A bonding apparatus includes a bond head structure, an optical unit and an actuator unit. The bond head structure includes a bond head collet, a connecting unit to which the bond head collet is attached and a look-through passage extending through the bond head collet and the connecting unit along a central axis of the bond head structure. In use, the bond head collet holds an electrical component to be bonded to a bonding area of a base member and the optical unit is positioned relative to the bond head structure to view and inspect the electrical component through the look-through passage of the bond head structure. The actuator unit moves the connecting unit of the bond head structure based on the inspection of the electrical component by the optical unit, to align the electrical component with the bonding area of the base member.

Methods, systems, and apparatus for cleaning and drying a tape-frame substrate are provided. In embodiments, an apparatus for supporting a tape-frame substrate includes a chuck having a first side and a second side opposite the first side, the first side having a convex surface configured to support the tape-frame substrate; and a plurality of channels extending through the chuck and having outlets along the first side, wherein the plurality of channels are configured to dispense fluid from the outlets along the convex surface of the first side. In embodiments, a support system includes the chuck and a holder configured to mount a tape-frame substrate to the chuck. The plurality of channels are configured to dispense fluid from the outlets and between the tape-frame substrate and the convex surface of the chuck when the tape-frame substrate is mounted to the chuck.

A semiconductor device package includes a substrate, a partition structure and a polymer film. The partition structure is disposed on the substrate and defines a space for accommodating a semiconductor device. The polymer film is adjacent to a side of the partition structure distal to the substrate. A first side surface of the polymer film substantially aligns with a first side surface of the partition structure.

A method for taping a wafer is disclosed. A wafer taping device comprising a wafer stage is provided. A wafer is mounted and secured on the wafer stage. A tape is delivered along a first direction over the wafer. The tape is forced into adhesion with a surface of the wafer in a non-contact manner. The tape is cut along a perimeter of the wafer.

Implementations of methods of making a semiconductor device may include: providing a partial semiconductor wafer. The method may also include providing a wafer holder including a tape portion with one or more openings through the tape portion. The method may include mounting the partial semiconductor wafer over the one or more openings in the tape portion of the wafer holder and providing an electrical connection to the partial semiconductor wafer through the one or more openings in the tape portion during probe test.

A method for transferring at least one chip, from a first support to a second support, includes forming, while the chip is assembled to the first support, an interlayer in the liquid state between, and in contact with, a front face of the chip and an assembly surface of a face of the second support and a solidification of the interlayer. Then, the chip is detached from the first support while maintaining the interlayer in the solid state.

A package structure includes a base material, at least one electronic device, at least one encapsulant and a plurality of dummy pillars. The electronic device is electrically connected to the base material. The encapsulant covers the electronic device. The dummy pillars are embedded in the encapsulant. At least two of the dummy pillars have different heights.

A method of manufacturing chips includes a preparing step of preparing a wafer unit in which a wafer having a plurality of devices formed thereon is affixed to a tape with a die-attach layer being interposed therebetween, the die-attach layer including fillers, and the devices are protected by a protective member and a face side of the wafer is exposed along the projected dicing lines, a wafer processing step of performing plasma etching on the wafer from the face side thereof to divide the wafer and expose the die-attach layer along the projected dicing lines, a die-attach layer processing step of performing plasma etching on the die-attach layer from the face side of the wafer, and a cleaning step of ejecting a fluid to the face side of the wafer to remove filler residuals along the projected dicing lines from the wafer unit.

In a described example, an apparatus includes: a first semiconductor die with a component on a first surface; a second semiconductor die mounted on a package substrate and having a third surface facing away from the package substrate; a solder seal bonded to and extending from the first surface of the first semiconductor die flip chip mounted to the third surface of the second semiconductor die, the solder seal at least partially surrounding the stress sensitive component; a first solder joint formed between the solder seal and the third surface of the second semiconductor die; a second solder joint formed between solder at an end of the post connect and the third surface of the second semiconductor die; and a mold compound covering the second surface of the first semiconductor die, a portion of the second semiconductor die, and an outside periphery of the solder seal.

A mounting apparatus for stacking and mounting two or more semiconductor chips at a plurality of locations on a substrate includes: a first mounting head for forming, at a plurality of locations on the substrate, temporarily stacked bodies in which two or more semiconductor chips are stacked in a temporarily press-attached state; and a second mounting head for forming chip stacked bodies by sequentially finally press-attaching the temporarily stacked bodies formed at the plurality of locations. The second mounting head includes: a press-attaching tool for heating and pressing an upper surface of a target temporarily stacked body to thereby finally press-attach the two or more semiconductor chips configuring the temporarily stacked body altogether; and one or more heat-dissipation tools having a heat-dissipating body which, by coming into contact with an upper surface of another stacked body positioned around the target temporarily stacked body, dissipates heat from the another stacked body.