Title :
Explicit Drain Current, Charge and Capacitance Model of Graphene Field-Effect Transistors
Author_Institution :
Dept. d´´Eng. Electron., Univ. Autonoma de Barcelona, Bellaterra, Spain
Abstract :
This paper presents a compact physics-based model of the drain current, charge, and capacitance of graphene field-effect transistors, which is of relevance for the exploration of dc, ac, and transient behavior of graphene-based circuits. The physical framework is a field-effect model and drift-diffusion carrier transport incorporating saturation velocity effects. First, an explicit model has been derived for the drain current. Using it as a basis, explicit closed-form expressions for the charge and capacitances based on the Ward-Dutton partition scheme were derived, covering continuously all the operation regions. The model is of special interest for analog and radio-frequency applications where bandgap engineering of graphene is not needed.
Keywords :
capacitance; field effect transistors; graphene; Ward-Dutton partition scheme; capacitance model; charge model; compact physics-based model; drain current; drift-diffusion carrier transport; field-effect model; graphene field-effect transistor; graphene-based circuit; saturation velocity effect; Analytical models; Capacitance; Charge carrier processes; Integrated circuit modeling; Logic gates; Radio frequency; Transistors; Analog; field-effect transistor (FET); graphene; modeling; radio frequency (RF);
Journal_Title :
Electron Devices, IEEE Transactions on
DOI :
10.1109/TED.2011.2168960
