A thermosetting silicone resin composition contains the following components (A-1) to (D): (A-1) an alkenyl group-containing linear organopolysiloxane; (A-2) a branched organopolysiloxane shown by (R.sup.1.sub.3SiO.sub.1/2).sub.a(R.sup.2.sub.3SiO.sub.1/2).sub.b(SiO.sub.4/2).sub.c (1); (B-1) a branched organohydrogenpolysiloxane shown by (HR.sup.2.sub.2SiO.sub.1/2).sub.d(R.sup.2.sub.3SiO.sub.1/2).sub.e(SiO.sub.4/2).sub.f (2); (B-2) a linear organohydrogenpolysiloxane shown by (R.sup.2.sub.3SiO.sub.1/2).sub.2(HR.sup.2SiO.sub.2/2).sub.x(R.sup.2.sub.2SiO.sub.2/2).sub.y (3); (C) an adhesion aid which is an epoxy group-containing branched organopolysiloxane; and (D) a catalyst containing a combination of a zero-valent platinum complex with a divalent platinum complex and/or a tetravalent platinum complex. This provides a thermosetting silicone resin composition which causes little contamination at a gold pad portion and has excellent adhesiveness to a silver lead frame.

According to one embodiment, a method for manufacturing a semiconductor device includes forming a plurality of recess portions on a first surface of a support. Each recess portion is between protrusion portions on the first surface. A stacked body is then placed into each of the recess portions. The stacked body is a plurality of semiconductor chips stacked on each other or the like. The recess portions are filled with a resin layer. The resin layer covers the stacked bodies inside the recess portions. A protrusion portion of the support is irradiated with a laser beam to form a modified portion in the protrusion portion. The support is divided along the protrusion portions into separate pieces.

A interposer sandwich structure comprises a top interposer and a bottom interposer enclosing an integrated circuit electronic device that includes means for attaching the device to the bottom interposer, and an interconnection structure connecting the top interposer to the bottom interposer. The top interposer may also be directly connected to a chip carrier in addition to the bottom interposer. The structure provides shielding and protection of the device against Electrostatic Discharge (ESD), Electromagnetic Interference (EMI), and Electromagnetic Conductivity (EMC) in miniaturized 3D packaging.

Capacitive interconnects and processes for fabricating the capacitive interconnects are provided. In some embodiments, the capacitive interconnect includes first metal layers, second metal layers; and dielectric layers including a dielectric layer that intercalates a first metal layer of the first metal layers and a second metal layer of the second metal layers. Such layers can be assembled in a nearly concentric arrangement, where the dielectric layer abuts the first metal layer and the second metal layer abuts the dielectric layer. In addition, the capacitive interconnect can include a first electrode electrically coupled to at least one of the first metal layers, and a second electrode electrically coupled to at least one of the second metal layers, the second electrode assembled opposite to the first electrode. The first electrode and the second electrode can include respective solder tops. The capacitive interconnects can be utilized in a semiconductor package, providing a compact assembly that can reduce the utilization of real estate in a board substrate onto which the semiconductor package is mounted.

A semiconductor device package that incorporates a combination of ceramic, organic, and metallic materials that are coupled using silver is provided. The silver is applied in the form of fine particles under pressure and a low temperature. After application, the silver forms a solid that has a typical melting point of silver, and therefore the finished package can withstand temperatures significantly higher than the manufacturing temperature. Further, since the silver is an interfacial material between the various combined materials, the effect of differing material properties between ceramic, organic, and metallic components, such as coefficient of thermal expansion, is reduced due to low temperature of bonding and the ductility of the silver.

A packaging substrate is provided, which includes: an insulating layer; a plurality of conductive bumps formed on the insulating layer, wherein each of the conductive bumps has a post body exposed from the insulating layer and a conductive pad embedded in the insulating layer, the post body being integrally formed with and less in width than the conductive pad; and a plurality of conductive posts disposed on the conductive pads and embedded in the insulating layer. As such, a semiconductor chip can be bonded to the packaging substrate through the conductive bumps. The present disclosure further provides a method for fabricating the packaging substrate.

Semiconductor package structures are provided. An interposer is bonded to a printed circuit board (PCB) or package substrate through first solder bumps disposed on a first side of the interposer. The first solder bumps have a first pitch. A plurality of semiconductor chips are formed, and each of the semiconductor chips is bonded to a second side of the interposer through second solder bumps. The second solder bumps have a second pitch that is less than the first pitch. Each of the semiconductor chips includes a substrate with one or more transistors or integrated circuits formed thereon.

Implementations of a semiconductor package may include: a substrate, a case coupled to the substrate and a plurality of press-fit pins. The press-fit pins are molded into and fixedly coupled with the case. The pins are also electrically and mechanically coupled to the substrate.

A semiconductor device, including a conductive plate having a front surface that includes a plurality of bonding regions and a plurality of non-bonding regions in peripheries of the bonding regions, a plurality of semiconductor elements mounted on the conductive plate in the bonding regions, and a resin encapsulating therein at least the plurality of semiconductor elements and the front surface of the conductive plate. The conductive plate has, at the front surface thereof in the non-bonding regions, a plurality of holes.

Exemplary embodiments of the invention include a method and apparatus for assembling a semiconductor device. The method may include heating the semiconductor device, which comprises a printed circuit card and a packaging laminate, according to a device heating profile to melt solder material located between an array of contact points on the printed circuit card and an array of corresponding contact points on the packaging laminate; and cooling the semiconductor device to solidify the solder material, wherein during at least a portion of the cooling a temperature of the printed circuit card is kept at substantially a same temperature or a higher temperature than a temperature of an electronic module attached to the packaging laminate opposite the corresponding array of contact points.