Molecular Dynamics Simulations of 2-(4-butyloxyphenyl)-5-octyloxypyrimidine and 5-(4-butyloxyphenyl)-2-octyloxypyrimidine Liquid Crystal Phases

Pecheanu, Rodica

28 October 2009

Molecular dynamics simulations of the liquid crystal phases of 2-(4-butyloxyphenyl)-5-octyloxypyrimidine (2PhP) and 5-(4-butyloxyphenyl)-2-octyloxy-pyrimidine (5PhP) are the focus of this thesis. The 2PhP and 5PhP mesogens display different liquid crystalline phase sequences, despite having very similar molecular structures. Specifically, both mesogens consist of aromatic phenyl and pyrimidine cores in between two flexible alkoxy tails, but they differ in the preferred core conformation. A multi-site coarse-grained model, in which the aromatic rings are represented by soft quadrupolar ellipsoids and the alkoxy chains are given a united atom representation, is proposed in this thesis. A parameterization route for the intra- and intermolecular potentials appropriate for liquid crystal simulations is developed. The ab initio based derivation of suitable molecular models for the two mesogens is discussed in detail, with particular emphasis on capturing proper phenyl-pyrimidine interactions which proved to be essential to correctly represent core-core interactions between neighboring molecules. A systematic determination of suitable Gay-Berne (GB) parameters has been adopted for the aromatic rings of 2PhP and 5PhP. To account for the pi-electron cloud below and above the ring plane, a quadrupole was added perpendicular to the ring. In the end, four parameterizations for aromatic rings have been selected for the simulations. Model characterization via pair interactions proved to be valuable in identifying and analyzing the short range structure in the phases. Extensive molecular dynamics simulations of these fluids at various temperatures are performed. Intermolecular structure and order, in aromatic core and the flexible tail regions, are analyzed. Intermolecular structure is divided into contributions parallel and perpendicular to the layers, as indicated by a layer normal or by a director, to differentiate smectic A (SmA) from smectic C (SmC). The presence of a ring quadrupole in the molecular model is shown to be essential to the correct reproduction of the experimentally observed phases. Simulations correctly indicate phases in agreement with experiment: SmC and SmA phases for 2PhP, and only a SmA phase for 5PhP. / Thesis (Ph.D, Chemistry) -- Queen's University, 2009-10-27 20:23:37.89

Optical and Electro-optical Properties of Nematic Liquid Crystals with Nanoparticle Additives

Mirzaei, Javad

January 2014

Liquid crystals (LCs) are an interesting class of materials that are attracting significant attention due to their ever-growing applications in a wide variety of fields such as liquid crystal display (LCD) technology, materials science and bioscience. In recent years, along with the developments of materials at the nanoscale, doping LCs with nanoparticles (NPs) has emerged as a very promising approach for improving LC properties. Nanoparticle additives can introduce novel effects on optical and electro-optical properties of nematic liquid crystals (N-LCs), such as altered molecular alignment, faster response time and increased efficiency. This thesis studies the impacts that the inclusion of metallic NPs made of gold or semiconductor CdSe quantum dots (QDs), have on optical and electro-optical properties of N-LCs. Using polarized optical microscopy and detailed capacitance and transmittance measurements of nematic mixtures in electro-optic test cells, characteristics such as optical texture, phase transition temperatures, switching voltages and dielectric anisotropy are investigated in pure as well as doped samples. Surface ligands in NPs and their chemical functionalization play an important role in the LC-NP interactions, largely by determining the dispersibility of NPs and stability of the nanocomposites. One important objective of this thesis is to investigate and prepare a series of gold nanoparticles (Au NPs) with specially formulated robust coatings that maximizes solubility and stability in LC medium. Silanization of NPs is developed as a method to overcome the stability challenge. The functionalization of silanized NPs with aliphatic ligands or liquid crystalline molecules, provides chemically and thermally stable NPs with hydrophobic and structurally compatible surfaces required for dispersion in N-LCs. After complete characterization the synthesized particles are used to make the new nematic nanocomposites. By analysis of the structure-property relationships governing LC-nanomaterial composites and by comparison of new results and data from previous studies on other types of NPs, this thesis will further reveal the mechanism of the interrelations between host LC molecules and NP, considering the role of variables such as core composition, size and surface chemistry of NPs (e.g. siloxane shell, aliphatic ligand vs. liquid crystalline ligand) in achieving stable LC composites with desired optical and electro-optical properties.

