Abstract: A method for manufacturing a semiconductor element includes providing a wafer having a sapphire substrate and a semiconductor stacked body disposed on the sapphire substrate, performing a first scanning of a portion of the sapphire substrate in which a laser beam is irradiated into an interior of the sapphire substrate, performing a second scanning of the portion of the sapphire substrate in which a laser beam is irradiated into the interior of the sapphire substrate, the second scanning occurring after the first scanning and before a void is produced in the interior of the sapphire substrate irradiated with the laser beam in the first scanning, and separating the wafer into a plurality of semiconductor elements.

Abstract: A method for manufacturing a light emitting element that includes preparing a wafer having a substrate and a semiconductor structure, the substrate including a plurality of protrusions at positions corresponding to lattice points on a triangular lattice. The method includes forming a plurality of first modified parts in the substrate by irradiating the substrate with a laser beam along first dividing lines, forming a plurality of second modified parts in the substrate by irradiating the substrate with a laser beam along second dividing lines, and dividing the wafer along the first modified parts and the second modified parts to obtain a plurality of light emitting elements.

Abstract: A method for manufacturing a semiconductor element includes providing a wafer having a sapphire substrate and a semiconductor stacked body disposed on the sapphire substrate, performing a first scanning of a portion of the sapphire substrate in which a laser beam is irradiated into an interior of the sapphire substrate, performing a second scanning of the portion of the sapphire substrate in which a laser beam is irradiated into the interior of the sapphire substrate, the second scanning occurring after the first scanning and before a void is produced in the interior of the sapphire substrate irradiated with the laser beam in the first scanning, and separating the wafer into a plurality of semiconductor elements.

Abstract: A method for manufacturing a semiconductor element is provided. The method includes providing a semiconductor wafer including a substrate and a semiconductor structure on the substrate, forming a cleavage starting portion in the semiconductor wafer, and dividing the semiconductor wafer into a plurality of semiconductor elements by transferring a pressing member on the semiconductor wafer in a state where the pressing member is pressed against the semiconductor wafer to separate the semiconductor wafer at the cleavage starting portion. The pressing member includes a tip portion to be pressed on the semiconductor wafer, and the tip portion has a spherical surface.

Abstract: A semiconductor element includes a substrate and a semiconductor layer. The substrate has a first main face and a second main face. The semiconductor layer is formed on a side of one of the first main face and the second main face of the substrate. The substrate has a plurality of isolated processed portions and an irregularity face that runs from the processed portions at least to the first main face of the substrate and links adjacent ones of the processed portions.

Abstract: A method for manufacturing a light emitting element includes: preparing a wafer that has a substrate in which a first main face is provided with a plurality of convex components; and dividing the wafer along first dividing lines and second dividing lines. The convex components are in the form of circular cones or truncated circular cones, each of which having a circular bottom face and a side face that is connected to the bottom face, and disposed regularly so that a plurality of bounded regions are present around the convex components, and a shortest distance between the convex components and the centers of the bounded regions is less than a radius of the bottom faces of the convex components. The first and second dividing lines extend in a direction that intersects straight lines that link the centers of the plurality of bounded regions around a single convex component.

Abstract: A method for manufacturing a light emitting element includes: preparing a wafer that has a substrate in which a first main face is provided with a plurality of convex components; and dividing the wafer along first dividing lines and second dividing lines. The convex components are in the form of circular cones or truncated circular cones, each of which having a circular bottom face and a side face that is connected to the bottom face, and disposed regularly so that a plurality of bounded regions are present around the convex components, and a shortest distance between the convex components and the centers of the bounded regions is less than a radius of the bottom faces of the convex components. The first and second dividing lines extend in a direction that intersects straight lines that link the centers of the plurality of bounded regions around a single convex component.

