Embodiments disclosed include a multilayer substrate for semiconductor packaging. The substrate may include a first layer with a first side with an xy-plane and individual locations on the first side have a first side distance below the first side xy-plane, and a second side with a second side xy-plane and individual locations on the second side may have a second side distance below the second side xy-plane; and a second layer with a first side coupled to the second side of the first layer and a second side opposite the first side of the second layer, wherein a thickness of the second layer at the individual locations on the second layer may be comprised of the first side distance plus the second side distance. Other embodiments may be described and/or claimed.

Provided is a wafer including a ring part and a processed part. The processed part is connected to the ring part. The processed part has a top surface which has been grounded and a bottom surface opposite to the top surface. The processed part is surrounded by the ring part. A region where the top surface connects to the ring part is a curved surface curved upwards.

A semiconductor device manufacturing method is provided. In a semiconductor wafer prepared, the width of a dicing line is larger than a cut region to be diced with a dicing blade, a first chip forming region and a second chip forming region are adjacent and have the dicing line therebetween, some of the pads are formed on a first chip forming region side, and the remaining pads are formed on a second chip forming region side. The semiconductor wafer is diced with the dicing blade in such manner that, when the some of the pads are diced, a part of the dicing blade on the second chip forming region side does not abut the some of the pads, and, when the remaining pads are diced, a part of the dicing blade on the first one chip forming region side does not abut the remaining pads.

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 substrate for epitaxial growth includes a central region that has a center of the substrate and that serves as a non-modified region, and a peripheral region that surrounds the central region in a manner to be spaced apart from the center of the substrate by a distance and that serves as a modified region having a plurality of modified points. A method for manufacturing a substrate for epitaxial growth includes providing a substrate and forming a plurality of modified points in an interior of the substrate in position corresponding to the modified region. A semiconductor device including the substrate and a method for manufacturing the semiconductor device are also disclosed.

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 wafer polishing method includes moving a polishing pad to a standby position where a gap is defined between the upper surface of a wafer held on a holding unit and the lower surface of the polishing pad, lowering the polishing pad from the standby position by a preset distance at a preset speed, determining whether or not a load measured by a load sensor is greater than or equal to a preset threshold value in a rest condition of the polishing pad after lowering the polishing pad, repeatedly the lowering the polishing pad until it is determined that the load measured by the load sensor is greater than or equal to the threshold value, and polishing the wafer in the condition where a load falling in a predetermined load range including the threshold value.

A crystalline material processing method includes forming subsurface laser damage at a first average depth position to form cracks in the substrate interior propagating outward from at least one subsurface laser damage pattern, followed by imaging the substrate top surface, analyzing the image to identify a condition indicative of presence of uncracked regions within the substrate, and taking one or more actions responsive to the analyzing. One potential action includes changing an instruction set for producing subsequent laser damage formation (at second or subsequent average depth positions), without necessarily forming additional damage at the first depth position. Another potential action includes forming additional subsurface laser damage at the first depth position. The substrate surface is illuminated with a diffuse light source arranged perpendicular to a primary substrate flat and positioned to a first side of the substrate, and imaged with an imaging device positioned to an opposing second side of the substrate.

A semiconductor device manufacturing method includes forming a ring-shaped rib at an outer circumferential edge of a semiconductor wafer by grinding a center of a back surface of the semiconductor wafer, so that the rib has a thickness greater than a thickness of the center of the semiconductor wafer, pasting a first protective film on the back surface of the semiconductor wafer, pasting a second protective film so as to cover an outer circumferential edge of the first protective film and an outer circumference of the rib, positioning the back surface of the semiconductor wafer so as to face a heating surface of a hot plate and directly heating the first protective film and the second protective film by using the hot plate, and performing a plating treatment on a surface of the semiconductor wafer.

A semiconductor device has a first semiconductor die and second semiconductor die with a conductive layer formed over the first semiconductor die and second semiconductor die. The second semiconductor die is disposed adjacent to the first semiconductor die with a side surface and the conductive layer of the first semiconductor die contacting a side surface and the conductive layer of the second semiconductor die. An interconnect, such as a conductive material, is formed across a junction between the conductive layers of the first and second semiconductor die. The conductive layer may extend down the side surface of the first semiconductor die and further down the side surface of the second semiconductor die. An extension of the side surface of the first semiconductor die can interlock with a recess of the side surface of the second semiconductor die. The conductive layer extends over the extension and into the recess.