A semiconductor structure includes two circuit regions and two inner seal rings, each of which surrounds one of the circuit regions. Each inner seal ring has a substantially rectangular periphery with four interior corner stress relief (CSR) structures. The semiconductor structure further includes an outer seal ring surrounding the two inner seal rings. The outer seal ring has a substantially rectangular periphery without CSR structures at four interior corners of the outer seal ring. The outer seal ring includes a plurality of first fin structures located between each of the two inner seal rings and a respective short side of the outer seal ring. Each first fin structure is parallel with the respective short side of the outer seal ring. Lengths of the first fin structures gradually decrease along a direction from the inner seal rings to the respective short side of the outer seal ring.

Semiconductor device includes circuit substrate, first semiconductor die, thermal interface material, package lid. First semiconductor die is disposed on and electrically connected to circuit substrate. Thermal interface material is disposed on first semiconductor die at opposite side of first semiconductor die with respect to circuit substrate. Package lid extends over first semiconductor die and is bonded to the circuit substrate. Package lid includes roof, footing, and island. Roof extends along first direction and second direction perpendicular to first direction. Footing is disposed at peripheral edge of roof and protrudes from roof towards circuit substrate along third direction perpendicular to first direction and second direction. Island protrudes from roof towards circuit substrate and contacts thermal interface material on first semiconductor die. Island is disconnected from footing along second direction.

Integrated circuit (IC) chips and seal ring structures are provided. An IC chip according to the present disclosure includes a device region, an inner ring surrounding the device region, an outer ring surrounding the inner ring, a first corner area between an outer corner of the inner ring and an inner corner of the outer ring, and a second corner area disposed at an outer corner of the outer ring. The first corner area includes a first active region including a channel region and a source/drain region, a first gate structure over the channel region of the first active region, and a first source/drain contact over the source/drain region of the first active region. The first source/drain contact continuously extends from a first edge of the first corner area to a second edge of the first corner area.

Structures and methods for reducing thermal expansion mismatch during chip scale packaging are disclosed. In one example, a semiconductor structure is disclosed. The semiconductor structure includes a first metal layer over a substrate, a dielectric region, and a polymer region. The first metal layer comprises a first device metal structure. The dielectric region is formed over the first metal layer. The polymer region is formed over the dielectric region. The dielectric region comprises a plurality of metal layers and an inter-metal dielectric layer comprising dielectric material between each pair of two adjacent metal layers in the plurality of metal layers. Each of the plurality of metal layers comprises a dummy metal structure over the first device metal structure. The dummy metal structures in each pair of two adjacent metal layers in the plurality of metal layers shield respectively two non-overlapping portions of the first device metal structure from a top view of the semiconductor structure.

A semiconductor package includes a package substrate; semiconductor devices disposed on the package substrate; a package ring disposed on a perimeter of the package substrate surrounding the semiconductor devices; a cover including silicon bonded to the package ring and covering the semiconductor devices; and a thermal interface structure (TIS) thermally connecting the semiconductor devices to the cover.

The present disclosure relates to a wafer, a manufacturing method thereof, and a semiconductor device. The wafer manufacturing method includes: providing a wafer having a scribe lane for die cutting. A plurality of through-silicon-vias for cracking stress release and prevention is formed on one side of the scribe lane, and the through-silicon-vias are filled with a protective material. Through the technique of through-silicon vias filled with protective materials on both sides of the scribe lane, the cutting stress can prevent damage to the die area during wafer cutting. The through-silicon-vias can effectively reduce the scribe lane width, which is conducive to miniaturizing the scribe lane and improving the effective utilization of wafers.

Various embodiments of the teachings herein include a method for joining and insulating a power electronic semiconductor component with contact surfaces to a substrate. In some embodiments, the method includes: preparing the substrate with a metallization defining an installation slot having joining material, wherein the substrate comprises an organic or a ceramic wiring support; arranging an electrically insulating film and the semiconductor component on the substrate, such that the contact surfaces of the semiconductor component facing the substrate are omitted from the film and regions of the semiconductor component exposed by the contact surfaces are insulated at least in part by the film from the substrate and from the contact surfaces; and joining the semiconductor component to the substrate and electrically insulating the semiconductor component at least in part by the film in one step.

An integrated circuit device includes a semiconductor substrate having a first device region, a second device region, and a scribe line region therein. The scribe line region, which extends between the first and second device regions, includes a first edge region adjacent the first device region, a second edge region adjacent the second device region and a cutting region extending between the first and second device regions. A lower interlayer insulating layer is provided on the first and second device regions and on the scribe line region. A first multi-level guard ring is provided, which at least partially surrounds the first device region, when viewed from a plan perspective. An insulating structure is provided, which has a recess therein. The recess extends adjacent the first multi-level guard rings and exposes an upper surface of the lower interlayer insulating layer.

According to an embodiment, a semiconductor device includes a first semiconductor region of a first conductivity type, a second semiconductor region of the first conductivity type, a first metal portion, a third semiconductor region of a second conductivity type, a first electrode, a fourth semiconductor region of the second conductivity type, and a second electrode. The first semiconductor region includes a first portion and a second portion. The second semiconductor region is provided on the first semiconductor region. The third semiconductor region is provided on part of the second semiconductor region. The first metal portion is provided in the first semiconductor region. The third semiconductor region is positioned on the first portion. The fourth semiconductor region is provided on another part of the second semiconductor region. The fourth semiconductor region is separated from the third semiconductor region. The fourth semiconductor region is positioned on the second portion.

According to one embodiment, a semiconductor wafer is formed with a plurality of first regions each provided with a circuit element and a second region between the first regions. The semiconductor wafer includes a first structure in which a first embedding material is embedded in a first recess extending in a first direction perpendicular to a surface of a substrate. The first structure is between edges of the first regions and a third region that is cut in the second region when the first regions are separated.