Photonic crystal

About: Photonic crystal is a research topic. Over the lifetime, 43424 publications have been published within this topic receiving 887083 citations.

Confined electrons and photons : new physics and applications

Abstract: Confined Electrons and Photons: A Summary:.- Basic Solid State Optics in Bulk and 2D Structures.- Dynamics of Optical Excitations in Semiconductors.- Optical Transitions, Excitons and Polaritons in Bulk and Low-Dimensional Semiconductor Structures.- Electron States in Biased Heterostructures.- Phonons and Electron-Phonon Interaction in Low-Dimensional Structures.- Excitonic Radiative Dynamics in Semiconductor Quantum Wells.- Superlattices and Quantum Wells in Organic Semiconductors: Excitons and Optical Non-linearities.- Intersubband Transitions in Quantum Wells.- Confined Electrons in 1D and 0D.- Principles of Electron Solid State Electron Optics.- Atomic-like Spectroscopy of Low Dimensional Electron Systems.- Inelastic Scattering and Thermalization in low-III-V Semiconductor Structures.- Synthesis and Spectroscopy of II-VI Quantum Dots: an Overview.- Prospects of High Efficiency Quantum Boxes obtained by direct epitaxial growth.- Confined Photons.- Atoms in Cavities.- Controlling Spontaneous Emission and Optical Microcavities.- Spontaneous Emission Control in Semiconductor Microcavities.- Strong Coupling in Semiconductor Microcavities.- Localization of Light in Disordered and Periodic Dielectrics.- Photonic Bloch Waves and Photonic Band Gaps.- Light Emission in Photonic Crystal Micro-Cavities.- Special Topics - Applications.- Semiconductor Nanostructure lasers: Fundamentals and Fabrications.- Quantum Wells Optical Switching Devices.- High-efficiency, Narrow Spectrum Resonant Cavity Light Emitting Diodes.- Short Papers (Seminars and Selected Posters).- Spontaneous Emission Control in Planar Structures: Er3+ in Si/SO2 Microcavities.- Vacuum Rabi Splitting in a Semiconductor Microcavity.- Impurity Modes in One-Dimensional Periodic Systems: The Transition from Photonic Bandgaps to Microcavities.- Photonic Bandgap Calculations: Inward and Outward Integral Equations and the KKR method.- Soliton-Polariton Interaction near an Excitonic Resonance in Semiconductors.- Dynamics of Excitons and Electron-Hole Plasma Confined in Semiconductor Nanocrystals.- Coupled-Quantum Wells for Optical Modulation.- In-plane Electro-Optic Effect in a Quantum Well.- Reprinted Papers: Basics.- Aspects of Polaritons.- Interband Optical Transitions in Extremely Anisotropic Semiconductors.- Effect of Retarded Interaction on the Exciton Spectrum in One-Dimensional and Two-Dimensional Crystals.- On the Exciton Luminescence at Low temperatures: Importance of the Polariton Viewpoint.- Spatial and Spectral Features of Polariton Fluorescence.- Reprinted Papers: Confined Electrons.- Studies of Exciton Localization in Quantum-Well Structures by Nonlinear-Optical Techniques.- Excitonic Optical Nonlinearity and Exciton Dynamics in Semiconductor Quantum Dots.- Very Large Optical Nonlinearity of Semiconductor Microcrystallites.- Reprinted Papers: Confined Photons.- Spontaneous Emission Probabilities at Radiofrequencies.- Inhibited Spontaneous Emission.- Inhibited Spontaneous Emission in Solid State Physics and Electronics.- Cavity Q.E.D.- Cavity Quantum Electrodynamics at Optical Frequencies.- Physics and Device Applications of Optical Microcavities.- Optical Processes in Microcavities.- Photon Number Squeezed States in Semiconductor Lasers.- Photonic Bandgap Structures.- Applications of Photonic Band gap Structures.- Contributors.

Nanoassembled Plasmonic-Photonic Hybrid Cavity for Tailored Light-Matter Coupling

Abstract: We propose and demonstrate a hybrid cavity system in which metal nanoparticles are evanescently coupled to a dielectric photonic crystal cavity using a nanoassembly method. While the metal constituents lead to strongly localized fields, optical feedback is provided by the surrounding photonic crystal structure. The combined effect of plasmonic field enhancement and high quality factor (Q ≈ 900) opens new routes for the control of light-matter interaction at the nanoscale.

Structural long-period gratings in photonic crystal fibers.

Abstract: We report what is believed to be the first example of structural long-period gratings written in pure silica photonic crystal fibers (PCFs) The gratings are realized by periodic collapse of the holes of the PCF by heat treatment with a CO2 laser The resulting periodic hole-size perturbation produces core-to-cladding-mode conversion These results can lead to a new family of structural all-fiber devices that use the unique properties of PCFs

Nanoparticle-based one-dimensional photonic crystals.

Abstract: Herein we present a fast, reliable method for building nanoparticle-based 1D photonic crystals in which a periodic modulation of the refractive index is built by alternating different types of nanoparticles and by controlling the level of porosity of each layer. The versatility of the method is further confirmed by building up optically doped photonic crystals in which the opening of transmission windows due to the creation of defect states in the gap is demonstrated. The potential of this new type of structure as a sensing material is illustrated by analyzing the specific color changes induced by the infiltration of solvents of different refractive indexes.

Tunable photonic crystals with semiconducting constituents

Abstract: We propose that the photonic band structure (PBS) of semiconductor-based photonic crystals (PCs) can be made tunable if the free-carrier density is sufficiently high. In this case, the dielectric constant of the semiconductor, modeled as varepsilon(omega) = varepsilon(0)(1-omega(2)(p)/omega(2)), depends on the temperature T and on the impurity concentration N through the plasma frequency omega(p). Then the PBS is strongly T and N dependent; it is even possible to obliterate a photonic band gap. This is shown by calculating the 2D PBS for PCs that incorporate either intrinsic InSb or extrinsic Ge.