Abstract: Method and apparatus are provided for polishing substrates comprising conductive and low k dielectric materials with reduced or minimum substrate surface damage and delamination. In one aspect, a method is provided for processing a substrate including positioning a substrate having a conductive material formed thereon in a polishing apparatus having one or more rotational carrier heads and one or more rotatable platens, wherein the carrier head comprises a retaining ring and a membrane for securing a substrate and the platen has a polishing article disposed thereon, contacting the substrate surface and the polishing article to each other at a retaining ring contact pressure of about 0.4 psi or greater than a membrane pressure, and polishing the substrate to remove conductive material.

Abstract: A carrier head for a chemical mechanical polishing apparatus includes a flexible membrane, the lower surface of which provides a substrate-receiving surface. The carrier head may include a projection which contacts an upper surface of the flexible membrane to apply an increased load to a potentially underpolished region of a substrate. Fluid jets may be used for the same purpose.

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: 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 carrier head for a chemical mechanical polishing apparatus includes a flexible membrane, the lower surface of which provides a substrate-receiving surface. The carrier head may include a projection which contacts an upper surface of the flexible membrane to apply an increased load to a potentially underpolished region of a substrate. Fluid jets may be used for the same purpose.

Abstract: A carrier head for a chemical mechanical polishing apparatus includes a flexible membrane, the lower surface of which provides a substrate-receiving surface. The carrier head may include a projection which contacts an upper surface of the flexible membrane to apply an increased load to a potentially underpolished region of a substrate. Fluid jets may be used for the same purpose.

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: In the formation of metal vias, plugs or lines, a metal layer is deposited onto a non-planar non-metallic surface of a substrate. The metal layer is chemical mechanical polished with a first polishing pad until the metal layer is substantially planarized and a residual layer having a thickness about equal to the depth of potential microscratches, between about 200 and 1000 angstroms, remains over the non-metallic surface. The residual layer is chemical mechanical polished with a second, softer polishing pad until the non-metallic surface is exposed and the residual layer is removed.

Abstract: A carrier head for a chemical mechanical polishing apparatus includes a flexible membrane, the lower surface of which provides a substrate-receiving surface. The carrier head may include a projection which contacts an upper surface of the flexible membrane to apply an increased load to a potentially underpolished region of a substrate. Fluid jets may be used for the purpose.