海水
电催化剂
过电位
析氧
电解
分解水
化学工程
无机化学
材料科学
催化作用
化学
电化学
电极
地质学
物理化学
海洋学
电解质
生物化学
工程类
光催化
作者
Muhaiminul Islam,Sambedan Jena,Saleem Sidra,Duy Thanh Tran,Do Hwan Kim,Nam Hoon Kim,Joong Hee Lee
标识
DOI:10.1016/j.cej.2024.150664
摘要
This study reports an electrocatalyst derived from multi-valent Mo4O11 nanosheets coupled Co-Ni (CN) nanowires (NW) (denoted as CN@Mo4O11) with improved catalytic coherency for both high-performance seawater splitting and Zn-seawater battery. The CN@Mo4O11 material significantly enhances the catalytical activity with a low overpotential of 63 mV/69 mV for hydrogen evolution and 100 mV/120 mV for oxygen evolution, respectively, to attain 10 mA cm−2 in alkaline freshwater/seawater. An electrolyzer cell of CN@Mo4O11(+,-) exhibits a low cell voltage of 1.40 V/1.44 V at 10 mA‧cm−2 during alkaline freshwater/seawater splitting with an excellent performance retention of 98.6 %/97.6 % after a long-term operation for 50 h. The solar cell coupled electrolyzer also delivers a high solar to hydrogen conversion efficiency of 15.54 %/16.1 % in alkaline freshwater/seawater. A Zn-seawater battery based on CN@Mo4O11 cathode also delivers high current and power densities of 82 mA‧cm−2 and 27.6 mW‧cm−2, respectively, with a stable discharge time of 40 h. The CN@Mo4O11 heterostructure imparts favorable density of states and optimized adsorption energy for HER and OER, as deduced from DFT calculations, leading to improved overall catalytic performance and corrosion resistance in seawater. Results of this work clearly prove that this proposed catalyst architecture indeed has a huge potential for both seawater splitting and Zn-seawater battery fabrication.
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