A method for forming an integrated circuit (IC) package is provided. In some embodiments, a semiconductor workpiece comprising a scribe line, a first IC die, a second IC die, and a passivation layer is formed. The scribe line separates the first and second IC dies, and the passivation layer covers the first and second IC dies. The first IC die comprises a circuit and a pad structure electrically coupled to the circuit. The pad structure comprises a first pad, a second pad, and a bridge. The bridge is within the scribe line and connects the first pad to the second pad. The passivation layer is patterned to expose the first pad, but not the second pad, and testing is performed on the circuit through the first pad. The semiconductor workpiece is cut along the scribe line to individualize the first and second IC dies, and to remove the bridge.

A metal joined body in which a joint is formed from a first metal member and a second metal member. Brazed joint portions provided intermittently with a brazing material and solder joints filling the spaces between the brazed joint portions with a solder having a fusion point lower than the brazing material, are formed at a seam of the joint. The resulting metal joint has excellent sealing properties and little thermal strain.

A method for interconnecting multiple components of a head-gimbal assembly with a solder joint, including the steps of positioning a first component adjacent to a second component to provide a connection area between the first and second components, dispensing a solder sphere to a capillary tube comprising tapered walls, wherein the capillary tube is positioned with an exit orifice above the connection area between the first and second components, pressurizing the capillary tube until a predetermined pressure is reached, applying a first laser pulse to the solder sphere to provide a level of thermal energy to liquefy the solder sphere, detecting the movement of the liquefied solder sphere after it has exited the exit orifice of the capillary tube, and applying a second laser pulse to reflow the solder sphere to create the solder joint between the first and second components.

Implementations described and claimed herein address the foregoing problems by providing a soldering method including mixing a plurality of spheres in a bond-head hopper wherein a first number of the plurality of the spheres have a diameter that is at least fifty (50) percent larger than the rest of the plurality of spheres.

An apparatus for the presentation of solder spheres to one or more pickup locations of assembly equipment simultaneously. An exemplary method conveys spherical material from a bulk reservoir by the use of a vacuum ported rotating cylinder with a number of apertures. Apertures in the rotating cylinder correspond with pickup locations on a host machine.

A device for manufacturing a plate solder according to the present invention includes a reel on which a thread solder is wound; a cutter that cuts the thread solder, provided between the reel and an end part of the thread solder extending from the reel; an aggregating part that aggregates a plurality of cut thread solders such that the plurality of thread solders are in contact with one another; and a roller that rolls the plurality of aggregated thread solders and pressure bonds them to one another to form a plate solder.

A method for forming an integrated circuit (IC) package is provided. In some embodiments, a semiconductor workpiece comprising a scribe line, a first IC die, a second IC die, and a passivation layer is formed. The scribe line separates the first and second IC dies, and the passivation layer covers the first and second IC dies. The first IC die comprises a circuit and a pad structure electrically coupled to the circuit. The pad structure comprises a first pad, a second pad, and a bridge. The bridge is within the scribe line and connects the first pad to the second pad. The passivation layer is patterned to expose the first pad, but not the second pad, and testing is performed on the circuit through the first pad. The semiconductor workpiece is cut along the scribe line to individualize the first and second IC dies, and to remove the bridge.

A solder ball attaching apparatus includes a working die, having an internal space maintained in a vacuum state, and a plurality of lifting members installed on the working die to be movable upwardly and downwardly. The working die may be provided with an upper plate on which the lifting members are installed. The upper plate may be provided with an insertion groove, into which an upper end portion of the lifting member is inserted when the lifting member is lowered, and a locking groove into which a lower end portion of the lifting member is inserted when the lifting member is raised. The lifting member may be lowered by a chip when the chip is seated on the lifting member and may be raised by elastic restoring force when the chip is removed.

Embodiments disclosed herein include electronic packages. In an embodiment, the electronic package comprises a first substrate; a second substrate; and an array of interconnects electrically coupling the first substrate to the second substrate. In an embodiment, the array of interconnects comprises first interconnects, wherein the first interconnects have a first volume and a first material composition, and second interconnects, wherein the second interconnects have a second volume and a second material composition, and wherein the first volume is different than the second volume and/or the first material composition is different than the second material composition.

Micro solder joint and stencil design. In one embodiment, a stencil for depositing solder on a printed circuit board (PCB) includes a plurality of stencil apertures, a first stencil aperture of the plurality of apertures having an aperture wall defining an aperture perimeter. The aperture wall is configured to not extend beyond an outer edge of a PCB pad provided on the printed circuit board, the aperture wall is also configured to not extend beyond an outer edge of a terminal of a surface mount component, and the first stencil aperture is configured to receive solder paste to form a non-convex solder joint between the PCB pad and the terminal.