The power module semiconductor device (2) includes: an insulating substrate (10); a first pattern (10a) (D) disposed on the insulating substrate (10); a semiconductor chip (Q) disposed on the first pattern; a power terminal (ST, DT) and a signal terminal (CS, G, SS) electrically connected to the semiconductor chip; and a resin layer (12) configured to cover the semiconductor chip and the insulating substrate. The signal terminal is disposed so as to be extended in a vertical direction with respect to a main surface of the insulating substrate.

A device includes an interposer including an insulative layer between a lower metal layer and a first upper metal layer and a second upper metal layer, a semiconductor transistor die attached to the first upper metal layer and comprising a first lower main face and a second upper main face, with a drain or collector pad on the first main face and electrically connected to the first upper metal layer, a source or emitter electrode pad and a gate electrode pad on the second main face, a leadframe connected to the interposer and comprising a first lead connected with the first upper metal layer, a second lead connected with the source electrode pad, and a third lead connected with the second upper metal layer, and wherein an electrical connector that is connected between the gate electrode pad and the second upper metal layer is orthogonal to a first electrical connector.

The present invention provides a silicon carbide composite wafer and a manufacturing method thereof. The silicon carbide composite wafer includes (a) a silicon carbide material and (b) a wafer substrate, and the upper surface of the wafer substrate is bonded to the lower surface of the silicon carbide material, wherein the lower surface of the silicon carbide material and/or the upper surface of the wafer substrate undergo a surface modification, thereby allowing the silicon carbide material to be bonded to the wafer substrate directly and firmly. The technical effects of the present invention include achieving strong bonding between the wafer and the substrate, reducing manufacturing process, increasing yield rate, and achieving high industrial applicability.

A chip structure including a chip body and a plurality of conductive bumps. The chip body includes an active surface and a plurality of bump pads disposed on the active surface. The conductive bumps are disposed on the active surface of the chip body and connected to the bump pads respectively, and at least one of the conductive bumps has a trapezoid shape having one pair of parallel sides and one pair of non-parallel sides.

Various embodiments may provide a semiconductor package. The semiconductor package may include a first electrical component, a second electrical component, a first heat sink, and a second heat sink bonded to a first package interconnection component and a second package interconnection component. The first package interconnection component and the second package interconnection component may provide lateral and vertical interconnections in the package.

A semiconductor device, having a first semiconductor chip including a first side portion at a front surface thereof and a first control electrode formed in the first side portion, a second semiconductor chip including a second side portion at a front surface thereof and a second control electrode formed in the second side portion, a first circuit pattern, on which the first semiconductor chip and the second semiconductor chip are disposed, a second circuit pattern, and a first control wire electrically connecting the first control electrode, the second control electrode, and the second circuit pattern. The first side portion and the second side portion are aligned. The first control electrode and the second control electrode are aligned. The second circuit pattern are aligned with the first control electrode and the second control electrode.

There is provided a bonding material which forms a bonding portion between two objects, which material contains (1) first metal particles comprising a first metal and having a median particle diameter in the range of 20 nm to 1 μm, and (2) second metal particles comprising, as a second metal, at least one alloy of Sn and at least one selected from Bi, In and Zn and having a melting point of not higher than 200° C.

The semiconductor module includes a first device that has an IGBT and a second device that has a reflux diode which is anti-parallel connected to the IGBT, which has a forward threshold voltage less than a reverse withstand voltage of the IGBT, and which has a forward breakdown voltage in excess of the reverse withstand voltage of the IGBT.

A package comprising a first integrated device comprising a first plurality of under bump metallization interconnects; a second integrated device comprising a second plurality of under bump metallization interconnects; a bridge coupled to the first integrated device and the second integrated device; an encapsulation layer at least partially encapsulating the first integrated device, the second integrated device, and the bridge; a metallization portion located over the first integrated device, the second integrated device, the bridge and the encapsulation layer, where the metallization portion includes at least one dielectric layer and a plurality of metallization interconnects; a first plurality of pillar interconnects coupled to the first plurality of under bump metallization interconnects, the first plurality of interconnects located in the encapsulation layer; and a second plurality of pillar interconnects coupled to the second plurality of under bump metallization interconnects, the second plurality of pillar interconnects located in the encapsulation layer.

A semiconductor device manufacturing method includes a preparation step and a sinter bonding step. In the preparation step, a sinter-bonding work having a multilayer structure including a substrate, semiconductor chips, and sinter-bonding material layers is prepared. The semiconductor chips are disposed on, and will bond to, one side of the substrate. Each sinter-bonding material layer contains sinterable particles and is disposed between each semiconductor chip and the substrate. In the sinter bonding step, a cushioning sheet having a thickness of 5 to 5000 μm and a tensile elastic modulus of 2 to 150 MPa is placed on the sinter-bonding work, the resulting stack is held between a pair of pressing faces, and, in this state, the sinter-bonding work between the pressing faces undergoes a heating process while being pressurized in its lamination direction, to form a sintered layer from each sinter-bonding material layer.