Enregistré dans:
Détails bibliographiques
Auteurs principaux: Yurui Zhang, Guilin Li, Laszlo Sajti, Min Wang, Shaojuan Zeng, Yutong Zhang, Junjie Xu, Jiaqi Feng, Xiangping Zhang
Format: Artículo Open Access
Publié: Wiley 2026
Sujets:
Accès en ligne:https://chemistry-europe.onlinelibrary.wiley.com/doi/10.1002/cssc.70657
Tags: Ajouter un tag
Pas de tags, Soyez le premier à ajouter un tag!
_version_ 1867002328949719040
author Yurui Zhang
Guilin Li
Laszlo Sajti
Min Wang
Shaojuan Zeng
Yutong Zhang
Junjie Xu
Jiaqi Feng
Xiangping Zhang
author_facet Yurui Zhang
Guilin Li
Laszlo Sajti
Min Wang
Shaojuan Zeng
Yutong Zhang
Junjie Xu
Jiaqi Feng
Xiangping Zhang
Yurui Zhang
Guilin Li
Laszlo Sajti
Min Wang
Shaojuan Zeng
Yutong Zhang
Junjie Xu
Jiaqi Feng
Xiangping Zhang
collection Wiley Open Access
contents Tailoring the Electric Field Gradient in Cu‐Based Bimetallic Catalyst to Boost the Product Selectivity for CO 2 Electroreduction Yurui Zhang Guilin Li Laszlo Sajti Min Wang Shaojuan Zeng Yutong Zhang Junjie Xu Jiaqi Feng Xiangping Zhang ChemSusChem The product selectivity of Cu‐based catalysts relates to a great extent to the electron localization at active sites in the electrochemical CO 2 reduction reaction (CO 2 RR). While internal electric field engineering offers a pathway to modulate Cu's electronic structure, the quantitative correlation between field intensity and CO 2 RR performance remains unexplored. This work systematically investigates gradient electric field effects in Cu‐based bimetallic systems, contrasting conventional electron‐withdrawing metals (Ag/Au) with electron‐donating counterparts. Indeed, guided by the theoretical calculations, the cost‐effective In, Fe, and Ni metals, which donate electrons to Cu interface, were integrated into Cu via single‐step co‐reduction. It achieves distinct selectivity at > 100 mA cm −2 with Cu‐In, delivering 87% CO Faradaic efficiency (FE), whereas Cu‐Fe/Ni shifts toward HCOOH (FE ~40%). In situ Raman spectroscopy characterization and density functional theory (DFT) calculations confirm that field‐regulated electron localization governs CO 2 adsorption and conversion pathways. This mechanistic insight establishes internal electric field optimization as a critical strategy for tuning Cu‐based bimetallic catalysts in CO 2 RR. 10.1002/cssc.70657 http://onlinelibrary.wiley.com/termsAndConditions#vor
doi_str_mv 10.1002/cssc.70657
format Artículo Open Access
id wiley_oa_10_1002_cssc_70657
institution Wiley Open Access
license_str_mv http://onlinelibrary.wiley.com/termsAndConditions#vor
publishDate 2026
publisher Wiley
record_format wiley_oa
spellingShingle Tailoring the Electric Field Gradient in Cu‐Based Bimetallic Catalyst to Boost the Product Selectivity for CO 2 Electroreduction
Yurui Zhang
Guilin Li
Laszlo Sajti
Min Wang
Shaojuan Zeng
Yutong Zhang
Junjie Xu
Jiaqi Feng
Xiangping Zhang
ChemSusChem
Tailoring the Electric Field Gradient in Cu‐Based Bimetallic Catalyst to Boost the Product Selectivity for CO 2 Electroreduction Yurui Zhang Guilin Li Laszlo Sajti Min Wang Shaojuan Zeng Yutong Zhang Junjie Xu Jiaqi Feng Xiangping Zhang ChemSusChem The product selectivity of Cu‐based catalysts relates to a great extent to the electron localization at active sites in the electrochemical CO 2 reduction reaction (CO 2 RR). While internal electric field engineering offers a pathway to modulate Cu's electronic structure, the quantitative correlation between field intensity and CO 2 RR performance remains unexplored. This work systematically investigates gradient electric field effects in Cu‐based bimetallic systems, contrasting conventional electron‐withdrawing metals (Ag/Au) with electron‐donating counterparts. Indeed, guided by the theoretical calculations, the cost‐effective In, Fe, and Ni metals, which donate electrons to Cu interface, were integrated into Cu via single‐step co‐reduction. It achieves distinct selectivity at > 100 mA cm −2 with Cu‐In, delivering 87% CO Faradaic efficiency (FE), whereas Cu‐Fe/Ni shifts toward HCOOH (FE ~40%). In situ Raman spectroscopy characterization and density functional theory (DFT) calculations confirm that field‐regulated electron localization governs CO 2 adsorption and conversion pathways. This mechanistic insight establishes internal electric field optimization as a critical strategy for tuning Cu‐based bimetallic catalysts in CO 2 RR. 10.1002/cssc.70657 http://onlinelibrary.wiley.com/termsAndConditions#vor
title Tailoring the Electric Field Gradient in Cu‐Based Bimetallic Catalyst to Boost the Product Selectivity for CO 2 Electroreduction
topic ChemSusChem
url https://chemistry-europe.onlinelibrary.wiley.com/doi/10.1002/cssc.70657