A system for surface patterning using a three dimensional holographic mask includes a light source configured to emit a light beam toward the holographic mask. The holographic mask can be formed as a topographical pattern on a transparent mask substrate. A semiconductor substrate can be positioned on an opposite site of the holographic mask as the light source and can be spaced apart from the holographic mask. The system can also include a base for supporting the semiconductor substrate.

The present disclosure relates to a debonding apparatus. In some embodiments, the debonding apparatus comprises a wafer chuck configured to hold a pair of bonded substrates on a chuck top surface. The debonding apparatus further comprises a pair of separating blades including a first separating blade and a second separating blade placed at edges of the pair of bonded substrates diametrically opposite to each other. The first separating blade has a first thickness that is smaller than a second thickness of the second separating blade. The debonding apparatus further comprises a flex wafer assembly placed above the pair of bonded substrates and configured to pull the pair of bonded substrates upwardly to separate a second substrate from a first substrate of the pair of bonded substrate. By providing unbalanced initial torques on opposite sides of the bonded substrate pair, edge defects and wafer breakage are reduced.

A method includes transmitting a radiation toward an electrostatic chuck, receiving a reflection of the radiation, analyzing the reflection of the radiation, determining whether a particle is present on the electrostatic chuck based on the analyzing the reflection of the radiation, and moving a cleaning tool to a location of the particle on the electrostatic chuck when the determination determines that the particle is present.

A method of producing packaged semiconductor devices includes providing a first packaging substrate panel. A second packaging substrate panel is provided. The first and second packaging substrate panels are moved through an assembly line that includes a plurality of package assembly tools using a control mechanism. First type packaged semiconductor devices are formed on the first packaging substrate panel and second type packaged semiconductor devices are formed on the second packaging substrate panel. The second type packaged semiconductor device is different than the first type packaged semiconductor device. The control mechanism moves both of the first and packaging substrate panels through the assembly line in a non-linear manner.

A support structure for a suspended injector includes a suspended injector having a tubular vertical portion extending in a vertical direction, one or more chamfered portions formed by chamfering an outer peripheral surface near an upper end of the tubular vertical portion, a pair of holding members each having a flat surface formed on an inner peripheral surface of each of the pair of holding members to engage with each of the chamfered portions, each of the pair of holding members holding the tubular vertical portion of the suspended injector by sandwiching the tubular vertical portion of the suspended injector from both sides each of the pair of holding members, and a support structure part configured to fixedly support the pair of holding members, and configured to suspend and support the suspended injector.

The present disclosure relates to high pressure processing apparatus for semiconductor processing. The apparatus described herein include a high pressure process chamber and a containment chamber surrounding the process chamber. A high pressure fluid delivery module is in fluid communication with the high pressure process chamber and is configured to deliver a high pressure fluid to the process chamber.

A method for treating a substrate includes a substrate treating step of treating the substrate by dispensing a treating liquid onto the substrate while rotating the substrate supported on a support plate in a processing space of a processing vessel and a vessel cleaning step of cleaning the processing vessel by dispensing a cleaning solution onto a jig while rotating the jig supported on the support plate. In the substrate treating step, the substrate is clamped to the support plate by a first vacuum pressure applied to the substrate. The vessel cleaning step includes a first clamping step of clamping the jig to the support plate by applying a second vacuum pressure to the jig. The first vacuum pressure and the second vacuum pressure are different from each other.

A protective cover for an electrostatic chuck may include a conductive wafer and a plasma resistant ceramic layer on at least one surface of the conductive wafer. The plasma resistant ceramic layer covers a top surface of the conductive wafer, side walls of the conductive wafer and an outer perimeter of a bottom surface of the conductive wafer. Alternatively, a protective cover for an electrostatic chuck may include a plasma resistant bulk sintered ceramic wafer and a conductive layer on a portion of a bottom surface of the plasma resistant bulk sintered ceramic wafer, wherein a perimeter of the bottom surface is not covered. The protective layer may be used to protect an electrostatic chuck during a plasma cleaning process.

A method for sawing a semiconductor wafer is provided. The method includes sawing a semiconductor wafer to form a first opening. In addition, the semiconductor wafer includes a dicing tape and a substrate attached to the dicing tape by a die attach film (DAF), and the first opening is formed in an upper portion of the substrate. The method further includes sawing through the substrate and the DAF of the semiconductor wafer from the first opening to form a middle opening under the first opening and a second opening under the middle opening, so that the semiconductor wafer is divided into two dies. In addition, a slope of a sidewall of the middle opening is different from slopes of sidewalls of the first opening and the second opening.

A manufacturing apparatus of a display device includes: a first stage including a plurality of cell units, each including: a display unit including a display area, and a pad area; and a protective film unit attached to the display unit, and including a display film portion corresponding to the display area, and a pad film portion corresponding to the pad area; a second stage; and a transfer unit to transfer the cell units to the second stage from the first stage, and to peel off the pad film portion. The transfer unit includes: a body member; a plurality of pins along a first direction on a first surface of the body member; a plurality of suction pads on the first surface of the body member along a second direction; and a reel member on a second surface of the body member to supply a peeling tape to the second surface.