Title :
Plasmonics: The Promise of Highly Integrated Optical Devices
Author :
Maier, Stefan A.
Author_Institution :
Dept. of Phys., Univ. of Bath
Abstract :
This paper reviews the fundamentals of surface plasmon polariton (SPP) excitations sustained by interfaces between metallic and insulating media, with a focus on applications in waveguiding of electromagnetic waves at visible and near-infrared frequencies. The large wavevectors accessible via SPP oscillations allow for significantly reduced wavelengths and thus increased confinement of the propagating modes, promising a subwavelength photonic infrastructure suitable for integration on Si-based photonic chips. Various geometries such as single interfaces, multilayer structures, and nanoparticle ensembles are discussed and their properties assessed in terms of light confinement and energy attenuation of the guided modes. Metal/insulator/metal (MIM) and certain forms of nanoparticle waveguides promise novel avenues for light confinement, guiding, and coupling, which could provide the basis for subwavelength photonic devices
Keywords :
integrated optics; plasmonics; polaritons; surface plasmons; Si-based photonic chips; electromagnetic waves; energy attenuation; guided modes; insulating media; integrated optical devices; light confinement; light coupling; light guiding; metal-insulator-metal; metallic media; multilayer structures; nanoparticle ensembles; nanoparticle waveguides; plasmonics; propagating modes; subwavelength photonic devices; surface plasmon polariton excitation; surface plasmon polariton oscillations; wavevectors; Electromagnetic propagation; Electromagnetic scattering; Frequency; Insulation; Metal-insulator structures; Optical devices; Optical propagation; Optical surface waves; Plasmons; Surface waves; Nanophotonics; optoelectronics; plasmonics;
Journal_Title :
Selected Topics in Quantum Electronics, IEEE Journal of
DOI :
10.1109/JSTQE.2006.884086
