Title :
Dual-poly CVD HfO2 gate stack for sub-100 nm CMOS technology
Author :
Lee, S.J. ; Lee, C.-H. ; Kim, Y.H. ; Luan, H.F. ; Bai, W.P. ; Jeon, T.S. ; Kwong, D.L.
Author_Institution :
Dept. of Electr. & Comput. Eng., Texas Univ., Austin, TX, USA
Abstract :
In this paper, the materials and processing challenges for the fabrication of high-quality, ultra-thin (EOT<1 nm) dual-poly high-k gate stack for sub-100 nm CMOS technology are reviewed along with recent results on CVD HfO/sub 2/. The requirement for ultra thin and robust interface layers to avoid any thickness increase due to post-deposition processing to achieve the thinnest possible EOT (equivalent oxide thickness) is discussed. Results are presented on the thermal stability of high-k materials, and interfacial reactions of high-k/Si and high-k/gate electrode interfaces. We also discuss key factors that govern the conduction and degradation mechanisms in high-k gate stacks. Finally, recent work on metal nitrides as possible gate electrode materials is reviewed and the upper thermal budget limit for such materials is discussed.
Keywords :
CMOS integrated circuits; chemical vapour deposition; dielectric thin films; hafnium compounds; integrated circuit interconnections; integrated circuit metallisation; integrated circuit reliability; interface structure; permittivity; surface chemistry; thermal stability; 1 nm; 100 nm; CMOS technology; CVD HfO/sub 2/; EOT; HfO/sub 2/-Si; conduction mechanisms; degradation mechanisms; dual-poly CVD HfO/sub 2/ gate stack; equivalent oxide thickness; high-k gate stack; high-k materials; high-k/Si interfacial reactions; high-k/gate electrode interfacial reactions; interface layer thickness; interfacial reactions; materials processing; metal nitride gate electrode materials; post-deposition processing; robust interface layers; thermal budget limit; thermal stability; ultra thin interface layers; ultra-thin dual-poly high-k gate stack fabrication; CMOS process; CMOS technology; Conducting materials; Electrodes; Fabrication; Hafnium oxide; High K dielectric materials; High-K gate dielectrics; Inorganic materials; Robustness;
Conference_Titel :
Gate Insulator, 2001. IWGI 2001. Extended Abstracts of International Workshop on
Conference_Location :
Tokyo, Japan
Print_ISBN :
4-89114-021-6
DOI :
10.1109/IWGI.2001.967552
