A method of producing a silicon wafer includes: a laser mark printing step of printing a laser mark having a plurality of dots on a silicon wafer; an etching step of performing etching on at least a laser-mark printed region in a surface of the silicon wafer; and a polishing step of performing polishing on both surfaces of the silicon wafer having been subjected to the etching step. In the laser mark printing step, each of the plurality of dots is formed by a first step of irradiating a predetermined position on a periphery of the silicon wafer with laser light of a first beam diameter thereby forming a first portion of the dot and a second step of irradiating the predetermined position with laser light of a second beam diameter that is smaller than the first beam diameter thereby forming a second portion of the dot.

Provided is a chemical-mechanical polishing composition comprising an abrasive, a basic component, at least one compound selected from the group consisting of a quaternary polyammonium salt, a quaternary ammonium salt having 6 or more carbon atoms, and an alkylated polymer having an amide structure, and an aqueous carrier; a rinse composition comprising the at least one compound and an aqueous carrier, as well as a method of chemically-mechanically polishing a substrate, and a method of rinsing a substrate, in which the respective compositions are used.

The present disclosure relates to a polishing pad, a method for manufacturing the polishing pad, and a method for manufacturing a semiconductor device using the polishing pad, and the present disclosure can prevent an error in detecting the end point due to the window in the polishing pad by minimizing the effect on transmittance according to the surface roughness of the window in the polishing pad in the polishing process, and allows the fluidity and loading rate of the polishing slurry in the polishing process to be implemented at similar levels by maintaining the surface roughness difference between the polishing layer and the window in the polishing pad within the predetermined range, thereby enabling the problem of deterioration of polishing performance due to the surface difference between the polishing layer and the window to be prevented.

Further, a method for manufacturing a semiconductor device to which a polishing pad is applied may be provided.

Provided is a novel polishing composition. The polishing composition comprises a water-soluble polymer at least comprising a vinyl alcohol-based resin having a side-chain group of 3 carbon atoms or more.

A group III nitride single crystal substrate comprises: a first main face; and a first back face opposite to the first main face, wherein an absolute value of a radius of curvature of the first main face of the substrate is 10 m or more; an absolute value of a radius of curvature of a crystal lattice plane at a center of the first main face of the substrate is 10 m or more; and a 1/1000 intensity width of an X-ray rocking curve of a low-incidence-angle face at the center of the first main face of the substrate is 1200 arcsec or less.

An object of the present invention is to provide a silica particle, a silica sol containing the silica particle, and a polishing composition containing the silica sol, which prevent secondary aggregation, have excellent dispersion stability, and are suitable for polishing. The present invention relates to a silica particle in which an average value of a circularity coefficient measured by a field-emission scanning electron microscope is 0.90 or more, and a standard deviation of the circularity coefficient is 0.05 or less.

A polishing composition that can not only achieve high polishing speed, but also can improve the surface smoothness (surface quality) of a polished substrate and reduce defects is provided. That is, provided is a polishing composition comprising silica particles and a water soluble polymer, wherein the contained silica particles satisfy the following requirements (a) to (c): (a) the primary particle diameter based on the specific surface area is 5 to 300 nm; (b) the coefficient of variation in the particle diameter is 10% or less; and (c) the Sears number Y is 10.0 to 12.0.

Provided is a method of transferring a semiconductor wafer to a single-side polishing apparatus without forming scratches on the surface of the semiconductor wafer. The method includes: starting to splay the liquid from each spray hole; placing the semiconductor wafer on the retainer portion to hold a surface of the semiconductor wafer by suction without contact, and raising the tray to attach the semiconductor wafer to the polishing head, wherein a period of time from a point at which the semiconductor wafer is held by the retainer portion to a point at which the attaching of the semiconductor wafer W to the polishing head is completed is 5 s or more, or wherein a ratio of a total area of the protrusions to an area of the semiconductor wafer is 15% or more.

Provided are a method and apparatus for final polishing of a silicon wafer. The method for final polishing includes: within a predetermined period of time remaining before completion of the final polishing, forming a hydrophilic silicon oxide film on a surface of the silicon wafer by using both a polishing slurry and an oxidizing solution as a polishing liquid.

The present invention addresses the problem of providing novel techniques for manufacturing a SiC substrate that enables reduced material loss when a strained layer is removed. The present invention is a method for manufacturing a SiC substrate 30 which includes a strained layer thinning step S1 for thinning a strained layer 12 of a SiC substrate body 10 by moving the strained layer 12 to a surface side. Including such a strained layer thinning step S1 in which the strain layer is moved to (concentrated toward) the surface side makes it possible to reduce material loss L when removing the strained layer 12.