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Informationen zum Autor PETER L. HAGELSTEIN is an associate professor in the Department of Electrical Engineering and Computer Science at MIT. He is a principal investigator in the Optics and Quantum Electronics Group of the Research Laboratory of Electronics.STEPHEN D. SENTURIA formerly held the Barton L. Weller Chair in Electrical Engineering at MIT. He retired in 2002! and currently serves as Chairman and Chief Technology Officer of Polychromix! Inc. in Woburn! Massachusetts. He is Senior Editor of the ASME/IEEE Journal of Microelectromechanical Systems.TERRY P. ORLANDO is a professor of electrical engineering and principal investigator at the Research Laboratory of Electronics at MIT. His research focuses on superconducting circuits for quantum computation and nonlinear dynamics. Klappentext An Applied Approach to Quantum MechanicsQuantum mechanics is vitally important in the study and design of semiconductor devices. The latest electronic and photonic devices have quantum mechanics at their core, and the emergence of quantum computing further increases the engineering importance of the subject. In contrast to the usual theoretical or experimental treatments of quantum physics, Introductory Applied Quantum and Statistical Mechanics approaches the subject from the point of view of an electrical engineer or materials scientist.Equally useful as a reference for the practitioner and as a text, Introductory Applied Quantum and Statistical Mechanics introduces the reader to the fundamental concepts of quantum physics and their applications to electrical engineering, applied physics, and materials science. Developed from an introductory graduate course in the EECS Department at MIT, this book is structured with an eye towards how the laws enable one to design and build new and better devices. Throughout, theoretical results are supported with real-world systems and applications, and mastery of the material is assisted by worked examples and self-study questions.A unique and useful resource, this book is a valuable tool for anyone seeking to apply the principles of quantum mechanics to the development of practical technical solutions. Zusammenfassung Dieses Lehrbuch der Quantenmechanik ist nicht für Physiker, sondern vorrangig für Elektroingenieure und Materialwissenschaftler gedacht. Entsprechend werden die theoretischen Konzepte durch praxisrelevante Beispiele, etwa aus der Halbleiterherstellung oder der Entwicklung von Quantencomputern, illustriert. Mit durchgearbeiteten Beispielen und Kontrollfragen für das Selbststudium; ein Lösungsheft ist erhältlich. Inhaltsverzeichnis Introduction.PART I: FOUNDATIONS.1. Particles and Waves.2. Probability Amplitudes.3. The Origins of Quantum Mechanics.4. The Schrödinger Equation and Wave Packet Solutions.5. Operators, Expectation Values, and Ehrenfest's Theorem.PART II: THE TIME-INDEPENDENT SCHRÖDINGER EQUATION.6. Eigenfunctions and Eigenvalues.7. Piecewise Constant Potentials: I.8. Piecewise Constant Potentials: II.PART III: THE SIMPLE HARMONIC OSCILLATOR.9. The Simple Harmonic Oscillator I.10. The Simple Harmonic Oscillator II: Operators.11. The Simple Harmonic Oscillator III: Wave Packet Solutions.12. The Quantum LC Circuit.PART IV: USEFUL APPROXIMATIONS.13. Overview of Approximate Methods for Eigenfunctions.14. The WKB Approximation.15. The Variational Method.16. Finite Basis Approximation.PART V: THE TWO-LEVEL SYSTEM.17. The Two-level System with Static Coupling.18. Th e Two-level System with Dynamical Coupling.19. Coupld Two-level System and Simple Harmonic Oscillator.PART VI: QUANTUM SYSTEMS WITH MANY DEGREES OF FREEDOM.20. Problems in More than One Dimension.21. Electromagnetic Field Quantization I: Resonator Fields.22. Electromagnetic Field Quantization II: Free-space Fields.23. The Density of States.24. The Golden Rules: The Calculation of Transition Raes.PART VII:...
