Title :
Sub-50-nm physical gate length CMOS technology and beyond using steep halo
Author :
Wakabayashi, Hitoshi ; Ueki, Makoto ; Narihiro, Mitsuru ; Fukai, Toshinori ; Ikezawa, Nobuyuki ; Matsuda, Tomoko ; Yoshida, Kazuyoshi ; Takeuchi, Kiyoshi ; Ochiai, Yukinori ; Mogami, Tohru ; Kunio, Takemitsu
Author_Institution :
Silicon Syst. Res. Labs., NEC Corp., Kanagawa, Japan
fDate :
1/1/2002 12:00:00 AM
Abstract :
Sub-50-nm CMOS devices are investigated using steep halo and shallow source/drain extensions. By using a high-ramp-rate spike annealing (HRR-SA) process and high-dose halo, 45-nm CMOS devices are fabricated with drive currents of 650 and 300 μA/μm for an off current of less than 10 nA/μm at 1.2 V with Toxinv =2.5 nm. For an off current less than 300 nA/μm, 33-nm pMOSFETs have a high drive current of 400 uA/μm. Short-channel effect and reverse short-channel effect are suppressed simultaneously by using the HRR-SA process to activate a source/drain extension (SDE) after forming a deep source/drain (S/D). This process sequence is defined as a reverse-order S/D (R-S/D) formation. By using this formation, 24-nm nMOSFETs are achieved with a high drive current of 800 μA/μm for an off current of less than 300 μA/μm at 1.2 V. This high drive current might be a result of a steep halo structure reducing the spreading resistance of source/drain extensions
Keywords :
CMOS integrated circuits; VLSI; annealing; integrated circuit technology; nanotechnology; 1.2 V; 24 to 45 micron; deep source/drain; high ramp-rate spike annealing; high-dose halo; nMOSFETs; pMOSFETs; reverse short-channel effect suppression; shallow source/drain extensions; short-channel effect suppression; spreading resistance reduction; steep halo structure; sub-50 nm CMOS devices; Annealing; CMOS process; CMOS technology; Laboratories; Lithography; MOSFETs; National electric code; Resists; Silicon; Ultra large scale integration;
Journal_Title :
Electron Devices, IEEE Transactions on
