Abstract: A substrate processing method includes step a), step b), step c), step d), step e), and step f). Step a) is a step of providing a substrate that has a pattern where a protection target film is positioned on a bottom part of the pattern. Step b) is a step of laminating a catalyst film on the protection target film. Step c) is a step of forming a protection film that supports the catalyst film from below and covers the protection target film, in the pattern, by a VLS growth method. Step d) is a step of removing the catalyst film. Step e) is a step of applying a predetermined process to a part of the substrate that is different from the pattern in a state where the protection target film is covered by the protection film. Step f) is a step of removing the protection film in the pattern.

Abstract: Methods for forming a boron nitride film by a plasma enhanced atomic layer deposition (PEALD) process are provided. The methods may include: providing a substrate into a reaction chamber; and performing at least one unit deposition cycle of a PEALD process, wherein a unit cycle comprises, contacting the substrate with a vapor phase reactant comprising a boron precursor, wherein the boron precursor comprises less than or equal to two halide atoms per boron atom; and contacting the substrate with a reactive species generated from a gas comprising a nitrogen precursor.

Abstract: 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 sub saturating 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.

Abstract: A method for fabricating a layer structure in a trench includes: simultaneously forming a dielectric film containing a Si—N bond on an upper surface, and a bottom surface and sidewalls of the trench, wherein a top/bottom portion of the film formed on the upper surface and the bottom surface and a sidewall portion of the film formed on the sidewalls are given different chemical resistance properties by bombardment of a plasma excited by applying voltage between two electrodes between which the substrate is place in parallel to the two electrodes; and substantially removing the sidewall portion of the film by wet etching which removes the sidewall portion of the film more predominantly than the top/bottom portion according to the different chemical resistance properties.

Abstract: Methods for forming a topographically selective silicon oxide film by a cyclical plasma-enhanced deposition process are provided. The methods may include: forming a topographically selective silicon oxide film by a plasma enhanced atomic layer deposition (PEALD) process or a cyclical plasma-enhanced chemical vapor deposition (cyclical PECVD) process. The methods may also include: forming a silicon oxide film either selectivity over the horizontal surfaces of a non-planar substrate or selectively over the vertical surfaces of a non-planar substrate.

Abstract: A film having filling capability is deposited by forming a viscous polymer in a gas phase by striking an Ar, He, or N2 plasma in a chamber filled with a volatile hydrocarbon precursor that can be polymerized within certain parameter ranges which define mainly partial pressure of precursor during a plasma strike, and wafer temperature.

Abstract: A method for forming a silicon oxide film on a step formed on a substrate includes: (a) designing a topology of a final silicon oxide film by preselecting a target portion of an initial silicon nitride film to be selectively deposited or removed or reformed with reference to a non-target portion of the initial silicon nitride film resulting in the final silicon oxide film; and (b) forming the initial silicon nitride film and the final silicon oxide film on the surfaces of the step according to the topology designed in process (a), wherein the initial silicon nitride film is deposited by ALD using a silicon-containing precursor containing halogen, and the initial silicon nitride film is converted to the final silicon oxide film by oxidizing the initial silicon nitride film without further depositing a film wherein a Si—N bond in the initial silicon nitride film is converted to a Si—O bond.

Abstract: Methods and systems for filling a recess on a surface of a substrate with carbon-containing material are disclosed. Exemplary methods include forming a first carbon layer within the recess, etching a portion of the first carbon layer within the recess, and forming a second carbon layer within the recess. Structures formed using the method or system are also disclosed.

Abstract: 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.

Abstract: Methods for forming a topographically selective silicon oxide film by a cyclical plasma-enhanced deposition process are provided. The methods may include: forming a topographically selective silicon oxide film by a plasma enhanced atomic layer deposition (PEALD) process or a cyclical plasma-enhanced chemical vapor deposition (cyclical PECVD) process. The methods may also include: forming a silicon oxide film either selectivity over the horizontal surfaces of a non-planar substrate or selectively over the vertical surfaces of a non-planar substrate.

