2022
DOI: 10.3390/app12030969
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Characteristics of 2.45 GHz Surface-Wave-Sustained Argon Discharge for Bio-Medical Applications

Abstract: Cold atmospheric plasma (CAP) applications in various fields, such as biology, medicine and agriculture, have significantly grown during recent years. Many new types of plasma sources operating at atmospheric pressure in open air were developed. In order to use such plasmas for the treatment of biological systems, plasma properties should fulfil strong requirements. One of the most important is the prevention from heating damage. That is why in many cases, the post-discharge region is used for treatment, but t… Show more

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Cited by 13 publications
(9 citation statements)
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“…When the discharge tube is shortly outside the surfatron, the electromagnetic wave continues traveling along the plasma-air interface, producing the plasma torch in the open space in this way (Figure 1). Usually, the plasma gas temperature T g of the torch is above 100 • C and depending on the electromagnetic wave power can reach 5000 • C. At low wave power (12 W in our case) and appropriate discharge conditions, the temperature of the plasma is below 40 • C [25], and at such conditions the microwave torch can be used as a CAP source. The treated samples are inside the active plasma-sustaining region in the plasma torch but not in an afterglow region.…”
Section: Microwave Plasma Torchmentioning
confidence: 94%
“…When the discharge tube is shortly outside the surfatron, the electromagnetic wave continues traveling along the plasma-air interface, producing the plasma torch in the open space in this way (Figure 1). Usually, the plasma gas temperature T g of the torch is above 100 • C and depending on the electromagnetic wave power can reach 5000 • C. At low wave power (12 W in our case) and appropriate discharge conditions, the temperature of the plasma is below 40 • C [25], and at such conditions the microwave torch can be used as a CAP source. The treated samples are inside the active plasma-sustaining region in the plasma torch but not in an afterglow region.…”
Section: Microwave Plasma Torchmentioning
confidence: 94%
“…This makes it valuable in applications where accurate temperature measurements are critical. Determination of the treated area's temperature and monitoring it during the in vivo treatments was performed with a Testo 865 infrared camera (produced by Testo SE & Co. KGaA, Titisee-Neustadt, Germany) as investigated in [27]. We measured the reflected radiation from a tilted 45-degree mica plate.…”
Section: Methodsmentioning
confidence: 99%
“…One of the problems is that the strong chemical reaction between the active atoms produced by microwave plasma and the surface of the metal electrodes will lead to electrode corrosion, which will limit the service life of plasma devices [18,19]. Therefore, many studies have proposed electrodeless discharge devices to overcome the problem of electrode poisoning caused by electrode discharge [20], such as surface-wave-sustained discharges [21][22][23], microwave plasma jets [24], plasma guns [25], etc. However, when we apply liquid water to these devices, many additional devices are often added to generate water vapor plasma, such as heating and evaporation equipment or vacuum sealing device.…”
Section: Introductionmentioning
confidence: 99%