The invention provides a method for polishing or planarizing a substrate of at least one of semiconductor, optical and magnetic substrates. The method includes attaching a polymer-polymer composite polishing pad having a polishing layer to a polishing device. A hydrophilic polymeric matrix forms the polishing layer. Cationic fluoropolymer particles having nitrogen-containing end groups are embedded in the polymeric matrix. A slurry containing anionic particles is applied to the polymer-polymer composite polishing pad and rubbed against the substrate to polish or planarize the substrate with the fluoropolymer particles interacting with the anionic particles to increase polishing removal rate.

The invention provides a method for polishing or planarizing a substrate. First, the method comprises attaching a polymer-polymer composite polishing pad to a polishing device. The polishing pad has a polymer matrix and fluoropolymer particles embedded in the polymeric matrix. The fluoropolymer particles have a zeta potential more negative than the polymeric matrix. Cationic particle-containing slurry is applied to the polishing pad. Conditioning the polymer-polymer composite polishing pad exposes the fluoropolymer particles to the polishing surface and creates fluoropolymer-containing debris particles in the slurry. Polishing or planarizing the substrate with the increased electronegativity from the fluoropolymer at the polishing surface and in the fluoropolymer-containing debris particles stabilizes the cationic particle-containing slurry to decreases the precipitation rate of the cationic particle-containing slurry.

The present invention is method for polishing silicon wafer, the method including recovering used slurry containing polishing abrasive grains that have been supplied to the silicon wafer and used for polishing, and circulating and supplying the recovered used slurry to the silicon wafer to polish the silicon wafer, wherein mixed alkali solution containing chelating agent and either or both of a pH adjuster and a polishing rate accelerator is added to the recovered used slurry without adding unused polishing abrasive grains, and the recovered used slurry is circulated and supplied to the silicon wafer to polish the silicon wafer. As a result, there is provided a method for polishing a silicon wafer that can suppress the occurrence of metal impurity contamination and stabilize the composition (e.g., the concentration of the chelating agent) of the used slurry when the used slurry is circulated and supplied to the silicon wafer for polishing.

The invention provides a polymer-polymer composite polishing pad useful for polishing or planarizing a substrate of at least one of semiconductor, optical and magnetic substrates. The polymer-polymer composite polishing pad includes a polishing layer having a polishing surface for polishing or planarizing the substrate; a polymeric matrix forming the polishing layer and including gas-filled or liquid-filled polymeric microelements; and fluoropolymer particles embedded in the polymeric matrix. The fluoropolymer particles have a tensile strength lower than the tensile strength of the polymeric matrix wherein diamond abrasive materials cut the fluoropolymer to form a reduced number of pad debris particles in the 1 μm to 10 μm size range.

To planarize a substrate having irregularities on its surface. Provided is a method of chemical mechanical polishing of a substrate. The method includes the step of polishing the substrate using a processing solution, and the step of changing concentration of an effective component in the processing solution, which contributes to the polishing of the substrate.

A polishing agent for polishing a resin comprises abrasive grains, a water-soluble polymer having an ether bond, an organic solvent and water, wherein the abrasive grains have a positive charge in the polishing agent and an average particle diameter of the abrasive grains is larger than 20 nm.

The invention provides a method for polishing or planarizing a substrate of at least one of semiconductor, optical and magnetic substrates. The method includes attaching a polymer-polymer composite polishing pad having a polishing layer to a polishing device. A hydrophilic polymeric matrix forms the polishing layer. Cationic fluoropolymer particles having nitrogen-containing end groups are embedded in the polymeric matrix. A slurry containing anionic particles is applied to the polymer-polymer composite polishing pad and rubbed against the substrate to polish or planarize the substrate with the fluoropolymer particles interacting with the anionic particles to increase polishing removal rate.

The invention provides a method for polishing or planarizing a substrate. First, the method comprises attaching a polymer-polymer composite polishing pad to a polishing device. The polishing pad has a polymer matrix and fluoropolymer particles embedded in the polymeric matrix. The fluoropolymer particles have a zeta potential more negative than the polymeric matrix. Cationic particle-containing slurry is applied to the polishing pad. Conditioning the polymer-polymer composite polishing pad exposes the fluoropolymer particles to the polishing surface and creates fluoropolymer-containing debris particles in the slurry. Polishing or planarizing the substrate with the increased electronegativity from the fluoropolymer at the polishing surface and in the fluoropolymer-containing debris particles stabilizes the cationic particle-containing slurry to decreases the precipitation rate of the cationic particle-containing slurry.

The invention provides a polymer-polymer composite polishing pad useful for polishing or planarizing a substrate of at least one of semiconductor, optical and magnetic substrates. The polymer-polymer composite polishing pad includes a polishing layer having a polishing surface for polishing or planarizing the substrate; a polymeric matrix forming the polishing layer and including gas-filled or liquid-filled polymeric microelements; and fluoropolymer particles embedded in the polymeric matrix. The fluoropolymer particles have a tensile strength lower than the tensile strength of the polymeric matrix wherein diamond abrasive materials cut the fluoropolymer to form a reduced number of pad debris particles in the 1 m to 10 m size range.

An embodiment provides a wafer edge polishing unit comprising: a process chamber; a polishing stage which is arranged in a lower region of the process chamber and on which a wafer is arranged; a polishing unit, arranged at an edge of the polishing stage, for polishing the wafer; a slurry storage unit arranged in an upper region of the process chamber; a slurry supply unit for supplying a slurry to the slurry storage unit; a pure water supply unit for supplying pure water to an upper region of the polishing stage; a first pipe for supplying the slurry from the slurry storage unit to the polishing stage; a turbidity detection unit for detecting the turbidity of the slurry inside the first pipe; a second pipe for recovering the slurry from the polishing stage to the slurry storage unit; and a control unit for adjusting the amount of the slurry supplied from the slurry supply unit to the slurry storage unit according to the detected turbidity.