Provided is a composition containing a silylamine compound and a method for manufacturing a silicon-containing thin film using the same, and more particularly, a composition for depositing a silicon-containing thin film, containing a silylamine compound capable of forming a silicon-containing thin film having a significantly excellent water vapor transmission rate to thereby be usefully used as a precursor of the silicon-containing thin film and an encapsulant of a display, and a method for manufacturing a silicon-containing thin film using the same.

A semiconductor device includes a fin structure that protrudes vertically out of a substrate, wherein the fin structure contains silicon germanium (SiGe). An epi-silicon layer is disposed on a sidewall of the fin structure. The epi-silicon layer contains nitrogen. One or more dielectric liner layers are disposed on the epi-silicon layer. A dielectric isolation structure is disposed over the one or more dielectric liner layers.

A method includes: forming a barrier layer in a substrate; depositing a first dielectric layer over the substrate; forming a patterned mask layer over the first dielectric layer; patterning the first dielectric layer into a first sublayer of a gate dielectric layer; converting at least part of the patterned mask layer into a second sublayer of the gate dielectric layer; depositing a second dielectric layer adjacent to the first and second sublayers to serve as a third sublayer of the gate dielectric layer; and depositing a gate electrode over the gate dielectric layer.

A selective plasma enhanced atomic layer deposition (ALD) process is disclosed. The process may comprise loading a substrate comprising a dielectric material, and a metal, into a reactor. The substrate may be reacted with a non-plasma based oxidant, thereby forming an oxidized metal surface on the metal. The substrate may be heated and exposed to a passivation agent that adsorbs more onto the oxidized metal than the dielectric material. Such exposure may form a passivation layer on the oxidized metal surface, and the substrate may be exposed to a silicon precursor that adsorbs more onto the dielectric material that the passivation layer, forming a chemi-adsorbed silicon-containing layer on the dielectric material. The substrate may be exposed to a plasma based oxidant, that simultaneously partially oxidizes the passivation layer, and oxidizes the chemi-adsorbed silicon-containing layer to form a dielectric film on the dielectric material.

Methods of depositing silicon-containing films by plasma-enhanced vapor deposition, e.g., plasma-enhanced chemical vapor deposition (PECVD) or plasma-enhanced atomic layer deposition (PEALD), are disclosed. Exemplary methods include exposing a substrate in a processing system to a silicon-containing precursor; exposing the substrate to an oxygen-containing reagent; and exposing the substrate to a plasma of an inert gas.

Exemplary processing methods may include providing one or more deposition precursors to a processing region of a semiconductor processing chamber. A substrate may be disposed within the processing region. A layer of a first silicon-containing material defining one or more features may be disposed on the substrate. The methods may include contacting the substrate with the one or more deposition precursors. The contacting may deposit a liner material on the first silicon-containing material. The methods may include performing an atomic layer deposition (ALD) process. The ALD process may deposit a silicon-and-oxygen-containing material in the one or more features.

According to one or more embodiments, a method includes positioning a substrate within a processing chamber. The substrate includes a hardmask layer disposed over a surface of the substrate, a first layer disposed over the hardmask layer, and a second layer disposed over the first layer. The method further includes flowing a process gas into the processing chamber, and delivering a microwave energy for a period of time to the process gas to selectively etch the hardmask layer and the first layer, wherein delivering the microwave energy to the process gas does not generate a plasma.

Methods of providing control of film properties during atomic layer deposition using intermittent plasma treatment in-situ are provided herein. Methods include modulating gas flow rate ratios used to generate plasma during intermittent plasma treatment, toggling plasma power, and modulating chamber pressure.

A semiconductor device includes a semiconductor layer of a first conductivity type. A well region that is a second conductivity type well region is formed on a surface layer portion of the semiconductor layer and has a channel region defined therein. A source region that is a first conductivity type source region is formed on a surface layer portion of the well region. A gate insulating film is formed on the semiconductor layer and has a multilayer structure. A gate electrode is opposed to the channel region of the well region where a channel is formed through the gate insulating film.

A method for depositing an oxide film on a substrate by a cyclical deposition is disclosed. The method may include: depositing a metal oxide film over the substrate utilizing at least one deposition cycle of a first sub-cycle of the cyclical deposition process; and depositing a silicon oxide film directly on the metal oxide film utilizing at least one deposition cycle of a second sub-cycle of the cyclical deposition process. Semiconductor device structures including an oxide film deposited by the methods of the disclosure are also disclosed.