The development of advanced optical structures has enabled tremendous control over the propagation and manipulation of light waves. At the forefront of these advances is the development of micro- and nanostructured optical devices that have dimensions smaller than the wavelength of light. In particular, the engineering of light localization, optical dispersion and plasmonic fields in complex optical media has the potential to boost the scaling of optical technologies below the diffraction limit, opening unprecedented opportunities for basic and applied research. This book bridges three closely related research fields of nanoplasmonics, metamaterials and light localization in complex media. The goal is to share recent progress, identify critical problems and provide promising solutions for the next generation of photonic functionality. Topics include: metamaterials and superlenses; metamaterials; and optical nanoantennas and decay engineering.

The current rapid development of photonics matches the progress of silicon-integrated circuits. However, the ultimate success of photonics requires integration of both active and passive functions into one compact form. For such integration, it is crucial to develop and integrate a large diversity of new materials and material structures that enable generation, manipulation and detection of optical signals at short-length scales. In many cases, the final performance will be fabrication-process-dependent, and controlling microstructure and materials interactions in the device synthesis will be critical. Realization of these devices requires the development of new methods for microprobing, testing and characterization. This book researches work in optoelectronics, integrated optics, microphotonics and related research areas. Areas cover semiconductors, insulators, ferroelectrics and polymers. The goal here is to share progress, identify critical problems and provide promising solutions Topics include: rare-earth-doped structures; photonic bandgap crystals; nanocrystals; new concepts and devices; electro-optic materials and luminescent materials.

The development of advanced optical structures has enabled tremendous control over the propagation and manipulation of light waves. At the forefront of these advances is the development of micro- and nanostructured optical devices that have dimensions smaller than the wavelength of light. In particular, the engineering of light localization, optical dispersion and plasmonic fields in complex optical media has the potential to boost the scaling of optical technologies below the diffraction limit, opening unprecedented opportunities for basic and applied research. This book bridges three closely related research fields of nanoplasmonics, metamaterials and light localization in complex media. The goal is to share recent progress, identify critical problems and provide promising solutions for the next generation of photonic functionality. Topics include: metamaterials and superlenses; metamaterials; and optical nanoantennas and decay engineering.