A method of manufacturing a semiconductor device includes: loading a substrate into a process container after dry-etching a portion of a silicon film formed in a recess on the substrate; performing etching to partially or entirely remove the silicon film remaining on a side wall inside the recess by supplying an etching gas selected from a hydrogen bromide gas and a hydrogen iodide gas into the process container of a vacuum atmosphere while heating the substrate; subsequently forming a silicon film inside the recess; and heating the substrate to increase a grain size of the silicon film.

A semiconductor wafer can include a substrate, a poly template layer, and a semiconductor layer. The substrate has a central region and an edge region, the poly template layer is disposed along a peripheral edge of the substrate, and a semiconductor layer over the central region, wherein the semiconductor layer is monocrystalline. In an embodiment, the poly template layer and the monocrystalline layer are laterally spaced apart from each other by an intermediate region. In another embodiment, the semiconductor layer can include aluminum. A process of forming the substrate can include forming a patterned poly template layer within the edge region and forming a semiconductor layer over the primary surface. Another process of forming the substrate can include forming a semiconductor layer over the primary surface and removing a portion of the semiconductor layer so that the semiconductor layer is spaced apart from an edge of the substrate.

A buffer layer is employed to fabricate diamond membranes and allow reuse of diamond substrates. In this approach, diamond membranes are fabricated on the buffer layer, which in turn is disposed on a diamond substrate that is lattice-matched to the diamond membrane. The weak bonding between the buffer layer and the diamond substrate allows ready release of the fabricated diamond membrane. The released diamond membrane is transferred to another substrate to fabricate diamond devices, while the diamond substrate is reused for another fabrication.

Provided is a thin film transistor including a highly-textured dielectric layer, an active layer, a gate electrode and a source/drain electrode that are stacked on a base substrate. The source/drain electrode includes a source electrode and a drain electrode. The gate electrode and the active layer are insulated from each other. The source electrode and the drain electrode are electrically connected to the active layer. Constituent particles of the active layer are of monocrystalline silicon-like structures. According to the present disclosure, the highly-textured dielectric layer is adopted to replace an original buffer layer to induce the active layer to grow into a monocrystalline silicon-like structure, such that the performance of the thin film transistor is improved.

A method for forming nanowire semiconductor devices includes a) providing a substrate including an oxide layer defining vias; and b) depositing nanowires in the vias. The nanowires are made of a material selected from a group consisting of germanium or silicon germanium. The method further includes c) selectively etching back the oxide layer relative to the nanowires to expose upper portions of the nanowires; and d) doping the exposed upper portions of the nanowires using a dopant species.

A method for forming a semiconductor device includes forming first fins from a first semiconductor material and second fins from a second semiconductor material and encapsulating the first fins and the second fins with a protective dielectric. Semiconductor material between the first fins and the second fins is etched to form trenches. A dielectric fill is employed to fill up the trenches, between the first fins and between the second fins. The first semiconductor material below the first fins and the second semiconductor material below the second fins are oxidized with the first and second fins being protected by the protective dielectric. Fins in an intermediary region between the first fins and the second fins are oxidized to form dummy fins in the intermediary region to maintain a substantially same topology across the device.

On an RAMO.sub.4 substrate containing a single crystal represented by the general formula RAMO.sub.4 (wherein R represents one or a plurality of trivalent elements selected from a group of elements including: Sc, In, Y, and a lanthanoid element, A represents one or a plurality of trivalent elements selected from a group of elements including: Fe(III), Ga, and Al, and M represents one or a plurality of divalent elements selected from a group of elements including: Mg, Mn, Fe(II), Co, Cu, Zn, and Cd), a buffer layer containing a nitride of In and a Group III element except for In is formed, and a Group III nitride crystal is formed on the buffer layer.

A shower head according to an embodiment includes: a mixing chamber to which process gas is supplied; a plurality of cooling portions provided below the mixing chamber with a gap therebetween, the cooling portion having a cooling hole provided in a horizontal direction, the process gas being introduced from the mixing chamber to the gaps; a plurality of buffer regions provided below the gaps, the process gas being introduced from the gaps to the buffer regions; and a shower plate provided below the buffer regions, the shower plate having a plurality of through holes disposed at a predetermined interval, the process gas being introduced from the buffer regions to the through holes.

A method of forming a strained channel for a field effect transistor, including forming a sacrificial layer on a substrate, forming a channel layer on the sacrificial layer, forming a stressor layer on the channel layer, wherein the stressor layer applies a stress to the channel layer, forming at least one etching trench by removing at least a portion of the stressor layer, channel layer, and sacrificial layer, wherein the etching trench exposes at least a portion of a sidewall of the sacrificial layer, and separates the stressor layer, channel layer, and sacrificial layer into two or more stressor islands, channel blocks, and sacrificial slabs, and removing the sacrificial slabs to release the channel blocks from the substrate using a selective etch, wherein the channel blocks adhere to the substrate surface.

A method for preparing semiconductor nanocrystals is disclosed. The method includes adding one or more cation precursors and one or more anion precursors in a reaction mixture including a solvent in a reaction vessel, maintaining the reaction mixture at a first temperature and for a first time period sufficient to produce semiconductor nanocrystal seed particles of the cation and the anion, and maintaining the reaction mixture at a second temperature that is higher than the first temperature for a second time period sufficient to enlarge the semiconductor nanocrystal seed particles to produce semiconductor nanocrystals from the cation and the anion.