Liquid Crystals. Iam-Choon Khoo

Liquid Crystals - Iam-Choon Khoo


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anisotropic liquid crystals. Frontiers in Physics 9: 633104, and references therein.

      50 50. I. C. Khoo, “Nonlinear organic liquid cored fiber array for all‐optical switching and sensor protection against short pulsed lasers,” IEEE Journal of Selected Topics in Quantum Electronics 14 (3): 946–951 (2008) and references therein.

      51 51. I. C. Khoo, K. L. Hong, S. Zhao, et al. “Blue‐phase liquid crystal cored optical fiber array with photonic bandgaps and nonlinear transmission properties,” Optics Express 21 (4): 4319–4327 (2013).

      52 52. C.‐W. Chen, H.‐C. Jau, C.‐T. Wang, et al. “Random lasing in blue phase liquid crystals,” Optics Express 20 (21): 23978–23984 (2012).

      2.1. BASIC CONCEPTS

      2.1.1. Introduction

      In the ordered phase, liquid crystals possess both crystalline and fluid properties. The theoretical framework for describing the crystalline properties of liquid crystals, termed elastic or continuum theory, is closer in form to that of solids and invokes similar classical mechanics terminology such as elastic constant, distortion energy, torque, free energies, etc. What makes liquid crystals unique is the fact that in such an ordered phase they also possess many fluidic properties similar to ordinary liquids. Nematic liquid crystals, for example, flow like liquids and thus require hydrodynamical theories for their complete description. These crystalline and flow properties of nematics are explained in further detail in the next chapter.

      In the disordered or isotropic phase, they behave like ordinary fluids of anisotropic molecules. They can thus be described by theories pertaining to anisotropic fluids. However, at the vicinity of the isotropic → nematic phase transition point, liquid crystals exhibit some highly correlated pre‐transitional effects such as enhanced but critically slowed response to external fields, owing to increased intermolecular correlations near the phase transition.

      In the following sections, we introduce some basic concepts and definitions, such as order parameter, short‐ and long‐range order, phase transition, and so on, which form the basis for describing the ordered and disordered phases of liquid crystals. Most of the discussions pertain to the exemplary nematic liquid crystals. Information on other phases may be found in later chapters and the references quoted therein.

      2.1.2. Scalar and Tensor Order Parameters

      The physics of liquid crystals is best described in terms of the so‐called order parameters [1, 2]. If we use the long axis of the molecule as a reference and denote it as ModifyingAbove k With ampersand c period circ semicolon, the microscopic scalar order parameter S is defined [1, 2] as follows:

      On the other hand, for molecules lacking such symmetry, or in cases where such rotational symmetry is “destroyed” by the presence of asymmetric dopants or intramolecular material interactions, a more general tensor order parameter Sij is needed. Sij is defined as

Schematic illustration of coordinate system defining the microscopic order parameter of a nematic liquid crystal molecule.

      (2.3a)upper S Subscript italic i i Baseline equals one half left pointing angle 3 sine squared theta cosine squared phi minus 1 right pointing angle comma

      (2.3b)upper S Subscript italic j j Baseline equals one half left pointing angle 3 sine squared theta sine squared phi minus 1 right pointing angle comma

      (2.3c)upper S Subscript italic k k Baseline equals one half left pointing angle 3 cosine squared theta minus 1 right pointing angle period

      Note that Sii+ Sjj+ Skk= 0. Put another way, S is a traceless tensor because its diagonal elements add up to zero.

      The order parameters defined previously in


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