Physics of electronic transport in low-dimensionality materials for future FETs

Author

Fischetti, M.V. ; Vandenberghe, W.G. ; Fu, Binglei ; Narayanan, Shrikanth ; Kim, Jung-Ho ; Ong, Z.-Y. ; Suarez-Negreira, A. ; Sachs, C. ; Aboud, S.J.

Author_Institution

Dept. of Mater. Sci. & Eng., Univ. of Texas at Dallas, Richardson, TX, USA

fYear

2014

fDate

9-11 Sept. 2014

Firstpage

1

Lastpage

4

Abstract

We show that scaling rules, quantum confinement in thin bodies, and the resulting gate leakage render imperative the use of low-dimensionality materials as channels in devices scaled beyond the 10 nm gate length. We then consider a few examples of two-dimensional materials of great interest, graphene and bilayer graphene, and show how the dielectric environment (gate and interlayer insulators, nearby gates) has a dramatically strong effect on the electronic properties of systems such as supported graphene, nanoribbons, and graphene bilayers in which a Bose-Einstein exciton condensation has been predicted to occur at high temperature. Finally, we consider the novel concept of devices based on monolayer tin (`stannanane´) as a topological insulator.

Keywords

Bose-Einstein condensation; electron transport theory; excitons; field effect transistors; graphene; Bose-Einstein exciton condensation; FET; bilayer graphene; electronic properties; electronic transport; graphene bilayers; interlayer insulators; low-dimensionality materials; nanoribbons; size 10 nm; two-dimensional materials; Dielectrics; Electron mobility; Graphene; Insulators; Logic gates; Materials; Scattering;

fLanguage

English

Publisher

ieee

Conference_Titel

Simulation of Semiconductor Processes and Devices (SISPAD), 2014 International Conference on

Conference_Location

Yokohama

ISSN

1946-1569

Print_ISBN

978-1-4799-5287-8

Type

conf

DOI

10.1109/SISPAD.2014.6931548

Filename

6931548