Abstract: A method for manufacturing a light emitting element, including steps of preparing a wafer that has a substrate with a first main face and a second main face, in which the first main face is provided with a plurality of convex components and valleys that connect these convex components, and a semiconductor structure that is provided on the first main face; and dividing the wafer by laser scribing in which a laser beam is emitted from the second main face side along first dividing lines and second dividing lines to obtain a plurality of light emitting elements. The convex components are in the form of pyramids, prisms, or truncated pyramids, each of which having a polyhedral bottom face with a plurality of apexes, edge lines that extend from the apexes, and side faces that link the edge lines to each other.

Abstract: A method for manufacturing a light emitting element, including steps of preparing a wafer that has a substrate with a first main face and a second main face, in which the first main face is provided with a plurality of convex components and valleys that connect these convex components, and a semiconductor structure that is provided on the first main face; and dividing the wafer by laser scribing in which a laser beam is emitted from the second main face side along first dividing lines and second dividing lines to obtain a plurality of light emitting elements. The convex components are in the form of pyramids, prisms, or truncated pyramids, each of which having a polyhedral bottom face with a plurality of apexes, edge lines that extend from the apexes, and side faces that link the edge lines to each other.

Abstract: A method for manufacturing a light emitting element that includes preparing a wafer having a substrate and a semiconductor structure, the substrate including a plurality of protrusions at positions corresponding to lattice points on a triangular lattice. The method includes forming a plurality of first modified parts in the substrate by irradiating the substrate with a laser beam along first dividing lines, forming a plurality of second modified parts in the substrate by irradiating the substrate with a laser beam along second dividing lines, and dividing the wafer along the first modified parts and the second modified parts to obtain a plurality of light emitting elements.

Abstract: A semiconductor element includes a substrate and a semiconductor layer. The substrate has a first main face and a second main face. The semiconductor layer is formed on a side of one of the first main face and the second main face of the substrate. The substrate has a plurality of isolated processed portions and an irregularity face that runs from the processed portions at least to the first main face of the substrate and links adjacent ones of the processed portions.

Abstract: A method for manufacturing a semiconductor element of the present invention, has: a laser irradiation step of focusing a pulsed laser beam inside of a substrate constituting a wafer, thereby forming a plurality of isolated processed portions along an intended dividing line inside of the substrate, and creating a fissure that runs from the processed portions at least to the surface of the substrate and links adjacent processed portions; and a wafer division step of dividing the wafer along the intended dividing line.

Abstract: A method for manufacturing a semiconductor element of the present invention, has: a laser irradiation step of focusing a pulsed laser beam inside of a substrate constituting a wafer, thereby forming a plurality of isolated processed portions along an intended dividing line inside of the substrate, and creating a fissure that runs from the processed portions at least to the surface of the substrate and links adjacent processed portions; and a wafer division step of dividing the wafer along the intended dividing line.

Abstract: Disclosed is a commutator type rotary electric machine which is designed to simplify the structure through reduction of number of component parts and allows to significantly enhance heat radiation from a brush. Both end bracket supports a rotary shaft and cylindrical brush holder are made of metal. The cylindrical brush holder is secured to the end bracket. The surface of internal periphery of brush holder is covered by an electrical insulator. Since it is sufficient for the electrical insulator to have a thickness effective to electrically insulate the brush from the cylindrical brush holder, heat generating from brush is effectively conducted to the end bracket and radiated from it.

Abstract: A magnet switch for a starter device includes a plunger on which a sufficient pull force can be exerted. The plunger drives a movable contact, and is guided by a sleeve so as to move therealong. An excited coil wound on a bobbin is provided around an outer periphery of the sleeve. The exciting coil is covered by a cylindrical frame of a magnetic material, and a bottom plate portion of the frame has an opening fitted on the outer periphery of the sleeve. A cushion spring is interposed between the bottom plate portion of the frame and the bobbin to hold the exciting coil in a predetermined position. The cushion spring has an annular portion disposed in contact with the bottom plate portion and the outer periphery of the sleeve, and a magnetic path can be formed between the annular portion and the plunger.