A semiconductor arrangement comprises a leadframe comprising at least a first and a second carrier, the first and second carriers being arranged laterally besides each other, at least a first and a second semiconductor die, the first semiconductor die being arranged on and electrically coupled to the first carrier and the second semiconductor die being arranged on and electrically coupled to the second carrier, and an interconnection configured to mechanically fix the first carrier to the second carrier and to electrically insulate the first carrier from the second carrier, wherein the first and second semiconductor dies are at least partially exposed to the outside.

A method of manufacturing semiconductor devices such as integrated circuits comprises: providing one or more semiconductor chips having first and second opposed surfaces, coupling the semiconductor chip or chips with a support substrate with the second surface towards the support substrate, embedding the semiconductor chip or chips coupled with the support substrate in electrically-insulating packaging material by providing in the packaging material electrically-conductive passageways. The electrically-conductive passageways comprise: electrically-conductive chip passageways towards the first surface of the at least one semiconductor chip, and/or electrically-conductive substrate passageways towards the support substrate.

A stacked die semiconductor package includes a leadframe including a die pad and lead terminals on at least two sides of the die pad, a top die having circuitry coupled to bond pads, and bottom die having a back side that is attached by die attach material to the die pad and a top side having at least one redistribution layer (RDL) over and coupled to a top metal level including connections to input/output (IO) nodes on the top metal level. The RDL provides a metal pattern including wirebond pads that match locations of the bond pads of the top die. The bond pads on the top die are flip-chip attached to the wirebond pads of the bottom die, and the bond wires are positioned between the wirebond pads and the lead terminals.

Implementations of a semiconductor package may include two or more die, each of the two more die coupled to a metal layer at a drain of each of the two more die, the two or more die and each metal layer arranged in two parallel planes; a first interconnect layer coupled at a source of each of the two more die; a second interconnect layer coupled to a gate of each of the two or more die and to a gate package contact through one or more vias; and an encapsulant that encapsulates the two or more die and at least a portion of the first interconnect layer, each metal layer, and the second interconnect layer.

A semiconductor device includes a semiconductor layer with a thickness of at most 50 μm. A first metallization structure is disposed on a first surface of the semiconductor layer. The first metallization structure includes a first copper region with a first thickness. A second metallization structure is disposed on a second surface of the semiconductor layer opposite to the first surface. The second metallization structure includes a second copper region with a second thickness.

A semiconductor device package includes a metal carrier, a passive device, a conductive adhesive material, a dielectric layer and a conductive via. The metal carrier has a first conductive pad and a second conductive pad spaced apart from the first conductive pad. The first conductive pad and the second conductive pad define a space therebetween. The passive device is disposed on top surfaces of first conductive pad and the second conductive pad. The conductive adhesive material electrically connects a first conductive contact and a second conductive contact of the passive device to the first conductive pad and the second conductive pad respectively. The dielectric layer covers the metal carrier and the passive device and exposes a bottom surface of the first conductive pad and the second conductive pad. The conductive via extends within the dielectric layer and is electrically connected to the first conductive pad and/or the second conductive pad.

A semiconductor package includes a semiconductor chip having an active surface, on which a connection pad is disposed, and an inactive surface disposed to oppose the active surface, a heat dissipation member, disposed on the inactive surface of the semiconductor chip, having a plurality of holes and including a graphite-based material, an encapsulant covering at least a portion of each of the semiconductor chip and the heat dissipation member, and a connection member, disposed on the active surface of the semiconductor chip, including a redistribution layer electrically connected to the connection pad. 0<b<0.6a, in which “a” denotes a planar area of the heat dissipation member and “b” denotes a sum of planar areas of the plurality of holes on a plane.

A power module includes a substrate having a dielectric layer, a first power semiconductor device disposed on an upper part of the substrate, and a second power semiconductor device disposed on a lower part of the substrate.

A method for forming a conductive structure is disclosed, the method comprising the steps of: forming a metallic frame having a plurality of metal parts separated from each other; forming an insulating layer on the top surface of the plurality of metal parts; and forming a conductive pattern layer on the insulating layer for making electrical connections with at least one portion of the plurality of metal parts.

A power semiconductor device including a first and second die, each including a plurality of conductive contact regions and a passivation region including a number of projecting dielectric regions and a number of windows. Adjacent windows are separated by a corresponding projecting dielectric region with each conductive contact region arranged within a corresponding window. A package of the surface mount type houses the first and second dice. The package includes a first bottom insulation multilayer and a second bottom insulation multilayer carrying, respectively, the first and second dice. A covering metal layer is arranged on top of the first and second dice and includes projecting metal regions extending into the windows to couple electrically with corresponding conductive contact regions. The covering metal layer moreover forms a number of cavities, which are interposed between the projecting metal regions so as to overlie corresponding projecting dielectric regions.