Manufacturable Processes for \leq 32-nm-node CMOS Enhancement by Synchronous Optimization of Strain-Engineered Channel and External Parasitic Resistances

Manufacturable processes to reduce both channel and external resistances (R Ext ) in CMOS devices are described. Simulations show that R Ext will become equivalent to strained Si channel resistance near the 32-nm logic node. Tensile stress in plasma-enhanced chemical-vapor-deposited SiN x liners is...

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Bibliographic Details
Published in:IEEE transactions on electron devices 2008-05, Vol.55 (5), p.1259-1264
Main Authors: Noori, A.M., Balseanu, M., Boelen, P., Cockburn, A., Demuynck, S., Felch, S., Gandikota, S., Gelatos, A.J., Khandelwal, A., Kittl, J.A., Lauwers, A., Wen-Chin Lee, Jianxin Lei, Mandrekar, T., Schreutelkamp, R., Shah, K., Thompson, S.E., Verheyen, P., Ching-Ya Wang, Li-Qun Xia, Arghavani, R.
Format: Article
Language:English
Subjects:
Cu contacts
external resistance
laser anneal
silicide
strain engineering
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Summary:Manufacturable processes to reduce both channel and external resistances (R Ext ) in CMOS devices are described. Simulations show that R Ext will become equivalent to strained Si channel resistance near the 32-nm logic node. Tensile stress in plasma-enhanced chemical-vapor-deposited SiN x liners is increased with UV curing, boosting the NMOS drive current by 20% relative to a neutral reference. W contact-plug resistance (R c ) is reduced by 40% by optimizing preclean, liner/barrier, and nucleation steps. Replacing the fill material with Cu reduces R c by > 35% as compared to W. The Schottky barrier height of silicide contacts to p-Si is reduced by 0.12 eV with a 10% addition of Pt, resulting in a ~10% increase in the PMOS drive current. By implementing a two-step anneal process (spike + laser), the source/drain-extension resistance can be reduced by 20%.
ISSN:0018-9383
1557-9646
DOI:10.1109/TED.2008.919558