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Subsurface engineering for directional-selective CO₂-to-ethanol electrocatalysis at industrial-level

Ming-Zheng Gu, Yuan Min, Ling Jiang, Fu Zhou, Qiao Chen, Xiaojun Zhang, Jie‐Jie Chen, Han‐Qing Yu, Guangfeng Wang

2025Nature Communications5 citationsDOIOpen Access PDF

Abstract

The challenge in precisely controlling the adsorption configuration of oxygen-binding intermediates in the branching path following C–C coupling constrains the directed selectivity of electroreduction CO2-to-ethanol. Here, we present a subsurface Co-doped CuS (Co-Sub-CuS) catalyst, which exhibits directed selectivity toward ethanol. We elucidate the role of subsurface doping in enhancing the oxophilicity of surface Cu sites, thereby facilitating the conversion of key intermediates (*CHCHO*) via the formation of surface-O bonds, guiding subsequent protonation towards ethanol. Moreover, the surface sulfur vacancies created by subsurface Co-doping help regulate the optimal distance between dual sites, facilitating asymmetric C–C coupling. Theoretical calculations combined with in-situ isotopic spectroscopy validate these views, and the branching pathway for converting *CHCO to *CHCHO* is captured. Consequently, in a membrane electrode assembly electrolyzer, the optimized Co-Sub-CuS achieves an ethanol Faradaic efficiency of 78.7% at a partial current density of 550.9 mA cm-2, with stability over 305 h at industrial-level current density of 700 mA cm-2. These findings provide a rational design for the development of directionally selective catalysts for CO2 electroreduction. Precisely controlling the configuration of oxygen-binding intermediates is crucial for selective CO2-to-ethanol electroreduction. Here, the authors present a subsurface Co-doped CuS catalyst, which transforms key intermediates via surface-O bonds to achieve directional selectivity for ethanol.

Topics & Concepts

ElectrocatalystProtonationFaraday efficiencySelectivityAdsorptionMaterials scienceCatalysisBranching (polymer chemistry)ChemistryNanotechnologyChemical physicsElectrodeSurface engineeringSulfurCurrent densityDensity functional theoryCoupling (piping)Reaction intermediateChemical engineeringMembraneSurface modificationRational designDopingDissociation (chemistry)Chemical stabilityCO2 Reduction Techniques and CatalystsAmmonia Synthesis and Nitrogen ReductionElectrocatalysts for Energy Conversion
Subsurface engineering for directional-selective CO₂-to-ethanol electrocatalysis at industrial-level | Litcius