Abstract: A process is provided for removing polymer from a backside of a workpiece. The process includes supporting the workpiece on the backside in a vacuum chamber while leaving at least a peripheral annular portion of the backside exposed. The process further includes confining gas flow at the edge of the workpiece within a gap at the edge of the workpiece on the order of about 1% of the diameter of the chamber, the gap defining a boundary between an upper process zone containing the wafer front side and a lower process zone containing the wafer backside. The process also includes providing a polymer etch precursor gas underneath the backside edge of the workpiece and applying RF power to a region underlying the backside edge of the workpiece to generate a first plasma of polymer etch species concentrated in an annular ring concentric with and underneath the backside edge of the workpiece.

Abstract: A process is provided for removing polymer from a backside of a workpiece. The process includes supporting the workpiece on the backside in a vacuum chamber while leaving at least a peripheral annular portion of the backside exposed. The process further includes confining gas flow at the edge of the workpiece within a gap at the edge of the workpiece on the order of about 1% of the diameter of the chamber, the gap defining a boundary between an upper process zone containing the wafer front side and a lower process zone containing the wafer backside. The process also includes providing a polymer etch precursor gas underneath the backside edge of the workpiece and applying RF power to a region underlying the backside edge of the workpiece to generate a first plasma of polymer etch species concentrated in an annular ring concentric with and underneath the backside edge of the workpiece.

Abstract: A reactor is provided for removing polymer from a backside of a workpiece. The reactor includes a vacuum chamber having a ceiling, a floor and a cylindrical side wall. The reactor further includes workpiece support apparatus within the chamber configured for a workpiece to be placed thereon with its front side facing the ceiling. The support apparatus is configured to leave at least an annular periphery of the backside of the workpiece exposed. A confinement member defines a narrow gap with an outer edge of the workpiece, the narrow gap being on the order of about 1% of the workpiece diameter, the narrow gap corresponding to a boundary dividing the chamber between an upper process zone and a lower process zone, the reactor further comprising a vacuum pump coupled to the lower process zone.

Abstract: A reactor is provided for removing polymer from a backside of a workpiece. The reactor includes a vacuum chamber having a ceiling, a floor and a cylindrical side wall. A workpiece support apparatus within the chamber is configured to support a workpiece thereon so that the workpiece has its front side facing the ceiling. The support apparatus leaves at least an annular periphery of the backside of the workpiece exposed. A confinement member defines a narrow gap with the outer edge of the workpiece, the narrow gap being on the order of about 1% of the workpiece diameter, the narrow gap corresponding to a boundary dividing the chamber between an upper process zone and a lower process zone. A vacuum pump is coupled to the lower process zone.

Abstract: A reactor is provided for removing polymer from a backside of a workpiece. The reactor includes a vacuum chamber having a ceiling, a floor and a cylindrical side wall. A workpiece support apparatus within the chamber is configured to support a workpiece thereon, so that the workpiece has its front side facing the ceiling. The support apparatus leaves at least an annular periphery of the backside of the workpiece exposed. A confinement member defines a narrow gap with the outer edge of the workpiece, the narrow gap being on the order of about 1% of workpiece diameter, the narrow gap corresponding to a boundary dividing the chamber between an upper process zone and a lower process zone. A vacuum pump is coupled to the lower process zone. A lower external plasma-generating chamber introduces a plasma by-product into the lower process zone and a supply of a polymer etch precursor gas coupled to the lower external plasma-generating chamber.

Abstract: A process is provided for removing polymer from a backside of a workpiece. The process includes supporting the workpiece on the backside in a vacuum chamber while leaving a peripheral annular portion of the backside exposed. The process further includes confining gas flow at an edge of the workpiece within a gap at the edge of the workpiece on the order of about 1% of the diameter of the chamber, the gap defining a boundary between an upper process zone containing the front side and a lower process zone containing the backside. A first plasma is generated in a local plasma chamber from a polymer etch precursor gas. The process includes directing a localized stream of an etchant by-product from the first plasma onto a target portion of the backside of the workpiece, the target portion having a diameter corresponding to a diameter of the stream, while rotating the workpiece.

