Enhanced Fenton Degradation of Tetracycline over Cerium-Doped MIL88-A/g-CN: Catalytic Performance and Mechanism.

Since enormous amounts of antibiotics are consumed daily by millions of patients all over the world, tons of pharmaceutical residuals reach aquatic bodies. Accordingly, our study adopted the Fenton catalytic degradation approach to conquer such detrimental pollutants. (CeFe) MIL-88A was fabricated by the hydrothermal method; then, it was supported on the surface of g-CN sheets using the post-synthetic approach to yield a heterogeneous Fenton-like (CeFe) MIL-88A/10%g-CN catalyst for degrading the tetracycline hydrochloride drug. The physicochemical characteristics of the catalyst were analyzed using FT-IR, SEM-EDX, XRD, BET, SEM, and XPS. The pH level, the HO concentration, the reaction temperature, the catalyst dose, and the initial TC concentration were all examined as influencing factors of TC degradation efficiency. Approximately 92.44% of the TC was degraded within 100 min under optimal conditions: pH = 7, catalyst dosage = 0.01 g, HO concentration = 100 mg/L, temperature = 25 °C, and TC concentration = 50 mg/L. It is noteworthy that the practical outcomes revealed how the Fenton-like process and adsorption work together. The degradation data were well-inspected by first-order and second-order models to define the reaction rate. The synergistic interaction between the (CeFe) MIL-88A/10%g-CN components produces a continuous redox cycle of two active metal species and the electron-rich source of g-CN. The quenching test demonstrates that OH is the primary active species for degrading TC in the HO-(CeFe) MIL-88A/10%g-CN system. The GC-MS spectrum elucidates the yielded intermediates from degrading the TC molecules.