An electronic device may be provided with a display and other electrical components. The display may be covered with a display cover layer. A rear housing member, the display cover layer, and other structures in the device may be formed from a transparent member. Transparent members in the device may be covered with layers such as layers of ink. The ink may have a polymer with colorant such as dye or pigment. Light-scattering particles such as inorganic dielectric particles may be incorporated into the polymer. The inorganic dielectric particles may have cores formed from materials such as titanium dioxide and coatings that help prevent discoloration of the titanium dioxide and degradation of surrounding polymer when the inorganic dielectric particles are exposed to ultraviolet light.

A display apparatus includes a window member, a display module, and a photocured adhesive layer. The window member includes a base member and a bezel layer overlapping a partial region of a rear surface of the base member, the bezel layer including a photosensitive material having a reduced transmittance with an increased amount of irradiated light. The display module is disposed on the lower side of the window module. The photocured adhesive layer is configured to bind the window member to the display module, and overlaps with the bezel layer on a plane.

An optically anisotropic layered body including a first optically anisotropic layer and a second optically anisotropic layer, wherein each of refractive indices of the second optically anisotropic layer, in-plane retardations of the first optically anisotropic layer, thickness direction retardations of the second optically anisotropic layer, in-plane retardations of the optically anisotropic layered body, NZ factors of the optically anisotropic layered body, and thickness direction retardations Rth of the optically anisotropic layered body satisfies specific relationships.

The optical multilayer film, which comprises a laminate in which a base layer, a primer layer, and a hard coat layer are sequentially laminated, has enhanced mechanical properties while preventing rainbow stains and a reduction in the visibility by adjusting the in-plane retardation of the base layer and the refractive indices of the respective layers. Thus, the optical component and the display device, which comprise the optical multilayer film, have excellent optical characteristics and can operate normally even in harsh environments.

An optical laminate has thin glass having a thickness equal to or smaller than 120 m and a cushioning layer which is disposed on one side of the thin glass and has a thickness equal to or greater than 5 m, in which the cushioning layer has a peak of tan within a range of 10.sup.1 to 10.sup.15 Hz at 25 C.

A spacing pad with water absorption function for liquid crystal panel comprises a first buffer layer, a second buffer layer disposed opposite to the first buffer layer, and a water absorption layer disposed between the first buffer layer and the second buffer layer. The first buffer layer is formed with multiple first water absorption holes thereon for exposing the water absorption layer, and the second buffer layer is formed with multiple second water absorption holes thereon for exposing the water absorption layer. The first buffer layer, the water absorption layer and the second buffer layer of the spacing pad with water absorption function for liquid crystal panel are arranged in a stacked structure, and the first buffer layer and the second buffer layer are made with water absorption holes thereon, for providing the spacing pad with buffer effect and at the same time able to absorb the water on the liquid crystal panel.

Provided is a display device including a film structure having excellent flexibility and moisture infiltration prevention effects via a structure including a first polymer and a second polymer in which an inorganic compound penetrates into the first polymer. The display device may have excellent durability without causing problems such as peeling off of a sealing layer and moisture infiltration even after the display device is repeatedly stretched.

A flexible display device including: a flexible display panel displaying an image; a touch sensing layer provided on the flexible display panel; and a window provided on the touch sensing layer and including a flat area and a bending area. The window includes a flexible film and a hard coating film provided on the flexible film, the thicknesses of the flexible film in the flat area and the bending area differ, and the thicknesses of the hard coating film in the flat area and the bending area also differ.

A flexible liquid crystal film using a fiber-based foldable transparent electrode and a method of fabricating the same are provided. A flexible liquid crystal film using a fiber-based foldable transparent electrode according to an exemplary embodiment of the present disclosure, the flexible liquid crystal film includes: a pair of fiber-based foldable transparent electrodes in which a nanofiber transparent thin film formed of a polymer and a Nylon-6 nanofiber is coated with a silver (Ag) nanowire; and a dispersed liquid crystal formed by being cured between the pair of fiber-based foldable transparent electrodes.

A liquid crystal light-adjusting film includes a polymer material substrate and a plurality of elliptical crystal cells. The polymer material substrate has a light incident surface and a light exiting surface opposite to each other. A direction from the light incident surface to the light exiting surface is a thickness direction of the polymer material substrate. The elliptical crystal cells are disposed in the polymer material substrate. A long axis direction of each of the elliptical crystal cells is arranged along a first direction perpendicular to the thickness direction, and each of the elliptical crystal cells comprises a plurality of liquid crystal molecules. A manufacturing method of the liquid crystal light-adjusting film and a backlight module using the liquid crystal light-adjusting film are also provided.