DocumentCode
885081
Title
On the FinFET extension implant energy
Author
Gossmann, H.-J.L. ; Agarwal, A. ; Parrill, Tom ; Rubin, L.M. ; Poate, J.M.
Author_Institution
Axcelis Technol., Beverly, MA, USA
Volume
2
Issue
4
fYear
2003
Firstpage
285
Lastpage
290
Abstract
The need of an ultrashallow junction technology for the extension of p-FinFETs has been investigated by integrated process and device simulations. For devices with 60 nm physical gate length, whose extensions are activated in a low thermal-budget process (spike anneal), it is found that the Ioff-Ion performance is invariant with respect to the extension implant energy. Nevertheless, the short-channel behavior worsens. This can be remedied by adding spacers to both sides of the gate before the extension implant, resulting in virtually identical dc characteristics and speed. Devices with gate lengths of 18 nm and below require dopant activation with negligible diffusion. Under those circumstances the short channel behavior of the FinFET is limited by the lateral straggle of the ion implant. Spacers may remedy what is otherwise poor short channel behavior due to a relatively high energy extension implant. However, this comes at the price of drastically worse drive current at a fixed off-current.
Keywords
MOSFET; annealing; diffusion; ion implantation; semiconductor device models; 18 nm; FinFET extension implant energy; device simulations; dopant activation; gate lengths; integrated process; low thermal-budget process; negligible diffusion; short channel behavior; spike anneal; ultrashallow junction technology; Annealing; Conferences; Doping; Energy capture; FinFETs; Implants; Ion implantation; MOSFET circuits; Semiconductor device modeling; Semiconductor devices;
fLanguage
English
Journal_Title
Nanotechnology, IEEE Transactions on
Publisher
ieee
ISSN
1536-125X
Type
jour
DOI
10.1109/TNANO.2003.820783
Filename
1264882
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