A method of establishing conductive connections is disclosed. The method includes providing an integrated circuit die having a plurality of solder balls each of which has an oxide layer on an outer surface of the solder ball. The method also includes performing a heating process to heat at least the solder balls and applying a force causing each of a plurality of piercing bond structures on a substrate to pierce one of the solder balls and its associated oxide layer to thereby establish a conductive connection between the solder ball and the piercing bond structure.

A method of soldering a semiconductor chip to a chip carrier includes arranging a solder deposit including solder and solder flux between a contact portion of the carrier and a contact portion of a chip pad arranged at a surface of the semiconductor chip. Arranging a dielectric layer at the surface of the semiconductor chip. The dielectric layer includes an opening within which the contact portion of the chip pad is exposed. The dielectric layer further includes arranging a solder flux outgassing trench separate from the opening and intersecting with the solder deposit. The method further includes melting the solder deposit which causes liquid solder to be moved over the solder flux outgassing trench for extraction of flux gas.

A method of soldering a semiconductor chip to a chip carrier includes arranging a solder deposit including solder and solder flux between a contact portion of the carrier and a contact portion of a chip pad arranged at a surface of the semiconductor chip. Arranging a dielectric layer at the surface of the semiconductor chip. The dielectric layer includes an opening within which the contact portion of the chip pad is exposed. The dielectric layer further includes arranging a solder flux outgassing trench separate from the opening and intersecting with the solder deposit. The method further includes melting the solder deposit which causes liquid solder to be moved over the solder flux outgassing trench for extraction of flux gas.

A semiconductor device assembly includes a semiconductor die, a substrate, and a spacer directly coupled to the substrate. The spacer includes a flexible main body and a support structure embedded in the flexible main body, wherein the support structure has a higher stiffness than the flexible main body. The spacer carries the semiconductor die. The flexible main body of the spacer mitigates the effects of thermomechanical stress, for example caused by a mismatch between the coefficient of thermal expansion of the semiconductor die and the substrate. The embedded support structure provides strength needed to support the semiconductor die during assembly.

A nitride-based semiconductor device includes a nitride-based semiconductor wafer, a protecting layer, and a plurality of connecting bumps. The nitride-based semiconductor wafer comprises a plurality of nitride-based dies. Each of the nitride-based dies comprises a connecting surface and a plurality of connecting pads and the connecting pads are embedded in the connecting surface. The protecting layer is disposed on the connecting surfaces of the nitride-based dies. The connecting bumps are embedded in the protecting layer. Every connecting bump connects one of the connecting pads. Every connecting bump has a first polished plane, and the first polished plane is free from the protecting layer. A manufacturing method of nitride-based semiconductor device is also provided.

A method of manufacture for a semiconductor package includes; forming a molding member on side surfaces of the semiconductor chips, using an adhesive to attach a carrier substrate to upper surfaces of the molding member and the semiconductor chips, using a first blade having a first blade-width to cut away selected portions of the carrier substrate and portions of the adhesive underlying the selected portions of the carrier substrate, and using the first blade to partially cut into an upper surface of the molding member to form a first cutting groove, wherein the selected portions of the carrier substrate are dispose above portions of the molding member between adjacent ones of semiconductor chips, using a second blade having a second blade-width narrower than the first blade-width to cut through a lower surface of the molding member to form a second cutting groove, wherein a combination of the first cutting groove and the second cutting groove separate a package structure including a semiconductor chip supported by a cut portion of the carrier substrate and bonding the package structure to an upper surface of a package substrate.

Provided is a semiconductor package, and more particularly, a semiconductor package in which a semiconductor device is protected in such a way that stress from push and thermal expansion generated while molding by a package housing is dispersed or absorbed through an electrical connecting member having a non-vertical structure bent in a z-letter shape.

A method of establishing conductive connections is disclosed. The method includes providing an integrated circuit die having a plurality of solder balls each of which has an oxide layer on an outer surface of the solder ball. The method also includes performing a heating process to heat at least the solder balls and applying a force causing each of a plurality of piercing bond structures on a substrate to pierce one of the solder balls and its associated oxide layer to thereby establish a conductive connection between the solder ball and the piercing bond structure.

Representative implementations of devices and techniques provide interconnect structures and components for coupling various carriers, printed circuit board (PCB) components, integrated circuit (IC) dice, and the like, using tall and/or fine pitch physical connections. Multiple layers of conductive structures or materials are arranged to form the interconnect structures and components. Nonwettable barriers may be used with one or more of the layers to form a shape, including a pitch of one or more of the layers.

A method of establishing conductive connections is disclosed. The method includes providing an integrated circuit die having a plurality of solder balls each of which has an oxide layer on an outer surface of the solder ball. The method also includes performing a heating process to heat at least the solder balls and applying a force causing each of a plurality of piercing bond structures on a substrate to pierce one of the solder balls and its associated oxide layer to thereby establish a conductive connection between the solder ball and the piercing bond structure.