Study of the electric field density distribution in cylindrical chamber with coaxial feed of super high frequency radiation energy

A. A. Dovgan; Довгань А. А.; I. Sh. Bahteev; Бахтеев И. Ш.; S. Yu. Molchanov; Молчанов С. Ю.; V. V. Martynov; Мартынов В. В.; B. M. Brzhozovskii; Бржозовский Б. М.; E. P. Zinina; Зинина Е. П.

doi:10.31857/S0367676522700405

Study of the electric field density distribution in cylindrical chamber with coaxial feed of super high frequency radiation energy

作者: Dovgan A.A.¹, Bahteev I.S.², Molchanov S.Y.², Martynov V.V.¹, Brzhozovskii B.M.¹, Zinina E.P.¹
隶属关系:
1. Mechanical Engineering Research Institute of the Russian Academy of Sciences
2. Institute of Solid State Physics of the Russian Academy of Sciences
期: 卷 87, 编号 2 (2023)
页面: 218-225
栏目: Articles
URL: https://ogarev-online.ru/0367-6765/article/view/135276
DOI: https://doi.org/10.31857/S0367676522700405
EDN: https://elibrary.ru/AEUGKB
ID: 135276

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The main design options for supplying SHF energy to the end wall of a cylindrical resonator were considered. 2 types of designs for coaxial feed of energy were selected and optimized, differing in the location of the coaxial line relative to the required direction of wave propagation. As a result of the calculations, the electric fields inside the cylindrical chamber and in the horn coaxial antennas were found, and the SWR of the systems was determined. A comparison in distribution of the electric field when metal objects were placed in the chamber was carried out. The areas of occurrence of a plasma SHF discharge on the surface of a cylindrical object were shown.

参考

Barnes B.K., Ouro-Koura H., Derickson J. et al. // Amer. J. Phys. 2021. V. 89. No. 4. P. 372.
Brcka J. // Proc. COMSOL Users Conf. (Boston, 2006) P. 431.
Turkoz E., Celik M. // J. Comput. Phys. 2015. V. 286. P. 87.
Бржозовский Б.М., Мартынов В.В., Молчанов C.Ю. и др. // Усп. прикл. физ. 2020. Т. 8. № 3. С. 189.
Werner F., Korzec D., Engemann J. // Plasma Sources Sci. Technol. 1994. V. 3. No. 4. P. 473.
Jiang Y., Hsu H.Y., Aranganadin K. et al. // Proc. IVEC-2019 (Busan, 2019). P. 1.
Liu F., Wang J., Dai S. // Int. J. Numer. Model. 2011. V. 24. No. 6. P. 526.
Hasegawa Y., Nakamura K., Lubomirsky D. et al. // Japan J. Appl. Phys. 2017. V. 56. No. 4. Art. No. 046203.
Deng X., Takaoka Y., Kousaka H., Umehara N. // Surf. Coat. Technol. 2014. V. 238. P. 80.
Kar S., Alberts L., Kousaka H. // AIP Advances. 2015. V. 5. No. 1. Art. No. 017104.
Latrasse L., Lacoste A., Sirou J., Pelletier J. // Plasma Sources Sci. Technol. 2006. V. 16. No. 1. P. 7.
Latrasse L., Radoiu M., Nelis T., Antonin O. // J. Microw. Power Electromagn. Energy. 2017. V. 51. No. 4. P. 237.
Калиничев В.И., Калошин В.А. // Журн. радиоэлектроники. 2007. № 10. С. 23.
Dehdasht-Heydari R., Hassani H.R., Mallahzadeh A.R. // Progr. Electromagn. Res. 2008. V. 79. P. 23.
Mallahzadeh A.R., Imani A. // Progr. Electromagn. Res. 2009. V. 91. P. 273.
Rackow K., Ehlbeck J., Krohmann U., Baeva M. // Plasma Sources Sci. Technol. 2011. V. 20. No. 3. Art. No. 035019.
Хлопов Ю.Н. Радиоэлектроника и связь. М.: Знание, 1967. 50 с.
Соколова Ж.М. Приборы и устройства СВЧ, КВЧ и ГВЧ диапазонов. Учебное пособие. Томск: ТУСУР, 2012. 283 с.
http://npp-elmika.ru/info/index.php?id=219.