Title :
Robust ternary metal gate electrodes for dual gate CMOS devices
Author :
Dae-Gyu Park ; Tae-Ho Cha ; Kwan-Yong Lim ; Heung-Jae Cho ; Tae-Kyun Kim ; Se-Aug Jang ; You-Seok Suh ; Veena Misra ; In-Seok Yeo ; Jae-Sung Roh ; Jin Won Park ; Hee-Koo Yoon
Author_Institution :
Adv. Process Team, Hynix Semicond. Inc., Kyoungki, South Korea
Abstract :
This report describes thermally stable dual metal gate electrodes for surface channel Si CMOS devices. We found that the ternary metal nitrides, i.e., Ti/sub 1-x/Al/sub x/N/sub y/ (TiAlN) and TaSi/sub x/N/sub y/ (TaSiN) films, are stable up to 1000/spl deg/C. Especially, the stoichiometric TiAlN (y/spl sim/1) exhibited highly robust p-type gate electrode (p-TiAlN) properties, demonstrating a work function (/spl Phi//sub m/) of /spl sim/5.1 eV and excellent gate oxide integrity against the thermal budget of conventional Si CMOS processing. The N-deficient TiAlN (y < 1) showed /spl Phi//sub m/ for n-type electrode (n-TiAlN) with limited thermal stability. The dual gate electrodes, p-TiAlN and TaSiN, exhibited negligible EOT (equivalent oxide thickness) variation on the high-k gate dielectrics (ZrO/sub 2/, HfO/sub 2/) up to 950/spl deg/C.
Keywords :
CMOS integrated circuits; MOS capacitors; aluminium compounds; electrodes; semiconductor device metallisation; semiconductor device reliability; tantalum compounds; thermal stability; titanium compounds; work function; 1000 C; 5.1 eV; 950 C; CMOS capacitors; MOS capacitors; TaSi/sub x/N/sub y/ gate electrodes; TaSiN-HfO/sub 2/-SiO/sub 2/-Si; Ti/sub 1-x/Al/sub x/N/sub y/ gate electrodes; TiAlN-HfO/sub 2/-SiO/sub 2/-Si; ZrO/sub 2/; dual gate CMOS devices; equivalent oxide thickness variation; gate oxide integrity; high-k gate dielectrics; robust p-type gate electrode properties; stoichiometric TiAlN; surface channel Si CMOS devices; ternary metal nitrides; thermal budget; thermally stable dual metal gate electrodes; work function; CMOS process; Capacitance-voltage characteristics; Electrodes; Hafnium; MOS capacitors; Oxidation; Rapid thermal annealing; Robustness; Surface resistance; Thermal stability;
Conference_Titel :
Electron Devices Meeting, 2001. IEDM '01. Technical Digest. International
Conference_Location :
Washington, DC, USA
Print_ISBN :
0-7803-7050-3
DOI :
10.1109/IEDM.2001.979597
