Thematische Bibliographien / Surface wave microwave discharge / Zeitschriftenartikel
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Zeitschriftenartikel zum Thema „Surface wave microwave discharge“

Autor: Grafiati
Veröffentlicht am 28. Juni 2021
Zuletzt aktualisiert am 12. Februar 2022

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1

Булат, П. В., Л. П. Грачев, И. И. Есаков und А. А. Раваев. „Граничное значение поля, разделяющее области подкритических и глубоко подкритических видов СВЧ-разряда, зажигаемого на диэлектрической поверхности“. Журнал технической физики 89, Nr. 1 (2019): 64. http://dx.doi.org/10.21883/jtf.2019.01.46963.128-18.

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AbstractMicrowave discharges initiated by an electromagnetic (EM) vibrator and ignited on the inner surface of a dielectric tube in a quasi-optical EM beam are experimentally studied. A threshold level of the microwave field that separates domains of subcritical and deeply subcritical microwave discharges is determined in experiments. Experiments show that streamer channels of the subcritical discharge propagate from the initiator along the propagation direction of the EM wave and in the opposite direction under certain conditions. Variations in the power of the microwave beam can be used to change length of the plasma region of the subcritical discharge along the wave vector of the microwave beam and control the level of the EM energy absorbed in the plasma regions of the deeply subcritical microwave discharge.
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2

Zhukov, V. I., D. M. Karfidov und K. F. Sergeichev. „Propagation of microwave surface-wave-sustained discharge in air“. Journal of Physics: Conference Series 1383 (November 2019): 012021. http://dx.doi.org/10.1088/1742-6596/1383/1/012021.

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3

Yanguas-Gil, A., J. L. Hueso, J. Cotrino, A. Caballero und A. R. González-Elipe. „Reforming of ethanol in a microwave surface-wave plasma discharge“. Applied Physics Letters 85, Nr. 18 (November 2004): 4004–6. http://dx.doi.org/10.1063/1.1808875.

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4

Yanagita, Norihito, Toshifumi Itagaki und Makoto Katsurai. „Experimental Investigations on Discharge Characteristicsof Plane Type Surface Wave Microwave Plasma“. IEEJ Transactions on Fundamentals and Materials 121, Nr. 1 (2001): 44–51. http://dx.doi.org/10.1541/ieejfms1990.121.1_44.

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5

Rakem, Z., P. Leprince und J. Marec. „Modelling of a microwave discharge created by a standing surface wave“. Journal of Physics D: Applied Physics 25, Nr. 6 (14.06.1992): 953–59. http://dx.doi.org/10.1088/0022-3727/25/6/009.

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6

AZARENKOV, N. A., I. B. DENISENKO und K. N. OSTRIKOV. „Microwave gas discharge produced and sustained by a surface wave propagating along a cylindrical metal antenna with a dielectric coating“. Journal of Plasma Physics 59, Nr. 1 (Januar 1998): 15–26. http://dx.doi.org/10.1017/s0022377897006272.

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The structure of a microwave gas discharge produced and sustained by a surface wave (SW) propagating along a cylindrical metal antenna with a dielectric coating is studied. The SW that produces and sustains the microwave gas discharge propagates along an external magnetic field and has an eigenfrequency in the range between the electron cyclotron and electron plasma frequencies. The presence of a dielectric (vacuum) sheath region separating the antenna from the plasma is assumed. The spatial distributions of the produced plasma density, electromagnetic fields, energy flow density, phase velocity and reverse skin depth of the SW are obtained analytically and numerically.
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7

Azarenkov, N. A., V. O. Girka und I. V. Pavlenko. „Microwave Gas Discharge Sustained by the Azimuthal Surface Waves“. Contributions to Plasma Physics 40, Nr. 5-6 (September 2000): 529–36. http://dx.doi.org/10.1002/1521-3986(200009)40:5/6<529::aid-ctpp529>3.0.co;2-1.

