Optimization of the waveguide structure of a plasma reactor supported by powerful microwave radiation of a gyrotron at a frequency of 24 GHz

D. A. Mansfeld; Мансфельд Д. А.; N. V. Chekmarev; Чекмарев Н. В.; S. V. Sintsov; Синцов С. В.; A. V. Vodopyanov; Водопьянов А. В.

doi:10.31857/S0033849424090033

Optimization of the waveguide structure of a plasma reactor supported by powerful microwave radiation of a gyrotron at a frequency of 24 GHz

Authors: Mansfeld D.A.¹, Chekmarev N.V.¹, Sintsov S.V.¹, Vodopyanov A.V.¹
Affiliations:
1. Federal Research Center A.V. Gaponov-Grekhov Institute of Applied Physics RAS
Issue: Vol 69, No 9 (2024)
Pages: 849-854
Section: ЭЛЕКТРОДИНАМИКА И РАСПРОСТРАНЕНИЕ РАДИОВОЛН
URL: https://journals.rcsi.science/0033-8494/article/view/281987
DOI: https://doi.org/10.31857/S0033849424090033
EDN: https://elibrary.ru/HSOKMP
ID: 281987

Cite item

Full Text

Open Access
Restricted Access

Access granted
Restricted Access

Subscription Access

Abstract
Full Text
About the authors
References
Supplementary files
Statistics

Abstract

Numerical simulation of electromagnetic fields in a waveguide plasma torch has been carried out, in which microwave plasma heating is carried out by continuous radiation from a technological gyrotron with a frequency of 24 GHz and a power of up to 5 kW. It is shown that a decrease in the output diameter of the plasma torch makes it possible to more than double the amplitude of the electric field, but when the diameter decreases to 8 mm, the reflection coefficient increases significantly, which leads to reflected radiation entering the gyrotron. It is shown that taking into account the collision frequency corresponding to the real parameters of the atmospheric pressure discharge leads to a decrease in the reflection coefficient by more than 10. It has been experimentally confirmed that with a decrease in the output diameter of the plasma torch, the range of discharge maintenance parameters significantly expands, and the absorption coefficient exceeds 80%.

Keywords

microwave plasmatron, numerical modeling, atmospheric pressure discharge

Full Text

About the authors

D. A. Mansfeld

Federal Research Center A.V. Gaponov-Grekhov Institute of Applied Physics RAS

Author for correspondence.
Email: mda1981@ipfran.ru
Russian Federation, 46 Ul’yanov Str., Nizhny Novgorod, 603950

N. V. Chekmarev

Federal Research Center A.V. Gaponov-Grekhov Institute of Applied Physics RAS

Email: mda1981@ipfran.ru
Russian Federation, 46 Ul’yanov Str., Nizhny Novgorod, 603950

S. V. Sintsov

Federal Research Center A.V. Gaponov-Grekhov Institute of Applied Physics RAS

Email: mda1981@ipfran.ru
Russian Federation, 46 Ul’yanov Str., Nizhny Novgorod, 603950

A. V. Vodopyanov

Federal Research Center A.V. Gaponov-Grekhov Institute of Applied Physics RAS

Email: mda1981@ipfran.ru
Russian Federation, 46 Ul’yanov Str., Nizhny Novgorod, 603950

References

Sabchevski S., Glyavin, M., Mitsudo S. et al. // J. Infrared, Millimeter, Terahertz Waves. 2021. V. 42. P. 715. https://doi.org/10.1007/s10762-021-00804-8
Egorov S.V., Eremeev A.G., Kholoptsev V.V. et al. // Rev. Sci. Instruments. 2022. V. 93. № 6. https://doi.org/10.1063/5.0093341
Bogdashov A.A., Fokin A.P., Glyavin M.Yu. et al. // J. Infrared, Millimeter, Terahertz Waves. 2020. V. 41. P. 164. https://doi.org/10.1007/s10762-019-00655-4
Мансфельд Д.А., Водопьянов А.В., Синцов С.В. и др. // Письма в ЖТФ. 2023. Т. 49. № 1. C. 39. https://doi.org/ 10.21883/PJTF.2023.01.54057.19384
Мансфельд Д.А. // Тез. докл. конф. “Физика низкотемпературной плазмы”. Казань, 5–9.06.2023. Казань: Изд-во Казан. ун-та, 2023. С. 56.
Raizer Yu.P. Gas Discharge Physics. New York: Springer, 1991.
Yukikazu Itikawa // J. Phys. Chem. Ref. Data. 2002. V. 31. P. 749. https://doi.org/10.1063/1.1481879

Supplementary files

Supplementary Files

Action

1. JATS XML

Download

2. Fig. 1. Schematic of the waveguide microwave plasmatron (a) and a photograph of the discharge (b).

Download (48KB)

Indexing metadata

3. Fig. 2. Model of microwave plasmatron in CST Microwave Studio environment.

Download (92KB)

Indexing metadata

4. Fig. 3. Distribution of the rms value of the electric field strength in the plasmatron in logarithmic scale at the outlet diameter of 10 (a) and 6 mm (b) and along the plasmatron axis in linear scale (c) for the outlet diameter of 6 (1) and 10 mm (2). Colour scale in logarithmic scale.

Download (162KB)

Indexing metadata

5. Fig. 4. Dependence of the reflection coefficient on the diameter of the plasmatron outlet.

Download (46KB)

Indexing metadata

6. Fig. 5. Dependence of the maximum value of the electric field strength on the plasmatron axis on the diameter of the plasmatron outlet at a source power of 1 W.

Download (51KB)

Indexing metadata

7. Fig. 6. Distribution of the rms value of the electric field strength in the plasmatron at an outlet diameter of 8 mm without plasma (a), with a plasma cylinder (black contour) with electron concentration ne = 6 × 1012 cm-3 (b) and at collision frequency νc = 1012 s-1 (c).

Download (151KB)

Indexing metadata

8. Fig. 7. Comparison of the reflection coefficient R (%) in the plasmatron model without plasma, with plasma cylinder, at ne = 6 × 1012 cm-3 without collisions and with collision plasma (νc = 1012 c-1) at different values of the plasmatron outlet diameter: d = 6 (1), 7 (2), 8 (3) and 10 mm (4).

Download (114KB)

Indexing metadata

9. Fig. 8. Dependence of the reflection coefficient R (1) and the transmission coefficient T (2) on the concentration of stemless plasma.

Download (69KB)

Indexing metadata

Username
Password
Remember me

Forgot password?	Register

Username
Password
Remember me

Forgot password?	Register

Vol 70, No 2 (2025)

Vol 70, No 2 (2025)

Optimization of the waveguide structure of a plasma reactor supported by powerful microwave radiation of a gyrotron at a frequency of 24 GHz

Full Text

Abstract

Keywords

Full Text

About the authors

D. A. Mansfeld

N. V. Chekmarev

S. V. Sintsov

A. V. Vodopyanov

References

Supplementary files