Abstract: Embodiments of the invention generally provide a substrate processing system and method. The substrate processing system generally includes a fluid basin configured to contain a plating solution therein, an anode assembly positioned in a lower portion of the fluid basin, a separation membrane positioned across the fluid basin above the anode assembly, a diffusion member positioned across the fluid basin above the separation membrane, and a plating membrane positioned across the fluid basin above the diffusion member.

Abstract: Embodiments of the present invention provide a process sequence and related hardware for filling a patterned feature on a substrate with a metal, such as copper. The sequence comprises first forming a reliable barrier layer in the patterned feature to prevent diffusion of the metal into the dielectric layer through which the patterned feature is formed. One sequence comprises forming a generally conformal barrier layer over a patterned dielectric, etching the barrier layer at the bottom of the patterned feature, depositing a second barrier layer, and then filling the patterned feature with a metal, such as copper.

Abstract: A component for a substrate processing chamber comprises a structure having a textured coating with surface grains. The component is evaluated by directing a beam of electrons onto the textured coating of the component to cause at least some of the electrons to be backscattered. The backscattered electrons are detected and a signal image is generated. The component is selected when the signal image exhibits surface grains sized from about 0.1 to about 5 micron. In one version, the component is also selected when the grains are substantially flower shaped.

Abstract: Methods system and apparatus, including computer program products, for monitoring polishing a substrate. A polishing pad mounted on a platen, is rotated at a first rotation rate, and a carrier head is rotated at a second rotation rate that is different from the first rotation rate. The carrier head carries a substrate and presses the substrate against the polishing pad. A sequence of data traces is acquired using a sensor mounted in the platen, wherein each data trace results from a separate scan with the sensor along a path across the substrate, and wherein the first and second rotation rates are such that a plurality of paths corresponding to a predetermined number of consecutive scans are substantially evenly radially distributed across the substrate.

Abstract: An apparatus for providing an electrical bias to a substrate in a processing system is described. The apparatus generally includes a conductive annular body defining a central opening. The conductive annular body may have a substrate seating surface adapted to receive the substrate and a plurality of scallops formed on a surface opposing the substrate seating surface. A plurality of electrical contacts may be formed on the substrate seating surface opposite the plurality of scallops. The electrical contacts may be adapted to engage a plating surface of the substrate.

Abstract: A local area of a sample is focally heated to produce a transient physical deformation. The surface of the structure is optically monitored while the heated area cools to a baseline temperature by illuminating the heated region with one or more probe beams from time to time and detecting returning light. In some embodiments heat dissipation within the structure is correlated with change in optical reflectivity over time. In other embodiments, surface deformation of the structure is correlated with changes in light scattering from the surface. Following application of a pump pulse and no more than 3 probe pulses, a time varying returning light signal is compared with a corresponding returning light signal from a reference. An anomaly in the sample is indicated by a deviation between the two signals. First-degree exponential decay curves may be constructed from the signals, and their decay constants compared.

Abstract: A method, composition, and computer readable medium for planarizing a substrate. In one aspect, the composition includes one or more chelating agents and ions of at least one transition metal, one or more surfactants, one or more oxidizers, one or more corrosion inhibitors, and deionized water. The composition may further comprise one or more agents to adjust the pH and/or abrasive particles. The method comprises planarizing a substrate using a composition including one or more chelating agents and ions of at least one transition metal.

Abstract: Methods and apparatus for feedback controlled polishing. A computer program product for generating feedback for chemical mechanical polishing. The product includes instructions operable to cause a processor to receive monitoring information during a current polishing cycle in which a first polishing process is performed on a substrate that includes a metal layer. The first polishing process clears the metal layer from the substrate during the current polishing cycle. The product includes instructions to calculate a representation of a clearing profile of the first polishing process. The calculation is based on the monitoring information received during the current polishing cycle. The product includes instructions to detect non-uniformity in the representation. The product includes instructions to generate, from the non-uniformity detected, feedback information for improving the uniformity of a clearing profile of the first polishing process for a subsequent polishing cycle.

Abstract: A method and apparatus for depositing a low dielectric constant film by reaction of an organo silane compound and an oxidizing gas. The oxidized organo silane film has excellent barrier properties for use as a liner or cap layer adjacent other dielectric layers. The oxidized organo silane film can also be used as an etch stop or an intermetal dielectric layer for fabricating dual damascene structures. The oxidized organo silane films also provide excellent adhesion between different dielectric layers. A preferred oxidized organo silane film is produced by reaction of methyl silane, CH3SiH3, and N2O.

Abstract: A substrate heater assembly for supporting a substrate of a predetermined standardized diameter during processing is provided. In one embodiment, the substrate heater assembly includes a body having an upper surface, a lower surface and an embedded heating element. A substrate support surface is formed in the upper surface of the body and defines a portion of a substrate receiving pocket. An annular wall is oriented perpendicular to the upper surface and has a length of at least one half a thickness of the substrate. The wall bounds an outer perimeter of the substrate receiving pocket and has a diameter less than about 0.5 mm greater than the predetermined substrate diameter.

