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This text on the electrical, optical, magnetic, and thermal properties of materials stresses concepts rather than mathematical formalism. Suitable for advanced undergraduates, it is intended for materials and electrical engineers who want to gain a fundamental understanding of alloys, semiconductor devices, lasers, magnetic materials, and so forth. The book is organized to be used in a one-semester course; to that end each section of applications, after the introduction to the fundamentals of electron theory, can be read independently of the others. Many examples from engineering practice serve to provide an understanding of common devices and methods. Among the modern applications covered are: high-temperature superconductors, optoelectronic materials, semiconductor device fabrication, xerography, magneto-optic memories, and amorphous ferromagnetics. The fourth edition has been revised and updated with an emphasis on the applications sections, which now cover devices of the next generation of electronics.

Electronic Properties of Materials

Part I: Fundamentals of Electron Theory: Introduction. Wave Properties of Electrons. The Schroedinger Equation. Solution of the Schroedinger Equation for Four Specific Problems. Energy Bands in Crystals. Electrons in a Crystal.- Part II: Electrical Properties of Materials: Electrical Conduction in Metals and Alloys. Semiconductors. Electrical Properties of Polymers, Ceramics, Dielectrics and Amorphous Materials.- Part III: Optical Properties of Materials: The Optical Constants. Atomistic Theory of the Optical Properties. Quantum Mechanical Treatment of the Optical Properties. Applications.- Part IV: Magnetic Properties of Materials: Foundations of Magnetism. Magnetic Phenomena and Their Interpretation - Classical Approach. Quantum Mechanical Considerations. Applications.- Part V: Thermal Properties of Materials: Introduction. Fundamentals of Thermal Properties. Heat Capacity. Thermal Conduction. Thermal Expansion.- Appendices.- Index.