27–31 (In Russian).