A semiconductor package according to the disclosure includes a terminal, a conductive pattern connected to the terminal, a barrier layer covering a top surface and a first side wall of the conductive pattern, an insulating layer surrounding the barrier layer, a protection layer covering a bottom surface of the insulating layer and a bottom surface of the barrier layer, a redistribution pattern connected to the barrier layer, a semiconductor chip electrically connected to the redistribution pattern, and a molding layer surrounding the semiconductor chip. A top surface of the protection layer includes a first portion contacting the conductive pattern, and a second portion contacting the barrier layer.

Disclosed are semiconductor packages and their fabricating methods. The semiconductor package includes a lower structure and an upper redistribution layer. The lower structure includes a first bump layer, a lower redistribution layer, a semiconductor chip, a molding layer, a conductive pillar, and an under pad layer. The upper redistribution layer includes a second bump layer and second redistribution layers. The first redistribution layer includes a lower redistribution pattern including a first line part and a first via part. A width of the first via part increases in a direction toward the first line part from a bottom surface of the first via part. The second redistribution layer includes an upper redistribution pattern including a second line part and the second via part. A width of the second via part increases in a direction toward the second line part from a top surface of the second via part.

Systems including power device embedded PCBs coupled to cooling devices and methods of forming the same are disclosed. One system includes a power device embedded PCB stack, a cooling assembly including a cold plate having one or more recesses therein, and a buffer cell disposed within each of the one or more recesses. The cooling assembly is bonded to the PCB stack with a insulation substrate disposed therebetween. The cooling assembly is arranged such that the buffer cell faces the PCB stack and absorbs stress generated at an interface of the PCB stack and the cooling assembly.

An organic interposer includes: a first organic insulating layer including a groove; a first metal wire located in the groove; a barrier metal material covering the first metal wire; and a second metal wire located above the first metal wire, wherein the barrier metal material includes: a first barrier metal film interposed between the first metal wire and an inner surface of the groove; and a second barrier metal film located on the first metal wire, and wherein the second metal wire is in contact with both of the first barrier metal film and the second barrier metal film.

A component carrier includes a stack including at least one electrically conductive layer structure and at least one electrically insulating layer structure and a component connected to the stack. The component has a planar redistribution layer at a main surface thereof.

A method includes forming an insulating layer over a package. The package has a plurality of locations where openings are subsequently formed. A first laser shot is performed, location by location, on each of the locations across the package. A first laser spot of the first laser shot overlaps with each of the locations. The first laser shot removes a first portion of the insulating layer below the first laser spot. Another laser shot is performed, location by location, on each of the locations across the package. Another laser spot of the another laser shot overlaps with each of the locations. The another laser shot removes another portion of the insulating layer below the another laser spot. Performing the another laser shot, location by location, on each of the locations across the package is repeated multiple times, until desired portions of the insulating layer are removed.

A packaging process for embedded chips includes: (1) mounting at least one IC chip on a circuit substrate, the IC chip having at least one exposed pin; (2) attaching a self-adhesive copper foil film to the surface of the circuit substrate, wherein the self-adhesive copper foil film has a copper foil layer and a B-stage insulating adhesive layer, the copper foil layer has at least one to-be-opened copper foil area corresponding to the pin, the insulating adhesive layer is applied on the copper foil layer, has no glass fiber, covers the IC chip, and has at least one to-be-opened insulating adhesive area corresponding to the pin, and the pin is in contact with the insulating adhesive layer but not with the copper foil layer; (3) removing the to-be-opened copper foil area; (4) removing the to-be-opened insulating adhesive area with an etching solution; and (5) curing the insulating adhesive layer completely.

A semiconductor package includes a semiconductor die, a first thermal conductive pattern and a second thermal conductive pattern. The semiconductor die is encapsulated by an encapsulant. The first thermal conductive pattern is disposed aside the semiconductor die in the encapsulant. The second thermal conductive pattern is disposed over the semiconductor die, wherein the first thermal conductive pattern is thermally coupled to the semiconductor die through the second thermal conductive pattern and electrically insulated from the semiconductor die.

A system and method of providing high bandwidth and low latency memory architecture solutions for next generation processors is disclosed. The package contains a substrate, a memory device embedded in the substrate via EMIB processes and a processor disposed on the substrate partially over the embedded memory device. The I/O pads of the processor and memory device are vertically aligned to minimize the distance therebetween and electrically connected through EMIB uvias. An additional memory device is disposed on the substrate partially over the embedded memory device or on the processor. I/O signals are routed using a redistribution layer on the embedded memory device or an organic VHD redistribution layer formed over the embedded memory device when the additional memory device is laterally adjacent to the processor and the I/O pads of the processor and additional memory device are vertically aligned when the additional memory device is on the processor.

A package includes an integrated circuit. The integrated circuit includes a first chip, a second chip, a third chip, and a fourth chip. The second chip and the third chip are disposed side by side on the first chip. The second chip and the third chip are hybrid bonded to the first chip. The fourth chip is fusion bonded to at least one of the second chip and the third chip.