Title :
Electron viscosity effects on electron drift velocity in silicon MOS inversion layers
Author_Institution :
NEC Corp., Kawasaki, Japan
fDate :
8/1/1991 12:00:00 AM
Abstract :
Electron drift mobility in MOS inversion layers was analyzed by applying the classical kinetic theory of gases for the viscosity in electron gases and the collision with the oxide interface. Drift velocity profiles for electrons, perpendicular to the MOS interface, were calculated by solving the transport equations for electrons with shear stresses due to electron viscosity. Considering the momentum balance at the MOS interface, the reduction in drift velocity by gate voltages is attributed to the change in the electron mean-free-path determined by electron-electron scattering near the MOS interface. Estimated electron scattering radii are consistent with those predicted for charged particles in plasma physics
Keywords :
carrier mean free path; carrier mobility; elemental semiconductors; inversion layers; metal-insulator-semiconductor structures; silicon; MOS inversion layers; Si; classical kinetic theory; electron drift velocity; electron mean-free-path; electron scattering radii; electron viscosity effects; electron-electron scattering; momentum balance; shear stresses; transport equations; Electron mobility; Equations; Gases; Kinetic theory; Particle scattering; Plasmas; Silicon; Stress; Viscosity; Voltage;
Journal_Title :
Electron Devices, IEEE Transactions on
