In some examples, a system comprises a first component having a first surface, a first set of nanoparticles coupled to the first surface, and a first set of nanowires extending from the first set of nanoparticles. The system also comprises a second component having a second surface, a second set of nanoparticles coupled to the second surface, and a second set of nanowires extending from the second set of nanoparticles. The system further includes an adhesive positioned between the first and second surfaces. The first and second sets of nanowires are positioned within the adhesive.

A method for producing a connection between component parts and a component made of component parts are disclosed. In an embodiment, a includes providing a first component part having a first exposed insulation layer and a second component part having a second exposed insulation layer, wherein each of the insulation layers has at least one opening, joining together the first and second component parts such that the opening of the first insulation layer and the opening of the second insulation layer overlap in top view, wherein an Au layer and a Sn layer are arranged one above the other in at least one of the openings and melting the Au layer and the Sn layer to form an AuSn alloy, wherein the AuSn alloy forms a through-via after cooling electrically conductively connecting the first component part to the second component part.

A semiconductor device includes a first body having a first coefficient of thermal expansion (CTE) and a first surface, a third body having a third CTE and a third surface facing the first surface, and a fourth surface at an angle with respect to the third surface defining an edge of the third body, and a second body having a second CTE higher than the first and the third CTE, the second body contacting the first and the third surfaces. A post having a fourth CTE lower than the second CTE, transects the second body and contacts the edge.

Package structures and methods of forming package structures are discussed. A package structure, in accordance with some embodiments, includes an integrated circuit die, an encapsulant at least laterally encapsulating the integrated circuit die, a redistribution structure on the integrated circuit die and the encapsulant, a connector support metallization coupled to the redistribution structure, a dummy pattern, a second dielectric layer, and an external connector on the connector support metallization. The redistribution structure comprises a first dielectric layer having a first surface disposed distally from the encapsulant and the integrated circuit die. The dummy pattern is on the first surface of the first dielectric layer and around the connector support metallization. The second dielectric layer is on the first surface of the first dielectric layer and on at least a portion of the dummy pattern. The second dielectric layer does not contact the connector support metallization.

A semiconductor device includes a semiconductor substrate, a conductive pad disposed on the semiconductor substrate, and a pillar pattern disposed on the conductive pad. The semiconductor device further includes a solder seed pattern disposed on the pillar pattern, and a solder portion disposed on the pillar pattern and the solder seed pattern. A first width of the solder seed pattern is less than a second width of a top surface of the pillar pattern.

A sensor device for use in harsh media, comprising a silicon die comprises a lowly doped region, and a contact layer, contacting the silicon die. The contact layer comprises a refractory metal and an ohmic contact to the silicon die via a silicide of the refractory metal. A noble metal layer is provided over the contact layer such that the contact layer is completely covered by the noble metal layer. The noble metal layer comprises palladium, platinum or a metal alloy of palladium and/or platinum. The noble metal layer is patterned to form an interconnect structure and a contact connecting via the contact layer to the ohmic contact. The noble metal layer is adapted for providing a shield to prevent modulation of the lowly doped region by surface charges. The noble metal layer may advantageously protect the contact layer against harsh media in an external environment of the sensor device.

A method of manufacturing a wafer assembly includes forming an array of planar wafer level metal posts extending from a surface of a substrate of a first wafer. After forming the array of posts, an oxide layer is applied over the surface of the first wafer and around the array of posts, the oxide layer being applied at a temperature of below 150 degrees Celsius.

A substrate or semiconductor device, semiconductor device assembly, and method of forming a semiconductor device assembly that includes a barrier on a solder cup. The semiconductor device assembly includes a substrate disposed over another substrate. At least one solder cup extends from one substrate towards an under bump metal (UBM) on the other substrate. The barrier on the exterior of the solder cup may be a standoff to control a bond line between the substrates. The barrier may reduce solder bridging during the formation of a semiconductor device assembly. The barrier may help to align the solder cup with a UBM when forming a semiconductor device assembly and may reduce misalignment due to lateral movement of substrates and/or semiconductor devices.

Provided is a die structure including a die, a bonding structure, and a protection structure. The die includes a substrate and a metal feature disposed over the substrate. The bonding structure is disposed over the die. The bonding structure includes a bonding dielectric layer and a bonding metal layer disposed in the bonding dielectric layer. The bonding metal layer is electrically connected to the metal feature of the die. The protection structure is disposed between a top portion of the bonding metal layer and a top portion of the bonding dielectric layer. A die stack structure and a method of fabricating the die structure are also provided.

The invention disclosed a method for manufacturing an electrode of a semiconductor device, comprising: forming a first interlayer dielectric layer having a first opening on a first surface of a semiconductor substrate; forming a first resist mask having a second opening on a surface of the first interlayer dielectric layer, wherein the first opening and the second opening are connected to form a first stacked opening; forming a first conductive layer on the first resist mask, wherein the first conductive layer comprises a first portion being located on a surface of the first resist mask and a second portion being located inside the first stacked opening; and removing the first resist mask, wherein the first portion of the first conductive layer is removed together with the first resist mask, and the second portion of the first conductive layer is retained as a first surface electrode.