Abstract: In one aspect, a process operation is conducted at a first pressure in a process chamber, and an epitaxial deposition operation is conducted at an atmospheric pressure in an epitaxial deposition chamber. The atmospheric pressure is greater than the first pressure. The process chamber is mounted to a first mainframe that operates at the first pressure (a reduced pressure), and the epitaxial deposition chamber is mounted to a second mainframe that operates at the atmospheric chamber. In one aspect, the process chamber is a cleaning chamber (such as a pre-clean chamber) and the process operation is a cleaning operation. In one aspect, the process chamber is an atmospheric pressure epitaxial deposition chamber and the process operation is an atmospheric pressure epitaxial deposition operation.

Abstract: Embodiments described herein relate semiconductor manufacturing and processing. More particularly, a processing systems for auto correcting misalignments of substrates in process chambers is provided. The processing system includes a process chamber having a substrate support disposed within a chamber volume of the process chamber. The substrate support includes a pocket for receiving a substrate, and a plurality of flow conduits extending between a top surface of the pocket and a bottom surface of the substrate support. An imaging device is coupled to the process chamber and configured to monitor a position of a substrate when loaded in the pocket of the substrate support.

Abstract: The present disclosure relates to flow guide structures and heat shield structures, and related methods, for deposition uniformity and process adjustability. In one implementation, an apparatus for substrate processing includes a chamber body that includes a processing volume. The apparatus includes one or more heat sources. The apparatus includes a flow guide structure positioned in the processing volume. The flow guide structure includes one or more first flow dividers that divide the processing volume into a plurality of flow levels, and one or more second flow dividers oriented to intersect the one or more first flow dividers and divide each flow level of the plurality of flow levels into a plurality of flow sections. The flow guide structure includes one or more third flow dividers oriented to intersect the one or more second flow dividers and divide the plurality of flow sections into a plurality of flow zones.

Abstract: The present disclosure relates to batch processing apparatus, systems, and related methods and structures for epitaxial deposition operations. In one implementation, an apparatus for substrate processing includes a cassette. The cassette is at least partially supported by a pedestal assembly. The cassette includes a plurality of levels arranged vertically with respect to each other, each level of the plurality of levels including a support surface configured to support a substrate. A level spacing between adjacent levels of the plurality of levels is 25 mm or higher, and the level spacing is defined between the support surfaces of the adjacent levels.

Abstract: The present disclosure relates to batch processing apparatus, systems, and related methods and structures for epitaxial deposition operations. In one implementation, an apparatus for substrate processing includes a chamber body. The chamber body includes a processing volume, a plurality of gas inject passages, and an exhaust port. The apparatus includes one or more upper heat sources positioned above the processing volume, one or more lower heat sources positioned below the processing volume, and a pedestal assembly positioned in the processing volume. The apparatus includes one or more side heat sources positioned outwardly of the processing volume and configured to heat the processing volume through a side of the processing volume. The chamber body can be a dual-chamber body that includes a second processing volume, and the one or more side heat sources can be positioned outwardly of one or more of the processing volume or the second processing volume.

Abstract: A plasma processing system for cleaning a substrate is provided. The plasma processing system includes a process chamber that includes: a chamber body enclosing an interior volume; and a substrate support disposed in the interior volume. The plasma processing system includes a vacuum pump; a first exhaust line fluidly coupled between the interior volume of the process chamber and the vacuum pump; and a second exhaust line fluidly coupled between the interior volume of the process chamber and the vacuum pump. The first exhaust line and the second exhaust line are arranged to provide alternative paths for the exhaust between the interior volume and the vacuum pump, and the first exhaust line has an internal diameter that is at least 50% smaller than the internal diameter of the second exhaust line.

