Characterization and simulation of sputtering etched profile by focused gallium ion beam on GaN substrate

With the continuous development of manufacturing technology of micro/nano devices based on GaN, focused gallium ion beam has become a momentous method for machining complex GaN structures. Therefore, this study focuses on the characterization and simulation of sputtering etched profile by Ga FIB on GaN substrate. First, the profile characterization experiments are carried out to analyze the influ-ence of ion dose, dwelling time, and scan area, and the results reflect that the sputtering etched regularity on GaN substrate differs from that on Si substrate, especially in redeposition effect, milling rate, and dro-plet phenomenon. In addition, the forming mechanism of droplet phenomenon is discussed, and the milling experiments are conducted to research the droplets avoidance method, which shows that the appearance of droplets is impacted by ion dose and dwelling time. Finally, the sputtering yield of GaN under focused gallium ion beam is measured and sorted, and the simulation program is developed based on continuous cellular automaton (CCA) model. This work can provide a guidance for the further appli-cation of GaN-based materials.

Automated summary

With the development of manufacturing technology of micro/nano devices based on GaN, focused gallium ion beam has become a significant method for machining complex GaN structures. This study focuses on the characterization and simulation of sputtering etched profile by Ga FIB on GaN substrate. The experimental results indicate that the sputtering etched regularity on GaN substrate differs from that on Si substrate, especially in terms of redeposition effect, milling rate, and droplet phenomenon. The forming mechanism of droplet phenomenon is discussed, and the impact of ion dose and dwelling time on droplet appearance is explored. The sputtering yield of GaN under focused gallium ion beam is measured, sorted, and a simulation program based on continuous cellular automaton (CCA) model is developed.