A method of manufacturing a semiconductor package includes: hybrid-bonding a semiconductor chip, including a through-silicon via, to an upper surface of a semiconductor wafer, wet-etching a surface of the semiconductor chip to expose the through-silicon via, covering the exposed through-silicon via with a material, including an organic resin and an inorganic filler, to form an encapsulation layer, removing an upper surface of the encapsulation layer to expose the through-silicon via, and forming a redistribution structure electrically connected to the through-silicon via.

A semiconductor device and a method of making the same are provided. A first die and a second die are placed over a carrier substrate. A first molding material is formed adjacent to the first die and the second die. A first redistribution layer is formed overlying the first molding material. A through via is formed over the first redistribution layer. A package component is on the first redistribution layer next to the copper pillar. The package component includes a second redistribution layer. The package component is positioned so that it overlies both the first die and the second die in part. A second molding material is formed adjacent to the package component and the first copper pillar. A third redistribution layer is formed overlying the second molding material. The second redistribution layer is placed on a substrate and bonded to the substrate.

Integrated circuit packages with multiple integrated circuit dies are provided. A multichip package may include at least two integrated circuit dies that communicate using an embedded multi-die interconnect bridge (EMIB) in a substrate of the multi-chip package. The EMIB may receive power at contact pads formed at a back side of the EMIB that are coupled to a back side conductor on which the EMIB is mounted. The back side conductor may be separated into multiple regions that are electrically isolated from one another and that each receive a different power supply voltage signal or data signal from a printed circuit board. These power supply voltage signals and data signals may be provided to the two integrated circuit dies through internal microvias or through-silicon vias formed in the EMIB.

A patch structure of an integrated circuit package comprises a core having a first side facing downwards and a second side facing upwards. A first solder resist (SR) layer is formed on the first side of the core, wherein the first SR layer comprises a first layer interconnect (FLI) and has a first set of one or more microbumps thereon to bond to one or more logic die. A second solder resist (SR) layer is formed on the second side of the core, wherein the second SR layer has a second set of one or more microbumps thereon to bond with a substrate. One or more bridge dies includes a respective sets of bumps, wherein the one or more bridge dies is disposed flipped over within the core such that the respective sets of bumps face downward and connect to the first set of one or more microbumps in the FLI.

A semiconductor structure includes a fan-out package, a packaging substrate, an solder material portions bonded to the fan-out package and the packaging substrate, an underfill material portion laterally surrounding the solder material portions, and at least one cushioning film located on the packaging substrate and contacting the underfill material portion and having a Young's modulus is lower than a Young's modulus of the underfill material portion.

An apparatus is provided which comprises: a plurality of dielectric layers forming a substrate, a plurality of first conductive contacts on a first surface of the substrate, a cavity in the first surface of the substrate defining a second surface parallel to the first surface, a plurality of second conductive contacts on the second surface of the substrate, one or more integrated circuit die(s) coupled with the second conductive contacts, and mold material at least partially covering the one or more integrated circuit die(s) and the first conductive contacts. Other embodiments are also disclosed and claimed.

Multiple component package structures are described in which an interposer chiplet is integrated to provide fine routing between components. In an embodiment, the interposer chiplet and a plurality of conductive vias are encapsulated in an encapsulation layer. A first plurality of terminals of the first and second components may be in electrical connection with the plurality of conductive pillars and a second plurality of terminals of first and second components may be in electrical connection with the interposer chiplet.

A chip package structure and a storage system are provided. The chip package structure includes a chipset, a first Re-Distribution Layer (RDL), and a bonding pad region. The chipset includes a plurality of chips distributed horizontally. The first RDL is disposed on a first surface of the chipset. The bonding pad region includes a plurality of bonding pads, the plurality of bonding pads are located on a side surface of the first RDL away from the chipset, and the plurality of bonding pads are connected to the plurality of chips through the first RDL.

According to the various aspects, the present device includes a printed circuit board having a top surface and a bottom surface, with a plurality of semiconductor devices coupled to the top surface and a flexible electromagnetic shield wrap conformally positioned over and between the plurality of semiconductor devices and the top surface of the printed circuit board. The flexible electromagnetic shield wrap is conformally positioned by applying a vacuum and is removable after the vacuum seal is broken.

An integrated circuit (IC) package comprising an IC die, the IC die having a first surface and an opposing second surface. The IC die comprises a semiconductor material. The first surface comprises an active layer. A thermoelectric cooler (TEC) comprising a thermoelectric material is embedded within the IC die between the first surface and the second surface and adjacent to the active layer. The TEC has an annular shape that is substantially parallel to the first and second surfaces of the IC die. The thermoelectric material is confined between an outer sidewall along an outer perimeter of the TEC and an inner sidewall along an inner perimeter of the TEC. The outer and inner sidewalls are substantially orthogonal to the first and second surfaces of the IC die.