Yu. P. Bobylev scite author profile

The insulating layers used for the alignment of ferroelectric liquid crystals (FLC) in electro-optical cells usually have non-negligible thickness and their capacitance determines the type of the director switching caused by a triangular-form external voltage U(tr) . With decreasing frequency of U(tr) , the hysteresis in a switching direction changes from the normal to the abnormal one at a characteristic hysteresis inversion frequency f(i) . In the vicinity of f(i) , the electro-optical response is thresholdless and the optical transmission manifests the V -shape field dependence. The V -shape regime is very interesting for certain applications, in particular to microdisplays due to a possibility of the gray scale realization. However, f(i) has to be enhanced from the usually observed frequency of a few Hz up to the range of hundreds of Hz. To this effect, a special FLC material has been designed and its basic properties (tilt angle, spontaneous polarization, rotational viscosity, and electric conductivity) have been measured over the entire range of the smectic-C* phase. Upon variation of cell parameters (thickness of both the FLC and alignment layers), temperature, and external voltage, the frequency of the V -shape effect as high as 150-1000 Hz (in the temperature range 30-75 degrees C) has been found experimentally. The operating voltage remains lower than 8 V. A quantitative interpretation of these results has been done using the modeling procedure developed earlier [S.P. Palto, Cryst. Rep. 48, 124 (2003)]. The modeling has been performed with the experimental values of the FLC material and the cell parameters and has shown very good agreement with experiment. The key point of this approach is consideration of the internal voltage on the FLC layer, the sign, amplitude, and form of which differ from U(tr) . The results of the modeling allow further improvement of the performance of electro-optical FLC cells for high frequency V-shape effect.

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Electric-field-controllable light scattering in helicoidal ferroelectric liquid crystals

Andreev

Andreeva

Kompanets

et al. 2010

J. Opt. Technol.

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11.1: Invited Paper: Ferroelectric Liquid Crystals as a Material for Volumetric Displays

Andreev

Bobylev

Fedosenkova

et al. 2005

SID Symposium Digest

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Three types of electrically controlled light scattering distinguished on the physical mechanism were studied in monomeric FLC compositions at different boundary conditions and electrical pulse regimes. The total time of scattering switching on and switching off was less than 150, 250 and 500 us for different scattering types. They are rather fast to be used in a volumetric screen based on a stack of 30-100 light-scattering shutters.

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Yu. P. Bobylev

Threshold Flexoelectric Effect in Nematic Liquid Crystal

Electric-field-controlled light scattering in ferroelectric liquid crystals

High frequency hysteresis-free switching in thin layers of smectic-C*ferroelectric liquid crystals

Electric-field-controllable light scattering in helicoidal ferroelectric liquid crystals

11.1: Invited Paper: Ferroelectric Liquid Crystals as a Material for Volumetric Displays

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