Abstract: An apparatus and method are provided for controlling the intensity and distribution of a plasma discharge in a plasma chamber. In one embodiment, a shaped electrode is embedded in a substrate support to provide an electric field with radial and axial components inside the chamber. In another embodiment, the face plate electrode of the showerhead assembly is divided into zones by isolators, enabling different voltages to be applied to the different zones. Additionally, one or more electrodes may be embedded in the chamber side walls.

Abstract: An apparatus and method are provided for controlling the intensity and distribution of a plasma discharge in a plasma chamber. In one embodiment, a shaped electrode is embedded in a substrate support to provide an electric field with radial and axial components inside the chamber. In another embodiment, the face plate electrode of the showerhead assembly is divided into zones by isolators, enabling different voltages to be applied to the different zones. Additionally, one or more electrodes may be embedded in the chamber side walls.

Abstract: A heater liner assembly suitable for covering the interior of a plasma processing chamber is provided. In some embodiments, a liner assembly for a processing chamber can include a heating element embedded in a body. A flange extending outward from an outer diameter of the body includes an upper surface having a sealing surface and at least one pad that extends from the upper surface of the flange to an elevation beyond the sealing surface. The pad contributes to control of the temperature of the liner assembly by maintaining the liner assembly spaced apart from the processing chamber.

Abstract: Embodiments described herein relate to a substrate processing system that integrates substrate edge processing capabilities. Illustrated examples of the processing system include, without limitations, a factory interface, a loadlock chamber, a transfer chamber, and one or more twin process chambers having two or more processing regions that are isolatable from each other and share a common gas supply and a common exhaust pump. The processing regions in each twin process chamber include separate gas distribution assemblies and RF power sources to provide plasma at selective regions on a substrate surface in each processing region. Each twin process chamber is thereby configured to allow multiple, isolated processes to be performed concurrently on at least two substrates in the processing regions.

Abstract: An apparatus and method are provided for controlling the intensity and distribution of a plasma discharge in a plasma chamber. In one embodiment, a shaped electrode is embedded in a substrate support to provide an electric field with radial and axial components inside the chamber. In another embodiment, the face plate electrode of the showerhead assembly is divided into zones by isolators, enabling different voltages to be applied to the different zones. Additionally, one or more electrodes may be embedded in the chamber side walls.

Abstract: Embodiments described herein relate to a substrate processing system that integrates substrate edge processing capabilities. Illustrated examples of the processing system include, without limitations, a factory interface, a loadlock chamber, a transfer chamber, and one or more twin process chambers having two or more processing regions that are isolatable from each other and share a common gas supply and a common exhaust pump. The processing regions in each twin process chamber include separate gas distribution assemblies and RF power sources to provide plasma at selective regions on a substrate surface in each processing region. Each twin process chamber is thereby configured to allow multiple, isolated processes to be performed concurrently on at least two substrates in the processing regions.

Abstract: The present invention comprises an apparatus and method for centering a substrate in a process chamber. In one embodiment, the apparatus comprises a substrate support having a support surface adapted to receive the placement of a substrate and a reference axis substantially perpendicular to the support surface, and a plurality of centering members extending above the support surface. Each centering member is biased into a first position and is movable to a second position by interacting with an opposing member. A movement between the first position and the second position thereby causes each centering member to releasably engage with a peripheral edge of the substrate to push the substrate in a direction toward the reference axis.

Abstract: Embodiments described herein generally provide a lift pin assembly having increased wafer placement accuracy, repeatability, reliability, and corrosion resistance. In one embodiment, a lift pin assembly for positioning a substrate relative to a substrate support is provided. The lift pin assembly comprises a lift pin comprising a pin shaft, a pin head coupled with a first end of the pin shaft for supporting the substrate, and a shoulder coupled with a second end of the pin shaft. The lift pin assembly further comprises a cylindrical body slidably coupled with the pin shaft and a locking pin for preventing the cylindrical body from sliding along the shaft, wherein the shoulder has a through-hole dimensioned to accommodate the locking pin.

Abstract: An apparatus and method are provided for controlling the intensity and distribution of a plasma discharge in a plasma chamber. In one embodiment, a shaped electrode is embedded in a substrate support to provide an electric field with radial and axial components inside the chamber. In another embodiment, the face plate electrode of the showerhead assembly is divided into zones by isolators, enabling different voltages to be applied to the different zones. Additionally, one or more electrodes may be embedded in the chamber side walls.

Abstract: The present invention comprises an apparatus and method for etching at a substrate edge region. In one embodiment, the apparatus comprises a chamber having a process volume, a substrate support arranged inside the process volume and having a substrate support surface, a plasma generator coupled to the chamber and configured to supply an etching agent in a plasma phase to a peripheral region of the substrate support surface, and a gas delivery assembly coupled to a gas source for generating a radial gas flow over the substrate support surface from an approximately central region of the substrate support surface toward the peripheral region of the substrate support surface.

