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Amide Covalent Bonding Engineering in Heterojunction for Efficient Solar-Driven CO<sub>2</sub> Reduction

Weidong Hou, Huazhang Guo, Minghong Wu, Liang Wang

2023ACS Nano123 citationsDOI

Abstract

Inefficient charge separation and slow interfacial reaction dynamics significantly hamper the efficiency of photocatalytic CO 2 reduction. Herein, a facile EDC/NHS-assisted linking strategy was developed to enhance charge separation in heterojunction photocatalysts. Using this approach, we successfully synthesized amide-bonded carbon quantum dot- g -C 3 N 4 (CQD-CN) heterojunction photocatalysts. The formation of amide covalent bonds between CN and CQDs in the CN-CQD facilitates efficient carrier migration, CO 2 adsorption, and activation. Exploiting these advantages, the CN-CQD photocatalysts exhibit high selectivity with CO and CH 4 evolution rates of 79.2 and 2.7 μmol g –1 h –1, respectively. These rates are about 1.7 and 3.6 times higher than those of CN@CQD and bulk CN, respectively. Importantly, the CN-CQD photocatalysts demonstrate exceptional stability, even after 12 h of continuous testing. The presence of the COOH* signal is identified as a crucial intermediate species in the conversion of CO 2 to CO. This study presents a covalent bonding engineering strategy for developing high-performance heterojunction photocatalysts for efficient solar-driven reduction of CO 2 .

Topics & Concepts

HeterojunctionCovalent bondMaterials scienceSelectivityPhotocatalysisChemical engineeringNanotechnologyAmideQuantum dotAdsorptionPhotochemistryCatalysisChemistryOptoelectronicsOrganic chemistryEngineeringAdvanced Photocatalysis TechniquesCovalent Organic Framework ApplicationsCO2 Reduction Techniques and Catalysts