Flexoelectricity

The nematic medium does not exhibit spontaneous polarization due to the apolar nature of the director. A macroscopic polarization can be induced in a nematic liquid crystal by splay and bend distortions of the director field. This was first shown by Meyer in 1969. According to Meyer’s model only nematics made of polar molecules with shape anisotropy can be expected to exhibit flexoelectricity. For example, a nematic consisting of pear shaped molecules with longitudinal dipole moments become polarized under splay distortion  and a nematic made of banana shaped molecules with transverse dipole moments becomes polarized under bend distortion. In the undistorted state, the dipole moments of the molecules are oriented with equal probability in opposite directions. They cancel each other and the net dipole density is zero. 

Let a nematic be made of pear or wedge shaped molecules with longitudinal dipole moments [Figure 4.1(a)]. If the system is deformed with splayed director [Figure 4.1(b)], the efficient packing of the molecules generates a net dipole moment, resulting in a macroscopic polarization. A similar type of effect is also observed in a nematic made of banana shaped molecules with transverse dipole moments [Figure 4.2(a)] subjected to a bend distortion [Figure 4.2(b)].

Figure 4.1: A nematic consisting of pear-shaped molecules with longitudinal dipole moments becomes polarized under splay deformation 

Figure 4.2: A  nematic consisting of banana-shaped molecules with transverse dipole molecules becomes polarized under bend distortion

There have been several techniques to measure the flexoelectric coefficients of nematics. Dozov et. al. devised a simple experimental technique using Hybrid Aligned Nematic (HAN) cell. In HAN cell bottom plate is coated for homogeneous alignment and the top plate is coated to get homeotropic alignment. The anchoring at the two surfaces is assumed to be strong. The director field in such a cell has a permanent splay-bend distortion, which generates flexoelectric polarization. Two wire electrodes are used as spacers to apply a field perpendicular to the plane of the distorted director.  At the bottom plate, the director is along the X axis and the tilt angle reduces continuously on moving towards the upper plate where the director is oriented along the Z axis. The tilt angle θ is a function of the coordinate z. If a uniform dc electric field E is applied along the Y axis, a twist distortion is produced in the medium due to the action of E on polarization. Under the action of E, the director continuously twists, getting a component along the Y axis with the twist angle φ also being a function of z.

Figure 4.3: Side view of the HAN cell.Arrow indicates the field direction

Figure 4.4: Side view of the HAN cell. Arrow indicates the field direction and length indicates the strength of field.

Simulation of TN Cell

Figure 3.1: 

Figure 3.1 shows the V-T characteristic of TN cell. The characteristic is changing for various values of K33/K11. Here only K33 is changing and all other parameters including K11 are fixed. Surprisingly  the transmittance (T) is increasing just above the threshold voltage for higher values of K33.

Figure 3.2:

Figure 3.2 is a closer look of Fig 3.1 for better visualization. 

Figure 3.3:

Figure 3.3 shows the gradient of transmittance (dT/dV) as a function of applied voltage for various K33. 

Figure 3.4: Director (θ, φ) profile as a function of unit thickness (z/L) for different applied voltages. K33/K11 = 1.0 is fixed. 

Figure 3.5: dφ/dz as a function of z/L for various applied voltages. K33/K11 = 1.0 is fixed.  

Figure 3.6: Director (θ, φ) profile as a function of unit thickness (z/L) for different applied voltages. K33/K11 = 2.0 is fixed.

Figure 3.7: Director (θ, φ) profile as a function of unit thickness (z/L) for different applied voltages. K33/K11 = 2.50 is fixed.

Figure 3.8: dφ/dz as a function of z/L for various applied voltages. K33/K11 = 2.5 is fixed.

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Now we increase thickness of the TN cell to get the maximum transmittance following Gooch-Tarry condition: Δnd = 0.476 μm for λ = 550 nm. 

Figure 3.9: Red dot indicates the threshold voltage

Figure 3.10:

Figure 3.11: 

Director Deformation of Twisted Nematic Cell

The twisted nematic (TN) display is made up of a nematic liquid crystal which has an optic axis that undergoes a 90° twist, in between two substrates. Each substrate is coated with a conductive transparent electrode, indium tin oxide (ITO), which is then coated by a surfactant that is rubbed parallel to the substrate to create groves for the liquid crystal to align in. The optic axis of the liquid crystal undergoes this twist because the two substrates are placed so the rub directions are at 90° angles to one another. In the normally white (NW) mode of operation the optic axes of the polarizers along each side of the substrate are crossed. It is called normally white because in the unactivated state the display is transparent. In the normally black mode of operation the optic axes of the polarizers are parallel. In the unactivated state the display is black.[1]

Figure 2.1: 

Figure 2.2: 

Figure 2.3: 

Figure 2.4:  

Figure 2.5: 

Figure 2.6: 

Figure 2.7: 

Ref: [1] http://www.lci.kent.edu/boslab/projects/optical_compensation/index.html