海水
阴极保护
制氢
电极
分解水
阳极
腐蚀
电解
电流密度
氢
电解水
催化作用
材料科学
冶金
化学工程
化学
海洋学
物理
工程类
地质学
电解质
物理化学
有机化学
量子力学
生物化学
光催化
作者
Xian Zhang,Huanyu Zhu,Ziteng Zuo,Mengtian Jin,Ouwen Peng,Qing Lian,Yulan Huang,Peng Chen,Zhong Ai,Shengling Xiang,Abbas Amini,Shaoxian Song,Feifei Jia,Zhiguang Guo,Chun Cheng
标识
DOI:10.1016/j.cej.2024.151705
摘要
The implementation of cheap iron-based catalysts for seawater electrolysis at high- current–density offers an economical and sustainable solution for industrial hydrogen production in near future. However, Fe-based electrodes suffer from poor intrinsic activity and corrosion resistance in seawater, resulting in unsatisfactory seawater splitting performance. Here, we reported the scale-up fabrication of whole-Fe-based electrodes (NiFe-X (X = O, P) NAs/Fe foam) by facile soaking-phosphating. Surface active layers exhibit enhanced corrosion resistance compared to bare Fe foam, and trace Ni modification lowers reaction energy barriers of cathodic NiFeP and in-situ generated anodic NiFeOOH, respectively. Thus, NiFe-P||NiFe-O pair only requires 1.93 V to deliver 3000 mA cm−2 at 6 M KOH, 60 °C for overall seawater splitting, and works stably for 200 h at 1000 mA cm−2. Furthermore, NiFe-X (X = O, P) NAs/Fe foam show impressive adaptation to fresh water/tap water/seawater and all kinds of renewable energies, presenting excellent flexibility for various environmental applications and scenarios.
科研通智能强力驱动
Strongly Powered by AbleSci AI