A laser lift-off integrated apparatus includes a laser light source configured to perform laser lift-off on a wafer to undergo lift-off, a lift-off chamber configured to bear the wafer to undergo lift-off, a heater configured to provide temperature required by the wafer to undergo lift-off during a lift-off process, a profile measuring device configured to acquire surface profile information of the wafer to undergo lift-off, and a movable device configured to, according to the surface profile information acquired by the profile measuring device, adjust a height of the wafer to undergo lift-off such that a focus of the laser light source is at a position where the wafer to undergo lift-off is to undergo lift-off.

The present invention provides an aluminum nitride wafer and a method for making the same. The method includes forming at least one alignment notch in or at least one flat alignment edge on a periphery of the aluminum nitride wafer. The alignment notch and the flat alignment edge can prevent the aluminum nitride wafer from being in a poor state during the semiconductor manufacturing process and makes it possible to position the aluminum nitride wafer precisely so that the fraction defective can be lowered. The aluminum nitride wafer of the present invention has advantages of effective insulation, efficient heat dissipation, and a high dielectric constant, and can be used in semiconductor manufacturing processes, electronic products, and semiconductor equipment.

A silicon carbide substrate production method includes: the step of providing covering layers 1b, 1b, each containing silicon oxide, silicon nitride, silicon carbonitride, or silicide, respectively on both surfaces of a base material substrate 1a carbon, silicon or silicon carbide, and turning the surface of each of the covering layers 1b, 1b into a smooth surface to prepare a support substrate 1; a step of forming a polycrystalline silicon carbide film 10 on both surfaces of the support substrate 1 by a gas phase growth method or a liquid phase growth method; and a step of separating the polycrystalline silicon carbide films from the support substrate while preserving, on the surface thereof, the smoothness of the covering layer surfaces 1b, 1b by chemically removing at least the covering layers 1b, 1b, from the support substrate 1. The silicon carbide substrate has a smooth surface and reduced internal stress.

The present disclosure provides a wafer annealing method, including: preparing a wafer, the wafer includes a plurality of regions concentrically disposed on the wafer; heating the plurality of regions, the heating process includes a plurality of heating stages, each of the heating stages has a different heating rate, temperatures of the plurality of regions vary in each of the heating stages; performing heat preservation on the plurality of regions; and cooling the plurality of regions through blowing nitrogen. The wafer annealing method can improve the electrical uniformity of the wafer.

A method for disassembling a stack of at least three substrates. The invention relates to the techniques for transferring thin films in the microelectronics field. It proposes a method for disassembling a stack of at least three substrates having between them two interfaces, one interface of which has an adhesion energy and an interface of which has an adhesion energy, with less than, the method comprising: 1) implementing a removal of material on the first substrate, in order to expose a surface of the second substrate, 2) transferring the stack onto a flexible adhesive film so that the surface has, with an adhesive layer of the film, an adhesion energy greater than, and 3) disassembling the third substrate at the interface between the second substrate and the third substrate. The method makes it possible to open the stack via the interface thereof with the highest adhesion energy.

A method for manufacturing a carbon-doped silicon single crystal wafer, including steps of: preparing a silicon single crystal wafer not doped with carbon; performing a first RTA treatment on the silicon single crystal wafer in an atmosphere containing compound gas; performing a second RTA treatment at a higher temperature than the first RTA treatment; cooling the silicon single crystal wafer after the second RTA treatment; and performing a third RTA treatment. The crystal wafer is modified to a carbon-doped silicon single crystal wafer, sequentially from a surface thereof: a 3C-SiC single crystal layer; a carbon precipitation layer; a diffusion layer of interstitial carbon and silicon; and a diffusion layer of vacancy and carbon. A carbon-doped silicon single crystal wafer having a surface layer with high carbon concentration and uniform carbon concentration distribution to enable wafer strength enhancement; and a method for manufacturing the carbon-doped silicon single crystal wafer.

A method of fabricating a silicon carbide material is provided. The method includes the following steps. A first annealing process is performed on a wafer or on an ingot that forms the wafer after wafer slicing. The conditions of the first annealing process include: a heating rate of 10° C./minute to 30° C./minute, an annealing temperature of 2000° C. or less, and a constant temperature annealing time of 2 minutes or more and 4 hours or less for performing the first annealing process. After performing the first annealing process, an average resistivity of the wafer or the ingot is greater than 10.sup.10 Ω.Math.cm.

A manufacturing method of a silicon carbide wafer includes the following. A raw material containing carbon and silicon and a seed located above the raw material are provided in a reactor. A nitrogen content in the reactor is reduced, which includes the following. An argon gas is passed into the reactor, where a flow rate of passing the argon gas into the reactor is 1,000 sccm to 5,000 sccm, and a time of passing the argon gas into the reactor is 2 hours to 48 hours. The reactor and the raw material are heated to form a silicon carbide material on the seed. The reactor and the raw material are cooled to obtain a silicon carbide ingot. The silicon carbide ingot is cut to obtain a plurality of silicon carbide wafers. A semiconductor structure is also provided.

The invention relates to a method of producing a substrate. The method comprises providing a workpiece having a first surface and a second surface opposite the first surface, and providing a carrier having a first surface and a second surface opposite the first surface. The method further comprises attaching the carrier to the workpiece, wherein at least a peripheral portion of the first surface of the carrier is attached to the first surface of the workpiece, and forming a modified layer inside the workpiece. Moreover, the method comprises dividing the workpiece along the modified layer, thereby obtaining the substrate, wherein the substrate has the carrier attached thereto, and removing carrier material from the side of the second surface of the carrier in a central portion of the carrier so as to form a recess in the carrier. The invention further relates to a substrate producing system for performing this method.

Provided is a method for manufacturing a monocrystalline substrate, the method including: a process of forming a seed layer on a base charged into a monocrystalline growth apparatus; a process of taking the base, on which the seed layer is formed, out of the monocrystalline growth apparatus and irradiating laser onto the seed layer from a lower side of the base to form a separation layer having a plurality of voids; a process of charging the base, on which the separation layer is formed, into the monocrystalline growth apparatus to form a monocrystalline layer on the separation layer; and a separation process of taking the base, on which the separation layer and the monocrystalline layer are formed, out of the monocrystalline growth apparatus to separate the monocrystalline layer from the base. Therefore, the monocrystalline layer may be grown on the flat surface of the separation layer, and the monocrystalline substrate having the excellent crystallinity and suppressed in occurrence of the defects may be prepared. That is, the monocrystalline substrate having the excellent crystallinity and suppressed in occurrence of the defects while omitting the planarization process for planarizing the surface of the flat separation layer may be prepared.