The disclosure is directed to wide band-gap semiconductor devices, such as power devices based on silicon carbide or gallium nitride materials. A power device die is attached to a carrier substrate or a base using sintered silver as a die attachment material or layer. The carrier substrate is, in some embodiments, copper plated with silver. The sintered silver die attachment layer is formed by sintering silver nanoparticle paste under a very low temperature, for example, lower than 200 C. and in some embodiments at about 150 C., and with no external pressures applied in the sintering process. The silver nanoparticle is synthesized through a chemical reduction process in an organic solvent. After the reduction process has completed, the organic solvent is removed through evaporation with a flux of inert gas being injected into the solution.

In a semiconductor device, a first wiring member is electrically connected to a first main electrode on a first surface of a semiconductor element, and a second wiring member is electrically connected to a second main electrode on a second surface of the semiconductor element. An encapsulating body encapsulates at least a part of each of the first and second wiring members, the semiconductor element and a bonding wire. The semiconductor element has a protective film on the first surface of the semiconductor substrate, and the pad has an exposed surface exposed from an opening of the protective film. The exposed surface includes a connection area to which the bonding wire is connected, and a peripheral area on a periphery of the connection area. The peripheral area has a surface that defines an angle of 90 degrees or less relative to a surface of the connection area.

An electric apparatus includes: a first stacked body in which a first semiconductor chip having a first switch is stacked on a first mounting portion; a second stacked body in which a second semiconductor chip having a second switch is stacked on a second mounting portion; a temperature sensor provided in the first stacked body to detect a temperature of the first switch; and a current sensor provided in the second stacked body to detect a current flowing through the second switch. The second stacked body has a heat dissipation property higher than that of the first stacked body.

Aspects of the present disclosure include systems, structures, circuits, and methods providing voltage-isolated integrated circuit (IC) packages or modules having a transformer integrated with or implemented on a lead frame. A portion of transformer windings may include a conductive portion of a lead frame. Conductive structure, such as wire bonds, may be used for other portions of transformer windings. In some examples, an insulating coating may be placed on the package to increase the isolation capability of the final package. The IC packages and modules may include various types of circuits; in some examples, IC packages or modules may include a galvanically isolated gate driver or other high voltage circuit.

A semiconductor device includes a leadframe, a first semiconductor chip arranged above a mounting surface of the leadframe, and a heatsink arranged above a top surface of the first semiconductor chip facing away from the mounting surface of the leadframe. At least one first lead of the leadframe extends towards a bottom surface of the heatsink facing the mounting surface of the leadframe. The at least one first lead is mechanically coupled to the bottom surface of the heatsink.

A power semiconductor module may comprise a common drain pad, a first power semiconductor device on a first region of the common drain pad, a second power semiconductor device on a second region of the common drain pad, a molding layer surrounding lateral parts of the first power semiconductor device and the second power semiconductor device on a peripheral region of the common drain pad, a common gate pad on the first power semiconductor device and the second power semiconductor device, and a source pad on the first power semiconductor device and the second power semiconductor device. The source pad may surround at least two outer lateral parts of the common gate pad.

The invention relates to a power semiconductor module comprising a conductive base, a conductive top, and at least two power semiconductor devices arranged between the conductive base and the conductive top. The semiconductor devices are each configured for a current of at least 1 A and/or for a voltage of at least 50 V. An insulating spacer layer is arranged on the power semiconductor devices and at least partially between the conductive base and the conductive top. At least two vertical connection elements pass from the power semiconductor devices through the spacer layer and conductively connect the conductive top with the power semiconductor devices. The spacer layer and the vertical connection elements are configured for compensating height differences of the power semiconductor devices.

A semiconductor package includes a lead frame, a low side field-effect transistor (FET), a high side FET, a metal clip, and a molding encapsulation. The low side FET is flipped and is attached to a first die paddle of the lead frame. The lead frame comprises one or more voltage input (Vin) leads; a gate lead; one or more switching node (Lx) leads; a first die paddle; a second die paddle; and an end paddle. Each of an exposed bottom surface of the one or more Lx leads is directly connected to an exposed bottom surface of the end paddle. A longitudinal direction of an exposed bottom surface of the gate lead is perpendicular to a longitudinal direction of each of the exposed bottom surface of the one or more Lx leads. An entirely of each of the one or more Vin leads is of the full thickness.

A low-inductance power module comprises a housing, upper-bridge MOSs, lower-bridge SBDs, lower-bridge MOSs, upper-bridge SBDs, output electrodes, a positive electrode and a negative electrode. A bottom plate is mounted inside the housing. An insulating substrate is mounted at the top of the bottom plate. A positive-electrode copper layer, a negative-electrode copper layer and an output-electrode copper layer are arranged on the upper surface of the insulating substrate. The output-electrode copper layer is divided into an upper-side output-electrode copper layer and a lower-side output-electrode copper layer.

A molded semiconductor package includes a lead frame having one or more first leads monolithically formed with a die pad and extending outward from the pad in a first direction. A semiconductor die is attached to the die pad at a first side of the die. A metal clip of a clip frame is attached to a power terminal at a second side of the die. One or more second leads monolithically formed with the metal clip extend outward from the clip in a second direction different than the first direction. A mold compound embeds the die. The first lead(s) and the second lead(s) are exposed at different sides of the mold compound and do not vertically overlap with one another. Within the mold compound, the clip transitions from a first level above the power terminal to a second level in a same plane as the leads.