AI Article Synopsis
- The study explores sulfate radical-based advanced oxidation processes (SR-AOPs), highlighting their low energy requirements and high efficiency for pollutant breakdown, particularly focusing on peroxomonosulfate (PMS) activation.
- A new catalyst, a CoFe PBA/g-CN heterojunction, was created by combining a metal-organic framework with g-CN nanosheets, achieving notable improvements in PMS activation efficiency, outperforming individual components significantly.
- The CoFe PBA/g-CN heterojunction is stable in degrading oxytetracycline and demonstrates a promising mechanism involving multiple factors for effective environmental remediation.
Article Abstract
The utilization of sulfate radical-based advanced oxidation processes (SR-AOPs) has captivated the academic community due to their minimal energy requirements and superior efficacy in peroxomonosulfate (PMS) activation for pollutant decomposition. Notwithstanding these advantages, engineering an effective and economical catalyst for PMS activation presents a considerable hurdle. In the present study, a metal-organic framework of CoFe PBA is ingeniously anchored onto g-CN nanosheets, resulting in the formation of an innovative CoFe PBA/g-CN S-scheme heterojunction that demonstrates remarkable efficiency in PMS activation. Intriguingly, the catalytic efficiency of CoFe PBA/g-CN surpasses that of g-CN and CoFe PBA by 7-fold and 2.33-fold, respectively. The heightened activity of CoFe PBA/g-CN heterojunction is attributed to the enhanced charge transfer efficiency, a consequence of the successful heterojunction formation. Concurrently, the ability of photoexcited electrons to reduce Co/Fe to Co/Fe bolsters PMS activation. Significantly, this heterojunction retains unparalleled stability in degrading oxytetracycline without discernible performance attenuation, heralding its commendable prospects in real-world applications. Besides, mechanism exploration indicates that SO, h, and electron transfer contribute to oxytetracycline degradation in the CoFe PBA/g-CN system. This investigation serves as a beacon for the strategic development of highly active and stable catalysts for PMS activation, aiming at environmental decontamination.
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| http://dx.doi.org/10.1016/j.scitotenv.2024.177326 | DOI Listing |
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