Abstract: High through-put CMP is achieved by the application of a cleaning composition on to an exposed surface of a metal layer prior to polishing the bulk metal layer. Embodiments of the present invention include applying an aqueous composition containing citric acid and ammonium hydroxide in deionized water to remove a native oxide film that forms on a copper containing layer and then polishing the copper containing layer to substantially planarize the metal layer.

Abstract: A substrate is chemical mechanical polished first with a single layer hard polishing pad and a high-selectivity slurry until a first endpoint is reached, and then with a soft polishing pad and a low-selectivity slurry until a second endpoint is reached. Dishing is reduced when low-selectivity slurry is used at the second polishing step. Low Within-Wafer-Non-Uniformity is achieved by using a single layer hard pad at low pressure at the first polishing step.

Abstract: Cu metallization is treated to reduce defects and effect passivation, and to reduce leakage between lines, by removing surface defects subsequent to CMP and barrier layer removal. Embodiments include the sequential steps of: CMP and barrier layer removal; buffing with a solution comprising citric acid, ammonium hydroxide and deionized water to remove copper oxide; rinsing with deionized water or an inhibitor solution, e.g., benzotriazole or 5-methyl triazole in deionized water; buffing with an abrasive slurry; and rinsing with deionized water or an inhibitor solution.

Abstract: A CMP slurry is formulated with a single component oxidizer capable of oxidizing a metal undergoing planarization and yielding a complexing agent which complexes with the oxidized metal thereby minimizing overetching. Embodiments include CMP Cu with a fixed abrasive pad or an abrasive containing slurry, employing a peroxy acid, e.g., peroxy benzoic acid, or a polyethylene glycol peroxy acid. In another embodiment, a single component is employed which dissociates in the slurry into an oxidizer and complexing agent, such as an amine-peroxy acid, e.g., urea peroxy acid.

Abstract: Cu metallization is treated to reduce defects and effect passivation by removing a thin surface layer or removing corrosion stains, subsequent to CMP and barrier layer removal, employing a cleaning composition comprising deionized water, an acid and ammonium hydroxide and/or an amine. Embodiments include removing up to about 100 Å of the Cu metallization surface in a damascene opening by sequentially treating the exposed Cu surface with: an optional corrosion inhibitor; a solution having a pH of about 4 to about 11 and containing an acid, ammonium hydroxide and/or an amine, and deionized water; and a corrosion inhibitor.

Abstract: Dishing in chemical mechanical polishing (CMP) is reduced by introducing a material that balances electrochemical forces. In a first embodiment of the invention, a polishing pad having copper material in grooves on the polishing pad surface is used in the polishing process to reduce dishing. In a second embodiment of the invention, the polishing pad has perforations with copper fillings. In a third embodiment of the invention, a copper retaining ring on the polishing head introduces copper material to the CMP process to reduce dishing. In a fourth embodiment of the invention, a conditioning plate of copper is used in the polishing apparatus. In a fifth embodiment of the invention, additional copper features are placed on the substrate to be polished. The polishing of the additional features introduces copper steadily through the polishing process. In a sixth embodiment of the invention, copper compounds are added to the polish slurry.

Abstract: Methods and apparatus for planarizing a substrate surface having copper containing materials thereon is provided. In one aspect, the invention provides a system for processing substrates comprising a first platen adapted for polishing a substrate with a hard polishing pad disposed on the first platen, a second platen adapted for polishing a substrate with a hard polishing pad disposed on the second platen, and a third platen adapted for polishing a substrate with a hard polishing pad disposed on the third platen. In another aspect, the invention provides a method for planarizing a substrate surface by the system described above including substantially removing bulk copper containing materials on the first platen, removing residual copper containing materials on the second platen, and then removing a barrier layer on the third platen. A computer readable program may also be provided for performing the methods described herein.

Abstract: The present invention generally provides a system and apparatus for cleaning a polishing pad, such as a fixed abrasive pad, in a substrate processing system. In one embodiment, the system includes one or more nozzles which spray a fluid at pressures of about 30 psi to about 300 psi or greater, as measured at the nozzle, onto a polishing pad at acute angles to the surface of the polishing pad. The nozzles can spray downward and outward toward the perimeter of the pad to facilitate the debris removal therefrom. The system can include a pressure source to produce a sufficient fluid pressure substantially higher than the typical fluid pressure available from a facility installation.

Abstract: An improved deposition chamber (2) includes a housing (4) defining a chamber (18) which houses a substrate support (14). A mixture of oxygen and SiF4 is delivered through a set of first nozzles (34) and silane is delivered through a set of second nozzles (34a) into the chamber around the periphery (40) of the substrate support. Silane (or a mixture of silane and SiF4) and oxygen are separately injected into the chamber generally centrally above the substrate from orifices (64, 76). The uniform dispersal of the gases coupled with the use of optimal flow rates for each gas results in uniformly low (under 3.4) dielectric constant across the film.

Abstract: Ion exchange materials are employed in CMP methodologies to polish or thin a semiconductor substrate or a layer thereon. Embodiments include a polishing pad having an ion exchange material thereon and polishing a semiconductor substrate or a layer thereon with the polishing pad or a CMP composition including an ion exchange material therein and polishing the substrate or a layer thereon with the CMP composition or both.

