Provided is a semiconductor device having a pad on a semiconductor chip, a first passivation film formed over the semiconductor chip and having an opening portion on the pad of a probe region and a coupling region, a second passivation film formed over the pad and the first passivation film and having an opening portion on the pad of the coupling region, and a rewiring layer formed over the coupling region and the second passivation film and electrically coupled to the pad. The pad of the probe region placed on the periphery side of the semiconductor chip relative to the coupling region has a probe mark and the rewiring layer extends from the coupling region to the center side of the semiconductor chip. The present invention provides a technology capable of achieving size reduction, particularly pitch narrowing, of a semiconductor device.

An integrated circuit component includes a semiconductor substrate, conductive pads, a passivation layer and conductive vias. The semiconductor substrate has an active surface. The conductive pads are located on the active surface of the semiconductor substrate and electrically connected to the semiconductor substrate, and the conductive pads each have a contact region and a testing region, where in each of the conductive pads, an edge of the contact region is in contact with an edge of the testing region. The passivation layer is located on the semiconductor substrate, where the conductive pads are located between the semiconductor substrate and the passivation layer, and the testing regions and the contact regions of the conductive pads are exposed by the passivation layer. The conductive vias are respectively located on the contact regions of the conductive pads.

A semiconductor device includes semiconductor substrate having outer peripheral sides in plan view, and at least a pair of first bonding pad and second bonding pad formed over the semiconductor substrate. The second bonding pad has a shape obtained by rotating the first bonding pad by 180 degrees in plan view. The first bonding pad and the second bonding pad are arranged so as to face each other in a first direction crossing the outer peripheral side. The first bonding pad has a first portion and a second portion of rectangular shape in the second direction along the outer peripheral side. A width of the first portion in the first direction is greater than a width of the second portion in the first direction.

A semiconductor device structure is provided, in some embodiments. The semiconductor device structure includes a semiconductor substrate having a first surface, a second surface, and sidewalls defining a recess that passes through the semiconductor substrate. The semiconductor device structure further includes an interconnect structure having one or more interconnect layers within a first dielectric structure that is disposed along the second surface. A conductive bonding structure is disposed within the recess and includes nickel. The conductive bonding structure has opposing outermost sidewalls that contact sidewalls of the interconnect structure.

Representative implementations of devices and techniques provide a temporary access point (e.g., for testing, programming, etc.) for a targeted interconnect located among multiple finely spaced interconnects on a surface of a microelectronic component. One or more sacrificial layers are disposed on the surface of the microelectronic component, overlaying the multiple interconnects. An insulating layer is disposed between a conductive layer and the surface, and includes a conductive via through the insulating layer that electrically couples the conductive layer to the target interconnect. The sacrificial layers are configured to be removed after the target interconnect has been accessed, without damaging the surface of the microelectronic component.

A semiconductor device including a test pad contact and a method of manufacturing the semiconductor device are disclosed. In an embodiment, a semiconductor device may include a first metal feature and a second metal feature disposed in a single top metal layer over a substrate. A test pad may be formed over and electrically connected to the first metal feature. A first passivation layer may be formed over the second metal feature and the test pad and may cover top and side surfaces of the test pad. A first via may be formed penetrating the first passivation layer and contacting the test pad and a second via may be formed penetrating the first passivation layer and contacting the second metal feature.

An integrated circuit component includes a semiconductor substrate, conductive pads, a passivation layer and conductive vias. The semiconductor substrate has an active surface. The conductive pads are located on the active surface of the semiconductor substrate and electrically connected to the semiconductor substrate, and the conductive pads each have a contact region and a testing region, where in each of the conductive pads, an edge of the contact region is in contact with an edge of the testing region. The passivation layer is located on the semiconductor substrate, where the conductive pads are located between the semiconductor substrate and the passivation layer, and the testing regions and the contact regions of the conductive pads are exposed by the passivation layer. The conductive vias are respectively located on the contact regions of the conductive pads.

A semiconductor device structure and method for forming the same are provided. The semiconductor device structure includes a substrate and a conductive pad formed over the substrate. The semiconductor device structure also includes a protection layer formed over the conductive pad, and the protection layer has a trench. The semiconductor device structure further includes a conductive structure accessibly arranged through the trench of the protection layer and electrically connected to the conductive pad. The conductive structure has a curved top surface that defines an apex, and an apex of the curved top surface is higher than a top surface of the protection layer.

A multi-chip module, and method of fabricating the multi-chip module. The multi-chip module includes: a substrate containing multiple wiring layers, each wiring layer having first pads on a top surface of the substrate and second pads on a bottom surface of the substrate, wherein the second pads include split pad and a conventional pad; a first solder ball in direct physical contact with a contiguous bottom surface of the conventional pad and connected to a next level of packaging under the conventional pad, wherein the first solder ball has a first height; and a second solder ball in direct physical contact with first and second sections of the split pad separated by a gap, wherein the second solder ball has a second height that is sufficiently less than the first height such that the second solder ball is not connected to the next level of packaging.

A package structure includes a semiconductor substrate, conductive pads, and conductive vias. The conductive pads are located on and electrically connected to the semiconductor substrate, and each have a testing region and a contact region comprising a core contact region and a buffer contact region, wherein along one direction, the conductive pads each have a maximum length less than a sum of a maximum length of the testing region and a maximum length of the buffer contact region. The conductive vias are respectively located on the core contact regions of the conductive pads.