Provided are a transparent electrode and a production method thereof, the transparent electrode using metal nanowires and/or metal nanotubes as conductive components, and showing favorable surface flatness, conductivity, and light transmittance. A transparent conductive ink is prepared by dispersing metal nanowires and/or metal nanotubes in a solution formed by dissolving a thermoset or thermoplastic binder resin having no fluidity within the range of 5 to 40° C. to a solvent, the content of the binder resin being 100 to 2500 parts by mass relative to 100 parts by mass of the metal nanowires and/or metal nanotubes. An electrode pattern having a desired shape is printed on a substrate with the transparent conductive ink, and pulsed light is irradiated to the printed electrode pattern, to thereby obtain a transparent electrode having a surface resistance of 0.1 to 500Ω/□ and a surface arithmetic average roughness Ra satisfying Ra≦5 nm.

A method for forming thin film conductors is disclosed. A thin film precursor material is initially deposited onto a porous substrate. The thin film precursor material is then irradiated with a light pulse in order to transform the thin film precursor material to a thin film such that the thin film is more electrically conductive than the thin film precursor material. Finally, compressive stress is applied to the thin film and the porous substrate to further increase the thin film's electrical conductivity.

The present invention relates to a method for formation of a redistribution layer using photo-sintering and to the redistribution layer formed by the method. The method for forming a redistribution layer using photo-sintering includes printing, on a substrate, a liquid electrode pattern for a redistribution layer; coating a transparent polymer on the substrate and the pattern; photo-sintering the electrode pattern using photonic energy; and evaporating an organic substance contained in the liquid electrode pattern via the photo-sintering to remove the polymer on a top face of the electrode pattern to form a redistribution layer as the sintered electrode pattern.

A calibration system includes: an exposure head support part that supports an exposure head so that a beam for exposure is incident on an exposure region on the substrate at the time of exposure; a sensor unit including an optical sensor; a sensor unit support part that supports the sensor unit so that, at the time of exposure, a light-receiving surface of the optical sensor is parallel to an exposure surface in the exposure region and the sensor unit support part is installed slidably relative to the exposure head support part; a movement mechanism that moves the exposure head support part and the sensor unit support part; and a control part that moves, at the time of calibration, the exposure head support part and the sensor unit support part so as to arrange the light-receiving surface at a position corresponding to the exposure surface.

A method for manufacturing a printed wiring board includes forming a seed layer on a surface of a resin insulating layer, applying a dry film onto the seed layer using a laminating roll device, cutting the dry film applied onto the seed layer to a predetermined size, applying pressure and heat to the dry film, forming a plating resist on the seed layer from the dry film using photographic technology, forming an electrolytic plating film on part of the seed layer exposed from the resist, removing the resist from the seed layer, and removing the part of the seed layer exposed from the electrolytic plating film. The applying of the pressure and heat includes applying the pressure and heat to the dry film applied onto the seed layer such that the pressure and heat are applied to the entire surface of the dry film cut to the predetermined size simultaneously.

An additive manufacturing process for forming a metallic layer on the surface of the substrate includes fabricating a substrate from a polymerizable composition by a stereolithographic process, and contacting the reactive surface with an aqueous solution including a metal precursor. The metal precursor includes a metal, and the polymerizable composition includes a multiplicity of multifunctional components. Each multifunctional component includes a reactive moiety extending from a surface of the substrate to form a reactive surface. An interface between the reactive surface and the aqueous solution is selectively irradiated to form nanoparticles including the metal in a desired pattern. The nanoparticles are chemically coupled to the reactive surface by reactive moieties, thereby forming a metallic layer on the surface of the substrate.

An additive manufacturing process for forming a metallic layer on the surface of the substrate includes fabricating a substrate from a polymerizable composition by a stereolithographic process, and contacting the reactive surface with an aqueous solution including a metal precursor. The metal precursor includes a metal, and the polymerizable composition includes a multiplicity of multifunctional components. Each multifunctional component includes a reactive moiety extending from a surface of the substrate to form a reactive surface. An interface between the reactive surface and the aqueous solution is irradiated to form nanoparticles including the metal. The nanoparticles are chemically coupled to the reactive surface by reactive moieties, thereby forming a metallic layer on the surface of the substrate.

A product article is prepared from a precursor article that has a substrate and a photosensitive thin film or a photosensitive thin film pattern on a supporting side. The product article have an electrically-conductive silver metal-containing film or thin film patterns, each of which contains electrically-conductive metallicsilver obtained by reduction of silver ions in the precursor article, an α-oxy carboxylate, an oxime compound, and a photosensitizer that can either reduce reducible silver ions or oxidize the α-oxy carboxylate.

An additive manufacturing process for forming a metallic layer on the surface of the substrate includes fabricating a substrate from a polymerizable composition by a stereolithographic process, and contacting the reactive surface with an aqueous solution including a metal precursor. The metal precursor includes a metal, and the polymerizable composition includes a multiplicity of multifunctional components. Each multifunctional component includes a reactive moiety extending from a surface of the substrate to form a reactive surface. An interface between the reactive surface and the aqueous solution is selectively irradiated to form nanoparticles including the metal in a desired pattern. The nanoparticles are chemically coupled to the reactive surface by reactive moieties, thereby forming a metallic layer on the surface of the substrate.

An object of the present invention is to provide a method for easily producing an electroconductive laminate having a three-dimensional shape and having a metal layer disposed thereon (for example, an electroconductive laminate having a three-dimensional shape including a curved surface and a metal layer disposed on the curved surface). Another object of the present invention is to provide a three-dimensional structure with a plated-layer precursor layer, a three-dimensional structure with a patterned plated layer, an electroconductive laminate, a touch sensor, a heat generating member, and a three-dimensional structure. The method for producing an electroconductive laminate of the present invention has a step of obtaining a three-dimensional structure with a plated-layer precursor layer including a three-dimensional structure and a plated-layer precursor layer disposed on the three-dimensional structure and having a functional group capable of interacting with a plating catalyst or a precursor thereof and a polymerizable group; a step of applying energy to the plated-layer precursor layer to form a patterned plated layer; and a step of subjecting the patterned plated layer to a plating treatment to form a patterned metal layer on the plated layer.