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8

Chen, Guoxing, Tiago Silva, Violeta Georgieva, Thomas Godfroid, Nikolay Britun, Rony Snyders und Marie Paule Delplancke-Ogletree. „Simultaneous dissociation of CO2 and H2O to syngas in a surface-wave microwave discharge“. International Journal of Hydrogen Energy 40, Nr. 9 (März 2015): 3789–96. http://dx.doi.org/10.1016/j.ijhydene.2015.01.084.

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9

Czylkowski, D., M. Jasiński, J. Mizeraczyk und Z. Zakrzewski. „Argon and neon plasma columns in continuous surface wave microwave discharge at atmospheric pressure“. Czechoslovak Journal of Physics 56, S2 (Oktober 2006): B684—B689. http://dx.doi.org/10.1007/s10582-006-0271-7.

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10

Bogdanov, Todor, Ivan Tsonev, Plamena Marinova, Evgenia Benova, Krasimir Rusanov, Mila Rusanova, Ivan Atanassov, Zdenka Kozáková und František Krčma. „Microwave Plasma Torch Generated in Argon for Small Berries Surface Treatment“. Applied Sciences 8, Nr. 10 (10.10.2018): 1870. http://dx.doi.org/10.3390/app8101870.

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Demand for food quality and extended freshness without the use of harmful chemicals has become a major topic over the last decade. New technologies are using UV light, strong electric field, ozone and other reactive agents to decontaminate food surfaces. The low-power non-equilibrium (cold) atmospheric pressure operating plasmas effectively combines all the qualities mentioned above and thus, due to their synergetic influence, promising results in fruit surface decontamination can be obtained. The present paper focuses on the applicability of the recently developed microwave surface wave sustained plasma torch for the treatment of selected small fruit. Optical emission spectroscopy is used for the determination of plasma active particles (radicals, UV light) and plasma parameters during the fruit treatment. The infrared camera images confirm low and fully applicable heating of the treated surface that ensures no fruit quality changes. The detailed study shows that the efficiency of the microbial decontamination of selected fruits naturally contaminated by microorganisms is strongly dependent on the fruit surface shape. The decontamination of the rough strawberry surface seems inefficient using the current configuration, but for smooth berries promising results were obtained. Finally, antioxidant activity measurements demonstrate no changes due to plasma treatment. The results confirm that the MW surface wave sustained discharge is applicable to fruit surface decontamination.
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11

Ghanashev, Ivan, Masaaki Nagatsu, Ge Xu und Hideo Sugai. „Mode Jumps and Hysteresis in Surface-Wave Sustained Microwave Discharges“. Japanese Journal of Applied Physics 36, Part 1, No. 7B (30.07.1997): 4704–10. http://dx.doi.org/10.1143/jjap.36.4704.

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12

Ricard, A., C. Barbeau, A. Besner, J. Hubert, J. Margot-Chaker, M. Moisan und G. Sauvé. „Production of metastable and resonant atoms in rare-gas (He, Ne, Ar) radio-frequency and microwave-sustained discharges“. Canadian Journal of Physics 66, Nr. 8 (01.08.1988): 740–48. http://dx.doi.org/10.1139/p88-122.

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Radial density distributions of excited atoms in plasma columns of helium, neon, and argon, sustained by a travelling electromagnetic surface wave, are examined as a function of frequency over the range 200 kHz – 2450 MHz. This investigation is conducted using an end-on measurement method. At low frequencies (<50 MHz), these radial distributions show a maximum at the axis (J0 Bessel-like behavior), whereas as frequency is increased beyond 50 MHz up to 2450 MHz, the radial distributions flatten and finally exhibit a minimum at the axis with a maximum close to the tube wall. Comparison with a DC positive column plasma, working under the same gas-pressure and tube-diameter conditions, is made as a function of cross-section average electron density. The surface-wave discharge operated in the microwave frequency range (>300 MHz) yields larger cross-section average densities for atoms in a metastable or resonant state, typically a factor of 2–3 at 1011 electrons∙cm−3. This result arises because the two types of discharges have different radial-density distributions for excited atoms.
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13

Girka, V. O. „Electron Heating During Microwave Gas Discharge Sustained by Surface Cyclotron Waves“. Physica Scripta 60, Nr. 3 (01.09.1999): 257–60. http://dx.doi.org/10.1238/physica.regular.060a00257.

