Semiconductor devices having an array of flexible connectors configured to mitigate thermomechanical stresses, and associated systems and methods, are disclosed herein. In one embodiment, a semiconductor assembly includes a substrate coupled to an array of flexible connectors. Each flexible connector can be transformed between a resting configuration and a loaded configuration. Each flexible connector can include a conductive wire electrically coupled to the substrate and a support material at least partially surrounding the conductive wire. The conductive wire can have a first shape when the flexible connector is in the resting configuration and a second, different shape when the flexible connector is in the loaded configuration.

A microelectronic component comprises a substrate having at least one bond pad on a surface thereof and a metal pillar structure on the at least one bond pad, the metal pillar structure comprising a metal pillar on the at least one bond pad and a solder material having a portion within a reservoir within the metal pillar and another portion protruding from an end of the metal pillar opposite the at least one bond pad. Methods for forming the metal pillar structures, metal pillar structures, assemblies and systems incorporating the metal pillar structures are also disclosed.

A semiconductor package may include: a first semiconductor chip; a second semiconductor chip disposed over the first semiconductor chip; and a bump structure interposed between the first semiconductor chip and the second semiconductor chip to connect the first semiconductor chip and the second semiconductor chip, wherein the bump structure includes a core portion and a shell portion, the shell portion surrounding all side ails of the core portion, and wherein the shell portion has a higher melting point than the core portion.

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 technique for fabricating a bump structure is disclosed. A substrate that includes a set of pads formed on a surface thereof is prepared, in which the pads includes first conductive material. A metallic adhesion layer is coated on each pad. A bump base is formed on each pad by sintering conductive particles using a mold layer, in which the conductive particles includes second conductive material different from the first conductive material.

Disclosed herein is a bump-on-trace interconnect with a wetted trace sidewall and a method for fabricating the same. A first substrate having conductive bump with solder applied is mounted to a second substrate with a trace disposed thereon by reflowing the solder on the bump so that the solder wets at least one sidewall of the trace, with the solder optionally wetting between at least half and all of the height of the trace sidewall. A plurality of traces and bumps may also be disposed on the first substrate and second substrate with a bump pitch of less than about 100 m, and volume of solder for application to the bump calculated based on at least one of a joint gap distance, desired solder joint width, predetermined solder joint separation, bump geometry, trace geometry, minimum trace sidewall wetting region height and trace separation distance.

A method of the present invention includes preparing a substrate having a surface on which a electrode pad is formed, forming a resist layer on the substrate, the resist layer having an opening on the electrode pad, filling conductive paste in the opening of the resist layer; sintering the conductive paste in the opening to form a conductive layer which covers a side wall of the resist layer and a surface of the electrode pad in the opening, a space on the conductive layer leading to the upper end of the opening being formed, filling solder in the space on the conductive layer and removing the resist layer.

A light emitting diode (LED) element is provided. The LED element includes: an active layer configured to generate light; a first semiconductor layer disposed on a first surface of the active layer and doped with an n-type dopant; a second semiconductor layer disposed on a second surface of the active layer opposite to the first surface, the second semiconductor layer being doped with a p-type dopant; a first electrode pad and a second electrode pad electrically connected to the first semiconductor layer and the second semiconductor layer, respectively, the first electrode pad comprising a first contact surface and the second electrode pad comprising a second contact surface; and a conductive filler disposed on at least one contact surface from among the first contact surface and the second contact surface to increase a contact area of the at least one contact surface.

A light emitting diode display device includes a display board comprising a plurality of unit pixels, a drive circuit board including a plurality of drive circuit regions corresponding to the plurality of unit pixels, and a plurality of bumps interposed between the plurality of unit pixels and the plurality of drive circuit regions. The plurality of unit pixels comprises a first unit pixel including a first P electrode. The plurality of drive circuit regions comprises a first drive circuit region corresponding to the first unit pixel and a first pad connected to a first drive transistor, the plurality of bumps includes a first solder in contact with the first pad, and a first bump on the first solder and including a first filler in contact with the first P electrode, the first solder includes at least one of tin and silver, and the first filler includes copper or nickel.

The present application discloses a semiconductor device and a method for fabricating the semiconductor device. The semiconductor device includes a semiconductor substrate, a stress-relieving structure including a conductive frame positioned above the semiconductor substrate and a plurality of insulating pillars positioned within the conductive frame, and a conductive structure including a supporting portion positioned above the stress-relieving structure, a conductive portion positioned adjacent to the supporting portion, and a plurality of spacers attached to two sides of the conductive portion. A width of the conductive frame is equal to a width of a bottom of the conductive portion.