Abstract: Embodiments of fast gas exchange (FGE) manifolds are provided herein. In some embodiments, a FGE manifold includes: a manifold housing having a plurality of inlets and a plurality of outlets for flowing a plurality of process gases therethrough, wherein the plurality of outlets correspond with a plurality of zones in the process chamber; a plurality of hybrid valves disposed in the manifold housing and fluidly coupled to the plurality of inlets; a plurality of mass flow controllers disposed in the manifold housing downstream of the plurality of hybrid valves; a plurality of mixing lines extending downstream from the plurality of mass flow controllers to a plurality of outlet lines; and a plurality of outlet valves disposed in line with corresponding ones of the plurality of outlet lines, wherein a flow path is defined between each inlet of the plurality of inlets and each outlet of the plurality of outlets.

Abstract: Exemplary substrate processing systems may include a body that defines processing and transfer regions. The systems may include a liner atop the body. The systems may include a faceplate atop the liner. The systems may include a support within the body. The support may be vertically translatable between process and transfer positions. The support may include a plate having a heater. The support may include a shaft coupled with the plate. The support may include a bowl about the shaft below the plate. The bowl may be in alignment with the liner. The support may include springs that push the bowl upward as the support translates to the process position. The support may include straps that couple the plate and bowl. The support may include a hard stop. The bowl may contact the liner in the process position and may be spaced apart from the liner in the transfer position.

Abstract: Exemplary semiconductor substrate supports may include a pedestal having a shaft and a platen. The semiconductor substrate supports may include a cover plate. The cover plate may be coupled with the platen along a first surface of the cover plate. The cover plate may define a recessed channel in a second surface of the cover plate opposite the first surface. The semiconductor substrate supports may include a puck coupled with the second surface of the cover plate. The puck may incorporate an electrode. The puck may define a plurality of apertures extending vertically through the puck to fluidly access the recessed channel defined in the cover plate.

Abstract: Embodiments of a lift apparatus for use in a substrate processing chamber are provided herein. In some embodiments, a lift apparatus includes: a plurality of first lift pin assemblies configured to raise or lower a substrate having a given diameter when disposed thereon, wherein each of the first lift pin assemblies includes a first lift pin disposed on a first bellows assembly; a plurality of second lift pin assemblies arranged in a circle having a diameter greater than the given diameter and configured to raise or lower an annular chamber component, wherein each of the second lift pin assemblies includes a second lift pin disposed on a second bellows assembly; an actuator; and a lift assembly coupled to the actuator and configured to raise or lower each of the first lift pin assemblies and the second lift pin assemblies by movement of the actuator.

Abstract: Exemplary semiconductor substrate supports may include a pedestal shaft. The semiconductor substrate supports may include a platen. The platen may define a fluid channel across a first surface of the platen. The semiconductor substrate supports may include a platen insulator positioned between the platen and the pedestal shaft. The semiconductor substrate supports may include a conductive puck coupled with the first surface of the platen and configured to contact a substrate supported on the semiconductor substrate support. The semiconductor substrate supports may include a conductive shield extending along a backside of the platen insulator and coupled between a portion of the platen insulator and the pedestal shaft.

Abstract: Exemplary substrate processing system may include a chamber body that defines a processing region. The systems may include a liner positioned atop the chamber body. The liner may include first disconnect members. The systems may include a faceplate that is positioned atop the liner. The systems may include a support disposed within the chamber body. The support may include a plate comprising a heater. The plate may include second disconnect members. The support may include a shaft coupled with the plate. The support may include a dynamic plate disposed about the shaft below the plate. The support may include metallic straps that couple the plate with the dynamic plate. The dynamic plate may include inner disconnect members and outer disconnect members. Inner disconnect members may be engageable with second disconnect members in a transfer position. Outer disconnect members may be engageable with first disconnect members in a process position.

Abstract: Exemplary semiconductor substrate supports may include a pedestal shaft. The semiconductor substrate supports may include a platen. The platen may define a fluid channel across a first surface of the platen. The semiconductor substrate supports may include a platen insulator positioned between the platen and the pedestal shaft. The semiconductor substrate supports may include a conductive puck coupled with the first surface of the platen and configured to contact a substrate supported on the semiconductor substrate support. The semiconductor substrate supports may include a conductive shield extending along a backside of the platen insulator and coupled between a portion of the platen insulator and the pedestal shaft.

Abstract: Exemplary substrate processing system may include a chamber body that defines a processing region. The systems may include a liner positioned atop the chamber body. The liner may include first disconnect members. The systems may include a faceplate that is positioned atop the liner. The systems may include a support disposed within the chamber body. The support may include a plate comprising a heater. The plate may include second disconnect members. The support may include a shaft coupled with the plate. The support may include a dynamic plate disposed about the shaft below the plate. The support may include metallic straps that couple the plate with the dynamic plate. The dynamic plate may include inner disconnect members and outer disconnect members. Inner disconnect members may be engageable with second disconnect members in a transfer position. Outer disconnect members may be engageable with first disconnect members in a process position.