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14

Nagatsu, M., G. Xu, I. Ghanashev, M. Kanoh und H. Sugai. „Mode identification of surface waves excited in a planar microwave discharge“. Plasma Sources Science and Technology 6, Nr. 3 (01.08.1997): 427–34. http://dx.doi.org/10.1088/0963-0252/6/3/020.

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15

Zhukov, V. I., D. M. Karfidov und K. F. Sergeichev. „Propagation of Microwave Discharge Sustained by Surface Wave in Quartz Tube Filled with Low-Pressure Air“. Plasma Physics Reports 46, Nr. 8 (August 2020): 837–45. http://dx.doi.org/10.1134/s1063780x20080127.

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16

Kutasi, Kinga, Vasco Guerra und Paulo A. Sá. „Active species downstream of an Ar–O2surface-wave microwave discharge for biomedicine, surface treatment and nanostructuring“. Plasma Sources Science and Technology 20, Nr. 3 (14.04.2011): 035006. http://dx.doi.org/10.1088/0963-0252/20/3/035006.

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17

Ivanova, K., I. Koleva, A. Shivarova und E. Tatarova. „Radiophysics plasma diagnostic methods applied to surface wave sustained microwave discharges“. Physica Scripta 47, Nr. 2 (01.02.1993): 224–29. http://dx.doi.org/10.1088/0031-8949/47/2/017.

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18

Makasheva, K., und A. Shivarova. „Plasma parameters of diffusion-controlled microwave discharges in surface-wave fields“. IEEE Transactions on Plasma Science 30, Nr. 1 (Februar 2002): 384–90. http://dx.doi.org/10.1109/tps.2002.1003885.

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19

Moreno, Sergio H., Andrzej I. Stankiewicz und Georgios D. Stefanidis. „A two-step modelling approach for plasma reactors – experimental validation for CO2 dissociation in surface wave microwave plasma“. Reaction Chemistry & Engineering 4, Nr. 7 (2019): 1253–69. http://dx.doi.org/10.1039/c9re00022d.

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20

Boudreau, Denis, Chantal Laverdure und Joseph Hubert. „Nitrogen Determination in Argon by Surface-Wave-Induced Plasma Atomic Emission Spectrometry“. Applied Spectroscopy 43, Nr. 3 (März 1989): 456–60. http://dx.doi.org/10.1366/0003702894202904.

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An on-line analyzer for traces of nitrogen in argon was developed with the use of microwave-induced plasma/atomic emission spectrometry (MIP-AES). The plasma is generated with a surface wave launcher called “Surfatron.” The emission spectra of the major impurities of argon were characterized in the spectral region from 600 to 900 nm. Effects on analyte emission of parameters such as observation height in the plasma, gas flow and pressure, applied power, and discharge tube geometry were studied. A charge-coupled device (CCD) was used as the multichannel detector for this analyzer. The automation of the CCD by a microcomputer allowed fast, unaided data acquisition and analysis, and the overall system had the compactness, ruggedness, and stability essential for on-line use. We measured a 0.4-ppm detection limit for nitrogen, and the system's long-term stability is greater than 99%. Also, comparative work with a commercial photodiode array (PDA) system was conducted, and a 0.05-ppm detection limit for nitrogen was obtained.
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21

Rousseau, A., E. Teboul und S. Béchu. „Comparison between Langmuir probe and microwave autointerferometry measurements at intermediate pressure in an argon surface wave discharge“. Journal of Applied Physics 98, Nr. 8 (15.10.2005): 083306. http://dx.doi.org/10.1063/1.2112172.

