Provided are a substrate processing method and a substrate processing apparatus, wherein a silicon oxide film is favorably embedded. The substrate processing method includes forming a silicon oxide film by repeating a cycle a plurality of times, the cycle including: forming an adsorption layer by supplying a silicon-containing gas to a substrate having a depression formed therein and causing the silicon-containing gas to be adsorbed on the substrate; etching at least a portion of the adsorption layer by supplying a shape control gas to the substrate; and supplying an oxygen-containing gas to the substrate and causing the oxygen-containing gas to react with the adsorption layer, wherein the temperature of the substrate is 400° C. or lower.

A film formation method for selectively forming a film on a substrate includes: a preparation step of preparing a substrate having a surface on which a first film and a second film are exposed; a first film forming step of supplying a compound for forming a self-assembled monolayer onto the substrate to form the self-assembled monolayer on the first film, the compound having a functional group including fluorine and carbon and suppressing formation of a third film; a second film forming step of forming the third film on the second film; and a first removal step of removing the third film formed in a vicinity of the self-assembled monolayer by irradiating the surface of the substrate with ions or active species, wherein the third film is a film which forms a volatile compound more easily than the first film by being bonded to fluorine and carbon in the self-assembled monolayer.

There is provided a technique that includes: (a) forming a film formation suppression layer on a surface of a first material of a concave portion of the substrate, by supplying a precursor to the substrate provided with the concave portion on a surface of the substrate to adsorb at least a portion of a molecular structure of molecules constituting the precursor on the surface of the first material of the concave portion, the concave portion having a top surface and a side surface composed of the first material containing a first element and a bottom surface composed of a second material containing a second element; and (b) growing a film on a surface of the second material of the concave portion by supplying a film-forming material to the substrate having the film formation suppression layer formed on the surface of the first material.

There is provided a technique that includes: (a) forming a film formation suppression layer on a surface of a first material of a concave portion of the substrate, by supplying a precursor to the substrate provided with the concave portion on a surface of the substrate to adsorb at least a portion of a molecular structure of molecules constituting the precursor on the surface of the first material of the concave portion, the concave portion having a top surface and a side surface composed of the first material containing a first element and a bottom surface composed of a second material containing a second element; and (b) growing a film on a surface of the second material of the concave portion by supplying a film-forming material to the substrate having the film formation suppression layer formed on the surface of the first material.

Methods of forming metal-containing films are provided. The methods include forming a blocking layer, for example, on a first substrate surface, by a first deposition process and forming the metal-containing film, for example, on a second substrate surface, by a second deposition process.

Methods of depositing silicon nitride on a surface of a substrate are disclosed. The methods include using an intermediate treatment process to increase a quality of the silicon nitride layer and a second treatment process.

A method of forming a device structure including a selectively-deposited gallium nitride layer is disclosed.

A method of fabricating air gaps in advanced semiconductor devices for low capacitance interconnects. The method includes exposing a substrate to a gas pulse sequence to deposit a material that forms an air gap between raised features.

Methods for selective deposition of silicon oxide films on metal or metallic surfaces relative to dielectric surfaces are provided. A dielectric surface of a substrate may be selectively passivated relative to a metal or metallic surface, such as by exposing the substrate to a silylating agent. Silicon oxide is then selectively deposited on the metal or metallic surface relative to the passivated oxide surface by contacting the metal surface with a metal catalyst and a silicon precursor comprising a silanol.

Vapor deposition methods for depositing transition metal dichalcogenide (TMDC) films, such as rhenium sulfide thin films, are provided. In some embodiments TMDC thin films are deposited using a deposition cycle in which a substrate in a reaction space is alternately and sequentially contacted with a vapor phase transition metal precursor, such as a transition metal halide, a reactant comprising a reducing agent, such as NH.sub.3 and a chalcogenide precursor. In some embodiments rhenium sulfide thin films are deposited using a vapor phase rhenium halide precursor, a reducing agent and a sulfur precursor. The deposited TMDC films can be etched by chemical vapor etching using an oxidant such as O.sub.2 as the etching reactant and an inert gas such as N.sub.2 to remove excess etching reactant. The TMDC thin films may find use, for example, as 2D materials.