A semiconductor structure includes a wafer having a wafer outer surface; a semiconductor chip; and a plurality of copper pillars on the semiconductor chip. The pillars have curved end portions and pillar outside surfaces. Also included are a plurality of copper pads on the wafer. The pads have end portions aligned with the curved end portions of the plurality of copper pillars on the semiconductor chip, and the curved end portions of the plurality of copper pillars and the end portions of the plurality of copper pads define a plurality of bonding material receiving regions. The pads have pad outside surfaces. A copper bonding layer is on the pillar outside surfaces, the pad outside surfaces, the bonding material receiving regions, and portions of the outer surface of the wafer. The portions have an annular shape about the copper pads when viewed in plan.

A semiconductor structure includes a wafer having a wafer outer surface; a semiconductor chip; and a plurality of copper pillars on the semiconductor chip. The pillars have curved end portions and pillar outside surfaces. Also included are a plurality of copper pads on the wafer. The pads have end portions aligned with the curved end portions of the plurality of copper pillars on the semiconductor chip, and the curved end portions of the plurality of copper pillars and the end portions of the plurality of copper pads define a plurality of bonding material receiving regions. The pads have pad outside surfaces. A copper bonding layer is on the pillar outside surfaces, the pad outside surfaces, the bonding material receiving regions, and portions of the outer surface of the wafer. The portions have an annular shape about the copper pads when viewed in plan.

A serigraphy method for producing a soulder bump on the front surface of a substrate includes: forming a film on the front surface, forming an opening in the film, filling the opening with a souldering material, and removing the film. Forming a film on the front surface is preceded by the formation of an intermediate layer between the film and the front surface, the intermediate layer being adapted to exhibit a force of adherence at one and/or the other interface formed with the first front surface and the film lower than the force of adherence that can be formed between the film and the first front surface.

A semiconductor device comprises a semiconductor substrate, a conductive pad over the semiconductor substrate, a conductive bump over the conductive pad, a conductive cap over the conductive bump, and a passivation layer over the semiconductor substrate and surrounding the conductive bump. A combination of the conductive bump and the conductive cap has a stepped sidewall profile. The passivation layer has an inner sidewall at least partially facing and spaced apart from an outer sidewall of the conductive bump.

A semiconductor device includes a conductive pattern disposed over a semiconductor substrate, and an interconnect structure disposed over the conductive pattern. The semiconductor device also includes an interconnect liner formed between the interconnect structure and the conductive pattern and surrounding the interconnect structure. The inner sidewall surfaces of the interconnect liner are in direct contact with the interconnect structure, and a maximum distance between outer sidewall surfaces of the interconnect liner is greater than a width of the conductive pattern. The semiconductor device further includes a semiconductor die bonded to the semiconductor substrate. The semiconductor die includes a conductive pad facing the interconnect structure, wherein the conductive pad is electrically connected to the conductive pattern.

A method for fabricating a resist structure is presented. The method includes preparing a substrate on which plural conductive pads are formed; and patterning a lower resist to form plural lower cavities. The lower resist is deposited above the substrate. Each of the plural lower cavities are located above a corresponding one of the plural conductive pads. Additionally, the method includes patterning an upper resist to form plural upper cavities. The upper resist is deposited on the lower resist. Each of the plural upper cavities are located on a corresponding one of the plural lower cavities and have a diameter larger than a diameter of the corresponding one of the plural lower cavities.

In some examples, a system comprises a set of nanoparticles and a set of nanowires extending from the set of nanoparticles.

A semiconductor device includes a semiconductor substrate, a conductive pad over the semiconductor substrate, a conductive bump, a conductive cap over the conductive bump, and a passivation layer. The conductive pad is over the semiconductor substrate. The conductive bump is over the conductive pad, wherein the conductive bump has a stepped sidewall structure including a lower sidewall, an upper sidewall laterally offset from the lower sidewall, and an intermediary surface laterally extending from a bottom edge of the upper sidewall to a top edge of the lower sidewall. The conductive cap is over the conductive bump. The passivation layer is over the semiconductor substrate and laterally surrounds the conductive bump, wherein the passivation layer has a top surface higher than the intermediary surface of the stepped sidewall structure of the conductive bump and lower than a top surface of conductive cap.

A printed structure includes a destination substrate comprising two or more contact pads disposed on or in a surface of the destination substrate, a component disposed on the surface, and two or more electrically conductive connection posts. Each of the connection posts extends from a common side of the component. Each of the connection posts is in electrical and physical contact with one of the contact pads. The component is tilted with respect to the surface of the destination substrate. Each of the connection posts has a flat distal surface.

A method of manufacturing a semiconductor device is described. The method includes depositing a photoresist layer over a semiconductor substrate. The photoresist layer is patterned to form an opening in the photoresist layer. A copper pillar is formed in the opening. A diffusion barrier layer is formed over the copper pillar and over a photoresist portion of the photoresist layer directly adjoining the opening. A solder structure is deposited over the diffusion barrier layer.