Abstract: A vacuum loadlock is provided for housing a pair of wafers in proper alignment for concurrent processing. In one embodiment, a single chamber loadlock is provided with a gas diffuser disposed therein to decrease venting times within the loadlock. In another embodiment, a dual chamber loadlock is provided having first and second isolatable region disposed adjacent a transfer region to increase throughput of the system.

Abstract: The invention is embodied in a plasma reactor having a vacuum chamber with a cylindrical side portion and a ceiling at a certain height above the top of the cylindrical side portion, a wafer-holding pedestal near the bottom of the vacuum chamber, gas injection ports near the cylindrical side portion and a vacuum pump, the reactor including a generally planar disk-shaped conductive ceiling electrode adjacent the ceiling, a helical coil antenna having a bottom winding near the top of the cylindrical side portion and a top winding generally corresponding to the second diameter near the planar disk-shaped conductive ceiling electrode, the helical coil antenna substantially spanning the height between the top of the cylindrical side portion and the ceiling, and a switch for individually connecting each one of the coil antenna, the ceiling electrode and the wafer pedestal to one of (a) a respective RF power source or (b) ground or (c) a floating potential (i.e., unconnected to any potential source).

Abstract: The present invention generally provides a cassette-to-cassette vacuum processing system which concurrently processes multiple wafers and combines the advantages of single wafer process chambers and multiple wafer handling for high quality wafer processing, high wafer throughput and reduced footprint. In accordance with one aspect of the invention, the system is preferably a staged vacuum system which generally includes a loadlock chamber for introducing wafers into the system and which also provides wafer cooling following processing, a transfer chamber for housing a wafer handler, and one or more processing chambers each having two or more processing regions which are isolatable from each other and preferably share a common gas supply and a common exhaust pump. The processing regions also preferably include separate gas distribution assemblies and RF power sources to provide a uniform plasma density over a wafer surface in each processing region.

Abstract: A process chamber is disclosed which provides a 360.degree. circular gas/vacuum distribution over a substrate being processed. The substrate being processed is supported on a heated and optionally cooled pedestal assembly. The substrate faces a one-piece gas distribution faceplate being connected to an RF power supply outside the vacuum environment of the processing chamber. A pumping channel view port is provided to verify and confirm instrumentation readings concerning the degree of surface deposition on process chamber internal surfaces. All process chamber wall surfaces facing the region where plasma will be present during processing (except the gas distribution faceplate) are ceramic and therefore highly resistant to corrosion. The pedestal an un-anodized metal is also covered with a loosely fitting ceramic surface having alignment features to maintain concentricity between the wafer support surface of the pedestal and the wafer being processed.

Abstract: The present invention provides a remote plasma source mountable on a process chamber and connectable on one end to a gas inletting system and on the other end to a gas distribution system disposed in a process chamber. Preferably, a conventional microwave generator is utilized to deliver microwaves into a remote chamber to excite a gas passed therethrough into an excited state.

Abstract: A multi-blade wafer handling device is provided to concurrently move two or more wafers through a vacuum processing system. The wafer handling device includes two motors magnetically coupled into a transfer chamber to move an arm assembly connected to a dual blade assembly. The preferred wafer handling device includes a first rotating member operated by the first motor, a second rotating member operated by the second motor, a blade assembly having at least first and second wafer blades wherein the wafer blades are co-planar, and an arm assembly connecting the first and second rotating members to the blade assembly.

Abstract: A semiconductor wafer processing system for processing wafers from a wafer storage cassette includes a wafer transfer chamber; a wafer storage elevator within the transfer chamber; one or more wafer processing chambers; and a wafer transfer apparatus for transferring a wafer between a standard storage cassette adjacent and outside the transfer chamber and the elevator, and between the elevator and the processing chamber. The storage chamber pressure varies between atmospheric when accepting wafers from outside, and a subatmospheric pressure when transferring wafers to or from a processing chamber. The transfer apparatus includes a robot arm; a thin flat wafer carrying blade at the leading end of the robot arm configured for engaging a wafer from the storage cassette or the elevator; and a wafer support tray configured for removable engagement with the blade and for engaging and positively positioning a wafer from the elevator, or a support pedestal within a processing chamber.

