Provided is a method of SiC wafer processing, and the method includes the following steps. A SiC wafer is provided, and the SiC wafer has a first surface and an opposing second surface. A fine grinding process is performed on the first surface and the second surface of the SiC wafer. A dry etching process is performed on the first surface and the second surface of the SiC wafer to make the roughness of the first surface and the second surface 2.5 nm or less. After the dry etching process, a polishing process is performed on the first surface and the second surface of the SiC wafer.

A polishing assembly for polishing of silicon wafers includes a polishing pad, a polishing head assembly, a temperature sensor, and a controller. The polishing head assembly holds a silicon wafer to position the silicon wafer in contact with the polishing pad. The polishing head assembly selectively varies a removal profile of the silicon wafer. The temperature sensor collects thermal data from a portion of the polishing pad. The controller is communicatively coupled to the polishing head assembly and the temperature sensor. The controller receives the thermal data from the temperature sensor and operates the polishing head assembly to selectively vary the removal profile of the silicon wafer based at least in part on the thermal data.

Disclosed is a turntable cloth peeling jig including: a cylindrical winding cylinder including a slit formed on an outer periphery of the cylindrical winding cylinder and extending in an axial direction thereof; a cloth clamping member disposed inside the winding cylinder and configured to clamp an outer peripheral edge of a cloth inserted into the slit; an extension bar attached to one end portion of the winding cylinder so as to extend coaxially therewith; an engaging portion provided at a tip end portion of the extension bar and engaged with a rotation jig configured to rotate the winding cylinder; and a handle provided in the engaging portion and configured to support the winding cylinder when rotating the rotating jig.

Provided are a method of polishing a silicon wafer and a method of producing a silicon wafer which can reduce the formation of step-forming microdefects on a silicon wafer. The method includes: a double-side polishing step of performing polishing on front and back surfaces of a silicon wafer; a notch portion polishing step of performing polishing on a beveled portion of a notch portion of the silicon wafer after the double-side polishing step; a peripheral beveled portion polishing step of performing polishing on the beveled portion on the periphery of the silicon wafer other than the beveled portion of the notch portion after the notch portion polishing step; and a finish polishing step of performing finish polishing on the front surface of the silicon wafer after the peripheral beveled portion polishing step. The notch portion polishing step is performed in a state where the front surface is wet with water.

A method may include thinning a silicon wafer to a particular thickness. The particular thickness may be based on a passband frequency spectrum of an adjustable optical filter. The method may also include covering a surface of the silicon wafer with an optical coating. The optical coating may filter an optical signal and may be based on the passband frequency spectrum. The method may additionally include depositing a plurality of thermal tuning components on the coated silicon wafer. The plurality of thermal tuning components may adjust a passband frequency range of the adjustable optical filter by adjusting a temperature of the coated silicon wafer. The passband frequency range may be within the passband frequency spectrum. The method may include dividing the coated silicon wafer into a plurality of silicon wafer dies. Each silicon wafer die may include multiple thermal tuning components and may be the adjustable optical filter.

Provided is a surface protectant that suppresses corrosion of a semiconductor wafer surface by a basic compound, and reduces defects in the semiconductor wafer. The semiconductor wafer surface protectant of the present invention includes a compound represented by Formula (1) below;
R.sup.1O—(C.sub.3H.sub.6O.sub.2).sub.n—H  (1) where R.sup.1 denotes a hydrogen atom, a hydrocarbon group that has from 1 to 24 carbon atoms and may have a hydroxyl group, or a group represented by R.sup.2CO, where the R.sup.2 denotes a hydrocarbon group having from 1 to 24 carbon atoms; and n indicates an average degree of polymerization of a glycerin unit shown in the parentheses, and is from 2 to 60.

Provided is a wafer polishing method capable of improving nanotopography characteristics within a site on the surface of a wafer having a 2 mm square area or a small area equivalent thereto and a silicon wafer polished by the wafer polishing method, and further provided is a method of chemical-mechanical polishing the surface of a wafer through a polishing step in two or more polishing steps with different polishing rates, in which the in-plane thickness variation (standard deviation) of a polishing pad 150 used in a polishing step with a machining allowance of 0.3 μm or more is 2.0 μm or less.

A ratio obtained by dividing a number of pits by a number of screw dislocations is equal to or smaller than 1%. The first main surface has a surface roughness equal to or smaller than 0.15 nm. An absolute value of a difference between the first wave number and the second wave number is equal to or smaller than 0.2 cm.sup.−1, and an absolute value of a difference between the first full width at half maximum and the second full width at half maximum is equal to or smaller than 0.25 cm.sup.−1.

Provided is a surface processing apparatus and a surface processing method for a SiC substrate using anodization. The surface processing apparatus for the SiC substrate includes a surface processing pad and a power supply device. The surface processing pad includes a grinding wheel layer. The grinding wheel layer is disposed facing a workpiece surface of the SiC substrate. The power supply device passes a pulsed current having a period greater than 0.01 seconds and less than or equal to 20 seconds for anodizing the workpiece surface to be processed by the grinding wheel layer through the SiC substrate as an anode in the presence of an electrolyte.

A surface processing method for a SiC substrate includes the following processes or steps: anodizing a workpiece surface of the SiC substrate by passing a current having a current density of 15 mA/cm.sup.2 or more through the SiC substrate as an anode in the presence of an electrolyte; disposing a grinding wheel layer of a surface processing pad to the workpiece surface and selectively removing, with the grinding wheel layer, an oxide formed on the workpiece surface through anodization; and performing, simultaneously or sequentially, the anodization of the workpiece surface and the selective removal of the oxide formed on the workpiece surface with the grinding wheel layer.