DOI: https://doi.org/10.31071/kit2018.14.11 Inventory reference ISSN 1812-7231 Klin.inform.telemed. Volume 13, Issue 14, 2018, Pages 102–107 Author(s) Yu. M. Penkin1, V. A. Katrich2, D. Yu. Penkin2, M. V. Nesterenko2 Institution(s) 1National University of Pharmacy, Kharkiv, Ukraine2V. N. Karazin Kharkiv National University, Ukraine Article title Simulator effects of longitudinal magnetic waves for biochemical research Abstract (resume) Introduction. In recent years, there has been an intense increase in research interest in the study of longitudinal electromagnetic waves. Separate for medical applications is the direction of research on the effects of longitudinal waves on biochemical objects. However, at present there are no experimental devices that provide researchers with the possibility of controlling the power of such waves and the variation of their frequency. The purpose of the work is to give a justification of the possibility of practical implementation of the simulator for the process of propagation of a longitudinal magnetic wave in a dielectric sample. Object and Methodology. The concept of an experimental simulator is based on the results obtained earlier by the authors using rigorous electrodynamic methods. Results. The concept of creating a simulator of the effect of a longitudinal magnetic wave on a dielectric sample under the conditions of controlling the power of influence and controlling the frequency of the wave process is substantiated. The simulator is proposed to be implemented on the basis of a two-channel junction of rectangular waveguides. The simulation of the wave process is based on the cyclic movements of the dielectric body inside the waveguide segment in a quasistationary magnetic field localized in the region of the coupling slots. Keywords Longitudinal magnetic wave, Wave process simulator, Waveguide device References 1. Ageev I. M., Shishkin G. G. Prodolnie volni [Longitudinal waves]. M., MAI Publ., 2014. 272 p. (In Russ.). 2. Hertz H. Untersuchungen Über die Ausbreitung der elektrischen Kraft. Leipzig, 1894, 34 s. 3. Ginzburg V. L. Rasprostranenie electromagnitnich voln v plasme [Electromagnetic Wave Propagation in a Plasma]. M., Nauka Publ., 1969. 683 p. (In Russ.). 4. Monstein C. and Wesley J. P. Observation of scalar longitudinal electrodynamic waves. Europhysics Letters, 2002, vol. 59, no. 4, pp. 514-520. 5. Abdulkerimov S. A., Ermolaev Yu. M., Rodionov B. N. Prodolnie electromagnitnie volni. Teoriya, experementi, perspective. [Longitudinal electromagnetic waves. Theory, experiments, application prospects]. M., MGUL Publ., 2003. 171 p. (In Russ.). 6. Bogdanov V. P., Nefedov E. I., Protopopov A. A. [Mutagenic and stimulating effect of longitudinal electromagnetic radiation]. Jelektrodinamika i tehnika SVCh i KVCh [Electrodynamics and technology of super high frequency radiation (SHF) and extremely high frequency (EHF)], 2000. vol. 8, no. 1-2(27), pp. 37-41. (In Russ.). 7. Penkin Yu. M., Berdnik S. L., Katrich V. A. and Nesterenko M. V. Influence of a Dielectric Insert on Energy Characteristics of a Cruciform Waveguide Junction. In Proc. XXI-th Inter Seminar/Workshop В"Direct and Inverse problems of electromagnetic and acoustic wave theory (DIPED)В", 2016, pp. 42-45. 8. Nesterenko M. V., Katrich V. A., Penkin D. Y., Berdnik S. L. and Kijko V. I. Electromagnetic waves scattering and radiation by vibrator-slot structure in a rectangular waveguide. Progress in Electromagnetics Research, M, 2012, pp. 69-84. 9. Nesterenko M. V., Katrich V. A., Penkin Yu. M. and Berdnik S. L. Analytical and Hybrid Methods in Theory of Slot-Hole Coupling of Electrodynamic Volumes. New York. Springer Science+Business Media, 2008, 146 p. 10. Yatzuk L. P., Dgironkina A. V., Katrich V. A., Penkin Yu. M. [The solution of the problem excitation of a rectangular waveguide by a magnetic current]. Izv. vuzov. Radioelectronika [University news. Radioelectronics]. 1987, vol. 30, no. 5, pp. 37-41. (In Russ.). Full-text version http://kit-journal.com.ua/en/viewer_en.html?doc/2018_14/011.pdf |
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