Apparatus and methods for forming and using internally divisible physical vapor deposition (PVD) process chambers using shutter disks are provided herein. In some embodiments, an internally divisible process chamber may include an upper chamber portion having a conical shield, a conical adaptor, a cover ring, and a target, a lower chamber portion having a substrate support having inner and outer deposition rings, and wherein the substrate support is vertically movable, and a shutter disk assembly configured to internally divide the process chamber and create a separate sealed deposition cavity and a separate sealed oxidation cavity, wherein the shutter disk assembly includes one or more seals disposed along its outer edges and configured to contact at least one of the conical shield, the conical adaptor, or the deposition rings to form the separate sealed deposition and oxidation cavities.

A substrate processing apparatus includes a placing table configured to hold a substrate having a processing target film, which is decomposed by irradiating an ultraviolet ray thereto under an oxygen-containing atmosphere; a processing chamber, configured to accommodate therein the substrate placed on the placing table, having therein the oxygen-containing atmosphere; and an ultraviolet ray irradiation device configured to irradiate the ultraviolet ray to the substrate within the processing chamber. Further, the placing table is provided with a surrounding member configured to surround the substrate placed on the placing table and restrict a gas introduction amount from an outside of the substrate toward above the substrate.

A transfer path is provided which is extended so as to be passed on a lateral side of a processing portion that processes a substrate. The substrate transferred between a container held by a holding unit and the processing portion passes through the transfer path. A first transfer robot carries the substrate into and out of the container held by the holding unit, and accesses a reception/delivery region arranged within the transfer path. A second transfer robot receives and delivers the substrate from and to the first transfer robot in the reception/delivery region, and carries the substrate into and out of the processing portion. A second transfer robot raising/lowering unit which raises and lowers the second transfer robot is arranged within the transfer path. The reception/delivery region and the second transfer robot raising/lowering unit are located between the first transfer robot and the second transfer robot.

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 substrate processing apparatus includes a base portion 1541 that is disposed in a manner of being adjacent to a chamber; a hand 155 that holds a substrate S; an arm 1542 that is attached to the base portion 1541, supports the hand, and moves the hand forward and rearward by horizontally moving the hand with respect to the base portion; and a cover portion 156 that accommodates the hand in an internal space. The cover portion has a cover main body 1561 forming the internal space and an extending member 1562 having a hollow structure which penetrates the cover portion in a horizontal direction and of which one end serves as an opening 1562a and being engaged with the cover main body in a state of being movable in the horizontal direction while the opening communicates with the internal space.

Apparatus and methods for forming and using internally divisible physical vapor deposition (PVD) process chambers using shutter disks are provided herein. In some embodiments, an internally divisible process chamber may include an upper chamber portion having a conical shield, a conical adaptor, a cover ring, and a target, a lower chamber portion having a substrate support having inner and outer deposition rings, and wherein the substrate support is vertically movable, and a shutter disk assembly configured to internally divide the process chamber and create a separate sealed deposition cavity and a separate sealed oxidation cavity, wherein the shutter disk assembly includes one or more seals disposed along its outer edges and configured to contact at least one of the conical shield, the conical adaptor, or the deposition rings to form the separate sealed deposition and oxidation cavities.

A method and apparatus for substrate processing and a cluster tool including a transfer chamber assembly and a plurality of processing assemblies. Processing chamber volumes are sealed from the transfer chamber volume using a support chuck on which a substrate is disposed. A seal ring assembly is coupled to the support chuck. The seal ring assembly includes an inner assembly, an assembly bellows circumscribing the inner assembly, and a bellows disposed between the inner and outer platform. An inner ring is disposed between inner assembly of the seal ring assembly and the bottom surface of the support chuck. An outer ring disposed between the seal ring assembly and the lower sealing surface of the process chamber wall. The support chuck is raised to form an isolation seal between the processing chamber volume and the transfer chamber volume using the bellows, the inner ring, and the outer ring.

A substrate cleaning and drying system includes a cleaning station, a drying station positioned adjacent the cleaning station, a cleaner robot to transfer a substrate from the cleaning station to the drying station, an aligner stage adjacent to the drying station, a robot arm rotatable between a substantially vertical first position for receiving the substrate from the drying station and a substantially horizontal second position for releasing the substrate onto the aligner stage, and a factory interface robot to transfer a substrate from the aligner stage into a factory interface module while in a horizontal orientation. The aligner stage includes a rotatable support to hold the substrate in a substantially horizontal orientation and to rotate the substrate to a desired orientation.

A substrate cleaning and drying system includes a cleaning station, a drying station positioned adjacent the cleaning station, a cleaner robot to transfer a substrate from the cleaning station to the drying station, an aligner stage adjacent to the drying station, a robot arm rotatable between a substantially vertical first position for receiving the substrate from the drying station and a substantially horizontal second position for releasing the substrate onto the aligner stage, and a factory interface robot to transfer a substrate from the aligner stage into a factory interface module while in a horizontal orientation. The aligner stage includes a rotatable support to hold the substrate in a substantially horizontal orientation and to rotate the substrate to a desired orientation.

A substrate cleaning system includes a cleaner module to clean a substrate after polishing of the substrate, a drier module to dry the substrate after cleaning by the cleaner module, a substrate support movable along a first axis from a first position in the drier module to a second position outside the drier module, and an in-line metrology station including a line-scan camera positioned to scan the substrate as the substrate is held by the substrate support and the substrate support is between the first position to the second position. The first axis is substantially parallel to a face of the substrate as held in by the substrate support.