Ebook: The Stationary Semiconductor Device Equations
- Tags: Optical and Electronic Materials, Power Electronics Electrical Machines and Networks, Electronics and Microelectronics Instrumentation
- Series: Computational Microelectronics
- Year: 1986
- Publisher: Springer-Verlag Wien
- Edition: 1
- Language: English
- pdf
In the last two decades semiconductor device simulation has become a research area, which thrives on a cooperation of physicists, electrical engineers and mathe maticians. In this book the static semiconductor device problem is presented and analysed from an applied mathematician's point of view. I shall derive the device equations - as obtained for the first time by Van Roosbroeck in 1950 - from physical principles, present a mathematical analysis, discuss their numerical solu tion by discretisation techniques and report on selected device simulation runs. To me personally the most fascinating aspect of mathematical device analysis is that an interplay of abstract mathematics, perturbation theory, numerical analysis and device physics is prompting the design and development of new technology. I very much hope to convey to the reader the importance of applied mathematics for technological progress. Each chapter of this book is designed to be as selfcontained as possible, however, the mathematical analysis of the device problem requires tools which cannot be presented completely here. Those readers who are not interested in the mathemati cal methodology and rigor can extract the desired information by simply ignoring details and proofs of theorems. Also, at the beginning of each chapter I refer to textbooks which introduce the interested reader to the required mathematical concepts.
The static semiconductor device problem is treated in an "applied mathematics” way. Qualitative properties, e.g. existence and uniqueness of solutions, and quantitative properties, particularly the structure of steady state solutions, are analysed. Physical interpretations of the mathematical results are given. Also, these results serve as a basis for the derivation and convergence analysis of numerical discretisation techniques.
The static semiconductor device problem is treated in an "applied mathematics” way. Qualitative properties, e.g. existence and uniqueness of solutions, and quantitative properties, particularly the structure of steady state solutions, are analysed. Physical interpretations of the mathematical results are given. Also, these results serve as a basis for the derivation and convergence analysis of numerical discretisation techniques.
Content:
Front Matter....Pages I-IX
Introduction....Pages 1-6
Mathematical Modeling of Semiconductor Devices....Pages 7-30
Analysis of the Basic Stationary Semiconductor Device Equations....Pages 31-67
Singular Perturbation Analysis of the Stationary Semiconductor Device Problem....Pages 68-130
Discretisation of the Stationary Device Problem....Pages 131-177
Numerical Simulation — A Case Study....Pages 178-183
Back Matter....Pages 184-195
The static semiconductor device problem is treated in an "applied mathematics” way. Qualitative properties, e.g. existence and uniqueness of solutions, and quantitative properties, particularly the structure of steady state solutions, are analysed. Physical interpretations of the mathematical results are given. Also, these results serve as a basis for the derivation and convergence analysis of numerical discretisation techniques.
Content:
Front Matter....Pages I-IX
Introduction....Pages 1-6
Mathematical Modeling of Semiconductor Devices....Pages 7-30
Analysis of the Basic Stationary Semiconductor Device Equations....Pages 31-67
Singular Perturbation Analysis of the Stationary Semiconductor Device Problem....Pages 68-130
Discretisation of the Stationary Device Problem....Pages 131-177
Numerical Simulation — A Case Study....Pages 178-183
Back Matter....Pages 184-195
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