A display device includes a display panel; a supporter disposed on a surface of the display panel; and an adhesive layer disposed between the supporter and the display panel, wherein the supporter includes metal layers spaced apart from each other; and a cushion layer surrounding the metal layers, the adhesive layer includes a first area overlapping the metal layers in a vertical direction to the display panel; and a second area not overlapping the metal layers in the vertical direction to the display panel, and a modulus of the second area of the adhesive layer is larger than a modulus of the first area of the adhesive layer.

Disclosed herein is a thermal radiation modulation system comprising a first low emissivity layer comprising a plurality of distributed, strain-dependent cracks, the first low emissivity layer comprising a first polymer composite layer and a first mirror-like metal layer with low emissivity covering a surface of the first polymer composite layer; a first elastomer layer bonded to the first low emissivity layer opposite to the mirror-like metal layer; and optionally a first stretchable heater, the first stretchable heater is attached to the first elastomer layer opposite to the first low emissivity layer, wherein a top surface of the first low emissivity layer comprising the mirror-like metal layer has a lower emissivity relative to the first elastomer layer. Methods of making and use of the system are further described.

A method of forming a building panel or a surface element, including providing a substrate, applying a sub-layer on the substrate, applying a mesh structure on the sub-layer, and applying heat and pressure to the mesh structure such that the sub-layer at least partially fills meshes of the mesh structure. Also, to such a building panel and a surface element.

A method for producing a substrate for millimeter wave comprises the steps of: (a) mixing ceramic powder and Teflon powder; (b) dispersing the mixed ceramic powder and Teflon powder in a dispersion equipment; (c) after the step of (b) dispersing is completed, outputting a paste of a mixture of the ceramic powder and the Teflon powder by additionally adding a solution and a binder to the dispersion equipment and then dispersing the mixture; (d) applying the paste to a first metal thin film; (e) drying the first metal thin film to which the paste is applied; and (f) laminating a second metal thin film on the opposite side of the paste bonded to the dried first metal thin film and then thermally bonding it.

A display device includes a display panel which contains an LED which emits light, a first layer containing a porous polymer and disposed on the display panel, a second layer containing a metal halide and disposed on the first layer, and a lenticular lens disposed on the display panel, where the first layer has a first refractive index and the second layer has a second refractive index less than the first refractive index.

According to one implementation of the present disclosure, a method is disclosed. The method includes forming one or more aircraft surfaces from at least one of one or more metal materials or metal composite materials; and forming a surface coating, at least partially covering the one or more aircraft surfaces, with one or more materials above a dielectric strength threshold.

A laminated metallic structure includes preformed metallic sheets of graduated three-dimensional sizes. The preformed metallic sheets have a three-dimensional shape and are nested together to form a preform. The preformed metallic sheets in the preform are bonded together to form a three-dimensional body, having a near-net three-dimensional shape.

A method for repairing an electrostatic chuck device that is formed by bonding an electrostatic chuck member made of ceramics and a temperature-controlling base member made of metal with a first adhesive layer sandwiched therebetween is provided. The method includes a step of repairing the first adhesive layer that has been eroded by using a cold-curing adhesive.

Spacers may be attached onto a membrane by a method in which adjacent ones of the spacers are spaced apart from one another with spacings that are accurate to a very fine tolerance. In the method, adjacent ones of the spacers may be attached to one another via lateral members so as to fix the relative spacing between the spacers. The spacers arranged with the fixed spacing may be attached to a transparent substrate via one or more intermediate layers, and thereafter, the lateral members may be severed. Afterwards, a surface of each of the spacers facing away from the transparent substrate may be coated with an adhesive layer. The spacers may be pressed against a membrane so as to attach the spacers to the membrane via the adhesive layer. After being attached to the membrane, the spacers may be detached from the transparent substrate.

An intermediate transfer member (ITM) for use with a printing system, the ITM having (a) a support layer; and (b) a release layer having an ink reception surface and a second surface opposing the ink reception surface, the second surface attached to the support layer, the release layer formed of an addition-cured, hydrophobic silicone material, wherein the release surface of the release layer has relatively hydrophilic properties with respect to the addition-cured, hydrophobic silicone material.