Abstract: A packaging substrate includes: a core board having opposite first and second surfaces and a cavity penetrating therethrough; a semiconductor chip disposed in the cavity and having an active surface with electrode pads and an opposite inactive surface; a first reinforcing dielectric layer containing a reinforcing material disposed on the first surface and the active surface and filling the gap between the chip and the cavity; a second reinforcing dielectric layer containing a reinforcing material disposed on the second surface and the inactive surface and filling the gap between the chip and the cavity; and first and second wiring layers disposed on the first and second reinforcing dielectric layers respectively and the first wiring layer electrically connecting to the electrode pads. The first and second reinforcing dielectric layers enhance the support force of the entire structure to thereby prevent delamination of the wiring layers from the dielectric layers and increase product yield and reliability.

Abstract: A method for fabricating a packaging substrate includes: stacking two metal layers; encapsulating the two metal layers with assistant dielectric layers; forming built-up structures on the assistant dielectric layers, respectively; and separating the built-up structures along the interface between the two metal layers so as to form two packaging substrates. Owing to the adhesive characteristic of the assistant dielectric layers, the two metal layers are unlikely to separate from each other during formation of the built-up structures. But after portions of the dielectric layer around the periphery of the metal layers are cut and removed, the two metal layers can be readily separated from each other. The two metal layers can be patterned to form wiring layers, metal bumps, or supporting structures to avoid waste of materials. A packaging substrate and a fabrication method thereof are provided.

Abstract: A method for fabricating a packaging substrate includes: providing a base having a release film with two opposite surfaces, two first auxiliary dielectric layers enclosing the release film, and two metal layers disposed on the two first auxiliary dielectric layers, therewith an effective area defined on the two metal layers; forming an inner wiring layer from the two metal layers; forming on each of the two first auxiliary dielectric layers and the inner wiring layers a built-up structure having first conductive pads so as for two initial substrates to be formed on the opposite surfaces of the release film; removing whatever is otherwise lying outside the effective area; removing the release film; and forming dielectric layer openings in the two first auxiliary dielectric layers so as for two substrate bodies to be formed from the initial substrates, wherein a portion of the inner wiring layers are exposed to thereby function as second conductive pads.

Abstract: A heat-conductive package structure includes a carrier board having a first surface and an opposing second surface and formed with a through opening passing the carrier board; a first heat-conductive structure including a heat-conductive hole in the through opening, a first heat-conductive sheet on the carrier board, and a second heat-conductive sheet on the carrier board, wherein the first and second heat-conductive sheets are conductively connected by the heat-conductive hole; a first dielectric layer formed on the first surface of the carrier board and formed with a first opening for exposing the first heat-conductive sheet; a second dielectric layer formed on the second surface of the carrier board and formed with at least a second opening for exposing a portion of the second heat-conductive sheet; and a second heat-conductive structure formed in the second opening and mounted on the second heat-conductive sheet.

Abstract: Provided are a circuit board structure and a fabrication method thereof, including the steps of: forming a first circuit layer in a first dielectric layer and exposing the first circuit layer therefrom; forming a second dielectric layer on the first dielectric layer and the first circuit layer, and forming a second circuit layer on the second dielectric layer; forming a plurality of first conductive vias in the second dielectric layer for electrically connecting to the first circuit layer to thereby dispense with a core board and electroplated holes and thus facilitate miniaturization. Further, the first dielectric layer is liquid before being hardened and is formed on the first dielectric layer that enhances the bonding between layers of the circuit board and the structure.

Abstract: A lid for a micro-electro-mechanical device and a method for fabricating the same are provided. The lid includes a board with opposite first and second surfaces and a first conductor layer. The first surface has a first metal layer thereon. The first metal layer and the board have a recess formed therein. The recess has a bottom surface and a side surface adjacent thereto. The first conductor layer is formed on the first metal layer and the bottom and side surfaces of the recess. The shielding effect of the side surface of the board is enhanced because of the recess integral to the board, the homogeneous bottom and side surfaces of the recess, and the first conductor layer covering the first metal layer, the bottom and side surfaces of the recess. Hence, the shielding effect upon the micro-electro-mechanical device is enhanced.

Abstract: A packaging substrate with an embedded semiconductor component and a method of fabricating the same are provided, including: fixing a semiconductor chip with electrode pads to an assisting layer with apertures through an adhesive member, wherein each of the electrode pads has a bump formed thereon, each of the apertures is filled with a filling material, and the bumps correspond to the apertures, respectively; forming a first dielectric layer on the assisting layer to encapsulate the semiconductor chip; removing the bumps and the filling material to form vias; and forming a first wiring layer on the first dielectric layer and forming first conductive vias in the vias to provide electrical connections between the electrode pads and the first wiring layer, wherein the first wiring layer comprises a plurality of conductive lands formed right on the first conductive vias, respectively.

Abstract: Provided are a package structure and a package substrate, including: a substrate body having a plurality of matrix-arranged electrical contact pads formed on at least one surface thereof, wherein a solder mask layer is formed on said surface and has a plurality of openings for exposing the electrical contact pads, respectively; a first electroless-plated layer disposed on the electrical contact pads, on the walls of the openings and at the peripheries of the openings; and a second electroless-plated layer disposed on the first electroless-plated layer, the first and second electroless-plated layers constituting a recessed electrical connection structure. By forming the even electroless-plated layers on the electrical contact pads. The invention overcomes drawbacks of the prior art, namely breakage of interfaces between solder bumps and electrical contact pads and even damage of the package structure otherwise caused by excessive differences in stress between the solder bumps.

Abstract: Disclosed is a package structure including a semiconductor chip disposed in a core board having a first surface and an opposite second surface. The package structure further includes a plurality of first and second electrode pads disposed on an active surface and an opposite inactive surface of the semiconductor chip respectively, the semiconductor chip having a plurality of through-silicon vias for electrically connecting the first and second electrode pads. As a result, the semiconductor chip is electrically connected to the two sides of the package structure via the through-silicon vias instead of conductive through holes, so as to enhance electrical quality and prevent the inactive surface of the semiconductor chip from occupying wiring layout space of the second surface of the core board to thereby increase wiring layout density and enhance electrical performance.

Abstract: A printed circuit board having a semiconductor component embedded therein and a method of fabricating the same are proposed, including: providing a circuit board body having a through hole, a first surface and an opposing second surface both provided with a core circuit layer thereon; forming on the first surface a first dielectric layer with a dielectric-layer opening for exposing part of the first surface; forming a first circuit layer on the first dielectric layer, and forming first conductive vias in the first dielectric layer; fixing in position to the through hole a semiconductor chip having an active surface with electrode pads thereon; forming in the dielectric-layer opening a third dielectric layer for covering the active surface of the semiconductor chip; forming a third circuit layer on the third dielectric layer, and forming third conductive vias in the third dielectric layer. The printed circuit board thus fabricated is warpage-free.