trunk/tengDissertation/LiquidCrystal.tex

\chapter{\label{chapt:liquidcrystal}LIQUID CRYSTAL}

\section{\label{liquidCrystalSection:introduction}Introduction}

Long range orientational order is one of the most fundamental
properties of liquid crystal mesophases. This orientational
anisotropy of the macroscopic phases originates in the shape
anisotropy of the constituent molecules. Among these anisotropy
mesogens, rod-like (calamitic) and disk-like molecules have been
exploited in great detail in the last two decades. Typically, these
mesogens consist of a rigid aromatic core and one or more attached
aliphatic chains. For short chain molecules, only nematic phases, in
which positional order is limited or absent, can be observed,
because the entropy of mixing different parts of the mesogens is
paramount to the dispersion interaction. In contrast, formation of
the one dimension lamellar sematic phase in rod-like molecules with
sufficiently long aliphatic chains has been reported, as well as the
segregation phenomena in disk-like molecules.

Recently, the banana-shaped or bent-core liquid crystal have became
one of the most active research areas in mesogenic materials and
supramolecular chemistry. Unlike rods and disks, the polarity and
biaxiality of the banana-shaped molecules allow the molecules
organize into a variety of novel liquid crystalline phases which
show interesting material properties. Of particular interest is the
spontaneous formation of macroscopic chiral layers from achiral
banana-shaped molecules, where polar molecule orientational ordering
is shown within the layer plane as well as the tilted arrangement of
the molecules relative to the polar axis. As a consequence of
supramolecular chirality, the spontaneous polarization arises in
ferroelectric (FE) and antiferroelectic (AF) switching of smectic
liquid crystal phases, demonstrating some promising applications in
second-order nonlinear optical devices. The most widely investigated
mesophase formed by banana-shaped moleculed is the $\text{B}_2$
phase, which is also referred to as $\text{SmCP}$. Of the most
important discover in this tilt lamellar phase is the four distinct
packing arrangements (two conglomerates and two macroscopic
racemates), which depend on the tilt direction and the polar
direction of the molecule in adjacent layer (see
Fig.~\cite{LCFig:SMCP}).

\begin{figure}
\centering
\includegraphics[width=\linewidth]{smcp.eps}
\caption[]
{}
\label{LCFig:SMCP}
\end{figure}

Many liquid crystal synthesis experiments suggest that the
occurrence of polarity and chirality strongly relies on the
molecular structure and intermolecular interaction. From a
theoretical point of view, it is of fundamental interest to study
the structural properties of liquid crystal phases formed by
banana-shaped molecules and understand their connection to the
molecular structure, especially with respect to the spontaneous
achiral symmetry breaking. As a complementary tool to experiment,
computer simulation can provide unique insight into molecular
ordering and phase behavior, and hence improve the development of
new experiments and theories. In the last two decades, all-atom
models have been adopted to investigate the structural properties of
smectic arrangements\cite{Cook2000, Lansac2001}, as well as other
bulk properties, such as rotational viscosity and flexoelectric
coefficients\cite{Cheung2002, Cheung2004}. However, due to the
limitation of time scale required for phase
transition\cite{Wilson1999} and the length scale required for
representing bulk behavior, the dominant models in the field of
liquid crystal phase behavior are generic
models\cite{Lebwohl1972,Perram1984, Gay1981}, which are based on the
observation that liquid crystal order is exhibited by a range of
non-molecular bodies with high shape anisotropies. Previous
simulation studies using hard spherocylinder dimer
model\cite{Camp1999} produce nematic phases, while hard rod
simulation studies identified a Landau point\cite{Bates2005}, at
which the isotropic phase undergoes a direct transition to the
biaxial nematic, as well as some possible liquid crystal
phases\cite{Lansac2003}. Other anisotropic models using
Gay-Berne(GB) potential, which produce interactions that favor local
alignment, give the evidence of the novel packing arrangements of
bent-core molecules\cite{Memmer2002,Orlandi2006}.

