A semiconductor device includes a SiC semiconductor layer that has a carbon density of 1.0×10.sup.22 cm.sup.−3 or more, a SiO.sub.2 layer that is formed on the SiC semiconductor layer and that has a connection surface contiguous to the SiC semiconductor layer and a non-connection surface positioned on a side opposite to the connection surface, a carbon-density-decreasing region that is formed at a surface layer portion of the connection surface of the SiO.sub.2 layer and in which a carbon density gradually decreases toward the non-connection surface of the SiO.sub.2 layer, and a low carbon density region that is formed at a surface layer portion of the non-connection surface of the SiO.sub.2 layer and that has a carbon density of 1.0×10.sup.19 cm.sup.−3 or less.

A method of forming a metal oxide semiconductor field effect transistor with improved gate-induced drain leakage performance, the method including providing a semiconductor substrate having a gate trench formed therein, performing an ion implantation process on upper portions of sidewalls of the gate trench to make the upper portions more susceptible to oxidation relative to non-implanted lower portions of the sidewalls, and performing an oxidation process on surfaces of the substrate, wherein the implanted upper portions of the sidewalls develop a thicker layer of oxidation relative to the non-implanted lower portions of the sidewalls.

A semiconductor device includes a gate structure on a substrate, a first spacer on sidewalls of gate structure, a second spacer on sidewalls of the first spacer, a polymer block adjacent to the first spacer and on a corner between the gate structure and the substrate, an interfacial layer under the polymer block, and a source/drain region adjacent to two sides of the first spacer. Preferably, the polymer block is surrounded by the first spacer, the interfacial layer, and the second spacer.

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.

Processes for oxidation of a workpiece are provided. In one example, a method includes placing a workpiece on a workpiece support in a processing chamber. The method includes performing a pre-oxidation treatment process on the workpiece in the processing chamber to initiate oxide layer formation on the workpiece. The method includes performing a remote plasma oxidation process on the workpiece in the processing chamber to continue the oxide layer formation on the workpiece. Subsequent to performing the pre-oxidation treatment process and the remote plasma oxidation process, the method can include removing the workpiece from the processing chamber. In some embodiments, the remote plasma oxidation process can include generating a first plasma from a remote plasma oxidation process gas in a plasma chamber; filtering species generated in the plasma to generate a mixture having one or more radicals; and exposing the one or more radicals to the workpiece.

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 film forming apparatus comprising: a processing container for accommodating a plurality of substrates, a substrate holder provided in the processing container and configured to hold the substrates such that the plurality of substrates are arranged along a circumferential direction; a rotating and revolving mechanism configured to rotate the plurality of substrates on the substrate holder and revolve the plurality of substrates on the substrate holder along the circumferential direction; and a sputtered particle emitting mechanism configured to emit sputtered particles to the plurality of substrates held by the substrate holder. Sputtering film formation is performed by emitting the sputtered particles from the sputtered particle emitting mechanism while rotating and revolving the plurality of substrates held by the substrate holder using the rotating and revolving mechanism.

A method of processing a substrate, includes: (a) modifying a surface of the substrate into a first oxide layer by supplying, to the substrate, a reactive species generated by plasma-exciting a first processing gas in which oxygen and hydrogen are contained and a ratio of hydrogen in the oxygen and hydrogen of the first processing gas is a first ratio; and (b) modifying the first oxide layer into a second oxide layer by supplying, to the substrate, a reactive species generated by plasma-exciting a second processing gas in which oxygen is contained and hydrogen is optionally contained and a ratio of hydrogen in the oxygen and hydrogen of the second processing gas is a second ratio smaller than the first ratio.

Fin trim plug structures for imparting channel stress are described. In an example, an integrated circuit structure includes a fin including silicon, the fin having a top and sidewalls. The fin has a trench separating a first fin portion and a second fin portion. A first gate structure including a gate electrode is over the top of and laterally adjacent to the sidewalls of the first fin portion. A second gate structure including a gate electrode is over the top of and laterally adjacent to the sidewalls of the second fin portion. An isolation structure is in the trench of the fin, the isolation structure between the first gate structure and the second gate structure. The isolation structure includes a first dielectric material laterally surrounding a recessed second dielectric material distinct from the first dielectric material, the recessed second dielectric material laterally surrounding an oxidation catalyst layer.