Abstract: A semiconductor package carrier board, a method for fabricating the same, and an electronic package having the same are provided. The method includes forming on a circuit structure a graphene layer that acts as an insulation heat dissipating layer. Since the heat conductivity of the graphene layer is far greater than the heat conductivity of ink (about 0.4 W/m·k), which is used as solder resist, the heat of the semiconductor package carrier board can be conducted quickly, and thus can avoid the problem that the heat will be accumulated on the semiconductor package carrier board.

Abstract: A surface acoustic wave (SAW) filter package structure includes a dielectric substrate having a dielectric layer, a first patterned conductive layer, a second patterned conductive layer, and a conductive connection layer. The conductive connection layer is electrically connected between the first patterned conductive layer and the second patterned conductive layer, which are disposed at opposite sides of the dielectric layer. The second patterned conductive layer has a finger electrode portion. An active surface of a chip is faced toward the finger electrode portion. A polymer sealing frame is disposed between the chip and the dielectric substrate and surrounds the periphery of the chip to form a chamber together with the chip and the dielectric substrate. The mold sealing layer is disposed on the dielectric substrate and covers the chip and the polymer sealing frame. A manufacturing method of the SAW filter package structure is also disclosed.

Abstract: A semiconductor packaging substrate and a method for fabricating the same are provided. The method includes forming a solder resist structure having a hole on a circuit structure, with a portion of the circuit structure exposed from the hole, and forming a cup-shaped solder stand on the exposed circuit layer and a hole wall of the hole. During a packaging process, the design of the solder stand increases a contact area of a solder tin ball with a metal material. Therefore, a bonding force between the solder tin ball and the solder stand is increased, and the solder tin ball can be protected from being broken or fell off. An electronic package having the semiconductor packaging substrate and a method for fabricating the electronic package are also provided.

Abstract: A package apparatus comprises a first wiring layer, a first dielectric material layer, a first conductive pillar layer, a first buffer layer, a second wiring layer, and a protection layer. The first wiring layer has a first surface and a second surface opposite to the first surface. The first dielectric material layer is disposed within partial zone of the first wiring layer. The first conductive pillar layer is disposed on the second surface of the first wiring layer. The first buffer layer is disposed within partial zone of the first conductive pillar layer. The second wiring layer is disposed on the first buffer layer and one end of the first conductive pillar layer. The protection layer is disposed on the first buffer layer and the second wiring layer.

Abstract: A package structure for a semiconductor device includes a first conductive layer, a second conductive layer, a first die, a second die, a plurality of first blind via pillars and a conductive structure. The first conductive layer has a first surface and a second surface. The first die and the second die respectively have an active surface and a back surface, which are disposed opposite to each other. There is a plurality of metal pads disposed on the active surface. The first die is attached to the first surface of the first conductive layer with its back surface, and the second die is attached to the second surface of the first conductive layer with its back surface. The first and second conductive layers, the first and second dies, the first blind hole pillars and conductive structure are covered by a dielectric material.

Abstract: A flip-chip package substrate and a method for fabricating the same are provided. An insulation layer is formed on two opposing sides of a middle layer to form a composite core structure and increase the rigidity of the flip-chip package substrate. Therefore, the core structure can be made thinner. The conductive structures can also have a smaller end size, and more conductive points can be disposed within a unit area. Therefore, a circuit structure can be produced that have a fine line pitch and a high wiring density, satisfy the packaging demands of highly integrated circuit/large size substrate, and avoid an electronic package from being warpage.

Abstract: A flip-chip package substrate and a method for preparing the same in accordance with the present disclosure includes stacking a reinforcement layer on two opposing sides of a middle layer in order to increase the rigidity of the flip-chip package substrate, and promoting a thin middle layer, wherein the sizes of the end faces of conductive portions can be minimized according to needs. This increases the number of electrical contacts possible in a unit area and enables the creation of finer line pitch and higher layout density of the circuit portions, thereby satisfying the need for packaging of high integration/large scale chips while preventing warpage from occurring in the electronic packages.

Abstract: A package substrate and method of manufacturing a package substrate and a semiconductor device package are provided. The package substrate includes a circuit layer, a molding layer and a sacrificial layer. The circuit layer includes conductive traces and conductive pads. The molding layer has an upper surface and a lower surface opposite to the upper surface, wherein the molding layer partially covers the conductive traces and the conductive pads, and first surfaces of the conductive traces and first surfaces of the conductive pads are exposed from the upper surface of the molding layer. The sacrificial layer covers the lower surface of the molding layer, second surfaces of the conductive pads.

Abstract: This disclosure provides a package substrate, a flip-chip package circuit, and their fabrication methods. The package substrate includes: a first wiring layer having a first dielectric material layer and a first metal wire protruding from the first dielectric material layer; a conductive pillar layer formed on the first wiring layer and including a molding compound layer, a second dielectric material layer formed on the molding compound layer, and a metal pillar connected to the first metal wire; a second wiring layer formed on the conductive pillar layer and including a second metal wire connected to the metal pillar; and a protection layer formed on the second wiring layer.

Abstract: A method for fabricating an interposer substrate is provided, including forming a wiring layer on a carrier, forming an insulating layer on the carrier, forming on the wiring layer a wiring build-up layer structure that is electrically connected to the wiring layer, forming on the wiring build-up layer structure external connection pillars that are electrically connected to the wiring build-up layer structure, and removing the carrier, with the wiring layer is exposed from a surface of the insulating layer. The fabrication process of the via can be bypassed in the fabrication process by forming coreless interposer substrate on the carrier, such that the overall cost of the fabrication process can be decreased, and the fabrication process is simple. This invention further provides the interposer substrate.

