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Enhanced Photo-Fenton Catalytic Performance toward Acid Orange II by FeOCl/CdS Quantum Dot Composites: Density Functional Theory Calculations and Mechanistic Insights

Dongao Xie, Changxin Tang, Dan Li, Jiren Yuan, Feigao Xu

2024The Journal of Physical Chemistry C28 citationsDOI

Abstract

FeOCl has attracted much attention for its good photo-Fenton properties. However, there are still some limitations to the removal efficiency of organic pollutants. Visible-light-responsive FeOCl/CdS quantum dot composites were prepared by calcination to overcome their flaws, and their catalytic activity was explored by the degradation of acid orange II (AO-II). The experimental results showed that the FeOCl/CdS composites exhibited better catalytic performance than pure components. The F 1 Cd 0.5 composite (mass ratio of FeOCl to CdS is 1:0.5) achieved 98.5% removal efficiency of AO-II, which is 14.8 times higher than that of FeOCl+CdS under similar experimental conditions; moreover, the F 1 Cd 0.5 composite still exhibits a high stability after five cycles. According to the characterization and experimental results with density functional theory calculations together, it is proposed that the type II carrier transfer-separation mechanism plays a leading role in enhancing the photodegradation performance of the photo-Fenton catalysts. This study provides a new idea to further improve the catalytic efficiency of the photo-Fenton technology for organic pollutant degradation.

Topics & Concepts

PhotodegradationCatalysisComposite numberCalcinationDensity functional theoryDegradation (telecommunications)Methyl orangeMaterials scienceCatalytic efficiencyQuantum dotChemical engineeringQuantum efficiencyPhotocatalysisChemistryPhotochemistryComposite materialNanotechnologyOptoelectronicsComputational chemistryOrganic chemistryComputer scienceEngineeringTelecommunicationsAdvanced Photocatalysis TechniquesTiO2 Photocatalysis and Solar CellsAdvanced oxidation water treatment