Multi‐Stage Porous Nickel–Iron Oxide Electrode for High Current Alkaline Water Electrolysis

Abstract Alkaline water electrolysis (AWE) is the promising technical pathway of large‐scale green hydrogen production. The sluggish oxygen evolution reaction seriously hampers the water decomposition reaction kinetics for AWE, especially at high current density above 500 mA cm −2 . It is closely related with bubbles removal dynamic performance of porous electrodes. In this study, the multi‐stage porous nickel–iron oxide electrode is prepared by a two‐step electro‐deposition method. The electrode shows good oxygen evolution reaction performance at high current densitiy of 1000 mA cm −2 , which is attributed to both the good electro‐catalytic performance of NiFeO x with nano‐cone structure and good bubbles removal performance of porous Ni interlayer with the curved pore channels. Bubbles motion inside the pore channels is deeply analyzed by Lattice Boltzmann simulation of gas–liquid two‐phase flows, combining with the experiments. The results indicate that bubbles motion speed is faster in curved pore channels than that in straight pore channels due to the role of bubble buoyancy. It illuminates the effects of pore channel curvature on bubbles motion for porous electrodes prepared by electro‐deposition. It provides the possibility of designing porous electrodes with both good electro‐catalytic performance and good bubbles removal performance by the electro‐deposition method, from the view of industrial applications.