A semiconductor package includes; laterally stacked semiconductor blocks disposed side by side in a first horizontal direction on a redistribution structure, wherein each semiconductor block among the laterally stacked semiconductor blocks includes laterally stacked semiconductor chips, a heat dissipation plate, and a first molding member on the laterally stacked semiconductor chips.

An electronic package is provided in the present disclosure. The electronic package comprises: a heat spreading component; a first electronic component disposed on the heat spreading component; and a second electronic component disposed on the first electronic component, wherein the second electronic component comprises an interconnection structure passing through the second electronic component and electrically connecting the first electronic component. In this way, through the use of the interconnection structure, the heat dissipation of the electronic components in the package can be improved. Also, through the use of the encapsulant, the stacked electronic components can be protected by the encapsulant so as to avoid being damaged.

A semiconductor package includes a plurality of inorganic dielectric layers including a plurality of metal interconnect layers formed therein and a plurality of first contact pads, a plurality of organic dielectric layers disposed on and electrically connected to the plurality of inorganic dielectric layers and including a plurality of metal redistribution layers formed therein, wherein the plurality of metal redistribution layers are physically connected to the plurality of first contact pads, and a semiconductor die mounted on the plurality of organic dielectric layers and electrically connected to the plurality of metal redistribution layers through the plurality of metal interconnect layers.

Ceramic interposers in a disaggregated-die semiconductor package allow for useful signal integrity and interconnecting components. Low-loss ceramics are used to tune ceramic interposers for a die assembly that may have components from different process-technology nodes.

In an embodiment, a structure includes a core substrate, a redistribution structure coupled, the redistribution structure including a plurality of redistribution layers, the plurality of redistribution layers comprising a dielectric layer and a metallization layer, a first local interconnect component embedded in a first redistribution layer of the plurality of redistribution layers, the first local interconnect component comprising conductive connectors, the conductive connectors being bonded to a metallization pattern of the first redistribution layer, the dielectric layer of the first redistribution layer encapsulating the first local interconnect component, a first integrated circuit die coupled to the redistribution structure, a second integrated circuit die coupled to the redistribution structure, an interconnect structure of the first local interconnect component electrically coupling the first integrated circuit die to the second integrated circuit die, and a set of conductive connectors coupled to a second side of the core substrate.

In a method of manufacturing a semiconductor package, a first semiconductor device is arranged on a package substrate. An electrostatic discharge structure is formed on at least one ground substrate pad exposed from an upper surface of the package substrate. A plurality of second semiconductor devices is stacked on the package substrate and spaced apart from the first semiconductor device, the electrostatic discharge structure being interposed between the first semiconductor device and the plurality of second semiconductor devices. A molding member is formed on the package substrate to cover the first semiconductor device and the plurality of second semiconductor devices.

A semiconductor device includes: a first chip including first and second electrodes provided at a first surface, and a third electrode provided at a second surface positioned at a side opposite to the first surface; a second chip including fourth and fifth electrodes provided at a third surface, and a sixth electrode provided at a fourth surface positioned at a side opposite to the third surface, wherein the second chip is disposed to cause the third surface to face the first surface; a first connector disposed between the first electrode and the fourth electrode and connected to the first and fourth electrodes; and a second connector disposed between the second electrode and the fifth electrode and connected to the second and fifth electrodes.

In a general aspect, a method for producing a semiconductor device assembly can include defining a cavity in a conductive spacer, and electrically and thermally coupling a semiconductor die with the conductive spacer, such that the semiconductor die is at least partially embedded in the cavity. The semiconductor die can have a first surface having active circuitry included therein, a second surface opposite the first surface, and a plurality of side surfaces each extending between the first surface of the semiconductor die and the second surface of the semiconductor die. The method can also include electrically coupling a direct bonded metal (DBM) substrate with the first surface of the semiconductor die.

A semiconductor device includes a vapor chamber lid for high power applications such as chip-on-wafer-on-substrate (CoWoS) applications using high performance processors (e.g., graphics processing unit (GPU)) and methods of manufacturing the same. The vapor chamber lid provides a thermal solution which enhances the thermal performance of a package with multiple chips. The vapor chamber lid improves hot spot dissipation in high performance chips, for example, at the three-dimensional (3D-IC) packaging level.

A semiconductor package includes a package substrate, an interposer provided on the package substrate, a plurality of semiconductor devices on the interposer and spaced apart from each other, and electrically connected to each other through the interposer, at least one dummy member on the interposer to cover at least one corner portion of the interposer and arranged spaced apart from a first semiconductor device among the plurality of semiconductor devices, and a sealing member contacting the interposer and filling a space between the first semiconductor device and the at least one dummy member so as to cover a first side surface of the first semiconductor device, a first side surface of the at least one dummy member, and an upper surface of the dummy member. A second side surface, opposite to the first side surface, of the at least one dummy member is uncovered by the sealing member.