Microelectronic assemblies, and related devices and methods, are disclosed herein. For example, in some embodiments, a microelectronic assembly may include a package substrate having a first surface and an opposing second surface, and a die secured to the package substrate, wherein the die has a first surface and an opposing second surface, the die has first conductive contacts at the first surface and second conductive contacts at the second surface, and the first conductive contacts are coupled to conductive pathways in the package substrate by first non-solder interconnects.

A power semiconductor device includes an insulating substrate on which a first conductor layer is arranged on one surface, a first conductor that is connected to the first conductor layer via a first connecting material, and a semiconductor element that is connected to the first conductor via a first connecting material. When viewed from a direction perpendicular to an electrode surface of the semiconductor element, the first conductor includes a peripheral portion formed larger than the semiconductor element. A first recess is formed in the peripheral portion so that a thickness of the first connecting material becomes thicker than other portions.

Embodiments disclosed herein include electronic packages. In an embodiment, the electronic package comprises a mold layer and a die embedded in the mold layer. In an embodiment the electronic package further comprises a solder resist with a first surface over the mold layer and a second surface opposite from the first surface. In an embodiment, the second surface comprises a first cavity into the solder resist.

A semiconductor device includes an insulating substrate and an upper inductor that is formed on the insulating substrate and is a component of a transformer that performs contactless communication between different potentials. Here, the upper inductor is configured to be applied with a first potential. The upper inductor is formed so as to be magnetically coupled to a lower inductor that is configured to be applied with a second potential different from the first potential.

A stacked package structure and a manufacturing method thereof are provided. The stacked package structure includes an upper redistribution layer, a first chip, and an upper molding layer. The first chip is disposed on the upper redistribution layer and is electrically connected to the upper redistribution layer. The upper molding layer is disposed on the first chip and the upper redistribution layer, and is configured to package the first chip. The upper molding layer includes a recess, the recess is recessed relative to a surface of the upper molding layer away from the upper redistribution layer, and the recess is circumferentially formed around a periphery of the upper molding layer.

In accordance with one aspect of the disclosure, an electronic assembly comprises a semiconductor device with a first side and a second side opposite the first side. The first side has a first conductive pad. The second side has a primary metallic surface. A first substrate (e.g. lead frame) is bonded to a first conductive pad via first metallic bonding layer. A second substrate (e.g., heat sinking circuit board) is bonded to a primary metallic surface via a second metallic bonding layer. In one configuration the second metallic bonding layer is composed of solder and copper, for example.

Provided are a semiconductor device which is provided with a circuit board and capable of suppressing an increase in its footprint, and a power conversion apparatus including the semiconductor device. The semiconductor device includes a circuit board, a power semiconductor element, an insulating block, a control signal terminal, a first main terminal, and a second main terminal. The insulating block is disposed so as to surround the power semiconductor element. The control signal terminal is inserted into the insulating block and thereby fixed to the insulating block. The control signal terminal includes a bent portion which partially protrudes above the power semiconductor element from the insulating block, and is bonded to the power semiconductor element. The first main terminal is bonded to the same power semiconductor element as the power semiconductor element to which the control signal terminal is bonded. The second main terminal is bonded to the circuit board.

The present invention relates to a printed circuit board embedding a power die wherein interconnections between the power die and the printed circuit board are composed of micro/nano wires, the printed circuit board comprising a cavity wherein the power die is placed, and wherein the cavity is further filled with a dielectric fluid.

A packaged integrated circuit (IC) device includes a first IC die with a first inductor, a first layer of adhesive on a first major surface of the first IC die, an isolation layer over the first layer of adhesive, a second layer of adhesive on the isolation layer, a second IC die on the second layer of adhesive, and a second inductor in the second IC die aligned to communicate with the first inductor. The isolation layer extends a prespecified distance beyond a first edge of the second IC die.

A semiconductor device includes a semiconductor chip including a substrate, a transistor provided on an upper surface of the substrate and having an input electrode to which a high frequency signal is input, an output electrode from which the high frequency signal is output, and a reference potential electrode to which a reference potential is supplied, and a metal pattern provided on the upper surface of the substrate and electrically connected to the reference potential electrode, a first capacitor including a first lower electrode provided on the metal pattern and electrically connected to the metal pattern, a first dielectric layer provided on the first lower electrode, and a first upper electrode provided on the first dielectric layer, and a first bonding wire electrically connecting the first upper electrode and a first electrode which is any one of the input electrode and the output electrode.