Title :
Scaled silicon MOSFET´s: universal mobility behavior
Author :
Vasileska, Dragica ; Ferry, David K.
Author_Institution :
Center for Solid State Electron. Res., Arizona State Univ., Tempe, AZ, USA
fDate :
4/1/1997 12:00:00 AM
Abstract :
We use a fully quantum-mechanical model to study the inversion layer mobility in a silicon MOS structure. The importance of depletion charge and surface-roughness scattering on the effective electron mobility is examined. The magnitude of the mobility is found to be considerably reduced by both depletion charge and interface-roughness scattering. The appropriate weighting coefficients a and b for the inversion and depletion charge densities in the definition of the effective electric field, which eliminate the doping dependence of the effective electron mobility, are also calculated. These are found to differ from the commonly used values of 0.5 and 1. In addition, the weighting coefficient for the depletion charge density is found to be significantly influenced by the actual shape of the doping profile and can be either >1 or <1
Keywords :
MOSFET; doping profiles; electron mobility; inversion layers; semiconductor device models; surface scattering; Si MOS structure; Si-SiO2; depletion charge density; doping dependence; doping profile shape; effective electron mobility; fully quantum-mechanical model; interface-roughness scattering; inversion layer mobility; scaled silicon MOSFET; surface-roughness scattering; universal mobility behavior; weighting coefficients; CMOS technology; Doping profiles; Electron mobility; MOSFET circuits; Particle scattering; Semiconductor device modeling; Semiconductor process modeling; Shape; Silicon; Substrates;
Journal_Title :
Electron Devices, IEEE Transactions on
