Yang Yifan, Li Xuanyang, Liu Guanglei, Liu Huixiang, Shi Yuehao, Ye Chuming, Fang Zhan, Ye Mingxin, Shen Jianfeng
Institute of Special Materials and Technology, Fudan University, Shanghai, 200433, P. R. China.
Department of Materials Science, Fudan University, Shanghai, 200433, P. R. China.
Adv Mater. 2024 Feb;36(7):e2307979. doi: 10.1002/adma.202307979. Epub 2023 Dec 7.
Hydrazine oxidation reaction coupled with hydrogen evolution reaction (HER) is an effective strategy to achieve low energy water splitting for hydrogen production. In order to realize the application of hydrazine-assisted HER system, researchers have been focusing on the development of electrocatalysts with integrated dual active sites, while the performance under high current density is still unsatisfying. In this work, hierarchical Ohmic contact interface engineering is designed and used as a bridge between the NiMo and Ni P heterojunction toward industrial current density applications, with the charge transfer impedance greatly eliminated via such a pathway with low energy barrier. As a proof-of-concept, the importance of charge redistribution and energy barrier at the Ohmic contact interface is investigated by significantly reducing the voltage of overall hydrazine splitting (OHzS) at high current density. Intriguingly, the NiMo/Ni P hierarchical Ohmic contact heterojunction can drive current densities of 100 and 500 mA cm with only 181 and 343 mV cell voltage in the OHzS electrolyzer with high electrocatalytic stability. The proposed hierarchical Ohmic contact interface engineering paves new avenue for hydrogen production with low energy consumption.
肼氧化反应与析氢反应(HER)耦合是实现低能耗水分解制氢的有效策略。为了实现肼辅助HER系统的应用,研究人员一直致力于开发具有集成双活性位点的电催化剂,然而其在高电流密度下的性能仍不尽人意。在这项工作中,设计了分级欧姆接触界面工程,并将其用作NiMo和NiP异质结之间通向工业电流密度应用的桥梁,通过这种低能垒途径大大消除了电荷转移阻抗。作为概念验证,通过显著降低高电流密度下整体肼分解(OHzS)的电压,研究了欧姆接触界面处电荷重新分布和能垒的重要性。有趣的是,NiMo/NiP分级欧姆接触异质结在OHzS电解槽中具有高电催化稳定性,仅需181和343 mV的电池电压就能驱动100和500 mA cm的电流密度。所提出的分级欧姆接触界面工程为低能耗制氢开辟了新途径。
