摘要:
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.
摘要:
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.
摘要:
The present invention is a semiconductor wafer including an orientation identification mark, which is used for identifying crystal orientation, on a peripheral surface thereof, in which the orientation identification mark is smoothly joined with a portion outside of the orientation identification mark on the peripheral surface, has a planar surface that is orthogonal to an inner diameter direction of the semiconductor wafer, and has a gloss different from that in the portion outside of the orientation identification mark on the peripheral surface.
摘要:
The present invention is a semiconductor wafer including an orientation identification mark, which is used for identifying crystal orientation, on a peripheral surface thereof, in which the orientation identification mark has a terraced structure that is concave toward an inner diameter direction of the semiconductor wafer with respect to a portion outside of the orientation identification mark on the peripheral surface, and has a planar surface that is orthogonal to a diameter direction of the semiconductor wafer; and has a gloss different from that of the portion outside of the orientation identification mark on the peripheral surface.
摘要:
A wafer manufacturing method includes after flattening both upper and lower surfaces of a wafer sliced from a single crystal ingot, processing the wafer having damage on both surfaces caused by the flattening, so as to obtain desired damage at least on the lower surface of the wafer, the desired damage having a damage depth ranging from 5 nm-10 μm; forming a polysilicon layer at least on the lower surface of the wafer while the damage on the lower surface of the wafer remains; single-wafer etching the upper surface of the wafer; and final polishing the upper surface of the wafer to have a mirrored surface, after the single-wafer etching.
摘要:
A semiconductor wafer with high flatness is provided. The semiconductor wafer has a diameter φ of 450 mm and a thickness of at least 900 μm and no greater than 1,100 μm.
摘要:
Local shape collapse of a wafer end portion is suppressed to the minimum level, and a wafer front surface as well as a wafer end portion is uniformly etched while preventing an etchant from flowing to a wafer rear surface. There is provided an etching method of a single wafer which supplies an etchant onto a wafer front surface in a state where a single wafer having flattened front and rear surfaces is held, and etches the wafer front surface and a front surface side end portion by using a centrifugal force generated by horizontally rotating the wafer. According to this method, the etchant is intermittently supplied onto the front surface of the wafer in twice or more, supply of the etchant is stopped after the etchant for one process is supplied, and the etchant for the next process is supplied after the supplied etchant flows off from the end portion of the wafer.