Faradaic and capacitive charging of an electrolyte-filled pore in response to a small applied potential

Abstract

Electrochemical devices often charge both through Faradaic reactions and electric double layer formation. Here, we study these coupled processes in a model system of a long electrolyte-filled pore subject to a small suddenly-applied potential, close to the equilibrium potential eq at which there is no net Faradaic charge transfer. Specifically, we solve the coupled Poisson-Nernst-Planck and Frumkin-Butler-Volmer equations by asymptotic approximations, using the pore's small inverse aspect ratio as the small parameter. In the early-time limit, the reaction-diffusion equations yield an extended Faradaic transmission line model that includes a voltage source, eq, biasing the Faradaic reactions, captured by the resistance RF. In the long-time limit, the model exhibits a nontrivial potential of zero charge, pzc = eq[1 - Z(0)/RF], where Z(0) is the experimentally accessible zero-frequency impedance of the system. This expression provides a new means to experimentally measure the Faradaic contribution to pzc.

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