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Carbon Nanotube and Graphene Device Physics


  • Date Published: December 2010
  • availability: Available
  • format: Hardback
  • isbn: 9780521519052

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About the Authors
  • Explaining the properties and performance of practical nanotube devices and related applications, this is the first introductory textbook on the subject. All the fundamental concepts are introduced, so that readers without an advanced scientific background can follow all the major ideas and results. Additional topics covered include nanotube transistors and interconnects, and the basic physics of graphene. Problem sets at the end of every chapter allow readers to test their knowledge of the material covered and gain a greater understanding of the analytical skill sets developed in the text. This is an ideal textbook for senior undergraduate and graduate students taking courses in semiconductor device physics and nanoelectronics. It is also a perfect self-study guide for professional device engineers and researchers.

    • The first introductory textbook to explain the properties and performance of practical nanotube devices and related applications
    • Covers the basic physics of graphene
    • Included problem sets at the end of each chapter to aid and test understanding
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    Product details

    • Date Published: December 2010
    • format: Hardback
    • isbn: 9780521519052
    • length: 262 pages
    • dimensions: 249 x 175 x 18 mm
    • weight: 0.66kg
    • contains: 125 b/w illus. 10 tables
    • availability: Available
  • Table of Contents

    1. Brief history of carbon
    2. Electrons in solids
    3. Graphene bandstructure
    4. Carbon nanotube bandstructure
    5. Carbon nanotube and graphene equilibrium properties
    6. Ideal quantum electronic properties
    7. Carbon nanotube interconnects
    8. Carbon nanotube field effect transistors
    9. Carbon nanotube diodes and capacitors
    10. Synthesis and placement of carbon nanotubes
    11. Survey of major applications of carbon nanotubes.

  • Resources for

    Carbon Nanotube and Graphene Device Physics

    H.-S. Philip Wong, Deji Akinwande

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    These resources are provided free of charge by Cambridge University Press with permission of the author of the corresponding work, but are subject to copyright. You are permitted to view, print and download these resources for your own personal use only, provided any copyright lines on the resources are not removed or altered in any way. Any other use, including but not limited to distribution of the resources in modified form, or via electronic or other media, is strictly prohibited unless you have permission from the author of the corresponding work and provided you give appropriate acknowledgement of the source.

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  • Instructors have used or reviewed this title for the following courses

    • Carbon Nanomaterials
  • Authors

    H.-S. Philip Wong, Stanford University
    H. S. Philip Wong is a Professor of Electrical Engineering at Stanford University, where he has worked since 2004. Prior to joining Stanford University, he spent 16 years at IBM T. J. Watson Research Center, Yorktown Heights, New York, where he held various positions from Research Staff Member to Senior Manager. He is a Fellow of the IEEE and his current research covers a broad range of topics including carbon nanotubes, semiconductor nanowires, self-assembly, exploratory logic devices, nanoelectromechanical devices, and novel memory devices.

    Deji Akinwande, University of Texas, Austin
    Deji Akinwande is an Assistant Professor at the University of Texas, Austin, which he joined after receiving his Ph.D. from Stanford University in 2009. Prior to beginning his Ph.D., he gained industry experience at Agilent Technologies, XtremeSpectrum/Freescale, and Motorola. He has published widely on carbon nanomaterials.

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