Abstract: An electronic device and method is disclosed. In one example, the electronic device includes an electrically insulating material, a first load electrode arranged on a first surface of the electrically insulating material, and a second load electrode arranged on a second surface of the electrically insulating material opposite to the first surface, wherein the load electrodes are separated by the electrically insulating material along the entire length on which the load electrodes have opposite sections, wherein surfaces of the load electrodes facing away from the electrically insulating material are uncovered by the electrically insulating material.

Abstract: A semiconductor assembly includes a laminate substrate that includes a plurality of laminate layers of electrically insulating material stacked on top of one another, a semiconductor package that includes a package body of electrically insulating encapsulant material and a plurality of electrical contacts that are exposed from the package body, wherein the semiconductor package is embedded within the laminate layers of the laminate substrate, wherein the semiconductor package comprises a delamination mitigation feature, wherein the delamination mitigation feature comprises one or both of a macrostructure that engages with the laminate layers, and a roughened surface of microstructures that enhances adhesion between the semiconductor package and the laminate layers.

Abstract: A chip package structure is disclosed. In one example, the chip package may include a chip, an encapsulation material, and an exposed pad that is electrically conductively connected to the chip. A layer of a porous or dendrite-comprising adhesion promoter is on a surface of the exposed pad. A thermal interface material that is attached to the exposed pad by the layer.

Abstract: A semiconductor device module includes an application board, a plurality of semiconductor device packages disposed on the application board, each one of the semiconductor device packages including a semiconductor die, a leadframe including a plurality of leads, the leads including a spring support and a heat dissipation element, and an encapsulant embedding the semiconductor die and first portions of the leads, an external heatsink, and one or more thermally conductive interface layers disposed between the semiconductor device package and the heatsink.

Abstract: A semiconductor power module comprises an insulating interposer comprising an insulative layer disposed between a lower metal layer, a first upper metal layer and a second upper metal layer, a semiconductor transistor die disposed on the first upper metal layer, an electrical connector connecting the semiconductor transistor die with the second upper metal layer, a housing enclosing the insulating interposer and the semiconductor transistor die, a first potting material covering at least selective portions of the semiconductor transistor die and the electrical connector; and a second potting material applied onto the first potting material, wherein the first and second potting materials are different from each other.

Abstract: A device includes an interposer including an insulative layer between a lower metal layer and a first upper metal layer and a second upper metal layer, a semiconductor transistor die attached to the first upper metal layer and comprising a first lower main face and a second upper main face, with a drain or collector pad on the first main face and electrically connected to the first upper metal layer, a source or emitter electrode pad and a gate electrode pad on the second main face, a leadframe connected to the interposer and comprising a first lead connected with the first upper metal layer, a second lead connected with the source electrode pad, and a third lead connected with the second upper metal layer, and wherein an electrical connector that is connected between the gate electrode pad and the second upper metal layer is orthogonal to a first electrical connector.

Abstract: A method includes providing a first lead frame that includes a first die pad and a first row of leads, providing a connection lug, mounting a first semiconductor die on the first die pad, the first semiconductor die including first and second voltage blocking terminals, electrically connecting the connection lug to one of the first and second voltage blocking terminals, electrically connecting a first one of the leads from the first row to an opposite one of the first and second voltage blocking terminals, and forming an encapsulant body of electrically insulating material that encapsulates first die pad and the first semiconductor die. After forming the encapsulant body, the first row of leads each protrude out of a first outer face of the encapsulant body and the connection lug protrudes out of a second outer face of the encapsulant body.

Abstract: A semiconductor package includes a first die pad, a first semiconductor die mounted on the first die pad, an encapsulant body of electrically insulating material that encapsulates first die pad and the first semiconductor die, a plurality of package leads that each protrude out of a first outer face of the encapsulant body, a connection lug that protrudes out of a second outer face of the encapsulant body, the second outer face being opposite from the first outer face. The first semiconductor die includes first and second voltage blocking terminals. The connection lug is electrically connected to one of the first and second voltage blocking terminals of the first semiconductor die. A first one of the package leads is electrically connected to an opposite one of the first and second voltage blocking terminals of the first semiconductor die that the first connection lug is electrically connected to.

Abstract: A power semiconductor device includes a semiconductor substrate having a wide bandgap semiconductor material and a first surface, an insulation layer above the first surface of the semiconductor substrate, the insulation layer including at least one opening extending through the insulation layer in a vertical direction, a front metallization above the insulation layer with the insulation layer being interposed between the front metallization and the first surface of the semiconductor substrate, and a metal connection arranged in the opening of the insulation layer and electrically conductively connecting the front metallization with the semiconductor substrate; wherein the front metallization includes at least one layer that is a metal or a metal alloy having a higher melting temperature than an intrinsic temperature of the wide bandgap semiconductor material of the semiconductor substrate.

