Disclosed are implementations for efficient purging of substrate carriers (and content held therein) and preventing external contaminants from entering a gas purge apparatus by coupling the gas purge apparatus to a substrate carrier, performing a first gas purging session of an environment of the substrate carrier, receiving a first signal of a first signal type, responsive to receiving the first signal, keeping the gas purge apparatus coupled to the substrate carrier, performing a second gas purging session of the environment of the substrate carrier, receiving a second signal of a second signal type, and, responsive to receiving the second signal, decoupling the purge apparatus from the substrate carrier.

A multiple die container load port may include a housing with an opening, and an elevator to accommodate a plurality of different sized die containers. The multiple die container load port may include a stage supported by the housing and moveable within the opening of the housing by the elevator. The stage may include one or more positioning mechanisms to facilitate positioning of the plurality of different sized die containers on the stage, and may include different portions movable by the elevator to accommodate the plurality of different sized die containers. The multiple die container load port may include a position sensor to identify one of the plurality of different sized die containers positioned on the stage.

A load port adapted for wafer cassettes of different sizes detects storage states of wafers stored in the wafer cassettes. The load port includes a body, a positioning mechanism, a sensing mechanism, and a detecting mechanism. The body has a carrier base. The positioning mechanism is disposed on the body and has a positioning unit disposed on the carrier base, a hooking unit, and a limiting unit. The hooking unit is disposed in the body and has a driving assembly and a hooking element. The driving assembly is disposed in the body. The hooking element is mounted to the driving assembly. The sensing mechanism is disposed on the carrier base. The detecting mechanism is disposed on the body, detects the storage states of wafers stored in the wafer cassette, and has a first detecting assembly and a second detecting assembly spaced apart from each other.

A carrier door opener includes one or more connector devices configured to interface with a door of a substrate carrier located at a load port. The carrier door opener further includes an outer surface forming a groove and a load port seal seated in the groove. The load port seal is configured to seal against a first portion of a planar surface of a panel of the load port around a panel opening formed by the panel. A second portion of the planar surface of the panel is configured to seal to a factory interface.

In some embodiments, a side storage pod of an equipment front end module is provided that includes (1) an outer enclosure having a sealing surface configured to couple to the equipment front end module; (2) a side storage pod chamber having a body with a plurality of vertically-spaced storage members each configured to support a substrate; and (3) an indexer operable to vertically move the side storage pod chamber so that different subgroups of storage members are accessible by a load-unload robot in the equipment front end module. In other embodiments, a heated side storage pod is provided enabling degassing of substrates stored therein. Methods for processing substrates are described, as are numerous other aspects.

A load port of a factory interface of an electronic device manufacturing system can include a purge apparats, a docking tray configured to receive a substrate carrier including a substrate carrier door and a substrate carrier housing, a backplane located adjacent to the docking tray, and a carrier door configured to seal an opening in the backplane when the carrier door opener is closed. The carrier door opener can include an inlet gas line therethrough that is coupled to one or more components of the purge apparatus. The load port can also include a controller that is configured to detect that the substrate carrier is placed in a docking position on the docking tray. The substrate carrier placed in the docking position on the docking tray can form a gap between the substrate carrier housing and the backplane. The controller can also purge a space between the carrier door and the carrier housing and/or an area between the carrier door and the carrier door opener via the inlet gas line and the gap between the substrate carrier housing and the backplane. The controller can cause the purge apparatus to stop the purge and close the gap between the substrate carrier housing and the backplane.

A system comprises a factory interface (FI) comprising an FI chamber and a carrier purge chamber, the FI configured to receive a substrate carrier that becomes coupled to the FI such that the carrier purge chamber is positioned between the FI chamber and the substrate carrier, the substrate carrier comprising a carrier door. The system further comprises an environmental control system coupled to at least one of the FI chamber or the carrier purge chamber and configured to couple to the substrate carrier, the environmental control system operable to separately control environmental conditions within at least one of: the carrier purge chamber and the substrate carrier; the carrier purge chamber and the FI chamber; or the FI chamber and the substrate carrier, while the carrier door of the substrate carrier is closed.

The disclosure relates to a semiconductor processing system for processing semiconductor substrates and provided with a housing formed by a wall. The system may further comprise a processing module and a cassette module, the cassette module located adjacent the processing module. An electronics module may be provided with a support for mounting electronic components, whereby the electronics module is located behind a door in the wall of the system to create access for maintenance. The electronic components have a straight mounting basis for mounting of the electronics components whereby the mounting basis is mounted in the system under an angle between 10 and 80 degrees with respect to the door when the door is closed.

A multiple transport carrier docking device may be capable of storing and/or staging a plurality of transport carriers in a chamber of the multiple transport carrier docking device, and may be capable of forming an air-tight seal around a transport carrier in the chamber. Semiconductor wafers in the transport carrier may be accessed by a wafer transport tool while the air-tight seal around the transport carrier prevents and/or reduces the likelihood that contaminants in the semiconductor fabrication facility will reach the semiconductor wafers. The air-tight seal around the transport carrier may reduce defects of the semiconductor wafers that might otherwise be caused by the contaminants, may increase manufacturing yield and quality in the semiconductor fabrication facility, and/or may permit the continued reduction in device and/or feature sizes of integrated circuits and/or semiconductor devices that are to be formed on semiconductor wafers.

Apparatus and methods for handling die carriers are disclosed. In one example, a disclosed apparatus includes: a load port configured to load a die carrier operable to hold a plurality of dies into a processing tool; and a lane changer coupled to the load port and configured to move at least one die in the die carrier to an input of the processing tool and transfer the at least one die into the processing tool for processing the at least one die.