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Equivalent circuit modeling of a dual-gate graphene fet

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Version 2 2024-06-05, 10:11
Version 1 2021-01-19, 08:13
journal contribution
posted on 2024-06-05, 10:11 authored by Saima HasanSaima Hasan, Abbas KouzaniAbbas Kouzani, MA Parvez Mahmud
This paper presents a simple and comprehensive model of a dual-gate graphene field effect transistor (FET). The quantum capacitance and surface potential dependence on the top-gate-to-source voltage were studied for monolayer and bilayer graphene channel by using equivalent circuit modeling. Additionally, the closed-form analytical equations for the drain current and drain-to-source voltage dependence on the drain current were investigated. The distribution of drain current with voltages in three regions (triode, unipolar saturation, and ambipolar) was plotted. The modeling results exhibited better output characteristics, transfer function, and transconductance behavior for GFET compared to FETs. The transconductance estimation as a function of gate voltage for different drain-to-source voltages depicted a proportional relationship; however, with the increase of gate voltage this value tended to decline. In the case of transit frequency response, a decrease in channel length resulted in an increase in transit frequency. The threshold voltage dependence on back-gate-source voltage for different dielectrics demonstrated an inverse relationship between the two. The analytical expressions and their implementation through graphical representation for a bilayer graphene channel will be extended to a multilayer channel in the future to improve the device performance.

History

Journal

Electronics (Switzerland)

Volume

10

Article number

ARTN 63

Pagination

1-13

Location

Basel, Switzerland

Open access

  • Yes

eISSN

2079-9292

Language

English

Publication classification

C1 Refereed article in a scholarly journal

Issue

1

Publisher

MDPI