A transparent conductive film (10) that has a substrate (14) having a surface (14a, 14b), a nanowire layer (12, 12a) over one or more portions of the surface (14a, 14b) of the substrate (14), and a conductive layer (16, 16a) on the portions comprising the nanowire layer (12, 12a), the conductive layer (16, 16a) comprising carbon nanotubes (CNT) and a binder.

A laminated glazing includes two transparent substrates which are separated by a lamination interlayer, and intended for fitting out buildings or vehicles. One of the transparent substrates is coated with a functional coating capable of acting on solar radiation and/or infrared radiation, and a low emissivity (so-called low E) coating is provided on one of the faces of the second substrate.

Provided is a transparent conductor including a transparent resin substrate, a first metal oxide layer, a metal layer containing a silver alloy, and a second metal oxide layer laminated in the order presented, wherein the second metal oxide layer contains zinc oxide, indium oxide, titanium oxide, and tin oxide.

A method for fabricating a flexible display device is provided. The method comprises: attaching a first flexible substrate of the flexible display device onto a conductive adhesive layer, wherein the conductive adhesive layer is disposed on a conductive rigid substrate; fabricating other parts of the flexible display device on the first flexible substrate; aging the conductive adhesive layer; peeling off the flexible substrate from the conductive rigid substrate so as to obtain the flexible display device.

A method for producing a touch input sensor includes stacking an intermediate resin layer (33) containing a photosensitive resin and an ultraviolet absorber and a transparent conductive film (32) on both surfaces of a transparent substrate (10) in that order, performing a pattern exposure with ultraviolet rays (L) applied to both surface sides, and performing developing to form a transparent electrode formed of the transparent conductive film (32) on both surfaces of the transparent substrate (10).

An active metal brazing substrate material and a method for producing the same are provided. The active metal brazing substrate material includes a ceramic substrate layer, a first brazing layer, a second brazing layer, and a conductive metal layer that are sequentially stacked. The first brazing layer includes a first metal composite material, which includes silver (Ag), copper (Cu), and a first active metal element. Based on a total weight of the first metal composite material being 100 parts by weight, a silver content is not less than 50 parts by weight. The second brazing layer includes a second metal composite material. The second metal composite material includes a low melting point metal element (e.g., Sn), copper (Cu), and a second active metal element, but does not include silver. A melting point of the low melting metal element is between 130 C. and 350 C.

A laminated pane having an outer pane and an inner pane, which are connected to one another via a thermoplastic intermediate layer. The laminated pane has an opaque masking region and a transparent see-through region. The intermediate layer has a functional film with at least one layer based on polyethylene terephthalate arranged at least partially in the masking region, an outer thermoplastic layer through which the functional film is connected to the outer pane, and a transparent inner thermoplastic layer through which the functional film is connected to the inner pane. The outer thermoplastic layer has at least one first outer connecting layer composed of at least one transparent connecting film and at least one opaque connecting film. The transparent connecting film is arranged in the viewing region and the opaque connecting film forms at least part of the masking region.

A glazing unit, containing a transparent substrate provided with a stack of thin layers including in an alternating arrangement three infrared radiation reflecting functional layers and four dielectric coatings. The three infrared radiation reflecting functional layers are referred to starting from a surface of the transparent substrate as a first functional layer Ag1, a second functional layer Ag2, and a third functional layer Ag3, and the four dielectric coatings are referred to starting from the surface of the transparent substrate as D1, D2, D3 and D4. Each of the three infrared radiation reflecting functional layers is surrounded by the dielectric coatings and the three infrared radiation reflecting functional layers contain silver.

A radiative cooling device that is in a state in which a radiative surface is colored is provided. A radiative cooling device CP includes an infrared radiative layer A that radiates infrared light IR from a radiative surface H, a light reflective layer B that is disposed on the side opposite to the radiative surface H with respect to the infrared radiative layer A, and a color portion X. The infrared radiative layer A is a resin material layer J that has a thickness adjusted so as to emit a heat radiation energy greater than an absorbed solar energy in a wavelength range from 8 m to 14 m, and the color portion X contains a colorant that absorbs light in the visible range.

A method for producing a touch input sensor includes stacking an intermediate resin layer (33) containing a photosensitive resin and an ultraviolet absorber and a transparent conductive film (32) on both surfaces of a transparent substrate (10) in that order, performing a pattern exposure with ultraviolet rays (L) applied to both surface sides, and performing developing to form a transparent electrode formed of the transparent conductive film (32) on both surfaces of the transparent substrate (10).