A linearly moving mechanism includes an internal moving body provided within a case body and configured to be moved in a linear direction, the internal moving body being configured to move an external moving body connected to a connection member protruded from the case body through an opening formed at the case body; a seal belt extending in the linear direction and provided within the case body to close the opening, a first surface side of both end portions of the seal belt in a widthwise direction thereof facing an edge portion of the opening while being spaced apart therefrom; and a deformation suppressing member provided to face a second surface side of the both end portions to suppress deformation of the seal belt, the seal belt being connected to the internal moving body to be moved along with a movement of the internal moving body.

A reticle pod includes an inner portion that includes a cover and a baseplate, and an outer portion including a pod dome and a pod door. The pod door includes a latch, and one or more movable posts that may be driven to move when the latch is operated. The baseplate includes movable reticle contacts that may be contacted by the movable posts. Contact between the movable posts and the movable reticle contacts moves the movable reticle contacts in the baseplate towards the cover. This movement can secure the reticle within the reticle pod.

A method for forming at least one electrode, said method comprising: a) providing an electronically conductive, inert material; b) cutting the substrate material to form at least one current collector; c) placing at least one current collector on a carrier; d) applying one or more protection layers to one or both sides of the current collector to form a coated electrode; and e) removing the electrode from the carrier.

Provided is processing of a substrate including: forming film on substrate by performing cycle, multiple times, including non-simultaneously performing: (a) supplying precursor gas and inert gas to the substrate; and (b) supplying reaction gas to the substrate. In (a), at least one of the precursor and inert gas stored in first tank is supplied to the substrate, and at least one of the precursor and inert gas stored in second tank is supplied to the substrate. A concentration of the precursor gas in the first tank differs from that in the second tank. Further, in (a), the at least one of the precursor and inert gas is supplied from the first tank to the substrate, and the at least one of the precursor and inert gas is supplied from the second tank to the substrate to suppress multiple adsorption of molecules constituting the precursor gas on the substrate's surface.

A pre-jig wafer carrier disc installation/uninstallation device and a method thereof, including a first displacement mechanism, a wafer frame installation/uninstallation mechanism, a wafer installation/uninstallation mechanism, a mask installation/uninstallation mechanism and a robotic arm arranged around the first displacement mechanism. The said mechanisms sequentially stack the wafer frame, the wafer and the mask on the first displacement mechanism to form an assembly. An installation/uninstallation mechanism is disposed at a movable end of the robotic arm. The robotic arm drives the installation/uninstallation mechanism to remove and lock the assembly on an assembly carrier section of a carrier disc for successive processing. After the wafers are processed, the robotic arm drives the installation/uninstallation mechanism to move the assembly back onto the first displacement mechanism. The said mechanisms sequentially disassemble the assembly and recover the mask, the wafer and the wafer frame.

The present disclosure relates to the technical field of semiconductors, and provides a mask pod and a semiconductor device. The mask pod includes: a body, wherein the body has an accommodation space configured to accommodate a mask, the accommodation space has a first opening, and the first opening is located on a circumferential side of the body; and a shielding member, wherein the shielding member is provided on the body and is movably provided relative to the body, to shield or release the first opening.

A cassette with embedded temperature sensors that is disposed within a load lock is disclosed. The temperature sensors may be disposed in a plurality of shelves of the load lock cassette to monitor the temperature of each of a plurality of workpieces disposed in the load lock. The output of these temperature sensors may be provided to a controller, which controls when the load lock is opened. The load lock cassette may also include cooling channels to accelerate the cooling of the workpieces to improve throughput. The cooling may be controlled using closed loop control, where a controller monitors the temperature of the workpieces during the cooling operation.

A substrate storage apparatus includes a stage on which a cassette that has a lid detachably mounted to an opening is disposed, a lid attaching/detaching plate that performs attaching/detaching of the lid to/from the opening of the cassette disposed on the stage, and is provided to be movable between a mounting position in contact with the lid disposed at a position of the opening and a retracted position not in contact with the lid disposed at the position of the opening, a lid holding sensor that detects whether the lid is being held by the lid attaching/detaching plate, and a controller that determines presence/absence of abnormality related to attachment/detachment of the lid based on a detection result of the lid holding sensor.

An apparatus for automatically cleaning a nozzle of a gas supply system is provided. The apparatus includes a carrier with a gas inlet that is adapted to sealingly mate with the nozzle of the gas supply system and an automated nozzle cleaning system in the carrier. The automated nozzle cleaning system includes a first nozzle cleaning device, a second nozzle cleaning device, and a function switching plate. The function switching plate comprises a plurality of through holes, a first through hole of the plurality of through holes is configured to engage the first nozzle cleaning device with the gas inlet when the function switching plate is positioned at a first position, and a second through hole of the plurality of through holes is configured to engage the second nozzle cleaning device with the gas inlet when the function switching plate is positioned at a second position.

Exemplary substrate support assemblies may include a platen characterized by a first surface configured to support a semiconductor substrate. The assemblies may include a first stem section coupled with a second surface of the platen opposite the first surface of the platen. The assemblies may include a second stem section coupled with the first stem section. The second stem section may include a housing and a rod holder disposed within the housing. The second stem section may include a connector seated within the rod holder at a first end of the connector. The second stem section may include a heater rod disposed within the first end of the connector and a heater extension rod coupled with the connector at a second end of the connector. The second stem section may include an RF rod and an RF strap coupling the RF rod with an RF extension rod.