Litcius/Paper detail

Asymmetric Coordination Induces Electron Localization at Ca Sites for Robust CO<sub>2</sub> Electroreduction to CO

Qiyou Wang, Minyang Dai, Hongmei Li, Ying‐Rui Lu, Ting‐Shan Chan, Chao Ma, Kang Liu, Junwei Fu, Wanru Liao, Shanyong Chen, Evangelina Pensa, Ye Wang, Shiguo Zhang, Yifei Sun, Emiliano Cortés, Min Liu

2023Advanced Materials138 citationsDOIOpen Access PDF

Abstract

Abstract Main group single atom catalysts (SACs) are promising for CO 2 electroreduction to CO by virtue of their ability in preventing the hydrogen evolution reaction and CO poisoning. Unfortunately, their delocalized orbitals reduce the CO 2 activation to *COOH. Herein, an O doping strategy to localize electrons on p‐orbitals through asymmetric coordination of Ca SAC sites (Ca‐N 3 O) is developed, thus enhancing the CO 2 activation. Theoretical calculations indicate that asymmetric coordination of Ca‐N 3 O improves electron‐localization around Ca sites and thus promotes *COOH formation. X‐ray absorption fine spectroscopy shows the obtained Ca‐N 3 O features: one O and three N coordinated atoms with one Ca as a reactive site. In situ attenuated total reflection infrared spectroscopy proves that Ca‐N 3 O promotes *COOH formation. As a result, the Ca‐N 3 O catalyst exhibits a state‐of‐the‐art turnover frequency of ≈15 000 per hour in an H‐cell and a large current density of −400 mA cm −2 with a CO Faradaic efficiency (FE) ≥ 90% in a flow cell. Moreover, Ca‐N 3 O sites retain a FE above 90% even with a 30% diluted CO 2 concentration.

Topics & Concepts

Delocalized electronCatalysisAtomic orbitalMaterials scienceSpectroscopyCoordination numberInfrared spectroscopyOxidation stateCrystallographyCoordination sphereAtom (system on chip)PhotochemistryElectronMetalChemistryIonPhysicsBiochemistryMetallurgyOrganic chemistryEmbedded systemComputer scienceQuantum mechanicsCO2 Reduction Techniques and CatalystsIonic liquids properties and applicationsElectrocatalysts for Energy Conversion