A circuit board including a substrate, a photo imageable dielectric layer and a plurality of conductive bumps is provided. The substrate has a first surface and a first circuit layer, wherein the first surface has a chip disposing area and an electrical connection area, and the first circuit layer is embedded in the first surface. The photo imageable dielectric layer is disposed on the electrical connection area and has a plurality of openings, wherein parts of the first circuit layer is exposed by the openings. The conductive bumps are disposed at the openings respectively and connected to the first circuit layer, wherein a side surface of each of the conductive bumps is at least partially covered by the photo imageable dielectric layer. In addition, a manufacturing method of the circuit board is also provided.

A method for manufacturing a printed wiring board includes forming on carrier a laminate including a second metal foil, a resin layer laminated on the second foil and a first metal foil laminated on the resin layer, irradiating laser upon the first foil such that opening is formed through the first foil and resin layer and exposes surface of the second foil at bottom, plating the first foil such that a via conductor is formed in the opening and a first conductor layer including the first foil and an electroplating film is formed on surface of the resin layer, removing the carrier from the laminate, patterning the first conductor layer on the resin layer, and patterning the second foil such that a second conductor layer including the second foil is formed on opposite surface of the resin layer. The second foil has thickness greater than thickness of the first foil.

A manufacturing method of a circuit substrate includes the following steps. The peripheries of two metal layers are bonded to form a sealed area. Two insulating layers are formed on the two metal layers. Two including upper and bottom conductive layers are formed on the two insulating layers. Then, the two insulating layers and the two conductive layers are laminated so that the two metal layers bonded to each other are embedded between the two insulating layers. A part of the two insulating layers and a part of the two conductive layers are removed to form a plurality of blind holes exposing the two metal layers. A conductive material is formed in the blind holes and on the remained two conductive layers. The sealed area of the two metal layers is separated to form two separated circuit substrates.

A method for manufacturing a printed wiring board with conductive posts includes forming on a first foil provided on carrier a first conductive layer including mounting pattern to connect electronic component via conductive posts, forming on the first foil a laminate including an insulating layer and a second foil to form the laminate on the first conductive layer, removing the carrier, forming a metal film on the laminate and first film, forming resist on the metal film to have pattern exposing portion of the metal film corresponding to the mounting pattern and portion of the second foil for a second conductive layer, forming an electroplating layer on the portion of the metal film not covered by the resist, removing the resist, and applying etching to remove the first and second foils below the metal film exposed by the removing the resist and to form the posts on the mounting pattern.

A printed circuit board, an electronic module and a method of manufacturing the printed circuit board are provided. The printed circuit board includes a plurality of insulation layers, metal layers formed on the plurality of insulation layers, a via formed for interlayer electrical connection of the metal layers, a trench penetrating the insulation layers, and a heat-transfer structure formed in the trench.

A printed wiring board includes a resin insulating layer, a projecting conductor layer formed on a surface of the resin insulating layer such that the projecting conductor layer is projecting from the surface of the resin insulating layer, and an integral conductor structure formed in the resin insulating layer and including a via conductor portion and an embedded conductor layer portion such that the embedded conductor layer portion is embedded in the resin insulating layer on the opposite side of the resin insulating layer with respect to the projecting conductor layer and has an exposed surface exposed from the resin insulating layer and the via conductor portion is formed through the resin insulating layer and is connecting the embedded conductor layer portion and projecting conductor layer. The projecting conductor layer and integral conductor structure are formed such that the projecting conductor layer and integral conductor structure are individual conductor structures.

A microelectronic device includes a laminated mounting substrate including a die side and a land side with a surface finish layer disposed in a recess on the mounting substrate die side. An electrically conductive first plug is in contact with the surface finish layer and an electrically conductive subsequent plug is disposed on the mounting substrate land side and it is electrically coupled to the electrically conductive first plug and disposed directly below the electrically conductive first plug.

Methods of forming a microelectronic packaging structure and associated structures formed thereby are described. Those methods may include attaching a microfluidic die to a package structure, wherein the microfluidic die comprises a plurality of asymmetric electrodes that may be coupled with signal pads disposed within the package structure.

A manufacturing method of a circuit substrate includes the following steps. The peripheries of two metal layers are bonded to form a sealed area. Two insulating layers are formed on the two metal layers. Two including upper and bottom conductive layers are formed on the two insulating layers. Then, the two insulating layers and the two conductive layers are laminated so that the two metal layers bonded to each other are embedded between the two insulating layers. A part of the two insulating layers and a part of the two conductive layers are removed to form a plurality of blind holes exposing the two metal layers. A conductive material is formed in the blind holes and on the remained two conductive layers. The sealed area of the two metal layers is separated to form two separated circuit substrates.

A manufacturing method of a circuit substrate includes the following steps. The peripheries of two metal layers are bonded to form a sealed area. At least a through hole passing through the sealed area is formed. Two insulating layers are formed on the two metal layers. Two conductive layers are formed on the two insulating layers. The two insulating layers and the two conductive layers are laminated to the two metal layers bonded to each other, wherein the metal layers are embedded between the two insulating layers, and the two insulating layers fill into the through hole. The sealed area of the two metal layers is separated to form two separated circuit substrates. Therefore, the thinner substrate can be operated in the following steps, such as patterning process or plating process. In addition, the method may be extended to manufacture the circuit substrate with odd-numbered layer or even-numbered layer.