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.

Connector structures and methods of forming the same are provided. A method includes forming a first patterned passivation layer on a workpiece, the first patterned passivation layer having a first opening exposing a conductive feature of the workpiece. A seed layer is formed over the first patterned passivation layer and in the first opening. A patterned mask layer is formed over the seed layer, the patterned mask layer having a second opening exposing the seed layer, the second opening overlapping with the first opening. A connector is formed in the second opening. The patterned mask layer is partially removed, an unremoved portion of the patterned mask layer remaining in the first opening. The seed layer is patterned using the unremoved portion of the patterned mask layer as a mask.

To provide a substrate device, an electronic apparatus, and a method for manufacturing a substrate device that can make large the gap between a semiconductor substrate and a wiring substrate by making the height of a solder ball high. A substrate device includes a substrate; an electrical connection unit provided on the substrate; a metal post provided on the electrical connection unit; and a metal film that is provided in one body from a tip surface to at least part of a side surface of the metal post and of which wettability to a solder material is lower than wettability to the solder material of the metal post.

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.

Connector structures and methods of forming the same are provided. A method includes forming a first patterned passivation layer on a workpiece, the first patterned passivation layer having a first opening exposing a conductive feature of the workpiece. A seed layer is formed over the first patterned passivation layer and in the first opening. A patterned mask layer is formed over the seed layer, the patterned mask layer having a second opening exposing the seed layer, the second opening overlapping with the first opening. A connector is formed in the second opening. The patterned mask layer is partially removed, an unremoved portion of the patterned mask layer remaining in the first opening. The seed layer is patterned using the unremoved portion of the patterned mask layer as a mask.

A method of manufacturing a semiconductor structure includes forming a precursor structure including a plurality of conductive pads on a substrate, an etch stop layer between the conductive pads, and an UBM layer on the conductive pads and the etch stop layer. A plurality of mask structures are formed on the UBM layer, and a plurality of openings are formed between thereof. Each of the mask structures is located on one of the conductive pads, and the openings expose a first portion of the UBM layer. A supporting layer is formed in the openings. The mask structures are removed to form a plurality of cavities exposing a second portion of the UBM layer. A conductive material layer is formed in the cavities. The supporting layer is removed. The first portion of the UBM layer is removed to form a plurality of conductive bumps separated from each other.

To prevent a tin alloy from coming into contact with a copper wiring layer when a tin alloy bump layer is reflowed. According to an aspect of the present invention, a method of manufacturing a substrate having a bump at a resist opening is provided. The method of manufacturing a substrate includes a step of forming a copper wiring layer on the substrate by plating at a first temperature, a step of forming a barrier layer on the copper wiring layer by plating at a second temperature that is approximately equal to the first temperature, and a step of forming a tin alloy bump layer on the barrier layer by plating.

To prevent a tin alloy from coming into contact with a copper wiring layer when a tin alloy bump layer is reflowed. According to an aspect of the present invention, a method of manufacturing a substrate having a bump at a resist opening is provided. The method of manufacturing a substrate includes a step of forming a copper wiring layer on the substrate by plating at a first temperature, a step of forming a barrier layer on the copper wiring layer by plating at a second temperature that is approximately equal to the first temperature, and a step of forming a tin alloy bump layer on the barrier layer by plating.

A pillar-type connection includes a first conductive layer that includes a hollow core. A second conductive layer is connected to the first conductive layer defining a conductive pillar that includes a top surface defining a recess aligned with the hollow core.

The disclosure is directed to an integrated circuit structure for joining wafers. The IC structure may include: a metallic pillar over a substrate, the metallic pillar including an upper surface; a wetting inhibitor layer about a periphery of the upper surface of the metallic pillar; and a solder material over the upper surface of the metallic pillar, the solder material being within and constrained by the wetting inhibitor layer. The sidewall of the metallic pillar may be free of the solder material.