An apparatus and method for manufacturing a semiconductor package structure are provided. The method includes: providing a process line comprising a first semiconductor manufacturing portion configured to provide a first operation including a first process step, and a second semiconductor manufacturing portion configured to provide a second operation including a second process step; passing a packaging structure through the second semiconductor manufacturing portion, wherein the second semiconductor manufacturing portion applies the second process step to the packaging structure; passing the packaging structure through the first semiconductor manufacturing portion, wherein the first semiconductor manufacturing portion applies the first process step to the packaging structure; and passing the packaging structure through the second semiconductor manufacturing portion again without applying the second process step thereon.

A dipping apparatus includes a squeegee device and a plate for forming a flux film out of flux. A surface of the plate has a rough surface with a nano-level arithmetically average roughness. The dipping apparatus is configured in such a way that the squeegee device and the plate are moved relatively to each other, and the flux is fed from the squeegee device to the rough surface of the plate.

An electronic device includes a multilevel package substrate with first and second levels extending in planes of first and second directions and spaced apart from one another along a third direction, the first level having a first side with landing areas and the second level having a second side with conductive landing pads. The electronic device includes a die with conductive terminals electrically coupled to respective ones of the landing areas, as well as solder balls attached to respective ones of the landing pads, and a package structure that encloses the die and a portion of the multilevel package substrate.

An electronic device includes a multilevel package substrate with first and second levels extending in planes of first and second directions and spaced apart from one another along a third direction, the first level having a first side with landing areas and the second level having a second side with conductive landing pads. The electronic device includes a die with conductive terminals electrically coupled to respective ones of the landing areas, as well as solder balls attached to respective ones of the landing pads, and a package structure that encloses the die and a portion of the multilevel package substrate.

A mechanism is described for facilitating stretchable and self-healing solders in microelectronics manufacturing environments. An apparatus of embodiments, as described herein, includes one or more solders associated with a microelectronics component, where the one or more solders contain a liquid metal and are wrapped in an encapsulation material. The apparatus further includes a substrate coupled to the one or more solders.

A method for fabricating a semiconductor device with a heterogeneous solder joint includes: providing a semiconductor die; providing a coupled element; and soldering the semiconductor die to the coupled element with a first solder joint. The first solder joint includes: a solder material including a first metal composition; and a coating including a second metal composition, different from the first metal composition, the coating at least partially covering the solder material. The second metal composition has a greater stiffness and/or a higher melting point than the first metal composition.

A method for bonding a first substrate and a second substrate, the first substrate having at least one first connection extending from one side of the first substrate, the method comprising fabricating a first adhesive material around and along a height of the at least one first connection; and bonding the at least one first connection, the first adhesive material, and the second substrate.

A semiconductor package structure includes a semiconductor die surface having a narrower pitch region and a wider pitch region adjacent to the narrower pitch region, a plurality of first type conductive pillars in the narrower pitch region, each of the first type conductive pillars having a copper-copper interface, and a plurality of second type conductive pillars in the wider pitch region, each of the second type conductive pillars having a copper-solder interface. A method for manufacturing the semiconductor package structure described herein is also disclosed.

A semiconductor package includes a first die, a second die, a molding compound and a redistribution structure. The first die has a first conductive pillar and a first complex compound sheath surrounding and covering a sidewall of the first conductive pillar. The second die has a second conductive pillar and a protection layer laterally surrounding the second conductive pillar. The molding compound laterally surrounds and wraps around the first and second dies, and is in contact with the first complex compound sheath of the first die. The redistribution structure is disposed on the first and second dies and the molding compound.

A method for forming solder deposits on elevated contact metallizations of terminal faces of a substrate formed in particular as a semiconductor component includes bringing wetting surfaces of the contact metallizations into physical contact with a solder material layer. The solder material is arranged on a solder material carrier. At least for the duration of the physical contact, a heating of the substrate and a tempering of the solder material layer takes place. Subsequently a separation of the physical contact between the contact metallizations wetted with solder material and the solder material layer takes place.