Quantum Mechanics for Nanostructures

Author:

Vladimir V. Mitin, State University of New York, Buffalo
Dmitry I. Sementsov, Ulyanovsk State University, Russia
Nizami Z. Vagidov, State University of New York, Buffalo

Published:

May 2010

Availability:

Available

Format:

Hardback

ISBN:

9780521763660

£70.99

GBP

Hardback

$105.00 USD

eBook

Description

The properties of new nanoscale materials, their fabrication and applications, as well as the operational principles of nanodevices and systems, are solely determined by quantum-mechanical laws and principles. This textbook introduces engineers to quantum mechanics and the world of nanostructures, enabling them to apply the theories to numerous nanostructure problems. The textbook covers the fundamentals of quantum mechanics, including uncertainty relations, the Schrödinger equation, perturbation theory, and tunneling. These are then applied to a quantum dot, the smallest artificial atom, and compared to hydrogen, the smallest atom in nature. Nanoscale objects with higher dimensionality, such as quantum wires and quantum wells, are introduced, as well as nanoscale materials and nanodevices. Numerous examples throughout the text help students to understand the material.

Introduces engineers to the principles of quantum mechanics, the building blocks of nanoelectronics and nanoscience
Covers the fundamentals of quantum mechanics, including uncertainty relations, the Schrödinger equation, perturbation theory, and tunneling
Quantum-mechanical theories are illustrated with numerous examples of nanostructures

Product details

Published: May 2010
Format: Adobe eBook Reader
ISBN: 9780511730993
Length: 0 pages
Weight: 0kg
Contains: 158 b/w illus. 90 exercises
Availability: This ISBN is for an eBook version which is distributed on our behalf by a third party.

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Contents

1. Nanoworld and quantum physics
2. Wave-particle duality and its manifestation in radiation and particle's behavior
3. Layered nanostructures as the simplest systems to study electron behavior in one-dimensional potential
4. Additional examples of quantized motion
5. Approximate methods of finding quantum states
6. Quantum states in atoms and molecules
7. Quantization in nanostructures
8. Nanostructures and their applications
Appendices
Index.

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About the authors

Authors

Vladimir V. Mitin , State University of New York, Buffalo
Vladimir V. Mitin is SUNY Distinguished Professor at the Department of Electrical Engineering and Adjunct Professor of Physics at the University at Buffalo, The State University of New York. He is the author of eight textbooks and monographs and more than 490 professional publications and presentations.
Dmitry I. Sementsov , Ulyanovsk State University, Russia
Dmitry I. Sementsov is Professor of Physics at Ulyanovsk State University, Russia. He is the author of more than 420 papers in peer-reviewed journals.
Nizami Z. Vagidov , State University of New York, Buffalo
Nizami Z. Vagidov is Research Assistant Professor of Electrical Engineering at the University at Buffalo, The State University of New York. He is the author of about 90 professional publications in the fields of solid-state electronics, nanoelectronics, and nanotechnology.

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