- In-depth explanations of key topics such as Ohm's Law, energy bands, and quantum tunneling.
- Detailed discussions on the applications of various models and equations in semiconductor device physics.
- Python code examples for practical implementation and a better understanding of the concepts. Book Description:
"Modeling Semiconductor Physics" takes readers on an exciting journey through the intricacies of semiconductor physics. Starting with the classical Drude model and introducing Ohm's Law, the book gradually dives into more complex subjects like quantum mechanics basics, energy bands, and the derivation of density of states. It then explores crucial topics such as pn junctions, MOS capacitor characteristics, quantum confinement effects, spintronics, and optoelectronics. What You Will Learn:
- Gain a strong foundation in the principles of semiconductor physics and their applications.
- Understand the mathematical formulation of Ohm's Law and its relevance in semiconductor physics.
- Explore the free electron model and its significance in conducting materials.
- Master the concepts of energy bands, Bloch's theorem, and Brillouin zones.
- Learn about the effective mass theorem, density of states, and Fermi-Dirac statistics.
- Dive into the analysis of charge carriers in semiconductors using Poisson's equation and the drift-diffusion model.
- Discover the intricacies of pn junctions, MOS capacitors, quantum tunneling, and much more. Who This Book is For:
This book is perfect for students, researchers, and professionals in the field of semiconductor physics. It provides a comprehensive and approachable introduction to the subject, making it suitable for beginners as well as those looking to deepen their understanding. The inclusion of Python code examples adds an interactive element that can benefit both self-study and classroom settings. Start your journey into the world of semiconductor physics today!
- In-depth explanations of key topics such as Ohm's Law, energy bands, and quantum tunneling.
- Detailed discussions on the applications of various models and equations in semiconductor device physics.
- Python code examples for practical implementation and a better understanding of the concepts. Book Description:
"Modeling Semiconductor Physics" takes readers on an exciting journey through the intricacies of semiconductor physics. Starting with the classical Drude model and introducing Ohm's Law, the book gradually dives into more complex subjects like quantum mechanics basics, energy bands, and the derivation of density of states. It then explores crucial topics such as pn junctions, MOS capacitor characteristics, quantum confinement effects, spintronics, and optoelectronics. What You Will Learn:
- Gain a strong foundation in the principles of semiconductor physics and their applications.
- Understand the mathematical formulation of Ohm's Law and its relevance in semiconductor physics.
- Explore the free electron model and its significance in conducting materials.
- Master the concepts of energy bands, Bloch's theorem, and Brillouin zones.
- Learn about the effective mass theorem, density of states, and Fermi-Dirac statistics.
- Dive into the analysis of charge carriers in semiconductors using Poisson's equation and the drift-diffusion model.
- Discover the intricacies of pn junctions, MOS capacitors, quantum tunneling, and much more. Who This Book is For:
This book is perfect for students, researchers, and professionals in the field of semiconductor physics. It provides a comprehensive and approachable introduction to the subject, making it suitable for beginners as well as those looking to deepen their understanding. The inclusion of Python code examples adds an interactive element that can benefit both self-study and classroom settings. Start your journey into the world of semiconductor physics today!
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