In this work, a modified, lumped element graphene field effect device model
is presented. The model is based on the "Top-of-the-barrier" approach which is
usually valid only for ballistic graphene nanotransistors. Proper modifications
are introduced to extend the model's validity so that it accurately describes
both ballistic and diffusive graphene devices. The model is compared to data
already presented in the literature. It is shown that a good agreement is
obtained for both nano-sized and large area graphene based channels. Accurate
prediction of drain current and transconductance for both cases is obtained

Canali

Castro Neto

Chen

D. Mencarelli

Datta

Dorgan

F. Coccetti

Fang

Fiori

G. Deligeorgis

G. Vincenzi

Jiménez

Khakifirooz

L. Pierantoni

Liang

M. Dragoman

McClure

Mencarelli

Meric

Mucciolo

Novoselov

Ouyang

R. Plana

Rahman

Reich

Ryzhii

Slonczewski

Thiele

Wallace

Wang

Yang

English

arXiv

International audienceIn this work, a modified, lumped element graphene field effect device model is presented. The model is based on the ''Top-of-the-barrier'' approach which is usually valid only for ballistic graphene nanotransistors. Proper modifications are introduced to extend the model's validity so that it accurately describes both ballistic and diffusive graphene devices. The model is compared to data already presented in the literature. It is shown that a good agreement is obtained for both nano-sized and large area graphene based channels. Accurate prediction of drain current and transconductance for both cases is obtained

Vincenzi, Giancarlo

Deligeorgis, Georgios

Coccetti, Fabio

Dragoman, M.

Pierantoni, Luca

Mencarelli, Davide

Plana, Robert

HAL-INSA Toulouse

Extending ballistic graphene FET lumped element models to diffusive devices

Crossref

Solid-State Electronics

HAL: Hyper Article en Ligne

Scientific Publications of the University of Toulouse II Le Mirail

In this work, a modified, lumped element graphene field effect device model is presented. The model is based on the “Top-of-the-barrier” approach which is usually valid only for ballistic graphene nanotransistors. Proper modifications are introduced to extend the model’s validity so that it accurately describes both ballistic and diffusive graphene devices. The model is compared to data already presented in the literature. It is shown that a good agreement is obtained for both nano-sized and large area graphene based channels. Accurate prediction of drain current and transconductance for both cases is obtaine

Vincenzi G.

Deligeorgis G.

Coccetti F.

Dragoman M.

Plana R.

PIERANTONI, Luca

MENCARELLI, Davide

IRIS UniversitÃ  Politecnica delle Marche

https://hal.science/hal-00718929v1/file/Extending_ballistic_graphene_FET_lumped_element_models_to_diffusive_devices_Author.pdf

Extending ballistic graphene FET lumped element models to diffusive
  devices

Extending ballistic graphene FET lumped element models to diffusive devices

Abstract

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HAL-INSA Toulouse

Crossref

HAL: Hyper Article en Ligne

Scientific Publications of the University of Toulouse II Le Mirail

IRIS UniversitÃ Politecnica delle Marche