Abstract: The present invention is a method of assisting the rinsing of a wafer in a single wafer cleaning apparatus. According to the present invention, after exposing a wafer to a cleaning and/or etching solution, the cleaning or etching solution is removed from the wafer by spinning the wafer and dispensing or spraying DI water onto the wafer as it is spun. The centrifugal force of the spinning wafer enhances the rinsing of the wafer. In order to enhance the rinsing of the wafer, in an embodiment of the present invention a solution having a lower surface tension than water, such as but not limited to isopropyl alcohol (IPA) is dispensed in liquid or vapor form onto the wafer after the DI water. In a specific embodiment of the present invention, the vapor of a solution with a lower surface tension than DI water, such as IPA vapor, is blown on the wafer in order to break up the DI water bulging up at the center of the spinning wafer.

Abstract: A technique and apparatus is disclosed for the optical monitoring and measurement of a thin film (or small region on a surface) undergoing thickness and other changes while it is rotating. An optical signal is routed from the monitored area through the axis of rotation and decoupled from the monitored rotating area. The signal can then be analyzed to determine an endpoint to the planarization process. The invention utilizes interferometric and spectrophotometric optical measurement techniques for the in situ, real-time endpoint control of chemical-mechanical polishing planarization in the fabrication of semiconductor or various optical devices. The apparatus utilizes a bifurcated fiber optic cable to monitor changes on the surface of the thin film.

Abstract: Embodiments of the invention generally provide an apparatus and a method for providing a uniform thermal profile to a plurality of substrates during heat processing. In one embodiment, a cassette containing one or more heated substrate supports is moveably disposed within a heating chamber having an about uniform thermal profile therein to more uniformly heat the substrates.

Abstract: A gas inlet manifold for a plasma chamber having a perforated gas distribution plate suspended by flexible side walls. The flexible suspension minimizes mechanical stress due to thermal expansion of the gas distribution plate. In another aspect, the suspension provides thermal isolation between the gas distribution plate and other components of the chamber.

Abstract: The thickness of a layer on a substrate is measured in-situ during chemical mechanical polishing. A light beam is divided through a window in a polishing pad, and the motion of the polishing pad relative to the substrate causes the light beam to move in a path across the substrate surface. An interference signal produced by the light beam reflecting off the substrate is monitored, and a plurality of intensity measurements are extracted from the interference signal. Each intensity measurement corresponds to a sampling zone in the path across the substrate surface. A radial position is determined for each sampling zone, and the intensity measurements are divided into a plurality of radial ranges according to the radial positions. The layer thickness is computed for each radial range from the intensity measurements associated with that radial range.

Abstract: A method of depositing a low dielectric constant film on a substrate and post-treating the low dielectric constant film is provided. The post-treatment includes rapidly heating the low dielectric constant film to a desired high temperature and then rapidly cooling the low dielectric constant film such that the low dielectric constant film is exposed to the desired high temperature for about five seconds or less. In one aspect, the post-treatment also includes exposing the low dielectric constant film to an electron beam treatment and/or UV radiation.

Abstract: A dual-position magnetron that is rotated about a central axis in back of a sputtering target, particularly for sputtering an edge of a target of a barrier material onto a wafer and cleaning material redeposited at a center of the target. During target cleaning, wafer bias is reduced. In one embodiment, an arc-shaped magnetron is supported on a pivot arm pivoting on the end of a bracket fixed to the rotary shaft. A spring biases the pivot arm such that the magnetron is urged towards and overlies the target center. Centrifugal force at increased rotation rate overcomes the spring bias and shift the magnetron to an outer position with the long magnetron dimension aligned with the target edge. Mechanical stops prevent excessive movement in either direction. Other mechanisms include linear slides and actuators.

Abstract: Method and apparatus for etching a metal layer disposed on a substrate, such as a photomask, are provided. In one aspect, a method is provided for processing a substrate including positioning the substrate in a processing chamber, introducing a processing gas comprising (i) hydrogen chloride, (ii) an oxygen containing gas, (iii) another chlorine containing gas, and optionally, (iv) an inert gas into the processing chamber, wherein the substrate is maintained at a reduced temperature, and the processing gas is excited into a plasma state at a reduced power level to etch exposed portions of the metal layer disposed on the substrate.

Abstract: A transfer chamber for a substrate processing tool includes a main body having side walls adapted to couple to at least one processing chamber and at least one load lock chamber. The main body houses at least a portion of a robot adapted to transport a substrate between the processing chamber and the load lock chamber. A lid couples to and seals a top of the main body of the transfer chamber. The transfer chamber also has a domed bottom adapted to couple to and to seal a bottom portion of the main body of the transfer chamber.

Abstract: Techniques for polishing a wafer (10) include closed-loop control. The wafer can be held by a carrier head (100) having at least one chamber whose pressure is controlled to apply a downward force on the wafer. Thickness-related measurements of the wafer can be obtained during polishing and a thickness profile for the wafer is calculated based on the thickness-related measurements. The calculated thickness profile is compared to a target thickness profile. The pressure in at least one carrier head chamber is adjusted based on results of the comparison. The carrier head chamber pressures can be adjusted to control the amount of downward force applied to the wafer during polishing and/or to control the size of a loading area on the wafer against which the downward force is applied.