DocumentCode
51834
Title
Simulation Study of Thin-Body Ballistic n-MOSFETs Involving Transport in Mixed 
-L Valleys
Author
Mehrotra, Saumitra ; Povolotskyi, Michael ; Elias, D.C. ; Kubis, Tillmann ; Law, Jeremy J. M. ; Rodwell, Mark J. W. ; Klimeck, Gerhard
Author_Institution
Network for Comput. Nanotechnol. & Birck Nanotechnol. Center, Purdue Univ., West Lafayette, IN, USA
Volume
34
Issue
9
fYear
2013
fDate
Sept. 2013
Firstpage
1196
Lastpage
1198
Abstract
Transistor designs based on using mixed Γ-L valleys for electron transport are proposed to overcome the density of states bottleneck while maintaining high injection velocities. Using a self-consistent top-of-the-barrier transport model, improved current density over Si is demonstrated in GaAs/AlAsSb, GaSb/AlAsSb, and Ge-on-insulator-based single-gate thin-body n-channel metal-oxide-semiconductor field-effect transistors. All the proposed designs successively begin to outperform strained-Si-on-insulator and InAs-on-insulator (InAs-OI) in terms of ON-state currents as the effective oxide thickness is reduced below 0.7 nm. InAs-OI still exhibits the lowest intrinsic delay (τ) due to its single Γ valley.
Keywords
MOSFET; ballistic transport; electron transport theory; silicon-on-insulator; electron transport; metal-oxide-semiconductor field-effect transistors; mixed Γ-L valleys; simulation; single-gate thin-body n-channel MOSFET; thin-body ballistic n-MOSFET; transistor designs; Capacitance; Gallium arsenide; Indium phosphide; Logic gates; MOSFET; Silicon; GaAs; GaSb; Ge; InAs; L-valley; Si; tight-binding (TB); ultrathin body (UTB);
fLanguage
English
Journal_Title
Electron Device Letters, IEEE
Publisher
ieee
ISSN
0741-3106
Type
jour
DOI
10.1109/LED.2013.2273072
Filename
6565346
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