Abstract: A process is provided for removing polymer from a backside of a workpiece. The process includes supporting the workpiece on the backside in a vacuum chamber while leaving a peripheral annular portion of the backside exposed. Gas flow is confined at the edge of the workpiece within a gap at the edge of the workpiece, the gap configured to be on the order of about 1% of the diameter of the chamber, the gap defining a boundary between an upper process zone containing the front side and a lower process zone containing the backside. The process further includes evacuating the lower process zone, generating a plasma in an external chamber from a polymer etch precursor gas, and introducing a by-product from the plasma into the lower process zone. The process further includes pumping a purge gas into the upper process zone to remove polymer etch species from the upper process zone.

Abstract: A workpiece is supported on the backside in a vacuum chamber while leaving at least a peripheral annular portion of a backside of the workpiece exposed. The process first increases the temperature of the workpiece starting at a temperature below about 200 degrees C. The edge of the workpiece is confined so as to establish a gap at the edge on the order of about 1% of the diameter of the chamber, the gap corresponding to a boundary between an upper process zone containing the front side and a lower process zone containing the backside. Before the workpiece temperature exceeds about 200 degrees C., backside polymer is removed using a first plasma containing polymer etch species in the lower process zone. After the workpiece temperature reaches about 300 degrees C., photoresist is stripped from the workpiece front side using by-products of a second plasma containing a photoresist strip species in the upper process zone.

Abstract: A process is provided for removing polymer from a backside of a workpiece. The process includes supporting the workpiece on the backside in a vacuum chamber while leaving a peripheral annular portion of the backside exposed. The process further includes confining gas flow at the edge of the workpiece within a gap at the edge of the workpiece on the order of about 1% of the diameter of the chamber, the gap defining a boundary between an upper process zone containing the front side and a lower process zone containing the backside. A first plasma is generated in a lower external chamber from a polymer etch precursor gas, and an etchant by-product is introduced from the first plasma into the lower process zone. A second plasma is generated in an upper external plasma chamber from a precursor gas of a scavenger of the etchant by-product, and scavenger species are introduced from the second plasma into the upper process zone.

Abstract: A method and apparatus for processing wafers including a chamber defining a plurality of isolated processing regions. The isolated processing regions have an upper end and a lower end. The chamber further includes a plurality of plasma generation devices each disposed adjacent the upper end of each isolated processing region, and one of a plurality of power supplies connected to each plasma generation device. The output frequency of the plurality of power supplies are phase and/or frequency locked together. Additionally, the chamber includes a plurality of gas distribution assemblies. Each gas distribution assembly is disposed within each isolated processing region. A movable wafer support is disposed within each isolated processing region to support a wafer for plasma processing thereon. The movable wafer support includes a bias electrode coupled to a bias power supply configured to control the bombardment of plasma ions toward the movable wafer support.

Abstract: A method and apparatus for processing wafers including a chamber defining a plurality of isolated processing regions. The isolated processing regions have an upper end and a lower end. The chamber further includes a plurality of plasma generation devices each disposed adjacent the upper end of each isolated processing region, and one of a plurality of power supplies connected to each plasma generation device. The output frequency of the plurality of power supplies are phase and/or frequency locked together. Additionally, the chamber includes a plurality of gas distribution assemblies. Each gas distribution assembly is disposed within each isolated processing region. A movable wafer support is disposed within each isolated processing region to support a wafer for plasma processing thereon. The movable wafer support includes a bias electrode coupled to a bias power supply configured to control the bombardment of plasma ions toward the movable wafer support.

Abstract: A substrate support assembly 30 comprises a substrate support 38 and a collar 130 which may comprise at least one slit 150. The slit allows for thermal expansion compensation in the support assembly 30. The collar 130 may, for example, protect the dielectric 45 from erosion in a process chamber 25. In one version, the collar 130 comprises a clamping ring 200 on the dielectric 45.

Abstract: A thermally conductive medium includes a body with a first melting point and phase-changing material encapsulating a portion of the body, with the phase-changing material having a second melting point. The first melting point is greater than the second melting point, and the phase-changing material is configured to be in a liquid phase at temperatures above the second melting point and a solid phase at temperatures below the same. In the liquid phase, an adhesive force is present between the body and the phase-changing material due to capillary attraction, and the phase-changing material may be wettable to one of the two surfaces.