Photocatalytic innovations in environmental remediation: mechanisms, materials, and challenges for persistent organic pollutant removal.

POPs (POPs), including pesticides, pharmaceuticals, and industrial chemicals, pose severe environmental and health risks due to their persistence, bioaccumulation, and toxicity. While conventional methods like adsorption and biological treatment are widely used, their inefficiency in mineralizing POPs and generating secondary waste has driven interest in AOPs, particularly photocatalysis. This review examines recent advancements in photocatalytic materials and mechanisms for POP degradation, focusing on semiconductors such as TiO₂, doped catalysts, and visible-light-active composites. Laboratory studies demonstrate that nanostructured TiO₂ doped with Fe3⁺ achieves 95% degradation of diclofenac under Vis, while field-scale applications, such as solar photocatalytic units in Spain, reduce endocrine disruptors by 80%. However, challenges Like rapid charge recombination, Limited solar utilization, and high costs hinder scalability. Recent innovations, including plasmonic photocatalysts and hybrid systems integrating membrane filtration, enhance efficiency and stability. For instance, PMRs achieve 70% higher degradation rates than standalone systems. Although photocatalysis shows promise for complete mineralization, its real-world efficacy depends on optimizing Light absorption, reactor design, and economic feasibility. Future research must address these barriers through interdisciplinary approaches, such as AI-driven catalyst design and circular economy integration. While lab-scale efficiencies are high, real matrices often impose 30-50% performance penalties and raise cost. Photocatalysis is most competitive when by-product toxicity is a concern and when solar or hybrid PMR designs are feasible. Clear mechanism-to-reactor rules are outlined to guide scale-up. This review uniquely integrates mechanistic insights, conventional treatment limitations, and field-scale evidence to establish clear mechanism-to-reactor design rules for photocatalysis. By critically benchmarking against established techniques and emphasizing by-product toxicity, we bridge laboratory innovation and practical deployment, guiding scalable, sustainable environmental remediation strategies for Persistent Organic Pollutants POPs.