Abstract: A dispersion plate for evenly flowing at low pressure into a processing chamber vaporized material, such as a tungsten compound for deposition of metal layers onto a semiconductor, has a disc-like body with a center axis, an input face and an output face. The dispersion plate has a cup-like entrance along the center axis in its input face for receiving a stream of vaporized material and a plurality of passages for flow of vapor with each passage having a length and a diameter and extending radially from the entrance like the spokes of a wheel at inclined angles relative to the center axis from the input face to the output face. Two annular grooves are cut into the output face and intersect with the respective ends of the passages. The plate has a center hole with a flared diameter extending along the center axis from the entrance in the input face to the output face.

Abstract: The present invention provides a semiconductor fabrication process and cluster tool utilizing individual gas boxes for each of the processing chambers. These individual gas boxes provide an enclosure where groupings of related gas components may be positioned above and/or adjacent to the semiconductor processing chamber requiring those objects or components. The proximity of the individual gas boxes to the respective processing chambers facilitates the delivery of gases to the chamber as needed. Furthermore, the individual gas panels enable a modular design comprising a processing chamber and gas panel combination. This modular design allows individual chambers and their respective gas panels to be run through various pre-installation tests.

Abstract: A temperature-controlled exhaust assembly with cold trap capability. One embodiment of the exhaust assembly comprises a multi-heater design which allows for independent multi-zone closed-loop temperature control. Another embodiment comprises a compact multi-valve uni-body design incorporating a single heater for simplified closed-loop temperature control. The cold trap incorporates a heater for temperature control at the inlet of the trap to minimize undesirable deposits. One embodiment also comprises a multi-stage cold trap and a particle trap. As a removable unit, this cold trap provides additional safety in the handling and disposal of the adsorbed condensables.

Abstract: A temperature-controlled exhaust assembly with cold trap capability. One embodiment of the exhaust assembly comprises a multi-heater design which allows for independent multi-zone closed-loop temperature control. Another embodiment comprises a compact multi-valve uni-body design incorporating a single heater for simplified closed-loop temperature control. The cold trap incorporates a heater for temperature control at the inlet of the trap to minimize undesirable deposits. One embodiment also comprises a multi-stage cold trap and a particle trap. As a removable unit, this cold trap provides additional safety in the handling and disposal of the adsorbed condensables.

Abstract: A wafer pedestal with a purge ring that circumscribes a peripheral edge of the wafer pedestal. The purge ring contains plurality of passages that are located proximate the peripheral edge of said wafer pedestal such that purge gas is directed towards the peripheral edge. Additionally, the purge ring cooperates with an edge ring assembly that circumscribes the purge ring. The purge ring and the edge ring assembly allow a dual-purge flow pattern to be established, which significantly reduces the accumulation of undesirable deposits upon the wafer pedestal.

Abstract: Vacuum CVD chambers are disclosed which provide a more uniformly deposited thin film on a substrate. The chamber susceptor mount for the substrate is heated resistively with a single coil firmly contacting the metal of the susceptor on all sides, providing uniform temperatures across the susceptor mount for a substrate. A purge gas line is connected to openings in the susceptor outside of the periphery of the substrate to prevent edge and backside contamination of the substrate. A vacuum feed line mounts the substrate to the susceptor plate during processing. A refractory purge guide, or a plurality of placement pins, maintain a fixed gap passage for the purge gases to pass alongside the edge of the wafer and into the processing area of the chamber. An exhaust pumping plate improves the uniformity of exhaustion of spent gases from the chamber.

Abstract: A substrate processing chamber, particularly a chemical vapor deposition (CVD) chamber used both for thermal deposition of a conductive material and a subsequently performed plasma process. The invention reduces thermal deposition of the conductive material on peripheral portions of the pedestal supporting a wafer and in a pumping channel exhausting the chamber. A peripheral ring placed on the pedestal, preferably also used to center the wafer, is thermally isolated from the pedestal so that its temperature is kept substantially lower than that of the wafer. The processing chamber includes a chamber lid assembly having an isolator ring member that has a sloping surface for confirming the plasma within a processing zone of the processing chamber while the wafer is being processed therein. A method for forming a CVD layer on a wafer comprising elevating the pedestal until an upper pedestal surface of the pedestal extends above a lower edge of the isolator ring member.

