Stress memorization in high-performance FDSOI devices with ultra-thin silicon channels and 25nm gate lengths

D.V. Singh,Jeffrey W. Sleight,John M. Hergenrother,Z. Ren,Keith A. Jenkins,Omer H. Dokumaci,Linda Black,Josephine B. Chang,H. Nakayama,Dureseti Chidambarrao,R. Venigalla,James Pan,Wesley C. Natzle,B.L. Tessier,A. Nomura,J. A. Ott,Meikei Ieong,Wilfried Haensch

Stress memorization in high-performance FDSOI devices with ultra-thin silicon channels and 25nm gate lengths

2005

D.V. Singh
Jeffrey W. Sleight
John M. Hergenrother
Z. Ren
Keith A. Jenkins
Omer H. Dokumaci
Linda Black
Josephine B. Chang
H. Nakayama
Dureseti Chidambarrao
R. Venigalla
James Pan
Wesley C. Natzle
B.L. Tessier
A. Nomura
J. A. Ott
Meikei Ieong
Wilfried Haensch

We report for the first time, the effect of stress memorization (SM), and the combined effects of SM and dual stress liner (DSL) on high performance fully-depleted ultra-thin channel devices with a raised source/drain architecture and channel thickness of 18nm. SM results in significant drive current and mobility enhancement, comparable to that obtained using the DSL approach. Stress transfer to the channel during SM likely occurs through the poly-gate, becoming more effective as the body is thinned. Combining SM and DSL results in a net gain that is substantially larger than that obtained using each technique separately

Keywords:

Optoelectronics
Electron mobility
Memorization
Silicon on insulator
Physics
Architecture
Electronic engineering
Net gain
Digital subscriber line
Communication channel
Silicon
stress effects

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