Plasmonic optics : theory and applications

Plasmonic optics is an emerging research field that combines electronics and photonics with nanostructures. It studies the interactions between electromagnetic waves and matter at the nanoscale. This Tutorial Text provides an introduction to plasmonic optics with distinct concepts and typical applications. Readers will learn about the physics and applications of nanoscale photophysics, leading to better understanding of the fundamental properties of photons in nanostructure materials. Topics include the physical basis of plasmonics, the extraordinary transmission of nanohole arrays, scattering enhancement of nanoparticles, perfect absorption of metamaterials, and nanoantenna for light radiation.

1 Optical Properties of Plasmonic Materials 1.1 Electromagnetic Waves Propagating through Materials 1.1.1 Fundamental equations of electromagnetic waves 1.1.2 Constitutive equations of inhomogeneous media 1.1.3 Isotropic and anisotropic media 1.1.4 Constitutive equations of dielectric media 1.2 Electromagnetic Properties of Materials 1.2.1 Permittivity and permeability 1.2.2 Loss tangent 1.2.3 Penetration depth and skin depth 1.3 Optical Properties of Metals 1.3.1 Free electrons and interband transitions 1.3.2 Harmonic oscillator model 1.3.3 Drude model and Lorentz model 1.3.4 Drude-Lorentz model 1.4 Optical Properties of Dielectric Materials 1.4.1 Dielectric function of dielectric media 1.4.2 Kramers-Kronig relation 1.4.3 Obtaining optical functions from physical observables 1.5 Effective Medium Approach for Composite Nanostructures 1.5.1 Effective medium theory 1.5.2 Topologies of metal-dielectric composites 1.5.3 Lorentz cavity model 1.5.4 Maxwell-Garnett theory 1.5.5 Bruggeman medium theory References 2 Surface Plasmon Polaritons at Planar Interfaces 2.1 Surface Plasmon Polaritons 2.1.1 Concepts 2.1.2 Dispersion relation 2.1.3 Requirements 2.1.4 Momentum mismatch 2.1.5 Dispersion relations in special cases 2.2 SPP Propagation Characteristics 2.2.1 Surface plasmon wavelength 2.2.2 Surface plasmon propagation length 2.2.3 Surface plasmon penetration depth 2.3 Excitation of Surface Plasmon Polaritons 2.3.1 Evanescent waves 2.3.2 Prism excitation 2.3.3 Corrugated grating excitation 2.3.4 Near-field excitation 2.3.5 Coupling to integrated photonic elements References 3 Localized Surface Plasmon Resonances 3.2 Nanoparticles in a Quasi-Static Approximation 3.2.1 Quasi-static approximation 3.2.2 Potentials inside the particle and the surrounding medium 3.2.3 Electric fields inside a particle and surrounding medium 3.2.4 Resonance surface modes 3.2.5 Damping the plasmon resonance 3.3 Extinction Efficiency of Nanoparticles 3.3.1 Extinction efficiency in Mie theory 3.3.2 Electromagnetic normal modes in Mie resonances 3.3.3 Extinction efficiency for small spherical particles 3.3.4 Extinction coefficient for large spherical particles 3.4 Spectral Properties of Localized Surface Plasmons 3.4.1 Beyond the quasi-static approximation 3.4.2 Spectrum shifting due to surrounding medium 3.4.3 Shape-dependent plasmon extinction spectra 3.5 Surface Plasmon Resonance Affinity Biosensors 3.5.1 Fluorescence enhancement by metal nanoparticles 3.5.2 Localized surface plasmon resonance sensing References 4 Extraordinary Transmission through Subwavelength Apertures 4.1 Extraordinary Optical Transmission 4.1.1 Diffraction through subwavelength apertures 4.1.2 Extraordinary optical transmission phenomena 4.1.3 Fano resonance in hole arrays 4.2 Transmission through a Single Aperture 4.2.1 Transmission properties of an isolated circular aperture 4.2.2 Polarization transmission of an isolated rectangular hole 4.2.3 Field distribution inside isolated rectangular aperture 4.3 Transmission through Aperture Arrays 4.3.1 Transmission spectrum of circular aperture arrays 4.3.2 Shape and size dependence 4.3.3 Influence of material properties 4.3.4 Effective optical properties in homogenous anisotropic films 4.4 Aperture Surrounded by Periodic Corrugations 4.4.1 Slit aperture surrounded by a groove structure 4.4.2 Directional emission of an aperture surrounded by slit grooves 4.4.3 Aperture surrounded by concentric grooves 4.4.4 Other geometrical aperture arrays References 5 Surface Plasmon Polariton Waveguides 5.1 Guided Modes in Dielectric and Metal Waveguides 5.1.1 Plasmonic waveguides 5.1.2 Symmetric and antisymmetric SPP modes 5.1.3 General description for a multiple-layer interface 5.2 Dispersion Relation for Plasmonic Waveguides 5.2.1 Dispersion relation of TM modes 5.2.2 Plasmon dispersion in insulator-metal-insulator 5.2.3 Plasmon dispersion in metal-insulator-metal 5.2.4 Channel plasmon polariton waveguides 5.3 Examples of SPP Waveguides 5.3.1 Figures of merit for surface plasmon waveguides 5.3.2 SPP modes in a metallic stripe 5.3.3 SPP modes in nanowires References 6 Optical Nanoantennas 6.1 Elements of Optical Antenna Theory 6.1.1 Radio and optical antennas 6.1.2 Near field and far field 6.1.3 Engineering spontaneous emission 6.1.4 Power dissipation of a quantum dipole 6.1.5 Reciprocity theorem 6.2 Properties of an Optical Antenna 6.2.1 Efficiency, directivity, and gain 6.2.2 Purcell effect and field enhancement 6.2.3 Strong and weak coupling 6.2.4 Wavelength scaling 6.3 Examples of Optical Antennas 6.3.1 Spherical nanoparticle 6.3.2 Ellipsoid nanoparticle optical antennas 6.4 Field Enhancement Due to Resonance Effects 6.4.1 Local field enhancement of a nanorod antenna 6.4.2 Bowtie nanoantennas for strong field enhancement 6.4.3 Yagi-Uda nanoantennas for radiation emission control 6.5 Nanoantennas for Photodetection and Photovoltaics 6.5.1 Photon absorption enhancement by plasmonic nanoantennas 6.5.2 Photodetection with active optical antennas 6.5.3 Multiple-band plasmonic absorber 6.6 Optical Antenna for Nanoscale Sensor Imaging 6.6.1 Metallic tip antennas for nanoscale imaging 6.6.2 Tip-enhanced Raman scattering References 7 Nanostructure Fabrication and Optical Characteristics 7.1 Fabrication Techniques for Metallic Nanostructures 7.1.1 General process 7.1.2 Electron-beam lithography 7.1.3 Focused ion-beam milling 7.1.4 Ion-beam etching and reactive ion etching 7.1.5 Atomic layer deposition 7.2 Large-Scale Nanofabrication 7.2.1 Nanosphere lithography 7.2.2 Nanoimprint lithography 7.3 Chemical Synthesis for Metal Nanostructures 7.3.1 Polyol synthesis process 7.3.2 Seed-mediated growth 7.3.3 Light-mediated synthesis 7.4 Optical Nanostructure Characterization 7.4.1 Near-field optical microscopy 7.4.2 NanoFTIR for chemical identification in nanostructures 7.4.3 STEM and electron-energy loss spectroscopy (EELS) References