Browsing by Subject "Waveguide"
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Item Open Access Metamaterial Waveguide Holography and Optical Bistability(2019) Huang, ZhiqinOver the last twenty years, progress on metamaterials (MMs), defined as three-dimensional artificial composites, has sprouted unprecedented phenomena through the manipulation of electromagnetic, acoustic and other waves, making the connection \textit{from structure to function}. By virtue of their spatial and spectral control of wave-matter interactions, MMs have emerged as a powerful building block for practical applications, including imaging, sensing, energy harvesting, beam shaping and steering, and many more. In recent years, the metasurface, as an alternative to volumetric metamaterials, with its reduced 2D profile, has gained increased attention for applications where weight, power and cost are of importance. In this dissertation, I will mainly explore two optical applications where the flexibility in design of a metasurface provides unique capabilities. In one application, waveguide holography, a multifunctional metasurface is used to couple light from a waveguide to free space, forming multicolor or multipolarization holograms. In the second application, a metasurface is used to enhance optical bistability.
First, in this dissertation I will present an investigation of a multicolor computer-generated hologram (CGH) in an all-dielectric metamaterial waveguide system. Light beams from three different color laser sources (red, green and blue) are coupled into the waveguide via a single period grating without any beam-splitters or prisms. A multicolor holographic image can be decoupled in the far field through a binary CGH without any lenses. This technology enables lens-free, ultra-miniature augmented and virtual reality displays. Then, I will continue to illustrate polarization-selective waveguide holography at optical frequencies based on a similar metamaterial multilayer system. I will show that two orthogonally polarized, spatially separated or overlapped holographic images can be incorporated into a single binary CGH, and use these two images to produce composite, stereo vision, 3D effect images observable using linear or circularly polarized lens glasses. Both polarizations are also used to construct radially and azimuthally polarized beams. The fundamental mode and the second mode of TM and TE modes in the waveguide are used to guide the two polarization states. We envision that incorporating polarization selection into waveguide holograms may be used to realize chip-scale displays and beams for optical trapping.
Furthermore, I will introduce another example of the principle \textit{from structure to function}, optical bistablity, in a film-coupled metasurface system, which is a promising platform for low-energy and all-optical switches. The large field enhancements that can be achieved in the dielectric spacer region between a nanopatch optical antenna and a metallic substrate can substantially enhance optical nonlinear processes. Utilizing a dielectric material that exhibits an optical Kerr effect as the spacer layer, we propose a new simulation method to vividly show the optical bistability processes. We expect this new method to be highly accurate compared with other numerical approaches, such as those based on graphical post-processing techniques, since it self-consistently solves for both the spatial field distribution and the intensity-dependent refractive index distribution of the spacer layer. This method offers an alternative approach to finite-difference time-domain (FDTD) modelling. One of the bistability metasurface designs exhibits exceptionally low switching intensities, corresponding to switching energies on the order of tens of attojoules. We propose our method as an effective tool for designing all-optical switches and modulators.
Item Open Access Subwavelength-scale Light Localization in Complete Photonic Bandgap Materials(2010) Tang, LinglingThe objective of this dissertation work is to examine light localization in semiconductors provided by a complete photonic bandgap via three-dimensional (3D) woodpile photonic crystals. A 3D photonic crystal is a periodic nanostructure that demonstrates omni-directional Bragg reflection. These materials are anticipated to become a powerful tool for engineering light propagation and localization within subwavelength scales due to their complete photonic bandgap and the distinctive dispersion relation.
The approach of realizing microcavities in this dissertation is to combine multi-directional etching fabrication methods with mode gap design. Modulation of unit cell size along a line-defect 3D waveguide could bring a guiding mode into the mode gap region of the waveguide and form a microcavity with a resonance inside the complete photonic bandgap. The designed microcavities could be fabricated by multi-directional etching methods because they can structurally be decomposed into two sets of connected and straight dielectric rods.
Ultra-high-quality factor microcavities and sub-wavelength-scale waveguides are designed without introduction of local disorders. Monopole, dipole, and quadrupole resonant modes are demonstrated with a small modal volume. The smallest modal volumes obtained are 0.36 cubic half-wavelengths for a resonance field in vacuum, and 2.88 cubic half-wavelengths for a resonance field in a dielectric. Direct metal contacts with the microcavities do not significantly deteriorate the quality factors because the resonant fields are located inside the microcavities. Single-mode woodpile waveguides are also designed in both lateral and vertical propagation directions.
The multi-directional etching method is a simple approach to the fabrication of woodpile photonic crystals and designed optical components with a variety of crystal orientations and surfaces, including (110), (001), (100), and (010) planes. An arbitrary surface plane (mn0) is obtained with this method, where m and n are integers. Moreover, it can also produce large area woodpile photonic crystals with high precision in silicon and GaAs materials.
These optical components in woodpile photonic crystals would be building blocks of high-density, low-loss 3D integrated optics, cavity quantum electrodynamics (QED), nonlinear optics, and enable the realization of current-injection optical devices.