Download This PaperRecognition-Enrichment-In-Situ Degradation of P-Chlorophenol by Fe-Il@Uio-66
39 Pages Posted: 8 Jan 2025
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Recognition-Enrichment-In-Situ Degradation of P-Chlorophenol by Fe-Il@Uio-66
Recognition-Enrichment-In-Situ Degradation of P-Chlorophenol by Fe-Il@Uio-66
Abstract
Persistent organic pollutants (POPs) represent a significant environmental and health risk due to their high toxicity, persistence, strong accumulation potential, and adverse effects on human health. 4-Chlorophenol(4-CP), a type of POP, has low catalytic efficiency at low concentrations and is easily interfered with by other pollutants, making its degradation challenging.A new “recognition-enrichment-in-situ degradation” strategy is introduced to selectively remove chlorophenols from contaminated aqueous environments. In this study, ionic liquids were incorporated into the UIO-66 framework as active sites for selective adsorption. 4-CP contains phenolic hydroxyl groups and exhibits high polarity. The dispersive interactions between 4-CP and ionic liquids, along with hydrogen-bonding interactions between the Tf2N anion and the hydroxyl groups of 4-CP, enhance the selective enrichment of 4-CP within the nanocavities of the metal-organic frameworks (MOFs). Fe3+ was then introduced, enabling in-situ degradation of 4-CP through photo-induced generation of free radicals and cavities from H2O2 catalyzed by Fe-IL@UIO-66. The results indicated that the adsorption capacity of IL@UIO-66 for 4-CP reached 53%, significantly higher than that for five other organic pollutants. The adsorption capacity of IL@UIO-66 for 4-CP reached 509.5 mg g-1, 49.9% greater than that of the original UIO-66. The degradation efficiency of 4-CP by Fe-IL@UIO-66 increased from 61% to 81%, and after four cycles, the material retained a catalytic activity with a degradation efficiency of 64.2%. This study provides valuable insights into the recognition-enrichment-in-situ catalytic strategy for treating low-concentration, highly toxic wastewater.
Keywords: UIO-66, Enrichment, Selective adsorption, Photocatalysis, Fenton-like reaction, 4-CP
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