A semiconductor device, includes: first semiconductor element including first and second electrodes; second semiconductor element including third and fourth electrodes; sealing resin covering the semiconductor elements; first, second, third, and fourth terminal portions respectively connected to the first, second, third, and fourth electrodes and exposed from the sealing resin; first island portion where the first semiconductor element is mounted; and second island portion where the second semiconductor element is mounted, wherein four quadrants divided by first imaginary line extending along second direction orthogonal to first direction and second imaginary line extending along third direction orthogonal to both the first and second directions are defined.

A method of forming a flip-chip integrated circuit die that includes a front side including active circuitry formed therein and a plurality of bond pads in electrical communication with the active circuitry, at least two through-wafer vias in electrical communication with the active circuitry and extending at least partially though the die and having portions at a rear side of the die, and a bond wire external to the die and electrically coupling the portions of the at least two through-wafer vias to one another at the rear side of the die.

A method of forming a flip-chip integrated circuit die that includes a front side including active circuitry formed therein and a plurality of bond pads in electrical communication with the active circuitry, at least two through-wafer vias in electrical communication with the active circuitry and extending at least partially though the die and having portions at a rear side of the die, and a bond wire external to the die and electrically coupling the portions of the at least two through-wafer vias to one another at the rear side of the die.

An electronic element mounting substrate includes: a first substrate including a first principal face and a second principal face opposite to the first principal face; a second substrate including a third principal face and a fourth principal face opposite to the third principal face, the second substrate being made of a carbon material; and a plurality of via conductors that are arranged in the first substrate. The second substrate is located inside the first substrate in the plan view. In the plan view, the plurality of via conductors are arranged with the second substrate in between. In the plan view, heat conduction of the second substrate is greater in a direction perpendicular to a direction in which the plurality of via conductors are arranged with the second substrate in between than in the direction in which the plurality of via conductors are arranged with the second substrate in between.

Multi-chip modules may include stacked semiconductor devices having spacers therebetween. Discrete conductive elements may extend over the active surface of an underlying semiconductor device from respective bond pads of the underlying semiconductor device, through a space formed by the spacers, to respective contact areas on a substrate. Each discrete conductive element extending through two side openings opposite one another may extend from a respective centrally located bond pad proximate to a central portion of the active surface of the underlying semiconductor device. Each discrete conductive element extending through another, perpendicular opening may extend from a respective peripheral bond pad located proximate to a peripheral portion of the active surface of the underlying semiconductor device.

The semiconductor device includes a semiconductor element, a first lead, and a second lead. The semiconductor element has an element obverse surface and an element reverse surface spaced apart from each other in a thickness direction. The semiconductor element includes an electron transit layer disposed between the element obverse surface and the element reverse surface and formed of a nitride semiconductor, a first electrode disposed on the element obverse surface, and a second electrode disposed on the element reverse surface and electrically connected to the first electrode. The semiconductor element is mounted on the first lead, and the second electrode is joined to the first lead. The second lead is electrically connected to the first electrode. The semiconductor element is a transistor. The second lead is spaced apart from the first lead and is configured such that a main current to be subjected to switching flows therethrough.

A semiconductor device includes: a multilayer substrate which includes a circuit board and an insulating plate on which the circuit board is formed; and a contact part having a cylindrical hollow hole therein and an open end bonded to a bonding area on the front surface of the circuit board via bonding material. In the case of this semiconductor device, wettability of a contact area of the contact part with respect to the bonding material is approximately equal to wettability of at least the bonding area of the circuit board with respect to the bonding material. Thus, the rising of the bonding material into the hollow hole of the contact part during heating performed when the contact part is bonded to the circuit board is reduced.

A semiconductor device includes: a multilayer substrate which includes a circuit board and an insulating plate on which the circuit board is formed; and a contact part having a cylindrical hollow hole therein and an open end bonded to a bonding area on the front surface of the circuit board via bonding material. In the case of this semiconductor device, wettability of a contact area of the contact part with respect to the bonding material is approximately equal to wettability of at least the bonding area of the circuit board with respect to the bonding material. Thus, the rising of the bonding material into the hollow hole of the contact part during heating performed when the contact part is bonded to the circuit board is reduced.

The present application provides a semiconductor module and a power conversion device wherein wiring inductance is reduced. The semiconductor module is characterized by including a semiconductor element, a first terminal on which the semiconductor element is mounted, a second terminal disposed in a periphery of the semiconductor element and having a multiple of wiring portions, and a multiple of connection lines extending in multiple directions from an upper face of the semiconductor element and connected to each of the multiple of wiring portions of the second terminal, wherein a free region is provided among the multiple of wiring portions, and the multiple of connection lines and the multiple of wiring portions forming current paths with each of the multiple of connection lines are of the same potential.

Disclosed are semiconductor devices that include additional gate pads, and methods of fabricating and testing such devices. A device may include a first gate pad, a second gate pad, and a third gate pad. The first gate pad is connected to a gate including a gate oxide layer. The second and third gate pads are part of an electro-static discharge (ESD) protection network for the device. The ESD protection network is initially isolated from the first gate pad and hence from the gate and gate oxide layer. Accordingly, gate oxide integrity (GOI) testing can be effectively performed and the reliability and quality of the gate oxide layer can be checked. The second gate pad can be subsequently connected to the first gate pad to enable the ESD protection network, and the third gate pad can be subsequently connected to an external terminal when the device is packaged.