Abstract: A silicon carbide device includes a silicon carbide substrate, a contact layer including nickel, silicon and aluminum, a barrier layer structure including titanium and tungsten, and a metallization layer including copper. The contact layer is located on the silicon carbide substrate. The contact layer is located between the silicon carbide substrate and at least a part of the barrier layer structure. The barrier layer structure is located between the silicon carbide substrate and the metallization layer.

Abstract: A lead frame includes a die pad, a row of two or more leads that extend away from a first side of the die pad, and a peripheral structure disposed opposite the die pad and connected to each lead. A first outermost lead is continuously connected to the die pad. A second outermost lead has an interior end that faces and is spaced apart from the die pad. A width of the second lead in a central span of the second lead is greater than the width of the second lead in interior and outer spans of the second lead, the interior span of the second lead separating the central span of the second lead from the interior end of the second lead, the outer span of the second lead separating the central span of the second lead from the peripheral structure.

Abstract: A molded semiconductor package includes: a semiconductor die embedded in a mold compound; a first heat spreader partly embedded in the mold compound and thermally coupled to a first side of the semiconductor die; and a second heat spreader partly embedded in the mold compound and thermally coupled to a second side of the semiconductor die opposite the first side. The first heat spreader includes at least one heat dissipative structure protruding from a side of the first heat spreader uncovered by the mold compound and facing away from the semiconductor die. The mold compound is configured to channel a fluid over the at least one heat dissipative structure in a direction parallel to the first side of the power semiconductor die. Corresponding methods of production and electronic assemblies are also described.

Abstract: A package is disclosed. In one example, the package includes a first main face for mounting a heat sink and an opposing second main face for being mounted on a mounting base. The package comprises a carrier, an electronic component mounted at the carrier, and an encapsulant encapsulating at least part of the electronic component and at least part of the carrier. Electrically insulating material covers electrically conductive material of the carrier at said first main face. The encapsulant comprises at least one step at the first main face.

Abstract: A package for mounting on a mounting base is disclosed. In one example, the package comprises a carrier, an electronic component mounted at the carrier, leads electrically coupled with the electronic component and to be electrically coupled with the mounting base, and a linear spacer for defining a spacing with respect to the carrier.

Abstract: A semiconductor chip includes a semiconductor body having a main surface and a rear surface opposite the main surface, a first bond pad disposed on the main surface, a second bond pad disposed on the rear surface, a first switching device that is monolithically integrated in the semiconductor body and has a first input-output terminal that is electrically connected to the first bond pad, and a second switching device that is monolithically integrated in the semiconductor body and has a first input-output terminal that is electrically connected to the second bond pad.

Abstract: A semiconductor device module includes a package carrier having an opening, wherein in the opening there is disposed a semiconductor package including a semiconductor die, an encapsulant, and first vertical contacts, wherein the encapsulant at least partially covers the semiconductor die, and the first vertical contacts are connected to the semiconductor die and extend at least partially through the encapsulant, and a first outer metallic contact layer electrically connected to the first vertical contacts.

Abstract: A semiconductor package includes: a carrier having an electrically insulative body and a first contact structure at a first side of the electrically insulative body; and a semiconductor die having a first pad attached to the first contact structure of the carrier, the first pad being at source or emitter potential. The first pad is spaced inward from an edge of the semiconductor die by a first distance. The semiconductor die has an edge termination region between the edge and the first pad. The first contact structure of the carrier is spaced inward from the edge of the semiconductor die by a second distance greater than the first distance such that an electric field that emanates from the edge termination region in a direction of the carrier during normal operation of the semiconductor die does not reach the first contact structure of the carrier. Methods of production are also provided.

Abstract: A semiconductor device package comprises an electrically conductive carrier, a semiconductor die disposed on the carrier, an encapsulant encapsulating part of the carrier and the semiconductor die, an electrically insulating and thermally conductive interface structure, in particular covering an exposed surface portion of the carrier and a connected surface portion of the encapsulant, wherein the interface structure comprises a glass transition temperature in a range between ?40° C. to 150° C.

Abstract: A lead frame includes a die pad, a row of two or more leads that extend away from a first side of the die pad, and a peripheral structure disposed opposite the die pad and connected to each lead. A first outermost lead is continuously connected to the die pad. A second outermost lead has an interior end that faces and is spaced apart from the die pad. A width of the second lead in a central span of the second lead is greater than the width of the second lead in interior and outer spans of the second lead, the interior span of the second lead separating the central span of the second lead from the interior end of the second lead, the outer span of the second lead separating the central span of the second lead from the peripheral structure.

Abstract: A semiconductor package includes a die pad comprising a die attach surface, a first lead extending away from the die pad, one or more semiconductor dies mounted on the die attach surface, the one or more semiconductor dies comprising first and second bond pads that each face away from the die attach surface, and a distribution element that provides a first transmission path for a first electrical signal between the first lead and the first bond pad of the one or more semiconductor dies and a second transmission path for the first electrical signal between the first lead and the second bond pad of the one or more semiconductor dies. The distribution element comprises at least one integrally formed circuit element that creates a difference in transmission characteristics between the first and second transmission paths.