A semiconductor structure includes a supporting layer including a pad area; and a groove formed in the pad area of the supporting layer, wherein a bottom width of the groove is greater than a top width of the groove; and a pad disposed in the pad area on the supporting layer, wherein the pad is partially embedded in the groove. This structure can help to release the bonding pressure during the wire bonding process. When the pad is squeezed out, it can enter the air cavity, which can prevent the protective layer from being lifted up or cracked, and avoid the pad from overflowing. At the same time, the bonding wire squeezed into the air cavity during bonding process increases the contact area between the pad and the supporting layer, thereby enhancing the stability of the overall structure.

A method of forming a semiconductor device with a metal pillar overlapping a first top metal interconnect and a second top metal interconnect is disclosed. The metal pillar overlapping the first top metal interconnect and second top metal interconnect is connected to the first top metal interconnect by top metal vias while the second top metal interconnect does not contain top metal vias and remains free of a direct electrical connection to the metal pillar. The metal pillars are attached directly to top metal vias without a bond pad of metal. The elimination of the bond pad layer reduces the mask count, processing, and cost of the device. In addition, the elimination of the bond pad results in reduced die area requirements for the metal pillar.

A method of forming a semiconductor device with a metal pillar overlapping a first top metal interconnect and a second top metal interconnect is disclosed. The metal pillar overlapping the first top metal interconnect and second top metal interconnect is connected to the first top metal interconnect by top metal vias while the second top metal interconnect does not contain top metal vias and remains free of a direct electrical connection to the metal pillar. The metal pillars are attached directly to top metal vias without a bond pad of metal. The elimination of the bond pad layer reduces the mask count, processing, and cost of the device. In addition, the elimination of the bond pad results in reduced die area requirements for the metal pillar.

The present application discloses a semiconductor device with slanted conductive layers and a method for fabricating the semiconductor device with the slanted conductive layers. The semiconductor device includes a substrate, a first insulating layer positioned above the substrate, first slanted conductive layers positioned in the first insulating layer, and a top conductive layer positioned covering the first slanted conductive layers.

The present application discloses a method for fabricating a semiconductor device with slanted conductive layers. The method for fabricating a semiconductor device includes providing a substrate, forming a first insulating layer above the substrate, forming first slanted recesses along the first insulating layer, and forming first slanted conductive layers in the first slanted recesses and a top conductive layer covering the first slanted conductive layers.

The invention provides a semiconductor bonding structure, the semiconductor bonding structure includes a first chip and a second chip which are bonded with each other, the first chip has a first bonding pad and the second bonding pad contacted and electrically connected to each other on a bonding interface, the first bonding pad and the second bonding pad are made of copper, and a heterogeneous contact combination in the first chip, the heterogeneous contact combination comprises a contact stack structure of a copper element, a tungsten element and an aluminum element, the tungsten element is located between the copper element and the aluminum element.

A method for manufacturing a bond pad structure includes providing a substrate structure including a substrate, a first metal layer on the substrate, and a passivation layer on the first metal layer, the passivation layer having an opening extending to the first metal layer; and filling the opening of the passivation layer with a second metal layer. The bond pad structure has a significantly increased thickness compared with the thickness of the exposed portion of the first metal layer in the opening, thereby ensuring wire bonding reliability and yield.

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.

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.

Semiconductor devices having metallization structures including crack-inhibiting structures, and associated systems and methods, are disclosed herein. In one embodiment, a semiconductor device includes a metallization structure formed over a semiconductor substrate. The metallization structure can include a bond pad electrically coupled to the semiconductor substrate via one or more layers of conductive material, and an insulating materialsuch as a low- dielectric materialat least partially around the conductive material. The metallization structure can further include a crack-inhibiting structure positioned beneath the bond pad between the bond pad and the semiconductor substrate. The crack-inhibiting structure can include (a) a metal lattice extending laterally between the bond pad and the semiconductor substrate and (b) barrier members extending vertically between the metal lattice and the bond pad.