Micro device optical inspection and repairing equipment adopting an adhesion device is provided. The micro device optical inspection and repairing equipment includes a carrying stage, an optical inspection module and at least one adhesion device. The optical inspection module is arranged corresponding to the carrying stage so as to capture image information and obtain a position coordinate from the image information. The adhesion device includes a main body and an adhesive portion. The adhesive portion is connected to the main body. The adhesion device can move to a target position of the carrying stage according to the position coordinate. The main body is adapted to drive the adhesive portion to move to the target position along a moving axis. An optical inspection and repairing method adopting the micro device optical inspection and repairing equipment is also provided.

A vaporizing apparatus for thin film deposition is provided. The vaporizing apparatus includes an atomizer configured to mix a source injected through a source inlet and a carrier gas injected through a carrier gas inlet and spray a mixed gas, a vaporizing unit including a first vaporization area and a second vaporization area, which are configured to vaporize the mixed gas sprayed from the atomizer, and configured to discharge a vaporized gas as a process gas through an outlet, and a heating unit configured to maintain the mixed gas in the vaporizing unit at a fixed temperature. The heating unit includes a first heating part arranged to surround the first vaporization area and configured to maintain the temperature of the mixed gas in the first vaporization area and a second heating part arranged to enclose the second vaporization area with the first heating part and configured to maintain the temperature of the mixed gas in the second vaporizing space.

A method of making a semiconductor manufacturing apparatus member includes a step of preparing an aluminum base having an alumite layer having a porous columnar structure at an upper surface thereof. The alumite layer is an anodic oxidation film, and a Young's modulus of the alumite layer is between 90 GPa and 120 GPa. The method also includes a step of forming a particle-resistant layer on the alumite layer by aerosol deposition, in which an aerosol containing fine particles of a brittle material dispersed in a gas is ejected from a nozzle to impact against a surface of the alumite layer, wherein the particle-resistant layer includes a polycrystalline ceramic; and wherein, when the resulting semiconductor manufacturing apparatus member is exposed to a plasma in a reference plasma resistance test, the particle-resistant layer has an arithmetic average height Sa of 0.060 or less after the reference plasma test is completed.

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.

A substrate support device relating to technology disclosed in the description of the present application includes: a holding plate for opposing a substrate bowable by being heated by irradiation with flash light; and a plurality of substrate support pins provided on the holding plate and being for supporting the substrate, wherein the plurality of substrate support pins are arranged at locations where a volume of a space between the holding plate and the substrate in an unbowed state and a volume of a space between the holding plate and the substrate in a bowed state are equal to each other. Breakage of the substrate can be suppressed in a case where the substrate is bowed by flash light.

A holding device for holding a plurality of substrates for plasma-enhanced deposition of a layer from the gas phase on the substrates, having: inner carrier plates, arranged parallel to one another and designed to carry substrates on mutually opposite sides; outer carrier plates, arranged parallel to the inner carrier plates and having an inner side facing the inner carrier plates, and an outer side facing away from the inner carrier plates, wherein each outer carrier plate is designed to carry one or more substrates on its inner side and to be free of substrates on its outer side; and shielding plates which are each arranged at a distance from the outer side of the outer carrier plate such that, as seen in a plan view of the outer carrier plates, the shielding plates at least predominantly shield the outer carrier plates, wherein each shielding plate is free of substrates.

A lift pin mechanism employed within a process module includes a plurality of lift pins distributed uniformly along a circumference of a lower electrode defined in the process module. Each lift pin includes a top member that is separated from a bottom member by a collar defined by a chamfer. A sleeve is defined in a housing within a body of the lower electrode on which a substrate is received for processing. The housing is disposed below a mid ring that is defined in the lower electrode. The collar of the lift pin is used to engage with a bottom side of the sleeve, and a top side of the sleeve is configured to engage with the mid ring, when the lift pins are activated. An actuator coupled to each of the plurality of lift pins and an actuator drive connected to the actuators is used to drive the plurality of lift pins. A controller is coupled to the actuator drive to control movement of the plurality of lift pins.

Examples of a predictive maintenance method includes determining whether analog data measured in a substrate treatment that has used a recipe exceeds an allowable threshold which corresponds to the recipe and has been determined beforehand, and notifying, in a case where it is determined that the analog data exceeds the allowable threshold in the determination, a user that a relating module which has been associated with the analog data beforehand has deteriorated.

Describes are shutter disks comprising one or more of titanium (Ti), barium (Ba), or cerium (Ce) for physical vapor deposition (PVD) that allows pasting to minimize outgassing and control defects during etching of a substrate. The shutter disks incorporate getter materials that are highly selective to reactive gas molecules, including O.sub.2, CO, CO.sub.2, and water.

A pick-and-place tool including a plurality of movable holder structures, and a plurality of pick-and-place structures, each holder structure accommodating two or more of the pick-and-place structures, wherein at least one of the two or more pick-and-place structures of a respective holder structure is able to move along a respective holder structure independently from another at least one of the two or more pick-and-place structures of the respective holder structure, and wherein each pick-and-place structure includes a pick-up element configured to pick up a donor component at a donor structure and place the donor component an acceptor structure.