Electrostatic doping-based all GNR tunnel FET: An energy-efficient design for power electronics

Electrostatic doping (ED)-based graphene nanoribbon (GNR) tunneling field-effect transistor (TFET) with trigate design is studied. The transfer and output characteristics of the GNR-TFET are explored using extended Hückel semiempirical method. An I_ON/I_OFF ratio as high as 10¹⁴ is obtained with the ON-state current on the order of 10³ μ A/μm. A sub-60 mv/decade subthreshold swing is also observed (35 mv/decade). Armchair GNR with widths of 11 and 9 dimmers is found to be the best geometry to obtain a high I_ON/I_OFF ratio, and channel length of greater than 6.9 nm suppresses short-channel effect. The scaling behavior of the ED-based GNR-TFET is also studied. It is observed that a smaller gate-to-gate distance facilitate large ON-state current and small OFF-state current. Moreover, it is shown that for a high-quality switching performance, the lowest required built-in gate voltage must provide enough energy differential ΔE between the source- A nd drain-side energy bands.