Modern Introduction to Surface Plasmons: Theory, Mathematica Modeling, and Applications [Kõva köide]

"In 1952 Pines and Bohm discussed a quantized bulk plasma oscillation of electronsin a metallic solid to explain the energy losses of fast electrons passing throughmetal foils [ 1]. They called this excitation a "plasmon"--Provided by publisher.

"Introducing graduate students in physics, optics, materials science and electrical engineering to surface plasmons, this book also covers guided modes at planar interfaces of metamaterials with negative refractive index. The physics of localized and propagating surface plasmons, on planar films, gratings, nanowires and nanoparticles, is developed using both analytical and numerical techniques. Guided modes at the interfaces between materials with any combination of positive or negative permittivity and permeability are analyzed in a systematic manner. Applications of surface plasmon physics are described, including near-field transducers in heat-assisted magnetic recording and biosensors. Resources at www.cambridge.org/9780521767170 include Mathematica code to generate figures from the book, color versions of many figures, and extended discussion of topics such as vector diffraction theory"--Provided by publisher.

Introducing graduate students in physics, optics, materials science, and electrical engineering to surface plasmons, this book also covers guided modes at planar interfaces of metamaterials with negative refractive index.

The physics of localized and propagating surface plasmons on planar films, gratings, nanowires, and nanoparticles is developed using both analytical and numerical techniques. Guided modes at the interfaces between materials with any combination of positive or negative permittivity and permeability are analyzed in a systematic manner. Applications of surface plasmon physics are described, including near-field transducers in heat-assisted magnetic recording and biosensors.

Cover illustration: a stylized theoretical image of the field intensity pattern around a lollipop nanoantenna at resonance. This antenna design was used in the first demonstration of near-field, heat-assisted magnetic recording with a flying recording head and rotating medium. It was used to confine laser energy on the medium to a recording track width of less than a tenth of a wavelength. Courtesy Seagate Technology.