An Electrochemical Technique for Measurements of Electrical Conductivity of Aqueous Electrolytes

TL;DR

This paper introduces an electrochemical method to measure the electrical conductivity of aqueous electrolytes by analyzing ohmic potential drops near a disk electrode, providing results comparable to traditional AC impedance techniques.

Contribution

The paper presents a novel electrochemical approach for conductivity measurement that simplifies analysis and aligns well with established methods.

Findings

The technique accurately measures electrolyte conductivity.

Results agree with conventional AC impedance measurements.

The method is effective for various aqueous electrolytes.

Abstract

The technique presented here for the measurement of electrical conductivity is based on the principle that the current converges on a small disk electrode. Most of the ohmic resistance therefore lies within a narrow region surrounding the disk. If the reference electrode is kept outside this zone, the potential difference between the working and the reference electrode includes practically all ohmic potential drops occurring in the solution. Moreover, this ohmic drop can be related to the conductivity of the solution by an analytical expression derived by Newman. At sufficiently high overpotentials, the rate of charge transfer is limited by the conduction of current from the bulk solution to the electrode. In this regime, the current varies linearly with the electrode potential and the conductivity of the solution can be estimated from the slope of the voltammogram using Newman's expression. The electrochemical reaction used for measuring conductivity of solutions of salts is the cathodic reduction of water and that used for aqueous acids is the cathodic reduction of hydrogen ions. The technique has been used to measure conductivity of several common aqueous electrolytes. A good agreement is found between the present technique and the conventional technique based on AC impedance analysis.