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Boosting CO <sub>2</sub> Fixation into Dimethyl Carbonate via Multiple Active Sites Constituted by V <sub>O‐Ce‐O</sub> Vacancy Clusters on Single‐Unit‐Cell CeO <sub>2</sub> Nano‐Sheets

Xiushuai Guan, Xiaokun Wang, Xiaochao Zhang, Changming Zhang, S. Chuang, Zhong Li

2025Angewandte Chemie International Edition36 citationsDOIOpen Access PDF

Abstract

Abstract The thermodynamic stability and intrinsic kinetic inertia of CO 2 present a critical challenge for its effective activation in the synthesis of high‐value dimethyl carbonate (DMC). In this work, we report the fabrication of novel O‐Ce‐O vacancy clusters (V O‐Ce‐O ) incorporated into CeO 2 nano‐sheets with a near single‐unit‐cell thickness to construct atomically adjacent multiple active sites on their surfaces. These active sites significantly enhance the activation of both CO 2 and CH 3 OH. Impressively, the as‐prepared CeO 2 with V O‐Ce‐O catalyst exhibits an excellent DMC yield of 31.2 mmol g −1 , surpassing previously reported Ce‐based catalysts under equivalent reaction conditions. Experimental results and theoretical calculations reveal that oxygen vacancy increases the reducibility of lattice oxygen, facilitating CO 2 activation, while cerium vacancies weaken the *CH 3 O adsorption, promoting the coupling reaction between *CH 3 O and *CO 2 to form the intermediate (*CH 3 OC(O) 2 ). Notably, the formation of vacancy clusters reduces the energy barrier for the rate‐controlled step (*CH 3 OC(O) 2 dissociation to *CH 3 OCO), thereby boosting the DMC yield. Our new findings provide valuable insights into surface engineering and active site modulation of cerium‐based catalysts, offering a viable pathway for green resource utilization of CO 2 .

Topics & Concepts

Vacancy defectNano-Boosting (machine learning)Materials scienceCarbonateCrystallographyChemistryMetallurgyComposite materialComputer scienceMachine learningCarbon dioxide utilization in catalysisCatalytic Processes in Materials ScienceCO2 Reduction Techniques and Catalysts