There is provided a technique that includes (a) supplying a fluorine-containing gas to a substrate including a first surface and a second surface; (b) supplying an oxygen- and hydrogen-containing gas and a catalyst to the substrate after performing (a); (c) supplying a modifying agent to the substrate after performing (b); and (d) supplying a film-forming agent to the substrate after performing (c).

Methods and systems for selectively depositing dielectric films on a first surface of a substrate relative to a passivation layer previously deposited on a second surface are provided. The methods can include at least one cyclical deposition process used to deposit material on the first surface while the passivation layer is removed, thereby preventing deposition over the passivation layer.

A method of forming a titanium nitride film includes: forming the titanium nitride film by alternately repeating supplying a raw material gas, which contains a titanium compound including chlorine and titanium, to a substrate accommodated in a processing container, and supplying a reaction gas, which contains a nitrogen compound including nitrogen and reacts with the titanium compound to form titanium nitride, to the substrate, wherein the forming the titanium nitride film is executed under a condition in which a pressure in the processing container is set within a range of 2.7 kPa to 12.6 kPa so that a specific resistance of the titanium nitride film becomes 57 micro-ohm-cm or less.

An apparatus for forming a thin film by repeating, plural times, a cycle including supplying and adsorbing a precursor gas onto a substrate and generating a reaction product by allowing the precursor gas on the substrate to react with a reaction gas, which includes: a main precursor gas supply part for supplying the precursor gas; a reaction gas supply part for supplying the reaction gas; an adjustment-purpose precursor gas supply part for supplying an adjustment-purpose precursor gas to adjust an in-plane film thickness distribution of the thin film; and a controller for outputting a control signal to execute a step of forming the thin film using the main precursor gas supply part and the reaction gas supply part, and subsequently a step of supplying the adjustment-purpose precursor gas from the adjustment-purpose precursor gas supply part to compensate for a film thickness of a portion having a relatively thin film thickness.

An electrochemical electrode according to the present invention may prevent agglomeration and desorption of a catalyst even when a catalyst in a particle form is used, because a protective layer containing hydrogel is used, such that stability may be secured, thereby implementing an electrode having a long duration.

A NAND structure and method of fabricating the structure are described. A multi-layer ONON stack is deposited on a Si substrate and a field oxide grown thereon. A portion of the field oxide is removed, and high-aspect-ratio channels are etched in the stack. The channels are filled with a Si oxide using a thermal ALD process. The thermal ALD process includes multiple growth cycles followed by a passivation cycle. Each growth cycle includes treating the surface oxide surface using an inhibitor followed by multiple cycles to deposit the oxide on the treated surface using a precursor and source of the oxide. The passivation after the growth cycle removes the residual inhibitor. The Si oxide is recess etched using a wet chemical etch of DHF and then capped using a poly-Si cap.

A film-forming method of embedding ruthenium in a substrate having a recess includes: (a) providing the substrate in a processing container; (b) supplying a gas containing a ruthenium raw material gas into the processing container to form a ruthenium layer; (c) annealing the ruthenium layer; and (d) supplying a gas containing an ozone gas into the processing container to etch the ruthenium layer, wherein (b), (c), and (d) are repeatedly executed in this order.

According to the invention there is provided a method of filling one or more gaps created during manufacturing of a feature on a substrate by providing a deposition method comprising; introducing a first reactant to the substrate with a first dose, thereby forming no more than about one monolayer by the first reactant; introducing a second reactant to the substrate with a second dose. The first reactant is introduced with a subsaturating first dose reaching only a top area of the surface of the one or more gaps and the second reactant is introduced with a saturating second dose reaching a bottom area of the surface of the one or more gaps. A third reactant may be provided to the substrate in the reaction chamber with a third dose, the third reactant reacting with at least one of the first and second reactant.

In some embodiments, methods are provided for simultaneously and selectively depositing a first material on a first surface of a substrate and a second, different material on a second, different surface of the same substrate using the same reaction chemistries. For example, a first material may be selectively deposited on a metal surface while a second material is simultaneously and selectively deposited on an adjacent dielectric surface. The first material and the second material have different material properties, such as different etch rates.

There is provided a film forming method of forming a film in a recess formed on a surface of a substrate. The film forming method includes: forming an adsorption-inhibiting region by supplying an adsorption-inhibiting gas to the substrate; adsorbing a silicon-containing gas to a region other than the adsorption-inhibiting region by supplying the silicon-containing gas to the substrate; and forming a silicon nitride film by exposing the substrate to a nitrogen-containing gas so that the nitrogen-containing gas reacts with the adsorbed silicon-containing gas, wherein the adsorbing the silicon-containing gas includes controlling a dose amount of the silicon-containing gas to be supplied to be equal to or greater than an adsorption saturation amount of the silicon-containing gas to be adsorbed on the substrate on which no adsorption-inhibiting region is formed.