Remote Iron dynamics of NiFe (oxy)hydroxides toward robust active sites in water oxidation

Jianxiong Zhao; Yuwei Zhang; Yike Ye; Qiucheng Xu; Songzhu Luo; Fanxu Meng; Siyuan Zhu; Xiaoning Li; Xinlong Lin; Anke Yu; Xiao Ren; Tianze Wu; Zhichuan J. Xu

doi:10.1038/s41467-025-60728-y

Remote Iron dynamics of NiFe (oxy)hydroxides toward robust active sites in water oxidation

Jianxiong Zhao, Yuwei Zhang, Yike Ye, Qiucheng Xu, Songzhu Luo, Fanxu Meng, Siyuan Zhu, Xiaoning Li, Xinlong Lin, Anke Yu, Xiao Ren, Tianze Wu^*, Zhichuan J. Xu^*

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

2 Citations (Scopus)

Abstract

Ni(Fe) (oxy)hydroxides have long been recognized as benchmark electrocatalysts for water oxidation in alkaline media. Maximizing their activity and longevity will be vital for facilitating scalable water electrolysis. However, progress is hindered by insufficient understandings of surface Fe dynamics and by the absence of effective regulatory approach. Here we show the surface Fe dynamics beyond the immediate vicinity of Ni(Fe) oxyhydroxides on working electrode but being remotely influenced by Fe diffusion and deposition on the counter electrode. While Fe could be highly active in reversible dynamics, disruptions in this process can result in significant activity decay due to the loss or deactivation of surface Fe species. On-site regulation of Fe dynamics is inspired by pre-catalysts. [Ni_0.75Fe_0.25]_0.6Zn_0.4Cl_x derives Ni(Fe) oxyhydroxide with enhanced performance due to Zn leaching and cation defects that improve Fe site accommodation. Theoretical studies suggest that Fe dissolution occurs when cation defects are lacking but shifts to Fe capture as defects increase, underscoring on-site defect manipulation to maintain the abundance of active Fe sites.

Original language	English
Article number	5601
Journal	Nature Communications
Volume	16
Issue number	1
DOIs	https://doi.org/10.1038/s41467-025-60728-y
Publication status	Published - Dec 2025
Externally published	Yes

Bibliographical note

Publisher Copyright:
© The Author(s) 2025.

ASJC Scopus Subject Areas

General Chemistry
General Biochemistry,Genetics and Molecular Biology
General
General Physics and Astronomy

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title = "Remote Iron dynamics of NiFe (oxy)hydroxides toward robust active sites in water oxidation",

abstract = "Ni(Fe) (oxy)hydroxides have long been recognized as benchmark electrocatalysts for water oxidation in alkaline media. Maximizing their activity and longevity will be vital for facilitating scalable water electrolysis. However, progress is hindered by insufficient understandings of surface Fe dynamics and by the absence of effective regulatory approach. Here we show the surface Fe dynamics beyond the immediate vicinity of Ni(Fe) oxyhydroxides on working electrode but being remotely influenced by Fe diffusion and deposition on the counter electrode. While Fe could be highly active in reversible dynamics, disruptions in this process can result in significant activity decay due to the loss or deactivation of surface Fe species. On-site regulation of Fe dynamics is inspired by pre-catalysts. [Ni0.75Fe0.25]0.6Zn0.4Clx derives Ni(Fe) oxyhydroxide with enhanced performance due to Zn leaching and cation defects that improve Fe site accommodation. Theoretical studies suggest that Fe dissolution occurs when cation defects are lacking but shifts to Fe capture as defects increase, underscoring on-site defect manipulation to maintain the abundance of active Fe sites.",

author = "Jianxiong Zhao and Yuwei Zhang and Yike Ye and Qiucheng Xu and Songzhu Luo and Fanxu Meng and Siyuan Zhu and Xiaoning Li and Xinlong Lin and Anke Yu and Xiao Ren and Tianze Wu and Xu, \{Zhichuan J.\}",

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doi = "10.1038/s41467-025-60728-y",

language = "English",

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T1 - Remote Iron dynamics of NiFe (oxy)hydroxides toward robust active sites in water oxidation

AU - Zhao, Jianxiong

AU - Zhang, Yuwei

AU - Ye, Yike

AU - Xu, Qiucheng

AU - Luo, Songzhu

AU - Meng, Fanxu

AU - Zhu, Siyuan

AU - Li, Xiaoning

AU - Lin, Xinlong

AU - Yu, Anke

AU - Ren, Xiao

AU - Wu, Tianze

AU - Xu, Zhichuan J.

PY - 2025/12

Y1 - 2025/12

N2 - Ni(Fe) (oxy)hydroxides have long been recognized as benchmark electrocatalysts for water oxidation in alkaline media. Maximizing their activity and longevity will be vital for facilitating scalable water electrolysis. However, progress is hindered by insufficient understandings of surface Fe dynamics and by the absence of effective regulatory approach. Here we show the surface Fe dynamics beyond the immediate vicinity of Ni(Fe) oxyhydroxides on working electrode but being remotely influenced by Fe diffusion and deposition on the counter electrode. While Fe could be highly active in reversible dynamics, disruptions in this process can result in significant activity decay due to the loss or deactivation of surface Fe species. On-site regulation of Fe dynamics is inspired by pre-catalysts. [Ni0.75Fe0.25]0.6Zn0.4Clx derives Ni(Fe) oxyhydroxide with enhanced performance due to Zn leaching and cation defects that improve Fe site accommodation. Theoretical studies suggest that Fe dissolution occurs when cation defects are lacking but shifts to Fe capture as defects increase, underscoring on-site defect manipulation to maintain the abundance of active Fe sites.

AB - Ni(Fe) (oxy)hydroxides have long been recognized as benchmark electrocatalysts for water oxidation in alkaline media. Maximizing their activity and longevity will be vital for facilitating scalable water electrolysis. However, progress is hindered by insufficient understandings of surface Fe dynamics and by the absence of effective regulatory approach. Here we show the surface Fe dynamics beyond the immediate vicinity of Ni(Fe) oxyhydroxides on working electrode but being remotely influenced by Fe diffusion and deposition on the counter electrode. While Fe could be highly active in reversible dynamics, disruptions in this process can result in significant activity decay due to the loss or deactivation of surface Fe species. On-site regulation of Fe dynamics is inspired by pre-catalysts. [Ni0.75Fe0.25]0.6Zn0.4Clx derives Ni(Fe) oxyhydroxide with enhanced performance due to Zn leaching and cation defects that improve Fe site accommodation. Theoretical studies suggest that Fe dissolution occurs when cation defects are lacking but shifts to Fe capture as defects increase, underscoring on-site defect manipulation to maintain the abundance of active Fe sites.

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Remote Iron dynamics of NiFe (oxy)hydroxides toward robust active sites in water oxidation

Abstract

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