A transparent conductive film (TCF) and methods for creating the TCF. The TCF includes a substrate having a surface, a metal mesh layer over at least a portion of the surface of the substrate, and a conductive layer over the metal mesh layer. The conductive layer includes carbon nanotubes and a binder.

A method for manufacturing a wiring board in which the adhesion between an underlayer and a seed layer is improved. A diffusion layer in which an element forming the underlayer and an element forming a coating layer are mutually diffused is formed between the underlayer and a wiring portion of the coating layer by irradiating the wiring portion with a laser beam. A seed layer is formed by removing a portion excluding the wiring portion of the coating layer from the underlayer. A metal layer is formed by disposing a solid electrolyte membrane between an anode and the seed layer and applying voltage between the anode and the underlayer. An exposed portion without the seed layer of the underlayer is removed from an insulating substrate.

An occupant or object sensing system in a vehicle includes electrical circuits for capacitive sensing and corresponding circuits shielding the sensing system from interference. A sensing circuit and a shielding circuit may be printed by screen printing with conductive ink on opposite sides of a non-conductive substrate. The substrate is a plastic film or other fabric that has an elastic memory structure that is resilient to stretching. The conductive inks used to print circuits onto the substrate have a similar resilience to stretching such that the substrate and the circuits thereon can be subject to deforming forces without breaking the printed circuits. The substrate may be covered with a carbon polymer layer to provide alternative conductive paths that enable fast recovery for conduction in the presence of any break in the printed conductive traces on the substrate.

A wiring board includes: a support body including at least one woven fabric woven from weaving yarns that are each formed by bundling insulating fibers; and a conductive body supported by the support body. The conductive body includes a first conductive path disposed on a first main face of the support body and that extends in a planar direction of the first main face. The first conductive path includes at least one of a first conductor portion disposed in a basket hole of the woven fabric and a first intervening portion disposed in a gap between the insulating fibers.

Conductive articles include an electrically insulating substrate with conductive regions on the substrate, the conductive regions are conductive patterns of a transparent conductor and a resist matrix. The substrate also has non-conductive regions, and exposed conductive contacts, where the conductive contacts are in electrical contact with the conductive regions. The non-conductive regions are formed by selective chemical etching of the transparent conductor coating, where the selective etching does not remove the conductive patterns or conductive contact.

There is provided a method for forming an electrically conductive ultrafine pattern which has an excellent pattern cross-sectional shape is provided by a composite technique including a printing process and a plating process, and furthermore, by imparting excellent adhesion to each interface of a laminate including a plating core pattern, an electrically conductive ultrafine pattern which can be preferably used as a highly accurate electric circuit and a method for manufacturing the same are also provided. The method includes (1) a step of applying a resin composition to form a receiving layer on a substrate; (2) a step of printing an ink containing plating core particles by a reverse offset printing method to form a plating core pattern on the receiving layer; and (3) a step of depositing a metal on the plating core pattern formed in the step (2) by an electrolytic plating method.

A preparation process of a copper powder metal plating layer, a metal substrate having the copper powder metal plating layer, an energy-saving anti-burst heat dissipation device and a preparation process thereof; the process of preparing the copper powder metal plating layer comprises the step of attaching the metal layer; the temperature of the liquid in the work tank is kept within a range of 1-15 C.; the attachment process of the metal layer comprises at least the steps of: attaching the bottom layer, attaching the snowflake-shaped layer and attaching the fastening layer.

An electronic device includes an insulating layer, a plurality of upper wiring electrode patterns formed on an upper surface of the insulating layer, and a plurality of lower wiring electrode patterns formed on a lower surface of the insulating layer. The upper wiring electrode patterns and the lower wiring electrode patterns each include an underlying electrode layer formed of a conductive paste and a plating electrode layer formed on the underlying electrode layer. With this configuration, the resistivity of the upper and lower wiring electrode patterns and can be made lower than that of the upper and lower wiring electrode patterns and each including only the underlying electrode layer formed of a conductive paste.

Disclosed herein is a method for manufacturing a planar coil, the method including forming a base conductive layer on a base material, the base conductive layer including: a coil wiring portion having one end, other end, and first to third connecting positions, the second connecting position being closer to the other end compared with the first connecting position, the third connecting position being closer to the one end compared with the second connecting position; a power-feed wiring portion that connects the first connecting position with an external power source; and a connection wiring portion that short-circuits the second connecting position and the third connecting position; forming a wiring conductive layer on the base conductive layer by electrolytic plating by feeding power from the external power source; and removing the power-feed wiring portion and the connection wiring portion.

Provided are a substrate with a functional fine line having excellent optical properties and excellent adhesion of the functional fine line, and a method for forming the functional fine line. The substrate with a functional fine line according to the present invention has an undercoat layer including a hydrophobically modified polyester resin on the substrate, and has a functional fine line including a deposit of functional microparticles and having a line width of 1 m or more and 10 m or less on the undercoat layer. The method for forming a functional fine line according to the present invention includes forming an undercoat layer including a hydrophobically modified polyester resin on a substrate, and then forming a functional fine line including a deposit of functional microparticles and having a line width of 1 m or more and 10 m or less on the undercoat layer.