Structures with altered crystallinity beneath semiconductor devices and methods associated with forming such structures. Trench isolation regions surround an active device region composed of a single-crystal semiconductor material. A first non-single-crystal layer is arranged beneath the trench isolation regions and the active device region. A second non-single-crystal layer is arranged beneath the trench isolation regions and the active device region. The first non-single-crystal layer is arranged between the second non-single-crystal layer and the active device region.

An apparatus includes: a processing container; a stage provided inside the processing container to place a substrate thereon; a gas supply mechanism for supplying a processing gas into the processing container; and at least three ultraviolet light sources provided to irradiate the processing gas inside the processing container with ultraviolet rays. The ultraviolet light sources are provided to be offset from a rotation axis of the stage in a plan view, and are arranged in a light source arrangement direction with distances from the ultraviolet light sources to the rotation axis being different from one another. The ultraviolet light sources include first to third ultraviolet light source. The third ultraviolet light source is arranged such that distances L1, L2, and L3 from the first to third ultraviolet light sources, respectively, to the rotation axis in a plan view satisfies a relationship of L1<L3<L2.

Apparatus, systems, and methods for processing workpieces are provided. In one example implementation, a hydrogen gas mixed with an inert gas can be reacted with an oxygen gas to oxidize a workpiece at atmospheric pressure. A chemical reaction of a hydrogen gas with an oxygen gas facilitated by a hot workpiece surface can positively affect an oxidation process. A reaction speed of the chemical reaction can be slowed down by mixing the hydrogen gas with an inert gas. Such mixture can effectively reduce a partial pressure of the hydrogen gas. As such, the oxidation process can be carried out at atmospheric pressure, thereby, in an atmospheric thermal processing chamber.

A process for preparing a support comprises the placing of a substrate on a susceptor in a chamber of a deposition system, the susceptor having an exposed surface not covered by the substrate; the flowing of a precursor containing carbon in the chamber at a deposition temperature so as to form at least one layer on an exposed face of the substrate, while at the same time depositing species of carbon and of silicon on the exposed surface of the susceptor. The process also comprises, directly after the removal of the substrate from the chamber, a first etch step consisting of the flowing of an etch gas in the chamber at a first etching temperature not higher than the deposition temperature so as to eliminate at least some of the species of carbon and silicon deposited on the susceptor.

A method for fabricating semiconductor device includes the steps of: forming a gate structure on a substrate; forming a polymer block on a corner between the gate structure and the substrate; performing a cleaning process; performing an oxidation process by injecting oxygen gas under 750° C. to form a first seal layer on sidewalls of the gate structure; and forming a source/drain region adjacent to two sides of the gate structure.

A method for making a semiconductor device includes forming a ROX layer on a substrate and a patterned silicon oxynitride layer on the patterned ROX layer; conformally forming a dielectric oxide layer to cover the substrate, the patterned silicon oxynitride layer, and the patterned ROX layer; and fully oxidizing the patterned silicon oxynitride layer to form a fully oxidized gate oxide layer on the substrate.

A method includes forming a silicon liner over a semiconductor device, which includes a dummy gate structure disposed over a substrate and S/D features disposed adjacent to the dummy gate structure, where the dummy gate structure traverses a channel region between the S/D features. The method further includes forming an ILD layer over the silicon liner, which includes elemental silicon, introducing a dopant species to the ILD layer, and subsequently removing the dummy gate structure to form a gate trench. Thereafter, the method proceeds to performing a thermal treatment to the doped ILD layer, thereby oxidizing the silicon liner, and forming a metal gate stack in the gate trench and over the oxidized silicon liner.

A method includes forming a semiconductor substrate having an oxide layer embedded therein, forming a multi-layer (ML) stack including alternating channel layers and non-channel layers over the semiconductor substrate, forming a dummy gate stack over the ML, forming an S/D recess in the ML to expose the oxide layer, forming an epitaxial S/D feature in the S/D recess, removing the non-channel layers from the ML to form openings between the channel layers, where the openings are formed adjacent to the epitaxial S/D feature, and forming a high-k metal gate stack (HKMG) in the openings between the channel layers and in place of the dummy gate stack.

A multilayer composite structure and a method of preparing a multilayer composite structure are provided. The multilayer composite structure comprises a semiconductor handle substrate having a minimum bulk region resistivity of at least about 500 ohm-cm and an isolation region that impedes the transfer of charge carriers along the surface of the handle substrate and reduces parasitic coupling between RF devices.

The present disclosure provides systems and methods for processing channel structures of substrates that include positioning the substrate in a first processing chamber having a first processing volume being in fluid communication with a plasma source. The substrate can include a channel structure with high aspect ratio features having aspect ratios greater than about 20:1. The method can also include forming an oxide cap layer over a silicon-containing layer of the channel structure and exposing the oxide cap layer to a hydrogen-or-deuterium radical to nucleate the silicon-containing layer of the channel structures of the substrate. Forming the oxide cap layer and exposing the channel structure with the hydrogen radical occurs in the first processing chamber to form a nucleated substrate. The method can also include positioning the nucleated substrate in a second processing chamber with a second processing volume and heating the nucleated substrate in the second processing chamber.