Semiconductors :bonds and bands /

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"Version: 20130901"--Title page verso.Includes bibliographical references.Preface -- Author biography -- Introduction -- What is included in device modeling? -- What is in this book?Electronic structure -- Periodic potentials -- Potentials and pseudopotentials -- Real-space methods -- Momentum space methods -- The k.p method -- The effective mass approximation -- Semiconductor alloysLattice dynamics -- Lattice waves and phonons -- Waves in deformable solids -- Lattice contribution to the dielectric function -- Models for calculating phonon dynamics -- Anharmonic forces and the phonon lifetimeThe electron-phonon interaction -- The basic interaction -- Acoustic deformation potential scattering -- Piezoelectric scattering -- Optical and intervalley scattering -- Polar optical phonon scattering -- Other scattering processesCarrier transport -- The Boltzmann transport equation -- The effect of spin on transport -- The ensemble Monte Carlo technique.Full-text restricted to subscribers or individual document purchasers.As we settle into this second decade of the 21st century, it is evident that the advances in microelectronics have truly revolutionized our day-to-day lifestyle. The growth of microelectronics itself has been driven, and in turn is calibrated by, the growth in density of transistors on a single integrated circuit, a growth that has come to be known as Moore's Law. Considering that the first transistor appeared only at the middle of the last century, it is remarkable that billions of transistors can now appear on a single chip. The technology is built upon semiconductors, materials in which the band gap has been engineered for special values suitable to the particular application. This book, written specifically for a one-semester course for graduate students, provides a thorough understanding of the key solid state physics of semiconductors and prepares readers for further advanced study, research and development work in semiconductor materials and applications. The book describes how quantum mechanics gives semiconductors unique properties that enabled the microelectronics revolution, and sustain the ever-growing importance of this revolution. Including chapters on electronic structure, lattice dynamics, electron-phonon interactions and carrier transport, it also discusses theoretical methods for computation of band structure, phonon spectra, the electron-phonon interaction and transport of carriers.Graduate students in physics and electrical engineering.Also available in print.Mode of access: World Wide Web.System requirements: Adobe Acrobat Reader.David K Ferry is Regents' Professor in the School of Electrical, Computer and Energy Engineering, at Arizona State University. He received his doctoral degree from the University of Texas, Austin, and was the recipient of the 1999 Cledo Brunetti Award from the Institute of Electrical and Electronics Engineers for his contributions to nanoelectronics. He is the author, or co-author, of numerous scientific articles and more than a dozen books.Title from PDF title page (viewed on March 28, 2014).

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Publisher

: .,

Collation

1 online resource (various pagings) :illustrations.

Language

English

ISBN/ISSN

9780750310444

Classification

537.6/22

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-

Edition

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Subject(s)

Semiconductors.
Solid state physics.
Semi-conductors & super-conductors.
TECHNOLOGY & ENGINEERING / Electronics / Semicondu

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David K Ferry.

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