A manufacturing method of a carrier for a double-side polishing apparatus, including: preparing a carrier base material and insert thicker than the carrier base material, inserting the insert into a holding hole so as to protrude the insert from both sides of the front surface and back surface of the carrier base material, measuring each of a front protruding amount of the insert protruded from front surface of the carrier base material and a back protruding amount of the insert protruded from back surface of the carrier base material, setting each rotational speed of the upper turn table and lower turn table in starting-up polishing of the carrier so as to decrease the difference between the front protruding amount and back protruding amount, and a starting-up polishing step to subject the carrier to starting-up polishing at each set rotational speed of the upper turn table and the lower turn table.

A polishing platform of a polishing apparatus includes a platen, a polishing pad, and an electric field element disposed between the platen and the polishing pad. The polishing apparatus further includes a controller configured to apply voltages to the electric field element. A first voltage is applied to the electric field element to attract charged particles of a polishing slurry toward the polishing pad. The attracted particles reduce overall topographic variation of a polishing surface presented to a workpiece for polishing. A second voltage is applied to the electric field element to attract additional charged particles of the polishing slurry toward the polishing pad. The additional attracted particles further reduce overall topographic variation of the polishing surface presented to the workpiece. A third voltage is applied to the electric field element to repel charged particles of the polishing slurry away from the polishing pad for improved cleaning thereof.

A method of controlling platen rotation includes receiving an electrical energy input at a rotator assembly, using the rotator assembly to increase a rotational kinetic energy of a platen based on the electrical energy input, using the rotator assembly to decrease the rotational kinetic energy of the platen, and generating an electrical energy output of the rotator assembly based on the decreased rotational kinetic energy of the platen.

A method for forming a semiconductor device structure is provided. The method includes providing a wafer over a polishing platen. The wafer includes a metal layer and a dielectric layer. The metal layer covers the dielectric layer and fills an opening of the dielectric layer. The method also includes polishing the wafer using a first operation to thin down the metal layer. The first operation has a first polishing selectivity of the metal layer to the dielectric layer. The method further includes polishing the wafer using a second operation to further thin down the metal layer until the dielectric layer is exposed. The second operation has a second polishing selectivity of the metal layer to the dielectric layer. The second polishing selectivity is different from the first polishing selectivity. The first operation and the second operation are performed in-situ on the polishing platen.

A method for polishing a glass substrate, by which a polishing speed that is higher than a conventional polishing speed can be maintained for a long period of time in processing for polishing a glass substrate using cerium oxide as polishing abrasive particles is provided. A polishing liquid containing cerium oxide as polishing abrasive particles is supplied to a polishing surface of a glass substrate, and the glass substrate is subjected to polishing processing. This polishing liquid contains the cerium oxide as polishing abrasive particles and a substance that reduces cerium oxide in response to light irradiation. Also, processing for irradiating the polishing liquid with light is performed when polishing processing is performed.

A method of CMP includes providing a slurry solution including ≥1 per-compound oxidizer in a concentration between 0.01 M and 2 M with a pH from 2 to 5 or 8 to 11, and ≥1 buffering agent which provides a buffering ratio ≥1.5 that compares an amount of a strong acid needed to reduce the pH from 9.0 to 3.0 as compared to an amount of strong acid to change the pH from 9.0 to 3.0 without the buffering agent. The slurry solution is exclusive any hard slurry particles or has only soft slurry particles that have throughout a Vickers hardness <300 Kg/mm.sup.2 or Mohs Hardness <4. The slurry solution is dispensed on a hard surface having a Vickers hardness >1,000 kg/mm.sup.2 is pressed by a polishing pad with the slurry solution in between while rotating the polishing pad relative to the hard surface.

A metal interconnect structure can be fabricated within an integrated circuit (IC). A recess can be created in an IC dielectric layer and a surface modulation liner can be formed by depositing two different metallic elements onto the surfaces of the recess. One metallic element can have a standard electrode potential greater than a standard electrode potential of an interconnect metal, and the other metallic element can have a standard electrode potential less than the standard electrode potential of the interconnect metal. A metal interconnect structure can be formed by filling the remainder of the recess with interconnect metal, which is physically separated from the dielectric layer by the surface modulation liner. The surface topography of the metal interconnect structure can be modulated with a polishing process, by removing a top portion of the interconnect metal and a top portion of the surface modulation liner.

A chemical mechanical planarization (CMP) system including a capacitive deionization module (CDM) for removing ions from a solution and a method for using the same are disclosed. In an embodiment, an apparatus includes a planarization unit for planarizing a wafer; a cleaning unit for cleaning the wafer; a wafer transportation unit for transporting the wafer between the planarization unit and the cleaning unit; and a capacitive deionization module for removing ions from a solution used in at least one of the planarization unit or the cleaning unit.

A polishing composition, includes an abrasive; a pH adjuster; a barrier film removal rate enhancer; a low-k removal rate inhibitor; an azole-containing corrosion inhibitor; and a ruthenium removal rate enhancer. A method of polishing a substrate includes the steps of: applying the polishing composition described herein to a surface of a substrate, wherein the surface comprises ruthenium or a hard mask material; and bringing a pad into contact with the surface of the substrate and moving the pad in relation to the substrate.

Provided herein are compositions comprising a first colloidal silica particle that is not surface-modified and a second colloidal silica particle that is surface modified to carry a negative charge. Also provided herein are methods for selectively removing HfO.sub.2 or SiO.sub.2 from a surface.