Liquid-to-Gas transfer of sodium in a liquid cathode glow discharge

Plasma Sources Science and Technology Pub Date : 2024-07-17 DOI:10.1088/1361-6595/ad647b

T. Srivastava, Arthur Dogariu, Anatoli Morozov, P. Bruggeman

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Abstract

Plasma-liquid interactions have been extensively studied with a focus on the transport of reactive species from the plasma to the liquid phase and their induced liquid phase chemistry and resulting applications. While solute transfer from the liquid to the gas phase in plasmas has been widely used in analytical chemistry, the underlying processes remain relatively unexplored. We report spatially and temporally resolved absolute density measurements of sodium in a plasma with a NaCl solution cathode using two-photon absorption laser induced fluorescence (TaLIF). The observed non-linear increase in sodium density with solution conductivity is shown to correlate with droplet generation as visualized by Mie scattering. The findings are explained by droplet generation by electrospray induced by Taylor cone formation as underpinning mechanism for the introduction of sodium in the plasma.An analytical sheath model combined with a scaling law shows an increase in electric field force with solution conductivity that is consistent with the observed non-linear increase in sodium density in the plasma with solution conductivity.

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液态阴极辉光放电中钠的液气传输

人们对等离子体与液体的相互作用进行了广泛的研究，重点是反应物从等离子体到液相的传输及其诱导的液相化学和由此产生的应用。虽然等离子体中从液相到气相的溶质迁移已广泛应用于分析化学，但其基本过程仍相对欠缺。我们报告了利用双光子吸收激光诱导荧光（TaLIF）对带有氯化钠溶液阴极的等离子体中钠的绝对密度进行空间和时间分辨测量的结果。观察到的钠密度随溶液电导率的非线性增加与米氏散射显示的液滴生成相关。结合缩放定律的分析鞘模型显示，电场力随溶液电导率的增加而增加，这与观察到的等离子体中钠密度随溶液电导率的非线性增加相一致。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Plasma Sources Science and Technology

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