Superior oxidation processes (AOPs) play a pivotal function in purifying water contaminants and securing ingesting water security. Transition metal-based supplies are extremely efficient AOP catalysts, whereas their purposes are restricted by their poor stability within the oxidative setting. On this research, we developed the composite catalyst, molybdenum disulfide/ferric oxide (MoS2/Fe3O4), to guage the catalytic efficiency and discover the underlying mechanisms in peroxymonosulfate activation. The powder composite was efficiently loaded onto an engineered wooden substrate, making a monolith wooden@MoS2/Fe3O4 composite for large-scale sensible purposes. The engineered bulk catalyst displays distinctive versatility and stability in wastewater remedy, sustaining practically 100% elimination effectivity over a steady operation of 144 hours. These findings underscore the numerous potential of wood-loaded nanomaterials for cost-effective wastewater remedy.
