2018
DOI: 10.1002/ppap.201700241
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Quantification of plasma produced OH radical density for water sterilization

Abstract: The interactions between plasma-generated excited particles and water play an integral role in sustainable degradation of pharmaceutical compounds, improving aerobic respiration of activated sludge, and efficient removal of microorganisms from water, and are fundamental to the intentional transfer of reactivity from plasmas to biological solutions for such medical applications as cancer treatment and wound healing. The physical and chemical mechanisms that govern this transfer of reactivity are complex, and in… Show more

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Cited by 78 publications
(58 citation statements)
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“…As shown in Figure 6, the optical emissions from the N 2 second positive system (C 3 Π → B 3 Π) at 316, 337, 357, 380, and 405 nm; the N 2 + first negative system (B 2 Σ u + → X 2 Σ g +) at 391.4 nm; and the OH emissions from the transition of A 2 Σ+ → X 2 Π at 309 nm were clearly observed for AALCA [44]. Evaporation of the liquid discussed above could be the source of OH radicals, which could be produced by electron impact dissociation of water molecules [14]. Despite the presence of hydrogen from evaporated water, hydrogen emission lines (e.g., H α and H β ) were not observed in the spectra.…”
Section: Species Generated In Gas Phasementioning
confidence: 94%
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“…As shown in Figure 6, the optical emissions from the N 2 second positive system (C 3 Π → B 3 Π) at 316, 337, 357, 380, and 405 nm; the N 2 + first negative system (B 2 Σ u + → X 2 Σ g +) at 391.4 nm; and the OH emissions from the transition of A 2 Σ+ → X 2 Π at 309 nm were clearly observed for AALCA [44]. Evaporation of the liquid discussed above could be the source of OH radicals, which could be produced by electron impact dissociation of water molecules [14]. Despite the presence of hydrogen from evaporated water, hydrogen emission lines (e.g., H α and H β ) were not observed in the spectra.…”
Section: Species Generated In Gas Phasementioning
confidence: 94%
“…The observed concentrations were two orders of magnitude higher than those of 5 mL DI water treated for 1 min with commercially available NEAPPJ operated with He (0.37 mg/L of H2O2, 0.18 mg/L of NO2 − , and 0.06 mg/L of NO3 − ). Additionally, considerably small concentrations of RONS in water treated using NEAPPJ (up to 890 µg/L of H2O2, up to 180 µg/L of NO2 − , and up to 410 µg/L of NO3 − ) [20][21][22]45,46] and custom plasma jets operated with air or addition of air (up to 9.3 mg/L of H2O2, up to 4 mg/L of NO2 − , and up to 5.5 mg/L of NO3 − ) [14,28,47,48] were reported elsewhere, confirming the high efficiency of the developed AALCA as compared with commonly used nonequilibrium plasma jets.…”
Section: Inactivation Of E Colimentioning
confidence: 99%
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“…Atmospheric pressure gas–liquid discharges have been widely applied in materials processing, water purification, and biomedicine, in great part due to the abundance of reactive chemical species . In these applications, the chemical activity of gas–liquid discharge plasma is crucial, and many efforts have been made to better serve the applications.…”
Section: Introductionmentioning
confidence: 99%