Behavior of liquid crystal (LC) is a result of interaction between the geometrical shape restrictions of the adjacent surface and molecular forces among LCs or adjacent surface. For years, continuous efforts have been made to control LC orientation and anchoring with pretilt angle for modulating the electro‐optical characteristics. For now, diverse driving modes have been developed including twisted nematic, optically compensated bend, electrically controlled birefringence, and vertical alignment. However, it has the limitation that different fabrication process should be adopted in different driving mode such as materials of alignment layer and techniques for aligning the LCs. Herein, selective LC modes are achieved by controlling the LC pretilt angle using nanopatterned organic/inorganic hybrid thin films composed of polyimide (PI) and tin oxide (SnO). It is possible to control the surface wettability according to the composition ratio between PI and SnO, thereby adjusting the pretilt angle of the LCs. Fabrication of SnO combined with PI applied via embossing allows for the large‐scale replication for LC alignment and based on consumer demand, devices can be manufactured in various modes through simple configuration changes. Therefore, an inorganic compound combined with an organic one permits designing addressable LC driving modes.
We have developed a very useful and cost-effective liquid crystal (LC) alignment layer of brush-coated TiO2 that is solution-processable for twisted nematic (TN) LC cells. TiO2 was prepared via the sol-gel method. The TiO2 solution was brush-coated on the substrate, followed by an annealing process. During the brush-coating process, a retracting force is generated on the deposited TiO solutions along the coating direction. The annealing process hardens the TiO2 and generates shearing stress arising from the retracting force along the brush-coating direction. The shearing stress created highly oriented nano/microstructure and uniformly aligned LCs with a stable pretilt angle of 0.6°. TN mode LC cells based on brush-coated TiO2 exhibited a performance of 12.5 ms of response and a threshold voltage of 1.8 V. Our brush-coated TiO2 incorporates two steps of the film deposition and alignment process into one step.
We
present a simple and economically convenient method to fabricate
nanopatterned ZnO films by imprinting lithography and use them for
the layer alignment of liquid crystal (LC) displays. First, a one-dimensional
nanopattern was obtained by laser interference lithography on a silicon
wafer, and the silicon mold replica was transferred onto a flexible
polydimethylsiloxane (PDMS) sheet for conformal patterning. The so-obtained
PDMS mold was then applied on a ZnO film spin-coated on a glass substrate.
During the imprinting process, the temperature was controlled from
100 to 250 °C to observe the transferring morphologies of the
ZnO film; the nanopattern was successfully transferred at annealing
temperatures of 200 and 250 °C because the ZnO film at the sol
state filled the cavities of the PDMS nanopattern and solidified,
forming a negative replica of the nanopattern. The direction of the
nanopatterned ZnO film served as a guide for aligning the LC molecules
on the LC surface at the centimeter scale and, due to their elastic
characteristics and group behavior, propagating their directional
states in the LC bulk. The resulting LC cell exhibited an enhanced
electro-optical performance and high thermal endurance above 180 °C.
The geometry of the alignment layer increased the electric field on
the ZnO film and showed reduced threshold voltage. In addition, since
flexible devices are generally based on polyimide, which imidized
at around 200 °C, the relatively low annealing temperatures of
our fabricated nanopatterned ZnO film allow it to be mounted on such
devices without any deterioration of the underlying thermoplastic
substrate. Therefore, nanopatterned ZnO has a considerable potential
for advanced LC displays.
This study uses imprint lithography to produce an anisotropic unidirectional indium gallium oxide (IGO) film for the uniform liquid crystal (LC) alignment layer. The curing temperature was controlled to 110, 180, and 250 °C during the process, and the 250 °C cured film presented a distinct one‐dimensional pattern transferred from the polydimethylsiloxane (PDMS) mold during scanning electron microscopy (SEM). X‐ray photoelectron spectroscopy (XPS) confirmed an active thermal oxidation effect at a high curing temperature, contributing to the formation of a unidirectional structure. This unidirectional IGO structure functioned as a guide for LCs and induced a uniform alignment state, verified by polarized optical microscopy (POM) and a pre‐tilt angle analysis. The IGO film also revealed improved thermal endurance to the LC alignment state and optical transmittance compared with the conventional rubbed polyimide (PI) layer. Given this performance, the one‐dimensional pattern‐imprinted IGO film can be a promising LC alignment layer for an advanced LC system.
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