A semiconductor package includes: a first redistribution structure; a first chip disposed on the first redistribution structure; a molding member at least partially surrounding the first chip and disposed on the first redistribution structure; a plurality of conductive pillars penetrating the molding member in a vertical direction; a support structure disposed between adjacent conductive pillars of the plurality of conductive pillars and disposed on the first redistribution structure; a second redistribution structure disposed on the molding member, the plurality of conductive pillars, and the support structure; a second chip disposed on the second redistribution structure and overlapping the plurality of conductive pillars; and a heat dissipation chip overlapping the first chip in the vertical direction.

A chip packaging structure includes a first substrate, an image sensor chip, a first molding layer, conductive pillars, metal wires, an adhesive layer, a second substrate, and a second molding layer. The first substrate includes traces between its upper surface and lower surface. The image sensor chip is fixed on the first substrate. The first molding layer is disposed on the first substrate and covers a side surface of the image sensor chip. The conductive pillars are disposed in the first molding layer, and the metal wires electrically connects the image sensor chip to the conductive pillars. The adhesive layer is disposed on the first molding layer and surrounds the image sensor chip. The second substrate is fixed on the adhesive layer. The second molding layer is disposed on the first molding layer and covers a side surface of the adhesive layer and a side surface of the second substrate.

A package structure is provided. The package structure includes a first electronic component and a second electronic component, and a data access structure. The data access structure is disposed partially in a gap between the first electronic component and the second electronic component. The data access structure includes a logic portion and a storage portion. One of the logic portion and the storage portion is in the gap, and the other one of the logic portion and the storage portion is outside of the gap.

The present invention relates to a semiconductor device including: a semiconductor substrate having: an active region through which a main current flows; and a termination region around the active region; a polyimide film disposed in the active region and the termination region; and a passivation film disposed as a film underlying the polyimide film, wherein the termination region includes, in order from a side of the active region, a breakdown voltage holding region and an outermost peripheral region, the polyimide film is disposed except for a dicing remaining portion of the outermost peripheral region, and the passivation film is disposed, as the underlying film, at least in a region where the polyimide film is disposed.

A semiconductor structure, including a first semiconductor structure, a second semiconductor structure, and a filling material is disclosed. The first semiconductor structure has a first surface and a second surface opposite to the first surface. The first semiconductor structure has a body portion and a semiconductor brim portion protruded from the body portion. The semiconductor brim portion is closer to the second surface. The second semiconductor structure is in contact with the first surface of the first semiconductor structure and bonded with the first semiconductor structure. The filling material surrounds the first semiconductor structure and is filled between the semiconductor brim portion and the second semiconductor structure. The filling material wraps around and covers the semiconductor brim portion, and a sidewall of the filling material is aligned with a sidewall of the second semiconductor structure.

An electronic device that includes a substrate and a die disposed on the substrate, the die having an active surface. Wire bonds are attached from the active surface of the die to the substrate. A radiation barrier is attached to the substrate and disposed over the die. The radiation barrier is configured to mitigate electromagnetic radiation exposure to the die. A mold compound is formed over the die, the wire bonds, and the radiation barrier.

A method for fabricating a package structure is provided. The method includes premixing cellulose nanofibrils (CNFs) and a graphene material in a solvent to form a solution; removing the solvent from the solution to form a composite filler; mixing a prepolymeric material with the composite filler to form a composite material; and performing a molding process using the composite material.

The present disclosure provides a memory system packaging structure and fabrication methods. The memory system packaging structure includes memory modules, a memory controller, a redistribution layer electrically connected to the memory controller, a plastic encapsulation layer encapsulating the memory modules and the memory controller, and one or more connecting pillars extending in the vertical direction and configured for providing electric power to the memory modules. Each memory module includes memory dies stacked in a vertical direction. Each connecting pillar includes a first portion being in physical contact with one of the memory dies and a second portion being in physical contact with the redistribution layer.

A device die including a first semiconductor die, a second semiconductor die, an anti-arcing layer and a first insulating encapsulant is provided. The second semiconductor die is stacked over and electrically connected to the first semiconductor die. The anti-arcing layer is in contact with the second semiconductor die. The first insulating encapsulant is disposed over the first semiconductor die and laterally encapsulates the second semiconductor die. Furthermore, methods for fabricating device dies are provided.

A chip package and a method of manufacturing the same are provided. The chip package includes at least one insulating protective layer disposed on a periphery of a surface of a seed layer correspondingly. A plurality of insulating protective layers is arranged at the seed layer of a plurality of rectangular chips of a wafer and located corresponding to a plurality of dicing streets. Thereby cutting tools only cut the insulating protective layer, without cutting a thick metal layer during cutting process. The insulating protective layer is formed on a periphery of the thick metal layer of the chip package after the cutting process.