A semiconductor device has a first semiconductor die and second semiconductor die with a conductive layer formed over the first semiconductor die and second semiconductor die. The second semiconductor die is disposed adjacent to the first semiconductor die with a side surface and the conductive layer of the first semiconductor die contacting a side surface and the conductive layer of the second semiconductor die. An interconnect, such as a conductive material, is formed across a junction between the conductive layers of the first and second semiconductor die. The conductive layer may extend down the side surface of the first semiconductor die and further down the side surface of the second semiconductor die. An extension of the side surface of the first semiconductor die can interlock with a recess of the side surface of the second semiconductor die. The conductive layer extends over the extension and into the recess.

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.

A conductive ball includes a copper ball, a nickel layer covering an outer surface of the copper ball, a copper layer covering an outer surface of the nickel layer, and a tin-based solder covering an outer surface of the copper layer. A copper weight of the copper layer relative to a summed weight of the tin-based solder and the copper layer is 0.7 wt % to 3 wt %.

A method for remapping an extracted die is provided. The method includes one or more of removing an extracted die from a previous integrated circuit package, the extracted die including a plurality of original bond pads having locations that do not correspond to desired pin assignments of a new package base and bonding an interposer to the extracted die. The interposer includes first bond pads configured to receive new bond wires from the plurality of original bond pads and second bond pads corresponding to desired pin assignments of the new package base, each individually electrically coupled to one of the first bond pads and configured to receive new bond wires from package leads or downbonds of the new package base.

Package structures and methods for forming the same are provided. A package structure includes a semiconductor die. The semiconductor die includes a passivation layer over a semiconductor substrate. The semiconductor die also includes a conductive pad in the passivation layer. The passivation layer partially exposes a top surface of the conductive pad. The package structure also includes an encapsulation layer surrounding the semiconductor die. The package structure further includes a dielectric layer covering the semiconductor die and the encapsulation layer. In addition, the package structure includes a redistribution layer covering the dielectric layer. The redistribution layer extends in the dielectric layer to be physically connected to the top surface of the conductive pad.

A semiconductor device includes a semiconductor substrate. A pad region is disposed on the semiconductor substrate. A micro bump is disposed on the pad region. The micro bump has a first portion on the pad region and a second portion on the first portion. The first portion and the second portion have different widths. The first portion has a first width and the second portion has a second width. The first width is larger or smaller than the second width. The micro bump includes nickel and gold. The semiconductor device also includes a passivation layer overlying a portion of the pad region.

A semiconductor device according to the present invention includes a first conductive-type SiC semiconductor layer, and a Schottky metal, comprising molybdenum and having a thickness of 10 nm to 150 nm, that contacts the surface of the SiC semiconductor layer. The junction of the SiC semiconductor layer to the Schottky metal has a planar structure, or a structure with recesses and protrusions of equal to or less than 5 nm.

A semiconductor structure is provided. The semiconductor structure includes a substrate, at least one semiconductor device, a through-substrate via (TSV), and a shield structure. The substrate has a front side surface and a back side surface. The semiconductor device is disposed on the front side surface. The TSV is disposed in the substrate. The TSV is exposed by the front side surface and the back side surface, and the TSV is electrically connected to the semiconductor device. The shield structure is disposed in the substrate and surrounds the TSV. The shield structure is exposed by the front side surface, the shield structure is electrically isolated from the TSV, and the shield structure is used to be electrically connected to a power terminal or a ground terminal.

A semiconductor device includes a semiconductor substrate SB and a wiring structure formed on a main surface of the semiconductor substrate SB. The uppermost first wiring layer among a plurality of wiring layers included in the wiring structure includes a pad PD, and the pad PD has a first region for bonding a copper wire and a second region for bringing a probe into contact with the pad. A second wiring layer that is lower by one layer than the first wiring layer among the plurality of wiring layers included in the wiring structure includes a wiring line M6 arranged immediately below the pad PD, the wiring line M6 is arranged immediately below a region other than the first region of the pad PD, and no conductor pattern in the same layer as a layer of the wiring line M6 belong is formed immediately below the first region of the pad PD.

A technique is provided that can prevent cracking of a protective film in the uppermost layer of a semiconductor device and improve the reliability of the semiconductor device. Bonding pads formed over a principal surface of a semiconductor chip are in a rectangular shape, and an opening is formed in a protective film over each bonding pad in such a manner that an overlapping width of the protective film in a wire bonding region of each bonding pad becomes wider than an overlapping width of the protective film in a probe region of each bonding pad.