Experimental studies by Levelut {\it et al.}~\cite{Levelut1981}
revealed that terminal cyano or nitro groups usually induce
permanent longitudinal dipole moments, which affect the phase
behavior considerably. A series of theoretical studies also drawn
equivalent conclusions. Monte Carlo studies of the GB potential with
fixed longitudinal dipoles (i.e. pointed along the principal axis of
rotation) were shown to enhance smectic phase
stability~\cite{Berardi1996,Satoh1996}. Molecular simulation of GB
ellipsoids with transverse dipoles at the terminus of the molecule
also demonstrated that partial striped bilayer structures were
developed from the smectic phase ~\cite{Berardi1996}. More
significant effects have been shown by including multiple
electrostatic moments. Adding longitudinal point quadrupole moments
to rod-shaped GB mesogens, Withers \textit{et al} induced tilted
smectic behaviour in the molecular system~\cite{Withers2003}. Thus,
it is clear that many liquid-crystal forming molecules, specially,
bent-core molecules, could be modeled more accurately by
incorporating electrostatic interaction.

In this chapter, we consider system consisting of banana-shaped
molecule represented by three rigid GB particles with one or two
point dipoles at different location. Performing a series of
molecular dynamics simulations, we explore the structural properties
of tilted smectic phases as well as the effect of electrostatic
interactions.

\section{\label{liquidCrystalSection:model}Model}

A typical banana-shaped molecule consists of a rigid aromatic
central bent unit with several rod-like wings which are held
together by some linking units and terminal chains (see
Fig.~\ref{LCFig:BananaMolecule}). In this work, each banana-shaped
mesogen has been modeled as a rigid body consisting of three
equivalent prolate ellipsoidal GB particles. The GB interaction
potential used to mimic the apolar characteristics of liquid crystal
molecules takes the familiar form of Lennard-Jones function with
orientation and position dependent range ($\sigma$) and well depth
($\epsilon$) parameters. It can can be expressed as,
\begin{equation}
V_{ij}^{GB}  = 4\epsilon (\hat u_i ,\hat u_j ,\hat r_{ij} )\left[
{\left( {\frac{{\sigma _0 }}{{r_{ij}  - \sigma (\hat u_i ,\hat u_j
,\hat r_{ij} )}}} \right)^{12}  - \left( {\frac{{\sigma _0
}}{{r_{ij}  - \sigma (\hat u_i ,\hat u_j ,\hat r_{ij} )}}} \right)^6
} \right] \label{LCEquation:gb}
\end{equation}
where $\hat u_i,\hat u_j$ are unit vectors specifying the
orientation of two molecules $i$ and $j$ separated by intermolecular
vector $r_{ij}$. $\hat r_{ij}$ is the unit vector along the
intermolecular vector. A schematic diagram of the orientation
vectors is shown in Fig.\ref{LCFigure:GBScheme}. The functional form
for $\sigma$ is given by
\begin{equation}
\sigma (\hat u_i ,\hat u_i ,\hat r_{ij} ) = \sigma _0 \left[ {1 -
\frac{\chi }{2}\left( {\frac{{(\hat r_{ij}  \cdot \hat u_i  + \hat
r_{ij}  \cdot \hat u_j )^2 }}{{1 + \chi \hat u_i  \cdot \hat u_j }}
+ \frac{{(\hat r_{ij}  \cdot \hat u_i  - \hat r_{ij}  \cdot \hat u_j
)^2 }}{{1 - \chi \hat u_i  \cdot \hat u_j }}} \right)} \right]^{ -
\frac{1}{2}},
\end{equation}
where the aspect ratio of the particles is governed by shape
anisotropy parameter
\begin{equation}
\chi  = \frac{{(\sigma _e /\sigma _s )^2  - 1}}{{(\sigma _e /\sigma
_s )^2  + 1}}.
\label{LCEquation:chi}
\end{equation}
Here, $\sigma_ s$ and $\sigma_{e}$ refer to the side-by-side breadth
and the end-to-end length of the ellipsoid, respectively. Twell
depth parameters takes the form
\begin{equation}
\epsilon (\hat u_i ,\hat u_j ,\hat r_{ij} ) = \epsilon _0 \epsilon
^v (\hat u_i ,\hat u_j )\epsilon '^\mu (\hat u_i ,\hat u_j ,\hat
r_{ij} )
\end{equation}
where $\epsilon_{0}$ is a constant term and
\begin{equation}
\epsilon (\hat u_i ,\hat u_j ) = \frac{1}{{\sqrt {1 - \chi ^2 (\hat
u_i  \cdot \hat u_j )^2 } }}
\end{equation}
and
\begin{equation}
\epsilon '(\hat u_i ,\hat u_j ,\hat r_{ij} ) = 1 - \frac{{\chi
'}}{2}\left[ {\frac{{(\hat r_{ij}  \cdot \hat u_i  + \hat r_{ij}
\cdot \hat u_j )^2 }}{{1 + \chi '\hat u_i  \cdot \hat u_j }} +
\frac{{(\hat r_{ij}  \cdot \hat u_i  - \hat r_{ij}  \cdot \hat u_j
)^2 }}{{1 - \chi '\hat u_i  \cdot \hat u_j }}} \right]
\end{equation}
where the well depth anisotropy parameter $\chi '$ depends on the
ratio between \textit{end-to-end} well depth $\epsilon _e$ and
\textit{side-by-side} well depth $\epsilon_s$,
\begin{eqaution}
\chi ' = \frac{{1 - (\epsilon _e /\epsilon _s )^{1/\mu} }}{{1 +
(\epsilon _e /\epsilon _s )^{1/\mu} }}.
\end{equation}

