A component carrier includes a stack having at least one electrically insulating layer structure and/or at least one electrically conductive layer structure; a heat removing and electrically conductive base structure; a component which is connected to the base structure so as to at least partially protrude from the base structure and so as to be laterally at least partially covered by an electrically insulating material of the stack; and an electrically conductive top structure on or above a top main surface of the component. A method of manufacturing such a component carrier is disclosed.

A method for forming a circuit board includes forming a first dielectric layer, a first circuit layer in the first dielectric layer, a second circuit layer on the first dielectric layer, and a plurality of conductive vias in the first dielectric layer and connecting the first circuit layer to the second circuit layer; forming a second dielectric layer on the first dielectric layer and the second circuit layer; forming a plurality of openings in the second dielectric layer to expose a plurality of parts of the second circuit layer; forming a seed layer on the exposed parts of the second circuit layer and sidewalls of the openings; and forming a plurality of bonding layers on the seed layer, wherein the bonding layers and the seed layer are made of copper, and the bonding layers are porous.

According to one aspect of the present invention, a printed circuit board includes: an insulating base film; a conductive pattern that is partially layered on a surface side of the base film; a coating layer that is layered on a surface of a layered structure including the base film and the conductive pattern and having an opening portion that partially exposes the conductive pattern; and a tin plating layer that is layered on a surface of the conductive pattern exposed from the opening portion, wherein an average peel length of the coating layer from the conductive pattern with an inner edge of the opening portion as a base end is less than or equal to 20 μm.

Light reflection from a metal mesh touch sensor is reduced or prevented by encasing the metal lines with a passivation coating and including non-reflective nanoparticles in the patterning photoresist. The photoresist is mixed with catalytic nanoparticles wherein the nanoparticles are formed to minimize light reflection. The nanoparticles may be carbon coated metallic particles, or uncoated palladium nanoparticles. Also, a standoff photoresist layer may be included between the substrate and the photoresist composition to prevent reflection from the edges of the metallic lines.

A flexible printed circuit board of the present invention includes an insulating base film and an electrode stacked on a first surface of the base film, in which the electrode includes a low-melting-point metal layer on a surface of the electrode, and a plate- or strip-like rigid member electrically insulated from the electrode is disposed in a region of a second surface of the base film opposite from the electrode.

A wiring board, a multilayer wiring board, and a method of manufacturing a wiring board adapted to make the filling of through holes and the formation of fine wiring patterns. The wiring board comprises an insulator; a through hole between front and back surfaces of the insulator; a through hole conductor for electrically connecting front and back surface side openings; through hole lands around the front and the back surface side openings, and connected to the through hole conductor; lid plating conductors on the front and the back surface sides, and placed on the respective through hole lands; and wiring patterns formed on the front are compatible and the back surface of the insulator. The thickness of the through hole lands is 1.0 m or more and 10.0 m or less, and the area of each lid plating conductor is less than the area of each through hole land.

Provided is a method for manufacturing a wiring board that forms a wiring layer having favorable adhesion without a resin resist pattern. A method prepares a substrate with seed-layer including: a underlayer on the surface of an insulating substrate; and a seed layer on the surface of the underlayer, the seed layer having a predetermined pattern and containing metal; presses a solid electrolyte membrane against the seed layer and the underlayer, and applies voltage between an anode and the underlayer to reduce metal ions in the membrane and form a metal layer on the surface of the seed layer; and removes an exposed region without the seed layer and the metal layer of the underlayer to form a wiring layer including the underlayer, the seed layer and the metal layer on the surface of the substrate.

A method of manufacturing a printed circuit board includes providing an insulating layer, forming a plating seed layer on the insulating layer, forming a first circuit pattern on the plating seed layer and a second circuit pattern on the first circuit pattern, and forming a top metal layer on the second circuit pattern. The second circuit pattern can be thinner than the first circuit pattern, and the top metal layer can be wider than the second circuit pattern.

A surface finish for a printed circuit board (PCB) and semiconductor wafer includes a nickel disposed over an aluminum or copper conductive metal surface. A barrier layer including all or fractions of a nitrogen-containing molecule is deposited on the surface of the nickel layer to make a barrier layer/electroless nickel (BLEN) surface finish. The barrier layer allows solder to be reflowed over the surface finish. Optionally, gold (e.g., immersion gold) may be coated over the barrier layer to create a nickel/barrier layer/gold (NBG) surface treatment. Presence of the barrier layer causes the surface treatment to be smoother than a conventional electroless nickel/immersion gold (ENIG) surface finish. Presence of the barrier layer causes a subsequently applied solder joint to be stronger and less subject to brittle failure than conventional ENIG.

A manufacturing method of electronic components includes the steps of: providing an insulating layer including a first region and a second region; providing a first metal layer disposed in the first region of the insulating layer; providing a second metal layer disposed on the first metal layer; providing a metal line in the second region of the insulating layer, wherein the metal line is electrically connected to the first metal layer; and removing the metal line to form an electronic component, wherein the electronic component includes the insulating layer; and a first metal bump disposed on the insulating layer and including: the first metal layer disposed on the insulating layer; and the second metal layer disposed on the first metal layer.