부산대학교 도서관

Graphene is a unique platform to naturally host a high quality 2D electron system. With hBN encapsulation to protect the graphene from the noisy environment, it has a potential to realize ultrahigh performance nanodevices, such as photodiodes and transistors. However, absence of a band gap at Dirac point poses challenges in using the system as a useful transistor. In this study, we investigate the functionality of a hBN-aligned monolayer graphene as a field effect transistor (FET). By precisely aligning the hBN and graphene, the band gaps open at the first Dirac point and at the hole-doped induced Dirac point via an interfacial moire potential. To characterize as a submicron scale FET, we fabricated a global bottom gate to tune the density of a conducting channel and a local top gate to switch-off the channel, demonstrating that this system can be tuned at an optimal on/off ratio regime by controlling the gates separately. These findings will present a useful reference point for further development of the FETs based on graphene heterostructures.