Abstract: Methods and precursors for depositing silicon nitride films by atomic layer deposition (ALD) are provided. In some embodiments the silicon precursors comprise an iodine ligand. The silicon nitride films may have a relatively uniform etch rate for both vertical and the horizontal portions when deposited onto three-dimensional structures such as FinFETS or other types of multiple gate FETs. In some embodiments, various silicon nitride films of the present disclosure have an etch rate of less than half the thermal oxide removal rate with diluted HF (0.5%).

Abstract: The present disclosure relates to the deposition of dopant films, such as doped silicon oxide films, by atomic layer deposition processes. In some embodiments, a substrate in a reaction space is contacted with pulses of a silicon precursor and a dopant precursor, such that the silicon precursor and dopant precursor adsorb on the substrate surface. Oxygen plasma is used to convert the adsorbed silicon precursor and dopant precursor to doped silicon oxide.

Abstract: 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, —NR2, or —OR.

Abstract: The present disclosure relates to the deposition of dopant films, such as doped silicon oxide films, by atomic layer deposition processes. In some embodiments, a substrate in a reaction space is contacted with pulses of a silicon precursor and a dopant precursor, such that the silicon precursor and dopant precursor adsorb on the substrate surface. Oxygen plasma is used to convert the adsorbed silicon precursor and dopant precursor to doped silicon oxide.

Abstract: 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.

Abstract: A method for forming a dielectric film containing a Si—O bond a trench formed in an upper surface of a substrate, includes: designing a topology of a final dielectric film containing a Si—O bond formed in the trench by preselecting a target portion to be selectively removed relative to a non-target portion of an initial dielectric film resulting in the final dielectric film; conformally depositing the initial dielectric film on the upper surface and in the trench; and relatively increasing an amount of impurities contained in the target portion of the initial dielectric film relative to an amount of impurities contained in the non-target portion of the initial dielectric film to obtain a treated dielectric film, thereby giving the target portion and the non-target portion different chemical resistance properties when subjected to etching.

Abstract: Methods and precursors for depositing silicon nitride films by atomic layer deposition (ALD) are provided. In some embodiments the silicon precursors comprise an iodine ligand. The silicon nitride films may have a relatively uniform etch rate for both vertical and the horizontal portions when deposited onto three-dimensional structures such as FinFETS or other types of multiple gate FETs. In some embodiments, various silicon nitride films of the present disclosure have an etch rate of less than half the thermal oxide removal rate with diluted HF (0.5%).

Abstract: Examples of a method for manufacturing a semiconductor device include forming an initial film having a film thickness of 1 to 3 nm made of a metal or a metal nitride by applying plasma film formation with plasma power of 0.07 to 0.30 W/cm2 and an RF pulse width within a range of 0.1 to 1 sec, and forming, after forming the initial film, a bulk film made of a metal or metal nitride on the initial film by applying plasma film formation with plasma power higher than the plasma power when the initial film is formed.

Abstract: Methods and systems for filling a recess on a surface of a substrate with carbon-containing material are disclosed. Exemplary methods include forming a first carbon layer within the recess, etching a portion of the first carbon layer within the recess, and forming a second carbon layer within the recess. Structures formed using the method or system are also disclosed.

Abstract: A method for forming a silicon oxide film on a step formed on a substrate includes: (a) designing a topology of a final silicon oxide film by preselecting a target portion of an initial silicon nitride film to be selectively deposited or removed or reformed with reference to a non-target portion of the initial silicon nitride film resulting in the final silicon oxide film; and (b) forming the initial silicon nitride film and the final silicon oxide film on the surfaces of the step according to the topology designed in process (a), wherein the initial silicon nitride film is deposited by ALD using a silicon-containing precursor containing halogen, and the initial silicon nitride film is converted to the final silicon oxide film by oxidizing the initial silicon nitride film without further depositing a film wherein a Si—N bond in the initial silicon nitride film is converted to a Si—O bond.