Liquid Crystals. Iam-Choon Khoo

Liquid Crystals - Iam-Choon Khoo


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exhibit a nematic phase. For n = 5–7, the material possesses a nematic range. For n > 8, smectic phases begin to appear.

      Another reliable observation is that the nematic → isotropic phase transition temperature Tc is a good indicator of the thermal stability of the nematic phase [6]; the higher the Tc, the greater is the thermal stability of the nematic phase. In this respect, the types of chemical groups used as substituents in the terminal groups or side chain play a significant role – an increase in the polarizability of the substituent tends to be accompanied by an increase in Tc.

      The theoretical formalism for describing the nematic → isotropic phase transition and some of the results and consequences are given in the next section. This is followed by a summary of some of the basic concepts introduced for the isotropic phase.

      Among the various theories developed to describe the order parameter and phase transitions in the liquid crystalline phase, the most popular and successful one is the theory first advanced by Maier and Saupe and corroborated in studies by others [8]. In this formalism, Coulombic intermolecular dipole–dipole interactions are assumed. The interaction energy of a molecule with its surroundings is then shown to be of the form [6]:

      2.3.1. Maier–Saupe Theory: Order Parameter Near Tc

      Following the formalism of deGennes, the interaction energy may be written as

      (2.12)upper G 1 equals minus one half upper U left-parenthesis p comma upper T right-parenthesis upper S left-parenthesis three halves cosine squared theta minus 1 right-parenthesis period

      The total free enthalpy per molecule is therefore

      (2.13)upper G left-parenthesis p comma upper T right-parenthesis equals upper G Subscript i Baseline left-parenthesis p comma upper T right-parenthesis plus upper K Subscript upper B Baseline upper T integral f left-parenthesis theta comma phi right-parenthesis log 4 italic pi f left-parenthesis theta comma phi right-parenthesis d normal upper Omega plus upper G 1 left-parenthesis p comma upper T comma upper S right-parenthesis comma

      (2.14)f left-parenthesis theta right-parenthesis equals StartFraction exp left-parenthesis m cosine squared theta right-parenthesis Over 4 italic pi z EndFraction comma

      where

      and the partition function z is given by

      (2.16)z equals integral Subscript 0 Superscript 1 Baseline e Superscript italic m x squared Baseline italic d x period

      From the definition of upper S equals negative one half plus three halves left pointing angle cosine squared theta right pointing angle, we have

      (2.18)StartFraction k Subscript upper B Baseline upper T Subscript c Baseline Over upper U left-parenthesis upper T Subscript c Baseline right-parenthesis EndFraction equals 4.55 period

      Figure 2.2 shows that curves 1 and 2 for S intersect at the origin O and two points N and M. Both points O and N correspond to minima of G, whereas M corresponds to a local maximum of G. For T < Tc, the value of G is lower at point N than at point O; that is, S is nonzero and corresponds to the nematic phase. For temperatures above Tc the stable (minimum energy) state corresponds to O; that is, S = O and corresponds to the isotropic phase.

      The transition at T = Tc is a first‐order one. The order parameter just below Tc is

      (2.19)upper S Subscript c Baseline identical-to upper S left-parenthesis upper T Subscript c Baseline right-parenthesis equals 0.44 period

      It has also been demonstrated that the temperature dependence of the order parameter of most nematics is well approximated by


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