Title :
Chemical reaction concerns of gate metal with gate dielectric in Ta gate MOS devices: an effect of self-sealing barrier configuration interposed between Ta and SiO2
Author :
Ushiki, Takeo ; Kawai, Kunihiro ; Ohshima, Ichiro ; Ohmi, Tadahiro
Author_Institution :
New Ind. Creation Hatchery Center, Tohoku Univ., Sendai, Japan
fDate :
11/1/2000 12:00:00 AM
Abstract :
Chemical reaction of gate metal with gate dielectric for Ta gate MOS devices has been experimentally investigated both by electrical and physical measurements: capacitance-voltage (C-V), current-voltage (I-V), transmission electron microscopy (TEM), energy dispersive X-ray (EDX), electron diffraction measurements. In spite of the chemical reaction of Ta with SiO2 consuming ~1-nm-thick in gate oxide, the interface trap densities of ~2×1010 cm-2 eV -1 at midgap and ideal channel mobility characteristics have been observed in the Ta gate MOS devices with 5.5-nm-thick thermal oxide gate dielectric. Considering the experimental data with theoretical calculation based on thermodynamics together, a barrier layer model has been developed for the Ta gate MOS systems. The physical mechanism involved is probably self-sealing barrier layer formation resulting from the chemical reaction kinetics in the free-energy change of Ta-Si-O system
Keywords :
MOSFET; X-ray chemical analysis; carrier mobility; characteristics measurement; dielectric thin films; electron diffraction; semiconductor device measurement; semiconductor device models; semiconductor device reliability; transmission electron microscopy; 5.5 nm; MOS devices; Ta-SiO2-Si; barrier layer model; capacitance-voltage characteristics; chemical reaction; current-voltage characteristics; electron diffraction measurements; energy dispersive X-ray measurements; free-energy change; gate dielectric; gate metal; ideal channel mobility characteristics; interface trap densities; reaction kinetics; self-sealing barrier configuration; thermal oxide; transmission electron microscopy; Capacitance measurement; Capacitance-voltage characteristics; Chemicals; Current measurement; Dielectric devices; Dielectric measurements; Electric variables measurement; Electrons; Energy measurement; MOS devices;
Journal_Title :
Electron Devices, IEEE Transactions on
