In an embodiment, a method of forming a stub-less via is provided. The method includes depositing a plurality of microcapsules containing a metal material in a via of a printed circuit board (PCB); rupturing the microcapsules and releasing the metal material; and sintering the metal material. In another embodiment, a method of forming a stub-less via is provided. The method includes forming a via in a printed circuit board (PCB); installing a plug in a portion of the via; depositing in the via a plurality of nanoparticles containing a metal material; and sintering the metal material.

Vias may be established in printed circuit boards or similar structures and filled with a monolithic metal body to promote heat transfer. Metal nanoparticle paste compositions, such as copper nanoparticle paste compositions, may provide a ready avenue for filling the vias and consolidating the metal nanoparticles under mild conditions to form each monolithic metal body. The monolithic metal body within each via can be placed in thermal contact with one or more heat sinks to promote heat transfer. Adherence of the monolithic metal bodies within the vias may be promoted by a coating upon the walls of the vias. A tin coating, for example, may be particularly suitable for promoting adherence of a monolithic metal body comprising copper.

A method for manufacturing a transparent circuit board includes the following steps. A composite substrate including a conductive layer and a transparent insulating layer on the conductive layer is provided. A wiring groove is formed on the transparent insulating layer by laser ablation and a carbon black layer is formed on an inner wall of the wiring groove. The wiring groove penetrates the transparent insulating layer, the wiring groove extends toward the conductive layer to pass through a part of the conductive layer. A conductive wiring corresponding to the wiring groove is formed and fully fills the wiring groove. A black oxide treatment is performed on a surface of the conductive wiring facing away from the conductive layer to form a blackened layer. A transparent cover film is pressed on a side of the transparent insulating layer facing away from the conductive layer. The conductive layer is removed.

An electronic device is provided. The electronic device includes a substrate, a first contacting element, a second contacting element and a connecting element. The substrate has a first surface and a second surface. The substrate has a through hole located between the first surface and the second surface. At least a part of the connecting element is disposed in the through hole. The first contacting element is disposed on the first surface. The second contacting element is disposed on the second surface. The first contacting element electrically connects the second contacting element through the connecting element.

An electrical connection method of a printed circuit includes overlapping a base material and a thin member in which a thin conductor is mounted, forming a through hole which passes through the base material overlapped with the thin member in the overlapping and reaches the thin conductor of the thin member, and forming a printed circuit on the base material by a screen printing method using conductive paste. The through hole formed in the forming of the through hole is filled with the conductive paste in the forming of the printed circuit.

Electrical connection between the backplane and the front electrode of an electro-optic display is provided by forming a front plane laminate (100) comprising, in order, a light-transmissive electrically-conductive layer (104), a layer of electro-optic material (106), and a layer of lamination adhesive (108); forming an aperture (114) through all three layers of the front plane laminate (100); and introducing a flowable, electrically-conductive material (118) into the aperture (114), the flowable, electrically-conductive material being in electrical contact with the light-transmissive electrically-conductive layer (104) and extending through the adhesive layer (108).

A manufacturing method of a circuit board includes: performing a first printing process to form a first insulating layer having a first circuit depressed pattern; performing a second printing process to form a first circuit layer in the first circuit depressed pattern; checking whether a real position of the first circuit layer is diverged from a predetermined position; determining whether the shift level of the position of the first circuit layer is more than a predetermined level; performing the first printing process to form the second insulating layer, wherein when the shift level is more than the predetermined level and the thickness of a second insulating layer to be formed on the first insulating layer is not greater than a tolerance thickness, the second insulating layer has a hole at least partially overlapping the real position; and performing the second printing process to form a conductive plug in the hole.

The invention relates to an electronic device having an electrically isolating support structure, an electrically conducting conductor path on a surface of the support structure, and an electrically conducting contact structure which extends from the surface into the support structure and is electrically connected to the conductor path at a connection point, thereby forming a common conductor track. The conductor path and the contact structure transition into each other in an enlargement-free manner at the connection point.

In a preparatory process of a method of manufacturing a multilayer substrate, an insulating substrate is prepared, with a conductor pattern formed only on one surface of the insulating substrate. At that time, the conductor pattern is constituted of the Cu element, a Ni layer is formed on the surface of the conductor pattern that is on the side of the insulating substrate. In a first forming process, a via hole having the conductor pattern as the bottom thereof is formed in the insulating substrate. At that time, the Ni layer that is in the area of the bottom is removed. In a filling process, a conductive paste is filled in the interior of the via hole. In a second forming process, a stacked body is formed by stacking a plurality of the insulating substrates. In a third forming process, the stacked body is heated while being subjected to pressure.

A component-embedded substrate includes: a plurality of insulating layers each including a wiring pattern formed on one surface; an embedded component including a connection terminal; and a plurality of vias that electrically connect the connection terminal to the wiring patterns adjacent to each other in a lamination direction. The plurality of insulating layers is laminated on the connection terminal. Each of the plurality of vias is composed of a via hole formed in the respective insulating layer of the plurality of the insulating layers and a conductive material provided in the via hole. One of the plurality of vias is a connection via directly connected to the connection terminal. Another of the plurality of vias is a first adjacent via adjacent to the connection via in the lamination direction. The first adjacent via is connected to the wiring pattern formed on a surface of a top insulating layer.