Improving hydrogen production activity of bifunctional CuCoFe-layered double hydroxides for electrocatalytic water splitting: Effects of valence state evolution and oxygen vacancies

•CuCoFe LDHs exhibit excellent electrocatalytic performance for both HER and OER.•Appropriate control of Cu/Co ratios can achieve optimized electrocatalytic activity.•Distortion of structural units caused by Cu2+ ions promotes formation of oxygen vacancies.•Oxygen vacancies enhance oxidation of Co2+...

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Published in:Fuel (Guildford) 2024-04, Vol.361, p.130711, Article 130711
Main Authors: Cheng, Shu-Yan, Wang, Tao, Kou, Jia-Wei, Cheng, Fang-Qin, Song, Hui-Ping, Zhao, Hua-Zhang
Format: Article
Language:English
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Layered double hydroxide
Oxygen vacancy
Valence state evolution
Water splitting
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container_title Fuel (Guildford)
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Wang, Tao
Kou, Jia-Wei
Cheng, Fang-Qin
Song, Hui-Ping
Zhao, Hua-Zhang
description •CuCoFe LDHs exhibit excellent electrocatalytic performance for both HER and OER.•Appropriate control of Cu/Co ratios can achieve optimized electrocatalytic activity.•Distortion of structural units caused by Cu2+ ions promotes formation of oxygen vacancies.•Oxygen vacancies enhance oxidation of Co2+ active sites. The development of noble metal-free electrocatalysts is crucial for efficient water splitting via both hydrogen (HER) and oxygen evolution reaction (OER) in alkaline electrolyte. In this study, bifunctional CuCoFe layered double hydroxides grown in-situ on Ni foam (NF) have been prepared to achieve high-efficient water splitting. The CuCoFe LDHs need a low overpotential of 49 mV for HER and 255 mV for OER to deliver a current density of 10 mA·cm−2, which is superior to many reported LDH-based electrocatalysts. On the one hand, the Cu2+ ions induce distortions of structure units, which promotes the formation of oxygen vacancies and facilitates electron migration as well as charge transfer. On the other hand, excessive addition of Cu2+ ions can lead to a reduction in active sites due to the acceleration of Co2+ oxidation during preparation. This work presents an opportunity to regulate the structure of LDH-based electrocatalysts by the new approach of Cu-doping, resulting in enhanced control over valence state evolution and oxygen vacancies.
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The development of noble metal-free electrocatalysts is crucial for efficient water splitting via both hydrogen (HER) and oxygen evolution reaction (OER) in alkaline electrolyte. In this study, bifunctional CuCoFe layered double hydroxides grown in-situ on Ni foam (NF) have been prepared to achieve high-efficient water splitting. The CuCoFe LDHs need a low overpotential of 49 mV for HER and 255 mV for OER to deliver a current density of 10 mA·cm−2, which is superior to many reported LDH-based electrocatalysts. On the one hand, the Cu2+ ions induce distortions of structure units, which promotes the formation of oxygen vacancies and facilitates electron migration as well as charge transfer. On the other hand, excessive addition of Cu2+ ions can lead to a reduction in active sites due to the acceleration of Co2+ oxidation during preparation. 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subjects Layered double hydroxide
Oxygen vacancy
Valence state evolution
Water splitting
title Improving hydrogen production activity of bifunctional CuCoFe-layered double hydroxides for electrocatalytic water splitting: Effects of valence state evolution and oxygen vacancies
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