A cleaner composition consisting essentially of (A) 92.0 wt % to less than 99.9 wt % of an organic solvent, (B) 0.1 wt % to less than 8.0 wt % of a C.sub.3-C.sub.6 alcohol, and (C) 0.001-3.0 wt % of a quaternary ammonium salt is effective for removing any silicone adhesive residues on a silicon semiconductor substrate. A satisfactory degree of cleanness is achieved within a short time and at a high efficiency without causing corrosion to the substrate.

A method for producing mirror-polished wafer, the method produces a plurality of mirror-polished wafers by performing, on plurality of silicon wafers obtained by slicing a silicon ingot, slicing strain removing step of removing strain on a surface caused by slicing, etching step of removing strain caused by the slicing strain removing step, and double-side polishing step of performing mirror polishing on both surfaces of the silicon wafers subjected to etching, each step being performed by batch processing, wherein silicon wafers which are processed in double-side polishing step by batch processing are selected from silicon wafers processed in same batch in the slicing strain removing step and the number of silicon wafers to be selected is made to be equal to the number of silicon wafers processed in the slicing strain removing step or submultiple thereof. As a result, a method that can produce mirror-polished wafers having high flatness is provided.

The present disclosure provides a semiconductor fabrication apparatus in accordance with one embodiment. The apparatus includes a wafer stage that is operable to secure and rotate a wafer; a polish head configured to polish a backside surface of the wafer; an air bearing module configured to apply an air pressure to a front surface of the wafer; and an edge sealing unit configured to seal edges of the wafer.

There is provided a processing method of a wafer. The processing method includes a protective sheet preparation step of preparing a protective sheet including a first sheet that is thermocompression-bonded to a surface of the wafer by heating, a second sheet that is laid on the first sheet and has fluidity due to the heating, and a third sheet that is laid on the second sheet and keeps flatness even with the heating. The processing method also includes a protective sheet laying step of causing a side of the first sheet to face a front surface of the wafer and executing heating to execute thermocompression bonding to lay the protective sheet on the front surface of the wafer and a grinding step of causing a side of the protective sheet to be held by a holding surface of a chuck table and grinding a back surface of the wafer.

Provided is a method of lapping a semiconductor wafer, which can suppress the formation of a ring-shaped pattern in a nanotopography map. The method of lapping a semiconductor wafer includes: a stopping step of stopping lapping of a semiconductor wafer; a reversing step of reversing surfaces of the semiconductor wafer facing a upper plate and a lower plate after the stopping step; and a resuming step of resuming lapping of the semiconductor wafer after the reversing step while maintaining the reversal of the surfaces facing the plates.

A silicon carbide single crystal substrate includes a first main surface, a second main surface, and a circumferential edge portion. The second main surface is opposite to the first main surface. The circumferential edge portion connects the first main surface and the second main surface. The circumferential edge portion has a linear orientation flat portion, a first arc portion having a first radius, and a second arc portion connecting the orientation flat portion and the first arc portion and having a second radius smaller than the first radius, when viewed along a direction perpendicular to the first main surface.

A method of manufacturing a semiconductor package structure is provided. The method includes providing a first carrier, forming a patterned buffer layer over the first carrier, forming a first redistribution structure that includes forming a first dielectric layer on the patterned buffer layer, after an electrical testing by applying an electric signal towards the first redistribution structure, removing the first carrier, removing portions of the first dielectric layer, resulting in a patterned first dielectric layer, the patterned first dielectric layer exposing portions of the first circuit layer, removing the exposed portions of the first circuit layer, using the patterned first dielectric layer as a mask, resulting in a patterned first circuit layer, and forming an electric conductor in a recess defined by the patterned first dielectric layer and the patterned first circuit layer.

Embodiments of semiconductor devices and fabrication methods thereof are disclosed. In an example, a semiconductor device includes a first semiconductor structure including a processor and a first bonding layer including a plurality of first bonding contacts. The semiconductor device also includes a second semiconductor structure including an array of static random-access memory (SRAM) cells and a second bonding layer including a plurality of second bonding contacts. The semiconductor device further includes a bonding interface between the first bonding layer and the second bonding layer. The first bonding contacts are in contact with the second bonding contacts at the bonding interface.

In a method for manufacturing an SiC wafer, a work-affected layer removal step of removing a work-affected layer generated in a surface and inside of an SiC wafer is performed, so that the SiC wafer from which the work-affected layer is at least partially removed is manufactured. In the work-affected layer removal step, the SiC wafer having undergone a polishing step is etched with an etching amount of 10 μm or less by being heated under Si vapor pressure so that the work-affected layer is removed. In the polishing step, an oxidizer is used to produce a reaction product in the SiC wafer while abrasive grains are used to remove the reaction product. In the SiC wafer having undergone the polishing step, an internal stress caused by the work-affected layer is present at a location inner than the work-affected layer, and an internal stress of the SiC wafer is reduced by removing the work-affected layer in the work-affected layer removal step.

A wafer manufacturing method, an epitaxial wafer manufacturing method, and a wafer and epitaxial wafer manufactured thereby, are provided. The wafer manufacturing method enables the manufacture of a wafer with a low density of micropipe defects and minimum numbers of particles and scratches. The epitaxial wafer manufacturing method enables the manufacture of an epitaxial wafer that has low densities of defects such as downfall, triangular, and carrot defects, exhibits excellent device characteristics, and improves the yield of devices.