A film forming method includes: (a) preparing a substrate having an oxide layer formed on the substrate; (b) supplying a nitrogen-containing gas to the substrate heated by a heater; and (c) forming a molybdenum film on the oxide layer by alternately supplying a raw material gas containing molybdenum and a reducing gas a plurality of times.

Disclosed herein is a chemical vapor infiltration method including flowing ceramic precursors through a preform and depositing a matrix material on the preform at a first gas infiltration pressure, increasing the gas filtration pressure to a second gas infiltration pressure, and lowering the gas infiltration pressure to a third gas infiltration pressure which is intermediate to the first and second gas infiltration pressures.

A method of forming a structure includes supporting a substrate within a reaction chamber of a semiconductor processing system, the substrate having a recess with a bottom surface and a sidewall surface extending upwards from the bottom surface of the recess. A film is deposited within the recess and onto the bottom surface and the sidewall surface of the recess, the film having a bottom segment overlaying the bottom surface of the recess and a sidewall segment deposited onto the sidewall surface of the recess. The sidewall segment of the film is removed while at least a portion bottom segment of the film is retained within the recess, the sidewall segment of the film removed from the sidewall surface more rapidly than removing the bottom segment of the film from the bottom surface of the recess. Semiconductor processing systems and structures formed using the method are also described.

A substrate processing system for treating a substrate includes a manifold and a plurality of injector assemblies located in a processing chamber. Each of the plurality of injector assemblies is in fluid communication with the manifold and includes a valve including an inlet and an outlet. A dose controller is configured to communicate with the valve in each of the plurality of injector assemblies and adjust a pulse width supplied to the valve in each of the plurality of injector assemblies based on at least one of manufacturing differences between the valves in each of the plurality of injector assemblies and non-uniformities of the valves in each of the plurality of injector assemblies to cause a desired dose to be supplied from the valve in each of the plurality of injector assemblies.

A deposition method according to one aspect of the present disclosure includes performing multiple execution cycles serially. Each of the multiple execution cycles includes: supplying a raw material gas into a process chamber; and supplying a reactant gas that reacts with the raw material gas. Among the multiple execution cycles, at least one execution cycle includes adjusting a pressure in the process chamber without supplying the raw material gas, and the adjusting of the pressure is performed prior to the supplying of the raw material gas.

Apparatus for mixing two or more gases prior to entering a reaction chamber, reactor systems including the apparatus, and methods of using the apparatus and systems are disclosed. The systems and methods as described herein can be used to, for example, pulse a mixture of two or more precursors to a reaction chamber.

A cutting tool includes a substrate and a coated film arranged on the substrate. The coated film includes a first layer. The first layer includes a plurality of crystal grains. The crystal grains are composed of Al.sub.xTi.sub.1−xC.sub.yN.sub.1−y, wherein x is more than 0.65 and less than 0.95, and y is not less than 0 and less than 0.1. In a first region, the crystal grains have an average aspect ratio of not more than 3.0. In a second region, the crystal grains have an average aspect ratio of more than 3.0 and not more than 10.0. The crystal grains include crystal grains having a cubic crystal structure. The first layer has a ratio of an area occupied by the crystal grains having a cubic crystal structure of not less than 90%. The first layer has a thickness of not less than 2 m and not more than 20 m.

A high-pressure processing system for processing a layer on a substrate includes a first chamber, a support to hold the substrate in the first chamber, a second chamber adjacent the first chamber, a foreline to remove gas from the second chamber, a vacuum processing system configured to lower a pressure within the second chamber to near vacuum, a valve assembly between the first chamber and the second chamber to isolate the pressure within the first chamber from the pressure within the second chamber, a gas delivery system configured to increase the pressure within the first chamber to at least 10 atmospheres while the first chamber is isolated from the second chamber, an exhaust system comprising an exhaust line to remove gas from the first chamber, and a common housing surrounding both the first gas delivery module and the second gas delivery module.

An apparatus that performs a film forming process includes: a rotary table having one surface on which substrates are placed and for revolving the substrates around a rotary shaft; a vacuum container configured to accommodate the rotary table and configured such that a space formed between the vacuum container and the one surface is separated into a first processing region and a second processing region, and the substrates repeatedly and alternately pass through the first and second processing regions; a vacuum chuck mechanism provided in the rotary table and including suction ports opened to placement regions on which the substrates are placed, to suction and fix the substrates, and suction flow paths provided to communicate with the suction ports; and a switching mechanism configured to switch an operation status of the vacuum chuck mechanism between a full fixed state and a selective release state.

Exemplary deposition methods may include delivering a ruthenium-containing precursor and a hydrogen-containing precursor to a processing region of a semiconductor processing chamber. At least one of the ruthenium-containing precursor or the hydrogen-containing precursor may include carbon. The methods may include forming a plasma of all precursors within the processing region of a semiconductor processing chamber. The methods may include depositing a ruthenium-and-carbon material on a substrate disposed within the processing region of the semiconductor processing chamber.