A method of manufacturing a component carrier is disclosed. The method includes providing an electrically insulating layer structure having a front side and a back side, wherein the front side is covered by a first electrically conductive layer structure and the back side is covered by a second electrically conductive layer structure, carrying out a first opening process, such as a first laser drilling, through the first electrically conductive layer structure and into the electrically insulating layer structure from the front side to thereby form a blind hole in the electrically insulating layer structure, and thereafter carrying out a second opening process, such as a second laser drilling, through the second electrically conductive layer structure and through the electrically insulating layer structure from the back side to thereby extend the blind hole into a through hole, in particular a laser through hole, with substantially trapezoidal shape.

The disclosed technology generally relates to forming metallization structures for integrated circuit devices by plating, and more particularly to plating metallization structures that are thicker than masking layers used to define the metallization structures. In one aspect, a method of metallizing an integrated circuit device includes plating a first metal on a substrate in a first opening formed through a first masking layer, where the first opening defines a first region of the substrate, and plating a second metal on the substrate in a second opening formed through a second masking layer, where the second opening defines a second region of the substrate. The second opening is wider than the first opening and the second region encompasses the first region of the substrate.

A catalytic resin is formed by mixing a resin and either homogeneous or heterogeneous catalytic particles, the resin infused into a woven glass fabric to form an A-stage pre-preg, the A-stage pre-preg cured into a B-stage pre-preg, thereafter held in a vacuum and between pressure plates at a gel point temperature for a duration of time sufficient for the catalytic particles to migrate away from the resin rich surfaces of the pre-preg, thereby forming a C-stage pre-preg after cooling. The C-stage pre-preg subsequently has trenches formed by removing the resin rich surface, the trenches extending into the depth of the catalytic particles, optionally including drilled holes to form vias, and the C-stage pre-preg with trenches and holes placed in an electroless bath, whereby traces form in the trenches and holes where the surface of the cured pre-preg has been removed.

A method for manufacturing a printed circuit board includes forming a through hole in an insulating layer of the printed circuit board, filling the through hole by plating to form a plating layer on the insulating layer, and removing the plating layer from the insulating layer; and forming a circuit pattern on the insulating layer.

The method for producing a laminate having a patterned metal foil includes masking the whole surface of a first metal foil in a laminate having the first metal foil, a first insulating resin layer having a thickness of 1 to 200 m and a second metal foil laminated in this order, and patterning the second metal foil.

A circuit board has a dielectric core, a foil top surface, and a thin foil bottom surface with a foil backing of sufficient thickness to absorb heat from a laser drilling operation to prevent the penetration of the thin foil bottom surface during laser drilling. A sequence of steps including a laser drilling step, removing the foil backing step, electroless plating step, patterned resist step, electroplating step, resist strip step, tin plate step, and copper etch step are performed, which provide dot vias of fine linewidth and resolution.

A process for making a circuit board from a catalytic laminate having a resin rich surface with catalytic particles dispersed below a surface exclusion depth includes drilling holes, etching the surface to expose the catalytic particles, electroless plating the unmasked areas, applying a mask to the etched surface, electroplating the exposed areas using the electroless plating to form a continuous conductor, then stripping the mask and etching away the electroless copper deposition.

A single-layer circuit board, multi-layer circuit board, and manufacturing methods therefor. The method for manufacturing the single-layer circuit board comprises the following steps: drilling a hole on a substrate, the hole comprising a blind hole and/or a through hole; on a surface of the substrate, forming a photoresist layer having a circuit negative image; forming a conductive seed layer on the surface of the substrate and a hole wall of the hole; removing the photoresist layer, and forming a circuit pattern on the surface of the substrate, wherein forming a conductive seed layer comprises implanting a conductive material below the surface of the substrate and below the hole wall of the hole via ion implantation, and forming an ion implantation layer as at least part of the conductive seed layer.

An inductor built-in substrate includes a core substrate having openings and first through holes, a magnetic resin filled in the openings and having second through holes, first through-hole conductors formed in the first through holes respectively such that each of the first through-hole conductors includes a metal film, second through-hole conductors formed in the second through holes respectively such that each of the second through-hole conductors includes a metal film, first through-hole lands formed on the core substrate such that each of the first through-hole lands includes a lowermost layer including a metal foil and that the first through-hole lands are connected to the first through-hole conductors respectively, and second through-hole lands formed on the magnetic resin such that each of the second through-hole lands includes a lowermost layer including a plating film and that the second through-hole lands are connected to the second through-hole conductors respectively.

Disclosed is a method for manufacturing a flexible printed circuit board and a flexible printed circuit board manufactured thereby, which minimizes a dielectric loss due to a high frequency signal and preventing a loss of the high frequency signal. The disclosed method for manufacturing the flexible printed circuit board according to an embodiment of the present disclosure includes preparing a base sheet; preparing a bonding sheet having a melting temperature lower than a melting temperature of the base sheet; forming a laminate by stacking the base sheet and the bonding sheet; and bonding by heating and pressurizing the laminate.