Litcius/Paper detail

Ligand vacancy channels in pillared inorganic-organic hybrids for electrocatalytic organic oxidation with enzyme-like activities

Zhe Chen, Jili Li, Lingshen Meng, Jianan Li, Yaming Hao, Tao Jiang, Xuejing Yang, Yefei Li, Zhi‐Pan Liu, Ming Gong

2023Nature Communications11 citationsDOIOpen Access PDF

Abstract

Abstract Simultaneously achieving abundant and well-defined active sites with high selectivity has been one of the ultimate goals for heterogeneous catalysis. Herein, we construct a class of Ni hydroxychloride-based inorganic-organic hybrid electrocatalysts with the inorganic Ni hydroxychloride chains pillared by the bidentate N-N ligands. The precise evacuation of N-N ligands under ultrahigh-vacuum forms ligand vacancies while partially retaining some ligands as structural pillars. The high density of ligand vacancies forms the active vacancy channel with abundant and highly-accessible undercoordinated Ni sites, exhibiting 5-25 fold and 20-400 fold activity enhancement compared to the hybrid pre-catalyst and standard β-Ni(OH) 2 for the electrochemical oxidation of 25 different organic substrates, respectively. The tunable N-N ligand can also tailor the sizes of the vacancy channels to significantly impact the substrate configuration leading to unprecedented substrate-dependent reactivities on hydroxide/oxide catalysts. This approach bridges heterogenous and homogeneous catalysis for creating efficient and functional catalysis with enzyme-like properties.

Topics & Concepts

CatalysisLigand (biochemistry)Substrate (aquarium)HydroxideElectrochemistryVacancy defectHybrid materialChemistryOxideMetal-organic frameworkDenticityHeterogeneous catalysisRedoxPolyoxometalateCombinatorial chemistrySelectivityElectrocatalystMaterials scienceInorganic chemistryMetalElectrodeCrystallographyOrganic chemistryPhysical chemistryReceptorOceanographyGeologyBiochemistryAdsorptionElectrocatalysts for Energy ConversionElectrochemical sensors and biosensorsAdvanced Nanomaterials in Catalysis