A 90-nm logic technology featuring strained-silicon

Thompson, Scott E.; Armstrong, M; Auth, C.; Alavi, M.; Buehler, Markus J.; Chau, R.; Cea, S.; Ghani, T.; Glass, G.; Hoffman, T.; Jan, C.-H.; Kenyon, C.; Klaus, J. W.; Kuhn, Kelin J.; Ma, Zhiyong; McIntyre, B.; Mistry, K.; Murthy, A.; Obradovic, B.; Nagisetty, Ramune; Nguyen, Phi Anh; Sivakumar, S.; Shaheed, R.; Shifren, L.; Tufts, Bruce J.; Tyagi, S.; Bohr, M.; El-Mansy, Y.A.

doi:10.1109/ted.2004.836648

articleIEEE Transactions on Electron DevicesOct 26, 2004Closed access

A 90-nm logic technology featuring strained-silicon

SEScott E. Thompson MAM Armstrong CAC. Auth MAM. Alavi MJMarkus J. Buehler

Intel (United States)

Indexed incrossref

Abstract

A leading-edge 90-nm technology with 1.2-nm physical gate oxide, 45-nm gate length, strained silicon, NiSi, seven layers of Cu interconnects, and low-/spl kappa/ CDO for high-performance dense logic is presented. Strained silicon is used to increase saturated n-type and p-type metal-oxide-semiconductor field-effect transistors (MOSFETs) drive currents by 10% and 25%, respectively. Using selective epitaxial Si/sub 1-x/Ge/sub x/ in the source and drain regions, longitudinal uniaxial compressive stress is introduced into the p-type MOSEFT to increase hole mobility by >50%. A tensile silicon nitride-capping layer is used to introduce tensile strain into the n-type MOSFET and enhance electron mobility by 20%.…

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665

total citations

FWCI: 36.95
Percentile: 100%
References: 52

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Authors

28

Topics & keywords

Topics

Keywords

Materials science
PMOS logic
MOSFET
Strained silicon
Silicon
Optoelectronics
Strain engineering
Electron mobility

UN Sustainable Development Goals

Affordable and clean energy

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