Title :
Scalability of strained-Si nMOSFETs down to 25 nm gate length
Author :
Goo, Jung-Suk ; Xiang, Qi ; Takamura, Yayoi ; Wang, Haihong ; Pan, James ; Arasnia, Farzad ; Paton, Eric N. ; Besser, Paul ; Sidorov, Maxim V. ; Adem, Ercan ; Lochtefeld, Anthony ; Braithwaite, Glyn ; Currie, Matthew T. ; Hammond, Richard ; Bulsara, Mayan
Author_Institution :
Technol. Dev. Group, Adv. Micro Devices Inc., Sunnyvale, CA, USA
fDate :
5/1/2003 12:00:00 AM
Abstract :
Strained-Si nMOSFETs with a standard polysilicon gate process were fabricated down to 25 nm gate length with well-behaved characteristics and small difference in short channel effects. The performance enhancement degrades linearly as the gate length becomes shorter, due to not only the parasitic resistance but also heavy halo implant. Thus the key integration issues are how to manage threshold difference and As diffusion without excess doping. With comparable doping and well controlled parasitic resistance, up to 45% improvement in drive current is predicted for sub-50 nm gate length strained-Si nMOSFETs on the Si/sub 0.8/Ge/sub 0.2/ substrate. In this work approximately 45% enhancement is in fact demonstrated for 35 nm gate length devices, through advanced channel engineering and implementation of metal gates.
Keywords :
MOSFET; diffusion; elemental semiconductors; ion implantation; silicon; 25 to 50 nm; As diffusion; Si/sub 0.8/Ge/sub 0.2/; Si/sub 0.8/Ge/sub 0.2/ substrate; Si:As; channel doping; channel engineering; device scalability; drive current; gate length; halo implantation; metal gate; parasitic resistance; polysilicon gate; short channel effect; strained Si n-MOSFET; threshold voltage; Current measurement; Degradation; Doping; Electron mobility; Implants; MOSFETs; Scalability; Strain control; Strain measurement; Threshold voltage;
Journal_Title :
Electron Device Letters, IEEE
DOI :
10.1109/LED.2003.812563
