Title :
Co-optimization of the metal gate/high-k stack to achieve high-field mobility >90% of SiO2 universal mobility with an EOT=∼1 nm
Author :
Zhang, Zhibo ; Song, S.C. ; Quevedo-Lopez, M.A. ; Choi, Kisik ; Kirsch, Paul ; Lysaght, Pat ; Lee, Byoung Hun
Author_Institution :
Texas Instrum. Inc., Dallas, TX, USA
fDate :
3/1/2006 12:00:00 AM
Abstract :
HfO2 and HfSiON gate dielectrics with high-field electron mobility greater than 90% of the SiO2 universal mobility and equivalent oxide thickness (EOT) approaching 1 nm are successfully achieved by co-optimizing the metal gate/high-k/bottom interface stack. Besides the thickness of the high-κ dielectrics, the thickness of the ALD TiN metal gate and the formation of the bottom interface also play an important role in scaling EOT and achieving high electron mobility. A phase transformation is observed for aggressively scaled HfO2 and HfSiON, which may be responsible for the high mobility and low charge trapping of the optimized HfO2 gate stack.
Keywords :
CMOS integrated circuits; MOSFET; atomic layer deposition; electron mobility; electron traps; hafnium compounds; high-k dielectric thin films; silicon compounds; titanium compounds; ALD; CMOS processing; MOSFET; TiN-HfO2; TiN-HfSiON; atomic layer deposition; charge carrier mobility; charge trapping; equivalent oxide thickness; gate stack; high electron mobility; high-k dielectrics; metal gate/high-k interface stack; phase transformation; universal mobility; Amorphous materials; CMOS process; CMOS technology; Dielectric substrates; Electron mobility; Electron traps; Hafnium oxide; High K dielectric materials; High-K gate dielectrics; Tin; Charge carrier mobility; HfO; HfSiON; MOSFETs; high-; metal gate;
Journal_Title :
Electron Device Letters, IEEE
DOI :
10.1109/LED.2006.870245