\begin{figure}
\centering
\includegraphics[width=\linewidth]{banana.eps}
\caption[]{} \label{LCFig:BananaMolecule}
\end{figure}

\begin{figure}
\centering
\includegraphics[width=\linewidth]{bananGB_grained.eps}
\caption[]{} \label{LCFigure:BananaGB}
\end{figure}

\begin{figure}
\centering
\includegraphics[width=\linewidth]{gb_scheme.eps}
\caption[]{Schematic diagram showing definitions of the orientation
vectors for a pair of Gay-Berne molecules}
\label{LCFigure:GBScheme}
\end{figure}

\section{\label{liquidCrystalSection:methods}Methods}

\section{\label{liquidCrystalSection:resultDiscussion}Results and Discussion}
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#	Content
1	\chapter{\label{chapt:liquidcrystal}LIQUID CRYSTAL}
2
3	\section{\label{liquidCrystalSection:introduction}Introduction}
4
5	Long range orientational order is one of the most fundamental
6	properties of liquid crystal mesophases. This orientational
7	anisotropy of the macroscopic phases originates in the shape
8	anisotropy of the constituent molecules. Among these anisotropy
9	mesogens, rod-like (calamitic) and disk-like molecules have been
10	exploited in great detail in the last two decades. Typically, these
11	mesogens consist of a rigid aromatic core and one or more attached
12	aliphatic chains. For short chain molecules, only nematic phases, in
13	which positional order is limited or absent, can be observed,
14	because the entropy of mixing different parts of the mesogens is
15	paramount to the dispersion interaction. In contrast, formation of
16	the one dimension lamellar sematic phase in rod-like molecules with
17	sufficiently long aliphatic chains has been reported, as well as the
18	segregation phenomena in disk-like molecules.
19
20	Recently, the banana-shaped or bent-core liquid crystal have became
21	one of the most active research areas in mesogenic materials and
22	supramolecular chemistry. Unlike rods and disks, the polarity and
23	biaxiality of the banana-shaped molecules allow the molecules
24	organize into a variety of novel liquid crystalline phases which
25	show interesting material properties. Of particular interest is the
26	spontaneous formation of macroscopic chiral layers from achiral
27	banana-shaped molecules, where polar molecule orientational ordering
28	is shown within the layer plane as well as the tilted arrangement of
29	the molecules relative to the polar axis. As a consequence of
30	supramolecular chirality, the spontaneous polarization arises in
31	ferroelectric (FE) and antiferroelectic (AF) switching of smectic
32	liquid crystal phases, demonstrating some promising applications in
33	second-order nonlinear optical devices. The most widely investigated
34	mesophase formed by banana-shaped moleculed is the $\text{B}_2$
35	phase, which is also referred to as $\text{SmCP}$. Of the most
36	important discover in this tilt lamellar phase is the four distinct
37	packing arrangements (two conglomerates and two macroscopic
38	racemates), which depend on the tilt direction and the polar
39	direction of the molecule in adjacent layer (see
40	Fig.~\cite{LCFig:SMCP}).
41
42	\begin{figure}
43	\centering
44	\includegraphics[width=\linewidth]{smcp.eps}
45	\caption[]
46	{}
47	\label{LCFig:SMCP}
48	\end{figure}
49
50	Many liquid crystal synthesis experiments suggest that the
51	occurrence of polarity and chirality strongly relies on the
52	molecular structure and intermolecular interaction. From a
53	theoretical point of view, it is of fundamental interest to study
54	the structural properties of liquid crystal phases formed by
55	banana-shaped molecules and understand their connection to the
