Title :
Novel fabrication process to realize ultra-thin (EOT = 0.7 nm) and ultra-low-leakage SiON gate dielectrics
Author :
Matsushita, Daisuke
Author_Institution :
Adv. LSI Technol. Lab., Toshiba Corp., Yokohama
Abstract :
The reaction mechanism of nitrogen atoms with Si was investigated based on first principles calculations and experimental results to realize ultra thin SiN-based SiON films with high insulation and good interfacial properties. Incorporation rate of nitrogen atoms into Si has a great influence on arranging 3-fold coordinated N atoms uniformly. By arranging 3-fold coordinated N atoms into the Si sub-surface layer uniformly, oxidation-resistant Si3N4 film can be formed and O atoms were successfully incorporated into the SiN/Si interface with minimum disruption of SiN structures. By using this novel process, a high-quality ultra-thin gate SiON film with an equivalent oxide thickness (EOT) of 0.7 nm and a leakage current (Jg) of 95 A/cm2, i.e., 1/10 or less than that of traditional SiON films was realized. Mobility is not reduced to less than 89% of an ideal SiO2 film
Keywords :
ab initio calculations; dielectric thin films; electron mobility; insulating thin films; leakage currents; nanotechnology; oxidation; permittivity; silicon compounds; 0.7 nm; 3-fold coordinated N atoms; Si; SiN-SiON; SiON gate dielectrics; equivalent oxide thickness; first principles calculations; insulation properties; interfacial properties; leakage current; nitrogen atoms; oxidation-resistant Si3N4 film; reaction mechanism; ultra thin SiN-based SiON films; ultra-thin gate SiON film; Atomic layer deposition; Degradation; Dielectrics and electrical insulation; Fabrication; High K dielectric materials; High-K gate dielectrics; Nitrogen; Oxidation; Semiconductor films; Silicon compounds;
Conference_Titel :
Advanced Thermal Processing of Semiconductors, 2005. RTP 2005. 13th IEEE International Conference on
Conference_Location :
Santa Barbara, CA
Print_ISBN :
0-7803-9223-X
DOI :
10.1109/RTP.2005.1613680
