Abstract: A high pressure, high throughput, single wafer, semiconductor processing reactor is disclosed which is capable of thermal CVD, plasma-enhanced CVD, plasma-assisted etchback, plasma self-cleaning, and deposition topography modification by sputtering, either separately or as part of in-situ multiple step processing. The reactor includes cooperating arrays of interdigitated susceptor and wafer support fingers which collectively remove the wafer from a robot transfer blade and position the wafer with variable, controlled, close parallel spacing between the wafer and the chamber gas inlet manifold, then return the wafer to the blade. A combined RF/gas feed-through device protects against process gas leaks and applies RF energy to the gas inlet manifold without internal breakdown or deposition of the gas. The gas inlet manifold is adapted for providing uniform gas flow over the wafer.

Abstract: A process for etching single crystal silicon, polysilicon, silicide and polycide using iodinate or brominate gas chemistry, is disclosed. The iodinate/brominate gas chemistry etches narrow deep trenches with very high aspect ratios and good profile control and without black silicon formation or other undesirable phenomena.

Abstract: An integrated modular multiple chamber vacuum processing system is disclosed. The system includes a load lock, may include an external cassette elevator, and an internal load lock wafer elevator, and also includes stations about the periphery of the load lock for connecting one, two or several vacuum process chambers to the load lock chamber. A robot is mounted within the load lock and utilizes a concentric shaft drive system connected to an end effector via a dual four-bar link mechanism for imparting selected R--.THETA. movement to the blade to load and unload wafers at the external elevator, internal elevator and individual process chambers. The system is uniquely adapted for enabling various types of IC processing including etch, deposition, sputtering and rapid thermal annealing chambers, thereby providing the opportunity for multiple step, sequential processing using different processes.

Abstract: A process for etching single crystal silicon, polysilicon, silicide and polycide using iodinate or brominate gas chemistry, is disclosed. The iodinate/brominate gas chemistry etches narrow deep trenches with very high aspect ratios and good profile control and without black silicon formation or other undesirable phenomena.

Abstract: A method for protecting a selected area of a substrate against deposition on the selected area. The method includes the steps of flowing a process gas into a substrate processing chamber and flowing a purge gas to the selected area of the substrate to prevent the process gas from contacting the selected area or minimize contact between the process gas and the selected area. In various embodiments the selected area is a backside periphery of the substrate or the edge of the substrate. Also in these embodiments, the process gas is flowed into a deposition zone in order to deposit a thin film layer over an upper surface of the substrate, and a flow of the process and purge gas is established such that the process gas flows radically across the upper surface of the substrate, combines with the purge gas near an edge of the substrate and exits the processing chamber through an exhaust system.

Abstract: A substrate processing reactor capable of thermal CVD, plasma-enhanced CVD, plasma-assisted etchback, plasma self-cleaning and other substrate processing operations all of which can either be performed separately or as part of in-situ multiple step processing. The reactor incorporates a uniform radial gas pumping system which enables uniform reactant gas flow across the wafer. Also included are upper and lower purge gas dispersers. The upper purge gas disperser directs purge gas flow downwardly toward the periphery of the wafer while the lower gas disperser directs purge gas across the backside of the wafer. The radial pumping gas system and purge gas dispersers sweep radially away from the wafer to prevent deposition external to the wafer and keep the chamber clean.

Abstract: A process for cleaning a reactor chamber both locally adjacent the RF electrodes and also throughout the chamber and the exhaust system to the including components such as the throttle valve. Preferably, a two-step continuous etch sequence is used in which the first step uses relatively high pressure, close electrode spacing and fluorocarbon gas chemistry for etching the electodes locally and the second step uses relatively lower pressure, farther electrode spacing and fluorinated gas chemistry for etching throughout the chamber and exhaust system. The local and extended etch steps may be used separately as well as together.

Abstract: A high pressure, high throughput, single wafer, semiconductor processing reactor is disclosed which is capable of thermal CVD, plasma-enhanced CVD, plasma-assisted etchback, plasma self-cleaning, and deposition topography modification by sputtering, either separately or as part of in-situ multiple step processing. The reactor includes cooperating arrays of interdigitated susceptor and wafer support fingers which collectively remove the wafer from a robot transfer blade and position the wafer with variable, controlled, close parallel spacing between the wafer and the chamber gas inlet manifold, then return the wafer to the blade. A combined RF/gas feed-through device protects against process gas leaks and applies RF energy to the gas inlet manifold without internal breakdown or deposition of the gas. The gas inlet manifold is adapted for providing uniform gas flow over the wafer.