Abstract: In one aspect, a process operation is conducted at a first pressure in a process chamber, and an epitaxial deposition operation is conducted at an atmospheric pressure in an epitaxial deposition chamber. The atmospheric pressure is greater than the first pressure. The process chamber is mounted to a first mainframe that operates at the first pressure (a reduced pressure), and the epitaxial deposition chamber is mounted to a second mainframe that operates at the atmospheric chamber. In one aspect, the process chamber is a cleaning chamber (such as a pre-clean chamber) and the process operation is a cleaning operation. In one aspect, the process chamber is an atmospheric pressure epitaxial deposition chamber and the process operation is an atmospheric pressure epitaxial deposition operation.

Abstract: Examples of the present invention provide an apparatus for transferring substrates and confining a processing environment in a chamber. One example provides a hoop assembly for use in a processing chamber. The hoop assembly includes a confinement ring defining a confinement region therein. A hoop body mates with the confinement ring. The hoop body is slanted to reduce a thickness across a diameter of the hoop body. Three or more lifting fingers are attached to the hoop body and extend downwards. Each of the three or more lifting fingers has a contact tip positioned radially inward from the hoop body to form a substrate support surface below and spaced apart from the confinement region.

Abstract: Embodiments of the present invention provide a dual load lock chamber capable of processing a substrate. In one embodiment, the dual load lock chamber includes a chamber body defining a first chamber volume and a second chamber volume isolated from one another. Each of the lower and second chamber volumes is selectively connectable to two processing environments through two openings configured for substrate transferring. The dual load lock chamber also includes a heated substrate support assembly disposed in the second chamber volume. The heated substrate support assembly is configured to support and heat a substrate thereon. The dual load lock chamber also includes a remote plasma source connected to the second chamber volume for supplying a plasma to the second chamber volume.

Abstract: Embodiments of the present invention provide a dual load lock chamber capable of processing a substrate. In one embodiment, the dual load lock chamber includes a chamber body defining a first chamber volume and a second chamber volume isolated from one another. Each of the lower and second chamber volumes is selectively connectable to two processing environments through two openings configured for substrate transferring. The dual load lock chamber also includes a heated substrate support assembly disposed in the second chamber volume. The heated substrate support assembly is configured to support and heat a substrate thereon. The dual load lock chamber also includes a remote plasma source connected to the second chamber volume for supplying a plasma to the second chamber volume.

Abstract: Embodiments of the invention generally provide a cooling mechanism utilized in a plasma reactor that may provide efficient temperature control during a plasma process. In one embodiment, a cooling mechanism disposed in a plasma processing apparatus includes a coil antenna enclosure formed in a processing chamber, a coil antenna assembly disposed in the coil antenna enclosure, a plurality of air circulating elements disposed in the coil antenna enclosure adjacent to the coil antenna assembly, and a baffle plate disposed in the coil antenna enclosure below and adjacent to the coil antenna assembly.

Abstract: Examples of the present disclosure provide a load that includes a chamber body assembly. The chamber body assembly defines a first chamber volume and a second chamber volume fluidly isolated from one another. The first chamber volume and second chamber volume are selectively connectable to two environments through two sets of openings configured for substrate transferring. A third chamber volume is selectively connectable to the two environments through two sets of openings. A remote plasma source couples a processing gas source to the second chamber volume. A cooled substrate support assembly, includes a plurality of cooling channels, bounds a portion of the first chamber volume. A heated substrate support assembly can support a substrate. A gas distribution assembly, includes a showerhead, is disposed in the second chamber volume and is coupled to the remote plasma source. The showerhead can provide a processing gas to the second chamber volume.

Abstract: Examples of the present invention provide an apparatus for transferring substrates and confining a processing environment in a chamber. One example provides a hoop assembly for use in a processing chamber. The hoop assembly includes a confinement ring defining a confinement region therein. A hoop body mates with the confinement ring. The hoop body is slanted to reduce a thickness across a diameter of the hoop body. Three or more lifting fingers are attached to the hoop body and extend downwards. Each of the three or more lifting fingers has a contact tip positioned radially inward from the hoop body to form a substrate support surface below and spaced apart from the confinement region.

