A carrier FOUP and a method of placing a carrier are provided. The carrier FOUP includes a body and a door. The body includes a plurality of chamfers, and one or more carriers are placed on, and supported by, the plurality of chamfers. The method of placing a carrier includes placing the carrier in the carrier FOUP and closing the door of the carrier FOUP. When the door is closed, the door pushes against the carrier and aligns the carrier with the alignment feature. The alignment features align the carrier, removing the need to be aligned by the factory interface robot when placing or removing the carrier from the carrier FOUP.

Disclosed is a substrate treating apparatus. The substrate treating apparatus includes an index unit including a load pot, in which a container is seated, and an index chamber connected to the load pot, and a process executing unit having a load lock chamber connected to the index chamber and a process chamber that treats a substrate transferred to the load lock chamber, the index unit further includes an alignment unit provided in the index chamber and that aligns a substrate type sensor transferred to the process chamber.

An apparatus includes a first portion and a second portion. The first portion includes a first front side wall, a first rear side wall, a top wall, and at least one pivotal pin structure extending from the first rear side wall. The at least one pivotal pin structure comprises a base, a shaft, and a head having a non-circular cross-sectional shape. The second portion includes a second front side wall, a second rear side wall, a bottom wall, and at least one pin holder extending from the second rear side wall. The at least one pin holder defines an opening for accepting the head of the at least one pivotal pin structure at an alignment. The head of the at least one pivotal pin structure extends through the opening. The first portion and the second portion are pivotally movable between an open configuration and a closed container configuration.

A method includes: inspecting a reticle in a reticle pod, the reticle pod including a sealed space to accommodate the reticle, and the reticle pod further comprising a window arranged on an upper surface of the reticle pod, wherein the inspecting is performed through the window; and moving the reticle out of the reticle pod for performing a lithography operation using the reticle.

A wafer container includes a pod, a door, a wafer cassette with a top wall, a baseplate, and a biasing member. The pod includes side wall(s), a closed end, and an open end. When closed by the door, the baseplate is located between the door and the wafer cassette and the biasing member is compressed between the wafer cassette and the closed end of the pod. A size adaption system for securing a wafer cassette within an internal space of a closed pod includes a baseplate and a biasing member. The baseplate includes at least one of a projection for coupling the baseplate and the wafer cassette and a notch for coupling the baseplate and the door. The biasing member to be disposed in compression between the wafer cassette and a closed end of the pod.

Described are substrate containers that include an opening, a door to close the opening, and a gasket to seal the opening with the door placed over the opening.

A wafer storage container and a cap assembly according to an embodiment include a storage container having a space accommodating at least one wafer therein, a fastening portion having a fastening space capable of fastening a cap, and the cap having a locking portion which is formed linearly on a first side of the cap and which has an end portion provided with a first protrusion portion, the cap being configured in a structure in which the locking portion is fastened to the fastening portion. The fastening portion includes an inner wall, and a fastening hole which is formed in a first side of the fastening portion such that the locking portion is fastened thereto. The cap includes a fixing wall in close contact with the inner wall, thereby fixing the cap to the fastening portion.

A side storage pod includes an outer enclosure having a sealing surface configured to couple to an EFEM and a side storage pod chamber having a body coupled to vertically-spaced storage members. Each of the vertically-spaced storage members is configured to support a corresponding substrate within the body. The side storage pod further includes a removable door. The removable door and the body are to seal relative to each other responsive to the removable door being in a closed position. A load-unload robot of the EFEM is to access the vertically-spaced storage members responsive to the removable door being in an open position. An environment within the side storage pod chamber is to be controlled to be one or more of: at first environmental conditions responsive to the removable door being in the closed position; or at second environmental conditions responsive to the removable door being in the open position.

A system for storing wafer is provided. The system includes a wafer box, an installing member, a detection tube, a control unit, and a detection unit. The wafer box includes an outlet connector and an inlet connector extending a wall of the wafer box. The installing member covers the wafer box to form a sealed receiving room. Two ends of the detection tube are coupled to the outlet connector and the inlet connector. The control unit are configured to output a first control signal to the detection unit. The detection unit includes a first sensor arranged in the detection tube. The first sensor is configured to detect a property of gas to obtain data of an environment where the wafer is stored upon the first control signal. A related system for monitoring pollution of wafer is also provided.

Proposed is an EFEM configured to perform wafer transfer between a wafer storage device and process equipment. More particularly, proposed is an EFEM that prevents harmful gases inside a transfer chamber in which wafer transfer is performed from escaping out of the EFEM.