Methods and apparatus for solder connections. An apparatus includes a substrate having a conductive terminal on a surface; a passivation layer overlying the surface of the substrate and the conductive terminal; an opening in the passivation layer exposing a portion of the conductive terminal; at least one stud bump bonded to the conductive terminal in the opening and extending in a direction normal to the surface of the substrate; and a solder connection formed on the conductive terminal in the opening and enclosing the at least one stud bump. Methods for forming the solder connections are disclosed.

A manufacturing method of a combing bump structure is disclosed. In the manufacturing method, a semiconductor substrate is provided, a pad is formed on the semiconductor substrate, a conductive layer is formed on the pad, a solder bump is formed on the conductive layer, and at least two metal side walls are formed disposed along opposing laterals of the solder bump respectively.

A pre-conductive array disposed on a target circuit substrate comprises a plurality of conductive electrode groups disposed on the target circuit substrate, and at least a conductive particle dispose on each of conductive electrodes of a part or all of the conductive electrode groups. The at least a conductive particle and the corresponding conductive electrode form a pre-conductive structure, and the pre-conductive structures form the pre-conductive array.

A filter package structure includes: a die substrate, a substrate, a solder resist layer, a package layer, and a conductive structure disposed; wherein the solder resist layer is disposed on the substrate, and a plurality of channels are formed in the solder resist layer, each of the channels being provided with a solder; the conductive structure includes a seal wall and a support electrode, the seal wall and one terminal of the support electrode being connected to the substrate via the solder; and the die substrate is provided with a filter, wherein the seal wall is disposed around a periphery of the filter, the die substrate, the substrate and the seal wall enclose to define an enclosed chamber, the support electrode is disposed in the enclosed chamber, and the package layer is disposed on a periphery, far away from the enclosed chamber, of the die substrate.

A system and method for preventing cracks is provided. An embodiment comprises placing crack stoppers into a connection between a semiconductor die and a substrate. The crack stoppers may be in the shape of hollow or solid cylinders and may be placed so as to prevent any cracks from propagating through the crack stoppers.

A microelectronic assembly includes a first substrate having a surface and a first conductive element and a second substrate having a surface and a second conductive element. The assembly further includes an electrically conductive alloy mass joined to the first and second conductive elements. First and second materials of the alloy mass each have a melting point lower than a melting point of the alloy. A concentration of the first material varies in concentration from a relatively higher amount at a location disposed toward the first conductive element to a relatively lower amount toward the second conductive element, and a concentration of the second material varies in concentration from a relatively higher amount at a location disposed toward the second conductive element to a relatively lower amount toward the first conductive element.

A bonding electrode structure of a flip-chip LED chip includes: a substrate; a light-emitting epitaxial layer over the substrate; a bonding electrode over the light-emitting epitaxial layer, wherein the bonding electrode structure includes a metal laminated layer having a bottom layer and an upper surface layer from bottom up. The bottom layer structure is oxidable metal and the side wall forms an oxide layer. The upper surface layer is non-oxidable metal. The bonding electrode structure has a main contact portion, and a grid-shape portion surrounding the main contact portion in a horizontal direction. The problems during packaging and soldering of the flip-chip LED chip structure, such as short circuit or electric leakage, can thus be solved.

Embodiments are directed to a method of forming a semiconductor chip package and resulting structures having a mixed under-bump metallization (UBM) size and pitch on a single die. A first set of UBMs having a first total plateable surface area is formed on a first region of a die. A second set of UBMs having an equal total plateable surface area is formed on a second region of the die. A solder bump having a calculated solder height is applied to a plateable surface of each UBM. The solder height is calculated such that a volume of solder in the first region is equal to a volume of solder in the second region.

A pre-conductive array disposed on a target circuit substrate comprises a plurality of conductive electrode groups disposed on the target circuit substrate, and at least a conductive particle dispose on each of conductive electrodes of a part or all of the conductive electrode groups. The at least a conductive particle and the corresponding conductive electrode form a pre-conductive structure, and the pre-conductive structures form the pre-conductive array.

An electronic device is disclosed. The electronic device includes a chip, a component, and a plurality of first interlayer elements. The chip has an upper surface and a first pad disposed over the upper surface. The component is disposed over the electronic component and configured to filter noise from the electronic component. The plurality of first interlayer elements connect the first pad. At least one of the plurality of the first interlayer elements is non-overlapping with the component in a direction substantially perpendicular to the upper surface of the component