In an embodiment, a method for forming a solder bump includes preparing a transfer mold having a solder pillar extending from a mold substrate and through a first photoresist layer and having a shape partially defined by a second photoresist layer that is removed prior to transfer of the solder. In an embodiment, the mold substrate is flexible. In an embodiment, the transfer mold is flexible. In an embodiment, the method includes providing a device substrate having a wettable pad. In an embodiment, the method includes placing the transfer mold and the device substrate into aligned contact such that the solder pillar is in contact with the wettable pad. In an embodiment, the method includes forming a metallic bond between the solder pillar and the wettable pad. In an embodiment, the method includes removing the mold substrate and first photoresist layer.

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.

A quality determination device is applied to a component mounter including a pallet and a suction nozzle, and includes a first determination section. The pallet includes supply units on which a solder ball group to be supplied to a target region, that is at least a part of a mounting area of a component to be mounted on a board is mounted. The solder ball group being disposed in accordance with electrode positions of the component. The suction nozzle picks up and holds a target object that is a supply unit or a solder ball group mounted on the supply unit, and supplies the target object to the target region of a board. The first determination section determines quality of the solder ball group mounted on at least one supply unit among the multiple supply units arranged in the pallet before the suction nozzle picks up the target object.

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 guiding board for a ball placement machine has a board body. The board body has a top surface, a bottom surface, a ball-dropping area, and multiple guiding grooves. The ball-dropping area is defined on the top surface. The guiding grooves are defined in the ball-dropping area and are parallel to each other. Each guiding groove has a bottom and multiple ball-dropping holes defined in the bottom and extending through the bottom surface of the board body.

An adhesive dispensing system and method of dispensing liquid material are disclosed. The adhesive dispensing system includes an adhesive dispensing module receiving hot melt adhesive through the inlet at a low pressure and rapidly developing high pressure at an outlet to thereby jet the hot melt adhesive therefrom. The system also includes a pressure container containing a supply of hot melt adhesive and configured to melt or maintain a heated temperature of the hot melt adhesive. A low pressure liquid passageway communicates between the adhesive dispensing module and the pressure container. The system also includes a pressurized air source in fluid communication with the adhesive dispensing module to operate the adhesive dispensing module by moving a piston to generate high pressure at the outlet of a nozzle for jetting hot melt adhesive as a discrete volume toward a substrate.

A method of manufacturing includes depositing a braze filler adjacent to a void between a first component and a second component thus holding the components in position before brazing. The first and second components are heated to melt and flow the braze filler into the void. A braze joint is formed between the first and second components by cooling the braze filler. Depositing the braze filler can include laser cladding the braze filler to the first and/or second components adjacent the void. The method also optionally includes welding the first and second components in position with the braze filler adjacent to the void. The braze filler may be deposited as a powder, cold spray, melted brazed filament, spherical ball or any other suitable form.

A method of manufacturing a plate-shaped solder according to the invention of the present application includes an aggregating step of aggregating a plurality of thread solders and a crimping step of crimping the plurality of aggregated thread solders to one another to form a plate-shaped solder. A manufacturing device of a plate-shaped solder according to the invention of the present application includes an aggregating portion for aggregating a plurality of thread solders and a crimping portion for crimping the plurality of thread solders to one another in the aggregating portion to form a plate-shaped solder.

A laser assembly is disclosed. The laser assembly includes a carrier for mounting a semiconductor laser diode (LD) and a capacitor thereon. The carrier provides, in a top surface thereof, a metal pattern having a die area for mounting the LD through a brazing material, a mounting area, and an auxiliary area for absorbing a surplus brazing material. The capacitor is mounted on the mounting area closer to the LD through another brazing material.

A method of making precise alignment and decal bonding of a pattern of solder preforms to a surface comprising cutting and placing a length of a solder ribbon onto a semiconductor release tape forming a solder ribbon and semiconductor release tape combination, placing the solder ribbon and semiconductor release tape combination on a vacuum chuck on X-Y stage pair in a laser micromachining system, adjusting the working distance, laser-cutting an outline, peeling off the solder ribbon, allowing the desired solder shape to remain, creating indexing holes, providing a target surface on an alignment fixture with indexing pins, aligning the indexing holes, placing the semiconductor release tape with the desired solder shape on the target surface, pressing the desired solder shape onto the target surface, removing the release tape, and making a pattern of the desired solder shape with precise alignment and decal bonding on the target surface.