According to one embodiment, a method of forming a pattern includes preparing a substrate having a liquid-repellent face and a lyophilic pattern which are located adjacent to each other on a surface of the substrate, the lyophilic pattern having a surface energy different from the liquid-repellent face, bringing ink into contact with the substrate, and applying the ink to the lyophilic pattern by moving a contacted ink surface. The lyophilic pattern includes a linear main lyophilic pattern and an auxiliary lyophilic pattern connected to the lyophilic pattern. A liquid-repellent region is defined in the liquid-repellent face between the main lyophilic pattern and the auxiliary lyophilic pattern.

A sealed electrical connection assembly joins an electrical component to a plug-in component. For liquid-tight sealing, the free, deformable ends of the conductor tracks of the electrical component and/or the contact elements of the plug-in component are provided with hydrophobic surfaces at least regionally, so that even after a plurality of plug contact operations have been performed, in the coupling position and, optionally, in the uncoupled position, the contact region is surrounded by hydrophobic surfaces.

Compositions including first and second silicon-containing compounds are described. The first silicon-containing compound includes a polyvalent transition metal having bonded thereto a hydrocarbyloxy group(s) and/or a (di-hydrocarbyl)(perfluoro/fluorinated-hydrocarbyl)silyloxy group(s), which is represented by Formula (I). The second silicon-containing compound includes a reaction product of a first reactant represented by Formula (II-A), which includes hyrdrocarbylsilyloxy groups, and a second reactant represented by Formula (II-B), which includes a perfluorohydrocarbyloxy group(s). The present invention also relates to, articles that include one or more layers formed from such compositions, methods of treating articles by applying thereover such compositions, and the second silicon-containing compound.

First, a patterned substrate including an insulating substrate, a conductive seed layer, and an insulating layer is prepared. The seed layer is disposed on the insulating substrate, and consists of a first part having a predetermined pattern corresponding to the wiring pattern and a second part as a part other than the first part. The insulating layer is disposed on the second part of the seed layer. Subsequently, a metal layer having a thickness larger than a thickness of the insulating layer is formed on the first part of the seed layer. Here, a voltage is applied between an anode and the seed layer while a resin film containing a metal ion-containing solution is disposed between the patterned substrate and the anode and the resin film and the seed layer are brought into pressure contact. Subsequently, the insulating layer and the second part of the seed layer are removed.

A wiring board and a method for manufacturing the same enabling simple and easy formation of a conductive pattern are provided. The method comprises a transferring step of bringing a resin composition containing a first compound inducing a low surface free energy and a second compound inducing a higher surface free energy than the first compound into contact with a master on which a desired surface free energy difference pattern is formed and curing to obtain a base material to which the surface free energy difference pattern is transferred; and a conductive pattern forming step of applying a conductive coating composition onto a surface of pattern transfer of the base material to form a conductive pattern.

The present disclosure provides a method for producing a wiring substrate. A seeded substrate is first prepared. The seeded substrate includes an insulation substrate, a conductive undercoat layer having a hydrophilic surface and provided on the insulation substrate, a conductive seed layer provided on a first region of the surface of the undercoat layer, the first region having a predetermined pattern, and a water-repellent layer on the second region of the surface of the undercoat layer, the second region being a region other than the first region. Subsequently, a metal layer is formed on the seed layer. A voltage is applied between the anode and the seed layer while a solid electrolyte membrane being disposed between the seeded substrate and the anode, and the solid electrolyte membrane and the seed layer being pressed into contact with each other. Thereafter, the water-repellent layer and the undercoat layer are etched.

The invention relates to display device and method of manufacturing the same. The display device includes: a substrate; a driving pad disposed on the substrate; an insulating layer exposing the driving pad and disposed on the substrate; a circuit board including a circuit pad overlapping the driving pad; and a connector disposed between the circuit board and the insulating layer and including a plurality of conductive particles electrically connecting the driving pad and the circuit pad, the driving pad including: a first pad disposed on the substrate; and a second pad disposed on the first pad and having an opening exposing the first pad.

A fluororesin base material containing a fluororesin as a main component includes a modified layer on at least a partial region of a surface thereof, the modified layer containing a siloxane bond and a hydrophilic organofunctional group, and a surface of the modified layer having a contact angle of 90° or less with pure water.

An elastic wiring board that includes an elastic substrate; a plurality of electrode wirings having elasticity; and an ion-migration resistant layer between at least a first electrode wiring of the plurality of electrode wirings and the elastic substrate.

A flexible circuitry layer may comprise a conductive mesh including a circuitry trace; and an interfacing component, comprising: a flexible substrate; a terminal electrically connected to the circuitry trace; and a connector configured to be detachably connected to an external device.