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Characterization of a kHz sinusoidal Argon plasma jet impinging on water using Thomson scattering and fast imaging

Elmar Slikboer, James L. Walsh

2021Journal of Physics D Applied Physics17 citationsDOIOpen Access PDF

Abstract

Abstract The electron dynamics in a stable and non-filamentary Argon plasma jet, generated using AC excitation at kHz frequencies and interacting with a liquid surface either at floating potential or electrically grounded were examined using laser Thomson scattering. In the case of a floating liquid, two discharge events were observed during each half-cycle of the applied sinusoidal voltage. In the grounded liquid case only one discharge event was observed, which occurred during the positive half period. Through spatio-temporal imaging of the discharge, its repetitive breakdown behavior was analyzed and divided into pre-, main-, and post-breakdown phases. The dynamics and presence of the various phases differed depending upon the grounding of the liquid. Thomson scattering measurements revealed maximum electron densities and temperatures of 6.0–6.3 × 10 14 cm −3 and 3.1–3.3 eV for the floating liquid case and 1.1 × 10 15 cm −3 and 4.3 eV in the grounded liquid case. Electron-driven reactions are the primary source of reactive chemical species in a plasma jet. Therefore, the electrical characteristics of the liquid sample can impact the fundamental physicochemical processes at play in the discharge, ultimately influencing its chemical composition.

Topics & Concepts

Thomson scatteringPlasmaJet (fluid)ScatteringAtomic physicsArgonElectronExcitationChemistryPlasma cleaningElectron temperatureAnalytical Chemistry (journal)Materials scienceOpticsMechanicsPhysicsNuclear physicsChromatographyQuantum mechanicsPlasma Applications and DiagnosticsElectrohydrodynamics and Fluid DynamicsPlasma Diagnostics and Applications
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