A substrate processing method and a substrate processing device capable of obtaining good embedding characteristics are provided. The substrate processing method includes: embedding a first insulating film in a recess of a substrate by repeating forming an adsorption layer on the substrate by supplying a silicon-containing gas and causing plasma of a reaction gas to react with the adsorption layer by generating the plasma of the reaction gas; and etching the first insulating film by generating plasma of an etching gas, wherein a shape of the first insulating film embedded in the recess after etching is controlled by controlling plasma generation parameters in the causing the plasma to react with the adsorption layer.

A plasma generation apparatus includes a housing fitted in a portion of an upper surface of a process chamber of a deposition apparatus and having a protruding portion having an elongated shape in a plan view and protruding upward from a bottom surface, a coil wound around a side surface of the protruding portion and having an elongated shape in the plan view, and an inclination adjustment mechanism configured to independently move upward and downward both ends in a longitudinal direction of the coil to change an inclination of the coil in the longitudinal direction.

Methods and systems for forming a structure including multiple carbon layers and structures formed using the methods or systems are disclosed. Exemplary methods include forming a first carbon layer with an initial first flowability and a second carbon layer with an initial second flowability, wherein first flowability is less than second flowability.

A film forming method includes: a first measurement process of measuring a substrate on which a pattern including recesses is formed using infrared spectroscopy; a film formation process of forming a film on the substrate after the first measurement process; a second measurement process of measuring the substrate using infrared spectroscopy after the film formation process; and an extraction process of extracting difference data between measurement data obtained in the first measurement process and measurement data obtained in the second measurement process.

Methods of forming treated silicon nitride layers are disclosed. Exemplary methods include forming a silicon nitride layer overlying the substrate by providing a silicon precursor to the reaction chamber for a silicon precursor pulse period, providing a nitrogen reactant to the reaction chamber for a reactant pulse period, during a deposition process applying a first plasma power having a first frequency for a first plasma power period, and during a treatment step, applying a second plasma power having a second frequency for a second plasma power period.

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 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.

A method for forming a metal nitride layer on a substrate includes exposing a substrate having features formed therein to a first deposition gas mixture including metal source material in a processing chamber to deposit metal source material in the features, supplying a first purge gas mixture into the processing chamber to remove excess metal source material and reaction byproducts from the processing chamber, exposing the substrate to a second deposition gas mixture including a nitride source compound in the processing chamber to form no more than one monolayer of metal nitride, supplying a second purge gas mixture into the processing chamber to remove excess nitride source compound and reaction byproducts from the processing chamber, and exposing the substrate to plasma using a microwave plasma source.

The use of selective deposition of silicon nitride can eliminate conventional patterning steps by allowing silicon nitride to be deposited only in selected and desired areas. Using a silicon iodide precursor alternately with a thermal nitrogen source in an ALD or pulsed CVD mode, silicon nitride can be deposited preferentially on a surface such as silicon nitride, silicon dioxide, germanium oxide, SiCO, SiOF, silicon carbide, silicon oxynitride, and low k substrates, while exhibiting very little deposition on exposed surfaces such as titanium nitride, tantalum nitride, aluminum nitride, hafnium oxide, zirconium oxide, aluminum oxide, titanium oxide, tantalum oxide, niobium oxide, lanthanum oxide, yttrium oxide, magnesium oxide, calcium oxide, and strontium oxide.

An oxide or nitride film containing carbon and at least one of silicon and metal is formed by ALD conducting one or more process cycles, each process cycle including: feeding a first precursor in a pulse to adsorb the first precursor on a substrate; feeding a second precursor in a pulse to adsorb the second precursor on the substrate; and forming a monolayer constituting an oxide or nitride film containing carbon and at least one of silicon and metal on the substrate by undergoing ligand substitution reaction between first and second functional groups included in the first and second precursors adsorbed on the substrate. The ligand may be a halogen group, —NR.sub.2, or —OR.