Various embodiments may provide a semiconductor package. The semiconductor package may include a semiconductor chip, a first mold compound layer at least partially covering the semiconductor chip, and a redistribution layer over the first mold compound layer, the redistribution layer including one or more electrically conductive lines in electrical connection with the semiconductor chip. The semiconductor package may additionally include a second mold compound layer over the redistribution layer, and an antenna array over the second mold compound layer, the antenna array configured to be coupled to the one or more electrically conductive lines.

A substrate for mounting electronic element includes: a first substrate including a first surface and a second surface opposite to the first surface; a second substrate including a third surface and a fourth surface opposite to the third surface; and heat dissipation bodies each including a fifth surface and a sixth surface opposite to the fifth surface. The first substrate includes at least one mounting portion for at least one electronic element at the first surface. Heat conduction of the heat dissipation bodies in a direction perpendicular to a longitudinal direction of the at least one mounting portion and perpendicular to a direction along opposite sides of the second substrate is greater than heat conduction of the heat dissipation bodies in the longitudinal direction of the at least one mounting portion and in the direction along opposite sides of the second substrate in a transparent plan view of the substrate.

An object is to provide a technology to suppress temperature unevenness in a semiconductor device while suppressing deterioration in productivity. A semiconductor device includes a heat sink having heat radiating fins on one surface side thereof, a plurality of semiconductor modules arranged on an other surface side of the heat sink, and a plurality of heat radiation members provided between the plurality of semiconductor modules and the heat sink, respectively, in which of the plurality of heat radiation members a thickness of the heat radiation member provided between the semiconductor module susceptible to temperature rise and the heat sink is thinner than a thickness of the heat radiation members other than thereof.

A carrier substrate (1) for electrical components, in particular metal-ceramic substrate (1) for electrical components, comprising an insulation layer (10), the insulation layer (10) preferably having a material comprising a ceramic or a composite comprising at least one ceramic layer, a component metallization (20) which is formed on a component side (BS) and has a first primary structuring (21), and a cooling part metallization (30) which is formed on a cooling side (KS) opposite the component side (BS) and has a second primary structuring (31), wherein the insulation layer (10), the component metallization (20) and the cooling part metallization (30) are arranged one above the other along a stacking direction (S), and
wherein the first primary structuring (21) and the second primary structuring (31), as viewed in the stacking direction (S), run congruently at least in portions.

This application discloses a chip package assembly, an electronic device, and a preparation method of a chip package assembly. The chip package assembly includes a package substrate, a chip, and a heat dissipation part. The package substrate includes an upper conductive layer, a lower conductive layer, and a conductive part connected between the upper conductive layer and the lower conductive layer. The chip includes a front electrode and a back electrode that are disposed opposite each other, the chip is embedded in the package substrate, the conductive part surrounds the chip, the front electrode is connected to the lower conductive layer, and the back electrode is connected to the upper conductive layer. The heat dissipation part is connected to a surface of the upper conductive layer that is away from the chip. The upper conductive layer, the lower conductive layer, and the conductive part each conduct heat.

An integrated circuit package includes first and second dies bonded to each other. The first die includes first die pads over a first device, first bonding pads over the first die pads, a first conductive via disposed between and electrically connected to a first one of the first die pads and a first one of the first bonding pads, and a first thermal via disposed between a second one of the first die pads and a second one of the first bonding pads and electrically insulated from the second one of the first die pads or the second one of the first bonding pads. The second die includes second bonding pads. The first one of the first bonding pads is connected to a first one of the second bonding pads. The second one of the first bonding pads is connected to a second one of the second bonding pads.

A method for forming a thermal conduction structure includes: a substrate is provided, at least a dielectric layer being formed on the substrate; a Through Silicon Via (TSV) and at least one silicon blind hole are formed, where the at least one silicon blind hole is located on at least one side of the TSV, the TSV penetrates through the substrate and the dielectric layer, and each silicon blind hole does not penetrate through the substrate.

The present invention includes a method of making a thermal management and signal control structure comprising forming in a substrate heat conductive vias and control vias, power vias, and ground vias, wherein the heat conductive vias and the control vias, power vias, and vias are aligned to a first metal plate on a first side of the substrate, wherein the control vias, power vias, and ground vias are surrounded by a glass layer; forming a second metal plate on a second side of the substrate, wherein the second metal plate is connected to the heat conductive vias; and forming a pad on each of the control vias, power vias, and ground vias, wherein each pad is configured to electrically connect the thermal management and signal control structure to at least one of: a printed circuit board, an integrated circuit, or a power management unit.

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.

A stacked module arrangement includes: a first molded electronic module; a second molded electronic module; and an interface by which the first molded electronic module and the second molded electronic module are physically and electrically connected to one another in a stacked configuration. The first molded electronic module is a power electronic module having a maximum breakdown voltage of at least 40 V and a maximum DC current of at least 10 A.