A method for manufacturing a semiconductor device is provided. The method for manufacturing a semiconductor device which uses an apparatus for manufacturing the semiconductor device including: a chamber, a support structure provided inside the chamber, and configured to support a bonding structure that comprises a first substrate structure, a second substrate structure, and a bonding metal layer provided between the first substrate structure and the second substrate structure, and a laser device which is provided above the chamber, the semiconductor device manufacturing method comprising: irradiating a laser beam to the bonding structure using the laser device.

A semiconductor structure includes a multi-level interconnect structure, a passivation layer, a barrier layer, and a pad layer. The passivation layer is above the multi-level interconnect structure. The barrier layer lines an inner sidewall of the passivation layer, a top surface of the passivation layer and a top surface of a conductive line of the multi-level interconnect structure. The barrier layer includes a first layer, a second layer, a third layer, and a fourth layer. The first layer is in a nano-crystalline phase. The second layer is above the first layer and in an amorphous phase. The third layer is above the second layer and in a polycrystalline phase. The fourth layer is above the third layer and in a nano-crystalline phase. The pad layer is above the barrier layer.

A method of manufacturing a mounting substrate according to an embodiment of the present technology includes the following three steps:

(1) a step of forming a plurality of electrodes on a semiconductor layer, and thereafter forming one of solder bumps at a position facing each of the electrodes;

(2) a step of covering the solder bumps with a coating layer, and thereafter selectively etching the semiconductor layer with use of the coating layer as a mask to separate the semiconductor layer into a plurality of elements; and

(3) a step of removing the coating layer, and thereafter mounting the elements on a wiring substrate to direct the solder bumps toward the wiring substrate, thereby forming the mounting substrate.

A semiconductor wafer has a plurality of semiconductor die with contact pads for electrical interconnect. An insulating layer is formed over the semiconductor wafer. A bump structure is formed over the contact pads. The bump structure has a buffer layer formed over the insulating layer and contact pad. A portion of the buffer layer is removed to expose the contact pad and an outer portion of the insulating layer. A UBM layer is formed over the buffer layer and contact pad. The UBM layer follows a contour of the buffer layer and contact pad. A ring-shaped conductive pillar is formed over the UBM layer using a patterned photoresist layer filled with electrically conductive material. A conductive barrier layer is formed over the ring-shaped conductive pillar. A bump is formed over the conductive barrier layer. The buffer layer reduces thermal and mechanical stress on the bump and contact pad.

A silicon carbide semiconductor device includes a first semiconductor layer of a first conductivity type provided on a front surface of a semiconductor substrate of the first conductivity type; a second semiconductor layer of a second conductivity type; a first semiconductor region of the first conductivity type; and a gate electrode having a striped-shape and provided on a gate insulating film. The silicon carbide semiconductor device further includes a first electrode provided on a surface of the second semiconductor layer and the first semiconductor region; a step film provided on the first electrode; a plating film provided on the first electrode and the step film; and a solder on the plating film. The step film is provided on the first electrode on which the solder and the plating film are provided, the step film being provided so as to be embedded in grooves formed on the first electrode.

Electrical connections for chip scale packaging are disclosed. In one embodiment, a semiconductor device includes a post-passivation layer disposed over a substrate, the substrate having a first direction of coefficient of thermal expansion mismatch. The semiconductor device includes a first opening through the post-passivation layer, the first opening comprising a plurality of elongated apertures. A longest of the plurality of elongated apertures comprises a first dimension, wherein the first dimension is aligned substantially perpendicular to the first direction of coefficient of thermal expansion mismatch.

A silicon integrated circuit. In some embodiments, the silicon integrated circuit includes a first conductive trace, on a top surface of the silicon integrated circuit, a dielectric layer, on the first conductive trace, and a second conductive trace, on the dielectric layer, connected to the first conductive trace through a first via.

In one embodiment, a semiconductor device includes one or more metallizations, such as, e.g., Cu-RDL metallizations, provided on a passivation layer over a dielectric layer. A via is provided through the passivation layer and the dielectric layer in the vicinity of the corners of the metallization. The via may be a “dummy” via without electrical connections to an active device and may be provided at a distance between approximately 1 micron (10.sup.−6 m.) and approximately 10 micron (10.sup.−5 m.) from each one of said converging sides landing on an underlying metal layer.

An interconnection structure and method disclosed for providing an interconnection structure that includes conductive features having reduced topographic variations. The interconnection structure includes a contact pad disposed over a substrate. The contact pad includes a first layer of a first conductive material and a second layer of a second conductive material over the first layer. The first conductive material and the second conductive material are made of substantially the same material and have a first average grain size and a second average grain size that is smaller than the first average grain size. The interconnection structure also includes a passivation layer covering the substrate and the contact pad, and the passivation layer has an opening exposing the contact pad.

A semiconductor device includes a chip carrier and a semiconductor die with a semiconductor portion and a conductive structure. A soldered layer mechanically and electrically connects the chip carrier and the conductive structure at a soldering side of the semiconductor die. At the soldering side an outermost surface portion along an edge of the semiconductor die has a greater distance to the chip carrier than a central surface portion. The conductive structure covers the central surface portion and at least a section of an intermediate surface portion tilted to the central surface portion. Solder material is effectively prevented from coating such semiconductor surfaces that are prone to damages and solder-induced contamination is significantly reduced.