Hierarchical Core‐Shell N‐Doped Carbon@FeP 4 ‐CoP Arrays as Robust Bifunctional Electrocatalysts for Overall Water Splitting at High Current Density

Exploring non‐precious metal‐based electrocatalysts at high current density and stability is an urgent issue for sustainable H 2 production. Here, hierarchical core‐shell N‐doped carbon encapsulated array‐like FeP 4 and CoP active components have been fabricated in situ on the surface of nickel foam (NC@FeP 4 ‐CoP/NF) by etching sheet‐like ZIF‐67 arrays, Prussian analog formation, and phosphating in turns. The crystallinity, hierarchical heterostructure, and chemical state have been carefully discussed. Electrochemical studies demonstrate that the catalyst displays excellent electrocatalytic activity and durability in electrochemical oxygen evolution reaction (η 20  = 218 mV) and hydrogen evolution reaction (η 10  = 116 mV), better than most previously reported bifunctional catalysts. Moreover, the bifunctional catalyst only needs 1.72 and 1.80 V cell voltages at 500 and 1000 mA cm −2 respectively, together with a good catalytic stability at 500 mA cm −2 for 48 h, implying potential commercialization prospects. This excellent electrocatalytic performance is mainly attributed to the distinctive hierarchical structure as well as core‐shell NC encapsulated FeP 4 ‐CoP active sites, which can enhance the charge transport rate, inhibit the exfoliation of the active materials, provide a larger active surface area, and facilitate electrolyte diffusion and gas release.