Nematic

Liquid Crystals

Nanoparticles

Nanocomposite

Colloidal Dispersion

Electro-optical

Silanized Gold Nanoparticles

Quantum Dots

PARTIALLY FLUORINATED POLYCYCLIC AROMATIC COMPOUNDS: SYNTHESIS AND SUPRAMOLECULAR BEHAVIOR

Cho, Don Mark

01 January 2007

The field of organic electronics has received much attention over the last few years, and engineering of organic crystals to grow with pi-electron systems arranged in a face-to-face motif has been shown to be beneficial in electronic devices. The effects of combining aromatic and perfluorinated aromatic derivatives have shown that the intramolecular stacking pattern can be changed from an edge-to-face arrangement to that of a face-to-face motif. Before the work described herein, there were no reported studies of the supramolecular behavior of fused polycyclic aromatic compounds with partial peripheral fluorination, inducing the desired face-to-face behavior. This is the main focus of the thesis. Furthermore, by exploiting the interactions between the fluorinated and non-fluorinated faces of the molecule, columnar liquid crystalline behavior can be achieved through variations of the alkyl substituents on the molecule.

Polarised photoselection and molecular dynamics in liquid crystals and proteins

Bryant, Jason

January 2000

No description available.

535

Guided mode studies of smectic liquid crystals

Hodder, Benjamin

January 2000

No description available.

530.41

The mathematics of instabilities in smectic C liquid crystals

Anderson, David Alexander

January 2001

No description available.

530.41

Toroidal droplets: instabilities, stabilizing and nematic order

Pairam, Ekapop

22 May 2014

The goal of this thesis is to study the ground or metastable state structure of nematic liquid crystal systems confined inside handled shapes such as a torus or double torus. We begin our work by introducing a new method to generate a toroidal droplet from a Newtonian liquid inside another, immiscible, Newtonian liquid. In this situation, a toroidal droplet is unstable and follows one of two routes in transforming into a spherical droplet: (i) its tube breaks in a way reminiscent to the breakup of a cylindrical jet, or (ii) its tube grows until it finally coalesces onto itself. However, to be able to probe the nematic structure, we need to address the issue of instabilities. This is done by replacing the outer liquid with a yield stress material, which ultimately leads to the stabilization of the toroidal droplet. Through the experimental investigation, we are able to establish the stabilization conditions. Finally, we generate and stabilize toroidal droplets with a nematic liquid crystal as the inner liquid and a yield stress material as the outer medium. Here we observe that in the ground state, the nematic liquid crystal exhibits an intriguing twisted structure irrespective of the aspect ratio of the torus. While there are no defects observed in a toroidal droplet case, two defects with -1 topological charge each emerge each time we increase the number of handles.

Toroidal droplet

Nematicliquid crystal

Nematic liquid crystals

Torus (Geometry)

Surfaces

Newtonian fluids

Integrative Chemistry based morphosyntheses of hierarchical composite materials for photovoltaic, photocatalysis and photoluminescence applications

Kinadjian, Natacha Monique Frédérique

January 2014

The shaping of functional materials and the control of their texture at all length scales are sine qua non conditions for the improvement of current systems. This PhD project consists in creating complex solid architectures using interdisciplinary methods such as sol-gel chemistry or complex fluids physics. Therefore, it is possible to synthesize Titanium Dioxide macroscopic fibers or films which possess a hierarchical porosity. This organization allows the optimization of the matter transport (liquid/gaz) for air depollution application (photocatalysis) or dye-sensitized solar cells. In another project, we were able to control the alignment of zinc oxide nanorods within a macroscopic fiber. This alignment provides to the fiber an anisotropic photoluminescence behavior which can be useful for switching devices application. Finally, we synthesized anisotropic particles and nano-sheets of polypyrrole (conducting polymer) in order to obtain smooth thin films presenting interesting electrical properties. The objective was to use them as electrolyte and/or electrode in dye-sensitized solar cells.

sol-gel

titanium dioxide

zinc oxide

material shaping

fibers

liquid crystals

integrative chemistry

polypyrrole

Physical properties of smectic C liquid crystal cells

Dunn, Paul Edward

January 1998

No description available.

530.41

Computational simulation of dynamics of nematic liquid crystals in the presence of nanoparticles and biological macromolecules

Wu, Huangli.

January 2006

Thesis (M.S.) -- Mississippi State University. Computational Engineering. / Title from title screen. Includes bibliographical references.