Abstract: In one aspect, a substrate processing apparatus is provided. The apparatus comprises a mechanism for forming a meniscus on a surface of a substrate by moving the substrate through a fluid; an air knife apparatus positioned to apply an air knife to shorten the meniscus formed on the surface of the substrate; and a drying vapor nozzle positioned to direct a drying vapor to the meniscus shortened by the air knife. Numerous other aspects are provided.

Abstract: Pad-assisted electropolishing of the substrate is conducted by performing anodic dissolution of metal at a first portion of the substrate and simultaneously mechanically buffing a second portion of the substrate with a buffing pad. Anodic dissolution includes forming a thin liquid layer of electropolishing liquid between the anodic substrate and a cathodic electropolishing head. The location of electrical contacts between the substrate and power supply allow peripheral edge regions of the substrate to be mechanically buffed with the pad. Preferably, a substrate is further planararized using an isotropic material-removal technique. An apparatus includes an electropolishing head that is movable to a position proximate to a first portion of a substrate to form a thin gap, and a buffing pad that mechanically buffs a second portion of the substrate using minimal pressure.

Abstract: Pad-assisted electropolishing of the substrate is conducted by performing anodic dissolution of metal at a first portion of the substrate and simultaneously mechanically buffing a second portion of the substrate with a buffing pad. Anodic dissolution includes forming a thin liquid layer of electropolishing liquid between the anodic substrate and a cathodic electropolishing head. The location of electrical contacts between the substrate and power supply allow peripheral edge regions of the substrate to be mechanically buffed with the pad. Preferably, a substrate is further planararized using an isotropic material-removal technique. An apparatus includes an electropolishing head that is movable to a position proximate to a first portion of a substrate to form a thin gap, and a buffing pad that mechanically buffs a second portion of the substrate using minimal pressure.

Abstract: Pad-assisted electropolishing of the substrate is conducted by performing anodic dissolution of metal at a first portion of the substrate and simultaneously mechanically buffing a second portion of the substrate with a buffing pad. Anodic dissolution includes forming a thin liquid layer of electropolishing liquid between the anodic substrate and a cathodic electropolishing head. The location of electrical contacts between the substrate and power supply allow peripheral edge regions of the substrate to be mechanically buffed with the pad. Preferably, a substrate is further planararized using an isotropic material-removal technique. An apparatus includes an electropolishing head that is movable to a position proximate to a first portion of a substrate to form a thin gap, and a buffing pad that mechanically buffs a second portion of the substrate using minimal pressure.

Abstract: In one aspect, an apparatus is provided. The apparatus comprises a chamber; a plurality of rollers adapted to support a wafer in a vertical orientation within a chamber; a pair of brushes adapted to scrub a first and a second side of the wafer respectively; a first spray bar adapted to spray a liquid on the wafer to form a meniscus on the wafer as the wafer is lifted out of the chamber; and a second spray bar adapted to direct a vapor to the meniscus, the vapor being adapted to lower a surface tension of the liquid at the meniscus to perform Marangoni drying of the wafer as the wafer is lifted out of the chamber. Numerous other aspects are provided.

Abstract: In one aspect, a substrate processing apparatus is provided. The apparatus comprises a mechanism for forming a meniscus on a surface of a substrate by moving the substrate through a fluid; an air knife apparatus positioned to apply an air knife to shorten the meniscus formed on the surface of the substrate; and a drying vapor nozzle positioned to direct a drying vapor to the meniscus shortened by the air knife. Numerous other aspects are provided.

Abstract: In one aspect, a method is provided. The method comprises forming a meniscus at an interface between a substrate and a fluid surface by moving the substrate through the fluid; shortening the meniscus by applying an air knife to the meniscus at the interface between the substrate and the fluid surface; and Marangoni drying the substrate by applying a drying vapor to the shortened meniscus. Numerous other aspects are provided.

Abstract: A dilution stage is adapted to supply a dilute chemistry to a semiconductor device processing apparatus. The dilution stage includes a first vessel adapted to store the chemistry after dilution and a second vessel adapted to store the chemistry prior to dilution. The dilution stage may also include a control mechanism which is adapted to selectively control flowing of the chemistry and a dilutant to the first vessel. The control mechanism may be operative to fill the second vessel with the chemistry, and to flow the dilutant to the first vessel via the second vessel.

Abstract: A method for polishing a metal layer on a workpiece is provided wherein relative motion is produced between the metal layer and a polishing surface and wherein the metal layer has a polish resistant film thereon. The metal layer is first pre-treated to substantially remove the polish resistant film. Next, the metal layer is polished at low pressure between the metal layer and the polishing surface in the presence of a polishing solution. The pretreating may be accomplished by, for example, sputtering, polishing the polish-resistant film in the presence of abrasive polishing solution, polishing the polish-resistant film at higher pressures between the film and the polishing surface, maintaining the temperature of the pretreating step to be substantially between 10 degrees Centigrade and 30 degrees Centigrade, and chemically removing the film.

