Title :
Tunneling and Short Channel Effects in Ultrascaled InGaAs Double Gate MOSFETs
Author :
Zhengping Jiang ; Behin-Aein, Behtash ; Krivokapic, Zoran ; Povolotskyi, Michael ; Klimeck, Gerhard
Author_Institution :
Network for Comput. Nanotechnol., Purdue Univ., West Lafayette, IN, USA
Abstract :
Full-band quantum transport simulations are performed to study the scaling of InGaAs MOSFETs. Short-channel effects evoke severe performance degradation in InGaAs MOSFETs and the tunneling leakage further deteriorates their performances. Reducing the body width is shown to suppress the short channel effects. Doping densities show big impacts on device performances. With inhomogeneous doping InGaAs could outperform Si at gate lengths below 15 nm with 5-nm body width. The density of state bottleneck does not affect InGaAs in simulated devices at 0.5 V supply voltage. At the ultrascaled dimensions the full band simulations are essential to capture strong nonparabolic dispersion. Comparison with a multivalley effective mass model shows that the population of higher conduction band valleys contributes to the total current at thin body widths.
Keywords :
III-V semiconductors; MOSFET; conduction bands; gallium arsenide; indium compounds; many-valley semiconductors; semiconductor doping; tunnelling; InGaAs; conduction band valley; doping density; full-band quantum transport simulation; gate length; inhomogeneous doping; metal oxide semiconductor field effect transistor; multivalley effective mass model; nonparabolic dispersion; performance degradation; short channel effect; size 5 nm; state bottleneck density; tunneling leakage; ultrascaled double gate MOSFET; voltage 0.5 V; Doping; Effective mass; FinFETs; Indium gallium arsenide; Logic gates; Silicon; Tunneling; III-V material; MOS devices; nonequilibrium Green???s function (NEGF); quantum tunneling; semiconductor device modeling; short channel effects (SCEs);
Journal_Title :
Electron Devices, IEEE Transactions on
DOI :
10.1109/TED.2014.2383392
