A method of manufacturing a bond pad structure may include depositing an aluminum-copper (AlCu) layer over a dielectric layer; and depositing an aluminum-chromium (AlCr) layer directly over the AlCu layer.

A component such as an interposer or microelectronic element can be fabricated with a set of vertically extending interconnects of wire bond structure. Such method may include forming a structure having wire bonds extending in an axial direction within one of more openings in an element and each wire bond spaced at least partially apart from a wall of the opening within which it extends, the element consisting essentially of a material having a coefficient of thermal expansion (CTE) of less than 10 parts per million per degree Celsius (ppm/ C.). First contacts can then be provided at a first surface of the component and second contacts provided at a second surface of the component facing in a direction opposite from the first surface, the first contacts electrically coupled with the second contacts through the wire bonds.

A method of forming an aluminum oxide layer is provided. The method includes providing a metal surface including at least one metal of a group of metals, the group of metals consisting of copper, aluminum, palladium, nickel, silver, and alloys thereof. The method further includes depositing an aluminum oxide layer on the metal surface by atomic layer deposition, wherein a maximum processing temperature during the depositing is 280 C., such that the aluminum oxide layer is formed with a surface having a liquid solder contact angle of less than 40.

A semiconductor device is provided. The semiconductor device includes an electrode pad provided above a semiconductor substrate; and a wire bonded on the electrode pad and including copper. The electrode pad includes an electrode layer including aluminum and a support layer harder than the wire and the electrode layer. The wire is in contact with the electrode layer and the support layer.

A pillar structure is disposed on a substrate. The pillar structure includes a pad, a metal wire bump, a metal wire, and a metal plating layer. The pad is disposed on the substrate. The metal wire bump is disposed on the pad. The metal wire is connected to the metal wire bump. The metal wire extends in a first extension direction, the substrate extends in a second extension direction, and the first extension direction is perpendicular to the second extension direction. The metal plating layer covers the pad and completely encapsulates the metal wire bump and the metal wire.

Various embodiments provide a semiconductor device, including a final metal layer having a top side and at least one sidewall; and a passivation layer disposed over at least part of at least one of the top side and the at least one sidewall of the final metal layer; wherein the passivation layer has a substantially uniform thickness.

The invention provides a semiconductor structure. The semiconductor structure includes a substrate. A first passivation layer is disposed on the substrate. A conductive pad is disposed on the first passivation layer. A second passivation layer is disposed on the first passivation layer. A conductive structure is disposed on the conductive pad, and a passive device is also disposed on the conductive pad, wherein the passive device has a first portion located above the second passivation layer and a second portion passing through the second passivation layer. A solderability preservative film covers the first portion of the passive device, and an under bump metallurgy (UBM) layer covers the second portion of the passive device and a portion of the conductive structure.

According to one embodiment, a semiconductor device includes a semiconductor element having a substrate with at least two bending portions formed on a first side surface thereof. The two bending portions are displaced from each other in a first direction that is perpendicular to the first side surface of the substrate and parallel to a front surface of the substrate and in a second direction parallel to the front surface of the substrate and perpendicular to a top surface of the substrate. A rearmost portion of the first side surface is substantially perpendicular to the front surface.

The present disclosure relates to techniques for manufacturing a semiconductor package assembly, with a semiconductor die structure mounted to a lead frame having terminals and encapsulated with a molding resin, as well as a semiconductor package assembly obtained with these techniques. An object of the present disclosure is to provide a manufacturing technique that results in a leaded/leadless power/MCD package or power module manufactured with less complex and less time-consuming process steps, and the connecting elements being implemented are of a straightforward design with reduced R.sub.DS(on) characteristic.

In an embodiment a carrier includes a shaped body, a lead frame, a first electrode and a second electrode, wherein the first electrode includes a first subregion of the lead frame, a second subregion of the lead frame, and an electrical connection connecting the first subregion to the second subregion, wherein the first subregion is laterally spaced from the second subregion by an intermediate region, wherein the lead frame has at least one subsection, which is located at least in places in the intermediate region and thus in a lateral direction between the first subregion and the second subregion of the first electrode, wherein the intermediate region is at least partially filled by the shaped body or directly adjoins the shaped body, the electrical connection being embedded in the shaped body, and wherein the subsection of the lead frame is neither a subregion of the first electrode nor a subregion of the second electrode.