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22

Nakagawa, Takashi, Jaeho Kim, Takayuki Toba und Makoto Katsurai. „Three Dimensional Numerical Analysis on Discharge Properties of Microwave Excited Ring-Dielectric-Line Surface Wave Processing Plasma Device“. IEEJ Transactions on Fundamentals and Materials 123, Nr. 5 (2003): 481–89. http://dx.doi.org/10.1541/ieejfms.123.481.

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23

Kutasi, Kinga, Dean Popović, Nikša Krstulović und Slobodan Milošević. „Tuning the composition of plasma-activated water by a surface-wave microwave discharge and a kHz plasma jet“. Plasma Sources Science and Technology 28, Nr. 9 (06.09.2019): 095010. http://dx.doi.org/10.1088/1361-6595/ab3c2f.

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24

Kutasi, Kinga, Cédric Noël, Thierry Belmonte und Vasco Guerra. „Tuning the afterglow plasma composition in Ar/N2/O2mixtures: characteristics of a flowing surface-wave microwave discharge system“. Plasma Sources Science and Technology 25, Nr. 5 (25.08.2016): 055014. http://dx.doi.org/10.1088/0963-0252/25/5/055014.

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25

Nakagawa, Takashi, Jaeho Kim, Takayuki Toba und Makoto Katsurai. „Three-dimensional numerical analysis on discharge properties of microwave excited ring dielectric line surface wave processing plasma device“. Electrical Engineering in Japan 150, Nr. 4 (2005): 1–12. http://dx.doi.org/10.1002/eej.10333.

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26

Zlobina, I. V., und A. A. Korotich. „IMPACT OF HIGH VOLTAGE ELECTRIC DISCHARGES ON THE CURED POLYMER COMPOSITE MATERIALS, MODIFIED IN A MICROWAVE ELECTROMAGNETIC FIELD“. Spravochnik. Inzhenernyi zhurnal, Nr. 284 (November 2020): 6–12. http://dx.doi.org/10.14489/hb.2020.11.pp.006-012.

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Due to the widespread use of carbon fiber-reinforced polymer composite materials (PCM) in the structural elements of aircraft with a distributed surface layer of lightning-proof coating (MFP) in the form of metal grids to reduce the risk of lightning strikes and the possibility of increasing their strength characteristics by processing in the microwave electromagnetic field, the need to study the impact of this method of processing on the resistance of PCM to high voltage electrical discharges. The studies of the impact of the discharge voltage 180…200 kV on samples of PCM with the minimum wage and no minimum wage. It is established that pretreatment of samples of the cured polymer composite MW in a microwave electromagnetic field energy flux density (17…18)104 µw/cm2 does not degrade their molniezaschita characteristics and contributes to reducing the size of the damaged area up to 1.5 times. Samples processed in the microwave electromagnetic field without MSP do not have delaminations and burns in contrast to the control ones. The obtained results indicate the possibility of strengthening treatment in the microwave electromagnetic field of structural elements of carbon fiber distributed in the surface layer of the MSP in the form of a metal grid.
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27

Zlobina, I. V., und A. A. Korotich. „IMPACT OF HIGH VOLTAGE ELECTRIC DISCHARGES ON THE CURED POLYMER COMPOSITE MATERIALS, MODIFIED IN A MICROWAVE ELECTROMAGNETIC FIELD“. Spravochnik. Inzhenernyi zhurnal, Nr. 284 (November 2020): 6–12. http://dx.doi.org/10.14489/hb.2020.11.pp.006-012.

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Due to the widespread use of carbon fiber-reinforced polymer composite materials (PCM) in the structural elements of aircraft with a distributed surface layer of lightning-proof coating (MFP) in the form of metal grids to reduce the risk of lightning strikes and the possibility of increasing their strength characteristics by processing in the microwave electromagnetic field, the need to study the impact of this method of processing on the resistance of PCM to high voltage electrical discharges. The studies of the impact of the discharge voltage 180…200 kV on samples of PCM with the minimum wage and no minimum wage. It is established that pretreatment of samples of the cured polymer composite MW in a microwave electromagnetic field energy flux density (17…18)104 µw/cm2 does not degrade their molniezaschita characteristics and contributes to reducing the size of the damaged area up to 1.5 times. Samples processed in the microwave electromagnetic field without MSP do not have delaminations and burns in contrast to the control ones. The obtained results indicate the possibility of strengthening treatment in the microwave electromagnetic field of structural elements of carbon fiber distributed in the surface layer of the MSP in the form of a metal grid.
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28

