Title :
A numerical method to compute isotropic band models from anisotropic semiconductor band structures
Author :
Abramo, Antonio ; Venturi, Franco ; Sangiorgi, Enrico ; Higman, Jack M. ; Riccò, Bruno
Author_Institution :
Dept. of Electron., Bologna Univ., Italy
fDate :
9/1/1993 12:00:00 AM
Abstract :
A numerical method for the determination of isotropic band models has been developed and applied to silicon. The resulting model accurately approximates both density of states and group velocity of the corresponding anisotropic band structure, thus providing an excellent agreement with both the collision and nonhomogeneous terms of the Boltzmann transport equation. The model, represented by a simple set of energy-wave vector tables, has been implemented in a Monte Carlo device simulator, but can also be extended to alternative methods for solving the Boltzmann equation. Simulation of homogeneous silicon shows a very good agreement with available experimental data. Comparison with results obtained using the complete anisotropic band structure, both in homogeneous and nonhomogeneous silicon devices, confirms the validity of the model
Keywords :
Monte Carlo methods; band structure of crystalline semiconductors and insulators; band theory models and calculation methods; electronic density of states; elemental semiconductors; numerical analysis; semiconductor device models; silicon; Boltzmann transport equation; Monte Carlo device simulator; Si; anisotropic semiconductor band structures; density of states; electron transport; energy-wave vector tables; group velocity; hole transport; isotropic band models; numerical method; Anisotropic magnetoresistance; Boltzmann equation; Dispersion; Helium; Hot carriers; Lifting equipment; Microscopy; Monte Carlo methods; Scattering; Silicon devices;
Journal_Title :
Computer-Aided Design of Integrated Circuits and Systems, IEEE Transactions on
