Provided are a photocatalyst transfer film allowing a photocatalyst layer that is uniform, highly transparent, and exhibits an antimicrobial property in dark places to be transferred to the surfaces of various transfer base materials; and a production method thereof. The photocatalyst transfer film has, on a base film, a photocatalyst layer containing a titanium oxide particle-containing photocatalyst, antimicrobial metal-containing alloy particles, a silicon compound and a surfactant. The production method of the photocatalyst transfer film includes applying a photocatalyst coating liquid to a base film; and performing drying. The photocatalyst coating liquid contains a titanium oxide particle-containing photocatalyst, antimicrobial metal-containing alloy particles, a silicon compound, a surfactant and an aqueous dispersion medium.

The present invention aims to provide a conductive layered body having excellent solvent resistance and scratch resistance as well as a low haze value and a significantly high light transmittance. The present invention relates to a conductive layered body including, as an outermost layer thereof, a conductive layer containing a conductive fibrous filler, wherein the conductive layered body has a Martens hardness of 150 to 3,000 N/mm.sup.2 as measured at an indentation depth of 100 nm from a surface, and a ratio, in atomic percentage, of a conductive material element constituting the conductive fibrous filler on an outermost surface-side surface of the conductive layer is 0.15 to 5.00 at %.

In order to provide a composite good in formability into a three-dimensional shape and easy to manufacture, in a laminate having a core material layer and a skin material laminated on the core material layer, the core material layer has a plurality of plate-shaped flakes lined up along a surface of the skin material, and adjacent plate-shaped flakes are separated from each other by a gap or by a cut in the core material layer, and cutting directions along a thickness direction, which is determined from cutting marks formed on an outer periphery, are identical to each other among the plurality of the plate-shaped flakes.

A guide film includes a main area, a first subsidiary area, and a second subsidiary area being apart from the first subsidiary area. The main area includes a central area having a rectangular shape in a plan view, a first side area arranged between the central area and the first subsidiary area, a second side area arranged between the central area and the second subsidiary area, and a first corner area connecting the first side area to the second side area.

Disclosed is a thermal transfer substrate including a base substrate and a touch module on the base substrate. A side of the touch module which is in contact with the base substrate is adhesive, the adhesiveness decreasing under a first condition while increasing under a second condition. The present disclosure solves the problem that the manufacturing yield rate of touch display panels is relatively low, and improves the manufacturing yield rate of the touch display panels. The present disclosure is used for manufacturing a touch display panel.

A digitally receptive coating method includes the steps of applying a digitally receptive coating to a first side of a film, metalizing the first side of the film and bonding the metallized first side of the film to a substrate to produce a laminate having a digitally receptive coating.

The present invention aims to provide a conductive layered body having excellent solvent resistance and scratch resistance as well as a low haze value and a significantly high light transmittance. The present invention relates to a conductive layered body including, as an outermost layer thereof, a conductive layer containing a conductive fibrous filler, wherein the conductive layered body has a Martens hardness of 150 to 3,000 N/mm.sup.2 as measured at an indentation depth of 100 nm from a surface, and a ratio, in atomic percentage, of a conductive material element constituting the conductive fibrous filler on an outermost surface-side surface of the conductive layer is 0.15 to 5.00 at %.

A method for attaching a fingerprint module which includes providing an adhesive tape which includes a base film, a protective film which is oppositely arranged to the base film, and a number of adhesive layers positioned between the base film and the protective film and are arranged at intervals, and each of the base film and the protective film is an integral piece of film which is continuous in an entire layer. The method further includes partially peeling off the protective film to expose a first adhesive surface of one of the plurality of adhesive layers; attaching the fingerprint module to the exposed first adhesive surface of the adhesive layer; and peeling off the attached fingerprint module and adhesive layer together from the base film to expose a second adhesive surface of the adhesive layer.

A multilayer nanofiber sheet (10) includes: a nanofiber layer (11) including nanofibers which comprise a water-soluble polymer compound; a substrate layer (12) arranged on one surface side of the nanofiber layer (11); and a water-insoluble porous layer (13) arranged on the other surface side of the nanofiber layer (11). The three layers are layered, and the multilayer nanofiber sheet is used in a state in which a surface thereof on the porous layer side is arranged so as to face a surface of an object. Preferably, the three layers are layered in a fixed state. Preferably, the porous layer (13) has a thickness of from 3 to 1000 μm.

Apparatus, systems, and methods for forming semiconductor materials (e.g., using nanofabrication) are generally described. In one example, a method comprises formation of a carbon buffer layer on a first substrate and a graphene layer on the carbon buffer layer by silicon sublimation, followed by removing the graphene layer so as to expose the carbon buffer layer and form a fabrication platform.