In one example, a semiconductor device comprises a substrate and an electronic device on a top side of the substrate, a lead frame on the top side of the substrate over the electronic device, wherein the lead frame comprises a connection bar and a lead, a component mounted to the connection bar and the lead on a top side of the lead frame, and an encapsulant on the top side of the substrate, wherein the encapsulant contacts a side of the electronic device and a side of the component. Other examples and related methods are also disclosed herein.

In one general aspect, a semiconductor device package can include a die attach paddle having a first surface and a second surface that is opposite the first surface. The package can also include a semiconductor die coupled with the first surface of the die attach paddle. The package can further include a direct-bonded-metal (DBM) substrate. The DBM substrate can include a ceramic layer having a first surface and a second surface that is opposite the first surface; a first metal layer disposed on the first surface of the ceramic layer and coupled with the second surface of the die attach paddle; and a second metal layer disposed on the second surface of the ceramic layer. The second metal layer can be exposed external to the semiconductor device package. The second metal layer can be electrically isolated from the first metal layer by the ceramic layer.

Provided is a semiconductor element including: a multilayer structure including: a conductive substrate; and an oxide semiconductor film arranged directly on the conductive substrate or over the conductive substrate via a different layer, the oxide semiconductor film including an oxide, as a major component, having a corundum structure, the conductive substrate having a larger area than the oxide semiconductor film.

Semiconductor chips are arranged on an elongated substrate and encapsulated by an insulating encapsulation. Electrically conductive formations and electrically conductive plating lines are plated on the insulating encapsulation using, for example, Laser Direct Structuring (LDS) or Direct Copper Interconnect (DCI) material. The electrically conductive plating lines include first transverse plating lines as well as second plating lines branching out from the first plating lines towards the electrically conductive formations. A first partial cutting step is then performed to form grooves which remove the first plating lines. An insulating material is dispensed in the grooves to encapsulate the end portions of the second plating lines. A second cutting step median along the groove and through the elongate substrate is performed to produce singulated semiconductor devices (such as “die pad up” Quad-Flat No-lead (QFN) packages). End portions of the second plating lines are encapsulated by the insulating material.

Various embodiments may provide a semiconductor package. The semiconductor package may include a first electrical component, a second electrical component, a first heat sink, and a second heat sink bonded to a first package interconnection component and a second package interconnection component. The first package interconnection component and the second package interconnection component may provide lateral and vertical interconnections in the package.

An embodiment of the present disclosure provides a substrate structure applied to a power module. In the substrate structure applied to a power module, the substrate includes an upper substrate and a lower substrate, a plurality of semiconductor devices disposed on the lower substrate, a source signal electrode transmitting a source signal to the semiconductor devices, and a gate signal electrode transmitting a gate signal to the semiconductor devices, one of the source signal electrode or the gate signal electrode is connected to the upper substrate through a conductive column, and a signal transmitted by one of the source signal electrode or the gate signal electrode is transmitted to the semiconductor devices through the upper substrate.

A method of fabricating an electronic power module by additive manufacturing, the electronic module including a substrate having an electrically insulating plate presenting opposite first and second faces, with a first metal layer arranged directly on the first face of the insulating plate, and a second metal layer arranged directly on the second face of the insulating plate. At least one of the metal layers is made by a step of depositing a thin layer of copper and a step of annealing the metal layer, and the method further includes a step of forming at least one thermomechanical transition layer on at least one of the first and second metal layers, the at least one thermomechanical transition layer including a material presenting a coefficient of thermal expansion that is less than that of the metal of the metal layer.

A semiconductor device comprises; a lead frame having leads and a die pad; a printed circuit board including an electrode for the connection of each of the leads and the die pad, a wiring pattern, and an opening exposing a part of a surface of the die pad; the semiconductor element for processing a high frequency signal, mounted on a surface of a metal block bonded to the surface of the die pad exposed through the opening, and connected to the wiring pattern with a metal wire; electronic components connected to the wiring pattern and mounted on a surface of the printed circuit board; and a sealing resin to seal the printed circuit board, the semiconductor element, the electronic components, and the metal wire so as to expose rear surfaces of the leads and the die pad.

A semiconductor package and a manufacturing method thereof are provided. The semiconductor package includes a first semiconductor die, a second semiconductor die, a molding compound, a heat dissipation module and an adhesive material. The first and second semiconductor dies are different types of dies and are disposed side by side. The molding compound encloses the first and second semiconductor dies. The heat dissipation module is located directly on and in contact with the back sides of the first and second semiconductor dies. The adhesive material is filled and contacted between the heat dissipation module and the molding compound. The semiconductor package has a central region and a peripheral region surrounding the central region. The first and second semiconductor dies are located within the central region. A sidewall of the heat dissipation module, a sidewall of the adhesive material and a sidewall of the molding compound are substantially coplanar.

Solid state switching device including: a pair of line terminals including first and second line terminals for electrical connection with a corresponding phase conductor of an electric line; a switching assembly including one or more solid state power switches, the switching assembly having a first and second power terminals electrically connected with the first and second lines terminals, respectively; a heat sink element in thermal coupling with the switching assembly to adsorb heat from the switching assembly; an additional heat extraction arrangement to extract heat from the switching assembly and convey at least a portion of the adsorbed heat along the phase conductor through the first and second line terminals.