Abstract: Examples of the present invention include a method for removing halogen-containing residues from a substrate. The method includes transferring a substrate to a substrate processing system through a first chamber volume of a load lock chamber. The load lock chamber is coupled to a transfer chamber of the substrate processing system. The substrate is etched in one or more processing chambers coupled to the transfer chamber of the substrate processing system with chemistry from a showerhead disposed over a heated substrate support assembly. The chemistry includes halogen. Halogen-containing residues are removed from the etched substrate in a second chamber volume of the load lock chamber. Cooling the etched substrate in a cooled substrate support assembly of the load lock chamber after removing the halogen-containing residue.

Abstract: Embodiments of the present invention provide a dual load lock chamber capable of processing a substrate. In one embodiment, the dual load lock chamber includes a chamber body defining a first chamber volume and a second chamber volume isolated from one another. Each of the lower and second chamber volumes is selectively connectable to two processing environments through two openings configured for substrate transferring. The dual load lock chamber also includes a heated substrate support assembly disposed in the second chamber volume. The heated substrate support assembly is configured to support and heat a substrate thereon. The dual load lock chamber also includes a remote plasma source connected to the second chamber volume for supplying a plasma to the second chamber volume.

Abstract: Embodiments of the present invention a load lock chamber including two or more isolated chamber volumes, wherein one chamber volume is configured for processing a substrate and another chamber volume is configured to provide cooling to a substrate. One embodiment of the present invention provides a load lock chamber having at least two isolated chamber volumes formed in a chamber body assembly. The at least two isolated chamber volumes may be vertically stacked. A first chamber volume may be used to process a substrate disposed therein using reactive species. A second chamber volume may include a cooled substrate support.

Abstract: Examples of the present disclosure provide a load that includes a chamber body assembly. The chamber body assembly defines a first chamber volume and a second chamber volume fluidly isolated from one another. The first chamber volume and second chamber volume are selectively connectable to two environments through two sets of openings configured for substrate transferring. A third chamber volume is selectively connectable to the two environments through two sets of openings. A remote plasma source couples a processing gas source to the second chamber volume. A cooled substrate support assembly, includes a plurality of cooling channels, bounds a portion of the first chamber volume. A heated substrate support assembly can support a substrate. A gas distribution assembly, includes a showerhead, is disposed in the second chamber volume and is coupled to the remote plasma source. The showerhead can provide a processing gas to the second chamber volume.

Abstract: Embodiments of the present invention provide a dual load lock chamber capable of processing a substrate. In one embodiment, the dual load lock chamber includes a chamber body defining a first chamber volume and a second chamber volume isolated from one another. Each of the lower and second chamber volumes is selectively connectable to two processing environments through two openings configured for substrate transferring. The dual load lock chamber also includes a heated substrate support assembly disposed in the second chamber volume. The heated substrate support assembly is configured to support and heat a substrate thereon. The dual load lock chamber also includes a remote plasma source connected to the second chamber volume for supplying a plasma to the second chamber volume.

Abstract: Embodiments of the present invention provide a dual load lock chamber capable of processing a substrate. In one embodiment, the dual load lock chamber includes a chamber body defining a first chamber volume and a second chamber volume isolated from one another. Each of the lower and second chamber volumes is selectively connectable to two processing environments through two openings configured for substrate transferring. The dual load lock chamber also includes a heated substrate support assembly disposed in the second chamber volume. The heated substrate support assembly is configured to support and heat a substrate thereon. The dual load lock chamber also includes a remote plasma source connected to the second chamber volume for supplying a plasma to the second chamber volume.

Abstract: Embodiments of the invention generally provide a cooling mechanism utilized in a plasma reactor that may provide efficient temperature control during a plasma process. In one embodiment, a cooling mechanism disposed in a plasma processing apparatus includes a coil antenna enclosure formed in a processing chamber, a coil antenna assembly disposed in the coil antenna enclosure, a plurality of air circulating elements disposed in the coil antenna enclosure adjacent to the coil antenna assembly, and a baffle plate disposed in the coil antenna enclosure below and adjacent to the coil antenna assembly.