Title :
Inclusion of the inertial effects in the drift-diffusion equation
Author :
Belde, Ramprasad ; Frensley, William R.
Author_Institution :
Dept. of Electr. & Comput. Eng., Texas Univ., Dallas, TX, USA
Abstract :
The authors point out that when the potential across the transit region of a device varies by kT/2|q| volts or more within a mean free path length the charge carrier inertia significantly influences the current transport. The conventional drift-diffusion model is corrected to include such inertial effects and obtain a unified transport model. Device modeling has been done using the modified transport model and used in the case of an n+nn+ structure to demonstrate the importance of the inertial or the ballistic effects on the carrier motion for very narrow potential barriers. The results show that the uniform transport model gives improved results compared to the drift-diffusion model
Keywords :
semiconductor device models; ballistic effects; charge carrier inertia; current transport; device modelling; drift-diffusion equation; inertial effects; modified transport model; n+nn+ structure; narrow potential barriers; transit region; uniform transport model; Charge carrier processes; Charge carriers; Difference equations; Fluid dynamics; Numerical models; Poisson equations; Predictive models; Semiconductor devices; Steady-state; Voltage;
Conference_Titel :
High Speed Semiconductor Devices and Circuits, 1991., Proceedings IEEE/Cornell Conference on Advanced Concepts in
Conference_Location :
Ithaca, NY
Print_ISBN :
0-7803-0491-8
DOI :
10.1109/CORNEL.1991.170038
