Effect of nano-hematite morphology on photocatalytic activity

Nano-hematites, i.e., hematites with nanoparticle-, nanorod-, and nanotube-like morphologies, were synthesized via the hydrothermal method by controlling the reaction time, temperature, and reactant concentration. The nano-hematites of different crystal shapes all exhibited band gaps within the visible-light region (1.56–2.1 eV). Further, they showed weak ferromagnetic behavior, and their coercive magnetic field was larger than that of the bulk hematite. Moreover, all the nano-hematites also exhibited high photocatalytic activities during the degradation of methylene blue under visible-light irradiation. The experimental data fitted the Langmuir–Hinshelwood kinetics model very well. The nanorods had the highest photocatalytic rate constant per unit surface area, possibly owing to a higher aspect ratios; this lowers the electron–hole recombination rate. These results suggest that the crystal morphology of hematites has a significant effect on their physical and photocatalytic properties. Therefore, controlling the morphology of the materials is essential for obtaining well-tailored photocatalysts.