Title :
Modeling of carrier density and quantum capacitance in graphene nanoribbon FETs
Author :
Kliros, George S.
Author_Institution :
Dept. of Aeronaut. Sci., Hellenic Air-Force Acad., Dekeleia AFB, Greece
Abstract :
Gate voltage control of carrier density and quantum capacitance is an important step for understanding the device physics and assessing the performance of nanoscale transistors. In this paper, we present a simple phenomenological model for the carrier density and quantum capacitance of graphene nanoribbon field-effect transistors as functions of gate voltage, Fermi level position and temperature. Quantum capacitance is calculated from the broadened density of states incorporating the presence of electron-hole puddles and possible finite lifetime of electronic states through a Gaussian broadening distribution. Thin gate-insulators of high-κ dielectric constant are used in our calculations in order to approach the quantum capacitance limit.
Keywords :
carrier density; field effect transistors; Fermi level position; Gaussian broadening distribution; carrier density; electron-hole puddles; electronic state; finite lifetime; gate voltage control; graphene nanoribbon FET; graphene nanoribbon field-effect transistor; nanoscale transistor; quantum capacitance limit; thin gate-insulator; Insulators; Logic gates; Photonic band gap; Quantum capacitance; Temperature; Transistors;
Conference_Titel :
Microelectronics (ICM), 2010 International Conference on
Conference_Location :
Cairo
Print_ISBN :
978-1-61284-149-6
DOI :
10.1109/ICM.2010.5696126
