A package comprising a first integrated device comprising a first plurality of under bump metallization interconnects; a second integrated device comprising a second plurality of under bump metallization interconnects; a bridge coupled to the first integrated device and the second integrated device; an encapsulation layer at least partially encapsulating the first integrated device, the second integrated device, and the bridge; a metallization portion located over the first integrated device, the second integrated device, the bridge and the encapsulation layer, where the metallization portion includes at least one dielectric layer and a plurality of metallization interconnects; a first plurality of pillar interconnects coupled to the first plurality of under bump metallization interconnects, the first plurality of interconnects located in the encapsulation layer; and a second plurality of pillar interconnects coupled to the second plurality of under bump metallization interconnects, the second plurality of pillar interconnects located in the encapsulation layer.

A semiconductor device and method is disclosed. Devices shown include a die coupled to an integrated routing layer, wherein the integrated routing layer includes a first width that is wider than the die. Devices shown further included a molded routing layer coupled to the integrated routing layer.

A semiconductor package including at least one functional die; at least one dummy die free of active circuit, wherein the dummy die comprises at least one metal-insulator-metal (MIM) capacitor; and a redistribution layer (RDL) structure interconnecting the MIM capacitor to the at least one functional die.

Disclosed is an apparatus including a molded multi-die high density interconnect including: a bridge die having a first plurality of interconnects and second plurality of interconnects. The apparatus also includes a first die having a first plurality of contacts and a second plurality of contacts, where the second plurality of contacts is coupled to the first plurality of interconnects of the bridge die. The apparatus also includes a second die having a first plurality of contacts and a second plurality of contacts, where the second plurality of contacts is coupled to the second plurality of interconnects of the bridge die. The coupled second plurality of contacts and interconnects have a smaller height than the first plurality of contacts of the first die and second die.

A semiconductor package includes an encapsulated semiconductor device and a redistribution structure. The encapsulated semiconductor device includes a semiconductor device encapsulated by an encapsulating material. The redistribution structure overlays the encapsulated semiconductor device and includes a plurality of vias and a redistribution line. The plurality of vias are located on different layers of the redistribution structure respectively and connected to one another through a plurality of conductive lines, wherein, from a top view, an angle greater than zero is included between adjacent two of the plurality of conductive lines. The redistribution line is disposed under the plurality of conductive lines and connects corresponding one of the plurality of vias and electrically connected to the semiconductor device through the plurality of vias.

A semiconductor package structure includes a semiconductor die and at least one pillar structure. The semiconductor die has an upper surface and includes at least one conductive pad disposed adjacent to the upper surface. The pillar structure is electrically connected to the conductive pad of the semiconductor die, and defines a recess portion recessed from a side surface of the pillar structure. A conductivity of the pillar structure is greater than a conductivity of the conductive pad.

A semiconductor device with redistribution layers on partial encapsulation is disclosed and may include providing a carrier with a non-photosensitive protection layer, forming a pattern in the non-photosensitive protection layer, providing a semiconductor die with a contact pad on a first surface, and bonding the semiconductor die to the non-photosensitive protection layer such that the contact pad aligns with the pattern formed in the non-photosensitive protection layer. A second surface opposite to the first surface of the semiconductor die, side surfaces between the first and second surfaces of the semiconductor die, and a portion of a first surface of the non-photosensitive protection layer may be encapsulated with an encapsulant. The carrier may be removed leaving the non-photosensitive protection layer bonded to the semiconductor die. A redistribution layer may be formed on the contact pad and a second surface of the non-photosensitive protection layer opposite to the first surface.

A method includes forming a release film over a carrier, attaching a device over the release film through a die-attach film, encapsulating the device in an encapsulating material, performing a planarization on the encapsulating material to expose the device, detaching the device and the encapsulating material from the carrier, etching the die-attach film to expose a back surface of the device, and applying a thermal conductive material on the back surface of the device.

A semiconductor package and a manufacturing method thereof are provided. The semiconductor package includes a first semiconductor die, a second semiconductor die, a molding compound, a heat dissipation module and an adhesive material. The first and second semiconductor dies are different types of dies and are disposed side by side. The molding compound encloses the first and second semiconductor dies. The heat dissipation module is located directly on and in contact with the back sides of the first and second semiconductor dies. The adhesive material is filled and contacted between the heat dissipation module and the molding compound. The semiconductor package has a central region and a peripheral region surrounding the central region. The first and second semiconductor dies are located within the central region. A sidewall of the heat dissipation module, a sidewall of the adhesive material and a sidewall of the molding compound are substantially coplanar.

The present description relates to a method of manufacturing an interconnection structure of an integrated circuit intended to be encapsulated in an encapsulation resin in contact with a first surface of a protection layer. The protection layer is resting on a first surface of the interconnection structure. The interconnection structure comprising copper interconnection elements extending at least partly through an insulating layer and flush with the first surface of said interconnection structure. The manufacturing method includes a step of structuring of the protection layer or a step of forming of the protection layer with a structuring. The structuring step or the forming step is adapted to structuring the first surface of the protection layer in the form of an alternation of ridges and troughs.