A semiconductor device includes a carrier, a first external contact, a second external contact, and a semiconductor die. The semiconductor die has a first main face, a second main face opposite to the first main face, a first contact pad disposed on the first main face, a second contact pad disposed on the second main face, a third contact pad disposed on the second main face, and a vertical transistor. The semiconductor die is disposed with the first main face on the carrier. A clip connects the second contact pad to the second external contact. A first bond wire is connected between the third contact pad and the first external contact. The first bond wire is disposed at least partially under the clip.

A semiconductor device includes a semiconductor die, an electrical contact arranged on a surface of the semiconductor die, and a metal layer arranged on the electrical contact, wherein the metal layer includes a singulated part of at least one of a metal foil, a metal sheet, a metal leadframe, or a metal plate. When viewed in a direction perpendicular to the surface of the semiconductor die, a footprint of the electrical contact and a footprint of the metal layer are substantially congruent.

A semiconductor package includes a power semiconductor chip comprising SiC, a leadframe part comprising Cu, wherein the power semiconductor chip is arranged on the leadframe part, and a solder joint electrically and mechanically coupling the power semiconductor chip to the leadframe part, wherein the solder joint comprises at least one intermetallic phase.

A method of liquid assisted bonding includes: forming a structure with a liquid layer between an electrode of a device and a contact pad of a substrate, and two opposite surfaces of the liquid layer being respectively in contact with the electrode and the contact pad in which hydrogen bonds are formed between the liquid layer and at least one of the electrode and the contact pad; and evaporating the liquid layer to break said hydrogen bonds such that at least one of a surface of the electrode facing the contact pad and a surface of the contact pad facing the electrode is activated so as to assist a formation of a diffusion bonding between the electrode of the device and the contact pad in which a contact area between the electrode and the contact pad is smaller than or equal to about 1 square millimeter.

A power-electronic metal-ceramic module (10) comprising a metal-ceramic substrate (12) made of a ceramic carrier (14) having a metal top and bottom ply (16, 18), which is joined on or in the metal top ply (16) and/or the metal bottom ply (18) with a metal layer (16, 18, 22, 23) forming a frame (24) for accommodating at least one electronic component (30) and at least one electronic component (30) accommodated in the frame (24).

A power semiconductor device is proposed. The power semiconductor device includes a semiconductor substrate. The power semiconductor device further includes an electrically conducting first layer. At least part of the electrically conducting first layer includes pores. The power semiconductor device further includes an electrically conducting second layer. The electrically conducting second layer is arranged between the semiconductor substrate and the electrically conducting first layer. The pores are at least partially filled with a phase change material.

A method of liquid assisted bonding includes: forming a structure with a liquid layer between an electrode of a device and a contact pad of a substrate, and two opposite surfaces of the liquid layer being respectively in contact with the electrode and the contact pad in which hydrogen bonds are formed between the liquid layer and at least one of the electrode and the contact pad; and evaporating the liquid layer to break said hydrogen bonds such that at least one of a surface of the electrode facing the contact pad and a surface of the contact pad facing the electrode is activated so as to assist a formation of a diffusion bonding between the electrode of the device and the contact pad in which a contact area between the electrode and the contact pad is smaller than or equal to about 1 square millimeter.

Provided is a power semiconductor module including: a metal base plate; an insulating substrate arranged on the metal base plate and provided with an electrode; a semiconductor element arranged on the insulating substrate; a case arranged on the metal base plate so as to surround the insulating substrate and the semiconductor element; and a potting material filled into a space defined by the metal base plate and the case so as to encapsulate the insulating substrate and the semiconductor element. The potting material includes: a silicone gel; and a conductivity-imparting agent that is added to the gel and contains a silicon atom and an ionic group.

Provided is a power semiconductor module including: a metal base plate; an insulating substrate arranged on the metal base plate and provided with an electrode; a semiconductor element arranged on the insulating substrate; a case arranged on the metal base plate so as to surround the insulating substrate and the semiconductor element; and a potting material filled into a space defined by the metal base plate and the case so as to encapsulate the insulating substrate and the semiconductor element. The potting material includes: a silicone gel; and a conductivity-imparting agent that is added to the gel and contains a silicon atom and an ionic group.

Encapsulated stress mitigation layers and assemblies having the same are disclosed. An assembly that includes a first substrate, a second substrate, an encapsulating layer disposed between the first and second substrates, and a stress mitigation layer disposed in the encapsulating layer such that the stress mitigation layer is encapsulated within the encapsulating layer. The stress mitigation layer has a lower melting temperature relative to a higher melting temperature of the encapsulating layer. The assembly includes an intermetallic compound layer disposed between the first substrate and the encapsulating layer such that the encapsulating layer is separated from the first substrate by the intermetallic compound layer. The stress mitigation layer melts into a liquid when the assembly operates at a temperature above the low melting temperature of the stress mitigation layer and the encapsulating layer maintains the liquid of the stress mitigation layer within the assembly.