Observation of OH radicals produced by pulsed discharges on the surface of a liquid

Kanazawa, Susumu; Kawano, Hirokazu; Watanabe, Satoshi; Furuki, Takashi; Akamine, Shuichi; Ichiki, Ryuta; Ohkubo, T.; Kočík, M.; Mizeraczyk, J.

doi:10.1088/0963-0252/20/3/034010

Cited by 310 publications

(216 citation statements)

References 31 publications

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“…12,17,19 Underwater streamer discharges at positive polarity also have two propagation modes: a primary streamer and a secondary streamer. [20][21][22][23][24][25][26][27] The primary streamer appears at lower applied voltage with a propagation velocity of 2-3 km/s, having a semi-spherical brush-like structure ($500 lm) composed of many filaments. 22,26 All but a few filaments disappear within 400 ns, resulting in a tree-like structure.…”

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confidence: 99%

“…23,24,26 Above a certain threshold voltage, the secondary streamer propagates with a velocity of greater than 10 km/s, for example, 25 reports, forming a filamentary structure of a few millimeters, dependent on gap distance. [20][21][22][23][24][25]27 In the case of low conductive water, secondary streamer propagation is followed by re-illuminations, which are restarts of the discharge in the formed gas channel, and show a dielectric-barrier discharge (DBD) like behavior with a stepwise propagation. 21,23,24 The secondary streamer and the re-illuminations are characterized by a continuous current with a duration of around 100 ns and subsequent spike currents.…”

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confidence: 99%

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Initiation process and propagation mechanism of positive streamer discharge in water

Fujita

Kanazawa

Ohtani

et al. 2014

Journal of Applied Physics

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The aim of this study was to clarify the initiation process and the propagation mechanism of positive underwater streamers under the application of pulsed voltage with a duration of 10 μs, focusing on two different theories of electrical discharges in liquids: the bubble theory and the direct ionization theory. The initiation process, which is the time lag from the beginning of voltage application to streamer inception, was found to be related to the bubble theory. In this process, Joule heating resulted in the formation of a bubble cluster at the tip of a needle electrode. Streamer inception was observed from the tip of a protrusion on the surface of this bubble cluster, which acted as a virtual sharp electrode to enhance the local electric field to a level greater than 10 MV/cm. Streak imaging of secondary streamer propagation showed that luminescence preceded gas channel generation, suggesting a mechanism of direct ionization in water. Streak imaging of primary streamer propagation revealed intermittent propagation, synchronized with repetitive pulsed currents. Shadowgraph imaging of streamers synchronized with the light emission signal indicated the possibility of direct ionization in water for primary streamer propagation as well as for secondary streamer propagation.

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confidence: 99%

Initiation process and propagation mechanism of positive streamer discharge in water

Fujita

Kanazawa

Ohtani

et al. 2014

Journal of Applied Physics

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“…This mass transport may have occurred due to an electrohydrodynamic flow in liquid and a flow caused by an ionic wind generated above the liquid, which induces convection and diffusion in liquid. 25 In conclusion, we demonstrated the decomposition of salicylic acid to inorganic carbon using non-thermal atmospheric pressure plasma jet. Large amounts of OH radical were generated by plasma irradiation, and the radicals directly decomposed salicylic acid within 10 min.…”

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Application of a Non-thermal Atmospheric Pressure Plasma Jet to the Decomposition of Salicylic Acid to Inorganic Carbon

et al. 2015

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“…Other researchers also show that the rate of OH radical formation varies from 10 −8 to 10 −10 M/s depending on plasma generation conditions. [44][45][46] It was observed that after 6-8 min of DBD operation, the intensity or concentration of 2-hydroxyterephthalic acid is reduced Fig. 4A, whereas the concentration of HTA is supposed to either increase or remain constant; it is to be noted that according to the reaction stoichiometry, the concentration of HTA is equivalent to the concentration of OH radicals.…”

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Roles of individual radicals generated by a submerged dielectric barrier discharge plasma reactor during Escherichia coli O157:H7 inactivation

2015

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A submerged dielectric barrier discharge plasma reactor (underwater DBD) has been used on Escherichia coli O157:H7 (ATCC 35150). Plasma treatment was carried out using clean dry air gas to investigate the individual effects of the radicals produced by underwater DBD on an E. coli O157:H7 suspension (8.0 log CFU/ml). E. coli O157:H7 was reduced by 6.0 log CFU/ml for 2 min of underwater DBD plasma treatment. Optical Emission Spectra (OES) shows that OH and NO (α, β) radicals, generated by underwater DBD along with ozone gas. E. coli O157:H7 were reduced by 2.3 log CFU/ml for 10 min of underwater DBD plasma treatment with the terephthalic acid (TA) OH radical scavenger solution, which is significantly lower (3.7 log CFU/ml) than the result obtained without using the OH radical scavenger. A maximum of 1.5 ppm of ozone gas was produced during the discharge of underwater DBD, and the obtained reduction difference in E.coli O157:H7 in presence and in absence of ozone gas was 1.68 log CFU/ml. The remainder of the 0.62 log CFU/ml reduction might be due to the effect of the NO (α, β) radicals or due to the combined effect of all the radicals produced by underwater DBD. A small amount of hydrogen peroxide was also generated but does not play any role in E. coli O157:H7 inactivation.

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Observation of OH radicals produced by pulsed discharges on the surface of a liquid

Cited by 310 publications

References 31 publications

Initiation process and propagation mechanism of positive streamer discharge in water

Initiation process and propagation mechanism of positive streamer discharge in water

Application of a Non-thermal Atmospheric Pressure Plasma Jet to the Decomposition of Salicylic Acid to Inorganic Carbon

Roles of individual radicals generated by a submerged dielectric barrier discharge plasma reactor during Escherichia coli O157:H7 inactivation

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