A semiconductor device includes a first switching element; a second switching element; a first metal member; a second metal member; a first terminal that has a potential on a high potential side; a second terminal that has a potential on a low potential side; a third terminal that has a midpoint potential; and a resin part. A first potential part has potential equal to potential of the first terminal. A second potential part has potential equal to potential of the second terminal. A third potential part has potential equal to potential of the third terminal. A first creepage distance between the first potential part and the second potential part is longer than a minimum value of a second creepage distance between the first potential part and the third potential part and a third creepage distance between the second potential part and the third potential part.

In a general aspect, an apparatus can include an inner package including a first silicon carbide die having a die gate conductor coupled to a common gate conductor, and a second silicon carbide die having a die gate conductor coupled to the common gate conductor. The apparatus can include an outer package including a substrate coupled to the common gate conductor, and a clip coupled to the inner package and coupled to the substrate.

Heat is transferred to a cold plate from one or more subassemblies in an array of subassemblies in an electronic package. The cold plate has a thermally conductive cold plate substrate, a pressure header, a pressure passage, and one or more pressure connections. Each of the pressure connections connects through a housing opening to housing volume defined by a flexible housing in an encapsulated liquid thermal interface (LTI). The flexible housing is in physical and thermal contact with one of the subassemblies through a housing bottom and a top surface of one or more components in the subassembly. A thermally conductive fluid fills the housing volume, housing opening, pressure connections, pressure passage, and pressure header which are all in fluid communication along with one or more other connections, housing openings, and LTIs on other subassemblies. The system transfers heat from the subassemblies to the cold plate while maintaining a constant pressure/stress on each of the subassemblies. The system pressure on each of the subassemblies is equal. The system pressure can be controlled to a preloaded pressure to insure good electrical contact between components. Shear on the subassemblies is minimized by the LTIs.

A semiconductor device includes a semiconductor package, including a package body that includes an encapsulant portion and an isolation structure, a semiconductor die embedded within the package body, and a plurality of leads that protrude out from the encapsulant body, wherein the encapsulant portion and the isolation structure are each electrically insulating structures, wherein the isolation structure has a greater thermal conductivity than the encapsulant portion, and wherein the isolation structure is thermally coupled to the semiconductor die, and a releasable layer affixed to the semiconductor package, wherein a first outer face of the package body includes a first surface of the isolation structure, wherein the releasable layer at least partially covers the first surface of the isolation structure, and wherein the releasable layer is releasable from the semiconductor package.

Provided is a planar power module with a spatially interleaved structure, including a top power substrate, a bottom power substrate arranged opposite to the top power substrate, and a plurality of interleaved switch units configured between the top power substrate and the bottom power substrate; wherein adjacent interleaved switch units are electrically connected through a current commutator so that the interleaved switch units form spatial position interleaving. Problems of uneven parallel currents and uneven heat dissipation in the power module are solved.

A heat sink includes a heat sink fin (HSF), a first heat sink plate (HSP), and a second HSP that is opposite to the first HSP. The HSF is located on the first HSP. The second HSP is flexible. Further, an elastic component is disposed between the first HSP and the second HSP. The second HSP is in contact with a heat source component (HSC). Thus, when the heat sink is placed on the HSC, the second HSP contacts the HSC, the second HSP is deformed because the heat sink and the HSC are pressed against each other, and the elastic component between the first HSP and the second HSP is compressed such that heat generated by the HSC is transferred to the heat sink.

A semiconductor device includes a semiconductor element, a sealing member, and a first conductive plate. The semiconductor element includes a first electrode. The sealing member seals the semiconductor element. The first conductive plate includes a first surface facing the first electrode inside the sealing member. The first surface of the first conductive plate includes a mounting region, a roughened region and a non-roughened region. The first electrode is joined to the mounting region. The roughened region is located around the mounting region. The non-roughened region is located between the roughened region and an outer peripheral edge of the first surface. Surface roughness of the roughened region is larger than surface roughness of the non-roughened region.

A semiconductor device includes a power module, a circuit package, and a joint portion joining the power module and the circuit package. The circuit package includes a semiconductor element, a wiring layer electrically connected with the semiconductor element, a heat conductive member, and a second mold resin portion sealing the semiconductor element and the heat conductive member. The wiring layer includes a connecting portion connected with the heat conductive member. One of the connecting portion or the heat conductive member is joined with a signal wire in the power module via the joint portion. The heat conductive member penetrates the second mold resin portion in a thickness direction of the semiconductor element. The heat conductive member and the connecting portion are arranged in a straight line in the thickness direction of the semiconductor element.

A thermal interface structure for transferring heat from an electronic component to a system heat sink includes a stack of one or more layers of a stiff thermal interface material and one or more layers of a compliant thermal interface material stacked on and connected to the one or more layers of the compliant thermal interface material. In some embodiments, the thermal interface structure also may include one or more layers of a shape memory alloy and/or a collapsible encasement.

A thermal interface structure for transferring heat from an electronic component to a system heat sink includes a stack of one or more layers of a stiff thermal interface material and one or more layers of a compliant thermal interface material stacked on and connected to the one or more layers of the compliant thermal interface material. In some embodiments, the thermal interface structure also may include one or more layers of a shape memory alloy and/or a collapsible encasement.