A turnaround mechanism of silicon wafers is provided. The turnaround mechanism includes a material frame, a supporting component, a second clamping component. The frame is provided with a material tank. The supporting component includes at least one first clamping component, and each of the at least one first clamping component is configured to clamp or release a support. The second clamping component includes two first rotating shafts disposed oppositely and two second clamping members, the two first rotating shafts are rotatably connected to the material frame, the two second clamping members are correspondingly disposed on the two first rotating shafts respectively, and each of the two second clamping members can rotate with a corresponding first rotating shaft, enabling the two second clamping members to move toward each other to clamp the silicon wafers to be separated.

The present disclosure provides a transfer apparatus and a processing system. The transfer apparatus includes a first transfer assembly configured to transfer a first workpiece to a chamber. The transfer apparatus includes a second transfer assembly configured to transfer a second workpiece from the chamber. The transfer apparatus includes an isolation assembly disposed between the first transfer assembly and the second transfer assembly and configured to isolate energy transfer between the first workpiece and the second workpiece. The transfer apparatus further includes a support assembly configured to restrict the isolation assembly between the first transfer assembly and the second transfer assembly.

A resin molding apparatus including a release film feeder configured to feed a release film is provided. The release film feeder including a feeding roller around which the release film is wound, a gripper configured to grip an end portion of the release film fed from the feeding roller, a support table configured to support the release film fed by a horizontal movement of the gripper in an X direction, the support table configured to horizontally move at least one of in the X direction or in a Y direction perpendicular to the X direction, the X and Y directions defining a surface parallel to a surface of the support table, and a position detecting sensor on the support table and configured to detect position information of the release film may be provided.

A substrate handling chamber body is formed from a castable aluminum alloy including a manganese (Mn) constituent and an iron (Fe) constituent. The castable aluminum alloy has a manganese (Mn) constituent-to-iron (Fe) constituent ratio that between about 1.125 and about 1.525 to limit microporosity and shrinkage porosity within the castable aluminum alloy forming the substrate handling chamber body. Semiconductor processing systems and methods of making substrate handling chamber bodies for semiconductor processing systems are also described.

A conveyance apparatus for conveying a substrate chuck includes a hand for supporting the substrate chuck, a main body for pivotally supporting the hand about a vertical axis and movable in horizontal and vertical directions, and a guiding portion for guiding pivotal motion of the hand. The hand includes hand distal end portions and a hand proximal end portion supported by the main body. An end surface of the hand proximal end portion facing the main body is formed in an arc shape of a circle centered about a vertical axis of a reference position between the hand distal end portions. The guiding portion includes a guiding surface that has a shape corresponding to the end surface of the hand proximal end portion and can slidably contact the end surface.

A transfer apparatus including a frame, multiple arms connected to the frame, each arm having an end effector and an independent drive axis for extension and retraction of the respective arm with respect to other ones of the multiple arms, a linear rail defining a degree of freedom for the independent drive axis for extension and retraction of at least one arm, and a common drive axis shared by each arm and configured to pivot the multiple arms about a common pivot axis, wherein at least one of the multiple arms having another drive axis defining an independent degree of freedom with respect to other ones of the multiple arms.

A method includes transferring a wafer to a position over a wafer chuck; ejecting a first gas from a purging device above the wafer to clean a top surface of the wafer; after ejecting the first gas, lifting a lifting pin through the wafer chuck to receive the wafer; and after the wafer is received by the lifting pin, ejecting a second gas from first openings in a sidewall of the lifting pin to a region between a bottom surface of the wafer and a top surface of the wafer chuck.

In an embodiment, a system includes: a tool port of a semiconductor processing tool; a processing port with an internal processing port location and an external processing port location; a robot configured to move a die vessel between the internal processing port location and the tool port; and an actuator configured to move the die vessel between the internal processing port location and the external processing port location.

Disclosed is a method for processing a substrate, comprising a liquid processing step of performing liquid processing on the substrate by supplying a processing liquid onto the substrate in a liquid processing chamber, a transfer step of transferring the substrate from the liquid processing chamber to a drying chamber, and a drying step of drying the substrate in the drying chamber. In the drying step, the substrate is dried while an edge region of the substrate other than a central region of the substrate is supported by a support unit, and in the liquid processing step, the liquid processing is performed on the substrate such that a height of the processing liquid remaining on the edge region of the substrate is greater than a height of the processing liquid remaining on the central region of the substrate when the liquid processing is completed in the liquid processing chamber.

A substrate transfer system includes a load lock module, an atmospheric transfer module having a first sidewall adjacent to the load lock module and a second sidewall remote from the load lock module, the atmospheric transfer module being connected to the load lock module, and a substrate transfer robot disposed in the atmospheric transfer module. The substrate transfer robot includes a base configured to reciprocate along the first sidewall, a substrate transfer arm disposed on the base, and a flow rectifier surrounding the base, the flow rectifier being configured, upon movement of the base, to create an obliquely downward air flow in a direction opposite to a moving direction of the base.