DocumentCode
919350
Title
Ultrathin-body strained-Si and SiGe heterostructure-on-insulator MOSFETs
Author
Åberg, Ingvar ; Chléirigh, Cáit Ní ; HOyt, Judy L.
Author_Institution
Microsyst. Technol. Labs., MIT, Cambridge, MA, USA
Volume
53
Issue
5
fYear
2006
fDate
5/1/2006 12:00:00 AM
Firstpage
1021
Lastpage
1029
Abstract
The combination of channel mobility-enhancement techniques such as strain engineering with nonclassical MOS device architectures, such as ultrathin-body (UTB) or double-gate structures, offers the promise of maximizing current drive while maintaining the electrostatic control required for aggressive device scaling in future technology nodes. The tradeoff between transport enhancement and OFF-state leakage current is compared experimentally for UTB MOSFETs in two types of materials: 1) strained Si directly on insulator (SSDOI) and 2) strained Si/strained Si1-zGez (z=0.46-0.55)/strained Si heterostructure-on-insulator (HOI). SSDOI of moderate strain level (e.g. ∼ 0.8%) yields high electron-mobility enhancements for all electron densities, while high strain levels (e.g. ∼ 1.6%) are required to obtain hole-mobility enhancements at high inversion charge densities. HOI is demonstrated to have similar electron-mobility characteristics to SSDOI, while hole mobilities are improved and can be maintained at high inversion charge densities. Hole mobility in strained channels with thickness below 10 nm is studied and compared for SSDOI and HOI. As the channel thickness is reduced, mobility decreases, as in unstrained silicon-on-insulator (SOI), though hole-mobility enhancements are demonstrated into the ultrathin-channel regime. Increased OFF-state leakage currents are observed in HOI compared to SSDOI and SOI. For a 4-nm-thick buried SiGe layer, leakage is reduced relative to devices with thicker SiGe channels.
Keywords
Ge-Si alloys; MOSFET; electron mobility; elemental semiconductors; hole mobility; internal stresses; leakage currents; silicon compounds; silicon-on-insulator; 4 nm; MOS device architectures; SSDOI technology; Si; SiGe; channel mobility-enhancement; double-gate structures; electron-mobility enhancement; electrostatic control; heterostructure on insulator MOSFET; hole-mobility enhancement; strain engineering; ultrathin-body heterostructures; Capacitive sensors; Electrostatics; Germanium silicon alloys; Leakage current; MOS devices; MOSFETs; Maintenance engineering; Silicon germanium; Silicon on insulator technology; Strain control; MOSFETs; Mobility; silicon germanium; silicon-on-insulator (SOI); strain;
fLanguage
English
Journal_Title
Electron Devices, IEEE Transactions on
Publisher
ieee
ISSN
0018-9383
Type
jour
DOI
10.1109/TED.2006.871847
Filename
1624681
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