DocumentCode
1044502
Title
Study of single- and dual-channel designs for high-performance strained-Si-SiGe n-MOSFETs
Author
Olsen, Sarah H. ; O´Neill, Anthony G. ; Chattopadhyay, Sanatan ; Driscoll, Luke S. ; Kwa, K.S.K. ; Norris, D.J. ; Cullis, A.G. ; Paul, Douglas J.
Author_Institution
Sch. of Electr., Univ. of Newcastle, UK
Volume
51
Issue
8
fYear
2004
Firstpage
1245
Lastpage
1253
Abstract
Results comparing strained-Si-SiGe n-channel MOSFET performance of single-and dual-surface channel devices fabricated using 15% Ge content SiGe virtual substrates are presented. Device fabrication used high thermal budget processes and virtual substrates were not polished. Mobility enhancement factors exceeding 1.6 are demonstrated for both single-and dual-channel device architectures compared with bulk-Si control devices. Single-channel devices exhibit improved gate oxide quality, and larger mobility enhancements, at higher vertical effective fields compared with the dual-channel strain-compensated devices. The compromised performance enhancements of the dual-channel devices are attributed to greater interface roughness and increased Ge diffusion resulting from the Si0.7Ge0.3 buried channel layer.
Keywords
MOSFET; semiconductor device manufacture; silicon compounds; substrates; Ge diffusion; Si-SiGe; Si0.7Ge0.3 buried channel layer; SiGe virtual substrates; bulk-Si control devices; device architectures; device fabrication; dual-channel device; gate oxide interface; gate oxide quality; high thermal budget process; high-performance n-MOSFET; interface roughness; mobility enhancement factors; single-channel device; strain-compensated device; strained-Si-SiGe n-MOSFET; strained-silicon; Capacitive sensors; Effective mass; Electron mobility; Epitaxial growth; Germanium alloys; Germanium silicon alloys; MOSFET circuits; Silicon germanium; Substrates; Tensile strain; Dual-channel; gate oxide interface; interface roughness; mobility enhancement; n-MOSFETs; silicon–germanium; single-channel; strained-silicon; thermal budget; virtual substrate;
fLanguage
English
Journal_Title
Electron Devices, IEEE Transactions on
Publisher
ieee
ISSN
0018-9383
Type
jour
DOI
10.1109/TED.2004.830652
Filename
1317145
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