The present invention provides a process and a structure of forming conductive vias using a light guide. In an exemplary embodiment, the process includes providing a via in a base material in a direction perpendicular to a plane of the base material, applying a photoresist layer to an interior surface of the via, inserting a light guide into the via, exposing, by the light guide, a portion of the photoresist layer to light, thereby resulting in an exposed portion of the photoresist layer and an unexposed portion of the photoresist layer, removing a portion of the photoresist layer, and plating an area of the via, where the photoresist has been removed, with a metal, thereby resulting in a portion of the via plated with metal and a portion of the via not plated with metal.

A circuit board includes at least two circuit board units. Each of the circuit board units includes a baseboard having a conductive hole filled with an electrical conductor, and a cover layer arranged on the baseboard and defining at least one trench and at least one opening. The at least one opening exposes out the electrical conductor. A circuit pattern is embedded in the at least one trench and includes a connecting portion. The connecting portion is embedded in the opening and is electrically coupled to the electrical conductor. The at least two circuit board units are stacked. Two sides of the at least one cover layer are respectively adhered to the corresponding baseboard. Two ends of the at least one connecting portion are respectively electrically coupled to the corresponding electrical conductor and electrically coupled the two adjacent circuit patterns.

An adhesive substrate is disclosed, which includes a base substrate and a heat-resistant elastomer layer formed on the base substrate, wherein the base substrate is flexible and has a thickness of 0.2 mm or more and 2 mm or less, wherein the adhesive substrate is used as part of a method for physically separating an object that has been held immovable in such a manner that the object has been adhered to by the heat-resistant elastomer layer and the object is anchored from the upper side, and wherein by starting to physically separate the end portion of the adhesive substrate downward the object is able to be separated.

A method of masking a feature of a substrate using a fixture includes removably coupling a fixture to a first side of the feature of the substrate, the fixture including walls configured to abut sides of the feature and extend beyond a top surface of the feature when the fixture is removably coupled to the first side. The method further includes applying a masking material to the top surface of the feature. The method further includes removably coupling the fixture to a second side of the feature, the second side opposing the first side, the walls of the fixture configured to abut the sides of the feature and extend beyond a bottom surface of the feature when the fixture is removably coupled to the second side. The method further includes applying the masking material to the bottom surface of the feature while the fixture is removably coupled.

Transparent conductive films comprising sparse metal conductive layers are processed after coating with an overcoat to lower the sheet resistance of the film. The sparse metal conductive layer can comprise a fused metal nanostructured network. A coating, such as a polymer overcoat or a polymer undercoat can noble metal ions that can further reduce the sheet resistance with the application of heat and optionally humidity. In particular, silver ions in a coating are demonstrated to provide important stabilization of sparse metal conductive layers, whether or not fused, upon the application of heat and humidity. A coating can further comprise a metal salt stabilization composition.

A flexible printed circuit according to the present invention comprises a flexible base, a wiring pattern arranged on the flexible base, and a via that is provided in the flexible base and is electrically connected to the wiring pattern, wherein the wiring pattern is formed to have an aspect ratio of at least 0.7 or more. This feature enables to increase the density of a wiring structure in the flexible printed circuit while improving the reliability thereof.

An electronic device module adapted to be removably attached by a heat-resistant tape includes a substrate, a waterproof enclosure and an electronic device. The substrate has a front surface and a rear surface that is opposite to the front surface. The waterproof enclosure is disposed on the rear surface of the substrate to form a closed path and is adapted to be attached by the heat-resistant tape so as to be interposed between the rear surface and the heat-resistant tape. The electronic device is formed on the front surface of the substrate.

A method for manufacturing conductive lines is provided. A first metal layer is formed over a carrier substrate. A second metal layer is formed over the first metal layer. A plurality of first conductive lines is formed on the second metal layer. A protective layer is formed on opposite sidewalls of the first conductive lines. An exposed portion of the second metal layer is removed to expose a portion of the first metal layer. The exposed portion of the first metal layer is removed, and the protective layer is removed.

The present invention provides a process and a structure of forming conductive vias using a light guide. In an exemplary embodiment, the process includes providing a via in a base material in a direction perpendicular to a plane of the base material, applying a photoresist layer to an interior surface of the via, inserting a light guide into the via, exposing, by the light guide, a portion of the photoresist layer to light, thereby resulting in an exposed portion of the photoresist layer and an unexposed portion of the photoresist layer, removing a portion of the photoresist layer, and plating an area of the via, where the photoresist has been removed, with a metal, thereby resulting in a portion of the via plated with metal and a portion of the via not plated with metal.

A method for treating a substrate having millimeter and/or micrometer and/or nanometer structures. The method includes applying at least one protective material to the structures, wherein the at least one protective material can be dissolved in a solvent, and the structures are produced by an imprinting process.