Title :
Quantum transport of Dirac fermions in graphene field effect transistors
Author :
Nguyen, V.Hung ; Bournel, A. ; Chassat, C. ; Dollfus, P.
Author_Institution :
CNRS, Univ. Paris Sud, Orsay, France
Abstract :
We present a quantum transport simulation of graphene field-effect transistors based on the self consistent solution of 2D-Poisson solver and Dirac equation within the non-equilibrium Green´s function formalism. The device operation of double gate 2D-graphene field effect transistors is investigated. The study emphasizes the band-to-band and Klein tunneling processes of massless carriers and the resulting features of the electrostatic modulation of I-V characteristics. A transconductance as high as a few hundreds of μS/μm is observed, despite low on/off current ratios. The model is also extended to massive carriers, which allows us to show the on/off current ratio enhancement due to finite bandgap. The obtained results suggest the feasibility of 2D-graphene devices for analogue applications.
Keywords :
Dirac equation; Green´s function methods; Poisson equation; field effect transistors; graphene; 2D Poisson solver; Dirac fermions; current ratio enhancement; electrostatic modulation; finite bandgap; graphene field effect transistors; nonequilibrium Green function formalism; quantum transport; Current density; Electric potential; Logic gates; Mathematical model; Photonic band gap; Transconductance; Tunneling;
Conference_Titel :
Simulation of Semiconductor Processes and Devices (SISPAD), 2010 International Conference on
Conference_Location :
Bologna
Print_ISBN :
978-1-4244-7701-2
Electronic_ISBN :
1946-1569
DOI :
10.1109/SISPAD.2010.5604585