Kortshagen, U., A. Shivarova, E. Tatarova und D. Zamfirov. „Electron energy distribution function in a microwave discharge created by propagating surface waves“. Journal of Physics D: Applied Physics 27, Nr. 2 (14.02.1994): 301–11. http://dx.doi.org/10.1088/0022-3727/27/2/019.

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29

Zhang, Wencong, Li Wu, Junwu Tao und Kama Huang. „Numerical Investigation of the Gas Flow Effects on Surface Wave Propagation and Discharge Properties in a Microwave Plasma Torch“. IEEE Transactions on Plasma Science 47, Nr. 1 (Januar 2019): 271–77. http://dx.doi.org/10.1109/tps.2018.2882637.

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30

Chen, Guoxing, Thomas Godfroid, Nikolay Britun, Violeta Georgieva, Marie-Paule Delplancke-Ogletree und Rony Snyders. „Plasma-catalytic conversion of CO 2 and CO 2 /H 2 O in a surface-wave sustained microwave discharge“. Applied Catalysis B: Environmental 214 (Oktober 2017): 114–25. http://dx.doi.org/10.1016/j.apcatb.2017.05.032.

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31

García, M. C., C. Yubero, M. D. Calzada und M. P. Martínez-Jiménez. „Spectroscopic Characterization of Two Different Microwave (2.45 GHz) Induced Argon Plasmas at Atmospheric Pressure“. Applied Spectroscopy 59, Nr. 4 (April 2005): 519–28. http://dx.doi.org/10.1366/0003702053641405.

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A surface-wave-sustained discharge created by using a surfatron device in a tube open to the atmosphere can be used to maintain a microwave (2.45 GHz) plasma at atmospheric pressure at powers of less than 300 W. The TIA ( Torche à Injection Axiale) is a device also producing a plasma that, moreover, permits us to work at high power (higher than 200 W and up to 1000 W). A study of the departure from the thermodynamic equilibrium existing in the argon plasmas created by both devices has been done by using optical emission spectroscopy techniques in order to characterize them and to evaluate their possible advantages when they are used for applied purposes.
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32

Artem'ev, K. V., N. K. Berezhetskaya, S. Yu Kazantsev, N. G. Kononov, I. A. Kossyi, N. A. Popov, N. M. Tarasova, E. A. Filimonova und K. N. Firsov. „Fast combustion waves and chemi-ionization processes in a flame initiated by a powerful local plasma source in a closed reactor“. Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences 373, Nr. 2048 (13.08.2015): 20140334. http://dx.doi.org/10.1098/rsta.2014.0334.

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Results are presented from experimental studies of the initiation of combustion in a stoichiometric methane–oxygen mixture by a freely localized laser spark and by a high-current multispark discharge in a closed chamber. It is shown that, preceding the stage of ‘explosive’ inflammation of a gas mixture, there appear two luminous objects moving away from the initiator along an axis: a relatively fast and uniform wave of ‘incomplete combustion’ under laser spark ignition and a wave with a brightly glowing plasmoid behind under ignition from high-current slipping surface discharge. The gas mixtures in both the ‘preflame’ and developed-flame states are characterized by a high degree of ionization as the result of chemical ionization (plasma density n e ≈10 12 cm −3 ) and a high frequency of electron–neutral collisions ( ν en ≈10 12 s −1 ). The role of chemical ionization in constructing an adequate theory for the ignition of a gas mixture is discussed. The feasibility of the microwave heating of both the preflame and developed-flame plasma, supplementary to a chemical energy source, is also discussed.
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33

Kutasi, Kinga, und Ihor Korolov. „Characteristics of the flowing afterglow of a surface-wave microwave discharge in a reactor loaded with a small diameter tube“. Plasma Processes and Polymers 14, Nr. 10 (06.04.2017): 1700028. http://dx.doi.org/10.1002/ppap.201700028.

