Abstract: A method for fabricating a semiconductor device including GaN (gallium nitride) that composes a semiconductor layer and includes forming a gate insulating film, in which at least one film selected from the group of a SiO2 film and an Al2O3 film is formed on a nitride layer containing GaN by using microwave plasma and the formed film is used as at least a part of the gate insulating film.

Abstract: A method for using a vertical film formation apparatus includes performing a coating process inside the process container without product target objects present therein to cover an inner surface of the process container with a coating film, and then performing a film formation process inside the process container accommodating the holder with the product target objects placed thereon to form a predetermined film on the product target objects. The coating process alternately supplies the first and second process gases into the process container without turning either of the first and second process gases into plasma. The film formation process alternately supplies the first and second process gases into the process container while turning at least one of the first and second process gases into plasma.

Abstract: A method of forming a germanium thin film on an underlying film includes forming a germanium seed layer by absorbing a germanium on a surface of the underlying film using an aminogermane-based gas, and forming a germanium thin film on the germanium seed layer using a germane-based gas.

Abstract: This invention discloses the method of forming silicon nitride, silicon oxynitride, silicon oxide, carbon-doped silicon nitride, carbon-doped silicon oxide and carbon-doped oxynitride films at low deposition temperatures. The silicon containing precursors used for the deposition are monochlorosilane (MCS) and monochloroalkylsilanes. The method is preferably carried out by using plasma enhanced atomic layer deposition, plasma enhanced chemical vapor deposition, and plasma enhanced cyclic chemical vapor deposition.

Abstract: A film formation method of forming a silicon oxide film on a surface of an object to be processed in a process chamber includes absorbing a seed gas comprising a silane-based gas on the surface of the object to be processed by supplying the seed gas into the process chamber, forming a silicon film having an impurity by supplying a silicon-containing gas as a material gas, and an addition gas including the impurity into the process chamber, and oxidizing the silicon film to convert the silicon film into the silicon oxide film. Accordingly, the silicon oxide film having the high density and the high stress is formed on the surface of the object to be processed.

Abstract: In a mask pattern forming method, a resist film is formed over a thin film, the resist film is processed into resist patterns having a predetermined pitch by photolithography, slimming of the resist patterns is performed, and an oxide film is formed on the thin film and the resist patterns after an end of the slimming step in a film deposition apparatus by supplying a source gas and an oxygen radical or an oxygen-containing gas. In the mask pattern forming method, the slimming and the oxide film forming are continuously performed in the film deposition apparatus.

Abstract: There is provided a micro pattern forming method including forming a thin film on a substrate; forming a film serving as a mask when processing the thin film; processing the film serving as a mask into a pattern including lines having a preset pitch; trimming the pattern including the lines; and forming an oxide film on the pattern including the lines and on the thin film by alternately supplying a source gas and an activated oxygen species. Here, the process of trimming the pattern and the process of forming an oxide film are consecutively performed in a film forming apparatus configured to form the oxide film.

Abstract: A silicon-containing insulating film is formed on a target substrate by CVD, in a process field to be selectively supplied with a first process gas including di-iso-propylaminosilane gas and a second process gas including an oxidizing gas or nitriding gas. The film is formed by performing a plurality of times a cycle alternately including first and second steps. The first step performs supply of the first process gas, thereby forming an adsorption layer containing silicon on a surface of the target substrate. The second performs supply of the second process gas, thereby oxidizing or nitriding the adsorption layer on the surface of the target substrate. The second step includes an excitation period of supplying the second process gas to the process field while exciting the second process gas by an exciting mechanism.

Abstract: A method for using a film formation apparatus includes performing a main cleaning process and a post cleaning process in this order inside a reaction chamber. The main cleaning process is arranged to supply a cleaning gas containing fluorine into the reaction chamber while exhausting gas from inside the reaction chamber, thereby etching a film formation by-product containing silicon. The post cleaning process is arranged to remove a silicon-containing fluoride generated by the main cleaning process and remaining inside the reaction chamber and to alternately repeat, a plurality of times, supplying an oxidizing gas into the reaction chamber to transform the silicon-containing fluoride into an intermediate product by oxidization, and supplying hydrogen fluoride gas into the reaction chamber while exhausting gas from inside the reaction chamber to remove the intermediate product by a reaction between the hydrogen fluoride gas and the intermediate product.

Abstract: Provided is a method and apparatus for forming a silicon film, which are capable of suppressing generation of a void or seam. The method includes performing a first film-forming process, performing an etching process, performing a doping process, and performing a second film-forming process. In the first film-forming process, a non-doped silicon film that is not doped with an impurity is formed so as to embed a groove of an object. In the etching process, the non-doped silicon film formed via the first film-forming process is etched. In the doping process, the non-doped silicon film etched via the etching process is doped with an impurity. In the second film-forming process, an impurity-doped silicon film is formed so as to embed the silicon film doped via the doping process.

