Solar-driven, highly sustained splitting of seawater into hydrogen and oxygen fuels

Yun Kuang(Beijing University of Chemical Technology), Michael J. Kenney(Stanford University), Yongtao Meng(Shandong University of Science and Technology), Wei‐Hsuan Hung(Feng Chia University), Yijin Liu(SLAC National Accelerator Laboratory), Jianan Erick Huang(Stanford University), Rohit Prasanna(Stanford University), Pengsong Li(Beijing University of Chemical Technology), Yaping Li(Beijing University of Chemical Technology), Lei Wang(Tianjin University of Technology), Meng‐Chang Lin(Shandong University of Science and Technology), Michael D. McGehee(University of Colorado Boulder), Xiaoming Sun(Beijing University of Chemical Technology), Hongjie Dai(Stanford University)
Proceedings of the National Academy of Sciences
March 18, 2019
10.1073/pnas.1900556116
Cited by 950Open Access
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Abstract

Significance Electrolysis of water to generate hydrogen fuel could be vital to the future renewable energy landscape. Electrodes that can sustain seawater splitting without chloride corrosion could address the issue of freshwater scarcity on Earth. Herein, a hierarchical anode consisting of a nickel–iron hydroxide electrocatalyst layer uniformly coated on a sulfide layer formed on Ni substrate was developed, affording superior catalytic activity and corrosion resistance in seawater electrolysis. In situ-generated polyanion-rich passivating layers formed in the anode are responsible for chloride repelling and high corrosion resistance, leading to new directions for designing and fabricating highly sustained seawater-splitting electrodes and providing an opportunity to use the vast seawater on Earth as an energy carrier.

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