Abstract: Provided is a method of lapping a semiconductor wafer, which can suppress the formation of a ring-shaped pattern in a nanotopography map. The method of lapping a semiconductor wafer includes: a stopping step of stopping lapping of a semiconductor wafer; a reversing step of reversing surfaces of the semiconductor wafer facing a upper plate and a lower plate after the stopping step; and a resuming step of resuming lapping of the semiconductor wafer after the reversing step while maintaining the reversal of the surfaces facing the plates.

Abstract: Provided is a method of lapping a semiconductor wafer, which can suppress the formation of a ring-shaped pattern in a nanotopography map. The method of lapping a semiconductor wafer includes: a stopping step of stopping lapping of a semiconductor wafer; a reversing step of reversing surfaces of the semiconductor wafer facing a upper plate and a lower plate after the stopping step; and a resuming step of resuming lapping of the semiconductor wafer after the reversing step while maintaining the reversal of the surfaces facing the plates.

Abstract: In a wafer processing method by which, by using, as a reference surface, a flat surface obtained by applying a curable material to the whole of one surface of a wafer obtained by slicing a semiconductor single-crystal ingot by using a wire saw apparatus, surface grinding is performed on the other surface of the wafer and surface grinding is performed on the one surface of the wafer by using the other surface of the wafer subjected to surface grinding as a reference surface, both surfaces of the wafer are planarized at the same time immediately after the wafer is obtained by slicing.

Abstract: Disclosure relates to a fixed abrasive-grain processing device and a method of fixed abrasive-grain processing used for producing a semiconductor wafer, and a method for producing a semiconductor wafer which make the surface of the semiconductor wafer possible to have preferable flatness and which can prevent the number of steps and the installation area of facilities from increasing.

Abstract: A surface of a semiconductor wafer is subjected to high flattening processing. A resin application and grinding step is repeatedly carried out, the step including determining as a reference surface a flat surface obtained by applying a curable material to one entire surface of a wafer sliced out from a semiconductor single crystal ingot with the use of a wire saw apparatus and performing surface grinding with respect to the other surface of the wafer, and determining as a reference surface the other surface of the wafer subjected to the surface grinding and performing the surface grinding with respect to the one surface of the wafer.

Abstract: In a wafer processing method by which, by using, as a reference surface, a flat surface obtained by applying a curable material to the whole of one surface of a wafer obtained by slicing a semiconductor single-crystal ingot by using a wire saw apparatus, surface grinding is performed on the other surface of the wafer and surface grinding is performed on the one surface of the wafer by using the other surface of the wafer subjected to surface grinding as a reference surface, both surfaces of the wafer are planarized at the same time immediately after the wafer is obtained by slicing.

Abstract: The present invention provides a polishing solution distribution apparatus capable of reducing distribution deviation of polishing solution even when leveling for installation is insufficient or inclination of an installation location varies and a polishing apparatus having the same. The polishing solution distribution apparatus includes a cone-shaped branch body in which a solution pan to store supplied polishing solution is formed and in which plural flow passages radially connected to a side face of the solution pan respectively and having a delivery port to supply polishing solution to a position lower than the connected position are formed, a support portion to support the branch body, and a universal joint mechanism to support the branch body via the support portion at a position being higher than the gravity center of the branch body.

Abstract: A surface of a semiconductor wafer is subjected to high flattening processing. A resin application and grinding step is repeatedly carried out, the step including determining as a reference surface a flat surface obtained by applying a curable material to one entire surface of a wafer sliced out from a semiconductor single crystal ingot with the use of a wire saw apparatus and performing surface grinding with respect to the other surface of the wafer, and determining as a reference surface the other surface of the wafer subjected to the surface grinding and performing the surface grinding with respect to the one surface of the wafer.

Abstract: A method for manufacturing an epitaxial wafer that can reduce occurrence of a surface defect or a slip formed on an epitaxial layer is provided. The manufacturing method is characterized by comprising: a smoothing step of controlling application of an etchant to a wafer surface in accordance with a surface shape of a silicon wafer to smooth the wafer surface; and an epitaxial layer forming step of forming an epitaxial layer formed of a silicon single crystal on the surface of the wafer based on epitaxial growth.

Abstract: An object of the present invention is to provide a method for etching a single wafer, which effectively realizes a high flatness of wafer and an increase in productivity thereof. In a method for etching a single wafer, a single thin disk-like wafer sliced from a silicon single crystal ingot is spun, and a front surface of the wafer is etched with an etching solution supplied thereto. In the method, a plurality of supply nozzles are disposed above and opposite to the front surface of the wafer at different portions in the radial direction of the wafer, respectively; and then one or more conditions selected from the group consisting of temperatures, kinds, and supply flow rates of etching solutions from the plurality of supply nozzles are changed.

