A method for forming a semiconductor structure includes forming a dielectric layer on a substrate, including a first region and a second region; forming a first gate opening and a second gate opening in dielectric layer of the first region and the second region, respectively; forming initial work function layers on bottom and sidewall surfaces of the first gate opening and the second gate opening; and performing at least one cycle of a combined etching process to etch the initial work function layers formed in the first gate opening and form a work function layer in the second gate opening from the initial work function layers. Each cycle of the combined etching process includes performing an oxide etching process to etch the initial work function layers; and then performing a main etching process on the initial work function layers to remove an exposed initial work function layer.

Provided is an indium phosphide substrate having good accuracy of flatness of the orientation flat, and a method for producing the indium phosphide substrate. An indium phosphide substrate having a main surface and an orientation flat, wherein a difference between maximum and minimum values of a maximum height Pz in each of four cross-sectional curves is less than or equal to 1.50/10000 of a length in a longitudinal direction of an orientation flat end face, wherein the four cross-sectional curves are set at intervals of one-fifth of a thickness of the substrate on a surface excluding a width portion of 3 mm inward from both ends of the orientation flat end face in the longitudinal direction of the orientation flat end face, and the maximum height Pz in each of the four cross-sectional curves is measured in accordance with JIS B 0601:2013.

A method includes a graphene precursor formation process of: heating a SiC substrate to sublimate Si atoms in a Si surface of the SiC substrate so that a graphene precursor is formed; and stopping the heating before the graphene precursor is covered with graphene. A SiC substrate to be treated in the graphene precursor formation process is provided with a step including a plurality of molecular layers. The step has a stepped structure in which a molecular layer whose C atom has two dangling bonds is disposed closer to the surface than a molecular layer whose C atom has one dangling bond.

Provided is an indium phosphide substrate having good linearity accuracy of a ridge line where the main surface is in contact with the orientation flat, and a method for producing the indium phosphide substrate. An indium phosphide substrate having a main surface and an orientation flat, wherein a maximum value of deviation is less than 1/1000 of a length of a ridge line where the main surface is in contact with the orientation flat, when a plurality of measurement points are set at intervals of 2 mm from a start point to an end point at the ridge line, except for a length portion of 3 mm inward from both ends of the ridge line, and based on a reference line which is a straight line connecting the start point and the end point, a distance of each measurement point from the reference line is defined as the deviation of each measurement point.

A method for manufacturing a wide band gap semiconductor device using a substrate of SiC wafer is disclosed. The method includes coating the substrate with a hard mask material, performing lithography to define patterned openings in the hard mask material of the substrate, etching the substrate to form patterned trenches from the defined patterned openings, removing the hard mask using a chemical process from the substrate, cleaning the substrate with the patterned trenches, performing epitaxy on the substrate to form a uniform single crystal layer over the patterned trenches to create a plurality of micro voids, kiss polishing the substrate, performing another epitaxy on the substrate using a fast epitaxial growth process to provide an active device epitaxial layer suitable to fabricate SiC devices, and after fabrication of the SiC devices, severing the plurality of micro voids to extract the SiC devices from the substrate of the SiC wafer.

A method for manufacturing a wafer product, including the steps of: chamfering a circumferential edge portion of a wafer; lapping or double-side grinding main surfaces thereof; etching; mirror-polishing the main surface; and mirror-polishing the chamfered portion. The chamfered portion has a cross-sectional shape including: a first inclined portion continuous from the first main surface; a first arc portion continuous from the first inclined portion and having a radius of curvature; a second inclined portion continuous from the second main surface; a second arc portion continuous from the second inclined portion and having a radius of curvature; and an end portion connecting the first arc portion to the second arc portion. This provides a method for manufacturing a wafer by which a variation in a chamfered cross-sectional shape in a circumferential direction caused by etching can be suppressed.

A device for manufacturing a SiC substrate, in which the occurrence of a work-affected layer is reduced, or from which a work-affected layer is removed, comprises: a main container which can accommodate a SiC substrate and which generates, by heating, a vapor pressure of a vapor-phase species including elemental Si and a vapor-phase species including elemental C in an internal space; and a heating furnace for accommodating the main container, generating a vapor pressure of the vapor-phase species including elemental Si in the internal space, and heating so that a temperature gradient is formed; the main container having an etching space formed by causing a portion of the main container disposed on the low-temperature side of the temperature gradient and the SiC substrate to face each other in a state in which the SiC substrate is disposed on the high-temperature side of the temperature gradient.

Methods and apparatus for far edge trimming are provided herein. For example, an apparatus includes an integrated tool for processing a silicon substrate, comprising a vacuum substrate transfer chamber, an edge trimming apparatus coupled to the vacuum substrate transfer chamber and comprising a high pulse frequency laser and substrate support, wherein at least one of the high pulse frequency laser or the substrate support are movable with respect to each other and configured to trim about 2 mm to about 5 mm from a peripheral edge of a substrate when disposed on the substrate support, and a plasma etching apparatus coupled to the vacuum substrate transfer chamber and configured to etch silicon.

A process of preparing a wafer having a diameter of two inches or more, at least a surface of the wafer being formed from a group III nitride crystal, including preparing an alkaline or acidic etching liquid containing a peroxodisulfate ion as an oxidizing agent that accepts an electron, accommodating the wafer such that the surface of the wafer is immersed in the etching liquid such that the surface of the wafer is parallel with a surface of the etching liquid; and radiating light from the surface side of the etching liquid onto the surface of the wafer without agitating the etching liquid. First and second etching areas disposed at an interval from each other are defined on the surface of the wafer. In the process of radiating the light onto the surface of the wafer, the light is radiated perpendicularly onto surfaces of the first and second etching areas.

There is provided a structure manufacturing method, including: preparing a wafer at least whose surface comprises Group III nitride crystal in a state of being immersed in an etching solution containing peroxodisulfate ions; and irradiating the surface of the wafer with light through the etching solution; wherein the group III nitride crystal has a composition in which a wavelength corresponding to a band gap is 310 nm or more, and during irradiation of the light, the surface of the wafer is irradiated with a first light having a wavelength of 200 nm or more and less than 310 nm under a first irradiation condition, and is irradiated with a second light having a wavelength of 310 nm or more and less than a wavelength corresponding to the band gap under a second irradiation condition controlled independently of the first irradiation condition.