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: A method for forming an SiCN film on target substrates placed in a process field inside a process container repeats a unit cycle a plurality of times to laminate thin films respectively formed, thereby forming the SiCN film with a predetermined thickness. The unit cycle includes performing and suspending supply of a silicon source gas, a nitriding gas, and a carbon hydride gas respectively from first, second, and third gas distribution nozzles to the process field. The unit cycle does not turn any one of the gases into plasma but heats the process field to a set temperature of 300 to 700° C. with the supply of the carbon hydride gas performed for a time period in total longer than that of the supply of the silicon source gas, so as to provide the SiCN film with a carbon concentration of 15.2% to 28.5%.

Abstract: This invention discloses the method of forming silicon nitride, silicon oxynitride, silicon oxide, carbon-doped silicon nitride, carbon-doped silicon oxide and carbon-doped oxynitride films at low deposition temperatures. The silicon containing precursors used for the deposition are monochlorosilane (MCS) and monochloroalkylsilanes. The method is preferably carried out by using plasma enhanced atomic layer deposition, plasma enhanced chemical vapor deposition, and plasma enhanced cyclic chemical vapor deposition.

Abstract: A disclosed film deposition method includes steps of loading plural substrates each of which includes a pattern including a concave part in a reaction chamber in the form of shelves; depositing a silicon oxide film on the plural substrates by supplying a silicon-containing gas and an oxygen-containing gas to the reaction chamber; etching the silicon oxide film deposited on the plural substrates in the step of depositing by supplying a fluorine-containing gas and an ammonia gas to the reaction chamber; and alternately repeating the step of depositing and the step of etching.

Abstract: A film formation method, in a vertical batch CVD apparatus, is preset to repeat a cycle a plurality of times to laminate thin films formed by respective times. The cycle alternately includes an adsorption step of adsorbing a source gas onto a surface of the target substrates and a reaction step of causing a reactive gas to react with the adsorbed source gas. The adsorption step is arranged to make a plurality of times a supply sub-step of performing supply of the source gas to the process field with an intermediate sub-step of stopping supply of the source gas to the process field interposed therebetween, while maintaining a shut-off state of supply of the reactive gas. The reaction step is arranged to continuously perform supply of the reactive gas to the process field, while maintaining a shut-off state of supply of the source gas.

Abstract: A method of forming a silicon nitride film on the surface of an object to be processed, the method including forming a seed layer functioning as a seed of the silicon nitride film on the surface of the object to be processed by using at least an aminosilane-based gas, prior to forming the silicon nitride film on the surface of the object to be processed.

Abstract: A film formation method includes setting a target object at a temperature of 150 to 550° C., the target object being placed inside the process container configured to hold a vacuum state therein, and then, repeating a cycle alternately including a first supply step and a second supply step a plurality of times to form a silicon nitride film on the target object. The first supply step is a step of supplying monochlorosilane gas as an Si source into the process container while setting the process container at a pressure of 66.65 to 666.5 Pa therein. The second supply step is a step of supplying a nitrogen-containing gas as a nitriding gas into the process container.

Abstract: Disclosed is a method for using a film formation apparatus to form a silicon nitride film by CVD on target substrates while suppressing particle generation. The apparatus includes a process container and an exciting mechanism attached on the process container. The method includes conducting a pre-coating process by performing pre-cycles and conducting a film formation process by performing main cycles. Each of the pre-cycles and main cycles alternately includes a step of supplying a silicon source gas and a step of supplying a nitriding gas with steps of exhausting gas from inside the process container interposed therebetween. The pre-coating process includes no period of exciting the nitriding gas by the exciting mechanism. The film formation process repeats a first cycle set that excites the nitriding gas by the exciting mechanism and a second cycle that does not excite the nitriding gas by the exciting mechanism.

Abstract: A film formation apparatus includes a gas supply mechanism for supplying an aminosilane-based gas, and a silane-based gas that does not include an amino group. Processes of forming a seed layer on a surface of the insulation film having the opening reaching the conductive substance and on a bottom surface of the opening by supplying the aminosilane-based gas into the process chamber, and forming a silicon film on the seed layer by supplying the silane-based gas that does not include the amino group into the process chamber, are sequentially performed in the process chamber.

Abstract: Provided is a vertical heat treatment apparatus which performs a film-forming process for substrates by supplying a film-forming gas to a plurality of substrates loaded onto a substrate supporter. The substrate supporter is rotated around an inclination axis, and the apparatus includes: a plurality of main holders which are provided at every reception position of the substrates in the substrate supporter and respectively supports the peripheries of the substrates at positions separated from each other in the circumferential direction; and first and second auxiliary holders which are located to be separated from the main holders in the circumferential direction and whose tops are lower than those of the main holders. Each substrate alternates between a position supported by the first auxiliary holder and the main holders and a position supported by the second auxiliary holder and the main holders every rotation of the substrate supporter.