Abstract: A ZnO film production method includes: disposing a substrate on an installation base; and, while supplying chlorine gas from a chlorine gas supply source to a first raw material storing part R1 and supplying oxygen gas from a third gas supply source (oxygen gas supply source) G3 into a reaction container, controlling heating units (heaters H1, H2 and H3) with a control device CONT such that temperature T1 of the first raw material storing part R1, temperature T2 of a second raw material storing part R2 and temperature T3 of the installation base on which the substrate is disposed satisfy a relationship of T1<T2<T3. Thus, according to the production method of the present disclosure, it is possible to produce a high-quality ZnO film.

Abstract: A ZnO film production method includes: disposing a substrate on an installation base; and, while supplying chlorine gas from a chlorine gas supply source to a first raw material storing part R1 and supplying oxygen gas from a third gas supply source (oxygen gas supply source) G3 into a reaction container, controlling heating units (heaters H1, H2 and H3) with a control device CONT such that temperature T1 of the first raw material storing part R1, temperature T2 of a second raw material storing part R2 and temperature T3 of the installation base on which the substrate is disposed satisfy a relationship of T1<T2<T3. Thus, according to the production method of the present disclosure, it is possible to produce a high-quality ZnO film.

Abstract: There is provided a plasma generation device, comprising: a waveguide configured to propagate a microwave; a plasma generation vessel connected to the waveguide; and a dielectric window interposed between the waveguide and the plasma generation vessel to introduce the microwave propagated by the waveguide into the plasma generation vessel. The plasma generation vessel is sphere-shaped and is disposed adjacent to a processing vessel configured to accommodate a substrate, and an interior of the plasma generation vessel is in communication with an interior of the processing vessel.

Abstract: Disclosed is a starting material for use in forming a silicon oxide film on a substrate by the CVD method, comprising a siloxane compound having a carbonyl group, wherein the starting material is decomposed by applying energy, thereby releasing CO and producing a product having no dangling bond in the chemical structure, and the product contributes to the formation of the film. As a result, a silicon oxide film having a favorable step coverage is formed.

Abstract: To provide a method for producing a filtration filter that can simplify the process for providing clean water or freshwater. By etching silicon substrate 1 using masking film formed on a surface of substrate 1 and having numerous openings to expose portions of the surface, numerous circular holes 2 with an approximate diameter of 100 nm are formed in substrate 1. Diameter (D1) at minimum-diameter portions 4 near the openings of circular holes 2 to be reduced by silica film 3 is adjusted to be 1 nm˜100 nm by depositing silica film 3 on the inner surfaces of circular holes 2.

Abstract: Disclosed is a film formation apparatus (1a) that forms a thin film upon a substrate (S), wherein partitions (41) separate the space above the substrate (S) into a plasma generation space (401) and an exhaust space (402) and extend downward from the ceiling of the processing container (10) to form an opening between the substrate (S) and the bottom end of the partitions, in which gas flows from the plasma generation space (401) to the exhaust space (402). An activating mechanism (42, 43) generates plasma by activating a first reactant gas that has been supplied to the plasma generation space (401). A second reactant gas supply section (411, 412) supplies a second reactant gas to the bottom of the plasma generation space (401), and an evacuation opening (23) evacuates the exhaust space (402) from a position that is higher than the bottom end of the partitions (41).

Abstract: Disclosed is a starting material for use in forming a silicon oxide film on a substrate by the CVD method, comprising a siloxane compound having a carbonyl group, wherein the starting material is decomposed by applying energy, thereby releasing CO and producing a product having no dangling bond in the chemical structure, and the product contributes to the formation of the film. As a result, a silicon oxide film having a favorable step coverage is formed.

Abstract: A quantum dot forming method for forming quantum dots on a surface of a substrate includes exciting a substrate surface with a laser beam having a standing wave which is irradiated from one side of the substrate along the surface of the substrate to excite the surface of the substrate at an interval of one half of a wavelength of the standing wave, and forming a quantum dot with a film differing in lattice constant from a base film forming the surface of the substrate by allowing the film differing in lattice constant to grow on the substrate to form the quantum dots in excited spots of the surface of the substrate.

Abstract: A wafer is disposed in a chamber, a plasma generating space is formed in the chamber, plasma processing is performed to the front surface of the processing object while keeping at least the front surface of the processing object in contact with the plasma generating space. The plasma processing is performed with the plasma generating space being kept in contact with at least the peripheral region of the back surface of the processing object.

Abstract: Film thickness uniformity and stoichiometry are controlled and deposition rate is increased in the chemical vapor deposition (CVD) of silicon nitride from complex gas mixtures in microwave plasmas. In Si2H6+NH3+Ar gas mixtures using a radial line slot antenna (RLSA) microwave plasma to deposit SiN by CVD, deposition rate and film uniformity are improved by limiting the amounts of atomic or molecular hydrogen from the gas mixture during the deposition process. A halogen, for example, fluorine, is added to a gas mixture of silane or disilane, ammonia and argon. The halogen scavenges hydrogen from the mixture, and prevents the hydrogen from blocking the nitrogen and silicon atoms and their fragments from bonding to the surface atoms and to grow stoichiometric silicon nitride. Adding the halogen generates free halogen radicals that react with hydrogen to create hydrogen halide, for example, HF or HCl, thereby scavenging the hydrogen.

Abstract: Film thickness uniformity and stoichiometry are controlled and deposition rate is increased in the chemical vapor deposition (CVD) of silicon nitride from complex gas mixtures in microwave plasmas. In Si2H6+NH3+Ar gas mixtures using a radial line slot antenna (RLSA) microwave plasma to deposit SiN by CVD, deposition rate and film uniformity are improved by limiting the amounts of atomic or molecular hydrogen from the gas mixture during the deposition process. A halogen, for example, fluorine, is added to a gas mixture of silane or disilane, ammonia and argon. The halogen scavenges hydrogen from the mixture, and prevents the hydrogen from blocking the nitrogen and silicon atoms and their fragments from bonding to the surface atoms and to grow stoichiometric silicon nitride. Adding the halogen generates free halogen radicals that react with hydrogen to create hydrogen halide, for example, HF or HCl, thereby scavenging the hydrogen.

Abstract: An organic material film formed on a surface of an object to be processed is cured by electron beams irradiated thereon through a hydrocarbon radical generating gas. By employing the electron beams and the hydrocarbon radical generating gas, a deterioration of a k value of the organic material film and a reduction of a chemical resistance thereof are suppressed.

Abstract: An organic material film formed on a surface of an object to be processed is cured by electron beams irradiated thereon through a hydrocarbon radical generating gas. By employing the electron beams and the hydrocarbon radical generating gas, a deterioration of a k value of the organic material film and a reduction of a chemical resistance thereof are suppressed.