Abstract: Apparatus and methods to process one or more wafers are described. A plurality of process stations are arranged in a circular configuration around a rotational axis. A support assembly with a rotatable center base defining a rotational axis, at least two support arms extending from the center base and heaters on each of the support arms is positioned adjacent the processing stations so that the heaters can be moved amongst the various process stations to perform one or more process condition.

Abstract: An electronic device manufacturing system includes a mainframe including a transfer chamber and facets defining side walls of the transfer chamber. The facets include first facet, second facet, third facet, and fourth facet that form the transfer chamber. The first facet has a first number of substrate access ports. The second facet has a second number of substrate access ports. A first substrate access port of the first facet has a first side dimension and a second substrate access port of the second facet has a second side dimension that is different from the first side dimension. The second facet is adjacent to the first facet. The third facet is adjacent to the second facet. The fourth facet has the second number of substrate access ports. The second number of substrate access ports is different than the first number of substrate access ports.

Abstract: A semiconductor processing system includes a first component forming a first chamber. A first sealed environment in the first chamber is at a first state prior to a door being opened. A load port structure is disposed between the first component and a second component. The load port structure includes walls disposed around an opening of the load port structure. The load port structure is separate from the first component and the second component. A third component is configured to change at least one of the first state of the first sealed environment within the first chamber or a second state of a second sealed environment within a second chamber formed by the second component to cause the first state and the second state to be substantially similar before the door between the first sealed environment and the second sealed environment is opened.

Abstract: A semiconductor processing system includes a first component and a second component. The first component forms a first chamber with a first sealed environment at a first state within the first chamber. The second component is coupled to the first component. The second component forms a second chamber with a second sealed environment at a second state within the second chamber. A third component is to change the first state of the first sealed environment within the first chamber to cause the first state to be substantially similar to the second state of the second sealed environment within the second chamber. The second sealed environment is at the second state prior to changing of the first state of the first sealed environment to be substantially similar to the second state.

Abstract: An electronic device manufacturing system includes a mainframe that includes a first transfer chamber and facets defining first side walls of the first transfer chamber. The facets include a first facet that has a first number of substrate access ports, a second facet that has a second number of substrate access ports, and a third facet that has the second number of substrate access ports. The second number of substrate access ports is different than the first number of substrate access ports.

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 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: 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 transfer chamber for semiconductor device manufacturing includes (1) a plurality of sides that define a region configured to maintain a vacuum level and allow transport of substrates between processing chambers, the plurality of sides defining a first portion and a second portion of the transfer chamber and including (a) a first side that couples to two twinned processing chambers; and (b) a second side that couples to a single processing chamber; (2) a first substrate handler located in the first portion of the transfer chamber; (3) a second substrate handler located in the second portion of the transfer chamber; and (4) a hand-off location configured to allow substrates to be passed between the first portion and the second portion of the transfer chamber using the first and second substrate handlers. Method aspects are also provided.

Abstract: An electronic device manufacturing system includes a mainframe that includes a first transfer chamber and facets defining first side walls of the first transfer chamber. The facets include a first facet that has a first number of substrate access ports, a second facet that has a second number of substrate access ports, and a third facet that has the second number of substrate access ports. The second number of substrate access ports is different than the first number of substrate access ports.

Abstract: A semiconductor processing system includes a first component and a second component. The first component forms a first chamber with a first sealed environment at a first state within the first chamber. The second component is coupled to the first component. The second component forms a second chamber with a second sealed environment at a second state within the second chamber. A third component is to change the first state of the first sealed environment within the first chamber to cause the first state to be substantially similar to the second state of the second sealed environment within the second chamber. The second sealed environment is at the second state prior to changing of the first state of the first sealed environment to be substantially similar to the second state.

Abstract: An electronic device manufacturing system may include a mainframe to which one or more process chambers of different size may be coupled. A different number of process chambers may be coupled to each facet (i.e., side wall) of the mainframe. The process chambers coupled to one facet may be of a different size than process chambers coupled to other facets. For example, one process chamber of a first size may be coupled to a first facet, two process chambers each of a second size different than the first size may be coupled to a second facet, and three process chambers each of a third size different than the first and second sizes may be coupled to a third facet. Other configurations are possible. The mainframe may have a square or rectangular shape. Methods of assembling an electronic device manufacturing system are also provided, as are other aspects.

Abstract: An electronic device manufacturing system is disclosed. The system includes a processing tool having one or more processing chambers each adapted to perform an electronic device manufacturing process on one or more substrates; a substrate carrier adapted to couple to the system and carry one or more substrates; and a component adapted to create a sealed environment relative to at least a portion of the substrate carrier and to substantially equalize the sealed environment with an environment within the substrate carrier. Methods of the invention 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: A transfer chamber for semiconductor device manufacturing includes (1) a plurality of sides that define a region configured to maintain a vacuum level and allow transport of substrates between processing chambers, the plurality of sides defining a first portion and a second portion of the transfer chamber and including (a) a first side that couples to two twinned processing chambers; and (b) a second side that couples to a single processing chamber; (2) a first substrate handler located in the first portion of the transfer chamber; (3) a second substrate handler located in the second portion of the transfer chamber; and (4) a hand-off location configured to allow substrates to be passed between the first portion and the second portion of the transfer chamber using the first and second substrate handlers. Method aspects are also provided.

Abstract: An electronic device manufacturing system is disclosed. The system includes a processing tool having one or more processing chambers each adapted to perform an electronic device manufacturing process on one or more substrates; a substrate carrier adapted to couple to the system and carry one or more substrates; and a component adapted to create a sealed environment relative to at least a portion of the substrate carrier and to substantially equalize the sealed environment with an environment within the substrate carrier. Methods of the invention are described as are numerous other aspects.

Abstract: An electronic device manufacturing system is disclosed. The system includes a processing tool having one or more processing chambers each adapted to perform an electronic device manufacturing process on one or more substrates; a substrate carrier adapted to couple to the system and carry one or more substrates; and a component adapted to create a sealed environment relative to at least a portion of the substrate carrier and to substantially equalize the sealed environment with an environment within the substrate carrier. Methods of the invention are described as are numerous other aspects.

Abstract: An electronic device manufacturing system may include a mainframe to which one or more process chambers of different size may be coupled. A different number of process chambers may be coupled to each facet (i.e., side wall) of the mainframe. The process chambers coupled to one facet may be of a different size than process chambers coupled to other facets. For example, one process chamber of a first size may be coupled to a first facet, two process chambers each of a second size different than the first size may be coupled to a second facet, and three process chambers each of a third size different than the first and second sizes may be coupled to a third facet. Other configurations are possible. The mainframe may have a square or rectangular shape. Methods of assembling an electronic device manufacturing system are also provided, as are other aspects.

Abstract: An electronic device manufacturing system may include a mainframe to which one or more process chambers of different size may be coupled. A different number of process chambers may be coupled to each facet (i.e., side wall) of the mainframe. The process chambers coupled to one facet may be of a different size than process chambers coupled to other facets. For example, one process chamber of a first size may be coupled to a first facet, two process chambers each of a second size different than the first size may be coupled to a second facet, and three process chambers each of a third size different than the first and second sizes may be coupled to a third facet. Other configurations are possible. The mainframe may have a square or rectangular shape. Methods of assembling an electronic device manufacturing system are also provided, as are 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.