Abstract: A thin film manufacturing method and a thin film manufacturing apparatus are provided to manufacture a thin film with good reproducibility. A dummy substrate is conveyed into a chamber, and a dummy processing gas is supplied to the dummy substrate. Moreover, a product substrate is conveyed into the chamber, and a raw material gas different from the dummy processing gas is supplied to the product substrate. The raw material gas contains metal material for manufacturing a thin film with a metal organic chemical vapor deposition (MOCVD) method. Since the raw material gas is not used as a dummy processing gas, the amount of metal material to be used can be minimized in manufacturing the thin film with good reproducibility.

Abstract: A thin film-forming apparatus, for ensuring uniform plane distribution of properties of a film formed on a substrate surface, has a gas-supply port 24a supplying a gas mixture from a gas-mixing chamber 24 to a shower head 25. The port is arranged at the peripheral portion on the bottom face of the gas-mixing chamber so that the gas mixture flows from the upper peripheral region of the head towards the center thereof. An exhaust port 32 discharging the exhaust gas generated in the film-forming chamber 3 is arranged at a position lower than the level of a stage 31 during film-formation directing the exhaust gas towards the side wall of the chamber 3 and discharging the exhaust gas through the exhaust port. The stage 31 is designed to move freely up and down to adjust the distance between the shower head 25 and substrate S.

Abstract: In order to provide a thin film manufacturing method and a thin film manufacturing apparatus, wherein a thin film with good reproducibility can be manufactured at low cost, and in a way wherein resources are saved, a dummy substrate (S2) is conveyed into a chamber (51), dummy processing gas is supplied to the dummy substrate (S2), a product substrate (S3) is conveyed into the chamber (51), and raw material gas different from the dummy processing gas, and containing therein metal material for manufacturing a thin film with the Metal Organic Chemical Vapor Deposition (MOCVD) method, is supplied to the product substrate (S3). Since the raw material gas is not used as dummy processing gas, the amount of metal material to be used can be inhibited, and a thin film with good reproducibility can be manufactured at low cost, and in a way wherein resources are saved.

Abstract: [Problem] To provide a thin film production process and a thin film production device, both of which enable the production of a dielectric thin film having small surface roughness. [Solution] This thin film production process comprises: supplying a mixed gas to a substrate (S) that is placed in a chamber (51) and has been heated, wherein the mixed gas comprises a metal raw material gas that serves as a raw material for a dielectric thin film having perovskite-type crystals and an oxidation gas that can react with the metal raw material gas; stopping the supply of the metal raw material gas to the substrate (S); and, subsequent to the stopping of the supply of the metal raw material gas, limiting the supply of the oxidation gas to the substrate (S).

Abstract: In an apparatus for manufacturing a ceramic thin film by employing a thermal CVD method, an internal jig, which is provided with a heat radiation material film on the surface, is provided at a position that faces a substrate (S) on which the film is to be formed. The thin film and a semiconductor device are manufactured using such apparatus.

Abstract: The present invention herein provides a shower head whose temperature can be controlled in consideration of the film-forming conditions selected and a thin film-manufacturing device which permits the stable and continuous formation of thin films including only a trace amount of particles while reproducing a good film thickness distribution and compositional distribution, and a high film-forming rate and which is excellent in the productivity and the mass-producing ability as well as a method for the preparation of such a film.

Abstract: Film-forming apparatus including a film-forming vacuum chamber having a stage for a substrate, a chamber for mixing gas comprising a raw gas and a reactive gas connected to the film-forming chamber, a chamber for vaporizing the raw material, and a gas head for introducing the mixed gas into the film-forming chamber, disposed on the upper face of the film-forming chamber and opposed to the stage. Particle traps with controllable temperatures are positioned between the vaporization chamber and the mixing chamber and on the downstream side of the mixing chamber. When forming a thin film with the apparatus, a reactive gas and/or a carrier gas are passed through the film-forming chamber while opening a valve in a by-pass line, connecting the primary side to the secondary side of the particle trap arranged at the downstream side of the mixing chamber. The valve is then closed and the film-forming operation is initiated.

Abstract: A thin film manufacturing system, wherein a stage for placing a substrate thereon is disposed within a vacuum reactor and a gas head for supplying a film forming gas to a central area on a top face of the vacuum reactor is arranged so that the gas head is opposed to the stage. A cylindrical sleeve member is disposed and comes in close contact with a side wall of the stage to surround a periphery of the stage. The height of the stage can be established at the position where the volume of a second space formed below the stage and connected to a vacuum discharge means is larger than that of a first space formed above the stage, in such a manner that an exhaust gas is isotropically discharged from the first space without causing any convection current therein through the interstice between the sleeve member and an inner wall surface constituting the reactor.

Abstract: A film forming method in which a crystalline film having PZT (111) as a principal component thereof is laminated on a foundation film having a (111) oriented noble metal as a principal component thereof, the method including the steps of: forming an oxide film whose interplanar spacing is closer to the PZT (111) than to the noble metal, on a surface of the foundation film; and forming the crystalline film on the surface of the foundation film by an MOCVD method.

Abstract: A film forming method in which crystalline film having PZT (001) or PZT (100) as a principal component thereof is laminated on a foundation film having a (111) oriented noble metal as a principal component thereof, the method including the steps of: performing reduction treatment on a surface of the foundation film; and forming the crystalline film by an MOCVD method on the surface of the foundation film.

