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.

A semiconductor device includes a substrate; a semiconductor layer; a first protective film; a first adhesive layer disposed on the first protective film; an electrode pad disposed on the first protective film; a second protective film disposed to cover and be in contact with the electrode pad and the first adhesive layer; and a first opening formed in part of the second protective film such that the upper surface of the electrode pad is exposed, wherein in a plan view, the first adhesive layer includes a first projection projecting from the electrode pad radially in a direction of the periphery of the electrode pad and continuously surrounding the periphery of the electrode pad; and the second protective film is continuously to cover and contact part of the upper and side surfaces of the electrode pad, the upper and side surfaces of first projection, and the first protective film.

To provide a semiconductor device having improved reliability. A method of manufacturing the semiconductor device includes connecting a wire comprised of copper with a conductive layer formed on the pad electrode of a semiconductor chip, heat treating the semiconductor chip, and then sealing the semiconductor chip and the wire with a resin.

An improvement is achieved in the reliability of a semiconductor device. A first semiconductor chip includes a semiconductor substrate, a wiring structure formed over the semiconductor substrate, an insulating film formed over the wiring structure, and a first insulating film formed over the insulating film. A second semiconductor chip includes a semiconductor substrate, a wiring structure formed over the semiconductor substrate, an insulating film formed over the wiring structure, and a second insulating film formed over the insulating film. The first insulating film forms an uppermost layer of the first semiconductor chip. The second insulating film forms an uppermost layer of the second semiconductor chip. Each of the first and second insulating films is made of a photosensitive resin film having an adhesive property. The first and second semiconductor chips are stacked such that the first insulating film of the first semiconductor chip and the second insulating film of the second semiconductor chip are in contact with each other.

An integrated circuit includes a semiconductor substrate. The integrated circuit also includes a trench in the semiconductor substrate, the trench including a layer of a nanoparticle material. The integrated circuit further includes an interconnect region above the trench.

An integrated circuit package can contain a semiconductor die and provide electrical connections between the semiconductor die and additional electronic components. The integrated circuit package can reduce stress placed on the semiconductor die due to movement of the integrated circuit package due to, for example, temperature changes and/or moisture levels. The integrated circuit package can at least partially mechanically isolate the semiconductor die from the integrated circuit package.

There is provided a palladium-coated copper bonding wire that does not cause a shrinkage cavity during first bonding, has high bonding reliability, and is capable of maintaining excellent bonding reliability for a long period of time even in high-temperature and high-humidity environments. A palladium-coated copper bonding wire in which a concentration of palladium is 1.0 mass % or more and 4.0 mass % or less relative to the total of copper, palladium, and a sulfur group element, a total concentration of the sulfur group element is 50 mass ppm or less, and a concentration of sulfur is 5 mass ppm or more and 12 mass ppm or less, a concentration of selenium is 5 mass ppm or more and 20 mass ppm or less, or a concentration of tellurium is 15 mass ppm or more and 50 mass ppm or less, and the palladium-coated copper bonding wire including a palladium-concentrated region with the average concentration of palladium of 6.5 atom % or more and 30.0 atom % or less relative to the total of copper and palladium within a range from a surface of a tip portion of a free air ball formed at a tip of the wire to 5.0 nm or more and 100.0 nm or less.

An electronic device comprises a multilevel metallization structure over a semiconductor layer and including a first region, a second region, a pre-metal level on the semiconductor layer, and N metallization structure levels over the pre-metal level, N being greater than 3. The electronic device also comprises an isolation component in the first region, the isolation component including a first terminal and a second terminal in different respective metallization structure levels, as well as a conductive shield between the first region and the second region in the multilevel metallization structure, the conductive shield including interconnected metal lines and trench vias in the respective metallization structure levels that at least partially encircle the first region.

To protect the insulating film so that crack is not produced in the insulating film even when stress is applied to the semiconductor device. A manufacturing method of a semiconductor device is provided, including: forming an insulating film above a semiconductor substrate; forming, in the insulating film, one or more openings that expose the semiconductor substrate; forming a tungsten portion deposited in the openings and above the insulating film; thinning the tungsten portion on condition that the tungsten portion remains in at least part of a region above the insulating film; and forming an upper electrode above the tungsten portion.

A semiconductor device includes a MOSFET including a PN junction diode. A unipolar device is connected in parallel to the MOSFET and has two terminals. A first wire connects the PN junction diode to one of the two terminals of the unipolar device. A second wire connects the one of the two terminals of the unipolar device to an output line, so that the output line is connected to the MOSFET and the unipolar device via the first wire and the second wire. In one embodiment the connection of the first wire to the diode is with its anode, and in another the connection is with the cathode.