Perovskite solar cells (PSCs) have advanced rapidly due to their superb photovoltaic (PV) properties along with the excellent charge-transporting materials used for charge separation. Thus, the strategic design of novel materials for charge transport are crucial for PV performance. Previously, we developed ZnO films via a novel low-temperature H₂O oxidation as electron-transporting layer (ETL) for PSCs [1]. However, H₂O oxidation using a conventional hot-plate heating is time consuming. In this study, we integrated microwave technology with H₂O oxidation (M-WO) to accelerate the growth of ZnO. Herein, glass/ITO/Zn thin film samples were immersed in a beaker filled with H₂O and placed inside the microwave oven. The effect of irradiation time was examined by applying a microwave power at 500 W for 0.5-2 h. Fig. 1(a) shows the resulting nanostructures (NSs) after M-WO process. Flat-topped ZnO NRs developed immediately after 30 min. Then after 1 h, the flat-topped NRs evolved to pointed NRs. Increasing the irradiation time to 1.5 h initiated the formation of some NTs, possibly due to the natural selective etching along the (001) plane of ZnO crystal. Finally, all the existing NRs were converted to NTs creating honeycomb-like structures after 2 h. The HRTEM and NBD pattern of a single flat-topped ZnO NR is shown in Fig. 1(b). It can be seen that the NR is highly crystalline with a lattice spacing of about 0.28 nm, corresponding to the (100) spacing of ZnO crystal lattice. In order to evaluate the overall applicability of the ZnO films in practical devices, we examined their ETL capability with perovskite films via steady-state PL analysis (Fig. 1(c)). The perovskite emission is clearly quenched when in contact with the ZnO films, signifying electron transfer. These preliminary results revealed the great potential of our ZnO films as ETL for solar cell applications.