Analysis of the electromagnetic field of multilayered biological objects for their irradiation in a waveguide system

Authors

DOI:

https://doi.org/10.15587/1729-4061.2017.118159

Keywords:

electromagnetic field, multi-layered biological objects, waveguide system, irradiation of biological objects

Abstract

We report theoretical study on the distribution of electromagnetic field in biological objects. To perform the analysis, we selected multilayer bio-objects the size less than a wavelength of the irradiating field. In order to investigate diffraction of electromagnetic wave on the biological objects of a given type, we used integral Maxwell equations in combination with boundary conditions both at the border of the object's layers and at the border of a guiding electrodynamic structure.

A theoretical research into creation of a waveguide system was conducted for the irradiation of biological objects with dimensions less than a wavelength of the irradiating field. The waveguide system employed two diffusers: a biological object and a metallic sphere. Location of the bio-object was permanent while the sphere could move along a section of the waveguide. The result of research is the obtained dependence of reflectance coefficient on the distance between diffusers. Reflectance coefficient was obtained for frequency 58.6 GHz, waveguide dimensions d=10.668 mm, h=4.318 mm, radius of the metallic sphere 4 mm, dielectric permittivity of biological objects from 2 to 14 units the size  Calculations showed that by selecting the distance between a bio-object and a metallic sphere, it is possible to achieve that the bio-object is located in the antinode of the electromagnetic field

Author Biographies

Vadym Popriadukhin, Tavria state agrotechnological university Khmelnytskoho ave., 18, Меlitopol, Ukraine, 72300

PhD

Department of Theoretical and General Electrical Engineering named after V. V. Ovcharova

Iryna Popova, Tavria state agrotechnological university Khmelnytskoho ave., 18, Меlitopol, Ukraine, 72300

PhD

Department of Theoretical and General Electrical Engineering named after V. V. Ovcharova

Natalia Kosulina, Kharkiv Petro Vasylenko National Technical University of Agriculture Alchevskih str., 44, Kharkiv, Ukraine, 61012

Doctor of technical Sciences, Professor, Head of Department

Department of technotrance and theoretical electrical engineering

Aleksandr Cherenkov, Kharkiv Petro Vasylenko National Technical University of Agriculture Alchevskih str., 44, Kharkiv, Ukraine, 61012

Doctor of technical Sciences, Professor

Department of technotrance and theoretical electrical engineering

Mariya Chorna, Kharkiv Petro Vasylenko National Technical University of Agriculture Alchevskih str., 44, Kharkiv, Ukraine, 61012

PhD

Department of technotrance and theoretical electrical engineering

References

  1. Konstantinov, I. S., Mamatov, A. V., Sapryka, V. A., Cherenkov, A. D., Sapryka, A. V., Kosulina, N. G. (2015). Theoretical Analysis of Electromagnetic Field Electric Tension Distribution in the Seeds of Cereals. Research journal of Pharmaceutical, Biological and Chemical Scinces, 6 (6), 1686–1694.
  2. Kosulina, N., Cherenkov, A., Pirotti, E., Moroz, S., Chorna, M. (2017). Determining parameters of electromagnetic radiation for energoinformational disinfection of wool in its pretreatment. Eastern-European Journal of Enterprise Technologies, 2 (5 (86)), 52–58. doi: 10.15587/1729-4061.2017.96074
  3. Chernaya, M. A., Kosulina, N. G. (2013). Biophysical analysis of the impact of information electromagnetic field on biological objects. Bulletin of Kharkiv national technical University of agriculture named of P. Vasilenko, 142, 86–87.
  4. Kovacic, P., Somanathan, R. (2010). Electromagnetic fields: mechanism, cell signaling, other bioprocesses, toxicity, radicals, antioxidants and beneficial effects. Journal of Receptors and Signal Transduction, 30 (4), 214–226. doi: 10.3109/10799893.2010.488650
  5. Kesari, K. K., Kumar, S., Behari, J. (2011). Pathophysiology of Microwave Radiation: Effect on Rat Brain. Applied Biochemistry and Biotechnology, 166 (2), 379–388. doi: 10.1007/s12010-011-9433-6
  6. Feng, B., Wang, Z. (2017). Effect of an electromagnetic field on the spectra and elliptic flow of particles. Physical Review C, 95 (5). doi: 10.1103/physrevc.95.054912
  7. Cichoń, N., Czarny, P., Bijak, M., Miller, E., Śliwiński, T., Szemraj, J., Saluk-Bijak, J. (2017). Benign Effect of Extremely Low-Frequency Electromagnetic Field on Brain Plasticity Assessed by Nitric Oxide Metabolism during Poststroke Rehabilitation. Oxidative Medicine and Cellular Longevity, 2017, 1–9. doi: 10.1155/2017/2181942
  8. Grundler, W., Kaiser, F., Keilmann, F., Walleczek, J. (1992). Mechanisms of electromagnetic interaction with cellular systems. Naturwissenschaften, 79 (12), 551–559. doi: 10.1007/bf01131411
  9. Watters, F. L. (1976). Microwave radiation for control of Tribolium confusum in wheat and flour. Journal of Stored Products Research, 12 (1), 19–25. doi: 10.1016/0022-474x(76)90018-7
  10. Boyarskii, D. A., Tikhonov, V. V., Komarova, N. Y. (2002). Model of Dielectric Constant of Bound Water in Soil for Applications of Microwave Remote Sensing. Progress In Electromagnetics Research, 35, 251–269. doi: 10.2528/pier01042403
  11. Van Lamsweerde-Gallez, D., Meessen, A. (1975). The role of proteins in a dipole model for steady-state ionic transport through biological membranes. The Journal of Membrane Biology, 23 (1), 103–137. doi: 10.1007/bf01870247
  12. Webb, S. J. (1975). Genetic continuity and metabolic regulation as seen by the effects of various microwave and black light frequencies on these phenomena. Annals of the New York Academy of Sciences, 247 (1 Biologic Effe), 327–351. doi: 10.1111/j.1749-6632.1975.tb36009.x
  13. Sher, L. D., Kresch, E. (2009). In the possibility of no thermal biological effects of pulsed electromagnetic radiation. Biophys. S., 18, 980–990.
  14. Lin, J. C. (2005). Advances in Electromagnetic Fields in Living Systems. Springer, 227. doi: 10.1007/b104216
  15. Nikol'skiy, V. V., Nikol'skaya, T. I. (2012). Electrodynamics and radio wave propagation. Мoscow: Librocom, 544.
  16. Pirotti, Ye. L., Kaplun, O. V. (2015). Mathematical models of electromagnetic fields in the middle of the cylindrical and spherical biological structures. Bulletin of Kharkiv national technical University of agriculture named of P. Vasilenko, 164, 166–168.

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Published

2017-12-12

How to Cite

Popriadukhin, V., Popova, I., Kosulina, N., Cherenkov, A., & Chorna, M. (2017). Analysis of the electromagnetic field of multilayered biological objects for their irradiation in a waveguide system. Eastern-European Journal of Enterprise Technologies, 6(5 (90), 58–65. https://doi.org/10.15587/1729-4061.2017.118159

Issue

Vol. 6 No. 5 (90) (2017): Applied physics

Section

Applied physics

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Copyright (c) 2017 Vadym Popriadukhin, Iryna Popova, Natalia Kosulina, Aleksandr Cherenkov, Mariya Chorna

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