An element electrode is located on a surface of a semiconductor element. A metal film is located on the element electrode and includes an inner region and an outer region located around the inner region. The metal film has an opening that exposes the element electrode between the inner region and the outer region. The element electrode has solder wettability lower than solder wettability of the metal film. An external electrode is solder-bonded to the inner region of the metal film.

A device is provided that includes a switch within a package. A first electrical connection is provided between a load terminal of the switch and first pin of the package, and a second electrical connection at least partially different from the first electrical connection is provided between the switch and a second pin of the package. The second pin is different from the first pin.

On the assumption that a pair of hanging parts is provided in a lead frame and a clip includes a main body part and a pair of extension parts, the pair of the extension parts is mounted and supported on the pair of the hanging parts. Accordingly, the clip is mounted on a lead (one point) and the pair of the hanging parts (two points), and the clip is supported by the three points.

A semiconductor device and an electronic device are improved in performances by supporting a large current. An emitter terminal protrudes from a first side of a sealing body, and signal terminals protrude from a second sides of the sealing body. Namely, the side of the sealing body from which the emitter terminal protrudes and the side of the sealing body from which the signal terminals protrude are different. More particularly, the signal terminals protrude from the side of the sealing body opposite the side thereof from which the emitter terminal protrudes. Further, a second semiconductor chip including a diode formed therein is mounted over a first surface of a chip mounting portion in such a manner as to be situated between the emitter terminal and the a first semiconductor chip including an IGBT formed therein in plan view.

A control electrode GE1 is formed in a lower portion of a trench TR1 formed in a semiconductor substrate SUB, and a gate electrode GE2 is formed in an upper portion inside the trench TR1. An insulating film G1 is formed between the control electrode GE1 and a side wall and a bottom surface of the trench TR1, an insulating film G2 is formed between the side wall of the trench TR1 and the gate electrode GE2, and an insulating film G3 is formed between the control electrode GE1 and the gate electrode GE2. A region adjacent to the trench TR1 includes an n.sup.+-type semiconductor region NR for a source, a p-type semiconductor region PR for a channel formation, and a semiconductor region for a drain. A wiring connected to the control electrode GE1 is not connected to a wiring connected to the gate electrode GE2, and is not connected to a wiring connected to the n.sup.+-type semiconductor region NR for a source.

A method of manufacturing a semiconductor device that includes an insulated circuit board having a conductive pattern, a first semiconductor chip with a rectangular shape connected through a first joining material to the conductive pattern, a second semiconductor chip with a rectangular shape disposed on the conductive pattern separated from the first semiconductor chip and connected through a second joining material to the conductive pattern, a terminal disposed above the semiconductor chips, respectively connected to the first and second semiconductor chips through third and fourth joining materials, the terminal having a through-hole above a place between the first and second semiconductor chips, the method including a positioning step in which the first and second semiconductor chips are respectively positioned at at least three positioning places, and at least one of the positioning places is positioned with a positioning member inserted into the through-hole.

A thermal management solution may be provided for a microelectronic system including a flexible integrated heat spreader, wherein the flexible integrated heat spreader may comprise a plurality of thermally conductive structures having a flexible thermally conductive film attached to and extending between each of the plurality of thermally conductive structures. The flexible integrated heat spreader may be incorporated into multi-chip package by providing a microelectronic substrate having a plurality of microelectronic devices attached thereto and by thermally contacting each of the plurality of thermally conductive structures of the flexible integrated heat spreader to its respective microelectronic device on the microelectronic substrate.

A device is provided that includes a switch within a package. A first electrical connection is provided between a load terminal of the switch and first pin of the package, and a second electrical connection at least partially different from the first electrical connection is provided between the switch and a second pin of the package. The second pin is different from the first pin.

In a semiconductor device, a multilayer substrate includes an insulating substrate, a first circuit board having a first semiconductor chip disposed thereon, and a second circuit board having a second semiconductor chip disposed thereon. On the multilayer substrate of the semiconductor device, a plate portion of a resin plate including a first positioning portion that regulates the position of each semiconductor chip is sandwiched between a first jumper terminal, which includes a first terminal connected to the first semiconductor chip and a first plate member perpendicular to the first terminal, and a second jumper terminal, which includes a second terminal connected to the second semiconductor chip and a second plate member perpendicular to the second terminal.

A semiconductor device package includes a conductive clip that has a recess and that is configured to mount to a substrate along a first surface and a second surface that bound the recess, and that includes at least two vertical channel transistors that are of a same type and that are mounted within the recess in a same orientation such that a drain or source contact is coupled to the conductive clip, and such that a gate contact and a source or drain contact extend exposed within the recess and along a same long axis of the conductive clip.