An Accurate and Verilog-A Compatible Compact Model for Graphene Field-Effect Transistors

Author

Landauer, Gerhard Martin ; Jimenez, Daniel ; Gonzalez, J.L.

Author_Institution

Dept. of Electron. Eng., Univ. Politec. de Catalunya, Barcelona, Spain

Volume

13

Issue

5

fYear

2014

fDate

Sept. 2014

Firstpage

895

Lastpage

904

Abstract

The present paper provides an accurate drift-diffusion model of the graphene field-effect transistor (GFET). A precise yet mathematically simple current-voltage relation is derived by focusing on device physics at energy levels close to the Dirac point. With respect to previous work, our approach extends modeling accuracy to the low-voltage biasing regime and improves the prediction of current saturation. These advantages are highlighted by a comparison study of the drain current, transconductance, output conductance, and intrinsic gain. The model has been implemented in Verilog-A and is compatible with conventional circuit simulators. It is provided as a tool for the exploration of GFET-based integrated circuit design. The model shows good agreement with measurement data from GFET prototypes.

Keywords

electrical conductivity; field effect transistors; fullerene devices; graphene; hardware description languages; semiconductor device models; C; Dirac point; GFET-based integrated circuit design; Verilog-A compatible compact model; circuit simulators; current saturation; current-voltage relation; drain current; drift-diffusion model; energy levels; graphene field-effect transistor; intrinsic gain; low-voltage biasing regime; output conductance; transconductance; Electric potential; Graphene; Integrated circuit modeling; Logic gates; Mathematical model; Quantum capacitance; Accuracy; Verilog-A; compact model; field-effect transistor; graphene;

fLanguage

English

Journal_Title

Nanotechnology, IEEE Transactions on

Publisher

ieee

ISSN

1536-125X

Type

jour

DOI

10.1109/TNANO.2014.2328782

Filename

6825842