A power converter module includes power transistors and a substrate having a first surface and a second surface that opposes the first surface. A thermal pad is situated on the second surface of the substrate, and the thermal pad is configured to be thermally coupled to a heat sink. The power converter module also includes a control module mounted on a first surface of the substrate. The control module also includes control IC chips coupled to the power transistors. A first control IC chip controls a first switching level of the power converter module and a second control IC chip controls a second switching level of the power converter module. Shielding planes overlay the substrate. A first shielding plane is situated between the thermal pad and the first control IC chip and a second shielding plane is situated between the thermal pad and a second control IC chip.

In some examples a method comprises forming an insulating member over a circuit on a device side of a semiconductor die, removing a portion of the insulating member to produce a cavity, and forming a seed layer on the insulating member and within the cavity. In addition, the method includes forming a conductive member on the seed layer in the cavity, wherein the conductive member comprises a plurality of layers of different metal materials. Further, the method includes removing the seed layer from atop the insulating member, outside the cavity, after forming the conductive member in the cavity such that a remaining portion of the seed layer is positioned between the conductive member and the insulating member.

Disclosed are semiconductor packages and their fabrication methods. The semiconductor package comprises a package substrate, a redistribution layer on the package substrate, a vertical connection terminals that connects the package substrate to the redistribution layer, a first semiconductor chip between the package substrate and the redistribution layer, a first molding layer that fills a space between the package substrate and the redistribution layer, a second semiconductor chip on the redistribution layer, a third semiconductor chip on the second semiconductor chip, a first connection wire that directly and vertically connects the redistribution layer to a first chip pad of the third semiconductor chip, the first chip pad is beside the second semiconductor chip and on a bottom surface of the third semiconductor chip, and a second molding layer on the redistribution layer and covering the second semiconductor chip and the third semiconductor chip.

An electronic device and associated methods are disclosed. In one example, the electronic device includes a plurality of dies, a logic die coupled to the plurality of dies, and a dummy die thereon. In selected examples, the dummy die is located between the logic die and the plurality of silicon dies. In selected examples, the dummy die is attached to the logic die.

A semiconductor device includes a substrate, a semiconductor element, a connection pad, a plated layer, a wire, and an encapsulation resin. The substrate includes a main surface. The semiconductor element is mounted on the main surface and includes a main surface electrode. The connection pad is formed of Cu, arranged with respect to the substrate, separated from the substrate, and includes a connection surface. The plated layer is formed of Ni and partially covers the connection surface. The wire is formed of Al and bonded to the main surface electrode and the plated layer. The encapsulation resin encapsulates the semiconductor element, the connection pad, the plated layer, and the wire.

A power module includes a substrate that is electrically insulative and includes a substrate main surface and a substrate back surface at opposite sides in a thickness direction. The power module also includes a mounting layer that is conductive and arranged on the substrate main surface. The power module further includes a graphite plate having anisotropic thermal conductivity and including a plate main surface and a plate back surface at opposite sides in the thickness direction. The plate back surface is connected to the mounting layer. The power module further includes a power semiconductor element arranged on the plate main surface.

A packaged power device includes a ceramic package body having a top drain pad having a first area, a top source pad having a second area smaller than the first area, and a top gate pad having a third area smaller than the second area; a power device having a bottom surface affixed to a top drain pad, a die source pad coupled to the top source pad, and a die gate pad coupled to the top gate pad; and a ceramic lid affixed to the ceramic package body to form the packaged power device.

A Freewheeling Diode of any kind (Fast Recovery Diode, Schottky Barrier Diode or other variants) is integrated with a Forced Extraction Device and in this way two entirely different functions—the Free-Wheeling function and the Forced Extraction function are combined in one device, simplifying the circuit and reducing the number of components. The FWD part of the integrated device is standard in the industry, but the Forced Extraction Device is made using a lateral or vertical PMOS with a votage capability between a control input and the output terminals that is as high or higher than the rating voltage of the Main Switch that will be used together with the FWD.

A package substrate and a semiconductor package including the same are provided. The semiconductor package includes a package substrate including a base having a front side and a back side, rear pads below the back side of the base, lower connection patterns below the rear pads and in contact with the rear pads, first and second front pads on the front side of the base, a first support pattern on the front side of the base having a thickness greater than a thickness of each of the first and second front pads, and a protective insulating layer on the front side of the base and having openings exposing the first and second front pads respectively, and on an upper surface and a side surface of the first support pattern; a lower semiconductor chip on the protective insulating layer of the package substrate, spaced apart from the first support pattern in a horizontal direction; and a first upper semiconductor chip on the package substrate vertically overlapping the lower semiconductor chip and the first support pattern.

A method includes forming a first bond layer on a first wafer, and forming a first thermal conductive channel extending into the first bond layer. The first thermal conductive channel has a first thermal conductivity value higher than a second thermal conductivity value of the first bond layer. The method further includes forming a second bond layer on a second wafer, and forming a second thermal conductive channel extending into the second bond layer. The second thermal conductive channel has a third thermal conductivity value higher than a fourth thermal conductivity value of the second bond layer. The first wafer is bonded to the second wafer, and the first thermal conductive channel at least physically contacts the second thermal conductive channel. An interconnect structure is formed over the first wafer. The interconnect structure is electrically connected to integrated circuit devices in the first wafer.