Linear sweep and cyclic voltammetry of porous mixed conducting oxygen electrode: Formal study of insertion, diffusion and chemical reaction model

The classical 1D continuum model of oxygen exchange in a porous mixed conductor (bulk path) is presented in terms of Linear Sweep Voltammetry (LSV) and Cyclic Voltammetry (CV). We show that, from a formal point of view, it corresponds to an insertion, diffusion and chemical reaction mechanism. Some general rules for LSV/CV curves are established. Using a dimensionless description, we evidence eight different limiting behaviors of the electrochemical model, which depend on four dimensionless parameters. For an almost full insertion level at equilibrium, these parameters can be reduced to only two, i.e. the dimensionless electrode thickness L and the dimensionless chemical rate constant lambda. We show that the resulting zone diagram, plotted using the representation log L versus log lambda, is useful to predict the possible sequences of model behaviors as a function of the potential sweep rate and the electrode thickness. This theoretical analysis is applied to a porous LSCF oxygen electrode under air at high temperature.

Automated summary

The paper presents the classical 1D continuum model of oxygen exchange in a porous mixed conductor in terms of Linear Sweep Voltammetry (LSV) and Cyclic Voltammetry (CV), showing an insertion, diffusion, and chemical reaction mechanism. It establishes general rules for LSV/CV curves and evidences eight different limiting behaviors of the electrochemical model. The theoretical analysis is applied to a porous LSCF oxygen electrode under high-temperature air.