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Orbital Hybridization‐Mediated Decoupling of Electrocatalytic Functions for Paired CO <sub>2</sub> Electrosynthesis

Youjia Wang, Bochen Tian, Yuxin Tian, Wenchao Wang, Xin Ma, Yansheng Liu, Junwei Hou

2026Advanced Science13 citationsDOIOpen Access PDF

Abstract

ABSTRACT The intrinsic trade‐offs between activity, selectivity, and stability pose a fundamental challenge in electrocatalyst design. Here, we address these challenges by constructing a dual‐scale catalytic architecture where traditionally competing functions are decoupled and optimized simultaneously. Our approach is guided by the unique orbital hybridization landscape of CeO 2 {110} facets, predicted by density functional theory (DFT) to confer a moderate Ag adsorption energy (−4.11 eV), to construct an electronically coupled interface of atomically dispersed Ag 1 (for CO 2 activation) and metallic Ag n sub‐nanoclusters (for electron transport). The resulting orbitally hybridized interface boosts oxygen vacancy (O V ) density by 1.84‐fold and reduces charge‐transfer resistance by 58%. When deployed in a membrane‐free paired electrolyzer, this catalyst enables direct dialkyl carbonate synthesis from CO 2 , achieving 88.53% Faradaic efficiency (FE) for dimethyl carbonate (DMC) at an industrial current density of 52.5 mA·cm −2 with 20 h stability, a performance competitive with the state‐of‐the‐art. The versatility of this morphology‐governed orbital hybridization strategy is further demonstrated by the selective production of diethyl carbonate (DEC). This work establishes a rational design principle that controls catalytic synergy through crystallographically defined orbital interactions, offering a promising approach to address persistent trade‐offs in electrocatalysis for CO 2 valorization.

Topics & Concepts

ElectrocatalystCatalysisDensity functional theoryDecoupling (probability)ElectrosynthesisFaraday efficiencyMaterials scienceNanotechnologyVacancy defectChemical physicsAdsorptionRational designCarbonateOxygen evolutionElectrochemistryChemical engineeringTransition metalChemistryCurrent densityHOMO/LUMOMetalTopology (electrical circuits)ElectronCO2 Reduction Techniques and CatalystsCarbon dioxide utilization in catalysisElectrocatalysts for Energy Conversion
Orbital Hybridization‐Mediated Decoupling of Electrocatalytic Functions for Paired CO <sub>2</sub> Electrosynthesis | Litcius