The instant disclosure discloses a container system, comprising an inner base, configured to receive a workpiece, the inner base including a first treatment area that corresponds to a workpiece accommodating region, a second treatment area arranged around the first treatment area of the inner base, and a workpiece supporting post arranged at a border region between the first treatment area and the second treatment area.

A carrier device that carries a substrate to a noncontact holder that is configured to support the substrate in a noncontact manner is equipped with: holding pads that hold a part of the substrate at a first position located above the noncontact holder; a drive section that moves downward the holding pads holding the substrate so that the substrate is supported in a noncontact manner by the noncontact holder; and adsorption pads that hold the substrate supported in a noncontact manner by the noncontact holder, after the substrate held by the holding pads is moved by the drive section, wherein the drive section moves the holding pads from the first position to a second position where the substrate can be delivered to the adsorption pads.

The present invention provides a substrate processing apparatus that processes a substrate, the apparatus including a stage configured to hold and move the substrate, a conveying unit configured to hold and convey the substrate between conveying unit and the stage, an accumulation unit configured to accumulate control information concerning the stage and the conveying unit which is generated by processing the substrate, and a determination unit configured to determine a conveying procedure when conveying the substrate between the stage and the conveying unit by selecting one of a plurality of conveying procedures which can be set for the stage and the conveying unit based on control information accumulated in the accumulation unit.

The present invention provides a substrate processing apparatus that processes a substrate, the apparatus including a stage configured to hold and move the substrate, a conveying unit configured to hold and convey the substrate between conveying unit and the stage, an accumulation unit configured to accumulate control information concerning the stage and the conveying unit which is generated by processing the substrate, and a determination unit configured to determine a conveying procedure when conveying the substrate between the stage and the conveying unit by selecting one of a plurality of conveying procedures which can be set for the stage and the conveying unit based on control information accumulated in the accumulation unit.

The present disclosure generally relates to a method and apparatus for loading, processing, and unloading substrates. A processing system comprises a load/unload system coupled to a photolithography system. The load/unload system comprises a first set of tracks having a first height and a first width, and a second set of tracks having a second height and a second width different than the first height and first width. An unprocessed substrate is transferred from a lift pin loader to a chuck along the first set of tracks on a first tray while a processed substrate is transferred from the chuck to the lift pin loader along the second set of tracks on a second tray. While a first tray remains with a substrate on the chuck during processing, the load/unload system is configured to unload a processed substrate and load an unprocessed substrate on a second tray.

A system for a semiconductor fabrication facility includes a manufacturing tool including a load port, a maintenance crane, a rectangular zone overlapping with the load port of the manufacturing tool, a plurality of first sensors at corners of the rectangular zone, an OHT vehicle, a second sensor on the OHT vehicle, a third sensor on the load port, and a control unit. The first sensors are configured to detect a location of the maintenance crane and to generate a first location data. The second sensor is configured to generate a second location data. The control unit is configured to receive the first location data of the maintenance crane and the second location data of the OHT vehicle. The control unit further sends signals to the second sensor and the third sensor or to cut off the signal to the second sensor.

An apparatus includes: a treatment block including treatment modules; and a relay block coupling the treatment block and an exposure apparatus in a width direction, and including a transfer-in/out mechanism for the exposure apparatus; and in the treatment block being multilayered in an up-down direction, a transfer mechanism is provided in a transfer region extending in the width direction, and in a layer, in the treatment block, at a position accessible from the transfer-in/out mechanism, a deliverer on which the substrate is mounted when the substrate is delivered between the blocks is provided at an end on the relay block side, pre-exposure storages storing the substrate before the exposure are provided along the width direction in two regions between which the transfer region is interposed in a depth direction, and a non-treatment unit is provided at a portion where the pre-exposure storages are not provided in the two regions.

A reticle retaining system comprising an inner pod and an outer pod. The inner pod comprises an inner base and an inner cover configured to couple to the inner base thereby forming an interior for housing a received workpiece, and a hold down pin movably arranged through the inner cover and configured to press the received workpiece. The outer pod comprises an outer base configured to receive the inner base, an outer cover, and a pushing element. Wherein the hold down pin, the outer cover and the pushing element have charge dissipation property. When the pushing element pushes the hold down pin to press the workpiece, a charge dissipation path from the received workpiece, through the hold down pin and the pushing element, to the outer cover is established.

A lithographic apparatus includes a substrate table, a post-exposure handling module, a substrate handling robot and a drying station. The substrate table is configured to support a substrate for an exposure process. The post-exposure handling module is configured to handle the substrate post-exposure. The substrate handling robot is configured to transfer the substrate from the substrate table along a substrate unloading path into the post-exposure handling module. The drying station is configured to actively remove liquid from a surface of the substrate. The drying station is located in the substrate unloading path. The drying station is located in the post-exposure handling module. The post-exposure handling module may be a substrate handler.

A system for a semiconductor fabrication facility includes a maintenance tool, a control unit, a first track, a second track, a maintenance crane movably mounted on the first track, a plurality of first sensors disposed on the first track, an OHT vehicle movably mounted on the second track, and a second sensor on the OHT vehicle. The first sensors detect a location of the maintenance crane and generate a first location data to the control unit. The second sensor generates a second location data to the control unit.