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34

Daviaud, S., C. Boisse-Laporte, P. Leprince und J. Marec. „Description of a surface-wave-produced microwave discharge in helium at low pressure in the presence of a gas flow“. Journal of Physics D: Applied Physics 22, Nr. 6 (14.06.1989): 770–79. http://dx.doi.org/10.1088/0022-3727/22/6/009.

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35

Chaker, M., M. Moisan und Z. Zakrzewski. „Microwave and RF surface wave sustained discharges as plasma sources for plasma chemistry and plasma processing“. Plasma Chemistry and Plasma Processing 6, Nr. 1 (März 1986): 79–96. http://dx.doi.org/10.1007/bf00573823.

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36

Kemaneci, Efe, Felix Mitschker, Jan Benedikt, Denis Eremin, Peter Awakowicz und Ralf Peter Brinkmann. „A numerical analysis of a microwave induced coaxial surface wave discharge fed with a mixture of oxygen and hexamethyldisiloxane for the purpose of deposition“. Plasma Sources Science and Technology 28, Nr. 11 (19.11.2019): 115003. http://dx.doi.org/10.1088/1361-6595/ab3f8a.

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37

Granier, A., D. Chéreau, K. Henda, R. Safari und P. Leprince. „Validity of actinometry to monitor oxygen atom concentration in microwave discharges created by surface wave in O2‐N2mixtures“. Journal of Applied Physics 75, Nr. 1 (Januar 1994): 104–14. http://dx.doi.org/10.1063/1.355897.

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38

Guerra, Vasco, Kinga Kutasi und Paulo A. Sá. „O2(a Δ1g) production in flowing Ar–O2 surface-wave microwave discharges: Possible use for oxygen-iodine laser excitation“. Applied Physics Letters 96, Nr. 7 (15.02.2010): 071503. http://dx.doi.org/10.1063/1.3318253.

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39

Szőke, Csaba, Zoltán Nagy, Krisztián Gierczik, András Székely, Tamás Spitkól, Zsuzsanna T. Zsuboril, Gábor Galiba, Csaba L. Marton und Kinga Kutasi. „Effect of the afterglows of low pressure Ar/N2 -O2 surface-wave microwave discharges on barley and maize seeds“. Plasma Processes and Polymers 15, Nr. 2 (27.11.2017): 1700138. http://dx.doi.org/10.1002/ppap.201700138.

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40

Tatarova, E., und D. Zamfirov. „A radially resolved experimental investigation of the electron energy distribution function in a microwave discharge sustained by propagating surface waves“. Journal of Physics D: Applied Physics 28, Nr. 7 (14.07.1995): 1354–61. http://dx.doi.org/10.1088/0022-3727/28/7/012.

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41

Olexandr A. Shchyptsov, Dmitry L. Kreta, Oleksiy G. Lebid und Natalia A. Sheviakina. „Use of remote sensing results in the tasks of navigational and hydrographic situation monitoring“. Environmental safety and natural resources 36, Nr. 4 (22.12.2020): 66–76. http://dx.doi.org/10.32347/2411-4049.2020.4.66-76.

