Effects of duty ratio on liquid- and polymer-surface treatment by a unipolar microsecond-pulsed helium atmospheric-pressure plasma jet

Effects of duty ratio of a unipolar microsecond-pulsed helium atmospheric-pressure plasma jet (APPJ) on liquid- and polymer-surface treatments were investigated. In addition, changes in the plasma plume length, gas temperature, excitation temperature, discharge current, absorption power, and optical emission spectra were examined by varying the other operating parameters, such as applied voltage and additive flow of oxygen or water vapor. As an example of liquid sample, de-ionized water (DW) was exposed to an APPJ, and the concentrations of the reactive species generated in the DW were measured as functions of the operating parameters. Polycarbonate, polypropylene, and polymethylmethacrylate were employed as exemplary substrate materials to investigate the effect of plasma treatment on polymeric surfaces. The APPJ treatment increased the surface energy and changed the wetting characteristics of the surface from hydrophobic to hydrophilic. X-ray photoelectron spectroscopy results showed that a short-time plasma treatment with He and/or He/O-2, He/H2O affects the surface wettability owing to the introduction of polar groups.

Automated summary

The effects of duty ratio of a unipolar microsecond-pulsed helium atmospheric-pressure plasma jet (APPJ) on liquid- and polymer-surface treatments were analyzed. By varying operating parameters such as applied voltage and additive flow, changes in plasma plume length, gas temperature, excitation temperature, discharge current, absorption power, and optical emission spectra were observed. The experiments included exposure of de-ionized water to the APPJ and investigating the effect of plasma treatment on polymeric surfaces using polycarbonate, polypropylene, and polymethylmethacrylate as substrates. The findings showed increased surface energy and changed wetting characteristics due to the introduction of polar groups.