Title :
MODFET 2-D hydrodynamic energy modeling: optimization of subquarter-micron-gate structures
Author :
Shawki, Tarek ; Salmer, Georges ; El-sayed, Osman
Author_Institution :
Univ. des Sci. et Tech. de Lilles-Flandres-Artois, Villeneuve, France
fDate :
1/1/1990 12:00:00 AM
Abstract :
Using a two-dimensional hydrodynamic energy model incorporating nonstationary electron dynamics and nonisothermal electron transport (which characterizes submicron-gate MODFETs), the main physical phenomena that govern the device performance at 300 K are highlighted. This covers velocity overshoot effects, stationary-domain formation, and real space transfer. The model is then used systematically to predict the precise values of the small-signal parameters for different bias conditions. The potential performance improvement achieved by reducing the gate length below 0.2 μm is investigated. It is shown that improvement in transconductance is achieved through gate-length reduction if a severe restriction on the aspect ratio is respected
Keywords :
electric admittance; high electron mobility transistors; semiconductor device models; 0.2 micron; 300 K; MODFET; aspect ratio; device performance; gate length; nonisothermal electron transport; nonstationary electron dynamics; physical phenomena; potential performance improvement; real space transfer; small-signal parameters; stationary-domain formation; subquarter-micron-gate structures; transconductance; two-dimensional hydrodynamic energy model; velocity overshoot effects; Electrons; Extraterrestrial phenomena; HEMTs; Hydrodynamics; Lattices; MODFETs; Particle scattering; Predictive models; Spontaneous emission; Temperature;
Journal_Title :
Electron Devices, IEEE Transactions on
