Influence of calcination temperature on photocatalytic H2O2 productivity of hierarchical porous ZnO microspheres

Photocatalytic production of H2O2 from water and atmospheric oxygen has been recognized as a green and sustainable chemical process, due to the abundance of raw materials and sustainable solar energy. Herein, flower-like hierarchical ZnO microspheres were prepared by hydrothermal method followed by calcination at different temperatures, and their photocatalytic performance in H2O2 production was examined under simulated sunlight irradiation. The calcination temperature plays a vital role in the structure, morphology, and surface area of the final ZnO products as well as their optical and electrochemical properties, which are determining factors in their photocatalytic activity. The ZnO calcined at 300 degrees C (Zn-300) exhibits the highest activity and optimal stability, showing productivity of 2793 mu mol l(-1) within 60 min of irradiation, which was 6.5 times higher than that of uncalcined ZnO precursor. The remarkable photocatalytic activity is attributed to enhanced light utilization, large surface area, abundant exposed active sites, improved separation efficiency, and prolonged carrier lifespan. Moreover, the results from cycling experiments indicate the as-prepared ZnO samples exhibit good stability and long-time performance. This work provides useful information for the preparation of hierarchical ZnO photocatalysts.

Automated summary

In this study, flower-like hierarchical ZnO microspheres were prepared by hydrothermal method followed by calcination at different temperatures, and their performance in H2O2 production was examined under simulated sunlight irradiation. The ZnO calcined at 300 degrees C exhibited the highest activity and optimal stability. Additionally, cycling experiments indicated good stability and long-term performance of the prepared ZnO samples.