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Tine Porenta
Mentor: prof. dr. Slobodan Žumer
Januar 2010
Seminar
Introduction in liquid crystals
Basics of flexoelectricity
Theory
Numerical method
Radial nematic-filled sphere
Radial nematic-filled sphere with point-like defect
Radial nematic-filled sphere with hedgehog defect
Conclusion
Introduction in liquid crystals
Materials with properties most useful for different
applications in the modern world
Liquid oily materials made of rigid organic molecules
In proper temperature region they can self orginise and
form a mesophases between the liquid and solid state
Mesophases are characterized by orientational and
positional order of the molecules
Nematic phase is the least ordered phase influenced only
by long-range order but no positional order.
Long-range order is the phenomenon that makes liquid
crystal unique
They are typically highly responsive to external fields
In confined geometries opposing
orientational ordering of different surfaces
can lead to formation of regions, where
orientation is undefined -> defects.
Defects can be either point-like or lines.
The average of the molecules are described as
a director n. Director is aporal, meaning the
orientation n an –n are equivalent.
Degree of order: Orientational fluctuations of
the molecules are defined as an ensemble
average of the second Legendre polynomials
S = <P2(cos )>
The director and the nematic degree of order can be joint
together in a single tensorial order parameter defined as
S
Qij (3ni n j ij )
2
By definition Qij is symmetric and traceless. Its largest
eigenvalue is nematic degree of order S and the
corresponding eigenvector is the director n
Phenomenological Landau – de Gennes (LdG) total free
energy is used to incorporate liquid crystal elasticity and
possible formation of defects:
1 Qij Qij
dV
F L
2 xk xk
LC
1
1
1
2
AQijQ ji BQijQ jk Qki C QijQ ji dV
2
3
4
LC
Elastic deformation modes:
(a) splay, (b) twist and (c) bend
Electric field couples with nematic through a dielectric
interaction with induced dipoles of the nematic molecules.
Within the LdG framework, the electric coupling is
introduced as an additional free energy density
contribution
1
Fd 0 ij Ei E j dV
2 LC
where ij is defined as
1
2
ij 2 || ij || Qij
3
3S
|| and are dielectric constant measured parallel and
perpendicular to the nematic director
From piezoelectricity to flexoelectricity
Piezoelectricity is the ability of some materials to generate
an electric field or electric potential in response to applied
mechanical stress.
The effect is closely related to a change of polarization
density within the material's volume.
The internal stress in this materials is proportional to
electric field inside.
Stress tensor is defined as
F
ij
u
ij
T , E
1 ui u j
uij
2 x j xi
T , E
Electric displacement field is then
Di Di ij E j i, jk ij
0
where i,jk tensor rank three with symmetry i,jk = i,kj .
If tensor is known, piezoelectric properties are entirely
determined
In liquid crystals exist phenomenon similar to
piezoelectricity that occurs from the deformation of
director filed
Di ij Ei e1n( n) e3 (( n) n)
wiht coefficients e1, e3 10-11 As/m
Polarisation induced by splay and bent deformation
The total macroscopic polarisation induced by
deformation of liquid crystal is introduced by using a
nematic degree of order
Qij
Pi Gijkl
xl
where Gijkl is a general fourth rank coupling tensor,
which incorporates flexoelectric coefficients e1 and e3
For simplicity -> one constant approximation Gijkl=G
The corresponding free energy:
Qij
E j dV
F G
xi
LC
Numerical method
Numeric relaxation method was developed to calculate
the effect of flexoelectricity
Electric potential and the profile of the nematic order
parameter tensor are alternatively computed, until
converged to the stable or metastable solutions
Cubic mesh with resolution of 10 nm
Strong anchoring on boundaries is assumed
The total free energy is
Electric potential is
miminized by using EulerLagrange algorithm
calculated from Maxwell’s
equations in an anisotropic
medium
1 Qij Qij
dV
F L
2 xk xk
LC
1
1
1
2
AQ
Q
BQ
Q
Q
C
Q
Q
dV
ij
ji
ij
jk
ki
ij
ji
LC 2
3
4
1
dV
0 ij
2 LC
xi x j
Qij
dV
G
xi x j
LC
2
Qij
0 ij
G
0
xi
x j
xi x j
1
2
ij 2 || ij || Qij
3
3S
Scheme:
Nematic and dielectric constants A, B, C, L, || and
are taken.
Radial nematic-filled sphere
Effect of the flexoelectricity are typically small in the
absence of the external fields (Fflex < 1% Ftotal), but in
some geometries like nematic filled sphere can
become substantial importance.
Radial nematic-filled sphere with point-like defect
existance of analytical solution of flexoelectric quantities
for isotropic medium
only splay deformation of a director field
director field can be represented in spherical coordinate
system as n=(1,0,0)
Pflex e1n ( n )
1 r 2
e1 (1,0,0) 2
r r
2e1
,0,0
r
( 0 E ) Pflex
0 E Pflex C
2e1
E
,0,0
r 0
Flexoelectric contribution to the total free energy
Fflex Pflex EdV
V
16e12 R
0
Radial nematic-filled sphere with hedgehog defect
Electric potential induced by flexoelectricity affects
the nematic profile, primarily in the core region of the
defects.
(a)Electric field induced by flexoelectricity and spatial
distribution of elastic (b), dielectric (c) and
flexoelectric (d) contribution to the
total free energy
Conclusion
Coupled numerical method was developed for the study of
flexoelectricity in nematic liquid crystals to show us that
flexoelectricity induces substantial electric potential in the
regions surrounding the defects
Flexoelectricity affects defect cores and changes their size
Flexoelectricity could change stability of defect
configurations in confined geometries
Flexoelectric contribution to the total free energy has
quadratic dependence on flexoelectric coefficient and
could become important factor for materials with high
flexoelectric coefficients