Abstract
Electro-optical cell based on the cholesteric liquid crystal is studied with unique combination of the boundary conditions: conical anchoring on the one substrate and planar anchoring on another one. Periodic structures in cholesteric layer and their transformation under applied electric field are considered by polarizing optical microscopy, the experimental findings are supported by the data of the calculations performed using the extended Frank elastic continuum approach. Such structures are the set of alternating over- and under-twisted defect lines whose azimuthal director angles differ by 180^circ. The U^+ and U^--defects of periodicity, which are the smooth transition between the defect lines, are observed at the edge of electrode area. The growth direction of defect lines forming a diffraction grating can be controlled by applying a voltage in the range of 0le , V le 1.3 V during the process. Resulting orientation and distance between the lines don’t change under voltage. However, at V>1.3 V U^+-defects move along the defect lines away from the electrode edges, and, finally, the grating lines collapse at the cell’s center. These results open a way for the use of such cholesteric material in applications with periodic defect structures where a periodicity, orientation, and configuration of defects should be adjusted.
Highlights
Electro-optical cell based on the cholesteric liquid crystal is studied with unique combination of the boundary conditions: conical anchoring on the one substrate and planar anchoring on another one
We have considered Cholesteric liquid crystals (CLCs)-filled sandwich-like cells of thickness d = 5.0 μ m consisting of two glass substrates with transparent ITO electrodes coated with polymer films (Fig. 1a)
The top substrate was covered by the poly(isobutyl methacrylate) (PiBMA) film without additional treatment after the deposition process, which results in conical boundary conditions with the tilt angle θ0 ∼= 50◦40,41
Summary
Electro-optical cell based on the cholesteric liquid crystal is studied with unique combination of the boundary conditions: conical anchoring on the one substrate and planar anchoring on another one. Cholesteric liquid crystals (CLCs) form helicoidal orientational structure at equilibrium, which results in a variety of possible director configurations and corresponding unique optical properties of materials based on them[1,2,3,4,5]. It allows using CLCs in controllable r eflectors6,7, shutters[8,9,10], diffraction and holographic gratings[11,12,13,14,15], tunable lasers[16,17], etc.
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