DocumentCode
1470603
Title
Graphene Nanoribbon Tunneling Field-Effect Transistors With a Semiconducting and a Semimetallic Heterojunction Channel
Author
Da, Haixia ; Lam, Kai-Tak ; Samudra, G. ; Chin, Sai-Kong ; Liang, Gengchiau
Author_Institution
Dept. of Electr. & Comput. Eng., Nat. Univ. of Singapore, Singapore, Singapore
Volume
59
Issue
5
fYear
2012
fDate
5/1/2012 12:00:00 AM
Firstpage
1454
Lastpage
1461
Abstract
We present a computational study of the device performance of graphene nanoribbon tunneling field-effect transistors (TFETs) with a heterogeneous channel. By varying the length and the energy bandgap (EG) of the heterogeneous region, the on- and off-state currents (ION and IOFF) can be effectively optimized independently. Both semiconducting and semimetallic heterogeneous regions are studied to understand the effects of EG engineering on device behaviors. In addition, the effect of gate coverage (GC) over the heterogeneous region is also investigated. We found that device performance is greatly affected by the positioning of the gate to modify the region where band-to-band tunneling occurs. For a given ION/IOFF of eight orders, our results show that, for the semiconducting heterojunction, a higher ION can be obtained by having the gate partially covering the heterogeneous region. This is due to a combination of a short tunneling length and resonant states, which leads to an increase in carrier concentration for the tunneling mechanism. On the other hand, for the semimetallic case, a similar ION/IOFF is only attainable when the heterogeneous region is not covered by the gate. A large IOFF is observed for even small GC due to the valence electrons from the source traveling to the conduction bands of the semimetallic region, enhancing the carrier transport toward the drain. Our study highlights the device design consideration required when optimizing the device performance of heterojunction TFETs.
Keywords
field effect transistors; graphene; nanoribbons; GC effect; band-to-band tunneling; carrier concentration; carrier transport; energy bandgap; gate coverage effect; graphene nanoribbon tunneling field-effect transistors; graphene tunneling field-effect transistors; heterojunction TFET; semiconducting heterogeneous regions; semiconducting heterojunction channel; semimetallic heterogeneous regions; semimetallic heterojunction channel; tunneling mechanism; valence electrons; Chemicals; Current density; Energy states; FETs; Logic gates; Performance evaluation; Tunneling; Graphene; heterojunction; tunneling transistors;
fLanguage
English
Journal_Title
Electron Devices, IEEE Transactions on
Publisher
ieee
ISSN
0018-9383
Type
jour
DOI
10.1109/TED.2012.2186577
Filename
6170552
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