Abstract: Embodiments of a lift apparatus for use in a substrate processing chamber are provided herein. In some embodiments, a lift apparatus includes: a plurality of first lift pin assemblies configured to raise or lower a substrate having a given diameter when disposed thereon, wherein each of the first lift pin assemblies includes a first lift pin disposed on a first bellows assembly; a plurality of second lift pin assemblies arranged in a circle having a diameter greater than the given diameter and configured to raise or lower an annular chamber component, wherein each of the second lift pin assemblies includes a second lift pin disposed on a second bellows assembly; an actuator; and a lift assembly coupled to the actuator and configured to raise or lower each of the first lift pin assemblies and the second lift pin assemblies by movement of the actuator.

Abstract: Methods and apparatus for processing a substrate are provided herein. For example, an apparatus for processing a substrate comprises a top delivery gas nozzle configured to direct process gas toward a substrate support surface of a substrate support and a side delivery gas nozzle configured to direct the process gas toward a side surface of the substrate support, a first gas line connected to the top delivery gas nozzle, a second gas line connected to the side delivery gas nozzle, and a plurality of valves connected to the first gas line and the second gas line for providing process gas to the processing volume of the processing chamber, and a first orifice flow restrictor or a first needle valve connected to the first gas line or a second orifice flow restrictor or a second needle valve connected to the second gas line.

Abstract: Exemplary substrate processing systems may include a body that defines processing and transfer regions. The systems may include a liner atop the body. The systems may include a faceplate atop the liner. The systems may include a support within the body. The support may be vertically translatable between process and transfer positions. The support may include a plate having a heater. The support may include a shaft coupled with the plate. The support may include a bowl about the shaft below the plate. The bowl may be in alignment with the liner. The support may include springs that push the bowl upward as the support translates to the process position. The support may include straps that couple the plate and bowl. The support may include a hard stop. The bowl may contact the liner in the process position and may be spaced apart from the liner in the transfer position.

Abstract: Exemplary substrate processing system may include a chamber body that defines a processing region. The systems may include a liner positioned atop the chamber body. The liner may include first disconnect members. The systems may include a faceplate that is positioned atop the liner. The systems may include a support disposed within the chamber body. The support may include a plate comprising a heater. The plate may include second disconnect members. The support may include a shaft coupled with the plate. The support may include a dynamic plate disposed about the shaft below the plate. The support may include metallic straps that couple the plate with the dynamic plate. The dynamic plate may include inner disconnect members and outer disconnect members. Inner disconnect members may be engageable with second disconnect members in a transfer position. Outer disconnect members may be engageable with first disconnect members in a process position.

Abstract: Exemplary semiconductor substrate supports may include a pedestal having a shaft and a platen. The semiconductor substrate supports may include a cover plate. The cover plate may be coupled with the platen along a first surface of the cover plate. The cover plate may define a recessed channel in a second surface of the cover plate opposite the first surface. The semiconductor substrate supports may include a puck coupled with the second surface of the cover plate. The puck may incorporate an electrode. The puck may define a plurality of apertures extending vertically through the puck to fluidly access the recessed channel defined in the cover plate.

Abstract: Exemplary semiconductor substrate supports may include a pedestal shaft. The semiconductor substrate supports may include a platen. The platen may define a fluid channel across a first surface of the platen. The semiconductor substrate supports may include a platen insulator positioned between the platen and the pedestal shaft. The semiconductor substrate supports may include a conductive puck coupled with the first surface of the platen and configured to contact a substrate supported on the semiconductor substrate support. The semiconductor substrate supports may include a conductive shield extending along a backside of the platen insulator and coupled between a portion of the platen insulator and the pedestal shaft.

Abstract: Implementations of the present disclosure generally relate to apparatus and methods for uniform deposition of thin films on substrates. In one implementation, a plasma-processing chamber comprises a chamber body including chamber walls, a chamber floor, and a lid support. The plasma-processing chamber further comprises a substrate support assembly at least partially disposed within the chamber body and configured to support a substrate. The plasma-processing chamber further comprises a lid assembly disposed over the support assembly and positioned on the lid support wherein the lid assembly and the chamber body define a first processing volume. The plasma-processing chamber further comprises a bottom isolation assembly that circumscribes at least a portion of the substrate support assembly and is vertically movable from a loading position to a processing position. A seal is formed between the bottom isolation assembly and the lid assembly when the bottom isolation assembly is in the processing position.

Abstract: Implementations of the present disclosure generally relate to apparatus and methods for uniform deposition of thin films on substrates. In one implementation, a plasma-processing chamber comprises a chamber body including chamber walls, a chamber floor, and a lid support. The plasma-processing chamber further comprises a substrate support assembly at least partially disposed within the chamber body and configured to support a substrate. The plasma-processing chamber further comprises a lid assembly disposed over the support assembly and positioned on the lid support wherein the lid assembly and the chamber body define a first processing volume. The plasma-processing chamber further comprises a bottom isolation assembly that circumscribes at least a portion of the substrate support assembly and is vertically movable from a loading position to a processing position. A seal is formed between the bottom isolation assembly and the lid assembly when the bottom isolation assembly is in the processing position.