Semiconductor module having a first substrate, a second substrate and a spacer distancing the substrates from each other, wherein the spacer is formed by at least one elastic shaped metal body.

It is an object of the present invention to improve a heat radiation property of a metal wire on a semiconductor chip in a power module. A power module includes: a plurality of metal wires connected to a surface of at least one semiconductor chip; and a thermal conductive sheet having contact with the metal wire. The metal wire includes: at least one first metal wire connecting a surface of the semiconductor chip and a circuit pattern and at least one second metal wire connecting two points on the surface of the semiconductor chip and having the same potential as the first metal wire. The thermal conductive sheet includes a graphite sheet, and a sheet surface of the thermal conductive sheet has contact with the at least one first metal wire and the at least one second metal wire.

An integrated circuit is formed by forming an isolation trench through at least a portion of an interconnect region, at least 40 microns deep into a substrate of the integrated circuit, leaving at least 200 microns of substrate material under the isolation trench. Dielectric material is formed in the isolation trench at a substrate temperature no greater than 320° C. to form an isolation structure which separates an isolated region of the integrated circuit from at least a portion of the substrate. The isolated region contains an isolated component. The isolated region of the integrated circuit may be a region of the substrate, and/or a region of the interconnect region. The isolated region may be a first portion of the substrate which is laterally separated from a second portion of the substrate. The isolated region may be a portion of the interconnect region above the isolation structure.

Isolators having a back-to-back configuration for providing electrical isolation between two circuits are described, in which multiple isolators formed on a single monolithic substrate are connect in series to achieve a higher amount of electrical isolation for a single substrate than for one of the isolators alone. A pair of isolators in the back-to-back configuration have top and bottom isolator components where the top isolator components are connected together and electrically isolated from the underlying substrate, resulting in floating top isolator components. The back-to-back isolator may provide one or more communication channels for transfer of information and/or power between different circuits.

An insulated gate bipolar field-effect transistor (IGBT) includes a semiconductor chip, a gate pin disposed around the semiconductor chip, and an emitter region and n gate regions that are disposed on the semiconductor chip, where n is an integer greater than or equal to 2; x gate regions in the n gate regions are connected to the gate pin, where x is greater than or equal to 1 and less than or equal to n; when there is a different quantity x of gate regions connected to the gate pin, the IGBT is correspondingly applicable to a scenario in which there is a different switching frequency and a different switching loss; and n−x gate regions in the n gate regions are connected to the emitter region.

A semiconductor memory device includes first and second memory chips, each including a region of a core circuit, a first area adjacent to a first side of the region in a first direction, a second area adjacent to a second side of the region in a second direction, a third area adjacent to the first area in the first direction and to the second area in the second direction, a first pad in the first area, a second pad in the second area, and third pad in the third area. In each memory chip, a first bonding wire connects the first and third pads. In addition, a second bonding wire connects the second pads of the first and second memory chips. The second memory chip is stacked on the first memory chip to expose the first, second, and third areas of the first memory chip in a third direction.

A lead frame for a multi-chip module includes a first conductor structure disposed on a substrate and having first and second arms linked at an angle. The first conductor structure is connected to ground. The lead frame also includes a second conductor structure disposed on the substrate and connected to a voltage supply. The second conductor structure is spaced apart and electrically isolated from the first conductor structure. The first and the second conductor structures are arranged to flank a plurality of integrated circuits (ICs) including one or more surge protection ICs disposed on the substrate. The first conductor structure is electrically connected to the plurality of ICs to provide electrical connections to ground, and the second conductor structure is electrically connected to the plurality of ICs to provide electrical connections to the voltage supply.

An object of the present disclosure is to suppress a shrinkage cavity without affecting the layout or the insulation performance of the semiconductor element in a power semiconductor device. A power semiconductor device includes a heat radiation plate; an insulating substrate bonded in a bonding region on an upper surface of the heat radiation plate with a bonding material containing a plurality of elements having different solidification points; a semiconductor element mounted on an upper surface of the insulating substrate; and a bonding wire bonded in the bonding region on the upper surface of the heat radiation plate such that the bonding wire surrounds the semiconductor element in plan view.

A semiconductor includes a multilayer substrate including an insulating plate and a plurality of circuit boards disposed on a top face of the insulating plate, a semiconductor element disposed on a top face of one of the plurality of circuit boards, and having a main electrode disposed on a top face thereof, and a temperature measurement device for measuring a temperature of the semiconductor element. The temperature measurement device includes a cable unit composed of an insulated optical fiber, and a temperature measurement unit provided on one end of the cable unit, the temperature measurement unit being bonded to the main electrode of the semiconductor element using a bonding material.

RC-IGBT chips and RC-IGBT chips correspond to a pair of adjacent RC-IGBT chips in an X direction between the RC-IGBT chips. The RC-IGBT chips satisfy a first arrangement condition in which the chips are separately arranged without a bonding point region and a bonding point region overlapping each other in a Y direction, and a second arrangement condition in which, in the Y direction, the chips are arranged to partially overlap so that a part of emitter electrodes excluding the bonding point region and the bonding point region overlap. The RC-IGBT chips also satisfy the first and second arrangement conditions described above.