A method for producing a cholesteric liquid crystal based shell is provided. The method comprises producing a cholesteric liquid crystal shell, solidifying the cholesteric liquid crystal shell so as to obtain a solid shell and perforating the solid shell. Also provided is a cholesteric liquid crystal based solid shell comprising a perforation. A coating composition comprising a plurality of cholesteric liquid crystal based solid shells, an item comprising a tag that comprises the cholesteric liquid crystal based solid shells and a method for authenticating the item are also provided.

An electro-optic modulator is disclosed. The electro-optic modulator includes a modulator material film layer. The modulator material film layer includes a polymer matrix. Liquid crystals and getter molecules are dispersed within the polymer matrix. The liquid crystals are configured to modulate light transmissivity through the electro-optic modulator. The getter molecules capture or coordinate with cationic impurities present within the polymer matrix. By gettering the cationic impurities, switching of the device at modulated low frequencies are improved as well as a reduction on the switching voltage of the device. Three classes of getter molecules have been so far demonstrated to work: inorganic ion traps (dihydrogen ammonium phosphate), organic cation traps (EDTA), and organic ion extractors (nicotinic acid). An amount for the getter molecules may be 0.01 to 1.0 percent by weight of the polymer matrix.

A method of fabricating a liquid crystal device (LCD) minimizes changes to optical properties of an internal RM retarder. In exemplary embodiments, the fabricating method comprises depositing a plurality of layers in an optical stack, the plurality of layers including from a viewing side: a first linear polariser; an external retarder; a colour filter substrate; a colour filter layer; an internal reactive mesogen (RM) retarder alignment layer; an internal reactive mesogen (RM) retarder; a liquid crystal (LC) layer; a thin film transistor (TFT) substrate; and a second linear polarizer. Any layer that is deposited after the internal RM retarder on a non-viewing side relative to the color filter substrate, and in direct contact with the internal RM retarder, has a solvent concentration at deposition of less than 15% of a solvent that can alter optical properties of the internal RM retarder (e.g., less than 15% NMP).

A transparent structure according to an embodiment of the present disclosure includes a first panel and a second panel, wherein the first panel includes: a first electrode; a second electrode separated from the first electrode; and a polymer dispersed liquid crystal layer disposed between the first electrode and the second electrode, the second panel includes: a third electrode; a fourth electrode separated from the third electrode; and a colloid layer disposed between the third electrode and the fourth electrode, the fourth electrode includes multiple openings, and the colloid layer includes charged particles of which surfaces exhibit (+) charge or (?) charge.

The present invention provides a liquid crystal display device and a method of producing the same in which the occurrence of a bright dot at an edge portion of a display region is suppressed during use in a wide temperature range. The liquid crystal display device of the present invention includes: a liquid crystal layer disposed between a first substrate and a second substrate; an alignment film disposed adjacent to the liquid crystal layer of at least one of the first substrate or the second substrate; and a sealing material to achieve adhesion between the first substrate and the second substrate, wherein the liquid crystal layer contains a liquid crystal material, the liquid crystal material contains an alkoxy group-containing liquid crystal compound and exhibits a liquid crystal phase at 10 C. or higher and 80 C. or lower, the sealing material is a cured product of an epoxy resin-containing sealant, and the alignment film includes at least one of a first alignment film including a polymer layer formed using a first alignment agent containing a polyamic acid and a polysiloxane, or a second alignment film including a polymer layer formed using a second alignment agent containing a polyamic acid in which a silane coupling agent is adsorbed onto a surface of the polymer layer.

The present invention relates to compositions for nanoencapsulation which comprise the mesogenic medium as set forth in claim 1, one or more polymerizable compounds and one or more surfactants, to nanocapsules containing the mesogenic medium and to their use in electro-optical devices.

Ink-jet printable compositions including nanoparticles capped with a protective layer of hydrocarbon chains and a single solvent exhibiting a single evaporation rate and having a specifically defined viscosity and surface tension that result in uniform and printable alignment layers for liquid crystal materials. Patterned liquid crystal-containing cells are also disclosed including one or more layers including the same or different nanoparticles capped with a protective layer of hydrocarbon chains printed on a surface of a substrate or even another nanoparticle-containing layer. Methods for producing the cells are also disclosed, including the step of printing a pattern on one or more portions of a cell surface utilizing a composition comprising the capped nanoparticles. Devices including the cells are also disclosed.

Ink-jet printable compositions including nanoparticles capped with a protective layer of hydrocarbon chains and a single solvent exhibiting a single evaporation rate and having a specifically defined viscosity and surface tension that result in uniform and printable alignment layers for liquid crystal materials. Patterned liquid crystal-containing cells are also disclosed including one or more layers including the same or different nanoparticles capped with a protective layer of hydrocarbon chains printed on a surface of a substrate or even another nanoparticle-containing layer. Methods for producing the cells are also disclosed, including the step of printing a pattern on one or more portions of a cell surface utilizing a composition comprising the capped nanoparticles. Devices including the cells are also disclosed.

The present disclosure provides a liquid crystal composition and a method for preparing the same, and a display panel, and the liquid crystal composition comprises a mixture of rod-shaped monomer molecules, a chiral agent, and a mixture of bent molecules, wherein the mixture of bent molecules comprises multiple bent molecules.

A liquid crystal polymer composite is disclosed herein. The liquid crystal polymer composite includes a solvent, a soluble liquid crystal polymer, and an additive. The soluble liquid crystal polymer is dissolved in the solvent. The additive includes an organic polymer or inorganic filler, while the additive is dispersed or dissolved in the solvent.