Electrically conductive patterns formed on a substrate are provided with a reduced visibility. A region of a major surface of the substrate is selectively roughened to form a roughened pattern on the major surface of the substrate. Electrically conductive traces are directly formed on the roughened region and are conformal with the roughened pattern on the major surface of the substrate.

A manufacturing method of a circuit board and a stamp are provided. The method includes the following steps. A circuit pattern and a dielectric layer covering the circuit pattern are formed on a dielectric substrate. A conductive via connected to the circuit pattern is formed in the dielectric layer. A photoresist material layer is formed on the dielectric layer. An imprinting process is performed on the photoresist material layer using a stamp to form a patterned photoresist layer, wherein the pressing side of the stamp facing the circuit pattern becomes sticky when subjected to pressure so as to catch photoresist residue from the photoresist material layer in the imprinting process. A patterned metal layer is formed on a region exposed by the patterned photoresist layer. The patterned photoresist layer is removed.

Disclosed are a thermoforming device and method for a flexible printed circuit board. The thermoforming device may include: a first forming mechanism provided with a first forming portion, the first forming portion being configured to carry the flexible printed circuit board to be processed; a second forming mechanism provided with a second forming portion which matches with the first forming portion, at least one of the first forming portion or the second forming portion is provided with a corresponding heating module configured for heat treatment of the flexible printed circuit board; a first driving mechanism configured to drive the first forming mechanism and the second forming mechanism to be displaced relative to each other in a first direction; a second driving mechanism configured to drive the second forming mechanism and the first forming mechanism to be displaced relative to each other in a second direction perpendicular to the first direction; and a controller.

A circuit board includes a board body and pair of connection portions disposed at both ends of the board body. Each of the pair of connection portions is inserted into a connector. Each of the pair of connection portions includes a connection terminal electrically connected to the connector, and at least one of the pair of connection portions includes an extending portion extending from the connection terminal to an insertion leading end of the at least one of the pair of connection portion. The extending portion is disposed at a position to avoid a virtual line extending in an insertion direction through a position where the connector and the connection terminal are electrically connected.

A system and method for shaping a flexible circuit (FC) having a set of conductive traces disposed within a set of insulation layers and a shaped FC, each involve using a non-conductive tool defining complimentary first and second tool portions and a shape therebetween, the tool being configured to receive a portion of the FC therebetween the first and second tool portions, a set of conductive heating elements arranged substantially in parallel with each other and disposed within the first and second tool portions, and a power source configured to provide power to the conductive heating elements causing the conductive heating elements to generate heat energy to shape the FC portion without removing any of the FC portion.

The disclosure describes a soft-matter electronic device having micron-scale features, and methods to fabricate the electronic device. In some embodiments, the device comprises an elastomer mold having microchannels, which are filled with an eutectic alloy to create an electrically conductive element. The microchannels are sealed with a polymer to prevent the alloy from escaping the microchannels. In some embodiments, the alloy is drawn into the microchannels using a micro-transfer printing technique. Additionally, the molds can be created using soft-lithography or other fabrication techniques. The method described herein allows creation of micron-scale circuit features with a line width and spacing that is an order-of-magnitude smaller than those previously demonstrated.

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 multilayer ceramic substrate includes: a plurality of ceramic layers 300a, 300b stacked together; a via hole 400a, 400b provided in each of the plurality of ceramic layers, the via holes of the plurality of ceramic layers being connected together in a layer stacking direction of the plurality of ceramic layers; a via wire 406a, 406b including an electrical conductor filled into each of the via holes; a first conductor 404a, 404b provided on an upper surface of at least one of the plurality of ceramic layers, the first conductor having an annular or partially annular shape surrounding the via wire; and a second conductor 403a, 403b including a first portion and a second portion, the first portion being located outside the first conductor on the upper surface of the at least one ceramic layer, the second portion overlying the first conductor, and an inner rim of the second portion being located outside an inner rim of the first conductor, wherein a thickness of the first conductor 404a, 404b is greater than a thickness of the second conductor 403a, 403b.

A manufacturing method of a circuit board and a stamp are provided. The method includes: forming a circuit pattern and a dielectric layer on a dielectric substrate; forming a conductive via in the dielectric layer; forming a thermal-sensitive adhesive layer on the dielectric layer; forming a photoresist material layer on the thermal-sensitive adhesive layer; imprinting the photoresist material layer using a stamp, wherein a first conductive layer is disposed on the surface of the pressing side of the stamp, a second conductive layer is disposed on the surface of the other portions; applying a current to the stamp; removing the stamp and the photoresist material layer and the thermal-sensitive adhesive layer below the pressing side to form a patterned photoresist layer and thermal-sensitive adhesive layer; forming a patterned metal layer on the region exposed by the patterned photoresist layer; removing the patterned photoresist layer and thermal-sensitive adhesive layer.

A manufacturing method of a circuit board including the following steps is provided. A carrier substrate is provided. A patterned photoresist layer is formed on the carrier substrate. An adhesive layer is formed on the top surface of the patterned photoresist layer. A dielectric substrate is provided. A circuit pattern and a dielectric layer covering the circuit pattern are formed on the dielectric substrate, wherein the dielectric layer has an opening exposing a portion of the circuit pattern. The adhesive layer is adhered to the dielectric layer in a direction that the adhesive layer faces of the dielectric layer. The carrier substrate is removed. A patterned metal layer is formed on a region exposed by the patterned photoresist layer. The patterned photoresist layer is removed. The adhesive layer is removed.