Abstract: A semiconductor wafer processing system for processing wafers from a wafer storage cassette includes a wafer transfer chamber; a wafer storage elevator within the transfer chamber; one or more wafer processing chambers; and a wafer transfer apparatus for transferring a wafer between a standard storage cassette adjacent and outside the transfer chamber and the elevator, and between the elevator and the processing chamber. The storage chamber pressure varies between atmospheric when accepting wafers from outside, and a subatmospheric pressure when transferring wafers to or from a processing chamber. The transfer apparatus includes a robot arm; a thin flat wafer carrying blade at the leading end of the robot arm configured for engaging a wafer from the storage cassette or the elevator; and a wafer support tray configured for removable engagement with the blade and for engaging and positively positioning a wafer from the elevator, or a support pedestal within a processing chamber.

Abstract: In one aspect, the invention is embodied in an RF inductively coupled plasma reactor including a vacuum chamber for processing a wafer, one or more gas sources for introducing into the chamber reactant gases, and an antenna capable of radiating RF energy into the chamber to generate a plasma therein by inductive coupling, the antenna lying in a two-dimensionally curved surface. In another aspect, invention is embodied in a plasma reactor including apparatus for spraying a reactant gas at a supersonic velocity toward the portion of the chamber overlying the wafer. In a still further aspect, the invention is embodied in a plasma reactor including a planar spray showerhead for spraying a reactant gas into the portion of the chamber overlying the wafer with plural spray nozzle openings facing the wafer, and plural magnets in an interior portion of the planar spray nozzle between adjacent ones of the plural nozzle openings, the plural magnets being oriented so as to repel ions from the spray nozzle openings.

Abstract: A semiconductor wafer processing system for processing wafers from a wafer storage cassette includes a wafer transfer chamber; a wafer storage elevator within the transfer chamber; one or more wafer processing chambers; and a wafer transfer apparatus for transferring a wafer between a standard storage cassette adjacent and outside the transfer chamber and the elevator, and between the elevator and the processing chamber. The storage chamber pressure varies between atmospheric when accepting wafers from outside, and a subatmospheric pressure when transferring wafers to or from a processing chamber. The transfer apparatus includes a robot arm; a thin flat wafer carrying blade at the leading end of the robot arm configured for engaging a wafer from the storage cassette or the elevator; and a wafer support tray configured for removable engagement with the blade and for engaging and positively positioning a wafer from the elevator, or a support pedestal within a processing chamber.

Abstract: A process chamber is disclosed which provides a 360.degree. circular gas/vacuum distribution over a substrate being processed. The substrate being processed is supported on a heated and optionally cooled pedestal assembly. The substrate faces a one-piece gas distribution faceplate being connected to an RF power supply outside the vacuum environment of the processing chamber. A pumping channel view port is provided to verify and confirm instrumentation readings concerning the degree of surface deposition on process chamber internal surfaces. All process chamber wall surfaces facing the region where plasma will be present during processing (except the gas distribution faceplate) are ceramic and therefore highly resistant to corrosion. The pedestal an un-anodized metal is also covered with a loosely fitting ceramic surface having alignment features to maintain concentricity between the wafer support surface of the pedestal and the wafer being processed.

Abstract: A semiconductor wafer processing system for processing wafers from a wafer storage cassette includes a wafer transfer chamber; a wafer storage elevator within the transfer chamber; one or more wafer processing chambers; and a wafer transfer apparatus for transferring a wafer between a standard storage cassette adjacent and outside the transfer chamber and the elevator, and between the elevator and the processing chamber. The environment of the storage chamber varies in pressure between atmospheric when accepting wafers from outside, and a subatmospheric pressure when transferring wafers to or from a processing chamber.

Abstract: A method for preventing cross-contamination of semiconductor wafers during processing comprising covering a surface portion of a support assembly with a process compatible material, engaging a semiconductor wafer with the support assembly, processing the wafer while it is engaged with the support member, and removing the process compatible material from the support assembly after said material is considered to be contaminated. A shield particularly adapted for this process includes a shield portion made from a process compatible material and a process-compatible adhesive for attaching the shield portion to the support assembly.

Abstract: A method for preventing cross-contamination of semiconductor wafers during processing comprising covering a surface portion of a support assembly with a process compatible material, engaging a semiconductor wafer with the support assembly, processing the wafer while it is engaged with the support member, and removing the process compatible material from the support assembly after said material is considered to be contaminated. A shield particularly adapted for this process includes a shield portion made from a process compatible material and a process-compatible adhesive for attaching the shield portion to the support assembly.