A semiconductor structure includes a first passivation layer disposed over a metal line, a copper-containing RDL disposed over the first passivation layer, where the copper-containing RDL is electrically coupled to the metal line and where a portion of the copper-containing RDL in contact with a top surface of the first passivation layer forms an acute angle, and a second passivation layer disposed over the copper-containing RDL, where an interface between the second passivation layer and a top surface of the copper-containing RDL is curved. The semiconductor structure may further include a polymeric layer disposed over the second passivation layer, where a portion of the polymeric layer extends to contact the copper-containing RDL, a bump electrically coupled to the copper-containing RDL, and a solder layer disposed over the bump.

An electronic component including a pad electrode provided on a wiring electrode and a Au bump provided on the pad electrode, wherein the uppermost layer of the wiring electrode is a first Ti layer, the uppermost layer of the pad electrode is a Au layer, and the thickness of the first Ti layer in at least a portion on which the Au bump is superposed in plan view is greater than the thickness of at least a portion of the first Ti layer in a portion on which the Au bump is not superposed in plan view.

An electronic component including a pad electrode provided on a wiring electrode and a Au bump provided on the pad electrode, wherein the uppermost layer of the wiring electrode is a first Ti layer, the uppermost layer of the pad electrode is a Au layer, and the thickness of the first Ti layer in at least a portion on which the Au bump is superposed in plan view is greater than the thickness of at least a portion of the first Ti layer in a portion on which the Au bump is not superposed in plan view.

The present disclosure provides an integrated circuit (IC) structure. The IC structure includes a semiconductor substrate; an interconnection structure formed on the semiconductor substrate; and a redistribution layer (RDL) metallic feature formed on the interconnection structure. The RDL metallic feature further includes a barrier layer disposed on the interconnection structure; a diffusion layer disposed on the barrier layer, wherein the diffusion layer includes metal and oxygen; and a metallic layer disposed on the diffusion 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.

Semiconductor packages including active die stacks, and methods of fabricating such semiconductor packages, are described. In an example, a semiconductor package includes an active die having a top surface covered by a molding compound, and a bonding pad attached to only one interconnect wire. A method of fabricating the semiconductor package includes bridging a pair of dies stacks by the interconnect wire, and dividing the interconnect wire to form separate wire segments attached to respective die stacks.

A multi-pin wafer level chip scale package is achieved. One or more solder pillars and one or more solder blocks are formed on a silicon wafer wherein the one or more solder pillars and the one or more solder blocks all have a top surface in a same horizontal plane. A pillar metal layer underlies the one or more solder pillars and electrically contacts the one or more solder pillars with the silicon wafer through an opening in a polymer layer over a passivation layer. A block metal layer underlies the one or more solder blocks and electrically contacts the one or more solder pillars with the silicon wafer through a plurality of via openings through the polymer layer over the passivation layer wherein the block metal layer is thicker than the pillar metal layer.

An electronic system supports superior coupling by implementing a communication mechanism that provides at least for horizontal communication for example, on the basis of wired and/or wireless communication channels, in the system. Hence, by enhancing vertical and horizontal communication capabilities in the electronic system, a reduced overall size may be achieved, while nevertheless reducing complexity in printed circuit boards coupled to the electronic system. In this manner, overall manufacturing costs and reliability of complex electronic systems may be enhanced.

A method includes forming a first dielectric layer over a conductive pad, forming a second dielectric layer over the first dielectric layer, and etching the second dielectric layer to form a first opening, with a top surface of the first dielectric layer exposed to the first opening. A template layer is formed to fill the first opening. A second opening is then formed in the template layer and the first dielectric layer, with a top surface of the conductive pad exposed to the second opening. A conductive pillar is formed in the second opening.

A multi-pin wafer level chip scale package is achieved. One or more solder pillars and one or more solder blocks are formed on a silicon wafer wherein the one or more solder pillars and the one or more solder blocks all have a top surface in a same horizontal plane. A pillar metal layer underlies the one or more solder pillars and electrically contacts the one or more solder pillars with the silicon wafer through an opening in a polymer layer over a passivation layer. A block metal layer underlies the one or more solder blocks and electrically contacts the one or more solder pillars with the silicon wafer through a plurality of via openings through the polymer layer over the passivation layer wherein the block metal layer is thicker than the pillar metal layer.