ScienceGate Book Chapters
JOURNAL ARTICLE

Antireconstruction Cu Nanowire Catalysts Enabled bySiO2 Encapsulation for Durable Electrochemical CO2 Reduction

Xiaodong Wen (1594522)Qizhi Min (21927184)Xiaodong Liu (403701)Gang Zhao (161405)Junyao Wang (5229197)Qinshang Xu (11887539)Guoshuai Shi (8406594)Liming Zhang (213971)Wenhua Zhang (317886)Yude Su (2919287)

Year: 2025 Journal:   OPAL (Open@LaTrobe) (La Trobe University)   Publisher: La Trobe University
   Get Full-Text PDF    Get Analytical Report

Abstract

Structural reconstructionan uncontrollable process that compromises the stability of Cu-based catalysts in electrochemical CO2 reduction (CO2R)presents a major scientific challenge that has yet to be overcome. In this work, we develop a well-controlled SiO2 encapsulation approach to stabilize Cu-based CO2R electrocatalysts against reconstruction. Using Cu nanowires (CuNWs) as a model platform, we demonstrate that SiO2 encapsulation can significantly suppress Cu reconstruction while retaining ∼95% of the initial CO2R performance over 24-h stability tests at −1.15 V vs reversible hydrogen electrode (VRHE). In contrast, unencapsulated CuNWs exhibit severe structural deterioration with attenuated CO2R activity under identical testing conditions. In situ Raman studies and density functional theory (DFT) calculations reveal that the antireconstruction effect results from the formation of a robust Cu–O–Si interface that can not only serve as a structural anchor but also contribute to strengthening the Cu–Cu bonding at the exposed Cu active sites during CO2R operation. These results decipher the stabilizing mechanism of SiO2 encapsulation, and provide key insights for designing durable Cu-based CO2R electrocatalysts toward practical applications.

Keywords:
Nanowire Encapsulation (networking) Electrochemistry Catalysis Electrode Raman spectroscopy Structural stability

Metrics

0
Cited By
0.00
FWCI (Field Weighted Citation Impact)
0
Refs
0.48
Citation Normalized Percentile
Is in top 1%
Is in top 10%

Topics

CO2 Reduction Techniques and Catalysts
Physical Sciences →  Energy →  Renewable Energy, Sustainability and the Environment
Catalysts for Methane Reforming
Physical Sciences →  Chemical Engineering →  Catalysis
Electrocatalysts for Energy Conversion
Physical Sciences →  Energy →  Renewable Energy, Sustainability and the Environment

Related Documents

JOURNAL ARTICLE

Antireconstruction Cu Nanowire Catalysts Enabled by SiO2 Encapsulation for Durable Electrochemical CO2 Reduction

Xiaodong WenMin QiuXiaodong LiuGang ZhaoJ. S. WangQinshang XuGuoshuai ShiLiming ZhangWenhua ZhangYude Su

Journal:   ACS Catalysis Year: 2025 Vol: 15 (16)Pages: 14215-14226
JOURNAL ARTICLE

Electrochemical Reduction of CO2 using Supported Cu2O Catalysts

Joel BugayongG. L. Griffin

Journal:   MRS Proceedings Year: 2013 Vol: 1542
JOURNAL ARTICLE

Carbon-based catalysts for electrochemical CO2 reduction

Chen JiaKamran DastafkanWenhao RenWanfeng YangChuan Zhao

Journal:   Sustainable Energy & Fuels Year: 2019 Vol: 3 (11)Pages: 2890-2906
JOURNAL ARTICLE

Metal Cluster Catalysts for Electrochemical CO2 Reduction

Khac Huy DinhLeta Takele MenisaHugh WarkentinTu N. NguyenCao‐Thang Dinh

Journal:   ACS Catalysis Year: 2025 Vol: 15 (7)Pages: 5731-5759
JOURNAL ARTICLE

Pd-Monolayer Catalysts for CO2 Electrochemical Reduction

Zhixiu LiangMiomir B. VukmirovicRadoslav R. Adžić

Journal:   ECS Meeting Abstracts Year: 2017 Vol: MA2017-01 (31)Pages: 1459-1459
© 2026 ScienceGate Book Chapters — All rights reserved.