
Metal-semiconductor nanostructures represent an important new class of materials employed in designing advanced optoelectronic and nanophotonic devices, such as plasmonic nanolasers, plasmon-enhanced light-emitting diodes and solar cells, plasmonic emitters of single photons, and quantum devices operating in infrared and terahertz domains. The combination of surface plasmon resonances in conducting structures, providing strong concentration of an electromagnetic optical field nearby, with sharp optical resonances in semiconductors, which are highly sensitive to external electromagnetic fields, creates a platform to control light on the nanoscale. The design of the composite metal-semiconductor system imposes the consideration of both the plasmonic resonances in metal and the optical transitions in semiconductors - a key issue being their resonant interaction providing a coupling regime. In this book the reader will find descriptions of electrodynamics of conducting structures, quantum physics of semiconductor nanostructures, and guidelines for advanced engineering of metal-semiconductor composites. These constituents form together the physical basics of the metal-semiconductor plasmonics, underlying many effective practical applications. The list of covered topics also includes the review of recent results, such as the achievement of a strong coupling regime, and the preservation of non-classical statistics of photons in plasmonic cavities combined with semiconductor nanostructures.
This book investigates the physical principles and engineering challenges involved in the resonant interaction between surface plasmons in metal nanostructures and optical transitions in semiconductors. Authors Alexey A. Toropov and Tatiana V. Shubina synthesize electrodynamics and quantum physics to provide a framework for designing composite systems that control light at the nanoscale. The text serves as a technical reference for researchers and engineers working on advanced optoelectronic devices, including nanolasers and high-efficiency solar cells.
What You Will Find
Scope Limits
Experts identify this work as a specialized resource for researchers focusing on the intersection of plasmonics and semiconductor physics. Readers frequently note the high level of technical density, making it most suitable for those with a strong background in quantum mechanics and electrodynamics.
Page Count:
400
Publication Date:
2015-01-01
Publisher:
OUP Oxford
ISBN-10:
0191054003
ISBN-13:
9780191054006
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