1st Edition

Nanoscale Physics for Materials Science

    288 Pages 150 B/W Illustrations
    by CRC Press

    Although there are many books available on the preparation, properties, and characterization of nanomaterials, few provide an interdisciplinary account of the physical phenomena that govern the novel properties of nanomaterials. Addressing this shortfall, Nanoscale Physics for Materials Science covers fundamental cross-disciplinary concepts in materials science and engineering. It presents a comprehensive description of the physical phenomena and changes that can be expected when macroscopically sized materials are reduced to the nanometer level.

    The text is divided according to physical phenomena and interactions. After reviewing the necessary theoretical background, the authors address the electrical, optical, and magnetic properties as functions of size and distance. They discuss the energy spectrum, the charging effect, tunneling phenomena, electronically induced stable nanostructures, absorption and scattering, electromagnetic interactions, magnetism, ferromagnetic domain-wall-related phenomena, and spin transport in magnetic nanostructures. Problem sets are included at the end of each chapter.

    Providing an excellent treatment of physical phenomena not covered in similar books, this text explores the electrical, optical, and magnetic properties of materials at the nanoscale level. It delves into the dramatic physical changes that occur on scales where the quantum nature of objects starts dominating their properties.

    Fundamentals of Quantum Mechanics and Band Structure
    Fundamentals of quantum mechanics
    Electronic band structure of solids
    Material properties with respect to characteristic size in nanostructures

    Electronic States and Electrical Properties of Nanoscale Materials

    Outline
    Low dimensionality and energy spectrum
    Quantization
    Edge (surface) localized states
    Charging effect
    Tunneling phenomena
    Limiting factors for size effects
    Electronically induced stable nanostructures

    Optical Properties and Interactions of Nanoscale Materials

    Size-dependent optical properties: absorption and emission
    Size-dependent optical properties: absorption and scattering
    Size-dependent electromagnetic interactions: particle–particle
    Size-dependent interactions: particle–light interactions in finite geometries

    Magnetic and Magnetotransport Properties of Nanoscale Materials

    Fundamentals of magnetism
    Size and surface effects in 3D confined systems
    Ferromagnetic domain-wall-related phenomena
    Spin transport in magnetic nanostructures—magnetic interface effect
    Index

    Problems and References appear at the end of each chapter.

    Biography

    Takaaki Tsurumi is a professor in the Department of Metallurgy and Ceramics Science at the Tokyo Institute of Technology in Japan.

    Hiroyuki Hirayama is a professor in the Department of Materials Science and Engineering at the Tokyo Institute of Technology in Japan.

    Martin Vacha is an associate professor in the Department of Organic and Polymeric Materials at the Tokyo Institute of Technology in Japan.

    Tomoyasu Taniyama is an associate professor in the Materials and Structures Laboratory at the Tokyo Institute of Technology in Japan.