A semiconductor device includes a first semiconductor chip having a first surface and a second surface; a first adhesive layer on the first surface; a second semiconductor chip that includes a third surface and a fourth surface, and a connection bump on the third surface. The connection bump is coupled to the first adhesive layer. The semiconductor device includes a wiring substrate connected to the connection bump. The semiconductor device includes a first resin layer covering the connection bump between the second semiconductor chip and the wiring substrate, and covers one side surface of the second semiconductor chip connecting the third surface and the fourth surface. The first adhesive layer covers an upper portion of the at least one side surface. The first resin layer covers a lower portion of the at least one side surface. The first adhesive layer and the first resin layer contact each other.

A chip package fabricating kit includes a metal cover, at least one screw, and at least one screw cap. The metal cover includes a cap portion and at least one leg. The cap portion substantially presses against the BGA package. The leg substantially presses a PCB board that loads the BGA package. The leg forms a concave space with the metal cover for substantially encompassing the BGA package. Each the screw screws through a corresponding leg from top to bottom. Each the screw screws the PCB board at a first side. The screw cap respectively corresponds to the screw and one leg. The screw cap caps and fixes a tail of its corresponding screw for affixing the PCB board. A height of the concave space is dynamically adjusted by adjusting a degree that the screw screws with the screw cap. Such that the concave space substantially clamps the BGA package.

The present invention relates generally to compositions for use in biological and chemical separations, as well as other applications. More specifically, the present invention relates to hybrid felts fabricated from electrospun nanofibers with high permeance and high capacity. Such hybrid felts utilize derivatized cellulose, and at least one non-cellulose-based polymer that may be removed from the felt by subjecting it to moderately elevated temperatures and/or solvents capable of dissolving the non-cellulose-based polymer to leave behind a porous nanofiber felt having more uniform pore sizes and other enhanced properties when compared to single component nanofiber felts.

The present invention relates generally to compositions for use in biological and chemical separations, as well as other applications. More specifically, the present invention relates to hybrid felts fabricated from electrospun nanofibers with high permeance and high capacity. Such hybrid felts utilize derivatized cellulose, and at least one non-cellulose-based polymer that may be removed from the felt by subjecting it to moderately elevated temperatures and/or solvents capable of dissolving the non-cellulose-based polymer to leave behind a porous nanofiber felt having more uniform pore sizes and other enhanced properties when compared to single component nanofiber felts.

The disclosed embodiments provide a method for integrating an optical interposer with one or more electronic dies and an optical-electronic (OE) printed circuit board (PCB). This method involves first applying surface-connection elements to a surface of the optical interposer, and then bonding the one or more electrical dies to the optical interposer using the surface-connection elements. Next, the method integrates the OE-PCB onto the surface of the optical interposer, wherein the integration causes the surface-connection elements to provide electrical connections between the optical interposer and the OE-PCB.

Embodiments include an encapsulation material, one or more semiconductor packages, and methods of the semiconductor packages. A semiconductor package including dies disposed on a package substrate. The semiconductor package also includes at least one of an underfill layer, a mold layer, and a dielectric layer on or in the package substrate. The semiconductor package further includes an encapsulation material having a fluorescent chemical compound and an epoxy. The encapsulation material may be incorporated into at least one of the underfill layer, the mold layer, and/or the dielectric layer on or in the package substrate. The fluorescent chemical compound of the encapsulation material may include at least one of a poly(vinylcarbazole) (PVCz), a 1,4-Bis(5-phenyl-2-oxazolyl) benzene (POPOP), and/or a plurality of conjugated, aromatic molecules and polymers. The encapsulation material may include at least one of a hardener, a filler, an additive, and/or a polymer.

Embodiments include an encapsulation material, one or more semiconductor packages, and methods of the semiconductor packages. A semiconductor package including dies disposed on a package substrate. The semiconductor package also includes at least one of an underfill layer, a mold layer, and a dielectric layer on or in the package substrate. The semiconductor package further includes an encapsulation material having a fluorescent chemical compound and an epoxy. The encapsulation material may be incorporated into at least one of the underfill layer, the mold layer, and/or the dielectric layer on or in the package substrate. The fluorescent chemical compound of the encapsulation material may include at least one of a poly(vinylcarbazole) (PVCz), a 1,4-Bis(5-phenyl-2-oxazolyl) benzene (POPOP), and/or a plurality of conjugated, aromatic molecules and polymers. The encapsulation material may include at least one of a hardener, a filler, an additive, and/or a polymer.

A method of establishing conductive connections is disclosed. The method includes providing an integrated circuit die having a plurality of solder balls each of which has an oxide layer on an outer surface of the solder ball. The method also includes performing a heating process to heat at least the solder balls and applying a force causing each of a plurality of piercing bond structures on a substrate to pierce one of the solder balls and its associated oxide layer to thereby establish a conductive connection between the solder ball and the piercing bond structure.

An adhesive member includes: a conductive particle layer including a plurality of conductive particles; a non-conductive layer disposed on the conductive particle layer; and a screening layer interposed between the conductive particle layer and the non-conductive layer and includes a plurality of screening members spaced apart from each other.

An adhesive member includes: a conductive particle layer including a plurality of conductive particles; a non-conductive layer disposed on the conductive particle layer; and a screening layer interposed between the conductive particle layer and the non-conductive layer and includes a plurality of screening members spaced apart from each other.