In order to respond flexibly to various processing modes, such as forming curved surface shapes, when cutting a workpiece using a wire saw, this wire saw device (1) is provided with: a single robot arm (2) that is capable of moving freely by means of multi-axis control; a wire saw unit (3) that is detachably connected to the robot arm (2) via a tool changer (7); a wire (8) that spans a plurality of pulleys supported within the wire saw unit (3); and a workpiece cutting zone (20) that is established between the pulleys. The workpiece is cut to a prescribed shape by moving the robot arm (2) in a preset direction while running the wire (8) of the wire saw unit (3) and pressing the wire (8) against the supported workpiece.

In order to respond flexibly to various processing modes, such as forming curved surface shapes, when cutting a workpiece using a wire saw, this wire saw device (1) is provided with: a single robot arm (2) that is capable of moving freely by means of multi-axis control; a wire saw unit (3) that is detachably connected to the robot arm (2) via a tool changer (7); a wire (8) that spans a plurality of pulleys supported within the wire saw unit (3); and a workpiece cutting zone (20) that is established between the pulleys. The workpiece is cut to a prescribed shape by moving the robot arm (2) in a preset direction while running the wire (8) of the wire saw unit (3) and pressing the wire (8) against the supported workpiece.

Systems and methods are described for controlled crack propagation in a material using ultrasonic waves. A first stress in applied to the material such that the first stress is below a critical point of the material and is insufficient to initiate cracking of the material. A controlled ultrasound wave is then applied to the material causing the total stress applied at a crack tip in the material to exceed the critical point. In some implementations, the controlled cracking is used for wafering of a material.

A method for manufacturing an ingot block in which an ingot of a silicon single crystal pulled up by a Czochralski process is cut and subjected to outer periphery grinding to manufacture an ingot block of the silicon single crystal, the method including: a step of measuring a radial center position of the ingot at one or more locations along a longitudinal direction of the ingot, a step of setting a reference position at which an offset amount of the measured radial center position of the ingot is equal to or less than a predetermined eccentricity amount, a step of cutting the ingot into the ingot blocks based on the set reference position, and a step of performing outer periphery grinding on each of the cut ingot blocks.

A method for manufacturing an ingot block in which an ingot of a silicon single crystal pulled up by a Czochralski process is cut and subjected to outer periphery grinding to manufacture an ingot block of the silicon single crystal, the method including: a step of measuring a radial center position of the ingot at one or more locations along a longitudinal direction of the ingot, a step of setting a reference position at which an offset amount of the measured radial center position of the ingot is equal to or less than a predetermined eccentricity amount, a step of cutting the ingot into the ingot blocks based on the set reference position, and a step of performing outer periphery grinding on each of the cut ingot blocks.

A wire saw apparatus including: a plurality of wire guides; a wire row formed of a wire which is wound around the plurality of wire guides and configured to reciprocatively travel in an axial direction; a nozzle configured to supply a coolant or slurry to the wire; a workpiece-holding portion configured to suspend and hold a workpiece plate having a workpiece bonded thereto with a beam interposed therebetween; a workpiece-feeding mechanism configured to press the workpiece against the wire row; and a mechanism configured to adjust a parallelism of axes of the plurality of wire guides around which the wire row is formed. Thereby, a wire saw apparatus and a method for manufacturing a wafer are provided which enable manufacturing of a wafer having any warp shape by controlling a warp in a wire travelling direction of a sliced workpiece.

Systems and methods are described for controlled crack propagation in a material using ultrasonic waves. A first stress in applied to the material such that the first stress is below a critical point of the material and is insufficient to initiate cracking of the material. A controlled ultrasound wave is then applied to the material causing the total stress applied at a crack tip in the material to exceed the critical point. In some implementations, the controlled cracking is used for wafering of a material.

A device includes: a separating unit 10 which forms a weak layer WL in a semiconductor wafer WF supported by a base support unit BS to divide the wafer WF into a thinned wafer WF1 and a residual wafer WF2 with the weak layer WL as a boundary, and separates the wafer WF2 from the wafer WF1; a first transfer unit 20 which transfers the wafer WF1 from which the wafer WF2 is separated by the unit 10; a processing unit 30 which applies predetermined processing to the WF1 transferred by the unit 20; a second transfer unit 40 which transfers the wafer WF1 to which the predetermined processing is applied by the unit 30; and a reinforcing member pasting unit 50 which pastes a reinforcing member AS on the wafer WF1 transferred by the unit 40. The unit 20 and the unit 40 transfer the wafer WF1 with the unit BS.

A processing method for processing a single-crystal silicon wafer that has a first surface and a second surface formed in such a manner that a specific crystal plane included in a crystal plane {100} is exposed in each of the first and second surfaces and has devices formed in the respective regions marked out by planned dividing lines in the first surface. The method includes forming dividing origins along each planned dividing line, forming a separation layer along the crystal plane of the second surface through relatively moving a focal point and the wafer along a first direction that is parallel to the crystal plane of the second surface and in which an acute angle formed between the first direction and the crystal orientation <100> is equal to or smaller than 5°, and separating the wafer into a first-surface-side wafer including devices and a second-surface-side wafer including no devices.

Methods of recycling silicon swarf into electronic grade polysilicon or metallurgical-grade silicon are described herein are described. In an example, a method includes cutting a silicon ingot and recovering silicon swarf having a first purity from the cutting process. The recovered silicon is purified in an upgraded metallurgical silicon process to produce electronic grade polysilicon particles having a second purity higher than the first purity. The upgraded metallurgical silicon process can include dissolving the recovered silicon particles in a molten aluminum metal smelt.