Abstract: The present invention herein provide a thin film-manufacturing device and a thin film-manufacturing method which are excellent in the mass-production ability and productivity, which permit the stable and continuous production of films over a long period of time while reproducing a good film thickness distribution, a good compositional distribution and a high film-forming rate and controlling the number of particles generated during the film-formation to a lower level.

Abstract: An oxide thin film having good characteristic properties is prepared by reducing an occurrence of an oxygen defect of the resulting oxide thin film and promoting the epitaxial growth of the film. The oxide thin film is prepared by admixing a raw gas, a carrier gas and an oxidation gas and supplying the resulting gas mixture on a heated substrate placed in a reaction chamber from a shower plate through a gas activating means which is maintained, by a heating means, at such a temperature that any liquefaction, deposition and film-formation of a raw material are never caused, to thus make the oxidation gas react with one another and to prepare the oxide thin film on the substrate. In this case, a rate of the oxidation gas flow rate is not less than 60% on the basis of the gas mixture. Furthermore, a flow rate of oxidation gas used for forming an initial layer by nucleation is less than 60%, and a flow rate of oxidation gas used in a subsequent film-forming process for forming a second layer is not less than 60%.

Abstract: A thin film manufacturing system, wherein a stage for placing a substrate thereon is disposed within a vacuum reactor and a gas head for supplying a film forming gas to a central area on a top face of the vacuum reactor is arranged so that the gas head is opposed to the stage. A cylindrical sleeve member is disposed and comes in close contact with a side wall of the stage to surround a periphery of the stage. The height of the stage can be established at the position where the volume of a second space formed below the stage and connected to a vacuum discharge means is larger than that of a first space formed above the stage, in such a manner that an exhaust gas is isotropically discharged from the first space without causing any convection current therein through the interstice between the sleeve member and an inner wall surface constituting the reactor.

Abstract: A thin film-forming apparatus, for ensuring uniform plane distribution of properties of a film formed on a substrate surface, has a gas-supply port 24a supplying a gas mixture from a gas-mixing chamber 24 to a shower head 25. The port is arranged at the peripheral portion on the bottom face of the gas-mixing chamber so that the gas mixture flows from the upper peripheral region of the head towards the center thereof. An exhaust port 32 discharging the exhaust gas generated in the film-forming chamber 3 is arranged at a position lower than the level of a stage 31 during film-formation directing the exhaust gas towards the side wall of the chamber 3 and discharging the exhaust gas through the exhaust port. The stage 31 is designed to move freely up and down to adjust the distance between the shower head 25 and substrate S.

Abstract: A thin film manufacturing system, wherein a stage for placing a substrate thereon is disposed within a vacuum reactor and a gas head for supplying a film forming gas to a central area on a top face of the vacuum reactor is arranged so that the gas head is opposed to the stage. A cylindrical sleeve member is disposed and comes in close contact with a side wall of the stage to surround a periphery of the stage. The height of the stage can be established at the position where the volume of a second space formed below the stage and connected to a vacuum discharge means is larger than that of a first space formed above the stage, in such a manner that an exhaust gas is isotropically discharged from the first space without causing any convection current therein through the interstice between the sleeve member and an inner wall surface constituting the reactor.

Abstract: The present invention herein provide a thin film-manufacturing device and a thin film-manufacturing method which are excellent in the mass-production ability and productivity, which permit the stable and continuous production of films over a long period of time while reproducing a good film thickness distribution, a good compositional distribution and a high film-forming rate and controlling the number of particles generated during the film-formation to a lower level.

Abstract: The present invention herein provides a shower head whose temperature can be controlled in consideration of the film-forming conditions selected and a thin film-manufacturing device which permits the stable and continuous formation of thin films including only a trace amount of particles while reproducing a good film thickness distribution and compositional distribution, and a high film-forming rate and which is excellent in the productivity and the mass-producing ability as well as a method for the preparation of such a film.

Abstract: A mixing box 1 comprises a stirring chamber 2 in which two gas-introduction pipes 5, 6 for introducing gases are arranged in such a manner that the gas-introduction inlets 5a, 6a thereof are opposed to one another and a diffusion chamber 3 for diffusing a gas mixture, wherein a partition plate 4 having a specific shape is positioned between the stirring chamber and the diffusion chamber in such a manner that the volume of the diffusion chamber is larger than that of the stirring chamber, wherein a gas-supply opening 7 is arranged, on the partition plate, at a desired position on the lower side of the direction perpendicular to the straight line connecting the two gas-introduction inlets, the box being able to uniformly admix gases having different masses and having a simple structure. The partition plate has a shape of a curve of second degree, which is convex with respect to the bottom of the mixing box.

Abstract: Film-forming apparatus including a film-forming vacuum chamber having a stage for a substrate, a chamber for mixing gas comprising a raw gas and a reactive gas connected to the film-forming chamber, a chamber for vaporizing the raw material, and a gas head for introducing the mixed gas into the film-forming chamber, disposed on the upper face of the film-forming chamber and opposed to the stage. Particle traps with controllable temperatures are positioned between the vaporization chamber and the mixing chamber and on the downstream side of the mixing chamber. When forming a thin film with the apparatus, a reactive gas and/or a carrier gas are passed through the film-forming chamber while opening a valve in a by-pass line, connecting the primary side to the secondary side of the particle trap arranged at the downstream side of the mixing chamber. The valve is then closed and the film-forming operation is initiated.