There are provided a printed circuit board and a method of manufacturing the same. The printed circuit board include a glass plate, an insulating member penetrating through the glass plate, insulating layers disposed on a first surface and a second surface of the glass plate, and a via through the insulating member.

A method is provided for fabricating an electromagnetic shield for an electronic component on a PCB. The method includes providing a patterned metal layer; laminating the patterned metal layer with a second dielectric layer; forming a cavity in the second dielectric layer; applying a dry film resist over the second dielectric layer and the cavity; stripping the dry film resist from the second dielectric layer and portions of the cavity adjacent the cavity side walls; depositing a seed layer and metal over the second dielectric layer and the dry film resist; etching the preplating layer and the seed layer from top surfaces of a remainder of the dry film resist and the second dielectric layer; and stripping the remainder of the dry film resist, thereby exposing the preplating layer on the side walls of the cavity to provide the electromagnetic shield.

A printed wiring board according to an aspect of the present invention includes: an electrically insulating base film; and an electrically conductive pattern stacked on at least one surface side of the base film, wherein an average width of a plurality of wiring portions included in the electrically conductive pattern is 5 μm or greater and 20 μm or less, wherein each of the wiring portions includes a seed layer and a plating layer, wherein the plating layer includes copper crystal planes of a (111) plane, a (200) plane, a (220) plane, and a (311) plane, and wherein an intensity ratio IR.sub.220 of an X-ray diffraction intensity of the copper crystal plane (220) obtained by Equation (1) below is 0.05 or greater and 0.14 or less,

IR.sub.220=I.sub.220/(I.sub.111+I.sub.220+I.sub.311)  (1)

(where I.sub.111 is an X-ray diffraction intensity of the (111) plane, I.sub.200 is an X-ray diffraction intensity of the (200) plane, I.sub.220 is the X-ray diffraction intensity of the (220) plane, and I.sub.311 is an X-ray diffraction intensity of the (311) plane in Equation (1)).

According to various embodiments described herein, an article comprises a glass or glass-ceramic substrate having a first major surface and a second major surface opposite the first major surface, and a via extending through the substrate from the first major surface to the second major surface over an axial length in an axial direction. The article further comprises a helium hermetic adhesion layer disposed on the interior surface; and a metal connector disposed within the via, wherein the metal connector is adhered to the helium hermetic adhesion layer. The metal connector coats the interior surface of the via along the axial length of the via to define a first cavity from the first major surface to a first cavity length, the metal connector comprising a coating thickness of less than 12 μm at the first major surface. Additionally, the metal connector coats the interior surface of the via along the axial length of the via to define a second cavity from the second major surface to a second cavity length, the metal connector comprising a coating thickness of less than 12 μm at the second major surface and fully fills the via between the first cavity and the second cavity.

A PCB for wireless power transfer includes an antenna and the antenna includes a coil. A method for manufacturing the PCB includes providing a prefabricated PCB, the prefabricated PCB including a PCB design and a first area and providing a first sheet of a conductive metal for the first area. The method includes applying an etch resistant coating on a coil area within the first area and laser cutting the first sheet within the coil area, based on a laser cutting path for a first plurality of turns for a first layer of the coil, the first geometry configured wireless power transfer. The method further includes substantially exposing the first sheet to an etching solution, the etching solution substantially removing first portions of the conductive metal from the substrate to define, at least, first turn gaps between at least two of the first plurality of turns.

A method of manufacturing a component for a stretchable electronic device comprises providing a silicon wafer comprising a first surface and a second surface; applying a layer of a conductive metal onto at least a portion of the first surface of the silicon wafer; providing a stretchable silicone substrate having a first surface and a second surface; and plasma bonding at least a portion of the second surface of the silicon wafer to at least a portion of the first surface of the stretchable silicone substrate.

A method of fabricating a substrate having a through via includes: providing a carrier board having a release layer thereon; attaching the substrate onto the carrier board via the release layer; applying a light beam to the substrate to form a first blind hole in the substrate, wherein the first blind hole penetrates a first surface and a second surface of the substrate; performing an enlargement process on the first blind hole to form a second blind hole; forming a through via in the second blind hole; and performing a de-bonding process to release the substrate having a through via from the carrier board.

A circuit board etching device for improving etching factor, comprising: a circuit board conveying device, which laterally conveys a circuit board; a circuit forming etching tank and a first etchant spraying unit, the first etchant spraying unit sprays a first etchant on the etching surface of the circuit board; and a circuit modification etching tank and a second etchant spraying unit, the second etchant spraying unit sprays a second etchant on the etching surface of the circuit board, and make the etching speed of the circuit modification etching tank slower than the etching speed of the circuit forming etching tank, whereby having the effect of improving the etching factor of the circuit board

A glass core device with a wiring pattern on a first surface of a glass core and a wiring pattern on a second surface thereof being electrically connected via a wiring pattern embedded in TGVs formed in the glass core. In a state of being cut out by dicing, each glass core has a second surface and side faces which are continuously covered with an outer protective layer.

A composite circuit board includes a composite circuit board unit, a first solder mask formed on a first metal protection layer of the composite circuit board unit, and a second solder mask formed on a second metal protection layer of the composite circuit board unit. Two ends of a first outer conductive circuit are bent back toward each other and spaced apart a predetermined distance to form a first window. Two ends of a second outer conductive circuit are bent back toward each other and spaced apart a predetermined distance to form a second window.