Permanganate activation with Mn oxides at different oxidation states: Insight into the surface-promoted electron transfer mechanism

The development of new strategies to improve the removal of organic pollutants with permanganate (KMnO4) is a hot topic in water treatment. While Mn oxides have been extensively used in Advanced Oxidation Processes through an electron transfer mechanism, the field of KMnO4 activation remains relatively unexplored. Interestingly, this study has discovered that Mn oxides with high oxidation states including & gamma;-MnOOH, & alpha;-Mn2O3 and & alpha;-MnO2, exhibited excellent performance to degrade phenols and antibiotics in the presence of KMnO4. The MnO4- species initially formed stable complexes with the surface Mn(III/IV) species and showed an increased oxidation potential and electron transfer reactivity, caused by the electron-withdrawing capacity of the Mn species acting as Lewis acids. Conversely, for MnO and & gamma;-Mn3O4 with Mn(II) species, they reacted with KMnO4 to produce cMnO2 with very low activity for phenol degradation. The direct electron transfer mechanism in & alpha;-MnO2/KMnO4 system was further confirmed through the inhibiting effect of acetonitrile and the galvanic oxidation process. Moreover, the adaptability and reusability of & alpha;-MnO2 in complicated waters indicated its potential for application in water treatment. Overall, the findings shed light on the development of Mn-based catalysts for organic pollutants degradation via KMnO4 activation and understanding of the surface-promoted mechanism.

Automated summary

This study has found that manganese oxides with high oxidation states, including γ-MnOOH, α-Mn2O3, and α-MnO2, exhibited excellent performance in degrading phenols and antibiotics when combined with KMnO4. The MnO4- species formed stable complexes with Mn(III/IV) species on the surface, leading to increased oxidation potential and electron transfer reactivity. In contrast, MnO and γ-Mn3O4 with Mn(II) species reacted with KMnO4 to produce cMnO2 with low activity for phenol degradation. These findings provide insight into the development of Mn-based catalysts for organic pollutant degradation via KMnO4 activation.