Various embodiments provide a reaction chamber including a support, a receptacle, and a sponge. The support includes a plurality of bars that are spaced from each other by a plurality of openings. Each of the bars has side surfaces that are slanted or tilted downward such that melted material may readily flow through the openings. The support is covered with a coating of silicon carbide to prevent materials from adhering to the support. The receptacle underlies the support and is configured to collect any melted material that is drained through the openings of the support. The sponge is positioned in the receptacle and under the support. The sponge is configured to absorb any melted material that is collected by the receptacle.

Implementations described herein generally relate to methods and systems for depositing layer on substrates, and more specifically, to methods for forming boron or gallium-doped germanium on silicon-containing surfaces. In one implementation, a method of processing a substrate is provided. The method comprises exposing a substrate having an exposed silicon-germanium surface and an exposed dielectric surface to a pre-treatment process, selectively depositing a boron-doped or a gallium-doped layer on the exposed silicon-germanium surface and exposing the substrate to a post-treatment process.

An apparatus and method for creating nanometric delta doped layers in epitaxial diamond includes providing a dummy gas load with gas impedance equivalent to the reactor, and switching gas supplied between the reactor and the gas dummy load without stopping either flow, thereby enabling rapid flow and rapid gas switching without turbulence. An atomically smooth, undamaged substrate can be prepared, preferably in the (100) plane, by etching the surface after polishing to remove subsurface damage. A gas phase chemical getter reactant such as hydrogen disulfide can be used to suppress incorporation of residual boron into the intrinsic layers. Embodiments can produce interfaces between doped and mobile layers that provide at least 100 cm.sup.2/Vsec carrier mobility and 10.sup.13 cm.sup.2 sheet carrier concentration.

An apparatus and method for creating nanometric delta doped layers in epitaxial diamond includes providing a dummy gas load with gas impedance equivalent to the reactor, and switching gas supplied between the reactor and the gas dummy load without stopping either flow, thereby enabling rapid flow and rapid gas switching without turbulence. An atomically smooth, undamaged substrate can be prepared, preferably in the (100) plane, by etching the surface after polishing to remove subsurface damage. A gas phase chemical getter reactant such as hydrogen disulfide can be used to suppress incorporation of residual boron into the intrinsic layers. Embodiments can produce interfaces between doped and mobile layers that provide at least 100 cm.sup.2/Vsec carrier mobility and 10.sup.13 cm.sup.2 sheet carrier concentration.

A p-channel tri-gate transistor has a silicon fin that protrudes from a bulk silicon substrate, a thin silicon-germanium active layer is formed on three sidewalls of the silicon fin, and a hole well is formed between the gate insulating film and the silicon fin in the active layer surrounded by the tri-gate by a valence band offset electric potential against the silicon fin for moving holes collected in the hole well along the active layer with a high hole-mobility. Thus, it is possible to have the effects of not only an ultra-high speed, low power operation, but also a body biasing through an integral structure of the silicon fin-body. The p-channel tri-gate transistor can be fabricated together with an n-channel FinFET transistor in one substrate by the same CMOS process.

A highly reliable transistor which includes an oxide semiconductor and has high field-effect mobility and in which a variation in threshold voltage is small is provided. By using the transistor, a high-performance semiconductor device, which has been difficult to realize, is provided. The transistor includes an oxide semiconductor film which contains two or more kinds, preferably three or more kinds of elements selected from indium, tin, zinc, and aluminum. The oxide semiconductor film is formed in a state where a substrate is heated. Further, oxygen is supplied to the oxide semiconductor film with an adjacent insulating film and/or by ion implantation in a manufacturing process of the transistor, so that oxygen deficiency which generates a carrier is reduced as much as possible. In addition, the oxide semiconductor film is highly purified in the manufacturing process of the transistor, so that the concentration of hydrogen is made extremely low.

Low temperature epitaxial silicon deposition for forming the top source or drain regions of VTFET structures. The methods generally include epitaxially growing a silicon layer with a dopant at a temperature less 500 C. on a first surface and an additional surface to form a single crystalline silicon on the first surface and a polysilicon or amorphous silicon on the additional surface. The epitaxially grown silicon layer is then exposed to an etchant include HCl and germane at a temperature less than 500 C. for a period of time effective to selectively remove the polysilicon/amorphous silicon on the additional surface and form a germanium diffused region on and in an outer surface of the single crystalline silicon formed on the first surface.

The invention pertains to formation of a semiconducting portion (60) by epitaxial growth on a strained germination portion (40), comprising the steps in which a cavity (21) is produced under a structured part (11) by rendering free a support layer (30) situated facing the structured part (11), a central portion (40), termed the strained germination portion, then being strained; and a semiconducting portion (60) is formed by epitaxial growth on the strained germination portion (40), wherein the structured part (11) is furthermore placed in contact with the support layer (30) in such a way as to bind the structured part (11) of the support layer.

A method of manufacturing a substrate for epitaxy is disclosed, including the following steps. Dispose a buffer layer on a base, wherein the buffer layer is constituted by stacked nitride layers formed by the process of atomic layer deposition. The buffer layer could alternatively be constituted by stacked at least one first buffer sub-layer and at least one second buffer sub-layer, wherein the first and second buffer sub-layers are respectively constituted by layered first nitride layers and layered second nitride layers, which are both formed by the process of atomic layer deposition. While forming the buffer layer, perform ion bombardment each time a single layer of the nitride layer, the first nitride layer, or the second nitride layer is formed. Whereby, the base and the buffer layer constitute the substrate for epitaxy, which effectively enhances the crystallinity of the buffer layer.

A method for manufacturing a submicron semiconductor structure on a substrate, including: forming at least one template layer over a support substrate; forming one or more template structures, including one or more recesses and/or mesas, in the template layer, the one or more template structures including one or more edges extending into or out of the top surface of the template layer; coating at least part of the one or more template structures with a liquid semiconductor precursor; and, annealing and/or exposing the liquid semiconductor precursor coated template structures to light, wherein during the annealing and/or light exposure a part of the liquid semiconductor precursor accumulates by capillary forces against at least part of the one or more edges, the annealing and/or light exposure transforming the accumulated liquid semiconductor precursor into a submicron semiconductor structure extending along at least part of the one or more edges.