BiOI-Sm2O3 nanocomposites on translucent porous polymer for visible-light decontamination of antibiotic wastewater

Efficient removal of pharmaceutical pollutants from water resources remains a challenge for ensuring eco-sustainability. Herein, we report a unique BiOI-Sm₂O₃ heterojunction nanocomposite (NC) for dissipating persistent pharmaceutical pollutants. The uniqueness of this work arises from the fabrication of a visible-light-responsive reusable/durable photocatalyst by uniformly dispersing BiOI-Sm₂O₃ (BS) NCs across a translucent macro-/meso-porous poly(EDGMA) monolith (PEM). From different ratios of BS NCs, the choice of BS-15, i.e.,(15 %)BiOI-(85 %)Sm₂O₃ showed brilliant visible-light photocatalysis for dissipating enrofloxacin (ENF) drug residues that remain persistent in environmental sources. The uniform dispersion of BS-15 NC across the monolithic template generated a renewable BS-15 PEM photocatalyst with superior surface and structural properties. The surface, structural, and porosity features of the BS NCs and BS-15 PEM photocatalyst were characterized using p-XRD, XPS, FE-SEM-EDX, HR-TEM-SAED, FT-IR, UV-Vis-DRS, PLS, EIS, and BET/BJH analysis. The inorganic-organic hybrid photocatalyst exhibited superior visible-light photocatalytic activity due to optimal energy band gap narrowing and greater surface area and porosity, facilitating faster diffusion and voluminous pollutant sorption for eVentual photocatalytic degradation. The optimization of the experimental parameters revealed a solution pH of 3.0, a photocatalyst dosage of 75 mg, an ENF concentration of 15 mg/L, H₂O₂ (oxidizer) of 1.0 mM, and a tungsten filament lamp of 150 W/cm², which were adequate for the dissipation (≥99.5 %) of ENF within 20 min of photocatalysis. The drug degradation pathways were analyzed using HR-MS, and the photocatalysis mechanisms were elucidated using EPR and VB-XPS analysis. The photocatalyst's excellent stability and photocatalytic efficiency offered a cost-effective solution for wastewater treatment.