A packaging semiconductor device, such as a fan-out Wafer-Level Packaging (FOWLP) device, is fabricated by providing a semiconductor device (20) having conductive patterns (22) disposed on a first surface and then forming, on the conductive patterns, photoresist islands (24) having a first predetermined shape defined by a first critical width dimension and a minimum height dimension so that a subsequently-formed dielectric polymer layer (26) surrounds but does not cover each photoresist island (24), thereby allowing each photoresist island to be selectively removed from the one or more conductive patterns to form one or more via openings (28) in the dielectric polymer layer such that each via opening has a second predetermined shape which matches at least part of the first predetermined shape of the photoresist islands.

A semiconductor device and a method for manufacturing the same are provided. The semiconductor device includes a semiconductor substrate, a conductive structure and at least one via structure. The conductive structure is disposed on an upper surface of the semiconductor substrate. The at least one via structure is disposed in the semiconductor substrate. A portion of the at least one via structure extends beyond the conductive structure.

A device, such as a computer system, includes an interconnection device die and at least two additional device dice. The additional device dies can be system on integrated chip (SOIC) dies laying face to face (F2F) on the interconnection device die. The interconnection device die includes electrical connectors on one surface, enabling connection to and/or among the additional device dice. The interconnection device die includes at least one redistribution circuit structure, which may be an integrated fan out (InFO) structure, and at least one through-silicon via (TSV). The TSV enables connection between a signal line, power line or ground line, from an opposite surface of the interconnection device die to the redistribution circuit structure and/or electrical connectors. At least one of the additional dice can be a three-dimensional integrated circuit (3DIC) die with face to back (F2B) stacking.

An embodiment is a method including forming a first interconnect structure over a first substrate, the first interconnect structure comprising dielectric layers and metallization patterns therein, patterning the first interconnect structure to form a first opening, coating the first opening with a barrier layer, etching a second opening through the barrier layer and the exposed portion of the first substrate, depositing a liner in the first opening and the second opening, filling the first opening and the second opening with a conductive material, and thinning the first substrate to expose a portion of the conductive material in the second opening, the conductive material extending through the first interconnect structure and the first substrate forming a through substrate via.

The present disclosure relates to an electronic chip comprising a semiconductor substrate carrying at least one metal contact extending, within the thickness of the substrate, along at least one flank of the chip.

A package structure and method of forming the same are provided. The package structure includes a die, a via, an encapsulant, an adhesion promoter layer, and a polymer layer. The via is laterally aside the die. The encapsulant laterally encapsulates the die and the via. The adhesion promoter layer is sandwiched between the via and the encapsulant. The encapsulant comprises a portion aside the via and under the adhesion promoter layer, and the portion of the encapsulant is sandwiched between the adhesion promoter layer and the polymer layer.

A semiconductor package includes a semiconductor substrate, a conductive pad on the semiconductor substrate, a redistribution line conductor, a coating insulator, and an aluminum oxide layer. The redistribution line conductor is electrically connected to the conductive pad. The coating insulator covers the redistribution line conductor and partially exposes the redistribution line conductor. The aluminum oxide layer is provided below the coating insulator and extends along a top surface of the redistribution line conductor, and the aluminum oxide layer is in contact with the redistribution line conductor.

A semiconductor device includes a chip body; a passivation layer on the chip body; a lower dielectric layer on the passivation layer; a first re-distribution pad on the lower dielectric layer; an upper dielectric layer on the lower dielectric layer, the upper dielectric layer having a groove that exposes an upper surface of the first re-distribution pad; and a second re-distribution pad on the upper dielectric layer. An upper surface of the second re-distribution pad is positioned at a higher level than the upper surface of the first re-distribution pad.

Systems, devices and methods of manufacturing a system on silicon wafer (SoSW) device and package are described herein. A plurality of functional dies is formed in a silicon wafer. Different sets of masks are used to form different types of the functional dies in the silicon wafer. A first redistribution structure is formed over the silicon wafer and provides local interconnects between adjacent dies of the same type and/or of different types. A second redistribution structure may be formed over the first redistribution layer and provides semi-global and/or global interconnects between non-adjacent dies of the same type and/or of different types. An optional backside redistribution structure may be formed over a second side of the silicon wafer opposite the first redistribution layer. The optional backside redistribution structure may provide backside interconnects between functional dies of different types.

A method includes bonding a first and a second device die to a third device die, forming a plurality of gap-filling layers extending between the first and the second device dies, and performing a first etching process to etch a first dielectric layer in the plurality of gap-filling layers to form an opening. A first etch stop layer in the plurality of gap-filling layers is used to stop the first etching process. The opening is then extended through the first etch stop layer. A second etching process is performed to extend the opening through a second dielectric layer underlying the first etch stop layer. The second etching process stops on a second etch stop layer in the plurality of gap-filling layers. The method further includes extending the opening through the second etch stop layer, and filling the opening with a conductive material to form a through-via.