Various embodiments of the teachings herein include a method for joining and insulating a power electronic semiconductor component with contact surfaces to a substrate. In some embodiments, the method includes: preparing the substrate with a metallization defining an installation slot having joining material, wherein the substrate comprises an organic or a ceramic wiring support; arranging an electrically insulating film and the semiconductor component on the substrate, such that the contact surfaces of the semiconductor component facing the substrate are omitted from the film and regions of the semiconductor component exposed by the contact surfaces are insulated at least in part by the film from the substrate and from the contact surfaces; and joining the semiconductor component to the substrate and electrically insulating the semiconductor component at least in part by the film in one step.

A semiconductor package and a method of manufacturing the same are provided. The semiconductor package includes a semiconductor die, an encapsulant and a redistribution structure. The encapsulant laterally encapsulates the semiconductor die. The redistribution structure is disposed on the encapsulant and electrically connected with the semiconductor die, wherein the redistribution structure comprises a first conductive via, a first conductive wiring layer and a second conductive via stacked along a stacking direction, the first conductive via has a first terminal surface contacting the first conductive wiring layer, the second conductive via has a second terminal surface contacting the first conductive wiring layer, an area of a first cross section of the first conductive via is greater than an area of the first terminal surface of the first conductive via, and an area of a second cross section of the second conductive via is greater than an area of the second terminal surface of the second conductive via.

A surface mount electronic device providing an electrical connection between an integrated circuit (IC) and a printed circuit board (PCB) is provided and includes a die and a dielectric material formed to cover portions of the die. Pillar contacts are electrically coupled to electronic components in the die and the pillar contacts extend from the die beyond an outer surface of the die. A conductive ink is printed on portions of a contact surface of the electronic device package and forms electrical terminations on portions of the dielectric material and electrical connector elements that connect an exposed end surface of the pillar contacts to the electrical terminations.

Embodiments include semiconductor packages. A semiconductor package includes a first patch and a second patch on an interposer. The semiconductor package also includes a first substrate in the first patch, and a second substrate in the second patch. The semiconductor package further includes an encapsulation layer over and around the first and second patches, a plurality of build-up layers on the first patch, the second patch, and the encapsulation layer, and a plurality of dies and a bridge on the build-up layers. The bridge may be communicatively coupled with the first substrate of the first patch and the second substrate of the second patch. The bridge may be an embedded multi-die interconnect bridge (EMIB). The first and second substrates may be EMIBs and/or high-density packaging (HDP) substrates. The bridge may be positioned between two dies, and over an edge of the first patch and an edge of the second patch.

A semiconductor package includes a substrate, a stacked structure, an encapsulation material, a lid structure, and a coupler. The stacked structure is disposed over and bonded to the substrate. The encapsulation material partially encapsulates the stacked structure. The lid structure is disposed on the substrate, wherein the lid structure surrounds the stacked structure and covers a top surface of the stacked structure. The coupler is bonded to the stacked structure, wherein a portion of the coupler penetrates through and extends out of the lid structure.

Before a semiconductor die of a brittle III-V compound semiconductor is encapsulated with a molding compound during package fabrication, side surfaces of the semiconductor die are treated to avoid or prevent surface imperfections from propagating and fracturing the crystal structure of the substrate of the III-V compound semiconductor under the stresses applied as the molding compound solidifies. Surfaces are treated to form a passivation layer, which may be a passivated layer of the substrate or a passivation material on the substrate. In a passivated layer, imperfections of an external layer are transformed to be less susceptible to fracture. Passivation material, such as a poly-crystalline layer on the substrate surface, diffuses stresses that are applied by the molding compound. Semiconductor dies in flip-chip and wire-bond chip packages with treated side surfaces as disclosed have a reduced incidence of failure caused by die fracturing.

A semiconductor device has a heat spreader with an opening formed through the heat spreader. The heat spreader is disposed over a substrate with a semiconductor die disposed on the substrate in the opening. A thermally conductive material, e.g., adhesive or an elastomer plug, is disposed in the opening between the heat spreader and semiconductor die. A conductive layer is formed over the substrate, heat spreader, and thermally conductive material.

Structures and formation methods of a chip package structure are provided. The chip package structure includes adjacent first and second semiconductor dies bonded over an interposer substrate. The chip package structure also includes an insulating layer formed over the interposer substrate. The insulating layer has a first portion surrounding the first and second semiconductor dies and a second portion extending between a first sidewall of the first semiconductor die and a second sidewall of the second semiconductor die, and between the interposer substrate and the first and second semiconductor dies. The lateral distance from the top end of the first sidewall to the top end of the second sidewall is greater than the lateral distance from the bottom end of the first sidewall to the bottom end of the second sidewall.

In an embodiment, a device includes: a processor die including circuit blocks, the circuit blocks including active devices of a first technology node; a power gating die including power semiconductor devices of a second technology node, the second technology node larger than the first technology node; and a first redistribution structure including first metallization patterns, the first metallization patterns including power supply source lines and power supply ground lines, where a first subset of the circuit blocks is electrically coupled to the power supply source lines and the power supply ground lines through the power semiconductor devices, and a second subset of the circuit blocks is permanently electrically coupled to the power supply source lines and the power supply ground lines.

In some examples, a package comprises a semiconductor die having a first surface and a second surface opposing the first surface, the semiconductor die including circuitry formed in the first surface. The package includes an acoustic waveguide in the semiconductor die, the acoustic waveguide including an array of capacitors. The array of capacitors includes a transducer portion and a diffraction grating portion. The transducer portion is configured to convert signals between electrical signals and acoustic waves, and the diffraction grating portion is configured to direct the acoustic waves toward and receive the acoustic waves from the second surface.