56	molecular structure, especially with respect to the spontaneous
57	achiral symmetry breaking. As a complementary tool to experiment,
58	computer simulation can provide unique insight into molecular
59	ordering and phase behavior, and hence improve the development of
60	new experiments and theories. In the last two decades, all-atom
61	models have been adopted to investigate the structural properties of
62	smectic arrangements\cite{Cook2000, Lansac2001}, as well as other
63	bulk properties, such as rotational viscosity and flexoelectric
64	coefficients\cite{Cheung2002, Cheung2004}. However, due to the
65	limitation of time scale required for phase
66	transition\cite{Wilson1999} and the length scale required for
67	representing bulk behavior, the dominant models in the field of
68	liquid crystal phase behavior are generic
69	models\cite{Lebwohl1972,Perram1984, Gay1981}, which are based on the
70	observation that liquid crystal order is exhibited by a range of
71	non-molecular bodies with high shape anisotropies. Previous
72	simulation studies using hard spherocylinder dimer
73	model\cite{Camp1999} produce nematic phases, while hard rod
74	simulation studies identified a Landau point\cite{Bates2005}, at
75	which the isotropic phase undergoes a direct transition to the
76	biaxial nematic, as well as some possible liquid crystal
77	phases\cite{Lansac2003}. Other anisotropic models using
78	Gay-Berne(GB) potential, which produce interactions that favor local
79	alignment, give the evidence of the novel packing arrangements of
80	bent-core molecules\cite{Memmer2002,Orlandi2006}.
81
82	Experimental studies by Levelut {\it et al.}~\cite{Levelut1981}
83	revealed that terminal cyano or nitro groups usually induce
84	permanent longitudinal dipole moments, which affect the phase
85	behavior considerably. A series of theoretical studies also drawn
86	equivalent conclusions. Monte Carlo studies of the GB potential with
87	fixed longitudinal dipoles (i.e. pointed along the principal axis of
88	rotation) were shown to enhance smectic phase
89	stability~\cite{Berardi1996,Satoh1996}. Molecular simulation of GB
90	ellipsoids with transverse dipoles at the terminus of the molecule
91	also demonstrated that partial striped bilayer structures were
92	developed from the smectic phase ~\cite{Berardi1996}. More
93	significant effects have been shown by including multiple
94	electrostatic moments. Adding longitudinal point quadrupole moments
95	to rod-shaped GB mesogens, Withers \textit{et al} induced tilted
96	smectic behaviour in the molecular system~\cite{Withers2003}. Thus,
97	it is clear that many liquid-crystal forming molecules, specially,
98	bent-core molecules, could be modeled more accurately by
99	incorporating electrostatic interaction.
100
101	In this chapter, we consider system consisting of banana-shaped
102	molecule represented by three rigid GB particles with one or two
103	point dipoles at different location. Performing a series of
104	molecular dynamics simulations, we explore the structural properties
105	of tilted smectic phases as well as the effect of electrostatic
106	interactions.
107
108	\section{\label{liquidCrystalSection:model}Model}
109
110	A typical banana-shaped molecule consists of a rigid aromatic
111	central bent unit with several rod-like wings which are held
112	together by some linking units and terminal chains (see
113	Fig.~\ref{LCFig:BananaMolecule}). In this work, each banana-shaped
114	mesogen has been modeled as a rigid body consisting of three
115	equivalent prolate ellipsoidal GB particles. The GB interaction
