Abstract: An improved vacuum plasma etching device for plasma etching semiconductor wafers that have a photo-resist pattern. The improved plasma etching device has a reaction chamber in which the plasma etching is performed during a process cycle, an entrance vacuum loadlock for holding the next semiconductor wafer to be plasma etched, an exit vacuum loadlock for transporting the semiconductor wafers out of the reaction chamber after the plasma etching process, and a source of ultraviolet light. Exposing the semiconductor wafer to the ultraviolet light cures the photo-resist patterns, thereby improving CD dispersion, enhancing pattern transfer, and preventing photo-resist reticulation. Curing the photo-resist patterns while the semiconductor wafer is being held during the process cycle in the entrance vacuum loadlock, increases efficiency and productivity.

Abstract: An improved vacuum plasma etching device for plasma etching semiconductor wafers that have a photo-resist pattern. The improved plasma etching device has a reaction chamber in which the plasma etching is performed during a process cycle, an entrance vacuum loadlock for holding the next semiconductor wafer to be plasma etched, an exit vacuum loadlock for transporting the semiconductor wafers out of the reaction chamber after the plasma etching process, and a source of ultraviolet light. Exposing the semiconductor wafer to the ultraviolet light cures the photo-resist patterns, thereby improving CD dispersion, enhancing pattern transfer, and preventing photo-resist reticulation. Curing the photo-resist patterns while the semiconductor wafer is being held during the process cycle in the entrance vacuum loadlock, increases efficiency and productivity.

Abstract: An improved vacuum plasma etching device for plasma etching semiconductor wafers that have a photo-resist pattern. The improved plasma etching device has a reaction chamber in which the plasma etching is performed during a process cycle, an entrance vacuum loadlock for holding the next semiconductor wafer to be plasma etched, an exit vacuum loadlock for transporting the semiconductor wafers out of the reaction chamber after the plasma etching process, and a source of ultraviolet light. Exposing the semiconductor wafer to the ultraviolet light cures the photo-resist patterns, thereby improving CD dispersion, enhancing pattern transfer, and preventing photo-resist reticulation. Curing the photo-resist patterns while the semiconductor wafer is being held during the process cycle in the entrance vacuum loadlock, increases efficiency and productivity.

Abstract: An improved vacuum plasma etching device for plasma etching semiconductor wafers that have a photo-resist pattern. The improved plasma etching device has a reaction chamber in which the plasma etching is performed during a process cycle, an entrance vacuum loadlock for holding the next semiconductor wafer to be plasma etched, an exit vacuum loadlock for transporting the semiconductor wafers out of the reaction chamber after the plasma etching process, and a source of ultraviolet light. Exposing the semiconductor wafer to the ultraviolet light cures the photo-resist patterns, thereby improving CD dispersion, enhancing pattern transfer, and preventing photo-resist reticulation. Curing the photo-resist patterns while the semiconductor wafer is being held during the process cycle in the entrance vacuum loadlock, increases efficiency and productivity.

Abstract: Method and system for monitoring a plasma etch process performed in a plasma processing chamber, the method and system being capable of accurately monitoring and controlling the plasma etch process without being affected by the change in a plasma light emission transmission characteristically caused by process polymer depositions on a detecting surface or sampling window.

Abstract: A method is provided for forming an isolation structure at a semiconducting surface of a body, and the isolation structure formed thereby. A masking layer is formed over selected regions of the substrate surface; the masking layer preferably comprising a nitride layer overlying a pad oxide layer. The masking layer is patterned and etched to form openings exposing selected regions of the substrate surface. Recesses are formed into the substrate in the openings. Preferably a portion of the pad oxide layer is isotropically etched under the nitride layer forming an undercut region. An etch stop layer is formed over the substrate in the recesses filling in the undercut along the sidewalls. A second masking layer, preferably of nitride is formed over the etch stop layer and anisotropically etched to form nitride sidewalls in the openings. The etch stop layer may be etched away from the horizontal surfaces.

Abstract: A method is provided for forming an isolation structure at a semiconducting surface of a body, and the isolation structure formed thereby. A masking layer is formed over selected regions of the substrate surface; the masking layer preferably comprising a nitride layer overlying a pad oxide layer. The masking layer is patterned and etched to form openings exposing selected regions of the substrate surface. Recesses are formed into the substrate in the openings. Preferably a portion of the pad oxide layer is isotropically etched under the nitride layer forming an undercut region. An etch stop layer is formed over the substrate in the recesses filling in the undercut along the sidewalls. A second masking layer, preferably of nitride is formed over the etch stop layer and anisotropically etched to form nitride sidewalls in the openings. The etch stop layer may be etched away from the horizontal surfaces.