静电纺丝
氧化剂
矿化(土壤科学)
浸出(土壤学)
化学
催化作用
化学工程
可见光谱
纳米纤维
比表面积
纳米技术
异质结
光催化
材料科学
吸水率
多孔性
复合数
吸收(声学)
纳米颗粒
四环素
作者
Laura Huidobro,Miquel Allés,Mahmoud Abid,Mikhael Bechelany,Carmen Sousa,E GOMEZ,Albert Serrà
标识
DOI:10.1016/j.cej.2026.174316
摘要
Engineered photocatalysts capable of operating under visible light and realistic water matrices are needed to address emerging pharmaceutical contaminants. Here, we fabricate SnO 2 /BiOI fibrous heterostructures by electrospinning SnO 2 nanofibers decorated with solvothermally synthesized BiOI followed by calcination. The electrospun fibers provide a mechanically robust, high-surface-area scaffold, while BiOI incorporation enhances visible-light absorption and creates SnO 2 /BiOI heterointerfaces. Textural, optical, and spectroscopic analyses reveal progressive surface decoration, increased surface area, and defect-rich Bi environments as BiOI loading increases. Using tetracycline (TC) as a model contaminant at neutral pH, SnO 2 /BiOI composites markedly outperform pristine SnO 2 under visible light and/or peroxymonosulfate (PMS), with an optimal BiOI content (SBO2) under single-stimulus conditions and near-complete TC mineralization for the highest loading (SBO3) in the PMS + visible-light system. Radical scavenging indicates that SO 4 ●- and ● OH are the dominant reactive species, with O 2 ●- , h + and e − playing secondary roles. A multipollutant mixture (TC, sulfamethoxazole, levofloxacin, lansoprazole) is mineralized by >80% in both Milli-Q and tap water, and SBO3 retains high activity over nine cycles with Bi and I leaching below 0.05% after 48 h. Density functional theory calculations, combined with XPS, support an S-scheme SnO 2 /BiOI heterojunction, enabling spatial separation of strongly reducing electrons in BiOI and oxidizing holes in SnO 2 . Although high PMS loadings can partially mask intrinsic catalyst differences, these results outline a practical design platform for heterogeneous (slurry), visible-responsive, PMS-assisted photocatalysts for pharmaceutical-laden effluents. • Electrospun SnO 2 /BiOI fibers enable robust visible-light/PMS-driven photocatalysis • S-scheme SnO 2 |BiOI heterojunction enhances charge separation and redox power • Near-complete tetracycline mineralization achieved under visible light + PMS • Multipollutant mixtures mineralized (>80%) in Milli-Q and real tap water • Fibrous catalysts show high stability with <0.05% Bi/I leaching over 48 h
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