A system of producing metal cored solder structures on a substrate includes: a decal, a carrier, and receiving elements. The decal includes one or more apertures each of which is tapered from a top surface to a bottom surface thereof. The carrier is positioned beneath the bottom of the decal and includes cavities in a top surface. The cavities are located in alignment with the apertures of the decal. The decal is positioned on the carrier having the decal bottom surface in contact with the carrier top surface to form feature cavities defined by the decal apertures and the carrier cavities. The feature cavities are shaped to receive one or more metal elements and are configured for receiving molten solder cooled in the cavities. The decal is separable from the carrier to partially expose metal core solder contacts. The receiving elements receive the metal core solder contacts thereon.

A semiconductor structure is provided. The semiconductor structure includes a first substrate and a metal pad formed over the first substrate. The semiconductor structure further includes a solder stud formed over the metal pad, and the solder stud has a flat top surface parallel to a top surface of the first substrate.

A system of producing metal cored solder structures on a substrate includes: a decal having a plurality of apertures, the apertures being tapered from a top surface to a bottom surface of the decal; a carrier configured for positioning beneath the bottom of the decal, the carrier having cavities in a top surface and the cavities located in alignment with the apertures of the decal; the decal being configured for positioning on the carrier having the decal bottom surface in contact with the carrier top surface to form feature cavities defined by the decal apertures and the carrier cavities, the feature cavities being shaped to receive a plurality of metal elements therein, the feature cavities configured for receiving molten solder being cooled in the cavities, the decal being separable from the carrier to partially expose metal core solder contacts; and receiving elements of a substrate being configured to receive the metal core solder contacts thereon, and the metal core solder contacts being exposed and positioned on the substrate.

An embodiment bump on trace (BOT) structure includes a contact element supported by an integrated circuit, an under bump metallurgy (UBM) feature electrically coupled to the contact element, a metal bump on the under bump metallurgy feature, and a substrate trace on a substrate, the substrate trace coupled to the metal bump through a solder joint and intermetallic compounds, a ratio of a first cross sectional area of the intermetallic compounds to a second cross sectional area of the solder joint greater than forty percent.

A bump structure includes a contact element formed on a substrate and a passivation layer overlying the substrate. The passivation layer includes a passivation opening exposing the contact element. The bump structure also includes a polyimide layer overlying the passivation layer and an under bump metallurgy (UBM) feature electrically coupled to the contact element. The polyimide layer has a polyimide opening exposing the contact element, and the under bump metallurgy feature has a UBM width. The bump structure further includes a copper pillar on the under bump metallurgy feature. A distal end of the copper pillar has a pillar width, and the UBM width is greater than the pillar width.

Improved bump coplanarity for semiconductor device assemblies, and associated methods and systems are disclosed. In one embodiment, when openings in a passivation layer of a semiconductor device are formed to expose surfaces of bond pads, additional openings may also be formed in the passivation layer. The additional openings may have depths shallower than the openings extending to the surfaces of bond pads by leveraging partial exposures to the passivation layer using a leaky chrome process. Subsequently, when active bumps (pillars) are formed on the exposed surfaces of bond pads, dummy bumps (pillars) may be formed on recessed surfaces of the additional openings such that differences in heights above the surface of the passivation between the active bumps and the dummy bumps are reduced to improve coplanarity.

Implementations of a semiconductor package may include: a first wafer having a first surface and a first set of blade interconnects, the first set of blade interconnects extending from the first surface. The package may include a second wafer having a first surface and a second set of blade interconnects, the second set of blade interconnects extending from the first surface and oriented substantially perpendicularly to a direction of orientation of the first set of blade interconnects. The first set of blade interconnects may be hybrid bonded to the second set of blade interconnects at a plurality of points of intersection between the first and second set of blade interconnects. The plurality of points of intersection may be located along a length of each blade interconnect of the first set of blade interconnects, and along the length of each blade interconnect of the second set of blade interconnects.

Electroplating methods enable the plating of photoresist defined features which have substantially uniform morphology. The electroplating methods include copper electroplating baths with reaction products of -amino acids and bisepoxides to electroplate the photoresist defined features. Such features include pillars, bond pads and line space features.

The present technology is directed to manufacturing collars for under-bump metal (UBM) structures for die-to-die and/or package-to-package interconnects and associated systems. A semiconductor die includes a semiconductor material having solid-state components and an interconnect extending at least partially through the semiconductor material. An under-bump metal (UBM) structure is formed over the semiconductor material and is electrically coupled to corresponding interconnects. A collar surrounds at least a portion of the side surface of the UBM structure, and a solder material is disposed over the top surface of the UBM structure.

The present technology is directed to manufacturing collars for under-bump metal (UBM) structures for die-to-die and/or package-to-package interconnects and associated systems. A semiconductor die includes a semiconductor material having solid-state components and an interconnect extending at least partially through the semiconductor material. An under-bump metal (UBM) structure is formed over the semiconductor material and is electrically coupled to corresponding interconnects. A collar surrounds at least a portion of the side surface of the UBM structure, and a solder material is disposed over the top surface of the UBM structure.