Engineering Multilevel Collaborative Catalytic Interfaces with Multifunctional Iron Sites Enabling High-Performance Real Seawater Splitting

Zhang, Fangming; Liu, Yilin; Fang, Yu; Pang, Hongjing; Zhou, Xuan; Li, Dongyang; Ma, Wenqi; Zhou, Qian; Mo, Yuxue; Zhou, Haiqing

doi:10.1021/acsnano.2c11844

articleACS NanoJan 3, 2023Closed access

Engineering Multilevel Collaborative Catalytic Interfaces with Multifunctional Iron Sites Enabling High-Performance Real Seawater Splitting

FZFangming Zhang YLYilin Liu YFYu Fang HPHongjing Pang XZXuan Zhou

Hunan Normal University · University of South China · +1 more institution

PubMed

Indexed incrossrefpubmed

Abstract

Given the abundant reserves of seawater and the scarcity of freshwater, real seawater electrolysis is a more economically appealing technology for hydrogen production relative to orthodox freshwater electrolysis. However, this technology is greatly precluded by the undesirable chlorine oxidation reaction and severe chloride corrosion at the anode, further restricting the catalytic efficiency of overall seawater splitting. Herein, a feasible strategy by engineering multifunctional collaborative catalytic interfaces is reported to develop porous metal nitride/phosphide heterostructure arrays anchoring on conductive Ni2P surfaces with affluent iron sites. Collaborative catalytic interfaces among iron phosphide,…

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193

total citations

FWCI: 11.61
Percentile: 100%
References: 53

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Authors

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Topics & keywords

Topics

Keywords

Water splitting
Bifunctional
Seawater
Electrolysis
Materials science
Catalysis
Oxygen evolution
Phosphide

UN Sustainable Development Goals

Life below water

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