A semiconductor wafer includes a first chip region and a second chip region spaced apart from each other by a scribe lane region. The semiconductor wafer also includes a test pad disposed in the scribe lane region. The semiconductor wafer additionally includes a protective layer partially covering the first chip region, the second chip region, and the scribe lane region, wherein the protective layer covers a portion of the test pad adjacent to the first chip region and leaves a remaining portion of the first test pad exposed.

A groove is formed between an inner peripheral edge of an opening of a pad electrode and an outer peripheral edge of a bonding region located inside the pad electrode in plan view.

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 lead frame is provided with a die pad portion, a first lead portion, a second lead portion, and an extension portion extending from a corner portion neighborhood of the die pad portion to the outside of the die pad portion. The first lead portion has a first terminal portion and a first lead post portion positioned on a side closer to the die pad portion relative to the first terminal portion and electrically connected to the first terminal portion. The second lead portion has a second terminal portion, a third terminal portion positioned between the first terminal portion and the second terminal portion, and a second lead post portion positioned on a side closer to the die pad portion relative to the second terminal portion and the third terminal portion and electrically connected to the second terminal portion and the third terminal portion.

The present disclosure, in some embodiments, relates to a method of forming an integrated chip. The method may be performed by forming a plurality of interconnect layers within a dielectric structure over an upper surface of a substrate. A passivation structure is formed over the dielectric structure. The passivation structure has sidewalls and a horizontally extending surface defining has a recess within an upper surface of the passivation structure. A bond pad is formed having a lower surface overlying the horizontally extending surface and one or more protrusions extending outward from the lower surface. The one or more protrusions extend through one or more openings within the horizontally extending surface to contact a first one of the plurality of interconnect layers. An upper passivation layer is deposited on sidewalls and an upper surface of the bond pad and on sidewalls and the upper surface of the passivation structure.

The present technology relates to a semiconductor device including semiconductor dies formed with vertical die bond pads on an edge of the dies. During wafer fabrication, vertical bond pad blocks are formed in scribe lines of the wafer and electrically coupled to the die bond pads of the semiconductor dies. The vertical bond pad blocks are cut through during wafer dicing, thereby leaving large, vertically oriented pads exposed on a vertical edge of each semiconductor die.

A device includes an interconnect structure, a barrier multi-layer structure, an oxide layer, a pad metal layer, and a passivation layer. The barrier multi-layer structure is over the interconnect structure, the barrier multi-layer structure includes a first metal nitride layer and a second metal nitride layer over the first metal nitride layer. The oxide layer is over the barrier multi-layer structure, in which the oxide layer is an oxide of the second metal nitride layer of the barrier multi-layer structure. The pad metal layer is over the oxide layer. The passivation layer is in contact with the barrier multi-layer structure, the oxide layer, and the pad metal layer.

A method for manufacturing a semiconductor device includes forming a thermosetting resin film on a first metal layer, forming an opening in the resin film, forming a second metal layer that covers a region from an upper surface of the first metal layer exposed from the opening of the resin film to an upper surface of the resin film, performing heat treatment at a temperature equal to or higher than a temperature at which the resin film is cured after forming the second metal layer, forming a cover film that covers the upper surface of the resin film and a side surface of the second metal layer after performing the heat treatment, and forming a solder on an upper surface of the second metal layer exposed from an opening of the cover film after forming the cover film.

A method for forming a semiconductor die, includes forming an interlayer dielectric layer on a substrate having a semiconductor die region, a seal-ring region, and a scribe line region, forming a metal pad and a test pad on the interlayer dielectric layer, forming a passivation dielectric layer on the interlayer dielectric layer, the metal pad, and the test pad, first etching the passivation dielectric layer and the interlayer dielectric layer existing between the seal-ring region and the scribe line region to a predetermined depth using a plasma etching process, second etching the passivation dielectric layer to expose the metal pad and the test pad, forming a bump on the metal pad, and dicing the substrate while removing the scribe line region by mechanical sawing.

Various embodiments of the present disclosure are directed towards a semiconductor structure including a bond pad disposed within a semiconductor substrate. The semiconductor substrate has a back-side surface and a front-side surface opposite the back-side surface. An upper surface of the semiconductor substrate is vertically below the back-side surface. The bond pad extends through the semiconductor substrate. The bond pad includes a conductive body over the upper surface of the semiconductor substrate and conductive protrusions extending from above the upper surface to below the front-side surface of the semiconductor substrate. A vertical distance between a top surface of the bond pad and the back-side surface of the semiconductor substrate is less than a height of the conductive protrusions. A first bond pad isolation structure extends through the semiconductor substrate and laterally surrounds the conductive protrusions.