Abstract: Embodiments described herein relate to a substrate processing system that integrates substrate edge processing capabilities. Illustrated examples of the processing system include, without limitations, a factory interface, a loadlock chamber, a transfer chamber, and one or more twin process chambers having two or more processing regions that are isolatable from each other and share a common gas supply and a common exhaust pump. The processing regions in each twin process chamber include separate gas distribution assemblies and RF power sources to provide plasma at selective regions on a substrate surface in each processing region. Each twin process chamber is thereby configured to allow multiple, isolated processes to be performed concurrently on at least two substrates in the processing regions.

Abstract: The present invention comprises an apparatus and method for centering a substrate in a process chamber. In one embodiment, the apparatus comprises a substrate support having a support surface adapted to receive the placement of a substrate and a reference axis substantially perpendicular to the support surface, and a plurality of centering members extending above the support surface. Each centering member is biased into a first position and is movable to a second position by interacting with an opposing member. A movement between the first position and the second position thereby causes each centering member to releasably engage with a peripheral edge of the substrate to push the substrate in a direction toward the reference axis.

Abstract: A heater liner assembly suitable for covering the interior of a plasma processing chamber is provided. In some embodiments, a liner assembly for a processing chamber can include a heating element embedded in a body. A flange extending outward from an outer diameter of the body includes an upper surface having a sealing surface and at least one pad that extends from the upper surface of the flange to an elevation beyond the sealing surface. The pad contributes to control of the temperature of the liner assembly by maintaining the liner assembly spaced apart from the processing chamber.

Abstract: Embodiments in accordance with the present invention relate to various techniques which may be employed alone or in combination, to reduce or eliminate the deposition of material on the bevel of a semiconductor workpiece. In one approach, a shadow ring overlies the edge of the substrate to impede the flow of gases to bevel regions. The geometric feature at the edge of the shadow ring directs the flow of gases toward the wafer in order to maintain thickness uniformity across the wafer while shadowing the edge. In another approach, a substrate heater/support is configured to flow purge gases to the edge of a substrate being supported. These purge gases prevent process gases from reaching the substrate edge and depositing material on bevel regions.

Abstract: A substrate support comprises a ceramic disc with an electrode that is chargeable through an electrode terminal. An electrical connector connects an external power source to the electrode terminal. The electrical connector has a pair of opposing pincer arms, a groove sized to fit around the electrode terminal, and a pair of through holes to receive a tightening assembly capable of tightening the opposing pincer arms about the electrode terminal.

Abstract: A substrate heater assembly for supporting a substrate of a predetermined standardized diameter during processing is provided. In one embodiment, the substrate heater assembly includes a body having an upper surface, a lower surface and an embedded heating element. A substrate support surface is formed in the upper surface of the body and defines a portion of a substrate receiving pocket. An annular wall is oriented perpendicular to the upper surface and has a length of at least one half a thickness of the substrate. The wall bounds an outer perimeter of the substrate receiving pocket and has a diameter less than about 0.5 mm greater than the predetermined substrate diameter.

Abstract: Non-bonded ceramic protection is provided for metal surfaces in a plasma processing chamber, particularly heated metal electrode surfaces, in a plasma processing chamber, to prevent or inhibit attack of the heated metal surfaces by chemically aggressive species generated in the plasma during processing of materials, without bonding the ceramic material to the metal surface. In accordance with the invention the ceramic protection material comprises a thin cover material which is fitted closely, but not bonded, to the heated metal. This form of ceramic protection is particularly useful for protecting the surfaces of glow discharge electrodes and gas distribution apparatus in plasma process chambers used for processing semiconductor substrates to form integrated circuit structures.

Abstract: A ceramic susceptor with an embedded metal electrode. The metal electrode has multiple apertures, and the ceramic material is cross-linked through the apertures. An electrical connection to the electrode protects the electrode from the environment in the processing chamber. The ceramic may be aluminum nitride, and the metal electrode may be a mesh of molybdenum wires. To form the electrical connection, the susceptor may be heated until an eutectic forms between a conductive connector and the metal electrode. Alternately, a brazing material may be placed between the metal layer and a conductive connector.

Abstract: Non-bonded ceramic protection is provided for metal surfaces in a plasma processing chamber, particularly heated metal electrode surfaces, in a plasma processing chamber, to prevent or inhibit attack of the heated metal surfaces by chemically aggressive species generated in the plasma during processing of materials, without bonding the ceramic material to the metal surface. In accordance with the invention the ceramic protection material comprises a thin cover material which is fitted closely, but not bonded, to the heated metal. This form of ceramic protection is particularly useful for protecting the surfaces of glow discharge electrodes and gas distribution apparatus in plasma process chambers used for processing semiconductor substrates to form integrated circuit structures.

Abstract: A ceramic susceptor with an embedded metal electrode. The metal electrode has multiple apertures, and the ceramic material is cross-linked through the apertures. An electrical connection to the electrode protects the electrode from the environment in the processing chamber. The ceramic may be aluminum nitride, and the metal electrode may be a mesh of molybdenum wires. To form the electrical connection, the susceptor may be heated until an eutectic forms between a conductive connector and the metal electrode. Alternately, a brazing material may be placed between the metal layer and a conductive connector.