Electronic Properties of Engineering Materials
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- Wiley
More About This Title Electronic Properties of Engineering Materials
English
It includes both chemical and physical approaches to the properties of solids, and clearly separates those aspects of materials properties that can be tackled with classical physics from those that require quantum mechanics.
* Quantum mechanics are introduced later to allow readers to be familiar with some of the mathematics necessary for quantum mechanics before being exposed to its bewildering fundamental concepts.
* Discusses the electronic properties of solids from the viewpoint of elementary band theory, and end with a brief treatment of semiconductors and some semiconducting devices.
* Quantum mechanics are introduced later to allow readers to be familiar with some of the mathematics necessary for quantum mechanics before being exposed to its bewildering fundamental concepts.
* Discusses the electronic properties of solids from the viewpoint of elementary band theory, and end with a brief treatment of semiconductors and some semiconducting devices.
English
After retiring from the Materials Department of General Electric’s Research and Development Center, Jim Livingston has been teaching undergraduate materials science at MIT since 1989. While working at GE, his research areas included hard and soft magnetic materials, high-field and high-temperature superconductors, dislocations, mechanical properties, and eutectic and eutectoid transformations.
Livingston earned a Bachelor of Engineering Physics at Cornell University, and an M.A. and Ph.D. at Harvard University. Along with writing over 150 technical articles, he has also authored a monograph on the metallurgy of superconductors and a popular-science book Driving Force: The Natural Magic of Magnets. Jim is a member of the National Academy of Engineering, a Fellow of ASM International and the American Physical Society, and a member of TMS, MRS, AAAS, and the IEEE Magnetics Society.
English
SEMI-CLASSICAL APPROACH.
Conductors and Resistors.
Windows, Doors, and Transparent Electrodes (Optical Properties of Conductors).
Insulators and Capacitors.
Lenses and Optical Fibers (Optical Properties of Insulators).
Inductors, Electromagnets, and Permanent Magnets.
Superconductors and Superconducting Magnets.
Elasticity, Springs, and Sonic Waves.
QUANTUM MECHANICAL APPROACH.
Light Particles, Electron Waves, and Quantum Wells, and Springs.
The Periodic Table, Atomic Spectra, and Neon Lights.
The Game Is Bonds, Interatomic Bonds.
From Bonds to Bands (and Why Grass Is Green).
Free Electron Waves in Metals.
Nearly-Free Electrons--Bands, Gaps, Holes, and Zones.
Metals and Insulators.
Semiconductors.
LEDs, Photodetectors, Solar Cells, and Transistors.
Suggestions for Further Reading.
Index.
Conductors and Resistors.
Windows, Doors, and Transparent Electrodes (Optical Properties of Conductors).
Insulators and Capacitors.
Lenses and Optical Fibers (Optical Properties of Insulators).
Inductors, Electromagnets, and Permanent Magnets.
Superconductors and Superconducting Magnets.
Elasticity, Springs, and Sonic Waves.
QUANTUM MECHANICAL APPROACH.
Light Particles, Electron Waves, and Quantum Wells, and Springs.
The Periodic Table, Atomic Spectra, and Neon Lights.
The Game Is Bonds, Interatomic Bonds.
From Bonds to Bands (and Why Grass Is Green).
Free Electron Waves in Metals.
Nearly-Free Electrons--Bands, Gaps, Holes, and Zones.
Metals and Insulators.
Semiconductors.
LEDs, Photodetectors, Solar Cells, and Transistors.
Suggestions for Further Reading.
Index.
