A semiconductor device including a first material layer adjacent to a second material layer, a first via passing through the first material layer and extending into the second material layer, and a second via extending into the first material layer, where along a common cross section parallel to an interface between the two material layers, the first via has a cross section larger than that of the second via.

A remapped extracted die is provided. The remapped extracted die includes an extracted die removed from a previous integrated circuit package. The extracted die includes a plurality of original bond pads having locations that do not correspond to desired pin assignments of a new package base and an interposer, bonded 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.

An electronic isolation device is formed on a monolithic substrate and includes a plurality of passive isolation components. The isolation components are formed in three metal levels. The first metal level is separated from the monolithic substrate by an inorganic PMD layer. The second metal level is separated from the first metal level by a layer of silicon dioxide. The third metal level is separated from the second metal level by at least 20 microns of polyimide or PBO. The isolation components include bondpads on the third metal level for connections to other devices. A dielectric layer is formed over the third metal level, exposing the bondpads. The isolation device contains no transistors.

A semiconductor device includes a singulated region of semiconductor material having a first major surface and a second major surface opposite to the first major surface. In one embodiment, the second major surface includes a recessed surface portion bounded by opposing sidewall portions extending outward from the region of semiconductor material in cross-sectional view. The sidewall portions have outer surfaces defining peripheral edge segments of the singulated region of semiconductor material. An active device region is disposed adjacent to the first major surface and a first conductive layer is disposed adjoining the recessed surface portion. The recessed surface portion provides a semiconductor device having improved electrical characteristics, and the sidewall portions provide a semiconductor device that is less susceptible to warpage, breakage, and other reliability issues.

Various aspects include an integrated circuit (IC), design structure, and a method of making the same. In one embodiment, the IC includes: a substrate; a dielectric layer disposed on the substrate; a set of wire components disposed on the dielectric layer, the set of wire components including a first wire component disposed proximate a second wire component; a bond pad disposed on the first wire component, the bond pad including an exposed portion; a passivation layer disposed on the dielectric layer about a portion of the bond pad and the set of wire components, the passivation layer defining a wire structure via connected to the second wire component; and a wire structure disposed on the passivation layer proximate the bond pad and connected to the second wire component through the wire structure via.

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.

Provided are a stacked image sensor package and a packaging method thereof. A stacked image sensor package includes: a stacked image sensor in which a pixel array die and a logic die are stacked; a redistribution layer formed on one surface of the stacked image sensor, rerouting an input/ output of the stacked image sensor, and including a first pad and a second pad; a memory die connected with the first pad of the redistribution layer and positioned on the stacked image sensor; and external connectors connected with the second pad, connecting the memory die and the stacked image sensor with an external device, and having the memory die positioned therebetween.

A semiconductor device manufacturing method includes: raising and moving a bonding tool, while paying out a wire, in a direction from a second toward a first bonding point to form in the wire a cut portion bent in a vicinity of the second bonding point; lowering and moving a tip of the bonding tool to the cut portion; lowering the bonding tool vertically to thin the cut portion; raising the bonding tool while paying out the wire; and moving the bonding tool in a direction away from the first and second bonding points and along a wire direction connecting the first and second bonding points and then cutting the wire at the cut portion to form a wire tail. This allows the length of the wire tail to be adjusted easily and efficiently to be constant.

A semiconductor device includes a first passivation layer over an interconnect structure. The semiconductor device further includes a first redistribution line (RDL) via extending through an opening in the first passivation layer to electrically connect to the interconnect structure. The first RDL via includes a first conductive material. The semiconductor device further includes an RDL over the first passivation layer and electrically connected to the first RDL via. The RDL comprises a second conductive material different from the first conductive material. The RDL extends beyond the first RDL via in a direction parallel to a top surface of the first passivation layer.

A photoelectric conversion device includes a first semiconductor substrate including a photoelectric conversion unit for generating a signal charge in accordance with an incident light, and a second semiconductor substrate including a signal processing unit for processing an electrical signal on the basis of the signal charge generated in the photoelectric conversion unit. The signal processing unit is situated in an orthogonal projection area from the photoelectric conversion unit to the second semiconductor substrate. A multilayer film including a plurality of insulator layers is provided between the first semiconductor substrate and the second semiconductor substrate. The thickness of the second semiconductor substrate is smaller than 500 micrometers. The thickness of the second semiconductor substrate is greater than the distance from the second semiconductor substrate and a light-receiving surface of the first semiconductor substrate.