Influence spatially inhomogeneous DC and AC magnetic field on aqueous solutions of NaCl and KCL to data of thermoluminescence of crystals
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Abstract
Method has been developed for estimation of influence of low-intensity electromagnetic fields, in particular permanent magnetic and radio-frequency electromagnetic field on aqueous solutions of salts. The method is based on dehydration of aqueous solution, to obtain crystals of salt and followed thermoluminescence of crystals. It is shown that depending on the spatial distribution of the external field changes the intensity of thermoluminescence of crystal structures of NaCl and KCl up to 2 times as compared with intact samples. Also shows the memory effect of aqueous solutions, Also shows the memory effect of aqueous solutions which is characterized by changes in thermoluminescence salt crystals, despite the fact that the time of impact on water solution significantly less time dehydration.
Reference 29, figures 3, tables 2.
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References
Binhi V.N., Savin A.V. (2003), “The effects of weak magnetic fields on biological systems: physical aspects”, Physics-Uspekhi (Advances in Physical Sciences), vol. 173, no. 3, pp. 256-300.
Chujan E.N. (2008), “Effect of low-intensity electromagnetic radiation of extremely high frequency on the microcirculation”, Uchenye zapiski Tavricheskogo nacional'nogo universiteta im. V.I. Vernadskogo, vol. 21, no. 1, pp. 156–166. (Rus)
Shvan H.P. (1980), “ Exposure to RF fields on biological systems: the electrical properties of the bio-physical mechanisms”, TIIJER, vol. 68, no. 1, pp. 121–132. (Rus)
Lovejkin V.S., Chovnjuk Ju.V., Kostyna O.Ju., Javorskaja A.V. (2010), "Exposure to RF fields of dif-ferent physical nature on biological micro-and nanosystems: molecular dynamics of the electronic structures of clusters of living matter, the fractal characteristics of surface interaction", Vestnik HNADU, no. 51, pp. 113–118. (Rus)
Loshic'kij P.P., Minzyk D. (2011), “ The study of the concentration dependence of aqueous solutions”, Medichna іnformatika ta іnzhenerіja, no. 2, pp. 29–34. (Rus)
Loboda O. A., V. V. Goncharuk (2009), “AB INITIO calculations of the formation of water clusters. vi-bration analysis and isotope effect”, Chemistry and Technology of Water, vol. 31, no. 2, pp. 173-189. (Rus).
Glinka N.L. (1983), “General Chemistry”, Leningrad: "Chemistry", P. 704. (Rus)
Dyadin Y. (1988), “Supramolecular chemistry: clathrate compounds”, Soros Educational Journal, no. 2 pp. 79-88.(Rus).
Glebov A.N. (1996),” Structural and dynamical properties of aqueous solutions of electrolytes”, Soro-sovskij obrazovatel'nyj zhurnal, no. 9, pp. 72-78. (Rus)
Gall L. N., Gall N. R. (2009), “Intermolecular energy transfer mechanism and the perception of ultra-weak interactions of chemical and biological systems”, Biophysics, vol. 54, no. 3. pp. 563 – 574. (Rus)
Nikolov N.A. (2011), "The change of the spontaneous luminescence of aqueous solutions under the influence of radio frequency electromagnetic radiation", Electronics and Communications, no. 5-6, pp. 18-24. (Rus)
Nikolov N.A., Solyar A.G. (2012), “Change in aqueous solutions’ superradiance as a result of their in-teraction with spatially-heterogeneous electromagnetic field”, Electronics and nanotechnology. Pro-ceedings of the XXXII international scientific Conference ELNANO 2012, Kiev, Ukraine, pp. 144-145, April 10-12.
Nikolov N.А., Solyar A.G., Yaroshenko O.Yu. (2013), “Experimental investigation of aqueous solutions of superradiance”, Electronics and nanotechnology. Proceedings of the XXXIII international scientific Conference ELNANO 2013, Kiev, Ukraine, pp. 273-275, April 16-19.
Dicke R. H. (1954), ”Coherence in spontaneous radiation processes”, Physical Review, vol. 93, no. 1, pp. 99-110.
A.V. Andreev, V.I. Emel’yanov, Yu.A. Il’inskii. (1980), “Collective spontaneous emission (Dicke super-radiance)”, Sov. Phys. Usp., vol. 23, pp. 493–514. (Rus)
Witthaut D. (2012), “Stochastic resonance driven by quantum shot noise in superradiant Raman scat-tering”, J. Phys. B: At. Mol. Opt. Phys., vol. 45, no. 22, P. 225501.
A. V. Shepelyov. (1999), “Perhaps the radiance increase in noninverted medium”, Physics-Uspekhi. vol. 169, № 2, pp. 213-215. (Rus)
Romanovsky Y.M. (1975), “Mathematical modeling in biophysics”. Moscow, Nauka, P. 344. (Rus)
Blechman I.I. (1981), “Sync prorode and Technology”. Moscow, “Nauka”, P. 352. (Rus).
Afraimovich V.S., Nekorkin V.I, Osipov G.V., (1989), “Structure and chaos in synchronization net-works”. Bitter: IPF AN SSSR, P.256. (Rus)
Nikolov N.A., Orel V.E., Smolanka I.I. (2008), “Apparatus for Short-Wave Inductothermy Magne-totherm”, IFMBE Proceedings, vol. 20, pp. 294 - 298.
Orel V.E., Nikolov N.A., Rykhalskiy A.Y. (2013), “Magnetic Nanotherapeutics of Guerin Carcinoma”, Proceedings of the IEEE XXXIII International Scientific Conference “Electronics and Nanotechnology” (ELNANO-2013), Kiev, Ukraine. pp. 241–245, April 16-19.
Orel V.E., Nikolov N.A., Romanov A.V. et al. (2012), “Antitumor effect of magnetic nanocomplex initi-ated by inhomogeneous constant magnetic field and alternating electromagnetic field on carcinosar-coma Walker 256”, Electronics and nanotechnology. Proceedings of the XXXII international scientific Conference ELNANO 2012, Kiev, Ukraine, pp. 164-165, April 10-12.
“Colour centers in alkali halide crystals. Collection of articles”, Translated A.S. Heynman, K.B. Tolpy-go. Moscow: "Foreign Literature", 341 p., 1958 (Rus).
Mirzade F.H. (2006), “Self-organization of spatially inhomogeneous structures in bulk crystallization of polydisperse systems”, Zhurnal tehnicheskoj fiziki, vol. 76, no. 9, pp. 74 -80. (Rus)
Trasevich Ju.Ju., Ajupova A.K. (2003), "The effect of diffusion on the separation of the components of biological fluid with wedge dehydration", Zhurnal tehnicheskoj fiziki, vol.73, no. 5. pp. 13-18. (Rus)
Gurin V.N., Nikanorov S.P., Korsukova M.M. (1997), "The change of the lattice period and composi-tion of crystals КCl and КBr at microgravity", Fizika tverdogo tela, vol. 39, no. 10. pp. 1792-1793.(Rus)
Koch A.E., Kononov N.G., Mokrushnikov P.V. (1999), “Manage thermal field and convection process for growing crystals”, Proc. 4th Intern. Conf. "Crystals: growth, properties, real structure”, Alexandrov, pp. 234-256. (Rus).
Kokh А.Е. Kononova N.G., Popov V.N., Mokruchnikov P.W. (2001), “BBO crystal growth in static and rotating heat fields of variable symmetry”, Proceedings of SPIE, vol. 4268, pp. 161-166.
