Surface structure, morphology and crystal phase-dependent photoactivity of MnO2 nanocatalysts under sunlight

MnO 2 exhibits numerous catalytic applications owing to its wide structural diversity with different chemical and physical properties. Different morphologies of MnO 2 nanomaterial have been prepared to investigate oxidation of methylene blue dye and reduction of nitrobenzene under natural sunlight. MnO 2 nanostructures displayed versatile photoactivity due to different surface and crystal structural morphologies. The prepared materials were characterized by XRD, SEM, EDS, DRS, DLS and fluorescence spectroscopy. The change in absorption maxima from 441 (sea urchin) to 444 nm (nanospheres) is due to change in shape, size and exposure of surface ligand density. Particle size distribution of α-MnO 2 nanorods, sea urchin is 51 and 90–190 nm, respectively, with body-centred tetragonal crystalline structure. The structure of synthesized polymorphs consists of octahedral (MnO 6 ) with different arrangements of edge and phase sharing. From SEM, variation in shapes from sea urchin to nanorods to nanospheres can be seen. MnO 2 -sea urchin (98%) and α-MnO 2 nanorods (91%) give better activity in photo-oxidation of dye relative to MnO 2 nanospheres. The overall photo-oxidation reaction follows pseudo first-order kinetics. Nitrobenzene (25 μmol) is selectively reduced to 80% aniline (20.5 μmol) by α-nanotubes of MnO 2 catalyst and 82.2% with MnO 2 -sea urchin photocatalyst. This paper explored the correlations between shape-dependent chemical and structural factors of surface of a catalyst. The excellent performance of hierarchical MnO 2 represents a potential heterogeneous catalyst for wastewater treatment.