Abstract: A substrate processing system includes a factory interface, a transfer chamber, and a robot. The transfer chamber includes four first facets adapted for attachment to one or more first processing chambers and three second facets, wherein each of the three second facets has a width that is narrower than that of each of the four first facets. The system includes a second processing chamber having a first interface attached to a first of the three second facets and a load lock attached to a second of the three second facets and to the factory interface. The system also includes a robot attached to a bottom of the transfer chamber, the robot adapted to transfer substrates to and from the one or more first processing chambers, the second processing chamber, and the load lock.

Abstract: Electronic device processing systems including environmental control of the factory interface, a carrier purge chamber, and one or more substrate carriers are described. One electronic device processing system has a factory interface having a factory interface chamber, one or more substrate carriers coupled to the factory interface, and an environmental control system coupled to the factory interface, the carrier purge chamber, and the one or more substrate carriers and operational to control an environment at least within the factory interface chamber, carrier purge chamber, and the one or more substrate carriers. Methods for processing substrates are described, as are numerous other aspects.

Abstract: A transfer chamber configured to be used during semiconductor device manufacturing is described. Transfer chamber includes at least one first side of a first width configured to couple to one or more substrate transfer units (e.g., one or more load locks or one or more pass-through units), and at least a second set of sides of a second width that is different than the first width, the second set of sides configured to couple to one or more processing chambers. A total number of sides of the transfer chamber is at least seven. Transfers within the transfer chamber are serviceable by a single robot. Process tools and methods for processing substrates are described, as are numerous other aspects.

Abstract: An equipment front end module (EFEM) includes sidewalls forming an EFEM chamber configured to receive inert gas from an inert gas supply. The sidewalls include a first sidewall configured to attach to a panel first side of a panel. The panel forms a panel opening extending between the panel first side and a panel second side. The panel second side is configured to attach to a side storage pod. The EFEM further includes a robot disposed in the EFEM chamber. The robot is configured to transfer substrates from the EFEM chamber into the side storage pod via the panel opening. An exhaust conduit is coupled to the side storage pod to exhaust gas from the side storage pod to an exterior of the side storage pod.

Abstract: Electronic device processing systems including side storage pods are described. One electronic device processing system has a side storage pod having a first chamber configured to receive a side storage container; a panel having a panel opening; the panel configured to be coupled between a side storage container and an equipment front end module; a side storage container received in the first chamber; and an exhaust conduit configured to be coupled to the side storage container received and extending to an exterior of the first chamber.

Abstract: A load lock door assembly with side actuation is disclosed. Load lock door assembly includes a load lock door and a door support assembly coupled thereto. Door support assembly includes one or more pivot members pivotable relative to one or more sides of the load lock body, a door support bracket coupled to the load lock door, one or more separator side actuators coupled between the door support bracket being actuatable to separate the load lock door from a sealing surface, and one or more pivot side actuator operable to pivot the load lock door above or below the load lock entry. Load lock apparatus with side actuation, systems including one or more load lock door assemblies with side actuation, and methods of operating load lock door assemblies are provided, as are numerous other aspects.

Abstract: Electronic device manufacturing systems may include an equipment front end module (EFEM) having a load port assembly configured to receiving a substrate carrier, which may be a front opening unified pod (FOUP). The load port assembly may have a receiving plate upon which the substrate carrier may be received. The receiving plate may have a plurality of gas nozzles that can be coupled to purge ports in a bottom of the substrate carrier and to a purge apparatus of the load port assembly. The purge apparatus is configured to provide a gas to the substrate carrier at a selectable gas flow rate and, in some embodiments, to provide a gas to different portions of the substrate carrier each at a selectable gas flow rate. Methods of providing selectable gas flow rates for purging a substrate carrier coupled to a load port assembly are also provided, as are other aspects.

Abstract: In some embodiments, a side storage pod apparatus of an equipment front end module (EFEM) includes a side storage enclosure having a surface configured to couple to a side wall of a body of the equipment front end module, and an opening configured to receive substrates from the equipment front end module. The EFEM further includes a side storage chamber within the side storage enclosure having a plurality of support members configured to support substrates thereon. The EFEM further includes a plenum chamber provided proximate the side storage chamber, the plenum chamber being a separate chamber from the side storage chamber and an exhaust port coupled to the plenum chamber.

Abstract: Electronic device processing systems including an equipment front end module with at least one side storage pod are described. The side storage pod has a chamber including a top substrate holder and a bottom substrate holder. In some embodiments, an exhaust port is located at a midpoint between the top substrate holder and the bottom substrate holder. Methods and systems in accordance with these and other embodiments are also disclosed.

Abstract: Electronic device processing systems including an equipment front end module with at least one side storage pod are described. The side storage pod has a side storage container and a container plenum. A fan draws purge gas from the equipment front end module chamber into the container plenum where the purge gas is directed into the side storage container to pass over substrates stored therein and is then exhausted back into the equipment front end module chamber. Methods and systems are also disclosed.

