A wafer dividing apparatus for dividing a wafer stuck to an adhesive tape and supported at an opening of a frame into individual chips along a scheduled division line is provided. The wafer dividing apparatus includes a cassette table movable upwardly and downwardly in a Z axis direction, a first carry-out/in unit that carries out the frame from the cassette placed on the cassette table or carry in the frame to the cassette, a first temporary receiving unit including a pair of first guide rails extending in the X axis direction and a guide rail opening/closing portion that increases the distance between the pair of first guide rails, a reversing unit including a holding portion that holds the frame and rotates by 180 degrees to reverse the front and back of the frame, and a transport unit that moves the reversed frame.

A wafer is produced from an ingot by confirming whether or not an inclined c-axis of the ingot and a second orientation flat of the ingot are perpendicular to each other, and detecting a processing feed direction perpendicular to the direction in which the c-axis is inclined. The method includes performing sampling irradiation of the ingot with a laser beam, along a direction parallel to the second orientation flat and a plurality of directions inclined clockwise and counterclockwise by respective predetermined angles from the second orientation flat, thereby forming a plurality of sampled reduced strength areas in the ingot; measuring the number of nodes which exist per unit length on each of the sampled reduced strength areas, and determining a direction in which the sampled reduced strength area where the measured number of nodes is zero extends as a processing feed direction.

An SiC wafer is produced from an SiC ingot by a method that includes a first modified layer forming step and a second modified layer forming step. In the first step, a first laser beam having a first power forms a plurality of discrete first modified layers at a first depth inside the ingot. In the second step, a second laser beam having a second power greater than the first power is applied to the ingot with the second laser beam focused at a depth greater than the first depth. A beam spot of the second laser beam overlaps any one of the plural first modified layers, thereby continuously forming a plurality of second modified layers connected in a line at the first depth. Cracks are formed on both sides of the line of the plural second modified layers so as to extend along a c-plane in the ingot.

There is provided a method for manufacturing a group III nitride substrate, including: preparing a plurality of seed crystal substrates formed into shapes that can be arranged with side surfaces opposed to each other; bonding the plurality of seed crystal substrates on a base material by an adhesive agent in an appearance that the seed crystal substrates are arranged with the side surfaces opposed to each other; growing a group III nitride crystals above main surfaces of the plurality of seed crystal substrates, so that crystals grown on each main surface are integrally combined each other; and obtaining a group III nitride substrate formed of the group III nitride crystal.

A laser processing method which can efficiently perform laser processing while minimizing the deviation of the converging point of a laser beam in end parts of an object to be processed is provided. This laser processing method comprises a preparatory step of holding a lens at an initial position set such that a converging point is located at a predetermined position within the object; a first processing step (S11 and S12) of emitting a first laser beam for processing while holding the lens at the initial position, and moving the lens and the ltd object relative to each other along a main surface so as to form a modified region in one end part of a line to cut; and a second processing step (S13 and S14) of releasing the lens from being held at the initial position after forming the modified region in the one end part of the line to cut, and then moving the lens and the object relative to each other along the main surface while adjusting the gap between the lens and the main surface after the release, so as to form the modified region.

An Si substrate manufacturing method includes a separation band forming step of forming a separation band through positioning a focal point of a laser beam with a wavelength having transmissibility with respect to Si to a depth, equivalent to a thickness of an Si substrate to be manufactured, from a flat surface of an Si ingot and irradiating the Si ingot with the laser beam while relatively moving the focal point and the Si ingot in a direction <110> parallel to a cross line at which a crystal plane {100} and a crystal plane {111} intersect or a direction [110] orthogonal to the cross line, and an indexing feed step of executing indexing feed of the focal point and the Si ingot relatively in a direction orthogonal to a direction in which the separation band is formed.

The present invention relates to a method for producing solid body layers. The claimed method comprises at least the following steps: providing a solid body (2) for separating at least one solid body layer (4), fixing the receiving layer (10) for holding the solid layer (4) to the solid body (2), said receiving layer having a plurality of holes for guiding a fluid and is fixed by means of a connecting layer to the solid body and the receiving layer (10) is subjected to thermal stress, in particular, mechanical stress, for generating voltages in the solid body (2), wherein a crack in the solid body (2) along a separation plane (8) expands due to the voltages, the solid layer (4) being separated from the solid body (2) due to the crack.

Embodiments of the invention are directed to a method of separating a wafer of light emitting devices. The method includes scribing a first groove on a dicing street on the wafer and checking the alignment of the wafer using a location of the first groove relative to a feature on the wafer. After checking the alignment, a second groove is scribed on the dicing street.

A substrate processing tool is prevented from falling out of a tool holder. This substrate processing tool is a tool for attachment to a substrate processing apparatus. The substrate processing tool includes a tool main body, a blade edge portion, and an engaging portion. A holding portion that is to be held by the chuck portion of the substrate processing apparatus is formed in at least a portion of the tool main body. The blade edge portion is formed on one end side of the tool main body. The engaging portion is formed on the other end side of the tool main body, and protrudes farther than the surface of the tool main body.

A wafer producing method produces a hexagonal single crystal wafer from a hexagonal single crystal ingot. The method includes a separation start point forming step of setting the focal point of a laser beam to the inside of the ingot at a predetermined depth from the upper surface of the ingot, which depth corresponds to the thickness of the wafer to be produced, and next applying the laser beam to the upper surface of the ingot while relatively moving the focal point and the ingot to thereby form a modified layer parallel to the upper surface of the ingot and cracks extending from the modified layer, thus forming a separation start point. The separation start point forming step includes an indexing step of relatively moving the focal point in a direction of formation of an off angle to thereby index the focal point by a predetermined index amount.