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1. Physical Properties of Plasma-Activated Water

   https://doi.org/10.3390/plasma6010005  

   Shaji, Mobish; Rabinovich, Alexander; Surace, Mikaela; Sales, Christopher; Fridman, Alexander (March 2023, Plasma)

   Recent observations of plasma-activated water (PAW)’s surfactant behavior suggest that the activation of water with non-equilibrium plasma can decrease the surface tension of the water. This suggested change to the surface tension also indicates that the addition of plasma can lead to changes in the physical properties of the water, knowledge of which can expand existing PAW applications and open new ones. While the chemical behavior of PAW has been extensively analyzed, to the best of our knowledge the physical properties of PAW have not been investigated. This study focuses on the need for experimental determination of PAW’s physical properties—namely, surface tension, viscosity, and contact angle. The experimental results of this study show that the addition of plasma lowers the surface tension of water at room temperature, increases the viscosity of water at high temperatures, and lowers the contact angle of droplets on glass surfaces at room temperatures. Potential factors influencing these changes include plasma alteration of the mesoscopic structure of water at low temperatures and plasma additives acting as foreign particles in water at higher temperatures. Ultimately, this investigation demonstrates that the physical properties of water change due to plasma activation, which could lead to potential industrial applications of PAW as a surfactant or as a washing-out and cleaning agent. 

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2. Attosecond chirp compensation in water window by plasma dispersion

   https://doi.org/10.1364/OE.26.033238  

   Chang, Zenghu (December 2018, Optics Express)
3. The influence of carrier gas on plasma properties and hydrogen peroxide production in a nanosecond pulsed plasma discharge generated in a water-film plasma reactor

   https://doi.org/10.1088/1361-6463/aaa835  

   Wang, Huihui; Wandell, Robert J; Locke, Bruce R (March 2018, Journal of Physics D: Applied Physics)
4. Water-Soluble Luminescent Silicon Nanocrystals by Plasma-Induced Acrylic Acid Grafting and PEGylation

   https://doi.org/10.1021/acsabm.1c00885  

   Li, Zhaohan; Mahajan, Advitiya; Andaraarachchi, Himashi P.; Lee, Yeonjoo; Kortshagen, Uwe R. (January 2022, ACS Applied Bio Materials)
5. Phase and Morphology of Water-ice Grains Formed in a Cryogenic Laboratory Plasma

   https://doi.org/10.3847/1538-4357/ad34b5  

   Nicolov, André; Gudipati, Murthy S; Bellan, Paul M (April 2024, The Astrophysical Journal)

   Grains of ice are formed spontaneously when water vapor is injected into a weakly ionized laboratory plasma in which the background gas has been cooled to cryogenic temperatures comparable to those of deep space. These ice grains are levitated indefinitely within the plasma so that their time evolution can be observed under free-floating conditions. Using microscope imaging, ice grains are shown to have a spindle-like fractal structure and grow over time. Both crystalline and amorphous phases of ice are observed using Fourier transform infrared spectroscopy. A mix of crystalline and amorphous grains coexists under certain thermal conditions, and a linear mixing model is used on the ice absorption band surrounding 3.2μm to examine the ice phase composition and its temporal stability. The extinction spectrum is also affected by inelastic scattering as grains grow, and characteristic grain radii are obtained from Mie scattering theory and compared to size measurements from direct imaging. Observations are used to compare possible ice nucleation mechanisms, and it is concluded that nucleation is likely catalyzed by ions, as ice does not nucleate in the absence of plasma and impurities are not detected. Ice grain properties and infrared extinction spectra show similarity to observations of some astrophysical ices observed in protoplanetary disks, implying that the fractal morphology of the ice and observed processes of homogeneous ice nucleation could occur as well in such astrophysical environments with weakly ionized conditions. 

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