Physics-Informed Electrochemical Model of Cathodic Corrosion in Alkaline Media

Abstract

Electrochemical corrosion significantly reduces the durability of electrodes in water electrolyzers, adversely affecting hydrogen (H2) production and cell efficiency. Current theoretical models inadequately assess corrosion behaviors in alkaline water electrolyzers. To address this, we developed a physics-informed electrochemical corrosion model evaluating the corrosion characteristics of cathodes in alkaline systems, accounting for factors such as exchange current density (J0), redox potential (E0), Gibbs free energy of hydrogen adsorption ( G H), electrolyte concentration (C), system pressure (P), and temperature (T). The model calculates metrics including corrosion potential (E corr), corrosion current density (J corr), and corrosion rate (CR). Our findings from potentiodynamic polarization indicate that gold (Au) shows the highest durability, while copper (Cu) and nickel (Ni) are promising cost-effective alternatives. This work enhances the understanding of corrosion dynamics, contributing to the design of more efficient electrolyzer cells for hydrogen production.