A light emitting device including at least one LED stack, electrode pads disposed on the LED stack, and cantilever electrodes disposed on the electrode pads, respectively, in which each of the cantilever electrodes has a fixed edge that is fixed to one of the electrode pads and a free standing edge that is spaced apart from the one of the electrode pads.

A pressing device for indirectly or directly applying pressure to power-semiconductor components of a power-semiconductor module, having a pressing plate, having a pressing nub element which is formed from an elastic material and which has a pressing nub plate and pressing nubs projecting therefrom, and having a receiving device for receiving the pressing nub element, which receiving device has a base plate provided with recesses, wherein the recesses run through the base plate, wherein the pressing nub plate is arranged on the base plate and the pressing nubs run through the recesses and, on the main side of the base plate facing away from the pressing nub plate, project beyond this main side of the base plate, and wherein the pressing nub plate is arranged between the pressing plate and the base plate.

A power semiconductor module includes a flexible first substrate and a flexible second substrate and a first and second power semiconductor switch arranged between the first and second substrate. The first substrate has an electrically conductive first metal layer facing towards the power semiconductor switches, an electrically conductive second metal layer and an electrically non-conductive first insulation film arranged between the first and second metal layer. The second substrate has an electrically non-conductive second insulation film and a third metal layer arranged on the second insulation film. The first and second power semiconductor switch are electrically interconnected by the first and second substrate to form a half-bridge circuit.

A semiconductor device includes a plurality of semiconductor chips, an insulating part, a first electrode, a second electrode, a first bus bar, and a second bus bar. The insulating part surrounds the semiconductor chips. The first electrode is in pressure contact with the semiconductor chips. The semiconductor chips are sandwiched between the first electrode and the second electrode in a first direction. The second electrode is in pressure contact with the semiconductor chips. The first bus bar is connected to the first electrode. The second bus bar is connected to the second electrode. The first bus bar and the second bus bar sandwich the insulating part in a second direction intersecting the first direction.

In an embodiment, a device includes: a package component including integrated circuit dies, an encapsulant around the integrated circuit dies, a redistribution structure over the encapsulant and the integrated circuit dies, and sockets over the redistribution structure; a mechanical brace physically coupled to the sockets, the mechanical brace having openings, each one of the openings exposing a respective one of the sockets; a thermal module physically and thermally coupled to the encapsulant and the integrated circuit dies; and bolts extending through the thermal module, the mechanical brace, and the package component.

The present disclosure provides a semiconductor module comprising a semiconductor device removably pressed-fit in a cavity formed in a printed circuit board and methods for manufacturing the same. The semiconductor device and the cavity of the printed circuit board can cooperate with each other and act as an electrical plug and an electrical socket respectively. Soldering the semiconductor device on the printed circuit board can be avoided. Therefore, the packaging process can be more flexible and reliability issues with solder joints can be eliminated. Moreover, heatsink can be mounted on top and/or bottom of the semiconductor device after being received in the cavity of the printed circuit board. Thermal dissipation efficiency can be greatly enhanced.

We disclose herein a semiconductor device sub-assembly comprising a plurality of semiconductor units of a first type, a plurality of semiconductor units of a second type; a plurality of conductive blocks operatively coupled with the plurality of semiconductor units, a conductive malleable layer operatively coupled with the plurality of conductive blocks, wherein the plurality of conductive blocks are located between the conductive malleable layer and the plurality of semiconductor units. In use, at least some of the plurality of conductive blocks are configured to apply a pressure on the conductive malleable layer, when a predetermined pressure is applied to the semiconductor device sub-assembly. At least one semiconductor unit of a second type is configured to withstand an applied pressure greater than a threshold pressure.

A mounting structure for a heater element includes a heater element having a surface to be cooled, a board on which the heater element is mounted, a cooling member that cools the surface to be cooled of the heater element mounted on the board, and a supporting member temporarily fixed to the board, the supporting member temporarily fixing the heater element.

Provided is a small-sized inexpensive semiconductor module in which increase of ON resistance and increase of turn-off surge voltage at low temperature are suppressed. The semiconductor module includes: a semiconductor switching element; and a stress application portion provided on one or each of a first surface and a second surface on an opposite side to the first surface of the semiconductor switching element, having a linear expansion coefficient larger than that of a main material of the semiconductor switching element, and having a larger thickness than the semiconductor switching element. The stress application portion generates compressive or tensile stress in the semiconductor switching element through thermal shrinkage or expansion of the stress application portion due to change in temperature. A threshold voltage at which the semiconductor switching element is turned on, decreases in association with increase of a magnitude of the compressive or tensile stress in the semiconductor switching element.

A semiconductor device may include a first plate-like element having a first substantially planar connection surface with a first connection pad and a second plate-like element having a second substantially planar connection surface with a second connection pad corresponding to the first connection pad. The device may also include a connection electrically and physically coupling the first and second plate-like elements and arranged between the first and second connection pads. The connection may include a deformed elongate element arranged on the first connection pad and extending toward the second connection pad and solder in contact with the second connection pad and the elongate element.