The present invention provides a joining that suppresses ion migration and also has excellent corrosion resistance, high bonding strength, and high reliability at the joining, and a semiconductor device. The present invention provides semiconductor joinings comprising: at least two semiconductor constituent members; and silver-containing bonding material layers that bond the semiconductor constituent members, in which a corrosion inhibitor coating layer is provided in contact with the silver-containing bonding material layers, and a semiconductor device including the same.

Embodiments of the present disclosure relate to a semiconductor package, a method of forming the package and an electronic device. For example, the semiconductor package may comprise a first substrate assembly comprising a first surface and a second surface opposite the first surface. The semiconductor package may also comprise one or more chips connected or coupled to the first surface of the first substrate assembly by a first thermally and electrically conductive connecting material. In addition, the semiconductor package further comprises a second substrate assembly comprising a third surface and a fourth surface opposite the third surface, the third surface and the first surface being arranged to face each other, and the third surface being connected to one or more chips by a second thermally and electrically conductive connecting material. At least one of the first surface and the third surface is shaped to have a stepped pattern to match a surface of the one or more chips. Embodiments of the present disclosure may at least simplify the double-sided heat dissipation structure and improve the heat dissipation effect of the chip.

In a described example, an apparatus includes: a package substrate having a die pad configured for mounting a semiconductor die, a first lead connected to the die pad, and a second lead spaced from and electrically isolated from the die pad; a spacer dielectric mounted on the die pad; a semiconductor die including a temperature sensor mounted on the spacer dielectric; electrical connections coupling the semiconductor die to the second lead; and mold compound covering the semiconductor die, the die pad, the electrical connections, and a portion of the package substrate, with portions of the first lead and portions of the second lead exposed from the mold compound to form terminals for a packaged temperature sensor device.

The object is to provide a technology for enabling enhancement of the reliability of a semiconductor device. The semiconductor device includes: a semiconductor element; a piece of linear wire connected to an upper surface of the semiconductor element; a coating material in contact with the semiconductor element, and the piece of wire in an upper region on the semiconductor element; and a sealant protecting the semiconductor element, the piece of wire, and the coating material, wherein the coating material contains substances with covalent bonds between oxygen and each of silicon and a metal, a silicon oxide, and siloxane.

In a described example, an apparatus includes: a lead frame having a first portion and having a second portion electrically isolated from the first portion, the first portion having a side surface normal to a planar opposite surface, and having a recessed edge that is notched or chamfered and extending between the side surface and a planar device side surface; a spacer dielectric mounted to the planar device side surface and partially covered by the first portion, and extending beyond the first portion; a semiconductor die mounted to the spacer dielectric, the semiconductor die partially covered by the spacer dielectric and extending beyond the spacer dielectric; the second portion of the lead frame comprising leads coupled to the semiconductor die by electrical connections; and mold compound covering the semiconductor die, the electrical connections, the spacer dielectric, and partially covering the first portion and the second portion.

An object is to provide a technique for suppressing solder from peeling from a copper block. A copper block is bonded on a copper pattern via first solder and an electrode terminal is bonded on the copper block via second solder. The sealing resin covers the copper pattern, the first solder, the copper block, the second solder, the electrode terminal, and the semiconductor element. The area of the portion of the copper block bonded by the first solder is greater than the area of the portion of the copper block bonded by the second solder.

In examples, a semiconductor package comprises a first driver die adapted to be coupled to a high-side switch of a power supply, the first driver die adapted to drive a gate of the high-side switch. The package also includes a second driver die adapted to be coupled to a low-side switch of the power supply, the second driver die adapted to drive a gate of the low-side switch. The package also includes a controller die positioned between the first and second driver dies and configured to control the first and second driver dies. The package also includes a pair of bond wires configured to provide a differential signal between the controller die and the first driver die, a vertical plane of a bond wire in the pair of bond wires and a vertical plane of a side surface of the first driver die having an angle therebetween ranging from 80 to 95 degrees.

A packaged electronic device includes a die pad directly connected to a first set of conductive leads of a leadframe structure, a semiconductor die attached to the conductive die pad, a conductive support structure directly connected to a second set of conductive leads, and spaced apart from all other conductive structures of the leadframe structure. A magnetic assembly is attached to the conductive support structure, and a molded package structure that encloses the conductive die pad, the conductive support structure, the semiconductor die, the magnetic assembly and portions of the conductive leads, the molded package structure including a top side, and an opposite bottom side, wherein the lamination structure is centered between the top and bottom sides.

A transistor device includes a semiconductor substrate having a first major surface and transistor cells formed therein. Each transistor cell includes a drift region of a first conductivity type, a body region of an opposing second conductivity type arranged on the drift region, a source region of the first conductivity type arranged on the body region, a columnar field plate trench extending into the first major surface and including a field plate, and a gate trench structure extending into the first major surface and including a gate electrode. A first metallization structure on the first major surface provides a first contact pad for wire bonding. At least one of depth and doping level of the body region is locally increased within the transistor cells located within one or more first areas of the first major surface. One or more of the first areas are located underneath the first contact pad.

The described techniques address issues associated with electrostatic discharge (ESD) protection for multi-die integrated circuits (ICs). The techniques include the use of two or more semiconductor dies within a multi-die IC, which may include a first semiconductor die without ESD protection but with full ESD exposure. The first semiconductor receives ESD protection via a second semiconductor die that is integrated as part of the same package with the first semiconductor die. The second semiconductor die may be electrically more remote from ESD-exposed pins compared to the first semiconductor die. The first semiconductor die may include integrated passive devices. The second semiconductor die enables ESD protection for both semiconductor dies in the same integrated IC package.