Title :
Two-dimensional simulation for resonant tunneling transistor
Author :
Tomizawa, Masaaki ; Taniyama, Hideaki ; Yoshii, Akira
Author_Institution :
NTT LSI Labs., Kanagawa, Japan
fDate :
6/1/1994 12:00:00 AM
Abstract :
A new two-dimensional device simulation for the resonant tunneling transistor is presented. In the simulation, the one-dimensional Schrodinger equation is solved for the intrinsic area of the transistor and the conventional two-dimensional drift-diffusion equations are solved for the extrinsic part. Both equations are coupled with the carrier generation-recombination term in the drift-diffusion equations. In addition, the Poisson equation is also solved self-consistently with them to take the charge distribution effect into account. The two-dimensional simulator has been successfully applied to the analysis of a resonant tunneling transistor and it was found that the current-voltage characteristics sensitively depend on the base resistance. This means that a two-dimensional treatment of the voltage drop in the base region is essential for an accurate simulation
Keywords :
Schrodinger equation; resonant tunnelling devices; semiconductor device models; simulation; transistors; 2D drift-diffusion equations; 2D simulation; Poisson equation; base region; base resistance; carrier generation-recombination term; charge distribution effect; current-voltage characteristics; one-dimensional Schrodinger equation; resonant tunneling transistor; two-dimensional device simulation; voltage drop; Analytical models; Doping; Fabrication; Large scale integration; Poisson equations; Resonant tunneling devices; Schrodinger equation; Semiconductor devices; Supercomputers; Voltage;
Journal_Title :
Electron Devices, IEEE Transactions on
