Provided herein is a method for manufacturing a conductive transparent substrate, the method including forming a plurality of main electrodes on the substrate such that the main electrodes are distanced from one another; and forming a connecting electrode that electrically connects two or more main electrodes such that the plurality of main electrodes are grouped into a plurality of group electrodes that are electrically disconnected from one another, thereby producing a conductive transparent substrate with excellent transmittance in a process of high yield.

The present disclosure provides an electronic product metal shell with an antenna groove and a method of manufacturing the same. The electronic product metal shell includes a metal layer, a hard anodic oxidation layer, a step recess, an antenna groove and a non-conductive material filled in the antenna groove. The metal layer may have a first surface and a second surface. The hard anodic oxidation layer may be coated on the first surface and the second surface of the metal layer. The step recess may be formed through the hard anodic oxidation layer on the first surface of the metal layer and partially into the metal layer. The antenna groove may be formed within the step recess extending through the metal layer to expose an inner side of the hard anodic oxidation layer on the second surface of the metal layer.

A method for producing a package substrate for mounting a semiconductor device includes:

forming a first substrate by forming a laminate in which a first metal layer that has a thickness of 1 μm to 70 μm and that is peelable from a core resin layer, a first insulating resin layer, and a second metal layer are arranged on both sides of the core resin layer having a thickness of 1 μm to 80 μm, and heating and pressurizing the laminate simultaneously;

forming a pattern on the second metal layer;

forming a second substrate by heating and pressurizing a laminate formed by arranging a second insulating resin layer and a third metal layer on a surface of the second metal layer; and

peeling, from the core resin layer, a third substrate including the first metal and insulating resin layers, the second metal and insulating layers, and the third metal layer.

A method for manufacturing a circuit board with narrow conductive traces and narrow spaces between traces includes a base layer and two first wiring layers disposed on opposite surfaces of the base layer. Each first wiring layer includes a first bottom wiring and a first electroplated copper wiring. The first bottom wiring is formed on the base layer. The first bottom wiring includes a first end facing the base layer, a second end opposite to the first end, and a first sidewall connecting the first end and the second end. The first electroplated copper wiring covers the second end and the first sidewall of the first bottom wiring.

A package structure, an electronic device and a method for manufacturing the package structure are presented. The package structure comprises: a substrate (100), a sensing module (200) disposed on an upper surface of the substrate (100) and electrically connected to the substrate (100), and a package colloid (300) disposed on the upper surface of the substrate (100) and coating at least one portion of the sensing module (200), wherein the sensing module (200) comprises a capacitive sensor (210) and an optical sensor (220), and the package colloid (300) comprises at least one portion of a photic zone (310) disposed corresponding to the optical sensor (220). Thus, the capacitive sensor and the optical sensor can be packaged in one package structure, so as to improve the degree of integration of the package structure and save the package space.

The object of the present invention is to provide a printed circuit board that improves the heat radiating effect as the entire printed circuit board and a manufacturing method for such a printed circuit board. A printed circuit board includes a base member having two main surfaces, at least one heat-radiating conductor layer formed on at least one of the main surfaces of the two main surfaces of the base member and a solder resist layer formed on a surface of the heat-radiating conductor layer, and in this printed circuit board, the heat-radiating conductor layer has two main surfaces and at least one side face, the heat-radiating conductor layer has its one main surface of the two main surfaces made in planar contact with the main surface of the base member, the solder resist layer further has an etching liquid resistance, and is formed on the other main surface of the two main surfaces of the heat-radiating conductor layer, with the side face of the heat-radiating conductor layer being exposed, and the heat-radiating conductor layer and the solder resist layer are allowed to form a laminate 24 having a substantially convex shape with an appropriate height.

The disclosure relates to a method for manufacturing a transfer film including an electrode layer, the method comprising: an electrode layer formation step of forming an electrode layer on a carrier member by using a conductive material; a placement step of placing the carrier member on at least one side of an insulating resin layer respectively; a bonding step of bonding the carrier member and the insulating resin layer together by applying pressure thereto; and a transfer step of removing the carrier member to transfer the electrode layer on the insulating resin layer.

Flexible electronic structure and methods for fabricating flexible electronic structures are provided. An example method includes applying a first layer to a substrate, creating a plurality of vias through the first layer to the substrate, and applying a second polymer layer to the first layer such that the second polymer forms anchors contacting at least a portion of the substrate. At least one electronic device layer is disposed on a portion of the second polymer layer. At least one trench is formed through the second polymer layer to expose at least a portion of the first layer. At least a portion of the first layer is removed by exposing the structure to a selective etchant to providing a flexible electronic structure that is in contact with the substrate. The electronic structure can be released from the substrate.

Provided are a method of manufacturing a substrate for chip packages and a method of manufacturing a chip package, the method of manufacturing the substrate including: forming a lower adhesive layer in a lower part of an insulation film; forming an upper adhesive layer in an upper part of the insulation film to form a base material; forming via holes in the base material; and forming a circuit pattern layer on the upper adhesive layer, so it is effective to improve adhesion power between the molding resin and the insulation film at the time of manufacturing a chip package later.

An etchant for copper includes an acid and one or more compounds selected from the group consisting of an aliphatic noncyclic compound, an aliphatic heterocyclic compound and a heteroaromatic compound. The aliphatic noncyclic compound is a saturated aliphatic noncyclic compound (A) including only two or more nitrogen atoms as heteroatoms, and 2 to 10 carbon atoms. The aliphatic heterocyclic compound is a compound (B) including a five-, six-, or seven-membered ring having one or more nitrogen atoms as one or more heteroatoms constituting the ring. The heteroaromatic compound is a compound (C) including a six-membered heteroaromatic ring having one or more nitrogen atoms as one or more heteroatoms constituting the ring.