Liquid Crystals. Iam-Choon Khoo

Liquid Crystals - Iam-Choon Khoo


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alt="Schematic illustration of the makeup of a blue-phase liquid crystal: (top) liquid crystal molecules in tightly wound double-twist cylinder; (middle) unit cell of BPI with BCC (body-centered cubic) lattice structure and discontinuous lines; (bottom) unit cell of BPII simple cubic lattice with continuous network of defect lines."/> Schematic illustration of reflectance from BPLC in polycrystalline (lower photo) and single-crystalline (upper photo) form.

      1.5.4. Photosensitive and Tunable Optical Waveguide, Photonic Crystals, and Metamaterial Nanostructures

      Liquid crystal‐guided wave optics such as planar and fiber waveguides are among the earliest to be investigated [40–42]. In these optical structures, liquid crystals are introduced either as the wave‐guiding cores or the adjacent claddings to the wave‐guiding structures; by modulating the liquid crystalline properties with an external field, the transmission and reflection properties of such waveguides can be correspondingly modulated. Other studies have employed more complex structures such as photonic crystals [43] or so‐called holey fibers [44], where additional mechanisms at work such as bandgaps and special band‐edge dispersions create a rich variety of transmission/reflection modulation possibilities. With the advent of nanotechnologies as well as the optical physics and electromagnetic theories of sub‐wavelength structure, liquid crystal cladded micro‐ring resonator [45], plasmonic waveguides [46], and metamaterials [47–49] with unusual tunable optical (UV – THz) and electromagnetic (GHz, microwave) properties have been actively investigated in recent years.

Schematic illustration of tunable micro- and nano-photonic structures incorporating liquid crystals.

      The problem is especially acute in plasmonic nanostructures where the light‐induced electric field penetrates only a very small fraction of the surrounding LC, unlike their counterpart in conventional LC cells. In general, therefore, the observed effective tuning or switching ability of such plasmonic or metamaterial (including metasurfaces) nanostructures is generally much lower than theoretical predictions based on the entire LC region being reoriented.

      1.5.5. Isotropic Liquid Crystal Cored Fiber Array

Schematic illustration of a focused laser propagating through the guiding (liquid crystal) core of fiber inside a fiber array. Schematic illustration of a capillary filled with dye-doped BPLC core for random laser action.

      1 1. P. G. deGennes, “The Physics of Liquid Crystals,” Clarendon Press, Oxford, 1974.

      2 2. I. C. Khoo and S. T. Wu, “Optics and Nonlinear Optics of Liquid Crystals.” World Scientific, Singapore, 1992.

      3 3. P. Yeh and C. Gu, “Optics of Liquid Crystal Displays,” Wiley, New York, 2009.

      4 4. I. C. Khoo, “Nonlinear optics of liquid crystalline materials,” Physics Report 471, pp. 221–267 [2009].

      5 5. H. Park, E. P. J. Parrott, F. Fan, et al. “Evaluating liquid crystal properties for use in terahertz devices,” Optics Express 20, pp. 11899–11905 (2012).

      6 6. J. R. Sambles, R. Kelly, and R. F. Yang, "Metal slits and liquid crystals at


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