ELECTRODYNAMIC CHARACTERISTICS OF A VOLUME RADIO-ABSORBING MATERIAL BASED ON NANOCARBON
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Abstract
The paper presents a technique for experimental study of the electrodynamic characteristics of radio-absorbing material. The results of an experimental study of the reflection coefficient and the attenuation coefficient of samples of bulk materials of electromagnetic protection based on nanocarbon in the frequency range of 8–12 GHz are presented. Recommendations are given for the practical application of the materials under study: microwave absorbers can be used inside the working cavities of units and equipment to prevent multiple reflections of microwave waves, and allow solving the problem of shielding at high frequencies by absorbing scattered radiation.
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References
Kovneristyj, Ju. K., Lazareva, I. Ju., & Ravaev, A. A. (1982). Materialy, pogloshchayushchie SVCh-izluchenie [Materials that absorb microwave radiation]. Moscow: Science. (In Russ).
Vlasenko, E. A., Bokova, E. S., & Dedov, A. V. (2016). Kompozicionnyj radiopogloshhajushhij material na osnove napolnennoj reziny i modificirovannogo netkanogo polotna [Composite radio-absorbing material based on bone rubber and modified non-woven fabric]. Materialovedenie [Materials Science], (2), 41–43. (In Russ).
Zhuravlev, V. A., Susljaev, V. I., Korovin, E. Ju., & Docenko, O. A. (2010). Radiopogloshhajushhie svojstva soderzhashhih karbonil'noe zhelezo kompozitov na SVCh i KVCh [Radio absorbing properties of composites containing carbonyl iron at microwave and EHF]. Issledovano v Rossii [Investigated in Russia], (35), 404–411.
Golubeva, N. S., & Mitrohin, V. N. (2006). Osnovy radiojelektroniki sverhvysokih chastot [Fundamentals of microwave radio electronics]. Moscow: Publishing house of MSTU named after N. E. Bauman. (In Russ).
Cejtlin, M. B. (2004). Pobochnye kolebanija v jelektronnyh priborah SVCh [Side oscillations in microwave electronic devices]. Moscow: Radio and Communications. (In Russ).
Latypova, A. F., & Kalinin, Ju. E. (2012). Analiz perspektivnyh radiopogloshhajushhih materialov [Analysis of promising radio-absorbing materials]. Vestnik Voronezhskogo gosudarstvennogo tehnicheskogo universiteta [Bulletin of the Voronezh State Technical University], 8(6), 70–76. (In Russ).
Kraev, I. D., Shul'deshov, E. M., Platonov, M. M., & Jurkov, G. Ju. (2016). Obzor kompozicionnyh materialov, sochetajushhih zvukozashhitnye i radiozashhitnye svojstva [Review of composite materials combining soundproof and radioprotective properties]. Aviacionnye materialy i tehnologii [Aviation materials and technologies], 4(45), 61–67. (In Russ).
Nikolajchuk, G. A., Ivanov, V. P., & Jakovlev, S. V. (2010). Radiopogloshhajushhie materialy na osnove nanostruktur [Radar absorbing materials based on nanostructures]. Jelektronika: nauka, tehnologija, biznes [Electronics: science, technology, business], (1), 92–95. (In Russ).
Chung, D. D. L. (2001). Electromagnetic interference shielding effectiveness of carbon materials. Carbon, (39), 279–285.
Bannyj, V. A., Carenko, I. V., & Krasjuk, S. I. (2018). Modificirovannye uglerodnym napolnitelem radiopogloshhajushhie kompozicionnye materialy na osnove polijetilena [Radar-absorbing composite materials based on polyethylene modified with carbon filler]. In Sovremennye problemy mashinovedenija [Modern problems of mechanical engineering] (129–130). Gomel: GSTU im. P. O. Sukhoi. (In Russ).
Kraev, I. D., Sorokin, A. E., Olihova, Ju. V., & Titkova, Ju. M. (2020). Konstrukcionnye materialy radiotehnicheskogo naznachenija, modificirovannye uglerodnymi nanotrubkami [Structural materials for radio engineering, modified with carbon nanotubes]. Plasticheskie massy [Plastic masses], (9–10), 62–66. (In Russ).
Fal'kovskij, O. I. (2009). Tehnicheskaja jelektrodinamika [Technical electrodynamics]. St. Petersburg: Publ. Lan. (In Russ).
Lagarkov, A. N., Semenenko, V. N., Kisel, V. N. & Chistyaev, V. A. (2003). Development and simulation of microwave artificial magnetic composites utilizing nonmagnetic inclusions. Journal of Magnetism and Magnetic Materials, (258–259), 161–166.
Serebrjannikov, S. V., Borodulin, V. N., Cheparin, V. P., Smirnov, D. O., & Konkin, D. N. (2008). Fiziko-mehanicheskie svojstva kompozicionnyh radiopogloshhajushhih materialov na osnove ferritov [Physical and mechanical properties of composite radio-absorbing materials based on ferrites]. In Radiolokacija i radiosvjaz' [Radar and Radio Communications] (579–587). Moscow: MPEI. (In Russ).
Priou, A., Sihvola, A., Tretyakov, S., & Vinogradov, A. (1997). Advances in complex electromagnetic materials. NATO ASI Series. 3. High Technology, Kluwer Akademic Publishers, (28), 396.
Lyn'kov, L. M., Bogush, V. A., Borbot'ko, T. V., Ukrainec, E. A., & Kolbun, N. V. (2004). Novye materialy dlja jekranov jelektromagnitnogo izluchenija [New materials for screens of electromagnetic radiation]. Doklady BGUIR [Reports of BSUIR], (3), 152–167. (In Russ).
Zhdanok, S. A., Krauklis, A. V., Bujakov, I. F., Volzhankin, V. M., Borisevich, K. O., & Samcov, P. P. (2008). Obrazovanie uglerodnyh nanostruktur pri razlozhenii metana v plazme vysokovol'tnogo razrjada atmosfernogo davlenija [Formation of Carbon Nanostructures during the Decomposition of Methane in High-Voltage Discharge Plasma at Atmospheric Pressure]. Inzhenerno-fizicheskij zhurnal [Engineering Physics Journal], 81(4), 617–620. (In Russ).
Zhdanok, S. A., Krauklis, A. V., Bujakov, I. F., Karpovich, V. A., Rodionova, V. N., & Tanana, O. V. (2011). Radiopogloshhajushhie svojstva uglerodnyh nanomaterialov [Radio absorbing properties of carbon nanomaterials]. Nanotehnika [Nanotechnology], (2), 72–75. (In Russ).