Publications

Journal of Physics D: Applied Physics

Parsey, Guy; Lietz, Amanda M.; Kushner, Mark J.

The optimal use of atmospheric pressure plasma jets (APPJs) for treatment of surfaces-inorganic, organic and liquid-depends on being able to control the flow of plasma-generated reactive species onto the surface. The typical APPJ is a rare gas mixture (RGM) flowed through a tube to which voltage is applied, producing an RGM plasma plume that extends into the ambient air. The RGM plasma plume is guided by a surrounding shroud of air due to the higher electric field required for an ionization wave (IW) to propagate into the air. The mixing of the ambient air with the RGM plasma plume then determines the production of reactive oxygen and nitrogen species (RONS). The APPJ is usually oriented perpendicular to the surface being treated. However, the angle of the APPJ with respect to the surface may be a method to control the production of reactive species to the surface due to the change in APPJ propagation properties and the resulting gas dynamics. In this paper, we discuss results from computational and experimental investigations addressing two points-propagation of IWs in APPJs with and without a guiding gas shroud as a function of angle of the APPJ with respect to the surface; and the use of this angle to control plasma activation of thin water layers. We found that APPJs propagating out of the plasma tube into a same-gas environment lack any of the directional properties of shroud-guided jets, and largely follow electric field lines as the angle of the plasma tube is changed. Guided APPJs propagate coaxially with the tube as the angle is changed, and turn perpendicularly towards the surface only a few mm above the surface. The angle of the APPJ produces different gas dynamic distributions, which enable some degree of control over the content of RONS transferred to thin water layers.

Journal of Physics. D, Applied Physics

Mohades, Soheila M.; Lietz, Amanda M.; Kushner, Mark J.

Activation of liquids with atmospheric pressure plasmas is being investigated for environmental and biomedical applications. When activating the liquid using gas plasma produced species (as opposed to plasmas sustained in the liquid), a rate limiting step is transport of these species into the liquid. To first order, the efficiency of activating the liquid is improved by increasing the ratio of the surface area of the water in contact with the plasma compared to its volume—often called the surface-to-volume ratio (SVR). Maximizing the SVR then motivates the plasma treatment of thin films of liquids. In this paper, results are discussed from a computational investigation using a global model of atmospheric pressure plasma treatment of thin water films by a dielectric barrier discharge (DBD) sustained in different gases (Ar, He, air, N₂, O₂). The densities of reactive species in the plasma activated water (PAW) are evaluated. The residence time of the water in contact with the plasma is increased by recirculating the PAW in plasma reactor. Longer lived species such as H₂O_2aq and NO₃^-_aq accumulate over time (aq denotes an aqueous species). DBDs sustained in Ar and He are the most efficient at producing H₂O_2aq, DBDs sustained in argon produces the largest density of NO₃^-_aq with the lowest pH, and discharges sustained in O₂ and air produce the highest densities of O_3aq. Finally, comparisons to experiments by others show agreement in the trends in densities in PAW including O_3aq, OH_aq, H₂O_2aq and NO₃^-_aq, and highlight the importance of controlling desolvation of species from the activated water.