Abstract: A method of fabricating a packaging substrate is provided, which includes: forming on a carrier a conductor layer having a plurality of openings; forming a plurality of conductive bumps on the conductor layer, wherein each of the conductive bumps has a post body disposed in a corresponding one of the openings and a conductive pad disposed on the conductor layer, the post body being integrally formed with the conductive pad and less in width than the conductive pad; forming a plurality of conductive posts on the conductive pads; forming on the carrier a first insulating layer that encapsulates the conductive bumps and the conductive posts; removing the carrier; and removing the entire conductor layer to expose the post bodies from a first surface of the first insulating layer. As such, a semiconductor chip can be bonded to the packaging substrate through the conductive bumps.

Abstract: An electronic package is provided, which includes: an insulating layer; an electronic element embedded in the insulating layer and having a sensing area exposed from the insulating layer; and a circuit layer formed on the insulating layer and electrically connected to the electronic element, thereby reducing the thickness of the overall package structure.

Abstract: This disclosure provides a package substrate fabrication method including: providing a carrier; forming a first dielectric layer on the carrier while enabling the first dielectric layer to be patterned including an opening; forming a first conducting unit on the carrier while enabling the first conducting unit to fill up the opening, a height of the first conducting unit at the opening larger than a thickness of the first dielectric layer, and a width of the first conducting unit larger than a width of the opening; forming a second dielectric layer on the first conducting unit; forming a second conducting unit on the second dielectric layer; forming a third dielectric layer on the second conducting unit; removing the carrier and the first dielectric layer while enabling the part of the first conducting unit in the opening to be removed; and forming a fourth dielectric layer to cover the first conducting unit.

Abstract: A method for fabricating bump structures on chips with a panel type process is provided. First, a panel type substrate is provided. Semiconductor chips are fixed on the panel type substrate. Each semiconductor chip includes metal pads and a passivation layer exposing the metal pads. At least an electroless plating process is performed to form under bump metallurgy structures on the metal pads. The method simplifies the processes of forming electrical connections for semiconductor chips. The panel type process can effectively increase the yield, and reduce the manufacturing cost.

Abstract: The invention provides an interposer substrate and a method of fabricating the same. The method includes: etching a carrier to form a recessed groove thereon; filling a dielectric material in the recessed groove to form a first dielectric material layer, or forming a patterned first dielectric material layer on the carrier; forming a first wiring layer, a first conductive block and a second dielectric material layer on the carrier and the first dielectric material layer sequentially, with the first wiring layer and the first conductive block embedded in the second dielectric material layer; and forming a second wiring layer and a second conductive block on the second dielectric material layer. A coreless interposer substrate having fine pitches is thus fabricated.

Abstract: A semiconductor package structure includes a substrate, a chip, bumps, an encapsulation layer and a thermal expansion-matching layer. The chip is located on a top surface of the substrate. The bumps electrically connect the chip and the inner connection pads of the substrate. The encapsulation layer covers the bumps, the chip and the top surface of the substrate. The thermal expansion-matching layer covers the whole top surface of the encapsulation layer, and exposes the side surfaces of the encapsulation layer. The thermal expansion coefficient of the thermal expansion-matching layer is different from that of the encapsulation layer. The side surface of the thermal expansion-matching layer is flush with that of the encapsulation layer. The thermal expansion-matching layer balances the inner stresses caused by the difference of the thermal expansion. Thus, the invention reduces the warpage problem of the formed package.

Abstract: The disclosure provides an interposer substrate and a method for manufacturing the same. The method includes forming an insulating protection layer having a phosphorus compound on a substrate body, thereby providing toughness and strength as required when the thickness of the interposer substrate becomes too thin, and preventing substrate warpage when the substrate has a shrinkage stress or structural asymmetries.

Abstract: The present disclosure provides an electronic package, including a package substrate and an electronic component formed on the package substrate. The substrate includes an insulating portion, a wiring portion embedded in the insulating portion, and a metal board disposed on the insulating portion and in contact with the wiring portion. The metal board is provided with a plurality of electrical contacts and a heat dissipating portion. The metal board can maintain a predefined heat dissipation area via the heat dissipating portion, and be connected to a circuit board via the electrical contacts.

Abstract: This disclosure provides a package substrate and its fabrication method. The package substrate comprises: a first dielectric material layer have an opening; a first conductive unit including a first part in the opening of the first dielectric material layer and a second part on the first dielectric material layer; and a second dielectric material layer covering the first conductive unit and the first dielectric material layer; wherein a height of the first conductive unit is larger than a thickness of the first dielectric material layer; wherein a cross-section of the second part is larger than that of the first part in the first conductive unit.

Abstract: An interposer substrate includes a first insulating layer having opposite first and second surfaces; a first wiring layer formed in the first insulating layer, with a surface of the first wiring layer exposed from the first surface; first conductive pillars formed in the first insulating layer; a second wiring layer formed on the second surface; second conductive pillars formed on the second wiring layer; a second insulating layer formed on the second surface and covering the second conductive pillars and the second wiring layer, with end surfaces of the second conductive pillars exposed from the second insulating layer; and immersion tin layers formed on the first wiring layer and the end surfaces of second conductive pillars. The immersion tin layers are used as surface processing layers to be applied to products having ball pads that need to be exposed extensively. A method for fabricating the interposer substrate is also provided.