Abstract: A dilution stage is adapted to supply a dilute chemistry to a semiconductor device processing apparatus. The dilution stage includes a first vessel adapted to store the chemistry after dilution and a second vessel adapted to store the chemistry prior to dilution. The dilution stage may also include a control mechanism which is adapted to selectively control flowing of the chemistry and a dilutant to the first vessel. The control mechanism may be operative to fill the second vessel with the chemistry, and to flow the dilutant to the first vessel via the second vessel.

Abstract: A dilution stage is adapted to supply a dilute chemistry to a semiconductor device processing apparatus. The dilution stage includes a first vessel adapted to store the chemistry after dilution and a second vessel adapted to store the chemistry prior to dilution. The dilution stage may also include a control mechanism which is adapted to selectively control flowing of the chemistry and a dilutant to the first vessel. The control mechanism may be operative to fill the second vessel with the chemistry, and to flow the dilutant to the first vessel via the second vessel.

Abstract: In one embodiment, a method for cleaning a chemical mechanical polishing (CMP) pad is provided. The CMP pad surface has a residue thereon. Chemicals are applied onto the surface of the CMP pad and the pad surface is rinsed so as to substantially remove by-product produced by the chemicals. A mechanical conditioning operation is performed on the surface of the pad. The wafer surface includes copper and oxide during the CMP operation.

Abstract: An apparatus is provided for scrubbing and drying a wafer. The apparatus comprises a chamber, a plurality of rollers adapted to support a wafer in a vertical orientation within the chamber, a pair of brushes adapted to respectively scrub a first and a second side of the wafer, a first spray bar adapted to spray a liquid on the wafer to thereby form a meniscus on the wafer as the wafer is lifted out of the chamber, and a second spray bar adapted to direct a vapor to the meniscus, the vapor being adapted to lower a surface tension of the liquid at the meniscus to thereby perform Marangoni drying of the wafer as the wafer is lifted out of the chamber. Also provided is a method of cleaning and drying a wafer. The method comprises scrubbing a wafer in a vertical orientation, lifting the wafer, spraying a fluid on the wafer as the wafer is lifted, thereby forming a meniscus on the surface of the wafer, and directing a drying vapor to the meniscus as the wafer is lifted, thereby Marangoni drying the wafer.

Abstract: A dilution stage is adapted to supply a dilute chemistry to a semiconductor device processing apparatus. The dilution stage includes a first vessel adapted to store the chemistry after dilution and a second vessel adapted to store the chemistry prior to dilution. The dilution stage may also include a control mechanism which is adapted to selectively control flowing of the chemistry and a dilutant to the first vessel. The control mechanism may be operative to fill the second vessel with the chemistry, and to flow the dilutant to the first vessel via the second vessel.

Abstract: In one aspect, a method of drying a substrate includes (1) setting a gas delivery angle for an air knife used during an immersion-drying process; (2) using the air knife during immersion drying of a hydrophilic substrate; and (3) using the air knife during immersion drying of a hydrophobic substrate. The gas delivery angle is unchanged during immersion drying of both the hydrophilic substrate and hydrophobic substrate. Numerous other aspects are provided.

Abstract: A method that involves spraying a liquid agitated with a sonic wave at a megasonic frequency onto a substrate from a nozzle positioned over the substrate. Simultaneously, the substrate is spun above 300 RPM while the nozzle is swept over the substrate. The substrate may be brushed in a brush station before agitating the liquid with the sonic wave. An apparatus having an arm in fluid communication with a nozzle that has an angular position &thgr; greater than 0°. Also, there is a substrate spinner positioned below the nozzle.

Abstract: The present invention describes a method and apparatus used in a substrate cleaning system wherein a substrate is placed into a first brush station while a chemical solution is delivered to the first brush station at a desired concentration level. The substrate is then scrubbed in the first brush station. After the substrate is scrubbed in the first brush station the substrate is transferred to a second brush station. The chemical solution used in the first brush station is then delivered to a brush in the second brush station in a ramp up manner in order to clean the brush in the second brush station. The delivery of the chemical solution to the second brush station is then stopped and deionized water is delivered to the second brush station. The substrate is then scrubbed using the deionized water in order to rinse the chemical solution from the substrate prior to transferring the substrate from the second brush station to another processing station.

Abstract: The present invention describes a method of cleaning a substrate wherein the substrate is placed into a first brush station while a chemical solution is delivered to the first brush station at a desired cleaning level. The substrate is then scrubbed in the first brush station. After the substrate is scrubbed in the first brush station the substrate is transferred to a second brush station. The chemical solution used in the first brush station is then delivered to a brush in the second brush station in a ramp up manner in order to clean the brush in the second brush station. The delivery of the chemical solution to the second brush station is then stopped and deionized water is delivered to the second brush station. The substrate is then scrubbed using the deionized water in order to rinse the chemical solution from the substrate prior to transferring the substrate from the second brush station to another processing station.