Abstract: Vacuum CVD chambers are disclosed which provide a more uniformly deposited thin film on a substrate. The chamber susceptor mount for the substrate is heated resistively with a single coil firmly contacting the metal of the susceptor on all sides, providing uniform temperatures across the susceptor mount for a substrate. A purge gas line is connected to openings in the susceptor outside of the periphery of the substrate to prevent edge and backside contamination of the substrate. A vacuum feed line mounts the substrate to the susceptor plate during processing. A refractory purge guide, or a plurality of placement pins, maintain a fixed gap passage for the purge gases to pass alongside the edge of the wafer and into the processing area of the chamber. An exhaust pumping plate improves the uniformity of exhaustion of spent gases from the chamber.

Abstract: This invention provides a method and apparatus for supporting a wafer in a processing chamber, where the wafer is supported and heated from below via a heater pedestal having a diameter larger than that of the wafer. A process fluid flowing downward toward the top of the wafer is inhibited from depositing near the wafer edge by a shadow ring. The shadow ring, which is placed over but does not contact the wafer, physically masks an annular strip of the wafer near its edge. The shadow ring inhibits deposition of process fluides on the wafer in two distinct ways. First, the shadow ring physically obstructs process gas, flowing downward from above the wafer, from depositing on the masked portion of the wafer. Second, the shadow ring is used to direct a flow of a purge gas to inhibit process gas from seeping under the shadow ring and depositing near the wafer edge. A purge gas manifold is defined by a cylindrical annulus located concentrically below the shadow ring and circumscribing the heater pedestal.

Abstract: An improved deposition chamber deposits useful layers on substrates. The improved chamber includes a substrate edge protection system which, in combination with a purge gas, protects selected portions of the edge and underside of the substrate from the deposition gas while preventing the creation of a masked area on the substrate edge. The substrate is supported on a solid receiving plate, and a positioning assembly aligns the substrate to the receiving plate. In some embodiments, the invention may include a stem interconnected to the substrate, a heat limiting member disposed about the stem, and a shroud extending about the stem.

Abstract: Vacuum CVD chambers are disclosed which provide a more uniformly deposited thin film on a substrate. The chamber susceptor mount for the substrate is heated resistively with a single coil firmly contacting the metal of the susceptor on all sides, providing uniform temperatures across the susceptor mount for a substrate. A purge gas line is connected to openings in the susceptor outside of the periphery of the substrate to prevent edge and backside contamination of the substrate. A vacuum feed line mounts the substrate to the susceptor plate during processing. A refractory purge guide, or a plurality of placement pins, maintain a fixed gap passage for the purge gases to pass alongside the edge of the wafer and into the processing area of the chamber. An exhaust pumping plate improves the uniformity of exhaustion of spent gases from the chamber.

Abstract: A apparatus for removing deposits from within a space at least partially delimited by a surface which is subject to attack from a plasma including a surface cover comprising a material which is inert to the plasma.

Abstract: An improved deposition chamber deposits useful layers on substrates. The improved chamber includes a substrate edge protection system which, in combination with a purge gas, protects selected portions of the edge and underside of the substrate from the deposition gas while preventing the creation of a masked area on the substrate edge. The substrate edge protection system includes a ring, which is received over a substrate received on the substrate support member and which is alignable with the substrate to provide a minimum gap between the edge of the substrate and the ring.

Abstract: A substrate processing apparatus comprising a processing chamber in which a substrate support is located. The substrate support, which is in the form of a heater pedestal, has a surface dimensioned to receive the substrate, and is circumscribed by a removable purge ring which defines an annulus between itself and the pedestal. At the outer edge of the pedestal is a purge gas manifold, in the form of a cavity between the purge ring and the pedestal. The lower end of the manifold is sealed by means of a mechanical seal that is formed at process temperature as the pedestal expands from heating and comes into contact with the purge ring's lower edge. The upper end of the manifold opens into the annulus defined by the purge ring and the pedestal. The manifold is arranged so that during processing, purge gas is injected into the manifold and projected toward the edge of a substrate received on the surface of the pedestal.

Abstract: A process for removing deposits from within a space at least partially delimited by a surface which is subject to attack from a plasma includes the steps of placing on the surface a cover comprising a material which is inert to the plasma, and then removing the deposits.

Abstract: An improved deposition chamber deposits useful layers on substrates. The improved chamber includes a substrate edge protection system which, in combination with a purge gas, protects selected portions of the edge and underside of the substrate from the deposition gas while preventing the creation of a masked area on the substrate edge. The substrate is supported on a solid receiving plate, which is supported by a stem having a heat limiting member and a shroud to protect the stem and a positioning assembly aligns the substrate to the receiving plate.