Experimental confirmation of solvated electron concentration and penetration scaling at a plasma–liquid interface

Abstract

In this work, the transport of the plasma injected solvated electron is experimentally studied using total internal reflection absorption spectroscopy (TIRAS). A recently derived a theoretical model predicts power-law scalings between the interfacial concentration n 0 and penetration depth l with plasma current density j, namely n 0 ∝ j e ( 2 3 ) and l ∝ j e ( − 1 3 ) . Here, we extend this model to show that the optical absorption intensity should follow a 1 3 power law behavior with current density, and we perform TIRAS measurements to confirm this behavior. By altering the ionic strength (salt concentration) of our electrolyte solution to control the current density, we find that at higher concentrations a scaling of approximately 1 3 power is observed. However, the scaling is linear at lower concentrations, which we show is due to the transient response of the TIRAS experiment operating in a modulated mode. Ultimately, the experimentally-confirmed scaling law predicts approximate upper limits of penetration depth and interfacial concentration for solvated electrons, findings essential for tailoring plasma-liquid systems for specific applications.

Document Details

Document Type

Pub Defense Publication

Publication Date

Mar 01, 2021

Source ID

10.1088/1361-6595/abe11c

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