Engineering In‐Plane Nickel Phosphide Heterointerfaces with Interfacial sp HP Hybridization for Highly Efficient and Durable Hydrogen Evolution at 2 A cm<sup>−2</sup>
Qian Zhou, Liling Liao, Qihang Bian, Yu Fang, Dongyang Li, Jinsong Zeng, Long Zhang, Hui Wang, Dongsheng Tang, Haiqing Zhou, Zhifeng Ren
Abstract
Abstract The catalytic hydrogen‐evolving activities of transition‐metal phosphides are greatly related to the phosphorus content, but the physical origin of performance enhancement remains ambiguous, and tuning the catalytic activity of nickel phosphides (NiP 2 /Ni 5 P 4 ) remains challenging due to unfavorable H* adsorption. Here, a strategy is introduced to integrate P‐rich NiP 2 and P‐poor Ni 5 P 4 into in‐plane heterostructures by anion substitution, in which P atoms at the in‐plane interfaces perform as active sites to adsorb H* and thus facilitate the hydrogen evolution reaction (HER) process via modulating the electronic structure between NiP 2 and Ni 5 P 4 . Consequently, the NiP 2 /Ni 5 P 4 hybrid exhibits an outstanding hydrogen‐evolving activity, requiring only 30 and 76 mV to afford 10 and 100 mA cm −2 in acid, respectively. It surpasses most of the earth‐abundant electrocatalysts thus far, and is comparable to Pt catalysts (30/72 mV at 10/100 mA cm −2 ). Particularly, it can run smoothly at large current density and only requires 247 mV to reach 2000 mA cm −2 . Detailed theoretical calculations reveal that its exceptional activity stems from the moderate overlap of density states between P 2p and H 1s orbitals, thus optimizing the H*‐adsorption strength. This work highlights a new avenue toward the fabrication of robust non‐noble electrocatalysts by constructing in‐plane heterojunctions.