Exemplary methods of semiconductor processing may include providing a silicon-containing precursor and a carbon-containing precursor to a processing region of a semiconductor processing chamber. The carbon-containing precursor may be characterized by a carbon-carbon double bond or a carbon-carbon triple bond. A substrate may be disposed within the processing region of the semiconductor processing chamber. The methods may include providing a boron-containing precursor to the processing region of the semiconductor processing chamber. The methods may include thermally reacting the silicon-containing precursor, the carbon-containing precursor, and the boron-containing precursor at a temperature above about 250° C. The methods may include forming a silicon-and-carbon-containing layer on the substrate.

A method of forming a fin field effect transistor (finFET), including forming a temporary gate structure having a sacrificial gate layer and a dummy gate layer on the sacrificial gate layer, forming a gate spacer layer on each sidewall of the temporary gate structure, forming a source/drain spacer layer on the outward-facing sidewall of each gate spacer layer, removing the dummy gate layer to expose the sacrificial gate layer, removing the sacrificial gate layer to form a plurality of recessed cavities, and forming a gate structure, where the gate structure occupies at least a portion of the plurality of recessed cavities.

A method of manufacturing a semiconductor device for forming a thin film having low permittivity, high etching resistance and high leak resistance is provided. The method includes: forming a film containing a predetermined element, oxygen, carbon and nitrogen on a substrate by performing a cycle a predetermined number of times. The cycle includes: (a) supplying a source gas containing the predetermined element and a halogen element to the substrate; (b) supplying a first reactive gas containing the three elements including carbon, nitrogen and hydrogen wherein a number of carbon atoms in each molecule of the first reactive gas is greater than that of nitrogen atoms in each molecule of the first reactive gas to the substrate; (c) supplying a nitriding gas as a second reactive gas to the substrate; and (d) supplying an oxidizing gas as a third reactive gas to the substrate, wherein (a) through (d) are non-simultaneously performed.

There is provided a technique that includes: supplying a film formation inhibition gas to the substrate, which includes a first base and a second base on a surface of the substrate, to form a film formation inhibition layer on a surface of the first base; supplying a film-forming gas to the substrate after forming the film formation inhibition layer on the surface of the first base, to form a film on a surface of the second base; and supplying a halogen-free substance, which chemically reacts with the film formation inhibition layer and the film, to the substrate after forming the film on the surface of the second base, in a non-plasma atmosphere.

A process for depositing a silicon carbon nitride film on a substrate can include a plurality of complete deposition cycles, each complete deposition cycle having a SiN sub-cycle and a SiCN sub-cycle. The SiN sub-cycle can include alternately and sequentially contacting the substrate with a silicon precursor and a SiN sub-cycle nitrogen precursor. The SiCN sub-cycle can include alternately and sequentially contacting the substrate with carbon-containing precursor and a SiCN sub-cycle nitrogen precursor. The SiN sub-cycle and the SiCN sub-cycle can include atomic layer deposition (ALD). The process for depositing the silicon carbon nitride film can include a plasma treatment. The plasma treatment can follow a completed plurality of complete deposition cycles.

There is provided a technique having a process that includes forming a film, which contains a first element and a second element on a substrate by performing a cycle a predetermined number of times, the cycle sequentially performing: (a) supplying a first precursor gas containing the first element to the substrate in a process chamber; (b) supplying a second precursor gas, which contains the first element and has a pyrolysis temperature lower than a pyrolysis temperature of the first precursor gas, to the substrate; and (c) supplying a reaction gas, which contains the second element that is different from the first element, to the substrate.

Provided are methods and apparatuses for densifying a silicon carbide film using remote plasma treatment. Operations of remote plasma deposition and remote plasma treatment of the silicon carbide film alternatingly occur to control film density. A first thickness of silicon carbide film is deposited followed by a remote plasma treatment, and then a second thickness of silicon carbide film is deposited followed by another remote plasma treatment. The remote plasma treatment can flow radicals of source gas in a substantially low energy state, such as radicals of hydrogen in a ground state, towards silicon carbide film deposited on a substrate. The radicals of source gas in the substantially low energy state promote cross-linking and film densification in the silicon carbide film.

Semiconductor devices and methods of forming semiconductor devices are provided. A method includes forming a first mask layer over an underlying layer, patterning the first mask layer to form a first opening, forming a non-conformal film over the first mask layer, wherein a first thickness of the non-conformal film formed on the top surface of the first mask layer is greater than a second thickness of the non-conformal film formed on a sidewall surface of the first mask layer, performing a descum process, wherein the descum process removes a portion of the non-conformal film within the first opening, and etching the underlying layer using the patterned first mask layer and remaining portions of the non-conformal film as an etching mask.

A film containing a prescribed element and carbon is formed on a substrate, by performing a cycle a prescribed number of times, the cycle including: supplying an organic-based source containing a prescribed element and a pseudo catalyst including at least one selected from the group including a halogen compound and a boron compound, into a process chamber in which the substrate is housed, and confining the organic-based source and the pseudo catalyst in the process chamber; maintaining a state in which the organic-based source and the pseudo catalyst are confined in the process chamber; and exhausting an inside of the process chamber.

Methods of filling a gap with a dielectric material including using an inhibitor plasma during deposition. The inhibitor plasma increases a nucleation barrier of the deposited film. When the inhibitor plasma interacts with material in the feature, the material at the bottom of the feature receives less plasma treatment than material located closer to a top portion of the feature or in field. Deposition at the top of the feature is then selectively inhibited and deposition in lower portions of the feature proceeds with less inhibition or without being inhibited. As a result, bottom-up fill is enhanced, which can create a sloped profile that mitigates the seam effect and prevents void formation. In some embodiments, an underlying material at the top of the feature is protected using an integrated liner. In some embodiments, a hydrogen chemistry is used during gap fill to reduce seam formation.