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Axially Coordinated Gold Nanoclusters Tailoring Fe–N–C Nanozymes for Enhanced Oxidase‐Like Specificity and Activity

Yameng Xie, Fu-li Sun, Kuan Chang, Guang Li, Zhijia Song, Jiayu Huang, Xiqing Cheng, Gui‐Lin Zhuang, Qin Kuang

2024Advanced Science38 citationsDOIOpen Access PDF

Abstract

Abstract Metal–organic frameworks (MOF) derived nitrogen‐doped carbon‐supported monodisperse Fe (Fe–N–C) catalysts are intensively studied, but great challenges remain in understanding the relationship between the coordination structure and the performance of Fe–N–C nanozymes. Herein, a novel nanocluster ligand‐bridging strategy is proposed for constructing Fe‐S 1 N 4 structures with axially coordinated S and Au nanoclusters on ZIF‐8 derived Fe–N–C (labeled Au x /Fe‐S 1 N 4 ‐C). The axial Au nanoclusters facilitate electron transfer to Fe active sites, utilizing the bridging ligand S as a medium, thereby enhancing the oxygen adsorption capacity of composite nanozymes. Compared to Fe‐N‐C, Au x /Fe‐S 1 N 4 ‐C exhibits high oxidase‐like specificity and activity, and holds great potential for detecting acetylcholinesterase activity with a detection limit of 5.1 µU mL −1 , surpassing most reported nanozymes.

Topics & Concepts

NanoclustersCatalysisLigand (biochemistry)ChemistryMetal-organic frameworkDetection limitNanocagesNanotechnologyMaterials scienceChemical engineeringAdsorptionPhysical chemistryOrganic chemistryChromatographyEngineeringReceptorBiochemistryAdvanced Nanomaterials in CatalysisNanocluster Synthesis and ApplicationsElectrochemical sensors and biosensors
Axially Coordinated Gold Nanoclusters Tailoring Fe–N–C Nanozymes for Enhanced Oxidase‐Like Specificity and Activity | Litcius