Abstract: All treatments performed in machining processes other than a polishing process are performed while pure water free from free abrasive grains is supplied. Thus, an amount of abrasive grains included in a used processing liquid discharged in each process is reduced and semiconductor scraps are collected from the used slurry for recycling.

Abstract: Disclosure relates to a fixed abrasive-grain processing device and a method of fixed abrasive-grain processing used for producing a semiconductor wafer, and a method for producing a semiconductor wafer which make the surface of the semiconductor wafer possible to have preferable flatness and which can prevent the number of steps and the installation area of facilities from increasing.

Abstract: A method of grinding semiconductor wafers including simultaneously grinding both surfaces of multiple semiconductor wafers by rotating the wafers between a pair of upper and lower rotating surface plates in a state where the wafers are held on a carrier so that centers of the wafers are positioned on a circumference of a single circle, wherein a ratio of an area of a circle passing through the centers of the wafers to an area of one of the wafers is greater than or equal to 1.33 but less than 2.0; surfaces of the fixed abrasive grains comprised in the surface plates are comprised of pellets disposed in a grid-like fashion, with the pellets provided in a center portion and pellets provided in a peripheral portion being larger in size than the pellets provided in an intermediate portion.

Abstract: An apparatus for etching a wafer by a single-wafer process comprises a fluid supplying device which feeds an etching fluid on a wafer, and a wafer-chuck for horizontally holding the wafer. The wafer-chuck is equipped with a gas injection device for injecting a gas to the wafer, a first fluid-aspirating device, and a second fluid-aspirating device. The etching fluid supplied on the wafer is spread by a rotation of the wafer. The etching fluid is scattered by a centrifugal force, or flows down over an edge portion of the wafer and is blown-off by the gas injected from the gas injection unit, and is aspirated by the first fluid-aspirating device or the second fluid-aspirating device.

Abstract: The present invention provides a polishing solution distribution apparatus capable of reducing distribution deviation of polishing solution even when leveling for installation is insufficient or inclination of an installation location varies and a polishing apparatus having the same. The polishing solution distribution apparatus includes a cone-shaped branch body in which a solution pan to store supplied polishing solution is formed and in which plural flow passages radially connected to a side face of the solution pan respectively and having a delivery port to supply polishing solution to a position lower than the connected position are formed, a support portion to support the branch body, and a universal joint mechanism to support the branch body via the support portion at a position being higher than the gravity center of the branch body.

Abstract: Disclosed is a method for smoothing the surface of at least one side of a wafer which is obtained by slicing a semiconductor ingot. In this method, a fluid is applied according to projections of the wafer surface, thereby reducing the projections. Alternatively, a fluid is applied over the wafer surface, thereby smoothing the entire surface of the wafer while reducing the projections in the wafer surface.

Abstract: An object of the present invention is to provide a single wafer etching apparatus realizing a high flatness of wafers and an increase in productivity thereof. In the single wafer etching apparatus, a single thin disk-like wafer sliced from a silicon single crystal ingot is mounted on a wafer chuck and spun thereon, and an overall front surface of the wafer is etched with an etching solution supplied thereto by centrifugal force generated by spinning the wafer 11. The singe wafer etching apparatus includes a plurality of supply nozzles 26, 27 capable of discharging the etching solution 14 from discharge openings 26a, 27a onto the front surface of the wafer 11, nozzle-moving devices each capable of independently moving the plurality of supply nozzles 28, 29, and an etching solution supplying device 30 for supplying the etching solution 14 to each of the plurality of supply nozzles and discharging the etching solution 14 from each of the discharge openings to the front surface of the wafer 11.

Abstract: A laser-marked semiconductor wafer having a good flatness in the vicinity of laser mark-printed sites is produced by a method comprising a slicing step; a planarization step; a laser mark printing step; a grinding step; an etching step; and a polishing step.

Abstract: Disclosed is a method for smoothing the surface of at least one side of a wafer which is obtained by slicing a semiconductor ingot. In this method, a fluid is applied according to projections of the wafer surface, thereby reducing the projections. Alternatively, a fluid is applied over the wafer surface, thereby smoothing the entire surface of the wafer while reducing the projections in the wafer surface.

Abstract: This wafer polishing apparatus includes: a polishing plate having a polishing pad; a carrier plate which is placed facing the polishing pad and which slides and presses wafers against the polishing pad, while rotating in a state of holding the wafers; and an abrasive slurry supply device, wherein the abrasive slurry supply device is able to supply different abrasive slurries, each of the abrasive slurries contains abrasives of which the average grain size is different from those contained in the other abrasive slurries. This method for polishing wafers includes: while supplying an abrasive slurry to a surface of a polishing pad, sliding and pressing wafers against the polishing pad, wherein different abrasive slurries are supplied to the surface of the polishing pad, and each of the abrasive slurries contains abrasives of which the average grain size is different from those contained in the other abrasive slurries.