Title :
Modeling of on-state MOSFET operation and derivation of maximum channel field
Author :
Tang, Yuan ; Kim, Dae M.
Author_Institution :
Oregon Graduate Inst. of Sci. & Technol., Beaverton, OR, USA
fDate :
11/1/1991 12:00:00 AM
Abstract :
A novel approach to modeling MOSFET operation in the threshold region is proposed. A two-dimensional Poisson equation is solved analytically and the current continuity equation is solved iteratively in a self-consistent feedback scheme. The I-V characteristics and the profiles of channel field and mobile charge sheet are found over the entire region of device operation. The boundary between linear and saturation regions of device operation is inherently nonexistent in the model. The physical mechanism underlying the high values of maximum channel field EL beyond channel pinch-off is highlighted. A simple analytical EL model is derived. A comparison of this EL model with previous models is made in the context of the experimental data
Keywords :
insulated gate field effect transistors; semiconductor device models; I-V characteristics; channel pinch-off; current continuity equation; maximum channel field; mobile charge sheet; model; on-state operation; saturation regions; self-consistent feedback scheme; threshold region; two-dimensional Poisson equation; Charge carrier density; Equations; Feedback; Helium; Hot carrier effects; Hot carriers; Impact ionization; MOSFET circuits; Virtual colonoscopy; Voltage;
Journal_Title :
Electron Devices, IEEE Transactions on
