There is provided a method for manufacturing a semiconductor device, including: attracting a semiconductor device wafer by a chuck mechanism and rotating the semiconductor device wafer horizontally; rotating a rotary blade horizontally by a vertical spindle to which ultrasonic waves are applied; trimming an outer peripheral end portion of the semiconductor device wafer that is horizontally rotating by the rotary blade that is horizontally rotating, to form a groove in the outer peripheral end portion; correcting a tip shape of the rotary blade that is horizontally rotating by a blade-forming grinding wheel during the trimming; and grinding one main surface of the semiconductor device wafer that is horizontally rotating by a cup grinding wheel that is horizontally rotating after the trimming.

Described are various coolant and/or lubricating compositions. Also described are various methods for grinding glass that employ such a coolant and/or lubricating composition. Such compositions may find use in the grinding of glass, such as automotive glass, flat glass, ophthalmic glass, precision ophthalmic glass, ceramics, quartz, solar glass, precision optical glass, lens glass, architectural glass, curtain wall glass, appliance glass, electronic-device glass, and/or various plastics.

Described are various coolant and/or lubricating compositions. Also described are various methods for grinding glass that employ such a coolant and/or lubricating composition. Such compositions may find use in the grinding of glass, such as automotive glass, flat glass, ophthalmic glass, precision ophthalmic glass, ceramics, quartz, solar glass, precision optical glass, lens glass, architectural glass, curtain wall glass, appliance glass, electronic-device glass, and/or various plastics.

A polishing unit of a polishing apparatus according to an embodiment includes: a polishing head having a pressing member configured to hold a polishing tape and press the polishing tape against a peripheral portion of a substrate from above; a tape supply and recovery mechanism configured to supply the polishing tape to the polishing head and recover the polishing tape from the polishing head; a first moving mechanism configured to move the polishing head in a radial direction of the substrate; and a second moving mechanism configured to move the tape supply and recovery mechanism in the radial direction of the substrate. The positioning unit includes a positioning block having a contacting surface, and alignment of the polishing tape is conducted by the second moving mechanism moving the tape supply and recovery mechanism so that a substrate-side edge of the polishing tape makes contact with the contacting surface.

The present invention relates to a polishing apparatus and a polishing method for polishing a substrate, such as a wafer, and more particularly to a polishing apparatus and a polishing method for polishing an edge portion of a wafer with use of a polishing tape. The polishing apparatus includes a substrate holder (1) configured to hold and rotate a substrate (W), and a polishing unit (7) configured to polish an edge portion of the substrate (W) with use of a polishing tape (5). The polishing unit (7) includes: a disk head (12) having a circumferential surface for supporting the polishing tape (5); and a head moving device (50) configured to move the disk head (12) in a tangential direction of the substrate (W) and to bring the polishing tape (5) on the circumferential surface of the disk head (12) into contact with the edge portion of the substrate (W).

A wafer processing method for processing a wafer includes an annular groove forming step, a close contact making step, a protective member fixing step, a grinding step, and a peeling step. The wafer has a device area and a peripheral marginal area surrounding the device area on the front side, and devices each having asperities are formed in the device area. In the annular groove forming step, an annular groove is formed on the front side of the wafer along the inner circumference of the peripheral marginal area. In the close contact making step, the device area and the annular groove are covered with a protective film, and the protective film is bring into close contact with the front side of the wafer.

A polishing apparatus polishes a periphery of a substrate by bringing a polishing tool into sliding contact with the substrate. The polishing apparatus includes a substrate-holding mechanism configured to hold a substrate and rotate the substrate, a polishing mechanism configured to press a polishing tool against a periphery of the substrate so as to polish the periphery, and a periphery-supporting mechanism configured to support the periphery of the substrate by a fluid. The periphery-supporting mechanism is configured to support a surface of the substrate from an opposite side or the same side of the periphery of the substrate.

A projecting/receiving unit (52) projects a laser light to a peripheral portion (30) and receives the reflected light while a liquid is being fed to a substrate (14) and is flowing on the peripheral portion (30). A signal processing controller (54) processes the electric signal of the reflected light to decide the state of the peripheral portion (30). The state of the peripheral portion being polished is monitored. Moreover, the polish end point is detected. A transmission wave other than the laser light may also be used. The peripheral portion (30) may also be enclosed by a passage forming member thereby to form a passage properly. The peripheral portion can be properly measured even in the situation where the liquid is flowing on the substrate peripheral portion.

Disclosed herein is an SiC substrate separating method for separating an SiC substrate into at least two parts in a planar manner. The SiC substrate separating method includes an adhesive tape attaching step of attaching a transparent adhesive tape to a first surface of the SiC substrate, a support member attaching step of attaching a support member to a second, opposite surface of the SiC substrate, and a separation start point forming step of setting the focal point of a laser beam at a predetermined depth from the adhesive tape and next applying the laser beam to the adhesive tape while relatively moving the focal point and the SiC substrate to thereby form a modified layer parallel to the first surface of the SiC substrate and cracks propagating from the modified layer, thus forming a separation start point.

This invention provides a method for growing monocrystalline silicon by applying Czochralski method comprising forming a melt of silicon-containing materials in a crucible and pulling the melt for monocrystalline silicon growth, which is characterized by, introducing a gas containing argon during formation of the melt, and, applying a magnetic field during the pulling step. This invention also provides a method for producing a wafer based on the above monocrystalline silicon.