In this work, Fe2O3-hBN composites with different Fe2O3 loadings (0.2–2 wt%) were synthesized via a dry impregnation approach and evaluated as sustainable photocatalysts for water purification. The materials were comprehensively characterized using XRD, SEM, TEM, XPS, FTIR, UV–Vis, PL, and N2 adsorption-desorption analyses to elucidate their structural, optical, and surface properties. Under simulated solar irradiation, the 0.5 wt% Fe2O3-hBN composite showed the most efficient photocatalytic activity among the tested materials. Approximately 80% removal of methylene blue and more than 70% degradation of ibuprofen were achieved within 120 min, highlighting the superior performance of this composition. This improvement was attributed to enhanced visible-light absorption and a reduced band gap (2.7 eV). Radical scavenging experiments identified photogenerated holes (h*) and superoxide radicals (O3 *-) as the main reactive species. The composite exhibited excellent stability and reusability across multiple cycles. These findings highlight Fe2O3-hBN as an efficient and eco-friendly photocatalyst for sustainable water remediation applications.
Development of visible-light-active Fe2O3-hBN photocatalysts for sustainable degradation of emerging pollutants under simulated sunlight conditions / M. Bouziani, A. Bouziani, A. Hsini, C.L. Bianchi, E. Falletta, G. Cerrato, A. Giordana, G. Çelik, R. Hausler. - In: JOURNAL OF HAZARDOUS MATERIALS ADVANCES. - ISSN 2772-4166. - 21:(2026), pp. 101064.1-101064.11. [10.1016/j.hazadv.2026.101064]
Development of visible-light-active Fe2O3-hBN photocatalysts for sustainable degradation of emerging pollutants under simulated sunlight conditions
C.L. Bianchi;E. Falletta;
2026
Abstract
In this work, Fe2O3-hBN composites with different Fe2O3 loadings (0.2–2 wt%) were synthesized via a dry impregnation approach and evaluated as sustainable photocatalysts for water purification. The materials were comprehensively characterized using XRD, SEM, TEM, XPS, FTIR, UV–Vis, PL, and N2 adsorption-desorption analyses to elucidate their structural, optical, and surface properties. Under simulated solar irradiation, the 0.5 wt% Fe2O3-hBN composite showed the most efficient photocatalytic activity among the tested materials. Approximately 80% removal of methylene blue and more than 70% degradation of ibuprofen were achieved within 120 min, highlighting the superior performance of this composition. This improvement was attributed to enhanced visible-light absorption and a reduced band gap (2.7 eV). Radical scavenging experiments identified photogenerated holes (h*) and superoxide radicals (O3 *-) as the main reactive species. The composite exhibited excellent stability and reusability across multiple cycles. These findings highlight Fe2O3-hBN as an efficient and eco-friendly photocatalyst for sustainable water remediation applications.
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