Authors: Meiling Wang, Zhengju Shi, Wenwen Shi, Jingyun Jiang, Jianhong Lan, Ruizhen Li, Yuanyuan Yan, Zhenyu Liu, Longyi Fu, Xuguang Liu, Shengbo Sang, Yingjie Hu, Jiadong Zhou
Published: 2024-11-29
Source: Full article
AbstractOrdered intermetallic Platinum‐Zinc (PtZn) shows potential in hydrogen evolution reaction (HER), but faces a huge challenge in activity enhancement due to the H‐repulsion properties of Zinc (Zn). Here, local disorder in ordered intermetallic PtZn nanoparticles confined in N‐doped porous carbon (I‐PtZn@NPC) via a confinement‐high‐temperature pyrolysis strategy is realized to boost the HER performance. Experiments and calculations demonstrate that the local substitution of Pt atoms for Zn atoms creates an ultra‐short H‐spillover channel (Pt site→Pt‐Zn bridge site →Zn site). Benefiting from such an ultra‐fast H‐migration from Pt site to Zn site, I‐PtZn@NPC exhibits enhanced intrinsic activity with an ultralow overpotential (η10: 2.3 mV, η100: 24 mV) than commercial Pt black catalyst. Furthermore, a 25 cm2 commercial proton exchange membrane (PEM) electrolyzer equipped with I‐PtZn@NPC achieved stable operation at 1.60 Vcell for 200 h at a current density of 1 A cm⁻2. This design of local Zn disorder in the ordered intermetallic PtZn sheds new light on the rational development of efficient Zn‐based alloy HER electrocatalysts.