In this paper, we present a new structure for Ar–N2 plasma jet generation where a pulsed electric field is modified with a second alternating electric field, referred to as mixed electric field. The electric field distribution through the jet tube is simulated for the conventional and newly designed plasma jet. It is demonstrated that the value of the electric field becomes stronger due to mixed electric field, particularly between the tip and ring electrodes through the tube. Not only does the length of plasma jet increase from 15 cm to 30 cm when a mixed electric field is employed, but also the temperature of the substrate surface decreases from 62 °C to 52 °C at the same power, which is favorable for industrial applications. It is shown that introducing more nitrogen into the plasma jet shortens the length of the jet, while the jet length could substantially be improved using the current design. The capability of surface treatment at different electrical power is also evaluated on deposited TiN layers by the conventional and current plasma jet. The surface treatment by the newly designed plasma jet based on mixed electric field shows no detectable damage on the TiN layer, while the conventional plasma jet degrades the surface at equal power. The hydrophilicity of the surface is also measured by the contact angle of a water droplet, which decreases from 66 to 31° after surface treatment, implying the surface becomes more hydrophilic. The temperature distribution on the substrate is also evaluated for Ar–N2 plasma jet and compared with the conventional plasma jet structure.
In this paper, the dynamics and flow behaviour of an atmospheric argon plasma jet was studied in the new nozzle structure similar to the surface dielectric barrier discharge (SDBD) using the Schlieren imaging method. The effect of plasma jet driven by repetitive high-voltage microsecond pulses with low-frequency sinusoidal bias was measured qualitatively in a single mirror Schlieren optical system. The enhancement of plasma jet length and cross-section of plasma jet with surface in this condition is due to highly turbulent flow of argon plasma jet in this structure. This study revealed the important role of SDBD structure and modulated electric field on the behaviour of plasma jet in a high diameter nozzle. In practice, this technique allows us to increase the jet length of the nozzle output to 5 cm and under these conditions, the diameter of the plasma jet cross-section is increased to 8 mm, without increasing the electrical power consumption. Eventually, the hydrophilicity of the surface is also measured by the contact angle of a water droplet that decreases from 78 • to 8 • after surface treatment, implying we were able to reach a super-hydrophilic surface with this plasma jet structure. K E Y W O R D S hydrophilicity, modulated electric field, plasma jet, Schlieren imaging, surface dielectric barrier discharge (SDBD)
In this study, the design, performance, and characteristics of a low-temperature argon plasma jet with cascading electrode technique (APJCE) are presented. APJCE is designed based on a tip-ring structure with a cascading ring. The effect of plasma jet driven by repetitive high-voltage microsecond pulses in APJCE structure was measured qualitatively in local surface temperature detection system. Then, by applying the generated plasma jet to biological surface and measuring and characterizing the electrical parameters, we obtained a plasma jet, which is electrically and thermally in the cold plasma regime. Simulation of the electric field distribution in the nozzle also yielded similar results to the experimental results. Finally, by cascading electrodes, we guided the plasma column to the nozzle output so that the plasma temperature within four centimeters of the nozzle output is 37 °C. The resulting plasma jets were studied by atomic emission spectroscopy and the intensity of the spectral lines of the atmospheric argon plasma jet spectra was obtained as a final experimental result at the output.
In this study, the design, performance, and characteristics of a low-temperature argon plasma jet with cascading electrode technique (APJCE) are presented. APJCE is designed based on a tip-ring structure with a cascading ring. The effect of plasma jet driven by repetitive high-voltage microsecond pulses in APJCE structure was measured qualitatively in local surface temperature detection system. Then, by applying the generated plasma jet to biological surface and measuring and characterizing the electrical parameters, we obtained a plasma jet, which is electrically and thermally in the cold plasma regime. Simulation of the electric field distribution in the nozzle also yielded similar results to the experimental results. Finally, by cascading electrodes, we were able to guide the plasma column to the nozzle output so that the plasma temperature in four centimeter of the nozzle output is 37℃. The resulting plasma jets were studied by atomic emission spectroscopy and the intensity of the spectral lines of the atmospheric argon plasma jet spectra was obtained as a final experimental result at the output.
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