Abstract: An insulating film is formed on a target substrate by CVD, in a process field to be selectively supplied with a first process gas containing a silane family gas, a second process gas containing a nitriding gas, and a third process gas containing a carbon hydride gas. This method includes repeatedly performing supply of the first process gas to the process field, supply of the second process gas to the process field, and supply of the third process gas to the process field. The supply of the third process gas includes an excitation period of supplying the third process gas to the process field while exciting the third process gas by an exciting mechanism.

Abstract: A film-formation method for a semiconductor process includes seed film formation and main film formation. In the seed film formation, a metal-containing raw material gas and a first assist gas to react therewith are supplied into a process container, which accommodates a target substrate having an underlying layer, thereby forming a seed film on the underlying layer by CVD. In the main film formation, the raw material gas and a second assist gas to react therewith are supplied into the process container, thereby forming a main film on the seed film by CVD. The seed film formation includes first and second periods performed alternately and continuously. In each first period, the raw material gas is supplied into the process container while the first assist gas is stopped. In each second period, the first assist gas is supplied into the process container while the raw material gas is stopped.

Abstract: A method for forming a silicon oxide film includes disposing a silicon oxide film on a surface of a target substrate, and performing a reformation process on the silicon oxide film. The reformation process is performed by annealing the silicon oxide film while exposing the silicon oxide film to oxygen radicals and hydroxyl group radicals.

Abstract: A method for subjecting target substrates to a heat process under a vacuum pressure includes a transfer step, heating-up and pressure-reducing step, and heat-processing step. The transfer step is arranged to transfer into a reaction chamber a holder that supports the substrates at intervals. The heating-up and pressure-reducing step following the transfer step is arranged to heat up the reaction chamber to a process temperature, and exhaust the reaction chamber to a process pressure. During the heating-up and pressure-reducing step, the reaction chamber is set at the process pressure after being set at the process temperature, to form a state where the reaction chamber has the process temperature under a pressure higher than the process pressure. The heat-processing step following the heating-up and pressure-reducing step is arranged to subject the substrates to the heat process at the process temperature and process pressure.

Abstract: A silicon-containing insulating film is formed on a target substrate by CVD, in a process field to be selectively supplied with a purge gas, a first process gas containing a silane family gas, and a second process gas containing a gas selected from the group consisting of nitriding, oxynitriding, and oxidizing gases. This method alternately includes first to fourth steps. The first, second, third, and fourth steps perform supply of the first process gas, purge gas, second process gas, and purge gas, respectively, while stopping supply of the other two gases. The process field is continuously vacuum-exhausted over the first to fourth steps through an exhaust passage provided with an opening degree adjustment valve. An opening degree of the valve in the first step is set to be 5 to 95% of that used in the second and fourth steps.

Abstract: An oxidation method is capable of forming oxide films in an improved interfilm thickness uniformity. The oxidation method includes the steps of supplying an oxidizing gas and a reducing gas into a processing vessel 22 capable of being evacuated and holding a plurality of workpieces W arranged at predetermined pitches, and creating a process atmosphere containing active oxygen species and active hydroxyl species in the processing vessel 22 through the interaction of the oxidizing gas-and the reducing gas. At least either of the oxidizing gas and the reducing gas is jetted into an upstream region S1, a middle region S2 and a downstream region S3, with respect to the flowing direction of the gas, of a processing space S containing the workpieces W.

Abstract: The present invention is a thermal processing unit including: a heating-furnace body whose upper end has an opening; a heating unit provided on an inside wall of the heating-furnace body; a reaction container consisting of a single tube contained in the heating-furnace body; a gas-discharging-pipe connecting portion formed at an upper portion of the reaction container; and a first temperature controlling unit provided around the gas-discharging-pipe connecting portion.

Abstract: A vapor-phase growing unit of this invention includes: a reaction container in which a substrate is arranged, a first gas-introducing part having a first gas-introducing tube in which a gas-spouting port opening in the reaction container is formed, the first gas-introducing part serving to supply into the reaction container a first gas consisting of an organic-metal including gas, and a second gas-introducing part having a second gas-introducing tube in which a gas-spouting port opening in the reaction container is formed, the second gas-introducing part serving to supply into the reaction container a second gas which reacts with the organic-metal including gas and whose density is smaller than that of the organic-metal including gas. The gas-spouting port of the first gas-introducing tube and the gas-spouting port of the second gas-introducing tube are arranged along an outside periphery of the substrate arranged in the reaction container.

Abstract: The present invention is a thermal processing unit including: a heating-furnace body whose upper end has an opening; a heating unit provided on an inside wall of the heating-furnace body; a reaction container consisting of a single tube contained in the heating-furnace body; a gas-discharging-pipe connecting portion formed at an upper portion of the reaction container; and a first temperature controlling unit provided around the gas-discharging-pipe connecting portion.

Abstract: An oxidation method is capable of forming oxide films in an improved interfilm thickness uniformity. The oxidation method includes the steps of supplying an oxidizing gas and a reducing gas into a processing vessel 22 capable of being evacuated and holding a plurality of workpieces W arranged at predetermined pitches, and creating a process atmosphere containing active oxygen species and active hydroxyl species in the processing vessel 22 through the interaction of the oxidizing gas and the reducing gas. At least either of the oxidizing gas and the reducing gas is jetted into an upstream region S1, a middle region S2 and a downstream region S3, with respect to the flowing direction of the gas, of a processing space S containing the workpieces W.