Abstract: A method of chemical mechanical polishing a metal layer on a substrate in which the substrate is polished at a first polishing rate. Polishing is monitored with an eddy current monitoring system, and the polishing rate is reduced to a second polishing rate when the eddy current monitoring system indicates that a predetermined thickness of the metal layer remains on the substrate. Then polishing is monitored with an optical monitoring system, and polishing is halted when the optical monitoring system indicates that an underlying layer is at least partially exposed.

Abstract: A method for performing electrochemical-mechanical planarization (EMP) of a workpiece surface including a pattern of electrical conductors comprises supplying a chemical-mechanical polishing (CMP)-type apparatus having an abrasive or non-abrasive polishing pad with an oxidizer-free, electrolytically conductive, abrasive or non-abrasive fluid and applying a time-varying anodic potential to the workpiece surface for controllably dissolving the material, e.g., metal, of the electrical conductors while simultaneously applying mechanical polishing action to the surface. The method advantageously reduces or substantially eliminates undesirable dishing characteristic of conventional CMP planarization processing utilizing chemical oxidizer agent(s). Apparatus for performing EMP are also disclosed.

Abstract: A chemical mechanical polishing apparatus includes a pad conditioner having a conditioner head, a cleaning cup for receiving and cleaning the conditioner head of the pad conditioner, and a fluid dispenser for dispensing a cleaning fluid onto the conditioner head.

Abstract: A method and composition for planarizing a substrate surface is provided. The polishing composition includes an oxidizer capable of oxidizing a metal undergoing planarization and yielding a complexing agent which complexes with the oxidized metal and a stabilizer such as a stannate salt. The composition may further include abrasive particles and/or inhibitors. The composition may be used in a multi-step polishing process including polishing a substrate surface to selectively remove a metal layer with respect to a barrier layer and dielectric layer and polishing a substrate surface using the composition to non-selectively remove the metal layer, a barrier layer, and a dielectric layer from the substrate surface.

Abstract: An inventive brush, pad or the like is provided that has functional groups (complexing agents) such as chelating reagents. The complexing agents may be chemically grafted to the brush or pad, may be resin beads physically blended with the brush materials, or the brush or pad may be made of a homogeneous material containing a complexing polymer. The immobilized complexing agents on the brush can effectively pick up metal ions or metal oxides from the substrate surface upon contact but may not etch into the metal lines.

Abstract: An improved deposition chamber (2) includes a housing (4) defining a chamber (18) which houses a substrate support (14). A mixture of oxygen and SiF4 is delivered through a set of first nozzles (34) and silane is delivered through a set of second nozzles (34a) into the chamber around the periphery (40) of the substrate support. Silane (or a mixture of silane and SiF4) and oxygen are separately injected into the chamber generally centrally above the substrate from orifices (64, 76). The uniform dispersal of the gases coupled with the use of optimal flow rates for each gas results in uniformly low (under 3.4) dielectric constant across the film.

Abstract: An apparatus and method for removing a metal residue from a process waste stream. In one aspect, an apparatus for a waste stream treatment assembly is provided which includes a waste stream metal removal reactor having at least one inlet and at least one outlet, a fluid delivery system connected to the at least one inlet of the waste stream metal removal reactor and a chelating agent supply source, and a filtering member disposed in communication with the at least one outlet of the waste stream metal removal reactor. In another aspect, a method is provided which includes adding a chelating agent to a process waste stream to form a metal complex, and removing the metal complex from the process waste stream prior to disposal.

Abstract: A substrate with a first layer disposed on a second layer is chemically mechanically polished. A polishing endpoint detection system generates a signal that is monitored for an endpoint criterion. The polishing rate of the substrate is reduced when the bulk of the first layer has been removed but before the second layer is exposed. For example, the polishing rate is reduced when the polishing time approaches an expected polishing end time but before the endpoint criterion is detected. Polishing stops once the endpoint criterion is detected after the underlying layer has been exposed.

Abstract: Polishing pad glazing during CMP of Al and Al alloys is eliminated or substantially reduced by utilizing a neutral polishing slurry containing a sufficient amount of a surfactant to prevent agglomeration of the abrasive particles with polishing by-products. Embodiments include CMP an Al or an Al alloy surface employing a slurry containing abrasive Al2O3 particles and about 0.02 to about 5 wt. % of a surfactant to prevent Al2O3 abrasive slurry particles from agglomerating with Al(OH)3 polishing by-products. Embodiments further include subsequent ex situ pad conditioning using an acid or base to dissolve, or a complexing agent to remove, Al(OH)3 polishing by-products.

Abstract: A process for treating a copper or copper alloy substrate surface with a composition and corrosion inhibitor solution to minimize defect formation and surface corrosion, the method including applying a composition including one or more chelating agents, a pH adjusting agent to produce a pH between about 3 and about 11, and deionized water, and then applying a corrosion inhibitor solution. The composition may further comprise a reducing agent and/or corrosion inhibitor. The method may further comprise applying the corrosion inhibitor solution prior to treating the substrate surface with the composition.