Reduced graphene oxide supported polyaniline/copper (II) oxide nanostructures for enhanced photocatalytic degradation of Congo red and hydrogen production from water

Industries release numerous toxic and carcinogenic organic compounds into natural water reservoirs which poses worldwide threat to both aquatic life and human beings. In this study, ternary nanocomposites comprising CuO nanoparticles, reduced graphene oxide (rGO), and polyaniline (Pani) were prepared by hydrothermal methodology. The Pani@rGO/CuO composites demonstrated a significant degradation efficiency up to 91.67 % for Congo red dye (CR) under optimized conditions of dosage and concentration. Notably, the reaction rate constant (k) of Pani@rGO/CuO for CR dye was 3.27 times greater than that of pure CuO. Additionally, the hydrogen production capability of Pani@rGO/CuO was evaluated, and it exhibited the highest performance of 16.7 mmol h−1 g−1. The integration of rGO and Pani with CuO enhanced CR dye degradation and hydrogen production by providing additional adsorption sites. Furthermore, the hybridization of CuO with rGO and Pani increased the functionality and binding sites for interaction with CR dye thereby resulting in improved adsorption efficiency. The concentration of CR and the catalyst dosage also influenced the degradation process. Hence, the response surface methodology was utilized to create 13 sets of randomized experiments by altering the catalyst dosage and degradation time to predict the degradation of CR dye. [Display omitted] •Polyaniline, rGO and CuO for enhanced congo red degradation and hydrogen production.•Proposed degradation mechanism based on theory & optimal experiments.•Structural, optical, chemical analysis for photocatalytic degradation mechanism.