Solder bumps are placed in direct contact with the silicon substrate of an amplifier integrated circuit having a flip chip configuration. A plurality of amplifier transistor arrays generate waste heat that promotes thermal run away of the amplifier if not directed out of the integrated circuit. The waste heat flows through the thermally conductive silicon substrate and out the solder bump to a heat-sinking plane of an interposer connected to the amplifier integrated circuit via the solder bumps.

A power module (1) includes a group of at least three rectangular electrical power components (11, 12, 13, 14, 23, 24, 25, 26) arranged on a substrate (2), wherein in that at least one side (31) of at least one of the rectangular electrical power components (11, 14) is not orthogonal or parallel to a line (3) that passes through the geometric centres of the remaining rectangular electrical power components (12, 13) of the group.

Provided is a metal jointed body, joined by solid-phase joining in the atmosphere, in which no protrusion of molten joining material occurs, that improves dimensional stability. A metal jointed body is formed by (A) making Ag films of two metal laminated bodies opposed to each other, the metal jointed body being configured by sequentially laminating a Zn film and an Ag film on an Al substrate serving as a member to be joined, and (B) bringing the Ag films into contact with each other, then (C) heating is performed while pressurizing, and closely adhering and solid-phase joining the Ag films to each other. The completed metal jointed body is a portion where Al—Ag alloy layers are provided on both sides of an Ag—Zn—Al alloy layer to join the Al substrates to each other.

The disclosure provides an electronic device which includes a substrate structure, a driving component, and a conductive pattern. The driving component and the conductive pattern are formed on the substrate structure, and the thickness of the conductive pattern is greater than or equal to 0.5 μm and less than or equal to 15 μm.

Disclosed herein are IC structures, packages, and devices that include planar III-N transistors with wrap-around gates and/or one or more wrap-around source/drain (S/D) contacts. An example IC structure includes a support structure (e.g., a substrate) and a planar III-N transistor. The transistor includes a channel stack of a III-N semiconductor material and a polarization material, provided over the support structure, a pair of S/D regions provided in the channel stack, and a gate stack of a gate dielectric material and a gate electrode material provided over a portion of the channel stack between the S/D regions, where the gate stack at least partially wraps around an upper portion of the channel stack.

A semiconductor device including an insulating circuit board. The insulating circuit board has an insulating plate, a plurality of circuit patterns disposed on a front surface of the insulating plate, any adjacent two of the circuit patterns having a gap therebetween, each circuit pattern having at least one corner, each corner being in a corner area that covers the corner and a portion of each gap adjacent to the corner, and a buffer material containing resin, applied at a plurality of corner areas, to fill the gaps in the plurality of corner areas.

Multichip package manufacturing process is disclosed to form external pins at one side or each side of die-bonding area of package carrier board and to bond first IC and second IC to die-bonding area in stack. First IC and second IC each comprise transistor layer with core circuits, plurality of metal layers, plurality of VIA layers and solder pad layer. During production of first IC, design of at least one metal layer, VIA layer and dummy pads can be modified according to change of design of second IC. After chip probing, die sawing and bonding, wire bonding, packaging and final test are performed to package the package carrier board, first IC and second IC into automotive multichip package, achieving purpose of first IC only need to modify at least one layer or more than one layer to cooperate with second IC design change to carry out multichip packaging process.

A power amplifier module includes a substrate including, in an upper surface of the substrate, an active region and an element isolation region. The power amplifier module further includes a collector layer, a base layer, and an emitter layer that are stacked on the active region; an interlayer insulating film that covers the collector layer, the base layer, and the emitter layer; a pad that is thermally coupled to the element isolation region; and an emitter bump that is disposed on the interlayer insulating film, electrically connected to the emitter layer through a via hole provided in the interlayer insulating film, and electrically connected to the pad. In plan view, the emitter bump partially overlaps an emitter region which is a region of the emitter layer and through which an emitter current flows.

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.

A component carrier includes a stack with at least one electrically conductive layer structure, at least one electrically insulating layer structure, a cavity delimited at a bottom side at least partially by a top side of a stepped metal structure of the at least one electrically conductive layer structure, and a component embedded in the cavity and arranged on the stepped metal structure. A bottom side of the stepped metal structure has a flat surface extending continuously along at least one horizontal direction.