DocumentCode :
1153179
Title :
Mechanisms Limiting EOT Scaling and Gate Leakage Currents of High- 
/Metal Gate Stacks Directly on SiGe
Author :
Huang, Jeff ; Kirsch, Paul D. ; Oh, Jungwoo ; Lee, Se Hoon ; Majhi, Prashant ; Harris, H. Rusty ; Gilmer, Daivd C. ; Bersuker, Gennadi ; Heh, Dawei ; Park, Chang Seo ; Park, Chanro ; Tseng, Hsing-Huang ; Jammy, Raj
Author_Institution :
SEMATECH, Austin, TX
Volume :
30
Issue :
3
fYear :
2009
fDate :
3/1/2009 12:00:00 AM
Firstpage :
285
Lastpage :
287
Abstract :
This letter addresses mechanisms responsible for a high gate leakage current (Jg) and a thick interfacial layer in the surface channel SiGe pFET enabling transistor fabrication with sub-1-nm equivalent-oxide-thickness (EOT) high-k /metal gate stack. The primary mechanism limiting EOT scaling is Ge-enhanced Si oxidation resulting in a thick (1.4-nm) SiOx interface layer. A secondary mechanism, i.e., Ge diffusion (ges3%) into high- k, results in high Jg. In the framework of this understanding, we optimized a high-k nitridation process to form as an efficient diffusion barrier, which reduces both O and Ge diffusion resulting in the total gate stack EOT ~ 0.9 nm with J g comparable to that of bulk Si substrate samples. The proposed plasma nitridation process enables fabrication of the sub-1-nm EOT gate-first gate stack with HfSiON dielectric directly on SiGe without Si cap.
Keywords :
Ge-Si alloys; diffusion; field effect transistors; high-k dielectric thin films; leakage currents; nitridation; oxidation; EOT scaling; SiGe; diffusion; diffusion barrier; equivalent-oxide-thickness; high gate leakage current; high-k nitridation process; high-k/metal gate; oxidation; plasma nitridation process; surface channel pFET; thick interfacial layer; transistor fabrication; Equivalent oxide thickness (EOT); HfSiON; SiGe; high- $k$
fLanguage :
English
Journal_Title :
Electron Device Letters, IEEE
Publisher :
ieee
ISSN :
0741-3106
Type :
jour
DOI :
10.1109/LED.2008.2011754
Filename :
4781543
Link To Document :
