Title :
Two dimensional numerical simulation of submicron GaAs MESFETs
Author :
Son, Sang Her ; Kwack, Kae Dal
Author_Institution :
Dept. of Comput. Sci. Eng., Soonchunhyang Univ., South Korea
Abstract :
A two-dimensional numerical simulation of a GaAs MESFET with 0.7-μm gate length is performed. The drift-diffusion model, which considers mobility as a function of local electric field, and the energy transport model, which considers mobility as a function of energy are investigated, and the results are compared and examined. The control-volume formulation is used as the discretization method, and, as a numerical scheme, the current hybrid scheme or upwind scheme is replaced by a power-law scheme. The I-V characteristic of the energy transport model is much larger than that of the drift-diffusion model; hence, the energy transport model is a good fit for the submicron GaAs MESFET device. The mechanisms of velocity saturation in the drift-diffusion model and velocity overshoot in the energy-transport model are described from the standpoints of velocity, energy, and electric field distribution at the bottom of the channel
Keywords :
III-V semiconductors; Schottky gate field effect transistors; carrier mobility; gallium arsenide; numerical methods; semiconductor device models; 07 micron; GaAs; I-V characteristic; MESFET; control-volume formulation; discretization method; drift-diffusion model; electric field distribution; energy transport model; gate length; local electric field; mobility; power-law scheme; two-dimensional numerical simulation; upwind scheme; velocity overshoot; velocity saturation; Electron mobility; Finite difference methods; Finite element methods; Gallium arsenide; Lattices; MESFETs; Numerical simulation; Particle scattering; Poisson equations; Temperature;
Conference_Titel :
Electronic Manufacturing Technology Symposium, 1989, Proceedings. Japan IEMT Symposium, Sixth IEEE/CHMT International
Conference_Location :
Nara
DOI :
10.1109/IEMTS.1989.76145
