This invention provides a high-yielding and high-density/ultra-fine pitch package for ultra-large-scale ICs and advanced ICs. The package includes a substrate and a semiconductor chip. The substrate has a passivation layer covering a first surface of the substrate, wherein a plurality of holes are formed in the passivation layer, and a plurality of solder balls respectively accommodated in the plurality of holes. The semiconductor chip has a first plurality of pads, wherein a plurality of copper pillar micro-bumps respectively extend from the first plurality of pads, and the plurality of copper pillar micro-bumps are respectively connected to the plurality of solder balls.

A semiconductor module includes a first power semiconductor device, a conductive wire, and a resin film. The conductive wire is joined to a surface of a first front electrode of the first power semiconductor device. The resin film is formed to be continuous on at least one of an end portion or an end portion of a first joint between the first front electrode and the conductive wire in a longitudinal direction of the conductive wire, a surface of the first front electrode, and a surface of the conductive wire. The resin film has an elastic elongation rate of 4.5% to 10.0%.

This application discloses a chip package assembly, an electronic device, and a preparation method of a chip package assembly. The chip package assembly includes a package substrate, a chip, and a heat dissipation part. The package substrate includes an upper conductive layer, a lower conductive layer, and a conductive part connected between the upper conductive layer and the lower conductive layer. The chip includes a front electrode and a back electrode that are disposed opposite each other, the chip is embedded in the package substrate, the conductive part surrounds the chip, the front electrode is connected to the lower conductive layer, and the back electrode is connected to the upper conductive layer. The heat dissipation part is connected to a surface of the upper conductive layer that is away from the chip. The upper conductive layer, the lower conductive layer, and the conductive part each conduct heat.

A semiconductor device includes a multi-layer board which a wiring pattern and a grounding pattern are formed. A plurality of semiconductor elements are mounted on the multi-layer board. An insulating sealing member is provided on the multi-layer board and is covering the plurality of semiconductor elements. A metal film is provided on the insulating sealing member. An in-groove metal is provided in contact with a plurality of grooves extending from a side-surface upper end of the insulating sealing member to a side-surface lower end of the multi-layer board. An in-hole metal is provided in an inner wall of a hole penetrating through the insulating sealing member and is extending to the multi-layer board. The in-hole metal is contacting with the metal film and the grounding pattern.

An electronic device includes: (i) a first chiplet including a first seal ring, which is disposed in metal layers embedded between a first surface of the first chiplet, and a first substrate of the first chiplet, (ii) a second chiplet including a second seal ring, which is disposed in metal layers embedded between a second surface of the second chiplet, and a second substrate of the second chiplet, and (iii) a third seal ring, which surrounds the first and second chiplets and is disposed in a dielectric substrate extrinsic to the metal layers and overlaying the first and second surfaces of the first and second chiplets.

Integrated circuit (IC) structures include transistor devices with interconnect structures, e.g., a source contact, drain contact, and/or gate contact. The interconnect structures have rounded top surfaces. Contouring the top surfaces of transistor contacts may decrease the likelihood of electrical shorting and may permit a larger volume of insulating dielectric between adjacent contacts.

A method includes forming an interconnect component including a plurality of dielectric layers that include an organic dielectric material, and a plurality of redistribution lines extending into the plurality of dielectric layers. The method further includes bonding a first package component and a second package component to the interconnect component, encapsulating the first package component and the second package component in an encapsulant, and precutting the interconnect component using a blade to form a trench. The trench penetrates through the interconnect component, and partially extends into the encapsulant. The method further includes performing a singulation process to separate the first package component and the second package component into a first package and a second package, respectively.

A semiconductor package includes a redistribution structure, a plurality of semiconductor devices, and a plurality of heat dissipation films. The plurality of semiconductor devices mounted on the redistribution structure. The plurality of heat dissipation films are respectively disposed on and jointly covering upper surfaces of the plurality of semiconductor devices. A plurality of trenches are respectively extended between each two of the plurality of heat dissipations and extended between each two of the plurality of semiconductor devices.

A semiconductor package includes a package substrate, an interposer on the package substrate, a lower molding layer on the package substrate and surrounding the interposer, a first semiconductor chip on the lower molding layer, a chip connection terminal between the first semiconductor chip and the package substrate and surrounded by the lower molding layer, a second semiconductor chip on the lower molding layer and at an outer side of the first semiconductor chip, interposer connection terminals that connect the first and second semiconductor chips to the interposer, and an upper molding layer on the lower molding layer and surrounding the first and second semiconductor chips.

The present disclosure provides a package device and a manufacturing method thereof. The package device includes an electronic device, a conductive pad having a first bottom surface, and a redistribution layer disposed between the conductive pad and the electronic device. The redistribution layer has a second bottom surface, and the conductive pad is electrically connected to the electronic device through the redistribution layer. The first bottom surface is closer to the electronic device than the second bottom in a normal direction of the electronic device.