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Bismuth oxyiodide-based composites for advanced visible-light activation of peroxymonosulfate in pharmaceutical mineralization

Laura Huidobro, Anna Domingo, Elvira Gómez, Albert Serrà

2024Chemosphere16 citationsDOIOpen Access PDF

Abstract

The presence of pharmaceutical pollutants in water bodies represents a significant environmental and public health concern, largely due to their inherent persistence and potential to induce antibiotic resistance. Advanced oxidation processes (AOPs) that employ peroxymonosulfate (PMS) activation have emerged as an effective means of degrading these contaminants. Bismuth oxyiodides (BiOI), which are known for their visible-light photocatalytic properties, demonstrate considerable potential for removal of pharmaceutical pollutants. This study examines the synthesis and performance of BiOI-based composites with barium ferrite (BFO) nanoparticles for enhanced PMS activation under visible light. BiOI and Bi 5 O 7 I were synthesized via solvothermal and electrodeposition methods, respectively, and their morphologies and crystalline structures were observed to exhibit distinctive characteristics following annealing. The formation of the composite with BFO resulted in an improvement in the catalytic properties, which in turn enhanced the surface area and availability of active sites. The objective of the photocatalytic studies was to evaluate the degradation and mineralization of tetracycline (TC) under visible light, PMS, and combined conditions. The Bi 5 O 7 I(ED)-BFO catalyst was identified as the optimal candidate, achieving up to 99.8% TC degradation and 99.4% mineralization within 90 minutes at room temperature. The synergistic effect of BFO in BiOI-based composites significantly enhanced performance across all conditions, indicating their potential for efficient remediation of pharmaceutical pollutant. The material's performance was further evaluated in tap water, where the degradation efficiency decreased to 56.4% and mineralization to 38.2%. These results reflect the challenges posed by complex water matrices. However, doubling the PMS concentration to 5 mM led to improved outcomes, with 93.8% degradation and 81.4% mineralization achieved. These findings demonstrate the material's robust potential for treating pharmaceutical pollutants in real-world conditions, advancing sustainable water treatment technologies. • Solvothermal BiOI yield microspheres, while electrodeposition flower-like structures. • BaFe 12 O 19 nanoparticles in BiOI and Bi 5 O 7 I enhanced photocatalytic performance. • Bi 5 O 7 I (ED)-BFO composite showed highest degradation and mineralization efficiency. • Composites are stable and reusable 15 cycles for water pollutant degradation.

Topics & Concepts

Mineralization (soil science)BismuthVisible spectrumChemistryComposite materialMaterials scienceChemical engineeringMetallurgyOrganic chemistryNitrogenOptoelectronicsEngineeringAdvanced Photocatalysis TechniquesAdvanced oxidation water treatmentTiO2 Photocatalysis and Solar Cells