A manufacturing method for manufacturing a stacked substrate by bonding two substrates includes: acquiring information about crystal structures of a plurality of substrates; and determining a combination of two substrates to be bonded to each other, based on the information about the crystal structures. In the manufacturing method described above, the information about the crystal structures may include at least one of plane orientations of bonding surfaces and crystal orientations in a direction in parallel with the bonding surfaces. In the manufacturing methods described above, the determining may include determining a combination of the two substrates with a misalignment amount after bonding being equal to or smaller than a predetermined threshold.

A method of manufacturing a semiconductor device according to example embodiments includes: sequentially forming first through third insulating layers on a substrate; forming an opening by etching the first through third insulating layers; forming a conductive layer configured in the opening; forming a fourth insulating layer in the opening after the forming of the conductive layer; and removing a portion of an edge region of the substrate after the forming of the fourth insulating layer.

A semiconductor device includes a semiconductor layer with opposing first and second main surfaces and a first column extending from the first main surface and having a first concentration of a dopant of the first conductivity type. A trench with a sidewall and bottom extends at least partially through the semiconductor layer from the first main surface. A second column between the trench sidewall and the first column has a second concentration of a dopant of a second conductivity type and is formed in the semiconductor layer and extends from the first main surface. A trench oxide layer is in contact with at least the trench sidewall and the trench bottom. A trench nitride layer covers the trench oxide layer at least on the trench sidewall. A dielectric seal material seals the trench proximate the first main surface of the semiconductor layer such that the trench is air-tight.

A method, apparatus, and system for forming a semiconductor structure. A first oxide layer located on a set of group III nitride layers formed on a silicon carbide substrate is bonded to a second oxide layer located on a carrier substrate to form an oxide layer located between the carrier substrate and the set of group III nitride layers. The silicon carbide substrate has a doped layer. The silicon carbide substrate having the doped layer is etched using a photo-electrochemical etching process, wherein a doping level of the doped layer is such that the doped layer is removed and a silicon carbide layer in the silicon carbide substrate remains unetched. The semiconductor structure is formed using the silicon carbide layer and the set of group III nitride layers.

Examples of an epitaxial-silicon wafer with a buried oxide layer are described herein. Examples of methods to manufacture an epitaxial-silicon wafer with a buried oxide layer are also described herein. In some examples, material may be removed from an epitaxial-silicon wafer at a surface opposite an epitaxial surface layer until the epitaxial-silicon wafer is a specified thickness. The thinned epitaxial-silicon wafer may be bonded to an oxidized-silicon wafer at an oxidized surface forming a buried oxide layer.

Wafers including a diamond layer and a semiconductor layer having III-Nitride compounds and methods for fabricating the wafers are provided. A nucleation layer, at least one semiconductor layer having III-Nitride compound and a protection layer are formed on a silicon substrate. Then, a silicon carrier wafer is glass bonded to the protection layer. Subsequently the silicon substrate, nucleation layer and a portion of the semiconductor layer are removed. Then, an intermediate layer, a seed layer and a diamond layer are sequentially deposited on the III-Nitride layer. Next, a support wafer that includes a GaN layer (or a silicon layer covered by a protection layer) is deposited on the diamond layer. Then, the silicon carrier wafer and the protection layer are removed.

A 3D semiconductor device, the device including: a first single crystal layer including a plurality of first transistors and at least two metal layers; a plurality of logic gates including the at least two metal layers interconnecting the plurality of first transistors; a plurality of second transistors disposed atop the at least two metal layers; a plurality of third transistors disposed atop the second transistors; a top metal layer disposed atop the third transistors; and a memory array including word-lines, where the memory array includes at least two rows by two columns of memory mini arrays, where each of the mini arrays includes at least four rows by four columns of memory cells, where each of the memory cells includes at least one of the second transistors or at least one of the third transistors, and where at least one of the second transistors include a metal gate.

Disclosed herein are techniques for bonding components of LEDs. According to certain embodiments, a device includes a first component having a semiconductor layer stack including an n-side semiconductor layer, an active light emitting layer, and a p-side semiconductor layer. A plurality of mesa shapes are formed within the n-side semiconductor layer, the active light emitting layer, and the p-side semiconductor layer. The semiconductor layer stack comprises a III-V semiconductor material. The device also includes a second component having a passive or an active matrix integrated circuit within a Si layer. A first dielectric material of the first component is bonded to a second dielectric material of the second component, first contacts of the first component are aligned with and bonded to second contacts of the second component, and a run-out between the first contacts and the second contacts is less than 200 nm.

A 3D semiconductor device, the device including: a first level including a first single crystal layer, the first level including first transistors, where the first transistors each include a single crystal channel; first metal layers interconnecting at least the first transistors; and a second level including a second single crystal layer, the second level including second transistors, where the second level overlays the first level, where the second level is bonded to the first level, where the bonded includes oxide to oxide bonds, where the second level includes an array of memory cells, and where each of the memory cells includes at least one recessed-channel-array-transistor (RCAT).

A method for producing a semiconductor-on-insulator type substrate includes epitaxial deposition of a first semiconductor layer on a smoothing layer supported by a monocrystalline support substrate to form a donor substrate; production of an assembly by contacting the donor substrate with a receiver substrate; transfer, onto the receiver substrate, of the first semiconductor layer, the smoothing layer and a portion of the support substrate; and selective etching of the portion of the support substrate relative to the smoothing layer. The epitaxial deposition of the first semiconductor layer can be preceded by a surface preparation annealing of the support substrate at a temperature greater than 650° C. After the selective etching of the portion of the support substrate, selective etching of the smoothing layer relative to the first semiconductor layer and epitaxial deposition of a second semiconductor layer on the first semiconductor layer may be carried out in an epitaxy frame.