Water scarcity combined with the increasing presence of pharmaceuticals, such as antibiotics, in aquatic systems poses a significant threat to environmental integrity and human and animal health. The increasing demand for efficient and sustainable materials for water treatment has driven research towards photocatalytic technologies. In this work, magnetic TiO₂/Carbon Quantum Dot (CQD) nanocomposites were synthesised and evaluated to assess the influence of synthesis methodology on the final material’s photocatalytic performance. CQDs were synthesised via a hydrothermal method using spent brewery grains (SBGs) as a sustainable carbon precursor. The process involved hydrothermal carbonisation at 200 ºC, with or without prior stirring at 70ºC of the precursors, followed by filtration and purification. Magnetic TiO₂/CQDs nanocomposites were then prepared via co-precipitation of iron salts, either in situ or ex situ, enabling facile recovery of the materials by means of magnetic separation. For the ex situ methodology, TiO₂/CQD nanocomposites were previously prepared through ultrasonication, followed by co-precipitation with iron oxide. In the in situ synthesis, CQDs, TiO₂, and iron salts were added together. Four magnetic TiO₂/CQDs composites were obtained by combining stirring and the synthesis route (in situ or ex situ).

The prepared materials were evaluated for the photocatalytic degradation of 10 mg/L trimethoprim (TMP) and sulfamethoxazole (SMX) in phosphate buffer (0.001 mg/L, pH 8) under simulated solar irradiation. The results show that all nanocomposites enhanced the degradation of both TMP and SMX compared to photolysis. The best-performing photocatalysts removed more than 70% after 1 h of irradiation, compared to less then 20% removal in photolysis. Under the tested conditions (500 mg/L), the ex situ photocatalyst with prior stirring exhibited the highest activity, yet the results were comparable to the in situ photocatalyst without prior stirring, which was selected as the most suitable photocatalyst due to simpler and faster synthesis.