Abstract: A method for separating wafers from donor substrates incudes: determining at least one individual property of a respective donor substrate, the at least one individual property including doping and/or crystal lattice dislocations of the respective donor substrate; generating donor substrate process data for the respective donor substrate, the donor substrate process data including analysis data of the analysis device, the analysis data describing the at least one individual property of the respective donor substrate; generating, via a laser device, modifications inside the respective donor substrate to form a separating region inside the respective donor substrate, the laser device being operable as a function of the donor substrate process data of the respective donor substrate; and generating mechanical stresses inside the respective donor substrate to initiate and/or guide a crack for separating at least one wafer from the respective donor substrate.

Abstract: Provided is a machining apparatus including a profile sensor unit configured to obtain shape information about a parent substrate; and a laser scan unit configured to direct a laser beam onto the parent substrate, wherein a laser beam axis of the laser beam is tilted to an exposed main surface of the parent substrate, and wherein a track of the laser beam on the parent substrate is controllable as a function of the shape information obtained from the profile sensor unit.

Abstract: A method of manufacturing a semiconductor device is described. The method includes providing a parent substrate including a substrate portion of a first conductivity type. The method further includes forming an absorption layer in the parent substrate by an ion implantation process of an element through a first surface of the parent substrate. The method further includes forming a semiconductor layer structure on the first surface of the parent substrate. The method further includes splitting the parent substrate along a splitting section through a detachment layer. The detachment layer is arranged between the absorption layer and a second surface of the parent substrate at a vertical distance to the absorption layer.

Abstract: Methods for processing a semiconductor substrate are proposed. An example of a method includes forming cavities in the semiconductor substrate by implanting ions through a first surface of the semiconductor substrate. The cavities define a separation layer in the semiconductor substrate. A semiconductor layer is formed on the first surface of the semiconductor substrate. Semiconductor device elements are formed in the semiconductor layer. The semiconductor substrate is separated along the separation layer into a first substrate part including the semiconductor layer and a second substrate part.

Abstract: A method of splitting off a semiconductor wafer from a semiconductor bottle includes: forming a separation region within the semiconductor boule, the separation region having at least one altered physical property which increases thermo-mechanical stress within the separation region relative to the remainder of the semiconductor boule; and applying an external force to the semiconductor boule such that at least one crack propagates along the separation region and a wafer splits from the semiconductor boule.

Abstract: A method for separating a solid-state layer from a solid-state material includes: moving the solid-state material relative to a laser processing system; successively emitting a plurality of laser beams from the laser processing system to the solid-state material to create modifications within the solid-state material; adjusting the laser processing system for defined focusing of the plurality of laser beams and/or for continuous adjustment of energy of the plurality of laser beams as a function of at least one parameter; and detaching the solid-state layer from the solid-state material in a region of the modifications.

Abstract: A solid body is disclosed. The solid body includes: a detachment plane in an interior space of the solid body, the detachment plane including laser radiation-induced modifications; and a region including layers and/or components. A multi-component arrangement is also disclosed. The multi-component arrangement includes: a solid-body layer including more than 50% SiC and modifications or modification components generating pressure tensions in a region of a first surface, the modifications being amorphized components of the solid-body layer, the modifications being spaced closer to the first surface than to a second surface opposite the first surface, the first surface being essentially level; and a metal layer on the first surface of the solid-body layer.

Abstract: A method for separating a solid-body layer from a donor substrate includes: providing a donor substrate having a planar surface, a longitudinal axis orthogonal to the planar surface, and a peripheral surface; producing a plurality of modifications within the donor substrate using at least one LASER beam, wherein the at least one LASER beam penetrates the donor substrate via the peripheral surface at an angle not equal to 90° relative to the longitudinal axis of the donor substrate; producing a stress-inducing polymer layer on the planar surface of the donor substrate; and producing mechanical stresses in the donor substrate by a thermal treatment of the stress-inducing polymer layer, wherein the mechanical stresses produce a crack for separating the solid-body layer, and wherein the crack propagates along the modifications.

Abstract: Methods for processing a semiconductor substrate are proposed. An example of a method includes forming cavities in the semiconductor substrate by implanting ions through a first surface of the semiconductor substrate. The cavities define a separation layer in the semiconductor substrate. A semiconductor layer is formed on the first surface of the semiconductor substrate. Semiconductor device elements are formed in the semiconductor layer. The semiconductor substrate is separated along the separation layer into a first substrate part including the semiconductor layer and a second substrate part.