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Nanoengineering Interfacial Reconstruction in Cu2O@SiO2 Catalysts to Tune C-C Coupling and Deep Hydrogenation in CO2 Electroreduction.

Created on 10 Jul 2026

Authors

Wancai Shi, Song Hong, Yuxin Chen, Xueying Li, Xinyi Tan, Baochang Sun, Alex W Robertson, Javier García-Martínez, Zhenyu Sun

Published in

ACS applied materials & interfaces. Jul 09, 2026. Epub Jul 09, 2026.

Abstract

Electrochemical CO2 reduction offers a promising route for converting CO2 into value-added chemicals and fuels; however, switching selectivity between C2+ and CH4 pathways by controlling interfacial reconstruction remains challenging. Herein, we report a simple and effective interface engineering strategy to address this issue. By tuning the thickness of the silica shell on Cu2O catalysts, the reaction pathway can be steered toward either C2+ products or CH4. Two distinct core-shell catalysts, Cu2O@tn-SiO2 (with a thin silica shell) and Cu2O@tk-SiO2 (with a thick silica shell), were synthesized using a wet-chemical method with controlled ammonia addition. For Cu2O@tn-SiO2, the thin SiO2 shell facilitates the formation of a Cu/Cu2O/SiO2 three-phase interface upon pre-reduction, favoring asymmetric coupling of *CO and *CHO intermediates and enabling C2+ production, with a maximum C2+ current density of -675.1 mA cm-2 and a faradaic efficiency (FE) of 80.9%. In contrast, the thick SiO2 shell in Cu2O@tk-SiO2 stabilizes the Cu2O/SiO2 interface, suppresses extensive reconstruction, and modulates the local availability and transfer of hydrogen species through Si-O-H containing interfacial sites, thereby favoring selective hydrogenation of *CHO toward CH4 with a peak partial current density of -464.4 mA cm-2 and an FE of 61.9%. Mechanistic studies support that the silica shell enhances structural stability, regulates intermediate adsorption, and tunes the interfacial hydrogen/water environment, collectively contributing to the observed switch in reaction pathway. This work provides a straightforward and effective strategy for designing copper-based catalysts with tunable product selectivity for practical CO2 electroreduction.

PMID:
42424552
Bibliographic data and abstract were imported from PubMed on 10 Jul 2026.

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