Abstract: An oxidation method for a semiconductor process, which oxidizes a surface of a target substrate, includes heating a process container that accommodates the target substrate, and supplying hydrogen gas and oxygen gas into the process container while exhausting the process container. The oxidation method also includes causing the hydrogen gas and the oxygen gas to react with each other in the process container at a process temperature and a process pressure to generate water vapor, and oxidizing the surface of the target substrate by the water vapor. The process pressure is set at 2000 Pa (15 Torr) or more.

Abstract: The present invention is a method of cleaning a heat treatment apparatus that deposits an SiO2 film by mean of TEOS on an object to be processed contained in a treatment vessel capable of forming a vacuum. In the cleaning method, the heat treatment apparatus is cleaned by supplying an HF gas and an NH3 gas into the treatment vessel.

Abstract: This invention is a cleaning method of a film-forming unit that forms a thin film on an object to be processed by supplying a process gas into a reaction chamber containing the object to be processed, the method comprising a purging step of purging an inside of the reaction chamber by supplying into the reaction chamber a nitrogen-including gas that includes nitrogen and that is capable of being activated. The purging step has a step of nitriding a surface of a member in the reaction chamber by activating the nitrogen-including gas.

Abstract: A silicon dioxide film removing method is capable of removing a silicon dioxide film, such as a natural oxide film or a chemical oxide film, at a temperature considerably higher than a room temperature. The silicon dioxide film removing method of removing a silicon dioxide film formed on a workpiece in a processing vessel 18 that can be evacuated uses a mixed gas containing HF gas and NH3 gas for removing the silicon dioxide film. The silicon dioxide film can be efficiently removed from the surface of the workpiece by using the mixed gas containing HF gas and NH3 gas.

Abstract: A film formation apparatus for a semiconductor process includes a process gas supply system configured to supply process gases. The process gas supply system includes a gas mixture tank configured to mix first and third process gases to form a mixture gas, a mixture gas supply line configured to supply the mixture gas from the gas mixture tank to a process field, a second process gas supply circuit having a second process gas supply line configured to supply a second process gas to the process field without passing through the gas mixture tank, and first and second switching valves disposed on the mixture gas supply line and the second process gas supply line, respectively. A control section controls the first and second switching valves to be opened and closed so as to alternately and pulse-wise supply the mixture gas and the second process gas to the process field.

Abstract: An insulating film is formed on a target substrate by CVD, in a process field to be selectively supplied with a first process gas containing a silane family gas, a second process gas containing a nitriding or oxynitriding gas, and a third process gas containing a carbon hydride gas. This method alternately includes first to fourth steps. The first step performs supply of the first and third process gases to the field while stopping supply of the second process gas to the process field. The second step stops supply of the first to third process gases to the field. The third step performs supply of the second process gas to the field while stopping supply of the first and third process gases to the field. The fourth step stops supply of the first to third process gases to the field.

Abstract: An insulting film is modified by subjecting the insulting film to a modification treatment comprising a combination of a plasma treatment and a thermal annealing treatment. There is provided a method of enhancing the characteristic of an insulating film by improving deterioration in the characteristic of the insulating film due to carbon, a suboxide, a dangling bond or the like contained in the insulating film.

Abstract: After silicon nitride films have been formed on wafers by a film forming process in a reaction vessel, the reaction vessel is processed by a purging process specified by a purging recipe and compatible with the film forming process to suppress production of gases and particles by removing surface parts of films deposited on the inside surface of the reaction vessel and causative of production of gases and particles. A wafer boat 25 holding a plurality of wafers W is loaded into a reaction vessel 2, and the wafers W are processed by a film forming process specified by a film forming recipe 1 specifying, for example, Si2Cl2 gas and NH3 gas as film forming gases. Subsequently, a purging recipe 1 specifying a purging process compatible to the film forming process is selected automatically, and the reaction vessel 2 is processed by the purging process specified by the purging recipe 1.

Abstract: A thermal processing unit of the present invention includes: a holder that holds a plurality of substrates; a reaction container into which the holder is conveyed; a process-gas supplying mechanism that supplies a process gas into the reaction container; and a heating mechanism that heats the reaction container to conduct a film-forming process to the substrates when the process gas is supplied. Flow-rate-parameter table-data associating number-data of the substrates to be processed by one batch-process with target-data of flow-rate parameter of the process gas is stored in a flow-rate-parameter table-data storing part. A controlling unit obtains target-data of flow-rate parameter of the process gas, depending on an actual number of the substrates to be processed by one batch-process, based on the flow-rate-parameter table-data stored in the flow-rate-parameter table-data storing part, and controls the process-gas supplying mechanism according to the obtained target-data.

Abstract: In a capacitor of an MIM (Metal-Insulator-Metal) structure, a silicon-containing high dielectric film (e.g., a hafnium silicate film) containing a silicon atom, as well as a silicon-free high dielectric film (e.g., a tantalum oxide film) containing no silicon atom is interposed between a lower electrode film and an upper electrode film which are made of metal or metal compound. By adding the silicon-containing high dielectric film, a leak current can be suppressed and the change in capacitor capacity accompanied with the change in applied voltage can be reduced.