116	potential used to mimic the apolar characteristics of liquid crystal
117	molecules takes the familiar form of Lennard-Jones function with
118	orientation and position dependent range ($\sigma$) and well depth
119	($\epsilon$) parameters. It can can be expressed as,
120	\begin{equation}
121	V_{ij}^{GB} = 4\epsilon (\hat u_i ,\hat u_j ,\hat r_{ij} )\left[
122	{\left( {\frac{{\sigma _0 }}{{r_{ij} - \sigma (\hat u_i ,\hat u_j
123	,\hat r_{ij} )}}} \right)^{12} - \left( {\frac{{\sigma _0
124	}}{{r_{ij} - \sigma (\hat u_i ,\hat u_j ,\hat r_{ij} )}}} \right)^6
125	} \right] \label{LCEquation:gb}
126	\end{equation}
127	where $\hat u_i,\hat u_j$ are unit vectors specifying the
128	orientation of two molecules $i$ and $j$ separated by intermolecular
129	vector $r_{ij}$. $\hat r_{ij}$ is the unit vector along the
130	intermolecular vector. A schematic diagram of the orientation
131	vectors is shown in Fig.\ref{LCFigure:GBScheme}. The functional form
132	for $\sigma$ is given by
133	\begin{equation}
134	\sigma (\hat u_i ,\hat u_i ,\hat r_{ij} ) = \sigma _0 \left[ {1 -
135	\frac{\chi }{2}\left( {\frac{{(\hat r_{ij} \cdot \hat u_i + \hat
136	r_{ij} \cdot \hat u_j )^2 }}{{1 + \chi \hat u_i \cdot \hat u_j }}
137	+ \frac{{(\hat r_{ij} \cdot \hat u_i - \hat r_{ij} \cdot \hat u_j
138	)^2 }}{{1 - \chi \hat u_i \cdot \hat u_j }}} \right)} \right]^{ -
139	\frac{1}{2}},
140	\end{equation}
141	where the aspect ratio of the particles is governed by shape
142	anisotropy parameter
143	\begin{equation}
144	\chi = \frac{{(\sigma _e /\sigma _s )^2 - 1}}{{(\sigma _e /\sigma
145	_s )^2 + 1}}.
146	\label{LCEquation:chi}
147	\end{equation}
148	Here, $\sigma_ s$ and $\sigma_{e}$ refer to the side-by-side breadth
149	and the end-to-end length of the ellipsoid, respectively. Twell
150	depth parameters takes the form
151	\begin{equation}
152	\epsilon (\hat u_i ,\hat u_j ,\hat r_{ij} ) = \epsilon _0 \epsilon
153	^v (\hat u_i ,\hat u_j )\epsilon '^\mu (\hat u_i ,\hat u_j ,\hat
154	r_{ij} )
155	\end{equation}
156	where $\epsilon_{0}$ is a constant term and
157	\begin{equation}
158	\epsilon (\hat u_i ,\hat u_j ) = \frac{1}{{\sqrt {1 - \chi ^2 (\hat
159	u_i \cdot \hat u_j )^2 } }}
160	\end{equation}
161	and
162	\begin{equation}
163	\epsilon '(\hat u_i ,\hat u_j ,\hat r_{ij} ) = 1 - \frac{{\chi
164	'}}{2}\left[ {\frac{{(\hat r_{ij} \cdot \hat u_i + \hat r_{ij}
165	\cdot \hat u_j )^2 }}{{1 + \chi '\hat u_i \cdot \hat u_j }} +
166	\frac{{(\hat r_{ij} \cdot \hat u_i - \hat r_{ij} \cdot \hat u_j
167	)^2 }}{{1 - \chi '\hat u_i \cdot \hat u_j }}} \right]
168	\end{equation}
169	where the well depth anisotropy parameter $\chi '$ depends on the
170	ratio between \textit{end-to-end} well depth $\epsilon _e$ and
171	\textit{side-by-side} well depth $\epsilon_s$,
172	\begin{eqaution}
173	\chi ' = \frac{{1 - (\epsilon _e /\epsilon _s )^{1/\mu} }}{{1 +
174	(\epsilon _e /\epsilon _s )^{1/\mu} }}.
175	\end{equation}
176
177	\begin{figure}
178	\centering
179	\includegraphics[width=\linewidth]{banana.eps}
180	\caption[]{} \label{LCFig:BananaMolecule}
181	\end{figure}
182
183	\begin{figure}
184	\centering
185	\includegraphics[width=\linewidth]{bananGB_grained.eps}
186	\caption[]{} \label{LCFigure:BananaGB}
187	\end{figure}
188
189	\begin{figure}
190	\centering
191	\includegraphics[width=\linewidth]{gb_scheme.eps}
192	\caption[]{Schematic diagram showing definitions of the orientation
193	vectors for a pair of Gay-Berne molecules}
194	\label{LCFigure:GBScheme}
195	\end{figure}
196
197	\section{\label{liquidCrystalSection:methods}Methods}
198
199	\section{\label{liquidCrystalSection:resultDiscussion}Results and Discussion}