A wafer carrier disc installation/uninstallation device and an installation/uninstallation method thereof. The installation/uninstallation device includes a first robotic arm 1, a second robotic arm 2, a carrier disc 3, a main correction mechanism 4, a wafer correction mechanism 5 and a material rest mechanism 6. The carrier disc 3, the main correction mechanism 4, the wafer correction mechanism 5 and the material rest mechanism 6 are positioned within the moving range of the first and second robotic arms 1 and 2. The first robotic arm 1 drives an image capturing assembly 11 and a wafer locating member installation/uninstallation mechanism 12 to move. The second robotic arm 2 drives a wafer taking/placing mechanism 21 to move. Multiple wafer discs 31 are disposed on the carrier disc 3. The main correction mechanism 4 corrects the image capturing assembly 11, the wafer locating member installation/uninstallation mechanism 12 to true operation positions.

The inventive concept provides a substrate treating apparatus. The substrate treating apparatus includes a first process treating unit configured to treat a substrate in a single-type method; a second process treating unit configured to treat a substrate in a batch-type method; and a posture changing unit provided between the first process treating unit and the second process treating unit and configured to change a posture of the substrate between a vertical posture and a horizontal posture, and wherein the substrate is loaded to and unloaded from the first process treating unit.

Provided is an electrostatic capacitance sensor which can remove an influence of a noise occurring from a static eliminator or a driving source and accurately perform measurement even on electrostatic capacitance detected by a thin-type detection unit which can be passed to a finger surface of a wafer transfer robot. The present invention is provided with an AC supply source which supplies an AC voltage to a detection unit, a parasitic capacitance compensation circuit, an operational amplifier, a differential amplifier, a phase detection means, and a low pass filter. An operational amplification output terminal is connected to an inversion input terminal of the differential amplifier through a first band pass filter, the AC supply source is connected to a non-inversion input terminal of the differential amplifier through a second band pass filter, an output terminal of the differential amplifier is connected to an input terminal of the phase detection means, and the phase detection means takes, as a reference signal, an AC signal output from the AC supply source.

A cleaning system for processing a substrate after polishing includes a sulfuric peroxide mix (SPM) module, at least two cleaning elements, and a plurality of robots. The SPM module includes a sulfuric peroxide mix (SPM) cleaner having a first container to hold a sulfuric peroxide mix liquid and five to twenty first supports to hold five to twenty substrates in the liquid in the first container, and a rinsing station having a second container to hold a rinsing liquid and five to twenty second supports to hold five to twenty substrates in the liquid in the second container. Each of the at least two cleaning elements are configured to process a single substrate at a time. Examples of a cleaning element include a megasonic cleaner, a rotating brush cleaner, a buff pad cleaner, a jet spray cleaner, a chemical spin cleaner, a spin drier, and a marangoni drier.

A technique that includes: a substrate holder provided with a substrate mounting table on which a substrate is mounted; a substrate transferrer configured to load or unload the substrate onto or from the substrate mounting table; a process container configured to accommodate the substrate holder holding the substrate; a film-forming gas supply system configured to supply a film-forming gas to the substrate in the process container; and a controller configured to be capable of controlling the substrate transferrer and the film-forming gas supply system to interrupt execution of a film forming process for supplying the film-forming gas to the substrate and perform a process for separating the substrate mounted on the substrate mounting table at least once until a film having a desired thickness is formed on the substrate after the film forming process is started.

One object of this application is to provide an advanced substrate holder including a clamper. A substrate holder holds a substrate by interposing the substrate between frames. The substrate holder includes a front frame, a rear frame, and one or a plurality of clampers. Each of the clampers includes a hook portion including a hook base and a hook main body, and a plate including at least one claw. At least one of the clampers includes the plate including a first claw for a lock and a second claw for a semi-lock.

A substrate processing system is disclosed which includes a processing chamber comprising a susceptor having a first surface and a second surface opposite to the first surface, a groove formed in the first surface adjacent to a perimeter thereof, and a substrate support structure including a plurality of carrier lift pins, each of the plurality of carrier lift pins movably disposed in an opening formed from the second surface to the first surface, wherein the opening is recessed from the groove.

A wafer processing system has a ring maintenance module for loading wafers into a chuck assembly, and for cleaning and inspecting the chuck assembly used in electroplating processors of the system. A shaft is attached to a rotor plate. A rotation motor rotates the shaft and a rotor plate on the shaft. A chuck clamp on an upper end of the shaft holds the chuck assembly onto the rotor plate. A lift motor raises and lowers the rotor plate and the shaft, to move open the chuck assembly for wafer loading and unloading, and to move the chuck assembly into different process positions. A swing arm having spray nozzles may be provided for cleaning the chuck assembly.

There is a substrate support comprising: a substrate supporting portion; a first ring disposed to surround the substrate supporting portion; a second ring surrounding the first ring without overlapping the first ring in plan view; a third ring disposed below the first ring and the second ring such that an inner portion of the third ring overlaps the first ring in plan view and an outer portion of the third ring overlaps the second ring in plan view, and having a hole at the inner portion of the third ring; a lifter having a first engaging portion protruding upward from the hole of the third ring and engaged with the first ring and a second engaging portion disposed below the first engaging portion and engaged with the third ring; and an actuator configured to raise and lower the lifter.

A substrate processing apparatus is described herein. The substrate processing apparatus comprises a transferring device including: a grasping section configured to grasp a substrate holder, a transferring section configured to transfer the substrate holder grasped by the grasping section, and a processing bath for storing a substrate held by the substrate holder so that a surface of the substrate is vertically oriented. The grasping section is configured to grasp the substrate holder with a surface of the substrate oriented horizontally. The transferring section is configured to transfer the substrate holder above the processing bath, with the surface of the substrate oriented horizontally.