A wire bond system. Implementations may include: a bond wire including copper (Cu), a bond pad including aluminum (Al) and a sacrificial anode electrically coupled with the bond pad, where the sacrificial anode includes one or more elements having a standard electrode potential below a standard electrode potential of Al.

In various embodiments, a chip package is provided. The chip package may include a chip, a metal contact structure including a non-noble metal and electrically contacting the chip, a packaging material, and a protective layer including or essentially consisting of a portion formed at an interface between a portion of the metal contact structure and the packaging material, wherein the protective layer may include a noble metal, wherein the portion of the protective layer may include a plurality of regions free from the noble metal, and wherein the regions free from the noble metal may provide an interface between the packaging material and the non-noble metal of the metal contact structure.

There is provided a bonding wire for a semiconductor device including a coating layer having Pd as a main component on a surface of a Cu alloy core material and a skin alloy layer containing Au and Pd on a surface of the coating layer, the bonding wire further improving 2nd bondability on a Pd-plated lead frame and achieving excellent ball bondability even in a high-humidity heating condition. The bonding wire for a semiconductor device including the coating layer having Pd as a main component on the surface of the Cu alloy core material and the skin alloy layer containing Au and Pd on the surface of the coating layer has a Cu concentration of 1 to 10 at % at an outermost surface thereof and has the core material containing either or both of Pd and Pt in a total amount of 0.1 to 3.0% by mass, thereby achieving improvement in the 2nd bondability and excellent ball bondability in the high-humidity heating condition. Furthermore, a maximum concentration of Au in the skin alloy layer is preferably 15 at % to 75 at %.

A semiconductor device including a first material layer adjacent to a second material layer, a first via passing through the first material layer and extending into the second material layer, and a second via extending into the first material layer, where along a common cross section parallel to an interface between the two material layers, the first via has a cross section larger than that of the second via.

A method and structure suitable for, e.g., improving high voltage breakdown reliability of a microelectronic device such as a capacitor usable for galvanic isolation of two circuits. A first dielectric layer has a first dielectric constant located over a semiconductor substrate. A metal structure located over the first dielectric layer has a side surface. A second dielectric layer having a second different dielectric constant is located adjacent the metal structure. A dielectric structure located between the side surface of the metal structure and the second dielectric layer has the first dielectric constant.

A solid-state imaging apparatus includes an imaging section and a substrate. The imaging section has a light-receiving portion for receiving light from an object to image the object and the imaging section is disposed on the substrate. A member is provided on the substrate in the neighborhood of the light receiving portion and the member is partially or entirely coated in black.

An integrated circuit has a thermal routing structure above a top interconnect level. The top interconnect level includes interconnects connected to lower interconnect levels, and does not include bond pads, probe pads, input/output pads, or a redistribution layer to bump bond pads. The thermal routing structure extends over a portion, but not all, of a plane of the integrated circuit containing the top interconnect level. The thermal routing structure includes a layer of nanoparticles in which adjacent nanoparticles are attached to each other. The layer of nanoparticles is free of an organic binder material. The thermal routing structure has a thermal conductivity higher than the metal in the top interconnect level. The layer of nanoparticles is formed by an additive process.

Method for fabricating A packaging structure is provided. The packaging structure includes a base substrate including a solder pad body region and a trench region adjacent to and around the solder pad body region. The packaging structure includes a passivation layer on the base substrate and exposing the solder pad body region and the trench region. The packaging structure includes a main body solder pad on the solder pad body region of the base substrate, and one or more trenches on the trench region of the base substrate and between the passivation layer and the main body solder pad. The packaging structure includes a bonding conductive wire having one end connected to the main body solder pad.

According to one embodiment, an isolator includes a first electrode, a second electrode, a conductive body, and a first insulating layer. The second electrode is provided on the first electrode and separated from the first electrode. The conductive body is provided around the first and second electrodes along a first plane perpendicular to a first direction. The first direction is from the first electrode toward the second electrode. The first insulating layer is provided on the second electrode. The first insulating layer includes silicon, carbon, and nitrogen.

A method of manufacturing a semiconductor device is provided. The method includes attaching a first end of a first bond wire to a first conductive lead and a second end of the first bond wire to a first bond pad of a first semiconductor die. A conductive lead extender is affixed to the first conductive lead by way of a conductive adhesive, the lead extender overlapping the first end of the first bond wire. A first end of a second bond wire is attached to the lead extender, the first end of the second bond wire conductively connected to the first end of the first bond wire.