Abstract: Electronic device processing assemblies including an equipment front end module (EFEM) with at least one side storage pod attached thereto are described. The side storage pod has a side storage container. In some embodiments, an exhaust conduit extends between the chamber and a pod plenum that can contain a chemical filter proximate thereto. A supplemental fan may draw purge gas from the pod plenum through the chemical filter and route the gas through a return duct to an upper plenum of the EFEM. Methods and side storage pods in accordance with these and other embodiments are also disclosed.

Abstract: A factory interface for an electronic device processing system includes a factory interface chamber, an inert gas supply conduit, an exhaust conduit and an inert gas recirculation system. The inert gas supply conduit supplies an inert gas into the factory interface chamber. The exhaust conduit exhausts the inert gas from the factory interface chamber. The inert gas recirculation system recirculates the inert gas exhausted from the factory interface chamber back into the factory interface chamber.

Abstract: Electronic device processing apparatus including a factory interface chamber purge apparatus with purge gas heating. The factory interface chamber purge apparatus includes one or more heating elements configured to heat the purge gas. In some embodiments, the provision of heated purge gas to the chamber filter assembly can rapidly reduce moisture contamination after the access door is opened for factory interface servicing. In further embodiments, the provision of heated purge gas to the factory interface chamber can aid in desorbing certain chemical compounds from the substrates following processing when a low-humidity environment is provided. Purge control methods and apparatus are described, as are numerous other aspects.

Abstract: Electronic device processing systems including environmental control of the factory interface, a carrier purge chamber, and one or more substrate carriers are described. One electronic device processing system has a factory interface having a factory interface chamber, one or more substrate carriers coupled to the factory interface, and an environmental control system coupled to the factory interface, the carrier purge chamber, and the one or more substrate carriers and operational to control an environment at least within the factory interface chamber, carrier purge chamber, and the one or more substrate carriers. Methods for processing substrates are described, as are numerous other aspects.

Abstract: Electronic device processing systems including side storage pods are described. One electronic device processing system has a side storage pod having a first chamber configured to receive a side storage container; a panel having a panel opening; the panel configured to be coupled between a side storage container and an equipment front end module; a side storage container received in the first chamber; and an exhaust conduit configured to be coupled to the side storage container received and extending to an exterior of the first chamber.

Abstract: Electronic device processing systems including side storage pods are described. One electronic device processing system has a side storage pod having a first chamber configured to receive a side storage container; a panel having a panel opening; the panel configured to be coupled between a side storage container and an equipment front end module; a side storage container received in the first chamber; and an exhaust conduit configured to be coupled to the side storage container received and extending to an exterior of the first chamber.

Abstract: Electronic device processing systems including environmental control of the factory interface, a carrier purge chamber, and one or more substrate carriers are described. One electronic device processing system has a factory interface having a factory interface chamber, one or more substrate carriers coupled to the factory interface, and an environmental control system coupled to the factory interface, the carrier purge chamber, and the one or more substrate carriers and operational to control an environment at least within the factory interface chamber, carrier purge chamber, and the one or more substrate carriers. Methods for processing substrates are described, as are numerous other aspects.

Abstract: A load lock door assembly with side actuation is disclosed. Load lock door assembly includes a load lock door and a door support assembly coupled thereto. Door support assembly includes one or more pivot members pivotable relative to one or more sides of the load lock body, a door support bracket coupled to the load lock door, one or more separator side actuators coupled between the door support bracket being actuatable to separate the load lock door from a sealing surface, and one or more pivot side actuator operable to pivot the load lock door above or below the load lock entry. Load lock apparatus with side actuation, systems including one or more load lock door assemblies with side actuation, and methods of operating load lock door assemblies are provided, as are numerous other aspects.

Abstract: A transfer chamber configured to be used during semiconductor device manufacturing is described. Transfer chamber includes at least one first side of a first width configured to couple to one or more substrate transfer units (e.g., one or more load locks or one or more pass-through units), and at least a second set of sides of a second width that is different than the first width, the second set of sides configured to couple to one or more processing chambers. A total number of sides of the transfer chamber is at least seven. Transfers within the transfer chamber are serviceable by a single robot. Process tools and methods for processing substrates are described, as are numerous other aspects.

Abstract: A load lock door assembly with side actuation is disclosed. Load lock door assembly includes a load lock door and a door support assembly coupled thereto. Door support assembly includes one or more pivot members pivotable relative to one or more sides of the load lock body, a door support bracket coupled to the load lock door, one or more separator side actuators coupled between the door support bracket being actuatable to separate the load lock door from a sealing surface, and one or more pivot side actuator operable to pivot the load lock door above or below the load lock entry. Load lock apparatus with side actuation, systems including one or more load lock door assemblies with side actuation, and methods of operating load lock door assemblies are provided, as are numerous other aspects.