In-situ growth of Fe-Co Prussian-blue-analog nanocages on Ni(OH)2/NF and the derivative electrocatalysts with hierarchical cage-on-sheet architectures for efficient water splitting

To design an efficient and cost-effective electrocatalyst based on Prussian blue and its analogs are a promising choice to realize energy transformation and storage via water-splitting. Herein, a facile and practical method is developed to in-situ grow Fe-Co Prussian-blue-analog (PBA) nanocages with an open hole in each face center on Ni(OH)(2)/NF substrate to form the hierarchical cage-on-plate structure. Furthermore, the Fe-Co PBA nanocages attached to Ni(OH)(2)/NF plates are hydrogenated and nitrogenized into FeCoNi/ NF and FeCoNiN/NF electrodes, respectively. As-prepared electrodes successfully retain the 3D hierarchical micro-nano structures of Fe-Co PBA@Ni(OH)(2)/NF precursor and can be used as a bifunctional water-splitting catalyst for overall water splitting. Compared to FeCoNi/NF, FeCoNiN/NF shows more efficiency and durability in the electrolytic water splitting tests in alkaline media. For the FeCoNiN/NF electrocatalyst, ultralow over potentials for hydrogen evolution reaction (HER) are only 56 and 290 mV at current densities of 10 and 500 mA cm(-2). Meanwhile, overpotentials for oxygen evolution reaction (OER) are 267 and 374 mV at current densities of 50 and 500 mA cm(-2). The FeCoNiN/NF electrode can act both the cathode and the anode for overall water splitting, this electrolyzer only requires a cell voltage of 1.492 V to afford a current density of 10 mA cm(-)2(.) This electrolyzer can stably deliver a viable high current density of 625 mA cm(-2) for 40 h to meet the condition of industrial application. (C) 2020 Hydrogen Energy Publications LLC. Published by Elsevier Ltd. All rights reserved.

Automated summary

A facile and practical method was developed to grow Fe-Co Prussian-blue-analog nanocages on Ni(OH)(2)/NF substrate, forming a bifunctional water-splitting catalyst with excellent efficiency and durability. The FeCoNiN/NF electrode showed ultralow overpotentials for hydrogen evolution and oxygen evolution reactions, making it suitable for overall water splitting in industrial applications.