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The paper presents the possibilities of using modern online sources of satellite information in the tasks of monitoring the ecological and navigational-hydrographic situation and building on their basis methods and information technologies to reflect the state of marine waters and operational forecasting of changes in this state. For the tasks of monitoring the ecological and navigational-hydrographic situation, one of the most convenient and informative is the marine environment monitoring service COPERNICUS (CMEMS). This service collects and presents data on observations of spatio-temporal variability of sea water temperature and salinity values, streams parameters, etc. by using specialized artificial satellites Sentinel-1 and Sentinel-2, which intended for use in the mission of a dual satellite with high viewing frequency and high resolution. CMEMS provides, on a regular and systematic basis, information on the physical condition, variability and dynamics of the oceanic and marine ecosystems. The principle of measurement uses natural microwave emissions on the sea surface, which vary depending on the degree of roughness of the sea surface. You can get the parameters of wind direction, atmospheric water vapor, rain speed, sea ice (age, concentration and limit), the length of the snow cover and the water content in the snow. High-resolution ice mapping services provide ice classification and floating ice data to navies and shipping companies to ensure safe year-round shipping. The ability of the Sentinel-1 to conduct observations in any weather and during the day or night makes it ideal for accurately determining the location and movement of the vessel at sea. Oil detection applications are used to gather evidence of illegal discharges, analyze the spread of oil spills and search for oil reserves by detecting natural infiltration. Sentinel-1 marine products, in combination with global sea wave models, help determine the direction, wavelength and height of waves on the open sea, as well as help predict the weather, the movement of ships and the use of wave energy. In addition, Sentinel-1 can provide data on the interaction of ocean waves and streams, which allows you to visualize large-scale ocean streams, cold/warm water massifs, coastal streams and internal waves. Software and hardware complexes and information-analytical systems created with the use of these methods and technologies can significantly increase the efficiency and effectiveness of solving problems of environmental monitoring, navigation and hydrographic support of navigation, search and rescue operations in marine waters.
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42

Moisan, Michel, und Helena Nowakowska. „Contribution of surface-wave (SW) sustained plasma columns to the modeling of RF and microwave discharges with new insight into some of their features. A survey of other types of SW discharges“. Plasma Sources Science and Technology 27, Nr. 7 (18.07.2018): 073001. http://dx.doi.org/10.1088/1361-6595/aac528.

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43

Aleksandrov, K. V., L. P. Grachev, I. I. Esakov und K. V. Khodataev. „Surface streamer microwave discharge“. Technical Physics 47, Nr. 7 (Juli 2002): 851–55. http://dx.doi.org/10.1134/1.1495046.

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Kirov, K., K. Makasheva und A. Shivarova. „Diagnostics of microwave discharges sustained by propagating surface waves“. Vacuum 58, Nr. 2-3 (August 2000): 280–86. http://dx.doi.org/10.1016/s0042-207x(00)00179-2.

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45

Boisse-Laporte, C., A. Granier, E. Dervisevic, P. Leprince und J. Marec. „Microwave discharges produced by surface waves in argon gas“. Journal of Physics D: Applied Physics 20, Nr. 2 (14.02.1987): 197–203. http://dx.doi.org/10.1088/0022-3727/20/2/008.

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46

Kutasi, Kinga, Paulo A. Sá und Vasco Guerra. „O2dissociation in Ar–O2surface-wave microwave discharges“. Journal of Physics D: Applied Physics 45, Nr. 19 (25.04.2012): 195205. http://dx.doi.org/10.1088/0022-3727/45/19/195205.

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47

Kutasi, Kinga, Vasco Guerra und Paulo Sá. „Theoretical insight into Ar–O2surface-wave microwave discharges“. Journal of Physics D: Applied Physics 43, Nr. 17 (15.04.2010): 175201. http://dx.doi.org/10.1088/0022-3727/43/17/175201.

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48

Esakov, Igor I., Lev P. Grachev, Kirill V. Khodataev, Vladimir L. Bychkov und David M. Van Wie. „Surface Discharge in a Microwave Beam“. IEEE Transactions on Plasma Science 35, Nr. 6 (Dezember 2007): 1658–63. http://dx.doi.org/10.1109/tps.2007.901881.

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49

Shibkov, V. M. „Mechanisms of Microwave Surface Discharge Propagation“. Technical Physics 50, Nr. 4 (2005): 462. http://dx.doi.org/10.1134/1.1901785.

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Shibkov, V. M. „Microwave Discharges and Their Application. I. Surface Microwave Discharge“. Moscow University Physics Bulletin 74, Nr. 5 (September 2019): 421–37. http://dx.doi.org/10.3103/s002713491905014x.

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