Disclosed is a substrate treating apparatus for performing a cleaning treatment on substrates. The apparatus includes an indexer block with an indexer robot, a treating block including a cleaning unit, and a path block disposed between the indexer block and the treating block. The indexer robot includes a guide rail, a base, an articulated arm, and a hand. The guide rail is positioned so as not to overlap a mount position of a substrate in the path block.

According to one embodiment, a vacuum processing device is provided which is capable of being controlled to create the most suitable gas flow under the situation where the device is placed by allowing a plurality of vacuum transfer chambers to communicate with each other via the intermediate chamber in an operation method of the vacuum processing device including the plurality of vacuum transfer chambers connected to each other via the intermediate chamber and a plurality of vacuum processing chambers respectively connected to the vacuum transfer chambers.

According to one embodiment, a substrate transfer apparatus includes: a first gripping plate; a first claw that is supported by the first gripping plate, and has an abutment surface abutting on the outer peripheral surface of a substrate located above and below a surface of the first gripping plate; a second gripping plate arranged as overlapping with the first gripping plate; a second claw that is supported by the second gripping plate, and has an abutment surface abutting on the outer peripheral surface of the substrate located above and below the surface of the first gripping plate; and a gripping part configured to move the first gripping plate and the second gripping plate relative to each other such that the first claw and the second claw move close to and away from each other in a direction intersecting the outer peripheral surface of the substrate.

Methods and apparatuses for aligning masks with substrates are provided. A method can include receiving a carrier having a substrate disposed thereon at an alignment stage of an alignment module, transferring a mask from a mask cassette of a mask stocker of the alignment module to a position over the alignment stage, and positioning the mask on the carrier. The method also includes acquiring one or more images of the mask and the substrate, where the mask contains one or more alignment holes passing through the mask and the substrate contains one or more alignment elements disposed on an upper surface of the substrate, analyzing the one or more images to determine one or more differences between one or more alignment holes of the mask and one or more alignment elements of the substrate, and aligning the mask with the substrate based on the differences.

An operating ratio is improved in a vacuum processing apparatus to which a plurality of vacuum transfer chambers are connected through a vacuum transfer intermediate chamber. In a method of operating the vacuum processing apparatus having the plurality of vacuum transfer chambers connected through the vacuum transfer intermediate chamber and a plurality of vacuum processing vessels connected to the vacuum transfer chambers, respectively, the plurality of vacuum transfer chambers are made to communicate through the vacuum transfer intermediate chamber, a purge gas is supplied to the vacuum transfer chamber connected to a lock chamber in the plurality of vacuum transfer chambers, an inside of the transfer chamber of the vacuum transfer chamber which is far from the lock chamber is decompressed/exhausted, and pressures in all the transfer chambers of the plurality of vacuum transfer chambers are raised to be higher than the pressure in the vacuum processing vessel.

The present disclosure generally relates to methods for removing contaminants and native oxides from substrate surfaces. The method includes exposing a surface of the substrate to first hydrogen radical species, wherein the substrate is silicon germanium having a concentration of germanium above about 30%, then exposing the surface of the substrate to a plasma formed from a fluorine-containing precursor and a hydrogen-containing precursor, and then exposing the surface of the substrate to second hydrogen radical species.

A substrate processing method includes forming a liquid film of an alkaline processing liquid on a substrate by supplying the alkaline processing liquid having a reduced oxygen concentration onto the substrate; and etching the substrate by rotating the substrate while supplying the alkaline processing liquid in a state that the liquid film having a given thickness is formed on the substrate.

A vacuum transfer device configured to transfer a substrate in a vacuum includes: a flat motor including a body, a plurality of electromagnetic coils arrayed in the body, and a current controller that controls a current supplied to the electromagnetic coil; a transfer unit including a substrate holder configured to hold a substrate, and a base having a plurality of magnets arrayed therein and magnetically levitating from a surface of the body by a magnetic field generated by the electromagnetic coil, and move in a magnetically levitating state thereby moving the substrate holder; and a temperature controller configured to adjust temperature of at least a portion of the body. The temperature of the transfer unit is adjusted by stopping the magnetic levitation of the base by controlling the current supplied to the electromagnetic coil, and bringing the base into contact with a temperature-adjusted portion of the body.

A substrate processing apparatus includes a first processing module including a first processing module, a second processing module, a first utility system adjacent to a back surface of the first processing module, and a second utility system adjacent to a back surface of the second processing module, a first exhaust box of the first utility system and a second exhaust box of the second utility system being disposed to face each other across a maintenance area located behind a part of the back surface of the first processing module that is close to the second processing module and behind a part of the back surface of the second processing module that is close to the first processing module, and a first supply box of the first utility system and a second supply box of the second utility system being disposed to face each other across the maintenance area.

A substrate processing system comprises an edge computing device including processor that executes instructions stored in a memory to process an image or video captured by camera(s) of at least one of a substrate and a component of the substrate processing system. The component is associated with a robot transporting the substrate between processing chambers of the substrate processing system or between the substrate processing system and a second substrate processing system. The cameras are located along a travel path of the substrate. The instructions configure the processor to transmit first data from the image to a remote server via a network and to receive second data from the remote server via the network in response to transmitting the first data to the remote server. The instructions configure the processor to operate the substrate processing system according to the second data in an automated or autonomous manner.